release note: SF Bug 385 - Raptor doesn't handle spaces in tool directory,
DPDEF143018 - Raptor doesn't handle spaces in GCCE installation directory correctly,
DPDEF141195 - Raptor doesn't handle spaces in tool paths
// Copyright (c) 2004-2009 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 e32 image creation and dump for elf2e32 tool
// @internalComponent
// @released
//
//
#include "pl_elfexecutable.h"
// get E32ImageHeader class...
#define INCLUDE_E32IMAGEHEADER_IMPLEMENTATION
#define RETURN_FAILURE(_r) return (fprintf(stderr, "line %d\n", __LINE__),_r)
//#define E32IMAGEHEADER_TRACE(_t) printf _t
#include "e32imagefile.h"
#include "pl_elfimportrelocation.h"
#include "pl_elflocalrelocation.h"
#include "pl_elfimports.h"
#include "elffilesupplied.h"
#include "pl_dllsymbol.h"
#include "h_ver.h"
#include "checksum.h"
#include "errorhandler.h"
#include <string>
#include <vector>
#include <cassert>
#include <iostream>
#ifndef __LINUX__
#include <io.h>
#else
#include <time.h>
#endif
#include <time.h>
#include <stdio.h>
using namespace std;
template <class T> inline T Align(T v, size_t s)
{
unsigned int inc = s-1;
unsigned int mask = ~inc;
unsigned int val = (unsigned int)v;
unsigned int res = (val+inc) & mask;
return (T)res;
}
// Need a default constructor for TVersion, but don't want all the other stuff in h_utl.cpp
/**
Default constructor for TVersion class.
@internalComponent
@released
*/
TVersion::TVersion(){}
/**
Constructor for TVersion class.
@internalComponent
@released
*/
TVersion::TVersion(TInt aMajor, TInt aMinor, TInt aBuild):
iMajor((TInt8)aMajor), iMinor((TInt8)aMinor), iBuild((TInt16)aBuild)
{
}
/**
Constructor for E32ImageChunkDesc class.
@internalComponent
@released
*/
E32ImageChunkDesc::E32ImageChunkDesc(char * aData, size_t aSize, size_t aOffset, char * aDoc):
iData(aData), iSize(aSize), iOffset(aOffset), iDoc(aDoc)
{
}
/**
Destructor for E32ImageChunkDesc class.
@internalComponent
@released
*/
E32ImageChunkDesc::~E32ImageChunkDesc()
{
}
/**
This function writes its data in the buffer.
@param aPlace - a location in the buffer
@internalComponent
@released
*/
void E32ImageChunkDesc::Write(char * aPlace)
{
memcpy(aPlace+iOffset, iData, iSize);
}
/**
Constructor for E32ImageChunks class.
@internalComponent
@released
*/
E32ImageChunks::E32ImageChunks():
iOffset(0)
{
}
/**
Destructor for E32ImageChunks class.
@internalComponent
@released
*/
E32ImageChunks::~E32ImageChunks()
{
if(iChunks.size())
{
ChunkList::iterator aItr = iChunks.begin();
ChunkList::iterator last = iChunks.end();
E32ImageChunkDesc *temp;
while( aItr != last)
{
temp = *aItr;
aItr++;
delete temp;
}
}
}
/**
This function creates and adds a chunk into a list.
@param aData - input buffer
@param asize - size of the input buffer
@param aOffset - byte offset of this chunk from the 1 byte in e32 image file.
@param aDoc - name of the chunk
@internalComponent
@released
*/
void E32ImageChunks::AddChunk(char * aData, size_t aSize, size_t aOffset, char * aDoc)
{
E32ImageChunkDesc * aChunk = new E32ImageChunkDesc(aData, aSize, aOffset, aDoc);
iChunks.push_back(aChunk);
iOffset += Align(aSize, sizeof(TUint32));
}
/**
This function returns the list of chunks.
@internalComponent
@released
*/
E32ImageChunks::ChunkList & E32ImageChunks::GetChunks()
{
return iChunks;
}
/**
This function returns the current offset pointing to the last chunk that
was added into the list of chunks.
@internalComponent
@released
*/
size_t E32ImageChunks::GetOffset()
{
return iOffset;
}
/**
This function sets the current offset pointing to the last chunk that
was added into the list of chunks.
@internalComponent
@released
*/
void E32ImageChunks::SetOffset(size_t aOffset)
{
iOffset = aOffset;
}
/**
Constructor for E32ImageFile class.
@internalComponent
@released
*/
E32ImageFile::E32ImageFile(const char * aFileName, ElfExecutable * aExecutable, ElfFileSupplied *aUseCase) :
iFileName(aFileName),
iE32Image(0),
iExportBitMap(0),
iElfExecutable(aExecutable),
iData(0),
iUseCase(aUseCase),
iHdr(0),
iHdrSize(sizeof(E32ImageHeaderV)),
iImportSection(0),
iImportSectionSize(0),
iCodeRelocs(0),
iCodeRelocsSize(0),
iDataRelocs(0),
iDataRelocsSize(0),
iExportOffset(0),
iLayoutDone(false),
iMissingExports(0),
iSymNameOffset(0)
{
}
/**
This function generates the E32 image.
@internalComponent
@released
*/
void E32ImageFile::GenerateE32Image()
{
if( iUseCase->GetNamedSymLookup() ){
ProcessSymbolInfo();
}
ProcessImports();
ProcessRelocations();
ConstructImage();
}
/**
This function processes the import map by looking into the dso files
from which the symbols are imported. It also fetches the ordinal numbers
for the corresponding symbols.
@internalComponent
@released
*/
void E32ImageFile::ProcessImports()
{
string aStrTab;
vector<int> aStrTabOffsets;
int aNumDlls = 0;
int aNumImports = 0;
bool aNamedLookup = iUseCase->GetNamedSymLookup();
TUint aImportTabEntryPos = 0;
ElfImports::ImportMap aImportMap = iElfExecutable->GetImports();
ElfImports::ImportMap::iterator p;
// First set up the string table and record offsets into string table of each
// LinkAs name.
for (p = aImportMap.begin(); p != aImportMap.end(); p++)
{
ElfImports::RelocationList & aImports = (*p).second;
char* aLinkAs = aImports[0]->iVerRecord->iLinkAs;
aStrTabOffsets.push_back(aStrTab.size()); //
string s = aLinkAs;
aStrTab.insert(aStrTab.end(),s.begin(),s.end());
aStrTab.insert(aStrTab.end(),0);
aNumDlls++;
aNumImports += aImports.size();
}
iNumDlls = aNumDlls;
iNumImports = aNumImports;
// Now we can figure out the size of everything
size_t aImportSectionSize = sizeof(E32ImportSection) +
(sizeof(E32ImportBlock) * aNumDlls) +
(sizeof(unsigned int) * aNumImports);
vector<Elf32_Word> aImportSection;
// This is the 'E32ImportSection' header - fill with 0 for the moment
aImportSection.push_back(0);
if( aNamedLookup ) {
// These are the 0th ordinals imported into the import table, one
// entry for each DLL.
aImportSectionSize += (sizeof(unsigned int) * aNumDlls);
}
// Now fill in the E32ImportBlocks
int idx = 0;
char * aDsoName;
for (p = aImportMap.begin(); p != aImportMap.end(); p++, idx++)
{
ElfImports::RelocationList & aImports = (*p).second;
aDsoName = aImports[0]->iVerRecord->iSOName;
//const char * aDSO = FindDSO((*p).first);
const char * aDSO = FindDSO(aDsoName);
aImportSection.push_back(aStrTabOffsets[idx] + aImportSectionSize);
int nImports = aImports.size();
// Take the additional 0th ordinal import into account
if( aNamedLookup )
nImports++;
aImportSection.push_back(nImports);
size_t aSize;
Elf32_Ehdr * aElfFile = 0;
ReadInputELFFile(aDSO, aSize, aElfFile);
ElfExecutable aElfExecutable(NULL);//(aElfFile, aSize);
aElfExecutable.ProcessElfFile(aElfFile);
ElfImports::RelocationList::iterator q;
for (q = aImports.begin(); q != aImports.end(); q++)
{
ElfImportRelocation * aReloc = *q;
char * aSymName = iElfExecutable->GetSymbolName(aReloc->iSymNdx);
unsigned int aOrdinal = aElfExecutable.GetSymbolOrdinal(aSymName);
//check the reloc refers to Code Segment
try
{
if (iElfExecutable->SegmentType(aReloc->iAddr) != ESegmentRO)
{
throw ImportRelocationError(ILLEGALEXPORTFROMDATASEGMENT, aSymName, iElfExecutable->iParameterListInterface->ElfInput());
}
}
/**This catch block introduced here is to avoid deleting partially constructed object(s).
Otherwise global catch block will delete the partially constructed object(s) and the tool will crash.
*/
catch(ErrorHandler& aError)
{
aError.Report();
exit(EXIT_FAILURE);
}
Elf32_Word aRelocOffset = iElfExecutable->GetRelocationOffset(aReloc);
aImportSection.push_back(aRelocOffset);
Elf32_Word * aRelocPlace = iElfExecutable->GetRelocationPlace(aReloc);
if (aOrdinal > 0xFFFF)
{
}
if (aReloc->iAddend > 0xFFFF)
{
}
* aRelocPlace = (aReloc->iAddend<<16) | aOrdinal;
}
if( aNamedLookup ) {
aImportTabEntryPos = aImportSection.size();
// Keep track of the location of the entry
iImportTabLocations.push_back(aImportTabEntryPos);
// Put the entry as 0 now, which shall be updated
aImportSection.push_back(0);
}
delete [] ((char*)aElfFile);
}
assert(aImportSectionSize == aImportSection.size() * sizeof(Elf32_Word));
size_t aTotalSize = Align(aImportSectionSize + aStrTab.size(), sizeof(Elf32_Word));
// Fill in the section header now we have the correct value.
aImportSection[0] = aTotalSize;
// Now construct the unified section
iImportSectionSize = aTotalSize;
iImportSection = (uint32 *)new char[aTotalSize];
memset(iImportSection, 0, aTotalSize);
memcpy(iImportSection, aImportSection.begin(), aImportSectionSize);
char * strTab = ((char *)iImportSection) + aImportSectionSize;
memcpy(strTab, aStrTab.data(), aStrTab.size());
}
/**
This function checks if a DSO file exists.
@param aPath - DSO file name.
@internalComponent
@released
*/
static bool ProbePath(string & aPath)
{
ifstream aInput;
const char * p = aPath.c_str();
aInput.open(p);
if (aInput.is_open())
{
aInput.close();
return true;
}
else
{
return false;
}
}
/**
This function allocates space for a DSO file name.
@param aPath - DSO file name
@internalComponent
@released
*/
const char * AllocatePath(string & aPath)
{
const char * p = aPath.c_str();
size_t len = aPath.size();
char * result = new char[len+1];
strcpy(result, p);
return (const char *)result;
}
/**
This function searches for a DSO in the libpath specified.
@param aName - DSO file name
@internalComponent
@released
*/
const char * E32ImageFile::FindDSO(const char * aName)
{
string aDSOName(aName);
string aDSOPath(aName);
const char *aNewDsoName;
if (ProbePath(aDSOName))
{
aNewDsoName = AllocatePath(aDSOName);
cleanupStack.push_back((char*)aNewDsoName);
return aNewDsoName;
}
ParameterListInterface::LibSearchPaths & paths = iUseCase->GetLibSearchPaths();
ParameterListInterface::LibSearchPaths::iterator p = paths.begin();
for (; p != paths.end(); p++)
{
string path(*p);
char dir = iUseCase->GetDirectorySeparator();
aDSOPath.erase();
aDSOPath.insert(aDSOPath.end(), path.begin(), path.end());
aDSOPath.insert(aDSOPath.end(), dir);
aDSOPath.insert(aDSOPath.end(), aDSOName.begin(), aDSOName.end());
if (ProbePath(aDSOPath))
{
aNewDsoName = AllocatePath(aDSOPath);
cleanupStack.push_back((char*)aNewDsoName);
return aNewDsoName;
}
}
throw ELFFileError(DSONOTFOUNDERROR,(char*)aName);
}
void E32ImageFile::ReadInputELFFile(const char * aName, size_t & aFileSize, Elf32_Ehdr * & aELFFile )
{
ifstream aInput;
aInput.open(aName, ifstream::binary|ifstream::in);
if (aInput.is_open())
{
aInput.seekg(0,ios::end);
aFileSize = (unsigned int) aInput.tellg();
aInput.seekg(0,ios::beg);
aELFFile = (Elf32_Ehdr *)new char [aFileSize];
aInput.read((char *)aELFFile, aFileSize);
aInput.close();
}
else
{
throw FileError(FILEOPENERROR,(char*)aName);
}
}
/**
This function processes relocations.
@internalComponent
@released
*/
void E32ImageFile::ProcessRelocations()
{
ProcessCodeRelocations();
ProcessDataRelocations();
}
/**
This function processes Code relocations.
@internalComponent
@released
*/
void E32ImageFile::ProcessCodeRelocations()
{
CreateRelocations(iElfExecutable->GetCodeRelocations(), iCodeRelocs, iCodeRelocsSize);
}
/**
This function processes Data relocations.
@internalComponent
@released
*/
void E32ImageFile::ProcessDataRelocations()
{
CreateRelocations(iElfExecutable->GetDataRelocations(), iDataRelocs, iDataRelocsSize);
}
/**
This function creates Code and Data relocations from the corresponding
ELF form to E32 form.
@internalComponent
@released
*/
void E32ImageFile::CreateRelocations(ElfRelocations::RelocationList & aRelocList, char * & aRelocs, size_t & aRelocsSize)
{
size_t rsize = RelocationsSize(aRelocList);
if (rsize)
{
aRelocsSize = Align(rsize + sizeof(E32RelocSection), sizeof(uint32));
uint32 aBase = (*aRelocList.begin())->iSegment->p_vaddr;
//add for cleanup to be done later..
cleanupStack.push_back(aRelocs);
aRelocs = new char [aRelocsSize];
memset(aRelocs, 0, aRelocsSize);
E32RelocSection * aRelocSection = (E32RelocSection * )aRelocs;
uint16 * data = (uint16 *)(aRelocSection + 1);
E32RelocPageDesc * startofblock = (E32RelocPageDesc *)data;
int page = -1;
int pagesize = sizeof(E32RelocPageDesc);
ElfRelocations::RelocationList::iterator r;
for (r = aRelocList.begin(); r != aRelocList.end(); r++)
{
ElfLocalRelocation * aReloc = *r;
int p = aReloc->iAddr & 0xfffff000;
if (page != p)
{
if (pagesize%4 != 0)
{
*data++ = 0;
pagesize += sizeof(uint16);
}
if (page == -1) page = p;
startofblock->aOffset = page - aBase;
startofblock->aSize = pagesize;
pagesize = sizeof(E32RelocPageDesc);
page = p;
startofblock = (E32RelocPageDesc *)data;
data = (uint16 *)(startofblock + 1);
}
uint16 relocType = aReloc->Fixup();
*data++ = (uint16)((aReloc->iAddr & 0xfff) | relocType);
pagesize += sizeof(uint16);
}
if (pagesize%4 != 0)
{
*data++ = 0;
pagesize += sizeof(uint16);
}
startofblock->aOffset = page - aBase;
startofblock->aSize = pagesize;
((E32RelocSection *)aRelocs)->iNumberOfRelocs = aRelocList.size();
((E32RelocSection *)aRelocs)->iSize = rsize;
}
}
/**
This function calculates the relocation taking into consideration
the page boundaries if they are crossed. The relocations are
sorted.
@param aRelocList - relocations found in the Elf file.
@internalComponent
@released
*/
size_t E32ImageFile::RelocationsSize(ElfRelocations::RelocationList & aRelocList)
{
size_t bytecount = 0;
int page = -1;
ElfRelocations::RelocationList::iterator r;
for (r = aRelocList.begin(); r != aRelocList.end(); r++)
{
ElfLocalRelocation * aReloc = *r;
int p = aReloc->iAddr & 0xfffff000;
if (page != p)
{
if (bytecount%4 != 0)
bytecount += sizeof(uint16);
bytecount += sizeof(E32RelocPageDesc); // page, block size
page = p;
}
bytecount += sizeof(uint16);
}
if (bytecount%4 != 0)
bytecount += sizeof(uint16);
return bytecount;
}
/**
This function returns the E32 interpretation for an Elf relocation type.
@param aReloc - relocation entry.
@internalComponent
@released
*/
E32ImageFile::uint16 E32ImageFile::GetE32RelocType(ElfRelocation * aReloc)
{
ESegmentType aSegType = aReloc->iSegmentType; // iElfExecutable->SegmentType(aReloc->iSymbol->st_value);
switch (aSegType)
{
case ESegmentRO:
return KTextRelocType;
case ESegmentRW:
return KDataRelocType;
default:
break;
};
// maybe this should be an error
return KInferredRelocType;
}
/**
This function constructs the E32 image.
@internalComponent
@released
*/
void E32ImageFile::ConstructImage()
{
InitE32ImageHeader();
ComputeE32ImageLayout();
FinalizeE32Image();
AllocateE32Image();
}
/**
This function calculates the timestamp.
@param aTime
@internalComponent
@released
*/
Int64 timeToInt64(TInt aTime)
{
aTime-=(30*365*24*60*60+7*24*60*60); // seconds since midnight Jan 1st, 2000
Int64 daysTo2000AD=730497;
Int64 t=daysTo2000AD*24*3600+aTime; // seconds since 0000
t=t+3600; // BST (?)
return t*1000000; // milliseconds
}
/**
This function returns the E32 image header size.
@internalComponent
@released
*/
size_t E32ImageFile::GetE32ImageHeaderSize()
{
return sizeof(E32ImageHeaderV);
}
/**
This function returns the extended E32 image header size.
@internalComponent
@released
*/
size_t E32ImageFile::GetExtendedE32ImageHeaderSize()
{
return iHdrSize;
}
/**
This function sets the extended E32 image header size.
@internalComponent
@released
*/
void E32ImageFile::SetExtendedE32ImageHeaderSize(size_t aSize)
{
iHdrSize = aSize;
}
/**
This function initialises the E32 image header fields.
@internalComponent
@released
*/
void E32ImageFile::InitE32ImageHeader()
{
iHdr = iUseCase->AllocateE32ImageHeader();
iHdr->iUid1 = 0;
iHdr->iUid2 = 0;
iHdr->iUid3 = 0;
iHdr->iHeaderCrc = 0;
iHdr->iSignature = 0x434f5045u;
iHdr->iModuleVersion = 0x00010000u;
iHdr->iCompressionType = 0;
iHdr->iToolsVersion = TVersion(MajorVersion, MinorVersion, Build);
Int64 ltime(timeToInt64(time(0)));
iHdr->iTimeLo=(uint32)ltime;
iHdr->iTimeHi=(uint32)(ltime>>32);
iHdr->iFlags = KImageHdrFmt_V;
// Confusingly, CodeSize means everything except writable data
iHdr->iCodeSize = 0;
iHdr->iDataSize = iElfExecutable->GetRWSize();
iHdr->iHeapSizeMin = 0;
iHdr->iHeapSizeMax = 0;
iHdr->iStackSize = 0;
iHdr->iBssSize = iElfExecutable->GetBssSize();
iHdr->iEntryPoint = 0;
iHdr->iCodeBase = iElfExecutable->GetROBase();
iHdr->iDataBase = iElfExecutable->GetRWBase();
iHdr->iDllRefTableCount = iNumDlls;
iHdr->iExportDirOffset = 0;
iHdr->iExportDirCount = iUseCase->GetNumExports();
iHdr->iTextSize = iElfExecutable->GetROSize();
iHdr->iCodeOffset = 0;
iHdr->iDataOffset = 0;
iHdr->iImportOffset = 0;
iHdr->iCodeRelocOffset = 0;
iHdr->iDataRelocOffset = 0;
iHdr->iProcessPriority = (uint16)EPriorityForeground;
iHdr->iUncompressedSize = 0;
iHdr->iS.iSecureId = 0;
iHdr->iS.iVendorId = 0;
iHdr->iExceptionDescriptor = 0;
iHdr->iSpare2 = 0;
iHdr->iExportDescSize = iUseCase->GetExportDescSize();
iHdr->iExportDescType = iUseCase->GetExportDescType();
if (iHdr->iExportDescSize == 0) iHdr->iExportDesc[0] = 0;
}
/**
This function creates the E32 image layout.
@internalComponent
@released
*/
void E32ImageFile::ComputeE32ImageLayout()
{
// E32Image header
iChunks.AddChunk((char *)iHdr, Align(GetExtendedE32ImageHeaderSize(), sizeof(uint32)), 0, "Image Header");
uint32 endOfHeader = iChunks.GetOffset();
// Code section
iHdr->iCodeOffset = iChunks.GetOffset();
iChunks.AddChunk(iElfExecutable->GetRawROSegment(), iElfExecutable->GetROSize(), iHdr->iCodeOffset, "Code Section");
// Exports Next - then we can set up CodeSize
// Call out to the use case so it can decide how we do this
// record exporttable offset for default case
bool aSymLkupEnabled = iUseCase->GetNamedSymLookup();
// The export table is required either when:
// a. there are exported symbols
// b. symbol lookup is enabled - because this table also indicates the dependencies
bool aExportTableNeeded = (iHdr->iExportDirCount || aSymLkupEnabled) ? 1 : 0;
iExportOffset = iChunks.GetOffset() + 4;
iHdr->iExportDirOffset = aExportTableNeeded ? iUseCase->GetExportOffset() : 0;
if ( aExportTableNeeded && iUseCase->AllocateExportTableP())
iChunks.AddChunk(iUseCase->GetExportTable(), iUseCase->GetExportTableSize(), iChunks.GetOffset(), "Export Table");
// Symbol info next
if( aSymLkupEnabled ){
E32EpocExpSymInfoHdr* aSymHdrInfo = (E32EpocExpSymInfoHdr*)CreateSymbolInfo(iChunks.GetOffset());
if( aSymHdrInfo )
iChunks.AddChunk( (char*)aSymHdrInfo, aSymHdrInfo->iSize, iChunks.GetOffset(), "Symbol Info" );
}
// CodeSize is current offset - endof header offset
iHdr->iTextSize = iHdr->iCodeSize = iChunks.GetOffset() - endOfHeader;
// Data section
if (iElfExecutable->GetRWSize())
{
iHdr->iDataOffset = iChunks.GetOffset();
iChunks.AddChunk(iElfExecutable->GetRawRWSegment(), iElfExecutable->GetRWSize(), iHdr->iDataOffset, "Data Section");
}
// Import Section
if (iImportSectionSize)
{
iHdr->iImportOffset = iChunks.GetOffset();
iChunks.AddChunk((char *)iImportSection, iImportSectionSize, iHdr->iImportOffset, "Import Section");
}
// Code relocs
if (iCodeRelocsSize)
{
iHdr->iCodeRelocOffset = iChunks.GetOffset();
iChunks.AddChunk((char *)iCodeRelocs, iCodeRelocsSize, iHdr->iCodeRelocOffset, "Code Relocs");
}
// Data relocs
if (iDataRelocsSize)
{
iHdr->iDataRelocOffset = iChunks.GetOffset();
iChunks.AddChunk((char *)iDataRelocs, iDataRelocsSize, iHdr->iDataRelocOffset, "Data Relocs");
}
iLayoutDone = true;
}
/**
This function returns the byte offset in the E32 image from where the
export table starts.
@internalComponent
@released
*/
size_t E32ImageFile::GetExportOffset()
{
return iExportOffset;
}
/**
This function returns E32 image size.
@internalComponent
@released
*/
size_t E32ImageFile::GetE32ImageSize()
{
assert(iLayoutDone);
return iChunks.GetOffset();
}
/**
This function creates the export bitmap also replacing the absent symbols
with the entry point functions.
@internalComponent
@released
*/
void E32ImageFile::CreateExportBitMap()
{
int nexp = iUseCase->GetNumExports();
size_t memsz = (nexp + 7) >> 3;
iExportBitMap = new uint8[memsz];
memset(iExportBitMap, 0xff, memsz);
// skip header
uint32 * exports = ((uint32 *)iUseCase->GetExportTable()) + 1;
uint32 absentVal = EntryPointOffset() + iElfExecutable->GetROBase();
iMissingExports = 0;
for (int i=0; i<nexp; ++i)
{
if (exports[i] == absentVal)
{
iExportBitMap[i>>3] &= ~(1u << (i & 7));
++iMissingExports;
}
}
}
/**
This function creates export desription for the absent symbols.
@internalComponent
@released
*/
void E32ImageFile::AddExportDescription()
{
CreateExportBitMap();
if (iMissingExports == 0)
return; // nothing to do
int nexp = iUseCase->GetNumExports();
size_t memsz = (nexp + 7) >> 3; // size of complete bitmap
size_t mbs = (memsz + 7) >> 3; // size of meta-bitmap
size_t nbytes = 0;
unsigned int i;
for (i=0; i<memsz; ++i)
if (iExportBitMap[i] != 0xff)
++nbytes; // number of groups of 8
uint8 edt = KImageHdr_ExpD_FullBitmap;
uint32 extra_space = memsz - 1;
if (mbs + nbytes < memsz)
{
edt = KImageHdr_ExpD_SparseBitmap8;
extra_space = mbs + nbytes - 1;
}
extra_space = (extra_space + sizeof(uint32) - 1) &~ (sizeof(uint32) - 1);
iHdr->iExportDescType = edt;
if (edt == KImageHdr_ExpD_FullBitmap)
{
iHdr->iExportDescSize = (uint16)memsz;
iHdr->iExportDesc[0] = iExportBitMap[0];
uint8 * aDesc = new uint8[extra_space];
memset(aDesc, 0, extra_space);
memcpy(aDesc, &iExportBitMap[1], memsz-1);
iChunks.AddChunk((char *)aDesc,extra_space, iChunks.GetOffset(), "Export Description");
}
else
{
iHdr->iExportDescSize = (uint16)(mbs + nbytes);
uint8 * aBuf = new uint8[extra_space + 1];
memset(aBuf , 0, extra_space + 1);
TUint8* mptr = aBuf;
TUint8* gptr = mptr + mbs;
for (i=0; i<memsz; ++i)
{
if (iExportBitMap[i] != 0xff)
{
mptr[i>>3] |= (1u << (i&7));
*gptr++ = iExportBitMap[i];
}
}
iHdr->iExportDesc[0] = aBuf[0];
uint8 * aDesc = new uint8[extra_space];
memcpy(aDesc, aBuf+1, extra_space);
delete[] aBuf;
iChunks.AddChunk((char *)aDesc,extra_space, iChunks.GetOffset(), "Export Description");
}
}
/**
This function sets the fields of the E32 image.
@internalComponent
@released
*/
void E32ImageFile::FinalizeE32Image()
{
// Arrange a header for this E32 Image
iHdr->iCpuIdentifier = GetCpuIdentifier();
// Import format is ELF-derived
iHdr->iFlags |= KImageImpFmt_ELF;
// ABI is ARM EABI
iHdr->iFlags |= KImageABI_EABI;
iHdr->iFlags |= KImageEpt_Eka2;
bool isDllp = iUseCase->ImageIsDll();
if (isDllp)
{
iHdr->iFlags |= KImageDll;
if (iHdr->iDataSize && !iUseCase->AllowDllData())
throw ELFFileError(DLLHASINITIALISEDDATAERROR, (char*)iUseCase->InputElfFileName());
if (iHdr->iBssSize && !iUseCase->AllowDllData())
throw ELFFileError(DLLHASUNINITIALISEDDATAERROR, (char*)iUseCase->InputElfFileName());
}
iHdr->iHeapSizeMin = iUseCase->HeapCommittedSize();
iHdr->iHeapSizeMax = iUseCase->HeapReservedSize();
iHdr->iStackSize = iUseCase->StackCommittedSize();
iHdr->iEntryPoint = EntryPointOffset();
EEntryPointStatus r = ValidateEntryPoint();
if (r == EEntryPointCorrupt)
throw ELFFileError(ENTRYPOINTCORRUPTERROR, (char*)iUseCase->InputElfFileName());
else if (r == EEntryPointNotSupported)
throw ELFFileError(ENTRYPOINTNOTSUPPORTEDERROR, (char*)iUseCase->InputElfFileName());
SetUpExceptions();
SetUids();
SetSecureId();
SetVendorId();
SetCallEntryPoints();
SetCapability();
SetPriority(isDllp);
SetFixedAddress(isDllp);
SetVersion();
SetCompressionType();
SetFPU();
SetPaged();
SetSymbolLookup();
SetDebuggable();
SetSmpSafe();
UpdateHeaderCrc();
}
/**
This function returns the CPU identifier for the E32 image header.
@internalComponent
@released
*/
E32ImageFile::uint16 E32ImageFile::GetCpuIdentifier()
{
return (uint16)ECpuArmV5;
}
/**
This function returns the entry point of the E32 image .
@internalComponent
@released
*/
E32ImageFile::uint32 E32ImageFile::EntryPointOffset()
{
return iElfExecutable->EntryPointOffset();
}
/**
This function validates the entry point of the E32 image .
@internalComponent
@released
*/
E32ImageFile::EEntryPointStatus E32ImageFile::ValidateEntryPoint()
{
uint32 epOffset = iHdr->iEntryPoint;
if (epOffset & 3)
return EEntryPointOK; // if entry point not 4 byte aligned, must be old style
uint32 fileOffset = epOffset + iElfExecutable->iCodeSegmentHdr->p_offset;
if (fileOffset+4 > iChunks.GetOffset())
return EEntryPointCorrupt; // entry point is past the end of the file??
int ept = 0; // old style if first instruction not recognised
uint8 * p = ELF_ENTRY_PTR(uint8, iElfExecutable->iElfHeader, fileOffset + 4);
uint32 x = *--p;
x<<=8;
x|=*--p;
x<<=8;
x|=*--p;
x<<=8;
x|=*--p;
if ((x & 0xffffff00) == 0xe31f0000)
{
// starts with tst pc, #n - new entry point
ept = (x & 0xff) + 1;
}
if (ept>7)
return EEntryPointNotSupported;
iHdr->iFlags |= (ept<<KImageEptShift);
return EEntryPointOK;
}
/**
This function sets the exciption descriptor in the E32 image .
@internalComponent
@released
*/
void E32ImageFile::SetUpExceptions()
{
char * aExDescName = "Symbian$$CPP$$Exception$$Descriptor";
Elf32_Sym * aSym = iElfExecutable->LookupStaticSymbol(aExDescName);
if (aSym)
{
uint32 aSymVaddr = aSym->st_value;
uint32 aROBase = iElfExecutable->GetROBase();
uint32 aROSize = iElfExecutable->GetROSize();
//check its in RO segment
if (aSymVaddr < aROBase || aSymVaddr >= (aROBase + aROSize))
{
throw ELFFileError(EXCEPTIONDESCRIPTOROUTSIDEROERROR,(char*)iUseCase->InputElfFileName());
}
// Set bottom bit so 0 in header slot means an old binary.
// The decriptor is always aligned on a 4 byte boundary.
iHdr->iExceptionDescriptor = (aSymVaddr - aROBase) | 0x00000001;
}
}
/**
This function sets the UIDs of the E32 image .
@internalComponent
@released
*/
void E32ImageFile::SetUids()
{
iHdr->iUid1=iUseCase->GetUid1();
iHdr->iUid2=iUseCase->GetUid2();
iHdr->iUid3=iUseCase->GetUid3();
}
/**
This function sets the secure ID of the E32 image as passed in the command line.
@internalComponent
@released
*/
void E32ImageFile::SetSecureId()
{
if (iUseCase->GetSecureIdOption())
iHdr->iS.iSecureId = iUseCase->GetSecureId();
else
iHdr->iS.iSecureId = iUseCase->GetUid3();
}
/**
This function sets the vendor Id of the E32 image as passed in command line.
@internalComponent
@released
*/
void E32ImageFile::SetVendorId()
{
iHdr->iS.iVendorId = iUseCase->GetVendorId();
}
/**
This function sets the call entry point of the E32 image .
@internalComponent
@released
*/
void E32ImageFile::SetCallEntryPoints()
{
if (iUseCase->GetCallEntryPoints())
iHdr->iFlags|=KImageNoCallEntryPoint;
else
iHdr->iFlags&=~KImageNoCallEntryPoint;
}
/**
This function sets the capcbility of the E32 image as specified in the command line.
@internalComponent
@released
*/
void E32ImageFile::SetCapability()
{
iHdr->iS.iCaps = iUseCase->GetCapability();
}
/**
This function sets the priority of the E32 exe.
@internalComponent
@released
*/
void E32ImageFile::SetPriority(bool isDllp)
{
if (iUseCase->GetPriority())
{
if (isDllp)
{
cerr << "Warning: Cannot set priority of a DLL." << endl;
}
else
iHdr->iProcessPriority = (unsigned short)iUseCase->GetPriority();
}
}
/**
This function sets the fixed address flag of the E32 image .
@internalComponent
@released
*/
void E32ImageFile::SetFixedAddress(bool isDllp)
{
if (iUseCase->GetFixedAddress())
{
if (isDllp)
{
cerr << "Warning: Cannot set fixed address for DLL." << endl;
}
else
iHdr->iFlags|=KImageFixedAddressExe;
}
else
iHdr->iFlags&=~KImageFixedAddressExe;
}
/**
This function sets the version of the E32 image .
@internalComponent
@released
*/
void E32ImageFile::SetVersion()
{
iHdr->iModuleVersion = iUseCase->GetVersion();
}
/**
This function sets the compression type of the E32 image .
@internalComponent
@released
*/
void E32ImageFile::SetCompressionType()
{
if(iUseCase->GetCompress())
iHdr->iCompressionType = iUseCase->GetCompressionMethod();
else
iHdr->iCompressionType = KFormatNotCompressed;
}
/**
This function sets the FPU type that the E32 image targets .
@internalComponent
@released
*/
void E32ImageFile::SetFPU()
{
iHdr->iFlags &=~ KImageHWFloatMask;
if (iUseCase->GetFPU() == 1)
iHdr->iFlags |= KImageHWFloat_VFPv2;
}
/**
This function sets the paging attribute in the E32 image.
@internalComponent
@released
*/
void E32ImageFile::SetPaged()
{
// Code paging.
if ( iUseCase->IsCodePaged() )
{
iHdr->iFlags |= KImageCodePaged;
iHdr->iFlags &= ~KImageCodeUnpaged;
}
else if ( iUseCase->IsCodeUnpaged() )
{
iHdr->iFlags |= KImageCodeUnpaged;
iHdr->iFlags &= ~KImageCodePaged;
}
else if ( iUseCase->IsCodeDefaultPaged() )
{
iHdr->iFlags &= ~KImageCodePaged;
iHdr->iFlags &= ~KImageCodeUnpaged;
}
// Data paging.
if ( iUseCase->IsDataPaged() )
{
iHdr->iFlags |= KImageDataPaged;
iHdr->iFlags &= ~KImageDataUnpaged;
}
else if ( iUseCase->IsDataUnpaged() )
{
iHdr->iFlags |= KImageDataUnpaged;
iHdr->iFlags &= ~KImageDataPaged;
}
else if ( iUseCase->IsDataDefaultPaged() )
{
iHdr->iFlags &= ~KImageDataPaged;
iHdr->iFlags &= ~KImageDataUnpaged;
}
}
/**
This function sets the Debuggable attribute in the E32 image.
@internalComponent
@released
*/
void E32ImageFile::SetDebuggable()
{
if (iUseCase->IsDebuggable() == true)
{
iHdr->iFlags |= KImageDebuggable;
}
else
{
iHdr->iFlags &= ~KImageDebuggable;
}
}
void E32ImageFile::SetSmpSafe()
{
if ( iUseCase->IsSmpSafe() )
{
iHdr->iFlags |= KImageSMPSafe;
}
else
{
iHdr->iFlags &= ~KImageSMPSafe;
}
}
/**
This function sets the named symol-lookup attribute in the E32 image.
@internalComponent
@released
*/
void E32ImageFile::SetSymbolLookup()
{
if(iUseCase->GetNamedSymLookup())
{
iHdr->iFlags |= KImageNmdExpData;
}
else
{
iHdr->iFlags &= ~KImageNmdExpData;
}
}
/**
Class for Uids.
@internalComponent
@released
*/
class TE32ImageUids
{
public:
TE32ImageUids(TUint32 aUid1, TUint32 aUid2, TUint32 aUid3);
void Set(const TUidType& aUidType);
TUint Check() { return ((checkSum(((TUint8*)this)+1)<<16)|checkSum(this));}
private:
TUidType iType;
TUint iCheck;
};
/**
Constructor for TE32ImageUids.
@internalComponent
@released
*/
TE32ImageUids::TE32ImageUids(TUint32 aUid1, TUint32 aUid2, TUint32 aUid3)
{
Set(TUidType(TUid::Uid(aUid1), TUid::Uid(aUid2), TUid::Uid(aUid3)));
}
/**
This function sets the Uid.
@internalComponent
@released
*/
void TE32ImageUids::Set(const TUidType& aUidType)
{
iType=aUidType;
iCheck=Check();
}
/**
Default constructor for TUidType class.
@internalComponent
@released
*/
TUidType::TUidType()
{
memset(this, 0, sizeof(TUidType));
}
/**
Constructor for TUidType class.
@internalComponent
@released
*/
TUidType::TUidType(TUid aUid1,TUid aUid2,TUid aUid3)
{
iUid[0]=aUid1;
iUid[1]=aUid2;
iUid[2]=aUid3;
}
// needed by E32ImageHeaderV::ValidateHeader...
TCheckedUid::TCheckedUid(const TUidType& aUidType)
{
iType = aUidType;
iCheck = ((TE32ImageUids*)this)->Check();
}
// needed by E32ImageHeaderV::ValidateHeader...
void Mem::Crc32(TUint32& aCrc, const TAny* aPtr, TInt aLength)
{
::Crc32(aCrc, aPtr, aLength);
}
/**
This function updates the CRC of the E32 Image.
@internalComponent
@released
*/
void E32ImageFile::UpdateHeaderCrc()
{
TE32ImageUids u(iHdr->iUid1, iHdr->iUid2, iHdr->iUid3);
iHdr->iUidChecksum = u.Check();
TInt hdrsz = GetExtendedE32ImageHeaderSize();
iHdr->iUncompressedSize = iChunks.GetOffset() - Align(GetExtendedE32ImageHeaderSize(), sizeof(uint32));
iHdr->iHeaderCrc = KImageCrcInitialiser;
uint32 crc = 0;
Crc32(crc, iHdr, hdrsz);
iHdr->iHeaderCrc = crc;
}
/**
This function creates a buffer and writes all the data into the buffer.
@internalComponent
@released
*/
void E32ImageFile::AllocateE32Image()
{
size_t aImageSize = iChunks.GetOffset();
iE32Image = new char[aImageSize];
memset(iE32Image, 0, aImageSize);
E32ImageChunks::ChunkList aChunkList = iChunks.GetChunks();
E32ImageChunks::ChunkList::iterator p;
for(p = aChunkList.begin(); p != aChunkList.end(); p++)
{
(*p)->Write(iE32Image);
}
E32ImageHeaderV* header = (E32ImageHeaderV*)iE32Image;
TInt headerSize = header->TotalSize();
if(KErrNone!=header->ValidateWholeImage(iE32Image+headerSize,GetE32ImageSize()-headerSize))
throw InvalidE32ImageError(VALIDATIONERROR, (char*)iUseCase->OutputE32FileName());
}
/**
This function deflates the compressed data.
@param bytes
@param size
@param os
@internalComponent
@released
*/
void DeflateCompress(char* bytes, size_t size, ofstream & os);
/**
This function Paged Pack the compressed data.
@param bytes
@param size
@param os
@internalComponent
@released
*/
void CompressPages(TUint8 * bytes, TInt size, ofstream& os);
/**
This function writes into the final E32 image file.
@param aName - E32 image file name
@internalComponent
@released
*/
bool E32ImageFile::WriteImage(const char * aName)
{
ofstream *os = new ofstream();
os->open(aName, ofstream::binary|ofstream::out);
if (os->is_open())
{
uint32 compression = iHdr->CompressionType();
if (compression == KUidCompressionDeflate)
{
size_t aHeaderSize = GetExtendedE32ImageHeaderSize();
size_t aBodySize = GetE32ImageSize() - aHeaderSize;
os->write(iE32Image, aHeaderSize);
DeflateCompress(iE32Image + aHeaderSize, aBodySize, *os);
}
else if (compression == KUidCompressionBytePair)
{
size_t aHeaderSize = GetExtendedE32ImageHeaderSize();
os->write(iE32Image, aHeaderSize);
// Compress and write out code part
int srcStart = GetExtendedE32ImageHeaderSize();
CompressPages( (TUint8*)iE32Image + srcStart, iHdr->iCodeSize, *os);
// Compress and write out data part
srcStart += iHdr->iCodeSize;
int srcLen = GetE32ImageSize() - srcStart;
CompressPages((TUint8*)iE32Image + srcStart, srcLen, *os);
}
else if (compression == 0)
{
os->write(iE32Image, GetE32ImageSize()); // image not compressed
}
}
else
{
throw FileError(FILEOPENERROR,(char*)aName);
}
os->close();
if(os!=NULL)
{
delete os;
os = NULL;
}
return true;
}
/**
Constructor for E32ImageFile class.
@internalComponent
@released
*/
E32ImageFile::E32ImageFile(): iFileName(NULL), iE32Image(NULL),iExportBitMap(0),cleanupStack(0), iData(NULL),iHdr(NULL),iImportSection(0), iSize(0), iOrigHdr(NULL), iError(0), iSource(EE32Image), iOrigHdrOffsetAdj(0)
{
};
/**
Destructor for E32ImageFile class.
@internalComponent
@released
*/
E32ImageFile::~E32ImageFile()
{
delete[] iData;
if (iHdr && iHdr != iOrigHdr)
delete iHdr;
delete [] iExportBitMap;
delete [] iE32Image;
delete [] iImportSection;
std::vector<char*>::iterator aPos;
char *aPtr;
aPos = cleanupStack.begin();
while( aPos != cleanupStack.end() )
{
aPtr = *aPos;
delete [] aPtr;
aPos++;
}
}
/**
Adjust the size of allocated data and fix the member data
@internalComponent
@released
*/
void E32ImageFile::Adjust(TInt aSize, TBool aAllowShrink)
{
TInt asize = ((aSize+0x3)&0xfffffffc);
if (asize == iSize)
return;
if (iSize == 0)
{
iSize = asize;
iData = new char[iSize];
memset(iData, 0, iSize);
}
else if (aAllowShrink || asize > iSize)
{
TInt oldsize = iSize;
iSize = asize;
iData = (char*)realloc(iData, iSize);
if (iSize > oldsize)
memset(iData+oldsize, 0, iSize-oldsize);
}
if (!iData)
iSize = 0;
if (iHdr && iHdr == iOrigHdr)
iHdr = (E32ImageHeaderV*)iData;
iOrigHdr = (E32ImageHeader*)iData;
}
/**
Read the E32 image.
@param is - input stream
@internalComponent
@released
*/
TInt E32ImageFile::ReadHeader(ifstream& is)
{
Adjust(sizeof(E32ImageHeader), EFalse);
is.read(iData, sizeof(E32ImageHeader));
TInt hdrsz = iOrigHdr->TotalSize();
if (hdrsz > 0x10000)
return KErrCorrupt; // sanity check
if (hdrsz > (TInt)sizeof(E32ImageHeader))
{
Adjust(hdrsz, EFalse);
is.read(iData+sizeof(E32ImageHeader), hdrsz-sizeof(E32ImageHeader));
}
TUint32 uncompressedSize;
TInt r = iOrigHdr->ValidateHeader(iFileSize,uncompressedSize);
if (r != KErrNone)
{
fprintf(stderr, "Integrity check failed %d\n", r);
return r;
}
iHdr = (E32ImageHeaderV*)iOrigHdr;
return KErrNone;
}
/**
Return the offset of the text section
@internalComponent
@released
*/
TUint E32ImageFile::TextOffset()
{
return 0;
}
/**
Return the offset of the data section
@internalComponent
@released
*/
TUint E32ImageFile::DataOffset()
{
return iHdr->iCodeSize;
}
/**
Return the offset of the bss section
@internalComponent
@released
*/
TUint E32ImageFile::BssOffset()
{
return DataOffset()+iHdr->iDataSize;
}
/**
This function creates the bitmap after reading the E32 image file
@internalComponent
@released
*/
void E32ImageFile::E32ImageExportBitMap()
{
TInt nexp = iOrigHdr->iExportDirCount;
TInt memsz = (nexp + 7) >> 3;
iExportBitMap = new TUint8[memsz];
memset(iExportBitMap, 0xff, memsz);
TUint* exports = (TUint*)(iData + iOrigHdr->iExportDirOffset);
TUint absoluteEntryPoint = iOrigHdr->iEntryPoint + iOrigHdr->iCodeBase;
TUint impfmt = iOrigHdr->ImportFormat();
TUint hdrfmt = iOrigHdr->HeaderFormat();
TUint absentVal = (impfmt == KImageImpFmt_ELF) ? absoluteEntryPoint : iOrigHdr->iEntryPoint;
TInt i;
iMissingExports = 0;
for (i=0; i<nexp; ++i)
{
if (exports[i] == absentVal)
{
iExportBitMap[i>>3] &= ~(1u << (i & 7));
++iMissingExports;
}
}
if (hdrfmt < KImageHdrFmt_V && iMissingExports)
{
fprintf(stderr, "Bad exports\n");
exit(999);
}
}
/**
This function creates the export description after reading the E32 image file
@internalComponent
@released
*/
TInt E32ImageFile::CheckExportDescription()
{
TUint hdrfmt = iOrigHdr->HeaderFormat();
if (hdrfmt < KImageHdrFmt_V && iMissingExports)
return KErrCorrupt;
if (iHdr->iExportDescType == KImageHdr_ExpD_NoHoles)
{
return iMissingExports ? KErrCorrupt : KErrNone;
}
TInt nexp = iOrigHdr->iExportDirCount;
TInt memsz = (nexp + 7) >> 3; // size of complete bitmap
TInt mbs = (memsz + 7) >> 3; // size of meta-bitmap
TInt eds = iHdr->iExportDescSize;
if (iHdr->iExportDescType == KImageHdr_ExpD_FullBitmap)
{
if (eds != memsz)
return KErrCorrupt;
if (memcmp(iHdr->iExportDesc, iExportBitMap, eds) == 0)
return KErrNone;
return KErrCorrupt;
}
if (iHdr->iExportDescType != KImageHdr_ExpD_SparseBitmap8)
return KErrNotSupported;
TInt nbytes = 0;
TInt i;
for (i=0; i<memsz; ++i)
if (iExportBitMap[i] != 0xff)
++nbytes; // number of groups of 8
TInt exp_extra = mbs + nbytes;
if (eds != exp_extra)
return KErrCorrupt;
const TUint8* mptr = iHdr->iExportDesc;
const TUint8* gptr = mptr + mbs;
for (i=0; i<memsz; ++i)
{
TUint mbit = mptr[i>>3] & (1u << (i&7));
if (iExportBitMap[i] != 0xff)
{
if (!mbit || *gptr++ != iExportBitMap[i])
return KErrCorrupt;
}
else if (mbit)
return KErrCorrupt;
}
return KErrNone;
}
int DecompressPages(TUint8 * bytes, ifstream& is);
/**
This function creates the E32 image reading from the file
@param is
@param aImage
@internalComponent
@released
*/
ifstream& operator>>(ifstream& is, E32ImageFile& aImage)
{
aImage.iError = aImage.ReadHeader(is);
if (aImage.iError != KErrNone)
return is;
E32ImageHeader* oh = aImage.iOrigHdr;
TInt orighdrsz = oh->TotalSize();
int remainder = aImage.iSize - orighdrsz;
TUint compression = oh->CompressionType();
if (compression == 0)
{
is.read(aImage.iData + orighdrsz, remainder);
}
else if (compression == KUidCompressionDeflate)
{ //Uncompress
aImage.iError = KErrNoMemory;
unsigned int uncompsize = ((E32ImageHeaderComp*)aImage.iOrigHdr)->iUncompressedSize;
aImage.Adjust(uncompsize + orighdrsz);
if (aImage.iData==NULL)
return is;
oh = aImage.iOrigHdr;
unsigned char* compressedData = new unsigned char[remainder];
if (compressedData==NULL)
return is;
is.read(reinterpret_cast<char *>(compressedData), remainder);
unsigned int destsize = uncompsize;
InflateUnCompress( compressedData, remainder, (unsigned char*)(aImage.iData + orighdrsz), destsize);
if (destsize != uncompsize)
MessageHandler::GetInstance()->ReportMessage(WARNING, HUFFMANINCONSISTENTSIZEERROR);
delete [] compressedData;
if ((TUint)orighdrsz > oh->iCodeOffset)
{
// need to adjust code offsets in original
aImage.iOrigHdrOffsetAdj = (TUint)orighdrsz - oh->iCodeOffset;
aImage.OffsetAdjust(oh->iCodeOffset);
aImage.OffsetAdjust(oh->iDataOffset);
aImage.OffsetAdjust(oh->iCodeRelocOffset);
aImage.OffsetAdjust(oh->iDataRelocOffset);
aImage.OffsetAdjust(oh->iImportOffset);
aImage.OffsetAdjust(oh->iExportDirOffset);
}
aImage.iError = KErrNone;
}
else if(compression == KUidCompressionBytePair)
{ // Uncompress
aImage.iError = KErrNoMemory;
unsigned int uncompsize = ((E32ImageHeaderComp*)aImage.iOrigHdr)->iUncompressedSize;
aImage.Adjust(uncompsize + orighdrsz);
if (aImage.iData==NULL)
return is;
oh = aImage.iOrigHdr;
// Read and decompress code part of the image
unsigned int uncompressedCodeSize = DecompressPages((TUint8 *) (aImage.iData + orighdrsz), is);
// Read and decompress data part of the image
unsigned int uncompressedDataSize = DecompressPages((TUint8 *) (aImage.iData + orighdrsz + uncompressedCodeSize), is);
if (uncompressedCodeSize + uncompressedDataSize != uncompsize)
MessageHandler::GetInstance()->ReportMessage(WARNING, BYTEPAIRINCONSISTENTSIZEERROR);
if ((TUint)orighdrsz > oh->iCodeOffset)
{
// need to adjust code offsets in original
aImage.iOrigHdrOffsetAdj = (TUint)orighdrsz - oh->iCodeOffset;
aImage.OffsetAdjust(oh->iCodeOffset);
aImage.OffsetAdjust(oh->iDataOffset);
aImage.OffsetAdjust(oh->iCodeRelocOffset);
aImage.OffsetAdjust(oh->iDataRelocOffset);
aImage.OffsetAdjust(oh->iImportOffset);
aImage.OffsetAdjust(oh->iExportDirOffset);
}
aImage.iError = KErrNone;
}
aImage.E32ImageExportBitMap();
return is;
}
#ifdef __LINUX__
#include <sys/stat.h>
/**
Simple function uses stdlib fstat to obtain the size of the file.
@param aFileName - e32 image file name
@internalComponent
@released
*/
int GetFileSize(const char* aFileName) {
// Open the file the old-fashioned way :-)
struct stat fileInfo;
if(stat(aFileName,&fileInfo)!=0) {
throw FileError(FILEOPENERROR,(char *)aFileName);
}
off_t fileSize = fileInfo.st_size;
return fileSize;
}
#else
int GetFileSize(const char* aFileName) {
_finddata_t fileinfo;
int ret=_findfirst((char *)aFileName,&fileinfo);
if (ret==-1)
{
throw FileError(FILEOPENERROR,(char *)aFileName);
}
return fileinfo.size;
}
#endif
/**
This function opens the e32 image file.
@param aFileName - e32 image file name
@internalComponent
@released
*/
TInt E32ImageFile::Open(const char* aFileName)
{
iFileSize = GetFileSize(aFileName);
Adjust(iFileSize);
ifstream ifile((char *)aFileName, ios::in | ios::binary);
if(!ifile.is_open())
{
throw FileError(FILEOPENERROR,(char *)aFileName);
}
ifile >> *this;
ifile.close();
if (iError != KErrNone)
return iError;
return KErrNone;
}
void E32ImageFile::ProcessSymbolInfo() {
Elf32_Addr aPlace = iUseCase->GetExportTableAddress() - 4;// This location points to 0th ord.
// Create a relocation entry for the 0th ordinal.
ElfLocalRelocation *aRel = new ElfLocalRelocation(iElfExecutable, aPlace, 0, 0, R_ARM_ABS32, \
NULL, ESegmentRO, NULL, false);
aRel->Add();
aPlace += iUseCase->GetExportTableSize();// aPlace now points to the symInfo
uint32 *aZerothOrd = (uint32*)iUseCase->GetExportTable();
*aZerothOrd = aPlace;
aPlace += sizeof(E32EpocExpSymInfoHdr);// aPlace now points to the symbol address
// which is just after the syminfo header.
if(!iElfExecutable->iExports)
return;
// Donot disturb the internal list sorting.
ElfExports::ExportList aList = iElfExecutable->iExports->GetExports(false);
ElfExports::ExportList::iterator aIter = aList.begin();
DllSymbol *aSym;
TUint aAlign, aNameLen;
char aPad[] = {'\0', '\0', '\0', '\0'};
while ( aIter != aList.end() ) {
aSym = *aIter;
iSymAddrTab.push_back(aSym->iElfSym->st_value);
// The symbol names always start at a 4-byte aligned offset.
iSymNameOffset = iSymbolNames.size() >> 2;
iSymNameOffTab.push_back(iSymNameOffset);
iSymbolNames += aSym->SymbolName();
iSymbolNames += '\0';
aNameLen = iSymbolNames.size();
aAlign = Align(aNameLen, sizeof(int));
aAlign = aAlign - aNameLen;
if(aAlign % 4){
iSymbolNames.append(aPad, aAlign);
}
//Create a relocation entry...
aRel = new ElfLocalRelocation(iElfExecutable, aPlace, 0, 0, R_ARM_ABS32, NULL,\
ESegmentRO, aSym->iElfSym, false);
aPlace += sizeof(uint32);
aRel->Add();
aIter++;
}
}
char* E32ImageFile::CreateSymbolInfo(size_t aBaseOffset) {
E32EpocExpSymInfoHdr aSymInf;
uint32 aSizeofNames, aSize;
SetSymInfo(aSymInf);
if( aSymInf.iFlags & 1) {
aSizeofNames = sizeof(uint32);
}
else {
aSizeofNames = sizeof(uint16);
}
aSize = aSymInf.iSize;
char* aInfo = new char[aSize];
memset(aInfo, 0, aSize);
memcpy(aInfo, (void*)&aSymInf, sizeof(aSymInf));
TUint aPos = aSymInf.iSymbolTblOffset;
memcpy(aInfo+aPos, iSymAddrTab.begin(), iSymAddrTab.size()*sizeof(uint32));
aPos += iSymAddrTab.size()*aSizeofNames;
aPos += iSymNameOffTab.size()*aSizeofNames;
aPos = Align(aPos, sizeof(uint32));
std::vector<uint32>::iterator Iter = iSymNameOffTab.begin();
TInt aOffLen = 2;
if(aSymInf.iFlags & 1)
aOffLen=4;
while(Iter != iSymNameOffTab.end()){
memcpy( ((void*)(aInfo+aPos)), ((void*)Iter), aOffLen);
aPos += aOffLen;
Iter++;
}
aPos = aSymInf.iStringTableOffset;
memcpy(aInfo+aPos, iSymbolNames.begin(), iSymbolNames.size());
// At the end, the dependencies are listed. They remain zeroes and shall be fixed up
// while relocating.
// Update the import table to have offsets to ordinal zero entries
uint32 *aLocation, aOffset;
uint32 *aImportTab = iImportSection;
std::vector<int>::iterator aIter = iImportTabLocations.begin();
aOffset = aBaseOffset - iHdr->iCodeOffset;// This gives the offset of syminfo table base
// wrt the code section start
aOffset += aSymInf.iDepDllZeroOrdTableOffset; // This points to the ordinal zero offset table now
while( aIter != iImportTabLocations.end()) {
aLocation = (aImportTab + *aIter);
*aLocation = aOffset;
aOffset += sizeof(uint32);
aIter++;
}
return aInfo;
}
void E32ImageFile::SetSymInfo(E32EpocExpSymInfoHdr& aSymInfo)
{
uint32 aSize = sizeof(E32EpocExpSymInfoHdr);
memset(&aSymInfo, 0, aSize);
uint16 aNSymbols = (uint16) iSymAddrTab.size();
aSymInfo.iSymCount = aNSymbols;
aSymInfo.iSymbolTblOffset = aSize;
aSize += aNSymbols * sizeof(uint32); // Symbol addresses
TUint aNameTabSz = iSymbolNames.size();
TInt aSizeofNames;
if( iSymNameOffset < 0xffff) {
aSizeofNames = sizeof(uint16);
aSymInfo.iFlags &= ~1;//reset the 0th bit
}
else {
aSizeofNames = sizeof(uint32);
aSymInfo.iFlags |= 1;//set the 0th bit
}
aSize += Align((aNSymbols * aSizeofNames), sizeof(uint32)); // Symbol name offsets
aSymInfo.iStringTableOffset = aSize;
aSize += aNameTabSz; // Symbol names in string tab
aSymInfo.iStringTableSz = aNameTabSz;
aSymInfo.iDepDllZeroOrdTableOffset = aSize;
aSymInfo.iDllCount = iNumDlls ;
aSize += iNumDlls * sizeof(uint32); // Dependency list - ordinal zero placeholder
aSymInfo.iSize = aSize;
}