// automatically generated by the FlatBuffers compiler, do not modify #ifndef FLATBUFFERS_GENERATED_TFQUANTIZEOP_MNN_H_ #define FLATBUFFERS_GENERATED_TFQUANTIZEOP_MNN_H_ #include "CaffeOp_generated.h" #include "Tensor_generated.h" #include "Type_generated.h" namespace MNN { struct QuantizedParam; struct QuantizedParamT; struct QuantizedAdd; struct QuantizedAddT; struct Dequantize; struct DequantizeT; struct QuantizedAvgPool; struct QuantizedAvgPoolT; struct QuantizedBiasAdd; struct QuantizedBiasAddT; struct QuantizedConcat; struct QuantizedConcatT; struct QuantizedLogistic; struct QuantizedLogisticT; struct QuantizedMatMul; struct QuantizedMatMulT; struct QuantizedMaxPool; struct QuantizedMaxPoolT; struct QuantizedRelu; struct QuantizedReluT; struct QuantizedRelu6; struct QuantizedRelu6T; struct QuantizedReshape; struct QuantizedReshapeT; struct QuantizedSoftmax; struct QuantizedSoftmaxT; struct QuantizeV2; struct QuantizeV2T; struct RequantizationRange; struct RequantizationRangeT; struct Requantize; struct RequantizeT; struct TfQuantizedConv2D; struct TfQuantizedConv2DT; inline const flatbuffers::TypeTable *QuantizedParamTypeTable(); inline const flatbuffers::TypeTable *QuantizedAddTypeTable(); inline const flatbuffers::TypeTable *DequantizeTypeTable(); inline const flatbuffers::TypeTable *QuantizedAvgPoolTypeTable(); inline const flatbuffers::TypeTable *QuantizedBiasAddTypeTable(); inline const flatbuffers::TypeTable *QuantizedConcatTypeTable(); inline const flatbuffers::TypeTable *QuantizedLogisticTypeTable(); inline const flatbuffers::TypeTable *QuantizedMatMulTypeTable(); inline const flatbuffers::TypeTable *QuantizedMaxPoolTypeTable(); inline const flatbuffers::TypeTable *QuantizedReluTypeTable(); inline const flatbuffers::TypeTable *QuantizedRelu6TypeTable(); inline const flatbuffers::TypeTable *QuantizedReshapeTypeTable(); inline const flatbuffers::TypeTable *QuantizedSoftmaxTypeTable(); inline const flatbuffers::TypeTable *QuantizeV2TypeTable(); inline const flatbuffers::TypeTable *RequantizationRangeTypeTable(); inline const flatbuffers::TypeTable *RequantizeTypeTable(); inline const flatbuffers::TypeTable *TfQuantizedConv2DTypeTable(); enum FusedActivation { FusedActivation_kTfLiteActNone = 0, FusedActivation_kTfLiteActRelu = 1, FusedActivation_kTfLiteActRelu1 = 2, FusedActivation_kTfLiteActRelu6 = 3, FusedActivation_kTfLiteActTanh = 4, FusedActivation_kTfLiteActSignBit = 5, FusedActivation_kTfLiteActSigmoid = 6, FusedActivation_MIN = FusedActivation_kTfLiteActNone, FusedActivation_MAX = FusedActivation_kTfLiteActSigmoid }; inline const FusedActivation (&EnumValuesFusedActivation())[7] { static const FusedActivation values[] = { FusedActivation_kTfLiteActNone, FusedActivation_kTfLiteActRelu, FusedActivation_kTfLiteActRelu1, FusedActivation_kTfLiteActRelu6, FusedActivation_kTfLiteActTanh, FusedActivation_kTfLiteActSignBit, FusedActivation_kTfLiteActSigmoid }; return values; } inline const char * const *EnumNamesFusedActivation() { static const char * const names[] = { "kTfLiteActNone", "kTfLiteActRelu", "kTfLiteActRelu1", "kTfLiteActRelu6", "kTfLiteActTanh", "kTfLiteActSignBit", "kTfLiteActSigmoid", nullptr }; return names; } inline const char *EnumNameFusedActivation(FusedActivation e) { if (e < FusedActivation_kTfLiteActNone || e > FusedActivation_kTfLiteActSigmoid) return ""; const size_t index = static_cast(e); return EnumNamesFusedActivation()[index]; } enum ModeFormat { ModeFormat_TENSORFLOW = 0, ModeFormat_TFLITE = 1, ModeFormat_MIN = ModeFormat_TENSORFLOW, ModeFormat_MAX = ModeFormat_TFLITE }; inline const ModeFormat (&EnumValuesModeFormat())[2] { static const ModeFormat values[] = { ModeFormat_TENSORFLOW, ModeFormat_TFLITE }; return values; } inline const char * const *EnumNamesModeFormat() { static const char * const names[] = { "TENSORFLOW", "TFLITE", nullptr }; return names; } inline const char *EnumNameModeFormat(ModeFormat e) { if (e < ModeFormat_TENSORFLOW || e > ModeFormat_TFLITE) return ""; const size_t index = static_cast(e); return EnumNamesModeFormat()[index]; } enum QuantizeMode { QuantizeMode_MIN_COMBINED = 0, QuantizeMode_MIN_FIRST = 1, QuantizeMode_SCALED = 2, QuantizeMode_MIN = QuantizeMode_MIN_COMBINED, QuantizeMode_MAX = QuantizeMode_SCALED }; inline const QuantizeMode (&EnumValuesQuantizeMode())[3] { static const QuantizeMode values[] = { QuantizeMode_MIN_COMBINED, QuantizeMode_MIN_FIRST, QuantizeMode_SCALED }; return values; } inline const char * const *EnumNamesQuantizeMode() { static const char * const names[] = { "MIN_COMBINED", "MIN_FIRST", "SCALED", nullptr }; return names; } inline const char *EnumNameQuantizeMode(QuantizeMode e) { if (e < QuantizeMode_MIN_COMBINED || e > QuantizeMode_SCALED) return ""; const size_t index = static_cast(e); return EnumNamesQuantizeMode()[index]; } enum QuantizeRoundMode { QuantizeRoundMode_HALF_AWAY_FROM_ZERO = 0, QuantizeRoundMode_HALF_TO_EVEN = 1, QuantizeRoundMode_MIN = QuantizeRoundMode_HALF_AWAY_FROM_ZERO, QuantizeRoundMode_MAX = QuantizeRoundMode_HALF_TO_EVEN }; inline const QuantizeRoundMode (&EnumValuesQuantizeRoundMode())[2] { static const QuantizeRoundMode values[] = { QuantizeRoundMode_HALF_AWAY_FROM_ZERO, QuantizeRoundMode_HALF_TO_EVEN }; return values; } inline const char * const *EnumNamesQuantizeRoundMode() { static const char * const names[] = { "HALF_AWAY_FROM_ZERO", "HALF_TO_EVEN", nullptr }; return names; } inline const char *EnumNameQuantizeRoundMode(QuantizeRoundMode e) { if (e < QuantizeRoundMode_HALF_AWAY_FROM_ZERO || e > QuantizeRoundMode_HALF_TO_EVEN) return ""; const size_t index = static_cast(e); return EnumNamesQuantizeRoundMode()[index]; } struct QuantizedParamT : public flatbuffers::NativeTable { typedef QuantizedParam TableType; int32_t zeroPoint; float scale; QuantizedParamT() : zeroPoint(0), scale(0.0f) { } }; struct QuantizedParam FLATBUFFERS_FINAL_CLASS : private flatbuffers::Table { typedef QuantizedParamT NativeTableType; static const flatbuffers::TypeTable *MiniReflectTypeTable() { return QuantizedParamTypeTable(); } int32_t zeroPoint() const { return GetField(4, 0); } float scale() const { return GetField(6, 0.0f); } bool Verify(flatbuffers::Verifier &verifier) const { return VerifyTableStart(verifier) && VerifyField(verifier, 4) && VerifyField(verifier, 6) && verifier.EndTable(); } QuantizedParamT *UnPack(const flatbuffers::resolver_function_t *_resolver = nullptr) const; void UnPackTo(QuantizedParamT *_o, const flatbuffers::resolver_function_t *_resolver = nullptr) const; static flatbuffers::Offset Pack(flatbuffers::FlatBufferBuilder &_fbb, const QuantizedParamT* _o, const flatbuffers::rehasher_function_t *_rehasher = nullptr); }; struct QuantizedParamBuilder { flatbuffers::FlatBufferBuilder &fbb_; flatbuffers::uoffset_t start_; void add_zeroPoint(int32_t zeroPoint) { fbb_.AddElement(4, zeroPoint, 0); } void add_scale(float scale) { fbb_.AddElement(6, scale, 0.0f); } explicit QuantizedParamBuilder(flatbuffers::FlatBufferBuilder &_fbb) : fbb_(_fbb) { start_ = fbb_.StartTable(); } QuantizedParamBuilder &operator=(const QuantizedParamBuilder &); flatbuffers::Offset Finish() { const auto end = fbb_.EndTable(start_); auto o = flatbuffers::Offset(end); return o; } }; inline flatbuffers::Offset CreateQuantizedParam( flatbuffers::FlatBufferBuilder &_fbb, int32_t zeroPoint = 0, float scale = 0.0f) { QuantizedParamBuilder builder_(_fbb); builder_.add_scale(scale); builder_.add_zeroPoint(zeroPoint); return builder_.Finish(); } flatbuffers::Offset CreateQuantizedParam(flatbuffers::FlatBufferBuilder &_fbb, const QuantizedParamT *_o, const flatbuffers::rehasher_function_t *_rehasher = nullptr); struct QuantizedAddT : public flatbuffers::NativeTable { typedef QuantizedAdd TableType; FusedActivation activationType; std::unique_ptr input1QuantizedParam; std::unique_ptr input2QuantizedParam; std::unique_ptr outputQuantizedParam; QuantizedAddT() : activationType(FusedActivation_kTfLiteActNone) { } }; struct QuantizedAdd FLATBUFFERS_FINAL_CLASS : private flatbuffers::Table { typedef QuantizedAddT NativeTableType; static const flatbuffers::TypeTable *MiniReflectTypeTable() { return QuantizedAddTypeTable(); } FusedActivation activationType() const { return static_cast(GetField(4, 0)); } const QuantizedParam *input1QuantizedParam() const { return GetPointer(6); } const QuantizedParam *input2QuantizedParam() const { return GetPointer(8); } const QuantizedParam *outputQuantizedParam() const { return GetPointer(10); } bool Verify(flatbuffers::Verifier &verifier) const { return VerifyTableStart(verifier) && VerifyField(verifier, 4) && VerifyOffset(verifier, 6) && verifier.VerifyTable(input1QuantizedParam()) && VerifyOffset(verifier, 8) && verifier.VerifyTable(input2QuantizedParam()) && VerifyOffset(verifier, 10) && verifier.VerifyTable(outputQuantizedParam()) && verifier.EndTable(); } QuantizedAddT *UnPack(const flatbuffers::resolver_function_t *_resolver = nullptr) const; void UnPackTo(QuantizedAddT *_o, const flatbuffers::resolver_function_t *_resolver = nullptr) const; static flatbuffers::Offset Pack(flatbuffers::FlatBufferBuilder &_fbb, const QuantizedAddT* _o, const flatbuffers::rehasher_function_t *_rehasher = nullptr); }; struct QuantizedAddBuilder { flatbuffers::FlatBufferBuilder &fbb_; flatbuffers::uoffset_t start_; void add_activationType(FusedActivation activationType) { fbb_.AddElement(4, static_cast(activationType), 0); } void add_input1QuantizedParam(flatbuffers::Offset input1QuantizedParam) { fbb_.AddOffset(6, input1QuantizedParam); } void add_input2QuantizedParam(flatbuffers::Offset input2QuantizedParam) { fbb_.AddOffset(8, input2QuantizedParam); } void add_outputQuantizedParam(flatbuffers::Offset outputQuantizedParam) { fbb_.AddOffset(10, outputQuantizedParam); } explicit QuantizedAddBuilder(flatbuffers::FlatBufferBuilder &_fbb) : fbb_(_fbb) { start_ = fbb_.StartTable(); } QuantizedAddBuilder &operator=(const QuantizedAddBuilder &); flatbuffers::Offset Finish() { const auto end = fbb_.EndTable(start_); auto o = flatbuffers::Offset(end); return o; } }; inline flatbuffers::Offset CreateQuantizedAdd( flatbuffers::FlatBufferBuilder &_fbb, FusedActivation activationType = FusedActivation_kTfLiteActNone, flatbuffers::Offset input1QuantizedParam = 0, flatbuffers::Offset input2QuantizedParam = 0, flatbuffers::Offset outputQuantizedParam = 0) { QuantizedAddBuilder builder_(_fbb); builder_.add_outputQuantizedParam(outputQuantizedParam); builder_.add_input2QuantizedParam(input2QuantizedParam); builder_.add_input1QuantizedParam(input1QuantizedParam); builder_.add_activationType(activationType); return builder_.Finish(); } flatbuffers::Offset CreateQuantizedAdd(flatbuffers::FlatBufferBuilder &_fbb, const QuantizedAddT *_o, const flatbuffers::rehasher_function_t *_rehasher = nullptr); struct DequantizeT : public flatbuffers::NativeTable { typedef Dequantize TableType; std::unique_ptr inputQuantizedParam; QuantizeMode mode; ModeFormat modelFormat; DataType type; DequantizeT() : mode(QuantizeMode_MIN_COMBINED), modelFormat(ModeFormat_TENSORFLOW), type(DataType_DT_INVALID) { } }; struct Dequantize FLATBUFFERS_FINAL_CLASS : private flatbuffers::Table { typedef DequantizeT NativeTableType; static const flatbuffers::TypeTable *MiniReflectTypeTable() { return DequantizeTypeTable(); } const QuantizedParam *inputQuantizedParam() const { return GetPointer(4); } QuantizeMode mode() const { return static_cast(GetField(6, 0)); } ModeFormat modelFormat() const { return static_cast(GetField(8, 0)); } DataType type() const { return static_cast(GetField(10, 0)); } bool Verify(flatbuffers::Verifier &verifier) const { return VerifyTableStart(verifier) && VerifyOffset(verifier, 4) && verifier.VerifyTable(inputQuantizedParam()) && VerifyField(verifier, 6) && VerifyField(verifier, 8) && VerifyField(verifier, 10) && verifier.EndTable(); } DequantizeT *UnPack(const flatbuffers::resolver_function_t *_resolver = nullptr) const; void UnPackTo(DequantizeT *_o, const flatbuffers::resolver_function_t *_resolver = nullptr) const; static flatbuffers::Offset Pack(flatbuffers::FlatBufferBuilder &_fbb, const DequantizeT* _o, const flatbuffers::rehasher_function_t *_rehasher = nullptr); }; struct DequantizeBuilder { flatbuffers::FlatBufferBuilder &fbb_; flatbuffers::uoffset_t start_; void add_inputQuantizedParam(flatbuffers::Offset inputQuantizedParam) { fbb_.AddOffset(4, inputQuantizedParam); } void add_mode(QuantizeMode mode) { fbb_.AddElement(6, static_cast(mode), 0); } void add_modelFormat(ModeFormat modelFormat) { fbb_.AddElement(8, static_cast(modelFormat), 0); } void add_type(DataType type) { fbb_.AddElement(10, static_cast(type), 0); } explicit DequantizeBuilder(flatbuffers::FlatBufferBuilder &_fbb) : fbb_(_fbb) { start_ = fbb_.StartTable(); } DequantizeBuilder &operator=(const DequantizeBuilder &); flatbuffers::Offset Finish() { const auto end = fbb_.EndTable(start_); auto o = flatbuffers::Offset(end); return o; } }; inline flatbuffers::Offset CreateDequantize( flatbuffers::FlatBufferBuilder &_fbb, flatbuffers::Offset inputQuantizedParam = 0, QuantizeMode mode = QuantizeMode_MIN_COMBINED, ModeFormat modelFormat = ModeFormat_TENSORFLOW, DataType type = DataType_DT_INVALID) { DequantizeBuilder builder_(_fbb); builder_.add_type(type); builder_.add_inputQuantizedParam(inputQuantizedParam); builder_.add_modelFormat(modelFormat); builder_.add_mode(mode); return builder_.Finish(); } flatbuffers::Offset CreateDequantize(flatbuffers::FlatBufferBuilder &_fbb, const DequantizeT *_o, const flatbuffers::rehasher_function_t *_rehasher = nullptr); struct QuantizedAvgPoolT : public flatbuffers::NativeTable { typedef QuantizedAvgPool TableType; int32_t kernelX; int32_t kernelY; ModeFormat modelFormat; int32_t outputActivationMax; int32_t outputActivationMin; PoolPadType padType; int32_t padX; int32_t padY; int32_t strideX; int32_t strideY; DataType type; QuantizedAvgPoolT() : kernelX(0), kernelY(0), modelFormat(ModeFormat_TENSORFLOW), outputActivationMax(0), outputActivationMin(0), padType(PoolPadType_CAFFE), padX(0), padY(0), strideX(0), strideY(0), type(DataType_DT_INVALID) { } }; struct QuantizedAvgPool FLATBUFFERS_FINAL_CLASS : private flatbuffers::Table { typedef QuantizedAvgPoolT NativeTableType; static const flatbuffers::TypeTable *MiniReflectTypeTable() { return QuantizedAvgPoolTypeTable(); } int32_t kernelX() const { return GetField(4, 0); } int32_t kernelY() const { return GetField(6, 0); } ModeFormat modelFormat() const { return static_cast(GetField(8, 0)); } int32_t outputActivationMax() const { return GetField(10, 0); } int32_t outputActivationMin() const { return GetField(12, 0); } PoolPadType padType() const { return static_cast(GetField(14, 0)); } int32_t padX() const { return GetField(16, 0); } int32_t padY() const { return GetField(18, 0); } int32_t strideX() const { return GetField(20, 0); } int32_t strideY() const { return GetField(22, 0); } DataType type() const { return static_cast(GetField(24, 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) && VerifyField(verifier, 20) && VerifyField(verifier, 22) && VerifyField(verifier, 24) && verifier.EndTable(); } QuantizedAvgPoolT *UnPack(const flatbuffers::resolver_function_t *_resolver = nullptr) const; void UnPackTo(QuantizedAvgPoolT *_o, const flatbuffers::resolver_function_t *_resolver = nullptr) const; static flatbuffers::Offset Pack(flatbuffers::FlatBufferBuilder &_fbb, const QuantizedAvgPoolT* _o, const flatbuffers::rehasher_function_t *_rehasher = nullptr); }; struct QuantizedAvgPoolBuilder { flatbuffers::FlatBufferBuilder &fbb_; flatbuffers::uoffset_t start_; void add_kernelX(int32_t kernelX) { fbb_.AddElement(4, kernelX, 0); } void add_kernelY(int32_t kernelY) { fbb_.AddElement(6, kernelY, 0); } void add_modelFormat(ModeFormat modelFormat) { fbb_.AddElement(8, static_cast(modelFormat), 0); } void add_outputActivationMax(int32_t outputActivationMax) { fbb_.AddElement(10, outputActivationMax, 0); } void add_outputActivationMin(int32_t outputActivationMin) { fbb_.AddElement(12, outputActivationMin, 0); } void add_padType(PoolPadType padType) { fbb_.AddElement(14, static_cast(padType), 0); } void add_padX(int32_t padX) { fbb_.AddElement(16, padX, 0); } void add_padY(int32_t padY) { fbb_.AddElement(18, padY, 0); } void add_strideX(int32_t strideX) { fbb_.AddElement(20, strideX, 0); } void add_strideY(int32_t strideY) { fbb_.AddElement(22, strideY, 0); } void add_type(DataType type) { fbb_.AddElement(24, static_cast(type), 0); } explicit QuantizedAvgPoolBuilder(flatbuffers::FlatBufferBuilder &_fbb) : fbb_(_fbb) { start_ = fbb_.StartTable(); } QuantizedAvgPoolBuilder &operator=(const QuantizedAvgPoolBuilder &); flatbuffers::Offset Finish() { const auto end = fbb_.EndTable(start_); auto o = flatbuffers::Offset(end); return o; } }; inline flatbuffers::Offset CreateQuantizedAvgPool( flatbuffers::FlatBufferBuilder &_fbb, int32_t kernelX = 0, int32_t kernelY = 0, ModeFormat modelFormat = ModeFormat_TENSORFLOW, int32_t outputActivationMax = 0, int32_t outputActivationMin = 0, PoolPadType padType = PoolPadType_CAFFE, int32_t padX = 0, int32_t padY = 0, int32_t strideX = 0, int32_t strideY = 0, DataType type = DataType_DT_INVALID) { QuantizedAvgPoolBuilder builder_(_fbb); builder_.add_type(type); builder_.add_strideY(strideY); builder_.add_strideX(strideX); builder_.add_padY(padY); builder_.add_padX(padX); builder_.add_outputActivationMin(outputActivationMin); builder_.add_outputActivationMax(outputActivationMax); builder_.add_kernelY(kernelY); builder_.add_kernelX(kernelX); builder_.add_padType(padType); builder_.add_modelFormat(modelFormat); return builder_.Finish(); } flatbuffers::Offset CreateQuantizedAvgPool(flatbuffers::FlatBufferBuilder &_fbb, const QuantizedAvgPoolT *_o, const flatbuffers::rehasher_function_t *_rehasher = nullptr); struct QuantizedBiasAddT : public flatbuffers::NativeTable { typedef QuantizedBiasAdd TableType; std::vector bias; DataType inputType; int32_t max; int32_t min; DataType outputType; QuantizedBiasAddT() : inputType(DataType_DT_INVALID), max(0), min(0), outputType(DataType_DT_INVALID) { } }; struct QuantizedBiasAdd FLATBUFFERS_FINAL_CLASS : private flatbuffers::Table { typedef QuantizedBiasAddT NativeTableType; static const flatbuffers::TypeTable *MiniReflectTypeTable() { return QuantizedBiasAddTypeTable(); } const flatbuffers::Vector *bias() const { return GetPointer *>(4); } DataType inputType() const { return static_cast(GetField(6, 0)); } int32_t max() const { return GetField(8, 0); } int32_t min() const { return GetField(10, 0); } DataType outputType() const { return static_cast(GetField(12, 0)); } bool Verify(flatbuffers::Verifier &verifier) const { return VerifyTableStart(verifier) && VerifyOffset(verifier, 4) && verifier.VerifyVector(bias()) && VerifyField(verifier, 6) && VerifyField(verifier, 8) && VerifyField(verifier, 10) && VerifyField(verifier, 12) && verifier.EndTable(); } QuantizedBiasAddT *UnPack(const flatbuffers::resolver_function_t *_resolver = nullptr) const; void UnPackTo(QuantizedBiasAddT *_o, const flatbuffers::resolver_function_t *_resolver = nullptr) const; static flatbuffers::Offset Pack(flatbuffers::FlatBufferBuilder &_fbb, const QuantizedBiasAddT* _o, const flatbuffers::rehasher_function_t *_rehasher = nullptr); }; struct QuantizedBiasAddBuilder { flatbuffers::FlatBufferBuilder &fbb_; flatbuffers::uoffset_t start_; void add_bias(flatbuffers::Offset> bias) { fbb_.AddOffset(4, bias); } void add_inputType(DataType inputType) { fbb_.AddElement(6, static_cast(inputType), 0); } void add_max(int32_t max) { fbb_.AddElement(8, max, 0); } void add_min(int32_t min) { fbb_.AddElement(10, min, 0); } void add_outputType(DataType outputType) { fbb_.AddElement(12, static_cast(outputType), 0); } explicit QuantizedBiasAddBuilder(flatbuffers::FlatBufferBuilder &_fbb) : fbb_(_fbb) { start_ = fbb_.StartTable(); } QuantizedBiasAddBuilder &operator=(const QuantizedBiasAddBuilder &); flatbuffers::Offset Finish() { const auto end = fbb_.EndTable(start_); auto o = flatbuffers::Offset(end); return o; } }; inline flatbuffers::Offset CreateQuantizedBiasAdd( flatbuffers::FlatBufferBuilder &_fbb, flatbuffers::Offset> bias = 0, DataType inputType = DataType_DT_INVALID, int32_t max = 0, int32_t min = 0, DataType outputType = DataType_DT_INVALID) { QuantizedBiasAddBuilder builder_(_fbb); builder_.add_outputType(outputType); builder_.add_min(min); builder_.add_max(max); builder_.add_inputType(inputType); builder_.add_bias(bias); return builder_.Finish(); } flatbuffers::Offset CreateQuantizedBiasAdd(flatbuffers::FlatBufferBuilder &_fbb, const QuantizedBiasAddT *_o, const flatbuffers::rehasher_function_t *_rehasher = nullptr); struct QuantizedConcatT : public flatbuffers::NativeTable { typedef QuantizedConcat TableType; FusedActivation activationType; int32_t axis; std::vector inputScale; std::vector inputZeroPoint; std::unique_ptr outputQuantizedParam; QuantizedConcatT() : activationType(FusedActivation_kTfLiteActNone), axis(0) { } }; struct QuantizedConcat FLATBUFFERS_FINAL_CLASS : private flatbuffers::Table { typedef QuantizedConcatT NativeTableType; static const flatbuffers::TypeTable *MiniReflectTypeTable() { return QuantizedConcatTypeTable(); } FusedActivation activationType() const { return static_cast(GetField(4, 0)); } int32_t axis() const { return GetField(6, 0); } const flatbuffers::Vector *inputScale() const { return GetPointer *>(8); } const flatbuffers::Vector *inputZeroPoint() const { return GetPointer *>(10); } const QuantizedParam *outputQuantizedParam() const { return GetPointer(12); } bool Verify(flatbuffers::Verifier &verifier) const { return VerifyTableStart(verifier) && VerifyField(verifier, 4) && VerifyField(verifier, 6) && VerifyOffset(verifier, 8) && verifier.VerifyVector(inputScale()) && VerifyOffset(verifier, 10) && verifier.VerifyVector(inputZeroPoint()) && VerifyOffset(verifier, 12) && verifier.VerifyTable(outputQuantizedParam()) && verifier.EndTable(); } QuantizedConcatT *UnPack(const flatbuffers::resolver_function_t *_resolver = nullptr) const; void UnPackTo(QuantizedConcatT *_o, const flatbuffers::resolver_function_t *_resolver = nullptr) const; static flatbuffers::Offset Pack(flatbuffers::FlatBufferBuilder &_fbb, const QuantizedConcatT* _o, const flatbuffers::rehasher_function_t *_rehasher = nullptr); }; struct QuantizedConcatBuilder { flatbuffers::FlatBufferBuilder &fbb_; flatbuffers::uoffset_t start_; void add_activationType(FusedActivation activationType) { fbb_.AddElement(4, static_cast(activationType), 0); } void add_axis(int32_t axis) { fbb_.AddElement(6, axis, 0); } void add_inputScale(flatbuffers::Offset> inputScale) { fbb_.AddOffset(8, inputScale); } void add_inputZeroPoint(flatbuffers::Offset> inputZeroPoint) { fbb_.AddOffset(10, inputZeroPoint); } void add_outputQuantizedParam(flatbuffers::Offset outputQuantizedParam) { fbb_.AddOffset(12, outputQuantizedParam); } explicit QuantizedConcatBuilder(flatbuffers::FlatBufferBuilder &_fbb) : fbb_(_fbb) { start_ = fbb_.StartTable(); } QuantizedConcatBuilder &operator=(const QuantizedConcatBuilder &); flatbuffers::Offset Finish() { const auto end = fbb_.EndTable(start_); auto o = flatbuffers::Offset(end); return o; } }; inline flatbuffers::Offset CreateQuantizedConcat( flatbuffers::FlatBufferBuilder &_fbb, FusedActivation activationType = FusedActivation_kTfLiteActNone, int32_t axis = 0, flatbuffers::Offset> inputScale = 0, flatbuffers::Offset> inputZeroPoint = 0, flatbuffers::Offset outputQuantizedParam = 0) { QuantizedConcatBuilder builder_(_fbb); builder_.add_outputQuantizedParam(outputQuantizedParam); builder_.add_inputZeroPoint(inputZeroPoint); builder_.add_inputScale(inputScale); builder_.add_axis(axis); builder_.add_activationType(activationType); return builder_.Finish(); } flatbuffers::Offset CreateQuantizedConcat(flatbuffers::FlatBufferBuilder &_fbb, const QuantizedConcatT *_o, const flatbuffers::rehasher_function_t *_rehasher = nullptr); struct QuantizedLogisticT : public flatbuffers::NativeTable { typedef QuantizedLogistic TableType; std::unique_ptr inputQuantizedParam; std::unique_ptr outputQuantizedParam; QuantizedLogisticT() { } }; struct QuantizedLogistic FLATBUFFERS_FINAL_CLASS : private flatbuffers::Table { typedef QuantizedLogisticT NativeTableType; static const flatbuffers::TypeTable *MiniReflectTypeTable() { return QuantizedLogisticTypeTable(); } const QuantizedParam *inputQuantizedParam() const { return GetPointer(4); } const QuantizedParam *outputQuantizedParam() const { return GetPointer(6); } bool Verify(flatbuffers::Verifier &verifier) const { return VerifyTableStart(verifier) && VerifyOffset(verifier, 4) && verifier.VerifyTable(inputQuantizedParam()) && VerifyOffset(verifier, 6) && verifier.VerifyTable(outputQuantizedParam()) && verifier.EndTable(); } QuantizedLogisticT *UnPack(const flatbuffers::resolver_function_t *_resolver = nullptr) const; void UnPackTo(QuantizedLogisticT *_o, const flatbuffers::resolver_function_t *_resolver = nullptr) const; static flatbuffers::Offset Pack(flatbuffers::FlatBufferBuilder &_fbb, const QuantizedLogisticT* _o, const flatbuffers::rehasher_function_t *_rehasher = nullptr); }; struct QuantizedLogisticBuilder { flatbuffers::FlatBufferBuilder &fbb_; flatbuffers::uoffset_t start_; void add_inputQuantizedParam(flatbuffers::Offset inputQuantizedParam) { fbb_.AddOffset(4, inputQuantizedParam); } void add_outputQuantizedParam(flatbuffers::Offset outputQuantizedParam) { fbb_.AddOffset(6, outputQuantizedParam); } explicit QuantizedLogisticBuilder(flatbuffers::FlatBufferBuilder &_fbb) : fbb_(_fbb) { start_ = fbb_.StartTable(); } QuantizedLogisticBuilder &operator=(const QuantizedLogisticBuilder &); flatbuffers::Offset Finish() { const auto end = fbb_.EndTable(start_); auto o = flatbuffers::Offset(end); return o; } }; inline flatbuffers::Offset CreateQuantizedLogistic( flatbuffers::FlatBufferBuilder &_fbb, flatbuffers::Offset inputQuantizedParam = 0, flatbuffers::Offset outputQuantizedParam = 0) { QuantizedLogisticBuilder builder_(_fbb); builder_.add_outputQuantizedParam(outputQuantizedParam); builder_.add_inputQuantizedParam(inputQuantizedParam); return builder_.Finish(); } flatbuffers::Offset CreateQuantizedLogistic(flatbuffers::FlatBufferBuilder &_fbb, const QuantizedLogisticT *_o, const flatbuffers::rehasher_function_t *_rehasher = nullptr); struct QuantizedMatMulT : public flatbuffers::NativeTable { typedef QuantizedMatMul TableType; bool transposeA; bool transposeB; QuantizedMatMulT() : transposeA(false), transposeB(false) { } }; struct QuantizedMatMul FLATBUFFERS_FINAL_CLASS : private flatbuffers::Table { typedef QuantizedMatMulT NativeTableType; static const flatbuffers::TypeTable *MiniReflectTypeTable() { return QuantizedMatMulTypeTable(); } bool transposeA() const { return GetField(4, 0) != 0; } bool transposeB() const { return GetField(6, 0) != 0; } bool Verify(flatbuffers::Verifier &verifier) const { return VerifyTableStart(verifier) && VerifyField(verifier, 4) && VerifyField(verifier, 6) && verifier.EndTable(); } QuantizedMatMulT *UnPack(const flatbuffers::resolver_function_t *_resolver = nullptr) const; void UnPackTo(QuantizedMatMulT *_o, const flatbuffers::resolver_function_t *_resolver = nullptr) const; static flatbuffers::Offset Pack(flatbuffers::FlatBufferBuilder &_fbb, const QuantizedMatMulT* _o, const flatbuffers::rehasher_function_t *_rehasher = nullptr); }; struct QuantizedMatMulBuilder { flatbuffers::FlatBufferBuilder &fbb_; flatbuffers::uoffset_t start_; void add_transposeA(bool transposeA) { fbb_.AddElement(4, static_cast(transposeA), 0); } void add_transposeB(bool transposeB) { fbb_.AddElement(6, static_cast(transposeB), 0); } explicit QuantizedMatMulBuilder(flatbuffers::FlatBufferBuilder &_fbb) : fbb_(_fbb) { start_ = fbb_.StartTable(); } QuantizedMatMulBuilder &operator=(const QuantizedMatMulBuilder &); flatbuffers::Offset Finish() { const auto end = fbb_.EndTable(start_); auto o = flatbuffers::Offset(end); return o; } }; inline flatbuffers::Offset CreateQuantizedMatMul( flatbuffers::FlatBufferBuilder &_fbb, bool transposeA = false, bool transposeB = false) { QuantizedMatMulBuilder builder_(_fbb); builder_.add_transposeB(transposeB); builder_.add_transposeA(transposeA); return builder_.Finish(); } flatbuffers::Offset CreateQuantizedMatMul(flatbuffers::FlatBufferBuilder &_fbb, const QuantizedMatMulT *_o, const flatbuffers::rehasher_function_t *_rehasher = nullptr); struct QuantizedMaxPoolT : public flatbuffers::NativeTable { typedef QuantizedMaxPool TableType; int32_t kernelX; int32_t kernelY; ModeFormat modelFormat; int32_t outputActivationMax; int32_t outputActivationMin; PoolPadType padType; int32_t padX; int32_t padY; int32_t strideX; int32_t strideY; DataType type; QuantizedMaxPoolT() : kernelX(0), kernelY(0), modelFormat(ModeFormat_TENSORFLOW), outputActivationMax(0), outputActivationMin(0), padType(PoolPadType_CAFFE), padX(0), padY(0), strideX(0), strideY(0), type(DataType_DT_INVALID) { } }; struct QuantizedMaxPool FLATBUFFERS_FINAL_CLASS : private flatbuffers::Table { typedef QuantizedMaxPoolT NativeTableType; static const flatbuffers::TypeTable *MiniReflectTypeTable() { return QuantizedMaxPoolTypeTable(); } int32_t kernelX() const { return GetField(4, 0); } int32_t kernelY() const { return GetField(6, 0); } ModeFormat modelFormat() const { return static_cast(GetField(8, 0)); } int32_t outputActivationMax() const { return GetField(10, 0); } int32_t outputActivationMin() const { return GetField(12, 0); } PoolPadType padType() const { return static_cast(GetField(14, 0)); } int32_t padX() const { return GetField(16, 0); } int32_t padY() const { return GetField(18, 0); } int32_t strideX() const { return GetField(20, 0); } int32_t strideY() const { return GetField(22, 0); } DataType type() const { return static_cast(GetField(24, 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) && VerifyField(verifier, 20) && VerifyField(verifier, 22) && VerifyField(verifier, 24) && verifier.EndTable(); } QuantizedMaxPoolT *UnPack(const flatbuffers::resolver_function_t *_resolver = nullptr) const; void UnPackTo(QuantizedMaxPoolT *_o, const flatbuffers::resolver_function_t *_resolver = nullptr) const; static flatbuffers::Offset Pack(flatbuffers::FlatBufferBuilder &_fbb, const QuantizedMaxPoolT* _o, const flatbuffers::rehasher_function_t *_rehasher = nullptr); }; struct QuantizedMaxPoolBuilder { flatbuffers::FlatBufferBuilder &fbb_; flatbuffers::uoffset_t start_; void add_kernelX(int32_t kernelX) { fbb_.AddElement(4, kernelX, 0); } void add_kernelY(int32_t kernelY) { fbb_.AddElement(6, kernelY, 0); } void add_modelFormat(ModeFormat modelFormat) { fbb_.AddElement(8, static_cast(modelFormat), 0); } void add_outputActivationMax(int32_t outputActivationMax) { fbb_.AddElement(10, outputActivationMax, 0); } void add_outputActivationMin(int32_t outputActivationMin) { fbb_.AddElement(12, outputActivationMin, 0); } void add_padType(PoolPadType padType) { fbb_.AddElement(14, static_cast(padType), 0); } void add_padX(int32_t padX) { fbb_.AddElement(16, padX, 0); } void add_padY(int32_t padY) { fbb_.AddElement(18, padY, 0); } void add_strideX(int32_t strideX) { fbb_.AddElement(20, strideX, 0); } void add_strideY(int32_t strideY) { fbb_.AddElement(22, strideY, 0); } void add_type(DataType type) { fbb_.AddElement(24, static_cast(type), 0); } explicit QuantizedMaxPoolBuilder(flatbuffers::FlatBufferBuilder &_fbb) : fbb_(_fbb) { start_ = fbb_.StartTable(); } QuantizedMaxPoolBuilder &operator=(const QuantizedMaxPoolBuilder &); flatbuffers::Offset Finish() { const auto end = fbb_.EndTable(start_); auto o = flatbuffers::Offset(end); return o; } }; inline flatbuffers::Offset CreateQuantizedMaxPool( flatbuffers::FlatBufferBuilder &_fbb, int32_t kernelX = 0, int32_t kernelY = 0, ModeFormat modelFormat = ModeFormat_TENSORFLOW, int32_t outputActivationMax = 0, int32_t outputActivationMin = 0, PoolPadType padType = PoolPadType_CAFFE, int32_t padX = 0, int32_t padY = 0, int32_t strideX = 0, int32_t strideY = 0, DataType type = DataType_DT_INVALID) { QuantizedMaxPoolBuilder builder_(_fbb); builder_.add_type(type); builder_.add_strideY(strideY); builder_.add_strideX(strideX); builder_.add_padY(padY); builder_.add_padX(padX); builder_.add_outputActivationMin(outputActivationMin); builder_.add_outputActivationMax(outputActivationMax); builder_.add_kernelY(kernelY); builder_.add_kernelX(kernelX); builder_.add_padType(padType); builder_.add_modelFormat(modelFormat); return builder_.Finish(); } flatbuffers::Offset CreateQuantizedMaxPool(flatbuffers::FlatBufferBuilder &_fbb, const QuantizedMaxPoolT *_o, const flatbuffers::rehasher_function_t *_rehasher = nullptr); struct QuantizedReluT : public flatbuffers::NativeTable { typedef QuantizedRelu TableType; DataType type; QuantizedReluT() : type(DataType_DT_INVALID) { } }; struct QuantizedRelu FLATBUFFERS_FINAL_CLASS : private flatbuffers::Table { typedef QuantizedReluT NativeTableType; static const flatbuffers::TypeTable *MiniReflectTypeTable() { return QuantizedReluTypeTable(); } DataType type() const { return static_cast(GetField(4, 0)); } bool Verify(flatbuffers::Verifier &verifier) const { return VerifyTableStart(verifier) && VerifyField(verifier, 4) && verifier.EndTable(); } QuantizedReluT *UnPack(const flatbuffers::resolver_function_t *_resolver = nullptr) const; void UnPackTo(QuantizedReluT *_o, const flatbuffers::resolver_function_t *_resolver = nullptr) const; static flatbuffers::Offset Pack(flatbuffers::FlatBufferBuilder &_fbb, const QuantizedReluT* _o, const flatbuffers::rehasher_function_t *_rehasher = nullptr); }; struct QuantizedReluBuilder { flatbuffers::FlatBufferBuilder &fbb_; flatbuffers::uoffset_t start_; void add_type(DataType type) { fbb_.AddElement(4, static_cast(type), 0); } explicit QuantizedReluBuilder(flatbuffers::FlatBufferBuilder &_fbb) : fbb_(_fbb) { start_ = fbb_.StartTable(); } QuantizedReluBuilder &operator=(const QuantizedReluBuilder &); flatbuffers::Offset Finish() { const auto end = fbb_.EndTable(start_); auto o = flatbuffers::Offset(end); return o; } }; inline flatbuffers::Offset CreateQuantizedRelu( flatbuffers::FlatBufferBuilder &_fbb, DataType type = DataType_DT_INVALID) { QuantizedReluBuilder builder_(_fbb); builder_.add_type(type); return builder_.Finish(); } flatbuffers::Offset CreateQuantizedRelu(flatbuffers::FlatBufferBuilder &_fbb, const QuantizedReluT *_o, const flatbuffers::rehasher_function_t *_rehasher = nullptr); struct QuantizedRelu6T : public flatbuffers::NativeTable { typedef QuantizedRelu6 TableType; DataType type; QuantizedRelu6T() : type(DataType_DT_INVALID) { } }; struct QuantizedRelu6 FLATBUFFERS_FINAL_CLASS : private flatbuffers::Table { typedef QuantizedRelu6T NativeTableType; static const flatbuffers::TypeTable *MiniReflectTypeTable() { return QuantizedRelu6TypeTable(); } DataType type() const { return static_cast(GetField(4, 0)); } bool Verify(flatbuffers::Verifier &verifier) const { return VerifyTableStart(verifier) && VerifyField(verifier, 4) && verifier.EndTable(); } QuantizedRelu6T *UnPack(const flatbuffers::resolver_function_t *_resolver = nullptr) const; void UnPackTo(QuantizedRelu6T *_o, const flatbuffers::resolver_function_t *_resolver = nullptr) const; static flatbuffers::Offset Pack(flatbuffers::FlatBufferBuilder &_fbb, const QuantizedRelu6T* _o, const flatbuffers::rehasher_function_t *_rehasher = nullptr); }; struct QuantizedRelu6Builder { flatbuffers::FlatBufferBuilder &fbb_; flatbuffers::uoffset_t start_; void add_type(DataType type) { fbb_.AddElement(4, static_cast(type), 0); } explicit QuantizedRelu6Builder(flatbuffers::FlatBufferBuilder &_fbb) : fbb_(_fbb) { start_ = fbb_.StartTable(); } QuantizedRelu6Builder &operator=(const QuantizedRelu6Builder &); flatbuffers::Offset Finish() { const auto end = fbb_.EndTable(start_); auto o = flatbuffers::Offset(end); return o; } }; inline flatbuffers::Offset CreateQuantizedRelu6( flatbuffers::FlatBufferBuilder &_fbb, DataType type = DataType_DT_INVALID) { QuantizedRelu6Builder builder_(_fbb); builder_.add_type(type); return builder_.Finish(); } flatbuffers::Offset CreateQuantizedRelu6(flatbuffers::FlatBufferBuilder &_fbb, const QuantizedRelu6T *_o, const flatbuffers::rehasher_function_t *_rehasher = nullptr); struct QuantizedReshapeT : public flatbuffers::NativeTable { typedef QuantizedReshape TableType; std::vector dims; ModeFormat modelFormat; QuantizedReshapeT() : modelFormat(ModeFormat_TENSORFLOW) { } }; struct QuantizedReshape FLATBUFFERS_FINAL_CLASS : private flatbuffers::Table { typedef QuantizedReshapeT NativeTableType; static const flatbuffers::TypeTable *MiniReflectTypeTable() { return QuantizedReshapeTypeTable(); } const flatbuffers::Vector *dims() const { return GetPointer *>(4); } ModeFormat modelFormat() const { return static_cast(GetField(6, 0)); } bool Verify(flatbuffers::Verifier &verifier) const { return VerifyTableStart(verifier) && VerifyOffset(verifier, 4) && verifier.VerifyVector(dims()) && VerifyField(verifier, 6) && verifier.EndTable(); } QuantizedReshapeT *UnPack(const flatbuffers::resolver_function_t *_resolver = nullptr) const; void UnPackTo(QuantizedReshapeT *_o, const flatbuffers::resolver_function_t *_resolver = nullptr) const; static flatbuffers::Offset Pack(flatbuffers::FlatBufferBuilder &_fbb, const QuantizedReshapeT* _o, const flatbuffers::rehasher_function_t *_rehasher = nullptr); }; struct QuantizedReshapeBuilder { flatbuffers::FlatBufferBuilder &fbb_; flatbuffers::uoffset_t start_; void add_dims(flatbuffers::Offset> dims) { fbb_.AddOffset(4, dims); } void add_modelFormat(ModeFormat modelFormat) { fbb_.AddElement(6, static_cast(modelFormat), 0); } explicit QuantizedReshapeBuilder(flatbuffers::FlatBufferBuilder &_fbb) : fbb_(_fbb) { start_ = fbb_.StartTable(); } QuantizedReshapeBuilder &operator=(const QuantizedReshapeBuilder &); flatbuffers::Offset Finish() { const auto end = fbb_.EndTable(start_); auto o = flatbuffers::Offset(end); return o; } }; inline flatbuffers::Offset CreateQuantizedReshape( flatbuffers::FlatBufferBuilder &_fbb, flatbuffers::Offset> dims = 0, ModeFormat modelFormat = ModeFormat_TENSORFLOW) { QuantizedReshapeBuilder builder_(_fbb); builder_.add_dims(dims); builder_.add_modelFormat(modelFormat); return builder_.Finish(); } flatbuffers::Offset CreateQuantizedReshape(flatbuffers::FlatBufferBuilder &_fbb, const QuantizedReshapeT *_o, const flatbuffers::rehasher_function_t *_rehasher = nullptr); struct QuantizedSoftmaxT : public flatbuffers::NativeTable { typedef QuantizedSoftmax TableType; float beta; float inputScale; QuantizedSoftmaxT() : beta(0.0f), inputScale(0.0f) { } }; struct QuantizedSoftmax FLATBUFFERS_FINAL_CLASS : private flatbuffers::Table { typedef QuantizedSoftmaxT NativeTableType; static const flatbuffers::TypeTable *MiniReflectTypeTable() { return QuantizedSoftmaxTypeTable(); } float beta() const { return GetField(4, 0.0f); } float inputScale() const { return GetField(6, 0.0f); } bool Verify(flatbuffers::Verifier &verifier) const { return VerifyTableStart(verifier) && VerifyField(verifier, 4) && VerifyField(verifier, 6) && verifier.EndTable(); } QuantizedSoftmaxT *UnPack(const flatbuffers::resolver_function_t *_resolver = nullptr) const; void UnPackTo(QuantizedSoftmaxT *_o, const flatbuffers::resolver_function_t *_resolver = nullptr) const; static flatbuffers::Offset Pack(flatbuffers::FlatBufferBuilder &_fbb, const QuantizedSoftmaxT* _o, const flatbuffers::rehasher_function_t *_rehasher = nullptr); }; struct QuantizedSoftmaxBuilder { flatbuffers::FlatBufferBuilder &fbb_; flatbuffers::uoffset_t start_; void add_beta(float beta) { fbb_.AddElement(4, beta, 0.0f); } void add_inputScale(float inputScale) { fbb_.AddElement(6, inputScale, 0.0f); } explicit QuantizedSoftmaxBuilder(flatbuffers::FlatBufferBuilder &_fbb) : fbb_(_fbb) { start_ = fbb_.StartTable(); } QuantizedSoftmaxBuilder &operator=(const QuantizedSoftmaxBuilder &); flatbuffers::Offset Finish() { const auto end = fbb_.EndTable(start_); auto o = flatbuffers::Offset(end); return o; } }; inline flatbuffers::Offset CreateQuantizedSoftmax( flatbuffers::FlatBufferBuilder &_fbb, float beta = 0.0f, float inputScale = 0.0f) { QuantizedSoftmaxBuilder builder_(_fbb); builder_.add_inputScale(inputScale); builder_.add_beta(beta); return builder_.Finish(); } flatbuffers::Offset CreateQuantizedSoftmax(flatbuffers::FlatBufferBuilder &_fbb, const QuantizedSoftmaxT *_o, const flatbuffers::rehasher_function_t *_rehasher = nullptr); struct QuantizeV2T : public flatbuffers::NativeTable { typedef QuantizeV2 TableType; DataType type; QuantizeMode mode; QuantizeRoundMode roundMode; QuantizeV2T() : type(DataType_DT_INVALID), mode(QuantizeMode_MIN_COMBINED), roundMode(QuantizeRoundMode_HALF_AWAY_FROM_ZERO) { } }; struct QuantizeV2 FLATBUFFERS_FINAL_CLASS : private flatbuffers::Table { typedef QuantizeV2T NativeTableType; static const flatbuffers::TypeTable *MiniReflectTypeTable() { return QuantizeV2TypeTable(); } DataType type() const { return static_cast(GetField(4, 0)); } QuantizeMode mode() const { return static_cast(GetField(6, 0)); } QuantizeRoundMode roundMode() 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(); } QuantizeV2T *UnPack(const flatbuffers::resolver_function_t *_resolver = nullptr) const; void UnPackTo(QuantizeV2T *_o, const flatbuffers::resolver_function_t *_resolver = nullptr) const; static flatbuffers::Offset Pack(flatbuffers::FlatBufferBuilder &_fbb, const QuantizeV2T* _o, const flatbuffers::rehasher_function_t *_rehasher = nullptr); }; struct QuantizeV2Builder { flatbuffers::FlatBufferBuilder &fbb_; flatbuffers::uoffset_t start_; void add_type(DataType type) { fbb_.AddElement(4, static_cast(type), 0); } void add_mode(QuantizeMode mode) { fbb_.AddElement(6, static_cast(mode), 0); } void add_roundMode(QuantizeRoundMode roundMode) { fbb_.AddElement(8, static_cast(roundMode), 0); } explicit QuantizeV2Builder(flatbuffers::FlatBufferBuilder &_fbb) : fbb_(_fbb) { start_ = fbb_.StartTable(); } QuantizeV2Builder &operator=(const QuantizeV2Builder &); flatbuffers::Offset Finish() { const auto end = fbb_.EndTable(start_); auto o = flatbuffers::Offset(end); return o; } }; inline flatbuffers::Offset CreateQuantizeV2( flatbuffers::FlatBufferBuilder &_fbb, DataType type = DataType_DT_INVALID, QuantizeMode mode = QuantizeMode_MIN_COMBINED, QuantizeRoundMode roundMode = QuantizeRoundMode_HALF_AWAY_FROM_ZERO) { QuantizeV2Builder builder_(_fbb); builder_.add_type(type); builder_.add_roundMode(roundMode); builder_.add_mode(mode); return builder_.Finish(); } flatbuffers::Offset CreateQuantizeV2(flatbuffers::FlatBufferBuilder &_fbb, const QuantizeV2T *_o, const flatbuffers::rehasher_function_t *_rehasher = nullptr); struct RequantizationRangeT : public flatbuffers::NativeTable { typedef RequantizationRange TableType; RequantizationRangeT() { } }; struct RequantizationRange FLATBUFFERS_FINAL_CLASS : private flatbuffers::Table { typedef RequantizationRangeT NativeTableType; static const flatbuffers::TypeTable *MiniReflectTypeTable() { return RequantizationRangeTypeTable(); } bool Verify(flatbuffers::Verifier &verifier) const { return VerifyTableStart(verifier) && verifier.EndTable(); } RequantizationRangeT *UnPack(const flatbuffers::resolver_function_t *_resolver = nullptr) const; void UnPackTo(RequantizationRangeT *_o, const flatbuffers::resolver_function_t *_resolver = nullptr) const; static flatbuffers::Offset Pack(flatbuffers::FlatBufferBuilder &_fbb, const RequantizationRangeT* _o, const flatbuffers::rehasher_function_t *_rehasher = nullptr); }; struct RequantizationRangeBuilder { flatbuffers::FlatBufferBuilder &fbb_; flatbuffers::uoffset_t start_; explicit RequantizationRangeBuilder(flatbuffers::FlatBufferBuilder &_fbb) : fbb_(_fbb) { start_ = fbb_.StartTable(); } RequantizationRangeBuilder &operator=(const RequantizationRangeBuilder &); flatbuffers::Offset Finish() { const auto end = fbb_.EndTable(start_); auto o = flatbuffers::Offset(end); return o; } }; inline flatbuffers::Offset CreateRequantizationRange( flatbuffers::FlatBufferBuilder &_fbb) { RequantizationRangeBuilder builder_(_fbb); return builder_.Finish(); } flatbuffers::Offset CreateRequantizationRange(flatbuffers::FlatBufferBuilder &_fbb, const RequantizationRangeT *_o, const flatbuffers::rehasher_function_t *_rehasher = nullptr); struct RequantizeT : public flatbuffers::NativeTable { typedef Requantize TableType; RequantizeT() { } }; struct Requantize FLATBUFFERS_FINAL_CLASS : private flatbuffers::Table { typedef RequantizeT NativeTableType; static const flatbuffers::TypeTable *MiniReflectTypeTable() { return RequantizeTypeTable(); } bool Verify(flatbuffers::Verifier &verifier) const { return VerifyTableStart(verifier) && verifier.EndTable(); } RequantizeT *UnPack(const flatbuffers::resolver_function_t *_resolver = nullptr) const; void UnPackTo(RequantizeT *_o, const flatbuffers::resolver_function_t *_resolver = nullptr) const; static flatbuffers::Offset Pack(flatbuffers::FlatBufferBuilder &_fbb, const RequantizeT* _o, const flatbuffers::rehasher_function_t *_rehasher = nullptr); }; struct RequantizeBuilder { flatbuffers::FlatBufferBuilder &fbb_; flatbuffers::uoffset_t start_; explicit RequantizeBuilder(flatbuffers::FlatBufferBuilder &_fbb) : fbb_(_fbb) { start_ = fbb_.StartTable(); } RequantizeBuilder &operator=(const RequantizeBuilder &); flatbuffers::Offset Finish() { const auto end = fbb_.EndTable(start_); auto o = flatbuffers::Offset(end); return o; } }; inline flatbuffers::Offset CreateRequantize( flatbuffers::FlatBufferBuilder &_fbb) { RequantizeBuilder builder_(_fbb); return builder_.Finish(); } flatbuffers::Offset CreateRequantize(flatbuffers::FlatBufferBuilder &_fbb, const RequantizeT *_o, const flatbuffers::rehasher_function_t *_rehasher = nullptr); struct TfQuantizedConv2DT : public flatbuffers::NativeTable { typedef TfQuantizedConv2D TableType; std::vector bias; bool biasflag; std::unique_ptr common; std::vector weight; FusedActivation activationType; int32_t multiplier; int32_t outMax; int32_t outMin; int32_t shift; std::unique_ptr biasQuantizedParam; int32_t depthMultiplier; std::unique_ptr filterQuantizedParam; std::unique_ptr inputQuantizedParam; ModeFormat modelFormat; std::unique_ptr outputQuantizedParam; TfQuantizedConv2DT() : biasflag(false), activationType(FusedActivation_kTfLiteActNone), multiplier(0), outMax(0), outMin(0), shift(0), depthMultiplier(0), modelFormat(ModeFormat_TENSORFLOW) { } }; struct TfQuantizedConv2D FLATBUFFERS_FINAL_CLASS : private flatbuffers::Table { typedef TfQuantizedConv2DT NativeTableType; static const flatbuffers::TypeTable *MiniReflectTypeTable() { return TfQuantizedConv2DTypeTable(); } const flatbuffers::Vector *bias() const { return GetPointer *>(4); } bool biasflag() const { return GetField(6, 0) != 0; } const Convolution2DCommon *common() const { return GetPointer(8); } const flatbuffers::Vector *weight() const { return GetPointer *>(10); } FusedActivation activationType() const { return static_cast(GetField(12, 0)); } int32_t multiplier() const { return GetField(14, 0); } int32_t outMax() const { return GetField(16, 0); } int32_t outMin() const { return GetField(18, 0); } int32_t shift() const { return GetField(20, 0); } const QuantizedParam *biasQuantizedParam() const { return GetPointer(22); } int32_t depthMultiplier() const { return GetField(24, 0); } const QuantizedParam *filterQuantizedParam() const { return GetPointer(26); } const QuantizedParam *inputQuantizedParam() const { return GetPointer(28); } ModeFormat modelFormat() const { return static_cast(GetField(30, 0)); } const QuantizedParam *outputQuantizedParam() const { return GetPointer(32); } bool Verify(flatbuffers::Verifier &verifier) const { return VerifyTableStart(verifier) && VerifyOffset(verifier, 4) && verifier.VerifyVector(bias()) && VerifyField(verifier, 6) && VerifyOffset(verifier, 8) && verifier.VerifyTable(common()) && VerifyOffset(verifier, 10) && verifier.VerifyVector(weight()) && VerifyField(verifier, 12) && VerifyField(verifier, 14) && VerifyField(verifier, 16) && VerifyField(verifier, 18) && VerifyField(verifier, 20) && VerifyOffset(verifier, 22) && verifier.VerifyTable(biasQuantizedParam()) && VerifyField(verifier, 24) && VerifyOffset(verifier, 26) && verifier.VerifyTable(filterQuantizedParam()) && VerifyOffset(verifier, 28) && verifier.VerifyTable(inputQuantizedParam()) && VerifyField(verifier, 30) && VerifyOffset(verifier, 32) && verifier.VerifyTable(outputQuantizedParam()) && verifier.EndTable(); } TfQuantizedConv2DT *UnPack(const flatbuffers::resolver_function_t *_resolver = nullptr) const; void UnPackTo(TfQuantizedConv2DT *_o, const flatbuffers::resolver_function_t *_resolver = nullptr) const; static flatbuffers::Offset Pack(flatbuffers::FlatBufferBuilder &_fbb, const TfQuantizedConv2DT* _o, const flatbuffers::rehasher_function_t *_rehasher = nullptr); }; struct TfQuantizedConv2DBuilder { flatbuffers::FlatBufferBuilder &fbb_; flatbuffers::uoffset_t start_; void add_bias(flatbuffers::Offset> bias) { fbb_.AddOffset(4, bias); } void add_biasflag(bool biasflag) { fbb_.AddElement(6, static_cast(biasflag), 0); } void add_common(flatbuffers::Offset common) { fbb_.AddOffset(8, common); } void add_weight(flatbuffers::Offset> weight) { fbb_.AddOffset(10, weight); } void add_activationType(FusedActivation activationType) { fbb_.AddElement(12, static_cast(activationType), 0); } void add_multiplier(int32_t multiplier) { fbb_.AddElement(14, multiplier, 0); } void add_outMax(int32_t outMax) { fbb_.AddElement(16, outMax, 0); } void add_outMin(int32_t outMin) { fbb_.AddElement(18, outMin, 0); } void add_shift(int32_t shift) { fbb_.AddElement(20, shift, 0); } void add_biasQuantizedParam(flatbuffers::Offset biasQuantizedParam) { fbb_.AddOffset(22, biasQuantizedParam); } void add_depthMultiplier(int32_t depthMultiplier) { fbb_.AddElement(24, depthMultiplier, 0); } void add_filterQuantizedParam(flatbuffers::Offset filterQuantizedParam) { fbb_.AddOffset(26, filterQuantizedParam); } void add_inputQuantizedParam(flatbuffers::Offset inputQuantizedParam) { fbb_.AddOffset(28, inputQuantizedParam); } void add_modelFormat(ModeFormat modelFormat) { fbb_.AddElement(30, static_cast(modelFormat), 0); } void add_outputQuantizedParam(flatbuffers::Offset outputQuantizedParam) { fbb_.AddOffset(32, outputQuantizedParam); } explicit TfQuantizedConv2DBuilder(flatbuffers::FlatBufferBuilder &_fbb) : fbb_(_fbb) { start_ = fbb_.StartTable(); } TfQuantizedConv2DBuilder &operator=(const TfQuantizedConv2DBuilder &); flatbuffers::Offset Finish() { const auto end = fbb_.EndTable(start_); auto o = flatbuffers::Offset(end); return o; } }; inline flatbuffers::Offset CreateTfQuantizedConv2D( flatbuffers::FlatBufferBuilder &_fbb, flatbuffers::Offset> bias = 0, bool biasflag = false, flatbuffers::Offset common = 0, flatbuffers::Offset> weight = 0, FusedActivation activationType = FusedActivation_kTfLiteActNone, int32_t multiplier = 0, int32_t outMax = 0, int32_t outMin = 0, int32_t shift = 0, flatbuffers::Offset biasQuantizedParam = 0, int32_t depthMultiplier = 0, flatbuffers::Offset filterQuantizedParam = 0, flatbuffers::Offset inputQuantizedParam = 0, ModeFormat modelFormat = ModeFormat_TENSORFLOW, flatbuffers::Offset outputQuantizedParam = 0) { TfQuantizedConv2DBuilder builder_(_fbb); builder_.add_outputQuantizedParam(outputQuantizedParam); builder_.add_inputQuantizedParam(inputQuantizedParam); builder_.add_filterQuantizedParam(filterQuantizedParam); builder_.add_depthMultiplier(depthMultiplier); builder_.add_biasQuantizedParam(biasQuantizedParam); builder_.add_shift(shift); builder_.add_outMin(outMin); builder_.add_outMax(outMax); builder_.add_multiplier(multiplier); builder_.add_weight(weight); builder_.add_common(common); builder_.add_bias(bias); builder_.add_modelFormat(modelFormat); builder_.add_activationType(activationType); builder_.add_biasflag(biasflag); return builder_.Finish(); } flatbuffers::Offset CreateTfQuantizedConv2D(flatbuffers::FlatBufferBuilder &_fbb, const TfQuantizedConv2DT *_o, const flatbuffers::rehasher_function_t *_rehasher = nullptr); inline QuantizedParamT *QuantizedParam::UnPack(const flatbuffers::resolver_function_t *_resolver) const { auto _o = new QuantizedParamT(); UnPackTo(_o, _resolver); return _o; } inline void QuantizedParam::UnPackTo(QuantizedParamT *_o, const flatbuffers::resolver_function_t *_resolver) const { (void)_o; (void)_resolver; { auto _e = zeroPoint(); _o->zeroPoint = _e; }; { auto _e = scale(); _o->scale = _e; }; } inline flatbuffers::Offset QuantizedParam::Pack(flatbuffers::FlatBufferBuilder &_fbb, const QuantizedParamT* _o, const flatbuffers::rehasher_function_t *_rehasher) { return CreateQuantizedParam(_fbb, _o, _rehasher); } inline flatbuffers::Offset CreateQuantizedParam(flatbuffers::FlatBufferBuilder &_fbb, const QuantizedParamT *_o, const flatbuffers::rehasher_function_t *_rehasher) { (void)_rehasher; (void)_o; struct _VectorArgs { flatbuffers::FlatBufferBuilder *__fbb; const QuantizedParamT* __o; const flatbuffers::rehasher_function_t *__rehasher; } _va = { &_fbb, _o, _rehasher}; (void)_va; auto _zeroPoint = _o->zeroPoint; auto _scale = _o->scale; return MNN::CreateQuantizedParam( _fbb, _zeroPoint, _scale); } inline QuantizedAddT *QuantizedAdd::UnPack(const flatbuffers::resolver_function_t *_resolver) const { auto _o = new QuantizedAddT(); UnPackTo(_o, _resolver); return _o; } inline void QuantizedAdd::UnPackTo(QuantizedAddT *_o, const flatbuffers::resolver_function_t *_resolver) const { (void)_o; (void)_resolver; { auto _e = activationType(); _o->activationType = _e; }; { auto _e = input1QuantizedParam(); if (_e) _o->input1QuantizedParam = std::unique_ptr(_e->UnPack(_resolver)); }; { auto _e = input2QuantizedParam(); if (_e) _o->input2QuantizedParam = std::unique_ptr(_e->UnPack(_resolver)); }; { auto _e = outputQuantizedParam(); if (_e) _o->outputQuantizedParam = std::unique_ptr(_e->UnPack(_resolver)); }; } inline flatbuffers::Offset QuantizedAdd::Pack(flatbuffers::FlatBufferBuilder &_fbb, const QuantizedAddT* _o, const flatbuffers::rehasher_function_t *_rehasher) { return CreateQuantizedAdd(_fbb, _o, _rehasher); } inline flatbuffers::Offset CreateQuantizedAdd(flatbuffers::FlatBufferBuilder &_fbb, const QuantizedAddT *_o, const flatbuffers::rehasher_function_t *_rehasher) { (void)_rehasher; (void)_o; struct _VectorArgs { flatbuffers::FlatBufferBuilder *__fbb; const QuantizedAddT* __o; const flatbuffers::rehasher_function_t *__rehasher; } _va = { &_fbb, _o, _rehasher}; (void)_va; auto _activationType = _o->activationType; auto _input1QuantizedParam = _o->input1QuantizedParam ? CreateQuantizedParam(_fbb, _o->input1QuantizedParam.get(), _rehasher) : 0; auto _input2QuantizedParam = _o->input2QuantizedParam ? CreateQuantizedParam(_fbb, _o->input2QuantizedParam.get(), _rehasher) : 0; auto _outputQuantizedParam = _o->outputQuantizedParam ? CreateQuantizedParam(_fbb, _o->outputQuantizedParam.get(), _rehasher) : 0; return MNN::CreateQuantizedAdd( _fbb, _activationType, _input1QuantizedParam, _input2QuantizedParam, _outputQuantizedParam); } inline DequantizeT *Dequantize::UnPack(const flatbuffers::resolver_function_t *_resolver) const { auto _o = new DequantizeT(); UnPackTo(_o, _resolver); return _o; } inline void Dequantize::UnPackTo(DequantizeT *_o, const flatbuffers::resolver_function_t *_resolver) const { (void)_o; (void)_resolver; { auto _e = inputQuantizedParam(); if (_e) _o->inputQuantizedParam = std::unique_ptr(_e->UnPack(_resolver)); }; { auto _e = mode(); _o->mode = _e; }; { auto _e = modelFormat(); _o->modelFormat = _e; }; { auto _e = type(); _o->type = _e; }; } inline flatbuffers::Offset Dequantize::Pack(flatbuffers::FlatBufferBuilder &_fbb, const DequantizeT* _o, const flatbuffers::rehasher_function_t *_rehasher) { return CreateDequantize(_fbb, _o, _rehasher); } inline flatbuffers::Offset CreateDequantize(flatbuffers::FlatBufferBuilder &_fbb, const DequantizeT *_o, const flatbuffers::rehasher_function_t *_rehasher) { (void)_rehasher; (void)_o; struct _VectorArgs { flatbuffers::FlatBufferBuilder *__fbb; const DequantizeT* __o; const flatbuffers::rehasher_function_t *__rehasher; } _va = { &_fbb, _o, _rehasher}; (void)_va; auto _inputQuantizedParam = _o->inputQuantizedParam ? CreateQuantizedParam(_fbb, _o->inputQuantizedParam.get(), _rehasher) : 0; auto _mode = _o->mode; auto _modelFormat = _o->modelFormat; auto _type = _o->type; return MNN::CreateDequantize( _fbb, _inputQuantizedParam, _mode, _modelFormat, _type); } inline QuantizedAvgPoolT *QuantizedAvgPool::UnPack(const flatbuffers::resolver_function_t *_resolver) const { auto _o = new QuantizedAvgPoolT(); UnPackTo(_o, _resolver); return _o; } inline void QuantizedAvgPool::UnPackTo(QuantizedAvgPoolT *_o, const flatbuffers::resolver_function_t *_resolver) const { (void)_o; (void)_resolver; { auto _e = kernelX(); _o->kernelX = _e; }; { auto _e = kernelY(); _o->kernelY = _e; }; { auto _e = modelFormat(); _o->modelFormat = _e; }; { auto _e = outputActivationMax(); _o->outputActivationMax = _e; }; { auto _e = outputActivationMin(); _o->outputActivationMin = _e; }; { auto _e = padType(); _o->padType = _e; }; { auto _e = padX(); _o->padX = _e; }; { auto _e = padY(); _o->padY = _e; }; { auto _e = strideX(); _o->strideX = _e; }; { auto _e = strideY(); _o->strideY = _e; }; { auto _e = type(); _o->type = _e; }; } inline flatbuffers::Offset QuantizedAvgPool::Pack(flatbuffers::FlatBufferBuilder &_fbb, const QuantizedAvgPoolT* _o, const flatbuffers::rehasher_function_t *_rehasher) { return CreateQuantizedAvgPool(_fbb, _o, _rehasher); } inline flatbuffers::Offset CreateQuantizedAvgPool(flatbuffers::FlatBufferBuilder &_fbb, const QuantizedAvgPoolT *_o, const flatbuffers::rehasher_function_t *_rehasher) { (void)_rehasher; (void)_o; struct _VectorArgs { flatbuffers::FlatBufferBuilder *__fbb; const QuantizedAvgPoolT* __o; const flatbuffers::rehasher_function_t *__rehasher; } _va = { &_fbb, _o, _rehasher}; (void)_va; auto _kernelX = _o->kernelX; auto _kernelY = _o->kernelY; auto _modelFormat = _o->modelFormat; auto _outputActivationMax = _o->outputActivationMax; auto _outputActivationMin = _o->outputActivationMin; auto _padType = _o->padType; auto _padX = _o->padX; auto _padY = _o->padY; auto _strideX = _o->strideX; auto _strideY = _o->strideY; auto _type = _o->type; return MNN::CreateQuantizedAvgPool( _fbb, _kernelX, _kernelY, _modelFormat, _outputActivationMax, _outputActivationMin, _padType, _padX, _padY, _strideX, _strideY, _type); } inline QuantizedBiasAddT *QuantizedBiasAdd::UnPack(const flatbuffers::resolver_function_t *_resolver) const { auto _o = new QuantizedBiasAddT(); UnPackTo(_o, _resolver); return _o; } inline void QuantizedBiasAdd::UnPackTo(QuantizedBiasAddT *_o, const flatbuffers::resolver_function_t *_resolver) const { (void)_o; (void)_resolver; { 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); } } }; { auto _e = inputType(); _o->inputType = _e; }; { auto _e = max(); _o->max = _e; }; { auto _e = min(); _o->min = _e; }; { auto _e = outputType(); _o->outputType = _e; }; } inline flatbuffers::Offset QuantizedBiasAdd::Pack(flatbuffers::FlatBufferBuilder &_fbb, const QuantizedBiasAddT* _o, const flatbuffers::rehasher_function_t *_rehasher) { return CreateQuantizedBiasAdd(_fbb, _o, _rehasher); } inline flatbuffers::Offset CreateQuantizedBiasAdd(flatbuffers::FlatBufferBuilder &_fbb, const QuantizedBiasAddT *_o, const flatbuffers::rehasher_function_t *_rehasher) { (void)_rehasher; (void)_o; struct _VectorArgs { flatbuffers::FlatBufferBuilder *__fbb; const QuantizedBiasAddT* __o; const flatbuffers::rehasher_function_t *__rehasher; } _va = { &_fbb, _o, _rehasher}; (void)_va; auto _bias = _o->bias.size() ? _fbb.CreateVector(_o->bias) : 0; auto _inputType = _o->inputType; auto _max = _o->max; auto _min = _o->min; auto _outputType = _o->outputType; return MNN::CreateQuantizedBiasAdd( _fbb, _bias, _inputType, _max, _min, _outputType); } inline QuantizedConcatT *QuantizedConcat::UnPack(const flatbuffers::resolver_function_t *_resolver) const { auto _o = new QuantizedConcatT(); UnPackTo(_o, _resolver); return _o; } inline void QuantizedConcat::UnPackTo(QuantizedConcatT *_o, const flatbuffers::resolver_function_t *_resolver) const { (void)_o; (void)_resolver; { auto _e = activationType(); _o->activationType = _e; }; { auto _e = axis(); _o->axis = _e; }; { auto _e = inputScale(); if (_e) { _o->inputScale.resize(_e->size()); for (flatbuffers::uoffset_t _i = 0; _i < _e->size(); _i++) { _o->inputScale[_i] = _e->Get(_i); } } }; { auto _e = inputZeroPoint(); if (_e) { _o->inputZeroPoint.resize(_e->size()); for (flatbuffers::uoffset_t _i = 0; _i < _e->size(); _i++) { _o->inputZeroPoint[_i] = _e->Get(_i); } } }; { auto _e = outputQuantizedParam(); if (_e) _o->outputQuantizedParam = std::unique_ptr(_e->UnPack(_resolver)); }; } inline flatbuffers::Offset QuantizedConcat::Pack(flatbuffers::FlatBufferBuilder &_fbb, const QuantizedConcatT* _o, const flatbuffers::rehasher_function_t *_rehasher) { return CreateQuantizedConcat(_fbb, _o, _rehasher); } inline flatbuffers::Offset CreateQuantizedConcat(flatbuffers::FlatBufferBuilder &_fbb, const QuantizedConcatT *_o, const flatbuffers::rehasher_function_t *_rehasher) { (void)_rehasher; (void)_o; struct _VectorArgs { flatbuffers::FlatBufferBuilder *__fbb; const QuantizedConcatT* __o; const flatbuffers::rehasher_function_t *__rehasher; } _va = { &_fbb, _o, _rehasher}; (void)_va; auto _activationType = _o->activationType; auto _axis = _o->axis; auto _inputScale = _o->inputScale.size() ? _fbb.CreateVector(_o->inputScale) : 0; auto _inputZeroPoint = _o->inputZeroPoint.size() ? _fbb.CreateVector(_o->inputZeroPoint) : 0; auto _outputQuantizedParam = _o->outputQuantizedParam ? CreateQuantizedParam(_fbb, _o->outputQuantizedParam.get(), _rehasher) : 0; return MNN::CreateQuantizedConcat( _fbb, _activationType, _axis, _inputScale, _inputZeroPoint, _outputQuantizedParam); } inline QuantizedLogisticT *QuantizedLogistic::UnPack(const flatbuffers::resolver_function_t *_resolver) const { auto _o = new QuantizedLogisticT(); UnPackTo(_o, _resolver); return _o; } inline void QuantizedLogistic::UnPackTo(QuantizedLogisticT *_o, const flatbuffers::resolver_function_t *_resolver) const { (void)_o; (void)_resolver; { auto _e = inputQuantizedParam(); if (_e) _o->inputQuantizedParam = std::unique_ptr(_e->UnPack(_resolver)); }; { auto _e = outputQuantizedParam(); if (_e) _o->outputQuantizedParam = std::unique_ptr(_e->UnPack(_resolver)); }; } inline flatbuffers::Offset QuantizedLogistic::Pack(flatbuffers::FlatBufferBuilder &_fbb, const QuantizedLogisticT* _o, const flatbuffers::rehasher_function_t *_rehasher) { return CreateQuantizedLogistic(_fbb, _o, _rehasher); } inline flatbuffers::Offset CreateQuantizedLogistic(flatbuffers::FlatBufferBuilder &_fbb, const QuantizedLogisticT *_o, const flatbuffers::rehasher_function_t *_rehasher) { (void)_rehasher; (void)_o; struct _VectorArgs { flatbuffers::FlatBufferBuilder *__fbb; const QuantizedLogisticT* __o; const flatbuffers::rehasher_function_t *__rehasher; } _va = { &_fbb, _o, _rehasher}; (void)_va; auto _inputQuantizedParam = _o->inputQuantizedParam ? CreateQuantizedParam(_fbb, _o->inputQuantizedParam.get(), _rehasher) : 0; auto _outputQuantizedParam = _o->outputQuantizedParam ? CreateQuantizedParam(_fbb, _o->outputQuantizedParam.get(), _rehasher) : 0; return MNN::CreateQuantizedLogistic( _fbb, _inputQuantizedParam, _outputQuantizedParam); } inline QuantizedMatMulT *QuantizedMatMul::UnPack(const flatbuffers::resolver_function_t *_resolver) const { auto _o = new QuantizedMatMulT(); UnPackTo(_o, _resolver); return _o; } inline void QuantizedMatMul::UnPackTo(QuantizedMatMulT *_o, const flatbuffers::resolver_function_t *_resolver) const { (void)_o; (void)_resolver; { auto _e = transposeA(); _o->transposeA = _e; }; { auto _e = transposeB(); _o->transposeB = _e; }; } inline flatbuffers::Offset QuantizedMatMul::Pack(flatbuffers::FlatBufferBuilder &_fbb, const QuantizedMatMulT* _o, const flatbuffers::rehasher_function_t *_rehasher) { return CreateQuantizedMatMul(_fbb, _o, _rehasher); } inline flatbuffers::Offset CreateQuantizedMatMul(flatbuffers::FlatBufferBuilder &_fbb, const QuantizedMatMulT *_o, const flatbuffers::rehasher_function_t *_rehasher) { (void)_rehasher; (void)_o; struct _VectorArgs { flatbuffers::FlatBufferBuilder *__fbb; const QuantizedMatMulT* __o; const flatbuffers::rehasher_function_t *__rehasher; } _va = { &_fbb, _o, _rehasher}; (void)_va; auto _transposeA = _o->transposeA; auto _transposeB = _o->transposeB; return MNN::CreateQuantizedMatMul( _fbb, _transposeA, _transposeB); } inline QuantizedMaxPoolT *QuantizedMaxPool::UnPack(const flatbuffers::resolver_function_t *_resolver) const { auto _o = new QuantizedMaxPoolT(); UnPackTo(_o, _resolver); return _o; } inline void QuantizedMaxPool::UnPackTo(QuantizedMaxPoolT *_o, const flatbuffers::resolver_function_t *_resolver) const { (void)_o; (void)_resolver; { auto _e = kernelX(); _o->kernelX = _e; }; { auto _e = kernelY(); _o->kernelY = _e; }; { auto _e = modelFormat(); _o->modelFormat = _e; }; { auto _e = outputActivationMax(); _o->outputActivationMax = _e; }; { auto _e = outputActivationMin(); _o->outputActivationMin = _e; }; { auto _e = padType(); _o->padType = _e; }; { auto _e = padX(); _o->padX = _e; }; { auto _e = padY(); _o->padY = _e; }; { auto _e = strideX(); _o->strideX = _e; }; { auto _e = strideY(); _o->strideY = _e; }; { auto _e = type(); _o->type = _e; }; } inline flatbuffers::Offset QuantizedMaxPool::Pack(flatbuffers::FlatBufferBuilder &_fbb, const QuantizedMaxPoolT* _o, const flatbuffers::rehasher_function_t *_rehasher) { return CreateQuantizedMaxPool(_fbb, _o, _rehasher); } inline flatbuffers::Offset CreateQuantizedMaxPool(flatbuffers::FlatBufferBuilder &_fbb, const QuantizedMaxPoolT *_o, const flatbuffers::rehasher_function_t *_rehasher) { (void)_rehasher; (void)_o; struct _VectorArgs { flatbuffers::FlatBufferBuilder *__fbb; const QuantizedMaxPoolT* __o; const flatbuffers::rehasher_function_t *__rehasher; } _va = { &_fbb, _o, _rehasher}; (void)_va; auto _kernelX = _o->kernelX; auto _kernelY = _o->kernelY; auto _modelFormat = _o->modelFormat; auto _outputActivationMax = _o->outputActivationMax; auto _outputActivationMin = _o->outputActivationMin; auto _padType = _o->padType; auto _padX = _o->padX; auto _padY = _o->padY; auto _strideX = _o->strideX; auto _strideY = _o->strideY; auto _type = _o->type; return MNN::CreateQuantizedMaxPool( _fbb, _kernelX, _kernelY, _modelFormat, _outputActivationMax, _outputActivationMin, _padType, _padX, _padY, _strideX, _strideY, _type); } inline QuantizedReluT *QuantizedRelu::UnPack(const flatbuffers::resolver_function_t *_resolver) const { auto _o = new QuantizedReluT(); UnPackTo(_o, _resolver); return _o; } inline void QuantizedRelu::UnPackTo(QuantizedReluT *_o, const flatbuffers::resolver_function_t *_resolver) const { (void)_o; (void)_resolver; { auto _e = type(); _o->type = _e; }; } inline flatbuffers::Offset QuantizedRelu::Pack(flatbuffers::FlatBufferBuilder &_fbb, const QuantizedReluT* _o, const flatbuffers::rehasher_function_t *_rehasher) { return CreateQuantizedRelu(_fbb, _o, _rehasher); } inline flatbuffers::Offset CreateQuantizedRelu(flatbuffers::FlatBufferBuilder &_fbb, const QuantizedReluT *_o, const flatbuffers::rehasher_function_t *_rehasher) { (void)_rehasher; (void)_o; struct _VectorArgs { flatbuffers::FlatBufferBuilder *__fbb; const QuantizedReluT* __o; const flatbuffers::rehasher_function_t *__rehasher; } _va = { &_fbb, _o, _rehasher}; (void)_va; auto _type = _o->type; return MNN::CreateQuantizedRelu( _fbb, _type); } inline QuantizedRelu6T *QuantizedRelu6::UnPack(const flatbuffers::resolver_function_t *_resolver) const { auto _o = new QuantizedRelu6T(); UnPackTo(_o, _resolver); return _o; } inline void QuantizedRelu6::UnPackTo(QuantizedRelu6T *_o, const flatbuffers::resolver_function_t *_resolver) const { (void)_o; (void)_resolver; { auto _e = type(); _o->type = _e; }; } inline flatbuffers::Offset QuantizedRelu6::Pack(flatbuffers::FlatBufferBuilder &_fbb, const QuantizedRelu6T* _o, const flatbuffers::rehasher_function_t *_rehasher) { return CreateQuantizedRelu6(_fbb, _o, _rehasher); } inline flatbuffers::Offset CreateQuantizedRelu6(flatbuffers::FlatBufferBuilder &_fbb, const QuantizedRelu6T *_o, const flatbuffers::rehasher_function_t *_rehasher) { (void)_rehasher; (void)_o; struct _VectorArgs { flatbuffers::FlatBufferBuilder *__fbb; const QuantizedRelu6T* __o; const flatbuffers::rehasher_function_t *__rehasher; } _va = { &_fbb, _o, _rehasher}; (void)_va; auto _type = _o->type; return MNN::CreateQuantizedRelu6( _fbb, _type); } inline QuantizedReshapeT *QuantizedReshape::UnPack(const flatbuffers::resolver_function_t *_resolver) const { auto _o = new QuantizedReshapeT(); UnPackTo(_o, _resolver); return _o; } inline void QuantizedReshape::UnPackTo(QuantizedReshapeT *_o, const flatbuffers::resolver_function_t *_resolver) const { (void)_o; (void)_resolver; { auto _e = dims(); if (_e) { _o->dims.resize(_e->size()); for (flatbuffers::uoffset_t _i = 0; _i < _e->size(); _i++) { _o->dims[_i] = _e->Get(_i); } } }; { auto _e = modelFormat(); _o->modelFormat = _e; }; } inline flatbuffers::Offset QuantizedReshape::Pack(flatbuffers::FlatBufferBuilder &_fbb, const QuantizedReshapeT* _o, const flatbuffers::rehasher_function_t *_rehasher) { return CreateQuantizedReshape(_fbb, _o, _rehasher); } inline flatbuffers::Offset CreateQuantizedReshape(flatbuffers::FlatBufferBuilder &_fbb, const QuantizedReshapeT *_o, const flatbuffers::rehasher_function_t *_rehasher) { (void)_rehasher; (void)_o; struct _VectorArgs { flatbuffers::FlatBufferBuilder *__fbb; const QuantizedReshapeT* __o; const flatbuffers::rehasher_function_t *__rehasher; } _va = { &_fbb, _o, _rehasher}; (void)_va; auto _dims = _o->dims.size() ? _fbb.CreateVector(_o->dims) : 0; auto _modelFormat = _o->modelFormat; return MNN::CreateQuantizedReshape( _fbb, _dims, _modelFormat); } inline QuantizedSoftmaxT *QuantizedSoftmax::UnPack(const flatbuffers::resolver_function_t *_resolver) const { auto _o = new QuantizedSoftmaxT(); UnPackTo(_o, _resolver); return _o; } inline void QuantizedSoftmax::UnPackTo(QuantizedSoftmaxT *_o, const flatbuffers::resolver_function_t *_resolver) const { (void)_o; (void)_resolver; { auto _e = beta(); _o->beta = _e; }; { auto _e = inputScale(); _o->inputScale = _e; }; } inline flatbuffers::Offset QuantizedSoftmax::Pack(flatbuffers::FlatBufferBuilder &_fbb, const QuantizedSoftmaxT* _o, const flatbuffers::rehasher_function_t *_rehasher) { return CreateQuantizedSoftmax(_fbb, _o, _rehasher); } inline flatbuffers::Offset CreateQuantizedSoftmax(flatbuffers::FlatBufferBuilder &_fbb, const QuantizedSoftmaxT *_o, const flatbuffers::rehasher_function_t *_rehasher) { (void)_rehasher; (void)_o; struct _VectorArgs { flatbuffers::FlatBufferBuilder *__fbb; const QuantizedSoftmaxT* __o; const flatbuffers::rehasher_function_t *__rehasher; } _va = { &_fbb, _o, _rehasher}; (void)_va; auto _beta = _o->beta; auto _inputScale = _o->inputScale; return MNN::CreateQuantizedSoftmax( _fbb, _beta, _inputScale); } inline QuantizeV2T *QuantizeV2::UnPack(const flatbuffers::resolver_function_t *_resolver) const { auto _o = new QuantizeV2T(); UnPackTo(_o, _resolver); return _o; } inline void QuantizeV2::UnPackTo(QuantizeV2T *_o, const flatbuffers::resolver_function_t *_resolver) const { (void)_o; (void)_resolver; { auto _e = type(); _o->type = _e; }; { auto _e = mode(); _o->mode = _e; }; { auto _e = roundMode(); _o->roundMode = _e; }; } inline flatbuffers::Offset QuantizeV2::Pack(flatbuffers::FlatBufferBuilder &_fbb, const QuantizeV2T* _o, const flatbuffers::rehasher_function_t *_rehasher) { return CreateQuantizeV2(_fbb, _o, _rehasher); } inline flatbuffers::Offset CreateQuantizeV2(flatbuffers::FlatBufferBuilder &_fbb, const QuantizeV2T *_o, const flatbuffers::rehasher_function_t *_rehasher) { (void)_rehasher; (void)_o; struct _VectorArgs { flatbuffers::FlatBufferBuilder *__fbb; const QuantizeV2T* __o; const flatbuffers::rehasher_function_t *__rehasher; } _va = { &_fbb, _o, _rehasher}; (void)_va; auto _type = _o->type; auto _mode = _o->mode; auto _roundMode = _o->roundMode; return MNN::CreateQuantizeV2( _fbb, _type, _mode, _roundMode); } inline RequantizationRangeT *RequantizationRange::UnPack(const flatbuffers::resolver_function_t *_resolver) const { auto _o = new RequantizationRangeT(); UnPackTo(_o, _resolver); return _o; } inline void RequantizationRange::UnPackTo(RequantizationRangeT *_o, const flatbuffers::resolver_function_t *_resolver) const { (void)_o; (void)_resolver; } inline flatbuffers::Offset RequantizationRange::Pack(flatbuffers::FlatBufferBuilder &_fbb, const RequantizationRangeT* _o, const flatbuffers::rehasher_function_t *_rehasher) { return CreateRequantizationRange(_fbb, _o, _rehasher); } inline flatbuffers::Offset CreateRequantizationRange(flatbuffers::FlatBufferBuilder &_fbb, const RequantizationRangeT *_o, const flatbuffers::rehasher_function_t *_rehasher) { (void)_rehasher; (void)_o; struct _VectorArgs { flatbuffers::FlatBufferBuilder *__fbb; const RequantizationRangeT* __o; const flatbuffers::rehasher_function_t *__rehasher; } _va = { &_fbb, _o, _rehasher}; (void)_va; return MNN::CreateRequantizationRange( _fbb); } inline RequantizeT *Requantize::UnPack(const flatbuffers::resolver_function_t *_resolver) const { auto _o = new RequantizeT(); UnPackTo(_o, _resolver); return _o; } inline void Requantize::UnPackTo(RequantizeT *_o, const flatbuffers::resolver_function_t *_resolver) const { (void)_o; (void)_resolver; } inline flatbuffers::Offset Requantize::Pack(flatbuffers::FlatBufferBuilder &_fbb, const RequantizeT* _o, const flatbuffers::rehasher_function_t *_rehasher) { return CreateRequantize(_fbb, _o, _rehasher); } inline flatbuffers::Offset CreateRequantize(flatbuffers::FlatBufferBuilder &_fbb, const RequantizeT *_o, const flatbuffers::rehasher_function_t *_rehasher) { (void)_rehasher; (void)_o; struct _VectorArgs { flatbuffers::FlatBufferBuilder *__fbb; const RequantizeT* __o; const flatbuffers::rehasher_function_t *__rehasher; } _va = { &_fbb, _o, _rehasher}; (void)_va; return MNN::CreateRequantize( _fbb); } inline TfQuantizedConv2DT *TfQuantizedConv2D::UnPack(const flatbuffers::resolver_function_t *_resolver) const { auto _o = new TfQuantizedConv2DT(); UnPackTo(_o, _resolver); return _o; } inline void TfQuantizedConv2D::UnPackTo(TfQuantizedConv2DT *_o, const flatbuffers::resolver_function_t *_resolver) const { (void)_o; (void)_resolver; { 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); } } }; { auto _e = biasflag(); _o->biasflag = _e; }; { auto _e = common(); if (_e) _o->common = std::unique_ptr(_e->UnPack(_resolver)); }; { 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 = activationType(); _o->activationType = _e; }; { auto _e = multiplier(); _o->multiplier = _e; }; { auto _e = outMax(); _o->outMax = _e; }; { auto _e = outMin(); _o->outMin = _e; }; { auto _e = shift(); _o->shift = _e; }; { auto _e = biasQuantizedParam(); if (_e) _o->biasQuantizedParam = std::unique_ptr(_e->UnPack(_resolver)); }; { auto _e = depthMultiplier(); _o->depthMultiplier = _e; }; { auto _e = filterQuantizedParam(); if (_e) _o->filterQuantizedParam = std::unique_ptr(_e->UnPack(_resolver)); }; { auto _e = inputQuantizedParam(); if (_e) _o->inputQuantizedParam = std::unique_ptr(_e->UnPack(_resolver)); }; { auto _e = modelFormat(); _o->modelFormat = _e; }; { auto _e = outputQuantizedParam(); if (_e) _o->outputQuantizedParam = std::unique_ptr(_e->UnPack(_resolver)); }; } inline flatbuffers::Offset TfQuantizedConv2D::Pack(flatbuffers::FlatBufferBuilder &_fbb, const TfQuantizedConv2DT* _o, const flatbuffers::rehasher_function_t *_rehasher) { return CreateTfQuantizedConv2D(_fbb, _o, _rehasher); } inline flatbuffers::Offset CreateTfQuantizedConv2D(flatbuffers::FlatBufferBuilder &_fbb, const TfQuantizedConv2DT *_o, const flatbuffers::rehasher_function_t *_rehasher) { (void)_rehasher; (void)_o; struct _VectorArgs { flatbuffers::FlatBufferBuilder *__fbb; const TfQuantizedConv2DT* __o; const flatbuffers::rehasher_function_t *__rehasher; } _va = { &_fbb, _o, _rehasher}; (void)_va; auto _bias = _o->bias.size() ? _fbb.CreateVector(_o->bias) : 0; auto _biasflag = _o->biasflag; auto _common = _o->common ? CreateConvolution2DCommon(_fbb, _o->common.get(), _rehasher) : 0; auto _weight = _o->weight.size() ? _fbb.CreateVector(_o->weight) : 0; auto _activationType = _o->activationType; auto _multiplier = _o->multiplier; auto _outMax = _o->outMax; auto _outMin = _o->outMin; auto _shift = _o->shift; auto _biasQuantizedParam = _o->biasQuantizedParam ? CreateQuantizedParam(_fbb, _o->biasQuantizedParam.get(), _rehasher) : 0; auto _depthMultiplier = _o->depthMultiplier; auto _filterQuantizedParam = _o->filterQuantizedParam ? CreateQuantizedParam(_fbb, _o->filterQuantizedParam.get(), _rehasher) : 0; auto _inputQuantizedParam = _o->inputQuantizedParam ? CreateQuantizedParam(_fbb, _o->inputQuantizedParam.get(), _rehasher) : 0; auto _modelFormat = _o->modelFormat; auto _outputQuantizedParam = _o->outputQuantizedParam ? CreateQuantizedParam(_fbb, _o->outputQuantizedParam.get(), _rehasher) : 0; return MNN::CreateTfQuantizedConv2D( _fbb, _bias, _biasflag, _common, _weight, _activationType, _multiplier, _outMax, _outMin, _shift, _biasQuantizedParam, _depthMultiplier, _filterQuantizedParam, _inputQuantizedParam, _modelFormat, _outputQuantizedParam); } inline const flatbuffers::TypeTable *FusedActivationTypeTable() { 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 } }; static const flatbuffers::TypeFunction type_refs[] = { FusedActivationTypeTable }; static const char * const names[] = { "kTfLiteActNone", "kTfLiteActRelu", "kTfLiteActRelu1", "kTfLiteActRelu6", "kTfLiteActTanh", "kTfLiteActSignBit", "kTfLiteActSigmoid" }; static const flatbuffers::TypeTable tt = { flatbuffers::ST_ENUM, 7, type_codes, type_refs, nullptr, names }; return &tt; } inline const flatbuffers::TypeTable *ModeFormatTypeTable() { static const flatbuffers::TypeCode type_codes[] = { { flatbuffers::ET_CHAR, 0, 0 }, { flatbuffers::ET_CHAR, 0, 0 } }; static const flatbuffers::TypeFunction type_refs[] = { ModeFormatTypeTable }; static const char * const names[] = { "TENSORFLOW", "TFLITE" }; static const flatbuffers::TypeTable tt = { flatbuffers::ST_ENUM, 2, type_codes, type_refs, nullptr, names }; return &tt; } inline const flatbuffers::TypeTable *QuantizeModeTypeTable() { static const flatbuffers::TypeCode type_codes[] = { { flatbuffers::ET_CHAR, 0, 0 }, { flatbuffers::ET_CHAR, 0, 0 }, { flatbuffers::ET_CHAR, 0, 0 } }; static const flatbuffers::TypeFunction type_refs[] = { QuantizeModeTypeTable }; static const char * const names[] = { "MIN_COMBINED", "MIN_FIRST", "SCALED" }; static const flatbuffers::TypeTable tt = { flatbuffers::ST_ENUM, 3, type_codes, type_refs, nullptr, names }; return &tt; } inline const flatbuffers::TypeTable *QuantizeRoundModeTypeTable() { static const flatbuffers::TypeCode type_codes[] = { { flatbuffers::ET_CHAR, 0, 0 }, { flatbuffers::ET_CHAR, 0, 0 } }; static const flatbuffers::TypeFunction type_refs[] = { QuantizeRoundModeTypeTable }; static const char * const names[] = { "HALF_AWAY_FROM_ZERO", "HALF_TO_EVEN" }; static const flatbuffers::TypeTable tt = { flatbuffers::ST_ENUM, 2, type_codes, type_refs, nullptr, names }; return &tt; } inline const flatbuffers::TypeTable *QuantizedParamTypeTable() { static const flatbuffers::TypeCode type_codes[] = { { flatbuffers::ET_INT, 0, -1 }, { flatbuffers::ET_FLOAT, 0, -1 } }; static const char * const names[] = { "zeroPoint", "scale" }; static const flatbuffers::TypeTable tt = { flatbuffers::ST_TABLE, 2, type_codes, nullptr, nullptr, names }; return &tt; } inline const flatbuffers::TypeTable *QuantizedAddTypeTable() { static const flatbuffers::TypeCode type_codes[] = { { flatbuffers::ET_CHAR, 0, 0 }, { flatbuffers::ET_SEQUENCE, 0, 1 }, { flatbuffers::ET_SEQUENCE, 0, 1 }, { flatbuffers::ET_SEQUENCE, 0, 1 } }; static const flatbuffers::TypeFunction type_refs[] = { FusedActivationTypeTable, QuantizedParamTypeTable }; static const char * const names[] = { "activationType", "input1QuantizedParam", "input2QuantizedParam", "outputQuantizedParam" }; static const flatbuffers::TypeTable tt = { flatbuffers::ST_TABLE, 4, type_codes, type_refs, nullptr, names }; return &tt; } inline const flatbuffers::TypeTable *DequantizeTypeTable() { static const flatbuffers::TypeCode type_codes[] = { { flatbuffers::ET_SEQUENCE, 0, 0 }, { flatbuffers::ET_CHAR, 0, 1 }, { flatbuffers::ET_CHAR, 0, 2 }, { flatbuffers::ET_INT, 0, 3 } }; static const flatbuffers::TypeFunction type_refs[] = { QuantizedParamTypeTable, QuantizeModeTypeTable, ModeFormatTypeTable, DataTypeTypeTable }; static const char * const names[] = { "inputQuantizedParam", "mode", "modelFormat", "type" }; static const flatbuffers::TypeTable tt = { flatbuffers::ST_TABLE, 4, type_codes, type_refs, nullptr, names }; return &tt; } inline const flatbuffers::TypeTable *QuantizedAvgPoolTypeTable() { static const flatbuffers::TypeCode type_codes[] = { { flatbuffers::ET_INT, 0, -1 }, { flatbuffers::ET_INT, 0, -1 }, { flatbuffers::ET_CHAR, 0, 0 }, { flatbuffers::ET_INT, 0, -1 }, { flatbuffers::ET_INT, 0, -1 }, { flatbuffers::ET_CHAR, 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, 2 } }; static const flatbuffers::TypeFunction type_refs[] = { ModeFormatTypeTable, PoolPadTypeTypeTable, DataTypeTypeTable }; static const char * const names[] = { "kernelX", "kernelY", "modelFormat", "outputActivationMax", "outputActivationMin", "padType", "padX", "padY", "strideX", "strideY", "type" }; static const flatbuffers::TypeTable tt = { flatbuffers::ST_TABLE, 11, type_codes, type_refs, nullptr, names }; return &tt; } inline const flatbuffers::TypeTable *QuantizedBiasAddTypeTable() { static const flatbuffers::TypeCode type_codes[] = { { flatbuffers::ET_INT, 1, -1 }, { flatbuffers::ET_INT, 0, 0 }, { flatbuffers::ET_INT, 0, -1 }, { flatbuffers::ET_INT, 0, -1 }, { flatbuffers::ET_INT, 0, 0 } }; static const flatbuffers::TypeFunction type_refs[] = { DataTypeTypeTable }; static const char * const names[] = { "bias", "inputType", "max", "min", "outputType" }; static const flatbuffers::TypeTable tt = { flatbuffers::ST_TABLE, 5, type_codes, type_refs, nullptr, names }; return &tt; } inline const flatbuffers::TypeTable *QuantizedConcatTypeTable() { static const flatbuffers::TypeCode type_codes[] = { { flatbuffers::ET_CHAR, 0, 0 }, { flatbuffers::ET_INT, 0, -1 }, { flatbuffers::ET_FLOAT, 1, -1 }, { flatbuffers::ET_INT, 1, -1 }, { flatbuffers::ET_SEQUENCE, 0, 1 } }; static const flatbuffers::TypeFunction type_refs[] = { FusedActivationTypeTable, QuantizedParamTypeTable }; static const char * const names[] = { "activationType", "axis", "inputScale", "inputZeroPoint", "outputQuantizedParam" }; static const flatbuffers::TypeTable tt = { flatbuffers::ST_TABLE, 5, type_codes, type_refs, nullptr, names }; return &tt; } inline const flatbuffers::TypeTable *QuantizedLogisticTypeTable() { static const flatbuffers::TypeCode type_codes[] = { { flatbuffers::ET_SEQUENCE, 0, 0 }, { flatbuffers::ET_SEQUENCE, 0, 0 } }; static const flatbuffers::TypeFunction type_refs[] = { QuantizedParamTypeTable }; static const char * const names[] = { "inputQuantizedParam", "outputQuantizedParam" }; static const flatbuffers::TypeTable tt = { flatbuffers::ST_TABLE, 2, type_codes, type_refs, nullptr, names }; return &tt; } inline const flatbuffers::TypeTable *QuantizedMatMulTypeTable() { static const flatbuffers::TypeCode type_codes[] = { { flatbuffers::ET_BOOL, 0, -1 }, { flatbuffers::ET_BOOL, 0, -1 } }; static const char * const names[] = { "transposeA", "transposeB" }; static const flatbuffers::TypeTable tt = { flatbuffers::ST_TABLE, 2, type_codes, nullptr, nullptr, names }; return &tt; } inline const flatbuffers::TypeTable *QuantizedMaxPoolTypeTable() { static const flatbuffers::TypeCode type_codes[] = { { flatbuffers::ET_INT, 0, -1 }, { flatbuffers::ET_INT, 0, -1 }, { flatbuffers::ET_CHAR, 0, 0 }, { flatbuffers::ET_INT, 0, -1 }, { flatbuffers::ET_INT, 0, -1 }, { flatbuffers::ET_CHAR, 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, 2 } }; static const flatbuffers::TypeFunction type_refs[] = { ModeFormatTypeTable, PoolPadTypeTypeTable, DataTypeTypeTable }; static const char * const names[] = { "kernelX", "kernelY", "modelFormat", "outputActivationMax", "outputActivationMin", "padType", "padX", "padY", "strideX", "strideY", "type" }; static const flatbuffers::TypeTable tt = { flatbuffers::ST_TABLE, 11, type_codes, type_refs, nullptr, names }; return &tt; } inline const flatbuffers::TypeTable *QuantizedReluTypeTable() { static const flatbuffers::TypeCode type_codes[] = { { flatbuffers::ET_INT, 0, 0 } }; static const flatbuffers::TypeFunction type_refs[] = { DataTypeTypeTable }; static const char * const names[] = { "type" }; static const flatbuffers::TypeTable tt = { flatbuffers::ST_TABLE, 1, type_codes, type_refs, nullptr, names }; return &tt; } inline const flatbuffers::TypeTable *QuantizedRelu6TypeTable() { static const flatbuffers::TypeCode type_codes[] = { { flatbuffers::ET_INT, 0, 0 } }; static const flatbuffers::TypeFunction type_refs[] = { DataTypeTypeTable }; static const char * const names[] = { "type" }; static const flatbuffers::TypeTable tt = { flatbuffers::ST_TABLE, 1, type_codes, type_refs, nullptr, names }; return &tt; } inline const flatbuffers::TypeTable *QuantizedReshapeTypeTable() { static const flatbuffers::TypeCode type_codes[] = { { flatbuffers::ET_INT, 1, -1 }, { flatbuffers::ET_CHAR, 0, 0 } }; static const flatbuffers::TypeFunction type_refs[] = { ModeFormatTypeTable }; static const char * const names[] = { "dims", "modelFormat" }; static const flatbuffers::TypeTable tt = { flatbuffers::ST_TABLE, 2, type_codes, type_refs, nullptr, names }; return &tt; } inline const flatbuffers::TypeTable *QuantizedSoftmaxTypeTable() { static const flatbuffers::TypeCode type_codes[] = { { flatbuffers::ET_FLOAT, 0, -1 }, { flatbuffers::ET_FLOAT, 0, -1 } }; static const char * const names[] = { "beta", "inputScale" }; static const flatbuffers::TypeTable tt = { flatbuffers::ST_TABLE, 2, type_codes, nullptr, nullptr, names }; return &tt; } inline const flatbuffers::TypeTable *QuantizeV2TypeTable() { static const flatbuffers::TypeCode type_codes[] = { { flatbuffers::ET_INT, 0, 0 }, { flatbuffers::ET_CHAR, 0, 1 }, { flatbuffers::ET_CHAR, 0, 2 } }; static const flatbuffers::TypeFunction type_refs[] = { DataTypeTypeTable, QuantizeModeTypeTable, QuantizeRoundModeTypeTable }; static const char * const names[] = { "type", "mode", "roundMode" }; static const flatbuffers::TypeTable tt = { flatbuffers::ST_TABLE, 3, type_codes, type_refs, nullptr, names }; return &tt; } inline const flatbuffers::TypeTable *RequantizationRangeTypeTable() { static const flatbuffers::TypeTable tt = { flatbuffers::ST_TABLE, 0, nullptr, nullptr, nullptr, nullptr }; return &tt; } inline const flatbuffers::TypeTable *RequantizeTypeTable() { static const flatbuffers::TypeTable tt = { flatbuffers::ST_TABLE, 0, nullptr, nullptr, nullptr, nullptr }; return &tt; } inline const flatbuffers::TypeTable *TfQuantizedConv2DTypeTable() { static const flatbuffers::TypeCode type_codes[] = { { flatbuffers::ET_INT, 1, -1 }, { flatbuffers::ET_BOOL, 0, -1 }, { flatbuffers::ET_SEQUENCE, 0, 0 }, { flatbuffers::ET_UCHAR, 1, -1 }, { flatbuffers::ET_CHAR, 0, 1 }, { flatbuffers::ET_INT, 0, -1 }, { flatbuffers::ET_INT, 0, -1 }, { flatbuffers::ET_INT, 0, -1 }, { flatbuffers::ET_INT, 0, -1 }, { flatbuffers::ET_SEQUENCE, 0, 2 }, { flatbuffers::ET_INT, 0, -1 }, { flatbuffers::ET_SEQUENCE, 0, 2 }, { flatbuffers::ET_SEQUENCE, 0, 2 }, { flatbuffers::ET_CHAR, 0, 3 }, { flatbuffers::ET_SEQUENCE, 0, 2 } }; static const flatbuffers::TypeFunction type_refs[] = { Convolution2DCommonTypeTable, FusedActivationTypeTable, QuantizedParamTypeTable, ModeFormatTypeTable }; static const char * const names[] = { "bias", "biasflag", "common", "weight", "activationType", "multiplier", "outMax", "outMin", "shift", "biasQuantizedParam", "depthMultiplier", "filterQuantizedParam", "inputQuantizedParam", "modelFormat", "outputQuantizedParam" }; static const flatbuffers::TypeTable tt = { flatbuffers::ST_TABLE, 15, type_codes, type_refs, nullptr, names }; return &tt; } } // namespace MNN #endif // FLATBUFFERS_GENERATED_TFQUANTIZEOP_MNN_H_