git-commit-vandalism/read-cache.c

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/*
* GIT - The information manager from hell
*
* Copyright (C) Linus Torvalds, 2005
*/
#include "cache.h"
#include "config.h"
#include "diff.h"
#include "diffcore.h"
#include "tempfile.h"
#include "lockfile.h"
#include "cache-tree.h"
#include "refs.h"
#include "dir.h"
#include "object-store.h"
#include "tree.h"
#include "commit.h"
#include "blob.h"
#include "resolve-undo.h"
#include "run-command.h"
#include "strbuf.h"
#include "varint.h"
#include "split-index.h"
#include "utf8.h"
#include "fsmonitor.h"
#include "thread-utils.h"
#include "progress.h"
sparse-index: convert from full to sparse If we have a full index, then we can convert it to a sparse index by replacing directories outside of the sparse cone with sparse directory entries. The convert_to_sparse() method does this, when the situation is appropriate. For now, we avoid converting the index to a sparse index if: 1. the index is split. 2. the index is already sparse. 3. sparse-checkout is disabled. 4. sparse-checkout does not use cone mode. Finally, we currently limit the conversion to when the GIT_TEST_SPARSE_INDEX environment variable is enabled. A mode using Git config will be added in a later change. The trickiest thing about this conversion is that we might not be able to mark a directory as a sparse directory just because it is outside the sparse cone. There might be unmerged files within that directory, so we need to look for those. Also, if there is some strange reason why a file is not marked with CE_SKIP_WORKTREE, then we should give up on converting that directory. There is still hope that some of its subdirectories might be able to convert to sparse, so we keep looking deeper. The conversion process is assisted by the cache-tree extension. This is calculated from the full index if it does not already exist. We then abandon the cache-tree as it no longer applies to the newly-sparse index. Thus, this cache-tree will be recalculated in every sparse-full-sparse round-trip until we integrate the cache-tree extension with the sparse index. Some Git commands use the index after writing it. For example, 'git add' will update the index, then write it to disk, then read its entries to report information. To keep the in-memory index in a full state after writing, we re-expand it to a full one after the write. This is wasteful for commands that only write the index and do not read from it again, but that is only the case until we make those commands "sparse aware." We can compare the behavior of the sparse-index in t1092-sparse-checkout-compability.sh by using GIT_TEST_SPARSE_INDEX=1 when operating on the 'sparse-index' repo. We can also compare the two sparse repos directly, such as comparing their indexes (when expanded to full in the case of the 'sparse-index' repo). We also verify that the index is actually populated with sparse directory entries. The 'checkout and reset (mixed)' test is marked for failure when comparing a sparse repo to a full repo, but we can compare the two sparse-checkout cases directly to ensure that we are not changing the behavior when using a sparse index. Signed-off-by: Derrick Stolee <dstolee@microsoft.com> Signed-off-by: Junio C Hamano <gitster@pobox.com>
2021-03-30 15:10:55 +02:00
#include "sparse-index.h"
read-cache: use hashfile instead of git_hash_ctx The do_write_index() method in read-cache.c has its own hashing logic and buffering mechanism. Specifically, the ce_write() method was introduced by 4990aadc (Speed up index file writing by chunking it nicely, 2005-04-20) and similar mechanisms were introduced a few months later in c38138cd (git-pack-objects: write the pack files with a SHA1 csum, 2005-06-26). Based on the timing, in the early days of the Git codebase, I figured that these roughly equivalent code paths were never unified only because it got lost in the shuffle. The hashfile API has since been used extensively in other file formats, such as pack-indexes, multi-pack-indexes, and commit-graphs. Therefore, it seems prudent to unify the index writing code to use the same mechanism. I discovered this disparity while trying to create a new index format that uses the chunk-format API. That API uses a hashfile as its base, so it is incompatible with the custom code in read-cache.c. This rewrite is rather straightforward. It replaces all writes to the temporary file with writes to the hashfile struct. This takes care of many of the direct interactions with the_hash_algo. There are still some git_hash_ctx uses remaining: the extension headers are hashed for use in the End of Index Entries (EOIE) extension. This use of the git_hash_ctx is left as-is. There are multiple reasons to not use a hashfile here, including the fact that the data is not actually writing to a file, just a hash computation. These hashes do not block our adoption of the chunk-format API in a future change to the index, so leave it as-is. The internals of the algorithms are mostly identical. Previously, the hashfile API used a smaller 8KB buffer instead of the 128KB buffer from read-cache.c. The previous change already unified these sizes. There is one subtle point: we do not pass the CSUM_FSYNC to the finalize_hashfile() method, which differs from most consumers of the hashfile API. The extra fsync() call indicated by this flag causes a significant peformance degradation that is noticeable for quick commands that write the index, such as "git add". Other consumers can absorb this cost with their more complicated data structure organization, and further writing structures such as pack-files and commit-graphs is rarely in the critical path for common user interactions. Some static methods become orphaned in this diff, so I marked them as MAYBE_UNUSED. The diff is much harder to read if they are deleted during this change. Instead, they will be deleted in the following change. In addition to the test suite passing, I computed indexes using the previous binaries and the binaries compiled after this change, and found the index data to be exactly equal. Finally, I did extensive performance testing of "git update-index --force-write" on repos of various sizes, including one with over 2 million paths at HEAD. These tests demonstrated less than 1% difference in behavior. As expected, the performance should be considered unchanged. The previous changes to increase the hashfile buffer size from 8K to 128K ensured this change would not create a peformance regression. Signed-off-by: Derrick Stolee <dstolee@microsoft.com> Signed-off-by: Junio C Hamano <gitster@pobox.com>
2021-05-18 20:32:47 +02:00
#include "csum-file.h"
#include "promisor-remote.h"
/* Mask for the name length in ce_flags in the on-disk index */
#define CE_NAMEMASK (0x0fff)
/* Index extensions.
*
* The first letter should be 'A'..'Z' for extensions that are not
* necessary for a correct operation (i.e. optimization data).
* When new extensions are added that _needs_ to be understood in
* order to correctly interpret the index file, pick character that
* is outside the range, to cause the reader to abort.
*/
#define CACHE_EXT(s) ( (s[0]<<24)|(s[1]<<16)|(s[2]<<8)|(s[3]) )
#define CACHE_EXT_TREE 0x54524545 /* "TREE" */
#define CACHE_EXT_RESOLVE_UNDO 0x52455543 /* "REUC" */
#define CACHE_EXT_LINK 0x6c696e6b /* "link" */
#define CACHE_EXT_UNTRACKED 0x554E5452 /* "UNTR" */
#define CACHE_EXT_FSMONITOR 0x46534D4E /* "FSMN" */
#define CACHE_EXT_ENDOFINDEXENTRIES 0x454F4945 /* "EOIE" */
#define CACHE_EXT_INDEXENTRYOFFSETTABLE 0x49454F54 /* "IEOT" */
#define CACHE_EXT_SPARSE_DIRECTORIES 0x73646972 /* "sdir" */
/* changes that can be kept in $GIT_DIR/index (basically all extensions) */
#define EXTMASK (RESOLVE_UNDO_CHANGED | CACHE_TREE_CHANGED | \
CE_ENTRY_ADDED | CE_ENTRY_REMOVED | CE_ENTRY_CHANGED | \
SPLIT_INDEX_ORDERED | UNTRACKED_CHANGED | FSMONITOR_CHANGED)
block alloc: allocate cache entries from mem_pool When reading large indexes from disk, a portion of the time is dominated in malloc() calls. This can be mitigated by allocating a large block of memory and manage it ourselves via memory pools. This change moves the cache entry allocation to be on top of memory pools. Design: The index_state struct will gain a notion of an associated memory_pool from which cache_entries will be allocated from. When reading in the index from disk, we have information on the number of entries and their size, which can guide us in deciding how large our initial memory allocation should be. When an index is discarded, the associated memory_pool will be discarded as well - so the lifetime of a cache_entry is tied to the lifetime of the index_state that it was allocated for. In the case of a Split Index, the following rules are followed. 1st, some terminology is defined: Terminology: - 'the_index': represents the logical view of the index - 'split_index': represents the "base" cache entries. Read from the split index file. 'the_index' can reference a single split_index, as well as cache_entries from the split_index. `the_index` will be discarded before the `split_index` is. This means that when we are allocating cache_entries in the presence of a split index, we need to allocate the entries from the `split_index`'s memory pool. This allows us to follow the pattern that `the_index` can reference cache_entries from the `split_index`, and that the cache_entries will not be freed while they are still being referenced. Managing transient cache_entry structs: Cache entries are usually allocated for an index, but this is not always the case. Cache entries are sometimes allocated because this is the type that the existing checkout_entry function works with. Because of this, the existing code needs to handle cache entries associated with an index / memory pool, and those that only exist transiently. Several strategies were contemplated around how to handle this: Chosen approach: An extra field was added to the cache_entry type to track whether the cache_entry was allocated from a memory pool or not. This is currently an int field, as there are no more available bits in the existing ce_flags bit field. If / when more bits are needed, this new field can be turned into a proper bit field. Alternatives: 1) Do not include any information about how the cache_entry was allocated. Calling code would be responsible for tracking whether the cache_entry needed to be freed or not. Pro: No extra memory overhead to track this state Con: Extra complexity in callers to handle this correctly. The extra complexity and burden to not regress this behavior in the future was more than we wanted. 2) cache_entry would gain knowledge about which mem_pool allocated it Pro: Could (potentially) do extra logic to know when a mem_pool no longer had references to any cache_entry Con: cache_entry would grow heavier by a pointer, instead of int We didn't see a tangible benefit to this approach 3) Do not add any extra information to a cache_entry, but when freeing a cache entry, check if the memory exists in a region managed by existing mem_pools. Pro: No extra memory overhead to track state Con: Extra computation is performed when freeing cache entries We decided tracking and iterating over known memory pool regions was less desirable than adding an extra field to track this stae. Signed-off-by: Jameson Miller <jamill@microsoft.com> Signed-off-by: Junio C Hamano <gitster@pobox.com>
2018-07-02 21:49:37 +02:00
/*
* This is an estimate of the pathname length in the index. We use
* this for V4 index files to guess the un-deltafied size of the index
* in memory because of pathname deltafication. This is not required
* for V2/V3 index formats because their pathnames are not compressed.
* If the initial amount of memory set aside is not sufficient, the
* mem pool will allocate extra memory.
*/
#define CACHE_ENTRY_PATH_LENGTH 80
enum index_search_mode {
NO_EXPAND_SPARSE = 0,
EXPAND_SPARSE = 1
};
block alloc: allocate cache entries from mem_pool When reading large indexes from disk, a portion of the time is dominated in malloc() calls. This can be mitigated by allocating a large block of memory and manage it ourselves via memory pools. This change moves the cache entry allocation to be on top of memory pools. Design: The index_state struct will gain a notion of an associated memory_pool from which cache_entries will be allocated from. When reading in the index from disk, we have information on the number of entries and their size, which can guide us in deciding how large our initial memory allocation should be. When an index is discarded, the associated memory_pool will be discarded as well - so the lifetime of a cache_entry is tied to the lifetime of the index_state that it was allocated for. In the case of a Split Index, the following rules are followed. 1st, some terminology is defined: Terminology: - 'the_index': represents the logical view of the index - 'split_index': represents the "base" cache entries. Read from the split index file. 'the_index' can reference a single split_index, as well as cache_entries from the split_index. `the_index` will be discarded before the `split_index` is. This means that when we are allocating cache_entries in the presence of a split index, we need to allocate the entries from the `split_index`'s memory pool. This allows us to follow the pattern that `the_index` can reference cache_entries from the `split_index`, and that the cache_entries will not be freed while they are still being referenced. Managing transient cache_entry structs: Cache entries are usually allocated for an index, but this is not always the case. Cache entries are sometimes allocated because this is the type that the existing checkout_entry function works with. Because of this, the existing code needs to handle cache entries associated with an index / memory pool, and those that only exist transiently. Several strategies were contemplated around how to handle this: Chosen approach: An extra field was added to the cache_entry type to track whether the cache_entry was allocated from a memory pool or not. This is currently an int field, as there are no more available bits in the existing ce_flags bit field. If / when more bits are needed, this new field can be turned into a proper bit field. Alternatives: 1) Do not include any information about how the cache_entry was allocated. Calling code would be responsible for tracking whether the cache_entry needed to be freed or not. Pro: No extra memory overhead to track this state Con: Extra complexity in callers to handle this correctly. The extra complexity and burden to not regress this behavior in the future was more than we wanted. 2) cache_entry would gain knowledge about which mem_pool allocated it Pro: Could (potentially) do extra logic to know when a mem_pool no longer had references to any cache_entry Con: cache_entry would grow heavier by a pointer, instead of int We didn't see a tangible benefit to this approach 3) Do not add any extra information to a cache_entry, but when freeing a cache entry, check if the memory exists in a region managed by existing mem_pools. Pro: No extra memory overhead to track state Con: Extra computation is performed when freeing cache entries We decided tracking and iterating over known memory pool regions was less desirable than adding an extra field to track this stae. Signed-off-by: Jameson Miller <jamill@microsoft.com> Signed-off-by: Junio C Hamano <gitster@pobox.com>
2018-07-02 21:49:37 +02:00
static inline struct cache_entry *mem_pool__ce_alloc(struct mem_pool *mem_pool, size_t len)
{
struct cache_entry *ce;
ce = mem_pool_alloc(mem_pool, cache_entry_size(len));
ce->mem_pool_allocated = 1;
return ce;
}
static inline struct cache_entry *mem_pool__ce_calloc(struct mem_pool *mem_pool, size_t len)
{
struct cache_entry * ce;
ce = mem_pool_calloc(mem_pool, 1, cache_entry_size(len));
ce->mem_pool_allocated = 1;
return ce;
}
static struct mem_pool *find_mem_pool(struct index_state *istate)
{
struct mem_pool **pool_ptr;
if (istate->split_index && istate->split_index->base)
pool_ptr = &istate->split_index->base->ce_mem_pool;
else
pool_ptr = &istate->ce_mem_pool;
mem-pool: use more standard initialization and finalization A typical memory type, such as strbuf, hashmap, or string_list can be stored on the stack or embedded within another structure. mem_pool cannot be, because of how mem_pool_init() and mem_pool_discard() are written. mem_pool_init() does essentially the following (simplified for purposes of explanation here): void mem_pool_init(struct mem_pool **pool...) { *pool = xcalloc(1, sizeof(*pool)); It seems weird to require that mem_pools can only be accessed through a pointer. It also seems slightly dangerous: unlike strbuf_release() or strbuf_reset() or string_list_clear(), all of which put the data structure into a state where it can be re-used after the call, mem_pool_discard(pool) will leave pool pointing at free'd memory. read-cache (and split-index) are the only current users of mem_pools, and they haven't fallen into a use-after-free mistake here, but it seems likely to be problematic for future users especially since several of the current callers of mem_pool_init() will only call it when the mem_pool* is not already allocated (i.e. is NULL). This type of mechanism also prevents finding synchronization points where one can free existing memory and then resume more operations. It would be natural at such points to run something like mem_pool_discard(pool...); and, if necessary, mem_pool_init(&pool...); and then carry on continuing to use the pool. However, this fails badly if several objects had a copy of the value of pool from before these commands; in such a case, those objects won't get the updated value of pool that mem_pool_init() overwrites pool with and they'll all instead be reading and writing from free'd memory. Modify mem_pool_init()/mem_pool_discard() to behave more like strbuf_init()/strbuf_release() or string_list_init()/string_list_clear() In particular: (1) make mem_pool_init() just take a mem_pool* and have it only worry about allocating struct mp_blocks, not the struct mem_pool itself, (2) make mem_pool_discard() free the memory that the pool was responsible for, but leave it in a state where it can be used to allocate more memory afterward (without the need to call mem_pool_init() again). Signed-off-by: Elijah Newren <newren@gmail.com> Signed-off-by: Junio C Hamano <gitster@pobox.com>
2020-08-15 19:37:56 +02:00
if (!*pool_ptr) {
*pool_ptr = xmalloc(sizeof(**pool_ptr));
mem_pool_init(*pool_ptr, 0);
}
block alloc: allocate cache entries from mem_pool When reading large indexes from disk, a portion of the time is dominated in malloc() calls. This can be mitigated by allocating a large block of memory and manage it ourselves via memory pools. This change moves the cache entry allocation to be on top of memory pools. Design: The index_state struct will gain a notion of an associated memory_pool from which cache_entries will be allocated from. When reading in the index from disk, we have information on the number of entries and their size, which can guide us in deciding how large our initial memory allocation should be. When an index is discarded, the associated memory_pool will be discarded as well - so the lifetime of a cache_entry is tied to the lifetime of the index_state that it was allocated for. In the case of a Split Index, the following rules are followed. 1st, some terminology is defined: Terminology: - 'the_index': represents the logical view of the index - 'split_index': represents the "base" cache entries. Read from the split index file. 'the_index' can reference a single split_index, as well as cache_entries from the split_index. `the_index` will be discarded before the `split_index` is. This means that when we are allocating cache_entries in the presence of a split index, we need to allocate the entries from the `split_index`'s memory pool. This allows us to follow the pattern that `the_index` can reference cache_entries from the `split_index`, and that the cache_entries will not be freed while they are still being referenced. Managing transient cache_entry structs: Cache entries are usually allocated for an index, but this is not always the case. Cache entries are sometimes allocated because this is the type that the existing checkout_entry function works with. Because of this, the existing code needs to handle cache entries associated with an index / memory pool, and those that only exist transiently. Several strategies were contemplated around how to handle this: Chosen approach: An extra field was added to the cache_entry type to track whether the cache_entry was allocated from a memory pool or not. This is currently an int field, as there are no more available bits in the existing ce_flags bit field. If / when more bits are needed, this new field can be turned into a proper bit field. Alternatives: 1) Do not include any information about how the cache_entry was allocated. Calling code would be responsible for tracking whether the cache_entry needed to be freed or not. Pro: No extra memory overhead to track this state Con: Extra complexity in callers to handle this correctly. The extra complexity and burden to not regress this behavior in the future was more than we wanted. 2) cache_entry would gain knowledge about which mem_pool allocated it Pro: Could (potentially) do extra logic to know when a mem_pool no longer had references to any cache_entry Con: cache_entry would grow heavier by a pointer, instead of int We didn't see a tangible benefit to this approach 3) Do not add any extra information to a cache_entry, but when freeing a cache entry, check if the memory exists in a region managed by existing mem_pools. Pro: No extra memory overhead to track state Con: Extra computation is performed when freeing cache entries We decided tracking and iterating over known memory pool regions was less desirable than adding an extra field to track this stae. Signed-off-by: Jameson Miller <jamill@microsoft.com> Signed-off-by: Junio C Hamano <gitster@pobox.com>
2018-07-02 21:49:37 +02:00
return *pool_ptr;
}
static const char *alternate_index_output;
static void set_index_entry(struct index_state *istate, int nr, struct cache_entry *ce)
{
if (S_ISSPARSEDIR(ce->ce_mode))
istate->sparse_index = 1;
istate->cache[nr] = ce;
add_name_hash(istate, ce);
}
Create pathname-based hash-table lookup into index This creates a hash index of every single file added to the index. Right now that hash index isn't actually used for much: I implemented a "cache_name_exists()" function that uses it to efficiently look up a filename in the index without having to do the O(logn) binary search, but quite frankly, that's not why this patch is interesting. No, the whole and only reason to create the hash of the filenames in the index is that by modifying the hash function, you can fairly easily do things like making it always hash equivalent names into the same bucket. That, in turn, means that suddenly questions like "does this name exist in the index under an _equivalent_ name?" becomes much much cheaper. Guiding principles behind this patch: - it shouldn't be too costly. In fact, my primary goal here was to actually speed up "git commit" with a fully populated kernel tree, by being faster at checking whether a file already existed in the index. I did succeed, but only barely: Best before: [torvalds@woody linux]$ time git commit > /dev/null real 0m0.255s user 0m0.168s sys 0m0.088s Best after: [torvalds@woody linux]$ time ~/git/git commit > /dev/null real 0m0.233s user 0m0.144s sys 0m0.088s so some things are actually faster (~8%). Caveat: that's really the best case. Other things are invariably going to be slightly slower, since we populate that index cache, and quite frankly, few things really use it to look things up. That said, the cost is really quite small. The worst case is probably doing a "git ls-files", which will do very little except puopulate the index, and never actually looks anything up in it, just lists it. Before: [torvalds@woody linux]$ time git ls-files > /dev/null real 0m0.016s user 0m0.016s sys 0m0.000s After: [torvalds@woody linux]$ time ~/git/git ls-files > /dev/null real 0m0.021s user 0m0.012s sys 0m0.008s and while the thing has really gotten relatively much slower, we're still talking about something almost unmeasurable (eg 5ms). And that really should be pretty much the worst case. So we lose 5ms on one "benchmark", but win 22ms on another. Pick your poison - this patch has the advantage that it will _likely_ speed up the cases that are complex and expensive more than it slows down the cases that are already so fast that nobody cares. But if you look at relative speedups/slowdowns, it doesn't look so good. - It should be simple and clean The code may be a bit subtle (the reasons I do hash removal the way I do etc), but it re-uses the existing hash.c files, so it really is fairly small and straightforward apart from a few odd details. Now, this patch on its own doesn't really do much, but I think it's worth looking at, if only because if done correctly, the name hashing really can make an improvement to the whole issue of "do we have a filename that looks like this in the index already". And at least it gets real testing by being used even by default (ie there is a real use-case for it even without any insane filesystems). NOTE NOTE NOTE! The current hash is a joke. I'm ashamed of it, I'm just not ashamed of it enough to really care. I took all the numbers out of my nether regions - I'm sure it's good enough that it works in practice, but the whole point was that you can make a really much fancier hash that hashes characters not directly, but by their upper-case value or something like that, and thus you get a case-insensitive hash, while still keeping the name and the index itself totally case sensitive. Signed-off-by: Linus Torvalds <torvalds@linux-foundation.org> Signed-off-by: Junio C Hamano <gitster@pobox.com>
2008-01-23 03:41:14 +01:00
static void replace_index_entry(struct index_state *istate, int nr, struct cache_entry *ce)
{
struct cache_entry *old = istate->cache[nr];
replace_index_entry_in_base(istate, old, ce);
name-hash.c: fix endless loop with core.ignorecase=true With core.ignorecase=true, name-hash.c builds a case insensitive index of all tracked directories. Currently, the existing cache entry structures are added multiple times to the same hashtable (with different name lengths and hash codes). However, there's only one dir_next pointer, which gets completely messed up in case of hash collisions. In the worst case, this causes an endless loop if ce == ce->dir_next (see t7062). Use a separate hashtable and separate structures for the directory index so that each directory entry has its own next pointer. Use reference counting to track which directory entry contains files. There are only slight changes to the name-hash.c API: - new free_name_hash() used by read_cache.c::discard_index() - remove_name_hash() takes an additional index_state parameter - index_name_exists() for a directory (trailing '/') may return a cache entry that has been removed (CE_UNHASHED). This is not a problem as the return value is only used to check if the directory exists (dir.c) or to normalize casing of directory names (read-cache.c). Getting rid of cache_entry.dir_next reduces memory consumption, especially with core.ignorecase=false (which doesn't use that member at all). With core.ignorecase=true, building the directory index is slightly faster as we add / check the parent directory first (instead of going through all directory levels for each file in the index). E.g. with WebKit (~200k files, ~7k dirs), time spent in lazy_init_name_hash is reduced from 176ms to 130ms. Signed-off-by: Karsten Blees <blees@dcon.de> Signed-off-by: Junio C Hamano <gitster@pobox.com>
2013-02-28 00:57:48 +01:00
remove_name_hash(istate, old);
block alloc: add lifecycle APIs for cache_entry structs It has been observed that the time spent loading an index with a large number of entries is partly dominated by malloc() calls. This change is in preparation for using memory pools to reduce the number of malloc() calls made to allocate cahce entries when loading an index. Add an API to allocate and discard cache entries, abstracting the details of managing the memory backing the cache entries. This commit does actually change how memory is managed - this will be done in a later commit in the series. This change makes the distinction between cache entries that are associated with an index and cache entries that are not associated with an index. A main use of cache entries is with an index, and we can optimize the memory management around this. We still have other cases where a cache entry is not persisted with an index, and so we need to handle the "transient" use case as well. To keep the congnitive overhead of managing the cache entries, there will only be a single discard function. This means there must be enough information kept with the cache entry so that we know how to discard them. A summary of the main functions in the API is: make_cache_entry: create cache entry for use in an index. Uses specified parameters to populate cache_entry fields. make_empty_cache_entry: Create an empty cache entry for use in an index. Returns cache entry with empty fields. make_transient_cache_entry: create cache entry that is not used in an index. Uses specified parameters to populate cache_entry fields. make_empty_transient_cache_entry: create cache entry that is not used in an index. Returns cache entry with empty fields. discard_cache_entry: A single function that knows how to discard a cache entry regardless of how it was allocated. Signed-off-by: Jameson Miller <jamill@microsoft.com> Signed-off-by: Junio C Hamano <gitster@pobox.com>
2018-07-02 21:49:31 +02:00
discard_cache_entry(old);
ce->ce_flags &= ~CE_HASHED;
Fix name re-hashing semantics We handled the case of removing and re-inserting cache entries badly, which is something that merging commonly needs to do (removing the different stages, and then re-inserting one of them as the merged state). We even had a rather ugly special case for this failure case, where replace_index_entry() basically turned itself into a no-op if the new and the old entries were the same, exactly because the hash routines didn't handle it on their own. So what this patch does is to not just have the UNHASHED bit, but a HASHED bit too, and when you insert an entry into the name hash, that involves: - clear the UNHASHED bit, because now it's valid again for lookup (which is really all that UNHASHED meant) - if we're being lazy, we're done here (but we still want to clear the UNHASHED bit regardless of lazy mode, since we can become unlazy later, and so we need the UNHASHED bit to always be set correctly, even if we never actually insert the entry into the hash list) - if it was already hashed, we just leave it on the list - otherwise mark it HASHED and insert it into the list this all means that unhashing and rehashing a name all just works automatically. Obviously, you cannot change the name of an entry (that would be a serious bug), but nothing can validly do that anyway (you'd have to allocate a new struct cache_entry anyway since the name length could change), so that's not a new limitation. The code actually gets simpler in many ways, although the lazy hashing does mean that there are a few odd cases (ie something can be marked unhashed even though it was never on the hash in the first place, and isn't actually marked hashed!). Signed-off-by: Linus Torvalds <torvalds@linux-foundation.org> Signed-off-by: Junio C Hamano <gitster@pobox.com>
2008-02-23 05:37:40 +01:00
set_index_entry(istate, nr, ce);
ce->ce_flags |= CE_UPDATE_IN_BASE;
mark_fsmonitor_invalid(istate, ce);
istate->cache_changed |= CE_ENTRY_CHANGED;
Create pathname-based hash-table lookup into index This creates a hash index of every single file added to the index. Right now that hash index isn't actually used for much: I implemented a "cache_name_exists()" function that uses it to efficiently look up a filename in the index without having to do the O(logn) binary search, but quite frankly, that's not why this patch is interesting. No, the whole and only reason to create the hash of the filenames in the index is that by modifying the hash function, you can fairly easily do things like making it always hash equivalent names into the same bucket. That, in turn, means that suddenly questions like "does this name exist in the index under an _equivalent_ name?" becomes much much cheaper. Guiding principles behind this patch: - it shouldn't be too costly. In fact, my primary goal here was to actually speed up "git commit" with a fully populated kernel tree, by being faster at checking whether a file already existed in the index. I did succeed, but only barely: Best before: [torvalds@woody linux]$ time git commit > /dev/null real 0m0.255s user 0m0.168s sys 0m0.088s Best after: [torvalds@woody linux]$ time ~/git/git commit > /dev/null real 0m0.233s user 0m0.144s sys 0m0.088s so some things are actually faster (~8%). Caveat: that's really the best case. Other things are invariably going to be slightly slower, since we populate that index cache, and quite frankly, few things really use it to look things up. That said, the cost is really quite small. The worst case is probably doing a "git ls-files", which will do very little except puopulate the index, and never actually looks anything up in it, just lists it. Before: [torvalds@woody linux]$ time git ls-files > /dev/null real 0m0.016s user 0m0.016s sys 0m0.000s After: [torvalds@woody linux]$ time ~/git/git ls-files > /dev/null real 0m0.021s user 0m0.012s sys 0m0.008s and while the thing has really gotten relatively much slower, we're still talking about something almost unmeasurable (eg 5ms). And that really should be pretty much the worst case. So we lose 5ms on one "benchmark", but win 22ms on another. Pick your poison - this patch has the advantage that it will _likely_ speed up the cases that are complex and expensive more than it slows down the cases that are already so fast that nobody cares. But if you look at relative speedups/slowdowns, it doesn't look so good. - It should be simple and clean The code may be a bit subtle (the reasons I do hash removal the way I do etc), but it re-uses the existing hash.c files, so it really is fairly small and straightforward apart from a few odd details. Now, this patch on its own doesn't really do much, but I think it's worth looking at, if only because if done correctly, the name hashing really can make an improvement to the whole issue of "do we have a filename that looks like this in the index already". And at least it gets real testing by being used even by default (ie there is a real use-case for it even without any insane filesystems). NOTE NOTE NOTE! The current hash is a joke. I'm ashamed of it, I'm just not ashamed of it enough to really care. I took all the numbers out of my nether regions - I'm sure it's good enough that it works in practice, but the whole point was that you can make a really much fancier hash that hashes characters not directly, but by their upper-case value or something like that, and thus you get a case-insensitive hash, while still keeping the name and the index itself totally case sensitive. Signed-off-by: Linus Torvalds <torvalds@linux-foundation.org> Signed-off-by: Junio C Hamano <gitster@pobox.com>
2008-01-23 03:41:14 +01:00
}
void rename_index_entry_at(struct index_state *istate, int nr, const char *new_name)
{
struct cache_entry *old_entry = istate->cache[nr], *new_entry;
int namelen = strlen(new_name);
block alloc: add lifecycle APIs for cache_entry structs It has been observed that the time spent loading an index with a large number of entries is partly dominated by malloc() calls. This change is in preparation for using memory pools to reduce the number of malloc() calls made to allocate cahce entries when loading an index. Add an API to allocate and discard cache entries, abstracting the details of managing the memory backing the cache entries. This commit does actually change how memory is managed - this will be done in a later commit in the series. This change makes the distinction between cache entries that are associated with an index and cache entries that are not associated with an index. A main use of cache entries is with an index, and we can optimize the memory management around this. We still have other cases where a cache entry is not persisted with an index, and so we need to handle the "transient" use case as well. To keep the congnitive overhead of managing the cache entries, there will only be a single discard function. This means there must be enough information kept with the cache entry so that we know how to discard them. A summary of the main functions in the API is: make_cache_entry: create cache entry for use in an index. Uses specified parameters to populate cache_entry fields. make_empty_cache_entry: Create an empty cache entry for use in an index. Returns cache entry with empty fields. make_transient_cache_entry: create cache entry that is not used in an index. Uses specified parameters to populate cache_entry fields. make_empty_transient_cache_entry: create cache entry that is not used in an index. Returns cache entry with empty fields. discard_cache_entry: A single function that knows how to discard a cache entry regardless of how it was allocated. Signed-off-by: Jameson Miller <jamill@microsoft.com> Signed-off-by: Junio C Hamano <gitster@pobox.com>
2018-07-02 21:49:31 +02:00
new_entry = make_empty_cache_entry(istate, namelen);
copy_cache_entry(new_entry, old_entry);
new_entry->ce_flags &= ~CE_HASHED;
new_entry->ce_namelen = namelen;
new_entry->index = 0;
memcpy(new_entry->name, new_name, namelen + 1);
cache_tree_invalidate_path(istate, old_entry->name);
untracked_cache_remove_from_index(istate, old_entry->name);
remove_index_entry_at(istate, nr);
add_index_entry(istate, new_entry, ADD_CACHE_OK_TO_ADD|ADD_CACHE_OK_TO_REPLACE);
}
void fill_stat_data(struct stat_data *sd, struct stat *st)
{
sd->sd_ctime.sec = (unsigned int)st->st_ctime;
sd->sd_mtime.sec = (unsigned int)st->st_mtime;
sd->sd_ctime.nsec = ST_CTIME_NSEC(*st);
sd->sd_mtime.nsec = ST_MTIME_NSEC(*st);
sd->sd_dev = st->st_dev;
sd->sd_ino = st->st_ino;
sd->sd_uid = st->st_uid;
sd->sd_gid = st->st_gid;
sd->sd_size = st->st_size;
}
int match_stat_data(const struct stat_data *sd, struct stat *st)
{
int changed = 0;
if (sd->sd_mtime.sec != (unsigned int)st->st_mtime)
changed |= MTIME_CHANGED;
if (trust_ctime && check_stat &&
sd->sd_ctime.sec != (unsigned int)st->st_ctime)
changed |= CTIME_CHANGED;
#ifdef USE_NSEC
if (check_stat && sd->sd_mtime.nsec != ST_MTIME_NSEC(*st))
changed |= MTIME_CHANGED;
if (trust_ctime && check_stat &&
sd->sd_ctime.nsec != ST_CTIME_NSEC(*st))
changed |= CTIME_CHANGED;
#endif
if (check_stat) {
if (sd->sd_uid != (unsigned int) st->st_uid ||
sd->sd_gid != (unsigned int) st->st_gid)
changed |= OWNER_CHANGED;
if (sd->sd_ino != (unsigned int) st->st_ino)
changed |= INODE_CHANGED;
}
#ifdef USE_STDEV
/*
* st_dev breaks on network filesystems where different
* clients will have different views of what "device"
* the filesystem is on
*/
if (check_stat && sd->sd_dev != (unsigned int) st->st_dev)
changed |= INODE_CHANGED;
#endif
if (sd->sd_size != (unsigned int) st->st_size)
changed |= DATA_CHANGED;
return changed;
}
/*
* This only updates the "non-critical" parts of the directory
* cache, ie the parts that aren't tracked by GIT, and only used
* to validate the cache.
*/
void fill_stat_cache_info(struct index_state *istate, struct cache_entry *ce, struct stat *st)
{
fill_stat_data(&ce->ce_stat_data, st);
"Assume unchanged" git This adds "assume unchanged" logic, started by this message in the list discussion recently: <Pine.LNX.4.64.0601311807470.7301@g5.osdl.org> This is a workaround for filesystems that do not have lstat() that is quick enough for the index mechanism to take advantage of. On the paths marked as "assumed to be unchanged", the user needs to explicitly use update-index to register the object name to be in the next commit. You can use two new options to update-index to set and reset the CE_VALID bit: git-update-index --assume-unchanged path... git-update-index --no-assume-unchanged path... These forms manipulate only the CE_VALID bit; it does not change the object name recorded in the index file. Nor they add a new entry to the index. When the configuration variable "core.ignorestat = true" is set, the index entries are marked with CE_VALID bit automatically after: - update-index to explicitly register the current object name to the index file. - when update-index --refresh finds the path to be up-to-date. - when tools like read-tree -u and apply --index update the working tree file and register the current object name to the index file. The flag is dropped upon read-tree that does not check out the index entry. This happens regardless of the core.ignorestat settings. Index entries marked with CE_VALID bit are assumed to be unchanged most of the time. However, there are cases that CE_VALID bit is ignored for the sake of safety and usability: - while "git-read-tree -m" or git-apply need to make sure that the paths involved in the merge do not have local modifications. This sacrifices performance for safety. - when git-checkout-index -f -q -u -a tries to see if it needs to checkout the paths. Otherwise you can never check anything out ;-). - when git-update-index --really-refresh (a new flag) tries to see if the index entry is up to date. You can start with everything marked as CE_VALID and run this once to drop CE_VALID bit for paths that are modified. Most notably, "update-index --refresh" honours CE_VALID and does not actively stat, so after you modified a file in the working tree, update-index --refresh would not notice until you tell the index about it with "git-update-index path" or "git-update-index --no-assume-unchanged path". This version is not expected to be perfect. I think diff between index and/or tree and working files may need some adjustment, and there probably needs other cases we should automatically unmark paths that are marked to be CE_VALID. But the basics seem to work, and ready to be tested by people who asked for this feature. Signed-off-by: Junio C Hamano <junkio@cox.net>
2006-02-09 06:15:24 +01:00
if (assume_unchanged)
ce->ce_flags |= CE_VALID;
if (S_ISREG(st->st_mode)) {
ce_mark_uptodate(ce);
mark_fsmonitor_valid(): mark the index as changed if needed Without this bug fix, t7519's four "status doesn't detect unreported modifications" test cases would fail occasionally (and, oddly enough, *a lot* more frequently on Windows). The reason is that these test cases intentionally use the side effect of `git status` to re-write the index if any updates were detected: they first clean the worktree, run `git status` to update the index as well as show the output to the casual reader, then make the worktree dirty again and expect no changes to reported if running with a mocked fsmonitor hook. The problem with this strategy was that the index was written during said `git status` on the clean worktree for the *wrong* reason: not because the index was marked as changed (it wasn't), but because the recorded mtimes were racy with the index' own mtime. As the mtime granularity on Windows is 100 nanoseconds (see e.g. https://docs.microsoft.com/en-us/windows/desktop/SysInfo/file-times), the mtimes of the files are often enough *not* racy with the index', so that that `git status` call currently does not always update the index (including the fsmonitor extension), causing the test case to fail. The obvious fix: if we change *any* index entry's `CE_FSMONITOR_VALID` flag, we should also mark the index as changed. That will cause the index to be written upon `git status`, *including* an updated fsmonitor extension. Side note: Even though the reader might think that the t7519 issue should be *much* more prevalent on Linux, given that the ext4 filesystem (that seems to be used by every Linux distribution) stores mtimes in nanosecond precision. However, ext4 uses `current_kernel_time()` (see https://unix.stackexchange.com/questions/11599#comment762968_11599; it is *amazingly* hard to find any proper source of information about such ext4 questions) whose accuracy seems to depend on many factors but is safely worse than the 100-nanosecond granularity of NTFS (again, it is *horribly* hard to find anything remotely authoritative about this question). So it seems that the racy index condition that hid the bug fixed by this patch simply is a lot more likely on Linux than on Windows. But not impossible ;-) Signed-off-by: Johannes Schindelin <johannes.schindelin@gmx.de> Signed-off-by: Junio C Hamano <gitster@pobox.com>
2019-05-24 14:23:48 +02:00
mark_fsmonitor_valid(istate, ce);
}
}
static int ce_compare_data(struct index_state *istate,
const struct cache_entry *ce,
struct stat *st)
Racy GIT This fixes the longstanding "Racy GIT" problem, which was pretty much there from the beginning of time, but was first demonstrated by Pasky in this message on October 24, 2005: http://marc.theaimsgroup.com/?l=git&m=113014629716878 If you run the following sequence of commands: echo frotz >infocom git update-index --add infocom echo xyzzy >infocom so that the second update to file "infocom" does not change st_mtime, what is recorded as the stat information for the cache entry "infocom" exactly matches what is on the filesystem (owner, group, inum, mtime, ctime, mode, length). After this sequence, we incorrectly think "infocom" file still has string "frotz" in it, and get really confused. E.g. git-diff-files would say there is no change, git-update-index --refresh would not even look at the filesystem to correct the situation. Some ways of working around this issue were already suggested by Linus in the same thread on the same day, including waiting until the next second before returning from update-index if a cache entry written out has the current timestamp, but that means we can make at most one commit per second, and given that the e-mail patch workflow used by Linus needs to process at least 5 commits per second, it is not an acceptable solution. Linus notes that git-apply is primarily used to update the index while processing e-mailed patches, which is true, and git-apply's up-to-date check is fooled by the same problem but luckily in the other direction, so it is not really a big issue, but still it is disturbing. The function ce_match_stat() is called to bypass the comparison against filesystem data when the stat data recorded in the cache entry matches what stat() returns from the filesystem. This patch tackles the problem by changing it to actually go to the filesystem data for cache entries that have the same mtime as the index file itself. This works as long as the index file and working tree files are on the filesystems that share the same monotonic clock. Files on network mounted filesystems sometimes get skewed timestamps compared to "date" output, but as long as working tree files' timestamps are skewed the same way as the index file's, this approach still works. The only problematic files are the ones that have the same timestamp as the index file's, because two file updates that sandwitch the index file update must happen within the same second to trigger the problem. Signed-off-by: Junio C Hamano <junkio@cox.net>
2005-12-20 09:02:15 +01:00
{
int match = -1;
int fd = git_open_cloexec(ce->name, O_RDONLY);
Racy GIT This fixes the longstanding "Racy GIT" problem, which was pretty much there from the beginning of time, but was first demonstrated by Pasky in this message on October 24, 2005: http://marc.theaimsgroup.com/?l=git&m=113014629716878 If you run the following sequence of commands: echo frotz >infocom git update-index --add infocom echo xyzzy >infocom so that the second update to file "infocom" does not change st_mtime, what is recorded as the stat information for the cache entry "infocom" exactly matches what is on the filesystem (owner, group, inum, mtime, ctime, mode, length). After this sequence, we incorrectly think "infocom" file still has string "frotz" in it, and get really confused. E.g. git-diff-files would say there is no change, git-update-index --refresh would not even look at the filesystem to correct the situation. Some ways of working around this issue were already suggested by Linus in the same thread on the same day, including waiting until the next second before returning from update-index if a cache entry written out has the current timestamp, but that means we can make at most one commit per second, and given that the e-mail patch workflow used by Linus needs to process at least 5 commits per second, it is not an acceptable solution. Linus notes that git-apply is primarily used to update the index while processing e-mailed patches, which is true, and git-apply's up-to-date check is fooled by the same problem but luckily in the other direction, so it is not really a big issue, but still it is disturbing. The function ce_match_stat() is called to bypass the comparison against filesystem data when the stat data recorded in the cache entry matches what stat() returns from the filesystem. This patch tackles the problem by changing it to actually go to the filesystem data for cache entries that have the same mtime as the index file itself. This works as long as the index file and working tree files are on the filesystems that share the same monotonic clock. Files on network mounted filesystems sometimes get skewed timestamps compared to "date" output, but as long as working tree files' timestamps are skewed the same way as the index file's, this approach still works. The only problematic files are the ones that have the same timestamp as the index file's, because two file updates that sandwitch the index file update must happen within the same second to trigger the problem. Signed-off-by: Junio C Hamano <junkio@cox.net>
2005-12-20 09:02:15 +01:00
if (fd >= 0) {
struct object_id oid;
if (!index_fd(istate, &oid, fd, st, OBJ_BLOB, ce->name, 0))
match = !oideq(&oid, &ce->oid);
/* index_fd() closed the file descriptor already */
Racy GIT This fixes the longstanding "Racy GIT" problem, which was pretty much there from the beginning of time, but was first demonstrated by Pasky in this message on October 24, 2005: http://marc.theaimsgroup.com/?l=git&m=113014629716878 If you run the following sequence of commands: echo frotz >infocom git update-index --add infocom echo xyzzy >infocom so that the second update to file "infocom" does not change st_mtime, what is recorded as the stat information for the cache entry "infocom" exactly matches what is on the filesystem (owner, group, inum, mtime, ctime, mode, length). After this sequence, we incorrectly think "infocom" file still has string "frotz" in it, and get really confused. E.g. git-diff-files would say there is no change, git-update-index --refresh would not even look at the filesystem to correct the situation. Some ways of working around this issue were already suggested by Linus in the same thread on the same day, including waiting until the next second before returning from update-index if a cache entry written out has the current timestamp, but that means we can make at most one commit per second, and given that the e-mail patch workflow used by Linus needs to process at least 5 commits per second, it is not an acceptable solution. Linus notes that git-apply is primarily used to update the index while processing e-mailed patches, which is true, and git-apply's up-to-date check is fooled by the same problem but luckily in the other direction, so it is not really a big issue, but still it is disturbing. The function ce_match_stat() is called to bypass the comparison against filesystem data when the stat data recorded in the cache entry matches what stat() returns from the filesystem. This patch tackles the problem by changing it to actually go to the filesystem data for cache entries that have the same mtime as the index file itself. This works as long as the index file and working tree files are on the filesystems that share the same monotonic clock. Files on network mounted filesystems sometimes get skewed timestamps compared to "date" output, but as long as working tree files' timestamps are skewed the same way as the index file's, this approach still works. The only problematic files are the ones that have the same timestamp as the index file's, because two file updates that sandwitch the index file update must happen within the same second to trigger the problem. Signed-off-by: Junio C Hamano <junkio@cox.net>
2005-12-20 09:02:15 +01:00
}
return match;
}
static int ce_compare_link(const struct cache_entry *ce, size_t expected_size)
Racy GIT This fixes the longstanding "Racy GIT" problem, which was pretty much there from the beginning of time, but was first demonstrated by Pasky in this message on October 24, 2005: http://marc.theaimsgroup.com/?l=git&m=113014629716878 If you run the following sequence of commands: echo frotz >infocom git update-index --add infocom echo xyzzy >infocom so that the second update to file "infocom" does not change st_mtime, what is recorded as the stat information for the cache entry "infocom" exactly matches what is on the filesystem (owner, group, inum, mtime, ctime, mode, length). After this sequence, we incorrectly think "infocom" file still has string "frotz" in it, and get really confused. E.g. git-diff-files would say there is no change, git-update-index --refresh would not even look at the filesystem to correct the situation. Some ways of working around this issue were already suggested by Linus in the same thread on the same day, including waiting until the next second before returning from update-index if a cache entry written out has the current timestamp, but that means we can make at most one commit per second, and given that the e-mail patch workflow used by Linus needs to process at least 5 commits per second, it is not an acceptable solution. Linus notes that git-apply is primarily used to update the index while processing e-mailed patches, which is true, and git-apply's up-to-date check is fooled by the same problem but luckily in the other direction, so it is not really a big issue, but still it is disturbing. The function ce_match_stat() is called to bypass the comparison against filesystem data when the stat data recorded in the cache entry matches what stat() returns from the filesystem. This patch tackles the problem by changing it to actually go to the filesystem data for cache entries that have the same mtime as the index file itself. This works as long as the index file and working tree files are on the filesystems that share the same monotonic clock. Files on network mounted filesystems sometimes get skewed timestamps compared to "date" output, but as long as working tree files' timestamps are skewed the same way as the index file's, this approach still works. The only problematic files are the ones that have the same timestamp as the index file's, because two file updates that sandwitch the index file update must happen within the same second to trigger the problem. Signed-off-by: Junio C Hamano <junkio@cox.net>
2005-12-20 09:02:15 +01:00
{
int match = -1;
void *buffer;
unsigned long size;
enum object_type type;
struct strbuf sb = STRBUF_INIT;
Racy GIT This fixes the longstanding "Racy GIT" problem, which was pretty much there from the beginning of time, but was first demonstrated by Pasky in this message on October 24, 2005: http://marc.theaimsgroup.com/?l=git&m=113014629716878 If you run the following sequence of commands: echo frotz >infocom git update-index --add infocom echo xyzzy >infocom so that the second update to file "infocom" does not change st_mtime, what is recorded as the stat information for the cache entry "infocom" exactly matches what is on the filesystem (owner, group, inum, mtime, ctime, mode, length). After this sequence, we incorrectly think "infocom" file still has string "frotz" in it, and get really confused. E.g. git-diff-files would say there is no change, git-update-index --refresh would not even look at the filesystem to correct the situation. Some ways of working around this issue were already suggested by Linus in the same thread on the same day, including waiting until the next second before returning from update-index if a cache entry written out has the current timestamp, but that means we can make at most one commit per second, and given that the e-mail patch workflow used by Linus needs to process at least 5 commits per second, it is not an acceptable solution. Linus notes that git-apply is primarily used to update the index while processing e-mailed patches, which is true, and git-apply's up-to-date check is fooled by the same problem but luckily in the other direction, so it is not really a big issue, but still it is disturbing. The function ce_match_stat() is called to bypass the comparison against filesystem data when the stat data recorded in the cache entry matches what stat() returns from the filesystem. This patch tackles the problem by changing it to actually go to the filesystem data for cache entries that have the same mtime as the index file itself. This works as long as the index file and working tree files are on the filesystems that share the same monotonic clock. Files on network mounted filesystems sometimes get skewed timestamps compared to "date" output, but as long as working tree files' timestamps are skewed the same way as the index file's, this approach still works. The only problematic files are the ones that have the same timestamp as the index file's, because two file updates that sandwitch the index file update must happen within the same second to trigger the problem. Signed-off-by: Junio C Hamano <junkio@cox.net>
2005-12-20 09:02:15 +01:00
if (strbuf_readlink(&sb, ce->name, expected_size))
Racy GIT This fixes the longstanding "Racy GIT" problem, which was pretty much there from the beginning of time, but was first demonstrated by Pasky in this message on October 24, 2005: http://marc.theaimsgroup.com/?l=git&m=113014629716878 If you run the following sequence of commands: echo frotz >infocom git update-index --add infocom echo xyzzy >infocom so that the second update to file "infocom" does not change st_mtime, what is recorded as the stat information for the cache entry "infocom" exactly matches what is on the filesystem (owner, group, inum, mtime, ctime, mode, length). After this sequence, we incorrectly think "infocom" file still has string "frotz" in it, and get really confused. E.g. git-diff-files would say there is no change, git-update-index --refresh would not even look at the filesystem to correct the situation. Some ways of working around this issue were already suggested by Linus in the same thread on the same day, including waiting until the next second before returning from update-index if a cache entry written out has the current timestamp, but that means we can make at most one commit per second, and given that the e-mail patch workflow used by Linus needs to process at least 5 commits per second, it is not an acceptable solution. Linus notes that git-apply is primarily used to update the index while processing e-mailed patches, which is true, and git-apply's up-to-date check is fooled by the same problem but luckily in the other direction, so it is not really a big issue, but still it is disturbing. The function ce_match_stat() is called to bypass the comparison against filesystem data when the stat data recorded in the cache entry matches what stat() returns from the filesystem. This patch tackles the problem by changing it to actually go to the filesystem data for cache entries that have the same mtime as the index file itself. This works as long as the index file and working tree files are on the filesystems that share the same monotonic clock. Files on network mounted filesystems sometimes get skewed timestamps compared to "date" output, but as long as working tree files' timestamps are skewed the same way as the index file's, this approach still works. The only problematic files are the ones that have the same timestamp as the index file's, because two file updates that sandwitch the index file update must happen within the same second to trigger the problem. Signed-off-by: Junio C Hamano <junkio@cox.net>
2005-12-20 09:02:15 +01:00
return -1;
buffer = read_object_file(&ce->oid, &type, &size);
if (buffer) {
if (size == sb.len)
match = memcmp(buffer, sb.buf, size);
free(buffer);
Racy GIT This fixes the longstanding "Racy GIT" problem, which was pretty much there from the beginning of time, but was first demonstrated by Pasky in this message on October 24, 2005: http://marc.theaimsgroup.com/?l=git&m=113014629716878 If you run the following sequence of commands: echo frotz >infocom git update-index --add infocom echo xyzzy >infocom so that the second update to file "infocom" does not change st_mtime, what is recorded as the stat information for the cache entry "infocom" exactly matches what is on the filesystem (owner, group, inum, mtime, ctime, mode, length). After this sequence, we incorrectly think "infocom" file still has string "frotz" in it, and get really confused. E.g. git-diff-files would say there is no change, git-update-index --refresh would not even look at the filesystem to correct the situation. Some ways of working around this issue were already suggested by Linus in the same thread on the same day, including waiting until the next second before returning from update-index if a cache entry written out has the current timestamp, but that means we can make at most one commit per second, and given that the e-mail patch workflow used by Linus needs to process at least 5 commits per second, it is not an acceptable solution. Linus notes that git-apply is primarily used to update the index while processing e-mailed patches, which is true, and git-apply's up-to-date check is fooled by the same problem but luckily in the other direction, so it is not really a big issue, but still it is disturbing. The function ce_match_stat() is called to bypass the comparison against filesystem data when the stat data recorded in the cache entry matches what stat() returns from the filesystem. This patch tackles the problem by changing it to actually go to the filesystem data for cache entries that have the same mtime as the index file itself. This works as long as the index file and working tree files are on the filesystems that share the same monotonic clock. Files on network mounted filesystems sometimes get skewed timestamps compared to "date" output, but as long as working tree files' timestamps are skewed the same way as the index file's, this approach still works. The only problematic files are the ones that have the same timestamp as the index file's, because two file updates that sandwitch the index file update must happen within the same second to trigger the problem. Signed-off-by: Junio C Hamano <junkio@cox.net>
2005-12-20 09:02:15 +01:00
}
strbuf_release(&sb);
Racy GIT This fixes the longstanding "Racy GIT" problem, which was pretty much there from the beginning of time, but was first demonstrated by Pasky in this message on October 24, 2005: http://marc.theaimsgroup.com/?l=git&m=113014629716878 If you run the following sequence of commands: echo frotz >infocom git update-index --add infocom echo xyzzy >infocom so that the second update to file "infocom" does not change st_mtime, what is recorded as the stat information for the cache entry "infocom" exactly matches what is on the filesystem (owner, group, inum, mtime, ctime, mode, length). After this sequence, we incorrectly think "infocom" file still has string "frotz" in it, and get really confused. E.g. git-diff-files would say there is no change, git-update-index --refresh would not even look at the filesystem to correct the situation. Some ways of working around this issue were already suggested by Linus in the same thread on the same day, including waiting until the next second before returning from update-index if a cache entry written out has the current timestamp, but that means we can make at most one commit per second, and given that the e-mail patch workflow used by Linus needs to process at least 5 commits per second, it is not an acceptable solution. Linus notes that git-apply is primarily used to update the index while processing e-mailed patches, which is true, and git-apply's up-to-date check is fooled by the same problem but luckily in the other direction, so it is not really a big issue, but still it is disturbing. The function ce_match_stat() is called to bypass the comparison against filesystem data when the stat data recorded in the cache entry matches what stat() returns from the filesystem. This patch tackles the problem by changing it to actually go to the filesystem data for cache entries that have the same mtime as the index file itself. This works as long as the index file and working tree files are on the filesystems that share the same monotonic clock. Files on network mounted filesystems sometimes get skewed timestamps compared to "date" output, but as long as working tree files' timestamps are skewed the same way as the index file's, this approach still works. The only problematic files are the ones that have the same timestamp as the index file's, because two file updates that sandwitch the index file update must happen within the same second to trigger the problem. Signed-off-by: Junio C Hamano <junkio@cox.net>
2005-12-20 09:02:15 +01:00
return match;
}
static int ce_compare_gitlink(const struct cache_entry *ce)
{
struct object_id oid;
/*
* We don't actually require that the .git directory
* under GITLINK directory be a valid git directory. It
* might even be missing (in case nobody populated that
* sub-project).
*
* If so, we consider it always to match.
*/
if (resolve_gitlink_ref(ce->name, "HEAD", &oid) < 0)
return 0;
return !oideq(&oid, &ce->oid);
}
static int ce_modified_check_fs(struct index_state *istate,
const struct cache_entry *ce,
struct stat *st)
Racy GIT This fixes the longstanding "Racy GIT" problem, which was pretty much there from the beginning of time, but was first demonstrated by Pasky in this message on October 24, 2005: http://marc.theaimsgroup.com/?l=git&m=113014629716878 If you run the following sequence of commands: echo frotz >infocom git update-index --add infocom echo xyzzy >infocom so that the second update to file "infocom" does not change st_mtime, what is recorded as the stat information for the cache entry "infocom" exactly matches what is on the filesystem (owner, group, inum, mtime, ctime, mode, length). After this sequence, we incorrectly think "infocom" file still has string "frotz" in it, and get really confused. E.g. git-diff-files would say there is no change, git-update-index --refresh would not even look at the filesystem to correct the situation. Some ways of working around this issue were already suggested by Linus in the same thread on the same day, including waiting until the next second before returning from update-index if a cache entry written out has the current timestamp, but that means we can make at most one commit per second, and given that the e-mail patch workflow used by Linus needs to process at least 5 commits per second, it is not an acceptable solution. Linus notes that git-apply is primarily used to update the index while processing e-mailed patches, which is true, and git-apply's up-to-date check is fooled by the same problem but luckily in the other direction, so it is not really a big issue, but still it is disturbing. The function ce_match_stat() is called to bypass the comparison against filesystem data when the stat data recorded in the cache entry matches what stat() returns from the filesystem. This patch tackles the problem by changing it to actually go to the filesystem data for cache entries that have the same mtime as the index file itself. This works as long as the index file and working tree files are on the filesystems that share the same monotonic clock. Files on network mounted filesystems sometimes get skewed timestamps compared to "date" output, but as long as working tree files' timestamps are skewed the same way as the index file's, this approach still works. The only problematic files are the ones that have the same timestamp as the index file's, because two file updates that sandwitch the index file update must happen within the same second to trigger the problem. Signed-off-by: Junio C Hamano <junkio@cox.net>
2005-12-20 09:02:15 +01:00
{
switch (st->st_mode & S_IFMT) {
case S_IFREG:
if (ce_compare_data(istate, ce, st))
Racy GIT This fixes the longstanding "Racy GIT" problem, which was pretty much there from the beginning of time, but was first demonstrated by Pasky in this message on October 24, 2005: http://marc.theaimsgroup.com/?l=git&m=113014629716878 If you run the following sequence of commands: echo frotz >infocom git update-index --add infocom echo xyzzy >infocom so that the second update to file "infocom" does not change st_mtime, what is recorded as the stat information for the cache entry "infocom" exactly matches what is on the filesystem (owner, group, inum, mtime, ctime, mode, length). After this sequence, we incorrectly think "infocom" file still has string "frotz" in it, and get really confused. E.g. git-diff-files would say there is no change, git-update-index --refresh would not even look at the filesystem to correct the situation. Some ways of working around this issue were already suggested by Linus in the same thread on the same day, including waiting until the next second before returning from update-index if a cache entry written out has the current timestamp, but that means we can make at most one commit per second, and given that the e-mail patch workflow used by Linus needs to process at least 5 commits per second, it is not an acceptable solution. Linus notes that git-apply is primarily used to update the index while processing e-mailed patches, which is true, and git-apply's up-to-date check is fooled by the same problem but luckily in the other direction, so it is not really a big issue, but still it is disturbing. The function ce_match_stat() is called to bypass the comparison against filesystem data when the stat data recorded in the cache entry matches what stat() returns from the filesystem. This patch tackles the problem by changing it to actually go to the filesystem data for cache entries that have the same mtime as the index file itself. This works as long as the index file and working tree files are on the filesystems that share the same monotonic clock. Files on network mounted filesystems sometimes get skewed timestamps compared to "date" output, but as long as working tree files' timestamps are skewed the same way as the index file's, this approach still works. The only problematic files are the ones that have the same timestamp as the index file's, because two file updates that sandwitch the index file update must happen within the same second to trigger the problem. Signed-off-by: Junio C Hamano <junkio@cox.net>
2005-12-20 09:02:15 +01:00
return DATA_CHANGED;
break;
case S_IFLNK:
if (ce_compare_link(ce, xsize_t(st->st_size)))
Racy GIT This fixes the longstanding "Racy GIT" problem, which was pretty much there from the beginning of time, but was first demonstrated by Pasky in this message on October 24, 2005: http://marc.theaimsgroup.com/?l=git&m=113014629716878 If you run the following sequence of commands: echo frotz >infocom git update-index --add infocom echo xyzzy >infocom so that the second update to file "infocom" does not change st_mtime, what is recorded as the stat information for the cache entry "infocom" exactly matches what is on the filesystem (owner, group, inum, mtime, ctime, mode, length). After this sequence, we incorrectly think "infocom" file still has string "frotz" in it, and get really confused. E.g. git-diff-files would say there is no change, git-update-index --refresh would not even look at the filesystem to correct the situation. Some ways of working around this issue were already suggested by Linus in the same thread on the same day, including waiting until the next second before returning from update-index if a cache entry written out has the current timestamp, but that means we can make at most one commit per second, and given that the e-mail patch workflow used by Linus needs to process at least 5 commits per second, it is not an acceptable solution. Linus notes that git-apply is primarily used to update the index while processing e-mailed patches, which is true, and git-apply's up-to-date check is fooled by the same problem but luckily in the other direction, so it is not really a big issue, but still it is disturbing. The function ce_match_stat() is called to bypass the comparison against filesystem data when the stat data recorded in the cache entry matches what stat() returns from the filesystem. This patch tackles the problem by changing it to actually go to the filesystem data for cache entries that have the same mtime as the index file itself. This works as long as the index file and working tree files are on the filesystems that share the same monotonic clock. Files on network mounted filesystems sometimes get skewed timestamps compared to "date" output, but as long as working tree files' timestamps are skewed the same way as the index file's, this approach still works. The only problematic files are the ones that have the same timestamp as the index file's, because two file updates that sandwitch the index file update must happen within the same second to trigger the problem. Signed-off-by: Junio C Hamano <junkio@cox.net>
2005-12-20 09:02:15 +01:00
return DATA_CHANGED;
break;
case S_IFDIR:
if (S_ISGITLINK(ce->ce_mode))
2008-07-29 10:13:44 +02:00
return ce_compare_gitlink(ce) ? DATA_CHANGED : 0;
consistently use "fallthrough" comments in switches Gcc 7 adds -Wimplicit-fallthrough, which can warn when a switch case falls through to the next case. The general idea is that the compiler can't tell if this was intentional or not, so you should annotate any intentional fall-throughs as such, leaving it to complain about any unannotated ones. There's a GNU __attribute__ which can be used for annotation, but of course we'd have to #ifdef it away on non-gcc compilers. Gcc will also recognize specially-formatted comments, which matches our current practice. Let's extend that practice to all of the unannotated sites (which I did look over and verify that they were behaving as intended). Ideally in each case we'd actually give some reasons in the comment about why we're falling through, or what we're falling through to. And gcc does support that with -Wimplicit-fallthrough=2, which relaxes the comment pattern matching to anything that contains "fallthrough" (or a variety of spelling variants). However, this isn't the default for -Wimplicit-fallthrough, nor for -Wextra. In the name of simplicity, it's probably better for us to support the default level, which requires "fallthrough" to be the only thing in the comment (modulo some window dressing like "else" and some punctuation; see the gcc manual for the complete set of patterns). This patch suppresses all warnings due to -Wimplicit-fallthrough. We might eventually want to add that to the DEVELOPER Makefile knob, but we should probably wait until gcc 7 is more widely adopted (since earlier versions will complain about the unknown warning type). Signed-off-by: Jeff King <peff@peff.net> Signed-off-by: Junio C Hamano <gitster@pobox.com>
2017-09-21 08:25:41 +02:00
/* else fallthrough */
Racy GIT This fixes the longstanding "Racy GIT" problem, which was pretty much there from the beginning of time, but was first demonstrated by Pasky in this message on October 24, 2005: http://marc.theaimsgroup.com/?l=git&m=113014629716878 If you run the following sequence of commands: echo frotz >infocom git update-index --add infocom echo xyzzy >infocom so that the second update to file "infocom" does not change st_mtime, what is recorded as the stat information for the cache entry "infocom" exactly matches what is on the filesystem (owner, group, inum, mtime, ctime, mode, length). After this sequence, we incorrectly think "infocom" file still has string "frotz" in it, and get really confused. E.g. git-diff-files would say there is no change, git-update-index --refresh would not even look at the filesystem to correct the situation. Some ways of working around this issue were already suggested by Linus in the same thread on the same day, including waiting until the next second before returning from update-index if a cache entry written out has the current timestamp, but that means we can make at most one commit per second, and given that the e-mail patch workflow used by Linus needs to process at least 5 commits per second, it is not an acceptable solution. Linus notes that git-apply is primarily used to update the index while processing e-mailed patches, which is true, and git-apply's up-to-date check is fooled by the same problem but luckily in the other direction, so it is not really a big issue, but still it is disturbing. The function ce_match_stat() is called to bypass the comparison against filesystem data when the stat data recorded in the cache entry matches what stat() returns from the filesystem. This patch tackles the problem by changing it to actually go to the filesystem data for cache entries that have the same mtime as the index file itself. This works as long as the index file and working tree files are on the filesystems that share the same monotonic clock. Files on network mounted filesystems sometimes get skewed timestamps compared to "date" output, but as long as working tree files' timestamps are skewed the same way as the index file's, this approach still works. The only problematic files are the ones that have the same timestamp as the index file's, because two file updates that sandwitch the index file update must happen within the same second to trigger the problem. Signed-off-by: Junio C Hamano <junkio@cox.net>
2005-12-20 09:02:15 +01:00
default:
return TYPE_CHANGED;
}
return 0;
}
static int ce_match_stat_basic(const struct cache_entry *ce, struct stat *st)
{
unsigned int changed = 0;
if (ce->ce_flags & CE_REMOVE)
return MODE_CHANGED | DATA_CHANGED | TYPE_CHANGED;
switch (ce->ce_mode & S_IFMT) {
case S_IFREG:
changed |= !S_ISREG(st->st_mode) ? TYPE_CHANGED : 0;
/* We consider only the owner x bit to be relevant for
* "mode changes"
*/
if (trust_executable_bit &&
(0100 & (ce->ce_mode ^ st->st_mode)))
changed |= MODE_CHANGED;
break;
case S_IFLNK:
if (!S_ISLNK(st->st_mode) &&
(has_symlinks || !S_ISREG(st->st_mode)))
changed |= TYPE_CHANGED;
break;
case S_IFGITLINK:
2008-07-29 10:13:44 +02:00
/* We ignore most of the st_xxx fields for gitlinks */
if (!S_ISDIR(st->st_mode))
changed |= TYPE_CHANGED;
else if (ce_compare_gitlink(ce))
changed |= DATA_CHANGED;
return changed;
default:
BUG("unsupported ce_mode: %o", ce->ce_mode);
}
changed |= match_stat_data(&ce->ce_stat_data, st);
/* Racily smudged entry? */
if (!ce->ce_stat_data.sd_size) {
if (!is_empty_blob_sha1(ce->oid.hash))
changed |= DATA_CHANGED;
}
return changed;
}
static int is_racy_stat(const struct index_state *istate,
const struct stat_data *sd)
{
return (istate->timestamp.sec &&
#ifdef USE_NSEC
/* nanosecond timestamped files can also be racy! */
(istate->timestamp.sec < sd->sd_mtime.sec ||
(istate->timestamp.sec == sd->sd_mtime.sec &&
istate->timestamp.nsec <= sd->sd_mtime.nsec))
#else
istate->timestamp.sec <= sd->sd_mtime.sec
#endif
);
}
split-index: smudge and add racily clean cache entries to split index Ever since the split index feature was introduced [1], refreshing a split index is prone to a variant of the classic racy git problem. Consider the following sequence of commands updating the split index when the shared index contains a racily clean cache entry, i.e. an entry whose cached stat data matches with the corresponding file in the worktree and the cached mtime matches that of the index: echo "cached content" >file git update-index --split-index --add file echo "dirty worktree" >file # size stays the same! # ... wait ... git update-index --add other-file Normally, when a non-split index is updated, then do_write_index() (the function responsible for writing all kinds of indexes, "regular", split, and shared) recognizes racily clean cache entries, and writes them with smudged stat data, i.e. with file size set to 0. When subsequent git commands read the index, they will notice that the smudged stat data doesn't match with the file in the worktree, and then go on to check the file's content and notice its dirtiness. In the above example, however, in the second 'git update-index' prepare_to_write_split_index() decides which cache entries stored only in the shared index should be replaced in the new split index. Alas, this function never looks out for racily clean cache entries, and since the file's stat data in the worktree hasn't changed since the shared index was written, it won't be replaced in the new split index. Consequently, do_write_index() doesn't even get this racily clean cache entry, and can't smudge its stat data. Subsequent git commands will then see that the index has more recent mtime than the file and that the (not smudged) cached stat data still matches with the file in the worktree, and, ultimately, will erroneously consider the file clean. Modify prepare_to_write_split_index() to recognize racily clean cache entries, and mark them to be added to the split index. Note that there are two places where it should check raciness: first those cache entries that are only stored in the shared index, and then those that have been copied by unpack_trees() from the shared index while it constructed a new index. This way do_write_index() will get these racily clean cache entries as well, and will then write them with smudged stat data to the new split index. This change makes all tests in 't1701-racy-split-index.sh' pass, so flip the two 'test_expect_failure' tests to success. Also add the '#' (as in nr. of trial) to those tests' description that were omitted when the tests expected failure. Note that after this change if the index is split when it contains a racily clean cache entry, then a smudged cache entry will be written both to the new shared and to the new split indexes. This doesn't affect regular git commands: as far as they are concerned this is just an entry in the split index replacing an outdated entry in the shared index. It did affect a few tests in 't1700-split-index.sh', though, because they actually check which entries are stored in the split index; a previous patch in this series has already made the necessary adjustments in 't1700'. And racily clean cache entries and index splitting are rare enough to not worry about the resulting duplicated smudged cache entries, and the additional complexity required to prevent them is not worth it. Several tests failed occasionally when the test suite was run with 'GIT_TEST_SPLIT_INDEX=yes'. Here are those that I managed to trace back to this racy split index problem, starting with those failing more frequently, with a link to a failing Travis CI build job for each. The highlighted line [2] shows when the racy file was written, which is not always in the failing test but in a preceeding setup test. t3903-stash.sh: https://travis-ci.org/git/git/jobs/385542084#L5858 t4024-diff-optimize-common.sh: https://travis-ci.org/git/git/jobs/386531969#L3174 t4015-diff-whitespace.sh: https://travis-ci.org/git/git/jobs/360797600#L8215 t2200-add-update.sh: https://travis-ci.org/git/git/jobs/382543426#L3051 t0090-cache-tree.sh: https://travis-ci.org/git/git/jobs/416583010#L3679 There might be others, e.g. perhaps 't1000-read-tree-m-3way.sh' and others using 'lib-read-tree-m-3way.sh', but I couldn't confirm yet. [1] In the branch leading to the merge commit v2.1.0-rc0~45 (Merge branch 'nd/split-index', 2014-07-16). [2] Note that those highlighted lines are in the 'after failure' fold, and your browser might unhelpfully fold it up before you could take a good look. Signed-off-by: SZEDER Gábor <szeder.dev@gmail.com> Signed-off-by: Junio C Hamano <gitster@pobox.com>
2018-10-11 11:43:09 +02:00
int is_racy_timestamp(const struct index_state *istate,
const struct cache_entry *ce)
{
return (!S_ISGITLINK(ce->ce_mode) &&
is_racy_stat(istate, &ce->ce_stat_data));
}
int match_stat_data_racy(const struct index_state *istate,
const struct stat_data *sd, struct stat *st)
{
if (is_racy_stat(istate, sd))
return MTIME_CHANGED;
return match_stat_data(sd, st);
}
int ie_match_stat(struct index_state *istate,
const struct cache_entry *ce, struct stat *st,
unsigned int options)
{
"Assume unchanged" git This adds "assume unchanged" logic, started by this message in the list discussion recently: <Pine.LNX.4.64.0601311807470.7301@g5.osdl.org> This is a workaround for filesystems that do not have lstat() that is quick enough for the index mechanism to take advantage of. On the paths marked as "assumed to be unchanged", the user needs to explicitly use update-index to register the object name to be in the next commit. You can use two new options to update-index to set and reset the CE_VALID bit: git-update-index --assume-unchanged path... git-update-index --no-assume-unchanged path... These forms manipulate only the CE_VALID bit; it does not change the object name recorded in the index file. Nor they add a new entry to the index. When the configuration variable "core.ignorestat = true" is set, the index entries are marked with CE_VALID bit automatically after: - update-index to explicitly register the current object name to the index file. - when update-index --refresh finds the path to be up-to-date. - when tools like read-tree -u and apply --index update the working tree file and register the current object name to the index file. The flag is dropped upon read-tree that does not check out the index entry. This happens regardless of the core.ignorestat settings. Index entries marked with CE_VALID bit are assumed to be unchanged most of the time. However, there are cases that CE_VALID bit is ignored for the sake of safety and usability: - while "git-read-tree -m" or git-apply need to make sure that the paths involved in the merge do not have local modifications. This sacrifices performance for safety. - when git-checkout-index -f -q -u -a tries to see if it needs to checkout the paths. Otherwise you can never check anything out ;-). - when git-update-index --really-refresh (a new flag) tries to see if the index entry is up to date. You can start with everything marked as CE_VALID and run this once to drop CE_VALID bit for paths that are modified. Most notably, "update-index --refresh" honours CE_VALID and does not actively stat, so after you modified a file in the working tree, update-index --refresh would not notice until you tell the index about it with "git-update-index path" or "git-update-index --no-assume-unchanged path". This version is not expected to be perfect. I think diff between index and/or tree and working files may need some adjustment, and there probably needs other cases we should automatically unmark paths that are marked to be CE_VALID. But the basics seem to work, and ready to be tested by people who asked for this feature. Signed-off-by: Junio C Hamano <junkio@cox.net>
2006-02-09 06:15:24 +01:00
unsigned int changed;
int ignore_valid = options & CE_MATCH_IGNORE_VALID;
int ignore_skip_worktree = options & CE_MATCH_IGNORE_SKIP_WORKTREE;
int assume_racy_is_modified = options & CE_MATCH_RACY_IS_DIRTY;
int ignore_fsmonitor = options & CE_MATCH_IGNORE_FSMONITOR;
"Assume unchanged" git This adds "assume unchanged" logic, started by this message in the list discussion recently: <Pine.LNX.4.64.0601311807470.7301@g5.osdl.org> This is a workaround for filesystems that do not have lstat() that is quick enough for the index mechanism to take advantage of. On the paths marked as "assumed to be unchanged", the user needs to explicitly use update-index to register the object name to be in the next commit. You can use two new options to update-index to set and reset the CE_VALID bit: git-update-index --assume-unchanged path... git-update-index --no-assume-unchanged path... These forms manipulate only the CE_VALID bit; it does not change the object name recorded in the index file. Nor they add a new entry to the index. When the configuration variable "core.ignorestat = true" is set, the index entries are marked with CE_VALID bit automatically after: - update-index to explicitly register the current object name to the index file. - when update-index --refresh finds the path to be up-to-date. - when tools like read-tree -u and apply --index update the working tree file and register the current object name to the index file. The flag is dropped upon read-tree that does not check out the index entry. This happens regardless of the core.ignorestat settings. Index entries marked with CE_VALID bit are assumed to be unchanged most of the time. However, there are cases that CE_VALID bit is ignored for the sake of safety and usability: - while "git-read-tree -m" or git-apply need to make sure that the paths involved in the merge do not have local modifications. This sacrifices performance for safety. - when git-checkout-index -f -q -u -a tries to see if it needs to checkout the paths. Otherwise you can never check anything out ;-). - when git-update-index --really-refresh (a new flag) tries to see if the index entry is up to date. You can start with everything marked as CE_VALID and run this once to drop CE_VALID bit for paths that are modified. Most notably, "update-index --refresh" honours CE_VALID and does not actively stat, so after you modified a file in the working tree, update-index --refresh would not notice until you tell the index about it with "git-update-index path" or "git-update-index --no-assume-unchanged path". This version is not expected to be perfect. I think diff between index and/or tree and working files may need some adjustment, and there probably needs other cases we should automatically unmark paths that are marked to be CE_VALID. But the basics seem to work, and ready to be tested by people who asked for this feature. Signed-off-by: Junio C Hamano <junkio@cox.net>
2006-02-09 06:15:24 +01:00
if (!ignore_fsmonitor)
refresh_fsmonitor(istate);
"Assume unchanged" git This adds "assume unchanged" logic, started by this message in the list discussion recently: <Pine.LNX.4.64.0601311807470.7301@g5.osdl.org> This is a workaround for filesystems that do not have lstat() that is quick enough for the index mechanism to take advantage of. On the paths marked as "assumed to be unchanged", the user needs to explicitly use update-index to register the object name to be in the next commit. You can use two new options to update-index to set and reset the CE_VALID bit: git-update-index --assume-unchanged path... git-update-index --no-assume-unchanged path... These forms manipulate only the CE_VALID bit; it does not change the object name recorded in the index file. Nor they add a new entry to the index. When the configuration variable "core.ignorestat = true" is set, the index entries are marked with CE_VALID bit automatically after: - update-index to explicitly register the current object name to the index file. - when update-index --refresh finds the path to be up-to-date. - when tools like read-tree -u and apply --index update the working tree file and register the current object name to the index file. The flag is dropped upon read-tree that does not check out the index entry. This happens regardless of the core.ignorestat settings. Index entries marked with CE_VALID bit are assumed to be unchanged most of the time. However, there are cases that CE_VALID bit is ignored for the sake of safety and usability: - while "git-read-tree -m" or git-apply need to make sure that the paths involved in the merge do not have local modifications. This sacrifices performance for safety. - when git-checkout-index -f -q -u -a tries to see if it needs to checkout the paths. Otherwise you can never check anything out ;-). - when git-update-index --really-refresh (a new flag) tries to see if the index entry is up to date. You can start with everything marked as CE_VALID and run this once to drop CE_VALID bit for paths that are modified. Most notably, "update-index --refresh" honours CE_VALID and does not actively stat, so after you modified a file in the working tree, update-index --refresh would not notice until you tell the index about it with "git-update-index path" or "git-update-index --no-assume-unchanged path". This version is not expected to be perfect. I think diff between index and/or tree and working files may need some adjustment, and there probably needs other cases we should automatically unmark paths that are marked to be CE_VALID. But the basics seem to work, and ready to be tested by people who asked for this feature. Signed-off-by: Junio C Hamano <junkio@cox.net>
2006-02-09 06:15:24 +01:00
/*
* If it's marked as always valid in the index, it's
* valid whatever the checked-out copy says.
*
* skip-worktree has the same effect with higher precedence
"Assume unchanged" git This adds "assume unchanged" logic, started by this message in the list discussion recently: <Pine.LNX.4.64.0601311807470.7301@g5.osdl.org> This is a workaround for filesystems that do not have lstat() that is quick enough for the index mechanism to take advantage of. On the paths marked as "assumed to be unchanged", the user needs to explicitly use update-index to register the object name to be in the next commit. You can use two new options to update-index to set and reset the CE_VALID bit: git-update-index --assume-unchanged path... git-update-index --no-assume-unchanged path... These forms manipulate only the CE_VALID bit; it does not change the object name recorded in the index file. Nor they add a new entry to the index. When the configuration variable "core.ignorestat = true" is set, the index entries are marked with CE_VALID bit automatically after: - update-index to explicitly register the current object name to the index file. - when update-index --refresh finds the path to be up-to-date. - when tools like read-tree -u and apply --index update the working tree file and register the current object name to the index file. The flag is dropped upon read-tree that does not check out the index entry. This happens regardless of the core.ignorestat settings. Index entries marked with CE_VALID bit are assumed to be unchanged most of the time. However, there are cases that CE_VALID bit is ignored for the sake of safety and usability: - while "git-read-tree -m" or git-apply need to make sure that the paths involved in the merge do not have local modifications. This sacrifices performance for safety. - when git-checkout-index -f -q -u -a tries to see if it needs to checkout the paths. Otherwise you can never check anything out ;-). - when git-update-index --really-refresh (a new flag) tries to see if the index entry is up to date. You can start with everything marked as CE_VALID and run this once to drop CE_VALID bit for paths that are modified. Most notably, "update-index --refresh" honours CE_VALID and does not actively stat, so after you modified a file in the working tree, update-index --refresh would not notice until you tell the index about it with "git-update-index path" or "git-update-index --no-assume-unchanged path". This version is not expected to be perfect. I think diff between index and/or tree and working files may need some adjustment, and there probably needs other cases we should automatically unmark paths that are marked to be CE_VALID. But the basics seem to work, and ready to be tested by people who asked for this feature. Signed-off-by: Junio C Hamano <junkio@cox.net>
2006-02-09 06:15:24 +01:00
*/
if (!ignore_skip_worktree && ce_skip_worktree(ce))
return 0;
if (!ignore_valid && (ce->ce_flags & CE_VALID))
"Assume unchanged" git This adds "assume unchanged" logic, started by this message in the list discussion recently: <Pine.LNX.4.64.0601311807470.7301@g5.osdl.org> This is a workaround for filesystems that do not have lstat() that is quick enough for the index mechanism to take advantage of. On the paths marked as "assumed to be unchanged", the user needs to explicitly use update-index to register the object name to be in the next commit. You can use two new options to update-index to set and reset the CE_VALID bit: git-update-index --assume-unchanged path... git-update-index --no-assume-unchanged path... These forms manipulate only the CE_VALID bit; it does not change the object name recorded in the index file. Nor they add a new entry to the index. When the configuration variable "core.ignorestat = true" is set, the index entries are marked with CE_VALID bit automatically after: - update-index to explicitly register the current object name to the index file. - when update-index --refresh finds the path to be up-to-date. - when tools like read-tree -u and apply --index update the working tree file and register the current object name to the index file. The flag is dropped upon read-tree that does not check out the index entry. This happens regardless of the core.ignorestat settings. Index entries marked with CE_VALID bit are assumed to be unchanged most of the time. However, there are cases that CE_VALID bit is ignored for the sake of safety and usability: - while "git-read-tree -m" or git-apply need to make sure that the paths involved in the merge do not have local modifications. This sacrifices performance for safety. - when git-checkout-index -f -q -u -a tries to see if it needs to checkout the paths. Otherwise you can never check anything out ;-). - when git-update-index --really-refresh (a new flag) tries to see if the index entry is up to date. You can start with everything marked as CE_VALID and run this once to drop CE_VALID bit for paths that are modified. Most notably, "update-index --refresh" honours CE_VALID and does not actively stat, so after you modified a file in the working tree, update-index --refresh would not notice until you tell the index about it with "git-update-index path" or "git-update-index --no-assume-unchanged path". This version is not expected to be perfect. I think diff between index and/or tree and working files may need some adjustment, and there probably needs other cases we should automatically unmark paths that are marked to be CE_VALID. But the basics seem to work, and ready to be tested by people who asked for this feature. Signed-off-by: Junio C Hamano <junkio@cox.net>
2006-02-09 06:15:24 +01:00
return 0;
if (!ignore_fsmonitor && (ce->ce_flags & CE_FSMONITOR_VALID))
return 0;
"Assume unchanged" git This adds "assume unchanged" logic, started by this message in the list discussion recently: <Pine.LNX.4.64.0601311807470.7301@g5.osdl.org> This is a workaround for filesystems that do not have lstat() that is quick enough for the index mechanism to take advantage of. On the paths marked as "assumed to be unchanged", the user needs to explicitly use update-index to register the object name to be in the next commit. You can use two new options to update-index to set and reset the CE_VALID bit: git-update-index --assume-unchanged path... git-update-index --no-assume-unchanged path... These forms manipulate only the CE_VALID bit; it does not change the object name recorded in the index file. Nor they add a new entry to the index. When the configuration variable "core.ignorestat = true" is set, the index entries are marked with CE_VALID bit automatically after: - update-index to explicitly register the current object name to the index file. - when update-index --refresh finds the path to be up-to-date. - when tools like read-tree -u and apply --index update the working tree file and register the current object name to the index file. The flag is dropped upon read-tree that does not check out the index entry. This happens regardless of the core.ignorestat settings. Index entries marked with CE_VALID bit are assumed to be unchanged most of the time. However, there are cases that CE_VALID bit is ignored for the sake of safety and usability: - while "git-read-tree -m" or git-apply need to make sure that the paths involved in the merge do not have local modifications. This sacrifices performance for safety. - when git-checkout-index -f -q -u -a tries to see if it needs to checkout the paths. Otherwise you can never check anything out ;-). - when git-update-index --really-refresh (a new flag) tries to see if the index entry is up to date. You can start with everything marked as CE_VALID and run this once to drop CE_VALID bit for paths that are modified. Most notably, "update-index --refresh" honours CE_VALID and does not actively stat, so after you modified a file in the working tree, update-index --refresh would not notice until you tell the index about it with "git-update-index path" or "git-update-index --no-assume-unchanged path". This version is not expected to be perfect. I think diff between index and/or tree and working files may need some adjustment, and there probably needs other cases we should automatically unmark paths that are marked to be CE_VALID. But the basics seem to work, and ready to be tested by people who asked for this feature. Signed-off-by: Junio C Hamano <junkio@cox.net>
2006-02-09 06:15:24 +01:00
/*
* Intent-to-add entries have not been added, so the index entry
* by definition never matches what is in the work tree until it
* actually gets added.
*/
if (ce_intent_to_add(ce))
return DATA_CHANGED | TYPE_CHANGED | MODE_CHANGED;
"Assume unchanged" git This adds "assume unchanged" logic, started by this message in the list discussion recently: <Pine.LNX.4.64.0601311807470.7301@g5.osdl.org> This is a workaround for filesystems that do not have lstat() that is quick enough for the index mechanism to take advantage of. On the paths marked as "assumed to be unchanged", the user needs to explicitly use update-index to register the object name to be in the next commit. You can use two new options to update-index to set and reset the CE_VALID bit: git-update-index --assume-unchanged path... git-update-index --no-assume-unchanged path... These forms manipulate only the CE_VALID bit; it does not change the object name recorded in the index file. Nor they add a new entry to the index. When the configuration variable "core.ignorestat = true" is set, the index entries are marked with CE_VALID bit automatically after: - update-index to explicitly register the current object name to the index file. - when update-index --refresh finds the path to be up-to-date. - when tools like read-tree -u and apply --index update the working tree file and register the current object name to the index file. The flag is dropped upon read-tree that does not check out the index entry. This happens regardless of the core.ignorestat settings. Index entries marked with CE_VALID bit are assumed to be unchanged most of the time. However, there are cases that CE_VALID bit is ignored for the sake of safety and usability: - while "git-read-tree -m" or git-apply need to make sure that the paths involved in the merge do not have local modifications. This sacrifices performance for safety. - when git-checkout-index -f -q -u -a tries to see if it needs to checkout the paths. Otherwise you can never check anything out ;-). - when git-update-index --really-refresh (a new flag) tries to see if the index entry is up to date. You can start with everything marked as CE_VALID and run this once to drop CE_VALID bit for paths that are modified. Most notably, "update-index --refresh" honours CE_VALID and does not actively stat, so after you modified a file in the working tree, update-index --refresh would not notice until you tell the index about it with "git-update-index path" or "git-update-index --no-assume-unchanged path". This version is not expected to be perfect. I think diff between index and/or tree and working files may need some adjustment, and there probably needs other cases we should automatically unmark paths that are marked to be CE_VALID. But the basics seem to work, and ready to be tested by people who asked for this feature. Signed-off-by: Junio C Hamano <junkio@cox.net>
2006-02-09 06:15:24 +01:00
changed = ce_match_stat_basic(ce, st);
Racy GIT This fixes the longstanding "Racy GIT" problem, which was pretty much there from the beginning of time, but was first demonstrated by Pasky in this message on October 24, 2005: http://marc.theaimsgroup.com/?l=git&m=113014629716878 If you run the following sequence of commands: echo frotz >infocom git update-index --add infocom echo xyzzy >infocom so that the second update to file "infocom" does not change st_mtime, what is recorded as the stat information for the cache entry "infocom" exactly matches what is on the filesystem (owner, group, inum, mtime, ctime, mode, length). After this sequence, we incorrectly think "infocom" file still has string "frotz" in it, and get really confused. E.g. git-diff-files would say there is no change, git-update-index --refresh would not even look at the filesystem to correct the situation. Some ways of working around this issue were already suggested by Linus in the same thread on the same day, including waiting until the next second before returning from update-index if a cache entry written out has the current timestamp, but that means we can make at most one commit per second, and given that the e-mail patch workflow used by Linus needs to process at least 5 commits per second, it is not an acceptable solution. Linus notes that git-apply is primarily used to update the index while processing e-mailed patches, which is true, and git-apply's up-to-date check is fooled by the same problem but luckily in the other direction, so it is not really a big issue, but still it is disturbing. The function ce_match_stat() is called to bypass the comparison against filesystem data when the stat data recorded in the cache entry matches what stat() returns from the filesystem. This patch tackles the problem by changing it to actually go to the filesystem data for cache entries that have the same mtime as the index file itself. This works as long as the index file and working tree files are on the filesystems that share the same monotonic clock. Files on network mounted filesystems sometimes get skewed timestamps compared to "date" output, but as long as working tree files' timestamps are skewed the same way as the index file's, this approach still works. The only problematic files are the ones that have the same timestamp as the index file's, because two file updates that sandwitch the index file update must happen within the same second to trigger the problem. Signed-off-by: Junio C Hamano <junkio@cox.net>
2005-12-20 09:02:15 +01:00
/*
* Within 1 second of this sequence:
* echo xyzzy >file && git-update-index --add file
* running this command:
* echo frotz >file
* would give a falsely clean cache entry. The mtime and
* length match the cache, and other stat fields do not change.
*
* We could detect this at update-index time (the cache entry
* being registered/updated records the same time as "now")
* and delay the return from git-update-index, but that would
* effectively mean we can make at most one commit per second,
* which is not acceptable. Instead, we check cache entries
* whose mtime are the same as the index file timestamp more
"Assume unchanged" git This adds "assume unchanged" logic, started by this message in the list discussion recently: <Pine.LNX.4.64.0601311807470.7301@g5.osdl.org> This is a workaround for filesystems that do not have lstat() that is quick enough for the index mechanism to take advantage of. On the paths marked as "assumed to be unchanged", the user needs to explicitly use update-index to register the object name to be in the next commit. You can use two new options to update-index to set and reset the CE_VALID bit: git-update-index --assume-unchanged path... git-update-index --no-assume-unchanged path... These forms manipulate only the CE_VALID bit; it does not change the object name recorded in the index file. Nor they add a new entry to the index. When the configuration variable "core.ignorestat = true" is set, the index entries are marked with CE_VALID bit automatically after: - update-index to explicitly register the current object name to the index file. - when update-index --refresh finds the path to be up-to-date. - when tools like read-tree -u and apply --index update the working tree file and register the current object name to the index file. The flag is dropped upon read-tree that does not check out the index entry. This happens regardless of the core.ignorestat settings. Index entries marked with CE_VALID bit are assumed to be unchanged most of the time. However, there are cases that CE_VALID bit is ignored for the sake of safety and usability: - while "git-read-tree -m" or git-apply need to make sure that the paths involved in the merge do not have local modifications. This sacrifices performance for safety. - when git-checkout-index -f -q -u -a tries to see if it needs to checkout the paths. Otherwise you can never check anything out ;-). - when git-update-index --really-refresh (a new flag) tries to see if the index entry is up to date. You can start with everything marked as CE_VALID and run this once to drop CE_VALID bit for paths that are modified. Most notably, "update-index --refresh" honours CE_VALID and does not actively stat, so after you modified a file in the working tree, update-index --refresh would not notice until you tell the index about it with "git-update-index path" or "git-update-index --no-assume-unchanged path". This version is not expected to be perfect. I think diff between index and/or tree and working files may need some adjustment, and there probably needs other cases we should automatically unmark paths that are marked to be CE_VALID. But the basics seem to work, and ready to be tested by people who asked for this feature. Signed-off-by: Junio C Hamano <junkio@cox.net>
2006-02-09 06:15:24 +01:00
* carefully than others.
Racy GIT This fixes the longstanding "Racy GIT" problem, which was pretty much there from the beginning of time, but was first demonstrated by Pasky in this message on October 24, 2005: http://marc.theaimsgroup.com/?l=git&m=113014629716878 If you run the following sequence of commands: echo frotz >infocom git update-index --add infocom echo xyzzy >infocom so that the second update to file "infocom" does not change st_mtime, what is recorded as the stat information for the cache entry "infocom" exactly matches what is on the filesystem (owner, group, inum, mtime, ctime, mode, length). After this sequence, we incorrectly think "infocom" file still has string "frotz" in it, and get really confused. E.g. git-diff-files would say there is no change, git-update-index --refresh would not even look at the filesystem to correct the situation. Some ways of working around this issue were already suggested by Linus in the same thread on the same day, including waiting until the next second before returning from update-index if a cache entry written out has the current timestamp, but that means we can make at most one commit per second, and given that the e-mail patch workflow used by Linus needs to process at least 5 commits per second, it is not an acceptable solution. Linus notes that git-apply is primarily used to update the index while processing e-mailed patches, which is true, and git-apply's up-to-date check is fooled by the same problem but luckily in the other direction, so it is not really a big issue, but still it is disturbing. The function ce_match_stat() is called to bypass the comparison against filesystem data when the stat data recorded in the cache entry matches what stat() returns from the filesystem. This patch tackles the problem by changing it to actually go to the filesystem data for cache entries that have the same mtime as the index file itself. This works as long as the index file and working tree files are on the filesystems that share the same monotonic clock. Files on network mounted filesystems sometimes get skewed timestamps compared to "date" output, but as long as working tree files' timestamps are skewed the same way as the index file's, this approach still works. The only problematic files are the ones that have the same timestamp as the index file's, because two file updates that sandwitch the index file update must happen within the same second to trigger the problem. Signed-off-by: Junio C Hamano <junkio@cox.net>
2005-12-20 09:02:15 +01:00
*/
if (!changed && is_racy_timestamp(istate, ce)) {
if (assume_racy_is_modified)
changed |= DATA_CHANGED;
else
changed |= ce_modified_check_fs(istate, ce, st);
}
Racy GIT This fixes the longstanding "Racy GIT" problem, which was pretty much there from the beginning of time, but was first demonstrated by Pasky in this message on October 24, 2005: http://marc.theaimsgroup.com/?l=git&m=113014629716878 If you run the following sequence of commands: echo frotz >infocom git update-index --add infocom echo xyzzy >infocom so that the second update to file "infocom" does not change st_mtime, what is recorded as the stat information for the cache entry "infocom" exactly matches what is on the filesystem (owner, group, inum, mtime, ctime, mode, length). After this sequence, we incorrectly think "infocom" file still has string "frotz" in it, and get really confused. E.g. git-diff-files would say there is no change, git-update-index --refresh would not even look at the filesystem to correct the situation. Some ways of working around this issue were already suggested by Linus in the same thread on the same day, including waiting until the next second before returning from update-index if a cache entry written out has the current timestamp, but that means we can make at most one commit per second, and given that the e-mail patch workflow used by Linus needs to process at least 5 commits per second, it is not an acceptable solution. Linus notes that git-apply is primarily used to update the index while processing e-mailed patches, which is true, and git-apply's up-to-date check is fooled by the same problem but luckily in the other direction, so it is not really a big issue, but still it is disturbing. The function ce_match_stat() is called to bypass the comparison against filesystem data when the stat data recorded in the cache entry matches what stat() returns from the filesystem. This patch tackles the problem by changing it to actually go to the filesystem data for cache entries that have the same mtime as the index file itself. This works as long as the index file and working tree files are on the filesystems that share the same monotonic clock. Files on network mounted filesystems sometimes get skewed timestamps compared to "date" output, but as long as working tree files' timestamps are skewed the same way as the index file's, this approach still works. The only problematic files are the ones that have the same timestamp as the index file's, because two file updates that sandwitch the index file update must happen within the same second to trigger the problem. Signed-off-by: Junio C Hamano <junkio@cox.net>
2005-12-20 09:02:15 +01:00
return changed;
}
int ie_modified(struct index_state *istate,
const struct cache_entry *ce,
struct stat *st, unsigned int options)
{
Racy GIT This fixes the longstanding "Racy GIT" problem, which was pretty much there from the beginning of time, but was first demonstrated by Pasky in this message on October 24, 2005: http://marc.theaimsgroup.com/?l=git&m=113014629716878 If you run the following sequence of commands: echo frotz >infocom git update-index --add infocom echo xyzzy >infocom so that the second update to file "infocom" does not change st_mtime, what is recorded as the stat information for the cache entry "infocom" exactly matches what is on the filesystem (owner, group, inum, mtime, ctime, mode, length). After this sequence, we incorrectly think "infocom" file still has string "frotz" in it, and get really confused. E.g. git-diff-files would say there is no change, git-update-index --refresh would not even look at the filesystem to correct the situation. Some ways of working around this issue were already suggested by Linus in the same thread on the same day, including waiting until the next second before returning from update-index if a cache entry written out has the current timestamp, but that means we can make at most one commit per second, and given that the e-mail patch workflow used by Linus needs to process at least 5 commits per second, it is not an acceptable solution. Linus notes that git-apply is primarily used to update the index while processing e-mailed patches, which is true, and git-apply's up-to-date check is fooled by the same problem but luckily in the other direction, so it is not really a big issue, but still it is disturbing. The function ce_match_stat() is called to bypass the comparison against filesystem data when the stat data recorded in the cache entry matches what stat() returns from the filesystem. This patch tackles the problem by changing it to actually go to the filesystem data for cache entries that have the same mtime as the index file itself. This works as long as the index file and working tree files are on the filesystems that share the same monotonic clock. Files on network mounted filesystems sometimes get skewed timestamps compared to "date" output, but as long as working tree files' timestamps are skewed the same way as the index file's, this approach still works. The only problematic files are the ones that have the same timestamp as the index file's, because two file updates that sandwitch the index file update must happen within the same second to trigger the problem. Signed-off-by: Junio C Hamano <junkio@cox.net>
2005-12-20 09:02:15 +01:00
int changed, changed_fs;
changed = ie_match_stat(istate, ce, st, options);
if (!changed)
return 0;
/*
* If the mode or type has changed, there's no point in trying
* to refresh the entry - it's not going to match
*/
if (changed & (MODE_CHANGED | TYPE_CHANGED))
return changed;
2008-07-29 10:13:44 +02:00
/*
* Immediately after read-tree or update-index --cacheinfo,
* the length field is zero, as we have never even read the
* lstat(2) information once, and we cannot trust DATA_CHANGED
* returned by ie_match_stat() which in turn was returned by
* ce_match_stat_basic() to signal that the filesize of the
* blob changed. We have to actually go to the filesystem to
* see if the contents match, and if so, should answer "unchanged".
*
* The logic does not apply to gitlinks, as ce_match_stat_basic()
* already has checked the actual HEAD from the filesystem in the
* subproject. If ie_match_stat() already said it is different,
* then we know it is.
*/
2008-07-29 10:13:44 +02:00
if ((changed & DATA_CHANGED) &&
(S_ISGITLINK(ce->ce_mode) || ce->ce_stat_data.sd_size != 0))
return changed;
changed_fs = ce_modified_check_fs(istate, ce, st);
Racy GIT This fixes the longstanding "Racy GIT" problem, which was pretty much there from the beginning of time, but was first demonstrated by Pasky in this message on October 24, 2005: http://marc.theaimsgroup.com/?l=git&m=113014629716878 If you run the following sequence of commands: echo frotz >infocom git update-index --add infocom echo xyzzy >infocom so that the second update to file "infocom" does not change st_mtime, what is recorded as the stat information for the cache entry "infocom" exactly matches what is on the filesystem (owner, group, inum, mtime, ctime, mode, length). After this sequence, we incorrectly think "infocom" file still has string "frotz" in it, and get really confused. E.g. git-diff-files would say there is no change, git-update-index --refresh would not even look at the filesystem to correct the situation. Some ways of working around this issue were already suggested by Linus in the same thread on the same day, including waiting until the next second before returning from update-index if a cache entry written out has the current timestamp, but that means we can make at most one commit per second, and given that the e-mail patch workflow used by Linus needs to process at least 5 commits per second, it is not an acceptable solution. Linus notes that git-apply is primarily used to update the index while processing e-mailed patches, which is true, and git-apply's up-to-date check is fooled by the same problem but luckily in the other direction, so it is not really a big issue, but still it is disturbing. The function ce_match_stat() is called to bypass the comparison against filesystem data when the stat data recorded in the cache entry matches what stat() returns from the filesystem. This patch tackles the problem by changing it to actually go to the filesystem data for cache entries that have the same mtime as the index file itself. This works as long as the index file and working tree files are on the filesystems that share the same monotonic clock. Files on network mounted filesystems sometimes get skewed timestamps compared to "date" output, but as long as working tree files' timestamps are skewed the same way as the index file's, this approach still works. The only problematic files are the ones that have the same timestamp as the index file's, because two file updates that sandwitch the index file update must happen within the same second to trigger the problem. Signed-off-by: Junio C Hamano <junkio@cox.net>
2005-12-20 09:02:15 +01:00
if (changed_fs)
return changed | changed_fs;
return 0;
}
int base_name_compare(const char *name1, int len1, int mode1,
const char *name2, int len2, int mode2)
{
unsigned char c1, c2;
int len = len1 < len2 ? len1 : len2;
int cmp;
cmp = memcmp(name1, name2, len);
if (cmp)
return cmp;
c1 = name1[len];
c2 = name2[len];
if (!c1 && S_ISDIR(mode1))
c1 = '/';
if (!c2 && S_ISDIR(mode2))
c2 = '/';
return (c1 < c2) ? -1 : (c1 > c2) ? 1 : 0;
}
/*
* df_name_compare() is identical to base_name_compare(), except it
* compares conflicting directory/file entries as equal. Note that
* while a directory name compares as equal to a regular file, they
* then individually compare _differently_ to a filename that has
* a dot after the basename (because '\0' < '.' < '/').
*
* This is used by routines that want to traverse the git namespace
* but then handle conflicting entries together when possible.
*/
int df_name_compare(const char *name1, int len1, int mode1,
const char *name2, int len2, int mode2)
{
int len = len1 < len2 ? len1 : len2, cmp;
unsigned char c1, c2;
cmp = memcmp(name1, name2, len);
if (cmp)
return cmp;
/* Directories and files compare equal (same length, same name) */
if (len1 == len2)
return 0;
c1 = name1[len];
if (!c1 && S_ISDIR(mode1))
c1 = '/';
c2 = name2[len];
if (!c2 && S_ISDIR(mode2))
c2 = '/';
if (c1 == '/' && !c2)
return 0;
if (c2 == '/' && !c1)
return 0;
return c1 - c2;
}
int name_compare(const char *name1, size_t len1, const char *name2, size_t len2)
{
size_t min_len = (len1 < len2) ? len1 : len2;
int cmp = memcmp(name1, name2, min_len);
if (cmp)
return cmp;
if (len1 < len2)
return -1;
if (len1 > len2)
return 1;
return 0;
}
int cache_name_stage_compare(const char *name1, int len1, int stage1, const char *name2, int len2, int stage2)
{
int cmp;
cmp = name_compare(name1, len1, name2, len2);
if (cmp)
return cmp;
"Assume unchanged" git This adds "assume unchanged" logic, started by this message in the list discussion recently: <Pine.LNX.4.64.0601311807470.7301@g5.osdl.org> This is a workaround for filesystems that do not have lstat() that is quick enough for the index mechanism to take advantage of. On the paths marked as "assumed to be unchanged", the user needs to explicitly use update-index to register the object name to be in the next commit. You can use two new options to update-index to set and reset the CE_VALID bit: git-update-index --assume-unchanged path... git-update-index --no-assume-unchanged path... These forms manipulate only the CE_VALID bit; it does not change the object name recorded in the index file. Nor they add a new entry to the index. When the configuration variable "core.ignorestat = true" is set, the index entries are marked with CE_VALID bit automatically after: - update-index to explicitly register the current object name to the index file. - when update-index --refresh finds the path to be up-to-date. - when tools like read-tree -u and apply --index update the working tree file and register the current object name to the index file. The flag is dropped upon read-tree that does not check out the index entry. This happens regardless of the core.ignorestat settings. Index entries marked with CE_VALID bit are assumed to be unchanged most of the time. However, there are cases that CE_VALID bit is ignored for the sake of safety and usability: - while "git-read-tree -m" or git-apply need to make sure that the paths involved in the merge do not have local modifications. This sacrifices performance for safety. - when git-checkout-index -f -q -u -a tries to see if it needs to checkout the paths. Otherwise you can never check anything out ;-). - when git-update-index --really-refresh (a new flag) tries to see if the index entry is up to date. You can start with everything marked as CE_VALID and run this once to drop CE_VALID bit for paths that are modified. Most notably, "update-index --refresh" honours CE_VALID and does not actively stat, so after you modified a file in the working tree, update-index --refresh would not notice until you tell the index about it with "git-update-index path" or "git-update-index --no-assume-unchanged path". This version is not expected to be perfect. I think diff between index and/or tree and working files may need some adjustment, and there probably needs other cases we should automatically unmark paths that are marked to be CE_VALID. But the basics seem to work, and ready to be tested by people who asked for this feature. Signed-off-by: Junio C Hamano <junkio@cox.net>
2006-02-09 06:15:24 +01:00
if (stage1 < stage2)
return -1;
if (stage1 > stage2)
return 1;
return 0;
}
static int index_name_stage_pos(struct index_state *istate,
const char *name, int namelen,
int stage,
enum index_search_mode search_mode)
{
int first, last;
first = 0;
last = istate->cache_nr;
while (last > first) {
int next = first + ((last - first) >> 1);
struct cache_entry *ce = istate->cache[next];
int cmp = cache_name_stage_compare(name, namelen, stage, ce->name, ce_namelen(ce), ce_stage(ce));
if (!cmp)
return next;
if (cmp < 0) {
last = next;
continue;
}
first = next+1;
}
if (search_mode == EXPAND_SPARSE && istate->sparse_index &&
first > 0) {
/* Note: first <= istate->cache_nr */
struct cache_entry *ce = istate->cache[first - 1];
/*
* If we are in a sparse-index _and_ the entry before the
* insertion position is a sparse-directory entry that is
* an ancestor of 'name', then we need to expand the index
* and search again. This will only trigger once, because
* thereafter the index is fully expanded.
*/
if (S_ISSPARSEDIR(ce->ce_mode) &&
ce_namelen(ce) < namelen &&
!strncmp(name, ce->name, ce_namelen(ce))) {
ensure_full_index(istate);
return index_name_stage_pos(istate, name, namelen, stage, search_mode);
}
}
return -first-1;
}
int index_name_pos(struct index_state *istate, const char *name, int namelen)
{
return index_name_stage_pos(istate, name, namelen, 0, EXPAND_SPARSE);
}
int index_entry_exists(struct index_state *istate, const char *name, int namelen)
{
return index_name_stage_pos(istate, name, namelen, 0, NO_EXPAND_SPARSE) >= 0;
}
int remove_index_entry_at(struct index_state *istate, int pos)
{
Create pathname-based hash-table lookup into index This creates a hash index of every single file added to the index. Right now that hash index isn't actually used for much: I implemented a "cache_name_exists()" function that uses it to efficiently look up a filename in the index without having to do the O(logn) binary search, but quite frankly, that's not why this patch is interesting. No, the whole and only reason to create the hash of the filenames in the index is that by modifying the hash function, you can fairly easily do things like making it always hash equivalent names into the same bucket. That, in turn, means that suddenly questions like "does this name exist in the index under an _equivalent_ name?" becomes much much cheaper. Guiding principles behind this patch: - it shouldn't be too costly. In fact, my primary goal here was to actually speed up "git commit" with a fully populated kernel tree, by being faster at checking whether a file already existed in the index. I did succeed, but only barely: Best before: [torvalds@woody linux]$ time git commit > /dev/null real 0m0.255s user 0m0.168s sys 0m0.088s Best after: [torvalds@woody linux]$ time ~/git/git commit > /dev/null real 0m0.233s user 0m0.144s sys 0m0.088s so some things are actually faster (~8%). Caveat: that's really the best case. Other things are invariably going to be slightly slower, since we populate that index cache, and quite frankly, few things really use it to look things up. That said, the cost is really quite small. The worst case is probably doing a "git ls-files", which will do very little except puopulate the index, and never actually looks anything up in it, just lists it. Before: [torvalds@woody linux]$ time git ls-files > /dev/null real 0m0.016s user 0m0.016s sys 0m0.000s After: [torvalds@woody linux]$ time ~/git/git ls-files > /dev/null real 0m0.021s user 0m0.012s sys 0m0.008s and while the thing has really gotten relatively much slower, we're still talking about something almost unmeasurable (eg 5ms). And that really should be pretty much the worst case. So we lose 5ms on one "benchmark", but win 22ms on another. Pick your poison - this patch has the advantage that it will _likely_ speed up the cases that are complex and expensive more than it slows down the cases that are already so fast that nobody cares. But if you look at relative speedups/slowdowns, it doesn't look so good. - It should be simple and clean The code may be a bit subtle (the reasons I do hash removal the way I do etc), but it re-uses the existing hash.c files, so it really is fairly small and straightforward apart from a few odd details. Now, this patch on its own doesn't really do much, but I think it's worth looking at, if only because if done correctly, the name hashing really can make an improvement to the whole issue of "do we have a filename that looks like this in the index already". And at least it gets real testing by being used even by default (ie there is a real use-case for it even without any insane filesystems). NOTE NOTE NOTE! The current hash is a joke. I'm ashamed of it, I'm just not ashamed of it enough to really care. I took all the numbers out of my nether regions - I'm sure it's good enough that it works in practice, but the whole point was that you can make a really much fancier hash that hashes characters not directly, but by their upper-case value or something like that, and thus you get a case-insensitive hash, while still keeping the name and the index itself totally case sensitive. Signed-off-by: Linus Torvalds <torvalds@linux-foundation.org> Signed-off-by: Junio C Hamano <gitster@pobox.com>
2008-01-23 03:41:14 +01:00
struct cache_entry *ce = istate->cache[pos];
record_resolve_undo(istate, ce);
name-hash.c: fix endless loop with core.ignorecase=true With core.ignorecase=true, name-hash.c builds a case insensitive index of all tracked directories. Currently, the existing cache entry structures are added multiple times to the same hashtable (with different name lengths and hash codes). However, there's only one dir_next pointer, which gets completely messed up in case of hash collisions. In the worst case, this causes an endless loop if ce == ce->dir_next (see t7062). Use a separate hashtable and separate structures for the directory index so that each directory entry has its own next pointer. Use reference counting to track which directory entry contains files. There are only slight changes to the name-hash.c API: - new free_name_hash() used by read_cache.c::discard_index() - remove_name_hash() takes an additional index_state parameter - index_name_exists() for a directory (trailing '/') may return a cache entry that has been removed (CE_UNHASHED). This is not a problem as the return value is only used to check if the directory exists (dir.c) or to normalize casing of directory names (read-cache.c). Getting rid of cache_entry.dir_next reduces memory consumption, especially with core.ignorecase=false (which doesn't use that member at all). With core.ignorecase=true, building the directory index is slightly faster as we add / check the parent directory first (instead of going through all directory levels for each file in the index). E.g. with WebKit (~200k files, ~7k dirs), time spent in lazy_init_name_hash is reduced from 176ms to 130ms. Signed-off-by: Karsten Blees <blees@dcon.de> Signed-off-by: Junio C Hamano <gitster@pobox.com>
2013-02-28 00:57:48 +01:00
remove_name_hash(istate, ce);
save_or_free_index_entry(istate, ce);
istate->cache_changed |= CE_ENTRY_REMOVED;
istate->cache_nr--;
if (pos >= istate->cache_nr)
return 0;
MOVE_ARRAY(istate->cache + pos, istate->cache + pos + 1,
istate->cache_nr - pos);
return 1;
}
check_updates(): effective removal of cache entries marked CE_REMOVE Below is oprofile output from GIT command 'git chekcout -q my-v2.6.25' (move from tag v2.6.27 to tag v2.6.25 of the Linux kernel): CPU: Core 2, speed 1999.95 MHz (estimated) Counted CPU_CLK_UNHALTED events (Clock cycles when not halted) with a unit mask of 0x00 (Unhalted core cycles) count 20000 Counted INST_RETIRED_ANY_P events (number of instructions retired) with a unit mask of 0x00 (No unit mask) count 20000 CPU_CLK_UNHALT...|INST_RETIRED:2...| samples| %| samples| %| ------------------------------------ 409247 100.000 342878 100.000 git CPU_CLK_UNHALT...|INST_RETIRED:2...| samples| %| samples| %| ------------------------------------ 260476 63.6476 257843 75.1996 libz.so.1.2.3 100876 24.6492 64378 18.7758 kernel-2.6.28.4_2.vmlinux 30850 7.5382 7874 2.2964 libc-2.9.so 14775 3.6103 8390 2.4469 git 2020 0.4936 4325 1.2614 libcrypto.so.0.9.8 191 0.0467 32 0.0093 libpthread-2.9.so 58 0.0142 36 0.0105 ld-2.9.so 1 2.4e-04 0 0 libldap-2.3.so.0.2.31 Detail list of the top 20 function entries (libz counted in one blob): CPU_CLK_UNHALTED INST_RETIRED_ANY_P samples % samples % image name symbol name 260476 63.6862 257843 75.2725 libz.so.1.2.3 /lib/libz.so.1.2.3 16587 4.0555 3636 1.0615 libc-2.9.so memcpy 7710 1.8851 277 0.0809 libc-2.9.so memmove 3679 0.8995 1108 0.3235 kernel-2.6.28.4_2.vmlinux d_validate 3546 0.8670 2607 0.7611 kernel-2.6.28.4_2.vmlinux __getblk 3174 0.7760 1813 0.5293 libc-2.9.so _int_malloc 2396 0.5858 3681 1.0746 kernel-2.6.28.4_2.vmlinux copy_to_user 2270 0.5550 2528 0.7380 kernel-2.6.28.4_2.vmlinux __link_path_walk 2205 0.5391 1797 0.5246 kernel-2.6.28.4_2.vmlinux ext4_mark_iloc_dirty 2103 0.5142 1203 0.3512 kernel-2.6.28.4_2.vmlinux find_first_zero_bit 2077 0.5078 997 0.2911 kernel-2.6.28.4_2.vmlinux do_get_write_access 2070 0.5061 514 0.1501 git cache_name_compare 2043 0.4995 1501 0.4382 kernel-2.6.28.4_2.vmlinux rcu_irq_exit 2022 0.4944 1732 0.5056 kernel-2.6.28.4_2.vmlinux __ext4_get_inode_loc 2020 0.4939 4325 1.2626 libcrypto.so.0.9.8 /usr/lib/libcrypto.so.0.9.8 1965 0.4804 1384 0.4040 git patch_delta 1708 0.4176 984 0.2873 kernel-2.6.28.4_2.vmlinux rcu_sched_grace_period 1682 0.4112 727 0.2122 kernel-2.6.28.4_2.vmlinux sysfs_slab_alias 1659 0.4056 290 0.0847 git find_pack_entry_one 1480 0.3619 1307 0.3816 kernel-2.6.28.4_2.vmlinux ext4_writepage_trans_blocks Notice the memmove line, where the CPU did 7710 / 277 = 27.8 cycles per instruction, and compared to the total cycles spent inside the source code of GIT for this command, all the memmove() calls translates to (7710 * 100) / 14775 = 52.2% of this. Retesting with a GIT program compiled for gcov usage, I found out that the memmove() calls came from remove_index_entry_at() in read-cache.c, where we have: memmove(istate->cache + pos, istate->cache + pos + 1, (istate->cache_nr - pos) * sizeof(struct cache_entry *)); remove_index_entry_at() is called 4902 times from check_updates() in unpack-trees.c, and each time called we move each cache_entry pointers (from the removed one) one step to the left. Since we have 28828 entries in the cache this time, and if we on average move half of them each time, we in total move approximately 4902 * 0.5 * 28828 * 4 = 282 629 712 bytes, or twice this amount if each pointer is 8 bytes (64 bit). OK, is seems that the function check_updates() is called 28 times, so the estimated guess above had been more correct if check_updates() had been called only once, but the point is: we get lots of bytes moved. To fix this, and use an O(N) algorithm instead, where N is the number of cache_entries, we delete/remove all entries in one loop through all entries. From a retest, the new remove_marked_cache_entries() from the patch below, ended up with the following output line from oprofile: 46 0.0105 15 0.0041 git remove_marked_cache_entries If we can trust the numbers from oprofile in this case, we saved approximately ((7710 - 46) * 20000) / (2 * 1000 * 1000 * 1000) = 0.077 seconds CPU time with this fix for this particular test. And notice that now the CPU did only 46 / 15 = 3.1 cycles/instruction. Signed-off-by: Kjetil Barvik <barvik@broadpark.no> Acked-by: Linus Torvalds <torvalds@linux-foundation.org> Signed-off-by: Junio C Hamano <gitster@pobox.com>
2009-02-18 23:18:03 +01:00
/*
* Remove all cache entries marked for removal, that is where
check_updates(): effective removal of cache entries marked CE_REMOVE Below is oprofile output from GIT command 'git chekcout -q my-v2.6.25' (move from tag v2.6.27 to tag v2.6.25 of the Linux kernel): CPU: Core 2, speed 1999.95 MHz (estimated) Counted CPU_CLK_UNHALTED events (Clock cycles when not halted) with a unit mask of 0x00 (Unhalted core cycles) count 20000 Counted INST_RETIRED_ANY_P events (number of instructions retired) with a unit mask of 0x00 (No unit mask) count 20000 CPU_CLK_UNHALT...|INST_RETIRED:2...| samples| %| samples| %| ------------------------------------ 409247 100.000 342878 100.000 git CPU_CLK_UNHALT...|INST_RETIRED:2...| samples| %| samples| %| ------------------------------------ 260476 63.6476 257843 75.1996 libz.so.1.2.3 100876 24.6492 64378 18.7758 kernel-2.6.28.4_2.vmlinux 30850 7.5382 7874 2.2964 libc-2.9.so 14775 3.6103 8390 2.4469 git 2020 0.4936 4325 1.2614 libcrypto.so.0.9.8 191 0.0467 32 0.0093 libpthread-2.9.so 58 0.0142 36 0.0105 ld-2.9.so 1 2.4e-04 0 0 libldap-2.3.so.0.2.31 Detail list of the top 20 function entries (libz counted in one blob): CPU_CLK_UNHALTED INST_RETIRED_ANY_P samples % samples % image name symbol name 260476 63.6862 257843 75.2725 libz.so.1.2.3 /lib/libz.so.1.2.3 16587 4.0555 3636 1.0615 libc-2.9.so memcpy 7710 1.8851 277 0.0809 libc-2.9.so memmove 3679 0.8995 1108 0.3235 kernel-2.6.28.4_2.vmlinux d_validate 3546 0.8670 2607 0.7611 kernel-2.6.28.4_2.vmlinux __getblk 3174 0.7760 1813 0.5293 libc-2.9.so _int_malloc 2396 0.5858 3681 1.0746 kernel-2.6.28.4_2.vmlinux copy_to_user 2270 0.5550 2528 0.7380 kernel-2.6.28.4_2.vmlinux __link_path_walk 2205 0.5391 1797 0.5246 kernel-2.6.28.4_2.vmlinux ext4_mark_iloc_dirty 2103 0.5142 1203 0.3512 kernel-2.6.28.4_2.vmlinux find_first_zero_bit 2077 0.5078 997 0.2911 kernel-2.6.28.4_2.vmlinux do_get_write_access 2070 0.5061 514 0.1501 git cache_name_compare 2043 0.4995 1501 0.4382 kernel-2.6.28.4_2.vmlinux rcu_irq_exit 2022 0.4944 1732 0.5056 kernel-2.6.28.4_2.vmlinux __ext4_get_inode_loc 2020 0.4939 4325 1.2626 libcrypto.so.0.9.8 /usr/lib/libcrypto.so.0.9.8 1965 0.4804 1384 0.4040 git patch_delta 1708 0.4176 984 0.2873 kernel-2.6.28.4_2.vmlinux rcu_sched_grace_period 1682 0.4112 727 0.2122 kernel-2.6.28.4_2.vmlinux sysfs_slab_alias 1659 0.4056 290 0.0847 git find_pack_entry_one 1480 0.3619 1307 0.3816 kernel-2.6.28.4_2.vmlinux ext4_writepage_trans_blocks Notice the memmove line, where the CPU did 7710 / 277 = 27.8 cycles per instruction, and compared to the total cycles spent inside the source code of GIT for this command, all the memmove() calls translates to (7710 * 100) / 14775 = 52.2% of this. Retesting with a GIT program compiled for gcov usage, I found out that the memmove() calls came from remove_index_entry_at() in read-cache.c, where we have: memmove(istate->cache + pos, istate->cache + pos + 1, (istate->cache_nr - pos) * sizeof(struct cache_entry *)); remove_index_entry_at() is called 4902 times from check_updates() in unpack-trees.c, and each time called we move each cache_entry pointers (from the removed one) one step to the left. Since we have 28828 entries in the cache this time, and if we on average move half of them each time, we in total move approximately 4902 * 0.5 * 28828 * 4 = 282 629 712 bytes, or twice this amount if each pointer is 8 bytes (64 bit). OK, is seems that the function check_updates() is called 28 times, so the estimated guess above had been more correct if check_updates() had been called only once, but the point is: we get lots of bytes moved. To fix this, and use an O(N) algorithm instead, where N is the number of cache_entries, we delete/remove all entries in one loop through all entries. From a retest, the new remove_marked_cache_entries() from the patch below, ended up with the following output line from oprofile: 46 0.0105 15 0.0041 git remove_marked_cache_entries If we can trust the numbers from oprofile in this case, we saved approximately ((7710 - 46) * 20000) / (2 * 1000 * 1000 * 1000) = 0.077 seconds CPU time with this fix for this particular test. And notice that now the CPU did only 46 / 15 = 3.1 cycles/instruction. Signed-off-by: Kjetil Barvik <barvik@broadpark.no> Acked-by: Linus Torvalds <torvalds@linux-foundation.org> Signed-off-by: Junio C Hamano <gitster@pobox.com>
2009-02-18 23:18:03 +01:00
* CE_REMOVE is set in ce_flags. This is much more effective than
* calling remove_index_entry_at() for each entry to be removed.
*/
void remove_marked_cache_entries(struct index_state *istate, int invalidate)
check_updates(): effective removal of cache entries marked CE_REMOVE Below is oprofile output from GIT command 'git chekcout -q my-v2.6.25' (move from tag v2.6.27 to tag v2.6.25 of the Linux kernel): CPU: Core 2, speed 1999.95 MHz (estimated) Counted CPU_CLK_UNHALTED events (Clock cycles when not halted) with a unit mask of 0x00 (Unhalted core cycles) count 20000 Counted INST_RETIRED_ANY_P events (number of instructions retired) with a unit mask of 0x00 (No unit mask) count 20000 CPU_CLK_UNHALT...|INST_RETIRED:2...| samples| %| samples| %| ------------------------------------ 409247 100.000 342878 100.000 git CPU_CLK_UNHALT...|INST_RETIRED:2...| samples| %| samples| %| ------------------------------------ 260476 63.6476 257843 75.1996 libz.so.1.2.3 100876 24.6492 64378 18.7758 kernel-2.6.28.4_2.vmlinux 30850 7.5382 7874 2.2964 libc-2.9.so 14775 3.6103 8390 2.4469 git 2020 0.4936 4325 1.2614 libcrypto.so.0.9.8 191 0.0467 32 0.0093 libpthread-2.9.so 58 0.0142 36 0.0105 ld-2.9.so 1 2.4e-04 0 0 libldap-2.3.so.0.2.31 Detail list of the top 20 function entries (libz counted in one blob): CPU_CLK_UNHALTED INST_RETIRED_ANY_P samples % samples % image name symbol name 260476 63.6862 257843 75.2725 libz.so.1.2.3 /lib/libz.so.1.2.3 16587 4.0555 3636 1.0615 libc-2.9.so memcpy 7710 1.8851 277 0.0809 libc-2.9.so memmove 3679 0.8995 1108 0.3235 kernel-2.6.28.4_2.vmlinux d_validate 3546 0.8670 2607 0.7611 kernel-2.6.28.4_2.vmlinux __getblk 3174 0.7760 1813 0.5293 libc-2.9.so _int_malloc 2396 0.5858 3681 1.0746 kernel-2.6.28.4_2.vmlinux copy_to_user 2270 0.5550 2528 0.7380 kernel-2.6.28.4_2.vmlinux __link_path_walk 2205 0.5391 1797 0.5246 kernel-2.6.28.4_2.vmlinux ext4_mark_iloc_dirty 2103 0.5142 1203 0.3512 kernel-2.6.28.4_2.vmlinux find_first_zero_bit 2077 0.5078 997 0.2911 kernel-2.6.28.4_2.vmlinux do_get_write_access 2070 0.5061 514 0.1501 git cache_name_compare 2043 0.4995 1501 0.4382 kernel-2.6.28.4_2.vmlinux rcu_irq_exit 2022 0.4944 1732 0.5056 kernel-2.6.28.4_2.vmlinux __ext4_get_inode_loc 2020 0.4939 4325 1.2626 libcrypto.so.0.9.8 /usr/lib/libcrypto.so.0.9.8 1965 0.4804 1384 0.4040 git patch_delta 1708 0.4176 984 0.2873 kernel-2.6.28.4_2.vmlinux rcu_sched_grace_period 1682 0.4112 727 0.2122 kernel-2.6.28.4_2.vmlinux sysfs_slab_alias 1659 0.4056 290 0.0847 git find_pack_entry_one 1480 0.3619 1307 0.3816 kernel-2.6.28.4_2.vmlinux ext4_writepage_trans_blocks Notice the memmove line, where the CPU did 7710 / 277 = 27.8 cycles per instruction, and compared to the total cycles spent inside the source code of GIT for this command, all the memmove() calls translates to (7710 * 100) / 14775 = 52.2% of this. Retesting with a GIT program compiled for gcov usage, I found out that the memmove() calls came from remove_index_entry_at() in read-cache.c, where we have: memmove(istate->cache + pos, istate->cache + pos + 1, (istate->cache_nr - pos) * sizeof(struct cache_entry *)); remove_index_entry_at() is called 4902 times from check_updates() in unpack-trees.c, and each time called we move each cache_entry pointers (from the removed one) one step to the left. Since we have 28828 entries in the cache this time, and if we on average move half of them each time, we in total move approximately 4902 * 0.5 * 28828 * 4 = 282 629 712 bytes, or twice this amount if each pointer is 8 bytes (64 bit). OK, is seems that the function check_updates() is called 28 times, so the estimated guess above had been more correct if check_updates() had been called only once, but the point is: we get lots of bytes moved. To fix this, and use an O(N) algorithm instead, where N is the number of cache_entries, we delete/remove all entries in one loop through all entries. From a retest, the new remove_marked_cache_entries() from the patch below, ended up with the following output line from oprofile: 46 0.0105 15 0.0041 git remove_marked_cache_entries If we can trust the numbers from oprofile in this case, we saved approximately ((7710 - 46) * 20000) / (2 * 1000 * 1000 * 1000) = 0.077 seconds CPU time with this fix for this particular test. And notice that now the CPU did only 46 / 15 = 3.1 cycles/instruction. Signed-off-by: Kjetil Barvik <barvik@broadpark.no> Acked-by: Linus Torvalds <torvalds@linux-foundation.org> Signed-off-by: Junio C Hamano <gitster@pobox.com>
2009-02-18 23:18:03 +01:00
{
struct cache_entry **ce_array = istate->cache;
unsigned int i, j;
for (i = j = 0; i < istate->cache_nr; i++) {
if (ce_array[i]->ce_flags & CE_REMOVE) {
if (invalidate) {
cache_tree_invalidate_path(istate,
ce_array[i]->name);
untracked_cache_remove_from_index(istate,
ce_array[i]->name);
}
name-hash.c: fix endless loop with core.ignorecase=true With core.ignorecase=true, name-hash.c builds a case insensitive index of all tracked directories. Currently, the existing cache entry structures are added multiple times to the same hashtable (with different name lengths and hash codes). However, there's only one dir_next pointer, which gets completely messed up in case of hash collisions. In the worst case, this causes an endless loop if ce == ce->dir_next (see t7062). Use a separate hashtable and separate structures for the directory index so that each directory entry has its own next pointer. Use reference counting to track which directory entry contains files. There are only slight changes to the name-hash.c API: - new free_name_hash() used by read_cache.c::discard_index() - remove_name_hash() takes an additional index_state parameter - index_name_exists() for a directory (trailing '/') may return a cache entry that has been removed (CE_UNHASHED). This is not a problem as the return value is only used to check if the directory exists (dir.c) or to normalize casing of directory names (read-cache.c). Getting rid of cache_entry.dir_next reduces memory consumption, especially with core.ignorecase=false (which doesn't use that member at all). With core.ignorecase=true, building the directory index is slightly faster as we add / check the parent directory first (instead of going through all directory levels for each file in the index). E.g. with WebKit (~200k files, ~7k dirs), time spent in lazy_init_name_hash is reduced from 176ms to 130ms. Signed-off-by: Karsten Blees <blees@dcon.de> Signed-off-by: Junio C Hamano <gitster@pobox.com>
2013-02-28 00:57:48 +01:00
remove_name_hash(istate, ce_array[i]);
save_or_free_index_entry(istate, ce_array[i]);
}
check_updates(): effective removal of cache entries marked CE_REMOVE Below is oprofile output from GIT command 'git chekcout -q my-v2.6.25' (move from tag v2.6.27 to tag v2.6.25 of the Linux kernel): CPU: Core 2, speed 1999.95 MHz (estimated) Counted CPU_CLK_UNHALTED events (Clock cycles when not halted) with a unit mask of 0x00 (Unhalted core cycles) count 20000 Counted INST_RETIRED_ANY_P events (number of instructions retired) with a unit mask of 0x00 (No unit mask) count 20000 CPU_CLK_UNHALT...|INST_RETIRED:2...| samples| %| samples| %| ------------------------------------ 409247 100.000 342878 100.000 git CPU_CLK_UNHALT...|INST_RETIRED:2...| samples| %| samples| %| ------------------------------------ 260476 63.6476 257843 75.1996 libz.so.1.2.3 100876 24.6492 64378 18.7758 kernel-2.6.28.4_2.vmlinux 30850 7.5382 7874 2.2964 libc-2.9.so 14775 3.6103 8390 2.4469 git 2020 0.4936 4325 1.2614 libcrypto.so.0.9.8 191 0.0467 32 0.0093 libpthread-2.9.so 58 0.0142 36 0.0105 ld-2.9.so 1 2.4e-04 0 0 libldap-2.3.so.0.2.31 Detail list of the top 20 function entries (libz counted in one blob): CPU_CLK_UNHALTED INST_RETIRED_ANY_P samples % samples % image name symbol name 260476 63.6862 257843 75.2725 libz.so.1.2.3 /lib/libz.so.1.2.3 16587 4.0555 3636 1.0615 libc-2.9.so memcpy 7710 1.8851 277 0.0809 libc-2.9.so memmove 3679 0.8995 1108 0.3235 kernel-2.6.28.4_2.vmlinux d_validate 3546 0.8670 2607 0.7611 kernel-2.6.28.4_2.vmlinux __getblk 3174 0.7760 1813 0.5293 libc-2.9.so _int_malloc 2396 0.5858 3681 1.0746 kernel-2.6.28.4_2.vmlinux copy_to_user 2270 0.5550 2528 0.7380 kernel-2.6.28.4_2.vmlinux __link_path_walk 2205 0.5391 1797 0.5246 kernel-2.6.28.4_2.vmlinux ext4_mark_iloc_dirty 2103 0.5142 1203 0.3512 kernel-2.6.28.4_2.vmlinux find_first_zero_bit 2077 0.5078 997 0.2911 kernel-2.6.28.4_2.vmlinux do_get_write_access 2070 0.5061 514 0.1501 git cache_name_compare 2043 0.4995 1501 0.4382 kernel-2.6.28.4_2.vmlinux rcu_irq_exit 2022 0.4944 1732 0.5056 kernel-2.6.28.4_2.vmlinux __ext4_get_inode_loc 2020 0.4939 4325 1.2626 libcrypto.so.0.9.8 /usr/lib/libcrypto.so.0.9.8 1965 0.4804 1384 0.4040 git patch_delta 1708 0.4176 984 0.2873 kernel-2.6.28.4_2.vmlinux rcu_sched_grace_period 1682 0.4112 727 0.2122 kernel-2.6.28.4_2.vmlinux sysfs_slab_alias 1659 0.4056 290 0.0847 git find_pack_entry_one 1480 0.3619 1307 0.3816 kernel-2.6.28.4_2.vmlinux ext4_writepage_trans_blocks Notice the memmove line, where the CPU did 7710 / 277 = 27.8 cycles per instruction, and compared to the total cycles spent inside the source code of GIT for this command, all the memmove() calls translates to (7710 * 100) / 14775 = 52.2% of this. Retesting with a GIT program compiled for gcov usage, I found out that the memmove() calls came from remove_index_entry_at() in read-cache.c, where we have: memmove(istate->cache + pos, istate->cache + pos + 1, (istate->cache_nr - pos) * sizeof(struct cache_entry *)); remove_index_entry_at() is called 4902 times from check_updates() in unpack-trees.c, and each time called we move each cache_entry pointers (from the removed one) one step to the left. Since we have 28828 entries in the cache this time, and if we on average move half of them each time, we in total move approximately 4902 * 0.5 * 28828 * 4 = 282 629 712 bytes, or twice this amount if each pointer is 8 bytes (64 bit). OK, is seems that the function check_updates() is called 28 times, so the estimated guess above had been more correct if check_updates() had been called only once, but the point is: we get lots of bytes moved. To fix this, and use an O(N) algorithm instead, where N is the number of cache_entries, we delete/remove all entries in one loop through all entries. From a retest, the new remove_marked_cache_entries() from the patch below, ended up with the following output line from oprofile: 46 0.0105 15 0.0041 git remove_marked_cache_entries If we can trust the numbers from oprofile in this case, we saved approximately ((7710 - 46) * 20000) / (2 * 1000 * 1000 * 1000) = 0.077 seconds CPU time with this fix for this particular test. And notice that now the CPU did only 46 / 15 = 3.1 cycles/instruction. Signed-off-by: Kjetil Barvik <barvik@broadpark.no> Acked-by: Linus Torvalds <torvalds@linux-foundation.org> Signed-off-by: Junio C Hamano <gitster@pobox.com>
2009-02-18 23:18:03 +01:00
else
ce_array[j++] = ce_array[i];
}
if (j == istate->cache_nr)
return;
istate->cache_changed |= CE_ENTRY_REMOVED;
check_updates(): effective removal of cache entries marked CE_REMOVE Below is oprofile output from GIT command 'git chekcout -q my-v2.6.25' (move from tag v2.6.27 to tag v2.6.25 of the Linux kernel): CPU: Core 2, speed 1999.95 MHz (estimated) Counted CPU_CLK_UNHALTED events (Clock cycles when not halted) with a unit mask of 0x00 (Unhalted core cycles) count 20000 Counted INST_RETIRED_ANY_P events (number of instructions retired) with a unit mask of 0x00 (No unit mask) count 20000 CPU_CLK_UNHALT...|INST_RETIRED:2...| samples| %| samples| %| ------------------------------------ 409247 100.000 342878 100.000 git CPU_CLK_UNHALT...|INST_RETIRED:2...| samples| %| samples| %| ------------------------------------ 260476 63.6476 257843 75.1996 libz.so.1.2.3 100876 24.6492 64378 18.7758 kernel-2.6.28.4_2.vmlinux 30850 7.5382 7874 2.2964 libc-2.9.so 14775 3.6103 8390 2.4469 git 2020 0.4936 4325 1.2614 libcrypto.so.0.9.8 191 0.0467 32 0.0093 libpthread-2.9.so 58 0.0142 36 0.0105 ld-2.9.so 1 2.4e-04 0 0 libldap-2.3.so.0.2.31 Detail list of the top 20 function entries (libz counted in one blob): CPU_CLK_UNHALTED INST_RETIRED_ANY_P samples % samples % image name symbol name 260476 63.6862 257843 75.2725 libz.so.1.2.3 /lib/libz.so.1.2.3 16587 4.0555 3636 1.0615 libc-2.9.so memcpy 7710 1.8851 277 0.0809 libc-2.9.so memmove 3679 0.8995 1108 0.3235 kernel-2.6.28.4_2.vmlinux d_validate 3546 0.8670 2607 0.7611 kernel-2.6.28.4_2.vmlinux __getblk 3174 0.7760 1813 0.5293 libc-2.9.so _int_malloc 2396 0.5858 3681 1.0746 kernel-2.6.28.4_2.vmlinux copy_to_user 2270 0.5550 2528 0.7380 kernel-2.6.28.4_2.vmlinux __link_path_walk 2205 0.5391 1797 0.5246 kernel-2.6.28.4_2.vmlinux ext4_mark_iloc_dirty 2103 0.5142 1203 0.3512 kernel-2.6.28.4_2.vmlinux find_first_zero_bit 2077 0.5078 997 0.2911 kernel-2.6.28.4_2.vmlinux do_get_write_access 2070 0.5061 514 0.1501 git cache_name_compare 2043 0.4995 1501 0.4382 kernel-2.6.28.4_2.vmlinux rcu_irq_exit 2022 0.4944 1732 0.5056 kernel-2.6.28.4_2.vmlinux __ext4_get_inode_loc 2020 0.4939 4325 1.2626 libcrypto.so.0.9.8 /usr/lib/libcrypto.so.0.9.8 1965 0.4804 1384 0.4040 git patch_delta 1708 0.4176 984 0.2873 kernel-2.6.28.4_2.vmlinux rcu_sched_grace_period 1682 0.4112 727 0.2122 kernel-2.6.28.4_2.vmlinux sysfs_slab_alias 1659 0.4056 290 0.0847 git find_pack_entry_one 1480 0.3619 1307 0.3816 kernel-2.6.28.4_2.vmlinux ext4_writepage_trans_blocks Notice the memmove line, where the CPU did 7710 / 277 = 27.8 cycles per instruction, and compared to the total cycles spent inside the source code of GIT for this command, all the memmove() calls translates to (7710 * 100) / 14775 = 52.2% of this. Retesting with a GIT program compiled for gcov usage, I found out that the memmove() calls came from remove_index_entry_at() in read-cache.c, where we have: memmove(istate->cache + pos, istate->cache + pos + 1, (istate->cache_nr - pos) * sizeof(struct cache_entry *)); remove_index_entry_at() is called 4902 times from check_updates() in unpack-trees.c, and each time called we move each cache_entry pointers (from the removed one) one step to the left. Since we have 28828 entries in the cache this time, and if we on average move half of them each time, we in total move approximately 4902 * 0.5 * 28828 * 4 = 282 629 712 bytes, or twice this amount if each pointer is 8 bytes (64 bit). OK, is seems that the function check_updates() is called 28 times, so the estimated guess above had been more correct if check_updates() had been called only once, but the point is: we get lots of bytes moved. To fix this, and use an O(N) algorithm instead, where N is the number of cache_entries, we delete/remove all entries in one loop through all entries. From a retest, the new remove_marked_cache_entries() from the patch below, ended up with the following output line from oprofile: 46 0.0105 15 0.0041 git remove_marked_cache_entries If we can trust the numbers from oprofile in this case, we saved approximately ((7710 - 46) * 20000) / (2 * 1000 * 1000 * 1000) = 0.077 seconds CPU time with this fix for this particular test. And notice that now the CPU did only 46 / 15 = 3.1 cycles/instruction. Signed-off-by: Kjetil Barvik <barvik@broadpark.no> Acked-by: Linus Torvalds <torvalds@linux-foundation.org> Signed-off-by: Junio C Hamano <gitster@pobox.com>
2009-02-18 23:18:03 +01:00
istate->cache_nr = j;
}
int remove_file_from_index(struct index_state *istate, const char *path)
{
int pos = index_name_pos(istate, path, strlen(path));
if (pos < 0)
pos = -pos-1;
cache_tree_invalidate_path(istate, path);
untracked_cache_remove_from_index(istate, path);
while (pos < istate->cache_nr && !strcmp(istate->cache[pos]->name, path))
remove_index_entry_at(istate, pos);
return 0;
}
static int compare_name(struct cache_entry *ce, const char *path, int namelen)
{
return namelen != ce_namelen(ce) || memcmp(path, ce->name, namelen);
}
static int index_name_pos_also_unmerged(struct index_state *istate,
const char *path, int namelen)
{
int pos = index_name_pos(istate, path, namelen);
struct cache_entry *ce;
if (pos >= 0)
return pos;
/* maybe unmerged? */
pos = -1 - pos;
if (pos >= istate->cache_nr ||
compare_name((ce = istate->cache[pos]), path, namelen))
return -1;
/* order of preference: stage 2, 1, 3 */
if (ce_stage(ce) == 1 && pos + 1 < istate->cache_nr &&
ce_stage((ce = istate->cache[pos + 1])) == 2 &&
!compare_name(ce, path, namelen))
pos++;
return pos;
}
static int different_name(struct cache_entry *ce, struct cache_entry *alias)
{
int len = ce_namelen(ce);
return ce_namelen(alias) != len || memcmp(ce->name, alias->name, len);
}
/*
* If we add a filename that aliases in the cache, we will use the
* name that we already have - but we don't want to update the same
* alias twice, because that implies that there were actually two
* different files with aliasing names!
*
* So we use the CE_ADDED flag to verify that the alias was an old
* one before we accept it as
*/
static struct cache_entry *create_alias_ce(struct index_state *istate,
struct cache_entry *ce,
struct cache_entry *alias)
{
int len;
struct cache_entry *new_entry;
if (alias->ce_flags & CE_ADDED)
die(_("will not add file alias '%s' ('%s' already exists in index)"),
ce->name, alias->name);
/* Ok, create the new entry using the name of the existing alias */
len = ce_namelen(alias);
block alloc: add lifecycle APIs for cache_entry structs It has been observed that the time spent loading an index with a large number of entries is partly dominated by malloc() calls. This change is in preparation for using memory pools to reduce the number of malloc() calls made to allocate cahce entries when loading an index. Add an API to allocate and discard cache entries, abstracting the details of managing the memory backing the cache entries. This commit does actually change how memory is managed - this will be done in a later commit in the series. This change makes the distinction between cache entries that are associated with an index and cache entries that are not associated with an index. A main use of cache entries is with an index, and we can optimize the memory management around this. We still have other cases where a cache entry is not persisted with an index, and so we need to handle the "transient" use case as well. To keep the congnitive overhead of managing the cache entries, there will only be a single discard function. This means there must be enough information kept with the cache entry so that we know how to discard them. A summary of the main functions in the API is: make_cache_entry: create cache entry for use in an index. Uses specified parameters to populate cache_entry fields. make_empty_cache_entry: Create an empty cache entry for use in an index. Returns cache entry with empty fields. make_transient_cache_entry: create cache entry that is not used in an index. Uses specified parameters to populate cache_entry fields. make_empty_transient_cache_entry: create cache entry that is not used in an index. Returns cache entry with empty fields. discard_cache_entry: A single function that knows how to discard a cache entry regardless of how it was allocated. Signed-off-by: Jameson Miller <jamill@microsoft.com> Signed-off-by: Junio C Hamano <gitster@pobox.com>
2018-07-02 21:49:31 +02:00
new_entry = make_empty_cache_entry(istate, len);
memcpy(new_entry->name, alias->name, len);
copy_cache_entry(new_entry, ce);
save_or_free_index_entry(istate, ce);
return new_entry;
}
void set_object_name_for_intent_to_add_entry(struct cache_entry *ce)
{
struct object_id oid;
if (write_object_file("", 0, blob_type, &oid))
die(_("cannot create an empty blob in the object database"));
oidcpy(&ce->oid, &oid);
}
int add_to_index(struct index_state *istate, const char *path, struct stat *st, int flags)
{
block alloc: add lifecycle APIs for cache_entry structs It has been observed that the time spent loading an index with a large number of entries is partly dominated by malloc() calls. This change is in preparation for using memory pools to reduce the number of malloc() calls made to allocate cahce entries when loading an index. Add an API to allocate and discard cache entries, abstracting the details of managing the memory backing the cache entries. This commit does actually change how memory is managed - this will be done in a later commit in the series. This change makes the distinction between cache entries that are associated with an index and cache entries that are not associated with an index. A main use of cache entries is with an index, and we can optimize the memory management around this. We still have other cases where a cache entry is not persisted with an index, and so we need to handle the "transient" use case as well. To keep the congnitive overhead of managing the cache entries, there will only be a single discard function. This means there must be enough information kept with the cache entry so that we know how to discard them. A summary of the main functions in the API is: make_cache_entry: create cache entry for use in an index. Uses specified parameters to populate cache_entry fields. make_empty_cache_entry: Create an empty cache entry for use in an index. Returns cache entry with empty fields. make_transient_cache_entry: create cache entry that is not used in an index. Uses specified parameters to populate cache_entry fields. make_empty_transient_cache_entry: create cache entry that is not used in an index. Returns cache entry with empty fields. discard_cache_entry: A single function that knows how to discard a cache entry regardless of how it was allocated. Signed-off-by: Jameson Miller <jamill@microsoft.com> Signed-off-by: Junio C Hamano <gitster@pobox.com>
2018-07-02 21:49:31 +02:00
int namelen, was_same;
mode_t st_mode = st->st_mode;
struct cache_entry *ce, *alias = NULL;
unsigned ce_option = CE_MATCH_IGNORE_VALID|CE_MATCH_IGNORE_SKIP_WORKTREE|CE_MATCH_RACY_IS_DIRTY;
int verbose = flags & (ADD_CACHE_VERBOSE | ADD_CACHE_PRETEND);
int pretend = flags & ADD_CACHE_PRETEND;
int intent_only = flags & ADD_CACHE_INTENT;
int add_option = (ADD_CACHE_OK_TO_ADD|ADD_CACHE_OK_TO_REPLACE|
(intent_only ? ADD_CACHE_NEW_ONLY : 0));
unsigned hash_flags = pretend ? 0 : HASH_WRITE_OBJECT;
struct object_id oid;
if (flags & ADD_CACHE_RENORMALIZE)
hash_flags |= HASH_RENORMALIZE;
if (!S_ISREG(st_mode) && !S_ISLNK(st_mode) && !S_ISDIR(st_mode))
return error(_("%s: can only add regular files, symbolic links or git-directories"), path);
namelen = strlen(path);
if (S_ISDIR(st_mode)) {
if (resolve_gitlink_ref(path, "HEAD", &oid) < 0)
return error(_("'%s' does not have a commit checked out"), path);
while (namelen && path[namelen-1] == '/')
namelen--;
}
block alloc: add lifecycle APIs for cache_entry structs It has been observed that the time spent loading an index with a large number of entries is partly dominated by malloc() calls. This change is in preparation for using memory pools to reduce the number of malloc() calls made to allocate cahce entries when loading an index. Add an API to allocate and discard cache entries, abstracting the details of managing the memory backing the cache entries. This commit does actually change how memory is managed - this will be done in a later commit in the series. This change makes the distinction between cache entries that are associated with an index and cache entries that are not associated with an index. A main use of cache entries is with an index, and we can optimize the memory management around this. We still have other cases where a cache entry is not persisted with an index, and so we need to handle the "transient" use case as well. To keep the congnitive overhead of managing the cache entries, there will only be a single discard function. This means there must be enough information kept with the cache entry so that we know how to discard them. A summary of the main functions in the API is: make_cache_entry: create cache entry for use in an index. Uses specified parameters to populate cache_entry fields. make_empty_cache_entry: Create an empty cache entry for use in an index. Returns cache entry with empty fields. make_transient_cache_entry: create cache entry that is not used in an index. Uses specified parameters to populate cache_entry fields. make_empty_transient_cache_entry: create cache entry that is not used in an index. Returns cache entry with empty fields. discard_cache_entry: A single function that knows how to discard a cache entry regardless of how it was allocated. Signed-off-by: Jameson Miller <jamill@microsoft.com> Signed-off-by: Junio C Hamano <gitster@pobox.com>
2018-07-02 21:49:31 +02:00
ce = make_empty_cache_entry(istate, namelen);
memcpy(ce->name, path, namelen);
ce->ce_namelen = namelen;
if (!intent_only)
fill_stat_cache_info(istate, ce, st);
else
ce->ce_flags |= CE_INTENT_TO_ADD;
if (trust_executable_bit && has_symlinks) {
ce->ce_mode = create_ce_mode(st_mode);
} else {
/* If there is an existing entry, pick the mode bits and type
* from it, otherwise assume unexecutable regular file.
*/
struct cache_entry *ent;
int pos = index_name_pos_also_unmerged(istate, path, namelen);
ent = (0 <= pos) ? istate->cache[pos] : NULL;
ce->ce_mode = ce_mode_from_stat(ent, st_mode);
}
/* When core.ignorecase=true, determine if a directory of the same name but differing
* case already exists within the Git repository. If it does, ensure the directory
* case of the file being added to the repository matches (is folded into) the existing
* entry's directory case.
*/
if (ignore_case) {
adjust_dirname_case(istate, ce->name);
}
if (!(flags & ADD_CACHE_RENORMALIZE)) {
alias = index_file_exists(istate, ce->name,
ce_namelen(ce), ignore_case);
if (alias &&
!ce_stage(alias) &&
!ie_match_stat(istate, alias, st, ce_option)) {
/* Nothing changed, really */
if (!S_ISGITLINK(alias->ce_mode))
ce_mark_uptodate(alias);
alias->ce_flags |= CE_ADDED;
block alloc: add lifecycle APIs for cache_entry structs It has been observed that the time spent loading an index with a large number of entries is partly dominated by malloc() calls. This change is in preparation for using memory pools to reduce the number of malloc() calls made to allocate cahce entries when loading an index. Add an API to allocate and discard cache entries, abstracting the details of managing the memory backing the cache entries. This commit does actually change how memory is managed - this will be done in a later commit in the series. This change makes the distinction between cache entries that are associated with an index and cache entries that are not associated with an index. A main use of cache entries is with an index, and we can optimize the memory management around this. We still have other cases where a cache entry is not persisted with an index, and so we need to handle the "transient" use case as well. To keep the congnitive overhead of managing the cache entries, there will only be a single discard function. This means there must be enough information kept with the cache entry so that we know how to discard them. A summary of the main functions in the API is: make_cache_entry: create cache entry for use in an index. Uses specified parameters to populate cache_entry fields. make_empty_cache_entry: Create an empty cache entry for use in an index. Returns cache entry with empty fields. make_transient_cache_entry: create cache entry that is not used in an index. Uses specified parameters to populate cache_entry fields. make_empty_transient_cache_entry: create cache entry that is not used in an index. Returns cache entry with empty fields. discard_cache_entry: A single function that knows how to discard a cache entry regardless of how it was allocated. Signed-off-by: Jameson Miller <jamill@microsoft.com> Signed-off-by: Junio C Hamano <gitster@pobox.com>
2018-07-02 21:49:31 +02:00
discard_cache_entry(ce);
return 0;
}
}
if (!intent_only) {
if (index_path(istate, &ce->oid, path, st, hash_flags)) {
block alloc: add lifecycle APIs for cache_entry structs It has been observed that the time spent loading an index with a large number of entries is partly dominated by malloc() calls. This change is in preparation for using memory pools to reduce the number of malloc() calls made to allocate cahce entries when loading an index. Add an API to allocate and discard cache entries, abstracting the details of managing the memory backing the cache entries. This commit does actually change how memory is managed - this will be done in a later commit in the series. This change makes the distinction between cache entries that are associated with an index and cache entries that are not associated with an index. A main use of cache entries is with an index, and we can optimize the memory management around this. We still have other cases where a cache entry is not persisted with an index, and so we need to handle the "transient" use case as well. To keep the congnitive overhead of managing the cache entries, there will only be a single discard function. This means there must be enough information kept with the cache entry so that we know how to discard them. A summary of the main functions in the API is: make_cache_entry: create cache entry for use in an index. Uses specified parameters to populate cache_entry fields. make_empty_cache_entry: Create an empty cache entry for use in an index. Returns cache entry with empty fields. make_transient_cache_entry: create cache entry that is not used in an index. Uses specified parameters to populate cache_entry fields. make_empty_transient_cache_entry: create cache entry that is not used in an index. Returns cache entry with empty fields. discard_cache_entry: A single function that knows how to discard a cache entry regardless of how it was allocated. Signed-off-by: Jameson Miller <jamill@microsoft.com> Signed-off-by: Junio C Hamano <gitster@pobox.com>
2018-07-02 21:49:31 +02:00
discard_cache_entry(ce);
return error(_("unable to index file '%s'"), path);
}
} else
set_object_name_for_intent_to_add_entry(ce);
if (ignore_case && alias && different_name(ce, alias))
ce = create_alias_ce(istate, ce, alias);
ce->ce_flags |= CE_ADDED;
/* It was suspected to be racily clean, but it turns out to be Ok */
was_same = (alias &&
!ce_stage(alias) &&
oideq(&alias->oid, &ce->oid) &&
ce->ce_mode == alias->ce_mode);
if (pretend)
block alloc: add lifecycle APIs for cache_entry structs It has been observed that the time spent loading an index with a large number of entries is partly dominated by malloc() calls. This change is in preparation for using memory pools to reduce the number of malloc() calls made to allocate cahce entries when loading an index. Add an API to allocate and discard cache entries, abstracting the details of managing the memory backing the cache entries. This commit does actually change how memory is managed - this will be done in a later commit in the series. This change makes the distinction between cache entries that are associated with an index and cache entries that are not associated with an index. A main use of cache entries is with an index, and we can optimize the memory management around this. We still have other cases where a cache entry is not persisted with an index, and so we need to handle the "transient" use case as well. To keep the congnitive overhead of managing the cache entries, there will only be a single discard function. This means there must be enough information kept with the cache entry so that we know how to discard them. A summary of the main functions in the API is: make_cache_entry: create cache entry for use in an index. Uses specified parameters to populate cache_entry fields. make_empty_cache_entry: Create an empty cache entry for use in an index. Returns cache entry with empty fields. make_transient_cache_entry: create cache entry that is not used in an index. Uses specified parameters to populate cache_entry fields. make_empty_transient_cache_entry: create cache entry that is not used in an index. Returns cache entry with empty fields. discard_cache_entry: A single function that knows how to discard a cache entry regardless of how it was allocated. Signed-off-by: Jameson Miller <jamill@microsoft.com> Signed-off-by: Junio C Hamano <gitster@pobox.com>
2018-07-02 21:49:31 +02:00
discard_cache_entry(ce);
else if (add_index_entry(istate, ce, add_option)) {
block alloc: add lifecycle APIs for cache_entry structs It has been observed that the time spent loading an index with a large number of entries is partly dominated by malloc() calls. This change is in preparation for using memory pools to reduce the number of malloc() calls made to allocate cahce entries when loading an index. Add an API to allocate and discard cache entries, abstracting the details of managing the memory backing the cache entries. This commit does actually change how memory is managed - this will be done in a later commit in the series. This change makes the distinction between cache entries that are associated with an index and cache entries that are not associated with an index. A main use of cache entries is with an index, and we can optimize the memory management around this. We still have other cases where a cache entry is not persisted with an index, and so we need to handle the "transient" use case as well. To keep the congnitive overhead of managing the cache entries, there will only be a single discard function. This means there must be enough information kept with the cache entry so that we know how to discard them. A summary of the main functions in the API is: make_cache_entry: create cache entry for use in an index. Uses specified parameters to populate cache_entry fields. make_empty_cache_entry: Create an empty cache entry for use in an index. Returns cache entry with empty fields. make_transient_cache_entry: create cache entry that is not used in an index. Uses specified parameters to populate cache_entry fields. make_empty_transient_cache_entry: create cache entry that is not used in an index. Returns cache entry with empty fields. discard_cache_entry: A single function that knows how to discard a cache entry regardless of how it was allocated. Signed-off-by: Jameson Miller <jamill@microsoft.com> Signed-off-by: Junio C Hamano <gitster@pobox.com>
2018-07-02 21:49:31 +02:00
discard_cache_entry(ce);
return error(_("unable to add '%s' to index"), path);
}
if (verbose && !was_same)
printf("add '%s'\n", path);
return 0;
}
int add_file_to_index(struct index_state *istate, const char *path, int flags)
{
struct stat st;
if (lstat(path, &st))
die_errno(_("unable to stat '%s'"), path);
return add_to_index(istate, path, &st, flags);
}
block alloc: add lifecycle APIs for cache_entry structs It has been observed that the time spent loading an index with a large number of entries is partly dominated by malloc() calls. This change is in preparation for using memory pools to reduce the number of malloc() calls made to allocate cahce entries when loading an index. Add an API to allocate and discard cache entries, abstracting the details of managing the memory backing the cache entries. This commit does actually change how memory is managed - this will be done in a later commit in the series. This change makes the distinction between cache entries that are associated with an index and cache entries that are not associated with an index. A main use of cache entries is with an index, and we can optimize the memory management around this. We still have other cases where a cache entry is not persisted with an index, and so we need to handle the "transient" use case as well. To keep the congnitive overhead of managing the cache entries, there will only be a single discard function. This means there must be enough information kept with the cache entry so that we know how to discard them. A summary of the main functions in the API is: make_cache_entry: create cache entry for use in an index. Uses specified parameters to populate cache_entry fields. make_empty_cache_entry: Create an empty cache entry for use in an index. Returns cache entry with empty fields. make_transient_cache_entry: create cache entry that is not used in an index. Uses specified parameters to populate cache_entry fields. make_empty_transient_cache_entry: create cache entry that is not used in an index. Returns cache entry with empty fields. discard_cache_entry: A single function that knows how to discard a cache entry regardless of how it was allocated. Signed-off-by: Jameson Miller <jamill@microsoft.com> Signed-off-by: Junio C Hamano <gitster@pobox.com>
2018-07-02 21:49:31 +02:00
struct cache_entry *make_empty_cache_entry(struct index_state *istate, size_t len)
{
block alloc: allocate cache entries from mem_pool When reading large indexes from disk, a portion of the time is dominated in malloc() calls. This can be mitigated by allocating a large block of memory and manage it ourselves via memory pools. This change moves the cache entry allocation to be on top of memory pools. Design: The index_state struct will gain a notion of an associated memory_pool from which cache_entries will be allocated from. When reading in the index from disk, we have information on the number of entries and their size, which can guide us in deciding how large our initial memory allocation should be. When an index is discarded, the associated memory_pool will be discarded as well - so the lifetime of a cache_entry is tied to the lifetime of the index_state that it was allocated for. In the case of a Split Index, the following rules are followed. 1st, some terminology is defined: Terminology: - 'the_index': represents the logical view of the index - 'split_index': represents the "base" cache entries. Read from the split index file. 'the_index' can reference a single split_index, as well as cache_entries from the split_index. `the_index` will be discarded before the `split_index` is. This means that when we are allocating cache_entries in the presence of a split index, we need to allocate the entries from the `split_index`'s memory pool. This allows us to follow the pattern that `the_index` can reference cache_entries from the `split_index`, and that the cache_entries will not be freed while they are still being referenced. Managing transient cache_entry structs: Cache entries are usually allocated for an index, but this is not always the case. Cache entries are sometimes allocated because this is the type that the existing checkout_entry function works with. Because of this, the existing code needs to handle cache entries associated with an index / memory pool, and those that only exist transiently. Several strategies were contemplated around how to handle this: Chosen approach: An extra field was added to the cache_entry type to track whether the cache_entry was allocated from a memory pool or not. This is currently an int field, as there are no more available bits in the existing ce_flags bit field. If / when more bits are needed, this new field can be turned into a proper bit field. Alternatives: 1) Do not include any information about how the cache_entry was allocated. Calling code would be responsible for tracking whether the cache_entry needed to be freed or not. Pro: No extra memory overhead to track this state Con: Extra complexity in callers to handle this correctly. The extra complexity and burden to not regress this behavior in the future was more than we wanted. 2) cache_entry would gain knowledge about which mem_pool allocated it Pro: Could (potentially) do extra logic to know when a mem_pool no longer had references to any cache_entry Con: cache_entry would grow heavier by a pointer, instead of int We didn't see a tangible benefit to this approach 3) Do not add any extra information to a cache_entry, but when freeing a cache entry, check if the memory exists in a region managed by existing mem_pools. Pro: No extra memory overhead to track state Con: Extra computation is performed when freeing cache entries We decided tracking and iterating over known memory pool regions was less desirable than adding an extra field to track this stae. Signed-off-by: Jameson Miller <jamill@microsoft.com> Signed-off-by: Junio C Hamano <gitster@pobox.com>
2018-07-02 21:49:37 +02:00
return mem_pool__ce_calloc(find_mem_pool(istate), len);
block alloc: add lifecycle APIs for cache_entry structs It has been observed that the time spent loading an index with a large number of entries is partly dominated by malloc() calls. This change is in preparation for using memory pools to reduce the number of malloc() calls made to allocate cahce entries when loading an index. Add an API to allocate and discard cache entries, abstracting the details of managing the memory backing the cache entries. This commit does actually change how memory is managed - this will be done in a later commit in the series. This change makes the distinction between cache entries that are associated with an index and cache entries that are not associated with an index. A main use of cache entries is with an index, and we can optimize the memory management around this. We still have other cases where a cache entry is not persisted with an index, and so we need to handle the "transient" use case as well. To keep the congnitive overhead of managing the cache entries, there will only be a single discard function. This means there must be enough information kept with the cache entry so that we know how to discard them. A summary of the main functions in the API is: make_cache_entry: create cache entry for use in an index. Uses specified parameters to populate cache_entry fields. make_empty_cache_entry: Create an empty cache entry for use in an index. Returns cache entry with empty fields. make_transient_cache_entry: create cache entry that is not used in an index. Uses specified parameters to populate cache_entry fields. make_empty_transient_cache_entry: create cache entry that is not used in an index. Returns cache entry with empty fields. discard_cache_entry: A single function that knows how to discard a cache entry regardless of how it was allocated. Signed-off-by: Jameson Miller <jamill@microsoft.com> Signed-off-by: Junio C Hamano <gitster@pobox.com>
2018-07-02 21:49:31 +02:00
}
struct cache_entry *make_empty_transient_cache_entry(size_t len,
struct mem_pool *ce_mem_pool)
block alloc: add lifecycle APIs for cache_entry structs It has been observed that the time spent loading an index with a large number of entries is partly dominated by malloc() calls. This change is in preparation for using memory pools to reduce the number of malloc() calls made to allocate cahce entries when loading an index. Add an API to allocate and discard cache entries, abstracting the details of managing the memory backing the cache entries. This commit does actually change how memory is managed - this will be done in a later commit in the series. This change makes the distinction between cache entries that are associated with an index and cache entries that are not associated with an index. A main use of cache entries is with an index, and we can optimize the memory management around this. We still have other cases where a cache entry is not persisted with an index, and so we need to handle the "transient" use case as well. To keep the congnitive overhead of managing the cache entries, there will only be a single discard function. This means there must be enough information kept with the cache entry so that we know how to discard them. A summary of the main functions in the API is: make_cache_entry: create cache entry for use in an index. Uses specified parameters to populate cache_entry fields. make_empty_cache_entry: Create an empty cache entry for use in an index. Returns cache entry with empty fields. make_transient_cache_entry: create cache entry that is not used in an index. Uses specified parameters to populate cache_entry fields. make_empty_transient_cache_entry: create cache entry that is not used in an index. Returns cache entry with empty fields. discard_cache_entry: A single function that knows how to discard a cache entry regardless of how it was allocated. Signed-off-by: Jameson Miller <jamill@microsoft.com> Signed-off-by: Junio C Hamano <gitster@pobox.com>
2018-07-02 21:49:31 +02:00
{
if (ce_mem_pool)
return mem_pool__ce_calloc(ce_mem_pool, len);
block alloc: add lifecycle APIs for cache_entry structs It has been observed that the time spent loading an index with a large number of entries is partly dominated by malloc() calls. This change is in preparation for using memory pools to reduce the number of malloc() calls made to allocate cahce entries when loading an index. Add an API to allocate and discard cache entries, abstracting the details of managing the memory backing the cache entries. This commit does actually change how memory is managed - this will be done in a later commit in the series. This change makes the distinction between cache entries that are associated with an index and cache entries that are not associated with an index. A main use of cache entries is with an index, and we can optimize the memory management around this. We still have other cases where a cache entry is not persisted with an index, and so we need to handle the "transient" use case as well. To keep the congnitive overhead of managing the cache entries, there will only be a single discard function. This means there must be enough information kept with the cache entry so that we know how to discard them. A summary of the main functions in the API is: make_cache_entry: create cache entry for use in an index. Uses specified parameters to populate cache_entry fields. make_empty_cache_entry: Create an empty cache entry for use in an index. Returns cache entry with empty fields. make_transient_cache_entry: create cache entry that is not used in an index. Uses specified parameters to populate cache_entry fields. make_empty_transient_cache_entry: create cache entry that is not used in an index. Returns cache entry with empty fields. discard_cache_entry: A single function that knows how to discard a cache entry regardless of how it was allocated. Signed-off-by: Jameson Miller <jamill@microsoft.com> Signed-off-by: Junio C Hamano <gitster@pobox.com>
2018-07-02 21:49:31 +02:00
return xcalloc(1, cache_entry_size(len));
}
enum verify_path_result {
PATH_OK,
PATH_INVALID,
PATH_DIR_WITH_SEP,
};
static enum verify_path_result verify_path_internal(const char *, unsigned);
int verify_path(const char *path, unsigned mode)
{
return verify_path_internal(path, mode) == PATH_OK;
}
block alloc: add lifecycle APIs for cache_entry structs It has been observed that the time spent loading an index with a large number of entries is partly dominated by malloc() calls. This change is in preparation for using memory pools to reduce the number of malloc() calls made to allocate cahce entries when loading an index. Add an API to allocate and discard cache entries, abstracting the details of managing the memory backing the cache entries. This commit does actually change how memory is managed - this will be done in a later commit in the series. This change makes the distinction between cache entries that are associated with an index and cache entries that are not associated with an index. A main use of cache entries is with an index, and we can optimize the memory management around this. We still have other cases where a cache entry is not persisted with an index, and so we need to handle the "transient" use case as well. To keep the congnitive overhead of managing the cache entries, there will only be a single discard function. This means there must be enough information kept with the cache entry so that we know how to discard them. A summary of the main functions in the API is: make_cache_entry: create cache entry for use in an index. Uses specified parameters to populate cache_entry fields. make_empty_cache_entry: Create an empty cache entry for use in an index. Returns cache entry with empty fields. make_transient_cache_entry: create cache entry that is not used in an index. Uses specified parameters to populate cache_entry fields. make_empty_transient_cache_entry: create cache entry that is not used in an index. Returns cache entry with empty fields. discard_cache_entry: A single function that knows how to discard a cache entry regardless of how it was allocated. Signed-off-by: Jameson Miller <jamill@microsoft.com> Signed-off-by: Junio C Hamano <gitster@pobox.com>
2018-07-02 21:49:31 +02:00
struct cache_entry *make_cache_entry(struct index_state *istate,
unsigned int mode,
const struct object_id *oid,
const char *path,
int stage,
unsigned int refresh_options)
{
struct cache_entry *ce, *ret;
block alloc: add lifecycle APIs for cache_entry structs It has been observed that the time spent loading an index with a large number of entries is partly dominated by malloc() calls. This change is in preparation for using memory pools to reduce the number of malloc() calls made to allocate cahce entries when loading an index. Add an API to allocate and discard cache entries, abstracting the details of managing the memory backing the cache entries. This commit does actually change how memory is managed - this will be done in a later commit in the series. This change makes the distinction between cache entries that are associated with an index and cache entries that are not associated with an index. A main use of cache entries is with an index, and we can optimize the memory management around this. We still have other cases where a cache entry is not persisted with an index, and so we need to handle the "transient" use case as well. To keep the congnitive overhead of managing the cache entries, there will only be a single discard function. This means there must be enough information kept with the cache entry so that we know how to discard them. A summary of the main functions in the API is: make_cache_entry: create cache entry for use in an index. Uses specified parameters to populate cache_entry fields. make_empty_cache_entry: Create an empty cache entry for use in an index. Returns cache entry with empty fields. make_transient_cache_entry: create cache entry that is not used in an index. Uses specified parameters to populate cache_entry fields. make_empty_transient_cache_entry: create cache entry that is not used in an index. Returns cache entry with empty fields. discard_cache_entry: A single function that knows how to discard a cache entry regardless of how it was allocated. Signed-off-by: Jameson Miller <jamill@microsoft.com> Signed-off-by: Junio C Hamano <gitster@pobox.com>
2018-07-02 21:49:31 +02:00
int len;
if (verify_path_internal(path, mode) == PATH_INVALID) {
error(_("invalid path '%s'"), path);
return NULL;
}
len = strlen(path);
block alloc: add lifecycle APIs for cache_entry structs It has been observed that the time spent loading an index with a large number of entries is partly dominated by malloc() calls. This change is in preparation for using memory pools to reduce the number of malloc() calls made to allocate cahce entries when loading an index. Add an API to allocate and discard cache entries, abstracting the details of managing the memory backing the cache entries. This commit does actually change how memory is managed - this will be done in a later commit in the series. This change makes the distinction between cache entries that are associated with an index and cache entries that are not associated with an index. A main use of cache entries is with an index, and we can optimize the memory management around this. We still have other cases where a cache entry is not persisted with an index, and so we need to handle the "transient" use case as well. To keep the congnitive overhead of managing the cache entries, there will only be a single discard function. This means there must be enough information kept with the cache entry so that we know how to discard them. A summary of the main functions in the API is: make_cache_entry: create cache entry for use in an index. Uses specified parameters to populate cache_entry fields. make_empty_cache_entry: Create an empty cache entry for use in an index. Returns cache entry with empty fields. make_transient_cache_entry: create cache entry that is not used in an index. Uses specified parameters to populate cache_entry fields. make_empty_transient_cache_entry: create cache entry that is not used in an index. Returns cache entry with empty fields. discard_cache_entry: A single function that knows how to discard a cache entry regardless of how it was allocated. Signed-off-by: Jameson Miller <jamill@microsoft.com> Signed-off-by: Junio C Hamano <gitster@pobox.com>
2018-07-02 21:49:31 +02:00
ce = make_empty_cache_entry(istate, len);
oidcpy(&ce->oid, oid);
memcpy(ce->name, path, len);
ce->ce_flags = create_ce_flags(stage);
ce->ce_namelen = len;
ce->ce_mode = create_ce_mode(mode);
ret = refresh_cache_entry(istate, ce, refresh_options);
if (ret != ce)
block alloc: add lifecycle APIs for cache_entry structs It has been observed that the time spent loading an index with a large number of entries is partly dominated by malloc() calls. This change is in preparation for using memory pools to reduce the number of malloc() calls made to allocate cahce entries when loading an index. Add an API to allocate and discard cache entries, abstracting the details of managing the memory backing the cache entries. This commit does actually change how memory is managed - this will be done in a later commit in the series. This change makes the distinction between cache entries that are associated with an index and cache entries that are not associated with an index. A main use of cache entries is with an index, and we can optimize the memory management around this. We still have other cases where a cache entry is not persisted with an index, and so we need to handle the "transient" use case as well. To keep the congnitive overhead of managing the cache entries, there will only be a single discard function. This means there must be enough information kept with the cache entry so that we know how to discard them. A summary of the main functions in the API is: make_cache_entry: create cache entry for use in an index. Uses specified parameters to populate cache_entry fields. make_empty_cache_entry: Create an empty cache entry for use in an index. Returns cache entry with empty fields. make_transient_cache_entry: create cache entry that is not used in an index. Uses specified parameters to populate cache_entry fields. make_empty_transient_cache_entry: create cache entry that is not used in an index. Returns cache entry with empty fields. discard_cache_entry: A single function that knows how to discard a cache entry regardless of how it was allocated. Signed-off-by: Jameson Miller <jamill@microsoft.com> Signed-off-by: Junio C Hamano <gitster@pobox.com>
2018-07-02 21:49:31 +02:00
discard_cache_entry(ce);
return ret;
}
struct cache_entry *make_transient_cache_entry(unsigned int mode,
const struct object_id *oid,
const char *path,
int stage,
struct mem_pool *ce_mem_pool)
block alloc: add lifecycle APIs for cache_entry structs It has been observed that the time spent loading an index with a large number of entries is partly dominated by malloc() calls. This change is in preparation for using memory pools to reduce the number of malloc() calls made to allocate cahce entries when loading an index. Add an API to allocate and discard cache entries, abstracting the details of managing the memory backing the cache entries. This commit does actually change how memory is managed - this will be done in a later commit in the series. This change makes the distinction between cache entries that are associated with an index and cache entries that are not associated with an index. A main use of cache entries is with an index, and we can optimize the memory management around this. We still have other cases where a cache entry is not persisted with an index, and so we need to handle the "transient" use case as well. To keep the congnitive overhead of managing the cache entries, there will only be a single discard function. This means there must be enough information kept with the cache entry so that we know how to discard them. A summary of the main functions in the API is: make_cache_entry: create cache entry for use in an index. Uses specified parameters to populate cache_entry fields. make_empty_cache_entry: Create an empty cache entry for use in an index. Returns cache entry with empty fields. make_transient_cache_entry: create cache entry that is not used in an index. Uses specified parameters to populate cache_entry fields. make_empty_transient_cache_entry: create cache entry that is not used in an index. Returns cache entry with empty fields. discard_cache_entry: A single function that knows how to discard a cache entry regardless of how it was allocated. Signed-off-by: Jameson Miller <jamill@microsoft.com> Signed-off-by: Junio C Hamano <gitster@pobox.com>
2018-07-02 21:49:31 +02:00
{
struct cache_entry *ce;
int len;
if (!verify_path(path, mode)) {
error(_("invalid path '%s'"), path);
block alloc: add lifecycle APIs for cache_entry structs It has been observed that the time spent loading an index with a large number of entries is partly dominated by malloc() calls. This change is in preparation for using memory pools to reduce the number of malloc() calls made to allocate cahce entries when loading an index. Add an API to allocate and discard cache entries, abstracting the details of managing the memory backing the cache entries. This commit does actually change how memory is managed - this will be done in a later commit in the series. This change makes the distinction between cache entries that are associated with an index and cache entries that are not associated with an index. A main use of cache entries is with an index, and we can optimize the memory management around this. We still have other cases where a cache entry is not persisted with an index, and so we need to handle the "transient" use case as well. To keep the congnitive overhead of managing the cache entries, there will only be a single discard function. This means there must be enough information kept with the cache entry so that we know how to discard them. A summary of the main functions in the API is: make_cache_entry: create cache entry for use in an index. Uses specified parameters to populate cache_entry fields. make_empty_cache_entry: Create an empty cache entry for use in an index. Returns cache entry with empty fields. make_transient_cache_entry: create cache entry that is not used in an index. Uses specified parameters to populate cache_entry fields. make_empty_transient_cache_entry: create cache entry that is not used in an index. Returns cache entry with empty fields. discard_cache_entry: A single function that knows how to discard a cache entry regardless of how it was allocated. Signed-off-by: Jameson Miller <jamill@microsoft.com> Signed-off-by: Junio C Hamano <gitster@pobox.com>
2018-07-02 21:49:31 +02:00
return NULL;
}
len = strlen(path);
ce = make_empty_transient_cache_entry(len, ce_mem_pool);
block alloc: add lifecycle APIs for cache_entry structs It has been observed that the time spent loading an index with a large number of entries is partly dominated by malloc() calls. This change is in preparation for using memory pools to reduce the number of malloc() calls made to allocate cahce entries when loading an index. Add an API to allocate and discard cache entries, abstracting the details of managing the memory backing the cache entries. This commit does actually change how memory is managed - this will be done in a later commit in the series. This change makes the distinction between cache entries that are associated with an index and cache entries that are not associated with an index. A main use of cache entries is with an index, and we can optimize the memory management around this. We still have other cases where a cache entry is not persisted with an index, and so we need to handle the "transient" use case as well. To keep the congnitive overhead of managing the cache entries, there will only be a single discard function. This means there must be enough information kept with the cache entry so that we know how to discard them. A summary of the main functions in the API is: make_cache_entry: create cache entry for use in an index. Uses specified parameters to populate cache_entry fields. make_empty_cache_entry: Create an empty cache entry for use in an index. Returns cache entry with empty fields. make_transient_cache_entry: create cache entry that is not used in an index. Uses specified parameters to populate cache_entry fields. make_empty_transient_cache_entry: create cache entry that is not used in an index. Returns cache entry with empty fields. discard_cache_entry: A single function that knows how to discard a cache entry regardless of how it was allocated. Signed-off-by: Jameson Miller <jamill@microsoft.com> Signed-off-by: Junio C Hamano <gitster@pobox.com>
2018-07-02 21:49:31 +02:00
oidcpy(&ce->oid, oid);
memcpy(ce->name, path, len);
ce->ce_flags = create_ce_flags(stage);
ce->ce_namelen = len;
ce->ce_mode = create_ce_mode(mode);
return ce;
}
/*
* Chmod an index entry with either +x or -x.
*
* Returns -1 if the chmod for the particular cache entry failed (if it's
* not a regular file), -2 if an invalid flip argument is passed in, 0
* otherwise.
*/
int chmod_index_entry(struct index_state *istate, struct cache_entry *ce,
char flip)
{
if (!S_ISREG(ce->ce_mode))
return -1;
switch (flip) {
case '+':
ce->ce_mode |= 0111;
break;
case '-':
ce->ce_mode &= ~0111;
break;
default:
return -2;
}
cache_tree_invalidate_path(istate, ce->name);
ce->ce_flags |= CE_UPDATE_IN_BASE;
mark_fsmonitor_invalid(istate, ce);
istate->cache_changed |= CE_ENTRY_CHANGED;
return 0;
}
Convert "struct cache_entry *" to "const ..." wherever possible I attempted to make index_state->cache[] a "const struct cache_entry **" to find out how existing entries in index are modified and where. The question I have is what do we do if we really need to keep track of on-disk changes in the index. The result is - diff-lib.c: setting CE_UPTODATE - name-hash.c: setting CE_HASHED - preload-index.c, read-cache.c, unpack-trees.c and builtin/update-index: obvious - entry.c: write_entry() may refresh the checked out entry via fill_stat_cache_info(). This causes "non-const struct cache_entry *" in builtin/apply.c, builtin/checkout-index.c and builtin/checkout.c - builtin/ls-files.c: --with-tree changes stagemask and may set CE_UPDATE Of these, write_entry() and its call sites are probably most interesting because it modifies on-disk info. But this is stat info and can be retrieved via refresh, at least for porcelain commands. Other just uses ce_flags for local purposes. So, keeping track of "dirty" entries is just a matter of setting a flag in index modification functions exposed by read-cache.c. Except unpack-trees, the rest of the code base does not do anything funny behind read-cache's back. The actual patch is less valueable than the summary above. But if anyone wants to re-identify the above sites. Applying this patch, then this: diff --git a/cache.h b/cache.h index 430d021..1692891 100644 --- a/cache.h +++ b/cache.h @@ -267,7 +267,7 @@ static inline unsigned int canon_mode(unsigned int mode) #define cache_entry_size(len) (offsetof(struct cache_entry,name) + (len) + 1) struct index_state { - struct cache_entry **cache; + const struct cache_entry **cache; unsigned int version; unsigned int cache_nr, cache_alloc, cache_changed; struct string_list *resolve_undo; will help quickly identify them without bogus warnings. Signed-off-by: Nguyễn Thái Ngọc Duy <pclouds@gmail.com> Signed-off-by: Junio C Hamano <gitster@pobox.com>
2013-07-09 17:29:00 +02:00
int ce_same_name(const struct cache_entry *a, const struct cache_entry *b)
{
int len = ce_namelen(a);
return ce_namelen(b) == len && !memcmp(a->name, b->name, len);
}
/*
* We fundamentally don't like some paths: we don't want
* dot or dot-dot anywhere, and for obvious reasons don't
* want to recurse into ".git" either.
*
* Also, we don't want double slashes or slashes at the
* end that can make pathnames ambiguous.
*/
static int verify_dotfile(const char *rest, unsigned mode)
{
/*
* The first character was '.', but that
* has already been discarded, we now test
* the rest.
*/
/* "." is not allowed */
if (*rest == '\0' || is_dir_sep(*rest))
return 0;
switch (*rest) {
/*
* ".git" followed by NUL or slash is bad. Note that we match
* case-insensitively here, even if ignore_case is not set.
* This outlaws ".GIT" everywhere out of an abundance of caution,
* since there's really no good reason to allow it.
*
* Once we've seen ".git", we can also find ".gitmodules", etc (also
* case-insensitively).
*/
case 'g':
case 'G':
if (rest[1] != 'i' && rest[1] != 'I')
break;
if (rest[2] != 't' && rest[2] != 'T')
break;
if (rest[3] == '\0' || is_dir_sep(rest[3]))
return 0;
if (S_ISLNK(mode)) {
rest += 3;
if (skip_iprefix(rest, "modules", &rest) &&
(*rest == '\0' || is_dir_sep(*rest)))
return 0;
}
break;
case '.':
if (rest[1] == '\0' || is_dir_sep(rest[1]))
return 0;
}
return 1;
}
static enum verify_path_result verify_path_internal(const char *path,
unsigned mode)
{
mingw: safeguard better against backslashes in file names In 224c7d70fa1 (mingw: only test index entries for backslashes, not tree entries, 2019-12-31), we relaxed the check for backslashes in tree entries to check only index entries. However, the code change was incorrect: it was added to `add_index_entry_with_check()`, not to `add_index_entry()`, so under certain circumstances it was possible to side-step the protection. Besides, the description of that commit purported that all index entries would be checked when in fact they were only checked when being added to the index (there are code paths that do not do that, constructing "transient" index entries). In any case, it was pointed out in one insightful review at https://github.com/git-for-windows/git/pull/2437#issuecomment-566771835 that it would be a much better idea to teach `verify_path()` to perform the check for a backslash. This is safer, even if it comes with two notable drawbacks: - `verify_path()` cannot say _what_ is wrong with the path, therefore the user will no longer be told that there was a backslash in the path, only that the path was invalid. - The `git apply` command also calls the `verify_path()` function, and might have been able to handle Windows-style paths (i.e. with backslashes instead of forward slashes). This will no longer be possible unless the user (temporarily) sets `core.protectNTFS=false`. Note that `git add <windows-path>` will _still_ work because `normalize_path_copy_len()` will convert the backslashes to forward slashes before hitting the code path that creates an index entry. The clear advantage is that `verify_path()`'s purpose is to check the validity of the file name, therefore we naturally tap into all the code paths that need safeguarding, also implicitly into future code paths. The benefits of that approach outweigh the downsides, so let's move the check from `add_index_entry_with_check()` to `verify_path()`. Signed-off-by: Johannes Schindelin <johannes.schindelin@gmx.de> Signed-off-by: Junio C Hamano <gitster@pobox.com>
2020-01-09 14:30:34 +01:00
char c = 0;
if (has_dos_drive_prefix(path))
return PATH_INVALID;
mingw: refuse to access paths with trailing spaces or periods When creating a directory on Windows whose path ends in a space or a period (or chains thereof), the Win32 API "helpfully" trims those. For example, `mkdir("abc ");` will return success, but actually create a directory called `abc` instead. This stems back to the DOS days, when all file names had exactly 8 characters plus exactly 3 characters for the file extension, and the only way to have shorter names was by padding with spaces. Sadly, this "helpful" behavior is a bit inconsistent: after a successful `mkdir("abc ");`, a `mkdir("abc /def")` will actually _fail_ (because the directory `abc ` does not actually exist). Even if it would work, we now have a serious problem because a Git repository could contain directories `abc` and `abc `, and on Windows, they would be "merged" unintentionally. As these paths are illegal on Windows, anyway, let's disallow any accesses to such paths on that Operating System. For practical reasons, this behavior is still guarded by the config setting `core.protectNTFS`: it is possible (and at least two regression tests make use of it) to create commits without involving the worktree. In such a scenario, it is of course possible -- even on Windows -- to create such file names. Among other consequences, this patch disallows submodules' paths to end in spaces on Windows (which would formerly have confused Git enough to try to write into incorrect paths, anyway). While this patch does not fix a vulnerability on its own, it prevents an attack vector that was exploited in demonstrations of a number of recently-fixed security bugs. The regression test added to `t/t7417-submodule-path-url.sh` reflects that attack vector. Note that we have to adjust the test case "prevent git~1 squatting on Windows" in `t/t7415-submodule-names.sh` because of a very subtle issue. It tries to clone two submodules whose names differ only in a trailing period character, and as a consequence their git directories differ in the same way. Previously, when Git tried to clone the second submodule, it thought that the git directory already existed (because on Windows, when you create a directory with the name `b.` it actually creates `b`), but with this patch, the first submodule's clone will fail because of the illegal name of the git directory. Therefore, when cloning the second submodule, Git will take a different code path: a fresh clone (without an existing git directory). Both code paths fail to clone the second submodule, both because the the corresponding worktree directory exists and is not empty, but the error messages are worded differently. Signed-off-by: Johannes Schindelin <johannes.schindelin@gmx.de>
2019-09-05 13:27:53 +02:00
if (!is_valid_path(path))
return PATH_INVALID;
mingw: refuse to access paths with trailing spaces or periods When creating a directory on Windows whose path ends in a space or a period (or chains thereof), the Win32 API "helpfully" trims those. For example, `mkdir("abc ");` will return success, but actually create a directory called `abc` instead. This stems back to the DOS days, when all file names had exactly 8 characters plus exactly 3 characters for the file extension, and the only way to have shorter names was by padding with spaces. Sadly, this "helpful" behavior is a bit inconsistent: after a successful `mkdir("abc ");`, a `mkdir("abc /def")` will actually _fail_ (because the directory `abc ` does not actually exist). Even if it would work, we now have a serious problem because a Git repository could contain directories `abc` and `abc `, and on Windows, they would be "merged" unintentionally. As these paths are illegal on Windows, anyway, let's disallow any accesses to such paths on that Operating System. For practical reasons, this behavior is still guarded by the config setting `core.protectNTFS`: it is possible (and at least two regression tests make use of it) to create commits without involving the worktree. In such a scenario, it is of course possible -- even on Windows -- to create such file names. Among other consequences, this patch disallows submodules' paths to end in spaces on Windows (which would formerly have confused Git enough to try to write into incorrect paths, anyway). While this patch does not fix a vulnerability on its own, it prevents an attack vector that was exploited in demonstrations of a number of recently-fixed security bugs. The regression test added to `t/t7417-submodule-path-url.sh` reflects that attack vector. Note that we have to adjust the test case "prevent git~1 squatting on Windows" in `t/t7415-submodule-names.sh` because of a very subtle issue. It tries to clone two submodules whose names differ only in a trailing period character, and as a consequence their git directories differ in the same way. Previously, when Git tried to clone the second submodule, it thought that the git directory already existed (because on Windows, when you create a directory with the name `b.` it actually creates `b`), but with this patch, the first submodule's clone will fail because of the illegal name of the git directory. Therefore, when cloning the second submodule, Git will take a different code path: a fresh clone (without an existing git directory). Both code paths fail to clone the second submodule, both because the the corresponding worktree directory exists and is not empty, but the error messages are worded differently. Signed-off-by: Johannes Schindelin <johannes.schindelin@gmx.de>
2019-09-05 13:27:53 +02:00
goto inside;
for (;;) {
if (!c)
return PATH_OK;
if (is_dir_sep(c)) {
inside:
if (protect_hfs) {
mingw: safeguard better against backslashes in file names In 224c7d70fa1 (mingw: only test index entries for backslashes, not tree entries, 2019-12-31), we relaxed the check for backslashes in tree entries to check only index entries. However, the code change was incorrect: it was added to `add_index_entry_with_check()`, not to `add_index_entry()`, so under certain circumstances it was possible to side-step the protection. Besides, the description of that commit purported that all index entries would be checked when in fact they were only checked when being added to the index (there are code paths that do not do that, constructing "transient" index entries). In any case, it was pointed out in one insightful review at https://github.com/git-for-windows/git/pull/2437#issuecomment-566771835 that it would be a much better idea to teach `verify_path()` to perform the check for a backslash. This is safer, even if it comes with two notable drawbacks: - `verify_path()` cannot say _what_ is wrong with the path, therefore the user will no longer be told that there was a backslash in the path, only that the path was invalid. - The `git apply` command also calls the `verify_path()` function, and might have been able to handle Windows-style paths (i.e. with backslashes instead of forward slashes). This will no longer be possible unless the user (temporarily) sets `core.protectNTFS=false`. Note that `git add <windows-path>` will _still_ work because `normalize_path_copy_len()` will convert the backslashes to forward slashes before hitting the code path that creates an index entry. The clear advantage is that `verify_path()`'s purpose is to check the validity of the file name, therefore we naturally tap into all the code paths that need safeguarding, also implicitly into future code paths. The benefits of that approach outweigh the downsides, so let's move the check from `add_index_entry_with_check()` to `verify_path()`. Signed-off-by: Johannes Schindelin <johannes.schindelin@gmx.de> Signed-off-by: Junio C Hamano <gitster@pobox.com>
2020-01-09 14:30:34 +01:00
if (is_hfs_dotgit(path))
return PATH_INVALID;
if (S_ISLNK(mode)) {
if (is_hfs_dotgitmodules(path))
return PATH_INVALID;
}
}
if (protect_ntfs) {
cygwin: disallow backslashes in file names The backslash character is not a valid part of a file name on Windows. If, in Windows, Git attempts to write a file that has a backslash character in the filename, it will be incorrectly interpreted as a directory separator. This caused CVE-2019-1354 in MinGW, as this behaviour can be manipulated to cause the checkout to write to files it ought not write to, such as adding code to the .git/hooks directory. This was fixed by e1d911dd4c (mingw: disallow backslash characters in tree objects' file names, 2019-09-12). However, the vulnerability also exists in Cygwin: while Cygwin mostly provides a POSIX-like path system, it will still interpret a backslash as a directory separator. To avoid this vulnerability, CVE-2021-29468, extend the previous fix to also apply to Cygwin. Similarly, extend the test case added by the previous version of the commit. The test suite doesn't have an easy way to say "run this test if in MinGW or Cygwin", so add a new test prerequisite that covers both. As well as checking behaviour in the presence of paths containing backslashes, the existing test also checks behaviour in the presence of paths that differ only by the presence of a trailing ".". MinGW follows normal Windows application behaviour and treats them as the same path, but Cygwin more closely emulates *nix systems (at the expense of compatibility with native Windows applications) and will create and distinguish between such paths. Gate the relevant bit of that test accordingly. Reported-by: RyotaK <security@ryotak.me> Helped-by: Johannes Schindelin <johannes.schindelin@gmx.de> Signed-off-by: Adam Dinwoodie <adam@dinwoodie.org> Signed-off-by: Junio C Hamano <gitster@pobox.com>
2021-04-29 22:11:44 +02:00
#if defined GIT_WINDOWS_NATIVE || defined __CYGWIN__
mingw: safeguard better against backslashes in file names In 224c7d70fa1 (mingw: only test index entries for backslashes, not tree entries, 2019-12-31), we relaxed the check for backslashes in tree entries to check only index entries. However, the code change was incorrect: it was added to `add_index_entry_with_check()`, not to `add_index_entry()`, so under certain circumstances it was possible to side-step the protection. Besides, the description of that commit purported that all index entries would be checked when in fact they were only checked when being added to the index (there are code paths that do not do that, constructing "transient" index entries). In any case, it was pointed out in one insightful review at https://github.com/git-for-windows/git/pull/2437#issuecomment-566771835 that it would be a much better idea to teach `verify_path()` to perform the check for a backslash. This is safer, even if it comes with two notable drawbacks: - `verify_path()` cannot say _what_ is wrong with the path, therefore the user will no longer be told that there was a backslash in the path, only that the path was invalid. - The `git apply` command also calls the `verify_path()` function, and might have been able to handle Windows-style paths (i.e. with backslashes instead of forward slashes). This will no longer be possible unless the user (temporarily) sets `core.protectNTFS=false`. Note that `git add <windows-path>` will _still_ work because `normalize_path_copy_len()` will convert the backslashes to forward slashes before hitting the code path that creates an index entry. The clear advantage is that `verify_path()`'s purpose is to check the validity of the file name, therefore we naturally tap into all the code paths that need safeguarding, also implicitly into future code paths. The benefits of that approach outweigh the downsides, so let's move the check from `add_index_entry_with_check()` to `verify_path()`. Signed-off-by: Johannes Schindelin <johannes.schindelin@gmx.de> Signed-off-by: Junio C Hamano <gitster@pobox.com>
2020-01-09 14:30:34 +01:00
if (c == '\\')
return PATH_INVALID;
mingw: safeguard better against backslashes in file names In 224c7d70fa1 (mingw: only test index entries for backslashes, not tree entries, 2019-12-31), we relaxed the check for backslashes in tree entries to check only index entries. However, the code change was incorrect: it was added to `add_index_entry_with_check()`, not to `add_index_entry()`, so under certain circumstances it was possible to side-step the protection. Besides, the description of that commit purported that all index entries would be checked when in fact they were only checked when being added to the index (there are code paths that do not do that, constructing "transient" index entries). In any case, it was pointed out in one insightful review at https://github.com/git-for-windows/git/pull/2437#issuecomment-566771835 that it would be a much better idea to teach `verify_path()` to perform the check for a backslash. This is safer, even if it comes with two notable drawbacks: - `verify_path()` cannot say _what_ is wrong with the path, therefore the user will no longer be told that there was a backslash in the path, only that the path was invalid. - The `git apply` command also calls the `verify_path()` function, and might have been able to handle Windows-style paths (i.e. with backslashes instead of forward slashes). This will no longer be possible unless the user (temporarily) sets `core.protectNTFS=false`. Note that `git add <windows-path>` will _still_ work because `normalize_path_copy_len()` will convert the backslashes to forward slashes before hitting the code path that creates an index entry. The clear advantage is that `verify_path()`'s purpose is to check the validity of the file name, therefore we naturally tap into all the code paths that need safeguarding, also implicitly into future code paths. The benefits of that approach outweigh the downsides, so let's move the check from `add_index_entry_with_check()` to `verify_path()`. Signed-off-by: Johannes Schindelin <johannes.schindelin@gmx.de> Signed-off-by: Junio C Hamano <gitster@pobox.com>
2020-01-09 14:30:34 +01:00
#endif
if (is_ntfs_dotgit(path))
return PATH_INVALID;
if (S_ISLNK(mode)) {
if (is_ntfs_dotgitmodules(path))
return PATH_INVALID;
}
}
c = *path++;
if ((c == '.' && !verify_dotfile(path, mode)) ||
sparse-index: convert from full to sparse If we have a full index, then we can convert it to a sparse index by replacing directories outside of the sparse cone with sparse directory entries. The convert_to_sparse() method does this, when the situation is appropriate. For now, we avoid converting the index to a sparse index if: 1. the index is split. 2. the index is already sparse. 3. sparse-checkout is disabled. 4. sparse-checkout does not use cone mode. Finally, we currently limit the conversion to when the GIT_TEST_SPARSE_INDEX environment variable is enabled. A mode using Git config will be added in a later change. The trickiest thing about this conversion is that we might not be able to mark a directory as a sparse directory just because it is outside the sparse cone. There might be unmerged files within that directory, so we need to look for those. Also, if there is some strange reason why a file is not marked with CE_SKIP_WORKTREE, then we should give up on converting that directory. There is still hope that some of its subdirectories might be able to convert to sparse, so we keep looking deeper. The conversion process is assisted by the cache-tree extension. This is calculated from the full index if it does not already exist. We then abandon the cache-tree as it no longer applies to the newly-sparse index. Thus, this cache-tree will be recalculated in every sparse-full-sparse round-trip until we integrate the cache-tree extension with the sparse index. Some Git commands use the index after writing it. For example, 'git add' will update the index, then write it to disk, then read its entries to report information. To keep the in-memory index in a full state after writing, we re-expand it to a full one after the write. This is wasteful for commands that only write the index and do not read from it again, but that is only the case until we make those commands "sparse aware." We can compare the behavior of the sparse-index in t1092-sparse-checkout-compability.sh by using GIT_TEST_SPARSE_INDEX=1 when operating on the 'sparse-index' repo. We can also compare the two sparse repos directly, such as comparing their indexes (when expanded to full in the case of the 'sparse-index' repo). We also verify that the index is actually populated with sparse directory entries. The 'checkout and reset (mixed)' test is marked for failure when comparing a sparse repo to a full repo, but we can compare the two sparse-checkout cases directly to ensure that we are not changing the behavior when using a sparse index. Signed-off-by: Derrick Stolee <dstolee@microsoft.com> Signed-off-by: Junio C Hamano <gitster@pobox.com>
2021-03-30 15:10:55 +02:00
is_dir_sep(c))
return PATH_INVALID;
sparse-index: convert from full to sparse If we have a full index, then we can convert it to a sparse index by replacing directories outside of the sparse cone with sparse directory entries. The convert_to_sparse() method does this, when the situation is appropriate. For now, we avoid converting the index to a sparse index if: 1. the index is split. 2. the index is already sparse. 3. sparse-checkout is disabled. 4. sparse-checkout does not use cone mode. Finally, we currently limit the conversion to when the GIT_TEST_SPARSE_INDEX environment variable is enabled. A mode using Git config will be added in a later change. The trickiest thing about this conversion is that we might not be able to mark a directory as a sparse directory just because it is outside the sparse cone. There might be unmerged files within that directory, so we need to look for those. Also, if there is some strange reason why a file is not marked with CE_SKIP_WORKTREE, then we should give up on converting that directory. There is still hope that some of its subdirectories might be able to convert to sparse, so we keep looking deeper. The conversion process is assisted by the cache-tree extension. This is calculated from the full index if it does not already exist. We then abandon the cache-tree as it no longer applies to the newly-sparse index. Thus, this cache-tree will be recalculated in every sparse-full-sparse round-trip until we integrate the cache-tree extension with the sparse index. Some Git commands use the index after writing it. For example, 'git add' will update the index, then write it to disk, then read its entries to report information. To keep the in-memory index in a full state after writing, we re-expand it to a full one after the write. This is wasteful for commands that only write the index and do not read from it again, but that is only the case until we make those commands "sparse aware." We can compare the behavior of the sparse-index in t1092-sparse-checkout-compability.sh by using GIT_TEST_SPARSE_INDEX=1 when operating on the 'sparse-index' repo. We can also compare the two sparse repos directly, such as comparing their indexes (when expanded to full in the case of the 'sparse-index' repo). We also verify that the index is actually populated with sparse directory entries. The 'checkout and reset (mixed)' test is marked for failure when comparing a sparse repo to a full repo, but we can compare the two sparse-checkout cases directly to ensure that we are not changing the behavior when using a sparse index. Signed-off-by: Derrick Stolee <dstolee@microsoft.com> Signed-off-by: Junio C Hamano <gitster@pobox.com>
2021-03-30 15:10:55 +02:00
/*
* allow terminating directory separators for
* sparse directory entries.
*/
if (c == '\0')
return S_ISDIR(mode) ? PATH_DIR_WITH_SEP :
PATH_INVALID;
is_ntfs_dotgit(): only verify the leading segment The config setting `core.protectNTFS` is specifically designed to work not only on Windows, but anywhere, to allow for repositories hosted on, say, Linux servers to be protected against NTFS-specific attack vectors. As a consequence, `is_ntfs_dotgit()` manually splits backslash-separated paths (but does not do the same for paths separated by forward slashes), under the assumption that the backslash might not be a valid directory separator on the _current_ Operating System. However, the two callers, `verify_path()` and `fsck_tree()`, are supposed to feed only individual path segments to the `is_ntfs_dotgit()` function. This causes a lot of duplicate scanning (and very inefficient scanning, too, as the inner loop of `is_ntfs_dotgit()` was optimized for readability rather than for speed. Let's simplify the design of `is_ntfs_dotgit()` by putting the burden of splitting the paths by backslashes as directory separators on the callers of said function. Consequently, the `verify_path()` function, which already splits the path by directory separators, now treats backslashes as directory separators _explicitly_ when `core.protectNTFS` is turned on, even on platforms where the backslash is _not_ a directory separator. Note that we have to repeat some code in `verify_path()`: if the backslash is not a directory separator on the current Operating System, we want to allow file names like `\`, but we _do_ want to disallow paths that are clearly intended to cause harm when the repository is cloned on Windows. The `fsck_tree()` function (the other caller of `is_ntfs_dotgit()`) now needs to look for backslashes in tree entries' names specifically when `core.protectNTFS` is turned on. While it would be tempting to completely disallow backslashes in that case (much like `fsck` reports names containing forward slashes as "full paths"), this would be overzealous: when `core.protectNTFS` is turned on in a non-Windows setup, backslashes are perfectly valid characters in file names while we _still_ want to disallow tree entries that are clearly designed to exploit NTFS-specific behavior. This simplification will make subsequent changes easier to implement, such as turning `core.protectNTFS` on by default (not only on Windows) or protecting against attack vectors involving NTFS Alternate Data Streams. Incidentally, this change allows for catching malicious repositories that contain tree entries of the form `dir\.gitmodules` already on the server side rather than only on the client side (and previously only on Windows): in contrast to `is_ntfs_dotgit()`, the `is_ntfs_dotgitmodules()` function already expects the caller to split the paths by directory separators. Signed-off-by: Johannes Schindelin <johannes.schindelin@gmx.de>
2019-09-23 08:58:11 +02:00
} else if (c == '\\' && protect_ntfs) {
if (is_ntfs_dotgit(path))
return PATH_INVALID;
is_ntfs_dotgit(): only verify the leading segment The config setting `core.protectNTFS` is specifically designed to work not only on Windows, but anywhere, to allow for repositories hosted on, say, Linux servers to be protected against NTFS-specific attack vectors. As a consequence, `is_ntfs_dotgit()` manually splits backslash-separated paths (but does not do the same for paths separated by forward slashes), under the assumption that the backslash might not be a valid directory separator on the _current_ Operating System. However, the two callers, `verify_path()` and `fsck_tree()`, are supposed to feed only individual path segments to the `is_ntfs_dotgit()` function. This causes a lot of duplicate scanning (and very inefficient scanning, too, as the inner loop of `is_ntfs_dotgit()` was optimized for readability rather than for speed. Let's simplify the design of `is_ntfs_dotgit()` by putting the burden of splitting the paths by backslashes as directory separators on the callers of said function. Consequently, the `verify_path()` function, which already splits the path by directory separators, now treats backslashes as directory separators _explicitly_ when `core.protectNTFS` is turned on, even on platforms where the backslash is _not_ a directory separator. Note that we have to repeat some code in `verify_path()`: if the backslash is not a directory separator on the current Operating System, we want to allow file names like `\`, but we _do_ want to disallow paths that are clearly intended to cause harm when the repository is cloned on Windows. The `fsck_tree()` function (the other caller of `is_ntfs_dotgit()`) now needs to look for backslashes in tree entries' names specifically when `core.protectNTFS` is turned on. While it would be tempting to completely disallow backslashes in that case (much like `fsck` reports names containing forward slashes as "full paths"), this would be overzealous: when `core.protectNTFS` is turned on in a non-Windows setup, backslashes are perfectly valid characters in file names while we _still_ want to disallow tree entries that are clearly designed to exploit NTFS-specific behavior. This simplification will make subsequent changes easier to implement, such as turning `core.protectNTFS` on by default (not only on Windows) or protecting against attack vectors involving NTFS Alternate Data Streams. Incidentally, this change allows for catching malicious repositories that contain tree entries of the form `dir\.gitmodules` already on the server side rather than only on the client side (and previously only on Windows): in contrast to `is_ntfs_dotgit()`, the `is_ntfs_dotgitmodules()` function already expects the caller to split the paths by directory separators. Signed-off-by: Johannes Schindelin <johannes.schindelin@gmx.de>
2019-09-23 08:58:11 +02:00
if (S_ISLNK(mode)) {
if (is_ntfs_dotgitmodules(path))
return PATH_INVALID;
is_ntfs_dotgit(): only verify the leading segment The config setting `core.protectNTFS` is specifically designed to work not only on Windows, but anywhere, to allow for repositories hosted on, say, Linux servers to be protected against NTFS-specific attack vectors. As a consequence, `is_ntfs_dotgit()` manually splits backslash-separated paths (but does not do the same for paths separated by forward slashes), under the assumption that the backslash might not be a valid directory separator on the _current_ Operating System. However, the two callers, `verify_path()` and `fsck_tree()`, are supposed to feed only individual path segments to the `is_ntfs_dotgit()` function. This causes a lot of duplicate scanning (and very inefficient scanning, too, as the inner loop of `is_ntfs_dotgit()` was optimized for readability rather than for speed. Let's simplify the design of `is_ntfs_dotgit()` by putting the burden of splitting the paths by backslashes as directory separators on the callers of said function. Consequently, the `verify_path()` function, which already splits the path by directory separators, now treats backslashes as directory separators _explicitly_ when `core.protectNTFS` is turned on, even on platforms where the backslash is _not_ a directory separator. Note that we have to repeat some code in `verify_path()`: if the backslash is not a directory separator on the current Operating System, we want to allow file names like `\`, but we _do_ want to disallow paths that are clearly intended to cause harm when the repository is cloned on Windows. The `fsck_tree()` function (the other caller of `is_ntfs_dotgit()`) now needs to look for backslashes in tree entries' names specifically when `core.protectNTFS` is turned on. While it would be tempting to completely disallow backslashes in that case (much like `fsck` reports names containing forward slashes as "full paths"), this would be overzealous: when `core.protectNTFS` is turned on in a non-Windows setup, backslashes are perfectly valid characters in file names while we _still_ want to disallow tree entries that are clearly designed to exploit NTFS-specific behavior. This simplification will make subsequent changes easier to implement, such as turning `core.protectNTFS` on by default (not only on Windows) or protecting against attack vectors involving NTFS Alternate Data Streams. Incidentally, this change allows for catching malicious repositories that contain tree entries of the form `dir\.gitmodules` already on the server side rather than only on the client side (and previously only on Windows): in contrast to `is_ntfs_dotgit()`, the `is_ntfs_dotgitmodules()` function already expects the caller to split the paths by directory separators. Signed-off-by: Johannes Schindelin <johannes.schindelin@gmx.de>
2019-09-23 08:58:11 +02:00
}
}
is_ntfs_dotgit(): only verify the leading segment The config setting `core.protectNTFS` is specifically designed to work not only on Windows, but anywhere, to allow for repositories hosted on, say, Linux servers to be protected against NTFS-specific attack vectors. As a consequence, `is_ntfs_dotgit()` manually splits backslash-separated paths (but does not do the same for paths separated by forward slashes), under the assumption that the backslash might not be a valid directory separator on the _current_ Operating System. However, the two callers, `verify_path()` and `fsck_tree()`, are supposed to feed only individual path segments to the `is_ntfs_dotgit()` function. This causes a lot of duplicate scanning (and very inefficient scanning, too, as the inner loop of `is_ntfs_dotgit()` was optimized for readability rather than for speed. Let's simplify the design of `is_ntfs_dotgit()` by putting the burden of splitting the paths by backslashes as directory separators on the callers of said function. Consequently, the `verify_path()` function, which already splits the path by directory separators, now treats backslashes as directory separators _explicitly_ when `core.protectNTFS` is turned on, even on platforms where the backslash is _not_ a directory separator. Note that we have to repeat some code in `verify_path()`: if the backslash is not a directory separator on the current Operating System, we want to allow file names like `\`, but we _do_ want to disallow paths that are clearly intended to cause harm when the repository is cloned on Windows. The `fsck_tree()` function (the other caller of `is_ntfs_dotgit()`) now needs to look for backslashes in tree entries' names specifically when `core.protectNTFS` is turned on. While it would be tempting to completely disallow backslashes in that case (much like `fsck` reports names containing forward slashes as "full paths"), this would be overzealous: when `core.protectNTFS` is turned on in a non-Windows setup, backslashes are perfectly valid characters in file names while we _still_ want to disallow tree entries that are clearly designed to exploit NTFS-specific behavior. This simplification will make subsequent changes easier to implement, such as turning `core.protectNTFS` on by default (not only on Windows) or protecting against attack vectors involving NTFS Alternate Data Streams. Incidentally, this change allows for catching malicious repositories that contain tree entries of the form `dir\.gitmodules` already on the server side rather than only on the client side (and previously only on Windows): in contrast to `is_ntfs_dotgit()`, the `is_ntfs_dotgitmodules()` function already expects the caller to split the paths by directory separators. Signed-off-by: Johannes Schindelin <johannes.schindelin@gmx.de>
2019-09-23 08:58:11 +02:00
c = *path++;
}
}
/*
* Do we have another file that has the beginning components being a
* proper superset of the name we're trying to add?
*/
static int has_file_name(struct index_state *istate,
const struct cache_entry *ce, int pos, int ok_to_replace)
{
int retval = 0;
int len = ce_namelen(ce);
int stage = ce_stage(ce);
const char *name = ce->name;
while (pos < istate->cache_nr) {
struct cache_entry *p = istate->cache[pos++];
if (len >= ce_namelen(p))
break;
if (memcmp(name, p->name, len))
break;
if (ce_stage(p) != stage)
continue;
if (p->name[len] != '/')
continue;
if (p->ce_flags & CE_REMOVE)
continue;
retval = -1;
if (!ok_to_replace)
break;
remove_index_entry_at(istate, --pos);
}
return retval;
}
/*
* Like strcmp(), but also return the offset of the first change.
* If strings are equal, return the length.
*/
int strcmp_offset(const char *s1, const char *s2, size_t *first_change)
{
size_t k;
if (!first_change)
return strcmp(s1, s2);
for (k = 0; s1[k] == s2[k]; k++)
if (s1[k] == '\0')
break;
*first_change = k;
return (unsigned char)s1[k] - (unsigned char)s2[k];
}
/*
* Do we have another file with a pathname that is a proper
* subset of the name we're trying to add?
*
* That is, is there another file in the index with a path
* that matches a sub-directory in the given entry?
*/
static int has_dir_name(struct index_state *istate,
const struct cache_entry *ce, int pos, int ok_to_replace)
{
int retval = 0;
int stage = ce_stage(ce);
const char *name = ce->name;
const char *slash = name + ce_namelen(ce);
size_t len_eq_last;
int cmp_last = 0;
/*
* We are frequently called during an iteration on a sorted
* list of pathnames and while building a new index. Therefore,
* there is a high probability that this entry will eventually
* be appended to the index, rather than inserted in the middle.
* If we can confirm that, we can avoid binary searches on the
* components of the pathname.
*
* Compare the entry's full path with the last path in the index.
*/
if (istate->cache_nr > 0) {
cmp_last = strcmp_offset(name,
istate->cache[istate->cache_nr - 1]->name,
&len_eq_last);
if (cmp_last > 0) {
if (len_eq_last == 0) {
/*
* The entry sorts AFTER the last one in the
* index and their paths have no common prefix,
* so there cannot be a F/D conflict.
*/
return retval;
} else {
/*
* The entry sorts AFTER the last one in the
* index, but has a common prefix. Fall through
* to the loop below to disect the entry's path
* and see where the difference is.
*/
}
} else if (cmp_last == 0) {
/*
* The entry exactly matches the last one in the
* index, but because of multiple stage and CE_REMOVE
* items, we fall through and let the regular search
* code handle it.
*/
}
}
for (;;) {
read-cache: speed up has_dir_name (part 2) Teach has_dir_name() to see if the path of the new item is greater than the last path in the index array before attempting to search for it. has_dir_name() is looking for file/directory collisions in the index and has to consider each sub-directory prefix in turn. This can cause multiple binary searches for each path. During operations like checkout, merge_working_tree() populates the new index in sorted order, so we expect to be able to append in many cases. This commit is part 2 of 2. This commit handles the additional possible short-cuts as we look at each sub-directory prefix. The net-net gains for add_index_entry_with_check() and both had_dir_name() commits are best seen for very large repos. Here are results for an INFLATED version of linux.git with 1M files. $ GIT_PERF_REPO=/mnt/test/linux_inflated.git/ ./run upstream/base HEAD ./p0006-read-tree-checkout.sh Test upstream/base HEAD 0006.2: read-tree br_base br_ballast (1043893) 3.79(3.63+0.15) 2.68(2.52+0.15) -29.3% 0006.3: switch between br_base br_ballast (1043893) 7.55(6.58+0.44) 6.03(4.60+0.43) -20.1% 0006.4: switch between br_ballast br_ballast_plus_1 (1043893) 10.84(9.26+0.59) 8.44(7.06+0.65) -22.1% 0006.5: switch between aliases (1043893) 10.93(9.39+0.58) 10.24(7.04+0.63) -6.3% Here are results for a synthetic repo with 4.2M files. $ GIT_PERF_REPO=~/work/gfw/t/perf/repos/gen-many-files-10.4.3.git/ ./run HEAD~3 HEAD ./p0006-read-tree-checkout.sh Test HEAD~3 HEAD 0006.2: read-tree br_base br_ballast (4194305) 29.96(19.26+10.50) 23.76(13.42+10.12) -20.7% 0006.3: switch between br_base br_ballast (4194305) 56.95(36.08+16.83) 45.54(25.94+15.68) -20.0% 0006.4: switch between br_ballast br_ballast_plus_1 (4194305) 90.94(51.50+31.52) 78.22(39.39+30.70) -14.0% 0006.5: switch between aliases (4194305) 93.72(51.63+34.09) 77.94(39.00+30.88) -16.8% Results for medium repos (like linux.git) are mixed and have more variance (probably do to disk IO unrelated to this test. $ GIT_PERF_REPO=/mnt/test/linux.git/ ./run HEAD~3 HEAD ./p0006-read-tree-checkout.sh Test HEAD~3 HEAD 0006.2: read-tree br_base br_ballast (57994) 0.25(0.21+0.03) 0.20(0.17+0.02) -20.0% 0006.3: switch between br_base br_ballast (57994) 10.67(6.06+2.92) 10.51(5.94+2.91) -1.5% 0006.4: switch between br_ballast br_ballast_plus_1 (57994) 0.59(0.47+0.16) 0.52(0.40+0.13) -11.9% 0006.5: switch between aliases (57994) 0.59(0.44+0.17) 0.51(0.38+0.14) -13.6% $ GIT_PERF_REPO=/mnt/test/linux.git/ ./run HEAD~3 HEAD ./p0006-read-tree-checkout.sh Test HEAD~3 HEAD 0006.2: read-tree br_base br_ballast (57994) 0.24(0.21+0.02) 0.21(0.18+0.02) -12.5% 0006.3: switch between br_base br_ballast (57994) 10.42(5.98+2.91) 10.66(5.86+3.09) +2.3% 0006.4: switch between br_ballast br_ballast_plus_1 (57994) 0.59(0.49+0.13) 0.53(0.37+0.16) -10.2% 0006.5: switch between aliases (57994) 0.59(0.43+0.17) 0.50(0.37+0.14) -15.3% Results for smaller repos (like git.git) are not significant. $ ./run HEAD~3 HEAD ./p0006-read-tree-checkout.sh Test HEAD~3 HEAD 0006.2: read-tree br_base br_ballast (3043) 0.01(0.00+0.00) 0.01(0.00+0.00) +0.0% 0006.3: switch between br_base br_ballast (3043) 0.31(0.17+0.11) 0.29(0.19+0.08) -6.5% 0006.4: switch between br_ballast br_ballast_plus_1 (3043) 0.03(0.02+0.00) 0.03(0.02+0.00) +0.0% 0006.5: switch between aliases (3043) 0.03(0.02+0.00) 0.03(0.02+0.00) +0.0% Signed-off-by: Jeff Hostetler <jeffhost@microsoft.com> Signed-off-by: Junio C Hamano <gitster@pobox.com>
2017-04-19 19:06:18 +02:00
size_t len;
for (;;) {
if (*--slash == '/')
break;
if (slash <= ce->name)
return retval;
}
len = slash - name;
read-cache: speed up has_dir_name (part 2) Teach has_dir_name() to see if the path of the new item is greater than the last path in the index array before attempting to search for it. has_dir_name() is looking for file/directory collisions in the index and has to consider each sub-directory prefix in turn. This can cause multiple binary searches for each path. During operations like checkout, merge_working_tree() populates the new index in sorted order, so we expect to be able to append in many cases. This commit is part 2 of 2. This commit handles the additional possible short-cuts as we look at each sub-directory prefix. The net-net gains for add_index_entry_with_check() and both had_dir_name() commits are best seen for very large repos. Here are results for an INFLATED version of linux.git with 1M files. $ GIT_PERF_REPO=/mnt/test/linux_inflated.git/ ./run upstream/base HEAD ./p0006-read-tree-checkout.sh Test upstream/base HEAD 0006.2: read-tree br_base br_ballast (1043893) 3.79(3.63+0.15) 2.68(2.52+0.15) -29.3% 0006.3: switch between br_base br_ballast (1043893) 7.55(6.58+0.44) 6.03(4.60+0.43) -20.1% 0006.4: switch between br_ballast br_ballast_plus_1 (1043893) 10.84(9.26+0.59) 8.44(7.06+0.65) -22.1% 0006.5: switch between aliases (1043893) 10.93(9.39+0.58) 10.24(7.04+0.63) -6.3% Here are results for a synthetic repo with 4.2M files. $ GIT_PERF_REPO=~/work/gfw/t/perf/repos/gen-many-files-10.4.3.git/ ./run HEAD~3 HEAD ./p0006-read-tree-checkout.sh Test HEAD~3 HEAD 0006.2: read-tree br_base br_ballast (4194305) 29.96(19.26+10.50) 23.76(13.42+10.12) -20.7% 0006.3: switch between br_base br_ballast (4194305) 56.95(36.08+16.83) 45.54(25.94+15.68) -20.0% 0006.4: switch between br_ballast br_ballast_plus_1 (4194305) 90.94(51.50+31.52) 78.22(39.39+30.70) -14.0% 0006.5: switch between aliases (4194305) 93.72(51.63+34.09) 77.94(39.00+30.88) -16.8% Results for medium repos (like linux.git) are mixed and have more variance (probably do to disk IO unrelated to this test. $ GIT_PERF_REPO=/mnt/test/linux.git/ ./run HEAD~3 HEAD ./p0006-read-tree-checkout.sh Test HEAD~3 HEAD 0006.2: read-tree br_base br_ballast (57994) 0.25(0.21+0.03) 0.20(0.17+0.02) -20.0% 0006.3: switch between br_base br_ballast (57994) 10.67(6.06+2.92) 10.51(5.94+2.91) -1.5% 0006.4: switch between br_ballast br_ballast_plus_1 (57994) 0.59(0.47+0.16) 0.52(0.40+0.13) -11.9% 0006.5: switch between aliases (57994) 0.59(0.44+0.17) 0.51(0.38+0.14) -13.6% $ GIT_PERF_REPO=/mnt/test/linux.git/ ./run HEAD~3 HEAD ./p0006-read-tree-checkout.sh Test HEAD~3 HEAD 0006.2: read-tree br_base br_ballast (57994) 0.24(0.21+0.02) 0.21(0.18+0.02) -12.5% 0006.3: switch between br_base br_ballast (57994) 10.42(5.98+2.91) 10.66(5.86+3.09) +2.3% 0006.4: switch between br_ballast br_ballast_plus_1 (57994) 0.59(0.49+0.13) 0.53(0.37+0.16) -10.2% 0006.5: switch between aliases (57994) 0.59(0.43+0.17) 0.50(0.37+0.14) -15.3% Results for smaller repos (like git.git) are not significant. $ ./run HEAD~3 HEAD ./p0006-read-tree-checkout.sh Test HEAD~3 HEAD 0006.2: read-tree br_base br_ballast (3043) 0.01(0.00+0.00) 0.01(0.00+0.00) +0.0% 0006.3: switch between br_base br_ballast (3043) 0.31(0.17+0.11) 0.29(0.19+0.08) -6.5% 0006.4: switch between br_ballast br_ballast_plus_1 (3043) 0.03(0.02+0.00) 0.03(0.02+0.00) +0.0% 0006.5: switch between aliases (3043) 0.03(0.02+0.00) 0.03(0.02+0.00) +0.0% Signed-off-by: Jeff Hostetler <jeffhost@microsoft.com> Signed-off-by: Junio C Hamano <gitster@pobox.com>
2017-04-19 19:06:18 +02:00
if (cmp_last > 0) {
/*
* (len + 1) is a directory boundary (including
* the trailing slash). And since the loop is
* decrementing "slash", the first iteration is
* the longest directory prefix; subsequent
* iterations consider parent directories.
*/
if (len + 1 <= len_eq_last) {
/*
* The directory prefix (including the trailing
* slash) also appears as a prefix in the last
* entry, so the remainder cannot collide (because
* strcmp said the whole path was greater).
*
* EQ: last: xxx/A
* this: xxx/B
*
* LT: last: xxx/file_A
* this: xxx/file_B
*/
return retval;
}
if (len > len_eq_last) {
/*
* This part of the directory prefix (excluding
* the trailing slash) is longer than the known
* equal portions, so this sub-directory cannot
* collide with a file.
*
* GT: last: xxxA
* this: xxxB/file
*/
return retval;
}
/*
* This is a possible collision. Fall through and
* let the regular search code handle it.
*
* last: xxx
* this: xxx/file
*/
}
pos = index_name_stage_pos(istate, name, len, stage, EXPAND_SPARSE);
if (pos >= 0) {
/*
* Found one, but not so fast. This could
* be a marker that says "I was here, but
* I am being removed". Such an entry is
* not a part of the resulting tree, and
* it is Ok to have a directory at the same
* path.
*/
if (!(istate->cache[pos]->ce_flags & CE_REMOVE)) {
retval = -1;
if (!ok_to_replace)
break;
remove_index_entry_at(istate, pos);
continue;
}
}
else
pos = -pos-1;
/*
* Trivial optimization: if we find an entry that
* already matches the sub-directory, then we know
* we're ok, and we can exit.
*/
while (pos < istate->cache_nr) {
struct cache_entry *p = istate->cache[pos];
if ((ce_namelen(p) <= len) ||
(p->name[len] != '/') ||
memcmp(p->name, name, len))
break; /* not our subdirectory */
if (ce_stage(p) == stage && !(p->ce_flags & CE_REMOVE))
/*
* p is at the same stage as our entry, and
* is a subdirectory of what we are looking
* at, so we cannot have conflicts at our
* level or anything shorter.
*/
return retval;
pos++;
}
}
return retval;
}
/* We may be in a situation where we already have path/file and path
* is being added, or we already have path and path/file is being
* added. Either one would result in a nonsense tree that has path
* twice when git-write-tree tries to write it out. Prevent it.
*
* If ok-to-replace is specified, we remove the conflicting entries
* from the cache so the caller should recompute the insert position.
* When this happens, we return non-zero.
*/
static int check_file_directory_conflict(struct index_state *istate,
const struct cache_entry *ce,
int pos, int ok_to_replace)
{
int retval;
/*
* When ce is an "I am going away" entry, we allow it to be added
*/
if (ce->ce_flags & CE_REMOVE)
return 0;
/*
* We check if the path is a sub-path of a subsequent pathname
* first, since removing those will not change the position
* in the array.
*/
retval = has_file_name(istate, ce, pos, ok_to_replace);
/*
* Then check if the path might have a clashing sub-directory
* before it.
*/
return retval + has_dir_name(istate, ce, pos, ok_to_replace);
}
static int add_index_entry_with_check(struct index_state *istate, struct cache_entry *ce, int option)
{
int pos;
int ok_to_add = option & ADD_CACHE_OK_TO_ADD;
int ok_to_replace = option & ADD_CACHE_OK_TO_REPLACE;
int skip_df_check = option & ADD_CACHE_SKIP_DFCHECK;
int new_only = option & ADD_CACHE_NEW_ONLY;
"Assume unchanged" git This adds "assume unchanged" logic, started by this message in the list discussion recently: <Pine.LNX.4.64.0601311807470.7301@g5.osdl.org> This is a workaround for filesystems that do not have lstat() that is quick enough for the index mechanism to take advantage of. On the paths marked as "assumed to be unchanged", the user needs to explicitly use update-index to register the object name to be in the next commit. You can use two new options to update-index to set and reset the CE_VALID bit: git-update-index --assume-unchanged path... git-update-index --no-assume-unchanged path... These forms manipulate only the CE_VALID bit; it does not change the object name recorded in the index file. Nor they add a new entry to the index. When the configuration variable "core.ignorestat = true" is set, the index entries are marked with CE_VALID bit automatically after: - update-index to explicitly register the current object name to the index file. - when update-index --refresh finds the path to be up-to-date. - when tools like read-tree -u and apply --index update the working tree file and register the current object name to the index file. The flag is dropped upon read-tree that does not check out the index entry. This happens regardless of the core.ignorestat settings. Index entries marked with CE_VALID bit are assumed to be unchanged most of the time. However, there are cases that CE_VALID bit is ignored for the sake of safety and usability: - while "git-read-tree -m" or git-apply need to make sure that the paths involved in the merge do not have local modifications. This sacrifices performance for safety. - when git-checkout-index -f -q -u -a tries to see if it needs to checkout the paths. Otherwise you can never check anything out ;-). - when git-update-index --really-refresh (a new flag) tries to see if the index entry is up to date. You can start with everything marked as CE_VALID and run this once to drop CE_VALID bit for paths that are modified. Most notably, "update-index --refresh" honours CE_VALID and does not actively stat, so after you modified a file in the working tree, update-index --refresh would not notice until you tell the index about it with "git-update-index path" or "git-update-index --no-assume-unchanged path". This version is not expected to be perfect. I think diff between index and/or tree and working files may need some adjustment, and there probably needs other cases we should automatically unmark paths that are marked to be CE_VALID. But the basics seem to work, and ready to be tested by people who asked for this feature. Signed-off-by: Junio C Hamano <junkio@cox.net>
2006-02-09 06:15:24 +01:00
if (!(option & ADD_CACHE_KEEP_CACHE_TREE))
cache_tree_invalidate_path(istate, ce->name);
/*
* If this entry's path sorts after the last entry in the index,
* we can avoid searching for it.
*/
if (istate->cache_nr > 0 &&
strcmp(ce->name, istate->cache[istate->cache_nr - 1]->name) > 0)
msvc: avoid using minus operator on unsigned types MSVC complains about this with `-Wall`, which can be taken as a sign that this is indeed a real bug. The symptom is: C4146: unary minus operator applied to unsigned type, result still unsigned Let's avoid this warning in the minimal way, e.g. writing `-1 - <unsigned value>` instead of `-<unsigned value> - 1`. Note that the change in the `estimate_cache_size()` function is needed because MSVC considers the "return type" of the `sizeof()` operator to be `size_t`, i.e. unsigned, and therefore it cannot be negated using the unary minus operator. Even worse, that arithmetic is doing extra work, in vain. We want to calculate the entry extra cache size as the difference between the size of the `cache_entry` structure minus the size of the `ondisk_cache_entry` structure, padded to the appropriate alignment boundary. To that end, we start by assigning that difference to the `per_entry` variable, and then abuse the `len` parameter of the `align_padding_size()` macro to take the negative size of the ondisk entry size. Essentially, we try to avoid passing the already calculated difference to that macro by passing the operands of that difference instead, when the macro expects operands of an addition: #define align_padding_size(size, len) \ ((size + (len) + 8) & ~7) - (size + len) Currently, we pass A and -B to that macro instead of passing A - B and 0, where A - B is already stored in the `per_entry` variable, ready to be used. This is neither necessary, nor intuitive. Let's fix this, and have code that is both easier to read and that also does not trigger MSVC's warning. While at it, we take care of reporting overflows (which are unlikely, but hey, defensive programming is good!). We _also_ take pains of casting the unsigned value to signed: otherwise, the signed operand (i.e. the `-1`) would be cast to unsigned before doing the arithmetic. Helped-by: Denton Liu <liu.denton@gmail.com> Signed-off-by: Johannes Schindelin <johannes.schindelin@gmx.de> Signed-off-by: Junio C Hamano <gitster@pobox.com>
2019-10-04 17:09:26 +02:00
pos = index_pos_to_insert_pos(istate->cache_nr);
else
pos = index_name_stage_pos(istate, ce->name, ce_namelen(ce), ce_stage(ce), EXPAND_SPARSE);
/* existing match? Just replace it. */
if (pos >= 0) {
if (!new_only)
replace_index_entry(istate, pos, ce);
return 0;
}
pos = -pos-1;
if (!(option & ADD_CACHE_KEEP_CACHE_TREE))
untracked_cache_add_to_index(istate, ce->name);
/*
* Inserting a merged entry ("stage 0") into the index
* will always replace all non-merged entries..
*/
if (pos < istate->cache_nr && ce_stage(ce) == 0) {
while (ce_same_name(istate->cache[pos], ce)) {
ok_to_add = 1;
if (!remove_index_entry_at(istate, pos))
break;
}
}
if (!ok_to_add)
return -1;
if (verify_path_internal(ce->name, ce->ce_mode) == PATH_INVALID)
return error(_("invalid path '%s'"), ce->name);
if (!skip_df_check &&
check_file_directory_conflict(istate, ce, pos, ok_to_replace)) {
if (!ok_to_replace)
return error(_("'%s' appears as both a file and as a directory"),
ce->name);
pos = index_name_stage_pos(istate, ce->name, ce_namelen(ce), ce_stage(ce), EXPAND_SPARSE);
pos = -pos-1;
}
return pos + 1;
}
int add_index_entry(struct index_state *istate, struct cache_entry *ce, int option)
{
int pos;
if (option & ADD_CACHE_JUST_APPEND)
pos = istate->cache_nr;
else {
int ret;
ret = add_index_entry_with_check(istate, ce, option);
if (ret <= 0)
return ret;
pos = ret - 1;
}
/* Make sure the array is big enough .. */
ALLOC_GROW(istate->cache, istate->cache_nr + 1, istate->cache_alloc);
/* Add it in.. */
istate->cache_nr++;
if (istate->cache_nr > pos + 1)
MOVE_ARRAY(istate->cache + pos + 1, istate->cache + pos,
istate->cache_nr - pos - 1);
Create pathname-based hash-table lookup into index This creates a hash index of every single file added to the index. Right now that hash index isn't actually used for much: I implemented a "cache_name_exists()" function that uses it to efficiently look up a filename in the index without having to do the O(logn) binary search, but quite frankly, that's not why this patch is interesting. No, the whole and only reason to create the hash of the filenames in the index is that by modifying the hash function, you can fairly easily do things like making it always hash equivalent names into the same bucket. That, in turn, means that suddenly questions like "does this name exist in the index under an _equivalent_ name?" becomes much much cheaper. Guiding principles behind this patch: - it shouldn't be too costly. In fact, my primary goal here was to actually speed up "git commit" with a fully populated kernel tree, by being faster at checking whether a file already existed in the index. I did succeed, but only barely: Best before: [torvalds@woody linux]$ time git commit > /dev/null real 0m0.255s user 0m0.168s sys 0m0.088s Best after: [torvalds@woody linux]$ time ~/git/git commit > /dev/null real 0m0.233s user 0m0.144s sys 0m0.088s so some things are actually faster (~8%). Caveat: that's really the best case. Other things are invariably going to be slightly slower, since we populate that index cache, and quite frankly, few things really use it to look things up. That said, the cost is really quite small. The worst case is probably doing a "git ls-files", which will do very little except puopulate the index, and never actually looks anything up in it, just lists it. Before: [torvalds@woody linux]$ time git ls-files > /dev/null real 0m0.016s user 0m0.016s sys 0m0.000s After: [torvalds@woody linux]$ time ~/git/git ls-files > /dev/null real 0m0.021s user 0m0.012s sys 0m0.008s and while the thing has really gotten relatively much slower, we're still talking about something almost unmeasurable (eg 5ms). And that really should be pretty much the worst case. So we lose 5ms on one "benchmark", but win 22ms on another. Pick your poison - this patch has the advantage that it will _likely_ speed up the cases that are complex and expensive more than it slows down the cases that are already so fast that nobody cares. But if you look at relative speedups/slowdowns, it doesn't look so good. - It should be simple and clean The code may be a bit subtle (the reasons I do hash removal the way I do etc), but it re-uses the existing hash.c files, so it really is fairly small and straightforward apart from a few odd details. Now, this patch on its own doesn't really do much, but I think it's worth looking at, if only because if done correctly, the name hashing really can make an improvement to the whole issue of "do we have a filename that looks like this in the index already". And at least it gets real testing by being used even by default (ie there is a real use-case for it even without any insane filesystems). NOTE NOTE NOTE! The current hash is a joke. I'm ashamed of it, I'm just not ashamed of it enough to really care. I took all the numbers out of my nether regions - I'm sure it's good enough that it works in practice, but the whole point was that you can make a really much fancier hash that hashes characters not directly, but by their upper-case value or something like that, and thus you get a case-insensitive hash, while still keeping the name and the index itself totally case sensitive. Signed-off-by: Linus Torvalds <torvalds@linux-foundation.org> Signed-off-by: Junio C Hamano <gitster@pobox.com>
2008-01-23 03:41:14 +01:00
set_index_entry(istate, pos, ce);
istate->cache_changed |= CE_ENTRY_ADDED;
return 0;
}
/*
* "refresh" does not calculate a new sha1 file or bring the
* cache up-to-date for mode/content changes. But what it
* _does_ do is to "re-match" the stat information of a file
* with the cache, so that you can refresh the cache for a
* file that hasn't been changed but where the stat entry is
* out of date.
*
* For example, you'd want to do this after doing a "git-read-tree",
* to link up the stat cache details with the proper files.
*/
static struct cache_entry *refresh_cache_ent(struct index_state *istate,
struct cache_entry *ce,
unsigned int options, int *err,
int *changed_ret,
int *t2_did_lstat,
int *t2_did_scan)
{
struct stat st;
struct cache_entry *updated;
block alloc: add lifecycle APIs for cache_entry structs It has been observed that the time spent loading an index with a large number of entries is partly dominated by malloc() calls. This change is in preparation for using memory pools to reduce the number of malloc() calls made to allocate cahce entries when loading an index. Add an API to allocate and discard cache entries, abstracting the details of managing the memory backing the cache entries. This commit does actually change how memory is managed - this will be done in a later commit in the series. This change makes the distinction between cache entries that are associated with an index and cache entries that are not associated with an index. A main use of cache entries is with an index, and we can optimize the memory management around this. We still have other cases where a cache entry is not persisted with an index, and so we need to handle the "transient" use case as well. To keep the congnitive overhead of managing the cache entries, there will only be a single discard function. This means there must be enough information kept with the cache entry so that we know how to discard them. A summary of the main functions in the API is: make_cache_entry: create cache entry for use in an index. Uses specified parameters to populate cache_entry fields. make_empty_cache_entry: Create an empty cache entry for use in an index. Returns cache entry with empty fields. make_transient_cache_entry: create cache entry that is not used in an index. Uses specified parameters to populate cache_entry fields. make_empty_transient_cache_entry: create cache entry that is not used in an index. Returns cache entry with empty fields. discard_cache_entry: A single function that knows how to discard a cache entry regardless of how it was allocated. Signed-off-by: Jameson Miller <jamill@microsoft.com> Signed-off-by: Junio C Hamano <gitster@pobox.com>
2018-07-02 21:49:31 +02:00
int changed;
int refresh = options & CE_MATCH_REFRESH;
int ignore_valid = options & CE_MATCH_IGNORE_VALID;
int ignore_skip_worktree = options & CE_MATCH_IGNORE_SKIP_WORKTREE;
int ignore_missing = options & CE_MATCH_IGNORE_MISSING;
int ignore_fsmonitor = options & CE_MATCH_IGNORE_FSMONITOR;
if (!refresh || ce_uptodate(ce))
return ce;
if (!ignore_fsmonitor)
refresh_fsmonitor(istate);
/*
* CE_VALID or CE_SKIP_WORKTREE means the user promised us
* that the change to the work tree does not matter and told
* us not to worry.
*/
if (!ignore_skip_worktree && ce_skip_worktree(ce)) {
ce_mark_uptodate(ce);
return ce;
}
if (!ignore_valid && (ce->ce_flags & CE_VALID)) {
ce_mark_uptodate(ce);
return ce;
}
if (!ignore_fsmonitor && (ce->ce_flags & CE_FSMONITOR_VALID)) {
ce_mark_uptodate(ce);
return ce;
}
if (has_symlink_leading_path(ce->name, ce_namelen(ce))) {
if (ignore_missing)
return ce;
if (err)
*err = ENOENT;
return NULL;
}
if (t2_did_lstat)
*t2_did_lstat = 1;
if (lstat(ce->name, &st) < 0) {
if (ignore_missing && errno == ENOENT)
return ce;
if (err)
*err = errno;
return NULL;
}
changed = ie_match_stat(istate, ce, &st, options);
if (changed_ret)
*changed_ret = changed;
if (!changed) {
/*
* The path is unchanged. If we were told to ignore
* valid bit, then we did the actual stat check and
* found that the entry is unmodified. If the entry
* is not marked VALID, this is the place to mark it
* valid again, under "assume unchanged" mode.
*/
if (ignore_valid && assume_unchanged &&
!(ce->ce_flags & CE_VALID))
; /* mark this one VALID again */
else {
/*
* We do not mark the index itself "modified"
* because CE_UPTODATE flag is in-core only;
* we are not going to write this change out.
*/
if (!S_ISGITLINK(ce->ce_mode)) {
Make ce_uptodate() trustworthy again The rule has always been that a cache entry that is ce_uptodate(ce) means that we already have checked the work tree entity and we know there is no change in the work tree compared to the index, and nobody should have to double check. Note that false ce_uptodate(ce) does not mean it is known to be dirty---it only means we don't know if it is clean. There are a few codepaths (refresh-index and preload-index are among them) that mark a cache entry as up-to-date based solely on the return value from ie_match_stat(); this function uses lstat() to see if the work tree entity has been touched, and for a submodule entry, if its HEAD points at the same commit as the commit recorded in the index of the superproject (a submodule that is not even cloned is considered clean). A submodule is no longer considered unmodified merely because its HEAD matches the index of the superproject these days, in order to prevent people from forgetting to commit in the submodule and updating the superproject index with the new submodule commit, before commiting the state in the superproject. However, the patch to do so didn't update the codepath that marks cache entries up-to-date based on the updated definition and instead worked it around by saying "we don't trust the return value of ce_uptodate() for submodules." This makes ce_uptodate() trustworthy again by not marking submodule entries up-to-date. The next step _could_ be to introduce a few "in-core" flag bits to cache_entry structure to record "this entry is _known_ to be dirty", call is_submodule_modified() from ie_match_stat(), and use these new bits to avoid running this rather expensive check more than once, but that can be a separate patch. Signed-off-by: Junio C Hamano <gitster@pobox.com>
2010-01-24 09:10:20 +01:00
ce_mark_uptodate(ce);
mark_fsmonitor_valid(): mark the index as changed if needed Without this bug fix, t7519's four "status doesn't detect unreported modifications" test cases would fail occasionally (and, oddly enough, *a lot* more frequently on Windows). The reason is that these test cases intentionally use the side effect of `git status` to re-write the index if any updates were detected: they first clean the worktree, run `git status` to update the index as well as show the output to the casual reader, then make the worktree dirty again and expect no changes to reported if running with a mocked fsmonitor hook. The problem with this strategy was that the index was written during said `git status` on the clean worktree for the *wrong* reason: not because the index was marked as changed (it wasn't), but because the recorded mtimes were racy with the index' own mtime. As the mtime granularity on Windows is 100 nanoseconds (see e.g. https://docs.microsoft.com/en-us/windows/desktop/SysInfo/file-times), the mtimes of the files are often enough *not* racy with the index', so that that `git status` call currently does not always update the index (including the fsmonitor extension), causing the test case to fail. The obvious fix: if we change *any* index entry's `CE_FSMONITOR_VALID` flag, we should also mark the index as changed. That will cause the index to be written upon `git status`, *including* an updated fsmonitor extension. Side note: Even though the reader might think that the t7519 issue should be *much* more prevalent on Linux, given that the ext4 filesystem (that seems to be used by every Linux distribution) stores mtimes in nanosecond precision. However, ext4 uses `current_kernel_time()` (see https://unix.stackexchange.com/questions/11599#comment762968_11599; it is *amazingly* hard to find any proper source of information about such ext4 questions) whose accuracy seems to depend on many factors but is safely worse than the 100-nanosecond granularity of NTFS (again, it is *horribly* hard to find anything remotely authoritative about this question). So it seems that the racy index condition that hid the bug fixed by this patch simply is a lot more likely on Linux than on Windows. But not impossible ;-) Signed-off-by: Johannes Schindelin <johannes.schindelin@gmx.de> Signed-off-by: Junio C Hamano <gitster@pobox.com>
2019-05-24 14:23:48 +02:00
mark_fsmonitor_valid(istate, ce);
}
return ce;
}
}
if (t2_did_scan)
*t2_did_scan = 1;
if (ie_modified(istate, ce, &st, options)) {
if (err)
*err = EINVAL;
return NULL;
}
block alloc: add lifecycle APIs for cache_entry structs It has been observed that the time spent loading an index with a large number of entries is partly dominated by malloc() calls. This change is in preparation for using memory pools to reduce the number of malloc() calls made to allocate cahce entries when loading an index. Add an API to allocate and discard cache entries, abstracting the details of managing the memory backing the cache entries. This commit does actually change how memory is managed - this will be done in a later commit in the series. This change makes the distinction between cache entries that are associated with an index and cache entries that are not associated with an index. A main use of cache entries is with an index, and we can optimize the memory management around this. We still have other cases where a cache entry is not persisted with an index, and so we need to handle the "transient" use case as well. To keep the congnitive overhead of managing the cache entries, there will only be a single discard function. This means there must be enough information kept with the cache entry so that we know how to discard them. A summary of the main functions in the API is: make_cache_entry: create cache entry for use in an index. Uses specified parameters to populate cache_entry fields. make_empty_cache_entry: Create an empty cache entry for use in an index. Returns cache entry with empty fields. make_transient_cache_entry: create cache entry that is not used in an index. Uses specified parameters to populate cache_entry fields. make_empty_transient_cache_entry: create cache entry that is not used in an index. Returns cache entry with empty fields. discard_cache_entry: A single function that knows how to discard a cache entry regardless of how it was allocated. Signed-off-by: Jameson Miller <jamill@microsoft.com> Signed-off-by: Junio C Hamano <gitster@pobox.com>
2018-07-02 21:49:31 +02:00
updated = make_empty_cache_entry(istate, ce_namelen(ce));
copy_cache_entry(updated, ce);
memcpy(updated->name, ce->name, ce->ce_namelen + 1);
fill_stat_cache_info(istate, updated, &st);
/*
* If ignore_valid is not set, we should leave CE_VALID bit
* alone. Otherwise, paths marked with --no-assume-unchanged
* (i.e. things to be edited) will reacquire CE_VALID bit
* automatically, which is not really what we want.
*/
if (!ignore_valid && assume_unchanged &&
!(ce->ce_flags & CE_VALID))
updated->ce_flags &= ~CE_VALID;
/* istate->cache_changed is updated in the caller */
return updated;
}
static void show_file(const char * fmt, const char * name, int in_porcelain,
int * first, const char *header_msg)
{
if (in_porcelain && *first && header_msg) {
printf("%s\n", header_msg);
*first = 0;
}
printf(fmt, name);
}
int repo_refresh_and_write_index(struct repository *repo,
unsigned int refresh_flags,
unsigned int write_flags,
int gentle,
const struct pathspec *pathspec,
char *seen, const char *header_msg)
{
struct lock_file lock_file = LOCK_INIT;
int fd, ret = 0;
fd = repo_hold_locked_index(repo, &lock_file, 0);
if (!gentle && fd < 0)
return -1;
if (refresh_index(repo->index, refresh_flags, pathspec, seen, header_msg))
ret = 1;
if (0 <= fd && write_locked_index(repo->index, &lock_file, COMMIT_LOCK | write_flags))
ret = -1;
return ret;
}
int refresh_index(struct index_state *istate, unsigned int flags,
const struct pathspec *pathspec,
char *seen, const char *header_msg)
{
int i;
int has_errors = 0;
int really = (flags & REFRESH_REALLY) != 0;
int allow_unmerged = (flags & REFRESH_UNMERGED) != 0;
int quiet = (flags & REFRESH_QUIET) != 0;
int not_new = (flags & REFRESH_IGNORE_MISSING) != 0;
int ignore_submodules = (flags & REFRESH_IGNORE_SUBMODULES) != 0;
int ignore_skip_worktree = (flags & REFRESH_IGNORE_SKIP_WORKTREE) != 0;
int first = 1;
int in_porcelain = (flags & REFRESH_IN_PORCELAIN);
unsigned int options = (CE_MATCH_REFRESH |
(really ? CE_MATCH_IGNORE_VALID : 0) |
(not_new ? CE_MATCH_IGNORE_MISSING : 0));
const char *modified_fmt;
const char *deleted_fmt;
const char *typechange_fmt;
const char *added_fmt;
const char *unmerged_fmt;
struct progress *progress = NULL;
int t2_sum_lstat = 0;
int t2_sum_scan = 0;
if (flags & REFRESH_PROGRESS && isatty(2))
progress = start_delayed_progress(_("Refresh index"),
istate->cache_nr);
trace_performance_enter();
modified_fmt = in_porcelain ? "M\t%s\n" : "%s: needs update\n";
deleted_fmt = in_porcelain ? "D\t%s\n" : "%s: needs update\n";
typechange_fmt = in_porcelain ? "T\t%s\n" : "%s: needs update\n";
added_fmt = in_porcelain ? "A\t%s\n" : "%s: needs update\n";
unmerged_fmt = in_porcelain ? "U\t%s\n" : "%s: needs merge\n";
/*
* Use the multi-threaded preload_index() to refresh most of the
* cache entries quickly then in the single threaded loop below,
* we only have to do the special cases that are left.
*/
preload_index(istate, pathspec, 0);
trace2_region_enter("index", "refresh", NULL);
status: use sparse-index throughout By testing 'git -c core.fsmonitor= status -uno', we can check for the simplest index operations that can be made sparse-aware. The necessary implementation details are already integrated with sparse-checkout, so modify command_requires_full_index to be zero for cmd_status(). In refresh_index(), we loop through the index entries to refresh their stat() information. However, sparse directories have no stat() information to populate. Ignore these entries. This allows 'git status' to no longer expand a sparse index to a full one. This is further tested by dropping the "-uno" option and adding an untracked file into the worktree. The performance test p2000-sparse-checkout-operations.sh demonstrates these improvements: Test HEAD~1 HEAD ----------------------------------------------------------------------------- 2000.2: git status (full-index-v3) 0.31(0.30+0.05) 0.31(0.29+0.06) +0.0% 2000.3: git status (full-index-v4) 0.31(0.29+0.07) 0.34(0.30+0.08) +9.7% 2000.4: git status (sparse-index-v3) 2.35(2.28+0.10) 0.04(0.04+0.05) -98.3% 2000.5: git status (sparse-index-v4) 2.35(2.24+0.15) 0.05(0.04+0.06) -97.9% Note that since HEAD~1 was expanding the sparse index by parsing trees, it was artificially slower than the full index case. Thus, the 98% improvement is misleading, and instead we should celebrate the 0.34s to 0.05s improvement of 85%. This is more indicative of the peformance gains we are expecting by using a sparse index. Note: we are dropping the assignment of core.fsmonitor here. This is not necessary for the test script as we are not altering the config any other way. Correct integration with FS Monitor will be validated in later changes. Reviewed-by: Elijah Newren <newren@gmail.com> Signed-off-by: Derrick Stolee <dstolee@microsoft.com> Signed-off-by: Junio C Hamano <gitster@pobox.com>
2021-07-14 15:12:37 +02:00
for (i = 0; i < istate->cache_nr; i++) {
struct cache_entry *ce, *new_entry;
int cache_errno = 0;
int changed = 0;
int filtered = 0;
int t2_did_lstat = 0;
int t2_did_scan = 0;
ce = istate->cache[i];
if (ignore_submodules && S_ISGITLINK(ce->ce_mode))
continue;
if (ignore_skip_worktree && ce_skip_worktree(ce))
continue;
status: use sparse-index throughout By testing 'git -c core.fsmonitor= status -uno', we can check for the simplest index operations that can be made sparse-aware. The necessary implementation details are already integrated with sparse-checkout, so modify command_requires_full_index to be zero for cmd_status(). In refresh_index(), we loop through the index entries to refresh their stat() information. However, sparse directories have no stat() information to populate. Ignore these entries. This allows 'git status' to no longer expand a sparse index to a full one. This is further tested by dropping the "-uno" option and adding an untracked file into the worktree. The performance test p2000-sparse-checkout-operations.sh demonstrates these improvements: Test HEAD~1 HEAD ----------------------------------------------------------------------------- 2000.2: git status (full-index-v3) 0.31(0.30+0.05) 0.31(0.29+0.06) +0.0% 2000.3: git status (full-index-v4) 0.31(0.29+0.07) 0.34(0.30+0.08) +9.7% 2000.4: git status (sparse-index-v3) 2.35(2.28+0.10) 0.04(0.04+0.05) -98.3% 2000.5: git status (sparse-index-v4) 2.35(2.24+0.15) 0.05(0.04+0.06) -97.9% Note that since HEAD~1 was expanding the sparse index by parsing trees, it was artificially slower than the full index case. Thus, the 98% improvement is misleading, and instead we should celebrate the 0.34s to 0.05s improvement of 85%. This is more indicative of the peformance gains we are expecting by using a sparse index. Note: we are dropping the assignment of core.fsmonitor here. This is not necessary for the test script as we are not altering the config any other way. Correct integration with FS Monitor will be validated in later changes. Reviewed-by: Elijah Newren <newren@gmail.com> Signed-off-by: Derrick Stolee <dstolee@microsoft.com> Signed-off-by: Junio C Hamano <gitster@pobox.com>
2021-07-14 15:12:37 +02:00
/*
* If this entry is a sparse directory, then there isn't
* any stat() information to update. Ignore the entry.
*/
if (S_ISSPARSEDIR(ce->ce_mode))
continue;
if (pathspec && !ce_path_match(istate, ce, pathspec, seen))
filtered = 1;
if (ce_stage(ce)) {
while ((i < istate->cache_nr) &&
! strcmp(istate->cache[i]->name, ce->name))
i++;
i--;
if (allow_unmerged)
continue;
if (!filtered)
show_file(unmerged_fmt, ce->name, in_porcelain,
&first, header_msg);
has_errors = 1;
continue;
}
if (filtered)
continue;
new_entry = refresh_cache_ent(istate, ce, options,
&cache_errno, &changed,
&t2_did_lstat, &t2_did_scan);
t2_sum_lstat += t2_did_lstat;
t2_sum_scan += t2_did_scan;
if (new_entry == ce)
continue;
display_progress(progress, i);
if (!new_entry) {
const char *fmt;
if (really && cache_errno == EINVAL) {
/* If we are doing --really-refresh that
* means the index is not valid anymore.
*/
ce->ce_flags &= ~CE_VALID;
ce->ce_flags |= CE_UPDATE_IN_BASE;
mark_fsmonitor_invalid(istate, ce);
istate->cache_changed |= CE_ENTRY_CHANGED;
}
if (quiet)
continue;
if (cache_errno == ENOENT)
fmt = deleted_fmt;
else if (ce_intent_to_add(ce))
fmt = added_fmt; /* must be before other checks */
else if (changed & TYPE_CHANGED)
fmt = typechange_fmt;
else
fmt = modified_fmt;
show_file(fmt,
ce->name, in_porcelain, &first, header_msg);
has_errors = 1;
continue;
}
Create pathname-based hash-table lookup into index This creates a hash index of every single file added to the index. Right now that hash index isn't actually used for much: I implemented a "cache_name_exists()" function that uses it to efficiently look up a filename in the index without having to do the O(logn) binary search, but quite frankly, that's not why this patch is interesting. No, the whole and only reason to create the hash of the filenames in the index is that by modifying the hash function, you can fairly easily do things like making it always hash equivalent names into the same bucket. That, in turn, means that suddenly questions like "does this name exist in the index under an _equivalent_ name?" becomes much much cheaper. Guiding principles behind this patch: - it shouldn't be too costly. In fact, my primary goal here was to actually speed up "git commit" with a fully populated kernel tree, by being faster at checking whether a file already existed in the index. I did succeed, but only barely: Best before: [torvalds@woody linux]$ time git commit > /dev/null real 0m0.255s user 0m0.168s sys 0m0.088s Best after: [torvalds@woody linux]$ time ~/git/git commit > /dev/null real 0m0.233s user 0m0.144s sys 0m0.088s so some things are actually faster (~8%). Caveat: that's really the best case. Other things are invariably going to be slightly slower, since we populate that index cache, and quite frankly, few things really use it to look things up. That said, the cost is really quite small. The worst case is probably doing a "git ls-files", which will do very little except puopulate the index, and never actually looks anything up in it, just lists it. Before: [torvalds@woody linux]$ time git ls-files > /dev/null real 0m0.016s user 0m0.016s sys 0m0.000s After: [torvalds@woody linux]$ time ~/git/git ls-files > /dev/null real 0m0.021s user 0m0.012s sys 0m0.008s and while the thing has really gotten relatively much slower, we're still talking about something almost unmeasurable (eg 5ms). And that really should be pretty much the worst case. So we lose 5ms on one "benchmark", but win 22ms on another. Pick your poison - this patch has the advantage that it will _likely_ speed up the cases that are complex and expensive more than it slows down the cases that are already so fast that nobody cares. But if you look at relative speedups/slowdowns, it doesn't look so good. - It should be simple and clean The code may be a bit subtle (the reasons I do hash removal the way I do etc), but it re-uses the existing hash.c files, so it really is fairly small and straightforward apart from a few odd details. Now, this patch on its own doesn't really do much, but I think it's worth looking at, if only because if done correctly, the name hashing really can make an improvement to the whole issue of "do we have a filename that looks like this in the index already". And at least it gets real testing by being used even by default (ie there is a real use-case for it even without any insane filesystems). NOTE NOTE NOTE! The current hash is a joke. I'm ashamed of it, I'm just not ashamed of it enough to really care. I took all the numbers out of my nether regions - I'm sure it's good enough that it works in practice, but the whole point was that you can make a really much fancier hash that hashes characters not directly, but by their upper-case value or something like that, and thus you get a case-insensitive hash, while still keeping the name and the index itself totally case sensitive. Signed-off-by: Linus Torvalds <torvalds@linux-foundation.org> Signed-off-by: Junio C Hamano <gitster@pobox.com>
2008-01-23 03:41:14 +01:00
replace_index_entry(istate, i, new_entry);
}
trace2_data_intmax("index", NULL, "refresh/sum_lstat", t2_sum_lstat);
trace2_data_intmax("index", NULL, "refresh/sum_scan", t2_sum_scan);
trace2_region_leave("index", "refresh", NULL);
display_progress(progress, istate->cache_nr);
stop_progress(&progress);
trace_performance_leave("refresh index");
return has_errors;
}
struct cache_entry *refresh_cache_entry(struct index_state *istate,
struct cache_entry *ce,
unsigned int options)
{
return refresh_cache_ent(istate, ce, options, NULL, NULL, NULL, NULL);
}
/*****************************************************************
* Index File I/O
*****************************************************************/
#define INDEX_FORMAT_DEFAULT 3
static unsigned int get_index_format_default(struct repository *r)
{
char *envversion = getenv("GIT_INDEX_VERSION");
char *endp;
unsigned int version = INDEX_FORMAT_DEFAULT;
if (!envversion) {
prepare_repo_settings(r);
if (r->settings.index_version >= 0)
version = r->settings.index_version;
if (version < INDEX_FORMAT_LB || INDEX_FORMAT_UB < version) {
warning(_("index.version set, but the value is invalid.\n"
"Using version %i"), INDEX_FORMAT_DEFAULT);
return INDEX_FORMAT_DEFAULT;
}
return version;
}
version = strtoul(envversion, &endp, 10);
if (*endp ||
version < INDEX_FORMAT_LB || INDEX_FORMAT_UB < version) {
warning(_("GIT_INDEX_VERSION set, but the value is invalid.\n"
"Using version %i"), INDEX_FORMAT_DEFAULT);
version = INDEX_FORMAT_DEFAULT;
}
return version;
}
/*
* dev/ino/uid/gid/size are also just tracked to the low 32 bits
* Again - this is just a (very strong in practice) heuristic that
* the inode hasn't changed.
*
* We save the fields in big-endian order to allow using the
* index file over NFS transparently.
*/
struct ondisk_cache_entry {
struct cache_time ctime;
struct cache_time mtime;
uint32_t dev;
uint32_t ino;
uint32_t mode;
uint32_t uid;
uint32_t gid;
uint32_t size;
/*
* unsigned char hash[hashsz];
* uint16_t flags;
* if (flags & CE_EXTENDED)
* uint16_t flags2;
*/
unsigned char data[GIT_MAX_RAWSZ + 2 * sizeof(uint16_t)];
char name[FLEX_ARRAY];
};
/* These are only used for v3 or lower */
#define align_padding_size(size, len) ((size + (len) + 8) & ~7) - (size + len)
#define align_flex_name(STRUCT,len) ((offsetof(struct STRUCT,data) + (len) + 8) & ~7)
#define ondisk_cache_entry_size(len) align_flex_name(ondisk_cache_entry,len)
#define ondisk_data_size(flags, len) (the_hash_algo->rawsz + \
((flags & CE_EXTENDED) ? 2 : 1) * sizeof(uint16_t) + len)
#define ondisk_data_size_max(len) (ondisk_data_size(CE_EXTENDED, len))
#define ondisk_ce_size(ce) (ondisk_cache_entry_size(ondisk_data_size((ce)->ce_flags, ce_namelen(ce))))
/* Allow fsck to force verification of the index checksum. */
int verify_index_checksum;
/* Allow fsck to force verification of the cache entry order. */
int verify_ce_order;
static int verify_hdr(const struct cache_header *hdr, unsigned long size)
{
git_hash_ctx c;
unsigned char hash[GIT_MAX_RAWSZ];
int hdr_version;
if (hdr->hdr_signature != htonl(CACHE_SIGNATURE))
return error(_("bad signature 0x%08x"), hdr->hdr_signature);
hdr_version = ntohl(hdr->hdr_version);
if (hdr_version < INDEX_FORMAT_LB || INDEX_FORMAT_UB < hdr_version)
return error(_("bad index version %d"), hdr_version);
if (!verify_index_checksum)
return 0;
the_hash_algo->init_fn(&c);
the_hash_algo->update_fn(&c, hdr, size - the_hash_algo->rawsz);
the_hash_algo->final_fn(hash, &c);
if (!hasheq(hash, (unsigned char *)hdr + size - the_hash_algo->rawsz))
return error(_("bad index file sha1 signature"));
return 0;
}
static int read_index_extension(struct index_state *istate,
const char *ext, const char *data, unsigned long sz)
{
switch (CACHE_EXT(ext)) {
case CACHE_EXT_TREE:
istate->cache_tree = cache_tree_read(data, sz);
break;
case CACHE_EXT_RESOLVE_UNDO:
istate->resolve_undo = resolve_undo_read(data, sz);
break;
case CACHE_EXT_LINK:
if (read_link_extension(istate, data, sz))
return -1;
break;
case CACHE_EXT_UNTRACKED:
istate->untracked = read_untracked_extension(data, sz);
break;
case CACHE_EXT_FSMONITOR:
read_fsmonitor_extension(istate, data, sz);
break;
case CACHE_EXT_ENDOFINDEXENTRIES:
case CACHE_EXT_INDEXENTRYOFFSETTABLE:
/* already handled in do_read_index() */
break;
case CACHE_EXT_SPARSE_DIRECTORIES:
/* no content, only an indicator */
istate->sparse_index = 1;
break;
default:
if (*ext < 'A' || 'Z' < *ext)
return error(_("index uses %.4s extension, which we do not understand"),
ext);
fprintf_ln(stderr, _("ignoring %.4s extension"), ext);
break;
}
return 0;
}
static struct cache_entry *create_from_disk(struct mem_pool *ce_mem_pool,
unsigned int version,
block alloc: add lifecycle APIs for cache_entry structs It has been observed that the time spent loading an index with a large number of entries is partly dominated by malloc() calls. This change is in preparation for using memory pools to reduce the number of malloc() calls made to allocate cahce entries when loading an index. Add an API to allocate and discard cache entries, abstracting the details of managing the memory backing the cache entries. This commit does actually change how memory is managed - this will be done in a later commit in the series. This change makes the distinction between cache entries that are associated with an index and cache entries that are not associated with an index. A main use of cache entries is with an index, and we can optimize the memory management around this. We still have other cases where a cache entry is not persisted with an index, and so we need to handle the "transient" use case as well. To keep the congnitive overhead of managing the cache entries, there will only be a single discard function. This means there must be enough information kept with the cache entry so that we know how to discard them. A summary of the main functions in the API is: make_cache_entry: create cache entry for use in an index. Uses specified parameters to populate cache_entry fields. make_empty_cache_entry: Create an empty cache entry for use in an index. Returns cache entry with empty fields. make_transient_cache_entry: create cache entry that is not used in an index. Uses specified parameters to populate cache_entry fields. make_empty_transient_cache_entry: create cache entry that is not used in an index. Returns cache entry with empty fields. discard_cache_entry: A single function that knows how to discard a cache entry regardless of how it was allocated. Signed-off-by: Jameson Miller <jamill@microsoft.com> Signed-off-by: Junio C Hamano <gitster@pobox.com>
2018-07-02 21:49:31 +02:00
struct ondisk_cache_entry *ondisk,
unsigned long *ent_size,
const struct cache_entry *previous_ce)
{
struct cache_entry *ce;
size_t len;
const char *name;
const unsigned hashsz = the_hash_algo->rawsz;
const uint16_t *flagsp = (const uint16_t *)(ondisk->data + hashsz);
unsigned int flags;
size_t copy_len = 0;
/*
* Adjacent cache entries tend to share the leading paths, so it makes
* sense to only store the differences in later entries. In the v4
* on-disk format of the index, each on-disk cache entry stores the
* number of bytes to be stripped from the end of the previous name,
* and the bytes to append to the result, to come up with its name.
*/
int expand_name_field = version == 4;
/* On-disk flags are just 16 bits */
flags = get_be16(flagsp);
len = flags & CE_NAMEMASK;
if (flags & CE_EXTENDED) {
int extended_flags;
extended_flags = get_be16(flagsp + 1) << 16;
/* We do not yet understand any bit out of CE_EXTENDED_FLAGS */
if (extended_flags & ~CE_EXTENDED_FLAGS)
die(_("unknown index entry format 0x%08x"), extended_flags);
flags |= extended_flags;
name = (const char *)(flagsp + 2);
}
else
name = (const char *)(flagsp + 1);
if (expand_name_field) {
const unsigned char *cp = (const unsigned char *)name;
size_t strip_len, previous_len;
/* If we're at the beginning of a block, ignore the previous name */
strip_len = decode_varint(&cp);
if (previous_ce) {
previous_len = previous_ce->ce_namelen;
if (previous_len < strip_len)
die(_("malformed name field in the index, near path '%s'"),
previous_ce->name);
copy_len = previous_len - strip_len;
}
name = (const char *)cp;
}
if (len == CE_NAMEMASK) {
len = strlen(name);
if (expand_name_field)
len += copy_len;
}
ce = mem_pool__ce_alloc(ce_mem_pool, len);
ce->ce_stat_data.sd_ctime.sec = get_be32(&ondisk->ctime.sec);
ce->ce_stat_data.sd_mtime.sec = get_be32(&ondisk->mtime.sec);
ce->ce_stat_data.sd_ctime.nsec = get_be32(&ondisk->ctime.nsec);
ce->ce_stat_data.sd_mtime.nsec = get_be32(&ondisk->mtime.nsec);
ce->ce_stat_data.sd_dev = get_be32(&ondisk->dev);
ce->ce_stat_data.sd_ino = get_be32(&ondisk->ino);
ce->ce_mode = get_be32(&ondisk->mode);
ce->ce_stat_data.sd_uid = get_be32(&ondisk->uid);
ce->ce_stat_data.sd_gid = get_be32(&ondisk->gid);
ce->ce_stat_data.sd_size = get_be32(&ondisk->size);
ce->ce_flags = flags & ~CE_NAMEMASK;
ce->ce_namelen = len;
ce->index = 0;
oidread(&ce->oid, ondisk->data);
memcpy(ce->name, name, len);
ce->name[len] = '\0';
if (expand_name_field) {
if (copy_len)
memcpy(ce->name, previous_ce->name, copy_len);
memcpy(ce->name + copy_len, name, len + 1 - copy_len);
*ent_size = (name - ((char *)ondisk)) + len + 1 - copy_len;
} else {
memcpy(ce->name, name, len + 1);
*ent_size = ondisk_ce_size(ce);
}
return ce;
Create pathname-based hash-table lookup into index This creates a hash index of every single file added to the index. Right now that hash index isn't actually used for much: I implemented a "cache_name_exists()" function that uses it to efficiently look up a filename in the index without having to do the O(logn) binary search, but quite frankly, that's not why this patch is interesting. No, the whole and only reason to create the hash of the filenames in the index is that by modifying the hash function, you can fairly easily do things like making it always hash equivalent names into the same bucket. That, in turn, means that suddenly questions like "does this name exist in the index under an _equivalent_ name?" becomes much much cheaper. Guiding principles behind this patch: - it shouldn't be too costly. In fact, my primary goal here was to actually speed up "git commit" with a fully populated kernel tree, by being faster at checking whether a file already existed in the index. I did succeed, but only barely: Best before: [torvalds@woody linux]$ time git commit > /dev/null real 0m0.255s user 0m0.168s sys 0m0.088s Best after: [torvalds@woody linux]$ time ~/git/git commit > /dev/null real 0m0.233s user 0m0.144s sys 0m0.088s so some things are actually faster (~8%). Caveat: that's really the best case. Other things are invariably going to be slightly slower, since we populate that index cache, and quite frankly, few things really use it to look things up. That said, the cost is really quite small. The worst case is probably doing a "git ls-files", which will do very little except puopulate the index, and never actually looks anything up in it, just lists it. Before: [torvalds@woody linux]$ time git ls-files > /dev/null real 0m0.016s user 0m0.016s sys 0m0.000s After: [torvalds@woody linux]$ time ~/git/git ls-files > /dev/null real 0m0.021s user 0m0.012s sys 0m0.008s and while the thing has really gotten relatively much slower, we're still talking about something almost unmeasurable (eg 5ms). And that really should be pretty much the worst case. So we lose 5ms on one "benchmark", but win 22ms on another. Pick your poison - this patch has the advantage that it will _likely_ speed up the cases that are complex and expensive more than it slows down the cases that are already so fast that nobody cares. But if you look at relative speedups/slowdowns, it doesn't look so good. - It should be simple and clean The code may be a bit subtle (the reasons I do hash removal the way I do etc), but it re-uses the existing hash.c files, so it really is fairly small and straightforward apart from a few odd details. Now, this patch on its own doesn't really do much, but I think it's worth looking at, if only because if done correctly, the name hashing really can make an improvement to the whole issue of "do we have a filename that looks like this in the index already". And at least it gets real testing by being used even by default (ie there is a real use-case for it even without any insane filesystems). NOTE NOTE NOTE! The current hash is a joke. I'm ashamed of it, I'm just not ashamed of it enough to really care. I took all the numbers out of my nether regions - I'm sure it's good enough that it works in practice, but the whole point was that you can make a really much fancier hash that hashes characters not directly, but by their upper-case value or something like that, and thus you get a case-insensitive hash, while still keeping the name and the index itself totally case sensitive. Signed-off-by: Linus Torvalds <torvalds@linux-foundation.org> Signed-off-by: Junio C Hamano <gitster@pobox.com>
2008-01-23 03:41:14 +01:00
}
static void check_ce_order(struct index_state *istate)
{
unsigned int i;
if (!verify_ce_order)
return;
for (i = 1; i < istate->cache_nr; i++) {
struct cache_entry *ce = istate->cache[i - 1];
struct cache_entry *next_ce = istate->cache[i];
int name_compare = strcmp(ce->name, next_ce->name);
if (0 < name_compare)
die(_("unordered stage entries in index"));
if (!name_compare) {
if (!ce_stage(ce))
die(_("multiple stage entries for merged file '%s'"),
ce->name);
if (ce_stage(ce) > ce_stage(next_ce))
die(_("unordered stage entries for '%s'"),
ce->name);
}
}
}
config: add core.untrackedCache When we know that mtime on directory as given by the environment is usable for the purpose of untracked cache, we may want the untracked cache to be always used without any mtime test or kernel name check being performed. Also when we know that mtime is not usable for the purpose of untracked cache, for example because the repo is shared over a network file system, we may want the untracked-cache to be automatically removed from the index. Allow the user to express such preference by setting the 'core.untrackedCache' configuration variable, which can take 'keep', 'false', or 'true' and default to 'keep'. When read_index_from() is called, it now adds or removes the untracked cache in the index to respect the value of this variable. So it does nothing if the value is `keep` or if the variable is unset; it adds the untracked cache if the value is `true`; and it removes the cache if the value is `false`. `git update-index --[no-|force-]untracked-cache` still adds the untracked cache to, or removes it, from the index, but this shows a warning if it goes against the value of core.untrackedCache, because the next time the index is read the untracked cache will be added or removed if the configuration is set to do so. Also `--untracked-cache` used to check that the underlying operating system and file system change `st_mtime` field of a directory if files are added or deleted in that directory. But because those tests take a long time, `--untracked-cache` no longer performs them. Instead, there is now `--test-untracked-cache` to perform the tests. This change makes `--untracked-cache` the same as `--force-untracked-cache`. This last change is backward incompatible and should be mentioned in the release notes. Helped-by: Duy Nguyen <pclouds@gmail.com> Helped-by: Torsten Bögershausen <tboegi@web.de> Helped-by: Stefan Beller <sbeller@google.com> Signed-off-by: Christian Couder <chriscool@tuxfamily.org> Signed-off-by: Ævar Arnfjörð Bjarmason <avarab@gmail.com> read-cache: Duy'sfixup Signed-off-by: Christian Couder <chriscool@tuxfamily.org> Signed-off-by: Junio C Hamano <gitster@pobox.com>
2016-01-27 07:58:05 +01:00
static void tweak_untracked_cache(struct index_state *istate)
{
struct repository *r = the_repository;
prepare_repo_settings(r);
switch (r->settings.core_untracked_cache) {
case UNTRACKED_CACHE_REMOVE:
config: add core.untrackedCache When we know that mtime on directory as given by the environment is usable for the purpose of untracked cache, we may want the untracked cache to be always used without any mtime test or kernel name check being performed. Also when we know that mtime is not usable for the purpose of untracked cache, for example because the repo is shared over a network file system, we may want the untracked-cache to be automatically removed from the index. Allow the user to express such preference by setting the 'core.untrackedCache' configuration variable, which can take 'keep', 'false', or 'true' and default to 'keep'. When read_index_from() is called, it now adds or removes the untracked cache in the index to respect the value of this variable. So it does nothing if the value is `keep` or if the variable is unset; it adds the untracked cache if the value is `true`; and it removes the cache if the value is `false`. `git update-index --[no-|force-]untracked-cache` still adds the untracked cache to, or removes it, from the index, but this shows a warning if it goes against the value of core.untrackedCache, because the next time the index is read the untracked cache will be added or removed if the configuration is set to do so. Also `--untracked-cache` used to check that the underlying operating system and file system change `st_mtime` field of a directory if files are added or deleted in that directory. But because those tests take a long time, `--untracked-cache` no longer performs them. Instead, there is now `--test-untracked-cache` to perform the tests. This change makes `--untracked-cache` the same as `--force-untracked-cache`. This last change is backward incompatible and should be mentioned in the release notes. Helped-by: Duy Nguyen <pclouds@gmail.com> Helped-by: Torsten Bögershausen <tboegi@web.de> Helped-by: Stefan Beller <sbeller@google.com> Signed-off-by: Christian Couder <chriscool@tuxfamily.org> Signed-off-by: Ævar Arnfjörð Bjarmason <avarab@gmail.com> read-cache: Duy'sfixup Signed-off-by: Christian Couder <chriscool@tuxfamily.org> Signed-off-by: Junio C Hamano <gitster@pobox.com>
2016-01-27 07:58:05 +01:00
remove_untracked_cache(istate);
break;
case UNTRACKED_CACHE_WRITE:
add_untracked_cache(istate);
break;
case UNTRACKED_CACHE_KEEP:
repo-settings.c: simplify the setup Simplify the setup code in repo-settings.c in various ways, making the code shorter, easier to read, and requiring fewer hacks to do the same thing as it did before: Since 7211b9e7534 (repo-settings: consolidate some config settings, 2019-08-13) we have memset() the whole "settings" structure to -1 in prepare_repo_settings(), and subsequently relied on the -1 value. Most of the fields did not need to be initialized to -1, and because we were doing that we had the enum labels "UNTRACKED_CACHE_UNSET" and "FETCH_NEGOTIATION_UNSET" purely to reflect the resulting state created this memset() in prepare_repo_settings(). No other code used or relied on them, more on that below. For the rest most of the subsequent "are we -1, then read xyz" can simply be removed by re-arranging what we read first. E.g. when setting the "index.version" setting we should have first read "feature.experimental", so that it (and "feature.manyfiles") can provide a default for our "index.version". Instead the code setting it, added when "feature.manyFiles"[1] was created, was using the UPDATE_DEFAULT_BOOL() macro added in an earlier commit[2]. That macro is now gone, since it was only needed for this pattern of reading things in the wrong order. This also fixes an (admittedly obscure) logic error where we'd conflate an explicit "-1" value in the config with our own earlier memset() -1. We can also remove the UPDATE_DEFAULT_BOOL() wrapper added in [3]. Using it is redundant to simply using the return value from repo_config_get_bool(), which is non-zero if the provided key exists in the config. Details on edge cases relating to the memset() to -1, continued from "more on that below" above: * UNTRACKED_CACHE_KEEP: In [4] the "unset" and "keep" handling for core.untrackedCache was consolidated. But it while we understand the "keep" value, we don't handle it differently than the case of any other unknown value. So let's retain UNTRACKED_CACHE_KEEP and remove the UNTRACKED_CACHE_UNSET setting (which was always implicitly UNTRACKED_CACHE_KEEP before). We don't need to inform any code after prepare_repo_settings() that the setting was "unset", as far as anyone else is concerned it's core.untrackedCache=keep. if "core.untrackedcache" isn't present in the config. * FETCH_NEGOTIATION_UNSET & FETCH_NEGOTIATION_NONE: Since these two two enum fields added in [5] don't rely on the memzero() setting them to "-1" anymore we don't have to provide them with explicit values. 1. c6cc4c5afd2 (repo-settings: create feature.manyFiles setting, 2019-08-13) 2. 31b1de6a09b (commit-graph: turn on commit-graph by default, 2019-08-13) 3. 31b1de6a09b (commit-graph: turn on commit-graph by default, 2019-08-13) 4. ad0fb659993 (repo-settings: parse core.untrackedCache, 2019-08-13) 5. aaf633c2ad1 (repo-settings: create feature.experimental setting, 2019-08-13) Signed-off-by: Ævar Arnfjörð Bjarmason <avarab@gmail.com> Signed-off-by: Junio C Hamano <gitster@pobox.com>
2021-09-21 15:13:02 +02:00
/*
* Either an explicit "core.untrackedCache=keep", the
* default if "core.untrackedCache" isn't configured,
* or a fallback on an unknown "core.untrackedCache"
* value.
*/
break;
}
config: add core.untrackedCache When we know that mtime on directory as given by the environment is usable for the purpose of untracked cache, we may want the untracked cache to be always used without any mtime test or kernel name check being performed. Also when we know that mtime is not usable for the purpose of untracked cache, for example because the repo is shared over a network file system, we may want the untracked-cache to be automatically removed from the index. Allow the user to express such preference by setting the 'core.untrackedCache' configuration variable, which can take 'keep', 'false', or 'true' and default to 'keep'. When read_index_from() is called, it now adds or removes the untracked cache in the index to respect the value of this variable. So it does nothing if the value is `keep` or if the variable is unset; it adds the untracked cache if the value is `true`; and it removes the cache if the value is `false`. `git update-index --[no-|force-]untracked-cache` still adds the untracked cache to, or removes it, from the index, but this shows a warning if it goes against the value of core.untrackedCache, because the next time the index is read the untracked cache will be added or removed if the configuration is set to do so. Also `--untracked-cache` used to check that the underlying operating system and file system change `st_mtime` field of a directory if files are added or deleted in that directory. But because those tests take a long time, `--untracked-cache` no longer performs them. Instead, there is now `--test-untracked-cache` to perform the tests. This change makes `--untracked-cache` the same as `--force-untracked-cache`. This last change is backward incompatible and should be mentioned in the release notes. Helped-by: Duy Nguyen <pclouds@gmail.com> Helped-by: Torsten Bögershausen <tboegi@web.de> Helped-by: Stefan Beller <sbeller@google.com> Signed-off-by: Christian Couder <chriscool@tuxfamily.org> Signed-off-by: Ævar Arnfjörð Bjarmason <avarab@gmail.com> read-cache: Duy'sfixup Signed-off-by: Christian Couder <chriscool@tuxfamily.org> Signed-off-by: Junio C Hamano <gitster@pobox.com>
2016-01-27 07:58:05 +01:00
}
static void tweak_split_index(struct index_state *istate)
{
switch (git_config_get_split_index()) {
case -1: /* unset: do nothing */
break;
case 0: /* false */
remove_split_index(istate);
break;
case 1: /* true */
add_split_index(istate);
break;
default: /* unknown value: do nothing */
break;
}
}
config: add core.untrackedCache When we know that mtime on directory as given by the environment is usable for the purpose of untracked cache, we may want the untracked cache to be always used without any mtime test or kernel name check being performed. Also when we know that mtime is not usable for the purpose of untracked cache, for example because the repo is shared over a network file system, we may want the untracked-cache to be automatically removed from the index. Allow the user to express such preference by setting the 'core.untrackedCache' configuration variable, which can take 'keep', 'false', or 'true' and default to 'keep'. When read_index_from() is called, it now adds or removes the untracked cache in the index to respect the value of this variable. So it does nothing if the value is `keep` or if the variable is unset; it adds the untracked cache if the value is `true`; and it removes the cache if the value is `false`. `git update-index --[no-|force-]untracked-cache` still adds the untracked cache to, or removes it, from the index, but this shows a warning if it goes against the value of core.untrackedCache, because the next time the index is read the untracked cache will be added or removed if the configuration is set to do so. Also `--untracked-cache` used to check that the underlying operating system and file system change `st_mtime` field of a directory if files are added or deleted in that directory. But because those tests take a long time, `--untracked-cache` no longer performs them. Instead, there is now `--test-untracked-cache` to perform the tests. This change makes `--untracked-cache` the same as `--force-untracked-cache`. This last change is backward incompatible and should be mentioned in the release notes. Helped-by: Duy Nguyen <pclouds@gmail.com> Helped-by: Torsten Bögershausen <tboegi@web.de> Helped-by: Stefan Beller <sbeller@google.com> Signed-off-by: Christian Couder <chriscool@tuxfamily.org> Signed-off-by: Ævar Arnfjörð Bjarmason <avarab@gmail.com> read-cache: Duy'sfixup Signed-off-by: Christian Couder <chriscool@tuxfamily.org> Signed-off-by: Junio C Hamano <gitster@pobox.com>
2016-01-27 07:58:05 +01:00
static void post_read_index_from(struct index_state *istate)
{
check_ce_order(istate);
tweak_untracked_cache(istate);
tweak_split_index(istate);
tweak_fsmonitor(istate);
config: add core.untrackedCache When we know that mtime on directory as given by the environment is usable for the purpose of untracked cache, we may want the untracked cache to be always used without any mtime test or kernel name check being performed. Also when we know that mtime is not usable for the purpose of untracked cache, for example because the repo is shared over a network file system, we may want the untracked-cache to be automatically removed from the index. Allow the user to express such preference by setting the 'core.untrackedCache' configuration variable, which can take 'keep', 'false', or 'true' and default to 'keep'. When read_index_from() is called, it now adds or removes the untracked cache in the index to respect the value of this variable. So it does nothing if the value is `keep` or if the variable is unset; it adds the untracked cache if the value is `true`; and it removes the cache if the value is `false`. `git update-index --[no-|force-]untracked-cache` still adds the untracked cache to, or removes it, from the index, but this shows a warning if it goes against the value of core.untrackedCache, because the next time the index is read the untracked cache will be added or removed if the configuration is set to do so. Also `--untracked-cache` used to check that the underlying operating system and file system change `st_mtime` field of a directory if files are added or deleted in that directory. But because those tests take a long time, `--untracked-cache` no longer performs them. Instead, there is now `--test-untracked-cache` to perform the tests. This change makes `--untracked-cache` the same as `--force-untracked-cache`. This last change is backward incompatible and should be mentioned in the release notes. Helped-by: Duy Nguyen <pclouds@gmail.com> Helped-by: Torsten Bögershausen <tboegi@web.de> Helped-by: Stefan Beller <sbeller@google.com> Signed-off-by: Christian Couder <chriscool@tuxfamily.org> Signed-off-by: Ævar Arnfjörð Bjarmason <avarab@gmail.com> read-cache: Duy'sfixup Signed-off-by: Christian Couder <chriscool@tuxfamily.org> Signed-off-by: Junio C Hamano <gitster@pobox.com>
2016-01-27 07:58:05 +01:00
}
block alloc: allocate cache entries from mem_pool When reading large indexes from disk, a portion of the time is dominated in malloc() calls. This can be mitigated by allocating a large block of memory and manage it ourselves via memory pools. This change moves the cache entry allocation to be on top of memory pools. Design: The index_state struct will gain a notion of an associated memory_pool from which cache_entries will be allocated from. When reading in the index from disk, we have information on the number of entries and their size, which can guide us in deciding how large our initial memory allocation should be. When an index is discarded, the associated memory_pool will be discarded as well - so the lifetime of a cache_entry is tied to the lifetime of the index_state that it was allocated for. In the case of a Split Index, the following rules are followed. 1st, some terminology is defined: Terminology: - 'the_index': represents the logical view of the index - 'split_index': represents the "base" cache entries. Read from the split index file. 'the_index' can reference a single split_index, as well as cache_entries from the split_index. `the_index` will be discarded before the `split_index` is. This means that when we are allocating cache_entries in the presence of a split index, we need to allocate the entries from the `split_index`'s memory pool. This allows us to follow the pattern that `the_index` can reference cache_entries from the `split_index`, and that the cache_entries will not be freed while they are still being referenced. Managing transient cache_entry structs: Cache entries are usually allocated for an index, but this is not always the case. Cache entries are sometimes allocated because this is the type that the existing checkout_entry function works with. Because of this, the existing code needs to handle cache entries associated with an index / memory pool, and those that only exist transiently. Several strategies were contemplated around how to handle this: Chosen approach: An extra field was added to the cache_entry type to track whether the cache_entry was allocated from a memory pool or not. This is currently an int field, as there are no more available bits in the existing ce_flags bit field. If / when more bits are needed, this new field can be turned into a proper bit field. Alternatives: 1) Do not include any information about how the cache_entry was allocated. Calling code would be responsible for tracking whether the cache_entry needed to be freed or not. Pro: No extra memory overhead to track this state Con: Extra complexity in callers to handle this correctly. The extra complexity and burden to not regress this behavior in the future was more than we wanted. 2) cache_entry would gain knowledge about which mem_pool allocated it Pro: Could (potentially) do extra logic to know when a mem_pool no longer had references to any cache_entry Con: cache_entry would grow heavier by a pointer, instead of int We didn't see a tangible benefit to this approach 3) Do not add any extra information to a cache_entry, but when freeing a cache entry, check if the memory exists in a region managed by existing mem_pools. Pro: No extra memory overhead to track state Con: Extra computation is performed when freeing cache entries We decided tracking and iterating over known memory pool regions was less desirable than adding an extra field to track this stae. Signed-off-by: Jameson Miller <jamill@microsoft.com> Signed-off-by: Junio C Hamano <gitster@pobox.com>
2018-07-02 21:49:37 +02:00
static size_t estimate_cache_size_from_compressed(unsigned int entries)
{
return entries * (sizeof(struct cache_entry) + CACHE_ENTRY_PATH_LENGTH);
}
static size_t estimate_cache_size(size_t ondisk_size, unsigned int entries)
{
long per_entry = sizeof(struct cache_entry) - sizeof(struct ondisk_cache_entry);
/*
* Account for potential alignment differences.
*/
msvc: avoid using minus operator on unsigned types MSVC complains about this with `-Wall`, which can be taken as a sign that this is indeed a real bug. The symptom is: C4146: unary minus operator applied to unsigned type, result still unsigned Let's avoid this warning in the minimal way, e.g. writing `-1 - <unsigned value>` instead of `-<unsigned value> - 1`. Note that the change in the `estimate_cache_size()` function is needed because MSVC considers the "return type" of the `sizeof()` operator to be `size_t`, i.e. unsigned, and therefore it cannot be negated using the unary minus operator. Even worse, that arithmetic is doing extra work, in vain. We want to calculate the entry extra cache size as the difference between the size of the `cache_entry` structure minus the size of the `ondisk_cache_entry` structure, padded to the appropriate alignment boundary. To that end, we start by assigning that difference to the `per_entry` variable, and then abuse the `len` parameter of the `align_padding_size()` macro to take the negative size of the ondisk entry size. Essentially, we try to avoid passing the already calculated difference to that macro by passing the operands of that difference instead, when the macro expects operands of an addition: #define align_padding_size(size, len) \ ((size + (len) + 8) & ~7) - (size + len) Currently, we pass A and -B to that macro instead of passing A - B and 0, where A - B is already stored in the `per_entry` variable, ready to be used. This is neither necessary, nor intuitive. Let's fix this, and have code that is both easier to read and that also does not trigger MSVC's warning. While at it, we take care of reporting overflows (which are unlikely, but hey, defensive programming is good!). We _also_ take pains of casting the unsigned value to signed: otherwise, the signed operand (i.e. the `-1`) would be cast to unsigned before doing the arithmetic. Helped-by: Denton Liu <liu.denton@gmail.com> Signed-off-by: Johannes Schindelin <johannes.schindelin@gmx.de> Signed-off-by: Junio C Hamano <gitster@pobox.com>
2019-10-04 17:09:26 +02:00
per_entry += align_padding_size(per_entry, 0);
block alloc: allocate cache entries from mem_pool When reading large indexes from disk, a portion of the time is dominated in malloc() calls. This can be mitigated by allocating a large block of memory and manage it ourselves via memory pools. This change moves the cache entry allocation to be on top of memory pools. Design: The index_state struct will gain a notion of an associated memory_pool from which cache_entries will be allocated from. When reading in the index from disk, we have information on the number of entries and their size, which can guide us in deciding how large our initial memory allocation should be. When an index is discarded, the associated memory_pool will be discarded as well - so the lifetime of a cache_entry is tied to the lifetime of the index_state that it was allocated for. In the case of a Split Index, the following rules are followed. 1st, some terminology is defined: Terminology: - 'the_index': represents the logical view of the index - 'split_index': represents the "base" cache entries. Read from the split index file. 'the_index' can reference a single split_index, as well as cache_entries from the split_index. `the_index` will be discarded before the `split_index` is. This means that when we are allocating cache_entries in the presence of a split index, we need to allocate the entries from the `split_index`'s memory pool. This allows us to follow the pattern that `the_index` can reference cache_entries from the `split_index`, and that the cache_entries will not be freed while they are still being referenced. Managing transient cache_entry structs: Cache entries are usually allocated for an index, but this is not always the case. Cache entries are sometimes allocated because this is the type that the existing checkout_entry function works with. Because of this, the existing code needs to handle cache entries associated with an index / memory pool, and those that only exist transiently. Several strategies were contemplated around how to handle this: Chosen approach: An extra field was added to the cache_entry type to track whether the cache_entry was allocated from a memory pool or not. This is currently an int field, as there are no more available bits in the existing ce_flags bit field. If / when more bits are needed, this new field can be turned into a proper bit field. Alternatives: 1) Do not include any information about how the cache_entry was allocated. Calling code would be responsible for tracking whether the cache_entry needed to be freed or not. Pro: No extra memory overhead to track this state Con: Extra complexity in callers to handle this correctly. The extra complexity and burden to not regress this behavior in the future was more than we wanted. 2) cache_entry would gain knowledge about which mem_pool allocated it Pro: Could (potentially) do extra logic to know when a mem_pool no longer had references to any cache_entry Con: cache_entry would grow heavier by a pointer, instead of int We didn't see a tangible benefit to this approach 3) Do not add any extra information to a cache_entry, but when freeing a cache entry, check if the memory exists in a region managed by existing mem_pools. Pro: No extra memory overhead to track state Con: Extra computation is performed when freeing cache entries We decided tracking and iterating over known memory pool regions was less desirable than adding an extra field to track this stae. Signed-off-by: Jameson Miller <jamill@microsoft.com> Signed-off-by: Junio C Hamano <gitster@pobox.com>
2018-07-02 21:49:37 +02:00
return ondisk_size + entries * per_entry;
}
struct index_entry_offset
{
/* starting byte offset into index file, count of index entries in this block */
int offset, nr;
};
struct index_entry_offset_table
{
int nr;
struct index_entry_offset entries[FLEX_ARRAY];
};
static struct index_entry_offset_table *read_ieot_extension(const char *mmap, size_t mmap_size, size_t offset);
static void write_ieot_extension(struct strbuf *sb, struct index_entry_offset_table *ieot);
static size_t read_eoie_extension(const char *mmap, size_t mmap_size);
static void write_eoie_extension(struct strbuf *sb, git_hash_ctx *eoie_context, size_t offset);
struct load_index_extensions
{
pthread_t pthread;
struct index_state *istate;
const char *mmap;
size_t mmap_size;
unsigned long src_offset;
};
static void *load_index_extensions(void *_data)
{
struct load_index_extensions *p = _data;
unsigned long src_offset = p->src_offset;
while (src_offset <= p->mmap_size - the_hash_algo->rawsz - 8) {
/* After an array of active_nr index entries,
* there can be arbitrary number of extended
* sections, each of which is prefixed with
* extension name (4-byte) and section length
* in 4-byte network byte order.
*/
uint32_t extsize = get_be32(p->mmap + src_offset + 4);
if (read_index_extension(p->istate,
p->mmap + src_offset,
p->mmap + src_offset + 8,
extsize) < 0) {
munmap((void *)p->mmap, p->mmap_size);
die(_("index file corrupt"));
}
src_offset += 8;
src_offset += extsize;
}
return NULL;
}
/*
* A helper function that will load the specified range of cache entries
* from the memory mapped file and add them to the given index.
*/
static unsigned long load_cache_entry_block(struct index_state *istate,
struct mem_pool *ce_mem_pool, int offset, int nr, const char *mmap,
unsigned long start_offset, const struct cache_entry *previous_ce)
{
int i;
unsigned long src_offset = start_offset;
for (i = offset; i < offset + nr; i++) {
struct ondisk_cache_entry *disk_ce;
struct cache_entry *ce;
unsigned long consumed;
disk_ce = (struct ondisk_cache_entry *)(mmap + src_offset);
ce = create_from_disk(ce_mem_pool, istate->version, disk_ce, &consumed, previous_ce);
set_index_entry(istate, i, ce);
src_offset += consumed;
previous_ce = ce;
}
return src_offset - start_offset;
}
static unsigned long load_all_cache_entries(struct index_state *istate,
const char *mmap, size_t mmap_size, unsigned long src_offset)
{
unsigned long consumed;
mem-pool: use more standard initialization and finalization A typical memory type, such as strbuf, hashmap, or string_list can be stored on the stack or embedded within another structure. mem_pool cannot be, because of how mem_pool_init() and mem_pool_discard() are written. mem_pool_init() does essentially the following (simplified for purposes of explanation here): void mem_pool_init(struct mem_pool **pool...) { *pool = xcalloc(1, sizeof(*pool)); It seems weird to require that mem_pools can only be accessed through a pointer. It also seems slightly dangerous: unlike strbuf_release() or strbuf_reset() or string_list_clear(), all of which put the data structure into a state where it can be re-used after the call, mem_pool_discard(pool) will leave pool pointing at free'd memory. read-cache (and split-index) are the only current users of mem_pools, and they haven't fallen into a use-after-free mistake here, but it seems likely to be problematic for future users especially since several of the current callers of mem_pool_init() will only call it when the mem_pool* is not already allocated (i.e. is NULL). This type of mechanism also prevents finding synchronization points where one can free existing memory and then resume more operations. It would be natural at such points to run something like mem_pool_discard(pool...); and, if necessary, mem_pool_init(&pool...); and then carry on continuing to use the pool. However, this fails badly if several objects had a copy of the value of pool from before these commands; in such a case, those objects won't get the updated value of pool that mem_pool_init() overwrites pool with and they'll all instead be reading and writing from free'd memory. Modify mem_pool_init()/mem_pool_discard() to behave more like strbuf_init()/strbuf_release() or string_list_init()/string_list_clear() In particular: (1) make mem_pool_init() just take a mem_pool* and have it only worry about allocating struct mp_blocks, not the struct mem_pool itself, (2) make mem_pool_discard() free the memory that the pool was responsible for, but leave it in a state where it can be used to allocate more memory afterward (without the need to call mem_pool_init() again). Signed-off-by: Elijah Newren <newren@gmail.com> Signed-off-by: Junio C Hamano <gitster@pobox.com>
2020-08-15 19:37:56 +02:00
istate->ce_mem_pool = xmalloc(sizeof(*istate->ce_mem_pool));
if (istate->version == 4) {
mem-pool: use more standard initialization and finalization A typical memory type, such as strbuf, hashmap, or string_list can be stored on the stack or embedded within another structure. mem_pool cannot be, because of how mem_pool_init() and mem_pool_discard() are written. mem_pool_init() does essentially the following (simplified for purposes of explanation here): void mem_pool_init(struct mem_pool **pool...) { *pool = xcalloc(1, sizeof(*pool)); It seems weird to require that mem_pools can only be accessed through a pointer. It also seems slightly dangerous: unlike strbuf_release() or strbuf_reset() or string_list_clear(), all of which put the data structure into a state where it can be re-used after the call, mem_pool_discard(pool) will leave pool pointing at free'd memory. read-cache (and split-index) are the only current users of mem_pools, and they haven't fallen into a use-after-free mistake here, but it seems likely to be problematic for future users especially since several of the current callers of mem_pool_init() will only call it when the mem_pool* is not already allocated (i.e. is NULL). This type of mechanism also prevents finding synchronization points where one can free existing memory and then resume more operations. It would be natural at such points to run something like mem_pool_discard(pool...); and, if necessary, mem_pool_init(&pool...); and then carry on continuing to use the pool. However, this fails badly if several objects had a copy of the value of pool from before these commands; in such a case, those objects won't get the updated value of pool that mem_pool_init() overwrites pool with and they'll all instead be reading and writing from free'd memory. Modify mem_pool_init()/mem_pool_discard() to behave more like strbuf_init()/strbuf_release() or string_list_init()/string_list_clear() In particular: (1) make mem_pool_init() just take a mem_pool* and have it only worry about allocating struct mp_blocks, not the struct mem_pool itself, (2) make mem_pool_discard() free the memory that the pool was responsible for, but leave it in a state where it can be used to allocate more memory afterward (without the need to call mem_pool_init() again). Signed-off-by: Elijah Newren <newren@gmail.com> Signed-off-by: Junio C Hamano <gitster@pobox.com>
2020-08-15 19:37:56 +02:00
mem_pool_init(istate->ce_mem_pool,
estimate_cache_size_from_compressed(istate->cache_nr));
} else {
mem-pool: use more standard initialization and finalization A typical memory type, such as strbuf, hashmap, or string_list can be stored on the stack or embedded within another structure. mem_pool cannot be, because of how mem_pool_init() and mem_pool_discard() are written. mem_pool_init() does essentially the following (simplified for purposes of explanation here): void mem_pool_init(struct mem_pool **pool...) { *pool = xcalloc(1, sizeof(*pool)); It seems weird to require that mem_pools can only be accessed through a pointer. It also seems slightly dangerous: unlike strbuf_release() or strbuf_reset() or string_list_clear(), all of which put the data structure into a state where it can be re-used after the call, mem_pool_discard(pool) will leave pool pointing at free'd memory. read-cache (and split-index) are the only current users of mem_pools, and they haven't fallen into a use-after-free mistake here, but it seems likely to be problematic for future users especially since several of the current callers of mem_pool_init() will only call it when the mem_pool* is not already allocated (i.e. is NULL). This type of mechanism also prevents finding synchronization points where one can free existing memory and then resume more operations. It would be natural at such points to run something like mem_pool_discard(pool...); and, if necessary, mem_pool_init(&pool...); and then carry on continuing to use the pool. However, this fails badly if several objects had a copy of the value of pool from before these commands; in such a case, those objects won't get the updated value of pool that mem_pool_init() overwrites pool with and they'll all instead be reading and writing from free'd memory. Modify mem_pool_init()/mem_pool_discard() to behave more like strbuf_init()/strbuf_release() or string_list_init()/string_list_clear() In particular: (1) make mem_pool_init() just take a mem_pool* and have it only worry about allocating struct mp_blocks, not the struct mem_pool itself, (2) make mem_pool_discard() free the memory that the pool was responsible for, but leave it in a state where it can be used to allocate more memory afterward (without the need to call mem_pool_init() again). Signed-off-by: Elijah Newren <newren@gmail.com> Signed-off-by: Junio C Hamano <gitster@pobox.com>
2020-08-15 19:37:56 +02:00
mem_pool_init(istate->ce_mem_pool,
estimate_cache_size(mmap_size, istate->cache_nr));
}
consumed = load_cache_entry_block(istate, istate->ce_mem_pool,
0, istate->cache_nr, mmap, src_offset, NULL);
return consumed;
}
/*
* Mostly randomly chosen maximum thread counts: we
* cap the parallelism to online_cpus() threads, and we want
* to have at least 10000 cache entries per thread for it to
* be worth starting a thread.
*/
#define THREAD_COST (10000)
struct load_cache_entries_thread_data
{
pthread_t pthread;
struct index_state *istate;
struct mem_pool *ce_mem_pool;
int offset;
const char *mmap;
struct index_entry_offset_table *ieot;
int ieot_start; /* starting index into the ieot array */
int ieot_blocks; /* count of ieot entries to process */
unsigned long consumed; /* return # of bytes in index file processed */
};
/*
* A thread proc to run the load_cache_entries() computation
* across multiple background threads.
*/
static void *load_cache_entries_thread(void *_data)
{
struct load_cache_entries_thread_data *p = _data;
int i;
/* iterate across all ieot blocks assigned to this thread */
for (i = p->ieot_start; i < p->ieot_start + p->ieot_blocks; i++) {
p->consumed += load_cache_entry_block(p->istate, p->ce_mem_pool,
p->offset, p->ieot->entries[i].nr, p->mmap, p->ieot->entries[i].offset, NULL);
p->offset += p->ieot->entries[i].nr;
}
return NULL;
}
static unsigned long load_cache_entries_threaded(struct index_state *istate, const char *mmap, size_t mmap_size,
int nr_threads, struct index_entry_offset_table *ieot)
{
int i, offset, ieot_blocks, ieot_start, err;
struct load_cache_entries_thread_data *data;
unsigned long consumed = 0;
/* a little sanity checking */
if (istate->name_hash_initialized)
BUG("the name hash isn't thread safe");
mem-pool: use more standard initialization and finalization A typical memory type, such as strbuf, hashmap, or string_list can be stored on the stack or embedded within another structure. mem_pool cannot be, because of how mem_pool_init() and mem_pool_discard() are written. mem_pool_init() does essentially the following (simplified for purposes of explanation here): void mem_pool_init(struct mem_pool **pool...) { *pool = xcalloc(1, sizeof(*pool)); It seems weird to require that mem_pools can only be accessed through a pointer. It also seems slightly dangerous: unlike strbuf_release() or strbuf_reset() or string_list_clear(), all of which put the data structure into a state where it can be re-used after the call, mem_pool_discard(pool) will leave pool pointing at free'd memory. read-cache (and split-index) are the only current users of mem_pools, and they haven't fallen into a use-after-free mistake here, but it seems likely to be problematic for future users especially since several of the current callers of mem_pool_init() will only call it when the mem_pool* is not already allocated (i.e. is NULL). This type of mechanism also prevents finding synchronization points where one can free existing memory and then resume more operations. It would be natural at such points to run something like mem_pool_discard(pool...); and, if necessary, mem_pool_init(&pool...); and then carry on continuing to use the pool. However, this fails badly if several objects had a copy of the value of pool from before these commands; in such a case, those objects won't get the updated value of pool that mem_pool_init() overwrites pool with and they'll all instead be reading and writing from free'd memory. Modify mem_pool_init()/mem_pool_discard() to behave more like strbuf_init()/strbuf_release() or string_list_init()/string_list_clear() In particular: (1) make mem_pool_init() just take a mem_pool* and have it only worry about allocating struct mp_blocks, not the struct mem_pool itself, (2) make mem_pool_discard() free the memory that the pool was responsible for, but leave it in a state where it can be used to allocate more memory afterward (without the need to call mem_pool_init() again). Signed-off-by: Elijah Newren <newren@gmail.com> Signed-off-by: Junio C Hamano <gitster@pobox.com>
2020-08-15 19:37:56 +02:00
istate->ce_mem_pool = xmalloc(sizeof(*istate->ce_mem_pool));
mem_pool_init(istate->ce_mem_pool, 0);
/* ensure we have no more threads than we have blocks to process */
if (nr_threads > ieot->nr)
nr_threads = ieot->nr;
CALLOC_ARRAY(data, nr_threads);
offset = ieot_start = 0;
ieot_blocks = DIV_ROUND_UP(ieot->nr, nr_threads);
for (i = 0; i < nr_threads; i++) {
struct load_cache_entries_thread_data *p = &data[i];
int nr, j;
if (ieot_start + ieot_blocks > ieot->nr)
ieot_blocks = ieot->nr - ieot_start;
p->istate = istate;
p->offset = offset;
p->mmap = mmap;
p->ieot = ieot;
p->ieot_start = ieot_start;
p->ieot_blocks = ieot_blocks;
/* create a mem_pool for each thread */
nr = 0;
for (j = p->ieot_start; j < p->ieot_start + p->ieot_blocks; j++)
nr += p->ieot->entries[j].nr;
p->ce_mem_pool = xmalloc(sizeof(*istate->ce_mem_pool));
if (istate->version == 4) {
mem-pool: use more standard initialization and finalization A typical memory type, such as strbuf, hashmap, or string_list can be stored on the stack or embedded within another structure. mem_pool cannot be, because of how mem_pool_init() and mem_pool_discard() are written. mem_pool_init() does essentially the following (simplified for purposes of explanation here): void mem_pool_init(struct mem_pool **pool...) { *pool = xcalloc(1, sizeof(*pool)); It seems weird to require that mem_pools can only be accessed through a pointer. It also seems slightly dangerous: unlike strbuf_release() or strbuf_reset() or string_list_clear(), all of which put the data structure into a state where it can be re-used after the call, mem_pool_discard(pool) will leave pool pointing at free'd memory. read-cache (and split-index) are the only current users of mem_pools, and they haven't fallen into a use-after-free mistake here, but it seems likely to be problematic for future users especially since several of the current callers of mem_pool_init() will only call it when the mem_pool* is not already allocated (i.e. is NULL). This type of mechanism also prevents finding synchronization points where one can free existing memory and then resume more operations. It would be natural at such points to run something like mem_pool_discard(pool...); and, if necessary, mem_pool_init(&pool...); and then carry on continuing to use the pool. However, this fails badly if several objects had a copy of the value of pool from before these commands; in such a case, those objects won't get the updated value of pool that mem_pool_init() overwrites pool with and they'll all instead be reading and writing from free'd memory. Modify mem_pool_init()/mem_pool_discard() to behave more like strbuf_init()/strbuf_release() or string_list_init()/string_list_clear() In particular: (1) make mem_pool_init() just take a mem_pool* and have it only worry about allocating struct mp_blocks, not the struct mem_pool itself, (2) make mem_pool_discard() free the memory that the pool was responsible for, but leave it in a state where it can be used to allocate more memory afterward (without the need to call mem_pool_init() again). Signed-off-by: Elijah Newren <newren@gmail.com> Signed-off-by: Junio C Hamano <gitster@pobox.com>
2020-08-15 19:37:56 +02:00
mem_pool_init(p->ce_mem_pool,
estimate_cache_size_from_compressed(nr));
} else {
mem-pool: use more standard initialization and finalization A typical memory type, such as strbuf, hashmap, or string_list can be stored on the stack or embedded within another structure. mem_pool cannot be, because of how mem_pool_init() and mem_pool_discard() are written. mem_pool_init() does essentially the following (simplified for purposes of explanation here): void mem_pool_init(struct mem_pool **pool...) { *pool = xcalloc(1, sizeof(*pool)); It seems weird to require that mem_pools can only be accessed through a pointer. It also seems slightly dangerous: unlike strbuf_release() or strbuf_reset() or string_list_clear(), all of which put the data structure into a state where it can be re-used after the call, mem_pool_discard(pool) will leave pool pointing at free'd memory. read-cache (and split-index) are the only current users of mem_pools, and they haven't fallen into a use-after-free mistake here, but it seems likely to be problematic for future users especially since several of the current callers of mem_pool_init() will only call it when the mem_pool* is not already allocated (i.e. is NULL). This type of mechanism also prevents finding synchronization points where one can free existing memory and then resume more operations. It would be natural at such points to run something like mem_pool_discard(pool...); and, if necessary, mem_pool_init(&pool...); and then carry on continuing to use the pool. However, this fails badly if several objects had a copy of the value of pool from before these commands; in such a case, those objects won't get the updated value of pool that mem_pool_init() overwrites pool with and they'll all instead be reading and writing from free'd memory. Modify mem_pool_init()/mem_pool_discard() to behave more like strbuf_init()/strbuf_release() or string_list_init()/string_list_clear() In particular: (1) make mem_pool_init() just take a mem_pool* and have it only worry about allocating struct mp_blocks, not the struct mem_pool itself, (2) make mem_pool_discard() free the memory that the pool was responsible for, but leave it in a state where it can be used to allocate more memory afterward (without the need to call mem_pool_init() again). Signed-off-by: Elijah Newren <newren@gmail.com> Signed-off-by: Junio C Hamano <gitster@pobox.com>
2020-08-15 19:37:56 +02:00
mem_pool_init(p->ce_mem_pool,
estimate_cache_size(mmap_size, nr));
}
err = pthread_create(&p->pthread, NULL, load_cache_entries_thread, p);
if (err)
die(_("unable to create load_cache_entries thread: %s"), strerror(err));
/* increment by the number of cache entries in the ieot block being processed */
for (j = 0; j < ieot_blocks; j++)
offset += ieot->entries[ieot_start + j].nr;
ieot_start += ieot_blocks;
}
for (i = 0; i < nr_threads; i++) {
struct load_cache_entries_thread_data *p = &data[i];
err = pthread_join(p->pthread, NULL);
if (err)
die(_("unable to join load_cache_entries thread: %s"), strerror(err));
mem_pool_combine(istate->ce_mem_pool, p->ce_mem_pool);
consumed += p->consumed;
}
free(data);
return consumed;
}
/* remember to discard_cache() before reading a different cache! */
int do_read_index(struct index_state *istate, const char *path, int must_exist)
{
int fd;
struct stat st;
unsigned long src_offset;
const struct cache_header *hdr;
const char *mmap;
size_t mmap_size;
struct load_index_extensions p;
size_t extension_offset = 0;
int nr_threads, cpus;
struct index_entry_offset_table *ieot = NULL;
unpack_trees(): protect the handcrafted in-core index from read_cache() unpack_trees() rebuilds the in-core index from scratch by allocating a new structure and finishing it off by copying the built one to the final index. The resulting in-core index is Ok for most use, but read_cache() does not recognize it as such. The function is meant to be no-op if you already have loaded the index, until you call discard_cache(). This change the way read_cache() detects an already initialized in-core index, by introducing an extra bit, and marks the handcrafted in-core index as initialized, to avoid this problem. A better fix in the longer term would be to change the read_cache() API so that it will always discard and re-read from the on-disk index to avoid confusion. But there are higher level API that have relied on the current semantics, and they and their users all need to get converted, which is outside the scope of 'maint' track. An example of such a higher level API is write_cache_as_tree(), which is used by git-write-tree as well as later Porcelains like git-merge, revert and cherry-pick. In the longer term, we should remove read_cache() from there and add one to cmd_write_tree(); other callers expect that the in-core index they prepared is what gets written as a tree so no other change is necessary for this particular codepath. The original version of this patch marked the index by pointing an otherwise wasted malloc'ed memory with o->result.alloc, but this version uses Linus's idea to use a new "initialized" bit, which is conceptually much cleaner. Signed-off-by: Junio C Hamano <gitster@pobox.com>
2008-08-23 21:57:30 +02:00
if (istate->initialized)
return istate->cache_nr;
istate->timestamp.sec = 0;
istate->timestamp.nsec = 0;
fd = open(path, O_RDONLY);
if (fd < 0) {
if (!must_exist && errno == ENOENT)
return 0;
die_errno(_("%s: index file open failed"), path);
}
if (fstat(fd, &st))
die_errno(_("%s: cannot stat the open index"), path);
mmap_size = xsize_t(st.st_size);
if (mmap_size < sizeof(struct cache_header) + the_hash_algo->rawsz)
die(_("%s: index file smaller than expected"), path);
mmap = xmmap_gently(NULL, mmap_size, PROT_READ, MAP_PRIVATE, fd, 0);
if (mmap == MAP_FAILED)
die_errno(_("%s: unable to map index file%s"), path,
mmap_os_err());
close(fd);
hdr = (const struct cache_header *)mmap;
if (verify_hdr(hdr, mmap_size) < 0)
goto unmap;
oidread(&istate->oid, (const unsigned char *)hdr + mmap_size - the_hash_algo->rawsz);
istate->version = ntohl(hdr->hdr_version);
istate->cache_nr = ntohl(hdr->hdr_entries);
istate->cache_alloc = alloc_nr(istate->cache_nr);
CALLOC_ARRAY(istate->cache, istate->cache_alloc);
unpack_trees(): protect the handcrafted in-core index from read_cache() unpack_trees() rebuilds the in-core index from scratch by allocating a new structure and finishing it off by copying the built one to the final index. The resulting in-core index is Ok for most use, but read_cache() does not recognize it as such. The function is meant to be no-op if you already have loaded the index, until you call discard_cache(). This change the way read_cache() detects an already initialized in-core index, by introducing an extra bit, and marks the handcrafted in-core index as initialized, to avoid this problem. A better fix in the longer term would be to change the read_cache() API so that it will always discard and re-read from the on-disk index to avoid confusion. But there are higher level API that have relied on the current semantics, and they and their users all need to get converted, which is outside the scope of 'maint' track. An example of such a higher level API is write_cache_as_tree(), which is used by git-write-tree as well as later Porcelains like git-merge, revert and cherry-pick. In the longer term, we should remove read_cache() from there and add one to cmd_write_tree(); other callers expect that the in-core index they prepared is what gets written as a tree so no other change is necessary for this particular codepath. The original version of this patch marked the index by pointing an otherwise wasted malloc'ed memory with o->result.alloc, but this version uses Linus's idea to use a new "initialized" bit, which is conceptually much cleaner. Signed-off-by: Junio C Hamano <gitster@pobox.com>
2008-08-23 21:57:30 +02:00
istate->initialized = 1;
p.istate = istate;
p.mmap = mmap;
p.mmap_size = mmap_size;
src_offset = sizeof(*hdr);
index: make index.threads=true enable ieot and eoie If a user explicitly sets [index] threads = true to read the index using multiple threads, ensure that index writes include the offset table by default to make that possible. This ensures that the user's intent of turning on threading is respected. In other words, permit the following configurations: - index.threads and index.recordOffsetTable unspecified: do not write the offset table yet (to avoid alarming the user with "ignoring IEOT extension" messages when an older version of Git accesses the repository) but do make use of multiple threads to read the index if the supporting offset table is present. This can also be requested explicitly by setting index.threads=true, 0, or >1 and index.recordOffsetTable=false. - index.threads=false or 1: do not write the offset table, and do not make use of the offset table. One can set index.recordOffsetTable=false as well, to be more explicit. - index.threads=true, 0, or >1 and index.recordOffsetTable unspecified: write the offset table and make use of threads at read time. This can also be requested by setting index.threads=true, 0, >1, or unspecified and index.recordOffsetTable=true. Fortunately the complication is temporary: once most Git installations have upgraded to a version with support for the IEOT and EOIE extensions, we can flip the defaults for index.recordEndOfIndexEntries and index.recordOffsetTable to true and eliminate the settings. Helped-by: Ben Peart <benpeart@microsoft.com> Signed-off-by: Jonathan Nieder <jrnieder@gmail.com> Signed-off-by: Junio C Hamano <gitster@pobox.com>
2018-11-20 07:14:26 +01:00
if (git_config_get_index_threads(&nr_threads))
nr_threads = 1;
/* TODO: does creating more threads than cores help? */
if (!nr_threads) {
nr_threads = istate->cache_nr / THREAD_COST;
cpus = online_cpus();
if (nr_threads > cpus)
nr_threads = cpus;
}
if (!HAVE_THREADS)
nr_threads = 1;
if (nr_threads > 1) {
extension_offset = read_eoie_extension(mmap, mmap_size);
if (extension_offset) {
int err;
p.src_offset = extension_offset;
err = pthread_create(&p.pthread, NULL, load_index_extensions, &p);
if (err)
die(_("unable to create load_index_extensions thread: %s"), strerror(err));
nr_threads--;
}
}
/*
* Locate and read the index entry offset table so that we can use it
* to multi-thread the reading of the cache entries.
*/
if (extension_offset && nr_threads > 1)
ieot = read_ieot_extension(mmap, mmap_size, extension_offset);
if (ieot) {
src_offset += load_cache_entries_threaded(istate, mmap, mmap_size, nr_threads, ieot);
free(ieot);
block alloc: allocate cache entries from mem_pool When reading large indexes from disk, a portion of the time is dominated in malloc() calls. This can be mitigated by allocating a large block of memory and manage it ourselves via memory pools. This change moves the cache entry allocation to be on top of memory pools. Design: The index_state struct will gain a notion of an associated memory_pool from which cache_entries will be allocated from. When reading in the index from disk, we have information on the number of entries and their size, which can guide us in deciding how large our initial memory allocation should be. When an index is discarded, the associated memory_pool will be discarded as well - so the lifetime of a cache_entry is tied to the lifetime of the index_state that it was allocated for. In the case of a Split Index, the following rules are followed. 1st, some terminology is defined: Terminology: - 'the_index': represents the logical view of the index - 'split_index': represents the "base" cache entries. Read from the split index file. 'the_index' can reference a single split_index, as well as cache_entries from the split_index. `the_index` will be discarded before the `split_index` is. This means that when we are allocating cache_entries in the presence of a split index, we need to allocate the entries from the `split_index`'s memory pool. This allows us to follow the pattern that `the_index` can reference cache_entries from the `split_index`, and that the cache_entries will not be freed while they are still being referenced. Managing transient cache_entry structs: Cache entries are usually allocated for an index, but this is not always the case. Cache entries are sometimes allocated because this is the type that the existing checkout_entry function works with. Because of this, the existing code needs to handle cache entries associated with an index / memory pool, and those that only exist transiently. Several strategies were contemplated around how to handle this: Chosen approach: An extra field was added to the cache_entry type to track whether the cache_entry was allocated from a memory pool or not. This is currently an int field, as there are no more available bits in the existing ce_flags bit field. If / when more bits are needed, this new field can be turned into a proper bit field. Alternatives: 1) Do not include any information about how the cache_entry was allocated. Calling code would be responsible for tracking whether the cache_entry needed to be freed or not. Pro: No extra memory overhead to track this state Con: Extra complexity in callers to handle this correctly. The extra complexity and burden to not regress this behavior in the future was more than we wanted. 2) cache_entry would gain knowledge about which mem_pool allocated it Pro: Could (potentially) do extra logic to know when a mem_pool no longer had references to any cache_entry Con: cache_entry would grow heavier by a pointer, instead of int We didn't see a tangible benefit to this approach 3) Do not add any extra information to a cache_entry, but when freeing a cache entry, check if the memory exists in a region managed by existing mem_pools. Pro: No extra memory overhead to track state Con: Extra computation is performed when freeing cache entries We decided tracking and iterating over known memory pool regions was less desirable than adding an extra field to track this stae. Signed-off-by: Jameson Miller <jamill@microsoft.com> Signed-off-by: Junio C Hamano <gitster@pobox.com>
2018-07-02 21:49:37 +02:00
} else {
src_offset += load_all_cache_entries(istate, mmap, mmap_size, src_offset);
block alloc: allocate cache entries from mem_pool When reading large indexes from disk, a portion of the time is dominated in malloc() calls. This can be mitigated by allocating a large block of memory and manage it ourselves via memory pools. This change moves the cache entry allocation to be on top of memory pools. Design: The index_state struct will gain a notion of an associated memory_pool from which cache_entries will be allocated from. When reading in the index from disk, we have information on the number of entries and their size, which can guide us in deciding how large our initial memory allocation should be. When an index is discarded, the associated memory_pool will be discarded as well - so the lifetime of a cache_entry is tied to the lifetime of the index_state that it was allocated for. In the case of a Split Index, the following rules are followed. 1st, some terminology is defined: Terminology: - 'the_index': represents the logical view of the index - 'split_index': represents the "base" cache entries. Read from the split index file. 'the_index' can reference a single split_index, as well as cache_entries from the split_index. `the_index` will be discarded before the `split_index` is. This means that when we are allocating cache_entries in the presence of a split index, we need to allocate the entries from the `split_index`'s memory pool. This allows us to follow the pattern that `the_index` can reference cache_entries from the `split_index`, and that the cache_entries will not be freed while they are still being referenced. Managing transient cache_entry structs: Cache entries are usually allocated for an index, but this is not always the case. Cache entries are sometimes allocated because this is the type that the existing checkout_entry function works with. Because of this, the existing code needs to handle cache entries associated with an index / memory pool, and those that only exist transiently. Several strategies were contemplated around how to handle this: Chosen approach: An extra field was added to the cache_entry type to track whether the cache_entry was allocated from a memory pool or not. This is currently an int field, as there are no more available bits in the existing ce_flags bit field. If / when more bits are needed, this new field can be turned into a proper bit field. Alternatives: 1) Do not include any information about how the cache_entry was allocated. Calling code would be responsible for tracking whether the cache_entry needed to be freed or not. Pro: No extra memory overhead to track this state Con: Extra complexity in callers to handle this correctly. The extra complexity and burden to not regress this behavior in the future was more than we wanted. 2) cache_entry would gain knowledge about which mem_pool allocated it Pro: Could (potentially) do extra logic to know when a mem_pool no longer had references to any cache_entry Con: cache_entry would grow heavier by a pointer, instead of int We didn't see a tangible benefit to this approach 3) Do not add any extra information to a cache_entry, but when freeing a cache entry, check if the memory exists in a region managed by existing mem_pools. Pro: No extra memory overhead to track state Con: Extra computation is performed when freeing cache entries We decided tracking and iterating over known memory pool regions was less desirable than adding an extra field to track this stae. Signed-off-by: Jameson Miller <jamill@microsoft.com> Signed-off-by: Junio C Hamano <gitster@pobox.com>
2018-07-02 21:49:37 +02:00
}
istate->timestamp.sec = st.st_mtime;
istate->timestamp.nsec = ST_MTIME_NSEC(st);
/* if we created a thread, join it otherwise load the extensions on the primary thread */
if (extension_offset) {
int ret = pthread_join(p.pthread, NULL);
if (ret)
die(_("unable to join load_index_extensions thread: %s"), strerror(ret));
} else {
p.src_offset = src_offset;
load_index_extensions(&p);
}
munmap((void *)mmap, mmap_size);
/*
* TODO trace2: replace "the_repository" with the actual repo instance
* that is associated with the given "istate".
*/
trace2_data_intmax("index", the_repository, "read/version",
istate->version);
trace2_data_intmax("index", the_repository, "read/cache_nr",
istate->cache_nr);
if (!istate->repo)
istate->repo = the_repository;
/*
* If the command explicitly requires a full index, force it
* to be full. Otherwise, correct the sparsity based on repository
* settings and other properties of the index (if necessary).
*/
prepare_repo_settings(istate->repo);
if (istate->repo->settings.command_requires_full_index)
ensure_full_index(istate);
else
ensure_correct_sparsity(istate);
return istate->cache_nr;
unmap:
munmap((void *)mmap, mmap_size);
die(_("index file corrupt"));
}
/*
* Signal that the shared index is used by updating its mtime.
*
* This way, shared index can be removed if they have not been used
* for some time.
*/
read-cache: fix reading the shared index for other repos read_index_from() takes a path argument for the location of the index file. For reading the shared index in split index mode however it just ignores that path argument, and reads it from the gitdir of the current repository. This works as long as an index in the_repository is read. Once that changes, such as when we read the index of a submodule, or of a different working tree than the current one, the gitdir of the_repository will no longer contain the appropriate shared index, and git will fail to read it. For example t3007-ls-files-recurse-submodules.sh was broken with GIT_TEST_SPLIT_INDEX set in 188dce131f ("ls-files: use repository object", 2017-06-22), and t7814-grep-recurse-submodules.sh was also broken in a similar manner, probably by introducing struct repository there, although I didn't track down the exact commit for that. be489d02d2 ("revision.c: --indexed-objects add objects from all worktrees", 2017-08-23) breaks with split index mode in a similar manner, not erroring out when it can't read the index, but instead carrying on with pruning, without taking the index of the worktree into account. Fix this by passing an additional gitdir parameter to read_index_from, to indicate where it should look for and read the shared index from. read_cache_from() defaults to using the gitdir of the_repository. As it is mostly a convenience macro, having to pass get_git_dir() for every call seems overkill, and if necessary users can have more control by using read_index_from(). Helped-by: Brandon Williams <bmwill@google.com> Signed-off-by: Thomas Gummerer <t.gummerer@gmail.com> Signed-off-by: Junio C Hamano <gitster@pobox.com>
2018-01-07 23:30:13 +01:00
static void freshen_shared_index(const char *shared_index, int warn)
{
if (!check_and_freshen_file(shared_index, 1) && warn)
warning(_("could not freshen shared index '%s'"), shared_index);
}
read-cache: fix reading the shared index for other repos read_index_from() takes a path argument for the location of the index file. For reading the shared index in split index mode however it just ignores that path argument, and reads it from the gitdir of the current repository. This works as long as an index in the_repository is read. Once that changes, such as when we read the index of a submodule, or of a different working tree than the current one, the gitdir of the_repository will no longer contain the appropriate shared index, and git will fail to read it. For example t3007-ls-files-recurse-submodules.sh was broken with GIT_TEST_SPLIT_INDEX set in 188dce131f ("ls-files: use repository object", 2017-06-22), and t7814-grep-recurse-submodules.sh was also broken in a similar manner, probably by introducing struct repository there, although I didn't track down the exact commit for that. be489d02d2 ("revision.c: --indexed-objects add objects from all worktrees", 2017-08-23) breaks with split index mode in a similar manner, not erroring out when it can't read the index, but instead carrying on with pruning, without taking the index of the worktree into account. Fix this by passing an additional gitdir parameter to read_index_from, to indicate where it should look for and read the shared index from. read_cache_from() defaults to using the gitdir of the_repository. As it is mostly a convenience macro, having to pass get_git_dir() for every call seems overkill, and if necessary users can have more control by using read_index_from(). Helped-by: Brandon Williams <bmwill@google.com> Signed-off-by: Thomas Gummerer <t.gummerer@gmail.com> Signed-off-by: Junio C Hamano <gitster@pobox.com>
2018-01-07 23:30:13 +01:00
int read_index_from(struct index_state *istate, const char *path,
const char *gitdir)
{
struct split_index *split_index;
int ret;
char *base_oid_hex;
read-cache: fix reading the shared index for other repos read_index_from() takes a path argument for the location of the index file. For reading the shared index in split index mode however it just ignores that path argument, and reads it from the gitdir of the current repository. This works as long as an index in the_repository is read. Once that changes, such as when we read the index of a submodule, or of a different working tree than the current one, the gitdir of the_repository will no longer contain the appropriate shared index, and git will fail to read it. For example t3007-ls-files-recurse-submodules.sh was broken with GIT_TEST_SPLIT_INDEX set in 188dce131f ("ls-files: use repository object", 2017-06-22), and t7814-grep-recurse-submodules.sh was also broken in a similar manner, probably by introducing struct repository there, although I didn't track down the exact commit for that. be489d02d2 ("revision.c: --indexed-objects add objects from all worktrees", 2017-08-23) breaks with split index mode in a similar manner, not erroring out when it can't read the index, but instead carrying on with pruning, without taking the index of the worktree into account. Fix this by passing an additional gitdir parameter to read_index_from, to indicate where it should look for and read the shared index from. read_cache_from() defaults to using the gitdir of the_repository. As it is mostly a convenience macro, having to pass get_git_dir() for every call seems overkill, and if necessary users can have more control by using read_index_from(). Helped-by: Brandon Williams <bmwill@google.com> Signed-off-by: Thomas Gummerer <t.gummerer@gmail.com> Signed-off-by: Junio C Hamano <gitster@pobox.com>
2018-01-07 23:30:13 +01:00
char *base_path;
/* istate->initialized covers both .git/index and .git/sharedindex.xxx */
if (istate->initialized)
return istate->cache_nr;
/*
* TODO trace2: replace "the_repository" with the actual repo instance
* that is associated with the given "istate".
*/
trace2_region_enter_printf("index", "do_read_index", the_repository,
"%s", path);
trace_performance_enter();
ret = do_read_index(istate, path, 0);
trace_performance_leave("read cache %s", path);
trace2_region_leave_printf("index", "do_read_index", the_repository,
"%s", path);
config: add core.untrackedCache When we know that mtime on directory as given by the environment is usable for the purpose of untracked cache, we may want the untracked cache to be always used without any mtime test or kernel name check being performed. Also when we know that mtime is not usable for the purpose of untracked cache, for example because the repo is shared over a network file system, we may want the untracked-cache to be automatically removed from the index. Allow the user to express such preference by setting the 'core.untrackedCache' configuration variable, which can take 'keep', 'false', or 'true' and default to 'keep'. When read_index_from() is called, it now adds or removes the untracked cache in the index to respect the value of this variable. So it does nothing if the value is `keep` or if the variable is unset; it adds the untracked cache if the value is `true`; and it removes the cache if the value is `false`. `git update-index --[no-|force-]untracked-cache` still adds the untracked cache to, or removes it, from the index, but this shows a warning if it goes against the value of core.untrackedCache, because the next time the index is read the untracked cache will be added or removed if the configuration is set to do so. Also `--untracked-cache` used to check that the underlying operating system and file system change `st_mtime` field of a directory if files are added or deleted in that directory. But because those tests take a long time, `--untracked-cache` no longer performs them. Instead, there is now `--test-untracked-cache` to perform the tests. This change makes `--untracked-cache` the same as `--force-untracked-cache`. This last change is backward incompatible and should be mentioned in the release notes. Helped-by: Duy Nguyen <pclouds@gmail.com> Helped-by: Torsten Bögershausen <tboegi@web.de> Helped-by: Stefan Beller <sbeller@google.com> Signed-off-by: Christian Couder <chriscool@tuxfamily.org> Signed-off-by: Ævar Arnfjörð Bjarmason <avarab@gmail.com> read-cache: Duy'sfixup Signed-off-by: Christian Couder <chriscool@tuxfamily.org> Signed-off-by: Junio C Hamano <gitster@pobox.com>
2016-01-27 07:58:05 +01:00
split_index = istate->split_index;
if (!split_index || is_null_oid(&split_index->base_oid)) {
config: add core.untrackedCache When we know that mtime on directory as given by the environment is usable for the purpose of untracked cache, we may want the untracked cache to be always used without any mtime test or kernel name check being performed. Also when we know that mtime is not usable for the purpose of untracked cache, for example because the repo is shared over a network file system, we may want the untracked-cache to be automatically removed from the index. Allow the user to express such preference by setting the 'core.untrackedCache' configuration variable, which can take 'keep', 'false', or 'true' and default to 'keep'. When read_index_from() is called, it now adds or removes the untracked cache in the index to respect the value of this variable. So it does nothing if the value is `keep` or if the variable is unset; it adds the untracked cache if the value is `true`; and it removes the cache if the value is `false`. `git update-index --[no-|force-]untracked-cache` still adds the untracked cache to, or removes it, from the index, but this shows a warning if it goes against the value of core.untrackedCache, because the next time the index is read the untracked cache will be added or removed if the configuration is set to do so. Also `--untracked-cache` used to check that the underlying operating system and file system change `st_mtime` field of a directory if files are added or deleted in that directory. But because those tests take a long time, `--untracked-cache` no longer performs them. Instead, there is now `--test-untracked-cache` to perform the tests. This change makes `--untracked-cache` the same as `--force-untracked-cache`. This last change is backward incompatible and should be mentioned in the release notes. Helped-by: Duy Nguyen <pclouds@gmail.com> Helped-by: Torsten Bögershausen <tboegi@web.de> Helped-by: Stefan Beller <sbeller@google.com> Signed-off-by: Christian Couder <chriscool@tuxfamily.org> Signed-off-by: Ævar Arnfjörð Bjarmason <avarab@gmail.com> read-cache: Duy'sfixup Signed-off-by: Christian Couder <chriscool@tuxfamily.org> Signed-off-by: Junio C Hamano <gitster@pobox.com>
2016-01-27 07:58:05 +01:00
post_read_index_from(istate);
return ret;
}
trace_performance_enter();
if (split_index->base)
discard_index(split_index->base);
else
CALLOC_ARRAY(split_index->base, 1);
base_oid_hex = oid_to_hex(&split_index->base_oid);
base_path = xstrfmt("%s/sharedindex.%s", gitdir, base_oid_hex);
trace2_region_enter_printf("index", "shared/do_read_index",
the_repository, "%s", base_path);
read-cache: look for shared index files next to the index, too When reading a split index git always looks for its referenced shared base index in the gitdir of the current repository, even when reading an alternate index specified via GIT_INDEX_FILE, and even when that alternate index file is the "main" '.git/index' file of an other repository. However, if that split index and its referenced shared index files were written by a git command running entirely in that other repository, then, naturally, the shared index file is written to that other repository's gitdir. Consequently, a git command attempting to read that shared index file while running in a different repository won't be able find it and will error out. I'm not sure in what use case it is necessary to read the index of one repository by a git command running in a different repository, but it is certainly possible to do so, and in fact the test 'bare repository: check that --cached honors index' in 't0003-attributes.sh' does exactly that. If GIT_TEST_SPLIT_INDEX=1 were to split the index in just the right moment [1], then this test would indeed fail, because the referenced shared index file could not be found. Let's look for the referenced shared index file not only in the gitdir of the current directory, but, if the shared index is not there, right next to the split index as well. [1] We haven't seen this issue trigger a failure in t0003 yet, because: - While GIT_TEST_SPLIT_INDEX=1 is supposed to trigger index splitting randomly, the first index write has always been deterministic and it has never split the index. - That alternate index file in the other repository is written only once in the entire test script, so it's never split. However, the next patch will fix GIT_TEST_SPLIT_INDEX, and while doing so it will slightly change its behavior to always split the index already on the first index write, and t0003 would always fail without this patch. Signed-off-by: SZEDER Gábor <szeder.dev@gmail.com> Acked-by: Derrick Stolee <dstolee@microsoft.com> Signed-off-by: Junio C Hamano <gitster@pobox.com>
2021-08-26 23:00:02 +02:00
ret = do_read_index(split_index->base, base_path, 0);
trace2_region_leave_printf("index", "shared/do_read_index",
the_repository, "%s", base_path);
read-cache: look for shared index files next to the index, too When reading a split index git always looks for its referenced shared base index in the gitdir of the current repository, even when reading an alternate index specified via GIT_INDEX_FILE, and even when that alternate index file is the "main" '.git/index' file of an other repository. However, if that split index and its referenced shared index files were written by a git command running entirely in that other repository, then, naturally, the shared index file is written to that other repository's gitdir. Consequently, a git command attempting to read that shared index file while running in a different repository won't be able find it and will error out. I'm not sure in what use case it is necessary to read the index of one repository by a git command running in a different repository, but it is certainly possible to do so, and in fact the test 'bare repository: check that --cached honors index' in 't0003-attributes.sh' does exactly that. If GIT_TEST_SPLIT_INDEX=1 were to split the index in just the right moment [1], then this test would indeed fail, because the referenced shared index file could not be found. Let's look for the referenced shared index file not only in the gitdir of the current directory, but, if the shared index is not there, right next to the split index as well. [1] We haven't seen this issue trigger a failure in t0003 yet, because: - While GIT_TEST_SPLIT_INDEX=1 is supposed to trigger index splitting randomly, the first index write has always been deterministic and it has never split the index. - That alternate index file in the other repository is written only once in the entire test script, so it's never split. However, the next patch will fix GIT_TEST_SPLIT_INDEX, and while doing so it will slightly change its behavior to always split the index already on the first index write, and t0003 would always fail without this patch. Signed-off-by: SZEDER Gábor <szeder.dev@gmail.com> Acked-by: Derrick Stolee <dstolee@microsoft.com> Signed-off-by: Junio C Hamano <gitster@pobox.com>
2021-08-26 23:00:02 +02:00
if (!ret) {
char *path_copy = xstrdup(path);
const char *base_path2 = xstrfmt("%s/sharedindex.%s",
dirname(path_copy),
base_oid_hex);
free(path_copy);
trace2_region_enter_printf("index", "shared/do_read_index",
the_repository, "%s", base_path2);
ret = do_read_index(split_index->base, base_path2, 1);
trace2_region_leave_printf("index", "shared/do_read_index",
the_repository, "%s", base_path2);
}
if (!oideq(&split_index->base_oid, &split_index->base->oid))
die(_("broken index, expect %s in %s, got %s"),
base_oid_hex, base_path,
oid_to_hex(&split_index->base->oid));
read-cache: fix reading the shared index for other repos read_index_from() takes a path argument for the location of the index file. For reading the shared index in split index mode however it just ignores that path argument, and reads it from the gitdir of the current repository. This works as long as an index in the_repository is read. Once that changes, such as when we read the index of a submodule, or of a different working tree than the current one, the gitdir of the_repository will no longer contain the appropriate shared index, and git will fail to read it. For example t3007-ls-files-recurse-submodules.sh was broken with GIT_TEST_SPLIT_INDEX set in 188dce131f ("ls-files: use repository object", 2017-06-22), and t7814-grep-recurse-submodules.sh was also broken in a similar manner, probably by introducing struct repository there, although I didn't track down the exact commit for that. be489d02d2 ("revision.c: --indexed-objects add objects from all worktrees", 2017-08-23) breaks with split index mode in a similar manner, not erroring out when it can't read the index, but instead carrying on with pruning, without taking the index of the worktree into account. Fix this by passing an additional gitdir parameter to read_index_from, to indicate where it should look for and read the shared index from. read_cache_from() defaults to using the gitdir of the_repository. As it is mostly a convenience macro, having to pass get_git_dir() for every call seems overkill, and if necessary users can have more control by using read_index_from(). Helped-by: Brandon Williams <bmwill@google.com> Signed-off-by: Thomas Gummerer <t.gummerer@gmail.com> Signed-off-by: Junio C Hamano <gitster@pobox.com>
2018-01-07 23:30:13 +01:00
freshen_shared_index(base_path, 0);
merge_base_index(istate);
config: add core.untrackedCache When we know that mtime on directory as given by the environment is usable for the purpose of untracked cache, we may want the untracked cache to be always used without any mtime test or kernel name check being performed. Also when we know that mtime is not usable for the purpose of untracked cache, for example because the repo is shared over a network file system, we may want the untracked-cache to be automatically removed from the index. Allow the user to express such preference by setting the 'core.untrackedCache' configuration variable, which can take 'keep', 'false', or 'true' and default to 'keep'. When read_index_from() is called, it now adds or removes the untracked cache in the index to respect the value of this variable. So it does nothing if the value is `keep` or if the variable is unset; it adds the untracked cache if the value is `true`; and it removes the cache if the value is `false`. `git update-index --[no-|force-]untracked-cache` still adds the untracked cache to, or removes it, from the index, but this shows a warning if it goes against the value of core.untrackedCache, because the next time the index is read the untracked cache will be added or removed if the configuration is set to do so. Also `--untracked-cache` used to check that the underlying operating system and file system change `st_mtime` field of a directory if files are added or deleted in that directory. But because those tests take a long time, `--untracked-cache` no longer performs them. Instead, there is now `--test-untracked-cache` to perform the tests. This change makes `--untracked-cache` the same as `--force-untracked-cache`. This last change is backward incompatible and should be mentioned in the release notes. Helped-by: Duy Nguyen <pclouds@gmail.com> Helped-by: Torsten Bögershausen <tboegi@web.de> Helped-by: Stefan Beller <sbeller@google.com> Signed-off-by: Christian Couder <chriscool@tuxfamily.org> Signed-off-by: Ævar Arnfjörð Bjarmason <avarab@gmail.com> read-cache: Duy'sfixup Signed-off-by: Christian Couder <chriscool@tuxfamily.org> Signed-off-by: Junio C Hamano <gitster@pobox.com>
2016-01-27 07:58:05 +01:00
post_read_index_from(istate);
trace_performance_leave("read cache %s", base_path);
free(base_path);
return ret;
}
int is_index_unborn(struct index_state *istate)
{
return (!istate->cache_nr && !istate->timestamp.sec);
}
int discard_index(struct index_state *istate)
{
block alloc: allocate cache entries from mem_pool When reading large indexes from disk, a portion of the time is dominated in malloc() calls. This can be mitigated by allocating a large block of memory and manage it ourselves via memory pools. This change moves the cache entry allocation to be on top of memory pools. Design: The index_state struct will gain a notion of an associated memory_pool from which cache_entries will be allocated from. When reading in the index from disk, we have information on the number of entries and their size, which can guide us in deciding how large our initial memory allocation should be. When an index is discarded, the associated memory_pool will be discarded as well - so the lifetime of a cache_entry is tied to the lifetime of the index_state that it was allocated for. In the case of a Split Index, the following rules are followed. 1st, some terminology is defined: Terminology: - 'the_index': represents the logical view of the index - 'split_index': represents the "base" cache entries. Read from the split index file. 'the_index' can reference a single split_index, as well as cache_entries from the split_index. `the_index` will be discarded before the `split_index` is. This means that when we are allocating cache_entries in the presence of a split index, we need to allocate the entries from the `split_index`'s memory pool. This allows us to follow the pattern that `the_index` can reference cache_entries from the `split_index`, and that the cache_entries will not be freed while they are still being referenced. Managing transient cache_entry structs: Cache entries are usually allocated for an index, but this is not always the case. Cache entries are sometimes allocated because this is the type that the existing checkout_entry function works with. Because of this, the existing code needs to handle cache entries associated with an index / memory pool, and those that only exist transiently. Several strategies were contemplated around how to handle this: Chosen approach: An extra field was added to the cache_entry type to track whether the cache_entry was allocated from a memory pool or not. This is currently an int field, as there are no more available bits in the existing ce_flags bit field. If / when more bits are needed, this new field can be turned into a proper bit field. Alternatives: 1) Do not include any information about how the cache_entry was allocated. Calling code would be responsible for tracking whether the cache_entry needed to be freed or not. Pro: No extra memory overhead to track this state Con: Extra complexity in callers to handle this correctly. The extra complexity and burden to not regress this behavior in the future was more than we wanted. 2) cache_entry would gain knowledge about which mem_pool allocated it Pro: Could (potentially) do extra logic to know when a mem_pool no longer had references to any cache_entry Con: cache_entry would grow heavier by a pointer, instead of int We didn't see a tangible benefit to this approach 3) Do not add any extra information to a cache_entry, but when freeing a cache entry, check if the memory exists in a region managed by existing mem_pools. Pro: No extra memory overhead to track state Con: Extra computation is performed when freeing cache entries We decided tracking and iterating over known memory pool regions was less desirable than adding an extra field to track this stae. Signed-off-by: Jameson Miller <jamill@microsoft.com> Signed-off-by: Junio C Hamano <gitster@pobox.com>
2018-07-02 21:49:37 +02:00
/*
* Cache entries in istate->cache[] should have been allocated
* from the memory pool associated with this index, or from an
* associated split_index. There is no need to free individual
* cache entries. validate_cache_entries can detect when this
* assertion does not hold.
block alloc: allocate cache entries from mem_pool When reading large indexes from disk, a portion of the time is dominated in malloc() calls. This can be mitigated by allocating a large block of memory and manage it ourselves via memory pools. This change moves the cache entry allocation to be on top of memory pools. Design: The index_state struct will gain a notion of an associated memory_pool from which cache_entries will be allocated from. When reading in the index from disk, we have information on the number of entries and their size, which can guide us in deciding how large our initial memory allocation should be. When an index is discarded, the associated memory_pool will be discarded as well - so the lifetime of a cache_entry is tied to the lifetime of the index_state that it was allocated for. In the case of a Split Index, the following rules are followed. 1st, some terminology is defined: Terminology: - 'the_index': represents the logical view of the index - 'split_index': represents the "base" cache entries. Read from the split index file. 'the_index' can reference a single split_index, as well as cache_entries from the split_index. `the_index` will be discarded before the `split_index` is. This means that when we are allocating cache_entries in the presence of a split index, we need to allocate the entries from the `split_index`'s memory pool. This allows us to follow the pattern that `the_index` can reference cache_entries from the `split_index`, and that the cache_entries will not be freed while they are still being referenced. Managing transient cache_entry structs: Cache entries are usually allocated for an index, but this is not always the case. Cache entries are sometimes allocated because this is the type that the existing checkout_entry function works with. Because of this, the existing code needs to handle cache entries associated with an index / memory pool, and those that only exist transiently. Several strategies were contemplated around how to handle this: Chosen approach: An extra field was added to the cache_entry type to track whether the cache_entry was allocated from a memory pool or not. This is currently an int field, as there are no more available bits in the existing ce_flags bit field. If / when more bits are needed, this new field can be turned into a proper bit field. Alternatives: 1) Do not include any information about how the cache_entry was allocated. Calling code would be responsible for tracking whether the cache_entry needed to be freed or not. Pro: No extra memory overhead to track this state Con: Extra complexity in callers to handle this correctly. The extra complexity and burden to not regress this behavior in the future was more than we wanted. 2) cache_entry would gain knowledge about which mem_pool allocated it Pro: Could (potentially) do extra logic to know when a mem_pool no longer had references to any cache_entry Con: cache_entry would grow heavier by a pointer, instead of int We didn't see a tangible benefit to this approach 3) Do not add any extra information to a cache_entry, but when freeing a cache entry, check if the memory exists in a region managed by existing mem_pools. Pro: No extra memory overhead to track state Con: Extra computation is performed when freeing cache entries We decided tracking and iterating over known memory pool regions was less desirable than adding an extra field to track this stae. Signed-off-by: Jameson Miller <jamill@microsoft.com> Signed-off-by: Junio C Hamano <gitster@pobox.com>
2018-07-02 21:49:37 +02:00
*/
validate_cache_entries(istate);
resolve_undo_clear_index(istate);
istate->cache_nr = 0;
istate->cache_changed = 0;
istate->timestamp.sec = 0;
istate->timestamp.nsec = 0;
name-hash.c: fix endless loop with core.ignorecase=true With core.ignorecase=true, name-hash.c builds a case insensitive index of all tracked directories. Currently, the existing cache entry structures are added multiple times to the same hashtable (with different name lengths and hash codes). However, there's only one dir_next pointer, which gets completely messed up in case of hash collisions. In the worst case, this causes an endless loop if ce == ce->dir_next (see t7062). Use a separate hashtable and separate structures for the directory index so that each directory entry has its own next pointer. Use reference counting to track which directory entry contains files. There are only slight changes to the name-hash.c API: - new free_name_hash() used by read_cache.c::discard_index() - remove_name_hash() takes an additional index_state parameter - index_name_exists() for a directory (trailing '/') may return a cache entry that has been removed (CE_UNHASHED). This is not a problem as the return value is only used to check if the directory exists (dir.c) or to normalize casing of directory names (read-cache.c). Getting rid of cache_entry.dir_next reduces memory consumption, especially with core.ignorecase=false (which doesn't use that member at all). With core.ignorecase=true, building the directory index is slightly faster as we add / check the parent directory first (instead of going through all directory levels for each file in the index). E.g. with WebKit (~200k files, ~7k dirs), time spent in lazy_init_name_hash is reduced from 176ms to 130ms. Signed-off-by: Karsten Blees <blees@dcon.de> Signed-off-by: Junio C Hamano <gitster@pobox.com>
2013-02-28 00:57:48 +01:00
free_name_hash(istate);
cache_tree_free(&(istate->cache_tree));
unpack_trees(): protect the handcrafted in-core index from read_cache() unpack_trees() rebuilds the in-core index from scratch by allocating a new structure and finishing it off by copying the built one to the final index. The resulting in-core index is Ok for most use, but read_cache() does not recognize it as such. The function is meant to be no-op if you already have loaded the index, until you call discard_cache(). This change the way read_cache() detects an already initialized in-core index, by introducing an extra bit, and marks the handcrafted in-core index as initialized, to avoid this problem. A better fix in the longer term would be to change the read_cache() API so that it will always discard and re-read from the on-disk index to avoid confusion. But there are higher level API that have relied on the current semantics, and they and their users all need to get converted, which is outside the scope of 'maint' track. An example of such a higher level API is write_cache_as_tree(), which is used by git-write-tree as well as later Porcelains like git-merge, revert and cherry-pick. In the longer term, we should remove read_cache() from there and add one to cmd_write_tree(); other callers expect that the in-core index they prepared is what gets written as a tree so no other change is necessary for this particular codepath. The original version of this patch marked the index by pointing an otherwise wasted malloc'ed memory with o->result.alloc, but this version uses Linus's idea to use a new "initialized" bit, which is conceptually much cleaner. Signed-off-by: Junio C Hamano <gitster@pobox.com>
2008-08-23 21:57:30 +02:00
istate->initialized = 0;
istate->fsmonitor_has_run_once = 0;
FREE_AND_NULL(istate->fsmonitor_last_update);
FREE_AND_NULL(istate->cache);
istate->cache_alloc = 0;
discard_split_index(istate);
free_untracked_cache(istate->untracked);
istate->untracked = NULL;
block alloc: allocate cache entries from mem_pool When reading large indexes from disk, a portion of the time is dominated in malloc() calls. This can be mitigated by allocating a large block of memory and manage it ourselves via memory pools. This change moves the cache entry allocation to be on top of memory pools. Design: The index_state struct will gain a notion of an associated memory_pool from which cache_entries will be allocated from. When reading in the index from disk, we have information on the number of entries and their size, which can guide us in deciding how large our initial memory allocation should be. When an index is discarded, the associated memory_pool will be discarded as well - so the lifetime of a cache_entry is tied to the lifetime of the index_state that it was allocated for. In the case of a Split Index, the following rules are followed. 1st, some terminology is defined: Terminology: - 'the_index': represents the logical view of the index - 'split_index': represents the "base" cache entries. Read from the split index file. 'the_index' can reference a single split_index, as well as cache_entries from the split_index. `the_index` will be discarded before the `split_index` is. This means that when we are allocating cache_entries in the presence of a split index, we need to allocate the entries from the `split_index`'s memory pool. This allows us to follow the pattern that `the_index` can reference cache_entries from the `split_index`, and that the cache_entries will not be freed while they are still being referenced. Managing transient cache_entry structs: Cache entries are usually allocated for an index, but this is not always the case. Cache entries are sometimes allocated because this is the type that the existing checkout_entry function works with. Because of this, the existing code needs to handle cache entries associated with an index / memory pool, and those that only exist transiently. Several strategies were contemplated around how to handle this: Chosen approach: An extra field was added to the cache_entry type to track whether the cache_entry was allocated from a memory pool or not. This is currently an int field, as there are no more available bits in the existing ce_flags bit field. If / when more bits are needed, this new field can be turned into a proper bit field. Alternatives: 1) Do not include any information about how the cache_entry was allocated. Calling code would be responsible for tracking whether the cache_entry needed to be freed or not. Pro: No extra memory overhead to track this state Con: Extra complexity in callers to handle this correctly. The extra complexity and burden to not regress this behavior in the future was more than we wanted. 2) cache_entry would gain knowledge about which mem_pool allocated it Pro: Could (potentially) do extra logic to know when a mem_pool no longer had references to any cache_entry Con: cache_entry would grow heavier by a pointer, instead of int We didn't see a tangible benefit to this approach 3) Do not add any extra information to a cache_entry, but when freeing a cache entry, check if the memory exists in a region managed by existing mem_pools. Pro: No extra memory overhead to track state Con: Extra computation is performed when freeing cache entries We decided tracking and iterating over known memory pool regions was less desirable than adding an extra field to track this stae. Signed-off-by: Jameson Miller <jamill@microsoft.com> Signed-off-by: Junio C Hamano <gitster@pobox.com>
2018-07-02 21:49:37 +02:00
if (istate->ce_mem_pool) {
mem_pool_discard(istate->ce_mem_pool, should_validate_cache_entries());
mem-pool: use more standard initialization and finalization A typical memory type, such as strbuf, hashmap, or string_list can be stored on the stack or embedded within another structure. mem_pool cannot be, because of how mem_pool_init() and mem_pool_discard() are written. mem_pool_init() does essentially the following (simplified for purposes of explanation here): void mem_pool_init(struct mem_pool **pool...) { *pool = xcalloc(1, sizeof(*pool)); It seems weird to require that mem_pools can only be accessed through a pointer. It also seems slightly dangerous: unlike strbuf_release() or strbuf_reset() or string_list_clear(), all of which put the data structure into a state where it can be re-used after the call, mem_pool_discard(pool) will leave pool pointing at free'd memory. read-cache (and split-index) are the only current users of mem_pools, and they haven't fallen into a use-after-free mistake here, but it seems likely to be problematic for future users especially since several of the current callers of mem_pool_init() will only call it when the mem_pool* is not already allocated (i.e. is NULL). This type of mechanism also prevents finding synchronization points where one can free existing memory and then resume more operations. It would be natural at such points to run something like mem_pool_discard(pool...); and, if necessary, mem_pool_init(&pool...); and then carry on continuing to use the pool. However, this fails badly if several objects had a copy of the value of pool from before these commands; in such a case, those objects won't get the updated value of pool that mem_pool_init() overwrites pool with and they'll all instead be reading and writing from free'd memory. Modify mem_pool_init()/mem_pool_discard() to behave more like strbuf_init()/strbuf_release() or string_list_init()/string_list_clear() In particular: (1) make mem_pool_init() just take a mem_pool* and have it only worry about allocating struct mp_blocks, not the struct mem_pool itself, (2) make mem_pool_discard() free the memory that the pool was responsible for, but leave it in a state where it can be used to allocate more memory afterward (without the need to call mem_pool_init() again). Signed-off-by: Elijah Newren <newren@gmail.com> Signed-off-by: Junio C Hamano <gitster@pobox.com>
2020-08-15 19:37:56 +02:00
FREE_AND_NULL(istate->ce_mem_pool);
block alloc: allocate cache entries from mem_pool When reading large indexes from disk, a portion of the time is dominated in malloc() calls. This can be mitigated by allocating a large block of memory and manage it ourselves via memory pools. This change moves the cache entry allocation to be on top of memory pools. Design: The index_state struct will gain a notion of an associated memory_pool from which cache_entries will be allocated from. When reading in the index from disk, we have information on the number of entries and their size, which can guide us in deciding how large our initial memory allocation should be. When an index is discarded, the associated memory_pool will be discarded as well - so the lifetime of a cache_entry is tied to the lifetime of the index_state that it was allocated for. In the case of a Split Index, the following rules are followed. 1st, some terminology is defined: Terminology: - 'the_index': represents the logical view of the index - 'split_index': represents the "base" cache entries. Read from the split index file. 'the_index' can reference a single split_index, as well as cache_entries from the split_index. `the_index` will be discarded before the `split_index` is. This means that when we are allocating cache_entries in the presence of a split index, we need to allocate the entries from the `split_index`'s memory pool. This allows us to follow the pattern that `the_index` can reference cache_entries from the `split_index`, and that the cache_entries will not be freed while they are still being referenced. Managing transient cache_entry structs: Cache entries are usually allocated for an index, but this is not always the case. Cache entries are sometimes allocated because this is the type that the existing checkout_entry function works with. Because of this, the existing code needs to handle cache entries associated with an index / memory pool, and those that only exist transiently. Several strategies were contemplated around how to handle this: Chosen approach: An extra field was added to the cache_entry type to track whether the cache_entry was allocated from a memory pool or not. This is currently an int field, as there are no more available bits in the existing ce_flags bit field. If / when more bits are needed, this new field can be turned into a proper bit field. Alternatives: 1) Do not include any information about how the cache_entry was allocated. Calling code would be responsible for tracking whether the cache_entry needed to be freed or not. Pro: No extra memory overhead to track this state Con: Extra complexity in callers to handle this correctly. The extra complexity and burden to not regress this behavior in the future was more than we wanted. 2) cache_entry would gain knowledge about which mem_pool allocated it Pro: Could (potentially) do extra logic to know when a mem_pool no longer had references to any cache_entry Con: cache_entry would grow heavier by a pointer, instead of int We didn't see a tangible benefit to this approach 3) Do not add any extra information to a cache_entry, but when freeing a cache entry, check if the memory exists in a region managed by existing mem_pools. Pro: No extra memory overhead to track state Con: Extra computation is performed when freeing cache entries We decided tracking and iterating over known memory pool regions was less desirable than adding an extra field to track this stae. Signed-off-by: Jameson Miller <jamill@microsoft.com> Signed-off-by: Junio C Hamano <gitster@pobox.com>
2018-07-02 21:49:37 +02:00
}
return 0;
}
/*
* Validate the cache entries of this index.
* All cache entries associated with this index
* should have been allocated by the memory pool
* associated with this index, or by a referenced
* split index.
*/
void validate_cache_entries(const struct index_state *istate)
{
int i;
if (!should_validate_cache_entries() ||!istate || !istate->initialized)
return;
for (i = 0; i < istate->cache_nr; i++) {
if (!istate) {
BUG("cache entry is not allocated from expected memory pool");
} else if (!istate->ce_mem_pool ||
!mem_pool_contains(istate->ce_mem_pool, istate->cache[i])) {
if (!istate->split_index ||
!istate->split_index->base ||
!istate->split_index->base->ce_mem_pool ||
!mem_pool_contains(istate->split_index->base->ce_mem_pool, istate->cache[i])) {
BUG("cache entry is not allocated from expected memory pool");
}
}
}
if (istate->split_index)
validate_cache_entries(istate->split_index->base);
}
int unmerged_index(const struct index_state *istate)
{
int i;
for (i = 0; i < istate->cache_nr; i++) {
if (ce_stage(istate->cache[i]))
return 1;
}
return 0;
}
int repo_index_has_changes(struct repository *repo,
struct tree *tree,
struct strbuf *sb)
{
struct index_state *istate = repo->index;
struct object_id cmp;
int i;
if (tree)
cmp = tree->object.oid;
if (tree || !get_oid_tree("HEAD", &cmp)) {
struct diff_options opt;
repo_diff_setup(repo, &opt);
opt.flags.exit_with_status = 1;
if (!sb)
opt.flags.quick = 1;
diff_setup_done(&opt);
do_diff_cache(&cmp, &opt);
diffcore_std(&opt);
for (i = 0; sb && i < diff_queued_diff.nr; i++) {
if (i)
strbuf_addch(sb, ' ');
strbuf_addstr(sb, diff_queued_diff.queue[i]->two->path);
}
diff_flush(&opt);
return opt.flags.has_changes != 0;
} else {
/* TODO: audit for interaction with sparse-index. */
ensure_full_index(istate);
for (i = 0; sb && i < istate->cache_nr; i++) {
if (i)
strbuf_addch(sb, ' ');
strbuf_addstr(sb, istate->cache[i]->name);
}
return !!istate->cache_nr;
}
}
read-cache: use hashfile instead of git_hash_ctx The do_write_index() method in read-cache.c has its own hashing logic and buffering mechanism. Specifically, the ce_write() method was introduced by 4990aadc (Speed up index file writing by chunking it nicely, 2005-04-20) and similar mechanisms were introduced a few months later in c38138cd (git-pack-objects: write the pack files with a SHA1 csum, 2005-06-26). Based on the timing, in the early days of the Git codebase, I figured that these roughly equivalent code paths were never unified only because it got lost in the shuffle. The hashfile API has since been used extensively in other file formats, such as pack-indexes, multi-pack-indexes, and commit-graphs. Therefore, it seems prudent to unify the index writing code to use the same mechanism. I discovered this disparity while trying to create a new index format that uses the chunk-format API. That API uses a hashfile as its base, so it is incompatible with the custom code in read-cache.c. This rewrite is rather straightforward. It replaces all writes to the temporary file with writes to the hashfile struct. This takes care of many of the direct interactions with the_hash_algo. There are still some git_hash_ctx uses remaining: the extension headers are hashed for use in the End of Index Entries (EOIE) extension. This use of the git_hash_ctx is left as-is. There are multiple reasons to not use a hashfile here, including the fact that the data is not actually writing to a file, just a hash computation. These hashes do not block our adoption of the chunk-format API in a future change to the index, so leave it as-is. The internals of the algorithms are mostly identical. Previously, the hashfile API used a smaller 8KB buffer instead of the 128KB buffer from read-cache.c. The previous change already unified these sizes. There is one subtle point: we do not pass the CSUM_FSYNC to the finalize_hashfile() method, which differs from most consumers of the hashfile API. The extra fsync() call indicated by this flag causes a significant peformance degradation that is noticeable for quick commands that write the index, such as "git add". Other consumers can absorb this cost with their more complicated data structure organization, and further writing structures such as pack-files and commit-graphs is rarely in the critical path for common user interactions. Some static methods become orphaned in this diff, so I marked them as MAYBE_UNUSED. The diff is much harder to read if they are deleted during this change. Instead, they will be deleted in the following change. In addition to the test suite passing, I computed indexes using the previous binaries and the binaries compiled after this change, and found the index data to be exactly equal. Finally, I did extensive performance testing of "git update-index --force-write" on repos of various sizes, including one with over 2 million paths at HEAD. These tests demonstrated less than 1% difference in behavior. As expected, the performance should be considered unchanged. The previous changes to increase the hashfile buffer size from 8K to 128K ensured this change would not create a peformance regression. Signed-off-by: Derrick Stolee <dstolee@microsoft.com> Signed-off-by: Junio C Hamano <gitster@pobox.com>
2021-05-18 20:32:47 +02:00
static int write_index_ext_header(struct hashfile *f,
git_hash_ctx *eoie_f,
unsigned int ext,
unsigned int sz)
{
read-cache: use hashfile instead of git_hash_ctx The do_write_index() method in read-cache.c has its own hashing logic and buffering mechanism. Specifically, the ce_write() method was introduced by 4990aadc (Speed up index file writing by chunking it nicely, 2005-04-20) and similar mechanisms were introduced a few months later in c38138cd (git-pack-objects: write the pack files with a SHA1 csum, 2005-06-26). Based on the timing, in the early days of the Git codebase, I figured that these roughly equivalent code paths were never unified only because it got lost in the shuffle. The hashfile API has since been used extensively in other file formats, such as pack-indexes, multi-pack-indexes, and commit-graphs. Therefore, it seems prudent to unify the index writing code to use the same mechanism. I discovered this disparity while trying to create a new index format that uses the chunk-format API. That API uses a hashfile as its base, so it is incompatible with the custom code in read-cache.c. This rewrite is rather straightforward. It replaces all writes to the temporary file with writes to the hashfile struct. This takes care of many of the direct interactions with the_hash_algo. There are still some git_hash_ctx uses remaining: the extension headers are hashed for use in the End of Index Entries (EOIE) extension. This use of the git_hash_ctx is left as-is. There are multiple reasons to not use a hashfile here, including the fact that the data is not actually writing to a file, just a hash computation. These hashes do not block our adoption of the chunk-format API in a future change to the index, so leave it as-is. The internals of the algorithms are mostly identical. Previously, the hashfile API used a smaller 8KB buffer instead of the 128KB buffer from read-cache.c. The previous change already unified these sizes. There is one subtle point: we do not pass the CSUM_FSYNC to the finalize_hashfile() method, which differs from most consumers of the hashfile API. The extra fsync() call indicated by this flag causes a significant peformance degradation that is noticeable for quick commands that write the index, such as "git add". Other consumers can absorb this cost with their more complicated data structure organization, and further writing structures such as pack-files and commit-graphs is rarely in the critical path for common user interactions. Some static methods become orphaned in this diff, so I marked them as MAYBE_UNUSED. The diff is much harder to read if they are deleted during this change. Instead, they will be deleted in the following change. In addition to the test suite passing, I computed indexes using the previous binaries and the binaries compiled after this change, and found the index data to be exactly equal. Finally, I did extensive performance testing of "git update-index --force-write" on repos of various sizes, including one with over 2 million paths at HEAD. These tests demonstrated less than 1% difference in behavior. As expected, the performance should be considered unchanged. The previous changes to increase the hashfile buffer size from 8K to 128K ensured this change would not create a peformance regression. Signed-off-by: Derrick Stolee <dstolee@microsoft.com> Signed-off-by: Junio C Hamano <gitster@pobox.com>
2021-05-18 20:32:47 +02:00
hashwrite_be32(f, ext);
hashwrite_be32(f, sz);
if (eoie_f) {
ext = htonl(ext);
sz = htonl(sz);
the_hash_algo->update_fn(eoie_f, &ext, sizeof(ext));
the_hash_algo->update_fn(eoie_f, &sz, sizeof(sz));
}
read-cache: use hashfile instead of git_hash_ctx The do_write_index() method in read-cache.c has its own hashing logic and buffering mechanism. Specifically, the ce_write() method was introduced by 4990aadc (Speed up index file writing by chunking it nicely, 2005-04-20) and similar mechanisms were introduced a few months later in c38138cd (git-pack-objects: write the pack files with a SHA1 csum, 2005-06-26). Based on the timing, in the early days of the Git codebase, I figured that these roughly equivalent code paths were never unified only because it got lost in the shuffle. The hashfile API has since been used extensively in other file formats, such as pack-indexes, multi-pack-indexes, and commit-graphs. Therefore, it seems prudent to unify the index writing code to use the same mechanism. I discovered this disparity while trying to create a new index format that uses the chunk-format API. That API uses a hashfile as its base, so it is incompatible with the custom code in read-cache.c. This rewrite is rather straightforward. It replaces all writes to the temporary file with writes to the hashfile struct. This takes care of many of the direct interactions with the_hash_algo. There are still some git_hash_ctx uses remaining: the extension headers are hashed for use in the End of Index Entries (EOIE) extension. This use of the git_hash_ctx is left as-is. There are multiple reasons to not use a hashfile here, including the fact that the data is not actually writing to a file, just a hash computation. These hashes do not block our adoption of the chunk-format API in a future change to the index, so leave it as-is. The internals of the algorithms are mostly identical. Previously, the hashfile API used a smaller 8KB buffer instead of the 128KB buffer from read-cache.c. The previous change already unified these sizes. There is one subtle point: we do not pass the CSUM_FSYNC to the finalize_hashfile() method, which differs from most consumers of the hashfile API. The extra fsync() call indicated by this flag causes a significant peformance degradation that is noticeable for quick commands that write the index, such as "git add". Other consumers can absorb this cost with their more complicated data structure organization, and further writing structures such as pack-files and commit-graphs is rarely in the critical path for common user interactions. Some static methods become orphaned in this diff, so I marked them as MAYBE_UNUSED. The diff is much harder to read if they are deleted during this change. Instead, they will be deleted in the following change. In addition to the test suite passing, I computed indexes using the previous binaries and the binaries compiled after this change, and found the index data to be exactly equal. Finally, I did extensive performance testing of "git update-index --force-write" on repos of various sizes, including one with over 2 million paths at HEAD. These tests demonstrated less than 1% difference in behavior. As expected, the performance should be considered unchanged. The previous changes to increase the hashfile buffer size from 8K to 128K ensured this change would not create a peformance regression. Signed-off-by: Derrick Stolee <dstolee@microsoft.com> Signed-off-by: Junio C Hamano <gitster@pobox.com>
2021-05-18 20:32:47 +02:00
return 0;
}
static void ce_smudge_racily_clean_entry(struct index_state *istate,
struct cache_entry *ce)
{
/*
* The only thing we care about in this function is to smudge the
* falsely clean entry due to touch-update-touch race, so we leave
* everything else as they are. We are called for entries whose
* ce_stat_data.sd_mtime match the index file mtime.
2008-07-29 10:13:44 +02:00
*
* Note that this actually does not do much for gitlinks, for
* which ce_match_stat_basic() always goes to the actual
* contents. The caller checks with is_racy_timestamp() which
* always says "no" for gitlinks, so we are not called for them ;-)
*/
struct stat st;
if (lstat(ce->name, &st) < 0)
return;
if (ce_match_stat_basic(ce, &st))
return;
if (ce_modified_check_fs(istate, ce, &st)) {
/* This is "racily clean"; smudge it. Note that this
* is a tricky code. At first glance, it may appear
* that it can break with this sequence:
*
* $ echo xyzzy >frotz
* $ git-update-index --add frotz
* $ : >frotz
* $ sleep 3
* $ echo filfre >nitfol
* $ git-update-index --add nitfol
*
* but it does not. When the second update-index runs,
* it notices that the entry "frotz" has the same timestamp
* as index, and if we were to smudge it by resetting its
* size to zero here, then the object name recorded
* in index is the 6-byte file but the cached stat information
* becomes zero --- which would then match what we would
* obtain from the filesystem next time we stat("frotz").
*
* However, the second update-index, before calling
* this function, notices that the cached size is 6
* bytes and what is on the filesystem is an empty
* file, and never calls us, so the cached size information
* for "frotz" stays 6 which does not match the filesystem.
*/
ce->ce_stat_data.sd_size = 0;
}
}
/* Copy miscellaneous fields but not the name */
static void copy_cache_entry_to_ondisk(struct ondisk_cache_entry *ondisk,
struct cache_entry *ce)
{
short flags;
const unsigned hashsz = the_hash_algo->rawsz;
uint16_t *flagsp = (uint16_t *)(ondisk->data + hashsz);
ondisk->ctime.sec = htonl(ce->ce_stat_data.sd_ctime.sec);
ondisk->mtime.sec = htonl(ce->ce_stat_data.sd_mtime.sec);
ondisk->ctime.nsec = htonl(ce->ce_stat_data.sd_ctime.nsec);
ondisk->mtime.nsec = htonl(ce->ce_stat_data.sd_mtime.nsec);
ondisk->dev = htonl(ce->ce_stat_data.sd_dev);
ondisk->ino = htonl(ce->ce_stat_data.sd_ino);
ondisk->mode = htonl(ce->ce_mode);
ondisk->uid = htonl(ce->ce_stat_data.sd_uid);
ondisk->gid = htonl(ce->ce_stat_data.sd_gid);
ondisk->size = htonl(ce->ce_stat_data.sd_size);
hashcpy(ondisk->data, ce->oid.hash);
flags = ce->ce_flags & ~CE_NAMEMASK;
flags |= (ce_namelen(ce) >= CE_NAMEMASK ? CE_NAMEMASK : ce_namelen(ce));
flagsp[0] = htons(flags);
if (ce->ce_flags & CE_EXTENDED) {
flagsp[1] = htons((ce->ce_flags & CE_EXTENDED_FLAGS) >> 16);
}
}
read-cache: use hashfile instead of git_hash_ctx The do_write_index() method in read-cache.c has its own hashing logic and buffering mechanism. Specifically, the ce_write() method was introduced by 4990aadc (Speed up index file writing by chunking it nicely, 2005-04-20) and similar mechanisms were introduced a few months later in c38138cd (git-pack-objects: write the pack files with a SHA1 csum, 2005-06-26). Based on the timing, in the early days of the Git codebase, I figured that these roughly equivalent code paths were never unified only because it got lost in the shuffle. The hashfile API has since been used extensively in other file formats, such as pack-indexes, multi-pack-indexes, and commit-graphs. Therefore, it seems prudent to unify the index writing code to use the same mechanism. I discovered this disparity while trying to create a new index format that uses the chunk-format API. That API uses a hashfile as its base, so it is incompatible with the custom code in read-cache.c. This rewrite is rather straightforward. It replaces all writes to the temporary file with writes to the hashfile struct. This takes care of many of the direct interactions with the_hash_algo. There are still some git_hash_ctx uses remaining: the extension headers are hashed for use in the End of Index Entries (EOIE) extension. This use of the git_hash_ctx is left as-is. There are multiple reasons to not use a hashfile here, including the fact that the data is not actually writing to a file, just a hash computation. These hashes do not block our adoption of the chunk-format API in a future change to the index, so leave it as-is. The internals of the algorithms are mostly identical. Previously, the hashfile API used a smaller 8KB buffer instead of the 128KB buffer from read-cache.c. The previous change already unified these sizes. There is one subtle point: we do not pass the CSUM_FSYNC to the finalize_hashfile() method, which differs from most consumers of the hashfile API. The extra fsync() call indicated by this flag causes a significant peformance degradation that is noticeable for quick commands that write the index, such as "git add". Other consumers can absorb this cost with their more complicated data structure organization, and further writing structures such as pack-files and commit-graphs is rarely in the critical path for common user interactions. Some static methods become orphaned in this diff, so I marked them as MAYBE_UNUSED. The diff is much harder to read if they are deleted during this change. Instead, they will be deleted in the following change. In addition to the test suite passing, I computed indexes using the previous binaries and the binaries compiled after this change, and found the index data to be exactly equal. Finally, I did extensive performance testing of "git update-index --force-write" on repos of various sizes, including one with over 2 million paths at HEAD. These tests demonstrated less than 1% difference in behavior. As expected, the performance should be considered unchanged. The previous changes to increase the hashfile buffer size from 8K to 128K ensured this change would not create a peformance regression. Signed-off-by: Derrick Stolee <dstolee@microsoft.com> Signed-off-by: Junio C Hamano <gitster@pobox.com>
2021-05-18 20:32:47 +02:00
static int ce_write_entry(struct hashfile *f, struct cache_entry *ce,
struct strbuf *previous_name, struct ondisk_cache_entry *ondisk)
{
int size;
read-cache: fix an -Wmaybe-uninitialized warning The function ce_write_entry() uses a 'self-initialised' variable construct, for the symbol 'saved_namelen', to suppress a gcc '-Wmaybe-uninitialized' warning, given that the warning is a false positive. For the purposes of this discussion, the ce_write_entry() function has three code blocks of interest, that look like so: /* block #1 */ if (ce->ce_flags & CE_STRIP_NAME) { saved_namelen = ce_namelen(ce); ce->ce_namelen = 0; } /* block #2 */ /* * several code blocks that contain, among others, calls * to copy_cache_entry_to_ondisk(ondisk, ce); */ /* block #3 */ if (ce->ce_flags & CE_STRIP_NAME) { ce->ce_namelen = saved_namelen; ce->ce_flags &= ~CE_STRIP_NAME; } The warning implies that gcc thinks it is possible that the first block is not entered, the calls to copy_cache_entry_to_ondisk() could toggle the CE_STRIP_NAME flag on, thereby entering block #3 with saved_namelen unset. However, the copy_cache_entry_to_ondisk() function does not write to ce->ce_flags (it only reads). gcc could easily determine this, since that function is local to this file, but it obviously doesn't. In order to suppress this warning, we make it clear to the reader (human and compiler), that block #3 will only be entered when the first block has been entered, by introducing a new 'stripped_name' boolean variable. We also take the opportunity to change the type of 'saved_namelen' to 'unsigned int' to match ce->ce_namelen. Signed-off-by: Ramsay Jones <ramsay@ramsayjones.plus.com> Signed-off-by: Junio C Hamano <gitster@pobox.com>
2018-03-19 18:56:11 +01:00
unsigned int saved_namelen;
int stripped_name = 0;
static unsigned char padding[8] = { 0x00 };
if (ce->ce_flags & CE_STRIP_NAME) {
saved_namelen = ce_namelen(ce);
ce->ce_namelen = 0;
read-cache: fix an -Wmaybe-uninitialized warning The function ce_write_entry() uses a 'self-initialised' variable construct, for the symbol 'saved_namelen', to suppress a gcc '-Wmaybe-uninitialized' warning, given that the warning is a false positive. For the purposes of this discussion, the ce_write_entry() function has three code blocks of interest, that look like so: /* block #1 */ if (ce->ce_flags & CE_STRIP_NAME) { saved_namelen = ce_namelen(ce); ce->ce_namelen = 0; } /* block #2 */ /* * several code blocks that contain, among others, calls * to copy_cache_entry_to_ondisk(ondisk, ce); */ /* block #3 */ if (ce->ce_flags & CE_STRIP_NAME) { ce->ce_namelen = saved_namelen; ce->ce_flags &= ~CE_STRIP_NAME; } The warning implies that gcc thinks it is possible that the first block is not entered, the calls to copy_cache_entry_to_ondisk() could toggle the CE_STRIP_NAME flag on, thereby entering block #3 with saved_namelen unset. However, the copy_cache_entry_to_ondisk() function does not write to ce->ce_flags (it only reads). gcc could easily determine this, since that function is local to this file, but it obviously doesn't. In order to suppress this warning, we make it clear to the reader (human and compiler), that block #3 will only be entered when the first block has been entered, by introducing a new 'stripped_name' boolean variable. We also take the opportunity to change the type of 'saved_namelen' to 'unsigned int' to match ce->ce_namelen. Signed-off-by: Ramsay Jones <ramsay@ramsayjones.plus.com> Signed-off-by: Junio C Hamano <gitster@pobox.com>
2018-03-19 18:56:11 +01:00
stripped_name = 1;
}
size = offsetof(struct ondisk_cache_entry,data) + ondisk_data_size(ce->ce_flags, 0);
if (!previous_name) {
int len = ce_namelen(ce);
copy_cache_entry_to_ondisk(ondisk, ce);
read-cache: use hashfile instead of git_hash_ctx The do_write_index() method in read-cache.c has its own hashing logic and buffering mechanism. Specifically, the ce_write() method was introduced by 4990aadc (Speed up index file writing by chunking it nicely, 2005-04-20) and similar mechanisms were introduced a few months later in c38138cd (git-pack-objects: write the pack files with a SHA1 csum, 2005-06-26). Based on the timing, in the early days of the Git codebase, I figured that these roughly equivalent code paths were never unified only because it got lost in the shuffle. The hashfile API has since been used extensively in other file formats, such as pack-indexes, multi-pack-indexes, and commit-graphs. Therefore, it seems prudent to unify the index writing code to use the same mechanism. I discovered this disparity while trying to create a new index format that uses the chunk-format API. That API uses a hashfile as its base, so it is incompatible with the custom code in read-cache.c. This rewrite is rather straightforward. It replaces all writes to the temporary file with writes to the hashfile struct. This takes care of many of the direct interactions with the_hash_algo. There are still some git_hash_ctx uses remaining: the extension headers are hashed for use in the End of Index Entries (EOIE) extension. This use of the git_hash_ctx is left as-is. There are multiple reasons to not use a hashfile here, including the fact that the data is not actually writing to a file, just a hash computation. These hashes do not block our adoption of the chunk-format API in a future change to the index, so leave it as-is. The internals of the algorithms are mostly identical. Previously, the hashfile API used a smaller 8KB buffer instead of the 128KB buffer from read-cache.c. The previous change already unified these sizes. There is one subtle point: we do not pass the CSUM_FSYNC to the finalize_hashfile() method, which differs from most consumers of the hashfile API. The extra fsync() call indicated by this flag causes a significant peformance degradation that is noticeable for quick commands that write the index, such as "git add". Other consumers can absorb this cost with their more complicated data structure organization, and further writing structures such as pack-files and commit-graphs is rarely in the critical path for common user interactions. Some static methods become orphaned in this diff, so I marked them as MAYBE_UNUSED. The diff is much harder to read if they are deleted during this change. Instead, they will be deleted in the following change. In addition to the test suite passing, I computed indexes using the previous binaries and the binaries compiled after this change, and found the index data to be exactly equal. Finally, I did extensive performance testing of "git update-index --force-write" on repos of various sizes, including one with over 2 million paths at HEAD. These tests demonstrated less than 1% difference in behavior. As expected, the performance should be considered unchanged. The previous changes to increase the hashfile buffer size from 8K to 128K ensured this change would not create a peformance regression. Signed-off-by: Derrick Stolee <dstolee@microsoft.com> Signed-off-by: Junio C Hamano <gitster@pobox.com>
2021-05-18 20:32:47 +02:00
hashwrite(f, ondisk, size);
hashwrite(f, ce->name, len);
hashwrite(f, padding, align_padding_size(size, len));
} else {
int common, to_remove, prefix_size;
unsigned char to_remove_vi[16];
for (common = 0;
(ce->name[common] &&
common < previous_name->len &&
ce->name[common] == previous_name->buf[common]);
common++)
; /* still matching */
to_remove = previous_name->len - common;
prefix_size = encode_varint(to_remove, to_remove_vi);
copy_cache_entry_to_ondisk(ondisk, ce);
read-cache: use hashfile instead of git_hash_ctx The do_write_index() method in read-cache.c has its own hashing logic and buffering mechanism. Specifically, the ce_write() method was introduced by 4990aadc (Speed up index file writing by chunking it nicely, 2005-04-20) and similar mechanisms were introduced a few months later in c38138cd (git-pack-objects: write the pack files with a SHA1 csum, 2005-06-26). Based on the timing, in the early days of the Git codebase, I figured that these roughly equivalent code paths were never unified only because it got lost in the shuffle. The hashfile API has since been used extensively in other file formats, such as pack-indexes, multi-pack-indexes, and commit-graphs. Therefore, it seems prudent to unify the index writing code to use the same mechanism. I discovered this disparity while trying to create a new index format that uses the chunk-format API. That API uses a hashfile as its base, so it is incompatible with the custom code in read-cache.c. This rewrite is rather straightforward. It replaces all writes to the temporary file with writes to the hashfile struct. This takes care of many of the direct interactions with the_hash_algo. There are still some git_hash_ctx uses remaining: the extension headers are hashed for use in the End of Index Entries (EOIE) extension. This use of the git_hash_ctx is left as-is. There are multiple reasons to not use a hashfile here, including the fact that the data is not actually writing to a file, just a hash computation. These hashes do not block our adoption of the chunk-format API in a future change to the index, so leave it as-is. The internals of the algorithms are mostly identical. Previously, the hashfile API used a smaller 8KB buffer instead of the 128KB buffer from read-cache.c. The previous change already unified these sizes. There is one subtle point: we do not pass the CSUM_FSYNC to the finalize_hashfile() method, which differs from most consumers of the hashfile API. The extra fsync() call indicated by this flag causes a significant peformance degradation that is noticeable for quick commands that write the index, such as "git add". Other consumers can absorb this cost with their more complicated data structure organization, and further writing structures such as pack-files and commit-graphs is rarely in the critical path for common user interactions. Some static methods become orphaned in this diff, so I marked them as MAYBE_UNUSED. The diff is much harder to read if they are deleted during this change. Instead, they will be deleted in the following change. In addition to the test suite passing, I computed indexes using the previous binaries and the binaries compiled after this change, and found the index data to be exactly equal. Finally, I did extensive performance testing of "git update-index --force-write" on repos of various sizes, including one with over 2 million paths at HEAD. These tests demonstrated less than 1% difference in behavior. As expected, the performance should be considered unchanged. The previous changes to increase the hashfile buffer size from 8K to 128K ensured this change would not create a peformance regression. Signed-off-by: Derrick Stolee <dstolee@microsoft.com> Signed-off-by: Junio C Hamano <gitster@pobox.com>
2021-05-18 20:32:47 +02:00
hashwrite(f, ondisk, size);
hashwrite(f, to_remove_vi, prefix_size);
hashwrite(f, ce->name + common, ce_namelen(ce) - common);
hashwrite(f, padding, 1);
strbuf_splice(previous_name, common, to_remove,
ce->name + common, ce_namelen(ce) - common);
}
read-cache: fix an -Wmaybe-uninitialized warning The function ce_write_entry() uses a 'self-initialised' variable construct, for the symbol 'saved_namelen', to suppress a gcc '-Wmaybe-uninitialized' warning, given that the warning is a false positive. For the purposes of this discussion, the ce_write_entry() function has three code blocks of interest, that look like so: /* block #1 */ if (ce->ce_flags & CE_STRIP_NAME) { saved_namelen = ce_namelen(ce); ce->ce_namelen = 0; } /* block #2 */ /* * several code blocks that contain, among others, calls * to copy_cache_entry_to_ondisk(ondisk, ce); */ /* block #3 */ if (ce->ce_flags & CE_STRIP_NAME) { ce->ce_namelen = saved_namelen; ce->ce_flags &= ~CE_STRIP_NAME; } The warning implies that gcc thinks it is possible that the first block is not entered, the calls to copy_cache_entry_to_ondisk() could toggle the CE_STRIP_NAME flag on, thereby entering block #3 with saved_namelen unset. However, the copy_cache_entry_to_ondisk() function does not write to ce->ce_flags (it only reads). gcc could easily determine this, since that function is local to this file, but it obviously doesn't. In order to suppress this warning, we make it clear to the reader (human and compiler), that block #3 will only be entered when the first block has been entered, by introducing a new 'stripped_name' boolean variable. We also take the opportunity to change the type of 'saved_namelen' to 'unsigned int' to match ce->ce_namelen. Signed-off-by: Ramsay Jones <ramsay@ramsayjones.plus.com> Signed-off-by: Junio C Hamano <gitster@pobox.com>
2018-03-19 18:56:11 +01:00
if (stripped_name) {
ce->ce_namelen = saved_namelen;
ce->ce_flags &= ~CE_STRIP_NAME;
}
read-cache: use hashfile instead of git_hash_ctx The do_write_index() method in read-cache.c has its own hashing logic and buffering mechanism. Specifically, the ce_write() method was introduced by 4990aadc (Speed up index file writing by chunking it nicely, 2005-04-20) and similar mechanisms were introduced a few months later in c38138cd (git-pack-objects: write the pack files with a SHA1 csum, 2005-06-26). Based on the timing, in the early days of the Git codebase, I figured that these roughly equivalent code paths were never unified only because it got lost in the shuffle. The hashfile API has since been used extensively in other file formats, such as pack-indexes, multi-pack-indexes, and commit-graphs. Therefore, it seems prudent to unify the index writing code to use the same mechanism. I discovered this disparity while trying to create a new index format that uses the chunk-format API. That API uses a hashfile as its base, so it is incompatible with the custom code in read-cache.c. This rewrite is rather straightforward. It replaces all writes to the temporary file with writes to the hashfile struct. This takes care of many of the direct interactions with the_hash_algo. There are still some git_hash_ctx uses remaining: the extension headers are hashed for use in the End of Index Entries (EOIE) extension. This use of the git_hash_ctx is left as-is. There are multiple reasons to not use a hashfile here, including the fact that the data is not actually writing to a file, just a hash computation. These hashes do not block our adoption of the chunk-format API in a future change to the index, so leave it as-is. The internals of the algorithms are mostly identical. Previously, the hashfile API used a smaller 8KB buffer instead of the 128KB buffer from read-cache.c. The previous change already unified these sizes. There is one subtle point: we do not pass the CSUM_FSYNC to the finalize_hashfile() method, which differs from most consumers of the hashfile API. The extra fsync() call indicated by this flag causes a significant peformance degradation that is noticeable for quick commands that write the index, such as "git add". Other consumers can absorb this cost with their more complicated data structure organization, and further writing structures such as pack-files and commit-graphs is rarely in the critical path for common user interactions. Some static methods become orphaned in this diff, so I marked them as MAYBE_UNUSED. The diff is much harder to read if they are deleted during this change. Instead, they will be deleted in the following change. In addition to the test suite passing, I computed indexes using the previous binaries and the binaries compiled after this change, and found the index data to be exactly equal. Finally, I did extensive performance testing of "git update-index --force-write" on repos of various sizes, including one with over 2 million paths at HEAD. These tests demonstrated less than 1% difference in behavior. As expected, the performance should be considered unchanged. The previous changes to increase the hashfile buffer size from 8K to 128K ensured this change would not create a peformance regression. Signed-off-by: Derrick Stolee <dstolee@microsoft.com> Signed-off-by: Junio C Hamano <gitster@pobox.com>
2021-05-18 20:32:47 +02:00
return 0;
}
/*
* This function verifies if index_state has the correct sha1 of the
* index file. Don't die if we have any other failure, just return 0.
*/
static int verify_index_from(const struct index_state *istate, const char *path)
{
int fd;
ssize_t n;
struct stat st;
unsigned char hash[GIT_MAX_RAWSZ];
if (!istate->initialized)
return 0;
fd = open(path, O_RDONLY);
if (fd < 0)
return 0;
if (fstat(fd, &st))
goto out;
if (st.st_size < sizeof(struct cache_header) + the_hash_algo->rawsz)
goto out;
n = pread_in_full(fd, hash, the_hash_algo->rawsz, st.st_size - the_hash_algo->rawsz);
if (n != the_hash_algo->rawsz)
goto out;
if (!hasheq(istate->oid.hash, hash))
goto out;
close(fd);
return 1;
out:
close(fd);
return 0;
}
static int repo_verify_index(struct repository *repo)
{
return verify_index_from(repo->index, repo->index_file);
}
static int has_racy_timestamp(struct index_state *istate)
{
int entries = istate->cache_nr;
int i;
for (i = 0; i < entries; i++) {
struct cache_entry *ce = istate->cache[i];
if (is_racy_timestamp(istate, ce))
return 1;
}
return 0;
}
void repo_update_index_if_able(struct repository *repo,
struct lock_file *lockfile)
{
if ((repo->index->cache_changed ||
has_racy_timestamp(repo->index)) &&
repo_verify_index(repo))
write_locked_index(repo->index, lockfile, COMMIT_LOCK);
else
rollback_lock_file(lockfile);
}
static int record_eoie(void)
{
int val;
if (!git_config_get_bool("index.recordendofindexentries", &val))
return val;
index: make index.threads=true enable ieot and eoie If a user explicitly sets [index] threads = true to read the index using multiple threads, ensure that index writes include the offset table by default to make that possible. This ensures that the user's intent of turning on threading is respected. In other words, permit the following configurations: - index.threads and index.recordOffsetTable unspecified: do not write the offset table yet (to avoid alarming the user with "ignoring IEOT extension" messages when an older version of Git accesses the repository) but do make use of multiple threads to read the index if the supporting offset table is present. This can also be requested explicitly by setting index.threads=true, 0, or >1 and index.recordOffsetTable=false. - index.threads=false or 1: do not write the offset table, and do not make use of the offset table. One can set index.recordOffsetTable=false as well, to be more explicit. - index.threads=true, 0, or >1 and index.recordOffsetTable unspecified: write the offset table and make use of threads at read time. This can also be requested by setting index.threads=true, 0, >1, or unspecified and index.recordOffsetTable=true. Fortunately the complication is temporary: once most Git installations have upgraded to a version with support for the IEOT and EOIE extensions, we can flip the defaults for index.recordEndOfIndexEntries and index.recordOffsetTable to true and eliminate the settings. Helped-by: Ben Peart <benpeart@microsoft.com> Signed-off-by: Jonathan Nieder <jrnieder@gmail.com> Signed-off-by: Junio C Hamano <gitster@pobox.com>
2018-11-20 07:14:26 +01:00
/*
* As a convenience, the end of index entries extension
* used for threading is written by default if the user
* explicitly requested threaded index reads.
*/
return !git_config_get_index_threads(&val) && val != 1;
}
static int record_ieot(void)
{
int val;
if (!git_config_get_bool("index.recordoffsettable", &val))
return val;
index: make index.threads=true enable ieot and eoie If a user explicitly sets [index] threads = true to read the index using multiple threads, ensure that index writes include the offset table by default to make that possible. This ensures that the user's intent of turning on threading is respected. In other words, permit the following configurations: - index.threads and index.recordOffsetTable unspecified: do not write the offset table yet (to avoid alarming the user with "ignoring IEOT extension" messages when an older version of Git accesses the repository) but do make use of multiple threads to read the index if the supporting offset table is present. This can also be requested explicitly by setting index.threads=true, 0, or >1 and index.recordOffsetTable=false. - index.threads=false or 1: do not write the offset table, and do not make use of the offset table. One can set index.recordOffsetTable=false as well, to be more explicit. - index.threads=true, 0, or >1 and index.recordOffsetTable unspecified: write the offset table and make use of threads at read time. This can also be requested by setting index.threads=true, 0, >1, or unspecified and index.recordOffsetTable=true. Fortunately the complication is temporary: once most Git installations have upgraded to a version with support for the IEOT and EOIE extensions, we can flip the defaults for index.recordEndOfIndexEntries and index.recordOffsetTable to true and eliminate the settings. Helped-by: Ben Peart <benpeart@microsoft.com> Signed-off-by: Jonathan Nieder <jrnieder@gmail.com> Signed-off-by: Junio C Hamano <gitster@pobox.com>
2018-11-20 07:14:26 +01:00
/*
* As a convenience, the offset table used for threading is
* written by default if the user explicitly requested
* threaded index reads.
*/
return !git_config_get_index_threads(&val) && val != 1;
}
/*
* On success, `tempfile` is closed. If it is the temporary file
* of a `struct lock_file`, we will therefore effectively perform
* a 'close_lock_file_gently()`. Since that is an implementation
* detail of lockfiles, callers of `do_write_index()` should not
* rely on it.
*/
static int do_write_index(struct index_state *istate, struct tempfile *tempfile,
int strip_extensions)
{
uint64_t start = getnanotime();
read-cache: use hashfile instead of git_hash_ctx The do_write_index() method in read-cache.c has its own hashing logic and buffering mechanism. Specifically, the ce_write() method was introduced by 4990aadc (Speed up index file writing by chunking it nicely, 2005-04-20) and similar mechanisms were introduced a few months later in c38138cd (git-pack-objects: write the pack files with a SHA1 csum, 2005-06-26). Based on the timing, in the early days of the Git codebase, I figured that these roughly equivalent code paths were never unified only because it got lost in the shuffle. The hashfile API has since been used extensively in other file formats, such as pack-indexes, multi-pack-indexes, and commit-graphs. Therefore, it seems prudent to unify the index writing code to use the same mechanism. I discovered this disparity while trying to create a new index format that uses the chunk-format API. That API uses a hashfile as its base, so it is incompatible with the custom code in read-cache.c. This rewrite is rather straightforward. It replaces all writes to the temporary file with writes to the hashfile struct. This takes care of many of the direct interactions with the_hash_algo. There are still some git_hash_ctx uses remaining: the extension headers are hashed for use in the End of Index Entries (EOIE) extension. This use of the git_hash_ctx is left as-is. There are multiple reasons to not use a hashfile here, including the fact that the data is not actually writing to a file, just a hash computation. These hashes do not block our adoption of the chunk-format API in a future change to the index, so leave it as-is. The internals of the algorithms are mostly identical. Previously, the hashfile API used a smaller 8KB buffer instead of the 128KB buffer from read-cache.c. The previous change already unified these sizes. There is one subtle point: we do not pass the CSUM_FSYNC to the finalize_hashfile() method, which differs from most consumers of the hashfile API. The extra fsync() call indicated by this flag causes a significant peformance degradation that is noticeable for quick commands that write the index, such as "git add". Other consumers can absorb this cost with their more complicated data structure organization, and further writing structures such as pack-files and commit-graphs is rarely in the critical path for common user interactions. Some static methods become orphaned in this diff, so I marked them as MAYBE_UNUSED. The diff is much harder to read if they are deleted during this change. Instead, they will be deleted in the following change. In addition to the test suite passing, I computed indexes using the previous binaries and the binaries compiled after this change, and found the index data to be exactly equal. Finally, I did extensive performance testing of "git update-index --force-write" on repos of various sizes, including one with over 2 million paths at HEAD. These tests demonstrated less than 1% difference in behavior. As expected, the performance should be considered unchanged. The previous changes to increase the hashfile buffer size from 8K to 128K ensured this change would not create a peformance regression. Signed-off-by: Derrick Stolee <dstolee@microsoft.com> Signed-off-by: Junio C Hamano <gitster@pobox.com>
2021-05-18 20:32:47 +02:00
struct hashfile *f;
git_hash_ctx *eoie_c = NULL;
struct cache_header hdr;
int i, err = 0, removed, extended, hdr_version;
struct cache_entry **cache = istate->cache;
int entries = istate->cache_nr;
struct stat st;
struct ondisk_cache_entry ondisk;
struct strbuf previous_name_buf = STRBUF_INIT, *previous_name;
int drop_cache_tree = istate->drop_cache_tree;
off_t offset;
int ieot_entries = 1;
struct index_entry_offset_table *ieot = NULL;
int nr, nr_threads;
read-cache: use hashfile instead of git_hash_ctx The do_write_index() method in read-cache.c has its own hashing logic and buffering mechanism. Specifically, the ce_write() method was introduced by 4990aadc (Speed up index file writing by chunking it nicely, 2005-04-20) and similar mechanisms were introduced a few months later in c38138cd (git-pack-objects: write the pack files with a SHA1 csum, 2005-06-26). Based on the timing, in the early days of the Git codebase, I figured that these roughly equivalent code paths were never unified only because it got lost in the shuffle. The hashfile API has since been used extensively in other file formats, such as pack-indexes, multi-pack-indexes, and commit-graphs. Therefore, it seems prudent to unify the index writing code to use the same mechanism. I discovered this disparity while trying to create a new index format that uses the chunk-format API. That API uses a hashfile as its base, so it is incompatible with the custom code in read-cache.c. This rewrite is rather straightforward. It replaces all writes to the temporary file with writes to the hashfile struct. This takes care of many of the direct interactions with the_hash_algo. There are still some git_hash_ctx uses remaining: the extension headers are hashed for use in the End of Index Entries (EOIE) extension. This use of the git_hash_ctx is left as-is. There are multiple reasons to not use a hashfile here, including the fact that the data is not actually writing to a file, just a hash computation. These hashes do not block our adoption of the chunk-format API in a future change to the index, so leave it as-is. The internals of the algorithms are mostly identical. Previously, the hashfile API used a smaller 8KB buffer instead of the 128KB buffer from read-cache.c. The previous change already unified these sizes. There is one subtle point: we do not pass the CSUM_FSYNC to the finalize_hashfile() method, which differs from most consumers of the hashfile API. The extra fsync() call indicated by this flag causes a significant peformance degradation that is noticeable for quick commands that write the index, such as "git add". Other consumers can absorb this cost with their more complicated data structure organization, and further writing structures such as pack-files and commit-graphs is rarely in the critical path for common user interactions. Some static methods become orphaned in this diff, so I marked them as MAYBE_UNUSED. The diff is much harder to read if they are deleted during this change. Instead, they will be deleted in the following change. In addition to the test suite passing, I computed indexes using the previous binaries and the binaries compiled after this change, and found the index data to be exactly equal. Finally, I did extensive performance testing of "git update-index --force-write" on repos of various sizes, including one with over 2 million paths at HEAD. These tests demonstrated less than 1% difference in behavior. As expected, the performance should be considered unchanged. The previous changes to increase the hashfile buffer size from 8K to 128K ensured this change would not create a peformance regression. Signed-off-by: Derrick Stolee <dstolee@microsoft.com> Signed-off-by: Junio C Hamano <gitster@pobox.com>
2021-05-18 20:32:47 +02:00
f = hashfd(tempfile->fd, tempfile->filename.buf);
for (i = removed = extended = 0; i < entries; i++) {
if (cache[i]->ce_flags & CE_REMOVE)
removed++;
/* reduce extended entries if possible */
cache[i]->ce_flags &= ~CE_EXTENDED;
if (cache[i]->ce_flags & CE_EXTENDED_FLAGS) {
extended++;
cache[i]->ce_flags |= CE_EXTENDED;
}
}
read-cache: fix GIT_TEST_SPLIT_INDEX Running tests with GIT_TEST_SPLIT_INDEX=1 is supposed to turn on the split index feature and trigger index splitting (mostly) randomly. Alas, this has been broken since 6e37c8ed3c (read-cache.c: fix writing "link" index ext with null base oid, 2019-02-13), and GIT_TEST_SPLIT_INDEX=1 hasn't triggered any index splitting since then. This patch makes GIT_TEST_SPLIT_INDEX work again, though it doesn't restore the pre-6e37c8ed3c behavior. To understand the bug, the fix, and the behavior change we first have to look at how GIT_TEST_SPLIT_INDEX used to work before 6e37c8ed3c: There are two places where we check the value of GIT_TEST_SPLIT_INDEX, and before 6e37c8ed3c they worked like this: 1) In the lower-level do_write_index(), where, if GIT_TEST_SPLIT_INDEX is enabled, we call init_split_index(). This call merely allocates and zero-initializes 'istate->split_index', but does nothing else (i.e. doesn't fill the base/shared index with cache entries, doesn't actually write a shared index file, etc.). Pertinent to this issue, the hash of the base index remains all zeroed out. 2) In the higher-level write_locked_index(), but only when 'istate->split_index' has already been initialized. Then, if GIT_TEST_SPLIT_INDEX is enabled, it randomly sets the flag that triggers index splitting later in this function. This randomness comes from the first byte of the hash of the base index via an 'if ((first_byte & 15) < 6)' condition. However, if 'istate->split_index' hasn't been initialized (i.e. it is still NULL), then write_locked_index() just calls do_write_locked_index(), which internally calls the above mentioned do_write_index(). This means that while GIT_TEST_SPLIT_INDEX=1 usually triggered index splitting randomly, the first two index writes were always deterministic (though I suspect this was unintentional): - The initial index write never splits the index. During the first index write write_locked_index() is called with 'istate->split_index' still uninitialized, so the check in 2) is not executed. It still calls do_write_index(), though, which then executes the check in 1). The resulting all zero base index hash then leads to the 'link' extension being written to '.git/index', though a shared index file is not written: $ rm .git/index $ GIT_TEST_SPLIT_INDEX=1 git update-index --add file $ test-tool dump-split-index .git/index own c6ef71168597caec8553c83d9d0048f1ef416170 base 0000000000000000000000000000000000000000 100644 d00491fd7e5bb6fa28c517a0bb32b8b506539d4d 0 file replacements: deletions: $ ls -l .git/sharedindex.* ls: cannot access '.git/sharedindex.*': No such file or directory - The second index write always splits the index. When the index written in the previous point is read, 'istate->split_index' is initialized because of the presence of the 'link' extension. So during the second write write_locked_index() does run the check in 2), and the first byte of the all zero base index hash always fulfills the randomness condition, which in turn always triggers the index splitting. - Subsequent index writes will find the 'link' extension with a real non-zero base index hash, so from then on the check in 2) is executed and the first byte of the base index hash is as random as it gets (coming from the SHA-1 of index data including timestamps and inodes...). All this worked until 6e37c8ed3c came along, and stopped writing the 'link' extension if the hash of the base index was all zero: $ rm .git/index $ GIT_TEST_SPLIT_INDEX=1 git update-index --add file $ test-tool dump-split-index .git/index own abbd6f6458d5dee73ae8e210ca15a68a390c6fd7 not a split index $ ls -l .git/sharedindex.* ls: cannot access '.git/sharedindex.*': No such file or directory So, since the first index write with GIT_TEST_SPLIT_INDEX=1 doesn't write a 'link' extension, in the second index write 'istate->split_index' remains uninitialized, and the check in 2) is not executed, and ultimately the index is never split. Fix this by modifying write_locked_index() to make sure to check GIT_TEST_SPLIT_INDEX even if 'istate->split_index' is still uninitialized, and initialize it if necessary. The check for GIT_TEST_SPLIT_INDEX and separate init_split_index() call in do_write_index() thus becomes unnecessary, so remove it. Furthermore, add a test to 't1700-split-index.sh' to make sure that GIT_TEST_SPLIT_INDEX=1 will keep working (though only check the index splitting on the first index write, because after that it will be random). Note that this change does not restore the pre-6e37c8ed3c behaviour, as it will deterministically split the index already on the first index write. Since GIT_TEST_SPLIT_INDEX is purely a developer aid, there is no backwards compatibility issue here. The new behaviour did trigger test failures in 't0003-attributes.sh' and 't1600-index.sh', though, which have been fixed in preparatory patches in this series. Signed-off-by: SZEDER Gábor <szeder.dev@gmail.com> Acked-by: Derrick Stolee <dstolee@microsoft.com> Signed-off-by: Junio C Hamano <gitster@pobox.com>
2021-08-26 23:00:04 +02:00
if (!istate->version)
istate->version = get_index_format_default(the_repository);
/* demote version 3 to version 2 when the latter suffices */
if (istate->version == 3 || istate->version == 2)
istate->version = extended ? 3 : 2;
hdr_version = istate->version;
hdr.hdr_signature = htonl(CACHE_SIGNATURE);
hdr.hdr_version = htonl(hdr_version);
hdr.hdr_entries = htonl(entries - removed);
read-cache: use hashfile instead of git_hash_ctx The do_write_index() method in read-cache.c has its own hashing logic and buffering mechanism. Specifically, the ce_write() method was introduced by 4990aadc (Speed up index file writing by chunking it nicely, 2005-04-20) and similar mechanisms were introduced a few months later in c38138cd (git-pack-objects: write the pack files with a SHA1 csum, 2005-06-26). Based on the timing, in the early days of the Git codebase, I figured that these roughly equivalent code paths were never unified only because it got lost in the shuffle. The hashfile API has since been used extensively in other file formats, such as pack-indexes, multi-pack-indexes, and commit-graphs. Therefore, it seems prudent to unify the index writing code to use the same mechanism. I discovered this disparity while trying to create a new index format that uses the chunk-format API. That API uses a hashfile as its base, so it is incompatible with the custom code in read-cache.c. This rewrite is rather straightforward. It replaces all writes to the temporary file with writes to the hashfile struct. This takes care of many of the direct interactions with the_hash_algo. There are still some git_hash_ctx uses remaining: the extension headers are hashed for use in the End of Index Entries (EOIE) extension. This use of the git_hash_ctx is left as-is. There are multiple reasons to not use a hashfile here, including the fact that the data is not actually writing to a file, just a hash computation. These hashes do not block our adoption of the chunk-format API in a future change to the index, so leave it as-is. The internals of the algorithms are mostly identical. Previously, the hashfile API used a smaller 8KB buffer instead of the 128KB buffer from read-cache.c. The previous change already unified these sizes. There is one subtle point: we do not pass the CSUM_FSYNC to the finalize_hashfile() method, which differs from most consumers of the hashfile API. The extra fsync() call indicated by this flag causes a significant peformance degradation that is noticeable for quick commands that write the index, such as "git add". Other consumers can absorb this cost with their more complicated data structure organization, and further writing structures such as pack-files and commit-graphs is rarely in the critical path for common user interactions. Some static methods become orphaned in this diff, so I marked them as MAYBE_UNUSED. The diff is much harder to read if they are deleted during this change. Instead, they will be deleted in the following change. In addition to the test suite passing, I computed indexes using the previous binaries and the binaries compiled after this change, and found the index data to be exactly equal. Finally, I did extensive performance testing of "git update-index --force-write" on repos of various sizes, including one with over 2 million paths at HEAD. These tests demonstrated less than 1% difference in behavior. As expected, the performance should be considered unchanged. The previous changes to increase the hashfile buffer size from 8K to 128K ensured this change would not create a peformance regression. Signed-off-by: Derrick Stolee <dstolee@microsoft.com> Signed-off-by: Junio C Hamano <gitster@pobox.com>
2021-05-18 20:32:47 +02:00
hashwrite(f, &hdr, sizeof(hdr));
index: make index.threads=true enable ieot and eoie If a user explicitly sets [index] threads = true to read the index using multiple threads, ensure that index writes include the offset table by default to make that possible. This ensures that the user's intent of turning on threading is respected. In other words, permit the following configurations: - index.threads and index.recordOffsetTable unspecified: do not write the offset table yet (to avoid alarming the user with "ignoring IEOT extension" messages when an older version of Git accesses the repository) but do make use of multiple threads to read the index if the supporting offset table is present. This can also be requested explicitly by setting index.threads=true, 0, or >1 and index.recordOffsetTable=false. - index.threads=false or 1: do not write the offset table, and do not make use of the offset table. One can set index.recordOffsetTable=false as well, to be more explicit. - index.threads=true, 0, or >1 and index.recordOffsetTable unspecified: write the offset table and make use of threads at read time. This can also be requested by setting index.threads=true, 0, >1, or unspecified and index.recordOffsetTable=true. Fortunately the complication is temporary: once most Git installations have upgraded to a version with support for the IEOT and EOIE extensions, we can flip the defaults for index.recordEndOfIndexEntries and index.recordOffsetTable to true and eliminate the settings. Helped-by: Ben Peart <benpeart@microsoft.com> Signed-off-by: Jonathan Nieder <jrnieder@gmail.com> Signed-off-by: Junio C Hamano <gitster@pobox.com>
2018-11-20 07:14:26 +01:00
if (!HAVE_THREADS || git_config_get_index_threads(&nr_threads))
nr_threads = 1;
if (nr_threads != 1 && record_ieot()) {
int ieot_blocks, cpus;
/*
* ensure default number of ieot blocks maps evenly to the
* default number of threads that will process them leaving
* room for the thread to load the index extensions.
*/
if (!nr_threads) {
ieot_blocks = istate->cache_nr / THREAD_COST;
cpus = online_cpus();
if (ieot_blocks > cpus - 1)
ieot_blocks = cpus - 1;
} else {
ieot_blocks = nr_threads;
if (ieot_blocks > istate->cache_nr)
ieot_blocks = istate->cache_nr;
}
/*
* no reason to write out the IEOT extension if we don't
* have enough blocks to utilize multi-threading
*/
if (ieot_blocks > 1) {
ieot = xcalloc(1, sizeof(struct index_entry_offset_table)
+ (ieot_blocks * sizeof(struct index_entry_offset)));
ieot_entries = DIV_ROUND_UP(entries, ieot_blocks);
}
}
read-cache: use hashfile instead of git_hash_ctx The do_write_index() method in read-cache.c has its own hashing logic and buffering mechanism. Specifically, the ce_write() method was introduced by 4990aadc (Speed up index file writing by chunking it nicely, 2005-04-20) and similar mechanisms were introduced a few months later in c38138cd (git-pack-objects: write the pack files with a SHA1 csum, 2005-06-26). Based on the timing, in the early days of the Git codebase, I figured that these roughly equivalent code paths were never unified only because it got lost in the shuffle. The hashfile API has since been used extensively in other file formats, such as pack-indexes, multi-pack-indexes, and commit-graphs. Therefore, it seems prudent to unify the index writing code to use the same mechanism. I discovered this disparity while trying to create a new index format that uses the chunk-format API. That API uses a hashfile as its base, so it is incompatible with the custom code in read-cache.c. This rewrite is rather straightforward. It replaces all writes to the temporary file with writes to the hashfile struct. This takes care of many of the direct interactions with the_hash_algo. There are still some git_hash_ctx uses remaining: the extension headers are hashed for use in the End of Index Entries (EOIE) extension. This use of the git_hash_ctx is left as-is. There are multiple reasons to not use a hashfile here, including the fact that the data is not actually writing to a file, just a hash computation. These hashes do not block our adoption of the chunk-format API in a future change to the index, so leave it as-is. The internals of the algorithms are mostly identical. Previously, the hashfile API used a smaller 8KB buffer instead of the 128KB buffer from read-cache.c. The previous change already unified these sizes. There is one subtle point: we do not pass the CSUM_FSYNC to the finalize_hashfile() method, which differs from most consumers of the hashfile API. The extra fsync() call indicated by this flag causes a significant peformance degradation that is noticeable for quick commands that write the index, such as "git add". Other consumers can absorb this cost with their more complicated data structure organization, and further writing structures such as pack-files and commit-graphs is rarely in the critical path for common user interactions. Some static methods become orphaned in this diff, so I marked them as MAYBE_UNUSED. The diff is much harder to read if they are deleted during this change. Instead, they will be deleted in the following change. In addition to the test suite passing, I computed indexes using the previous binaries and the binaries compiled after this change, and found the index data to be exactly equal. Finally, I did extensive performance testing of "git update-index --force-write" on repos of various sizes, including one with over 2 million paths at HEAD. These tests demonstrated less than 1% difference in behavior. As expected, the performance should be considered unchanged. The previous changes to increase the hashfile buffer size from 8K to 128K ensured this change would not create a peformance regression. Signed-off-by: Derrick Stolee <dstolee@microsoft.com> Signed-off-by: Junio C Hamano <gitster@pobox.com>
2021-05-18 20:32:47 +02:00
offset = hashfile_total(f);
nr = 0;
previous_name = (hdr_version == 4) ? &previous_name_buf : NULL;
for (i = 0; i < entries; i++) {
struct cache_entry *ce = cache[i];
if (ce->ce_flags & CE_REMOVE)
continue;
if (!ce_uptodate(ce) && is_racy_timestamp(istate, ce))
ce_smudge_racily_clean_entry(istate, ce);
if (is_null_oid(&ce->oid)) {
write_index: optionally allow broken null sha1s Commit 4337b58 (do not write null sha1s to on-disk index, 2012-07-28) added a safety check preventing git from writing null sha1s into the index. The intent was to catch errors in other parts of the code that might let such an entry slip into the index (or worse, a tree). Some existing repositories may have invalid trees that contain null sha1s already, though. Until 4337b58, a common way to clean this up would be to use git-filter-branch's index-filter to repair such broken entries. That now fails when filter-branch tries to write out the index. Introduce a GIT_ALLOW_NULL_SHA1 environment variable to relax this check and make it easier to recover from such a history. It is tempting to not involve filter-branch in this commit at all, and instead require the user to manually invoke GIT_ALLOW_NULL_SHA1=1 git filter-branch ... to perform an index-filter on a history with trees with null sha1s. That would be slightly safer, but requires some specialized knowledge from the user. So let's set the GIT_ALLOW_NULL_SHA1 variable automatically when checking out the to-be-filtered trees. Advice on using filter-branch to remove such entries already exists on places like stackoverflow, and this patch makes it Just Work again on recent versions of git. Further commands that touch the index will still notice and fail, unless they actually remove the broken entries. A filter-branch whose filters do not touch the index at all will not error out (since we complain of the null sha1 only on writing, not when making a tree out of the index), but this is acceptable, as we still print a loud warning, so the problem is unlikely to go unnoticed. Signed-off-by: Jeff King <peff@peff.net> Reviewed-by: Jonathan Nieder <jrnieder@gmail.com> Signed-off-by: Junio C Hamano <gitster@pobox.com>
2013-08-27 22:41:12 +02:00
static const char msg[] = "cache entry has null sha1: %s";
static int allow = -1;
if (allow < 0)
allow = git_env_bool("GIT_ALLOW_NULL_SHA1", 0);
if (allow)
warning(msg, ce->name);
else
err = error(msg, ce->name);
cache-tree: reject entries with null sha1 We generally disallow null sha1s from entering the index, due to 4337b5856 (do not write null sha1s to on-disk index, 2012-07-28). However, we loosened that in 83bd7437c (write_index: optionally allow broken null sha1s, 2013-08-27) so that tools like filter-branch could be used to repair broken history. However, we should make sure that these broken entries do not get propagated into new trees. For most entries, we'd catch them with the missing-object check (since presumably the null sha1 does not exist in our object database). But gitlink entries do not need reachability, so we may blindly copy the entry into a bogus tree. This patch rejects all null sha1s (with the same "invalid entry" message that missing objects get) when building trees from the index. It does so even for non-gitlinks, and even when "write-tree" is given the --missing-ok flag. The null sha1 is a special sentinel value that is already rejected in trees by fsck; whether the object exists or not, it is an error to put it in a tree. Note that for this to work, we must also avoid reusing an existing cache-tree that contains the null sha1. This patch does so by just refusing to write out any cache tree when the index contains a null sha1. This is blunter than we need to be; we could just reject the subtree that contains the offending entry. But it's not worth the complexity. The behavior is unchanged unless you have a broken index entry, and even then we'd refuse the whole index write unless the emergency GIT_ALLOW_NULL_SHA1 is in use. And even then the end result is only a performance drop (any write-tree will have to generate the whole cache-tree from scratch). The tests bear some explanation. The existing test in t7009 doesn't catch this problem, because our index-filter runs "git rm --cached", which will try to rewrite the updated index and barf on the bogus entry. So we never even make it to write-tree. The new test there adds a noop index-filter, which does show the problem. The new tests in t1601 are slightly redundant with what filter-branch is doing under the hood in t7009. But as they're much more direct, they're easier to reason about. And should filter-branch ever change or go away, we'd want to make sure that these plumbing commands behave sanely. Signed-off-by: Jeff King <peff@peff.net> Signed-off-by: Junio C Hamano <gitster@pobox.com>
2017-04-21 20:46:17 +02:00
drop_cache_tree = 1;
write_index: optionally allow broken null sha1s Commit 4337b58 (do not write null sha1s to on-disk index, 2012-07-28) added a safety check preventing git from writing null sha1s into the index. The intent was to catch errors in other parts of the code that might let such an entry slip into the index (or worse, a tree). Some existing repositories may have invalid trees that contain null sha1s already, though. Until 4337b58, a common way to clean this up would be to use git-filter-branch's index-filter to repair such broken entries. That now fails when filter-branch tries to write out the index. Introduce a GIT_ALLOW_NULL_SHA1 environment variable to relax this check and make it easier to recover from such a history. It is tempting to not involve filter-branch in this commit at all, and instead require the user to manually invoke GIT_ALLOW_NULL_SHA1=1 git filter-branch ... to perform an index-filter on a history with trees with null sha1s. That would be slightly safer, but requires some specialized knowledge from the user. So let's set the GIT_ALLOW_NULL_SHA1 variable automatically when checking out the to-be-filtered trees. Advice on using filter-branch to remove such entries already exists on places like stackoverflow, and this patch makes it Just Work again on recent versions of git. Further commands that touch the index will still notice and fail, unless they actually remove the broken entries. A filter-branch whose filters do not touch the index at all will not error out (since we complain of the null sha1 only on writing, not when making a tree out of the index), but this is acceptable, as we still print a loud warning, so the problem is unlikely to go unnoticed. Signed-off-by: Jeff King <peff@peff.net> Reviewed-by: Jonathan Nieder <jrnieder@gmail.com> Signed-off-by: Junio C Hamano <gitster@pobox.com>
2013-08-27 22:41:12 +02:00
}
if (ieot && i && (i % ieot_entries == 0)) {
ieot->entries[ieot->nr].nr = nr;
ieot->entries[ieot->nr].offset = offset;
ieot->nr++;
/*
* If we have a V4 index, set the first byte to an invalid
* character to ensure there is nothing common with the previous
* entry
*/
if (previous_name)
previous_name->buf[0] = 0;
nr = 0;
read-cache: use hashfile instead of git_hash_ctx The do_write_index() method in read-cache.c has its own hashing logic and buffering mechanism. Specifically, the ce_write() method was introduced by 4990aadc (Speed up index file writing by chunking it nicely, 2005-04-20) and similar mechanisms were introduced a few months later in c38138cd (git-pack-objects: write the pack files with a SHA1 csum, 2005-06-26). Based on the timing, in the early days of the Git codebase, I figured that these roughly equivalent code paths were never unified only because it got lost in the shuffle. The hashfile API has since been used extensively in other file formats, such as pack-indexes, multi-pack-indexes, and commit-graphs. Therefore, it seems prudent to unify the index writing code to use the same mechanism. I discovered this disparity while trying to create a new index format that uses the chunk-format API. That API uses a hashfile as its base, so it is incompatible with the custom code in read-cache.c. This rewrite is rather straightforward. It replaces all writes to the temporary file with writes to the hashfile struct. This takes care of many of the direct interactions with the_hash_algo. There are still some git_hash_ctx uses remaining: the extension headers are hashed for use in the End of Index Entries (EOIE) extension. This use of the git_hash_ctx is left as-is. There are multiple reasons to not use a hashfile here, including the fact that the data is not actually writing to a file, just a hash computation. These hashes do not block our adoption of the chunk-format API in a future change to the index, so leave it as-is. The internals of the algorithms are mostly identical. Previously, the hashfile API used a smaller 8KB buffer instead of the 128KB buffer from read-cache.c. The previous change already unified these sizes. There is one subtle point: we do not pass the CSUM_FSYNC to the finalize_hashfile() method, which differs from most consumers of the hashfile API. The extra fsync() call indicated by this flag causes a significant peformance degradation that is noticeable for quick commands that write the index, such as "git add". Other consumers can absorb this cost with their more complicated data structure organization, and further writing structures such as pack-files and commit-graphs is rarely in the critical path for common user interactions. Some static methods become orphaned in this diff, so I marked them as MAYBE_UNUSED. The diff is much harder to read if they are deleted during this change. Instead, they will be deleted in the following change. In addition to the test suite passing, I computed indexes using the previous binaries and the binaries compiled after this change, and found the index data to be exactly equal. Finally, I did extensive performance testing of "git update-index --force-write" on repos of various sizes, including one with over 2 million paths at HEAD. These tests demonstrated less than 1% difference in behavior. As expected, the performance should be considered unchanged. The previous changes to increase the hashfile buffer size from 8K to 128K ensured this change would not create a peformance regression. Signed-off-by: Derrick Stolee <dstolee@microsoft.com> Signed-off-by: Junio C Hamano <gitster@pobox.com>
2021-05-18 20:32:47 +02:00
offset = hashfile_total(f);
}
read-cache: use hashfile instead of git_hash_ctx The do_write_index() method in read-cache.c has its own hashing logic and buffering mechanism. Specifically, the ce_write() method was introduced by 4990aadc (Speed up index file writing by chunking it nicely, 2005-04-20) and similar mechanisms were introduced a few months later in c38138cd (git-pack-objects: write the pack files with a SHA1 csum, 2005-06-26). Based on the timing, in the early days of the Git codebase, I figured that these roughly equivalent code paths were never unified only because it got lost in the shuffle. The hashfile API has since been used extensively in other file formats, such as pack-indexes, multi-pack-indexes, and commit-graphs. Therefore, it seems prudent to unify the index writing code to use the same mechanism. I discovered this disparity while trying to create a new index format that uses the chunk-format API. That API uses a hashfile as its base, so it is incompatible with the custom code in read-cache.c. This rewrite is rather straightforward. It replaces all writes to the temporary file with writes to the hashfile struct. This takes care of many of the direct interactions with the_hash_algo. There are still some git_hash_ctx uses remaining: the extension headers are hashed for use in the End of Index Entries (EOIE) extension. This use of the git_hash_ctx is left as-is. There are multiple reasons to not use a hashfile here, including the fact that the data is not actually writing to a file, just a hash computation. These hashes do not block our adoption of the chunk-format API in a future change to the index, so leave it as-is. The internals of the algorithms are mostly identical. Previously, the hashfile API used a smaller 8KB buffer instead of the 128KB buffer from read-cache.c. The previous change already unified these sizes. There is one subtle point: we do not pass the CSUM_FSYNC to the finalize_hashfile() method, which differs from most consumers of the hashfile API. The extra fsync() call indicated by this flag causes a significant peformance degradation that is noticeable for quick commands that write the index, such as "git add". Other consumers can absorb this cost with their more complicated data structure organization, and further writing structures such as pack-files and commit-graphs is rarely in the critical path for common user interactions. Some static methods become orphaned in this diff, so I marked them as MAYBE_UNUSED. The diff is much harder to read if they are deleted during this change. Instead, they will be deleted in the following change. In addition to the test suite passing, I computed indexes using the previous binaries and the binaries compiled after this change, and found the index data to be exactly equal. Finally, I did extensive performance testing of "git update-index --force-write" on repos of various sizes, including one with over 2 million paths at HEAD. These tests demonstrated less than 1% difference in behavior. As expected, the performance should be considered unchanged. The previous changes to increase the hashfile buffer size from 8K to 128K ensured this change would not create a peformance regression. Signed-off-by: Derrick Stolee <dstolee@microsoft.com> Signed-off-by: Junio C Hamano <gitster@pobox.com>
2021-05-18 20:32:47 +02:00
if (ce_write_entry(f, ce, previous_name, (struct ondisk_cache_entry *)&ondisk) < 0)
err = -1;
if (err)
break;
nr++;
}
if (ieot && nr) {
ieot->entries[ieot->nr].nr = nr;
ieot->entries[ieot->nr].offset = offset;
ieot->nr++;
}
strbuf_release(&previous_name_buf);
if (err) {
free(ieot);
return err;
}
read-cache: use hashfile instead of git_hash_ctx The do_write_index() method in read-cache.c has its own hashing logic and buffering mechanism. Specifically, the ce_write() method was introduced by 4990aadc (Speed up index file writing by chunking it nicely, 2005-04-20) and similar mechanisms were introduced a few months later in c38138cd (git-pack-objects: write the pack files with a SHA1 csum, 2005-06-26). Based on the timing, in the early days of the Git codebase, I figured that these roughly equivalent code paths were never unified only because it got lost in the shuffle. The hashfile API has since been used extensively in other file formats, such as pack-indexes, multi-pack-indexes, and commit-graphs. Therefore, it seems prudent to unify the index writing code to use the same mechanism. I discovered this disparity while trying to create a new index format that uses the chunk-format API. That API uses a hashfile as its base, so it is incompatible with the custom code in read-cache.c. This rewrite is rather straightforward. It replaces all writes to the temporary file with writes to the hashfile struct. This takes care of many of the direct interactions with the_hash_algo. There are still some git_hash_ctx uses remaining: the extension headers are hashed for use in the End of Index Entries (EOIE) extension. This use of the git_hash_ctx is left as-is. There are multiple reasons to not use a hashfile here, including the fact that the data is not actually writing to a file, just a hash computation. These hashes do not block our adoption of the chunk-format API in a future change to the index, so leave it as-is. The internals of the algorithms are mostly identical. Previously, the hashfile API used a smaller 8KB buffer instead of the 128KB buffer from read-cache.c. The previous change already unified these sizes. There is one subtle point: we do not pass the CSUM_FSYNC to the finalize_hashfile() method, which differs from most consumers of the hashfile API. The extra fsync() call indicated by this flag causes a significant peformance degradation that is noticeable for quick commands that write the index, such as "git add". Other consumers can absorb this cost with their more complicated data structure organization, and further writing structures such as pack-files and commit-graphs is rarely in the critical path for common user interactions. Some static methods become orphaned in this diff, so I marked them as MAYBE_UNUSED. The diff is much harder to read if they are deleted during this change. Instead, they will be deleted in the following change. In addition to the test suite passing, I computed indexes using the previous binaries and the binaries compiled after this change, and found the index data to be exactly equal. Finally, I did extensive performance testing of "git update-index --force-write" on repos of various sizes, including one with over 2 million paths at HEAD. These tests demonstrated less than 1% difference in behavior. As expected, the performance should be considered unchanged. The previous changes to increase the hashfile buffer size from 8K to 128K ensured this change would not create a peformance regression. Signed-off-by: Derrick Stolee <dstolee@microsoft.com> Signed-off-by: Junio C Hamano <gitster@pobox.com>
2021-05-18 20:32:47 +02:00
offset = hashfile_total(f);
/*
* The extension headers must be hashed on their own for the
* EOIE extension. Create a hashfile here to compute that hash.
*/
if (offset && record_eoie()) {
CALLOC_ARRAY(eoie_c, 1);
the_hash_algo->init_fn(eoie_c);
}
/*
* Lets write out CACHE_EXT_INDEXENTRYOFFSETTABLE first so that we
* can minimize the number of extensions we have to scan through to
* find it during load. Write it out regardless of the
* strip_extensions parameter as we need it when loading the shared
* index.
*/
if (ieot) {
struct strbuf sb = STRBUF_INIT;
write_ieot_extension(&sb, ieot);
read-cache: use hashfile instead of git_hash_ctx The do_write_index() method in read-cache.c has its own hashing logic and buffering mechanism. Specifically, the ce_write() method was introduced by 4990aadc (Speed up index file writing by chunking it nicely, 2005-04-20) and similar mechanisms were introduced a few months later in c38138cd (git-pack-objects: write the pack files with a SHA1 csum, 2005-06-26). Based on the timing, in the early days of the Git codebase, I figured that these roughly equivalent code paths were never unified only because it got lost in the shuffle. The hashfile API has since been used extensively in other file formats, such as pack-indexes, multi-pack-indexes, and commit-graphs. Therefore, it seems prudent to unify the index writing code to use the same mechanism. I discovered this disparity while trying to create a new index format that uses the chunk-format API. That API uses a hashfile as its base, so it is incompatible with the custom code in read-cache.c. This rewrite is rather straightforward. It replaces all writes to the temporary file with writes to the hashfile struct. This takes care of many of the direct interactions with the_hash_algo. There are still some git_hash_ctx uses remaining: the extension headers are hashed for use in the End of Index Entries (EOIE) extension. This use of the git_hash_ctx is left as-is. There are multiple reasons to not use a hashfile here, including the fact that the data is not actually writing to a file, just a hash computation. These hashes do not block our adoption of the chunk-format API in a future change to the index, so leave it as-is. The internals of the algorithms are mostly identical. Previously, the hashfile API used a smaller 8KB buffer instead of the 128KB buffer from read-cache.c. The previous change already unified these sizes. There is one subtle point: we do not pass the CSUM_FSYNC to the finalize_hashfile() method, which differs from most consumers of the hashfile API. The extra fsync() call indicated by this flag causes a significant peformance degradation that is noticeable for quick commands that write the index, such as "git add". Other consumers can absorb this cost with their more complicated data structure organization, and further writing structures such as pack-files and commit-graphs is rarely in the critical path for common user interactions. Some static methods become orphaned in this diff, so I marked them as MAYBE_UNUSED. The diff is much harder to read if they are deleted during this change. Instead, they will be deleted in the following change. In addition to the test suite passing, I computed indexes using the previous binaries and the binaries compiled after this change, and found the index data to be exactly equal. Finally, I did extensive performance testing of "git update-index --force-write" on repos of various sizes, including one with over 2 million paths at HEAD. These tests demonstrated less than 1% difference in behavior. As expected, the performance should be considered unchanged. The previous changes to increase the hashfile buffer size from 8K to 128K ensured this change would not create a peformance regression. Signed-off-by: Derrick Stolee <dstolee@microsoft.com> Signed-off-by: Junio C Hamano <gitster@pobox.com>
2021-05-18 20:32:47 +02:00
err = write_index_ext_header(f, eoie_c, CACHE_EXT_INDEXENTRYOFFSETTABLE, sb.len) < 0;
hashwrite(f, sb.buf, sb.len);
strbuf_release(&sb);
free(ieot);
if (err)
return -1;
}
read-cache.c: fix writing "link" index ext with null base oid Since commit 7db118303a (unpack_trees: fix breakage when o->src_index != o->dst_index - 2018-04-23) and changes in merge code to use separate index_state for source and destination, when doing a merge with split index activated, we may run into this line in unpack_trees(): o->result.split_index = init_split_index(&o->result); This is by itself not wrong. But this split index information is not fully populated (and it's only so when move_cache_to_base_index() is called, aka force splitting the index, or loading index_state from a file). Both "base_oid" and "base" in this case remain null. So when writing the main index down, we link to this index with null oid (default value after init_split_index()), which also means "no split index" internally. This triggers an incorrect base index refresh: warning: could not freshen shared index '.../sharedindex.0{40}' This patch makes sure we will not refresh null base_oid (because the file is never there). It also makes sure not to write "link" extension with null base_oid in the first place (no point having it at all). Read code already has protection against null base_oid. There is also another side fix in remove_split_index() that causes a crash when doing "git update-index --no-split-index" when base_oid in the index file is null. In this case we will not load istate->split_index->base but we dereference it anyway and are rewarded with a segfault. This should not happen anymore, but it's still wrong to dereference a potential NULL pointer, especially when we do check for NULL pointer in the next code. Reported-by: Luke Diamand <luke@diamand.org> Signed-off-by: Nguyễn Thái Ngọc Duy <pclouds@gmail.com> Signed-off-by: Junio C Hamano <gitster@pobox.com>
2019-02-13 10:51:29 +01:00
if (!strip_extensions && istate->split_index &&
!is_null_oid(&istate->split_index->base_oid)) {
struct strbuf sb = STRBUF_INIT;
err = write_link_extension(&sb, istate) < 0 ||
read-cache: use hashfile instead of git_hash_ctx The do_write_index() method in read-cache.c has its own hashing logic and buffering mechanism. Specifically, the ce_write() method was introduced by 4990aadc (Speed up index file writing by chunking it nicely, 2005-04-20) and similar mechanisms were introduced a few months later in c38138cd (git-pack-objects: write the pack files with a SHA1 csum, 2005-06-26). Based on the timing, in the early days of the Git codebase, I figured that these roughly equivalent code paths were never unified only because it got lost in the shuffle. The hashfile API has since been used extensively in other file formats, such as pack-indexes, multi-pack-indexes, and commit-graphs. Therefore, it seems prudent to unify the index writing code to use the same mechanism. I discovered this disparity while trying to create a new index format that uses the chunk-format API. That API uses a hashfile as its base, so it is incompatible with the custom code in read-cache.c. This rewrite is rather straightforward. It replaces all writes to the temporary file with writes to the hashfile struct. This takes care of many of the direct interactions with the_hash_algo. There are still some git_hash_ctx uses remaining: the extension headers are hashed for use in the End of Index Entries (EOIE) extension. This use of the git_hash_ctx is left as-is. There are multiple reasons to not use a hashfile here, including the fact that the data is not actually writing to a file, just a hash computation. These hashes do not block our adoption of the chunk-format API in a future change to the index, so leave it as-is. The internals of the algorithms are mostly identical. Previously, the hashfile API used a smaller 8KB buffer instead of the 128KB buffer from read-cache.c. The previous change already unified these sizes. There is one subtle point: we do not pass the CSUM_FSYNC to the finalize_hashfile() method, which differs from most consumers of the hashfile API. The extra fsync() call indicated by this flag causes a significant peformance degradation that is noticeable for quick commands that write the index, such as "git add". Other consumers can absorb this cost with their more complicated data structure organization, and further writing structures such as pack-files and commit-graphs is rarely in the critical path for common user interactions. Some static methods become orphaned in this diff, so I marked them as MAYBE_UNUSED. The diff is much harder to read if they are deleted during this change. Instead, they will be deleted in the following change. In addition to the test suite passing, I computed indexes using the previous binaries and the binaries compiled after this change, and found the index data to be exactly equal. Finally, I did extensive performance testing of "git update-index --force-write" on repos of various sizes, including one with over 2 million paths at HEAD. These tests demonstrated less than 1% difference in behavior. As expected, the performance should be considered unchanged. The previous changes to increase the hashfile buffer size from 8K to 128K ensured this change would not create a peformance regression. Signed-off-by: Derrick Stolee <dstolee@microsoft.com> Signed-off-by: Junio C Hamano <gitster@pobox.com>
2021-05-18 20:32:47 +02:00
write_index_ext_header(f, eoie_c, CACHE_EXT_LINK,
sb.len) < 0;
hashwrite(f, sb.buf, sb.len);
strbuf_release(&sb);
if (err)
return -1;
}
cache-tree: reject entries with null sha1 We generally disallow null sha1s from entering the index, due to 4337b5856 (do not write null sha1s to on-disk index, 2012-07-28). However, we loosened that in 83bd7437c (write_index: optionally allow broken null sha1s, 2013-08-27) so that tools like filter-branch could be used to repair broken history. However, we should make sure that these broken entries do not get propagated into new trees. For most entries, we'd catch them with the missing-object check (since presumably the null sha1 does not exist in our object database). But gitlink entries do not need reachability, so we may blindly copy the entry into a bogus tree. This patch rejects all null sha1s (with the same "invalid entry" message that missing objects get) when building trees from the index. It does so even for non-gitlinks, and even when "write-tree" is given the --missing-ok flag. The null sha1 is a special sentinel value that is already rejected in trees by fsck; whether the object exists or not, it is an error to put it in a tree. Note that for this to work, we must also avoid reusing an existing cache-tree that contains the null sha1. This patch does so by just refusing to write out any cache tree when the index contains a null sha1. This is blunter than we need to be; we could just reject the subtree that contains the offending entry. But it's not worth the complexity. The behavior is unchanged unless you have a broken index entry, and even then we'd refuse the whole index write unless the emergency GIT_ALLOW_NULL_SHA1 is in use. And even then the end result is only a performance drop (any write-tree will have to generate the whole cache-tree from scratch). The tests bear some explanation. The existing test in t7009 doesn't catch this problem, because our index-filter runs "git rm --cached", which will try to rewrite the updated index and barf on the bogus entry. So we never even make it to write-tree. The new test there adds a noop index-filter, which does show the problem. The new tests in t1601 are slightly redundant with what filter-branch is doing under the hood in t7009. But as they're much more direct, they're easier to reason about. And should filter-branch ever change or go away, we'd want to make sure that these plumbing commands behave sanely. Signed-off-by: Jeff King <peff@peff.net> Signed-off-by: Junio C Hamano <gitster@pobox.com>
2017-04-21 20:46:17 +02:00
if (!strip_extensions && !drop_cache_tree && istate->cache_tree) {
struct strbuf sb = STRBUF_INIT;
cache_tree_write(&sb, istate->cache_tree);
read-cache: use hashfile instead of git_hash_ctx The do_write_index() method in read-cache.c has its own hashing logic and buffering mechanism. Specifically, the ce_write() method was introduced by 4990aadc (Speed up index file writing by chunking it nicely, 2005-04-20) and similar mechanisms were introduced a few months later in c38138cd (git-pack-objects: write the pack files with a SHA1 csum, 2005-06-26). Based on the timing, in the early days of the Git codebase, I figured that these roughly equivalent code paths were never unified only because it got lost in the shuffle. The hashfile API has since been used extensively in other file formats, such as pack-indexes, multi-pack-indexes, and commit-graphs. Therefore, it seems prudent to unify the index writing code to use the same mechanism. I discovered this disparity while trying to create a new index format that uses the chunk-format API. That API uses a hashfile as its base, so it is incompatible with the custom code in read-cache.c. This rewrite is rather straightforward. It replaces all writes to the temporary file with writes to the hashfile struct. This takes care of many of the direct interactions with the_hash_algo. There are still some git_hash_ctx uses remaining: the extension headers are hashed for use in the End of Index Entries (EOIE) extension. This use of the git_hash_ctx is left as-is. There are multiple reasons to not use a hashfile here, including the fact that the data is not actually writing to a file, just a hash computation. These hashes do not block our adoption of the chunk-format API in a future change to the index, so leave it as-is. The internals of the algorithms are mostly identical. Previously, the hashfile API used a smaller 8KB buffer instead of the 128KB buffer from read-cache.c. The previous change already unified these sizes. There is one subtle point: we do not pass the CSUM_FSYNC to the finalize_hashfile() method, which differs from most consumers of the hashfile API. The extra fsync() call indicated by this flag causes a significant peformance degradation that is noticeable for quick commands that write the index, such as "git add". Other consumers can absorb this cost with their more complicated data structure organization, and further writing structures such as pack-files and commit-graphs is rarely in the critical path for common user interactions. Some static methods become orphaned in this diff, so I marked them as MAYBE_UNUSED. The diff is much harder to read if they are deleted during this change. Instead, they will be deleted in the following change. In addition to the test suite passing, I computed indexes using the previous binaries and the binaries compiled after this change, and found the index data to be exactly equal. Finally, I did extensive performance testing of "git update-index --force-write" on repos of various sizes, including one with over 2 million paths at HEAD. These tests demonstrated less than 1% difference in behavior. As expected, the performance should be considered unchanged. The previous changes to increase the hashfile buffer size from 8K to 128K ensured this change would not create a peformance regression. Signed-off-by: Derrick Stolee <dstolee@microsoft.com> Signed-off-by: Junio C Hamano <gitster@pobox.com>
2021-05-18 20:32:47 +02:00
err = write_index_ext_header(f, eoie_c, CACHE_EXT_TREE, sb.len) < 0;
hashwrite(f, sb.buf, sb.len);
strbuf_release(&sb);
if (err)
return -1;
}
if (!strip_extensions && istate->resolve_undo) {
struct strbuf sb = STRBUF_INIT;
resolve_undo_write(&sb, istate->resolve_undo);
read-cache: use hashfile instead of git_hash_ctx The do_write_index() method in read-cache.c has its own hashing logic and buffering mechanism. Specifically, the ce_write() method was introduced by 4990aadc (Speed up index file writing by chunking it nicely, 2005-04-20) and similar mechanisms were introduced a few months later in c38138cd (git-pack-objects: write the pack files with a SHA1 csum, 2005-06-26). Based on the timing, in the early days of the Git codebase, I figured that these roughly equivalent code paths were never unified only because it got lost in the shuffle. The hashfile API has since been used extensively in other file formats, such as pack-indexes, multi-pack-indexes, and commit-graphs. Therefore, it seems prudent to unify the index writing code to use the same mechanism. I discovered this disparity while trying to create a new index format that uses the chunk-format API. That API uses a hashfile as its base, so it is incompatible with the custom code in read-cache.c. This rewrite is rather straightforward. It replaces all writes to the temporary file with writes to the hashfile struct. This takes care of many of the direct interactions with the_hash_algo. There are still some git_hash_ctx uses remaining: the extension headers are hashed for use in the End of Index Entries (EOIE) extension. This use of the git_hash_ctx is left as-is. There are multiple reasons to not use a hashfile here, including the fact that the data is not actually writing to a file, just a hash computation. These hashes do not block our adoption of the chunk-format API in a future change to the index, so leave it as-is. The internals of the algorithms are mostly identical. Previously, the hashfile API used a smaller 8KB buffer instead of the 128KB buffer from read-cache.c. The previous change already unified these sizes. There is one subtle point: we do not pass the CSUM_FSYNC to the finalize_hashfile() method, which differs from most consumers of the hashfile API. The extra fsync() call indicated by this flag causes a significant peformance degradation that is noticeable for quick commands that write the index, such as "git add". Other consumers can absorb this cost with their more complicated data structure organization, and further writing structures such as pack-files and commit-graphs is rarely in the critical path for common user interactions. Some static methods become orphaned in this diff, so I marked them as MAYBE_UNUSED. The diff is much harder to read if they are deleted during this change. Instead, they will be deleted in the following change. In addition to the test suite passing, I computed indexes using the previous binaries and the binaries compiled after this change, and found the index data to be exactly equal. Finally, I did extensive performance testing of "git update-index --force-write" on repos of various sizes, including one with over 2 million paths at HEAD. These tests demonstrated less than 1% difference in behavior. As expected, the performance should be considered unchanged. The previous changes to increase the hashfile buffer size from 8K to 128K ensured this change would not create a peformance regression. Signed-off-by: Derrick Stolee <dstolee@microsoft.com> Signed-off-by: Junio C Hamano <gitster@pobox.com>
2021-05-18 20:32:47 +02:00
err = write_index_ext_header(f, eoie_c, CACHE_EXT_RESOLVE_UNDO,
sb.len) < 0;
hashwrite(f, sb.buf, sb.len);
strbuf_release(&sb);
if (err)
return -1;
}
if (!strip_extensions && istate->untracked) {
struct strbuf sb = STRBUF_INIT;
write_untracked_extension(&sb, istate->untracked);
read-cache: use hashfile instead of git_hash_ctx The do_write_index() method in read-cache.c has its own hashing logic and buffering mechanism. Specifically, the ce_write() method was introduced by 4990aadc (Speed up index file writing by chunking it nicely, 2005-04-20) and similar mechanisms were introduced a few months later in c38138cd (git-pack-objects: write the pack files with a SHA1 csum, 2005-06-26). Based on the timing, in the early days of the Git codebase, I figured that these roughly equivalent code paths were never unified only because it got lost in the shuffle. The hashfile API has since been used extensively in other file formats, such as pack-indexes, multi-pack-indexes, and commit-graphs. Therefore, it seems prudent to unify the index writing code to use the same mechanism. I discovered this disparity while trying to create a new index format that uses the chunk-format API. That API uses a hashfile as its base, so it is incompatible with the custom code in read-cache.c. This rewrite is rather straightforward. It replaces all writes to the temporary file with writes to the hashfile struct. This takes care of many of the direct interactions with the_hash_algo. There are still some git_hash_ctx uses remaining: the extension headers are hashed for use in the End of Index Entries (EOIE) extension. This use of the git_hash_ctx is left as-is. There are multiple reasons to not use a hashfile here, including the fact that the data is not actually writing to a file, just a hash computation. These hashes do not block our adoption of the chunk-format API in a future change to the index, so leave it as-is. The internals of the algorithms are mostly identical. Previously, the hashfile API used a smaller 8KB buffer instead of the 128KB buffer from read-cache.c. The previous change already unified these sizes. There is one subtle point: we do not pass the CSUM_FSYNC to the finalize_hashfile() method, which differs from most consumers of the hashfile API. The extra fsync() call indicated by this flag causes a significant peformance degradation that is noticeable for quick commands that write the index, such as "git add". Other consumers can absorb this cost with their more complicated data structure organization, and further writing structures such as pack-files and commit-graphs is rarely in the critical path for common user interactions. Some static methods become orphaned in this diff, so I marked them as MAYBE_UNUSED. The diff is much harder to read if they are deleted during this change. Instead, they will be deleted in the following change. In addition to the test suite passing, I computed indexes using the previous binaries and the binaries compiled after this change, and found the index data to be exactly equal. Finally, I did extensive performance testing of "git update-index --force-write" on repos of various sizes, including one with over 2 million paths at HEAD. These tests demonstrated less than 1% difference in behavior. As expected, the performance should be considered unchanged. The previous changes to increase the hashfile buffer size from 8K to 128K ensured this change would not create a peformance regression. Signed-off-by: Derrick Stolee <dstolee@microsoft.com> Signed-off-by: Junio C Hamano <gitster@pobox.com>
2021-05-18 20:32:47 +02:00
err = write_index_ext_header(f, eoie_c, CACHE_EXT_UNTRACKED,
sb.len) < 0;
hashwrite(f, sb.buf, sb.len);
strbuf_release(&sb);
if (err)
return -1;
}
if (!strip_extensions && istate->fsmonitor_last_update) {
struct strbuf sb = STRBUF_INIT;
write_fsmonitor_extension(&sb, istate);
read-cache: use hashfile instead of git_hash_ctx The do_write_index() method in read-cache.c has its own hashing logic and buffering mechanism. Specifically, the ce_write() method was introduced by 4990aadc (Speed up index file writing by chunking it nicely, 2005-04-20) and similar mechanisms were introduced a few months later in c38138cd (git-pack-objects: write the pack files with a SHA1 csum, 2005-06-26). Based on the timing, in the early days of the Git codebase, I figured that these roughly equivalent code paths were never unified only because it got lost in the shuffle. The hashfile API has since been used extensively in other file formats, such as pack-indexes, multi-pack-indexes, and commit-graphs. Therefore, it seems prudent to unify the index writing code to use the same mechanism. I discovered this disparity while trying to create a new index format that uses the chunk-format API. That API uses a hashfile as its base, so it is incompatible with the custom code in read-cache.c. This rewrite is rather straightforward. It replaces all writes to the temporary file with writes to the hashfile struct. This takes care of many of the direct interactions with the_hash_algo. There are still some git_hash_ctx uses remaining: the extension headers are hashed for use in the End of Index Entries (EOIE) extension. This use of the git_hash_ctx is left as-is. There are multiple reasons to not use a hashfile here, including the fact that the data is not actually writing to a file, just a hash computation. These hashes do not block our adoption of the chunk-format API in a future change to the index, so leave it as-is. The internals of the algorithms are mostly identical. Previously, the hashfile API used a smaller 8KB buffer instead of the 128KB buffer from read-cache.c. The previous change already unified these sizes. There is one subtle point: we do not pass the CSUM_FSYNC to the finalize_hashfile() method, which differs from most consumers of the hashfile API. The extra fsync() call indicated by this flag causes a significant peformance degradation that is noticeable for quick commands that write the index, such as "git add". Other consumers can absorb this cost with their more complicated data structure organization, and further writing structures such as pack-files and commit-graphs is rarely in the critical path for common user interactions. Some static methods become orphaned in this diff, so I marked them as MAYBE_UNUSED. The diff is much harder to read if they are deleted during this change. Instead, they will be deleted in the following change. In addition to the test suite passing, I computed indexes using the previous binaries and the binaries compiled after this change, and found the index data to be exactly equal. Finally, I did extensive performance testing of "git update-index --force-write" on repos of various sizes, including one with over 2 million paths at HEAD. These tests demonstrated less than 1% difference in behavior. As expected, the performance should be considered unchanged. The previous changes to increase the hashfile buffer size from 8K to 128K ensured this change would not create a peformance regression. Signed-off-by: Derrick Stolee <dstolee@microsoft.com> Signed-off-by: Junio C Hamano <gitster@pobox.com>
2021-05-18 20:32:47 +02:00
err = write_index_ext_header(f, eoie_c, CACHE_EXT_FSMONITOR, sb.len) < 0;
hashwrite(f, sb.buf, sb.len);
strbuf_release(&sb);
if (err)
return -1;
}
if (istate->sparse_index) {
read-cache: use hashfile instead of git_hash_ctx The do_write_index() method in read-cache.c has its own hashing logic and buffering mechanism. Specifically, the ce_write() method was introduced by 4990aadc (Speed up index file writing by chunking it nicely, 2005-04-20) and similar mechanisms were introduced a few months later in c38138cd (git-pack-objects: write the pack files with a SHA1 csum, 2005-06-26). Based on the timing, in the early days of the Git codebase, I figured that these roughly equivalent code paths were never unified only because it got lost in the shuffle. The hashfile API has since been used extensively in other file formats, such as pack-indexes, multi-pack-indexes, and commit-graphs. Therefore, it seems prudent to unify the index writing code to use the same mechanism. I discovered this disparity while trying to create a new index format that uses the chunk-format API. That API uses a hashfile as its base, so it is incompatible with the custom code in read-cache.c. This rewrite is rather straightforward. It replaces all writes to the temporary file with writes to the hashfile struct. This takes care of many of the direct interactions with the_hash_algo. There are still some git_hash_ctx uses remaining: the extension headers are hashed for use in the End of Index Entries (EOIE) extension. This use of the git_hash_ctx is left as-is. There are multiple reasons to not use a hashfile here, including the fact that the data is not actually writing to a file, just a hash computation. These hashes do not block our adoption of the chunk-format API in a future change to the index, so leave it as-is. The internals of the algorithms are mostly identical. Previously, the hashfile API used a smaller 8KB buffer instead of the 128KB buffer from read-cache.c. The previous change already unified these sizes. There is one subtle point: we do not pass the CSUM_FSYNC to the finalize_hashfile() method, which differs from most consumers of the hashfile API. The extra fsync() call indicated by this flag causes a significant peformance degradation that is noticeable for quick commands that write the index, such as "git add". Other consumers can absorb this cost with their more complicated data structure organization, and further writing structures such as pack-files and commit-graphs is rarely in the critical path for common user interactions. Some static methods become orphaned in this diff, so I marked them as MAYBE_UNUSED. The diff is much harder to read if they are deleted during this change. Instead, they will be deleted in the following change. In addition to the test suite passing, I computed indexes using the previous binaries and the binaries compiled after this change, and found the index data to be exactly equal. Finally, I did extensive performance testing of "git update-index --force-write" on repos of various sizes, including one with over 2 million paths at HEAD. These tests demonstrated less than 1% difference in behavior. As expected, the performance should be considered unchanged. The previous changes to increase the hashfile buffer size from 8K to 128K ensured this change would not create a peformance regression. Signed-off-by: Derrick Stolee <dstolee@microsoft.com> Signed-off-by: Junio C Hamano <gitster@pobox.com>
2021-05-18 20:32:47 +02:00
if (write_index_ext_header(f, eoie_c, CACHE_EXT_SPARSE_DIRECTORIES, 0) < 0)
return -1;
}
/*
* CACHE_EXT_ENDOFINDEXENTRIES must be written as the last entry before the SHA1
* so that it can be found and processed before all the index entries are
* read. Write it out regardless of the strip_extensions parameter as we need it
* when loading the shared index.
*/
read-cache: use hashfile instead of git_hash_ctx The do_write_index() method in read-cache.c has its own hashing logic and buffering mechanism. Specifically, the ce_write() method was introduced by 4990aadc (Speed up index file writing by chunking it nicely, 2005-04-20) and similar mechanisms were introduced a few months later in c38138cd (git-pack-objects: write the pack files with a SHA1 csum, 2005-06-26). Based on the timing, in the early days of the Git codebase, I figured that these roughly equivalent code paths were never unified only because it got lost in the shuffle. The hashfile API has since been used extensively in other file formats, such as pack-indexes, multi-pack-indexes, and commit-graphs. Therefore, it seems prudent to unify the index writing code to use the same mechanism. I discovered this disparity while trying to create a new index format that uses the chunk-format API. That API uses a hashfile as its base, so it is incompatible with the custom code in read-cache.c. This rewrite is rather straightforward. It replaces all writes to the temporary file with writes to the hashfile struct. This takes care of many of the direct interactions with the_hash_algo. There are still some git_hash_ctx uses remaining: the extension headers are hashed for use in the End of Index Entries (EOIE) extension. This use of the git_hash_ctx is left as-is. There are multiple reasons to not use a hashfile here, including the fact that the data is not actually writing to a file, just a hash computation. These hashes do not block our adoption of the chunk-format API in a future change to the index, so leave it as-is. The internals of the algorithms are mostly identical. Previously, the hashfile API used a smaller 8KB buffer instead of the 128KB buffer from read-cache.c. The previous change already unified these sizes. There is one subtle point: we do not pass the CSUM_FSYNC to the finalize_hashfile() method, which differs from most consumers of the hashfile API. The extra fsync() call indicated by this flag causes a significant peformance degradation that is noticeable for quick commands that write the index, such as "git add". Other consumers can absorb this cost with their more complicated data structure organization, and further writing structures such as pack-files and commit-graphs is rarely in the critical path for common user interactions. Some static methods become orphaned in this diff, so I marked them as MAYBE_UNUSED. The diff is much harder to read if they are deleted during this change. Instead, they will be deleted in the following change. In addition to the test suite passing, I computed indexes using the previous binaries and the binaries compiled after this change, and found the index data to be exactly equal. Finally, I did extensive performance testing of "git update-index --force-write" on repos of various sizes, including one with over 2 million paths at HEAD. These tests demonstrated less than 1% difference in behavior. As expected, the performance should be considered unchanged. The previous changes to increase the hashfile buffer size from 8K to 128K ensured this change would not create a peformance regression. Signed-off-by: Derrick Stolee <dstolee@microsoft.com> Signed-off-by: Junio C Hamano <gitster@pobox.com>
2021-05-18 20:32:47 +02:00
if (eoie_c) {
struct strbuf sb = STRBUF_INIT;
read-cache: use hashfile instead of git_hash_ctx The do_write_index() method in read-cache.c has its own hashing logic and buffering mechanism. Specifically, the ce_write() method was introduced by 4990aadc (Speed up index file writing by chunking it nicely, 2005-04-20) and similar mechanisms were introduced a few months later in c38138cd (git-pack-objects: write the pack files with a SHA1 csum, 2005-06-26). Based on the timing, in the early days of the Git codebase, I figured that these roughly equivalent code paths were never unified only because it got lost in the shuffle. The hashfile API has since been used extensively in other file formats, such as pack-indexes, multi-pack-indexes, and commit-graphs. Therefore, it seems prudent to unify the index writing code to use the same mechanism. I discovered this disparity while trying to create a new index format that uses the chunk-format API. That API uses a hashfile as its base, so it is incompatible with the custom code in read-cache.c. This rewrite is rather straightforward. It replaces all writes to the temporary file with writes to the hashfile struct. This takes care of many of the direct interactions with the_hash_algo. There are still some git_hash_ctx uses remaining: the extension headers are hashed for use in the End of Index Entries (EOIE) extension. This use of the git_hash_ctx is left as-is. There are multiple reasons to not use a hashfile here, including the fact that the data is not actually writing to a file, just a hash computation. These hashes do not block our adoption of the chunk-format API in a future change to the index, so leave it as-is. The internals of the algorithms are mostly identical. Previously, the hashfile API used a smaller 8KB buffer instead of the 128KB buffer from read-cache.c. The previous change already unified these sizes. There is one subtle point: we do not pass the CSUM_FSYNC to the finalize_hashfile() method, which differs from most consumers of the hashfile API. The extra fsync() call indicated by this flag causes a significant peformance degradation that is noticeable for quick commands that write the index, such as "git add". Other consumers can absorb this cost with their more complicated data structure organization, and further writing structures such as pack-files and commit-graphs is rarely in the critical path for common user interactions. Some static methods become orphaned in this diff, so I marked them as MAYBE_UNUSED. The diff is much harder to read if they are deleted during this change. Instead, they will be deleted in the following change. In addition to the test suite passing, I computed indexes using the previous binaries and the binaries compiled after this change, and found the index data to be exactly equal. Finally, I did extensive performance testing of "git update-index --force-write" on repos of various sizes, including one with over 2 million paths at HEAD. These tests demonstrated less than 1% difference in behavior. As expected, the performance should be considered unchanged. The previous changes to increase the hashfile buffer size from 8K to 128K ensured this change would not create a peformance regression. Signed-off-by: Derrick Stolee <dstolee@microsoft.com> Signed-off-by: Junio C Hamano <gitster@pobox.com>
2021-05-18 20:32:47 +02:00
write_eoie_extension(&sb, eoie_c, offset);
err = write_index_ext_header(f, NULL, CACHE_EXT_ENDOFINDEXENTRIES, sb.len) < 0;
hashwrite(f, sb.buf, sb.len);
strbuf_release(&sb);
if (err)
return -1;
}
read-cache: use hashfile instead of git_hash_ctx The do_write_index() method in read-cache.c has its own hashing logic and buffering mechanism. Specifically, the ce_write() method was introduced by 4990aadc (Speed up index file writing by chunking it nicely, 2005-04-20) and similar mechanisms were introduced a few months later in c38138cd (git-pack-objects: write the pack files with a SHA1 csum, 2005-06-26). Based on the timing, in the early days of the Git codebase, I figured that these roughly equivalent code paths were never unified only because it got lost in the shuffle. The hashfile API has since been used extensively in other file formats, such as pack-indexes, multi-pack-indexes, and commit-graphs. Therefore, it seems prudent to unify the index writing code to use the same mechanism. I discovered this disparity while trying to create a new index format that uses the chunk-format API. That API uses a hashfile as its base, so it is incompatible with the custom code in read-cache.c. This rewrite is rather straightforward. It replaces all writes to the temporary file with writes to the hashfile struct. This takes care of many of the direct interactions with the_hash_algo. There are still some git_hash_ctx uses remaining: the extension headers are hashed for use in the End of Index Entries (EOIE) extension. This use of the git_hash_ctx is left as-is. There are multiple reasons to not use a hashfile here, including the fact that the data is not actually writing to a file, just a hash computation. These hashes do not block our adoption of the chunk-format API in a future change to the index, so leave it as-is. The internals of the algorithms are mostly identical. Previously, the hashfile API used a smaller 8KB buffer instead of the 128KB buffer from read-cache.c. The previous change already unified these sizes. There is one subtle point: we do not pass the CSUM_FSYNC to the finalize_hashfile() method, which differs from most consumers of the hashfile API. The extra fsync() call indicated by this flag causes a significant peformance degradation that is noticeable for quick commands that write the index, such as "git add". Other consumers can absorb this cost with their more complicated data structure organization, and further writing structures such as pack-files and commit-graphs is rarely in the critical path for common user interactions. Some static methods become orphaned in this diff, so I marked them as MAYBE_UNUSED. The diff is much harder to read if they are deleted during this change. Instead, they will be deleted in the following change. In addition to the test suite passing, I computed indexes using the previous binaries and the binaries compiled after this change, and found the index data to be exactly equal. Finally, I did extensive performance testing of "git update-index --force-write" on repos of various sizes, including one with over 2 million paths at HEAD. These tests demonstrated less than 1% difference in behavior. As expected, the performance should be considered unchanged. The previous changes to increase the hashfile buffer size from 8K to 128K ensured this change would not create a peformance regression. Signed-off-by: Derrick Stolee <dstolee@microsoft.com> Signed-off-by: Junio C Hamano <gitster@pobox.com>
2021-05-18 20:32:47 +02:00
finalize_hashfile(f, istate->oid.hash, CSUM_HASH_IN_STREAM);
tempfile: do not delete tempfile on failed close When close_tempfile() fails, we delete the tempfile and reset the fields of the tempfile struct. This makes it easier for callers to return without cleaning up, but it also makes this common pattern: if (close_tempfile(tempfile)) return error_errno("error closing %s", tempfile->filename.buf); wrong, because the "filename" field has been reset after the failed close. And it's not easy to fix, as in many cases we don't have another copy of the filename (e.g., if it was created via one of the mks_tempfile functions, and we just have the original template string). Let's drop the feature that a failed close automatically deletes the file. This puts the burden on the caller to do the deletion themselves, but this isn't that big a deal. Callers which do: if (write(...) || close_tempfile(...)) { delete_tempfile(...); return -1; } already had to call delete when the write() failed, and so aren't affected. Likewise, any caller which just calls die() in the error path is OK; we'll delete the tempfile during the atexit handler. Because this patch changes the semantics of close_tempfile() without changing its signature, all callers need to be manually checked and converted to the new scheme. This patch covers all in-tree callers, but there may be others for not-yet-merged topics. To catch these, we rename the function to close_tempfile_gently(), which will attract compile-time attention to new callers. (Technically the original could be considered "gentle" already in that it didn't die() on errors, but this one is even more so). Signed-off-by: Jeff King <peff@peff.net> Signed-off-by: Junio C Hamano <gitster@pobox.com>
2017-09-05 14:14:30 +02:00
if (close_tempfile_gently(tempfile)) {
error(_("could not close '%s'"), get_tempfile_path(tempfile));
tempfile: do not delete tempfile on failed close When close_tempfile() fails, we delete the tempfile and reset the fields of the tempfile struct. This makes it easier for callers to return without cleaning up, but it also makes this common pattern: if (close_tempfile(tempfile)) return error_errno("error closing %s", tempfile->filename.buf); wrong, because the "filename" field has been reset after the failed close. And it's not easy to fix, as in many cases we don't have another copy of the filename (e.g., if it was created via one of the mks_tempfile functions, and we just have the original template string). Let's drop the feature that a failed close automatically deletes the file. This puts the burden on the caller to do the deletion themselves, but this isn't that big a deal. Callers which do: if (write(...) || close_tempfile(...)) { delete_tempfile(...); return -1; } already had to call delete when the write() failed, and so aren't affected. Likewise, any caller which just calls die() in the error path is OK; we'll delete the tempfile during the atexit handler. Because this patch changes the semantics of close_tempfile() without changing its signature, all callers need to be manually checked and converted to the new scheme. This patch covers all in-tree callers, but there may be others for not-yet-merged topics. To catch these, we rename the function to close_tempfile_gently(), which will attract compile-time attention to new callers. (Technically the original could be considered "gentle" already in that it didn't die() on errors, but this one is even more so). Signed-off-by: Jeff King <peff@peff.net> Signed-off-by: Junio C Hamano <gitster@pobox.com>
2017-09-05 14:14:30 +02:00
return -1;
}
if (stat(get_tempfile_path(tempfile), &st))
return -1;
istate->timestamp.sec = (unsigned int)st.st_mtime;
istate->timestamp.nsec = ST_MTIME_NSEC(st);
trace_performance_since(start, "write index, changed mask = %x", istate->cache_changed);
/*
* TODO trace2: replace "the_repository" with the actual repo instance
* that is associated with the given "istate".
*/
trace2_data_intmax("index", the_repository, "write/version",
istate->version);
trace2_data_intmax("index", the_repository, "write/cache_nr",
istate->cache_nr);
return 0;
}
void set_alternate_index_output(const char *name)
{
alternate_index_output = name;
}
static int commit_locked_index(struct lock_file *lk)
{
if (alternate_index_output)
return commit_lock_file_to(lk, alternate_index_output);
else
return commit_lock_file(lk);
}
static int do_write_locked_index(struct index_state *istate, struct lock_file *lock,
unsigned flags)
{
int ret;
sparse-index: convert from full to sparse If we have a full index, then we can convert it to a sparse index by replacing directories outside of the sparse cone with sparse directory entries. The convert_to_sparse() method does this, when the situation is appropriate. For now, we avoid converting the index to a sparse index if: 1. the index is split. 2. the index is already sparse. 3. sparse-checkout is disabled. 4. sparse-checkout does not use cone mode. Finally, we currently limit the conversion to when the GIT_TEST_SPARSE_INDEX environment variable is enabled. A mode using Git config will be added in a later change. The trickiest thing about this conversion is that we might not be able to mark a directory as a sparse directory just because it is outside the sparse cone. There might be unmerged files within that directory, so we need to look for those. Also, if there is some strange reason why a file is not marked with CE_SKIP_WORKTREE, then we should give up on converting that directory. There is still hope that some of its subdirectories might be able to convert to sparse, so we keep looking deeper. The conversion process is assisted by the cache-tree extension. This is calculated from the full index if it does not already exist. We then abandon the cache-tree as it no longer applies to the newly-sparse index. Thus, this cache-tree will be recalculated in every sparse-full-sparse round-trip until we integrate the cache-tree extension with the sparse index. Some Git commands use the index after writing it. For example, 'git add' will update the index, then write it to disk, then read its entries to report information. To keep the in-memory index in a full state after writing, we re-expand it to a full one after the write. This is wasteful for commands that only write the index and do not read from it again, but that is only the case until we make those commands "sparse aware." We can compare the behavior of the sparse-index in t1092-sparse-checkout-compability.sh by using GIT_TEST_SPARSE_INDEX=1 when operating on the 'sparse-index' repo. We can also compare the two sparse repos directly, such as comparing their indexes (when expanded to full in the case of the 'sparse-index' repo). We also verify that the index is actually populated with sparse directory entries. The 'checkout and reset (mixed)' test is marked for failure when comparing a sparse repo to a full repo, but we can compare the two sparse-checkout cases directly to ensure that we are not changing the behavior when using a sparse index. Signed-off-by: Derrick Stolee <dstolee@microsoft.com> Signed-off-by: Junio C Hamano <gitster@pobox.com>
2021-03-30 15:10:55 +02:00
int was_full = !istate->sparse_index;
ret = convert_to_sparse(istate, 0);
sparse-index: convert from full to sparse If we have a full index, then we can convert it to a sparse index by replacing directories outside of the sparse cone with sparse directory entries. The convert_to_sparse() method does this, when the situation is appropriate. For now, we avoid converting the index to a sparse index if: 1. the index is split. 2. the index is already sparse. 3. sparse-checkout is disabled. 4. sparse-checkout does not use cone mode. Finally, we currently limit the conversion to when the GIT_TEST_SPARSE_INDEX environment variable is enabled. A mode using Git config will be added in a later change. The trickiest thing about this conversion is that we might not be able to mark a directory as a sparse directory just because it is outside the sparse cone. There might be unmerged files within that directory, so we need to look for those. Also, if there is some strange reason why a file is not marked with CE_SKIP_WORKTREE, then we should give up on converting that directory. There is still hope that some of its subdirectories might be able to convert to sparse, so we keep looking deeper. The conversion process is assisted by the cache-tree extension. This is calculated from the full index if it does not already exist. We then abandon the cache-tree as it no longer applies to the newly-sparse index. Thus, this cache-tree will be recalculated in every sparse-full-sparse round-trip until we integrate the cache-tree extension with the sparse index. Some Git commands use the index after writing it. For example, 'git add' will update the index, then write it to disk, then read its entries to report information. To keep the in-memory index in a full state after writing, we re-expand it to a full one after the write. This is wasteful for commands that only write the index and do not read from it again, but that is only the case until we make those commands "sparse aware." We can compare the behavior of the sparse-index in t1092-sparse-checkout-compability.sh by using GIT_TEST_SPARSE_INDEX=1 when operating on the 'sparse-index' repo. We can also compare the two sparse repos directly, such as comparing their indexes (when expanded to full in the case of the 'sparse-index' repo). We also verify that the index is actually populated with sparse directory entries. The 'checkout and reset (mixed)' test is marked for failure when comparing a sparse repo to a full repo, but we can compare the two sparse-checkout cases directly to ensure that we are not changing the behavior when using a sparse index. Signed-off-by: Derrick Stolee <dstolee@microsoft.com> Signed-off-by: Junio C Hamano <gitster@pobox.com>
2021-03-30 15:10:55 +02:00
if (ret) {
warning(_("failed to convert to a sparse-index"));
return ret;
}
/*
* TODO trace2: replace "the_repository" with the actual repo instance
* that is associated with the given "istate".
*/
trace2_region_enter_printf("index", "do_write_index", the_repository,
"%s", get_lock_file_path(lock));
ret = do_write_index(istate, lock->tempfile, 0);
trace2_region_leave_printf("index", "do_write_index", the_repository,
"%s", get_lock_file_path(lock));
sparse-index: convert from full to sparse If we have a full index, then we can convert it to a sparse index by replacing directories outside of the sparse cone with sparse directory entries. The convert_to_sparse() method does this, when the situation is appropriate. For now, we avoid converting the index to a sparse index if: 1. the index is split. 2. the index is already sparse. 3. sparse-checkout is disabled. 4. sparse-checkout does not use cone mode. Finally, we currently limit the conversion to when the GIT_TEST_SPARSE_INDEX environment variable is enabled. A mode using Git config will be added in a later change. The trickiest thing about this conversion is that we might not be able to mark a directory as a sparse directory just because it is outside the sparse cone. There might be unmerged files within that directory, so we need to look for those. Also, if there is some strange reason why a file is not marked with CE_SKIP_WORKTREE, then we should give up on converting that directory. There is still hope that some of its subdirectories might be able to convert to sparse, so we keep looking deeper. The conversion process is assisted by the cache-tree extension. This is calculated from the full index if it does not already exist. We then abandon the cache-tree as it no longer applies to the newly-sparse index. Thus, this cache-tree will be recalculated in every sparse-full-sparse round-trip until we integrate the cache-tree extension with the sparse index. Some Git commands use the index after writing it. For example, 'git add' will update the index, then write it to disk, then read its entries to report information. To keep the in-memory index in a full state after writing, we re-expand it to a full one after the write. This is wasteful for commands that only write the index and do not read from it again, but that is only the case until we make those commands "sparse aware." We can compare the behavior of the sparse-index in t1092-sparse-checkout-compability.sh by using GIT_TEST_SPARSE_INDEX=1 when operating on the 'sparse-index' repo. We can also compare the two sparse repos directly, such as comparing their indexes (when expanded to full in the case of the 'sparse-index' repo). We also verify that the index is actually populated with sparse directory entries. The 'checkout and reset (mixed)' test is marked for failure when comparing a sparse repo to a full repo, but we can compare the two sparse-checkout cases directly to ensure that we are not changing the behavior when using a sparse index. Signed-off-by: Derrick Stolee <dstolee@microsoft.com> Signed-off-by: Junio C Hamano <gitster@pobox.com>
2021-03-30 15:10:55 +02:00
if (was_full)
ensure_full_index(istate);
if (ret)
return ret;
if (flags & COMMIT_LOCK)
ret = commit_locked_index(lock);
else
ret = close_lock_file_gently(lock);
run_hook_le(NULL, "post-index-change",
istate->updated_workdir ? "1" : "0",
istate->updated_skipworktree ? "1" : "0", NULL);
istate->updated_workdir = 0;
istate->updated_skipworktree = 0;
return ret;
}
static int write_split_index(struct index_state *istate,
struct lock_file *lock,
unsigned flags)
{
int ret;
prepare_to_write_split_index(istate);
ret = do_write_locked_index(istate, lock, flags);
finish_writing_split_index(istate);
return ret;
}
static const char *shared_index_expire = "2.weeks.ago";
static unsigned long get_shared_index_expire_date(void)
{
static unsigned long shared_index_expire_date;
static int shared_index_expire_date_prepared;
if (!shared_index_expire_date_prepared) {
git_config_get_expiry("splitindex.sharedindexexpire",
&shared_index_expire);
shared_index_expire_date = approxidate(shared_index_expire);
shared_index_expire_date_prepared = 1;
}
return shared_index_expire_date;
}
static int should_delete_shared_index(const char *shared_index_path)
{
struct stat st;
unsigned long expiration;
/* Check timestamp */
expiration = get_shared_index_expire_date();
if (!expiration)
return 0;
if (stat(shared_index_path, &st))
return error_errno(_("could not stat '%s'"), shared_index_path);
if (st.st_mtime > expiration)
return 0;
return 1;
}
static int clean_shared_index_files(const char *current_hex)
{
struct dirent *de;
DIR *dir = opendir(get_git_dir());
if (!dir)
return error_errno(_("unable to open git dir: %s"), get_git_dir());
while ((de = readdir(dir)) != NULL) {
const char *sha1_hex;
const char *shared_index_path;
if (!skip_prefix(de->d_name, "sharedindex.", &sha1_hex))
continue;
if (!strcmp(sha1_hex, current_hex))
continue;
shared_index_path = git_path("%s", de->d_name);
if (should_delete_shared_index(shared_index_path) > 0 &&
unlink(shared_index_path))
warning_errno(_("unable to unlink: %s"), shared_index_path);
}
closedir(dir);
return 0;
}
static int write_shared_index(struct index_state *istate,
struct tempfile **temp)
{
struct split_index *si = istate->split_index;
sparse-index: convert from full to sparse If we have a full index, then we can convert it to a sparse index by replacing directories outside of the sparse cone with sparse directory entries. The convert_to_sparse() method does this, when the situation is appropriate. For now, we avoid converting the index to a sparse index if: 1. the index is split. 2. the index is already sparse. 3. sparse-checkout is disabled. 4. sparse-checkout does not use cone mode. Finally, we currently limit the conversion to when the GIT_TEST_SPARSE_INDEX environment variable is enabled. A mode using Git config will be added in a later change. The trickiest thing about this conversion is that we might not be able to mark a directory as a sparse directory just because it is outside the sparse cone. There might be unmerged files within that directory, so we need to look for those. Also, if there is some strange reason why a file is not marked with CE_SKIP_WORKTREE, then we should give up on converting that directory. There is still hope that some of its subdirectories might be able to convert to sparse, so we keep looking deeper. The conversion process is assisted by the cache-tree extension. This is calculated from the full index if it does not already exist. We then abandon the cache-tree as it no longer applies to the newly-sparse index. Thus, this cache-tree will be recalculated in every sparse-full-sparse round-trip until we integrate the cache-tree extension with the sparse index. Some Git commands use the index after writing it. For example, 'git add' will update the index, then write it to disk, then read its entries to report information. To keep the in-memory index in a full state after writing, we re-expand it to a full one after the write. This is wasteful for commands that only write the index and do not read from it again, but that is only the case until we make those commands "sparse aware." We can compare the behavior of the sparse-index in t1092-sparse-checkout-compability.sh by using GIT_TEST_SPARSE_INDEX=1 when operating on the 'sparse-index' repo. We can also compare the two sparse repos directly, such as comparing their indexes (when expanded to full in the case of the 'sparse-index' repo). We also verify that the index is actually populated with sparse directory entries. The 'checkout and reset (mixed)' test is marked for failure when comparing a sparse repo to a full repo, but we can compare the two sparse-checkout cases directly to ensure that we are not changing the behavior when using a sparse index. Signed-off-by: Derrick Stolee <dstolee@microsoft.com> Signed-off-by: Junio C Hamano <gitster@pobox.com>
2021-03-30 15:10:55 +02:00
int ret, was_full = !istate->sparse_index;
move_cache_to_base_index(istate);
convert_to_sparse(istate, 0);
trace2_region_enter_printf("index", "shared/do_write_index",
the_repository, "%s", get_tempfile_path(*temp));
ret = do_write_index(si->base, *temp, 1);
trace2_region_leave_printf("index", "shared/do_write_index",
the_repository, "%s", get_tempfile_path(*temp));
sparse-index: convert from full to sparse If we have a full index, then we can convert it to a sparse index by replacing directories outside of the sparse cone with sparse directory entries. The convert_to_sparse() method does this, when the situation is appropriate. For now, we avoid converting the index to a sparse index if: 1. the index is split. 2. the index is already sparse. 3. sparse-checkout is disabled. 4. sparse-checkout does not use cone mode. Finally, we currently limit the conversion to when the GIT_TEST_SPARSE_INDEX environment variable is enabled. A mode using Git config will be added in a later change. The trickiest thing about this conversion is that we might not be able to mark a directory as a sparse directory just because it is outside the sparse cone. There might be unmerged files within that directory, so we need to look for those. Also, if there is some strange reason why a file is not marked with CE_SKIP_WORKTREE, then we should give up on converting that directory. There is still hope that some of its subdirectories might be able to convert to sparse, so we keep looking deeper. The conversion process is assisted by the cache-tree extension. This is calculated from the full index if it does not already exist. We then abandon the cache-tree as it no longer applies to the newly-sparse index. Thus, this cache-tree will be recalculated in every sparse-full-sparse round-trip until we integrate the cache-tree extension with the sparse index. Some Git commands use the index after writing it. For example, 'git add' will update the index, then write it to disk, then read its entries to report information. To keep the in-memory index in a full state after writing, we re-expand it to a full one after the write. This is wasteful for commands that only write the index and do not read from it again, but that is only the case until we make those commands "sparse aware." We can compare the behavior of the sparse-index in t1092-sparse-checkout-compability.sh by using GIT_TEST_SPARSE_INDEX=1 when operating on the 'sparse-index' repo. We can also compare the two sparse repos directly, such as comparing their indexes (when expanded to full in the case of the 'sparse-index' repo). We also verify that the index is actually populated with sparse directory entries. The 'checkout and reset (mixed)' test is marked for failure when comparing a sparse repo to a full repo, but we can compare the two sparse-checkout cases directly to ensure that we are not changing the behavior when using a sparse index. Signed-off-by: Derrick Stolee <dstolee@microsoft.com> Signed-off-by: Junio C Hamano <gitster@pobox.com>
2021-03-30 15:10:55 +02:00
if (was_full)
ensure_full_index(istate);
if (ret)
return ret;
ret = adjust_shared_perm(get_tempfile_path(*temp));
if (ret) {
error(_("cannot fix permission bits on '%s'"), get_tempfile_path(*temp));
return ret;
}
ret = rename_tempfile(temp,
git_path("sharedindex.%s", oid_to_hex(&si->base->oid)));
if (!ret) {
oidcpy(&si->base_oid, &si->base->oid);
clean_shared_index_files(oid_to_hex(&si->base->oid));
}
return ret;
}
static const int default_max_percent_split_change = 20;
static int too_many_not_shared_entries(struct index_state *istate)
{
int i, not_shared = 0;
int max_split = git_config_get_max_percent_split_change();
switch (max_split) {
case -1:
/* not or badly configured: use the default value */
max_split = default_max_percent_split_change;
break;
case 0:
return 1; /* 0% means always write a new shared index */
case 100:
return 0; /* 100% means never write a new shared index */
default:
break; /* just use the configured value */
}
/* Count not shared entries */
for (i = 0; i < istate->cache_nr; i++) {
struct cache_entry *ce = istate->cache[i];
if (!ce->index)
not_shared++;
}
return (int64_t)istate->cache_nr * max_split < (int64_t)not_shared * 100;
}
int write_locked_index(struct index_state *istate, struct lock_file *lock,
unsigned flags)
{
read-cache: fix GIT_TEST_SPLIT_INDEX Running tests with GIT_TEST_SPLIT_INDEX=1 is supposed to turn on the split index feature and trigger index splitting (mostly) randomly. Alas, this has been broken since 6e37c8ed3c (read-cache.c: fix writing "link" index ext with null base oid, 2019-02-13), and GIT_TEST_SPLIT_INDEX=1 hasn't triggered any index splitting since then. This patch makes GIT_TEST_SPLIT_INDEX work again, though it doesn't restore the pre-6e37c8ed3c behavior. To understand the bug, the fix, and the behavior change we first have to look at how GIT_TEST_SPLIT_INDEX used to work before 6e37c8ed3c: There are two places where we check the value of GIT_TEST_SPLIT_INDEX, and before 6e37c8ed3c they worked like this: 1) In the lower-level do_write_index(), where, if GIT_TEST_SPLIT_INDEX is enabled, we call init_split_index(). This call merely allocates and zero-initializes 'istate->split_index', but does nothing else (i.e. doesn't fill the base/shared index with cache entries, doesn't actually write a shared index file, etc.). Pertinent to this issue, the hash of the base index remains all zeroed out. 2) In the higher-level write_locked_index(), but only when 'istate->split_index' has already been initialized. Then, if GIT_TEST_SPLIT_INDEX is enabled, it randomly sets the flag that triggers index splitting later in this function. This randomness comes from the first byte of the hash of the base index via an 'if ((first_byte & 15) < 6)' condition. However, if 'istate->split_index' hasn't been initialized (i.e. it is still NULL), then write_locked_index() just calls do_write_locked_index(), which internally calls the above mentioned do_write_index(). This means that while GIT_TEST_SPLIT_INDEX=1 usually triggered index splitting randomly, the first two index writes were always deterministic (though I suspect this was unintentional): - The initial index write never splits the index. During the first index write write_locked_index() is called with 'istate->split_index' still uninitialized, so the check in 2) is not executed. It still calls do_write_index(), though, which then executes the check in 1). The resulting all zero base index hash then leads to the 'link' extension being written to '.git/index', though a shared index file is not written: $ rm .git/index $ GIT_TEST_SPLIT_INDEX=1 git update-index --add file $ test-tool dump-split-index .git/index own c6ef71168597caec8553c83d9d0048f1ef416170 base 0000000000000000000000000000000000000000 100644 d00491fd7e5bb6fa28c517a0bb32b8b506539d4d 0 file replacements: deletions: $ ls -l .git/sharedindex.* ls: cannot access '.git/sharedindex.*': No such file or directory - The second index write always splits the index. When the index written in the previous point is read, 'istate->split_index' is initialized because of the presence of the 'link' extension. So during the second write write_locked_index() does run the check in 2), and the first byte of the all zero base index hash always fulfills the randomness condition, which in turn always triggers the index splitting. - Subsequent index writes will find the 'link' extension with a real non-zero base index hash, so from then on the check in 2) is executed and the first byte of the base index hash is as random as it gets (coming from the SHA-1 of index data including timestamps and inodes...). All this worked until 6e37c8ed3c came along, and stopped writing the 'link' extension if the hash of the base index was all zero: $ rm .git/index $ GIT_TEST_SPLIT_INDEX=1 git update-index --add file $ test-tool dump-split-index .git/index own abbd6f6458d5dee73ae8e210ca15a68a390c6fd7 not a split index $ ls -l .git/sharedindex.* ls: cannot access '.git/sharedindex.*': No such file or directory So, since the first index write with GIT_TEST_SPLIT_INDEX=1 doesn't write a 'link' extension, in the second index write 'istate->split_index' remains uninitialized, and the check in 2) is not executed, and ultimately the index is never split. Fix this by modifying write_locked_index() to make sure to check GIT_TEST_SPLIT_INDEX even if 'istate->split_index' is still uninitialized, and initialize it if necessary. The check for GIT_TEST_SPLIT_INDEX and separate init_split_index() call in do_write_index() thus becomes unnecessary, so remove it. Furthermore, add a test to 't1700-split-index.sh' to make sure that GIT_TEST_SPLIT_INDEX=1 will keep working (though only check the index splitting on the first index write, because after that it will be random). Note that this change does not restore the pre-6e37c8ed3c behaviour, as it will deterministically split the index already on the first index write. Since GIT_TEST_SPLIT_INDEX is purely a developer aid, there is no backwards compatibility issue here. The new behaviour did trigger test failures in 't0003-attributes.sh' and 't1600-index.sh', though, which have been fixed in preparatory patches in this series. Signed-off-by: SZEDER Gábor <szeder.dev@gmail.com> Acked-by: Derrick Stolee <dstolee@microsoft.com> Signed-off-by: Junio C Hamano <gitster@pobox.com>
2021-08-26 23:00:04 +02:00
int new_shared_index, ret, test_split_index_env;
struct split_index *si = istate->split_index;
if (git_env_bool("GIT_TEST_CHECK_CACHE_TREE", 0))
cache_tree_verify(the_repository, istate);
if ((flags & SKIP_IF_UNCHANGED) && !istate->cache_changed) {
if (flags & COMMIT_LOCK)
rollback_lock_file(lock);
return 0;
}
if (istate->fsmonitor_last_update)
fill_fsmonitor_bitmap(istate);
read-cache: fix GIT_TEST_SPLIT_INDEX Running tests with GIT_TEST_SPLIT_INDEX=1 is supposed to turn on the split index feature and trigger index splitting (mostly) randomly. Alas, this has been broken since 6e37c8ed3c (read-cache.c: fix writing "link" index ext with null base oid, 2019-02-13), and GIT_TEST_SPLIT_INDEX=1 hasn't triggered any index splitting since then. This patch makes GIT_TEST_SPLIT_INDEX work again, though it doesn't restore the pre-6e37c8ed3c behavior. To understand the bug, the fix, and the behavior change we first have to look at how GIT_TEST_SPLIT_INDEX used to work before 6e37c8ed3c: There are two places where we check the value of GIT_TEST_SPLIT_INDEX, and before 6e37c8ed3c they worked like this: 1) In the lower-level do_write_index(), where, if GIT_TEST_SPLIT_INDEX is enabled, we call init_split_index(). This call merely allocates and zero-initializes 'istate->split_index', but does nothing else (i.e. doesn't fill the base/shared index with cache entries, doesn't actually write a shared index file, etc.). Pertinent to this issue, the hash of the base index remains all zeroed out. 2) In the higher-level write_locked_index(), but only when 'istate->split_index' has already been initialized. Then, if GIT_TEST_SPLIT_INDEX is enabled, it randomly sets the flag that triggers index splitting later in this function. This randomness comes from the first byte of the hash of the base index via an 'if ((first_byte & 15) < 6)' condition. However, if 'istate->split_index' hasn't been initialized (i.e. it is still NULL), then write_locked_index() just calls do_write_locked_index(), which internally calls the above mentioned do_write_index(). This means that while GIT_TEST_SPLIT_INDEX=1 usually triggered index splitting randomly, the first two index writes were always deterministic (though I suspect this was unintentional): - The initial index write never splits the index. During the first index write write_locked_index() is called with 'istate->split_index' still uninitialized, so the check in 2) is not executed. It still calls do_write_index(), though, which then executes the check in 1). The resulting all zero base index hash then leads to the 'link' extension being written to '.git/index', though a shared index file is not written: $ rm .git/index $ GIT_TEST_SPLIT_INDEX=1 git update-index --add file $ test-tool dump-split-index .git/index own c6ef71168597caec8553c83d9d0048f1ef416170 base 0000000000000000000000000000000000000000 100644 d00491fd7e5bb6fa28c517a0bb32b8b506539d4d 0 file replacements: deletions: $ ls -l .git/sharedindex.* ls: cannot access '.git/sharedindex.*': No such file or directory - The second index write always splits the index. When the index written in the previous point is read, 'istate->split_index' is initialized because of the presence of the 'link' extension. So during the second write write_locked_index() does run the check in 2), and the first byte of the all zero base index hash always fulfills the randomness condition, which in turn always triggers the index splitting. - Subsequent index writes will find the 'link' extension with a real non-zero base index hash, so from then on the check in 2) is executed and the first byte of the base index hash is as random as it gets (coming from the SHA-1 of index data including timestamps and inodes...). All this worked until 6e37c8ed3c came along, and stopped writing the 'link' extension if the hash of the base index was all zero: $ rm .git/index $ GIT_TEST_SPLIT_INDEX=1 git update-index --add file $ test-tool dump-split-index .git/index own abbd6f6458d5dee73ae8e210ca15a68a390c6fd7 not a split index $ ls -l .git/sharedindex.* ls: cannot access '.git/sharedindex.*': No such file or directory So, since the first index write with GIT_TEST_SPLIT_INDEX=1 doesn't write a 'link' extension, in the second index write 'istate->split_index' remains uninitialized, and the check in 2) is not executed, and ultimately the index is never split. Fix this by modifying write_locked_index() to make sure to check GIT_TEST_SPLIT_INDEX even if 'istate->split_index' is still uninitialized, and initialize it if necessary. The check for GIT_TEST_SPLIT_INDEX and separate init_split_index() call in do_write_index() thus becomes unnecessary, so remove it. Furthermore, add a test to 't1700-split-index.sh' to make sure that GIT_TEST_SPLIT_INDEX=1 will keep working (though only check the index splitting on the first index write, because after that it will be random). Note that this change does not restore the pre-6e37c8ed3c behaviour, as it will deterministically split the index already on the first index write. Since GIT_TEST_SPLIT_INDEX is purely a developer aid, there is no backwards compatibility issue here. The new behaviour did trigger test failures in 't0003-attributes.sh' and 't1600-index.sh', though, which have been fixed in preparatory patches in this series. Signed-off-by: SZEDER Gábor <szeder.dev@gmail.com> Acked-by: Derrick Stolee <dstolee@microsoft.com> Signed-off-by: Junio C Hamano <gitster@pobox.com>
2021-08-26 23:00:04 +02:00
test_split_index_env = git_env_bool("GIT_TEST_SPLIT_INDEX", 0);
if ((!si && !test_split_index_env) ||
alternate_index_output ||
(istate->cache_changed & ~EXTMASK)) {
if (si)
oidclr(&si->base_oid);
read-cache: leave lock in right state in `write_locked_index()` If the original version of `write_locked_index()` returned with an error, it didn't roll back the lockfile unless the error occured at the very end, during closing/committing. See commit 03b866477 (read-cache: new API write_locked_index instead of write_index/write_cache, 2014-06-13). In commit 9f41c7a6b (read-cache: close index.lock in do_write_index, 2017-04-26), we learned to close the lock slightly earlier in the callstack. That was mostly a side-effect of lockfiles being implemented using temporary files, but didn't cause any real harm. Recently, commit 076aa2cbd (tempfile: auto-allocate tempfiles on heap, 2017-09-05) introduced a subtle bug. If the temporary file is deleted (i.e., the lockfile is rolled back), the tempfile-pointer in the `struct lock_file` will be left dangling. Thus, an attempt to reuse the lockfile, or even just to roll it back, will induce undefined behavior -- most likely a crash. Besides not crashing, we clearly want to make things consistent. The guarantees which the lockfile-machinery itself provides is A) if we ask to commit and it fails, roll back, and B) if we ask to close and it fails, do _not_ roll back. Let's do the same for consistency. Do not delete the temporary file in `do_write_index()`. One of its callers, `write_locked_index()` will thereby avoid rolling back the lock. The other caller, `write_shared_index()`, will delete its temporary file anyway. Both of these callers will avoid undefined behavior (crashing). Teach `write_locked_index(..., COMMIT_LOCK)` to roll back the lock before returning. If we have already succeeded and committed, it will be a noop. Simplify the existing callers where we now have a superfluous call to `rollback_lockfile()`. That should keep future readers from wondering why the callers are inconsistent. Signed-off-by: Martin Ågren <martin.agren@gmail.com> Signed-off-by: Junio C Hamano <gitster@pobox.com>
2017-10-06 22:12:13 +02:00
ret = do_write_locked_index(istate, lock, flags);
goto out;
}
read-cache: fix GIT_TEST_SPLIT_INDEX Running tests with GIT_TEST_SPLIT_INDEX=1 is supposed to turn on the split index feature and trigger index splitting (mostly) randomly. Alas, this has been broken since 6e37c8ed3c (read-cache.c: fix writing "link" index ext with null base oid, 2019-02-13), and GIT_TEST_SPLIT_INDEX=1 hasn't triggered any index splitting since then. This patch makes GIT_TEST_SPLIT_INDEX work again, though it doesn't restore the pre-6e37c8ed3c behavior. To understand the bug, the fix, and the behavior change we first have to look at how GIT_TEST_SPLIT_INDEX used to work before 6e37c8ed3c: There are two places where we check the value of GIT_TEST_SPLIT_INDEX, and before 6e37c8ed3c they worked like this: 1) In the lower-level do_write_index(), where, if GIT_TEST_SPLIT_INDEX is enabled, we call init_split_index(). This call merely allocates and zero-initializes 'istate->split_index', but does nothing else (i.e. doesn't fill the base/shared index with cache entries, doesn't actually write a shared index file, etc.). Pertinent to this issue, the hash of the base index remains all zeroed out. 2) In the higher-level write_locked_index(), but only when 'istate->split_index' has already been initialized. Then, if GIT_TEST_SPLIT_INDEX is enabled, it randomly sets the flag that triggers index splitting later in this function. This randomness comes from the first byte of the hash of the base index via an 'if ((first_byte & 15) < 6)' condition. However, if 'istate->split_index' hasn't been initialized (i.e. it is still NULL), then write_locked_index() just calls do_write_locked_index(), which internally calls the above mentioned do_write_index(). This means that while GIT_TEST_SPLIT_INDEX=1 usually triggered index splitting randomly, the first two index writes were always deterministic (though I suspect this was unintentional): - The initial index write never splits the index. During the first index write write_locked_index() is called with 'istate->split_index' still uninitialized, so the check in 2) is not executed. It still calls do_write_index(), though, which then executes the check in 1). The resulting all zero base index hash then leads to the 'link' extension being written to '.git/index', though a shared index file is not written: $ rm .git/index $ GIT_TEST_SPLIT_INDEX=1 git update-index --add file $ test-tool dump-split-index .git/index own c6ef71168597caec8553c83d9d0048f1ef416170 base 0000000000000000000000000000000000000000 100644 d00491fd7e5bb6fa28c517a0bb32b8b506539d4d 0 file replacements: deletions: $ ls -l .git/sharedindex.* ls: cannot access '.git/sharedindex.*': No such file or directory - The second index write always splits the index. When the index written in the previous point is read, 'istate->split_index' is initialized because of the presence of the 'link' extension. So during the second write write_locked_index() does run the check in 2), and the first byte of the all zero base index hash always fulfills the randomness condition, which in turn always triggers the index splitting. - Subsequent index writes will find the 'link' extension with a real non-zero base index hash, so from then on the check in 2) is executed and the first byte of the base index hash is as random as it gets (coming from the SHA-1 of index data including timestamps and inodes...). All this worked until 6e37c8ed3c came along, and stopped writing the 'link' extension if the hash of the base index was all zero: $ rm .git/index $ GIT_TEST_SPLIT_INDEX=1 git update-index --add file $ test-tool dump-split-index .git/index own abbd6f6458d5dee73ae8e210ca15a68a390c6fd7 not a split index $ ls -l .git/sharedindex.* ls: cannot access '.git/sharedindex.*': No such file or directory So, since the first index write with GIT_TEST_SPLIT_INDEX=1 doesn't write a 'link' extension, in the second index write 'istate->split_index' remains uninitialized, and the check in 2) is not executed, and ultimately the index is never split. Fix this by modifying write_locked_index() to make sure to check GIT_TEST_SPLIT_INDEX even if 'istate->split_index' is still uninitialized, and initialize it if necessary. The check for GIT_TEST_SPLIT_INDEX and separate init_split_index() call in do_write_index() thus becomes unnecessary, so remove it. Furthermore, add a test to 't1700-split-index.sh' to make sure that GIT_TEST_SPLIT_INDEX=1 will keep working (though only check the index splitting on the first index write, because after that it will be random). Note that this change does not restore the pre-6e37c8ed3c behaviour, as it will deterministically split the index already on the first index write. Since GIT_TEST_SPLIT_INDEX is purely a developer aid, there is no backwards compatibility issue here. The new behaviour did trigger test failures in 't0003-attributes.sh' and 't1600-index.sh', though, which have been fixed in preparatory patches in this series. Signed-off-by: SZEDER Gábor <szeder.dev@gmail.com> Acked-by: Derrick Stolee <dstolee@microsoft.com> Signed-off-by: Junio C Hamano <gitster@pobox.com>
2021-08-26 23:00:04 +02:00
if (test_split_index_env) {
if (!si) {
si = init_split_index(istate);
istate->cache_changed |= SPLIT_INDEX_ORDERED;
read-cache: fix GIT_TEST_SPLIT_INDEX Running tests with GIT_TEST_SPLIT_INDEX=1 is supposed to turn on the split index feature and trigger index splitting (mostly) randomly. Alas, this has been broken since 6e37c8ed3c (read-cache.c: fix writing "link" index ext with null base oid, 2019-02-13), and GIT_TEST_SPLIT_INDEX=1 hasn't triggered any index splitting since then. This patch makes GIT_TEST_SPLIT_INDEX work again, though it doesn't restore the pre-6e37c8ed3c behavior. To understand the bug, the fix, and the behavior change we first have to look at how GIT_TEST_SPLIT_INDEX used to work before 6e37c8ed3c: There are two places where we check the value of GIT_TEST_SPLIT_INDEX, and before 6e37c8ed3c they worked like this: 1) In the lower-level do_write_index(), where, if GIT_TEST_SPLIT_INDEX is enabled, we call init_split_index(). This call merely allocates and zero-initializes 'istate->split_index', but does nothing else (i.e. doesn't fill the base/shared index with cache entries, doesn't actually write a shared index file, etc.). Pertinent to this issue, the hash of the base index remains all zeroed out. 2) In the higher-level write_locked_index(), but only when 'istate->split_index' has already been initialized. Then, if GIT_TEST_SPLIT_INDEX is enabled, it randomly sets the flag that triggers index splitting later in this function. This randomness comes from the first byte of the hash of the base index via an 'if ((first_byte & 15) < 6)' condition. However, if 'istate->split_index' hasn't been initialized (i.e. it is still NULL), then write_locked_index() just calls do_write_locked_index(), which internally calls the above mentioned do_write_index(). This means that while GIT_TEST_SPLIT_INDEX=1 usually triggered index splitting randomly, the first two index writes were always deterministic (though I suspect this was unintentional): - The initial index write never splits the index. During the first index write write_locked_index() is called with 'istate->split_index' still uninitialized, so the check in 2) is not executed. It still calls do_write_index(), though, which then executes the check in 1). The resulting all zero base index hash then leads to the 'link' extension being written to '.git/index', though a shared index file is not written: $ rm .git/index $ GIT_TEST_SPLIT_INDEX=1 git update-index --add file $ test-tool dump-split-index .git/index own c6ef71168597caec8553c83d9d0048f1ef416170 base 0000000000000000000000000000000000000000 100644 d00491fd7e5bb6fa28c517a0bb32b8b506539d4d 0 file replacements: deletions: $ ls -l .git/sharedindex.* ls: cannot access '.git/sharedindex.*': No such file or directory - The second index write always splits the index. When the index written in the previous point is read, 'istate->split_index' is initialized because of the presence of the 'link' extension. So during the second write write_locked_index() does run the check in 2), and the first byte of the all zero base index hash always fulfills the randomness condition, which in turn always triggers the index splitting. - Subsequent index writes will find the 'link' extension with a real non-zero base index hash, so from then on the check in 2) is executed and the first byte of the base index hash is as random as it gets (coming from the SHA-1 of index data including timestamps and inodes...). All this worked until 6e37c8ed3c came along, and stopped writing the 'link' extension if the hash of the base index was all zero: $ rm .git/index $ GIT_TEST_SPLIT_INDEX=1 git update-index --add file $ test-tool dump-split-index .git/index own abbd6f6458d5dee73ae8e210ca15a68a390c6fd7 not a split index $ ls -l .git/sharedindex.* ls: cannot access '.git/sharedindex.*': No such file or directory So, since the first index write with GIT_TEST_SPLIT_INDEX=1 doesn't write a 'link' extension, in the second index write 'istate->split_index' remains uninitialized, and the check in 2) is not executed, and ultimately the index is never split. Fix this by modifying write_locked_index() to make sure to check GIT_TEST_SPLIT_INDEX even if 'istate->split_index' is still uninitialized, and initialize it if necessary. The check for GIT_TEST_SPLIT_INDEX and separate init_split_index() call in do_write_index() thus becomes unnecessary, so remove it. Furthermore, add a test to 't1700-split-index.sh' to make sure that GIT_TEST_SPLIT_INDEX=1 will keep working (though only check the index splitting on the first index write, because after that it will be random). Note that this change does not restore the pre-6e37c8ed3c behaviour, as it will deterministically split the index already on the first index write. Since GIT_TEST_SPLIT_INDEX is purely a developer aid, there is no backwards compatibility issue here. The new behaviour did trigger test failures in 't0003-attributes.sh' and 't1600-index.sh', though, which have been fixed in preparatory patches in this series. Signed-off-by: SZEDER Gábor <szeder.dev@gmail.com> Acked-by: Derrick Stolee <dstolee@microsoft.com> Signed-off-by: Junio C Hamano <gitster@pobox.com>
2021-08-26 23:00:04 +02:00
} else {
int v = si->base_oid.hash[0];
if ((v & 15) < 6)
istate->cache_changed |= SPLIT_INDEX_ORDERED;
}
}
if (too_many_not_shared_entries(istate))
istate->cache_changed |= SPLIT_INDEX_ORDERED;
new_shared_index = istate->cache_changed & SPLIT_INDEX_ORDERED;
if (new_shared_index) {
struct tempfile *temp;
int saved_errno;
/* Same initial permissions as the main .git/index file */
temp = mks_tempfile_sm(git_path("sharedindex_XXXXXX"), 0, 0666);
if (!temp) {
oidclr(&si->base_oid);
ret = do_write_locked_index(istate, lock, flags);
goto out;
}
ret = write_shared_index(istate, &temp);
saved_errno = errno;
if (is_tempfile_active(temp))
delete_tempfile(&temp);
errno = saved_errno;
if (ret)
read-cache: leave lock in right state in `write_locked_index()` If the original version of `write_locked_index()` returned with an error, it didn't roll back the lockfile unless the error occured at the very end, during closing/committing. See commit 03b866477 (read-cache: new API write_locked_index instead of write_index/write_cache, 2014-06-13). In commit 9f41c7a6b (read-cache: close index.lock in do_write_index, 2017-04-26), we learned to close the lock slightly earlier in the callstack. That was mostly a side-effect of lockfiles being implemented using temporary files, but didn't cause any real harm. Recently, commit 076aa2cbd (tempfile: auto-allocate tempfiles on heap, 2017-09-05) introduced a subtle bug. If the temporary file is deleted (i.e., the lockfile is rolled back), the tempfile-pointer in the `struct lock_file` will be left dangling. Thus, an attempt to reuse the lockfile, or even just to roll it back, will induce undefined behavior -- most likely a crash. Besides not crashing, we clearly want to make things consistent. The guarantees which the lockfile-machinery itself provides is A) if we ask to commit and it fails, roll back, and B) if we ask to close and it fails, do _not_ roll back. Let's do the same for consistency. Do not delete the temporary file in `do_write_index()`. One of its callers, `write_locked_index()` will thereby avoid rolling back the lock. The other caller, `write_shared_index()`, will delete its temporary file anyway. Both of these callers will avoid undefined behavior (crashing). Teach `write_locked_index(..., COMMIT_LOCK)` to roll back the lock before returning. If we have already succeeded and committed, it will be a noop. Simplify the existing callers where we now have a superfluous call to `rollback_lockfile()`. That should keep future readers from wondering why the callers are inconsistent. Signed-off-by: Martin Ågren <martin.agren@gmail.com> Signed-off-by: Junio C Hamano <gitster@pobox.com>
2017-10-06 22:12:13 +02:00
goto out;
}
ret = write_split_index(istate, lock, flags);
/* Freshen the shared index only if the split-index was written */
read-cache.c: fix writing "link" index ext with null base oid Since commit 7db118303a (unpack_trees: fix breakage when o->src_index != o->dst_index - 2018-04-23) and changes in merge code to use separate index_state for source and destination, when doing a merge with split index activated, we may run into this line in unpack_trees(): o->result.split_index = init_split_index(&o->result); This is by itself not wrong. But this split index information is not fully populated (and it's only so when move_cache_to_base_index() is called, aka force splitting the index, or loading index_state from a file). Both "base_oid" and "base" in this case remain null. So when writing the main index down, we link to this index with null oid (default value after init_split_index()), which also means "no split index" internally. This triggers an incorrect base index refresh: warning: could not freshen shared index '.../sharedindex.0{40}' This patch makes sure we will not refresh null base_oid (because the file is never there). It also makes sure not to write "link" extension with null base_oid in the first place (no point having it at all). Read code already has protection against null base_oid. There is also another side fix in remove_split_index() that causes a crash when doing "git update-index --no-split-index" when base_oid in the index file is null. In this case we will not load istate->split_index->base but we dereference it anyway and are rewarded with a segfault. This should not happen anymore, but it's still wrong to dereference a potential NULL pointer, especially when we do check for NULL pointer in the next code. Reported-by: Luke Diamand <luke@diamand.org> Signed-off-by: Nguyễn Thái Ngọc Duy <pclouds@gmail.com> Signed-off-by: Junio C Hamano <gitster@pobox.com>
2019-02-13 10:51:29 +01:00
if (!ret && !new_shared_index && !is_null_oid(&si->base_oid)) {
read-cache: fix reading the shared index for other repos read_index_from() takes a path argument for the location of the index file. For reading the shared index in split index mode however it just ignores that path argument, and reads it from the gitdir of the current repository. This works as long as an index in the_repository is read. Once that changes, such as when we read the index of a submodule, or of a different working tree than the current one, the gitdir of the_repository will no longer contain the appropriate shared index, and git will fail to read it. For example t3007-ls-files-recurse-submodules.sh was broken with GIT_TEST_SPLIT_INDEX set in 188dce131f ("ls-files: use repository object", 2017-06-22), and t7814-grep-recurse-submodules.sh was also broken in a similar manner, probably by introducing struct repository there, although I didn't track down the exact commit for that. be489d02d2 ("revision.c: --indexed-objects add objects from all worktrees", 2017-08-23) breaks with split index mode in a similar manner, not erroring out when it can't read the index, but instead carrying on with pruning, without taking the index of the worktree into account. Fix this by passing an additional gitdir parameter to read_index_from, to indicate where it should look for and read the shared index from. read_cache_from() defaults to using the gitdir of the_repository. As it is mostly a convenience macro, having to pass get_git_dir() for every call seems overkill, and if necessary users can have more control by using read_index_from(). Helped-by: Brandon Williams <bmwill@google.com> Signed-off-by: Thomas Gummerer <t.gummerer@gmail.com> Signed-off-by: Junio C Hamano <gitster@pobox.com>
2018-01-07 23:30:13 +01:00
const char *shared_index = git_path("sharedindex.%s",
oid_to_hex(&si->base_oid));
read-cache: fix reading the shared index for other repos read_index_from() takes a path argument for the location of the index file. For reading the shared index in split index mode however it just ignores that path argument, and reads it from the gitdir of the current repository. This works as long as an index in the_repository is read. Once that changes, such as when we read the index of a submodule, or of a different working tree than the current one, the gitdir of the_repository will no longer contain the appropriate shared index, and git will fail to read it. For example t3007-ls-files-recurse-submodules.sh was broken with GIT_TEST_SPLIT_INDEX set in 188dce131f ("ls-files: use repository object", 2017-06-22), and t7814-grep-recurse-submodules.sh was also broken in a similar manner, probably by introducing struct repository there, although I didn't track down the exact commit for that. be489d02d2 ("revision.c: --indexed-objects add objects from all worktrees", 2017-08-23) breaks with split index mode in a similar manner, not erroring out when it can't read the index, but instead carrying on with pruning, without taking the index of the worktree into account. Fix this by passing an additional gitdir parameter to read_index_from, to indicate where it should look for and read the shared index from. read_cache_from() defaults to using the gitdir of the_repository. As it is mostly a convenience macro, having to pass get_git_dir() for every call seems overkill, and if necessary users can have more control by using read_index_from(). Helped-by: Brandon Williams <bmwill@google.com> Signed-off-by: Thomas Gummerer <t.gummerer@gmail.com> Signed-off-by: Junio C Hamano <gitster@pobox.com>
2018-01-07 23:30:13 +01:00
freshen_shared_index(shared_index, 1);
}
read-cache: leave lock in right state in `write_locked_index()` If the original version of `write_locked_index()` returned with an error, it didn't roll back the lockfile unless the error occured at the very end, during closing/committing. See commit 03b866477 (read-cache: new API write_locked_index instead of write_index/write_cache, 2014-06-13). In commit 9f41c7a6b (read-cache: close index.lock in do_write_index, 2017-04-26), we learned to close the lock slightly earlier in the callstack. That was mostly a side-effect of lockfiles being implemented using temporary files, but didn't cause any real harm. Recently, commit 076aa2cbd (tempfile: auto-allocate tempfiles on heap, 2017-09-05) introduced a subtle bug. If the temporary file is deleted (i.e., the lockfile is rolled back), the tempfile-pointer in the `struct lock_file` will be left dangling. Thus, an attempt to reuse the lockfile, or even just to roll it back, will induce undefined behavior -- most likely a crash. Besides not crashing, we clearly want to make things consistent. The guarantees which the lockfile-machinery itself provides is A) if we ask to commit and it fails, roll back, and B) if we ask to close and it fails, do _not_ roll back. Let's do the same for consistency. Do not delete the temporary file in `do_write_index()`. One of its callers, `write_locked_index()` will thereby avoid rolling back the lock. The other caller, `write_shared_index()`, will delete its temporary file anyway. Both of these callers will avoid undefined behavior (crashing). Teach `write_locked_index(..., COMMIT_LOCK)` to roll back the lock before returning. If we have already succeeded and committed, it will be a noop. Simplify the existing callers where we now have a superfluous call to `rollback_lockfile()`. That should keep future readers from wondering why the callers are inconsistent. Signed-off-by: Martin Ågren <martin.agren@gmail.com> Signed-off-by: Junio C Hamano <gitster@pobox.com>
2017-10-06 22:12:13 +02:00
out:
if (flags & COMMIT_LOCK)
rollback_lock_file(lock);
return ret;
}
/*
* Read the index file that is potentially unmerged into given
read-cache: fix directory/file conflict handling in read_index_unmerged() read_index_unmerged() has two intended purposes: * return 1 if there are any unmerged entries, 0 otherwise * drops any higher-stage entries down to stage #0 There are several callers of read_index_unmerged() that check the return value to see if it is non-zero, all of which then die() if that condition is met. For these callers, dropping higher-stage entries down to stage #0 is a waste of resources, and returning immediately on first unmerged entry would be better. But it's probably only a very minor difference and isn't the focus of this series. The remaining callers ignore the return value and call this function for the side effect of dropping higher-stage entries down to stage #0. As mentioned in commit e11d7b596970 ("'reset --merge': fix unmerged case", 2009-12-31), The _only_ reason we want to keep a previously unmerged entry in the index at stage #0 is so that we don't forget the fact that we have corresponding file in the work tree in order to be able to remove it when the tree we are resetting to does not have the path. In fact, prior to commit d1a43f2aa4bf ("reset --hard/read-tree --reset -u: remove unmerged new paths", 2008-10-15), read_index_unmerged() did just remove unmerged entries from the cache immediately but that had the unwanted effect of leaving around new untracked files in the tree from aborted merges. So, that's the intended purpose of this function. The problem is that when directory/files conflicts are present, trying to add the file to the index at stage 0 fails (because there is still a directory in the way), and the function returns early with a -1 return code to signify the error. As noted above, none of the callers who want the drop-to-stage-0 behavior check the return status, though, so this means all remaining unmerged entries remain in the index and the callers proceed assuming otherwise. Users then see errors of the form: error: 'DIR-OR-FILE' appears as both a file and as a directory error: DIR-OR-FILE: cannot drop to stage #0 and potentially also messages about other unmerged entries which came lexicographically later than whatever pathname was both a file and a directory. Google finds a few hits searching for those messages, suggesting there were probably a couple people who hit this besides me. Luckily, calling `git reset --hard` multiple times would workaround this bug. Since the whole purpose here is to just put the entry *temporarily* into the index so that any associated file in the working copy can be removed, we can just skip the DFCHECK and allow both the file and directory to appear in the index. The temporary simultaneous appearance of the directory and file entries in the index will be removed by the callers by calling unpack_trees(), which excludes these unmerged entries marked with CE_CONFLICTED flag from the resulting index, before they attempt to write the index anywhere. Signed-off-by: Elijah Newren <newren@gmail.com> Signed-off-by: Junio C Hamano <gitster@pobox.com>
2018-07-31 19:12:05 +02:00
* index_state, dropping any unmerged entries to stage #0 (potentially
* resulting in a path appearing as both a file and a directory in the
* index; the caller is responsible to clear out the extra entries
* before writing the index to a tree). Returns true if the index is
* unmerged. Callers who want to refuse to work from an unmerged
* state can call this and check its return value, instead of calling
* read_cache().
*/
int repo_read_index_unmerged(struct repository *repo)
{
struct index_state *istate;
int i;
int unmerged = 0;
repo_read_index(repo);
istate = repo->index;
for (i = 0; i < istate->cache_nr; i++) {
struct cache_entry *ce = istate->cache[i];
struct cache_entry *new_ce;
block alloc: add lifecycle APIs for cache_entry structs It has been observed that the time spent loading an index with a large number of entries is partly dominated by malloc() calls. This change is in preparation for using memory pools to reduce the number of malloc() calls made to allocate cahce entries when loading an index. Add an API to allocate and discard cache entries, abstracting the details of managing the memory backing the cache entries. This commit does actually change how memory is managed - this will be done in a later commit in the series. This change makes the distinction between cache entries that are associated with an index and cache entries that are not associated with an index. A main use of cache entries is with an index, and we can optimize the memory management around this. We still have other cases where a cache entry is not persisted with an index, and so we need to handle the "transient" use case as well. To keep the congnitive overhead of managing the cache entries, there will only be a single discard function. This means there must be enough information kept with the cache entry so that we know how to discard them. A summary of the main functions in the API is: make_cache_entry: create cache entry for use in an index. Uses specified parameters to populate cache_entry fields. make_empty_cache_entry: Create an empty cache entry for use in an index. Returns cache entry with empty fields. make_transient_cache_entry: create cache entry that is not used in an index. Uses specified parameters to populate cache_entry fields. make_empty_transient_cache_entry: create cache entry that is not used in an index. Returns cache entry with empty fields. discard_cache_entry: A single function that knows how to discard a cache entry regardless of how it was allocated. Signed-off-by: Jameson Miller <jamill@microsoft.com> Signed-off-by: Junio C Hamano <gitster@pobox.com>
2018-07-02 21:49:31 +02:00
int len;
if (!ce_stage(ce))
continue;
unmerged = 1;
len = ce_namelen(ce);
block alloc: add lifecycle APIs for cache_entry structs It has been observed that the time spent loading an index with a large number of entries is partly dominated by malloc() calls. This change is in preparation for using memory pools to reduce the number of malloc() calls made to allocate cahce entries when loading an index. Add an API to allocate and discard cache entries, abstracting the details of managing the memory backing the cache entries. This commit does actually change how memory is managed - this will be done in a later commit in the series. This change makes the distinction between cache entries that are associated with an index and cache entries that are not associated with an index. A main use of cache entries is with an index, and we can optimize the memory management around this. We still have other cases where a cache entry is not persisted with an index, and so we need to handle the "transient" use case as well. To keep the congnitive overhead of managing the cache entries, there will only be a single discard function. This means there must be enough information kept with the cache entry so that we know how to discard them. A summary of the main functions in the API is: make_cache_entry: create cache entry for use in an index. Uses specified parameters to populate cache_entry fields. make_empty_cache_entry: Create an empty cache entry for use in an index. Returns cache entry with empty fields. make_transient_cache_entry: create cache entry that is not used in an index. Uses specified parameters to populate cache_entry fields. make_empty_transient_cache_entry: create cache entry that is not used in an index. Returns cache entry with empty fields. discard_cache_entry: A single function that knows how to discard a cache entry regardless of how it was allocated. Signed-off-by: Jameson Miller <jamill@microsoft.com> Signed-off-by: Junio C Hamano <gitster@pobox.com>
2018-07-02 21:49:31 +02:00
new_ce = make_empty_cache_entry(istate, len);
memcpy(new_ce->name, ce->name, len);
new_ce->ce_flags = create_ce_flags(0) | CE_CONFLICTED;
new_ce->ce_namelen = len;
new_ce->ce_mode = ce->ce_mode;
read-cache: fix directory/file conflict handling in read_index_unmerged() read_index_unmerged() has two intended purposes: * return 1 if there are any unmerged entries, 0 otherwise * drops any higher-stage entries down to stage #0 There are several callers of read_index_unmerged() that check the return value to see if it is non-zero, all of which then die() if that condition is met. For these callers, dropping higher-stage entries down to stage #0 is a waste of resources, and returning immediately on first unmerged entry would be better. But it's probably only a very minor difference and isn't the focus of this series. The remaining callers ignore the return value and call this function for the side effect of dropping higher-stage entries down to stage #0. As mentioned in commit e11d7b596970 ("'reset --merge': fix unmerged case", 2009-12-31), The _only_ reason we want to keep a previously unmerged entry in the index at stage #0 is so that we don't forget the fact that we have corresponding file in the work tree in order to be able to remove it when the tree we are resetting to does not have the path. In fact, prior to commit d1a43f2aa4bf ("reset --hard/read-tree --reset -u: remove unmerged new paths", 2008-10-15), read_index_unmerged() did just remove unmerged entries from the cache immediately but that had the unwanted effect of leaving around new untracked files in the tree from aborted merges. So, that's the intended purpose of this function. The problem is that when directory/files conflicts are present, trying to add the file to the index at stage 0 fails (because there is still a directory in the way), and the function returns early with a -1 return code to signify the error. As noted above, none of the callers who want the drop-to-stage-0 behavior check the return status, though, so this means all remaining unmerged entries remain in the index and the callers proceed assuming otherwise. Users then see errors of the form: error: 'DIR-OR-FILE' appears as both a file and as a directory error: DIR-OR-FILE: cannot drop to stage #0 and potentially also messages about other unmerged entries which came lexicographically later than whatever pathname was both a file and a directory. Google finds a few hits searching for those messages, suggesting there were probably a couple people who hit this besides me. Luckily, calling `git reset --hard` multiple times would workaround this bug. Since the whole purpose here is to just put the entry *temporarily* into the index so that any associated file in the working copy can be removed, we can just skip the DFCHECK and allow both the file and directory to appear in the index. The temporary simultaneous appearance of the directory and file entries in the index will be removed by the callers by calling unpack_trees(), which excludes these unmerged entries marked with CE_CONFLICTED flag from the resulting index, before they attempt to write the index anywhere. Signed-off-by: Elijah Newren <newren@gmail.com> Signed-off-by: Junio C Hamano <gitster@pobox.com>
2018-07-31 19:12:05 +02:00
if (add_index_entry(istate, new_ce, ADD_CACHE_SKIP_DFCHECK))
return error(_("%s: cannot drop to stage #0"),
new_ce->name);
}
return unmerged;
}
/*
* Returns 1 if the path is an "other" path with respect to
* the index; that is, the path is not mentioned in the index at all,
* either as a file, a directory with some files in the index,
* or as an unmerged entry.
*
* We helpfully remove a trailing "/" from directories so that
* the output of read_directory can be used as-is.
*/
int index_name_is_other(struct index_state *istate, const char *name,
int namelen)
{
int pos;
if (namelen && name[namelen - 1] == '/')
namelen--;
pos = index_name_pos(istate, name, namelen);
if (0 <= pos)
return 0; /* exact match */
pos = -pos - 1;
if (pos < istate->cache_nr) {
struct cache_entry *ce = istate->cache[pos];
if (ce_namelen(ce) == namelen &&
!memcmp(ce->name, name, namelen))
return 0; /* Yup, this one exists unmerged */
}
return 1;
}
void *read_blob_data_from_index(struct index_state *istate,
const char *path, unsigned long *size)
{
int pos, len;
unsigned long sz;
enum object_type type;
void *data;
len = strlen(path);
pos = index_name_pos(istate, path, len);
if (pos < 0) {
/*
* We might be in the middle of a merge, in which
* case we would read stage #2 (ours).
*/
int i;
for (i = -pos - 1;
(pos < 0 && i < istate->cache_nr &&
!strcmp(istate->cache[i]->name, path));
i++)
if (ce_stage(istate->cache[i]) == 2)
pos = i;
}
if (pos < 0)
return NULL;
data = read_object_file(&istate->cache[pos]->oid, &type, &sz);
if (!data || type != OBJ_BLOB) {
free(data);
return NULL;
}
if (size)
*size = sz;
return data;
}
void stat_validity_clear(struct stat_validity *sv)
{
FREE_AND_NULL(sv->sd);
}
int stat_validity_check(struct stat_validity *sv, const char *path)
{
struct stat st;
if (stat(path, &st) < 0)
return sv->sd == NULL;
if (!sv->sd)
return 0;
return S_ISREG(st.st_mode) && !match_stat_data(sv->sd, &st);
}
void stat_validity_update(struct stat_validity *sv, int fd)
{
struct stat st;
if (fstat(fd, &st) < 0 || !S_ISREG(st.st_mode))
stat_validity_clear(sv);
else {
if (!sv->sd)
CALLOC_ARRAY(sv->sd, 1);
fill_stat_data(sv->sd, &st);
}
}
void move_index_extensions(struct index_state *dst, struct index_state *src)
{
dst->untracked = src->untracked;
src->untracked = NULL;
unpack-trees: reuse (still valid) cache-tree from src_index We do n-way merge by walking the source index and n trees at the same time and add merge results to a new temporary index called o->result. The merge result for any given path could be either - keep_entry(): same old index entry in o->src_index is reused - merged_entry(): either a new entry is added, or an existing one updated - deleted_entry(): one entry from o->src_index is removed For some reason [1] we keep making sure that the source index's cache-tree is still valid if used by o->result: for all those merged/deleted entries, we invalidate the same path in o->src_index, so only cache-trees covering the "keep_entry" parts remain good. Because of this, the cache-tree from o->src_index can be perfectly reused in o->result. And in fact we already rely on this logic to reuse untracked cache in edf3b90553 (unpack-trees: preserve index extensions - 2017-05-08). Move the cache-tree to o->result before doing cache_tree_update() to reduce hashing cost. Since cache_tree_update() has risen up as one of the most expensive parts in unpack_trees() after the last few patches. This does help reduce unpack_trees() time significantly (on webkit.git): before after -------------------------------------------------------------------- 0.080394752 0.051258167 s: read cache .git/index 0.216010838 0.212106298 s: preload index 0.008534301 0.280521764 s: refresh index 0.251992198 0.218160442 s: traverse_trees 0.377031383 0.374948191 s: check_updates 0.372768105 0.037040114 s: cache_tree_update 1.045887251 0.672031609 s: unpack_trees 0.314983512 0.317456290 s: write index, changed mask = 2e 0.062572653 0.038382654 s: traverse_trees 0.000022544 0.000042731 s: check_updates 0.073795585 0.050930053 s: unpack_trees 0.073807557 0.051099735 s: diff-index 1.938191592 1.614241153 s: git command: git checkout - [1] I'm pretty sure the reason is an oversight in 34110cd4e3 (Make 'unpack_trees()' have a separate source and destination index - 2008-03-06). That patch aims to _not_ update the source index at all. The invalidation should have been done on o->result in that patch. But then there was no cache-tree on o->result even then so it's pointless to do so. Signed-off-by: Nguyễn Thái Ngọc Duy <pclouds@gmail.com> Signed-off-by: Junio C Hamano <gitster@pobox.com>
2018-08-18 16:41:26 +02:00
dst->cache_tree = src->cache_tree;
src->cache_tree = NULL;
}
block alloc: add lifecycle APIs for cache_entry structs It has been observed that the time spent loading an index with a large number of entries is partly dominated by malloc() calls. This change is in preparation for using memory pools to reduce the number of malloc() calls made to allocate cahce entries when loading an index. Add an API to allocate and discard cache entries, abstracting the details of managing the memory backing the cache entries. This commit does actually change how memory is managed - this will be done in a later commit in the series. This change makes the distinction between cache entries that are associated with an index and cache entries that are not associated with an index. A main use of cache entries is with an index, and we can optimize the memory management around this. We still have other cases where a cache entry is not persisted with an index, and so we need to handle the "transient" use case as well. To keep the congnitive overhead of managing the cache entries, there will only be a single discard function. This means there must be enough information kept with the cache entry so that we know how to discard them. A summary of the main functions in the API is: make_cache_entry: create cache entry for use in an index. Uses specified parameters to populate cache_entry fields. make_empty_cache_entry: Create an empty cache entry for use in an index. Returns cache entry with empty fields. make_transient_cache_entry: create cache entry that is not used in an index. Uses specified parameters to populate cache_entry fields. make_empty_transient_cache_entry: create cache entry that is not used in an index. Returns cache entry with empty fields. discard_cache_entry: A single function that knows how to discard a cache entry regardless of how it was allocated. Signed-off-by: Jameson Miller <jamill@microsoft.com> Signed-off-by: Junio C Hamano <gitster@pobox.com>
2018-07-02 21:49:31 +02:00
block alloc: allocate cache entries from mem_pool When reading large indexes from disk, a portion of the time is dominated in malloc() calls. This can be mitigated by allocating a large block of memory and manage it ourselves via memory pools. This change moves the cache entry allocation to be on top of memory pools. Design: The index_state struct will gain a notion of an associated memory_pool from which cache_entries will be allocated from. When reading in the index from disk, we have information on the number of entries and their size, which can guide us in deciding how large our initial memory allocation should be. When an index is discarded, the associated memory_pool will be discarded as well - so the lifetime of a cache_entry is tied to the lifetime of the index_state that it was allocated for. In the case of a Split Index, the following rules are followed. 1st, some terminology is defined: Terminology: - 'the_index': represents the logical view of the index - 'split_index': represents the "base" cache entries. Read from the split index file. 'the_index' can reference a single split_index, as well as cache_entries from the split_index. `the_index` will be discarded before the `split_index` is. This means that when we are allocating cache_entries in the presence of a split index, we need to allocate the entries from the `split_index`'s memory pool. This allows us to follow the pattern that `the_index` can reference cache_entries from the `split_index`, and that the cache_entries will not be freed while they are still being referenced. Managing transient cache_entry structs: Cache entries are usually allocated for an index, but this is not always the case. Cache entries are sometimes allocated because this is the type that the existing checkout_entry function works with. Because of this, the existing code needs to handle cache entries associated with an index / memory pool, and those that only exist transiently. Several strategies were contemplated around how to handle this: Chosen approach: An extra field was added to the cache_entry type to track whether the cache_entry was allocated from a memory pool or not. This is currently an int field, as there are no more available bits in the existing ce_flags bit field. If / when more bits are needed, this new field can be turned into a proper bit field. Alternatives: 1) Do not include any information about how the cache_entry was allocated. Calling code would be responsible for tracking whether the cache_entry needed to be freed or not. Pro: No extra memory overhead to track this state Con: Extra complexity in callers to handle this correctly. The extra complexity and burden to not regress this behavior in the future was more than we wanted. 2) cache_entry would gain knowledge about which mem_pool allocated it Pro: Could (potentially) do extra logic to know when a mem_pool no longer had references to any cache_entry Con: cache_entry would grow heavier by a pointer, instead of int We didn't see a tangible benefit to this approach 3) Do not add any extra information to a cache_entry, but when freeing a cache entry, check if the memory exists in a region managed by existing mem_pools. Pro: No extra memory overhead to track state Con: Extra computation is performed when freeing cache entries We decided tracking and iterating over known memory pool regions was less desirable than adding an extra field to track this stae. Signed-off-by: Jameson Miller <jamill@microsoft.com> Signed-off-by: Junio C Hamano <gitster@pobox.com>
2018-07-02 21:49:37 +02:00
struct cache_entry *dup_cache_entry(const struct cache_entry *ce,
struct index_state *istate)
{
unsigned int size = ce_size(ce);
int mem_pool_allocated;
struct cache_entry *new_entry = make_empty_cache_entry(istate, ce_namelen(ce));
mem_pool_allocated = new_entry->mem_pool_allocated;
memcpy(new_entry, ce, size);
new_entry->mem_pool_allocated = mem_pool_allocated;
return new_entry;
}
block alloc: add lifecycle APIs for cache_entry structs It has been observed that the time spent loading an index with a large number of entries is partly dominated by malloc() calls. This change is in preparation for using memory pools to reduce the number of malloc() calls made to allocate cahce entries when loading an index. Add an API to allocate and discard cache entries, abstracting the details of managing the memory backing the cache entries. This commit does actually change how memory is managed - this will be done in a later commit in the series. This change makes the distinction between cache entries that are associated with an index and cache entries that are not associated with an index. A main use of cache entries is with an index, and we can optimize the memory management around this. We still have other cases where a cache entry is not persisted with an index, and so we need to handle the "transient" use case as well. To keep the congnitive overhead of managing the cache entries, there will only be a single discard function. This means there must be enough information kept with the cache entry so that we know how to discard them. A summary of the main functions in the API is: make_cache_entry: create cache entry for use in an index. Uses specified parameters to populate cache_entry fields. make_empty_cache_entry: Create an empty cache entry for use in an index. Returns cache entry with empty fields. make_transient_cache_entry: create cache entry that is not used in an index. Uses specified parameters to populate cache_entry fields. make_empty_transient_cache_entry: create cache entry that is not used in an index. Returns cache entry with empty fields. discard_cache_entry: A single function that knows how to discard a cache entry regardless of how it was allocated. Signed-off-by: Jameson Miller <jamill@microsoft.com> Signed-off-by: Junio C Hamano <gitster@pobox.com>
2018-07-02 21:49:31 +02:00
void discard_cache_entry(struct cache_entry *ce)
{
if (ce && should_validate_cache_entries())
memset(ce, 0xCD, cache_entry_size(ce->ce_namelen));
block alloc: allocate cache entries from mem_pool When reading large indexes from disk, a portion of the time is dominated in malloc() calls. This can be mitigated by allocating a large block of memory and manage it ourselves via memory pools. This change moves the cache entry allocation to be on top of memory pools. Design: The index_state struct will gain a notion of an associated memory_pool from which cache_entries will be allocated from. When reading in the index from disk, we have information on the number of entries and their size, which can guide us in deciding how large our initial memory allocation should be. When an index is discarded, the associated memory_pool will be discarded as well - so the lifetime of a cache_entry is tied to the lifetime of the index_state that it was allocated for. In the case of a Split Index, the following rules are followed. 1st, some terminology is defined: Terminology: - 'the_index': represents the logical view of the index - 'split_index': represents the "base" cache entries. Read from the split index file. 'the_index' can reference a single split_index, as well as cache_entries from the split_index. `the_index` will be discarded before the `split_index` is. This means that when we are allocating cache_entries in the presence of a split index, we need to allocate the entries from the `split_index`'s memory pool. This allows us to follow the pattern that `the_index` can reference cache_entries from the `split_index`, and that the cache_entries will not be freed while they are still being referenced. Managing transient cache_entry structs: Cache entries are usually allocated for an index, but this is not always the case. Cache entries are sometimes allocated because this is the type that the existing checkout_entry function works with. Because of this, the existing code needs to handle cache entries associated with an index / memory pool, and those that only exist transiently. Several strategies were contemplated around how to handle this: Chosen approach: An extra field was added to the cache_entry type to track whether the cache_entry was allocated from a memory pool or not. This is currently an int field, as there are no more available bits in the existing ce_flags bit field. If / when more bits are needed, this new field can be turned into a proper bit field. Alternatives: 1) Do not include any information about how the cache_entry was allocated. Calling code would be responsible for tracking whether the cache_entry needed to be freed or not. Pro: No extra memory overhead to track this state Con: Extra complexity in callers to handle this correctly. The extra complexity and burden to not regress this behavior in the future was more than we wanted. 2) cache_entry would gain knowledge about which mem_pool allocated it Pro: Could (potentially) do extra logic to know when a mem_pool no longer had references to any cache_entry Con: cache_entry would grow heavier by a pointer, instead of int We didn't see a tangible benefit to this approach 3) Do not add any extra information to a cache_entry, but when freeing a cache entry, check if the memory exists in a region managed by existing mem_pools. Pro: No extra memory overhead to track state Con: Extra computation is performed when freeing cache entries We decided tracking and iterating over known memory pool regions was less desirable than adding an extra field to track this stae. Signed-off-by: Jameson Miller <jamill@microsoft.com> Signed-off-by: Junio C Hamano <gitster@pobox.com>
2018-07-02 21:49:37 +02:00
if (ce && ce->mem_pool_allocated)
return;
block alloc: add lifecycle APIs for cache_entry structs It has been observed that the time spent loading an index with a large number of entries is partly dominated by malloc() calls. This change is in preparation for using memory pools to reduce the number of malloc() calls made to allocate cahce entries when loading an index. Add an API to allocate and discard cache entries, abstracting the details of managing the memory backing the cache entries. This commit does actually change how memory is managed - this will be done in a later commit in the series. This change makes the distinction between cache entries that are associated with an index and cache entries that are not associated with an index. A main use of cache entries is with an index, and we can optimize the memory management around this. We still have other cases where a cache entry is not persisted with an index, and so we need to handle the "transient" use case as well. To keep the congnitive overhead of managing the cache entries, there will only be a single discard function. This means there must be enough information kept with the cache entry so that we know how to discard them. A summary of the main functions in the API is: make_cache_entry: create cache entry for use in an index. Uses specified parameters to populate cache_entry fields. make_empty_cache_entry: Create an empty cache entry for use in an index. Returns cache entry with empty fields. make_transient_cache_entry: create cache entry that is not used in an index. Uses specified parameters to populate cache_entry fields. make_empty_transient_cache_entry: create cache entry that is not used in an index. Returns cache entry with empty fields. discard_cache_entry: A single function that knows how to discard a cache entry regardless of how it was allocated. Signed-off-by: Jameson Miller <jamill@microsoft.com> Signed-off-by: Junio C Hamano <gitster@pobox.com>
2018-07-02 21:49:31 +02:00
free(ce);
}
int should_validate_cache_entries(void)
{
static int validate_index_cache_entries = -1;
if (validate_index_cache_entries < 0) {
if (getenv("GIT_TEST_VALIDATE_INDEX_CACHE_ENTRIES"))
validate_index_cache_entries = 1;
else
validate_index_cache_entries = 0;
}
return validate_index_cache_entries;
}
#define EOIE_SIZE (4 + GIT_SHA1_RAWSZ) /* <4-byte offset> + <20-byte hash> */
#define EOIE_SIZE_WITH_HEADER (4 + 4 + EOIE_SIZE) /* <4-byte signature> + <4-byte length> + EOIE_SIZE */
static size_t read_eoie_extension(const char *mmap, size_t mmap_size)
{
/*
* The end of index entries (EOIE) extension is guaranteed to be last
* so that it can be found by scanning backwards from the EOF.
*
* "EOIE"
* <4-byte length>
* <4-byte offset>
* <20-byte hash>
*/
const char *index, *eoie;
uint32_t extsize;
size_t offset, src_offset;
unsigned char hash[GIT_MAX_RAWSZ];
git_hash_ctx c;
/* ensure we have an index big enough to contain an EOIE extension */
if (mmap_size < sizeof(struct cache_header) + EOIE_SIZE_WITH_HEADER + the_hash_algo->rawsz)
return 0;
/* validate the extension signature */
index = eoie = mmap + mmap_size - EOIE_SIZE_WITH_HEADER - the_hash_algo->rawsz;
if (CACHE_EXT(index) != CACHE_EXT_ENDOFINDEXENTRIES)
return 0;
index += sizeof(uint32_t);
/* validate the extension size */
extsize = get_be32(index);
if (extsize != EOIE_SIZE)
return 0;
index += sizeof(uint32_t);
/*
* Validate the offset we're going to look for the first extension
* signature is after the index header and before the eoie extension.
*/
offset = get_be32(index);
if (mmap + offset < mmap + sizeof(struct cache_header))
return 0;
if (mmap + offset >= eoie)
return 0;
index += sizeof(uint32_t);
/*
* The hash is computed over extension types and their sizes (but not
* their contents). E.g. if we have "TREE" extension that is N-bytes
* long, "REUC" extension that is M-bytes long, followed by "EOIE",
* then the hash would be:
*
* SHA-1("TREE" + <binary representation of N> +
* "REUC" + <binary representation of M>)
*/
src_offset = offset;
the_hash_algo->init_fn(&c);
while (src_offset < mmap_size - the_hash_algo->rawsz - EOIE_SIZE_WITH_HEADER) {
/* After an array of active_nr index entries,
* there can be arbitrary number of extended
* sections, each of which is prefixed with
* extension name (4-byte) and section length
* in 4-byte network byte order.
*/
uint32_t extsize;
memcpy(&extsize, mmap + src_offset + 4, 4);
extsize = ntohl(extsize);
/* verify the extension size isn't so large it will wrap around */
if (src_offset + 8 + extsize < src_offset)
return 0;
the_hash_algo->update_fn(&c, mmap + src_offset, 8);
src_offset += 8;
src_offset += extsize;
}
the_hash_algo->final_fn(hash, &c);
if (!hasheq(hash, (const unsigned char *)index))
return 0;
/* Validate that the extension offsets returned us back to the eoie extension. */
if (src_offset != mmap_size - the_hash_algo->rawsz - EOIE_SIZE_WITH_HEADER)
return 0;
return offset;
}
static void write_eoie_extension(struct strbuf *sb, git_hash_ctx *eoie_context, size_t offset)
{
uint32_t buffer;
unsigned char hash[GIT_MAX_RAWSZ];
/* offset */
put_be32(&buffer, offset);
strbuf_add(sb, &buffer, sizeof(uint32_t));
/* hash */
the_hash_algo->final_fn(hash, eoie_context);
strbuf_add(sb, hash, the_hash_algo->rawsz);
}
#define IEOT_VERSION (1)
static struct index_entry_offset_table *read_ieot_extension(const char *mmap, size_t mmap_size, size_t offset)
{
const char *index = NULL;
uint32_t extsize, ext_version;
struct index_entry_offset_table *ieot;
int i, nr;
/* find the IEOT extension */
if (!offset)
return NULL;
while (offset <= mmap_size - the_hash_algo->rawsz - 8) {
extsize = get_be32(mmap + offset + 4);
if (CACHE_EXT((mmap + offset)) == CACHE_EXT_INDEXENTRYOFFSETTABLE) {
index = mmap + offset + 4 + 4;
break;
}
offset += 8;
offset += extsize;
}
if (!index)
return NULL;
/* validate the version is IEOT_VERSION */
ext_version = get_be32(index);
if (ext_version != IEOT_VERSION) {
error("invalid IEOT version %d", ext_version);
return NULL;
}
index += sizeof(uint32_t);
/* extension size - version bytes / bytes per entry */
nr = (extsize - sizeof(uint32_t)) / (sizeof(uint32_t) + sizeof(uint32_t));
if (!nr) {
error("invalid number of IEOT entries %d", nr);
return NULL;
}
ieot = xmalloc(sizeof(struct index_entry_offset_table)
+ (nr * sizeof(struct index_entry_offset)));
ieot->nr = nr;
for (i = 0; i < nr; i++) {
ieot->entries[i].offset = get_be32(index);
index += sizeof(uint32_t);
ieot->entries[i].nr = get_be32(index);
index += sizeof(uint32_t);
}
return ieot;
}
static void write_ieot_extension(struct strbuf *sb, struct index_entry_offset_table *ieot)
{
uint32_t buffer;
int i;
/* version */
put_be32(&buffer, IEOT_VERSION);
strbuf_add(sb, &buffer, sizeof(uint32_t));
/* ieot */
for (i = 0; i < ieot->nr; i++) {
/* offset */
put_be32(&buffer, ieot->entries[i].offset);
strbuf_add(sb, &buffer, sizeof(uint32_t));
/* count */
put_be32(&buffer, ieot->entries[i].nr);
strbuf_add(sb, &buffer, sizeof(uint32_t));
}
}
void prefetch_cache_entries(const struct index_state *istate,
must_prefetch_predicate must_prefetch)
{
int i;
struct oid_array to_fetch = OID_ARRAY_INIT;
for (i = 0; i < istate->cache_nr; i++) {
struct cache_entry *ce = istate->cache[i];
if (S_ISGITLINK(ce->ce_mode) || !must_prefetch(ce))
continue;
if (!oid_object_info_extended(the_repository, &ce->oid,
NULL,
OBJECT_INFO_FOR_PREFETCH))
continue;
oid_array_append(&to_fetch, &ce->oid);
}
promisor_remote_get_direct(the_repository,
to_fetch.oid, to_fetch.nr);
oid_array_clear(&to_fetch);
}