#include "builtin.h" #include "config.h" #include "delta.h" #include "pack.h" #include "csum-file.h" #include "blob.h" #include "commit.h" #include "tag.h" #include "tree.h" #include "progress.h" #include "fsck.h" #include "exec-cmd.h" #include "streaming.h" #include "thread-utils.h" #include "packfile.h" #include "object-store.h" #include "promisor-remote.h" static const char index_pack_usage[] = "git index-pack [-v] [-o ] [--keep | --keep=] [--[no-]rev-index] [--verify] [--strict] ( | --stdin [--fix-thin] [])"; struct object_entry { struct pack_idx_entry idx; unsigned long size; unsigned char hdr_size; signed char type; signed char real_type; }; struct object_stat { unsigned delta_depth; int base_object_no; }; struct base_data { /* Initialized by make_base(). */ struct base_data *base; struct object_entry *obj; int ref_first, ref_last; int ofs_first, ofs_last; /* * Threads should increment retain_data if they are about to call * patch_delta() using this struct's data as a base, and decrement this * when they are done. While retain_data is nonzero, this struct's data * will not be freed even if the delta base cache limit is exceeded. */ int retain_data; /* * The number of direct children that have not been fully processed * (entered work_head, entered done_head, left done_head). When this * number reaches zero, this struct base_data can be freed. */ int children_remaining; /* Not initialized by make_base(). */ struct list_head list; void *data; unsigned long size; }; /* * Stack of struct base_data that have unprocessed children. * threaded_second_pass() uses this as a source of work (the other being the * objects array). * * Guarded by work_mutex. */ static LIST_HEAD(work_head); /* * Stack of struct base_data that have children, all of whom have been * processed or are being processed, and at least one child is being processed. * These struct base_data must be kept around until the last child is * processed. * * Guarded by work_mutex. */ static LIST_HEAD(done_head); /* * All threads share one delta base cache. * * base_cache_used is guarded by work_mutex, and base_cache_limit is read-only * in a thread. */ static size_t base_cache_used; static size_t base_cache_limit; struct thread_local { pthread_t thread; int pack_fd; }; /* Remember to update object flag allocation in object.h */ #define FLAG_LINK (1u<<20) #define FLAG_CHECKED (1u<<21) struct ofs_delta_entry { off_t offset; int obj_no; }; struct ref_delta_entry { struct object_id oid; int obj_no; }; static struct object_entry *objects; static struct object_stat *obj_stat; static struct ofs_delta_entry *ofs_deltas; static struct ref_delta_entry *ref_deltas; static struct thread_local nothread_data; static int nr_objects; static int nr_ofs_deltas; static int nr_ref_deltas; static int ref_deltas_alloc; static int nr_resolved_deltas; static int nr_threads; static int from_stdin; static int strict; static int do_fsck_object; static struct fsck_options fsck_options = FSCK_OPTIONS_MISSING_GITMODULES; static int verbose; static int show_resolving_progress; static int show_stat; static int check_self_contained_and_connected; static struct progress *progress; /* We always read in 4kB chunks. */ static unsigned char input_buffer[4096]; static unsigned int input_offset, input_len; static off_t consumed_bytes; static off_t max_input_size; static unsigned deepest_delta; static git_hash_ctx input_ctx; static uint32_t input_crc32; static int input_fd, output_fd; static const char *curr_pack; static struct thread_local *thread_data; static int nr_dispatched; static int threads_active; static pthread_mutex_t read_mutex; #define read_lock() lock_mutex(&read_mutex) #define read_unlock() unlock_mutex(&read_mutex) static pthread_mutex_t counter_mutex; #define counter_lock() lock_mutex(&counter_mutex) #define counter_unlock() unlock_mutex(&counter_mutex) static pthread_mutex_t work_mutex; #define work_lock() lock_mutex(&work_mutex) #define work_unlock() unlock_mutex(&work_mutex) static pthread_mutex_t deepest_delta_mutex; #define deepest_delta_lock() lock_mutex(&deepest_delta_mutex) #define deepest_delta_unlock() unlock_mutex(&deepest_delta_mutex) static pthread_key_t key; static inline void lock_mutex(pthread_mutex_t *mutex) { if (threads_active) pthread_mutex_lock(mutex); } static inline void unlock_mutex(pthread_mutex_t *mutex) { if (threads_active) pthread_mutex_unlock(mutex); } /* * Mutex and conditional variable can't be statically-initialized on Windows. */ static void init_thread(void) { int i; init_recursive_mutex(&read_mutex); pthread_mutex_init(&counter_mutex, NULL); pthread_mutex_init(&work_mutex, NULL); if (show_stat) pthread_mutex_init(&deepest_delta_mutex, NULL); pthread_key_create(&key, NULL); thread_data = xcalloc(nr_threads, sizeof(*thread_data)); for (i = 0; i < nr_threads; i++) { thread_data[i].pack_fd = open(curr_pack, O_RDONLY); if (thread_data[i].pack_fd == -1) die_errno(_("unable to open %s"), curr_pack); } threads_active = 1; } static void cleanup_thread(void) { int i; if (!threads_active) return; threads_active = 0; pthread_mutex_destroy(&read_mutex); pthread_mutex_destroy(&counter_mutex); pthread_mutex_destroy(&work_mutex); if (show_stat) pthread_mutex_destroy(&deepest_delta_mutex); for (i = 0; i < nr_threads; i++) close(thread_data[i].pack_fd); pthread_key_delete(key); free(thread_data); } static int mark_link(struct object *obj, enum object_type type, void *data, struct fsck_options *options) { if (!obj) return -1; if (type != OBJ_ANY && obj->type != type) die(_("object type mismatch at %s"), oid_to_hex(&obj->oid)); obj->flags |= FLAG_LINK; return 0; } /* The content of each linked object must have been checked or it must be already present in the object database */ static unsigned check_object(struct object *obj) { if (!obj) return 0; if (!(obj->flags & FLAG_LINK)) return 0; if (!(obj->flags & FLAG_CHECKED)) { unsigned long size; int type = oid_object_info(the_repository, &obj->oid, &size); if (type <= 0) die(_("did not receive expected object %s"), oid_to_hex(&obj->oid)); if (type != obj->type) die(_("object %s: expected type %s, found %s"), oid_to_hex(&obj->oid), type_name(obj->type), type_name(type)); obj->flags |= FLAG_CHECKED; return 1; } return 0; } static unsigned check_objects(void) { unsigned i, max, foreign_nr = 0; max = get_max_object_index(); if (verbose) progress = start_delayed_progress(_("Checking objects"), max); for (i = 0; i < max; i++) { foreign_nr += check_object(get_indexed_object(i)); display_progress(progress, i + 1); } stop_progress(&progress); return foreign_nr; } /* Discard current buffer used content. */ static void flush(void) { if (input_offset) { if (output_fd >= 0) write_or_die(output_fd, input_buffer, input_offset); the_hash_algo->update_fn(&input_ctx, input_buffer, input_offset); memmove(input_buffer, input_buffer + input_offset, input_len); input_offset = 0; } } /* * Make sure at least "min" bytes are available in the buffer, and * return the pointer to the buffer. */ static void *fill(int min) { if (min <= input_len) return input_buffer + input_offset; if (min > sizeof(input_buffer)) die(Q_("cannot fill %d byte", "cannot fill %d bytes", min), min); flush(); do { ssize_t ret = xread(input_fd, input_buffer + input_len, sizeof(input_buffer) - input_len); if (ret <= 0) { if (!ret) die(_("early EOF")); die_errno(_("read error on input")); } input_len += ret; if (from_stdin) display_throughput(progress, consumed_bytes + input_len); } while (input_len < min); return input_buffer; } static void use(int bytes) { if (bytes > input_len) die(_("used more bytes than were available")); input_crc32 = crc32(input_crc32, input_buffer + input_offset, bytes); input_len -= bytes; input_offset += bytes; /* make sure off_t is sufficiently large not to wrap */ if (signed_add_overflows(consumed_bytes, bytes)) die(_("pack too large for current definition of off_t")); consumed_bytes += bytes; if (max_input_size && consumed_bytes > max_input_size) die(_("pack exceeds maximum allowed size")); } static const char *open_pack_file(const char *pack_name) { if (from_stdin) { input_fd = 0; if (!pack_name) { struct strbuf tmp_file = STRBUF_INIT; output_fd = odb_mkstemp(&tmp_file, "pack/tmp_pack_XXXXXX"); pack_name = strbuf_detach(&tmp_file, NULL); } else { output_fd = open(pack_name, O_CREAT|O_EXCL|O_RDWR, 0600); if (output_fd < 0) die_errno(_("unable to create '%s'"), pack_name); } nothread_data.pack_fd = output_fd; } else { input_fd = open(pack_name, O_RDONLY); if (input_fd < 0) die_errno(_("cannot open packfile '%s'"), pack_name); output_fd = -1; nothread_data.pack_fd = input_fd; } the_hash_algo->init_fn(&input_ctx); return pack_name; } static void parse_pack_header(void) { struct pack_header *hdr = fill(sizeof(struct pack_header)); /* Header consistency check */ if (hdr->hdr_signature != htonl(PACK_SIGNATURE)) die(_("pack signature mismatch")); if (!pack_version_ok(hdr->hdr_version)) die(_("pack version %"PRIu32" unsupported"), ntohl(hdr->hdr_version)); nr_objects = ntohl(hdr->hdr_entries); use(sizeof(struct pack_header)); } static NORETURN void bad_object(off_t offset, const char *format, ...) __attribute__((format (printf, 2, 3))); static NORETURN void bad_object(off_t offset, const char *format, ...) { va_list params; char buf[1024]; va_start(params, format); vsnprintf(buf, sizeof(buf), format, params); va_end(params); die(_("pack has bad object at offset %"PRIuMAX": %s"), (uintmax_t)offset, buf); } static inline struct thread_local *get_thread_data(void) { if (HAVE_THREADS) { if (threads_active) return pthread_getspecific(key); assert(!threads_active && "This should only be reached when all threads are gone"); } return ¬hread_data; } static void set_thread_data(struct thread_local *data) { if (threads_active) pthread_setspecific(key, data); } static void free_base_data(struct base_data *c) { if (c->data) { FREE_AND_NULL(c->data); base_cache_used -= c->size; } } static void prune_base_data(struct base_data *retain) { struct list_head *pos; if (base_cache_used <= base_cache_limit) return; list_for_each_prev(pos, &done_head) { struct base_data *b = list_entry(pos, struct base_data, list); if (b->retain_data || b == retain) continue; if (b->data) { free_base_data(b); if (base_cache_used <= base_cache_limit) return; } } list_for_each_prev(pos, &work_head) { struct base_data *b = list_entry(pos, struct base_data, list); if (b->retain_data || b == retain) continue; if (b->data) { free_base_data(b); if (base_cache_used <= base_cache_limit) return; } } } static int is_delta_type(enum object_type type) { return (type == OBJ_REF_DELTA || type == OBJ_OFS_DELTA); } static void *unpack_entry_data(off_t offset, unsigned long size, enum object_type type, struct object_id *oid) { static char fixed_buf[8192]; int status; git_zstream stream; void *buf; git_hash_ctx c; char hdr[32]; int hdrlen; if (!is_delta_type(type)) { hdrlen = xsnprintf(hdr, sizeof(hdr), "%s %"PRIuMAX, type_name(type),(uintmax_t)size) + 1; the_hash_algo->init_fn(&c); the_hash_algo->update_fn(&c, hdr, hdrlen); } else oid = NULL; if (type == OBJ_BLOB && size > big_file_threshold) buf = fixed_buf; else buf = xmallocz(size); memset(&stream, 0, sizeof(stream)); git_inflate_init(&stream); stream.next_out = buf; stream.avail_out = buf == fixed_buf ? sizeof(fixed_buf) : size; do { unsigned char *last_out = stream.next_out; stream.next_in = fill(1); stream.avail_in = input_len; status = git_inflate(&stream, 0); use(input_len - stream.avail_in); if (oid) the_hash_algo->update_fn(&c, last_out, stream.next_out - last_out); if (buf == fixed_buf) { stream.next_out = buf; stream.avail_out = sizeof(fixed_buf); } } while (status == Z_OK); if (stream.total_out != size || status != Z_STREAM_END) bad_object(offset, _("inflate returned %d"), status); git_inflate_end(&stream); if (oid) the_hash_algo->final_fn(oid->hash, &c); return buf == fixed_buf ? NULL : buf; } static void *unpack_raw_entry(struct object_entry *obj, off_t *ofs_offset, struct object_id *ref_oid, struct object_id *oid) { unsigned char *p; unsigned long size, c; off_t base_offset; unsigned shift; void *data; obj->idx.offset = consumed_bytes; input_crc32 = crc32(0, NULL, 0); p = fill(1); c = *p; use(1); obj->type = (c >> 4) & 7; size = (c & 15); shift = 4; while (c & 0x80) { p = fill(1); c = *p; use(1); size += (c & 0x7f) << shift; shift += 7; } obj->size = size; switch (obj->type) { case OBJ_REF_DELTA: hashcpy(ref_oid->hash, fill(the_hash_algo->rawsz)); use(the_hash_algo->rawsz); break; case OBJ_OFS_DELTA: p = fill(1); c = *p; use(1); base_offset = c & 127; while (c & 128) { base_offset += 1; if (!base_offset || MSB(base_offset, 7)) bad_object(obj->idx.offset, _("offset value overflow for delta base object")); p = fill(1); c = *p; use(1); base_offset = (base_offset << 7) + (c & 127); } *ofs_offset = obj->idx.offset - base_offset; if (*ofs_offset <= 0 || *ofs_offset >= obj->idx.offset) bad_object(obj->idx.offset, _("delta base offset is out of bound")); break; case OBJ_COMMIT: case OBJ_TREE: case OBJ_BLOB: case OBJ_TAG: break; default: bad_object(obj->idx.offset, _("unknown object type %d"), obj->type); } obj->hdr_size = consumed_bytes - obj->idx.offset; data = unpack_entry_data(obj->idx.offset, obj->size, obj->type, oid); obj->idx.crc32 = input_crc32; return data; } static void *unpack_data(struct object_entry *obj, int (*consume)(const unsigned char *, unsigned long, void *), void *cb_data) { off_t from = obj[0].idx.offset + obj[0].hdr_size; off_t len = obj[1].idx.offset - from; unsigned char *data, *inbuf; git_zstream stream; int status; data = xmallocz(consume ? 64*1024 : obj->size); inbuf = xmalloc((len < 64*1024) ? (int)len : 64*1024); memset(&stream, 0, sizeof(stream)); git_inflate_init(&stream); stream.next_out = data; stream.avail_out = consume ? 64*1024 : obj->size; do { ssize_t n = (len < 64*1024) ? (ssize_t)len : 64*1024; n = xpread(get_thread_data()->pack_fd, inbuf, n, from); if (n < 0) die_errno(_("cannot pread pack file")); if (!n) die(Q_("premature end of pack file, %"PRIuMAX" byte missing", "premature end of pack file, %"PRIuMAX" bytes missing", (unsigned int)len), (uintmax_t)len); from += n; len -= n; stream.next_in = inbuf; stream.avail_in = n; if (!consume) status = git_inflate(&stream, 0); else { do { status = git_inflate(&stream, 0); if (consume(data, stream.next_out - data, cb_data)) { free(inbuf); free(data); return NULL; } stream.next_out = data; stream.avail_out = 64*1024; } while (status == Z_OK && stream.avail_in); } } while (len && status == Z_OK && !stream.avail_in); /* This has been inflated OK when first encountered, so... */ if (status != Z_STREAM_END || stream.total_out != obj->size) die(_("serious inflate inconsistency")); git_inflate_end(&stream); free(inbuf); if (consume) { FREE_AND_NULL(data); } return data; } static void *get_data_from_pack(struct object_entry *obj) { return unpack_data(obj, NULL, NULL); } static int compare_ofs_delta_bases(off_t offset1, off_t offset2, enum object_type type1, enum object_type type2) { int cmp = type1 - type2; if (cmp) return cmp; return offset1 < offset2 ? -1 : offset1 > offset2 ? 1 : 0; } static int find_ofs_delta(const off_t offset) { int first = 0, last = nr_ofs_deltas; while (first < last) { int next = first + (last - first) / 2; struct ofs_delta_entry *delta = &ofs_deltas[next]; int cmp; cmp = compare_ofs_delta_bases(offset, delta->offset, OBJ_OFS_DELTA, objects[delta->obj_no].type); if (!cmp) return next; if (cmp < 0) { last = next; continue; } first = next+1; } return -first-1; } static void find_ofs_delta_children(off_t offset, int *first_index, int *last_index) { int first = find_ofs_delta(offset); int last = first; int end = nr_ofs_deltas - 1; if (first < 0) { *first_index = 0; *last_index = -1; return; } while (first > 0 && ofs_deltas[first - 1].offset == offset) --first; while (last < end && ofs_deltas[last + 1].offset == offset) ++last; *first_index = first; *last_index = last; } static int compare_ref_delta_bases(const struct object_id *oid1, const struct object_id *oid2, enum object_type type1, enum object_type type2) { int cmp = type1 - type2; if (cmp) return cmp; return oidcmp(oid1, oid2); } static int find_ref_delta(const struct object_id *oid) { int first = 0, last = nr_ref_deltas; while (first < last) { int next = first + (last - first) / 2; struct ref_delta_entry *delta = &ref_deltas[next]; int cmp; cmp = compare_ref_delta_bases(oid, &delta->oid, OBJ_REF_DELTA, objects[delta->obj_no].type); if (!cmp) return next; if (cmp < 0) { last = next; continue; } first = next+1; } return -first-1; } static void find_ref_delta_children(const struct object_id *oid, int *first_index, int *last_index) { int first = find_ref_delta(oid); int last = first; int end = nr_ref_deltas - 1; if (first < 0) { *first_index = 0; *last_index = -1; return; } while (first > 0 && oideq(&ref_deltas[first - 1].oid, oid)) --first; while (last < end && oideq(&ref_deltas[last + 1].oid, oid)) ++last; *first_index = first; *last_index = last; } struct compare_data { struct object_entry *entry; struct git_istream *st; unsigned char *buf; unsigned long buf_size; }; static int compare_objects(const unsigned char *buf, unsigned long size, void *cb_data) { struct compare_data *data = cb_data; if (data->buf_size < size) { free(data->buf); data->buf = xmalloc(size); data->buf_size = size; } while (size) { ssize_t len = read_istream(data->st, data->buf, size); if (len == 0) die(_("SHA1 COLLISION FOUND WITH %s !"), oid_to_hex(&data->entry->idx.oid)); if (len < 0) die(_("unable to read %s"), oid_to_hex(&data->entry->idx.oid)); if (memcmp(buf, data->buf, len)) die(_("SHA1 COLLISION FOUND WITH %s !"), oid_to_hex(&data->entry->idx.oid)); size -= len; buf += len; } return 0; } static int check_collison(struct object_entry *entry) { struct compare_data data; enum object_type type; unsigned long size; if (entry->size <= big_file_threshold || entry->type != OBJ_BLOB) return -1; memset(&data, 0, sizeof(data)); data.entry = entry; data.st = open_istream(the_repository, &entry->idx.oid, &type, &size, NULL); if (!data.st) return -1; if (size != entry->size || type != entry->type) die(_("SHA1 COLLISION FOUND WITH %s !"), oid_to_hex(&entry->idx.oid)); unpack_data(entry, compare_objects, &data); close_istream(data.st); free(data.buf); return 0; } static void sha1_object(const void *data, struct object_entry *obj_entry, unsigned long size, enum object_type type, const struct object_id *oid) { void *new_data = NULL; int collision_test_needed = 0; assert(data || obj_entry); if (startup_info->have_repository) { read_lock(); collision_test_needed = has_object_file_with_flags(oid, OBJECT_INFO_QUICK); read_unlock(); } if (collision_test_needed && !data) { read_lock(); if (!check_collison(obj_entry)) collision_test_needed = 0; read_unlock(); } if (collision_test_needed) { void *has_data; enum object_type has_type; unsigned long has_size; read_lock(); has_type = oid_object_info(the_repository, oid, &has_size); if (has_type < 0) die(_("cannot read existing object info %s"), oid_to_hex(oid)); if (has_type != type || has_size != size) die(_("SHA1 COLLISION FOUND WITH %s !"), oid_to_hex(oid)); has_data = read_object_file(oid, &has_type, &has_size); read_unlock(); if (!data) data = new_data = get_data_from_pack(obj_entry); if (!has_data) die(_("cannot read existing object %s"), oid_to_hex(oid)); if (size != has_size || type != has_type || memcmp(data, has_data, size) != 0) die(_("SHA1 COLLISION FOUND WITH %s !"), oid_to_hex(oid)); free(has_data); } if (strict || do_fsck_object) { read_lock(); if (type == OBJ_BLOB) { struct blob *blob = lookup_blob(the_repository, oid); if (blob) blob->object.flags |= FLAG_CHECKED; else die(_("invalid blob object %s"), oid_to_hex(oid)); if (do_fsck_object && fsck_object(&blob->object, (void *)data, size, &fsck_options)) die(_("fsck error in packed object")); } else { struct object *obj; int eaten; void *buf = (void *) data; assert(data && "data can only be NULL for large _blobs_"); /* * we do not need to free the memory here, as the * buf is deleted by the caller. */ obj = parse_object_buffer(the_repository, oid, type, size, buf, &eaten); if (!obj) die(_("invalid %s"), type_name(type)); if (do_fsck_object && fsck_object(obj, buf, size, &fsck_options)) die(_("fsck error in packed object")); if (strict && fsck_walk(obj, NULL, &fsck_options)) die(_("Not all child objects of %s are reachable"), oid_to_hex(&obj->oid)); if (obj->type == OBJ_TREE) { struct tree *item = (struct tree *) obj; item->buffer = NULL; obj->parsed = 0; } if (obj->type == OBJ_COMMIT) { struct commit *commit = (struct commit *) obj; if (detach_commit_buffer(commit, NULL) != data) BUG("parse_object_buffer transmogrified our buffer"); } obj->flags |= FLAG_CHECKED; } read_unlock(); } free(new_data); } /* * Ensure that this node has been reconstructed and return its contents. * * In the typical and best case, this node would already be reconstructed * (through the invocation to resolve_delta() in threaded_second_pass()) and it * would not be pruned. However, if pruning of this node was necessary due to * reaching delta_base_cache_limit, this function will find the closest * ancestor with reconstructed data that has not been pruned (or if there is * none, the ultimate base object), and reconstruct each node in the delta * chain in order to generate the reconstructed data for this node. */ static void *get_base_data(struct base_data *c) { if (!c->data) { struct object_entry *obj = c->obj; struct base_data **delta = NULL; int delta_nr = 0, delta_alloc = 0; while (is_delta_type(c->obj->type) && !c->data) { ALLOC_GROW(delta, delta_nr + 1, delta_alloc); delta[delta_nr++] = c; c = c->base; } if (!delta_nr) { c->data = get_data_from_pack(obj); c->size = obj->size; base_cache_used += c->size; prune_base_data(c); } for (; delta_nr > 0; delta_nr--) { void *base, *raw; c = delta[delta_nr - 1]; obj = c->obj; base = get_base_data(c->base); raw = get_data_from_pack(obj); c->data = patch_delta( base, c->base->size, raw, obj->size, &c->size); free(raw); if (!c->data) bad_object(obj->idx.offset, _("failed to apply delta")); base_cache_used += c->size; prune_base_data(c); } free(delta); } return c->data; } static struct base_data *make_base(struct object_entry *obj, struct base_data *parent) { struct base_data *base = xcalloc(1, sizeof(struct base_data)); base->base = parent; base->obj = obj; find_ref_delta_children(&obj->idx.oid, &base->ref_first, &base->ref_last); find_ofs_delta_children(obj->idx.offset, &base->ofs_first, &base->ofs_last); base->children_remaining = base->ref_last - base->ref_first + base->ofs_last - base->ofs_first + 2; return base; } static struct base_data *resolve_delta(struct object_entry *delta_obj, struct base_data *base) { void *delta_data, *result_data; struct base_data *result; unsigned long result_size; if (show_stat) { int i = delta_obj - objects; int j = base->obj - objects; obj_stat[i].delta_depth = obj_stat[j].delta_depth + 1; deepest_delta_lock(); if (deepest_delta < obj_stat[i].delta_depth) deepest_delta = obj_stat[i].delta_depth; deepest_delta_unlock(); obj_stat[i].base_object_no = j; } delta_data = get_data_from_pack(delta_obj); assert(base->data); result_data = patch_delta(base->data, base->size, delta_data, delta_obj->size, &result_size); free(delta_data); if (!result_data) bad_object(delta_obj->idx.offset, _("failed to apply delta")); hash_object_file(the_hash_algo, result_data, result_size, type_name(delta_obj->real_type), &delta_obj->idx.oid); sha1_object(result_data, NULL, result_size, delta_obj->real_type, &delta_obj->idx.oid); result = make_base(delta_obj, base); result->data = result_data; result->size = result_size; counter_lock(); nr_resolved_deltas++; counter_unlock(); return result; } static int compare_ofs_delta_entry(const void *a, const void *b) { const struct ofs_delta_entry *delta_a = a; const struct ofs_delta_entry *delta_b = b; return delta_a->offset < delta_b->offset ? -1 : delta_a->offset > delta_b->offset ? 1 : 0; } static int compare_ref_delta_entry(const void *a, const void *b) { const struct ref_delta_entry *delta_a = a; const struct ref_delta_entry *delta_b = b; return oidcmp(&delta_a->oid, &delta_b->oid); } static void *threaded_second_pass(void *data) { if (data) set_thread_data(data); for (;;) { struct base_data *parent = NULL; struct object_entry *child_obj; struct base_data *child; counter_lock(); display_progress(progress, nr_resolved_deltas); counter_unlock(); work_lock(); if (list_empty(&work_head)) { /* * Take an object from the object array. */ while (nr_dispatched < nr_objects && is_delta_type(objects[nr_dispatched].type)) nr_dispatched++; if (nr_dispatched >= nr_objects) { work_unlock(); break; } child_obj = &objects[nr_dispatched++]; } else { /* * Peek at the top of the stack, and take a child from * it. */ parent = list_first_entry(&work_head, struct base_data, list); if (parent->ref_first <= parent->ref_last) { int offset = ref_deltas[parent->ref_first++].obj_no; child_obj = objects + offset; if (child_obj->real_type != OBJ_REF_DELTA) die("REF_DELTA at offset %"PRIuMAX" already resolved (duplicate base %s?)", (uintmax_t) child_obj->idx.offset, oid_to_hex(&parent->obj->idx.oid)); child_obj->real_type = parent->obj->real_type; } else { child_obj = objects + ofs_deltas[parent->ofs_first++].obj_no; assert(child_obj->real_type == OBJ_OFS_DELTA); child_obj->real_type = parent->obj->real_type; } if (parent->ref_first > parent->ref_last && parent->ofs_first > parent->ofs_last) { /* * This parent has run out of children, so move * it to done_head. */ list_del(&parent->list); list_add(&parent->list, &done_head); } /* * Ensure that the parent has data, since we will need * it later. * * NEEDSWORK: If parent data needs to be reloaded, this * prolongs the time that the current thread spends in * the mutex. A mitigating factor is that parent data * needs to be reloaded only if the delta base cache * limit is exceeded, so in the typical case, this does * not happen. */ get_base_data(parent); parent->retain_data++; } work_unlock(); if (parent) { child = resolve_delta(child_obj, parent); if (!child->children_remaining) FREE_AND_NULL(child->data); } else { child = make_base(child_obj, NULL); if (child->children_remaining) { /* * Since this child has its own delta children, * we will need this data in the future. * Inflate now so that future iterations will * have access to this object's data while * outside the work mutex. */ child->data = get_data_from_pack(child_obj); child->size = child_obj->size; } } work_lock(); if (parent) parent->retain_data--; if (child->data) { /* * This child has its own children, so add it to * work_head. */ list_add(&child->list, &work_head); base_cache_used += child->size; prune_base_data(NULL); } else { /* * This child does not have its own children. It may be * the last descendant of its ancestors; free those * that we can. */ struct base_data *p = parent; while (p) { struct base_data *next_p; p->children_remaining--; if (p->children_remaining) break; next_p = p->base; free_base_data(p); list_del(&p->list); free(p); p = next_p; } } work_unlock(); } return NULL; } /* * First pass: * - find locations of all objects; * - calculate SHA1 of all non-delta objects; * - remember base (SHA1 or offset) for all deltas. */ static void parse_pack_objects(unsigned char *hash) { int i, nr_delays = 0; struct ofs_delta_entry *ofs_delta = ofs_deltas; struct object_id ref_delta_oid; struct stat st; if (verbose) progress = start_progress( from_stdin ? _("Receiving objects") : _("Indexing objects"), nr_objects); for (i = 0; i < nr_objects; i++) { struct object_entry *obj = &objects[i]; void *data = unpack_raw_entry(obj, &ofs_delta->offset, &ref_delta_oid, &obj->idx.oid); obj->real_type = obj->type; if (obj->type == OBJ_OFS_DELTA) { nr_ofs_deltas++; ofs_delta->obj_no = i; ofs_delta++; } else if (obj->type == OBJ_REF_DELTA) { ALLOC_GROW(ref_deltas, nr_ref_deltas + 1, ref_deltas_alloc); oidcpy(&ref_deltas[nr_ref_deltas].oid, &ref_delta_oid); ref_deltas[nr_ref_deltas].obj_no = i; nr_ref_deltas++; } else if (!data) { /* large blobs, check later */ obj->real_type = OBJ_BAD; nr_delays++; } else sha1_object(data, NULL, obj->size, obj->type, &obj->idx.oid); free(data); display_progress(progress, i+1); } objects[i].idx.offset = consumed_bytes; stop_progress(&progress); /* Check pack integrity */ flush(); the_hash_algo->final_fn(hash, &input_ctx); if (!hasheq(fill(the_hash_algo->rawsz), hash)) die(_("pack is corrupted (SHA1 mismatch)")); use(the_hash_algo->rawsz); /* If input_fd is a file, we should have reached its end now. */ if (fstat(input_fd, &st)) die_errno(_("cannot fstat packfile")); if (S_ISREG(st.st_mode) && lseek(input_fd, 0, SEEK_CUR) - input_len != st.st_size) die(_("pack has junk at the end")); for (i = 0; i < nr_objects; i++) { struct object_entry *obj = &objects[i]; if (obj->real_type != OBJ_BAD) continue; obj->real_type = obj->type; sha1_object(NULL, obj, obj->size, obj->type, &obj->idx.oid); nr_delays--; } if (nr_delays) die(_("confusion beyond insanity in parse_pack_objects()")); } /* * Second pass: * - for all non-delta objects, look if it is used as a base for * deltas; * - if used as a base, uncompress the object and apply all deltas, * recursively checking if the resulting object is used as a base * for some more deltas. */ static void resolve_deltas(void) { int i; if (!nr_ofs_deltas && !nr_ref_deltas) return; /* Sort deltas by base SHA1/offset for fast searching */ QSORT(ofs_deltas, nr_ofs_deltas, compare_ofs_delta_entry); QSORT(ref_deltas, nr_ref_deltas, compare_ref_delta_entry); if (verbose || show_resolving_progress) progress = start_progress(_("Resolving deltas"), nr_ref_deltas + nr_ofs_deltas); nr_dispatched = 0; base_cache_limit = delta_base_cache_limit * nr_threads; if (nr_threads > 1 || getenv("GIT_FORCE_THREADS")) { init_thread(); for (i = 0; i < nr_threads; i++) { int ret = pthread_create(&thread_data[i].thread, NULL, threaded_second_pass, thread_data + i); if (ret) die(_("unable to create thread: %s"), strerror(ret)); } for (i = 0; i < nr_threads; i++) pthread_join(thread_data[i].thread, NULL); cleanup_thread(); return; } threaded_second_pass(¬hread_data); } /* * Third pass: * - append objects to convert thin pack to full pack if required * - write the final pack hash */ static void fix_unresolved_deltas(struct hashfile *f); static void conclude_pack(int fix_thin_pack, const char *curr_pack, unsigned char *pack_hash) { if (nr_ref_deltas + nr_ofs_deltas == nr_resolved_deltas) { stop_progress(&progress); /* Flush remaining pack final hash. */ flush(); return; } if (fix_thin_pack) { struct hashfile *f; unsigned char read_hash[GIT_MAX_RAWSZ], tail_hash[GIT_MAX_RAWSZ]; struct strbuf msg = STRBUF_INIT; int nr_unresolved = nr_ofs_deltas + nr_ref_deltas - nr_resolved_deltas; int nr_objects_initial = nr_objects; if (nr_unresolved <= 0) die(_("confusion beyond insanity")); REALLOC_ARRAY(objects, nr_objects + nr_unresolved + 1); memset(objects + nr_objects + 1, 0, nr_unresolved * sizeof(*objects)); f = hashfd(output_fd, curr_pack); fix_unresolved_deltas(f); strbuf_addf(&msg, Q_("completed with %d local object", "completed with %d local objects", nr_objects - nr_objects_initial), nr_objects - nr_objects_initial); stop_progress_msg(&progress, msg.buf); strbuf_release(&msg); finalize_hashfile(f, tail_hash, 0); hashcpy(read_hash, pack_hash); fixup_pack_header_footer(output_fd, pack_hash, curr_pack, nr_objects, read_hash, consumed_bytes-the_hash_algo->rawsz); if (!hasheq(read_hash, tail_hash)) die(_("Unexpected tail checksum for %s " "(disk corruption?)"), curr_pack); } if (nr_ofs_deltas + nr_ref_deltas != nr_resolved_deltas) die(Q_("pack has %d unresolved delta", "pack has %d unresolved deltas", nr_ofs_deltas + nr_ref_deltas - nr_resolved_deltas), nr_ofs_deltas + nr_ref_deltas - nr_resolved_deltas); } static int write_compressed(struct hashfile *f, void *in, unsigned int size) { git_zstream stream; int status; unsigned char outbuf[4096]; git_deflate_init(&stream, zlib_compression_level); stream.next_in = in; stream.avail_in = size; do { stream.next_out = outbuf; stream.avail_out = sizeof(outbuf); status = git_deflate(&stream, Z_FINISH); hashwrite(f, outbuf, sizeof(outbuf) - stream.avail_out); } while (status == Z_OK); if (status != Z_STREAM_END) die(_("unable to deflate appended object (%d)"), status); size = stream.total_out; git_deflate_end(&stream); return size; } static struct object_entry *append_obj_to_pack(struct hashfile *f, const unsigned char *sha1, void *buf, unsigned long size, enum object_type type) { struct object_entry *obj = &objects[nr_objects++]; unsigned char header[10]; unsigned long s = size; int n = 0; unsigned char c = (type << 4) | (s & 15); s >>= 4; while (s) { header[n++] = c | 0x80; c = s & 0x7f; s >>= 7; } header[n++] = c; crc32_begin(f); hashwrite(f, header, n); obj[0].size = size; obj[0].hdr_size = n; obj[0].type = type; obj[0].real_type = type; obj[1].idx.offset = obj[0].idx.offset + n; obj[1].idx.offset += write_compressed(f, buf, size); obj[0].idx.crc32 = crc32_end(f); hashflush(f); hashcpy(obj->idx.oid.hash, sha1); return obj; } static int delta_pos_compare(const void *_a, const void *_b) { struct ref_delta_entry *a = *(struct ref_delta_entry **)_a; struct ref_delta_entry *b = *(struct ref_delta_entry **)_b; return a->obj_no - b->obj_no; } static void fix_unresolved_deltas(struct hashfile *f) { struct ref_delta_entry **sorted_by_pos; int i; /* * Since many unresolved deltas may well be themselves base objects * for more unresolved deltas, we really want to include the * smallest number of base objects that would cover as much delta * as possible by picking the * trunc deltas first, allowing for other deltas to resolve without * additional base objects. Since most base objects are to be found * before deltas depending on them, a good heuristic is to start * resolving deltas in the same order as their position in the pack. */ ALLOC_ARRAY(sorted_by_pos, nr_ref_deltas); for (i = 0; i < nr_ref_deltas; i++) sorted_by_pos[i] = &ref_deltas[i]; QSORT(sorted_by_pos, nr_ref_deltas, delta_pos_compare); if (has_promisor_remote()) { /* * Prefetch the delta bases. */ struct oid_array to_fetch = OID_ARRAY_INIT; for (i = 0; i < nr_ref_deltas; i++) { struct ref_delta_entry *d = sorted_by_pos[i]; if (!oid_object_info_extended(the_repository, &d->oid, NULL, OBJECT_INFO_FOR_PREFETCH)) continue; oid_array_append(&to_fetch, &d->oid); } promisor_remote_get_direct(the_repository, to_fetch.oid, to_fetch.nr); oid_array_clear(&to_fetch); } for (i = 0; i < nr_ref_deltas; i++) { struct ref_delta_entry *d = sorted_by_pos[i]; enum object_type type; void *data; unsigned long size; if (objects[d->obj_no].real_type != OBJ_REF_DELTA) continue; data = read_object_file(&d->oid, &type, &size); if (!data) continue; if (check_object_signature(the_repository, &d->oid, data, size, type_name(type))) die(_("local object %s is corrupt"), oid_to_hex(&d->oid)); /* * Add this as an object to the objects array and call * threaded_second_pass() (which will pick up the added * object). */ append_obj_to_pack(f, d->oid.hash, data, size, type); threaded_second_pass(NULL); display_progress(progress, nr_resolved_deltas); } free(sorted_by_pos); } static const char *derive_filename(const char *pack_name, const char *strip, const char *suffix, struct strbuf *buf) { size_t len; if (!strip_suffix(pack_name, strip, &len) || !len || pack_name[len - 1] != '.') die(_("packfile name '%s' does not end with '.%s'"), pack_name, strip); strbuf_add(buf, pack_name, len); strbuf_addstr(buf, suffix); return buf->buf; } static void write_special_file(const char *suffix, const char *msg, const char *pack_name, const unsigned char *hash, const char **report) { struct strbuf name_buf = STRBUF_INIT; const char *filename; int fd; int msg_len = strlen(msg); if (pack_name) filename = derive_filename(pack_name, "pack", suffix, &name_buf); else filename = odb_pack_name(&name_buf, hash, suffix); fd = odb_pack_keep(filename); if (fd < 0) { if (errno != EEXIST) die_errno(_("cannot write %s file '%s'"), suffix, filename); } else { if (msg_len > 0) { write_or_die(fd, msg, msg_len); write_or_die(fd, "\n", 1); } if (close(fd) != 0) die_errno(_("cannot close written %s file '%s'"), suffix, filename); if (report) *report = suffix; } strbuf_release(&name_buf); } static void final(const char *final_pack_name, const char *curr_pack_name, const char *final_index_name, const char *curr_index_name, const char *final_rev_index_name, const char *curr_rev_index_name, const char *keep_msg, const char *promisor_msg, unsigned char *hash) { const char *report = "pack"; struct strbuf pack_name = STRBUF_INIT; struct strbuf index_name = STRBUF_INIT; struct strbuf rev_index_name = STRBUF_INIT; int err; if (!from_stdin) { close(input_fd); } else { fsync_or_die(output_fd, curr_pack_name); err = close(output_fd); if (err) die_errno(_("error while closing pack file")); } if (keep_msg) write_special_file("keep", keep_msg, final_pack_name, hash, &report); if (promisor_msg) write_special_file("promisor", promisor_msg, final_pack_name, hash, NULL); if (final_pack_name != curr_pack_name) { if (!final_pack_name) final_pack_name = odb_pack_name(&pack_name, hash, "pack"); if (finalize_object_file(curr_pack_name, final_pack_name)) die(_("cannot store pack file")); } else if (from_stdin) chmod(final_pack_name, 0444); if (final_index_name != curr_index_name) { if (!final_index_name) final_index_name = odb_pack_name(&index_name, hash, "idx"); if (finalize_object_file(curr_index_name, final_index_name)) die(_("cannot store index file")); } else chmod(final_index_name, 0444); if (curr_rev_index_name) { if (final_rev_index_name != curr_rev_index_name) { if (!final_rev_index_name) final_rev_index_name = odb_pack_name(&rev_index_name, hash, "rev"); if (finalize_object_file(curr_rev_index_name, final_rev_index_name)) die(_("cannot store reverse index file")); } else chmod(final_rev_index_name, 0444); } if (do_fsck_object) { struct packed_git *p; p = add_packed_git(final_index_name, strlen(final_index_name), 0); if (p) install_packed_git(the_repository, p); } if (!from_stdin) { printf("%s\n", hash_to_hex(hash)); } else { struct strbuf buf = STRBUF_INIT; strbuf_addf(&buf, "%s\t%s\n", report, hash_to_hex(hash)); write_or_die(1, buf.buf, buf.len); strbuf_release(&buf); /* * Let's just mimic git-unpack-objects here and write * the last part of the input buffer to stdout. */ while (input_len) { err = xwrite(1, input_buffer + input_offset, input_len); if (err <= 0) break; input_len -= err; input_offset += err; } } strbuf_release(&rev_index_name); strbuf_release(&index_name); strbuf_release(&pack_name); } static int git_index_pack_config(const char *k, const char *v, void *cb) { struct pack_idx_option *opts = cb; if (!strcmp(k, "pack.indexversion")) { opts->version = git_config_int(k, v); if (opts->version > 2) die(_("bad pack.indexversion=%"PRIu32), opts->version); return 0; } if (!strcmp(k, "pack.threads")) { nr_threads = git_config_int(k, v); if (nr_threads < 0) die(_("invalid number of threads specified (%d)"), nr_threads); if (!HAVE_THREADS && nr_threads != 1) { warning(_("no threads support, ignoring %s"), k); nr_threads = 1; } return 0; } if (!strcmp(k, "pack.writereverseindex")) { if (git_config_bool(k, v)) opts->flags |= WRITE_REV; else opts->flags &= ~WRITE_REV; } return git_default_config(k, v, cb); } static int cmp_uint32(const void *a_, const void *b_) { uint32_t a = *((uint32_t *)a_); uint32_t b = *((uint32_t *)b_); return (a < b) ? -1 : (a != b); } static void read_v2_anomalous_offsets(struct packed_git *p, struct pack_idx_option *opts) { const uint32_t *idx1, *idx2; uint32_t i; /* The address of the 4-byte offset table */ idx1 = (((const uint32_t *)((const uint8_t *)p->index_data + p->crc_offset)) + (size_t)p->num_objects /* CRC32 table */ ); /* The address of the 8-byte offset table */ idx2 = idx1 + p->num_objects; for (i = 0; i < p->num_objects; i++) { uint32_t off = ntohl(idx1[i]); if (!(off & 0x80000000)) continue; off = off & 0x7fffffff; check_pack_index_ptr(p, &idx2[off * 2]); if (idx2[off * 2]) continue; /* * The real offset is ntohl(idx2[off * 2]) in high 4 * octets, and ntohl(idx2[off * 2 + 1]) in low 4 * octets. But idx2[off * 2] is Zero!!! */ ALLOC_GROW(opts->anomaly, opts->anomaly_nr + 1, opts->anomaly_alloc); opts->anomaly[opts->anomaly_nr++] = ntohl(idx2[off * 2 + 1]); } QSORT(opts->anomaly, opts->anomaly_nr, cmp_uint32); } static void read_idx_option(struct pack_idx_option *opts, const char *pack_name) { struct packed_git *p = add_packed_git(pack_name, strlen(pack_name), 1); if (!p) die(_("Cannot open existing pack file '%s'"), pack_name); if (open_pack_index(p)) die(_("Cannot open existing pack idx file for '%s'"), pack_name); /* Read the attributes from the existing idx file */ opts->version = p->index_version; if (opts->version == 2) read_v2_anomalous_offsets(p, opts); /* * Get rid of the idx file as we do not need it anymore. * NEEDSWORK: extract this bit from free_pack_by_name() in * object-file.c, perhaps? It shouldn't matter very much as we * know we haven't installed this pack (hence we never have * read anything from it). */ close_pack_index(p); free(p); } static void show_pack_info(int stat_only) { int i, baseobjects = nr_objects - nr_ref_deltas - nr_ofs_deltas; unsigned long *chain_histogram = NULL; if (deepest_delta) chain_histogram = xcalloc(deepest_delta, sizeof(unsigned long)); for (i = 0; i < nr_objects; i++) { struct object_entry *obj = &objects[i]; if (is_delta_type(obj->type)) chain_histogram[obj_stat[i].delta_depth - 1]++; if (stat_only) continue; printf("%s %-6s %"PRIuMAX" %"PRIuMAX" %"PRIuMAX, oid_to_hex(&obj->idx.oid), type_name(obj->real_type), (uintmax_t)obj->size, (uintmax_t)(obj[1].idx.offset - obj->idx.offset), (uintmax_t)obj->idx.offset); if (is_delta_type(obj->type)) { struct object_entry *bobj = &objects[obj_stat[i].base_object_no]; printf(" %u %s", obj_stat[i].delta_depth, oid_to_hex(&bobj->idx.oid)); } putchar('\n'); } if (baseobjects) printf_ln(Q_("non delta: %d object", "non delta: %d objects", baseobjects), baseobjects); for (i = 0; i < deepest_delta; i++) { if (!chain_histogram[i]) continue; printf_ln(Q_("chain length = %d: %lu object", "chain length = %d: %lu objects", chain_histogram[i]), i + 1, chain_histogram[i]); } } int cmd_index_pack(int argc, const char **argv, const char *prefix) { int i, fix_thin_pack = 0, verify = 0, stat_only = 0, rev_index; const char *curr_index; const char *curr_rev_index = NULL; const char *index_name = NULL, *pack_name = NULL, *rev_index_name = NULL; const char *keep_msg = NULL; const char *promisor_msg = NULL; struct strbuf index_name_buf = STRBUF_INIT; struct strbuf rev_index_name_buf = STRBUF_INIT; struct pack_idx_entry **idx_objects; struct pack_idx_option opts; unsigned char pack_hash[GIT_MAX_RAWSZ]; unsigned foreign_nr = 1; /* zero is a "good" value, assume bad */ int report_end_of_input = 0; int hash_algo = 0; /* * index-pack never needs to fetch missing objects except when * REF_DELTA bases are missing (which are explicitly handled). It only * accesses the repo to do hash collision checks and to check which * REF_DELTA bases need to be fetched. */ fetch_if_missing = 0; if (argc == 2 && !strcmp(argv[1], "-h")) usage(index_pack_usage); read_replace_refs = 0; fsck_options.walk = mark_link; reset_pack_idx_option(&opts); git_config(git_index_pack_config, &opts); if (prefix && chdir(prefix)) die(_("Cannot come back to cwd")); if (git_env_bool(GIT_TEST_WRITE_REV_INDEX, 0)) rev_index = 1; else rev_index = !!(opts.flags & (WRITE_REV_VERIFY | WRITE_REV)); for (i = 1; i < argc; i++) { const char *arg = argv[i]; if (*arg == '-') { if (!strcmp(arg, "--stdin")) { from_stdin = 1; } else if (!strcmp(arg, "--fix-thin")) { fix_thin_pack = 1; } else if (skip_to_optional_arg(arg, "--strict", &arg)) { strict = 1; do_fsck_object = 1; fsck_set_msg_types(&fsck_options, arg); } else if (!strcmp(arg, "--check-self-contained-and-connected")) { strict = 1; check_self_contained_and_connected = 1; } else if (!strcmp(arg, "--fsck-objects")) { do_fsck_object = 1; } else if (!strcmp(arg, "--verify")) { verify = 1; } else if (!strcmp(arg, "--verify-stat")) { verify = 1; show_stat = 1; } else if (!strcmp(arg, "--verify-stat-only")) { verify = 1; show_stat = 1; stat_only = 1; } else if (skip_to_optional_arg(arg, "--keep", &keep_msg)) { ; /* nothing to do */ } else if (skip_to_optional_arg(arg, "--promisor", &promisor_msg)) { ; /* already parsed */ } else if (starts_with(arg, "--threads=")) { char *end; nr_threads = strtoul(arg+10, &end, 0); if (!arg[10] || *end || nr_threads < 0) usage(index_pack_usage); if (!HAVE_THREADS && nr_threads != 1) { warning(_("no threads support, ignoring %s"), arg); nr_threads = 1; } } else if (starts_with(arg, "--pack_header=")) { struct pack_header *hdr; char *c; hdr = (struct pack_header *)input_buffer; hdr->hdr_signature = htonl(PACK_SIGNATURE); hdr->hdr_version = htonl(strtoul(arg + 14, &c, 10)); if (*c != ',') die(_("bad %s"), arg); hdr->hdr_entries = htonl(strtoul(c + 1, &c, 10)); if (*c) die(_("bad %s"), arg); input_len = sizeof(*hdr); } else if (!strcmp(arg, "-v")) { verbose = 1; } else if (!strcmp(arg, "--show-resolving-progress")) { show_resolving_progress = 1; } else if (!strcmp(arg, "--report-end-of-input")) { report_end_of_input = 1; } else if (!strcmp(arg, "-o")) { if (index_name || (i+1) >= argc) usage(index_pack_usage); index_name = argv[++i]; } else if (starts_with(arg, "--index-version=")) { char *c; opts.version = strtoul(arg + 16, &c, 10); if (opts.version > 2) die(_("bad %s"), arg); if (*c == ',') opts.off32_limit = strtoul(c+1, &c, 0); if (*c || opts.off32_limit & 0x80000000) die(_("bad %s"), arg); } else if (skip_prefix(arg, "--max-input-size=", &arg)) { max_input_size = strtoumax(arg, NULL, 10); } else if (skip_prefix(arg, "--object-format=", &arg)) { hash_algo = hash_algo_by_name(arg); if (hash_algo == GIT_HASH_UNKNOWN) die(_("unknown hash algorithm '%s'"), arg); repo_set_hash_algo(the_repository, hash_algo); } else if (!strcmp(arg, "--rev-index")) { rev_index = 1; } else if (!strcmp(arg, "--no-rev-index")) { rev_index = 0; } else usage(index_pack_usage); continue; } if (pack_name) usage(index_pack_usage); pack_name = arg; } if (!pack_name && !from_stdin) usage(index_pack_usage); if (fix_thin_pack && !from_stdin) die(_("--fix-thin cannot be used without --stdin")); if (from_stdin && !startup_info->have_repository) die(_("--stdin requires a git repository")); if (from_stdin && hash_algo) die(_("--object-format cannot be used with --stdin")); if (!index_name && pack_name) index_name = derive_filename(pack_name, "pack", "idx", &index_name_buf); opts.flags &= ~(WRITE_REV | WRITE_REV_VERIFY); if (rev_index) { opts.flags |= verify ? WRITE_REV_VERIFY : WRITE_REV; if (index_name) rev_index_name = derive_filename(index_name, "idx", "rev", &rev_index_name_buf); } if (verify) { if (!index_name) die(_("--verify with no packfile name given")); read_idx_option(&opts, index_name); opts.flags |= WRITE_IDX_VERIFY | WRITE_IDX_STRICT; } if (strict) opts.flags |= WRITE_IDX_STRICT; if (HAVE_THREADS && !nr_threads) { nr_threads = online_cpus(); /* * Experiments show that going above 20 threads doesn't help, * no matter how many cores you have. Below that, we tend to * max at half the number of online_cpus(), presumably because * half of those are hyperthreads rather than full cores. We'll * never reduce the level below "3", though, to match a * historical value that nobody complained about. */ if (nr_threads < 4) ; /* too few cores to consider capping */ else if (nr_threads < 6) nr_threads = 3; /* historic cap */ else if (nr_threads < 40) nr_threads /= 2; else nr_threads = 20; /* hard cap */ } curr_pack = open_pack_file(pack_name); parse_pack_header(); objects = xcalloc(st_add(nr_objects, 1), sizeof(struct object_entry)); if (show_stat) obj_stat = xcalloc(st_add(nr_objects, 1), sizeof(struct object_stat)); ofs_deltas = xcalloc(nr_objects, sizeof(struct ofs_delta_entry)); parse_pack_objects(pack_hash); if (report_end_of_input) write_in_full(2, "\0", 1); resolve_deltas(); conclude_pack(fix_thin_pack, curr_pack, pack_hash); free(ofs_deltas); free(ref_deltas); if (strict) foreign_nr = check_objects(); if (show_stat) show_pack_info(stat_only); ALLOC_ARRAY(idx_objects, nr_objects); for (i = 0; i < nr_objects; i++) idx_objects[i] = &objects[i].idx; curr_index = write_idx_file(index_name, idx_objects, nr_objects, &opts, pack_hash); if (rev_index) curr_rev_index = write_rev_file(rev_index_name, idx_objects, nr_objects, pack_hash, opts.flags); free(idx_objects); if (!verify) final(pack_name, curr_pack, index_name, curr_index, rev_index_name, curr_rev_index, keep_msg, promisor_msg, pack_hash); else close(input_fd); if (do_fsck_object && fsck_finish(&fsck_options)) die(_("fsck error in pack objects")); free(objects); strbuf_release(&index_name_buf); strbuf_release(&rev_index_name_buf); if (pack_name == NULL) free((void *) curr_pack); if (index_name == NULL) free((void *) curr_index); if (rev_index_name == NULL) free((void *) curr_rev_index); /* * Let the caller know this pack is not self contained */ if (check_self_contained_and_connected && foreign_nr) return 1; return 0; }