#include "cache.h" #include "object.h" #include "replace-object.h" #include "object-store.h" #include "blob.h" #include "tree.h" #include "commit.h" #include "tag.h" #include "alloc.h" #include "object-store.h" #include "packfile.h" unsigned int get_max_object_index(void) { return the_repository->parsed_objects->obj_hash_size; } struct object *get_indexed_object(unsigned int idx) { return the_repository->parsed_objects->obj_hash[idx]; } static const char *object_type_strings[] = { NULL, /* OBJ_NONE = 0 */ "commit", /* OBJ_COMMIT = 1 */ "tree", /* OBJ_TREE = 2 */ "blob", /* OBJ_BLOB = 3 */ "tag", /* OBJ_TAG = 4 */ }; const char *type_name(unsigned int type) { if (type >= ARRAY_SIZE(object_type_strings)) return NULL; return object_type_strings[type]; } int type_from_string_gently(const char *str, ssize_t len, int gentle) { int i; if (len < 0) len = strlen(str); for (i = 1; i < ARRAY_SIZE(object_type_strings); i++) if (!strncmp(str, object_type_strings[i], len) && object_type_strings[i][len] == '\0') return i; if (gentle) return -1; die("invalid object type \"%s\"", str); } /* * Return a numerical hash value between 0 and n-1 for the object with * the specified sha1. n must be a power of 2. Please note that the * return value is *not* consistent across computer architectures. */ static unsigned int hash_obj(const unsigned char *sha1, unsigned int n) { return sha1hash(sha1) & (n - 1); } /* * Insert obj into the hash table hash, which has length size (which * must be a power of 2). On collisions, simply overflow to the next * empty bucket. */ static void insert_obj_hash(struct object *obj, struct object **hash, unsigned int size) { unsigned int j = hash_obj(obj->oid.hash, size); while (hash[j]) { j++; if (j >= size) j = 0; } hash[j] = obj; } /* * Look up the record for the given sha1 in the hash map stored in * obj_hash. Return NULL if it was not found. */ struct object *lookup_object(const unsigned char *sha1) { unsigned int i, first; struct object *obj; if (!the_repository->parsed_objects->obj_hash) return NULL; first = i = hash_obj(sha1, the_repository->parsed_objects->obj_hash_size); while ((obj = the_repository->parsed_objects->obj_hash[i]) != NULL) { if (!hashcmp(sha1, obj->oid.hash)) break; i++; if (i == the_repository->parsed_objects->obj_hash_size) i = 0; } if (obj && i != first) { /* * Move object to where we started to look for it so * that we do not need to walk the hash table the next * time we look for it. */ SWAP(the_repository->parsed_objects->obj_hash[i], the_repository->parsed_objects->obj_hash[first]); } return obj; } /* * Increase the size of the hash map stored in obj_hash to the next * power of 2 (but at least 32). Copy the existing values to the new * hash map. */ static void grow_object_hash(struct repository *r) { int i; /* * Note that this size must always be power-of-2 to match hash_obj * above. */ int new_hash_size = r->parsed_objects->obj_hash_size < 32 ? 32 : 2 * r->parsed_objects->obj_hash_size; struct object **new_hash; new_hash = xcalloc(new_hash_size, sizeof(struct object *)); for (i = 0; i < r->parsed_objects->obj_hash_size; i++) { struct object *obj = r->parsed_objects->obj_hash[i]; if (!obj) continue; insert_obj_hash(obj, new_hash, new_hash_size); } free(r->parsed_objects->obj_hash); r->parsed_objects->obj_hash = new_hash; r->parsed_objects->obj_hash_size = new_hash_size; } void *create_object(struct repository *r, const unsigned char *sha1, void *o) { struct object *obj = o; obj->parsed = 0; obj->flags = 0; hashcpy(obj->oid.hash, sha1); if (r->parsed_objects->obj_hash_size - 1 <= r->parsed_objects->nr_objs * 2) grow_object_hash(r); insert_obj_hash(obj, r->parsed_objects->obj_hash, r->parsed_objects->obj_hash_size); r->parsed_objects->nr_objs++; return obj; } void *object_as_type(struct object *obj, enum object_type type, int quiet) { if (obj->type == type) return obj; else if (obj->type == OBJ_NONE) { if (type == OBJ_COMMIT) ((struct commit *)obj)->index = alloc_commit_index(the_repository); obj->type = type; return obj; } else { if (!quiet) error("object %s is a %s, not a %s", oid_to_hex(&obj->oid), type_name(obj->type), type_name(type)); return NULL; } } struct object *lookup_unknown_object(const unsigned char *sha1) { struct object *obj = lookup_object(sha1); if (!obj) obj = create_object(the_repository, sha1, alloc_object_node(the_repository)); return obj; } struct object *parse_object_buffer(const struct object_id *oid, enum object_type type, unsigned long size, void *buffer, int *eaten_p) { struct object *obj; *eaten_p = 0; obj = NULL; if (type == OBJ_BLOB) { struct blob *blob = lookup_blob(oid); if (blob) { if (parse_blob_buffer(blob, buffer, size)) return NULL; obj = &blob->object; } } else if (type == OBJ_TREE) { struct tree *tree = lookup_tree(oid); if (tree) { obj = &tree->object; if (!tree->buffer) tree->object.parsed = 0; if (!tree->object.parsed) { if (parse_tree_buffer(tree, buffer, size)) return NULL; *eaten_p = 1; } } } else if (type == OBJ_COMMIT) { struct commit *commit = lookup_commit(oid); if (commit) { if (parse_commit_buffer(commit, buffer, size)) return NULL; if (!get_cached_commit_buffer(commit, NULL)) { set_commit_buffer(commit, buffer, size); *eaten_p = 1; } obj = &commit->object; } } else if (type == OBJ_TAG) { struct tag *tag = lookup_tag(oid); if (tag) { if (parse_tag_buffer(tag, buffer, size)) return NULL; obj = &tag->object; } } else { warning("object %s has unknown type id %d", oid_to_hex(oid), type); obj = NULL; } return obj; } struct object *parse_object_or_die(const struct object_id *oid, const char *name) { struct object *o = parse_object(oid); if (o) return o; die(_("unable to parse object: %s"), name ? name : oid_to_hex(oid)); } struct object *parse_object(const struct object_id *oid) { unsigned long size; enum object_type type; int eaten; const struct object_id *repl = lookup_replace_object(the_repository, oid); void *buffer; struct object *obj; obj = lookup_object(oid->hash); if (obj && obj->parsed) return obj; if ((obj && obj->type == OBJ_BLOB && has_object_file(oid)) || (!obj && has_object_file(oid) && oid_object_info(the_repository, oid, NULL) == OBJ_BLOB)) { if (check_object_signature(repl, NULL, 0, NULL) < 0) { error("sha1 mismatch %s", oid_to_hex(oid)); return NULL; } parse_blob_buffer(lookup_blob(oid), NULL, 0); return lookup_object(oid->hash); } buffer = read_object_file(oid, &type, &size); if (buffer) { if (check_object_signature(repl, buffer, size, type_name(type)) < 0) { free(buffer); error("sha1 mismatch %s", oid_to_hex(repl)); return NULL; } obj = parse_object_buffer(oid, type, size, buffer, &eaten); if (!eaten) free(buffer); return obj; } return NULL; } struct object_list *object_list_insert(struct object *item, struct object_list **list_p) { struct object_list *new_list = xmalloc(sizeof(struct object_list)); new_list->item = item; new_list->next = *list_p; *list_p = new_list; return new_list; } int object_list_contains(struct object_list *list, struct object *obj) { while (list) { if (list->item == obj) return 1; list = list->next; } return 0; } /* * A zero-length string to which object_array_entry::name can be * initialized without requiring a malloc/free. */ static char object_array_slopbuf[1]; void add_object_array_with_path(struct object *obj, const char *name, struct object_array *array, unsigned mode, const char *path) { unsigned nr = array->nr; unsigned alloc = array->alloc; struct object_array_entry *objects = array->objects; struct object_array_entry *entry; if (nr >= alloc) { alloc = (alloc + 32) * 2; REALLOC_ARRAY(objects, alloc); array->alloc = alloc; array->objects = objects; } entry = &objects[nr]; entry->item = obj; if (!name) entry->name = NULL; else if (!*name) /* Use our own empty string instead of allocating one: */ entry->name = object_array_slopbuf; else entry->name = xstrdup(name); entry->mode = mode; if (path) entry->path = xstrdup(path); else entry->path = NULL; array->nr = ++nr; } void add_object_array(struct object *obj, const char *name, struct object_array *array) { add_object_array_with_path(obj, name, array, S_IFINVALID, NULL); } /* * Free all memory associated with an entry; the result is * in an unspecified state and should not be examined. */ static void object_array_release_entry(struct object_array_entry *ent) { if (ent->name != object_array_slopbuf) free(ent->name); free(ent->path); } struct object *object_array_pop(struct object_array *array) { struct object *ret; if (!array->nr) return NULL; ret = array->objects[array->nr - 1].item; object_array_release_entry(&array->objects[array->nr - 1]); array->nr--; return ret; } void object_array_filter(struct object_array *array, object_array_each_func_t want, void *cb_data) { unsigned nr = array->nr, src, dst; struct object_array_entry *objects = array->objects; for (src = dst = 0; src < nr; src++) { if (want(&objects[src], cb_data)) { if (src != dst) objects[dst] = objects[src]; dst++; } else { object_array_release_entry(&objects[src]); } } array->nr = dst; } void object_array_clear(struct object_array *array) { int i; for (i = 0; i < array->nr; i++) object_array_release_entry(&array->objects[i]); FREE_AND_NULL(array->objects); array->nr = array->alloc = 0; } /* * Return true iff array already contains an entry with name. */ static int contains_name(struct object_array *array, const char *name) { unsigned nr = array->nr, i; struct object_array_entry *object = array->objects; for (i = 0; i < nr; i++, object++) if (!strcmp(object->name, name)) return 1; return 0; } void object_array_remove_duplicates(struct object_array *array) { unsigned nr = array->nr, src; struct object_array_entry *objects = array->objects; array->nr = 0; for (src = 0; src < nr; src++) { if (!contains_name(array, objects[src].name)) { if (src != array->nr) objects[array->nr] = objects[src]; array->nr++; } else { object_array_release_entry(&objects[src]); } } } void clear_object_flags(unsigned flags) { int i; for (i=0; i < the_repository->parsed_objects->obj_hash_size; i++) { struct object *obj = the_repository->parsed_objects->obj_hash[i]; if (obj) obj->flags &= ~flags; } } void clear_commit_marks_all(unsigned int flags) { int i; for (i = 0; i < the_repository->parsed_objects->obj_hash_size; i++) { struct object *obj = the_repository->parsed_objects->obj_hash[i]; if (obj && obj->type == OBJ_COMMIT) obj->flags &= ~flags; } } struct parsed_object_pool *parsed_object_pool_new(void) { struct parsed_object_pool *o = xmalloc(sizeof(*o)); memset(o, 0, sizeof(*o)); o->blob_state = allocate_alloc_state(); o->tree_state = allocate_alloc_state(); o->commit_state = allocate_alloc_state(); o->tag_state = allocate_alloc_state(); o->object_state = allocate_alloc_state(); o->is_shallow = -1; o->shallow_stat = xcalloc(1, sizeof(*o->shallow_stat)); return o; } struct raw_object_store *raw_object_store_new(void) { struct raw_object_store *o = xmalloc(sizeof(*o)); memset(o, 0, sizeof(*o)); INIT_LIST_HEAD(&o->packed_git_mru); return o; } static void free_alt_odb(struct alternate_object_database *alt) { strbuf_release(&alt->scratch); oid_array_clear(&alt->loose_objects_cache); free(alt); } static void free_alt_odbs(struct raw_object_store *o) { while (o->alt_odb_list) { struct alternate_object_database *next; next = o->alt_odb_list->next; free_alt_odb(o->alt_odb_list); o->alt_odb_list = next; } } void raw_object_store_clear(struct raw_object_store *o) { FREE_AND_NULL(o->objectdir); FREE_AND_NULL(o->alternate_db); free_alt_odbs(o); o->alt_odb_tail = NULL; INIT_LIST_HEAD(&o->packed_git_mru); close_all_packs(o); o->packed_git = NULL; } void parsed_object_pool_clear(struct parsed_object_pool *o) { /* * As objects are allocated in slabs (see alloc.c), we do * not need to free each object, but each slab instead. * * Before doing so, we need to free any additional memory * the objects may hold. */ unsigned i; for (i = 0; i < o->obj_hash_size; i++) { struct object *obj = o->obj_hash[i]; if (!obj) continue; if (obj->type == OBJ_TREE) free_tree_buffer((struct tree*)obj); else if (obj->type == OBJ_COMMIT) release_commit_memory((struct commit*)obj); else if (obj->type == OBJ_TAG) release_tag_memory((struct tag*)obj); } FREE_AND_NULL(o->obj_hash); o->obj_hash_size = 0; clear_alloc_state(o->blob_state); clear_alloc_state(o->tree_state); clear_alloc_state(o->commit_state); clear_alloc_state(o->tag_state); clear_alloc_state(o->object_state); FREE_AND_NULL(o->blob_state); FREE_AND_NULL(o->tree_state); FREE_AND_NULL(o->commit_state); FREE_AND_NULL(o->tag_state); FREE_AND_NULL(o->object_state); }