#pragma once #include #include "util/base64.h" #include #include #include #include #include #include #include #include #include #include #include #include #include namespace tiniergltf { static inline void check(bool cond) { if (!cond) throw std::runtime_error("invalid glTF"); } template static inline void checkIndex(const std::optional> &vec, const std::optional &i) { if (!i.has_value()) return; check(vec.has_value()); check(i < vec->size()); } template static inline void checkIndex(const std::vector &vec, const std::optional &i) { if (!i.has_value()) return; check(i < vec.size()); } template static inline void checkForall(const std::optional> &vec, const F &cond) { if (!vec.has_value()) return; for (const T &v : vec.value()) cond(v); } template static inline void checkDuplicateFree(const std::vector &vec) { check(std::unordered_set(vec.begin(), vec.end()).size() == vec.size()); } template static inline T as(const Json::Value &o); template<> bool as(const Json::Value &o) { check(o.isBool()); return o.asBool(); } template<> double as (const Json::Value &o) { check(o.isDouble()); return o.asDouble(); } template<> std::size_t as(const Json::Value &o) { check(o.isUInt64()); auto u = o.asUInt64(); check(u <= std::numeric_limits::max()); return u; } template<> std::string as(const Json::Value &o) { check(o.isString()); return o.asString(); } template std::vector asVec(const Json::Value &o) { check(o.isArray()); std::vector res; res.reserve(o.size()); for (Json::ArrayIndex i = 0; i < o.size(); ++i) { res.push_back(as(o[i])); } return res; } template std::array asArr(const Json::Value &o) { check(o.isArray()); check(o.size() == n); std::array res; for (Json::ArrayIndex i = 0; i < n; ++i) { res[i] = as(o[i]); } return res; } struct AccessorSparseIndices { std::size_t bufferView; std::size_t byteOffset; // as defined in the glTF specification enum class ComponentType { UNSIGNED_BYTE, UNSIGNED_SHORT, UNSIGNED_INT, }; ComponentType componentType; std::size_t componentSize() const { switch (componentType) { case ComponentType::UNSIGNED_BYTE: return 1; case ComponentType::UNSIGNED_SHORT: return 2; case ComponentType::UNSIGNED_INT: return 4; } throw std::logic_error("invalid component type"); } std::size_t elementSize() const { return componentSize(); } AccessorSparseIndices(const Json::Value &o) : bufferView(as(o["bufferView"])) , byteOffset(0) { check(o.isObject()); if (o.isMember("byteOffset")) { byteOffset = as(o["byteOffset"]); check(byteOffset >= 0); } { static std::unordered_map map = { {5121, ComponentType::UNSIGNED_BYTE}, {5123, ComponentType::UNSIGNED_SHORT}, {5125, ComponentType::UNSIGNED_INT}, }; const auto &v = o["componentType"]; check(v.isUInt64()); componentType = map.at(v.asUInt64()); } } }; template<> AccessorSparseIndices as(const Json::Value &o) { return o; } struct AccessorSparseValues { std::size_t bufferView; std::size_t byteOffset; AccessorSparseValues(const Json::Value &o) : bufferView(as(o["bufferView"])) , byteOffset(0) { check(o.isObject()); if (o.isMember("byteOffset")) { byteOffset = as(o["byteOffset"]); check(byteOffset >= 0); } } }; template<> AccessorSparseValues as(const Json::Value &o) { return o; } struct AccessorSparse { std::size_t count; AccessorSparseIndices indices; AccessorSparseValues values; AccessorSparse(const Json::Value &o) : count(as(o["count"])) , indices(as(o["indices"])) , values(as(o["values"])) { check(o.isObject()); check(count >= 1); } }; template<> AccessorSparse as(const Json::Value &o) { return o; } struct Accessor { std::optional bufferView; std::size_t byteOffset; // as defined in the glTF specification enum class ComponentType { BYTE, UNSIGNED_BYTE, SHORT, UNSIGNED_SHORT, UNSIGNED_INT, FLOAT, }; ComponentType componentType; std::size_t componentSize() const { switch (componentType) { case ComponentType::BYTE: case ComponentType::UNSIGNED_BYTE: return 1; case ComponentType::SHORT: case ComponentType::UNSIGNED_SHORT: return 2; case ComponentType::UNSIGNED_INT: case ComponentType::FLOAT: return 4; } throw std::logic_error("invalid component type"); } std::size_t count; std::optional> max; std::optional> min; std::optional name; bool normalized; std::optional sparse; enum class Type { MAT2, MAT3, MAT4, SCALAR, VEC2, VEC3, VEC4, }; std::size_t typeCount() const { switch (type) { case Type::SCALAR: return 1; case Type::VEC2: return 2; case Type::VEC3: return 3; case Type::MAT2: case Type::VEC4: return 4; case Type::MAT3: return 9; case Type::MAT4: return 16; } throw std::logic_error("invalid type"); } Type type; std::size_t elementSize() const { return componentSize() * typeCount(); } Accessor(const Json::Value &o) : byteOffset(0) , count(as(o["count"])) , normalized(false) { check(o.isObject()); if (o.isMember("bufferView")) { bufferView = as(o["bufferView"]); } { static std::unordered_map map = { {5120, ComponentType::BYTE}, {5121, ComponentType::UNSIGNED_BYTE}, {5122, ComponentType::SHORT}, {5123, ComponentType::UNSIGNED_SHORT}, {5125, ComponentType::UNSIGNED_INT}, {5126, ComponentType::FLOAT}, }; const auto &v = o["componentType"]; check(v.isUInt64()); componentType = map.at(v.asUInt64()); } if (o.isMember("byteOffset")) { byteOffset = as(o["byteOffset"]); check(byteOffset >= 0); check(byteOffset % componentSize() == 0); } check(count >= 1); if (o.isMember("name")) { name = as(o["name"]); } if (o.isMember("normalized")) { normalized = as(o["normalized"]); } if (o.isMember("sparse")) { sparse = as(o["sparse"]); } { static std::unordered_map map = { {"MAT2", Type::MAT2}, {"MAT3", Type::MAT3}, {"MAT4", Type::MAT4}, {"SCALAR", Type::SCALAR}, {"VEC2", Type::VEC2}, {"VEC3", Type::VEC3}, {"VEC4", Type::VEC4}, }; const auto &v = o["type"]; check(v.isString()); type = map.at(v.asString()); } if (o.isMember("max")) { max = asVec(o["max"]); check(max->size() == typeCount()); } if (o.isMember("min")) { min = asVec(o["min"]); check(min->size() == typeCount()); } } }; template<> Accessor as(const Json::Value &o) { return o; } struct AnimationChannelTarget { std::optional node; enum class Path { ROTATION, SCALE, TRANSLATION, WEIGHTS, }; Path path; AnimationChannelTarget(const Json::Value &o) { check(o.isObject()); if (o.isMember("node")) { node = as(o["node"]); } { static std::unordered_map map = { {"rotation", Path::ROTATION}, {"scale", Path::SCALE}, {"translation", Path::TRANSLATION}, {"weights", Path::WEIGHTS}, }; const auto &v = o["path"]; check(v.isString()); path = map.at(v.asString()); } } }; template<> AnimationChannelTarget as(const Json::Value &o) { return o; } struct AnimationChannel { std::size_t sampler; AnimationChannelTarget target; AnimationChannel(const Json::Value &o) : sampler(as(o["sampler"])) , target(as(o["target"])) { check(o.isObject()); } }; template<> AnimationChannel as(const Json::Value &o) { return o; } struct AnimationSampler { std::size_t input; enum class Interpolation { CUBICSPLINE, LINEAR, STEP, }; Interpolation interpolation; std::size_t output; AnimationSampler(const Json::Value &o) : input(as(o["input"])) , interpolation(Interpolation::LINEAR) , output(as(o["output"])) { check(o.isObject()); if (o.isMember("interpolation")) { static std::unordered_map map = { {"CUBICSPLINE", Interpolation::CUBICSPLINE}, {"LINEAR", Interpolation::LINEAR}, {"STEP", Interpolation::STEP}, }; const auto &v = o["interpolation"]; check(v.isString()); interpolation = map.at(v.asString()); } } }; template<> AnimationSampler as(const Json::Value &o) { return o; } struct Animation { std::vector channels; std::optional name; std::vector samplers; Animation(const Json::Value &o) : channels(asVec(o["channels"])) , samplers(asVec(o["samplers"])) { check(o.isObject()); check(channels.size() >= 1); if (o.isMember("name")) { name = as(o["name"]); } check(samplers.size() >= 1); } }; template<> Animation as(const Json::Value &o) { return o; } struct Asset { std::optional copyright; std::optional generator; std::optional minVersion; std::string version; Asset(const Json::Value &o) : version(as(o["version"])) { check(o.isObject()); if (o.isMember("copyright")) { copyright = as(o["copyright"]); } if (o.isMember("generator")) { generator = as(o["generator"]); } if (o.isMember("minVersion")) { minVersion = as(o["minVersion"]); } } }; template<> Asset as(const Json::Value &o) { return o; } struct BufferView { std::size_t buffer; std::size_t byteLength; std::size_t byteOffset; std::optional byteStride; std::optional name; enum class Target { ARRAY_BUFFER, ELEMENT_ARRAY_BUFFER, }; std::optional target; BufferView(const Json::Value &o) : buffer(as(o["buffer"])) , byteLength(as(o["byteLength"])) , byteOffset(0) { check(o.isObject()); check(byteLength >= 1); if (o.isMember("byteOffset")) { byteOffset = as(o["byteOffset"]); check(byteOffset >= 0); } if (o.isMember("byteStride")) { byteStride = as(o["byteStride"]); check(byteStride.value() >= 4); check(byteStride.value() <= 252); check(byteStride.value() % 4 == 0); } if (o.isMember("name")) { name = as(o["name"]); } if (o.isMember("target")) { static std::unordered_map map = { {34962, Target::ARRAY_BUFFER}, {34963, Target::ELEMENT_ARRAY_BUFFER}, }; const auto &v = o["target"]; check(v.isUInt64()); target = map.at(v.asUInt64()); } } }; template<> BufferView as(const Json::Value &o) { return o; } struct Buffer { std::size_t byteLength; std::optional name; std::string data; Buffer(const Json::Value &o, const std::function &resolveURI, std::optional &&glbData = std::nullopt) : byteLength(as(o["byteLength"])) { check(o.isObject()); check(byteLength >= 1); if (o.isMember("name")) { name = as(o["name"]); } if (glbData.has_value()) { check(!o.isMember("uri")); data = *std::move(glbData); // GLB allows padding, which need not be reflected in the JSON check(byteLength + 3 >= data.size()); check(data.size() >= byteLength); } else { check(o.isMember("uri")); bool dataURI = false; const std::string uri = as(o["uri"]); for (auto &prefix : std::array { "data:application/octet-stream;base64,", "data:application/gltf-buffer;base64," }) { if (std::string_view(uri).substr(0, prefix.length()) == prefix) { auto view = std::string_view(uri).substr(prefix.length()); check(base64_is_valid(view)); data = base64_decode(view); dataURI = true; break; } } if (!dataURI) data = resolveURI(uri); check(data.size() >= byteLength); } data.resize(byteLength); } }; struct CameraOrthographic { double xmag; double ymag; double zfar; double znear; CameraOrthographic(const Json::Value &o) : xmag(as(o["xmag"])) , ymag(as(o["ymag"])) , zfar(as(o["zfar"])) , znear(as(o["znear"])) { check(o.isObject()); check(zfar > 0); check(znear >= 0); } }; template<> CameraOrthographic as(const Json::Value &o) { return o; } struct CameraPerspective { std::optional aspectRatio; double yfov; std::optional zfar; double znear; CameraPerspective(const Json::Value &o) : yfov(as(o["yfov"])) , znear(as(o["znear"])) { check(o.isObject()); if (o.isMember("aspectRatio")) { aspectRatio = as(o["aspectRatio"]); check(aspectRatio.value() > 0); } check(yfov > 0); if (o.isMember("zfar")) { zfar = as(o["zfar"]); check(zfar.value() > 0); } check(znear > 0); } }; template<> CameraPerspective as(const Json::Value &o) { return o; } struct Camera { std::optional name; std::optional orthographic; std::optional perspective; enum class Type { ORTHOGRAPHIC, PERSPECTIVE, }; Type type; Camera(const Json::Value &o) { check(o.isObject()); if (o.isMember("name")) { name = as(o["name"]); } if (o.isMember("orthographic")) { orthographic = as(o["orthographic"]); } if (o.isMember("perspective")) { perspective = as(o["perspective"]); } { static std::unordered_map map = { {"orthographic", Type::ORTHOGRAPHIC}, {"perspective", Type::PERSPECTIVE}, }; const auto &v = o["type"]; check(v.isString()); type = map.at(v.asString()); } } }; template<> Camera as(const Json::Value &o) { return o; } struct Image { std::optional bufferView; enum class MimeType { IMAGE_JPEG, IMAGE_PNG, }; std::optional mimeType; std::optional name; std::optional uri; Image(const Json::Value &o) { check(o.isObject()); if (o.isMember("bufferView")) { bufferView = as(o["bufferView"]); } if (o.isMember("mimeType")) { static std::unordered_map map = { {"image/jpeg", MimeType::IMAGE_JPEG}, {"image/png", MimeType::IMAGE_PNG}, }; const auto &v = o["mimeType"]; check(v.isString()); mimeType = map.at(v.asString()); } if (o.isMember("name")) { name = as(o["name"]); } if (o.isMember("uri")) { uri = as(o["uri"]); } } }; template<> Image as(const Json::Value &o) { return o; } struct TextureInfo { std::size_t index; std::size_t texCoord; TextureInfo(const Json::Value &o) : index(as(o["index"])) , texCoord(0) { check(o.isObject()); if (o.isMember("texCoord")) { texCoord = as(o["texCoord"]); check(texCoord >= 0); } } }; template<> TextureInfo as(const Json::Value &o) { return o; } struct MaterialNormalTextureInfo { std::size_t index; double scale; std::size_t texCoord; MaterialNormalTextureInfo(const Json::Value &o) : index(as(o["index"])) , scale(1) , texCoord(0) { check(o.isObject()); if (o.isMember("scale")) { scale = as(o["scale"]); } if (o.isMember("texCoord")) { texCoord = as(o["texCoord"]); } } }; template<> MaterialNormalTextureInfo as(const Json::Value &o) { return o; } struct MaterialOcclusionTextureInfo { std::size_t index; double strength; std::size_t texCoord; MaterialOcclusionTextureInfo(const Json::Value &o) : index(as(o["index"])) , strength(1) , texCoord(0) { check(o.isObject()); if (o.isMember("strength")) { strength = as(o["strength"]); check(strength >= 0); check(strength <= 1); } if (o.isMember("texCoord")) { texCoord = as(o["texCoord"]); } } }; template<> MaterialOcclusionTextureInfo as(const Json::Value &o) { return o; } struct MaterialPbrMetallicRoughness { std::array baseColorFactor; std::optional baseColorTexture; double metallicFactor; std::optional metallicRoughnessTexture; double roughnessFactor; MaterialPbrMetallicRoughness(const Json::Value &o) : baseColorFactor{1, 1, 1, 1} , metallicFactor(1) , roughnessFactor(1) { check(o.isObject()); if (o.isMember("baseColorFactor")) { baseColorFactor = asArr(o["baseColorFactor"]); for (auto v: baseColorFactor) { check(v >= 0); check(v <= 1); } } if (o.isMember("baseColorTexture")) { baseColorTexture = as(o["baseColorTexture"]); } if (o.isMember("metallicFactor")) { metallicFactor = as(o["metallicFactor"]); check(metallicFactor >= 0); check(metallicFactor <= 1); } if (o.isMember("metallicRoughnessTexture")) { metallicRoughnessTexture = as(o["metallicRoughnessTexture"]); } if (o.isMember("roughnessFactor")) { roughnessFactor = as(o["roughnessFactor"]); check(roughnessFactor >= 0); check(roughnessFactor <= 1); } } }; template<> MaterialPbrMetallicRoughness as(const Json::Value &o) { return o; } struct Material { double alphaCutoff; enum class AlphaMode { BLEND, MASK, OPAQUE, }; AlphaMode alphaMode; bool doubleSided; std::array emissiveFactor; std::optional emissiveTexture; std::optional name; std::optional normalTexture; std::optional occlusionTexture; std::optional pbrMetallicRoughness; Material(const Json::Value &o) : alphaCutoff(0.5) , alphaMode(AlphaMode::OPAQUE) , doubleSided(false) , emissiveFactor{0, 0, 0} { check(o.isObject()); if (o.isMember("alphaCutoff")) { alphaCutoff = as(o["alphaCutoff"]); check(alphaCutoff >= 0); } if (o.isMember("alphaMode")){ static std::unordered_map map = { {"BLEND", AlphaMode::BLEND}, {"MASK", AlphaMode::MASK}, {"OPAQUE", AlphaMode::OPAQUE}, }; const auto &v = o["alphaMode"]; check(v.isString()); alphaMode = map.at(v.asString()); } if (o.isMember("doubleSided")) { doubleSided = as(o["doubleSided"]); } if (o.isMember("emissiveFactor")) { emissiveFactor = asArr(o["emissiveFactor"]); for (const auto &v: emissiveFactor) { check(v >= 0); check(v <= 1); } } if (o.isMember("emissiveTexture")) { emissiveTexture = as(o["emissiveTexture"]); } if (o.isMember("name")) { name = as(o["name"]); } if (o.isMember("normalTexture")) { normalTexture = as(o["normalTexture"]); } if (o.isMember("occlusionTexture")) { occlusionTexture = as(o["occlusionTexture"]); } if (o.isMember("pbrMetallicRoughness")) { pbrMetallicRoughness = as(o["pbrMetallicRoughness"]); } } }; template<> Material as(const Json::Value &o) { return o; } struct MeshPrimitive { static void enumeratedProps(const Json::Value &o, const std::string &name, std::optional> &attr) { for (std::size_t i = 0;; ++i) { const std::string s = name + "_" + std::to_string(i); if (!o.isMember(s)) break; if (i == 0) { attr = std::vector(); } attr->push_back(as(o[s])); } } struct Attributes { std::optional position, normal, tangent; std::optional> texcoord, color, joints, weights; Attributes(const Json::Value &o) { if (o.isMember("POSITION")) position = as(o["POSITION"]); if (o.isMember("NORMAL")) normal = as(o["NORMAL"]); if (o.isMember("TANGENT")) tangent = as(o["TANGENT"]); enumeratedProps(o, "TEXCOORD", texcoord); enumeratedProps(o, "COLOR", color); enumeratedProps(o, "JOINTS", joints); enumeratedProps(o, "WEIGHTS", weights); check(joints.has_value() == weights.has_value()); if (joints.has_value()) { check(joints->size() == weights->size()); } check(position.has_value() || normal.has_value() || tangent.has_value() || texcoord.has_value() || color.has_value() || joints.has_value() || weights.has_value()); } }; Attributes attributes; std::optional indices; std::optional material; enum class Mode { POINTS, LINES, LINE_LOOP, LINE_STRIP, TRIANGLES, TRIANGLE_STRIP, TRIANGLE_FAN, }; Mode mode; struct MorphTargets { std::optional position, normal, tangent; std::optional> texcoord, color; MorphTargets(const Json::Value &o) { if (o.isMember("POSITION")) position = as(o["POSITION"]); if (o.isMember("NORMAL")) normal = as(o["NORMAL"]); if (o.isMember("TANGENT")) tangent = as(o["TANGENT"]); enumeratedProps(o, "TEXCOORD", texcoord); enumeratedProps(o, "COLOR", color); check(position.has_value() || normal.has_value() || tangent.has_value() || texcoord.has_value() || color.has_value()); } }; std::optional> targets; MeshPrimitive(const Json::Value &o) : attributes(Attributes(o["attributes"])) , mode(Mode::TRIANGLES) { check(o.isObject()); if (o.isMember("indices")) { indices = as(o["indices"]); } if (o.isMember("material")) { material = as(o["material"]); } if (o.isMember("mode")) { static std::unordered_map map = { {0, Mode::POINTS}, {1, Mode::LINES}, {2, Mode::LINE_LOOP}, {3, Mode::LINE_STRIP}, {4, Mode::TRIANGLES}, {5, Mode::TRIANGLE_STRIP}, {6, Mode::TRIANGLE_FAN}, }; const auto &v = o["mode"]; check(v.isUInt64()); mode = map.at(v.asUInt64()); } if (o.isMember("targets")) { targets = asVec(o["targets"]); check(targets->size() >= 1); } } }; template<> MeshPrimitive::MorphTargets as(const Json::Value &o) { return o; } template<> MeshPrimitive as(const Json::Value &o) { return o; } struct Mesh { std::optional name; std::vector primitives; std::optional> weights; Mesh(const Json::Value &o) : primitives(asVec(o["primitives"])) { check(o.isObject()); if (o.isMember("name")) { name = as(o["name"]); } check(primitives.size() >= 1); if (o.isMember("weights")) { weights = asVec(o["weights"]); check(weights->size() >= 1); } } }; template<> Mesh as(const Json::Value &o) { return o; } struct Node { std::optional camera; std::optional> children; typedef std::array Matrix; struct TRS { std::array translation = {0, 0, 0}; std::array rotation = {0, 0, 0, 1}; std::array scale = {1, 1, 1}; }; std::variant transform; std::optional mesh; std::optional name; std::optional skin; std::optional> weights; Node(const Json::Value &o) : transform(Matrix { 1, 0, 0, 0, 0, 1, 0, 0, 0, 0, 1, 0, 0, 0, 0, 1 }) { check(o.isObject()); if (o.isMember("camera")) { camera = as(o["camera"]); } if (o.isMember("children")) { children = asVec(o["children"]); check(children->size() >= 1); checkDuplicateFree(*children); } bool hasTRS = o.isMember("translation") || o.isMember("rotation") || o.isMember("scale"); if (o.isMember("matrix")) { check(!hasTRS); transform = asArr(o["matrix"]); } else if (hasTRS) { TRS trs; if (o.isMember("translation")) { trs.translation = asArr(o["translation"]); } if (o.isMember("rotation")) { trs.rotation = asArr(o["rotation"]); for (auto v: trs.rotation) { check(v >= -1); check(v <= 1); } } if (o.isMember("scale")) { trs.scale = asArr(o["scale"]); } transform = trs; } if (o.isMember("mesh")) { mesh = as(o["mesh"]); } if (o.isMember("name")) { name = as(o["name"]); } if (o.isMember("skin")) { check(mesh.has_value()); skin = as(o["skin"]); } if (o.isMember("weights")) { weights = asVec(o["weights"]); check(weights->size() >= 1); } } }; template<> Node as(const Json::Value &o) { return o; } struct Sampler { enum class MagFilter { NEAREST, LINEAR, }; std::optional magFilter; enum class MinFilter { NEAREST, LINEAR, NEAREST_MIPMAP_NEAREST, LINEAR_MIPMAP_NEAREST, NEAREST_MIPMAP_LINEAR, LINEAR_MIPMAP_LINEAR, }; std::optional minFilter; std::optional name; enum class Wrap { REPEAT, CLAMP_TO_EDGE, MIRRORED_REPEAT, }; Wrap wrapS; Wrap wrapT; Sampler(const Json::Value &o) : wrapS(Wrap::REPEAT) , wrapT(Wrap::REPEAT) { check(o.isObject()); if (o.isMember("magFilter")) { static std::unordered_map map = { {9728, MagFilter::NEAREST}, {9729, MagFilter::LINEAR}, }; const auto &v = o["magFilter"]; check(v.isUInt64()); magFilter = map.at(v.asUInt64()); } if (o.isMember("minFilter")) { static std::unordered_map map = { {9728, MinFilter::NEAREST}, {9729, MinFilter::LINEAR}, {9984, MinFilter::NEAREST_MIPMAP_NEAREST}, {9985, MinFilter::LINEAR_MIPMAP_NEAREST}, {9986, MinFilter::NEAREST_MIPMAP_LINEAR}, {9987, MinFilter::LINEAR_MIPMAP_LINEAR}, }; const auto &v = o["minFilter"]; check(v.isUInt64()); minFilter = map.at(v.asUInt64()); } if (o.isMember("name")) { name = as(o["name"]); } static std::unordered_map map = { {10497, Wrap::REPEAT}, {33071, Wrap::CLAMP_TO_EDGE}, {33648, Wrap::MIRRORED_REPEAT}, }; if (o.isMember("wrapS")) { const auto &v = o["wrapS"]; check(v.isUInt64()); wrapS = map.at(v.asUInt64()); } if (o.isMember("wrapT")) { const auto &v = o["wrapT"]; check(v.isUInt64()); wrapT = map.at(v.asUInt64()); } } }; template<> Sampler as(const Json::Value &o) { return o; } struct Scene { std::optional name; std::optional> nodes; Scene(const Json::Value &o) { check(o.isObject()); if (o.isMember("name")) { name = as(o["name"]); } if (o.isMember("nodes")) { nodes = asVec(o["nodes"]); check(nodes->size() >= 1); checkDuplicateFree(*nodes); } } }; template<> Scene as(const Json::Value &o) { return o; } struct Skin { std::optional inverseBindMatrices; std::vector joints; std::optional name; std::optional skeleton; Skin(const Json::Value &o) : joints(asVec(o["joints"])) { check(o.isObject()); if (o.isMember("inverseBindMatrices")) { inverseBindMatrices = as(o["inverseBindMatrices"]); } check(joints.size() >= 1); checkDuplicateFree(joints); if (o.isMember("name")) { name = as(o["name"]); } if (o.isMember("skeleton")) { skeleton = as(o["skeleton"]); } } }; template<> Skin as(const Json::Value &o) { return o; } struct Texture { std::optional name; std::optional sampler; std::optional source; Texture(const Json::Value &o) { check(o.isObject()); if (o.isMember("name")) { name = as(o["name"]); } if (o.isMember("sampler")) { sampler = as(o["sampler"]); } if (o.isMember("source")) { source = as(o["source"]); } } }; template<> Texture as(const Json::Value &o) { return o; } using UriResolver = std::function; static inline std::string uriError(const std::string &uri) { // only base64 data URI support by default throw std::runtime_error("unsupported URI: " + uri); } struct GlTF { std::optional> accessors; std::optional> animations; Asset asset; std::optional> bufferViews; std::optional> buffers; std::optional> cameras; std::optional> extensionsRequired; std::optional> extensionsUsed; std::optional> images; std::optional> materials; std::optional> meshes; std::optional> nodes; std::optional> samplers; std::optional scene; std::optional> scenes; std::optional> skins; std::optional> textures; GlTF(const Json::Value &o, const UriResolver &resolveUri = uriError, std::optional &&glbData = std::nullopt) : asset(as(o["asset"])) { check(o.isObject()); if (o.isMember("accessors")) { accessors = asVec(o["accessors"]); check(accessors->size() >= 1); } if (o.isMember("animations")) { animations = asVec(o["animations"]); check(animations->size() >= 1); } if (o.isMember("bufferViews")) { bufferViews = asVec(o["bufferViews"]); check(bufferViews->size() >= 1); } if (o.isMember("buffers")) { auto b = o["buffers"]; check(b.isArray()); std::vector bufs; bufs.reserve(b.size()); for (Json::ArrayIndex i = 0; i < b.size(); ++i) { bufs.emplace_back(b[i], resolveUri, i == 0 ? std::move(glbData) : std::nullopt); } check(bufs.size() >= 1); buffers = std::move(bufs); } if (o.isMember("cameras")) { cameras = asVec(o["cameras"]); check(cameras->size() >= 1); } if (o.isMember("extensionsRequired")) { extensionsRequired = asVec(o["extensionsRequired"]); check(extensionsRequired->size() >= 1); checkDuplicateFree(*extensionsRequired); } if (o.isMember("extensionsUsed")) { extensionsUsed = asVec(o["extensionsUsed"]); check(extensionsUsed->size() >= 1); checkDuplicateFree(*extensionsUsed); } if (o.isMember("images")) { images = asVec(o["images"]); check(images->size() >= 1); } if (o.isMember("materials")) { materials = asVec(o["materials"]); check(materials->size() >= 1); } if (o.isMember("meshes")) { meshes = asVec(o["meshes"]); check(meshes->size() >= 1); } if (o.isMember("nodes")) { nodes = asVec(o["nodes"]); check(nodes->size() >= 1); // Nodes must be a forest: // 1. Each node should have indegree 0 or 1: std::vector indeg(nodes->size()); for (std::size_t i = 0; i < nodes->size(); ++i) { auto children = nodes->at(i).children; if (!children.has_value()) continue; for (auto child : children.value()) { ++indeg.at(child); } } for (const auto deg : indeg) { check(deg <= 1); } // 2. There should be no cycles: std::vector visited(nodes->size()); std::stack> toVisit; for (std::size_t i = 0; i < nodes->size(); ++i) { // Only start DFS in roots. if (indeg[i] > 0) continue; toVisit.push(i); do { std::size_t j = toVisit.top(); check(!visited.at(j)); visited[j] = true; toVisit.pop(); auto children = nodes->at(j).children; if (!children.has_value()) continue; for (auto child : *children) { toVisit.push(child); } } while (!toVisit.empty()); } } if (o.isMember("samplers")) { samplers = asVec(o["samplers"]); check(samplers->size() >= 1); } if (o.isMember("scene")) { scene = as(o["scene"]); } if (o.isMember("scenes")) { scenes = asVec(o["scenes"]); check(scenes->size() >= 1); } if (o.isMember("skins")) { skins = asVec(o["skins"]); check(skins->size() >= 1); } if (o.isMember("textures")) { textures = asVec(o["textures"]); check(textures->size() >= 1); } // Validation checkForall(bufferViews, [&](const BufferView &view) { check(buffers.has_value()); const Buffer &buf = buffers->at(view.buffer); // Be careful because of possible integer overflows. check(view.byteOffset < buf.byteLength); check(view.byteLength <= buf.byteLength); check(view.byteOffset <= buf.byteLength - view.byteLength); }); const auto checkAccessor = [&](const auto &accessor, std::size_t bufferView, std::size_t byteOffset, std::size_t count) { const BufferView &view = bufferViews->at(bufferView); if (view.byteStride.has_value()) check(*view.byteStride % accessor.componentSize() == 0); check(byteOffset < view.byteLength); // Use division to avoid overflows. const auto effective_byte_stride = view.byteStride.value_or(accessor.elementSize()); check(count <= (view.byteLength - byteOffset) / effective_byte_stride); }; checkForall(accessors, [&](const Accessor &accessor) { if (accessor.bufferView.has_value()) checkAccessor(accessor, *accessor.bufferView, accessor.byteOffset, accessor.count); if (accessor.sparse.has_value()) { const auto &indices = accessor.sparse->indices; checkAccessor(indices, indices.bufferView, indices.byteOffset, accessor.sparse->count); const auto &values = accessor.sparse->values; checkAccessor(accessor, values.bufferView, values.byteOffset, accessor.sparse->count); } }); checkForall(images, [&](const Image &image) { checkIndex(bufferViews, image.bufferView); }); checkForall(meshes, [&](const Mesh &mesh) { for (const auto &primitive : mesh.primitives) { checkIndex(accessors, primitive.indices); checkIndex(materials, primitive.material); checkIndex(accessors, primitive.attributes.normal); checkIndex(accessors, primitive.attributes.position); checkIndex(accessors, primitive.attributes.tangent); checkForall(primitive.attributes.texcoord, [&](const std::size_t &i) { checkIndex(accessors, i); }); checkForall(primitive.attributes.color, [&](const std::size_t &i) { checkIndex(accessors, i); }); checkForall(primitive.attributes.joints, [&](const std::size_t &i) { checkIndex(accessors, i); }); checkForall(primitive.attributes.weights, [&](const std::size_t &i) { checkIndex(accessors, i); }); if (primitive.material.has_value()) { const Material &material = materials->at(primitive.material.value()); if (material.emissiveTexture.has_value()) { check(primitive.attributes.texcoord.has_value()); check(material.emissiveTexture->texCoord < primitive.attributes.texcoord->size()); } if (material.normalTexture.has_value()) { check(primitive.attributes.texcoord.has_value()); check(material.normalTexture->texCoord < primitive.attributes.texcoord->size()); } if (material.occlusionTexture.has_value()) { check(primitive.attributes.texcoord.has_value()); check(material.occlusionTexture->texCoord < primitive.attributes.texcoord->size()); } } checkForall(primitive.targets, [&](const MeshPrimitive::MorphTargets &target) { checkIndex(accessors, target.normal); checkIndex(accessors, target.position); checkIndex(accessors, target.tangent); checkForall(target.texcoord, [&](const std::size_t &i) { checkIndex(accessors, i); }); checkForall(target.color, [&](const std::size_t &i) { checkIndex(accessors, i); }); }); } }); checkForall(nodes, [&](const Node &node) { checkIndex(cameras, node.camera); checkIndex(meshes, node.mesh); checkIndex(skins, node.skin); }); checkForall(scenes, [&](const Scene &scene) { checkForall(scene.nodes, [&](const size_t &i) { checkIndex(nodes, i); }); }); checkForall(skins, [&](const Skin &skin) { checkIndex(accessors, skin.inverseBindMatrices); for (const std::size_t &i : skin.joints) checkIndex(nodes, i); checkIndex(nodes, skin.skeleton); }); checkForall(textures, [&](const Texture &texture) { checkIndex(samplers, texture.sampler); checkIndex(images, texture.source); }); checkForall(animations, [&](const Animation &animation) { for (const auto &sampler : animation.samplers) { checkIndex(accessors, sampler.input); const auto &accessor = accessors->at(sampler.input); check(accessor.type == Accessor::Type::SCALAR); check(accessor.componentType == Accessor::ComponentType::FLOAT); checkIndex(accessors, sampler.output); } for (const auto &channel : animation.channels) { checkIndex(nodes, channel.target.node); checkIndex(animation.samplers, channel.sampler); } }); checkIndex(scenes, scene); } }; // std::span is C++ 20, so we roll our own little struct here. template struct Span { T *ptr; uint32_t len; bool empty() const { return len == 0; } T *end() const { return ptr + len; } template Span cast() const { return {(U *) ptr, len}; } }; static Json::Value readJson(Span span) { Json::CharReaderBuilder builder; const std::unique_ptr reader(builder.newCharReader()); Json::Value json; JSONCPP_STRING err; if (!reader->parse(span.ptr, span.end(), &json, &err)) throw std::runtime_error(std::string("invalid JSON: ") + err); return json; } inline GlTF readGlb(const char *data, std::size_t len, const UriResolver &resolveUri = uriError) { struct Chunk { uint32_t type; Span span; }; struct Stream { Span span; bool eof() const { return span.empty(); } void advance(uint32_t n) { span.len -= n; span.ptr += n; } uint32_t readUint32() { if (span.len < 4) throw std::runtime_error("premature EOF"); uint32_t res = 0; for (int i = 0; i < 4; ++i) res += span.ptr[i] << (i * 8); advance(4); return res; } Chunk readChunk() { const auto chunkLen = readUint32(); if (chunkLen % 4 != 0) throw std::runtime_error("chunk length must be multiple of 4"); const auto chunkType = readUint32(); auto chunkPtr = span.ptr; if (span.len < chunkLen) throw std::runtime_error("premature EOF"); advance(chunkLen); return {chunkType, {chunkPtr, chunkLen}}; } }; constexpr uint32_t MAGIC_GLTF = 0x46546C67; constexpr uint32_t MAGIC_JSON = 0x4E4F534A; constexpr uint32_t MAGIC_BIN = 0x004E4942; if (len > std::numeric_limits::max()) throw std::runtime_error("too large"); Stream is{{(const uint8_t *) data, static_cast(len)}}; const auto magic = is.readUint32(); if (magic != MAGIC_GLTF) throw std::runtime_error("wrong magic number"); const auto version = is.readUint32(); if (version != 2) throw std::runtime_error("wrong version"); const auto length = is.readUint32(); if (length != len) throw std::runtime_error("wrong length"); const auto json = is.readChunk(); if (json.type != MAGIC_JSON) throw std::runtime_error("expected JSON chunk"); std::optional buffer; if (!is.eof()) { const auto chunk = is.readChunk(); if (chunk.type == MAGIC_BIN) buffer = std::string((const char *) chunk.span.ptr, chunk.span.len); else if (chunk.type == MAGIC_JSON) throw std::runtime_error("unexpected chunk"); // Ignore all other chunks. We still want to validate that // 1. These chunks are valid; // 2. These chunks are *not* JSON or BIN chunks while (!is.eof()) { const auto type = is.readChunk().type; if (type == MAGIC_JSON || type == MAGIC_BIN) throw std::runtime_error("unexpected chunk"); } } return GlTF(readJson(json.span.cast()), resolveUri, std::move(buffer)); } inline GlTF readGlTF(const char *data, std::size_t len, const UriResolver &resolveUri = uriError) { if (len > std::numeric_limits::max()) throw std::runtime_error("too large"); return GlTF(readJson({data, static_cast(len)}), resolveUri); } }