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// This file is part of OpenCV project.
// It is subject to the license terms in the LICENSE file found in the top-level directory
// of this distribution and at http://opencv.org/license.html
#include "precomp.hpp"
/*
Media Foundation-based Video Capturing module is based on
videoInput library by Evgeny Pereguda:
http://www.codeproject.com/Articles/559437/Capturing-of-video-from-web-camera-on-Windows-7-an
Originally licensed under The Code Project Open License (CPOL) 1.02:
http://www.codeproject.com/info/cpol10.aspx
*/
Add support for WinRT in the MF capture framework by removing the disallowed calls to enumerate devices and create a sample grabber sink and adding framework for the MediaCapture interface and a custom sink which interfaces with the sample grabber callback interface. The change requires discussion for making it completely functional as redundancy is required given that if the source is a video file, the old code pathways must be used. Otherwise all IMFMediaSession, IMFMediaSource, and IMFActivate code must use a MediaCapture code path and all sink code must use the CMediaSink custom sink. Support for the custom sink is extended to non-WinRT not for compatibility as Windows Vista client is a minimum regardless, but because it offers more flexibility, could be faster and is able to be used as an optionally different code path during sink creation based on a future configuration parameter. My discussion and proposal to finish this change: Devices are so easily enumerated through WinRT Windows.Devices namespace that wrapping the calls in a library is quite a chore for little benefit though to get the various modes and formats could still be a worthwhile project. For now conditional compilation to remove videodevices and any offending non-video file related activity in videodevice. In my opinion, this is a different , far less fundamental and important change which can possibly be done as a future project and also much more easily implemented in C++/CX. ImageGrabber has the IMFSampleGrabberSinkCallback replaced with a base class (SharedSampleGrabber) which also be is base class for ImageGrabberRT. This change is necessary as the custom sink does not require a thread to pump events which is done through MediaCapture already. IMFSampleGrabberSinkCallback is the common element between both models and that piece can be shared. Initializing the new ImageGrabberRT is as simple as passing an already initialized MediaCapture object and any video format/encoding parameters. The concurrency event is necessary to wait for completion and is the way the underlying, IAsyncAction wrappers in the task library work as well. Native WIN32 event objects would be an option if HAVE_CONCURRENCY is not defined. I could even imagine doing it with sleep/thread yield and InterlockedCompareExchange yet I am not enthusiastic about that approach either. Since there is a specific compiler HAVE_ for concurrency, I do not like pulling it in though I think for WinRT it is safe to say we will always have it available though should probably conditionally compile with the Interlocked option as WIN32 events would require HAVE_WIN32. It looks like C++/CX cannot be used for the IMediaExtension sink (which should not be a problem) as using COM objects requires WRL and though deriving from IMediaExtension can be done, there is little purpose without COM. Objects from C++/CX can be swapped to interact with objects from native C++ as Inspectable* can reinterpret_cast to the ref object IInspectable^ and vice-versa. A solution to the COM class with C++/CX would be great so we could have dual support. Also without #define for every WRL object in use, the code will get quite muddy given that the */^ would need to be ifdef'd everywhere. Fixed bugs and completed the change. I believe the new classes need to be moved to a header file as the file has become to large and more classes need to be added for handling all the asynchronous problems (one wrapping IAsyncAction in a task and another for making a task out of IAsyncAction). Unfortunately, blocking on the UI thread is not an option in WinRT so a synchronous architecture is considered "illegal" by Microsoft's standards even if implementable (C++/CX ppltasks library throws errors if you try it). Worse, either by design or a bug in the MF MediaCapture class with Custom Sinks causes a crash if stop/start previewing without reinitializing (spPreferredPreviewMediaType is fatally nulled). After decompiling Windows.Media.dll, I worked around this in my own projects by using an activate-able custom sink ID which strangely assigns 1 to this pointer allowing it to be reinitialized in what can only be described as a hack by Microsoft. This would add additional overhead to the project to implement especially for static libraries as it requires IDL/DLL exporting followed by manifest declaration. Better to document that it is not supported. Furthermore, an additional class for IMFAttributes should be implemented to make clean architecture for passing around attributes as opposed to directly calling non-COM interface calls on the objects and making use of SetProperties which would also be a set up for an object that uses the RuntimeClass activation ID. The remaining changes are not difficult and will be complete soon along with debug tracing messages. Update and rename cap_msmf.h to cap_msmf.hpp Successful test - samples are grabbed Library updated and cleaned up with comments, marshaling, exceptions and linker settings Fixed trailing whitespace VS 2013 support and cleanup consistency plus C++/CX new object fixed Conflicts: modules/highgui/src/cap_msmf.cpp modules/highgui/src/cap_msmf.hpp modules/highgui/src/ppltasks_winrt.h Fix merge conflicts VS 2013 Update 2 library bug fix integrated a-wi's changed integrated
11 years ago
//require Windows 8 for some of the formats defined otherwise could baseline on lower version
#if WINVER < _WIN32_WINNT_WIN8
Add support for WinRT in the MF capture framework by removing the disallowed calls to enumerate devices and create a sample grabber sink and adding framework for the MediaCapture interface and a custom sink which interfaces with the sample grabber callback interface. The change requires discussion for making it completely functional as redundancy is required given that if the source is a video file, the old code pathways must be used. Otherwise all IMFMediaSession, IMFMediaSource, and IMFActivate code must use a MediaCapture code path and all sink code must use the CMediaSink custom sink. Support for the custom sink is extended to non-WinRT not for compatibility as Windows Vista client is a minimum regardless, but because it offers more flexibility, could be faster and is able to be used as an optionally different code path during sink creation based on a future configuration parameter. My discussion and proposal to finish this change: Devices are so easily enumerated through WinRT Windows.Devices namespace that wrapping the calls in a library is quite a chore for little benefit though to get the various modes and formats could still be a worthwhile project. For now conditional compilation to remove videodevices and any offending non-video file related activity in videodevice. In my opinion, this is a different , far less fundamental and important change which can possibly be done as a future project and also much more easily implemented in C++/CX. ImageGrabber has the IMFSampleGrabberSinkCallback replaced with a base class (SharedSampleGrabber) which also be is base class for ImageGrabberRT. This change is necessary as the custom sink does not require a thread to pump events which is done through MediaCapture already. IMFSampleGrabberSinkCallback is the common element between both models and that piece can be shared. Initializing the new ImageGrabberRT is as simple as passing an already initialized MediaCapture object and any video format/encoding parameters. The concurrency event is necessary to wait for completion and is the way the underlying, IAsyncAction wrappers in the task library work as well. Native WIN32 event objects would be an option if HAVE_CONCURRENCY is not defined. I could even imagine doing it with sleep/thread yield and InterlockedCompareExchange yet I am not enthusiastic about that approach either. Since there is a specific compiler HAVE_ for concurrency, I do not like pulling it in though I think for WinRT it is safe to say we will always have it available though should probably conditionally compile with the Interlocked option as WIN32 events would require HAVE_WIN32. It looks like C++/CX cannot be used for the IMediaExtension sink (which should not be a problem) as using COM objects requires WRL and though deriving from IMediaExtension can be done, there is little purpose without COM. Objects from C++/CX can be swapped to interact with objects from native C++ as Inspectable* can reinterpret_cast to the ref object IInspectable^ and vice-versa. A solution to the COM class with C++/CX would be great so we could have dual support. Also without #define for every WRL object in use, the code will get quite muddy given that the */^ would need to be ifdef'd everywhere. Fixed bugs and completed the change. I believe the new classes need to be moved to a header file as the file has become to large and more classes need to be added for handling all the asynchronous problems (one wrapping IAsyncAction in a task and another for making a task out of IAsyncAction). Unfortunately, blocking on the UI thread is not an option in WinRT so a synchronous architecture is considered "illegal" by Microsoft's standards even if implementable (C++/CX ppltasks library throws errors if you try it). Worse, either by design or a bug in the MF MediaCapture class with Custom Sinks causes a crash if stop/start previewing without reinitializing (spPreferredPreviewMediaType is fatally nulled). After decompiling Windows.Media.dll, I worked around this in my own projects by using an activate-able custom sink ID which strangely assigns 1 to this pointer allowing it to be reinitialized in what can only be described as a hack by Microsoft. This would add additional overhead to the project to implement especially for static libraries as it requires IDL/DLL exporting followed by manifest declaration. Better to document that it is not supported. Furthermore, an additional class for IMFAttributes should be implemented to make clean architecture for passing around attributes as opposed to directly calling non-COM interface calls on the objects and making use of SetProperties which would also be a set up for an object that uses the RuntimeClass activation ID. The remaining changes are not difficult and will be complete soon along with debug tracing messages. Update and rename cap_msmf.h to cap_msmf.hpp Successful test - samples are grabbed Library updated and cleaned up with comments, marshaling, exceptions and linker settings Fixed trailing whitespace VS 2013 support and cleanup consistency plus C++/CX new object fixed Conflicts: modules/highgui/src/cap_msmf.cpp modules/highgui/src/cap_msmf.hpp modules/highgui/src/ppltasks_winrt.h Fix merge conflicts VS 2013 Update 2 library bug fix integrated a-wi's changed integrated
11 years ago
#undef WINVER
#define WINVER _WIN32_WINNT_WIN8
Add support for WinRT in the MF capture framework by removing the disallowed calls to enumerate devices and create a sample grabber sink and adding framework for the MediaCapture interface and a custom sink which interfaces with the sample grabber callback interface. The change requires discussion for making it completely functional as redundancy is required given that if the source is a video file, the old code pathways must be used. Otherwise all IMFMediaSession, IMFMediaSource, and IMFActivate code must use a MediaCapture code path and all sink code must use the CMediaSink custom sink. Support for the custom sink is extended to non-WinRT not for compatibility as Windows Vista client is a minimum regardless, but because it offers more flexibility, could be faster and is able to be used as an optionally different code path during sink creation based on a future configuration parameter. My discussion and proposal to finish this change: Devices are so easily enumerated through WinRT Windows.Devices namespace that wrapping the calls in a library is quite a chore for little benefit though to get the various modes and formats could still be a worthwhile project. For now conditional compilation to remove videodevices and any offending non-video file related activity in videodevice. In my opinion, this is a different , far less fundamental and important change which can possibly be done as a future project and also much more easily implemented in C++/CX. ImageGrabber has the IMFSampleGrabberSinkCallback replaced with a base class (SharedSampleGrabber) which also be is base class for ImageGrabberRT. This change is necessary as the custom sink does not require a thread to pump events which is done through MediaCapture already. IMFSampleGrabberSinkCallback is the common element between both models and that piece can be shared. Initializing the new ImageGrabberRT is as simple as passing an already initialized MediaCapture object and any video format/encoding parameters. The concurrency event is necessary to wait for completion and is the way the underlying, IAsyncAction wrappers in the task library work as well. Native WIN32 event objects would be an option if HAVE_CONCURRENCY is not defined. I could even imagine doing it with sleep/thread yield and InterlockedCompareExchange yet I am not enthusiastic about that approach either. Since there is a specific compiler HAVE_ for concurrency, I do not like pulling it in though I think for WinRT it is safe to say we will always have it available though should probably conditionally compile with the Interlocked option as WIN32 events would require HAVE_WIN32. It looks like C++/CX cannot be used for the IMediaExtension sink (which should not be a problem) as using COM objects requires WRL and though deriving from IMediaExtension can be done, there is little purpose without COM. Objects from C++/CX can be swapped to interact with objects from native C++ as Inspectable* can reinterpret_cast to the ref object IInspectable^ and vice-versa. A solution to the COM class with C++/CX would be great so we could have dual support. Also without #define for every WRL object in use, the code will get quite muddy given that the */^ would need to be ifdef'd everywhere. Fixed bugs and completed the change. I believe the new classes need to be moved to a header file as the file has become to large and more classes need to be added for handling all the asynchronous problems (one wrapping IAsyncAction in a task and another for making a task out of IAsyncAction). Unfortunately, blocking on the UI thread is not an option in WinRT so a synchronous architecture is considered "illegal" by Microsoft's standards even if implementable (C++/CX ppltasks library throws errors if you try it). Worse, either by design or a bug in the MF MediaCapture class with Custom Sinks causes a crash if stop/start previewing without reinitializing (spPreferredPreviewMediaType is fatally nulled). After decompiling Windows.Media.dll, I worked around this in my own projects by using an activate-able custom sink ID which strangely assigns 1 to this pointer allowing it to be reinitialized in what can only be described as a hack by Microsoft. This would add additional overhead to the project to implement especially for static libraries as it requires IDL/DLL exporting followed by manifest declaration. Better to document that it is not supported. Furthermore, an additional class for IMFAttributes should be implemented to make clean architecture for passing around attributes as opposed to directly calling non-COM interface calls on the objects and making use of SetProperties which would also be a set up for an object that uses the RuntimeClass activation ID. The remaining changes are not difficult and will be complete soon along with debug tracing messages. Update and rename cap_msmf.h to cap_msmf.hpp Successful test - samples are grabbed Library updated and cleaned up with comments, marshaling, exceptions and linker settings Fixed trailing whitespace VS 2013 support and cleanup consistency plus C++/CX new object fixed Conflicts: modules/highgui/src/cap_msmf.cpp modules/highgui/src/cap_msmf.hpp modules/highgui/src/ppltasks_winrt.h Fix merge conflicts VS 2013 Update 2 library bug fix integrated a-wi's changed integrated
11 years ago
#endif
#include <windows.h>
#include <guiddef.h>
#include <mfidl.h>
#include <mfapi.h>
#include <mfplay.h>
#include <mfobjects.h>
Add support for WinRT in the MF capture framework by removing the disallowed calls to enumerate devices and create a sample grabber sink and adding framework for the MediaCapture interface and a custom sink which interfaces with the sample grabber callback interface. The change requires discussion for making it completely functional as redundancy is required given that if the source is a video file, the old code pathways must be used. Otherwise all IMFMediaSession, IMFMediaSource, and IMFActivate code must use a MediaCapture code path and all sink code must use the CMediaSink custom sink. Support for the custom sink is extended to non-WinRT not for compatibility as Windows Vista client is a minimum regardless, but because it offers more flexibility, could be faster and is able to be used as an optionally different code path during sink creation based on a future configuration parameter. My discussion and proposal to finish this change: Devices are so easily enumerated through WinRT Windows.Devices namespace that wrapping the calls in a library is quite a chore for little benefit though to get the various modes and formats could still be a worthwhile project. For now conditional compilation to remove videodevices and any offending non-video file related activity in videodevice. In my opinion, this is a different , far less fundamental and important change which can possibly be done as a future project and also much more easily implemented in C++/CX. ImageGrabber has the IMFSampleGrabberSinkCallback replaced with a base class (SharedSampleGrabber) which also be is base class for ImageGrabberRT. This change is necessary as the custom sink does not require a thread to pump events which is done through MediaCapture already. IMFSampleGrabberSinkCallback is the common element between both models and that piece can be shared. Initializing the new ImageGrabberRT is as simple as passing an already initialized MediaCapture object and any video format/encoding parameters. The concurrency event is necessary to wait for completion and is the way the underlying, IAsyncAction wrappers in the task library work as well. Native WIN32 event objects would be an option if HAVE_CONCURRENCY is not defined. I could even imagine doing it with sleep/thread yield and InterlockedCompareExchange yet I am not enthusiastic about that approach either. Since there is a specific compiler HAVE_ for concurrency, I do not like pulling it in though I think for WinRT it is safe to say we will always have it available though should probably conditionally compile with the Interlocked option as WIN32 events would require HAVE_WIN32. It looks like C++/CX cannot be used for the IMediaExtension sink (which should not be a problem) as using COM objects requires WRL and though deriving from IMediaExtension can be done, there is little purpose without COM. Objects from C++/CX can be swapped to interact with objects from native C++ as Inspectable* can reinterpret_cast to the ref object IInspectable^ and vice-versa. A solution to the COM class with C++/CX would be great so we could have dual support. Also without #define for every WRL object in use, the code will get quite muddy given that the */^ would need to be ifdef'd everywhere. Fixed bugs and completed the change. I believe the new classes need to be moved to a header file as the file has become to large and more classes need to be added for handling all the asynchronous problems (one wrapping IAsyncAction in a task and another for making a task out of IAsyncAction). Unfortunately, blocking on the UI thread is not an option in WinRT so a synchronous architecture is considered "illegal" by Microsoft's standards even if implementable (C++/CX ppltasks library throws errors if you try it). Worse, either by design or a bug in the MF MediaCapture class with Custom Sinks causes a crash if stop/start previewing without reinitializing (spPreferredPreviewMediaType is fatally nulled). After decompiling Windows.Media.dll, I worked around this in my own projects by using an activate-able custom sink ID which strangely assigns 1 to this pointer allowing it to be reinitialized in what can only be described as a hack by Microsoft. This would add additional overhead to the project to implement especially for static libraries as it requires IDL/DLL exporting followed by manifest declaration. Better to document that it is not supported. Furthermore, an additional class for IMFAttributes should be implemented to make clean architecture for passing around attributes as opposed to directly calling non-COM interface calls on the objects and making use of SetProperties which would also be a set up for an object that uses the RuntimeClass activation ID. The remaining changes are not difficult and will be complete soon along with debug tracing messages. Update and rename cap_msmf.h to cap_msmf.hpp Successful test - samples are grabbed Library updated and cleaned up with comments, marshaling, exceptions and linker settings Fixed trailing whitespace VS 2013 support and cleanup consistency plus C++/CX new object fixed Conflicts: modules/highgui/src/cap_msmf.cpp modules/highgui/src/cap_msmf.hpp modules/highgui/src/ppltasks_winrt.h Fix merge conflicts VS 2013 Update 2 library bug fix integrated a-wi's changed integrated
11 years ago
#include <tchar.h>
#include <strsafe.h>
#include <mfreadwrite.h>
#ifdef HAVE_MSMF_DXVA
#include <d3d11.h>
#include <d3d11_4.h>
#endif
#include <new>
#include <map>
#include <vector>
#include <string>
#include <algorithm>
#include <stdio.h>
#include <stdarg.h>
#include <string.h>
#ifdef _MSC_VER
#pragma warning(disable:4503)
#pragma comment(lib, "mfplat")
#pragma comment(lib, "mf")
#pragma comment(lib, "mfuuid")
#pragma comment(lib, "Strmiids")
#pragma comment(lib, "Mfreadwrite")
#ifdef HAVE_MSMF_DXVA
#pragma comment(lib, "d3d11")
// MFCreateDXGIDeviceManager() is available since Win8 only.
// To avoid OpenCV loading failure on Win7 use dynamic detection of this symbol.
// Details: https://github.com/opencv/opencv/issues/11858
typedef HRESULT (WINAPI *FN_MFCreateDXGIDeviceManager)(UINT *resetToken, IMFDXGIDeviceManager **ppDeviceManager);
static bool pMFCreateDXGIDeviceManager_initialized = false;
static FN_MFCreateDXGIDeviceManager pMFCreateDXGIDeviceManager = NULL;
static void init_MFCreateDXGIDeviceManager()
{
HMODULE h = LoadLibraryExA("mfplat.dll", NULL, LOAD_LIBRARY_SEARCH_SYSTEM32);
if (h)
{
pMFCreateDXGIDeviceManager = (FN_MFCreateDXGIDeviceManager)GetProcAddress(h, "MFCreateDXGIDeviceManager");
}
pMFCreateDXGIDeviceManager_initialized = true;
}
#endif
#pragma comment(lib, "Shlwapi.lib")
#endif
Update cap_msmf.cpp Add support for WinRT in the MF capture framework by removing the disallowed calls to enumerate devices and create a sample grabber sink and adding framework for the MediaCapture interface and a custom sink which interfaces with the sample grabber callback interface. The change requires discussion for making it completely functional as redundancy is required given that if the source is a video file, the old code pathways must be used. Otherwise all IMFMediaSession, IMFMediaSource, and IMFActivate code must use a MediaCapture code path and all sink code must use the CMediaSink custom sink. Support for the custom sink is extended to non-WinRT not for compatibility as Windows Vista client is a minimum regardless, but because it offers more flexibility, could be faster and is able to be used as an optionally different code path during sink creation based on a future configuration parameter. My discussion and proposal to finish this change: Devices are so easily enumerated through WinRT Windows.Devices namespace that wrapping the calls in a library is quite a chore for little benefit though to get the various modes and formats could still be a worthwhile project. For now conditional compilation to remove videodevices and any offending non-video file related activity in videodevice. In my opinion, this is a different , far less fundamental and important change which can possibly be done as a future project and also much more easily implemented in C++/CX. ImageGrabber has the IMFSampleGrabberSinkCallback replaced with a base class (SharedSampleGrabber) which also be is base class for ImageGrabberRT. This change is necessary as the custom sink does not require a thread to pump events which is done through MediaCapture already. IMFSampleGrabberSinkCallback is the common element between both models and that piece can be shared. Initializing the new ImageGrabberRT is as simple as passing an already initialized MediaCapture object and any video format/encoding parameters. The concurrency event is necessary to wait for completion and is the way the underlying, IAsyncAction wrappers in the task library work as well. Native WIN32 event objects would be an option if HAVE_CONCURRENCY is not defined. I could even imagine doing it with sleep/thread yield and InterlockedCompareExchange yet I am not enthusiastic about that approach either. Since there is a specific compiler HAVE_ for concurrency, I do not like pulling it in though I think for WinRT it is safe to say we will always have it available though should probably conditionally compile with the Interlocked option as WIN32 events would require HAVE_WIN32. It looks like C++/CX cannot be used for the IMediaExtension sink (which should not be a problem) as using COM objects requires WRL and though deriving from IMediaExtension can be done, there is little purpose without COM. Objects from C++/CX can be swapped to interact with objects from native C++ as Inspectable* can reinterpret_cast to the ref object IInspectable^ and vice-versa. A solution to the COM class with C++/CX would be great so we could have dual support. Also without #define for every WRL object in use, the code will get quite muddy given that the */^ would need to be ifdef'd everywhere. Update cap_msmf.cpp Fixed bugs and completed the change. I believe the new classes need to be moved to a header file as the file has become to large and more classes need to be added for handling all the asynchronous problems (one wrapping IAsyncAction in a task and another for making a task out of IAsyncAction). Unfortunately, blocking on the UI thread is not an option in WinRT so a synchronous architecture is considered "illegal" by Microsoft's standards even if implementable (C++/CX ppltasks library throws errors if you try it). Worse, either by design or a bug in the MF MediaCapture class with Custom Sinks causes a crash if stop/start previewing without reinitializing (spPreferredPreviewMediaType is fatally nulled). After decompiling Windows.Media.dll, I worked around this in my own projects by using an activate-able custom sink ID which strangely assigns 1 to this pointer allowing it to be reinitialized in what can only be described as a hack by Microsoft. This would add additional overhead to the project to implement especially for static libraries as it requires IDL/DLL exporting followed by manifest declaration. Better to document that it is not supported. Furthermore, an additional class for IMFAttributes should be implemented to make clean architecture for passing around attributes as opposed to directly calling non-COM interface calls on the objects and making use of SetProperties which would also be a set up for an object that uses the RuntimeClass activation ID. The remaining changes are not difficult and will be complete soon along with debug tracing messages. Update cap_msmf.cpp Create cap_msmf.h Update cap_msmf.cpp Update cap_msmf.h Update cap_msmf.cpp Update cap_msmf.h Update and rename cap_msmf.h to cap_msmf.hpp Update cap_msmf.cpp Update CMakeLists.txt Update cap_msmf.hpp Update cap_msmf.cpp Update cap_msmf.cpp Update cap_msmf.cpp Update cap_msmf.hpp Update cap_msmf.hpp Update cap_msmf.cpp Successful test - samples are grabbed Update cap_msmf.cpp Update cap_msmf.hpp Update cap_msmf.cpp Update cap_msmf.hpp Update cap_msmf.hpp Update cap_msmf.cpp Update cap_msmf.hpp Update cap_msmf.cpp Update cap_msmf.hpp Update cap_msmf.cpp Update cap_msmf.hpp Create ppltasks_winrt.h Update cap_msmf.hpp Update cap_msmf.hpp Update cap_msmf.cpp Update ppltasks_winrt.h Library updated and cleaned up with comments, marshaling, exceptions and linker settings Update ppltasks_winrt.h Fixed trailing whitespace
11 years ago
#include <mferror.h>
#include <comdef.h>
Update cap_msmf.cpp Add support for WinRT in the MF capture framework by removing the disallowed calls to enumerate devices and create a sample grabber sink and adding framework for the MediaCapture interface and a custom sink which interfaces with the sample grabber callback interface. The change requires discussion for making it completely functional as redundancy is required given that if the source is a video file, the old code pathways must be used. Otherwise all IMFMediaSession, IMFMediaSource, and IMFActivate code must use a MediaCapture code path and all sink code must use the CMediaSink custom sink. Support for the custom sink is extended to non-WinRT not for compatibility as Windows Vista client is a minimum regardless, but because it offers more flexibility, could be faster and is able to be used as an optionally different code path during sink creation based on a future configuration parameter. My discussion and proposal to finish this change: Devices are so easily enumerated through WinRT Windows.Devices namespace that wrapping the calls in a library is quite a chore for little benefit though to get the various modes and formats could still be a worthwhile project. For now conditional compilation to remove videodevices and any offending non-video file related activity in videodevice. In my opinion, this is a different , far less fundamental and important change which can possibly be done as a future project and also much more easily implemented in C++/CX. ImageGrabber has the IMFSampleGrabberSinkCallback replaced with a base class (SharedSampleGrabber) which also be is base class for ImageGrabberRT. This change is necessary as the custom sink does not require a thread to pump events which is done through MediaCapture already. IMFSampleGrabberSinkCallback is the common element between both models and that piece can be shared. Initializing the new ImageGrabberRT is as simple as passing an already initialized MediaCapture object and any video format/encoding parameters. The concurrency event is necessary to wait for completion and is the way the underlying, IAsyncAction wrappers in the task library work as well. Native WIN32 event objects would be an option if HAVE_CONCURRENCY is not defined. I could even imagine doing it with sleep/thread yield and InterlockedCompareExchange yet I am not enthusiastic about that approach either. Since there is a specific compiler HAVE_ for concurrency, I do not like pulling it in though I think for WinRT it is safe to say we will always have it available though should probably conditionally compile with the Interlocked option as WIN32 events would require HAVE_WIN32. It looks like C++/CX cannot be used for the IMediaExtension sink (which should not be a problem) as using COM objects requires WRL and though deriving from IMediaExtension can be done, there is little purpose without COM. Objects from C++/CX can be swapped to interact with objects from native C++ as Inspectable* can reinterpret_cast to the ref object IInspectable^ and vice-versa. A solution to the COM class with C++/CX would be great so we could have dual support. Also without #define for every WRL object in use, the code will get quite muddy given that the */^ would need to be ifdef'd everywhere. Update cap_msmf.cpp Fixed bugs and completed the change. I believe the new classes need to be moved to a header file as the file has become to large and more classes need to be added for handling all the asynchronous problems (one wrapping IAsyncAction in a task and another for making a task out of IAsyncAction). Unfortunately, blocking on the UI thread is not an option in WinRT so a synchronous architecture is considered "illegal" by Microsoft's standards even if implementable (C++/CX ppltasks library throws errors if you try it). Worse, either by design or a bug in the MF MediaCapture class with Custom Sinks causes a crash if stop/start previewing without reinitializing (spPreferredPreviewMediaType is fatally nulled). After decompiling Windows.Media.dll, I worked around this in my own projects by using an activate-able custom sink ID which strangely assigns 1 to this pointer allowing it to be reinitialized in what can only be described as a hack by Microsoft. This would add additional overhead to the project to implement especially for static libraries as it requires IDL/DLL exporting followed by manifest declaration. Better to document that it is not supported. Furthermore, an additional class for IMFAttributes should be implemented to make clean architecture for passing around attributes as opposed to directly calling non-COM interface calls on the objects and making use of SetProperties which would also be a set up for an object that uses the RuntimeClass activation ID. The remaining changes are not difficult and will be complete soon along with debug tracing messages. Update cap_msmf.cpp Create cap_msmf.h Update cap_msmf.cpp Update cap_msmf.h Update cap_msmf.cpp Update cap_msmf.h Update and rename cap_msmf.h to cap_msmf.hpp Update cap_msmf.cpp Update CMakeLists.txt Update cap_msmf.hpp Update cap_msmf.cpp Update cap_msmf.cpp Update cap_msmf.cpp Update cap_msmf.hpp Update cap_msmf.hpp Update cap_msmf.cpp Successful test - samples are grabbed Update cap_msmf.cpp Update cap_msmf.hpp Update cap_msmf.cpp Update cap_msmf.hpp Update cap_msmf.hpp Update cap_msmf.cpp Update cap_msmf.hpp Update cap_msmf.cpp Update cap_msmf.hpp Update cap_msmf.cpp Update cap_msmf.hpp Create ppltasks_winrt.h Update cap_msmf.hpp Update cap_msmf.hpp Update cap_msmf.cpp Update ppltasks_winrt.h Library updated and cleaned up with comments, marshaling, exceptions and linker settings Update ppltasks_winrt.h Fixed trailing whitespace
11 years ago
#include <shlwapi.h> // QISearch
struct IMFMediaType;
struct IMFActivate;
struct IMFMediaSource;
struct IMFAttributes;
#define CV_CAP_MODE_BGR CV_FOURCC_MACRO('B','G','R','3')
#define CV_CAP_MODE_RGB CV_FOURCC_MACRO('R','G','B','3')
#define CV_CAP_MODE_GRAY CV_FOURCC_MACRO('G','R','E','Y')
#define CV_CAP_MODE_YUYV CV_FOURCC_MACRO('Y', 'U', 'Y', 'V')
namespace
{
template <class T>
class ComPtr
{
public:
ComPtr()
{
}
ComPtr(T* lp)
{
p = lp;
}
ComPtr(_In_ const ComPtr<T>& lp)
{
p = lp.p;
}
virtual ~ComPtr()
{
}
T** operator&()
{
CV_Assert(p == NULL);
return p.operator&();
}
T* operator->() const
{
CV_Assert(p != NULL);
return p.operator->();
}
operator bool()
{
return p.operator!=(NULL);
}
T* Get() const
{
return p;
}
void Release()
{
if (p)
p.Release();
}
// query for U interface
template<typename U>
HRESULT As(_Out_ ComPtr<U>& lp) const
{
lp.Release();
return p->QueryInterface(__uuidof(U), reinterpret_cast<void**>((T**)&lp));
}
private:
_COM_SMARTPTR_TYPEDEF(T, __uuidof(T));
TPtr p;
};
#define _ComPtr ComPtr
Update cap_msmf.cpp Add support for WinRT in the MF capture framework by removing the disallowed calls to enumerate devices and create a sample grabber sink and adding framework for the MediaCapture interface and a custom sink which interfaces with the sample grabber callback interface. The change requires discussion for making it completely functional as redundancy is required given that if the source is a video file, the old code pathways must be used. Otherwise all IMFMediaSession, IMFMediaSource, and IMFActivate code must use a MediaCapture code path and all sink code must use the CMediaSink custom sink. Support for the custom sink is extended to non-WinRT not for compatibility as Windows Vista client is a minimum regardless, but because it offers more flexibility, could be faster and is able to be used as an optionally different code path during sink creation based on a future configuration parameter. My discussion and proposal to finish this change: Devices are so easily enumerated through WinRT Windows.Devices namespace that wrapping the calls in a library is quite a chore for little benefit though to get the various modes and formats could still be a worthwhile project. For now conditional compilation to remove videodevices and any offending non-video file related activity in videodevice. In my opinion, this is a different , far less fundamental and important change which can possibly be done as a future project and also much more easily implemented in C++/CX. ImageGrabber has the IMFSampleGrabberSinkCallback replaced with a base class (SharedSampleGrabber) which also be is base class for ImageGrabberRT. This change is necessary as the custom sink does not require a thread to pump events which is done through MediaCapture already. IMFSampleGrabberSinkCallback is the common element between both models and that piece can be shared. Initializing the new ImageGrabberRT is as simple as passing an already initialized MediaCapture object and any video format/encoding parameters. The concurrency event is necessary to wait for completion and is the way the underlying, IAsyncAction wrappers in the task library work as well. Native WIN32 event objects would be an option if HAVE_CONCURRENCY is not defined. I could even imagine doing it with sleep/thread yield and InterlockedCompareExchange yet I am not enthusiastic about that approach either. Since there is a specific compiler HAVE_ for concurrency, I do not like pulling it in though I think for WinRT it is safe to say we will always have it available though should probably conditionally compile with the Interlocked option as WIN32 events would require HAVE_WIN32. It looks like C++/CX cannot be used for the IMediaExtension sink (which should not be a problem) as using COM objects requires WRL and though deriving from IMediaExtension can be done, there is little purpose without COM. Objects from C++/CX can be swapped to interact with objects from native C++ as Inspectable* can reinterpret_cast to the ref object IInspectable^ and vice-versa. A solution to the COM class with C++/CX would be great so we could have dual support. Also without #define for every WRL object in use, the code will get quite muddy given that the */^ would need to be ifdef'd everywhere. Update cap_msmf.cpp Fixed bugs and completed the change. I believe the new classes need to be moved to a header file as the file has become to large and more classes need to be added for handling all the asynchronous problems (one wrapping IAsyncAction in a task and another for making a task out of IAsyncAction). Unfortunately, blocking on the UI thread is not an option in WinRT so a synchronous architecture is considered "illegal" by Microsoft's standards even if implementable (C++/CX ppltasks library throws errors if you try it). Worse, either by design or a bug in the MF MediaCapture class with Custom Sinks causes a crash if stop/start previewing without reinitializing (spPreferredPreviewMediaType is fatally nulled). After decompiling Windows.Media.dll, I worked around this in my own projects by using an activate-able custom sink ID which strangely assigns 1 to this pointer allowing it to be reinitialized in what can only be described as a hack by Microsoft. This would add additional overhead to the project to implement especially for static libraries as it requires IDL/DLL exporting followed by manifest declaration. Better to document that it is not supported. Furthermore, an additional class for IMFAttributes should be implemented to make clean architecture for passing around attributes as opposed to directly calling non-COM interface calls on the objects and making use of SetProperties which would also be a set up for an object that uses the RuntimeClass activation ID. The remaining changes are not difficult and will be complete soon along with debug tracing messages. Update cap_msmf.cpp Create cap_msmf.h Update cap_msmf.cpp Update cap_msmf.h Update cap_msmf.cpp Update cap_msmf.h Update and rename cap_msmf.h to cap_msmf.hpp Update cap_msmf.cpp Update CMakeLists.txt Update cap_msmf.hpp Update cap_msmf.cpp Update cap_msmf.cpp Update cap_msmf.cpp Update cap_msmf.hpp Update cap_msmf.hpp Update cap_msmf.cpp Successful test - samples are grabbed Update cap_msmf.cpp Update cap_msmf.hpp Update cap_msmf.cpp Update cap_msmf.hpp Update cap_msmf.hpp Update cap_msmf.cpp Update cap_msmf.hpp Update cap_msmf.cpp Update cap_msmf.hpp Update cap_msmf.cpp Update cap_msmf.hpp Create ppltasks_winrt.h Update cap_msmf.hpp Update cap_msmf.hpp Update cap_msmf.cpp Update ppltasks_winrt.h Library updated and cleaned up with comments, marshaling, exceptions and linker settings Update ppltasks_winrt.h Fixed trailing whitespace
11 years ago
template <typename T> inline T absDiff(T a, T b) { return a >= b ? a - b : b - a; }
//==================================================================================================
// Structure for collecting info about types of video which are supported by current video device
struct MediaType
{
UINT32 width;
UINT32 height;
INT32 stride; // stride is negative if image is bottom-up
UINT32 isFixedSize;
UINT32 frameRateNum;
UINT32 frameRateDenom;
UINT32 aspectRatioNum;
UINT32 aspectRatioDenom;
UINT32 sampleSize;
UINT32 interlaceMode;
GUID majorType; // video or audio
GUID subType; // fourCC
MediaType(IMFMediaType *pType = 0) :
width(0), height(0),
stride(0),
isFixedSize(true),
frameRateNum(1), frameRateDenom(1),
aspectRatioNum(1), aspectRatioDenom(1),
sampleSize(0),
interlaceMode(0),
majorType(MFMediaType_Video),
subType({ 0 })
{
if (pType)
{
MFGetAttributeSize(pType, MF_MT_FRAME_SIZE, &width, &height);
pType->GetUINT32(MF_MT_DEFAULT_STRIDE, (UINT32*)&stride); // value is stored as UINT32 but should be casted to INT3)
pType->GetUINT32(MF_MT_FIXED_SIZE_SAMPLES, &isFixedSize);
MFGetAttributeRatio(pType, MF_MT_FRAME_RATE, &frameRateNum, &frameRateDenom);
MFGetAttributeRatio(pType, MF_MT_PIXEL_ASPECT_RATIO, &aspectRatioNum, &aspectRatioDenom);
pType->GetUINT32(MF_MT_SAMPLE_SIZE, &sampleSize);
pType->GetUINT32(MF_MT_INTERLACE_MODE, &interlaceMode);
pType->GetGUID(MF_MT_MAJOR_TYPE, &majorType);
pType->GetGUID(MF_MT_SUBTYPE, &subType);
}
}
static MediaType createDefault()
{
MediaType res;
res.width = 640;
res.height = 480;
res.setFramerate(30.0);
return res;
}
inline bool isEmpty() const
{
return width == 0 && height == 0;
}
_ComPtr<IMFMediaType> createMediaType() const
{
_ComPtr<IMFMediaType> res;
MFCreateMediaType(&res);
if (width != 0 || height != 0)
MFSetAttributeSize(res.Get(), MF_MT_FRAME_SIZE, width, height);
if (stride != 0)
res->SetUINT32(MF_MT_DEFAULT_STRIDE, stride);
res->SetUINT32(MF_MT_FIXED_SIZE_SAMPLES, isFixedSize);
if (frameRateNum != 0 || frameRateDenom != 0)
MFSetAttributeRatio(res.Get(), MF_MT_FRAME_RATE, frameRateNum, frameRateDenom);
if (aspectRatioNum != 0 || aspectRatioDenom != 0)
MFSetAttributeRatio(res.Get(), MF_MT_PIXEL_ASPECT_RATIO, aspectRatioNum, aspectRatioDenom);
if (sampleSize > 0)
res->SetUINT32(MF_MT_SAMPLE_SIZE, sampleSize);
res->SetUINT32(MF_MT_INTERLACE_MODE, interlaceMode);
if (majorType != GUID())
res->SetGUID(MF_MT_MAJOR_TYPE, majorType);
if (subType != GUID())
res->SetGUID(MF_MT_SUBTYPE, subType);
return res;
}
void setFramerate(double fps)
{
frameRateNum = (UINT32)cvRound(fps * 1000.0);
frameRateDenom = 1000;
}
double getFramerate() const
{
return frameRateDenom != 0 ? ((double)frameRateNum) / ((double)frameRateDenom) : 0;
}
LONGLONG getFrameStep() const
{
const double fps = getFramerate();
return (LONGLONG)(fps > 0 ? 1e7 / fps : 0);
}
inline unsigned long resolutionDiff(const MediaType& other) const
{
const unsigned long wdiff = absDiff(width, other.width);
const unsigned long hdiff = absDiff(height, other.height);
return wdiff + hdiff;
}
// check if 'this' is better than 'other' comparing to reference
bool isBetterThan(const MediaType& other, const MediaType& ref) const
{
const unsigned long thisDiff = resolutionDiff(ref);
const unsigned long otherDiff = other.resolutionDiff(ref);
if (thisDiff < otherDiff)
return true;
if (thisDiff == otherDiff)
{
if (width > other.width)
return true;
if (width == other.width && height > other.height)
return true;
if (width == other.width && height == other.height)
{
const double thisRateDiff = absDiff(getFramerate(), ref.getFramerate());
const double otherRateDiff = absDiff(other.getFramerate(), ref.getFramerate());
if (thisRateDiff < otherRateDiff)
return true;
}
}
return false;
}
};
void printFormat(std::ostream& out, const GUID& fmt)
{
#define PRNT(FMT) else if (fmt == FMT) out << #FMT;
if (fmt == MFVideoFormat_Base) out << "Base";
PRNT(MFVideoFormat_RGB32)
PRNT(MFVideoFormat_ARGB32)
PRNT(MFVideoFormat_RGB24)
PRNT(MFVideoFormat_RGB555)
PRNT(MFVideoFormat_RGB565)
PRNT(MFVideoFormat_RGB8)
else
{
char fourcc[5] = { 0 };
memcpy(fourcc, &fmt.Data1, 4);
out << fourcc;
}
#undef PRNT
}
std::ostream& operator<<(std::ostream& out, const MediaType& mt)
{
out << "(" << mt.width << "x" << mt.height << " @ " << mt.getFramerate() << ") ";
printFormat(out, mt.subType);
return out;
}
//==================================================================================================
// Class for creating of Media Foundation context
class Media_Foundation
{
public:
~Media_Foundation(void) { /*CV_Assert(SUCCEEDED(MFShutdown()));*/ CoUninitialize(); }
static Media_Foundation& getInstance()
{
static Media_Foundation instance;
return instance;
}
private:
Media_Foundation(void) { CoInitialize(0); CV_Assert(SUCCEEDED(MFStartup(MF_VERSION))); }
};
//==================================================================================================
class SourceReaderCB : public IMFSourceReaderCallback
{
public:
SourceReaderCB() :
m_nRefCount(0), m_hEvent(CreateEvent(NULL, FALSE, FALSE, NULL)), m_bEOS(FALSE), m_hrStatus(S_OK), m_reader(NULL), m_dwStreamIndex(0)
{
}
// IUnknown methods
STDMETHODIMP QueryInterface(REFIID iid, void** ppv) CV_OVERRIDE
{
#ifdef _MSC_VER
#pragma warning(push)
#pragma warning(disable:4838)
#endif
static const QITAB qit[] =
{
QITABENT(SourceReaderCB, IMFSourceReaderCallback),
{ 0 },
};
#ifdef _MSC_VER
#pragma warning(pop)
#endif
return QISearch(this, qit, iid, ppv);
}
STDMETHODIMP_(ULONG) AddRef() CV_OVERRIDE
{
return InterlockedIncrement(&m_nRefCount);
}
STDMETHODIMP_(ULONG) Release() CV_OVERRIDE
{
ULONG uCount = InterlockedDecrement(&m_nRefCount);
if (uCount == 0)
{
delete this;
}
return uCount;
}
STDMETHODIMP OnReadSample(HRESULT hrStatus, DWORD dwStreamIndex, DWORD dwStreamFlags, LONGLONG llTimestamp, IMFSample *pSample) CV_OVERRIDE
{
HRESULT hr = 0;
cv::AutoLock lock(m_mutex);
if (SUCCEEDED(hrStatus))
{
if (pSample)
{
CV_LOG_DEBUG(NULL, "videoio(MSMF): got frame at " << llTimestamp);
if (m_lastSample.Get())
{
CV_LOG_DEBUG(NULL, "videoio(MSMF): drop frame (not processed)");
}
m_lastSampleTimestamp = llTimestamp;
m_lastSample = pSample;
}
}
else
{
CV_LOG_WARNING(NULL, "videoio(MSMF): OnReadSample() is called with error status: " << hrStatus);
}
if (MF_SOURCE_READERF_ENDOFSTREAM & dwStreamFlags)
{
// Reached the end of the stream.
m_bEOS = true;
}
m_hrStatus = hrStatus;
if (FAILED(hr = m_reader->ReadSample(dwStreamIndex, 0, NULL, NULL, NULL, NULL)))
{
CV_LOG_WARNING(NULL, "videoio(MSMF): async ReadSample() call is failed with error status: " << hr);
m_bEOS = true;
}
if (pSample || m_bEOS)
{
SetEvent(m_hEvent);
}
return S_OK;
}
STDMETHODIMP OnEvent(DWORD, IMFMediaEvent *) CV_OVERRIDE
{
return S_OK;
}
STDMETHODIMP OnFlush(DWORD) CV_OVERRIDE
{
return S_OK;
}
HRESULT Wait(DWORD dwMilliseconds, _ComPtr<IMFSample>& videoSample, BOOL& pbEOS)
{
pbEOS = FALSE;
DWORD dwResult = WaitForSingleObject(m_hEvent, dwMilliseconds);
if (dwResult == WAIT_TIMEOUT)
{
return E_PENDING;
}
else if (dwResult != WAIT_OBJECT_0)
{
return HRESULT_FROM_WIN32(GetLastError());
}
pbEOS = m_bEOS;
if (!pbEOS)
{
cv::AutoLock lock(m_mutex);
videoSample = m_lastSample;
CV_Assert(videoSample);
m_lastSample.Release();
ResetEvent(m_hEvent); // event is auto-reset, but we need this forced reset due time gap between wait() and mutex hold.
}
return m_hrStatus;
}
private:
// Destructor is private. Caller should call Release.
virtual ~SourceReaderCB()
{
CV_LOG_WARNING(NULL, "terminating async callback");
}
public:
long m_nRefCount; // Reference count.
cv::Mutex m_mutex;
HANDLE m_hEvent;
BOOL m_bEOS;
HRESULT m_hrStatus;
IMFSourceReader *m_reader;
DWORD m_dwStreamIndex;
LONGLONG m_lastSampleTimestamp;
_ComPtr<IMFSample> m_lastSample;
};
//==================================================================================================
// Enumerate and store supported formats and finds format which is most similar to the one requested
class FormatStorage
{
public:
struct MediaID
{
DWORD stream;
DWORD media;
MediaID() : stream(0), media(0) {}
void nextStream()
{
stream++;
media = 0;
}
void nextMedia()
{
media++;
}
bool operator<(const MediaID& other) const
{
return (stream < other.stream) || (stream == other.stream && media < other.media);
}
};
void read(IMFSourceReader* source)
{
HRESULT hr = S_OK;
MediaID cur;
while (SUCCEEDED(hr))
{
_ComPtr<IMFMediaType> raw_type;
hr = source->GetNativeMediaType(cur.stream, cur.media, &raw_type);
if (hr == MF_E_NO_MORE_TYPES)
{
hr = S_OK;
cur.nextStream();
}
else if (SUCCEEDED(hr))
{
formats[cur] = MediaType(raw_type.Get());
cur.nextMedia();
}
}
}
std::pair<MediaID, MediaType> findBestVideoFormat(const MediaType& newType)
{
std::pair<MediaID, MediaType> best;
std::map<MediaID, MediaType>::const_iterator i = formats.begin();
for (; i != formats.end(); ++i)
{
if (i->second.majorType != MFMediaType_Video)
continue;
if (newType.isEmpty()) // file input - choose first returned media type
{
best = *i;
break;
}
if (best.second.isEmpty() || i->second.isBetterThan(best.second, newType))
{
best = *i;
}
}
return best;
}
private:
std::map<MediaID, MediaType> formats;
};
//==================================================================================================
// Enumerates devices and activates one of them
class DeviceList
{
public:
DeviceList() : devices(NULL), count(0) {}
~DeviceList()
{
if (devices)
{
for (UINT32 i = 0; i < count; ++i)
if (devices[i])
devices[i]->Release();
CoTaskMemFree(devices);
}
}
UINT32 read(IID sourceType = MF_DEVSOURCE_ATTRIBUTE_SOURCE_TYPE_VIDCAP_GUID)
{
_ComPtr<IMFAttributes> attr;
if (FAILED(MFCreateAttributes(&attr, 1)) ||
FAILED(attr->SetGUID(MF_DEVSOURCE_ATTRIBUTE_SOURCE_TYPE, sourceType)))
{
CV_Error(CV_StsError, "Failed to create attributes");
}
if (FAILED(MFEnumDeviceSources(attr.Get(), &devices, &count)))
{
CV_LOG_DEBUG(NULL, "Failed to enumerate MSMF devices");
return 0;
}
return count;
}
_ComPtr<IMFMediaSource> activateSource(UINT32 index)
{
_ComPtr<IMFMediaSource> result;
if (count == 0 || index >= count || FAILED(devices[index]->ActivateObject(__uuidof(IMFMediaSource), (void**)&result)))
{
CV_LOG_DEBUG(NULL, "Failed to activate media source (device " << index << ")");
}
return result;
}
private:
IMFActivate** devices;
UINT32 count;
};
} // namespace::
//==================================================================================================
/******* Capturing video from camera or file via Microsoft Media Foundation **********/
class CvCapture_MSMF : public cv::IVideoCapture
{
public:
typedef enum {
MODE_SW = 0,
MODE_HW = 1
} MSMFCapture_Mode;
CvCapture_MSMF();
virtual ~CvCapture_MSMF();
virtual bool open(int);
virtual bool open(const cv::String&);
virtual void close();
virtual double getProperty(int) const CV_OVERRIDE;
virtual bool setProperty(int, double) CV_OVERRIDE;
virtual bool grabFrame() CV_OVERRIDE;
virtual bool retrieveFrame(int, cv::OutputArray) CV_OVERRIDE;
virtual bool isOpened() const CV_OVERRIDE { return isOpen; }
virtual int getCaptureDomain() CV_OVERRIDE { return CV_CAP_MSMF; }
protected:
bool configureOutput(MediaType newType, cv::uint32_t outFormat);
bool setTime(double time, bool rough);
bool configureHW(bool enable);
template <typename CtrlT>
bool readComplexPropery(long prop, long& val) const;
template <typename CtrlT>
bool writeComplexProperty(long prop, double val, long flags);
_ComPtr<IMFAttributes> getDefaultSourceConfig(UINT32 num = 10);
bool initStream(DWORD streamID, const MediaType& mt);
Media_Foundation& MF;
cv::String filename;
int camid;
MSMFCapture_Mode captureMode;
#ifdef HAVE_MSMF_DXVA
_ComPtr<ID3D11Device> D3DDev;
_ComPtr<IMFDXGIDeviceManager> D3DMgr;
#endif
_ComPtr<IMFSourceReader> videoFileSource;
DWORD dwStreamIndex;
MediaType nativeFormat;
MediaType captureFormat;
int outputFormat;
bool convertFormat;
MFTIME duration;
LONGLONG frameStep;
_ComPtr<IMFSample> videoSample;
LONGLONG sampleTime;
bool isOpen;
_ComPtr<IMFSourceReaderCallback> readCallback; // non-NULL for "live" streams (camera capture)
};
CvCapture_MSMF::CvCapture_MSMF():
MF(Media_Foundation::getInstance()),
filename(""),
camid(-1),
captureMode(MODE_SW),
#ifdef HAVE_MSMF_DXVA
D3DDev(NULL),
D3DMgr(NULL),
#endif
videoFileSource(NULL),
videoSample(NULL),
outputFormat(CV_CAP_MODE_BGR),
convertFormat(true),
sampleTime(0),
isOpen(false)
{
configureHW(true);
}
CvCapture_MSMF::~CvCapture_MSMF()
{
close();
configureHW(false);
}
void CvCapture_MSMF::close()
{
if (isOpen)
{
isOpen = false;
videoSample.Release();
videoFileSource.Release();
camid = -1;
filename.clear();
}
readCallback.Release();
}
bool CvCapture_MSMF::initStream(DWORD streamID, const MediaType& mt)
{
CV_LOG_DEBUG(NULL, "Init stream " << streamID << " with MediaType " << mt);
_ComPtr<IMFMediaType> mediaTypeOut = mt.createMediaType();
if (FAILED(videoFileSource->SetStreamSelection((DWORD)MF_SOURCE_READER_ALL_STREAMS, false)))
{
CV_LOG_WARNING(NULL, "Failed to reset streams");
return false;
}
if (FAILED(videoFileSource->SetStreamSelection(streamID, true)))
{
CV_LOG_WARNING(NULL, "Failed to select stream " << streamID);
return false;
}
HRESULT hr = videoFileSource->SetCurrentMediaType(streamID, NULL, mediaTypeOut.Get());
if (hr == MF_E_TOPO_CODEC_NOT_FOUND)
{
CV_LOG_WARNING(NULL, "Failed to set mediaType (stream " << streamID << ", " << mt << "(codec not found)");
return false;
}
else if (hr == MF_E_INVALIDMEDIATYPE)
{
CV_LOG_WARNING(NULL, "Failed to set mediaType (stream " << streamID << ", " << mt << "(unsupported media type)");
return false;
}
else if (FAILED(hr))
{
CV_LOG_WARNING(NULL, "Failed to set mediaType (stream " << streamID << ", " << mt << "(HRESULT " << hr << ")");
return false;
}
captureFormat = mt;
return true;
}
_ComPtr<IMFAttributes> CvCapture_MSMF::getDefaultSourceConfig(UINT32 num)
{
CV_Assert(num > 0);
_ComPtr<IMFAttributes> res;
if (FAILED(MFCreateAttributes(&res, num)) ||
FAILED(res->SetUINT32(MF_READWRITE_ENABLE_HARDWARE_TRANSFORMS, true)) ||
FAILED(res->SetUINT32(MF_SOURCE_READER_DISABLE_DXVA, false)) ||
FAILED(res->SetUINT32(MF_SOURCE_READER_ENABLE_VIDEO_PROCESSING, false)) ||
FAILED(res->SetUINT32(MF_SOURCE_READER_ENABLE_ADVANCED_VIDEO_PROCESSING, true))
)
{
CV_Error(CV_StsError, "Failed to create attributes");
}
#ifdef HAVE_MSMF_DXVA
if (D3DMgr)
{
if (FAILED(res->SetUnknown(MF_SOURCE_READER_D3D_MANAGER, D3DMgr.Get())))
{
CV_Error(CV_StsError, "Failed to create attributes");
}
}
#endif
return res;
}
bool CvCapture_MSMF::configureHW(bool enable)
{
#ifdef HAVE_MSMF_DXVA
if ((enable && D3DMgr && D3DDev) || (!enable && !D3DMgr && !D3DDev))
return true;
if (!pMFCreateDXGIDeviceManager_initialized)
init_MFCreateDXGIDeviceManager();
if (enable && !pMFCreateDXGIDeviceManager)
return false;
bool reopen = isOpen;
int prevcam = camid;
cv::String prevfile = filename;
close();
if (enable)
{
D3D_FEATURE_LEVEL levels[] = { D3D_FEATURE_LEVEL_11_1, D3D_FEATURE_LEVEL_11_0,
D3D_FEATURE_LEVEL_10_1, D3D_FEATURE_LEVEL_10_0,
D3D_FEATURE_LEVEL_9_3, D3D_FEATURE_LEVEL_9_2, D3D_FEATURE_LEVEL_9_1 };
if (SUCCEEDED(D3D11CreateDevice(NULL, D3D_DRIVER_TYPE_HARDWARE, NULL, D3D11_CREATE_DEVICE_BGRA_SUPPORT | D3D11_CREATE_DEVICE_VIDEO_SUPPORT,
levels, sizeof(levels) / sizeof(*levels), D3D11_SDK_VERSION, &D3DDev, NULL, NULL)))
{
// NOTE: Getting ready for multi-threaded operation
_ComPtr<ID3D11Multithread> D3DDevMT;
UINT mgrRToken;
if (SUCCEEDED(D3DDev->QueryInterface(IID_PPV_ARGS(&D3DDevMT))))
{
D3DDevMT->SetMultithreadProtected(TRUE);
D3DDevMT.Release();
if (SUCCEEDED(pMFCreateDXGIDeviceManager(&mgrRToken, &D3DMgr)))
{
if (SUCCEEDED(D3DMgr->ResetDevice(D3DDev.Get(), mgrRToken)))
{
captureMode = MODE_HW;
return reopen ? (prevcam >= 0 ? open(prevcam) : open(prevfile.c_str())) : true;
}
D3DMgr.Release();
}
}
D3DDev.Release();
}
return false;
}
else
{
if (D3DMgr)
D3DMgr.Release();
if (D3DDev)
D3DDev.Release();
captureMode = MODE_SW;
return reopen ? (prevcam >= 0 ? open(prevcam) : open(prevfile.c_str())) : true;
}
#else
return !enable;
#endif
}
bool CvCapture_MSMF::configureOutput(MediaType newType, cv::uint32_t outFormat)
{
FormatStorage formats;
formats.read(videoFileSource.Get());
std::pair<FormatStorage::MediaID, MediaType> bestMatch = formats.findBestVideoFormat(newType);
if (bestMatch.second.isEmpty())
{
CV_LOG_DEBUG(NULL, "Can not find video stream with requested parameters");
return false;
}
dwStreamIndex = bestMatch.first.stream;
nativeFormat = bestMatch.second;
MediaType newFormat = nativeFormat;
if (convertFormat)
{
switch (outFormat)
{
case CV_CAP_MODE_BGR:
case CV_CAP_MODE_RGB:
newFormat.subType = captureMode == MODE_HW ? MFVideoFormat_RGB32 : MFVideoFormat_RGB24;
newFormat.stride = (captureMode == MODE_HW ? 4 : 3) * newFormat.width;
newFormat.sampleSize = newFormat.stride * newFormat.height;
break;
case CV_CAP_MODE_GRAY:
newFormat.subType = MFVideoFormat_YUY2;
newFormat.stride = newFormat.width;
newFormat.sampleSize = newFormat.stride * newFormat.height * 3 / 2;
break;
case CV_CAP_MODE_YUYV:
newFormat.subType = MFVideoFormat_YUY2;
newFormat.stride = 2 * newFormat.width;
newFormat.sampleSize = newFormat.stride * newFormat.height;
break;
default:
return false;
}
newFormat.interlaceMode = MFVideoInterlace_Progressive;
newFormat.isFixedSize = true;
if (nativeFormat.subType == MFVideoFormat_MP43) //Unable to estimate FPS for MP43
newFormat.frameRateNum = 0;
}
// we select native format first and then our requested format (related issue #12822)
if (!newType.isEmpty()) // camera input
initStream(dwStreamIndex, nativeFormat);
return initStream(dwStreamIndex, newFormat);
}
bool CvCapture_MSMF::open(int index)
{
close();
if (index < 0)
return false;
DeviceList devices;
UINT32 count = devices.read();
if (count == 0 || static_cast<UINT32>(index) > count)
{
CV_LOG_DEBUG(NULL, "Device " << index << " not found (total " << count << " devices)");
return false;
}
_ComPtr<IMFAttributes> attr = getDefaultSourceConfig();
_ComPtr<IMFSourceReaderCallback> cb = new SourceReaderCB();
attr->SetUnknown(MF_SOURCE_READER_ASYNC_CALLBACK, cb.Get());
_ComPtr<IMFMediaSource> src = devices.activateSource(index);
if (!src.Get() || FAILED(MFCreateSourceReaderFromMediaSource(src.Get(), attr.Get(), &videoFileSource)))
{
CV_LOG_DEBUG(NULL, "Failed to create source reader");
return false;
}
isOpen = true;
camid = index;
readCallback = cb;
duration = 0;
if (configureOutput(MediaType::createDefault(), outputFormat))
{
frameStep = captureFormat.getFrameStep();
}
return isOpen;
}
bool CvCapture_MSMF::open(const cv::String& _filename)
{
close();
if (_filename.empty())
return false;
// Set source reader parameters
_ComPtr<IMFAttributes> attr = getDefaultSourceConfig();
cv::AutoBuffer<wchar_t> unicodeFileName(_filename.length() + 1);
MultiByteToWideChar(CP_ACP, 0, _filename.c_str(), -1, unicodeFileName.data(), (int)_filename.length() + 1);
if (SUCCEEDED(MFCreateSourceReaderFromURL(unicodeFileName.data(), attr.Get(), &videoFileSource)))
{
isOpen = true;
sampleTime = 0;
if (configureOutput(MediaType(), outputFormat))
{
frameStep = captureFormat.getFrameStep();
filename = _filename;
PROPVARIANT var;
HRESULT hr;
if (SUCCEEDED(hr = videoFileSource->GetPresentationAttribute((DWORD)MF_SOURCE_READER_MEDIASOURCE, MF_PD_DURATION, &var)) &&
var.vt == VT_UI8)
{
duration = var.uhVal.QuadPart;
PropVariantClear(&var);
}
else
duration = 0;
}
}
return isOpen;
}
bool CvCapture_MSMF::grabFrame()
{
CV_TRACE_FUNCTION();
if (readCallback) // async "live" capture mode
{
HRESULT hr = 0;
SourceReaderCB* reader = ((SourceReaderCB*)readCallback.Get());
if (!reader->m_reader)
{
// Initiate capturing with async callback
reader->m_reader = videoFileSource.Get();
reader->m_dwStreamIndex = dwStreamIndex;
if (FAILED(hr = videoFileSource->ReadSample(dwStreamIndex, 0, NULL, NULL, NULL, NULL)))
{
CV_LOG_ERROR(NULL, "videoio(MSMF): can't grab frame - initial async ReadSample() call failed: " << hr);
reader->m_reader = NULL;
return false;
}
}
BOOL bEOS = false;
if (FAILED(hr = reader->Wait(10000, videoSample, bEOS))) // 10 sec
{
CV_LOG_WARNING(NULL, "videoio(MSMF): can't grab frame. Error: " << hr);
return false;
}
if (bEOS)
{
CV_LOG_WARNING(NULL, "videoio(MSMF): EOS signal. Capture stream is lost");
return false;
}
sampleTime = reader->m_lastSampleTimestamp;
return true;
}
else if (isOpen)
{
DWORD streamIndex, flags;
videoSample.Release();
HRESULT hr;
for(;;)
{
CV_TRACE_REGION("ReadSample");
if (!SUCCEEDED(hr = videoFileSource->ReadSample(
dwStreamIndex, // Stream index.
0, // Flags.
&streamIndex, // Receives the actual stream index.
&flags, // Receives status flags.
&sampleTime, // Receives the time stamp.
&videoSample // Receives the sample or NULL.
)))
break;
if (streamIndex != dwStreamIndex)
break;
if (flags & (MF_SOURCE_READERF_ERROR | MF_SOURCE_READERF_ALLEFFECTSREMOVED | MF_SOURCE_READERF_ENDOFSTREAM))
break;
if (videoSample)
break;
if (flags & MF_SOURCE_READERF_STREAMTICK)
{
CV_LOG_DEBUG(NULL, "videoio(MSMF): Stream tick detected. Retrying to grab the frame");
}
}
if (SUCCEEDED(hr))
{
if (streamIndex != dwStreamIndex)
{
CV_LOG_DEBUG(NULL, "videoio(MSMF): Wrong stream read. Abort capturing");
close();
}
else if (flags & MF_SOURCE_READERF_ERROR)
{
CV_LOG_DEBUG(NULL, "videoio(MSMF): Stream reading error. Abort capturing");
close();
}
else if (flags & MF_SOURCE_READERF_ALLEFFECTSREMOVED)
{
CV_LOG_DEBUG(NULL, "videoio(MSMF): Stream decoding error. Abort capturing");
close();
}
else if (flags & MF_SOURCE_READERF_ENDOFSTREAM)
{
sampleTime += frameStep;
CV_LOG_DEBUG(NULL, "videoio(MSMF): End of stream detected");
}
else
{
sampleTime += frameStep;
if (flags & MF_SOURCE_READERF_NEWSTREAM)
{
CV_LOG_DEBUG(NULL, "videoio(MSMF): New stream detected");
}
if (flags & MF_SOURCE_READERF_NATIVEMEDIATYPECHANGED)
{
CV_LOG_DEBUG(NULL, "videoio(MSMF): Stream native media type changed");
}
if (flags & MF_SOURCE_READERF_CURRENTMEDIATYPECHANGED)
{
CV_LOG_DEBUG(NULL, "videoio(MSMF): Stream current media type changed");
}
return true;
}
}
}
return false;
}
bool CvCapture_MSMF::retrieveFrame(int, cv::OutputArray frame)
{
CV_TRACE_FUNCTION();
do
{
if (!videoSample)
break;
_ComPtr<IMFMediaBuffer> buf = NULL;
CV_TRACE_REGION("get_contiguous_buffer");
if (!SUCCEEDED(videoSample->ConvertToContiguousBuffer(&buf)))
{
CV_TRACE_REGION("get_buffer");
DWORD bcnt = 0;
if (!SUCCEEDED(videoSample->GetBufferCount(&bcnt)))
break;
if (bcnt == 0)
break;
if (!SUCCEEDED(videoSample->GetBufferByIndex(0, &buf)))
break;
}
bool lock2d = false;
BYTE* ptr = NULL;
LONG pitch = 0;
DWORD maxsize = 0, cursize = 0;
// "For 2-D buffers, the Lock2D method is more efficient than the Lock method"
// see IMFMediaBuffer::Lock method documentation: https://msdn.microsoft.com/en-us/library/windows/desktop/bb970366(v=vs.85).aspx
_ComPtr<IMF2DBuffer> buffer2d;
if (convertFormat)
{
if (SUCCEEDED(buf.As<IMF2DBuffer>(buffer2d)))
{
CV_TRACE_REGION_NEXT("lock2d");
if (SUCCEEDED(buffer2d->Lock2D(&ptr, &pitch)))
{
lock2d = true;
}
}
}
if (ptr == NULL)
{
CV_Assert(lock2d == false);
CV_TRACE_REGION_NEXT("lock");
if (!SUCCEEDED(buf->Lock(&ptr, &maxsize, &cursize)))
{
break;
}
}
if (!ptr)
break;
if (convertFormat)
{
if (lock2d || (unsigned int)cursize == captureFormat.sampleSize)
{
switch (outputFormat)
{
case CV_CAP_MODE_YUYV:
cv::Mat(captureFormat.height, captureFormat.width, CV_8UC2, ptr, pitch).copyTo(frame);
break;
case CV_CAP_MODE_BGR:
if (captureMode == MODE_HW)
cv::cvtColor(cv::Mat(captureFormat.height, captureFormat.width, CV_8UC4, ptr, pitch), frame, cv::COLOR_BGRA2BGR);
else
cv::Mat(captureFormat.height, captureFormat.width, CV_8UC3, ptr, pitch).copyTo(frame);
break;
case CV_CAP_MODE_RGB:
if (captureMode == MODE_HW)
cv::cvtColor(cv::Mat(captureFormat.height, captureFormat.width, CV_8UC4, ptr, pitch), frame, cv::COLOR_BGRA2BGR);
else
cv::cvtColor(cv::Mat(captureFormat.height, captureFormat.width, CV_8UC3, ptr, pitch), frame, cv::COLOR_BGR2RGB);
break;
case CV_CAP_MODE_GRAY:
cv::Mat(captureFormat.height, captureFormat.width, CV_8UC1, ptr, pitch).copyTo(frame);
break;
default:
frame.release();
break;
}
}
else
frame.release();
}
else
{
cv::Mat(1, cursize, CV_8UC1, ptr, pitch).copyTo(frame);
}
CV_TRACE_REGION_NEXT("unlock");
if (lock2d)
buffer2d->Unlock2D();
else
buf->Unlock();
return !frame.empty();
} while (0);
frame.release();
return false;
}
bool CvCapture_MSMF::setTime(double time, bool rough)
{
PROPVARIANT var;
if (SUCCEEDED(videoFileSource->GetPresentationAttribute((DWORD)MF_SOURCE_READER_MEDIASOURCE, MF_SOURCE_READER_MEDIASOURCE_CHARACTERISTICS, &var)) &&
var.vt == VT_UI4 && var.ulVal & MFMEDIASOURCE_CAN_SEEK)
{
videoSample.Release();
bool useGrabbing = time > 0 && !rough && !(var.ulVal & MFMEDIASOURCE_HAS_SLOW_SEEK);
PropVariantClear(&var);
sampleTime = (useGrabbing && time >= frameStep) ? (LONGLONG)floor(time + 0.5) - frameStep : (LONGLONG)floor(time + 0.5);
var.vt = VT_I8;
var.hVal.QuadPart = sampleTime;
bool resOK = SUCCEEDED(videoFileSource->SetCurrentPosition(GUID_NULL, var));
PropVariantClear(&var);
if (resOK && useGrabbing)
{
LONGLONG timeborder = (LONGLONG)floor(time + 0.5) - frameStep / 2;
do { resOK = grabFrame(); videoSample.Release(); } while (resOK && sampleTime < timeborder);
}
return resOK;
}
return false;
}
template <typename CtrlT>
bool CvCapture_MSMF::readComplexPropery(long prop, long & val) const
{
_ComPtr<CtrlT> ctrl;
if (FAILED(videoFileSource->GetServiceForStream((DWORD)MF_SOURCE_READER_MEDIASOURCE, GUID_NULL, IID_PPV_ARGS(&ctrl))))
{
CV_LOG_DEBUG(NULL, "Failed to get service for stream");
return false;
}
long paramVal, paramFlag;
if (FAILED(ctrl->Get(prop, &paramVal, &paramFlag)))
{
CV_LOG_DEBUG(NULL, "Failed to get property " << prop);
// we continue
}
// fallback - get default value
long minVal, maxVal, stepVal;
if (FAILED(ctrl->GetRange(prop, &minVal, &maxVal, &stepVal, &paramVal, &paramFlag)))
{
CV_LOG_DEBUG(NULL, "Failed to get default value for property " << prop);
return false;
}
val = paramVal;
return true;
}
double CvCapture_MSMF::getProperty( int property_id ) const
{
long cVal = 0;
if (isOpen)
switch (property_id)
{
case CV_CAP_PROP_MODE:
return captureMode;
case CV_CAP_PROP_CONVERT_RGB:
return convertFormat ? 1 : 0;
case CV_CAP_PROP_SAR_NUM:
return captureFormat.aspectRatioNum;
case CV_CAP_PROP_SAR_DEN:
return captureFormat.aspectRatioDenom;
case CV_CAP_PROP_FRAME_WIDTH:
return captureFormat.width;
case CV_CAP_PROP_FRAME_HEIGHT:
return captureFormat.height;
case CV_CAP_PROP_FOURCC:
return captureFormat.subType.Data1;
case CV_CAP_PROP_FPS:
return captureFormat.getFramerate();
case CV_CAP_PROP_FRAME_COUNT:
if (duration != 0)
return floor(((double)duration / 1e7)* captureFormat.getFramerate() + 0.5);
else
break;
case CV_CAP_PROP_POS_FRAMES:
return floor(((double)sampleTime / 1e7)* captureFormat.getFramerate() + 0.5);
case CV_CAP_PROP_POS_MSEC:
return (double)sampleTime / 1e4;
case CV_CAP_PROP_POS_AVI_RATIO:
if (duration != 0)
return (double)sampleTime / duration;
else
break;
case CV_CAP_PROP_BRIGHTNESS:
if (readComplexPropery<IAMVideoProcAmp>(VideoProcAmp_Brightness, cVal))
return cVal;
break;
case CV_CAP_PROP_CONTRAST:
if (readComplexPropery<IAMVideoProcAmp>(VideoProcAmp_Contrast, cVal))
return cVal;
break;
case CV_CAP_PROP_SATURATION:
if (readComplexPropery<IAMVideoProcAmp>(VideoProcAmp_Saturation, cVal))
return cVal;
break;
case CV_CAP_PROP_HUE:
if (readComplexPropery<IAMVideoProcAmp>(VideoProcAmp_Hue, cVal))
return cVal;
break;
case CV_CAP_PROP_GAIN:
if (readComplexPropery<IAMVideoProcAmp>(VideoProcAmp_Gain, cVal))
return cVal;
break;
case CV_CAP_PROP_SHARPNESS:
if (readComplexPropery<IAMVideoProcAmp>(VideoProcAmp_Sharpness, cVal))
return cVal;
break;
case CV_CAP_PROP_GAMMA:
if (readComplexPropery<IAMVideoProcAmp>(VideoProcAmp_Gamma, cVal))
return cVal;
break;
case CV_CAP_PROP_BACKLIGHT:
if (readComplexPropery<IAMVideoProcAmp>(VideoProcAmp_BacklightCompensation, cVal))
return cVal;
break;
case CV_CAP_PROP_MONOCHROME:
if (readComplexPropery<IAMVideoProcAmp>(VideoProcAmp_ColorEnable, cVal))
return cVal == 0 ? 1 : 0;
break;
case CV_CAP_PROP_TEMPERATURE:
if (readComplexPropery<IAMVideoProcAmp>(VideoProcAmp_WhiteBalance, cVal))
return cVal;
break;
case CV_CAP_PROP_PAN:
if (readComplexPropery<IAMCameraControl>(CameraControl_Pan, cVal))
return cVal;
break;
case CV_CAP_PROP_TILT:
if (readComplexPropery<IAMCameraControl>(CameraControl_Tilt, cVal))
return cVal;
break;
case CV_CAP_PROP_ROLL:
if (readComplexPropery<IAMCameraControl>(CameraControl_Roll, cVal))
return cVal;
break;
case CV_CAP_PROP_IRIS:
if (readComplexPropery<IAMCameraControl>(CameraControl_Iris, cVal))
return cVal;
break;
case CV_CAP_PROP_EXPOSURE:
case CV_CAP_PROP_AUTO_EXPOSURE:
if (readComplexPropery<IAMCameraControl>(CameraControl_Exposure, cVal))
{
if (property_id == CV_CAP_PROP_EXPOSURE)
return cVal;
else
return cVal == VideoProcAmp_Flags_Auto;
}
break;
case CV_CAP_PROP_ZOOM:
if (readComplexPropery<IAMCameraControl>(CameraControl_Zoom, cVal))
return cVal;
break;
case CV_CAP_PROP_FOCUS:
case CV_CAP_PROP_AUTOFOCUS:
if (readComplexPropery<IAMCameraControl>(CameraControl_Focus, cVal))
{
if (property_id == CV_CAP_PROP_FOCUS)
return cVal;
else
return cVal == VideoProcAmp_Flags_Auto;
}
break;
case CV_CAP_PROP_WHITE_BALANCE_BLUE_U:
case CV_CAP_PROP_WHITE_BALANCE_RED_V:
case CV_CAP_PROP_RECTIFICATION:
case CV_CAP_PROP_TRIGGER:
case CV_CAP_PROP_TRIGGER_DELAY:
case CV_CAP_PROP_GUID:
case CV_CAP_PROP_ISO_SPEED:
case CV_CAP_PROP_SETTINGS:
case CV_CAP_PROP_BUFFERSIZE:
default:
break;
}
return -1;
}
template <typename CtrlT>
bool CvCapture_MSMF::writeComplexProperty(long prop, double val, long flags)
{
_ComPtr<CtrlT> ctrl;
if (FAILED(videoFileSource->GetServiceForStream((DWORD)MF_SOURCE_READER_MEDIASOURCE, GUID_NULL, IID_PPV_ARGS(&ctrl))))
{
CV_LOG_DEBUG(NULL, "Failed get service for stream");
return false;
}
if (FAILED(ctrl->Set(prop, (long)val, flags)))
{
CV_LOG_DEBUG(NULL, "Failed to set property " << prop);
return false;
}
return true;
}
bool CvCapture_MSMF::setProperty( int property_id, double value )
{
MediaType newFormat = captureFormat;
if (isOpen)
switch (property_id)
{
case CV_CAP_PROP_MODE:
switch ((MSMFCapture_Mode)((int)value))
{
case MODE_SW:
return configureHW(false);
case MODE_HW:
return configureHW(true);
default:
return false;
}
case CV_CAP_PROP_FOURCC:
return configureOutput(newFormat, (int)cvRound(value));
case CV_CAP_PROP_FORMAT:
return configureOutput(newFormat, (int)cvRound(value));
case CV_CAP_PROP_CONVERT_RGB:
convertFormat = (value != 0);
return configureOutput(newFormat, outputFormat);
case CV_CAP_PROP_SAR_NUM:
if (value > 0)
{
newFormat.aspectRatioNum = (UINT32)cvRound(value);
return configureOutput(newFormat, outputFormat);
}
break;
case CV_CAP_PROP_SAR_DEN:
if (value > 0)
{
newFormat.aspectRatioDenom = (UINT32)cvRound(value);
return configureOutput(newFormat, outputFormat);
}
break;
case CV_CAP_PROP_FRAME_WIDTH:
if (value >= 0)
{
newFormat.width = (UINT32)cvRound(value);
return configureOutput(newFormat, outputFormat);
}
break;
case CV_CAP_PROP_FRAME_HEIGHT:
if (value >= 0)
{
newFormat.height = (UINT32)cvRound(value);
return configureOutput(newFormat, outputFormat);
}
break;
case CV_CAP_PROP_FPS:
if (value >= 0)
{
newFormat.setFramerate(value);
return configureOutput(newFormat, outputFormat);
}
break;
case CV_CAP_PROP_FRAME_COUNT:
break;
case CV_CAP_PROP_POS_AVI_RATIO:
if (duration != 0)
return setTime(duration * value, true);
break;
case CV_CAP_PROP_POS_FRAMES:
if (std::fabs(captureFormat.getFramerate()) > 0)
return setTime(value * 1e7 / captureFormat.getFramerate(), false);
break;
case CV_CAP_PROP_POS_MSEC:
return setTime(value * 1e4, false);
case CV_CAP_PROP_BRIGHTNESS:
return writeComplexProperty<IAMVideoProcAmp>(VideoProcAmp_Brightness, value, VideoProcAmp_Flags_Manual);
case CV_CAP_PROP_CONTRAST:
return writeComplexProperty<IAMVideoProcAmp>(VideoProcAmp_Contrast, value, VideoProcAmp_Flags_Manual);
case CV_CAP_PROP_SATURATION:
return writeComplexProperty<IAMVideoProcAmp>(VideoProcAmp_Saturation, value, VideoProcAmp_Flags_Manual);
case CV_CAP_PROP_HUE:
return writeComplexProperty<IAMVideoProcAmp>(VideoProcAmp_Hue, value, VideoProcAmp_Flags_Manual);
case CV_CAP_PROP_GAIN:
return writeComplexProperty<IAMVideoProcAmp>(VideoProcAmp_Gain, value, VideoProcAmp_Flags_Manual);
case CV_CAP_PROP_SHARPNESS:
return writeComplexProperty<IAMVideoProcAmp>(VideoProcAmp_Sharpness, value, VideoProcAmp_Flags_Manual);
case CV_CAP_PROP_GAMMA:
return writeComplexProperty<IAMVideoProcAmp>(VideoProcAmp_Gamma, value, VideoProcAmp_Flags_Manual);
case CV_CAP_PROP_BACKLIGHT:
return writeComplexProperty<IAMVideoProcAmp>(VideoProcAmp_BacklightCompensation, value, VideoProcAmp_Flags_Manual);
case CV_CAP_PROP_MONOCHROME:
return writeComplexProperty<IAMVideoProcAmp>(VideoProcAmp_ColorEnable, value, VideoProcAmp_Flags_Manual);
case CV_CAP_PROP_TEMPERATURE:
return writeComplexProperty<IAMVideoProcAmp>(VideoProcAmp_WhiteBalance, value, VideoProcAmp_Flags_Manual);
case CV_CAP_PROP_PAN:
return writeComplexProperty<IAMCameraControl>(CameraControl_Pan, value, CameraControl_Flags_Manual);
case CV_CAP_PROP_TILT:
return writeComplexProperty<IAMCameraControl>(CameraControl_Tilt, value, CameraControl_Flags_Manual);
case CV_CAP_PROP_ROLL:
return writeComplexProperty<IAMCameraControl>(CameraControl_Roll, value, CameraControl_Flags_Manual);
case CV_CAP_PROP_IRIS:
return writeComplexProperty<IAMCameraControl>(CameraControl_Iris, value, CameraControl_Flags_Manual);
case CV_CAP_PROP_EXPOSURE:
return writeComplexProperty<IAMCameraControl>(CameraControl_Exposure, value, CameraControl_Flags_Manual);
case CV_CAP_PROP_AUTO_EXPOSURE:
return writeComplexProperty<IAMCameraControl>(CameraControl_Exposure, value, value != 0 ? VideoProcAmp_Flags_Auto : VideoProcAmp_Flags_Manual);
case CV_CAP_PROP_ZOOM:
return writeComplexProperty<IAMCameraControl>(CameraControl_Zoom, value, CameraControl_Flags_Manual);
case CV_CAP_PROP_FOCUS:
return writeComplexProperty<IAMCameraControl>(CameraControl_Focus, value, CameraControl_Flags_Manual);
case CV_CAP_PROP_AUTOFOCUS:
return writeComplexProperty<IAMCameraControl>(CameraControl_Focus, value, value != 0 ? CameraControl_Flags_Auto : CameraControl_Flags_Manual);
case CV_CAP_PROP_WHITE_BALANCE_BLUE_U:
case CV_CAP_PROP_WHITE_BALANCE_RED_V:
case CV_CAP_PROP_RECTIFICATION:
case CV_CAP_PROP_TRIGGER:
case CV_CAP_PROP_TRIGGER_DELAY:
case CV_CAP_PROP_GUID:
case CV_CAP_PROP_ISO_SPEED:
case CV_CAP_PROP_SETTINGS:
case CV_CAP_PROP_BUFFERSIZE:
default:
break;
}
return false;
}
cv::Ptr<cv::IVideoCapture> cv::cvCreateCapture_MSMF( int index )
{
cv::Ptr<CvCapture_MSMF> capture = cv::makePtr<CvCapture_MSMF>();
if (capture)
{
capture->open(index);
if (capture->isOpened())
return capture;
}
return cv::Ptr<cv::IVideoCapture>();
}
cv::Ptr<cv::IVideoCapture> cv::cvCreateCapture_MSMF (const cv::String& filename)
{
cv::Ptr<CvCapture_MSMF> capture = cv::makePtr<CvCapture_MSMF>();
if (capture)
{
capture->open(filename);
if (capture->isOpened())
return capture;
}
return cv::Ptr<cv::IVideoCapture>();
}
//
//
// Media Foundation-based Video Writer
//
//
class CvVideoWriter_MSMF : public cv::IVideoWriter
{
public:
CvVideoWriter_MSMF();
virtual ~CvVideoWriter_MSMF();
virtual bool open(const cv::String& filename, int fourcc,
double fps, cv::Size frameSize, bool isColor);
virtual void close();
virtual void write(cv::InputArray);
virtual double getProperty(int) const { return 0; }
virtual bool setProperty(int, double) { return false; }
virtual bool isOpened() const { return initiated; }
int getCaptureDomain() const CV_OVERRIDE { return cv::CAP_MSMF; }
private:
Media_Foundation& MF;
UINT32 videoWidth;
UINT32 videoHeight;
double fps;
UINT32 bitRate;
UINT32 frameSize;
GUID encodingFormat;
GUID inputFormat;
DWORD streamIndex;
Add support for WinRT in the MF capture framework by removing the disallowed calls to enumerate devices and create a sample grabber sink and adding framework for the MediaCapture interface and a custom sink which interfaces with the sample grabber callback interface. The change requires discussion for making it completely functional as redundancy is required given that if the source is a video file, the old code pathways must be used. Otherwise all IMFMediaSession, IMFMediaSource, and IMFActivate code must use a MediaCapture code path and all sink code must use the CMediaSink custom sink. Support for the custom sink is extended to non-WinRT not for compatibility as Windows Vista client is a minimum regardless, but because it offers more flexibility, could be faster and is able to be used as an optionally different code path during sink creation based on a future configuration parameter. My discussion and proposal to finish this change: Devices are so easily enumerated through WinRT Windows.Devices namespace that wrapping the calls in a library is quite a chore for little benefit though to get the various modes and formats could still be a worthwhile project. For now conditional compilation to remove videodevices and any offending non-video file related activity in videodevice. In my opinion, this is a different , far less fundamental and important change which can possibly be done as a future project and also much more easily implemented in C++/CX. ImageGrabber has the IMFSampleGrabberSinkCallback replaced with a base class (SharedSampleGrabber) which also be is base class for ImageGrabberRT. This change is necessary as the custom sink does not require a thread to pump events which is done through MediaCapture already. IMFSampleGrabberSinkCallback is the common element between both models and that piece can be shared. Initializing the new ImageGrabberRT is as simple as passing an already initialized MediaCapture object and any video format/encoding parameters. The concurrency event is necessary to wait for completion and is the way the underlying, IAsyncAction wrappers in the task library work as well. Native WIN32 event objects would be an option if HAVE_CONCURRENCY is not defined. I could even imagine doing it with sleep/thread yield and InterlockedCompareExchange yet I am not enthusiastic about that approach either. Since there is a specific compiler HAVE_ for concurrency, I do not like pulling it in though I think for WinRT it is safe to say we will always have it available though should probably conditionally compile with the Interlocked option as WIN32 events would require HAVE_WIN32. It looks like C++/CX cannot be used for the IMediaExtension sink (which should not be a problem) as using COM objects requires WRL and though deriving from IMediaExtension can be done, there is little purpose without COM. Objects from C++/CX can be swapped to interact with objects from native C++ as Inspectable* can reinterpret_cast to the ref object IInspectable^ and vice-versa. A solution to the COM class with C++/CX would be great so we could have dual support. Also without #define for every WRL object in use, the code will get quite muddy given that the */^ would need to be ifdef'd everywhere. Fixed bugs and completed the change. I believe the new classes need to be moved to a header file as the file has become to large and more classes need to be added for handling all the asynchronous problems (one wrapping IAsyncAction in a task and another for making a task out of IAsyncAction). Unfortunately, blocking on the UI thread is not an option in WinRT so a synchronous architecture is considered "illegal" by Microsoft's standards even if implementable (C++/CX ppltasks library throws errors if you try it). Worse, either by design or a bug in the MF MediaCapture class with Custom Sinks causes a crash if stop/start previewing without reinitializing (spPreferredPreviewMediaType is fatally nulled). After decompiling Windows.Media.dll, I worked around this in my own projects by using an activate-able custom sink ID which strangely assigns 1 to this pointer allowing it to be reinitialized in what can only be described as a hack by Microsoft. This would add additional overhead to the project to implement especially for static libraries as it requires IDL/DLL exporting followed by manifest declaration. Better to document that it is not supported. Furthermore, an additional class for IMFAttributes should be implemented to make clean architecture for passing around attributes as opposed to directly calling non-COM interface calls on the objects and making use of SetProperties which would also be a set up for an object that uses the RuntimeClass activation ID. The remaining changes are not difficult and will be complete soon along with debug tracing messages. Update and rename cap_msmf.h to cap_msmf.hpp Successful test - samples are grabbed Library updated and cleaned up with comments, marshaling, exceptions and linker settings Fixed trailing whitespace VS 2013 support and cleanup consistency plus C++/CX new object fixed Conflicts: modules/highgui/src/cap_msmf.cpp modules/highgui/src/cap_msmf.hpp modules/highgui/src/ppltasks_winrt.h Fix merge conflicts VS 2013 Update 2 library bug fix integrated a-wi's changed integrated
11 years ago
_ComPtr<IMFSinkWriter> sinkWriter;
bool initiated;
LONGLONG rtStart;
UINT64 rtDuration;
static const GUID FourCC2GUID(int fourcc);
};
CvVideoWriter_MSMF::CvVideoWriter_MSMF():
MF(Media_Foundation::getInstance()),
videoWidth(0),
videoHeight(0),
fps(0),
bitRate(0),
frameSize(0),
encodingFormat(),
inputFormat(),
streamIndex(0),
initiated(false),
rtStart(0),
rtDuration(0)
{
}
CvVideoWriter_MSMF::~CvVideoWriter_MSMF()
{
close();
}
const GUID CvVideoWriter_MSMF::FourCC2GUID(int fourcc)
{
switch(fourcc)
{
case CV_FOURCC_MACRO('d', 'v', '2', '5'):
return MFVideoFormat_DV25; break;
case CV_FOURCC_MACRO('d', 'v', '5', '0'):
return MFVideoFormat_DV50; break;
case CV_FOURCC_MACRO('d', 'v', 'c', ' '):
return MFVideoFormat_DVC; break;
case CV_FOURCC_MACRO('d', 'v', 'h', '1'):
return MFVideoFormat_DVH1; break;
case CV_FOURCC_MACRO('d', 'v', 'h', 'd'):
return MFVideoFormat_DVHD; break;
case CV_FOURCC_MACRO('d', 'v', 's', 'd'):
return MFVideoFormat_DVSD; break;
case CV_FOURCC_MACRO('d', 'v', 's', 'l'):
return MFVideoFormat_DVSL; break;
#if (WINVER >= 0x0602)
Add support for WinRT in the MF capture framework by removing the disallowed calls to enumerate devices and create a sample grabber sink and adding framework for the MediaCapture interface and a custom sink which interfaces with the sample grabber callback interface. The change requires discussion for making it completely functional as redundancy is required given that if the source is a video file, the old code pathways must be used. Otherwise all IMFMediaSession, IMFMediaSource, and IMFActivate code must use a MediaCapture code path and all sink code must use the CMediaSink custom sink. Support for the custom sink is extended to non-WinRT not for compatibility as Windows Vista client is a minimum regardless, but because it offers more flexibility, could be faster and is able to be used as an optionally different code path during sink creation based on a future configuration parameter. My discussion and proposal to finish this change: Devices are so easily enumerated through WinRT Windows.Devices namespace that wrapping the calls in a library is quite a chore for little benefit though to get the various modes and formats could still be a worthwhile project. For now conditional compilation to remove videodevices and any offending non-video file related activity in videodevice. In my opinion, this is a different , far less fundamental and important change which can possibly be done as a future project and also much more easily implemented in C++/CX. ImageGrabber has the IMFSampleGrabberSinkCallback replaced with a base class (SharedSampleGrabber) which also be is base class for ImageGrabberRT. This change is necessary as the custom sink does not require a thread to pump events which is done through MediaCapture already. IMFSampleGrabberSinkCallback is the common element between both models and that piece can be shared. Initializing the new ImageGrabberRT is as simple as passing an already initialized MediaCapture object and any video format/encoding parameters. The concurrency event is necessary to wait for completion and is the way the underlying, IAsyncAction wrappers in the task library work as well. Native WIN32 event objects would be an option if HAVE_CONCURRENCY is not defined. I could even imagine doing it with sleep/thread yield and InterlockedCompareExchange yet I am not enthusiastic about that approach either. Since there is a specific compiler HAVE_ for concurrency, I do not like pulling it in though I think for WinRT it is safe to say we will always have it available though should probably conditionally compile with the Interlocked option as WIN32 events would require HAVE_WIN32. It looks like C++/CX cannot be used for the IMediaExtension sink (which should not be a problem) as using COM objects requires WRL and though deriving from IMediaExtension can be done, there is little purpose without COM. Objects from C++/CX can be swapped to interact with objects from native C++ as Inspectable* can reinterpret_cast to the ref object IInspectable^ and vice-versa. A solution to the COM class with C++/CX would be great so we could have dual support. Also without #define for every WRL object in use, the code will get quite muddy given that the */^ would need to be ifdef'd everywhere. Fixed bugs and completed the change. I believe the new classes need to be moved to a header file as the file has become to large and more classes need to be added for handling all the asynchronous problems (one wrapping IAsyncAction in a task and another for making a task out of IAsyncAction). Unfortunately, blocking on the UI thread is not an option in WinRT so a synchronous architecture is considered "illegal" by Microsoft's standards even if implementable (C++/CX ppltasks library throws errors if you try it). Worse, either by design or a bug in the MF MediaCapture class with Custom Sinks causes a crash if stop/start previewing without reinitializing (spPreferredPreviewMediaType is fatally nulled). After decompiling Windows.Media.dll, I worked around this in my own projects by using an activate-able custom sink ID which strangely assigns 1 to this pointer allowing it to be reinitialized in what can only be described as a hack by Microsoft. This would add additional overhead to the project to implement especially for static libraries as it requires IDL/DLL exporting followed by manifest declaration. Better to document that it is not supported. Furthermore, an additional class for IMFAttributes should be implemented to make clean architecture for passing around attributes as opposed to directly calling non-COM interface calls on the objects and making use of SetProperties which would also be a set up for an object that uses the RuntimeClass activation ID. The remaining changes are not difficult and will be complete soon along with debug tracing messages. Update and rename cap_msmf.h to cap_msmf.hpp Successful test - samples are grabbed Library updated and cleaned up with comments, marshaling, exceptions and linker settings Fixed trailing whitespace VS 2013 support and cleanup consistency plus C++/CX new object fixed Conflicts: modules/highgui/src/cap_msmf.cpp modules/highgui/src/cap_msmf.hpp modules/highgui/src/ppltasks_winrt.h Fix merge conflicts VS 2013 Update 2 library bug fix integrated a-wi's changed integrated
11 years ago
case CV_FOURCC_MACRO('H', '2', '6', '3'): // Available only for Win 8 target.
return MFVideoFormat_H263; break;
Add support for WinRT in the MF capture framework by removing the disallowed calls to enumerate devices and create a sample grabber sink and adding framework for the MediaCapture interface and a custom sink which interfaces with the sample grabber callback interface. The change requires discussion for making it completely functional as redundancy is required given that if the source is a video file, the old code pathways must be used. Otherwise all IMFMediaSession, IMFMediaSource, and IMFActivate code must use a MediaCapture code path and all sink code must use the CMediaSink custom sink. Support for the custom sink is extended to non-WinRT not for compatibility as Windows Vista client is a minimum regardless, but because it offers more flexibility, could be faster and is able to be used as an optionally different code path during sink creation based on a future configuration parameter. My discussion and proposal to finish this change: Devices are so easily enumerated through WinRT Windows.Devices namespace that wrapping the calls in a library is quite a chore for little benefit though to get the various modes and formats could still be a worthwhile project. For now conditional compilation to remove videodevices and any offending non-video file related activity in videodevice. In my opinion, this is a different , far less fundamental and important change which can possibly be done as a future project and also much more easily implemented in C++/CX. ImageGrabber has the IMFSampleGrabberSinkCallback replaced with a base class (SharedSampleGrabber) which also be is base class for ImageGrabberRT. This change is necessary as the custom sink does not require a thread to pump events which is done through MediaCapture already. IMFSampleGrabberSinkCallback is the common element between both models and that piece can be shared. Initializing the new ImageGrabberRT is as simple as passing an already initialized MediaCapture object and any video format/encoding parameters. The concurrency event is necessary to wait for completion and is the way the underlying, IAsyncAction wrappers in the task library work as well. Native WIN32 event objects would be an option if HAVE_CONCURRENCY is not defined. I could even imagine doing it with sleep/thread yield and InterlockedCompareExchange yet I am not enthusiastic about that approach either. Since there is a specific compiler HAVE_ for concurrency, I do not like pulling it in though I think for WinRT it is safe to say we will always have it available though should probably conditionally compile with the Interlocked option as WIN32 events would require HAVE_WIN32. It looks like C++/CX cannot be used for the IMediaExtension sink (which should not be a problem) as using COM objects requires WRL and though deriving from IMediaExtension can be done, there is little purpose without COM. Objects from C++/CX can be swapped to interact with objects from native C++ as Inspectable* can reinterpret_cast to the ref object IInspectable^ and vice-versa. A solution to the COM class with C++/CX would be great so we could have dual support. Also without #define for every WRL object in use, the code will get quite muddy given that the */^ would need to be ifdef'd everywhere. Fixed bugs and completed the change. I believe the new classes need to be moved to a header file as the file has become to large and more classes need to be added for handling all the asynchronous problems (one wrapping IAsyncAction in a task and another for making a task out of IAsyncAction). Unfortunately, blocking on the UI thread is not an option in WinRT so a synchronous architecture is considered "illegal" by Microsoft's standards even if implementable (C++/CX ppltasks library throws errors if you try it). Worse, either by design or a bug in the MF MediaCapture class with Custom Sinks causes a crash if stop/start previewing without reinitializing (spPreferredPreviewMediaType is fatally nulled). After decompiling Windows.Media.dll, I worked around this in my own projects by using an activate-able custom sink ID which strangely assigns 1 to this pointer allowing it to be reinitialized in what can only be described as a hack by Microsoft. This would add additional overhead to the project to implement especially for static libraries as it requires IDL/DLL exporting followed by manifest declaration. Better to document that it is not supported. Furthermore, an additional class for IMFAttributes should be implemented to make clean architecture for passing around attributes as opposed to directly calling non-COM interface calls on the objects and making use of SetProperties which would also be a set up for an object that uses the RuntimeClass activation ID. The remaining changes are not difficult and will be complete soon along with debug tracing messages. Update and rename cap_msmf.h to cap_msmf.hpp Successful test - samples are grabbed Library updated and cleaned up with comments, marshaling, exceptions and linker settings Fixed trailing whitespace VS 2013 support and cleanup consistency plus C++/CX new object fixed Conflicts: modules/highgui/src/cap_msmf.cpp modules/highgui/src/cap_msmf.hpp modules/highgui/src/ppltasks_winrt.h Fix merge conflicts VS 2013 Update 2 library bug fix integrated a-wi's changed integrated
11 years ago
#endif
case CV_FOURCC_MACRO('H', '2', '6', '4'):
return MFVideoFormat_H264; break;
case CV_FOURCC_MACRO('M', '4', 'S', '2'):
return MFVideoFormat_M4S2; break;
case CV_FOURCC_MACRO('M', 'J', 'P', 'G'):
return MFVideoFormat_MJPG; break;
case CV_FOURCC_MACRO('M', 'P', '4', '3'):
return MFVideoFormat_MP43; break;
case CV_FOURCC_MACRO('M', 'P', '4', 'S'):
return MFVideoFormat_MP4S; break;
case CV_FOURCC_MACRO('M', 'P', '4', 'V'):
return MFVideoFormat_MP4V; break;
case CV_FOURCC_MACRO('M', 'P', 'G', '1'):
return MFVideoFormat_MPG1; break;
case CV_FOURCC_MACRO('M', 'S', 'S', '1'):
return MFVideoFormat_MSS1; break;
case CV_FOURCC_MACRO('M', 'S', 'S', '2'):
return MFVideoFormat_MSS2; break;
case CV_FOURCC_MACRO('W', 'M', 'V', '1'):
return MFVideoFormat_WMV1; break;
case CV_FOURCC_MACRO('W', 'M', 'V', '2'):
return MFVideoFormat_WMV2; break;
case CV_FOURCC_MACRO('W', 'M', 'V', '3'):
return MFVideoFormat_WMV3; break;
case CV_FOURCC_MACRO('W', 'V', 'C', '1'):
return MFVideoFormat_WVC1; break;
default:
return MFVideoFormat_H264;
}
}
bool CvVideoWriter_MSMF::open( const cv::String& filename, int fourcc,
double _fps, cv::Size _frameSize, bool /*isColor*/ )
{
if (initiated)
close();
videoWidth = _frameSize.width;
videoHeight = _frameSize.height;
fps = _fps;
bitRate = (UINT32)fps*videoWidth*videoHeight; // 1-bit per pixel
encodingFormat = FourCC2GUID(fourcc);
inputFormat = MFVideoFormat_RGB32;
_ComPtr<IMFMediaType> mediaTypeOut;
_ComPtr<IMFMediaType> mediaTypeIn;
_ComPtr<IMFAttributes> spAttr;
if (// Set the output media type.
SUCCEEDED(MFCreateMediaType(&mediaTypeOut)) &&
SUCCEEDED(mediaTypeOut->SetGUID(MF_MT_MAJOR_TYPE, MFMediaType_Video)) &&
SUCCEEDED(mediaTypeOut->SetGUID(MF_MT_SUBTYPE, encodingFormat)) &&
SUCCEEDED(mediaTypeOut->SetUINT32(MF_MT_AVG_BITRATE, bitRate)) &&
SUCCEEDED(mediaTypeOut->SetUINT32(MF_MT_INTERLACE_MODE, MFVideoInterlace_Progressive)) &&
SUCCEEDED(MFSetAttributeSize(mediaTypeOut.Get(), MF_MT_FRAME_SIZE, videoWidth, videoHeight)) &&
SUCCEEDED(MFSetAttributeRatio(mediaTypeOut.Get(), MF_MT_FRAME_RATE, (UINT32)(fps * 1000), 1000)) &&
SUCCEEDED(MFSetAttributeRatio(mediaTypeOut.Get(), MF_MT_PIXEL_ASPECT_RATIO, 1, 1)) &&
// Set the input media type.
SUCCEEDED(MFCreateMediaType(&mediaTypeIn)) &&
SUCCEEDED(mediaTypeIn->SetGUID(MF_MT_MAJOR_TYPE, MFMediaType_Video)) &&
SUCCEEDED(mediaTypeIn->SetGUID(MF_MT_SUBTYPE, inputFormat)) &&
SUCCEEDED(mediaTypeIn->SetUINT32(MF_MT_INTERLACE_MODE, MFVideoInterlace_Progressive)) &&
SUCCEEDED(mediaTypeIn->SetUINT32(MF_MT_DEFAULT_STRIDE, 4 * videoWidth)) && //Assume BGR32 input
SUCCEEDED(MFSetAttributeSize(mediaTypeIn.Get(), MF_MT_FRAME_SIZE, videoWidth, videoHeight)) &&
SUCCEEDED(MFSetAttributeRatio(mediaTypeIn.Get(), MF_MT_FRAME_RATE, (UINT32)(fps * 1000), 1000)) &&
SUCCEEDED(MFSetAttributeRatio(mediaTypeIn.Get(), MF_MT_PIXEL_ASPECT_RATIO, 1, 1)) &&
// Set sink writer parameters
SUCCEEDED(MFCreateAttributes(&spAttr, 10)) &&
SUCCEEDED(spAttr->SetUINT32(MF_READWRITE_ENABLE_HARDWARE_TRANSFORMS, true)) &&
SUCCEEDED(spAttr->SetUINT32(MF_SINK_WRITER_DISABLE_THROTTLING, true))
)
{
// Create the sink writer
cv::AutoBuffer<wchar_t> unicodeFileName(filename.length() + 1);
MultiByteToWideChar(CP_ACP, 0, filename.c_str(), -1, unicodeFileName.data(), (int)filename.length() + 1);
HRESULT hr = MFCreateSinkWriterFromURL(unicodeFileName.data(), NULL, spAttr.Get(), &sinkWriter);
if (SUCCEEDED(hr))
{
// Configure the sink writer and tell it start to start accepting data
if (SUCCEEDED(sinkWriter->AddStream(mediaTypeOut.Get(), &streamIndex)) &&
SUCCEEDED(sinkWriter->SetInputMediaType(streamIndex, mediaTypeIn.Get(), NULL)) &&
SUCCEEDED(sinkWriter->BeginWriting()))
{
initiated = true;
rtStart = 0;
MFFrameRateToAverageTimePerFrame((UINT32)(fps * 1000), 1000, &rtDuration);
return true;
}
}
}
return false;
}
void CvVideoWriter_MSMF::close()
{
if (initiated)
{
initiated = false;
sinkWriter->Finalize();
sinkWriter.Release();
}
}
void CvVideoWriter_MSMF::write(cv::InputArray img)
{
if (img.empty() ||
(img.channels() != 1 && img.channels() != 3 && img.channels() != 4) ||
(UINT32)img.cols() != videoWidth || (UINT32)img.rows() != videoHeight)
return;
const LONG cbWidth = 4 * videoWidth;
const DWORD cbBuffer = cbWidth * videoHeight;
_ComPtr<IMFSample> sample;
_ComPtr<IMFMediaBuffer> buffer;
BYTE *pData = NULL;
// Prepare a media sample.
if (SUCCEEDED(MFCreateSample(&sample)) &&
// Set sample time stamp and duration.
SUCCEEDED(sample->SetSampleTime(rtStart)) &&
SUCCEEDED(sample->SetSampleDuration(rtDuration)) &&
// Create a memory buffer.
SUCCEEDED(MFCreateMemoryBuffer(cbBuffer, &buffer)) &&
// Set the data length of the buffer.
SUCCEEDED(buffer->SetCurrentLength(cbBuffer)) &&
// Add the buffer to the sample.
SUCCEEDED(sample->AddBuffer(buffer.Get())) &&
// Lock the buffer.
SUCCEEDED(buffer->Lock(&pData, NULL, NULL)))
{
// Copy the video frame to the buffer.
cv::cvtColor(img.getMat(), cv::Mat(videoHeight, videoWidth, CV_8UC4, pData, cbWidth), img.channels() > 1 ? cv::COLOR_BGR2BGRA : cv::COLOR_GRAY2BGRA);
buffer->Unlock();
// Send media sample to the Sink Writer.
if (SUCCEEDED(sinkWriter->WriteSample(streamIndex, sample.Get())))
{
rtStart += rtDuration;
}
}
}
cv::Ptr<cv::IVideoWriter> cv::cvCreateVideoWriter_MSMF( const std::string& filename, int fourcc,
double fps, const cv::Size& frameSize,
const VideoWriterParameters& params)
{
cv::Ptr<CvVideoWriter_MSMF> writer = cv::makePtr<CvVideoWriter_MSMF>();
if (writer)
{
const bool isColor = params.get(VIDEOWRITER_PROP_IS_COLOR, true);
writer->open(filename, fourcc, fps, frameSize, isColor);
if (writer->isOpened())
return writer;
}
return cv::Ptr<cv::IVideoWriter>();
}
#if defined(BUILD_PLUGIN)
#include "plugin_api.hpp"
namespace cv {
typedef CvCapture_MSMF CaptureT;
typedef CvVideoWriter_MSMF WriterT;
static
CvResult CV_API_CALL cv_capture_open(const char* filename, int camera_index, CV_OUT CvPluginCapture* handle)
{
if (!handle)
return CV_ERROR_FAIL;
*handle = NULL;
if (!filename)
return CV_ERROR_FAIL;
CaptureT* cap = 0;
try
{
cap = new CaptureT();
bool res;
if (filename)
res = cap->open(std::string(filename));
else
res = cap->open(camera_index);
if (res)
{
*handle = (CvPluginCapture)cap;
return CV_ERROR_OK;
}
}
catch (...)
{
}
if (cap)
delete cap;
return CV_ERROR_FAIL;
}
static
CvResult CV_API_CALL cv_capture_release(CvPluginCapture handle)
{
if (!handle)
return CV_ERROR_FAIL;
CaptureT* instance = (CaptureT*)handle;
delete instance;
return CV_ERROR_OK;
}
static
CvResult CV_API_CALL cv_capture_get_prop(CvPluginCapture handle, int prop, CV_OUT double* val)
{
if (!handle)
return CV_ERROR_FAIL;
if (!val)
return CV_ERROR_FAIL;
try
{
CaptureT* instance = (CaptureT*)handle;
*val = instance->getProperty(prop);
return CV_ERROR_OK;
}
catch (...)
{
return CV_ERROR_FAIL;
}
}
static
CvResult CV_API_CALL cv_capture_set_prop(CvPluginCapture handle, int prop, double val)
{
if (!handle)
return CV_ERROR_FAIL;
try
{
CaptureT* instance = (CaptureT*)handle;
return instance->setProperty(prop, val) ? CV_ERROR_OK : CV_ERROR_FAIL;
}
catch (...)
{
return CV_ERROR_FAIL;
}
}
static
CvResult CV_API_CALL cv_capture_grab(CvPluginCapture handle)
{
if (!handle)
return CV_ERROR_FAIL;
try
{
CaptureT* instance = (CaptureT*)handle;
return instance->grabFrame() ? CV_ERROR_OK : CV_ERROR_FAIL;
}
catch (...)
{
return CV_ERROR_FAIL;
}
}
static
CvResult CV_API_CALL cv_capture_retrieve(CvPluginCapture handle, int stream_idx, cv_videoio_retrieve_cb_t callback, void* userdata)
{
if (!handle)
return CV_ERROR_FAIL;
try
{
CaptureT* instance = (CaptureT*)handle;
Mat img;
if (instance->retrieveFrame(stream_idx, img))
return callback(stream_idx, img.data, (int)img.step, img.cols, img.rows, img.channels(), userdata);
return CV_ERROR_FAIL;
}
catch (...)
{
return CV_ERROR_FAIL;
}
}
static
CvResult CV_API_CALL cv_writer_open(const char* filename, int fourcc, double fps, int width, int height, int isColor, CV_OUT CvPluginWriter* handle)
{
WriterT* wrt = 0;
try
{
wrt = new WriterT();
Size sz(width, height);
if (wrt && wrt->open(filename, fourcc, fps, sz, isColor != 0))
{
*handle = (CvPluginWriter)wrt;
return CV_ERROR_OK;
}
}
catch (...)
{
}
if (wrt)
delete wrt;
return CV_ERROR_FAIL;
}
static
CvResult CV_API_CALL cv_writer_release(CvPluginWriter handle)
{
if (!handle)
return CV_ERROR_FAIL;
WriterT* instance = (WriterT*)handle;
delete instance;
return CV_ERROR_OK;
}
static
CvResult CV_API_CALL cv_writer_get_prop(CvPluginWriter /*handle*/, int /*prop*/, CV_OUT double* /*val*/)
{
return CV_ERROR_FAIL;
}
static
CvResult CV_API_CALL cv_writer_set_prop(CvPluginWriter /*handle*/, int /*prop*/, double /*val*/)
{
return CV_ERROR_FAIL;
}
static
CvResult CV_API_CALL cv_writer_write(CvPluginWriter handle, const unsigned char* data, int step, int width, int height, int cn)
{
if (!handle)
return CV_ERROR_FAIL;
try
{
CV_Assert(step >= 0);
WriterT* instance = (WriterT*)handle;
Size sz(width, height);
Mat img(sz, CV_MAKETYPE(CV_8U, cn), (void*)data, (size_t)step);
instance->write(img);
return CV_ERROR_OK;
}
catch (...)
{
return CV_ERROR_FAIL;
}
}
static const OpenCV_VideoIO_Plugin_API_preview plugin_api_v0 =
{
{
sizeof(OpenCV_VideoIO_Plugin_API_preview), ABI_VERSION, 0/*API_VERSION*/,
CV_VERSION_MAJOR, CV_VERSION_MINOR, CV_VERSION_REVISION, CV_VERSION_STATUS,
"Microsoft Media Foundation OpenCV Video I/O plugin"
},
/* 1*/CAP_MSMF,
/* 2*/cv_capture_open,
/* 3*/cv_capture_release,
/* 4*/cv_capture_get_prop,
/* 5*/cv_capture_set_prop,
/* 6*/cv_capture_grab,
/* 7*/cv_capture_retrieve,
/* 8*/cv_writer_open,
/* 9*/cv_writer_release,
/* 10*/cv_writer_get_prop,
/* 11*/cv_writer_set_prop,
/* 12*/cv_writer_write
};
} // namespace
const OpenCV_VideoIO_Plugin_API_preview* opencv_videoio_plugin_init_v0(int requested_abi_version, int requested_api_version, void* /*reserved=NULL*/) CV_NOEXCEPT
{
if (requested_abi_version != 0)
return NULL;
if (requested_api_version != 0)
return NULL;
return &cv::plugin_api_v0;
}
#endif // BUILD_PLUGIN