/*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 Video I/O

  @brief Read and write video or images sequence with OpenCV

  ### See also:

  - @ref videoio_overview

  - Tutorials: @ref tutorial_table_of_content_app

  @{

    @defgroup videoio_flags_base Flags for video I/O

    @defgroup videoio_flags_others Additional flags for video I/O API backends

    @defgroup videoio_hwaccel Hardware-accelerated video decoding and encoding

    @defgroup videoio_c C API for video I/O

    @defgroup videoio_ios iOS glue for video I/O

    @defgroup videoio_winrt WinRT glue for video I/O

    @defgroup videoio_registry Query I/O API backends registry

  @}

*/

////////////////////////////////// video io /////////////////////////////////

typedef struct CvCapture CvCapture;

typedef struct CvVideoWriter CvVideoWriter;

namespace cv

{

//! @addtogroup videoio

//! @{

//! @addtogroup videoio_flags_base

//! @{

/** @brief cv::VideoCapture API backends identifier.

Select preferred API for a capture object.

To be used in the VideoCapture::VideoCapture() constructor or VideoCapture::open()

@note

-   Backends are available only if they have been built with your OpenCV binaries.

See @ref videoio_overview for more information.

-   Microsoft Media Foundation backend tries to use hardware accelerated transformations

if possible. Environment flag "OPENCV_VIDEOIO_MSMF_ENABLE_HW_TRANSFORMS" set to 0

disables it and may improve initialization time. More details:

https://learn.microsoft.com/en-us/windows/win32/medfound/mf-readwrite-enable-hardware-transforms

*/

enum VideoCaptureAPIs {

       CAP_ANY          = 0,            //!< Auto detect == 0

       CAP_VFW          = 200,          //!< Video For Windows (obsolete, removed)

       CAP_V4L          = 200,          //!< V4L/V4L2 capturing support

       CAP_V4L2         = CAP_V4L,      //!< Same as CAP_V4L

       CAP_FIREWIRE     = 300,          //!< IEEE 1394 drivers

       CAP_FIREWARE     = CAP_FIREWIRE, //!< Same value as CAP_FIREWIRE

       CAP_IEEE1394     = CAP_FIREWIRE, //!< Same value as CAP_FIREWIRE

       CAP_DC1394       = CAP_FIREWIRE, //!< Same value as CAP_FIREWIRE

       CAP_CMU1394      = CAP_FIREWIRE, //!< Same value as CAP_FIREWIRE

       CAP_QT           = 500,          //!< QuickTime (obsolete, removed)

       CAP_UNICAP       = 600,          //!< Unicap drivers (obsolete, removed)

       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,         //!< MediaNDK (API Level 21+) and NDK Camera (API level 24+) for 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). See platform specific notes above.

       CAP_WINRT        = 1410,         //!< Microsoft Windows Runtime using Media Foundation

       CAP_INTELPERC    = 1500,         //!< RealSense (former Intel Perceptual Computing SDK)

       CAP_REALSENSE    = 1500,         //!< Synonym for CAP_INTELPERC

       CAP_OPENNI2      = 1600,         //!< OpenNI2 (for Kinect)

       CAP_OPENNI2_ASUS = 1610,         //!< OpenNI2 (for Asus Xtion and Occipital Structure sensors)

       CAP_OPENNI2_ASTRA= 1620,         //!< OpenNI2 (for Orbbec Astra)

       CAP_GPHOTO2      = 1700,         //!< gPhoto2 connection

       CAP_GSTREAMER    = 1800,         //!< GStreamer

       CAP_FFMPEG       = 1900,         //!< Open and record video file or stream using the FFMPEG library

       CAP_IMAGES       = 2000,         //!< OpenCV Image Sequence (e.g. img_%02d.jpg)

       CAP_ARAVIS       = 2100,         //!< Aravis SDK

       CAP_OPENCV_MJPEG = 2200,         //!< Built-in OpenCV MotionJPEG codec

       CAP_INTEL_MFX    = 2300,         //!< Intel MediaSDK

       CAP_XINE         = 2400,         //!< XINE engine (Linux)

       CAP_UEYE         = 2500,         //!< uEye Camera API

       CAP_OBSENSOR     = 2600,         //!< For Orbbec 3D-Sensor device/module (Astra+, Femto, Astra2, Gemini2, Gemini2L, Gemini2XL, Gemini330, Femto Mega) attention: Astra2 cameras currently only support Windows and Linux kernel versions no higher than 4.15, and higher versions of Linux kernel may have exceptions.

     };

/** @brief cv::VideoCapture generic properties identifier.

 Reading / writing properties involves many layers. Some unexpected result might happens along this chain.

 Effective behaviour depends from device hardware, driver and API Backend.

 @sa videoio_flags_others, VideoCapture::get(), VideoCapture::set()

*/

enum VideoCaptureProperties {

       CAP_PROP_POS_MSEC       =0, //!< Current position of the video file in milliseconds.

       CAP_PROP_POS_FRAMES     =1, //!< 0-based index of the frame to be decoded/captured next. When the index i is set in RAW mode (CAP_PROP_FORMAT == -1) this will seek to the key frame k, where k <= i.

       CAP_PROP_POS_AVI_RATIO  =2, //!< Relative position of the video file: 0=start of the film, 1=end of the film.

       CAP_PROP_FRAME_WIDTH    =3, //!< Width of the frames in the video stream.

       CAP_PROP_FRAME_HEIGHT   =4, //!< Height of the frames in the video stream.

       CAP_PROP_FPS            =5, //!< Frame rate.

       CAP_PROP_FOURCC         =6, //!< 4-character code of codec. see VideoWriter::fourcc .

       CAP_PROP_FRAME_COUNT    =7, //!< Number of frames in the video file.

       CAP_PROP_FORMAT         =8, //!< Format of the %Mat objects (see Mat::type()) returned by VideoCapture::retrieve().

                                   //!< Set value -1 to fetch undecoded RAW video streams (as Mat 8UC1).

       CAP_PROP_MODE           =9, //!< Backend-specific value indicating the current capture mode.

       CAP_PROP_BRIGHTNESS    =10, //!< Brightness of the image (only for those cameras that support).

       CAP_PROP_CONTRAST      =11, //!< Contrast of the image (only for cameras).

       CAP_PROP_SATURATION    =12, //!< Saturation of the image (only for cameras).

       CAP_PROP_HUE           =13, //!< Hue of the image (only for cameras).

       CAP_PROP_GAIN          =14, //!< Gain of the image (only for those cameras that support).

       CAP_PROP_EXPOSURE      =15, //!< Exposure (only for those cameras that support).

       CAP_PROP_CONVERT_RGB   =16, //!< Boolean flags indicating whether images should be converted to RGB. <br/>

                                   //!< *GStreamer note*: The flag is ignored in case if custom pipeline is used. It's user responsibility to interpret pipeline output.

       CAP_PROP_WHITE_BALANCE_BLUE_U =17, //!< Currently unsupported.

       CAP_PROP_RECTIFICATION =18, //!< Rectification flag for stereo cameras (note: only supported by DC1394 v 2.x backend currently).

       CAP_PROP_MONOCHROME    =19,

       CAP_PROP_SHARPNESS     =20,

       CAP_PROP_AUTO_EXPOSURE =21, //!< DC1394: exposure control done by camera, user can adjust reference 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, //!< Android: May switch physical cameras/lenses. Factor and range are hardware-dependent.

       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, //!< Pop up video/camera filter dialog (note: only supported by DSHOW backend currently. The property value is ignored)

       CAP_PROP_BUFFERSIZE    =38,

       CAP_PROP_AUTOFOCUS     =39,

       CAP_PROP_SAR_NUM       =40, //!< Sample aspect ratio: num/den (num)

       CAP_PROP_SAR_DEN       =41, //!< Sample aspect ratio: num/den (den)

       CAP_PROP_BACKEND       =42, //!< Current backend (enum VideoCaptureAPIs). Read-only property

       CAP_PROP_CHANNEL       =43, //!< Video input or Channel Number (only for those cameras that support)

       CAP_PROP_AUTO_WB       =44, //!< enable/ disable auto white-balance

       CAP_PROP_WB_TEMPERATURE=45, //!< white-balance color temperature

       CAP_PROP_CODEC_PIXEL_FORMAT =46,    //!< (read-only) codec's pixel format. 4-character code - see VideoWriter::fourcc . Subset of [AV_PIX_FMT_*](https://github.com/FFmpeg/FFmpeg/blob/master/libavcodec/raw.c) or -1 if unknown

       CAP_PROP_BITRATE       =47, //!< (read-only) Video bitrate in kbits/s

       CAP_PROP_ORIENTATION_META=48, //!< (read-only) Frame rotation defined by stream meta (applicable for FFmpeg and AVFoundation back-ends only)

       CAP_PROP_ORIENTATION_AUTO=49, //!< if true - rotates output frames of CvCapture considering video file's metadata  (applicable for FFmpeg and AVFoundation back-ends only) (https://github.com/opencv/opencv/issues/15499)

       CAP_PROP_HW_ACCELERATION=50, //!< (**open-only**) Hardware acceleration type (see #VideoAccelerationType). Setting supported only via `params` parameter in cv::VideoCapture constructor / .open() method. Default value is backend-specific.

       CAP_PROP_HW_DEVICE      =51, //!< (**open-only**) Hardware device index (select GPU if multiple available). Device enumeration is acceleration type specific.

       CAP_PROP_HW_ACCELERATION_USE_OPENCL=52, //!< (**open-only**) If non-zero, create new OpenCL context and bind it to current thread. The OpenCL context created with Video Acceleration context attached it (if not attached yet) for optimized GPU data copy between HW accelerated decoder and cv::UMat.

       CAP_PROP_OPEN_TIMEOUT_MSEC=53, //!< (**open-only**) timeout in milliseconds for opening a video capture (applicable for FFmpeg and GStreamer back-ends only)

       CAP_PROP_READ_TIMEOUT_MSEC=54, //!< (**open-only**) timeout in milliseconds for reading from a video capture (applicable for FFmpeg and GStreamer back-ends only)

       CAP_PROP_STREAM_OPEN_TIME_USEC =55, //!< (read-only) time in microseconds since Jan 1 1970 when stream was opened. Applicable for FFmpeg backend only. Useful for RTSP and other live streams

       CAP_PROP_VIDEO_TOTAL_CHANNELS = 56, //!< (read-only) Number of video channels

       CAP_PROP_VIDEO_STREAM = 57, //!< (**open-only**) Specify video stream, 0-based index. Use -1 to disable video stream from file or IP cameras. Default value is 0.

       CAP_PROP_AUDIO_STREAM = 58, //!< (**open-only**) Specify stream in multi-language media files, -1 - disable audio processing or microphone. Default value is -1.

       CAP_PROP_AUDIO_POS = 59, //!< (read-only) Audio position is measured in samples. Accurate audio sample timestamp of previous grabbed fragment. See CAP_PROP_AUDIO_SAMPLES_PER_SECOND and CAP_PROP_AUDIO_SHIFT_NSEC.

       CAP_PROP_AUDIO_SHIFT_NSEC = 60, //!< (read only) Contains the time difference between the start of the audio stream and the video stream in nanoseconds. Positive value means that audio is started after the first video frame. Negative value means that audio is started before the first video frame.

       CAP_PROP_AUDIO_DATA_DEPTH = 61, //!< (open, read) Alternative definition to bits-per-sample, but with clear handling of 32F / 32S

       CAP_PROP_AUDIO_SAMPLES_PER_SECOND = 62, //!< (open, read) determined from file/codec input. If not specified, then selected audio sample rate is 44100

       CAP_PROP_AUDIO_BASE_INDEX = 63, //!< (read-only) Index of the first audio channel for .retrieve() calls. That audio channel number continues enumeration after video channels.

       CAP_PROP_AUDIO_TOTAL_CHANNELS = 64, //!< (read-only) Number of audio channels in the selected audio stream (mono, stereo, etc)

       CAP_PROP_AUDIO_TOTAL_STREAMS = 65, //!< (read-only) Number of audio streams.

       CAP_PROP_AUDIO_SYNCHRONIZE = 66, //!< (open, read) Enables audio synchronization.

       CAP_PROP_LRF_HAS_KEY_FRAME = 67, //!< FFmpeg back-end only - Indicates whether the Last Raw Frame (LRF), output from VideoCapture::read() when VideoCapture is initialized with VideoCapture::open(CAP_FFMPEG, {CAP_PROP_FORMAT, -1}) or VideoCapture::set(CAP_PROP_FORMAT,-1) is called before the first call to VideoCapture::read(), contains encoded data for a key frame.

       CAP_PROP_CODEC_EXTRADATA_INDEX = 68, //!< Positive index indicates that returning extra data is supported by the video back end.  This can be retrieved as cap.retrieve(data, <returned index>).  E.g. When reading from a h264 encoded RTSP stream, the FFmpeg backend could return the SPS and/or PPS if available (if sent in reply to a DESCRIBE request), from calls to cap.retrieve(data, <returned index>).

       CAP_PROP_FRAME_TYPE = 69, //!< (read-only) FFmpeg back-end only - Frame type ascii code (73 = 'I', 80 = 'P', 66 = 'B' or 63 = '?' if unknown) of the most recently read frame.

       CAP_PROP_N_THREADS = 70, //!< (**open-only**) Set the maximum number of threads to use. Use 0 to use as many threads as CPU cores (applicable for FFmpeg back-end only).

       CAP_PROP_PTS = 71, //!<  (read-only) FFmpeg back-end only - presentation timestamp of the most recently read frame using the FPS time base.  e.g. fps = 25, VideoCapture::get(\ref CAP_PROP_PTS) = 3, presentation time = 3/25 seconds.

       CAP_PROP_DTS_DELAY = 72, //!<  (read-only) FFmpeg back-end only - maximum difference between presentation (pts) and decompression timestamps (dts) using FPS time base.  e.g. delay is maximum when frame_num = 0, if true, VideoCapture::get(\ref CAP_PROP_PTS) = 0 and VideoCapture::get(\ref CAP_PROP_DTS_DELAY) = 2, dts = -2.  Non zero values usually imply the stream is encoded using B-frames which are not decoded in presentation order.

#ifndef CV_DOXYGEN

       CV__CAP_PROP_LATEST

#endif

     };

/** @brief cv::VideoWriter generic properties identifier.

 @sa VideoWriter::get(), VideoWriter::set()

*/

enum VideoWriterProperties {

  VIDEOWRITER_PROP_QUALITY = 1,    //!< Current quality (0..100%) of the encoded videostream. Can be adjusted dynamically in some codecs.

  VIDEOWRITER_PROP_FRAMEBYTES = 2, //!< (Read-only): Size of just encoded video frame. Note that the encoding order may be different from representation order.

  VIDEOWRITER_PROP_NSTRIPES = 3,   //!< Number of stripes for parallel encoding. -1 for auto detection.

  VIDEOWRITER_PROP_IS_COLOR = 4,   //!< If it is not zero, the encoder will expect and encode color frames, otherwise it

                                   //!< will work with grayscale frames.

  VIDEOWRITER_PROP_DEPTH = 5,      //!< Defaults to \ref CV_8U.

  VIDEOWRITER_PROP_HW_ACCELERATION = 6, //!< (**open-only**) Hardware acceleration type (see #VideoAccelerationType). Setting supported only via `params` parameter in VideoWriter constructor / .open() method. Default value is backend-specific.

  VIDEOWRITER_PROP_HW_DEVICE       = 7, //!< (**open-only**) Hardware device index (select GPU if multiple available). Device enumeration is acceleration type specific.

  VIDEOWRITER_PROP_HW_ACCELERATION_USE_OPENCL= 8, //!< (**open-only**) If non-zero, create new OpenCL context and bind it to current thread. The OpenCL context created with Video Acceleration context attached it (if not attached yet) for optimized GPU data copy between cv::UMat and HW accelerated encoder.

  VIDEOWRITER_PROP_RAW_VIDEO = 9, //!< (**open-only**) Set to non-zero to enable encapsulation of an encoded raw video stream. Each raw encoded video frame should be passed to VideoWriter::write() as single row or column of a \ref CV_8UC1 Mat. \note If the key frame interval is not 1 then it must be manually specified by the user. This can either be performed during initialization passing \ref VIDEOWRITER_PROP_KEY_INTERVAL as one of the extra encoder params  to \ref VideoWriter::VideoWriter(const String &, int, double, const Size &, const std::vector< int > &params) or afterwards by setting the \ref VIDEOWRITER_PROP_KEY_FLAG with \ref VideoWriter::set() before writing each frame. FFMpeg backend only.

  VIDEOWRITER_PROP_KEY_INTERVAL = 10, //!< (**open-only**) Set the key frame interval using raw video encapsulation (\ref VIDEOWRITER_PROP_RAW_VIDEO != 0). Defaults to 1 when not set. FFmpeg back-end only.

  VIDEOWRITER_PROP_KEY_FLAG = 11, //!< Set to non-zero to signal that the following frames are key frames or zero if not, when encapsulating raw video (\ref VIDEOWRITER_PROP_RAW_VIDEO != 0). FFmpeg back-end only.

  VIDEOWRITER_PROP_PTS = 12, //!< Specifies the frame presentation timestamp for each frame using the FPS time base. This property is **only** necessary when encapsulating **externally** encoded video where the decoding order differs from the presentation order, such as in GOP patterns with bi-directional B-frames. The value should be provided by your external encoder and for video sources with fixed frame rates it is equivalent to dividing the current frame's presentation time (\ref CAP_PROP_POS_MSEC) by the frame duration (1000.0 / VideoCapture::get(\ref CAP_PROP_FPS)). It can be queried from the resulting encapsulated video file using VideoCapture::get(\ref CAP_PROP_PTS). FFmpeg back-end only.

  VIDEOWRITER_PROP_DTS_DELAY = 13, //!< Specifies the maximum difference between presentation (pts) and decompression timestamps (dts) using the FPS time base. This property is necessary **only** when encapsulating **externally** encoded video where the decoding order differs from the presentation order, such as in GOP patterns with bi-directional B-frames. The value should be calculated based on the specific GOP pattern used during encoding. For example, in a GOP with presentation order IBP and decoding order IPB, this value would be 1, as the B-frame is the second frame presented but the third to be decoded. It can be queried from the resulting encapsulated video file using VideoCapture::get(\ref CAP_PROP_DTS_DELAY). Non-zero values usually imply the stream is encoded using B-frames. FFmpeg back-end only.

#ifndef CV_DOXYGEN

  CV__VIDEOWRITER_PROP_LATEST

#endif

};

//! @} videoio_flags_base

//! @addtogroup videoio_flags_others

//! @{

/** @name Hardware acceleration support

    @{

*/

/** @brief Video Acceleration type

 *

 * Used as value in #CAP_PROP_HW_ACCELERATION and #VIDEOWRITER_PROP_HW_ACCELERATION

 *

 * @note In case of FFmpeg backend, it translated to enum AVHWDeviceType (https://github.com/FFmpeg/FFmpeg/blob/master/libavutil/hwcontext.h)

 */

enum VideoAccelerationType

{

    VIDEO_ACCELERATION_NONE     =  0,  //!< Do not require any specific H/W acceleration, prefer software processing.

                                       //!< Reading of this value means that special H/W accelerated handling is not added or not detected by OpenCV.

    VIDEO_ACCELERATION_ANY      =  1,  //!< Prefer to use H/W acceleration. If no one supported, then fallback to software processing.

                                       //!< @note H/W acceleration may require special configuration of used environment.

                                       //!< @note Results in encoding scenario may differ between software and hardware accelerated encoders.

    VIDEO_ACCELERATION_D3D11    =  2,  //!< DirectX 11

    VIDEO_ACCELERATION_VAAPI    =  3,  //!< VAAPI

    VIDEO_ACCELERATION_MFX      =  4,  //!< libmfx (Intel MediaSDK/oneVPL)

    VIDEO_ACCELERATION_DRM       =  5,  //!< Raspberry Pi V4

};

//! @} Hardware acceleration support

/** @name IEEE 1394 drivers

    @{

*/

/** @brief Modes of the IEEE 1394 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

     };

//! @} IEEE 1394 drivers

/** @name OpenNI (for Kinect)

    @{

*/

//! OpenNI map generators

enum { CAP_OPENNI_DEPTH_GENERATOR = 1 << 31,

       CAP_OPENNI_IMAGE_GENERATOR = 1 << 30,

       CAP_OPENNI_IR_GENERATOR    = 1 << 29,

       CAP_OPENNI_GENERATORS_MASK = CAP_OPENNI_DEPTH_GENERATOR + CAP_OPENNI_IMAGE_GENERATOR + CAP_OPENNI_IR_GENERATOR

     };

//! Properties of cameras available through OpenNI backend

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

     };

#ifdef _MSC_VER

#pragma warning( push )

#pragma warning( disable: 5054 )

#endif

//! OpenNI shortcuts

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_PRESENT         = +CAP_OPENNI_DEPTH_GENERATOR + CAP_PROP_OPENNI_GENERATOR_PRESENT,

       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,

       CAP_OPENNI_IR_GENERATOR_PRESENT            = +CAP_OPENNI_IR_GENERATOR + CAP_PROP_OPENNI_GENERATOR_PRESENT

     };

#ifdef _MSC_VER

#pragma warning( pop )

#endif

//! 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

       CAP_OPENNI_BGR_IMAGE         = 5, //!< Data given from RGB image generator

       CAP_OPENNI_GRAY_IMAGE        = 6, //!< Data given from RGB image generator

       CAP_OPENNI_IR_IMAGE          = 7  //!< Data given from IR image generator

     };

//! 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

     };

//! @} OpenNI

/** @name GStreamer

    @{

*/

enum { CAP_PROP_GSTREAMER_QUEUE_LENGTH = 200 //!< Default is 1

     };

//! @} GStreamer

/** @name PvAPI, Prosilica GigE SDK

    @{

*/

//! PVAPI

enum { CAP_PROP_PVAPI_MULTICASTIP           = 300, //!< IP for enable 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

     };

//! @} PvAPI

/** @name XIMEA Camera API

    @{

*/

//! Properties of cameras available through XIMEA SDK backend

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.

       CAP_PROP_XI_EXPOSURE                                     = 421, //!< Exposure time in microseconds.

       CAP_PROP_XI_EXPOSURE_BURST_COUNT                         = 422, //!< Sets the number of times of exposure in one frame.

       CAP_PROP_XI_GAIN_SELECTOR                                = 423, //!< Gain selector for parameter Gain allows to select different type of gains.

       CAP_PROP_XI_GAIN                                         = 424, //!< Gain in dB.

       CAP_PROP_XI_DOWNSAMPLING_TYPE                            = 426, //!< Change image downsampling type.

       CAP_PROP_XI_BINNING_SELECTOR                             = 427, //!< Binning engine selector.

       CAP_PROP_XI_BINNING_VERTICAL                             = 428, //!< Vertical Binning - number of vertical photo-sensitive cells to combine together.

       CAP_PROP_XI_BINNING_HORIZONTAL                           = 429, //!< Horizontal Binning - number of horizontal photo-sensitive cells to combine together.

       CAP_PROP_XI_BINNING_PATTERN                              = 430, //!< Binning pattern type.

       CAP_PROP_XI_DECIMATION_SELECTOR                          = 431, //!< Decimation engine selector.

       CAP_PROP_XI_DECIMATION_VERTICAL                          = 432, //!< Vertical Decimation - vertical sub-sampling of the image - reduces the vertical resolution of the image by the specified vertical decimation factor.

       CAP_PROP_XI_DECIMATION_HORIZONTAL                        = 433, //!< Horizontal Decimation - horizontal sub-sampling of the image - reduces the horizontal resolution of the image by the specified vertical decimation factor.

       CAP_PROP_XI_DECIMATION_PATTERN                           = 434, //!< Decimation pattern type.

       CAP_PROP_XI_TEST_PATTERN_GENERATOR_SELECTOR              = 587, //!< Selects which test pattern generator is controlled by the TestPattern feature.

       CAP_PROP_XI_TEST_PATTERN                                 = 588, //!< Selects which test pattern type is generated by the selected generator.

       CAP_PROP_XI_IMAGE_DATA_FORMAT                            = 435, //!< Output data format.

       CAP_PROP_XI_SHUTTER_TYPE                                 = 436, //!< Change sensor shutter type(CMOS sensor).

       CAP_PROP_XI_SENSOR_TAPS                                  = 437, //!< Number of taps.

       CAP_PROP_XI_AEAG_ROI_OFFSET_X                            = 439, //!< Automatic exposure/gain ROI offset X.

       CAP_PROP_XI_AEAG_ROI_OFFSET_Y                            = 440, //!< Automatic exposure/gain ROI offset Y.

       CAP_PROP_XI_AEAG_ROI_WIDTH                               = 441, //!< Automatic exposure/gain ROI Width.

       CAP_PROP_XI_AEAG_ROI_HEIGHT                              = 442, //!< Automatic exposure/gain ROI Height.

       CAP_PROP_XI_BPC                                          = 445, //!< Correction of bad pixels.

       CAP_PROP_XI_WB_KR                                        = 448, //!< White balance red coefficient.

       CAP_PROP_XI_WB_KG                                        = 449, //!< White balance green coefficient.

       CAP_PROP_XI_WB_KB                                        = 450, //!< White balance blue coefficient.

       CAP_PROP_XI_WIDTH                                        = 451, //!< Width of the Image provided by the device (in pixels).

       CAP_PROP_XI_HEIGHT                                       = 452, //!< Height of the Image provided by the device (in pixels).

       CAP_PROP_XI_REGION_SELECTOR                              = 589, //!< Selects Region in Multiple ROI which parameters are set by width, height, ... ,region mode.

       CAP_PROP_XI_REGION_MODE                                  = 595, //!< Activates/deactivates Region selected by Region Selector.

       CAP_PROP_XI_LIMIT_BANDWIDTH                              = 459, //!< Set/get bandwidth(datarate)(in Megabits).

       CAP_PROP_XI_SENSOR_DATA_BIT_DEPTH                        = 460, //!< Sensor output data bit depth.

       CAP_PROP_XI_OUTPUT_DATA_BIT_DEPTH                        = 461, //!< Device output data bit depth.

       CAP_PROP_XI_IMAGE_DATA_BIT_DEPTH                         = 462, //!< bitdepth of data returned by function xiGetImage.

       CAP_PROP_XI_OUTPUT_DATA_PACKING                          = 463, //!< Device output data packing (or grouping) enabled. Packing could be enabled if output_data_bit_depth > 8 and packing capability is available.

       CAP_PROP_XI_OUTPUT_DATA_PACKING_TYPE                     = 464, //!< Data packing type. Some cameras supports only specific packing type.

       CAP_PROP_XI_IS_COOLED                                    = 465, //!< Returns 1 for cameras that support cooling.

       CAP_PROP_XI_COOLING                                      = 466, //!< Start camera cooling.

       CAP_PROP_XI_TARGET_TEMP                                  = 467, //!< Set sensor target temperature for cooling.

       CAP_PROP_XI_CHIP_TEMP                                    = 468, //!< Camera sensor temperature.

       CAP_PROP_XI_HOUS_TEMP                                    = 469, //!< Camera housing temperature.

       CAP_PROP_XI_HOUS_BACK_SIDE_TEMP                          = 590, //!< Camera housing back side temperature.

       CAP_PROP_XI_SENSOR_BOARD_TEMP                            = 596, //!< Camera sensor board temperature.

       CAP_PROP_XI_CMS                                          = 470, //!< Mode of color management system.

       CAP_PROP_XI_APPLY_CMS                                    = 471, //!< Enable applying of CMS profiles to xiGetImage (see XI_PRM_INPUT_CMS_PROFILE, XI_PRM_OUTPUT_CMS_PROFILE).

       CAP_PROP_XI_IMAGE_IS_COLOR                               = 474, //!< Returns 1 for color cameras.

       CAP_PROP_XI_COLOR_FILTER_ARRAY                           = 475, //!< Returns color filter array type of RAW data.

       CAP_PROP_XI_GAMMAY                                       = 476, //!< Luminosity gamma.

       CAP_PROP_XI_GAMMAC                                       = 477, //!< Chromaticity gamma.

       CAP_PROP_XI_SHARPNESS                                    = 478, //!< Sharpness Strength.

       CAP_PROP_XI_CC_MATRIX_00                                 = 479, //!< Color Correction Matrix element [0][0].

       CAP_PROP_XI_CC_MATRIX_01                                 = 480, //!< Color Correction Matrix element [0][1].

       CAP_PROP_XI_CC_MATRIX_02                                 = 481, //!< Color Correction Matrix element [0][2].

       CAP_PROP_XI_CC_MATRIX_03                                 = 482, //!< Color Correction Matrix element [0][3].

       CAP_PROP_XI_CC_MATRIX_10                                 = 483, //!< Color Correction Matrix element [1][0].

       CAP_PROP_XI_CC_MATRIX_11                                 = 484, //!< Color Correction Matrix element [1][1].

       CAP_PROP_XI_CC_MATRIX_12                                 = 485, //!< Color Correction Matrix element [1][2].

       CAP_PROP_XI_CC_MATRIX_13                                 = 486, //!< Color Correction Matrix element [1][3].

       CAP_PROP_XI_CC_MATRIX_20                                 = 487, //!< Color Correction Matrix element [2][0].

       CAP_PROP_XI_CC_MATRIX_21                                 = 488, //!< Color Correction Matrix element [2][1].

       CAP_PROP_XI_CC_MATRIX_22                                 = 489, //!< Color Correction Matrix element [2][2].

       CAP_PROP_XI_CC_MATRIX_23                                 = 490, //!< Color Correction Matrix element [2][3].

       CAP_PROP_XI_CC_MATRIX_30                                 = 491, //!< Color Correction Matrix element [3][0].

       CAP_PROP_XI_CC_MATRIX_31                                 = 492, //!< Color Correction Matrix element [3][1].

       CAP_PROP_XI_CC_MATRIX_32                                 = 493, //!< Color Correction Matrix element [3][2].

       CAP_PROP_XI_CC_MATRIX_33                                 = 494, //!< Color Correction Matrix element [3][3].

       CAP_PROP_XI_DEFAULT_CC_MATRIX                            = 495, //!< Set default Color Correction Matrix.

       CAP_PROP_XI_TRG_SELECTOR                                 = 498, //!< Selects the type of trigger.

       CAP_PROP_XI_ACQ_FRAME_BURST_COUNT                        = 499, //!< Sets number of frames acquired by burst. This burst is used only if trigger is set to FrameBurstStart.

       CAP_PROP_XI_DEBOUNCE_EN                                  = 507, //!< Enable/Disable debounce to selected GPI.

       CAP_PROP_XI_DEBOUNCE_T0                                  = 508, //!< Debounce time (x * 10us).

       CAP_PROP_XI_DEBOUNCE_T1                                  = 509, //!< Debounce time (x * 10us).

       CAP_PROP_XI_DEBOUNCE_POL                                 = 510, //!< Debounce polarity (pol = 1 t0 - falling edge, t1 - rising edge).

       CAP_PROP_XI_LENS_MODE                                    = 511, //!< Status of lens control interface. This shall be set to XI_ON before any Lens operations.

       CAP_PROP_XI_LENS_APERTURE_VALUE                          = 512, //!< Current lens aperture value in stops. Examples: 2.8, 4, 5.6, 8, 11.

       CAP_PROP_XI_LENS_FOCUS_MOVEMENT_VALUE                    = 513, //!< Lens current focus movement value to be used by XI_PRM_LENS_FOCUS_MOVE in motor steps.

       CAP_PROP_XI_LENS_FOCUS_MOVE                              = 514, //!< Moves lens focus motor by steps set in XI_PRM_LENS_FOCUS_MOVEMENT_VALUE.

       CAP_PROP_XI_LENS_FOCUS_DISTANCE                          = 515, //!< Lens focus distance in cm.

       CAP_PROP_XI_LENS_FOCAL_LENGTH                            = 516, //!< Lens focal distance in mm.

       CAP_PROP_XI_LENS_FEATURE_SELECTOR                        = 517, //!< Selects the current feature which is accessible by XI_PRM_LENS_FEATURE.

       CAP_PROP_XI_LENS_FEATURE                                 = 518, //!< Allows access to lens feature value currently selected by XI_PRM_LENS_FEATURE_SELECTOR.

       CAP_PROP_XI_DEVICE_MODEL_ID                              = 521, //!< Returns device model id.

       CAP_PROP_XI_DEVICE_SN                                    = 522, //!< Returns device serial number.

       CAP_PROP_XI_IMAGE_DATA_FORMAT_RGB32_ALPHA                = 529, //!< The alpha channel of RGB32 output image format.

       CAP_PROP_XI_IMAGE_PAYLOAD_SIZE                           = 530, //!< Buffer size in bytes sufficient for output image returned by xiGetImage.

       CAP_PROP_XI_TRANSPORT_PIXEL_FORMAT                       = 531, //!< Current format of pixels on transport layer.

       CAP_PROP_XI_SENSOR_CLOCK_FREQ_HZ                         = 532, //!< Sensor clock frequency in Hz.

       CAP_PROP_XI_SENSOR_CLOCK_FREQ_INDEX                      = 533, //!< Sensor clock frequency index. Sensor with selected frequencies have possibility to set the frequency only by this index.

       CAP_PROP_XI_SENSOR_OUTPUT_CHANNEL_COUNT                  = 534, //!< Number of output channels from sensor used for data transfer.

       CAP_PROP_XI_FRAMERATE                                    = 535, //!< Define framerate in Hz.

       CAP_PROP_XI_COUNTER_SELECTOR                             = 536, //!< Select counter.

       CAP_PROP_XI_COUNTER_VALUE                                = 537, //!< Counter status.

       CAP_PROP_XI_ACQ_TIMING_MODE                              = 538, //!< Type of sensor frames timing.

       CAP_PROP_XI_AVAILABLE_BANDWIDTH                          = 539, //!< Calculate and returns available interface bandwidth(int Megabits).

       CAP_PROP_XI_BUFFER_POLICY                                = 540, //!< Data move policy.

       CAP_PROP_XI_LUT_EN                                       = 541, //!< Activates LUT.

       CAP_PROP_XI_LUT_INDEX                                    = 542, //!< Control the index (offset) of the coefficient to access in the LUT.

       CAP_PROP_XI_LUT_VALUE                                    = 543, //!< Value at entry LUTIndex of the LUT.

       CAP_PROP_XI_TRG_DELAY                                    = 544, //!< Specifies the delay in microseconds (us) to apply after the trigger reception before activating it.

       CAP_PROP_XI_TS_RST_MODE                                  = 545, //!< Defines how time stamp reset engine will be armed.

       CAP_PROP_XI_TS_RST_SOURCE                                = 546, //!< Defines which source will be used for timestamp reset. Writing this parameter will trigger settings of engine (arming).

       CAP_PROP_XI_IS_DEVICE_EXIST                              = 547, //!< Returns 1 if camera connected and works properly.

       CAP_PROP_XI_ACQ_BUFFER_SIZE                              = 548, //!< Acquisition buffer size in buffer_size_unit. Default bytes.

       CAP_PROP_XI_ACQ_BUFFER_SIZE_UNIT                         = 549, //!< Acquisition buffer size unit in bytes. Default 1. E.g. Value 1024 means that buffer_size is in KiBytes.

       CAP_PROP_XI_ACQ_TRANSPORT_BUFFER_SIZE                    = 550, //!< Acquisition transport buffer size in bytes.

       CAP_PROP_XI_BUFFERS_QUEUE_SIZE                           = 551, //!< Queue of field/frame buffers.

       CAP_PROP_XI_ACQ_TRANSPORT_BUFFER_COMMIT                  = 552, //!< Number of buffers to commit to low level.

       CAP_PROP_XI_RECENT_FRAME                                 = 553, //!< GetImage returns most recent frame.

       CAP_PROP_XI_DEVICE_RESET                                 = 554, //!< Resets the camera to default state.

       CAP_PROP_XI_COLUMN_FPN_CORRECTION                        = 555, //!< Correction of column FPN.

       CAP_PROP_XI_ROW_FPN_CORRECTION                           = 591, //!< Correction of row FPN.

       CAP_PROP_XI_SENSOR_MODE                                  = 558, //!< Current sensor mode. Allows to select sensor mode by one integer. Setting of this parameter affects: image dimensions and downsampling.

       CAP_PROP_XI_HDR                                          = 559, //!< Enable High Dynamic Range feature.

       CAP_PROP_XI_HDR_KNEEPOINT_COUNT                          = 560, //!< The number of kneepoints in the PWLR.

       CAP_PROP_XI_HDR_T1                                       = 561, //!< Position of first kneepoint(in % of XI_PRM_EXPOSURE).

       CAP_PROP_XI_HDR_T2                                       = 562, //!< Position of second kneepoint (in % of XI_PRM_EXPOSURE).

       CAP_PROP_XI_KNEEPOINT1                                   = 563, //!< Value of first kneepoint (% of sensor saturation).

       CAP_PROP_XI_KNEEPOINT2                                   = 564, //!< Value of second kneepoint (% of sensor saturation).

       CAP_PROP_XI_IMAGE_BLACK_LEVEL                            = 565, //!< Last image black level counts. Can be used for Offline processing to recall it.

       CAP_PROP_XI_HW_REVISION                                  = 571, //!< Returns hardware revision number.

       CAP_PROP_XI_DEBUG_LEVEL                                  = 572, //!< Set debug level.

       CAP_PROP_XI_AUTO_BANDWIDTH_CALCULATION                   = 573, //!< Automatic bandwidth calculation.

       CAP_PROP_XI_FFS_FILE_ID                                  = 594, //!< File number.

       CAP_PROP_XI_FFS_FILE_SIZE                                = 580, //!< Size of file.

       CAP_PROP_XI_FREE_FFS_SIZE                                = 581, //!< Size of free camera FFS.

       CAP_PROP_XI_USED_FFS_SIZE                                = 582, //!< Size of used camera FFS.

       CAP_PROP_XI_FFS_ACCESS_KEY                               = 583, //!< Setting of key enables file operations on some cameras.

       CAP_PROP_XI_SENSOR_FEATURE_SELECTOR                      = 585, //!< Selects the current feature which is accessible by XI_PRM_SENSOR_FEATURE_VALUE.

       CAP_PROP_XI_SENSOR_FEATURE_VALUE                         = 586, //!< Allows access to sensor feature value currently selected by XI_PRM_SENSOR_FEATURE_SELECTOR.

     };

//! @} XIMEA

/** @name ARAVIS Camera API

    @{

*/

//! Properties of cameras available through ARAVIS backend

enum { CAP_PROP_ARAVIS_AUTOTRIGGER                              = 600 //!< Automatically trigger frame capture if camera is configured with software trigger

};

//! @} ARAVIS

/** @name Android

    @{

*/

//! Properties of cameras available through NDK Camera API backend

enum { CAP_PROP_ANDROID_DEVICE_TORCH = 8001,

     };

//! @} Android

/** @name AVFoundation framework for iOS

    @{

*/

//! Properties of cameras available through AVFOUNDATION backend

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

     };

//! @} AVFoundation framework for iOS

/** @name Smartek Giganetix GigEVisionSDK

    @{

*/

//! Properties of cameras available through Smartek Giganetix Ethernet Vision backend

/* --- 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

     };

//! @} Smartek

/** @name Intel Perceptual Computing SDK

    @{

*/

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 Perceptual Streams

enum { CAP_INTELPERC_DEPTH_GENERATOR = 1 << 29,

       CAP_INTELPERC_IMAGE_GENERATOR = 1 << 28,

       CAP_INTELPERC_IR_GENERATOR    = 1 << 27,

       CAP_INTELPERC_GENERATORS_MASK = CAP_INTELPERC_DEPTH_GENERATOR + CAP_INTELPERC_IMAGE_GENERATOR + CAP_INTELPERC_IR_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

     };

//! @} Intel Perceptual

/** @name gPhoto2 connection

    @{

*/

/** @brief gPhoto2 properties

If `propertyId` is less than 0 then work on widget with that __additive inversed__ camera setting ID

Get IDs by using CAP_PROP_GPHOTO2_WIDGET_ENUMERATE.

@see CvCaptureCAM_GPHOTO2 for more info

*/

enum { CAP_PROP_GPHOTO2_PREVIEW           = 17001, //!< Capture only preview from liveview mode.

       CAP_PROP_GPHOTO2_WIDGET_ENUMERATE  = 17002, //!< Readonly, returns (const char *).

       CAP_PROP_GPHOTO2_RELOAD_CONFIG     = 17003, //!< Trigger, only by set. Reload camera settings.

       CAP_PROP_GPHOTO2_RELOAD_ON_CHANGE  = 17004, //!< Reload all settings on set.

       CAP_PROP_GPHOTO2_COLLECT_MSGS      = 17005, //!< Collect messages with details.

       CAP_PROP_GPHOTO2_FLUSH_MSGS        = 17006, //!< Readonly, returns (const char *).

       CAP_PROP_SPEED                     = 17007, //!< Exposure speed. Can be readonly, depends on camera program.

       CAP_PROP_APERTURE                  = 17008, //!< Aperture. Can be readonly, depends on camera program.

       CAP_PROP_EXPOSUREPROGRAM           = 17009, //!< Camera exposure program.

       CAP_PROP_VIEWFINDER                = 17010  //!< Enter liveview mode.

     };

//! @} gPhoto2

/** @name Images backend

    @{

*/

/** @brief Images backend properties

*/

enum { CAP_PROP_IMAGES_BASE = 18000,

       CAP_PROP_IMAGES_LAST = 19000 // excluding

     };

//! @} Images

/** @name OBSENSOR (for Orbbec 3D-Sensor device/module )

    @{

*/

//! OBSENSOR data given from image generator

enum VideoCaptureOBSensorDataType{

    CAP_OBSENSOR_DEPTH_MAP = 0, //!< Depth values in mm (CV_16UC1)

    CAP_OBSENSOR_BGR_IMAGE = 1, //!< Data given from BGR stream generator

    CAP_OBSENSOR_IR_IMAGE = 2   //!< Data given from IR stream generator(CV_16UC1)

};

//! OBSENSOR stream generator

enum VideoCaptureOBSensorGenerators{

    CAP_OBSENSOR_DEPTH_GENERATOR = 1 << 29,

    CAP_OBSENSOR_IMAGE_GENERATOR = 1 << 28,

    CAP_OBSENSOR_IR_GENERATOR    = 1 << 27,

    CAP_OBSENSOR_GENERATORS_MASK = CAP_OBSENSOR_DEPTH_GENERATOR + CAP_OBSENSOR_IMAGE_GENERATOR + CAP_OBSENSOR_IR_GENERATOR

};

//!OBSENSOR properties

enum VideoCaptureOBSensorProperties{

    // INTRINSIC

    CAP_PROP_OBSENSOR_INTRINSIC_FX=26001,

    CAP_PROP_OBSENSOR_INTRINSIC_FY=26002,

    CAP_PROP_OBSENSOR_INTRINSIC_CX=26003,

    CAP_PROP_OBSENSOR_INTRINSIC_CY=26004,

};

//! @} OBSENSOR

//! @} videoio_flags_others

/** @brief Read data stream interface

 */

class CV_EXPORTS_W IStreamReader

{

public:

    virtual ~IStreamReader();

    /** @brief Read bytes from stream

     *

     * @param buffer already allocated buffer of at least @p size bytes

     * @param size maximum number of bytes to read

     *

     * @return actual number of read bytes

     */

    CV_WRAP virtual long long read(char* buffer, long long size) = 0;

    /** @brief Sets the stream position

     *

     * @param offset Seek offset

     * @param origin SEEK_SET / SEEK_END / SEEK_CUR

     *

     * @see fseek

     */

    CV_WRAP virtual long long seek(long long offset, int origin) = 0;

};

class IVideoCapture;

//! @cond IGNORED

namespace internal { class VideoCapturePrivateAccessor; }

//! @endcond IGNORED

/** @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:

@include samples/cpp/videocapture_basic.cpp

@note In @ref videoio_c "C API" the black-box structure `CvCapture` is used instead of %VideoCapture.

@note

-   (C++) A basic sample on using the %VideoCapture interface can be found at

    `OPENCV_SOURCE_CODE/samples/cpp/videocapture_starter.cpp`

-   (Python) A basic sample on using the %VideoCapture interface can be found at

    `OPENCV_SOURCE_CODE/samples/python/video.py`

-   (Python) A multi threaded video processing sample can be found at

    `OPENCV_SOURCE_CODE/samples/python/video_threaded.py`

-   (Python) %VideoCapture sample showcasing some features of the Video4Linux2 backend

    `OPENCV_SOURCE_CODE/samples/python/video_v4l2.py`

 */

class CV_EXPORTS_W VideoCapture

{

public:

    /** @brief Default constructor

    @note In @ref videoio_c "C API", when you finished working with video, release CvCapture structure with

    cvReleaseCapture(), or use Ptr\<CvCapture\> that calls cvReleaseCapture() automatically in the

    destructor.

     */

    CV_WRAP VideoCapture();

    /** @overload

    @brief  Opens a video file or a capturing device or an IP video stream for video capturing with API Preference

    @param filename it can be:

    - name of 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, ...`)

    - or URL of video stream (eg. `protocol://host:port/script_name?script_params|auth`)

    - or GStreamer pipeline string in gst-launch tool format in case if GStreamer is used as backend

      Note that each video stream or IP camera feed has its own URL scheme. Please refer to the

      documentation of source stream to know the right URL.

    @param apiPreference preferred Capture API backends to use. Can be used to enforce a specific reader

    implementation if multiple are available: e.g. cv::CAP_FFMPEG or cv::CAP_IMAGES or cv::CAP_DSHOW.

    @sa cv::VideoCaptureAPIs

    */

    CV_WRAP explicit VideoCapture(const String& filename, int apiPreference = CAP_ANY);

    /** @overload

    @brief Opens a video file or a capturing device or an IP video stream for video capturing with API Preference and parameters

    The `params` parameter allows to specify extra parameters encoded as pairs `(paramId_1, paramValue_1, paramId_2, paramValue_2, ...)`.

    See cv::VideoCaptureProperties

    */

    CV_WRAP explicit VideoCapture(const String& filename, int apiPreference, const std::vector<int>& params);

    /** @overload

    @brief  Opens a camera for video capturing

    @param index id of the video capturing device to open. To open default camera using default backend just pass 0.

    (to backward compatibility usage of camera_id + domain_offset (CAP_*) is valid when apiPreference is CAP_ANY)

    @param apiPreference preferred Capture API backends to use. Can be used to enforce a specific reader

    implementation if multiple are available: e.g. cv::CAP_DSHOW or cv::CAP_MSMF or cv::CAP_V4L.

    @sa cv::VideoCaptureAPIs

    */

    CV_WRAP explicit VideoCapture(int index, int apiPreference = CAP_ANY);

    /** @overload

    @brief Opens a camera for video capturing with API Preference and parameters

    The `params` parameter allows to specify extra parameters encoded as pairs `(paramId_1, paramValue_1, paramId_2, paramValue_2, ...)`.

    See cv::VideoCaptureProperties

    */

    CV_WRAP explicit VideoCapture(int index, int apiPreference, const std::vector<int>& params);

    /** @overload

    @brief Opens a video using data stream.

    The `params` parameter allows to specify extra parameters encoded as pairs `(paramId_1, paramValue_1, paramId_2, paramValue_2, ...)`.

    See cv::VideoCaptureProperties

    */

    CV_WRAP VideoCapture(const Ptr<IStreamReader>& source, int apiPreference, const std::vector<int>& params);

    /** @brief Default destructor

    The method first calls VideoCapture::release to close the already opened file or camera.

    */

    virtual ~VideoCapture();

    /** @brief  Opens a video file or a capturing device or an IP video stream for video capturing.

    @overload

    Parameters are same as the constructor VideoCapture(const String& filename, int apiPreference = CAP_ANY)

    @return `true` if the file has been successfully opened

    The method first calls VideoCapture::release to close the already opened file or camera.

     */

    CV_WRAP virtual bool open(const String& filename, int apiPreference = CAP_ANY);

    /** @brief  Opens a video file or a capturing device or an IP video stream for video capturing with API Preference and parameters

    @overload

    The `params` parameter allows to specify extra parameters encoded as pairs `(paramId_1, paramValue_1, paramId_2, paramValue_2, ...)`.

    See cv::VideoCaptureProperties

    @return `true` if the file has been successfully opened

    The method first calls VideoCapture::release to close the already opened file or camera.

     */

    CV_WRAP virtual bool open(const String& filename, int apiPreference, const std::vector<int>& params);

    /** @brief  Opens a camera for video capturing

    @overload

    Parameters are same as the constructor VideoCapture(int index, int apiPreference = CAP_ANY)

    @return `true` if the camera has been successfully opened.

    The method first calls VideoCapture::release to close the already opened file or camera.

    */

    CV_WRAP virtual bool open(int index, int apiPreference = CAP_ANY);

    /** @brief  Opens a camera for video capturing with API Preference and parameters

    @overload

    The `params` parameter allows to specify extra parameters encoded as pairs `(paramId_1, paramValue_1, paramId_2, paramValue_2, ...)`.

    See cv::VideoCaptureProperties

    @return `true` if the camera has been successfully opened.

    The method first calls VideoCapture::release to close the already opened file or camera.

    */

    CV_WRAP virtual bool open(int index, int apiPreference, const std::vector<int>& params);

    /** @brief Opens a video using data stream.

    @overload

    The `params` parameter allows to specify extra parameters encoded as pairs `(paramId_1, paramValue_1, paramId_2, paramValue_2, ...)`.

    See cv::VideoCaptureProperties

    @return `true` if the file has been successfully opened

    The method first calls VideoCapture::release to close the already opened file or camera.

     */

    CV_WRAP virtual bool open(const Ptr<IStreamReader>& source, int apiPreference, const std::vector<int>& params);

    /** @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 method is 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.

    @return `true` (non-zero) in the case of success.

    The method/function grabs the next frame from video file or camera and returns 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.

    @ref tutorial_kinect_openni

     */

    CV_WRAP virtual bool grab();

    /** @brief Decodes and returns the grabbed video frame.

    @param [out] image the video frame is returned here. If no frames has been grabbed the image will be empty.

    @param flag it could be a frame index or a driver specific flag

    @return `false` if no frames has been grabbed

    The method decodes and returns the just grabbed frame. If no frames has been grabbed

    (camera has been disconnected, or there are no more frames in video file), the method returns false

    and the function returns an empty image (with %cv::Mat, test it with Mat::empty()).

    @sa read()

    @note In @ref videoio_c "C API", 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

    cvCloneImage and then do whatever you want with the copy.

     */

    CV_WRAP virtual bool retrieve(OutputArray image, int flag = 0);

    /** @brief Stream operator to read the next video frame.

    @sa read()

    */

    virtual VideoCapture& operator >> (CV_OUT Mat& image);

    /** @overload

    @sa read()

    */

    virtual VideoCapture& operator >> (CV_OUT UMat& image);

    /** @brief Grabs, decodes and returns the next video frame.

    @param [out] image the video frame is returned here. If no frames has been grabbed the image will be empty.

    @return `false` if no frames has been grabbed

    The method/function combines VideoCapture::grab() and VideoCapture::retrieve() in one call. This is the

    most convenient method for reading video files or capturing data from decode and returns the just

    grabbed frame. If no frames has been grabbed (camera has been disconnected, or there are no more

    frames in video file), the method returns false and the function returns empty image (with %cv::Mat, test it with Mat::empty()).

    @note In @ref videoio_c "C API", 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

    cvCloneImage 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 from cv::VideoCaptureProperties (eg. cv::CAP_PROP_POS_MSEC, cv::CAP_PROP_POS_FRAMES, ...)

    or one from @ref videoio_flags_others

    @param value Value of the property.

    @return `true` if the property is supported by backend used by the VideoCapture instance.

    @note Even if it returns `true` this doesn't ensure that the property

    value has been accepted by the capture device. See note in VideoCapture::get()

     */

    CV_WRAP virtual bool set(int propId, double value);

    /** @brief Returns the specified VideoCapture property

    @param propId Property identifier from cv::VideoCaptureProperties (eg. cv::CAP_PROP_POS_MSEC, cv::CAP_PROP_POS_FRAMES, ...)

    or one from @ref videoio_flags_others

    @return Value for the specified property. Value 0 is returned when querying a property that is

    not supported by the backend used by the VideoCapture instance.

    @note Reading / writing properties involves many layers. Some unexpected result might happens

    along this chain.

    @code{.txt}

    VideoCapture -> API Backend -> Operating System -> Device Driver -> Device Hardware

    @endcode

    The returned value might be different from what really used by the device or it could be encoded

    using device dependent rules (eg. steps or percentage). Effective behaviour depends from device

    driver and API Backend

    */

    CV_WRAP virtual double get(int propId) const;

    /** @brief Returns used backend API name

     @note Stream should be opened.

     */

    CV_WRAP String getBackendName() const;

    /** Switches exceptions mode

     *

     * methods raise exceptions if not successful instead of returning an error code

     */

    CV_WRAP void setExceptionMode(bool enable) { throwOnFail = enable; }

    /// query if exception mode is active

    CV_WRAP bool getExceptionMode() const { return throwOnFail; }

    /** @brief Wait for ready frames from VideoCapture.

    @param streams input video streams

    @param readyIndex stream indexes with grabbed frames (ready to use .retrieve() to fetch actual frame)

    @param timeoutNs number of nanoseconds (0 - infinite)

    @return `true` if streamReady is not empty

    @throws Exception %Exception on stream errors (check .isOpened() to filter out malformed streams) or VideoCapture type is not supported

    The primary use of the function is in multi-camera environments.

    The method fills the ready state vector, grabs video frame, if camera is ready.

    After this call use VideoCapture::retrieve() to decode and fetch frame data.

    */

    CV_WRAP static

    bool waitAny(

            const std::vector<VideoCapture>& streams,

            CV_OUT std::vector<int>& readyIndex,

            int64 timeoutNs = 0);

protected:

    Ptr<CvCapture> cap;

    Ptr<IVideoCapture> icap;

    bool throwOnFail;

    friend class internal::VideoCapturePrivateAccessor;

};

class IVideoWriter;

/** @example samples/cpp/tutorial_code/videoio/video-write/video-write.cpp

Check @ref tutorial_video_write "the corresponding tutorial" for more details

*/

/** @example samples/cpp/videowriter_basic.cpp

An example using VideoCapture and VideoWriter class

*/

/** @brief Video writer class.

The class provides C++ API for writing video files or image sequences.

*/

class CV_EXPORTS_W VideoWriter

{

public:

    /** @brief Default constructors

    The constructors/functions initialize video writers.

    -   On Linux FFMPEG is used to write videos;

    -   On Windows FFMPEG or MSWF or DSHOW is used;

    -   On MacOSX AVFoundation 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

    [MSDN](https://docs.microsoft.com/en-us/windows/win32/medfound/video-fourccs) page

    or with this [page](https://fourcc.org/codecs.php)

    of the fourcc site for a more complete list). FFMPEG backend with MP4 container natively uses

    other values as fourcc code: see [ObjectType](http://mp4ra.org/#/codecs),

    so you may receive a warning message from OpenCV about fourcc code conversion.

    @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.

    @b Tips:

    - With some backends `fourcc=-1` pops up the codec selection dialog from the system.

    - To save image sequence use a proper filename (eg. `img_%02d.jpg`) and `fourcc=0`

      OR `fps=0`. Use uncompressed image format (eg. `img_%02d.BMP`) to save raw frames.

    - Most codecs are lossy. If you want lossless video file you need to use a lossless codecs

      (eg. FFMPEG FFV1, Huffman HFYU, Lagarith LAGS, etc...)

    - If FFMPEG is enabled, using `codec=0; fps=0;` you can create an uncompressed (raw) video file.

    - If FFMPEG is used, we allow frames of odd width or height, but in this case we truncate

      the rightmost column/the bottom row. Probably, this should be handled more elegantly,

      but some internal functions inside FFMPEG swscale require even width/height.

    */

    CV_WRAP VideoWriter(const String& filename, int fourcc, double fps,

                Size frameSize, bool isColor = true);

    /** @overload

    The `apiPreference` parameter allows to specify API backends to use. Can be used to enforce a specific reader implementation

    if multiple are available: e.g. cv::CAP_FFMPEG or cv::CAP_GSTREAMER.

     */

    CV_WRAP VideoWriter(const String& filename, int apiPreference, int fourcc, double fps,

                Size frameSize, bool isColor = true);

    /** @overload

     * The `params` parameter allows to specify extra encoder parameters encoded as pairs (paramId_1, paramValue_1, paramId_2, paramValue_2, ... .)

     * see cv::VideoWriterProperties

     */

    CV_WRAP VideoWriter(const String& filename, int fourcc, double fps, const Size& frameSize,

                        const std::vector<int>& params);

    /** @overload

     */

    CV_WRAP VideoWriter(const String& filename, int apiPreference, int fourcc, double fps,

                        const Size& frameSize, const std::vector<int>& params);

    /** @brief Default destructor

    The method first calls VideoWriter::release to close the already opened file.

    */

    virtual ~VideoWriter();

    /** @brief Initializes or reinitializes video writer.

    The method opens video writer. Parameters are the same as in the constructor

    VideoWriter::VideoWriter.