/*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) 2000-2008, Intel Corporation, all rights reserved. // Copyright (C) 2009, Willow Garage Inc., 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*/ #ifndef __OPENCV_VIDEOIO_HPP__ #define __OPENCV_VIDEOIO_HPP__ #include "opencv2/core.hpp" /** @defgroup videoio Media I/O @{ @defgroup videoio_c C API @defgroup videoio_ios iOS glue @} */ ////////////////////////////////// video io ///////////////////////////////// typedef struct CvCapture CvCapture; typedef struct CvVideoWriter CvVideoWriter; namespace cv { //! @addtogroup videoio //! @{ // Camera API enum { CAP_ANY = 0, // autodetect CAP_VFW = 200, // platform native CAP_V4L = 200, CAP_V4L2 = CAP_V4L, CAP_FIREWARE = 300, // IEEE 1394 drivers CAP_FIREWIRE = CAP_FIREWARE, CAP_IEEE1394 = CAP_FIREWARE, CAP_DC1394 = CAP_FIREWARE, CAP_CMU1394 = CAP_FIREWARE, CAP_QT = 500, // QuickTime CAP_UNICAP = 600, // Unicap drivers CAP_DSHOW = 700, // DirectShow (via videoInput) CAP_PVAPI = 800, // PvAPI, Prosilica GigE SDK CAP_OPENNI = 900, // OpenNI (for Kinect) CAP_OPENNI_ASUS = 910, // OpenNI (for Asus Xtion) CAP_ANDROID = 1000, // Android CAP_XIAPI = 1100, // XIMEA Camera API CAP_AVFOUNDATION = 1200, // AVFoundation framework for iOS (OS X Lion will have the same API) CAP_GIGANETIX = 1300, // Smartek Giganetix GigEVisionSDK CAP_MSMF = 1400, // Microsoft Media Foundation (via videoInput) CAP_INTELPERC = 1500, // Intel Perceptual Computing SDK CAP_OPENNI2 = 1600, // OpenNI2 (for Kinect) CAP_OPENNI2_ASUS = 1610 // OpenNI2 (for Asus Xtion and Occipital Structure sensors) }; // generic properties (based on DC1394 properties) enum { CAP_PROP_POS_MSEC =0, CAP_PROP_POS_FRAMES =1, CAP_PROP_POS_AVI_RATIO =2, CAP_PROP_FRAME_WIDTH =3, CAP_PROP_FRAME_HEIGHT =4, CAP_PROP_FPS =5, CAP_PROP_FOURCC =6, CAP_PROP_FRAME_COUNT =7, CAP_PROP_FORMAT =8, CAP_PROP_MODE =9, CAP_PROP_BRIGHTNESS =10, CAP_PROP_CONTRAST =11, CAP_PROP_SATURATION =12, CAP_PROP_HUE =13, CAP_PROP_GAIN =14, CAP_PROP_EXPOSURE =15, CAP_PROP_CONVERT_RGB =16, CAP_PROP_WHITE_BALANCE_BLUE_U =17, CAP_PROP_RECTIFICATION =18, CAP_PROP_MONOCHROME =19, CAP_PROP_SHARPNESS =20, CAP_PROP_AUTO_EXPOSURE =21, // DC1394: exposure control done by camera, user can adjust refernce level using this feature CAP_PROP_GAMMA =22, CAP_PROP_TEMPERATURE =23, CAP_PROP_TRIGGER =24, CAP_PROP_TRIGGER_DELAY =25, CAP_PROP_WHITE_BALANCE_RED_V =26, CAP_PROP_ZOOM =27, CAP_PROP_FOCUS =28, CAP_PROP_GUID =29, CAP_PROP_ISO_SPEED =30, CAP_PROP_BACKLIGHT =32, CAP_PROP_PAN =33, CAP_PROP_TILT =34, CAP_PROP_ROLL =35, CAP_PROP_IRIS =36, CAP_PROP_SETTINGS =37 }; // Generic camera output modes. // Currently, these are supported through the libv4l interface only. enum { CAP_MODE_BGR = 0, // BGR24 (default) CAP_MODE_RGB = 1, // RGB24 CAP_MODE_GRAY = 2, // Y8 CAP_MODE_YUYV = 3 // YUYV }; // DC1394 only // modes of the controlling registers (can be: auto, manual, auto single push, absolute Latter allowed with any other mode) // every feature can have only one mode turned on at a time enum { CAP_PROP_DC1394_OFF = -4, //turn the feature off (not controlled manually nor automatically) CAP_PROP_DC1394_MODE_MANUAL = -3, //set automatically when a value of the feature is set by the user CAP_PROP_DC1394_MODE_AUTO = -2, CAP_PROP_DC1394_MODE_ONE_PUSH_AUTO = -1, CAP_PROP_DC1394_MAX = 31 }; // OpenNI map generators enum { CAP_OPENNI_DEPTH_GENERATOR = 1 << 31, CAP_OPENNI_IMAGE_GENERATOR = 1 << 30, CAP_OPENNI_GENERATORS_MASK = CAP_OPENNI_DEPTH_GENERATOR + CAP_OPENNI_IMAGE_GENERATOR }; // Properties of cameras available through OpenNI interfaces enum { CAP_PROP_OPENNI_OUTPUT_MODE = 100, CAP_PROP_OPENNI_FRAME_MAX_DEPTH = 101, // in mm CAP_PROP_OPENNI_BASELINE = 102, // in mm CAP_PROP_OPENNI_FOCAL_LENGTH = 103, // in pixels CAP_PROP_OPENNI_REGISTRATION = 104, // flag that synchronizes the remapping depth map to image map // by changing depth generator's view point (if the flag is "on") or // sets this view point to its normal one (if the flag is "off"). CAP_PROP_OPENNI_REGISTRATION_ON = CAP_PROP_OPENNI_REGISTRATION, CAP_PROP_OPENNI_APPROX_FRAME_SYNC = 105, CAP_PROP_OPENNI_MAX_BUFFER_SIZE = 106, CAP_PROP_OPENNI_CIRCLE_BUFFER = 107, CAP_PROP_OPENNI_MAX_TIME_DURATION = 108, CAP_PROP_OPENNI_GENERATOR_PRESENT = 109, CAP_PROP_OPENNI2_SYNC = 110, CAP_PROP_OPENNI2_MIRROR = 111 }; // OpenNI shortcats enum { CAP_OPENNI_IMAGE_GENERATOR_PRESENT = CAP_OPENNI_IMAGE_GENERATOR + CAP_PROP_OPENNI_GENERATOR_PRESENT, CAP_OPENNI_IMAGE_GENERATOR_OUTPUT_MODE = CAP_OPENNI_IMAGE_GENERATOR + CAP_PROP_OPENNI_OUTPUT_MODE, CAP_OPENNI_DEPTH_GENERATOR_BASELINE = CAP_OPENNI_DEPTH_GENERATOR + CAP_PROP_OPENNI_BASELINE, CAP_OPENNI_DEPTH_GENERATOR_FOCAL_LENGTH = CAP_OPENNI_DEPTH_GENERATOR + CAP_PROP_OPENNI_FOCAL_LENGTH, CAP_OPENNI_DEPTH_GENERATOR_REGISTRATION = CAP_OPENNI_DEPTH_GENERATOR + CAP_PROP_OPENNI_REGISTRATION, CAP_OPENNI_DEPTH_GENERATOR_REGISTRATION_ON = CAP_OPENNI_DEPTH_GENERATOR_REGISTRATION }; // OpenNI data given from depth generator enum { CAP_OPENNI_DEPTH_MAP = 0, // Depth values in mm (CV_16UC1) CAP_OPENNI_POINT_CLOUD_MAP = 1, // XYZ in meters (CV_32FC3) CAP_OPENNI_DISPARITY_MAP = 2, // Disparity in pixels (CV_8UC1) CAP_OPENNI_DISPARITY_MAP_32F = 3, // Disparity in pixels (CV_32FC1) CAP_OPENNI_VALID_DEPTH_MASK = 4, // CV_8UC1 // Data given from RGB image generator CAP_OPENNI_BGR_IMAGE = 5, CAP_OPENNI_GRAY_IMAGE = 6 }; // Supported output modes of OpenNI image generator enum { CAP_OPENNI_VGA_30HZ = 0, CAP_OPENNI_SXGA_15HZ = 1, CAP_OPENNI_SXGA_30HZ = 2, CAP_OPENNI_QVGA_30HZ = 3, CAP_OPENNI_QVGA_60HZ = 4 }; // GStreamer enum { CAP_PROP_GSTREAMER_QUEUE_LENGTH = 200 // default is 1 }; // PVAPI enum { CAP_PROP_PVAPI_MULTICASTIP = 300, // ip for anable multicast master mode. 0 for disable multicast CAP_PROP_PVAPI_FRAMESTARTTRIGGERMODE = 301, // FrameStartTriggerMode: Determines how a frame is initiated CAP_PROP_PVAPI_DECIMATIONHORIZONTAL = 302, // Horizontal sub-sampling of the image CAP_PROP_PVAPI_DECIMATIONVERTICAL = 303, // Vertical sub-sampling of the image CAP_PROP_PVAPI_BINNINGX = 304, // Horizontal binning factor CAP_PROP_PVAPI_BINNINGY = 305, // Vertical binning factor CAP_PROP_PVAPI_PIXELFORMAT = 306 // Pixel format }; // PVAPI: FrameStartTriggerMode enum { CAP_PVAPI_FSTRIGMODE_FREERUN = 0, // Freerun CAP_PVAPI_FSTRIGMODE_SYNCIN1 = 1, // SyncIn1 CAP_PVAPI_FSTRIGMODE_SYNCIN2 = 2, // SyncIn2 CAP_PVAPI_FSTRIGMODE_FIXEDRATE = 3, // FixedRate CAP_PVAPI_FSTRIGMODE_SOFTWARE = 4 // Software }; // PVAPI: DecimationHorizontal, DecimationVertical enum { CAP_PVAPI_DECIMATION_OFF = 1, // Off CAP_PVAPI_DECIMATION_2OUTOF4 = 2, // 2 out of 4 decimation CAP_PVAPI_DECIMATION_2OUTOF8 = 4, // 2 out of 8 decimation CAP_PVAPI_DECIMATION_2OUTOF16 = 8 // 2 out of 16 decimation }; // PVAPI: PixelFormat enum { CAP_PVAPI_PIXELFORMAT_MONO8 = 1, // Mono8 CAP_PVAPI_PIXELFORMAT_MONO16 = 2, // Mono16 CAP_PVAPI_PIXELFORMAT_BAYER8 = 3, // Bayer8 CAP_PVAPI_PIXELFORMAT_BAYER16 = 4, // Bayer16 CAP_PVAPI_PIXELFORMAT_RGB24 = 5, // Rgb24 CAP_PVAPI_PIXELFORMAT_BGR24 = 6, // Bgr24 CAP_PVAPI_PIXELFORMAT_RGBA32 = 7, // Rgba32 CAP_PVAPI_PIXELFORMAT_BGRA32 = 8, // Bgra32 }; // Properties of cameras available through XIMEA SDK interface enum { CAP_PROP_XI_DOWNSAMPLING = 400, // Change image resolution by binning or skipping. CAP_PROP_XI_DATA_FORMAT = 401, // Output data format. CAP_PROP_XI_OFFSET_X = 402, // Horizontal offset from the origin to the area of interest (in pixels). CAP_PROP_XI_OFFSET_Y = 403, // Vertical offset from the origin to the area of interest (in pixels). CAP_PROP_XI_TRG_SOURCE = 404, // Defines source of trigger. CAP_PROP_XI_TRG_SOFTWARE = 405, // Generates an internal trigger. PRM_TRG_SOURCE must be set to TRG_SOFTWARE. CAP_PROP_XI_GPI_SELECTOR = 406, // Selects general purpose input CAP_PROP_XI_GPI_MODE = 407, // Set general purpose input mode CAP_PROP_XI_GPI_LEVEL = 408, // Get general purpose level CAP_PROP_XI_GPO_SELECTOR = 409, // Selects general purpose output CAP_PROP_XI_GPO_MODE = 410, // Set general purpose output mode CAP_PROP_XI_LED_SELECTOR = 411, // Selects camera signalling LED CAP_PROP_XI_LED_MODE = 412, // Define camera signalling LED functionality CAP_PROP_XI_MANUAL_WB = 413, // Calculates White Balance(must be called during acquisition) CAP_PROP_XI_AUTO_WB = 414, // Automatic white balance CAP_PROP_XI_AEAG = 415, // Automatic exposure/gain CAP_PROP_XI_EXP_PRIORITY = 416, // Exposure priority (0.5 - exposure 50%, gain 50%). CAP_PROP_XI_AE_MAX_LIMIT = 417, // Maximum limit of exposure in AEAG procedure CAP_PROP_XI_AG_MAX_LIMIT = 418, // Maximum limit of gain in AEAG procedure CAP_PROP_XI_AEAG_LEVEL = 419, // Average intensity of output signal AEAG should achieve(in %) CAP_PROP_XI_TIMEOUT = 420 // Image capture timeout in milliseconds }; // Properties for Android cameras enum { CAP_PROP_ANDROID_AUTOGRAB = 1024, CAP_PROP_ANDROID_PREVIEW_SIZES_STRING = 1025, // readonly, tricky property, returns const char* indeed CAP_PROP_ANDROID_PREVIEW_FORMAT = 1026, // readonly, tricky property, returns const char* indeed CAP_PROP_ANDROID_FLASH_MODE = 8001, CAP_PROP_ANDROID_FOCUS_MODE = 8002, CAP_PROP_ANDROID_WHITE_BALANCE = 8003, CAP_PROP_ANDROID_ANTIBANDING = 8004, CAP_PROP_ANDROID_FOCAL_LENGTH = 8005, CAP_PROP_ANDROID_FOCUS_DISTANCE_NEAR = 8006, CAP_PROP_ANDROID_FOCUS_DISTANCE_OPTIMAL = 8007, CAP_PROP_ANDROID_FOCUS_DISTANCE_FAR = 8008 }; // Android camera output formats enum { CAP_ANDROID_COLOR_FRAME_BGR = 0, //BGR CAP_ANDROID_COLOR_FRAME = CAP_ANDROID_COLOR_FRAME_BGR, CAP_ANDROID_GREY_FRAME = 1, //Y CAP_ANDROID_GRAY_FRAME = CAP_ANDROID_GREY_FRAME, CAP_ANDROID_COLOR_FRAME_RGB = 2, CAP_ANDROID_COLOR_FRAME_BGRA = 3, CAP_ANDROID_COLOR_FRAME_RGBA = 4 }; // Android camera flash modes enum { CAP_ANDROID_FLASH_MODE_AUTO = 0, CAP_ANDROID_FLASH_MODE_OFF = 1, CAP_ANDROID_FLASH_MODE_ON = 2, CAP_ANDROID_FLASH_MODE_RED_EYE = 3, CAP_ANDROID_FLASH_MODE_TORCH = 4 }; // Android camera focus modes enum { CAP_ANDROID_FOCUS_MODE_AUTO = 0, CAP_ANDROID_FOCUS_MODE_CONTINUOUS_VIDEO = 1, CAP_ANDROID_FOCUS_MODE_EDOF = 2, CAP_ANDROID_FOCUS_MODE_FIXED = 3, CAP_ANDROID_FOCUS_MODE_INFINITY = 4, CAP_ANDROID_FOCUS_MODE_MACRO = 5 }; // Android camera white balance modes enum { CAP_ANDROID_WHITE_BALANCE_AUTO = 0, CAP_ANDROID_WHITE_BALANCE_CLOUDY_DAYLIGHT = 1, CAP_ANDROID_WHITE_BALANCE_DAYLIGHT = 2, CAP_ANDROID_WHITE_BALANCE_FLUORESCENT = 3, CAP_ANDROID_WHITE_BALANCE_INCANDESCENT = 4, CAP_ANDROID_WHITE_BALANCE_SHADE = 5, CAP_ANDROID_WHITE_BALANCE_TWILIGHT = 6, CAP_ANDROID_WHITE_BALANCE_WARM_FLUORESCENT = 7 }; // Android camera antibanding modes enum { CAP_ANDROID_ANTIBANDING_50HZ = 0, CAP_ANDROID_ANTIBANDING_60HZ = 1, CAP_ANDROID_ANTIBANDING_AUTO = 2, CAP_ANDROID_ANTIBANDING_OFF = 3 }; // Properties of cameras available through AVFOUNDATION interface enum { CAP_PROP_IOS_DEVICE_FOCUS = 9001, CAP_PROP_IOS_DEVICE_EXPOSURE = 9002, CAP_PROP_IOS_DEVICE_FLASH = 9003, CAP_PROP_IOS_DEVICE_WHITEBALANCE = 9004, CAP_PROP_IOS_DEVICE_TORCH = 9005 }; // Properties of cameras available through Smartek Giganetix Ethernet Vision interface /* --- Vladimir Litvinenko (litvinenko.vladimir@gmail.com) --- */ enum { CAP_PROP_GIGA_FRAME_OFFSET_X = 10001, CAP_PROP_GIGA_FRAME_OFFSET_Y = 10002, CAP_PROP_GIGA_FRAME_WIDTH_MAX = 10003, CAP_PROP_GIGA_FRAME_HEIGH_MAX = 10004, CAP_PROP_GIGA_FRAME_SENS_WIDTH = 10005, CAP_PROP_GIGA_FRAME_SENS_HEIGH = 10006 }; enum { CAP_PROP_INTELPERC_PROFILE_COUNT = 11001, CAP_PROP_INTELPERC_PROFILE_IDX = 11002, CAP_PROP_INTELPERC_DEPTH_LOW_CONFIDENCE_VALUE = 11003, CAP_PROP_INTELPERC_DEPTH_SATURATION_VALUE = 11004, CAP_PROP_INTELPERC_DEPTH_CONFIDENCE_THRESHOLD = 11005, CAP_PROP_INTELPERC_DEPTH_FOCAL_LENGTH_HORZ = 11006, CAP_PROP_INTELPERC_DEPTH_FOCAL_LENGTH_VERT = 11007 }; // Intel PerC streams enum { CAP_INTELPERC_DEPTH_GENERATOR = 1 << 29, CAP_INTELPERC_IMAGE_GENERATOR = 1 << 28, CAP_INTELPERC_GENERATORS_MASK = CAP_INTELPERC_DEPTH_GENERATOR + CAP_INTELPERC_IMAGE_GENERATOR }; enum { CAP_INTELPERC_DEPTH_MAP = 0, // Each pixel is a 16-bit integer. The value indicates the distance from an object to the camera's XY plane or the Cartesian depth. CAP_INTELPERC_UVDEPTH_MAP = 1, // Each pixel contains two 32-bit floating point values in the range of 0-1, representing the mapping of depth coordinates to the color coordinates. CAP_INTELPERC_IR_MAP = 2, // Each pixel is a 16-bit integer. The value indicates the intensity of the reflected laser beam. CAP_INTELPERC_IMAGE = 3 }; class IVideoCapture; /** @brief Class for video capturing from video files, image sequences or cameras. The class provides C++ API for capturing video from cameras or for reading video files and image sequences. Here is how the class can be used: : @code #include "opencv2/opencv.hpp" using namespace cv; int main(int, char**) { VideoCapture cap(0); // open the default camera if(!cap.isOpened()) // check if we succeeded return -1; Mat edges; namedWindow("edges",1); for(;;) { Mat frame; cap >> frame; // get a new frame from camera cvtColor(frame, edges, COLOR_BGR2GRAY); GaussianBlur(edges, edges, Size(7,7), 1.5, 1.5); Canny(edges, edges, 0, 30, 3); imshow("edges", edges); if(waitKey(30) >= 0) break; } // the camera will be deinitialized automatically in VideoCapture destructor return 0; } @endcode @note In C API the black-box structure CvCapture is used instead of VideoCapture. @note - A basic sample on using the VideoCapture interface can be found at opencv_source_code/samples/cpp/starter_video.cpp - Another basic video processing sample can be found at opencv_source_code/samples/cpp/video_dmtx.cpp - (Python) A basic sample on using the VideoCapture interface can be found at opencv_source_code/samples/python2/video.py - (Python) Another basic video processing sample can be found at opencv_source_code/samples/python2/video_dmtx.py - (Python) A multi threaded video processing sample can be found at opencv_source_code/samples/python2/video_threaded.py */ class CV_EXPORTS_W VideoCapture { public: /** @brief @note In C API, when you finished working with video, release CvCapture structure with cvReleaseCapture(), or use Ptr\ that calls cvReleaseCapture() automatically in the destructor. */ CV_WRAP VideoCapture(); /** @overload @param filename name of the opened video file (eg. video.avi) or image sequence (eg. img_%02d.jpg, which will read samples like img_00.jpg, img_01.jpg, img_02.jpg, ...) */ CV_WRAP VideoCapture(const String& filename); /** @overload @param device id of the opened video capturing device (i.e. a camera index). If there is a single camera connected, just pass 0. */ CV_WRAP VideoCapture(int device); virtual ~VideoCapture(); /** @brief Open video file or a capturing device for video capturing @param filename name of the opened video file (eg. video.avi) or image sequence (eg. img_%02d.jpg, which will read samples like img_00.jpg, img_01.jpg, img_02.jpg, ...) The methods first call VideoCapture::release to close the already opened file or camera. */ CV_WRAP virtual bool open(const String& filename); /** @overload @param device id of the opened video capturing device (i.e. a camera index). */ CV_WRAP virtual bool open(int device); /** @brief Returns true if video capturing has been initialized already. If the previous call to VideoCapture constructor or VideoCapture::open succeeded, the method returns true. */ CV_WRAP virtual bool isOpened() const; /** @brief Closes video file or capturing device. The methods are automatically called by subsequent VideoCapture::open and by VideoCapture destructor. The C function also deallocates memory and clears \*capture pointer. */ CV_WRAP virtual void release(); /** @brief Grabs the next frame from video file or capturing device. The methods/functions grab the next frame from video file or camera and return true (non-zero) in the case of success. The primary use of the function is in multi-camera environments, especially when the cameras do not have hardware synchronization. That is, you call VideoCapture::grab() for each camera and after that call the slower method VideoCapture::retrieve() to decode and get frame from each camera. This way the overhead on demosaicing or motion jpeg decompression etc. is eliminated and the retrieved frames from different cameras will be closer in time. Also, when a connected camera is multi-head (for example, a stereo camera or a Kinect device), the correct way of retrieving data from it is to call VideoCapture::grab first and then call VideoCapture::retrieve one or more times with different values of the channel parameter. See */ CV_WRAP virtual bool grab(); /** @brief Decodes and returns the grabbed video frame. The methods/functions decode and return the just grabbed frame. If no frames has been grabbed (camera has been disconnected, or there are no more frames in video file), the methods return false and the functions return NULL pointer. @note OpenCV 1.x functions cvRetrieveFrame and cv.RetrieveFrame return image stored inside the video capturing structure. It is not allowed to modify or release the image! You can copy the frame using :ocvcvCloneImage and then do whatever you want with the copy. */ CV_WRAP virtual bool retrieve(OutputArray image, int flag = 0); virtual VideoCapture& operator >> (CV_OUT Mat& image); virtual VideoCapture& operator >> (CV_OUT UMat& image); /** @brief Grabs, decodes and returns the next video frame. The methods/functions combine VideoCapture::grab and VideoCapture::retrieve in one call. This is the most convenient method for reading video files or capturing data from decode and return the just grabbed frame. If no frames has been grabbed (camera has been disconnected, or there are no more frames in video file), the methods return false and the functions return NULL pointer. @note OpenCV 1.x functions cvRetrieveFrame and cv.RetrieveFrame return image stored inside the video capturing structure. It is not allowed to modify or release the image! You can copy the frame using :ocvcvCloneImage and then do whatever you want with the copy. */ CV_WRAP virtual bool read(OutputArray image); /** @brief Sets a property in the VideoCapture. @param propId Property identifier. It can be one of the following: - **CV_CAP_PROP_POS_MSEC** Current position of the video file in milliseconds. - **CV_CAP_PROP_POS_FRAMES** 0-based index of the frame to be decoded/captured next. - **CV_CAP_PROP_POS_AVI_RATIO** Relative position of the video file: 0 - start of the film, 1 - end of the film. - **CV_CAP_PROP_FRAME_WIDTH** Width of the frames in the video stream. - **CV_CAP_PROP_FRAME_HEIGHT** Height of the frames in the video stream. - **CV_CAP_PROP_FPS** Frame rate. - **CV_CAP_PROP_FOURCC** 4-character code of codec. - **CV_CAP_PROP_FRAME_COUNT** Number of frames in the video file. - **CV_CAP_PROP_FORMAT** Format of the Mat objects returned by retrieve() . - **CV_CAP_PROP_MODE** Backend-specific value indicating the current capture mode. - **CV_CAP_PROP_BRIGHTNESS** Brightness of the image (only for cameras). - **CV_CAP_PROP_CONTRAST** Contrast of the image (only for cameras). - **CV_CAP_PROP_SATURATION** Saturation of the image (only for cameras). - **CV_CAP_PROP_HUE** Hue of the image (only for cameras). - **CV_CAP_PROP_GAIN** Gain of the image (only for cameras). - **CV_CAP_PROP_EXPOSURE** Exposure (only for cameras). - **CV_CAP_PROP_CONVERT_RGB** Boolean flags indicating whether images should be converted to RGB. - **CV_CAP_PROP_WHITE_BALANCE** Currently unsupported - **CV_CAP_PROP_RECTIFICATION** Rectification flag for stereo cameras (note: only supported by DC1394 v 2.x backend currently) @param value Value of the property. */ CV_WRAP virtual bool set(int propId, double value); /** @brief Returns the specified VideoCapture property @param propId Property identifier. It can be one of the following: - **CV_CAP_PROP_POS_MSEC** Current position of the video file in milliseconds or video capture timestamp. - **CV_CAP_PROP_POS_FRAMES** 0-based index of the frame to be decoded/captured next. - **CV_CAP_PROP_POS_AVI_RATIO** Relative position of the video file: 0 - start of the film, 1 - end of the film. - **CV_CAP_PROP_FRAME_WIDTH** Width of the frames in the video stream. - **CV_CAP_PROP_FRAME_HEIGHT** Height of the frames in the video stream. - **CV_CAP_PROP_FPS** Frame rate. - **CV_CAP_PROP_FOURCC** 4-character code of codec. - **CV_CAP_PROP_FRAME_COUNT** Number of frames in the video file. - **CV_CAP_PROP_FORMAT** Format of the Mat objects returned by retrieve() . - **CV_CAP_PROP_MODE** Backend-specific value indicating the current capture mode. - **CV_CAP_PROP_BRIGHTNESS** Brightness of the image (only for cameras). - **CV_CAP_PROP_CONTRAST** Contrast of the image (only for cameras). - **CV_CAP_PROP_SATURATION** Saturation of the image (only for cameras). - **CV_CAP_PROP_HUE** Hue of the image (only for cameras). - **CV_CAP_PROP_GAIN** Gain of the image (only for cameras). - **CV_CAP_PROP_EXPOSURE** Exposure (only for cameras). - **CV_CAP_PROP_CONVERT_RGB** Boolean flags indicating whether images should be converted to RGB. - **CV_CAP_PROP_WHITE_BALANCE** Currently not supported - **CV_CAP_PROP_RECTIFICATION** Rectification flag for stereo cameras (note: only supported by DC1394 v 2.x backend currently) **Note**: When querying a property that is not supported by the backend used by the VideoCapture class, value 0 is returned. */ CV_WRAP virtual double get(int propId) const; protected: Ptr cap; Ptr icap; private: static Ptr createCameraCapture(int index); }; /** @brief Video writer class. */ class CV_EXPORTS_W VideoWriter { public: /** @brief VideoWriter constructors The constructors/functions initialize video writers. On Linux FFMPEG is used to write videos; on Windows FFMPEG or VFW is used; on MacOSX QTKit is used. */ CV_WRAP VideoWriter(); /** @overload @param filename Name of the output video file. @param fourcc 4-character code of codec used to compress the frames. For example, VideoWriter::fourcc('P','I','M','1') is a MPEG-1 codec, VideoWriter::fourcc('M','J','P','G') is a motion-jpeg codec etc. List of codes can be obtained at [Video Codecs by FOURCC](http://www.fourcc.org/codecs.php) page. @param fps Framerate of the created video stream. @param frameSize Size of the video frames. @param isColor If it is not zero, the encoder will expect and encode color frames, otherwise it will work with grayscale frames (the flag is currently supported on Windows only). */ CV_WRAP VideoWriter(const String& filename, int fourcc, double fps, Size frameSize, bool isColor = true); virtual ~VideoWriter(); /** @brief Initializes or reinitializes video writer. The method opens video writer. Parameters are the same as in the constructor VideoWriter::VideoWriter. */ CV_WRAP virtual bool open(const String& filename, int fourcc, double fps, Size frameSize, bool isColor = true); /** @brief Returns true if video writer has been successfully initialized. */ CV_WRAP virtual bool isOpened() const; CV_WRAP virtual void release(); virtual VideoWriter& operator << (const Mat& image); /** @brief Writes the next video frame @param image The written frame The functions/methods write the specified image to video file. It must have the same size as has been specified when opening the video writer. */ CV_WRAP virtual void write(const Mat& image); /** @brief Concatenates 4 chars to a fourcc code This static method constructs the fourcc code of the codec to be used in the constructor VideoWriter::VideoWriter or VideoWriter::open. */ CV_WRAP static int fourcc(char c1, char c2, char c3, char c4); protected: Ptr writer; }; template<> CV_EXPORTS void DefaultDeleter::operator ()(CvCapture* obj) const; template<> CV_EXPORTS void DefaultDeleter::operator ()(CvVideoWriter* obj) const; //! @} videoio } // cv #endif //__OPENCV_VIDEOIO_HPP__