/*
* SampleFormatMediaSoundation.cpp
* -------------------------------
* Purpose: MediaFoundation sample import.
* Notes :
* Authors: Joern Heusipp
* OpenMPT Devs
* The OpenMPT source code is released under the BSD license. Read LICENSE for more details.
*/
#include "stdafx.h"
#include "Sndfile.h"
#ifndef MODPLUG_NO_FILESAVE
#include "../common/mptFileIO.h"
#endif
#include "../common/misc_util.h"
#include "Tagging.h"
#include "Loaders.h"
#include "../common/FileReader.h"
#include "modsmp_ctrl.h"
#include "openmpt/soundbase/Copy.hpp"
#include "../soundlib/ModSampleCopy.h"
#include "../common/ComponentManager.h"
#if defined(MPT_WITH_MEDIAFOUNDATION)
#include <windows.h>
#include <atlbase.h>
#include <mfapi.h>
#include <mfidl.h>
#include <mfreadwrite.h>
#include <mferror.h>
#include <Propvarutil.h>
#endif // MPT_WITH_MEDIAFOUNDATION
OPENMPT_NAMESPACE_BEGIN
#if defined(MPT_WITH_MEDIAFOUNDATION)
struct PropVariant : PROPVARIANT
{
PropVariant() { PropVariantInit(this); }
~PropVariant() { PropVariantClear(this); }
};
// Implementing IMFByteStream is apparently not enough to stream raw bytes
// data to MediaFoundation.
// Additionally, one has to also implement a custom IMFAsyncResult for the
// BeginRead/EndRead interface which allows transferring the number of read
// bytes around.
// To make things even worse, MediaFoundation fails to detect some AAC and MPEG
// files if a non-file-based or read-only stream is used for opening.
// The only sane option which remains if we do not have an on-disk filename
// available:
// 1 - write a temporary file
// 2 - close it
// 3 - open it using MediaFoundation.
// We use FILE_ATTRIBUTE_TEMPORARY which will try to keep the file data in
// memory just like regular allocated memory and reduce the overhead basically
// to memcpy.
static FileTags ReadMFMetadata(IMFMediaSource *mediaSource)
{
FileTags tags;
CComPtr<IMFPresentationDescriptor> presentationDescriptor;
if(!SUCCEEDED(mediaSource->CreatePresentationDescriptor(&presentationDescriptor)))
{
return tags;
}
DWORD streams = 0;
if(!SUCCEEDED(presentationDescriptor->GetStreamDescriptorCount(&streams)))
{
return tags;
}
CComPtr<IMFMetadataProvider> metadataProvider;
if(!SUCCEEDED(MFGetService(mediaSource, MF_METADATA_PROVIDER_SERVICE, IID_IMFMetadataProvider, (void**)&metadataProvider)))
{
return tags;
}
CComPtr<IMFMetadata> metadata;
if(!SUCCEEDED(metadataProvider->GetMFMetadata(presentationDescriptor, 0, 0, &metadata)))
{
return tags;
}
PropVariant varPropNames;
if(!SUCCEEDED(metadata->GetAllPropertyNames(&varPropNames)))
{
return tags;
}
for(DWORD propIndex = 0; propIndex < varPropNames.calpwstr.cElems; ++propIndex)
{
PropVariant propVal;
LPWSTR propName = varPropNames.calpwstr.pElems[propIndex];
if(S_OK != metadata->GetProperty(propName, &propVal))
{
break;
}
std::wstring stringVal;
#if !MPT_OS_WINDOWS_WINRT
// WTF, no PropVariantToString() in WinRT
std::vector<WCHAR> wcharVal(256);
for(;;)
{
HRESULT hrToString = PropVariantToString(propVal, wcharVal.data(), mpt::saturate_cast<UINT>(wcharVal.size()));
if(hrToString == S_OK)
{
stringVal = wcharVal.data();
break;
} else if(hrToString == ERROR_INSUFFICIENT_BUFFER)
{
wcharVal.resize(mpt::exponential_grow(wcharVal.size()));
} else
{
break;
}
}
#endif // !MPT_OS_WINDOWS_WINRT
if(stringVal.length() > 0)
{
if(propName == std::wstring(L"Author")) tags.artist = mpt::ToUnicode(stringVal);
if(propName == std::wstring(L"Title")) tags.title = mpt::ToUnicode(stringVal);
if(propName == std::wstring(L"WM/AlbumTitle")) tags.album = mpt::ToUnicode(stringVal);
if(propName == std::wstring(L"WM/Track")) tags.trackno = mpt::ToUnicode(stringVal);
if(propName == std::wstring(L"WM/Year")) tags.year = mpt::ToUnicode(stringVal);
if(propName == std::wstring(L"WM/Genre")) tags.genre = mpt::ToUnicode(stringVal);
}
}
return tags;
}
class ComponentMediaFoundation : public ComponentLibrary
{
MPT_DECLARE_COMPONENT_MEMBERS(ComponentMediaFoundation, "MediaFoundation")
public:
ComponentMediaFoundation()
: ComponentLibrary(ComponentTypeSystem)
{
return;
}
bool DoInitialize() override
{
#if !MPT_OS_WINDOWS_WINRT
if(!(true
&& AddLibrary("mf", mpt::LibraryPath::System(P_("mf")))
&& AddLibrary("mfplat", mpt::LibraryPath::System(P_("mfplat")))
&& AddLibrary("mfreadwrite", mpt::LibraryPath::System(P_("mfreadwrite")))
&& AddLibrary("propsys", mpt::LibraryPath::System(P_("propsys")))
))
{
return false;
}
#endif // !MPT_OS_WINDOWS_WINRT
if(!SUCCEEDED(MFStartup(MF_VERSION)))
{
return false;
}
return true;
}
virtual ~ComponentMediaFoundation()
{
if(IsAvailable())
{
MFShutdown();
}
}
};
#endif // MPT_WITH_MEDIAFOUNDATION
#ifdef MODPLUG_TRACKER
std::vector<FileType> CSoundFile::GetMediaFoundationFileTypes()
{
std::vector<FileType> result;
#if defined(MPT_WITH_MEDIAFOUNDATION)
ComponentHandle<ComponentMediaFoundation> mf;
if(!IsComponentAvailable(mf))
{
return result;
}
std::map<std::wstring, FileType> guidMap;
HKEY hkHandlers = NULL;
LSTATUS regResult = RegOpenKeyExW(HKEY_LOCAL_MACHINE, L"SOFTWARE\\Microsoft\\Windows Media Foundation\\ByteStreamHandlers", 0, KEY_READ, &hkHandlers);
if(regResult != ERROR_SUCCESS)
{
return result;
}
for(DWORD handlerIndex = 0; ; ++handlerIndex)
{
WCHAR handlerTypeBuf[256];
MemsetZero(handlerTypeBuf);
regResult = RegEnumKeyW(hkHandlers, handlerIndex, handlerTypeBuf, 256);
if(regResult != ERROR_SUCCESS)
{
break;
}
std::wstring handlerType = handlerTypeBuf;
if(handlerType.length() < 1)
{
continue;
}
HKEY hkHandler = NULL;
regResult = RegOpenKeyExW(hkHandlers, handlerTypeBuf, 0, KEY_READ, &hkHandler);
if(regResult != ERROR_SUCCESS)
{
continue;
}
std::vector<WCHAR> valueNameBuf(16384);
std::vector<BYTE> valueData(16384);
for(DWORD valueIndex = 0; ; ++valueIndex)
{
std::fill(valueNameBuf.begin(), valueNameBuf.end(), WCHAR{0});
DWORD valueNameBufLen = 16384;
DWORD valueType = 0;
std::fill(valueData.begin(), valueData.end(), BYTE{0});
DWORD valueDataLen = 16384;
regResult = RegEnumValueW(hkHandler, valueIndex, valueNameBuf.data(), &valueNameBufLen, NULL, &valueType, valueData.data(), &valueDataLen);
if(regResult != ERROR_SUCCESS)
{
break;
}
if(valueNameBufLen <= 0 || valueType != REG_SZ || valueDataLen <= 0)
{
continue;
}
std::wstring guid = std::wstring(valueNameBuf.data());
mpt::ustring description = mpt::ToUnicode(ParseMaybeNullTerminatedStringFromBufferWithSizeInBytes<std::wstring>(valueData.data(), valueDataLen));
description = mpt::replace(description, U_("Byte Stream Handler"), U_("Files"));
description = mpt::replace(description, U_("ByteStreamHandler"), U_("Files"));
guidMap[guid]
.ShortName(U_("mf"))
.Description(description)
;
if(handlerType[0] == L'.')
{
guidMap[guid].AddExtension(mpt::PathString::FromWide(handlerType.substr(1)));
} else
{
guidMap[guid].AddMimeType(mpt::ToCharset(mpt::Charset::ASCII, handlerType));
}
}
RegCloseKey(hkHandler);
hkHandler = NULL;
}
RegCloseKey(hkHandlers);
hkHandlers = NULL;
for(const auto &it : guidMap)
{
result.push_back(it.second);
}
#endif // MPT_WITH_MEDIAFOUNDATION
return result;
}
#endif // MODPLUG_TRACKER
bool CSoundFile::ReadMediaFoundationSample(SAMPLEINDEX sample, FileReader &file, bool mo3Decode)
{
#if !defined(MPT_WITH_MEDIAFOUNDATION)
MPT_UNREFERENCED_PARAMETER(sample);
MPT_UNREFERENCED_PARAMETER(file);
MPT_UNREFERENCED_PARAMETER(mo3Decode);
return false;
#else
ComponentHandle<ComponentMediaFoundation> mf;
if(!IsComponentAvailable(mf))
{
return false;
}
file.Rewind();
// When using MF to decode MP3 samples in MO3 files, we need the mp3 file extension
// for some of them or otherwise MF refuses to recognize them.
mpt::PathString tmpfileExtension = (mo3Decode ? P_("mp3") : P_("tmp"));
OnDiskFileWrapper diskfile(file, tmpfileExtension);
if(!diskfile.IsValid())
{
return false;
}
#define MPT_MF_CHECKED(x) do { \
HRESULT hr = (x); \
if(!SUCCEEDED(hr)) \
{ \
return false; \
} \
} while(0)
CComPtr<IMFSourceResolver> sourceResolver;
MPT_MF_CHECKED(MFCreateSourceResolver(&sourceResolver));
MF_OBJECT_TYPE objectType = MF_OBJECT_INVALID;
CComPtr<IUnknown> unknownMediaSource;
MPT_MF_CHECKED(sourceResolver->CreateObjectFromURL(diskfile.GetFilename().ToWide().c_str(), MF_RESOLUTION_MEDIASOURCE | MF_RESOLUTION_CONTENT_DOES_NOT_HAVE_TO_MATCH_EXTENSION_OR_MIME_TYPE | MF_RESOLUTION_READ, NULL, &objectType, &unknownMediaSource));
if(objectType != MF_OBJECT_MEDIASOURCE)
{
return false;
}
CComPtr<IMFMediaSource> mediaSource;
MPT_MF_CHECKED(unknownMediaSource->QueryInterface(&mediaSource));
FileTags tags = ReadMFMetadata(mediaSource);
CComPtr<IMFSourceReader> sourceReader;
MPT_MF_CHECKED(MFCreateSourceReaderFromMediaSource(mediaSource, NULL, &sourceReader));
CComPtr<IMFMediaType> partialType;
MPT_MF_CHECKED(MFCreateMediaType(&partialType));
MPT_MF_CHECKED(partialType->SetGUID(MF_MT_MAJOR_TYPE, MFMediaType_Audio));
MPT_MF_CHECKED(partialType->SetGUID(MF_MT_SUBTYPE, MFAudioFormat_PCM));
MPT_MF_CHECKED(sourceReader->SetCurrentMediaType((DWORD)MF_SOURCE_READER_FIRST_AUDIO_STREAM, NULL, partialType));
CComPtr<IMFMediaType> uncompressedAudioType;
MPT_MF_CHECKED(sourceReader->GetCurrentMediaType((DWORD)MF_SOURCE_READER_FIRST_AUDIO_STREAM, &uncompressedAudioType));
MPT_MF_CHECKED(sourceReader->SetStreamSelection((DWORD)MF_SOURCE_READER_FIRST_AUDIO_STREAM, TRUE));
UINT32 numChannels = 0;
MPT_MF_CHECKED(uncompressedAudioType->GetUINT32(MF_MT_AUDIO_NUM_CHANNELS, &numChannels));
UINT32 samplesPerSecond = 0;
MPT_MF_CHECKED(uncompressedAudioType->GetUINT32(MF_MT_AUDIO_SAMPLES_PER_SECOND, &samplesPerSecond));
UINT32 bitsPerSample = 0;
MPT_MF_CHECKED(uncompressedAudioType->GetUINT32(MF_MT_AUDIO_BITS_PER_SAMPLE, &bitsPerSample));
if(numChannels <= 0 || numChannels > 2)
{
return false;
}
if(samplesPerSecond <= 0)
{
return false;
}
if(bitsPerSample != 8 && bitsPerSample != 16 && bitsPerSample != 24 && bitsPerSample != 32)
{
return false;
}
std::vector<char> rawData;
for(;;)
{
CComPtr<IMFSample> mfSample;
DWORD mfSampleFlags = 0;
CComPtr<IMFMediaBuffer> buffer;
MPT_MF_CHECKED(sourceReader->ReadSample((DWORD)MF_SOURCE_READER_FIRST_AUDIO_STREAM, 0, NULL, &mfSampleFlags, NULL, &mfSample));
if(mfSampleFlags & MF_SOURCE_READERF_CURRENTMEDIATYPECHANGED)
{
break;
}
if(mfSampleFlags & MF_SOURCE_READERF_ENDOFSTREAM)
{
break;
}
MPT_MF_CHECKED(mfSample->ConvertToContiguousBuffer(&buffer));
{
BYTE *data = NULL;
DWORD dataSize = 0;
MPT_MF_CHECKED(buffer->Lock(&data, NULL, &dataSize));
mpt::append(rawData, mpt::byte_cast<char*>(data), mpt::byte_cast<char*>(data + dataSize));
MPT_MF_CHECKED(buffer->Unlock());
if(rawData.size() / numChannels / (bitsPerSample / 8) > MAX_SAMPLE_LENGTH)
{
break;
}
}
}
std::string sampleName = mpt::ToCharset(GetCharsetInternal(), GetSampleNameFromTags(tags));
if(rawData.size() / numChannels / (bitsPerSample / 8) > MAX_SAMPLE_LENGTH)
{
return false;
}
SmpLength length = mpt::saturate_cast<SmpLength>(rawData.size() / numChannels / (bitsPerSample/8));
DestroySampleThreadsafe(sample);
if(!mo3Decode)
{
m_szNames[sample] = sampleName;
Samples[sample].Initialize();
Samples[sample].nC5Speed = samplesPerSecond;
}
Samples[sample].nLength = length;
Samples[sample].uFlags.set(CHN_16BIT, bitsPerSample >= 16);
Samples[sample].uFlags.set(CHN_STEREO, numChannels == 2);
Samples[sample].AllocateSample();
if(!Samples[sample].HasSampleData())
{
return false;
}
if(bitsPerSample == 24)
{
if(numChannels == 2)
{
CopyStereoInterleavedSample<SC::ConversionChain<SC::Convert<int16, int32>, SC::DecodeInt24<0, littleEndian24> > >(Samples[sample], rawData.data(), rawData.size());
} else
{
CopyMonoSample<SC::ConversionChain<SC::Convert<int16, int32>, SC::DecodeInt24<0, littleEndian24> > >(Samples[sample], rawData.data(), rawData.size());
}
} else if(bitsPerSample == 32)
{
if(numChannels == 2)
{
CopyStereoInterleavedSample<SC::ConversionChain<SC::Convert<int16, int32>, SC::DecodeInt32<0, littleEndian32> > >(Samples[sample], rawData.data(), rawData.size());
} else
{
CopyMonoSample<SC::ConversionChain<SC::Convert<int16, int32>, SC::DecodeInt32<0, littleEndian32> > >(Samples[sample], rawData.data(), rawData.size());
}
} else
{
// just copy
std::copy(rawData.data(), rawData.data() + rawData.size(), mpt::byte_cast<char*>(Samples[sample].sampleb()));
}
#undef MPT_MF_CHECKED
if(!mo3Decode)
{
Samples[sample].Convert(MOD_TYPE_IT, GetType());
Samples[sample].PrecomputeLoops(*this, false);
}
return true;
#endif
}
OPENMPT_NAMESPACE_END