// 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. static void im2col_sgemm_pack8to1_int8_msa(const Mat& bottom_im2col, Mat& top_blob, const Mat& kernel, const Option& opt) { // Mat bottom_im2col(size, maxk, inch, 8u, 8, opt.workspace_allocator); const int size = bottom_im2col.w; const int maxk = bottom_im2col.h; const int inch = bottom_im2col.c; const int outch = top_blob.c; // permute Mat tmp; if (size >= 2) tmp.create(2 * maxk, inch, size / 2 + size % 2, 8u, 8, opt.workspace_allocator); else tmp.create(maxk, inch, size, 8u, 8, opt.workspace_allocator); { int remain_size_start = 0; int nn_size = (size - remain_size_start) >> 1; #pragma omp parallel for num_threads(opt.num_threads) for (int ii = 0; ii < nn_size; ii++) { int i = remain_size_start + ii * 2; int64_t* tmpptr = tmp.channel(i / 2); for (int q = 0; q < inch; q++) { const int64_t* img0 = (const int64_t*)bottom_im2col.channel(q) + i; for (int k = 0; k < maxk; k++) { v16i8 _v = __msa_ld_b(img0, 0); __msa_st_b(_v, tmpptr, 0); tmpptr += 2; img0 += size; } } } remain_size_start += nn_size << 1; #pragma omp parallel for num_threads(opt.num_threads) for (int i = remain_size_start; i < size; i++) { int64_t* tmpptr = tmp.channel(i / 2 + i % 2); for (int q = 0; q < inch; q++) { const int64_t* img0 = (const int64_t*)bottom_im2col.channel(q) + i; for (int k = 0; k < maxk; k++) { tmpptr[0] = img0[0]; tmpptr += 1; img0 += size; } } } } int nn_outch = 0; int remain_outch_start = 0; nn_outch = outch >> 2; #pragma omp parallel for num_threads(opt.num_threads) for (int pp = 0; pp < nn_outch; pp++) { int p = pp * 4; int* outptr0 = top_blob.channel(p); int* outptr1 = top_blob.channel(p + 1); int* outptr2 = top_blob.channel(p + 2); int* outptr3 = top_blob.channel(p + 3); int i = 0; for (; i + 1 < size; i += 2) { const signed char* tmpptr = tmp.channel(i / 2); const signed char* kptr = kernel.channel(p / 4); int nn = inch * maxk; // inch always > 0 v4i32 _sum00 = __msa_fill_w(0); v4i32 _sum01 = __msa_fill_w(0); v4i32 _sum02 = __msa_fill_w(0); v4i32 _sum03 = __msa_fill_w(0); v4i32 _sum10 = __msa_fill_w(0); v4i32 _sum11 = __msa_fill_w(0); v4i32 _sum12 = __msa_fill_w(0); v4i32 _sum13 = __msa_fill_w(0); int j = 0; for (; j < nn; j++) { __builtin_prefetch(tmpptr + 64); __builtin_prefetch(kptr + 128); v16i8 _val01 = __msa_ld_b(tmpptr, 0); v16i8 _extval01 = __msa_clti_s_b(_val01, 0); v8i16 _val0 = (v8i16)__msa_ilvr_b(_extval01, _val01); v8i16 _val1 = (v8i16)__msa_ilvl_b(_extval01, _val01); v16i8 _w01 = __msa_ld_b(kptr, 0); v16i8 _w23 = __msa_ld_b(kptr + 16, 0); v16i8 _extw01 = __msa_clti_s_b(_w01, 0); v16i8 _extw23 = __msa_clti_s_b(_w23, 0); v8i16 _w0 = (v8i16)__msa_ilvr_b(_extw01, _w01); v8i16 _w1 = (v8i16)__msa_ilvl_b(_extw01, _w01); v8i16 _w2 = (v8i16)__msa_ilvr_b(_extw23, _w23); v8i16 _w3 = (v8i16)__msa_ilvl_b(_extw23, _w23); v8i16 _s00 = __msa_mulv_h(_val0, _w0); v8i16 _s01 = __msa_mulv_h(_val0, _w1); v8i16 _s02 = __msa_mulv_h(_val0, _w2); v8i16 _s03 = __msa_mulv_h(_val0, _w3); v8i16 _s10 = __msa_mulv_h(_val1, _w0); v8i16 _s11 = __msa_mulv_h(_val1, _w1); v8i16 _s12 = __msa_mulv_h(_val1, _w2); v8i16 _s13 = __msa_mulv_h(_val1, _w3); _sum00 = __msa_addv_w(_sum00, __msa_hadd_s_w(_s00, _s00)); _sum01 = __msa_addv_w(_sum01, __msa_hadd_s_w(_s01, _s01)); _sum02 = __msa_addv_w(_sum02, __msa_hadd_s_w(_s02, _s02)); _sum03 = __msa_addv_w(_sum03, __msa_hadd_s_w(_s03, _s03)); _sum10 = __msa_addv_w(_sum10, __msa_hadd_s_w(_s10, _s10)); _sum11 = __msa_addv_w(_sum11, __msa_hadd_s_w(_s11, _s11)); _sum12 = __msa_addv_w(_sum12, __msa_hadd_s_w(_s12, _s12)); _sum13 = __msa_addv_w(_sum13, __msa_hadd_s_w(_s13, _s13)); tmpptr += 16; kptr += 32; } // transpose 4x4 { v4i32 _tmp0, _tmp1, _tmp2, _tmp3; _tmp0 = __msa_ilvr_w(_sum01, _sum00); _tmp1 = __msa_ilvr_w(_sum03, _sum02); _tmp2 = __msa_ilvl_w(_sum01, _sum00); _tmp3 = __msa_ilvl_w(_sum03, _sum02); _sum00 = (v4i32)__msa_ilvr_d((v2i64)_tmp1, (v2i64)_tmp0); _sum01 = (v4i32)__msa_ilvl_d((v2i64)_tmp1, (v2i64)_tmp0); _sum02 = (v4i32)__msa_ilvr_d((v2i64)_tmp3, (v2i64)_tmp2); _sum03 = (v4i32)__msa_ilvl_d((v2i64)_tmp3, (v2i64)_tmp2); } { v4i32 _tmp0, _tmp1, _tmp2, _tmp3; _tmp0 = __msa_ilvr_w(_sum11, _sum10); _tmp1 = __msa_ilvr_w(_sum13, _sum12); _tmp2 = __msa_ilvl_w(_sum11, _sum10); _tmp3 = __msa_ilvl_w(_sum13, _sum12); _sum10 = (v4i32)__msa_ilvr_d((v2i64)_tmp1, (v2i64)_tmp0); _sum11 = (v4i32)__msa_ilvl_d((v2i64)_tmp1, (v2i64)_tmp0); _sum12 = (v4i32)__msa_ilvr_d((v2i64)_tmp3, (v2i64)_tmp2); _sum13 = (v4i32)__msa_ilvl_d((v2i64)_tmp3, (v2i64)_tmp2); } _sum00 = __msa_addv_w(_sum00, _sum01); _sum02 = __msa_addv_w(_sum02, _sum03); _sum10 = __msa_addv_w(_sum10, _sum11); _sum12 = __msa_addv_w(_sum12, _sum13); _sum00 = __msa_addv_w(_sum00, _sum02); _sum10 = __msa_addv_w(_sum10, _sum12); int sum[8]; __msa_st_w(_sum00, sum, 0); __msa_st_w(_sum10, sum + 4, 0); outptr0[0] = sum[0]; outptr1[0] = sum[1]; outptr2[0] = sum[2]; outptr3[0] = sum[3]; outptr0[1] = sum[4]; outptr1[1] = sum[5]; outptr2[1] = sum[6]; outptr3[1] = sum[7]; outptr0 += 2; outptr1 += 2; outptr2 += 2; outptr3 += 2; } for (; i < size; i++) { const signed char* tmpptr = tmp.channel(i / 2 + i % 2); const signed char* kptr = kernel.channel(p / 4); int nn = inch * maxk; // inch always > 0 v4i32 _sum0 = __msa_fill_w(0); v4i32 _sum1 = __msa_fill_w(0); v4i32 _sum2 = __msa_fill_w(0); v4i32 _sum3 = __msa_fill_w(0); int j = 0; for (; j < nn; j++) { __builtin_prefetch(tmpptr + 32); __builtin_prefetch(kptr + 128); v16i8 _val = __msa_ld_b(tmpptr, 0); v8i16 _val16 = (v8i16)__msa_ilvr_b(__msa_clti_s_b(_val, 0), _val); v16i8 _w01 = __msa_ld_b(kptr, 0); v16i8 _w23 = __msa_ld_b(kptr + 16, 0); v16i8 _extw01 = __msa_clti_s_b(_w01, 0); v16i8 _extw23 = __msa_clti_s_b(_w23, 0); v8i16 _w0 = (v8i16)__msa_ilvr_b(_extw01, _w01); v8i16 _w1 = (v8i16)__msa_ilvl_b(_extw01, _w01); v8i16 _w2 = (v8i16)__msa_ilvr_b(_extw23, _w23); v8i16 _w3 = (v8i16)__msa_ilvl_b(_extw23, _w23); v8i16 _s0 = __msa_mulv_h(_val16, _w0); v8i16 _s1 = __msa_mulv_h(_val16, _w1); v8i16 _s2 = __msa_mulv_h(_val16, _w2); v8i16 _s3 = __msa_mulv_h(_val16, _w3); _sum0 = __msa_addv_w(_sum0, __msa_hadd_s_w(_s0, _s0)); _sum1 = __msa_addv_w(_sum1, __msa_hadd_s_w(_s1, _s1)); _sum2 = __msa_addv_w(_sum2, __msa_hadd_s_w(_s2, _s2)); _sum3 = __msa_addv_w(_sum3, __msa_hadd_s_w(_s3, _s3)); tmpptr += 8; kptr += 32; } // transpose 4x4 { v4i32 _tmp0, _tmp1, _tmp2, _tmp3; _tmp0 = __msa_ilvr_w(_sum1, _sum0); _tmp1 = __msa_ilvr_w(_sum3, _sum2); _tmp2 = __msa_ilvl_w(_sum1, _sum0); _tmp3 = __msa_ilvl_w(_sum3, _sum2); _sum0 = (v4i32)__msa_ilvr_d((v2i64)_tmp1, (v2i64)_tmp0); _sum1 = (v4i32)__msa_ilvl_d((v2i64)_tmp1, (v2i64)_tmp0); _sum2 = (v4i32)__msa_ilvr_d((v2i64)_tmp3, (v2i64)_tmp2); _sum3 = (v4i32)__msa_ilvl_d((v2i64)_tmp3, (v2i64)_tmp2); } _sum0 = __msa_addv_w(_sum0, _sum1); _sum2 = __msa_addv_w(_sum2, _sum3); _sum0 = __msa_addv_w(_sum0, _sum2); int sum[4]; __msa_st_w(_sum0, sum, 0); outptr0[0] = sum[0]; outptr1[0] = sum[1]; outptr2[0] = sum[2]; outptr3[0] = sum[3]; outptr0 += 1; outptr1 += 1; outptr2 += 1; outptr3 += 1; } } remain_outch_start += nn_outch << 2; #pragma omp parallel for num_threads(opt.num_threads) for (int p = remain_outch_start; p < outch; p++) { int* outptr0 = top_blob.channel(p); int i = 0; for (; i + 1 < size; i += 2) { const signed char* tmpptr = tmp.channel(i / 2); const signed char* kptr = kernel.channel(p / 4 + p % 4); int nn = inch * maxk; // inch always > 0 v4i32 _sum0 = __msa_fill_w(0); v4i32 _sum1 = __msa_fill_w(0); int j = 0; for (; j < nn; j++) { __builtin_prefetch(tmpptr + 64); __builtin_prefetch(kptr + 32); v16i8 _val01 = __msa_ld_b(tmpptr, 0); v16i8 _extval01 = __msa_clti_s_b(_val01, 0); v8i16 _val0 = (v8i16)__msa_ilvr_b(_extval01, _val01); v8i16 _val1 = (v8i16)__msa_ilvl_b(_extval01, _val01); v16i8 _w = __msa_ld_b(kptr, 0); v8i16 _w16 = (v8i16)__msa_ilvr_b(__msa_clti_s_b(_w, 0), _w); v8i16 _s0 = __msa_mulv_h(_val0, _w16); v8i16 _s1 = __msa_mulv_h(_val1, _w16); _sum0 = __msa_addv_w(_sum0, __msa_hadd_s_w(_s0, _s0)); _sum1 = __msa_addv_w(_sum1, __msa_hadd_s_w(_s1, _s1)); tmpptr += 16; kptr += 8; } outptr0[0] = __msa_reduce_add_w(_sum0); outptr0[1] = __msa_reduce_add_w(_sum1); outptr0 += 2; } for (; i < size; i++) { const signed char* tmpptr = tmp.channel(i / 2 + i % 2); const signed char* kptr = kernel.channel(p / 4 + p % 4); int nn = inch * maxk; // inch always > 0 v4i32 _sum = __msa_fill_w(0); int j = 0; for (; j < nn; j++) { __builtin_prefetch(tmpptr + 32); __builtin_prefetch(kptr + 32); v16i8 _val = __msa_ld_b(tmpptr, 0); v8i16 _val16 = (v8i16)__msa_ilvr_b(__msa_clti_s_b(_val, 0), _val); v16i8 _w = __msa_ld_b(kptr, 0); v8i16 _w16 = (v8i16)__msa_ilvr_b(__msa_clti_s_b(_w, 0), _w); v8i16 _s0 = __msa_mulv_h(_val16, _w16); _sum = __msa_addv_w(_sum, __msa_hadd_s_w(_s0, _s0)); tmpptr += 8; kptr += 8; } outptr0[0] = __msa_reduce_add_w(_sum); outptr0 += 1; } } } static void convolution_im2col_sgemm_transform_kernel_pack8to1_int8_msa(const Mat& _kernel, Mat& kernel_tm, int inch, int outch, int kernel_w, int kernel_h) { const int maxk = kernel_w * kernel_h; // interleave // src = maxk-inch-outch // dst = 8a-4b-maxk-inch/8a-outch/4b Mat kernel = _kernel.reshape(maxk, inch, outch); if (outch >= 4) kernel_tm.create(32 * maxk, inch / 8, outch / 4 + outch % 4, (size_t)1u); else kernel_tm.create(8 * maxk, inch / 8, outch, (size_t)1u); int q = 0; for (; q + 3 < outch; q += 4) { signed char* g00 = kernel_tm.channel(q / 4); for (int p = 0; p + 7 < inch; p += 8) { for (int k = 0; k < maxk; k++) { for (int i = 0; i < 4; i++) { for (int j = 0; j < 8; j++) { const signed char* k00 = kernel.channel(q + i).row(p + j); g00[0] = k00[k]; g00++; } } } } } // TODO unroll 2 for (; q < outch; q++) { signed char* g00 = kernel_tm.channel(q / 4 + q % 4); for (int p = 0; p + 7 < inch; p += 8) { for (int k = 0; k < maxk; k++) { for (int j = 0; j < 8; j++) { const signed char* k00 = kernel.channel(q).row(p + j); g00[0] = k00[k]; g00++; } } } } } static void convolution_im2col_sgemm_pack8to1_int8_msa(const Mat& bottom_blob, Mat& top_blob, const Mat& kernel, int kernel_w, int kernel_h, int dilation_w, int dilation_h, int stride_w, int stride_h, const Option& opt) { int w = bottom_blob.w; int inch = bottom_blob.c; int outw = top_blob.w; int outh = top_blob.h; const int size = outw * outh; const int maxk = kernel_w * kernel_h; // im2col Mat bottom_im2col(size, maxk, inch, 8u, 8, opt.workspace_allocator); { const int gap = w * stride_h - outw * stride_w; #pragma omp parallel for num_threads(opt.num_threads) for (int p = 0; p < inch; p++) { const Mat img = bottom_blob.channel(p); int64_t* ptr = bottom_im2col.channel(p); for (int u = 0; u < kernel_h; u++) { for (int v = 0; v < kernel_w; v++) { const int64_t* sptr = img.row(dilation_h * u) + dilation_w * v; for (int i = 0; i < outh; i++) { int j = 0; for (; j < outw; j++) { ptr[0] = sptr[0]; sptr += stride_w; ptr += 1; } sptr += gap; } } } } } im2col_sgemm_pack8to1_int8_msa(bottom_im2col, top_blob, kernel, opt); }