// Copyright (c) 2008-2010 Nokia Corporation and/or its subsidiary(-ies).
// All rights reserved.
// This component and the accompanying materials are made available
// under the terms of the License "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:
// f32test\server\t_fatcharsetconv_aux.cpp
//
//
#include <f32dbg.h>
#include "t_fatcharsetconv_aux.h"
CFileMan* gFileMan = NULL;
RPointerArray<RFile>* gFileHandles = NULL;
TTestLogFailureData gLogFailureData;
RRawDisk TheDisk;
TFatBootSector gBootSector;
TBool gIOTesting;
TBool gAutoTest; // is BTB test
RFs TheFs;
RFile TheFile;
RDir TheDir;
TFileName gSessionPath;
TInt gAllocFailOff=KAllocFailureOff;
TInt gAllocFailOn=KAllocFailureOff;
TChar gDriveToTest;
TFileName gFileName;
TTCType gTCType;
TUint gTCId;
GLDEF_C void Format(TInt aDrive)
//
// Format current drive
//
{
test.Next(_L("Format"));
TBuf<4> driveBuf=_L("?:\\");
driveBuf[0]=(TText)(aDrive+'A');
RFormat format;
TInt count;
TInt r=format.Open(TheFs,driveBuf,EQuickFormat,count);
test_KErrNone(r);
while(count)
{
TInt r=format.Next(count);
test_KErrNone(r);
}
format.Close();
}
void MakeDir(const TDesC& aDirName)
//
// Make a directory
//
{
TInt r=TheFs.MkDirAll(aDirName);
test_Value(r, r == KErrNone || r==KErrAlreadyExists);
}
void ReportCheckDiskFailure(TInt aRet)
//
// Report the failure of checkdisk
//
{
test.Printf(_L("CHECKDISK FAILED: "));
switch(aRet)
{
case 1: test.Printf(_L("File cluster chain contains a bad value (<2 or >maxCluster)\n")); break;
case 2: test.Printf(_L("Two files are linked to the same cluster\n")); break;
case 3: test.Printf(_L("Unallocated cluster contains a value != 0\n")); break;
case 4: test.Printf(_L("Size of file != number of clusters in chain\n")); break;
default: test.Printf(_L("Undefined Error value %d\n"),aRet);
}
test(EFalse);
}
void CreateTestDirectory(const TDesC& aSessionPath)
//
// Create directory for test
//
{
TParsePtrC path(aSessionPath);
test(path.DrivePresent()==EFalse);
TInt r=TheFs.SetSessionPath(aSessionPath);
test_KErrNone(r);
r=TheFs.SessionPath(gSessionPath);
test_KErrNone(r);
r=TheFs.MkDirAll(gSessionPath);
test_Value(r, r == KErrNone || r==KErrAlreadyExists);
}
TInt CurrentDrive(TChar aDriveChar)
//
// Return the current drive number
//
{
TInt driveNum;
TInt r = TheFs.CharToDrive(aDriveChar,driveNum);
test_KErrNone(r);
gDriveToTest = gSessionPath[0] = (TText)aDriveChar;
return(driveNum);
}
TInt CurrentDrive()
//
// Return the current drive number
//
{
TInt driveNum;
TInt r = TheFs.CharToDrive(gSessionPath[0],driveNum);
test_KErrNone(r);
return(driveNum);
}
void MakeFile(const TDesC& aFileName,const TUidType& aUidType,const TDesC8& aFileContents)
//
// Make a file and write uid and data
//
{
RFile file;
TInt r=file.Replace(TheFs,aFileName,0);
test_Value(r, r == KErrNone || r==KErrPathNotFound);
if (r==KErrPathNotFound)
{
r=TheFs.MkDirAll(aFileName);
test_KErrNone(r);
r=file.Replace(TheFs,aFileName,0);
test_KErrNone(r);
}
TCheckedUid checkedUid(aUidType);
TPtrC8 uidData((TUint8*)&checkedUid,sizeof(TCheckedUid));
r=file.Write(uidData);
test_KErrNone(r);
r=file.Write(aFileContents);
test_KErrNone(r);
file.Close();
}
void MakeFile(const TDesC& aFileName,const TDesC8& aFileContents)
//
// Make a file and write something in it
//
{
RFile file;
TInt r=file.Replace(TheFs,aFileName,0);
if(r!=KErrNone && r!=KErrPathNotFound)
{
test.Printf(_L("ERROR: r=%d"),r);
test(EFalse);
}
test_Value(r, r == KErrNone || r==KErrPathNotFound);
if (r==KErrPathNotFound)
{
r=TheFs.MkDirAll(aFileName);
test_KErrNone(r);
r=file.Replace(TheFs,aFileName,0);
test_KErrNone(r);
}
r=file.Write(aFileContents);
test_KErrNone(r);
file.Close();
}
void MakeFile(const TDesC& aFileName,TInt anAttributes)
//
// Make a file and write something in it
//
{
RFile file;
TInt r=file.Replace(TheFs,aFileName,0);
test_Value(r, r == KErrNone || r==KErrPathNotFound);
if (r==KErrPathNotFound)
{
r=TheFs.MkDirAll(aFileName);
test_KErrNone(r);
r=file.Replace(TheFs,aFileName,0);
test_KErrNone(r);
}
file.Close();
r=TheFs.SetAtt(aFileName,anAttributes,0);
test_KErrNone(r);
}
void MakeFile(const TDesC& aFileName)
//
// Make a file
//
{
MakeFile(aFileName,_L8(""));
}
#if defined(_DEBUG) || defined(_DEBUG_RELEASE)
void QuickFormat()
{
FormatFatDrive(TheFs, CurrentDrive(), ETrue);
}
void ReadBootSector(TFatBootSector& aBootSector)
{
TInt r = ReadBootSector(TheFs, CurrentDrive(), KBootSectorNum<<KDefaultSectorLog2, aBootSector);
test_KErrNone(r);
if(!aBootSector.IsValid())
{
test.Printf(_L("Wrong bootsector! Dump:\n"));
aBootSector.PrintDebugInfo();
test(0);
}
}
void GetBootInfo()
{
QuickFormat();
ReadBootSector(gBootSector);
}
#endif
void CheckIfIOTesting(TTestSwitches& aSwitches)
{
if( ((aSwitches.iExeOnSymbian || aSwitches.iExeOnWindows) && !(aSwitches.iVerOnSymbian || aSwitches.iVerOnWindows))
||((aSwitches.iVerOnSymbian || aSwitches.iVerOnWindows) && !(aSwitches.iExeOnSymbian || aSwitches.iExeOnWindows))
)
{
gIOTesting = ETrue;
}
}
void CheckDisk()
{
TInt r=TheFs.CheckDisk(gSessionPath);
if (r!=KErrNone && r!=KErrNotSupported)
ReportCheckDiskFailure(r);
r = TheFs.ScanDrive(gSessionPath);
if (r!=KErrNone && r!=KErrNotSupported && r!=KErrInUse)
ReportCheckDiskFailure(r);
}
void InitLogData()
{
gLogFailureData.iExeOsName = KNone;
gLogFailureData.iVerOsName = KNone;
gLogFailureData.iExeDrive = 'A';
gLogFailureData.iVerDrive = 'A';
}
void ClearTCLogData()
{
gLogFailureData.iTCTypeName.SetLength(0);
gLogFailureData.iTCFailureOn.SetLength(0);
gLogFailureData.iTCId = 0;
gLogFailureData.iTCUniquePath.SetLength(0);
gLogFailureData.iAPIName.SetLength(0);
gLogFailureData.iLineNum = 0;
// gLogFailureData.iFileName.SetLength(0);
}
/*
* Search test cases by the index of the array of test case group, overloaded version for basic unitary cases.
* @param aIdx the test case index in search
* @param aBasicUnitaryTestCaseGroup the input test group, should always be gBasicUnitaryTestCases[]
* @param aTestCaseFound contains params of the test case found by the test case Id.
* @return KErrNone if only one test case on the id is found
* KErrNotFound if no test case is found
*/
TInt SearchTestCaseByArrayIdx(TUint aIdx, const TTestCaseUnitaryBasic aBasicUnitaryTestCaseGroup[],
TTestParamAll& aTestCaseFound, TBool aIsWithDLL=EFalse)
{
if (aBasicUnitaryTestCaseGroup[aIdx].iBasic.iTestCaseID != 0)
{
aTestCaseFound.iTestCaseID = aBasicUnitaryTestCaseGroup[aIdx].iBasic.iTestCaseID;
aTestCaseFound.iAPI = aBasicUnitaryTestCaseGroup[aIdx].iBasic.iAPI;
aTestCaseFound.iSrcDrvChar = aBasicUnitaryTestCaseGroup[aIdx].iSrcPrsBasic.iDrvChar;
aTestCaseFound.iSrcCmdPath.Copy(aBasicUnitaryTestCaseGroup[aIdx].iSrcPrsBasic.iCmdPath);
aTestCaseFound.iSrcPrsPath.Copy(aBasicUnitaryTestCaseGroup[aIdx].iSrcPrsBasic.iPrsPath);
aTestCaseFound.iSrcPrsFiles = aBasicUnitaryTestCaseGroup[aIdx].iSrcPrsBasic.iPrsFiles;
aTestCaseFound.iIsWithDLL = aIsWithDLL;
// To make every test case uniquely indentified for interOP
// update the test case id and its path correspondingly
TBuf<15> tempName = _L("_");
if(aTestCaseFound.iIsWithDLL)
tempName.Append(_L("DLL"));
else
tempName.Append(_L("NDLL"));
TInt idx = aTestCaseFound.iSrcCmdPath.Find(_L("\\Src\\"));
aTestCaseFound.iSrcCmdPath.Insert(idx, tempName);
aTestCaseFound.iSrcPrsPath.Insert(idx, tempName);
}
else
return KErrNotFound;
return KErrNone;
}
/*
* Search test cases by the index of the array of test case group, overloaded version for basic binary cases.
* @param aIdx the test case index in search
* @param aBasicUnitaryTestCaseGroup the input test group, should always be gBasicBinaryTestCases[]
* @param aTestCaseFound contains params of the test case found by the test case Id.
* @return KErrNone if only one test case on the id is found
* KErrNotFound if no test case is found
*/
TInt SearchTestCaseByArrayIdx(TUint aIdx, const TTestCaseBinaryBasic aBasicBinaryTestCaseGroup[],
TTestParamAll& aTestCaseFound, TBool aIsWithDLL=EFalse)
{
if (aBasicBinaryTestCaseGroup[aIdx].iBasic.iTestCaseID != 0)
{
aTestCaseFound.iTestCaseID = aBasicBinaryTestCaseGroup[aIdx].iBasic.iTestCaseID;
aTestCaseFound.iAPI = aBasicBinaryTestCaseGroup[aIdx].iBasic.iAPI;
aTestCaseFound.iSrcDrvChar = aBasicBinaryTestCaseGroup[aIdx].iSrcPrsBasic.iDrvChar;
aTestCaseFound.iSrcCmdPath.Copy(aBasicBinaryTestCaseGroup[aIdx].iSrcPrsBasic.iCmdPath);
aTestCaseFound.iSrcPrsPath.Copy(aBasicBinaryTestCaseGroup[aIdx].iSrcPrsBasic.iPrsPath);
aTestCaseFound.iSrcPrsFiles = aBasicBinaryTestCaseGroup[aIdx].iSrcPrsBasic.iPrsFiles;
aTestCaseFound.iTrgDrvChar = aBasicBinaryTestCaseGroup[aIdx].iTrgPrsBasic.iDrvChar;
aTestCaseFound.iTrgCmdPath.Copy(aBasicBinaryTestCaseGroup[aIdx].iTrgPrsBasic.iCmdPath);
aTestCaseFound.iIsWithDLL = aIsWithDLL;
// To make every test case uniquely indentified for interOP
// update the test case id and its path correspondingly
TBuf<15> tempBuf;
TInt idx = aTestCaseFound.iSrcCmdPath.Find(_L("\\T_FCSC\\")) + 8 /* Len of \\T_FCSC\\ */;
TInt i = 0;
while(aTestCaseFound.iSrcCmdPath[idx] != '\\')
{
tempBuf.SetLength(i+1);
tempBuf[i++] = aTestCaseFound.iSrcCmdPath[idx++];
}
tempBuf.Append(_L("_"));
if(aTestCaseFound.iIsWithDLL)
tempBuf.Append(_L("DLL"));
else
tempBuf.Append(_L("NDLL"));
TInt len = 0;
idx = aTestCaseFound.iSrcCmdPath.Find(_L("\\T_FCSC\\")) + 8;
while(aTestCaseFound.iSrcCmdPath[idx] != '\\')
{
len++;
aTestCaseFound.iSrcCmdPath[idx++];
}
aTestCaseFound.iSrcCmdPath.Replace(idx-len, len, tempBuf);
len =0;
idx = aTestCaseFound.iSrcPrsPath.Find(_L("\\T_FCSC\\")) + 8;
while(aTestCaseFound.iSrcPrsPath[idx] != '\\')
{
len++;
aTestCaseFound.iSrcCmdPath[idx++];
}
aTestCaseFound.iSrcPrsPath.Replace(idx-len, len, tempBuf);
len =0;
idx = aTestCaseFound.iTrgCmdPath.Find(_L("\\T_FCSC\\")) + 8;
while(aTestCaseFound.iTrgCmdPath[idx] != '\\')
{
len++;
aTestCaseFound.iTrgCmdPath[idx++];
}
aTestCaseFound.iTrgCmdPath.Replace(idx-len, len, tempBuf);
}
else
{
return KErrNotFound;
}
return KErrNone;
}
void Help()
{
RDebug::Print(_L("t_fatcharsetconv [-x {s,w}] [-d {dt}][-v {sw}]"));
RDebug::Print(_L("\t-x : for executing tests"));
RDebug::Print(_L("\t\t s or S for execution on Symbian"));
RDebug::Print(_L("\t\t w or W for execution on Windows"));
RDebug::Print(_L("\t-d: drive to test for execution/verification"));
RDebug::Print(_L("\t\t This test runs on FAT or Win32 file systems only"));
RDebug::Print(_L("\t\t d or D for test drive on Symbian (FAT file system)"));
RDebug::Print(_L("\t\t Any FAT/Win32 file system drive on emulator i.e. T, X etc"));
RDebug::Print(_L("\t-v : for validating tests"));
RDebug::Print(_L("\t\t s or S for verification on symbian"));
RDebug::Print(_L("\t\t w or W for verification on Windows"));
}
void ClearSwitches(TTestSwitches& aSwitches)
{
// clear the switches
aSwitches.iExeOnSymbian = EFalse;
aSwitches.iVerOnSymbian = EFalse;
aSwitches.iExeOnWindows = EFalse;
aSwitches.iVerOnWindows = EFalse;
aSwitches.iExeDriveChar =' ';
aSwitches.iVerDriveChar =' ';
aSwitches.iExeDriveNum =0;
aSwitches.iVerDriveNum =0;
aSwitches.iMountedFSName.SetLength(0);
}
void ParseCommandArguments(TTestSwitches& aSwitches)
{
TBuf<256> cmd;
User::CommandLine(cmd);
RDebug::Print(_L("Command Line : %S"), &cmd);
TChar testDrive = 'C';
InitLogData();
ClearSwitches(aSwitches);
TFileName currentFile=RProcess().FileName();
TLex lex(cmd);
TPtrC token=lex.NextToken();
if (token.MatchF(currentFile)==0)
{
token.Set(lex.NextToken());
}
if (token.Length()==0)
{
testDrive = 'C'; // default drives
gAutoTest = ETrue;
}
else if((token[0] >='A' && token[0]<='Z') || (token[0] >='a' && token[0]<='z'))
{
testDrive = token[0];
gAutoTest = ETrue;
}
else
{
while (!lex.Eos())
{
if (token.Length()==0)
{
continue; // ignore trailing whitespace
}
if (token==_L("-x") || token==_L("-X"))
{
token.Set(lex.NextToken());
if((token==_L("s")) || (token==_L("S")))
{
aSwitches.iExeOnSymbian = ETrue;
gLogFailureData.iExeOsName = KSymbian;
}
else if((token==_L("w")) || (token==_L("W")))
{
aSwitches.iExeOnWindows = ETrue;
gLogFailureData.iExeOsName = KWindows;
}
token.Set(lex.NextToken());
continue;
}
if (token==_L("-d") || token==_L("-D"))
{
token.Set(lex.NextToken());
testDrive = token[0];
token.Set(lex.NextToken());
continue;
}
if (token==_L("-v") || token==_L("-V"))
{
token.Set(lex.NextToken());
if((token==_L("s")) || (token==_L("S")))
{
aSwitches.iVerOnSymbian = ETrue;
gLogFailureData.iVerOsName = KSymbian;
}
else if((token==_L("w")) || (token==_L("W")))
{
aSwitches.iVerOnWindows = ETrue;
gLogFailureData.iVerOsName = KWindows;
}
token.Set(lex.NextToken());
continue;
}
RDebug::Print(_L("Unknown option %S"), &token);
Help();
return;
}
}
CheckIfIOTesting(aSwitches);
if(gIOTesting)
{
gAutoTest = EFalse;
}
else
{
gAutoTest = ETrue;
}
testDrive.UpperCase();
if (gAutoTest)
{
#if defined (__WINS__)
//execution phase
aSwitches.iExeOnWindows = ETrue;
aSwitches.iExeDriveChar = testDrive;
aSwitches.iExeDriveNum = CurrentDrive(aSwitches.iExeDriveChar);
gLogFailureData.iExeDrive = aSwitches.iExeDriveChar;
gLogFailureData.iExeOsName = KWindows;
//verification phase
aSwitches.iVerOnWindows = ETrue;
aSwitches.iVerDriveChar = testDrive;
aSwitches.iVerDriveNum = CurrentDrive(aSwitches.iVerDriveChar);
gLogFailureData.iVerDrive = aSwitches.iVerDriveChar;
gLogFailureData.iVerOsName = KWindows;
#else
//execution phase
aSwitches.iExeOnSymbian = ETrue;
aSwitches.iExeDriveChar = testDrive;
aSwitches.iExeDriveNum = CurrentDrive(aSwitches.iExeDriveChar);
gLogFailureData.iExeDrive = aSwitches.iExeDriveChar;
gLogFailureData.iExeOsName = KSymbian;
//verification phase
aSwitches.iVerOnSymbian = ETrue;
aSwitches.iVerDriveChar = testDrive;
aSwitches.iVerDriveNum = CurrentDrive(aSwitches.iVerDriveChar);
gLogFailureData.iVerDrive = aSwitches.iVerDriveChar;
gLogFailureData.iVerOsName = KSymbian;
#endif
}
if(aSwitches.iExeOnWindows || aSwitches.iExeOnSymbian)
{
aSwitches.iExeDriveChar = testDrive;
aSwitches.iExeDriveNum = CurrentDrive(aSwitches.iExeDriveChar);
gLogFailureData.iExeDrive = aSwitches.iExeDriveChar;
}
if(aSwitches.iVerOnWindows || aSwitches.iVerOnSymbian)
{
aSwitches.iVerDriveChar = testDrive;
aSwitches.iVerDriveNum = CurrentDrive(aSwitches.iVerDriveChar);
gLogFailureData.iVerDrive = aSwitches.iVerDriveChar;
}
}
void InitialiseL()
{
gFileMan=CFileMan::NewL(TheFs);
}
void RmDir(const TDesC& aDirName)
{
TFileName filename_dir = aDirName;
TInt r = 0;
r = TheFs.SetAtt(filename_dir, 0, KEntryAttReadOnly);
test_KErrNone(r);
r=gFileMan->RmDir(filename_dir);
test_Value(r, r == KErrNone || r==KErrNotFound || r==KErrPathNotFound || r==KErrInUse);
}
// Cleanup test variables
void Cleanup()
{
delete gFileMan;
}
/**
Parsing Dir Data Block
@param aDataBlock data block in TInt[] for parsing
@param aDirDataArray returning dir data array after parsing
@panic if data setup error
*/
void ParsingDirDataBlock(const TInt aDataBlock[], RArray<TInt>& aDirDataArray)
{
TInt err = KErrNone;
aDirDataArray.Reset();
if (aDataBlock[0] == EOB)
{
return;
}
TInt i = 1;
FOREVER
{
TInt lastItem = aDataBlock[i-1];
TInt currentItem = aDataBlock[i];
// check currentItem
if (currentItem == EOB)
{
if (lastItem == CON || lastItem > LAST)
//check last
{
test.Printf(_L("ERROR<SetupDir>: wrong dir data setup! err=%d\n"), err);
test(EFalse);
}
else
// passed, insert last, break
{
err = aDirDataArray.InsertInOrder(lastItem);
if (err != KErrNone && err != KErrAlreadyExists)
{
test.Printf(_L("ERROR<SetupDir>: wrong dir data setup! err=%d\n"), err);
test(EFalse);
}
break;
}
}
else if (currentItem == CON)
// if current == CON
{
if (lastItem == CON || lastItem >= LAST)
// check last item
{
test.Printf(_L("ERROR<SetupDir>: wrong dir data setup! err=%d\n"), err);
test(EFalse);
}
else // last < LAST, last != CON
{
// check next item
TInt nextItem = aDataBlock[i+1];
if (nextItem <= 0 || nextItem > LAST || lastItem >= nextItem)
{
test.Printf(_L("ERROR<SetupDir>: wrong dir data setup! err=%d\n"), err);
test(EFalse);
}
else
{
// all valid
for (TInt j = lastItem; j < nextItem; j++)
{
err = aDirDataArray.InsertInOrder(j);
if (err != KErrNone && err != KErrAlreadyExists)
{
test.Printf(_L("ERROR<SetupDir>: wrong dir data setup! err=%d\n"), err);
test(EFalse);
}
}
}
}
i++;
}
else if (0 <= currentItem && currentItem <= LAST)
// if current == normal item
{
if (lastItem == CON)
{
i++;
continue;
}
else if (lastItem >= LAST)
// check last item
{
test.Printf(_L("ERROR<SetupDir>: wrong dir data setup! err=%d\n"), err);
test(EFalse);
}
else
// passed, insert last
{
err = aDirDataArray.InsertInOrder(lastItem);
if (err != KErrNone && err != KErrAlreadyExists)
{
test.Printf(_L("ERROR<SetupDir>: wrong dir data setup! err=%d\n"), err);
test(EFalse);
}
}
i++;
}
else // invalid input
{
test.Printf(_L("ERROR<SetupDir>: wrong dir data setup! err=%d\n"), err);
test(EFalse);
}
}
}
/**
Setup dir structure for testing and verifying functional results
@param datastr data structure to setup directory
@param iOperation Operation to be performed
@param SrcDrive Source drive
@param Targetdrive Target drive input
@panic if data structure definition is incorrect
*/
void SetupDirFiles(const TDesC& aPath, const TDirSetupFiles& aDirFiles)
{
TFileName path = aPath;
if (path.Length() == 0)
{
test.Printf(_L("ERROR<SetupDirFiles()>: Zero length src path!\n"));
test(EFalse);
}
MakeDir(path);
RArray<TInt> addBlockDataArray;
RArray<TInt> deductBlockDataArray;
ParsingDirDataBlock(aDirFiles.iAddingBlock, addBlockDataArray);
ParsingDirDataBlock(aDirFiles.iDeductBlock, deductBlockDataArray);
if (addBlockDataArray.Count() == 0)
// empty dir setup
{
return;
}
for (TInt i = 0; i < deductBlockDataArray.Count(); ++i)
{
TInt idxToDelete = addBlockDataArray.FindInOrder(deductBlockDataArray[i]);
if (idxToDelete >= 0)
{
addBlockDataArray.Remove(idxToDelete);
}
else if (idxToDelete == KErrNotFound)
{
continue;
}
else
{
test.Printf(_L("ERROR<<SetupDir>>: wrong dir data setup! err=%d\n"), idxToDelete);
test(EFalse);
}
}
if (addBlockDataArray.Count() > 0)
{
for (TInt i = 0; i < addBlockDataArray.Count(); ++i)
{
TInt idx = addBlockDataArray[i];
path = aPath;
path += gDirPatterns[idx];
if (path[path.Length() - 1] == '\\')
{
MakeDir(path);
}
else
{
MakeFile(path, _L8("blahblah"));
}
}
}
addBlockDataArray.Reset();
deductBlockDataArray.Reset();
}
void LogTestFailureData(TTCType tcType, TFileName failedOn,
TUint tcId, TFileName tcUniquePath, TInt line)
{
if(tcType == EUnitaryTest)
gLogFailureData.iTCTypeName = KUnitary;
else if(tcType == EBinaryTest)
gLogFailureData.iTCTypeName = KBinary;
gLogFailureData.iTCFailureOn = failedOn;
gLogFailureData.iTCId = tcId;
gLogFailureData.iTCUniquePath.Copy(tcUniquePath);
gLogFailureData.iLineNum = line;
gLogFailureData.iFileName.Copy(gFileName);
RFile file;
TBuf8<256> tempBuf;
TFileName logFileName;
if(gIOTesting)
{
if(failedOn == KExecution)
{
logFileName.Append(KExeLogFileName);
}
else
{
logFileName.Append(KVerLogFileName);
}
}
else
{
logFileName.Append(KLogFileName);
}
logFileName.Append(KUnderScore);
logFileName.Append(gDriveToTest);
logFileName.Append(KExtension);
TInt r = file.Create(TheFs, logFileName, EFileRead|EFileWrite);
test_Value(r, r == KErrNone || r == KErrAlreadyExists);
if (r == KErrNone)
{
tempBuf.Append(KLogFileHeader);
file.Write(tempBuf);
}
if (r == KErrAlreadyExists)
{
r = file.Open(TheFs, logFileName, EFileRead|EFileWrite);
test_KErrNone(r);
TInt start = 0;
r=file.Seek(ESeekEnd,start);
test_KErrNone(r);
}
tempBuf.SetLength(0);
tempBuf.Append(KNewLine);
if(gIOTesting)
tempBuf.Append(KYes);
else
tempBuf.Append(KNo);
tempBuf.Append(KComma);
file.Write(tempBuf);
tempBuf.SetLength(0);
tempBuf.Append(gLogFailureData.iTCTypeName);
tempBuf.Append(KComma);
file.Write(tempBuf);
tempBuf.SetLength(0);
tempBuf.Append(gLogFailureData.iTCFailureOn);
tempBuf.Append(KComma);
file.Write(tempBuf);
tempBuf.SetLength(0);
tempBuf.AppendNum(gLogFailureData.iTCId);
tempBuf.Append(KComma);
file.Write(tempBuf);
tempBuf.SetLength(0);
tempBuf.Append(gLogFailureData.iTCUniquePath);
tempBuf.Append(KComma);
file.Write(tempBuf);
tempBuf.SetLength(0);
tempBuf.Append(gLogFailureData.iFSName);
tempBuf.Append(KComma);
file.Write(tempBuf);
tempBuf.SetLength(0);
tempBuf.Append(gLogFailureData.iExeOsName);
tempBuf.Append(KComma);
file.Write(tempBuf);
tempBuf.SetLength(0);
tempBuf.Append(gLogFailureData.iExeDrive);
tempBuf.Append(KComma);
file.Write(tempBuf);
tempBuf.SetLength(0);
tempBuf.Append(gLogFailureData.iVerOsName);
tempBuf.Append(KComma);
file.Write(tempBuf);
tempBuf.SetLength(0);
tempBuf.Append(gLogFailureData.iVerDrive);
tempBuf.Append(KComma);
file.Write(tempBuf);
tempBuf.SetLength(0);
tempBuf.Append(gLogFailureData.iAPIName);
tempBuf.Append(KComma);
file.Write(tempBuf);
tempBuf.SetLength(0);
tempBuf.AppendNum(gLogFailureData.iLineNum);
tempBuf.Append(KComma);
file.Write(tempBuf);
tempBuf.SetLength(0);
tempBuf.Append(gLogFailureData.iFuncName);
tempBuf.Append(KComma);
file.Write(tempBuf);
tempBuf.SetLength(0);
tempBuf.Append(gLogFailureData.iFileName);
file.Write(tempBuf);
file.Close();
}