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d2e08a524e
Multi-argument CV_Assert() is accessible via CV_Assert_N() (with malformed messages).
162 lines
5.8 KiB
C++
162 lines
5.8 KiB
C++
#include <opencv2/imgproc.hpp>
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#include <opencv2/highgui.hpp>
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#include <opencv2/dnn.hpp>
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using namespace cv;
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using namespace cv::dnn;
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const char* keys =
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"{ help h | | Print help message. }"
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"{ input i | | Path to input image or video file. Skip this argument to capture frames from a camera.}"
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"{ model m | | Path to a binary .pb file contains trained network.}"
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"{ width | 320 | Preprocess input image by resizing to a specific width. It should be multiple by 32. }"
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"{ height | 320 | Preprocess input image by resizing to a specific height. It should be multiple by 32. }"
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"{ thr | 0.5 | Confidence threshold. }"
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"{ nms | 0.4 | Non-maximum suppression threshold. }";
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void decode(const Mat& scores, const Mat& geometry, float scoreThresh,
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std::vector<RotatedRect>& detections, std::vector<float>& confidences);
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int main(int argc, char** argv)
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{
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// Parse command line arguments.
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CommandLineParser parser(argc, argv, keys);
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parser.about("Use this script to run TensorFlow implementation (https://github.com/argman/EAST) of "
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"EAST: An Efficient and Accurate Scene Text Detector (https://arxiv.org/abs/1704.03155v2)");
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if (argc == 1 || parser.has("help"))
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{
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parser.printMessage();
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return 0;
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}
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float confThreshold = parser.get<float>("thr");
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float nmsThreshold = parser.get<float>("nms");
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int inpWidth = parser.get<int>("width");
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int inpHeight = parser.get<int>("height");
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String model = parser.get<String>("model");
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if (!parser.check())
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{
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parser.printErrors();
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return 1;
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}
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CV_Assert(!model.empty());
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// Load network.
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Net net = readNet(model);
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// Open a video file or an image file or a camera stream.
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VideoCapture cap;
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if (parser.has("input"))
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cap.open(parser.get<String>("input"));
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else
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cap.open(0);
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static const std::string kWinName = "EAST: An Efficient and Accurate Scene Text Detector";
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namedWindow(kWinName, WINDOW_NORMAL);
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std::vector<Mat> outs;
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std::vector<String> outNames(2);
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outNames[0] = "feature_fusion/Conv_7/Sigmoid";
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outNames[1] = "feature_fusion/concat_3";
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Mat frame, blob;
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while (waitKey(1) < 0)
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{
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cap >> frame;
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if (frame.empty())
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{
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waitKey();
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break;
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}
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blobFromImage(frame, blob, 1.0, Size(inpWidth, inpHeight), Scalar(123.68, 116.78, 103.94), true, false);
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net.setInput(blob);
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net.forward(outs, outNames);
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Mat scores = outs[0];
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Mat geometry = outs[1];
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// Decode predicted bounding boxes.
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std::vector<RotatedRect> boxes;
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std::vector<float> confidences;
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decode(scores, geometry, confThreshold, boxes, confidences);
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// Apply non-maximum suppression procedure.
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std::vector<int> indices;
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NMSBoxes(boxes, confidences, confThreshold, nmsThreshold, indices);
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// Render detections.
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Point2f ratio((float)frame.cols / inpWidth, (float)frame.rows / inpHeight);
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for (size_t i = 0; i < indices.size(); ++i)
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{
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RotatedRect& box = boxes[indices[i]];
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Point2f vertices[4];
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box.points(vertices);
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for (int j = 0; j < 4; ++j)
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{
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vertices[j].x *= ratio.x;
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vertices[j].y *= ratio.y;
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}
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for (int j = 0; j < 4; ++j)
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line(frame, vertices[j], vertices[(j + 1) % 4], Scalar(0, 255, 0), 1);
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}
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// Put efficiency information.
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std::vector<double> layersTimes;
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double freq = getTickFrequency() / 1000;
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double t = net.getPerfProfile(layersTimes) / freq;
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std::string label = format("Inference time: %.2f ms", t);
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putText(frame, label, Point(0, 15), FONT_HERSHEY_SIMPLEX, 0.5, Scalar(0, 255, 0));
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imshow(kWinName, frame);
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}
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return 0;
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}
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void decode(const Mat& scores, const Mat& geometry, float scoreThresh,
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std::vector<RotatedRect>& detections, std::vector<float>& confidences)
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{
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detections.clear();
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CV_Assert(scores.dims == 4); CV_Assert(geometry.dims == 4); CV_Assert(scores.size[0] == 1);
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CV_Assert(geometry.size[0] == 1); CV_Assert(scores.size[1] == 1); CV_Assert(geometry.size[1] == 5);
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CV_Assert(scores.size[2] == geometry.size[2]); CV_Assert(scores.size[3] == geometry.size[3]);
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const int height = scores.size[2];
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const int width = scores.size[3];
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for (int y = 0; y < height; ++y)
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{
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const float* scoresData = scores.ptr<float>(0, 0, y);
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const float* x0_data = geometry.ptr<float>(0, 0, y);
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const float* x1_data = geometry.ptr<float>(0, 1, y);
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const float* x2_data = geometry.ptr<float>(0, 2, y);
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const float* x3_data = geometry.ptr<float>(0, 3, y);
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const float* anglesData = geometry.ptr<float>(0, 4, y);
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for (int x = 0; x < width; ++x)
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{
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float score = scoresData[x];
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if (score < scoreThresh)
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continue;
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// Decode a prediction.
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// Multiple by 4 because feature maps are 4 time less than input image.
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float offsetX = x * 4.0f, offsetY = y * 4.0f;
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float angle = anglesData[x];
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float cosA = std::cos(angle);
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float sinA = std::sin(angle);
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float h = x0_data[x] + x2_data[x];
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float w = x1_data[x] + x3_data[x];
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Point2f offset(offsetX + cosA * x1_data[x] + sinA * x2_data[x],
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offsetY - sinA * x1_data[x] + cosA * x2_data[x]);
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Point2f p1 = Point2f(-sinA * h, -cosA * h) + offset;
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Point2f p3 = Point2f(-cosA * w, sinA * w) + offset;
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RotatedRect r(0.5f * (p1 + p3), Size2f(w, h), -angle * 180.0f / (float)CV_PI);
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detections.push_back(r);
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confidences.push_back(score);
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}
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}
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}
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