/* * GIT - The information manager from hell * * Copyright (C) Linus Torvalds, 2005 * * This handles basic git sha1 object files - packing, unpacking, * creation etc. */ #include "cache.h" #include "config.h" #include "string-list.h" #include "lockfile.h" #include "delta.h" #include "pack.h" #include "blob.h" #include "commit.h" #include "run-command.h" #include "tag.h" #include "tree.h" #include "tree-walk.h" #include "refs.h" #include "pack-revindex.h" #include "sha1-lookup.h" #include "bulk-checkin.h" #include "streaming.h" #include "dir.h" #include "mru.h" #include "list.h" #include "mergesort.h" #include "quote.h" #include "packfile.h" const unsigned char null_sha1[20]; const struct object_id null_oid; const struct object_id empty_tree_oid = { EMPTY_TREE_SHA1_BIN_LITERAL }; const struct object_id empty_blob_oid = { EMPTY_BLOB_SHA1_BIN_LITERAL }; /* * This is meant to hold a *small* number of objects that you would * want read_sha1_file() to be able to return, but yet you do not want * to write them into the object store (e.g. a browse-only * application). */ static struct cached_object { unsigned char sha1[20]; enum object_type type; void *buf; unsigned long size; } *cached_objects; static int cached_object_nr, cached_object_alloc; static struct cached_object empty_tree = { EMPTY_TREE_SHA1_BIN_LITERAL, OBJ_TREE, "", 0 }; static struct cached_object *find_cached_object(const unsigned char *sha1) { int i; struct cached_object *co = cached_objects; for (i = 0; i < cached_object_nr; i++, co++) { if (!hashcmp(co->sha1, sha1)) return co; } if (!hashcmp(sha1, empty_tree.sha1)) return &empty_tree; return NULL; } int mkdir_in_gitdir(const char *path) { if (mkdir(path, 0777)) { int saved_errno = errno; struct stat st; struct strbuf sb = STRBUF_INIT; if (errno != EEXIST) return -1; /* * Are we looking at a path in a symlinked worktree * whose original repository does not yet have it? * e.g. .git/rr-cache pointing at its original * repository in which the user hasn't performed any * conflict resolution yet? */ if (lstat(path, &st) || !S_ISLNK(st.st_mode) || strbuf_readlink(&sb, path, st.st_size) || !is_absolute_path(sb.buf) || mkdir(sb.buf, 0777)) { strbuf_release(&sb); errno = saved_errno; return -1; } strbuf_release(&sb); } return adjust_shared_perm(path); } enum scld_error safe_create_leading_directories(char *path) { char *next_component = path + offset_1st_component(path); enum scld_error ret = SCLD_OK; while (ret == SCLD_OK && next_component) { struct stat st; char *slash = next_component, slash_character; while (*slash && !is_dir_sep(*slash)) slash++; if (!*slash) break; next_component = slash + 1; while (is_dir_sep(*next_component)) next_component++; if (!*next_component) break; slash_character = *slash; *slash = '\0'; if (!stat(path, &st)) { /* path exists */ if (!S_ISDIR(st.st_mode)) { errno = ENOTDIR; ret = SCLD_EXISTS; } } else if (mkdir(path, 0777)) { if (errno == EEXIST && !stat(path, &st) && S_ISDIR(st.st_mode)) ; /* somebody created it since we checked */ else if (errno == ENOENT) /* * Either mkdir() failed because * somebody just pruned the containing * directory, or stat() failed because * the file that was in our way was * just removed. Either way, inform * the caller that it might be worth * trying again: */ ret = SCLD_VANISHED; else ret = SCLD_FAILED; } else if (adjust_shared_perm(path)) { ret = SCLD_PERMS; } *slash = slash_character; } return ret; } enum scld_error safe_create_leading_directories_const(const char *path) { int save_errno; /* path points to cache entries, so xstrdup before messing with it */ char *buf = xstrdup(path); enum scld_error result = safe_create_leading_directories(buf); save_errno = errno; free(buf); errno = save_errno; return result; } int raceproof_create_file(const char *path, create_file_fn fn, void *cb) { /* * The number of times we will try to remove empty directories * in the way of path. This is only 1 because if another * process is racily creating directories that conflict with * us, we don't want to fight against them. */ int remove_directories_remaining = 1; /* * The number of times that we will try to create the * directories containing path. We are willing to attempt this * more than once, because another process could be trying to * clean up empty directories at the same time as we are * trying to create them. */ int create_directories_remaining = 3; /* A scratch copy of path, filled lazily if we need it: */ struct strbuf path_copy = STRBUF_INIT; int ret, save_errno; /* Sanity check: */ assert(*path); retry_fn: ret = fn(path, cb); save_errno = errno; if (!ret) goto out; if (errno == EISDIR && remove_directories_remaining-- > 0) { /* * A directory is in the way. Maybe it is empty; try * to remove it: */ if (!path_copy.len) strbuf_addstr(&path_copy, path); if (!remove_dir_recursively(&path_copy, REMOVE_DIR_EMPTY_ONLY)) goto retry_fn; } else if (errno == ENOENT && create_directories_remaining-- > 0) { /* * Maybe the containing directory didn't exist, or * maybe it was just deleted by a process that is * racing with us to clean up empty directories. Try * to create it: */ enum scld_error scld_result; if (!path_copy.len) strbuf_addstr(&path_copy, path); do { scld_result = safe_create_leading_directories(path_copy.buf); if (scld_result == SCLD_OK) goto retry_fn; } while (scld_result == SCLD_VANISHED && create_directories_remaining-- > 0); } out: strbuf_release(&path_copy); errno = save_errno; return ret; } static void fill_sha1_path(struct strbuf *buf, const unsigned char *sha1) { int i; for (i = 0; i < 20; i++) { static char hex[] = "0123456789abcdef"; unsigned int val = sha1[i]; strbuf_addch(buf, hex[val >> 4]); strbuf_addch(buf, hex[val & 0xf]); if (!i) strbuf_addch(buf, '/'); } } const char *sha1_file_name(const unsigned char *sha1) { static struct strbuf buf = STRBUF_INIT; strbuf_reset(&buf); strbuf_addf(&buf, "%s/", get_object_directory()); fill_sha1_path(&buf, sha1); return buf.buf; } struct strbuf *alt_scratch_buf(struct alternate_object_database *alt) { strbuf_setlen(&alt->scratch, alt->base_len); return &alt->scratch; } static const char *alt_sha1_path(struct alternate_object_database *alt, const unsigned char *sha1) { struct strbuf *buf = alt_scratch_buf(alt); fill_sha1_path(buf, sha1); return buf->buf; } struct alternate_object_database *alt_odb_list; static struct alternate_object_database **alt_odb_tail; /* * Return non-zero iff the path is usable as an alternate object database. */ static int alt_odb_usable(struct strbuf *path, const char *normalized_objdir) { struct alternate_object_database *alt; /* Detect cases where alternate disappeared */ if (!is_directory(path->buf)) { error("object directory %s does not exist; " "check .git/objects/info/alternates.", path->buf); return 0; } /* * Prevent the common mistake of listing the same * thing twice, or object directory itself. */ for (alt = alt_odb_list; alt; alt = alt->next) { if (!fspathcmp(path->buf, alt->path)) return 0; } if (!fspathcmp(path->buf, normalized_objdir)) return 0; return 1; } /* * Prepare alternate object database registry. * * The variable alt_odb_list points at the list of struct * alternate_object_database. The elements on this list come from * non-empty elements from colon separated ALTERNATE_DB_ENVIRONMENT * environment variable, and $GIT_OBJECT_DIRECTORY/info/alternates, * whose contents is similar to that environment variable but can be * LF separated. Its base points at a statically allocated buffer that * contains "/the/directory/corresponding/to/.git/objects/...", while * its name points just after the slash at the end of ".git/objects/" * in the example above, and has enough space to hold 40-byte hex * SHA1, an extra slash for the first level indirection, and the * terminating NUL. */ static void read_info_alternates(const char * relative_base, int depth); static int link_alt_odb_entry(const char *entry, const char *relative_base, int depth, const char *normalized_objdir) { struct alternate_object_database *ent; struct strbuf pathbuf = STRBUF_INIT; if (!is_absolute_path(entry) && relative_base) { strbuf_realpath(&pathbuf, relative_base, 1); strbuf_addch(&pathbuf, '/'); } strbuf_addstr(&pathbuf, entry); if (strbuf_normalize_path(&pathbuf) < 0 && relative_base) { error("unable to normalize alternate object path: %s", pathbuf.buf); strbuf_release(&pathbuf); return -1; } /* * The trailing slash after the directory name is given by * this function at the end. Remove duplicates. */ while (pathbuf.len && pathbuf.buf[pathbuf.len - 1] == '/') strbuf_setlen(&pathbuf, pathbuf.len - 1); if (!alt_odb_usable(&pathbuf, normalized_objdir)) { strbuf_release(&pathbuf); return -1; } ent = alloc_alt_odb(pathbuf.buf); /* add the alternate entry */ *alt_odb_tail = ent; alt_odb_tail = &(ent->next); ent->next = NULL; /* recursively add alternates */ read_info_alternates(pathbuf.buf, depth + 1); strbuf_release(&pathbuf); return 0; } static const char *parse_alt_odb_entry(const char *string, int sep, struct strbuf *out) { const char *end; strbuf_reset(out); if (*string == '#') { /* comment; consume up to next separator */ end = strchrnul(string, sep); } else if (*string == '"' && !unquote_c_style(out, string, &end)) { /* * quoted path; unquote_c_style has copied the * data for us and set "end". Broken quoting (e.g., * an entry that doesn't end with a quote) falls * back to the unquoted case below. */ } else { /* normal, unquoted path */ end = strchrnul(string, sep); strbuf_add(out, string, end - string); } if (*end) end++; return end; } static void link_alt_odb_entries(const char *alt, int len, int sep, const char *relative_base, int depth) { struct strbuf objdirbuf = STRBUF_INIT; struct strbuf entry = STRBUF_INIT; if (depth > 5) { error("%s: ignoring alternate object stores, nesting too deep.", relative_base); return; } strbuf_add_absolute_path(&objdirbuf, get_object_directory()); if (strbuf_normalize_path(&objdirbuf) < 0) die("unable to normalize object directory: %s", objdirbuf.buf); while (*alt) { alt = parse_alt_odb_entry(alt, sep, &entry); if (!entry.len) continue; link_alt_odb_entry(entry.buf, relative_base, depth, objdirbuf.buf); } strbuf_release(&entry); strbuf_release(&objdirbuf); } static void read_info_alternates(const char * relative_base, int depth) { char *map; size_t mapsz; struct stat st; char *path; int fd; path = xstrfmt("%s/info/alternates", relative_base); fd = git_open(path); free(path); if (fd < 0) return; if (fstat(fd, &st) || (st.st_size == 0)) { close(fd); return; } mapsz = xsize_t(st.st_size); map = xmmap(NULL, mapsz, PROT_READ, MAP_PRIVATE, fd, 0); close(fd); link_alt_odb_entries(map, mapsz, '\n', relative_base, depth); munmap(map, mapsz); } struct alternate_object_database *alloc_alt_odb(const char *dir) { struct alternate_object_database *ent; FLEX_ALLOC_STR(ent, path, dir); strbuf_init(&ent->scratch, 0); strbuf_addf(&ent->scratch, "%s/", dir); ent->base_len = ent->scratch.len; return ent; } void add_to_alternates_file(const char *reference) { struct lock_file *lock = xcalloc(1, sizeof(struct lock_file)); char *alts = git_pathdup("objects/info/alternates"); FILE *in, *out; hold_lock_file_for_update(lock, alts, LOCK_DIE_ON_ERROR); out = fdopen_lock_file(lock, "w"); if (!out) die_errno("unable to fdopen alternates lockfile"); in = fopen(alts, "r"); if (in) { struct strbuf line = STRBUF_INIT; int found = 0; while (strbuf_getline(&line, in) != EOF) { if (!strcmp(reference, line.buf)) { found = 1; break; } fprintf_or_die(out, "%s\n", line.buf); } strbuf_release(&line); fclose(in); if (found) { rollback_lock_file(lock); lock = NULL; } } else if (errno != ENOENT) die_errno("unable to read alternates file"); if (lock) { fprintf_or_die(out, "%s\n", reference); if (commit_lock_file(lock)) die_errno("unable to move new alternates file into place"); if (alt_odb_tail) link_alt_odb_entries(reference, strlen(reference), '\n', NULL, 0); } free(alts); } void add_to_alternates_memory(const char *reference) { /* * Make sure alternates are initialized, or else our entry may be * overwritten when they are. */ prepare_alt_odb(); link_alt_odb_entries(reference, strlen(reference), '\n', NULL, 0); } /* * Compute the exact path an alternate is at and returns it. In case of * error NULL is returned and the human readable error is added to `err` * `path` may be relative and should point to $GITDIR. * `err` must not be null. */ char *compute_alternate_path(const char *path, struct strbuf *err) { char *ref_git = NULL; const char *repo, *ref_git_s; int seen_error = 0; ref_git_s = real_path_if_valid(path); if (!ref_git_s) { seen_error = 1; strbuf_addf(err, _("path '%s' does not exist"), path); goto out; } else /* * Beware: read_gitfile(), real_path() and mkpath() * return static buffer */ ref_git = xstrdup(ref_git_s); repo = read_gitfile(ref_git); if (!repo) repo = read_gitfile(mkpath("%s/.git", ref_git)); if (repo) { free(ref_git); ref_git = xstrdup(repo); } if (!repo && is_directory(mkpath("%s/.git/objects", ref_git))) { char *ref_git_git = mkpathdup("%s/.git", ref_git); free(ref_git); ref_git = ref_git_git; } else if (!is_directory(mkpath("%s/objects", ref_git))) { struct strbuf sb = STRBUF_INIT; seen_error = 1; if (get_common_dir(&sb, ref_git)) { strbuf_addf(err, _("reference repository '%s' as a linked " "checkout is not supported yet."), path); goto out; } strbuf_addf(err, _("reference repository '%s' is not a " "local repository."), path); goto out; } if (!access(mkpath("%s/shallow", ref_git), F_OK)) { strbuf_addf(err, _("reference repository '%s' is shallow"), path); seen_error = 1; goto out; } if (!access(mkpath("%s/info/grafts", ref_git), F_OK)) { strbuf_addf(err, _("reference repository '%s' is grafted"), path); seen_error = 1; goto out; } out: if (seen_error) { FREE_AND_NULL(ref_git); } return ref_git; } int foreach_alt_odb(alt_odb_fn fn, void *cb) { struct alternate_object_database *ent; int r = 0; prepare_alt_odb(); for (ent = alt_odb_list; ent; ent = ent->next) { r = fn(ent, cb); if (r) break; } return r; } void prepare_alt_odb(void) { const char *alt; if (alt_odb_tail) return; alt = getenv(ALTERNATE_DB_ENVIRONMENT); if (!alt) alt = ""; alt_odb_tail = &alt_odb_list; link_alt_odb_entries(alt, strlen(alt), PATH_SEP, NULL, 0); read_info_alternates(get_object_directory(), 0); } /* Returns 1 if we have successfully freshened the file, 0 otherwise. */ static int freshen_file(const char *fn) { struct utimbuf t; t.actime = t.modtime = time(NULL); return !utime(fn, &t); } /* * All of the check_and_freshen functions return 1 if the file exists and was * freshened (if freshening was requested), 0 otherwise. If they return * 0, you should not assume that it is safe to skip a write of the object (it * either does not exist on disk, or has a stale mtime and may be subject to * pruning). */ int check_and_freshen_file(const char *fn, int freshen) { if (access(fn, F_OK)) return 0; if (freshen && !freshen_file(fn)) return 0; return 1; } static int check_and_freshen_local(const unsigned char *sha1, int freshen) { return check_and_freshen_file(sha1_file_name(sha1), freshen); } static int check_and_freshen_nonlocal(const unsigned char *sha1, int freshen) { struct alternate_object_database *alt; prepare_alt_odb(); for (alt = alt_odb_list; alt; alt = alt->next) { const char *path = alt_sha1_path(alt, sha1); if (check_and_freshen_file(path, freshen)) return 1; } return 0; } static int check_and_freshen(const unsigned char *sha1, int freshen) { return check_and_freshen_local(sha1, freshen) || check_and_freshen_nonlocal(sha1, freshen); } int has_loose_object_nonlocal(const unsigned char *sha1) { return check_and_freshen_nonlocal(sha1, 0); } static int has_loose_object(const unsigned char *sha1) { return check_and_freshen(sha1, 0); } static void mmap_limit_check(size_t length) { static size_t limit = 0; if (!limit) { limit = git_env_ulong("GIT_MMAP_LIMIT", 0); if (!limit) limit = SIZE_MAX; } if (length > limit) die("attempting to mmap %"PRIuMAX" over limit %"PRIuMAX, (uintmax_t)length, (uintmax_t)limit); } void *xmmap_gently(void *start, size_t length, int prot, int flags, int fd, off_t offset) { void *ret; mmap_limit_check(length); ret = mmap(start, length, prot, flags, fd, offset); if (ret == MAP_FAILED) { if (!length) return NULL; release_pack_memory(length); ret = mmap(start, length, prot, flags, fd, offset); } return ret; } void *xmmap(void *start, size_t length, int prot, int flags, int fd, off_t offset) { void *ret = xmmap_gently(start, length, prot, flags, fd, offset); if (ret == MAP_FAILED) die_errno("mmap failed"); return ret; } static void mark_bad_packed_object(struct packed_git *p, const unsigned char *sha1) { unsigned i; for (i = 0; i < p->num_bad_objects; i++) if (!hashcmp(sha1, p->bad_object_sha1 + GIT_SHA1_RAWSZ * i)) return; p->bad_object_sha1 = xrealloc(p->bad_object_sha1, st_mult(GIT_MAX_RAWSZ, st_add(p->num_bad_objects, 1))); hashcpy(p->bad_object_sha1 + GIT_SHA1_RAWSZ * p->num_bad_objects, sha1); p->num_bad_objects++; } static const struct packed_git *has_packed_and_bad(const unsigned char *sha1) { struct packed_git *p; unsigned i; for (p = packed_git; p; p = p->next) for (i = 0; i < p->num_bad_objects; i++) if (!hashcmp(sha1, p->bad_object_sha1 + 20 * i)) return p; return NULL; } /* * With an in-core object data in "map", rehash it to make sure the * object name actually matches "sha1" to detect object corruption. * With "map" == NULL, try reading the object named with "sha1" using * the streaming interface and rehash it to do the same. */ int check_sha1_signature(const unsigned char *sha1, void *map, unsigned long size, const char *type) { unsigned char real_sha1[20]; enum object_type obj_type; struct git_istream *st; git_SHA_CTX c; char hdr[32]; int hdrlen; if (map) { hash_sha1_file(map, size, type, real_sha1); return hashcmp(sha1, real_sha1) ? -1 : 0; } st = open_istream(sha1, &obj_type, &size, NULL); if (!st) return -1; /* Generate the header */ hdrlen = xsnprintf(hdr, sizeof(hdr), "%s %lu", typename(obj_type), size) + 1; /* Sha1.. */ git_SHA1_Init(&c); git_SHA1_Update(&c, hdr, hdrlen); for (;;) { char buf[1024 * 16]; ssize_t readlen = read_istream(st, buf, sizeof(buf)); if (readlen < 0) { close_istream(st); return -1; } if (!readlen) break; git_SHA1_Update(&c, buf, readlen); } git_SHA1_Final(real_sha1, &c); close_istream(st); return hashcmp(sha1, real_sha1) ? -1 : 0; } int git_open_cloexec(const char *name, int flags) { int fd; static int o_cloexec = O_CLOEXEC; fd = open(name, flags | o_cloexec); if ((o_cloexec & O_CLOEXEC) && fd < 0 && errno == EINVAL) { /* Try again w/o O_CLOEXEC: the kernel might not support it */ o_cloexec &= ~O_CLOEXEC; fd = open(name, flags | o_cloexec); } #if defined(F_GETFD) && defined(F_SETFD) && defined(FD_CLOEXEC) { static int fd_cloexec = FD_CLOEXEC; if (!o_cloexec && 0 <= fd && fd_cloexec) { /* Opened w/o O_CLOEXEC? try with fcntl(2) to add it */ int flags = fcntl(fd, F_GETFD); if (fcntl(fd, F_SETFD, flags | fd_cloexec)) fd_cloexec = 0; } } #endif return fd; } /* * Find "sha1" as a loose object in the local repository or in an alternate. * Returns 0 on success, negative on failure. * * The "path" out-parameter will give the path of the object we found (if any). * Note that it may point to static storage and is only valid until another * call to sha1_file_name(), etc. */ static int stat_sha1_file(const unsigned char *sha1, struct stat *st, const char **path) { struct alternate_object_database *alt; *path = sha1_file_name(sha1); if (!lstat(*path, st)) return 0; prepare_alt_odb(); errno = ENOENT; for (alt = alt_odb_list; alt; alt = alt->next) { *path = alt_sha1_path(alt, sha1); if (!lstat(*path, st)) return 0; } return -1; } /* * Like stat_sha1_file(), but actually open the object and return the * descriptor. See the caveats on the "path" parameter above. */ static int open_sha1_file(const unsigned char *sha1, const char **path) { int fd; struct alternate_object_database *alt; int most_interesting_errno; *path = sha1_file_name(sha1); fd = git_open(*path); if (fd >= 0) return fd; most_interesting_errno = errno; prepare_alt_odb(); for (alt = alt_odb_list; alt; alt = alt->next) { *path = alt_sha1_path(alt, sha1); fd = git_open(*path); if (fd >= 0) return fd; if (most_interesting_errno == ENOENT) most_interesting_errno = errno; } errno = most_interesting_errno; return -1; } /* * Map the loose object at "path" if it is not NULL, or the path found by * searching for a loose object named "sha1". */ static void *map_sha1_file_1(const char *path, const unsigned char *sha1, unsigned long *size) { void *map; int fd; if (path) fd = git_open(path); else fd = open_sha1_file(sha1, &path); map = NULL; if (fd >= 0) { struct stat st; if (!fstat(fd, &st)) { *size = xsize_t(st.st_size); if (!*size) { /* mmap() is forbidden on empty files */ error("object file %s is empty", path); return NULL; } map = xmmap(NULL, *size, PROT_READ, MAP_PRIVATE, fd, 0); } close(fd); } return map; } void *map_sha1_file(const unsigned char *sha1, unsigned long *size) { return map_sha1_file_1(NULL, sha1, size); } static int unpack_sha1_short_header(git_zstream *stream, unsigned char *map, unsigned long mapsize, void *buffer, unsigned long bufsiz) { /* Get the data stream */ memset(stream, 0, sizeof(*stream)); stream->next_in = map; stream->avail_in = mapsize; stream->next_out = buffer; stream->avail_out = bufsiz; git_inflate_init(stream); return git_inflate(stream, 0); } int unpack_sha1_header(git_zstream *stream, unsigned char *map, unsigned long mapsize, void *buffer, unsigned long bufsiz) { int status = unpack_sha1_short_header(stream, map, mapsize, buffer, bufsiz); if (status < Z_OK) return status; /* Make sure we have the terminating NUL */ if (!memchr(buffer, '\0', stream->next_out - (unsigned char *)buffer)) return -1; return 0; } static int unpack_sha1_header_to_strbuf(git_zstream *stream, unsigned char *map, unsigned long mapsize, void *buffer, unsigned long bufsiz, struct strbuf *header) { int status; status = unpack_sha1_short_header(stream, map, mapsize, buffer, bufsiz); if (status < Z_OK) return -1; /* * Check if entire header is unpacked in the first iteration. */ if (memchr(buffer, '\0', stream->next_out - (unsigned char *)buffer)) return 0; /* * buffer[0..bufsiz] was not large enough. Copy the partial * result out to header, and then append the result of further * reading the stream. */ strbuf_add(header, buffer, stream->next_out - (unsigned char *)buffer); stream->next_out = buffer; stream->avail_out = bufsiz; do { status = git_inflate(stream, 0); strbuf_add(header, buffer, stream->next_out - (unsigned char *)buffer); if (memchr(buffer, '\0', stream->next_out - (unsigned char *)buffer)) return 0; stream->next_out = buffer; stream->avail_out = bufsiz; } while (status != Z_STREAM_END); return -1; } static void *unpack_sha1_rest(git_zstream *stream, void *buffer, unsigned long size, const unsigned char *sha1) { int bytes = strlen(buffer) + 1; unsigned char *buf = xmallocz(size); unsigned long n; int status = Z_OK; n = stream->total_out - bytes; if (n > size) n = size; memcpy(buf, (char *) buffer + bytes, n); bytes = n; if (bytes <= size) { /* * The above condition must be (bytes <= size), not * (bytes < size). In other words, even though we * expect no more output and set avail_out to zero, * the input zlib stream may have bytes that express * "this concludes the stream", and we *do* want to * eat that input. * * Otherwise we would not be able to test that we * consumed all the input to reach the expected size; * we also want to check that zlib tells us that all * went well with status == Z_STREAM_END at the end. */ stream->next_out = buf + bytes; stream->avail_out = size - bytes; while (status == Z_OK) status = git_inflate(stream, Z_FINISH); } if (status == Z_STREAM_END && !stream->avail_in) { git_inflate_end(stream); return buf; } if (status < 0) error("corrupt loose object '%s'", sha1_to_hex(sha1)); else if (stream->avail_in) error("garbage at end of loose object '%s'", sha1_to_hex(sha1)); free(buf); return NULL; } /* * We used to just use "sscanf()", but that's actually way * too permissive for what we want to check. So do an anal * object header parse by hand. */ static int parse_sha1_header_extended(const char *hdr, struct object_info *oi, unsigned int flags) { const char *type_buf = hdr; unsigned long size; int type, type_len = 0; /* * The type can be of any size but is followed by * a space. */ for (;;) { char c = *hdr++; if (!c) return -1; if (c == ' ') break; type_len++; } type = type_from_string_gently(type_buf, type_len, 1); if (oi->typename) strbuf_add(oi->typename, type_buf, type_len); /* * Set type to 0 if its an unknown object and * we're obtaining the type using '--allow-unknown-type' * option. */ if ((flags & OBJECT_INFO_ALLOW_UNKNOWN_TYPE) && (type < 0)) type = 0; else if (type < 0) die("invalid object type"); if (oi->typep) *oi->typep = type; /* * The length must follow immediately, and be in canonical * decimal format (ie "010" is not valid). */ size = *hdr++ - '0'; if (size > 9) return -1; if (size) { for (;;) { unsigned long c = *hdr - '0'; if (c > 9) break; hdr++; size = size * 10 + c; } } if (oi->sizep) *oi->sizep = size; /* * The length must be followed by a zero byte */ return *hdr ? -1 : type; } int parse_sha1_header(const char *hdr, unsigned long *sizep) { struct object_info oi = OBJECT_INFO_INIT; oi.sizep = sizep; return parse_sha1_header_extended(hdr, &oi, 0); } unsigned long get_size_from_delta(struct packed_git *p, struct pack_window **w_curs, off_t curpos) { const unsigned char *data; unsigned char delta_head[20], *in; git_zstream stream; int st; memset(&stream, 0, sizeof(stream)); stream.next_out = delta_head; stream.avail_out = sizeof(delta_head); git_inflate_init(&stream); do { in = use_pack(p, w_curs, curpos, &stream.avail_in); stream.next_in = in; st = git_inflate(&stream, Z_FINISH); curpos += stream.next_in - in; } while ((st == Z_OK || st == Z_BUF_ERROR) && stream.total_out < sizeof(delta_head)); git_inflate_end(&stream); if ((st != Z_STREAM_END) && stream.total_out != sizeof(delta_head)) { error("delta data unpack-initial failed"); return 0; } /* Examine the initial part of the delta to figure out * the result size. */ data = delta_head; /* ignore base size */ get_delta_hdr_size(&data, delta_head+sizeof(delta_head)); /* Read the result size */ return get_delta_hdr_size(&data, delta_head+sizeof(delta_head)); } static off_t get_delta_base(struct packed_git *p, struct pack_window **w_curs, off_t *curpos, enum object_type type, off_t delta_obj_offset) { unsigned char *base_info = use_pack(p, w_curs, *curpos, NULL); off_t base_offset; /* use_pack() assured us we have [base_info, base_info + 20) * as a range that we can look at without walking off the * end of the mapped window. Its actually the hash size * that is assured. An OFS_DELTA longer than the hash size * is stupid, as then a REF_DELTA would be smaller to store. */ if (type == OBJ_OFS_DELTA) { unsigned used = 0; unsigned char c = base_info[used++]; base_offset = c & 127; while (c & 128) { base_offset += 1; if (!base_offset || MSB(base_offset, 7)) return 0; /* overflow */ c = base_info[used++]; base_offset = (base_offset << 7) + (c & 127); } base_offset = delta_obj_offset - base_offset; if (base_offset <= 0 || base_offset >= delta_obj_offset) return 0; /* out of bound */ *curpos += used; } else if (type == OBJ_REF_DELTA) { /* The base entry _must_ be in the same pack */ base_offset = find_pack_entry_one(base_info, p); *curpos += 20; } else die("I am totally screwed"); return base_offset; } /* * Like get_delta_base above, but we return the sha1 instead of the pack * offset. This means it is cheaper for REF deltas (we do not have to do * the final object lookup), but more expensive for OFS deltas (we * have to load the revidx to convert the offset back into a sha1). */ static const unsigned char *get_delta_base_sha1(struct packed_git *p, struct pack_window **w_curs, off_t curpos, enum object_type type, off_t delta_obj_offset) { if (type == OBJ_REF_DELTA) { unsigned char *base = use_pack(p, w_curs, curpos, NULL); return base; } else if (type == OBJ_OFS_DELTA) { struct revindex_entry *revidx; off_t base_offset = get_delta_base(p, w_curs, &curpos, type, delta_obj_offset); if (!base_offset) return NULL; revidx = find_pack_revindex(p, base_offset); if (!revidx) return NULL; return nth_packed_object_sha1(p, revidx->nr); } else return NULL; } int unpack_object_header(struct packed_git *p, struct pack_window **w_curs, off_t *curpos, unsigned long *sizep) { unsigned char *base; unsigned long left; unsigned long used; enum object_type type; /* use_pack() assures us we have [base, base + 20) available * as a range that we can look at. (Its actually the hash * size that is assured.) With our object header encoding * the maximum deflated object size is 2^137, which is just * insane, so we know won't exceed what we have been given. */ base = use_pack(p, w_curs, *curpos, &left); used = unpack_object_header_buffer(base, left, &type, sizep); if (!used) { type = OBJ_BAD; } else *curpos += used; return type; } static int retry_bad_packed_offset(struct packed_git *p, off_t obj_offset) { int type; struct revindex_entry *revidx; const unsigned char *sha1; revidx = find_pack_revindex(p, obj_offset); if (!revidx) return OBJ_BAD; sha1 = nth_packed_object_sha1(p, revidx->nr); mark_bad_packed_object(p, sha1); type = sha1_object_info(sha1, NULL); if (type <= OBJ_NONE) return OBJ_BAD; return type; } #define POI_STACK_PREALLOC 64 static enum object_type packed_to_object_type(struct packed_git *p, off_t obj_offset, enum object_type type, struct pack_window **w_curs, off_t curpos) { off_t small_poi_stack[POI_STACK_PREALLOC]; off_t *poi_stack = small_poi_stack; int poi_stack_nr = 0, poi_stack_alloc = POI_STACK_PREALLOC; while (type == OBJ_OFS_DELTA || type == OBJ_REF_DELTA) { off_t base_offset; unsigned long size; /* Push the object we're going to leave behind */ if (poi_stack_nr >= poi_stack_alloc && poi_stack == small_poi_stack) { poi_stack_alloc = alloc_nr(poi_stack_nr); ALLOC_ARRAY(poi_stack, poi_stack_alloc); memcpy(poi_stack, small_poi_stack, sizeof(off_t)*poi_stack_nr); } else { ALLOC_GROW(poi_stack, poi_stack_nr+1, poi_stack_alloc); } poi_stack[poi_stack_nr++] = obj_offset; /* If parsing the base offset fails, just unwind */ base_offset = get_delta_base(p, w_curs, &curpos, type, obj_offset); if (!base_offset) goto unwind; curpos = obj_offset = base_offset; type = unpack_object_header(p, w_curs, &curpos, &size); if (type <= OBJ_NONE) { /* If getting the base itself fails, we first * retry the base, otherwise unwind */ type = retry_bad_packed_offset(p, base_offset); if (type > OBJ_NONE) goto out; goto unwind; } } switch (type) { case OBJ_BAD: case OBJ_COMMIT: case OBJ_TREE: case OBJ_BLOB: case OBJ_TAG: break; default: error("unknown object type %i at offset %"PRIuMAX" in %s", type, (uintmax_t)obj_offset, p->pack_name); type = OBJ_BAD; } out: if (poi_stack != small_poi_stack) free(poi_stack); return type; unwind: while (poi_stack_nr) { obj_offset = poi_stack[--poi_stack_nr]; type = retry_bad_packed_offset(p, obj_offset); if (type > OBJ_NONE) goto out; } type = OBJ_BAD; goto out; } static struct hashmap delta_base_cache; static size_t delta_base_cached; static LIST_HEAD(delta_base_cache_lru); struct delta_base_cache_key { struct packed_git *p; off_t base_offset; }; struct delta_base_cache_entry { struct hashmap hash; struct delta_base_cache_key key; struct list_head lru; void *data; unsigned long size; enum object_type type; }; static unsigned int pack_entry_hash(struct packed_git *p, off_t base_offset) { unsigned int hash; hash = (unsigned int)(intptr_t)p + (unsigned int)base_offset; hash += (hash >> 8) + (hash >> 16); return hash; } static struct delta_base_cache_entry * get_delta_base_cache_entry(struct packed_git *p, off_t base_offset) { struct hashmap_entry entry; struct delta_base_cache_key key; if (!delta_base_cache.cmpfn) return NULL; hashmap_entry_init(&entry, pack_entry_hash(p, base_offset)); key.p = p; key.base_offset = base_offset; return hashmap_get(&delta_base_cache, &entry, &key); } static int delta_base_cache_key_eq(const struct delta_base_cache_key *a, const struct delta_base_cache_key *b) { return a->p == b->p && a->base_offset == b->base_offset; } static int delta_base_cache_hash_cmp(const void *unused_cmp_data, const void *va, const void *vb, const void *vkey) { const struct delta_base_cache_entry *a = va, *b = vb; const struct delta_base_cache_key *key = vkey; if (key) return !delta_base_cache_key_eq(&a->key, key); else return !delta_base_cache_key_eq(&a->key, &b->key); } static int in_delta_base_cache(struct packed_git *p, off_t base_offset) { return !!get_delta_base_cache_entry(p, base_offset); } /* * Remove the entry from the cache, but do _not_ free the associated * entry data. The caller takes ownership of the "data" buffer, and * should copy out any fields it wants before detaching. */ static void detach_delta_base_cache_entry(struct delta_base_cache_entry *ent) { hashmap_remove(&delta_base_cache, ent, &ent->key); list_del(&ent->lru); delta_base_cached -= ent->size; free(ent); } static void *cache_or_unpack_entry(struct packed_git *p, off_t base_offset, unsigned long *base_size, enum object_type *type) { struct delta_base_cache_entry *ent; ent = get_delta_base_cache_entry(p, base_offset); if (!ent) return unpack_entry(p, base_offset, type, base_size); if (type) *type = ent->type; if (base_size) *base_size = ent->size; return xmemdupz(ent->data, ent->size); } static inline void release_delta_base_cache(struct delta_base_cache_entry *ent) { free(ent->data); detach_delta_base_cache_entry(ent); } void clear_delta_base_cache(void) { struct list_head *lru, *tmp; list_for_each_safe(lru, tmp, &delta_base_cache_lru) { struct delta_base_cache_entry *entry = list_entry(lru, struct delta_base_cache_entry, lru); release_delta_base_cache(entry); } } static void add_delta_base_cache(struct packed_git *p, off_t base_offset, void *base, unsigned long base_size, enum object_type type) { struct delta_base_cache_entry *ent = xmalloc(sizeof(*ent)); struct list_head *lru, *tmp; delta_base_cached += base_size; list_for_each_safe(lru, tmp, &delta_base_cache_lru) { struct delta_base_cache_entry *f = list_entry(lru, struct delta_base_cache_entry, lru); if (delta_base_cached <= delta_base_cache_limit) break; release_delta_base_cache(f); } ent->key.p = p; ent->key.base_offset = base_offset; ent->type = type; ent->data = base; ent->size = base_size; list_add_tail(&ent->lru, &delta_base_cache_lru); if (!delta_base_cache.cmpfn) hashmap_init(&delta_base_cache, delta_base_cache_hash_cmp, NULL, 0); hashmap_entry_init(ent, pack_entry_hash(p, base_offset)); hashmap_add(&delta_base_cache, ent); } int packed_object_info(struct packed_git *p, off_t obj_offset, struct object_info *oi) { struct pack_window *w_curs = NULL; unsigned long size; off_t curpos = obj_offset; enum object_type type; /* * We always get the representation type, but only convert it to * a "real" type later if the caller is interested. */ if (oi->contentp) { *oi->contentp = cache_or_unpack_entry(p, obj_offset, oi->sizep, &type); if (!*oi->contentp) type = OBJ_BAD; } else { type = unpack_object_header(p, &w_curs, &curpos, &size); } if (!oi->contentp && oi->sizep) { if (type == OBJ_OFS_DELTA || type == OBJ_REF_DELTA) { off_t tmp_pos = curpos; off_t base_offset = get_delta_base(p, &w_curs, &tmp_pos, type, obj_offset); if (!base_offset) { type = OBJ_BAD; goto out; } *oi->sizep = get_size_from_delta(p, &w_curs, tmp_pos); if (*oi->sizep == 0) { type = OBJ_BAD; goto out; } } else { *oi->sizep = size; } } if (oi->disk_sizep) { struct revindex_entry *revidx = find_pack_revindex(p, obj_offset); *oi->disk_sizep = revidx[1].offset - obj_offset; } if (oi->typep || oi->typename) { enum object_type ptot; ptot = packed_to_object_type(p, obj_offset, type, &w_curs, curpos); if (oi->typep) *oi->typep = ptot; if (oi->typename) { const char *tn = typename(ptot); if (tn) strbuf_addstr(oi->typename, tn); } if (ptot < 0) { type = OBJ_BAD; goto out; } } if (oi->delta_base_sha1) { if (type == OBJ_OFS_DELTA || type == OBJ_REF_DELTA) { const unsigned char *base; base = get_delta_base_sha1(p, &w_curs, curpos, type, obj_offset); if (!base) { type = OBJ_BAD; goto out; } hashcpy(oi->delta_base_sha1, base); } else hashclr(oi->delta_base_sha1); } oi->whence = in_delta_base_cache(p, obj_offset) ? OI_DBCACHED : OI_PACKED; out: unuse_pack(&w_curs); return type; } static void *unpack_compressed_entry(struct packed_git *p, struct pack_window **w_curs, off_t curpos, unsigned long size) { int st; git_zstream stream; unsigned char *buffer, *in; buffer = xmallocz_gently(size); if (!buffer) return NULL; memset(&stream, 0, sizeof(stream)); stream.next_out = buffer; stream.avail_out = size + 1; git_inflate_init(&stream); do { in = use_pack(p, w_curs, curpos, &stream.avail_in); stream.next_in = in; st = git_inflate(&stream, Z_FINISH); if (!stream.avail_out) break; /* the payload is larger than it should be */ curpos += stream.next_in - in; } while (st == Z_OK || st == Z_BUF_ERROR); git_inflate_end(&stream); if ((st != Z_STREAM_END) || stream.total_out != size) { free(buffer); return NULL; } return buffer; } static void *read_object(const unsigned char *sha1, enum object_type *type, unsigned long *size); static void write_pack_access_log(struct packed_git *p, off_t obj_offset) { static struct trace_key pack_access = TRACE_KEY_INIT(PACK_ACCESS); trace_printf_key(&pack_access, "%s %"PRIuMAX"\n", p->pack_name, (uintmax_t)obj_offset); } int do_check_packed_object_crc; #define UNPACK_ENTRY_STACK_PREALLOC 64 struct unpack_entry_stack_ent { off_t obj_offset; off_t curpos; unsigned long size; }; void *unpack_entry(struct packed_git *p, off_t obj_offset, enum object_type *final_type, unsigned long *final_size) { struct pack_window *w_curs = NULL; off_t curpos = obj_offset; void *data = NULL; unsigned long size; enum object_type type; struct unpack_entry_stack_ent small_delta_stack[UNPACK_ENTRY_STACK_PREALLOC]; struct unpack_entry_stack_ent *delta_stack = small_delta_stack; int delta_stack_nr = 0, delta_stack_alloc = UNPACK_ENTRY_STACK_PREALLOC; int base_from_cache = 0; write_pack_access_log(p, obj_offset); /* PHASE 1: drill down to the innermost base object */ for (;;) { off_t base_offset; int i; struct delta_base_cache_entry *ent; ent = get_delta_base_cache_entry(p, curpos); if (ent) { type = ent->type; data = ent->data; size = ent->size; detach_delta_base_cache_entry(ent); base_from_cache = 1; break; } if (do_check_packed_object_crc && p->index_version > 1) { struct revindex_entry *revidx = find_pack_revindex(p, obj_offset); off_t len = revidx[1].offset - obj_offset; if (check_pack_crc(p, &w_curs, obj_offset, len, revidx->nr)) { const unsigned char *sha1 = nth_packed_object_sha1(p, revidx->nr); error("bad packed object CRC for %s", sha1_to_hex(sha1)); mark_bad_packed_object(p, sha1); data = NULL; goto out; } } type = unpack_object_header(p, &w_curs, &curpos, &size); if (type != OBJ_OFS_DELTA && type != OBJ_REF_DELTA) break; base_offset = get_delta_base(p, &w_curs, &curpos, type, obj_offset); if (!base_offset) { error("failed to validate delta base reference " "at offset %"PRIuMAX" from %s", (uintmax_t)curpos, p->pack_name); /* bail to phase 2, in hopes of recovery */ data = NULL; break; } /* push object, proceed to base */ if (delta_stack_nr >= delta_stack_alloc && delta_stack == small_delta_stack) { delta_stack_alloc = alloc_nr(delta_stack_nr); ALLOC_ARRAY(delta_stack, delta_stack_alloc); memcpy(delta_stack, small_delta_stack, sizeof(*delta_stack)*delta_stack_nr); } else { ALLOC_GROW(delta_stack, delta_stack_nr+1, delta_stack_alloc); } i = delta_stack_nr++; delta_stack[i].obj_offset = obj_offset; delta_stack[i].curpos = curpos; delta_stack[i].size = size; curpos = obj_offset = base_offset; } /* PHASE 2: handle the base */ switch (type) { case OBJ_OFS_DELTA: case OBJ_REF_DELTA: if (data) die("BUG: unpack_entry: left loop at a valid delta"); break; case OBJ_COMMIT: case OBJ_TREE: case OBJ_BLOB: case OBJ_TAG: if (!base_from_cache) data = unpack_compressed_entry(p, &w_curs, curpos, size); break; default: data = NULL; error("unknown object type %i at offset %"PRIuMAX" in %s", type, (uintmax_t)obj_offset, p->pack_name); } /* PHASE 3: apply deltas in order */ /* invariants: * 'data' holds the base data, or NULL if there was corruption */ while (delta_stack_nr) { void *delta_data; void *base = data; void *external_base = NULL; unsigned long delta_size, base_size = size; int i; data = NULL; if (base) add_delta_base_cache(p, obj_offset, base, base_size, type); if (!base) { /* * We're probably in deep shit, but let's try to fetch * the required base anyway from another pack or loose. * This is costly but should happen only in the presence * of a corrupted pack, and is better than failing outright. */ struct revindex_entry *revidx; const unsigned char *base_sha1; revidx = find_pack_revindex(p, obj_offset); if (revidx) { base_sha1 = nth_packed_object_sha1(p, revidx->nr); error("failed to read delta base object %s" " at offset %"PRIuMAX" from %s", sha1_to_hex(base_sha1), (uintmax_t)obj_offset, p->pack_name); mark_bad_packed_object(p, base_sha1); base = read_object(base_sha1, &type, &base_size); external_base = base; } } i = --delta_stack_nr; obj_offset = delta_stack[i].obj_offset; curpos = delta_stack[i].curpos; delta_size = delta_stack[i].size; if (!base) continue; delta_data = unpack_compressed_entry(p, &w_curs, curpos, delta_size); if (!delta_data) { error("failed to unpack compressed delta " "at offset %"PRIuMAX" from %s", (uintmax_t)curpos, p->pack_name); data = NULL; free(external_base); continue; } data = patch_delta(base, base_size, delta_data, delta_size, &size); /* * We could not apply the delta; warn the user, but keep going. * Our failure will be noticed either in the next iteration of * the loop, or if this is the final delta, in the caller when * we return NULL. Those code paths will take care of making * a more explicit warning and retrying with another copy of * the object. */ if (!data) error("failed to apply delta"); free(delta_data); free(external_base); } if (final_type) *final_type = type; if (final_size) *final_size = size; out: unuse_pack(&w_curs); if (delta_stack != small_delta_stack) free(delta_stack); return data; } const unsigned char *nth_packed_object_sha1(struct packed_git *p, uint32_t n) { const unsigned char *index = p->index_data; if (!index) { if (open_pack_index(p)) return NULL; index = p->index_data; } if (n >= p->num_objects) return NULL; index += 4 * 256; if (p->index_version == 1) { return index + 24 * n + 4; } else { index += 8; return index + 20 * n; } } const struct object_id *nth_packed_object_oid(struct object_id *oid, struct packed_git *p, uint32_t n) { const unsigned char *hash = nth_packed_object_sha1(p, n); if (!hash) return NULL; hashcpy(oid->hash, hash); return oid; } void check_pack_index_ptr(const struct packed_git *p, const void *vptr) { const unsigned char *ptr = vptr; const unsigned char *start = p->index_data; const unsigned char *end = start + p->index_size; if (ptr < start) die(_("offset before start of pack index for %s (corrupt index?)"), p->pack_name); /* No need to check for underflow; .idx files must be at least 8 bytes */ if (ptr >= end - 8) die(_("offset beyond end of pack index for %s (truncated index?)"), p->pack_name); } off_t nth_packed_object_offset(const struct packed_git *p, uint32_t n) { const unsigned char *index = p->index_data; index += 4 * 256; if (p->index_version == 1) { return ntohl(*((uint32_t *)(index + 24 * n))); } else { uint32_t off; index += 8 + p->num_objects * (20 + 4); off = ntohl(*((uint32_t *)(index + 4 * n))); if (!(off & 0x80000000)) return off; index += p->num_objects * 4 + (off & 0x7fffffff) * 8; check_pack_index_ptr(p, index); return (((uint64_t)ntohl(*((uint32_t *)(index + 0)))) << 32) | ntohl(*((uint32_t *)(index + 4))); } } off_t find_pack_entry_one(const unsigned char *sha1, struct packed_git *p) { const uint32_t *level1_ofs = p->index_data; const unsigned char *index = p->index_data; unsigned hi, lo, stride; static int debug_lookup = -1; if (debug_lookup < 0) debug_lookup = !!getenv("GIT_DEBUG_LOOKUP"); if (!index) { if (open_pack_index(p)) return 0; level1_ofs = p->index_data; index = p->index_data; } if (p->index_version > 1) { level1_ofs += 2; index += 8; } index += 4 * 256; hi = ntohl(level1_ofs[*sha1]); lo = ((*sha1 == 0x0) ? 0 : ntohl(level1_ofs[*sha1 - 1])); if (p->index_version > 1) { stride = 20; } else { stride = 24; index += 4; } if (debug_lookup) printf("%02x%02x%02x... lo %u hi %u nr %"PRIu32"\n", sha1[0], sha1[1], sha1[2], lo, hi, p->num_objects); while (lo < hi) { unsigned mi = (lo + hi) / 2; int cmp = hashcmp(index + mi * stride, sha1); if (debug_lookup) printf("lo %u hi %u rg %u mi %u\n", lo, hi, hi - lo, mi); if (!cmp) return nth_packed_object_offset(p, mi); if (cmp > 0) hi = mi; else lo = mi+1; } return 0; } int is_pack_valid(struct packed_git *p) { /* An already open pack is known to be valid. */ if (p->pack_fd != -1) return 1; /* If the pack has one window completely covering the * file size, the pack is known to be valid even if * the descriptor is not currently open. */ if (p->windows) { struct pack_window *w = p->windows; if (!w->offset && w->len == p->pack_size) return 1; } /* Force the pack to open to prove its valid. */ return !open_packed_git(p); } static int fill_pack_entry(const unsigned char *sha1, struct pack_entry *e, struct packed_git *p) { off_t offset; if (p->num_bad_objects) { unsigned i; for (i = 0; i < p->num_bad_objects; i++) if (!hashcmp(sha1, p->bad_object_sha1 + 20 * i)) return 0; } offset = find_pack_entry_one(sha1, p); if (!offset) return 0; /* * We are about to tell the caller where they can locate the * requested object. We better make sure the packfile is * still here and can be accessed before supplying that * answer, as it may have been deleted since the index was * loaded! */ if (!is_pack_valid(p)) return 0; e->offset = offset; e->p = p; hashcpy(e->sha1, sha1); return 1; } /* * Iff a pack file contains the object named by sha1, return true and * store its location to e. */ static int find_pack_entry(const unsigned char *sha1, struct pack_entry *e) { struct mru_entry *p; prepare_packed_git(); if (!packed_git) return 0; for (p = packed_git_mru->head; p; p = p->next) { if (fill_pack_entry(sha1, e, p->item)) { mru_mark(packed_git_mru, p); return 1; } } return 0; } struct packed_git *find_sha1_pack(const unsigned char *sha1, struct packed_git *packs) { struct packed_git *p; for (p = packs; p; p = p->next) { if (find_pack_entry_one(sha1, p)) return p; } return NULL; } static int sha1_loose_object_info(const unsigned char *sha1, struct object_info *oi, int flags) { int status = 0; unsigned long mapsize; void *map; git_zstream stream; char hdr[32]; struct strbuf hdrbuf = STRBUF_INIT; unsigned long size_scratch; if (oi->delta_base_sha1) hashclr(oi->delta_base_sha1); /* * If we don't care about type or size, then we don't * need to look inside the object at all. Note that we * do not optimize out the stat call, even if the * caller doesn't care about the disk-size, since our * return value implicitly indicates whether the * object even exists. */ if (!oi->typep && !oi->typename && !oi->sizep && !oi->contentp) { const char *path; struct stat st; if (stat_sha1_file(sha1, &st, &path) < 0) return -1; if (oi->disk_sizep) *oi->disk_sizep = st.st_size; return 0; } map = map_sha1_file(sha1, &mapsize); if (!map) return -1; if (!oi->sizep) oi->sizep = &size_scratch; if (oi->disk_sizep) *oi->disk_sizep = mapsize; if ((flags & OBJECT_INFO_ALLOW_UNKNOWN_TYPE)) { if (unpack_sha1_header_to_strbuf(&stream, map, mapsize, hdr, sizeof(hdr), &hdrbuf) < 0) status = error("unable to unpack %s header with --allow-unknown-type", sha1_to_hex(sha1)); } else if (unpack_sha1_header(&stream, map, mapsize, hdr, sizeof(hdr)) < 0) status = error("unable to unpack %s header", sha1_to_hex(sha1)); if (status < 0) ; /* Do nothing */ else if (hdrbuf.len) { if ((status = parse_sha1_header_extended(hdrbuf.buf, oi, flags)) < 0) status = error("unable to parse %s header with --allow-unknown-type", sha1_to_hex(sha1)); } else if ((status = parse_sha1_header_extended(hdr, oi, flags)) < 0) status = error("unable to parse %s header", sha1_to_hex(sha1)); if (status >= 0 && oi->contentp) *oi->contentp = unpack_sha1_rest(&stream, hdr, *oi->sizep, sha1); else git_inflate_end(&stream); munmap(map, mapsize); if (status && oi->typep) *oi->typep = status; if (oi->sizep == &size_scratch) oi->sizep = NULL; strbuf_release(&hdrbuf); oi->whence = OI_LOOSE; return (status < 0) ? status : 0; } int sha1_object_info_extended(const unsigned char *sha1, struct object_info *oi, unsigned flags) { static struct object_info blank_oi = OBJECT_INFO_INIT; struct pack_entry e; int rtype; const unsigned char *real = (flags & OBJECT_INFO_LOOKUP_REPLACE) ? lookup_replace_object(sha1) : sha1; if (!oi) oi = &blank_oi; if (!(flags & OBJECT_INFO_SKIP_CACHED)) { struct cached_object *co = find_cached_object(real); if (co) { if (oi->typep) *(oi->typep) = co->type; if (oi->sizep) *(oi->sizep) = co->size; if (oi->disk_sizep) *(oi->disk_sizep) = 0; if (oi->delta_base_sha1) hashclr(oi->delta_base_sha1); if (oi->typename) strbuf_addstr(oi->typename, typename(co->type)); if (oi->contentp) *oi->contentp = xmemdupz(co->buf, co->size); oi->whence = OI_CACHED; return 0; } } if (!find_pack_entry(real, &e)) { /* Most likely it's a loose object. */ if (!sha1_loose_object_info(real, oi, flags)) return 0; /* Not a loose object; someone else may have just packed it. */ if (flags & OBJECT_INFO_QUICK) { return -1; } else { reprepare_packed_git(); if (!find_pack_entry(real, &e)) return -1; } } if (oi == &blank_oi) /* * We know that the caller doesn't actually need the * information below, so return early. */ return 0; rtype = packed_object_info(e.p, e.offset, oi); if (rtype < 0) { mark_bad_packed_object(e.p, real); return sha1_object_info_extended(real, oi, 0); } else if (oi->whence == OI_PACKED) { oi->u.packed.offset = e.offset; oi->u.packed.pack = e.p; oi->u.packed.is_delta = (rtype == OBJ_REF_DELTA || rtype == OBJ_OFS_DELTA); } return 0; } /* returns enum object_type or negative */ int sha1_object_info(const unsigned char *sha1, unsigned long *sizep) { enum object_type type; struct object_info oi = OBJECT_INFO_INIT; oi.typep = &type; oi.sizep = sizep; if (sha1_object_info_extended(sha1, &oi, OBJECT_INFO_LOOKUP_REPLACE) < 0) return -1; return type; } int pretend_sha1_file(void *buf, unsigned long len, enum object_type type, unsigned char *sha1) { struct cached_object *co; hash_sha1_file(buf, len, typename(type), sha1); if (has_sha1_file(sha1) || find_cached_object(sha1)) return 0; ALLOC_GROW(cached_objects, cached_object_nr + 1, cached_object_alloc); co = &cached_objects[cached_object_nr++]; co->size = len; co->type = type; co->buf = xmalloc(len); memcpy(co->buf, buf, len); hashcpy(co->sha1, sha1); return 0; } static void *read_object(const unsigned char *sha1, enum object_type *type, unsigned long *size) { struct object_info oi = OBJECT_INFO_INIT; void *content; oi.typep = type; oi.sizep = size; oi.contentp = &content; if (sha1_object_info_extended(sha1, &oi, 0) < 0) return NULL; return content; } /* * This function dies on corrupt objects; the callers who want to * deal with them should arrange to call read_object() and give error * messages themselves. */ void *read_sha1_file_extended(const unsigned char *sha1, enum object_type *type, unsigned long *size, int lookup_replace) { void *data; const struct packed_git *p; const char *path; struct stat st; const unsigned char *repl = lookup_replace ? lookup_replace_object(sha1) : sha1; errno = 0; data = read_object(repl, type, size); if (data) return data; if (errno && errno != ENOENT) die_errno("failed to read object %s", sha1_to_hex(sha1)); /* die if we replaced an object with one that does not exist */ if (repl != sha1) die("replacement %s not found for %s", sha1_to_hex(repl), sha1_to_hex(sha1)); if (!stat_sha1_file(repl, &st, &path)) die("loose object %s (stored in %s) is corrupt", sha1_to_hex(repl), path); if ((p = has_packed_and_bad(repl)) != NULL) die("packed object %s (stored in %s) is corrupt", sha1_to_hex(repl), p->pack_name); return NULL; } void *read_object_with_reference(const unsigned char *sha1, const char *required_type_name, unsigned long *size, unsigned char *actual_sha1_return) { enum object_type type, required_type; void *buffer; unsigned long isize; unsigned char actual_sha1[20]; required_type = type_from_string(required_type_name); hashcpy(actual_sha1, sha1); while (1) { int ref_length = -1; const char *ref_type = NULL; buffer = read_sha1_file(actual_sha1, &type, &isize); if (!buffer) return NULL; if (type == required_type) { *size = isize; if (actual_sha1_return) hashcpy(actual_sha1_return, actual_sha1); return buffer; } /* Handle references */ else if (type == OBJ_COMMIT) ref_type = "tree "; else if (type == OBJ_TAG) ref_type = "object "; else { free(buffer); return NULL; } ref_length = strlen(ref_type); if (ref_length + 40 > isize || memcmp(buffer, ref_type, ref_length) || get_sha1_hex((char *) buffer + ref_length, actual_sha1)) { free(buffer); return NULL; } free(buffer); /* Now we have the ID of the referred-to object in * actual_sha1. Check again. */ } } static void write_sha1_file_prepare(const void *buf, unsigned long len, const char *type, unsigned char *sha1, char *hdr, int *hdrlen) { git_SHA_CTX c; /* Generate the header */ *hdrlen = xsnprintf(hdr, *hdrlen, "%s %lu", type, len)+1; /* Sha1.. */ git_SHA1_Init(&c); git_SHA1_Update(&c, hdr, *hdrlen); git_SHA1_Update(&c, buf, len); git_SHA1_Final(sha1, &c); } /* * Move the just written object into its final resting place. */ int finalize_object_file(const char *tmpfile, const char *filename) { int ret = 0; if (object_creation_mode == OBJECT_CREATION_USES_RENAMES) goto try_rename; else if (link(tmpfile, filename)) ret = errno; /* * Coda hack - coda doesn't like cross-directory links, * so we fall back to a rename, which will mean that it * won't be able to check collisions, but that's not a * big deal. * * The same holds for FAT formatted media. * * When this succeeds, we just return. We have nothing * left to unlink. */ if (ret && ret != EEXIST) { try_rename: if (!rename(tmpfile, filename)) goto out; ret = errno; } unlink_or_warn(tmpfile); if (ret) { if (ret != EEXIST) { return error_errno("unable to write sha1 filename %s", filename); } /* FIXME!!! Collision check here ? */ } out: if (adjust_shared_perm(filename)) return error("unable to set permission to '%s'", filename); return 0; } static int write_buffer(int fd, const void *buf, size_t len) { if (write_in_full(fd, buf, len) < 0) return error_errno("file write error"); return 0; } int hash_sha1_file(const void *buf, unsigned long len, const char *type, unsigned char *sha1) { char hdr[32]; int hdrlen = sizeof(hdr); write_sha1_file_prepare(buf, len, type, sha1, hdr, &hdrlen); return 0; } /* Finalize a file on disk, and close it. */ static void close_sha1_file(int fd) { if (fsync_object_files) fsync_or_die(fd, "sha1 file"); if (close(fd) != 0) die_errno("error when closing sha1 file"); } /* Size of directory component, including the ending '/' */ static inline int directory_size(const char *filename) { const char *s = strrchr(filename, '/'); if (!s) return 0; return s - filename + 1; } /* * This creates a temporary file in the same directory as the final * 'filename' * * We want to avoid cross-directory filename renames, because those * can have problems on various filesystems (FAT, NFS, Coda). */ static int create_tmpfile(struct strbuf *tmp, const char *filename) { int fd, dirlen = directory_size(filename); strbuf_reset(tmp); strbuf_add(tmp, filename, dirlen); strbuf_addstr(tmp, "tmp_obj_XXXXXX"); fd = git_mkstemp_mode(tmp->buf, 0444); if (fd < 0 && dirlen && errno == ENOENT) { /* * Make sure the directory exists; note that the contents * of the buffer are undefined after mkstemp returns an * error, so we have to rewrite the whole buffer from * scratch. */ strbuf_reset(tmp); strbuf_add(tmp, filename, dirlen - 1); if (mkdir(tmp->buf, 0777) && errno != EEXIST) return -1; if (adjust_shared_perm(tmp->buf)) return -1; /* Try again */ strbuf_addstr(tmp, "/tmp_obj_XXXXXX"); fd = git_mkstemp_mode(tmp->buf, 0444); } return fd; } static int write_loose_object(const unsigned char *sha1, char *hdr, int hdrlen, const void *buf, unsigned long len, time_t mtime) { int fd, ret; unsigned char compressed[4096]; git_zstream stream; git_SHA_CTX c; unsigned char parano_sha1[20]; static struct strbuf tmp_file = STRBUF_INIT; const char *filename = sha1_file_name(sha1); fd = create_tmpfile(&tmp_file, filename); if (fd < 0) { if (errno == EACCES) return error("insufficient permission for adding an object to repository database %s", get_object_directory()); else return error_errno("unable to create temporary file"); } /* Set it up */ git_deflate_init(&stream, zlib_compression_level); stream.next_out = compressed; stream.avail_out = sizeof(compressed); git_SHA1_Init(&c); /* First header.. */ stream.next_in = (unsigned char *)hdr; stream.avail_in = hdrlen; while (git_deflate(&stream, 0) == Z_OK) ; /* nothing */ git_SHA1_Update(&c, hdr, hdrlen); /* Then the data itself.. */ stream.next_in = (void *)buf; stream.avail_in = len; do { unsigned char *in0 = stream.next_in; ret = git_deflate(&stream, Z_FINISH); git_SHA1_Update(&c, in0, stream.next_in - in0); if (write_buffer(fd, compressed, stream.next_out - compressed) < 0) die("unable to write sha1 file"); stream.next_out = compressed; stream.avail_out = sizeof(compressed); } while (ret == Z_OK); if (ret != Z_STREAM_END) die("unable to deflate new object %s (%d)", sha1_to_hex(sha1), ret); ret = git_deflate_end_gently(&stream); if (ret != Z_OK) die("deflateEnd on object %s failed (%d)", sha1_to_hex(sha1), ret); git_SHA1_Final(parano_sha1, &c); if (hashcmp(sha1, parano_sha1) != 0) die("confused by unstable object source data for %s", sha1_to_hex(sha1)); close_sha1_file(fd); if (mtime) { struct utimbuf utb; utb.actime = mtime; utb.modtime = mtime; if (utime(tmp_file.buf, &utb) < 0) warning_errno("failed utime() on %s", tmp_file.buf); } return finalize_object_file(tmp_file.buf, filename); } static int freshen_loose_object(const unsigned char *sha1) { return check_and_freshen(sha1, 1); } static int freshen_packed_object(const unsigned char *sha1) { struct pack_entry e; if (!find_pack_entry(sha1, &e)) return 0; if (e.p->freshened) return 1; if (!freshen_file(e.p->pack_name)) return 0; e.p->freshened = 1; return 1; } int write_sha1_file(const void *buf, unsigned long len, const char *type, unsigned char *sha1) { char hdr[32]; int hdrlen = sizeof(hdr); /* Normally if we have it in the pack then we do not bother writing * it out into .git/objects/??/?{38} file. */ write_sha1_file_prepare(buf, len, type, sha1, hdr, &hdrlen); if (freshen_packed_object(sha1) || freshen_loose_object(sha1)) return 0; return write_loose_object(sha1, hdr, hdrlen, buf, len, 0); } int hash_sha1_file_literally(const void *buf, unsigned long len, const char *type, unsigned char *sha1, unsigned flags) { char *header; int hdrlen, status = 0; /* type string, SP, %lu of the length plus NUL must fit this */ hdrlen = strlen(type) + 32; header = xmalloc(hdrlen); write_sha1_file_prepare(buf, len, type, sha1, header, &hdrlen); if (!(flags & HASH_WRITE_OBJECT)) goto cleanup; if (freshen_packed_object(sha1) || freshen_loose_object(sha1)) goto cleanup; status = write_loose_object(sha1, header, hdrlen, buf, len, 0); cleanup: free(header); return status; } int force_object_loose(const unsigned char *sha1, time_t mtime) { void *buf; unsigned long len; enum object_type type; char hdr[32]; int hdrlen; int ret; if (has_loose_object(sha1)) return 0; buf = read_object(sha1, &type, &len); if (!buf) return error("cannot read sha1_file for %s", sha1_to_hex(sha1)); hdrlen = xsnprintf(hdr, sizeof(hdr), "%s %lu", typename(type), len) + 1; ret = write_loose_object(sha1, hdr, hdrlen, buf, len, mtime); free(buf); return ret; } int has_pack_index(const unsigned char *sha1) { struct stat st; if (stat(sha1_pack_index_name(sha1), &st)) return 0; return 1; } int has_sha1_pack(const unsigned char *sha1) { struct pack_entry e; return find_pack_entry(sha1, &e); } int has_sha1_file_with_flags(const unsigned char *sha1, int flags) { if (!startup_info->have_repository) return 0; return sha1_object_info_extended(sha1, NULL, flags | OBJECT_INFO_SKIP_CACHED) >= 0; } int has_object_file(const struct object_id *oid) { return has_sha1_file(oid->hash); } int has_object_file_with_flags(const struct object_id *oid, int flags) { return has_sha1_file_with_flags(oid->hash, flags); } static void check_tree(const void *buf, size_t size) { struct tree_desc desc; struct name_entry entry; init_tree_desc(&desc, buf, size); while (tree_entry(&desc, &entry)) /* do nothing * tree_entry() will die() on malformed entries */ ; } static void check_commit(const void *buf, size_t size) { struct commit c; memset(&c, 0, sizeof(c)); if (parse_commit_buffer(&c, buf, size)) die("corrupt commit"); } static void check_tag(const void *buf, size_t size) { struct tag t; memset(&t, 0, sizeof(t)); if (parse_tag_buffer(&t, buf, size)) die("corrupt tag"); } static int index_mem(unsigned char *sha1, void *buf, size_t size, enum object_type type, const char *path, unsigned flags) { int ret, re_allocated = 0; int write_object = flags & HASH_WRITE_OBJECT; if (!type) type = OBJ_BLOB; /* * Convert blobs to git internal format */ if ((type == OBJ_BLOB) && path) { struct strbuf nbuf = STRBUF_INIT; if (convert_to_git(&the_index, path, buf, size, &nbuf, write_object ? safe_crlf : SAFE_CRLF_FALSE)) { buf = strbuf_detach(&nbuf, &size); re_allocated = 1; } } if (flags & HASH_FORMAT_CHECK) { if (type == OBJ_TREE) check_tree(buf, size); if (type == OBJ_COMMIT) check_commit(buf, size); if (type == OBJ_TAG) check_tag(buf, size); } if (write_object) ret = write_sha1_file(buf, size, typename(type), sha1); else ret = hash_sha1_file(buf, size, typename(type), sha1); if (re_allocated) free(buf); return ret; } static int index_stream_convert_blob(unsigned char *sha1, int fd, const char *path, unsigned flags) { int ret; const int write_object = flags & HASH_WRITE_OBJECT; struct strbuf sbuf = STRBUF_INIT; assert(path); assert(would_convert_to_git_filter_fd(path)); convert_to_git_filter_fd(&the_index, path, fd, &sbuf, write_object ? safe_crlf : SAFE_CRLF_FALSE); if (write_object) ret = write_sha1_file(sbuf.buf, sbuf.len, typename(OBJ_BLOB), sha1); else ret = hash_sha1_file(sbuf.buf, sbuf.len, typename(OBJ_BLOB), sha1); strbuf_release(&sbuf); return ret; } static int index_pipe(unsigned char *sha1, int fd, enum object_type type, const char *path, unsigned flags) { struct strbuf sbuf = STRBUF_INIT; int ret; if (strbuf_read(&sbuf, fd, 4096) >= 0) ret = index_mem(sha1, sbuf.buf, sbuf.len, type, path, flags); else ret = -1; strbuf_release(&sbuf); return ret; } #define SMALL_FILE_SIZE (32*1024) static int index_core(unsigned char *sha1, int fd, size_t size, enum object_type type, const char *path, unsigned flags) { int ret; if (!size) { ret = index_mem(sha1, "", size, type, path, flags); } else if (size <= SMALL_FILE_SIZE) { char *buf = xmalloc(size); if (size == read_in_full(fd, buf, size)) ret = index_mem(sha1, buf, size, type, path, flags); else ret = error_errno("short read"); free(buf); } else { void *buf = xmmap(NULL, size, PROT_READ, MAP_PRIVATE, fd, 0); ret = index_mem(sha1, buf, size, type, path, flags); munmap(buf, size); } return ret; } /* * This creates one packfile per large blob unless bulk-checkin * machinery is "plugged". * * This also bypasses the usual "convert-to-git" dance, and that is on * purpose. We could write a streaming version of the converting * functions and insert that before feeding the data to fast-import * (or equivalent in-core API described above). However, that is * somewhat complicated, as we do not know the size of the filter * result, which we need to know beforehand when writing a git object. * Since the primary motivation for trying to stream from the working * tree file and to avoid mmaping it in core is to deal with large * binary blobs, they generally do not want to get any conversion, and * callers should avoid this code path when filters are requested. */ static int index_stream(unsigned char *sha1, int fd, size_t size, enum object_type type, const char *path, unsigned flags) { return index_bulk_checkin(sha1, fd, size, type, path, flags); } int index_fd(unsigned char *sha1, int fd, struct stat *st, enum object_type type, const char *path, unsigned flags) { int ret; /* * Call xsize_t() only when needed to avoid potentially unnecessary * die() for large files. */ if (type == OBJ_BLOB && path && would_convert_to_git_filter_fd(path)) ret = index_stream_convert_blob(sha1, fd, path, flags); else if (!S_ISREG(st->st_mode)) ret = index_pipe(sha1, fd, type, path, flags); else if (st->st_size <= big_file_threshold || type != OBJ_BLOB || (path && would_convert_to_git(&the_index, path))) ret = index_core(sha1, fd, xsize_t(st->st_size), type, path, flags); else ret = index_stream(sha1, fd, xsize_t(st->st_size), type, path, flags); close(fd); return ret; } int index_path(unsigned char *sha1, const char *path, struct stat *st, unsigned flags) { int fd; struct strbuf sb = STRBUF_INIT; switch (st->st_mode & S_IFMT) { case S_IFREG: fd = open(path, O_RDONLY); if (fd < 0) return error_errno("open(\"%s\")", path); if (index_fd(sha1, fd, st, OBJ_BLOB, path, flags) < 0) return error("%s: failed to insert into database", path); break; case S_IFLNK: if (strbuf_readlink(&sb, path, st->st_size)) return error_errno("readlink(\"%s\")", path); if (!(flags & HASH_WRITE_OBJECT)) hash_sha1_file(sb.buf, sb.len, blob_type, sha1); else if (write_sha1_file(sb.buf, sb.len, blob_type, sha1)) return error("%s: failed to insert into database", path); strbuf_release(&sb); break; case S_IFDIR: return resolve_gitlink_ref(path, "HEAD", sha1); default: return error("%s: unsupported file type", path); } return 0; } int read_pack_header(int fd, struct pack_header *header) { if (read_in_full(fd, header, sizeof(*header)) < sizeof(*header)) /* "eof before pack header was fully read" */ return PH_ERROR_EOF; if (header->hdr_signature != htonl(PACK_SIGNATURE)) /* "protocol error (pack signature mismatch detected)" */ return PH_ERROR_PACK_SIGNATURE; if (!pack_version_ok(header->hdr_version)) /* "protocol error (pack version unsupported)" */ return PH_ERROR_PROTOCOL; return 0; } void assert_sha1_type(const unsigned char *sha1, enum object_type expect) { enum object_type type = sha1_object_info(sha1, NULL); if (type < 0) die("%s is not a valid object", sha1_to_hex(sha1)); if (type != expect) die("%s is not a valid '%s' object", sha1_to_hex(sha1), typename(expect)); } int for_each_file_in_obj_subdir(unsigned int subdir_nr, struct strbuf *path, each_loose_object_fn obj_cb, each_loose_cruft_fn cruft_cb, each_loose_subdir_fn subdir_cb, void *data) { size_t origlen, baselen; DIR *dir; struct dirent *de; int r = 0; if (subdir_nr > 0xff) BUG("invalid loose object subdirectory: %x", subdir_nr); origlen = path->len; strbuf_complete(path, '/'); strbuf_addf(path, "%02x", subdir_nr); baselen = path->len; dir = opendir(path->buf); if (!dir) { if (errno != ENOENT) r = error_errno("unable to open %s", path->buf); strbuf_setlen(path, origlen); return r; } while ((de = readdir(dir))) { if (is_dot_or_dotdot(de->d_name)) continue; strbuf_setlen(path, baselen); strbuf_addf(path, "/%s", de->d_name); if (strlen(de->d_name) == GIT_SHA1_HEXSZ - 2) { char hex[GIT_MAX_HEXSZ+1]; struct object_id oid; xsnprintf(hex, sizeof(hex), "%02x%s", subdir_nr, de->d_name); if (!get_oid_hex(hex, &oid)) { if (obj_cb) { r = obj_cb(&oid, path->buf, data); if (r) break; } continue; } } if (cruft_cb) { r = cruft_cb(de->d_name, path->buf, data); if (r) break; } } closedir(dir); strbuf_setlen(path, baselen); if (!r && subdir_cb) r = subdir_cb(subdir_nr, path->buf, data); strbuf_setlen(path, origlen); return r; } int for_each_loose_file_in_objdir_buf(struct strbuf *path, each_loose_object_fn obj_cb, each_loose_cruft_fn cruft_cb, each_loose_subdir_fn subdir_cb, void *data) { int r = 0; int i; for (i = 0; i < 256; i++) { r = for_each_file_in_obj_subdir(i, path, obj_cb, cruft_cb, subdir_cb, data); if (r) break; } return r; } int for_each_loose_file_in_objdir(const char *path, each_loose_object_fn obj_cb, each_loose_cruft_fn cruft_cb, each_loose_subdir_fn subdir_cb, void *data) { struct strbuf buf = STRBUF_INIT; int r; strbuf_addstr(&buf, path); r = for_each_loose_file_in_objdir_buf(&buf, obj_cb, cruft_cb, subdir_cb, data); strbuf_release(&buf); return r; } struct loose_alt_odb_data { each_loose_object_fn *cb; void *data; }; static int loose_from_alt_odb(struct alternate_object_database *alt, void *vdata) { struct loose_alt_odb_data *data = vdata; struct strbuf buf = STRBUF_INIT; int r; strbuf_addstr(&buf, alt->path); r = for_each_loose_file_in_objdir_buf(&buf, data->cb, NULL, NULL, data->data); strbuf_release(&buf); return r; } int for_each_loose_object(each_loose_object_fn cb, void *data, unsigned flags) { struct loose_alt_odb_data alt; int r; r = for_each_loose_file_in_objdir(get_object_directory(), cb, NULL, NULL, data); if (r) return r; if (flags & FOR_EACH_OBJECT_LOCAL_ONLY) return 0; alt.cb = cb; alt.data = data; return foreach_alt_odb(loose_from_alt_odb, &alt); } static int for_each_object_in_pack(struct packed_git *p, each_packed_object_fn cb, void *data) { uint32_t i; int r = 0; for (i = 0; i < p->num_objects; i++) { struct object_id oid; if (!nth_packed_object_oid(&oid, p, i)) return error("unable to get sha1 of object %u in %s", i, p->pack_name); r = cb(&oid, p, i, data); if (r) break; } return r; } int for_each_packed_object(each_packed_object_fn cb, void *data, unsigned flags) { struct packed_git *p; int r = 0; int pack_errors = 0; prepare_packed_git(); for (p = packed_git; p; p = p->next) { if ((flags & FOR_EACH_OBJECT_LOCAL_ONLY) && !p->pack_local) continue; if (open_pack_index(p)) { pack_errors = 1; continue; } r = for_each_object_in_pack(p, cb, data); if (r) break; } return r ? r : pack_errors; } static int check_stream_sha1(git_zstream *stream, const char *hdr, unsigned long size, const char *path, const unsigned char *expected_sha1) { git_SHA_CTX c; unsigned char real_sha1[GIT_MAX_RAWSZ]; unsigned char buf[4096]; unsigned long total_read; int status = Z_OK; git_SHA1_Init(&c); git_SHA1_Update(&c, hdr, stream->total_out); /* * We already read some bytes into hdr, but the ones up to the NUL * do not count against the object's content size. */ total_read = stream->total_out - strlen(hdr) - 1; /* * This size comparison must be "<=" to read the final zlib packets; * see the comment in unpack_sha1_rest for details. */ while (total_read <= size && (status == Z_OK || status == Z_BUF_ERROR)) { stream->next_out = buf; stream->avail_out = sizeof(buf); if (size - total_read < stream->avail_out) stream->avail_out = size - total_read; status = git_inflate(stream, Z_FINISH); git_SHA1_Update(&c, buf, stream->next_out - buf); total_read += stream->next_out - buf; } git_inflate_end(stream); if (status != Z_STREAM_END) { error("corrupt loose object '%s'", sha1_to_hex(expected_sha1)); return -1; } if (stream->avail_in) { error("garbage at end of loose object '%s'", sha1_to_hex(expected_sha1)); return -1; } git_SHA1_Final(real_sha1, &c); if (hashcmp(expected_sha1, real_sha1)) { error("sha1 mismatch for %s (expected %s)", path, sha1_to_hex(expected_sha1)); return -1; } return 0; } int read_loose_object(const char *path, const unsigned char *expected_sha1, enum object_type *type, unsigned long *size, void **contents) { int ret = -1; void *map = NULL; unsigned long mapsize; git_zstream stream; char hdr[32]; *contents = NULL; map = map_sha1_file_1(path, NULL, &mapsize); if (!map) { error_errno("unable to mmap %s", path); goto out; } if (unpack_sha1_header(&stream, map, mapsize, hdr, sizeof(hdr)) < 0) { error("unable to unpack header of %s", path); goto out; } *type = parse_sha1_header(hdr, size); if (*type < 0) { error("unable to parse header of %s", path); git_inflate_end(&stream); goto out; } if (*type == OBJ_BLOB) { if (check_stream_sha1(&stream, hdr, *size, path, expected_sha1) < 0) goto out; } else { *contents = unpack_sha1_rest(&stream, hdr, *size, expected_sha1); if (!*contents) { error("unable to unpack contents of %s", path); git_inflate_end(&stream); goto out; } if (check_sha1_signature(expected_sha1, *contents, *size, typename(*type))) { error("sha1 mismatch for %s (expected %s)", path, sha1_to_hex(expected_sha1)); free(*contents); goto out; } } ret = 0; /* everything checks out */ out: if (map) munmap(map, mapsize); return ret; }