assimp/code/AssetLib/glTF2/glTF2Asset.inl

/*
Open Asset Import Library (assimp)
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All rights reserved.

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* Redistributions in binary form must reproduce the above
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"AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT
LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR
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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,
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*/

#include "AssetLib/glTF/glTFCommon.h"

#include <assimp/StringUtils.h>
#include <assimp/DefaultLogger.hpp>

using namespace Assimp;

namespace glTF2 {

namespace {

//
// JSON Value reading helpers
//

template <class T>
struct ReadHelper {
    static bool Read(Value &val, T &out) {
        return val.IsInt() ? out = static_cast<T>(val.GetInt()), true : false;
    }
};

template <>
struct ReadHelper<bool> {
    static bool Read(Value &val, bool &out) {
        return val.IsBool() ? out = val.GetBool(), true : false;
    }
};

template <>
struct ReadHelper<float> {
    static bool Read(Value &val, float &out) {
        return val.IsNumber() ? out = static_cast<float>(val.GetDouble()), true : false;
    }
};

template <unsigned int N>
struct ReadHelper<float[N]> {
    static bool Read(Value &val, float (&out)[N]) {
        if (!val.IsArray() || val.Size() != N) return false;
        for (unsigned int i = 0; i < N; ++i) {
            if (val[i].IsNumber())
                out[i] = static_cast<float>(val[i].GetDouble());
        }
        return true;
    }
};

template <>
struct ReadHelper<const char *> {
    static bool Read(Value &val, const char *&out) {
        return val.IsString() ? (out = val.GetString(), true) : false;
    }
};

template <>
struct ReadHelper<std::string> {
    static bool Read(Value &val, std::string &out) {
        return val.IsString() ? (out = std::string(val.GetString(), val.GetStringLength()), true) : false;
    }
};

template <>
struct ReadHelper<uint64_t> {
    static bool Read(Value &val, uint64_t &out) {
        return val.IsUint64() ? out = val.GetUint64(), true : false;
    }
};

template <>
struct ReadHelper<int64_t> {
    static bool Read(Value &val, int64_t &out) {
        return val.IsInt64() ? out = val.GetInt64(), true : false;
    }
};

template <class T>
struct ReadHelper<Nullable<T>> {
    static bool Read(Value &val, Nullable<T> &out) {
        return out.isPresent = ReadHelper<T>::Read(val, out.value);
    }
};

template <class T>
inline static bool ReadValue(Value &val, T &out) {
    return ReadHelper<T>::Read(val, out);
}

template <class T>
inline static bool ReadMember(Value &obj, const char *id, T &out) {
    Value::MemberIterator it = obj.FindMember(id);
    if (it != obj.MemberEnd()) {
        return ReadHelper<T>::Read(it->value, out);
    }
    return false;
}

template <class T>
inline static T MemberOrDefault(Value &obj, const char *id, T defaultValue) {
    T out;
    return ReadMember(obj, id, out) ? out : defaultValue;
}

inline Value *FindMember(Value &val, const char *id) {
    Value::MemberIterator it = val.FindMember(id);
    return (it != val.MemberEnd()) ? &it->value : 0;
}

inline Value *FindString(Value &val, const char *id) {
    Value::MemberIterator it = val.FindMember(id);
    return (it != val.MemberEnd() && it->value.IsString()) ? &it->value : 0;
}

inline Value *FindNumber(Value &val, const char *id) {
    Value::MemberIterator it = val.FindMember(id);
    return (it != val.MemberEnd() && it->value.IsNumber()) ? &it->value : 0;
}

inline Value *FindUInt(Value &val, const char *id) {
    Value::MemberIterator it = val.FindMember(id);
    return (it != val.MemberEnd() && it->value.IsUint()) ? &it->value : 0;
}

inline Value *FindArray(Value &val, const char *id) {
    Value::MemberIterator it = val.FindMember(id);
    return (it != val.MemberEnd() && it->value.IsArray()) ? &it->value : 0;
}

inline Value *FindObject(Value &val, const char *id) {
    Value::MemberIterator it = val.FindMember(id);
    return (it != val.MemberEnd() && it->value.IsObject()) ? &it->value : 0;
}
} // namespace

//
// LazyDict methods
//

template <class T>
inline LazyDict<T>::LazyDict(Asset &asset, const char *dictId, const char *extId) :
        mDictId(dictId),
        mExtId(extId),
        mDict(0),
        mAsset(asset) {
    asset.mDicts.push_back(this); // register to the list of dictionaries
}

template <class T>
inline LazyDict<T>::~LazyDict() {
    for (size_t i = 0; i < mObjs.size(); ++i) {
        delete mObjs[i];
    }
}

template <class T>
inline void LazyDict<T>::AttachToDocument(Document &doc) {
    Value *container = 0;

    if (mExtId) {
        if (Value *exts = FindObject(doc, "extensions")) {
            container = FindObject(*exts, mExtId);
        }
    } else {
        container = &doc;
    }

    if (container) {
        mDict = FindArray(*container, mDictId);
    }
}

template <class T>
inline void LazyDict<T>::DetachFromDocument() {
    mDict = 0;
}

template <class T>
unsigned int LazyDict<T>::Remove(const char *id) {
    id = T::TranslateId(mAsset, id);

    typename IdDict::iterator objIt = mObjsById.find(id);

    if (objIt == mObjsById.end()) {
        throw DeadlyExportError("GLTF: Object with id \"" + std::string(id) + "\" is not found");
    }

    const unsigned int index = objIt->second;

    mAsset.mUsedIds[id] = false;
    mObjsById.erase(id);
    mObjsByOIndex.erase(index);
    mObjs.erase(mObjs.begin() + index);

    //update index of object in mObjs;
    for (unsigned int i = index; i < mObjs.size(); ++i) {
        T *obj = mObjs[i];

        obj->index = i;
    }

    for (IdDict::iterator it = mObjsById.begin(); it != mObjsById.end(); ++it) {
        if (it->second <= index) {
            continue;
        }

        mObjsById[it->first] = it->second - 1;
    }

    for (Dict::iterator it = mObjsByOIndex.begin(); it != mObjsByOIndex.end(); ++it) {
        if (it->second <= index) {
            continue;
        }

        mObjsByOIndex[it->first] = it->second - 1;
    }

    return index;
}

template <class T>
Ref<T> LazyDict<T>::Retrieve(unsigned int i) {

    typename Dict::iterator it = mObjsByOIndex.find(i);
    if (it != mObjsByOIndex.end()) { // already created?
        return Ref<T>(mObjs, it->second);
    }

    // read it from the JSON object
    if (!mDict) {
        throw DeadlyImportError("GLTF: Missing section \"" + std::string(mDictId) + "\"");
    }

    if (!mDict->IsArray()) {
        throw DeadlyImportError("GLTF: Field is not an array \"" + std::string(mDictId) + "\"");
    }

    Value &obj = (*mDict)[i];

    if (!obj.IsObject()) {
        throw DeadlyImportError("GLTF: Object at index \"" + to_string(i) + "\" is not a JSON object");
    }

    if (mRecursiveReferenceCheck.find(i) != mRecursiveReferenceCheck.end()) {
        throw DeadlyImportError("GLTF: Object at index \"" + to_string(i) + "\" has recursive reference to itself");
    }
    mRecursiveReferenceCheck.insert(i);

    // Unique ptr prevents memory leak in case of Read throws an exception
    auto inst = std::unique_ptr<T>(new T());
    inst->id = std::string(mDictId) + "_" + to_string(i);
    inst->oIndex = i;
    ReadMember(obj, "name", inst->name);
    inst->Read(obj, mAsset);

    Ref<T> result = Add(inst.release());
    mRecursiveReferenceCheck.erase(i);
    return result;
}

template <class T>
Ref<T> LazyDict<T>::Get(unsigned int i) {
    return Ref<T>(mObjs, i);
}

template <class T>
Ref<T> LazyDict<T>::Get(const char *id) {
    id = T::TranslateId(mAsset, id);

    typename IdDict::iterator it = mObjsById.find(id);
    if (it != mObjsById.end()) { // already created?
        return Ref<T>(mObjs, it->second);
    }

    return Ref<T>();
}

template <class T>
Ref<T> LazyDict<T>::Add(T *obj) {
    unsigned int idx = unsigned(mObjs.size());
    mObjs.push_back(obj);
    mObjsByOIndex[obj->oIndex] = idx;
    mObjsById[obj->id] = idx;
    mAsset.mUsedIds[obj->id] = true;
    return Ref<T>(mObjs, idx);
}

template <class T>
Ref<T> LazyDict<T>::Create(const char *id) {
    Asset::IdMap::iterator it = mAsset.mUsedIds.find(id);
    if (it != mAsset.mUsedIds.end()) {
        throw DeadlyImportError("GLTF: two objects with the same ID exist");
    }
    T *inst = new T();
    unsigned int idx = unsigned(mObjs.size());
    inst->id = id;
    inst->index = idx;
    inst->oIndex = idx;
    return Add(inst);
}

//
// glTF dictionary objects methods
//

inline Buffer::Buffer() :
        byteLength(0),
        type(Type_arraybuffer),
        EncodedRegion_Current(nullptr),
        mIsSpecial(false) {}

inline Buffer::~Buffer() {
    for (SEncodedRegion *reg : EncodedRegion_List)
        delete reg;
}

inline const char *Buffer::TranslateId(Asset & /*r*/, const char *id) {
    return id;
}

inline void Buffer::Read(Value &obj, Asset &r) {
    size_t statedLength = MemberOrDefault<size_t>(obj, "byteLength", 0);
    byteLength = statedLength;

    Value *it = FindString(obj, "uri");
    if (!it) {
        if (statedLength > 0) {
            throw DeadlyImportError("GLTF: buffer with non-zero length missing the \"uri\" attribute");
        }
        return;
    }

    const char *uri = it->GetString();

    glTFCommon::Util::DataURI dataURI;
    if (ParseDataURI(uri, it->GetStringLength(), dataURI)) {
        if (dataURI.base64) {
            uint8_t *data = 0;
            this->byteLength = glTFCommon::Util::DecodeBase64(dataURI.data, dataURI.dataLength, data);
            this->mData.reset(data, std::default_delete<uint8_t[]>());

            if (statedLength > 0 && this->byteLength != statedLength) {
                throw DeadlyImportError("GLTF: buffer \"" + id + "\", expected " + to_string(statedLength) +
                                        " bytes, but found " + to_string(dataURI.dataLength));
            }
        } else { // assume raw data
            if (statedLength != dataURI.dataLength) {
                throw DeadlyImportError("GLTF: buffer \"" + id + "\", expected " + to_string(statedLength) +
                                        " bytes, but found " + to_string(dataURI.dataLength));
            }

            this->mData.reset(new uint8_t[dataURI.dataLength], std::default_delete<uint8_t[]>());
            memcpy(this->mData.get(), dataURI.data, dataURI.dataLength);
        }
    } else { // Local file
        if (byteLength > 0) {
            std::string dir = !r.mCurrentAssetDir.empty() ? (r.mCurrentAssetDir) : "";

            IOStream *file = r.OpenFile(dir + uri, "rb");
            if (file) {
                bool ok = LoadFromStream(*file, byteLength);
                delete file;

                if (!ok)
                    throw DeadlyImportError("GLTF: error while reading referenced file \"" + std::string(uri) + "\"");
            } else {
                throw DeadlyImportError("GLTF: could not open referenced file \"" + std::string(uri) + "\"");
            }
        }
    }
}

inline bool Buffer::LoadFromStream(IOStream &stream, size_t length, size_t baseOffset) {
    byteLength = length ? length : stream.FileSize();

    if (baseOffset) {
        stream.Seek(baseOffset, aiOrigin_SET);
    }

    mData.reset(new uint8_t[byteLength], std::default_delete<uint8_t[]>());

    if (stream.Read(mData.get(), byteLength, 1) != 1) {
        return false;
    }
    return true;
}

inline void Buffer::EncodedRegion_Mark(const size_t pOffset, const size_t pEncodedData_Length, uint8_t *pDecodedData, const size_t pDecodedData_Length, const std::string &pID) {
    // Check pointer to data
    if (pDecodedData == nullptr) throw DeadlyImportError("GLTF: for marking encoded region pointer to decoded data must be provided.");

    // Check offset
    if (pOffset > byteLength) {
        const uint8_t val_size = 32;

        char val[val_size];

        ai_snprintf(val, val_size, AI_SIZEFMT, pOffset);
        throw DeadlyImportError(std::string("GLTF: incorrect offset value (") + val + ") for marking encoded region.");
    }

    // Check length
    if ((pOffset + pEncodedData_Length) > byteLength) {
        const uint8_t val_size = 64;

        char val[val_size];

        ai_snprintf(val, val_size, AI_SIZEFMT "/" AI_SIZEFMT, pOffset, pEncodedData_Length);
        throw DeadlyImportError(std::string("GLTF: encoded region with offset/length (") + val + ") is out of range.");
    }

    // Add new region
    EncodedRegion_List.push_back(new SEncodedRegion(pOffset, pEncodedData_Length, pDecodedData, pDecodedData_Length, pID));
    // And set new value for "byteLength"
    byteLength += (pDecodedData_Length - pEncodedData_Length);
}

inline void Buffer::EncodedRegion_SetCurrent(const std::string &pID) {
    if ((EncodedRegion_Current != nullptr) && (EncodedRegion_Current->ID == pID)) return;

    for (SEncodedRegion *reg : EncodedRegion_List) {
        if (reg->ID == pID) {
            EncodedRegion_Current = reg;

            return;
        }
    }

    throw DeadlyImportError("GLTF: EncodedRegion with ID: \"" + pID + "\" not found.");
}

inline bool Buffer::ReplaceData(const size_t pBufferData_Offset, const size_t pBufferData_Count, const uint8_t *pReplace_Data, const size_t pReplace_Count) {

    if ((pBufferData_Count == 0) || (pReplace_Count == 0) || (pReplace_Data == nullptr)) {
        return false;
    }

    const size_t new_data_size = byteLength + pReplace_Count - pBufferData_Count;
    uint8_t *new_data = new uint8_t[new_data_size];
    // Copy data which place before replacing part.
    ::memcpy(new_data, mData.get(), pBufferData_Offset);
    // Copy new data.
    ::memcpy(&new_data[pBufferData_Offset], pReplace_Data, pReplace_Count);
    // Copy data which place after replacing part.
    ::memcpy(&new_data[pBufferData_Offset + pReplace_Count], &mData.get()[pBufferData_Offset + pBufferData_Count], pBufferData_Offset);
    // Apply new data
    mData.reset(new_data, std::default_delete<uint8_t[]>());
    byteLength = new_data_size;

    return true;
}

inline bool Buffer::ReplaceData_joint(const size_t pBufferData_Offset, const size_t pBufferData_Count, const uint8_t *pReplace_Data, const size_t pReplace_Count) {
    if ((pBufferData_Count == 0) || (pReplace_Count == 0) || (pReplace_Data == nullptr)) {
        return false;
    }

    const size_t new_data_size = byteLength + pReplace_Count - pBufferData_Count;
    uint8_t *new_data = new uint8_t[new_data_size];
    // Copy data which place before replacing part.
    memcpy(new_data, mData.get(), pBufferData_Offset);
    // Copy new data.
    memcpy(&new_data[pBufferData_Offset], pReplace_Data, pReplace_Count);
    // Copy data which place after replacing part.
    memcpy(&new_data[pBufferData_Offset + pReplace_Count], &mData.get()[pBufferData_Offset + pBufferData_Count], new_data_size - (pBufferData_Offset + pReplace_Count));
    // Apply new data
    mData.reset(new_data, std::default_delete<uint8_t[]>());
    byteLength = new_data_size;

    return true;
}

inline size_t Buffer::AppendData(uint8_t *data, size_t length) {
    size_t offset = this->byteLength;
    // Force alignment to 4 bits
    Grow((length + 3) & ~3);
    memcpy(mData.get() + offset, data, length);
    return offset;
}

inline void Buffer::Grow(size_t amount) {
    if (amount <= 0) {
        return;
    }

    // Capacity is big enough
    if (capacity >= byteLength + amount) {
        byteLength += amount;
        return;
    }

    // Just allocate data which we need
    capacity = byteLength + amount;

    uint8_t *b = new uint8_t[capacity];
    if (nullptr != mData) {
        memcpy(b, mData.get(), byteLength);
    }
    mData.reset(b, std::default_delete<uint8_t[]>());
    byteLength += amount;
}

//
// struct BufferView
//

inline void BufferView::Read(Value &obj, Asset &r) {

    if (Value *bufferVal = FindUInt(obj, "buffer")) {
        buffer = r.buffers.Retrieve(bufferVal->GetUint());
    }

    byteOffset = MemberOrDefault(obj, "byteOffset", size_t(0));
    byteLength = MemberOrDefault(obj, "byteLength", size_t(0));
    byteStride = MemberOrDefault(obj, "byteStride", 0u);
}

inline uint8_t *BufferView::GetPointer(size_t accOffset) {
    if (!buffer) return 0;
    uint8_t *basePtr = buffer->GetPointer();
    if (!basePtr) return 0;

    size_t offset = accOffset + byteOffset;
    if (buffer->EncodedRegion_Current != nullptr) {
        const size_t begin = buffer->EncodedRegion_Current->Offset;
        const size_t end = begin + buffer->EncodedRegion_Current->DecodedData_Length;
        if ((offset >= begin) && (offset < end))
            return &buffer->EncodedRegion_Current->DecodedData[offset - begin];
    }

    return basePtr + offset;
}

//
// struct Accessor
//
inline void Accessor::Sparse::PopulateData(size_t numBytes, uint8_t *bytes) {
    if (bytes) {
        data.assign(bytes, bytes + numBytes);
    } else {
        data.resize(numBytes, 0x00);
    }
}

inline void Accessor::Sparse::PatchData(unsigned int elementSize) {
    uint8_t *pIndices = indices->GetPointer(indicesByteOffset);
    const unsigned int indexSize = int(ComponentTypeSize(indicesType));
    uint8_t *indicesEnd = pIndices + count * indexSize;

    uint8_t *pValues = values->GetPointer(valuesByteOffset);
    while (pIndices != indicesEnd) {
        size_t offset;
        switch (indicesType) {
        case ComponentType_UNSIGNED_BYTE:
            offset = *pIndices;
            break;
        case ComponentType_UNSIGNED_SHORT:
            offset = *reinterpret_cast<uint16_t *>(pIndices);
            break;
        case ComponentType_UNSIGNED_INT:
            offset = *reinterpret_cast<uint32_t *>(pIndices);
            break;
        default:
            // have fun with float and negative values from signed types as indices.
            throw DeadlyImportError("Unsupported component type in index.");
        }

        offset *= elementSize;
        std::memcpy(data.data() + offset, pValues, elementSize);

        pValues += elementSize;
        pIndices += indexSize;
    }
}

inline void Accessor::Read(Value &obj, Asset &r) {

    if (Value *bufferViewVal = FindUInt(obj, "bufferView")) {
        bufferView = r.bufferViews.Retrieve(bufferViewVal->GetUint());
    }

    byteOffset = MemberOrDefault(obj, "byteOffset", size_t(0));
    componentType = MemberOrDefault(obj, "componentType", ComponentType_BYTE);
    count = MemberOrDefault(obj, "count", size_t(0));

    const char *typestr;
    type = ReadMember(obj, "type", typestr) ? AttribType::FromString(typestr) : AttribType::SCALAR;

    if (Value *sparseValue = FindObject(obj, "sparse")) {
        sparse.reset(new Sparse);
        // count
        ReadMember(*sparseValue, "count", sparse->count);

        // indices
        if (Value *indicesValue = FindObject(*sparseValue, "indices")) {
            //indices bufferView
            Value *indiceViewID = FindUInt(*indicesValue, "bufferView");
            sparse->indices = r.bufferViews.Retrieve(indiceViewID->GetUint());
            //indices byteOffset
            sparse->indicesByteOffset = MemberOrDefault(*indicesValue, "byteOffset", size_t(0));
            //indices componentType
            sparse->indicesType = MemberOrDefault(*indicesValue, "componentType", ComponentType_BYTE);
            //sparse->indices->Read(*indicesValue, r);
        }

        // value
        if (Value *valuesValue = FindObject(*sparseValue, "values")) {
            //value bufferView
            Value *valueViewID = FindUInt(*valuesValue, "bufferView");
            sparse->values = r.bufferViews.Retrieve(valueViewID->GetUint());
            //value byteOffset
            sparse->valuesByteOffset = MemberOrDefault(*valuesValue, "byteOffset", size_t(0));
            //sparse->values->Read(*valuesValue, r);
        }

        // indicesType
        sparse->indicesType = MemberOrDefault(*sparseValue, "componentType", ComponentType_UNSIGNED_SHORT);

        const unsigned int elementSize = GetElementSize();
        const size_t dataSize = count * elementSize;
        sparse->PopulateData(dataSize, bufferView ? bufferView->GetPointer(byteOffset) : 0);
        sparse->PatchData(elementSize);
    }
}

inline unsigned int Accessor::GetNumComponents() {
    return AttribType::GetNumComponents(type);
}

inline unsigned int Accessor::GetBytesPerComponent() {
    return int(ComponentTypeSize(componentType));
}

inline unsigned int Accessor::GetElementSize() {
    return GetNumComponents() * GetBytesPerComponent();
}

inline uint8_t *Accessor::GetPointer() {
    if (sparse)
        return sparse->data.data();

    if (!bufferView || !bufferView->buffer) return 0;
    uint8_t *basePtr = bufferView->buffer->GetPointer();
    if (!basePtr) return 0;

    size_t offset = byteOffset + bufferView->byteOffset;

    // Check if region is encoded.
    if (bufferView->buffer->EncodedRegion_Current != nullptr) {
        const size_t begin = bufferView->buffer->EncodedRegion_Current->Offset;
        const size_t end = begin + bufferView->buffer->EncodedRegion_Current->DecodedData_Length;

        if ((offset >= begin) && (offset < end))
            return &bufferView->buffer->EncodedRegion_Current->DecodedData[offset - begin];
    }

    return basePtr + offset;
}

namespace {
inline void CopyData(size_t count,
        const uint8_t *src, size_t src_stride,
        uint8_t *dst, size_t dst_stride) {
    if (src_stride == dst_stride) {
        memcpy(dst, src, count * src_stride);
    } else {
        size_t sz = std::min(src_stride, dst_stride);
        for (size_t i = 0; i < count; ++i) {
            memcpy(dst, src, sz);
            if (sz < dst_stride) {
                memset(dst + sz, 0, dst_stride - sz);
            }
            src += src_stride;
            dst += dst_stride;
        }
    }
}
} // namespace

template <class T>
void Accessor::ExtractData(T *&outData) {
    uint8_t *data = GetPointer();
    if (!data) {
        throw DeadlyImportError("GLTF2: data is nullptr.");
    }

    const size_t elemSize = GetElementSize();
    const size_t totalSize = elemSize * count;

    const size_t stride = bufferView && bufferView->byteStride ? bufferView->byteStride : elemSize;

    const size_t targetElemSize = sizeof(T);
    ai_assert(elemSize <= targetElemSize);
    ai_assert(count * stride <= (bufferView ? bufferView->byteLength : sparse->data.size()));

    outData = new T[count];
    if (stride == elemSize && targetElemSize == elemSize) {
        memcpy(outData, data, totalSize);
    } else {
        for (size_t i = 0; i < count; ++i) {
            memcpy(outData + i, data + i * stride, elemSize);
        }
    }
}

inline void Accessor::WriteData(size_t _count, const void *src_buffer, size_t src_stride) {
    uint8_t *buffer_ptr = bufferView->buffer->GetPointer();
    size_t offset = byteOffset + bufferView->byteOffset;

    size_t dst_stride = GetNumComponents() * GetBytesPerComponent();

    const uint8_t *src = reinterpret_cast<const uint8_t *>(src_buffer);
    uint8_t *dst = reinterpret_cast<uint8_t *>(buffer_ptr + offset);

    ai_assert(dst + _count * dst_stride <= buffer_ptr + bufferView->buffer->byteLength);
    CopyData(_count, src, src_stride, dst, dst_stride);
}

inline void Accessor::WriteSparseValues(size_t _count, const void *src_data, size_t src_dataStride) {
    if (!sparse)
        return;

    // values
    uint8_t *value_buffer_ptr = sparse->values->buffer->GetPointer();
    size_t value_offset = sparse->valuesByteOffset + sparse->values->byteOffset;
    size_t value_dst_stride = GetNumComponents() * GetBytesPerComponent();
    const uint8_t *value_src = reinterpret_cast<const uint8_t *>(src_data);
    uint8_t *value_dst = reinterpret_cast<uint8_t *>(value_buffer_ptr + value_offset);
    ai_assert(value_dst + _count * value_dst_stride <= value_buffer_ptr + sparse->values->buffer->byteLength);
    CopyData(_count, value_src, src_dataStride, value_dst, value_dst_stride);
}

inline void Accessor::WriteSparseIndices(size_t _count, const void *src_idx, size_t src_idxStride) {
    if (!sparse)
        return;

    // indices
    uint8_t *indices_buffer_ptr = sparse->indices->buffer->GetPointer();
    size_t indices_offset = sparse->indicesByteOffset + sparse->indices->byteOffset;
    size_t indices_dst_stride = 1 * sizeof(unsigned short);
    const uint8_t *indices_src = reinterpret_cast<const uint8_t *>(src_idx);
    uint8_t *indices_dst = reinterpret_cast<uint8_t *>(indices_buffer_ptr + indices_offset);
    ai_assert(indices_dst + _count * indices_dst_stride <= indices_buffer_ptr + sparse->indices->buffer->byteLength);
    CopyData(_count, indices_src, src_idxStride, indices_dst, indices_dst_stride);
}
inline Accessor::Indexer::Indexer(Accessor &acc) :
        accessor(acc),
        data(acc.GetPointer()),
        elemSize(acc.GetElementSize()),
        stride(acc.bufferView && acc.bufferView->byteStride ? acc.bufferView->byteStride : elemSize) {
}

//! Accesses the i-th value as defined by the accessor
template <class T>
T Accessor::Indexer::GetValue(int i) {
    ai_assert(data);
    ai_assert(i * stride < accessor.bufferView->byteLength);
    T value = T();
    memcpy(&value, data + i * stride, elemSize);
    //value >>= 8 * (sizeof(T) - elemSize);
    return value;
}

inline Image::Image() :
        width(0),
        height(0),
        mDataLength(0) {
}

inline void Image::Read(Value &obj, Asset &r) {
    if (!mDataLength) {
        Value *curUri = FindString(obj, "uri");
        if (nullptr != curUri) {
            const char *uristr = curUri->GetString();

            glTFCommon::Util::DataURI dataURI;
            if (ParseDataURI(uristr, curUri->GetStringLength(), dataURI)) {
                mimeType = dataURI.mediaType;
                if (dataURI.base64) {
                    uint8_t *ptr = nullptr;
                    mDataLength = glTFCommon::Util::DecodeBase64(dataURI.data, dataURI.dataLength, ptr);
                    mData.reset(ptr);
                }
            } else {
                this->uri = uristr;
            }
        } else if (Value *bufferViewVal = FindUInt(obj, "bufferView")) {
            this->bufferView = r.bufferViews.Retrieve(bufferViewVal->GetUint());
            Ref<Buffer> buffer = this->bufferView->buffer;

            this->mDataLength = this->bufferView->byteLength;
            // maybe this memcpy could be avoided if aiTexture does not delete[] pcData at destruction.

            this->mData.reset(new uint8_t[this->mDataLength]);
            memcpy(this->mData.get(), buffer->GetPointer() + this->bufferView->byteOffset, this->mDataLength);

            if (Value *mtype = FindString(obj, "mimeType")) {
                this->mimeType = mtype->GetString();
            }
        }
    }
}

inline uint8_t *Image::StealData() {
    mDataLength = 0;
    return mData.release();
}

// Never take over the ownership of data whenever binary or not
inline void Image::SetData(uint8_t *data, size_t length, Asset &r) {
    Ref<Buffer> b = r.GetBodyBuffer();
    if (b) { // binary file: append to body
        std::string bvId = r.FindUniqueID(this->id, "imgdata");
        bufferView = r.bufferViews.Create(bvId);

        bufferView->buffer = b;
        bufferView->byteLength = length;
        bufferView->byteOffset = b->AppendData(data, length);
    } else { // text file: will be stored as a data uri
        uint8_t *temp = new uint8_t[length];
        memcpy(temp, data, length);
        this->mData.reset(temp);
        this->mDataLength = length;
    }
}

inline void Sampler::Read(Value &obj, Asset & /*r*/) {
    SetDefaults();

    ReadMember(obj, "name", name);
    ReadMember(obj, "magFilter", magFilter);
    ReadMember(obj, "minFilter", minFilter);
    ReadMember(obj, "wrapS", wrapS);
    ReadMember(obj, "wrapT", wrapT);
}

inline void Sampler::SetDefaults() {
    //only wrapping modes have defaults
    wrapS = SamplerWrap::Repeat;
    wrapT = SamplerWrap::Repeat;
    magFilter = SamplerMagFilter::UNSET;
    minFilter = SamplerMinFilter::UNSET;
}

inline void Texture::Read(Value &obj, Asset &r) {
    if (Value *sourceVal = FindUInt(obj, "source")) {
        source = r.images.Retrieve(sourceVal->GetUint());
    }

    if (Value *samplerVal = FindUInt(obj, "sampler")) {
        sampler = r.samplers.Retrieve(samplerVal->GetUint());
    }
}

namespace {
inline void SetTextureProperties(Asset &r, Value *prop, TextureInfo &out) {
    if (r.extensionsUsed.KHR_texture_transform) {
        if (Value *extensions = FindObject(*prop, "extensions")) {
            out.textureTransformSupported = true;
            if (Value *pKHR_texture_transform = FindObject(*extensions, "KHR_texture_transform")) {
                if (Value *array = FindArray(*pKHR_texture_transform, "offset")) {
                    out.TextureTransformExt_t.offset[0] = (*array)[0].GetFloat();
                    out.TextureTransformExt_t.offset[1] = (*array)[1].GetFloat();
                } else {
                    out.TextureTransformExt_t.offset[0] = 0;
                    out.TextureTransformExt_t.offset[1] = 0;
                }

                if (!ReadMember(*pKHR_texture_transform, "rotation", out.TextureTransformExt_t.rotation)) {
                    out.TextureTransformExt_t.rotation = 0;
                }

                if (Value *array = FindArray(*pKHR_texture_transform, "scale")) {
                    out.TextureTransformExt_t.scale[0] = (*array)[0].GetFloat();
                    out.TextureTransformExt_t.scale[1] = (*array)[1].GetFloat();
                } else {
                    out.TextureTransformExt_t.scale[0] = 1;
                    out.TextureTransformExt_t.scale[1] = 1;
                }
            }
        }
    }

    if (Value *index = FindUInt(*prop, "index")) {
        out.texture = r.textures.Retrieve(index->GetUint());
    }

    if (Value *texcoord = FindUInt(*prop, "texCoord")) {
        out.texCoord = texcoord->GetUint();
    }
}

inline void ReadTextureProperty(Asset &r, Value &vals, const char *propName, TextureInfo &out) {
    if (Value *prop = FindMember(vals, propName)) {
        SetTextureProperties(r, prop, out);
    }
}

inline void ReadTextureProperty(Asset &r, Value &vals, const char *propName, NormalTextureInfo &out) {
    if (Value *prop = FindMember(vals, propName)) {
        SetTextureProperties(r, prop, out);

        if (Value *scale = FindNumber(*prop, "scale")) {
            out.scale = static_cast<float>(scale->GetDouble());
        }
    }
}

inline void ReadTextureProperty(Asset &r, Value &vals, const char *propName, OcclusionTextureInfo &out) {
    if (Value *prop = FindMember(vals, propName)) {
        SetTextureProperties(r, prop, out);

        if (Value *strength = FindNumber(*prop, "strength")) {
            out.strength = static_cast<float>(strength->GetDouble());
        }
    }
}
} // namespace

inline void Material::Read(Value &material, Asset &r) {
    SetDefaults();

    if (Value *curPbrMetallicRoughness = FindObject(material, "pbrMetallicRoughness")) {
        ReadMember(*curPbrMetallicRoughness, "baseColorFactor", this->pbrMetallicRoughness.baseColorFactor);
        ReadTextureProperty(r, *curPbrMetallicRoughness, "baseColorTexture", this->pbrMetallicRoughness.baseColorTexture);
        ReadTextureProperty(r, *curPbrMetallicRoughness, "metallicRoughnessTexture", this->pbrMetallicRoughness.metallicRoughnessTexture);
        ReadMember(*curPbrMetallicRoughness, "metallicFactor", this->pbrMetallicRoughness.metallicFactor);
        ReadMember(*curPbrMetallicRoughness, "roughnessFactor", this->pbrMetallicRoughness.roughnessFactor);
    }

    ReadTextureProperty(r, material, "normalTexture", this->normalTexture);
    ReadTextureProperty(r, material, "occlusionTexture", this->occlusionTexture);
    ReadTextureProperty(r, material, "emissiveTexture", this->emissiveTexture);
    ReadMember(material, "emissiveFactor", this->emissiveFactor);

    ReadMember(material, "doubleSided", this->doubleSided);
    ReadMember(material, "alphaMode", this->alphaMode);
    ReadMember(material, "alphaCutoff", this->alphaCutoff);

    if (Value *extensions = FindObject(material, "extensions")) {
        if (r.extensionsUsed.KHR_materials_pbrSpecularGlossiness) {
            if (Value *curPbrSpecularGlossiness = FindObject(*extensions, "KHR_materials_pbrSpecularGlossiness")) {
                PbrSpecularGlossiness pbrSG;

                ReadMember(*curPbrSpecularGlossiness, "diffuseFactor", pbrSG.diffuseFactor);
                ReadTextureProperty(r, *curPbrSpecularGlossiness, "diffuseTexture", pbrSG.diffuseTexture);
                ReadTextureProperty(r, *curPbrSpecularGlossiness, "specularGlossinessTexture", pbrSG.specularGlossinessTexture);
                ReadMember(*curPbrSpecularGlossiness, "specularFactor", pbrSG.specularFactor);
                ReadMember(*curPbrSpecularGlossiness, "glossinessFactor", pbrSG.glossinessFactor);

                this->pbrSpecularGlossiness = Nullable<PbrSpecularGlossiness>(pbrSG);
            }
        }

        if (r.extensionsUsed.KHR_texture_transform) {
        }

        unlit = nullptr != FindObject(*extensions, "KHR_materials_unlit");
    }
}

namespace {
void SetVector(vec4 &v, const float (&in)[4]) {
    v[0] = in[0];
    v[1] = in[1];
    v[2] = in[2];
    v[3] = in[3];
}

void SetVector(vec3 &v, const float (&in)[3]) {
    v[0] = in[0];
    v[1] = in[1];
    v[2] = in[2];
}
} // namespace

inline void Material::SetDefaults() {
    //pbr materials
    SetVector(pbrMetallicRoughness.baseColorFactor, defaultBaseColor);
    pbrMetallicRoughness.metallicFactor = 1.0;
    pbrMetallicRoughness.roughnessFactor = 1.0;

    SetVector(emissiveFactor, defaultEmissiveFactor);
    alphaMode = "OPAQUE";
    alphaCutoff = 0.5;
    doubleSided = false;
    unlit = false;
}

inline void PbrSpecularGlossiness::SetDefaults() {
    //pbrSpecularGlossiness properties
    SetVector(diffuseFactor, defaultDiffuseFactor);
    SetVector(specularFactor, defaultSpecularFactor);
    glossinessFactor = 1.0;
}

namespace {

template <int N>
inline int Compare(const char *attr, const char (&str)[N]) {
    return (strncmp(attr, str, N - 1) == 0) ? N - 1 : 0;
}

#if _MSC_VER
#pragma warning(push)
#pragma warning(disable : 4706)
#endif // _MSC_VER

inline bool GetAttribVector(Mesh::Primitive &p, const char *attr, Mesh::AccessorList *&v, int &pos) {
    if ((pos = Compare(attr, "POSITION"))) {
        v = &(p.attributes.position);
    } else if ((pos = Compare(attr, "NORMAL"))) {
        v = &(p.attributes.normal);
    } else if ((pos = Compare(attr, "TANGENT"))) {
        v = &(p.attributes.tangent);
    } else if ((pos = Compare(attr, "TEXCOORD"))) {
        v = &(p.attributes.texcoord);
    } else if ((pos = Compare(attr, "COLOR"))) {
        v = &(p.attributes.color);
    } else if ((pos = Compare(attr, "JOINT"))) {
        v = &(p.attributes.joint);
    } else if ((pos = Compare(attr, "JOINTMATRIX"))) {
        v = &(p.attributes.jointmatrix);
    } else if ((pos = Compare(attr, "WEIGHT"))) {
        v = &(p.attributes.weight);
    } else
        return false;
    return true;
}

inline bool GetAttribTargetVector(Mesh::Primitive &p, const int targetIndex, const char *attr, Mesh::AccessorList *&v, int &pos) {
    if ((pos = Compare(attr, "POSITION"))) {
        v = &(p.targets[targetIndex].position);
    } else if ((pos = Compare(attr, "NORMAL"))) {
        v = &(p.targets[targetIndex].normal);
    } else if ((pos = Compare(attr, "TANGENT"))) {
        v = &(p.targets[targetIndex].tangent);
    } else
        return false;
    return true;
}
} // namespace

inline void Mesh::Read(Value &pJSON_Object, Asset &pAsset_Root) {
    Value *curName = FindMember(pJSON_Object, "name");
    if (nullptr != curName) {
        name = curName->GetString();
    }

    /****************** Mesh primitives ******************/
    Value *curPrimitives = FindArray(pJSON_Object, "primitives");
    if (nullptr != curPrimitives) {
        this->primitives.resize(curPrimitives->Size());
        for (unsigned int i = 0; i < curPrimitives->Size(); ++i) {
            Value &primitive = (*curPrimitives)[i];

            Primitive &prim = this->primitives[i];
            prim.mode = MemberOrDefault(primitive, "mode", PrimitiveMode_TRIANGLES);

            if (Value *attrs = FindObject(primitive, "attributes")) {
                for (Value::MemberIterator it = attrs->MemberBegin(); it != attrs->MemberEnd(); ++it) {
                    if (!it->value.IsUint()) continue;
                    const char *attr = it->name.GetString();
                    // Valid attribute semantics include POSITION, NORMAL, TANGENT, TEXCOORD, COLOR, JOINT, JOINTMATRIX,
                    // and WEIGHT.Attribute semantics can be of the form[semantic]_[set_index], e.g., TEXCOORD_0, TEXCOORD_1, etc.

                    int undPos = 0;
                    Mesh::AccessorList *vec = 0;
                    if (GetAttribVector(prim, attr, vec, undPos)) {
                        size_t idx = (attr[undPos] == '_') ? atoi(attr + undPos + 1) : 0;
                        if ((*vec).size() <= idx) (*vec).resize(idx + 1);
                        (*vec)[idx] = pAsset_Root.accessors.Retrieve(it->value.GetUint());
                    }
                }
            }

            Value *targetsArray = FindArray(primitive, "targets");
            if (nullptr != targetsArray) {
                prim.targets.resize(targetsArray->Size());
                for (unsigned int j = 0; j < targetsArray->Size(); ++j) {
                    Value &target = (*targetsArray)[j];
                    if (!target.IsObject()) {
                        continue;
                    }
                    for (Value::MemberIterator it = target.MemberBegin(); it != target.MemberEnd(); ++it) {
                        if (!it->value.IsUint()) {
                            continue;
                        }
                        const char *attr = it->name.GetString();
                        // Valid attribute semantics include POSITION, NORMAL, TANGENT
                        int undPos = 0;
                        Mesh::AccessorList *vec = 0;
                        if (GetAttribTargetVector(prim, j, attr, vec, undPos)) {
                            size_t idx = (attr[undPos] == '_') ? atoi(attr + undPos + 1) : 0;
                            if ((*vec).size() <= idx) {
                                (*vec).resize(idx + 1);
                            }
                            (*vec)[idx] = pAsset_Root.accessors.Retrieve(it->value.GetUint());
                        }
                    }
                }
            }

            if (Value *indices = FindUInt(primitive, "indices")) {
                prim.indices = pAsset_Root.accessors.Retrieve(indices->GetUint());
            }

            if (Value *material = FindUInt(primitive, "material")) {
                prim.material = pAsset_Root.materials.Retrieve(material->GetUint());
            }
        }
    }

    Value *curWeights = FindArray(pJSON_Object, "weights");
    if (nullptr != curWeights) {
        this->weights.resize(curWeights->Size());
        for (unsigned int i = 0; i < curWeights->Size(); ++i) {
            Value &weightValue = (*curWeights)[i];
            if (weightValue.IsNumber()) {
                this->weights[i] = weightValue.GetFloat();
            }
        }
    }

    Value *extras = FindObject(pJSON_Object, "extras");
    if (nullptr != extras) {
        if (Value *curTargetNames = FindArray(*extras, "targetNames")) {
            this->targetNames.resize(curTargetNames->Size());
            for (unsigned int i = 0; i < curTargetNames->Size(); ++i) {
                Value &targetNameValue = (*curTargetNames)[i];
                if (targetNameValue.IsString()) {
                    this->targetNames[i] = targetNameValue.GetString();
                }
            }
        }
    }
}

inline void Camera::Read(Value &obj, Asset & /*r*/) {
    std::string type_string = std::string(MemberOrDefault(obj, "type", "perspective"));
    if (type_string == "orthographic") {
        type = Camera::Orthographic;
    } else {
        type = Camera::Perspective;
    }

    const char *subobjId = (type == Camera::Orthographic) ? "orthographic" : "perspective";

    Value *it = FindObject(obj, subobjId);
    if (!it) throw DeadlyImportError("GLTF: Camera missing its parameters");

    if (type == Camera::Perspective) {
        cameraProperties.perspective.aspectRatio = MemberOrDefault(*it, "aspectRatio", 0.f);
        cameraProperties.perspective.yfov = MemberOrDefault(*it, "yfov", 3.1415f / 2.f);
        cameraProperties.perspective.zfar = MemberOrDefault(*it, "zfar", 100.f);
        cameraProperties.perspective.znear = MemberOrDefault(*it, "znear", 0.01f);
    } else {
        cameraProperties.ortographic.xmag = MemberOrDefault(*it, "xmag", 1.f);
        cameraProperties.ortographic.ymag = MemberOrDefault(*it, "ymag", 1.f);
        cameraProperties.ortographic.zfar = MemberOrDefault(*it, "zfar", 100.f);
        cameraProperties.ortographic.znear = MemberOrDefault(*it, "znear", 0.01f);
    }
}

inline void Light::Read(Value &obj, Asset & /*r*/) {
#ifndef M_PI
    const float M_PI = 3.14159265358979323846f;
#endif

    std::string type_string;
    ReadMember(obj, "type", type_string);
    if (type_string == "directional")
        type = Light::Directional;
    else if (type_string == "point")
        type = Light::Point;
    else
        type = Light::Spot;

    name = MemberOrDefault(obj, "name", "");

    SetVector(color, vec3{ 1.0f, 1.0f, 1.0f });
    ReadMember(obj, "color", color);

    intensity = MemberOrDefault(obj, "intensity", 1.0f);

    ReadMember(obj, "range", range);

    if (type == Light::Spot) {
        Value *spot = FindObject(obj, "spot");
        if (!spot) throw DeadlyImportError("GLTF: Light missing its spot parameters");
        innerConeAngle = MemberOrDefault(*spot, "innerConeAngle", 0.0f);
        outerConeAngle = MemberOrDefault(*spot, "outerConeAngle", M_PI / 4.0f);
    }
}

inline CustomExtension ReadExtensions(const char *name, Value& obj) {
    CustomExtension ret;
    ret.name = name;
    if (obj.IsObject()) {
        ret.mValues.isPresent = true;
        for (auto it = obj.MemberBegin(); it != obj.MemberEnd(); ++it) {
            auto& val = it->value;
            ret.mValues.value.push_back(ReadExtensions(it->name.GetString(), val));
        }
    }
    else if (obj.IsArray()) {
        ret.mValues.value.reserve(obj.Size());
        ret.mValues.isPresent = true;
        for (unsigned int i = 0; i < obj.Size(); ++i)
        {
            ret.mValues.value.push_back(ReadExtensions(name, obj[i]));
        }
    }
    else if (obj.IsNumber()) {
        if (obj.IsUint64()) {
            ret.mUint64Value.value = obj.GetUint64();
            ret.mUint64Value.isPresent = true;
        } else if (obj.IsInt64()) {
            ret.mInt64Value.value = obj.GetInt64();
            ret.mInt64Value.isPresent = true;
        } else if (obj.IsDouble()) {
            ret.mDoubleValue.value = obj.GetDouble();
            ret.mDoubleValue.isPresent = true;
        }
    }
    else if (obj.IsString()) {
        ReadValue(obj, ret.mStringValue);
        ret.mStringValue.isPresent = true;
    }
    else if (obj.IsBool()) {
        ret.mBoolValue.value = obj.GetBool();
        ret.mBoolValue.isPresent = true;
    }
    return ret;
}

inline void Node::Read(Value &obj, Asset &r) {
    if (name.empty()) {
        name = id;
    }

    Value *curChildren = FindArray(obj, "children");
    if (nullptr != curChildren) {
        this->children.reserve(curChildren->Size());
        for (unsigned int i = 0; i < curChildren->Size(); ++i) {
            Value &child = (*curChildren)[i];
            if (child.IsUint()) {
                // get/create the child node
                Ref<Node> chn = r.nodes.Retrieve(child.GetUint());
                if (chn) {
                    this->children.push_back(chn);
                }
            }
        }
    }

    Value *curMatrix = FindArray(obj, "matrix");
    if (nullptr != curMatrix) {
        ReadValue(*curMatrix, this->matrix);
    } else {
        ReadMember(obj, "translation", translation);
        ReadMember(obj, "scale", scale);
        ReadMember(obj, "rotation", rotation);
    }

    Value *curMesh = FindUInt(obj, "mesh");
    if (nullptr != curMesh) {
        unsigned int numMeshes = 1;
        this->meshes.reserve(numMeshes);
        Ref<Mesh> meshRef = r.meshes.Retrieve((*curMesh).GetUint());
        if (meshRef) {
            this->meshes.push_back(meshRef);
        }
    }

	// Do not retrieve a skin here, just take a reference, to avoid infinite recursion
    // Skins will be properly loaded later
    Value *curSkin = FindUInt(obj, "skin");
    if (nullptr != curSkin) {
        this->skin = r.skins.Get(curSkin->GetUint());
    }

    Value *curCamera = FindUInt(obj, "camera");
    if (nullptr != curCamera) {
        this->camera = r.cameras.Retrieve(curCamera->GetUint());
        if (this->camera) {
            this->camera->id = this->id;
        }
    }

    Value *curExtensions = FindObject(obj, "extensions");
    if (nullptr != curExtensions) {
        this->extensions = ReadExtensions("extensions", *curExtensions);

        if (r.extensionsUsed.KHR_lights_punctual) {
            if (Value *ext = FindObject(*curExtensions, "KHR_lights_punctual")) {
                Value *curLight = FindUInt(*ext, "light");
                if (nullptr != curLight) {
                    this->light = r.lights.Retrieve(curLight->GetUint());
                    if (this->light) {
                        this->light->id = this->id;
                    }
                }
            }
        }
    }
}

inline void Scene::Read(Value &obj, Asset &r) {
    if (Value *array = FindArray(obj, "nodes")) {
        for (unsigned int i = 0; i < array->Size(); ++i) {
            if (!(*array)[i].IsUint()) continue;
            Ref<Node> node = r.nodes.Retrieve((*array)[i].GetUint());
            if (node)
                this->nodes.push_back(node);
        }
    }
}

inline void Skin::Read(Value &obj, Asset &r) {
    if (Value *matrices = FindUInt(obj, "inverseBindMatrices")) {
        inverseBindMatrices = r.accessors.Retrieve(matrices->GetUint());
    }

    if (Value *joints = FindArray(obj, "joints")) {
        for (unsigned i = 0; i < joints->Size(); ++i) {
            if (!(*joints)[i].IsUint()) continue;
            Ref<Node> node = r.nodes.Retrieve((*joints)[i].GetUint());
            if (node) {
                this->jointNames.push_back(node);
            }
        }
    }
}

inline void Animation::Read(Value &obj, Asset &r) {
    Value *curSamplers = FindArray(obj, "samplers");
    if (nullptr != curSamplers) {
        for (unsigned i = 0; i < curSamplers->Size(); ++i) {
            Value &sampler = (*curSamplers)[i];

            Sampler s;
            if (Value *input = FindUInt(sampler, "input")) {
                s.input = r.accessors.Retrieve(input->GetUint());
            }
            if (Value *output = FindUInt(sampler, "output")) {
                s.output = r.accessors.Retrieve(output->GetUint());
            }
            s.interpolation = Interpolation_LINEAR;
            if (Value *interpolation = FindString(sampler, "interpolation")) {
                const std::string interp = interpolation->GetString();
                if (interp == "LINEAR") {
                    s.interpolation = Interpolation_LINEAR;
                } else if (interp == "STEP") {
                    s.interpolation = Interpolation_STEP;
                } else if (interp == "CUBICSPLINE") {
                    s.interpolation = Interpolation_CUBICSPLINE;
                }
            }
            this->samplers.push_back(s);
        }
    }

    Value *curChannels = FindArray(obj, "channels");
    if (nullptr != curChannels) {
        for (unsigned i = 0; i < curChannels->Size(); ++i) {
            Value &channel = (*curChannels)[i];

            Channel c;
            Value *curSampler = FindUInt(channel, "sampler");
            if (nullptr != curSampler) {
                c.sampler = curSampler->GetUint();
            }

            if (Value *target = FindObject(channel, "target")) {
                if (Value *node = FindUInt(*target, "node")) {
                    c.target.node = r.nodes.Retrieve(node->GetUint());
                }
                if (Value *path = FindString(*target, "path")) {
                    const std::string p = path->GetString();
                    if (p == "translation") {
                        c.target.path = AnimationPath_TRANSLATION;
                    } else if (p == "rotation") {
                        c.target.path = AnimationPath_ROTATION;
                    } else if (p == "scale") {
                        c.target.path = AnimationPath_SCALE;
                    } else if (p == "weights") {
                        c.target.path = AnimationPath_WEIGHTS;
                    }
                }
            }
            this->channels.push_back(c);
        }
    }
}

inline void AssetMetadata::Read(Document &doc) {
    if (Value *obj = FindObject(doc, "asset")) {
        ReadMember(*obj, "copyright", copyright);
        ReadMember(*obj, "generator", generator);

        if (Value *versionString = FindString(*obj, "version")) {
            version = versionString->GetString();
        } else if (Value *versionNumber = FindNumber(*obj, "version")) {
            char buf[4];

            ai_snprintf(buf, 4, "%.1f", versionNumber->GetDouble());

            version = buf;
        }

        Value *curProfile = FindObject(*obj, "profile");
        if (nullptr != curProfile) {
            ReadMember(*curProfile, "api", this->profile.api);
            ReadMember(*curProfile, "version", this->profile.version);
        }
    }

    if (version.empty() || version[0] != '2') {
        throw DeadlyImportError("GLTF: Unsupported glTF version: " + version);
    }
}

//
// Asset methods implementation
//

inline void Asset::ReadBinaryHeader(IOStream &stream, std::vector<char> &sceneData) {
    ASSIMP_LOG_DEBUG("Reading GLTF2 binary");
    GLB_Header header;
    if (stream.Read(&header, sizeof(header), 1) != 1) {
        throw DeadlyImportError("GLTF: Unable to read the file header");
    }

    if (strncmp((char *)header.magic, AI_GLB_MAGIC_NUMBER, sizeof(header.magic)) != 0) {
        throw DeadlyImportError("GLTF: Invalid binary glTF file");
    }

    AI_SWAP4(header.version);
    asset.version = to_string(header.version);
    if (header.version != 2) {
        throw DeadlyImportError("GLTF: Unsupported binary glTF version");
    }

    GLB_Chunk chunk;
    if (stream.Read(&chunk, sizeof(chunk), 1) != 1) {
        throw DeadlyImportError("GLTF: Unable to read JSON chunk");
    }

    AI_SWAP4(chunk.chunkLength);
    AI_SWAP4(chunk.chunkType);

    if (chunk.chunkType != ChunkType_JSON) {
        throw DeadlyImportError("GLTF: JSON chunk missing");
    }

    // read the scene data

    mSceneLength = chunk.chunkLength;
    sceneData.resize(mSceneLength + 1);
    sceneData[mSceneLength] = '\0';

    if (stream.Read(&sceneData[0], 1, mSceneLength) != mSceneLength) {
        throw DeadlyImportError("GLTF: Could not read the file contents");
    }

    uint32_t padding = ((chunk.chunkLength + 3) & ~3) - chunk.chunkLength;
    if (padding > 0) {
        stream.Seek(padding, aiOrigin_CUR);
    }

    AI_SWAP4(header.length);
    mBodyOffset = 12 + 8 + chunk.chunkLength + padding + 8;
    if (header.length >= mBodyOffset) {
        if (stream.Read(&chunk, sizeof(chunk), 1) != 1) {
            throw DeadlyImportError("GLTF: Unable to read BIN chunk");
        }

        AI_SWAP4(chunk.chunkLength);
        AI_SWAP4(chunk.chunkType);

        if (chunk.chunkType != ChunkType_BIN) {
            throw DeadlyImportError("GLTF: BIN chunk missing");
        }

        mBodyLength = chunk.chunkLength;
    } else {
        mBodyOffset = mBodyLength = 0;
    }
}

inline void Asset::Load(const std::string &pFile, bool isBinary) {
    ASSIMP_LOG_DEBUG("Loading GLTF2 asset");
    mCurrentAssetDir.clear();
    /*int pos = std::max(int(pFile.rfind('/')), int(pFile.rfind('\\')));
    if (pos != int(std::string::npos)) */

    mCurrentAssetDir = glTFCommon::getCurrentAssetDir(pFile);

    shared_ptr<IOStream> stream(OpenFile(pFile.c_str(), "rb", true));
    if (!stream) {
        throw DeadlyImportError("GLTF: Could not open file for reading");
    }

    // is binary? then read the header
    std::vector<char> sceneData;
    if (isBinary) {
        SetAsBinary(); // also creates the body buffer
        ReadBinaryHeader(*stream, sceneData);
    } else {
        mSceneLength = stream->FileSize();
        mBodyLength = 0;

        // read the scene data

        sceneData.resize(mSceneLength + 1);
        sceneData[mSceneLength] = '\0';

        if (stream->Read(&sceneData[0], 1, mSceneLength) != mSceneLength) {
            throw DeadlyImportError("GLTF: Could not read the file contents");
        }
    }

    // parse the JSON document
    ASSIMP_LOG_DEBUG("Parsing GLTF2 JSON");
    Document doc;
    doc.ParseInsitu(&sceneData[0]);

    if (doc.HasParseError()) {
        char buffer[32];
        ai_snprintf(buffer, 32, "%d", static_cast<int>(doc.GetErrorOffset()));
        throw DeadlyImportError(std::string("GLTF: JSON parse error, offset ") + buffer + ": " + GetParseError_En(doc.GetParseError()));
    }

    if (!doc.IsObject()) {
        throw DeadlyImportError("GLTF: JSON document root must be a JSON object");
    }

    // Fill the buffer instance for the current file embedded contents
    if (mBodyLength > 0) {
        if (!mBodyBuffer->LoadFromStream(*stream, mBodyLength, mBodyOffset)) {
            throw DeadlyImportError("GLTF: Unable to read gltf file");
        }
    }

    // Load the metadata
    asset.Read(doc);
    ReadExtensionsUsed(doc);
    ReadExtensionsRequired(doc);

    // Currently Draco is not supported
    if (extensionsRequired.KHR_draco_mesh_compression) {
        throw DeadlyImportError("GLTF: Draco mesh compression not currently supported.");
    }

    // Prepare the dictionaries
    for (size_t i = 0; i < mDicts.size(); ++i) {
        mDicts[i]->AttachToDocument(doc);
    }

    // Read the "scene" property, which specifies which scene to load
    // and recursively load everything referenced by it
    unsigned int sceneIndex = 0;
    Value *curScene = FindUInt(doc, "scene");
    if (nullptr != curScene) {
        sceneIndex = curScene->GetUint();
    }

    if (Value *scenesArray = FindArray(doc, "scenes")) {
        if (sceneIndex < scenesArray->Size()) {
            this->scene = scenes.Retrieve(sceneIndex);
        }
    }

    if (Value *skinsArray = FindArray(doc, "skins")) {
        for (unsigned int i = 0; i < skinsArray->Size(); ++i) {
            skins.Retrieve(i);
        }
    }

    if (Value *animsArray = FindArray(doc, "animations")) {
        for (unsigned int i = 0; i < animsArray->Size(); ++i) {
            animations.Retrieve(i);
        }
    }

    // Clean up
    for (size_t i = 0; i < mDicts.size(); ++i) {
        mDicts[i]->DetachFromDocument();
    }
}

inline void Asset::SetAsBinary() {
    if (!mBodyBuffer) {
        mBodyBuffer = buffers.Create("binary_glTF");
        mBodyBuffer->MarkAsSpecial();
    }
}

// As required extensions are only a concept in glTF 2.0, this is here
// instead of glTFCommon.h
#define CHECK_REQUIRED_EXT(EXT) \
    if (exts.find(#EXT) != exts.end()) extensionsRequired.EXT = true;

inline void Asset::ReadExtensionsRequired(Document &doc) {
    Value *extsRequired = FindArray(doc, "extensionsRequired");
    if (nullptr == extsRequired) {
        return;
    }

    std::gltf_unordered_map<std::string, bool> exts;
    for (unsigned int i = 0; i < extsRequired->Size(); ++i) {
        if ((*extsRequired)[i].IsString()) {
            exts[(*extsRequired)[i].GetString()] = true;
        }
    }

    CHECK_REQUIRED_EXT(KHR_draco_mesh_compression);

#undef CHECK_REQUIRED_EXT
}

inline void Asset::ReadExtensionsUsed(Document &doc) {
    Value *extsUsed = FindArray(doc, "extensionsUsed");
    if (!extsUsed) return;

    std::gltf_unordered_map<std::string, bool> exts;

    for (unsigned int i = 0; i < extsUsed->Size(); ++i) {
        if ((*extsUsed)[i].IsString()) {
            exts[(*extsUsed)[i].GetString()] = true;
        }
    }

    CHECK_EXT(KHR_materials_pbrSpecularGlossiness);
    CHECK_EXT(KHR_materials_unlit);
    CHECK_EXT(KHR_lights_punctual);
    CHECK_EXT(KHR_texture_transform);

#undef CHECK_EXT
}

inline IOStream *Asset::OpenFile(std::string path, const char *mode, bool /*absolute*/) {
#ifdef ASSIMP_API
    return mIOSystem->Open(path, mode);
#else
    if (path.size() < 2) return 0;
    if (!absolute && path[1] != ':' && path[0] != '/') { // relative?
        path = mCurrentAssetDir + path;
    }
    FILE *f = fopen(path.c_str(), mode);
    return f ? new IOStream(f) : 0;
#endif
}

inline std::string Asset::FindUniqueID(const std::string &str, const char *suffix) {
    std::string id = str;

    if (!id.empty()) {
        if (mUsedIds.find(id) == mUsedIds.end())
            return id;

        id += "_";
    }

    id += suffix;

    Asset::IdMap::iterator it = mUsedIds.find(id);
    if (it == mUsedIds.end()) {
        return id;
    }

    std::vector<char> buffer;
    buffer.resize(id.size() + 16);
    int offset = ai_snprintf(buffer.data(), buffer.size(), "%s_", id.c_str());
    for (int i = 0; it != mUsedIds.end(); ++i) {
        ai_snprintf(buffer.data() + offset, buffer.size() - offset, "%d", i);
        id = buffer.data();
        it = mUsedIds.find(id);
    }

    return id;
}

#if _MSC_VER
#   pragma warning(pop)
#endif // _MSC_VER

} // namespace glTF2