pcsx2/3rdparty/baseclasses/transip.cpp

975 lines
33 KiB
C++

//------------------------------------------------------------------------------
// File: TransIP.cpp
//
// Desc: DirectShow base classes - implements class for simple Transform-
// In-Place filters such as audio.
//
// Copyright (c) 1992-2001 Microsoft Corporation. All rights reserved.
//------------------------------------------------------------------------------
// How allocators are decided.
//
// An in-place transform tries to do its work in someone else's buffers.
// It tries to persuade the filters on either side to use the same allocator
// (and for that matter the same media type). In desperation, if the downstream
// filter refuses to supply an allocator and the upstream filter offers only
// a read-only one then it will provide an allocator.
// if the upstream filter insists on a read-only allocator then the transform
// filter will (reluctantly) copy the data before transforming it.
//
// In order to pass an allocator through it needs to remember the one it got
// from the first connection to pass it on to the second one.
//
// It is good if we can avoid insisting on a particular order of connection
// (There is a precedent for insisting on the input
// being connected first. Insisting on the output being connected first is
// not allowed. That would break RenderFile.)
//
// The base pin classes (CBaseOutputPin and CBaseInputPin) both have a
// m_pAllocator member which is used in places like
// CBaseOutputPin::GetDeliveryBuffer and CBaseInputPin::Inactive.
// To avoid lots of extra overriding, we should keep these happy
// by using these pointers.
//
// When each pin is connected, it will set the corresponding m_pAllocator
// and will have a single ref-count on that allocator.
//
// Refcounts are acquired by GetAllocator calls which return AddReffed
// allocators and are released in one of:
// CBaseInputPin::Disconnect
// CBaseOutputPin::BreakConect
// In each case m_pAllocator is set to NULL after the release, so this
// is the last chance to ever release it. If there should ever be
// multiple refcounts associated with the same pointer, this had better
// be cleared up before that happens. To avoid such problems, we'll
// stick with one per pointer.
// RECONNECTING and STATE CHANGES
//
// Each pin could be disconnected, connected with a read-only allocator,
// connected with an upstream read/write allocator, connected with an
// allocator from downstream or connected with its own allocator.
// Five states for each pin gives a data space of 25 states.
//
// Notation:
//
// R/W == read/write
// R-O == read-only
//
// <input pin state> <output pin state> <comments>
//
// 00 means an unconnected pin.
// <- means using a R/W allocator from the upstream filter
// <= means using a R-O allocator from an upstream filter
// || means using our own (R/W) allocator.
// -> means using a R/W allocator from a downstream filter
// (a R-O allocator from downstream is nonsense, it can't ever work).
//
//
// That makes 25 possible states. Some states are nonsense (two different
// allocators from the same place). These are just an artifact of the notation.
// <= <- Nonsense.
// <- <= Nonsense
// Some states are illegal (the output pin never accepts a R-O allocator):
// 00 <= !! Error !!
// <= <= !! Error !!
// || <= !! Error !!
// -> <= !! Error !!
// Three states appears to be inaccessible:
// -> || Inaccessible
// || -> Inaccessible
// || <- Inaccessible
// Some states only ever occur as intermediates with a pending reconnect which
// is guaranteed to finish in another state.
// -> 00 ?? unstable goes to || 00
// 00 <- ?? unstable goes to 00 ||
// -> <- ?? unstable goes to -> ->
// <- || ?? unstable goes to <- <-
// <- -> ?? unstable goes to <- <-
// And that leaves 11 possible resting states:
// 1 00 00 Nothing connected.
// 2 <- 00 Input pin connected.
// 3 <= 00 Input pin connected using R-O allocator.
// 4 || 00 Needs several state changes to get here.
// 5 00 || Output pin connected using our allocator
// 6 00 -> Downstream only connected
// 7 || || Undesirable but can be forced upon us.
// 8 <= || Copy forced. <= -> is preferable
// 9 <= -> OK - forced to copy.
// 10 <- <- Transform in place (ideal)
// 11 -> -> Transform in place (ideal)
//
// The object of the exercise is to ensure that we finish up in states
// 10 or 11 whenever possible. State 10 is only possible if the upstream
// filter has a R/W allocator (the AVI splitter notoriously
// doesn't) and state 11 is only possible if the downstream filter does
// offer an allocator.
//
// The transition table (entries marked * go via a reconnect)
//
// There are 8 possible transitions:
// A: Connect upstream to filter with R-O allocator that insists on using it.
// B: Connect upstream to filter with R-O allocator but chooses not to use it.
// C: Connect upstream to filter with R/W allocator and insists on using it.
// D: Connect upstream to filter with R/W allocator but chooses not to use it.
// E: Connect downstream to a filter that offers an allocator
// F: Connect downstream to a filter that does not offer an allocator
// G: disconnect upstream
// H: Disconnect downstream
//
// A B C D E F G H
// ---------------------------------------------------------
// 00 00 1 | 3 3 2 2 6 5 . . |1 00 00
// <- 00 2 | . . . . *10/11 10 1 . |2 <- 00
// <= 00 3 | . . . . *9/11 *7/8 1 . |3 <= 00
// || 00 4 | . . . . *8 *7 1 . |4 || 00
// 00 || 5 | 8 7 *10 7 . . . 1 |5 00 ||
// 00 -> 6 | 9 11 *10 11 . . . 1 |6 00 ->
// || || 7 | . . . . . . 5 4 |7 || ||
// <= || 8 | . . . . . . 5 3 |8 <= ||
// <= -> 9 | . . . . . . 6 3 |9 <= ->
// <- <- 10| . . . . . . *5/6 2 |10 <- <-
// -> -> 11| . . . . . . 6 *2/3 |11 -> ->
// ---------------------------------------------------------
// A B C D E F G H
//
// All these states are accessible without requiring any filter to
// change its behaviour but not all transitions are accessible, for
// instance a transition from state 4 to anywhere other than
// state 8 requires that the upstream filter first offer a R-O allocator
// and then changes its mind and offer R/W. This is NOT allowable - it
// leads to things like the output pin getting a R/W allocator from
// upstream and then the input pin being told it can only have a R-O one.
// Note that you CAN change (say) the upstream filter for a different one, but
// only as a disconnect / connect, not as a Reconnect. (Exercise for
// the reader is to see how you get into state 4).
//
// The reconnection stuff goes as follows (some of the cases shown here as
// "no reconnect" may get one to finalise media type - an old story).
// If there is a reconnect where it says "no reconnect" here then the
// reconnection must not change the allocator choice.
//
// state 2: <- 00 transition E <- <- case C <- <- (no change)
// case D -> <- and then to -> ->
//
// state 2: <- 00 transition F <- <- (no reconnect)
//
// state 3: <= 00 transition E <= -> case A <= -> (no change)
// case B -> ->
// transition F <= || case A <= || (no change)
// case B || ||
//
// state 4: || 00 transition E || || case B -> || and then all cases to -> ->
// F || || case B || || (no change)
//
// state 5: 00 || transition A <= || (no reconnect)
// B || || (no reconnect)
// C <- || all cases <- <-
// D || || (unfortunate, but upstream's choice)
//
// state 6: 00 -> transition A <= -> (no reconnect)
// B -> -> (no reconnect)
// C <- -> all cases <- <-
// D -> -> (no reconnect)
//
// state 10:<- <- transition G 00 <- case E 00 ->
// case F 00 ||
//
// state 11:-> -> transition H -> 00 case A <= 00 (schizo)
// case B <= 00
// case C <- 00 (schizo)
// case D <- 00
//
// The Rules:
// To sort out media types:
// The input is reconnected
// if the input pin is connected and the output pin connects
// The output is reconnected
// If the output pin is connected
// and the input pin connects to a different media type
//
// To sort out allocators:
// The input is reconnected
// if the output disconnects and the input was using a downstream allocator
// The output pin calls SetAllocator to pass on a new allocator
// if the output is connected and
// if the input disconnects and the output was using an upstream allocator
// if the input acquires an allocator different from the output one
// and that new allocator is not R-O
//
// Data is copied (i.e. call getbuffer and copy the data before transforming it)
// if the two allocators are different.
// CHAINS of filters:
//
// We sit between two filters (call them A and Z). We should finish up
// with the same allocator on both of our pins and that should be the
// same one that A and Z would have agreed on if we hadn't been in the
// way. Furthermore, it should not matter how many in-place transforms
// are in the way. Let B, C, D... be in-place transforms ("us").
// Here's how it goes:
//
// 1.
// A connects to B. They agree on A's allocator.
// A-a->B
//
// 2.
// B connects to C. Same story. There is no point in a reconnect, but
// B will request an input reconnect anyway.
// A-a->B-a->C
//
// 3.
// C connects to Z.
// C insists on using A's allocator, but compromises by requesting a reconnect.
// of C's input.
// A-a->B-?->C-a->Z
//
// We now have pending reconnects on both A--->B and B--->C
//
// 4.
// The A--->B link is reconnected.
// A asks B for an allocator. B sees that it has a downstream connection so
// asks its downstream input pin i.e. C's input pin for an allocator. C sees
// that it too has a downstream connection so asks Z for an allocator.
//
// Even though Z's input pin is connected, it is being asked for an allocator.
// It could refuse, in which case the chain is done and will use A's allocator
// Alternatively, Z may supply one. A chooses either Z's or A's own one.
// B's input pin gets NotifyAllocator called to tell it the decision and it
// propagates this downstream by calling ReceiveAllocator on its output pin
// which calls NotifyAllocator on the next input pin downstream etc.
// If the choice is Z then it goes:
// A-z->B-a->C-a->Z
// A-z->B-z->C-a->Z
// A-z->B-z->C-z->Z
//
// And that's IT!! Any further (essentially spurious) reconnects peter out
// with no change in the chain.
#include <streams.h>
#include <measure.h>
#include <transip.h>
// =================================================================
// Implements the CTransInPlaceFilter class
// =================================================================
CTransInPlaceFilter::CTransInPlaceFilter
( __in_opt LPCTSTR pName,
__inout_opt LPUNKNOWN pUnk,
REFCLSID clsid,
__inout HRESULT *phr,
bool bModifiesData
)
: CTransformFilter(pName, pUnk, clsid),
m_bModifiesData(bModifiesData)
{
#ifdef PERF
RegisterPerfId();
#endif // PERF
} // constructor
#ifdef UNICODE
CTransInPlaceFilter::CTransInPlaceFilter
( __in_opt LPCSTR pName,
__inout_opt LPUNKNOWN pUnk,
REFCLSID clsid,
__inout HRESULT *phr,
bool bModifiesData
)
: CTransformFilter(pName, pUnk, clsid),
m_bModifiesData(bModifiesData)
{
#ifdef PERF
RegisterPerfId();
#endif // PERF
} // constructor
#endif
// return a non-addrefed CBasePin * for the user to addref if he holds onto it
// for longer than his pointer to us. We create the pins dynamically when they
// are asked for rather than in the constructor. This is because we want to
// give the derived class an oppportunity to return different pin objects
// As soon as any pin is needed we create both (this is different from the
// usual transform filter) because enumerators, allocators etc are passed
// through from one pin to another and it becomes very painful if the other
// pin isn't there. If we fail to create either pin we ensure we fail both.
CBasePin *
CTransInPlaceFilter::GetPin(int n)
{
HRESULT hr = S_OK;
// Create an input pin if not already done
if (m_pInput == NULL) {
m_pInput = new CTransInPlaceInputPin( NAME("TransInPlace input pin")
, this // Owner filter
, &hr // Result code
, L"Input" // Pin name
);
// Constructor for CTransInPlaceInputPin can't fail
ASSERT(SUCCEEDED(hr));
}
// Create an output pin if not already done
if (m_pInput!=NULL && m_pOutput == NULL) {
m_pOutput = new CTransInPlaceOutputPin( NAME("TransInPlace output pin")
, this // Owner filter
, &hr // Result code
, L"Output" // Pin name
);
// a failed return code should delete the object
ASSERT(SUCCEEDED(hr));
if (m_pOutput == NULL) {
delete m_pInput;
m_pInput = NULL;
}
}
// Return the appropriate pin
ASSERT (n>=0 && n<=1);
if (n == 0) {
return m_pInput;
} else if (n==1) {
return m_pOutput;
} else {
return NULL;
}
} // GetPin
// dir is the direction of our pin.
// pReceivePin is the pin we are connecting to.
HRESULT CTransInPlaceFilter::CompleteConnect(PIN_DIRECTION dir, IPin *pReceivePin)
{
UNREFERENCED_PARAMETER(pReceivePin);
ASSERT(m_pInput);
ASSERT(m_pOutput);
// if we are not part of a graph, then don't indirect the pointer
// this probably prevents use of the filter without a filtergraph
if (!m_pGraph) {
return VFW_E_NOT_IN_GRAPH;
}
// Always reconnect the input to account for buffering changes
//
// Because we don't get to suggest a type on ReceiveConnection
// we need another way of making sure the right type gets used.
//
// One way would be to have our EnumMediaTypes return our output
// connection type first but more deterministic and simple is to
// call ReconnectEx passing the type we want to reconnect with
// via the base class ReconeectPin method.
if (dir == PINDIR_OUTPUT) {
if( m_pInput->IsConnected() ) {
return ReconnectPin( m_pInput, &m_pOutput->CurrentMediaType() );
}
return NOERROR;
}
ASSERT(dir == PINDIR_INPUT);
// Reconnect output if necessary
if( m_pOutput->IsConnected() ) {
if ( m_pInput->CurrentMediaType()
!= m_pOutput->CurrentMediaType()
) {
return ReconnectPin( m_pOutput, &m_pInput->CurrentMediaType() );
}
}
return NOERROR;
} // ComnpleteConnect
//
// DecideBufferSize
//
// Tell the output pin's allocator what size buffers we require.
// *pAlloc will be the allocator our output pin is using.
//
HRESULT CTransInPlaceFilter::DecideBufferSize
( IMemAllocator *pAlloc
, __inout ALLOCATOR_PROPERTIES *pProperties
)
{
ALLOCATOR_PROPERTIES Request, Actual;
HRESULT hr;
// If we are connected upstream, get his views
if (m_pInput->IsConnected()) {
// Get the input pin allocator, and get its size and count.
// we don't care about his alignment and prefix.
hr = InputPin()->PeekAllocator()->GetProperties(&Request);
if (FAILED(hr)) {
// Input connected but with a secretive allocator - enough!
return hr;
}
} else {
// Propose one byte
// If this isn't enough then when the other pin does get connected
// we can revise it.
ZeroMemory(&Request, sizeof(Request));
Request.cBuffers = 1;
Request.cbBuffer = 1;
}
DbgLog((LOG_MEMORY,1,TEXT("Setting Allocator Requirements")));
DbgLog((LOG_MEMORY,1,TEXT("Count %d, Size %d"),
Request.cBuffers, Request.cbBuffer));
// Pass the allocator requirements to our output side
// but do a little sanity checking first or we'll just hit
// asserts in the allocator.
pProperties->cBuffers = Request.cBuffers;
pProperties->cbBuffer = Request.cbBuffer;
pProperties->cbAlign = Request.cbAlign;
if (pProperties->cBuffers<=0) {pProperties->cBuffers = 1; }
if (pProperties->cbBuffer<=0) {pProperties->cbBuffer = 1; }
hr = pAlloc->SetProperties(pProperties, &Actual);
if (FAILED(hr)) {
return hr;
}
DbgLog((LOG_MEMORY,1,TEXT("Obtained Allocator Requirements")));
DbgLog((LOG_MEMORY,1,TEXT("Count %d, Size %d, Alignment %d"),
Actual.cBuffers, Actual.cbBuffer, Actual.cbAlign));
// Make sure we got the right alignment and at least the minimum required
if ( (Request.cBuffers > Actual.cBuffers)
|| (Request.cbBuffer > Actual.cbBuffer)
|| (Request.cbAlign > Actual.cbAlign)
) {
return E_FAIL;
}
return NOERROR;
} // DecideBufferSize
//
// Copy
//
// return a pointer to an identical copy of pSample
__out_opt IMediaSample * CTransInPlaceFilter::Copy(IMediaSample *pSource)
{
IMediaSample * pDest;
HRESULT hr;
REFERENCE_TIME tStart, tStop;
const BOOL bTime = S_OK == pSource->GetTime( &tStart, &tStop);
// this may block for an indeterminate amount of time
hr = OutputPin()->PeekAllocator()->GetBuffer(
&pDest
, bTime ? &tStart : NULL
, bTime ? &tStop : NULL
, m_bSampleSkipped ? AM_GBF_PREVFRAMESKIPPED : 0
);
if (FAILED(hr)) {
return NULL;
}
ASSERT(pDest);
IMediaSample2 *pSample2;
if (SUCCEEDED(pDest->QueryInterface(IID_IMediaSample2, (void **)&pSample2))) {
HRESULT hrProps = pSample2->SetProperties(
FIELD_OFFSET(AM_SAMPLE2_PROPERTIES, pbBuffer),
(PBYTE)m_pInput->SampleProps());
pSample2->Release();
if (FAILED(hrProps)) {
pDest->Release();
return NULL;
}
} else {
if (bTime) {
pDest->SetTime(&tStart, &tStop);
}
if (S_OK == pSource->IsSyncPoint()) {
pDest->SetSyncPoint(TRUE);
}
if (S_OK == pSource->IsDiscontinuity() || m_bSampleSkipped) {
pDest->SetDiscontinuity(TRUE);
}
if (S_OK == pSource->IsPreroll()) {
pDest->SetPreroll(TRUE);
}
// Copy the media type
AM_MEDIA_TYPE *pMediaType;
if (S_OK == pSource->GetMediaType(&pMediaType)) {
pDest->SetMediaType(pMediaType);
DeleteMediaType( pMediaType );
}
}
m_bSampleSkipped = FALSE;
// Copy the sample media times
REFERENCE_TIME TimeStart, TimeEnd;
if (pSource->GetMediaTime(&TimeStart,&TimeEnd) == NOERROR) {
pDest->SetMediaTime(&TimeStart,&TimeEnd);
}
// Copy the actual data length and the actual data.
{
const long lDataLength = pSource->GetActualDataLength();
if (FAILED(pDest->SetActualDataLength(lDataLength))) {
pDest->Release();
return NULL;
}
// Copy the sample data
{
BYTE *pSourceBuffer, *pDestBuffer;
long lSourceSize = pSource->GetSize();
long lDestSize = pDest->GetSize();
ASSERT(lDestSize >= lSourceSize && lDestSize >= lDataLength);
if (FAILED(pSource->GetPointer(&pSourceBuffer)) ||
FAILED(pDest->GetPointer(&pDestBuffer)) ||
lDestSize < lDataLength ||
lDataLength < 0) {
pDest->Release();
return NULL;
}
ASSERT(lDestSize == 0 || pSourceBuffer != NULL && pDestBuffer != NULL);
CopyMemory( (PVOID) pDestBuffer, (PVOID) pSourceBuffer, lDataLength );
}
}
return pDest;
} // Copy
// override this to customize the transform process
HRESULT
CTransInPlaceFilter::Receive(IMediaSample *pSample)
{
/* Check for other streams and pass them on */
AM_SAMPLE2_PROPERTIES * const pProps = m_pInput->SampleProps();
if (pProps->dwStreamId != AM_STREAM_MEDIA) {
return m_pOutput->Deliver(pSample);
}
HRESULT hr;
// Start timing the TransInPlace (if PERF is defined)
MSR_START(m_idTransInPlace);
if (UsingDifferentAllocators()) {
// We have to copy the data.
pSample = Copy(pSample);
if (pSample==NULL) {
MSR_STOP(m_idTransInPlace);
return E_UNEXPECTED;
}
}
// have the derived class transform the data
hr = Transform(pSample);
// Stop the clock and log it (if PERF is defined)
MSR_STOP(m_idTransInPlace);
if (FAILED(hr)) {
DbgLog((LOG_TRACE, 1, TEXT("Error from TransInPlace")));
if (UsingDifferentAllocators()) {
pSample->Release();
}
return hr;
}
// the Transform() function can return S_FALSE to indicate that the
// sample should not be delivered; we only deliver the sample if it's
// really S_OK (same as NOERROR, of course.)
if (hr == NOERROR) {
hr = m_pOutput->Deliver(pSample);
} else {
// But it would be an error to return this private workaround
// to the caller ...
if (S_FALSE == hr) {
// S_FALSE returned from Transform is a PRIVATE agreement
// We should return NOERROR from Receive() in this cause because
// returning S_FALSE from Receive() means that this is the end
// of the stream and no more data should be sent.
m_bSampleSkipped = TRUE;
if (!m_bQualityChanged) {
NotifyEvent(EC_QUALITY_CHANGE,0,0);
m_bQualityChanged = TRUE;
}
hr = NOERROR;
}
}
// release the output buffer. If the connected pin still needs it,
// it will have addrefed it itself.
if (UsingDifferentAllocators()) {
pSample->Release();
}
return hr;
} // Receive
// =================================================================
// Implements the CTransInPlaceInputPin class
// =================================================================
// constructor
CTransInPlaceInputPin::CTransInPlaceInputPin
( __in_opt LPCTSTR pObjectName
, __inout CTransInPlaceFilter *pFilter
, __inout HRESULT *phr
, __in_opt LPCWSTR pName
)
: CTransformInputPin(pObjectName,
pFilter,
phr,
pName)
, m_bReadOnly(FALSE)
, m_pTIPFilter(pFilter)
{
DbgLog((LOG_TRACE, 2
, TEXT("CTransInPlaceInputPin::CTransInPlaceInputPin")));
} // constructor
// =================================================================
// Implements IMemInputPin interface
// =================================================================
// If the downstream filter has one then offer that (even if our own output
// pin is not using it yet. If the upstream filter chooses it then we will
// tell our output pin to ReceiveAllocator).
// Else if our output pin is using an allocator then offer that.
// ( This could mean offering the upstream filter his own allocator,
// it could mean offerring our own
// ) or it could mean offering the one from downstream
// Else fail to offer any allocator at all.
STDMETHODIMP CTransInPlaceInputPin::GetAllocator(__deref_out IMemAllocator ** ppAllocator)
{
CheckPointer(ppAllocator,E_POINTER);
ValidateReadWritePtr(ppAllocator,sizeof(IMemAllocator *));
CAutoLock cObjectLock(m_pLock);
HRESULT hr;
if ( m_pTIPFilter->m_pOutput->IsConnected() ) {
// Store the allocator we got
hr = m_pTIPFilter->OutputPin()->ConnectedIMemInputPin()
->GetAllocator( ppAllocator );
if (SUCCEEDED(hr)) {
m_pTIPFilter->OutputPin()->SetAllocator( *ppAllocator );
}
}
else {
// Help upstream filter (eg TIP filter which is having to do a copy)
// by providing a temp allocator here - we'll never use
// this allocator because when our output is connected we'll
// reconnect this pin
hr = CTransformInputPin::GetAllocator( ppAllocator );
}
return hr;
} // GetAllocator
/* Get told which allocator the upstream output pin is actually going to use */
STDMETHODIMP
CTransInPlaceInputPin::NotifyAllocator(
IMemAllocator * pAllocator,
BOOL bReadOnly)
{
HRESULT hr = S_OK;
CheckPointer(pAllocator,E_POINTER);
ValidateReadPtr(pAllocator,sizeof(IMemAllocator));
CAutoLock cObjectLock(m_pLock);
m_bReadOnly = bReadOnly;
// If we modify data then don't accept the allocator if it's
// the same as the output pin's allocator
// If our output is not connected just accept the allocator
// We're never going to use this allocator because when our
// output pin is connected we'll reconnect this pin
if (!m_pTIPFilter->OutputPin()->IsConnected()) {
return CTransformInputPin::NotifyAllocator(pAllocator, bReadOnly);
}
// If the allocator is read-only and we're modifying data
// and the allocator is the same as the output pin's
// then reject
if (bReadOnly && m_pTIPFilter->m_bModifiesData) {
IMemAllocator *pOutputAllocator =
m_pTIPFilter->OutputPin()->PeekAllocator();
// Make sure we have an output allocator
if (pOutputAllocator == NULL) {
hr = m_pTIPFilter->OutputPin()->ConnectedIMemInputPin()->
GetAllocator(&pOutputAllocator);
if(FAILED(hr)) {
hr = CreateMemoryAllocator(&pOutputAllocator);
}
if (SUCCEEDED(hr)) {
m_pTIPFilter->OutputPin()->SetAllocator(pOutputAllocator);
pOutputAllocator->Release();
}
}
if (pAllocator == pOutputAllocator) {
hr = E_FAIL;
} else if(SUCCEEDED(hr)) {
// Must copy so set the allocator properties on the output
ALLOCATOR_PROPERTIES Props, Actual;
hr = pAllocator->GetProperties(&Props);
if (SUCCEEDED(hr)) {
hr = pOutputAllocator->SetProperties(&Props, &Actual);
}
if (SUCCEEDED(hr)) {
if ( (Props.cBuffers > Actual.cBuffers)
|| (Props.cbBuffer > Actual.cbBuffer)
|| (Props.cbAlign > Actual.cbAlign)
) {
hr = E_FAIL;
}
}
// Set the allocator on the output pin
if (SUCCEEDED(hr)) {
hr = m_pTIPFilter->OutputPin()->ConnectedIMemInputPin()
->NotifyAllocator( pOutputAllocator, FALSE );
}
}
} else {
hr = m_pTIPFilter->OutputPin()->ConnectedIMemInputPin()
->NotifyAllocator( pAllocator, bReadOnly );
if (SUCCEEDED(hr)) {
m_pTIPFilter->OutputPin()->SetAllocator( pAllocator );
}
}
if (SUCCEEDED(hr)) {
// It's possible that the old and the new are the same thing.
// AddRef before release ensures that we don't unload it.
pAllocator->AddRef();
if( m_pAllocator != NULL )
m_pAllocator->Release();
m_pAllocator = pAllocator; // We have an allocator for the input pin
}
return hr;
} // NotifyAllocator
// EnumMediaTypes
// - pass through to our downstream filter
STDMETHODIMP CTransInPlaceInputPin::EnumMediaTypes( __deref_out IEnumMediaTypes **ppEnum )
{
// Can only pass through if connected
if( !m_pTIPFilter->m_pOutput->IsConnected() )
return VFW_E_NOT_CONNECTED;
return m_pTIPFilter->m_pOutput->GetConnected()->EnumMediaTypes( ppEnum );
} // EnumMediaTypes
// CheckMediaType
// - agree to anything if not connected,
// otherwise pass through to the downstream filter.
// This assumes that the filter does not change the media type.
HRESULT CTransInPlaceInputPin::CheckMediaType(const CMediaType *pmt )
{
HRESULT hr = m_pTIPFilter->CheckInputType(pmt);
if (hr!=S_OK) return hr;
if( m_pTIPFilter->m_pOutput->IsConnected() )
return m_pTIPFilter->m_pOutput->GetConnected()->QueryAccept( pmt );
else
return S_OK;
} // CheckMediaType
// If upstream asks us what our requirements are, we will try to ask downstream
// if that doesn't work, we'll just take the defaults.
STDMETHODIMP
CTransInPlaceInputPin::GetAllocatorRequirements(__out ALLOCATOR_PROPERTIES *pProps)
{
if( m_pTIPFilter->m_pOutput->IsConnected() )
return m_pTIPFilter->OutputPin()
->ConnectedIMemInputPin()->GetAllocatorRequirements( pProps );
else
return E_NOTIMPL;
} // GetAllocatorRequirements
// CTransInPlaceInputPin::CompleteConnect() calls CBaseInputPin::CompleteConnect()
// and then calls CTransInPlaceFilter::CompleteConnect(). It does this because
// CTransInPlaceFilter::CompleteConnect() can reconnect a pin and we do not
// want to reconnect a pin if CBaseInputPin::CompleteConnect() fails.
HRESULT
CTransInPlaceInputPin::CompleteConnect(IPin *pReceivePin)
{
HRESULT hr = CBaseInputPin::CompleteConnect(pReceivePin);
if (FAILED(hr)) {
return hr;
}
return m_pTransformFilter->CompleteConnect(PINDIR_INPUT,pReceivePin);
} // CompleteConnect
// =================================================================
// Implements the CTransInPlaceOutputPin class
// =================================================================
// constructor
CTransInPlaceOutputPin::CTransInPlaceOutputPin(
__in_opt LPCTSTR pObjectName,
__inout CTransInPlaceFilter *pFilter,
__inout HRESULT * phr,
__in_opt LPCWSTR pPinName)
: CTransformOutputPin( pObjectName
, pFilter
, phr
, pPinName),
m_pTIPFilter(pFilter)
{
DbgLog(( LOG_TRACE, 2
, TEXT("CTransInPlaceOutputPin::CTransInPlaceOutputPin")));
} // constructor
// EnumMediaTypes
// - pass through to our upstream filter
STDMETHODIMP CTransInPlaceOutputPin::EnumMediaTypes( __deref_out IEnumMediaTypes **ppEnum )
{
// Can only pass through if connected.
if( ! m_pTIPFilter->m_pInput->IsConnected() )
return VFW_E_NOT_CONNECTED;
return m_pTIPFilter->m_pInput->GetConnected()->EnumMediaTypes( ppEnum );
} // EnumMediaTypes
// CheckMediaType
// - agree to anything if not connected,
// otherwise pass through to the upstream filter.
HRESULT CTransInPlaceOutputPin::CheckMediaType(const CMediaType *pmt )
{
// Don't accept any output pin type changes if we're copying
// between allocators - it's too late to change the input
// allocator size.
if (m_pTIPFilter->UsingDifferentAllocators() && !m_pFilter->IsStopped()) {
if (*pmt == m_mt) {
return S_OK;
} else {
return VFW_E_TYPE_NOT_ACCEPTED;
}
}
// Assumes the type does not change. That's why we're calling
// CheckINPUTType here on the OUTPUT pin.
HRESULT hr = m_pTIPFilter->CheckInputType(pmt);
if (hr!=S_OK) return hr;
if( m_pTIPFilter->m_pInput->IsConnected() )
return m_pTIPFilter->m_pInput->GetConnected()->QueryAccept( pmt );
else
return S_OK;
} // CheckMediaType
/* Save the allocator pointer in the output pin
*/
void
CTransInPlaceOutputPin::SetAllocator(IMemAllocator * pAllocator)
{
pAllocator->AddRef();
if (m_pAllocator) {
m_pAllocator->Release();
}
m_pAllocator = pAllocator;
} // SetAllocator
// CTransInPlaceOutputPin::CompleteConnect() calls CBaseOutputPin::CompleteConnect()
// and then calls CTransInPlaceFilter::CompleteConnect(). It does this because
// CTransInPlaceFilter::CompleteConnect() can reconnect a pin and we do not want to
// reconnect a pin if CBaseOutputPin::CompleteConnect() fails.
// CBaseOutputPin::CompleteConnect() often fails when our output pin is being connected
// to the Video Mixing Renderer.
HRESULT
CTransInPlaceOutputPin::CompleteConnect(IPin *pReceivePin)
{
HRESULT hr = CBaseOutputPin::CompleteConnect(pReceivePin);
if (FAILED(hr)) {
return hr;
}
return m_pTransformFilter->CompleteConnect(PINDIR_OUTPUT,pReceivePin);
} // CompleteConnect