Joinsysdef schema calculation handles missing files. rootsystef generation does not modify embedded metatdata.
// Copyright (c) 1995-2009 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:
//
#include <string.h>
#include <e32std.h>
#include <e32std_private.h>
#include <e32rom.h>
#include "e32image.h"
#include "pe_defs.h"
#include "pe_file.h"
#include "h_utl.h"
TBool hadText, hadReloc = EFalse;
TUint32 PEFile::iRomMemBase=0;
TUint32 PEFile::iRomLinearBase=0;
extern char* gX86imp;
extern int gX86num_imp_dlls;
PEFile::PEFile()
:iMemBase(0),iEntryPoint(0),iImageSize(0),iCodeSize(0),iDataSize(0),
iHeapReservedSize(0),iHeapCommittedSize(0),iStackReservedSize(0),iStackCommittedSize(0),
iBssSize(0),iBssOffset(0),iSectionAlign(0),iExpDirectoryOffset(0),iDataOffset(0),
iImageIsDll(EFalse),
iHeader(0),iExpDirectory(0),iImpDescriptor(0),iFileName(0),iFileHandle(0),
iLinkedBase(0),iStartOfHeaders(0),iSizeOfHeaders(0),iNumSections(0),
iRomRunAddr(0),iRamRunAddr(0),iRomDelta(0),iRamDelta(0),iHadDataSection(EFalse),
iBssSectionLinkedAddr(0),iBssSectionAddr(0),iBssSectionSize(0),
iDataSectionLinkedAddr(0),iDataSectionAddr(0),iDataSectionSize(0),
iCodeSectionAddr(0),iCodeSectionSize(0),
iRDataSectionAddr(0),iRDataSectionSize(0),
iCRTSectionAddr(0),iCRTSectionSize(0),
iExportDataDir(0)
//
// Constructor
//
{
for (TInt i=0; i<KNumberOfSections; i++)
{
iSectionHeader[i]=NULL;
iSectionData[i]=NULL;
}
}
PEFile::~PEFile()
//
// Destructor
//
{
delete [] iFileName;
for (TInt i=0; i<KNumberOfSections; i++)
{
delete iSectionHeader[i];
delete iSectionData[i];
}
}
TBool PEFile::Init(const char * const aFileName)
//
// Reads the PE headers to fill in lots of nice instance variables with info about the file
//
{
delete [] iFileName;
iFileName = new char[strlen((const char *)aFileName)+1];
strcpy ((char *)iFileName, (const char *)aFileName);
iHeader = (PIMAGE_NT_HEADERS)(HMem::Alloc(0,sizeof(IMAGE_DOS_HEADER)+sizeof(IMAGE_NT_HEADERS)));
if (!iHeader)
{
Print(EPeError,"Failed to allocate memory for headers.\n");
return EFalse;
}
TInt error = HFile::Open(iFileName, &iFileHandle);
if (error!=0)
return EFalse;
if (!HFile::Read(iFileHandle,iHeader,sizeof(IMAGE_DOS_HEADER)))
{
Print(EPeError,"Unable to read file %s.\n",iFileName);
HFile::Close(iFileHandle);
return EFalse;
}
if (IsValidDOSHeader((PIMAGE_DOS_HEADER)iHeader)) // read in the rest, overwriting the DOS header
iStartOfHeaders = ((PIMAGE_DOS_HEADER)iHeader)->e_lfanew;
else
iStartOfHeaders = 0;
if (!HFile::Seek(iFileHandle, iStartOfHeaders))
{
Print(EPeError,"File %s is not large enough to contain valid headers.\n",iFileName);
HFile::Close(iFileHandle);
return EFalse;
}
if (!HFile::Read(iFileHandle,iHeader,sizeof(IMAGE_NT_HEADERS)))
{
Print(EPeError,"Unable to read NT headers.\n");
HFile::Close(iFileHandle);
return EFalse;
}
if (!IsValidNTHeader(iHeader))
{
Print(EPeError,"Invalid NT header.\n");
HFile::Close(iFileHandle);
return EFalse;
}
if (!(IsValidFileHeader((PIMAGE_FILE_HEADER)&iHeader->FileHeader)))
{
Print(EPeError,"Invalid file header.\n");
HFile::Close(iFileHandle);
return EFalse;
}
// PIMAGE_NT_HEADERS pNTHeader = iHeader;
PIMAGE_FILE_HEADER pFileHeader = (PIMAGE_FILE_HEADER)&iHeader->FileHeader;
PIMAGE_OPTIONAL_HEADER pOptionalHeader = (PIMAGE_OPTIONAL_HEADER)&iHeader->OptionalHeader;
// PIMAGE_SECTION_HEADER pSectionHeader = (PIMAGE_SECTION_HEADER)(iHeader+1);
iImageSize = pOptionalHeader->SizeOfImage;
iCodeSize = pOptionalHeader->SizeOfCode;
iDataSize = pOptionalHeader->SizeOfInitializedData;
iEntryPoint = pOptionalHeader->AddressOfEntryPoint;
iHeapReservedSize = pOptionalHeader->SizeOfHeapReserve;
iHeapCommittedSize = pOptionalHeader->SizeOfHeapCommit;
iStackReservedSize = 0x2000;
iStackCommittedSize = 0x2000;
iBssSize = pOptionalHeader->SizeOfUninitializedData;
iSectionAlign = pOptionalHeader->SectionAlignment;
if (pFileHeader->Characteristics & IMAGE_FILE_DLL)
iImageIsDll = ETrue;
else
iImageIsDll = EFalse;
iLinkedBase=pOptionalHeader->ImageBase;
iNumSections = pFileHeader->NumberOfSections;
iSizeOfHeaders = pOptionalHeader->SizeOfHeaders;
iExportDataDir=pOptionalHeader->DataDirectory[IMAGE_DIRECTORY_ENTRY_EXPORT].VirtualAddress;
iExportDirSize=pOptionalHeader->DataDirectory[IMAGE_DIRECTORY_ENTRY_EXPORT].Size;
//
iCpu=pFileHeader->Machine;
HMem::Free(iHeader);
iHeader=0;
return ETrue;
}
void PEFile::Close()
//
// close the pe file
//
{
HFile::Close(iFileHandle);
}
TInt PEFile::ReadExportDirectory()
//
// Read in just the export directory
//
{
if (iExportDataDir==0)
return KErrNotFound;
TInt r=ReadSectionHeaders();
if (r!=KErrNone)
return r;
iSectionData[KConstSection]=ReadSectionData(iSectionHeader[KConstSection]);
iExpDirectoryOffset=iSectionHeader[KConstSection]->VirtualAddress;
iExpDirectory=(PIMAGE_EXPORT_DIRECTORY)(iSectionData[KConstSection]+iExportDataDir-iExpDirectoryOffset);
return KErrNone;
}
TInt PEFile::ReadSectionHeaders()
//
// Read in the section headers
//
{
TInt i;
for (i=0; i<KNumberOfSections; i++)
iSectionHeader[i]=NULL;
HFile::Seek(iFileHandle, iStartOfHeaders+sizeof(IMAGE_NT_HEADERS));
for (i=0; i<(TInt)iNumSections; i++)
{
PIMAGE_SECTION_HEADER header = new IMAGE_SECTION_HEADER;
if (!HFile::Read(iFileHandle, header, sizeof(IMAGE_SECTION_HEADER)))
return Print(EError, "Cannot read section header.\n");
if (CmpSectionName(header, ".text"))
iSectionHeader[KTextSection]=header;
else if (CmpSectionName(header, ".rdata"))
iSectionHeader[KConstSection]=header;
else if (CmpSectionName(header, ".edata"))
iSectionHeader[KExportSection]=header;
else if (CmpSectionName(header, ".data"))
iSectionHeader[KDataSection]=header;
else if (CmpSectionName(header, ".bss"))
iSectionHeader[KBssSection]=header;
else if (CmpSectionName(header, ".idata"))
iSectionHeader[KImportSection]=header;
else if (CmpSectionName(header, ".reloc"))
iSectionHeader[KRelocSection]=header;
else if (CmpSectionName(header, ".CRT"))
iSectionHeader[KCrtSection]=header;
else if (CmpSectionName(header, ".stab"))
delete header;
else if (CmpSectionName(header, ".stabstr"))
delete header;
else if (CmpSectionName(header,".E32_UID"))
delete header;
else if (CmpSectionName(header,".rsrc"))
delete header;
else
{
Print(EWarning, "Section '%.8s' removed.\n", header->Name);
delete header;
}
}
return KErrNone;
}
char *PEFile::ReadSectionData(PIMAGE_SECTION_HEADER aPeHeader)
//
// Read in the data for this section
//
{
char *section=NULL;
if (aPeHeader)
{
section=(char *)HMem::Alloc(NULL, aPeHeader->SizeOfRawData);
if (section==NULL)
return NULL;
HFile::Seek(iFileHandle, aPeHeader->PointerToRawData);
HFile::Read(iFileHandle, section, aPeHeader->SizeOfRawData);
}
return section;
}
TInt PEFile::ReadData()
//
//
//
{
TInt i;
for (i=0; i<KNumberOfSections; i++)
{
if (iSectionHeader[i])
{
iSectionData[i]=ReadSectionData(iSectionHeader[i]);
if (iSectionData[i]==NULL)
return Print(EError, "Cannot read %s section data.\n", iSectionHeader[i]->Name);
}
else
iSectionData[i]=NULL;
}
return KErrNone;
}
TInt PEFile::NumberOfImports() const
//
// Count the total number of imports for this image
//
{
// if (gX86imp)
// return gX86num_imp_dlls;
char *importData=iSectionData[KImportSection];
PIMAGE_SECTION_HEADER importHeader=iSectionHeader[KImportSection];
if (importData==NULL)
return 0;
TInt n=0;
TUint *src=(TUint *)importData;
while (*src)
{
TUint vaoffset=src[4];
if (!gLittleEndian) ByteSwap(vaoffset);
TUint offset=vaoffset-importHeader->VirtualAddress; // find the offset into the section of import addr table
TUint *p=(TUint *)(importData+offset);
while (*p++)
n++;
src+=5; // sizeof pe import block/4
}
return n;
}
TInt PEFile::NumberOfImportDlls() const
//
// Count the number of referenced Dlls
//
{
char *importData=iSectionData[KImportSection];
// PIMAGE_SECTION_HEADER importHeader=iSectionHeader[KImportSection];
if (importData==NULL)
return 0;
TInt n=0;
while (*(TUint *)importData)
{
n++;
importData+=5*4; // size of pe import block
}
return n;
}
TInt PEFile::NumberOfExports() const
//
// Count the number of exported symbols
//
{
if (iExportDataDir==0)
return 0;
return ((PIMAGE_EXPORT_DIRECTORY)iSectionData[KExportSection])->NumberOfFunctions;
}
TInt PEFile::NumberOfRelocs()
//
// Count the number of reloctions
//
{
if (iSectionData[KRelocSection]==NULL)
return 0;
char *relocs=iSectionData[KRelocSection];
TInt n=0;
TInt dudrelocs=0;
TInt blocksize;
TUint page;
TInt size=iSectionHeader[KRelocSection]->Misc.VirtualSize;
TUint *rrelocs=(TUint *)relocs;
TUint ssize=size;
if (!gLittleEndian) ByteSwap(rrelocs, ssize);
while (size>0)
{
page=*(TUint *)relocs;
blocksize=*(TInt *)(relocs+4);
if (blocksize==0)
break;
size-=blocksize;
TUint16 *p=(TUint16 *)(relocs+8);
relocs+=blocksize;
blocksize-=8;
while (blocksize>0)
{
TInt rtype=(*p&0xf000)>>12;
if (rtype==IMAGE_REL_BASED_HIGHLOW)
{
TUint va=page+(*p&0xfff);
// va is the address requiring relocation, so it must be in a section and can't have been offset
TInt section=FindSectionByVa(va+iLinkedBase);
if (section==KTextSection || section==KConstSection || section==KDataSection || section==KCrtSection)
n++;
else
dudrelocs++;
}
else if (rtype!=IMAGE_REL_BASED_ABSOLUTE) // used for padding
Print(EWarning, "Relocation type other than IMAGE_REL_BASED_HIGHLOW has been ignored.\n");
*p++;
blocksize-=2;
}
}
#if defined(_DEBUG)
if (dudrelocs>0)
Print(EWarning, "Image '%s' has %d relocations pointing at uninitialised data.\n", iFileName, dudrelocs);
#endif
if (!gLittleEndian) ByteSwap(rrelocs, ssize);
return n;
}
void PEFile::GetRelocs(TUint *aReloc, TUint *aRelocSection, TInt /*aNumberOfRelocs*/)
//
// load the relocs from the reloc section into relocation and relocsection arrays
//
{
TUint *relocation=aReloc;
TUint *relocsection=aRelocSection;
char *aRelocData=iSectionData[KRelocSection];
TUint16 *relocs=(TUint16 *)aRelocData;
TInt relocsize=iSectionHeader[KRelocSection]->Misc.VirtualSize;
TUint offset;
TUint page;
TInt i=0;
TUint *rrelocs=(TUint *)aRelocData;
TUint ssize=relocsize;
if (!gLittleEndian) ByteSwap(rrelocs, ssize);
while (relocsize>0)
{
page=*(TUint *)relocs;
relocs+=2;
TInt size=*(TUint *)relocs;
if (size==0)
break;
relocsize-=size;
relocs+=2;
size-=8;
while (size>0)
{
offset=*relocs++;
TInt type=offset&0xf000;
if (type==0x3000)
{
TUint va=page+(offset&0xfff);
// va is the address requiring relocation, so it must be in a section and can't have been offset
TInt section=FindSectionByVa(va+iLinkedBase);
if (section==KTextSection || section==KConstSection || section==KDataSection || section==KCrtSection)
{
relocsection[i]=section;
relocation[i++]=va;
}
}
size-=2;
}
}
if (!gLittleEndian) ByteSwap(rrelocs, ssize);
}
TInt PEFile::Normalise()
//
// Remove the MSVC anomalies
//
{
// MSVC puts export data in with .rdata
if (iExportDataDir && iSectionHeader[KExportSection]==NULL)
{
if (!PEFile::VirtualAddressInSection(iExportDataDir+iLinkedBase, iSectionHeader[KConstSection]))
return Print(EError, "Can't find exports in this PE file.\n");
else
{
iSectionHeader[KExportSection]=new IMAGE_SECTION_HEADER;
iSectionHeader[KExportSection]->VirtualAddress=iExportDataDir;
iSectionHeader[KExportSection]->Misc.VirtualSize=iExportDirSize;
iSectionHeader[KExportSection]->SizeOfRawData=iExportDirSize;
iSectionData[KExportSection]=new char [iExportDirSize];
if (iSectionData[KExportSection]==NULL)
return Print(EError, "Out of memory.\n");
memcpy(iSectionData[KExportSection], iSectionData[KConstSection]+iExportDataDir-iSectionHeader[KConstSection]->VirtualAddress, iExportDirSize);
// adjust .rdata so it does not include .edata
iSectionHeader[KConstSection]->Misc.VirtualSize-=iExportDirSize;
iSectionHeader[KConstSection]->SizeOfRawData-=iExportDirSize;
char *c=new char [iSectionHeader[KConstSection]->SizeOfRawData];
if (c==NULL)
return Print(EError, "Out of memory.\n");
memcpy(c, iSectionData[KConstSection], iSectionHeader[KConstSection]->SizeOfRawData);
delete iSectionData[KConstSection];
iSectionData[KConstSection]=c;
}
}
// Stupid compilers generate .idata sections even when there are no imports
if (iSectionHeader[KImportSection])
{
if (NumberOfImports()==0)
{
delete iSectionHeader[KImportSection];
delete iSectionData[KImportSection];
iSectionHeader[KImportSection]=NULL;
iSectionData[KImportSection]=NULL;
}
}
return KErrNone;
}
TInt PEFile::HasInitialisedData(PIMAGE_SECTION_HEADER aHeader)
//
// Returns true if the pe file section contains any initialised data
//
{
if (aHeader==NULL)
return FALSE;
if (aHeader->SizeOfRawData==0)
return FALSE;
return TRUE;
}
void PEFile::CopySectionData(TAny *source, TAny *dest, TUint32 fileLength, TUint32 memLength)
{
if (fileLength <= memLength)
{
Print(EScreen," Copying %08x bytes from file at %08x to memory at %08x\n", fileLength, source, dest);
HMem::Copy(dest,source,fileLength);
dest = (TAny *)((TUint32)dest + fileLength);
TUint32 remainingSize = memLength - fileLength;
Print(EScreen," Zeroing remaining %08x bytes at %08x\n", remainingSize, dest);
HMem::Set(dest, 0, remainingSize);
}
else
{
Print(EScreen," Copying %08x bytes from file at %08x to memory at %08x\n", memLength, source, dest);
HMem::Copy(dest,source,memLength);
}
}
TBool PEFile::ProcessRelocData(TAny *relocData,TInt dataSize)
{
TBool hadBadRelocs=EFalse;
PIMAGE_BASE_RELOCATION pRelocData = (PIMAGE_BASE_RELOCATION)((TUint32)relocData);
Print(ELog," Info on .reloc section...\n");
while (pRelocData->SizeOfBlock != 0)
{
TUint16 relocType;
TUint32 relocOffset;
TUint32 *relocAddr;
Print(ELog," Virtual address: %08x size: %08x\n",pRelocData->VirtualAddress, pRelocData->SizeOfBlock);
TUint numEntries = (pRelocData->SizeOfBlock-sizeof(*pRelocData))/sizeof(TUint16);
TUint16 *pEntry = (TUint16 *)((TUint32)pRelocData+sizeof(*pRelocData));
for (TUint i=0; i<numEntries; i++)
{
// Extract the top 4 bits of the relocation entry. This is the type
relocType = (TUint16)((*pEntry & 0xF000)>>12);
// The rest of the field is the offset
relocOffset = (*pEntry & 0x0FFF);
switch (relocType)
{
case 0: // Just padding
pEntry++;
break;
case 1:
case 2:
case 4:
case 5:
Print(EPeError,".reloc section, relocation type not handled.\n");
return EFalse;
break;
case 3:
{
if (pRelocData->VirtualAddress==0) // Defect in .reloc section of arm ekern.exe
{
pEntry++;
break;
}
TUint thisReloc=0;
relocAddr = (TUint32 *)((TUint32)iMemBase + (TUint32)pRelocData->VirtualAddress + relocOffset);
TUint32 reloc = *relocAddr;
if (IsInCode((TUint32)relocAddr) || IsInData((TUint32)relocAddr))
{
if (IsInDataReloc(reloc))
{
if (iImageIsDll)
{
Print(EPeError,"Dlls should have no RAM (data) relocations.\n");
return(EFalse);
}
thisReloc=reloc+iRamDelta;
}
else
thisReloc=reloc+iRomDelta;
*relocAddr = thisReloc; // this line here to enable breaking on values of thisReloc
}
else
hadBadRelocs=ETrue;
pEntry++;
}
break;
default:
Print(EPeError,".reloc section, invalid relocation type.\n");
return(EFalse);
}
}
dataSize-=pRelocData->SizeOfBlock;
if(dataSize<=0)
break;
pRelocData = (PIMAGE_BASE_RELOCATION)((TUint32)pRelocData+pRelocData->SizeOfBlock);
}
if (hadBadRelocs)
Print(EPeError,"File %s has relocation in invalid section\n",iFileName);
return(ETrue);
}
TBool PEFile::IsInCode(TUint32 anAddr)
{
if ((anAddr>=iCodeSectionAddr) && (anAddr<(iCodeSectionAddr+iCodeSectionSize)))
return(ETrue);
if ((anAddr>=iRDataSectionAddr) && (anAddr<(iRDataSectionAddr+iRDataSectionSize)))
return(ETrue);
if ((anAddr>=iCRTSectionAddr) && (anAddr<(iCRTSectionAddr+iCRTSectionSize)))
return(ETrue);
return(EFalse);
}
TBool PEFile::IsInData(TUint32 anAddr)
{
if ((anAddr>=iDataSectionAddr) && (anAddr<(iDataSectionAddr+iDataSectionSize)))
return(ETrue);
if ((anAddr>=iBssSectionAddr) && (anAddr<(iBssSectionAddr+iBssSectionSize)))
return(ETrue);
return(EFalse);
}
TBool PEFile::IsInDataReloc(TUint32 anAddr)
{
if ((anAddr>=iDataSectionLinkedAddr) && (anAddr<(iDataSectionLinkedAddr+iDataSectionSize)))
return(ETrue);
if ((anAddr>=iBssSectionLinkedAddr) && (anAddr<(iBssSectionLinkedAddr+iBssSectionSize)))
return(ETrue);
return(EFalse);
}
TBool PEFile::IsValidDOSHeader(PIMAGE_DOS_HEADER aDOSHeader)
{
if (aDOSHeader->e_magic!=IMAGE_DOS_SIGNATURE)
{
Print(EPeError,"File does not have valid DOS MZ signature.\n");
return EFalse;
}
else
return ETrue;
}
TBool PEFile::IsValidNTHeader(PIMAGE_NT_HEADERS aNTHeader)
{
if (aNTHeader->Signature != IMAGE_NT_SIGNATURE )
{
Print(EPeError,"File does not have valid NT PE signature.\n");
return EFalse;
}
else
return ETrue;
}
TBool PEFile::IsValidFileHeader(PIMAGE_FILE_HEADER aFileHeader)
{
if ((aFileHeader->Machine != IMAGE_FILE_MACHINE_I386)
&& (aFileHeader->Machine != 0xa00)
&& (aFileHeader->Machine != 0xb00)
&& (aFileHeader->Machine !=IMAGE_FILE_MACHINE_ALPHA))
{
Print(EPeError,"File is not a valid i386, ARM, M*Core or ALPHA executable.\n");
return EFalse;
}
if (aFileHeader->SizeOfOptionalHeader == 0)
{
Print(EPeError,"Optional header is 0 bytes in length - this is probably an object, not an executable\n");
return EFalse;
}
if (!(aFileHeader->Characteristics & IMAGE_FILE_EXECUTABLE_IMAGE))
{
Print(EPeError,"File is not a valid executable - probably linker error\n");
return EFalse;
}
return ETrue;
}
// Get details of the next import to fix-up in the current file. Fill in the name of the dll
//it is imported from, the ordinal number and the address to write back to.
#define ORDINAL_DONE 0x40000000
TImportStat PEFile::GetNextImport(char * &aDllName, TUint16 &aOrdinal, TUint32 * &aThunk)
{
PIMAGE_THUNK_DATA pLookupTable = 0;
TUint32 *pThunk = 0;
TUint32 rawOrdinal = ORDINAL_DONE;
TImportStat res = EImpDone;
PIMAGE_IMPORT_DESCRIPTOR impDesc = iImpDescriptor;
char *expDllName = 0;
if (impDesc == 0)
return EImpDone; // This file imports nothing
while ((rawOrdinal & ORDINAL_DONE) && ((impDesc->TimeDateStamp!=0 ) || (impDesc->Name!=0)))
{
expDllName = (char *)(iMemBase + impDesc->Name);
pLookupTable = (PIMAGE_THUNK_DATA)(iMemBase + impDesc->Characteristics);
pThunk = (TUint32 *)(iMemBase + (TUint32)impDesc->FirstThunk);
while ((rawOrdinal & ORDINAL_DONE) && (pLookupTable->u1.AddressOfData != 0))
{
if (pLookupTable->u1.Ordinal & IMAGE_ORDINAL_FLAG )
rawOrdinal = pLookupTable->u1.Ordinal;
else
{
Print(EPeError,"in file %s\n",iFileName);
Print(EPeError,"It is importing a symbol by name from %s\n",expDllName);
return EImpError;
}
pThunk++;
pLookupTable++;
}
impDesc++;
}
if (!(rawOrdinal & ORDINAL_DONE))
{
pThunk--;
pLookupTable--;
res = EImpSuccess;
aDllName = expDllName;
aThunk = pThunk;
aOrdinal = (TUint16)(rawOrdinal & 0xFFFF);
pLookupTable->u1.Ordinal |= ORDINAL_DONE;
}
return res;
}
TUint32 PEFile::GetFixUp(const TUint16 aOrdinal)
//
// Look through export directory to find fix-up for given ordinal
//
{
TUint32 ordBase = iExpDirectory->Base;
TUint32 *functions = (TUint32 *)((TUint32)iExpDirectory->AddressOfFunctions + iMemBase);
TUint32 fixupAddr = functions[aOrdinal-ordBase] + iRomRunAddr;
return fixupAddr;
}
TUint PEFile::GetNumberOfExportedFunctions()
{
return iExpDirectory->NumberOfFunctions;
}
TUint PEFile::GetOrdinalBase()
{
return iExpDirectory->Base;
}
TBool PEFile::ExportSectionExists()
{
if (iExpDirectory)
return ETrue;
else
return EFalse;
}
TBool PEFile::ImportSectionExists()
{
if (iImpDescriptor)
return ETrue;
else
return EFalse;
}
TUint PEFile::RoundToSectionSize(TUint aSize)
//
// Round to the nearest size in sections
//
{
TUint sAlign = iSectionAlign;
return ((aSize+sAlign-1)/sAlign)*sAlign ;
}
void PEFile::DumpPeHeaders()
//
// Print out loads of stuff from the PE header
//
{
TInt err = HFile::Open(iFileName, &iFileHandle);
if (err!=0)
return;
iHeader = (PIMAGE_NT_HEADERS)(HMem::Alloc(0,iSizeOfHeaders-iStartOfHeaders));
if (!iHeader)
return;
if (!HFile::Seek(iFileHandle, iStartOfHeaders))
return;
if (!HFile::Read(iFileHandle, iHeader, iSizeOfHeaders-iStartOfHeaders))
return;
PIMAGE_FILE_HEADER pFileHeader = (PIMAGE_FILE_HEADER)&iHeader->FileHeader;
PIMAGE_OPTIONAL_HEADER pOptionalHeader = (PIMAGE_OPTIONAL_HEADER)&iHeader->OptionalHeader;
PIMAGE_SECTION_HEADER pSectionHeader = (PIMAGE_SECTION_HEADER)(iHeader+1);
printf("File header\n");
printf("-----------\n\n");
char *szMachine=0;
switch( pFileHeader->Machine )
{
case 0xa00:
szMachine = (char *)"ARM"; break;
case 0xb00:
szMachine = (char *)"M*Core"; break;
case IMAGE_FILE_MACHINE_I386:
szMachine = (char *)"i386"; break;
case IMAGE_FILE_MACHINE_I860:
szMachine = (char *)"i860"; break;
case IMAGE_FILE_MACHINE_R3000:
szMachine = (char *)"R3000"; break;
case IMAGE_FILE_MACHINE_R4000:
szMachine = (char *)"R4000"; break;
case IMAGE_FILE_MACHINE_ALPHA:
szMachine = (char *)"Alpha"; break;
case IMAGE_FILE_MACHINE_POWERPC:
szMachine = (char *)"IBM PowerPC"; break;
default:
printf ("ERROR - machine not specified.\n");
szMachine = (char *)"unknown";
break;
}
printf("\n Machine: %s (Id=%04x)",szMachine, pFileHeader->Machine);
if ((pFileHeader->Machine != 0xa00) // ARM
&& (pFileHeader->Machine != 0xb00)) // M*Core
printf("..........ERROR!!");
printf("\n Number of sections : %04x",pFileHeader->NumberOfSections);
printf("\n Time date stamp : %08lx",pFileHeader->TimeDateStamp);
if (pFileHeader->TimeDateStamp == 0)
printf("..........ERROR!!");
printf("\n Pointer to symbol table : %08lx",pFileHeader->PointerToSymbolTable);
printf("\n Number of symbols : %08lx",pFileHeader->NumberOfSymbols);
printf("\n Size of optional header : %08x",pFileHeader->SizeOfOptionalHeader);
if (pFileHeader->SizeOfOptionalHeader == 0)
printf("..........ERROR!!");
printf("\n Characteristics : %08x\n",pFileHeader->Characteristics);
if (pFileHeader->Characteristics & IMAGE_FILE_RELOCS_STRIPPED)
printf("\n Relocations stripped..........ERROR!!");
if (pFileHeader->Characteristics & IMAGE_FILE_EXECUTABLE_IMAGE)
printf("\n Executable image.");
else
printf("\n Not executable image..........ERROR!!");
if (pFileHeader->Characteristics & IMAGE_FILE_CHAR_REVERSED_LO)
printf("\n Bytes reversed lo..........ERROR!!");
if (pFileHeader->Characteristics & IMAGE_FILE_32BIT_MACHINE)
printf("\n 32bit image.");
else
printf("\n Not 32bit image..........ERROR!!");
if (pFileHeader->Characteristics & IMAGE_FILE_SYSTEM)
printf("\n System file.");
if (pFileHeader->Characteristics & IMAGE_FILE_DLL)
printf("\n Dll file.");
if (pFileHeader->Characteristics & IMAGE_FILE_CHAR_REVERSED_HI)
printf("\n Bytes reversed hi..........ERROR!!");
printf ("\n\n\nOptional Header\n");
printf ("------------------");
printf("\n Magic = %04x", pOptionalHeader->Magic);
printf("\n Major Linker Version = %02x", pOptionalHeader->MajorLinkerVersion);
printf("\n Minor Linker Version = %02x", pOptionalHeader->MinorLinkerVersion);
printf("\n Size of code (bytes) = %08lx", pOptionalHeader->SizeOfCode);
printf("\n Size of initialized data (bytes) = %08lx", pOptionalHeader->SizeOfInitializedData);
printf("\n Size of uninitialized data (bytes) = %08lx", pOptionalHeader->SizeOfUninitializedData);
printf("\n Entrypoint RVA = %08lx", pOptionalHeader->AddressOfEntryPoint);
if (pOptionalHeader->AddressOfEntryPoint & 0x80000000)
printf("..........ERROR!!");
printf("\n Base of code = %08lx", pOptionalHeader->BaseOfCode);
if (pOptionalHeader->BaseOfCode & 0x80000000)
printf("..........ERROR!!");
printf("\n Base of data = %08lx", pOptionalHeader->BaseOfData);
if (pOptionalHeader->BaseOfData & 0x80000000)
printf("..........ERROR!!");
printf("\n Image base = %08lx", pOptionalHeader->ImageBase);
if (pOptionalHeader->ImageBase & 0x80000000)
printf("..........ERROR!!");
printf("\n Section alignment (bytes) = %08lx",pOptionalHeader->SectionAlignment);
if (pOptionalHeader->SectionAlignment & 0x80000000)
printf("..........ERROR!!\n");
printf("\n File alignment (bytes) = %08lx", pOptionalHeader->FileAlignment);
if (pOptionalHeader->FileAlignment & 0x80000000)
printf("..........ERROR!!");
printf("\n Major Operating System Version = %04x", pOptionalHeader->MajorOperatingSystemVersion);
printf("\n Minor Operating System Version = %04x", pOptionalHeader->MinorOperatingSystemVersion);
printf("\n Major Image Version = %04x", pOptionalHeader->MajorImageVersion);
printf("\n Minor Image Version = %04x", pOptionalHeader->MinorImageVersion);
printf("\n Major Subsystem Version = %04x", pOptionalHeader->MajorSubsystemVersion);
printf("\n Minor Subsystem Version = %04x", pOptionalHeader->MinorSubsystemVersion);
printf("\n Size of image (bytes) = %08lx", pOptionalHeader->SizeOfImage);
if (pOptionalHeader->SizeOfImage & 0x80000000)
printf("..........ERROR!!");
printf("\n Size of headers (bytes) = %08lx",pOptionalHeader->SizeOfHeaders);
if (pOptionalHeader->SizeOfHeaders & 0x80000000)
printf("..........ERROR!!");
printf("\n CheckSum = %04lx", pOptionalHeader->CheckSum);
printf("\n Subsystem = %04x", pOptionalHeader->Subsystem);
printf("\n Dll Characteristics = %04x", pOptionalHeader->DllCharacteristics);
printf("\n Size Of Stack Reserve = %04lx", pOptionalHeader->SizeOfStackReserve);
printf("\n Size Of Stack Commit = %04lx", pOptionalHeader->SizeOfStackCommit);
printf("\n Size Of Heap Reserve = %04lx", pOptionalHeader->SizeOfHeapReserve);
printf("\n Size Of Heap Commit = %04lx", pOptionalHeader->SizeOfHeapCommit);
printf("\n Loader Flags = %04lx", pOptionalHeader->LoaderFlags);
printf("\n Number Of Rva and Sizes = %04lx", pOptionalHeader->NumberOfRvaAndSizes);
printf("\n\n\nSection Headers\n");
printf("---------------\n\n");
for (TUint i=0;i<iNumSections;i++)
{
DumpNextSectionInFile(pSectionHeader);
pSectionHeader++;
}
if (!hadText)
printf("\nERROR - missing code section.");
if (!hadReloc)
printf("\nERROR - missing reloc section. (All images must be relocatable.)");
HMem::Free(iHeader);
}
void PEFile::DumpNextSectionInFile(PIMAGE_SECTION_HEADER pSectionHeader)
//
// Print out loads of stuff from the section header
//
{
printf("\nSection name %-8.8s\n",pSectionHeader->Name);
printf("\n Virtual size : %08lx", pSectionHeader->Misc.VirtualSize);
printf("\n RVA of section data : %08lx", pSectionHeader->VirtualAddress);
if (pSectionHeader->VirtualAddress & 0x80000000)
printf("..........ERROR!!");
printf("\n Size of raw data : %08lx", pSectionHeader->SizeOfRawData);
printf("\n Pointer to raw data : %08lx", pSectionHeader->PointerToRawData);
printf("\n Characteristics: %08lx\n", pSectionHeader->Characteristics);
if (pSectionHeader->Characteristics & IMAGE_SCN_LNK_REMOVE)
printf("\nERROR - Section should have been removed by linker.\n");
// read the section in
TUint32 filePos = pSectionHeader->PointerToRawData;
TUint32 fileLength = pSectionHeader->SizeOfRawData;
// TUint32 memLength = pSectionHeader->Misc.VirtualSize;
TAny *sectionFile = HMem::Alloc((TAny *)0, fileLength); // get a buffer
HFile::Seek(iFileHandle, filePos);
HFile::Read(iFileHandle, sectionFile, fileLength); // and read the file into the buffer
// TAny *sectionMem = (TAny *)((TUint32)iMemBase + pSectionHeader->VirtualAddress);
if (strnicmp((const char *)pSectionHeader->Name, ".text", IMAGE_SIZEOF_SHORT_NAME) == 0)
{
hadText = ETrue;
if (!(pSectionHeader->Characteristics & IMAGE_SCN_CNT_CODE))
printf("\nERROR - Code section has incorrect characteristics.\n");
else if (!(pSectionHeader->Characteristics & IMAGE_SCN_MEM_EXECUTE))
printf("\nERROR - Code section has incorrect characteristics.\n");
else if (!(pSectionHeader->Characteristics & IMAGE_SCN_MEM_READ))
printf("\nERROR - Code section has incorrect characteristics.\n");
}
else if (strnicmp((const char *)pSectionHeader->Name, ".data", IMAGE_SIZEOF_SHORT_NAME) == 0)
{
if (iImageIsDll)
{
printf ("\nERROR - DLL has data section.\n");
}
else
{
if (!(pSectionHeader->Characteristics & IMAGE_SCN_CNT_INITIALIZED_DATA))
printf("\nERROR - data section has incorrect characteristics.\n");
else if (!(pSectionHeader->Characteristics & IMAGE_SCN_MEM_WRITE))
printf("\nERROR - data section has incorrect characteristics.\n");
else if (!(pSectionHeader->Characteristics & IMAGE_SCN_MEM_READ))
printf("\nERROR - data section has incorrect characteristics.\n");
}
}
else if (strnicmp((const char *)pSectionHeader->Name, ".rdata", IMAGE_SIZEOF_SHORT_NAME) == 0)
{
}
else if (strnicmp((const char *)pSectionHeader->Name, ".bss", IMAGE_SIZEOF_SHORT_NAME) == 0)
{
if (iImageIsDll)
{
printf ("\nERROR - DLL has bss section.\n");
}
else
{
if (!(pSectionHeader->Characteristics & IMAGE_SCN_CNT_UNINITIALIZED_DATA))
printf("\nERROR - BSS section has incorrect characteristics.\n");
else if (!(pSectionHeader->Characteristics & IMAGE_SCN_MEM_WRITE))
printf("\nERROR - BSS section has incorrect characteristics.\n");
else if (!(pSectionHeader->Characteristics & IMAGE_SCN_MEM_READ))
printf("\nERROR - BSS section has incorrect characteristics.\n");
}
}
else if (strnicmp((const char *)pSectionHeader->Name, ".reloc", IMAGE_SIZEOF_SHORT_NAME) == 0)
{
hadReloc = ETrue;
}
else if (strnicmp((const char *)pSectionHeader->Name, ".idata", IMAGE_SIZEOF_SHORT_NAME) == 0)
{
}
else if (strnicmp((const char *)pSectionHeader->Name, ".edata", IMAGE_SIZEOF_SHORT_NAME) == 0)
{
iExpDirectory = (PIMAGE_EXPORT_DIRECTORY)(sectionFile);
if (iImageIsDll)
{
printf("\n Ordinal base = %08lx", iExpDirectory->Base);
printf("\n Number of functions = %08lx", iExpDirectory->NumberOfFunctions);
printf("\n Number of names = %08lx", iExpDirectory->NumberOfNames);
printf("\n Export address table RVA = %08lx", (TUint32)iExpDirectory->AddressOfFunctions);
printf("\n Name pointer RVA = %08lx", (TUint32)iExpDirectory->AddressOfNames);
printf("\n Ordinal table RVA = %08lx", (TUint32)iExpDirectory->AddressOfNameOrdinals);
}
else
{
printf("\nERROR - non-DLL with export section.");
}
}
else
{
printf("\nERROR - unexpected section.");
}
HMem::Free(sectionFile);
return;
}