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//
// Copyright (C) 2021 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_msa(const Mat& bottom_im2col, Mat& top_blob, const Mat& kernel, const Mat& _bias, const Option& opt)
{
// Mat bottom_im2col(size, maxk, inch, 4u, 1, 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;
const float* bias = _bias;
// permute
Mat tmp;
if (size >= 4)
tmp.create(4 * maxk, inch, size / 4 + size % 4, 4u, 1, opt.workspace_allocator);
else
tmp.create(maxk, inch, size, 4u, 1, opt.workspace_allocator);
{
int nn_size = size / 4;
#pragma omp parallel for num_threads(opt.num_threads)
for (int ii = 0; ii < nn_size; ii++)
{
int i = ii * 4;
float* tmpptr = tmp.channel(i / 4);
for (int q = 0; q < inch; q++)
{
const float* img0 = (const float*)bottom_im2col.channel(q) + i;
for (int k = 0; k < maxk; k++)
{
#if __mips_msa
__msa_st_w(__msa_ld_w(img0, 0), tmpptr, 0);
#else
tmpptr[0] = img0[0];
tmpptr[1] = img0[1];
tmpptr[2] = img0[2];
tmpptr[3] = img0[3];
#endif
img0 += size;
tmpptr += 4;
}
}
}
int remain_size_start = nn_size * 4;
#pragma omp parallel for num_threads(opt.num_threads)
for (int i = remain_size_start; i < size; i++)
{
float* tmpptr = tmp.channel(i / 4 + i % 4);
for (int q = 0; q < inch; q++)
{
const float* img0 = (const float*)bottom_im2col.channel(q) + i;
for (int k = 0; k < maxk; k++)
{
tmpptr[0] = img0[0];
img0 += size;
tmpptr += 1;
}
}
}
}
#if __mips_msa
int nn_outch = outch >> 3;
int remain_outch_start = nn_outch << 3;
#pragma omp parallel for num_threads(opt.num_threads)
for (int pp = 0; pp < nn_outch; pp++)
{
int p = pp * 8;
float* outptr0 = top_blob.channel(p);
float* outptr1 = top_blob.channel(p + 1);
float* outptr2 = top_blob.channel(p + 2);
float* outptr3 = top_blob.channel(p + 3);
float* outptr4 = top_blob.channel(p + 4);
float* outptr5 = top_blob.channel(p + 5);
float* outptr6 = top_blob.channel(p + 6);
float* outptr7 = top_blob.channel(p + 7);
const float zeros[8] = {0.f, 0.f, 0.f, 0.f, 0.f, 0.f, 0.f, 0.f};
const float* biasptr = bias ? bias + p : zeros;
int i = 0;
for (; i + 3 < size; i += 4)
{
const float* tmpptr = tmp.channel(i / 4);
const float* kptr = kernel.channel(p / 8);
int nn = inch * maxk; // inch always > 0
v4f32 _sum0 = __msa_fill_w_f32(biasptr[0]);
v4f32 _sum1 = __msa_fill_w_f32(biasptr[1]);
v4f32 _sum2 = __msa_fill_w_f32(biasptr[2]);
v4f32 _sum3 = __msa_fill_w_f32(biasptr[3]);
v4f32 _sum4 = __msa_fill_w_f32(biasptr[4]);
v4f32 _sum5 = __msa_fill_w_f32(biasptr[5]);
v4f32 _sum6 = __msa_fill_w_f32(biasptr[6]);
v4f32 _sum7 = __msa_fill_w_f32(biasptr[7]);
for (int q = 0; q < nn; q++)
{
__builtin_prefetch(tmpptr + 16);
__builtin_prefetch(kptr + 32);
v4f32 _val = (v4f32)__msa_ld_w(tmpptr, 0);
v4i32 _w0123 = __msa_ld_w(kptr, 0);
v4i32 _w4567 = __msa_ld_w(kptr + 4, 0);
_sum0 = __msa_fmadd_w(_sum0, _val, (v4f32)__msa_splati_w(_w0123, 0));
_sum1 = __msa_fmadd_w(_sum1, _val, (v4f32)__msa_splati_w(_w0123, 1));
_sum2 = __msa_fmadd_w(_sum2, _val, (v4f32)__msa_splati_w(_w0123, 2));
_sum3 = __msa_fmadd_w(_sum3, _val, (v4f32)__msa_splati_w(_w0123, 3));
_sum4 = __msa_fmadd_w(_sum4, _val, (v4f32)__msa_splati_w(_w4567, 0));
_sum5 = __msa_fmadd_w(_sum5, _val, (v4f32)__msa_splati_w(_w4567, 1));
_sum6 = __msa_fmadd_w(_sum6, _val, (v4f32)__msa_splati_w(_w4567, 2));
_sum7 = __msa_fmadd_w(_sum7, _val, (v4f32)__msa_splati_w(_w4567, 3));
tmpptr += 4;
kptr += 8;
}
__msa_st_w((v4i32)_sum0, outptr0, 0);
__msa_st_w((v4i32)_sum1, outptr1, 0);
__msa_st_w((v4i32)_sum2, outptr2, 0);
__msa_st_w((v4i32)_sum3, outptr3, 0);
__msa_st_w((v4i32)_sum4, outptr4, 0);
__msa_st_w((v4i32)_sum5, outptr5, 0);
__msa_st_w((v4i32)_sum6, outptr6, 0);
__msa_st_w((v4i32)_sum7, outptr7, 0);
outptr0 += 4;
outptr1 += 4;
outptr2 += 4;
outptr3 += 4;
outptr4 += 4;
outptr5 += 4;
outptr6 += 4;
outptr7 += 4;
}
for (; i < size; i++)
{
const float* tmpptr = tmp.channel(i / 4 + i % 4);
const float* kptr = kernel.channel(p / 8);
int nn = inch * maxk; // inch always > 0
float sum0 = biasptr[0];
float sum1 = biasptr[1];
float sum2 = biasptr[2];
float sum3 = biasptr[3];
float sum4 = biasptr[4];
float sum5 = biasptr[5];
float sum6 = biasptr[6];
float sum7 = biasptr[7];
for (int q = 0; q < nn; q++)
{
sum0 += tmpptr[0] * kptr[0];
sum1 += tmpptr[0] * kptr[1];
sum2 += tmpptr[0] * kptr[2];
sum3 += tmpptr[0] * kptr[3];
sum4 += tmpptr[0] * kptr[4];
sum5 += tmpptr[0] * kptr[5];
sum6 += tmpptr[0] * kptr[6];
sum7 += tmpptr[0] * kptr[7];
tmpptr++;
kptr += 8;
}
outptr0[0] = sum0;
outptr1[0] = sum1;
outptr2[0] = sum2;
outptr3[0] = sum3;
outptr4[0] = sum4;
outptr5[0] = sum5;
outptr6[0] = sum6;
outptr7[0] = sum7;
outptr0++;
outptr1++;
outptr2++;
outptr3++;
outptr4++;
outptr5++;
outptr6++;
outptr7++;
}
}
nn_outch = (outch - remain_outch_start) >> 2;
#pragma omp parallel for num_threads(opt.num_threads)
for (int pp = 0; pp < nn_outch; pp++)
{
int p = remain_outch_start + pp * 4;
float* outptr0 = top_blob.channel(p);
float* outptr1 = top_blob.channel(p + 1);
float* outptr2 = top_blob.channel(p + 2);
float* outptr3 = top_blob.channel(p + 3);
const float zeros[4] = {0.f, 0.f, 0.f, 0.f};
const float* biasptr = bias ? bias + p : zeros;
int i = 0;
for (; i + 3 < size; i += 4)
{
const float* tmpptr = tmp.channel(i / 4);
const float* kptr = kernel.channel(p / 8 + (p % 8) / 4);
int nn = inch * maxk; // inch always > 0
v4f32 _sum0 = __msa_fill_w_f32(biasptr[0]);
v4f32 _sum1 = __msa_fill_w_f32(biasptr[1]);
v4f32 _sum2 = __msa_fill_w_f32(biasptr[2]);
v4f32 _sum3 = __msa_fill_w_f32(biasptr[3]);
for (int q = 0; q < nn; q++)
{
__builtin_prefetch(tmpptr + 16);
__builtin_prefetch(kptr + 16);
v4f32 _val = (v4f32)__msa_ld_w(tmpptr, 0);
v4i32 _w0123 = __msa_ld_w(kptr, 0);
_sum0 = __msa_fmadd_w(_sum0, _val, (v4f32)__msa_splati_w(_w0123, 0));
_sum1 = __msa_fmadd_w(_sum1, _val, (v4f32)__msa_splati_w(_w0123, 1));
_sum2 = __msa_fmadd_w(_sum2, _val, (v4f32)__msa_splati_w(_w0123, 2));
_sum3 = __msa_fmadd_w(_sum3, _val, (v4f32)__msa_splati_w(_w0123, 3));
tmpptr += 4;
kptr += 4;
}
__msa_st_w((v4i32)_sum0, outptr0, 0);
__msa_st_w((v4i32)_sum1, outptr1, 0);
__msa_st_w((v4i32)_sum2, outptr2, 0);
__msa_st_w((v4i32)_sum3, outptr3, 0);
outptr0 += 4;
outptr1 += 4;
outptr2 += 4;
outptr3 += 4;
}
for (; i < size; i++)
{
const float* tmpptr = tmp.channel(i / 4 + i % 4);
const float* kptr = kernel.channel(p / 8 + (p % 8) / 4);
int nn = inch * maxk; // inch always > 0
float sum0 = biasptr[0];
float sum1 = biasptr[1];
float sum2 = biasptr[2];
float sum3 = biasptr[3];
for (int q = 0; q < nn; q++)
{
sum0 += tmpptr[0] * kptr[0];
sum1 += tmpptr[0] * kptr[1];
sum2 += tmpptr[0] * kptr[2];
sum3 += tmpptr[0] * kptr[3];
tmpptr++;
kptr += 4;
}
outptr0[0] = sum0;
outptr1[0] = sum1;
outptr2[0] = sum2;
outptr3[0] = sum3;
outptr0++;
outptr1++;
outptr2++;
outptr3++;
}
}
remain_outch_start += nn_outch << 2;
#else // __mips_msa
int nn_outch = outch >> 1;
int remain_outch_start = nn_outch << 1;
#pragma omp parallel for num_threads(opt.num_threads)
for (int pp = 0; pp < nn_outch; pp++)
{
int p = pp * 2;
float* outptr0 = top_blob.channel(p);
float* outptr1 = top_blob.channel(p + 1);
const float zeros[2] = {0.f, 0.f};
const float* biasptr = bias ? bias + p : zeros;
int i = 0;
for (; i + 3 < size; i += 4)
{
const float* tmpptr = tmp.channel(i / 4);
const float* kptr = kernel.channel(p / 2);
int nn = inch * maxk; // inch always > 0
float sum00 = biasptr[0];
float sum01 = biasptr[0];
float sum02 = biasptr[0];
float sum03 = biasptr[0];
float sum10 = biasptr[1];
float sum11 = biasptr[1];
float sum12 = biasptr[1];
float sum13 = biasptr[1];
for (int q = 0; q < nn; q++)
{
__builtin_prefetch(tmpptr + 16);
__builtin_prefetch(kptr + 8);
float k0 = kptr[0];
float k1 = kptr[1];
sum00 += tmpptr[0] * k0;
sum01 += tmpptr[1] * k0;
sum02 += tmpptr[2] * k0;
sum03 += tmpptr[3] * k0;
sum10 += tmpptr[0] * k1;
sum11 += tmpptr[1] * k1;
sum12 += tmpptr[2] * k1;
sum13 += tmpptr[3] * k1;
tmpptr += 4;
kptr += 2;
}
outptr0[0] = sum00;
outptr0[1] = sum01;
outptr0[2] = sum02;
outptr0[3] = sum03;
outptr1[0] = sum10;
outptr1[1] = sum11;
outptr1[2] = sum12;
outptr1[3] = sum13;
outptr0 += 4;
outptr1 += 4;
}
for (; i < size; i++)
{
const float* tmpptr = tmp.channel(i / 4 + i % 4);
const float* kptr = kernel.channel(p / 2);
int nn = inch * maxk; // inch always > 0
float sum0 = biasptr[0];
float sum1 = biasptr[1];
for (int q = 0; q < nn; q++)
{
__builtin_prefetch(tmpptr + 4);
__builtin_prefetch(kptr + 8);
sum0 += tmpptr[0] * kptr[0];
sum1 += tmpptr[0] * kptr[1];
tmpptr++;
kptr += 2;
}
outptr0[0] = sum0;
outptr1[0] = sum1;
outptr0++;
outptr1++;
}
}
#endif // __mips_msa
#pragma omp parallel for num_threads(opt.num_threads)
for (int p = remain_outch_start; p < outch; p++)
{
float* outptr0 = top_blob.channel(p);
const float bias0 = bias ? bias[p] : 0.f;
int i = 0;
for (; i + 3 < size; i += 4)
{
const float* tmpptr = tmp.channel(i / 4);
#if __mips_msa
const float* kptr = kernel.channel(p / 8 + (p % 8) / 4 + p % 4);
#else
const float* kptr = kernel.channel(p / 2 + p % 2);
#endif
int nn = inch * maxk; // inch always > 0
#if __mips_msa
v4f32 _sum0 = __msa_fill_w_f32(bias0);
for (int q = 0; q < nn; q++)
{
_sum0 = __msa_fmadd_w(_sum0, __msa_fill_w_f32(kptr[0]), (v4f32)__msa_ld_w(tmpptr, 0));
tmpptr += 4;
kptr++;
}
__msa_st_w((v4i32)_sum0, outptr0, 0);
outptr0 += 4;
#else
float sum0 = bias0;
float sum1 = bias0;
float sum2 = bias0;
float sum3 = bias0;
for (int q = 0; q < nn; q++)
{
__builtin_prefetch(tmpptr + 16);
__builtin_prefetch(kptr + 4);
sum0 += tmpptr[0] * kptr[0];
sum1 += tmpptr[1] * kptr[0];
sum2 += tmpptr[2] * kptr[0];
sum3 += tmpptr[3] * kptr[0];
tmpptr += 4;
kptr++;
}
outptr0[0] = sum0;
outptr0[1] = sum1;
outptr0[2] = sum2;
outptr0[3] = sum3;
outptr0 += 4;
#endif // __mips_msa
}
for (; i < size; i++)
{
const float* tmpptr = tmp.channel(i / 4 + i % 4);
#if __mips_msa
const float* kptr = kernel.channel(p / 8 + (p % 8) / 4 + p % 4);
#else
const float* kptr = kernel.channel(p / 2 + p % 2);
#endif
int nn = inch * maxk; // inch always > 0
float sum0 = bias0;
for (int q = 0; q < nn; q++)
{
sum0 += tmpptr[0] * kptr[0];
tmpptr++;
kptr++;
}
outptr0[0] = sum0;
outptr0++;
}
}
}
static void convolution_im2col_sgemm_transform_kernel_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 = 8b-maxk-inch-outch/8b
Mat kernel = _kernel.reshape(maxk, inch, outch);
#if __mips_msa
kernel_tm.create(8 * maxk, inch, outch / 8 + (outch % 8) / 4 + outch % 4);
#else
kernel_tm.create(2 * maxk, inch, outch / 2 + outch % 2);
#endif
int q = 0;
#if __mips_msa
for (; q + 7 < outch; q += 8)
{
const Mat k0 = kernel.channel(q);
const Mat k1 = kernel.channel(q + 1);
const Mat k2 = kernel.channel(q + 2);
const Mat k3 = kernel.channel(q + 3);
const Mat k4 = kernel.channel(q + 4);
const Mat k5 = kernel.channel(q + 5);
const Mat k6 = kernel.channel(q + 6);
const Mat k7 = kernel.channel(q + 7);
float* g00 = kernel_tm.channel(q / 8);
for (int p = 0; p < inch; p++)
{
const float* k00 = k0.row(p);
const float* k10 = k1.row(p);
const float* k20 = k2.row(p);
const float* k30 = k3.row(p);
const float* k40 = k4.row(p);
const float* k50 = k5.row(p);
const float* k60 = k6.row(p);
const float* k70 = k7.row(p);
for (int k = 0; k < maxk; k++)
{
g00[0] = k00[k];
g00[1] = k10[k];
g00[2] = k20[k];
g00[3] = k30[k];
g00[4] = k40[k];
g00[5] = k50[k];
g00[6] = k60[k];
g00[7] = k70[k];
g00 += 8;
}
}
}
for (; q + 3 < outch; q += 4)
{
const Mat k0 = kernel.channel(q);
const Mat k1 = kernel.channel(q + 1);
const Mat k2 = kernel.channel(q + 2);
const Mat k3 = kernel.channel(q + 3);
float* g00 = kernel_tm.channel(q / 8 + (q % 8) / 4);
for (int p = 0; p < inch; p++)
{
const float* k00 = k0.row(p);
const float* k10 = k1.row(p);
const float* k20 = k2.row(p);
const float* k30 = k3.row(p);
for (int k = 0; k < maxk; k++)
{
g00[0] = k00[k];
g00[1] = k10[k];
g00[2] = k20[k];
g00[3] = k30[k];
g00 += 4;
}
}
}
#else
for (; q + 1 < outch; q += 2)
{
const Mat k0 = kernel.channel(q);
const Mat k1 = kernel.channel(q + 1);
float* g00 = kernel_tm.channel(q / 2);
for (int p = 0; p < inch; p++)
{
const float* k00 = k0.row(p);
const float* k10 = k1.row(p);
for (int k = 0; k < maxk; k++)
{
g00[0] = k00[k];
g00[1] = k10[k];
g00 += 2;
}
}
}
#endif // __mips_msa
for (; q < outch; q++)
{
const Mat k0 = kernel.channel(q);
#if __mips_msa
float* g00 = kernel_tm.channel(q / 8 + (q % 8) / 4 + q % 4);
#else
float* g00 = kernel_tm.channel(q / 2 + q % 2);
#endif
for (int p = 0; p < inch; p++)
{
const float* k00 = k0.row(p);
for (int k = 0; k < maxk; k++)
{
g00[0] = k00[k];
g00 += 1;
}
}
}
}
static void convolution_im2col_sgemm_msa(const Mat& bottom_blob, Mat& top_blob, const Mat& kernel, const Mat& _bias, 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, 4u, 1, 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);
float* ptr = bottom_im2col.channel(p);
for (int u = 0; u < kernel_h; u++)
{
for (int v = 0; v < kernel_w; v++)
{
const float* sptr = img.row<const float>(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_msa(bottom_im2col, top_blob, kernel, _bias, opt);
}
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