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caffe2ncnn.cpp 36 kB

9 years ago
9 years ago
9 years ago
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  1. // Tencent is pleased to support the open source community by making ncnn available.
  2. //
  3. // Copyright (C) 2017 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. #include <stdio.h>
  15. #include <limits.h>
  16. #include <math.h>
  17. #include <fstream>
  18. #include <set>
  19. #include <limits>
  20. #include <algorithm>
  21. #include <google/protobuf/io/coded_stream.h>
  22. #include <google/protobuf/io/zero_copy_stream_impl.h>
  23. #include <google/protobuf/text_format.h>
  24. #include <google/protobuf/message.h>
  25. #include "caffe.pb.h"
  26. static inline size_t alignSize(size_t sz, int n)
  27. {
  28. return (sz + n-1) & -n;
  29. }
  30. // convert float to half precision floating point
  31. static unsigned short float2half(float value)
  32. {
  33. // 1 : 8 : 23
  34. union
  35. {
  36. unsigned int u;
  37. float f;
  38. } tmp;
  39. tmp.f = value;
  40. // 1 : 8 : 23
  41. unsigned short sign = (tmp.u & 0x80000000) >> 31;
  42. unsigned short exponent = (tmp.u & 0x7F800000) >> 23;
  43. unsigned int significand = tmp.u & 0x7FFFFF;
  44. // fprintf(stderr, "%d %d %d\n", sign, exponent, significand);
  45. // 1 : 5 : 10
  46. unsigned short fp16;
  47. if (exponent == 0)
  48. {
  49. // zero or denormal, always underflow
  50. fp16 = (sign << 15) | (0x00 << 10) | 0x00;
  51. }
  52. else if (exponent == 0xFF)
  53. {
  54. // infinity or NaN
  55. fp16 = (sign << 15) | (0x1F << 10) | (significand ? 0x200 : 0x00);
  56. }
  57. else
  58. {
  59. // normalized
  60. short newexp = exponent + (- 127 + 15);
  61. if (newexp >= 31)
  62. {
  63. // overflow, return infinity
  64. fp16 = (sign << 15) | (0x1F << 10) | 0x00;
  65. }
  66. else if (newexp <= 0)
  67. {
  68. // underflow
  69. if (newexp >= -10)
  70. {
  71. // denormal half-precision
  72. unsigned short sig = (significand | 0x800000) >> (14 - newexp);
  73. fp16 = (sign << 15) | (0x00 << 10) | sig;
  74. }
  75. else
  76. {
  77. // underflow
  78. fp16 = (sign << 15) | (0x00 << 10) | 0x00;
  79. }
  80. }
  81. else
  82. {
  83. fp16 = (sign << 15) | (newexp << 10) | (significand >> 13);
  84. }
  85. }
  86. return fp16;
  87. }
  88. static int quantize_weight(float *data, size_t data_length, std::vector<unsigned short>& float16_weights)
  89. {
  90. float16_weights.resize(data_length);
  91. for (size_t i = 0; i < data_length; i++)
  92. {
  93. float f = data[i];
  94. unsigned short fp16 = float2half(f);
  95. float16_weights[i] = fp16;
  96. }
  97. // magic tag for half-precision floating point
  98. return 0x01306B47;
  99. }
  100. static bool quantize_weight(float *data, size_t data_length, int quantize_level, std::vector<float> &quantize_table, std::vector<unsigned char> &quantize_index) {
  101. assert(quantize_level != 0);
  102. assert(data != NULL);
  103. assert(data_length > 0);
  104. if (data_length < static_cast<size_t>(quantize_level)) {
  105. fprintf(stderr, "No need quantize,because: data_length < quantize_level");
  106. return false;
  107. }
  108. quantize_table.reserve(quantize_level);
  109. quantize_index.reserve(data_length);
  110. // 1. Find min and max value
  111. float max_value = std::numeric_limits<float>::min();
  112. float min_value = std::numeric_limits<float>::max();
  113. for (size_t i = 0; i < data_length; ++i)
  114. {
  115. if (max_value < data[i]) max_value = data[i];
  116. if (min_value > data[i]) min_value = data[i];
  117. }
  118. float strides = (max_value - min_value) / quantize_level;
  119. // 2. Generate quantize table
  120. for (int i = 0; i < quantize_level; ++i)
  121. {
  122. quantize_table.push_back(min_value + i * strides);
  123. }
  124. // 3. Align data to the quantized value
  125. for (size_t i = 0; i < data_length; ++i)
  126. {
  127. size_t table_index = int((data[i] - min_value) / strides);
  128. table_index = std::min<float>(table_index, quantize_level - 1);
  129. float low_value = quantize_table[table_index];
  130. float high_value = low_value + strides;
  131. // find a nearest value between low and high value.
  132. float targetValue = data[i] - low_value < high_value - data[i] ? low_value : high_value;
  133. table_index = int((targetValue - min_value) / strides);
  134. table_index = std::min<float>(table_index, quantize_level - 1);
  135. quantize_index.push_back(table_index);
  136. }
  137. return true;
  138. }
  139. static bool read_proto_from_text(const char* filepath, google::protobuf::Message* message)
  140. {
  141. std::ifstream fs(filepath, std::ifstream::in);
  142. if (!fs.is_open())
  143. {
  144. fprintf(stderr, "open failed %s\n", filepath);
  145. return false;
  146. }
  147. google::protobuf::io::IstreamInputStream input(&fs);
  148. bool success = google::protobuf::TextFormat::Parse(&input, message);
  149. fs.close();
  150. return success;
  151. }
  152. static bool read_proto_from_binary(const char* filepath, google::protobuf::Message* message)
  153. {
  154. std::ifstream fs(filepath, std::ifstream::in | std::ifstream::binary);
  155. if (!fs.is_open())
  156. {
  157. fprintf(stderr, "open failed %s\n", filepath);
  158. return false;
  159. }
  160. google::protobuf::io::IstreamInputStream input(&fs);
  161. google::protobuf::io::CodedInputStream codedstr(&input);
  162. codedstr.SetTotalBytesLimit(INT_MAX, INT_MAX / 2);
  163. bool success = message->ParseFromCodedStream(&codedstr);
  164. fs.close();
  165. return success;
  166. }
  167. int main(int argc, char** argv)
  168. {
  169. if (!(argc == 3 || argc == 5 || argc == 6))
  170. {
  171. fprintf(stderr, "Usage: %s [caffeproto] [caffemodel] [ncnnproto] [ncnnbin] [quantizelevel]\n", argv[0]);
  172. return -1;
  173. }
  174. const char* caffeproto = argv[1];
  175. const char* caffemodel = argv[2];
  176. const char* ncnn_prototxt = argc >= 5 ? argv[3] : "ncnn.proto";
  177. const char* ncnn_modelbin = argc >= 5 ? argv[4] : "ncnn.bin";
  178. const char* quantize_param = argc == 6 ? argv[5] : "0";
  179. int quantize_level = atoi(quantize_param);
  180. if (quantize_level != 0 && quantize_level != 256 && quantize_level != 65536) {
  181. fprintf(stderr, "%s: only support quantize level = 0, 256, or 65536", argv[0]);
  182. return -1;
  183. }
  184. caffe::NetParameter proto;
  185. caffe::NetParameter net;
  186. // load
  187. bool s0 = read_proto_from_text(caffeproto, &proto);
  188. if (!s0)
  189. {
  190. fprintf(stderr, "read_proto_from_text failed\n");
  191. return -1;
  192. }
  193. bool s1 = read_proto_from_binary(caffemodel, &net);
  194. if (!s1)
  195. {
  196. fprintf(stderr, "read_proto_from_binary failed\n");
  197. return -1;
  198. }
  199. FILE* pp = fopen(ncnn_prototxt, "wb");
  200. FILE* bp = fopen(ncnn_modelbin, "wb");
  201. // rename mapping for identical bottom top style
  202. std::map<std::string, std::string> blob_name_decorated;
  203. // bottom blob reference
  204. std::map<std::string, int> bottom_reference;
  205. // global definition line
  206. // [layer count] [blob count]
  207. int layer_count = proto.layer_size();
  208. std::set<std::string> blob_names;
  209. for (int i=0; i<layer_count; i++)
  210. {
  211. const caffe::LayerParameter& layer = proto.layer(i);
  212. for (int j=0; j<layer.bottom_size(); j++)
  213. {
  214. std::string blob_name = layer.bottom(j);
  215. if (blob_name_decorated.find(blob_name) != blob_name_decorated.end())
  216. {
  217. blob_name = blob_name_decorated[blob_name];
  218. }
  219. blob_names.insert(blob_name);
  220. if (bottom_reference.find(blob_name) == bottom_reference.end())
  221. {
  222. bottom_reference[blob_name] = 1;
  223. }
  224. else
  225. {
  226. bottom_reference[blob_name] = bottom_reference[blob_name] + 1;
  227. }
  228. }
  229. if (layer.bottom_size() == 1 && layer.top_size() == 1 && layer.bottom(0) == layer.top(0))
  230. {
  231. std::string blob_name = layer.top(0) + "_" + layer.name();
  232. blob_name_decorated[layer.top(0)] = blob_name;
  233. blob_names.insert(blob_name);
  234. }
  235. else
  236. {
  237. for (int j=0; j<layer.top_size(); j++)
  238. {
  239. std::string blob_name = layer.top(j);
  240. blob_names.insert(blob_name);
  241. }
  242. }
  243. }
  244. // remove bottom_reference entry with reference equals to one
  245. int splitncnn_blob_count = 0;
  246. std::map<std::string, int>::iterator it = bottom_reference.begin();
  247. while (it != bottom_reference.end())
  248. {
  249. if (it->second == 1)
  250. {
  251. bottom_reference.erase(it++);
  252. }
  253. else
  254. {
  255. splitncnn_blob_count += it->second;
  256. // fprintf(stderr, "%s %d\n", it->first.c_str(), it->second);
  257. ++it;
  258. }
  259. }
  260. fprintf(pp, "%lu %lu\n", layer_count + bottom_reference.size(), blob_names.size() + splitncnn_blob_count);
  261. // populate
  262. blob_name_decorated.clear();
  263. int internal_split = 0;
  264. for (int i=0; i<layer_count; i++)
  265. {
  266. const caffe::LayerParameter& layer = proto.layer(i);
  267. // layer definition line, repeated
  268. // [type] [name] [bottom blob count] [top blob count] [bottom blobs] [top blobs] [layer specific params]
  269. if (layer.type() == "Concat")
  270. {
  271. const caffe::ConcatParameter& concat_param = layer.concat_param();
  272. if (concat_param.axis() != 1)
  273. fprintf(pp, "%-16s", "ConcatV2");
  274. else
  275. fprintf(pp, "%-16s", "Concat");
  276. }
  277. else if (layer.type() == "Convolution")
  278. {
  279. const caffe::ConvolutionParameter& convolution_param = layer.convolution_param();
  280. if (convolution_param.group() != 1)
  281. fprintf(pp, "%-16s", "ConvolutionDepthWise");
  282. else
  283. fprintf(pp, "%-16s", "Convolution");
  284. }
  285. else
  286. {
  287. fprintf(pp, "%-16s", layer.type().c_str());
  288. }
  289. fprintf(pp, " %-16s %d %d", layer.name().c_str(), layer.bottom_size(), layer.top_size());
  290. for (int j=0; j<layer.bottom_size(); j++)
  291. {
  292. std::string blob_name = layer.bottom(j);
  293. if (blob_name_decorated.find(layer.bottom(j)) != blob_name_decorated.end())
  294. {
  295. blob_name = blob_name_decorated[layer.bottom(j)];
  296. }
  297. if (bottom_reference.find(blob_name) != bottom_reference.end())
  298. {
  299. int refidx = bottom_reference[blob_name] - 1;
  300. bottom_reference[blob_name] = refidx;
  301. char splitsuffix[256];
  302. sprintf(splitsuffix, "_splitncnn_%d", refidx);
  303. blob_name = blob_name + splitsuffix;
  304. }
  305. fprintf(pp, " %s", blob_name.c_str());
  306. }
  307. // decorated
  308. if (layer.bottom_size() == 1 && layer.top_size() == 1 && layer.bottom(0) == layer.top(0))
  309. {
  310. std::string blob_name = layer.top(0) + "_" + layer.name();
  311. blob_name_decorated[layer.top(0)] = blob_name;
  312. fprintf(pp, " %s", blob_name.c_str());
  313. }
  314. else
  315. {
  316. for (int j=0; j<layer.top_size(); j++)
  317. {
  318. std::string blob_name = layer.top(j);
  319. fprintf(pp, " %s", blob_name.c_str());
  320. }
  321. }
  322. // find blob binary by layer name
  323. int netidx;
  324. for (netidx=0; netidx<net.layer_size(); netidx++)
  325. {
  326. if (net.layer(netidx).name() == layer.name())
  327. {
  328. break;
  329. }
  330. }
  331. // layer specific params
  332. if (layer.type() == "BatchNorm")
  333. {
  334. const caffe::LayerParameter& binlayer = net.layer(netidx);
  335. const caffe::BlobProto& mean_blob = binlayer.blobs(0);
  336. const caffe::BlobProto& var_blob = binlayer.blobs(1);
  337. fprintf(pp, " %d", (int)mean_blob.data_size());
  338. const caffe::BatchNormParameter& batch_norm_param = layer.batch_norm_param();
  339. float eps = batch_norm_param.eps();
  340. std::vector<float> ones(mean_blob.data_size(), 1.f);
  341. fwrite(ones.data(), sizeof(float), ones.size(), bp);// slope
  342. if (binlayer.blobs_size() < 3)
  343. {
  344. fwrite(mean_blob.data().data(), sizeof(float), mean_blob.data_size(), bp);
  345. float tmp;
  346. for (int j=0; j<var_blob.data_size(); j++)
  347. {
  348. tmp = var_blob.data().data()[j] + eps;
  349. fwrite(&tmp, sizeof(float), 1, bp);
  350. }
  351. }
  352. else
  353. {
  354. float scale_factor = 1 / binlayer.blobs(2).data().data()[0];
  355. // premultiply scale_factor to mean and variance
  356. float tmp;
  357. for (int j=0; j<mean_blob.data_size(); j++)
  358. {
  359. tmp = mean_blob.data().data()[j] * scale_factor;
  360. fwrite(&tmp, sizeof(float), 1, bp);
  361. }
  362. for (int j=0; j<var_blob.data_size(); j++)
  363. {
  364. tmp = var_blob.data().data()[j] * scale_factor + eps;
  365. fwrite(&tmp, sizeof(float), 1, bp);
  366. }
  367. }
  368. std::vector<float> zeros(mean_blob.data_size(), 0.f);
  369. fwrite(zeros.data(), sizeof(float), zeros.size(), bp);// bias
  370. }
  371. else if (layer.type() == "Concat")
  372. {
  373. const caffe::ConcatParameter& concat_param = layer.concat_param();
  374. if (concat_param.axis() != 1)
  375. {
  376. int dim = concat_param.axis() >= 1 ? concat_param.axis() - 1 : 0;
  377. fprintf(pp, " %d", dim);
  378. }
  379. }
  380. else if (layer.type() == "Convolution")
  381. {
  382. const caffe::LayerParameter& binlayer = net.layer(netidx);
  383. const caffe::BlobProto& weight_blob = binlayer.blobs(0);
  384. const caffe::ConvolutionParameter& convolution_param = layer.convolution_param();
  385. fprintf(pp, " %d %d %d %d %d %d %d", convolution_param.num_output(), convolution_param.kernel_size(0),
  386. convolution_param.dilation_size() != 0 ? convolution_param.dilation(0) : 1,
  387. convolution_param.stride_size() != 0 ? convolution_param.stride(0) : 1,
  388. convolution_param.pad_size() != 0 ? convolution_param.pad(0) : 0,
  389. convolution_param.bias_term(),
  390. weight_blob.data_size());
  391. if (convolution_param.group() != 1)
  392. {
  393. fprintf(pp, " %d", convolution_param.group());
  394. }
  395. for (int j = 0; j < binlayer.blobs_size(); j++)
  396. {
  397. int quantize_tag = 0;
  398. const caffe::BlobProto& blob = binlayer.blobs(j);
  399. std::vector<float> quantize_table;
  400. std::vector<unsigned char> quantize_index;
  401. std::vector<unsigned short> float16_weights;
  402. // we will not quantize the bias values
  403. if (j == 0 && quantize_level != 0)
  404. {
  405. if (quantize_level == 256)
  406. {
  407. quantize_tag = quantize_weight((float *)blob.data().data(), blob.data_size(), quantize_level, quantize_table, quantize_index);
  408. }
  409. else if (quantize_level == 65536)
  410. {
  411. quantize_tag = quantize_weight((float *)blob.data().data(), blob.data_size(), float16_weights);
  412. }
  413. }
  414. // write quantize tag first
  415. if (j == 0)
  416. fwrite(&quantize_tag, sizeof(int), 1, bp);
  417. if (quantize_tag)
  418. {
  419. int p0 = ftell(bp);
  420. if (quantize_level == 256)
  421. {
  422. // write quantize table and index
  423. fwrite(quantize_table.data(), sizeof(float), quantize_table.size(), bp);
  424. fwrite(quantize_index.data(), sizeof(unsigned char), quantize_index.size(), bp);
  425. }
  426. else if (quantize_level == 65536)
  427. {
  428. fwrite(float16_weights.data(), sizeof(unsigned short), float16_weights.size(), bp);
  429. }
  430. // padding to 32bit align
  431. int nwrite = ftell(bp) - p0;
  432. int nalign = alignSize(nwrite, 4);
  433. unsigned char padding[4] = {0x00, 0x00, 0x00, 0x00};
  434. fwrite(padding, sizeof(unsigned char), nalign - nwrite, bp);
  435. }
  436. else
  437. {
  438. // write original data
  439. fwrite(blob.data().data(), sizeof(float), blob.data_size(), bp);
  440. }
  441. }
  442. }
  443. else if (layer.type() == "Crop")
  444. {
  445. const caffe::CropParameter& crop_param = layer.crop_param();
  446. int num_offset = crop_param.offset_size();
  447. int woffset = (num_offset == 2) ? crop_param.offset(0) : 0;
  448. int hoffset = (num_offset == 2) ? crop_param.offset(1) : 0;
  449. fprintf(pp, " %d %d", woffset, hoffset);
  450. }
  451. else if (layer.type() == "Deconvolution")
  452. {
  453. const caffe::LayerParameter& binlayer = net.layer(netidx);
  454. const caffe::BlobProto& weight_blob = binlayer.blobs(0);
  455. const caffe::ConvolutionParameter& convolution_param = layer.convolution_param();
  456. fprintf(pp, " %d %d %d %d %d %d %d", convolution_param.num_output(), convolution_param.kernel_size(0),
  457. convolution_param.dilation_size() != 0 ? convolution_param.dilation(0) : 1,
  458. convolution_param.stride_size() != 0 ? convolution_param.stride(0) : 1,
  459. convolution_param.pad_size() != 0 ? convolution_param.pad(0) : 0,
  460. convolution_param.bias_term(),
  461. weight_blob.data_size());
  462. int quantized_weight = 0;
  463. fwrite(&quantized_weight, sizeof(int), 1, bp);
  464. // reorder weight from inch-outch to outch-inch
  465. int ksize = convolution_param.kernel_size(0);
  466. int num_output = convolution_param.num_output();
  467. int num_input = weight_blob.data_size() / (ksize * ksize) / num_output;
  468. const float* weight_data_ptr = weight_blob.data().data();
  469. for (int k=0; k<num_output; k++)
  470. {
  471. for (int j=0; j<num_input; j++)
  472. {
  473. fwrite(weight_data_ptr + (j*num_output + k) * ksize * ksize, sizeof(float), ksize * ksize, bp);
  474. }
  475. }
  476. for (int j=1; j<binlayer.blobs_size(); j++)
  477. {
  478. const caffe::BlobProto& blob = binlayer.blobs(j);
  479. fwrite(blob.data().data(), sizeof(float), blob.data_size(), bp);
  480. }
  481. }
  482. else if (layer.type() == "Eltwise")
  483. {
  484. const caffe::EltwiseParameter& eltwise_param = layer.eltwise_param();
  485. int coeff_size = eltwise_param.coeff_size();
  486. fprintf(pp, " %d %d", (int)eltwise_param.operation(), coeff_size);
  487. for (int j=0; j<coeff_size; j++)
  488. {
  489. fprintf(pp, " %f", eltwise_param.coeff(j));
  490. }
  491. }
  492. else if (layer.type() == "ELU")
  493. {
  494. const caffe::ELUParameter& elu_param = layer.elu_param();
  495. fprintf(pp, " %f", elu_param.alpha());
  496. }
  497. else if (layer.type() == "InnerProduct")
  498. {
  499. const caffe::LayerParameter& binlayer = net.layer(netidx);
  500. const caffe::BlobProto& weight_blob = binlayer.blobs(0);
  501. const caffe::InnerProductParameter& inner_product_param = layer.inner_product_param();
  502. fprintf(pp, " %d %d %d", inner_product_param.num_output(), inner_product_param.bias_term(),
  503. weight_blob.data_size());
  504. for (int j=0; j<binlayer.blobs_size(); j++)
  505. {
  506. int quantize_tag = 0;
  507. const caffe::BlobProto& blob = binlayer.blobs(j);
  508. std::vector<float> quantize_table;
  509. std::vector<unsigned char> quantize_index;
  510. std::vector<unsigned short> float16_weights;
  511. // we will not quantize the bias values
  512. if (j == 0 && quantize_level != 0)
  513. {
  514. if (quantize_level == 256)
  515. {
  516. quantize_tag = quantize_weight((float *)blob.data().data(), blob.data_size(), quantize_level, quantize_table, quantize_index);
  517. }
  518. else if (quantize_level == 65536)
  519. {
  520. quantize_tag = quantize_weight((float *)blob.data().data(), blob.data_size(), float16_weights);
  521. }
  522. }
  523. // write quantize tag first
  524. if (j == 0)
  525. fwrite(&quantize_tag, sizeof(int), 1, bp);
  526. if (quantize_tag)
  527. {
  528. int p0 = ftell(bp);
  529. if (quantize_level == 256)
  530. {
  531. // write quantize table and index
  532. fwrite(quantize_table.data(), sizeof(float), quantize_table.size(), bp);
  533. fwrite(quantize_index.data(), sizeof(unsigned char), quantize_index.size(), bp);
  534. }
  535. else if (quantize_level == 65536)
  536. {
  537. fwrite(float16_weights.data(), sizeof(unsigned short), float16_weights.size(), bp);
  538. }
  539. // padding to 32bit align
  540. int nwrite = ftell(bp) - p0;
  541. int nalign = alignSize(nwrite, 4);
  542. unsigned char padding[4] = {0x00, 0x00, 0x00, 0x00};
  543. fwrite(padding, sizeof(unsigned char), nalign - nwrite, bp);
  544. }
  545. else
  546. {
  547. // write original data
  548. fwrite(blob.data().data(), sizeof(float), blob.data_size(), bp);
  549. }
  550. }
  551. }
  552. else if (layer.type() == "Input")
  553. {
  554. const caffe::InputParameter& input_param = layer.input_param();
  555. const caffe::BlobShape& bs = input_param.shape(0);
  556. for (int j=1; j<std::min((int)bs.dim_size(), 4); j++)
  557. {
  558. fprintf(pp, " %ld", bs.dim(j));
  559. }
  560. for (int j=bs.dim_size(); j<4; j++)
  561. {
  562. fprintf(pp, " -233");
  563. }
  564. }
  565. else if (layer.type() == "LRN")
  566. {
  567. const caffe::LRNParameter& lrn_param = layer.lrn_param();
  568. fprintf(pp, " %d %d %.8f %.8f", lrn_param.norm_region(), lrn_param.local_size(), lrn_param.alpha(), lrn_param.beta());
  569. }
  570. else if (layer.type() == "MemoryData")
  571. {
  572. const caffe::MemoryDataParameter& memory_data_param = layer.memory_data_param();
  573. fprintf(pp, " %d %d %d", memory_data_param.channels(), memory_data_param.width(), memory_data_param.height());
  574. }
  575. else if (layer.type() == "Normalize")
  576. {
  577. const caffe::LayerParameter& binlayer = net.layer(netidx);
  578. const caffe::BlobProto& scale_blob = binlayer.blobs(0);
  579. const caffe::NormalizeParameter& norm_param = layer.norm_param();
  580. fprintf(pp, " %d %d %f %d", norm_param.across_spatial(), norm_param.channel_shared(), norm_param.eps(), scale_blob.data_size());
  581. fwrite(scale_blob.data().data(), sizeof(float), scale_blob.data_size(), bp);
  582. }
  583. else if (layer.type() == "Permute")
  584. {
  585. const caffe::PermuteParameter& permute_param = layer.permute_param();
  586. int order_size = permute_param.order_size();
  587. int order_type = 0;
  588. if (order_size == 0)
  589. order_type = 0;
  590. if (order_size == 1)
  591. {
  592. int order0 = permute_param.order(0);
  593. if (order0 == 0)
  594. order_type = 0;
  595. // permute with N not supported
  596. }
  597. if (order_size == 2)
  598. {
  599. int order0 = permute_param.order(0);
  600. int order1 = permute_param.order(1);
  601. if (order0 == 0)
  602. {
  603. if (order1 == 1) // 0 1 2 3
  604. order_type = 0;
  605. else if (order1 == 2) // 0 2 1 3
  606. order_type = 2;
  607. else if (order1 == 3) // 0 3 1 2
  608. order_type = 4;
  609. }
  610. // permute with N not supported
  611. }
  612. if (order_size == 3 || order_size == 4)
  613. {
  614. int order0 = permute_param.order(0);
  615. int order1 = permute_param.order(1);
  616. int order2 = permute_param.order(2);
  617. if (order0 == 0)
  618. {
  619. if (order1 == 1)
  620. {
  621. if (order2 == 2) // 0 1 2 3
  622. order_type = 0;
  623. if (order2 == 3) // 0 1 3 2
  624. order_type = 1;
  625. }
  626. else if (order1 == 2)
  627. {
  628. if (order2 == 1) // 0 2 1 3
  629. order_type = 2;
  630. if (order2 == 3) // 0 2 3 1
  631. order_type = 3;
  632. }
  633. else if (order1 == 3)
  634. {
  635. if (order2 == 1) // 0 3 1 2
  636. order_type = 4;
  637. if (order2 == 2) // 0 3 2 1
  638. order_type = 5;
  639. }
  640. }
  641. // permute with N not supported
  642. }
  643. fprintf(pp, " %d", order_type);
  644. }
  645. else if (layer.type() == "Pooling")
  646. {
  647. const caffe::PoolingParameter& pooling_param = layer.pooling_param();
  648. fprintf(pp, " %d %d %d %d %d", pooling_param.pool(), pooling_param.kernel_size(), pooling_param.stride(), pooling_param.pad(),
  649. pooling_param.has_global_pooling() ? pooling_param.global_pooling() : 0);
  650. }
  651. else if (layer.type() == "Power")
  652. {
  653. const caffe::PowerParameter& power_param = layer.power_param();
  654. fprintf(pp, " %f %f %f", power_param.power(), power_param.scale(), power_param.shift());
  655. }
  656. else if (layer.type() == "PReLU")
  657. {
  658. const caffe::LayerParameter& binlayer = net.layer(netidx);
  659. const caffe::BlobProto& slope_blob = binlayer.blobs(0);
  660. fprintf(pp, " %d", slope_blob.data_size());
  661. fwrite(slope_blob.data().data(), sizeof(float), slope_blob.data_size(), bp);
  662. }
  663. else if (layer.type() == "PriorBox")
  664. {
  665. const caffe::PriorBoxParameter& prior_box_param = layer.prior_box_param();
  666. int num_aspect_ratio = prior_box_param.aspect_ratio_size();
  667. for (int j=0; j<prior_box_param.aspect_ratio_size(); j++)
  668. {
  669. float ar = prior_box_param.aspect_ratio(j);
  670. if (fabs(ar - 1.) < 1e-6) {
  671. num_aspect_ratio--;
  672. }
  673. }
  674. float variances[4] = {0.1f, 0.1f, 0.1f, 0.1f};
  675. if (prior_box_param.variance_size() == 4)
  676. {
  677. variances[0] = prior_box_param.variance(0);
  678. variances[1] = prior_box_param.variance(1);
  679. variances[2] = prior_box_param.variance(2);
  680. variances[3] = prior_box_param.variance(3);
  681. }
  682. else if (prior_box_param.variance_size() == 1)
  683. {
  684. variances[0] = prior_box_param.variance(0);
  685. variances[1] = prior_box_param.variance(0);
  686. variances[2] = prior_box_param.variance(0);
  687. variances[3] = prior_box_param.variance(0);
  688. }
  689. int flip = prior_box_param.has_flip() ? prior_box_param.flip() : 1;
  690. int clip = prior_box_param.has_clip() ? prior_box_param.clip() : 0;
  691. int image_width = -233;
  692. int image_height = -233;
  693. if (prior_box_param.has_img_size())
  694. {
  695. image_width = prior_box_param.img_size();
  696. image_height = prior_box_param.img_size();
  697. }
  698. else if (prior_box_param.has_img_w() && prior_box_param.has_img_h())
  699. {
  700. image_width = prior_box_param.img_w();
  701. image_height = prior_box_param.img_h();
  702. }
  703. float step_width = -233;
  704. float step_height = -233;
  705. if (prior_box_param.has_step())
  706. {
  707. step_width = prior_box_param.step();
  708. step_height = prior_box_param.step();
  709. }
  710. else if (prior_box_param.has_step_w() && prior_box_param.has_step_h())
  711. {
  712. step_width = prior_box_param.step_w();
  713. step_height = prior_box_param.step_h();
  714. }
  715. fprintf(pp, " %d %d %d %f %f %f %f %d %d %d %d %f %f %f", prior_box_param.min_size_size(),
  716. prior_box_param.max_size_size(), num_aspect_ratio,
  717. variances[0], variances[1], variances[2], variances[3],
  718. flip, clip, image_width, image_height,
  719. step_width, step_height, prior_box_param.offset());
  720. for (int j=0; j<prior_box_param.min_size_size(); j++)
  721. {
  722. fprintf(pp, " %f", prior_box_param.min_size(j));
  723. }
  724. for (int j=0; j<prior_box_param.max_size_size(); j++)
  725. {
  726. fprintf(pp, " %f", prior_box_param.max_size(j));
  727. }
  728. for (int j=0; j<prior_box_param.aspect_ratio_size(); j++)
  729. {
  730. float ar = prior_box_param.aspect_ratio(j);
  731. if (fabs(ar - 1.) < 1e-6) {
  732. continue;
  733. }
  734. fprintf(pp, " %f", ar);
  735. }
  736. }
  737. else if (layer.type() == "Proposal")
  738. {
  739. const caffe::PythonParameter& python_param = layer.python_param();
  740. int feat_stride = 16;
  741. sscanf(python_param.param_str().c_str(), "'feat_stride': %d", &feat_stride);
  742. int base_size = 16;
  743. // float ratio;
  744. // float scale;
  745. int pre_nms_topN = 6000;
  746. int after_nms_topN = 5;
  747. float nms_thresh = 0.7;
  748. int min_size = 16;
  749. fprintf(pp, " %d %d %d %d %f %d", feat_stride, base_size, pre_nms_topN, after_nms_topN, nms_thresh, min_size);
  750. }
  751. else if (layer.type() == "ReLU")
  752. {
  753. const caffe::ReLUParameter& relu_param = layer.relu_param();
  754. fprintf(pp, " %f", relu_param.negative_slope());
  755. }
  756. else if (layer.type() == "Reshape")
  757. {
  758. const caffe::ReshapeParameter& reshape_param = layer.reshape_param();
  759. const caffe::BlobShape& bs = reshape_param.shape();
  760. if (bs.dim_size() == 1)
  761. {
  762. fprintf(pp, " %ld -233 -233", bs.dim(0));
  763. }
  764. else if (bs.dim_size() == 2)
  765. {
  766. fprintf(pp, " %ld %ld -233", bs.dim(1), bs.dim(0));
  767. }
  768. else if (bs.dim_size() == 3)
  769. {
  770. fprintf(pp, " %ld %ld %ld", bs.dim(2), bs.dim(1), bs.dim(0));
  771. }
  772. else // bs.dim_size() == 4
  773. {
  774. fprintf(pp, " %ld %ld %ld", bs.dim(3), bs.dim(2), bs.dim(1));
  775. }
  776. fprintf(pp, " 0");// permute
  777. }
  778. else if (layer.type() == "ROIPooling")
  779. {
  780. const caffe::ROIPoolingParameter& roi_pooling_param = layer.roi_pooling_param();
  781. fprintf(pp, " %d %d %.8f", roi_pooling_param.pooled_w(), roi_pooling_param.pooled_h(), roi_pooling_param.spatial_scale());
  782. }
  783. else if (layer.type() == "Scale")
  784. {
  785. const caffe::LayerParameter& binlayer = net.layer(netidx);
  786. const caffe::BlobProto& weight_blob = binlayer.blobs(0);
  787. const caffe::ScaleParameter& scale_param = layer.scale_param();
  788. fprintf(pp, " %d %d", (int)weight_blob.data_size(), scale_param.bias_term());
  789. for (int j=0; j<binlayer.blobs_size(); j++)
  790. {
  791. const caffe::BlobProto& blob = binlayer.blobs(j);
  792. fwrite(blob.data().data(), sizeof(float), blob.data_size(), bp);
  793. }
  794. }
  795. else if (layer.type() == "Slice")
  796. {
  797. const caffe::SliceParameter& slice_param = layer.slice_param();
  798. if (slice_param.has_slice_dim())
  799. {
  800. int num_slice = layer.top_size();
  801. fprintf(pp, " %d", num_slice);
  802. for (int j=0; j<num_slice; j++)
  803. {
  804. fprintf(pp, " -233");
  805. }
  806. }
  807. else
  808. {
  809. int num_slice = slice_param.slice_point_size() + 1;
  810. fprintf(pp, " %d", num_slice);
  811. int prev_offset = 0;
  812. for (int j=0; j<slice_param.slice_point_size(); j++)
  813. {
  814. int offset = slice_param.slice_point(j);
  815. fprintf(pp, " %d", offset - prev_offset);
  816. prev_offset = offset;
  817. }
  818. fprintf(pp, " -233");
  819. }
  820. }
  821. else if (layer.type() == "Threshold")
  822. {
  823. const caffe::ThresholdParameter& threshold_param = layer.threshold_param();
  824. fprintf(pp, " %f", threshold_param.threshold());
  825. }
  826. fprintf(pp, "\n");
  827. // add split layer if top reference larger than one
  828. if (layer.bottom_size() == 1 && layer.top_size() == 1 && layer.bottom(0) == layer.top(0))
  829. {
  830. std::string blob_name = blob_name_decorated[layer.top(0)];
  831. if (bottom_reference.find(blob_name) != bottom_reference.end())
  832. {
  833. int refcount = bottom_reference[blob_name];
  834. if (refcount > 1)
  835. {
  836. char splitname[256];
  837. sprintf(splitname, "splitncnn_%d", internal_split);
  838. fprintf(pp, "%-16s %-16s %d %d", "Split", splitname, 1, refcount);
  839. fprintf(pp, " %s", blob_name.c_str());
  840. for (int j=0; j<refcount; j++)
  841. {
  842. fprintf(pp, " %s_splitncnn_%d", blob_name.c_str(), j);
  843. }
  844. fprintf(pp, "\n");
  845. internal_split++;
  846. }
  847. }
  848. }
  849. else
  850. {
  851. for (int j=0; j<layer.top_size(); j++)
  852. {
  853. std::string blob_name = layer.top(j);
  854. if (bottom_reference.find(blob_name) != bottom_reference.end())
  855. {
  856. int refcount = bottom_reference[blob_name];
  857. if (refcount > 1)
  858. {
  859. char splitname[256];
  860. sprintf(splitname, "splitncnn_%d", internal_split);
  861. fprintf(pp, "%-16s %-16s %d %d", "Split", splitname, 1, refcount);
  862. fprintf(pp, " %s", blob_name.c_str());
  863. for (int j=0; j<refcount; j++)
  864. {
  865. fprintf(pp, " %s_splitncnn_%d", blob_name.c_str(), j);
  866. }
  867. fprintf(pp, "\n");
  868. internal_split++;
  869. }
  870. }
  871. }
  872. }
  873. }
  874. fclose(pp);
  875. fclose(bp);
  876. return 0;
  877. }