#include "../cache.h" #include "../refs.h" #include "refs-internal.h" #include "ref-cache.h" #include "../iterator.h" /* FIXME: This declaration shouldn't be here */ void read_loose_refs(const char *dirname, struct ref_dir *dir); void add_entry_to_dir(struct ref_dir *dir, struct ref_entry *entry) { ALLOC_GROW(dir->entries, dir->nr + 1, dir->alloc); dir->entries[dir->nr++] = entry; /* optimize for the case that entries are added in order */ if (dir->nr == 1 || (dir->nr == dir->sorted + 1 && strcmp(dir->entries[dir->nr - 2]->name, dir->entries[dir->nr - 1]->name) < 0)) dir->sorted = dir->nr; } struct ref_dir *get_ref_dir(struct ref_entry *entry) { struct ref_dir *dir; assert(entry->flag & REF_DIR); dir = &entry->u.subdir; if (entry->flag & REF_INCOMPLETE) { read_loose_refs(entry->name, dir); /* * Manually add refs/bisect, which, being * per-worktree, might not appear in the directory * listing for refs/ in the main repo. */ if (!strcmp(entry->name, "refs/")) { int pos = search_ref_dir(dir, "refs/bisect/", 12); if (pos < 0) { struct ref_entry *child_entry; child_entry = create_dir_entry(dir->ref_store, "refs/bisect/", 12, 1); add_entry_to_dir(dir, child_entry); } } entry->flag &= ~REF_INCOMPLETE; } return dir; } struct ref_entry *create_ref_entry(const char *refname, const unsigned char *sha1, int flag, int check_name) { struct ref_entry *ref; if (check_name && check_refname_format(refname, REFNAME_ALLOW_ONELEVEL)) die("Reference has invalid format: '%s'", refname); FLEX_ALLOC_STR(ref, name, refname); hashcpy(ref->u.value.oid.hash, sha1); oidclr(&ref->u.value.peeled); ref->flag = flag; return ref; } static void clear_ref_dir(struct ref_dir *dir); void free_ref_entry(struct ref_entry *entry) { if (entry->flag & REF_DIR) { /* * Do not use get_ref_dir() here, as that might * trigger the reading of loose refs. */ clear_ref_dir(&entry->u.subdir); } free(entry); } /* * Clear and free all entries in dir, recursively. */ static void clear_ref_dir(struct ref_dir *dir) { int i; for (i = 0; i < dir->nr; i++) free_ref_entry(dir->entries[i]); free(dir->entries); dir->sorted = dir->nr = dir->alloc = 0; dir->entries = NULL; } struct ref_entry *create_dir_entry(struct files_ref_store *ref_store, const char *dirname, size_t len, int incomplete) { struct ref_entry *direntry; FLEX_ALLOC_MEM(direntry, name, dirname, len); direntry->u.subdir.ref_store = ref_store; direntry->flag = REF_DIR | (incomplete ? REF_INCOMPLETE : 0); return direntry; } static int ref_entry_cmp(const void *a, const void *b) { struct ref_entry *one = *(struct ref_entry **)a; struct ref_entry *two = *(struct ref_entry **)b; return strcmp(one->name, two->name); } static void sort_ref_dir(struct ref_dir *dir); struct string_slice { size_t len; const char *str; }; static int ref_entry_cmp_sslice(const void *key_, const void *ent_) { const struct string_slice *key = key_; const struct ref_entry *ent = *(const struct ref_entry * const *)ent_; int cmp = strncmp(key->str, ent->name, key->len); if (cmp) return cmp; return '\0' - (unsigned char)ent->name[key->len]; } int search_ref_dir(struct ref_dir *dir, const char *refname, size_t len) { struct ref_entry **r; struct string_slice key; if (refname == NULL || !dir->nr) return -1; sort_ref_dir(dir); key.len = len; key.str = refname; r = bsearch(&key, dir->entries, dir->nr, sizeof(*dir->entries), ref_entry_cmp_sslice); if (r == NULL) return -1; return r - dir->entries; } /* * Search for a directory entry directly within dir (without * recursing). Sort dir if necessary. subdirname must be a directory * name (i.e., end in '/'). If mkdir is set, then create the * directory if it is missing; otherwise, return NULL if the desired * directory cannot be found. dir must already be complete. */ static struct ref_dir *search_for_subdir(struct ref_dir *dir, const char *subdirname, size_t len, int mkdir) { int entry_index = search_ref_dir(dir, subdirname, len); struct ref_entry *entry; if (entry_index == -1) { if (!mkdir) return NULL; /* * Since dir is complete, the absence of a subdir * means that the subdir really doesn't exist; * therefore, create an empty record for it but mark * the record complete. */ entry = create_dir_entry(dir->ref_store, subdirname, len, 0); add_entry_to_dir(dir, entry); } else { entry = dir->entries[entry_index]; } return get_ref_dir(entry); } struct ref_dir *find_containing_dir(struct ref_dir *dir, const char *refname, int mkdir) { const char *slash; for (slash = strchr(refname, '/'); slash; slash = strchr(slash + 1, '/')) { size_t dirnamelen = slash - refname + 1; struct ref_dir *subdir; subdir = search_for_subdir(dir, refname, dirnamelen, mkdir); if (!subdir) { dir = NULL; break; } dir = subdir; } return dir; } struct ref_entry *find_ref_entry(struct ref_dir *dir, const char *refname) { int entry_index; struct ref_entry *entry; dir = find_containing_dir(dir, refname, 0); if (!dir) return NULL; entry_index = search_ref_dir(dir, refname, strlen(refname)); if (entry_index == -1) return NULL; entry = dir->entries[entry_index]; return (entry->flag & REF_DIR) ? NULL : entry; } int remove_entry_from_dir(struct ref_dir *dir, const char *refname) { int refname_len = strlen(refname); int entry_index; struct ref_entry *entry; int is_dir = refname[refname_len - 1] == '/'; if (is_dir) { /* * refname represents a reference directory. Remove * the trailing slash; otherwise we will get the * directory *representing* refname rather than the * one *containing* it. */ char *dirname = xmemdupz(refname, refname_len - 1); dir = find_containing_dir(dir, dirname, 0); free(dirname); } else { dir = find_containing_dir(dir, refname, 0); } if (!dir) return -1; entry_index = search_ref_dir(dir, refname, refname_len); if (entry_index == -1) return -1; entry = dir->entries[entry_index]; memmove(&dir->entries[entry_index], &dir->entries[entry_index + 1], (dir->nr - entry_index - 1) * sizeof(*dir->entries) ); dir->nr--; if (dir->sorted > entry_index) dir->sorted--; free_ref_entry(entry); return dir->nr; } int add_ref_entry(struct ref_dir *dir, struct ref_entry *ref) { dir = find_containing_dir(dir, ref->name, 1); if (!dir) return -1; add_entry_to_dir(dir, ref); return 0; } /* * Emit a warning and return true iff ref1 and ref2 have the same name * and the same sha1. Die if they have the same name but different * sha1s. */ static int is_dup_ref(const struct ref_entry *ref1, const struct ref_entry *ref2) { if (strcmp(ref1->name, ref2->name)) return 0; /* Duplicate name; make sure that they don't conflict: */ if ((ref1->flag & REF_DIR) || (ref2->flag & REF_DIR)) /* This is impossible by construction */ die("Reference directory conflict: %s", ref1->name); if (oidcmp(&ref1->u.value.oid, &ref2->u.value.oid)) die("Duplicated ref, and SHA1s don't match: %s", ref1->name); warning("Duplicated ref: %s", ref1->name); return 1; } /* * Sort the entries in dir non-recursively (if they are not already * sorted) and remove any duplicate entries. */ static void sort_ref_dir(struct ref_dir *dir) { int i, j; struct ref_entry *last = NULL; /* * This check also prevents passing a zero-length array to qsort(), * which is a problem on some platforms. */ if (dir->sorted == dir->nr) return; QSORT(dir->entries, dir->nr, ref_entry_cmp); /* Remove any duplicates: */ for (i = 0, j = 0; j < dir->nr; j++) { struct ref_entry *entry = dir->entries[j]; if (last && is_dup_ref(last, entry)) free_ref_entry(entry); else last = dir->entries[i++] = entry; } dir->sorted = dir->nr = i; } int do_for_each_entry_in_dir(struct ref_dir *dir, int offset, each_ref_entry_fn fn, void *cb_data) { int i; assert(dir->sorted == dir->nr); for (i = offset; i < dir->nr; i++) { struct ref_entry *entry = dir->entries[i]; int retval; if (entry->flag & REF_DIR) { struct ref_dir *subdir = get_ref_dir(entry); sort_ref_dir(subdir); retval = do_for_each_entry_in_dir(subdir, 0, fn, cb_data); } else { retval = fn(entry, cb_data); } if (retval) return retval; } return 0; } void prime_ref_dir(struct ref_dir *dir) { /* * The hard work of loading loose refs is done by get_ref_dir(), so we * just need to recurse through all of the sub-directories. We do not * even need to care about sorting, as traversal order does not matter * to us. */ int i; for (i = 0; i < dir->nr; i++) { struct ref_entry *entry = dir->entries[i]; if (entry->flag & REF_DIR) prime_ref_dir(get_ref_dir(entry)); } } /* * A level in the reference hierarchy that is currently being iterated * through. */ struct cache_ref_iterator_level { /* * The ref_dir being iterated over at this level. The ref_dir * is sorted before being stored here. */ struct ref_dir *dir; /* * The index of the current entry within dir (which might * itself be a directory). If index == -1, then the iteration * hasn't yet begun. If index == dir->nr, then the iteration * through this level is over. */ int index; }; /* * Represent an iteration through a ref_dir in the memory cache. The * iteration recurses through subdirectories. */ struct cache_ref_iterator { struct ref_iterator base; /* * The number of levels currently on the stack. This is always * at least 1, because when it becomes zero the iteration is * ended and this struct is freed. */ size_t levels_nr; /* The number of levels that have been allocated on the stack */ size_t levels_alloc; /* * A stack of levels. levels[0] is the uppermost level that is * being iterated over in this iteration. (This is not * necessary the top level in the references hierarchy. If we * are iterating through a subtree, then levels[0] will hold * the ref_dir for that subtree, and subsequent levels will go * on from there.) */ struct cache_ref_iterator_level *levels; }; static int cache_ref_iterator_advance(struct ref_iterator *ref_iterator) { struct cache_ref_iterator *iter = (struct cache_ref_iterator *)ref_iterator; while (1) { struct cache_ref_iterator_level *level = &iter->levels[iter->levels_nr - 1]; struct ref_dir *dir = level->dir; struct ref_entry *entry; if (level->index == -1) sort_ref_dir(dir); if (++level->index == level->dir->nr) { /* This level is exhausted; pop up a level */ if (--iter->levels_nr == 0) return ref_iterator_abort(ref_iterator); continue; } entry = dir->entries[level->index]; if (entry->flag & REF_DIR) { /* push down a level */ ALLOC_GROW(iter->levels, iter->levels_nr + 1, iter->levels_alloc); level = &iter->levels[iter->levels_nr++]; level->dir = get_ref_dir(entry); level->index = -1; } else { iter->base.refname = entry->name; iter->base.oid = &entry->u.value.oid; iter->base.flags = entry->flag; return ITER_OK; } } } enum peel_status peel_entry(struct ref_entry *entry, int repeel) { enum peel_status status; if (entry->flag & REF_KNOWS_PEELED) { if (repeel) { entry->flag &= ~REF_KNOWS_PEELED; oidclr(&entry->u.value.peeled); } else { return is_null_oid(&entry->u.value.peeled) ? PEEL_NON_TAG : PEEL_PEELED; } } if (entry->flag & REF_ISBROKEN) return PEEL_BROKEN; if (entry->flag & REF_ISSYMREF) return PEEL_IS_SYMREF; status = peel_object(entry->u.value.oid.hash, entry->u.value.peeled.hash); if (status == PEEL_PEELED || status == PEEL_NON_TAG) entry->flag |= REF_KNOWS_PEELED; return status; } static int cache_ref_iterator_peel(struct ref_iterator *ref_iterator, struct object_id *peeled) { struct cache_ref_iterator *iter = (struct cache_ref_iterator *)ref_iterator; struct cache_ref_iterator_level *level; struct ref_entry *entry; level = &iter->levels[iter->levels_nr - 1]; if (level->index == -1) die("BUG: peel called before advance for cache iterator"); entry = level->dir->entries[level->index]; if (peel_entry(entry, 0)) return -1; oidcpy(peeled, &entry->u.value.peeled); return 0; } static int cache_ref_iterator_abort(struct ref_iterator *ref_iterator) { struct cache_ref_iterator *iter = (struct cache_ref_iterator *)ref_iterator; free(iter->levels); base_ref_iterator_free(ref_iterator); return ITER_DONE; } static struct ref_iterator_vtable cache_ref_iterator_vtable = { cache_ref_iterator_advance, cache_ref_iterator_peel, cache_ref_iterator_abort }; struct ref_iterator *cache_ref_iterator_begin(struct ref_dir *dir) { struct cache_ref_iterator *iter; struct ref_iterator *ref_iterator; struct cache_ref_iterator_level *level; iter = xcalloc(1, sizeof(*iter)); ref_iterator = &iter->base; base_ref_iterator_init(ref_iterator, &cache_ref_iterator_vtable); ALLOC_GROW(iter->levels, 10, iter->levels_alloc); iter->levels_nr = 1; level = &iter->levels[0]; level->index = -1; level->dir = dir; return ref_iterator; }