// 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 "convolution_arm.h" #include "benchmark.h" #include "layer_type.h" #if __ARM_NEON #include #include "neon_mathfun.h" #endif // __ARM_NEON namespace ncnn { #include "convolution_1x1.h" #include "convolution_2x2.h" #include "convolution_3x3.h" #include "convolution_4x4.h" #include "convolution_5x5.h" #include "convolution_7x7.h" #include "convolution_sgemm.h" #include "convolution_sgemm_int8.h" #include "convolution_1x1_int8.h" #include "convolution_3x3_int8.h" #include "convolution_5x5_int8.h" #include "convolution_7x7_int8.h" #if __ARM_NEON #include "convolution_1x1_pack4.h" #include "convolution_3x3_pack4.h" #include "convolution_3x3_pack1to4.h" #endif // __ARM_NEON DEFINE_LAYER_CREATOR(Convolution_arm) Convolution_arm::Convolution_arm() { #if __ARM_NEON support_packing = true; #endif // __ARM_NEON activation = 0; } int Convolution_arm::create_pipeline(const Option& opt) { if (activation_type == 1) { activation = ncnn::create_layer(ncnn::LayerType::ReLU); ncnn::ParamDict pd; activation->load_param(pd); } else if (activation_type == 2) { activation = ncnn::create_layer(ncnn::LayerType::ReLU); ncnn::ParamDict pd; pd.set(0, activation_params[0]);// slope activation->load_param(pd); } else if (activation_type == 3) { activation = ncnn::create_layer(ncnn::LayerType::Clip); ncnn::ParamDict pd; pd.set(0, activation_params[0]);// min pd.set(1, activation_params[1]);// max activation->load_param(pd); } else if (activation_type == 4) { activation = ncnn::create_layer(ncnn::LayerType::Sigmoid); ncnn::ParamDict pd; activation->load_param(pd); } if (activation) { Option opt_cpu = opt; opt_cpu.use_vulkan_compute = false; activation->create_pipeline(opt_cpu); } const int maxk = kernel_w * kernel_h; int num_input = weight_data_size / maxk / num_output; #if __ARM_NEON if (opt.use_packing_layout) { // pack4 if (num_input % 4 == 0 && num_output % 4 == 0) { // src = kw-kh-inch-outch // dst = 4b-4a-kw-kh-inch/4a-outch/4b { Mat weight_data_r2 = weight_data.reshape(maxk, num_input, num_output); weight_data_pack4.create(maxk, num_input/4, num_output/4, (size_t)4*16, 16); for (int q=0; q+3= 16 && num_output >= 16) use_winograd3x3 = true; if (use_int8_inference) use_winograd3x3 = true; } // TODO assume more proper condition if (opt.use_sgemm_convolution && kernel_w == 1 && kernel_h == 1 && dilation_w == 1 && dilation_h == 1 && stride_w == 1 && stride_h == 1) { if (num_input >= 64 && num_output >= 64) use_sgemm1x1 = true; } if (use_int8_inference) { if (use_winograd3x3) { // conv3x3s1_winograd23_transform_kernel_int8_neon(weight_data, weight_3x3_winograd23_int8_data, num_input, num_output); conv3x3s1_winograd43_transform_kernel_int8_neon(weight_data, weight_3x3_winograd23_int8_data, num_input, num_output); } if (kernel_w == 3 && kernel_h == 3 && dilation_w == 1 && dilation_h == 1 && stride_w == 2 && stride_h == 2) { conv3x3s2_transform_kernel_int8_neon(weight_data, weight_3x3s2_int8_data, num_input, num_output); } else if (kernel_w == 1 && kernel_h == 1 && dilation_w == 1 && dilation_h == 1 && stride_w == 1 && stride_h == 1) { conv1x1s1_sgemm_transform_kernel_int8_neon(weight_data, weight_1x1s1_sgemm_int8_data, num_input, num_output); use_sgemm1x1 = true; } else { conv_im2col_sgemm_transform_kernel_int8_neon(weight_data, weight_sgemm_int8_data, num_input, num_output, maxk); } return 0; } if (impl_type > 0) { switch(impl_type) { case 1: // winograd conv3x3s1_winograd64_transform_kernel_neon5(weight_data, weight_3x3_winograd64_data, num_input, num_output); break; case 2: // pointwise conv1x1s1_sgemm_transform_kernel_neon(weight_data, weight_1x1_sgemm_data, num_input, num_output); break; case 3: // im2col conv_im2col_sgemm_transform_kernel_neon(weight_data, weight_sgemm_data, num_input, num_output, maxk); break; case 4: // direct break; case 5: // conv3x3s2 conv3x3s2_transform_kernel_neon(weight_data, weight_3x3s2_data, num_input, num_output); break; default: return -1; } return 0; } if (use_winograd3x3) { // conv3x3s1_winograd64_transform_kernel_neon(weight_data, weight_3x3_winograd64_data, num_input, num_output); conv3x3s1_winograd64_transform_kernel_neon5(weight_data, weight_3x3_winograd64_data, num_input, num_output); } if (use_sgemm1x1) { conv1x1s1_sgemm_transform_kernel_neon(weight_data, weight_1x1_sgemm_data, num_input, num_output); } if (kernel_w == 3 && kernel_h == 3 && dilation_w == 1 && dilation_h == 1 && stride_w == 2 && stride_h == 2) { conv3x3s2_transform_kernel_neon(weight_data, weight_3x3s2_data, num_input, num_output); } { conv_im2col_sgemm_transform_kernel_neon(weight_data, weight_sgemm_data, num_input, num_output, maxk); } return 0; } int Convolution_arm::destroy_pipeline(const Option& opt) { if (activation) { Option opt_cpu = opt; opt_cpu.use_vulkan_compute = false; activation->destroy_pipeline(opt_cpu); delete activation; activation = 0; } return 0; } int Convolution_arm::forwardDilation(const Mat& bottom_blob, Mat& top_blob, conv_func conv, const Option& opt) const { int w = bottom_blob.w; int h = bottom_blob.h; size_t elemsize = bottom_blob.elemsize; const int kernel_size = kernel_w; const int stride = stride_w; const int dilation = dilation_w; const int kernel_extent = dilation * (kernel_size - 1) + 1; Mat 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); if (bottom_blob_bordered.empty()) return -100; w = bottom_blob_bordered.w; h = bottom_blob_bordered.h; } else if (pad_left == -233 && pad_right == -233 && pad_top == -233 && pad_bottom == -233) { int wpad = kernel_extent + (w - 1) / stride * stride - w; int hpad = kernel_extent + (h - 1) / stride * stride - 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); if (bottom_blob_bordered.empty()) return -100; } w = bottom_blob_bordered.w; h = bottom_blob_bordered.h; } else if (pad_left == -234 && pad_right == -234 && pad_top == -234 && pad_bottom == -234) { int wpad = kernel_extent + (w - 1) / stride * stride - w; int hpad = kernel_extent + (h - 1) / stride * stride - 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 (bottom_blob_bordered.empty()) return -100; } w = bottom_blob_bordered.w; h = bottom_blob_bordered.h; } int outw = (w - kernel_extent) / stride + 1; int outh = (h - kernel_extent) / stride + 1; top_blob.create(outw, outh, num_output, elemsize, opt.blob_allocator); if (top_blob.empty()) return -100; // Make (dilation * dilation) batches Mat inner_bottom_blob; Mat inner_top_blob; for (int x = 0; x < dilation; x ++) { for (int y = 0; y < dilation; y ++) { int inner_w = (w - y + dilation - 1) / dilation; int inner_h = (h - x + dilation - 1) / dilation; int inner_outw = (inner_w - kernel_size) / stride + 1; int inner_outh = (inner_h - kernel_size) / stride + 1; inner_bottom_blob.create(inner_w, inner_h, bottom_blob.c, elemsize, opt.workspace_allocator); if (inner_bottom_blob.empty()) return -100; inner_top_blob.create(inner_outw, inner_outh, num_output, elemsize, opt.workspace_allocator); if (inner_top_blob.empty()) return -100; #pragma omp parallel for num_threads(opt.num_threads) for (int c = 0; c < bottom_blob.c; c ++) { float *outptr = inner_bottom_blob.channel(c); for (int i = 0; i < inner_h; i ++) { const float *ptr = (const float *) bottom_blob_bordered.channel(c) + dilation * i * w + x * w + y; for (int j = 0; j < inner_w; j ++) { outptr[j] = ptr[j*dilation]; } outptr += inner_w; } } ncnn::Option opt_g = opt; opt_g.blob_allocator = inner_top_blob.allocator; conv(inner_bottom_blob, inner_top_blob, weight_data, bias_data, opt_g); #pragma omp parallel for num_threads(opt.num_threads) for (int c = 0; c < num_output; c ++) { float *outptr = (float *) top_blob.channel(c) + x * outw + y; for (int i = 0; i < inner_outh; i ++) { const float *ptr = (const float *) inner_top_blob.channel(c) + i * inner_outw; for (int j = 0; j < inner_outw; j ++) { outptr[j*dilation] = ptr[j]; } outptr += dilation * outw; } } } } return 0; } int Convolution_arm::forward(const Mat& bottom_blob, Mat& top_blob, const Option& opt) const { // convolv with NxN kernel // value = value + bias #if __ARM_NEON if (opt.use_packing_layout) { int w = bottom_blob.w; int h = bottom_blob.h; int channels = bottom_blob.c; size_t elemsize = bottom_blob.elemsize; int elempack = bottom_blob.elempack; // fprintf(stderr, "Convolution input %d x %d pad = %d %d ksize=%d %d stride=%d %d\n", 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_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) { 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) { 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 (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; int out_elempack = num_output % 4 == 0 ? 4 : 1; size_t out_elemsize = elemsize / elempack * out_elempack; 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; } } // float32 top_blob.create(outw, outh, num_output / out_elempack, out_elemsize, out_elempack, opt.blob_allocator); if (top_blob.empty()) return -100; if (elempack == 4 && out_elempack == 4) { if (kernel_w == 1 && kernel_h == 1 && stride_w == 1 && stride_h == 1 && dilation_w == 1 && dilation_h == 1) { conv1x1s1_sgemm_pack4_neon(bottom_blob_bordered, top_blob, weight_data_pack4, bias_data, opt); if (activation) { activation->forward_inplace(top_blob, opt); } return 0; } if (kernel_w == 3 && kernel_h == 3 && stride_w == 1 && stride_h == 1 && dilation_w == 1 && dilation_h == 1) { conv3x3s1_winograd64_pack4_neon(bottom_blob_bordered, top_blob, weight_3x3_winograd64_data_pack4, bias_data, opt); if (activation) { activation->forward_inplace(top_blob, opt); } return 0; } // num_output #pragma omp parallel for num_threads(opt.num_threads) for (int p=0; pforward_inplace(top_blob, opt); } return 0; } if (kernel_w == 3 && kernel_h == 3 && stride_w == 2 && stride_h == 2 && dilation_w == 1 && dilation_h == 1) { conv3x3s2_pack1to4_neon(bottom_blob_bordered, top_blob, weight_data_pack1to4, bias_data, opt); if (activation) { activation->forward_inplace(top_blob, opt); } return 0; } // num_output #pragma omp parallel for num_threads(opt.num_threads) for (int p=0; p 0.f ? sum : sum * slope; } else if (activation_type == 3) { float min = activation_params[0]; float max = activation_params[1]; if (sum < min) sum = min; if (sum > max) sum = max; } else if (activation_type == 4) { sum = 1.f / (1.f + exp(-sum)); } outptr[j] = sum; } outptr += outw; } } return 0; } } // opt.use_packed_layout #endif // __ARM_NEON if (bottom_blob.dims != 3) { return Convolution::forward(bottom_blob, top_blob, opt); } if (kernel_w != kernel_h || stride_w != stride_h) { return Convolution::forward(bottom_blob, top_blob, opt); } const int kernel_size = kernel_w; //const int stride = stride_w; int stride = stride_w; if (kernel_size > 7 || stride > 4 || dilation_w != dilation_h) { return Convolution::forward(bottom_blob, top_blob, opt); } typedef void (*conv_func)(const Mat&, Mat&, const Mat&, const Mat&, const Option&); // kernel_size x stride conv_func conv_func_table[7][4] = { { conv1x1s1_neon, conv1x1s2_neon, 0, 0 }, // kernel_size = 1 { conv2x2s1_neon, 0, 0, 0 }, // kernel_size = 2 { conv3x3s1_neon, conv3x3s2_neon, 0, 0 }, // kernel_size = 3 { 0, 0, 0, conv4x4s4_neon }, // kernel_size = 4 { conv5x5s1_neon, conv5x5s2_neon, 0, 0 }, // kernel_size = 5 { 0, 0, 0, 0 }, // kernel_size = 6 { conv7x7s1_neon, conv7x7s2_neon, 0, 0 } // kernel_size = 7 }; typedef void (*conv_int8_func)(const Mat&, Mat&, const Mat&, const Option&); // kernel_size x stride conv_int8_func conv_int8_func_table[7][4] = { { conv1x1s1_int8_neon, conv1x1s2_int8_neon, 0, 0 }, // kernel_size = 1 { 0, 0, 0, 0 }, // kernel_size = 2 { conv3x3s1_int8_neon, conv3x3s2_int8_neon, 0, 0 }, // kernel_size = 3 { 0, 0, 0, 0 }, // kernel_size = 4 { conv5x5s1_int8_neon, conv5x5s2_int8_neon, 0, 0 }, // kernel_size = 5 { 0, 0, 0, 0 }, // kernel_size = 6 { conv7x7s1_int8_neon, conv7x7s2_int8_neon, 0, 0 } // kernel_size = 7 }; conv_func conv = 0; conv_int8_func conv_int8 = 0; if (use_int8_inference) { conv_int8 = conv_int8_func_table[kernel_size-1][stride-1]; if (!conv_int8) { return Convolution::forward(bottom_blob, top_blob, opt); } } else { conv = conv_func_table[kernel_size-1][stride-1]; if (!conv) { return Convolution::forward(bottom_blob, top_blob, opt); } if (dilation_w != 1) { if (stride != 1) return Convolution::forward(bottom_blob, top_blob, opt); return forwardDilation(bottom_blob, top_blob, conv, opt); } } int w = bottom_blob.w; int h = bottom_blob.h; int channels = bottom_blob.c; size_t elemsize = bottom_blob.elemsize; Mat bottom_blob_unbordered = bottom_blob; if (use_int8_inference && elemsize != 1) { Mat bottom_blob_int8; bottom_blob_int8.create(w, h, channels, (size_t)1u, opt.workspace_allocator); if (bottom_blob_int8.empty()) return -100; // quantize, scale and round to nearest { ncnn::Option opt_g = opt; opt_g.blob_allocator = bottom_blob_int8.allocator; quantize->forward(bottom_blob, bottom_blob_int8, opt_g); } bottom_blob_unbordered = bottom_blob_int8; } Mat bottom_blob_bordered = bottom_blob_unbordered; 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_unbordered, 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) { int wpad = kernel_size + (w - 1) / stride * stride - w; int hpad = kernel_size + (h - 1) / stride * stride - h; if (wpad > 0 || hpad > 0) { Option opt_b = opt; opt_b.blob_allocator = opt.workspace_allocator; copy_make_border(bottom_blob_unbordered, 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) { int wpad = kernel_size + (w - 1) / stride * stride - w; int hpad = kernel_size + (h - 1) / stride * stride - h; if (wpad > 0 || hpad > 0) { Option opt_b = opt; opt_b.blob_allocator = opt.workspace_allocator; copy_make_border(bottom_blob_unbordered, bottom_blob_bordered, hpad - hpad / 2, hpad / 2, wpad - wpad / 2, wpad / 2, BORDER_CONSTANT, pad_value, opt_b); } } if (bottom_blob_bordered.empty()) return -100; w = bottom_blob_bordered.w; h = bottom_blob_bordered.h; int outw = (w - kernel_size) / stride + 1; int outh = (h - kernel_size) / stride + 1; // int8 if (use_int8_inference) { if (use_int8_requantize == true) { Mat top_blob_tm; top_blob_tm.create(outw, outh, num_output, (size_t)4u, opt.workspace_allocator); if (top_blob_tm.empty()) return -100; top_blob.create(outw, outh, num_output, (size_t)1u, opt.blob_allocator); if (top_blob.empty()) return -100; if (use_sgemm1x1) { conv1x1s1_sgemm_int8_requant_neon(bottom_blob_bordered, top_blob, weight_1x1s1_sgemm_int8_data, bias_data, requantize_scales, opt); if (activation) { activation->forward_inplace(top_blob, opt); } return 0; } else if (use_winograd3x3) { // conv3x3s1_winograd23_int8_neon(bottom_blob_bordered, top_blob_tm, weight_3x3_winograd23_int8_data, opt); conv3x3s1_winograd43_int8_neon(bottom_blob_bordered, top_blob_tm, weight_3x3_winograd23_int8_data, opt); } else if (kernel_w == 3 && kernel_h == 3 && dilation_w == 1 && dilation_h == 1 && stride_w == 2 && stride_h == 2) { conv3x3s2_packed_int8_neon(bottom_blob_bordered, top_blob_tm, weight_3x3s2_int8_data, opt); } else { conv_int8(bottom_blob_bordered, top_blob_tm, weight_sgemm_int8_data, opt); } // requantize, reverse scale inplace #pragma omp parallel for num_threads(opt.num_threads) for (int p=0; pforward(top_blob_tm_g, top_blob_g, opt_g); } } else { top_blob.create(outw, outh, num_output, (size_t)4u, opt.blob_allocator); if (top_blob.empty()) return -100; if (use_sgemm1x1) { conv1x1s1_sgemm_int8_neon(bottom_blob_bordered, top_blob, weight_1x1s1_sgemm_int8_data, opt); } else if (use_winograd3x3) { // conv3x3s1_winograd23_int8_neon(bottom_blob_bordered, top_blob, weight_3x3_winograd23_int8_data, opt); // conv3x3s1_winograd43_int8_neon(bottom_blob_bordered, top_blob, weight_3x3_winograd23_int8_data, opt); conv3x3s1_winograd43_dequant_int8_neon(bottom_blob_bordered, top_blob, weight_3x3_winograd23_int8_data, bias_data, dequantize_scales, opt); if (activation) { activation->forward_inplace(top_blob, opt); } return 0; } else if (kernel_w == 3 && kernel_h == 3 && dilation_w == 1 && dilation_h == 1 && stride_w == 2 && stride_h == 2) { conv3x3s2_packed_int8_neon(bottom_blob_bordered, top_blob, weight_3x3s2_int8_data, opt); } else { conv_int8(bottom_blob_bordered, top_blob, weight_sgemm_int8_data, opt); } // dequantize, reverse scale inplace #pragma omp parallel for num_threads(opt.num_threads) for (int p=0; pforward_inplace(top_blob_g, opt_g); } } if (activation) { activation->forward_inplace(top_blob, opt); } return 0; } // float32 top_blob.create(outw, outh, num_output, elemsize, opt.blob_allocator); if (top_blob.empty()) return -100; if (impl_type > 0) { // engineering is magic. switch(impl_type) { case 1: conv3x3s1_winograd64_neon5(bottom_blob_bordered, top_blob, weight_3x3_winograd64_data, bias_data, opt); break; case 2: conv1x1s1_sgemm_neon(bottom_blob_bordered, top_blob, weight_1x1_sgemm_data, bias_data, opt); break; case 3: conv_im2col_sgemm_neon(bottom_blob_bordered, top_blob, weight_sgemm_data, bias_data, kernel_w, kernel_h, stride_w, stride_h, opt); break; case 4: conv(bottom_blob_bordered, top_blob, weight_data, bias_data, opt); break; case 5: conv3x3s2_packed_neon(bottom_blob_bordered, top_blob, weight_3x3s2_data, bias_data, opt); break; default: return -1; } } else { if (use_winograd3x3 && w <= 120 && h <= 120) { // conv3x3s1_winograd64_neon4(bottom_blob_bordered, top_blob, weight_3x3_winograd64_data, bias_data, opt); conv3x3s1_winograd64_neon5(bottom_blob_bordered, top_blob, weight_3x3_winograd64_data, bias_data, opt); } else if (use_sgemm1x1) { conv1x1s1_sgemm_neon(bottom_blob_bordered, top_blob, weight_1x1_sgemm_data, bias_data, opt); } else if (kernel_w == 1 && kernel_h == 1 && dilation_w == 1 && dilation_h == 1 && stride_w == 2 && stride_h == 2) { conv_im2col_sgemm_neon(bottom_blob_bordered, top_blob, weight_sgemm_data, bias_data, kernel_w, kernel_h, stride_w, stride_h, opt); } else if (kernel_w == 3 && kernel_h == 3 && dilation_w == 1 && dilation_h == 1 && stride_w == 2 && stride_h == 2) { if (outw >=8 && outh >=8) conv3x3s2_packed_neon(bottom_blob_bordered, top_blob, weight_3x3s2_data, bias_data, opt); else conv_im2col_sgemm_neon(bottom_blob_bordered, top_blob, weight_sgemm_data, bias_data, kernel_w, kernel_h, stride_w, stride_h, opt); } else conv(bottom_blob_bordered, top_blob, weight_data, bias_data, opt); } if (activation) { activation->forward_inplace(top_blob, opt); } return 0; } } // namespace ncnn