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Diffstat (limited to 'src/mesh/assimp-master/code/AssetLib/FBX/FBXExporter.cpp')
-rw-r--r-- | src/mesh/assimp-master/code/AssetLib/FBX/FBXExporter.cpp | 2799 |
1 files changed, 2799 insertions, 0 deletions
diff --git a/src/mesh/assimp-master/code/AssetLib/FBX/FBXExporter.cpp b/src/mesh/assimp-master/code/AssetLib/FBX/FBXExporter.cpp new file mode 100644 index 0000000..6956728 --- /dev/null +++ b/src/mesh/assimp-master/code/AssetLib/FBX/FBXExporter.cpp @@ -0,0 +1,2799 @@ +/* +Open Asset Import Library (assimp) +---------------------------------------------------------------------- + +Copyright (c) 2006-2022, assimp team + +All rights reserved. + +Redistribution and use of this software in source and binary forms, +with or without modification, are permitted provided that the +following conditions are met: + +* Redistributions of source code must retain the above +copyright notice, this list of conditions and the +following disclaimer. + +* Redistributions in binary form must reproduce the above +copyright notice, this list of conditions and the +following disclaimer in the documentation and/or other +materials provided with the distribution. + +* Neither the name of the assimp team, nor the names of its +contributors may be used to endorse or promote products +derived from this software without specific prior +written permission of the assimp team. + +THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS +"AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT +LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR +A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT +OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, +SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT +LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, +DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY +THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT +(INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE +OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. + +---------------------------------------------------------------------- +*/ +#ifndef ASSIMP_BUILD_NO_EXPORT +#ifndef ASSIMP_BUILD_NO_FBX_EXPORTER + +#include "FBXExporter.h" +#include "FBXExportNode.h" +#include "FBXExportProperty.h" +#include "FBXCommon.h" +#include "FBXUtil.h" + +#include <assimp/version.h> // aiGetVersion +#include <assimp/IOSystem.hpp> +#include <assimp/Exporter.hpp> +#include <assimp/DefaultLogger.hpp> +#include <assimp/StreamWriter.h> // StreamWriterLE +#include <assimp/Exceptional.h> // DeadlyExportError +#include <assimp/material.h> // aiTextureType +#include <assimp/scene.h> +#include <assimp/mesh.h> + +// Header files, standard library. +#include <memory> // shared_ptr +#include <string> +#include <sstream> // stringstream +#include <ctime> // localtime, tm_* +#include <map> +#include <set> +#include <vector> +#include <array> +#include <unordered_set> +#include <numeric> + +// RESOURCES: +// https://code.blender.org/2013/08/fbx-binary-file-format-specification/ +// https://wiki.blender.org/index.php/User:Mont29/Foundation/FBX_File_Structure + +const ai_real DEG = ai_real( 57.29577951308232087679815481 ); // degrees per radian + +using namespace Assimp; +using namespace Assimp::FBX; + +// some constants that we'll use for writing metadata +namespace Assimp { +namespace FBX { + const std::string EXPORT_VERSION_STR = "7.5.0"; + const uint32_t EXPORT_VERSION_INT = 7500; // 7.5 == 2016+ + // FBX files have some hashed values that depend on the creation time field, + // but for now we don't actually know how to generate these. + // what we can do is set them to a known-working version. + // this is the data that Blender uses in their FBX export process. + const std::string GENERIC_CTIME = "1970-01-01 10:00:00:000"; + const std::string GENERIC_FILEID = + "\x28\xb3\x2a\xeb\xb6\x24\xcc\xc2\xbf\xc8\xb0\x2a\xa9\x2b\xfc\xf1"; + const std::string GENERIC_FOOTID = + "\xfa\xbc\xab\x09\xd0\xc8\xd4\x66\xb1\x76\xfb\x83\x1c\xf7\x26\x7e"; + const std::string FOOT_MAGIC = + "\xf8\x5a\x8c\x6a\xde\xf5\xd9\x7e\xec\xe9\x0c\xe3\x75\x8f\x29\x0b"; + const std::string COMMENT_UNDERLINE = + ";------------------------------------------------------------------"; +} + + // --------------------------------------------------------------------- + // Worker function for exporting a scene to binary FBX. + // Prototyped and registered in Exporter.cpp + void ExportSceneFBX ( + const char* pFile, + IOSystem* pIOSystem, + const aiScene* pScene, + const ExportProperties* pProperties + ){ + // initialize the exporter + FBXExporter exporter(pScene, pProperties); + + // perform binary export + exporter.ExportBinary(pFile, pIOSystem); + } + + // --------------------------------------------------------------------- + // Worker function for exporting a scene to ASCII FBX. + // Prototyped and registered in Exporter.cpp + void ExportSceneFBXA ( + const char* pFile, + IOSystem* pIOSystem, + const aiScene* pScene, + const ExportProperties* pProperties + + ){ + // initialize the exporter + FBXExporter exporter(pScene, pProperties); + + // perform ascii export + exporter.ExportAscii(pFile, pIOSystem); + } + +} // end of namespace Assimp + +FBXExporter::FBXExporter ( const aiScene* pScene, const ExportProperties* pProperties ) +: binary(false) +, mScene(pScene) +, mProperties(pProperties) +, outfile() +, connections() +, mesh_uids() +, material_uids() +, node_uids() { + // will probably need to determine UIDs, connections, etc here. + // basically anything that needs to be known + // before we start writing sections to the stream. +} + +void FBXExporter::ExportBinary ( + const char* pFile, + IOSystem* pIOSystem +){ + // remember that we're exporting in binary mode + binary = true; + + // we're not currently using these preferences, + // but clang will cry about it if we never touch it. + // TODO: some of these might be relevant to export + (void)mProperties; + + // open the indicated file for writing (in binary mode) + outfile.reset(pIOSystem->Open(pFile,"wb")); + if (!outfile) { + throw DeadlyExportError( + "could not open output .fbx file: " + std::string(pFile) + ); + } + + // first a binary-specific file header + WriteBinaryHeader(); + + // the rest of the file is in node entries. + // we have to serialize each entry before we write to the output, + // as the first thing we write is the byte offset of the _next_ entry. + // Either that or we can skip back to write the offset when we finish. + WriteAllNodes(); + + // finally we have a binary footer to the file + WriteBinaryFooter(); + + // explicitly release file pointer, + // so we don't have to rely on class destruction. + outfile.reset(); +} + +void FBXExporter::ExportAscii ( + const char* pFile, + IOSystem* pIOSystem +){ + // remember that we're exporting in ascii mode + binary = false; + + // open the indicated file for writing in text mode + outfile.reset(pIOSystem->Open(pFile,"wt")); + if (!outfile) { + throw DeadlyExportError( + "could not open output .fbx file: " + std::string(pFile) + ); + } + + // write the ascii header + WriteAsciiHeader(); + + // write all the sections + WriteAllNodes(); + + // make sure the file ends with a newline. + // note: if the file is opened in text mode, + // this should do the right cross-platform thing. + outfile->Write("\n", 1, 1); + + // explicitly release file pointer, + // so we don't have to rely on class destruction. + outfile.reset(); +} + +void FBXExporter::WriteAsciiHeader() +{ + // basically just a comment at the top of the file + std::stringstream head; + head << "; FBX " << EXPORT_VERSION_STR << " project file\n"; + head << "; Created by the Open Asset Import Library (Assimp)\n"; + head << "; http://assimp.org\n"; + head << "; -------------------------------------------------\n"; + const std::string ascii_header = head.str(); + outfile->Write(ascii_header.c_str(), ascii_header.size(), 1); +} + +void FBXExporter::WriteAsciiSectionHeader(const std::string& title) +{ + StreamWriterLE outstream(outfile); + std::stringstream s; + s << "\n\n; " << title << '\n'; + s << FBX::COMMENT_UNDERLINE << "\n"; + outstream.PutString(s.str()); +} + +void FBXExporter::WriteBinaryHeader() +{ + // first a specific sequence of 23 bytes, always the same + const char binary_header[24] = "Kaydara FBX Binary\x20\x20\x00\x1a\x00"; + outfile->Write(binary_header, 1, 23); + + // then FBX version number, "multiplied" by 1000, as little-endian uint32. + // so 7.3 becomes 7300 == 0x841C0000, 7.4 becomes 7400 == 0xE81C0000, etc + { + StreamWriterLE outstream(outfile); + outstream.PutU4(EXPORT_VERSION_INT); + } // StreamWriter destructor writes the data to the file + + // after this the node data starts immediately + // (probably with the FBXHEaderExtension node) +} + +void FBXExporter::WriteBinaryFooter() +{ + outfile->Write(NULL_RECORD.c_str(), NULL_RECORD.size(), 1); + + outfile->Write(GENERIC_FOOTID.c_str(), GENERIC_FOOTID.size(), 1); + + // here some padding is added for alignment to 16 bytes. + // if already aligned, the full 16 bytes is added. + size_t pos = outfile->Tell(); + size_t pad = 16 - (pos % 16); + for (size_t i = 0; i < pad; ++i) { + outfile->Write("\x00", 1, 1); + } + + // not sure what this is, but it seems to always be 0 in modern files + for (size_t i = 0; i < 4; ++i) { + outfile->Write("\x00", 1, 1); + } + + // now the file version again + { + StreamWriterLE outstream(outfile); + outstream.PutU4(EXPORT_VERSION_INT); + } // StreamWriter destructor writes the data to the file + + // and finally some binary footer added to all files + for (size_t i = 0; i < 120; ++i) { + outfile->Write("\x00", 1, 1); + } + outfile->Write(FOOT_MAGIC.c_str(), FOOT_MAGIC.size(), 1); +} + +void FBXExporter::WriteAllNodes () +{ + // header + // (and fileid, creation time, creator, if binary) + WriteHeaderExtension(); + + // global settings + WriteGlobalSettings(); + + // documents + WriteDocuments(); + + // references + WriteReferences(); + + // definitions + WriteDefinitions(); + + // objects + WriteObjects(); + + // connections + WriteConnections(); + + // WriteTakes? (deprecated since at least 2015 (fbx 7.4)) +} + +//FBXHeaderExtension top-level node +void FBXExporter::WriteHeaderExtension () +{ + if (!binary) { + // no title, follows directly from the top comment + } + FBX::Node n("FBXHeaderExtension"); + StreamWriterLE outstream(outfile); + int indent = 0; + + // begin node + n.Begin(outstream, binary, indent); + + // write properties + // (none) + + // finish properties + n.EndProperties(outstream, binary, indent, 0); + + // begin children + n.BeginChildren(outstream, binary, indent); + + indent = 1; + + // write child nodes + FBX::Node::WritePropertyNode( + "FBXHeaderVersion", int32_t(1003), outstream, binary, indent + ); + FBX::Node::WritePropertyNode( + "FBXVersion", int32_t(EXPORT_VERSION_INT), outstream, binary, indent + ); + if (binary) { + FBX::Node::WritePropertyNode( + "EncryptionType", int32_t(0), outstream, binary, indent + ); + } + + FBX::Node CreationTimeStamp("CreationTimeStamp"); + time_t rawtime; + time(&rawtime); + struct tm * now = localtime(&rawtime); + CreationTimeStamp.AddChild("Version", int32_t(1000)); + CreationTimeStamp.AddChild("Year", int32_t(now->tm_year + 1900)); + CreationTimeStamp.AddChild("Month", int32_t(now->tm_mon + 1)); + CreationTimeStamp.AddChild("Day", int32_t(now->tm_mday)); + CreationTimeStamp.AddChild("Hour", int32_t(now->tm_hour)); + CreationTimeStamp.AddChild("Minute", int32_t(now->tm_min)); + CreationTimeStamp.AddChild("Second", int32_t(now->tm_sec)); + CreationTimeStamp.AddChild("Millisecond", int32_t(0)); + CreationTimeStamp.Dump(outstream, binary, indent); + + std::stringstream creator; + creator << "Open Asset Import Library (Assimp) " << aiGetVersionMajor() + << "." << aiGetVersionMinor() << "." << aiGetVersionRevision(); + FBX::Node::WritePropertyNode( + "Creator", creator.str(), outstream, binary, indent + ); + + //FBX::Node sceneinfo("SceneInfo"); + //sceneinfo.AddProperty("GlobalInfo" + FBX::SEPARATOR + "SceneInfo"); + // not sure if any of this is actually needed, + // so just write an empty node for now. + //sceneinfo.Dump(outstream, binary, indent); + + indent = 0; + + // finish node + n.End(outstream, binary, indent, true); + + // that's it for FBXHeaderExtension... + if (!binary) { return; } + + // but binary files also need top-level FileID, CreationTime, Creator: + std::vector<uint8_t> raw(GENERIC_FILEID.size()); + for (size_t i = 0; i < GENERIC_FILEID.size(); ++i) { + raw[i] = uint8_t(GENERIC_FILEID[i]); + } + FBX::Node::WritePropertyNode( + "FileId", raw, outstream, binary, indent + ); + FBX::Node::WritePropertyNode( + "CreationTime", GENERIC_CTIME, outstream, binary, indent + ); + FBX::Node::WritePropertyNode( + "Creator", creator.str(), outstream, binary, indent + ); +} + +// WriteGlobalSettings helpers + +void WritePropInt(const aiScene* scene, FBX::Node& p, const std::string& key, int defaultValue) +{ + int value; + if (scene->mMetaData != nullptr && scene->mMetaData->Get(key, value)) { + p.AddP70int(key, value); + } else { + p.AddP70int(key, defaultValue); + } +} + +void WritePropDouble(const aiScene* scene, FBX::Node& p, const std::string& key, double defaultValue) +{ + double value; + if (scene->mMetaData != nullptr && scene->mMetaData->Get(key, value)) { + p.AddP70double(key, value); + } else { + // fallback lookup float instead + float floatValue; + if (scene->mMetaData != nullptr && scene->mMetaData->Get(key, floatValue)) { + p.AddP70double(key, (double)floatValue); + } else { + p.AddP70double(key, defaultValue); + } + } +} + +void WritePropEnum(const aiScene* scene, FBX::Node& p, const std::string& key, int defaultValue) +{ + int value; + if (scene->mMetaData != nullptr && scene->mMetaData->Get(key, value)) { + p.AddP70enum(key, value); + } else { + p.AddP70enum(key, defaultValue); + } +} + +void WritePropColor(const aiScene* scene, FBX::Node& p, const std::string& key, const aiVector3D& defaultValue) +{ + aiVector3D value; + if (scene->mMetaData != nullptr && scene->mMetaData->Get(key, value)) { + // ai_real can be float or double, cast to avoid warnings + p.AddP70color(key, (double)value.x, (double)value.y, (double)value.z); + } else { + p.AddP70color(key, (double)defaultValue.x, (double)defaultValue.y, (double)defaultValue.z); + } +} + +void WritePropString(const aiScene* scene, FBX::Node& p, const std::string& key, const std::string& defaultValue) +{ + aiString value; // MetaData doesn't hold std::string + if (scene->mMetaData != nullptr && scene->mMetaData->Get(key, value)) { + p.AddP70string(key, value.C_Str()); + } else { + p.AddP70string(key, defaultValue); + } +} + +void FBXExporter::WriteGlobalSettings () +{ + if (!binary) { + // no title, follows directly from the header extension + } + FBX::Node gs("GlobalSettings"); + gs.AddChild("Version", int32_t(1000)); + + FBX::Node p("Properties70"); + WritePropInt(mScene, p, "UpAxis", 1); + WritePropInt(mScene, p, "UpAxisSign", 1); + WritePropInt(mScene, p, "FrontAxis", 2); + WritePropInt(mScene, p, "FrontAxisSign", 1); + WritePropInt(mScene, p, "CoordAxis", 0); + WritePropInt(mScene, p, "CoordAxisSign", 1); + WritePropInt(mScene, p, "OriginalUpAxis", 1); + WritePropInt(mScene, p, "OriginalUpAxisSign", 1); + WritePropDouble(mScene, p, "UnitScaleFactor", 1.0); + WritePropDouble(mScene, p, "OriginalUnitScaleFactor", 1.0); + WritePropColor(mScene, p, "AmbientColor", aiVector3D((ai_real)0.0, (ai_real)0.0, (ai_real)0.0)); + WritePropString(mScene, p,"DefaultCamera", "Producer Perspective"); + WritePropEnum(mScene, p, "TimeMode", 11); + WritePropEnum(mScene, p, "TimeProtocol", 2); + WritePropEnum(mScene, p, "SnapOnFrameMode", 0); + p.AddP70time("TimeSpanStart", 0); // TODO: animation support + p.AddP70time("TimeSpanStop", FBX::SECOND); // TODO: animation support + WritePropDouble(mScene, p, "CustomFrameRate", -1.0); + p.AddP70("TimeMarker", "Compound", "", ""); // not sure what this is + WritePropInt(mScene, p, "CurrentTimeMarker", -1); + gs.AddChild(p); + + gs.Dump(outfile, binary, 0); +} + +void FBXExporter::WriteDocuments () +{ + if (!binary) { + WriteAsciiSectionHeader("Documents Description"); + } + + // not sure what the use of multiple documents would be, + // or whether any end-application supports it + FBX::Node docs("Documents"); + docs.AddChild("Count", int32_t(1)); + FBX::Node doc("Document"); + + // generate uid + int64_t uid = generate_uid(); + doc.AddProperties(uid, "", "Scene"); + FBX::Node p("Properties70"); + p.AddP70("SourceObject", "object", "", ""); // what is this even for? + p.AddP70string("ActiveAnimStackName", ""); // should do this properly? + doc.AddChild(p); + + // UID for root node in scene hierarchy. + // always set to 0 in the case of a single document. + // not sure what happens if more than one document exists, + // but that won't matter to us as we're exporting a single scene. + doc.AddChild("RootNode", int64_t(0)); + + docs.AddChild(doc); + docs.Dump(outfile, binary, 0); +} + +void FBXExporter::WriteReferences () +{ + if (!binary) { + WriteAsciiSectionHeader("Document References"); + } + // always empty for now. + // not really sure what this is for. + FBX::Node n("References"); + n.force_has_children = true; + n.Dump(outfile, binary, 0); +} + + +// --------------------------------------------------------------- +// some internal helper functions used for writing the definitions +// (before any actual data is written) +// --------------------------------------------------------------- + +size_t count_nodes(const aiNode* n, const aiNode* root) { + size_t count; + if (n == root) { + count = n->mNumMeshes; // (not counting root node) + } else if (n->mNumMeshes > 1) { + count = n->mNumMeshes + 1; + } else { + count = 1; + } + for (size_t i = 0; i < n->mNumChildren; ++i) { + count += count_nodes(n->mChildren[i], root); + } + return count; +} + +bool has_phong_mat(const aiScene* scene) +{ + // just search for any material with a shininess exponent + for (size_t i = 0; i < scene->mNumMaterials; ++i) { + aiMaterial* mat = scene->mMaterials[i]; + float shininess = 0; + mat->Get(AI_MATKEY_SHININESS, shininess); + if (shininess > 0) { + return true; + } + } + return false; +} + +size_t count_images(const aiScene* scene) { + std::unordered_set<std::string> images; + aiString texpath; + for (size_t i = 0; i < scene->mNumMaterials; ++i) { + aiMaterial* mat = scene->mMaterials[i]; + for ( + size_t tt = aiTextureType_DIFFUSE; + tt < aiTextureType_UNKNOWN; + ++tt + ){ + const aiTextureType textype = static_cast<aiTextureType>(tt); + const size_t texcount = mat->GetTextureCount(textype); + for (unsigned int j = 0; j < texcount; ++j) { + mat->GetTexture(textype, j, &texpath); + images.insert(std::string(texpath.C_Str())); + } + } + } + return images.size(); +} + +size_t count_textures(const aiScene* scene) { + size_t count = 0; + for (size_t i = 0; i < scene->mNumMaterials; ++i) { + aiMaterial* mat = scene->mMaterials[i]; + for ( + size_t tt = aiTextureType_DIFFUSE; + tt < aiTextureType_UNKNOWN; + ++tt + ){ + // TODO: handle layered textures + if (mat->GetTextureCount(static_cast<aiTextureType>(tt)) > 0) { + count += 1; + } + } + } + return count; +} + +size_t count_deformers(const aiScene* scene) { + size_t count = 0; + for (size_t i = 0; i < scene->mNumMeshes; ++i) { + const size_t n = scene->mMeshes[i]->mNumBones; + if (n) { + // 1 main deformer, 1 subdeformer per bone + count += n + 1; + } + } + return count; +} + +void FBXExporter::WriteDefinitions () +{ + // basically this is just bookkeeping: + // determining how many of each type of object there are + // and specifying the base properties to use when otherwise unspecified. + + // ascii section header + if (!binary) { + WriteAsciiSectionHeader("Object definitions"); + } + + // we need to count the objects + int32_t count; + int32_t total_count = 0; + + // and store them + std::vector<FBX::Node> object_nodes; + FBX::Node n, pt, p; + + // GlobalSettings + // this seems to always be here in Maya exports + n = FBX::Node("ObjectType", "GlobalSettings"); + count = 1; + n.AddChild("Count", count); + object_nodes.push_back(n); + total_count += count; + + // AnimationStack / FbxAnimStack + // this seems to always be here in Maya exports, + // but no harm seems to come of leaving it out. + count = mScene->mNumAnimations; + if (count) { + n = FBX::Node("ObjectType", "AnimationStack"); + n.AddChild("Count", count); + pt = FBX::Node("PropertyTemplate", "FbxAnimStack"); + p = FBX::Node("Properties70"); + p.AddP70string("Description", ""); + p.AddP70time("LocalStart", 0); + p.AddP70time("LocalStop", 0); + p.AddP70time("ReferenceStart", 0); + p.AddP70time("ReferenceStop", 0); + pt.AddChild(p); + n.AddChild(pt); + object_nodes.push_back(n); + total_count += count; + } + + // AnimationLayer / FbxAnimLayer + // this seems to always be here in Maya exports, + // but no harm seems to come of leaving it out. + // Assimp doesn't support animation layers, + // so there will be one per aiAnimation + count = mScene->mNumAnimations; + if (count) { + n = FBX::Node("ObjectType", "AnimationLayer"); + n.AddChild("Count", count); + pt = FBX::Node("PropertyTemplate", "FBXAnimLayer"); + p = FBX::Node("Properties70"); + p.AddP70("Weight", "Number", "", "A", double(100)); + p.AddP70bool("Mute", 0); + p.AddP70bool("Solo", 0); + p.AddP70bool("Lock", 0); + p.AddP70color("Color", 0.8, 0.8, 0.8); + p.AddP70("BlendMode", "enum", "", "", int32_t(0)); + p.AddP70("RotationAccumulationMode", "enum", "", "", int32_t(0)); + p.AddP70("ScaleAccumulationMode", "enum", "", "", int32_t(0)); + p.AddP70("BlendModeBypass", "ULongLong", "", "", int64_t(0)); + pt.AddChild(p); + n.AddChild(pt); + object_nodes.push_back(n); + total_count += count; + } + + // NodeAttribute + // this is completely absurd. + // there can only be one "NodeAttribute" template, + // but FbxSkeleton, FbxCamera, FbxLight all are "NodeAttributes". + // so if only one exists we should set the template for that, + // otherwise... we just pick one :/. + // the others have to set all their properties every instance, + // because there's no template. + count = 1; // TODO: select properly + if (count) { + // FbxSkeleton + n = FBX::Node("ObjectType", "NodeAttribute"); + n.AddChild("Count", count); + pt = FBX::Node("PropertyTemplate", "FbxSkeleton"); + p = FBX::Node("Properties70"); + p.AddP70color("Color", 0.8, 0.8, 0.8); + p.AddP70double("Size", 33.333333333333); + p.AddP70("LimbLength", "double", "Number", "H", double(1)); + // note: not sure what the "H" flag is for - hidden? + pt.AddChild(p); + n.AddChild(pt); + object_nodes.push_back(n); + total_count += count; + } + + // Model / FbxNode + // <~~ node hierarchy + count = int32_t(count_nodes(mScene->mRootNode, mScene->mRootNode)); + if (count) { + n = FBX::Node("ObjectType", "Model"); + n.AddChild("Count", count); + pt = FBX::Node("PropertyTemplate", "FbxNode"); + p = FBX::Node("Properties70"); + p.AddP70enum("QuaternionInterpolate", 0); + p.AddP70vector("RotationOffset", 0.0, 0.0, 0.0); + p.AddP70vector("RotationPivot", 0.0, 0.0, 0.0); + p.AddP70vector("ScalingOffset", 0.0, 0.0, 0.0); + p.AddP70vector("ScalingPivot", 0.0, 0.0, 0.0); + p.AddP70bool("TranslationActive", 0); + p.AddP70vector("TranslationMin", 0.0, 0.0, 0.0); + p.AddP70vector("TranslationMax", 0.0, 0.0, 0.0); + p.AddP70bool("TranslationMinX", 0); + p.AddP70bool("TranslationMinY", 0); + p.AddP70bool("TranslationMinZ", 0); + p.AddP70bool("TranslationMaxX", 0); + p.AddP70bool("TranslationMaxY", 0); + p.AddP70bool("TranslationMaxZ", 0); + p.AddP70enum("RotationOrder", 0); + p.AddP70bool("RotationSpaceForLimitOnly", 0); + p.AddP70double("RotationStiffnessX", 0.0); + p.AddP70double("RotationStiffnessY", 0.0); + p.AddP70double("RotationStiffnessZ", 0.0); + p.AddP70double("AxisLen", 10.0); + p.AddP70vector("PreRotation", 0.0, 0.0, 0.0); + p.AddP70vector("PostRotation", 0.0, 0.0, 0.0); + p.AddP70bool("RotationActive", 0); + p.AddP70vector("RotationMin", 0.0, 0.0, 0.0); + p.AddP70vector("RotationMax", 0.0, 0.0, 0.0); + p.AddP70bool("RotationMinX", 0); + p.AddP70bool("RotationMinY", 0); + p.AddP70bool("RotationMinZ", 0); + p.AddP70bool("RotationMaxX", 0); + p.AddP70bool("RotationMaxY", 0); + p.AddP70bool("RotationMaxZ", 0); + p.AddP70enum("InheritType", 0); + p.AddP70bool("ScalingActive", 0); + p.AddP70vector("ScalingMin", 0.0, 0.0, 0.0); + p.AddP70vector("ScalingMax", 1.0, 1.0, 1.0); + p.AddP70bool("ScalingMinX", 0); + p.AddP70bool("ScalingMinY", 0); + p.AddP70bool("ScalingMinZ", 0); + p.AddP70bool("ScalingMaxX", 0); + p.AddP70bool("ScalingMaxY", 0); + p.AddP70bool("ScalingMaxZ", 0); + p.AddP70vector("GeometricTranslation", 0.0, 0.0, 0.0); + p.AddP70vector("GeometricRotation", 0.0, 0.0, 0.0); + p.AddP70vector("GeometricScaling", 1.0, 1.0, 1.0); + p.AddP70double("MinDampRangeX", 0.0); + p.AddP70double("MinDampRangeY", 0.0); + p.AddP70double("MinDampRangeZ", 0.0); + p.AddP70double("MaxDampRangeX", 0.0); + p.AddP70double("MaxDampRangeY", 0.0); + p.AddP70double("MaxDampRangeZ", 0.0); + p.AddP70double("MinDampStrengthX", 0.0); + p.AddP70double("MinDampStrengthY", 0.0); + p.AddP70double("MinDampStrengthZ", 0.0); + p.AddP70double("MaxDampStrengthX", 0.0); + p.AddP70double("MaxDampStrengthY", 0.0); + p.AddP70double("MaxDampStrengthZ", 0.0); + p.AddP70double("PreferedAngleX", 0.0); + p.AddP70double("PreferedAngleY", 0.0); + p.AddP70double("PreferedAngleZ", 0.0); + p.AddP70("LookAtProperty", "object", "", ""); + p.AddP70("UpVectorProperty", "object", "", ""); + p.AddP70bool("Show", 1); + p.AddP70bool("NegativePercentShapeSupport", 1); + p.AddP70int("DefaultAttributeIndex", -1); + p.AddP70bool("Freeze", 0); + p.AddP70bool("LODBox", 0); + p.AddP70( + "Lcl Translation", "Lcl Translation", "", "A", + double(0), double(0), double(0) + ); + p.AddP70( + "Lcl Rotation", "Lcl Rotation", "", "A", + double(0), double(0), double(0) + ); + p.AddP70( + "Lcl Scaling", "Lcl Scaling", "", "A", + double(1), double(1), double(1) + ); + p.AddP70("Visibility", "Visibility", "", "A", double(1)); + p.AddP70( + "Visibility Inheritance", "Visibility Inheritance", "", "", + int32_t(1) + ); + pt.AddChild(p); + n.AddChild(pt); + object_nodes.push_back(n); + total_count += count; + } + + // Geometry / FbxMesh + // <~~ aiMesh + count = mScene->mNumMeshes; + + // Blendshapes are considered Geometry + int32_t bsDeformerCount=0; + for (size_t mi = 0; mi < mScene->mNumMeshes; ++mi) { + aiMesh* m = mScene->mMeshes[mi]; + if (m->mNumAnimMeshes > 0) { + count+=m->mNumAnimMeshes; + bsDeformerCount+=m->mNumAnimMeshes; // One deformer per blendshape + bsDeformerCount++; // Plus one master blendshape deformer + } + } + + if (count) { + n = FBX::Node("ObjectType", "Geometry"); + n.AddChild("Count", count); + pt = FBX::Node("PropertyTemplate", "FbxMesh"); + p = FBX::Node("Properties70"); + p.AddP70color("Color", 0, 0, 0); + p.AddP70vector("BBoxMin", 0, 0, 0); + p.AddP70vector("BBoxMax", 0, 0, 0); + p.AddP70bool("Primary Visibility", 1); + p.AddP70bool("Casts Shadows", 1); + p.AddP70bool("Receive Shadows", 1); + pt.AddChild(p); + n.AddChild(pt); + object_nodes.push_back(n); + total_count += count; + } + + // Material / FbxSurfacePhong, FbxSurfaceLambert, FbxSurfaceMaterial + // <~~ aiMaterial + // basically if there's any phong material this is defined as phong, + // and otherwise lambert. + // More complex materials cause a bare-bones FbxSurfaceMaterial definition + // and are treated specially, as they're not really supported by FBX. + // TODO: support Maya's Stingray PBS material + count = mScene->mNumMaterials; + if (count) { + bool has_phong = has_phong_mat(mScene); + n = FBX::Node("ObjectType", "Material"); + n.AddChild("Count", count); + pt = FBX::Node("PropertyTemplate"); + if (has_phong) { + pt.AddProperty("FbxSurfacePhong"); + } else { + pt.AddProperty("FbxSurfaceLambert"); + } + p = FBX::Node("Properties70"); + if (has_phong) { + p.AddP70string("ShadingModel", "Phong"); + } else { + p.AddP70string("ShadingModel", "Lambert"); + } + p.AddP70bool("MultiLayer", 0); + p.AddP70colorA("EmissiveColor", 0.0, 0.0, 0.0); + p.AddP70numberA("EmissiveFactor", 1.0); + p.AddP70colorA("AmbientColor", 0.2, 0.2, 0.2); + p.AddP70numberA("AmbientFactor", 1.0); + p.AddP70colorA("DiffuseColor", 0.8, 0.8, 0.8); + p.AddP70numberA("DiffuseFactor", 1.0); + p.AddP70vector("Bump", 0.0, 0.0, 0.0); + p.AddP70vector("NormalMap", 0.0, 0.0, 0.0); + p.AddP70double("BumpFactor", 1.0); + p.AddP70colorA("TransparentColor", 0.0, 0.0, 0.0); + p.AddP70numberA("TransparencyFactor", 0.0); + p.AddP70color("DisplacementColor", 0.0, 0.0, 0.0); + p.AddP70double("DisplacementFactor", 1.0); + p.AddP70color("VectorDisplacementColor", 0.0, 0.0, 0.0); + p.AddP70double("VectorDisplacementFactor", 1.0); + if (has_phong) { + p.AddP70colorA("SpecularColor", 0.2, 0.2, 0.2); + p.AddP70numberA("SpecularFactor", 1.0); + p.AddP70numberA("ShininessExponent", 20.0); + p.AddP70colorA("ReflectionColor", 0.0, 0.0, 0.0); + p.AddP70numberA("ReflectionFactor", 1.0); + } + pt.AddChild(p); + n.AddChild(pt); + object_nodes.push_back(n); + total_count += count; + } + + // Video / FbxVideo + // one for each image file. + count = int32_t(count_images(mScene)); + if (count) { + n = FBX::Node("ObjectType", "Video"); + n.AddChild("Count", count); + pt = FBX::Node("PropertyTemplate", "FbxVideo"); + p = FBX::Node("Properties70"); + p.AddP70bool("ImageSequence", 0); + p.AddP70int("ImageSequenceOffset", 0); + p.AddP70double("FrameRate", 0.0); + p.AddP70int("LastFrame", 0); + p.AddP70int("Width", 0); + p.AddP70int("Height", 0); + p.AddP70("Path", "KString", "XRefUrl", "", ""); + p.AddP70int("StartFrame", 0); + p.AddP70int("StopFrame", 0); + p.AddP70double("PlaySpeed", 0.0); + p.AddP70time("Offset", 0); + p.AddP70enum("InterlaceMode", 0); + p.AddP70bool("FreeRunning", 0); + p.AddP70bool("Loop", 0); + p.AddP70enum("AccessMode", 0); + pt.AddChild(p); + n.AddChild(pt); + object_nodes.push_back(n); + total_count += count; + } + + // Texture / FbxFileTexture + // <~~ aiTexture + count = int32_t(count_textures(mScene)); + if (count) { + n = FBX::Node("ObjectType", "Texture"); + n.AddChild("Count", count); + pt = FBX::Node("PropertyTemplate", "FbxFileTexture"); + p = FBX::Node("Properties70"); + p.AddP70enum("TextureTypeUse", 0); + p.AddP70numberA("Texture alpha", 1.0); + p.AddP70enum("CurrentMappingType", 0); + p.AddP70enum("WrapModeU", 0); + p.AddP70enum("WrapModeV", 0); + p.AddP70bool("UVSwap", 0); + p.AddP70bool("PremultiplyAlpha", 1); + p.AddP70vectorA("Translation", 0.0, 0.0, 0.0); + p.AddP70vectorA("Rotation", 0.0, 0.0, 0.0); + p.AddP70vectorA("Scaling", 1.0, 1.0, 1.0); + p.AddP70vector("TextureRotationPivot", 0.0, 0.0, 0.0); + p.AddP70vector("TextureScalingPivot", 0.0, 0.0, 0.0); + p.AddP70enum("CurrentTextureBlendMode", 1); + p.AddP70string("UVSet", "default"); + p.AddP70bool("UseMaterial", 0); + p.AddP70bool("UseMipMap", 0); + pt.AddChild(p); + n.AddChild(pt); + object_nodes.push_back(n); + total_count += count; + } + + // AnimationCurveNode / FbxAnimCurveNode + count = mScene->mNumAnimations * 3; + if (count) { + n = FBX::Node("ObjectType", "AnimationCurveNode"); + n.AddChild("Count", count); + pt = FBX::Node("PropertyTemplate", "FbxAnimCurveNode"); + p = FBX::Node("Properties70"); + p.AddP70("d", "Compound", "", ""); + pt.AddChild(p); + n.AddChild(pt); + object_nodes.push_back(n); + total_count += count; + } + + // AnimationCurve / FbxAnimCurve + count = mScene->mNumAnimations * 9; + if (count) { + n = FBX::Node("ObjectType", "AnimationCurve"); + n.AddChild("Count", count); + object_nodes.push_back(n); + total_count += count; + } + + // Pose + count = 0; + for (size_t i = 0; i < mScene->mNumMeshes; ++i) { + aiMesh* mesh = mScene->mMeshes[i]; + if (mesh->HasBones()) { ++count; } + } + if (count) { + n = FBX::Node("ObjectType", "Pose"); + n.AddChild("Count", count); + object_nodes.push_back(n); + total_count += count; + } + + // Deformer + count = int32_t(count_deformers(mScene))+bsDeformerCount; + if (count) { + n = FBX::Node("ObjectType", "Deformer"); + n.AddChild("Count", count); + object_nodes.push_back(n); + total_count += count; + } + + // (template) + count = 0; + if (count) { + n = FBX::Node("ObjectType", ""); + n.AddChild("Count", count); + pt = FBX::Node("PropertyTemplate", ""); + p = FBX::Node("Properties70"); + pt.AddChild(p); + n.AddChild(pt); + object_nodes.push_back(n); + total_count += count; + } + + // now write it all + FBX::Node defs("Definitions"); + defs.AddChild("Version", int32_t(100)); + defs.AddChild("Count", int32_t(total_count)); + for (auto &on : object_nodes) { + defs.AddChild(on); + } + defs.Dump(outfile, binary, 0); +} + + +// ------------------------------------------------------------------- +// some internal helper functions used for writing the objects section +// (which holds the actual data) +// ------------------------------------------------------------------- + +aiNode* get_node_for_mesh(unsigned int meshIndex, aiNode* node) +{ + for (size_t i = 0; i < node->mNumMeshes; ++i) { + if (node->mMeshes[i] == meshIndex) { + return node; + } + } + for (size_t i = 0; i < node->mNumChildren; ++i) { + aiNode* ret = get_node_for_mesh(meshIndex, node->mChildren[i]); + if (ret) { return ret; } + } + return nullptr; +} + +aiMatrix4x4 get_world_transform(const aiNode* node, const aiScene* scene) +{ + std::vector<const aiNode*> node_chain; + while (node != scene->mRootNode) { + node_chain.push_back(node); + node = node->mParent; + } + aiMatrix4x4 transform; + for (auto n = node_chain.rbegin(); n != node_chain.rend(); ++n) { + transform *= (*n)->mTransformation; + } + return transform; +} + +int64_t to_ktime(double ticks, const aiAnimation* anim) { + if (anim->mTicksPerSecond <= 0) { + return static_cast<int64_t>(ticks) * FBX::SECOND; + } + return (static_cast<int64_t>(ticks) / static_cast<int64_t>(anim->mTicksPerSecond)) * FBX::SECOND; +} + +int64_t to_ktime(double time) { + return (static_cast<int64_t>(time * FBX::SECOND)); +} + +void FBXExporter::WriteObjects () +{ + if (!binary) { + WriteAsciiSectionHeader("Object properties"); + } + // numbers should match those given in definitions! make sure to check + StreamWriterLE outstream(outfile); + FBX::Node object_node("Objects"); + int indent = 0; + object_node.Begin(outstream, binary, indent); + object_node.EndProperties(outstream, binary, indent); + object_node.BeginChildren(outstream, binary, indent); + + bool bJoinIdenticalVertices = mProperties->GetPropertyBool("bJoinIdenticalVertices", true); + std::vector<std::vector<int32_t>> vVertexIndice;//save vertex_indices as it is needed later + + // geometry (aiMesh) + mesh_uids.clear(); + indent = 1; + for (size_t mi = 0; mi < mScene->mNumMeshes; ++mi) { + // it's all about this mesh + aiMesh* m = mScene->mMeshes[mi]; + + // start the node record + FBX::Node n("Geometry"); + int64_t uid = generate_uid(); + mesh_uids.push_back(uid); + n.AddProperty(uid); + n.AddProperty(FBX::SEPARATOR + "Geometry"); + n.AddProperty("Mesh"); + n.Begin(outstream, binary, indent); + n.DumpProperties(outstream, binary, indent); + n.EndProperties(outstream, binary, indent); + n.BeginChildren(outstream, binary, indent); + indent = 2; + + // output vertex data - each vertex should be unique (probably) + std::vector<double> flattened_vertices; + // index of original vertex in vertex data vector + std::vector<int32_t> vertex_indices; + // map of vertex value to its index in the data vector + std::map<aiVector3D,size_t> index_by_vertex_value; + if(bJoinIdenticalVertices){ + int32_t index = 0; + for (size_t vi = 0; vi < m->mNumVertices; ++vi) { + aiVector3D vtx = m->mVertices[vi]; + auto elem = index_by_vertex_value.find(vtx); + if (elem == index_by_vertex_value.end()) { + vertex_indices.push_back(index); + index_by_vertex_value[vtx] = index; + flattened_vertices.push_back(vtx[0]); + flattened_vertices.push_back(vtx[1]); + flattened_vertices.push_back(vtx[2]); + ++index; + } else { + vertex_indices.push_back(int32_t(elem->second)); + } + } + } + else { // do not join vertex, respect the export flag + vertex_indices.resize(m->mNumVertices); + std::iota(vertex_indices.begin(), vertex_indices.end(), 0); + for(unsigned int v = 0; v < m->mNumVertices; ++ v) { + aiVector3D vtx = m->mVertices[v]; + flattened_vertices.push_back(vtx.x); + flattened_vertices.push_back(vtx.y); + flattened_vertices.push_back(vtx.z); + } + } + vVertexIndice.push_back(vertex_indices); + + FBX::Node::WritePropertyNode( + "Vertices", flattened_vertices, outstream, binary, indent + ); + + // output polygon data as a flattened array of vertex indices. + // the last vertex index of each polygon is negated and - 1 + std::vector<int32_t> polygon_data; + for (size_t fi = 0; fi < m->mNumFaces; ++fi) { + const aiFace &f = m->mFaces[fi]; + for (size_t pvi = 0; pvi < f.mNumIndices - 1; ++pvi) { + polygon_data.push_back(vertex_indices[f.mIndices[pvi]]); + } + polygon_data.push_back( + -1 - vertex_indices[f.mIndices[f.mNumIndices-1]] + ); + } + FBX::Node::WritePropertyNode( + "PolygonVertexIndex", polygon_data, outstream, binary, indent + ); + + // here could be edges but they're insane. + // it's optional anyway, so let's ignore it. + + FBX::Node::WritePropertyNode( + "GeometryVersion", int32_t(124), outstream, binary, indent + ); + + // normals, if any + if (m->HasNormals()) { + FBX::Node normals("LayerElementNormal", int32_t(0)); + normals.Begin(outstream, binary, indent); + normals.DumpProperties(outstream, binary, indent); + normals.EndProperties(outstream, binary, indent); + normals.BeginChildren(outstream, binary, indent); + indent = 3; + FBX::Node::WritePropertyNode( + "Version", int32_t(101), outstream, binary, indent + ); + FBX::Node::WritePropertyNode( + "Name", "", outstream, binary, indent + ); + FBX::Node::WritePropertyNode( + "MappingInformationType", "ByPolygonVertex", + outstream, binary, indent + ); + // TODO: vertex-normals or indexed normals when appropriate + FBX::Node::WritePropertyNode( + "ReferenceInformationType", "Direct", + outstream, binary, indent + ); + std::vector<double> normal_data; + normal_data.reserve(3 * polygon_data.size()); + for (size_t fi = 0; fi < m->mNumFaces; ++fi) { + const aiFace &f = m->mFaces[fi]; + for (size_t pvi = 0; pvi < f.mNumIndices; ++pvi) { + const aiVector3D &curN = m->mNormals[f.mIndices[pvi]]; + normal_data.push_back(curN.x); + normal_data.push_back(curN.y); + normal_data.push_back(curN.z); + } + } + FBX::Node::WritePropertyNode( + "Normals", normal_data, outstream, binary, indent + ); + // note: version 102 has a NormalsW also... not sure what it is, + // so we can stick with version 101 for now. + indent = 2; + normals.End(outstream, binary, indent, true); + } + + // colors, if any + // TODO only one color channel currently + const int32_t colorChannelIndex = 0; + if (m->HasVertexColors(colorChannelIndex)) { + FBX::Node vertexcolors("LayerElementColor", int32_t(colorChannelIndex)); + vertexcolors.Begin(outstream, binary, indent); + vertexcolors.DumpProperties(outstream, binary, indent); + vertexcolors.EndProperties(outstream, binary, indent); + vertexcolors.BeginChildren(outstream, binary, indent); + indent = 3; + FBX::Node::WritePropertyNode( + "Version", int32_t(101), outstream, binary, indent + ); + char layerName[8]; + sprintf(layerName, "COLOR_%d", colorChannelIndex); + FBX::Node::WritePropertyNode( + "Name", (const char*)layerName, outstream, binary, indent + ); + FBX::Node::WritePropertyNode( + "MappingInformationType", "ByPolygonVertex", + outstream, binary, indent + ); + FBX::Node::WritePropertyNode( + "ReferenceInformationType", "Direct", + outstream, binary, indent + ); + std::vector<double> color_data; + color_data.reserve(4 * polygon_data.size()); + for (size_t fi = 0; fi < m->mNumFaces; ++fi) { + const aiFace &f = m->mFaces[fi]; + for (size_t pvi = 0; pvi < f.mNumIndices; ++pvi) { + const aiColor4D &c = m->mColors[colorChannelIndex][f.mIndices[pvi]]; + color_data.push_back(c.r); + color_data.push_back(c.g); + color_data.push_back(c.b); + color_data.push_back(c.a); + } + } + FBX::Node::WritePropertyNode( + "Colors", color_data, outstream, binary, indent + ); + indent = 2; + vertexcolors.End(outstream, binary, indent, true); + } + + // uvs, if any + for (size_t uvi = 0; uvi < m->GetNumUVChannels(); ++uvi) { + if (m->mNumUVComponents[uvi] > 2) { + // FBX only supports 2-channel UV maps... + // or at least i'm not sure how to indicate a different number + std::stringstream err; + err << "Only 2-channel UV maps supported by FBX,"; + err << " but mesh " << mi; + if (m->mName.length) { + err << " (" << m->mName.C_Str() << ")"; + } + err << " UV map " << uvi; + err << " has " << m->mNumUVComponents[uvi]; + err << " components! Data will be preserved,"; + err << " but may be incorrectly interpreted on load."; + ASSIMP_LOG_WARN(err.str()); + } + FBX::Node uv("LayerElementUV", int32_t(uvi)); + uv.Begin(outstream, binary, indent); + uv.DumpProperties(outstream, binary, indent); + uv.EndProperties(outstream, binary, indent); + uv.BeginChildren(outstream, binary, indent); + indent = 3; + FBX::Node::WritePropertyNode( + "Version", int32_t(101), outstream, binary, indent + ); + // it doesn't seem like assimp keeps the uv map name, + // so just leave it blank. + FBX::Node::WritePropertyNode( + "Name", "", outstream, binary, indent + ); + FBX::Node::WritePropertyNode( + "MappingInformationType", "ByPolygonVertex", + outstream, binary, indent + ); + FBX::Node::WritePropertyNode( + "ReferenceInformationType", "IndexToDirect", + outstream, binary, indent + ); + + std::vector<double> uv_data; + std::vector<int32_t> uv_indices; + std::map<aiVector3D,int32_t> index_by_uv; + int32_t index = 0; + for (size_t fi = 0; fi < m->mNumFaces; ++fi) { + const aiFace &f = m->mFaces[fi]; + for (size_t pvi = 0; pvi < f.mNumIndices; ++pvi) { + const aiVector3D &curUv = + m->mTextureCoords[uvi][f.mIndices[pvi]]; + auto elem = index_by_uv.find(curUv); + if (elem == index_by_uv.end()) { + index_by_uv[curUv] = index; + uv_indices.push_back(index); + for (unsigned int x = 0; x < m->mNumUVComponents[uvi]; ++x) { + uv_data.push_back(curUv[x]); + } + ++index; + } else { + uv_indices.push_back(elem->second); + } + } + } + FBX::Node::WritePropertyNode( + "UV", uv_data, outstream, binary, indent + ); + FBX::Node::WritePropertyNode( + "UVIndex", uv_indices, outstream, binary, indent + ); + indent = 2; + uv.End(outstream, binary, indent, true); + } + + // i'm not really sure why this material section exists, + // as the material is linked via "Connections". + // it seems to always have the same "0" value. + FBX::Node mat("LayerElementMaterial", int32_t(0)); + mat.AddChild("Version", int32_t(101)); + mat.AddChild("Name", ""); + mat.AddChild("MappingInformationType", "AllSame"); + mat.AddChild("ReferenceInformationType", "IndexToDirect"); + std::vector<int32_t> mat_indices = {0}; + mat.AddChild("Materials", mat_indices); + mat.Dump(outstream, binary, indent); + + // finally we have the layer specifications, + // which select the normals / UV set / etc to use. + // TODO: handle multiple uv sets correctly? + FBX::Node layer("Layer", int32_t(0)); + layer.AddChild("Version", int32_t(100)); + FBX::Node le("LayerElement"); + le.AddChild("Type", "LayerElementNormal"); + le.AddChild("TypedIndex", int32_t(0)); + layer.AddChild(le); + // TODO only 1 color channel currently + le = FBX::Node("LayerElement"); + le.AddChild("Type", "LayerElementColor"); + le.AddChild("TypedIndex", int32_t(0)); + layer.AddChild(le); + le = FBX::Node("LayerElement"); + le.AddChild("Type", "LayerElementMaterial"); + le.AddChild("TypedIndex", int32_t(0)); + layer.AddChild(le); + le = FBX::Node("LayerElement"); + le.AddChild("Type", "LayerElementUV"); + le.AddChild("TypedIndex", int32_t(0)); + layer.AddChild(le); + layer.Dump(outstream, binary, indent); + + for(unsigned int lr = 1; lr < m->GetNumUVChannels(); ++ lr) + { + FBX::Node layerExtra("Layer", int32_t(lr)); + layerExtra.AddChild("Version", int32_t(100)); + FBX::Node leExtra("LayerElement"); + leExtra.AddChild("Type", "LayerElementUV"); + leExtra.AddChild("TypedIndex", int32_t(lr)); + layerExtra.AddChild(leExtra); + layerExtra.Dump(outstream, binary, indent); + } + // finish the node record + indent = 1; + n.End(outstream, binary, indent, true); + } + + + // aiMaterial + material_uids.clear(); + for (size_t i = 0; i < mScene->mNumMaterials; ++i) { + // it's all about this material + aiMaterial* m = mScene->mMaterials[i]; + + // these are used to receive material data + float f; aiColor3D c; + + // start the node record + FBX::Node n("Material"); + + int64_t uid = generate_uid(); + material_uids.push_back(uid); + n.AddProperty(uid); + + aiString name; + m->Get(AI_MATKEY_NAME, name); + n.AddProperty(name.C_Str() + FBX::SEPARATOR + "Material"); + + n.AddProperty(""); + + n.AddChild("Version", int32_t(102)); + f = 0; + m->Get(AI_MATKEY_SHININESS, f); + bool phong = (f > 0); + if (phong) { + n.AddChild("ShadingModel", "phong"); + } else { + n.AddChild("ShadingModel", "lambert"); + } + n.AddChild("MultiLayer", int32_t(0)); + + FBX::Node p("Properties70"); + + // materials exported using the FBX SDK have two sets of fields. + // there are the properties specified in the PropertyTemplate, + // which are those supported by the modernFBX SDK, + // and an extra set of properties with simpler names. + // The extra properties are a legacy material system from pre-2009. + // + // In the modern system, each property has "color" and "factor". + // Generally the interpretation of these seems to be + // that the colour is multiplied by the factor before use, + // but this is not always clear-cut. + // + // Usually assimp only stores the colour, + // so we can just leave the factors at the default "1.0". + + // first we can export the "standard" properties + if (m->Get(AI_MATKEY_COLOR_AMBIENT, c) == aiReturn_SUCCESS) { + p.AddP70colorA("AmbientColor", c.r, c.g, c.b); + //p.AddP70numberA("AmbientFactor", 1.0); + } + if (m->Get(AI_MATKEY_COLOR_DIFFUSE, c) == aiReturn_SUCCESS) { + p.AddP70colorA("DiffuseColor", c.r, c.g, c.b); + //p.AddP70numberA("DiffuseFactor", 1.0); + } + if (m->Get(AI_MATKEY_COLOR_TRANSPARENT, c) == aiReturn_SUCCESS) { + // "TransparentColor" / "TransparencyFactor"... + // thanks FBX, for your insightful interpretation of consistency + p.AddP70colorA("TransparentColor", c.r, c.g, c.b); + // TransparencyFactor defaults to 0.0, so set it to 1.0. + // note: Maya always sets this to 1.0, + // so we can't use it sensibly as "Opacity". + // In stead we rely on the legacy "Opacity" value, below. + // Blender also relies on "Opacity" not "TransparencyFactor", + // probably for a similar reason. + p.AddP70numberA("TransparencyFactor", 1.0); + } + if (m->Get(AI_MATKEY_COLOR_REFLECTIVE, c) == aiReturn_SUCCESS) { + p.AddP70colorA("ReflectionColor", c.r, c.g, c.b); + } + if (m->Get(AI_MATKEY_REFLECTIVITY, f) == aiReturn_SUCCESS) { + p.AddP70numberA("ReflectionFactor", f); + } + if (phong) { + if (m->Get(AI_MATKEY_COLOR_SPECULAR, c) == aiReturn_SUCCESS) { + p.AddP70colorA("SpecularColor", c.r, c.g, c.b); + } + if (m->Get(AI_MATKEY_SHININESS_STRENGTH, f) == aiReturn_SUCCESS) { + p.AddP70numberA("ShininessFactor", f); + } + if (m->Get(AI_MATKEY_SHININESS, f) == aiReturn_SUCCESS) { + p.AddP70numberA("ShininessExponent", f); + } + if (m->Get(AI_MATKEY_REFLECTIVITY, f) == aiReturn_SUCCESS) { + p.AddP70numberA("ReflectionFactor", f); + } + } + + // Now the legacy system. + // For safety let's include it. + // thrse values don't exist in the property template, + // and usually are completely ignored when loading. + // One notable exception is the "Opacity" property, + // which Blender uses as (1.0 - alpha). + c.r = 0.0f; c.g = 0.0f; c.b = 0.0f; + m->Get(AI_MATKEY_COLOR_EMISSIVE, c); + p.AddP70vector("Emissive", c.r, c.g, c.b); + c.r = 0.2f; c.g = 0.2f; c.b = 0.2f; + m->Get(AI_MATKEY_COLOR_AMBIENT, c); + p.AddP70vector("Ambient", c.r, c.g, c.b); + c.r = 0.8f; c.g = 0.8f; c.b = 0.8f; + m->Get(AI_MATKEY_COLOR_DIFFUSE, c); + p.AddP70vector("Diffuse", c.r, c.g, c.b); + // The FBX SDK determines "Opacity" from transparency colour (RGB) + // and factor (F) as: O = (1.0 - F * ((R + G + B) / 3)). + // However we actually have an opacity value, + // so we should take it from AI_MATKEY_OPACITY if possible. + // It might make more sense to use TransparencyFactor, + // but Blender actually loads "Opacity" correctly, so let's use it. + f = 1.0f; + if (m->Get(AI_MATKEY_COLOR_TRANSPARENT, c) == aiReturn_SUCCESS) { + f = 1.0f - ((c.r + c.g + c.b) / 3.0f); + } + m->Get(AI_MATKEY_OPACITY, f); + p.AddP70double("Opacity", f); + if (phong) { + // specular color is multiplied by shininess_strength + c.r = 0.2f; c.g = 0.2f; c.b = 0.2f; + m->Get(AI_MATKEY_COLOR_SPECULAR, c); + f = 1.0f; + m->Get(AI_MATKEY_SHININESS_STRENGTH, f); + p.AddP70vector("Specular", f*c.r, f*c.g, f*c.b); + f = 20.0f; + m->Get(AI_MATKEY_SHININESS, f); + p.AddP70double("Shininess", f); + // Legacy "Reflectivity" is F*F*((R+G+B)/3), + // where F is the proportion of light reflected (AKA reflectivity), + // and RGB is the reflective colour of the material. + // No idea why, but we might as well set it the same way. + f = 0.0f; + m->Get(AI_MATKEY_REFLECTIVITY, f); + c.r = 1.0f, c.g = 1.0f, c.b = 1.0f; + m->Get(AI_MATKEY_COLOR_REFLECTIVE, c); + p.AddP70double("Reflectivity", f*f*((c.r+c.g+c.b)/3.0)); + } + + n.AddChild(p); + + n.Dump(outstream, binary, indent); + } + + // we need to look up all the images we're using, + // so we can generate uids, and eliminate duplicates. + std::map<std::string, int64_t> uid_by_image; + for (size_t i = 0; i < mScene->mNumMaterials; ++i) { + aiString texpath; + aiMaterial* mat = mScene->mMaterials[i]; + for ( + size_t tt = aiTextureType_DIFFUSE; + tt < aiTextureType_UNKNOWN; + ++tt + ){ + const aiTextureType textype = static_cast<aiTextureType>(tt); + const size_t texcount = mat->GetTextureCount(textype); + for (size_t j = 0; j < texcount; ++j) { + mat->GetTexture(textype, (unsigned int)j, &texpath); + const std::string texstring = texpath.C_Str(); + auto elem = uid_by_image.find(texstring); + if (elem == uid_by_image.end()) { + uid_by_image[texstring] = generate_uid(); + } + } + } + } + + // FbxVideo - stores images used by textures. + for (const auto &it : uid_by_image) { + FBX::Node n("Video"); + const int64_t& uid = it.second; + const std::string name = ""; // TODO: ... name??? + n.AddProperties(uid, name + FBX::SEPARATOR + "Video", "Clip"); + n.AddChild("Type", "Clip"); + FBX::Node p("Properties70"); + // TODO: get full path... relative path... etc... ugh... + // for now just use the same path for everything, + // and hopefully one of them will work out. + std::string path = it.first; + // try get embedded texture + const aiTexture* embedded_texture = mScene->GetEmbeddedTexture(it.first.c_str()); + if (embedded_texture != nullptr) { + // change the path (use original filename, if available. If name is empty, concatenate texture index with file extension) + std::stringstream newPath; + if (embedded_texture->mFilename.length > 0) { + newPath << embedded_texture->mFilename.C_Str(); + } else if (embedded_texture->achFormatHint[0]) { + int texture_index = std::stoi(path.substr(1, path.size() - 1)); + newPath << texture_index << "." << embedded_texture->achFormatHint; + } + path = newPath.str(); + // embed the texture + size_t texture_size = static_cast<size_t>(embedded_texture->mWidth * std::max(embedded_texture->mHeight, 1u)); + if (binary) { + // embed texture as binary data + std::vector<uint8_t> tex_data; + tex_data.resize(texture_size); + memcpy(&tex_data[0], (char*)embedded_texture->pcData, texture_size); + n.AddChild("Content", tex_data); + } else { + // embed texture in base64 encoding + std::string encoded_texture = FBX::Util::EncodeBase64((char*)embedded_texture->pcData, texture_size); + n.AddChild("Content", encoded_texture); + } + } + p.AddP70("Path", "KString", "XRefUrl", "", path); + n.AddChild(p); + n.AddChild("UseMipMap", int32_t(0)); + n.AddChild("Filename", path); + n.AddChild("RelativeFilename", path); + n.Dump(outstream, binary, indent); + } + + // Textures + // referenced by material_index/texture_type pairs. + std::map<std::pair<size_t,size_t>,int64_t> texture_uids; + const std::map<aiTextureType,std::string> prop_name_by_tt = { + {aiTextureType_DIFFUSE, "DiffuseColor"}, + {aiTextureType_SPECULAR, "SpecularColor"}, + {aiTextureType_AMBIENT, "AmbientColor"}, + {aiTextureType_EMISSIVE, "EmissiveColor"}, + {aiTextureType_HEIGHT, "Bump"}, + {aiTextureType_NORMALS, "NormalMap"}, + {aiTextureType_SHININESS, "ShininessExponent"}, + {aiTextureType_OPACITY, "TransparentColor"}, + {aiTextureType_DISPLACEMENT, "DisplacementColor"}, + //{aiTextureType_LIGHTMAP, "???"}, + {aiTextureType_REFLECTION, "ReflectionColor"} + //{aiTextureType_UNKNOWN, ""} + }; + for (size_t i = 0; i < mScene->mNumMaterials; ++i) { + // textures are attached to materials + aiMaterial* mat = mScene->mMaterials[i]; + int64_t material_uid = material_uids[i]; + + for ( + size_t j = aiTextureType_DIFFUSE; + j < aiTextureType_UNKNOWN; + ++j + ) { + const aiTextureType tt = static_cast<aiTextureType>(j); + size_t n = mat->GetTextureCount(tt); + + if (n < 1) { // no texture of this type + continue; + } + + if (n > 1) { + // TODO: multilayer textures + std::stringstream err; + err << "Multilayer textures not supported (for now),"; + err << " skipping texture type " << j; + err << " of material " << i; + ASSIMP_LOG_WARN(err.str()); + } + + // get image path for this (single-image) texture + aiString tpath; + if (mat->GetTexture(tt, 0, &tpath) != aiReturn_SUCCESS) { + std::stringstream err; + err << "Failed to get texture 0 for texture of type " << tt; + err << " on material " << i; + err << ", however GetTextureCount returned 1."; + throw DeadlyExportError(err.str()); + } + const std::string texture_path(tpath.C_Str()); + + // get connected image uid + auto elem = uid_by_image.find(texture_path); + if (elem == uid_by_image.end()) { + // this should never happen + std::stringstream err; + err << "Failed to find video element for texture with path"; + err << " \"" << texture_path << "\""; + err << ", type " << j << ", material " << i; + throw DeadlyExportError(err.str()); + } + const int64_t image_uid = elem->second; + + // get the name of the material property to connect to + auto elem2 = prop_name_by_tt.find(tt); + if (elem2 == prop_name_by_tt.end()) { + // don't know how to handle this type of texture, + // so skip it. + std::stringstream err; + err << "Not sure how to handle texture of type " << j; + err << " on material " << i; + err << ", skipping..."; + ASSIMP_LOG_WARN(err.str()); + continue; + } + const std::string& prop_name = elem2->second; + + // generate a uid for this texture + const int64_t texture_uid = generate_uid(); + + // link the texture to the material + connections.emplace_back( + "C", "OP", texture_uid, material_uid, prop_name + ); + + // link the image data to the texture + connections.emplace_back("C", "OO", image_uid, texture_uid); + + aiUVTransform trafo; + unsigned int max = sizeof(aiUVTransform); + aiGetMaterialFloatArray(mat, AI_MATKEY_UVTRANSFORM(aiTextureType_DIFFUSE, 0), (ai_real *)&trafo, &max); + + // now write the actual texture node + FBX::Node tnode("Texture"); + // TODO: some way to determine texture name? + const std::string texture_name = "" + FBX::SEPARATOR + "Texture"; + tnode.AddProperties(texture_uid, texture_name, ""); + // there really doesn't seem to be a better type than this: + tnode.AddChild("Type", "TextureVideoClip"); + tnode.AddChild("Version", int32_t(202)); + tnode.AddChild("TextureName", texture_name); + FBX::Node p("Properties70"); + p.AddP70vectorA("Translation", trafo.mTranslation[0], trafo.mTranslation[1], 0.0); + p.AddP70vectorA("Rotation", 0, 0, trafo.mRotation); + p.AddP70vectorA("Scaling", trafo.mScaling[0], trafo.mScaling[1], 0.0); + p.AddP70enum("CurrentTextureBlendMode", 0); // TODO: verify + //p.AddP70string("UVSet", ""); // TODO: how should this work? + p.AddP70bool("UseMaterial", 1); + tnode.AddChild(p); + // can't easily determine which texture path will be correct, + // so just store what we have in every field. + // these being incorrect is a common problem with FBX anyway. + tnode.AddChild("FileName", texture_path); + tnode.AddChild("RelativeFilename", texture_path); + tnode.AddChild("ModelUVTranslation", double(0.0), double(0.0)); + tnode.AddChild("ModelUVScaling", double(1.0), double(1.0)); + tnode.AddChild("Texture_Alpha_Source", "None"); + tnode.AddChild( + "Cropping", int32_t(0), int32_t(0), int32_t(0), int32_t(0) + ); + tnode.Dump(outstream, binary, indent); + } + } + + // Blendshapes, if any + for (size_t mi = 0; mi < mScene->mNumMeshes; ++mi) { + const aiMesh* m = mScene->mMeshes[mi]; + if (m->mNumAnimMeshes == 0) { + continue; + } + // make a deformer for this mesh + int64_t deformer_uid = generate_uid(); + FBX::Node dnode("Deformer"); + dnode.AddProperties(deformer_uid, m->mName.data + FBX::SEPARATOR + "Blendshapes", "BlendShape"); + dnode.AddChild("Version", int32_t(101)); + dnode.Dump(outstream, binary, indent); + // connect it + connections.emplace_back("C", "OO", deformer_uid, mesh_uids[mi]); + std::vector<int32_t> vertex_indices = vVertexIndice[mi]; + + for (unsigned int am = 0; am < m->mNumAnimMeshes; ++am) { + aiAnimMesh *pAnimMesh = m->mAnimMeshes[am]; + std::string blendshape_name = pAnimMesh->mName.data; + + // start the node record + FBX::Node bsnode("Geometry"); + int64_t blendshape_uid = generate_uid(); + mesh_uids.push_back(blendshape_uid); + bsnode.AddProperty(blendshape_uid); + bsnode.AddProperty(blendshape_name + FBX::SEPARATOR + "Blendshape"); + bsnode.AddProperty("Shape"); + bsnode.AddChild("Version", int32_t(100)); + bsnode.Begin(outstream, binary, indent); + bsnode.DumpProperties(outstream, binary, indent); + bsnode.EndProperties(outstream, binary, indent); + bsnode.BeginChildren(outstream, binary, indent); + indent++; + if (pAnimMesh->HasPositions()) { + std::vector<int32_t>shape_indices; + std::vector<double>pPositionDiff; + std::vector<double>pNormalDiff; + + for (unsigned int vt = 0; vt < vertex_indices.size(); ++vt) { + aiVector3D pDiff = (pAnimMesh->mVertices[vertex_indices[vt]] - m->mVertices[vertex_indices[vt]]); + if(pDiff.Length()>1e-8){ + shape_indices.push_back(vertex_indices[vt]); + pPositionDiff.push_back(pDiff[0]); + pPositionDiff.push_back(pDiff[1]); + pPositionDiff.push_back(pDiff[2]); + + if (pAnimMesh->HasNormals()) { + aiVector3D nDiff = (pAnimMesh->mNormals[vertex_indices[vt]] - m->mNormals[vertex_indices[vt]]); + pNormalDiff.push_back(nDiff[0]); + pNormalDiff.push_back(nDiff[1]); + pNormalDiff.push_back(nDiff[2]); + } + } + } + + FBX::Node::WritePropertyNode( + "Indexes", shape_indices, outstream, binary, indent + ); + + FBX::Node::WritePropertyNode( + "Vertices", pPositionDiff, outstream, binary, indent + ); + + if (pNormalDiff.size()>0) { + FBX::Node::WritePropertyNode( + "Normals", pNormalDiff, outstream, binary, indent + ); + } + } + indent--; + bsnode.End(outstream, binary, indent, true); + + // Add blendshape Channel Deformer + FBX::Node sdnode("Deformer"); + const int64_t blendchannel_uid = generate_uid(); + sdnode.AddProperties( + blendchannel_uid, blendshape_name + FBX::SEPARATOR + "SubDeformer", "BlendShapeChannel" + ); + sdnode.AddChild("Version", int32_t(100)); + sdnode.AddChild("DeformPercent", float(0.0)); + FBX::Node p("Properties70"); + p.AddP70numberA("DeformPercent", 0.0); + sdnode.AddChild(p); + // TODO: Normally just one weight per channel, adding stub for later development + std::vector<float>fFullWeights; + fFullWeights.push_back(100.); + sdnode.AddChild("FullWeights", fFullWeights); + sdnode.Dump(outstream, binary, indent); + + connections.emplace_back("C", "OO", blendchannel_uid, deformer_uid); + connections.emplace_back("C", "OO", blendshape_uid, blendchannel_uid); + } + } + + // bones. + // + // output structure: + // subset of node hierarchy that are "skeleton", + // i.e. do not have meshes but only bones. + // but.. i'm not sure how anyone could guarantee that... + // + // input... + // well, for each mesh it has "bones", + // and the bone names correspond to nodes. + // of course we also need the parent nodes, + // as they give some of the transform........ + // + // well. we can assume a sane input, i suppose. + // + // so input is the bone node hierarchy, + // with an extra thing for the transformation of the MESH in BONE space. + // + // output is a set of bone nodes, + // a "bindpose" which indicates the default local transform of all bones, + // and a set of "deformers". + // each deformer is parented to a mesh geometry, + // and has one or more "subdeformer"s as children. + // each subdeformer has one bone node as a child, + // and represents the influence of that bone on the grandparent mesh. + // the subdeformer has a list of indices, and weights, + // with indices specifying vertex indices, + // and weights specifying the corresponding influence of this bone. + // it also has Transform and TransformLink elements, + // specifying the transform of the MESH in BONE space, + // and the transformation of the BONE in WORLD space, + // likely in the bindpose. + // + // the input bone structure is different but similar, + // storing the number of weights for this bone, + // and an array of (vertex index, weight) pairs. + // + // one sticky point is that the number of vertices may not match, + // because assimp splits vertices by normal, uv, etc. + + // functor for aiNode sorting + struct SortNodeByName + { + bool operator()(const aiNode *lhs, const aiNode *rhs) const + { + return strcmp(lhs->mName.C_Str(), rhs->mName.C_Str()) < 0; + } + }; + + // first we should mark the skeleton for each mesh. + // the skeleton must include not only the aiBones, + // but also all their parent nodes. + // anything that affects the position of any bone node must be included. + // Use SorNodeByName to make sure the exported result will be the same across all systems + // Otherwise the aiNodes of the skeleton would be sorted based on the pointer address, which isn't consistent + std::vector<std::set<const aiNode*, SortNodeByName>> skeleton_by_mesh(mScene->mNumMeshes); + // at the same time we can build a list of all the skeleton nodes, + // which will be used later to mark them as type "limbNode". + std::unordered_set<const aiNode*> limbnodes; + + //actual bone nodes in fbx, without parenting-up + std::unordered_set<std::string> setAllBoneNamesInScene; + for(unsigned int m = 0; m < mScene->mNumMeshes; ++ m) + { + aiMesh* pMesh = mScene->mMeshes[m]; + for(unsigned int b = 0; b < pMesh->mNumBones; ++ b) + setAllBoneNamesInScene.insert(pMesh->mBones[b]->mName.data); + } + aiMatrix4x4 mxTransIdentity; + + // and a map of nodes by bone name, as finding them is annoying. + std::map<std::string,aiNode*> node_by_bone; + for (size_t mi = 0; mi < mScene->mNumMeshes; ++mi) { + const aiMesh* m = mScene->mMeshes[mi]; + std::set<const aiNode*, SortNodeByName> skeleton; + for (size_t bi =0; bi < m->mNumBones; ++bi) { + const aiBone* b = m->mBones[bi]; + const std::string name(b->mName.C_Str()); + auto elem = node_by_bone.find(name); + aiNode* n; + if (elem != node_by_bone.end()) { + n = elem->second; + } else { + n = mScene->mRootNode->FindNode(b->mName); + if (!n) { + // this should never happen + std::stringstream err; + err << "Failed to find node for bone: \"" << name << "\""; + throw DeadlyExportError(err.str()); + } + node_by_bone[name] = n; + limbnodes.insert(n); + } + skeleton.insert(n); + // mark all parent nodes as skeleton as well, + // up until we find the root node, + // or else the node containing the mesh, + // or else the parent of a node containing the mesh. + for ( + const aiNode* parent = n->mParent; + parent && parent != mScene->mRootNode; + parent = parent->mParent + ) { + // if we've already done this node we can skip it all + if (skeleton.count(parent)) { + break; + } + // ignore fbx transform nodes as these will be collapsed later + // TODO: cache this by aiNode* + const std::string node_name(parent->mName.C_Str()); + if (node_name.find(MAGIC_NODE_TAG) != std::string::npos) { + continue; + } + //not a bone in scene && no effect in transform + if(setAllBoneNamesInScene.find(node_name)==setAllBoneNamesInScene.end() + && parent->mTransformation == mxTransIdentity) { + continue; + } + // otherwise check if this is the root of the skeleton + bool end = false; + // is the mesh part of this node? + for (size_t i = 0; i < parent->mNumMeshes; ++i) { + if (parent->mMeshes[i] == mi) { + end = true; + break; + } + } + // is the mesh in one of the children of this node? + for (size_t j = 0; j < parent->mNumChildren; ++j) { + aiNode* child = parent->mChildren[j]; + for (size_t i = 0; i < child->mNumMeshes; ++i) { + if (child->mMeshes[i] == mi) { + end = true; + break; + } + } + if (end) { break; } + } + + // if it was the skeleton root we can finish here + if (end) { break; } + } + } + skeleton_by_mesh[mi] = skeleton; + } + + // we'll need the uids for the bone nodes, so generate them now + for (size_t i = 0; i < mScene->mNumMeshes; ++i) { + auto &s = skeleton_by_mesh[i]; + for (const aiNode* n : s) { + auto elem = node_uids.find(n); + if (elem == node_uids.end()) { + node_uids[n] = generate_uid(); + } + } + } + + // now, for each aiMesh, we need to export a deformer, + // and for each aiBone a subdeformer, + // which should have all the skinning info. + // these will need to be connected properly to the mesh, + // and we can do that all now. + for (size_t mi = 0; mi < mScene->mNumMeshes; ++mi) { + const aiMesh* m = mScene->mMeshes[mi]; + if (!m->HasBones()) { + continue; + } + // make a deformer for this mesh + int64_t deformer_uid = generate_uid(); + FBX::Node dnode("Deformer"); + dnode.AddProperties(deformer_uid, FBX::SEPARATOR + "Deformer", "Skin"); + dnode.AddChild("Version", int32_t(101)); + // "acuracy"... this is not a typo.... + dnode.AddChild("Link_DeformAcuracy", double(50)); + dnode.AddChild("SkinningType", "Linear"); // TODO: other modes? + dnode.Dump(outstream, binary, indent); + + // connect it + connections.emplace_back("C", "OO", deformer_uid, mesh_uids[mi]); + + //computed before + std::vector<int32_t>& vertex_indices = vVertexIndice[mi]; + + // TODO, FIXME: this won't work if anything is not in the bind pose. + // for now if such a situation is detected, we throw an exception. + std::set<const aiBone*> not_in_bind_pose; + std::set<const aiNode*> no_offset_matrix; + + // first get this mesh's position in world space, + // as we'll need it for each subdeformer. + // + // ...of course taking the position of the MESH doesn't make sense, + // as it can be instanced to many nodes. + // All we can do is assume no instancing, + // and take the first node we find that contains the mesh. + aiNode* mesh_node = get_node_for_mesh((unsigned int)mi, mScene->mRootNode); + aiMatrix4x4 mesh_xform = get_world_transform(mesh_node, mScene); + + // now make a subdeformer for each bone in the skeleton + const std::set<const aiNode*, SortNodeByName> skeleton= skeleton_by_mesh[mi]; + for (const aiNode* bone_node : skeleton) { + // if there's a bone for this node, find it + const aiBone* b = nullptr; + for (size_t bi = 0; bi < m->mNumBones; ++bi) { + // TODO: this probably should index by something else + const std::string name(m->mBones[bi]->mName.C_Str()); + if (node_by_bone[name] == bone_node) { + b = m->mBones[bi]; + break; + } + } + if (!b) { + no_offset_matrix.insert(bone_node); + } + + // start the subdeformer node + const int64_t subdeformer_uid = generate_uid(); + FBX::Node sdnode("Deformer"); + sdnode.AddProperties( + subdeformer_uid, FBX::SEPARATOR + "SubDeformer", "Cluster" + ); + sdnode.AddChild("Version", int32_t(100)); + sdnode.AddChild("UserData", "", ""); + + std::set<int32_t> setWeightedVertex; + // add indices and weights, if any + if (b) { + std::vector<int32_t> subdef_indices; + std::vector<double> subdef_weights; + int32_t last_index = -1; + for (size_t wi = 0; wi < b->mNumWeights; ++wi) { + int32_t vi = vertex_indices[b->mWeights[wi].mVertexId]; + bool bIsWeightedAlready = (setWeightedVertex.find(vi) != setWeightedVertex.end()); + if (vi == last_index || bIsWeightedAlready) { + // only for vertices we exported to fbx + // TODO, FIXME: this assumes identically-located vertices + // will always deform in the same way. + // as assimp doesn't store a separate list of "positions", + // there's not much that can be done about this + // other than assuming that identical position means + // identical vertex. + continue; + } + setWeightedVertex.insert(vi); + subdef_indices.push_back(vi); + subdef_weights.push_back(b->mWeights[wi].mWeight); + last_index = vi; + } + // yes, "indexes" + sdnode.AddChild("Indexes", subdef_indices); + sdnode.AddChild("Weights", subdef_weights); + } + + // transform is the transform of the mesh, but in bone space. + // if the skeleton is in the bind pose, + // we can take the inverse of the world-space bone transform + // and multiply by the world-space transform of the mesh. + aiMatrix4x4 bone_xform = get_world_transform(bone_node, mScene); + aiMatrix4x4 inverse_bone_xform = bone_xform; + inverse_bone_xform.Inverse(); + aiMatrix4x4 tr = inverse_bone_xform * mesh_xform; + + sdnode.AddChild("Transform", tr); + + + sdnode.AddChild("TransformLink", bone_xform); + // note: this means we ALWAYS rely on the mesh node transform + // being unchanged from the time the skeleton was bound. + // there's not really any way around this at the moment. + + // done + sdnode.Dump(outstream, binary, indent); + + // lastly, connect to the parent deformer + connections.emplace_back( + "C", "OO", subdeformer_uid, deformer_uid + ); + + // we also need to connect the limb node to the subdeformer. + connections.emplace_back( + "C", "OO", node_uids[bone_node], subdeformer_uid + ); + } + + // if we cannot create a valid FBX file, simply die. + // this will both prevent unnecessary bug reports, + // and tell the user what they can do to fix the situation + // (i.e. export their model in the bind pose). + if (no_offset_matrix.size() && not_in_bind_pose.size()) { + std::stringstream err; + err << "Not enough information to construct bind pose"; + err << " for mesh " << mi << "!"; + err << " Transform matrix for bone \""; + err << (*not_in_bind_pose.begin())->mName.C_Str() << "\""; + if (not_in_bind_pose.size() > 1) { + err << " (and " << not_in_bind_pose.size() - 1 << " more)"; + } + err << " does not match mOffsetMatrix,"; + err << " and node \""; + err << (*no_offset_matrix.begin())->mName.C_Str() << "\""; + if (no_offset_matrix.size() > 1) { + err << " (and " << no_offset_matrix.size() - 1 << " more)"; + } + err << " has no offset matrix to rely on."; + err << " Please ensure bones are in the bind pose to export."; + throw DeadlyExportError(err.str()); + } + + } + + // BindPose + // + // This is a legacy system, which should be unnecessary. + // + // Somehow including it slows file loading by the official FBX SDK, + // and as it can reconstruct it from the deformers anyway, + // this is not currently included. + // + // The code is kept here in case it's useful in the future, + // but it's pretty much a hack anyway, + // as assimp doesn't store bindpose information for full skeletons. + // + /*for (size_t mi = 0; mi < mScene->mNumMeshes; ++mi) { + aiMesh* mesh = mScene->mMeshes[mi]; + if (! mesh->HasBones()) { continue; } + int64_t bindpose_uid = generate_uid(); + FBX::Node bpnode("Pose"); + bpnode.AddProperty(bindpose_uid); + // note: this uid is never linked or connected to anything. + bpnode.AddProperty(FBX::SEPARATOR + "Pose"); // blank name + bpnode.AddProperty("BindPose"); + + bpnode.AddChild("Type", "BindPose"); + bpnode.AddChild("Version", int32_t(100)); + + aiNode* mesh_node = get_node_for_mesh(mi, mScene->mRootNode); + + // next get the whole skeleton for this mesh. + // we need it all to define the bindpose section. + // the FBX SDK will complain if it's missing, + // and also if parents of used bones don't have a subdeformer. + // order shouldn't matter. + std::set<aiNode*> skeleton; + for (size_t bi = 0; bi < mesh->mNumBones; ++bi) { + // bone node should have already been indexed + const aiBone* b = mesh->mBones[bi]; + const std::string bone_name(b->mName.C_Str()); + aiNode* parent = node_by_bone[bone_name]; + // insert all nodes down to the root or mesh node + while ( + parent + && parent != mScene->mRootNode + && parent != mesh_node + ) { + skeleton.insert(parent); + parent = parent->mParent; + } + } + + // number of pose nodes. includes one for the mesh itself. + bpnode.AddChild("NbPoseNodes", int32_t(1 + skeleton.size())); + + // the first pose node is always the mesh itself + FBX::Node pose("PoseNode"); + pose.AddChild("Node", mesh_uids[mi]); + aiMatrix4x4 mesh_node_xform = get_world_transform(mesh_node, mScene); + pose.AddChild("Matrix", mesh_node_xform); + bpnode.AddChild(pose); + + for (aiNode* bonenode : skeleton) { + // does this node have a uid yet? + int64_t node_uid; + auto node_uid_iter = node_uids.find(bonenode); + if (node_uid_iter != node_uids.end()) { + node_uid = node_uid_iter->second; + } else { + node_uid = generate_uid(); + node_uids[bonenode] = node_uid; + } + + // make a pose thingy + pose = FBX::Node("PoseNode"); + pose.AddChild("Node", node_uid); + aiMatrix4x4 node_xform = get_world_transform(bonenode, mScene); + pose.AddChild("Matrix", node_xform); + bpnode.AddChild(pose); + } + + // now write it + bpnode.Dump(outstream, binary, indent); + }*/ + + // lights + indent = 1; + lights_uids.clear(); + for (size_t li = 0; li < mScene->mNumLights; ++li) { + aiLight* l = mScene->mLights[li]; + + int64_t uid = generate_uid(); + const std::string lightNodeAttributeName = l->mName.C_Str() + FBX::SEPARATOR + "NodeAttribute"; + + FBX::Node lna("NodeAttribute"); + lna.AddProperties(uid, lightNodeAttributeName, "Light"); + FBX::Node lnap("Properties70"); + + // Light color. + lnap.AddP70colorA("Color", l->mColorDiffuse.r, l->mColorDiffuse.g, l->mColorDiffuse.b); + + // TODO Assimp light description is quite concise and do not handle light intensity. + // Default value to 1000W. + lnap.AddP70numberA("Intensity", 1000); + + // FBXLight::EType conversion + switch (l->mType) { + case aiLightSource_POINT: + lnap.AddP70enum("LightType", 0); + break; + case aiLightSource_DIRECTIONAL: + lnap.AddP70enum("LightType", 1); + break; + case aiLightSource_SPOT: + lnap.AddP70enum("LightType", 2); + lnap.AddP70numberA("InnerAngle", AI_RAD_TO_DEG(l->mAngleInnerCone)); + lnap.AddP70numberA("OuterAngle", AI_RAD_TO_DEG(l->mAngleOuterCone)); + break; + // TODO Assimp do not handle 'area' nor 'volume' lights, but FBX does. + /*case aiLightSource_AREA: + lnap.AddP70enum("LightType", 3); + lnap.AddP70enum("AreaLightShape", 0); // 0=Rectangle, 1=Sphere + break; + case aiLightSource_VOLUME: + lnap.AddP70enum("LightType", 4); + break;*/ + default: + break; + } + + // Did not understood how to configure the decay so disabling attenuation. + lnap.AddP70enum("DecayType", 0); + + // Dump to FBX stream + lna.AddChild(lnap); + lna.AddChild("TypeFlags", FBX::FBXExportProperty("Light")); + lna.AddChild("GeometryVersion", FBX::FBXExportProperty(int32_t(124))); + lna.Dump(outstream, binary, indent); + + // Store name and uid (will be used later when parsing scene nodes) + lights_uids[l->mName.C_Str()] = uid; + } + + // TODO: cameras + + // write nodes (i.e. model hierarchy) + // start at root node + WriteModelNodes( + outstream, mScene->mRootNode, 0, limbnodes + ); + + // animations + // + // in FBX there are: + // * AnimationStack - corresponds to an aiAnimation + // * AnimationLayer - a combinable animation component + // * AnimationCurveNode - links the property to be animated + // * AnimationCurve - defines animation data for a single property value + // + // the CurveNode also provides the default value for a property, + // such as the X, Y, Z coordinates for animatable translation. + // + // the Curve only specifies values for one component of the property, + // so there will be a separate AnimationCurve for X, Y, and Z. + // + // Assimp has: + // * aiAnimation - basically corresponds to an AnimationStack + // * aiNodeAnim - defines all animation for one aiNode + // * aiVectorKey/aiQuatKey - define the keyframe data for T/R/S + // + // assimp has no equivalent for AnimationLayer, + // and these are flattened on FBX import. + // we can assume there will be one per AnimationStack. + // + // the aiNodeAnim contains all animation data for a single aiNode, + // which will correspond to three AnimationCurveNode's: + // one each for translation, rotation and scale. + // The data for each of these will be put in 9 AnimationCurve's, + // T.X, T.Y, T.Z, R.X, R.Y, R.Z, etc. + + // AnimationStack / aiAnimation + std::vector<int64_t> animation_stack_uids(mScene->mNumAnimations); + for (size_t ai = 0; ai < mScene->mNumAnimations; ++ai) { + int64_t animstack_uid = generate_uid(); + animation_stack_uids[ai] = animstack_uid; + const aiAnimation* anim = mScene->mAnimations[ai]; + + FBX::Node asnode("AnimationStack"); + std::string name = anim->mName.C_Str() + FBX::SEPARATOR + "AnimStack"; + asnode.AddProperties(animstack_uid, name, ""); + FBX::Node p("Properties70"); + p.AddP70time("LocalStart", 0); // assimp doesn't store this + p.AddP70time("LocalStop", to_ktime(anim->mDuration, anim)); + p.AddP70time("ReferenceStart", 0); + p.AddP70time("ReferenceStop", to_ktime(anim->mDuration, anim)); + asnode.AddChild(p); + + // this node absurdly always pretends it has children + // (in this case it does, but just in case...) + asnode.force_has_children = true; + asnode.Dump(outstream, binary, indent); + + // note: animation stacks are not connected to anything + } + + // AnimationLayer - one per aiAnimation + std::vector<int64_t> animation_layer_uids(mScene->mNumAnimations); + for (size_t ai = 0; ai < mScene->mNumAnimations; ++ai) { + int64_t animlayer_uid = generate_uid(); + animation_layer_uids[ai] = animlayer_uid; + FBX::Node alnode("AnimationLayer"); + alnode.AddProperties(animlayer_uid, FBX::SEPARATOR + "AnimLayer", ""); + + // this node absurdly always pretends it has children + alnode.force_has_children = true; + alnode.Dump(outstream, binary, indent); + + // connect to the relevant animstack + connections.emplace_back( + "C", "OO", animlayer_uid, animation_stack_uids[ai] + ); + } + + // AnimCurveNode - three per aiNodeAnim + std::vector<std::vector<std::array<int64_t,3>>> curve_node_uids; + for (size_t ai = 0; ai < mScene->mNumAnimations; ++ai) { + const aiAnimation* anim = mScene->mAnimations[ai]; + const int64_t layer_uid = animation_layer_uids[ai]; + std::vector<std::array<int64_t,3>> nodeanim_uids; + for (size_t nai = 0; nai < anim->mNumChannels; ++nai) { + const aiNodeAnim* na = anim->mChannels[nai]; + // get the corresponding aiNode + const aiNode* node = mScene->mRootNode->FindNode(na->mNodeName); + // and its transform + const aiMatrix4x4 node_xfm = get_world_transform(node, mScene); + aiVector3D T, R, S; + node_xfm.Decompose(S, R, T); + + // AnimationCurveNode uids + std::array<int64_t,3> ids; + ids[0] = generate_uid(); // T + ids[1] = generate_uid(); // R + ids[2] = generate_uid(); // S + + // translation + WriteAnimationCurveNode(outstream, + ids[0], "T", T, "Lcl Translation", + layer_uid, node_uids[node] + ); + + // rotation + WriteAnimationCurveNode(outstream, + ids[1], "R", R, "Lcl Rotation", + layer_uid, node_uids[node] + ); + + // scale + WriteAnimationCurveNode(outstream, + ids[2], "S", S, "Lcl Scale", + layer_uid, node_uids[node] + ); + + // store the uids for later use + nodeanim_uids.push_back(ids); + } + curve_node_uids.push_back(nodeanim_uids); + } + + // AnimCurve - defines actual keyframe data. + // there's a separate curve for every component of every vector, + // for example a transform curvenode will have separate X/Y/Z AnimCurve's + for (size_t ai = 0; ai < mScene->mNumAnimations; ++ai) { + const aiAnimation* anim = mScene->mAnimations[ai]; + for (size_t nai = 0; nai < anim->mNumChannels; ++nai) { + const aiNodeAnim* na = anim->mChannels[nai]; + // get the corresponding aiNode + const aiNode* node = mScene->mRootNode->FindNode(na->mNodeName); + // and its transform + const aiMatrix4x4 node_xfm = get_world_transform(node, mScene); + aiVector3D T, R, S; + node_xfm.Decompose(S, R, T); + const std::array<int64_t,3>& ids = curve_node_uids[ai][nai]; + + std::vector<int64_t> times; + std::vector<float> xval, yval, zval; + + // position/translation + for (size_t ki = 0; ki < na->mNumPositionKeys; ++ki) { + const aiVectorKey& k = na->mPositionKeys[ki]; + times.push_back(to_ktime(k.mTime)); + xval.push_back(k.mValue.x); + yval.push_back(k.mValue.y); + zval.push_back(k.mValue.z); + } + // one curve each for X, Y, Z + WriteAnimationCurve(outstream, T.x, times, xval, ids[0], "d|X"); + WriteAnimationCurve(outstream, T.y, times, yval, ids[0], "d|Y"); + WriteAnimationCurve(outstream, T.z, times, zval, ids[0], "d|Z"); + + // rotation + times.clear(); xval.clear(); yval.clear(); zval.clear(); + for (size_t ki = 0; ki < na->mNumRotationKeys; ++ki) { + const aiQuatKey& k = na->mRotationKeys[ki]; + times.push_back(to_ktime(k.mTime)); + // TODO: aiQuaternion method to convert to Euler... + aiMatrix4x4 m(k.mValue.GetMatrix()); + aiVector3D qs, qr, qt; + m.Decompose(qs, qr, qt); + qr *= DEG; + xval.push_back(qr.x); + yval.push_back(qr.y); + zval.push_back(qr.z); + } + WriteAnimationCurve(outstream, R.x, times, xval, ids[1], "d|X"); + WriteAnimationCurve(outstream, R.y, times, yval, ids[1], "d|Y"); + WriteAnimationCurve(outstream, R.z, times, zval, ids[1], "d|Z"); + + // scaling/scale + times.clear(); xval.clear(); yval.clear(); zval.clear(); + for (size_t ki = 0; ki < na->mNumScalingKeys; ++ki) { + const aiVectorKey& k = na->mScalingKeys[ki]; + times.push_back(to_ktime(k.mTime)); + xval.push_back(k.mValue.x); + yval.push_back(k.mValue.y); + zval.push_back(k.mValue.z); + } + WriteAnimationCurve(outstream, S.x, times, xval, ids[2], "d|X"); + WriteAnimationCurve(outstream, S.y, times, yval, ids[2], "d|Y"); + WriteAnimationCurve(outstream, S.z, times, zval, ids[2], "d|Z"); + } + } + + indent = 0; + object_node.End(outstream, binary, indent, true); +} + +// convenience map of magic node name strings to FBX properties, +// including the expected type of transform. +const std::map<std::string,std::pair<std::string,char>> transform_types = { + {"Translation", {"Lcl Translation", 't'}}, + {"RotationOffset", {"RotationOffset", 't'}}, + {"RotationPivot", {"RotationPivot", 't'}}, + {"PreRotation", {"PreRotation", 'r'}}, + {"Rotation", {"Lcl Rotation", 'r'}}, + {"PostRotation", {"PostRotation", 'r'}}, + {"RotationPivotInverse", {"RotationPivotInverse", 'i'}}, + {"ScalingOffset", {"ScalingOffset", 't'}}, + {"ScalingPivot", {"ScalingPivot", 't'}}, + {"Scaling", {"Lcl Scaling", 's'}}, + {"ScalingPivotInverse", {"ScalingPivotInverse", 'i'}}, + {"GeometricScaling", {"GeometricScaling", 's'}}, + {"GeometricRotation", {"GeometricRotation", 'r'}}, + {"GeometricTranslation", {"GeometricTranslation", 't'}}, + {"GeometricTranslationInverse", {"GeometricTranslationInverse", 'i'}}, + {"GeometricRotationInverse", {"GeometricRotationInverse", 'i'}}, + {"GeometricScalingInverse", {"GeometricScalingInverse", 'i'}} +}; + +// write a single model node to the stream +void FBXExporter::WriteModelNode( + StreamWriterLE& outstream, + bool, + const aiNode* node, + int64_t node_uid, + const std::string& type, + const std::vector<std::pair<std::string,aiVector3D>>& transform_chain, + TransformInheritance inherit_type +){ + const aiVector3D zero = {0, 0, 0}; + const aiVector3D one = {1, 1, 1}; + FBX::Node m("Model"); + std::string name = node->mName.C_Str() + FBX::SEPARATOR + "Model"; + m.AddProperties(node_uid, name, type); + m.AddChild("Version", int32_t(232)); + FBX::Node p("Properties70"); + p.AddP70bool("RotationActive", 1); + p.AddP70int("DefaultAttributeIndex", 0); + p.AddP70enum("InheritType", inherit_type); + if (transform_chain.empty()) { + // decompose 4x4 transform matrix into TRS + aiVector3D t, r, s; + node->mTransformation.Decompose(s, r, t); + if (t != zero) { + p.AddP70( + "Lcl Translation", "Lcl Translation", "", "A", + double(t.x), double(t.y), double(t.z) + ); + } + if (r != zero) { + p.AddP70( + "Lcl Rotation", "Lcl Rotation", "", "A", + double(DEG*r.x), double(DEG*r.y), double(DEG*r.z) + ); + } + if (s != one) { + p.AddP70( + "Lcl Scaling", "Lcl Scaling", "", "A", + double(s.x), double(s.y), double(s.z) + ); + } + } else { + // apply the transformation chain. + // these transformation elements are created when importing FBX, + // which has a complex transformation hierarchy for each node. + // as such we can bake the hierarchy back into the node on export. + for (auto &item : transform_chain) { + auto elem = transform_types.find(item.first); + if (elem == transform_types.end()) { + // then this is a bug + std::stringstream err; + err << "unrecognized FBX transformation type: "; + err << item.first; + throw DeadlyExportError(err.str()); + } + const std::string &cur_name = elem->second.first; + const aiVector3D &v = item.second; + if (cur_name.compare(0, 4, "Lcl ") == 0) { + // special handling for animatable properties + p.AddP70( cur_name, cur_name, "", "A", double(v.x), double(v.y), double(v.z) ); + } else { + p.AddP70vector(cur_name, v.x, v.y, v.z); + } + } + } + m.AddChild(p); + + // not sure what these are for, + // but they seem to be omnipresent + m.AddChild("Shading", FBXExportProperty(true)); + m.AddChild("Culling", FBXExportProperty("CullingOff")); + + m.Dump(outstream, binary, 1); +} + +// wrapper for WriteModelNodes to create and pass a blank transform chain +void FBXExporter::WriteModelNodes( + StreamWriterLE& s, + const aiNode* node, + int64_t parent_uid, + const std::unordered_set<const aiNode*>& limbnodes +) { + std::vector<std::pair<std::string,aiVector3D>> chain; + WriteModelNodes(s, node, parent_uid, limbnodes, chain); +} + +void FBXExporter::WriteModelNodes( + StreamWriterLE& outstream, + const aiNode* node, + int64_t parent_uid, + const std::unordered_set<const aiNode*>& limbnodes, + std::vector<std::pair<std::string,aiVector3D>>& transform_chain +) { + // first collapse any expanded transformation chains created by FBX import. + std::string node_name(node->mName.C_Str()); + if (node_name.find(MAGIC_NODE_TAG) != std::string::npos) { + auto pos = node_name.find(MAGIC_NODE_TAG) + MAGIC_NODE_TAG.size() + 1; + std::string type_name = node_name.substr(pos); + auto elem = transform_types.find(type_name); + if (elem == transform_types.end()) { + // then this is a bug and should be fixed + std::stringstream err; + err << "unrecognized FBX transformation node"; + err << " of type " << type_name << " in node " << node_name; + throw DeadlyExportError(err.str()); + } + aiVector3D t, r, s; + node->mTransformation.Decompose(s, r, t); + switch (elem->second.second) { + case 'i': // inverse + // we don't need to worry about the inverse matrices + break; + case 't': // translation + transform_chain.emplace_back(elem->first, t); + break; + case 'r': // rotation + r *= float(DEG); + transform_chain.emplace_back(elem->first, r); + break; + case 's': // scale + transform_chain.emplace_back(elem->first, s); + break; + default: + // this should never happen + std::stringstream err; + err << "unrecognized FBX transformation type code: "; + err << elem->second.second; + throw DeadlyExportError(err.str()); + } + // now continue on to any child nodes + for (unsigned i = 0; i < node->mNumChildren; ++i) { + WriteModelNodes( + outstream, + node->mChildren[i], + parent_uid, + limbnodes, + transform_chain + ); + } + return; + } + + int64_t node_uid = 0; + // generate uid and connect to parent, if not the root node, + if (node != mScene->mRootNode) { + auto elem = node_uids.find(node); + if (elem != node_uids.end()) { + node_uid = elem->second; + } else { + node_uid = generate_uid(); + node_uids[node] = node_uid; + } + connections.emplace_back("C", "OO", node_uid, parent_uid); + } + + // what type of node is this? + if (node == mScene->mRootNode) { + // handled later + } else if (node->mNumMeshes == 1) { + // connect to child mesh, which should have been written previously + connections.emplace_back( + "C", "OO", mesh_uids[node->mMeshes[0]], node_uid + ); + // also connect to the material for the child mesh + connections.emplace_back( + "C", "OO", + material_uids[mScene->mMeshes[node->mMeshes[0]]->mMaterialIndex], + node_uid + ); + // write model node + WriteModelNode( + outstream, binary, node, node_uid, "Mesh", transform_chain + ); + } else if (limbnodes.count(node)) { + WriteModelNode( + outstream, binary, node, node_uid, "LimbNode", transform_chain + ); + // we also need to write a nodeattribute to mark it as a skeleton + int64_t node_attribute_uid = generate_uid(); + FBX::Node na("NodeAttribute"); + na.AddProperties( + node_attribute_uid, FBX::SEPARATOR + "NodeAttribute", "LimbNode" + ); + na.AddChild("TypeFlags", FBXExportProperty("Skeleton")); + na.Dump(outstream, binary, 1); + // and connect them + connections.emplace_back("C", "OO", node_attribute_uid, node_uid); + } else { + const auto& lightIt = lights_uids.find(node->mName.C_Str()); + if(lightIt != lights_uids.end()) { + // Node has a light connected to it. + WriteModelNode( + outstream, binary, node, node_uid, "Light", transform_chain + ); + connections.emplace_back("C", "OO", lightIt->second, node_uid); + } else { + // generate a null node so we can add children to it + WriteModelNode( + outstream, binary, node, node_uid, "Null", transform_chain + ); + } + } + + // if more than one child mesh, make nodes for each mesh + if (node->mNumMeshes > 1 || node == mScene->mRootNode) { + for (size_t i = 0; i < node->mNumMeshes; ++i) { + // make a new model node + int64_t new_node_uid = generate_uid(); + // connect to parent node + connections.emplace_back("C", "OO", new_node_uid, node_uid); + // connect to child mesh, which should have been written previously + connections.emplace_back( + "C", "OO", mesh_uids[node->mMeshes[i]], new_node_uid + ); + // also connect to the material for the child mesh + connections.emplace_back( + "C", "OO", + material_uids[ + mScene->mMeshes[node->mMeshes[i]]->mMaterialIndex + ], + new_node_uid + ); + + aiNode new_node; + // take name from mesh name, if it exists + new_node.mName = mScene->mMeshes[node->mMeshes[i]]->mName; + // write model node + WriteModelNode( + outstream, binary, &new_node, new_node_uid, "Mesh", std::vector<std::pair<std::string,aiVector3D>>() + ); + } + } + + // now recurse into children + for (size_t i = 0; i < node->mNumChildren; ++i) { + WriteModelNodes( + outstream, node->mChildren[i], node_uid, limbnodes + ); + } +} + +void FBXExporter::WriteAnimationCurveNode( + StreamWriterLE &outstream, + int64_t uid, + const std::string &name, // "T", "R", or "S" + aiVector3D default_value, + const std::string &property_name, // "Lcl Translation" etc + int64_t layer_uid, + int64_t node_uid) { + FBX::Node n("AnimationCurveNode"); + n.AddProperties(uid, name + FBX::SEPARATOR + "AnimCurveNode", ""); + FBX::Node p("Properties70"); + p.AddP70numberA("d|X", default_value.x); + p.AddP70numberA("d|Y", default_value.y); + p.AddP70numberA("d|Z", default_value.z); + n.AddChild(p); + n.Dump(outstream, binary, 1); + // connect to layer + this->connections.emplace_back("C", "OO", uid, layer_uid); + // connect to bone + this->connections.emplace_back("C", "OP", uid, node_uid, property_name); +} + +void FBXExporter::WriteAnimationCurve( + StreamWriterLE& outstream, + double default_value, + const std::vector<int64_t>& times, + const std::vector<float>& values, + int64_t curvenode_uid, + const std::string& property_link // "d|X", "d|Y", etc +) { + FBX::Node n("AnimationCurve"); + int64_t curve_uid = generate_uid(); + n.AddProperties(curve_uid, FBX::SEPARATOR + "AnimCurve", ""); + n.AddChild("Default", default_value); + n.AddChild("KeyVer", int32_t(4009)); + n.AddChild("KeyTime", times); + n.AddChild("KeyValueFloat", values); + // TODO: keyattr flags and data (STUB for now) + n.AddChild("KeyAttrFlags", std::vector<int32_t>{0}); + n.AddChild("KeyAttrDataFloat", std::vector<float>{0,0,0,0}); + n.AddChild( + "KeyAttrRefCount", + std::vector<int32_t>{static_cast<int32_t>(times.size())} + ); + n.Dump(outstream, binary, 1); + this->connections.emplace_back( + "C", "OP", curve_uid, curvenode_uid, property_link + ); +} + + +void FBXExporter::WriteConnections () +{ + // we should have completed the connection graph already, + // so basically just dump it here + if (!binary) { + WriteAsciiSectionHeader("Object connections"); + } + // TODO: comments with names in the ascii version + FBX::Node conn("Connections"); + StreamWriterLE outstream(outfile); + conn.Begin(outstream, binary, 0); + conn.BeginChildren(outstream, binary, 0); + for (auto &n : connections) { + n.Dump(outstream, binary, 1); + } + conn.End(outstream, binary, 0, !connections.empty()); + connections.clear(); +} + +#endif // ASSIMP_BUILD_NO_FBX_EXPORTER +#endif // ASSIMP_BUILD_NO_EXPORT |