test2/source/blender/blenkernel/intern/cryptomatte.cc

/* SPDX-FileCopyrightText: 2020 Blender Authors
 *
 * SPDX-License-Identifier: GPL-2.0-or-later */

/** \file
 * \ingroup bke
 */

#include "BKE_cryptomatte.h"
#include "BKE_cryptomatte.hh"
#include "BKE_image.h"
#include "BKE_layer.hh"
#include "BKE_main.hh"
#include "BKE_material.h"

#include "DNA_layer_types.h"
#include "DNA_material_types.h"
#include "DNA_node_types.h"
#include "DNA_object_types.h"
#include "DNA_scene_types.h"

#include "BLI_compiler_attrs.h"
#include "BLI_dynstr.h"
#include "BLI_hash_mm3.hh"
#include "BLI_listbase.h"
#include "BLI_string.h"

#include "RE_pipeline.h"

#include "MEM_guardedalloc.h"

#include <cctype>
#include <cstring>
#include <iomanip>
#include <sstream>
#include <string>
#include <string_view>

struct CryptomatteSession {
  blender::Map<std::string, blender::bke::cryptomatte::CryptomatteLayer> layers;
  /* Layer names in order of creation. */
  blender::Vector<std::string> layer_names;

  CryptomatteSession() = default;
  CryptomatteSession(const Main *bmain);
  CryptomatteSession(StampData *stamp_data);
  CryptomatteSession(const ViewLayer *view_layer);
  CryptomatteSession(const Scene *scene, bool build_meta_data = false);
  void init(const ViewLayer *view_layer, bool build_meta_data = false);

  blender::bke::cryptomatte::CryptomatteLayer &add_layer(std::string layer_name);
  std::optional<std::string> operator[](float encoded_hash) const;

#ifdef WITH_CXX_GUARDEDALLOC
  MEM_CXX_CLASS_ALLOC_FUNCS("cryptomatte:CryptomatteSession")
#endif
};

CryptomatteSession::CryptomatteSession(const Main *bmain)
{
  if (!BLI_listbase_is_empty(&bmain->objects)) {
    blender::bke::cryptomatte::CryptomatteLayer &objects = add_layer(
        RE_PASSNAME_CRYPTOMATTE_OBJECT);
    LISTBASE_FOREACH (ID *, id, &bmain->objects) {
      objects.add_ID(*id);
    }
  }
  if (!BLI_listbase_is_empty(&bmain->materials)) {
    blender::bke::cryptomatte::CryptomatteLayer &materials = add_layer(
        RE_PASSNAME_CRYPTOMATTE_MATERIAL);
    LISTBASE_FOREACH (ID *, id, &bmain->materials) {
      materials.add_ID(*id);
    }
  }
}

CryptomatteSession::CryptomatteSession(StampData *stamp_data)
{
  blender::bke::cryptomatte::CryptomatteStampDataCallbackData callback_data;
  callback_data.session = this;
  BKE_stamp_info_callback(
      &callback_data,
      stamp_data,
      blender::bke::cryptomatte::CryptomatteStampDataCallbackData::extract_layer_names,
      false);
  BKE_stamp_info_callback(
      &callback_data,
      stamp_data,
      blender::bke::cryptomatte::CryptomatteStampDataCallbackData::extract_layer_manifest,
      false);
}

CryptomatteSession::CryptomatteSession(const ViewLayer *view_layer)
{
  init(view_layer);
}

CryptomatteSession::CryptomatteSession(const Scene *scene, bool build_meta_data)
{

  if (build_meta_data) {
    BKE_scene_view_layers_synced_ensure(scene);
  }

  LISTBASE_FOREACH (const ViewLayer *, view_layer, &scene->view_layers) {
    init(view_layer, build_meta_data);
  }
}

void CryptomatteSession::init(const ViewLayer *view_layer, bool build_meta_data)
{
  eViewLayerCryptomatteFlags cryptoflags = static_cast<eViewLayerCryptomatteFlags>(
      view_layer->cryptomatte_flag & VIEW_LAYER_CRYPTOMATTE_ALL);
  if (cryptoflags == 0) {
    cryptoflags = static_cast<eViewLayerCryptomatteFlags>(VIEW_LAYER_CRYPTOMATTE_ALL);
  }

  ListBase *object_bases = BKE_view_layer_object_bases_get(const_cast<ViewLayer *>(view_layer));

  if (cryptoflags & VIEW_LAYER_CRYPTOMATTE_OBJECT) {
    blender::bke::cryptomatte::CryptomatteLayer &objects = add_layer(
        blender::StringRefNull(view_layer->name) + "." + RE_PASSNAME_CRYPTOMATTE_OBJECT);

    if (build_meta_data) {
      LISTBASE_FOREACH (Base *, base, object_bases) {
        objects.add_ID(base->object->id);
      }
    }
  }

  if (cryptoflags & VIEW_LAYER_CRYPTOMATTE_ASSET) {
    add_layer(blender::StringRefNull(view_layer->name) + "." + RE_PASSNAME_CRYPTOMATTE_ASSET);
  }

  if (cryptoflags & VIEW_LAYER_CRYPTOMATTE_MATERIAL) {
    blender::bke::cryptomatte::CryptomatteLayer &materials = add_layer(
        blender::StringRefNull(view_layer->name) + "." + RE_PASSNAME_CRYPTOMATTE_MATERIAL);

    if (build_meta_data) {
      LISTBASE_FOREACH (Base *, base, object_bases) {
        for (int i = 0; i < base->object->totcol; i++) {
          Material *material = BKE_object_material_get(base->object, i + 1);
          if (material) {
            materials.add_ID(material->id);
          }
        }
      }
    }
  }
}

blender::bke::cryptomatte::CryptomatteLayer &CryptomatteSession::add_layer(std::string layer_name)
{
  if (!layer_names.contains(layer_name)) {
    layer_names.append(layer_name);
  }
  return layers.lookup_or_add_default(layer_name);
}

std::optional<std::string> CryptomatteSession::operator[](float encoded_hash) const
{
  for (const blender::bke::cryptomatte::CryptomatteLayer &layer : layers.values()) {
    std::optional<std::string> result = layer[encoded_hash];
    if (result) {
      return result;
    }
  }
  return std::nullopt;
}

CryptomatteSession *BKE_cryptomatte_init()
{
  CryptomatteSession *session = new CryptomatteSession();
  return session;
}

CryptomatteSession *BKE_cryptomatte_init_from_render_result(const RenderResult *render_result)
{
  CryptomatteSession *session = new CryptomatteSession(render_result->stamp_data);
  return session;
}

CryptomatteSession *BKE_cryptomatte_init_from_scene(const Scene *scene, bool build_meta_data)
{
  CryptomatteSession *session = new CryptomatteSession(scene, build_meta_data);
  return session;
}

CryptomatteSession *BKE_cryptomatte_init_from_view_layer(const ViewLayer *view_layer)
{
  CryptomatteSession *session = new CryptomatteSession(view_layer);
  return session;
}

void BKE_cryptomatte_add_layer(CryptomatteSession *session, const char *layer_name)
{
  session->add_layer(layer_name);
}

void BKE_cryptomatte_free(CryptomatteSession *session)
{
  BLI_assert(session != nullptr);
  delete session;
}

uint32_t BKE_cryptomatte_hash(const char *name, const int name_len)
{
  blender::bke::cryptomatte::CryptomatteHash hash(name, name_len);
  return hash.hash;
}

uint32_t BKE_cryptomatte_object_hash(CryptomatteSession *session,
                                     const char *layer_name,
                                     const Object *object)
{
  blender::bke::cryptomatte::CryptomatteLayer *layer = session->layers.lookup_ptr(layer_name);
  BLI_assert(layer);
  return layer->add_ID(object->id);
}

uint32_t BKE_cryptomatte_material_hash(CryptomatteSession *session,
                                       const char *layer_name,
                                       const Material *material)
{
  if (material == nullptr) {
    return 0.0f;
  }
  blender::bke::cryptomatte::CryptomatteLayer *layer = session->layers.lookup_ptr(layer_name);
  BLI_assert(layer);
  return layer->add_ID(material->id);
}

uint32_t BKE_cryptomatte_asset_hash(CryptomatteSession *session,
                                    const char *layer_name,
                                    const Object *object)
{
  const Object *asset_object = object;
  while (asset_object->parent != nullptr) {
    asset_object = asset_object->parent;
  }
  return BKE_cryptomatte_object_hash(session, layer_name, asset_object);
}

float BKE_cryptomatte_hash_to_float(uint32_t cryptomatte_hash)
{
  return blender::bke::cryptomatte::CryptomatteHash(cryptomatte_hash).float_encoded();
}

bool BKE_cryptomatte_find_name(const CryptomatteSession *session,
                               const float encoded_hash,
                               char *r_name,
                               int name_maxncpy)
{
  std::optional<std::string> name = (*session)[encoded_hash];
  if (!name) {
    return false;
  }

  BLI_strncpy(r_name, name->c_str(), name_maxncpy);
  return true;
}

char *BKE_cryptomatte_entries_to_matte_id(NodeCryptomatte *node_storage)
{
  DynStr *matte_id = BLI_dynstr_new();
  bool first = true;
  LISTBASE_FOREACH (CryptomatteEntry *, entry, &node_storage->entries) {
    if (!first) {
      BLI_dynstr_append(matte_id, ",");
    }
    if (BLI_strnlen(entry->name, sizeof(entry->name)) != 0) {
      BLI_dynstr_nappend(matte_id, entry->name, sizeof(entry->name));
    }
    else {
      BLI_dynstr_appendf(matte_id, "<%.9g>", entry->encoded_hash);
    }
    first = false;
  }
  char *result = BLI_dynstr_get_cstring(matte_id);
  BLI_dynstr_free(matte_id);
  return result;
}

void BKE_cryptomatte_matte_id_to_entries(NodeCryptomatte *node_storage, const char *matte_id)
{
  BLI_freelistN(&node_storage->entries);

  if (matte_id == nullptr) {
    MEM_SAFE_FREE(node_storage->matte_id);
    return;
  }
  /* Update the matte_id so the files can be opened in versions that don't
   * use `CryptomatteEntry`. */
  if (matte_id != node_storage->matte_id && node_storage->matte_id &&
      STREQ(node_storage->matte_id, matte_id))
  {
    MEM_SAFE_FREE(node_storage->matte_id);
    node_storage->matte_id = static_cast<char *>(MEM_dupallocN(matte_id));
  }

  std::istringstream ss(matte_id);
  while (ss.good()) {
    CryptomatteEntry *entry = nullptr;
    std::string token;
    getline(ss, token, ',');
    /* Ignore empty tokens. */
    if (token.length() > 0) {
      size_t first = token.find_first_not_of(' ');
      size_t last = token.find_last_not_of(' ');
      if (first == std::string::npos || last == std::string::npos) {
        break;
      }
      token = token.substr(first, (last - first + 1));
      if (*token.begin() == '<' && *(--token.end()) == '>') {
        float encoded_hash = atof(token.substr(1, token.length() - 2).c_str());
        entry = MEM_cnew<CryptomatteEntry>(__func__);
        entry->encoded_hash = encoded_hash;
      }
      else {
        const char *name = token.c_str();
        int name_len = token.length();
        entry = MEM_cnew<CryptomatteEntry>(__func__);
        STRNCPY(entry->name, name);
        uint32_t hash = BKE_cryptomatte_hash(name, name_len);
        entry->encoded_hash = BKE_cryptomatte_hash_to_float(hash);
      }
    }
    if (entry != nullptr) {
      BLI_addtail(&node_storage->entries, entry);
    }
  }
}

static uint32_t cryptomatte_determine_identifier(const blender::StringRef name)
{
  return BLI_hash_mm3(reinterpret_cast<const uchar *>(name.data()), name.size(), 0);
}

static void add_render_result_meta_data(RenderResult *render_result,
                                        const blender::StringRef layer_name,
                                        const blender::StringRefNull key_name,
                                        const blender::StringRefNull value)
{
  BKE_render_result_stamp_data(
      render_result,
      blender::bke::cryptomatte::BKE_cryptomatte_meta_data_key(layer_name, key_name).c_str(),
      value.data());
}

void BKE_cryptomatte_store_metadata(const CryptomatteSession *session, RenderResult *render_result)
{
  for (const blender::MapItem<std::string, blender::bke::cryptomatte::CryptomatteLayer> item :
       session->layers.items())
  {
    const blender::StringRefNull layer_name(item.key);
    const blender::bke::cryptomatte::CryptomatteLayer &layer = item.value;

    const std::string manifest = layer.manifest();

    add_render_result_meta_data(render_result, layer_name, "name", layer_name);
    add_render_result_meta_data(render_result, layer_name, "hash", "MurmurHash3_32");
    add_render_result_meta_data(render_result, layer_name, "conversion", "uint32_to_float32");
    add_render_result_meta_data(render_result, layer_name, "manifest", manifest);
  }
}

namespace blender::bke::cryptomatte {
namespace manifest {
constexpr StringRef WHITESPACES = " \t\n\v\f\r";

static constexpr blender::StringRef skip_whitespaces_(blender::StringRef ref)
{
  size_t skip = ref.find_first_not_of(WHITESPACES);
  if (skip == blender::StringRef::not_found) {
    return ref;
  }
  return ref.drop_prefix(skip);
}

static constexpr int quoted_string_len_(blender::StringRef ref)
{
  int len = 1;
  bool skip_next = false;
  while (len < ref.size()) {
    char current_char = ref[len];
    if (skip_next) {
      skip_next = false;
    }
    else {
      if (current_char == '\\') {
        skip_next = true;
      }
      if (current_char == '\"') {
        len += 1;
        break;
      }
    }
    len += 1;
  }
  return len;
}

static std::string unquote_(const blender::StringRef ref)
{
  std::ostringstream stream;
  for (char c : ref) {
    if (c != '\\') {
      stream << c;
    }
  }
  return stream.str();
}

static bool from_manifest(CryptomatteLayer &layer, blender::StringRefNull manifest)
{
  StringRef ref = manifest;
  ref = skip_whitespaces_(ref);
  if (ref.is_empty() || ref.front() != '{') {
    return false;
  }
  ref = ref.drop_prefix(1);
  while (!ref.is_empty()) {
    char front = ref.front();

    if (front == '\"') {
      const int quoted_name_len = quoted_string_len_(ref);
      const int name_len = quoted_name_len - 2;
      std::string name = unquote_(ref.substr(1, name_len));
      ref = ref.drop_prefix(quoted_name_len);
      ref = skip_whitespaces_(ref);

      if (ref.is_empty()) {
        return false;
      }
      char colon = ref.front();
      if (colon != ':') {
        return false;
      }
      ref = ref.drop_prefix(1);
      ref = skip_whitespaces_(ref);

      if (ref.is_empty() || ref.front() != '\"') {
        return false;
      }

      const int quoted_hash_len = quoted_string_len_(ref);
      if (quoted_hash_len < 2) {
        return false;
      }
      const int hash_len = quoted_hash_len - 2;
      CryptomatteHash hash = CryptomatteHash::from_hex_encoded(ref.substr(1, hash_len));
      ref = ref.drop_prefix(quoted_hash_len);
      layer.add_hash(name, hash);
    }
    else if (front == ',') {
      ref = ref.drop_prefix(1);
    }
    else if (front == '}') {
      ref = ref.drop_prefix(1);
      ref = skip_whitespaces_(ref);
      break;
    }
    ref = skip_whitespaces_(ref);
  }

  if (!ref.is_empty()) {
    return false;
  }

  return true;
}

static std::string to_manifest(const CryptomatteLayer *layer)
{
  std::stringstream manifest;

  bool is_first = true;
  const blender::Map<std::string, CryptomatteHash> &const_map = layer->hashes;
  manifest << "{";
  for (blender::MapItem<std::string, CryptomatteHash> item : const_map.items()) {
    if (is_first) {
      is_first = false;
    }
    else {
      manifest << ",";
    }
    manifest << quoted(item.key) << ":\"" << item.value.hex_encoded() << "\"";
  }
  manifest << "}";
  return manifest.str();
}

}  // namespace manifest

/* Return the hash of the given cryptomatte layer name.
 *
 * The cryptomatte specification limits the hash to 7 characters.
 * The 7 position limitation solves issues when using cryptomatte together with OpenEXR.
 * The specification suggests to use the first 7 chars of the hashed layer_name.
 */
static std::string cryptomatte_layer_name_hash(const StringRef layer_name)
{
  std::stringstream stream;
  const uint32_t render_pass_identifier = cryptomatte_determine_identifier(layer_name);
  stream << std::setfill('0') << std::setw(sizeof(uint32_t) * 2) << std::hex
         << render_pass_identifier;
  return stream.str().substr(0, 7);
}

std::string BKE_cryptomatte_meta_data_key(const StringRef layer_name, const StringRefNull key_name)
{
  return "cryptomatte/" + cryptomatte_layer_name_hash(layer_name) + "/" + key_name;
}

StringRef BKE_cryptomatte_extract_layer_name(const StringRef render_pass_name)
{
  int64_t last_token = render_pass_name.size();
  while (last_token > 0 && std::isdigit(render_pass_name[last_token - 1])) {
    last_token -= 1;
  }
  return render_pass_name.substr(0, last_token);
}

CryptomatteHash::CryptomatteHash(uint32_t hash) : hash(hash) {}

CryptomatteHash CryptomatteHash::from_hex_encoded(blender::StringRef hex_encoded)
{
  CryptomatteHash result(0);
  std::istringstream(hex_encoded) >> std::hex >> result.hash;
  return result;
}

std::string CryptomatteHash::hex_encoded() const
{
  std::stringstream encoded;
  encoded << std::setfill('0') << std::setw(sizeof(uint32_t) * 2) << std::hex << hash;
  return encoded.str();
}

std::unique_ptr<CryptomatteLayer> CryptomatteLayer::read_from_manifest(
    blender::StringRefNull manifest)
{
  std::unique_ptr<CryptomatteLayer> layer = std::make_unique<CryptomatteLayer>();
  blender::bke::cryptomatte::manifest::from_manifest(*layer, manifest);
  return layer;
}

uint32_t CryptomatteLayer::add_ID(const ID &id)
{
  const char *name = &id.name[2];
  const int name_len = BLI_strnlen(name, MAX_NAME - 2);
  uint32_t cryptohash_int = BKE_cryptomatte_hash(name, name_len);

  add_hash(blender::StringRef(name, name_len), cryptohash_int);

  return cryptohash_int;
}

void CryptomatteLayer::add_hash(blender::StringRef name, CryptomatteHash cryptomatte_hash)
{
  hashes.add_overwrite(name, cryptomatte_hash);
}

std::optional<std::string> CryptomatteLayer::operator[](float encoded_hash) const
{
  const blender::Map<std::string, CryptomatteHash> &const_map = hashes;
  for (blender::MapItem<std::string, CryptomatteHash> item : const_map.items()) {
    if (BKE_cryptomatte_hash_to_float(item.value.hash) == encoded_hash) {
      return std::make_optional(item.key);
    }
  }
  return std::nullopt;
}

std::string CryptomatteLayer::manifest() const
{
  return blender::bke::cryptomatte::manifest::to_manifest(this);
}

blender::StringRef CryptomatteStampDataCallbackData::extract_layer_hash(blender::StringRefNull key)
{
  BLI_assert(key.startswith("cryptomatte/"));

  size_t start_index = key.find_first_of('/');
  size_t end_index = key.find_last_of('/');
  if (start_index == blender::StringRef::not_found) {
    return "";
  }
  if (end_index == blender::StringRef::not_found) {
    return "";
  }
  if (end_index <= start_index) {
    return "";
  }
  return key.substr(start_index + 1, end_index - start_index - 1);
}

void CryptomatteStampDataCallbackData::extract_layer_names(void *_data,
                                                           const char *propname,
                                                           char *propvalue,
                                                           int /*propvalue_maxncpy*/)
{
  CryptomatteStampDataCallbackData *data = static_cast<CryptomatteStampDataCallbackData *>(_data);

  blender::StringRefNull key(propname);
  if (!key.startswith("cryptomatte/")) {
    return;
  }
  if (!key.endswith("/name")) {
    return;
  }
  blender::StringRef layer_hash = extract_layer_hash(key);
  data->hash_to_layer_name.add(layer_hash, propvalue);
}

void CryptomatteStampDataCallbackData::extract_layer_manifest(void *_data,
                                                              const char *propname,
                                                              char *propvalue,
                                                              int /*propvalue_maxncpy*/)
{
  CryptomatteStampDataCallbackData *data = static_cast<CryptomatteStampDataCallbackData *>(_data);

  blender::StringRefNull key(propname);
  if (!key.startswith("cryptomatte/")) {
    return;
  }
  if (!key.endswith("/manifest")) {
    return;
  }
  blender::StringRef layer_hash = extract_layer_hash(key);
  if (!data->hash_to_layer_name.contains(layer_hash)) {
    return;
  }

  blender::StringRef layer_name = data->hash_to_layer_name.lookup(layer_hash);
  blender::bke::cryptomatte::CryptomatteLayer &layer = data->session->add_layer(layer_name);
  blender::bke::cryptomatte::manifest::from_manifest(layer, propvalue);
}

const blender::Vector<std::string> &BKE_cryptomatte_layer_names_get(
    const CryptomatteSession &session)
{
  return session.layer_names;
}

CryptomatteLayer *BKE_cryptomatte_layer_get(CryptomatteSession &session, StringRef layer_name)
{
  return session.layers.lookup_ptr(layer_name);
}

}  // namespace blender::bke::cryptomatte