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ncnn/src/layer/arm/concat_arm.cpp

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  1. // Tencent is pleased to support the open source community by making ncnn available.

  2. //

  3. // Copyright (C) 2019 THL A29 Limited, a Tencent company. All rights reserved.

  4. //

  5. // Licensed under the BSD 3-Clause License (the "License"); you may not use this file except

  6. // in compliance with the License. You may obtain a copy of the License at

  7. //

  8. // https://opensource.org/licenses/BSD-3-Clause

  9. //

  10. // Unless required by applicable law or agreed to in writing, software distributed

  11. // under the License is distributed on an "AS IS" BASIS, WITHOUT WARRANTIES OR

  12. // CONDITIONS OF ANY KIND, either express or implied. See the License for the

  13. // specific language governing permissions and limitations under the License.

  14. 

  15. #include "concat_arm.h"

  16. #include <algorithm>

  17. #include "layer_type.h"

  18. 

  19. namespace ncnn {

  20. 

  21. DEFINE_LAYER_CREATOR(Concat_arm)

  22. 

  23. Concat_arm::Concat_arm()

  24. {

  25. #if __ARM_NEON

  26.     support_packing = true;

  27. 

  28.     packing_pack4 = 0;

  29. #endif // __ARM_NEON

  30. }

  31. 

  32. int Concat_arm::create_pipeline(const Option& opt)

  33. {

  34. #if __ARM_NEON

  35.     if (opt.use_packing_layout)

  36.     {

  37. 

  38.     {

  39.         packing_pack4 = ncnn::create_layer(ncnn::LayerType::Packing);

  40. 

  41.         ncnn::ParamDict pd;

  42.         pd.set(0, 4);

  43. 

  44.         packing_pack4->load_param(pd);

  45. 

  46.         packing_pack4->create_pipeline(opt);

  47.     }

  48. 

  49.     }

  50. #endif // __ARM_NEON

  51. 

  52.     return 0;

  53. }

  54. 

  55. int Concat_arm::destroy_pipeline(const Option& opt)

  56. {

  57. #if __ARM_NEON

  58.     if (opt.use_packing_layout)

  59.     {

  60. 

  61.     if (packing_pack4)

  62.     {

  63.         packing_pack4->destroy_pipeline(opt);

  64.         delete packing_pack4;

  65.         packing_pack4 = 0;

  66.     }

  67. 

  68.     }

  69. #endif // __ARM_NEON

  70. 

  71.     return 0;

  72. }

  73. 

  74. int Concat_arm::forward(const std::vector<Mat>& bottom_blobs, std::vector<Mat>& top_blobs, const Option& opt) const

  75. {

  76.     int dims = bottom_blobs[0].dims;

  77. 

  78. #if __ARM_NEON

  79.     if (opt.use_packing_layout)

  80.     {

  81. 

  82.     if (dims == 1) // axis == 0

  83.     {

  84.         // concat vector

  85.         // total length

  86.         size_t elemsize = bottom_blobs[0].elemsize;

  87.         int elempack = bottom_blobs[0].elempack;

  88.         int top_w = 0;

  89.         for (size_t b=0; b<bottom_blobs.size(); b++)

  90.         {

  91.             const Mat& bottom_blob = bottom_blobs[b];

  92.             top_w += bottom_blob.w * bottom_blob.elempack;

  93.         }

  94. 

  95.         int out_elempack = top_w % 4 == 0 ? 4 : 1;

  96.         size_t out_elemsize = elemsize / elempack * out_elempack;

  97. 

  98.         Mat& top_blob = top_blobs[0];

  99.         top_blob.create(top_w / out_elempack, out_elemsize, out_elempack, opt.blob_allocator);

  100.         if (top_blob.empty())

  101.             return -100;

  102. 

  103.         float* outptr = top_blob;

  104.         for (size_t b=0; b<bottom_blobs.size(); b++)

  105.         {

  106.             const Mat& bottom_blob = bottom_blobs[b];

  107. 

  108.             const float* ptr = bottom_blob;

  109.             memcpy(outptr, ptr, bottom_blob.w * bottom_blob.elemsize);

  110. 

  111.             outptr += bottom_blob.w * bottom_blob.elempack;

  112.         }

  113. 

  114.         return 0;

  115.     }

  116. 

  117.     if (dims == 2 && axis == 0)

  118.     {

  119.         // concat image

  120.         int w = bottom_blobs[0].w;

  121. 

  122.         // total height

  123.         size_t elemsize = bottom_blobs[0].elemsize;

  124.         int elempack = bottom_blobs[0].elempack;

  125.         int top_h = 0;

  126.         for (size_t b=0; b<bottom_blobs.size(); b++)

  127.         {

  128.             const Mat& bottom_blob = bottom_blobs[b];

  129.             elemsize = std::min(elemsize, bottom_blob.elemsize);

  130.             elempack = std::min(elempack, bottom_blob.elempack);

  131.             top_h += bottom_blob.h * bottom_blob.elempack;

  132.         }

  133. 

  134.         int out_elempack = top_h % 4 == 0 ? 4 : 1;

  135.         size_t out_elemsize = elemsize / elempack * out_elempack;

  136. 

  137.         Mat& top_blob = top_blobs[0];

  138.         top_blob.create(w, top_h / out_elempack, out_elemsize, out_elempack, opt.blob_allocator);

  139.         if (top_blob.empty())

  140.             return -100;

  141. 

  142.         Mat top_blob_unpacked = top_blob;

  143.         if (elempack == 1 && out_elempack == 4)

  144.         {

  145.             top_blob_unpacked.create(w, top_h / elempack, elemsize, elempack, opt.workspace_allocator);

  146.             if (top_blob_unpacked.empty())

  147.                 return -100;

  148.         }

  149. 

  150.         float* outptr = top_blob_unpacked;

  151.         for (size_t b=0; b<bottom_blobs.size(); b++)

  152.         {

  153.             const Mat& bottom_blob = bottom_blobs[b];

  154. 

  155.             if (bottom_blob.elempack == 4 && elempack == 1)

  156.             {

  157.                 for (int i=0; i<bottom_blob.h; i++)

  158.                 {

  159.                     const float* r0 = bottom_blob.row(i);

  160. 

  161.                     float* outptr0 = outptr;

  162.                     float* outptr1 = outptr + w;

  163.                     float* outptr2 = outptr + w*2;

  164.                     float* outptr3 = outptr + w*3;

  165. 

  166.                     for (int j=0; j<w; j++)

  167.                     {

  168.                         *outptr0++ = r0[0];

  169.                         *outptr1++ = r0[1];

  170.                         *outptr2++ = r0[2];

  171.                         *outptr3++ = r0[3];

  172. 

  173.                         r0 += 4;

  174.                     }

  175. 

  176.                     outptr += w * 4;

  177.                 }

  178.             }

  179.             else // if (bottom_blob.elempack == 1 && elempack == 1) if (bottom_blob.elempack == 4 && elempack == 4)

  180.             {

  181.                 int size = w * bottom_blob.h;

  182. 

  183.                 const float* ptr = bottom_blob;

  184.                 memcpy(outptr, ptr, size * bottom_blob.elemsize);

  185. 

  186.                 outptr += size * bottom_blob.elempack;

  187.             }

  188.         }

  189. 

  190.         // packing

  191.         if (elempack == 1 && out_elempack == 4)

  192.         {

  193.             packing_pack4->forward(top_blob_unpacked, top_blob, opt);

  194.         }

  195. 

  196.         return 0;

  197.     }

  198. 

  199.     if (dims == 2 && axis == 1)

  200.     {

  201.         // interleave image row

  202.         int h = bottom_blobs[0].h;

  203.         size_t elemsize = bottom_blobs[0].elemsize;

  204.         int elempack = bottom_blobs[0].elempack;

  205. 

  206.         // total width

  207.         int top_w = 0;

  208.         for (size_t b=0; b<bottom_blobs.size(); b++)

  209.         {

  210.             const Mat& bottom_blob = bottom_blobs[b];

  211.             top_w += bottom_blob.w;

  212.         }

  213. 

  214.         Mat& top_blob = top_blobs[0];

  215.         top_blob.create(top_w, h, elemsize, elempack, opt.blob_allocator);

  216.         if (top_blob.empty())

  217.             return -100;

  218. 

  219.         #pragma omp parallel for num_threads(opt.num_threads)

  220.         for (int i=0; i<h; i++)

  221.         {

  222.             float* outptr = top_blob.row(i);

  223.             for (size_t b=0; b<bottom_blobs.size(); b++)

  224.             {

  225.                 const Mat& bottom_blob = bottom_blobs[b];

  226. 

  227.                 const float* ptr = bottom_blob.row(i);

  228.                 memcpy(outptr, ptr, bottom_blob.w * elemsize);

  229. 

  230.                 outptr += bottom_blob.w * elempack;

  231.             }

  232.         }

  233. 

  234.         return 0;

  235.     }

  236. 

  237.     if (dims == 3 && axis == 0)

  238.     {

  239.         // concat dim

  240.         int w = bottom_blobs[0].w;

  241.         int h = bottom_blobs[0].h;

  242. 

  243.         // total channels

  244.         size_t elemsize = bottom_blobs[0].elemsize;

  245.         int elempack = bottom_blobs[0].elempack;

  246.         int top_channels = 0;

  247.         for (size_t b=0; b<bottom_blobs.size(); b++)

  248.         {

  249.             const Mat& bottom_blob = bottom_blobs[b];

  250.             elemsize = std::min(elemsize, bottom_blob.elemsize);

  251.             elempack = std::min(elempack, bottom_blob.elempack);

  252.             top_channels += bottom_blob.c * bottom_blob.elempack;

  253.         }

  254. 

  255.         int out_elempack = top_channels % 4 == 0 ? 4 : 1;

  256.         size_t out_elemsize = elemsize / elempack * out_elempack;

  257. 

  258.         Mat& top_blob = top_blobs[0];

  259.         top_blob.create(w, h, top_channels / out_elempack, out_elemsize, out_elempack, opt.blob_allocator);

  260.         if (top_blob.empty())

  261.             return -100;

  262. 

  263.         Mat top_blob_unpacked = top_blob;

  264.         if (elempack == 1 && out_elempack == 4)

  265.         {

  266.             top_blob_unpacked.create(w, h, top_channels / elempack, elemsize, elempack, opt.workspace_allocator);

  267.             if (top_blob_unpacked.empty())

  268.                 return -100;

  269.         }

  270. 

  271.         int p = 0;

  272.         for (size_t b=0; b<bottom_blobs.size(); b++)

  273.         {

  274.             const Mat& bottom_blob = bottom_blobs[b];

  275. 

  276.             if (bottom_blob.elempack == 4 && elempack == 1)

  277.             {

  278.                 int size = bottom_blob.w * bottom_blob.h;

  279. 

  280.                 for (int q=0; q<bottom_blob.c; q++)

  281.                 {

  282.                     const float* r0 = bottom_blob.channel(q);

  283. 

  284.                     float* outptr0 = top_blob_unpacked.channel(p);

  285.                     float* outptr1 = top_blob_unpacked.channel(p+1);

  286.                     float* outptr2 = top_blob_unpacked.channel(p+2);

  287.                     float* outptr3 = top_blob_unpacked.channel(p+3);

  288. 

  289.                     for (int i=0; i<size; i++)

  290.                     {

  291.                         *outptr0++ = r0[0];

  292.                         *outptr1++ = r0[1];

  293.                         *outptr2++ = r0[2];

  294.                         *outptr3++ = r0[3];

  295. 

  296.                         r0 += 4;

  297.                     }

  298. 

  299.                     p += 4;

  300.                 }

  301.             }

  302.             else // if (bottom_blob.elempack == 1 && elempack == 1) if (bottom_blob.elempack == 4 && elempack == 4)

  303.             {

  304.                 int size = bottom_blob.total();

  305. 

  306.                 const float* ptr = bottom_blob;

  307.                 float* outptr = top_blob_unpacked.channel(p);

  308.                 memcpy(outptr, ptr, size * bottom_blob.elemsize);

  309. 

  310.                 p += bottom_blob.c;

  311.             }

  312.         }

  313. 

  314.         // packing

  315.         if (elempack == 1 && out_elempack == 4)

  316.         {

  317.             packing_pack4->forward(top_blob_unpacked, top_blob, opt);

  318.         }

  319. 

  320.         return 0;

  321.     }

  322. 

  323.     if (dims == 3 && axis == 1)

  324.     {

  325.         // interleave dim height

  326.         int w = bottom_blobs[0].w;

  327.         int channels = bottom_blobs[0].c;

  328.         size_t elemsize = bottom_blobs[0].elemsize;

  329.         int elempack = bottom_blobs[0].elempack;

  330. 

  331.         // total height

  332.         int top_h = 0;

  333.         for (size_t b=0; b<bottom_blobs.size(); b++)

  334.         {

  335.             const Mat& bottom_blob = bottom_blobs[b];

  336.             top_h += bottom_blob.h;

  337.         }

  338. 

  339.         Mat& top_blob = top_blobs[0];

  340.         top_blob.create(w, top_h, channels, elemsize, elempack, opt.blob_allocator);

  341.         if (top_blob.empty())

  342.             return -100;

  343. 

  344.         #pragma omp parallel for num_threads(opt.num_threads)

  345.         for (int q=0; q<channels; q++)

  346.         {

  347.             float* outptr = top_blob.channel(q);

  348. 

  349.             for (size_t b=0; b<bottom_blobs.size(); b++)

  350.             {

  351.                 const Mat& bottom_blob = bottom_blobs[b];

  352. 

  353.                 int size = bottom_blob.w * bottom_blob.h;

  354. 

  355.                 const float* ptr = bottom_blob.channel(q);

  356.                 memcpy(outptr, ptr, size * elemsize);

  357. 

  358.                 outptr += size * elempack;

  359.             }

  360.         }

  361. 

  362.         return 0;

  363.     }

  364. 

  365.     if (dims == 3 && axis == 2)

  366.     {

  367.         // interleave dim width

  368.         int h = bottom_blobs[0].h;

  369.         int channels = bottom_blobs[0].c;

  370.         size_t elemsize = bottom_blobs[0].elemsize;

  371.         int elempack = bottom_blobs[0].elempack;

  372. 

  373.         // total height

  374.         int top_w = 0;

  375.         for (size_t b=0; b<bottom_blobs.size(); b++)

  376.         {

  377.             const Mat& bottom_blob = bottom_blobs[b];

  378.             top_w += bottom_blob.w;

  379.         }

  380. 

  381.         Mat& top_blob = top_blobs[0];

  382.         top_blob.create(top_w, h, channels, elemsize, elempack, opt.blob_allocator);

  383.         if (top_blob.empty())

  384.             return -100;

  385. 

  386.         #pragma omp parallel for num_threads(opt.num_threads)

  387.         for (int q=0; q<channels; q++)

  388.         {

  389.             float* outptr = top_blob.channel(q);

  390. 

  391.             for (int i=0; i<h; i++)

  392.             {

  393.                 for (size_t b=0; b<bottom_blobs.size(); b++)

  394.                 {

  395.                     const Mat& bottom_blob = bottom_blobs[b];

  396. 

  397.                     const float* ptr = bottom_blob.channel(q).row(i);

  398.                     memcpy(outptr, ptr, bottom_blob.w * elemsize);

  399. 

  400.                     outptr += bottom_blob.w * elempack;

  401.                 }

  402.             }

  403.         }

  404. 

  405.         return 0;

  406.     }

  407. 

  408.     } // opt.use_packing_layout

  409. #endif // __ARM_NEON

  410. 

  411.     return Concat::forward(bottom_blobs, top_blobs, opt);

  412. }

  413. 

  414. } // namespace ncnn