// Tencent is pleased to support the open source community by making ncnn available. // // Copyright (C) 2017 THL A29 Limited, a Tencent company. All rights reserved. // // Licensed under the BSD 3-Clause License (the "License"); you may not use this file except // in compliance with the License. You may obtain a copy of the License at // // https://opensource.org/licenses/BSD-3-Clause // // 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. #include "convolutiondepthwise.h" #include "layer_type.h" #include "fused_activation.h" namespace ncnn { ConvolutionDepthWise::ConvolutionDepthWise() { one_blob_only = true; support_inplace = false; } int ConvolutionDepthWise::load_param(const ParamDict& pd) { num_output = pd.get(0, 0); kernel_w = pd.get(1, 0); kernel_h = pd.get(11, kernel_w); dilation_w = pd.get(2, 1); dilation_h = pd.get(12, dilation_w); stride_w = pd.get(3, 1); stride_h = pd.get(13, stride_w); pad_left = pd.get(4, 0); pad_right = pd.get(15, pad_left); pad_top = pd.get(14, pad_left); pad_bottom = pd.get(16, pad_top); pad_value = pd.get(18, 0.f); bias_term = pd.get(5, 0); weight_data_size = pd.get(6, 0); group = pd.get(7, 1); int8_scale_term = pd.get(8, 0); activation_type = pd.get(9, 0); activation_params = pd.get(10, Mat()); dynamic_weight = pd.get(19, 0); if (dynamic_weight) { one_blob_only = false; } if (num_output % group != 0) { // reject invalid group return -100; } if (int8_scale_term) { #if NCNN_INT8 support_int8_storage = true; #else NCNN_LOGE("please build ncnn with NCNN_INT8 enabled for int8 inference"); return -1; #endif } return 0; } int ConvolutionDepthWise::load_model(const ModelBin& mb) { if (dynamic_weight) return 0; weight_data = mb.load(weight_data_size, 0); if (weight_data.empty()) return -100; if (bias_term) { bias_data = mb.load(num_output, 1); if (bias_data.empty()) return -100; } #if NCNN_INT8 if (int8_scale_term == 1 || int8_scale_term == 101) { weight_data_int8_scales = mb.load(group, 1); bottom_blob_int8_scales = mb.load(1, 1); float bottom_blob_int8_scale = bottom_blob_int8_scales[0]; bottom_blob_int8_scales = Mat(group); bottom_blob_int8_scales.fill(bottom_blob_int8_scale); } else if (int8_scale_term == 2 || int8_scale_term == 102) { weight_data_int8_scales = mb.load(1, 1); bottom_blob_int8_scales = mb.load(1, 1); // extend group if only one provided float weight_data_int8_scale = weight_data_int8_scales[0]; weight_data_int8_scales = Mat(group); weight_data_int8_scales.fill(weight_data_int8_scale); float bottom_blob_int8_scale = bottom_blob_int8_scales[0]; bottom_blob_int8_scales = Mat(group); bottom_blob_int8_scales.fill(bottom_blob_int8_scale); } if (int8_scale_term > 100) { top_blob_int8_scales = mb.load(1, 1); float top_blob_int8_scale = top_blob_int8_scales[0]; top_blob_int8_scales = Mat(group); top_blob_int8_scales.fill(top_blob_int8_scale); } #endif // NCNN_INT8 return 0; } int ConvolutionDepthWise::create_pipeline(const Option& opt) { #if NCNN_INT8 // runtime quantize the weight data if (opt.use_int8_inference && weight_data.elemsize == (size_t)4u && int8_scale_term) { Mat int8_weight_data(weight_data_size, (size_t)1u); if (int8_weight_data.empty()) return -100; const int weight_data_size_g = weight_data_size / group; for (int g = 0; g < group; g++) { Option opt_q = opt; opt_q.blob_allocator = int8_weight_data.allocator; opt_q.use_packing_layout = false; const Mat weight_data_g = weight_data.range(weight_data_size_g * g, weight_data_size_g); Mat int8_weight_data_g = int8_weight_data.range(weight_data_size_g * g, weight_data_size_g); const Mat weight_data_int8_scales_g = weight_data_int8_scales.range(g, 1); quantize_to_int8(weight_data_g, int8_weight_data_g, weight_data_int8_scales_g, opt_q); } weight_data = int8_weight_data; } #else (void)(opt); #endif // NCNN_INT8 return 0; } static int convolutiondepthwise(const Mat& bottom_blob, Mat& top_blob, const Mat& weight_data, const Mat& bias_data, int kernel_w, int kernel_h, int stride_w, int stride_h, int dilation_w, int dilation_h, int group, int activation_type, const Mat& activation_params, const Option& opt) { const int w = bottom_blob.w; const int inch = bottom_blob.c; const int outw = top_blob.w; const int outh = top_blob.h; const int outch = top_blob.c; const int bias_term = bias_data.empty() ? 0 : 1; const int maxk = kernel_w * kernel_h; // kernel offsets std::vector _space_ofs(maxk); int* space_ofs = &_space_ofs[0]; { int p1 = 0; int p2 = 0; int gap = w * dilation_h - kernel_w * dilation_w; for (int i = 0; i < kernel_h; i++) { for (int j = 0; j < kernel_w; j++) { space_ofs[p1] = p2; p1++; p2 += dilation_w; } p2 += gap; } } // depth-wise if (inch == group && group == outch) { #pragma omp parallel for num_threads(opt.num_threads) for (int g = 0; g < group; g++) { float* outptr = top_blob.channel(g); const float* kptr = (const float*)weight_data + maxk * g; const Mat m = bottom_blob.channel(g); for (int i = 0; i < outh; i++) { for (int j = 0; j < outw; j++) { float sum = 0.f; if (bias_term) sum = bias_data[g]; const float* sptr = m.row(i * stride_h) + j * stride_w; for (int k = 0; k < maxk; k++) { float val = sptr[space_ofs[k]]; float w = kptr[k]; sum += val * w; } outptr[j] = activation_ss(sum, activation_type, activation_params); } outptr += outw; } } } else { // group convolution const int inch_g = inch / group; const int outch_g = outch / group; #ifdef _WIN32 #pragma omp parallel for num_threads(opt.num_threads) #else #pragma omp parallel for collapse(2) num_threads(opt.num_threads) #endif for (int g = 0; g < group; g++) { for (int p = 0; p < outch_g; p++) { float* outptr = top_blob.channel(g * outch_g + p); const float* weight_data_ptr = (const float*)weight_data + maxk * inch_g * outch_g * g; // shadowed variable for less openmp task args const int outw = top_blob.w; const int outh = top_blob.h; for (int i = 0; i < outh; i++) { for (int j = 0; j < outw; j++) { float sum = 0.f; if (bias_term) sum = bias_data[outch_g * g + p]; const float* kptr = weight_data_ptr + maxk * inch_g * p; for (int q = 0; q < inch_g; q++) { const Mat m = bottom_blob.channel(inch_g * g + q); const float* sptr = m.row(i * stride_h) + j * stride_w; for (int k = 0; k < maxk; k++) { float val = sptr[space_ofs[k]]; float w = kptr[k]; sum += val * w; } kptr += maxk; } outptr[j] = activation_ss(sum, activation_type, activation_params); } outptr += outw; } } } } return 0; } int ConvolutionDepthWise::forward(const Mat& bottom_blob, Mat& top_blob, const Option& opt) const { // convolv with NxN kernel // value = value + bias #if NCNN_INT8 if (opt.use_int8_inference && weight_data.elemsize == (size_t)1u) { return forward_int8(bottom_blob, top_blob, opt); } #endif // NCNN_LOGE("ConvolutionDepthWise input %d x %d pad = %d %d ksize=%d %d stride=%d %d", w, h, pad_w, pad_h, kernel_w, kernel_h, stride_w, stride_h); Mat bottom_blob_bordered; make_padding(bottom_blob, bottom_blob_bordered, opt); if (bottom_blob_bordered.empty()) return -100; const int w = bottom_blob_bordered.w; const int h = bottom_blob_bordered.h; const size_t elemsize = bottom_blob_bordered.elemsize; const int kernel_extent_w = dilation_w * (kernel_w - 1) + 1; const int kernel_extent_h = dilation_h * (kernel_h - 1) + 1; const int outw = (w - kernel_extent_w) / stride_w + 1; const int outh = (h - kernel_extent_h) / stride_h + 1; top_blob.create(outw, outh, num_output, elemsize, opt.blob_allocator); if (top_blob.empty()) return -100; int ret = convolutiondepthwise(bottom_blob_bordered, top_blob, weight_data, bias_data, kernel_w, kernel_h, stride_w, stride_h, dilation_w, dilation_h, group, activation_type, activation_params, opt); if (ret != 0) return ret; return 0; } int ConvolutionDepthWise::forward(const std::vector& bottom_blobs, std::vector& top_blobs, const Option& opt) const { const Mat& bottom_blob = bottom_blobs[0]; const Mat& _weight_data = bottom_blobs[1]; Mat& top_blob = top_blobs[0]; const int _kernel_w = _weight_data.w; const int _kernel_h = _weight_data.h; const int _num_output = _weight_data.c; Mat weight_data_flattened; flatten(_weight_data, weight_data_flattened, opt); if (weight_data_flattened.empty()) return -100; Mat bias_data_flattened; if (bias_term) { const Mat& _bias_data = bottom_blobs[2]; flatten(_bias_data, bias_data_flattened, opt); if (bias_data_flattened.empty()) return -100; } Mat bottom_blob_bordered; make_padding(bottom_blob, bottom_blob_bordered, _kernel_w, _kernel_h, opt); if (bottom_blob_bordered.empty()) return -100; const int w = bottom_blob_bordered.w; const int h = bottom_blob_bordered.h; const size_t elemsize = bottom_blob_bordered.elemsize; const int kernel_extent_w = dilation_w * (_kernel_w - 1) + 1; const int kernel_extent_h = dilation_h * (_kernel_h - 1) + 1; const int outw = (w - kernel_extent_w) / stride_w + 1; const int outh = (h - kernel_extent_h) / stride_h + 1; top_blob.create(outw, outh, _num_output, elemsize, opt.blob_allocator); if (top_blob.empty()) return -100; int ret = convolutiondepthwise(bottom_blob_bordered, top_blob, weight_data_flattened, bias_data_flattened, _kernel_w, _kernel_h, stride_w, stride_h, dilation_w, dilation_h, group, activation_type, activation_params, opt); if (ret != 0) return ret; return 0; } void ConvolutionDepthWise::make_padding(const Mat& bottom_blob, Mat& bottom_blob_bordered, const Option& opt) const { make_padding(bottom_blob, bottom_blob_bordered, kernel_w, kernel_h, opt); } void ConvolutionDepthWise::make_padding(const Mat& bottom_blob, Mat& bottom_blob_bordered, int _kernel_w, int _kernel_h, const Option& opt) const { int w = bottom_blob.w; int h = bottom_blob.h; const int kernel_extent_w = dilation_w * (_kernel_w - 1) + 1; const int kernel_extent_h = dilation_h * (_kernel_h - 1) + 1; bottom_blob_bordered = bottom_blob; if (pad_left > 0 || pad_right > 0 || pad_top > 0 || pad_bottom > 0) { Option opt_b = opt; opt_b.blob_allocator = opt.workspace_allocator; copy_make_border(bottom_blob, bottom_blob_bordered, pad_top, pad_bottom, pad_left, pad_right, BORDER_CONSTANT, pad_value, opt_b); } else if (pad_left == -233 && pad_right == -233 && pad_top == -233 && pad_bottom == -233) { // tensorflow padding=SAME or onnx padding=SAME_UPPER int wpad = kernel_extent_w + (w - 1) / stride_w * stride_w - w; int hpad = kernel_extent_h + (h - 1) / stride_h * stride_h - h; if (wpad > 0 || hpad > 0) { Option opt_b = opt; opt_b.blob_allocator = opt.workspace_allocator; copy_make_border(bottom_blob, bottom_blob_bordered, hpad / 2, hpad - hpad / 2, wpad / 2, wpad - wpad / 2, BORDER_CONSTANT, pad_value, opt_b); } } else if (pad_left == -234 && pad_right == -234 && pad_top == -234 && pad_bottom == -234) { // onnx padding=SAME_LOWER int wpad = kernel_extent_w + (w - 1) / stride_w * stride_w - w; int hpad = kernel_extent_h + (h - 1) / stride_h * stride_h - h; if (wpad > 0 || hpad > 0) { Option opt_b = opt; opt_b.blob_allocator = opt.workspace_allocator; copy_make_border(bottom_blob, bottom_blob_bordered, hpad - hpad / 2, hpad / 2, wpad - wpad / 2, wpad / 2, BORDER_CONSTANT, pad_value, opt_b); } } } #if NCNN_INT8 static inline signed char float2int8(float v) { int int32 = static_cast(round(v)); if (int32 > 127) return 127; if (int32 < -127) return -127; return (signed char)int32; } int ConvolutionDepthWise::forward_int8(const Mat& bottom_blob, Mat& top_blob, const Option& opt) const { // convolv with NxN kernel // value = value + bias int w = bottom_blob.w; int h = bottom_blob.h; int channels = bottom_blob.c; size_t elemsize = bottom_blob.elemsize; if (channels % group != 0 || num_output % group != 0) { // reject invalid group return -100; } // NCNN_LOGE("ConvolutionDepthWise input %d x %d pad = %d %d ksize=%d %d stride=%d %d", w, h, pad_w, pad_h, kernel_w, kernel_h, stride_w, stride_h); const int kernel_extent_w = dilation_w * (kernel_w - 1) + 1; const int kernel_extent_h = dilation_h * (kernel_h - 1) + 1; Mat bottom_blob_int8 = bottom_blob; if (elemsize != 1) { const int channels_g = channels / group; Mat scales(channels); { float* ps = scales; for (int g = 0; g < group; g++) { float scale = bottom_blob_int8_scales[g]; for (int q = 0; q < channels_g; q++) { *ps++ = scale; } } } Option opt_q = opt; opt_q.blob_allocator = opt.workspace_allocator; quantize_to_int8(bottom_blob, bottom_blob_int8, scales, opt_q); } Mat bottom_blob_bordered; make_padding(bottom_blob_int8, bottom_blob_bordered, opt); if (bottom_blob_bordered.empty()) return -100; w = bottom_blob_bordered.w; h = bottom_blob_bordered.h; int outw = (w - kernel_extent_w) / stride_w + 1; int outh = (h - kernel_extent_h) / stride_h + 1; const int maxk = kernel_w * kernel_h; // kernel offsets std::vector _space_ofs(maxk); int* space_ofs = &_space_ofs[0]; { int p1 = 0; int p2 = 0; int gap = w * dilation_h - kernel_w * dilation_w; for (int i = 0; i < kernel_h; i++) { for (int j = 0; j < kernel_w; j++) { space_ofs[p1] = p2; p1++; p2 += dilation_w; } p2 += gap; } } // int8 bool use_int8_requantize = int8_scale_term > 100; size_t out_elemsize = use_int8_requantize ? 1u : 4u; top_blob.create(outw, outh, num_output, out_elemsize, opt.blob_allocator); if (top_blob.empty()) return -100; // depth-wise if (channels == group && group == num_output) { #pragma omp parallel for num_threads(opt.num_threads) for (int g = 0; g < group; g++) { signed char* outptr = top_blob.channel(g); const signed char* kptr = (const signed char*)weight_data + maxk * g; const Mat m = bottom_blob_bordered.channel(g); for (int i = 0; i < outh; i++) { for (int j = 0; j < outw; j++) { int sum = 0; const signed char* sptr = m.row(i * stride_h) + j * stride_w; for (int k = 0; k < maxk; k++) { signed char val = sptr[space_ofs[k]]; signed char w = kptr[k]; sum += val * w; } float scale_in; if (weight_data_int8_scales[g] == 0) scale_in = 0; else scale_in = 1.f / (bottom_blob_int8_scales[g] * weight_data_int8_scales[g]); float sumfp32 = sum * scale_in; if (bias_term) sumfp32 += bias_data[g]; sumfp32 = activation_ss(sumfp32, activation_type, activation_params); if (use_int8_requantize) { // requantize float scale_out = top_blob_int8_scales[g]; signed char sums8 = float2int8(sumfp32 * scale_out); outptr[0] = sums8; outptr += 1; } else { // dequantize ((float*)outptr)[0] = sumfp32; outptr += 4; } } } } } else { // group convolution const int channels_g = channels / group; const int num_output_g = num_output / group; #ifdef _WIN32 #pragma omp parallel for num_threads(opt.num_threads) #else // _WIN32 #pragma omp parallel for collapse(2) num_threads(opt.num_threads) #endif // _WIN32 for (int g = 0; g < group; g++) { for (int p = 0; p < num_output_g; p++) { signed char* outptr = top_blob.channel(g * num_output_g + p); const signed char* weight_data_ptr = (const signed char*)weight_data + maxk * channels_g * num_output_g * g; for (int i = 0; i < outh; i++) { for (int j = 0; j < outw; j++) { int sum = 0; const signed char* kptr = weight_data_ptr + maxk * channels_g * p; // channels_g for (int q = 0; q < channels_g; q++) { const Mat m = bottom_blob_bordered.channel(channels_g * g + q); const signed char* sptr = m.row(i * stride_h) + j * stride_w; for (int k = 0; k < maxk; k++) { signed char val = sptr[space_ofs[k]]; signed char w = kptr[k]; sum += val * w; } kptr += maxk; } float scale_in; if (weight_data_int8_scales[g] == 0) scale_in = 0; else scale_in = 1.f / (bottom_blob_int8_scales[g] * weight_data_int8_scales[g]); float sumfp32 = sum * scale_in; if (bias_term) sumfp32 += bias_data[g * num_output_g + p]; sumfp32 = activation_ss(sumfp32, activation_type, activation_params); if (use_int8_requantize) { // requantize float scale_out = top_blob_int8_scales[g]; signed char sums8 = float2int8(sumfp32 * scale_out); outptr[0] = sums8; outptr += 1; } else { // dequantize ((float*)outptr)[0] = sumfp32; outptr += 4; } } } } } } return 0; } #endif // NCNN_INT8 } // namespace ncnn