static void Test_EssenceStreamPullWrite(
IAAFFile *pFile,
CAAFBuiltinDefs & defs)
{
IAAFTypeDefSP pTypeDef;
IAAFTypeDefStream3SP pTypeDefStream3;
// Get the direct access interfaces.
IAAFObjectSP pObject;
IAAFPropertyDefSP pDataPropertyDef;
IAAFPropertyDefSP pSampleIndexPropertyDef;
IAAFPropertyValueSP pStreamPropertyValue;
IAAFStreamAccess *cb = 0;
IAAFEssenceDataSP pEssenceData;
IAAFHeaderSP pHeader;
IAAFDictionarySP pDictionary;
IAAFSourceMobSP pSourceMob;
IAAFMobSP pMob;
IAAFEssenceDescriptorSP pEssenceDesciptor;
CheckResult (pFile->GetHeader (&pHeader));
CheckResult (pHeader->GetDictionary (&pDictionary));
// Create an EssenceData object and associated Mob
Test_CreateEssenceData(defs, pHeader, sMobID[2], sMobName[2], &pEssenceData);
// Normally we'd add the essence data object here and, with it attached,
// write essence to it. Instead establish a call back so that the data
// may be written later during save.
CheckResult(pEssenceData->QueryInterface(IID_IAAFObject, (void **)&pObject));
Test_LookupEssenceDataStreamPropertyDefinitions(pDictionary,
&pDataPropertyDef,
&pSampleIndexPropertyDef);
CheckResult(pObject->GetPropertyValue(pDataPropertyDef,
&pStreamPropertyValue));
CheckResult(pStreamPropertyValue->GetType(&pTypeDef));
CheckResult(pTypeDef->QueryInterface(IID_IAAFTypeDefStream3,
(void **)&pTypeDefStream3));
CheckResult(TestStreamAccess::Create(&cb));
CheckResult(pTypeDefStream3->SetCallback(pStreamPropertyValue, cb,
reinterpret_cast<aafMemPtr_t>(const_cast<char *>(sSmiley))));
cb->Release();
}
// Create the test file.
void CAAFTypeDefStream_read (aafCharacter_constptr pFileName) // throw HRESULT
{
IAAFFileSP pFile;
try
{
IAAFHeaderSP pHeader;
IAAFDictionarySP pDictionary;
IAAFEssenceDataSP pEssenceData;
IAAFPropertyValueSP pDataPropertyValue;
IAAFPropertyValueSP pSampleIndexPropertyValue;
aafUID_t fileKind;
aafBool isAAFFile = kAAFFalse;
CheckResult (AAFFileIsAAFFile(pFileName, &fileKind, &isAAFFile));
CheckExpression(isAAFFile == kAAFTrue, AAFRESULT_TEST_FAILED);
CheckResult (AAFFileOpenExistingRead(pFileName, 0, &pFile));
CheckResult (pFile->GetHeader (&pHeader));
CheckResult (pHeader->GetDictionary (&pDictionary));
CAAFBuiltinDefs defs (pDictionary);
#if 1
// Missing api method!
CheckResult (pHeader->LookupEssenceData(sMobID[0], &pEssenceData));
#else
// For this version of the test assume that there is only a single
// essence data...
aafUInt32 count;
CheckResult(pHeader->CountEssenceData(&count));
CheckExpression(1 == count, AAFRESULT_TEST_FAILED);
IEnumAAFEssenceDataSP pEnumEssenceData;
CheckResult(pHeader->EnumEssenceData(&pEnumEssenceData));
CheckResult(pEnumEssenceData->NextOne(&pEssenceData));
aafMobID_t testMobID = {{0,0,0,0,0,0,0,0,0,0,0,0},0,0,0,0,
{0,0,0,{0,0,0,0,0,0,0,0}}};
CheckResult(pEssenceData->GetFileMobID(&testMobID));
CheckExpression(0 == memcmp(&testMobID, &sMobID[0], sizeof(aafMobID_t)),
AAFRESULT_TEST_FAILED);
#endif
Test_EssenceStreamPropertyValues(pDictionary,
pEssenceData,
&pDataPropertyValue,
&pSampleIndexPropertyValue);
// Test the required property
Test_EssenceStreamRead(defs, pDataPropertyValue);
if(pSampleIndexPropertyValue)
{
// Test the optional property
Test_EssenceStreamRead(defs, pSampleIndexPropertyValue);
}
// Test IAAFTypeDefStream2 methods
IAAFEssenceDataSP pEssenceData2;
// sMobID[3] may not be in the file, in the case
// the file was created by an older test.
if(pHeader->LookupEssenceData(sMobID[3], &pEssenceData2)==AAFRESULT_SUCCESS)
{
IAAFPropertyValueSP pDataPropertyValue2;
IAAFPropertyValueSP pSampleIndexPropertyValue2;
Test_EssenceStreamPropertyValues(pDictionary,
pEssenceData2,
&pDataPropertyValue2,
&pSampleIndexPropertyValue2);
}
// Test IAAFTypeDefStream3 methods
IAAFEssenceDataSP pEssenceData3;
// sMobID[4] may not be in the file, in the case
// the file was created by an older test.
if(pHeader->LookupEssenceData(sMobID[4], &pEssenceData3)==AAFRESULT_SUCCESS)
{
IAAFPropertyValueSP pDataPropertyValue3;
IAAFPropertyValueSP pSampleIndexPropertyValue3;
Test_EssenceStreamPropertyValues(pDictionary,
pEssenceData3,
&pDataPropertyValue3,
&pSampleIndexPropertyValue3);
Test_KLVStreamParametersOnRead(defs, pDataPropertyValue3);
Test_EssenceStreamRead(defs, pDataPropertyValue3);
}
// Test the case when the stream data size approaches the KLV
// Alignment Grid (KAG) boundary and leaves some but not enough
// space to pad to the end of the boundary.
// (This is a test of edge conditions specific to KLV encoded files.)
IAAFEssenceDataSP pEssenceData4;
// sMobID[4] may not be in the file, in the case
// the file was created by an older test.
if(pHeader->LookupEssenceData(sMobID[5], &pEssenceData4)==AAFRESULT_SUCCESS)
{
IAAFPropertyValueSP pDataPropertyValue4;
IAAFPropertyValueSP pSampleIndexPropertyValue4;
Test_EssenceStreamPropertyValues(pDictionary,
pEssenceData4,
&pDataPropertyValue4,
&pSampleIndexPropertyValue4);
Test_NearKAGBoundaryRead(defs, pDataPropertyValue4);
}
CheckResult(pFile->Close());
}
catch(AAFRESULT& hr)
{
// Ignore failure if file not open
pFile->Close();
CheckResult(hr);
}
}
// Create the test file.
void CAAFTypeDefStream_create (
aafCharacter_constptr pFileName,
aafUID_constref fileKind,
testRawStorageType_t rawStorageType,
aafProductIdentification_constref productID)
{
IAAFFileSP pFile;
try
{
IAAFHeaderSP pHeader;
IAAFDictionarySP pDictionary;
IAAFSourceMobSP pSourceMob;
IAAFMobSP pMob;
IAAFEssenceDescriptorSP pEssenceDesciptor;
IAAFEssenceDataSP pEssenceData;
IAAFPropertyValueSP pDataPropertyValue;
IAAFPropertyValueSP pSampleIndexPropertyValue;
// Remove the previous test file is one exists
::RemoveTestFile (pFileName);
// Create the file.
CheckResult (CreateTestFile( pFileName, fileKind, rawStorageType, productID, &pFile ));
CheckResult (pFile->GetHeader (&pHeader));
CheckResult (pHeader->GetDictionary (&pDictionary));
CAAFBuiltinDefs defs (pDictionary);
// Create an EssenceData object and associated Mob
Test_CreateEssenceData(defs, pHeader, sMobID[0], sMobName[0], &pEssenceData);
Test_EssenceStreamPropertyValues(pDictionary,
pEssenceData,
&pDataPropertyValue,
&pSampleIndexPropertyValue);
// Test the required property
Test_EssenceStreamWrite(defs, pDataPropertyValue);
Test_EssenceStreamRead(defs, pDataPropertyValue);
if (pSampleIndexPropertyValue)
{
// Test the optional property
Test_EssenceStreamWrite(defs, pSampleIndexPropertyValue);
Test_EssenceStreamRead(defs, pSampleIndexPropertyValue);
}
Test_EssenceStreamPullWrite(pFile, defs);
// Test IAAFTypeDefStream2 methods
IAAFEssenceDataSP pEssenceData2;
IAAFPropertyValueSP pDataPropertyValue2;
IAAFPropertyValueSP pSampleIndexPropertyValue2;
Test_CreateEssenceData(defs, pHeader, sMobID[3], sMobName[3], &pEssenceData2);
Test_EssenceStreamPropertyValues(pDictionary,
pEssenceData2,
&pDataPropertyValue2,
&pSampleIndexPropertyValue2);
// Test IAAFTypeDefStream3 methods
IAAFEssenceDataSP pEssenceData3;
IAAFPropertyValueSP pDataPropertyValue3;
IAAFPropertyValueSP pSampleIndexPropertyValue3;
Test_CreateEssenceData(defs, pHeader, sMobID[4], sMobName[4], &pEssenceData3);
Test_EssenceStreamPropertyValues(pDictionary,
pEssenceData3,
&pDataPropertyValue3,
&pSampleIndexPropertyValue3);
Test_KLVStreamParametersOnWrite(defs, pDataPropertyValue3);
Test_EssenceStreamWrite(defs, pDataPropertyValue3);
Test_KLVStreamParametersOnRead(defs, pDataPropertyValue3);
Test_EssenceStreamRead(defs, pDataPropertyValue3);
// Test the case when the stream data size approaches the KLV
// Alignment Grid (KAG) boundary and leaves some but not enough
// space to pad to the end of the boundary.
// (This is a test of edge conditions specific to KLV encoded files.)
IAAFEssenceDataSP pEssenceData4;
IAAFPropertyValueSP pDataPropertyValue4;
IAAFPropertyValueSP pSampleIndexPropertyValue4;
Test_CreateEssenceData(defs, pHeader, sMobID[5], sMobName[5], &pEssenceData4);
Test_EssenceStreamPropertyValues(pDictionary,
pEssenceData4,
&pDataPropertyValue4,
&pSampleIndexPropertyValue4);
Test_NearKAGBoundaryWrite(defs, pDataPropertyValue4);
Test_NearKAGBoundaryRead(defs, pDataPropertyValue4);
CheckResult(pFile->Save());
CheckResult(pFile->Close());
}
catch(AAFRESULT& hr)
{
// Ignore failure if file not open
pFile->Close();
CheckResult(hr);
}
}
static HRESULT ReadRecord (const aafWChar * pFileName, int loadingMode)
{
HRESULT hr = E_FAIL;
IAAFFileSP pFile;
try
{
// Open the file, and get the dictionary.
checkResult(AAFFileOpenExistingRead(pFileName, loadingMode, &pFile));
IAAFHeaderSP pHeader;
checkResult(pFile->GetHeader(&pHeader));
IAAFDictionarySP pDict;
checkResult (pHeader->GetDictionary(&pDict));
CAAFBuiltinDefs defs(pDict);
// get the SDK version against which we are testing
aafProductVersion_t testVer;
checkResult(pHeader->GetRefImplVersion(&testVer));
// Get the type definitions for our new types.
IAAFTypeDefSP ptd;
checkResult (pDict->LookupTypeDef (sTypeId_Rational16,
&ptd));
IAAFTypeDefRecordSP ptdr16;
checkResult (ptd->QueryInterface (IID_IAAFTypeDefRecord,
(void**) &ptdr16));
// check for duplicate initialization
aafUID_t nullUid = { 0 };
HRESULT temphr;
temphr = ptdr16->Initialize (nullUid,
0,
0,
1,
L"foo");
checkExpression (AAFRESULT_ALREADY_INITIALIZED == temphr,
AAFRESULT_TEST_FAILED);
aafUInt32 count = 0;
checkResult (ptdr16->GetCount (&count));
checkExpression (2 == count, AAFRESULT_TEST_FAILED);
aafUInt32 nameLen = 0;
aafCharacter nameBuf [100];
checkResult (ptdr16->GetMemberNameBufLen (0, &nameLen));
checkExpression (((wcslen(L"Numerator")+1)*sizeof(aafCharacter))
== nameLen,
AAFRESULT_TEST_FAILED);
checkExpression (nameLen < 100,
AAFRESULT_TEST_FAILED);
checkResult (ptdr16->GetMemberName (0,
nameBuf,
sizeof (nameBuf)));
checkExpression (0 == wcscmp (L"Numerator", nameBuf),
AAFRESULT_TEST_FAILED);
checkResult (ptdr16->GetMemberNameBufLen (1, &nameLen));
checkExpression (((wcslen(L"Denominator")+1)*sizeof (aafCharacter))
== nameLen,
AAFRESULT_TEST_FAILED);
checkExpression (nameLen < 100,
AAFRESULT_TEST_FAILED);
checkResult (ptdr16->GetMemberName (1,
nameBuf,
sizeof (nameBuf)));
checkExpression (0 == wcscmp (L"Denominator", nameBuf),
AAFRESULT_TEST_FAILED);
temphr = ptdr16->GetMemberNameBufLen (2, &nameLen);
checkExpression (AAFRESULT_ILLEGAL_VALUE == temphr,
AAFRESULT_TEST_FAILED);
temphr = ptdr16->GetMemberName (2,
nameBuf,
sizeof (nameBuf));
checkExpression (AAFRESULT_ILLEGAL_VALUE == temphr,
AAFRESULT_TEST_FAILED);
checkResult (pDict->LookupTypeDef (sTypeId_Rational16_pair,
&ptd));
IAAFTypeDefRecordSP ptdr16p;
checkResult (ptd->QueryInterface (IID_IAAFTypeDefRecord,
(void**) &ptdr16p));
// check for duplicate initialization
temphr = ptdr16p->Initialize (nullUid,
0,
0,
1,
L"foo");
checkExpression (AAFRESULT_ALREADY_INITIALIZED == temphr,
AAFRESULT_TEST_FAILED);
count = 0;
checkResult (ptdr16p->GetCount (&count));
checkExpression (2 == count, AAFRESULT_TEST_FAILED);
// Now attempt to register offsets of Rational16_pair. This
// should fail, because offsets of its members (of type
// Rational16) have not yet been registered.
temphr = RegisterRational16PairOffsets (ptdr16p);
checkExpression (temphr == AAFRESULT_NOT_REGISTERED,
AAFRESULT_TEST_FAILED);
// Now let's attempt registration the right way.
checkResult (RegisterRational16Offsets (ptdr16));
checkResult (RegisterRational16PairOffsets (ptdr16p));
// Setup to read the Velocity property which is of typed Mixed_t
checkResult (pDict->LookupTypeDef (sTypeId_Mixed, &ptd));
IAAFTypeDefRecordSP ptdrmixed;
checkResult (ptd->QueryInterface (IID_IAAFTypeDefRecord, (void**) &ptdrmixed));
temphr = RegisterMixedOffsets(ptdrmixed);
/* It is ok to return default already used due to current limitation
* in implementation that default registration may occur and tie us
* to a specific structural layout before we get the ability to
* register own offsets/layout. This is slated for fixing in
* future rev of the SDK.
*/
if (temphr == AAFRESULT_DEFAULT_ALREADY_USED) {
temphr = AAFRESULT_SUCCESS;
throw temphr;
}
checkResult (temphr);
IAAFTypeDef * pTempTd = 0;
checkResult (ptdr16->QueryInterface (IID_IAAFTypeDef,
(void**) &pTempTd));
CheckMemberTypeEqual (ptdr16p, 0, pTempTd);
CheckMemberTypeEqual (ptdr16p, 1, pTempTd);
pTempTd->Release ();
pTempTd = 0;
temphr = ptdr16p->GetMemberType (2, &pTempTd);
checkExpression (temphr == AAFRESULT_ILLEGAL_VALUE,
AAFRESULT_TEST_FAILED);
// register variable array of Rational16Pair records
IAAFTypeDefVariableArraySP ptdvaarpr;
IAAFTypeDefSP ptdarpr;
// perform this part only for specified versions
if( versionUInt(testVer) >= versionUInt(1,1,1,0) )
{
checkResult (pDict->LookupTypeDef (sTypeId_Rational16_array,&ptdarpr));
checkResult (ptdarpr->QueryInterface (IID_IAAFTypeDefVariableArray,(void**) &ptdvaarpr));
}
// Now read the CompositionMob to which we added some optional
// properties.
IEnumAAFMobsSP pEnumMobs;
checkResult (pHeader->GetMobs (0, &pEnumMobs));
IAAFMobSP pMob;
checkResult (pEnumMobs->NextOne (&pMob));
IAAFObjectSP pObj;
checkResult (pMob->QueryInterface (IID_IAAFObject,
(void**) &pObj));
// get the property definitions for the added properties
IAAFPropertyDefSP pPdPosA;
checkResult (defs.cdCompositionMob()->
LookupPropertyDef (sPropertyId_positionA,
&pPdPosA));
IAAFPropertyDefSP pPdPosB;
checkResult (defs.cdCompositionMob()->
LookupPropertyDef (sPropertyId_positionB,
&pPdPosB));
IAAFPropertyDefSP pPdPosC;
checkResult (defs.cdCompositionMob()->
LookupPropertyDef (sPropertyId_positionC,
&pPdPosC));
IAAFPropertyValueSP pPVa;
checkResult (pObj->GetPropertyValue (pPdPosA, &pPVa));
IAAFPropertyValueSP pPVb;
checkResult (pObj->GetPropertyValue (pPdPosB, &pPVb));
IAAFPropertyValueSP pPVc;
checkResult (pObj->GetPropertyValue (pPdPosC, &pPVc));
// Read back the value of the Velocity property
IAAFPropertyDefSP pPdvelocity;
checkResult (defs.cdCompositionMob()->LookupPropertyDef(sPropertyId_velocity, &pPdvelocity));
IAAFPropertyValueSP pPVvelocity;
checkResult (pObj->GetPropertyValue (pPdvelocity, &pPVvelocity));
Mixed_t velocity = {0, 0};
checkResult (ptdrmixed->GetStruct (pPVvelocity, (aafMemPtr_t) &velocity, sizeof (velocity)));
checkExpression (15 == velocity.angle, AAFRESULT_TEST_FAILED);
checkExpression (2001 == velocity.speed, AAFRESULT_TEST_FAILED);
// Try to read the first one with GetStruct.
Rational16pair_t valA = { {0,0},{0,0} };
checkResult (ptdr16p->GetStruct (pPVa,
(aafMemPtr_t) &valA,
sizeof (valA)));
checkExpression (1 == valA.X_Position.Numerator,
AAFRESULT_TEST_FAILED);
checkExpression (2 == valA.X_Position.Denominator,
AAFRESULT_TEST_FAILED);
checkExpression (3 == valA.Y_Position.Numerator,
AAFRESULT_TEST_FAILED);
checkExpression (4 == valA.Y_Position.Denominator,
AAFRESULT_TEST_FAILED);
// Try to read the second one by decomposing with GetValue.
Rational16pair_t valB = { {5, 6}, {7, 8} };
CheckRational16PairByValues (ptdr16p, ptdr16, pPVb, valB);
// Read the last two with GetStruct just to get it over with. ;)
Rational16pair_t valC = { {0,0},{0,0} };
temphr = ptdr16p->GetStruct (pPVc,
(aafMemPtr_t) &valC,
sizeof (valC)-1);
checkExpression (AAFRESULT_ILLEGAL_VALUE == temphr,
AAFRESULT_TEST_FAILED);
temphr = ptdr16p->GetStruct (0,
(aafMemPtr_t) &valC,
sizeof (valC));
checkExpression (AAFRESULT_NULL_PARAM == temphr,
AAFRESULT_TEST_FAILED);
temphr = ptdr16p->GetStruct (pPVc,
0,
sizeof (valC));
checkExpression (AAFRESULT_NULL_PARAM == temphr,
AAFRESULT_TEST_FAILED);
checkResult (ptdr16p->GetStruct (pPVc,
(aafMemPtr_t) &valC,
sizeof (valC)));
checkExpression (9 == valC.X_Position.Numerator,
AAFRESULT_TEST_FAILED);
checkExpression (10 == valC.X_Position.Denominator,
AAFRESULT_TEST_FAILED);
checkExpression (11 == valC.Y_Position.Numerator,
AAFRESULT_TEST_FAILED);
checkExpression (12 == valC.Y_Position.Denominator,
AAFRESULT_TEST_FAILED);
// test variable array of records
// perform this part only for specified versions
if( versionUInt(testVer) >= versionUInt(1,1,1,0) )
{
IAAFPropertyDefSP pPdPosN;
checkResult (defs.cdCompositionMob()->LookupPropertyDef (sPropertyId_positionN, &pPdPosN));
IAAFPropertyValueSP pPVN;
checkResult (pObj->GetPropertyValue (pPdPosN, &pPVN));
// get the middle element of the array, 9abc
IAAFPropertyValueSP pPVN1;
checkResult (ptdvaarpr->GetElementValue (pPVN, 1, &pPVN1));
// Read the value with GetStruct
Rational16pair_t valN1 = { {0,0},{0,0} };
checkResult (ptdr16p->GetStruct (pPVN1,
(aafMemPtr_t) &valN1,
sizeof (valN1)));
checkExpression (9 == valN1.X_Position.Numerator,
AAFRESULT_TEST_FAILED);
checkExpression (10 == valN1.X_Position.Denominator,
AAFRESULT_TEST_FAILED);
checkExpression (11 == valN1.Y_Position.Numerator,
AAFRESULT_TEST_FAILED);
checkExpression (12 == valN1.Y_Position.Denominator,
AAFRESULT_TEST_FAILED);
}
// Attempt to close the file.
checkResult(pFile->Close());
IAAFFileSP nullFile;
pFile = nullFile; // zeros the pFile, and releases it.
hr = AAFRESULT_SUCCESS;
}
catch (HRESULT& rResult)
{
hr = rResult;
}
// cleanup
if (pFile)
{
pFile->Close();
}
return hr;
}
static HRESULT ReadRecordNoStructs (const aafWChar * pFileName, int loadingMode)
{
HRESULT hr = E_FAIL;
HRESULT temphr;
IAAFFileSP pFile;
try
{
// Open the file, and get the dictionary.
checkResult(AAFFileOpenExistingRead(pFileName, loadingMode, &pFile));
IAAFHeaderSP pHeader;
checkResult(pFile->GetHeader(&pHeader));
IAAFDictionarySP pDict;
checkResult (pHeader->GetDictionary(&pDict));
CAAFBuiltinDefs defs(pDict);
// get the SDK version against which we are testing
aafProductVersion_t testVer;
checkResult(pHeader->GetRefImplVersion(&testVer));
// Get the type definitions for our new types.
IAAFTypeDefSP ptd;
checkResult (pDict->LookupTypeDef (sTypeId_Rational16,
&ptd));
IAAFTypeDefRecordSP ptdr16;
checkResult (ptd->QueryInterface (IID_IAAFTypeDefRecord,
(void**) &ptdr16));
checkResult (pDict->LookupTypeDef (sTypeId_Rational16_pair,
&ptd));
IAAFTypeDefRecordSP ptdr16p;
checkResult (ptd->QueryInterface (IID_IAAFTypeDefRecord,
(void**) &ptdr16p));
// Setup to read the Velocity property which is of typed Mixed_t
checkResult (pDict->LookupTypeDef (sTypeId_Mixed, &ptd));
IAAFTypeDefRecordSP ptdrmixed;
checkResult (ptd->QueryInterface (IID_IAAFTypeDefRecord, (void**) &ptdrmixed));
IAAFTypeDef * pTempTd = 0;
checkResult (ptdr16->QueryInterface (IID_IAAFTypeDef,
(void**) &pTempTd));
CheckMemberTypeEqual (ptdr16p, 0, pTempTd);
CheckMemberTypeEqual (ptdr16p, 1, pTempTd);
pTempTd->Release ();
pTempTd = 0;
temphr = ptdr16p->GetMemberType (2, &pTempTd);
checkExpression (temphr == AAFRESULT_ILLEGAL_VALUE,
AAFRESULT_TEST_FAILED);
// register variable array of Rational16Pair records
IAAFTypeDefVariableArraySP ptdvaarpr;
IAAFTypeDefSP ptdarpr;
// perform this part only for specified versions
if( versionUInt(testVer) >= versionUInt(1,1,1,0) )
{
checkResult (pDict->LookupTypeDef (sTypeId_Rational16_array,&ptdarpr));
checkResult (ptdarpr->QueryInterface (IID_IAAFTypeDefVariableArray,(void**) &ptdvaarpr));
}
// Now read the CompositionMob to which we added some optional
// properties.
IEnumAAFMobsSP pEnumMobs;
checkResult (pHeader->GetMobs (0, &pEnumMobs));
IAAFMobSP pMob;
checkResult (pEnumMobs->NextOne (&pMob));
IAAFObjectSP pObj;
checkResult (pMob->QueryInterface (IID_IAAFObject,
(void**) &pObj));
// get the property definitions for the added properties
IAAFPropertyDefSP pPdPosA;
checkResult (defs.cdCompositionMob()->
LookupPropertyDef (sPropertyId_positionA,
&pPdPosA));
IAAFPropertyDefSP pPdPosB;
checkResult (defs.cdCompositionMob()->
LookupPropertyDef (sPropertyId_positionB,
&pPdPosB));
IAAFPropertyDefSP pPdPosC;
checkResult (defs.cdCompositionMob()->
LookupPropertyDef (sPropertyId_positionC,
&pPdPosC));
IAAFPropertyValueSP pPVa;
checkResult (pObj->GetPropertyValue (pPdPosA, &pPVa));
IAAFPropertyValueSP pPVb;
checkResult (pObj->GetPropertyValue (pPdPosB, &pPVb));
IAAFPropertyValueSP pPVc;
checkResult (pObj->GetPropertyValue (pPdPosC, &pPVc));
// Read back the value of the Velocity property
IAAFPropertyDefSP pPdvelocity;
checkResult (defs.cdCompositionMob()->LookupPropertyDef(sPropertyId_velocity, &pPdvelocity));
IAAFPropertyValueSP pPVvelocity;
checkResult (pObj->GetPropertyValue (pPdvelocity, &pPVvelocity));
IAAFPropertyValueSP pPVvelocityAngle, pPVvelocitySpeed;
checkResult (ptdrmixed->GetValue (pPVvelocity, 0, &pPVvelocityAngle));
checkResult (ptdrmixed->GetValue (pPVvelocity, 1, &pPVvelocitySpeed));
Mixed_t velocity = {0, 0};
IAAFTypeDefSP pTDmem;
IAAFTypeDefIntSP pTDIntMem;
checkResult (ptdrmixed->GetMemberType (0, &pTDmem));
checkResult (pTDmem->QueryInterface (IID_IAAFTypeDefInt,
(void **) &pTDIntMem));
checkResult (pTDIntMem->GetInteger (pPVvelocityAngle,
(aafMemPtr_t)(&velocity.angle),
sizeof(velocity.angle)));
checkResult (ptdrmixed->GetMemberType (1, &pTDmem));
checkResult (pTDmem->QueryInterface (IID_IAAFTypeDefInt,
(void **) &pTDIntMem));
checkResult (pTDIntMem->GetInteger (pPVvelocitySpeed,
(aafMemPtr_t)(&velocity.speed),
sizeof(velocity.speed)));
checkExpression (15 == velocity.angle, AAFRESULT_TEST_FAILED);
checkExpression (2001 == velocity.speed, AAFRESULT_TEST_FAILED);
// Try to read the first one
Rational16pair_t valA = { {1, 2}, {3, 4} };
CheckRational16PairByValues (ptdr16p, ptdr16, pPVa, valA);
// Try to read the second one
Rational16pair_t valB = { {5, 6}, {7, 8} };
CheckRational16PairByValues (ptdr16p, ptdr16, pPVb, valB);
// Check misc. error return conditions for TypeDefRecord GetValue
IAAFPropertyValueSP junkPv;
temphr = ptdr16->GetValue (0, 1, &junkPv);
checkExpression (AAFRESULT_NULL_PARAM == temphr,
AAFRESULT_TEST_FAILED);
temphr = ptdr16p->GetValue (pPVb, 1, 0);
checkExpression (AAFRESULT_NULL_PARAM == temphr,
AAFRESULT_TEST_FAILED);
// Read the last two with GetStruct just to get it over with. ;)
Rational16pair_t valC = { {9, 10}, {11, 12} };
CheckRational16PairByValues (ptdr16p, ptdr16, pPVc, valC);
// test variable array of records
// perform this part only for specified versions
if( versionUInt(testVer) >= versionUInt(1,1,1,0) )
{
IAAFPropertyDefSP pPdPosN;
checkResult (defs.cdCompositionMob()->LookupPropertyDef (sPropertyId_positionN, &pPdPosN));
IAAFPropertyValueSP pPVN;
checkResult (pObj->GetPropertyValue (pPdPosN, &pPVN));
// get the middle element of the array, 9abc
IAAFPropertyValueSP pPVN1;
checkResult (ptdvaarpr->GetElementValue (pPVN, 1, &pPVN1));
// Read the value with GetStruct
Rational16pair_t valN1 = { {9,10},{11,12} };
CheckRational16PairByValues (ptdr16p, ptdr16, pPVN1, valN1);
}
// Attempt to close the file.
checkResult(pFile->Close());
IAAFFileSP nullFile;
pFile = nullFile; // zeros the pFile, and releases it.
hr = AAFRESULT_SUCCESS;
}
catch (HRESULT& rResult)
{
hr = rResult;
}
// cleanup
if (pFile)
{
pFile->Close();
}
return hr;
}
static HRESULT WriteRecord (
const aafWChar * pFileName,
aafUID_constref fileKind,
testRawStorageType_t rawStorageType,
aafProductIdentification_constref productID)
{
HRESULT hr = E_FAIL;
IAAFFileSP pFile;
try
{
HRESULT temphr;
// Remove the previous test file if any.
RemoveTestFile(pFileName);
// Create the file and get the new file's header.
checkResult(CreateTestFile( pFileName, fileKind, rawStorageType, productID, &pFile ));
IAAFHeaderSP pHeader;
checkResult(pFile->GetHeader(&pHeader));
IAAFDictionarySP pDict;
checkResult (pHeader->GetDictionary(&pDict));
CAAFBuiltinDefs defs(pDict);
// get the SDK version against which we are testing
aafProductVersion_t testVer;
checkResult(pHeader->GetRefImplVersion(&testVer));
// Create, initialize, and register the Rational16 type, to
// consist of an Int16 numerator and a UInt16 denominator.
IAAFTypeDef* tdr16MemberTypes[] =
{defs.tdInt16(),
defs.tdUInt16()};
aafWChar numerator[] = L"Numerator";
aafWChar denominator[] = L"Denominator";
aafString_t tdr16MemberNames[] =
{numerator,
denominator};
IAAFTypeDefRecordSP ptdr16;
checkResult (pDict->
CreateMetaInstance (kAAFClassID_TypeDefRecord,
IID_IAAFTypeDefRecord,
(IUnknown**) &ptdr16));
checkResult (ptdr16->Initialize (sTypeId_Rational16,
tdr16MemberTypes,
tdr16MemberNames,
2,
L"Rational16"));
// check for duplicate initialization
temphr = ptdr16->Initialize (sTypeId_Rational16,
tdr16MemberTypes,
tdr16MemberNames,
2,
L"Rational16");
checkExpression (AAFRESULT_ALREADY_INITIALIZED == temphr,
AAFRESULT_TEST_FAILED);
IAAFTypeDefSP ptd;
checkResult (ptdr16->QueryInterface (IID_IAAFTypeDef, (void**) &ptd));
checkResult (pDict->RegisterTypeDef (ptd));
// Create, initialize, and register the Rational16Position type,
// to consist of a Rational16 X and Rational16 Y coordinates.
IAAFTypeDefRecordSP ptdr16p;
//checkResult (defs.cdTypeDefRecord()->
// CreateInstance (IID_IAAFTypeDefRecord,
// (IUnknown**)&ptdr16p));
checkResult (pDict->
CreateMetaInstance (kAAFClassID_TypeDefRecord,
IID_IAAFTypeDefRecord,
(IUnknown**) &ptdr16p));
IAAFTypeDef * pTempTd = 0;
checkResult (ptdr16->QueryInterface (IID_IAAFTypeDef,
(void**) &pTempTd));
IAAFTypeDef* tdr16pMemberTypes[] =
{pTempTd,
pTempTd};
aafWChar xpos[] = L"X Position";
aafWChar ypos[] = L"Y Position";
aafString_t tdr16pMemberNames[] =
{xpos,
ypos};
checkResult (ptdr16p->Initialize (sTypeId_Rational16_pair,
tdr16pMemberTypes,
tdr16pMemberNames,
2,
L"Rational16Pair"));
// check for duplicate initialization
temphr = ptdr16p->Initialize (sTypeId_Rational16,
tdr16pMemberTypes,
tdr16pMemberNames,
2,
L"Rational16Pair");
checkExpression (AAFRESULT_ALREADY_INITIALIZED == temphr,
AAFRESULT_TEST_FAILED);
pTempTd->Release ();
pTempTd = 0;
checkResult (ptdr16p->QueryInterface (IID_IAAFTypeDef, (void**) &ptd));
checkResult (pDict->RegisterTypeDef (ptd));
// Now attempt to register offsets of Rational16_pair. This
// should fail, because offsets of its members (of type
// Rational16) have not yet been registered.
temphr = RegisterRational16PairOffsets (ptdr16p);
checkExpression (temphr == AAFRESULT_NOT_REGISTERED,
AAFRESULT_TEST_FAILED);
// Now let's attempt registration the right way.
checkResult (RegisterRational16Offsets (ptdr16));
checkResult (RegisterRational16PairOffsets (ptdr16p));
// register variable array of Rational16Pair records
IAAFTypeDefVariableArraySP ptdvaarpr;
IAAFTypeDefSP ptdarpr;
// perform this part only for specified versions
if( versionUInt(testVer) >= versionUInt(1,1,1,0) )
{
//Create a Variable Array
checkResult(pDict->CreateMetaInstance (AUID_AAFTypeDefVariableArray, IID_IAAFTypeDefVariableArray, (IUnknown **) &ptdvaarpr));
//IAAFTypeDefVariableArray::Initialize
checkResult(ptdvaarpr->Initialize(sTypeId_Rational16_array, ptd, L"Rational16PairArray"));
// Register our new VA type def :
checkResult(ptdvaarpr->QueryInterface(IID_IAAFTypeDef, (void**)&ptdarpr));
checkResult(pDict->RegisterTypeDef(ptdarpr));
}
// Create a new property on Composition mob (called Position)
// whose type is Rational16_pair.
checkResult (ptdr16p->QueryInterface (IID_IAAFTypeDef,
(void**) &ptd));
IAAFPropertyDefSP pPropDefPosA;
IAAFPropertyDefSP pPropDefPosB;
IAAFPropertyDefSP pPropDefPosC;
checkResult (defs.cdCompositionMob()->RegisterOptionalPropertyDef
(sPropertyId_positionA,
L"PositionA",
ptd,
&pPropDefPosA));
checkResult (defs.cdCompositionMob()->RegisterOptionalPropertyDef
(sPropertyId_positionB,
L"PositionB",
ptd,
&pPropDefPosB));
checkResult (defs.cdCompositionMob()->RegisterOptionalPropertyDef
(sPropertyId_positionC,
L"PositionC",
ptd,
&pPropDefPosC));
// register property of type variable array of Rational16Pair records
IAAFPropertyDefSP pPropDefPosN;
// perform this part only for specified versions
if( versionUInt(testVer) >= versionUInt(1,1,1,0) )
{
checkResult (defs.cdCompositionMob()->RegisterOptionalPropertyDef
(sPropertyId_positionN,
L"PositionN",
ptdarpr,
&pPropDefPosN));
}
// Register the Mixed_t type
IAAFTypeDef* tdMixedMemberTypes[] = {defs.tdInt8(), defs.tdUInt32()};
aafWChar str_angle[] = L"Angle";
aafWChar str_speed[] = L"Speed";
aafString_t tdMixedMemberNames[] = {str_angle, str_speed};
IAAFTypeDefRecordSP ptdrmixed;
checkResult(pDict->CreateMetaInstance(kAAFClassID_TypeDefRecord, IID_IAAFTypeDefRecord, (IUnknown**) &ptdrmixed));
checkResult(ptdrmixed->Initialize(sTypeId_Mixed, tdMixedMemberTypes, tdMixedMemberNames, 2, L"Mixed"));
// Register Mixed type def
IAAFTypeDefSP ptdmixed;
checkResult(ptdrmixed->QueryInterface(IID_IAAFTypeDef, (void**)&ptdmixed));
checkResult(pDict->RegisterTypeDef(ptdmixed));
checkResult(RegisterMixedOffsets(ptdrmixed));
// Added Velocity property to Composition Mob
IAAFPropertyDefSP pPropDefVelocity;
checkResult (defs.cdCompositionMob()->RegisterOptionalPropertyDef
(sPropertyId_velocity,
L"Velocity",
ptdmixed,
&pPropDefVelocity));
// Create one of our new CompositionMobs, and add a values for
// the Position property.
IAAFCompositionMobSP pcm;
checkResult (defs.cdCompositionMob()->
CreateInstance (IID_IAAFCompositionMob,
(IUnknown**)&pcm));
// Add property value for PositionA using CreateValueFromValues
// methods. The constituent property values will be created
// from CreateValueFromStruct, and from SetValueFromStruct.
const Rational16_t v_12 = {1, 2};
const Rational16_t v_34 = {3, 4};
IAAFPropertyValue * pValRat[2] = { 0 };
checkResult (ptdr16->
CreateValueFromStruct ((aafMemPtr_t) &v_12,
sizeof (v_12),
&pValRat[0]));
// create it with wrong data, and use SetStruct to give it right
// data
checkResult (ptdr16->
CreateValueFromStruct ((aafMemPtr_t) &v_12,
sizeof (v_12),
&pValRat[1]));
checkResult (ptdr16->
SetStruct (pValRat[1],
(aafMemPtr_t) &v_34,
sizeof (v_34)));
// Create the Rational16_pair property value from the
// Rational16 property values.
IAAFPropertyValueSP pRat16PairVal_1234;
temphr = ptdr16p->CreateValueFromValues (0,
2,
&pRat16PairVal_1234);
checkExpression (AAFRESULT_NULL_PARAM == temphr,
AAFRESULT_TEST_FAILED);
temphr = ptdr16p->CreateValueFromValues (pValRat,
1,
&pRat16PairVal_1234);
checkExpression (AAFRESULT_ILLEGAL_VALUE == temphr,
AAFRESULT_TEST_FAILED);
checkResult (ptdr16p->CreateValueFromValues (pValRat,
2,
&pRat16PairVal_1234));
pValRat[0]->Release ();
pValRat[0] = 0;
pValRat[1]->Release ();
pValRat[1] = 0;
IAAFObjectSP pObj;
checkResult (pcm->QueryInterface (IID_IAAFObject,
(void**) &pObj));
checkResult (pObj->SetPropertyValue (pPropDefPosA,
pRat16PairVal_1234));
// Add property value for PositionB using CreateValueFromStruct
// methods.
const Rational16_t r16_56 = {5, 6};
const Rational16_t r16_78 = {7, 8};
Rational16pair_t r16p_5678;
r16p_5678.X_Position = r16_56;
r16p_5678.Y_Position = r16_78;
IAAFPropertyValueSP pRat16PairVal_5678;
temphr = ptdr16p->
CreateValueFromStruct (0,
sizeof (r16p_5678),
&pRat16PairVal_5678);
checkExpression (AAFRESULT_NULL_PARAM == temphr,
AAFRESULT_TEST_FAILED);
temphr = ptdr16p->
CreateValueFromStruct ((aafMemPtr_t) &r16p_5678,
sizeof (r16p_5678),
0);
checkExpression (AAFRESULT_NULL_PARAM == temphr,
AAFRESULT_TEST_FAILED);
temphr = ptdr16p->
CreateValueFromStruct ((aafMemPtr_t) &r16p_5678,
sizeof (r16p_5678)+1,
&pRat16PairVal_5678);
checkExpression (AAFRESULT_ILLEGAL_VALUE == temphr,
AAFRESULT_TEST_FAILED);
checkResult (ptdr16p->
CreateValueFromStruct ((aafMemPtr_t) &r16p_5678,
sizeof (r16p_5678),
&pRat16PairVal_5678));
checkResult (pObj->SetPropertyValue (pPropDefPosB,
pRat16PairVal_5678));
// Add property value for PositionC using CreateValueFromStruct
// methods, and then use SetStruct to set the value.
const Rational16_t r16_9a = {9, 10};
const Rational16_t r16_bc = {11, 12};
Rational16pair_t r16p_9abc;
r16p_9abc.X_Position = r16_9a;
r16p_9abc.Y_Position = r16_bc;
IAAFPropertyValueSP pRat16PairVal_9abc;
checkResult (ptdr16p->
CreateValueFromStruct ((aafMemPtr_t) &r16p_5678,
sizeof (r16p_5678),
&pRat16PairVal_9abc));
temphr = ptdr16p->SetStruct (0,
(aafMemPtr_t) &r16p_9abc,
sizeof (r16p_9abc));
checkExpression (AAFRESULT_NULL_PARAM == temphr,
AAFRESULT_TEST_FAILED);
temphr = ptdr16p->SetStruct (pRat16PairVal_9abc,
0,
sizeof (r16p_9abc));
checkExpression (AAFRESULT_NULL_PARAM == temphr,
AAFRESULT_TEST_FAILED);
temphr = ptdr16p->SetStruct (pRat16PairVal_9abc,
(aafMemPtr_t) &r16p_9abc,
sizeof (r16p_9abc)-1);
checkExpression (AAFRESULT_ILLEGAL_VALUE == temphr,
AAFRESULT_TEST_FAILED);
checkResult (ptdr16p->SetStruct (pRat16PairVal_9abc,
(aafMemPtr_t) &r16p_9abc,
sizeof (r16p_9abc)));
checkResult (pObj->SetPropertyValue (pPropDefPosC,
pRat16PairVal_9abc));
// add a value of PropertyN
IAAFPropertyValueSP spArrayPropertyValue;
// perform this part only for specified versions
if( versionUInt(testVer) >= versionUInt(1,1,1,0) )
{
// Create an empty array and then fill it by appending elements...
checkResult( ptdvaarpr->CreateEmptyValue (&spArrayPropertyValue) );
// intentionally in permuted order
checkResult( ptdvaarpr->AppendElement(spArrayPropertyValue, pRat16PairVal_5678) );
checkResult( ptdvaarpr->AppendElement(spArrayPropertyValue, pRat16PairVal_9abc) );
checkResult( ptdvaarpr->AppendElement(spArrayPropertyValue, pRat16PairVal_1234) );
// set PropertyN
checkResult ( pObj->SetPropertyValue( pPropDefPosN, spArrayPropertyValue ) );
}
// Set the value on the new Velocity property (of Mixed_t type)
const Mixed_t velocty = {15, 2001};
IAAFPropertyValueSP pVelocity;
checkResult (ptdrmixed->CreateValueFromStruct((aafMemPtr_t) &velocty, sizeof(velocty), &pVelocity));
checkResult (pObj->SetPropertyValue(pPropDefVelocity, pVelocity));
//Put the modified comp mob into the file.
IAAFMobSP pMob;
checkResult (pcm->QueryInterface (IID_IAAFMob,
(void**) &pMob));
checkResult (pHeader->AddMob(pMob));
// Attempt to save the file.
checkResult(pFile->Save());
// Attempt to close the file.
checkResult(pFile->Close());
IAAFFileSP nullFile;
pFile = nullFile; // zeros the pFile, and releases it.
hr = AAFRESULT_SUCCESS;
}
catch (HRESULT& rResult)
{
hr = rResult;
}
// cleanup
if (pFile)
{
pFile->Save();
pFile->Close();
}
return hr;
}
static HRESULT ReadAAFFile(aafWChar* pFileName)
{
IAAFFileSP pFile;
IAAFHeaderSP pHeader;
IEnumAAFMobsSP pMobIter;
IAAFMobSP pMob;
IEnumAAFMobSlotsSP pSlotIter;
IAAFMobSlotSP pSlot;
IAAFComponentSP pComp;
IAAFSegmentSP pSegment;
IAAFDataDefSP pDataDef;
IAAFSequenceSP pSequence;
IAAFDictionarySP pDictionary;
IEnumAAFComponentsSP pCompIter;
aafNumSlots_t numMobs;
aafSearchCrit_t criteria;
HRESULT hr = S_OK;
try
{
// Open the AAF file
checkResult(AAFFileOpenExistingRead(pFileName, 0, &pFile));
// Get the AAF file header.
checkResult(pFile->GetHeader(&pHeader));
// Validate that there is only one composition mob.
checkResult(pHeader->CountMobs(kAAFCompMob, &numMobs));
checkExpression(1 == numMobs, AAFRESULT_TEST_FAILED);
// Get the AAF Dictionary so that we can create valid AAF objects.
checkResult(pHeader->GetDictionary(&pDictionary));
CAAFBuiltinDefs defs (pDictionary);
// Check a data definition from a composition MOB in order to test weak references
criteria.searchTag = kAAFByMobKind;
criteria.tags.mobKind = kAAFCompMob;
checkResult(pHeader->GetMobs(&criteria, &pMobIter));
while (pMobIter && pMobIter->NextOne(&pMob) == AAFRESULT_SUCCESS)
{
// Enumerate the first MOB slot for this MOB
checkResult(pMob->GetSlots(&pSlotIter));
checkResult(pSlotIter->NextOne(&pSlot));
checkResult(pSlot->GetSegment(&pSegment));
checkResult(pSegment->QueryInterface(IID_IAAFSequence, (void **) &pSequence));
checkResult(pSequence->GetComponents(&pCompIter));
checkResult(pCompIter->NextOne(&pComp));
aafBool testBool;
checkResult(pComp->GetDataDef(&pDataDef));
checkResult(pDataDef->IsSoundKind(&testBool));
checkExpression(testBool == kAAFFalse, AAFRESULT_TEST_FAILED);
checkResult(pDataDef->IsDataDefOf(defs.ddkAAFPictureWithMatte(), &testBool));
checkExpression(testBool == kAAFTrue, AAFRESULT_TEST_FAILED);
// Make sure first component is a filler, and is our extended
// class. To do that, we'll compare the class def we looked
// up in the dict, with the one we got from the new object.
//
// First get the class from the object.
IAAFFillerSP pFill;
checkResult(pComp->QueryInterface(IID_IAAFFiller,
(void **) &pFill));
assert (pFill);
IAAFObjectSP pObj;
checkResult(pFill->QueryInterface(IID_IAAFObject,
(void **) &pObj));
assert (pObj);
IAAFClassDefSP pClassFromObj;
checkResult (pObj->GetDefinition (&pClassFromObj));
assert (pClassFromObj);
IUnknownSP pUnkFromObj;
checkResult(pClassFromObj->QueryInterface(IID_IUnknown,
(void **) &pUnkFromObj));
// Now get the class from the dict
IAAFClassDefSP pClassFromDict;
checkResult (pDictionary->LookupClassDef (kClassAUID_NewFill,
&pClassFromDict));
assert (pClassFromDict);
IUnknownSP pUnkFromDict;
checkResult(pClassFromDict->QueryInterface(IID_IUnknown,
(void **) &pUnkFromDict));
// Compare class from object with class from dict. Compare
// using IUnknown pointers.
assert (((IUnknown*)pUnkFromObj) ==
((IUnknown*)pUnkFromDict));
// To test GetClassDefinitions(), try explicit lookup.
IEnumAAFClassDefsSP pClassDefEnum;
checkResult (pDictionary->GetClassDefs (&pClassDefEnum));
bool found = false;
IAAFClassDefSP cd;
while (SUCCEEDED (pClassDefEnum->NextOne (&cd)))
{
IAAFMetaDefinitionSP def;
checkResult(cd->QueryInterface(IID_IAAFMetaDefinition,
(void **) &def));
aafUID_t classid;
checkResult (def->GetAUID (&classid));
if (EqualGUID (&classid, &kClassAUID_NewFill))
{
// Found it the hard way.
found = true;
break;
}
}
// make sure we found it the hard way.
checkExpression(found == kAAFTrue, AAFRESULT_TEST_FAILED);
// Get the 'odor' property from our new fill clip. Make
// sure it is set to the value we think it should be
// ('42').
//
// First get the property def from the class.
IAAFPropertyDefSP pPropDef;
checkResult (pClassFromObj->LookupPropertyDef
(kPropAUID_NewFill_Odor,
&pPropDef));
//
// Get the property value from the object
IAAFPropertyValueSP pPropVal;
checkResult (pObj->GetPropertyValue (pPropDef, &pPropVal));
//
// We know the property is int32; get the int32 type def
IAAFTypeDefSP ptd;
checkResult (pDictionary->LookupTypeDef
(kAAFTypeID_UInt32,
&ptd));
IAAFTypeDefIntSP pTDUint32;
checkResult(ptd->QueryInterface(IID_IAAFTypeDefInt,
(void **) &pTDUint32));
assert (pTDUint32);
//
// Ask the typedef to interpret this property value for us.
aafUInt32 odorValue = 0;
checkResult (pTDUint32->GetInteger
(pPropVal,
(aafMemPtr_t) &odorValue,
sizeof (odorValue)));
//
// make sure it's what we expect.
assert (42 == odorValue);
}
checkResult (LookupDefs (pDictionary));
//Test the Lookup KLV and Tagged methods
IAAFKLVDataDefinition *pKLVLook = NULL;
IAAFTaggedValueDefinition *pTAGDefLook = NULL;
IAAFDictionary2 *pDic2 = NULL;
IAAFDefObject *pKLVDataDefObj = NULL;
IAAFDefObject *pTaggedValueDefObj = NULL;
aafUID_t auid;
checkResult( pDictionary->QueryInterface( IID_IAAFDictionary2, reinterpret_cast<void**>(&pDic2) ) );
assert(pDic2);
//test LookUpKLV()
if(pDic2->LookupKLVDataDef(KLVDef_TestData, &pKLVLook) != AAFRESULT_SUCCESS)
checkResult(AAFRESULT_TEST_FAILED);
checkResult( pKLVLook->QueryInterface( IID_IAAFDefObject, reinterpret_cast<void**>(&pKLVDataDefObj) ) );
assert(pKLVDataDefObj);
//ensure the KLVLook auid is equal to KLVDef_TestData auid
checkResult(pKLVDataDefObj->GetAUID(&auid));
if(auid != KLVDef_TestData)
checkResult(AAFRESULT_TEST_FAILED);
//test LookUpTagged()
if(pDic2->LookupTaggedValueDef(TAGDef_TestData, &pTAGDefLook) != AAFRESULT_SUCCESS)
checkResult(AAFRESULT_TEST_FAILED);
checkResult( pTAGDefLook->QueryInterface( IID_IAAFDefObject, reinterpret_cast<void**>(&pTaggedValueDefObj) ) );
assert(pTaggedValueDefObj);
//ensure the TAGDefLook auid is equal to TAGDef_TestData auid
checkResult(pTaggedValueDefObj->GetAUID(&auid));
if(auid != TAGDef_TestData)
checkResult(AAFRESULT_TEST_FAILED);
//cleanup
pDic2->Release();
pDic2 = NULL;
pKLVLook->Release();
pKLVLook = NULL;
pTAGDefLook->Release();
pTAGDefLook = NULL;
pKLVDataDefObj->Release();
pKLVDataDefObj = NULL;
pTaggedValueDefObj->Release();
pTaggedValueDefObj = NULL;
}
catch (HRESULT& rResult)
{
hr = rResult;
}
// Cleanup and return.
if (pFile)
{
pFile->Close();
}
return hr;
}
static HRESULT CreateAAFFile(
aafWChar * pFileName,
aafUID_constref fileKind,
testRawStorageType_t rawStorageType,
aafProductIdentification_constref productID)
{
IAAFFileSP pFile;
IAAFHeaderSP pHeader;
IAAFDictionarySP pDictionary;
IAAFMobSP pMob;
IAAFTimelineMobSlotSP pMobSlot;
IAAFSequenceSP pSequence;
IAAFSegmentSP pSegment;
IAAFComponentSP pComponent;
int i;
HRESULT hr = S_OK;
try
{
// Remove the previous test file if any.
RemoveTestFile(pFileName);
// Create the AAF file
checkResult(CreateTestFile( pFileName, fileKind, rawStorageType, productID, &pFile ));
// Get the AAF file header.
checkResult(pFile->GetHeader(&pHeader));
// Get the AAF Dictionary so that we can create valid AAF objects.
checkResult(pHeader->GetDictionary(&pDictionary));
// Create a new class, and register it in the dictionary.
RegisterNewClass (pDictionary);
CAAFBuiltinDefs defs (pDictionary);
// Create a Composition Mob
checkResult(defs.cdCompositionMob()->
CreateInstance(IID_IAAFMob,
(IUnknown **)&pMob));
checkResult(pMob->SetMobID(TEST_MobID));
checkResult(pMob->SetName(L"AAFDictionaryTest"));
// Add mob slot w/ Sequence
checkResult(defs.cdSequence()->
CreateInstance(IID_IAAFSequence,
(IUnknown **)&pSequence));
checkResult(pSequence->Initialize(defs.ddkAAFPicture()));
//
// Add some segments. Need to test failure conditions
// (i.e. starting/ending w/ transition, two trans back
// to back).
//
for(i = 0; i < kNumComponents; i++)
{
aafLength_t len = 10;
// For the first component, make it our extended filler.
if(i == 0)
{
IAAFClassDefSP pNewFillClassDef;
checkResult(pDictionary->LookupClassDef(kClassAUID_NewFill,
&pNewFillClassDef));
checkResult
(pNewFillClassDef->CreateInstance(IID_IAAFComponent,
(IUnknown**)&pComponent));
checkResult(pComponent->SetDataDef(defs.ddkAAFPictureWithMatte()));
}
else
{
checkResult
(defs.cdFiller()->CreateInstance(IID_IAAFComponent,
(IUnknown**)&pComponent));
checkResult(pComponent->SetDataDef(defs.ddkAAFPicture()));
}
checkResult(pComponent->SetLength(len));
checkResult(pSequence->AppendComponent(pComponent));
// For our first component, set the 'odor' value. Must be
// done after the component has been inserted in sequence.
if (i == 0)
{
// Set the odor value.
//
// 1) Get type def for uint32
IAAFTypeDefSP ptd;
checkResult (pDictionary->LookupTypeDef (kAAFTypeID_UInt32,
&ptd));
assert (ptd);
IAAFTypeDefIntSP pTDUint32;
checkResult(ptd->QueryInterface (IID_IAAFTypeDefInt,
(void **)&pTDUint32));
assert (pTDUint32);
// 2) Create a property value for the odor property, and
// set it to 42.
IAAFPropertyValueSP pVal;
const aafUInt32 odorValue = 42;
checkResult (pTDUint32->CreateValue ((aafMemPtr_t) &odorValue,
sizeof (odorValue),
&pVal));
// 3) Look up the property def for the odor property in
// the new fill class.
IAAFClassDefSP pNewFillClass;
checkResult (pDictionary->LookupClassDef (kClassAUID_NewFill,
&pNewFillClass));
IAAFPropertyDefSP pPropDef;
checkResult (pNewFillClass->LookupPropertyDef (kPropAUID_NewFill_Odor,
&pPropDef));
// 4) Get IAAFObject interface for new fill object, and
// set the odor property.
IAAFObjectSP pObj;
checkResult(pComponent->QueryInterface (IID_IAAFObject,
(void **)&pObj));
checkResult (pObj->SetPropertyValue (pPropDef, pVal));
}
}
checkResult(pSequence->QueryInterface (IID_IAAFSegment, (void **)&pSegment));
aafRational_t editRate = { 0, 1};
checkResult(pMob->AppendNewTimelineSlot(editRate,
pSegment,
1,
L"AAF Test Sequence",
0,
&pMobSlot));
// Add the master mob to the file and cleanup
pHeader->AddMob(pMob);
checkResult (RegisterDefs (pDictionary));
testKLVDataDefinitions(pDictionary, pMob);
testTaggedDefinitions(pDictionary, pMob);
}
catch (HRESULT& rResult)
{
hr = rResult;
}
// Cleanup and return
if (pFile)
{
pFile->Save();
pFile->Close();
}
return hr;
}
static HRESULT TestTypeDef (
testMode_t mode,
aafUID_constref fileKind,
testRawStorageType_t rawStorageType,
aafProductIdentification_constref productID)
{
HRESULT hr = E_FAIL;
GenerateTestFileName( productID.productName, fileKind, fileNameBufLen, testFileName );
IAAFFileSP pFile;
if(mode == kAAFUnitTestReadWrite)
{
RemoveTestFile (testFileName);
hr = CreateTestFile( testFileName, fileKind, rawStorageType, productID, &pFile );
}
else
{
hr = AAFFileOpenExistingRead(testFileName, 0, &pFile);
}
if (! SUCCEEDED (hr)) return hr;
IAAFHeaderSP pHeader;
hr = pFile->GetHeader (&pHeader);
if (! SUCCEEDED (hr)) return hr;
assert (pHeader);
IAAFDictionarySP pDict;
hr = pHeader->GetDictionary (&pDict);
if (! SUCCEEDED (hr)) return hr;
assert (pDict);
CAAFBuiltinDefs defs (pDict);
// Let's try to do something interesting with a type definition
IAAFTypeDefIntSP pTypeDefInt;
hr = defs.tdInt32()->QueryInterface (IID_IAAFTypeDefInt, (void **) &pTypeDefInt);
if (! SUCCEEDED (hr)) return hr;
assert (pTypeDefInt);
IAAFTypeDefSP pTypeDef;
hr = pTypeDefInt->QueryInterface(IID_IAAFTypeDef, (void **)&pTypeDef);
if (! SUCCEEDED (hr)) return hr;
assert (pTypeDef);
//
// Test GetTypeCategory() method
//
// first, test error conditions
hr = pTypeDef->GetTypeCategory(NULL);
if (AAFRESULT_NULL_PARAM != hr)
return AAFRESULT_TEST_FAILED;
// now, test for valid value. Our type def is integral.
eAAFTypeCategory_t typeCat = kAAFTypeCatUnknown;
hr = pTypeDef->GetTypeCategory(&typeCat);
if (! SUCCEEDED (hr)) return hr;
if (kAAFTypeCatInt != typeCat)
return AAFRESULT_TEST_FAILED;
// Test for RawAccessType(). It should be array of unsigned chars.
IAAFTypeDefSP pRawType;
hr = pTypeDef->RawAccessType (&pRawType);
if (! SUCCEEDED (hr)) return hr;
IUnknownSP pUnkRawType;
hr = pRawType->QueryInterface(IID_IUnknown, (void **)&pUnkRawType);
if (! SUCCEEDED (hr)) return hr;
IAAFTypeDefSP pUInt8ArrayType;
hr = pDict->LookupTypeDef (kAAFTypeID_UInt8Array, &pUInt8ArrayType);
if (! SUCCEEDED (hr)) return hr;
IUnknownSP pUnkUInt8Array;
hr = pUInt8ArrayType->QueryInterface(IID_IUnknown, (void **)&pUnkUInt8Array);
if (! SUCCEEDED (hr)) return hr;
if (pUnkUInt8Array != pUnkRawType)
return AAFRESULT_TEST_FAILED;
// that's all we can test for. Clean up.
if(mode == kAAFUnitTestReadWrite)
{
hr = pFile->Save();
if (! SUCCEEDED (hr)) return hr;
}
hr = pFile->Close();
if (! SUCCEEDED (hr)) return hr;
return AAFRESULT_SUCCESS;
}
// Create the test file.
void CAAFTypeDefWeakObjRef_create (
aafCharacter_constptr pFileName,
aafUID_constref fileKind,
testRawStorageType_t rawStorageType,
aafProductIdentification_constref productID)
{
// Remove the previous test file is one exists
RemoveTestFile (pFileName);
// Create the file.
IAAFFileSP pFile;
checkResult (CreateTestFile( pFileName, fileKind, rawStorageType, productID, &pFile ));
try
{
IAAFHeaderSP pHeader;
checkResult (pFile->GetHeader (&pHeader));
aafProductVersion_t toolkitVersion;
checkResult(GetAAFVersions(pHeader, &toolkitVersion, NULL));
bool weakReferencesSupported = WeakReferencesSupported(toolkitVersion);
IAAFDictionarySP pDictionary;
checkResult (pHeader->GetDictionary (&pDictionary));
CAAFBuiltinDefs defs (pDictionary);
if (weakReferencesSupported)
{
// Create a Weak reference to a type definition.
IAAFTypeDefWeakObjRefSP pWeakObjRef;
checkResult(pDictionary->CreateMetaInstance(AUID_AAFTypeDefWeakObjRef,
IID_IAAFTypeDefWeakObjRef,
(IUnknown **)&pWeakObjRef));
// Find the class definition for all type definitions.
IAAFClassDefSP pClassDef;
checkResult(pDictionary->LookupClassDef(AUID_AAFTypeDef, &pClassDef));
aafUID_t targetSet[2];
targetSet[0] = kAAFPropID_Root_MetaDictionary;
targetSet[1] = kAAFPropID_MetaDictionary_TypeDefinitions;
checkResult(pWeakObjRef->Initialize(kAAFTypeID_TestWeakReferenceToType,
pClassDef,
kMyWeakReferenceToTypeDefinitionName,
sizeof(targetSet)/sizeof(aafUID_t),
targetSet));
// Validate that we make the correct "type" by inspecting the type category.
IAAFTypeDefSP pTypeDef;
checkResult(pWeakObjRef->QueryInterface(IID_IAAFTypeDef, (void **)&pTypeDef));
eAAFTypeCategory_t category;
checkResult(pTypeDef->GetTypeCategory(&category));
checkExpression(kAAFTypeCatWeakObjRef == category, AAFRESULT_TEST_FAILED);
// Add the new type to the dictionary.
checkResult(pDictionary->RegisterTypeDef(pTypeDef));
// Now add a new optional weak reference property to an existing class.
IAAFClassDefSP pFillerClass;
IAAFPropertyDefSP pWeakRefPropertyDef;
checkResult(pDictionary->LookupClassDef(AUID_AAFComponent, &pFillerClass));
checkResult(pFillerClass->RegisterOptionalPropertyDef(
kAAFPropID_TestWeakReferenceToType,
kMyWeakReferenceToTypeDefinitionPropertyName,
pTypeDef,
&pWeakRefPropertyDef));
}
#ifndef NO_REFERENCE_TO_MOB_TEST
if (weakReferencesSupported)
{
// Create a Weak reference to a mob.
IAAFTypeDefWeakObjRefSP pWeakObjRef;
checkResult(pDictionary->CreateMetaInstance(AUID_AAFTypeDefWeakObjRef,
IID_IAAFTypeDefWeakObjRef,
(IUnknown **)&pWeakObjRef));
// Find the class definition for all mobs.
IAAFClassDefSP pClassDef;
checkResult(pDictionary->LookupClassDef(AUID_AAFMob, &pClassDef));
aafUID_t targetSet[3];
targetSet[0] = kAAFPropID_Root_Header;
targetSet[1] = kAAFPropID_Header_Content;
targetSet[2] = kAAFPropID_ContentStorage_Mobs;
checkResult(pWeakObjRef->Initialize(kAAFTypeID_TestWeakReferenceToMob,
pClassDef,
kMyWeakReferenceToMobName,
sizeof(targetSet)/sizeof(aafUID_t),
targetSet));
// Validate that we make the correct "type" by inspecting the type category.
IAAFTypeDefSP pTypeDef;
checkResult(pWeakObjRef->QueryInterface(IID_IAAFTypeDef, (void **)&pTypeDef));
eAAFTypeCategory_t category;
checkResult(pTypeDef->GetTypeCategory(&category));
checkExpression(kAAFTypeCatWeakObjRef == category, AAFRESULT_TEST_FAILED);
// Add the new type to the dictionary.
checkResult(pDictionary->RegisterTypeDef(pTypeDef));
// Now add a new optional weak reference property to an existing class.
IAAFClassDefSP pFillerClass;
IAAFPropertyDefSP pWeakRefPropertyDef;
checkResult(pDictionary->LookupClassDef(AUID_AAFComponent, &pFillerClass));
checkResult(pFillerClass->RegisterOptionalPropertyDef(
kAAFPropID_TestWeakReferenceToMob,
kMyWeakReferenceToMobPropertyName,
pTypeDef,
&pWeakRefPropertyDef));
}
#endif
//
// Create a Composition Mob
//
IAAFMobSP pMob;
checkResult(defs.cdCompositionMob()->CreateInstance(IID_IAAFMob, (IUnknown **)&pMob));
checkResult(pMob->SetMobID(TEST_MobID));
checkResult(pMob->SetName(L"TestCompMob"));
//
// Create a sequence to hold our test fillers components.
//
IAAFSequenceSP pSequence;
checkResult (defs.cdSequence()->CreateInstance(IID_IAAFSequence, (IUnknown **)&pSequence));
checkResult (pSequence->Initialize (defs.ddkAAFPicture()));
IAAFFillerSP pFiller1;
checkResult (defs.cdFiller()->CreateInstance(IID_IAAFFiller, (IUnknown **)&pFiller1));
checkResult (pFiller1->Initialize (defs.ddkAAFPicture(), 16));
IAAFFillerSP pFiller2;
checkResult (defs.cdFiller()->CreateInstance(IID_IAAFFiller, (IUnknown **)&pFiller2));
checkResult (pFiller2->Initialize (defs.ddkAAFPicture(), 32));
if (weakReferencesSupported)
{
// Try adding a weak reference before filler is attached to the file.
CreateWeakReference(pFiller1, defs.tdInt64());
CheckWeakReference(pFiller1, defs.tdInt64());
ChangeWeakReference(pFiller1, defs.tdString());
CreateWeakReference(pFiller2, defs.tdInt32());
}
//
// Add the initialized fillers to the sequence.
//
IAAFComponentSP pComp1;
checkResult(pFiller1->QueryInterface(IID_IAAFComponent, (void **)&pComp1));
checkResult(pSequence->AppendComponent(pComp1));
IAAFComponentSP pComp2;
checkResult(pFiller2->QueryInterface(IID_IAAFComponent, (void **)&pComp2));
checkResult(pSequence->AppendComponent(pComp2));
//
// Append the sequence as the segment in a new timeline mob slot.
//
IAAFSegmentSP pSegment;
checkResult(pSequence->QueryInterface(IID_IAAFSegment, (void **)&pSegment));
aafRational_t editRate = {30000, 1001};
aafCharacter_constptr pSlotName = L"Slot 1";
aafPosition_t origin = 0;
IAAFTimelineMobSlotSP pNewSlot;
checkResult(pMob->AppendNewTimelineSlot(editRate, pSegment, TEST_SlotID, pSlotName, origin, &pNewSlot));
//
// Add to the set of mobs in the file.
//
checkResult(pHeader->AddMob(pMob));
#ifndef NO_REFERENCE_TO_MOB_TEST
if (weakReferencesSupported)
{
// The referenced object needs to be attached to the file.
CreateWeakReference(pFiller1, pMob);
CheckWeakReference(pFiller1, pMob);
}
#endif
// if (weakReferencesSupported)
// {
// // Try adding a weak reference after filler is attached to the file.
// CreateWeakReference(pFiller2, defs.tdInt32());
// }
// Verify the data before the save.
CAAFTypeDefWeakObjRef_verify (pHeader);
checkResult(pFile->Save());
checkResult(pFile->Close());
}
catch (HRESULT& rhr)
{
if (pFile) // only save & close the file if it was actually opened
{
pFile->Save(); // This may not be safe???
pFile->Close();
}
throw rhr;
}
catch (...)
{
if (pFile) // only close the file if it was actually opened
pFile->Close();
throw;
}
}