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410 lines
13 KiB
410 lines
13 KiB
// This file is part of OpenCV project. |
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// It is subject to the license terms in the LICENSE file found in the top-level directory |
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// of this distribution and at http://opencv.org/license.html. |
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// |
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// Copyright (C) 2020 Intel Corporation |
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#ifndef OPENCV_GAPI_PARSERS_TESTS_COMMON_HPP |
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#define OPENCV_GAPI_PARSERS_TESTS_COMMON_HPP |
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#include "gapi_tests_common.hpp" |
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#include "../../include/opencv2/gapi/infer/parsers.hpp" |
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namespace opencv_test |
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{ |
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class ParserSSDTest |
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{ |
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public: |
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cv::Mat generateSSDoutput(const cv::Size& in_sz) |
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{ |
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constexpr int maxN = 200; |
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constexpr int objSize = 7; |
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std::vector<int> dims{ 1, 1, maxN, objSize }; |
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cv::Mat mat(dims, CV_32FC1); |
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auto data = mat.ptr<float>(); |
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for (int i = 0; i < maxN; ++i) |
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{ |
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float* it = data + i * objSize; |
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auto ssdIt = generateItem(i, in_sz); |
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it[0] = ssdIt.image_id; |
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it[1] = ssdIt.label; |
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it[2] = ssdIt.confidence; |
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it[3] = ssdIt.rc_left; |
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it[4] = ssdIt.rc_top; |
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it[5] = ssdIt.rc_right; |
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it[6] = ssdIt.rc_bottom; |
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} |
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return mat; |
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} |
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void parseSSDref(const cv::Mat& in_ssd_result, |
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const cv::Size& in_size, |
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const float confidence_threshold, |
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const bool alignment_to_square, |
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const bool filter_out_of_bounds, |
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std::vector<cv::Rect>& out_boxes) |
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{ |
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out_boxes.clear(); |
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const auto &in_ssd_dims = in_ssd_result.size; |
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CV_Assert(in_ssd_dims.dims() == 4u); |
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const int MAX_PROPOSALS = in_ssd_dims[2]; |
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const int OBJECT_SIZE = in_ssd_dims[3]; |
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CV_Assert(OBJECT_SIZE == 7); // fixed SSD object size |
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const float *data = in_ssd_result.ptr<float>(); |
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cv::Rect surface({0,0}, in_size), rc; |
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float image_id, confidence; |
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int label; |
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for (int i = 0; i < MAX_PROPOSALS; ++i) |
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{ |
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std::tie(rc, image_id, confidence, label) |
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= extract(data + i*OBJECT_SIZE, in_size); |
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if (image_id < 0.f) |
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{ |
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break; // marks end-of-detections |
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} |
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if (confidence < confidence_threshold) |
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{ |
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continue; // skip objects with low confidence |
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} |
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if (alignment_to_square) |
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{ |
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adjustBoundingBox(rc); |
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} |
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const auto clipped_rc = rc & surface; |
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if (filter_out_of_bounds) |
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{ |
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if (clipped_rc.area() != rc.area()) |
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{ |
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continue; |
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} |
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} |
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out_boxes.emplace_back(clipped_rc); |
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} |
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} |
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void parseSSDBLref(const cv::Mat& in_ssd_result, |
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const cv::Size& in_size, |
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const float confidence_threshold, |
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const int filter_label, |
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std::vector<cv::Rect>& out_boxes, |
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std::vector<int>& out_labels) |
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{ |
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out_boxes.clear(); |
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out_labels.clear(); |
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const auto &in_ssd_dims = in_ssd_result.size; |
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CV_Assert(in_ssd_dims.dims() == 4u); |
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const int MAX_PROPOSALS = in_ssd_dims[2]; |
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const int OBJECT_SIZE = in_ssd_dims[3]; |
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CV_Assert(OBJECT_SIZE == 7); // fixed SSD object size |
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cv::Rect surface({0,0}, in_size), rc; |
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float image_id, confidence; |
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int label; |
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const float *data = in_ssd_result.ptr<float>(); |
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for (int i = 0; i < MAX_PROPOSALS; i++) |
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{ |
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std::tie(rc, image_id, confidence, label) |
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= extract(data + i*OBJECT_SIZE, in_size); |
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if (image_id < 0.f) |
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{ |
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break; // marks end-of-detections |
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} |
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if (confidence < confidence_threshold || |
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(filter_label != -1 && label != filter_label)) |
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{ |
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continue; // filter out object classes if filter is specified |
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} |
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out_boxes.emplace_back(rc & surface); |
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out_labels.emplace_back(label); |
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} |
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} |
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private: |
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void adjustBoundingBox(cv::Rect& boundingBox) |
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{ |
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auto w = boundingBox.width; |
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auto h = boundingBox.height; |
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boundingBox.x -= static_cast<int>(0.067 * w); |
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boundingBox.y -= static_cast<int>(0.028 * h); |
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boundingBox.width += static_cast<int>(0.15 * w); |
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boundingBox.height += static_cast<int>(0.13 * h); |
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if (boundingBox.width < boundingBox.height) |
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{ |
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auto dx = (boundingBox.height - boundingBox.width); |
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boundingBox.x -= dx / 2; |
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boundingBox.width += dx; |
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} |
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else |
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{ |
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auto dy = (boundingBox.width - boundingBox.height); |
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boundingBox.y -= dy / 2; |
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boundingBox.height += dy; |
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} |
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} |
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std::tuple<cv::Rect, float, float, int> extract(const float* it, |
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const cv::Size& in_size) |
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{ |
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float image_id = it[0]; |
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int label = static_cast<int>(it[1]); |
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float confidence = it[2]; |
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float rc_left = it[3]; |
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float rc_top = it[4]; |
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float rc_right = it[5]; |
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float rc_bottom = it[6]; |
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cv::Rect rc; // map relative coordinates to the original image scale |
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rc.x = static_cast<int>(rc_left * in_size.width); |
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rc.y = static_cast<int>(rc_top * in_size.height); |
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rc.width = static_cast<int>(rc_right * in_size.width) - rc.x; |
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rc.height = static_cast<int>(rc_bottom * in_size.height) - rc.y; |
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return std::make_tuple(rc, image_id, confidence, label); |
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} |
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int randInRange(const int start, const int end) |
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{ |
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GAPI_Assert(start <= end); |
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return start + std::rand() % (end - start + 1); |
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} |
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cv::Rect generateBox(const cv::Size& in_sz) |
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{ |
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// Generated rectangle can reside outside of the initial image by border pixels |
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constexpr int border = 10; |
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constexpr int minW = 16; |
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constexpr int minH = 16; |
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cv::Rect box; |
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box.width = randInRange(minW, in_sz.width + 2*border); |
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box.height = randInRange(minH, in_sz.height + 2*border); |
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box.x = randInRange(-border, in_sz.width + border - box.width); |
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box.y = randInRange(-border, in_sz.height + border - box.height); |
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return box; |
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} |
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struct SSDitem |
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{ |
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float image_id = 0.0f; |
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float label = 0.0f; |
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float confidence = 0.0f; |
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float rc_left = 0.0f; |
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float rc_top = 0.0f; |
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float rc_right = 0.0f; |
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float rc_bottom = 0.0f; |
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}; |
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SSDitem generateItem(const int i, const cv::Size& in_sz) |
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{ |
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const auto normalize = [](int v, int range) { return static_cast<float>(v) / range; }; |
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SSDitem it; |
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it.image_id = static_cast<float>(i); |
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it.label = static_cast<float>(randInRange(0, 9)); |
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it.confidence = static_cast<float>(std::rand()) / RAND_MAX; |
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auto box = generateBox(in_sz); |
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it.rc_left = normalize(box.x, in_sz.width); |
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it.rc_right = normalize(box.x + box.width, in_sz.width); |
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it.rc_top = normalize(box.y, in_sz.height); |
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it.rc_bottom = normalize(box.y + box.height, in_sz.height); |
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return it; |
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} |
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}; |
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class ParserYoloTest |
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{ |
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public: |
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cv::Mat generateYoloOutput(const int num_classes, std::pair<bool,int> dims_config = {false, 4}) |
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{ |
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bool one_dim = false; |
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int num_dims = 0; |
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std::tie(one_dim, num_dims) = dims_config; |
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GAPI_Assert(num_dims <= 4); |
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GAPI_Assert((!one_dim && num_dims >= 3) || |
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( one_dim && num_dims >= 1)); |
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std::vector<int> dims(num_dims, 1); |
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if (one_dim) { |
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dims.back() = (num_classes+5)*5*13*13; |
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} else { |
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dims.back() = (num_classes+5)*5; |
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dims[num_dims-2] = 13; |
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dims[num_dims-3] = 13; |
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} |
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cv::Mat mat(dims, CV_32FC1); |
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auto data = mat.ptr<float>(); |
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const size_t range = std::accumulate(dims.begin(), dims.end(), 1, std::multiplies<int>()); |
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for (size_t i = 0; i < range; ++i) |
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{ |
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data[i] = static_cast<float>(std::rand()) / RAND_MAX; |
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} |
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return mat; |
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} |
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void parseYoloRef(const cv::Mat& in_yolo_result, |
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const cv::Size& in_size, |
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const float confidence_threshold, |
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const float nms_threshold, |
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const int num_classes, |
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const std::vector<float>& anchors, |
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std::vector<cv::Rect>& out_boxes, |
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std::vector<int>& out_labels) |
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{ |
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YoloParams params; |
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constexpr auto side_square = 13 * 13; |
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this->m_out = in_yolo_result.ptr<float>(); |
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this->m_side = 13; |
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this->m_lcoords = params.coords; |
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this->m_lclasses = num_classes; |
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std::vector<Detection> detections; |
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for (int i = 0; i < side_square; ++i) |
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{ |
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for (int b = 0; b < params.num; ++b) |
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{ |
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float scale = this->scale(i, b); |
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if (scale < confidence_threshold) |
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{ |
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continue; |
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} |
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double x = this->x(i, b); |
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double y = this->y(i, b); |
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double height = this->height(i, b, anchors[2 * b + 1]); |
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double width = this->width(i, b, anchors[2 * b]); |
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for (int label = 0; label < num_classes; ++label) |
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{ |
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float prob = scale * classConf(i,b,label); |
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if (prob < confidence_threshold) |
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{ |
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continue; |
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} |
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auto box = toBox(x, y, height, width, in_size); |
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detections.emplace_back(Detection(box, prob, label)); |
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} |
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} |
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} |
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std::stable_sort(std::begin(detections), std::end(detections), |
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[](const Detection& a, const Detection& b) |
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{ |
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return a.conf > b.conf; |
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}); |
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if (nms_threshold < 1.0f) |
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{ |
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for (const auto& d : detections) |
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{ |
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if (std::end(out_boxes) == |
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std::find_if(std::begin(out_boxes), std::end(out_boxes), |
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[&d, nms_threshold](const cv::Rect& r) |
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{ |
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float rectOverlap = 1.f - static_cast<float>(jaccardDistance(r, d.rect)); |
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return rectOverlap > nms_threshold; |
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})) |
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{ |
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out_boxes. emplace_back(d.rect); |
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out_labels.emplace_back(d.label); |
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} |
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} |
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} |
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else |
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{ |
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for (const auto& d: detections) |
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{ |
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out_boxes. emplace_back(d.rect); |
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out_labels.emplace_back(d.label); |
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} |
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} |
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} |
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private: |
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struct Detection |
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{ |
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Detection(const cv::Rect& in_rect, const float in_conf, const int in_label) |
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: rect(in_rect), conf(in_conf), label(in_label) |
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{} |
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cv::Rect rect; |
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float conf = 0.0f; |
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int label = 0; |
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}; |
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struct YoloParams |
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{ |
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int num = 5; |
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int coords = 4; |
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}; |
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float scale(const int i, const int b) |
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{ |
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int obj_index = index(i, b, m_lcoords); |
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return m_out[obj_index]; |
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} |
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double x(const int i, const int b) |
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{ |
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int box_index = index(i, b, 0); |
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int col = i % m_side; |
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return (col + m_out[box_index]) / m_side; |
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} |
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double y(const int i, const int b) |
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{ |
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int box_index = index(i, b, 0); |
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int row = i / m_side; |
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return (row + m_out[box_index + m_side * m_side]) / m_side; |
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} |
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double width(const int i, const int b, const float anchor) |
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{ |
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int box_index = index(i, b, 0); |
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return std::exp(m_out[box_index + 2 * m_side * m_side]) * anchor / m_side; |
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} |
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double height(const int i, const int b, const float anchor) |
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{ |
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int box_index = index(i, b, 0); |
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return std::exp(m_out[box_index + 3 * m_side * m_side]) * anchor / m_side; |
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} |
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float classConf(const int i, const int b, const int label) |
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{ |
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int class_index = index(i, b, m_lcoords + 1 + label); |
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return m_out[class_index]; |
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} |
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cv::Rect toBox(const double x, const double y, const double h, const double w, const cv::Size& in_sz) |
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{ |
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auto h_scale = in_sz.height; |
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auto w_scale = in_sz.width; |
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cv::Rect r; |
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r.x = static_cast<int>((x - w / 2) * w_scale); |
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r.y = static_cast<int>((y - h / 2) * h_scale); |
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r.width = static_cast<int>(w * w_scale); |
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r.height = static_cast<int>(h * h_scale); |
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return r; |
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} |
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int index(const int i, const int b, const int entry) |
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{ |
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return b * m_side * m_side * (m_lcoords + m_lclasses + 1) + entry * m_side * m_side + i; |
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} |
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const float* m_out = nullptr; |
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int m_side = 0, m_lcoords = 0, m_lclasses = 0; |
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}; |
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} // namespace opencv_test |
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#endif // OPENCV_GAPI_PARSERS_TESTS_COMMON_HPP
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