/* * GIT - The information manager from hell * * Copyright (C) Linus Torvalds, 2005 */ #include "cache.h" #include "cache-tree.h" /* 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" */ struct cache_entry **active_cache; static time_t index_file_timestamp; unsigned int active_nr, active_alloc, active_cache_changed; struct cache_tree *active_cache_tree; int cache_errno; static void *cache_mmap; static size_t cache_mmap_size; /* * 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 cache_entry *ce, struct stat *st) { ce->ce_ctime.sec = htonl(st->st_ctime); ce->ce_mtime.sec = htonl(st->st_mtime); #ifdef USE_NSEC ce->ce_ctime.nsec = htonl(st->st_ctim.tv_nsec); ce->ce_mtime.nsec = htonl(st->st_mtim.tv_nsec); #endif ce->ce_dev = htonl(st->st_dev); ce->ce_ino = htonl(st->st_ino); ce->ce_uid = htonl(st->st_uid); ce->ce_gid = htonl(st->st_gid); ce->ce_size = htonl(st->st_size); if (assume_unchanged) ce->ce_flags |= htons(CE_VALID); } static int ce_compare_data(struct cache_entry *ce, struct stat *st) { int match = -1; int fd = open(ce->name, O_RDONLY); if (fd >= 0) { unsigned char sha1[20]; if (!index_fd(sha1, fd, st, 0, NULL)) match = hashcmp(sha1, ce->sha1); /* index_fd() closed the file descriptor already */ } return match; } static int ce_compare_link(struct cache_entry *ce, unsigned long expected_size) { int match = -1; char *target; void *buffer; unsigned long size; char type[10]; int len; target = xmalloc(expected_size); len = readlink(ce->name, target, expected_size); if (len != expected_size) { free(target); return -1; } buffer = read_sha1_file(ce->sha1, type, &size); if (!buffer) { free(target); return -1; } if (size == expected_size) match = memcmp(buffer, target, size); free(buffer); free(target); return match; } static int ce_modified_check_fs(struct cache_entry *ce, struct stat *st) { switch (st->st_mode & S_IFMT) { case S_IFREG: if (ce_compare_data(ce, st)) return DATA_CHANGED; break; case S_IFLNK: if (ce_compare_link(ce, st->st_size)) return DATA_CHANGED; break; default: return TYPE_CHANGED; } return 0; } static int ce_match_stat_basic(struct cache_entry *ce, struct stat *st) { unsigned int changed = 0; switch (ntohl(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 & (ntohl(ce->ce_mode) ^ st->st_mode))) changed |= MODE_CHANGED; break; case S_IFLNK: changed |= !S_ISLNK(st->st_mode) ? TYPE_CHANGED : 0; break; default: die("internal error: ce_mode is %o", ntohl(ce->ce_mode)); } if (ce->ce_mtime.sec != htonl(st->st_mtime)) changed |= MTIME_CHANGED; if (ce->ce_ctime.sec != htonl(st->st_ctime)) changed |= CTIME_CHANGED; #ifdef USE_NSEC /* * nsec seems unreliable - not all filesystems support it, so * as long as it is in the inode cache you get right nsec * but after it gets flushed, you get zero nsec. */ if (ce->ce_mtime.nsec != htonl(st->st_mtim.tv_nsec)) changed |= MTIME_CHANGED; if (ce->ce_ctime.nsec != htonl(st->st_ctim.tv_nsec)) changed |= CTIME_CHANGED; #endif if (ce->ce_uid != htonl(st->st_uid) || ce->ce_gid != htonl(st->st_gid)) changed |= OWNER_CHANGED; if (ce->ce_ino != htonl(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 (ce->ce_dev != htonl(st->st_dev)) changed |= INODE_CHANGED; #endif if (ce->ce_size != htonl(st->st_size)) changed |= DATA_CHANGED; return changed; } int ce_match_stat(struct cache_entry *ce, struct stat *st, int options) { unsigned int changed; int ignore_valid = options & 01; int assume_racy_is_modified = options & 02; /* * If it's marked as always valid in the index, it's * valid whatever the checked-out copy says. */ if (!ignore_valid && (ce->ce_flags & htons(CE_VALID))) return 0; changed = ce_match_stat_basic(ce, st); /* * 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 * carefully than others. */ if (!changed && index_file_timestamp && index_file_timestamp <= ntohl(ce->ce_mtime.sec)) { if (assume_racy_is_modified) changed |= DATA_CHANGED; else changed |= ce_modified_check_fs(ce, st); } return changed; } int ce_modified(struct cache_entry *ce, struct stat *st, int really) { int changed, changed_fs; changed = ce_match_stat(ce, st, really); 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; /* Immediately after read-tree or update-index --cacheinfo, * the length field is zero. For other cases the ce_size * should match the SHA1 recorded in the index entry. */ if ((changed & DATA_CHANGED) && ce->ce_size != htonl(0)) return changed; changed_fs = ce_modified_check_fs(ce, st); 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; } int cache_name_compare(const char *name1, int flags1, const char *name2, int flags2) { int len1 = flags1 & CE_NAMEMASK; int len2 = flags2 & CE_NAMEMASK; int len = len1 < len2 ? len1 : len2; int cmp; cmp = memcmp(name1, name2, len); if (cmp) return cmp; if (len1 < len2) return -1; if (len1 > len2) return 1; /* Compare stages */ flags1 &= CE_STAGEMASK; flags2 &= CE_STAGEMASK; if (flags1 < flags2) return -1; if (flags1 > flags2) return 1; return 0; } int cache_name_pos(const char *name, int namelen) { int first, last; first = 0; last = active_nr; while (last > first) { int next = (last + first) >> 1; struct cache_entry *ce = active_cache[next]; int cmp = cache_name_compare(name, namelen, ce->name, ntohs(ce->ce_flags)); if (!cmp) return next; if (cmp < 0) { last = next; continue; } first = next+1; } return -first-1; } /* Remove entry, return true if there are more entries to go.. */ int remove_cache_entry_at(int pos) { active_cache_changed = 1; active_nr--; if (pos >= active_nr) return 0; memmove(active_cache + pos, active_cache + pos + 1, (active_nr - pos) * sizeof(struct cache_entry *)); return 1; } int remove_file_from_cache(const char *path) { int pos = cache_name_pos(path, strlen(path)); if (pos < 0) pos = -pos-1; while (pos < active_nr && !strcmp(active_cache[pos]->name, path)) remove_cache_entry_at(pos); return 0; } int add_file_to_index(const char *path, int verbose) { int size, namelen; struct stat st; struct cache_entry *ce; if (lstat(path, &st)) die("%s: unable to stat (%s)", path, strerror(errno)); if (!S_ISREG(st.st_mode) && !S_ISLNK(st.st_mode)) die("%s: can only add regular files or symbolic links", path); namelen = strlen(path); size = cache_entry_size(namelen); ce = xcalloc(1, size); memcpy(ce->name, path, namelen); ce->ce_flags = htons(namelen); fill_stat_cache_info(ce, &st); ce->ce_mode = create_ce_mode(st.st_mode); if (!trust_executable_bit) { /* If there is an existing entry, pick the mode bits * from it, otherwise assume unexecutable. */ int pos = cache_name_pos(path, namelen); if (pos >= 0) ce->ce_mode = active_cache[pos]->ce_mode; else if (S_ISREG(st.st_mode)) ce->ce_mode = create_ce_mode(S_IFREG | 0666); } if (index_path(ce->sha1, path, &st, 1)) die("unable to index file %s", path); if (add_cache_entry(ce, ADD_CACHE_OK_TO_ADD)) die("unable to add %s to index",path); if (verbose) printf("add '%s'\n", path); cache_tree_invalidate_path(active_cache_tree, path); return 0; } int ce_same_name(struct cache_entry *a, struct cache_entry *b) { int len = ce_namelen(a); return ce_namelen(b) == len && !memcmp(a->name, b->name, len); } int ce_path_match(const struct cache_entry *ce, const char **pathspec) { const char *match, *name; int len; if (!pathspec) return 1; len = ce_namelen(ce); name = ce->name; while ((match = *pathspec++) != NULL) { int matchlen = strlen(match); if (matchlen > len) continue; if (memcmp(name, match, matchlen)) continue; if (matchlen && name[matchlen-1] == '/') return 1; if (name[matchlen] == '/' || !name[matchlen]) return 1; if (!matchlen) return 1; } return 0; } /* * 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) { /* * The first character was '.', but that * has already been discarded, we now test * the rest. */ switch (*rest) { /* "." is not allowed */ case '\0': case '/': return 0; /* * ".git" followed by NUL or slash is bad. This * shares the path end test with the ".." case. */ case 'g': if (rest[1] != 'i') break; if (rest[2] != 't') break; rest += 2; /* fallthrough */ case '.': if (rest[1] == '\0' || rest[1] == '/') return 0; } return 1; } int verify_path(const char *path) { char c; goto inside; for (;;) { if (!c) return 1; if (c == '/') { inside: c = *path++; switch (c) { default: continue; case '/': case '\0': break; case '.': if (verify_dotfile(path)) continue; } return 0; } 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(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 < active_nr) { struct cache_entry *p = active_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; retval = -1; if (!ok_to_replace) break; remove_cache_entry_at(--pos); } return retval; } /* * Do we have another file with a pathname that is a proper * subset of the name we're trying to add? */ static int has_dir_name(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); for (;;) { int len; for (;;) { if (*--slash == '/') break; if (slash <= ce->name) return retval; } len = slash - name; pos = cache_name_pos(name, ntohs(create_ce_flags(len, stage))); if (pos >= 0) { retval = -1; if (ok_to_replace) break; remove_cache_entry_at(pos); continue; } /* * Trivial optimization: if we find an entry that * already matches the sub-directory, then we know * we're ok, and we can exit. */ pos = -pos-1; while (pos < active_nr) { struct cache_entry *p = active_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 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(const struct cache_entry *ce, int pos, int ok_to_replace) { /* * 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 */ int retval = has_file_name(ce, pos, ok_to_replace); /* * Then check if the path might have a clashing sub-directory * before it. */ return retval + has_dir_name(ce, pos, ok_to_replace); } int add_cache_entry(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; pos = cache_name_pos(ce->name, ntohs(ce->ce_flags)); /* existing match? Just replace it. */ if (pos >= 0) { active_cache_changed = 1; active_cache[pos] = ce; return 0; } pos = -pos-1; /* * Inserting a merged entry ("stage 0") into the index * will always replace all non-merged entries.. */ if (pos < active_nr && ce_stage(ce) == 0) { while (ce_same_name(active_cache[pos], ce)) { ok_to_add = 1; if (!remove_cache_entry_at(pos)) break; } } if (!ok_to_add) return -1; if (!verify_path(ce->name)) return -1; if (!skip_df_check && check_file_directory_conflict(ce, pos, ok_to_replace)) { if (!ok_to_replace) return -1; pos = cache_name_pos(ce->name, ntohs(ce->ce_flags)); pos = -pos-1; } /* Make sure the array is big enough .. */ if (active_nr == active_alloc) { active_alloc = alloc_nr(active_alloc); active_cache = xrealloc(active_cache, active_alloc * sizeof(struct cache_entry *)); } /* Add it in.. */ active_nr++; if (active_nr > pos) memmove(active_cache + pos + 1, active_cache + pos, (active_nr - pos - 1) * sizeof(ce)); active_cache[pos] = ce; active_cache_changed = 1; 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. */ struct cache_entry *refresh_cache_entry(struct cache_entry *ce, int really) { struct stat st; struct cache_entry *updated; int changed, size; if (lstat(ce->name, &st) < 0) { cache_errno = errno; return NULL; } changed = ce_match_stat(ce, &st, really); if (!changed) { if (really && assume_unchanged && !(ce->ce_flags & htons(CE_VALID))) ; /* mark this one VALID again */ else return ce; } if (ce_modified(ce, &st, really)) { cache_errno = EINVAL; return NULL; } size = ce_size(ce); updated = xmalloc(size); memcpy(updated, ce, size); fill_stat_cache_info(updated, &st); /* In this case, if really 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 (!really && assume_unchanged && !(ce->ce_flags & htons(CE_VALID))) updated->ce_flags &= ~htons(CE_VALID); return updated; } int refresh_cache(unsigned int flags) { 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; for (i = 0; i < active_nr; i++) { struct cache_entry *ce, *new; ce = active_cache[i]; if (ce_stage(ce)) { while ((i < active_nr) && ! strcmp(active_cache[i]->name, ce->name)) i++; i--; if (allow_unmerged) continue; printf("%s: needs merge\n", ce->name); has_errors = 1; continue; } new = refresh_cache_entry(ce, really); if (new == ce) continue; if (!new) { if (not_new && cache_errno == ENOENT) continue; if (really && cache_errno == EINVAL) { /* If we are doing --really-refresh that * means the index is not valid anymore. */ ce->ce_flags &= ~htons(CE_VALID); active_cache_changed = 1; } if (quiet) continue; printf("%s: needs update\n", ce->name); has_errors = 1; continue; } active_cache_changed = 1; /* You can NOT just free active_cache[i] here, since it * might not be necessarily malloc()ed but can also come * from mmap(). */ active_cache[i] = new; } return has_errors; } static int verify_hdr(struct cache_header *hdr, unsigned long size) { SHA_CTX c; unsigned char sha1[20]; if (hdr->hdr_signature != htonl(CACHE_SIGNATURE)) return error("bad signature"); if (hdr->hdr_version != htonl(2)) return error("bad index version"); SHA1_Init(&c); SHA1_Update(&c, hdr, size - 20); SHA1_Final(sha1, &c); if (hashcmp(sha1, (unsigned char *)hdr + size - 20)) return error("bad index file sha1 signature"); return 0; } static int read_index_extension(const char *ext, void *data, unsigned long sz) { switch (CACHE_EXT(ext)) { case CACHE_EXT_TREE: active_cache_tree = cache_tree_read(data, sz); break; default: if (*ext < 'A' || 'Z' < *ext) return error("index uses %.4s extension, which we do not understand", ext); fprintf(stderr, "ignoring %.4s extension\n", ext); break; } return 0; } int read_cache(void) { return read_cache_from(get_index_file()); } /* remember to discard_cache() before reading a different cache! */ int read_cache_from(const char *path) { int fd, i; struct stat st; unsigned long offset; struct cache_header *hdr; errno = EBUSY; if (cache_mmap) return active_nr; errno = ENOENT; index_file_timestamp = 0; fd = open(path, O_RDONLY); if (fd < 0) { if (errno == ENOENT) return 0; die("index file open failed (%s)", strerror(errno)); } cache_mmap = MAP_FAILED; if (!fstat(fd, &st)) { cache_mmap_size = st.st_size; errno = EINVAL; if (cache_mmap_size >= sizeof(struct cache_header) + 20) cache_mmap = mmap(NULL, cache_mmap_size, PROT_READ | PROT_WRITE, MAP_PRIVATE, fd, 0); } close(fd); if (cache_mmap == MAP_FAILED) die("index file mmap failed (%s)", strerror(errno)); hdr = cache_mmap; if (verify_hdr(hdr, cache_mmap_size) < 0) goto unmap; active_nr = ntohl(hdr->hdr_entries); active_alloc = alloc_nr(active_nr); active_cache = xcalloc(active_alloc, sizeof(struct cache_entry *)); offset = sizeof(*hdr); for (i = 0; i < active_nr; i++) { struct cache_entry *ce = (struct cache_entry *) ((char *) cache_mmap + offset); offset = offset + ce_size(ce); active_cache[i] = ce; } index_file_timestamp = st.st_mtime; while (offset <= cache_mmap_size - 20 - 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. */ unsigned long extsize; memcpy(&extsize, (char *) cache_mmap + offset + 4, 4); extsize = ntohl(extsize); if (read_index_extension(((const char *) cache_mmap) + offset, (char *) cache_mmap + offset + 8, extsize) < 0) goto unmap; offset += 8; offset += extsize; } return active_nr; unmap: munmap(cache_mmap, cache_mmap_size); errno = EINVAL; die("index file corrupt"); } int discard_cache(void) { int ret; active_nr = active_cache_changed = 0; index_file_timestamp = 0; cache_tree_free(&active_cache_tree); if (cache_mmap == NULL) return 0; ret = munmap(cache_mmap, cache_mmap_size); cache_mmap = NULL; cache_mmap_size = 0; /* no need to throw away allocated active_cache */ return ret; } #define WRITE_BUFFER_SIZE 8192 static unsigned char write_buffer[WRITE_BUFFER_SIZE]; static unsigned long write_buffer_len; static int ce_write_flush(SHA_CTX *context, int fd) { unsigned int buffered = write_buffer_len; if (buffered) { SHA1_Update(context, write_buffer, buffered); if (write(fd, write_buffer, buffered) != buffered) return -1; write_buffer_len = 0; } return 0; } static int ce_write(SHA_CTX *context, int fd, void *data, unsigned int len) { while (len) { unsigned int buffered = write_buffer_len; unsigned int partial = WRITE_BUFFER_SIZE - buffered; if (partial > len) partial = len; memcpy(write_buffer + buffered, data, partial); buffered += partial; if (buffered == WRITE_BUFFER_SIZE) { write_buffer_len = buffered; if (ce_write_flush(context, fd)) return -1; buffered = 0; } write_buffer_len = buffered; len -= partial; data = (char *) data + partial; } return 0; } static int write_index_ext_header(SHA_CTX *context, int fd, unsigned int ext, unsigned int sz) { ext = htonl(ext); sz = htonl(sz); return ((ce_write(context, fd, &ext, 4) < 0) || (ce_write(context, fd, &sz, 4) < 0)) ? -1 : 0; } static int ce_flush(SHA_CTX *context, int fd) { unsigned int left = write_buffer_len; if (left) { write_buffer_len = 0; SHA1_Update(context, write_buffer, left); } /* Flush first if not enough space for SHA1 signature */ if (left + 20 > WRITE_BUFFER_SIZE) { if (write(fd, write_buffer, left) != left) return -1; left = 0; } /* Append the SHA1 signature at the end */ SHA1_Final(write_buffer + left, context); left += 20; return (write(fd, write_buffer, left) != left) ? -1 : 0; } static void ce_smudge_racily_clean_entry(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_mtime match the index file mtime. */ struct stat st; if (lstat(ce->name, &st) < 0) return; if (ce_match_stat_basic(ce, &st)) return; if (ce_modified_check_fs(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_size = htonl(0); } } int write_cache(int newfd, struct cache_entry **cache, int entries) { SHA_CTX c; struct cache_header hdr; int i, removed; for (i = removed = 0; i < entries; i++) if (!cache[i]->ce_mode) removed++; hdr.hdr_signature = htonl(CACHE_SIGNATURE); hdr.hdr_version = htonl(2); hdr.hdr_entries = htonl(entries - removed); SHA1_Init(&c); if (ce_write(&c, newfd, &hdr, sizeof(hdr)) < 0) return -1; for (i = 0; i < entries; i++) { struct cache_entry *ce = cache[i]; if (!ce->ce_mode) continue; if (index_file_timestamp && index_file_timestamp <= ntohl(ce->ce_mtime.sec)) ce_smudge_racily_clean_entry(ce); if (ce_write(&c, newfd, ce, ce_size(ce)) < 0) return -1; } /* Write extension data here */ if (active_cache_tree) { unsigned long sz; void *data = cache_tree_write(active_cache_tree, &sz); if (data && !write_index_ext_header(&c, newfd, CACHE_EXT_TREE, sz) && !ce_write(&c, newfd, data, sz)) ; else { free(data); return -1; } } return ce_flush(&c, newfd); }