/* * Copyright (C) 2017 The Android Open Source Project * * Licensed under the Apache License, Version 2.0 (the "License"); * you may not use this file except in compliance with the License. * You may obtain a copy of the License at * * http://www.apache.org/licenses/LICENSE-2.0 * * Unless required by applicable law or agreed to in writing, software * distributed under the License is distributed on an "AS IS" BASIS, * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. * See the License for the specific language governing permissions and * limitations under the License. */ #define LOG_TAG "Operations" #include "DepthwiseConv2D.h" #include #include #include "OperationResolver.h" #include "Operations.h" #include "Tracing.h" #ifdef NN_INCLUDE_CPU_IMPLEMENTATION #pragma clang diagnostic push #pragma clang diagnostic ignored "-Wunused-parameter" #include #include #pragma clang diagnostic pop #include "CpuOperationUtils.h" #endif // NN_INCLUDE_CPU_IMPLEMENTATION namespace android { namespace nn { namespace depthwise_conv_2d { #ifdef NN_INCLUDE_CPU_IMPLEMENTATION namespace { struct DepthwiseConv2dParam { int32_t padding_left, padding_right; int32_t padding_top, padding_bottom; int32_t stride_width, stride_height; int32_t dilation_width_factor = 1, dilation_height_factor = 1; int32_t depth_multiplier; int32_t activation; bool useNchw = false; bool initialize(const IOperationExecutionContext* context) { uint32_t inCount = context->getNumInputs(); int32_t padding_implicit = 0; bool useImplicitPadding = false; if ((inCount >= 9 && context->getInputType(8) == OperandType::BOOL) || inCount == 8) { padding_implicit = context->getInputValue(3); stride_width = context->getInputValue(4); stride_height = context->getInputValue(5); depth_multiplier = context->getInputValue(6); activation = context->getInputValue(7); if (inCount >= 9) { useNchw = context->getInputValue(8); } if (inCount == 11) { dilation_width_factor = context->getInputValue(9); dilation_height_factor = context->getInputValue(10); } useImplicitPadding = true; } else if (inCount >= 11 && context->getInputType(8) == OperandType::INT32) { padding_left = context->getInputValue(3); padding_right = context->getInputValue(4); padding_top = context->getInputValue(5); padding_bottom = context->getInputValue(6); stride_width = context->getInputValue(7); stride_height = context->getInputValue(8); depth_multiplier = context->getInputValue(9); activation = context->getInputValue(10); if (inCount >= 12) { useNchw = context->getInputValue(11); } if (inCount == 14) { dilation_width_factor = context->getInputValue(12); dilation_height_factor = context->getInputValue(13); } } else { NN_RET_CHECK_FAIL() << "Unsupported input spec for operation " << kOperationName; } if (useImplicitPadding) { Shape inputShape = context->getInputShape(kInputTensor); Shape filterShape = context->getInputShape(kFilterTensor); int32_t input_width = getSizeOfDimension(inputShape, useNchw ? 3 : 2); int32_t input_height = getSizeOfDimension(inputShape, useNchw ? 2 : 1); int32_t filter_width = getSizeOfDimension(filterShape, 2); int32_t filter_height = getSizeOfDimension(filterShape, 1); calculateExplicitPadding(input_width, stride_width, dilation_width_factor, filter_width, padding_implicit, &padding_left, &padding_right); calculateExplicitPadding(input_height, stride_height, dilation_height_factor, filter_height, padding_implicit, &padding_top, &padding_bottom); } NN_RET_CHECK_GE(padding_left, 0); NN_RET_CHECK_GE(padding_right, 0); NN_RET_CHECK_GE(padding_top, 0); NN_RET_CHECK_GE(padding_bottom, 0); NN_RET_CHECK_GT(stride_width, 0); NN_RET_CHECK_GT(stride_height, 0); NN_RET_CHECK_GT(dilation_width_factor, 0); NN_RET_CHECK_GT(dilation_height_factor, 0); NN_RET_CHECK_GT(depth_multiplier, 0); NN_RET_CHECK_GE(activation, 0); return true; } }; #define ANDROID_NN_DEPTHWISE_CONV_PARAMETERS \ [[maybe_unused]] uint32_t height = getSizeOfDimension(inputShape, 1); \ [[maybe_unused]] uint32_t width = getSizeOfDimension(inputShape, 2); \ [[maybe_unused]] uint32_t filterHeight = getSizeOfDimension(filterShape, 1); \ [[maybe_unused]] uint32_t filterWidth = getSizeOfDimension(filterShape, 2); \ [[maybe_unused]] uint32_t outHeight = getSizeOfDimension(outputShape, 1); \ [[maybe_unused]] uint32_t outWidth = getSizeOfDimension(outputShape, 2); \ \ uint32_t paddingHeight = (uint32_t)paddingTop; \ uint32_t paddingWidth = (uint32_t)paddingLeft; bool depthwiseConvNhwc(const float* inputData, const Shape& inputShape, const float* filterData, const Shape& filterShape, const float* biasData, const Shape& biasShape, int32_t paddingLeft, int32_t /*paddingRight*/, int32_t paddingTop, int32_t /*paddingBottom*/, int32_t strideWidth, int32_t strideHeight, int32_t dilationWidthFactor, int32_t dilationHeightFactor, int32_t depthMultiplier, int32_t activation, float* outputData, const Shape& outputShape) { NNTRACE_TRANS("depthwiseConvFloat32"); ANDROID_NN_DEPTHWISE_CONV_PARAMETERS float output_activation_min, output_activation_max; CalculateActivationRangeFloat(activation, &output_activation_min, &output_activation_max); tflite::DepthwiseParams params{ .padding_values = {static_cast(paddingWidth), static_cast(paddingHeight), 0 /*width_offset*/, 0 /*height_offset*/}, .stride_width = static_cast(strideWidth), .stride_height = static_cast(strideHeight), .dilation_width_factor = static_cast(dilationWidthFactor), .dilation_height_factor = static_cast(dilationHeightFactor), .depth_multiplier = static_cast(depthMultiplier), .float_activation_min = output_activation_min, .float_activation_max = output_activation_max, }; NNTRACE_COMP_SWITCH("optimized_ops::DepthwiseConv"); tflite::reference_ops::DepthwiseConv(params, convertShapeToTflshape(inputShape), inputData, convertShapeToTflshape(filterShape), filterData, convertShapeToTflshape(biasShape), biasData, convertShapeToTflshape(outputShape), outputData); return true; } bool depthwiseConvNhwc(const _Float16* inputData, const Shape& inputShape, const _Float16* filterData, const Shape& filterShape, const _Float16* biasData, const Shape& biasShape, int32_t paddingLeft, int32_t paddingRight, int32_t paddingTop, int32_t paddingBottom, int32_t strideWidth, int32_t strideHeight, int32_t dilationWidthFactor, int32_t dilationHeightFactor, int32_t depthMultiplier, int32_t activation, _Float16* outputData, const Shape& outputShape) { NNTRACE_TRANS("depthwiseConvFloat16"); std::vector inputDataFloat32(getNumberOfElements(inputShape)); convertFloat16ToFloat32(inputData, &inputDataFloat32); std::vector filterDataFloat32(getNumberOfElements(filterShape)); convertFloat16ToFloat32(filterData, &filterDataFloat32); std::vector biasDataFloat32(getNumberOfElements(biasShape)); convertFloat16ToFloat32(biasData, &biasDataFloat32); std::vector outputDataFloat32(getNumberOfElements(outputShape)); depthwiseConvNhwc(inputDataFloat32.data(), inputShape, filterDataFloat32.data(), filterShape, biasDataFloat32.data(), biasShape, paddingLeft, paddingRight, paddingTop, paddingBottom, strideWidth, strideHeight, dilationWidthFactor, dilationHeightFactor, depthMultiplier, activation, outputDataFloat32.data(), outputShape); convertFloat32ToFloat16(outputDataFloat32, outputData); return true; } bool depthwiseConvNhwc(const uint8_t* inputData, const Shape& inputShape, const uint8_t* filterData, const Shape& filterShape, const int32_t* biasData, const Shape& biasShape, int32_t paddingLeft, int32_t /*paddingRight*/, int32_t paddingTop, int32_t /*paddingBottom*/, int32_t strideWidth, int32_t strideHeight, int32_t dilationWidthFactor, int32_t dilationHeightFactor, int32_t depthMultiplier, int32_t activation, uint8_t* outputData, const Shape& outputShape) { NNTRACE_TRANS("depthwiseConvQuant8"); ANDROID_NN_DEPTHWISE_CONV_PARAMETERS double real_multiplier = 0.0; int32_t output_multiplier = 0; int32_t output_shift = 0; int32_t output_activation_min = 0; int32_t output_activation_max = 0; NN_RET_CHECK(GetQuantizedConvolutionMultiplier(inputShape, filterShape, biasShape, outputShape, &real_multiplier)); int exponent; NN_RET_CHECK(QuantizeMultiplier(real_multiplier, &output_multiplier, &exponent)); output_shift = -exponent; CalculateActivationRangeUint8(activation, outputShape, &output_activation_min, &output_activation_max); tflite::DepthwiseParams params{ .padding_values = {static_cast(paddingWidth), static_cast(paddingHeight), 0 /*width_offset*/, 0 /*height_offset*/}, .stride_width = static_cast(strideWidth), .stride_height = static_cast(strideHeight), .dilation_width_factor = static_cast(dilationWidthFactor), .dilation_height_factor = static_cast(dilationHeightFactor), .depth_multiplier = static_cast(depthMultiplier), .input_offset = -inputShape.offset, .weights_offset = -filterShape.offset, .output_offset = outputShape.offset, .output_multiplier = output_multiplier, .output_shift = -output_shift, .quantized_activation_min = output_activation_min, .quantized_activation_max = output_activation_max, }; NNTRACE_COMP_SWITCH("optimized_ops::DepthwiseConv"); tflite::reference_ops::DepthwiseConv(params, convertShapeToTflshape(inputShape), inputData, convertShapeToTflshape(filterShape), filterData, convertShapeToTflshape(biasShape), biasData, convertShapeToTflshape(outputShape), outputData); return true; } // Passing input, filter and output shapes by value, so that we can change the // offsets without modifying the actual shapes. bool depthwiseConvNhwc(const int8_t* inputData, Shape inputShape, const int8_t* filterData, Shape filterShape, const int32_t* biasData, const Shape& biasShape, int32_t paddingLeft, int32_t paddingRight, int32_t paddingTop, int32_t paddingBottom, int32_t strideWidth, int32_t strideHeight, int32_t dilationWidthFactor, int32_t dilationHeightFactor, int32_t depthMultiplier, int32_t activation, int8_t* outputData, Shape outputShape) { NNTRACE_TRANS("depthwiseConvQuant8"); std::vector unsignedInput(getNumberOfElements(inputShape)); convertInt8ToUInt8(inputData, &unsignedInput); inputShape.offset += 128; std::vector unsignedFilter(getNumberOfElements(filterShape)); convertInt8ToUInt8(filterData, &unsignedFilter); filterShape.offset += 128; std::vector unsignedOutput(getNumberOfElements(outputShape)); outputShape.offset += 128; NN_RET_CHECK(depthwiseConvNhwc(unsignedInput.data(), inputShape, unsignedFilter.data(), filterShape, biasData, biasShape, paddingLeft, paddingRight, paddingTop, paddingBottom, strideWidth, strideHeight, dilationWidthFactor, dilationHeightFactor, depthMultiplier, activation, unsignedOutput.data(), outputShape)); convertUInt8ToInt8(unsignedOutput, outputData); return true; } template bool depthwiseConvQuant8PerChannelNhwc( const T* inputData, const Shape& inputShape, const int8_t* filterData, const Shape& filterShape, const float* filterScales, const int32_t* biasData, const Shape& biasShape, int32_t paddingLeft, int32_t /*paddingRight*/, int32_t paddingTop, int32_t /*paddingBottom*/, int32_t strideWidth, int32_t strideHeight, int32_t dilationWidthFactor, int32_t dilationHeightFactor, int32_t depthMultiplier, int32_t activation, T* outputData, const Shape& outputShape) { NNTRACE_TRANS("depthwiseConvQuant8"); [[maybe_unused]] uint32_t paddingHeight = (uint32_t)paddingTop; [[maybe_unused]] uint32_t paddingWidth = (uint32_t)paddingLeft; uint32_t numBatches = getSizeOfDimension(inputShape, 0); uint32_t inputHeight = getSizeOfDimension(inputShape, 1); uint32_t inputWidth = getSizeOfDimension(inputShape, 2); uint32_t inputDepth = getSizeOfDimension(inputShape, 3); uint32_t filterHeight = getSizeOfDimension(filterShape, 1); uint32_t filterWidth = getSizeOfDimension(filterShape, 2); uint32_t filterDepth = getSizeOfDimension(filterShape, 3); uint32_t outputHeight = getSizeOfDimension(outputShape, 1); uint32_t outputWidth = getSizeOfDimension(outputShape, 2); uint32_t outputDepth = getSizeOfDimension(outputShape, 3); int32_t inputOffset = -inputShape.offset; int32_t outputOffset = outputShape.offset; auto realMultiplier = std::vector(outputDepth, .0f); auto outputMultiplier = std::vector(outputDepth, 0); auto outputShift = std::vector(outputDepth, .0f); for (uint32_t i = 0; i < outputDepth; ++i) { Shape filterChannelShape = filterShape; filterChannelShape.scale = filterScales[i]; Shape biasChannelShape = biasShape; biasChannelShape.scale = filterScales[i] * inputShape.scale; NN_RET_CHECK(GetQuantizedConvolutionMultiplier( inputShape, filterChannelShape, biasChannelShape, outputShape, &realMultiplier[i])); int exponent; NN_RET_CHECK(QuantizeMultiplier(realMultiplier[i], &outputMultiplier[i], &exponent)); outputShift[i] = -exponent; } int32_t output_activation_min = 0, output_activation_max = 0; CalculateActivationRange(activation, outputShape, &output_activation_min, &output_activation_max); const T* inputBase = inputData; T* outPtr = outputData; for (uint32_t b = 0; b < numBatches; b++) { for (uint32_t h = 0; h < outputHeight; h++) { for (uint32_t w = 0; w < outputWidth; w++) { for (uint32_t ic = 0; ic < inputDepth; ic++) { for (int32_t m = 0; m < depthMultiplier; m++) { int32_t wInputOrigin = static_cast(w) * strideWidth - paddingLeft; int32_t hInputOrigin = static_cast(h) * strideHeight - paddingTop; const int oc = m + ic * depthMultiplier; int32_t sum = 0.0f; for (uint32_t i = 0; i < filterHeight; i++) { for (uint32_t j = 0; j < filterWidth; j++) { int32_t hInput = hInputOrigin + dilationHeightFactor * static_cast(i); int32_t wInput = wInputOrigin + dilationWidthFactor * static_cast(j); if (hInput >= 0 && hInput < static_cast(inputHeight) && wInput >= 0 && wInput < static_cast(inputWidth)) { uint32_t filterIndex = i * filterWidth * filterDepth + j * filterDepth + oc; uint32_t inputIndex = hInput * inputWidth * inputDepth + wInput * inputDepth + ic; sum += (static_cast(filterData[filterIndex])) * (static_cast(inputBase[inputIndex]) + inputOffset); } } } sum += biasData[oc]; sum = tflite::MultiplyByQuantizedMultiplier(sum, outputMultiplier[oc], -outputShift[oc]); sum += outputOffset; sum = std::max(std::min(sum, output_activation_max), output_activation_min); outPtr[m] = static_cast(sum); } outPtr += depthMultiplier; } } } inputBase += inputHeight * inputWidth * inputDepth; } return true; } template bool depthwiseConv(const T_Input* inputData, const Shape& inputShape, const T_Filter* filterData, const Shape& filterShape, const T_Bias* biasData, const Shape& biasShape, int32_t paddingLeft, int32_t paddingRight, int32_t paddingTop, int32_t paddingBottom, int32_t strideWidth, int32_t strideHeight, int32_t dilationWidthFactor, int32_t dilationHeightFactor, int32_t depthMultiplier, int32_t activation, bool useNchw, T_Input* outputData, const Shape& outputShape) { InputWithLayout input(useNchw); OutputWithLayout output(useNchw); NN_RET_CHECK(input.initialize(inputData, inputShape)); NN_RET_CHECK(output.initialize(outputData, outputShape)); NN_RET_CHECK(depthwiseConvNhwc(input.getNhwcBuffer(), input.getNhwcShape(), filterData, filterShape, biasData, biasShape, paddingLeft, paddingRight, paddingTop, paddingBottom, strideWidth, strideHeight, dilationWidthFactor, dilationHeightFactor, depthMultiplier, activation, output.getNhwcBuffer(), output.getNhwcShape())); NN_RET_CHECK(output.commit()); return true; } template bool depthwiseConvQuant8PerChannel(const T* inputData, const Shape& inputShape, const int8_t* filterData, const Shape& filterShape, const float* filterScales, const int32_t* biasData, const Shape& biasShape, int32_t paddingLeft, int32_t paddingRight, int32_t paddingTop, int32_t paddingBottom, int32_t strideWidth, int32_t strideHeight, int32_t dilationWidthFactor, int32_t dilationHeightFactor, int32_t depthMultiplier, int32_t activation, bool useNchw, T* outputData, const Shape& outputShape) { InputWithLayout input(useNchw); OutputWithLayout output(useNchw); NN_RET_CHECK(input.initialize(inputData, inputShape)); NN_RET_CHECK(output.initialize(outputData, outputShape)); NN_RET_CHECK(depthwiseConvQuant8PerChannelNhwc( input.getNhwcBuffer(), input.getNhwcShape(), filterData, filterShape, filterScales, biasData, biasShape, paddingLeft, paddingRight, paddingTop, paddingBottom, strideWidth, strideHeight, dilationWidthFactor, dilationHeightFactor, depthMultiplier, activation, output.getNhwcBuffer(), output.getNhwcShape())); NN_RET_CHECK(output.commit()); return true; } #undef ANDROID_NN_DEPTHWISE_CONV_PARAMETERS } // namespace bool prepare(IOperationExecutionContext* context) { Shape input = context->getInputShape(kInputTensor); Shape filter = context->getInputShape(kFilterTensor); Shape bias = context->getInputShape(kBiasTensor); if (filter.type == OperandType::TENSOR_QUANT8_SYMM_PER_CHANNEL) { NN_RET_CHECK(input.type == OperandType::TENSOR_QUANT8_ASYMM || input.type == OperandType::TENSOR_QUANT8_ASYMM_SIGNED); } else { NN_RET_CHECK(input.type == filter.type); } if (input.type == OperandType::TENSOR_QUANT8_ASYMM || input.type == OperandType::TENSOR_QUANT8_ASYMM_SIGNED) { NN_RET_CHECK(bias.type == OperandType::TENSOR_INT32); } else { NN_RET_CHECK(input.type == bias.type); } NN_RET_CHECK_EQ(getNumberOfDimensions(input), 4u); NN_RET_CHECK_EQ(getNumberOfDimensions(filter), 4u); NN_RET_CHECK_EQ(getNumberOfDimensions(bias), 1u); NN_RET_CHECK_EQ(getSizeOfDimension(filter, 0), 1u); NN_RET_CHECK_EQ(getSizeOfDimension(filter, 3), getSizeOfDimension(bias, 0)); DepthwiseConv2dParam param; NN_RET_CHECK(param.initialize(context)); uint32_t batches = getSizeOfDimension(input, 0); uint32_t height = getSizeOfDimension(input, param.useNchw ? 2 : 1); uint32_t width = getSizeOfDimension(input, param.useNchw ? 3 : 2); uint32_t channels_in = getSizeOfDimension(input, param.useNchw ? 1 : 3); uint32_t channels_out = getSizeOfDimension(filter, 3); uint32_t filterHeight = getSizeOfDimension(filter, 1); uint32_t filterWidth = getSizeOfDimension(filter, 2); NN_OPS_CHECK(param.depth_multiplier * channels_in == channels_out); int32_t effectiveFilterWidth = (filterWidth - 1) * param.dilation_width_factor + 1; int32_t effectiveFilterHeight = (filterHeight - 1) * param.dilation_height_factor + 1; NN_RET_CHECK_GT(effectiveFilterWidth, param.padding_left); NN_RET_CHECK_GT(effectiveFilterWidth, param.padding_right); NN_RET_CHECK_GT(effectiveFilterHeight, param.padding_top); NN_RET_CHECK_GT(effectiveFilterHeight, param.padding_bottom); uint32_t outHeight = computeOutSize(height, filterHeight, param.stride_height, param.dilation_height_factor, param.padding_top, param.padding_bottom); uint32_t outWidth = computeOutSize(width, filterWidth, param.stride_width, param.dilation_width_factor, param.padding_left, param.padding_right); Shape output = context->getOutputShape(kOutputTensor); output.type = input.type; if (param.useNchw) { output.dimensions = {batches, channels_out, outHeight, outWidth}; } else { output.dimensions = {batches, outHeight, outWidth, channels_out}; } return context->setOutputShape(kOutputTensor, output); } bool execute(IOperationExecutionContext* context) { // Bypass execution in the case of zero-sized input. if (getNumberOfElements(context->getOutputShape(kOutputTensor)) == 0) return true; DepthwiseConv2dParam param; NN_RET_CHECK(param.initialize(context)); switch (context->getInputType(kInputTensor)) { case OperandType::TENSOR_FLOAT32: return depthwiseConv(context->getInputBuffer(kInputTensor), context->getInputShape(kInputTensor), context->getInputBuffer(kFilterTensor), context->getInputShape(kFilterTensor), context->getInputBuffer(kBiasTensor), context->getInputShape(kBiasTensor), param.padding_left, param.padding_right, param.padding_top, param.padding_bottom, param.stride_width, param.stride_height, param.dilation_width_factor, param.dilation_height_factor, param.depth_multiplier, param.activation, param.useNchw, context->getOutputBuffer(kOutputTensor), context->getOutputShape(kOutputTensor)); case OperandType::TENSOR_FLOAT16: return depthwiseConv(context->getInputBuffer<_Float16>(kInputTensor), context->getInputShape(kInputTensor), context->getInputBuffer<_Float16>(kFilterTensor), context->getInputShape(kFilterTensor), context->getInputBuffer<_Float16>(kBiasTensor), context->getInputShape(kBiasTensor), param.padding_left, param.padding_right, param.padding_top, param.padding_bottom, param.stride_width, param.stride_height, param.dilation_width_factor, param.dilation_height_factor, param.depth_multiplier, param.activation, param.useNchw, context->getOutputBuffer<_Float16>(kOutputTensor), context->getOutputShape(kOutputTensor)); case OperandType::TENSOR_QUANT8_ASYMM: if (context->getInputType(kFilterTensor) == OperandType::TENSOR_QUANT8_SYMM_PER_CHANNEL) { return depthwiseConvQuant8PerChannel( context->getInputBuffer(kInputTensor), context->getInputShape(kInputTensor), context->getInputBuffer(kFilterTensor), context->getInputShape(kFilterTensor), std::get( context->getInputExtraParams(kFilterTensor)) .scales.data(), context->getInputBuffer(kBiasTensor), context->getInputShape(kBiasTensor), param.padding_left, param.padding_right, param.padding_top, param.padding_bottom, param.stride_width, param.stride_height, param.dilation_width_factor, param.dilation_height_factor, param.depth_multiplier, param.activation, param.useNchw, context->getOutputBuffer(kOutputTensor), context->getOutputShape(kOutputTensor)); } else if (context->getInputType(kFilterTensor) == OperandType::TENSOR_QUANT8_ASYMM) { return depthwiseConv(context->getInputBuffer(kInputTensor), context->getInputShape(kInputTensor), context->getInputBuffer(kFilterTensor), context->getInputShape(kFilterTensor), context->getInputBuffer(kBiasTensor), context->getInputShape(kBiasTensor), param.padding_left, param.padding_right, param.padding_top, param.padding_bottom, param.stride_width, param.stride_height, param.dilation_width_factor, param.dilation_height_factor, param.depth_multiplier, param.activation, param.useNchw, context->getOutputBuffer(kOutputTensor), context->getOutputShape(kOutputTensor)); } else { NN_RET_CHECK_FAIL() << "Unsupported filter type for operation " << kOperationName; } case OperandType::TENSOR_QUANT8_ASYMM_SIGNED: if (context->getInputType(kFilterTensor) == OperandType::TENSOR_QUANT8_SYMM_PER_CHANNEL) { return depthwiseConvQuant8PerChannel( context->getInputBuffer(kInputTensor), context->getInputShape(kInputTensor), context->getInputBuffer(kFilterTensor), context->getInputShape(kFilterTensor), std::get( context->getInputExtraParams(kFilterTensor)) .scales.data(), context->getInputBuffer(kBiasTensor), context->getInputShape(kBiasTensor), param.padding_left, param.padding_right, param.padding_top, param.padding_bottom, param.stride_width, param.stride_height, param.dilation_width_factor, param.dilation_height_factor, param.depth_multiplier, param.activation, param.useNchw, context->getOutputBuffer(kOutputTensor), context->getOutputShape(kOutputTensor)); } else if (context->getInputType(kFilterTensor) == OperandType::TENSOR_QUANT8_ASYMM_SIGNED) { return depthwiseConv(context->getInputBuffer(kInputTensor), context->getInputShape(kInputTensor), context->getInputBuffer(kFilterTensor), context->getInputShape(kFilterTensor), context->getInputBuffer(kBiasTensor), context->getInputShape(kBiasTensor), param.padding_left, param.padding_right, param.padding_top, param.padding_bottom, param.stride_width, param.stride_height, param.dilation_width_factor, param.dilation_height_factor, param.depth_multiplier, param.activation, param.useNchw, context->getOutputBuffer(kOutputTensor), context->getOutputShape(kOutputTensor)); } else { NN_RET_CHECK_FAIL() << "Unsupported filter type for operation " << kOperationName; } default: NN_RET_CHECK_FAIL() << "Unsupported tensor type for operation " << kOperationName; } } #endif // NN_INCLUDE_CPU_IMPLEMENTATION } // namespace depthwise_conv_2d NN_REGISTER_OPERATION_DEFAULT_VALIDATION(DEPTHWISE_CONV_2D, depthwise_conv_2d::prepare, depthwise_conv_2d::execute, .allowZeroSizedInput = true); } // namespace nn } // namespace android