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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.
#include "convolution1d_mips.h"
#if __mips_msa
#include <msa.h>
#endif // __mips_msa
#include "mips_activation.h"
#include "mips_usability.h"
namespace ncnn {
Convolution1D_mips::Convolution1D_mips()
{
#if __mips_msa
support_packing = true;
#endif // __mips_msa
}
int Convolution1D_mips::create_pipeline(const Option& opt)
{
if (dynamic_weight)
return 0;
const int num_input = weight_data_size / kernel_w / num_output;
int elempack = 1;
int out_elempack = 1;
#if __mips_msa
if (opt.use_packing_layout)
{
elempack = num_input % 4 == 0 ? 4 : 1;
out_elempack = num_output % 4 == 0 ? 4 : 1;
}
#endif
// src = kw-inch-outch
// dst = pb-pa-kw-inch/pa-outch/pb
{
Mat weight_data_r2 = weight_data.reshape(kernel_w, num_input, num_output);
weight_data_packed.create(kernel_w, num_input / elempack, num_output / out_elempack, (size_t)4u * elempack * out_elempack, elempack * out_elempack);
for (int q = 0; q + (out_elempack - 1) < num_output; q += out_elempack)
{
float* g00 = weight_data_packed.channel(q / out_elempack);
for (int p = 0; p + (elempack - 1) < num_input; p += elempack)
{
for (int k = 0; k < kernel_w; 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] = k00[k];
g00++;
}
}
}
}
}
}
return 0;
}
int Convolution1D_mips::destroy_pipeline(const Option& /*opt*/)
{
return 0;
}
int Convolution1D_mips::forward(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;
const int kernel_extent_w = dilation_w * (kernel_w - 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 out_elempack = 1;
#if __mips_msa
if (opt.use_packing_layout)
{
out_elempack = num_output % 4 == 0 ? 4 : 1;
}
#endif
size_t out_elemsize = elemsize / elempack * out_elempack;
const int outw = (w - kernel_extent_w) / stride_w + 1;
const int outh = num_output / out_elempack;
top_blob.create(outw, outh, out_elemsize, out_elempack, opt.blob_allocator);
if (top_blob.empty())
return -100;
#if __mips_msa
if (elempack == 4 && out_elempack == 4)
{
{
#pragma omp parallel for num_threads(opt.num_threads)
for (int p = 0; p < outh; p++)
{
float* outptr = top_blob.row(p);
for (int j = 0; j < outw; j++)
{
v4f32 _sum = (v4f32)__msa_fill_w(0);
if (bias_term)
{
_sum = (v4f32)__msa_ld_w((const float*)bias_data + p * 4, 0);
}
const float* kptr = weight_data_packed.channel(p);
for (int q = 0; q < h; q++)
{
const float* sptr = bottom_blob_bordered.row(q) + j * stride_w * 4;
for (int k = 0; k < kernel_w; k++)
{
v4f32 _val0 = __msa_fill_w_f32(sptr[0]);
v4f32 _val1 = __msa_fill_w_f32(sptr[1]);
v4f32 _val2 = __msa_fill_w_f32(sptr[2]);
v4f32 _val3 = __msa_fill_w_f32(sptr[3]);
v4f32 _w0 = (v4f32)__msa_ld_w(kptr, 0);
v4f32 _w1 = (v4f32)__msa_ld_w(kptr + 4, 0);
v4f32 _w2 = (v4f32)__msa_ld_w(kptr + 8, 0);
v4f32 _w3 = (v4f32)__msa_ld_w(kptr + 12, 0);
_sum = __msa_fmadd_w(_sum, _val0, _w0);
_sum = __msa_fmadd_w(_sum, _val1, _w1);
_sum = __msa_fmadd_w(_sum, _val2, _w2);
_sum = __msa_fmadd_w(_sum, _val3, _w3);
sptr += dilation_w * 4;
kptr += 16;
}
}
_sum = activation_ps(_sum, activation_type, activation_params);
__msa_st_w((v4i32)_sum, outptr, 0);
outptr += 4;
}
}
}
}
if (elempack == 1 && out_elempack == 4)
{
{
#pragma omp parallel for num_threads(opt.num_threads)
for (int p = 0; p < outh; p++)
{
float* outptr = top_blob.row(p);
for (int j = 0; j < outw; j++)
{
v4f32 _sum = (v4f32)__msa_fill_w(0);
if (bias_term)
{
_sum = (v4f32)__msa_ld_w((const float*)bias_data + p * 4, 0);
}
const float* kptr = weight_data_packed.channel(p);
for (int q = 0; q < h; q++)
{
const float* sptr = bottom_blob_bordered.row(q) + j * stride_w;
for (int k = 0; k < kernel_w; k++)
{
v4f32 _val = __msa_fill_w_f32(sptr[0]);
v4f32 _w = (v4f32)__msa_ld_w(kptr, 0);
_sum = __msa_fmadd_w(_sum, _val, _w);
sptr += dilation_w;
kptr += 4;
}
}
_sum = activation_ps(_sum, activation_type, activation_params);
__msa_st_w((v4i32)_sum, outptr, 0);
outptr += 4;
}
}
}
}
if (elempack == 4 && out_elempack == 1)
{
{
#pragma omp parallel for num_threads(opt.num_threads)
for (int p = 0; p < outh; p++)
{
float* outptr = top_blob.row(p);
for (int j = 0; j < outw; j++)
{
float sum = 0.f;
if (bias_term)
{
sum = bias_data[p];
}
v4f32 _sum = (v4f32)__msa_fill_w(0);
const float* kptr = weight_data_packed.channel(p);
for (int q = 0; q < h; q++)
{
const float* sptr = bottom_blob_bordered.row(q) + j * stride_w * 4;
for (int k = 0; k < kernel_w; k++)
{
v4f32 _val = (v4f32)__msa_ld_w(sptr, 0);
v4f32 _w = (v4f32)__msa_ld_w(kptr, 0);
_sum = __msa_fmadd_w(_sum, _val, _w);
sptr += dilation_w * 4;
kptr += 4;
}
}
sum += __msa_reduce_fadd_w(_sum);
sum = activation_ss(sum, activation_type, activation_params);
outptr[j] = sum;
}
}
}
}
#endif // __mips_msa
if (elempack == 1 && out_elempack == 1)
{
{
#pragma omp parallel for num_threads(opt.num_threads)
for (int p = 0; p < outh; p++)
{
float* outptr = top_blob.row(p);
for (int j = 0; j < outw; j++)
{
float sum = 0.f;
if (bias_term)
{
sum = bias_data[p];
}
const float* kptr = (const float*)weight_data + kernel_w * h * p;
for (int q = 0; q < h; q++)
{
const float* sptr = bottom_blob_bordered.row(q) + j * stride_w;
for (int k = 0; k < kernel_w; k++)
{
float val = sptr[0];
float wt = kptr[0];
sum += val * wt;
sptr += dilation_w;
kptr += 1;
}
}
sum = activation_ss(sum, activation_type, activation_params);
outptr[j] = sum;
}
}
}
}
return 0;
}
int Convolution1D_mips::forward(const std::vector<Mat>& bottom_blobs, std::vector<Mat>& 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 _num_output = _weight_data.c * _weight_data.elempack;
Mat weight_data_flattened;
flatten(_weight_data, weight_data_flattened, opt);
if (weight_data_flattened.empty())
return -100;
// weight_data_flattened as pack1
weight_data_flattened.w *= weight_data_flattened.elempack;
weight_data_flattened.elemsize /= weight_data_flattened.elempack;
weight_data_flattened.elempack = 1;
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;
// bias_data_flattened as pack1
bias_data_flattened.w *= bias_data_flattened.elempack;
bias_data_flattened.elemsize /= bias_data_flattened.elempack;
bias_data_flattened.elempack = 1;
}
ncnn::Layer* op = ncnn::create_layer(ncnn::LayerType::Convolution1D);
ncnn::ParamDict pd;
pd.set(0, _num_output);
pd.set(1, _kernel_w);
pd.set(2, dilation_w);
pd.set(3, stride_w);
pd.set(4, pad_left);
pd.set(15, pad_right);
pd.set(18, pad_value);
pd.set(5, bias_term);
pd.set(6, weight_data_flattened.w);
pd.set(9, activation_type);
pd.set(10, activation_params);
op->load_param(pd);
ncnn::Mat weights[2];
weights[0] = weight_data_flattened;
weights[1] = bias_data_flattened;
op->load_model(ncnn::ModelBinFromMatArray(weights));
op->create_pipeline(opt);
op->forward(bottom_blob, top_blob, opt);
op->destroy_pipeline(opt);
delete op;
return 0;
}
} // namespace ncnn
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