// Copyright (c) 2005-2009 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:
// Implementation of the e32 image dump for the elf2e32 tool
// @internalComponent
// @released
//
//
#define __REFERENCE_CAPABILITY_NAMES__
#include "e32imagefile.h"
#include "pl_common.h"
#include <string.h>
#include <stdarg.h>
#include <stdio.h>
#ifdef __LINUX__
#define VSNPRINTF vsnprintf
#else
#define VSNPRINTF _vsnprintf
#endif
using std::cout;
const TInt KMaxStringLength=0x400;
/**
Variadic Function to print string.
@internalComponent
@released
@param aFmt
Formatted string.
*/
void PrintString(const char *aFmt,...)
{
TText imageText[KMaxStringLength];
va_list list;
va_start(list,aFmt);
VSNPRINTF((char *)imageText,KMaxStringLength,aFmt,list);
va_end(list);
cout << imageText;
cout.flush();
}
/**
Function to set priority.
@internalComponent
@released
@param aPri
Priority Type passed in
@param aStr
The priority value corresponding to the appropriate priority type
*/
void PriorityToStr(TProcessPriority aPri, char *aStr)
{
if (aPri==EPrioritySupervisor)
strcpy(aStr,"Supervisor");
else if (aPri>EPriorityRealTimeServer)
sprintf(aStr, "RealTime+%d", aPri-EPriorityRealTimeServer);
else if (aPri==EPriorityRealTimeServer)
strcpy(aStr,"RealTime");
else if (aPri>EPriorityFileServer)
sprintf(aStr, "FileServer+%d", aPri-EPriorityFileServer);
else if (aPri==EPriorityFileServer)
strcpy(aStr,"FileServer");
else if (aPri>EPriorityWindowServer)
sprintf(aStr, "WindowServer+%d", aPri-EPriorityWindowServer);
else if (aPri==EPriorityWindowServer)
strcpy(aStr,"WindowServer");
else if (aPri>EPriorityHigh)
sprintf(aStr, "High+%d", aPri-EPriorityHigh);
else if (aPri==EPriorityHigh)
strcpy(aStr,"High");
else if (aPri>EPriorityForeground)
sprintf(aStr, "Foreground+%d", aPri-EPriorityForeground);
else if (aPri==EPriorityForeground)
strcpy(aStr,"Foreground");
else if (aPri>EPriorityBackground)
sprintf(aStr, "Background+%d", aPri-EPriorityBackground);
else if (aPri==EPriorityBackground)
strcpy(aStr,"Background");
else if (aPri>EPriorityLow)
sprintf(aStr, "Low+%d", aPri-EPriorityLow);
else if (aPri==EPriorityLow)
strcpy(aStr,"Low");
else
sprintf(aStr, "Illegal (%d)", aPri);
}
/**
Function to dump e32 image.
@internalComponent
@released
@param aFileName
Name of the E32image to be dumped.
@param aDumpFlags
sub options passed to the 'dump' option
*/
void E32ImageFile::Dump(TText *aFileName,TInt aDumpFlags)
{
PrintString("E32ImageFile '%s'\n", aFileName);
DumpHeader(aDumpFlags);
DumpData(aDumpFlags);
}
/**
Function to dump e32 image header.
@internalComponent
@released
@param aDumpFlags
The flags set based on the sub options provided to the program.
*/
void E32ImageFile::DumpHeader(TInt aDumpFlags)
{
TUint flags = iOrigHdr->iFlags;
TUint abi = E32ImageHeader::ABIFromFlags(flags);
TUint hdrfmt = E32ImageHeader::HdrFmtFromFlags(flags);
TUint impfmt = E32ImageHeader::ImpFmtFromFlags(flags);
TUint ept = E32ImageHeader::EptFromFlags(flags);
TBool isARM = EFalse;
if(aDumpFlags&EDumpHeader)
{
PrintString("V%d.%02d(%03d)", iOrigHdr->iToolsVersion.iMajor,iOrigHdr->iToolsVersion.iMinor,iOrigHdr->iToolsVersion.iBuild);
PrintString("\tTime Stamp: %08x,%08x\n", iOrigHdr->iTimeHi, iOrigHdr->iTimeLo);
char sig[5];
memcpy(sig, (const char*)&iOrigHdr->iSignature, 4);
sig[4]=0;
PrintString(sig);
if (iOrigHdr->iFlags&KImageDll)
PrintString(" Dll for ");
else
PrintString(" Exe for ");
switch (iOrigHdr->CpuIdentifier())
{
case ECpuX86:
PrintString("X86 CPU\n");
break;
case ECpuArmV4:
isARM = ETrue;
PrintString("ARMV4 CPU\n");
break;
case ECpuArmV5:
isARM = ETrue;
PrintString("ARMV5 CPU\n");
break;
case ECpuMCore:
PrintString("M*Core CPU\n");
break;
case ECpuUnknown:
PrintString("Unknown CPU\n");
break;
default:
PrintString("something or other\n");
break;
}
PrintString("Flags:\t%08x\n", flags);
if (!(flags & KImageDll))
{
char str[80];
PriorityToStr(iOrigHdr->ProcessPriority(), str);
PrintString("Priority %s\n", str);
if (flags & KImageFixedAddressExe)
PrintString("Fixed process\n");
}
if (flags & KImageNoCallEntryPoint)
PrintString("Entry points are not called\n");
PrintString("Image header is format %d\n", hdrfmt>>24);
TUint compression = iOrigHdr->CompressionType();
switch (compression)
{
case KFormatNotCompressed:
PrintString("Image is not compressed\n");
break;
case KUidCompressionDeflate:
PrintString("Image is compressed using the DEFLATE algorithm\n");
break;
case KUidCompressionBytePair:
PrintString("Image is compressed using the BYTEPAIR algorithm\n");
break;
default:
PrintString("Image compression type UNKNOWN (%08x)\n", compression);
}
if (compression)
{
PrintString("Uncompressed size %08x\n", iOrigHdr->UncompressedFileSize());
}
TUint FPU = flags & KImageHWFloatMask;
if (FPU == KImageHWFloat_None)
PrintString("Image FPU support : Soft VFP\n");
else if (FPU == KImageHWFloat_VFPv2)
PrintString("Image FPU support : VFPv2\n");
else
PrintString("Image FPU support : Unknown\n");
// Code paging.
if (flags & KImageCodeUnpaged)
{
PrintString("Code Paging : Unpaged\n");
}
else if (flags & KImageCodePaged)
{
PrintString("Code Paging : Paged\n");
}
else
{
PrintString("Code Paging : Default\n");
}
// Data paging.
if (flags & KImageDataUnpaged)
{
PrintString("Data Paging : Unpaged\n");
}
else if (flags & KImageDataPaged)
{
PrintString("Data Paging : Paged\n");
}
else
{
PrintString("Data Paging : Default\n");
}
if (iOrigHdr->iFlags & KImageDebuggable)
{
PrintString("Debuggable : True\n");
}
else
{
PrintString("Debuggable : False\n");
}
if (iOrigHdr->iFlags & KImageSMPSafe)
{
PrintString("SMP Safe : True\n");
}
else
{
PrintString("SMP Safe : False\n");
}
}
if (hdrfmt >= KImageHdrFmt_V && (aDumpFlags&(EDumpHeader|EDumpSecurityInfo)))
{
//
// Important. Don't change output format of following security info
// because this is relied on by used by "Symbian Signed".
//
E32ImageHeaderV* v = iHdr;
PrintString("Secure ID: %08x\n", v->iS.iSecureId);
PrintString("Vendor ID: %08x\n", v->iS.iVendorId);
PrintString("Capabilities: %08x %08x\n", v->iS.iCaps[1], v->iS.iCaps[0]);
if(aDumpFlags&EDumpSecurityInfo)
{
TInt i;
for(i=0; i<ECapability_Limit; i++)
if(v->iS.iCaps[i>>5]&(1<<(i&31)))
PrintString(" %s\n", CapabilityNames[i]);
PrintString("\n");
}
}
if(aDumpFlags&EDumpHeader)
{
if (hdrfmt >= KImageHdrFmt_V)
{
E32ImageHeaderV* v = iHdr;
TUint32 xd = v->iExceptionDescriptor;
if ((xd & 1) && (xd != 0xffffffffu))
{
xd &= ~1;
PrintString("Exception Descriptor Offset: %08x\n", v->iExceptionDescriptor);
TExceptionDescriptor * aED = (TExceptionDescriptor * )(iData + v->iCodeOffset + xd);
PrintString("Exception Index Table Base: %08x\n", aED->iExIdxBase);
PrintString("Exception Index Table Limit: %08x\n", aED->iExIdxLimit);
PrintString("RO Segment Base: %08x\n", aED->iROSegmentBase);
PrintString("RO Segment Limit: %08x\n", aED->iROSegmentLimit);
}
else
PrintString("No Exception Descriptor\n");
PrintString("Export Description: Size=%03x, Type=%02x\n", v->iExportDescSize, v->iExportDescType);
if (v->iExportDescType != KImageHdr_ExpD_NoHoles)
{
TInt nb = v->iExportDescSize;
TInt i;
TInt j = 0;
for (i=0; i<nb; ++i)
{
if (++j == 8)
{
j = 0;
PrintString("\n");
}
PrintString(" %02x", v->iExportDesc[i]);
}
PrintString("\n");
}
TInt r = CheckExportDescription();
if (r == KErrNone)
PrintString("Export description consistent\n");
else if (r == KErrNotSupported)
PrintString("Export description type not recognised\n");
else
PrintString("!! Export description inconsistent !!\n");
}
TUint32 mv = iOrigHdr->ModuleVersion();
PrintString("Module Version: %d.%d\n", mv>>16, mv&0xffff);
if (impfmt == KImageImpFmt_PE)
{
PrintString("Imports are PE-style\n");
}
else if (impfmt == KImageImpFmt_ELF)
{
PrintString("Imports are ELF-style\n");
}
else if (impfmt == KImageImpFmt_PE2)
{
PrintString("Imports are PE-style without redundant ordinal lists\n");
}
if (isARM)
{
if (abi == KImageABI_GCC98r2)
{
PrintString("GCC98r2 ABI\n");
}
else if (abi == KImageABI_EABI)
{
PrintString("ARM EABI\n");
}
if (ept == KImageEpt_Eka1)
{
PrintString("Built against EKA1\n");
}
else if (ept == KImageEpt_Eka2)
{
PrintString("Built against EKA2\n");
}
}
PrintString("Uids:\t\t%08x %08x %08x (%08x)\n", iOrigHdr->iUid1, iOrigHdr->iUid2, iOrigHdr->iUid3, iOrigHdr->iUidChecksum);
if (hdrfmt >= KImageHdrFmt_V)
PrintString("Header CRC:\t%08x\n", iHdr->iHeaderCrc);
PrintString("File Size:\t%08x\n", iSize);
PrintString("Code Size:\t%08x\n", iOrigHdr->iCodeSize);
PrintString("Data Size:\t%08x\n", iOrigHdr->iDataSize);
PrintString("Compression:\t%08x\n", iOrigHdr->iCompressionType);
PrintString("Min Heap Size:\t%08x\n", iOrigHdr->iHeapSizeMin);
PrintString("Max Heap Size:\t%08x\n", iOrigHdr->iHeapSizeMax);
PrintString("Stack Size:\t%08x\n", iOrigHdr->iStackSize);
PrintString("Code link addr:\t%08x\n", iOrigHdr->iCodeBase);
PrintString("Data link addr:\t%08x\n", iOrigHdr->iDataBase);
PrintString("Code reloc offset:\t%08x\n", OrigCodeRelocOffset());
PrintString("Data reloc offset:\t%08x\n", OrigDataRelocOffset());
PrintString("Dll ref table count: %d\n", iOrigHdr->iDllRefTableCount);
if (iOrigHdr->iCodeSize || iOrigHdr->iDataSize || iOrigHdr->iBssSize || iOrigHdr->iImportOffset)
PrintString(" Offset Size Relocs #Relocs\n");
PrintString("Code %06x %06x", OrigCodeOffset(), iOrigHdr->iCodeSize);
if (iOrigHdr->iCodeRelocOffset)
{
E32RelocSection *r=(E32RelocSection *)(iData + iOrigHdr->iCodeRelocOffset);
PrintString(" %06x %06x", OrigCodeRelocOffset(), r->iNumberOfRelocs);
}
else
PrintString(" ");
PrintString(" +%06x (entry pnt)", iOrigHdr->iEntryPoint);
PrintString("\n");
PrintString("Data %06x %06x", OrigDataOffset(), iOrigHdr->iDataSize);
if (iOrigHdr->iDataRelocOffset)
{
E32RelocSection *r=(E32RelocSection *)(iData + iOrigHdr->iDataRelocOffset);
PrintString(" %06x %06x", OrigDataRelocOffset(), r->iNumberOfRelocs);
}
PrintString("\n");
PrintString("Bss %06x\n", iOrigHdr->iBssSize);
if (iOrigHdr->iExportDirOffset)
PrintString("Export %06x %06x (%d entries)\n", OrigExportDirOffset(), iOrigHdr->iExportDirCount*4, iOrigHdr->iExportDirCount);
if (iOrigHdr->iImportOffset)
PrintString("Import %06x\n", OrigImportOffset());
}
}
/**
Function to dump e32 image.
@internalComponent
@released
@param aData
Data to be dumped
@param aLength
Length of the file
*/
void dump(TUint *aData, TInt aLength)
{
TUint *p=aData;
TInt i=0;
char line[256];
char *cp=(char*)aData;
TInt j=0;
memset(line,' ',sizeof(line));
while (i<aLength)
{
TInt ccount=0;
char* linep=&line[8*9+2];
PrintString("%06x:", i);
while (i<aLength && ccount<8)
{
PrintString(" %08x", *p++);
i+=4;
ccount++;
for (j=0; j<4; j++)
{
char c=*cp++;
if (c<32 || c>127)
{
c = '.';
}
*linep++ = c;
}
}
*linep='\0';
PrintString("%s", line+(ccount*9));
PrintString("\n");
}
}
/**
Function to dump relocations.
@internalComponent
@released
@param aRelocs
Character pointer to relocations.
*/
void dumprelocs(char *aRelocs)
{
TInt num=((E32RelocSection *)aRelocs)->iNumberOfRelocs;
PrintString("%d relocs\n", num);
aRelocs+=sizeof(E32RelocSection);
TInt printed=0;
while (num>0)
{
TInt page=*(TUint *)aRelocs;
TInt size=*(TUint *)(aRelocs+4);
TInt pagesize=size;
size-=8;
TUint16 *p=(TUint16 *)(aRelocs+8);
while (size>0)
{
TUint a=*p++;
TUint relocType = (a & 0x3000) >> 12;
if ((relocType == 1) || (relocType == 3)) //only relocation type1 and type3
{
PrintString("%08x(%d) ", page + (a&0x0fff), relocType);
printed++;
if (printed>3)
{
PrintString("\n");
printed=0;
}
}
size-=2;
num--;
}
aRelocs+=pagesize;
}
PrintString("\n");
}
/**
Function to dump e32 image data.
@internalComponent
@released
@param aDumpFlags
The flags set based on the sub options provided to the program.
*/
void E32ImageFile::DumpData(TInt aDumpFlags)
{
if(aDumpFlags&EDumpCode)
{
PrintString("\nCode (text size=%08x)\n", iOrigHdr->iTextSize);
dump((TUint *)(iData + iOrigHdr->iCodeOffset), iOrigHdr->iCodeSize);
if (iOrigHdr->iCodeRelocOffset)
dumprelocs(iData + iOrigHdr->iCodeRelocOffset);
}
if((aDumpFlags&EDumpData) && iOrigHdr->iDataOffset)
{
PrintString("\nData\n");
dump((TUint *)(iData + iOrigHdr->iDataOffset), iOrigHdr->iDataSize);
if (iOrigHdr->iDataRelocOffset)
dumprelocs(iData + iOrigHdr->iDataRelocOffset);
}
if(aDumpFlags&EDumpExports)
{
PrintString("\nNumber of exports = %d\n", iOrigHdr->iExportDirCount);
TInt i;
TUint* exports = (TUint*)(iData + iOrigHdr->iExportDirOffset);
TUint absoluteEntryPoint = iOrigHdr->iEntryPoint + iOrigHdr->iCodeBase;
TUint impfmt = iOrigHdr->ImportFormat();
TUint absentVal = (impfmt == KImageImpFmt_ELF) ? absoluteEntryPoint : iOrigHdr->iEntryPoint;
for (i=0; i<iOrigHdr->iExportDirCount; ++i)
{
TUint exp = exports[i];
if (exp == absentVal)
PrintString("\tOrdinal %5d:\tABSENT\n", i+1);
else
PrintString("\tOrdinal %5d:\t%08x\n", i+1, exp);
}
}
// Important. Don't change output format of following inport info
// because this is relied on by tools used by "Symbian Signed".
if((aDumpFlags&EDumpImports) && iOrigHdr->iImportOffset)
{
const E32ImportSection* isection = (const E32ImportSection*)(iData + iOrigHdr->iImportOffset);
TUint* iat = (TUint*)((TUint8*)iData + iOrigHdr->iCodeOffset + iOrigHdr->iTextSize);
PrintString("\nIdata\tSize=%08x\n", isection->iSize);
PrintString("Offset of import address table (relative to code section): %08x\n", iOrigHdr->iTextSize);
TInt d;
const E32ImportBlock* b = (const E32ImportBlock*)(isection + 1);
for (d=0; d<iOrigHdr->iDllRefTableCount; d++)
{
char* dllname = iData + iOrigHdr->iImportOffset + b->iOffsetOfDllName;
TInt n = b->iNumberOfImports;
PrintString("%d imports from %s\n", b->iNumberOfImports, dllname);
const TUint* p = b->Imports();
TUint impfmt = iOrigHdr->ImportFormat();
if (impfmt == KImageImpFmt_ELF)
{
while (n--)
{
TUint impd_offset = *p++;
TUint impd = *(TUint*)(iData + iOrigHdr->iCodeOffset + impd_offset);
TUint ordinal = impd & 0xffff;
TUint offset = impd >> 16;
if (offset)
PrintString("%10d offset by %d\n", ordinal, offset);
else
PrintString("%10d\n", ordinal);
}
}
else
{
while (n--)
PrintString("\t%d\n", *iat++);
}
b = b->NextBlock(impfmt);
}
}
if((aDumpFlags & EDumpSymbols) && (iOrigHdr->iFlags & KImageNmdExpData))
{
TUint* aExpTbl = (TUint*)(iData + iOrigHdr->iExportDirOffset);
TUint* aZeroethOrd = aExpTbl - 1;
E32EpocExpSymInfoHdr *aSymInfoHdr = (E32EpocExpSymInfoHdr*)(iData + \
iOrigHdr->iCodeOffset + \
*aZeroethOrd - iOrigHdr->iCodeBase ) ;
DumpSymbolInfo(aSymInfoHdr);
}
}
void E32ImageFile::DumpSymbolInfo(E32EpocExpSymInfoHdr *aSymInfoHdr)
{
if(!aSymInfoHdr)
return;
char *aSymTblBase = (char*)aSymInfoHdr;
TUint *aSymAddrTbl;
char *aSymNameTbl;
char *aStrTable = aSymTblBase + aSymInfoHdr->iStringTableOffset;
aSymAddrTbl = (TUint*)(aSymTblBase + aSymInfoHdr->iSymbolTblOffset);
aSymNameTbl = (char*)(aSymAddrTbl + aSymInfoHdr->iSymCount);
int aIdx;
char *aSymName;
PrintString("\n\n\t\tSymbol Info\n");
if(aSymInfoHdr->iSymCount)
{
PrintString("0x%x Symbols exported\n",aSymInfoHdr->iSymCount);
PrintString(" Addr\t\tName\n");
PrintString("----------------------------------------\n");
TUint aNameOffset = 0;
for(aIdx=0;aIdx<aSymInfoHdr->iSymCount ; aIdx++)
{
if(aSymInfoHdr->iFlags & 1)
{
TUint32* aOff = ((TUint32*)aSymNameTbl+aIdx);
aNameOffset = (*aOff) << 2;
aSymName = aStrTable + aNameOffset;
}
else
{
TUint16* aOff = ((TUint16*)aSymNameTbl+aIdx);
aNameOffset = (*aOff) << 2;
aSymName = aStrTable + aNameOffset;
}
PrintString("0x%08x \t%s\t\n",aSymAddrTbl[aIdx], aSymName);
}
}
else
{
PrintString("No Symbol exported\n");
}
PrintString("\n\n");
if(aSymInfoHdr->iDllCount)
{
// The import table orders the dependencies alphabetically...
// We need to list out in the link order...
PrintString("%d Static dependencies found\n", aSymInfoHdr->iDllCount);
TUint* aDepTbl = (TUint*)((char*)aSymInfoHdr + aSymInfoHdr->iDepDllZeroOrdTableOffset);
TUint* aDepOffset = (TUint*)((char*)aDepTbl - iData);
const E32ImportSection* isection = (const E32ImportSection*)(iData + iOrigHdr->iImportOffset);
TInt d;
/* The import table has offsets to the location (in code section) where the
* import is required. For dependencies pointed by 0th ordinal, this offset
* must be same as the offset of the dependency table entry (relative to
* the code section).
*/
bool aZerothFound;
for(int aDep = 0; aDep < aSymInfoHdr->iDllCount; aDep++)
{
const E32ImportBlock* b = (const E32ImportBlock*)(isection + 1);
aZerothFound = false;
for (d=0; d<iOrigHdr->iDllRefTableCount; d++)
{
char* dllname = iData + iOrigHdr->iImportOffset + b->iOffsetOfDllName;
TInt n = b->iNumberOfImports;
const TUint* p = b->Imports()+ (n - 1);//start from the end of the import table
TUint impfmt = iOrigHdr->ImportFormat();
if (impfmt == KImageImpFmt_ELF)
{
while (n--)
{
TUint impd_offset = *p--;
TUint impd = *(TUint*)(iData + iOrigHdr->iCodeOffset + impd_offset);
TUint ordinal = impd & 0xffff;
if (ordinal == 0 )
{
if( impd_offset == ((TUint)aDepOffset - iOrigHdr->iCodeOffset))
{
/* The offset in import table is same as the offset of this
* dependency entry
*/
PrintString("\t%s\n", dllname);
aZerothFound = true;
}
break;
}
}
}
if(aZerothFound)
break;
b = b->NextBlock(impfmt);
}
if(!aZerothFound)
{
PrintString("!!Invalid dependency listed at %d\n",aDep );
}
aDepOffset++;
}
}
}