blender-archive/source/blender/nodes/intern/node_common.cc

/* SPDX-License-Identifier: GPL-2.0-or-later
 * Copyright 2007 Blender Foundation. All rights reserved. */

/** \file
 * \ingroup nodes
 */

#include <cstddef>
#include <cstring>

#include "DNA_node_types.h"

#include "BLI_listbase.h"
#include "BLI_map.hh"
#include "BLI_multi_value_map.hh"
#include "BLI_set.hh"
#include "BLI_stack.hh"
#include "BLI_string.h"
#include "BLI_string_ref.hh"
#include "BLI_utildefines.h"

#include "BLT_translation.h"

#include "BKE_node.h"
#include "BKE_node_tree_update.h"

#include "RNA_types.h"

#include "MEM_guardedalloc.h"

#include "NOD_common.h"
#include "node_common.h"
#include "node_util.h"

using blender::Map;
using blender::MultiValueMap;
using blender::Set;
using blender::Stack;
using blender::StringRef;
using blender::Vector;

/* -------------------------------------------------------------------- */
/** \name Node Group
 * \{ */

static bNodeSocket *find_matching_socket(ListBase &sockets, StringRef identifier)
{
  LISTBASE_FOREACH (bNodeSocket *, socket, &sockets) {
    if (socket->identifier == identifier) {
      return socket;
    }
  }
  return nullptr;
}

bNodeSocket *node_group_find_input_socket(bNode *groupnode, const char *identifier)
{
  return find_matching_socket(groupnode->inputs, identifier);
}

bNodeSocket *node_group_find_output_socket(bNode *groupnode, const char *identifier)
{
  return find_matching_socket(groupnode->outputs, identifier);
}

void node_group_label(const bNodeTree *UNUSED(ntree), const bNode *node, char *label, int maxlen)
{
  BLI_strncpy(label, (node->id) ? node->id->name + 2 : IFACE_("Missing Data-Block"), maxlen);
}

bool node_group_poll_instance(bNode *node, bNodeTree *nodetree, const char **disabled_hint)
{
  if (node->typeinfo->poll(node->typeinfo, nodetree, disabled_hint)) {
    bNodeTree *grouptree = (bNodeTree *)node->id;
    if (grouptree) {
      return nodeGroupPoll(nodetree, grouptree, disabled_hint);
    }

    return true; /* without a linked node tree, group node is always ok */
  }

  return false;
}

bool nodeGroupPoll(bNodeTree *nodetree, bNodeTree *grouptree, const char **r_disabled_hint)
{
  bool valid = true;

  /* unspecified node group, generally allowed
   * (if anything, should be avoided on operator level)
   */
  if (grouptree == nullptr) {
    return true;
  }

  if (nodetree == grouptree) {
    *r_disabled_hint = TIP_("Nesting a node group inside of itself is not allowed");
    return false;
  }

  LISTBASE_FOREACH (bNode *, node, &grouptree->nodes) {
    if (node->typeinfo->poll_instance &&
        !node->typeinfo->poll_instance(node, nodetree, r_disabled_hint)) {
      valid = false;
      break;
    }
  }
  return valid;
}

static void add_new_socket_from_interface(bNodeTree &node_tree,
                                          bNode &node,
                                          const bNodeSocket &interface_socket,
                                          const eNodeSocketInOut in_out)
{
  bNodeSocket *socket = nodeAddSocket(&node_tree,
                                      &node,
                                      in_out,
                                      interface_socket.idname,
                                      interface_socket.identifier,
                                      interface_socket.name);

  if (interface_socket.typeinfo->interface_init_socket) {
    interface_socket.typeinfo->interface_init_socket(
        &node_tree, &interface_socket, &node, socket, "interface");
  }
}

static void update_socket_to_match_interface(bNodeTree &node_tree,
                                             bNode &node,
                                             bNodeSocket &socket_to_update,
                                             const bNodeSocket &interface_socket)
{
  strcpy(socket_to_update.name, interface_socket.name);

  const int mask = SOCK_HIDE_VALUE;
  socket_to_update.flag = (socket_to_update.flag & ~mask) | (interface_socket.flag & mask);

  /* Update socket type if necessary */
  if (socket_to_update.typeinfo != interface_socket.typeinfo) {
    nodeModifySocketType(&node_tree, &node, &socket_to_update, interface_socket.idname);
  }

  if (interface_socket.typeinfo->interface_verify_socket) {
    interface_socket.typeinfo->interface_verify_socket(
        &node_tree, &interface_socket, &node, &socket_to_update, "interface");
  }
}

/**
 * Used for group nodes and group input/output nodes to update the list of input or output sockets
 * on a node to match the provided interface. Assumes that \a verify_lb is the node's matching
 * input or output socket list, depending on whether the node is a group input/output or a group
 * node.
 */
static void group_verify_socket_list(bNodeTree &node_tree,
                                     bNode &node,
                                     const ListBase &interface_sockets,
                                     ListBase &verify_lb,
                                     const eNodeSocketInOut in_out,
                                     const bool ensure_extend_socket_exists)
{
  ListBase old_sockets = verify_lb;
  Vector<bNodeSocket *> ordered_old_sockets = old_sockets;
  BLI_listbase_clear(&verify_lb);

  LISTBASE_FOREACH (const bNodeSocket *, interface_socket, &interface_sockets) {
    bNodeSocket *matching_socket = find_matching_socket(old_sockets, interface_socket->identifier);
    if (matching_socket) {
      /* If a socket with the same identifier exists in the previous socket list, update it
       * with the correct name, type, etc. Then move it from the old list to the new one. */
      update_socket_to_match_interface(node_tree, node, *matching_socket, *interface_socket);
      BLI_remlink(&old_sockets, matching_socket);
      BLI_addtail(&verify_lb, matching_socket);
    }
    else {
      /* If there was no socket with the same identifier already, simply create a new socket
       * based on the interface socket, which will already add it to the new list. */
      add_new_socket_from_interface(node_tree, node, *interface_socket, in_out);
    }
  }

  if (ensure_extend_socket_exists) {
    bNodeSocket *last_socket = static_cast<bNodeSocket *>(old_sockets.last);
    if (last_socket != nullptr && STREQ(last_socket->identifier, "__extend__")) {
      BLI_remlink(&old_sockets, last_socket);
      BLI_addtail(&verify_lb, last_socket);
    }
    else {
      nodeAddSocket(&node_tree, &node, in_out, "NodeSocketVirtual", "__extend__", "");
    }
  }

  /* Remove leftover sockets that didn't match the node group's interface. */
  LISTBASE_FOREACH_MUTABLE (bNodeSocket *, unused_socket, &old_sockets) {
    nodeRemoveSocket(&node_tree, &node, unused_socket);
  }

  {
    /* Check if new sockets match the old sockets. */
    int index;
    LISTBASE_FOREACH_INDEX (bNodeSocket *, new_socket, &verify_lb, index) {
      if (index < ordered_old_sockets.size()) {
        if (ordered_old_sockets[index] != new_socket) {
          BKE_ntree_update_tag_interface(&node_tree);
          break;
        }
      }
    }
  }
}

void node_group_update(struct bNodeTree *ntree, struct bNode *node)
{
  /* check inputs and outputs, and remove or insert them */
  if (node->id == nullptr) {
    nodeRemoveAllSockets(ntree, node);
  }
  else if ((ID_IS_LINKED(node->id) && (node->id->tag & LIB_TAG_MISSING))) {
    /* Missing data-block, leave sockets unchanged so that when it comes back
     * the links remain valid. */
  }
  else {
    bNodeTree *ngroup = (bNodeTree *)node->id;
    group_verify_socket_list(*ntree, *node, ngroup->inputs, node->inputs, SOCK_IN, false);
    group_verify_socket_list(*ntree, *node, ngroup->outputs, node->outputs, SOCK_OUT, false);
  }
}

/** \} */

/* -------------------------------------------------------------------- */
/** \name Node Frame
 * \{ */

static void node_frame_init(bNodeTree *UNUSED(ntree), bNode *node)
{
  NodeFrame *data = MEM_cnew<NodeFrame>("frame node storage");
  node->storage = data;

  data->flag |= NODE_FRAME_SHRINK;

  data->label_size = 20;
}

void register_node_type_frame()
{
  /* frame type is used for all tree types, needs dynamic allocation */
  bNodeType *ntype = MEM_cnew<bNodeType>("frame node type");
  ntype->free_self = (void (*)(bNodeType *))MEM_freeN;

  node_type_base(ntype, NODE_FRAME, "Frame", NODE_CLASS_LAYOUT);
  node_type_init(ntype, node_frame_init);
  node_type_storage(ntype, "NodeFrame", node_free_standard_storage, node_copy_standard_storage);
  node_type_size(ntype, 150, 100, 0);
  ntype->flag |= NODE_BACKGROUND;

  nodeRegisterType(ntype);
}

/** \} */

/* -------------------------------------------------------------------- */
/** \name Node Re-Route
 * \{ */

static void node_reroute_init(bNodeTree *ntree, bNode *node)
{
  /* NOTE: Cannot use socket templates for this, since it would reset the socket type
   * on each file read via the template verification procedure.
   */
  nodeAddStaticSocket(ntree, node, SOCK_IN, SOCK_RGBA, PROP_NONE, "Input", "Input");
  nodeAddStaticSocket(ntree, node, SOCK_OUT, SOCK_RGBA, PROP_NONE, "Output", "Output");
}

void register_node_type_reroute()
{
  /* frame type is used for all tree types, needs dynamic allocation */
  bNodeType *ntype = MEM_cnew<bNodeType>("frame node type");
  ntype->free_self = (void (*)(bNodeType *))MEM_freeN;

  node_type_base(ntype, NODE_REROUTE, "Reroute", NODE_CLASS_LAYOUT);
  node_type_init(ntype, node_reroute_init);

  nodeRegisterType(ntype);
}

static void propagate_reroute_type_from_start_socket(
    bNodeSocket *start_socket,
    const MultiValueMap<bNodeSocket *, bNodeLink *> &links_map,
    Map<bNode *, const bNodeSocketType *> &r_reroute_types)
{
  Stack<bNode *> nodes_to_check;
  for (bNodeLink *link : links_map.lookup(start_socket)) {
    if (link->tonode->type == NODE_REROUTE) {
      nodes_to_check.push(link->tonode);
    }
    if (link->fromnode->type == NODE_REROUTE) {
      nodes_to_check.push(link->fromnode);
    }
  }
  const bNodeSocketType *current_type = start_socket->typeinfo;
  while (!nodes_to_check.is_empty()) {
    bNode *reroute_node = nodes_to_check.pop();
    BLI_assert(reroute_node->type == NODE_REROUTE);
    if (r_reroute_types.add(reroute_node, current_type)) {
      for (bNodeLink *link : links_map.lookup((bNodeSocket *)reroute_node->inputs.first)) {
        if (link->fromnode->type == NODE_REROUTE) {
          nodes_to_check.push(link->fromnode);
        }
      }
      for (bNodeLink *link : links_map.lookup((bNodeSocket *)reroute_node->outputs.first)) {
        if (link->tonode->type == NODE_REROUTE) {
          nodes_to_check.push(link->tonode);
        }
      }
    }
  }
}

void ntree_update_reroute_nodes(bNodeTree *ntree)
{
  /* Contains nodes that are linked to at least one reroute node. */
  Set<bNode *> nodes_linked_with_reroutes;
  /* Contains all links that are linked to at least one reroute node. */
  MultiValueMap<bNodeSocket *, bNodeLink *> links_map;
  /* Build acceleration data structures for the algorithm below. */
  LISTBASE_FOREACH (bNodeLink *, link, &ntree->links) {
    if (link->fromsock == nullptr || link->tosock == nullptr) {
      continue;
    }
    if (link->fromnode->type != NODE_REROUTE && link->tonode->type != NODE_REROUTE) {
      continue;
    }
    if (link->fromnode->type != NODE_REROUTE) {
      nodes_linked_with_reroutes.add(link->fromnode);
    }
    if (link->tonode->type != NODE_REROUTE) {
      nodes_linked_with_reroutes.add(link->tonode);
    }
    links_map.add(link->fromsock, link);
    links_map.add(link->tosock, link);
  }

  /* Will contain the socket type for every linked reroute node. */
  Map<bNode *, const bNodeSocketType *> reroute_types;

  /* Propagate socket types from left to right. */
  for (bNode *start_node : nodes_linked_with_reroutes) {
    LISTBASE_FOREACH (bNodeSocket *, output_socket, &start_node->outputs) {
      propagate_reroute_type_from_start_socket(output_socket, links_map, reroute_types);
    }
  }

  /* Propagate socket types from right to left. This affects reroute nodes that haven't been
   * changed in the loop above. */
  for (bNode *start_node : nodes_linked_with_reroutes) {
    LISTBASE_FOREACH (bNodeSocket *, input_socket, &start_node->inputs) {
      propagate_reroute_type_from_start_socket(input_socket, links_map, reroute_types);
    }
  }

  /* Actually update reroute nodes with changed types. */
  for (const auto item : reroute_types.items()) {
    bNode *reroute_node = item.key;
    const bNodeSocketType *socket_type = item.value;
    bNodeSocket *input_socket = (bNodeSocket *)reroute_node->inputs.first;
    bNodeSocket *output_socket = (bNodeSocket *)reroute_node->outputs.first;

    if (input_socket->typeinfo != socket_type) {
      nodeModifySocketType(ntree, reroute_node, input_socket, socket_type->idname);
    }
    if (output_socket->typeinfo != socket_type) {
      nodeModifySocketType(ntree, reroute_node, output_socket, socket_type->idname);
    }
  }
}

static bool node_is_connected_to_output_recursive(bNodeTree *ntree, bNode *node)
{
  bNodeLink *link;

  /* avoid redundant checks, and infinite loops in case of cyclic node links */
  if (node->done) {
    return false;
  }
  node->done = 1;

  /* main test, done before child loop so it catches output nodes themselves as well */
  if (node->typeinfo->nclass == NODE_CLASS_OUTPUT && node->flag & NODE_DO_OUTPUT) {
    return true;
  }

  /* test all connected nodes, first positive find is sufficient to return true */
  for (link = (bNodeLink *)ntree->links.first; link; link = link->next) {
    if (link->fromnode == node) {
      if (node_is_connected_to_output_recursive(ntree, link->tonode)) {
        return true;
      }
    }
  }
  return false;
}

bool BKE_node_is_connected_to_output(bNodeTree *ntree, bNode *node)
{
  bNode *tnode;

  /* clear flags */
  for (tnode = (bNode *)ntree->nodes.first; tnode; tnode = tnode->next) {
    tnode->done = 0;
  }

  return node_is_connected_to_output_recursive(ntree, node);
}

void BKE_node_tree_unlink_id(ID *id, struct bNodeTree *ntree)
{
  bNode *node;

  for (node = (bNode *)ntree->nodes.first; node; node = node->next) {
    if (node->id == id) {
      node->id = nullptr;
    }
  }
}

/** \} */

/* -------------------------------------------------------------------- */
/** \name Node #GROUP_INPUT / #GROUP_OUTPUT
 * \{ */

static bool is_group_extension_socket(const bNode *node, const bNodeSocket *socket)
{
  return socket->type == SOCK_CUSTOM && ELEM(node->type, NODE_GROUP_OUTPUT, NODE_GROUP_INPUT);
}

static void node_group_input_init(bNodeTree *ntree, bNode *node)
{
  node_group_input_update(ntree, node);
}

bNodeSocket *node_group_input_find_socket(bNode *node, const char *identifier)
{
  bNodeSocket *sock;
  for (sock = (bNodeSocket *)node->outputs.first; sock; sock = sock->next) {
    if (STREQ(sock->identifier, identifier)) {
      return sock;
    }
  }
  return nullptr;
}

void node_group_input_update(bNodeTree *ntree, bNode *node)
{
  bNodeSocket *extsock = (bNodeSocket *)node->outputs.last;
  bNodeLink *link, *linknext, *exposelink;
  /* Adding a tree socket and verifying will remove the extension socket!
   * This list caches the existing links from the extension socket
   * so they can be recreated after verification.
   */
  ListBase tmplinks;

  /* find links from the extension socket and store them */
  BLI_listbase_clear(&tmplinks);
  for (link = (bNodeLink *)ntree->links.first; link; link = linknext) {
    linknext = link->next;
    if (nodeLinkIsHidden(link)) {
      continue;
    }

    if (link->fromsock == extsock) {
      bNodeLink *tlink = MEM_cnew<bNodeLink>("temporary link");
      *tlink = *link;
      BLI_addtail(&tmplinks, tlink);

      nodeRemLink(ntree, link);
    }
  }

  /* find valid link to expose */
  exposelink = nullptr;
  for (link = (bNodeLink *)tmplinks.first; link; link = link->next) {
    /* XXX Multiple sockets can be connected to the extension socket at once,
     * in that case the arbitrary first link determines name and type.
     * This could be improved by choosing the "best" type among all links,
     * whatever that means.
     */
    if (!is_group_extension_socket(link->tonode, link->tosock)) {
      exposelink = link;
      break;
    }
  }

  if (exposelink) {
    bNodeSocket *gsock, *newsock;

    gsock = ntreeAddSocketInterfaceFromSocket(ntree, exposelink->tonode, exposelink->tosock);

    node_group_input_update(ntree, node);
    newsock = node_group_input_find_socket(node, gsock->identifier);

    /* redirect links from the extension socket */
    for (link = (bNodeLink *)tmplinks.first; link; link = link->next) {
      bNodeLink *newlink = nodeAddLink(ntree, node, newsock, link->tonode, link->tosock);
      if (newlink->tosock->flag & SOCK_MULTI_INPUT) {
        newlink->multi_input_socket_index = link->multi_input_socket_index;
      }
    }
  }

  BLI_freelistN(&tmplinks);
  group_verify_socket_list(*ntree, *node, ntree->inputs, node->outputs, SOCK_OUT, true);
}

void register_node_type_group_input()
{
  /* used for all tree types, needs dynamic allocation */
  bNodeType *ntype = MEM_cnew<bNodeType>("node type");
  ntype->free_self = (void (*)(bNodeType *))MEM_freeN;

  node_type_base(ntype, NODE_GROUP_INPUT, "Group Input", NODE_CLASS_INTERFACE);
  node_type_size(ntype, 140, 80, 400);
  node_type_init(ntype, node_group_input_init);
  node_type_update(ntype, node_group_input_update);

  nodeRegisterType(ntype);
}

static void node_group_output_init(bNodeTree *ntree, bNode *node)
{
  node_group_output_update(ntree, node);
}

bNodeSocket *node_group_output_find_socket(bNode *node, const char *identifier)
{
  bNodeSocket *sock;
  for (sock = (bNodeSocket *)node->inputs.first; sock; sock = sock->next) {
    if (STREQ(sock->identifier, identifier)) {
      return sock;
    }
  }
  return nullptr;
}

void node_group_output_update(bNodeTree *ntree, bNode *node)
{
  bNodeSocket *extsock = (bNodeSocket *)node->inputs.last;
  bNodeLink *link, *linknext, *exposelink;
  /* Adding a tree socket and verifying will remove the extension socket!
   * This list caches the existing links to the extension socket
   * so they can be recreated after verification.
   */
  ListBase tmplinks;

  /* find links to the extension socket and store them */
  BLI_listbase_clear(&tmplinks);
  for (link = (bNodeLink *)ntree->links.first; link; link = linknext) {
    linknext = link->next;
    if (nodeLinkIsHidden(link)) {
      continue;
    }

    if (link->tosock == extsock) {
      bNodeLink *tlink = MEM_cnew<bNodeLink>("temporary link");
      *tlink = *link;
      BLI_addtail(&tmplinks, tlink);

      nodeRemLink(ntree, link);
    }
  }

  /* find valid link to expose */
  exposelink = nullptr;
  for (link = (bNodeLink *)tmplinks.first; link; link = link->next) {
    /* XXX Multiple sockets can be connected to the extension socket at once,
     * in that case the arbitrary first link determines name and type.
     * This could be improved by choosing the "best" type among all links,
     * whatever that means.
     */
    if (!is_group_extension_socket(link->fromnode, link->fromsock)) {
      exposelink = link;
      break;
    }
  }

  if (exposelink) {
    bNodeSocket *gsock, *newsock;

    /* XXX what if connecting virtual to virtual socket?? */
    gsock = ntreeAddSocketInterfaceFromSocket(ntree, exposelink->fromnode, exposelink->fromsock);

    node_group_output_update(ntree, node);
    newsock = node_group_output_find_socket(node, gsock->identifier);

    /* redirect links to the extension socket */
    for (link = (bNodeLink *)tmplinks.first; link; link = link->next) {
      nodeAddLink(ntree, link->fromnode, link->fromsock, node, newsock);
    }
  }

  BLI_freelistN(&tmplinks);
  group_verify_socket_list(*ntree, *node, ntree->outputs, node->inputs, SOCK_IN, true);
}

void register_node_type_group_output()
{
  /* used for all tree types, needs dynamic allocation */
  bNodeType *ntype = MEM_cnew<bNodeType>("node type");
  ntype->free_self = (void (*)(bNodeType *))MEM_freeN;

  node_type_base(ntype, NODE_GROUP_OUTPUT, "Group Output", NODE_CLASS_INTERFACE);
  node_type_size(ntype, 140, 80, 400);
  node_type_init(ntype, node_group_output_init);
  node_type_update(ntype, node_group_output_update);

  ntype->no_muting = true;

  nodeRegisterType(ntype);
}

/** \} */