/*
* Copyright (c) 2002 Nokia Corporation and/or its subsidiary(-ies).
* All rights reserved.
* This component and the accompanying materials are made available
* under the terms of "Eclipse Public License v1.0"
* which accompanies this distribution, and is available
* at the URL "http://www.eclipse.org/legal/epl-v10.html".
*
* Initial Contributors:
* Nokia Corporation - initial contribution.
*
* Contributors:
*
* Description: ICMSTIF class member functions
*
*/
// INCLUDE FILES
#include <e32cmn.h>
#include <StifTestInterface.h>
#include "ICMSTIF.h"
#include <e32debug.h>
// EXTERNAL DATA STRUCTURES
//extern ?external_data;
// EXTERNAL FUNCTION PROTOTYPES
//extern ?external_function( ?arg_type,?arg_type );
// CONSTANTS
//const ?type ?constant_var = ?constant;
// MACROS
//#define ?macro ?macro_def
// LOCAL CONSTANTS AND MACROS
//const ?type ?constant_var = ?constant;
//#define ?macro_name ?macro_def
// MODULE DATA STRUCTURES
//enum ?declaration
//typedef ?declaration
// LOCAL FUNCTION PROTOTYPES
//?type ?function_name( ?arg_type, ?arg_type );
// FORWARD DECLARATIONS
//class ?FORWARD_CLASSNAME;
// ============================= LOCAL FUNCTIONS ===============================
// -----------------------------------------------------------------------------
// ?function_name ?description.
// ?description
// Returns: ?value_1: ?description
// ?value_n: ?description_line1
// ?description_line2
// -----------------------------------------------------------------------------
//
/*
?type ?function_name(
?arg_type arg, // ?description
?arg_type arg) // ?description
{
?code // ?comment
// ?comment
?code
}
*/
// ============================ MEMBER FUNCTIONS ===============================
// -----------------------------------------------------------------------------
// CICMSTIF::CICMSTIF
// C++ default constructor can NOT contain any code, that
// might leave.
// -----------------------------------------------------------------------------
//
CICMSTIF::CICMSTIF()
{
}
// -----------------------------------------------------------------------------
// CICMSTIF::ConstructL
// Symbian 2nd phase constructor can leave.
// Note: If OOM test case uses STIF Logger, then STIF Logger must be created
// with static buffer size parameter (aStaticBufferSize). Otherwise Logger
// allocates memory from heap and therefore causes error situations with OOM
// testing. For more information about STIF Logger construction, see STIF Users
// Guide.
// -----------------------------------------------------------------------------
//
void CICMSTIF::ConstructL()
{
iLog = CStifLogger::NewL( KICMSTIFLogPath,
KICMSTIFLogFile);
/* // SetAllocFailureSimulation( RHeap::EDeterministic, 0 ); // Enable OOM test loop
SetAllocFailureSimulation( RHeap::ENone, 0 ); // Disable OOM test loop
iMemTestEnabled = ETrue;*/
}
// -----------------------------------------------------------------------------
// CICMSTIF::NewL
// Two-phased constructor.
// -----------------------------------------------------------------------------
//
CICMSTIF* CICMSTIF::NewL()
{
CICMSTIF* self = new (ELeave) CICMSTIF;
CleanupStack::PushL( self );
self->ConstructL();
CleanupStack::Pop();
return self;
}
// Destructor
CICMSTIF::~CICMSTIF()
{
delete iLog;
}
// -----------------------------------------------------------------------------
// CICMSTIF::InitL
// InitL is used to initialize the Test Module.
// -----------------------------------------------------------------------------
//
TInt CICMSTIF::InitL(
TFileName& /*aIniFile*/,
TBool /*aFirstTime*/ )
{
return KErrNone;
}
// -----------------------------------------------------------------------------
// CICMSTIF::Case
// Returns a test case by number.
//
// This function contains an array of all available test cases
// i.e pair of case name and test function. If case specified by parameter
// aCaseNumber is found from array, then that item is returned.
//
// The reason for this rather complicated function is to specify all the
// test cases only in one place. It is not necessary to understand how
// function pointers to class member functions works when adding new test
// cases. See function body for instructions how to add new test case.
// -----------------------------------------------------------------------------
//
const TCaseInfo CICMSTIF::Case (
const TInt aCaseNumber ) const
{
/**
* To add new test cases, implement new test case function and add new
* line to KCases array specify the name of the case and the function
* doing the test case
* In practice, do following
* 1) Make copy of existing test case function and change its name
* and functionality. Note that the function must be added to
* ICMSTIF.cpp file and to ICMSTIF.h
* header file.
* 2) Add entry to following KCases array either by using FUNCENTRY or
* ENTRY macro.
* ENTRY macro takes two parameters: test case name and test case
* function name.
* FUNCENTRY macro takes only test case function name as a parameter and uses
* that as a test case name and test case function name.
*/
static TCaseInfoInternal const KCases[] =
{
// To add new test cases, add new items to this array
ENTRY( "TestCase001", CICMSTIF::TestCase_001L ),
ENTRY( "TestCase002", CICMSTIF::TestCase_002L ),
ENTRY( "TestCase003", CICMSTIF::TestCase_003L ),
ENTRY( "TestCase004", CICMSTIF::TestCase_004L ),
ENTRY( "TestCase005", CICMSTIF::TestCase_005L ),
ENTRY( "TestCase006", CICMSTIF::TestCase_006L ),
ENTRY( "TestCase007", CICMSTIF::TestCase_007L ),
ENTRY( "TestCase008", CICMSTIF::TestCase_008L ),
ENTRY( "TestCase009", CICMSTIF::TestCase_009L ),
ENTRY( "TestCase010", CICMSTIF::TestCase_010L ),
ENTRY( "TestOOM", CICMSTIF::TestCase_OOML )
};
// Verify that case number is valid
if( (TUint) aCaseNumber >= sizeof( KCases ) /
sizeof( TCaseInfoInternal ) )
{
// Invalid case, construct empty object
TCaseInfo null( (const TText*) L"" );
null.iMethod = NULL;
return null;
}
// Construct TCaseInfo object and return it
TCaseInfo tmp ( KCases[ aCaseNumber ].iCaseName );
tmp.iMethod = KCases[ aCaseNumber ].iMethod;
return tmp;
}
// -----------------------------------------------------------------------------
// CICMSTIF::TestCase_001L
//
// <INSERT DESCRIPTION HERE>
//
// Pre-Condition: <INSERT PRE-CONDITIONS HERE>
// -----------------------------------------------------------------------------
//
TInt CICMSTIF::TestCase_001L( TTestResult& aResult )
{
CImagingConfigManager* icm = CImagingConfigManager::NewL();
delete icm;
CImagingConfigManager* icm2 = CImagingConfigManager::NewLC();
CleanupStack::Pop( icm2 );
aResult.iResult = KErrNone;
aResult.iResultDes = _L("CImagingConfigManager creations with NewL and NewLC succeeded both.");
return KErrNone;
}
// -----------------------------------------------------------------------------
// CICMSTIF::TestCase_002L
//
// <INSERT DESCRIPTION HERE>
//
// Pre-Condition: <INSERT PRE-CONDITIONS HERE>
// -----------------------------------------------------------------------------
//
TInt CICMSTIF::TestCase_002L( TTestResult& aResult )
{
CImagingConfigManager* icm = CImagingConfigManager::NewL();
if(icm->NumberOfVideoQualityLevels() < 1 || icm->NumberOfVideoQualityLevels() > 100)
{
aResult.iResult = KErrGeneral;
aResult.iResultDes = _L("NumberOfVideoQualityLevels() didn't return value between 1-100.");
}
else
{
aResult.iResult = KErrNone;
aResult.iResultDes = _L("NumberOfVideoQualityLevels() OK.");
}
delete icm;
return KErrNone;
}
// -----------------------------------------------------------------------------
// CICMSTIF::TestCase_003L
//
// <INSERT DESCRIPTION HERE>
//
// Pre-Condition: <INSERT PRE-CONDITIONS HERE>
// -----------------------------------------------------------------------------
//
TInt CICMSTIF::TestCase_003L( TTestResult& aResult )
{
_LIT8(KFileMime, "video/3gpp");
_LIT8(KVideoCodecMimeType, "video/H263-2000");
_LIT8(KPreferredSupplier, "Nokia");
const TUint32 KAudioFourCCType = 0x524D4120;
CImagingConfigManager* icm = CImagingConfigManager::NewL();
CleanupStack::PushL( icm );
CArrayFixFlat<TUint>* levels = new( ELeave ) CArrayFixFlat< TUint >( 1 );
TVideoQualitySet videoset;
icm->GetVideoQualityLevelsL(*levels);
if(levels->Count() != 10 || levels->At(0) != 98
|| levels->At(1) != 99 || levels->At(2) != 200
|| levels->At(3) != 201 || levels->At(4) != 202 || levels->At(5) != 203
|| levels->At(6) != 301 || levels->At(7) != 302 || levels->At(8) != 303
|| levels->At(9) != 304 )
{
aResult.iResult = KErrGeneral;
aResult.iResultDes = _L("GetVideoQualityLevelsL()->At didn't return the expected values.");
}
else
{
icm->GetVideoQualitySet( videoset, /*100*/levels->At(1) );
TInt length1 = KMaxStringLength;
TInt length2 = KMaxStringLength;
TInt length3 = KMaxStringLength;
for( TInt i=0; i<KMaxStringLength; i++)
{
if(videoset.iVideoFileMimeType[i] == '\0')
{
length1 = i;
break;
}
}
for( TInt i=0; i<KMaxStringLength; i++)
{
if(videoset.iVideoCodecMimeType[i] == '\0')
{
length2 = i;
break;
}
}
for( TInt i=0; i<KMaxStringLength; i++)
{
if(videoset.iPreferredSupplier[i] == '\0')
{
length3 = i;
break;
}
}
if( videoset.iVideoQualitySetLevel != 99 ||
memcompare(videoset.iVideoFileMimeType, length1, KFileMime().Ptr(), KFileMime().Length()) ||
memcompare(videoset.iVideoCodecMimeType, length2, KVideoCodecMimeType().Ptr(), KVideoCodecMimeType().Length()) ||
videoset.iVideoWidth != 176 ||
videoset.iVideoHeight != 144 ||
videoset.iVideoFrameRate != 15.0 ||
videoset.iVideoBitRate != 60000 ||
videoset.iVideoEncoderUID.iUid != 0 ||
videoset.iRandomAccessRate != 0.2 ||
videoset.iVideoPixelAspectRatioNum != 12 ||
videoset.iVideoPixelAspectRatioDenom != 11 ||
memcompare(videoset.iPreferredSupplier, length3, KPreferredSupplier().Ptr(), KPreferredSupplier().Length()) ||
videoset.iAudioFourCCType.FourCC() != KAudioFourCCType ||
videoset.iAudioBitRate != 12200 ||
videoset.iAudioSamplingRate != 8000 ||
videoset.iAudioChannels != 1 ||
videoset.iAudioEncoderUID.iUid != 0 ||
videoset.iAVSyncStartDelay != -200 ||
videoset.iAVSyncResumeDelay != 0 ||
videoset.iCameraDisplayId != 2 ||
videoset.iCamcorderVisible != 100)
{
aResult.iResult = KErrGeneral;
aResult.iResultDes = _L("GetVideoQualitySetL() didn't return expected values.");
}
else
{
aResult.iResult = KErrNone;
aResult.iResultDes = _L("GetVideoQualitySetL() OK.");
}
}
CleanupStack::Pop( icm );
delete levels;
delete icm;
return KErrNone;
}
// -----------------------------------------------------------------------------
// CICMSTIF::TestCase_004L
//
// <INSERT DESCRIPTION HERE>
//
// Pre-Condition: <INSERT PRE-CONDITIONS HERE>
// -----------------------------------------------------------------------------
//
TInt CICMSTIF::TestCase_004L( TTestResult& aResult )
{
_LIT8(KFileMime, "video/3gpp");
_LIT8(KVideoCodecMimeType, "video/H263-2000");
_LIT8(KPreferredSupplier, "Nokia");
const TUint32 KAudioFourCCType = 0x524D4120;
CImagingConfigManager* icm = CImagingConfigManager::NewL();
TVideoQualitySet videoset;
TSize resolution(176,144);
icm->GetVideoQualitySet(videoset, resolution, KVideoCodecMimeType(), 0, 0, TFourCC(KAudioFourCCType));
if(videoset.iVideoHeight != resolution.iHeight ||
videoset.iVideoWidth != resolution.iWidth ||
videoset.iVideoQualitySetLevel != 99)
{
aResult.iResult = KErrGeneral;
aResult.iResultDes = _L("GetVideoQualitySetL() didn't return expected value.");
}
else
{
TInt length1 = KMaxStringLength;
TInt length2 = KMaxStringLength;
TInt length3 = KMaxStringLength;
for( TInt i=0; i<KMaxStringLength; i++)
{
if(videoset.iVideoFileMimeType[i] == '\0')
{
length1 = i;
break;
}
}
for( TInt i=0; i<KMaxStringLength; i++)
{
if(videoset.iVideoCodecMimeType[i] == '\0')
{
length2 = i;
break;
}
}
for( TInt i=0; i<KMaxStringLength; i++)
{
if(videoset.iPreferredSupplier[i] == '\0')
{
length3 = i;
break;
}
}
if( memcompare(videoset.iVideoFileMimeType, length1, KFileMime().Ptr(), KFileMime().Length()) ||
memcompare(videoset.iVideoCodecMimeType, length2, KVideoCodecMimeType().Ptr(), KVideoCodecMimeType().Length()) ||
videoset.iVideoWidth != 176 ||
videoset.iVideoHeight != 144 ||
videoset.iVideoFrameRate != 15.0 ||
videoset.iVideoBitRate != 60000 ||
videoset.iVideoEncoderUID.iUid != 0 ||
videoset.iRandomAccessRate != 0.2 ||
videoset.iVideoPixelAspectRatioNum != 12 ||
videoset.iVideoPixelAspectRatioDenom != 11 ||
memcompare(videoset.iPreferredSupplier, length3, KPreferredSupplier().Ptr(), KPreferredSupplier().Length()) ||
videoset.iAudioFourCCType.FourCC() != KAudioFourCCType ||
videoset.iAudioBitRate != 12200 ||
videoset.iAudioSamplingRate != 8000 ||
videoset.iAudioChannels != 1 ||
videoset.iAudioEncoderUID.iUid != 0 ||
videoset.iAVSyncStartDelay != -200 ||
videoset.iAVSyncResumeDelay != 0 ||
videoset.iCameraDisplayId != 2 ||
videoset.iCamcorderVisible != 100)
{
aResult.iResult = KErrGeneral;
aResult.iResultDes = _L("GetVideoQualitySetL() didn't return expected values.");
}
else
{
aResult.iResult = KErrNone;
aResult.iResultDes = _L("GetVideoQualitySetL() OK.");
}
}
delete icm;
return KErrNone;
}
// -----------------------------------------------------------------------------
// CICMSTIF::TestCase_005L
//
// <INSERT DESCRIPTION HERE>
//
// Pre-Condition: <INSERT PRE-CONDITIONS HERE>
// -----------------------------------------------------------------------------
//
TInt CICMSTIF::TestCase_005L( TTestResult& aResult )
{
CImagingConfigManager* icm = CImagingConfigManager::NewL();
TCamcorderMMFPluginSettings ccorSettings;
icm->GetCamcorderMMFPluginSettings(ccorSettings);
if(ccorSettings.iVideoNightFrameRate != 5.00 ||
ccorSettings.iCMRAvgVideoBitRateScaler != 0.9 ||
ccorSettings.iVideoComplexitySetting != 1 ||
ccorSettings.iCMRLatencyQualityTradeoff != 1.0 ||
ccorSettings.iCMRPictureQuality != 50 ||
ccorSettings.iCMRQualityTemporalTradeoff != 0.8 ||
ccorSettings.iCMRNumCameraBuffers != 2 ||
ccorSettings.iCMRNumCameraBuffersARM != 1 ||
ccorSettings.iCMRMinNumOutputBuffers != 4)
{
aResult.iResult = KErrGeneral;
aResult.iResultDes = _L("GetCamcorderMMFPluginSettingsL() didn't return expected value.");
}
else
{
aResult.iResult = KErrNone;
aResult.iResultDes = _L("GetCamcorderMMFPluginSettingsL() OK.");
}
delete icm;
return KErrNone;
}
// -----------------------------------------------------------------------------
// CICMSTIF::TestCase_006L
//
// <INSERT DESCRIPTION HERE>
//
// Pre-Condition: <INSERT PRE-CONDITIONS HERE>
// -----------------------------------------------------------------------------
//
TInt CICMSTIF::TestCase_006L( TTestResult& aResult )
{
CImagingConfigManager* icm = CImagingConfigManager::NewL();
if(icm->NumberOfImageQualityLevels() != 27)
{
aResult.iResult = KErrGeneral;
aResult.iResultDes = _L("NumberOfImageQualityLevels() didn't return 27 as expected.");
}
else
{
aResult.iResult = KErrNone;
aResult.iResultDes = _L("NumberOfImageQualityLevels() OK.");
}
delete icm;
return KErrNone;
}
// -----------------------------------------------------------------------------
// CICMSTIF::TestCase_007L
//
// <INSERT DESCRIPTION HERE>
//
// Pre-Condition: <INSERT PRE-CONDITIONS HERE>
// -----------------------------------------------------------------------------
//
TInt CICMSTIF::TestCase_007L( TTestResult& aResult )
{
_LIT8(KImageFileMimeType, "image/jpeg");
_LIT8(KImageFileExtension, ".jpg");
CImagingConfigManager* icm = CImagingConfigManager::NewL();
CleanupStack::PushL( icm );
CArrayFixFlat<TUint>* levels = new( ELeave ) CArrayFixFlat< TUint >( 1 );
TImageQualitySet imageset;
icm->GetImageQualityLevelsL(*levels, 2);
if(levels->Count() != 24 || levels->At(0) != 99 || levels->At(1) != 100 || levels->At(2) != 101
|| levels->At(3) != 102 || levels->At(4) != 103 || levels->At(5) != 104
|| levels->At(6) != 105 || levels->At(7) != 106 || levels->At(8) != 199
|| levels->At(9) != 200 || levels->At(10) != 201 || levels->At(11) != 202
|| levels->At(12) != 203 || levels->At(13) != 204 || levels->At(14) != 205
|| levels->At(15) != 206 || levels->At(16) != 299 || levels->At(17) != 300
|| levels->At(18) != 301 || levels->At(19) != 302 || levels->At(20) != 303
|| levels->At(21) != 304 || levels->At(22) != 305 || levels->At(23) != 306)
{
aResult.iResult = KErrGeneral;
aResult.iResultDes = _L("GetImageQualityLevelsL()->At didn't return expected value.");
}
else
{
icm->GetImageQualitySet( imageset, levels->At(1) );
TInt length1 = KMaxStringLength;
TInt length2 = KMaxStringLength;
for( TInt i=0; i<KMaxStringLength; i++)
{
if(imageset.iImageFileMimeType[i] == '\0')
{
length1 = i;
break;
}
}
for( TInt i=0; i<KMaxStringLength; i++)
{
if(imageset.iImageFileExtension[i] == '\0')
{
length2 = i;
break;
}
}
if( memcompare(imageset.iImageFileMimeType, length1, KImageFileMimeType().Ptr(), KImageFileMimeType().Length()) ||
memcompare(imageset.iImageFileExtension, length2, KImageFileExtension().Ptr(), KImageFileExtension().Length()) ||
imageset.iImageWidth < 160 ||
imageset.iImageWidth > 13333 ||
imageset.iImageHeight < 120 ||
imageset.iImageHeight > 10000 ||
imageset.iCompressionQuality < 10 ||
imageset.iCompressionQuality > 100 ||
imageset.iEstimatedSize < 1024 ||
imageset.iEstimatedSize > 10240000 ||
imageset.iCameraDisplayId > 10000 ||
imageset.iCamcorderVisible > 10000)
{
aResult.iResult = KErrGeneral;
aResult.iResultDes = _L("GetImageQualityLevelsL() didn't return expected values.");
}
else
{
aResult.iResult = KErrNone;
aResult.iResultDes = _L("GetImageQualityLevelsL() OK.");
}
}
CleanupStack::Pop( icm );
delete levels;
delete icm;
return KErrNone;
}
// -----------------------------------------------------------------------------
// CICMSTIF::TestCase_008L
//
// <INSERT DESCRIPTION HERE>
//
// Pre-Condition: <INSERT PRE-CONDITIONS HERE>
// -----------------------------------------------------------------------------
//
TInt CICMSTIF::TestCase_008L( TTestResult& aResult )
{
_LIT8(KImageFileMimeType, "image/jpeg");
_LIT8(KImageFileExtension, ".jpg");
CImagingConfigManager* icm = CImagingConfigManager::NewL();
TImageQualitySet imageset;
TSize resolution(1280,960);
icm->GetImageQualitySet(imageset, resolution, 2);
if(imageset.iImageHeight != resolution.iHeight ||
imageset.iImageWidth != resolution.iWidth ||
imageset.iImageQualitySetLevel > 10000)
{
aResult.iResult = KErrGeneral;
aResult.iResultDes = _L("GetImageQualitySetL() resolution didn't return expected value.");
}
else
{
TInt length1 = KMaxStringLength;
TInt length2 = KMaxStringLength;
for( TInt i=0; i<KMaxStringLength; i++)
{
if(imageset.iImageFileMimeType[i] == '\0')
{
length1 = i;
break;
}
}
for( TInt i=0; i<KMaxStringLength; i++)
{
if(imageset.iImageFileExtension[i] == '\0')
{
length2 = i;
break;
}
}
if( memcompare(imageset.iImageFileMimeType, length1, KImageFileMimeType().Ptr(), KImageFileMimeType().Length()) ||
memcompare(imageset.iImageFileExtension, length2, KImageFileExtension().Ptr(), KImageFileExtension().Length()) ||
imageset.iCompressionQuality < 10 ||
imageset.iCompressionQuality > 100 ||
imageset.iEstimatedSize < 1024 ||
imageset.iEstimatedSize > 10240000 ||
imageset.iCameraDisplayId > 10000 ||
imageset.iCamcorderVisible > 10000)
{
aResult.iResult = KErrGeneral;
aResult.iResultDes = _L("GetImageQualitySetL() didn't return expected values.");
}
else
{
aResult.iResult = KErrNone;
aResult.iResultDes = _L("GetImageQualitySetL() OK.");
}
}
delete icm;
return KErrNone;
}
// -----------------------------------------------------------------------------
// CICMSTIF::TestCase_009L
//
// <INSERT DESCRIPTION HERE>
//
// Pre-Condition: <INSERT PRE-CONDITIONS HERE>
// -----------------------------------------------------------------------------
//
TInt CICMSTIF::TestCase_009L( TTestResult& aResult )
{
_LIT8(KFileMime, "video/3gpp");
_LIT8(KVideoCodecMimeType, "video/H263-2000");
_LIT8(KPreferredSupplier, "Nokia");
const TUint32 KAudioFourCCType = 0x524D4120;
CImagingConfigManager* icm = CImagingConfigManager::NewL();
TVideoQualitySet videoset;
TSize resolution(176,144);
icm->GetVideoQualitySet( videoset, 125 );// This should return video set num 99
if(videoset.iVideoHeight != resolution.iHeight ||
videoset.iVideoWidth != resolution.iWidth ||
videoset.iVideoQualitySetLevel != 99)
{
aResult.iResult = KErrGeneral;
aResult.iResultDes = _L("GetVideoQualitySetL() didn't return expected value.");
}
else
{
TInt length1 = KMaxStringLength;
TInt length2 = KMaxStringLength;
TInt length3 = KMaxStringLength;
for( TInt i=0; i<KMaxStringLength; i++)
{
if(videoset.iVideoFileMimeType[i] == '\0')
{
length1 = i;
break;
}
}
for( TInt i=0; i<KMaxStringLength; i++)
{
if(videoset.iVideoCodecMimeType[i] == '\0')
{
length2 = i;
break;
}
}
for( TInt i=0; i<KMaxStringLength; i++)
{
if(videoset.iPreferredSupplier[i] == '\0')
{
length3 = i;
break;
}
}
if( memcompare(videoset.iVideoFileMimeType, length1, KFileMime().Ptr(), KFileMime().Length()) ||
memcompare(videoset.iVideoCodecMimeType, length2, KVideoCodecMimeType().Ptr(), KVideoCodecMimeType().Length()) ||
videoset.iVideoWidth != 176 ||
videoset.iVideoHeight != 144 ||
videoset.iVideoFrameRate != 15.0 ||
videoset.iVideoBitRate != 60000 ||
videoset.iVideoEncoderUID.iUid != 0 ||
videoset.iRandomAccessRate != 0.2 ||
videoset.iVideoPixelAspectRatioNum != 12 ||
videoset.iVideoPixelAspectRatioDenom != 11 ||
memcompare(videoset.iPreferredSupplier, length3, KPreferredSupplier().Ptr(), KPreferredSupplier().Length()) ||
videoset.iAudioFourCCType.FourCC() != KAudioFourCCType ||
videoset.iAudioBitRate != 12200 ||
videoset.iAudioSamplingRate != 8000 ||
videoset.iAudioChannels != 1 ||
videoset.iAudioEncoderUID.iUid != 0 ||
videoset.iAVSyncStartDelay != -200 ||
videoset.iAVSyncResumeDelay != 0 ||
videoset.iCameraDisplayId != 2 ||
videoset.iCamcorderVisible != 100)
{
aResult.iResult = KErrGeneral;
aResult.iResultDes = _L("GetVideoQualitySetL() didn't return expected values.");
}
else
{
aResult.iResult = KErrNone;
aResult.iResultDes = _L("GetVideoQualitySetL() OK.");
}
}
delete icm;
return KErrNone;
}
// -----------------------------------------------------------------------------
// CICMSTIF::TestCase_010L
//
// <INSERT DESCRIPTION HERE>
//
// Pre-Condition: <INSERT PRE-CONDITIONS HERE>
// -----------------------------------------------------------------------------
//
TInt CICMSTIF::TestCase_010L( TTestResult& aResult )
{
_LIT8(KImageFileMimeType, "image/jpeg");
_LIT8(KImageFileExtension, ".jpg");
CImagingConfigManager* icm = CImagingConfigManager::NewL();
TImageQualitySet imageset;
icm->GetImageQualitySet( imageset, 305, 2 );
TInt length1 = KMaxStringLength;
TInt length2 = KMaxStringLength;
for( TInt i=0; i<KMaxStringLength; i++)
{
if(imageset.iImageFileMimeType[i] == '\0')
{
length1 = i;
break;
}
}
for( TInt i=0; i<KMaxStringLength; i++)
{
if(imageset.iImageFileExtension[i] == '\0')
{
length2 = i;
break;
}
}
if( memcompare(imageset.iImageFileMimeType, length1, KImageFileMimeType().Ptr(), KImageFileMimeType().Length()) ||
memcompare(imageset.iImageFileExtension, length2, KImageFileExtension().Ptr(), KImageFileExtension().Length()) ||
imageset.iImageWidth < 160 ||
imageset.iImageWidth > 13000 ||
imageset.iImageHeight < 120 ||
imageset.iImageHeight > 10000 ||
imageset.iCompressionQuality < 10 ||
imageset.iCompressionQuality > 100 ||
imageset.iEstimatedSize < 1024 ||
imageset.iEstimatedSize > 10240000 ||
imageset.iCameraDisplayId > 10000 ||
imageset.iCamcorderVisible > 10000)
{
aResult.iResult = KErrGeneral;
aResult.iResultDes = _L("GetImageQualityLevelsL() didn't return expected values.");
}
else
{
aResult.iResult = KErrNone;
aResult.iResultDes = _L("GetImageQualityLevelsL() OK.");
}
delete icm;
return KErrNone;
}
// -----------------------------------------------------------------------------
// CICMSTIF::TestCase_OOML
//
// <INSERT DESCRIPTION HERE>
//
// Pre-Condition: <INSERT PRE-CONDITIONS HERE>
// -----------------------------------------------------------------------------
//
TInt CICMSTIF::TestCase_OOML( TTestResult& aResult )
{
TInt error = KErrNone;
_LIT(KTestCase, "TestCase0??");
for( TInt i = 0; Case(i).iMethod != NULL && !error; i++ )
{
// Get the pointer to test case function
TCaseInfo tmp = Case(i);
if(KErrNotFound == tmp.iCaseName.Match(KTestCase()))
{
break;
}
SetAllocFailureSimulation( RHeap::EDeterministic, 1 ); // Enable OOM test loop
aResult.SetResult( KErrNoMemory, _L("") ); // Initial value
for (; ( aResult.iResult == KErrNoMemory ) && !error;)
{
// Switches on alloc failure simulation if the parameters are set for it
AllocFailureSimulation( ETrue );
RDebug::Print(_L("*** OOM loop : %d ***\n"), iCurrentAllocFailureRate );
iMethod = tmp.iMethod;
TRAP( error, ( this->*iMethod )( aResult ) );
if ( error == KErrNoMemory )
{
error = KErrNone;
}
}
AllocFailureSimulation( EFalse );
}
SetAllocFailureSimulation( RHeap::ENone, 1 ); // Disable OOM test loop
User::LeaveIfError( error );
return KErrNone;
}
/*
*/
void CICMSTIF::AllocFailureSimulation (TBool aSwitchedOn)
{
if (aSwitchedOn)
{
__UHEAP_SETFAIL ( iAllocFailureType, iCurrentAllocFailureRate );
iCurrentAllocFailureRate++;
}
else
{
__UHEAP_RESET;
iCurrentAllocFailureRate = iAllocFailureRate;
}
}
/*
*/
void CICMSTIF::SetAllocFailureSimulation( RHeap::TAllocFail aAllocFailureType, TInt aAllocFailureRate )
{
iAllocFailureType = aAllocFailureType;
iAllocFailureRate = aAllocFailureRate;
iCurrentAllocFailureRate = aAllocFailureRate;
}
// -----------------------------------------------------------------------------
// CICMSTIF::GetTestCasesL
// GetTestCases is used to inquire test cases from the Test Module. Test
// cases are stored to array of test cases. The Test Framework will be
// the owner of the data in the RPointerArray after GetTestCases return
// and it does the memory deallocation.
// -----------------------------------------------------------------------------
//
TInt CICMSTIF::GetTestCasesL(
const TFileName& /*aConfig*/,
RPointerArray<TTestCaseInfo>& aTestCases )
{
// Loop through all test cases and create new
// TTestCaseInfo items and append items to aTestCase array
for( TInt i = 0; Case(i).iMethod != NULL; i++ )
{
// Allocate new TTestCaseInfo from heap for a testcase definition.
TTestCaseInfo* newCase = new( ELeave ) TTestCaseInfo();
// PushL TTestCaseInfo to CleanupStack.
CleanupStack::PushL( newCase );
// Set number for the testcase.
// When the testcase is run, this comes as a parameter to RunTestCaseL.
newCase->iCaseNumber = i;
// Set title for the test case. This is shown in UI to user.
newCase->iTitle.Copy( Case(i).iCaseName );
// Append TTestCaseInfo to the testcase array. After appended
// successfully the TTestCaseInfo object is owned (and freed)
// by the TestServer.
User::LeaveIfError(aTestCases.Append ( newCase ) );
// Pop TTestCaseInfo from the CleanupStack.
CleanupStack::Pop( newCase );
}
return KErrNone;
}
// -----------------------------------------------------------------------------
// CICMSTIF::RunTestCaseL
// RunTestCaseL is used to run an individual test case specified
// by aTestCase. Test cases that can be run may be requested from
// Test Module by GetTestCases method before calling RunTestCase.
// -----------------------------------------------------------------------------
//
TInt CICMSTIF::RunTestCaseL(
const TInt aCaseNumber ,
const TFileName& /*aConfig*/,
TTestResult& aResult )
{
// Return value
TInt execStatus = KErrNone;
// Get the pointer to test case function
TCaseInfo tmp = Case ( aCaseNumber );
// Check that case number was valid
if ( tmp.iMethod != NULL )
{
// Valid case was found, call it via function pointer
iMethod = tmp.iMethod;
execStatus = ( this->*iMethod )( aResult );
}
else
{
// Valid case was not found, return error.
execStatus = KErrNotFound;
}
// Return case execution status (not the result of the case execution)
return execStatus;
}
// -----------------------------------------------------------------------------
// CICMSTIF::OOMTestQueryL
// Used to check if a particular test case should be run in OOM conditions and
// which memory allocations should fail.
//
// NOTE: This method is virtual and must be implemented only if test case
// should be executed using OOM conditions.
// -----------------------------------------------------------------------------
//
TBool CICMSTIF::OOMTestQueryL(
const TFileName& /* aTestCaseFile */,
const TInt /* aCaseNumber */,
TOOMFailureType& /* aFailureType */,
TInt& /* aFirstMemFailure */,
TInt& /* aLastMemFailure */ )
{
_LIT( KOOMTestQueryL, "CICMSTIF::OOMTestQueryL" );
iLog->Log( KOOMTestQueryL );
return EFalse;
}
// -----------------------------------------------------------------------------
// CICMSTIF::OOMTestInitializeL
// Used to perform the test environment setup for a particular OOM test case.
// Test Modules may use the initialization file to read parameters for Test
// Module initialization but they can also have their own configure file or
// some other routine to initialize themselves.
//
// NOTE: This method is virtual and must be implemented only if test case
// should be executed using OOM conditions.
// -----------------------------------------------------------------------------
//
void CICMSTIF::OOMTestInitializeL(
const TFileName& /* aTestCaseFile */,
const TInt /* aCaseNumber */ )
{
}
// -----------------------------------------------------------------------------
// CICMSTIF::OOMHandleWarningL
// In some cases the heap memory allocation should be skipped, either due to
// problems in the OS code or components used by the code being tested, or even
// inside the tested components which are implemented this way on purpose (by
// design), so it is important to give the tester a way to bypass allocation
// failures.
//
// NOTE: This method is virtual and must be implemented only if test case
// should be executed using OOM conditions.
// -----------------------------------------------------------------------------
//
void CICMSTIF::OOMHandleWarningL(
const TFileName& /* aTestCaseFile */,
const TInt /* aCaseNumber */,
TInt& /* aFailNextValue */ )
{
}
// -----------------------------------------------------------------------------
// CICMSTIF::OOMTestFinalizeL
// Used to perform the test environment cleanup for a particular OOM test case.
//
// NOTE: This method is virtual and must be implemented only if test case
// should be executed using OOM conditions.
// -----------------------------------------------------------------------------
//
void CICMSTIF::OOMTestFinalizeL(
const TFileName& /* aTestCaseFile */,
const TInt /* aCaseNumber */ )
{
}
// ========================== OTHER EXPORTED FUNCTIONS =========================
// -----------------------------------------------------------------------------
// LibEntryL is a polymorphic Dll entry point
// Returns: CTestModuleBase*: Pointer to Test Module object
// -----------------------------------------------------------------------------
//
EXPORT_C CTestModuleBase* LibEntryL()
{
return CICMSTIF::NewL();
}
// -----------------------------------------------------------------------------
// SetRequirements handles test module parameters(implements evolution
// version 1 for test module's heap and stack sizes configuring).
// Returns: TInt: Symbian error code.
// -----------------------------------------------------------------------------
//
EXPORT_C TInt SetRequirements( CTestModuleParam*& aTestModuleParam,
TUint32& aParameterValid )
{
/* --------------------------------- NOTE ---------------------------------
USER PANICS occurs in test thread creation when:
1) "The panic occurs when the value of the stack size is negative."
2) "The panic occurs if the minimum heap size specified is less
than KMinHeapSize".
KMinHeapSize: "Functions that require a new heap to be allocated will
either panic, or will reset the required heap size to this value if
a smaller heap size is specified".
3) "The panic occurs if the minimum heap size specified is greater than
the maximum size to which the heap can grow".
Other:
1) Make sure that your hardware or Symbian OS is supporting given sizes.
e.g. Hardware might support only sizes that are divisible by four.
------------------------------- NOTE end ------------------------------- */
// Normally STIF uses default heap and stack sizes for test thread, see:
// KTestThreadMinHeap, KTestThreadMinHeap and KStackSize.
// If needed heap and stack sizes can be configured here by user. Remove
// comments and define sizes.
aParameterValid = KStifTestModuleParameterChanged;
CTestModuleParamVer01* param = CTestModuleParamVer01::NewL();
// Stack size
param->iTestThreadStackSize= 2*16384; // 32K stack
// Heap sizes
param->iTestThreadMinHeap = 4096; // 4K heap min
param->iTestThreadMaxHeap = 8*1048576;// 8M heap max
aTestModuleParam = param;
return KErrNone;
}
// -----------------------------------------------------------------------------
// E32Dll is a DLL entry point function
// Returns: KErrNone: No error
// -----------------------------------------------------------------------------
//
#ifndef EKA2 // Hide Dll entry point to EKA2
GLDEF_C TInt E32Dll(
TDllReason /*aReason*/) // Reason
{
return(KErrNone);
}
#endif // EKA2
// End of File