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120f16fa1f1efd3cbb4da191d2912e0a6ce3ea59
blender-archive/source/blender/blenkernel/intern/node.cc
Johnny Matthews 120f16fa1f Geometry Nodes: Duplicate Elements Node 
This adds a node which copies part of a geometry a dynamic number
of times.

Different parts of the geometry can be copied differing amounts
of times, controlled by the amount input field. Geometry can also
be ignored by use of the selection input.

The output geometry contains only the copies created by the node.
if the amount input is set to zero, the output geometry will be
empty. The duplicate index output is an integer index with the copy
number of each duplicate.

Differential Revision: https://developer.blender.org/D13701
2022-02-23 09:08:16 -06:00

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/* SPDX-License-Identifier: GPL-2.0-or-later
* Copyright 2005 Blender Foundation. All rights reserved. */
/** \file
* \ingroup bke
*/
#include "CLG_log.h"
#include "MEM_guardedalloc.h"
#include <climits>
#include <cstddef>
#include <cstdlib>
#include <cstring>
/* Allow using deprecated functionality for .blend file I/O. */
#define DNA_DEPRECATED_ALLOW
#include "DNA_action_types.h"
#include "DNA_anim_types.h"
#include "DNA_collection_types.h"
#include "DNA_gpencil_types.h"
#include "DNA_light_types.h"
#include "DNA_linestyle_types.h"
#include "DNA_material_types.h"
#include "DNA_modifier_types.h"
#include "DNA_node_types.h"
#include "DNA_scene_types.h"
#include "DNA_simulation_types.h"
#include "DNA_texture_types.h"
#include "DNA_world_types.h"
#include "BLI_color.hh"
#include "BLI_ghash.h"
#include "BLI_listbase.h"
#include "BLI_map.hh"
#include "BLI_path_util.h"
#include "BLI_set.hh"
#include "BLI_stack.hh"
#include "BLI_string.h"
#include "BLI_string_utils.h"
#include "BLI_threads.h"
#include "BLI_utildefines.h"
#include "BLI_vector_set.hh"
#include "BLT_translation.h"
#include "BKE_anim_data.h"
#include "BKE_animsys.h"
#include "BKE_bpath.h"
#include "BKE_colortools.h"
#include "BKE_context.h"
#include "BKE_cryptomatte.h"
#include "BKE_global.h"
#include "BKE_icons.h"
#include "BKE_idprop.h"
#include "BKE_idtype.h"
#include "BKE_lib_id.h"
#include "BKE_lib_query.h"
#include "BKE_main.h"
#include "BKE_node.h"
#include "BKE_node_tree_update.h"
#include "RNA_access.h"
#include "RNA_define.h"
#include "NOD_common.h"
#include "NOD_composite.h"
#include "NOD_function.h"
#include "NOD_geometry.h"
#include "NOD_node_declaration.hh"
#include "NOD_node_tree_ref.hh"
#include "NOD_shader.h"
#include "NOD_socket.h"
#include "NOD_texture.h"
#include "DEG_depsgraph.h"
#include "DEG_depsgraph_build.h"
#include "BLO_read_write.h"
#include "MOD_nodes.h"
#define NODE_DEFAULT_MAX_WIDTH 700
using blender::Array;
using blender::Map;
using blender::MutableSpan;
using blender::Set;
using blender::Span;
using blender::Stack;
using blender::StringRef;
using blender::Vector;
using blender::VectorSet;
using blender::nodes::FieldInferencingInterface;
using blender::nodes::InputSocketFieldType;
using blender::nodes::NodeDeclaration;
using blender::nodes::OutputFieldDependency;
using blender::nodes::OutputSocketFieldType;
using blender::nodes::SocketDeclaration;
using namespace blender::nodes::node_tree_ref_types;
/* Fallback types for undefined tree, nodes, sockets */
static bNodeTreeType NodeTreeTypeUndefined;
bNodeType NodeTypeUndefined;
bNodeSocketType NodeSocketTypeUndefined;
static CLG_LogRef LOG = {"bke.node"};
static void ntree_set_typeinfo(bNodeTree *ntree, bNodeTreeType *typeinfo);
static void node_socket_copy(bNodeSocket *sock_dst, const bNodeSocket *sock_src, const int flag);
static void free_localized_node_groups(bNodeTree *ntree);
static void node_free_node(bNodeTree *ntree, bNode *node);
static void node_socket_interface_free(bNodeTree *UNUSED(ntree),
bNodeSocket *sock,
const bool do_id_user);
static void nodeMuteRerouteOutputLinks(struct bNodeTree *ntree,
struct bNode *node,
const bool mute);
static void ntree_init_data(ID *id)
{
bNodeTree *ntree = (bNodeTree *)id;
ntree_set_typeinfo(ntree, nullptr);
}
static void ntree_copy_data(Main *UNUSED(bmain), ID *id_dst, const ID *id_src, const int flag)
{
bNodeTree *ntree_dst = (bNodeTree *)id_dst;
const bNodeTree *ntree_src = (const bNodeTree *)id_src;
/* We never handle usercount here for own data. */
const int flag_subdata = flag | LIB_ID_CREATE_NO_USER_REFCOUNT;
/* in case a running nodetree is copied */
ntree_dst->execdata = nullptr;
BLI_listbase_clear(&ntree_dst->nodes);
BLI_listbase_clear(&ntree_dst->links);
Map<const bNode *, bNode *> node_map;
Map<const bNodeSocket *, bNodeSocket *> socket_map;
BLI_listbase_clear(&ntree_dst->nodes);
LISTBASE_FOREACH (const bNode *, src_node, &ntree_src->nodes) {
/* Don't find a unique name for every node, since they should have valid names already. */
bNode *new_node = blender::bke::node_copy_with_mapping(
ntree_dst, *src_node, flag_subdata, false, socket_map);
node_map.add(src_node, new_node);
}
/* copy links */
BLI_listbase_clear(&ntree_dst->links);
LISTBASE_FOREACH (const bNodeLink *, src_link, &ntree_src->links) {
bNodeLink *dst_link = (bNodeLink *)MEM_dupallocN(src_link);
dst_link->fromnode = node_map.lookup(src_link->fromnode);
dst_link->fromsock = socket_map.lookup(src_link->fromsock);
dst_link->tonode = node_map.lookup(src_link->tonode);
dst_link->tosock = socket_map.lookup(src_link->tosock);
BLI_assert(dst_link->tosock);
dst_link->tosock->link = dst_link;
BLI_addtail(&ntree_dst->links, dst_link);
}
/* copy interface sockets */
BLI_listbase_clear(&ntree_dst->inputs);
LISTBASE_FOREACH (const bNodeSocket *, src_socket, &ntree_src->inputs) {
bNodeSocket *dst_socket = (bNodeSocket *)MEM_dupallocN(src_socket);
node_socket_copy(dst_socket, src_socket, flag_subdata);
BLI_addtail(&ntree_dst->inputs, dst_socket);
}
BLI_listbase_clear(&ntree_dst->outputs);
LISTBASE_FOREACH (const bNodeSocket *, src_socket, &ntree_src->outputs) {
bNodeSocket *dst_socket = (bNodeSocket *)MEM_dupallocN(src_socket);
node_socket_copy(dst_socket, src_socket, flag_subdata);
BLI_addtail(&ntree_dst->outputs, dst_socket);
}
/* copy preview hash */
if (ntree_src->previews && (flag & LIB_ID_COPY_NO_PREVIEW) == 0) {
bNodeInstanceHashIterator iter;
ntree_dst->previews = BKE_node_instance_hash_new("node previews");
NODE_INSTANCE_HASH_ITER (iter, ntree_src->previews) {
bNodeInstanceKey key = BKE_node_instance_hash_iterator_get_key(&iter);
bNodePreview *preview = (bNodePreview *)BKE_node_instance_hash_iterator_get_value(&iter);
BKE_node_instance_hash_insert(ntree_dst->previews, key, BKE_node_preview_copy(preview));
}
}
else {
ntree_dst->previews = nullptr;
}
/* update node->parent pointers */
LISTBASE_FOREACH (bNode *, new_node, &ntree_dst->nodes) {
if (new_node->parent) {
new_node->parent = node_map.lookup(new_node->parent);
}
}
/* node tree will generate its own interface type */
ntree_dst->interface_type = nullptr;
if (ntree_src->field_inferencing_interface) {
ntree_dst->field_inferencing_interface = new FieldInferencingInterface(
*ntree_src->field_inferencing_interface);
}
if (flag & LIB_ID_COPY_NO_PREVIEW) {
ntree_dst->preview = nullptr;
}
else {
BKE_previewimg_id_copy(&ntree_dst->id, &ntree_src->id);
}
}
static void ntree_free_data(ID *id)
{
bNodeTree *ntree = (bNodeTree *)id;
/* XXX hack! node trees should not store execution graphs at all.
* This should be removed when old tree types no longer require it.
* Currently the execution data for texture nodes remains in the tree
* after execution, until the node tree is updated or freed. */
if (ntree->execdata) {
switch (ntree->type) {
case NTREE_SHADER:
ntreeShaderEndExecTree(ntree->execdata);
break;
case NTREE_TEXTURE:
ntreeTexEndExecTree(ntree->execdata);
ntree->execdata = nullptr;
break;
}
}
/* XXX not nice, but needed to free localized node groups properly */
free_localized_node_groups(ntree);
/* Unregister associated RNA types. */
ntreeInterfaceTypeFree(ntree);
BLI_freelistN(&ntree->links);
LISTBASE_FOREACH_MUTABLE (bNode *, node, &ntree->nodes) {
node_free_node(ntree, node);
}
/* free interface sockets */
LISTBASE_FOREACH_MUTABLE (bNodeSocket *, sock, &ntree->inputs) {
node_socket_interface_free(ntree, sock, false);
MEM_freeN(sock);
}
LISTBASE_FOREACH_MUTABLE (bNodeSocket *, sock, &ntree->outputs) {
node_socket_interface_free(ntree, sock, false);
MEM_freeN(sock);
}
delete ntree->field_inferencing_interface;
/* free preview hash */
if (ntree->previews) {
BKE_node_instance_hash_free(ntree->previews, (bNodeInstanceValueFP)BKE_node_preview_free);
}
if (ntree->id.tag & LIB_TAG_LOCALIZED) {
BKE_libblock_free_data(&ntree->id, true);
}
BKE_previewimg_free(&ntree->preview);
}
static void library_foreach_node_socket(LibraryForeachIDData *data, bNodeSocket *sock)
{
BKE_LIB_FOREACHID_PROCESS_FUNCTION_CALL(
data,
IDP_foreach_property(
sock->prop, IDP_TYPE_FILTER_ID, BKE_lib_query_idpropertiesForeachIDLink_callback, data));
switch ((eNodeSocketDatatype)sock->type) {
case SOCK_OBJECT: {
bNodeSocketValueObject *default_value = (bNodeSocketValueObject *)sock->default_value;
BKE_LIB_FOREACHID_PROCESS_IDSUPER(data, default_value->value, IDWALK_CB_USER);
break;
}
case SOCK_IMAGE: {
bNodeSocketValueImage *default_value = (bNodeSocketValueImage *)sock->default_value;
BKE_LIB_FOREACHID_PROCESS_IDSUPER(data, default_value->value, IDWALK_CB_USER);
break;
}
case SOCK_COLLECTION: {
bNodeSocketValueCollection *default_value = (bNodeSocketValueCollection *)
sock->default_value;
BKE_LIB_FOREACHID_PROCESS_IDSUPER(data, default_value->value, IDWALK_CB_USER);
break;
}
case SOCK_TEXTURE: {
bNodeSocketValueTexture *default_value = (bNodeSocketValueTexture *)sock->default_value;
BKE_LIB_FOREACHID_PROCESS_IDSUPER(data, default_value->value, IDWALK_CB_USER);
break;
}
case SOCK_MATERIAL: {
bNodeSocketValueMaterial *default_value = (bNodeSocketValueMaterial *)sock->default_value;
BKE_LIB_FOREACHID_PROCESS_IDSUPER(data, default_value->value, IDWALK_CB_USER);
break;
}
case SOCK_FLOAT:
case SOCK_VECTOR:
case SOCK_RGBA:
case SOCK_BOOLEAN:
case SOCK_INT:
case SOCK_STRING:
case __SOCK_MESH:
case SOCK_CUSTOM:
case SOCK_SHADER:
case SOCK_GEOMETRY:
break;
}
}
static void node_foreach_id(ID *id, LibraryForeachIDData *data)
{
bNodeTree *ntree = (bNodeTree *)id;
BKE_LIB_FOREACHID_PROCESS_IDSUPER(data, ntree->gpd, IDWALK_CB_USER);
LISTBASE_FOREACH (bNode *, node, &ntree->nodes) {
BKE_LIB_FOREACHID_PROCESS_ID(data, node->id, IDWALK_CB_USER);
BKE_LIB_FOREACHID_PROCESS_FUNCTION_CALL(
data,
IDP_foreach_property(node->prop,
IDP_TYPE_FILTER_ID,
BKE_lib_query_idpropertiesForeachIDLink_callback,
data));
LISTBASE_FOREACH (bNodeSocket *, sock, &node->inputs) {
BKE_LIB_FOREACHID_PROCESS_FUNCTION_CALL(data, library_foreach_node_socket(data, sock));
}
LISTBASE_FOREACH (bNodeSocket *, sock, &node->outputs) {
BKE_LIB_FOREACHID_PROCESS_FUNCTION_CALL(data, library_foreach_node_socket(data, sock));
}
}
LISTBASE_FOREACH (bNodeSocket *, sock, &ntree->inputs) {
BKE_LIB_FOREACHID_PROCESS_FUNCTION_CALL(data, library_foreach_node_socket(data, sock));
}
LISTBASE_FOREACH (bNodeSocket *, sock, &ntree->outputs) {
BKE_LIB_FOREACHID_PROCESS_FUNCTION_CALL(data, library_foreach_node_socket(data, sock));
}
}
static void node_foreach_cache(ID *id,
IDTypeForeachCacheFunctionCallback function_callback,
void *user_data)
{
bNodeTree *nodetree = (bNodeTree *)id;
IDCacheKey key = {0};
key.id_session_uuid = id->session_uuid;
key.offset_in_ID = offsetof(bNodeTree, previews);
key.cache_v = nodetree->previews;
/* TODO: see also `direct_link_nodetree()` in readfile.c. */
#if 0
function_callback(id, &key, (void **)&nodetree->previews, 0, user_data);
#endif
if (nodetree->type == NTREE_COMPOSIT) {
LISTBASE_FOREACH (bNode *, node, &nodetree->nodes) {
if (node->type == CMP_NODE_MOVIEDISTORTION) {
key.offset_in_ID = (size_t)BLI_ghashutil_strhash_p(node->name);
key.cache_v = node->storage;
function_callback(id, &key, (void **)&node->storage, 0, user_data);
}
}
}
}
static void node_foreach_path(ID *id, BPathForeachPathData *bpath_data)
{
bNodeTree *ntree = reinterpret_cast<bNodeTree *>(id);
switch (ntree->type) {
case NTREE_SHADER: {
LISTBASE_FOREACH (bNode *, node, &ntree->nodes) {
if (node->type == SH_NODE_SCRIPT) {
NodeShaderScript *nss = reinterpret_cast<NodeShaderScript *>(node->storage);
BKE_bpath_foreach_path_fixed_process(bpath_data, nss->filepath);
}
else if (node->type == SH_NODE_TEX_IES) {
NodeShaderTexIES *ies = reinterpret_cast<NodeShaderTexIES *>(node->storage);
BKE_bpath_foreach_path_fixed_process(bpath_data, ies->filepath);
}
}
break;
}
default:
break;
}
}
static ID *node_owner_get(Main *bmain, ID *id)
{
if ((id->flag & LIB_EMBEDDED_DATA) == 0) {
return id;
}
/* TODO: Sort this NO_MAIN or not for embedded node trees. See T86119. */
// BLI_assert((id->tag & LIB_TAG_NO_MAIN) == 0);
ListBase *lists[] = {&bmain->materials,
&bmain->lights,
&bmain->worlds,
&bmain->textures,
&bmain->scenes,
&bmain->linestyles,
&bmain->simulations,
nullptr};
bNodeTree *ntree = (bNodeTree *)id;
for (int i = 0; lists[i] != nullptr; i++) {
LISTBASE_FOREACH (ID *, id_iter, lists[i]) {
if (ntreeFromID(id_iter) == ntree) {
return id_iter;
}
}
}
BLI_assert_msg(0, "Embedded node tree with no owner. Critical Main inconsistency.");
return nullptr;
}
static void write_node_socket_default_value(BlendWriter *writer, bNodeSocket *sock)
{
if (sock->default_value == nullptr) {
return;
}
switch ((eNodeSocketDatatype)sock->type) {
case SOCK_FLOAT:
BLO_write_struct(writer, bNodeSocketValueFloat, sock->default_value);
break;
case SOCK_VECTOR:
BLO_write_struct(writer, bNodeSocketValueVector, sock->default_value);
break;
case SOCK_RGBA:
BLO_write_struct(writer, bNodeSocketValueRGBA, sock->default_value);
break;
case SOCK_BOOLEAN:
BLO_write_struct(writer, bNodeSocketValueBoolean, sock->default_value);
break;
case SOCK_INT:
BLO_write_struct(writer, bNodeSocketValueInt, sock->default_value);
break;
case SOCK_STRING:
BLO_write_struct(writer, bNodeSocketValueString, sock->default_value);
break;
case SOCK_OBJECT:
BLO_write_struct(writer, bNodeSocketValueObject, sock->default_value);
break;
case SOCK_IMAGE:
BLO_write_struct(writer, bNodeSocketValueImage, sock->default_value);
break;
case SOCK_COLLECTION:
BLO_write_struct(writer, bNodeSocketValueCollection, sock->default_value);
break;
case SOCK_TEXTURE:
BLO_write_struct(writer, bNodeSocketValueTexture, sock->default_value);
break;
case SOCK_MATERIAL:
BLO_write_struct(writer, bNodeSocketValueMaterial, sock->default_value);
break;
case SOCK_CUSTOM:
/* Custom node sockets where default_value is defined uses custom properties for storage. */
break;
case __SOCK_MESH:
case SOCK_SHADER:
case SOCK_GEOMETRY:
BLI_assert_unreachable();
break;
}
}
static void write_node_socket(BlendWriter *writer, bNodeSocket *sock)
{
BLO_write_struct(writer, bNodeSocket, sock);
if (sock->prop) {
IDP_BlendWrite(writer, sock->prop);
}
write_node_socket_default_value(writer, sock);
}
static void write_node_socket_interface(BlendWriter *writer, bNodeSocket *sock)
{
BLO_write_struct(writer, bNodeSocket, sock);
if (sock->prop) {
IDP_BlendWrite(writer, sock->prop);
}
write_node_socket_default_value(writer, sock);
}
void ntreeBlendWrite(BlendWriter *writer, bNodeTree *ntree)
{
BKE_id_blend_write(writer, &ntree->id);
if (ntree->adt) {
BKE_animdata_blend_write(writer, ntree->adt);
}
LISTBASE_FOREACH (bNode *, node, &ntree->nodes) {
BLO_write_struct(writer, bNode, node);
if (node->prop) {
IDP_BlendWrite(writer, node->prop);
}
LISTBASE_FOREACH (bNodeSocket *, sock, &node->inputs) {
write_node_socket(writer, sock);
}
LISTBASE_FOREACH (bNodeSocket *, sock, &node->outputs) {
write_node_socket(writer, sock);
}
LISTBASE_FOREACH (bNodeLink *, link, &node->internal_links) {
BLO_write_struct(writer, bNodeLink, link);
}
if (node->storage) {
if (ELEM(ntree->type, NTREE_SHADER, NTREE_GEOMETRY) &&
ELEM(node->type, SH_NODE_CURVE_VEC, SH_NODE_CURVE_RGB, SH_NODE_CURVE_FLOAT)) {
BKE_curvemapping_blend_write(writer, (const CurveMapping *)node->storage);
}
else if ((ntree->type == NTREE_GEOMETRY) &&
(node->type == GEO_NODE_LEGACY_ATTRIBUTE_CURVE_MAP)) {
BLO_write_struct_by_name(writer, node->typeinfo->storagename, node->storage);
NodeAttributeCurveMap *data = (NodeAttributeCurveMap *)node->storage;
BKE_curvemapping_blend_write(writer, (const CurveMapping *)data->curve_vec);
BKE_curvemapping_blend_write(writer, (const CurveMapping *)data->curve_rgb);
}
else if (ntree->type == NTREE_SHADER && (node->type == SH_NODE_SCRIPT)) {
NodeShaderScript *nss = (NodeShaderScript *)node->storage;
if (nss->bytecode) {
BLO_write_string(writer, nss->bytecode);
}
BLO_write_struct_by_name(writer, node->typeinfo->storagename, node->storage);
}
else if ((ntree->type == NTREE_COMPOSIT) && ELEM(node->type,
CMP_NODE_TIME,
CMP_NODE_CURVE_VEC,
CMP_NODE_CURVE_RGB,
CMP_NODE_HUECORRECT)) {
BKE_curvemapping_blend_write(writer, (const CurveMapping *)node->storage);
}
else if ((ntree->type == NTREE_TEXTURE) &&
(node->type == TEX_NODE_CURVE_RGB || node->type == TEX_NODE_CURVE_TIME)) {
BKE_curvemapping_blend_write(writer, (const CurveMapping *)node->storage);
}
else if ((ntree->type == NTREE_COMPOSIT) && (node->type == CMP_NODE_MOVIEDISTORTION)) {
/* pass */
}
else if ((ntree->type == NTREE_COMPOSIT) && (node->type == CMP_NODE_GLARE)) {
/* Simple forward compatibility for fix for T50736.
* Not ideal (there is no ideal solution here), but should do for now. */
NodeGlare *ndg = (NodeGlare *)node->storage;
/* Not in undo case. */
if (!BLO_write_is_undo(writer)) {
switch (ndg->type) {
case 2: /* Grrrr! magic numbers :( */
ndg->angle = ndg->streaks;
break;
case 0:
ndg->angle = ndg->star_45;
break;
default:
break;
}
}
BLO_write_struct_by_name(writer, node->typeinfo->storagename, node->storage);
}
else if ((ntree->type == NTREE_COMPOSIT) &&
(ELEM(node->type, CMP_NODE_CRYPTOMATTE, CMP_NODE_CRYPTOMATTE_LEGACY))) {
NodeCryptomatte *nc = (NodeCryptomatte *)node->storage;
BLO_write_string(writer, nc->matte_id);
LISTBASE_FOREACH (CryptomatteEntry *, entry, &nc->entries) {
BLO_write_struct(writer, CryptomatteEntry, entry);
}
BLO_write_struct_by_name(writer, node->typeinfo->storagename, node->storage);
}
else if (node->type == FN_NODE_INPUT_STRING) {
NodeInputString *storage = (NodeInputString *)node->storage;
if (storage->string) {
BLO_write_string(writer, storage->string);
}
BLO_write_struct_by_name(writer, node->typeinfo->storagename, storage);
}
else if (node->typeinfo != &NodeTypeUndefined) {
BLO_write_struct_by_name(writer, node->typeinfo->storagename, node->storage);
}
}
if (node->type == CMP_NODE_OUTPUT_FILE) {
/* Inputs have their own storage data. */
LISTBASE_FOREACH (bNodeSocket *, sock, &node->inputs) {
BLO_write_struct(writer, NodeImageMultiFileSocket, sock->storage);
}
}
if (ELEM(node->type, CMP_NODE_IMAGE, CMP_NODE_R_LAYERS)) {
/* Write extra socket info. */
LISTBASE_FOREACH (bNodeSocket *, sock, &node->outputs) {
BLO_write_struct(writer, NodeImageLayer, sock->storage);
}
}
}
LISTBASE_FOREACH (bNodeLink *, link, &ntree->links) {
BLO_write_struct(writer, bNodeLink, link);
}
LISTBASE_FOREACH (bNodeSocket *, sock, &ntree->inputs) {
write_node_socket_interface(writer, sock);
}
LISTBASE_FOREACH (bNodeSocket *, sock, &ntree->outputs) {
write_node_socket_interface(writer, sock);
}
BKE_previewimg_blend_write(writer, ntree->preview);
}
static void ntree_blend_write(BlendWriter *writer, ID *id, const void *id_address)
{
bNodeTree *ntree = (bNodeTree *)id;
/* Clean up, important in undo case to reduce false detection of changed datablocks. */
ntree->is_updating = false;
ntree->typeinfo = nullptr;
ntree->interface_type = nullptr;
ntree->progress = nullptr;
ntree->execdata = nullptr;
BLO_write_id_struct(writer, bNodeTree, id_address, &ntree->id);
ntreeBlendWrite(writer, ntree);
}
static void direct_link_node_socket(BlendDataReader *reader, bNodeSocket *sock)
{
BLO_read_data_address(reader, &sock->prop);
IDP_BlendDataRead(reader, &sock->prop);
BLO_read_data_address(reader, &sock->link);
sock->typeinfo = nullptr;
BLO_read_data_address(reader, &sock->storage);
BLO_read_data_address(reader, &sock->default_value);
sock->total_inputs = 0; /* Clear runtime data set before drawing. */
sock->cache = nullptr;
sock->declaration = nullptr;
}
void ntreeBlendReadData(BlendDataReader *reader, bNodeTree *ntree)
{
/* NOTE: writing and reading goes in sync, for speed. */
ntree->is_updating = false;
ntree->typeinfo = nullptr;
ntree->interface_type = nullptr;
ntree->progress = nullptr;
ntree->execdata = nullptr;
ntree->field_inferencing_interface = nullptr;
BKE_ntree_update_tag_missing_runtime_data(ntree);
BLO_read_data_address(reader, &ntree->adt);
BKE_animdata_blend_read_data(reader, ntree->adt);
BLO_read_list(reader, &ntree->nodes);
LISTBASE_FOREACH (bNode *, node, &ntree->nodes) {
node->typeinfo = nullptr;
node->declaration = nullptr;
BLO_read_list(reader, &node->inputs);
BLO_read_list(reader, &node->outputs);
BLO_read_data_address(reader, &node->prop);
IDP_BlendDataRead(reader, &node->prop);
BLO_read_list(reader, &node->internal_links);
LISTBASE_FOREACH (bNodeLink *, link, &node->internal_links) {
BLO_read_data_address(reader, &link->fromnode);
BLO_read_data_address(reader, &link->fromsock);
BLO_read_data_address(reader, &link->tonode);
BLO_read_data_address(reader, &link->tosock);
}
if (node->type == CMP_NODE_MOVIEDISTORTION) {
/* Do nothing, this is runtime cache and hence handled by generic code using
* `IDTypeInfo.foreach_cache` callback. */
}
else {
BLO_read_data_address(reader, &node->storage);
}
if (node->storage) {
switch (node->type) {
case SH_NODE_CURVE_VEC:
case SH_NODE_CURVE_RGB:
case SH_NODE_CURVE_FLOAT:
case CMP_NODE_TIME:
case CMP_NODE_CURVE_VEC:
case CMP_NODE_CURVE_RGB:
case CMP_NODE_HUECORRECT:
case TEX_NODE_CURVE_RGB:
case TEX_NODE_CURVE_TIME: {
BKE_curvemapping_blend_read(reader, (CurveMapping *)node->storage);
break;
}
case GEO_NODE_LEGACY_ATTRIBUTE_CURVE_MAP: {
NodeAttributeCurveMap *data = (NodeAttributeCurveMap *)node->storage;
BLO_read_data_address(reader, &data->curve_vec);
if (data->curve_vec) {
BKE_curvemapping_blend_read(reader, data->curve_vec);
}
BLO_read_data_address(reader, &data->curve_rgb);
if (data->curve_rgb) {
BKE_curvemapping_blend_read(reader, data->curve_rgb);
}
break;
}
case SH_NODE_SCRIPT: {
NodeShaderScript *nss = (NodeShaderScript *)node->storage;
BLO_read_data_address(reader, &nss->bytecode);
break;
}
case SH_NODE_TEX_POINTDENSITY: {
NodeShaderTexPointDensity *npd = (NodeShaderTexPointDensity *)node->storage;
memset(&npd->pd, 0, sizeof(npd->pd));
break;
}
case SH_NODE_TEX_IMAGE: {
NodeTexImage *tex = (NodeTexImage *)node->storage;
tex->iuser.scene = nullptr;
break;
}
case SH_NODE_TEX_ENVIRONMENT: {
NodeTexEnvironment *tex = (NodeTexEnvironment *)node->storage;
tex->iuser.scene = nullptr;
break;
}
case CMP_NODE_IMAGE:
case CMP_NODE_R_LAYERS:
case CMP_NODE_VIEWER:
case CMP_NODE_SPLITVIEWER: {
ImageUser *iuser = (ImageUser *)node->storage;
iuser->scene = nullptr;
break;
}
case CMP_NODE_CRYPTOMATTE_LEGACY:
case CMP_NODE_CRYPTOMATTE: {
NodeCryptomatte *nc = (NodeCryptomatte *)node->storage;
BLO_read_data_address(reader, &nc->matte_id);
BLO_read_list(reader, &nc->entries);
BLI_listbase_clear(&nc->runtime.layers);
break;
}
case TEX_NODE_IMAGE: {
ImageUser *iuser = (ImageUser *)node->storage;
iuser->scene = nullptr;
break;
}
case FN_NODE_INPUT_STRING: {
NodeInputString *storage = (NodeInputString *)node->storage;
BLO_read_data_address(reader, &storage->string);
break;
}
default:
break;
}
}
}
BLO_read_list(reader, &ntree->links);
/* and we connect the rest */
LISTBASE_FOREACH (bNode *, node, &ntree->nodes) {
BLO_read_data_address(reader, &node->parent);
LISTBASE_FOREACH (bNodeSocket *, sock, &node->inputs) {
direct_link_node_socket(reader, sock);
}
LISTBASE_FOREACH (bNodeSocket *, sock, &node->outputs) {
direct_link_node_socket(reader, sock);
}
}
/* interface socket lists */
BLO_read_list(reader, &ntree->inputs);
BLO_read_list(reader, &ntree->outputs);
LISTBASE_FOREACH (bNodeSocket *, sock, &ntree->inputs) {
direct_link_node_socket(reader, sock);
}
LISTBASE_FOREACH (bNodeSocket *, sock, &ntree->outputs) {
direct_link_node_socket(reader, sock);
}
LISTBASE_FOREACH (bNodeLink *, link, &ntree->links) {
BLO_read_data_address(reader, &link->fromnode);
BLO_read_data_address(reader, &link->tonode);
BLO_read_data_address(reader, &link->fromsock);
BLO_read_data_address(reader, &link->tosock);
}
/* TODO: should be dealt by new generic cache handling of IDs... */
ntree->previews = nullptr;
BLO_read_data_address(reader, &ntree->preview);
BKE_previewimg_blend_read(reader, ntree->preview);
/* type verification is in lib-link */
}
static void ntree_blend_read_data(BlendDataReader *reader, ID *id)
{
bNodeTree *ntree = (bNodeTree *)id;
ntreeBlendReadData(reader, ntree);
}
static void lib_link_node_socket(BlendLibReader *reader, Library *lib, bNodeSocket *sock)
{
IDP_BlendReadLib(reader, sock->prop);
/* This can happen for all socket types when a file is saved in an older version of Blender than
* it was originally created in (T86298). Some socket types still require a default value. The
* default value of those sockets will be created in `ntreeSetTypes`. */
if (sock->default_value == nullptr) {
return;
}
switch ((eNodeSocketDatatype)sock->type) {
case SOCK_OBJECT: {
bNodeSocketValueObject *default_value = (bNodeSocketValueObject *)sock->default_value;
BLO_read_id_address(reader, lib, &default_value->value);
break;
}
case SOCK_IMAGE: {
bNodeSocketValueImage *default_value = (bNodeSocketValueImage *)sock->default_value;
BLO_read_id_address(reader, lib, &default_value->value);
break;
}
case SOCK_COLLECTION: {
bNodeSocketValueCollection *default_value = (bNodeSocketValueCollection *)
sock->default_value;
BLO_read_id_address(reader, lib, &default_value->value);
break;
}
case SOCK_TEXTURE: {
bNodeSocketValueTexture *default_value = (bNodeSocketValueTexture *)sock->default_value;
BLO_read_id_address(reader, lib, &default_value->value);
break;
}
case SOCK_MATERIAL: {
bNodeSocketValueMaterial *default_value = (bNodeSocketValueMaterial *)sock->default_value;
BLO_read_id_address(reader, lib, &default_value->value);
break;
}
case SOCK_FLOAT:
case SOCK_VECTOR:
case SOCK_RGBA:
case SOCK_BOOLEAN:
case SOCK_INT:
case SOCK_STRING:
case __SOCK_MESH:
case SOCK_CUSTOM:
case SOCK_SHADER:
case SOCK_GEOMETRY:
break;
}
}
static void lib_link_node_sockets(BlendLibReader *reader, Library *lib, ListBase *sockets)
{
LISTBASE_FOREACH (bNodeSocket *, sock, sockets) {
lib_link_node_socket(reader, lib, sock);
}
}
void ntreeBlendReadLib(struct BlendLibReader *reader, struct bNodeTree *ntree)
{
Library *lib = ntree->id.lib;
BLO_read_id_address(reader, lib, &ntree->gpd);
LISTBASE_FOREACH (bNode *, node, &ntree->nodes) {
/* Link ID Properties -- and copy this comment EXACTLY for easy finding
* of library blocks that implement this. */
IDP_BlendReadLib(reader, node->prop);
BLO_read_id_address(reader, lib, &node->id);
lib_link_node_sockets(reader, lib, &node->inputs);
lib_link_node_sockets(reader, lib, &node->outputs);
}
lib_link_node_sockets(reader, lib, &ntree->inputs);
lib_link_node_sockets(reader, lib, &ntree->outputs);
/* Set node->typeinfo pointers. This is done in lib linking, after the
* first versioning that can change types still without functions that
* update the typeinfo pointers. Versioning after lib linking needs
* these top be valid. */
ntreeSetTypes(nullptr, ntree);
/* For nodes with static socket layout, add/remove sockets as needed
* to match the static layout. */
if (!BLO_read_lib_is_undo(reader)) {
LISTBASE_FOREACH (bNode *, node, &ntree->nodes) {
node_verify_sockets(ntree, node, false);
}
}
}
static void ntree_blend_read_lib(BlendLibReader *reader, ID *id)
{
bNodeTree *ntree = (bNodeTree *)id;
ntreeBlendReadLib(reader, ntree);
}
static void expand_node_socket(BlendExpander *expander, bNodeSocket *sock)
{
IDP_BlendReadExpand(expander, sock->prop);
if (sock->default_value != nullptr) {
switch ((eNodeSocketDatatype)sock->type) {
case SOCK_OBJECT: {
bNodeSocketValueObject *default_value = (bNodeSocketValueObject *)sock->default_value;
BLO_expand(expander, default_value->value);
break;
}
case SOCK_IMAGE: {
bNodeSocketValueImage *default_value = (bNodeSocketValueImage *)sock->default_value;
BLO_expand(expander, default_value->value);
break;
}
case SOCK_COLLECTION: {
bNodeSocketValueCollection *default_value = (bNodeSocketValueCollection *)
sock->default_value;
BLO_expand(expander, default_value->value);
break;
}
case SOCK_TEXTURE: {
bNodeSocketValueTexture *default_value = (bNodeSocketValueTexture *)sock->default_value;
BLO_expand(expander, default_value->value);
break;
}
case SOCK_MATERIAL: {
bNodeSocketValueMaterial *default_value = (bNodeSocketValueMaterial *)sock->default_value;
BLO_expand(expander, default_value->value);
break;
}
case SOCK_FLOAT:
case SOCK_VECTOR:
case SOCK_RGBA:
case SOCK_BOOLEAN:
case SOCK_INT:
case SOCK_STRING:
case __SOCK_MESH:
case SOCK_CUSTOM:
case SOCK_SHADER:
case SOCK_GEOMETRY:
break;
}
}
}
static void expand_node_sockets(BlendExpander *expander, ListBase *sockets)
{
LISTBASE_FOREACH (bNodeSocket *, sock, sockets) {
expand_node_socket(expander, sock);
}
}
void ntreeBlendReadExpand(BlendExpander *expander, bNodeTree *ntree)
{
if (ntree->gpd) {
BLO_expand(expander, ntree->gpd);
}
LISTBASE_FOREACH (bNode *, node, &ntree->nodes) {
if (node->id && !(node->type == CMP_NODE_R_LAYERS) &&
!(node->type == CMP_NODE_CRYPTOMATTE && node->custom1 == CMP_CRYPTOMATTE_SRC_RENDER)) {
BLO_expand(expander, node->id);
}
IDP_BlendReadExpand(expander, node->prop);
expand_node_sockets(expander, &node->inputs);
expand_node_sockets(expander, &node->outputs);
}
expand_node_sockets(expander, &ntree->inputs);
expand_node_sockets(expander, &ntree->outputs);
}
static void ntree_blend_read_expand(BlendExpander *expander, ID *id)
{
bNodeTree *ntree = (bNodeTree *)id;
ntreeBlendReadExpand(expander, ntree);
}
IDTypeInfo IDType_ID_NT = {
/* id_code */ ID_NT,
/* id_filter */ FILTER_ID_NT,
/* main_listbase_index */ INDEX_ID_NT,
/* struct_size */ sizeof(bNodeTree),
/* name */ "NodeTree",
/* name_plural */ "node_groups",
/* translation_context */ BLT_I18NCONTEXT_ID_NODETREE,
/* flags */ IDTYPE_FLAGS_APPEND_IS_REUSABLE,
/* asset_type_info */ nullptr,
/* init_data */ ntree_init_data,
/* copy_data */ ntree_copy_data,
/* free_data */ ntree_free_data,
/* make_local */ nullptr,
/* foreach_id */ node_foreach_id,
/* foreach_cache */ node_foreach_cache,
/* foreach_path */ node_foreach_path,
/* owner_get */ node_owner_get,
/* blend_write */ ntree_blend_write,
/* blend_read_data */ ntree_blend_read_data,
/* blend_read_lib */ ntree_blend_read_lib,
/* blend_read_expand */ ntree_blend_read_expand,
/* blend_read_undo_preserve */ nullptr,
/* lib_override_apply_post */ nullptr,
};
static void node_add_sockets_from_type(bNodeTree *ntree, bNode *node, bNodeType *ntype)
{
if (ntype->declare != nullptr) {
node_verify_sockets(ntree, node, true);
return;
}
bNodeSocketTemplate *sockdef;
if (ntype->inputs) {
sockdef = ntype->inputs;
while (sockdef->type != -1) {
node_add_socket_from_template(ntree, node, sockdef, SOCK_IN);
sockdef++;
}
}
if (ntype->outputs) {
sockdef = ntype->outputs;
while (sockdef->type != -1) {
node_add_socket_from_template(ntree, node, sockdef, SOCK_OUT);
sockdef++;
}
}
}
/* NOTE: This function is called to initialize node data based on the type.
* The bNodeType may not be registered at creation time of the node,
* so this can be delayed until the node type gets registered.
*/
static void node_init(const struct bContext *C, bNodeTree *ntree, bNode *node)
{
bNodeType *ntype = node->typeinfo;
if (ntype == &NodeTypeUndefined) {
return;
}
/* only do this once */
if (node->flag & NODE_INIT) {
return;
}
node->flag = NODE_SELECT | NODE_OPTIONS | ntype->flag;
node->width = ntype->width;
node->miniwidth = 42.0f;
node->height = ntype->height;
node->color[0] = node->color[1] = node->color[2] = 0.608; /* default theme color */
/* initialize the node name with the node label.
* NOTE: do this after the initfunc so nodes get their data set which may be used in naming
* (node groups for example) */
/* XXX Do not use nodeLabel() here, it returns translated content for UI,
* which should *only* be used in UI, *never* in data...
* Data have their own translation option!
* This solution may be a bit rougher than nodeLabel()'s returned string, but it's simpler
* than adding "do_translate" flags to this func (and labelfunc() as well). */
BLI_strncpy(node->name, DATA_(ntype->ui_name), NODE_MAXSTR);
nodeUniqueName(ntree, node);
node_add_sockets_from_type(ntree, node, ntype);
if (ntype->initfunc != nullptr) {
ntype->initfunc(ntree, node);
}
if (ntree->typeinfo->node_add_init != nullptr) {
ntree->typeinfo->node_add_init(ntree, node);
}
if (node->id) {
id_us_plus(node->id);
}
/* extra init callback */
if (ntype->initfunc_api) {
PointerRNA ptr;
RNA_pointer_create((ID *)ntree, &RNA_Node, node, &ptr);
/* XXX Warning: context can be nullptr in case nodes are added in do_versions.
* Delayed init is not supported for nodes with context-based `initfunc_api` at the moment. */
BLI_assert(C != nullptr);
ntype->initfunc_api(C, &ptr);
}
node->flag |= NODE_INIT;
}
static void ntree_set_typeinfo(bNodeTree *ntree, bNodeTreeType *typeinfo)
{
if (typeinfo) {
ntree->typeinfo = typeinfo;
}
else {
ntree->typeinfo = &NodeTreeTypeUndefined;
}
/* Deprecated integer type. */
ntree->type = ntree->typeinfo->type;
BKE_ntree_update_tag_all(ntree);
}
static void node_set_typeinfo(const struct bContext *C,
bNodeTree *ntree,
bNode *node,
bNodeType *typeinfo)
{
/* for nodes saved in older versions storage can get lost, make undefined then */
if (node->flag & NODE_INIT) {
if (typeinfo && typeinfo->storagename[0] && !node->storage) {
typeinfo = nullptr;
}
}
if (typeinfo) {
node->typeinfo = typeinfo;
/* deprecated integer type */
node->type = typeinfo->type;
/* initialize the node if necessary */
node_init(C, ntree, node);
}
else {
node->typeinfo = &NodeTypeUndefined;
}
}
static void node_socket_set_typeinfo(bNodeTree *ntree,
bNodeSocket *sock,
bNodeSocketType *typeinfo)
{
if (typeinfo) {
sock->typeinfo = typeinfo;
/* deprecated integer type */
sock->type = typeinfo->type;
if (sock->default_value == nullptr) {
/* initialize the default_value pointer used by standard socket types */
node_socket_init_default_value(sock);
}
}
else {
sock->typeinfo = &NodeSocketTypeUndefined;
}
BKE_ntree_update_tag_socket_type(ntree, sock);
}
/* Set specific typeinfo pointers in all node trees on register/unregister */
static void update_typeinfo(Main *bmain,
const struct bContext *C,
bNodeTreeType *treetype,
bNodeType *nodetype,
bNodeSocketType *socktype,
bool unregister)
{
if (!bmain) {
return;
}
FOREACH_NODETREE_BEGIN (bmain, ntree, id) {
if (treetype && STREQ(ntree->idname, treetype->idname)) {
ntree_set_typeinfo(ntree, unregister ? nullptr : treetype);
}
/* initialize nodes */
LISTBASE_FOREACH (bNode *, node, &ntree->nodes) {
if (nodetype && STREQ(node->idname, nodetype->idname)) {
node_set_typeinfo(C, ntree, node, unregister ? nullptr : nodetype);
}
/* initialize node sockets */
LISTBASE_FOREACH (bNodeSocket *, sock, &node->inputs) {
if (socktype && STREQ(sock->idname, socktype->idname)) {
node_socket_set_typeinfo(ntree, sock, unregister ? nullptr : socktype);
}
}
LISTBASE_FOREACH (bNodeSocket *, sock, &node->outputs) {
if (socktype && STREQ(sock->idname, socktype->idname)) {
node_socket_set_typeinfo(ntree, sock, unregister ? nullptr : socktype);
}
}
}
/* initialize tree sockets */
LISTBASE_FOREACH (bNodeSocket *, sock, &ntree->inputs) {
if (socktype && STREQ(sock->idname, socktype->idname)) {
node_socket_set_typeinfo(ntree, sock, unregister ? nullptr : socktype);
}
}
LISTBASE_FOREACH (bNodeSocket *, sock, &ntree->outputs) {
if (socktype && STREQ(sock->idname, socktype->idname)) {
node_socket_set_typeinfo(ntree, sock, unregister ? nullptr : socktype);
}
}
}
FOREACH_NODETREE_END;
}
void ntreeSetTypes(const struct bContext *C, bNodeTree *ntree)
{
ntree_set_typeinfo(ntree, ntreeTypeFind(ntree->idname));
LISTBASE_FOREACH (bNode *, node, &ntree->nodes) {
node_set_typeinfo(C, ntree, node, nodeTypeFind(node->idname));
LISTBASE_FOREACH (bNodeSocket *, sock, &node->inputs) {
node_socket_set_typeinfo(ntree, sock, nodeSocketTypeFind(sock->idname));
}
LISTBASE_FOREACH (bNodeSocket *, sock, &node->outputs) {
node_socket_set_typeinfo(ntree, sock, nodeSocketTypeFind(sock->idname));
}
}
LISTBASE_FOREACH (bNodeSocket *, sock, &ntree->inputs) {
node_socket_set_typeinfo(ntree, sock, nodeSocketTypeFind(sock->idname));
}
LISTBASE_FOREACH (bNodeSocket *, sock, &ntree->outputs) {
node_socket_set_typeinfo(ntree, sock, nodeSocketTypeFind(sock->idname));
}
}
static GHash *nodetreetypes_hash = nullptr;
static GHash *nodetypes_hash = nullptr;
static GHash *nodesockettypes_hash = nullptr;
bNodeTreeType *ntreeTypeFind(const char *idname)
{
if (idname[0]) {
bNodeTreeType *nt = (bNodeTreeType *)BLI_ghash_lookup(nodetreetypes_hash, idname);
if (nt) {
return nt;
}
}
return nullptr;
}
void ntreeTypeAdd(bNodeTreeType *nt)
{
BLI_ghash_insert(nodetreetypes_hash, nt->idname, nt);
/* XXX pass Main to register function? */
/* Probably not. It is pretty much expected we want to update G_MAIN here I think -
* or we'd want to update *all* active Mains, which we cannot do anyway currently. */
update_typeinfo(G_MAIN, nullptr, nt, nullptr, nullptr, false);
}
/* callback for hash value free function */
static void ntree_free_type(void *treetype_v)
{
bNodeTreeType *treetype = (bNodeTreeType *)treetype_v;
/* XXX pass Main to unregister function? */
/* Probably not. It is pretty much expected we want to update G_MAIN here I think -
* or we'd want to update *all* active Mains, which we cannot do anyway currently. */
update_typeinfo(G_MAIN, nullptr, treetype, nullptr, nullptr, true);
MEM_freeN(treetype);
}
void ntreeTypeFreeLink(const bNodeTreeType *nt)
{
BLI_ghash_remove(nodetreetypes_hash, nt->idname, nullptr, ntree_free_type);
}
bool ntreeIsRegistered(bNodeTree *ntree)
{
return (ntree->typeinfo != &NodeTreeTypeUndefined);
}
GHashIterator *ntreeTypeGetIterator()
{
return BLI_ghashIterator_new(nodetreetypes_hash);
}
bNodeType *nodeTypeFind(const char *idname)
{
if (idname[0]) {
bNodeType *nt = (bNodeType *)BLI_ghash_lookup(nodetypes_hash, idname);
if (nt) {
return nt;
}
}
return nullptr;
}
/* callback for hash value free function */
static void node_free_type(void *nodetype_v)
{
bNodeType *nodetype = (bNodeType *)nodetype_v;
/* XXX pass Main to unregister function? */
/* Probably not. It is pretty much expected we want to update G_MAIN here I think -
* or we'd want to update *all* active Mains, which we cannot do anyway currently. */
update_typeinfo(G_MAIN, nullptr, nullptr, nodetype, nullptr, true);
delete nodetype->fixed_declaration;
nodetype->fixed_declaration = nullptr;
/* Can be null when the type is not dynamically allocated. */
if (nodetype->free_self) {
nodetype->free_self(nodetype);
}
}
void nodeRegisterType(bNodeType *nt)
{
/* debug only: basic verification of registered types */
BLI_assert(nt->idname[0] != '\0');
BLI_assert(nt->poll != nullptr);
if (nt->declare && !nt->declaration_is_dynamic) {
if (nt->fixed_declaration == nullptr) {
nt->fixed_declaration = new blender::nodes::NodeDeclaration();
blender::nodes::NodeDeclarationBuilder builder{*nt->fixed_declaration};
nt->declare(builder);
}
}
BLI_ghash_insert(nodetypes_hash, nt->idname, nt);
/* XXX pass Main to register function? */
/* Probably not. It is pretty much expected we want to update G_MAIN here I think -
* or we'd want to update *all* active Mains, which we cannot do anyway currently. */
update_typeinfo(G_MAIN, nullptr, nullptr, nt, nullptr, false);
}
void nodeUnregisterType(bNodeType *nt)
{
BLI_ghash_remove(nodetypes_hash, nt->idname, nullptr, node_free_type);
}
bool nodeTypeUndefined(const bNode *node)
{
return (node->typeinfo == &NodeTypeUndefined) ||
((ELEM(node->type, NODE_GROUP, NODE_CUSTOM_GROUP)) && node->id &&
ID_IS_LINKED(node->id) && (node->id->tag & LIB_TAG_MISSING));
}
GHashIterator *nodeTypeGetIterator()
{
return BLI_ghashIterator_new(nodetypes_hash);
}
bNodeSocketType *nodeSocketTypeFind(const char *idname)
{
if (idname[0]) {
bNodeSocketType *st = (bNodeSocketType *)BLI_ghash_lookup(nodesockettypes_hash, idname);
if (st) {
return st;
}
}
return nullptr;
}
/* callback for hash value free function */
static void node_free_socket_type(void *socktype_v)
{
bNodeSocketType *socktype = (bNodeSocketType *)socktype_v;
/* XXX pass Main to unregister function? */
/* Probably not. It is pretty much expected we want to update G_MAIN here I think -
* or we'd want to update *all* active Mains, which we cannot do anyway currently. */
update_typeinfo(G_MAIN, nullptr, nullptr, nullptr, socktype, true);
socktype->free_self(socktype);
}
void nodeRegisterSocketType(bNodeSocketType *st)
{
BLI_ghash_insert(nodesockettypes_hash, (void *)st->idname, st);
/* XXX pass Main to register function? */
/* Probably not. It is pretty much expected we want to update G_MAIN here I think -
* or we'd want to update *all* active Mains, which we cannot do anyway currently. */
update_typeinfo(G_MAIN, nullptr, nullptr, nullptr, st, false);
}
void nodeUnregisterSocketType(bNodeSocketType *st)
{
BLI_ghash_remove(nodesockettypes_hash, st->idname, nullptr, node_free_socket_type);
}
bool nodeSocketIsRegistered(bNodeSocket *sock)
{
return (sock->typeinfo != &NodeSocketTypeUndefined);
}
GHashIterator *nodeSocketTypeGetIterator()
{
return BLI_ghashIterator_new(nodesockettypes_hash);
}
const char *nodeSocketTypeLabel(const bNodeSocketType *stype)
{
/* Use socket type name as a fallback if label is undefined. */
return stype->label[0] != '\0' ? stype->label : RNA_struct_ui_name(stype->ext_socket.srna);
}
struct bNodeSocket *nodeFindSocket(const bNode *node,
eNodeSocketInOut in_out,
const char *identifier)
{
const ListBase *sockets = (in_out == SOCK_IN) ? &node->inputs : &node->outputs;
LISTBASE_FOREACH (bNodeSocket *, sock, sockets) {
if (STREQ(sock->identifier, identifier)) {
return sock;
}
}
return nullptr;
}
namespace blender::bke {
bNodeSocket *node_find_enabled_socket(bNode &node,
const eNodeSocketInOut in_out,
const StringRef name)
{
ListBase *sockets = (in_out == SOCK_IN) ? &node.inputs : &node.outputs;
LISTBASE_FOREACH (bNodeSocket *, socket, sockets) {
if (!(socket->flag & SOCK_UNAVAIL) && socket->name == name) {
return socket;
}
}
return nullptr;
}
bNodeSocket *node_find_enabled_input_socket(bNode &node, StringRef name)
{
return node_find_enabled_socket(node, SOCK_IN, name);
}
bNodeSocket *node_find_enabled_output_socket(bNode &node, StringRef name)
{
return node_find_enabled_socket(node, SOCK_OUT, name);
}
} // namespace blender::bke
/* find unique socket identifier */
static bool unique_identifier_check(void *arg, const char *identifier)
{
const ListBase *lb = (const ListBase *)arg;
LISTBASE_FOREACH (bNodeSocket *, sock, lb) {
if (STREQ(sock->identifier, identifier)) {
return true;
}
}
return false;
}
static bNodeSocket *make_socket(bNodeTree *ntree,
bNode *UNUSED(node),
int in_out,
ListBase *lb,
const char *idname,
const char *identifier,
const char *name)
{
char auto_identifier[MAX_NAME];
if (identifier && identifier[0] != '\0') {
/* use explicit identifier */
BLI_strncpy(auto_identifier, identifier, sizeof(auto_identifier));
}
else {
/* if no explicit identifier is given, assign a unique identifier based on the name */
BLI_strncpy(auto_identifier, name, sizeof(auto_identifier));
}
/* Make the identifier unique. */
BLI_uniquename_cb(
unique_identifier_check, lb, "socket", '_', auto_identifier, sizeof(auto_identifier));
bNodeSocket *sock = MEM_cnew<bNodeSocket>("sock");
sock->in_out = in_out;
BLI_strncpy(sock->identifier, auto_identifier, NODE_MAXSTR);
sock->limit = (in_out == SOCK_IN ? 1 : 0xFFF);
BLI_strncpy(sock->name, name, NODE_MAXSTR);
sock->storage = nullptr;
sock->flag |= SOCK_COLLAPSED;
sock->type = SOCK_CUSTOM; /* int type undefined by default */
BLI_strncpy(sock->idname, idname, sizeof(sock->idname));
node_socket_set_typeinfo(ntree, sock, nodeSocketTypeFind(idname));
return sock;
}
static void socket_id_user_increment(bNodeSocket *sock)
{
switch ((eNodeSocketDatatype)sock->type) {
case SOCK_OBJECT: {
bNodeSocketValueObject *default_value = (bNodeSocketValueObject *)sock->default_value;
id_us_plus((ID *)default_value->value);
break;
}
case SOCK_IMAGE: {
bNodeSocketValueImage *default_value = (bNodeSocketValueImage *)sock->default_value;
id_us_plus((ID *)default_value->value);
break;
}
case SOCK_COLLECTION: {
bNodeSocketValueCollection *default_value = (bNodeSocketValueCollection *)
sock->default_value;
id_us_plus((ID *)default_value->value);
break;
}
case SOCK_TEXTURE: {
bNodeSocketValueTexture *default_value = (bNodeSocketValueTexture *)sock->default_value;
id_us_plus((ID *)default_value->value);
break;
}
case SOCK_MATERIAL: {
bNodeSocketValueMaterial *default_value = (bNodeSocketValueMaterial *)sock->default_value;
id_us_plus((ID *)default_value->value);
break;
}
case SOCK_FLOAT:
case SOCK_VECTOR:
case SOCK_RGBA:
case SOCK_BOOLEAN:
case SOCK_INT:
case SOCK_STRING:
case __SOCK_MESH:
case SOCK_CUSTOM:
case SOCK_SHADER:
case SOCK_GEOMETRY:
break;
}
}
/** \return True if the socket had an ID default value. */
static bool socket_id_user_decrement(bNodeSocket *sock)
{
switch ((eNodeSocketDatatype)sock->type) {
case SOCK_OBJECT: {
bNodeSocketValueObject *default_value = (bNodeSocketValueObject *)sock->default_value;
if (default_value->value != nullptr) {
id_us_min(&default_value->value->id);
return true;
}
break;
}
case SOCK_IMAGE: {
bNodeSocketValueImage *default_value = (bNodeSocketValueImage *)sock->default_value;
if (default_value->value != nullptr) {
id_us_min(&default_value->value->id);
return true;
}
break;
}
case SOCK_COLLECTION: {
bNodeSocketValueCollection *default_value = (bNodeSocketValueCollection *)
sock->default_value;
if (default_value->value != nullptr) {
id_us_min(&default_value->value->id);
return true;
}
break;
}
case SOCK_TEXTURE: {
bNodeSocketValueTexture *default_value = (bNodeSocketValueTexture *)sock->default_value;
if (default_value->value != nullptr) {
id_us_min(&default_value->value->id);
return true;
}
break;
}
case SOCK_MATERIAL: {
bNodeSocketValueMaterial *default_value = (bNodeSocketValueMaterial *)sock->default_value;
if (default_value->value != nullptr) {
id_us_min(&default_value->value->id);
return true;
}
break;
}
case SOCK_FLOAT:
case SOCK_VECTOR:
case SOCK_RGBA:
case SOCK_BOOLEAN:
case SOCK_INT:
case SOCK_STRING:
case __SOCK_MESH:
case SOCK_CUSTOM:
case SOCK_SHADER:
case SOCK_GEOMETRY:
break;
}
return false;
}
void nodeModifySocketType(bNodeTree *ntree,
bNode *UNUSED(node),
bNodeSocket *sock,
const char *idname)
{
bNodeSocketType *socktype = nodeSocketTypeFind(idname);
if (!socktype) {
CLOG_ERROR(&LOG, "node socket type %s undefined", idname);
return;
}
if (sock->default_value) {
socket_id_user_decrement(sock);
MEM_freeN(sock->default_value);
sock->default_value = nullptr;
}
BLI_strncpy(sock->idname, idname, sizeof(sock->idname));
node_socket_set_typeinfo(ntree, sock, socktype);
}
void nodeModifySocketTypeStatic(
bNodeTree *ntree, bNode *node, bNodeSocket *sock, int type, int subtype)
{
const char *idname = nodeStaticSocketType(type, subtype);
if (!idname) {
CLOG_ERROR(&LOG, "static node socket type %d undefined", type);
return;
}
nodeModifySocketType(ntree, node, sock, idname);
}
bNodeSocket *nodeAddSocket(bNodeTree *ntree,
bNode *node,
eNodeSocketInOut in_out,
const char *idname,
const char *identifier,
const char *name)
{
BLI_assert(node->type != NODE_FRAME);
BLI_assert(!(in_out == SOCK_IN && node->type == NODE_GROUP_INPUT));
BLI_assert(!(in_out == SOCK_OUT && node->type == NODE_GROUP_OUTPUT));
ListBase *lb = (in_out == SOCK_IN ? &node->inputs : &node->outputs);
bNodeSocket *sock = make_socket(ntree, node, in_out, lb, idname, identifier, name);
BLI_remlink(lb, sock); /* does nothing for new socket */
BLI_addtail(lb, sock);
BKE_ntree_update_tag_socket_new(ntree, sock);
return sock;
}
bool nodeIsStaticSocketType(const struct bNodeSocketType *stype)
{
/*
* Cannot rely on type==SOCK_CUSTOM here, because type is 0 by default
* and can be changed on custom sockets.
*/
return RNA_struct_is_a(stype->ext_socket.srna, &RNA_NodeSocketStandard);
}
const char *nodeStaticSocketType(int type, int subtype)
{
switch (type) {
case SOCK_FLOAT:
switch (subtype) {
case PROP_UNSIGNED:
return "NodeSocketFloatUnsigned";
case PROP_PERCENTAGE:
return "NodeSocketFloatPercentage";
case PROP_FACTOR:
return "NodeSocketFloatFactor";
case PROP_ANGLE:
return "NodeSocketFloatAngle";
case PROP_TIME:
return "NodeSocketFloatTime";
case PROP_TIME_ABSOLUTE:
return "NodeSocketFloatTimeAbsolute";
case PROP_DISTANCE:
return "NodeSocketFloatDistance";
case PROP_NONE:
default:
return "NodeSocketFloat";
}
case SOCK_INT:
switch (subtype) {
case PROP_UNSIGNED:
return "NodeSocketIntUnsigned";
case PROP_PERCENTAGE:
return "NodeSocketIntPercentage";
case PROP_FACTOR:
return "NodeSocketIntFactor";
case PROP_NONE:
default:
return "NodeSocketInt";
}
case SOCK_BOOLEAN:
return "NodeSocketBool";
case SOCK_VECTOR:
switch (subtype) {
case PROP_TRANSLATION:
return "NodeSocketVectorTranslation";
case PROP_DIRECTION:
return "NodeSocketVectorDirection";
case PROP_VELOCITY:
return "NodeSocketVectorVelocity";
case PROP_ACCELERATION:
return "NodeSocketVectorAcceleration";
case PROP_EULER:
return "NodeSocketVectorEuler";
case PROP_XYZ:
return "NodeSocketVectorXYZ";
case PROP_NONE:
default:
return "NodeSocketVector";
}
case SOCK_RGBA:
return "NodeSocketColor";
case SOCK_STRING:
return "NodeSocketString";
case SOCK_SHADER:
return "NodeSocketShader";
case SOCK_OBJECT:
return "NodeSocketObject";
case SOCK_IMAGE:
return "NodeSocketImage";
case SOCK_GEOMETRY:
return "NodeSocketGeometry";
case SOCK_COLLECTION:
return "NodeSocketCollection";
case SOCK_TEXTURE:
return "NodeSocketTexture";
case SOCK_MATERIAL:
return "NodeSocketMaterial";
}
return nullptr;
}
const char *nodeStaticSocketInterfaceType(int type, int subtype)
{
switch (type) {
case SOCK_FLOAT:
switch (subtype) {
case PROP_UNSIGNED:
return "NodeSocketInterfaceFloatUnsigned";
case PROP_PERCENTAGE:
return "NodeSocketInterfaceFloatPercentage";
case PROP_FACTOR:
return "NodeSocketInterfaceFloatFactor";
case PROP_ANGLE:
return "NodeSocketInterfaceFloatAngle";
case PROP_TIME:
return "NodeSocketInterfaceFloatTime";
case PROP_TIME_ABSOLUTE:
return "NodeSocketInterfaceFloatTimeAbsolute";
case PROP_DISTANCE:
return "NodeSocketInterfaceFloatDistance";
case PROP_NONE:
default:
return "NodeSocketInterfaceFloat";
}
case SOCK_INT:
switch (subtype) {
case PROP_UNSIGNED:
return "NodeSocketInterfaceIntUnsigned";
case PROP_PERCENTAGE:
return "NodeSocketInterfaceIntPercentage";
case PROP_FACTOR:
return "NodeSocketInterfaceIntFactor";
case PROP_NONE:
default:
return "NodeSocketInterfaceInt";
}
case SOCK_BOOLEAN:
return "NodeSocketInterfaceBool";
case SOCK_VECTOR:
switch (subtype) {
case PROP_TRANSLATION:
return "NodeSocketInterfaceVectorTranslation";
case PROP_DIRECTION:
return "NodeSocketInterfaceVectorDirection";
case PROP_VELOCITY:
return "NodeSocketInterfaceVectorVelocity";
case PROP_ACCELERATION:
return "NodeSocketInterfaceVectorAcceleration";
case PROP_EULER:
return "NodeSocketInterfaceVectorEuler";
case PROP_XYZ:
return "NodeSocketInterfaceVectorXYZ";
case PROP_NONE:
default:
return "NodeSocketInterfaceVector";
}
case SOCK_RGBA:
return "NodeSocketInterfaceColor";
case SOCK_STRING:
return "NodeSocketInterfaceString";
case SOCK_SHADER:
return "NodeSocketInterfaceShader";
case SOCK_OBJECT:
return "NodeSocketInterfaceObject";
case SOCK_IMAGE:
return "NodeSocketInterfaceImage";
case SOCK_GEOMETRY:
return "NodeSocketInterfaceGeometry";
case SOCK_COLLECTION:
return "NodeSocketInterfaceCollection";
case SOCK_TEXTURE:
return "NodeSocketInterfaceTexture";
case SOCK_MATERIAL:
return "NodeSocketInterfaceMaterial";
}
return nullptr;
}
const char *nodeStaticSocketLabel(int type, int UNUSED(subtype))
{
switch (type) {
case SOCK_FLOAT:
return "Float";
case SOCK_INT:
return "Integer";
case SOCK_BOOLEAN:
return "Boolean";
case SOCK_VECTOR:
return "Vector";
case SOCK_RGBA:
return "Color";
case SOCK_STRING:
return "String";
case SOCK_SHADER:
return "Shader";
case SOCK_OBJECT:
return "Object";
case SOCK_IMAGE:
return "Image";
case SOCK_GEOMETRY:
return "Geometry";
case SOCK_COLLECTION:
return "Collection";
case SOCK_TEXTURE:
return "Texture";
case SOCK_MATERIAL:
return "Material";
}
return nullptr;
}
bNodeSocket *nodeAddStaticSocket(bNodeTree *ntree,
bNode *node,
eNodeSocketInOut in_out,
int type,
int subtype,
const char *identifier,
const char *name)
{
const char *idname = nodeStaticSocketType(type, subtype);
if (!idname) {
CLOG_ERROR(&LOG, "static node socket type %d undefined", type);
return nullptr;
}
bNodeSocket *sock = nodeAddSocket(ntree, node, in_out, idname, identifier, name);
sock->type = type;
return sock;
}
static void node_socket_free(bNodeSocket *sock, const bool do_id_user)
{
if (sock->prop) {
IDP_FreePropertyContent_ex(sock->prop, do_id_user);
MEM_freeN(sock->prop);
}
if (sock->default_value) {
if (do_id_user) {
socket_id_user_decrement(sock);
}
MEM_freeN(sock->default_value);
}
}
void nodeRemoveSocket(bNodeTree *ntree, bNode *node, bNodeSocket *sock)
{
nodeRemoveSocketEx(ntree, node, sock, true);
}
void nodeRemoveSocketEx(struct bNodeTree *ntree,
struct bNode *node,
struct bNodeSocket *sock,
bool do_id_user)
{
LISTBASE_FOREACH_MUTABLE (bNodeLink *, link, &ntree->links) {
if (link->fromsock == sock || link->tosock == sock) {
nodeRemLink(ntree, link);
}
}
LISTBASE_FOREACH_MUTABLE (bNodeLink *, link, &node->internal_links) {
if (link->fromsock == sock || link->tosock == sock) {
BLI_remlink(&node->internal_links, link);
MEM_freeN(link);
BKE_ntree_update_tag_node_internal_link(ntree, node);
}
}
/* this is fast, this way we don't need an in_out argument */
BLI_remlink(&node->inputs, sock);
BLI_remlink(&node->outputs, sock);
node_socket_free(sock, do_id_user);
MEM_freeN(sock);
BKE_ntree_update_tag_socket_removed(ntree);
}
void nodeRemoveAllSockets(bNodeTree *ntree, bNode *node)
{
LISTBASE_FOREACH_MUTABLE (bNodeLink *, link, &ntree->links) {
if (link->fromnode == node || link->tonode == node) {
nodeRemLink(ntree, link);
}
}
LISTBASE_FOREACH_MUTABLE (bNodeSocket *, sock, &node->inputs) {
node_socket_free(sock, true);
MEM_freeN(sock);
}
BLI_listbase_clear(&node->inputs);
LISTBASE_FOREACH_MUTABLE (bNodeSocket *, sock, &node->outputs) {
node_socket_free(sock, true);
MEM_freeN(sock);
}
BLI_listbase_clear(&node->outputs);
BKE_ntree_update_tag_socket_removed(ntree);
}
bNode *nodeFindNodebyName(bNodeTree *ntree, const char *name)
{
return (bNode *)BLI_findstring(&ntree->nodes, name, offsetof(bNode, name));
}
bool nodeFindNode(bNodeTree *ntree, bNodeSocket *sock, bNode **r_node, int *r_sockindex)
{
*r_node = nullptr;
LISTBASE_FOREACH (bNode *, node, &ntree->nodes) {
ListBase *sockets = (sock->in_out == SOCK_IN) ? &node->inputs : &node->outputs;
int index = 0;
LISTBASE_FOREACH (bNodeSocket *, tsock, sockets) {
if (sock == tsock) {
if (r_node != nullptr) {
*r_node = node;
}
if (r_sockindex != nullptr) {
*r_sockindex = index;
}
return true;
}
index++;
}
}
return false;
}
bNode *nodeFindRootParent(bNode *node)
{
if (node->parent) {
return nodeFindRootParent(node->parent);
}
return node->type == NODE_FRAME ? node : nullptr;
}
bool nodeIsChildOf(const bNode *parent, const bNode *child)
{
if (parent == child) {
return true;
}
if (child->parent) {
return nodeIsChildOf(parent, child->parent);
}
return false;
}
void nodeChainIter(const bNodeTree *ntree,
const bNode *node_start,
bool (*callback)(bNode *, bNode *, void *, const bool),
void *userdata,
const bool reversed)
{
LISTBASE_FOREACH (bNodeLink *, link, &ntree->links) {
if ((link->flag & NODE_LINK_VALID) == 0) {
/* Skip links marked as cyclic. */
continue;
}
if (link->tonode && link->fromnode) {
/* Is the link part of the chain meaning node_start == fromnode
* (or tonode for reversed case)? */
if ((reversed && (link->tonode == node_start)) ||
(!reversed && link->fromnode == node_start)) {
if (!callback(link->fromnode, link->tonode, userdata, reversed)) {
return;
}
nodeChainIter(
ntree, reversed ? link->fromnode : link->tonode, callback, userdata, reversed);
}
}
}
}
static void iter_backwards_ex(const bNodeTree *ntree,
const bNode *node_start,
bool (*callback)(bNode *, bNode *, void *),
void *userdata,
char recursion_mask)
{
LISTBASE_FOREACH (bNodeSocket *, sock, &node_start->inputs) {
bNodeLink *link = sock->link;
if (link == nullptr) {
continue;
}
if ((link->flag & NODE_LINK_VALID) == 0) {
/* Skip links marked as cyclic. */
continue;
}
if (link->fromnode->iter_flag & recursion_mask) {
continue;
}
link->fromnode->iter_flag |= recursion_mask;
if (!callback(link->fromnode, link->tonode, userdata)) {
return;
}
iter_backwards_ex(ntree, link->fromnode, callback, userdata, recursion_mask);
}
}
void nodeChainIterBackwards(const bNodeTree *ntree,
const bNode *node_start,
bool (*callback)(bNode *, bNode *, void *),
void *userdata,
int recursion_lvl)
{
if (!node_start) {
return;
}
/* Limited by iter_flag type. */
BLI_assert(recursion_lvl < 8);
char recursion_mask = (1 << recursion_lvl);
/* Reset flag. */
LISTBASE_FOREACH (bNode *, node, &ntree->nodes) {
node->iter_flag &= ~recursion_mask;
}
iter_backwards_ex(ntree, node_start, callback, userdata, recursion_mask);
}
void nodeParentsIter(bNode *node, bool (*callback)(bNode *, void *), void *userdata)
{
if (node->parent) {
if (!callback(node->parent, userdata)) {
return;
}
nodeParentsIter(node->parent, callback, userdata);
}
}
/* ************** Add stuff ********** */
void nodeUniqueName(bNodeTree *ntree, bNode *node)
{
BLI_uniquename(
&ntree->nodes, node, DATA_("Node"), '.', offsetof(bNode, name), sizeof(node->name));
}
bNode *nodeAddNode(const struct bContext *C, bNodeTree *ntree, const char *idname)
{
bNode *node = MEM_cnew<bNode>("new node");
BLI_addtail(&ntree->nodes, node);
BLI_strncpy(node->idname, idname, sizeof(node->idname));
node_set_typeinfo(C, ntree, node, nodeTypeFind(idname));
BKE_ntree_update_tag_node_new(ntree, node);
if (node->type == GEO_NODE_INPUT_SCENE_TIME) {
DEG_relations_tag_update(CTX_data_main(C));
}
return node;
}
bNode *nodeAddStaticNode(const struct bContext *C, bNodeTree *ntree, int type)
{
const char *idname = nullptr;
NODE_TYPES_BEGIN (ntype) {
/* Do an extra poll here, because some int types are used
* for multiple node types, this helps find the desired type. */
const char *disabled_hint;
if (ntype->type == type && (!ntype->poll || ntype->poll(ntype, ntree, &disabled_hint))) {
idname = ntype->idname;
break;
}
}
NODE_TYPES_END;
if (!idname) {
CLOG_ERROR(&LOG, "static node type %d undefined", type);
return nullptr;
}
return nodeAddNode(C, ntree, idname);
}
static void node_socket_copy(bNodeSocket *sock_dst, const bNodeSocket *sock_src, const int flag)
{
if (sock_src->prop) {
sock_dst->prop = IDP_CopyProperty_ex(sock_src->prop, flag);
}
if (sock_src->default_value) {
sock_dst->default_value = MEM_dupallocN(sock_src->default_value);
if ((flag & LIB_ID_CREATE_NO_USER_REFCOUNT) == 0) {
socket_id_user_increment(sock_dst);
}
}
sock_dst->stack_index = 0;
/* XXX some compositor nodes (e.g. image, render layers) still store
* some persistent buffer data here, need to clear this to avoid dangling pointers. */
sock_dst->cache = nullptr;
}
namespace blender::bke {
bNode *node_copy_with_mapping(bNodeTree *dst_tree,
const bNode &node_src,
const int flag,
const bool unique_name,
Map<const bNodeSocket *, bNodeSocket *> &socket_map)
{
bNode *node_dst = (bNode *)MEM_mallocN(sizeof(bNode), __func__);
*node_dst = node_src;
/* Can be called for nodes outside a node tree (e.g. clipboard). */
if (dst_tree) {
if (unique_name) {
nodeUniqueName(dst_tree, node_dst);
}
BLI_addtail(&dst_tree->nodes, node_dst);
}
BLI_listbase_clear(&node_dst->inputs);
LISTBASE_FOREACH (const bNodeSocket *, src_socket, &node_src.inputs) {
bNodeSocket *dst_socket = (bNodeSocket *)MEM_dupallocN(src_socket);
node_socket_copy(dst_socket, src_socket, flag);
BLI_addtail(&node_dst->inputs, dst_socket);
socket_map.add_new(src_socket, dst_socket);
}
BLI_listbase_clear(&node_dst->outputs);
LISTBASE_FOREACH (const bNodeSocket *, src_socket, &node_src.outputs) {
bNodeSocket *dst_socket = (bNodeSocket *)MEM_dupallocN(src_socket);
node_socket_copy(dst_socket, src_socket, flag);
BLI_addtail(&node_dst->outputs, dst_socket);
socket_map.add_new(src_socket, dst_socket);
}
if (node_src.prop) {
node_dst->prop = IDP_CopyProperty_ex(node_src.prop, flag);
}
BLI_listbase_clear(&node_dst->internal_links);
LISTBASE_FOREACH (const bNodeLink *, src_link, &node_src.internal_links) {
bNodeLink *dst_link = (bNodeLink *)MEM_dupallocN(src_link);
dst_link->fromnode = node_dst;
dst_link->tonode = node_dst;
dst_link->fromsock = socket_map.lookup(src_link->fromsock);
dst_link->tosock = socket_map.lookup(src_link->tosock);
BLI_addtail(&node_dst->internal_links, dst_link);
}
if ((flag & LIB_ID_CREATE_NO_USER_REFCOUNT) == 0) {
id_us_plus(node_dst->id);
}
if (node_src.typeinfo->copyfunc) {
node_src.typeinfo->copyfunc(dst_tree, node_dst, &node_src);
}
/* Only call copy function when a copy is made for the main database, not
* for cases like the dependency graph and localization. */
if (node_dst->typeinfo->copyfunc_api && !(flag & LIB_ID_CREATE_NO_MAIN)) {
PointerRNA ptr;
RNA_pointer_create((ID *)dst_tree, &RNA_Node, node_dst, &ptr);
node_dst->typeinfo->copyfunc_api(&ptr, &node_src);
}
if (dst_tree) {
BKE_ntree_update_tag_node_new(dst_tree, node_dst);
}
/* Reset the declaration of the new node. */
node_dst->declaration = nullptr;
nodeDeclarationEnsure(dst_tree, node_dst);
return node_dst;
}
bNode *node_copy(bNodeTree *dst_tree,
const bNode &src_node,
const int flag,
const bool unique_name)
{
Map<const bNodeSocket *, bNodeSocket *> socket_map;
return node_copy_with_mapping(dst_tree, src_node, flag, unique_name, socket_map);
}
} // namespace blender::bke
static int node_count_links(const bNodeTree *ntree, const bNodeSocket *socket)
{
int count = 0;
LISTBASE_FOREACH (bNodeLink *, link, &ntree->links) {
if (ELEM(socket, link->fromsock, link->tosock)) {
count++;
}
}
return count;
}
bNodeLink *nodeAddLink(
bNodeTree *ntree, bNode *fromnode, bNodeSocket *fromsock, bNode *tonode, bNodeSocket *tosock)
{
bNodeLink *link = nullptr;
/* Test valid input. */
BLI_assert(fromnode);
BLI_assert(tonode);
if (fromsock->in_out == SOCK_OUT && tosock->in_out == SOCK_IN) {
link = MEM_cnew<bNodeLink>("link");
if (ntree) {
BLI_addtail(&ntree->links, link);
}
link->fromnode = fromnode;
link->fromsock = fromsock;
link->tonode = tonode;
link->tosock = tosock;
}
else if (fromsock->in_out == SOCK_IN && tosock->in_out == SOCK_OUT) {
/* OK but flip */
link = MEM_cnew<bNodeLink>("link");
if (ntree) {
BLI_addtail(&ntree->links, link);
}
link->fromnode = tonode;
link->fromsock = tosock;
link->tonode = fromnode;
link->tosock = fromsock;
}
if (ntree) {
BKE_ntree_update_tag_link_added(ntree, link);
}
if (link != nullptr && link->tosock->flag & SOCK_MULTI_INPUT) {
link->multi_input_socket_index = node_count_links(ntree, link->tosock) - 1;
}
return link;
}
void nodeRemLink(bNodeTree *ntree, bNodeLink *link)
{
/* Can be called for links outside a node tree (e.g. clipboard). */
if (ntree) {
BLI_remlink(&ntree->links, link);
}
if (link->tosock) {
link->tosock->link = nullptr;
}
MEM_freeN(link);
if (ntree) {
BKE_ntree_update_tag_link_removed(ntree);
}
}
/* Check if all output links are muted or not. */
static bool nodeMuteFromSocketLinks(const bNodeTree *ntree, const bNodeSocket *sock)
{
int tot = 0;
int muted = 0;
LISTBASE_FOREACH (const bNodeLink *, link, &ntree->links) {
if (link->fromsock == sock) {
tot++;
if (link->flag & NODE_LINK_MUTED) {
muted++;
}
}
}
return tot == muted;
}
static void nodeMuteLink(bNodeLink *link)
{
link->flag |= NODE_LINK_MUTED;
link->flag |= NODE_LINK_TEST;
if (!(link->tosock->flag & SOCK_MULTI_INPUT)) {
link->tosock->flag &= ~SOCK_IN_USE;
}
}
static void nodeUnMuteLink(bNodeLink *link)
{
link->flag &= ~NODE_LINK_MUTED;
link->flag |= NODE_LINK_TEST;
link->tosock->flag |= SOCK_IN_USE;
}
/* Upstream muting. Always happens when unmuting but checks when muting. O(n^2) algorithm. */
static void nodeMuteRerouteInputLinks(bNodeTree *ntree, bNode *node, const bool mute)
{
if (node->type != NODE_REROUTE) {
return;
}
if (!mute || nodeMuteFromSocketLinks(ntree, (bNodeSocket *)node->outputs.first)) {
bNodeSocket *sock = (bNodeSocket *)node->inputs.first;
LISTBASE_FOREACH (bNodeLink *, link, &ntree->links) {
if (!(link->flag & NODE_LINK_VALID) || (link->tosock != sock)) {
continue;
}
if (mute) {
nodeMuteLink(link);
}
else {
nodeUnMuteLink(link);
}
nodeMuteRerouteInputLinks(ntree, link->fromnode, mute);
}
}
}
/* Downstream muting propagates when reaching reroute nodes. O(n^2) algorithm. */
static void nodeMuteRerouteOutputLinks(bNodeTree *ntree, bNode *node, const bool mute)
{
if (node->type != NODE_REROUTE) {
return;
}
bNodeSocket *sock;
sock = (bNodeSocket *)node->outputs.first;
LISTBASE_FOREACH (bNodeLink *, link, &ntree->links) {
if (!(link->flag & NODE_LINK_VALID) || (link->fromsock != sock)) {
continue;
}
if (mute) {
nodeMuteLink(link);
}
else {
nodeUnMuteLink(link);
}
nodeMuteRerouteOutputLinks(ntree, link->tonode, mute);
}
}
void nodeMuteLinkToggle(bNodeTree *ntree, bNodeLink *link)
{
if (link->tosock) {
bool mute = !(link->flag & NODE_LINK_MUTED);
if (mute) {
nodeMuteLink(link);
}
else {
nodeUnMuteLink(link);
}
if (link->tonode->type == NODE_REROUTE) {
nodeMuteRerouteOutputLinks(ntree, link->tonode, mute);
}
if (link->fromnode->type == NODE_REROUTE) {
nodeMuteRerouteInputLinks(ntree, link->fromnode, mute);
}
}
if (ntree) {
BKE_ntree_update_tag_link_mute(ntree, link);
}
}
void nodeRemSocketLinks(bNodeTree *ntree, bNodeSocket *sock)
{
LISTBASE_FOREACH_MUTABLE (bNodeLink *, link, &ntree->links) {
if (link->fromsock == sock || link->tosock == sock) {
nodeRemLink(ntree, link);
}
}
}
bool nodeLinkIsHidden(const bNodeLink *link)
{
return nodeSocketIsHidden(link->fromsock) || nodeSocketIsHidden(link->tosock);
}
/* Adjust the indices of links connected to the given multi input socket after deleting the link at
* `deleted_index`. This function also works if the link has not yet been deleted. */
static void adjust_multi_input_indices_after_removed_link(bNodeTree *ntree,
bNodeSocket *sock,
int deleted_index)
{
LISTBASE_FOREACH (bNodeLink *, link, &ntree->links) {
/* We only need to adjust those with a greater index, because the others will have the same
* index. */
if (link->tosock != sock || link->multi_input_socket_index <= deleted_index) {
continue;
}
link->multi_input_socket_index -= 1;
}
}
void nodeInternalRelink(bNodeTree *ntree, bNode *node)
{
/* store link pointers in output sockets, for efficient lookup */
LISTBASE_FOREACH (bNodeLink *, link, &node->internal_links) {
link->tosock->link = link;
}
/* redirect downstream links */
LISTBASE_FOREACH_MUTABLE (bNodeLink *, link, &ntree->links) {
/* do we have internal link? */
if (link->fromnode == node) {
if (link->fromsock->link) {
/* get the upstream input link */
bNodeLink *fromlink = link->fromsock->link->fromsock->link;
/* skip the node */
if (fromlink) {
if (link->tosock->flag & SOCK_MULTI_INPUT) {
/* remove the link that would be the same as the relinked one */
LISTBASE_FOREACH_MUTABLE (bNodeLink *, link_to_compare, &ntree->links) {
if (link_to_compare->fromsock == fromlink->fromsock &&
link_to_compare->tosock == link->tosock) {
adjust_multi_input_indices_after_removed_link(
ntree, link_to_compare->tosock, link_to_compare->multi_input_socket_index);
nodeRemLink(ntree, link_to_compare);
}
}
}
link->fromnode = fromlink->fromnode;
link->fromsock = fromlink->fromsock;
/* if the up- or downstream link is invalid,
* the replacement link will be invalid too.
*/
if (!(fromlink->flag & NODE_LINK_VALID)) {
link->flag &= ~NODE_LINK_VALID;
}
if (fromlink->flag & NODE_LINK_MUTED) {
link->flag |= NODE_LINK_MUTED;
}
BKE_ntree_update_tag_link_changed(ntree);
}
else {
if (link->tosock->flag & SOCK_MULTI_INPUT) {
adjust_multi_input_indices_after_removed_link(
ntree, link->tosock, link->multi_input_socket_index);
}
nodeRemLink(ntree, link);
}
}
else {
if (link->tosock->flag & SOCK_MULTI_INPUT) {
adjust_multi_input_indices_after_removed_link(
ntree, link->tosock, link->multi_input_socket_index);
};
nodeRemLink(ntree, link);
}
}
}
/* remove remaining upstream links */
LISTBASE_FOREACH_MUTABLE (bNodeLink *, link, &ntree->links) {
if (link->tonode == node) {
nodeRemLink(ntree, link);
}
}
}
void nodeToView(const bNode *node, float x, float y, float *rx, float *ry)
{
if (node->parent) {
nodeToView(node->parent, x + node->locx, y + node->locy, rx, ry);
}
else {
*rx = x + node->locx;
*ry = y + node->locy;
}
}
void nodeFromView(const bNode *node, float x, float y, float *rx, float *ry)
{
if (node->parent) {
nodeFromView(node->parent, x, y, rx, ry);
*rx -= node->locx;
*ry -= node->locy;
}
else {
*rx = x - node->locx;
*ry = y - node->locy;
}
}
bool nodeAttachNodeCheck(const bNode *node, const bNode *parent)
{
for (const bNode *parent_iter = node; parent_iter; parent_iter = parent_iter->parent) {
if (parent_iter == parent) {
return true;
}
}
return false;
}
void nodeAttachNode(bNode *node, bNode *parent)
{
BLI_assert(parent->type == NODE_FRAME);
BLI_assert(nodeAttachNodeCheck(parent, node) == false);
float locx, locy;
nodeToView(node, 0.0f, 0.0f, &locx, &locy);
node->parent = parent;
/* transform to parent space */
nodeFromView(parent, locx, locy, &node->locx, &node->locy);
}
void nodeDetachNode(struct bNode *node)
{
if (node->parent) {
BLI_assert(node->parent->type == NODE_FRAME);
/* transform to view space */
float locx, locy;
nodeToView(node, 0.0f, 0.0f, &locx, &locy);
node->locx = locx;
node->locy = locy;
node->parent = nullptr;
}
}
void nodePositionRelative(bNode *from_node,
bNode *to_node,
bNodeSocket *from_sock,
bNodeSocket *to_sock)
{
float offset_x;
int tot_sock_idx;
/* Socket to plug into. */
if (SOCK_IN == to_sock->in_out) {
offset_x = -(from_node->typeinfo->width + 50);
tot_sock_idx = BLI_listbase_count(&to_node->outputs);
tot_sock_idx += BLI_findindex(&to_node->inputs, to_sock);
}
else {
offset_x = to_node->typeinfo->width + 50;
tot_sock_idx = BLI_findindex(&to_node->outputs, to_sock);
}
BLI_assert(tot_sock_idx != -1);
float offset_y = U.widget_unit * tot_sock_idx;
/* Output socket. */
if (from_sock) {
if (SOCK_IN == from_sock->in_out) {
tot_sock_idx = BLI_listbase_count(&from_node->outputs);
tot_sock_idx += BLI_findindex(&from_node->inputs, from_sock);
}
else {
tot_sock_idx = BLI_findindex(&from_node->outputs, from_sock);
}
}
BLI_assert(tot_sock_idx != -1);
offset_y -= U.widget_unit * tot_sock_idx;
from_node->locx = to_node->locx + offset_x;
from_node->locy = to_node->locy - offset_y;
}
void nodePositionPropagate(bNode *node)
{
LISTBASE_FOREACH (bNodeSocket *, nsock, &node->inputs) {
if (nsock->link != nullptr) {
bNodeLink *link = nsock->link;
nodePositionRelative(link->fromnode, link->tonode, link->fromsock, link->tosock);
nodePositionPropagate(link->fromnode);
}
}
}
bNodeTree *ntreeAddTree(Main *bmain, const char *name, const char *idname)
{
/* trees are created as local trees for compositor, material or texture nodes,
* node groups and other tree types are created as library data.
*/
const bool is_embedded = (bmain == nullptr);
int flag = 0;
if (is_embedded) {
flag |= LIB_ID_CREATE_NO_MAIN;
}
bNodeTree *ntree = (bNodeTree *)BKE_libblock_alloc(bmain, ID_NT, name, flag);
if (is_embedded) {
ntree->id.flag |= LIB_EMBEDDED_DATA;
}
BLI_strncpy(ntree->idname, idname, sizeof(ntree->idname));
ntree_set_typeinfo(ntree, ntreeTypeFind(idname));
return ntree;
}
bNodeTree *ntreeCopyTree_ex(const bNodeTree *ntree, Main *bmain, const bool do_id_user)
{
const int flag = do_id_user ? 0 : LIB_ID_CREATE_NO_USER_REFCOUNT | LIB_ID_CREATE_NO_MAIN;
bNodeTree *ntree_copy = (bNodeTree *)BKE_id_copy_ex(bmain, (ID *)ntree, nullptr, flag);
return ntree_copy;
}
bNodeTree *ntreeCopyTree(Main *bmain, const bNodeTree *ntree)
{
return ntreeCopyTree_ex(ntree, bmain, true);
}
/* *************** Node Preview *********** */
/* XXX this should be removed eventually ...
* Currently BKE functions are modeled closely on previous code,
* using BKE_node_preview_init_tree to set up previews for a whole node tree in advance.
* This should be left more to the individual node tree implementations. */
bool BKE_node_preview_used(const bNode *node)
{
/* XXX check for closed nodes? */
return (node->typeinfo->flag & NODE_PREVIEW) != 0;
}
bNodePreview *BKE_node_preview_verify(bNodeInstanceHash *previews,
bNodeInstanceKey key,
const int xsize,
const int ysize,
const bool create)
{
bNodePreview *preview = (bNodePreview *)BKE_node_instance_hash_lookup(previews, key);
if (!preview) {
if (create) {
preview = MEM_cnew<bNodePreview>("node preview");
BKE_node_instance_hash_insert(previews, key, preview);
}
else {
return nullptr;
}
}
/* node previews can get added with variable size this way */
if (xsize == 0 || ysize == 0) {
return preview;
}
/* sanity checks & initialize */
if (preview->rect) {
if (preview->xsize != xsize || preview->ysize != ysize) {
MEM_freeN(preview->rect);
preview->rect = nullptr;
}
}
if (preview->rect == nullptr) {
preview->rect = (unsigned char *)MEM_callocN(4 * xsize + xsize * ysize * sizeof(char[4]),
"node preview rect");
preview->xsize = xsize;
preview->ysize = ysize;
}
/* no clear, makes nicer previews */
return preview;
}
bNodePreview *BKE_node_preview_copy(bNodePreview *preview)
{
bNodePreview *new_preview = (bNodePreview *)MEM_dupallocN(preview);
if (preview->rect) {
new_preview->rect = (unsigned char *)MEM_dupallocN(preview->rect);
}
return new_preview;
}
void BKE_node_preview_free(bNodePreview *preview)
{
if (preview->rect) {
MEM_freeN(preview->rect);
}
MEM_freeN(preview);
}
static void node_preview_init_tree_recursive(bNodeInstanceHash *previews,
bNodeTree *ntree,
bNodeInstanceKey parent_key,
const int xsize,
const int ysize)
{
LISTBASE_FOREACH (bNode *, node, &ntree->nodes) {
bNodeInstanceKey key = BKE_node_instance_key(parent_key, ntree, node);
if (BKE_node_preview_used(node)) {
node->preview_xsize = xsize;
node->preview_ysize = ysize;
BKE_node_preview_verify(previews, key, xsize, ysize, false);
}
if (node->type == NODE_GROUP && node->id) {
node_preview_init_tree_recursive(previews, (bNodeTree *)node->id, key, xsize, ysize);
}
}
}
void BKE_node_preview_init_tree(bNodeTree *ntree, int xsize, int ysize)
{
if (!ntree) {
return;
}
if (!ntree->previews) {
ntree->previews = BKE_node_instance_hash_new("node previews");
}
node_preview_init_tree_recursive(ntree->previews, ntree, NODE_INSTANCE_KEY_BASE, xsize, ysize);
}
static void node_preview_tag_used_recursive(bNodeInstanceHash *previews,
bNodeTree *ntree,
bNodeInstanceKey parent_key)
{
LISTBASE_FOREACH (bNode *, node, &ntree->nodes) {
bNodeInstanceKey key = BKE_node_instance_key(parent_key, ntree, node);
if (BKE_node_preview_used(node)) {
BKE_node_instance_hash_tag_key(previews, key);
}
if (node->type == NODE_GROUP && node->id) {
node_preview_tag_used_recursive(previews, (bNodeTree *)node->id, key);
}
}
}
void BKE_node_preview_remove_unused(bNodeTree *ntree)
{
if (!ntree || !ntree->previews) {
return;
}
/* use the instance hash functions for tagging and removing unused previews */
BKE_node_instance_hash_clear_tags(ntree->previews);
node_preview_tag_used_recursive(ntree->previews, ntree, NODE_INSTANCE_KEY_BASE);
BKE_node_instance_hash_remove_untagged(ntree->previews,
(bNodeInstanceValueFP)BKE_node_preview_free);
}
void BKE_node_preview_clear(bNodePreview *preview)
{
if (preview && preview->rect) {
memset(preview->rect, 0, MEM_allocN_len(preview->rect));
}
}
void BKE_node_preview_clear_tree(bNodeTree *ntree)
{
if (!ntree || !ntree->previews) {
return;
}
bNodeInstanceHashIterator iter;
NODE_INSTANCE_HASH_ITER (iter, ntree->previews) {
bNodePreview *preview = (bNodePreview *)BKE_node_instance_hash_iterator_get_value(&iter);
BKE_node_preview_clear(preview);
}
}
void BKE_node_preview_merge_tree(bNodeTree *to_ntree, bNodeTree *from_ntree, bool remove_old)
{
if (remove_old || !to_ntree->previews) {
/* free old previews */
if (to_ntree->previews) {
BKE_node_instance_hash_free(to_ntree->previews, (bNodeInstanceValueFP)BKE_node_preview_free);
}
/* transfer previews */
to_ntree->previews = from_ntree->previews;
from_ntree->previews = nullptr;
/* clean up, in case any to_ntree nodes have been removed */
BKE_node_preview_remove_unused(to_ntree);
}
else {
if (from_ntree->previews) {
bNodeInstanceHashIterator iter;
NODE_INSTANCE_HASH_ITER (iter, from_ntree->previews) {
bNodeInstanceKey key = BKE_node_instance_hash_iterator_get_key(&iter);
bNodePreview *preview = (bNodePreview *)BKE_node_instance_hash_iterator_get_value(&iter);
/* replace existing previews */
BKE_node_instance_hash_remove(
to_ntree->previews, key, (bNodeInstanceValueFP)BKE_node_preview_free);
BKE_node_instance_hash_insert(to_ntree->previews, key, preview);
}
/* NOTE: null free function here,
* because pointers have already been moved over to to_ntree->previews! */
BKE_node_instance_hash_free(from_ntree->previews, nullptr);
from_ntree->previews = nullptr;
}
}
}
/* ************** Free stuff ********** */
void nodeUnlinkNode(bNodeTree *ntree, bNode *node)
{
LISTBASE_FOREACH_MUTABLE (bNodeLink *, link, &ntree->links) {
ListBase *lb;
if (link->fromnode == node) {
lb = &node->outputs;
}
else if (link->tonode == node) {
lb = &node->inputs;
}
else {
lb = nullptr;
}
if (lb) {
/* Only bother adjusting if the socket is not on the node we're deleting. */
if (link->tonode != node && link->tosock->flag & SOCK_MULTI_INPUT) {
adjust_multi_input_indices_after_removed_link(
ntree, link->tosock, link->multi_input_socket_index);
}
LISTBASE_FOREACH (bNodeSocket *, sock, lb) {
if (link->fromsock == sock || link->tosock == sock) {
nodeRemLink(ntree, link);
break;
}
}
}
}
}
static void node_unlink_attached(bNodeTree *ntree, bNode *parent)
{
LISTBASE_FOREACH (bNode *, node, &ntree->nodes) {
if (node->parent == parent) {
nodeDetachNode(node);
}
}
}
/* Free the node itself. ID user refcounting is up the caller,
* that does not happen here. */
static void node_free_node(bNodeTree *ntree, bNode *node)
{
/* since it is called while free database, node->id is undefined */
/* can be called for nodes outside a node tree (e.g. clipboard) */
if (ntree) {
BLI_remlink(&ntree->nodes, node);
if (ntree->typeinfo->free_node_cache) {
ntree->typeinfo->free_node_cache(ntree, node);
}
/* texture node has bad habit of keeping exec data around */
if (ntree->type == NTREE_TEXTURE && ntree->execdata) {
ntreeTexEndExecTree(ntree->execdata);
ntree->execdata = nullptr;
}
}
if (node->typeinfo->freefunc) {
node->typeinfo->freefunc(node);
}
LISTBASE_FOREACH_MUTABLE (bNodeSocket *, sock, &node->inputs) {
/* Remember, no ID user refcount management here! */
node_socket_free(sock, false);
MEM_freeN(sock);
}
LISTBASE_FOREACH_MUTABLE (bNodeSocket *, sock, &node->outputs) {
/* Remember, no ID user refcount management here! */
node_socket_free(sock, false);
MEM_freeN(sock);
}
BLI_freelistN(&node->internal_links);
if (node->prop) {
/* Remember, no ID user refcount management here! */
IDP_FreePropertyContent_ex(node->prop, false);
MEM_freeN(node->prop);
}
if (node->typeinfo->declaration_is_dynamic) {
delete node->declaration;
}
MEM_freeN(node);
if (ntree) {
BKE_ntree_update_tag_node_removed(ntree);
}
}
void ntreeFreeLocalNode(bNodeTree *ntree, bNode *node)
{
/* For removing nodes while editing localized node trees. */
BLI_assert((ntree->id.tag & LIB_TAG_LOCALIZED) != 0);
/* These two lines assume the caller might want to free a single node and maintain
* a valid state in the node tree. */
nodeUnlinkNode(ntree, node);
node_unlink_attached(ntree, node);
node_free_node(ntree, node);
}
void nodeRemoveNode(Main *bmain, bNodeTree *ntree, bNode *node, bool do_id_user)
{
/* This function is not for localized node trees, we do not want
* do to ID user refcounting and removal of animdation data then. */
BLI_assert((ntree->id.tag & LIB_TAG_LOCALIZED) == 0);
bool node_has_id = false;
if (do_id_user) {
/* Free callback for NodeCustomGroup. */
if (node->typeinfo->freefunc_api) {
PointerRNA ptr;
RNA_pointer_create((ID *)ntree, &RNA_Node, node, &ptr);
node->typeinfo->freefunc_api(&ptr);
}
/* Do user counting. */
if (node->id) {
id_us_min(node->id);
node_has_id = true;
}
LISTBASE_FOREACH (bNodeSocket *, sock, &node->inputs) {
node_has_id |= socket_id_user_decrement(sock);
}
LISTBASE_FOREACH (bNodeSocket *, sock, &node->outputs) {
node_has_id |= socket_id_user_decrement(sock);
}
}
/* Remove animation data. */
char propname_esc[MAX_IDPROP_NAME * 2];
char prefix[MAX_IDPROP_NAME * 2];
BLI_str_escape(propname_esc, node->name, sizeof(propname_esc));
BLI_snprintf(prefix, sizeof(prefix), "nodes[\"%s\"]", propname_esc);
if (BKE_animdata_fix_paths_remove((ID *)ntree, prefix)) {
if (bmain != nullptr) {
DEG_relations_tag_update(bmain);
}
}
if (node_has_id) {
if (bmain != nullptr) {
DEG_relations_tag_update(bmain);
}
}
nodeUnlinkNode(ntree, node);
node_unlink_attached(ntree, node);
/* Free node itself. */
node_free_node(ntree, node);
}
static void node_socket_interface_free(bNodeTree *UNUSED(ntree),
bNodeSocket *sock,
const bool do_id_user)
{
if (sock->prop) {
IDP_FreeProperty_ex(sock->prop, do_id_user);
}
if (sock->default_value) {
if (do_id_user) {
socket_id_user_decrement(sock);
}
MEM_freeN(sock->default_value);
}
}
static void free_localized_node_groups(bNodeTree *ntree)
{
/* Only localized node trees store a copy for each node group tree.
* Each node group tree in a localized node tree can be freed,
* since it is a localized copy itself (no risk of accessing free'd
* data in main, see T37939). */
if (!(ntree->id.tag & LIB_TAG_LOCALIZED)) {
return;
}
LISTBASE_FOREACH (bNode *, node, &ntree->nodes) {
if (ELEM(node->type, NODE_GROUP, NODE_CUSTOM_GROUP) && node->id) {
bNodeTree *ngroup = (bNodeTree *)node->id;
ntreeFreeTree(ngroup);
MEM_freeN(ngroup);
}
}
}
void ntreeFreeTree(bNodeTree *ntree)
{
ntree_free_data(&ntree->id);
BKE_animdata_free(&ntree->id, false);
}
void ntreeFreeEmbeddedTree(bNodeTree *ntree)
{
ntreeFreeTree(ntree);
BKE_libblock_free_data(&ntree->id, true);
BKE_libblock_free_data_py(&ntree->id);
}
void ntreeFreeLocalTree(bNodeTree *ntree)
{
if (ntree->id.tag & LIB_TAG_LOCALIZED) {
ntreeFreeTree(ntree);
}
else {
ntreeFreeTree(ntree);
BKE_libblock_free_data(&ntree->id, true);
}
}
void ntreeFreeCache(bNodeTree *ntree)
{
if (ntree == nullptr) {
return;
}
if (ntree->typeinfo->free_cache) {
ntree->typeinfo->free_cache(ntree);
}
}
void ntreeSetOutput(bNodeTree *ntree)
{
/* find the active outputs, might become tree type dependent handler */
LISTBASE_FOREACH (bNode *, node, &ntree->nodes) {
if (node->typeinfo->nclass == NODE_CLASS_OUTPUT) {
/* we need a check for which output node should be tagged like this, below an exception */
if (node->type == CMP_NODE_OUTPUT_FILE) {
continue;
}
int output = 0;
/* there is more types having output class, each one is checked */
LISTBASE_FOREACH (bNode *, tnode, &ntree->nodes) {
if (tnode->typeinfo->nclass == NODE_CLASS_OUTPUT) {
if (ntree->type == NTREE_COMPOSIT) {
/* same type, exception for viewer */
if (tnode->type == node->type ||
(ELEM(tnode->type, CMP_NODE_VIEWER, CMP_NODE_SPLITVIEWER, GEO_NODE_VIEWER) &&
ELEM(node->type, CMP_NODE_VIEWER, CMP_NODE_SPLITVIEWER, GEO_NODE_VIEWER))) {
if (tnode->flag & NODE_DO_OUTPUT) {
output++;
if (output > 1) {
tnode->flag &= ~NODE_DO_OUTPUT;
}
}
}
}
else {
/* same type */
if (tnode->type == node->type) {
if (tnode->flag & NODE_DO_OUTPUT) {
output++;
if (output > 1) {
tnode->flag &= ~NODE_DO_OUTPUT;
}
}
}
}
}
}
if (output == 0) {
node->flag |= NODE_DO_OUTPUT;
}
}
/* group node outputs use this flag too */
if (node->type == NODE_GROUP_OUTPUT) {
int output = 0;
LISTBASE_FOREACH (bNode *, tnode, &ntree->nodes) {
if (tnode->type == NODE_GROUP_OUTPUT) {
if (tnode->flag & NODE_DO_OUTPUT) {
output++;
if (output > 1) {
tnode->flag &= ~NODE_DO_OUTPUT;
}
}
}
}
if (output == 0) {
node->flag |= NODE_DO_OUTPUT;
}
}
}
/* here we could recursively set which nodes have to be done,
* might be different for editor or for "real" use... */
}
bNodeTree **BKE_ntree_ptr_from_id(ID *id)
{
switch (GS(id->name)) {
case ID_MA:
return &((Material *)id)->nodetree;
case ID_LA:
return &((Light *)id)->nodetree;
case ID_WO:
return &((World *)id)->nodetree;
case ID_TE:
return &((Tex *)id)->nodetree;
case ID_SCE:
return &((Scene *)id)->nodetree;
case ID_LS:
return &((FreestyleLineStyle *)id)->nodetree;
case ID_SIM:
return &((Simulation *)id)->nodetree;
default:
return nullptr;
}
}
bNodeTree *ntreeFromID(ID *id)
{
bNodeTree **nodetree = BKE_ntree_ptr_from_id(id);
return (nodetree != nullptr) ? *nodetree : nullptr;
}
void ntreeNodeFlagSet(const bNodeTree *ntree, const int flag, const bool enable)
{
LISTBASE_FOREACH (bNode *, node, &ntree->nodes) {
if (enable) {
node->flag |= flag;
}
else {
node->flag &= ~flag;
}
}
}
bNodeTree *ntreeLocalize(bNodeTree *ntree)
{
if (ntree == nullptr) {
return nullptr;
}
/* Make full copy outside of Main database.
* NOTE: previews are not copied here. */
bNodeTree *ltree = (bNodeTree *)BKE_id_copy_ex(
nullptr, &ntree->id, nullptr, (LIB_ID_COPY_LOCALIZE | LIB_ID_COPY_NO_ANIMDATA));
ltree->id.tag |= LIB_TAG_LOCALIZED;
LISTBASE_FOREACH (bNode *, node, &ltree->nodes) {
if (ELEM(node->type, NODE_GROUP, NODE_CUSTOM_GROUP) && node->id) {
node->id = (ID *)ntreeLocalize((bNodeTree *)node->id);
}
}
/* Ensures only a single output node is enabled. */
ntreeSetOutput(ntree);
bNode *node_src = (bNode *)ntree->nodes.first;
bNode *node_local = (bNode *)ltree->nodes.first;
while (node_src != nullptr) {
node_local->original = node_src;
node_src = node_src->next;
node_local = node_local->next;
}
if (ntree->typeinfo->localize) {
ntree->typeinfo->localize(ltree, ntree);
}
return ltree;
}
void ntreeLocalMerge(Main *bmain, bNodeTree *localtree, bNodeTree *ntree)
{
if (ntree && localtree) {
if (ntree->typeinfo->local_merge) {
ntree->typeinfo->local_merge(bmain, localtree, ntree);
}
ntreeFreeTree(localtree);
MEM_freeN(localtree);
}
}
/* ************ NODE TREE INTERFACE *************** */
static bNodeSocket *make_socket_interface(bNodeTree *ntree,
eNodeSocketInOut in_out,
const char *idname,
const char *name)
{
bNodeSocketType *stype = nodeSocketTypeFind(idname);
if (stype == nullptr) {
return nullptr;
}
bNodeSocket *sock = MEM_cnew<bNodeSocket>("socket template");
BLI_strncpy(sock->idname, stype->idname, sizeof(sock->idname));
node_socket_set_typeinfo(ntree, sock, stype);
sock->in_out = in_out;
sock->type = SOCK_CUSTOM; /* int type undefined by default */
/* assign new unique index */
const int own_index = ntree->cur_index++;
/* use the own_index as socket identifier */
if (in_out == SOCK_IN) {
BLI_snprintf(sock->identifier, MAX_NAME, "Input_%d", own_index);
}
else {
BLI_snprintf(sock->identifier, MAX_NAME, "Output_%d", own_index);
}
sock->limit = (in_out == SOCK_IN ? 1 : 0xFFF);
BLI_strncpy(sock->name, name, NODE_MAXSTR);
sock->storage = nullptr;
sock->flag |= SOCK_COLLAPSED;
return sock;
}
bNodeSocket *ntreeFindSocketInterface(bNodeTree *ntree,
eNodeSocketInOut in_out,
const char *identifier)
{
ListBase *sockets = (in_out == SOCK_IN) ? &ntree->inputs : &ntree->outputs;
LISTBASE_FOREACH (bNodeSocket *, iosock, sockets) {
if (STREQ(iosock->identifier, identifier)) {
return iosock;
}
}
return nullptr;
}
bNodeSocket *ntreeAddSocketInterface(bNodeTree *ntree,
eNodeSocketInOut in_out,
const char *idname,
const char *name)
{
bNodeSocket *iosock = make_socket_interface(ntree, in_out, idname, name);
if (in_out == SOCK_IN) {
BLI_addtail(&ntree->inputs, iosock);
}
else if (in_out == SOCK_OUT) {
BLI_addtail(&ntree->outputs, iosock);
}
BKE_ntree_update_tag_interface(ntree);
return iosock;
}
bNodeSocket *ntreeInsertSocketInterface(bNodeTree *ntree,
eNodeSocketInOut in_out,
const char *idname,
bNodeSocket *next_sock,
const char *name)
{
bNodeSocket *iosock = make_socket_interface(ntree, in_out, idname, name);
if (in_out == SOCK_IN) {
BLI_insertlinkbefore(&ntree->inputs, next_sock, iosock);
}
else if (in_out == SOCK_OUT) {
BLI_insertlinkbefore(&ntree->outputs, next_sock, iosock);
}
BKE_ntree_update_tag_interface(ntree);
return iosock;
}
struct bNodeSocket *ntreeAddSocketInterfaceFromSocket(bNodeTree *ntree,
bNode *from_node,
bNodeSocket *from_sock)
{
bNodeSocket *iosock = ntreeAddSocketInterface(
ntree, static_cast<eNodeSocketInOut>(from_sock->in_out), from_sock->idname, from_sock->name);
if (iosock) {
if (iosock->typeinfo->interface_from_socket) {
iosock->typeinfo->interface_from_socket(ntree, iosock, from_node, from_sock);
}
}
return iosock;
}
struct bNodeSocket *ntreeInsertSocketInterfaceFromSocket(bNodeTree *ntree,
bNodeSocket *next_sock,
bNode *from_node,
bNodeSocket *from_sock)
{
bNodeSocket *iosock = ntreeInsertSocketInterface(
ntree,
static_cast<eNodeSocketInOut>(from_sock->in_out),
from_sock->idname,
next_sock,
from_sock->name);
if (iosock) {
if (iosock->typeinfo->interface_from_socket) {
iosock->typeinfo->interface_from_socket(ntree, iosock, from_node, from_sock);
}
}
return iosock;
}
void ntreeRemoveSocketInterface(bNodeTree *ntree, bNodeSocket *sock)
{
/* this is fast, this way we don't need an in_out argument */
BLI_remlink(&ntree->inputs, sock);
BLI_remlink(&ntree->outputs, sock);
node_socket_interface_free(ntree, sock, true);
MEM_freeN(sock);
BKE_ntree_update_tag_interface(ntree);
}
/* generates a valid RNA identifier from the node tree name */
static void ntree_interface_identifier_base(bNodeTree *ntree, char *base)
{
/* generate a valid RNA identifier */
sprintf(base, "NodeTreeInterface_%s", ntree->id.name + 2);
RNA_identifier_sanitize(base, false);
}
/* check if the identifier is already in use */
static bool ntree_interface_unique_identifier_check(void *UNUSED(data), const char *identifier)
{
return (RNA_struct_find(identifier) != nullptr);
}
/* generates the actual unique identifier and ui name and description */
static void ntree_interface_identifier(bNodeTree *ntree,
const char *base,
char *identifier,
int maxlen,
char *name,
char *description)
{
/* There is a possibility that different node tree names get mapped to the same identifier
* after sanitation (e.g. "SomeGroup_A", "SomeGroup.A" both get sanitized to "SomeGroup_A").
* On top of the sanitized id string add a number suffix if necessary to avoid duplicates.
*/
identifier[0] = '\0';
BLI_uniquename_cb(
ntree_interface_unique_identifier_check, nullptr, base, '_', identifier, maxlen);
sprintf(name, "Node Tree %s Interface", ntree->id.name + 2);
sprintf(description, "Interface properties of node group %s", ntree->id.name + 2);
}
static void ntree_interface_type_create(bNodeTree *ntree)
{
/* strings are generated from base string + ID name, sizes are sufficient */
char base[MAX_ID_NAME + 64], identifier[MAX_ID_NAME + 64], name[MAX_ID_NAME + 64],
description[MAX_ID_NAME + 64];
/* generate a valid RNA identifier */
ntree_interface_identifier_base(ntree, base);
ntree_interface_identifier(ntree, base, identifier, sizeof(identifier), name, description);
/* register a subtype of PropertyGroup */
StructRNA *srna = RNA_def_struct_ptr(&BLENDER_RNA, identifier, &RNA_PropertyGroup);
RNA_def_struct_ui_text(srna, name, description);
RNA_def_struct_duplicate_pointers(&BLENDER_RNA, srna);
/* associate the RNA type with the node tree */
ntree->interface_type = srna;
RNA_struct_blender_type_set(srna, ntree);
/* add socket properties */
LISTBASE_FOREACH (bNodeSocket *, sock, &ntree->inputs) {
bNodeSocketType *stype = sock->typeinfo;
if (stype && stype->interface_register_properties) {
stype->interface_register_properties(ntree, sock, srna);
}
}
LISTBASE_FOREACH (bNodeSocket *, sock, &ntree->outputs) {
bNodeSocketType *stype = sock->typeinfo;
if (stype && stype->interface_register_properties) {
stype->interface_register_properties(ntree, sock, srna);
}
}
}
StructRNA *ntreeInterfaceTypeGet(bNodeTree *ntree, bool create)
{
if (ntree->interface_type) {
/* strings are generated from base string + ID name, sizes are sufficient */
char base[MAX_ID_NAME + 64], identifier[MAX_ID_NAME + 64], name[MAX_ID_NAME + 64],
description[MAX_ID_NAME + 64];
/* A bit of a hack: when changing the ID name, update the RNA type identifier too,
* so that the names match. This is not strictly necessary to keep it working,
* but better for identifying associated NodeTree blocks and RNA types.
*/
StructRNA *srna = ntree->interface_type;
ntree_interface_identifier_base(ntree, base);
/* RNA identifier may have a number suffix, but should start with the idbase string */
if (!STREQLEN(RNA_struct_identifier(srna), base, sizeof(base))) {
/* generate new unique RNA identifier from the ID name */
ntree_interface_identifier(ntree, base, identifier, sizeof(identifier), name, description);
/* rename the RNA type */
RNA_def_struct_free_pointers(&BLENDER_RNA, srna);
RNA_def_struct_identifier(&BLENDER_RNA, srna, identifier);
RNA_def_struct_ui_text(srna, name, description);
RNA_def_struct_duplicate_pointers(&BLENDER_RNA, srna);
}
}
else if (create) {
ntree_interface_type_create(ntree);
}
return ntree->interface_type;
}
void ntreeInterfaceTypeFree(bNodeTree *ntree)
{
if (ntree->interface_type) {
RNA_struct_free(&BLENDER_RNA, ntree->interface_type);
ntree->interface_type = nullptr;
}
}
void ntreeInterfaceTypeUpdate(bNodeTree *ntree)
{
/* XXX it would be sufficient to just recreate all properties
* instead of re-registering the whole struct type,
* but there is currently no good way to do this in the RNA functions.
* Overhead should be negligible.
*/
ntreeInterfaceTypeFree(ntree);
ntree_interface_type_create(ntree);
}
/* ************ find stuff *************** */
bNode *ntreeFindType(const bNodeTree *ntree, int type)
{
if (ntree) {
LISTBASE_FOREACH (bNode *, node, &ntree->nodes) {
if (node->type == type) {
return node;
}
}
}
return nullptr;
}
bool ntreeHasTree(const bNodeTree *ntree, const bNodeTree *lookup)
{
if (ntree == lookup) {
return true;
}
LISTBASE_FOREACH (bNode *, node, &ntree->nodes) {
if (ELEM(node->type, NODE_GROUP, NODE_CUSTOM_GROUP) && node->id) {
if (ntreeHasTree((bNodeTree *)node->id, lookup)) {
return true;
}
}
}
return false;
}
bNodeLink *nodeFindLink(bNodeTree *ntree, const bNodeSocket *from, const bNodeSocket *to)
{
LISTBASE_FOREACH (bNodeLink *, link, &ntree->links) {
if (link->fromsock == from && link->tosock == to) {
return link;
}
if (link->fromsock == to && link->tosock == from) { /* hrms? */
return link;
}
}
return nullptr;
}
int nodeCountSocketLinks(const bNodeTree *ntree, const bNodeSocket *sock)
{
int tot = 0;
LISTBASE_FOREACH (const bNodeLink *, link, &ntree->links) {
if (link->fromsock == sock || link->tosock == sock) {
tot++;
}
}
return tot;
}
bNode *nodeGetActive(bNodeTree *ntree)
{
if (ntree == nullptr) {
return nullptr;
}
LISTBASE_FOREACH (bNode *, node, &ntree->nodes) {
if (node->flag & NODE_ACTIVE) {
return node;
}
}
return nullptr;
}
void nodeSetSelected(bNode *node, bool select)
{
if (select) {
node->flag |= NODE_SELECT;
}
else {
node->flag &= ~NODE_SELECT;
/* deselect sockets too */
LISTBASE_FOREACH (bNodeSocket *, sock, &node->inputs) {
sock->flag &= ~NODE_SELECT;
}
LISTBASE_FOREACH (bNodeSocket *, sock, &node->outputs) {
sock->flag &= ~NODE_SELECT;
}
}
}
void nodeClearActive(bNodeTree *ntree)
{
if (ntree == nullptr) {
return;
}
LISTBASE_FOREACH (bNode *, node, &ntree->nodes) {
node->flag &= ~NODE_ACTIVE;
}
}
void nodeSetActive(bNodeTree *ntree, bNode *node)
{
/* make sure only one node is active, and only one per ID type */
LISTBASE_FOREACH (bNode *, tnode, &ntree->nodes) {
tnode->flag &= ~NODE_ACTIVE;
if ((node->typeinfo->nclass == NODE_CLASS_TEXTURE) ||
(node->typeinfo->type == GEO_NODE_LEGACY_ATTRIBUTE_SAMPLE_TEXTURE)) {
tnode->flag &= ~NODE_ACTIVE_TEXTURE;
}
}
node->flag |= NODE_ACTIVE;
if ((node->typeinfo->nclass == NODE_CLASS_TEXTURE) ||
(node->typeinfo->type == GEO_NODE_LEGACY_ATTRIBUTE_SAMPLE_TEXTURE)) {
node->flag |= NODE_ACTIVE_TEXTURE;
}
}
int nodeSocketIsHidden(const bNodeSocket *sock)
{
return ((sock->flag & (SOCK_HIDDEN | SOCK_UNAVAIL)) != 0);
}
void nodeSetSocketAvailability(bNodeTree *ntree, bNodeSocket *sock, bool is_available)
{
const bool was_available = (sock->flag & SOCK_UNAVAIL) == 0;
if (is_available != was_available) {
BKE_ntree_update_tag_socket_availability(ntree, sock);
}
if (is_available) {
sock->flag &= ~SOCK_UNAVAIL;
}
else {
sock->flag |= SOCK_UNAVAIL;
}
}
int nodeSocketLinkLimit(const bNodeSocket *sock)
{
bNodeSocketType *stype = sock->typeinfo;
if (sock->flag & SOCK_MULTI_INPUT) {
return 4095;
}
if (stype != nullptr && stype->use_link_limits_of_type) {
int limit = (sock->in_out == SOCK_IN) ? stype->input_link_limit : stype->output_link_limit;
return limit;
}
return sock->limit;
}
static void update_socket_declarations(ListBase *sockets,
Span<blender::nodes::SocketDeclarationPtr> declarations)
{
int index;
LISTBASE_FOREACH_INDEX (bNodeSocket *, socket, sockets, index) {
const SocketDeclaration &socket_decl = *declarations[index];
socket->declaration = &socket_decl;
}
}
void nodeSocketDeclarationsUpdate(bNode *node)
{
BLI_assert(node->declaration != nullptr);
update_socket_declarations(&node->inputs, node->declaration->inputs());
update_socket_declarations(&node->outputs, node->declaration->outputs());
}
bool nodeDeclarationEnsureOnOutdatedNode(bNodeTree *UNUSED(ntree), bNode *node)
{
if (node->declaration != nullptr) {
return false;
}
if (node->typeinfo->declare == nullptr) {
return false;
}
if (node->typeinfo->declaration_is_dynamic) {
node->declaration = new blender::nodes::NodeDeclaration();
blender::nodes::NodeDeclarationBuilder builder{*node->declaration};
node->typeinfo->declare(builder);
}
else {
/* Declaration should have been created in #nodeRegisterType. */
BLI_assert(node->typeinfo->fixed_declaration != nullptr);
node->declaration = node->typeinfo->fixed_declaration;
}
return true;
}
bool nodeDeclarationEnsure(bNodeTree *ntree, bNode *node)
{
if (nodeDeclarationEnsureOnOutdatedNode(ntree, node)) {
nodeSocketDeclarationsUpdate(node);
return true;
}
return false;
}
/* ************** Node Clipboard *********** */
#define USE_NODE_CB_VALIDATE
#ifdef USE_NODE_CB_VALIDATE
/**
* This data structure is to validate the node on creation,
* otherwise we may reference missing data.
*
* Currently its only used for ID's, but nodes may one day
* reference other pointers which need validation.
*/
struct bNodeClipboardExtraInfo {
struct bNodeClipboardExtraInfo *next, *prev;
ID *id;
char id_name[MAX_ID_NAME];
char library_name[FILE_MAX];
};
#endif /* USE_NODE_CB_VALIDATE */
struct bNodeClipboard {
ListBase nodes;
#ifdef USE_NODE_CB_VALIDATE
ListBase nodes_extra_info;
#endif
ListBase links;
int type;
};
static bNodeClipboard node_clipboard = {{nullptr}};
void BKE_node_clipboard_init(const struct bNodeTree *ntree)
{
node_clipboard.type = ntree->type;
}
void BKE_node_clipboard_clear()
{
LISTBASE_FOREACH_MUTABLE (bNodeLink *, link, &node_clipboard.links) {
nodeRemLink(nullptr, link);
}
BLI_listbase_clear(&node_clipboard.links);
LISTBASE_FOREACH_MUTABLE (bNode *, node, &node_clipboard.nodes) {
node_free_node(nullptr, node);
}
BLI_listbase_clear(&node_clipboard.nodes);
#ifdef USE_NODE_CB_VALIDATE
BLI_freelistN(&node_clipboard.nodes_extra_info);
#endif
}
bool BKE_node_clipboard_validate()
{
bool ok = true;
#ifdef USE_NODE_CB_VALIDATE
bNodeClipboardExtraInfo *node_info;
bNode *node;
/* lists must be aligned */
BLI_assert(BLI_listbase_count(&node_clipboard.nodes) ==
BLI_listbase_count(&node_clipboard.nodes_extra_info));
for (node = (bNode *)node_clipboard.nodes.first,
node_info = (bNodeClipboardExtraInfo *)node_clipboard.nodes_extra_info.first;
node;
node = (bNode *)node->next, node_info = (bNodeClipboardExtraInfo *)node_info->next) {
/* validate the node against the stored node info */
/* re-assign each loop since we may clear,
* open a new file where the ID is valid, and paste again */
node->id = node_info->id;
/* currently only validate the ID */
if (node->id) {
/* We want to search into current blend file, so using G_MAIN is valid here too. */
ListBase *lb = which_libbase(G_MAIN, GS(node_info->id_name));
BLI_assert(lb != nullptr);
if (BLI_findindex(lb, node_info->id) == -1) {
/* May assign null. */
node->id = (ID *)BLI_findstring(lb, node_info->id_name + 2, offsetof(ID, name) + 2);
if (node->id == nullptr) {
ok = false;
}
}
}
}
#endif /* USE_NODE_CB_VALIDATE */
return ok;
}
void BKE_node_clipboard_add_node(bNode *node)
{
#ifdef USE_NODE_CB_VALIDATE
/* add extra info */
bNodeClipboardExtraInfo *node_info = (bNodeClipboardExtraInfo *)MEM_mallocN(
sizeof(bNodeClipboardExtraInfo), __func__);
node_info->id = node->id;
if (node->id) {
BLI_strncpy(node_info->id_name, node->id->name, sizeof(node_info->id_name));
if (ID_IS_LINKED(node->id)) {
BLI_strncpy(
node_info->library_name, node->id->lib->filepath_abs, sizeof(node_info->library_name));
}
else {
node_info->library_name[0] = '\0';
}
}
else {
node_info->id_name[0] = '\0';
node_info->library_name[0] = '\0';
}
BLI_addtail(&node_clipboard.nodes_extra_info, node_info);
/* end extra info */
#endif /* USE_NODE_CB_VALIDATE */
/* add node */
BLI_addtail(&node_clipboard.nodes, node);
}
void BKE_node_clipboard_add_link(bNodeLink *link)
{
BLI_addtail(&node_clipboard.links, link);
}
const ListBase *BKE_node_clipboard_get_nodes()
{
return &node_clipboard.nodes;
}
const ListBase *BKE_node_clipboard_get_links()
{
return &node_clipboard.links;
}
int BKE_node_clipboard_get_type()
{
return node_clipboard.type;
}
void BKE_node_clipboard_free()
{
BKE_node_clipboard_validate();
BKE_node_clipboard_clear();
}
/* Node Instance Hash */
const bNodeInstanceKey NODE_INSTANCE_KEY_BASE = {5381};
const bNodeInstanceKey NODE_INSTANCE_KEY_NONE = {0};
/* Generate a hash key from ntree and node names
* Uses the djb2 algorithm with xor by Bernstein:
* http://www.cse.yorku.ca/~oz/hash.html
*/
static bNodeInstanceKey node_hash_int_str(bNodeInstanceKey hash, const char *str)
{
char c;
while ((c = *str++)) {
hash.value = ((hash.value << 5) + hash.value) ^ c; /* (hash * 33) ^ c */
}
/* separator '\0' character, to avoid ambiguity from concatenated strings */
hash.value = (hash.value << 5) + hash.value; /* hash * 33 */
return hash;
}
bNodeInstanceKey BKE_node_instance_key(bNodeInstanceKey parent_key,
const bNodeTree *ntree,
const bNode *node)
{
bNodeInstanceKey key = node_hash_int_str(parent_key, ntree->id.name + 2);
if (node) {
key = node_hash_int_str(key, node->name);
}
return key;
}
static unsigned int node_instance_hash_key(const void *key)
{
return ((const bNodeInstanceKey *)key)->value;
}
static bool node_instance_hash_key_cmp(const void *a, const void *b)
{
unsigned int value_a = ((const bNodeInstanceKey *)a)->value;
unsigned int value_b = ((const bNodeInstanceKey *)b)->value;
return (value_a != value_b);
}
bNodeInstanceHash *BKE_node_instance_hash_new(const char *info)
{
bNodeInstanceHash *hash = (bNodeInstanceHash *)MEM_mallocN(sizeof(bNodeInstanceHash), info);
hash->ghash = BLI_ghash_new(
node_instance_hash_key, node_instance_hash_key_cmp, "node instance hash ghash");
return hash;
}
void BKE_node_instance_hash_free(bNodeInstanceHash *hash, bNodeInstanceValueFP valfreefp)
{
BLI_ghash_free(hash->ghash, nullptr, (GHashValFreeFP)valfreefp);
MEM_freeN(hash);
}
void BKE_node_instance_hash_insert(bNodeInstanceHash *hash, bNodeInstanceKey key, void *value)
{
bNodeInstanceHashEntry *entry = (bNodeInstanceHashEntry *)value;
entry->key = key;
entry->tag = 0;
BLI_ghash_insert(hash->ghash, &entry->key, value);
}
void *BKE_node_instance_hash_lookup(bNodeInstanceHash *hash, bNodeInstanceKey key)
{
return BLI_ghash_lookup(hash->ghash, &key);
}
int BKE_node_instance_hash_remove(bNodeInstanceHash *hash,
bNodeInstanceKey key,
bNodeInstanceValueFP valfreefp)
{
return BLI_ghash_remove(hash->ghash, &key, nullptr, (GHashValFreeFP)valfreefp);
}
void BKE_node_instance_hash_clear(bNodeInstanceHash *hash, bNodeInstanceValueFP valfreefp)
{
BLI_ghash_clear(hash->ghash, nullptr, (GHashValFreeFP)valfreefp);
}
void *BKE_node_instance_hash_pop(bNodeInstanceHash *hash, bNodeInstanceKey key)
{
return BLI_ghash_popkey(hash->ghash, &key, nullptr);
}
int BKE_node_instance_hash_haskey(bNodeInstanceHash *hash, bNodeInstanceKey key)
{
return BLI_ghash_haskey(hash->ghash, &key);
}
int BKE_node_instance_hash_size(bNodeInstanceHash *hash)
{
return BLI_ghash_len(hash->ghash);
}
void BKE_node_instance_hash_clear_tags(bNodeInstanceHash *hash)
{
bNodeInstanceHashIterator iter;
NODE_INSTANCE_HASH_ITER (iter, hash) {
bNodeInstanceHashEntry *value = (bNodeInstanceHashEntry *)
BKE_node_instance_hash_iterator_get_value(&iter);
value->tag = 0;
}
}
void BKE_node_instance_hash_tag(bNodeInstanceHash *UNUSED(hash), void *value)
{
bNodeInstanceHashEntry *entry = (bNodeInstanceHashEntry *)value;
entry->tag = 1;
}
bool BKE_node_instance_hash_tag_key(bNodeInstanceHash *hash, bNodeInstanceKey key)
{
bNodeInstanceHashEntry *entry = (bNodeInstanceHashEntry *)BKE_node_instance_hash_lookup(hash,
key);
if (entry) {
entry->tag = 1;
return true;
}
return false;
}
void BKE_node_instance_hash_remove_untagged(bNodeInstanceHash *hash,
bNodeInstanceValueFP valfreefp)
{
/* NOTE: Hash must not be mutated during iterating!
* Store tagged entries in a separate list and remove items afterward.
*/
bNodeInstanceKey *untagged = (bNodeInstanceKey *)MEM_mallocN(
sizeof(bNodeInstanceKey) * BKE_node_instance_hash_size(hash),
"temporary node instance key list");
bNodeInstanceHashIterator iter;
int num_untagged = 0;
NODE_INSTANCE_HASH_ITER (iter, hash) {
bNodeInstanceHashEntry *value = (bNodeInstanceHashEntry *)
BKE_node_instance_hash_iterator_get_value(&iter);
if (!value->tag) {
untagged[num_untagged++] = BKE_node_instance_hash_iterator_get_key(&iter);
}
}
for (int i = 0; i < num_untagged; i++) {
BKE_node_instance_hash_remove(hash, untagged[i], valfreefp);
}
MEM_freeN(untagged);
}
/* ************** dependency stuff *********** */
/* node is guaranteed to be not checked before */
static int node_get_deplist_recurs(bNodeTree *ntree, bNode *node, bNode ***nsort)
{
int level = 0xFFF;
node->done = true;
/* check linked nodes */
LISTBASE_FOREACH (bNodeLink *, link, &ntree->links) {
if (link->tonode == node) {
bNode *fromnode = link->fromnode;
if (fromnode->done == 0) {
fromnode->level = node_get_deplist_recurs(ntree, fromnode, nsort);
}
if (fromnode->level <= level) {
level = fromnode->level - 1;
}
}
}
/* check parent node */
if (node->parent) {
if (node->parent->done == 0) {
node->parent->level = node_get_deplist_recurs(ntree, node->parent, nsort);
}
if (node->parent->level <= level) {
level = node->parent->level - 1;
}
}
if (nsort) {
**nsort = node;
(*nsort)++;
}
return level;
}
void ntreeGetDependencyList(struct bNodeTree *ntree, struct bNode ***r_deplist, int *r_deplist_len)
{
*r_deplist_len = 0;
/* first clear data */
LISTBASE_FOREACH (bNode *, node, &ntree->nodes) {
node->done = false;
(*r_deplist_len)++;
}
if (*r_deplist_len == 0) {
*r_deplist = nullptr;
return;
}
bNode **nsort;
nsort = *r_deplist = (bNode **)MEM_callocN((*r_deplist_len) * sizeof(bNode *),
"sorted node array");
/* recursive check */
LISTBASE_FOREACH (bNode *, node, &ntree->nodes) {
if (node->done == 0) {
node->level = node_get_deplist_recurs(ntree, node, &nsort);
}
}
}
/* only updates node->level for detecting cycles links */
void ntreeUpdateNodeLevels(bNodeTree *ntree)
{
/* first clear tag */
LISTBASE_FOREACH (bNode *, node, &ntree->nodes) {
node->done = false;
}
/* recursive check */
LISTBASE_FOREACH (bNode *, node, &ntree->nodes) {
if (node->done == 0) {
node->level = node_get_deplist_recurs(ntree, node, nullptr);
}
}
}
void ntreeUpdateAllNew(Main *main)
{
Vector<bNodeTree *> new_ntrees;
/* Update all new node trees on file read or append, to add/remove sockets
* in groups nodes if the group changed, and handle any update flags that
* might have been set in file reading or versioning. */
FOREACH_NODETREE_BEGIN (main, ntree, owner_id) {
if (owner_id->tag & LIB_TAG_NEW) {
BKE_ntree_update_tag_all(ntree);
}
}
FOREACH_NODETREE_END;
BKE_ntree_update_main(main, nullptr);
}
void ntreeUpdateAllUsers(Main *main, ID *id)
{
if (id == nullptr) {
return;
}
bool need_update = false;
/* Update all users of ngroup, to add/remove sockets as needed. */
FOREACH_NODETREE_BEGIN (main, ntree, owner_id) {
LISTBASE_FOREACH (bNode *, node, &ntree->nodes) {
if (node->id == id) {
BKE_ntree_update_tag_node_property(ntree, node);
need_update = true;
}
}
}
FOREACH_NODETREE_END;
if (need_update) {
BKE_ntree_update_main(main, nullptr);
}
}
/* ************* node type access ********** */
void nodeLabel(const bNodeTree *ntree, const bNode *node, char *label, int maxlen)
{
label[0] = '\0';
if (node->label[0] != '\0') {
BLI_strncpy(label, node->label, maxlen);
}
else if (node->typeinfo->labelfunc) {
node->typeinfo->labelfunc(ntree, node, label, maxlen);
}
/* The previous methods (labelfunc) could not provide an adequate label for the node. */
if (label[0] == '\0') {
/* Kind of hacky and weak... Ideally would be better to use RNA here. :| */
const char *tmp = CTX_IFACE_(BLT_I18NCONTEXT_ID_NODETREE, node->typeinfo->ui_name);
if (tmp == node->typeinfo->ui_name) {
tmp = IFACE_(node->typeinfo->ui_name);
}
BLI_strncpy(label, tmp, maxlen);
}
}
const char *nodeSocketLabel(const bNodeSocket *sock)
{
return (sock->label[0] != '\0') ? sock->label : sock->name;
}
static void node_type_base_defaults(bNodeType *ntype)
{
/* default size values */
node_type_size_preset(ntype, NODE_SIZE_DEFAULT);
ntype->height = 100;
ntype->minheight = 30;
ntype->maxheight = FLT_MAX;
}
/* allow this node for any tree type */
static bool node_poll_default(bNodeType *UNUSED(ntype),
bNodeTree *UNUSED(ntree),
const char **UNUSED(disabled_hint))
{
return true;
}
/* use the basic poll function */
static bool node_poll_instance_default(bNode *node, bNodeTree *ntree, const char **disabled_hint)
{
return node->typeinfo->poll(node->typeinfo, ntree, disabled_hint);
}
void node_type_base(bNodeType *ntype, int type, const char *name, short nclass)
{
/* Use static type info header to map static int type to identifier string and RNA struct type.
* Associate the RNA struct type with the bNodeType.
* Dynamically registered nodes will create an RNA type at runtime
* and call RNA_struct_blender_type_set, so this only needs to be done for old RNA types
* created in makesrna, which can not be associated to a bNodeType immediately,
* since bNodeTypes are registered afterward ...
*/
#define DefNode(Category, ID, DefFunc, EnumName, StructName, UIName, UIDesc) \
case ID: \
BLI_strncpy(ntype->idname, #Category #StructName, sizeof(ntype->idname)); \
ntype->rna_ext.srna = RNA_struct_find(#Category #StructName); \
BLI_assert(ntype->rna_ext.srna != nullptr); \
RNA_struct_blender_type_set(ntype->rna_ext.srna, ntype); \
break;
switch (type) {
#include "NOD_static_types.h"
}
/* make sure we have a valid type (everything registered) */
BLI_assert(ntype->idname[0] != '\0');
ntype->type = type;
BLI_strncpy(ntype->ui_name, name, sizeof(ntype->ui_name));
ntype->nclass = nclass;
node_type_base_defaults(ntype);
ntype->poll = node_poll_default;
ntype->poll_instance = node_poll_instance_default;
}
void node_type_base_custom(bNodeType *ntype, const char *idname, const char *name, short nclass)
{
BLI_strncpy(ntype->idname, idname, sizeof(ntype->idname));
ntype->type = NODE_CUSTOM;
BLI_strncpy(ntype->ui_name, name, sizeof(ntype->ui_name));
ntype->nclass = nclass;
node_type_base_defaults(ntype);
}
struct SocketTemplateIdentifierCallbackData {
bNodeSocketTemplate *list;
bNodeSocketTemplate *ntemp;
};
static bool unique_socket_template_identifier_check(void *arg, const char *name)
{
SocketTemplateIdentifierCallbackData *data = (SocketTemplateIdentifierCallbackData *)arg;
for (bNodeSocketTemplate *ntemp = data->list; ntemp->type >= 0; ntemp++) {
if (ntemp != data->ntemp) {
if (STREQ(ntemp->identifier, name)) {
return true;
}
}
}
return false;
}
static void unique_socket_template_identifier(bNodeSocketTemplate *list,
bNodeSocketTemplate *ntemp,
const char defname[],
char delim)
{
SocketTemplateIdentifierCallbackData data;
data.list = list;
data.ntemp = ntemp;
BLI_uniquename_cb(unique_socket_template_identifier_check,
&data,
defname,
delim,
ntemp->identifier,
sizeof(ntemp->identifier));
}
void node_type_socket_templates(struct bNodeType *ntype,
struct bNodeSocketTemplate *inputs,
struct bNodeSocketTemplate *outputs)
{
ntype->inputs = inputs;
ntype->outputs = outputs;
/* automatically generate unique identifiers */
if (inputs) {
/* clear identifier strings (uninitialized memory) */
for (bNodeSocketTemplate *ntemp = inputs; ntemp->type >= 0; ntemp++) {
ntemp->identifier[0] = '\0';
}
for (bNodeSocketTemplate *ntemp = inputs; ntemp->type >= 0; ntemp++) {
BLI_strncpy(ntemp->identifier, ntemp->name, sizeof(ntemp->identifier));
unique_socket_template_identifier(inputs, ntemp, ntemp->identifier, '_');
}
}
if (outputs) {
/* clear identifier strings (uninitialized memory) */
for (bNodeSocketTemplate *ntemp = outputs; ntemp->type >= 0; ntemp++) {
ntemp->identifier[0] = '\0';
}
for (bNodeSocketTemplate *ntemp = outputs; ntemp->type >= 0; ntemp++) {
BLI_strncpy(ntemp->identifier, ntemp->name, sizeof(ntemp->identifier));
unique_socket_template_identifier(outputs, ntemp, ntemp->identifier, '_');
}
}
}
void node_type_init(struct bNodeType *ntype,
void (*initfunc)(struct bNodeTree *ntree, struct bNode *node))
{
ntype->initfunc = initfunc;
}
void node_type_size(struct bNodeType *ntype, int width, int minwidth, int maxwidth)
{
ntype->width = width;
ntype->minwidth = minwidth;
if (maxwidth <= minwidth) {
ntype->maxwidth = FLT_MAX;
}
else {
ntype->maxwidth = maxwidth;
}
}
void node_type_size_preset(struct bNodeType *ntype, eNodeSizePreset size)
{
switch (size) {
case NODE_SIZE_DEFAULT:
node_type_size(ntype, 140, 100, NODE_DEFAULT_MAX_WIDTH);
break;
case NODE_SIZE_SMALL:
node_type_size(ntype, 100, 80, NODE_DEFAULT_MAX_WIDTH);
break;
case NODE_SIZE_MIDDLE:
node_type_size(ntype, 150, 120, NODE_DEFAULT_MAX_WIDTH);
break;
case NODE_SIZE_LARGE:
node_type_size(ntype, 240, 140, NODE_DEFAULT_MAX_WIDTH);
break;
}
}
void node_type_storage(bNodeType *ntype,
const char *storagename,
void (*freefunc)(struct bNode *node),
void (*copyfunc)(struct bNodeTree *dest_ntree,
struct bNode *dest_node,
const struct bNode *src_node))
{
if (storagename) {
BLI_strncpy(ntype->storagename, storagename, sizeof(ntype->storagename));
}
else {
ntype->storagename[0] = '\0';
}
ntype->copyfunc = copyfunc;
ntype->freefunc = freefunc;
}
void node_type_update(struct bNodeType *ntype,
void (*updatefunc)(struct bNodeTree *ntree, struct bNode *node))
{
ntype->updatefunc = updatefunc;
}
void node_type_group_update(struct bNodeType *ntype,
void (*group_update_func)(struct bNodeTree *ntree, struct bNode *node))
{
ntype->group_update_func = group_update_func;
}
void node_type_exec(struct bNodeType *ntype,
NodeInitExecFunction init_exec_fn,
NodeFreeExecFunction free_exec_fn,
NodeExecFunction exec_fn)
{
ntype->init_exec_fn = init_exec_fn;
ntype->free_exec_fn = free_exec_fn;
ntype->exec_fn = exec_fn;
}
void node_type_gpu(struct bNodeType *ntype, NodeGPUExecFunction gpu_fn)
{
ntype->gpu_fn = gpu_fn;
}
/* callbacks for undefined types */
static bool node_undefined_poll(bNodeType *UNUSED(ntype),
bNodeTree *UNUSED(nodetree),
const char **UNUSED(r_disabled_hint))
{
/* this type can not be added deliberately, it's just a placeholder */
return false;
}
/* register fallback types used for undefined tree, nodes, sockets */
static void register_undefined_types()
{
/* NOTE: these types are not registered in the type hashes,
* they are just used as placeholders in case the actual types are not registered.
*/
NodeTreeTypeUndefined.type = NTREE_UNDEFINED;
strcpy(NodeTreeTypeUndefined.idname, "NodeTreeUndefined");
strcpy(NodeTreeTypeUndefined.ui_name, N_("Undefined"));
strcpy(NodeTreeTypeUndefined.ui_description, N_("Undefined Node Tree Type"));
node_type_base_custom(&NodeTypeUndefined, "NodeUndefined", "Undefined", 0);
NodeTypeUndefined.poll = node_undefined_poll;
BLI_strncpy(NodeSocketTypeUndefined.idname,
"NodeSocketUndefined",
sizeof(NodeSocketTypeUndefined.idname));
/* extra type info for standard socket types */
NodeSocketTypeUndefined.type = SOCK_CUSTOM;
NodeSocketTypeUndefined.subtype = PROP_NONE;
NodeSocketTypeUndefined.use_link_limits_of_type = true;
NodeSocketTypeUndefined.input_link_limit = 0xFFF;
NodeSocketTypeUndefined.output_link_limit = 0xFFF;
}
static void registerCompositNodes()
{
register_node_type_cmp_group();
register_node_type_cmp_rlayers();
register_node_type_cmp_image();
register_node_type_cmp_texture();
register_node_type_cmp_value();
register_node_type_cmp_rgb();
register_node_type_cmp_curve_time();
register_node_type_cmp_scene_time();
register_node_type_cmp_movieclip();
register_node_type_cmp_composite();
register_node_type_cmp_viewer();
register_node_type_cmp_splitviewer();
register_node_type_cmp_output_file();
register_node_type_cmp_view_levels();
register_node_type_cmp_curve_rgb();
register_node_type_cmp_mix_rgb();
register_node_type_cmp_hue_sat();
register_node_type_cmp_brightcontrast();
register_node_type_cmp_gamma();
register_node_type_cmp_exposure();
register_node_type_cmp_invert();
register_node_type_cmp_alphaover();
register_node_type_cmp_zcombine();
register_node_type_cmp_colorbalance();
register_node_type_cmp_huecorrect();
register_node_type_cmp_normal();
register_node_type_cmp_curve_vec();
register_node_type_cmp_map_value();
register_node_type_cmp_map_range();
register_node_type_cmp_normalize();
register_node_type_cmp_filter();
register_node_type_cmp_blur();
register_node_type_cmp_dblur();
register_node_type_cmp_bilateralblur();
register_node_type_cmp_vecblur();
register_node_type_cmp_dilateerode();
register_node_type_cmp_inpaint();
register_node_type_cmp_despeckle();
register_node_type_cmp_defocus();
register_node_type_cmp_posterize();
register_node_type_cmp_sunbeams();
register_node_type_cmp_denoise();
register_node_type_cmp_antialiasing();
register_node_type_cmp_convert_color_space();
register_node_type_cmp_valtorgb();
register_node_type_cmp_rgbtobw();
register_node_type_cmp_setalpha();
register_node_type_cmp_idmask();
register_node_type_cmp_math();
register_node_type_cmp_seprgba();
register_node_type_cmp_combrgba();
register_node_type_cmp_sephsva();
register_node_type_cmp_combhsva();
register_node_type_cmp_sepyuva();
register_node_type_cmp_combyuva();
register_node_type_cmp_sepycca();
register_node_type_cmp_combycca();
register_node_type_cmp_premulkey();
register_node_type_cmp_separate_xyz();
register_node_type_cmp_combine_xyz();
register_node_type_cmp_diff_matte();
register_node_type_cmp_distance_matte();
register_node_type_cmp_chroma_matte();
register_node_type_cmp_color_matte();
register_node_type_cmp_channel_matte();
register_node_type_cmp_color_spill();
register_node_type_cmp_luma_matte();
register_node_type_cmp_doubleedgemask();
register_node_type_cmp_keyingscreen();
register_node_type_cmp_keying();
register_node_type_cmp_cryptomatte();
register_node_type_cmp_cryptomatte_legacy();
register_node_type_cmp_translate();
register_node_type_cmp_rotate();
register_node_type_cmp_scale();
register_node_type_cmp_flip();
register_node_type_cmp_crop();
register_node_type_cmp_displace();
register_node_type_cmp_mapuv();
register_node_type_cmp_glare();
register_node_type_cmp_tonemap();
register_node_type_cmp_lensdist();
register_node_type_cmp_transform();
register_node_type_cmp_stabilize2d();
register_node_type_cmp_moviedistortion();
register_node_type_cmp_colorcorrection();
register_node_type_cmp_boxmask();
register_node_type_cmp_ellipsemask();
register_node_type_cmp_bokehimage();
register_node_type_cmp_bokehblur();
register_node_type_cmp_switch();
register_node_type_cmp_switch_view();
register_node_type_cmp_pixelate();
register_node_type_cmp_mask();
register_node_type_cmp_trackpos();
register_node_type_cmp_planetrackdeform();
register_node_type_cmp_cornerpin();
}
static void registerShaderNodes()
{
register_node_type_sh_group();
register_node_type_sh_camera();
register_node_type_sh_gamma();
register_node_type_sh_brightcontrast();
register_node_type_sh_value();
register_node_type_sh_rgb();
register_node_type_sh_wireframe();
register_node_type_sh_wavelength();
register_node_type_sh_blackbody();
register_node_type_sh_mix_rgb();
register_node_type_sh_valtorgb();
register_node_type_sh_rgbtobw();
register_node_type_sh_shadertorgb();
register_node_type_sh_normal();
register_node_type_sh_mapping();
register_node_type_sh_curve_float();
register_node_type_sh_curve_vec();
register_node_type_sh_curve_rgb();
register_node_type_sh_map_range();
register_node_type_sh_clamp();
register_node_type_sh_math();
register_node_type_sh_vect_math();
register_node_type_sh_vector_rotate();
register_node_type_sh_vect_transform();
register_node_type_sh_squeeze();
register_node_type_sh_invert();
register_node_type_sh_seprgb();
register_node_type_sh_combrgb();
register_node_type_sh_sephsv();
register_node_type_sh_combhsv();
register_node_type_sh_sepxyz();
register_node_type_sh_combxyz();
register_node_type_sh_hue_sat();
register_node_type_sh_attribute();
register_node_type_sh_bevel();
register_node_type_sh_displacement();
register_node_type_sh_vector_displacement();
register_node_type_sh_geometry();
register_node_type_sh_light_path();
register_node_type_sh_light_falloff();
register_node_type_sh_object_info();
register_node_type_sh_fresnel();
register_node_type_sh_layer_weight();
register_node_type_sh_tex_coord();
register_node_type_sh_particle_info();
register_node_type_sh_bump();
register_node_type_sh_vertex_color();
register_node_type_sh_background();
register_node_type_sh_bsdf_anisotropic();
register_node_type_sh_bsdf_diffuse();
register_node_type_sh_bsdf_principled();
register_node_type_sh_bsdf_glossy();
register_node_type_sh_bsdf_glass();
register_node_type_sh_bsdf_translucent();
register_node_type_sh_bsdf_transparent();
register_node_type_sh_bsdf_velvet();
register_node_type_sh_bsdf_toon();
register_node_type_sh_bsdf_hair();
register_node_type_sh_bsdf_hair_principled();
register_node_type_sh_emission();
register_node_type_sh_holdout();
register_node_type_sh_volume_absorption();
register_node_type_sh_volume_scatter();
register_node_type_sh_volume_principled();
register_node_type_sh_subsurface_scattering();
register_node_type_sh_mix_shader();
register_node_type_sh_add_shader();
register_node_type_sh_uvmap();
register_node_type_sh_uvalongstroke();
register_node_type_sh_eevee_specular();
register_node_type_sh_output_light();
register_node_type_sh_output_material();
register_node_type_sh_output_world();
register_node_type_sh_output_linestyle();
register_node_type_sh_output_aov();
register_node_type_sh_tex_image();
register_node_type_sh_tex_environment();
register_node_type_sh_tex_sky();
register_node_type_sh_tex_noise();
register_node_type_sh_tex_wave();
register_node_type_sh_tex_voronoi();
register_node_type_sh_tex_musgrave();
register_node_type_sh_tex_gradient();
register_node_type_sh_tex_magic();
register_node_type_sh_tex_checker();
register_node_type_sh_tex_brick();
register_node_type_sh_tex_pointdensity();
register_node_type_sh_tex_ies();
register_node_type_sh_tex_white_noise();
}
static void registerTextureNodes()
{
register_node_type_tex_group();
register_node_type_tex_math();
register_node_type_tex_mix_rgb();
register_node_type_tex_valtorgb();
register_node_type_tex_rgbtobw();
register_node_type_tex_valtonor();
register_node_type_tex_curve_rgb();
register_node_type_tex_curve_time();
register_node_type_tex_invert();
register_node_type_tex_hue_sat();
register_node_type_tex_coord();
register_node_type_tex_distance();
register_node_type_tex_compose();
register_node_type_tex_decompose();
register_node_type_tex_output();
register_node_type_tex_viewer();
register_node_type_sh_script();
register_node_type_sh_tangent();
register_node_type_sh_normal_map();
register_node_type_sh_hair_info();
register_node_type_sh_point_info();
register_node_type_sh_volume_info();
register_node_type_tex_checker();
register_node_type_tex_texture();
register_node_type_tex_bricks();
register_node_type_tex_image();
register_node_type_sh_bsdf_refraction();
register_node_type_sh_ambient_occlusion();
register_node_type_tex_rotate();
register_node_type_tex_translate();
register_node_type_tex_scale();
register_node_type_tex_at();
register_node_type_tex_proc_voronoi();
register_node_type_tex_proc_blend();
register_node_type_tex_proc_magic();
register_node_type_tex_proc_marble();
register_node_type_tex_proc_clouds();
register_node_type_tex_proc_wood();
register_node_type_tex_proc_musgrave();
register_node_type_tex_proc_noise();
register_node_type_tex_proc_stucci();
register_node_type_tex_proc_distnoise();
}
static void registerGeometryNodes()
{
register_node_type_geo_group();
register_node_type_geo_legacy_attribute_proximity();
register_node_type_geo_legacy_attribute_randomize();
register_node_type_geo_legacy_attribute_transfer();
register_node_type_geo_legacy_curve_endpoints();
register_node_type_geo_legacy_curve_reverse();
register_node_type_geo_legacy_curve_set_handles();
register_node_type_geo_legacy_curve_spline_type();
register_node_type_geo_legacy_curve_subdivide();
register_node_type_geo_legacy_curve_to_points();
register_node_type_geo_legacy_delete_geometry();
register_node_type_geo_legacy_edge_split();
register_node_type_geo_legacy_material_assign();
register_node_type_geo_legacy_mesh_to_curve();
register_node_type_geo_legacy_points_to_volume();
register_node_type_geo_legacy_raycast();
register_node_type_geo_legacy_select_by_handle_type();
register_node_type_geo_legacy_select_by_material();
register_node_type_geo_legacy_subdivision_surface();
register_node_type_geo_legacy_volume_to_mesh();
register_node_type_geo_accumulate_field();
register_node_type_geo_align_rotation_to_vector();
register_node_type_geo_attribute_capture();
register_node_type_geo_attribute_clamp();
register_node_type_geo_attribute_color_ramp();
register_node_type_geo_attribute_combine_xyz();
register_node_type_geo_attribute_compare();
register_node_type_geo_attribute_convert();
register_node_type_geo_attribute_curve_map();
register_node_type_geo_attribute_domain_size();
register_node_type_geo_attribute_fill();
register_node_type_geo_attribute_map_range();
register_node_type_geo_attribute_math();
register_node_type_geo_attribute_mix();
register_node_type_geo_attribute_remove();
register_node_type_geo_attribute_separate_xyz();
register_node_type_geo_attribute_statistic();
register_node_type_geo_attribute_vector_math();
register_node_type_geo_attribute_vector_rotate();
register_node_type_geo_boolean();
register_node_type_geo_bounding_box();
register_node_type_geo_collection_info();
register_node_type_geo_convex_hull();
register_node_type_geo_curve_endpoint_selection();
register_node_type_geo_curve_fill();
register_node_type_geo_curve_fillet();
register_node_type_geo_curve_handle_type_selection();
register_node_type_geo_curve_length();
register_node_type_geo_curve_primitive_arc();
register_node_type_geo_curve_primitive_bezier_segment();
register_node_type_geo_curve_primitive_circle();
register_node_type_geo_curve_primitive_line();
register_node_type_geo_curve_primitive_quadratic_bezier();
register_node_type_geo_curve_primitive_quadrilateral();
register_node_type_geo_curve_primitive_spiral();
register_node_type_geo_curve_primitive_star();
register_node_type_geo_curve_resample();
register_node_type_geo_curve_reverse();
register_node_type_geo_curve_sample();
register_node_type_geo_curve_set_handles();
register_node_type_geo_curve_spline_parameter();
register_node_type_geo_curve_spline_type();
register_node_type_geo_curve_subdivide();
register_node_type_geo_curve_to_mesh();
register_node_type_geo_curve_to_points();
register_node_type_geo_curve_trim();
register_node_type_geo_delete_geometry();
register_node_type_geo_duplicate_elements();
register_node_type_geo_distribute_points_on_faces();
register_node_type_geo_dual_mesh();
register_node_type_geo_edge_split();
register_node_type_geo_extrude_mesh();
register_node_type_geo_field_at_index();
register_node_type_geo_flip_faces();
register_node_type_geo_geometry_to_instance();
register_node_type_geo_image_texture();
register_node_type_geo_input_curve_handles();
register_node_type_geo_input_curve_tilt();
register_node_type_geo_input_id();
register_node_type_geo_input_index();
register_node_type_geo_input_material_index();
register_node_type_geo_input_material();
register_node_type_geo_input_mesh_edge_angle();
register_node_type_geo_input_mesh_edge_neighbors();
register_node_type_geo_input_mesh_edge_vertices();
register_node_type_geo_input_mesh_face_area();
register_node_type_geo_input_mesh_face_neighbors();
register_node_type_geo_input_mesh_island();
register_node_type_geo_input_mesh_vertex_neighbors();
register_node_type_geo_input_normal();
register_node_type_geo_input_position();
register_node_type_geo_input_radius();
register_node_type_geo_input_scene_time();
register_node_type_geo_input_shade_smooth();
register_node_type_geo_input_spline_cyclic();
register_node_type_geo_input_spline_length();
register_node_type_geo_input_spline_resolution();
register_node_type_geo_input_tangent();
register_node_type_geo_instance_on_points();
register_node_type_geo_instances_to_points();
register_node_type_geo_is_viewport();
register_node_type_geo_join_geometry();
register_node_type_geo_material_replace();
register_node_type_geo_material_selection();
register_node_type_geo_merge_by_distance();
register_node_type_geo_mesh_primitive_circle();
register_node_type_geo_mesh_primitive_cone();
register_node_type_geo_mesh_primitive_cube();
register_node_type_geo_mesh_primitive_cylinder();
register_node_type_geo_mesh_primitive_grid();
register_node_type_geo_mesh_primitive_ico_sphere();
register_node_type_geo_mesh_primitive_line();
register_node_type_geo_mesh_primitive_uv_sphere();
register_node_type_geo_mesh_subdivide();
register_node_type_geo_mesh_to_curve();
register_node_type_geo_mesh_to_points();
register_node_type_geo_object_info();
register_node_type_geo_point_distribute();
register_node_type_geo_point_instance();
register_node_type_geo_point_rotate();
register_node_type_geo_point_scale();
register_node_type_geo_point_separate();
register_node_type_geo_point_translate();
register_node_type_geo_points_to_vertices();
register_node_type_geo_points_to_volume();
register_node_type_geo_proximity();
register_node_type_geo_raycast();
register_node_type_geo_realize_instances();
register_node_type_geo_rotate_instances();
register_node_type_geo_sample_texture();
register_node_type_geo_scale_elements();
register_node_type_geo_scale_instances();
register_node_type_geo_separate_components();
register_node_type_geo_separate_geometry();
register_node_type_geo_set_curve_handles();
register_node_type_geo_set_curve_radius();
register_node_type_geo_set_curve_tilt();
register_node_type_geo_set_id();
register_node_type_geo_set_material_index();
register_node_type_geo_set_material();
register_node_type_geo_set_point_radius();
register_node_type_geo_set_position();
register_node_type_geo_set_shade_smooth();
register_node_type_geo_set_spline_cyclic();
register_node_type_geo_set_spline_resolution();
register_node_type_geo_string_join();
register_node_type_geo_string_to_curves();
register_node_type_geo_subdivision_surface();
register_node_type_geo_switch();
register_node_type_geo_transfer_attribute();
register_node_type_geo_transform();
register_node_type_geo_translate_instances();
register_node_type_geo_triangulate();
register_node_type_geo_viewer();
register_node_type_geo_volume_to_mesh();
}
static void registerFunctionNodes()
{
register_node_type_fn_legacy_random_float();
register_node_type_fn_align_euler_to_vector();
register_node_type_fn_boolean_math();
register_node_type_fn_compare();
register_node_type_fn_float_to_int();
register_node_type_fn_input_bool();
register_node_type_fn_input_color();
register_node_type_fn_input_int();
register_node_type_fn_input_special_characters();
register_node_type_fn_input_string();
register_node_type_fn_input_vector();
register_node_type_fn_random_value();
register_node_type_fn_replace_string();
register_node_type_fn_rotate_euler();
register_node_type_fn_slice_string();
register_node_type_fn_string_length();
register_node_type_fn_value_to_string();
}
void BKE_node_system_init()
{
nodetreetypes_hash = BLI_ghash_str_new("nodetreetypes_hash gh");
nodetypes_hash = BLI_ghash_str_new("nodetypes_hash gh");
nodesockettypes_hash = BLI_ghash_str_new("nodesockettypes_hash gh");
register_undefined_types();
register_standard_node_socket_types();
register_node_tree_type_cmp();
register_node_tree_type_sh();
register_node_tree_type_tex();
register_node_tree_type_geo();
register_node_type_frame();
register_node_type_reroute();
register_node_type_group_input();
register_node_type_group_output();
registerCompositNodes();
registerShaderNodes();
registerTextureNodes();
registerGeometryNodes();
registerFunctionNodes();
}
void BKE_node_system_exit()
{
if (nodetypes_hash) {
NODE_TYPES_BEGIN (nt) {
if (nt->rna_ext.free) {
nt->rna_ext.free(nt->rna_ext.data);
}
}
NODE_TYPES_END;
BLI_ghash_free(nodetypes_hash, nullptr, node_free_type);
nodetypes_hash = nullptr;
}
if (nodesockettypes_hash) {
NODE_SOCKET_TYPES_BEGIN (st) {
if (st->ext_socket.free) {
st->ext_socket.free(st->ext_socket.data);
}
if (st->ext_interface.free) {
st->ext_interface.free(st->ext_interface.data);
}
}
NODE_SOCKET_TYPES_END;
BLI_ghash_free(nodesockettypes_hash, nullptr, node_free_socket_type);
nodesockettypes_hash = nullptr;
}
if (nodetreetypes_hash) {
NODE_TREE_TYPES_BEGIN (nt) {
if (nt->rna_ext.free) {
nt->rna_ext.free(nt->rna_ext.data);
}
}
NODE_TREE_TYPES_END;
BLI_ghash_free(nodetreetypes_hash, nullptr, ntree_free_type);
nodetreetypes_hash = nullptr;
}
}
/* -------------------------------------------------------------------- */
/* NodeTree Iterator Helpers (FOREACH_NODETREE_BEGIN) */
void BKE_node_tree_iter_init(struct NodeTreeIterStore *ntreeiter, struct Main *bmain)
{
ntreeiter->ngroup = (bNodeTree *)bmain->nodetrees.first;
ntreeiter->scene = (Scene *)bmain->scenes.first;
ntreeiter->mat = (Material *)bmain->materials.first;
ntreeiter->tex = (Tex *)bmain->textures.first;
ntreeiter->light = (Light *)bmain->lights.first;
ntreeiter->world = (World *)bmain->worlds.first;
ntreeiter->linestyle = (FreestyleLineStyle *)bmain->linestyles.first;
ntreeiter->simulation = (Simulation *)bmain->simulations.first;
}
bool BKE_node_tree_iter_step(struct NodeTreeIterStore *ntreeiter,
bNodeTree **r_nodetree,
struct ID **r_id)
{
if (ntreeiter->ngroup) {
*r_nodetree = (bNodeTree *)ntreeiter->ngroup;
*r_id = (ID *)ntreeiter->ngroup;
ntreeiter->ngroup = (bNodeTree *)ntreeiter->ngroup->id.next;
}
else if (ntreeiter->scene) {
*r_nodetree = (bNodeTree *)ntreeiter->scene->nodetree;
*r_id = (ID *)ntreeiter->scene;
ntreeiter->scene = (Scene *)ntreeiter->scene->id.next;
}
else if (ntreeiter->mat) {
*r_nodetree = (bNodeTree *)ntreeiter->mat->nodetree;
*r_id = (ID *)ntreeiter->mat;
ntreeiter->mat = (Material *)ntreeiter->mat->id.next;
}
else if (ntreeiter->tex) {
*r_nodetree = (bNodeTree *)ntreeiter->tex->nodetree;
*r_id = (ID *)ntreeiter->tex;
ntreeiter->tex = (Tex *)ntreeiter->tex->id.next;
}
else if (ntreeiter->light) {
*r_nodetree = (bNodeTree *)ntreeiter->light->nodetree;
*r_id = (ID *)ntreeiter->light;
ntreeiter->light = (Light *)ntreeiter->light->id.next;
}
else if (ntreeiter->world) {
*r_nodetree = (bNodeTree *)ntreeiter->world->nodetree;
*r_id = (ID *)ntreeiter->world;
ntreeiter->world = (World *)ntreeiter->world->id.next;
}
else if (ntreeiter->linestyle) {
*r_nodetree = (bNodeTree *)ntreeiter->linestyle->nodetree;
*r_id = (ID *)ntreeiter->linestyle;
ntreeiter->linestyle = (FreestyleLineStyle *)ntreeiter->linestyle->id.next;
}
else if (ntreeiter->simulation) {
*r_nodetree = (bNodeTree *)ntreeiter->simulation->nodetree;
*r_id = (ID *)ntreeiter->simulation;
ntreeiter->simulation = (Simulation *)ntreeiter->simulation->id.next;
}
else {
return false;
}
return true;
}
/* -------------------------------------------------------------------- */
/* NodeTree kernel functions */
void BKE_nodetree_remove_layer_n(bNodeTree *ntree, Scene *scene, const int layer_index)
{
BLI_assert(layer_index != -1);
LISTBASE_FOREACH (bNode *, node, &ntree->nodes) {
if (node->type == CMP_NODE_R_LAYERS && (Scene *)node->id == scene) {
if (node->custom1 == layer_index) {
node->custom1 = 0;
}
else if (node->custom1 > layer_index) {
node->custom1--;
}
}
}
}
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