// Tencent is pleased to support the open source community by making ncnn available. // // Copyright (C) 2022 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 "cpu.h" #if __ARM_NEON #include #endif // __ARM_NEON #include "arm_activation.h" #include "arm_usability.h" namespace ncnn { #if __ARM_NEON #if __ARM_FEATURE_FP16_VECTOR_ARITHMETIC #include "convolution_packed_fp16s.h" #include "convolution_3x3_winograd_fp16s.h" #include "convolution_im2col_gemm_bf16s_fp16s.h" #include "convolution_im2col_gemm_fp16s.h" #if NCNN_GNU_INLINE_ASM #include "convolution_3x3_pack4_fp16s.h" #include "convolution_3x3_pack1to8_fp16s.h" #include "convolution_3x3_pack1to4_fp16s.h" #include "convolution_3x3_pack8_fp16s.h" #include "convolution_5x5_pack8_fp16s.h" #include "convolution_7x7_pack1to8_fp16s.h" #endif // NCNN_GNU_INLINE_ASM #endif #endif // __ARM_NEON #if __ARM_FEATURE_FP16_VECTOR_ARITHMETIC static void convolution_transform_kernel_packed_fp16s_neon(const Mat& weight_data, Mat& weight_data_tm, int num_input, int num_output, int kernel_w, int kernel_h, int elempack, int out_elempack) { const int maxk = kernel_w * kernel_h; // src = kw-kh-inch-outch // dst = pb-pa-kw-kh-inch/pa-outch/pb { Mat weight_data_r2 = weight_data.reshape(maxk, num_input, num_output); weight_data_tm.create(maxk, num_input / elempack, num_output / out_elempack, (size_t)2u * elempack * out_elempack, elempack * out_elempack); for (int q = 0; q + (out_elempack - 1) < num_output; q += out_elempack) { __fp16* g00 = weight_data_tm.channel(q / out_elempack); for (int p = 0; p + (elempack - 1) < num_input; p += elempack) { for (int k = 0; k < maxk; k++) { for (int i = 0; i < elempack; i++) { for (int j = 0; j < out_elempack; j++) { const float* k00 = weight_data_r2.channel(q + j).row(p + i); g00[0] = (__fp16)k00[k]; g00++; } } } } } } } int Convolution_arm::create_pipeline_fp16s(const Option& opt) { const int maxk = kernel_w * kernel_h; const int num_input = weight_data_size / maxk / num_output; int elempack = 1; int out_elempack = 1; if (opt.use_packing_layout) { elempack = opt.use_fp16_arithmetic && num_input % 8 == 0 ? 8 : num_input % 4 == 0 ? 4 : 1; out_elempack = opt.use_fp16_arithmetic && num_output % 8 == 0 ? 8 : num_output % 4 == 0 ? 4 : 1; } bool prefer_winograd = (opt.use_winograd23_convolution || opt.use_winograd43_convolution || opt.use_winograd63_convolution) && (num_input >= 16 || num_output >= 16); if (opt.use_fp16_arithmetic && opt.use_winograd_convolution && prefer_winograd && kernel_w == 3 && kernel_h == 3 && dilation_w == 1 && dilation_h == 1 && stride_w == 1 && stride_h == 1) { // dynamic shape if (opt.use_winograd63_convolution && (num_input <= 128 && num_output <= 128)) conv3x3s1_winograd63_transform_kernel_fp16sa(weight_data, weight_winograd63_data, num_input, num_output, opt); else if (opt.use_winograd43_convolution && (num_input >= 16 && num_output >= 16)) conv3x3s1_winograd43_transform_kernel_fp16sa(weight_data, weight_winograd43_data, num_input, num_output, opt); else conv3x3s1_winograd23_transform_kernel_fp16sa(weight_data, weight_winograd23_data, num_input, num_output, opt); if (opt.lightmode) { weight_data.release(); } if (opt.use_fp16_arithmetic) { ncnn::cast_float32_to_float16(bias_data, bias_data_fp16, opt); } return 0; } int l2_cache_size_fp16 = get_cpu_level2_cache_size() / sizeof(unsigned short); bool prefer_sgemm = num_input * num_output * kernel_w * kernel_h * dilation_w * dilation_h * stride_w * stride_h * 2 > l2_cache_size_fp16 || (num_input > 16 || num_output > 16); #if NCNN_GNU_INLINE_ASM if (elempack == 8 && out_elempack == 8) { if (kernel_w == 3 && kernel_h == 3 && dilation_w == 1 && dilation_h == 1 && stride_w == 1 && stride_h == 1) { prefer_sgemm = false; } if (kernel_w == 3 && kernel_h == 3 && dilation_w == 1 && dilation_h == 1 && stride_w == 2 && stride_h == 2 && (num_input < 64 || num_output < 128)) { prefer_sgemm = false; } if (kernel_w == 5 && kernel_h == 5 && dilation_w == 1 && dilation_h == 1 && stride_w == 1 && stride_h == 1) { prefer_sgemm = false; } if (kernel_w == 5 && kernel_h == 5 && dilation_w == 1 && dilation_h == 1 && stride_w == 2 && stride_h == 2 && (num_input < 16 || num_output < 88)) { prefer_sgemm = false; } } if (elempack == 1 && out_elempack == 8) { if (kernel_w == 3 && kernel_h == 3 && dilation_w == 1 && dilation_h == 1 && stride_w == 1 && stride_h == 1) { prefer_sgemm = false; } if (kernel_w == 3 && kernel_h == 3 && dilation_w == 1 && dilation_h == 1 && stride_w == 2 && stride_h == 2) { prefer_sgemm = false; } if (kernel_w == 7 && kernel_h == 7 && dilation_w == 1 && dilation_h == 1 && stride_w == 2 && stride_h == 2) { prefer_sgemm = false; } } if (elempack == 4 && out_elempack == 4) { if (kernel_w == 3 && kernel_h == 3 && dilation_w == 1 && dilation_h == 1 && stride_w == 1 && stride_h == 1) { prefer_sgemm = false; } } if (elempack == 1 && out_elempack == 4) { if (kernel_w == 3 && kernel_h == 3 && dilation_w == 1 && dilation_h == 1 && stride_w == 1 && stride_h == 1) { prefer_sgemm = false; } else if (kernel_w == 3 && kernel_h == 3 && dilation_w == 1 && dilation_h == 1 && stride_w == 2 && stride_h == 2) { prefer_sgemm = false; } else if (kernel_w == 7 && kernel_h == 7 && dilation_w == 1 && dilation_h == 1 && stride_w == 2 && stride_h == 2) { prefer_sgemm = false; } } #endif // NCNN_GNU_INLINE_ASM if (opt.use_fp16_arithmetic && ((opt.use_sgemm_convolution && prefer_sgemm) || (kernel_w == 1 && kernel_h == 1))) { convolution_im2col_gemm_transform_kernel_fp16sa(weight_data, weight_sgemm_data, num_input, num_output, kernel_w, kernel_h, opt); ncnn::cast_float32_to_float16(bias_data, bias_data_fp16, opt); if (opt.lightmode) { weight_data.release(); } return 0; } #if NCNN_GNU_INLINE_ASM if ((elempack == 8 && out_elempack == 8 && kernel_w == 3 && kernel_h == 3 && dilation_w == 1 && dilation_h == 1 && stride_w == 1 && stride_h == 1) || (elempack == 8 && out_elempack == 8 && kernel_w == 3 && kernel_h == 3 && dilation_w == 1 && dilation_h == 1 && stride_w == 2 && stride_h == 2) || (elempack == 8 && out_elempack == 8 && kernel_w == 5 && kernel_h == 5 && dilation_w == 1 && dilation_h == 1 && stride_w == 1 && stride_h == 1) || (elempack == 8 && out_elempack == 8 && kernel_w == 5 && kernel_h == 5 && dilation_w == 1 && dilation_h == 1 && stride_w == 2 && stride_h == 2) || (elempack == 1 && out_elempack == 8 && kernel_w == 3 && kernel_h == 3 && dilation_w == 1 && dilation_h == 1 && stride_w == 1 && stride_h == 1) || (elempack == 1 && out_elempack == 8 && kernel_w == 3 && kernel_h == 3 && dilation_w == 1 && dilation_h == 1 && stride_w == 2 && stride_h == 2) || (elempack == 1 && out_elempack == 8 && kernel_w == 7 && kernel_h == 7 && dilation_w == 1 && dilation_h == 1 && stride_w == 2 && stride_h == 2) || (opt.use_fp16_arithmetic && elempack == 4 && out_elempack == 4 && kernel_w == 3 && kernel_h == 3 && dilation_w == 1 && dilation_h == 1 && stride_w == 1 && stride_h == 1) || (opt.use_fp16_arithmetic && elempack == 1 && out_elempack == 4 && kernel_w == 3 && kernel_h == 3 && dilation_w == 1 && dilation_h == 1 && stride_w == 1 && stride_h == 1) || (opt.use_fp16_arithmetic && elempack == 1 && out_elempack == 4 && kernel_w == 3 && kernel_h == 3 && dilation_w == 1 && dilation_h == 1 && stride_w == 2 && stride_h == 2)) { convolution_transform_kernel_packed_fp16s_neon(weight_data, weight_data_tm, num_input, num_output, kernel_w, kernel_h, elempack, out_elempack); } else #endif // NCNN_GNU_INLINE_ASM { convolution_transform_kernel_packed_fp16s(weight_data, weight_data_tm, num_input, num_output, kernel_w, kernel_h); } if (opt.use_fp16_arithmetic) { ncnn::cast_float32_to_float16(bias_data, bias_data_fp16, opt); } if (opt.lightmode) { weight_data.release(); } return 0; } int Convolution_arm::forward_fp16s(const Mat& bottom_blob, Mat& top_blob, const Option& opt) const { int w = bottom_blob.w; int h = bottom_blob.h; size_t elemsize = bottom_blob.elemsize; int elempack = bottom_blob.elempack; // NCNN_LOGE("Convolution 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_bordered; make_padding(bottom_blob, 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; int out_elempack = (opt.use_packing_layout && num_output % 4 == 0) ? 4 : 1; size_t out_elemsize = elemsize / elempack * out_elempack; top_blob.create(outw, outh, num_output / out_elempack, out_elemsize, out_elempack, opt.blob_allocator); if (top_blob.empty()) return -100; // TODO dilated conv for bf16s // if ((!support_packing || !opt.use_packing_layout) && kernel_w == kernel_h && dilation_w != 1 && dilation_h == dilation_w && stride_w == 1 && stride_h == 1) // { // return forwardDilation_arm(bottom_blob_bordered, top_blob, opt); // } if (elempack == 4 && out_elempack == 4) { convolution_packed_fp16s(bottom_blob_bordered, top_blob, weight_data_tm, bias_data, kernel_w, kernel_h, dilation_w, dilation_h, stride_w, stride_h, activation_type, activation_params, opt); } if (elempack == 1 && out_elempack == 4) { convolution_packed_fp16s(bottom_blob_bordered, top_blob, weight_data_tm, bias_data, kernel_w, kernel_h, dilation_w, dilation_h, stride_w, stride_h, activation_type, activation_params, opt); } if (elempack == 4 && out_elempack == 1) { convolution_packed_fp16s(bottom_blob_bordered, top_blob, weight_data_tm, bias_data, kernel_w, kernel_h, dilation_w, dilation_h, stride_w, stride_h, activation_type, activation_params, opt); } if (elempack == 1 && out_elempack == 1) { convolution_packed_fp16s(bottom_blob_bordered, top_blob, weight_data_tm, bias_data, kernel_w, kernel_h, dilation_w, dilation_h, stride_w, stride_h, activation_type, activation_params, opt); } return 0; } int Convolution_arm::forward_fp16sa(const Mat& bottom_blob, Mat& top_blob, const Option& opt) const { 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; // NCNN_LOGE("Convolution 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_bordered; make_padding(bottom_blob, 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; int out_elempack = 1; if (opt.use_packing_layout) { out_elempack = num_output % 8 == 0 ? 8 : num_output % 4 == 0 ? 4 : 1; } size_t out_elemsize = elemsize / elempack * out_elempack; top_blob.create(outw, outh, num_output / out_elempack, out_elemsize, out_elempack, opt.blob_allocator); if (top_blob.empty()) return -100; // TODO dilated conv for bf16s // if ((!support_packing || !opt.use_packing_layout) && kernel_w == kernel_h && dilation_w != 1 && dilation_h == dilation_w && stride_w == 1 && stride_h == 1) // { // return forwardDilation_arm(bottom_blob_bordered, top_blob, opt); // } const int num_input = channels * elempack; bool prefer_winograd = (opt.use_winograd23_convolution || opt.use_winograd43_convolution || opt.use_winograd63_convolution) && (num_input >= 16 || num_output >= 16); if (opt.use_winograd_convolution && prefer_winograd && kernel_w == 3 && kernel_h == 3 && dilation_w == 1 && dilation_h == 1 && stride_w == 1 && stride_h == 1) { bool prefer_winograd63 = false; bool prefer_winograd23 = false; bool prefer_winograd43 = !prefer_winograd63 && !prefer_winograd23; if (prefer_winograd23 && (!opt.use_winograd23_convolution || weight_winograd23_data.empty())) { // f23 fallback to f43 prefer_winograd23 = false; prefer_winograd43 = true; } if (prefer_winograd63 && (!opt.use_winograd63_convolution || weight_winograd63_data.empty())) { // f63 fallback to f43 prefer_winograd63 = false; prefer_winograd43 = true; } if (prefer_winograd43 && (!opt.use_winograd43_convolution || weight_winograd43_data.empty())) { // f43 fallback to f63 or f23 prefer_winograd43 = false; if (opt.use_winograd63_convolution && !weight_winograd63_data.empty()) { prefer_winograd63 = true; } else { prefer_winograd23 = true; } } // NCNN_LOGE("prefer_winograd %d %d %d", prefer_winograd23, prefer_winograd43, prefer_winograd63); int _nT = nT ? nT : opt.num_threads; if (nT != 0 && opt.num_threads != nT) { // force num_threads the same as in create_pipeline // so we could use pre-packed A/B from the same tile config NCNN_LOGE("opt.num_threads %d changed, convolution winograd will use load-time value %d", opt.num_threads, nT); } if (prefer_winograd23) { conv3x3s1_winograd23_fp16sa(bottom_blob_bordered, top_blob, weight_winograd23_data, bias_data_fp16, _nT, opt); } else if (prefer_winograd43) { conv3x3s1_winograd43_fp16sa(bottom_blob_bordered, top_blob, weight_winograd43_data, bias_data_fp16, _nT, opt); } else if (prefer_winograd63) { conv3x3s1_winograd63_fp16sa(bottom_blob_bordered, top_blob, weight_winograd63_data, bias_data_fp16, _nT, opt); } else { // should never reach here } if (activation) { activation->forward_inplace(top_blob, opt); } return 0; } int l2_cache_size_fp16 = get_cpu_level2_cache_size() / sizeof(unsigned short); bool prefer_sgemm = num_input * num_output * kernel_w * kernel_h * dilation_w * dilation_h * stride_w * stride_h * 2 > l2_cache_size_fp16 || (num_input > 16 || num_output > 16); #if NCNN_GNU_INLINE_ASM if (elempack == 8 && out_elempack == 8) { if (kernel_w == 3 && kernel_h == 3 && dilation_w == 1 && dilation_h == 1 && stride_w == 1 && stride_h == 1) { prefer_sgemm = false; } if (kernel_w == 3 && kernel_h == 3 && dilation_w == 1 && dilation_h == 1 && stride_w == 2 && stride_h == 2 && (num_input < 64 || num_output < 128)) { prefer_sgemm = false; } if (kernel_w == 5 && kernel_h == 5 && dilation_w == 1 && dilation_h == 1 && stride_w == 1 && stride_h == 1) { prefer_sgemm = false; } if (kernel_w == 5 && kernel_h == 5 && dilation_w == 1 && dilation_h == 1 && stride_w == 2 && stride_h == 2 && (num_input < 16 || num_output < 88)) { prefer_sgemm = false; } } if (elempack == 1 && out_elempack == 8) { if (kernel_w == 3 && kernel_h == 3 && dilation_w == 1 && dilation_h == 1 && stride_w == 1 && stride_h == 1) { prefer_sgemm = false; } if (kernel_w == 3 && kernel_h == 3 && dilation_w == 1 && dilation_h == 1 && stride_w == 2 && stride_h == 2) { prefer_sgemm = false; } if (kernel_w == 7 && kernel_h == 7 && dilation_w == 1 && dilation_h == 1 && stride_w == 2 && stride_h == 2) { prefer_sgemm = false; } } if (elempack == 4 && out_elempack == 4) { if (kernel_w == 3 && kernel_h == 3 && dilation_w == 1 && dilation_h == 1 && stride_w == 1 && stride_h == 1) { prefer_sgemm = false; } } if (elempack == 1 && out_elempack == 4) { if (kernel_w == 3 && kernel_h == 3 && dilation_w == 1 && dilation_h == 1 && stride_w == 1 && stride_h == 1) { prefer_sgemm = false; } else if (kernel_w == 3 && kernel_h == 3 && dilation_w == 1 && dilation_h == 1 && stride_w == 2 && stride_h == 2) { prefer_sgemm = false; } else if (kernel_w == 7 && kernel_h == 7 && dilation_w == 1 && dilation_h == 1 && stride_w == 2 && stride_h == 2) { prefer_sgemm = false; } } #endif // NCNN_GNU_INLINE_ASM if ((opt.use_sgemm_convolution && prefer_sgemm) || (kernel_w == 1 && kernel_h == 1)) { int _nT = nT ? nT : opt.num_threads; if (nT != 0 && opt.num_threads != nT) { // force num_threads the same as in create_pipeline // so we could use pre-packed A/B from the same tile config NCNN_LOGE("opt.num_threads %d changed, convolution gemm will use load-time value %d", opt.num_threads, nT); } convolution_im2col_gemm_fp16sa(bottom_blob_bordered, top_blob, weight_sgemm_data, bias_data_fp16, kernel_w, kernel_h, dilation_w, dilation_h, stride_w, stride_h, _nT, opt); if (activation) { activation->forward_inplace(top_blob, opt); } return 0; } #if NCNN_GNU_INLINE_ASM if (elempack == 8 && out_elempack == 8) { if (kernel_w == 3 && kernel_h == 3 && dilation_w == 1 && dilation_h == 1 && stride_w == 1 && stride_h == 1) { conv3x3s1_pack8_fp16sa_neon(bottom_blob_bordered, top_blob, weight_data_tm, bias_data_fp16, opt); if (activation) { activation->forward_inplace(top_blob, opt); } } else if (kernel_w == 3 && kernel_h == 3 && dilation_w == 1 && dilation_h == 1 && stride_w == 2 && stride_h == 2) { conv3x3s2_pack8_fp16sa_neon(bottom_blob_bordered, top_blob, weight_data_tm, bias_data_fp16, opt); if (activation) { activation->forward_inplace(top_blob, opt); } } else if (kernel_w == 5 && kernel_h == 5 && dilation_w == 1 && dilation_h == 1 && stride_w == 1 && stride_h == 1) { conv5x5s1_pack8_fp16sa_neon(bottom_blob_bordered, top_blob, weight_data_tm, bias_data_fp16, opt); if (activation) { activation->forward_inplace(top_blob, opt); } } else if (kernel_w == 5 && kernel_h == 5 && dilation_w == 1 && dilation_h == 1 && stride_w == 2 && stride_h == 2) { conv5x5s2_pack8_fp16sa_neon(bottom_blob_bordered, top_blob, weight_data_tm, bias_data_fp16, opt); if (activation) { activation->forward_inplace(top_blob, opt); } } else { convolution_packed_fp16sa(bottom_blob_bordered, top_blob, weight_data_tm, bias_data_fp16, kernel_w, kernel_h, dilation_w, dilation_h, stride_w, stride_h, activation_type, activation_params, opt); } } if (elempack == 1 && out_elempack == 8) { if (kernel_w == 3 && kernel_h == 3 && dilation_w == 1 && dilation_h == 1 && stride_w == 1 && stride_h == 1) { conv3x3s1_pack1to8_fp16sa_neon(bottom_blob_bordered, top_blob, weight_data_tm, bias_data_fp16, opt); if (activation) { activation->forward_inplace(top_blob, opt); } } else if (kernel_w == 3 && kernel_h == 3 && dilation_w == 1 && dilation_h == 1 && stride_w == 2 && stride_h == 2) { conv3x3s2_pack1to8_fp16sa_neon(bottom_blob_bordered, top_blob, weight_data_tm, bias_data_fp16, opt); if (activation) { activation->forward_inplace(top_blob, opt); } } else if (kernel_w == 7 && kernel_h == 7 && dilation_w == 1 && dilation_h == 1 && stride_w == 2 && stride_h == 2) { conv7x7s2_pack1to8_fp16sa_neon(bottom_blob_bordered, top_blob, weight_data_tm, bias_data_fp16, opt); if (activation) { activation->forward_inplace(top_blob, opt); } } else { convolution_packed_fp16sa(bottom_blob_bordered, top_blob, weight_data_tm, bias_data_fp16, kernel_w, kernel_h, dilation_w, dilation_h, stride_w, stride_h, activation_type, activation_params, opt); } } if (elempack == 4 && out_elempack == 8) { { convolution_packed_fp16sa(bottom_blob_bordered, top_blob, weight_data_tm, bias_data_fp16, kernel_w, kernel_h, dilation_w, dilation_h, stride_w, stride_h, activation_type, activation_params, opt); } } if (elempack == 8 && out_elempack == 1) { { convolution_packed_fp16sa(bottom_blob_bordered, top_blob, weight_data_tm, bias_data_fp16, kernel_w, kernel_h, dilation_w, dilation_h, stride_w, stride_h, activation_type, activation_params, opt); } } if (elempack == 8 && out_elempack == 4) { { convolution_packed_fp16sa(bottom_blob_bordered, top_blob, weight_data_tm, bias_data_fp16, kernel_w, kernel_h, dilation_w, dilation_h, stride_w, stride_h, activation_type, activation_params, opt); } } if (elempack == 4 && out_elempack == 4) { if (kernel_w == 3 && kernel_h == 3 && dilation_w == 1 && dilation_h == 1 && stride_w == 1 && stride_h == 1) { conv3x3s1_pack4_fp16sa_neon(bottom_blob_bordered, top_blob, weight_data_tm, bias_data_fp16, opt); if (activation) { activation->forward_inplace(top_blob, opt); } } else { convolution_packed_fp16sa(bottom_blob_bordered, top_blob, weight_data_tm, bias_data_fp16, kernel_w, kernel_h, dilation_w, dilation_h, stride_w, stride_h, activation_type, activation_params, opt); } } if (elempack == 1 && out_elempack == 4) { if (kernel_w == 3 && kernel_h == 3 && dilation_w == 1 && dilation_h == 1 && stride_w == 1 && stride_h == 1) { conv3x3s1_pack1to4_fp16sa_neon(bottom_blob_bordered, top_blob, weight_data_tm, bias_data_fp16, opt); if (activation) { activation->forward_inplace(top_blob, opt); } } else if (kernel_w == 3 && kernel_h == 3 && dilation_w == 1 && dilation_h == 1 && stride_w == 2 && stride_h == 2) { conv3x3s2_pack1to4_fp16sa_neon(bottom_blob_bordered, top_blob, weight_data_tm, bias_data_fp16, opt); if (activation) { activation->forward_inplace(top_blob, opt); } } else { convolution_packed_fp16sa(bottom_blob_bordered, top_blob, weight_data_tm, bias_data_fp16, kernel_w, kernel_h, dilation_w, dilation_h, stride_w, stride_h, activation_type, activation_params, opt); } } if (elempack == 4 && out_elempack == 1) { { convolution_packed_fp16sa(bottom_blob_bordered, top_blob, weight_data_tm, bias_data_fp16, kernel_w, kernel_h, dilation_w, dilation_h, stride_w, stride_h, activation_type, activation_params, opt); } } if (elempack == 1 && out_elempack == 1) { { convolution_packed_fp16sa(bottom_blob_bordered, top_blob, weight_data_tm, bias_data_fp16, kernel_w, kernel_h, dilation_w, dilation_h, stride_w, stride_h, activation_type, activation_params, opt); } } #else // NCNN_GNU_INLINE_ASM { convolution_packed_fp16sa(bottom_blob_bordered, top_blob, weight_data_tm, bias_data_fp16, kernel_w, kernel_h, dilation_w, dilation_h, stride_w, stride_h, activation_type, activation_params, opt); } #endif // NCNN_GNU_INLINE_ASM return 0; } #endif // __ARM_FEATURE_FP16_VECTOR_ARITHMETIC } // namespace ncnn