/* SPDX-FileCopyrightText: 2001-2002 NaN Holding BV. All rights reserved. * * SPDX-License-Identifier: GPL-2.0-or-later */ /** \file * \ingroup bke * * Contains management of ID's and libraries * allocate and free of all library data */ #include #include #include #include #include #include "CLG_log.h" #include "MEM_guardedalloc.h" /* all types are needed here, in order to do memory operations */ #include "DNA_ID.h" #include "DNA_anim_types.h" #include "DNA_collection_types.h" #include "DNA_gpencil_legacy_types.h" #include "DNA_key_types.h" #include "DNA_node_types.h" #include "DNA_workspace_types.h" #include "BLI_utildefines.h" #include "BLI_alloca.h" #include "BLI_array.hh" #include "BLI_blenlib.h" #include "BLI_ghash.h" #include "BLI_linklist.h" #include "BLI_memarena.h" #include "BLI_string_utils.hh" #include "BLT_translation.hh" #include "BKE_anim_data.hh" #include "BKE_armature.hh" #include "BKE_asset.hh" #include "BKE_bpath.hh" #include "BKE_context.hh" #include "BKE_global.hh" #include "BKE_gpencil_legacy.h" #include "BKE_idprop.hh" #include "BKE_idtype.hh" #include "BKE_key.hh" #include "BKE_lib_id.hh" #include "BKE_lib_override.hh" #include "BKE_lib_query.hh" #include "BKE_lib_remap.hh" #include "BKE_main.hh" #include "BKE_main_namemap.hh" #include "BKE_node.hh" #include "BKE_rigidbody.h" #include "DEG_depsgraph.hh" #include "DEG_depsgraph_build.hh" #include "DEG_depsgraph_query.hh" #include "RNA_access.hh" #include "BLO_read_write.hh" #include "atomic_ops.h" #include "lib_intern.hh" // #define DEBUG_TIME #ifdef DEBUG_TIME # include "BLI_time_utildefines.h" #endif using blender::Vector; using namespace blender::bke::id; static CLG_LogRef LOG = {"bke.lib_id"}; IDTypeInfo IDType_ID_LINK_PLACEHOLDER = { /*id_code*/ ID_LINK_PLACEHOLDER, /*id_filter*/ 0, /*dependencies_id_types*/ 0, /*main_listbase_index*/ INDEX_ID_NULL, /*struct_size*/ sizeof(ID), /*name*/ "LinkPlaceholder", /*name_plural*/ N_("link_placeholders"), /*translation_context*/ BLT_I18NCONTEXT_ID_ID, /*flags*/ IDTYPE_FLAGS_NO_COPY | IDTYPE_FLAGS_NO_LIBLINKING, /*asset_type_info*/ nullptr, /*init_data*/ nullptr, /*copy_data*/ nullptr, /*free_data*/ nullptr, /*make_local*/ nullptr, /*foreach_id*/ nullptr, /*foreach_cache*/ nullptr, /*foreach_path*/ nullptr, /*owner_pointer_get*/ nullptr, /*blend_write*/ nullptr, /*blend_read_data*/ nullptr, /*blend_read_after_liblink*/ nullptr, /*blend_read_undo_preserve*/ nullptr, /*lib_override_apply_post*/ nullptr, }; /* GS reads the memory pointed at in a specific ordering. * only use this definition, makes little and big endian systems * work fine, in conjunction with MAKE_ID */ /* ************* general ************************ */ /** * Rewrites a relative path to be relative to the main file - unless the path is * absolute, in which case it is not altered. */ static bool lib_id_library_local_paths_callback(BPathForeachPathData *bpath_data, char *path_dst, size_t path_dst_maxncpy, const char *path_src) { const char **data = static_cast(bpath_data->user_data); /* be sure there is low chance of the path being too short */ char filepath[(FILE_MAXDIR * 2) + FILE_MAXFILE]; const char *base_new = data[0]; const char *base_old = data[1]; if (BLI_path_is_rel(base_old)) { CLOG_ERROR(&LOG, "old base path '%s' is not absolute.", base_old); return false; } /* Make referenced file absolute. This would be a side-effect of * BLI_path_normalize, but we do it explicitly so we know if it changed. */ BLI_strncpy(filepath, path_src, FILE_MAX); if (BLI_path_abs(filepath, base_old)) { /* Path was relative and is now absolute. Remap. * Important BLI_path_normalize runs before the path is made relative * because it won't work for paths that start with "//../" */ BLI_path_normalize(filepath); BLI_path_rel(filepath, base_new); BLI_strncpy(path_dst, filepath, path_dst_maxncpy); return true; } /* Path was not relative to begin with. */ return false; } /** * This has to be called from each make_local_* func, we could call from BKE_lib_id_make_local() * but then the make local functions would not be self contained. * * NOTE(@ideasman42): that the id _must_ have a library. * TODO: This can probably be replaced by an ID-level version of #BKE_bpath_relative_rebase. */ static void lib_id_library_local_paths(Main *bmain, Library *lib, ID *id) { const char *bpath_user_data[2] = {BKE_main_blendfile_path(bmain), lib->runtime.filepath_abs}; BPathForeachPathData path_data{}; path_data.bmain = bmain; path_data.callback_function = lib_id_library_local_paths_callback; path_data.flag = BKE_BPATH_FOREACH_PATH_SKIP_MULTIFILE; path_data.user_data = (void *)bpath_user_data; BKE_bpath_foreach_path_id(&path_data, id); } static int lib_id_clear_library_data_users_update_cb(LibraryIDLinkCallbackData *cb_data) { ID *id = static_cast(cb_data->user_data); if (*cb_data->id_pointer == id) { /* Even though the ID itself remain the same after being made local, from depsgraph point of * view this is a different ID. Hence we need to tag all of its users for a copy-on-eval * update. */ DEG_id_tag_update_ex( cb_data->bmain, cb_data->owner_id, ID_RECALC_TAG_FOR_UNDO | ID_RECALC_SYNC_TO_EVAL); return IDWALK_RET_STOP_ITER; } return IDWALK_RET_NOP; } void BKE_lib_id_clear_library_data(Main *bmain, ID *id, const int flags) { const bool id_in_mainlist = (id->tag & LIB_TAG_NO_MAIN) == 0 && (id->flag & LIB_EMBEDDED_DATA) == 0; if (id_in_mainlist) { BKE_main_namemap_remove_name(bmain, id, id->name + 2); } lib_id_library_local_paths(bmain, id->lib, id); id_fake_user_clear(id); id->lib = nullptr; id->tag &= ~(LIB_TAG_INDIRECT | LIB_TAG_EXTERN); id->flag &= ~LIB_INDIRECT_WEAK_LINK; if (id_in_mainlist) { if (BKE_id_new_name_validate(bmain, which_libbase(bmain, GS(id->name)), id, nullptr, false)) { bmain->is_memfile_undo_written = false; } } /* Conceptually, an ID made local is not the same as the linked one anymore. Reflect that by * regenerating its session UID. */ if ((id->tag & LIB_TAG_TEMP_MAIN) == 0) { BKE_lib_libblock_session_uid_renew(id); } if (ID_IS_ASSET(id)) { if ((flags & LIB_ID_MAKELOCAL_ASSET_DATA_CLEAR) != 0) { const IDTypeInfo *idtype_info = BKE_idtype_get_info_from_id(id); if (idtype_info && idtype_info->asset_type_info && idtype_info->asset_type_info->on_clear_asset_fn) { idtype_info->asset_type_info->on_clear_asset_fn(id, id->asset_data); } BKE_asset_metadata_free(&id->asset_data); } else { /* Assets should always have a fake user. Ensure this is the case after "Make Local". */ id_fake_user_set(id); } } /* We need to tag this IDs and all of its users, conceptually new local ID and original linked * ones are two completely different data-blocks that were virtually remapped, even though in * reality they remain the same data. For undo this info is critical now. */ DEG_id_tag_update_ex(bmain, id, ID_RECALC_SYNC_TO_EVAL); ID *id_iter; FOREACH_MAIN_ID_BEGIN (bmain, id_iter) { BKE_library_foreach_ID_link( bmain, id_iter, lib_id_clear_library_data_users_update_cb, id, IDWALK_READONLY); } FOREACH_MAIN_ID_END; /* Internal shape key blocks inside data-blocks also stores id->lib, * make sure this stays in sync (note that we do not need any explicit handling for real EMBEDDED * IDs here, this is down automatically in `lib_id_expand_local_cb()`. */ Key *key = BKE_key_from_id(id); if (key != nullptr) { BKE_lib_id_clear_library_data(bmain, &key->id, flags); } /* Even though the ID itself remain the same after being made local, from depsgraph point of view * this is a different ID. Hence we rebuild depsgraph relationships. */ DEG_relations_tag_update(bmain); } void id_lib_extern(ID *id) { if (id && ID_IS_LINKED(id)) { BLI_assert(BKE_idtype_idcode_is_linkable(GS(id->name))); if (id->tag & LIB_TAG_INDIRECT) { id->tag &= ~LIB_TAG_INDIRECT; id->flag &= ~LIB_INDIRECT_WEAK_LINK; id->tag |= LIB_TAG_EXTERN; id->lib->runtime.parent = nullptr; } } } void id_lib_indirect_weak_link(ID *id) { if (id && ID_IS_LINKED(id)) { BLI_assert(BKE_idtype_idcode_is_linkable(GS(id->name))); if (id->tag & LIB_TAG_INDIRECT) { id->flag |= LIB_INDIRECT_WEAK_LINK; } } } void id_us_ensure_real(ID *id) { if (id) { const int limit = ID_FAKE_USERS(id); id->tag |= LIB_TAG_EXTRAUSER; if (id->us <= limit) { if (id->us < limit || ((id->us == limit) && (id->tag & LIB_TAG_EXTRAUSER_SET))) { CLOG_ERROR(&LOG, "ID user count error: %s (from '%s')", id->name, id->lib ? id->lib->runtime.filepath_abs : "[Main]"); } id->us = limit + 1; id->tag |= LIB_TAG_EXTRAUSER_SET; } } } void id_us_clear_real(ID *id) { if (id && (id->tag & LIB_TAG_EXTRAUSER)) { if (id->tag & LIB_TAG_EXTRAUSER_SET) { id->us--; BLI_assert(id->us >= ID_FAKE_USERS(id)); } id->tag &= ~(LIB_TAG_EXTRAUSER | LIB_TAG_EXTRAUSER_SET); } } void id_us_plus_no_lib(ID *id) { if (id) { if ((id->tag & LIB_TAG_EXTRAUSER) && (id->tag & LIB_TAG_EXTRAUSER_SET)) { BLI_assert(id->us >= 1); /* No need to increase count, just tag extra user as no more set. * Avoids annoying & inconsistent +1 in user count. */ id->tag &= ~LIB_TAG_EXTRAUSER_SET; } else { BLI_assert(id->us >= 0); id->us++; } } } void id_us_plus(ID *id) { if (id) { id_us_plus_no_lib(id); id_lib_extern(id); } } void id_us_min(ID *id) { if (id) { const int limit = ID_FAKE_USERS(id); if (id->us <= limit) { if (!ID_TYPE_IS_DEPRECATED(GS(id->name))) { /* Do not assert on deprecated ID types, we cannot really ensure that their ID * reference-counting is valid. */ CLOG_ERROR(&LOG, "ID user decrement error: %s (from '%s'): %d <= %d", id->name, id->lib ? id->lib->runtime.filepath_abs : "[Main]", id->us, limit); } id->us = limit; } else { id->us--; } if ((id->us == limit) && (id->tag & LIB_TAG_EXTRAUSER)) { /* We need an extra user here, but never actually incremented user count for it so far, * do it now. */ id_us_ensure_real(id); } } } void id_fake_user_set(ID *id) { if (id && !(id->flag & LIB_FAKEUSER)) { id->flag |= LIB_FAKEUSER; id_us_plus(id); } } void id_fake_user_clear(ID *id) { if (id && (id->flag & LIB_FAKEUSER)) { id->flag &= ~LIB_FAKEUSER; id_us_min(id); } } void BKE_id_newptr_and_tag_clear(ID *id) { /* We assume that if this ID has no new ID, its embedded data has not either. */ if (id->newid == nullptr) { return; } id->newid->tag &= ~LIB_TAG_NEW; id->newid = nullptr; /* Deal with embedded data too. */ /* NOTE: even though ShapeKeys are not technically embedded data currently, they behave as such * in most cases, so for sake of consistency treat them as such here. Also mirrors the behavior * in `BKE_lib_id_make_local`. */ Key *key = BKE_key_from_id(id); if (key != nullptr) { BKE_id_newptr_and_tag_clear(&key->id); } bNodeTree *ntree = blender::bke::ntreeFromID(id); if (ntree != nullptr) { BKE_id_newptr_and_tag_clear(&ntree->id); } if (GS(id->name) == ID_SCE) { Collection *master_collection = ((Scene *)id)->master_collection; if (master_collection != nullptr) { BKE_id_newptr_and_tag_clear(&master_collection->id); } } } static int lib_id_expand_local_cb(LibraryIDLinkCallbackData *cb_data) { Main *bmain = cb_data->bmain; ID *self_id = cb_data->self_id; ID **id_pointer = cb_data->id_pointer; int const cb_flag = cb_data->cb_flag; const int flags = POINTER_AS_INT(cb_data->user_data); if (cb_flag & IDWALK_CB_LOOPBACK) { /* We should never have anything to do with loop-back pointers here. */ return IDWALK_RET_NOP; } if (cb_flag & (IDWALK_CB_EMBEDDED | IDWALK_CB_EMBEDDED_NOT_OWNING)) { /* Embedded data-blocks need to be made fully local as well. * Note however that in some cases (when owner ID had to be duplicated instead of being made * local directly), its embedded IDs should also have already been duplicated, and hence be * fully local here already. */ if (*id_pointer != nullptr && ID_IS_LINKED(*id_pointer)) { BLI_assert(*id_pointer != self_id); BKE_lib_id_clear_library_data(bmain, *id_pointer, flags); } return IDWALK_RET_NOP; } /* Can happen that we get un-linkable ID here, e.g. with shape-key referring to itself * (through drivers)... * Just skip it, shape key can only be either indirectly linked, or fully local, period. * And let's curse one more time that stupid useless shape-key ID type! */ if (*id_pointer && *id_pointer != self_id && BKE_idtype_idcode_is_linkable(GS((*id_pointer)->name))) { id_lib_extern(*id_pointer); } return IDWALK_RET_NOP; } void BKE_lib_id_expand_local(Main *bmain, ID *id, const int flags) { BKE_library_foreach_ID_link( bmain, id, lib_id_expand_local_cb, POINTER_FROM_INT(flags), IDWALK_READONLY); } /** * Ensure new (copied) ID is fully made local. */ void lib_id_copy_ensure_local(Main *bmain, const ID *old_id, ID *new_id, const int flags) { if (ID_IS_LINKED(old_id)) { BKE_lib_id_expand_local(bmain, new_id, flags); lib_id_library_local_paths(bmain, old_id->lib, new_id); } } void BKE_lib_id_make_local_generic_action_define( Main *bmain, ID *id, int flags, bool *r_force_local, bool *r_force_copy) { bool force_local = (flags & LIB_ID_MAKELOCAL_FORCE_LOCAL) != 0; bool force_copy = (flags & LIB_ID_MAKELOCAL_FORCE_COPY) != 0; BLI_assert(force_copy == false || force_copy != force_local); if (force_local || force_copy) { /* Already set by caller code, nothing to do here. */ *r_force_local = force_local; *r_force_copy = force_copy; return; } const bool lib_local = (flags & LIB_ID_MAKELOCAL_FULL_LIBRARY) != 0; bool is_local = false, is_lib = false; /* - no user (neither lib nor local): make local (happens e.g. with UI-used only data). * - only lib users: do nothing (unless force_local is set) * - only local users: make local * - mixed: make copy * In case we make a whole lib's content local, * we always want to localize, and we skip remapping (done later). */ BKE_library_ID_test_usages(bmain, id, &is_local, &is_lib); if (!lib_local && !is_local && !is_lib) { force_local = true; } else if (lib_local || is_local) { if (!is_lib) { force_local = true; } else { force_copy = true; } } *r_force_local = force_local; *r_force_copy = force_copy; } void BKE_lib_id_make_local_generic(Main *bmain, ID *id, const int flags) { if (!ID_IS_LINKED(id)) { return; } bool force_local, force_copy; BKE_lib_id_make_local_generic_action_define(bmain, id, flags, &force_local, &force_copy); if (force_local) { BKE_lib_id_clear_library_data(bmain, id, flags); if ((flags & LIB_ID_MAKELOCAL_LIBOVERRIDE_CLEAR) != 0) { BKE_lib_override_library_make_local(bmain, id); } BKE_lib_id_expand_local(bmain, id, flags); } else if (force_copy) { const int copy_flags = (LIB_ID_COPY_DEFAULT | ((flags & LIB_ID_MAKELOCAL_LIBOVERRIDE_CLEAR) != 0 ? LIB_ID_COPY_NO_LIB_OVERRIDE : 0)); ID *id_new = BKE_id_copy_ex(bmain, id, nullptr, copy_flags); /* Should not fail in expected use cases, * but a few ID types cannot be copied (LIB, WM, SCR...). */ if (id_new != nullptr) { id_new->us = 0; /* setting newid is mandatory for complex make_lib_local logic... */ ID_NEW_SET(id, id_new); Key *key = BKE_key_from_id(id), *key_new = BKE_key_from_id(id); if (key && key_new) { ID_NEW_SET(key, key_new); } bNodeTree *ntree = blender::bke::ntreeFromID(id), *ntree_new = blender::bke::ntreeFromID(id_new); if (ntree && ntree_new) { ID_NEW_SET(ntree, ntree_new); } if (GS(id->name) == ID_SCE) { Collection *master_collection = ((Scene *)id)->master_collection, *master_collection_new = ((Scene *)id_new)->master_collection; if (master_collection && master_collection_new) { ID_NEW_SET(master_collection, master_collection_new); } } const bool lib_local = (flags & LIB_ID_MAKELOCAL_FULL_LIBRARY) != 0; if (!lib_local) { BKE_libblock_remap(bmain, id, id_new, ID_REMAP_SKIP_INDIRECT_USAGE); } } } } bool BKE_lib_id_make_local(Main *bmain, ID *id, const int flags) { const bool lib_local = (flags & LIB_ID_MAKELOCAL_FULL_LIBRARY) != 0; /* We don't care whether ID is directly or indirectly linked * in case we are making a whole lib local... */ if (!lib_local && (id->tag & LIB_TAG_INDIRECT)) { return false; } const IDTypeInfo *idtype_info = BKE_idtype_get_info_from_id(id); if (idtype_info == nullptr) { BLI_assert_msg(0, "IDType Missing IDTypeInfo"); return false; } BLI_assert((idtype_info->flags & IDTYPE_FLAGS_NO_LIBLINKING) == 0); if (idtype_info->make_local != nullptr) { idtype_info->make_local(bmain, id, flags); } else { BKE_lib_id_make_local_generic(bmain, id, flags); } return true; } struct IDCopyLibManagementData { const ID *id_src; ID *id_dst; int flag; }; /** Increases user-count as required, and remap self ID pointers. */ static int id_copy_libmanagement_cb(LibraryIDLinkCallbackData *cb_data) { ID **id_pointer = cb_data->id_pointer; ID *id = *id_pointer; const int cb_flag = cb_data->cb_flag; IDCopyLibManagementData *data = static_cast(cb_data->user_data); /* Remap self-references to new copied ID. */ if (id == data->id_src) { /* We cannot use self_id here, it is not *always* id_dst (thanks to confounded node-trees!). */ id = *id_pointer = data->id_dst; } /* Increase used IDs refcount if needed and required. */ if ((data->flag & LIB_ID_CREATE_NO_USER_REFCOUNT) == 0 && (cb_flag & IDWALK_CB_USER)) { if ((data->flag & LIB_ID_CREATE_NO_MAIN) != 0) { BLI_assert(cb_data->self_id->tag & LIB_TAG_NO_MAIN); id_us_plus_no_lib(id); } else { id_us_plus(id); } } return IDWALK_RET_NOP; } bool BKE_id_copy_is_allowed(const ID *id) { #define LIB_ID_TYPES_NOCOPY ID_LI, ID_SCR, ID_WM, ID_WS /* Not supported */ return !ID_TYPE_IS_DEPRECATED(GS(id->name)) && !ELEM(GS(id->name), LIB_ID_TYPES_NOCOPY); #undef LIB_ID_TYPES_NOCOPY } ID *BKE_id_copy_in_lib(Main *bmain, std::optional owner_library, const ID *id, const ID *new_owner_id, ID **r_newid, const int flag) { ID *newid = (r_newid != nullptr) ? *r_newid : nullptr; BLI_assert_msg(newid || (flag & LIB_ID_CREATE_NO_ALLOCATE) == 0, "Copying with 'no allocate' behavior should always get a non-null new ID buffer"); /* Make sure destination pointer is all good. */ if ((flag & LIB_ID_CREATE_NO_ALLOCATE) == 0) { newid = nullptr; } else { if (!newid) { /* Invalid case, already caught by the assert above. */ return nullptr; } /* Allow some garbage non-initialized memory to go in, and clean it up here. */ const size_t size = BKE_libblock_get_alloc_info(GS(id->name), nullptr); memset(newid, 0, size); } /* Early output if source is nullptr. */ if (id == nullptr) { return nullptr; } const IDTypeInfo *idtype_info = BKE_idtype_get_info_from_id(id); if (idtype_info != nullptr) { if ((idtype_info->flags & IDTYPE_FLAGS_NO_COPY) != 0) { return nullptr; } BKE_libblock_copy_in_lib(bmain, owner_library, id, new_owner_id, &newid, flag); if (idtype_info->copy_data != nullptr) { idtype_info->copy_data(bmain, owner_library, newid, id, flag); } } else { BLI_assert_msg(0, "IDType Missing IDTypeInfo"); } BLI_assert_msg(newid, "Could not get an allocated new ID to copy into"); if (!newid) { return nullptr; } /* Update ID refcount, remap pointers to self in new ID. */ IDCopyLibManagementData data{}; data.id_src = id; data.id_dst = newid; data.flag = flag; BKE_library_foreach_ID_link(bmain, newid, id_copy_libmanagement_cb, &data, IDWALK_NOP); /* Do not make new copy local in case we are copying outside of main... * XXX TODO: is this behavior OK, or should we need a separate flag to control that? */ if ((flag & LIB_ID_CREATE_NO_MAIN) == 0) { BLI_assert(!owner_library || newid->lib == *owner_library); /* Expanding local linked ID usages should never be needed with embedded IDs - this will be * handled together with their owner ID copying code. */ if (!ID_IS_LINKED(newid) && (newid->flag & LIB_EMBEDDED_DATA) == 0) { lib_id_copy_ensure_local(bmain, id, newid, 0); } } else { /* NOTE: Do not call `ensure_local` for IDs copied outside of Main, even if they do become * local. * * Most of the time, this would not be the desired behavior currently. * * In the few cases where this is actually needed (e.g. from liboverride resync code, see * #lib_override_library_create_from), calling code is responsible for this. */ newid->lib = owner_library ? *owner_library : id->lib; } if (r_newid != nullptr) { *r_newid = newid; } return newid; } ID *BKE_id_copy_ex(Main *bmain, const ID *id, ID **r_newid, const int flag) { return BKE_id_copy_in_lib(bmain, std::nullopt, id, nullptr, r_newid, flag); } ID *BKE_id_copy(Main *bmain, const ID *id) { return BKE_id_copy_in_lib(bmain, std::nullopt, id, nullptr, nullptr, LIB_ID_COPY_DEFAULT); } ID *BKE_id_copy_for_duplicate(Main *bmain, ID *id, const eDupli_ID_Flags duplicate_flags, const int copy_flags) { if (id == nullptr) { return id; } if (id->newid == nullptr) { const bool do_linked_id = (duplicate_flags & USER_DUP_LINKED_ID) != 0; if (!(do_linked_id || !ID_IS_LINKED(id))) { return id; } ID *id_new = BKE_id_copy_ex(bmain, id, nullptr, copy_flags); /* Copying add one user by default, need to get rid of that one. */ id_us_min(id_new); ID_NEW_SET(id, id_new); /* Shape keys are always copied with their owner ID, by default. */ ID *key_new = (ID *)BKE_key_from_id(id_new); ID *key = (ID *)BKE_key_from_id(id); if (key != nullptr) { ID_NEW_SET(key, key_new); } /* NOTE: embedded data (root node-trees and master collections) should never be referenced by * anything else, so we do not need to set their newid pointer and flag. */ BKE_animdata_duplicate_id_action(bmain, id_new, duplicate_flags); if (key_new != nullptr) { BKE_animdata_duplicate_id_action(bmain, key_new, duplicate_flags); } /* Note that actions of embedded data (root node-trees and master collections) are handled * by #BKE_animdata_duplicate_id_action as well. */ } return id->newid; } static int foreach_assign_id_to_orig_callback(LibraryIDLinkCallbackData *cb_data) { ID **id_p = cb_data->id_pointer; if (*id_p) { ID *id = *id_p; *id_p = DEG_get_original_id(id); /* If the ID changes increase the user count. * * This means that the reference to evaluated ID has been changed with a reference to the * original ID which implies that the user count of the original ID is increased. * * The evaluated IDs do not maintain their user counter, so do not change it to avoid issues * with the user counter going negative. */ if (*id_p != id) { if ((cb_data->cb_flag & IDWALK_CB_USER) != 0) { id_us_plus(*id_p); } } } return IDWALK_RET_NOP; } ID *BKE_id_copy_for_use_in_bmain(Main *bmain, const ID *id) { ID *newid = BKE_id_copy(bmain, id); if (newid == nullptr) { return newid; } /* Assign ID references directly used by the given ID to their original complementary parts. * * For example, when is called on an evaluated object will assign object->data to its original * pointer, the evaluated object->data will be kept unchanged. */ BKE_library_foreach_ID_link( nullptr, newid, foreach_assign_id_to_orig_callback, nullptr, IDWALK_NOP); /* Shape keys reference on evaluated ID is preserved to keep driver paths available, but the key * data is likely to be invalid now due to modifiers, so clear the shape key reference avoiding * any possible shape corruption. */ if (DEG_is_evaluated_id(id)) { Key **key_p = BKE_key_from_id_p(newid); if (key_p) { *key_p = nullptr; } } return newid; } static void id_embedded_swap(ID **embedded_id_a, ID **embedded_id_b, const bool do_full_id, IDRemapper *remapper_id_a, IDRemapper *remapper_id_b); /** * Does a mere memory swap over the whole IDs data (including type-specific memory). * \note Most internal ID data itself is not swapped (only IDProperties are). */ static void id_swap(Main *bmain, ID *id_a, ID *id_b, const bool do_full_id, const bool do_self_remap, IDRemapper *input_remapper_id_a, IDRemapper *input_remapper_id_b, const int self_remap_flags) { BLI_assert(GS(id_a->name) == GS(id_b->name)); IDRemapper *remapper_id_a = input_remapper_id_a; IDRemapper *remapper_id_b = input_remapper_id_b; if (do_self_remap) { if (remapper_id_a == nullptr) { remapper_id_a = MEM_new(__func__); } if (remapper_id_b == nullptr) { remapper_id_b = MEM_new(__func__); } } const IDTypeInfo *id_type = BKE_idtype_get_info_from_id(id_a); BLI_assert(id_type != nullptr); const size_t id_struct_size = id_type->struct_size; const ID id_a_back = *id_a; const ID id_b_back = *id_b; char *id_swap_buff = static_cast(alloca(id_struct_size)); memcpy(id_swap_buff, id_a, id_struct_size); memcpy(id_a, id_b, id_struct_size); memcpy(id_b, id_swap_buff, id_struct_size); if (!do_full_id) { /* Restore original ID's internal data. */ *id_a = id_a_back; *id_b = id_b_back; /* Exception: IDProperties. */ id_a->properties = id_b_back.properties; id_b->properties = id_a_back.properties; /* Exception: recalc flags. */ id_a->recalc = id_b_back.recalc; id_b->recalc = id_a_back.recalc; } id_embedded_swap((ID **)blender::bke::BKE_ntree_ptr_from_id(id_a), (ID **)blender::bke::BKE_ntree_ptr_from_id(id_b), do_full_id, remapper_id_a, remapper_id_b); if (GS(id_a->name) == ID_SCE) { Scene *scene_a = (Scene *)id_a; Scene *scene_b = (Scene *)id_b; id_embedded_swap((ID **)&scene_a->master_collection, (ID **)&scene_b->master_collection, do_full_id, remapper_id_a, remapper_id_b); } if (remapper_id_a != nullptr) { remapper_id_a->add(id_b, id_a); } if (remapper_id_b != nullptr) { remapper_id_b->add(id_a, id_b); } /* Finalize remapping of internal references to self broken by swapping, if requested. */ if (do_self_remap) { BKE_libblock_relink_multiple( bmain, {id_a}, ID_REMAP_TYPE_REMAP, *remapper_id_a, self_remap_flags); BKE_libblock_relink_multiple( bmain, {id_b}, ID_REMAP_TYPE_REMAP, *remapper_id_b, self_remap_flags); } if (input_remapper_id_a == nullptr && remapper_id_a != nullptr) { MEM_delete(remapper_id_a); } if (input_remapper_id_b == nullptr && remapper_id_b != nullptr) { MEM_delete(remapper_id_b); } } /* Conceptually, embedded IDs are part of their owner's data. However, some parts of the code * (like e.g. the depsgraph) may treat them as independent IDs, so swapping them here and * switching their pointers in the owner IDs allows to help not break cached relationships and * such (by preserving the pointer values). */ static void id_embedded_swap(ID **embedded_id_a, ID **embedded_id_b, const bool do_full_id, IDRemapper *remapper_id_a, IDRemapper *remapper_id_b) { if (embedded_id_a != nullptr && *embedded_id_a != nullptr) { BLI_assert(embedded_id_b != nullptr); if (*embedded_id_b == nullptr) { /* Cannot swap anything if one of the embedded IDs is nullptr. */ return; } /* Do not remap internal references to itself here, since embedded IDs pointers also need to be * potentially remapped in owner ID's data, which will also handle embedded IDs data. */ id_swap(nullptr, *embedded_id_a, *embedded_id_b, do_full_id, false, remapper_id_a, remapper_id_b, 0); /* Manual 'remap' of owning embedded pointer in owner ID. */ std::swap(*embedded_id_a, *embedded_id_b); /* Restore internal pointers to the swapped embedded IDs in their owners' data. This also * includes the potential self-references inside the embedded IDs themselves. */ if (remapper_id_a != nullptr) { remapper_id_a->add(*embedded_id_b, *embedded_id_a); } if (remapper_id_b != nullptr) { remapper_id_b->add(*embedded_id_a, *embedded_id_b); } } } void BKE_lib_id_swap( Main *bmain, ID *id_a, ID *id_b, const bool do_self_remap, const int self_remap_flags) { id_swap(bmain, id_a, id_b, false, do_self_remap, nullptr, nullptr, self_remap_flags); } void BKE_lib_id_swap_full( Main *bmain, ID *id_a, ID *id_b, const bool do_self_remap, const int self_remap_flags) { id_swap(bmain, id_a, id_b, true, do_self_remap, nullptr, nullptr, self_remap_flags); } bool id_single_user(bContext *C, ID *id, PointerRNA *ptr, PropertyRNA *prop) { ID *newid = nullptr; if (id && (ID_REAL_USERS(id) > 1)) { /* If property isn't editable, * we're going to have an extra block hanging around until we save. */ if (RNA_property_editable(ptr, prop)) { Main *bmain = CTX_data_main(C); /* copy animation actions too */ newid = BKE_id_copy_ex(bmain, id, nullptr, LIB_ID_COPY_DEFAULT | LIB_ID_COPY_ACTIONS); if (newid != nullptr) { /* us is 1 by convention with new IDs, but RNA_property_pointer_set * will also increment it, decrement it here. */ id_us_min(newid); /* assign copy */ PointerRNA idptr = RNA_id_pointer_create(newid); RNA_property_pointer_set(ptr, prop, idptr, nullptr); RNA_property_update(C, ptr, prop); /* tag grease pencil data-block and disable onion */ if (GS(id->name) == ID_GD_LEGACY) { DEG_id_tag_update(id, ID_RECALC_TRANSFORM | ID_RECALC_GEOMETRY); DEG_id_tag_update(newid, ID_RECALC_TRANSFORM | ID_RECALC_GEOMETRY); bGPdata *gpd = (bGPdata *)newid; gpd->flag &= ~GP_DATA_SHOW_ONIONSKINS; } return true; } } } return false; } static int libblock_management_us_plus(LibraryIDLinkCallbackData *cb_data) { ID **id_pointer = cb_data->id_pointer; const int cb_flag = cb_data->cb_flag; if (cb_flag & IDWALK_CB_USER) { id_us_plus(*id_pointer); } if (cb_flag & IDWALK_CB_USER_ONE) { id_us_ensure_real(*id_pointer); } return IDWALK_RET_NOP; } static int libblock_management_us_min(LibraryIDLinkCallbackData *cb_data) { ID **id_pointer = cb_data->id_pointer; const int cb_flag = cb_data->cb_flag; if (cb_flag & IDWALK_CB_USER) { id_us_min(*id_pointer); } /* We can do nothing in IDWALK_CB_USER_ONE case! */ return IDWALK_RET_NOP; } void BKE_libblock_management_main_add(Main *bmain, void *idv) { ID *id = static_cast(idv); BLI_assert(bmain != nullptr); if ((id->tag & LIB_TAG_NO_MAIN) == 0) { return; } if ((id->tag & LIB_TAG_NOT_ALLOCATED) != 0) { /* We cannot add non-allocated ID to Main! */ return; } /* We cannot allow non-userrefcounting IDs in Main database! */ if ((id->tag & LIB_TAG_NO_USER_REFCOUNT) != 0) { BKE_library_foreach_ID_link(bmain, id, libblock_management_us_plus, nullptr, IDWALK_NOP); } ListBase *lb = which_libbase(bmain, GS(id->name)); BKE_main_lock(bmain); BLI_addtail(lb, id); /* We need to allow adding extra datablocks into libraries too, e.g. to support generating new * overrides for recursive resync. */ BKE_id_new_name_validate(bmain, lb, id, nullptr, true); /* alphabetic insertion: is in new_id */ id->tag &= ~(LIB_TAG_NO_MAIN | LIB_TAG_NO_USER_REFCOUNT); bmain->is_memfile_undo_written = false; BKE_main_unlock(bmain); BKE_lib_libblock_session_uid_ensure(id); } void BKE_libblock_management_main_remove(Main *bmain, void *idv) { ID *id = static_cast(idv); BLI_assert(bmain != nullptr); if ((id->tag & LIB_TAG_NO_MAIN) != 0) { return; } /* For now, allow userrefcounting IDs to get out of Main - can be handy in some cases... */ ListBase *lb = which_libbase(bmain, GS(id->name)); BKE_main_lock(bmain); BLI_remlink(lb, id); BKE_main_namemap_remove_name(bmain, id, id->name + 2); id->tag |= LIB_TAG_NO_MAIN; bmain->is_memfile_undo_written = false; BKE_main_unlock(bmain); } void BKE_libblock_management_usercounts_set(Main *bmain, void *idv) { ID *id = static_cast(idv); if ((id->tag & LIB_TAG_NO_USER_REFCOUNT) == 0) { return; } BKE_library_foreach_ID_link(bmain, id, libblock_management_us_plus, nullptr, IDWALK_NOP); id->tag &= ~LIB_TAG_NO_USER_REFCOUNT; } void BKE_libblock_management_usercounts_clear(Main *bmain, void *idv) { ID *id = static_cast(idv); /* We do not allow IDs in Main database to not be userrefcounting. */ if ((id->tag & LIB_TAG_NO_USER_REFCOUNT) != 0 || (id->tag & LIB_TAG_NO_MAIN) != 0) { return; } BKE_library_foreach_ID_link(bmain, id, libblock_management_us_min, nullptr, IDWALK_NOP); id->tag |= LIB_TAG_NO_USER_REFCOUNT; } void BKE_main_id_tag_listbase(ListBase *lb, const int tag, const bool value) { ID *id; if (value) { for (id = static_cast(lb->first); id; id = static_cast(id->next)) { id->tag |= tag; } } else { const int ntag = ~tag; for (id = static_cast(lb->first); id; id = static_cast(id->next)) { id->tag &= ntag; } } } void BKE_main_id_tag_idcode(Main *mainvar, const short type, const int tag, const bool value) { ListBase *lb = which_libbase(mainvar, type); BKE_main_id_tag_listbase(lb, tag, value); } void BKE_main_id_tag_all(Main *mainvar, const int tag, const bool value) { ListBase *lbarray[INDEX_ID_MAX]; int a; a = set_listbasepointers(mainvar, lbarray); while (a--) { BKE_main_id_tag_listbase(lbarray[a], tag, value); } } void BKE_main_id_flag_listbase(ListBase *lb, const int flag, const bool value) { ID *id; if (value) { for (id = static_cast(lb->first); id; id = static_cast(id->next)) { id->tag |= flag; } } else { const int nflag = ~flag; for (id = static_cast(lb->first); id; id = static_cast(id->next)) { id->tag &= nflag; } } } void BKE_main_id_flag_all(Main *bmain, const int flag, const bool value) { ListBase *lbarray[INDEX_ID_MAX]; int a; a = set_listbasepointers(bmain, lbarray); while (a--) { BKE_main_id_flag_listbase(lbarray[a], flag, value); } } void BKE_main_id_repair_duplicate_names_listbase(Main *bmain, ListBase *lb) { int lb_len = 0; LISTBASE_FOREACH (ID *, id, lb) { if (!ID_IS_LINKED(id)) { lb_len += 1; } } if (lb_len <= 1) { return; } /* Fill an array because renaming sorts. */ ID **id_array = static_cast(MEM_mallocN(sizeof(*id_array) * lb_len, __func__)); GSet *gset = BLI_gset_str_new_ex(__func__, lb_len); int i = 0; LISTBASE_FOREACH (ID *, id, lb) { if (!ID_IS_LINKED(id)) { id_array[i] = id; i++; } } for (i = 0; i < lb_len; i++) { if (!BLI_gset_add(gset, id_array[i]->name + 2)) { BKE_id_new_name_validate(bmain, lb, id_array[i], nullptr, false); } } BLI_gset_free(gset, nullptr); MEM_freeN(id_array); } void BKE_main_lib_objects_recalc_all(Main *bmain) { Object *ob; /* flag for full recalc */ for (ob = static_cast(bmain->objects.first); ob; ob = static_cast(ob->id.next)) { if (ID_IS_LINKED(ob)) { DEG_id_tag_update(&ob->id, ID_RECALC_TRANSFORM | ID_RECALC_GEOMETRY | ID_RECALC_ANIMATION); } } DEG_id_type_tag(bmain, ID_OB); } /* *********** ALLOC AND FREE ***************** * * BKE_libblock_free(ListBase *lb, ID *id ) * provide a list-basis and data-block, but only ID is read * * void *BKE_libblock_alloc(ListBase *lb, type, name) * inserts in list and returns a new ID * * **************************** */ size_t BKE_libblock_get_alloc_info(short type, const char **name) { const IDTypeInfo *id_type = BKE_idtype_get_info_from_idcode(type); if (id_type == nullptr) { if (name != nullptr) { *name = nullptr; } return 0; } if (name != nullptr) { *name = id_type->name; } return id_type->struct_size; } void *BKE_libblock_alloc_notest(short type) { const char *name; size_t size = BKE_libblock_get_alloc_info(type, &name); if (size != 0) { return MEM_callocN(size, name); } BLI_assert_msg(0, "Request to allocate unknown data type"); return nullptr; } void *BKE_libblock_alloc_in_lib(Main *bmain, std::optional owner_library, short type, const char *name, const int flag) { BLI_assert((flag & LIB_ID_CREATE_NO_ALLOCATE) == 0); BLI_assert((flag & LIB_ID_CREATE_NO_MAIN) != 0 || bmain != nullptr); BLI_assert((flag & LIB_ID_CREATE_NO_MAIN) != 0 || (flag & LIB_ID_CREATE_LOCAL) == 0); ID *id = static_cast(BKE_libblock_alloc_notest(type)); if (id) { if ((flag & LIB_ID_CREATE_NO_MAIN) != 0) { id->tag |= LIB_TAG_NO_MAIN; } if ((flag & LIB_ID_CREATE_NO_USER_REFCOUNT) != 0) { id->tag |= LIB_TAG_NO_USER_REFCOUNT; } if (flag & LIB_ID_CREATE_LOCAL) { id->tag |= LIB_TAG_LOCALIZED; } id->icon_id = 0; *((short *)id->name) = type; if ((flag & LIB_ID_CREATE_NO_USER_REFCOUNT) == 0) { id->us = 1; } if ((flag & LIB_ID_CREATE_NO_MAIN) == 0) { /* Note that 2.8x versioning has tested not to cause conflicts. Node trees are * skipped in this check to allow adding a geometry node tree for versioning. */ BLI_assert(bmain->is_locked_for_linking == false || ELEM(type, ID_WS, ID_GR, ID_NT)); ListBase *lb = which_libbase(bmain, type); /* This is important in 'readfile doversion after liblink' context mainly, but is a good * behavior for consistency in general: ID created for a Main should get that main's current * library pointer. * * NOTE: A bit convoluted. * - When Main has a defined `curlib`, it is assumed to be a split main containing only IDs * from that library. In that case, the library can be set later, and it avoids * synchronization issues in the namemap between the one of that temp 'library' Main and * the library ID runtime namemap itself. In a way, the ID can be assumed local to the * current Main, for its assignment to this Main. * - In all other cases, the Main is assumed 'complete', i.e. containing all local and * linked IDs, In that case, it is critical that the ID gets the correct library assigned * now, to ensure that the call to #BKE_id_new_name_validate gives a fully valid result * once it has been assigned to the current Main. */ if (bmain->curlib) { id->lib = nullptr; } else { id->lib = owner_library ? *owner_library : nullptr; } BKE_main_lock(bmain); BLI_addtail(lb, id); BKE_id_new_name_validate(bmain, lb, id, name, true); bmain->is_memfile_undo_written = false; /* alphabetic insertion: is in new_id */ BKE_main_unlock(bmain); /* Split Main case, now the ID should get the Main's #curlib. */ if (bmain->curlib) { BLI_assert(!owner_library || *owner_library == bmain->curlib); id->lib = bmain->curlib; } /* This assert avoids having to keep name_map consistency when changing the library of an ID, * if this check is not true anymore it will have to be done here too. */ BLI_assert(bmain->curlib == nullptr || bmain->curlib->runtime.name_map == nullptr); /* TODO: to be removed from here! */ if ((flag & LIB_ID_CREATE_NO_DEG_TAG) == 0) { DEG_id_type_tag(bmain, type); } } else { BLI_strncpy(id->name + 2, name, sizeof(id->name) - 2); id->lib = owner_library ? *owner_library : nullptr; } /* We also need to ensure a valid `session_uid` for some non-main data (like embedded IDs). * IDs not allocated however should not need those (this would e.g. avoid generating session * uids for depsgraph evaluated IDs, if it was using this function). */ if ((flag & LIB_ID_CREATE_NO_ALLOCATE) == 0) { BKE_lib_libblock_session_uid_ensure(id); } } return id; } void *BKE_libblock_alloc(Main *bmain, short type, const char *name, const int flag) { return BKE_libblock_alloc_in_lib(bmain, std::nullopt, type, name, flag); } void BKE_libblock_init_empty(ID *id) { const IDTypeInfo *idtype_info = BKE_idtype_get_info_from_id(id); if (idtype_info != nullptr) { if (idtype_info->init_data != nullptr) { idtype_info->init_data(id); } return; } BLI_assert_msg(0, "IDType Missing IDTypeInfo"); } void BKE_libblock_runtime_reset_remapping_status(ID *id) { id->runtime.remap.status = 0; id->runtime.remap.skipped_refcounted = 0; id->runtime.remap.skipped_direct = 0; id->runtime.remap.skipped_indirect = 0; } /* ********** ID session-wise UID management. ********** */ static uint global_session_uid = 0; void BKE_lib_libblock_session_uid_ensure(ID *id) { if (id->session_uid == MAIN_ID_SESSION_UID_UNSET) { BLI_assert((id->tag & LIB_TAG_TEMP_MAIN) == 0); /* Caller must ensure this. */ id->session_uid = atomic_add_and_fetch_uint32(&global_session_uid, 1); /* In case overflow happens, still assign a valid ID. This way opening files many times works * correctly. */ if (UNLIKELY(id->session_uid == MAIN_ID_SESSION_UID_UNSET)) { id->session_uid = atomic_add_and_fetch_uint32(&global_session_uid, 1); } } } void BKE_lib_libblock_session_uid_renew(ID *id) { id->session_uid = MAIN_ID_SESSION_UID_UNSET; BKE_lib_libblock_session_uid_ensure(id); } void *BKE_id_new_in_lib(Main *bmain, std::optional owner_library, const short type, const char *name) { BLI_assert(bmain != nullptr); if (name == nullptr) { name = DATA_(BKE_idtype_idcode_to_name(type)); } ID *id = static_cast(BKE_libblock_alloc_in_lib(bmain, owner_library, type, name, 0)); BKE_libblock_init_empty(id); return id; } void *BKE_id_new(Main *bmain, const short type, const char *name) { return BKE_id_new_in_lib(bmain, std::nullopt, type, name); } void *BKE_id_new_nomain(const short type, const char *name) { if (name == nullptr) { name = DATA_(BKE_idtype_idcode_to_name(type)); } ID *id = static_cast(BKE_libblock_alloc( nullptr, type, name, LIB_ID_CREATE_NO_MAIN | LIB_ID_CREATE_NO_USER_REFCOUNT | LIB_ID_CREATE_NO_DEG_TAG)); BKE_libblock_init_empty(id); return id; } void BKE_libblock_copy_in_lib(Main *bmain, std::optional owner_library, const ID *id, const ID *new_owner_id, ID **r_newid, const int orig_flag) { ID *new_id = *r_newid; int flag = orig_flag; const bool is_embedded_id = (id->flag & LIB_EMBEDDED_DATA) != 0; BLI_assert((flag & LIB_ID_CREATE_NO_MAIN) != 0 || bmain != nullptr); BLI_assert((flag & LIB_ID_CREATE_NO_MAIN) != 0 || (flag & LIB_ID_CREATE_NO_ALLOCATE) == 0); BLI_assert((flag & LIB_ID_CREATE_NO_MAIN) != 0 || (flag & LIB_ID_CREATE_LOCAL) == 0); /* Embedded ID handling. * * NOTE: This makes copying code of embedded IDs non-reentrant (i.e. copying an embedded ID as * part of another embedded ID would not work properly). This is not an issue currently, but may * need to be addressed in the future. */ if ((bmain != nullptr) && is_embedded_id) { flag |= LIB_ID_CREATE_NO_MAIN; } /* The id->flag bits to copy over. */ const int copy_idflag_mask = LIB_EMBEDDED_DATA; if ((flag & LIB_ID_CREATE_NO_ALLOCATE) != 0) { /* r_newid already contains pointer to allocated memory. */ /* TODO: do we want to memset(0) whole mem before filling it? */ STRNCPY(new_id->name, id->name); new_id->us = 0; new_id->tag |= LIB_TAG_NOT_ALLOCATED | LIB_TAG_NO_MAIN | LIB_TAG_NO_USER_REFCOUNT; new_id->lib = owner_library ? *owner_library : id->lib; /* TODO: Do we want/need to copy more from ID struct itself? */ } else { new_id = static_cast( BKE_libblock_alloc_in_lib(bmain, owner_library, GS(id->name), id->name + 2, flag)); } BLI_assert(new_id != nullptr); if ((flag & LIB_ID_COPY_SET_COPIED_ON_WRITE) != 0) { new_id->tag |= LIB_TAG_COPIED_ON_EVAL; } else { new_id->tag &= ~LIB_TAG_COPIED_ON_EVAL; } const size_t id_len = BKE_libblock_get_alloc_info(GS(new_id->name), nullptr); const size_t id_offset = sizeof(ID); if (int(id_len) - int(id_offset) > 0) { /* signed to allow neg result */ /* XXX ????? */ const char *cp = (const char *)id; char *cpn = (char *)new_id; memcpy(cpn + id_offset, cp + id_offset, id_len - id_offset); } new_id->flag = (new_id->flag & ~copy_idflag_mask) | (id->flag & copy_idflag_mask); /* Embedded ID data handling. */ if (is_embedded_id && (orig_flag & LIB_ID_CREATE_NO_MAIN) == 0) { new_id->tag &= ~LIB_TAG_NO_MAIN; } /* NOTE: This also needs to run for ShapeKeys, which are not (yet) actual embedded IDs. * NOTE: for now, keep existing owner ID (i.e. owner of the source embedded ID) if no new one * is given. In some cases (e.g. depsgraph), this is important for later remapping to work * properly. */ if (new_owner_id) { const IDTypeInfo *idtype = BKE_idtype_get_info_from_id(new_id); BLI_assert(idtype->owner_pointer_get != nullptr); ID **owner_id_pointer = idtype->owner_pointer_get(new_id, false); *owner_id_pointer = const_cast(new_owner_id); } /* We do not want any handling of user-count in code duplicating the data here, we do that all * at once in id_copy_libmanagement_cb() at the end. */ const int copy_data_flag = orig_flag | LIB_ID_CREATE_NO_USER_REFCOUNT; if (id->properties) { new_id->properties = IDP_CopyProperty_ex(id->properties, copy_data_flag); } /* This is never duplicated, only one existing ID should have a given weak ref to library/ID. */ new_id->library_weak_reference = nullptr; if ((orig_flag & LIB_ID_COPY_NO_LIB_OVERRIDE) == 0) { if (ID_IS_OVERRIDE_LIBRARY_REAL(id)) { /* We do not want to copy existing override rules here, as they would break the proper * remapping between IDs. Proper overrides rules will be re-generated anyway. */ BKE_lib_override_library_copy(new_id, id, false); } else if (ID_IS_OVERRIDE_LIBRARY_VIRTUAL(id)) { /* Just ensure virtual overrides do get properly tagged, there is not actual override data to * copy here. */ new_id->flag |= LIB_EMBEDDED_DATA_LIB_OVERRIDE; } } if (id_can_have_animdata(new_id)) { IdAdtTemplate *iat = (IdAdtTemplate *)new_id; /* the duplicate should get a copy of the animdata */ if ((flag & LIB_ID_COPY_NO_ANIMDATA) == 0) { /* Note that even though horrors like root node-trees are not in bmain, the actions they use * in their anim data *are* in bmain... super-mega-hooray. */ BLI_assert((copy_data_flag & LIB_ID_COPY_ACTIONS) == 0 || (copy_data_flag & LIB_ID_CREATE_NO_MAIN) == 0); iat->adt = BKE_animdata_copy_in_lib(bmain, owner_library, iat->adt, copy_data_flag); } else { iat->adt = nullptr; } } if ((flag & LIB_ID_CREATE_NO_DEG_TAG) == 0 && (flag & LIB_ID_CREATE_NO_MAIN) == 0) { DEG_id_type_tag(bmain, GS(new_id->name)); } *r_newid = new_id; } void BKE_libblock_copy_ex(Main *bmain, const ID *id, ID **r_newid, const int orig_flag) { BKE_libblock_copy_in_lib(bmain, std::nullopt, id, nullptr, r_newid, orig_flag); } void *BKE_libblock_copy(Main *bmain, const ID *id) { ID *idn; BKE_libblock_copy_in_lib(bmain, std::nullopt, id, nullptr, &idn, 0); return idn; } /* ***************** ID ************************ */ ID *BKE_libblock_find_name(Main *bmain, const short type, const char *name) { ListBase *lb = which_libbase(bmain, type); BLI_assert(lb != nullptr); return static_cast(BLI_findstring(lb, name, offsetof(ID, name) + 2)); } ID *BKE_libblock_find_session_uid(Main *bmain, const short type, const uint32_t session_uid) { ListBase *lb = which_libbase(bmain, type); BLI_assert(lb != nullptr); LISTBASE_FOREACH (ID *, id, lb) { if (id->session_uid == session_uid) { return id; } } return nullptr; } ID *BKE_libblock_find_name_and_library(Main *bmain, const short type, const char *name, const char *lib_name) { ListBase *lb = which_libbase(bmain, type); BLI_assert(lb != nullptr); LISTBASE_FOREACH (ID *, id, lb) { if (!STREQ(id->name + 2, name)) { continue; } if (lib_name == nullptr || lib_name[0] == '\0') { if (id->lib == nullptr) { return id; } return nullptr; } if (!STREQ(id->lib->id.name + 2, lib_name)) { continue; } return id; } return nullptr; } void id_sort_by_name(ListBase *lb, ID *id, ID *id_sorting_hint) { #define ID_SORT_STEP_SIZE 512 ID *idtest; /* insert alphabetically */ if (lb->first == lb->last) { return; } BLI_remlink(lb, id); /* Check if we can actually insert id before or after id_sorting_hint, if given. */ if (!ELEM(id_sorting_hint, nullptr, id) && id_sorting_hint->lib == id->lib) { BLI_assert(BLI_findindex(lb, id_sorting_hint) >= 0); ID *id_sorting_hint_next = static_cast(id_sorting_hint->next); if (BLI_strcasecmp(id_sorting_hint->name, id->name) < 0 && (id_sorting_hint_next == nullptr || id_sorting_hint_next->lib != id->lib || BLI_strcasecmp(id_sorting_hint_next->name, id->name) > 0)) { BLI_insertlinkafter(lb, id_sorting_hint, id); return; } ID *id_sorting_hint_prev = static_cast(id_sorting_hint->prev); if (BLI_strcasecmp(id_sorting_hint->name, id->name) > 0 && (id_sorting_hint_prev == nullptr || id_sorting_hint_prev->lib != id->lib || BLI_strcasecmp(id_sorting_hint_prev->name, id->name) < 0)) { BLI_insertlinkbefore(lb, id_sorting_hint, id); return; } } void *item_array[ID_SORT_STEP_SIZE]; int item_array_index; /* Step one: We go backward over a whole chunk of items at once, until we find a limit item * that is lower than, or equal (should never happen!) to the one we want to insert. */ /* NOTE: We start from the end, because in typical 'heavy' case (insertion of lots of IDs at * once using the same base name), newly inserted items will generally be towards the end * (higher extension numbers). */ bool is_in_library = false; item_array_index = ID_SORT_STEP_SIZE - 1; for (idtest = static_cast(lb->last); idtest != nullptr; idtest = static_cast(idtest->prev)) { if (is_in_library) { if (idtest->lib != id->lib) { /* We got out of expected library 'range' in the list, so we are done here and can move on * to the next step. */ break; } } else if (idtest->lib == id->lib) { /* We are entering the expected library 'range' of IDs in the list. */ is_in_library = true; } if (!is_in_library) { continue; } item_array[item_array_index] = idtest; if (item_array_index == 0) { if (BLI_strcasecmp(idtest->name, id->name) <= 0) { break; } item_array_index = ID_SORT_STEP_SIZE; } item_array_index--; } /* Step two: we go forward in the selected chunk of items and check all of them, as we know * that our target is in there. */ /* If we reached start of the list, current item_array_index is off-by-one. * Otherwise, we already know that it points to an item lower-or-equal-than the one we want to * insert, no need to redo the check for that one. * So we can increment that index in any case. */ for (item_array_index++; item_array_index < ID_SORT_STEP_SIZE; item_array_index++) { idtest = static_cast(item_array[item_array_index]); if (BLI_strcasecmp(idtest->name, id->name) > 0) { BLI_insertlinkbefore(lb, idtest, id); break; } } if (item_array_index == ID_SORT_STEP_SIZE) { if (idtest == nullptr) { /* If idtest is nullptr here, it means that in the first loop, the last comparison was * performed exactly on the first item of the list, and that it also failed. And that the * second loop was not walked at all. * * In other words, if `id` is local, all the items in the list are greater than the inserted * one, so we can put it at the start of the list. Or, if `id` is linked, it is the first one * of its library, and we can put it at the very end of the list. */ if (ID_IS_LINKED(id)) { BLI_addtail(lb, id); } else { BLI_addhead(lb, id); } } else { BLI_insertlinkafter(lb, idtest, id); } } #undef ID_SORT_STEP_SIZE } bool BKE_id_new_name_validate( Main *bmain, ListBase *lb, ID *id, const char *tname, const bool do_linked_data) { bool result = false; char name[MAX_ID_NAME - 2]; /* If library, don't rename (unless explicitly required), but do ensure proper sorting. */ if (!do_linked_data && ID_IS_LINKED(id)) { id_sort_by_name(lb, id, nullptr); return result; } /* If no name given, use name of current ID. */ if (tname == nullptr) { tname = id->name + 2; } /* Make a copy of given name (tname args can be const). */ STRNCPY(name, tname); if (name[0] == '\0') { /* Disallow empty names. */ STRNCPY_UTF8(name, DATA_(BKE_idtype_idcode_to_name(GS(id->name)))); } else { /* disallow non utf8 chars, * the interface checks for this but new ID's based on file names don't */ BLI_str_utf8_invalid_strip(name, strlen(name)); } result = BKE_main_namemap_get_name(bmain, id, name, false); if (!result && !STREQ(id->name + 2, name)) { result = true; } BLI_strncpy(id->name + 2, name, sizeof(id->name) - 2); id_sort_by_name(lb, id, nullptr); return result; } void BKE_main_id_newptr_and_tag_clear(Main *bmain) { ID *id; FOREACH_MAIN_ID_BEGIN (bmain, id) { BKE_id_newptr_and_tag_clear(id); } FOREACH_MAIN_ID_END; } static int id_refcount_recompute_callback(LibraryIDLinkCallbackData *cb_data) { ID **id_pointer = cb_data->id_pointer; const int cb_flag = cb_data->cb_flag; const bool do_linked_only = bool(POINTER_AS_INT(cb_data->user_data)); if (*id_pointer == nullptr) { return IDWALK_RET_NOP; } if (do_linked_only && !ID_IS_LINKED(*id_pointer)) { return IDWALK_RET_NOP; } if (cb_flag & IDWALK_CB_USER) { /* Do not touch to direct/indirect linked status here... */ id_us_plus_no_lib(*id_pointer); } if (cb_flag & IDWALK_CB_USER_ONE) { id_us_ensure_real(*id_pointer); } return IDWALK_RET_NOP; } void BKE_main_id_refcount_recompute(Main *bmain, const bool do_linked_only) { ID *id; FOREACH_MAIN_ID_BEGIN (bmain, id) { if (!ID_IS_LINKED(id) && do_linked_only) { continue; } id->us = ID_FAKE_USERS(id); /* Note that we keep EXTRAUSER tag here, since some UI users may define it too... */ if (id->tag & LIB_TAG_EXTRAUSER) { id->tag &= ~(LIB_TAG_EXTRAUSER | LIB_TAG_EXTRAUSER_SET); id_us_ensure_real(id); } if (ELEM(GS(id->name), ID_SCE, ID_WM, ID_WS)) { /* These IDs should always have a 'virtual' user. */ id_us_ensure_real(id); } } FOREACH_MAIN_ID_END; /* Go over whole Main database to re-generate proper user-counts. */ FOREACH_MAIN_ID_BEGIN (bmain, id) { BKE_library_foreach_ID_link(bmain, id, id_refcount_recompute_callback, POINTER_FROM_INT(int(do_linked_only)), IDWALK_READONLY | IDWALK_INCLUDE_UI); } FOREACH_MAIN_ID_END; } static void library_make_local_copying_check(ID *id, GSet *loop_tags, MainIDRelations *id_relations, GSet *done_ids) { if (BLI_gset_haskey(done_ids, id)) { return; /* Already checked, nothing else to do. */ } MainIDRelationsEntry *entry = static_cast( BLI_ghash_lookup(id_relations->relations_from_pointers, id)); BLI_gset_insert(loop_tags, id); for (MainIDRelationsEntryItem *from_id_entry = entry->from_ids; from_id_entry != nullptr; from_id_entry = from_id_entry->next) { /* Our oh-so-beloved 'from' pointers... Those should always be ignored here, since the actual * relation we want to check is in the other way around. */ if (from_id_entry->usage_flag & IDWALK_CB_LOOPBACK) { continue; } ID *from_id = from_id_entry->id_pointer.from; /* Shape-keys are considered 'private' to their owner ID here, and never tagged * (since they cannot be linked), so we have to switch effective parent to their owner. */ if (GS(from_id->name) == ID_KE) { from_id = ((Key *)from_id)->from; } if (!ID_IS_LINKED(from_id)) { /* Local user, early out to avoid some gset querying... */ continue; } if (!BLI_gset_haskey(done_ids, from_id)) { if (BLI_gset_haskey(loop_tags, from_id)) { /* We are in a 'dependency loop' of IDs, this does not say us anything, skip it. * Note that this is the situation that can lead to archipelagos of linked data-blocks * (since all of them have non-local users, they would all be duplicated, * leading to a loop of unused linked data-blocks that cannot be freed since they all use * each other...). */ continue; } /* Else, recursively check that user ID. */ library_make_local_copying_check(from_id, loop_tags, id_relations, done_ids); } if (from_id->tag & LIB_TAG_DOIT) { /* This user will be fully local in future, so far so good, * nothing to do here but check next user. */ } else { /* This user won't be fully local in future, so current ID won't be either. * And we are done checking it. */ id->tag &= ~LIB_TAG_DOIT; break; } } BLI_gset_add(done_ids, id); BLI_gset_remove(loop_tags, id, nullptr); } void BKE_library_make_local(Main *bmain, const Library *lib, GHash *old_to_new_ids, const bool untagged_only, const bool set_fake) { /* NOTE: Old (2.77) version was simply making (tagging) data-blocks as local, * without actually making any check whether they were also indirectly used or not... * * Current version uses regular id_make_local callback, with advanced pre-processing step to * detect all cases of IDs currently indirectly used, but which will be used by local data only * once this function is finished. This allows to avoid any unneeded duplication of IDs, and * hence all time lost afterwards to remove orphaned linked data-blocks. */ ListBase *lbarray[INDEX_ID_MAX]; LinkNode *todo_ids = nullptr; LinkNode *copied_ids = nullptr; MemArena *linklist_mem = BLI_memarena_new(512 * sizeof(*todo_ids), __func__); GSet *done_ids = BLI_gset_ptr_new(__func__); #ifdef DEBUG_TIME TIMEIT_START(make_local); #endif BKE_main_relations_create(bmain, 0); #ifdef DEBUG_TIME printf("Pre-compute current ID relations: Done.\n"); TIMEIT_VALUE_PRINT(make_local); #endif /* Step 1: Detect data-blocks to make local. */ for (int a = set_listbasepointers(bmain, lbarray); a--;) { ID *id = static_cast(lbarray[a]->first); /* Do not explicitly make local non-linkable IDs (shape-keys, in fact), * they are assumed to be handled by real data-blocks responsible of them. */ const bool do_skip = (id && !BKE_idtype_idcode_is_linkable(GS(id->name))); for (; id; id = static_cast(id->next)) { ID *ntree = (ID *)blender::bke::ntreeFromID(id); id->tag &= ~LIB_TAG_DOIT; if (ntree != nullptr) { ntree->tag &= ~LIB_TAG_DOIT; } if (!ID_IS_LINKED(id)) { id->tag &= ~(LIB_TAG_EXTERN | LIB_TAG_INDIRECT | LIB_TAG_NEW); id->flag &= ~LIB_INDIRECT_WEAK_LINK; if (ID_IS_OVERRIDE_LIBRARY_REAL(id) && ELEM(lib, nullptr, id->override_library->reference->lib) && ((untagged_only == false) || !(id->tag & LIB_TAG_PRE_EXISTING))) { /* Validating liboverride hierarchy root pointers will happen later in this function, * rather than doing it for each and every localized ID. */ BKE_lib_override_library_make_local(nullptr, id); } } /* The check on the fourth line (LIB_TAG_PRE_EXISTING) is done so it's possible to tag data * you don't want to be made local, used for appending data, * so any libdata already linked won't become local (very nasty * to discover all your links are lost after appending). * Also, never ever make proxified objects local, would not make any sense. */ /* Some more notes: * - Shape-keys are never tagged here (since they are not linkable). * - Node-trees used in materials etc. have to be tagged manually, * since they do not exist in Main (!). * This is ok-ish on 'make local' side of things * (since those are handled by their 'owner' IDs), * but complicates slightly the pre-processing of relations between IDs at step 2... */ else if (!do_skip && id->tag & (LIB_TAG_EXTERN | LIB_TAG_INDIRECT | LIB_TAG_NEW) && ELEM(lib, nullptr, id->lib) && ((untagged_only == false) || !(id->tag & LIB_TAG_PRE_EXISTING))) { BLI_linklist_prepend_arena(&todo_ids, id, linklist_mem); id->tag |= LIB_TAG_DOIT; /* Tag those nasty non-ID node-trees, * but do not add them to todo list, making them local is handled by 'owner' ID. * This is needed for library_make_local_copying_check() to work OK at step 2. */ if (ntree != nullptr) { ntree->tag |= LIB_TAG_DOIT; } } else { /* Linked ID that we won't be making local (needed info for step 2, see below). */ BLI_gset_add(done_ids, id); } } } #ifdef DEBUG_TIME printf("Step 1: Detect data-blocks to make local: Done.\n"); TIMEIT_VALUE_PRINT(make_local); #endif /* Step 2: Check which data-blocks we can directly make local * (because they are only used by already, or future, local data), * others will need to be duplicated. */ GSet *loop_tags = BLI_gset_ptr_new(__func__); for (LinkNode *it = todo_ids; it; it = it->next) { library_make_local_copying_check( static_cast(it->link), loop_tags, bmain->relations, done_ids); BLI_assert(BLI_gset_len(loop_tags) == 0); } BLI_gset_free(loop_tags, nullptr); BLI_gset_free(done_ids, nullptr); /* Next step will most likely add new IDs, better to get rid of this mapping now. */ BKE_main_relations_free(bmain); #ifdef DEBUG_TIME printf("Step 2: Check which data-blocks we can directly make local: Done.\n"); TIMEIT_VALUE_PRINT(make_local); #endif /* Step 3: Make IDs local, either directly (quick and simple), or using generic process, * which involves more complex checks and might instead * create a local copy of original linked ID. */ for (LinkNode *it = todo_ids, *it_next; it; it = it_next) { it_next = it->next; ID *id = static_cast(it->link); if (id->tag & LIB_TAG_DOIT) { /* We know all users of this object are local or will be made fully local, even if * currently there are some indirect usages. So instead of making a copy that we'll likely * get rid of later, directly make that data block local. * Saves a tremendous amount of time with complex scenes... */ BKE_lib_id_clear_library_data(bmain, id, 0); BKE_lib_id_expand_local(bmain, id, 0); id->tag &= ~LIB_TAG_DOIT; if (GS(id->name) == ID_OB) { BKE_rigidbody_ensure_local_object(bmain, (Object *)id); } } else { /* In this specific case, we do want to make ID local even if it has no local usage yet... */ BKE_lib_id_make_local(bmain, id, LIB_ID_MAKELOCAL_FULL_LIBRARY); if (id->newid) { if (GS(id->newid->name) == ID_OB) { BKE_rigidbody_ensure_local_object(bmain, (Object *)id->newid); } /* Reuse already allocated LinkNode (transferring it from todo_ids to copied_ids). */ BLI_linklist_prepend_nlink(&copied_ids, id, it); } } if (set_fake) { if (!ELEM(GS(id->name), ID_OB, ID_GR)) { /* do not set fake user on objects, groups (instancing) */ id_fake_user_set(id); } } } #ifdef DEBUG_TIME printf("Step 3: Make IDs local: Done.\n"); TIMEIT_VALUE_PRINT(make_local); #endif /* At this point, we are done with directly made local IDs. * Now we have to handle duplicated ones, since their * remaining linked original counterpart may not be needed anymore... */ todo_ids = nullptr; /* Step 4: We have to remap local usages of old (linked) ID to new (local) * ID in a separated loop, * as lbarray ordering is not enough to ensure us we did catch all dependencies * (e.g. if making local a parent object before its child...). See #48907. */ /* TODO: This is now the biggest step by far (in term of processing time). * We may be able to gain here by using again main->relations mapping, but... * this implies BKE_libblock_remap & co to be able to update main->relations on the fly. * Have to think about it a bit more, and see whether new code is OK first, anyway. */ for (LinkNode *it = copied_ids; it; it = it->next) { ID *id = static_cast(it->link); BLI_assert(id->newid != nullptr); BLI_assert(ID_IS_LINKED(id)); BKE_libblock_remap(bmain, id, id->newid, ID_REMAP_SKIP_INDIRECT_USAGE); if (old_to_new_ids) { BLI_ghash_insert(old_to_new_ids, id, id->newid); } /* Special hack for groups... Thing is, since we can't instantiate them here, we need to * ensure they remain 'alive' (only instantiation is a real group 'user'... *sigh* See * #49722. */ if (GS(id->name) == ID_GR && (id->tag & LIB_TAG_INDIRECT) != 0) { id_us_ensure_real(id->newid); } } /* Making some liboverride local may have had some impact on validity of liboverrides hierarchy * roots, these need to be re-validated/re-generated. */ BKE_lib_override_library_main_hierarchy_root_ensure(bmain); #ifdef DEBUG_TIME printf("Step 4: Remap local usages of old (linked) ID to new (local) ID: Done.\n"); TIMEIT_VALUE_PRINT(make_local); #endif /* This is probably more of a hack than something we should do here, but... * Issue is, the whole copying + remapping done in complex cases above may leave pose-channels * of armatures in complete invalid state (more precisely, the bone pointers of the * pose-channels - very crappy cross-data-blocks relationship), so we tag it to be fully * recomputed, but this does not seems to be enough in some cases, and evaluation code ends up * trying to evaluate a not-yet-updated armature object's deformations. * Try "make all local" in 04_01_H.lighting.blend from Agent327 without this, e.g. */ for (Object *ob = static_cast(bmain->objects.first); ob; ob = static_cast(ob->id.next)) { if (ob->data != nullptr && ob->type == OB_ARMATURE && ob->pose != nullptr && ob->pose->flag & POSE_RECALC) { BKE_pose_rebuild(bmain, ob, static_cast(ob->data), true); } } #ifdef DEBUG_TIME printf("Hack: Forcefully rebuild armature object poses: Done.\n"); TIMEIT_VALUE_PRINT(make_local); #endif BKE_main_id_newptr_and_tag_clear(bmain); BLI_memarena_free(linklist_mem); #ifdef DEBUG_TIME printf("Cleanup and finish: Done.\n"); TIMEIT_END(make_local); #endif } void BKE_libblock_rename(Main *bmain, ID *id, const char *name) { BLI_assert(ID_IS_EDITABLE(id)); if (STREQ(id->name + 2, name)) { return; } BKE_main_namemap_remove_name(bmain, id, id->name + 2); ListBase *lb = which_libbase(bmain, GS(id->name)); if (BKE_id_new_name_validate(bmain, lb, id, name, false)) { bmain->is_memfile_undo_written = false; } } void BKE_id_full_name_get(char name[MAX_ID_FULL_NAME], const ID *id, char separator_char) { BLI_strncpy(name, id->name + 2, MAX_ID_FULL_NAME); if (ID_IS_LINKED(id)) { const size_t idname_len = strlen(id->name + 2); const size_t libname_len = strlen(id->lib->id.name + 2); name[idname_len] = separator_char ? separator_char : ' '; name[idname_len + 1] = '['; BLI_strncpy(name + idname_len + 2, id->lib->id.name + 2, MAX_ID_FULL_NAME - (idname_len + 2)); name[idname_len + 2 + libname_len] = ']'; name[idname_len + 2 + libname_len + 1] = '\0'; } } void BKE_id_full_name_ui_prefix_get(char name[MAX_ID_FULL_NAME_UI], const ID *id, const bool add_lib_hint, char separator_char, int *r_prefix_len) { int i = 0; if (add_lib_hint) { name[i++] = id->lib ? (ID_MISSING(id) ? 'M' : 'L') : ID_IS_OVERRIDE_LIBRARY(id) ? 'O' : ' '; } name[i++] = (id->flag & LIB_FAKEUSER) ? 'F' : ((id->us == 0) ? '0' : ' '); name[i++] = ' '; BKE_id_full_name_get(name + i, id, separator_char); if (r_prefix_len) { *r_prefix_len = i; } } char *BKE_id_to_unique_string_key(const ID *id) { if (!ID_IS_LINKED(id)) { return BLI_strdup(id->name); } /* Prefix with an ascii character in the range of 32..96 (visible) * this ensures we can't have a library ID pair that collide. * Where 'LIfooOBbarOBbaz' could be ('LIfoo, OBbarOBbaz') or ('LIfooOBbar', 'OBbaz'). */ const char ascii_len = strlen(id->lib->id.name + 2) + 32; return BLI_sprintfN("%c%s%s", ascii_len, id->lib->id.name, id->name); } void BKE_id_tag_set_atomic(ID *id, int tag) { atomic_fetch_and_or_int32(&id->tag, tag); } void BKE_id_tag_clear_atomic(ID *id, int tag) { atomic_fetch_and_and_int32(&id->tag, ~tag); } bool BKE_id_is_in_global_main(ID *id) { /* We do not want to fail when id is nullptr here, even though this is a bit strange behavior... */ return (id == nullptr || BLI_findindex(which_libbase(G_MAIN, GS(id->name)), id) != -1); } bool BKE_id_can_be_asset(const ID *id) { return ID_IS_EDITABLE(id) && !ID_IS_OVERRIDE_LIBRARY(id) && BKE_idtype_idcode_is_linkable(GS(id->name)); } ID *BKE_id_owner_get(ID *id, const bool debug_relationship_assert) { const IDTypeInfo *idtype = BKE_idtype_get_info_from_id(id); if (idtype->owner_pointer_get != nullptr) { ID **owner_id_pointer = idtype->owner_pointer_get(id, debug_relationship_assert); if (owner_id_pointer != nullptr) { return *owner_id_pointer; } } return nullptr; } bool BKE_id_is_editable(const Main *bmain, const ID *id) { return ID_IS_EDITABLE(id) && !BKE_lib_override_library_is_system_defined(bmain, id); } /************************* Datablock order in UI **************************/ static int *id_order_get(ID *id) { /* Only for workspace tabs currently. */ switch (GS(id->name)) { case ID_WS: return &((WorkSpace *)id)->order; default: return nullptr; } } static bool id_order_compare(ID *a, ID *b) { int *order_a = id_order_get(a); int *order_b = id_order_get(b); if (order_a && order_b) { if (*order_a < *order_b) { return true; } if (*order_a > *order_b) { return false; } } return strcmp(a->name, b->name) <= 0; } Vector BKE_id_ordered_list(const ListBase *lb) { Vector ordered; LISTBASE_FOREACH (ID *, id, lb) { ordered.append(id); } std::sort(ordered.begin(), ordered.end(), id_order_compare); for (const int i : ordered.index_range()) { if (int *order = id_order_get(ordered[i])) { *order = i; } } return ordered; } void BKE_id_reorder(const ListBase *lb, ID *id, ID *relative, bool after) { int *id_order = id_order_get(id); int relative_order; if (relative) { relative_order = *id_order_get(relative); } else { relative_order = (after) ? BLI_listbase_count(lb) : 0; } if (after) { /* Insert after. */ LISTBASE_FOREACH (ID *, other, lb) { int *order = id_order_get(other); if (*order > relative_order) { (*order)++; } } *id_order = relative_order + 1; } else { /* Insert before. */ LISTBASE_FOREACH (ID *, other, lb) { int *order = id_order_get(other); if (*order < relative_order) { (*order)--; } } *id_order = relative_order - 1; } } void BKE_id_blend_write(BlendWriter *writer, ID *id) { if (id->asset_data) { BKE_asset_metadata_write(writer, id->asset_data); } if (id->library_weak_reference != nullptr) { BLO_write_struct(writer, LibraryWeakReference, id->library_weak_reference); } /* ID_WM's id->properties are considered runtime only, and never written in .blend file. */ if (id->properties && !ELEM(GS(id->name), ID_WM)) { IDP_BlendWrite(writer, id->properties); } BKE_animdata_blend_write(writer, id); if (id->override_library) { BLO_write_struct(writer, IDOverrideLibrary, id->override_library); BLO_write_struct_list(writer, IDOverrideLibraryProperty, &id->override_library->properties); LISTBASE_FOREACH (IDOverrideLibraryProperty *, op, &id->override_library->properties) { BLO_write_string(writer, op->rna_path); BLO_write_struct_list(writer, IDOverrideLibraryPropertyOperation, &op->operations); LISTBASE_FOREACH (IDOverrideLibraryPropertyOperation *, opop, &op->operations) { if (opop->subitem_reference_name) { BLO_write_string(writer, opop->subitem_reference_name); } if (opop->subitem_local_name) { BLO_write_string(writer, opop->subitem_local_name); } } } } }