68faf68938
This merge strategy largely piggy-backs on git-merge-recursive. When merging trees A and B, if B corresponds to a subtree of A, B is first adjusted to match the tree structure of A, instead of reading the trees at the same level. This adjustment is also done to the common ancestor tree. If you are pulling updates from git-gui repository into git.git repository, the root level of the former corresponds to git-gui/ subdirectory of the latter. The tree object of git-gui's toplevel is wrapped in a fake tree object, whose sole entry has name 'git-gui' and records object name of the true tree, before being used by the 3-way merge code. If you are merging the other way, only the git-gui/ subtree of git.git is extracted and merged into git-gui's toplevel. The detection of corresponding subtree is done by comparing the pathnames and types in the toplevel of the tree. Heuristics galore! That's the git way ;-). Signed-off-by: Junio C Hamano <junkio@cox.net>
305 lines
7.1 KiB
C
305 lines
7.1 KiB
C
#include "cache.h"
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#include "tree.h"
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#include "tree-walk.h"
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static int score_missing(unsigned mode, const char *path)
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{
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int score;
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if (S_ISDIR(mode))
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score = -1000;
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else if (S_ISLNK(mode))
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score = -500;
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else
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score = -50;
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return score;
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}
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static int score_differs(unsigned mode1, unsigned mode2, const char *path)
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{
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int score;
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if (S_ISDIR(mode1) != S_ISDIR(mode2))
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score = -100;
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else if (S_ISLNK(mode1) != S_ISLNK(mode2))
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score = -50;
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else
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score = -5;
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return score;
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}
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static int score_matches(unsigned mode1, unsigned mode2, const char *path)
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{
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int score;
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/* Heh, we found SHA-1 collisions between different kind of objects */
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if (S_ISDIR(mode1) != S_ISDIR(mode2))
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score = -100;
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else if (S_ISLNK(mode1) != S_ISLNK(mode2))
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score = -50;
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else if (S_ISDIR(mode1))
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score = 1000;
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else if (S_ISLNK(mode1))
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score = 500;
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else
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score = 250;
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return score;
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}
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/*
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* Inspect two trees, and give a score that tells how similar they are.
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*/
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static int score_trees(const unsigned char *hash1, const unsigned char *hash2)
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{
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struct tree_desc one;
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struct tree_desc two;
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void *one_buf, *two_buf;
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int score = 0;
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enum object_type type;
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unsigned long size;
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one_buf = read_sha1_file(hash1, &type, &size);
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if (!one_buf)
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die("unable to read tree (%s)", sha1_to_hex(hash1));
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if (type != OBJ_TREE)
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die("%s is not a tree", sha1_to_hex(hash1));
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init_tree_desc(&one, one_buf, size);
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two_buf = read_sha1_file(hash2, &type, &size);
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if (!two_buf)
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die("unable to read tree (%s)", sha1_to_hex(hash2));
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if (type != OBJ_TREE)
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die("%s is not a tree", sha1_to_hex(hash2));
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init_tree_desc(&two, two_buf, size);
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while (one.size | two.size) {
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const unsigned char *elem1 = elem1;
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const unsigned char *elem2 = elem2;
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const char *path1 = path1;
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const char *path2 = path2;
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unsigned mode1 = mode1;
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unsigned mode2 = mode2;
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int cmp;
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if (one.size)
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elem1 = tree_entry_extract(&one, &path1, &mode1);
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if (two.size)
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elem2 = tree_entry_extract(&two, &path2, &mode2);
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if (!one.size) {
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/* two has more entries */
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score += score_missing(mode2, path2);
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update_tree_entry(&two);
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continue;
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}
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if (!two.size) {
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/* two lacks this entry */
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score += score_missing(mode1, path1);
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update_tree_entry(&one);
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continue;
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}
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cmp = base_name_compare(path1, strlen(path1), mode1,
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path2, strlen(path2), mode2);
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if (cmp < 0) {
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/* path1 does not appear in two */
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score += score_missing(mode1, path1);
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update_tree_entry(&one);
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continue;
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}
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else if (cmp > 0) {
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/* path2 does not appear in one */
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score += score_missing(mode2, path2);
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update_tree_entry(&two);
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continue;
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}
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else if (hashcmp(elem1, elem2))
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/* they are different */
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score += score_differs(mode1, mode2, path1);
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else
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/* same subtree or blob */
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score += score_matches(mode1, mode2, path1);
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update_tree_entry(&one);
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update_tree_entry(&two);
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}
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free(one_buf);
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free(two_buf);
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return score;
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}
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/*
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* Match one itself and its subtrees with two and pick the best match.
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*/
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static void match_trees(const unsigned char *hash1,
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const unsigned char *hash2,
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int *best_score,
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char **best_match,
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char *base,
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int recurse_limit)
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{
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struct tree_desc one;
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void *one_buf;
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enum object_type type;
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unsigned long size;
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one_buf = read_sha1_file(hash1, &type, &size);
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if (!one_buf)
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die("unable to read tree (%s)", sha1_to_hex(hash1));
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if (type != OBJ_TREE)
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die("%s is not a tree", sha1_to_hex(hash1));
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init_tree_desc(&one, one_buf, size);
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while (one.size) {
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const char *path;
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const unsigned char *elem;
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unsigned mode;
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int score;
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elem = tree_entry_extract(&one, &path, &mode);
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if (!S_ISDIR(mode))
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goto next;
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score = score_trees(elem, hash2);
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if (*best_score < score) {
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char *newpath;
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newpath = xmalloc(strlen(base) + strlen(path) + 1);
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sprintf(newpath, "%s%s", base, path);
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free(*best_match);
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*best_match = newpath;
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*best_score = score;
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}
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if (recurse_limit) {
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char *newbase;
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newbase = xmalloc(strlen(base) + strlen(path) + 2);
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sprintf(newbase, "%s%s/", base, path);
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match_trees(elem, hash2, best_score, best_match,
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newbase, recurse_limit - 1);
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free(newbase);
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}
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next:
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update_tree_entry(&one);
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}
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free(one_buf);
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}
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/*
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* A tree "hash1" has a subdirectory at "prefix". Come up with a
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* tree object by replacing it with another tree "hash2".
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*/
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static int splice_tree(const unsigned char *hash1,
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char *prefix,
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const unsigned char *hash2,
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unsigned char *result)
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{
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char *subpath;
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int toplen;
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char *buf;
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unsigned long sz;
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struct tree_desc desc;
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unsigned char *rewrite_here;
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const unsigned char *rewrite_with;
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unsigned char subtree[20];
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enum object_type type;
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int status;
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subpath = strchr(prefix, '/');
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if (!subpath)
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toplen = strlen(prefix);
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else {
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toplen = subpath - prefix;
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subpath++;
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}
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buf = read_sha1_file(hash1, &type, &sz);
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if (!buf)
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die("cannot read tree %s", sha1_to_hex(hash1));
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init_tree_desc(&desc, buf, sz);
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rewrite_here = NULL;
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while (desc.size) {
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const char *name;
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unsigned mode;
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const unsigned char *sha1;
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sha1 = tree_entry_extract(&desc, &name, &mode);
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if (strlen(name) == toplen &&
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!memcmp(name, prefix, toplen)) {
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if (!S_ISDIR(mode))
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die("entry %s in tree %s is not a tree",
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name, sha1_to_hex(hash1));
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rewrite_here = (unsigned char *) sha1;
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break;
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}
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update_tree_entry(&desc);
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}
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if (!rewrite_here)
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die("entry %.*s not found in tree %s",
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toplen, prefix, sha1_to_hex(hash1));
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if (subpath) {
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status = splice_tree(rewrite_here, subpath, hash2, subtree);
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if (status)
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return status;
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rewrite_with = subtree;
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}
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else
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rewrite_with = hash2;
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hashcpy(rewrite_here, rewrite_with);
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status = write_sha1_file(buf, sz, tree_type, result);
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free(buf);
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return status;
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}
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/*
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* We are trying to come up with a merge between one and two that
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* results in a tree shape similar to one. The tree two might
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* correspond to a subtree of one, in which case it needs to be
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* shifted down by prefixing otherwise empty directories. On the
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* other hand, it could cover tree one and we might need to pick a
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* subtree of it.
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*/
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void shift_tree(const unsigned char *hash1,
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const unsigned char *hash2,
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unsigned char *shifted,
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int depth_limit)
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{
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char *add_prefix;
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char *del_prefix;
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int add_score, del_score;
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add_score = del_score = score_trees(hash1, hash2);
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add_prefix = xcalloc(1, 1);
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del_prefix = xcalloc(1, 1);
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/*
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* See if one's subtree resembles two; if so we need to prefix
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* two with a few fake trees to match the prefix.
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*/
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match_trees(hash1, hash2, &add_score, &add_prefix, "", depth_limit);
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/*
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* See if two's subtree resembles one; if so we need to
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* pick only subtree of two.
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*/
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match_trees(hash2, hash1, &del_score, &del_prefix, "", depth_limit);
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/* Assume we do not have to do any shifting */
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hashcpy(shifted, hash2);
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if (add_score < del_score) {
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/* We need to pick a subtree of two */
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unsigned mode;
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if (!*del_prefix)
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return;
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if (get_tree_entry(hash2, del_prefix, shifted, &mode))
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die("cannot find path %s in tree %s",
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del_prefix, sha1_to_hex(hash2));
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return;
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}
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if (!*add_prefix)
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return;
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splice_tree(hash1, add_prefix, hash2, shifted);
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}
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