/*M /////////////////////////////////////////////////////////////////////////////////////// // // IMPORTANT: READ BEFORE DOWNLOADING, COPYING, INSTALLING OR USING. // // By downloading, copying, installing or using the software you agree to this license. // If you do not agree to this license, do not download, install, // copy or use the software. // // // License Agreement // For Open Source Computer Vision Library // // Copyright (C) 2013, OpenCV Foundation, all rights reserved. // Copyright (C) 2017, Intel Corporation, all rights reserved. // Third party copyrights are property of their respective owners. // // Redistribution and use in source and binary forms, with or without modification, // are permitted provided that the following conditions are met: // // * Redistribution's of source code must retain the above copyright notice, // this list of conditions and the following disclaimer. // // * Redistribution's in binary form must reproduce the above copyright notice, // this list of conditions and the following disclaimer in the documentation // and/or other materials provided with the distribution. // // * The name of the copyright holders may not be used to endorse or promote products // derived from this software without specific prior written permission. // // This software is provided by the copyright holders and contributors "as is" and // any express or implied warranties, including, but not limited to, the implied // warranties of merchantability and fitness for a particular purpose are disclaimed. // In no event shall the Intel Corporation or contributors be liable for any direct, // indirect, incidental, special, exemplary, or consequential damages // (including, but not limited to, procurement of substitute goods or services; // loss of use, data, or profits; or business interruption) however caused // and on any theory of liability, whether in contract, strict liability, // or tort (including negligence or otherwise) arising in any way out of // the use of this software, even if advised of the possibility of such damage. // //M*/ #include "../precomp.hpp" #include "layers_common.hpp" #include #include #include "../nms.inl.hpp" #include "opencl_kernels_dnn.hpp" namespace cv { namespace dnn { namespace util { class NormalizedBBox { public: float xmin, ymin, xmax, ymax; NormalizedBBox() : xmin(0), ymin(0), xmax(0), ymax(0), has_size_(false), size_(0) {} float size() const { return size_; } bool has_size() const { return has_size_; } void set_size(float value) { size_ = value; has_size_ = true; } void clear_size() { size_ = 0; has_size_ = false; } private: bool has_size_; float size_; }; template static inline bool SortScorePairDescend(const std::pair& pair1, const std::pair& pair2) { return pair1.first > pair2.first; } static inline float caffe_box_overlap(const util::NormalizedBBox& a, const util::NormalizedBBox& b); } // namespace class DetectionOutputLayerImpl : public DetectionOutputLayer { public: unsigned _numClasses; bool _shareLocation; int _numLocClasses; int _backgroundLabelId; cv::String _codeType; bool _varianceEncodedInTarget; int _keepTopK; float _confidenceThreshold; float _nmsThreshold; int _topK; // Whenever predicted bounding boxes are respresented in YXHW instead of XYWH layout. bool _locPredTransposed; enum { _numAxes = 4 }; static const std::string _layerName; typedef std::map > LabelBBox; bool getParameterDict(const LayerParams ¶ms, const std::string ¶meterName, DictValue& result) { if (!params.has(parameterName)) { return false; } result = params.get(parameterName); return true; } template T getParameter(const LayerParams ¶ms, const std::string ¶meterName, const size_t &idx=0, const bool required=true, const T& defaultValue=T()) { DictValue dictValue; bool success = getParameterDict(params, parameterName, dictValue); if(!success) { if(required) { std::string message = _layerName; message += " layer parameter does not contain "; message += parameterName; message += " parameter."; CV_ErrorNoReturn(Error::StsBadArg, message); } else { return defaultValue; } } return dictValue.get(idx); } void getCodeType(const LayerParams ¶ms) { String codeTypeString = params.get("code_type").toLowerCase(); if (codeTypeString == "center_size") _codeType = "CENTER_SIZE"; else _codeType = "CORNER"; } DetectionOutputLayerImpl(const LayerParams ¶ms) { _numClasses = getParameter(params, "num_classes"); _shareLocation = getParameter(params, "share_location"); _numLocClasses = _shareLocation ? 1 : _numClasses; _backgroundLabelId = getParameter(params, "background_label_id"); _varianceEncodedInTarget = getParameter(params, "variance_encoded_in_target", 0, false, false); _keepTopK = getParameter(params, "keep_top_k"); _confidenceThreshold = getParameter(params, "confidence_threshold", 0, false, -FLT_MAX); _topK = getParameter(params, "top_k", 0, false, -1); _locPredTransposed = getParameter(params, "loc_pred_transposed", 0, false, false); getCodeType(params); // Parameters used in nms. _nmsThreshold = getParameter(params, "nms_threshold"); CV_Assert(_nmsThreshold > 0.); setParamsFrom(params); } void checkInputs(const std::vector &inputs) { for (size_t i = 1; i < inputs.size(); i++) { CV_Assert(inputs[i]->size == inputs[0]->size); } } bool getMemoryShapes(const std::vector &inputs, const int requiredOutputs, std::vector &outputs, std::vector &internals) const { CV_Assert(inputs.size() > 0); CV_Assert(inputs[0][0] == inputs[1][0]); int numPriors = inputs[2][2] / 4; CV_Assert((numPriors * _numLocClasses * 4) == inputs[0][1]); CV_Assert(int(numPriors * _numClasses) == inputs[1][1]); // num() and channels() are 1. // Since the number of bboxes to be kept is unknown before nms, we manually // set it to (fake) 1. // Each row is a 7 dimension std::vector, which stores // [image_id, label, confidence, xmin, ymin, xmax, ymax] outputs.resize(1, shape(1, 1, 1, 7)); return false; } #ifdef HAVE_OPENCL // Decode all bboxes in a batch bool ocl_DecodeBBoxesAll(UMat& loc_mat, UMat& prior_mat, const int num, const int numPriors, const bool share_location, const int num_loc_classes, const int background_label_id, const cv::String& code_type, const bool variance_encoded_in_target, const bool clip, std::vector& all_decode_bboxes) { UMat outmat = UMat(loc_mat.dims, loc_mat.size, CV_32F); size_t nthreads = loc_mat.total(); String kernel_name; if (code_type == "CORNER") kernel_name = "DecodeBBoxesCORNER"; else if (code_type == "CENTER_SIZE") kernel_name = "DecodeBBoxesCENTER_SIZE"; else return false; for (int i = 0; i < num; ++i) { ocl::Kernel kernel(kernel_name.c_str(), ocl::dnn::detection_output_oclsrc); kernel.set(0, (int)nthreads); kernel.set(1, ocl::KernelArg::PtrReadOnly(loc_mat)); kernel.set(2, ocl::KernelArg::PtrReadOnly(prior_mat)); kernel.set(3, (int)variance_encoded_in_target); kernel.set(4, (int)numPriors); kernel.set(5, (int)share_location); kernel.set(6, (int)num_loc_classes); kernel.set(7, (int)background_label_id); kernel.set(8, (int)clip); kernel.set(9, ocl::KernelArg::PtrWriteOnly(outmat)); if (!kernel.run(1, &nthreads, NULL, false)) return false; } all_decode_bboxes.clear(); all_decode_bboxes.resize(num); { Mat mat = outmat.getMat(ACCESS_READ); const float* decode_data = mat.ptr(); for (int i = 0; i < num; ++i) { LabelBBox& decode_bboxes = all_decode_bboxes[i]; for (int c = 0; c < num_loc_classes; ++c) { int label = share_location ? -1 : c; decode_bboxes[label].resize(numPriors); for (int p = 0; p < numPriors; ++p) { int startIdx = p * num_loc_classes * 4; util::NormalizedBBox& bbox = decode_bboxes[label][p]; bbox.xmin = decode_data[startIdx + c * 4]; bbox.ymin = decode_data[startIdx + c * 4 + 1]; bbox.xmax = decode_data[startIdx + c * 4 + 2]; bbox.ymax = decode_data[startIdx + c * 4 + 3]; } } } } return true; } void ocl_GetConfidenceScores(const UMat& inp1, const int num, const int numPredsPerClass, const int numClasses, std::vector& confPreds) { int shape[] = { numClasses, numPredsPerClass }; for (int i = 0; i < num; i++) confPreds.push_back(Mat(2, shape, CV_32F)); UMat umat = inp1.reshape(1, num * numPredsPerClass); for (int i = 0; i < num; ++i) { Range ranges[] = { Range(i * numPredsPerClass, (i + 1) * numPredsPerClass), Range::all() }; transpose(umat(ranges), confPreds[i]); } } bool forward_ocl(InputArrayOfArrays inps, OutputArrayOfArrays outs, OutputArrayOfArrays internals) { std::vector inputs; std::vector outputs; inps.getUMatVector(inputs); outs.getUMatVector(outputs); std::vector allDecodedBBoxes; std::vector allConfidenceScores; int num = inputs[0].size[0]; // extract predictions from input layers { int numPriors = inputs[2].size[2] / 4; // Retrieve all confidences ocl_GetConfidenceScores(inputs[1], num, numPriors, _numClasses, allConfidenceScores); // Decode all loc predictions to bboxes bool ret = ocl_DecodeBBoxesAll(inputs[0], inputs[2], num, numPriors, _shareLocation, _numLocClasses, _backgroundLabelId, _codeType, _varianceEncodedInTarget, false, allDecodedBBoxes); if (!ret) return false; } size_t numKept = 0; std::vector > > allIndices; for (int i = 0; i < num; ++i) { numKept += processDetections_(allDecodedBBoxes[i], allConfidenceScores[i], allIndices); } if (numKept == 0) { // Set confidences to zeros. Range ranges[] = {Range::all(), Range::all(), Range::all(), Range(2, 3)}; outputs[0](ranges).setTo(0); return true; } int outputShape[] = {1, 1, (int)numKept, 7}; UMat umat = UMat(4, outputShape, CV_32F); { Mat mat = umat.getMat(ACCESS_WRITE); float* outputsData = mat.ptr(); size_t count = 0; for (int i = 0; i < num; ++i) { count += outputDetections_(i, &outputsData[count * 7], allDecodedBBoxes[i], allConfidenceScores[i], allIndices[i]); } CV_Assert(count == numKept); } outputs.clear(); outputs.push_back(umat); outs.assign(outputs); return true; } #endif void forward(InputArrayOfArrays inputs_arr, OutputArrayOfArrays outputs_arr, OutputArrayOfArrays internals_arr) { CV_TRACE_FUNCTION(); CV_TRACE_ARG_VALUE(name, "name", name.c_str()); CV_OCL_RUN((preferableTarget == DNN_TARGET_OPENCL) && OCL_PERFORMANCE_CHECK(ocl::Device::getDefault().isIntel()), forward_ocl(inputs_arr, outputs_arr, internals_arr)) Layer::forward_fallback(inputs_arr, outputs_arr, internals_arr); } void forward(std::vector &inputs, std::vector &outputs, std::vector &internals) { CV_TRACE_FUNCTION(); CV_TRACE_ARG_VALUE(name, "name", name.c_str()); std::vector allDecodedBBoxes; std::vector allConfidenceScores; int num = inputs[0]->size[0]; // extract predictions from input layers { int numPriors = inputs[2]->size[2] / 4; const float* locationData = inputs[0]->ptr(); const float* confidenceData = inputs[1]->ptr(); const float* priorData = inputs[2]->ptr(); // Retrieve all location predictions std::vector allLocationPredictions; GetLocPredictions(locationData, num, numPriors, _numLocClasses, _shareLocation, _locPredTransposed, allLocationPredictions); // Retrieve all confidences GetConfidenceScores(confidenceData, num, numPriors, _numClasses, allConfidenceScores); // Retrieve all prior bboxes std::vector priorBBoxes; std::vector > priorVariances; GetPriorBBoxes(priorData, numPriors, priorBBoxes, priorVariances); // Decode all loc predictions to bboxes DecodeBBoxesAll(allLocationPredictions, priorBBoxes, priorVariances, num, _shareLocation, _numLocClasses, _backgroundLabelId, _codeType, _varianceEncodedInTarget, false, allDecodedBBoxes); } size_t numKept = 0; std::vector > > allIndices; for (int i = 0; i < num; ++i) { numKept += processDetections_(allDecodedBBoxes[i], allConfidenceScores[i], allIndices); } if (numKept == 0) { // Set confidences to zeros. Range ranges[] = {Range::all(), Range::all(), Range::all(), Range(2, 3)}; outputs[0](ranges).setTo(0); return; } int outputShape[] = {1, 1, (int)numKept, 7}; outputs[0].create(4, outputShape, CV_32F); float* outputsData = outputs[0].ptr(); size_t count = 0; for (int i = 0; i < num; ++i) { count += outputDetections_(i, &outputsData[count * 7], allDecodedBBoxes[i], allConfidenceScores[i], allIndices[i]); } CV_Assert(count == numKept); } size_t outputDetections_( const int i, float* outputsData, const LabelBBox& decodeBBoxes, Mat& confidenceScores, const std::map >& indicesMap ) { size_t count = 0; for (std::map >::const_iterator it = indicesMap.begin(); it != indicesMap.end(); ++it) { int label = it->first; if (confidenceScores.rows <= label) CV_ErrorNoReturn_(cv::Error::StsError, ("Could not find confidence predictions for label %d", label)); const std::vector& scores = confidenceScores.row(label); int locLabel = _shareLocation ? -1 : label; LabelBBox::const_iterator label_bboxes = decodeBBoxes.find(locLabel); if (label_bboxes == decodeBBoxes.end()) CV_ErrorNoReturn_(cv::Error::StsError, ("Could not find location predictions for label %d", locLabel)); const std::vector& indices = it->second; for (size_t j = 0; j < indices.size(); ++j, ++count) { int idx = indices[j]; const util::NormalizedBBox& decode_bbox = label_bboxes->second[idx]; outputsData[count * 7] = i; outputsData[count * 7 + 1] = label; outputsData[count * 7 + 2] = scores[idx]; outputsData[count * 7 + 3] = decode_bbox.xmin; outputsData[count * 7 + 4] = decode_bbox.ymin; outputsData[count * 7 + 5] = decode_bbox.xmax; outputsData[count * 7 + 6] = decode_bbox.ymax; } } return count; } size_t processDetections_( const LabelBBox& decodeBBoxes, Mat& confidenceScores, std::vector > >& allIndices ) { std::map > indices; size_t numDetections = 0; for (int c = 0; c < (int)_numClasses; ++c) { if (c == _backgroundLabelId) continue; // Ignore background class. if (c >= confidenceScores.rows) CV_ErrorNoReturn_(cv::Error::StsError, ("Could not find confidence predictions for label %d", c)); const std::vector scores = confidenceScores.row(c); int label = _shareLocation ? -1 : c; LabelBBox::const_iterator label_bboxes = decodeBBoxes.find(label); if (label_bboxes == decodeBBoxes.end()) CV_ErrorNoReturn_(cv::Error::StsError, ("Could not find location predictions for label %d", label)); NMSFast_(label_bboxes->second, scores, _confidenceThreshold, _nmsThreshold, 1.0, _topK, indices[c], util::caffe_box_overlap); numDetections += indices[c].size(); } if (_keepTopK > -1 && numDetections > (size_t)_keepTopK) { std::vector > > scoreIndexPairs; for (std::map >::iterator it = indices.begin(); it != indices.end(); ++it) { int label = it->first; const std::vector& labelIndices = it->second; if (label >= confidenceScores.rows) CV_ErrorNoReturn_(cv::Error::StsError, ("Could not find location predictions for label %d", label)); const std::vector& scores = confidenceScores.row(label); for (size_t j = 0; j < labelIndices.size(); ++j) { size_t idx = labelIndices[j]; CV_Assert(idx < scores.size()); scoreIndexPairs.push_back(std::make_pair(scores[idx], std::make_pair(label, idx))); } } // Keep outputs k results per image. std::sort(scoreIndexPairs.begin(), scoreIndexPairs.end(), util::SortScorePairDescend >); scoreIndexPairs.resize(_keepTopK); std::map > newIndices; for (size_t j = 0; j < scoreIndexPairs.size(); ++j) { int label = scoreIndexPairs[j].second.first; int idx = scoreIndexPairs[j].second.second; newIndices[label].push_back(idx); } allIndices.push_back(newIndices); return (size_t)_keepTopK; } else { allIndices.push_back(indices); return numDetections; } } // ************************************************************** // Utility functions // ************************************************************** // Compute bbox size template static float BBoxSize(const util::NormalizedBBox& bbox) { if (bbox.xmax < bbox.xmin || bbox.ymax < bbox.ymin) { return 0; // If bbox is invalid (e.g. xmax < xmin or ymax < ymin), return 0. } else { if (bbox.has_size()) { return bbox.size(); } else { float width = bbox.xmax - bbox.xmin; float height = bbox.ymax - bbox.ymin; if (normalized) { return width * height; } else { // If bbox is not within range [0, 1]. return (width + 1) * (height + 1); } } } } // Decode a bbox according to a prior bbox template static void DecodeBBox( const util::NormalizedBBox& prior_bbox, const std::vector& prior_variance, const cv::String& code_type, const bool clip_bbox, const util::NormalizedBBox& bbox, util::NormalizedBBox& decode_bbox) { float bbox_xmin = variance_encoded_in_target ? bbox.xmin : prior_variance[0] * bbox.xmin; float bbox_ymin = variance_encoded_in_target ? bbox.ymin : prior_variance[1] * bbox.ymin; float bbox_xmax = variance_encoded_in_target ? bbox.xmax : prior_variance[2] * bbox.xmax; float bbox_ymax = variance_encoded_in_target ? bbox.ymax : prior_variance[3] * bbox.ymax; if (code_type == "CORNER") { decode_bbox.xmin = prior_bbox.xmin + bbox_xmin; decode_bbox.ymin = prior_bbox.ymin + bbox_ymin; decode_bbox.xmax = prior_bbox.xmax + bbox_xmax; decode_bbox.ymax = prior_bbox.ymax + bbox_ymax; } else if (code_type == "CENTER_SIZE") { float prior_width = prior_bbox.xmax - prior_bbox.xmin; CV_Assert(prior_width > 0); float prior_height = prior_bbox.ymax - prior_bbox.ymin; CV_Assert(prior_height > 0); float prior_center_x = (prior_bbox.xmin + prior_bbox.xmax) * .5; float prior_center_y = (prior_bbox.ymin + prior_bbox.ymax) * .5; float decode_bbox_center_x, decode_bbox_center_y; float decode_bbox_width, decode_bbox_height; decode_bbox_center_x = bbox_xmin * prior_width + prior_center_x; decode_bbox_center_y = bbox_ymin * prior_height + prior_center_y; decode_bbox_width = exp(bbox_xmax) * prior_width; decode_bbox_height = exp(bbox_ymax) * prior_height; decode_bbox.xmin = decode_bbox_center_x - decode_bbox_width * .5; decode_bbox.ymin = decode_bbox_center_y - decode_bbox_height * .5; decode_bbox.xmax = decode_bbox_center_x + decode_bbox_width * .5; decode_bbox.ymax = decode_bbox_center_y + decode_bbox_height * .5; } else CV_ErrorNoReturn(Error::StsBadArg, "Unknown type."); if (clip_bbox) { // Clip the util::NormalizedBBox such that the range for each corner is [0, 1] decode_bbox.xmin = std::max(std::min(decode_bbox.xmin, 1.f), 0.f); decode_bbox.ymin = std::max(std::min(decode_bbox.ymin, 1.f), 0.f); decode_bbox.xmax = std::max(std::min(decode_bbox.xmax, 1.f), 0.f); decode_bbox.ymax = std::max(std::min(decode_bbox.ymax, 1.f), 0.f); } decode_bbox.clear_size(); decode_bbox.set_size(BBoxSize(decode_bbox)); } // Decode a set of bboxes according to a set of prior bboxes static void DecodeBBoxes( const std::vector& prior_bboxes, const std::vector >& prior_variances, const cv::String& code_type, const bool variance_encoded_in_target, const bool clip_bbox, const std::vector& bboxes, std::vector& decode_bboxes) { CV_Assert(prior_bboxes.size() == prior_variances.size()); CV_Assert(prior_bboxes.size() == bboxes.size()); size_t num_bboxes = prior_bboxes.size(); CV_Assert(num_bboxes == 0 || prior_variances[0].size() == 4); decode_bboxes.clear(); decode_bboxes.resize(num_bboxes); if(variance_encoded_in_target) { for (int i = 0; i < num_bboxes; ++i) DecodeBBox(prior_bboxes[i], prior_variances[i], code_type, clip_bbox, bboxes[i], decode_bboxes[i]); } else { for (int i = 0; i < num_bboxes; ++i) DecodeBBox(prior_bboxes[i], prior_variances[i], code_type, clip_bbox, bboxes[i], decode_bboxes[i]); } } // Decode all bboxes in a batch static void DecodeBBoxesAll(const std::vector& all_loc_preds, const std::vector& prior_bboxes, const std::vector >& prior_variances, const int num, const bool share_location, const int num_loc_classes, const int background_label_id, const cv::String& code_type, const bool variance_encoded_in_target, const bool clip, std::vector& all_decode_bboxes) { CV_Assert(all_loc_preds.size() == num); all_decode_bboxes.clear(); all_decode_bboxes.resize(num); for (int i = 0; i < num; ++i) { // Decode predictions into bboxes. const LabelBBox& loc_preds = all_loc_preds[i]; LabelBBox& decode_bboxes = all_decode_bboxes[i]; for (int c = 0; c < num_loc_classes; ++c) { int label = share_location ? -1 : c; if (label == background_label_id) continue; // Ignore background class. LabelBBox::const_iterator label_loc_preds = loc_preds.find(label); if (label_loc_preds == loc_preds.end()) CV_ErrorNoReturn_(cv::Error::StsError, ("Could not find location predictions for label %d", label)); DecodeBBoxes(prior_bboxes, prior_variances, code_type, variance_encoded_in_target, clip, label_loc_preds->second, decode_bboxes[label]); } } } // Get prior bounding boxes from prior_data // prior_data: 1 x 2 x num_priors * 4 x 1 blob. // num_priors: number of priors. // prior_bboxes: stores all the prior bboxes in the format of util::NormalizedBBox. // prior_variances: stores all the variances needed by prior bboxes. static void GetPriorBBoxes(const float* priorData, const int& numPriors, std::vector& priorBBoxes, std::vector >& priorVariances) { priorBBoxes.clear(); priorBBoxes.resize(numPriors); priorVariances.clear(); priorVariances.resize(numPriors); for (int i = 0; i < numPriors; ++i) { int startIdx = i * 4; util::NormalizedBBox& bbox = priorBBoxes[i]; bbox.xmin = priorData[startIdx]; bbox.ymin = priorData[startIdx + 1]; bbox.xmax = priorData[startIdx + 2]; bbox.ymax = priorData[startIdx + 3]; bbox.set_size(BBoxSize(bbox)); } for (int i = 0; i < numPriors; ++i) { int startIdx = (numPriors + i) * 4; // not needed here: priorVariances[i].clear(); for (int j = 0; j < 4; ++j) { priorVariances[i].push_back(priorData[startIdx + j]); } } } // Get location predictions from loc_data. // loc_data: num x num_preds_per_class * num_loc_classes * 4 blob. // num: the number of images. // num_preds_per_class: number of predictions per class. // num_loc_classes: number of location classes. It is 1 if share_location is // true; and is equal to number of classes needed to predict otherwise. // share_location: if true, all classes share the same location prediction. // loc_pred_transposed: if true, represent four bounding box values as // [y,x,height,width] or [x,y,width,height] otherwise. // loc_preds: stores the location prediction, where each item contains // location prediction for an image. static void GetLocPredictions(const float* locData, const int num, const int numPredsPerClass, const int numLocClasses, const bool shareLocation, const bool locPredTransposed, std::vector& locPreds) { locPreds.clear(); if (shareLocation) { CV_Assert(numLocClasses == 1); } locPreds.resize(num); for (int i = 0; i < num; ++i, locData += numPredsPerClass * numLocClasses * 4) { LabelBBox& labelBBox = locPreds[i]; for (int p = 0; p < numPredsPerClass; ++p) { int startIdx = p * numLocClasses * 4; for (int c = 0; c < numLocClasses; ++c) { int label = shareLocation ? -1 : c; if (labelBBox.find(label) == labelBBox.end()) { labelBBox[label].resize(numPredsPerClass); } util::NormalizedBBox& bbox = labelBBox[label][p]; if (locPredTransposed) { bbox.ymin = locData[startIdx + c * 4]; bbox.xmin = locData[startIdx + c * 4 + 1]; bbox.ymax = locData[startIdx + c * 4 + 2]; bbox.xmax = locData[startIdx + c * 4 + 3]; } else { bbox.xmin = locData[startIdx + c * 4]; bbox.ymin = locData[startIdx + c * 4 + 1]; bbox.xmax = locData[startIdx + c * 4 + 2]; bbox.ymax = locData[startIdx + c * 4 + 3]; } } } } } // Get confidence predictions from conf_data. // conf_data: num x num_preds_per_class * num_classes blob. // num: the number of images. // num_preds_per_class: number of predictions per class. // num_classes: number of classes. // conf_preds: stores the confidence prediction, where each item contains // confidence prediction for an image. static void GetConfidenceScores(const float* confData, const int num, const int numPredsPerClass, const int numClasses, std::vector& confPreds) { int shape[] = { numClasses, numPredsPerClass }; for (int i = 0; i < num; i++) confPreds.push_back(Mat(2, shape, CV_32F)); for (int i = 0; i < num; ++i, confData += numPredsPerClass * numClasses) { Mat labelScores = confPreds[i]; for (int c = 0; c < numClasses; ++c) { for (int p = 0; p < numPredsPerClass; ++p) { labelScores.at(c, p) = confData[p * numClasses + c]; } } } } // Compute the jaccard (intersection over union IoU) overlap between two bboxes. template static float JaccardOverlap(const util::NormalizedBBox& bbox1, const util::NormalizedBBox& bbox2) { util::NormalizedBBox intersect_bbox; if (bbox2.xmin > bbox1.xmax || bbox2.xmax < bbox1.xmin || bbox2.ymin > bbox1.ymax || bbox2.ymax < bbox1.ymin) { // Return [0, 0, 0, 0] if there is no intersection. intersect_bbox.xmin = 0; intersect_bbox.ymin = 0; intersect_bbox.xmax = 0; intersect_bbox.ymax = 0; } else { intersect_bbox.xmin = std::max(bbox1.xmin, bbox2.xmin); intersect_bbox.ymin = std::max(bbox1.ymin, bbox2.ymin); intersect_bbox.xmax = std::min(bbox1.xmax, bbox2.xmax); intersect_bbox.ymax = std::min(bbox1.ymax, bbox2.ymax); } float intersect_width, intersect_height; intersect_width = intersect_bbox.xmax - intersect_bbox.xmin; intersect_height = intersect_bbox.ymax - intersect_bbox.ymin; if (intersect_width > 0 && intersect_height > 0) { if (!normalized) { intersect_width++; intersect_height++; } float intersect_size = intersect_width * intersect_height; float bbox1_size = BBoxSize(bbox1); float bbox2_size = BBoxSize(bbox2); return intersect_size / (bbox1_size + bbox2_size - intersect_size); } else { return 0.; } } }; float util::caffe_box_overlap(const util::NormalizedBBox& a, const util::NormalizedBBox& b) { return DetectionOutputLayerImpl::JaccardOverlap(a, b); } const std::string DetectionOutputLayerImpl::_layerName = std::string("DetectionOutput"); Ptr DetectionOutputLayer::create(const LayerParams ¶ms) { return Ptr(new DetectionOutputLayerImpl(params)); } } }