// automatically generated by the FlatBuffers compiler, do not modify #ifndef FLATBUFFERS_GENERATED_TENSORFLOWOP_MNN_H_ #define FLATBUFFERS_GENERATED_TENSORFLOWOP_MNN_H_ #include "Tensor_generated.h" #include "Type_generated.h" namespace MNN { struct BinaryOp; struct BinaryOpT; struct PackParam; struct PackParamT; struct StridedSliceParam; struct StridedSliceParamT; struct SqueezeParam; struct SqueezeParamT; struct CastParam; struct CastParamT; struct ReductionParam; struct ReductionParamT; struct Gather; struct GatherT; struct ExpandDims; struct ExpandDimsT; struct Selu; struct SeluT; struct AsString; struct AsStringT; struct ReduceJoin; struct ReduceJoinT; struct UnaryOp; struct UnaryOpT; struct TopKV2; struct TopKV2T; struct CropAndResize; struct CropAndResizeT; struct Fill; struct FillT; struct GatherV2; struct GatherV2T; struct NonMaxSuppressionV2; struct NonMaxSuppressionV2T; struct Range; struct RangeT; struct Rank; struct RankT; struct Size; struct SizeT; struct Transpose; struct TransposeT; struct SliceTf; struct SliceTfT; struct QuantizeMaxMin; struct QuantizeMaxMinT; struct Crop; struct CropT; struct SpaceBatch; struct SpaceBatchT; struct MatMul; struct MatMulT; struct MomentsParam; struct MomentsParamT; struct RNNParam; struct RNNParamT; struct BatchMatMulParam; struct BatchMatMulParamT; struct DepthSpaceParam; struct DepthSpaceParamT; struct ReverseSequenceParam; struct ReverseSequenceParamT; struct DetectionPostProcessParam; struct DetectionPostProcessParamT; struct OneHotParam; struct OneHotParamT; struct PadParam; struct PadParamT; struct LayerNorm; struct LayerNormT; struct GroupNorm; struct GroupNormT; struct RandomUniform; struct RandomUniformT; struct TensorArray; struct TensorArrayT; struct LSTMBlockCell; struct LSTMBlockCellT; inline const flatbuffers::TypeTable *BinaryOpTypeTable(); inline const flatbuffers::TypeTable *PackParamTypeTable(); inline const flatbuffers::TypeTable *StridedSliceParamTypeTable(); inline const flatbuffers::TypeTable *SqueezeParamTypeTable(); inline const flatbuffers::TypeTable *CastParamTypeTable(); inline const flatbuffers::TypeTable *ReductionParamTypeTable(); inline const flatbuffers::TypeTable *GatherTypeTable(); inline const flatbuffers::TypeTable *ExpandDimsTypeTable(); inline const flatbuffers::TypeTable *SeluTypeTable(); inline const flatbuffers::TypeTable *AsStringTypeTable(); inline const flatbuffers::TypeTable *ReduceJoinTypeTable(); inline const flatbuffers::TypeTable *UnaryOpTypeTable(); inline const flatbuffers::TypeTable *TopKV2TypeTable(); inline const flatbuffers::TypeTable *CropAndResizeTypeTable(); inline const flatbuffers::TypeTable *FillTypeTable(); inline const flatbuffers::TypeTable *GatherV2TypeTable(); inline const flatbuffers::TypeTable *NonMaxSuppressionV2TypeTable(); inline const flatbuffers::TypeTable *RangeTypeTable(); inline const flatbuffers::TypeTable *RankTypeTable(); inline const flatbuffers::TypeTable *SizeTypeTable(); inline const flatbuffers::TypeTable *TransposeTypeTable(); inline const flatbuffers::TypeTable *SliceTfTypeTable(); inline const flatbuffers::TypeTable *QuantizeMaxMinTypeTable(); inline const flatbuffers::TypeTable *CropTypeTable(); inline const flatbuffers::TypeTable *SpaceBatchTypeTable(); inline const flatbuffers::TypeTable *MatMulTypeTable(); inline const flatbuffers::TypeTable *MomentsParamTypeTable(); inline const flatbuffers::TypeTable *RNNParamTypeTable(); inline const flatbuffers::TypeTable *BatchMatMulParamTypeTable(); inline const flatbuffers::TypeTable *DepthSpaceParamTypeTable(); inline const flatbuffers::TypeTable *ReverseSequenceParamTypeTable(); inline const flatbuffers::TypeTable *DetectionPostProcessParamTypeTable(); inline const flatbuffers::TypeTable *OneHotParamTypeTable(); inline const flatbuffers::TypeTable *PadParamTypeTable(); inline const flatbuffers::TypeTable *LayerNormTypeTable(); inline const flatbuffers::TypeTable *GroupNormTypeTable(); inline const flatbuffers::TypeTable *RandomUniformTypeTable(); inline const flatbuffers::TypeTable *TensorArrayTypeTable(); inline const flatbuffers::TypeTable *LSTMBlockCellTypeTable(); enum BinaryOpOperation { BinaryOpOperation_ADD = 0, BinaryOpOperation_SUB = 1, BinaryOpOperation_MUL = 2, BinaryOpOperation_DIV = 3, BinaryOpOperation_MAX_TEMP = 4, BinaryOpOperation_MIN_TEMP = 5, BinaryOpOperation_POW = 6, BinaryOpOperation_REALDIV = 7, BinaryOpOperation_MINIMUM = 8, BinaryOpOperation_MAXIMUM = 9, BinaryOpOperation_GREATER = 10, BinaryOpOperation_GREATER_EQUAL = 11, BinaryOpOperation_LESS = 12, BinaryOpOperation_FLOORDIV = 13, BinaryOpOperation_SquaredDifference = 14, BinaryOpOperation_EQUAL = 15, BinaryOpOperation_LESS_EQUAL = 16, BinaryOpOperation_FLOORMOD = 17, BinaryOpOperation_MOD = 19, BinaryOpOperation_ATAN2 = 20, BinaryOpOperation_LOGICALOR = 21, BinaryOpOperation_NOTEQUAL = 22, BinaryOpOperation_BITWISE_AND = 23, BinaryOpOperation_BITWISE_OR = 24, BinaryOpOperation_BITWISE_XOR = 25, BinaryOpOperation_LOGICALXOR = 26, BinaryOpOperation_LEFTSHIFT = 27, BinaryOpOperation_RIGHTSHIFT = 28, BinaryOpOperation_MUL_SILU = 29, BinaryOpOperation_MIN = BinaryOpOperation_ADD, BinaryOpOperation_MAX = BinaryOpOperation_MUL_SILU }; inline const BinaryOpOperation (&EnumValuesBinaryOpOperation())[29] { static const BinaryOpOperation values[] = { BinaryOpOperation_ADD, BinaryOpOperation_SUB, BinaryOpOperation_MUL, BinaryOpOperation_DIV, BinaryOpOperation_MAX_TEMP, BinaryOpOperation_MIN_TEMP, BinaryOpOperation_POW, BinaryOpOperation_REALDIV, BinaryOpOperation_MINIMUM, BinaryOpOperation_MAXIMUM, BinaryOpOperation_GREATER, BinaryOpOperation_GREATER_EQUAL, BinaryOpOperation_LESS, BinaryOpOperation_FLOORDIV, BinaryOpOperation_SquaredDifference, BinaryOpOperation_EQUAL, BinaryOpOperation_LESS_EQUAL, BinaryOpOperation_FLOORMOD, BinaryOpOperation_MOD, BinaryOpOperation_ATAN2, BinaryOpOperation_LOGICALOR, BinaryOpOperation_NOTEQUAL, BinaryOpOperation_BITWISE_AND, BinaryOpOperation_BITWISE_OR, BinaryOpOperation_BITWISE_XOR, BinaryOpOperation_LOGICALXOR, BinaryOpOperation_LEFTSHIFT, BinaryOpOperation_RIGHTSHIFT, BinaryOpOperation_MUL_SILU }; return values; } inline const char * const *EnumNamesBinaryOpOperation() { static const char * const names[] = { "ADD", "SUB", "MUL", "DIV", "MAX_TEMP", "MIN_TEMP", "POW", "REALDIV", "MINIMUM", "MAXIMUM", "GREATER", "GREATER_EQUAL", "LESS", "FLOORDIV", "SquaredDifference", "EQUAL", "LESS_EQUAL", "FLOORMOD", "", "MOD", "ATAN2", "LOGICALOR", "NOTEQUAL", "BITWISE_AND", "BITWISE_OR", "BITWISE_XOR", "LOGICALXOR", "LEFTSHIFT", "RIGHTSHIFT", "MUL_SILU", nullptr }; return names; } inline const char *EnumNameBinaryOpOperation(BinaryOpOperation e) { if (e < BinaryOpOperation_ADD || e > BinaryOpOperation_MUL_SILU) return ""; const size_t index = static_cast(e); return EnumNamesBinaryOpOperation()[index]; } enum ReductionType { ReductionType_SUM = 0, ReductionType_ASUM = 1, ReductionType_SUMSQ = 2, ReductionType_MEAN = 3, ReductionType_MAXIMUM = 4, ReductionType_MINIMUM = 5, ReductionType_PROD = 6, ReductionType_ANY = 7, ReductionType_ALL = 8, ReductionType_MIN = ReductionType_SUM, ReductionType_MAX = ReductionType_ALL }; inline const ReductionType (&EnumValuesReductionType())[9] { static const ReductionType values[] = { ReductionType_SUM, ReductionType_ASUM, ReductionType_SUMSQ, ReductionType_MEAN, ReductionType_MAXIMUM, ReductionType_MINIMUM, ReductionType_PROD, ReductionType_ANY, ReductionType_ALL }; return values; } inline const char * const *EnumNamesReductionType() { static const char * const names[] = { "SUM", "ASUM", "SUMSQ", "MEAN", "MAXIMUM", "MINIMUM", "PROD", "ANY", "ALL", nullptr }; return names; } inline const char *EnumNameReductionType(ReductionType e) { if (e < ReductionType_SUM || e > ReductionType_ALL) return ""; const size_t index = static_cast(e); return EnumNamesReductionType()[index]; } enum UnaryOpOperation { UnaryOpOperation_ABS = 0, UnaryOpOperation_NEG = 1, UnaryOpOperation_FLOOR = 2, UnaryOpOperation_CEIL = 3, UnaryOpOperation_SQUARE = 4, UnaryOpOperation_SQRT = 5, UnaryOpOperation_RSQRT = 6, UnaryOpOperation_EXP = 7, UnaryOpOperation_LOG = 8, UnaryOpOperation_SIN = 9, UnaryOpOperation_COS = 10, UnaryOpOperation_TAN = 11, UnaryOpOperation_ASIN = 12, UnaryOpOperation_ACOS = 13, UnaryOpOperation_ATAN = 14, UnaryOpOperation_RECIPROCAL = 15, UnaryOpOperation_LOG1P = 16, UnaryOpOperation_BNLL = 17, UnaryOpOperation_ACOSH = 18, UnaryOpOperation_SINH = 19, UnaryOpOperation_ASINH = 20, UnaryOpOperation_ATANH = 21, UnaryOpOperation_SIGN = 22, UnaryOpOperation_ROUND = 23, UnaryOpOperation_COSH = 24, UnaryOpOperation_ERF = 25, UnaryOpOperation_ERFC = 26, UnaryOpOperation_ERFINV = 27, UnaryOpOperation_EXPM1 = 28, UnaryOpOperation_SIGMOID = 29, UnaryOpOperation_TANH = 30, UnaryOpOperation_HARDSWISH = 31, UnaryOpOperation_GELU = 32, UnaryOpOperation_GELU_STANDARD = 33, UnaryOpOperation_SILU = 34, UnaryOpOperation_MIN = UnaryOpOperation_ABS, UnaryOpOperation_MAX = UnaryOpOperation_SILU }; inline const UnaryOpOperation (&EnumValuesUnaryOpOperation())[35] { static const UnaryOpOperation values[] = { UnaryOpOperation_ABS, UnaryOpOperation_NEG, UnaryOpOperation_FLOOR, UnaryOpOperation_CEIL, UnaryOpOperation_SQUARE, UnaryOpOperation_SQRT, UnaryOpOperation_RSQRT, UnaryOpOperation_EXP, UnaryOpOperation_LOG, UnaryOpOperation_SIN, UnaryOpOperation_COS, UnaryOpOperation_TAN, UnaryOpOperation_ASIN, UnaryOpOperation_ACOS, UnaryOpOperation_ATAN, UnaryOpOperation_RECIPROCAL, UnaryOpOperation_LOG1P, UnaryOpOperation_BNLL, UnaryOpOperation_ACOSH, UnaryOpOperation_SINH, UnaryOpOperation_ASINH, UnaryOpOperation_ATANH, UnaryOpOperation_SIGN, UnaryOpOperation_ROUND, UnaryOpOperation_COSH, UnaryOpOperation_ERF, UnaryOpOperation_ERFC, UnaryOpOperation_ERFINV, UnaryOpOperation_EXPM1, UnaryOpOperation_SIGMOID, UnaryOpOperation_TANH, UnaryOpOperation_HARDSWISH, UnaryOpOperation_GELU, UnaryOpOperation_GELU_STANDARD, UnaryOpOperation_SILU }; return values; } inline const char * const *EnumNamesUnaryOpOperation() { static const char * const names[] = { "ABS", "NEG", "FLOOR", "CEIL", "SQUARE", "SQRT", "RSQRT", "EXP", "LOG", "SIN", "COS", "TAN", "ASIN", "ACOS", "ATAN", "RECIPROCAL", "LOG1P", "BNLL", "ACOSH", "SINH", "ASINH", "ATANH", "SIGN", "ROUND", "COSH", "ERF", "ERFC", "ERFINV", "EXPM1", "SIGMOID", "TANH", "HARDSWISH", "GELU", "GELU_STANDARD", "SILU", nullptr }; return names; } inline const char *EnumNameUnaryOpOperation(UnaryOpOperation e) { if (e < UnaryOpOperation_ABS || e > UnaryOpOperation_SILU) return ""; const size_t index = static_cast(e); return EnumNamesUnaryOpOperation()[index]; } enum CropAndResizeMethod { CropAndResizeMethod_BILINEAR = 0, CropAndResizeMethod_NEAREST = 1, CropAndResizeMethod_MIN = CropAndResizeMethod_BILINEAR, CropAndResizeMethod_MAX = CropAndResizeMethod_NEAREST }; inline const CropAndResizeMethod (&EnumValuesCropAndResizeMethod())[2] { static const CropAndResizeMethod values[] = { CropAndResizeMethod_BILINEAR, CropAndResizeMethod_NEAREST }; return values; } inline const char * const *EnumNamesCropAndResizeMethod() { static const char * const names[] = { "BILINEAR", "NEAREST", nullptr }; return names; } inline const char *EnumNameCropAndResizeMethod(CropAndResizeMethod e) { if (e < CropAndResizeMethod_BILINEAR || e > CropAndResizeMethod_NEAREST) return ""; const size_t index = static_cast(e); return EnumNamesCropAndResizeMethod()[index]; } enum DepthToSpaceMode { DepthToSpaceMode_DCR = 0, DepthToSpaceMode_CRD = 1, DepthToSpaceMode_MIN = DepthToSpaceMode_DCR, DepthToSpaceMode_MAX = DepthToSpaceMode_CRD }; inline const DepthToSpaceMode (&EnumValuesDepthToSpaceMode())[2] { static const DepthToSpaceMode values[] = { DepthToSpaceMode_DCR, DepthToSpaceMode_CRD }; return values; } inline const char * const *EnumNamesDepthToSpaceMode() { static const char * const names[] = { "DCR", "CRD", nullptr }; return names; } inline const char *EnumNameDepthToSpaceMode(DepthToSpaceMode e) { if (e < DepthToSpaceMode_DCR || e > DepthToSpaceMode_CRD) return ""; const size_t index = static_cast(e); return EnumNamesDepthToSpaceMode()[index]; } enum PadValueMode { PadValueMode_CONSTANT = 0, PadValueMode_REFLECT = 1, PadValueMode_SYMMETRIC = 2, PadValueMode_EDGE = 3, PadValueMode_MIN = PadValueMode_CONSTANT, PadValueMode_MAX = PadValueMode_EDGE }; inline const PadValueMode (&EnumValuesPadValueMode())[4] { static const PadValueMode values[] = { PadValueMode_CONSTANT, PadValueMode_REFLECT, PadValueMode_SYMMETRIC, PadValueMode_EDGE }; return values; } inline const char * const *EnumNamesPadValueMode() { static const char * const names[] = { "CONSTANT", "REFLECT", "SYMMETRIC", "EDGE", nullptr }; return names; } inline const char *EnumNamePadValueMode(PadValueMode e) { if (e < PadValueMode_CONSTANT || e > PadValueMode_EDGE) return ""; const size_t index = static_cast(e); return EnumNamesPadValueMode()[index]; } struct BinaryOpT : public flatbuffers::NativeTable { typedef BinaryOp TableType; BinaryOpOperation opType; DataType T; int32_t activationType; BinaryOpT() : opType(BinaryOpOperation_ADD), T(DataType_DT_FLOAT), activationType(0) { } }; struct BinaryOp FLATBUFFERS_FINAL_CLASS : private flatbuffers::Table { typedef BinaryOpT NativeTableType; static const flatbuffers::TypeTable *MiniReflectTypeTable() { return BinaryOpTypeTable(); } BinaryOpOperation opType() const { return static_cast(GetField(4, 0)); } DataType T() const { return static_cast(GetField(6, 1)); } int32_t activationType() const { return GetField(8, 0); } bool Verify(flatbuffers::Verifier &verifier) const { return VerifyTableStart(verifier) && VerifyField(verifier, 4) && VerifyField(verifier, 6) && VerifyField(verifier, 8) && verifier.EndTable(); } BinaryOpT *UnPack(const flatbuffers::resolver_function_t *_resolver = nullptr) const; void UnPackTo(BinaryOpT *_o, const flatbuffers::resolver_function_t *_resolver = nullptr) const; static flatbuffers::Offset Pack(flatbuffers::FlatBufferBuilder &_fbb, const BinaryOpT* _o, const flatbuffers::rehasher_function_t *_rehasher = nullptr); }; struct BinaryOpBuilder { flatbuffers::FlatBufferBuilder &fbb_; flatbuffers::uoffset_t start_; void add_opType(BinaryOpOperation opType) { fbb_.AddElement(4, static_cast(opType), 0); } void add_T(DataType T) { fbb_.AddElement(6, static_cast(T), 1); } void add_activationType(int32_t activationType) { fbb_.AddElement(8, activationType, 0); } explicit BinaryOpBuilder(flatbuffers::FlatBufferBuilder &_fbb) : fbb_(_fbb) { start_ = fbb_.StartTable(); } BinaryOpBuilder &operator=(const BinaryOpBuilder &); flatbuffers::Offset Finish() { const auto end = fbb_.EndTable(start_); auto o = flatbuffers::Offset(end); return o; } }; inline flatbuffers::Offset CreateBinaryOp( flatbuffers::FlatBufferBuilder &_fbb, BinaryOpOperation opType = BinaryOpOperation_ADD, DataType T = DataType_DT_FLOAT, int32_t activationType = 0) { BinaryOpBuilder builder_(_fbb); builder_.add_activationType(activationType); builder_.add_T(T); builder_.add_opType(opType); return builder_.Finish(); } flatbuffers::Offset CreateBinaryOp(flatbuffers::FlatBufferBuilder &_fbb, const BinaryOpT *_o, const flatbuffers::rehasher_function_t *_rehasher = nullptr); struct PackParamT : public flatbuffers::NativeTable { typedef PackParam TableType; DataType dataType; int32_t axis; PackParamT() : dataType(DataType_DT_INVALID), axis(0) { } }; struct PackParam FLATBUFFERS_FINAL_CLASS : private flatbuffers::Table { typedef PackParamT NativeTableType; static const flatbuffers::TypeTable *MiniReflectTypeTable() { return PackParamTypeTable(); } DataType dataType() const { return static_cast(GetField(4, 0)); } int32_t axis() const { return GetField(6, 0); } bool Verify(flatbuffers::Verifier &verifier) const { return VerifyTableStart(verifier) && VerifyField(verifier, 4) && VerifyField(verifier, 6) && verifier.EndTable(); } PackParamT *UnPack(const flatbuffers::resolver_function_t *_resolver = nullptr) const; void UnPackTo(PackParamT *_o, const flatbuffers::resolver_function_t *_resolver = nullptr) const; static flatbuffers::Offset Pack(flatbuffers::FlatBufferBuilder &_fbb, const PackParamT* _o, const flatbuffers::rehasher_function_t *_rehasher = nullptr); }; struct PackParamBuilder { flatbuffers::FlatBufferBuilder &fbb_; flatbuffers::uoffset_t start_; void add_dataType(DataType dataType) { fbb_.AddElement(4, static_cast(dataType), 0); } void add_axis(int32_t axis) { fbb_.AddElement(6, axis, 0); } explicit PackParamBuilder(flatbuffers::FlatBufferBuilder &_fbb) : fbb_(_fbb) { start_ = fbb_.StartTable(); } PackParamBuilder &operator=(const PackParamBuilder &); flatbuffers::Offset Finish() { const auto end = fbb_.EndTable(start_); auto o = flatbuffers::Offset(end); return o; } }; inline flatbuffers::Offset CreatePackParam( flatbuffers::FlatBufferBuilder &_fbb, DataType dataType = DataType_DT_INVALID, int32_t axis = 0) { PackParamBuilder builder_(_fbb); builder_.add_axis(axis); builder_.add_dataType(dataType); return builder_.Finish(); } flatbuffers::Offset CreatePackParam(flatbuffers::FlatBufferBuilder &_fbb, const PackParamT *_o, const flatbuffers::rehasher_function_t *_rehasher = nullptr); struct StridedSliceParamT : public flatbuffers::NativeTable { typedef StridedSliceParam TableType; DataType Index; DataType T; int32_t beginMask; int32_t endMask; int32_t ellipsisMask; int32_t newAxisMask; int32_t shrinkAxisMask; int32_t fromType; StridedSliceParamT() : Index(DataType_DT_INVALID), T(DataType_DT_INVALID), beginMask(0), endMask(0), ellipsisMask(0), newAxisMask(0), shrinkAxisMask(0), fromType(0) { } }; struct StridedSliceParam FLATBUFFERS_FINAL_CLASS : private flatbuffers::Table { typedef StridedSliceParamT NativeTableType; static const flatbuffers::TypeTable *MiniReflectTypeTable() { return StridedSliceParamTypeTable(); } DataType Index() const { return static_cast(GetField(4, 0)); } DataType T() const { return static_cast(GetField(6, 0)); } int32_t beginMask() const { return GetField(8, 0); } int32_t endMask() const { return GetField(10, 0); } int32_t ellipsisMask() const { return GetField(12, 0); } int32_t newAxisMask() const { return GetField(14, 0); } int32_t shrinkAxisMask() const { return GetField(16, 0); } int32_t fromType() const { return GetField(18, 0); } bool Verify(flatbuffers::Verifier &verifier) const { return VerifyTableStart(verifier) && VerifyField(verifier, 4) && VerifyField(verifier, 6) && VerifyField(verifier, 8) && VerifyField(verifier, 10) && VerifyField(verifier, 12) && VerifyField(verifier, 14) && VerifyField(verifier, 16) && VerifyField(verifier, 18) && verifier.EndTable(); } StridedSliceParamT *UnPack(const flatbuffers::resolver_function_t *_resolver = nullptr) const; void UnPackTo(StridedSliceParamT *_o, const flatbuffers::resolver_function_t *_resolver = nullptr) const; static flatbuffers::Offset Pack(flatbuffers::FlatBufferBuilder &_fbb, const StridedSliceParamT* _o, const flatbuffers::rehasher_function_t *_rehasher = nullptr); }; struct StridedSliceParamBuilder { flatbuffers::FlatBufferBuilder &fbb_; flatbuffers::uoffset_t start_; void add_Index(DataType Index) { fbb_.AddElement(4, static_cast(Index), 0); } void add_T(DataType T) { fbb_.AddElement(6, static_cast(T), 0); } void add_beginMask(int32_t beginMask) { fbb_.AddElement(8, beginMask, 0); } void add_endMask(int32_t endMask) { fbb_.AddElement(10, endMask, 0); } void add_ellipsisMask(int32_t ellipsisMask) { fbb_.AddElement(12, ellipsisMask, 0); } void add_newAxisMask(int32_t newAxisMask) { fbb_.AddElement(14, newAxisMask, 0); } void add_shrinkAxisMask(int32_t shrinkAxisMask) { fbb_.AddElement(16, shrinkAxisMask, 0); } void add_fromType(int32_t fromType) { fbb_.AddElement(18, fromType, 0); } explicit StridedSliceParamBuilder(flatbuffers::FlatBufferBuilder &_fbb) : fbb_(_fbb) { start_ = fbb_.StartTable(); } StridedSliceParamBuilder &operator=(const StridedSliceParamBuilder &); flatbuffers::Offset Finish() { const auto end = fbb_.EndTable(start_); auto o = flatbuffers::Offset(end); return o; } }; inline flatbuffers::Offset CreateStridedSliceParam( flatbuffers::FlatBufferBuilder &_fbb, DataType Index = DataType_DT_INVALID, DataType T = DataType_DT_INVALID, int32_t beginMask = 0, int32_t endMask = 0, int32_t ellipsisMask = 0, int32_t newAxisMask = 0, int32_t shrinkAxisMask = 0, int32_t fromType = 0) { StridedSliceParamBuilder builder_(_fbb); builder_.add_fromType(fromType); builder_.add_shrinkAxisMask(shrinkAxisMask); builder_.add_newAxisMask(newAxisMask); builder_.add_ellipsisMask(ellipsisMask); builder_.add_endMask(endMask); builder_.add_beginMask(beginMask); builder_.add_T(T); builder_.add_Index(Index); return builder_.Finish(); } flatbuffers::Offset CreateStridedSliceParam(flatbuffers::FlatBufferBuilder &_fbb, const StridedSliceParamT *_o, const flatbuffers::rehasher_function_t *_rehasher = nullptr); struct SqueezeParamT : public flatbuffers::NativeTable { typedef SqueezeParam TableType; std::vector squeezeDims; SqueezeParamT() { } }; struct SqueezeParam FLATBUFFERS_FINAL_CLASS : private flatbuffers::Table { typedef SqueezeParamT NativeTableType; static const flatbuffers::TypeTable *MiniReflectTypeTable() { return SqueezeParamTypeTable(); } const flatbuffers::Vector *squeezeDims() const { return GetPointer *>(4); } bool Verify(flatbuffers::Verifier &verifier) const { return VerifyTableStart(verifier) && VerifyOffset(verifier, 4) && verifier.VerifyVector(squeezeDims()) && verifier.EndTable(); } SqueezeParamT *UnPack(const flatbuffers::resolver_function_t *_resolver = nullptr) const; void UnPackTo(SqueezeParamT *_o, const flatbuffers::resolver_function_t *_resolver = nullptr) const; static flatbuffers::Offset Pack(flatbuffers::FlatBufferBuilder &_fbb, const SqueezeParamT* _o, const flatbuffers::rehasher_function_t *_rehasher = nullptr); }; struct SqueezeParamBuilder { flatbuffers::FlatBufferBuilder &fbb_; flatbuffers::uoffset_t start_; void add_squeezeDims(flatbuffers::Offset> squeezeDims) { fbb_.AddOffset(4, squeezeDims); } explicit SqueezeParamBuilder(flatbuffers::FlatBufferBuilder &_fbb) : fbb_(_fbb) { start_ = fbb_.StartTable(); } SqueezeParamBuilder &operator=(const SqueezeParamBuilder &); flatbuffers::Offset Finish() { const auto end = fbb_.EndTable(start_); auto o = flatbuffers::Offset(end); return o; } }; inline flatbuffers::Offset CreateSqueezeParam( flatbuffers::FlatBufferBuilder &_fbb, flatbuffers::Offset> squeezeDims = 0) { SqueezeParamBuilder builder_(_fbb); builder_.add_squeezeDims(squeezeDims); return builder_.Finish(); } flatbuffers::Offset CreateSqueezeParam(flatbuffers::FlatBufferBuilder &_fbb, const SqueezeParamT *_o, const flatbuffers::rehasher_function_t *_rehasher = nullptr); struct CastParamT : public flatbuffers::NativeTable { typedef CastParam TableType; DataType srcT; DataType dstT; CastParamT() : srcT(DataType_DT_INVALID), dstT(DataType_DT_INVALID) { } }; struct CastParam FLATBUFFERS_FINAL_CLASS : private flatbuffers::Table { typedef CastParamT NativeTableType; static const flatbuffers::TypeTable *MiniReflectTypeTable() { return CastParamTypeTable(); } DataType srcT() const { return static_cast(GetField(4, 0)); } DataType dstT() const { return static_cast(GetField(6, 0)); } bool Verify(flatbuffers::Verifier &verifier) const { return VerifyTableStart(verifier) && VerifyField(verifier, 4) && VerifyField(verifier, 6) && verifier.EndTable(); } CastParamT *UnPack(const flatbuffers::resolver_function_t *_resolver = nullptr) const; void UnPackTo(CastParamT *_o, const flatbuffers::resolver_function_t *_resolver = nullptr) const; static flatbuffers::Offset Pack(flatbuffers::FlatBufferBuilder &_fbb, const CastParamT* _o, const flatbuffers::rehasher_function_t *_rehasher = nullptr); }; struct CastParamBuilder { flatbuffers::FlatBufferBuilder &fbb_; flatbuffers::uoffset_t start_; void add_srcT(DataType srcT) { fbb_.AddElement(4, static_cast(srcT), 0); } void add_dstT(DataType dstT) { fbb_.AddElement(6, static_cast(dstT), 0); } explicit CastParamBuilder(flatbuffers::FlatBufferBuilder &_fbb) : fbb_(_fbb) { start_ = fbb_.StartTable(); } CastParamBuilder &operator=(const CastParamBuilder &); flatbuffers::Offset Finish() { const auto end = fbb_.EndTable(start_); auto o = flatbuffers::Offset(end); return o; } }; inline flatbuffers::Offset CreateCastParam( flatbuffers::FlatBufferBuilder &_fbb, DataType srcT = DataType_DT_INVALID, DataType dstT = DataType_DT_INVALID) { CastParamBuilder builder_(_fbb); builder_.add_dstT(dstT); builder_.add_srcT(srcT); return builder_.Finish(); } flatbuffers::Offset CreateCastParam(flatbuffers::FlatBufferBuilder &_fbb, const CastParamT *_o, const flatbuffers::rehasher_function_t *_rehasher = nullptr); struct ReductionParamT : public flatbuffers::NativeTable { typedef ReductionParam TableType; ReductionType operation; std::vector dim; float coeff; bool keepDims; DataType dType; ReductionParamT() : operation(ReductionType_SUM), coeff(0.0f), keepDims(false), dType(DataType_DT_FLOAT) { } }; struct ReductionParam FLATBUFFERS_FINAL_CLASS : private flatbuffers::Table { typedef ReductionParamT NativeTableType; static const flatbuffers::TypeTable *MiniReflectTypeTable() { return ReductionParamTypeTable(); } ReductionType operation() const { return static_cast(GetField(4, 0)); } const flatbuffers::Vector *dim() const { return GetPointer *>(6); } float coeff() const { return GetField(8, 0.0f); } bool keepDims() const { return GetField(10, 0) != 0; } DataType dType() const { return static_cast(GetField(12, 1)); } bool Verify(flatbuffers::Verifier &verifier) const { return VerifyTableStart(verifier) && VerifyField(verifier, 4) && VerifyOffset(verifier, 6) && verifier.VerifyVector(dim()) && VerifyField(verifier, 8) && VerifyField(verifier, 10) && VerifyField(verifier, 12) && verifier.EndTable(); } ReductionParamT *UnPack(const flatbuffers::resolver_function_t *_resolver = nullptr) const; void UnPackTo(ReductionParamT *_o, const flatbuffers::resolver_function_t *_resolver = nullptr) const; static flatbuffers::Offset Pack(flatbuffers::FlatBufferBuilder &_fbb, const ReductionParamT* _o, const flatbuffers::rehasher_function_t *_rehasher = nullptr); }; struct ReductionParamBuilder { flatbuffers::FlatBufferBuilder &fbb_; flatbuffers::uoffset_t start_; void add_operation(ReductionType operation) { fbb_.AddElement(4, static_cast(operation), 0); } void add_dim(flatbuffers::Offset> dim) { fbb_.AddOffset(6, dim); } void add_coeff(float coeff) { fbb_.AddElement(8, coeff, 0.0f); } void add_keepDims(bool keepDims) { fbb_.AddElement(10, static_cast(keepDims), 0); } void add_dType(DataType dType) { fbb_.AddElement(12, static_cast(dType), 1); } explicit ReductionParamBuilder(flatbuffers::FlatBufferBuilder &_fbb) : fbb_(_fbb) { start_ = fbb_.StartTable(); } ReductionParamBuilder &operator=(const ReductionParamBuilder &); flatbuffers::Offset Finish() { const auto end = fbb_.EndTable(start_); auto o = flatbuffers::Offset(end); return o; } }; inline flatbuffers::Offset CreateReductionParam( flatbuffers::FlatBufferBuilder &_fbb, ReductionType operation = ReductionType_SUM, flatbuffers::Offset> dim = 0, float coeff = 0.0f, bool keepDims = false, DataType dType = DataType_DT_FLOAT) { ReductionParamBuilder builder_(_fbb); builder_.add_dType(dType); builder_.add_coeff(coeff); builder_.add_dim(dim); builder_.add_keepDims(keepDims); builder_.add_operation(operation); return builder_.Finish(); } flatbuffers::Offset CreateReductionParam(flatbuffers::FlatBufferBuilder &_fbb, const ReductionParamT *_o, const flatbuffers::rehasher_function_t *_rehasher = nullptr); struct GatherT : public flatbuffers::NativeTable { typedef Gather TableType; DataType Tindices; DataType Tparams; bool validateIndices; int32_t axis; GatherT() : Tindices(DataType_DT_INVALID), Tparams(DataType_DT_INVALID), validateIndices(false), axis(0) { } }; struct Gather FLATBUFFERS_FINAL_CLASS : private flatbuffers::Table { typedef GatherT NativeTableType; static const flatbuffers::TypeTable *MiniReflectTypeTable() { return GatherTypeTable(); } DataType Tindices() const { return static_cast(GetField(4, 0)); } DataType Tparams() const { return static_cast(GetField(6, 0)); } bool validateIndices() const { return GetField(8, 0) != 0; } int32_t axis() const { return GetField(10, 0); } bool Verify(flatbuffers::Verifier &verifier) const { return VerifyTableStart(verifier) && VerifyField(verifier, 4) && VerifyField(verifier, 6) && VerifyField(verifier, 8) && VerifyField(verifier, 10) && verifier.EndTable(); } GatherT *UnPack(const flatbuffers::resolver_function_t *_resolver = nullptr) const; void UnPackTo(GatherT *_o, const flatbuffers::resolver_function_t *_resolver = nullptr) const; static flatbuffers::Offset Pack(flatbuffers::FlatBufferBuilder &_fbb, const GatherT* _o, const flatbuffers::rehasher_function_t *_rehasher = nullptr); }; struct GatherBuilder { flatbuffers::FlatBufferBuilder &fbb_; flatbuffers::uoffset_t start_; void add_Tindices(DataType Tindices) { fbb_.AddElement(4, static_cast(Tindices), 0); } void add_Tparams(DataType Tparams) { fbb_.AddElement(6, static_cast(Tparams), 0); } void add_validateIndices(bool validateIndices) { fbb_.AddElement(8, static_cast(validateIndices), 0); } void add_axis(int32_t axis) { fbb_.AddElement(10, axis, 0); } explicit GatherBuilder(flatbuffers::FlatBufferBuilder &_fbb) : fbb_(_fbb) { start_ = fbb_.StartTable(); } GatherBuilder &operator=(const GatherBuilder &); flatbuffers::Offset Finish() { const auto end = fbb_.EndTable(start_); auto o = flatbuffers::Offset(end); return o; } }; inline flatbuffers::Offset CreateGather( flatbuffers::FlatBufferBuilder &_fbb, DataType Tindices = DataType_DT_INVALID, DataType Tparams = DataType_DT_INVALID, bool validateIndices = false, int32_t axis = 0) { GatherBuilder builder_(_fbb); builder_.add_axis(axis); builder_.add_Tparams(Tparams); builder_.add_Tindices(Tindices); builder_.add_validateIndices(validateIndices); return builder_.Finish(); } flatbuffers::Offset CreateGather(flatbuffers::FlatBufferBuilder &_fbb, const GatherT *_o, const flatbuffers::rehasher_function_t *_rehasher = nullptr); struct ExpandDimsT : public flatbuffers::NativeTable { typedef ExpandDims TableType; DataType T; DataType Tdim; int32_t axis; ExpandDimsT() : T(DataType_DT_INVALID), Tdim(DataType_DT_INVALID), axis(0) { } }; struct ExpandDims FLATBUFFERS_FINAL_CLASS : private flatbuffers::Table { typedef ExpandDimsT NativeTableType; static const flatbuffers::TypeTable *MiniReflectTypeTable() { return ExpandDimsTypeTable(); } DataType T() const { return static_cast(GetField(4, 0)); } DataType Tdim() const { return static_cast(GetField(6, 0)); } int32_t axis() const { return GetField(8, 0); } bool Verify(flatbuffers::Verifier &verifier) const { return VerifyTableStart(verifier) && VerifyField(verifier, 4) && VerifyField(verifier, 6) && VerifyField(verifier, 8) && verifier.EndTable(); } ExpandDimsT *UnPack(const flatbuffers::resolver_function_t *_resolver = nullptr) const; void UnPackTo(ExpandDimsT *_o, const flatbuffers::resolver_function_t *_resolver = nullptr) const; static flatbuffers::Offset Pack(flatbuffers::FlatBufferBuilder &_fbb, const ExpandDimsT* _o, const flatbuffers::rehasher_function_t *_rehasher = nullptr); }; struct ExpandDimsBuilder { flatbuffers::FlatBufferBuilder &fbb_; flatbuffers::uoffset_t start_; void add_T(DataType T) { fbb_.AddElement(4, static_cast(T), 0); } void add_Tdim(DataType Tdim) { fbb_.AddElement(6, static_cast(Tdim), 0); } void add_axis(int32_t axis) { fbb_.AddElement(8, axis, 0); } explicit ExpandDimsBuilder(flatbuffers::FlatBufferBuilder &_fbb) : fbb_(_fbb) { start_ = fbb_.StartTable(); } ExpandDimsBuilder &operator=(const ExpandDimsBuilder &); flatbuffers::Offset Finish() { const auto end = fbb_.EndTable(start_); auto o = flatbuffers::Offset(end); return o; } }; inline flatbuffers::Offset CreateExpandDims( flatbuffers::FlatBufferBuilder &_fbb, DataType T = DataType_DT_INVALID, DataType Tdim = DataType_DT_INVALID, int32_t axis = 0) { ExpandDimsBuilder builder_(_fbb); builder_.add_axis(axis); builder_.add_Tdim(Tdim); builder_.add_T(T); return builder_.Finish(); } flatbuffers::Offset CreateExpandDims(flatbuffers::FlatBufferBuilder &_fbb, const ExpandDimsT *_o, const flatbuffers::rehasher_function_t *_rehasher = nullptr); struct SeluT : public flatbuffers::NativeTable { typedef Selu TableType; float scale; float alpha; SeluT() : scale(0.0f), alpha(0.0f) { } }; struct Selu FLATBUFFERS_FINAL_CLASS : private flatbuffers::Table { typedef SeluT NativeTableType; static const flatbuffers::TypeTable *MiniReflectTypeTable() { return SeluTypeTable(); } float scale() const { return GetField(4, 0.0f); } float alpha() const { return GetField(6, 0.0f); } bool Verify(flatbuffers::Verifier &verifier) const { return VerifyTableStart(verifier) && VerifyField(verifier, 4) && VerifyField(verifier, 6) && verifier.EndTable(); } SeluT *UnPack(const flatbuffers::resolver_function_t *_resolver = nullptr) const; void UnPackTo(SeluT *_o, const flatbuffers::resolver_function_t *_resolver = nullptr) const; static flatbuffers::Offset Pack(flatbuffers::FlatBufferBuilder &_fbb, const SeluT* _o, const flatbuffers::rehasher_function_t *_rehasher = nullptr); }; struct SeluBuilder { flatbuffers::FlatBufferBuilder &fbb_; flatbuffers::uoffset_t start_; void add_scale(float scale) { fbb_.AddElement(4, scale, 0.0f); } void add_alpha(float alpha) { fbb_.AddElement(6, alpha, 0.0f); } explicit SeluBuilder(flatbuffers::FlatBufferBuilder &_fbb) : fbb_(_fbb) { start_ = fbb_.StartTable(); } SeluBuilder &operator=(const SeluBuilder &); flatbuffers::Offset Finish() { const auto end = fbb_.EndTable(start_); auto o = flatbuffers::Offset(end); return o; } }; inline flatbuffers::Offset CreateSelu( flatbuffers::FlatBufferBuilder &_fbb, float scale = 0.0f, float alpha = 0.0f) { SeluBuilder builder_(_fbb); builder_.add_alpha(alpha); builder_.add_scale(scale); return builder_.Finish(); } flatbuffers::Offset CreateSelu(flatbuffers::FlatBufferBuilder &_fbb, const SeluT *_o, const flatbuffers::rehasher_function_t *_rehasher = nullptr); struct AsStringT : public flatbuffers::NativeTable { typedef AsString TableType; DataType T; int32_t precision; bool scientific; bool shortest; int32_t width; std::string fillString; AsStringT() : T(DataType_DT_INVALID), precision(0), scientific(false), shortest(false), width(0) { } }; struct AsString FLATBUFFERS_FINAL_CLASS : private flatbuffers::Table { typedef AsStringT NativeTableType; static const flatbuffers::TypeTable *MiniReflectTypeTable() { return AsStringTypeTable(); } DataType T() const { return static_cast(GetField(4, 0)); } int32_t precision() const { return GetField(6, 0); } bool scientific() const { return GetField(8, 0) != 0; } bool shortest() const { return GetField(10, 0) != 0; } int32_t width() const { return GetField(12, 0); } const flatbuffers::String *fillString() const { return GetPointer(14); } bool Verify(flatbuffers::Verifier &verifier) const { return VerifyTableStart(verifier) && VerifyField(verifier, 4) && VerifyField(verifier, 6) && VerifyField(verifier, 8) && VerifyField(verifier, 10) && VerifyField(verifier, 12) && VerifyOffset(verifier, 14) && verifier.VerifyString(fillString()) && verifier.EndTable(); } AsStringT *UnPack(const flatbuffers::resolver_function_t *_resolver = nullptr) const; void UnPackTo(AsStringT *_o, const flatbuffers::resolver_function_t *_resolver = nullptr) const; static flatbuffers::Offset Pack(flatbuffers::FlatBufferBuilder &_fbb, const AsStringT* _o, const flatbuffers::rehasher_function_t *_rehasher = nullptr); }; struct AsStringBuilder { flatbuffers::FlatBufferBuilder &fbb_; flatbuffers::uoffset_t start_; void add_T(DataType T) { fbb_.AddElement(4, static_cast(T), 0); } void add_precision(int32_t precision) { fbb_.AddElement(6, precision, 0); } void add_scientific(bool scientific) { fbb_.AddElement(8, static_cast(scientific), 0); } void add_shortest(bool shortest) { fbb_.AddElement(10, static_cast(shortest), 0); } void add_width(int32_t width) { fbb_.AddElement(12, width, 0); } void add_fillString(flatbuffers::Offset fillString) { fbb_.AddOffset(14, fillString); } explicit AsStringBuilder(flatbuffers::FlatBufferBuilder &_fbb) : fbb_(_fbb) { start_ = fbb_.StartTable(); } AsStringBuilder &operator=(const AsStringBuilder &); flatbuffers::Offset Finish() { const auto end = fbb_.EndTable(start_); auto o = flatbuffers::Offset(end); return o; } }; inline flatbuffers::Offset CreateAsString( flatbuffers::FlatBufferBuilder &_fbb, DataType T = DataType_DT_INVALID, int32_t precision = 0, bool scientific = false, bool shortest = false, int32_t width = 0, flatbuffers::Offset fillString = 0) { AsStringBuilder builder_(_fbb); builder_.add_fillString(fillString); builder_.add_width(width); builder_.add_precision(precision); builder_.add_T(T); builder_.add_shortest(shortest); builder_.add_scientific(scientific); return builder_.Finish(); } flatbuffers::Offset CreateAsString(flatbuffers::FlatBufferBuilder &_fbb, const AsStringT *_o, const flatbuffers::rehasher_function_t *_rehasher = nullptr); struct ReduceJoinT : public flatbuffers::NativeTable { typedef ReduceJoin TableType; bool keepDims; std::string separator; ReduceJoinT() : keepDims(false) { } }; struct ReduceJoin FLATBUFFERS_FINAL_CLASS : private flatbuffers::Table { typedef ReduceJoinT NativeTableType; static const flatbuffers::TypeTable *MiniReflectTypeTable() { return ReduceJoinTypeTable(); } bool keepDims() const { return GetField(4, 0) != 0; } const flatbuffers::String *separator() const { return GetPointer(6); } bool Verify(flatbuffers::Verifier &verifier) const { return VerifyTableStart(verifier) && VerifyField(verifier, 4) && VerifyOffset(verifier, 6) && verifier.VerifyString(separator()) && verifier.EndTable(); } ReduceJoinT *UnPack(const flatbuffers::resolver_function_t *_resolver = nullptr) const; void UnPackTo(ReduceJoinT *_o, const flatbuffers::resolver_function_t *_resolver = nullptr) const; static flatbuffers::Offset Pack(flatbuffers::FlatBufferBuilder &_fbb, const ReduceJoinT* _o, const flatbuffers::rehasher_function_t *_rehasher = nullptr); }; struct ReduceJoinBuilder { flatbuffers::FlatBufferBuilder &fbb_; flatbuffers::uoffset_t start_; void add_keepDims(bool keepDims) { fbb_.AddElement(4, static_cast(keepDims), 0); } void add_separator(flatbuffers::Offset separator) { fbb_.AddOffset(6, separator); } explicit ReduceJoinBuilder(flatbuffers::FlatBufferBuilder &_fbb) : fbb_(_fbb) { start_ = fbb_.StartTable(); } ReduceJoinBuilder &operator=(const ReduceJoinBuilder &); flatbuffers::Offset Finish() { const auto end = fbb_.EndTable(start_); auto o = flatbuffers::Offset(end); return o; } }; inline flatbuffers::Offset CreateReduceJoin( flatbuffers::FlatBufferBuilder &_fbb, bool keepDims = false, flatbuffers::Offset separator = 0) { ReduceJoinBuilder builder_(_fbb); builder_.add_separator(separator); builder_.add_keepDims(keepDims); return builder_.Finish(); } flatbuffers::Offset CreateReduceJoin(flatbuffers::FlatBufferBuilder &_fbb, const ReduceJoinT *_o, const flatbuffers::rehasher_function_t *_rehasher = nullptr); struct UnaryOpT : public flatbuffers::NativeTable { typedef UnaryOp TableType; UnaryOpOperation opType; DataType T; std::vector tableInt8; UnaryOpT() : opType(UnaryOpOperation_ABS), T(DataType_DT_INVALID) { } }; struct UnaryOp FLATBUFFERS_FINAL_CLASS : private flatbuffers::Table { typedef UnaryOpT NativeTableType; static const flatbuffers::TypeTable *MiniReflectTypeTable() { return UnaryOpTypeTable(); } UnaryOpOperation opType() const { return static_cast(GetField(4, 0)); } DataType T() const { return static_cast(GetField(6, 0)); } const flatbuffers::Vector *tableInt8() const { return GetPointer *>(8); } bool Verify(flatbuffers::Verifier &verifier) const { return VerifyTableStart(verifier) && VerifyField(verifier, 4) && VerifyField(verifier, 6) && VerifyOffset(verifier, 8) && verifier.VerifyVector(tableInt8()) && verifier.EndTable(); } UnaryOpT *UnPack(const flatbuffers::resolver_function_t *_resolver = nullptr) const; void UnPackTo(UnaryOpT *_o, const flatbuffers::resolver_function_t *_resolver = nullptr) const; static flatbuffers::Offset Pack(flatbuffers::FlatBufferBuilder &_fbb, const UnaryOpT* _o, const flatbuffers::rehasher_function_t *_rehasher = nullptr); }; struct UnaryOpBuilder { flatbuffers::FlatBufferBuilder &fbb_; flatbuffers::uoffset_t start_; void add_opType(UnaryOpOperation opType) { fbb_.AddElement(4, static_cast(opType), 0); } void add_T(DataType T) { fbb_.AddElement(6, static_cast(T), 0); } void add_tableInt8(flatbuffers::Offset> tableInt8) { fbb_.AddOffset(8, tableInt8); } explicit UnaryOpBuilder(flatbuffers::FlatBufferBuilder &_fbb) : fbb_(_fbb) { start_ = fbb_.StartTable(); } UnaryOpBuilder &operator=(const UnaryOpBuilder &); flatbuffers::Offset Finish() { const auto end = fbb_.EndTable(start_); auto o = flatbuffers::Offset(end); return o; } }; inline flatbuffers::Offset CreateUnaryOp( flatbuffers::FlatBufferBuilder &_fbb, UnaryOpOperation opType = UnaryOpOperation_ABS, DataType T = DataType_DT_INVALID, flatbuffers::Offset> tableInt8 = 0) { UnaryOpBuilder builder_(_fbb); builder_.add_tableInt8(tableInt8); builder_.add_T(T); builder_.add_opType(opType); return builder_.Finish(); } flatbuffers::Offset CreateUnaryOp(flatbuffers::FlatBufferBuilder &_fbb, const UnaryOpT *_o, const flatbuffers::rehasher_function_t *_rehasher = nullptr); struct TopKV2T : public flatbuffers::NativeTable { typedef TopKV2 TableType; DataType T; bool sorted; bool largest; TopKV2T() : T(DataType_DT_FLOAT), sorted(false), largest(true) { } }; struct TopKV2 FLATBUFFERS_FINAL_CLASS : private flatbuffers::Table { typedef TopKV2T NativeTableType; static const flatbuffers::TypeTable *MiniReflectTypeTable() { return TopKV2TypeTable(); } DataType T() const { return static_cast(GetField(4, 1)); } bool sorted() const { return GetField(6, 0) != 0; } bool largest() const { return GetField(8, 1) != 0; } bool Verify(flatbuffers::Verifier &verifier) const { return VerifyTableStart(verifier) && VerifyField(verifier, 4) && VerifyField(verifier, 6) && VerifyField(verifier, 8) && verifier.EndTable(); } TopKV2T *UnPack(const flatbuffers::resolver_function_t *_resolver = nullptr) const; void UnPackTo(TopKV2T *_o, const flatbuffers::resolver_function_t *_resolver = nullptr) const; static flatbuffers::Offset Pack(flatbuffers::FlatBufferBuilder &_fbb, const TopKV2T* _o, const flatbuffers::rehasher_function_t *_rehasher = nullptr); }; struct TopKV2Builder { flatbuffers::FlatBufferBuilder &fbb_; flatbuffers::uoffset_t start_; void add_T(DataType T) { fbb_.AddElement(4, static_cast(T), 1); } void add_sorted(bool sorted) { fbb_.AddElement(6, static_cast(sorted), 0); } void add_largest(bool largest) { fbb_.AddElement(8, static_cast(largest), 1); } explicit TopKV2Builder(flatbuffers::FlatBufferBuilder &_fbb) : fbb_(_fbb) { start_ = fbb_.StartTable(); } TopKV2Builder &operator=(const TopKV2Builder &); flatbuffers::Offset Finish() { const auto end = fbb_.EndTable(start_); auto o = flatbuffers::Offset(end); return o; } }; inline flatbuffers::Offset CreateTopKV2( flatbuffers::FlatBufferBuilder &_fbb, DataType T = DataType_DT_FLOAT, bool sorted = false, bool largest = true) { TopKV2Builder builder_(_fbb); builder_.add_T(T); builder_.add_largest(largest); builder_.add_sorted(sorted); return builder_.Finish(); } flatbuffers::Offset CreateTopKV2(flatbuffers::FlatBufferBuilder &_fbb, const TopKV2T *_o, const flatbuffers::rehasher_function_t *_rehasher = nullptr); struct CropAndResizeT : public flatbuffers::NativeTable { typedef CropAndResize TableType; float extrapolationValue; CropAndResizeMethod method; CropAndResizeT() : extrapolationValue(0.0f), method(CropAndResizeMethod_BILINEAR) { } }; struct CropAndResize FLATBUFFERS_FINAL_CLASS : private flatbuffers::Table { typedef CropAndResizeT NativeTableType; static const flatbuffers::TypeTable *MiniReflectTypeTable() { return CropAndResizeTypeTable(); } float extrapolationValue() const { return GetField(4, 0.0f); } CropAndResizeMethod method() const { return static_cast(GetField(6, 0)); } bool Verify(flatbuffers::Verifier &verifier) const { return VerifyTableStart(verifier) && VerifyField(verifier, 4) && VerifyField(verifier, 6) && verifier.EndTable(); } CropAndResizeT *UnPack(const flatbuffers::resolver_function_t *_resolver = nullptr) const; void UnPackTo(CropAndResizeT *_o, const flatbuffers::resolver_function_t *_resolver = nullptr) const; static flatbuffers::Offset Pack(flatbuffers::FlatBufferBuilder &_fbb, const CropAndResizeT* _o, const flatbuffers::rehasher_function_t *_rehasher = nullptr); }; struct CropAndResizeBuilder { flatbuffers::FlatBufferBuilder &fbb_; flatbuffers::uoffset_t start_; void add_extrapolationValue(float extrapolationValue) { fbb_.AddElement(4, extrapolationValue, 0.0f); } void add_method(CropAndResizeMethod method) { fbb_.AddElement(6, static_cast(method), 0); } explicit CropAndResizeBuilder(flatbuffers::FlatBufferBuilder &_fbb) : fbb_(_fbb) { start_ = fbb_.StartTable(); } CropAndResizeBuilder &operator=(const CropAndResizeBuilder &); flatbuffers::Offset Finish() { const auto end = fbb_.EndTable(start_); auto o = flatbuffers::Offset(end); return o; } }; inline flatbuffers::Offset CreateCropAndResize( flatbuffers::FlatBufferBuilder &_fbb, float extrapolationValue = 0.0f, CropAndResizeMethod method = CropAndResizeMethod_BILINEAR) { CropAndResizeBuilder builder_(_fbb); builder_.add_extrapolationValue(extrapolationValue); builder_.add_method(method); return builder_.Finish(); } flatbuffers::Offset CreateCropAndResize(flatbuffers::FlatBufferBuilder &_fbb, const CropAndResizeT *_o, const flatbuffers::rehasher_function_t *_rehasher = nullptr); struct FillT : public flatbuffers::NativeTable { typedef Fill TableType; FillT() { } }; struct Fill FLATBUFFERS_FINAL_CLASS : private flatbuffers::Table { typedef FillT NativeTableType; static const flatbuffers::TypeTable *MiniReflectTypeTable() { return FillTypeTable(); } bool Verify(flatbuffers::Verifier &verifier) const { return VerifyTableStart(verifier) && verifier.EndTable(); } FillT *UnPack(const flatbuffers::resolver_function_t *_resolver = nullptr) const; void UnPackTo(FillT *_o, const flatbuffers::resolver_function_t *_resolver = nullptr) const; static flatbuffers::Offset Pack(flatbuffers::FlatBufferBuilder &_fbb, const FillT* _o, const flatbuffers::rehasher_function_t *_rehasher = nullptr); }; struct FillBuilder { flatbuffers::FlatBufferBuilder &fbb_; flatbuffers::uoffset_t start_; explicit FillBuilder(flatbuffers::FlatBufferBuilder &_fbb) : fbb_(_fbb) { start_ = fbb_.StartTable(); } FillBuilder &operator=(const FillBuilder &); flatbuffers::Offset Finish() { const auto end = fbb_.EndTable(start_); auto o = flatbuffers::Offset(end); return o; } }; inline flatbuffers::Offset CreateFill( flatbuffers::FlatBufferBuilder &_fbb) { FillBuilder builder_(_fbb); return builder_.Finish(); } flatbuffers::Offset CreateFill(flatbuffers::FlatBufferBuilder &_fbb, const FillT *_o, const flatbuffers::rehasher_function_t *_rehasher = nullptr); struct GatherV2T : public flatbuffers::NativeTable { typedef GatherV2 TableType; DataType Taxis; DataType Tindices; DataType Tparams; GatherV2T() : Taxis(DataType_DT_INVALID), Tindices(DataType_DT_INVALID), Tparams(DataType_DT_INVALID) { } }; struct GatherV2 FLATBUFFERS_FINAL_CLASS : private flatbuffers::Table { typedef GatherV2T NativeTableType; static const flatbuffers::TypeTable *MiniReflectTypeTable() { return GatherV2TypeTable(); } DataType Taxis() const { return static_cast(GetField(4, 0)); } DataType Tindices() const { return static_cast(GetField(6, 0)); } DataType Tparams() const { return static_cast(GetField(8, 0)); } bool Verify(flatbuffers::Verifier &verifier) const { return VerifyTableStart(verifier) && VerifyField(verifier, 4) && VerifyField(verifier, 6) && VerifyField(verifier, 8) && verifier.EndTable(); } GatherV2T *UnPack(const flatbuffers::resolver_function_t *_resolver = nullptr) const; void UnPackTo(GatherV2T *_o, const flatbuffers::resolver_function_t *_resolver = nullptr) const; static flatbuffers::Offset Pack(flatbuffers::FlatBufferBuilder &_fbb, const GatherV2T* _o, const flatbuffers::rehasher_function_t *_rehasher = nullptr); }; struct GatherV2Builder { flatbuffers::FlatBufferBuilder &fbb_; flatbuffers::uoffset_t start_; void add_Taxis(DataType Taxis) { fbb_.AddElement(4, static_cast(Taxis), 0); } void add_Tindices(DataType Tindices) { fbb_.AddElement(6, static_cast(Tindices), 0); } void add_Tparams(DataType Tparams) { fbb_.AddElement(8, static_cast(Tparams), 0); } explicit GatherV2Builder(flatbuffers::FlatBufferBuilder &_fbb) : fbb_(_fbb) { start_ = fbb_.StartTable(); } GatherV2Builder &operator=(const GatherV2Builder &); flatbuffers::Offset Finish() { const auto end = fbb_.EndTable(start_); auto o = flatbuffers::Offset(end); return o; } }; inline flatbuffers::Offset CreateGatherV2( flatbuffers::FlatBufferBuilder &_fbb, DataType Taxis = DataType_DT_INVALID, DataType Tindices = DataType_DT_INVALID, DataType Tparams = DataType_DT_INVALID) { GatherV2Builder builder_(_fbb); builder_.add_Tparams(Tparams); builder_.add_Tindices(Tindices); builder_.add_Taxis(Taxis); return builder_.Finish(); } flatbuffers::Offset CreateGatherV2(flatbuffers::FlatBufferBuilder &_fbb, const GatherV2T *_o, const flatbuffers::rehasher_function_t *_rehasher = nullptr); struct NonMaxSuppressionV2T : public flatbuffers::NativeTable { typedef NonMaxSuppressionV2 TableType; NonMaxSuppressionV2T() { } }; struct NonMaxSuppressionV2 FLATBUFFERS_FINAL_CLASS : private flatbuffers::Table { typedef NonMaxSuppressionV2T NativeTableType; static const flatbuffers::TypeTable *MiniReflectTypeTable() { return NonMaxSuppressionV2TypeTable(); } bool Verify(flatbuffers::Verifier &verifier) const { return VerifyTableStart(verifier) && verifier.EndTable(); } NonMaxSuppressionV2T *UnPack(const flatbuffers::resolver_function_t *_resolver = nullptr) const; void UnPackTo(NonMaxSuppressionV2T *_o, const flatbuffers::resolver_function_t *_resolver = nullptr) const; static flatbuffers::Offset Pack(flatbuffers::FlatBufferBuilder &_fbb, const NonMaxSuppressionV2T* _o, const flatbuffers::rehasher_function_t *_rehasher = nullptr); }; struct NonMaxSuppressionV2Builder { flatbuffers::FlatBufferBuilder &fbb_; flatbuffers::uoffset_t start_; explicit NonMaxSuppressionV2Builder(flatbuffers::FlatBufferBuilder &_fbb) : fbb_(_fbb) { start_ = fbb_.StartTable(); } NonMaxSuppressionV2Builder &operator=(const NonMaxSuppressionV2Builder &); flatbuffers::Offset Finish() { const auto end = fbb_.EndTable(start_); auto o = flatbuffers::Offset(end); return o; } }; inline flatbuffers::Offset CreateNonMaxSuppressionV2( flatbuffers::FlatBufferBuilder &_fbb) { NonMaxSuppressionV2Builder builder_(_fbb); return builder_.Finish(); } flatbuffers::Offset CreateNonMaxSuppressionV2(flatbuffers::FlatBufferBuilder &_fbb, const NonMaxSuppressionV2T *_o, const flatbuffers::rehasher_function_t *_rehasher = nullptr); struct RangeT : public flatbuffers::NativeTable { typedef Range TableType; DataType Tidx; RangeT() : Tidx(DataType_DT_INVALID) { } }; struct Range FLATBUFFERS_FINAL_CLASS : private flatbuffers::Table { typedef RangeT NativeTableType; static const flatbuffers::TypeTable *MiniReflectTypeTable() { return RangeTypeTable(); } DataType Tidx() const { return static_cast(GetField(4, 0)); } bool Verify(flatbuffers::Verifier &verifier) const { return VerifyTableStart(verifier) && VerifyField(verifier, 4) && verifier.EndTable(); } RangeT *UnPack(const flatbuffers::resolver_function_t *_resolver = nullptr) const; void UnPackTo(RangeT *_o, const flatbuffers::resolver_function_t *_resolver = nullptr) const; static flatbuffers::Offset Pack(flatbuffers::FlatBufferBuilder &_fbb, const RangeT* _o, const flatbuffers::rehasher_function_t *_rehasher = nullptr); }; struct RangeBuilder { flatbuffers::FlatBufferBuilder &fbb_; flatbuffers::uoffset_t start_; void add_Tidx(DataType Tidx) { fbb_.AddElement(4, static_cast(Tidx), 0); } explicit RangeBuilder(flatbuffers::FlatBufferBuilder &_fbb) : fbb_(_fbb) { start_ = fbb_.StartTable(); } RangeBuilder &operator=(const RangeBuilder &); flatbuffers::Offset Finish() { const auto end = fbb_.EndTable(start_); auto o = flatbuffers::Offset(end); return o; } }; inline flatbuffers::Offset CreateRange( flatbuffers::FlatBufferBuilder &_fbb, DataType Tidx = DataType_DT_INVALID) { RangeBuilder builder_(_fbb); builder_.add_Tidx(Tidx); return builder_.Finish(); } flatbuffers::Offset CreateRange(flatbuffers::FlatBufferBuilder &_fbb, const RangeT *_o, const flatbuffers::rehasher_function_t *_rehasher = nullptr); struct RankT : public flatbuffers::NativeTable { typedef Rank TableType; RankT() { } }; struct Rank FLATBUFFERS_FINAL_CLASS : private flatbuffers::Table { typedef RankT NativeTableType; static const flatbuffers::TypeTable *MiniReflectTypeTable() { return RankTypeTable(); } bool Verify(flatbuffers::Verifier &verifier) const { return VerifyTableStart(verifier) && verifier.EndTable(); } RankT *UnPack(const flatbuffers::resolver_function_t *_resolver = nullptr) const; void UnPackTo(RankT *_o, const flatbuffers::resolver_function_t *_resolver = nullptr) const; static flatbuffers::Offset Pack(flatbuffers::FlatBufferBuilder &_fbb, const RankT* _o, const flatbuffers::rehasher_function_t *_rehasher = nullptr); }; struct RankBuilder { flatbuffers::FlatBufferBuilder &fbb_; flatbuffers::uoffset_t start_; explicit RankBuilder(flatbuffers::FlatBufferBuilder &_fbb) : fbb_(_fbb) { start_ = fbb_.StartTable(); } RankBuilder &operator=(const RankBuilder &); flatbuffers::Offset Finish() { const auto end = fbb_.EndTable(start_); auto o = flatbuffers::Offset(end); return o; } }; inline flatbuffers::Offset CreateRank( flatbuffers::FlatBufferBuilder &_fbb) { RankBuilder builder_(_fbb); return builder_.Finish(); } flatbuffers::Offset CreateRank(flatbuffers::FlatBufferBuilder &_fbb, const RankT *_o, const flatbuffers::rehasher_function_t *_rehasher = nullptr); struct SizeT : public flatbuffers::NativeTable { typedef Size TableType; DataType outputDataType; SizeT() : outputDataType(DataType_DT_INVALID) { } }; struct Size FLATBUFFERS_FINAL_CLASS : private flatbuffers::Table { typedef SizeT NativeTableType; static const flatbuffers::TypeTable *MiniReflectTypeTable() { return SizeTypeTable(); } DataType outputDataType() const { return static_cast(GetField(4, 0)); } bool Verify(flatbuffers::Verifier &verifier) const { return VerifyTableStart(verifier) && VerifyField(verifier, 4) && verifier.EndTable(); } SizeT *UnPack(const flatbuffers::resolver_function_t *_resolver = nullptr) const; void UnPackTo(SizeT *_o, const flatbuffers::resolver_function_t *_resolver = nullptr) const; static flatbuffers::Offset Pack(flatbuffers::FlatBufferBuilder &_fbb, const SizeT* _o, const flatbuffers::rehasher_function_t *_rehasher = nullptr); }; struct SizeBuilder { flatbuffers::FlatBufferBuilder &fbb_; flatbuffers::uoffset_t start_; void add_outputDataType(DataType outputDataType) { fbb_.AddElement(4, static_cast(outputDataType), 0); } explicit SizeBuilder(flatbuffers::FlatBufferBuilder &_fbb) : fbb_(_fbb) { start_ = fbb_.StartTable(); } SizeBuilder &operator=(const SizeBuilder &); flatbuffers::Offset Finish() { const auto end = fbb_.EndTable(start_); auto o = flatbuffers::Offset(end); return o; } }; inline flatbuffers::Offset CreateSize( flatbuffers::FlatBufferBuilder &_fbb, DataType outputDataType = DataType_DT_INVALID) { SizeBuilder builder_(_fbb); builder_.add_outputDataType(outputDataType); return builder_.Finish(); } flatbuffers::Offset CreateSize(flatbuffers::FlatBufferBuilder &_fbb, const SizeT *_o, const flatbuffers::rehasher_function_t *_rehasher = nullptr); struct TransposeT : public flatbuffers::NativeTable { typedef Transpose TableType; DataType Tperm; TransposeT() : Tperm(DataType_DT_INVALID) { } }; struct Transpose FLATBUFFERS_FINAL_CLASS : private flatbuffers::Table { typedef TransposeT NativeTableType; static const flatbuffers::TypeTable *MiniReflectTypeTable() { return TransposeTypeTable(); } DataType Tperm() const { return static_cast(GetField(4, 0)); } bool Verify(flatbuffers::Verifier &verifier) const { return VerifyTableStart(verifier) && VerifyField(verifier, 4) && verifier.EndTable(); } TransposeT *UnPack(const flatbuffers::resolver_function_t *_resolver = nullptr) const; void UnPackTo(TransposeT *_o, const flatbuffers::resolver_function_t *_resolver = nullptr) const; static flatbuffers::Offset Pack(flatbuffers::FlatBufferBuilder &_fbb, const TransposeT* _o, const flatbuffers::rehasher_function_t *_rehasher = nullptr); }; struct TransposeBuilder { flatbuffers::FlatBufferBuilder &fbb_; flatbuffers::uoffset_t start_; void add_Tperm(DataType Tperm) { fbb_.AddElement(4, static_cast(Tperm), 0); } explicit TransposeBuilder(flatbuffers::FlatBufferBuilder &_fbb) : fbb_(_fbb) { start_ = fbb_.StartTable(); } TransposeBuilder &operator=(const TransposeBuilder &); flatbuffers::Offset Finish() { const auto end = fbb_.EndTable(start_); auto o = flatbuffers::Offset(end); return o; } }; inline flatbuffers::Offset CreateTranspose( flatbuffers::FlatBufferBuilder &_fbb, DataType Tperm = DataType_DT_INVALID) { TransposeBuilder builder_(_fbb); builder_.add_Tperm(Tperm); return builder_.Finish(); } flatbuffers::Offset CreateTranspose(flatbuffers::FlatBufferBuilder &_fbb, const TransposeT *_o, const flatbuffers::rehasher_function_t *_rehasher = nullptr); struct SliceTfT : public flatbuffers::NativeTable { typedef SliceTf TableType; DataType T; SliceTfT() : T(DataType_DT_INVALID) { } }; struct SliceTf FLATBUFFERS_FINAL_CLASS : private flatbuffers::Table { typedef SliceTfT NativeTableType; static const flatbuffers::TypeTable *MiniReflectTypeTable() { return SliceTfTypeTable(); } DataType T() const { return static_cast(GetField(4, 0)); } bool Verify(flatbuffers::Verifier &verifier) const { return VerifyTableStart(verifier) && VerifyField(verifier, 4) && verifier.EndTable(); } SliceTfT *UnPack(const flatbuffers::resolver_function_t *_resolver = nullptr) const; void UnPackTo(SliceTfT *_o, const flatbuffers::resolver_function_t *_resolver = nullptr) const; static flatbuffers::Offset Pack(flatbuffers::FlatBufferBuilder &_fbb, const SliceTfT* _o, const flatbuffers::rehasher_function_t *_rehasher = nullptr); }; struct SliceTfBuilder { flatbuffers::FlatBufferBuilder &fbb_; flatbuffers::uoffset_t start_; void add_T(DataType T) { fbb_.AddElement(4, static_cast(T), 0); } explicit SliceTfBuilder(flatbuffers::FlatBufferBuilder &_fbb) : fbb_(_fbb) { start_ = fbb_.StartTable(); } SliceTfBuilder &operator=(const SliceTfBuilder &); flatbuffers::Offset Finish() { const auto end = fbb_.EndTable(start_); auto o = flatbuffers::Offset(end); return o; } }; inline flatbuffers::Offset CreateSliceTf( flatbuffers::FlatBufferBuilder &_fbb, DataType T = DataType_DT_INVALID) { SliceTfBuilder builder_(_fbb); builder_.add_T(T); return builder_.Finish(); } flatbuffers::Offset CreateSliceTf(flatbuffers::FlatBufferBuilder &_fbb, const SliceTfT *_o, const flatbuffers::rehasher_function_t *_rehasher = nullptr); struct QuantizeMaxMinT : public flatbuffers::NativeTable { typedef QuantizeMaxMin TableType; DataType T; QuantizeMaxMinT() : T(DataType_DT_INVALID) { } }; struct QuantizeMaxMin FLATBUFFERS_FINAL_CLASS : private flatbuffers::Table { typedef QuantizeMaxMinT NativeTableType; static const flatbuffers::TypeTable *MiniReflectTypeTable() { return QuantizeMaxMinTypeTable(); } DataType T() const { return static_cast(GetField(4, 0)); } bool Verify(flatbuffers::Verifier &verifier) const { return VerifyTableStart(verifier) && VerifyField(verifier, 4) && verifier.EndTable(); } QuantizeMaxMinT *UnPack(const flatbuffers::resolver_function_t *_resolver = nullptr) const; void UnPackTo(QuantizeMaxMinT *_o, const flatbuffers::resolver_function_t *_resolver = nullptr) const; static flatbuffers::Offset Pack(flatbuffers::FlatBufferBuilder &_fbb, const QuantizeMaxMinT* _o, const flatbuffers::rehasher_function_t *_rehasher = nullptr); }; struct QuantizeMaxMinBuilder { flatbuffers::FlatBufferBuilder &fbb_; flatbuffers::uoffset_t start_; void add_T(DataType T) { fbb_.AddElement(4, static_cast(T), 0); } explicit QuantizeMaxMinBuilder(flatbuffers::FlatBufferBuilder &_fbb) : fbb_(_fbb) { start_ = fbb_.StartTable(); } QuantizeMaxMinBuilder &operator=(const QuantizeMaxMinBuilder &); flatbuffers::Offset Finish() { const auto end = fbb_.EndTable(start_); auto o = flatbuffers::Offset(end); return o; } }; inline flatbuffers::Offset CreateQuantizeMaxMin( flatbuffers::FlatBufferBuilder &_fbb, DataType T = DataType_DT_INVALID) { QuantizeMaxMinBuilder builder_(_fbb); builder_.add_T(T); return builder_.Finish(); } flatbuffers::Offset CreateQuantizeMaxMin(flatbuffers::FlatBufferBuilder &_fbb, const QuantizeMaxMinT *_o, const flatbuffers::rehasher_function_t *_rehasher = nullptr); struct CropT : public flatbuffers::NativeTable { typedef Crop TableType; int32_t axis; std::vector offset; CropT() : axis(2) { } }; struct Crop FLATBUFFERS_FINAL_CLASS : private flatbuffers::Table { typedef CropT NativeTableType; static const flatbuffers::TypeTable *MiniReflectTypeTable() { return CropTypeTable(); } int32_t axis() const { return GetField(4, 2); } const flatbuffers::Vector *offset() const { return GetPointer *>(6); } bool Verify(flatbuffers::Verifier &verifier) const { return VerifyTableStart(verifier) && VerifyField(verifier, 4) && VerifyOffset(verifier, 6) && verifier.VerifyVector(offset()) && verifier.EndTable(); } CropT *UnPack(const flatbuffers::resolver_function_t *_resolver = nullptr) const; void UnPackTo(CropT *_o, const flatbuffers::resolver_function_t *_resolver = nullptr) const; static flatbuffers::Offset Pack(flatbuffers::FlatBufferBuilder &_fbb, const CropT* _o, const flatbuffers::rehasher_function_t *_rehasher = nullptr); }; struct CropBuilder { flatbuffers::FlatBufferBuilder &fbb_; flatbuffers::uoffset_t start_; void add_axis(int32_t axis) { fbb_.AddElement(4, axis, 2); } void add_offset(flatbuffers::Offset> offset) { fbb_.AddOffset(6, offset); } explicit CropBuilder(flatbuffers::FlatBufferBuilder &_fbb) : fbb_(_fbb) { start_ = fbb_.StartTable(); } CropBuilder &operator=(const CropBuilder &); flatbuffers::Offset Finish() { const auto end = fbb_.EndTable(start_); auto o = flatbuffers::Offset(end); return o; } }; inline flatbuffers::Offset CreateCrop( flatbuffers::FlatBufferBuilder &_fbb, int32_t axis = 2, flatbuffers::Offset> offset = 0) { CropBuilder builder_(_fbb); builder_.add_offset(offset); builder_.add_axis(axis); return builder_.Finish(); } flatbuffers::Offset CreateCrop(flatbuffers::FlatBufferBuilder &_fbb, const CropT *_o, const flatbuffers::rehasher_function_t *_rehasher = nullptr); struct SpaceBatchT : public flatbuffers::NativeTable { typedef SpaceBatch TableType; std::unique_ptr blockShape; std::unique_ptr padding; SpaceBatchT() { } }; struct SpaceBatch FLATBUFFERS_FINAL_CLASS : private flatbuffers::Table { typedef SpaceBatchT NativeTableType; static const flatbuffers::TypeTable *MiniReflectTypeTable() { return SpaceBatchTypeTable(); } const Blob *blockShape() const { return GetPointer(4); } const Blob *padding() const { return GetPointer(6); } bool Verify(flatbuffers::Verifier &verifier) const { return VerifyTableStart(verifier) && VerifyOffset(verifier, 4) && verifier.VerifyTable(blockShape()) && VerifyOffset(verifier, 6) && verifier.VerifyTable(padding()) && verifier.EndTable(); } SpaceBatchT *UnPack(const flatbuffers::resolver_function_t *_resolver = nullptr) const; void UnPackTo(SpaceBatchT *_o, const flatbuffers::resolver_function_t *_resolver = nullptr) const; static flatbuffers::Offset Pack(flatbuffers::FlatBufferBuilder &_fbb, const SpaceBatchT* _o, const flatbuffers::rehasher_function_t *_rehasher = nullptr); }; struct SpaceBatchBuilder { flatbuffers::FlatBufferBuilder &fbb_; flatbuffers::uoffset_t start_; void add_blockShape(flatbuffers::Offset blockShape) { fbb_.AddOffset(4, blockShape); } void add_padding(flatbuffers::Offset padding) { fbb_.AddOffset(6, padding); } explicit SpaceBatchBuilder(flatbuffers::FlatBufferBuilder &_fbb) : fbb_(_fbb) { start_ = fbb_.StartTable(); } SpaceBatchBuilder &operator=(const SpaceBatchBuilder &); flatbuffers::Offset Finish() { const auto end = fbb_.EndTable(start_); auto o = flatbuffers::Offset(end); return o; } }; inline flatbuffers::Offset CreateSpaceBatch( flatbuffers::FlatBufferBuilder &_fbb, flatbuffers::Offset blockShape = 0, flatbuffers::Offset padding = 0) { SpaceBatchBuilder builder_(_fbb); builder_.add_padding(padding); builder_.add_blockShape(blockShape); return builder_.Finish(); } flatbuffers::Offset CreateSpaceBatch(flatbuffers::FlatBufferBuilder &_fbb, const SpaceBatchT *_o, const flatbuffers::rehasher_function_t *_rehasher = nullptr); struct MatMulT : public flatbuffers::NativeTable { typedef MatMul TableType; DataType T; bool transposeA; bool transposeB; std::vector weight; std::vector bias; MatMulT() : T(DataType_DT_INVALID), transposeA(false), transposeB(false) { } }; struct MatMul FLATBUFFERS_FINAL_CLASS : private flatbuffers::Table { typedef MatMulT NativeTableType; static const flatbuffers::TypeTable *MiniReflectTypeTable() { return MatMulTypeTable(); } DataType T() const { return static_cast(GetField(4, 0)); } bool transposeA() const { return GetField(6, 0) != 0; } bool transposeB() const { return GetField(8, 0) != 0; } const flatbuffers::Vector *weight() const { return GetPointer *>(10); } const flatbuffers::Vector *bias() const { return GetPointer *>(12); } bool Verify(flatbuffers::Verifier &verifier) const { return VerifyTableStart(verifier) && VerifyField(verifier, 4) && VerifyField(verifier, 6) && VerifyField(verifier, 8) && VerifyOffset(verifier, 10) && verifier.VerifyVector(weight()) && VerifyOffset(verifier, 12) && verifier.VerifyVector(bias()) && verifier.EndTable(); } MatMulT *UnPack(const flatbuffers::resolver_function_t *_resolver = nullptr) const; void UnPackTo(MatMulT *_o, const flatbuffers::resolver_function_t *_resolver = nullptr) const; static flatbuffers::Offset Pack(flatbuffers::FlatBufferBuilder &_fbb, const MatMulT* _o, const flatbuffers::rehasher_function_t *_rehasher = nullptr); }; struct MatMulBuilder { flatbuffers::FlatBufferBuilder &fbb_; flatbuffers::uoffset_t start_; void add_T(DataType T) { fbb_.AddElement(4, static_cast(T), 0); } void add_transposeA(bool transposeA) { fbb_.AddElement(6, static_cast(transposeA), 0); } void add_transposeB(bool transposeB) { fbb_.AddElement(8, static_cast(transposeB), 0); } void add_weight(flatbuffers::Offset> weight) { fbb_.AddOffset(10, weight); } void add_bias(flatbuffers::Offset> bias) { fbb_.AddOffset(12, bias); } explicit MatMulBuilder(flatbuffers::FlatBufferBuilder &_fbb) : fbb_(_fbb) { start_ = fbb_.StartTable(); } MatMulBuilder &operator=(const MatMulBuilder &); flatbuffers::Offset Finish() { const auto end = fbb_.EndTable(start_); auto o = flatbuffers::Offset(end); return o; } }; inline flatbuffers::Offset CreateMatMul( flatbuffers::FlatBufferBuilder &_fbb, DataType T = DataType_DT_INVALID, bool transposeA = false, bool transposeB = false, flatbuffers::Offset> weight = 0, flatbuffers::Offset> bias = 0) { MatMulBuilder builder_(_fbb); builder_.add_bias(bias); builder_.add_weight(weight); builder_.add_T(T); builder_.add_transposeB(transposeB); builder_.add_transposeA(transposeA); return builder_.Finish(); } flatbuffers::Offset CreateMatMul(flatbuffers::FlatBufferBuilder &_fbb, const MatMulT *_o, const flatbuffers::rehasher_function_t *_rehasher = nullptr); struct MomentsParamT : public flatbuffers::NativeTable { typedef MomentsParam TableType; std::vector dim; bool keepDims; DataType dType; MomentsParamT() : keepDims(true), dType(DataType_DT_FLOAT) { } }; struct MomentsParam FLATBUFFERS_FINAL_CLASS : private flatbuffers::Table { typedef MomentsParamT NativeTableType; static const flatbuffers::TypeTable *MiniReflectTypeTable() { return MomentsParamTypeTable(); } const flatbuffers::Vector *dim() const { return GetPointer *>(4); } bool keepDims() const { return GetField(6, 1) != 0; } DataType dType() const { return static_cast(GetField(8, 1)); } bool Verify(flatbuffers::Verifier &verifier) const { return VerifyTableStart(verifier) && VerifyOffset(verifier, 4) && verifier.VerifyVector(dim()) && VerifyField(verifier, 6) && VerifyField(verifier, 8) && verifier.EndTable(); } MomentsParamT *UnPack(const flatbuffers::resolver_function_t *_resolver = nullptr) const; void UnPackTo(MomentsParamT *_o, const flatbuffers::resolver_function_t *_resolver = nullptr) const; static flatbuffers::Offset Pack(flatbuffers::FlatBufferBuilder &_fbb, const MomentsParamT* _o, const flatbuffers::rehasher_function_t *_rehasher = nullptr); }; struct MomentsParamBuilder { flatbuffers::FlatBufferBuilder &fbb_; flatbuffers::uoffset_t start_; void add_dim(flatbuffers::Offset> dim) { fbb_.AddOffset(4, dim); } void add_keepDims(bool keepDims) { fbb_.AddElement(6, static_cast(keepDims), 1); } void add_dType(DataType dType) { fbb_.AddElement(8, static_cast(dType), 1); } explicit MomentsParamBuilder(flatbuffers::FlatBufferBuilder &_fbb) : fbb_(_fbb) { start_ = fbb_.StartTable(); } MomentsParamBuilder &operator=(const MomentsParamBuilder &); flatbuffers::Offset Finish() { const auto end = fbb_.EndTable(start_); auto o = flatbuffers::Offset(end); return o; } }; inline flatbuffers::Offset CreateMomentsParam( flatbuffers::FlatBufferBuilder &_fbb, flatbuffers::Offset> dim = 0, bool keepDims = true, DataType dType = DataType_DT_FLOAT) { MomentsParamBuilder builder_(_fbb); builder_.add_dType(dType); builder_.add_dim(dim); builder_.add_keepDims(keepDims); return builder_.Finish(); } flatbuffers::Offset CreateMomentsParam(flatbuffers::FlatBufferBuilder &_fbb, const MomentsParamT *_o, const flatbuffers::rehasher_function_t *_rehasher = nullptr); struct RNNParamT : public flatbuffers::NativeTable { typedef RNNParam TableType; int32_t numUnits; bool isBidirectionalRNN; bool linearBeforeReset; bool keepAllOutputs; std::unique_ptr fwGateWeight; std::unique_ptr fwGateBias; std::unique_ptr fwCandidateWeight; std::unique_ptr fwCandidateBias; std::unique_ptr fwRecurrentBias; std::unique_ptr bwGateWeight; std::unique_ptr bwGateBias; std::unique_ptr bwCandidateWeight; std::unique_ptr bwCandidateBias; std::unique_ptr bwRecurrentBias; RNNParamT() : numUnits(0), isBidirectionalRNN(false), linearBeforeReset(false), keepAllOutputs(false) { } }; struct RNNParam FLATBUFFERS_FINAL_CLASS : private flatbuffers::Table { typedef RNNParamT NativeTableType; static const flatbuffers::TypeTable *MiniReflectTypeTable() { return RNNParamTypeTable(); } int32_t numUnits() const { return GetField(4, 0); } bool isBidirectionalRNN() const { return GetField(6, 0) != 0; } bool linearBeforeReset() const { return GetField(8, 0) != 0; } bool keepAllOutputs() const { return GetField(10, 0) != 0; } const Blob *fwGateWeight() const { return GetPointer(12); } const Blob *fwGateBias() const { return GetPointer(14); } const Blob *fwCandidateWeight() const { return GetPointer(16); } const Blob *fwCandidateBias() const { return GetPointer(18); } const Blob *fwRecurrentBias() const { return GetPointer(20); } const Blob *bwGateWeight() const { return GetPointer(22); } const Blob *bwGateBias() const { return GetPointer(24); } const Blob *bwCandidateWeight() const { return GetPointer(26); } const Blob *bwCandidateBias() const { return GetPointer(28); } const Blob *bwRecurrentBias() const { return GetPointer(30); } bool Verify(flatbuffers::Verifier &verifier) const { return VerifyTableStart(verifier) && VerifyField(verifier, 4) && VerifyField(verifier, 6) && VerifyField(verifier, 8) && VerifyField(verifier, 10) && VerifyOffset(verifier, 12) && verifier.VerifyTable(fwGateWeight()) && VerifyOffset(verifier, 14) && verifier.VerifyTable(fwGateBias()) && VerifyOffset(verifier, 16) && verifier.VerifyTable(fwCandidateWeight()) && VerifyOffset(verifier, 18) && verifier.VerifyTable(fwCandidateBias()) && VerifyOffset(verifier, 20) && verifier.VerifyTable(fwRecurrentBias()) && VerifyOffset(verifier, 22) && verifier.VerifyTable(bwGateWeight()) && VerifyOffset(verifier, 24) && verifier.VerifyTable(bwGateBias()) && VerifyOffset(verifier, 26) && verifier.VerifyTable(bwCandidateWeight()) && VerifyOffset(verifier, 28) && verifier.VerifyTable(bwCandidateBias()) && VerifyOffset(verifier, 30) && verifier.VerifyTable(bwRecurrentBias()) && verifier.EndTable(); } RNNParamT *UnPack(const flatbuffers::resolver_function_t *_resolver = nullptr) const; void UnPackTo(RNNParamT *_o, const flatbuffers::resolver_function_t *_resolver = nullptr) const; static flatbuffers::Offset Pack(flatbuffers::FlatBufferBuilder &_fbb, const RNNParamT* _o, const flatbuffers::rehasher_function_t *_rehasher = nullptr); }; struct RNNParamBuilder { flatbuffers::FlatBufferBuilder &fbb_; flatbuffers::uoffset_t start_; void add_numUnits(int32_t numUnits) { fbb_.AddElement(4, numUnits, 0); } void add_isBidirectionalRNN(bool isBidirectionalRNN) { fbb_.AddElement(6, static_cast(isBidirectionalRNN), 0); } void add_linearBeforeReset(bool linearBeforeReset) { fbb_.AddElement(8, static_cast(linearBeforeReset), 0); } void add_keepAllOutputs(bool keepAllOutputs) { fbb_.AddElement(10, static_cast(keepAllOutputs), 0); } void add_fwGateWeight(flatbuffers::Offset fwGateWeight) { fbb_.AddOffset(12, fwGateWeight); } void add_fwGateBias(flatbuffers::Offset fwGateBias) { fbb_.AddOffset(14, fwGateBias); } void add_fwCandidateWeight(flatbuffers::Offset fwCandidateWeight) { fbb_.AddOffset(16, fwCandidateWeight); } void add_fwCandidateBias(flatbuffers::Offset fwCandidateBias) { fbb_.AddOffset(18, fwCandidateBias); } void add_fwRecurrentBias(flatbuffers::Offset fwRecurrentBias) { fbb_.AddOffset(20, fwRecurrentBias); } void add_bwGateWeight(flatbuffers::Offset bwGateWeight) { fbb_.AddOffset(22, bwGateWeight); } void add_bwGateBias(flatbuffers::Offset bwGateBias) { fbb_.AddOffset(24, bwGateBias); } void add_bwCandidateWeight(flatbuffers::Offset bwCandidateWeight) { fbb_.AddOffset(26, bwCandidateWeight); } void add_bwCandidateBias(flatbuffers::Offset bwCandidateBias) { fbb_.AddOffset(28, bwCandidateBias); } void add_bwRecurrentBias(flatbuffers::Offset bwRecurrentBias) { fbb_.AddOffset(30, bwRecurrentBias); } explicit RNNParamBuilder(flatbuffers::FlatBufferBuilder &_fbb) : fbb_(_fbb) { start_ = fbb_.StartTable(); } RNNParamBuilder &operator=(const RNNParamBuilder &); flatbuffers::Offset Finish() { const auto end = fbb_.EndTable(start_); auto o = flatbuffers::Offset(end); return o; } }; inline flatbuffers::Offset CreateRNNParam( flatbuffers::FlatBufferBuilder &_fbb, int32_t numUnits = 0, bool isBidirectionalRNN = false, bool linearBeforeReset = false, bool keepAllOutputs = false, flatbuffers::Offset fwGateWeight = 0, flatbuffers::Offset fwGateBias = 0, flatbuffers::Offset fwCandidateWeight = 0, flatbuffers::Offset fwCandidateBias = 0, flatbuffers::Offset fwRecurrentBias = 0, flatbuffers::Offset bwGateWeight = 0, flatbuffers::Offset bwGateBias = 0, flatbuffers::Offset bwCandidateWeight = 0, flatbuffers::Offset bwCandidateBias = 0, flatbuffers::Offset bwRecurrentBias = 0) { RNNParamBuilder builder_(_fbb); builder_.add_bwRecurrentBias(bwRecurrentBias); builder_.add_bwCandidateBias(bwCandidateBias); builder_.add_bwCandidateWeight(bwCandidateWeight); builder_.add_bwGateBias(bwGateBias); builder_.add_bwGateWeight(bwGateWeight); builder_.add_fwRecurrentBias(fwRecurrentBias); builder_.add_fwCandidateBias(fwCandidateBias); builder_.add_fwCandidateWeight(fwCandidateWeight); builder_.add_fwGateBias(fwGateBias); builder_.add_fwGateWeight(fwGateWeight); builder_.add_numUnits(numUnits); builder_.add_keepAllOutputs(keepAllOutputs); builder_.add_linearBeforeReset(linearBeforeReset); builder_.add_isBidirectionalRNN(isBidirectionalRNN); return builder_.Finish(); } flatbuffers::Offset CreateRNNParam(flatbuffers::FlatBufferBuilder &_fbb, const RNNParamT *_o, const flatbuffers::rehasher_function_t *_rehasher = nullptr); struct BatchMatMulParamT : public flatbuffers::NativeTable { typedef BatchMatMulParam TableType; bool adjX; bool adjY; BatchMatMulParamT() : adjX(false), adjY(false) { } }; struct BatchMatMulParam FLATBUFFERS_FINAL_CLASS : private flatbuffers::Table { typedef BatchMatMulParamT NativeTableType; static const flatbuffers::TypeTable *MiniReflectTypeTable() { return BatchMatMulParamTypeTable(); } bool adjX() const { return GetField(4, 0) != 0; } bool adjY() const { return GetField(6, 0) != 0; } bool Verify(flatbuffers::Verifier &verifier) const { return VerifyTableStart(verifier) && VerifyField(verifier, 4) && VerifyField(verifier, 6) && verifier.EndTable(); } BatchMatMulParamT *UnPack(const flatbuffers::resolver_function_t *_resolver = nullptr) const; void UnPackTo(BatchMatMulParamT *_o, const flatbuffers::resolver_function_t *_resolver = nullptr) const; static flatbuffers::Offset Pack(flatbuffers::FlatBufferBuilder &_fbb, const BatchMatMulParamT* _o, const flatbuffers::rehasher_function_t *_rehasher = nullptr); }; struct BatchMatMulParamBuilder { flatbuffers::FlatBufferBuilder &fbb_; flatbuffers::uoffset_t start_; void add_adjX(bool adjX) { fbb_.AddElement(4, static_cast(adjX), 0); } void add_adjY(bool adjY) { fbb_.AddElement(6, static_cast(adjY), 0); } explicit BatchMatMulParamBuilder(flatbuffers::FlatBufferBuilder &_fbb) : fbb_(_fbb) { start_ = fbb_.StartTable(); } BatchMatMulParamBuilder &operator=(const BatchMatMulParamBuilder &); flatbuffers::Offset Finish() { const auto end = fbb_.EndTable(start_); auto o = flatbuffers::Offset(end); return o; } }; inline flatbuffers::Offset CreateBatchMatMulParam( flatbuffers::FlatBufferBuilder &_fbb, bool adjX = false, bool adjY = false) { BatchMatMulParamBuilder builder_(_fbb); builder_.add_adjY(adjY); builder_.add_adjX(adjX); return builder_.Finish(); } flatbuffers::Offset CreateBatchMatMulParam(flatbuffers::FlatBufferBuilder &_fbb, const BatchMatMulParamT *_o, const flatbuffers::rehasher_function_t *_rehasher = nullptr); struct DepthSpaceParamT : public flatbuffers::NativeTable { typedef DepthSpaceParam TableType; int32_t blockSize; DepthToSpaceMode mode; DepthSpaceParamT() : blockSize(0), mode(DepthToSpaceMode_DCR) { } }; struct DepthSpaceParam FLATBUFFERS_FINAL_CLASS : private flatbuffers::Table { typedef DepthSpaceParamT NativeTableType; static const flatbuffers::TypeTable *MiniReflectTypeTable() { return DepthSpaceParamTypeTable(); } int32_t blockSize() const { return GetField(4, 0); } DepthToSpaceMode mode() const { return static_cast(GetField(6, 0)); } bool Verify(flatbuffers::Verifier &verifier) const { return VerifyTableStart(verifier) && VerifyField(verifier, 4) && VerifyField(verifier, 6) && verifier.EndTable(); } DepthSpaceParamT *UnPack(const flatbuffers::resolver_function_t *_resolver = nullptr) const; void UnPackTo(DepthSpaceParamT *_o, const flatbuffers::resolver_function_t *_resolver = nullptr) const; static flatbuffers::Offset Pack(flatbuffers::FlatBufferBuilder &_fbb, const DepthSpaceParamT* _o, const flatbuffers::rehasher_function_t *_rehasher = nullptr); }; struct DepthSpaceParamBuilder { flatbuffers::FlatBufferBuilder &fbb_; flatbuffers::uoffset_t start_; void add_blockSize(int32_t blockSize) { fbb_.AddElement(4, blockSize, 0); } void add_mode(DepthToSpaceMode mode) { fbb_.AddElement(6, static_cast(mode), 0); } explicit DepthSpaceParamBuilder(flatbuffers::FlatBufferBuilder &_fbb) : fbb_(_fbb) { start_ = fbb_.StartTable(); } DepthSpaceParamBuilder &operator=(const DepthSpaceParamBuilder &); flatbuffers::Offset Finish() { const auto end = fbb_.EndTable(start_); auto o = flatbuffers::Offset(end); return o; } }; inline flatbuffers::Offset CreateDepthSpaceParam( flatbuffers::FlatBufferBuilder &_fbb, int32_t blockSize = 0, DepthToSpaceMode mode = DepthToSpaceMode_DCR) { DepthSpaceParamBuilder builder_(_fbb); builder_.add_blockSize(blockSize); builder_.add_mode(mode); return builder_.Finish(); } flatbuffers::Offset CreateDepthSpaceParam(flatbuffers::FlatBufferBuilder &_fbb, const DepthSpaceParamT *_o, const flatbuffers::rehasher_function_t *_rehasher = nullptr); struct ReverseSequenceParamT : public flatbuffers::NativeTable { typedef ReverseSequenceParam TableType; int32_t batchDim; int32_t seqDim; ReverseSequenceParamT() : batchDim(0), seqDim(0) { } }; struct ReverseSequenceParam FLATBUFFERS_FINAL_CLASS : private flatbuffers::Table { typedef ReverseSequenceParamT NativeTableType; static const flatbuffers::TypeTable *MiniReflectTypeTable() { return ReverseSequenceParamTypeTable(); } int32_t batchDim() const { return GetField(4, 0); } int32_t seqDim() const { return GetField(6, 0); } bool Verify(flatbuffers::Verifier &verifier) const { return VerifyTableStart(verifier) && VerifyField(verifier, 4) && VerifyField(verifier, 6) && verifier.EndTable(); } ReverseSequenceParamT *UnPack(const flatbuffers::resolver_function_t *_resolver = nullptr) const; void UnPackTo(ReverseSequenceParamT *_o, const flatbuffers::resolver_function_t *_resolver = nullptr) const; static flatbuffers::Offset Pack(flatbuffers::FlatBufferBuilder &_fbb, const ReverseSequenceParamT* _o, const flatbuffers::rehasher_function_t *_rehasher = nullptr); }; struct ReverseSequenceParamBuilder { flatbuffers::FlatBufferBuilder &fbb_; flatbuffers::uoffset_t start_; void add_batchDim(int32_t batchDim) { fbb_.AddElement(4, batchDim, 0); } void add_seqDim(int32_t seqDim) { fbb_.AddElement(6, seqDim, 0); } explicit ReverseSequenceParamBuilder(flatbuffers::FlatBufferBuilder &_fbb) : fbb_(_fbb) { start_ = fbb_.StartTable(); } ReverseSequenceParamBuilder &operator=(const ReverseSequenceParamBuilder &); flatbuffers::Offset Finish() { const auto end = fbb_.EndTable(start_); auto o = flatbuffers::Offset(end); return o; } }; inline flatbuffers::Offset CreateReverseSequenceParam( flatbuffers::FlatBufferBuilder &_fbb, int32_t batchDim = 0, int32_t seqDim = 0) { ReverseSequenceParamBuilder builder_(_fbb); builder_.add_seqDim(seqDim); builder_.add_batchDim(batchDim); return builder_.Finish(); } flatbuffers::Offset CreateReverseSequenceParam(flatbuffers::FlatBufferBuilder &_fbb, const ReverseSequenceParamT *_o, const flatbuffers::rehasher_function_t *_rehasher = nullptr); struct DetectionPostProcessParamT : public flatbuffers::NativeTable { typedef DetectionPostProcessParam TableType; int32_t maxDetections; int32_t maxClassesPerDetection; int32_t detectionsPerClass; float nmsScoreThreshold; float iouThreshold; int32_t numClasses; bool useRegularNMS; std::vector centerSizeEncoding; DetectionPostProcessParamT() : maxDetections(0), maxClassesPerDetection(0), detectionsPerClass(0), nmsScoreThreshold(0.0f), iouThreshold(0.0f), numClasses(0), useRegularNMS(false) { } }; struct DetectionPostProcessParam FLATBUFFERS_FINAL_CLASS : private flatbuffers::Table { typedef DetectionPostProcessParamT NativeTableType; static const flatbuffers::TypeTable *MiniReflectTypeTable() { return DetectionPostProcessParamTypeTable(); } int32_t maxDetections() const { return GetField(4, 0); } int32_t maxClassesPerDetection() const { return GetField(6, 0); } int32_t detectionsPerClass() const { return GetField(8, 0); } float nmsScoreThreshold() const { return GetField(10, 0.0f); } float iouThreshold() const { return GetField(12, 0.0f); } int32_t numClasses() const { return GetField(14, 0); } bool useRegularNMS() const { return GetField(16, 0) != 0; } const flatbuffers::Vector *centerSizeEncoding() const { return GetPointer *>(18); } bool Verify(flatbuffers::Verifier &verifier) const { return VerifyTableStart(verifier) && VerifyField(verifier, 4) && VerifyField(verifier, 6) && VerifyField(verifier, 8) && VerifyField(verifier, 10) && VerifyField(verifier, 12) && VerifyField(verifier, 14) && VerifyField(verifier, 16) && VerifyOffset(verifier, 18) && verifier.VerifyVector(centerSizeEncoding()) && verifier.EndTable(); } DetectionPostProcessParamT *UnPack(const flatbuffers::resolver_function_t *_resolver = nullptr) const; void UnPackTo(DetectionPostProcessParamT *_o, const flatbuffers::resolver_function_t *_resolver = nullptr) const; static flatbuffers::Offset Pack(flatbuffers::FlatBufferBuilder &_fbb, const DetectionPostProcessParamT* _o, const flatbuffers::rehasher_function_t *_rehasher = nullptr); }; struct DetectionPostProcessParamBuilder { flatbuffers::FlatBufferBuilder &fbb_; flatbuffers::uoffset_t start_; void add_maxDetections(int32_t maxDetections) { fbb_.AddElement(4, maxDetections, 0); } void add_maxClassesPerDetection(int32_t maxClassesPerDetection) { fbb_.AddElement(6, maxClassesPerDetection, 0); } void add_detectionsPerClass(int32_t detectionsPerClass) { fbb_.AddElement(8, detectionsPerClass, 0); } void add_nmsScoreThreshold(float nmsScoreThreshold) { fbb_.AddElement(10, nmsScoreThreshold, 0.0f); } void add_iouThreshold(float iouThreshold) { fbb_.AddElement(12, iouThreshold, 0.0f); } void add_numClasses(int32_t numClasses) { fbb_.AddElement(14, numClasses, 0); } void add_useRegularNMS(bool useRegularNMS) { fbb_.AddElement(16, static_cast(useRegularNMS), 0); } void add_centerSizeEncoding(flatbuffers::Offset> centerSizeEncoding) { fbb_.AddOffset(18, centerSizeEncoding); } explicit DetectionPostProcessParamBuilder(flatbuffers::FlatBufferBuilder &_fbb) : fbb_(_fbb) { start_ = fbb_.StartTable(); } DetectionPostProcessParamBuilder &operator=(const DetectionPostProcessParamBuilder &); flatbuffers::Offset Finish() { const auto end = fbb_.EndTable(start_); auto o = flatbuffers::Offset(end); return o; } }; inline flatbuffers::Offset CreateDetectionPostProcessParam( flatbuffers::FlatBufferBuilder &_fbb, int32_t maxDetections = 0, int32_t maxClassesPerDetection = 0, int32_t detectionsPerClass = 0, float nmsScoreThreshold = 0.0f, float iouThreshold = 0.0f, int32_t numClasses = 0, bool useRegularNMS = false, flatbuffers::Offset> centerSizeEncoding = 0) { DetectionPostProcessParamBuilder builder_(_fbb); builder_.add_centerSizeEncoding(centerSizeEncoding); builder_.add_numClasses(numClasses); builder_.add_iouThreshold(iouThreshold); builder_.add_nmsScoreThreshold(nmsScoreThreshold); builder_.add_detectionsPerClass(detectionsPerClass); builder_.add_maxClassesPerDetection(maxClassesPerDetection); builder_.add_maxDetections(maxDetections); builder_.add_useRegularNMS(useRegularNMS); return builder_.Finish(); } flatbuffers::Offset CreateDetectionPostProcessParam(flatbuffers::FlatBufferBuilder &_fbb, const DetectionPostProcessParamT *_o, const flatbuffers::rehasher_function_t *_rehasher = nullptr); struct OneHotParamT : public flatbuffers::NativeTable { typedef OneHotParam TableType; DataType dType; int32_t axis; OneHotParamT() : dType(DataType_DT_FLOAT), axis(-1) { } }; struct OneHotParam FLATBUFFERS_FINAL_CLASS : private flatbuffers::Table { typedef OneHotParamT NativeTableType; static const flatbuffers::TypeTable *MiniReflectTypeTable() { return OneHotParamTypeTable(); } DataType dType() const { return static_cast(GetField(4, 1)); } int32_t axis() const { return GetField(6, -1); } bool Verify(flatbuffers::Verifier &verifier) const { return VerifyTableStart(verifier) && VerifyField(verifier, 4) && VerifyField(verifier, 6) && verifier.EndTable(); } OneHotParamT *UnPack(const flatbuffers::resolver_function_t *_resolver = nullptr) const; void UnPackTo(OneHotParamT *_o, const flatbuffers::resolver_function_t *_resolver = nullptr) const; static flatbuffers::Offset Pack(flatbuffers::FlatBufferBuilder &_fbb, const OneHotParamT* _o, const flatbuffers::rehasher_function_t *_rehasher = nullptr); }; struct OneHotParamBuilder { flatbuffers::FlatBufferBuilder &fbb_; flatbuffers::uoffset_t start_; void add_dType(DataType dType) { fbb_.AddElement(4, static_cast(dType), 1); } void add_axis(int32_t axis) { fbb_.AddElement(6, axis, -1); } explicit OneHotParamBuilder(flatbuffers::FlatBufferBuilder &_fbb) : fbb_(_fbb) { start_ = fbb_.StartTable(); } OneHotParamBuilder &operator=(const OneHotParamBuilder &); flatbuffers::Offset Finish() { const auto end = fbb_.EndTable(start_); auto o = flatbuffers::Offset(end); return o; } }; inline flatbuffers::Offset CreateOneHotParam( flatbuffers::FlatBufferBuilder &_fbb, DataType dType = DataType_DT_FLOAT, int32_t axis = -1) { OneHotParamBuilder builder_(_fbb); builder_.add_axis(axis); builder_.add_dType(dType); return builder_.Finish(); } flatbuffers::Offset CreateOneHotParam(flatbuffers::FlatBufferBuilder &_fbb, const OneHotParamT *_o, const flatbuffers::rehasher_function_t *_rehasher = nullptr); struct PadParamT : public flatbuffers::NativeTable { typedef PadParam TableType; PadValueMode mode; PadParamT() : mode(PadValueMode_CONSTANT) { } }; struct PadParam FLATBUFFERS_FINAL_CLASS : private flatbuffers::Table { typedef PadParamT NativeTableType; static const flatbuffers::TypeTable *MiniReflectTypeTable() { return PadParamTypeTable(); } PadValueMode mode() const { return static_cast(GetField(4, 0)); } bool Verify(flatbuffers::Verifier &verifier) const { return VerifyTableStart(verifier) && VerifyField(verifier, 4) && verifier.EndTable(); } PadParamT *UnPack(const flatbuffers::resolver_function_t *_resolver = nullptr) const; void UnPackTo(PadParamT *_o, const flatbuffers::resolver_function_t *_resolver = nullptr) const; static flatbuffers::Offset Pack(flatbuffers::FlatBufferBuilder &_fbb, const PadParamT* _o, const flatbuffers::rehasher_function_t *_rehasher = nullptr); }; struct PadParamBuilder { flatbuffers::FlatBufferBuilder &fbb_; flatbuffers::uoffset_t start_; void add_mode(PadValueMode mode) { fbb_.AddElement(4, static_cast(mode), 0); } explicit PadParamBuilder(flatbuffers::FlatBufferBuilder &_fbb) : fbb_(_fbb) { start_ = fbb_.StartTable(); } PadParamBuilder &operator=(const PadParamBuilder &); flatbuffers::Offset Finish() { const auto end = fbb_.EndTable(start_); auto o = flatbuffers::Offset(end); return o; } }; inline flatbuffers::Offset CreatePadParam( flatbuffers::FlatBufferBuilder &_fbb, PadValueMode mode = PadValueMode_CONSTANT) { PadParamBuilder builder_(_fbb); builder_.add_mode(mode); return builder_.Finish(); } flatbuffers::Offset CreatePadParam(flatbuffers::FlatBufferBuilder &_fbb, const PadParamT *_o, const flatbuffers::rehasher_function_t *_rehasher = nullptr); struct LayerNormT : public flatbuffers::NativeTable { typedef LayerNorm TableType; std::vector axis; float epsilon; std::vector gamma; std::vector beta; int32_t group; std::vector external; bool useRMSNorm; LayerNormT() : epsilon(0.0f), group(1), useRMSNorm(false) { } }; struct LayerNorm FLATBUFFERS_FINAL_CLASS : private flatbuffers::Table { typedef LayerNormT NativeTableType; static const flatbuffers::TypeTable *MiniReflectTypeTable() { return LayerNormTypeTable(); } const flatbuffers::Vector *axis() const { return GetPointer *>(4); } float epsilon() const { return GetField(6, 0.0f); } const flatbuffers::Vector *gamma() const { return GetPointer *>(8); } const flatbuffers::Vector *beta() const { return GetPointer *>(10); } int32_t group() const { return GetField(12, 1); } const flatbuffers::Vector *external() const { return GetPointer *>(14); } bool useRMSNorm() const { return GetField(16, 0) != 0; } bool Verify(flatbuffers::Verifier &verifier) const { return VerifyTableStart(verifier) && VerifyOffset(verifier, 4) && verifier.VerifyVector(axis()) && VerifyField(verifier, 6) && VerifyOffset(verifier, 8) && verifier.VerifyVector(gamma()) && VerifyOffset(verifier, 10) && verifier.VerifyVector(beta()) && VerifyField(verifier, 12) && VerifyOffset(verifier, 14) && verifier.VerifyVector(external()) && VerifyField(verifier, 16) && verifier.EndTable(); } LayerNormT *UnPack(const flatbuffers::resolver_function_t *_resolver = nullptr) const; void UnPackTo(LayerNormT *_o, const flatbuffers::resolver_function_t *_resolver = nullptr) const; static flatbuffers::Offset Pack(flatbuffers::FlatBufferBuilder &_fbb, const LayerNormT* _o, const flatbuffers::rehasher_function_t *_rehasher = nullptr); }; struct LayerNormBuilder { flatbuffers::FlatBufferBuilder &fbb_; flatbuffers::uoffset_t start_; void add_axis(flatbuffers::Offset> axis) { fbb_.AddOffset(4, axis); } void add_epsilon(float epsilon) { fbb_.AddElement(6, epsilon, 0.0f); } void add_gamma(flatbuffers::Offset> gamma) { fbb_.AddOffset(8, gamma); } void add_beta(flatbuffers::Offset> beta) { fbb_.AddOffset(10, beta); } void add_group(int32_t group) { fbb_.AddElement(12, group, 1); } void add_external(flatbuffers::Offset> external) { fbb_.AddOffset(14, external); } void add_useRMSNorm(bool useRMSNorm) { fbb_.AddElement(16, static_cast(useRMSNorm), 0); } explicit LayerNormBuilder(flatbuffers::FlatBufferBuilder &_fbb) : fbb_(_fbb) { start_ = fbb_.StartTable(); } LayerNormBuilder &operator=(const LayerNormBuilder &); flatbuffers::Offset Finish() { const auto end = fbb_.EndTable(start_); auto o = flatbuffers::Offset(end); return o; } }; inline flatbuffers::Offset CreateLayerNorm( flatbuffers::FlatBufferBuilder &_fbb, flatbuffers::Offset> axis = 0, float epsilon = 0.0f, flatbuffers::Offset> gamma = 0, flatbuffers::Offset> beta = 0, int32_t group = 1, flatbuffers::Offset> external = 0, bool useRMSNorm = false) { LayerNormBuilder builder_(_fbb); builder_.add_external(external); builder_.add_group(group); builder_.add_beta(beta); builder_.add_gamma(gamma); builder_.add_epsilon(epsilon); builder_.add_axis(axis); builder_.add_useRMSNorm(useRMSNorm); return builder_.Finish(); } flatbuffers::Offset CreateLayerNorm(flatbuffers::FlatBufferBuilder &_fbb, const LayerNormT *_o, const flatbuffers::rehasher_function_t *_rehasher = nullptr); struct GroupNormT : public flatbuffers::NativeTable { typedef GroupNorm TableType; int32_t axis; float epsilon; std::vector gamma; std::vector beta; int32_t group; int32_t bSwish; std::vector external; GroupNormT() : axis(0), epsilon(0.0f), group(1), bSwish(0) { } }; struct GroupNorm FLATBUFFERS_FINAL_CLASS : private flatbuffers::Table { typedef GroupNormT NativeTableType; static const flatbuffers::TypeTable *MiniReflectTypeTable() { return GroupNormTypeTable(); } int32_t axis() const { return GetField(4, 0); } float epsilon() const { return GetField(6, 0.0f); } const flatbuffers::Vector *gamma() const { return GetPointer *>(8); } const flatbuffers::Vector *beta() const { return GetPointer *>(10); } int32_t group() const { return GetField(12, 1); } int32_t bSwish() const { return GetField(14, 0); } const flatbuffers::Vector *external() const { return GetPointer *>(16); } bool Verify(flatbuffers::Verifier &verifier) const { return VerifyTableStart(verifier) && VerifyField(verifier, 4) && VerifyField(verifier, 6) && VerifyOffset(verifier, 8) && verifier.VerifyVector(gamma()) && VerifyOffset(verifier, 10) && verifier.VerifyVector(beta()) && VerifyField(verifier, 12) && VerifyField(verifier, 14) && VerifyOffset(verifier, 16) && verifier.VerifyVector(external()) && verifier.EndTable(); } GroupNormT *UnPack(const flatbuffers::resolver_function_t *_resolver = nullptr) const; void UnPackTo(GroupNormT *_o, const flatbuffers::resolver_function_t *_resolver = nullptr) const; static flatbuffers::Offset Pack(flatbuffers::FlatBufferBuilder &_fbb, const GroupNormT* _o, const flatbuffers::rehasher_function_t *_rehasher = nullptr); }; struct GroupNormBuilder { flatbuffers::FlatBufferBuilder &fbb_; flatbuffers::uoffset_t start_; void add_axis(int32_t axis) { fbb_.AddElement(4, axis, 0); } void add_epsilon(float epsilon) { fbb_.AddElement(6, epsilon, 0.0f); } void add_gamma(flatbuffers::Offset> gamma) { fbb_.AddOffset(8, gamma); } void add_beta(flatbuffers::Offset> beta) { fbb_.AddOffset(10, beta); } void add_group(int32_t group) { fbb_.AddElement(12, group, 1); } void add_bSwish(int32_t bSwish) { fbb_.AddElement(14, bSwish, 0); } void add_external(flatbuffers::Offset> external) { fbb_.AddOffset(16, external); } explicit GroupNormBuilder(flatbuffers::FlatBufferBuilder &_fbb) : fbb_(_fbb) { start_ = fbb_.StartTable(); } GroupNormBuilder &operator=(const GroupNormBuilder &); flatbuffers::Offset Finish() { const auto end = fbb_.EndTable(start_); auto o = flatbuffers::Offset(end); return o; } }; inline flatbuffers::Offset CreateGroupNorm( flatbuffers::FlatBufferBuilder &_fbb, int32_t axis = 0, float epsilon = 0.0f, flatbuffers::Offset> gamma = 0, flatbuffers::Offset> beta = 0, int32_t group = 1, int32_t bSwish = 0, flatbuffers::Offset> external = 0) { GroupNormBuilder builder_(_fbb); builder_.add_external(external); builder_.add_bSwish(bSwish); builder_.add_group(group); builder_.add_beta(beta); builder_.add_gamma(gamma); builder_.add_epsilon(epsilon); builder_.add_axis(axis); return builder_.Finish(); } flatbuffers::Offset CreateGroupNorm(flatbuffers::FlatBufferBuilder &_fbb, const GroupNormT *_o, const flatbuffers::rehasher_function_t *_rehasher = nullptr); struct RandomUniformT : public flatbuffers::NativeTable { typedef RandomUniform TableType; int32_t seed; int32_t seed2; DataType type; float low; float high; RandomUniformT() : seed(0), seed2(0), type(DataType_DT_FLOAT), low(0.0f), high(1.0f) { } }; struct RandomUniform FLATBUFFERS_FINAL_CLASS : private flatbuffers::Table { typedef RandomUniformT NativeTableType; static const flatbuffers::TypeTable *MiniReflectTypeTable() { return RandomUniformTypeTable(); } int32_t seed() const { return GetField(4, 0); } int32_t seed2() const { return GetField(6, 0); } DataType type() const { return static_cast(GetField(8, 1)); } float low() const { return GetField(10, 0.0f); } float high() const { return GetField(12, 1.0f); } bool Verify(flatbuffers::Verifier &verifier) const { return VerifyTableStart(verifier) && VerifyField(verifier, 4) && VerifyField(verifier, 6) && VerifyField(verifier, 8) && VerifyField(verifier, 10) && VerifyField(verifier, 12) && verifier.EndTable(); } RandomUniformT *UnPack(const flatbuffers::resolver_function_t *_resolver = nullptr) const; void UnPackTo(RandomUniformT *_o, const flatbuffers::resolver_function_t *_resolver = nullptr) const; static flatbuffers::Offset Pack(flatbuffers::FlatBufferBuilder &_fbb, const RandomUniformT* _o, const flatbuffers::rehasher_function_t *_rehasher = nullptr); }; struct RandomUniformBuilder { flatbuffers::FlatBufferBuilder &fbb_; flatbuffers::uoffset_t start_; void add_seed(int32_t seed) { fbb_.AddElement(4, seed, 0); } void add_seed2(int32_t seed2) { fbb_.AddElement(6, seed2, 0); } void add_type(DataType type) { fbb_.AddElement(8, static_cast(type), 1); } void add_low(float low) { fbb_.AddElement(10, low, 0.0f); } void add_high(float high) { fbb_.AddElement(12, high, 1.0f); } explicit RandomUniformBuilder(flatbuffers::FlatBufferBuilder &_fbb) : fbb_(_fbb) { start_ = fbb_.StartTable(); } RandomUniformBuilder &operator=(const RandomUniformBuilder &); flatbuffers::Offset Finish() { const auto end = fbb_.EndTable(start_); auto o = flatbuffers::Offset(end); return o; } }; inline flatbuffers::Offset CreateRandomUniform( flatbuffers::FlatBufferBuilder &_fbb, int32_t seed = 0, int32_t seed2 = 0, DataType type = DataType_DT_FLOAT, float low = 0.0f, float high = 1.0f) { RandomUniformBuilder builder_(_fbb); builder_.add_high(high); builder_.add_low(low); builder_.add_type(type); builder_.add_seed2(seed2); builder_.add_seed(seed); return builder_.Finish(); } flatbuffers::Offset CreateRandomUniform(flatbuffers::FlatBufferBuilder &_fbb, const RandomUniformT *_o, const flatbuffers::rehasher_function_t *_rehasher = nullptr); struct TensorArrayT : public flatbuffers::NativeTable { typedef TensorArray TableType; bool dynamic_size; bool identical_element_shapes; std::vector element_shape; DataType T; int32_t axis; bool keepdims; bool new_axis; TensorArrayT() : dynamic_size(false), identical_element_shapes(false), T(DataType_DT_FLOAT), axis(0), keepdims(true), new_axis(false) { } }; struct TensorArray FLATBUFFERS_FINAL_CLASS : private flatbuffers::Table { typedef TensorArrayT NativeTableType; static const flatbuffers::TypeTable *MiniReflectTypeTable() { return TensorArrayTypeTable(); } bool dynamic_size() const { return GetField(4, 0) != 0; } bool identical_element_shapes() const { return GetField(6, 0) != 0; } const flatbuffers::Vector *element_shape() const { return GetPointer *>(8); } DataType T() const { return static_cast(GetField(10, 1)); } int32_t axis() const { return GetField(12, 0); } bool keepdims() const { return GetField(14, 1) != 0; } bool new_axis() const { return GetField(16, 0) != 0; } bool Verify(flatbuffers::Verifier &verifier) const { return VerifyTableStart(verifier) && VerifyField(verifier, 4) && VerifyField(verifier, 6) && VerifyOffset(verifier, 8) && verifier.VerifyVector(element_shape()) && VerifyField(verifier, 10) && VerifyField(verifier, 12) && VerifyField(verifier, 14) && VerifyField(verifier, 16) && verifier.EndTable(); } TensorArrayT *UnPack(const flatbuffers::resolver_function_t *_resolver = nullptr) const; void UnPackTo(TensorArrayT *_o, const flatbuffers::resolver_function_t *_resolver = nullptr) const; static flatbuffers::Offset Pack(flatbuffers::FlatBufferBuilder &_fbb, const TensorArrayT* _o, const flatbuffers::rehasher_function_t *_rehasher = nullptr); }; struct TensorArrayBuilder { flatbuffers::FlatBufferBuilder &fbb_; flatbuffers::uoffset_t start_; void add_dynamic_size(bool dynamic_size) { fbb_.AddElement(4, static_cast(dynamic_size), 0); } void add_identical_element_shapes(bool identical_element_shapes) { fbb_.AddElement(6, static_cast(identical_element_shapes), 0); } void add_element_shape(flatbuffers::Offset> element_shape) { fbb_.AddOffset(8, element_shape); } void add_T(DataType T) { fbb_.AddElement(10, static_cast(T), 1); } void add_axis(int32_t axis) { fbb_.AddElement(12, axis, 0); } void add_keepdims(bool keepdims) { fbb_.AddElement(14, static_cast(keepdims), 1); } void add_new_axis(bool new_axis) { fbb_.AddElement(16, static_cast(new_axis), 0); } explicit TensorArrayBuilder(flatbuffers::FlatBufferBuilder &_fbb) : fbb_(_fbb) { start_ = fbb_.StartTable(); } TensorArrayBuilder &operator=(const TensorArrayBuilder &); flatbuffers::Offset Finish() { const auto end = fbb_.EndTable(start_); auto o = flatbuffers::Offset(end); return o; } }; inline flatbuffers::Offset CreateTensorArray( flatbuffers::FlatBufferBuilder &_fbb, bool dynamic_size = false, bool identical_element_shapes = false, flatbuffers::Offset> element_shape = 0, DataType T = DataType_DT_FLOAT, int32_t axis = 0, bool keepdims = true, bool new_axis = false) { TensorArrayBuilder builder_(_fbb); builder_.add_axis(axis); builder_.add_T(T); builder_.add_element_shape(element_shape); builder_.add_new_axis(new_axis); builder_.add_keepdims(keepdims); builder_.add_identical_element_shapes(identical_element_shapes); builder_.add_dynamic_size(dynamic_size); return builder_.Finish(); } flatbuffers::Offset CreateTensorArray(flatbuffers::FlatBufferBuilder &_fbb, const TensorArrayT *_o, const flatbuffers::rehasher_function_t *_rehasher = nullptr); struct LSTMBlockCellT : public flatbuffers::NativeTable { typedef LSTMBlockCell TableType; float cell_clip; float forget_bias; bool use_peephole; LSTMBlockCellT() : cell_clip(3.0f), forget_bias(1.0f), use_peephole(false) { } }; struct LSTMBlockCell FLATBUFFERS_FINAL_CLASS : private flatbuffers::Table { typedef LSTMBlockCellT NativeTableType; static const flatbuffers::TypeTable *MiniReflectTypeTable() { return LSTMBlockCellTypeTable(); } float cell_clip() const { return GetField(4, 3.0f); } float forget_bias() const { return GetField(6, 1.0f); } bool use_peephole() const { return GetField(8, 0) != 0; } bool Verify(flatbuffers::Verifier &verifier) const { return VerifyTableStart(verifier) && VerifyField(verifier, 4) && VerifyField(verifier, 6) && VerifyField(verifier, 8) && verifier.EndTable(); } LSTMBlockCellT *UnPack(const flatbuffers::resolver_function_t *_resolver = nullptr) const; void UnPackTo(LSTMBlockCellT *_o, const flatbuffers::resolver_function_t *_resolver = nullptr) const; static flatbuffers::Offset Pack(flatbuffers::FlatBufferBuilder &_fbb, const LSTMBlockCellT* _o, const flatbuffers::rehasher_function_t *_rehasher = nullptr); }; struct LSTMBlockCellBuilder { flatbuffers::FlatBufferBuilder &fbb_; flatbuffers::uoffset_t start_; void add_cell_clip(float cell_clip) { fbb_.AddElement(4, cell_clip, 3.0f); } void add_forget_bias(float forget_bias) { fbb_.AddElement(6, forget_bias, 1.0f); } void add_use_peephole(bool use_peephole) { fbb_.AddElement(8, static_cast(use_peephole), 0); } explicit LSTMBlockCellBuilder(flatbuffers::FlatBufferBuilder &_fbb) : fbb_(_fbb) { start_ = fbb_.StartTable(); } LSTMBlockCellBuilder &operator=(const LSTMBlockCellBuilder &); flatbuffers::Offset Finish() { const auto end = fbb_.EndTable(start_); auto o = flatbuffers::Offset(end); return o; } }; inline flatbuffers::Offset CreateLSTMBlockCell( flatbuffers::FlatBufferBuilder &_fbb, float cell_clip = 3.0f, float forget_bias = 1.0f, bool use_peephole = false) { LSTMBlockCellBuilder builder_(_fbb); builder_.add_forget_bias(forget_bias); builder_.add_cell_clip(cell_clip); builder_.add_use_peephole(use_peephole); return builder_.Finish(); } flatbuffers::Offset CreateLSTMBlockCell(flatbuffers::FlatBufferBuilder &_fbb, const LSTMBlockCellT *_o, const flatbuffers::rehasher_function_t *_rehasher = nullptr); inline BinaryOpT *BinaryOp::UnPack(const flatbuffers::resolver_function_t *_resolver) const { auto _o = new BinaryOpT(); UnPackTo(_o, _resolver); return _o; } inline void BinaryOp::UnPackTo(BinaryOpT *_o, const flatbuffers::resolver_function_t *_resolver) const { (void)_o; (void)_resolver; { auto _e = opType(); _o->opType = _e; }; { auto _e = T(); _o->T = _e; }; { auto _e = activationType(); _o->activationType = _e; }; } inline flatbuffers::Offset BinaryOp::Pack(flatbuffers::FlatBufferBuilder &_fbb, const BinaryOpT* _o, const flatbuffers::rehasher_function_t *_rehasher) { return CreateBinaryOp(_fbb, _o, _rehasher); } inline flatbuffers::Offset CreateBinaryOp(flatbuffers::FlatBufferBuilder &_fbb, const BinaryOpT *_o, const flatbuffers::rehasher_function_t *_rehasher) { (void)_rehasher; (void)_o; struct _VectorArgs { flatbuffers::FlatBufferBuilder *__fbb; const BinaryOpT* __o; const flatbuffers::rehasher_function_t *__rehasher; } _va = { &_fbb, _o, _rehasher}; (void)_va; auto _opType = _o->opType; auto _T = _o->T; auto _activationType = _o->activationType; return MNN::CreateBinaryOp( _fbb, _opType, _T, _activationType); } inline PackParamT *PackParam::UnPack(const flatbuffers::resolver_function_t *_resolver) const { auto _o = new PackParamT(); UnPackTo(_o, _resolver); return _o; } inline void PackParam::UnPackTo(PackParamT *_o, const flatbuffers::resolver_function_t *_resolver) const { (void)_o; (void)_resolver; { auto _e = dataType(); _o->dataType = _e; }; { auto _e = axis(); _o->axis = _e; }; } inline flatbuffers::Offset PackParam::Pack(flatbuffers::FlatBufferBuilder &_fbb, const PackParamT* _o, const flatbuffers::rehasher_function_t *_rehasher) { return CreatePackParam(_fbb, _o, _rehasher); } inline flatbuffers::Offset CreatePackParam(flatbuffers::FlatBufferBuilder &_fbb, const PackParamT *_o, const flatbuffers::rehasher_function_t *_rehasher) { (void)_rehasher; (void)_o; struct _VectorArgs { flatbuffers::FlatBufferBuilder *__fbb; const PackParamT* __o; const flatbuffers::rehasher_function_t *__rehasher; } _va = { &_fbb, _o, _rehasher}; (void)_va; auto _dataType = _o->dataType; auto _axis = _o->axis; return MNN::CreatePackParam( _fbb, _dataType, _axis); } inline StridedSliceParamT *StridedSliceParam::UnPack(const flatbuffers::resolver_function_t *_resolver) const { auto _o = new StridedSliceParamT(); UnPackTo(_o, _resolver); return _o; } inline void StridedSliceParam::UnPackTo(StridedSliceParamT *_o, const flatbuffers::resolver_function_t *_resolver) const { (void)_o; (void)_resolver; { auto _e = Index(); _o->Index = _e; }; { auto _e = T(); _o->T = _e; }; { auto _e = beginMask(); _o->beginMask = _e; }; { auto _e = endMask(); _o->endMask = _e; }; { auto _e = ellipsisMask(); _o->ellipsisMask = _e; }; { auto _e = newAxisMask(); _o->newAxisMask = _e; }; { auto _e = shrinkAxisMask(); _o->shrinkAxisMask = _e; }; { auto _e = fromType(); _o->fromType = _e; }; } inline flatbuffers::Offset StridedSliceParam::Pack(flatbuffers::FlatBufferBuilder &_fbb, const StridedSliceParamT* _o, const flatbuffers::rehasher_function_t *_rehasher) { return CreateStridedSliceParam(_fbb, _o, _rehasher); } inline flatbuffers::Offset CreateStridedSliceParam(flatbuffers::FlatBufferBuilder &_fbb, const StridedSliceParamT *_o, const flatbuffers::rehasher_function_t *_rehasher) { (void)_rehasher; (void)_o; struct _VectorArgs { flatbuffers::FlatBufferBuilder *__fbb; const StridedSliceParamT* __o; const flatbuffers::rehasher_function_t *__rehasher; } _va = { &_fbb, _o, _rehasher}; (void)_va; auto _Index = _o->Index; auto _T = _o->T; auto _beginMask = _o->beginMask; auto _endMask = _o->endMask; auto _ellipsisMask = _o->ellipsisMask; auto _newAxisMask = _o->newAxisMask; auto _shrinkAxisMask = _o->shrinkAxisMask; auto _fromType = _o->fromType; return MNN::CreateStridedSliceParam( _fbb, _Index, _T, _beginMask, _endMask, _ellipsisMask, _newAxisMask, _shrinkAxisMask, _fromType); } inline SqueezeParamT *SqueezeParam::UnPack(const flatbuffers::resolver_function_t *_resolver) const { auto _o = new SqueezeParamT(); UnPackTo(_o, _resolver); return _o; } inline void SqueezeParam::UnPackTo(SqueezeParamT *_o, const flatbuffers::resolver_function_t *_resolver) const { (void)_o; (void)_resolver; { auto _e = squeezeDims(); if (_e) { _o->squeezeDims.resize(_e->size()); for (flatbuffers::uoffset_t _i = 0; _i < _e->size(); _i++) { _o->squeezeDims[_i] = _e->Get(_i); } } }; } inline flatbuffers::Offset SqueezeParam::Pack(flatbuffers::FlatBufferBuilder &_fbb, const SqueezeParamT* _o, const flatbuffers::rehasher_function_t *_rehasher) { return CreateSqueezeParam(_fbb, _o, _rehasher); } inline flatbuffers::Offset CreateSqueezeParam(flatbuffers::FlatBufferBuilder &_fbb, const SqueezeParamT *_o, const flatbuffers::rehasher_function_t *_rehasher) { (void)_rehasher; (void)_o; struct _VectorArgs { flatbuffers::FlatBufferBuilder *__fbb; const SqueezeParamT* __o; const flatbuffers::rehasher_function_t *__rehasher; } _va = { &_fbb, _o, _rehasher}; (void)_va; auto _squeezeDims = _o->squeezeDims.size() ? _fbb.CreateVector(_o->squeezeDims) : 0; return MNN::CreateSqueezeParam( _fbb, _squeezeDims); } inline CastParamT *CastParam::UnPack(const flatbuffers::resolver_function_t *_resolver) const { auto _o = new CastParamT(); UnPackTo(_o, _resolver); return _o; } inline void CastParam::UnPackTo(CastParamT *_o, const flatbuffers::resolver_function_t *_resolver) const { (void)_o; (void)_resolver; { auto _e = srcT(); _o->srcT = _e; }; { auto _e = dstT(); _o->dstT = _e; }; } inline flatbuffers::Offset CastParam::Pack(flatbuffers::FlatBufferBuilder &_fbb, const CastParamT* _o, const flatbuffers::rehasher_function_t *_rehasher) { return CreateCastParam(_fbb, _o, _rehasher); } inline flatbuffers::Offset CreateCastParam(flatbuffers::FlatBufferBuilder &_fbb, const CastParamT *_o, const flatbuffers::rehasher_function_t *_rehasher) { (void)_rehasher; (void)_o; struct _VectorArgs { flatbuffers::FlatBufferBuilder *__fbb; const CastParamT* __o; const flatbuffers::rehasher_function_t *__rehasher; } _va = { &_fbb, _o, _rehasher}; (void)_va; auto _srcT = _o->srcT; auto _dstT = _o->dstT; return MNN::CreateCastParam( _fbb, _srcT, _dstT); } inline ReductionParamT *ReductionParam::UnPack(const flatbuffers::resolver_function_t *_resolver) const { auto _o = new ReductionParamT(); UnPackTo(_o, _resolver); return _o; } inline void ReductionParam::UnPackTo(ReductionParamT *_o, const flatbuffers::resolver_function_t *_resolver) const { (void)_o; (void)_resolver; { auto _e = operation(); _o->operation = _e; }; { auto _e = dim(); if (_e) { _o->dim.resize(_e->size()); for (flatbuffers::uoffset_t _i = 0; _i < _e->size(); _i++) { _o->dim[_i] = _e->Get(_i); } } }; { auto _e = coeff(); _o->coeff = _e; }; { auto _e = keepDims(); _o->keepDims = _e; }; { auto _e = dType(); _o->dType = _e; }; } inline flatbuffers::Offset ReductionParam::Pack(flatbuffers::FlatBufferBuilder &_fbb, const ReductionParamT* _o, const flatbuffers::rehasher_function_t *_rehasher) { return CreateReductionParam(_fbb, _o, _rehasher); } inline flatbuffers::Offset CreateReductionParam(flatbuffers::FlatBufferBuilder &_fbb, const ReductionParamT *_o, const flatbuffers::rehasher_function_t *_rehasher) { (void)_rehasher; (void)_o; struct _VectorArgs { flatbuffers::FlatBufferBuilder *__fbb; const ReductionParamT* __o; const flatbuffers::rehasher_function_t *__rehasher; } _va = { &_fbb, _o, _rehasher}; (void)_va; auto _operation = _o->operation; auto _dim = _o->dim.size() ? _fbb.CreateVector(_o->dim) : 0; auto _coeff = _o->coeff; auto _keepDims = _o->keepDims; auto _dType = _o->dType; return MNN::CreateReductionParam( _fbb, _operation, _dim, _coeff, _keepDims, _dType); } inline GatherT *Gather::UnPack(const flatbuffers::resolver_function_t *_resolver) const { auto _o = new GatherT(); UnPackTo(_o, _resolver); return _o; } inline void Gather::UnPackTo(GatherT *_o, const flatbuffers::resolver_function_t *_resolver) const { (void)_o; (void)_resolver; { auto _e = Tindices(); _o->Tindices = _e; }; { auto _e = Tparams(); _o->Tparams = _e; }; { auto _e = validateIndices(); _o->validateIndices = _e; }; { auto _e = axis(); _o->axis = _e; }; } inline flatbuffers::Offset Gather::Pack(flatbuffers::FlatBufferBuilder &_fbb, const GatherT* _o, const flatbuffers::rehasher_function_t *_rehasher) { return CreateGather(_fbb, _o, _rehasher); } inline flatbuffers::Offset CreateGather(flatbuffers::FlatBufferBuilder &_fbb, const GatherT *_o, const flatbuffers::rehasher_function_t *_rehasher) { (void)_rehasher; (void)_o; struct _VectorArgs { flatbuffers::FlatBufferBuilder *__fbb; const GatherT* __o; const flatbuffers::rehasher_function_t *__rehasher; } _va = { &_fbb, _o, _rehasher}; (void)_va; auto _Tindices = _o->Tindices; auto _Tparams = _o->Tparams; auto _validateIndices = _o->validateIndices; auto _axis = _o->axis; return MNN::CreateGather( _fbb, _Tindices, _Tparams, _validateIndices, _axis); } inline ExpandDimsT *ExpandDims::UnPack(const flatbuffers::resolver_function_t *_resolver) const { auto _o = new ExpandDimsT(); UnPackTo(_o, _resolver); return _o; } inline void ExpandDims::UnPackTo(ExpandDimsT *_o, const flatbuffers::resolver_function_t *_resolver) const { (void)_o; (void)_resolver; { auto _e = T(); _o->T = _e; }; { auto _e = Tdim(); _o->Tdim = _e; }; { auto _e = axis(); _o->axis = _e; }; } inline flatbuffers::Offset ExpandDims::Pack(flatbuffers::FlatBufferBuilder &_fbb, const ExpandDimsT* _o, const flatbuffers::rehasher_function_t *_rehasher) { return CreateExpandDims(_fbb, _o, _rehasher); } inline flatbuffers::Offset CreateExpandDims(flatbuffers::FlatBufferBuilder &_fbb, const ExpandDimsT *_o, const flatbuffers::rehasher_function_t *_rehasher) { (void)_rehasher; (void)_o; struct _VectorArgs { flatbuffers::FlatBufferBuilder *__fbb; const ExpandDimsT* __o; const flatbuffers::rehasher_function_t *__rehasher; } _va = { &_fbb, _o, _rehasher}; (void)_va; auto _T = _o->T; auto _Tdim = _o->Tdim; auto _axis = _o->axis; return MNN::CreateExpandDims( _fbb, _T, _Tdim, _axis); } inline SeluT *Selu::UnPack(const flatbuffers::resolver_function_t *_resolver) const { auto _o = new SeluT(); UnPackTo(_o, _resolver); return _o; } inline void Selu::UnPackTo(SeluT *_o, const flatbuffers::resolver_function_t *_resolver) const { (void)_o; (void)_resolver; { auto _e = scale(); _o->scale = _e; }; { auto _e = alpha(); _o->alpha = _e; }; } inline flatbuffers::Offset Selu::Pack(flatbuffers::FlatBufferBuilder &_fbb, const SeluT* _o, const flatbuffers::rehasher_function_t *_rehasher) { return CreateSelu(_fbb, _o, _rehasher); } inline flatbuffers::Offset CreateSelu(flatbuffers::FlatBufferBuilder &_fbb, const SeluT *_o, const flatbuffers::rehasher_function_t *_rehasher) { (void)_rehasher; (void)_o; struct _VectorArgs { flatbuffers::FlatBufferBuilder *__fbb; const SeluT* __o; const flatbuffers::rehasher_function_t *__rehasher; } _va = { &_fbb, _o, _rehasher}; (void)_va; auto _scale = _o->scale; auto _alpha = _o->alpha; return MNN::CreateSelu( _fbb, _scale, _alpha); } inline AsStringT *AsString::UnPack(const flatbuffers::resolver_function_t *_resolver) const { auto _o = new AsStringT(); UnPackTo(_o, _resolver); return _o; } inline void AsString::UnPackTo(AsStringT *_o, const flatbuffers::resolver_function_t *_resolver) const { (void)_o; (void)_resolver; { auto _e = T(); _o->T = _e; }; { auto _e = precision(); _o->precision = _e; }; { auto _e = scientific(); _o->scientific = _e; }; { auto _e = shortest(); _o->shortest = _e; }; { auto _e = width(); _o->width = _e; }; { auto _e = fillString(); if (_e) _o->fillString = _e->str(); }; } inline flatbuffers::Offset AsString::Pack(flatbuffers::FlatBufferBuilder &_fbb, const AsStringT* _o, const flatbuffers::rehasher_function_t *_rehasher) { return CreateAsString(_fbb, _o, _rehasher); } inline flatbuffers::Offset CreateAsString(flatbuffers::FlatBufferBuilder &_fbb, const AsStringT *_o, const flatbuffers::rehasher_function_t *_rehasher) { (void)_rehasher; (void)_o; struct _VectorArgs { flatbuffers::FlatBufferBuilder *__fbb; const AsStringT* __o; const flatbuffers::rehasher_function_t *__rehasher; } _va = { &_fbb, _o, _rehasher}; (void)_va; auto _T = _o->T; auto _precision = _o->precision; auto _scientific = _o->scientific; auto _shortest = _o->shortest; auto _width = _o->width; auto _fillString = _o->fillString.empty() ? 0 : _fbb.CreateString(_o->fillString); return MNN::CreateAsString( _fbb, _T, _precision, _scientific, _shortest, _width, _fillString); } inline ReduceJoinT *ReduceJoin::UnPack(const flatbuffers::resolver_function_t *_resolver) const { auto _o = new ReduceJoinT(); UnPackTo(_o, _resolver); return _o; } inline void ReduceJoin::UnPackTo(ReduceJoinT *_o, const flatbuffers::resolver_function_t *_resolver) const { (void)_o; (void)_resolver; { auto _e = keepDims(); _o->keepDims = _e; }; { auto _e = separator(); if (_e) _o->separator = _e->str(); }; } inline flatbuffers::Offset ReduceJoin::Pack(flatbuffers::FlatBufferBuilder &_fbb, const ReduceJoinT* _o, const flatbuffers::rehasher_function_t *_rehasher) { return CreateReduceJoin(_fbb, _o, _rehasher); } inline flatbuffers::Offset CreateReduceJoin(flatbuffers::FlatBufferBuilder &_fbb, const ReduceJoinT *_o, const flatbuffers::rehasher_function_t *_rehasher) { (void)_rehasher; (void)_o; struct _VectorArgs { flatbuffers::FlatBufferBuilder *__fbb; const ReduceJoinT* __o; const flatbuffers::rehasher_function_t *__rehasher; } _va = { &_fbb, _o, _rehasher}; (void)_va; auto _keepDims = _o->keepDims; auto _separator = _o->separator.empty() ? 0 : _fbb.CreateString(_o->separator); return MNN::CreateReduceJoin( _fbb, _keepDims, _separator); } inline UnaryOpT *UnaryOp::UnPack(const flatbuffers::resolver_function_t *_resolver) const { auto _o = new UnaryOpT(); UnPackTo(_o, _resolver); return _o; } inline void UnaryOp::UnPackTo(UnaryOpT *_o, const flatbuffers::resolver_function_t *_resolver) const { (void)_o; (void)_resolver; { auto _e = opType(); _o->opType = _e; }; { auto _e = T(); _o->T = _e; }; { auto _e = tableInt8(); if (_e) { _o->tableInt8.resize(_e->size()); for (flatbuffers::uoffset_t _i = 0; _i < _e->size(); _i++) { _o->tableInt8[_i] = _e->Get(_i); } } }; } inline flatbuffers::Offset UnaryOp::Pack(flatbuffers::FlatBufferBuilder &_fbb, const UnaryOpT* _o, const flatbuffers::rehasher_function_t *_rehasher) { return CreateUnaryOp(_fbb, _o, _rehasher); } inline flatbuffers::Offset CreateUnaryOp(flatbuffers::FlatBufferBuilder &_fbb, const UnaryOpT *_o, const flatbuffers::rehasher_function_t *_rehasher) { (void)_rehasher; (void)_o; struct _VectorArgs { flatbuffers::FlatBufferBuilder *__fbb; const UnaryOpT* __o; const flatbuffers::rehasher_function_t *__rehasher; } _va = { &_fbb, _o, _rehasher}; (void)_va; auto _opType = _o->opType; auto _T = _o->T; auto _tableInt8 = _o->tableInt8.size() ? _fbb.CreateVector(_o->tableInt8) : 0; return MNN::CreateUnaryOp( _fbb, _opType, _T, _tableInt8); } inline TopKV2T *TopKV2::UnPack(const flatbuffers::resolver_function_t *_resolver) const { auto _o = new TopKV2T(); UnPackTo(_o, _resolver); return _o; } inline void TopKV2::UnPackTo(TopKV2T *_o, const flatbuffers::resolver_function_t *_resolver) const { (void)_o; (void)_resolver; { auto _e = T(); _o->T = _e; }; { auto _e = sorted(); _o->sorted = _e; }; { auto _e = largest(); _o->largest = _e; }; } inline flatbuffers::Offset TopKV2::Pack(flatbuffers::FlatBufferBuilder &_fbb, const TopKV2T* _o, const flatbuffers::rehasher_function_t *_rehasher) { return CreateTopKV2(_fbb, _o, _rehasher); } inline flatbuffers::Offset CreateTopKV2(flatbuffers::FlatBufferBuilder &_fbb, const TopKV2T *_o, const flatbuffers::rehasher_function_t *_rehasher) { (void)_rehasher; (void)_o; struct _VectorArgs { flatbuffers::FlatBufferBuilder *__fbb; const TopKV2T* __o; const flatbuffers::rehasher_function_t *__rehasher; } _va = { &_fbb, _o, _rehasher}; (void)_va; auto _T = _o->T; auto _sorted = _o->sorted; auto _largest = _o->largest; return MNN::CreateTopKV2( _fbb, _T, _sorted, _largest); } inline CropAndResizeT *CropAndResize::UnPack(const flatbuffers::resolver_function_t *_resolver) const { auto _o = new CropAndResizeT(); UnPackTo(_o, _resolver); return _o; } inline void CropAndResize::UnPackTo(CropAndResizeT *_o, const flatbuffers::resolver_function_t *_resolver) const { (void)_o; (void)_resolver; { auto _e = extrapolationValue(); _o->extrapolationValue = _e; }; { auto _e = method(); _o->method = _e; }; } inline flatbuffers::Offset CropAndResize::Pack(flatbuffers::FlatBufferBuilder &_fbb, const CropAndResizeT* _o, const flatbuffers::rehasher_function_t *_rehasher) { return CreateCropAndResize(_fbb, _o, _rehasher); } inline flatbuffers::Offset CreateCropAndResize(flatbuffers::FlatBufferBuilder &_fbb, const CropAndResizeT *_o, const flatbuffers::rehasher_function_t *_rehasher) { (void)_rehasher; (void)_o; struct _VectorArgs { flatbuffers::FlatBufferBuilder *__fbb; const CropAndResizeT* __o; const flatbuffers::rehasher_function_t *__rehasher; } _va = { &_fbb, _o, _rehasher}; (void)_va; auto _extrapolationValue = _o->extrapolationValue; auto _method = _o->method; return MNN::CreateCropAndResize( _fbb, _extrapolationValue, _method); } inline FillT *Fill::UnPack(const flatbuffers::resolver_function_t *_resolver) const { auto _o = new FillT(); UnPackTo(_o, _resolver); return _o; } inline void Fill::UnPackTo(FillT *_o, const flatbuffers::resolver_function_t *_resolver) const { (void)_o; (void)_resolver; } inline flatbuffers::Offset Fill::Pack(flatbuffers::FlatBufferBuilder &_fbb, const FillT* _o, const flatbuffers::rehasher_function_t *_rehasher) { return CreateFill(_fbb, _o, _rehasher); } inline flatbuffers::Offset CreateFill(flatbuffers::FlatBufferBuilder &_fbb, const FillT *_o, const flatbuffers::rehasher_function_t *_rehasher) { (void)_rehasher; (void)_o; struct _VectorArgs { flatbuffers::FlatBufferBuilder *__fbb; const FillT* __o; const flatbuffers::rehasher_function_t *__rehasher; } _va = { &_fbb, _o, _rehasher}; (void)_va; return MNN::CreateFill( _fbb); } inline GatherV2T *GatherV2::UnPack(const flatbuffers::resolver_function_t *_resolver) const { auto _o = new GatherV2T(); UnPackTo(_o, _resolver); return _o; } inline void GatherV2::UnPackTo(GatherV2T *_o, const flatbuffers::resolver_function_t *_resolver) const { (void)_o; (void)_resolver; { auto _e = Taxis(); _o->Taxis = _e; }; { auto _e = Tindices(); _o->Tindices = _e; }; { auto _e = Tparams(); _o->Tparams = _e; }; } inline flatbuffers::Offset GatherV2::Pack(flatbuffers::FlatBufferBuilder &_fbb, const GatherV2T* _o, const flatbuffers::rehasher_function_t *_rehasher) { return CreateGatherV2(_fbb, _o, _rehasher); } inline flatbuffers::Offset CreateGatherV2(flatbuffers::FlatBufferBuilder &_fbb, const GatherV2T *_o, const flatbuffers::rehasher_function_t *_rehasher) { (void)_rehasher; (void)_o; struct _VectorArgs { flatbuffers::FlatBufferBuilder *__fbb; const GatherV2T* __o; const flatbuffers::rehasher_function_t *__rehasher; } _va = { &_fbb, _o, _rehasher}; (void)_va; auto _Taxis = _o->Taxis; auto _Tindices = _o->Tindices; auto _Tparams = _o->Tparams; return MNN::CreateGatherV2( _fbb, _Taxis, _Tindices, _Tparams); } inline NonMaxSuppressionV2T *NonMaxSuppressionV2::UnPack(const flatbuffers::resolver_function_t *_resolver) const { auto _o = new NonMaxSuppressionV2T(); UnPackTo(_o, _resolver); return _o; } inline void NonMaxSuppressionV2::UnPackTo(NonMaxSuppressionV2T *_o, const flatbuffers::resolver_function_t *_resolver) const { (void)_o; (void)_resolver; } inline flatbuffers::Offset NonMaxSuppressionV2::Pack(flatbuffers::FlatBufferBuilder &_fbb, const NonMaxSuppressionV2T* _o, const flatbuffers::rehasher_function_t *_rehasher) { return CreateNonMaxSuppressionV2(_fbb, _o, _rehasher); } inline flatbuffers::Offset CreateNonMaxSuppressionV2(flatbuffers::FlatBufferBuilder &_fbb, const NonMaxSuppressionV2T *_o, const flatbuffers::rehasher_function_t *_rehasher) { (void)_rehasher; (void)_o; struct _VectorArgs { flatbuffers::FlatBufferBuilder *__fbb; const NonMaxSuppressionV2T* __o; const flatbuffers::rehasher_function_t *__rehasher; } _va = { &_fbb, _o, _rehasher}; (void)_va; return MNN::CreateNonMaxSuppressionV2( _fbb); } inline RangeT *Range::UnPack(const flatbuffers::resolver_function_t *_resolver) const { auto _o = new RangeT(); UnPackTo(_o, _resolver); return _o; } inline void Range::UnPackTo(RangeT *_o, const flatbuffers::resolver_function_t *_resolver) const { (void)_o; (void)_resolver; { auto _e = Tidx(); _o->Tidx = _e; }; } inline flatbuffers::Offset Range::Pack(flatbuffers::FlatBufferBuilder &_fbb, const RangeT* _o, const flatbuffers::rehasher_function_t *_rehasher) { return CreateRange(_fbb, _o, _rehasher); } inline flatbuffers::Offset CreateRange(flatbuffers::FlatBufferBuilder &_fbb, const RangeT *_o, const flatbuffers::rehasher_function_t *_rehasher) { (void)_rehasher; (void)_o; struct _VectorArgs { flatbuffers::FlatBufferBuilder *__fbb; const RangeT* __o; const flatbuffers::rehasher_function_t *__rehasher; } _va = { &_fbb, _o, _rehasher}; (void)_va; auto _Tidx = _o->Tidx; return MNN::CreateRange( _fbb, _Tidx); } inline RankT *Rank::UnPack(const flatbuffers::resolver_function_t *_resolver) const { auto _o = new RankT(); UnPackTo(_o, _resolver); return _o; } inline void Rank::UnPackTo(RankT *_o, const flatbuffers::resolver_function_t *_resolver) const { (void)_o; (void)_resolver; } inline flatbuffers::Offset Rank::Pack(flatbuffers::FlatBufferBuilder &_fbb, const RankT* _o, const flatbuffers::rehasher_function_t *_rehasher) { return CreateRank(_fbb, _o, _rehasher); } inline flatbuffers::Offset CreateRank(flatbuffers::FlatBufferBuilder &_fbb, const RankT *_o, const flatbuffers::rehasher_function_t *_rehasher) { (void)_rehasher; (void)_o; struct _VectorArgs { flatbuffers::FlatBufferBuilder *__fbb; const RankT* __o; const flatbuffers::rehasher_function_t *__rehasher; } _va = { &_fbb, _o, _rehasher}; (void)_va; return MNN::CreateRank( _fbb); } inline SizeT *Size::UnPack(const flatbuffers::resolver_function_t *_resolver) const { auto _o = new SizeT(); UnPackTo(_o, _resolver); return _o; } inline void Size::UnPackTo(SizeT *_o, const flatbuffers::resolver_function_t *_resolver) const { (void)_o; (void)_resolver; { auto _e = outputDataType(); _o->outputDataType = _e; }; } inline flatbuffers::Offset Size::Pack(flatbuffers::FlatBufferBuilder &_fbb, const SizeT* _o, const flatbuffers::rehasher_function_t *_rehasher) { return CreateSize(_fbb, _o, _rehasher); } inline flatbuffers::Offset CreateSize(flatbuffers::FlatBufferBuilder &_fbb, const SizeT *_o, const flatbuffers::rehasher_function_t *_rehasher) { (void)_rehasher; (void)_o; struct _VectorArgs { flatbuffers::FlatBufferBuilder *__fbb; const SizeT* __o; const flatbuffers::rehasher_function_t *__rehasher; } _va = { &_fbb, _o, _rehasher}; (void)_va; auto _outputDataType = _o->outputDataType; return MNN::CreateSize( _fbb, _outputDataType); } inline TransposeT *Transpose::UnPack(const flatbuffers::resolver_function_t *_resolver) const { auto _o = new TransposeT(); UnPackTo(_o, _resolver); return _o; } inline void Transpose::UnPackTo(TransposeT *_o, const flatbuffers::resolver_function_t *_resolver) const { (void)_o; (void)_resolver; { auto _e = Tperm(); _o->Tperm = _e; }; } inline flatbuffers::Offset Transpose::Pack(flatbuffers::FlatBufferBuilder &_fbb, const TransposeT* _o, const flatbuffers::rehasher_function_t *_rehasher) { return CreateTranspose(_fbb, _o, _rehasher); } inline flatbuffers::Offset CreateTranspose(flatbuffers::FlatBufferBuilder &_fbb, const TransposeT *_o, const flatbuffers::rehasher_function_t *_rehasher) { (void)_rehasher; (void)_o; struct _VectorArgs { flatbuffers::FlatBufferBuilder *__fbb; const TransposeT* __o; const flatbuffers::rehasher_function_t *__rehasher; } _va = { &_fbb, _o, _rehasher}; (void)_va; auto _Tperm = _o->Tperm; return MNN::CreateTranspose( _fbb, _Tperm); } inline SliceTfT *SliceTf::UnPack(const flatbuffers::resolver_function_t *_resolver) const { auto _o = new SliceTfT(); UnPackTo(_o, _resolver); return _o; } inline void SliceTf::UnPackTo(SliceTfT *_o, const flatbuffers::resolver_function_t *_resolver) const { (void)_o; (void)_resolver; { auto _e = T(); _o->T = _e; }; } inline flatbuffers::Offset SliceTf::Pack(flatbuffers::FlatBufferBuilder &_fbb, const SliceTfT* _o, const flatbuffers::rehasher_function_t *_rehasher) { return CreateSliceTf(_fbb, _o, _rehasher); } inline flatbuffers::Offset CreateSliceTf(flatbuffers::FlatBufferBuilder &_fbb, const SliceTfT *_o, const flatbuffers::rehasher_function_t *_rehasher) { (void)_rehasher; (void)_o; struct _VectorArgs { flatbuffers::FlatBufferBuilder *__fbb; const SliceTfT* __o; const flatbuffers::rehasher_function_t *__rehasher; } _va = { &_fbb, _o, _rehasher}; (void)_va; auto _T = _o->T; return MNN::CreateSliceTf( _fbb, _T); } inline QuantizeMaxMinT *QuantizeMaxMin::UnPack(const flatbuffers::resolver_function_t *_resolver) const { auto _o = new QuantizeMaxMinT(); UnPackTo(_o, _resolver); return _o; } inline void QuantizeMaxMin::UnPackTo(QuantizeMaxMinT *_o, const flatbuffers::resolver_function_t *_resolver) const { (void)_o; (void)_resolver; { auto _e = T(); _o->T = _e; }; } inline flatbuffers::Offset QuantizeMaxMin::Pack(flatbuffers::FlatBufferBuilder &_fbb, const QuantizeMaxMinT* _o, const flatbuffers::rehasher_function_t *_rehasher) { return CreateQuantizeMaxMin(_fbb, _o, _rehasher); } inline flatbuffers::Offset CreateQuantizeMaxMin(flatbuffers::FlatBufferBuilder &_fbb, const QuantizeMaxMinT *_o, const flatbuffers::rehasher_function_t *_rehasher) { (void)_rehasher; (void)_o; struct _VectorArgs { flatbuffers::FlatBufferBuilder *__fbb; const QuantizeMaxMinT* __o; const flatbuffers::rehasher_function_t *__rehasher; } _va = { &_fbb, _o, _rehasher}; (void)_va; auto _T = _o->T; return MNN::CreateQuantizeMaxMin( _fbb, _T); } inline CropT *Crop::UnPack(const flatbuffers::resolver_function_t *_resolver) const { auto _o = new CropT(); UnPackTo(_o, _resolver); return _o; } inline void Crop::UnPackTo(CropT *_o, const flatbuffers::resolver_function_t *_resolver) const { (void)_o; (void)_resolver; { auto _e = axis(); _o->axis = _e; }; { auto _e = offset(); if (_e) { _o->offset.resize(_e->size()); for (flatbuffers::uoffset_t _i = 0; _i < _e->size(); _i++) { _o->offset[_i] = _e->Get(_i); } } }; } inline flatbuffers::Offset Crop::Pack(flatbuffers::FlatBufferBuilder &_fbb, const CropT* _o, const flatbuffers::rehasher_function_t *_rehasher) { return CreateCrop(_fbb, _o, _rehasher); } inline flatbuffers::Offset CreateCrop(flatbuffers::FlatBufferBuilder &_fbb, const CropT *_o, const flatbuffers::rehasher_function_t *_rehasher) { (void)_rehasher; (void)_o; struct _VectorArgs { flatbuffers::FlatBufferBuilder *__fbb; const CropT* __o; const flatbuffers::rehasher_function_t *__rehasher; } _va = { &_fbb, _o, _rehasher}; (void)_va; auto _axis = _o->axis; auto _offset = _o->offset.size() ? _fbb.CreateVector(_o->offset) : 0; return MNN::CreateCrop( _fbb, _axis, _offset); } inline SpaceBatchT *SpaceBatch::UnPack(const flatbuffers::resolver_function_t *_resolver) const { auto _o = new SpaceBatchT(); UnPackTo(_o, _resolver); return _o; } inline void SpaceBatch::UnPackTo(SpaceBatchT *_o, const flatbuffers::resolver_function_t *_resolver) const { (void)_o; (void)_resolver; { auto _e = blockShape(); if (_e) _o->blockShape = std::unique_ptr(_e->UnPack(_resolver)); }; { auto _e = padding(); if (_e) _o->padding = std::unique_ptr(_e->UnPack(_resolver)); }; } inline flatbuffers::Offset SpaceBatch::Pack(flatbuffers::FlatBufferBuilder &_fbb, const SpaceBatchT* _o, const flatbuffers::rehasher_function_t *_rehasher) { return CreateSpaceBatch(_fbb, _o, _rehasher); } inline flatbuffers::Offset CreateSpaceBatch(flatbuffers::FlatBufferBuilder &_fbb, const SpaceBatchT *_o, const flatbuffers::rehasher_function_t *_rehasher) { (void)_rehasher; (void)_o; struct _VectorArgs { flatbuffers::FlatBufferBuilder *__fbb; const SpaceBatchT* __o; const flatbuffers::rehasher_function_t *__rehasher; } _va = { &_fbb, _o, _rehasher}; (void)_va; auto _blockShape = _o->blockShape ? CreateBlob(_fbb, _o->blockShape.get(), _rehasher) : 0; auto _padding = _o->padding ? CreateBlob(_fbb, _o->padding.get(), _rehasher) : 0; return MNN::CreateSpaceBatch( _fbb, _blockShape, _padding); } inline MatMulT *MatMul::UnPack(const flatbuffers::resolver_function_t *_resolver) const { auto _o = new MatMulT(); UnPackTo(_o, _resolver); return _o; } inline void MatMul::UnPackTo(MatMulT *_o, const flatbuffers::resolver_function_t *_resolver) const { (void)_o; (void)_resolver; { auto _e = T(); _o->T = _e; }; { auto _e = transposeA(); _o->transposeA = _e; }; { auto _e = transposeB(); _o->transposeB = _e; }; { auto _e = weight(); if (_e) { _o->weight.resize(_e->size()); for (flatbuffers::uoffset_t _i = 0; _i < _e->size(); _i++) { _o->weight[_i] = _e->Get(_i); } } }; { auto _e = bias(); if (_e) { _o->bias.resize(_e->size()); for (flatbuffers::uoffset_t _i = 0; _i < _e->size(); _i++) { _o->bias[_i] = _e->Get(_i); } } }; } inline flatbuffers::Offset MatMul::Pack(flatbuffers::FlatBufferBuilder &_fbb, const MatMulT* _o, const flatbuffers::rehasher_function_t *_rehasher) { return CreateMatMul(_fbb, _o, _rehasher); } inline flatbuffers::Offset CreateMatMul(flatbuffers::FlatBufferBuilder &_fbb, const MatMulT *_o, const flatbuffers::rehasher_function_t *_rehasher) { (void)_rehasher; (void)_o; struct _VectorArgs { flatbuffers::FlatBufferBuilder *__fbb; const MatMulT* __o; const flatbuffers::rehasher_function_t *__rehasher; } _va = { &_fbb, _o, _rehasher}; (void)_va; auto _T = _o->T; auto _transposeA = _o->transposeA; auto _transposeB = _o->transposeB; auto _weight = _o->weight.size() ? _fbb.CreateVector(_o->weight) : 0; auto _bias = _o->bias.size() ? _fbb.CreateVector(_o->bias) : 0; return MNN::CreateMatMul( _fbb, _T, _transposeA, _transposeB, _weight, _bias); } inline MomentsParamT *MomentsParam::UnPack(const flatbuffers::resolver_function_t *_resolver) const { auto _o = new MomentsParamT(); UnPackTo(_o, _resolver); return _o; } inline void MomentsParam::UnPackTo(MomentsParamT *_o, const flatbuffers::resolver_function_t *_resolver) const { (void)_o; (void)_resolver; { auto _e = dim(); if (_e) { _o->dim.resize(_e->size()); for (flatbuffers::uoffset_t _i = 0; _i < _e->size(); _i++) { _o->dim[_i] = _e->Get(_i); } } }; { auto _e = keepDims(); _o->keepDims = _e; }; { auto _e = dType(); _o->dType = _e; }; } inline flatbuffers::Offset MomentsParam::Pack(flatbuffers::FlatBufferBuilder &_fbb, const MomentsParamT* _o, const flatbuffers::rehasher_function_t *_rehasher) { return CreateMomentsParam(_fbb, _o, _rehasher); } inline flatbuffers::Offset CreateMomentsParam(flatbuffers::FlatBufferBuilder &_fbb, const MomentsParamT *_o, const flatbuffers::rehasher_function_t *_rehasher) { (void)_rehasher; (void)_o; struct _VectorArgs { flatbuffers::FlatBufferBuilder *__fbb; const MomentsParamT* __o; const flatbuffers::rehasher_function_t *__rehasher; } _va = { &_fbb, _o, _rehasher}; (void)_va; auto _dim = _o->dim.size() ? _fbb.CreateVector(_o->dim) : 0; auto _keepDims = _o->keepDims; auto _dType = _o->dType; return MNN::CreateMomentsParam( _fbb, _dim, _keepDims, _dType); } inline RNNParamT *RNNParam::UnPack(const flatbuffers::resolver_function_t *_resolver) const { auto _o = new RNNParamT(); UnPackTo(_o, _resolver); return _o; } inline void RNNParam::UnPackTo(RNNParamT *_o, const flatbuffers::resolver_function_t *_resolver) const { (void)_o; (void)_resolver; { auto _e = numUnits(); _o->numUnits = _e; }; { auto _e = isBidirectionalRNN(); _o->isBidirectionalRNN = _e; }; { auto _e = linearBeforeReset(); _o->linearBeforeReset = _e; }; { auto _e = keepAllOutputs(); _o->keepAllOutputs = _e; }; { auto _e = fwGateWeight(); if (_e) _o->fwGateWeight = std::unique_ptr(_e->UnPack(_resolver)); }; { auto _e = fwGateBias(); if (_e) _o->fwGateBias = std::unique_ptr(_e->UnPack(_resolver)); }; { auto _e = fwCandidateWeight(); if (_e) _o->fwCandidateWeight = std::unique_ptr(_e->UnPack(_resolver)); }; { auto _e = fwCandidateBias(); if (_e) _o->fwCandidateBias = std::unique_ptr(_e->UnPack(_resolver)); }; { auto _e = fwRecurrentBias(); if (_e) _o->fwRecurrentBias = std::unique_ptr(_e->UnPack(_resolver)); }; { auto _e = bwGateWeight(); if (_e) _o->bwGateWeight = std::unique_ptr(_e->UnPack(_resolver)); }; { auto _e = bwGateBias(); if (_e) _o->bwGateBias = std::unique_ptr(_e->UnPack(_resolver)); }; { auto _e = bwCandidateWeight(); if (_e) _o->bwCandidateWeight = std::unique_ptr(_e->UnPack(_resolver)); }; { auto _e = bwCandidateBias(); if (_e) _o->bwCandidateBias = std::unique_ptr(_e->UnPack(_resolver)); }; { auto _e = bwRecurrentBias(); if (_e) _o->bwRecurrentBias = std::unique_ptr(_e->UnPack(_resolver)); }; } inline flatbuffers::Offset RNNParam::Pack(flatbuffers::FlatBufferBuilder &_fbb, const RNNParamT* _o, const flatbuffers::rehasher_function_t *_rehasher) { return CreateRNNParam(_fbb, _o, _rehasher); } inline flatbuffers::Offset CreateRNNParam(flatbuffers::FlatBufferBuilder &_fbb, const RNNParamT *_o, const flatbuffers::rehasher_function_t *_rehasher) { (void)_rehasher; (void)_o; struct _VectorArgs { flatbuffers::FlatBufferBuilder *__fbb; const RNNParamT* __o; const flatbuffers::rehasher_function_t *__rehasher; } _va = { &_fbb, _o, _rehasher}; (void)_va; auto _numUnits = _o->numUnits; auto _isBidirectionalRNN = _o->isBidirectionalRNN; auto _linearBeforeReset = _o->linearBeforeReset; auto _keepAllOutputs = _o->keepAllOutputs; auto _fwGateWeight = _o->fwGateWeight ? CreateBlob(_fbb, _o->fwGateWeight.get(), _rehasher) : 0; auto _fwGateBias = _o->fwGateBias ? CreateBlob(_fbb, _o->fwGateBias.get(), _rehasher) : 0; auto _fwCandidateWeight = _o->fwCandidateWeight ? CreateBlob(_fbb, _o->fwCandidateWeight.get(), _rehasher) : 0; auto _fwCandidateBias = _o->fwCandidateBias ? CreateBlob(_fbb, _o->fwCandidateBias.get(), _rehasher) : 0; auto _fwRecurrentBias = _o->fwRecurrentBias ? CreateBlob(_fbb, _o->fwRecurrentBias.get(), _rehasher) : 0; auto _bwGateWeight = _o->bwGateWeight ? CreateBlob(_fbb, _o->bwGateWeight.get(), _rehasher) : 0; auto _bwGateBias = _o->bwGateBias ? CreateBlob(_fbb, _o->bwGateBias.get(), _rehasher) : 0; auto _bwCandidateWeight = _o->bwCandidateWeight ? CreateBlob(_fbb, _o->bwCandidateWeight.get(), _rehasher) : 0; auto _bwCandidateBias = _o->bwCandidateBias ? CreateBlob(_fbb, _o->bwCandidateBias.get(), _rehasher) : 0; auto _bwRecurrentBias = _o->bwRecurrentBias ? CreateBlob(_fbb, _o->bwRecurrentBias.get(), _rehasher) : 0; return MNN::CreateRNNParam( _fbb, _numUnits, _isBidirectionalRNN, _linearBeforeReset, _keepAllOutputs, _fwGateWeight, _fwGateBias, _fwCandidateWeight, _fwCandidateBias, _fwRecurrentBias, _bwGateWeight, _bwGateBias, _bwCandidateWeight, _bwCandidateBias, _bwRecurrentBias); } inline BatchMatMulParamT *BatchMatMulParam::UnPack(const flatbuffers::resolver_function_t *_resolver) const { auto _o = new BatchMatMulParamT(); UnPackTo(_o, _resolver); return _o; } inline void BatchMatMulParam::UnPackTo(BatchMatMulParamT *_o, const flatbuffers::resolver_function_t *_resolver) const { (void)_o; (void)_resolver; { auto _e = adjX(); _o->adjX = _e; }; { auto _e = adjY(); _o->adjY = _e; }; } inline flatbuffers::Offset BatchMatMulParam::Pack(flatbuffers::FlatBufferBuilder &_fbb, const BatchMatMulParamT* _o, const flatbuffers::rehasher_function_t *_rehasher) { return CreateBatchMatMulParam(_fbb, _o, _rehasher); } inline flatbuffers::Offset CreateBatchMatMulParam(flatbuffers::FlatBufferBuilder &_fbb, const BatchMatMulParamT *_o, const flatbuffers::rehasher_function_t *_rehasher) { (void)_rehasher; (void)_o; struct _VectorArgs { flatbuffers::FlatBufferBuilder *__fbb; const BatchMatMulParamT* __o; const flatbuffers::rehasher_function_t *__rehasher; } _va = { &_fbb, _o, _rehasher}; (void)_va; auto _adjX = _o->adjX; auto _adjY = _o->adjY; return MNN::CreateBatchMatMulParam( _fbb, _adjX, _adjY); } inline DepthSpaceParamT *DepthSpaceParam::UnPack(const flatbuffers::resolver_function_t *_resolver) const { auto _o = new DepthSpaceParamT(); UnPackTo(_o, _resolver); return _o; } inline void DepthSpaceParam::UnPackTo(DepthSpaceParamT *_o, const flatbuffers::resolver_function_t *_resolver) const { (void)_o; (void)_resolver; { auto _e = blockSize(); _o->blockSize = _e; }; { auto _e = mode(); _o->mode = _e; }; } inline flatbuffers::Offset DepthSpaceParam::Pack(flatbuffers::FlatBufferBuilder &_fbb, const DepthSpaceParamT* _o, const flatbuffers::rehasher_function_t *_rehasher) { return CreateDepthSpaceParam(_fbb, _o, _rehasher); } inline flatbuffers::Offset CreateDepthSpaceParam(flatbuffers::FlatBufferBuilder &_fbb, const DepthSpaceParamT *_o, const flatbuffers::rehasher_function_t *_rehasher) { (void)_rehasher; (void)_o; struct _VectorArgs { flatbuffers::FlatBufferBuilder *__fbb; const DepthSpaceParamT* __o; const flatbuffers::rehasher_function_t *__rehasher; } _va = { &_fbb, _o, _rehasher}; (void)_va; auto _blockSize = _o->blockSize; auto _mode = _o->mode; return MNN::CreateDepthSpaceParam( _fbb, _blockSize, _mode); } inline ReverseSequenceParamT *ReverseSequenceParam::UnPack(const flatbuffers::resolver_function_t *_resolver) const { auto _o = new ReverseSequenceParamT(); UnPackTo(_o, _resolver); return _o; } inline void ReverseSequenceParam::UnPackTo(ReverseSequenceParamT *_o, const flatbuffers::resolver_function_t *_resolver) const { (void)_o; (void)_resolver; { auto _e = batchDim(); _o->batchDim = _e; }; { auto _e = seqDim(); _o->seqDim = _e; }; } inline flatbuffers::Offset ReverseSequenceParam::Pack(flatbuffers::FlatBufferBuilder &_fbb, const ReverseSequenceParamT* _o, const flatbuffers::rehasher_function_t *_rehasher) { return CreateReverseSequenceParam(_fbb, _o, _rehasher); } inline flatbuffers::Offset CreateReverseSequenceParam(flatbuffers::FlatBufferBuilder &_fbb, const ReverseSequenceParamT *_o, const flatbuffers::rehasher_function_t *_rehasher) { (void)_rehasher; (void)_o; struct _VectorArgs { flatbuffers::FlatBufferBuilder *__fbb; const ReverseSequenceParamT* __o; const flatbuffers::rehasher_function_t *__rehasher; } _va = { &_fbb, _o, _rehasher}; (void)_va; auto _batchDim = _o->batchDim; auto _seqDim = _o->seqDim; return MNN::CreateReverseSequenceParam( _fbb, _batchDim, _seqDim); } inline DetectionPostProcessParamT *DetectionPostProcessParam::UnPack(const flatbuffers::resolver_function_t *_resolver) const { auto _o = new DetectionPostProcessParamT(); UnPackTo(_o, _resolver); return _o; } inline void DetectionPostProcessParam::UnPackTo(DetectionPostProcessParamT *_o, const flatbuffers::resolver_function_t *_resolver) const { (void)_o; (void)_resolver; { auto _e = maxDetections(); _o->maxDetections = _e; }; { auto _e = maxClassesPerDetection(); _o->maxClassesPerDetection = _e; }; { auto _e = detectionsPerClass(); _o->detectionsPerClass = _e; }; { auto _e = nmsScoreThreshold(); _o->nmsScoreThreshold = _e; }; { auto _e = iouThreshold(); _o->iouThreshold = _e; }; { auto _e = numClasses(); _o->numClasses = _e; }; { auto _e = useRegularNMS(); _o->useRegularNMS = _e; }; { auto _e = centerSizeEncoding(); if (_e) { _o->centerSizeEncoding.resize(_e->size()); for (flatbuffers::uoffset_t _i = 0; _i < _e->size(); _i++) { _o->centerSizeEncoding[_i] = _e->Get(_i); } } }; } inline flatbuffers::Offset DetectionPostProcessParam::Pack(flatbuffers::FlatBufferBuilder &_fbb, const DetectionPostProcessParamT* _o, const flatbuffers::rehasher_function_t *_rehasher) { return CreateDetectionPostProcessParam(_fbb, _o, _rehasher); } inline flatbuffers::Offset CreateDetectionPostProcessParam(flatbuffers::FlatBufferBuilder &_fbb, const DetectionPostProcessParamT *_o, const flatbuffers::rehasher_function_t *_rehasher) { (void)_rehasher; (void)_o; struct _VectorArgs { flatbuffers::FlatBufferBuilder *__fbb; const DetectionPostProcessParamT* __o; const flatbuffers::rehasher_function_t *__rehasher; } _va = { &_fbb, _o, _rehasher}; (void)_va; auto _maxDetections = _o->maxDetections; auto _maxClassesPerDetection = _o->maxClassesPerDetection; auto _detectionsPerClass = _o->detectionsPerClass; auto _nmsScoreThreshold = _o->nmsScoreThreshold; auto _iouThreshold = _o->iouThreshold; auto _numClasses = _o->numClasses; auto _useRegularNMS = _o->useRegularNMS; auto _centerSizeEncoding = _o->centerSizeEncoding.size() ? _fbb.CreateVector(_o->centerSizeEncoding) : 0; return MNN::CreateDetectionPostProcessParam( _fbb, _maxDetections, _maxClassesPerDetection, _detectionsPerClass, _nmsScoreThreshold, _iouThreshold, _numClasses, _useRegularNMS, _centerSizeEncoding); } inline OneHotParamT *OneHotParam::UnPack(const flatbuffers::resolver_function_t *_resolver) const { auto _o = new OneHotParamT(); UnPackTo(_o, _resolver); return _o; } inline void OneHotParam::UnPackTo(OneHotParamT *_o, const flatbuffers::resolver_function_t *_resolver) const { (void)_o; (void)_resolver; { auto _e = dType(); _o->dType = _e; }; { auto _e = axis(); _o->axis = _e; }; } inline flatbuffers::Offset OneHotParam::Pack(flatbuffers::FlatBufferBuilder &_fbb, const OneHotParamT* _o, const flatbuffers::rehasher_function_t *_rehasher) { return CreateOneHotParam(_fbb, _o, _rehasher); } inline flatbuffers::Offset CreateOneHotParam(flatbuffers::FlatBufferBuilder &_fbb, const OneHotParamT *_o, const flatbuffers::rehasher_function_t *_rehasher) { (void)_rehasher; (void)_o; struct _VectorArgs { flatbuffers::FlatBufferBuilder *__fbb; const OneHotParamT* __o; const flatbuffers::rehasher_function_t *__rehasher; } _va = { &_fbb, _o, _rehasher}; (void)_va; auto _dType = _o->dType; auto _axis = _o->axis; return MNN::CreateOneHotParam( _fbb, _dType, _axis); } inline PadParamT *PadParam::UnPack(const flatbuffers::resolver_function_t *_resolver) const { auto _o = new PadParamT(); UnPackTo(_o, _resolver); return _o; } inline void PadParam::UnPackTo(PadParamT *_o, const flatbuffers::resolver_function_t *_resolver) const { (void)_o; (void)_resolver; { auto _e = mode(); _o->mode = _e; }; } inline flatbuffers::Offset PadParam::Pack(flatbuffers::FlatBufferBuilder &_fbb, const PadParamT* _o, const flatbuffers::rehasher_function_t *_rehasher) { return CreatePadParam(_fbb, _o, _rehasher); } inline flatbuffers::Offset CreatePadParam(flatbuffers::FlatBufferBuilder &_fbb, const PadParamT *_o, const flatbuffers::rehasher_function_t *_rehasher) { (void)_rehasher; (void)_o; struct _VectorArgs { flatbuffers::FlatBufferBuilder *__fbb; const PadParamT* __o; const flatbuffers::rehasher_function_t *__rehasher; } _va = { &_fbb, _o, _rehasher}; (void)_va; auto _mode = _o->mode; return MNN::CreatePadParam( _fbb, _mode); } inline LayerNormT *LayerNorm::UnPack(const flatbuffers::resolver_function_t *_resolver) const { auto _o = new LayerNormT(); UnPackTo(_o, _resolver); return _o; } inline void LayerNorm::UnPackTo(LayerNormT *_o, const flatbuffers::resolver_function_t *_resolver) const { (void)_o; (void)_resolver; { auto _e = axis(); if (_e) { _o->axis.resize(_e->size()); for (flatbuffers::uoffset_t _i = 0; _i < _e->size(); _i++) { _o->axis[_i] = _e->Get(_i); } } }; { auto _e = epsilon(); _o->epsilon = _e; }; { auto _e = gamma(); if (_e) { _o->gamma.resize(_e->size()); for (flatbuffers::uoffset_t _i = 0; _i < _e->size(); _i++) { _o->gamma[_i] = _e->Get(_i); } } }; { auto _e = beta(); if (_e) { _o->beta.resize(_e->size()); for (flatbuffers::uoffset_t _i = 0; _i < _e->size(); _i++) { _o->beta[_i] = _e->Get(_i); } } }; { auto _e = group(); _o->group = _e; }; { auto _e = external(); if (_e) { _o->external.resize(_e->size()); for (flatbuffers::uoffset_t _i = 0; _i < _e->size(); _i++) { _o->external[_i] = _e->Get(_i); } } }; { auto _e = useRMSNorm(); _o->useRMSNorm = _e; }; } inline flatbuffers::Offset LayerNorm::Pack(flatbuffers::FlatBufferBuilder &_fbb, const LayerNormT* _o, const flatbuffers::rehasher_function_t *_rehasher) { return CreateLayerNorm(_fbb, _o, _rehasher); } inline flatbuffers::Offset CreateLayerNorm(flatbuffers::FlatBufferBuilder &_fbb, const LayerNormT *_o, const flatbuffers::rehasher_function_t *_rehasher) { (void)_rehasher; (void)_o; struct _VectorArgs { flatbuffers::FlatBufferBuilder *__fbb; const LayerNormT* __o; const flatbuffers::rehasher_function_t *__rehasher; } _va = { &_fbb, _o, _rehasher}; (void)_va; auto _axis = _o->axis.size() ? _fbb.CreateVector(_o->axis) : 0; auto _epsilon = _o->epsilon; auto _gamma = _o->gamma.size() ? _fbb.CreateVector(_o->gamma) : 0; auto _beta = _o->beta.size() ? _fbb.CreateVector(_o->beta) : 0; auto _group = _o->group; auto _external = _o->external.size() ? _fbb.CreateVector(_o->external) : 0; auto _useRMSNorm = _o->useRMSNorm; return MNN::CreateLayerNorm( _fbb, _axis, _epsilon, _gamma, _beta, _group, _external, _useRMSNorm); } inline GroupNormT *GroupNorm::UnPack(const flatbuffers::resolver_function_t *_resolver) const { auto _o = new GroupNormT(); UnPackTo(_o, _resolver); return _o; } inline void GroupNorm::UnPackTo(GroupNormT *_o, const flatbuffers::resolver_function_t *_resolver) const { (void)_o; (void)_resolver; { auto _e = axis(); _o->axis = _e; }; { auto _e = epsilon(); _o->epsilon = _e; }; { auto _e = gamma(); if (_e) { _o->gamma.resize(_e->size()); for (flatbuffers::uoffset_t _i = 0; _i < _e->size(); _i++) { _o->gamma[_i] = _e->Get(_i); } } }; { auto _e = beta(); if (_e) { _o->beta.resize(_e->size()); for (flatbuffers::uoffset_t _i = 0; _i < _e->size(); _i++) { _o->beta[_i] = _e->Get(_i); } } }; { auto _e = group(); _o->group = _e; }; { auto _e = bSwish(); _o->bSwish = _e; }; { auto _e = external(); if (_e) { _o->external.resize(_e->size()); for (flatbuffers::uoffset_t _i = 0; _i < _e->size(); _i++) { _o->external[_i] = _e->Get(_i); } } }; } inline flatbuffers::Offset GroupNorm::Pack(flatbuffers::FlatBufferBuilder &_fbb, const GroupNormT* _o, const flatbuffers::rehasher_function_t *_rehasher) { return CreateGroupNorm(_fbb, _o, _rehasher); } inline flatbuffers::Offset CreateGroupNorm(flatbuffers::FlatBufferBuilder &_fbb, const GroupNormT *_o, const flatbuffers::rehasher_function_t *_rehasher) { (void)_rehasher; (void)_o; struct _VectorArgs { flatbuffers::FlatBufferBuilder *__fbb; const GroupNormT* __o; const flatbuffers::rehasher_function_t *__rehasher; } _va = { &_fbb, _o, _rehasher}; (void)_va; auto _axis = _o->axis; auto _epsilon = _o->epsilon; auto _gamma = _o->gamma.size() ? _fbb.CreateVector(_o->gamma) : 0; auto _beta = _o->beta.size() ? _fbb.CreateVector(_o->beta) : 0; auto _group = _o->group; auto _bSwish = _o->bSwish; auto _external = _o->external.size() ? _fbb.CreateVector(_o->external) : 0; return MNN::CreateGroupNorm( _fbb, _axis, _epsilon, _gamma, _beta, _group, _bSwish, _external); } inline RandomUniformT *RandomUniform::UnPack(const flatbuffers::resolver_function_t *_resolver) const { auto _o = new RandomUniformT(); UnPackTo(_o, _resolver); return _o; } inline void RandomUniform::UnPackTo(RandomUniformT *_o, const flatbuffers::resolver_function_t *_resolver) const { (void)_o; (void)_resolver; { auto _e = seed(); _o->seed = _e; }; { auto _e = seed2(); _o->seed2 = _e; }; { auto _e = type(); _o->type = _e; }; { auto _e = low(); _o->low = _e; }; { auto _e = high(); _o->high = _e; }; } inline flatbuffers::Offset RandomUniform::Pack(flatbuffers::FlatBufferBuilder &_fbb, const RandomUniformT* _o, const flatbuffers::rehasher_function_t *_rehasher) { return CreateRandomUniform(_fbb, _o, _rehasher); } inline flatbuffers::Offset CreateRandomUniform(flatbuffers::FlatBufferBuilder &_fbb, const RandomUniformT *_o, const flatbuffers::rehasher_function_t *_rehasher) { (void)_rehasher; (void)_o; struct _VectorArgs { flatbuffers::FlatBufferBuilder *__fbb; const RandomUniformT* __o; const flatbuffers::rehasher_function_t *__rehasher; } _va = { &_fbb, _o, _rehasher}; (void)_va; auto _seed = _o->seed; auto _seed2 = _o->seed2; auto _type = _o->type; auto _low = _o->low; auto _high = _o->high; return MNN::CreateRandomUniform( _fbb, _seed, _seed2, _type, _low, _high); } inline TensorArrayT *TensorArray::UnPack(const flatbuffers::resolver_function_t *_resolver) const { auto _o = new TensorArrayT(); UnPackTo(_o, _resolver); return _o; } inline void TensorArray::UnPackTo(TensorArrayT *_o, const flatbuffers::resolver_function_t *_resolver) const { (void)_o; (void)_resolver; { auto _e = dynamic_size(); _o->dynamic_size = _e; }; { auto _e = identical_element_shapes(); _o->identical_element_shapes = _e; }; { auto _e = element_shape(); if (_e) { _o->element_shape.resize(_e->size()); for (flatbuffers::uoffset_t _i = 0; _i < _e->size(); _i++) { _o->element_shape[_i] = _e->Get(_i); } } }; { auto _e = T(); _o->T = _e; }; { auto _e = axis(); _o->axis = _e; }; { auto _e = keepdims(); _o->keepdims = _e; }; { auto _e = new_axis(); _o->new_axis = _e; }; } inline flatbuffers::Offset TensorArray::Pack(flatbuffers::FlatBufferBuilder &_fbb, const TensorArrayT* _o, const flatbuffers::rehasher_function_t *_rehasher) { return CreateTensorArray(_fbb, _o, _rehasher); } inline flatbuffers::Offset CreateTensorArray(flatbuffers::FlatBufferBuilder &_fbb, const TensorArrayT *_o, const flatbuffers::rehasher_function_t *_rehasher) { (void)_rehasher; (void)_o; struct _VectorArgs { flatbuffers::FlatBufferBuilder *__fbb; const TensorArrayT* __o; const flatbuffers::rehasher_function_t *__rehasher; } _va = { &_fbb, _o, _rehasher}; (void)_va; auto _dynamic_size = _o->dynamic_size; auto _identical_element_shapes = _o->identical_element_shapes; auto _element_shape = _o->element_shape.size() ? _fbb.CreateVector(_o->element_shape) : 0; auto _T = _o->T; auto _axis = _o->axis; auto _keepdims = _o->keepdims; auto _new_axis = _o->new_axis; return MNN::CreateTensorArray( _fbb, _dynamic_size, _identical_element_shapes, _element_shape, _T, _axis, _keepdims, _new_axis); } inline LSTMBlockCellT *LSTMBlockCell::UnPack(const flatbuffers::resolver_function_t *_resolver) const { auto _o = new LSTMBlockCellT(); UnPackTo(_o, _resolver); return _o; } inline void LSTMBlockCell::UnPackTo(LSTMBlockCellT *_o, const flatbuffers::resolver_function_t *_resolver) const { (void)_o; (void)_resolver; { auto _e = cell_clip(); _o->cell_clip = _e; }; { auto _e = forget_bias(); _o->forget_bias = _e; }; { auto _e = use_peephole(); _o->use_peephole = _e; }; } inline flatbuffers::Offset LSTMBlockCell::Pack(flatbuffers::FlatBufferBuilder &_fbb, const LSTMBlockCellT* _o, const flatbuffers::rehasher_function_t *_rehasher) { return CreateLSTMBlockCell(_fbb, _o, _rehasher); } inline flatbuffers::Offset CreateLSTMBlockCell(flatbuffers::FlatBufferBuilder &_fbb, const LSTMBlockCellT *_o, const flatbuffers::rehasher_function_t *_rehasher) { (void)_rehasher; (void)_o; struct _VectorArgs { flatbuffers::FlatBufferBuilder *__fbb; const LSTMBlockCellT* __o; const flatbuffers::rehasher_function_t *__rehasher; } _va = { &_fbb, _o, _rehasher}; (void)_va; auto _cell_clip = _o->cell_clip; auto _forget_bias = _o->forget_bias; auto _use_peephole = _o->use_peephole; return MNN::CreateLSTMBlockCell( _fbb, _cell_clip, _forget_bias, _use_peephole); } inline const flatbuffers::TypeTable *BinaryOpOperationTypeTable() { static const flatbuffers::TypeCode type_codes[] = { { flatbuffers::ET_INT, 0, 0 }, { flatbuffers::ET_INT, 0, 0 }, { flatbuffers::ET_INT, 0, 0 }, { flatbuffers::ET_INT, 0, 0 }, { flatbuffers::ET_INT, 0, 0 }, { flatbuffers::ET_INT, 0, 0 }, { flatbuffers::ET_INT, 0, 0 }, { flatbuffers::ET_INT, 0, 0 }, { flatbuffers::ET_INT, 0, 0 }, { flatbuffers::ET_INT, 0, 0 }, { flatbuffers::ET_INT, 0, 0 }, { flatbuffers::ET_INT, 0, 0 }, { flatbuffers::ET_INT, 0, 0 }, { flatbuffers::ET_INT, 0, 0 }, { flatbuffers::ET_INT, 0, 0 }, { flatbuffers::ET_INT, 0, 0 }, { flatbuffers::ET_INT, 0, 0 }, { flatbuffers::ET_INT, 0, 0 }, { flatbuffers::ET_INT, 0, 0 }, { flatbuffers::ET_INT, 0, 0 }, { flatbuffers::ET_INT, 0, 0 }, { flatbuffers::ET_INT, 0, 0 }, { flatbuffers::ET_INT, 0, 0 }, { flatbuffers::ET_INT, 0, 0 }, { flatbuffers::ET_INT, 0, 0 }, { flatbuffers::ET_INT, 0, 0 }, { flatbuffers::ET_INT, 0, 0 }, { flatbuffers::ET_INT, 0, 0 }, { flatbuffers::ET_INT, 0, 0 } }; static const flatbuffers::TypeFunction type_refs[] = { BinaryOpOperationTypeTable }; static const int64_t values[] = { 0, 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16, 17, 19, 20, 21, 22, 23, 24, 25, 26, 27, 28, 29 }; static const char * const names[] = { "ADD", "SUB", "MUL", "DIV", "MAX_TEMP", "MIN_TEMP", "POW", "REALDIV", "MINIMUM", "MAXIMUM", "GREATER", "GREATER_EQUAL", "LESS", "FLOORDIV", "SquaredDifference", "EQUAL", "LESS_EQUAL", "FLOORMOD", "MOD", "ATAN2", "LOGICALOR", "NOTEQUAL", "BITWISE_AND", "BITWISE_OR", "BITWISE_XOR", "LOGICALXOR", "LEFTSHIFT", "RIGHTSHIFT", "MUL_SILU" }; static const flatbuffers::TypeTable tt = { flatbuffers::ST_ENUM, 29, type_codes, type_refs, values, names }; return &tt; } inline const flatbuffers::TypeTable *ReductionTypeTypeTable() { static const flatbuffers::TypeCode type_codes[] = { { flatbuffers::ET_CHAR, 0, 0 }, { flatbuffers::ET_CHAR, 0, 0 }, { flatbuffers::ET_CHAR, 0, 0 }, { flatbuffers::ET_CHAR, 0, 0 }, { flatbuffers::ET_CHAR, 0, 0 }, { flatbuffers::ET_CHAR, 0, 0 }, { flatbuffers::ET_CHAR, 0, 0 }, { flatbuffers::ET_CHAR, 0, 0 }, { flatbuffers::ET_CHAR, 0, 0 } }; static const flatbuffers::TypeFunction type_refs[] = { ReductionTypeTypeTable }; static const char * const names[] = { "SUM", "ASUM", "SUMSQ", "MEAN", "MAXIMUM", "MINIMUM", "PROD", "ANY", "ALL" }; static const flatbuffers::TypeTable tt = { flatbuffers::ST_ENUM, 9, type_codes, type_refs, nullptr, names }; return &tt; } inline const flatbuffers::TypeTable *UnaryOpOperationTypeTable() { static const flatbuffers::TypeCode type_codes[] = { { flatbuffers::ET_INT, 0, 0 }, { flatbuffers::ET_INT, 0, 0 }, { flatbuffers::ET_INT, 0, 0 }, { flatbuffers::ET_INT, 0, 0 }, { flatbuffers::ET_INT, 0, 0 }, { flatbuffers::ET_INT, 0, 0 }, { flatbuffers::ET_INT, 0, 0 }, { flatbuffers::ET_INT, 0, 0 }, { flatbuffers::ET_INT, 0, 0 }, { flatbuffers::ET_INT, 0, 0 }, { flatbuffers::ET_INT, 0, 0 }, { flatbuffers::ET_INT, 0, 0 }, { flatbuffers::ET_INT, 0, 0 }, { flatbuffers::ET_INT, 0, 0 }, { flatbuffers::ET_INT, 0, 0 }, { flatbuffers::ET_INT, 0, 0 }, { flatbuffers::ET_INT, 0, 0 }, { flatbuffers::ET_INT, 0, 0 }, { flatbuffers::ET_INT, 0, 0 }, { flatbuffers::ET_INT, 0, 0 }, { flatbuffers::ET_INT, 0, 0 }, { flatbuffers::ET_INT, 0, 0 }, { flatbuffers::ET_INT, 0, 0 }, { flatbuffers::ET_INT, 0, 0 }, { flatbuffers::ET_INT, 0, 0 }, { flatbuffers::ET_INT, 0, 0 }, { flatbuffers::ET_INT, 0, 0 }, { flatbuffers::ET_INT, 0, 0 }, { flatbuffers::ET_INT, 0, 0 }, { flatbuffers::ET_INT, 0, 0 }, { flatbuffers::ET_INT, 0, 0 }, { flatbuffers::ET_INT, 0, 0 }, { flatbuffers::ET_INT, 0, 0 }, { flatbuffers::ET_INT, 0, 0 }, { flatbuffers::ET_INT, 0, 0 } }; static const flatbuffers::TypeFunction type_refs[] = { UnaryOpOperationTypeTable }; static const char * const names[] = { "ABS", "NEG", "FLOOR", "CEIL", "SQUARE", "SQRT", "RSQRT", "EXP", "LOG", "SIN", "COS", "TAN", "ASIN", "ACOS", "ATAN", "RECIPROCAL", "LOG1P", "BNLL", "ACOSH", "SINH", "ASINH", "ATANH", "SIGN", "ROUND", "COSH", "ERF", "ERFC", "ERFINV", "EXPM1", "SIGMOID", "TANH", "HARDSWISH", "GELU", "GELU_STANDARD", "SILU" }; static const flatbuffers::TypeTable tt = { flatbuffers::ST_ENUM, 35, type_codes, type_refs, nullptr, names }; return &tt; } inline const flatbuffers::TypeTable *CropAndResizeMethodTypeTable() { static const flatbuffers::TypeCode type_codes[] = { { flatbuffers::ET_CHAR, 0, 0 }, { flatbuffers::ET_CHAR, 0, 0 } }; static const flatbuffers::TypeFunction type_refs[] = { CropAndResizeMethodTypeTable }; static const char * const names[] = { "BILINEAR", "NEAREST" }; static const flatbuffers::TypeTable tt = { flatbuffers::ST_ENUM, 2, type_codes, type_refs, nullptr, names }; return &tt; } inline const flatbuffers::TypeTable *DepthToSpaceModeTypeTable() { static const flatbuffers::TypeCode type_codes[] = { { flatbuffers::ET_CHAR, 0, 0 }, { flatbuffers::ET_CHAR, 0, 0 } }; static const flatbuffers::TypeFunction type_refs[] = { DepthToSpaceModeTypeTable }; static const char * const names[] = { "DCR", "CRD" }; static const flatbuffers::TypeTable tt = { flatbuffers::ST_ENUM, 2, type_codes, type_refs, nullptr, names }; return &tt; } inline const flatbuffers::TypeTable *PadValueModeTypeTable() { static const flatbuffers::TypeCode type_codes[] = { { flatbuffers::ET_CHAR, 0, 0 }, { flatbuffers::ET_CHAR, 0, 0 }, { flatbuffers::ET_CHAR, 0, 0 }, { flatbuffers::ET_CHAR, 0, 0 } }; static const flatbuffers::TypeFunction type_refs[] = { PadValueModeTypeTable }; static const char * const names[] = { "CONSTANT", "REFLECT", "SYMMETRIC", "EDGE" }; static const flatbuffers::TypeTable tt = { flatbuffers::ST_ENUM, 4, type_codes, type_refs, nullptr, names }; return &tt; } inline const flatbuffers::TypeTable *BinaryOpTypeTable() { static const flatbuffers::TypeCode type_codes[] = { { flatbuffers::ET_INT, 0, 0 }, { flatbuffers::ET_INT, 0, 1 }, { flatbuffers::ET_INT, 0, -1 } }; static const flatbuffers::TypeFunction type_refs[] = { BinaryOpOperationTypeTable, DataTypeTypeTable }; static const char * const names[] = { "opType", "T", "activationType" }; static const flatbuffers::TypeTable tt = { flatbuffers::ST_TABLE, 3, type_codes, type_refs, nullptr, names }; return &tt; } inline const flatbuffers::TypeTable *PackParamTypeTable() { static const flatbuffers::TypeCode type_codes[] = { { flatbuffers::ET_INT, 0, 0 }, { flatbuffers::ET_INT, 0, -1 } }; static const flatbuffers::TypeFunction type_refs[] = { DataTypeTypeTable }; static const char * const names[] = { "dataType", "axis" }; static const flatbuffers::TypeTable tt = { flatbuffers::ST_TABLE, 2, type_codes, type_refs, nullptr, names }; return &tt; } inline const flatbuffers::TypeTable *StridedSliceParamTypeTable() { static const flatbuffers::TypeCode type_codes[] = { { flatbuffers::ET_INT, 0, 0 }, { flatbuffers::ET_INT, 0, 0 }, { flatbuffers::ET_INT, 0, -1 }, { flatbuffers::ET_INT, 0, -1 }, { flatbuffers::ET_INT, 0, -1 }, { flatbuffers::ET_INT, 0, -1 }, { flatbuffers::ET_INT, 0, -1 }, { flatbuffers::ET_INT, 0, -1 } }; static const flatbuffers::TypeFunction type_refs[] = { DataTypeTypeTable }; static const char * const names[] = { "Index", "T", "beginMask", "endMask", "ellipsisMask", "newAxisMask", "shrinkAxisMask", "fromType" }; static const flatbuffers::TypeTable tt = { flatbuffers::ST_TABLE, 8, type_codes, type_refs, nullptr, names }; return &tt; } inline const flatbuffers::TypeTable *SqueezeParamTypeTable() { static const flatbuffers::TypeCode type_codes[] = { { flatbuffers::ET_INT, 1, -1 } }; static const char * const names[] = { "squeezeDims" }; static const flatbuffers::TypeTable tt = { flatbuffers::ST_TABLE, 1, type_codes, nullptr, nullptr, names }; return &tt; } inline const flatbuffers::TypeTable *CastParamTypeTable() { static const flatbuffers::TypeCode type_codes[] = { { flatbuffers::ET_INT, 0, 0 }, { flatbuffers::ET_INT, 0, 0 } }; static const flatbuffers::TypeFunction type_refs[] = { DataTypeTypeTable }; static const char * const names[] = { "srcT", "dstT" }; static const flatbuffers::TypeTable tt = { flatbuffers::ST_TABLE, 2, type_codes, type_refs, nullptr, names }; return &tt; } inline const flatbuffers::TypeTable *ReductionParamTypeTable() { static const flatbuffers::TypeCode type_codes[] = { { flatbuffers::ET_CHAR, 0, 0 }, { flatbuffers::ET_INT, 1, -1 }, { flatbuffers::ET_FLOAT, 0, -1 }, { flatbuffers::ET_BOOL, 0, -1 }, { flatbuffers::ET_INT, 0, 1 } }; static const flatbuffers::TypeFunction type_refs[] = { ReductionTypeTypeTable, DataTypeTypeTable }; static const char * const names[] = { "operation", "dim", "coeff", "keepDims", "dType" }; static const flatbuffers::TypeTable tt = { flatbuffers::ST_TABLE, 5, type_codes, type_refs, nullptr, names }; return &tt; } inline const flatbuffers::TypeTable *GatherTypeTable() { static const flatbuffers::TypeCode type_codes[] = { { flatbuffers::ET_INT, 0, 0 }, { flatbuffers::ET_INT, 0, 0 }, { flatbuffers::ET_BOOL, 0, -1 }, { flatbuffers::ET_INT, 0, -1 } }; static const flatbuffers::TypeFunction type_refs[] = { DataTypeTypeTable }; static const char * const names[] = { "Tindices", "Tparams", "validateIndices", "axis" }; static const flatbuffers::TypeTable tt = { flatbuffers::ST_TABLE, 4, type_codes, type_refs, nullptr, names }; return &tt; } inline const flatbuffers::TypeTable *ExpandDimsTypeTable() { static const flatbuffers::TypeCode type_codes[] = { { flatbuffers::ET_INT, 0, 0 }, { flatbuffers::ET_INT, 0, 0 }, { flatbuffers::ET_INT, 0, -1 } }; static const flatbuffers::TypeFunction type_refs[] = { DataTypeTypeTable }; static const char * const names[] = { "T", "Tdim", "axis" }; static const flatbuffers::TypeTable tt = { flatbuffers::ST_TABLE, 3, type_codes, type_refs, nullptr, names }; return &tt; } inline const flatbuffers::TypeTable *SeluTypeTable() { static const flatbuffers::TypeCode type_codes[] = { { flatbuffers::ET_FLOAT, 0, -1 }, { flatbuffers::ET_FLOAT, 0, -1 } }; static const char * const names[] = { "scale", "alpha" }; static const flatbuffers::TypeTable tt = { flatbuffers::ST_TABLE, 2, type_codes, nullptr, nullptr, names }; return &tt; } inline const flatbuffers::TypeTable *AsStringTypeTable() { static const flatbuffers::TypeCode type_codes[] = { { flatbuffers::ET_INT, 0, 0 }, { flatbuffers::ET_INT, 0, -1 }, { flatbuffers::ET_BOOL, 0, -1 }, { flatbuffers::ET_BOOL, 0, -1 }, { flatbuffers::ET_INT, 0, -1 }, { flatbuffers::ET_STRING, 0, -1 } }; static const flatbuffers::TypeFunction type_refs[] = { DataTypeTypeTable }; static const char * const names[] = { "T", "precision", "scientific", "shortest", "width", "fillString" }; static const flatbuffers::TypeTable tt = { flatbuffers::ST_TABLE, 6, type_codes, type_refs, nullptr, names }; return &tt; } inline const flatbuffers::TypeTable *ReduceJoinTypeTable() { static const flatbuffers::TypeCode type_codes[] = { { flatbuffers::ET_BOOL, 0, -1 }, { flatbuffers::ET_STRING, 0, -1 } }; static const char * const names[] = { "keepDims", "separator" }; static const flatbuffers::TypeTable tt = { flatbuffers::ST_TABLE, 2, type_codes, nullptr, nullptr, names }; return &tt; } inline const flatbuffers::TypeTable *UnaryOpTypeTable() { static const flatbuffers::TypeCode type_codes[] = { { flatbuffers::ET_INT, 0, 0 }, { flatbuffers::ET_INT, 0, 1 }, { flatbuffers::ET_CHAR, 1, -1 } }; static const flatbuffers::TypeFunction type_refs[] = { UnaryOpOperationTypeTable, DataTypeTypeTable }; static const char * const names[] = { "opType", "T", "tableInt8" }; static const flatbuffers::TypeTable tt = { flatbuffers::ST_TABLE, 3, type_codes, type_refs, nullptr, names }; return &tt; } inline const flatbuffers::TypeTable *TopKV2TypeTable() { static const flatbuffers::TypeCode type_codes[] = { { flatbuffers::ET_INT, 0, 0 }, { flatbuffers::ET_BOOL, 0, -1 }, { flatbuffers::ET_BOOL, 0, -1 } }; static const flatbuffers::TypeFunction type_refs[] = { DataTypeTypeTable }; static const char * const names[] = { "T", "sorted", "largest" }; static const flatbuffers::TypeTable tt = { flatbuffers::ST_TABLE, 3, type_codes, type_refs, nullptr, names }; return &tt; } inline const flatbuffers::TypeTable *CropAndResizeTypeTable() { static const flatbuffers::TypeCode type_codes[] = { { flatbuffers::ET_FLOAT, 0, -1 }, { flatbuffers::ET_CHAR, 0, 0 } }; static const flatbuffers::TypeFunction type_refs[] = { CropAndResizeMethodTypeTable }; static const char * const names[] = { "extrapolationValue", "method" }; static const flatbuffers::TypeTable tt = { flatbuffers::ST_TABLE, 2, type_codes, type_refs, nullptr, names }; return &tt; } inline const flatbuffers::TypeTable *FillTypeTable() { static const flatbuffers::TypeTable tt = { flatbuffers::ST_TABLE, 0, nullptr, nullptr, nullptr, nullptr }; return &tt; } inline const flatbuffers::TypeTable *GatherV2TypeTable() { static const flatbuffers::TypeCode type_codes[] = { { flatbuffers::ET_INT, 0, 0 }, { flatbuffers::ET_INT, 0, 0 }, { flatbuffers::ET_INT, 0, 0 } }; static const flatbuffers::TypeFunction type_refs[] = { DataTypeTypeTable }; static const char * const names[] = { "Taxis", "Tindices", "Tparams" }; static const flatbuffers::TypeTable tt = { flatbuffers::ST_TABLE, 3, type_codes, type_refs, nullptr, names }; return &tt; } inline const flatbuffers::TypeTable *NonMaxSuppressionV2TypeTable() { static const flatbuffers::TypeTable tt = { flatbuffers::ST_TABLE, 0, nullptr, nullptr, nullptr, nullptr }; return &tt; } inline const flatbuffers::TypeTable *RangeTypeTable() { static const flatbuffers::TypeCode type_codes[] = { { flatbuffers::ET_INT, 0, 0 } }; static const flatbuffers::TypeFunction type_refs[] = { DataTypeTypeTable }; static const char * const names[] = { "Tidx" }; static const flatbuffers::TypeTable tt = { flatbuffers::ST_TABLE, 1, type_codes, type_refs, nullptr, names }; return &tt; } inline const flatbuffers::TypeTable *RankTypeTable() { static const flatbuffers::TypeTable tt = { flatbuffers::ST_TABLE, 0, nullptr, nullptr, nullptr, nullptr }; return &tt; } inline const flatbuffers::TypeTable *SizeTypeTable() { static const flatbuffers::TypeCode type_codes[] = { { flatbuffers::ET_INT, 0, 0 } }; static const flatbuffers::TypeFunction type_refs[] = { DataTypeTypeTable }; static const char * const names[] = { "outputDataType" }; static const flatbuffers::TypeTable tt = { flatbuffers::ST_TABLE, 1, type_codes, type_refs, nullptr, names }; return &tt; } inline const flatbuffers::TypeTable *TransposeTypeTable() { static const flatbuffers::TypeCode type_codes[] = { { flatbuffers::ET_INT, 0, 0 } }; static const flatbuffers::TypeFunction type_refs[] = { DataTypeTypeTable }; static const char * const names[] = { "Tperm" }; static const flatbuffers::TypeTable tt = { flatbuffers::ST_TABLE, 1, type_codes, type_refs, nullptr, names }; return &tt; } inline const flatbuffers::TypeTable *SliceTfTypeTable() { static const flatbuffers::TypeCode type_codes[] = { { flatbuffers::ET_INT, 0, 0 } }; static const flatbuffers::TypeFunction type_refs[] = { DataTypeTypeTable }; static const char * const names[] = { "T" }; static const flatbuffers::TypeTable tt = { flatbuffers::ST_TABLE, 1, type_codes, type_refs, nullptr, names }; return &tt; } inline const flatbuffers::TypeTable *QuantizeMaxMinTypeTable() { static const flatbuffers::TypeCode type_codes[] = { { flatbuffers::ET_INT, 0, 0 } }; static const flatbuffers::TypeFunction type_refs[] = { DataTypeTypeTable }; static const char * const names[] = { "T" }; static const flatbuffers::TypeTable tt = { flatbuffers::ST_TABLE, 1, type_codes, type_refs, nullptr, names }; return &tt; } inline const flatbuffers::TypeTable *CropTypeTable() { static const flatbuffers::TypeCode type_codes[] = { { flatbuffers::ET_INT, 0, -1 }, { flatbuffers::ET_INT, 1, -1 } }; static const char * const names[] = { "axis", "offset" }; static const flatbuffers::TypeTable tt = { flatbuffers::ST_TABLE, 2, type_codes, nullptr, nullptr, names }; return &tt; } inline const flatbuffers::TypeTable *SpaceBatchTypeTable() { static const flatbuffers::TypeCode type_codes[] = { { flatbuffers::ET_SEQUENCE, 0, 0 }, { flatbuffers::ET_SEQUENCE, 0, 0 } }; static const flatbuffers::TypeFunction type_refs[] = { BlobTypeTable }; static const char * const names[] = { "blockShape", "padding" }; static const flatbuffers::TypeTable tt = { flatbuffers::ST_TABLE, 2, type_codes, type_refs, nullptr, names }; return &tt; } inline const flatbuffers::TypeTable *MatMulTypeTable() { static const flatbuffers::TypeCode type_codes[] = { { flatbuffers::ET_INT, 0, 0 }, { flatbuffers::ET_BOOL, 0, -1 }, { flatbuffers::ET_BOOL, 0, -1 }, { flatbuffers::ET_FLOAT, 1, -1 }, { flatbuffers::ET_FLOAT, 1, -1 } }; static const flatbuffers::TypeFunction type_refs[] = { DataTypeTypeTable }; static const char * const names[] = { "T", "transposeA", "transposeB", "weight", "bias" }; static const flatbuffers::TypeTable tt = { flatbuffers::ST_TABLE, 5, type_codes, type_refs, nullptr, names }; return &tt; } inline const flatbuffers::TypeTable *MomentsParamTypeTable() { static const flatbuffers::TypeCode type_codes[] = { { flatbuffers::ET_INT, 1, -1 }, { flatbuffers::ET_BOOL, 0, -1 }, { flatbuffers::ET_INT, 0, 0 } }; static const flatbuffers::TypeFunction type_refs[] = { DataTypeTypeTable }; static const char * const names[] = { "dim", "keepDims", "dType" }; static const flatbuffers::TypeTable tt = { flatbuffers::ST_TABLE, 3, type_codes, type_refs, nullptr, names }; return &tt; } inline const flatbuffers::TypeTable *RNNParamTypeTable() { static const flatbuffers::TypeCode type_codes[] = { { flatbuffers::ET_INT, 0, -1 }, { flatbuffers::ET_BOOL, 0, -1 }, { flatbuffers::ET_BOOL, 0, -1 }, { flatbuffers::ET_BOOL, 0, -1 }, { flatbuffers::ET_SEQUENCE, 0, 0 }, { flatbuffers::ET_SEQUENCE, 0, 0 }, { flatbuffers::ET_SEQUENCE, 0, 0 }, { flatbuffers::ET_SEQUENCE, 0, 0 }, { flatbuffers::ET_SEQUENCE, 0, 0 }, { flatbuffers::ET_SEQUENCE, 0, 0 }, { flatbuffers::ET_SEQUENCE, 0, 0 }, { flatbuffers::ET_SEQUENCE, 0, 0 }, { flatbuffers::ET_SEQUENCE, 0, 0 }, { flatbuffers::ET_SEQUENCE, 0, 0 } }; static const flatbuffers::TypeFunction type_refs[] = { BlobTypeTable }; static const char * const names[] = { "numUnits", "isBidirectionalRNN", "linearBeforeReset", "keepAllOutputs", "fwGateWeight", "fwGateBias", "fwCandidateWeight", "fwCandidateBias", "fwRecurrentBias", "bwGateWeight", "bwGateBias", "bwCandidateWeight", "bwCandidateBias", "bwRecurrentBias" }; static const flatbuffers::TypeTable tt = { flatbuffers::ST_TABLE, 14, type_codes, type_refs, nullptr, names }; return &tt; } inline const flatbuffers::TypeTable *BatchMatMulParamTypeTable() { static const flatbuffers::TypeCode type_codes[] = { { flatbuffers::ET_BOOL, 0, -1 }, { flatbuffers::ET_BOOL, 0, -1 } }; static const char * const names[] = { "adjX", "adjY" }; static const flatbuffers::TypeTable tt = { flatbuffers::ST_TABLE, 2, type_codes, nullptr, nullptr, names }; return &tt; } inline const flatbuffers::TypeTable *DepthSpaceParamTypeTable() { static const flatbuffers::TypeCode type_codes[] = { { flatbuffers::ET_INT, 0, -1 }, { flatbuffers::ET_CHAR, 0, 0 } }; static const flatbuffers::TypeFunction type_refs[] = { DepthToSpaceModeTypeTable }; static const char * const names[] = { "blockSize", "mode" }; static const flatbuffers::TypeTable tt = { flatbuffers::ST_TABLE, 2, type_codes, type_refs, nullptr, names }; return &tt; } inline const flatbuffers::TypeTable *ReverseSequenceParamTypeTable() { static const flatbuffers::TypeCode type_codes[] = { { flatbuffers::ET_INT, 0, -1 }, { flatbuffers::ET_INT, 0, -1 } }; static const char * const names[] = { "batchDim", "seqDim" }; static const flatbuffers::TypeTable tt = { flatbuffers::ST_TABLE, 2, type_codes, nullptr, nullptr, names }; return &tt; } inline const flatbuffers::TypeTable *DetectionPostProcessParamTypeTable() { static const flatbuffers::TypeCode type_codes[] = { { flatbuffers::ET_INT, 0, -1 }, { flatbuffers::ET_INT, 0, -1 }, { flatbuffers::ET_INT, 0, -1 }, { flatbuffers::ET_FLOAT, 0, -1 }, { flatbuffers::ET_FLOAT, 0, -1 }, { flatbuffers::ET_INT, 0, -1 }, { flatbuffers::ET_BOOL, 0, -1 }, { flatbuffers::ET_FLOAT, 1, -1 } }; static const char * const names[] = { "maxDetections", "maxClassesPerDetection", "detectionsPerClass", "nmsScoreThreshold", "iouThreshold", "numClasses", "useRegularNMS", "centerSizeEncoding" }; static const flatbuffers::TypeTable tt = { flatbuffers::ST_TABLE, 8, type_codes, nullptr, nullptr, names }; return &tt; } inline const flatbuffers::TypeTable *OneHotParamTypeTable() { static const flatbuffers::TypeCode type_codes[] = { { flatbuffers::ET_INT, 0, 0 }, { flatbuffers::ET_INT, 0, -1 } }; static const flatbuffers::TypeFunction type_refs[] = { DataTypeTypeTable }; static const char * const names[] = { "dType", "axis" }; static const flatbuffers::TypeTable tt = { flatbuffers::ST_TABLE, 2, type_codes, type_refs, nullptr, names }; return &tt; } inline const flatbuffers::TypeTable *PadParamTypeTable() { static const flatbuffers::TypeCode type_codes[] = { { flatbuffers::ET_CHAR, 0, 0 } }; static const flatbuffers::TypeFunction type_refs[] = { PadValueModeTypeTable }; static const char * const names[] = { "mode" }; static const flatbuffers::TypeTable tt = { flatbuffers::ST_TABLE, 1, type_codes, type_refs, nullptr, names }; return &tt; } inline const flatbuffers::TypeTable *LayerNormTypeTable() { static const flatbuffers::TypeCode type_codes[] = { { flatbuffers::ET_INT, 1, -1 }, { flatbuffers::ET_FLOAT, 0, -1 }, { flatbuffers::ET_FLOAT, 1, -1 }, { flatbuffers::ET_FLOAT, 1, -1 }, { flatbuffers::ET_INT, 0, -1 }, { flatbuffers::ET_LONG, 1, -1 }, { flatbuffers::ET_BOOL, 0, -1 } }; static const char * const names[] = { "axis", "epsilon", "gamma", "beta", "group", "external", "useRMSNorm" }; static const flatbuffers::TypeTable tt = { flatbuffers::ST_TABLE, 7, type_codes, nullptr, nullptr, names }; return &tt; } inline const flatbuffers::TypeTable *GroupNormTypeTable() { static const flatbuffers::TypeCode type_codes[] = { { flatbuffers::ET_INT, 0, -1 }, { flatbuffers::ET_FLOAT, 0, -1 }, { flatbuffers::ET_FLOAT, 1, -1 }, { flatbuffers::ET_FLOAT, 1, -1 }, { flatbuffers::ET_INT, 0, -1 }, { flatbuffers::ET_INT, 0, -1 }, { flatbuffers::ET_LONG, 1, -1 } }; static const char * const names[] = { "axis", "epsilon", "gamma", "beta", "group", "bSwish", "external" }; static const flatbuffers::TypeTable tt = { flatbuffers::ST_TABLE, 7, type_codes, nullptr, nullptr, names }; return &tt; } inline const flatbuffers::TypeTable *RandomUniformTypeTable() { static const flatbuffers::TypeCode type_codes[] = { { flatbuffers::ET_INT, 0, -1 }, { flatbuffers::ET_INT, 0, -1 }, { flatbuffers::ET_INT, 0, 0 }, { flatbuffers::ET_FLOAT, 0, -1 }, { flatbuffers::ET_FLOAT, 0, -1 } }; static const flatbuffers::TypeFunction type_refs[] = { DataTypeTypeTable }; static const char * const names[] = { "seed", "seed2", "type", "low", "high" }; static const flatbuffers::TypeTable tt = { flatbuffers::ST_TABLE, 5, type_codes, type_refs, nullptr, names }; return &tt; } inline const flatbuffers::TypeTable *TensorArrayTypeTable() { static const flatbuffers::TypeCode type_codes[] = { { flatbuffers::ET_BOOL, 0, -1 }, { flatbuffers::ET_BOOL, 0, -1 }, { flatbuffers::ET_INT, 1, -1 }, { flatbuffers::ET_INT, 0, 0 }, { flatbuffers::ET_INT, 0, -1 }, { flatbuffers::ET_BOOL, 0, -1 }, { flatbuffers::ET_BOOL, 0, -1 } }; static const flatbuffers::TypeFunction type_refs[] = { DataTypeTypeTable }; static const char * const names[] = { "dynamic_size", "identical_element_shapes", "element_shape", "T", "axis", "keepdims", "new_axis" }; static const flatbuffers::TypeTable tt = { flatbuffers::ST_TABLE, 7, type_codes, type_refs, nullptr, names }; return &tt; } inline const flatbuffers::TypeTable *LSTMBlockCellTypeTable() { static const flatbuffers::TypeCode type_codes[] = { { flatbuffers::ET_FLOAT, 0, -1 }, { flatbuffers::ET_FLOAT, 0, -1 }, { flatbuffers::ET_BOOL, 0, -1 } }; static const char * const names[] = { "cell_clip", "forget_bias", "use_peephole" }; static const flatbuffers::TypeTable tt = { flatbuffers::ST_TABLE, 3, type_codes, nullptr, nullptr, names }; return &tt; } } // namespace MNN #endif // FLATBUFFERS_GENERATED_TENSORFLOWOP_MNN_H_