Add first proof of concept

10 years ago · 14cdb2c0fb
3 changed files with 298 additions and 0 deletions
--- a/CMakeLists.txt
+++ b/CMakeLists.txt
@ -0,0 +1,30 @@
 cmake_minimum_required(VERSION 2.8.3)
 project(papillon)
 find_package(catkin REQUIRED COMPONENTS
  roscpp
  std_msgs
  image_transport
  cv_bridge
 )
 find_package(OpenCV)
 catkin_package(CATKIN_DEPENDS
  roscpp
  std_msgs
  image_transport
  cv_bridge
 )
 include_directories  (${catkin_INCLUDE_DIRS})
 add_executable       (papillon src/papillon.cpp)
 target_link_libraries(papillon ${catkin_LIBRARIES})
 set_property         (TARGET papillon APPEND PROPERTY INCLUDE_DIRECTORIES ${OpenCV_INCLUDE_DIRS})
 set_property         (TARGET papillon APPEND PROPERTY INCLUDE_DIRECTORIES ${catkin_INCLUDE_DIRS})
 set_property         (TARGET papillon APPEND PROPERTY LINK_LIBRARIES      ${OpenCV_LIBRARIES})
 install(TARGETS papillon DESTINATION ${CATKIN_PACKAGE_BIN_DESTINATION})
 add_definitions(-Wall -std=c++11)
--- a/package.xml
+++ b/package.xml
@ -0,0 +1,60 @@
 <?xml version="1.0"?>
 <package>
  <name>papillon</name>
  <version>0.0.0</version>
  <description>Papillon : les drones font la chenille</description>
  <!-- One maintainer tag required, multiple allowed, one person per tag -->
  <!-- Example:  -->
  <!-- <maintainer email="jane.doe@example.com">Jane Doe</maintainer> -->
  <maintainer email="goulven.kermarec@metz.supelec.fr">Goulven</maintainer>
  <maintainer email="jean-christophe.carli@metz.supelec.fr">JC</maintainer>
  <!-- One license tag required, multiple allowed, one license per tag -->
  <!-- Commonly used license strings: -->
  <!--   BSD, MIT, Boost Software License, GPLv2, GPLv3, LGPLv2.1, LGPLv3 -->
  <license>TODO</license>
  <!-- Url tags are optional, but mutiple are allowed, one per tag -->
  <!-- Optional attribute type can be: website, bugtracker, or repository -->
  <!-- Example: -->
  <!-- <url type="website">http://wiki.ros.org/test-opencv</url> -->
  <!-- Author tags are optional, mutiple are allowed, one per tag -->
  <!-- Authors do not have to be maintianers, but could be -->
  <!-- Example: -->
  <!-- <author email="jane.doe@example.com">Jane Doe</author> -->
  <!-- The *_depend tags are used to specify dependencies -->
  <!-- Dependencies can be catkin packages or system dependencies -->
  <!-- Examples: -->
  <!-- Use build_depend for packages you need at compile time: -->
  <!--   <build_depend>message_generation</build_depend> -->
  <!-- Use buildtool_depend for build tool packages: -->
  <!--   <buildtool_depend>catkin</buildtool_depend> -->
  <!-- Use run_depend for packages you need at runtime: -->
  <!--   <run_depend>message_runtime</run_depend> -->
  <!-- Use test_depend for packages you need only for testing: -->
  <!--   <test_depend>gtest</test_depend> -->
  <buildtool_depend>catkin</buildtool_depend>
  <build_depend>roscpp</build_depend>
  <build_depend>std_msgs</build_depend>
  <build_depend>image_transport</build_depend>
  <build_depend>cv_bridge</build_depend>
  <run_depend>roscpp</run_depend>
  <run_depend>std_msgs</run_depend>
  <run_depend>image_transport</run_depend>
  <run_depend>cv_bridge</run_depend>
  <!-- The export tag contains other, unspecified, tags -->
  <export>
    <!-- Other tools can request additional information be placed here -->
  </export>
 </package>
--- a/src/papillon.cpp
+++ b/src/papillon.cpp
@ -0,0 +1,208 @@
 #include "ros/ros.h"
 #include <image_transport/image_transport.h>
 #include <cv_bridge/cv_bridge.h>
 #include <sensor_msgs/image_encodings.h>
 #include <opencv/cv.h>
 #include <sstream>
 using namespace cv;
 using namespace std;
 class Traite_image {
 	public:
 		Mat prev;
 		bool first = true;
 		int resize_f = 8;
 		ros::NodeHandle n;
 		image_transport::ImageTransport it;
 		image_transport::Publisher      pub;
 		image_transport::Subscriber     sub;
 		Traite_image() : n("~"),it(n) {
 			pub = it.advertise("/image_out", 1);
 			sub = it.subscribe("/usb_cam/image_raw", 1, [this](const sensor_msgs::ImageConstPtr& img) -> void { this->on_image(img);},ros::VoidPtr(),image_transport::TransportHints("compressed"));
 		}
 		// This processes an image and publishes the result.
 		void on_image(const sensor_msgs::ImageConstPtr& msg) {
 			cv_bridge::CvImageConstPtr bridge_input;
 			try {
 				bridge_input = cv_bridge::toCvShare(msg,sensor_msgs::image_encodings::RGB8);
 			}
 			catch (Exception& e) {
 				std::ostringstream errstr;
 				errstr << "cv_bridge exception caught: " << e.what();
 				return;
 			}
 			//Mat& input  = const_cast<Mat&>(bridge_input->image);
 			const Mat& input = bridge_input->image;
 			Mat next;
 			resize(input, next, Size(input.size().width/resize_f, input.size().height/resize_f));
 			cvtColor(next, next, CV_BGR2GRAY);
 			Mat output; //   (input.rows, input.cols, CV_32FC2);
 			ROS_INFO("got input");
 			if (first) {
 				prev = next.clone();
 				first = false;
 				ROS_INFO("first done");
 			}
 			//unsigned int size           = input.rows * input.cols * 3;
 			//unsigned char* begin_input  = (unsigned char*)(input.data);
 			//unsigned char* end_input    = (unsigned char*)(input.data) + size;
 			//unsigned char* out          = (unsigned char*)(output.data);
 			//unsigned char* in           = begin_input;
 			// This is an efficient way to process each channel in each pixel,
 			// with an iterator taste.
 			//while(in != end_input) {
 			//  *(out++) = *(ptr_prev) - *(in);
 			//  *(ptr_prev++) = *(in++);
 			//}
 			Mat_<Point2f> flow;
 			Ptr<DenseOpticalFlow> tvl1 = createOptFlow_DualTVL1();
 			tvl1->calc(prev, next, flow);
 			drawOpticalFlow(flow, output);
 			pub.publish(cv_bridge::CvImage(msg->header, "rgb8", output).toImageMsg());
 			// bridge_input is handled by a smart-pointer. No explicit delete needed.
 			ROS_INFO("pub");
 			prev = next.clone();
 		}
 		inline bool isFlowCorrect(Point2f u)
 		{
 			return !cvIsNaN(u.x) && !cvIsNaN(u.y) && fabs(u.x) < 1e9 && fabs(u.y) < 1e9;
 		}
 		Vec3b computeColor(float fx, float fy)
 		{
 			static bool first = true;
 			// relative lengths of color transitions:
 			// these are chosen based on perceptual similarity
 			// (e.g. one can distinguish more shades between red and yellow
 			//  than between yellow and green)
 			const int RY = 15;
 			const int YG = 6;
 			const int GC = 4;
 			const int CB = 11;
 			const int BM = 13;
 			const int MR = 6;
 			const int NCOLS = RY + YG + GC + CB + BM + MR;
 			static Vec3i colorWheel[NCOLS];
 			if (first)
 			{
 				int k = 0;
 				for (int i = 0; i < RY; ++i, ++k)
 					colorWheel[k] = Vec3i(255, 255 * i / RY, 0);
 				for (int i = 0; i < YG; ++i, ++k)
 					colorWheel[k] = Vec3i(255 - 255 * i / YG, 255, 0);
 				for (int i = 0; i < GC; ++i, ++k)
 					colorWheel[k] = Vec3i(0, 255, 255 * i / GC);
 				for (int i = 0; i < CB; ++i, ++k)
 					colorWheel[k] = Vec3i(0, 255 - 255 * i / CB, 255);
 				for (int i = 0; i < BM; ++i, ++k)
 					colorWheel[k] = Vec3i(255 * i / BM, 0, 255);
 				for (int i = 0; i < MR; ++i, ++k)
 					colorWheel[k] = Vec3i(255, 0, 255 - 255 * i / MR);
 				first = false;
 			}
 			const float rad = sqrt(fx * fx + fy * fy);
 			const float a = atan2(-fy, -fx) / (float)CV_PI;
 			const float fk = (a + 1.0f) / 2.0f * (NCOLS - 1);
 			const int k0 = static_cast<int>(fk);
 			const int k1 = (k0 + 1) % NCOLS;
 			const float f = fk - k0;
 			Vec3b pix;
 			for (int b = 0; b < 3; b++)
 			{
 				const float col0 = colorWheel[k0][b] / 255.f;
 				const float col1 = colorWheel[k1][b] / 255.f;
 				float col = (1 - f) * col0 + f * col1;
 				if (rad <= 1)
 					col = 1 - rad * (1 - col); // increase saturation with radius
 				else
 					col *= .75; // out of range
 				pix[2 - b] = static_cast<uchar>(255.f * col);
 			}
 			return pix;
 		}
 		void drawOpticalFlow(const Mat_<Point2f>& flow, Mat& dst, float maxmotion = -1)
 		{
 			dst.create(flow.size(), CV_8UC3);
 			dst.setTo(Scalar::all(0));
 			// determine motion range:
 			float maxrad = maxmotion;
 			if (maxmotion <= 0)
 			{
 				maxrad = 1;
 				for (int y = 0; y < flow.rows; ++y)
 				{
 					for (int x = 0; x < flow.cols; ++x)
 					{
 						Point2f u = flow(y, x);
 						if (!isFlowCorrect(u))
 							continue;
 						maxrad = max(maxrad, sqrt(u.x * u.x + u.y * u.y));
 					}
 				}
 			}
 			for (int y = 0; y < flow.rows; ++y)
 			{
 				for (int x = 0; x < flow.cols; ++x)
 				{
 					Point2f u = flow(y, x);
 					if (isFlowCorrect(u))
 						dst.at<Vec3b>(y, x) = computeColor(u.x / maxrad, u.y / maxrad);
 				}
 			}
 		}
 };
 int main(int argc, char **argv)
 {
 	ros::init(argc, argv, "test_opencv");
 	Traite_image dataset=Traite_image();
 	ros::spin();
 	return 0;
 }