release note: SF Bug 2007 - [Raptor] GCCE 4.4.1 builds require 4.3.1 and 4.3.2 SBS_GCCE???BIN env vars etc.
// 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 the Class ElfExecutable for the elf2e32 tool
// @internalComponent
// @released
//
//
#include "pl_elfexecutable.h"
#include "errorhandler.h"
#include <stdio.h>
#include "parameterlistinterface.h"
#include "pl_elfimportrelocation.h"
#include "pl_dllsymbol.h"
#include "messagehandler.h"
#include "pl_elflocalrelocation.h"
/**
Constructor for class ElfExecutable
@param aParameterListInterface - Instance of class ParameterListInterface
@internalComponent
@released
*/
ElfExecutable::ElfExecutable(ParameterListInterface *aParameterListInterface) :\
iElfHeader(NULL), \
iEntryPoint(0),\
iProgHeader(NULL), \
iSONameOffset(0) ,\
iSections (NULL) , \
iVersionDef (NULL) , iVerDefCount(0), \
iVersionNeed (NULL) , iVerNeedCount(0), \
iVersionTbl (NULL) ,iRelSize(0),iRelEntSize(0), \
iNRelocs(0),
iRel (NULL) ,iRelaSize(0), iRelaEntSize(0), \
iRela(NULL),
iStringTable (NULL) , \
iSectionHdrStrTbl(NULL), \
iVerInfo(NULL), iElfDynSym (NULL), \
iSymTab (NULL), \
iStrTab (NULL), \
iLim (NULL), \
iNSymbols(0), \
iHashTbl (NULL) , \
iDynSegmentHdr (NULL) , \
iDataSegmentHdr (NULL) ,iDataSegment(NULL), iDataSegmentSize(0), iDataSegmentIdx(0), \
iCodeSegmentHdr (NULL) , iCodeSegment(NULL), iCodeSegmentSize(0), iCodeSegmentIdx(0), \
iExports (NULL), \
iParameterListInterface(aParameterListInterface),\
iPltGotBase(0), iPltGotLimit(0), iStrTabSz(0), iSymEntSz(0), \
iPltGot(NULL), iPltRel(NULL),iPltRelaSz(0), iPltRela(NULL), iPltRelSz(0) \
{
}
/**
Destructor for class ElfExecutable
@internalComponent
@released
*/
ElfExecutable::~ElfExecutable()
{
delete iExports;
delete [] iVerInfo;
/*
all of these were getting deleted, they are not allocated by
ElfExecutable, they simply refer to a linear array of images
in an ElfImage, hence they shouldn't be de-allocated
delete iRela;
delete iPltRel;
delete iPltRela; */
iNeeded.clear();
iSymbolTable.clear();
}
/**
Function to process Elf file
@param aElfHdr - pointer to Elf header
@return 0 if its valid ELF file
@internalComponent
@released
*/
PLUINT32 ElfExecutable::ProcessElfFile(Elf32_Ehdr *aElfHdr) {
iElfHeader = aElfHdr;
iEntryPoint = aElfHdr->e_entry;
ValidateElfFile();
/* A valid ELF file so far..*/
/* Get the Section base..*/
if(iElfHeader->e_shnum) {
iSections = ELF_ENTRY_PTR(Elf32_Shdr, iElfHeader, iElfHeader->e_shoff);
}
/* Get the program header..*/
if(iElfHeader->e_phnum) {
iProgHeader = ELF_ENTRY_PTR(Elf32_Phdr, iElfHeader, iElfHeader->e_phoff);
}
/* Get the section-header-string table..*/
if(iElfHeader->e_shstrndx != SHN_UNDEF) {
if(iElfHeader->e_shstrndx > iElfHeader->e_shnum ) {
throw ELFFormatError(ELFSHSTRINDEXERROR,iParameterListInterface->ElfInput());
}
iSectionHdrStrTbl = ELF_ENTRY_PTR(char, iElfHeader, iSections[iElfHeader->e_shstrndx].sh_offset);
}
if( iProgHeader ) {
PLUINT32 aIdx = 0;
while( aIdx < iElfHeader->e_phnum) {
switch( iProgHeader[aIdx].p_type ) {
case PT_DYNAMIC:
{
iDynSegmentHdr = &iProgHeader[aIdx];
}
break;
case PT_LOAD:
{
if( (iProgHeader[aIdx].p_flags) & (PF_X | PF_ARM_ENTRY) ) {
iCodeSegmentHdr = &iProgHeader[aIdx];
iCodeSegmentIdx = aIdx;
iCodeSegment = ELF_ENTRY_PTR(char, iElfHeader, iCodeSegmentHdr->p_offset);
iCodeSegmentSize = iCodeSegmentHdr->p_filesz;
}
else if( (iProgHeader[aIdx].p_flags) & (PF_W | PF_R) ) {
iDataSegmentHdr = &iProgHeader[aIdx];
iDataSegmentIdx = aIdx;
iDataSegment = ELF_ENTRY_PTR(char, iElfHeader, iDataSegmentHdr->p_offset);
iDataSegmentSize = iDataSegmentHdr->p_filesz;
}
}
break;
default:
break;
}
aIdx++;
}
if( iDynSegmentHdr ) {
ProcessDynamicEntries();
}
ProcessSymbols();
ProcessRelocations();
}
return 0;
}
/**
Function to Find the Static Symbol Table
@internalComponent
@released
*/
void ElfExecutable::FindStaticSymbolTable()
{
size_t nShdrs = iElfHeader->e_shnum;
if (nShdrs)
{
// Find the static symbol table and string table
for (PLUINT32 i = 0; i < nShdrs; i++)
{
if (iSections[i].sh_type == SHT_SYMTAB)
{
iSymTab = ELF_ENTRY_PTR(Elf32_Sym, iElfHeader, iSections[i].sh_offset);
iLim = ELF_ENTRY_PTR(Elf32_Sym, iSymTab, iSections[i].sh_size);
if (iStrTab) break;
}
else if (iSections[i].sh_type == SHT_STRTAB)
{
char * aSectionName = iSectionHdrStrTbl + iSections[i].sh_name;
if (!strcmp(aSectionName, ".strtab"))
{
iStrTab = ELF_ENTRY_PTR(char, iElfHeader, iSections[i].sh_offset);
if (iSymTab) break;
}
}
}
}
}
/**
Function to Find the Comment Section
@return aComment - Pointer to Comment Section
@internalComponent
@released
*/
char* ElfExecutable::FindCommentSection()
{
size_t nShdrs = iElfHeader->e_shnum;
char *aCommentSection = ".comment";
char *aComment;
if (nShdrs)
{
// find the comment section
for (PLUINT32 i = 0; i < nShdrs; i++)
{
if (iSections[i].sh_type == SHT_PROGBITS)
{
char * aSectionName = iSectionHdrStrTbl + iSections[i].sh_name;
int length = strlen(aCommentSection);
if (!strncmp(aSectionName, aCommentSection, length))
{
aComment = ELF_ENTRY_PTR(char, iElfHeader, iSections[i].sh_offset);
return aComment;
}
}
}
}
return NULL;
}
/**
Function to process the ARM to Thumb veneers
@internalComponent
@released
*/
void ElfExecutable::ProcessVeneers()
{
if (iSymTab && iStrTab)
{
ElfRelocations::RelocationList & iLocalCodeRelocs = GetCodeRelocations();
Elf32_Sym *aSymTab = iSymTab;
int length = strlen("$Ven$AT$L$$");
// Process the symbol table to find Long ARM to Thumb Veneers
// i.e. symbols of the form '$Ven$AT$L$$'
for(; aSymTab < iLim; aSymTab++)
{
if (!aSymTab->st_name) continue;
char * aSymName = iStrTab + aSymTab->st_name;
Elf32_Sym *aSym;
if (!strncmp(aSymName, "$Ven$AT$L$$", length))
{
aSym = aSymTab;
Elf32_Addr r_offset = aSym->st_value;
Elf32_Addr aOffset = r_offset + 4;
Elf32_Word aInstruction = FindValueAtLoc(r_offset);
bool aRelocEntryFound = false;
ElfRelocations::RelocationList::iterator r;
for (r = iLocalCodeRelocs.begin(); r != iLocalCodeRelocs.end(); r++)
{
ElfLocalRelocation * aReloc = *r;
// Check if there is a relocation entry for the veneer symbol
if (aReloc->iAddr == aOffset)
{
aRelocEntryFound = true;
break;
}
}
Elf32_Word aPointer = FindValueAtLoc(aOffset);
/* If the symbol addresses a Thumb instruction, its value is the
* address of the instruction with bit zero set (in a
* relocatable object, the section offset with bit zero set).
* This allows a linker to distinguish ARM and Thumb code symbols
* without having to refer to the map. An ARM symbol will always have
* an even value, while a Thumb symbol will always have an odd value.
* Reference: Section 4.5.3 in Elf for the ARM Architecture Doc
* aIsThumbSymbol will be 1 for a thumb symbol and 0 for ARM symbol
*/
int aIsThumbSymbol = aPointer & 0x1;
/* The relocation entry should be generated for the veneer only if
* the following three conditions are satisfied:
* 1) Check if the instruction at the symbol is as expected
* i.e. has the bit pattern 0xe51ff004 == 'LDR pc,[pc,#-4]'
* 2) There is no relocation entry generated for the veneer symbol
* 3) The instruction in the location provided by the pointer is a thumb symbol
*/
if (aInstruction == 0xE51FF004 && !aRelocEntryFound && aIsThumbSymbol)
{
ElfLocalRelocation *aRel;
PLUCHAR aType = R_ARM_NONE;
aRel = new ElfLocalRelocation(this, aOffset, 0, 0, aType, NULL, ESegmentRO, aSym, false, true);
if(aRel)
{
aRel->Add();
}
}
}
}
}
}
/**
Function to find the content of the address passed in
@param aOffset - Address
@return aLocVal - The content of the address, like instruction or a pointer
@internalComponent
@released
*/
Elf32_Word ElfExecutable::FindValueAtLoc(Elf32_Addr aOffset)
{
Elf32_Phdr *aHdr = Segment(aOffset);
PLUINT32 aLoc = aHdr->p_offset + aOffset - aHdr->p_vaddr;
Elf32_Word *aLocVal = ELF_ENTRY_PTR(Elf32_Word, iElfHeader, aLoc);
return *aLocVal;
}
/**
Function to process Elf symbols
@internalComponent
@released
*/
PLUINT32 ElfExecutable::ProcessSymbols(){
PLUINT32 aSymIdx = 0;
DllSymbol *aSymbol;
char *aDllName;
char *aSymName, *aNewSymName;
SymbolType aType;
while( aSymIdx < iNSymbols ) {
aSymName = ELF_ENTRY_PTR(char, iStringTable, iElfDynSym[aSymIdx].st_name );
if( ExportedSymbol( &iElfDynSym[aSymIdx] ) ){
if( FunctionSymbol( &iElfDynSym[aSymIdx] ))
aType = SymbolTypeCode;
else
aType = SymbolTypeData;
aSymName = ELF_ENTRY_PTR(char, iStringTable, iElfDynSym[aSymIdx].st_name );
aDllName = iVerInfo[iVersionTbl[aSymIdx]].iLinkAs;
aNewSymName = new char[strlen(aSymName)+1];
strcpy(aNewSymName, aSymName);
aSymbol = new DllSymbol( aNewSymName, aType, &iElfDynSym[aSymIdx], aSymIdx);
aSymbol->SetSymbolSize(iElfDynSym[aSymIdx].st_size);
//Putting the symbols into a hash table - Used later while processing relocations
iSymbolTable[aSymIdx] = aSymbol ;
if( !AddToExports( aDllName, aSymbol ))
{
//Not a valid export... delete it..
delete aSymbol;
}
}
else if( ImportedSymbol( &iElfDynSym[aSymIdx] ) ){
if( FunctionSymbol( &iElfDynSym[aSymIdx] ))
aType = SymbolTypeCode;
else
aType = SymbolTypeData;
aSymName = ELF_ENTRY_PTR(char, iStringTable, iElfDynSym[aSymIdx].st_name );
/*
* All imported symbols must be informed via the version needed information.
*/
if( iVerInfo[iVersionTbl[aSymIdx]].iVerCategory != VER_CAT_NEEDED ) {
throw UndefinedSymbolError(UNDEFINEDSYMBOLERROR, iParameterListInterface->ElfInput(), aSymName);
}
aDllName = iVerInfo[iVersionTbl[aSymIdx]].iLinkAs;
//aSymbol = new DllSymbol( aSymName, aType, &iElfDynSym[aSymIdx], aSymIdx);
//Putting the symbols into a hash table
//iSymbolTable[aSymIdx] = aSymbol ;
}
aSymIdx++;
}
return 0;
}
/**
This function Dump all the sections with their section details (i.e., the section name, type,
size and linked section if any)
@param aFile - ELF file name
@internalComponent
@released
*/
void ElfExecutable::DumpElfFile(char* aFile){
aFile = aFile;
}
/**
This function adds exports into the export list
@param aDll - Dll name
@param aSymbol - Symbol
@return
@internalComponent
@released
*/
DllSymbol* ElfExecutable::AddToExports(char* aDll, DllSymbol* aSymbol){
if( !iExports ) {
iExports = new ElfExports();
}
return iExports->Add( aDll, this, aSymbol );
}
/**
This function adds imports into the map
@param aReloc - Instance of class ElfImportRelocation
@internalComponent
@released
*/
void ElfExecutable::AddToImports(ElfImportRelocation* aReloc){
SetVersionRecord(aReloc);
//char *aDll = iVerInfo[iVersionTbl[aReloc->iSymNdx]].iLinkAs;
char *aDll = aReloc->iVerRecord->iLinkAs;
iImports.Add( (const char*)aDll, aReloc );
}
/**
This function adds local relocation into a list
@param aReloc - Instance of class ElfImportRelocation
@internalComponent
@released
*/
void ElfExecutable::AddToLocalRelocations(ElfRelocation* aReloc) {
iLocalRelocations.Add((ElfLocalRelocation*)aReloc);
}
/**
This function records the version of an imported symbol
@param aReloc - Instance of class ElfImportRelocation
@internalComponent
@released
*/
void ElfExecutable::SetVersionRecord( ElfRelocation* aReloc ) {
if( !aReloc )
return;
((ElfImportRelocation*)aReloc)->iVerRecord = &iVerInfo[ iVersionTbl[aReloc->iSymNdx]];
}
/**
This function validates the ELF file
@internalComponent
@released
*/
PLUINT32 ElfExecutable::ValidateElfFile() {
/*Check if the ELF-Magic is correct*/
if(!(iElfHeader->e_ident[EI_MAG0] == ELFMAG0) &&
(iElfHeader->e_ident[EI_MAG1] == ELFMAG1) &&
(iElfHeader->e_ident[EI_MAG2] == ELFMAG2) &&
(iElfHeader->e_ident[EI_MAG3] == ELFMAG3) ) {
throw ELFFormatError(ELFMAGICERROR, iParameterListInterface->ElfInput());
}
/*32-bit ELF file*/
if(iElfHeader->e_ident[EI_CLASS] != ELFCLASS32) {
throw ELFFormatError(ELFCLASSERROR, iParameterListInterface->ElfInput());
}
/* Check if the ELF file is in Little endian format*/
if(iElfHeader->e_ident[EI_DATA] != ELFDATA2LSB) {
throw ELFFormatError(ELFLEERROR, iParameterListInterface->ElfInput());
}
/* The ELF executable must be a DLL or an EXE*/
if( iElfHeader->e_type != ET_EXEC && iElfHeader->e_type != ET_DYN) {
throw ELFFormatError(ELFEXECUTABLEERROR, iParameterListInterface->ElfInput());
}
return 0;
}
/**
This function processes the dynamic table.
@internalComponent
@released
*/
PLUINT32 ElfExecutable::ProcessDynamicEntries(){
PLUINT32 aIdx = 0;
bool aSONameFound = false;
bool aPltRelTypeSeen = false, aJmpRelSeen = false;
list<PLUINT32> aNeeded;
Elf32_Dyn *aDyn = ELF_ENTRY_PTR(Elf32_Dyn, iElfHeader, iDynSegmentHdr->p_offset);
while( aDyn[aIdx].d_tag != DT_NULL ) {
switch (aDyn[aIdx].d_tag) {
case DT_NEEDED:
aNeeded.push_back( aDyn[aIdx].d_val );
break;
case DT_HASH:
iHashTbl = ELF_ENTRY_PTR(Elf32_HashTable, iElfHeader, aDyn[aIdx].d_val);
break;
case DT_STRTAB:
iStringTable = ELF_ENTRY_PTR(char, iElfHeader, aDyn[aIdx].d_val);
break;
case DT_SYMTAB:
iElfDynSym = ELF_ENTRY_PTR(Elf32_Sym, iElfHeader, aDyn[aIdx].d_val);
break;
case DT_RELA:
iRela = ELF_ENTRY_PTR(Elf32_Rela, iElfHeader, aDyn[aIdx].d_val);
break;
case DT_RELASZ:
iRelaSize = aDyn[aIdx].d_val;
break;
case DT_RELAENT:
iRelaEntSize = aDyn[aIdx].d_val;
break;
case DT_SONAME:
aSONameFound = true;
iSONameOffset = aDyn[aIdx].d_val;
break;
case DT_REL:
iRel = ELF_ENTRY_PTR(Elf32_Rel, iElfHeader, aDyn[aIdx].d_val);
break;
case DT_RELSZ:
iRelSize = aDyn[aIdx].d_val;
break;
case DT_RELENT:
iRelEntSize = aDyn[aIdx].d_val;
break;
case DT_VERSYM:
iVersionTbl = ELF_ENTRY_PTR(Elf32_Half, iElfHeader, aDyn[aIdx].d_val);
break;
case DT_VERDEF:
iVersionDef = ELF_ENTRY_PTR(Elf32_Verdef, iElfHeader, aDyn[aIdx].d_val);
break;
case DT_VERDEFNUM:
iVerDefCount = aDyn[aIdx].d_val;
break;
case DT_VERNEED:
iVersionNeed = ELF_ENTRY_PTR(Elf32_Verneed, iElfHeader, aDyn[aIdx].d_val);
break;
case DT_VERNEEDNUM:
iVerNeedCount = aDyn[aIdx].d_val;
break;
case DT_STRSZ:
iStrTabSz = aDyn[aIdx].d_val;
break;
case DT_SYMENT:
iSymEntSz = aDyn[aIdx].d_val;
break;
case DT_PLTRELSZ:
iPltRelSz = aDyn[aIdx].d_val;
break;
case DT_PLTGOT:
iPltGot = ELF_ENTRY_PTR(Elf32_Word, iElfHeader, aDyn[aIdx].d_val);
break;
case DT_RPATH:
break;
case DT_SYMBOLIC:
break;
case DT_INIT:
break;
case DT_FINI:
break;
case DT_PLTREL:
aPltRelTypeSeen = true;
iPltRelType = aDyn[aIdx].d_val;
break;
case DT_DEBUG:
break;
case DT_TEXTREL:
break;
case DT_JMPREL:
aJmpRelSeen = true;
iJmpRelOffset = aDyn[aIdx].d_val;
break;
case DT_BIND_NOW:
break;
case DT_INIT_ARRAY:
break;
case DT_FINI_ARRAY:
break;
case DT_INIT_ARRAYSZ:
break;
case DT_FINI_ARRAYSZ:
break;
case DT_RELCOUNT:
break;
case DT_ARM_PLTGOTBASE:
iPltGotBase = aDyn[aIdx].d_val;
break;
case DT_ARM_PLTGOTLIMIT:
iPltGotLimit = aDyn[aIdx].d_val;
break;
case DT_ARM_SYMTABSZ:
iNSymbols = aDyn[aIdx].d_val;
break;
default:
//cout << "Unknown entry in dynamic table Tag=0x%x Value=0x%x",aDyn[aIdx].d_tag, aDyn[aIdx].d_val);
break;
}
aIdx++;
}
//String table is found, so get the strings...
if(aSONameFound) {
iSOName = ELF_ENTRY_PTR(char, iStringTable, iSONameOffset);
}
std::list<PLUINT32>::iterator aItr = aNeeded.begin();
char *aStr;
for( ; aItr != aNeeded.end();aItr++ ) {
aStr = ELF_ENTRY_PTR(char, iStringTable, *aItr);
iNeeded.push_back( aStr );
}
if(iVerNeedCount || iVerDefCount) {
ProcessVerInfo();
}
if(iHashTbl)
{
//The number of symbols should be same as the number of chains in hashtable
if (iNSymbols && (iNSymbols != iHashTbl->nChains))
throw ELFFormatError(SYMBOLCOUNTMISMATCHERROR,(char*)iParameterListInterface->ElfInput());
else
//The number of symbols is same as the number of chains in hashtable
iNSymbols = iHashTbl->nChains;
}
if( aPltRelTypeSeen && aJmpRelSeen) {
if (iPltRelType == DT_REL)
{
iPltRel = ELF_ENTRY_PTR(Elf32_Rel, iElfHeader, iJmpRelOffset);
// check to see if PltRels are included in iRel. If they are
// ignore them since we don't care about the distinction
if (iRel <= iPltRel && iPltRel < ELF_ENTRY_PTR(Elf32_Rel, iRel, iRelSize))
iPltRel = 0;
}
else
{
iPltRela = ELF_ENTRY_PTR(Elf32_Rela, iElfHeader, iJmpRelOffset);
// check to see if PltRels are included in iRel. If they are
// ignore them since we don't care about the distinction
if (iRela <= iPltRela && iPltRela < ELF_ENTRY_PTR(Elf32_Rela, iRela, iRelaSize))
iPltRela = 0;
}
}
return 0;
}
/**
This function processes version information
@internalComponent
@released
*/
void ElfExecutable::ProcessVerInfo() {
PLUINT32 aSz = iVerNeedCount + iVerDefCount + 1;
iVerInfo = new VersionInfo[aSz];
Elf32_Verdef *aDef;
Elf32_Verdaux *aDaux;
Elf32_Verneed *aNeed;
Elf32_Vernaux *aNaux;
char *aSoName;
char *aLinkAs;
aDef = iVersionDef;
while( aDef ) {
aDaux = ELF_ENTRY_PTR( Elf32_Verdaux, aDef, aDef->vd_aux);
aLinkAs = ELF_ENTRY_PTR(char, iStringTable, aDaux->vda_name );
aSoName = iSOName;
iVerInfo[aDef->vd_ndx].iLinkAs = aLinkAs;
iVerInfo[aDef->vd_ndx].iSOName = aSoName;
iVerInfo[aDef->vd_ndx].iVerCategory = VER_CAT_DEFINED;
if( !aDef->vd_next ) {
break;
}
aDef = ELF_ENTRY_PTR(Elf32_Verdef, aDef, aDef->vd_next);
}
aNeed = iVersionNeed;
while( aNeed ) {
aNaux = ELF_ENTRY_PTR(Elf32_Vernaux, aNeed, aNeed->vn_aux);
aLinkAs = ELF_ENTRY_PTR(char, iStringTable, aNaux->vna_name);
aSoName = ELF_ENTRY_PTR(char, iStringTable, aNeed->vn_file);
iVerInfo[aNaux->vna_other].iLinkAs = aLinkAs;
iVerInfo[aNaux->vna_other].iSOName = aSoName;
iVerInfo[aNaux->vna_other].iVerCategory = VER_CAT_NEEDED;
if( !aNeed->vn_next ) {
break;
}
aNeed = ELF_ENTRY_PTR(Elf32_Verneed, aNeed, aNeed->vn_next);
}
}
/**
This function processes Elf relocations
@internalComponent
@released
*/
void ElfExecutable::ProcessRelocations(){
ProcessRelocations(iRel, iRelSize);
ProcessRelocations(iRela, iRelaSize);
ProcessRelocations(iPltRel, iPltRelSz);
ProcessRelocations(iPltRela, iPltRelaSz);
}
/**
Template Function to process relocations
@param aElfRel - relocation table
@param aSize - relocation table size
@internalComponent
@released
*/
template <class T>
void ElfExecutable::ProcessRelocations(T *aElfRel, size_t aSize){
if( !aElfRel )
return;
T * aElfRelLimit = ELF_ENTRY_PTR(T, aElfRel, aSize);
PLUINT32 aSymIdx;
PLUCHAR aType;
ElfRelocation *aRel;
bool aImported;
Elf32_Word aAddend;
while( aElfRel < aElfRelLimit) {
aType = ELF32_R_TYPE(aElfRel->r_info );
if(ElfRelocation::ValidRelocEntry(aType)) {
aSymIdx = ELF32_R_SYM(aElfRel->r_info);
aImported = ImportedSymbol( &iElfDynSym[aSymIdx] );
aAddend = Addend(aElfRel);
aRel = ElfRelocation::NewRelocEntry(this, aElfRel->r_offset, aAddend, \
aSymIdx, aType, aElfRel, aImported);
if(aRel) {
aRel->Add();
}
}
aElfRel++;
}
}
/**
This function finds the addend associated with a relocation entry.
@param aRel - relocation entry
@return location in the elf image
@internalComponent
@released
*/
Elf32_Word ElfExecutable::Addend(Elf32_Rel* aRel) {
PLUINT32 aOffset;
Elf32_Word *aAddendPlace;
Elf32_Phdr *aHdr = Segment(aRel->r_offset);
aOffset = aHdr->p_offset + aRel->r_offset - aHdr->p_vaddr;
aAddendPlace = ELF_ENTRY_PTR(Elf32_Word, iElfHeader, aOffset);
return *aAddendPlace;
}
/**
This function returns the addend for a relocation entry
@param aRel - relocation entry
@return location in the elf image
@internalComponent
@released
*/
Elf32_Word ElfExecutable::Addend(Elf32_Rela* aRel) {
return aRel->r_addend;
}
/**
This function gets the version info at an index
@param aIndex - index into the version table
@return version record
@internalComponent
@released
*/
VersionInfo* ElfExecutable::GetVersionInfo(PLUINT32 aIndex){
return &iVerInfo[ iVersionTbl[aIndex]];
}
/**
This function returns the Dll name in which an imported symbol is
defined by looking in the version required section.
@param aSymbolIndex - Index of symbol
@return Dll name
@internalComponent
@released
*/
char* ElfExecutable::SymbolDefinedInDll(PLUINT32 aSymbolIndex){
VersionInfo *aVInfo = GetVersionInfo(aSymbolIndex);
return aVInfo ? aVInfo->iLinkAs : NULL;
}
/**
This function returns the DSO(import library) name where the Symbol information can be found.
This DSO is then looked up for the ordinal number of this symbol.
@param aSymbolIndex - Index of symbol
@return DSO name
@internalComponent
@released
*/
char* ElfExecutable::SymbolFromDSO(PLUINT32 aSymbolIndex){
VersionInfo *aVInfo = GetVersionInfo(aSymbolIndex);
return aVInfo ? aVInfo->iSOName : NULL;
}
/**
This function returns the segment type
@param aAddr - Address
@return Segment type
@internalComponent
@released
*/
ESegmentType ElfExecutable::SegmentType(Elf32_Addr aAddr) {
try {
Elf32_Phdr *aHdr = Segment(aAddr);
if( !aHdr )
return ESegmentUndefined;
if( aHdr == iCodeSegmentHdr)
return ESegmentRO;
else if(aHdr == iDataSegmentHdr)
return ESegmentRW;
else
return ESegmentUndefined;
}
catch(...)
{
}
return ESegmentUndefined;
}
/**
This function returns the segment type
@param aType
@return Segment header
@internalComponent
@released
*/
Elf32_Phdr* ElfExecutable::Segment(ESegmentType aType) {
switch(aType)
{
case ESegmentRO:
return iCodeSegmentHdr;
case ESegmentRW:
return iDataSegmentHdr;
default:
return NULL;
}
}
/**
Function to get segment header
@param aAddr - Address
@return Segment header
@internalComponent
@released
*/
Elf32_Phdr* ElfExecutable::Segment(Elf32_Addr aAddr) {
if(iCodeSegmentHdr) {
PLUINT32 aBase = iCodeSegmentHdr->p_vaddr;
if( aBase <= aAddr && aAddr < (aBase + iCodeSegmentHdr->p_memsz) ) {
return iCodeSegmentHdr;
}
}
if(iDataSegmentHdr) {
PLUINT32 aBase = iDataSegmentHdr->p_vaddr;
if( aBase <= aAddr && aAddr < (aBase + iDataSegmentHdr->p_memsz) ) {
return iDataSegmentHdr;
}
}
throw int(0);
}
/**
Thsi function returns the segment header to which the address refers.
@param aAddr - location
@return Segment header.
@internalComponent
@released
*/
Elf32_Phdr* ElfExecutable::SegmentFromAbs(Elf32_Addr aAddr) {
if(iCodeSegmentHdr) {
PLUINT32 aBase = iCodeSegmentHdr->p_vaddr;
if( aBase <= aAddr && aAddr <= (aBase + iCodeSegmentHdr->p_memsz) ) {
return iCodeSegmentHdr;
}
}
if(iDataSegmentHdr) {
PLUINT32 aBase = iDataSegmentHdr->p_vaddr;
if( aBase <= aAddr && aAddr <= (aBase + iDataSegmentHdr->p_memsz) ) {
return iDataSegmentHdr;
}
}
return NULL;
}
/**
This function says if the symbol is global.
@param aSym - Symbol
@return True if symbol is global, otherwise false
@internalComponent
@released
*/
bool ElfExecutable::GlobalSymbol(Elf32_Sym* aSym)
{
return (ELF32_ST_BIND(aSym->st_info) == STB_GLOBAL);
}
/**
This function says if the symbol is exported.
@param aSym - Symbol
@return True if symbol is exported, otherwise false
@internalComponent
@released
*/
bool ElfExecutable::ExportedSymbol(Elf32_Sym* aSym)
{
PLUINT32 aIdx = aSym->st_shndx;
if(GlobalSymbol(aSym) && VisibleSymbol(aSym) && DefinedSymbol(aSym) && \
(aIdx != SHN_UNDEF) && (FunctionSymbol(aSym) || DataSymbol(aSym) ) && aIdx < SHN_ABS )
return true;
return false;
}
/**
This function says if the symbol is imported.
@param aSym - Symbol
@return True if symbol is imported, otherwise false
@internalComponent
@released
*/
bool ElfExecutable::ImportedSymbol(Elf32_Sym* aSym)
{
PLUINT32 aIdx = aSym->st_shndx;
if( (aIdx == SHN_UNDEF) && GlobalSymbol(aSym) && VisibleSymbol(aSym) && (!DefinedSymbol(aSym)) )
return true;
return false;
}
/**
This function says if the symbol refers to code or data.
@param aSym - Symbol
@return True if symbol refers to code, otherwise false
@internalComponent
@released
*/
bool ElfExecutable::FunctionSymbol(Elf32_Sym* aSym)
{
return (STT_FUNC == ELF32_ST_TYPE(aSym->st_info));
}
/**
This function says if the symbol refers to code or data.
@param aSym - Symbol
@return True if symbol refers to data, otherwise false
@internalComponent
@released
*/
bool ElfExecutable::DataSymbol(Elf32_Sym* aSym)
{
return (STT_OBJECT == ELF32_ST_TYPE(aSym->st_info));
}
/**
This function says if the symbol is defined in the Elf executable.
@param aSym - Symbol
@return True if symbol is defined, otherwise false
@internalComponent
@released
*/
bool ElfExecutable::DefinedSymbol(Elf32_Sym* aSym)
{
if( aSym->st_shndx == SHN_UNDEF )
return false;
ESegmentType aType = SegmentType(aSym->st_value);
return ((aType == ESegmentRO) || (aType == ESegmentRW));
}
/**
This function says if the visibility of the symbol is default.
@param aSym - Symbol
@return True if symbol has default visibility, otherwise false
@internalComponent
@released
*/
bool ElfExecutable::VisibleSymbol(Elf32_Sym* aSym)
{
return (STV_DEFAULT == ELF32_ST_VISIBILITY(aSym->st_other) || STV_PROTECTED == ELF32_ST_VISIBILITY(aSym->st_other));
}
/**
This function finds symbol using the hash table
@param aName - Symbol name
@return elf symbol.
@internalComponent
@released
*/
Elf32_Sym* ElfExecutable::FindSymbol(char* aName) {
if(!aName )
return NULL;
PLULONG aHashVal = Util::elf_hash((const PLUCHAR*) aName );
Elf32_Sword* aBuckets = ELF_ENTRY_PTR(Elf32_Sword, iHashTbl, sizeof(Elf32_HashTable) );
Elf32_Sword* aChains = ELF_ENTRY_PTR(Elf32_Sword, aBuckets, sizeof(Elf32_Sword)*(iHashTbl->nBuckets) );
Elf32_Sword aIdx = aHashVal % iHashTbl->nBuckets;
aIdx = aBuckets[aIdx];
char *aSymName;
do {
aSymName = ELF_ENTRY_PTR(char, iStringTable, iElfDynSym[aIdx].st_name);
if( !strcmp(aSymName, aName) ) {
return &iElfDynSym[aIdx];
}
aIdx = aChains[aIdx];
}while( aIdx > 0 );
return NULL;
}
/**
Function to get symbol name
@param aSymIdx - Index of symbol
@return Symbol name
@internalComponent
@released
*/
char* ElfExecutable::GetSymbolName( PLUINT32 aSymIdx) {
return ELF_ENTRY_PTR(char, iStringTable, iElfDynSym[aSymIdx].st_name);
}
/**
Function to get symbol ordinal
@param aSymName - Symbol name
@return Symbol ordinal
@internalComponent
@released
*/
PLUINT32 ElfExecutable::GetSymbolOrdinal( char* aSymName) {
Elf32_Sym *aSym = FindSymbol(aSymName);
if( !aSym )
return (PLUINT32)-1;
return GetSymbolOrdinal( aSym );
}
/**
Function to get symbol ordinal
@param aSym - Symbol
@return Symbol ordinal
@internalComponent
@released
*/
PLUINT32 ElfExecutable::GetSymbolOrdinal( Elf32_Sym* aSym) {
PLUINT32 aOrd = (PLUINT32)-1;
if( aSym->st_shndx == ESegmentRO) {
Elf32_Word *aLocation, aOffset;
aOffset = iCodeSegmentHdr->p_offset + aSym->st_value - iCodeSegmentHdr->p_vaddr;
aLocation = ELF_ENTRY_PTR(Elf32_Word, iElfHeader, aOffset);
aOrd = *aLocation;
}
return aOrd;
}
/**
Function to get relocation offset
@param aReloc - Instance of class ElfRelocation
@return offset
@internalComponent
@released
*/
Elf32_Word ElfExecutable::GetRelocationOffset(ElfRelocation * aReloc)
{
Elf32_Phdr * aHdr = Segment(aReloc->iAddr);
unsigned int aOffset = aReloc->iAddr - aHdr->p_vaddr;
return aOffset;
}
/**
Function to get relocation place address
@param aReloc - Instance of class ElfRelocation
@return address to place relocation
@internalComponent
@released
*/
Elf32_Word * ElfExecutable::GetRelocationPlace(ElfRelocation * aReloc)
{
Elf32_Phdr * aHdr = Segment(aReloc->iAddr);
unsigned int aOffset = aHdr->p_offset + aReloc->iAddr - aHdr->p_vaddr;
Elf32_Word * aPlace = ELF_ENTRY_PTR(Elf32_Word, iElfHeader, aOffset);
return aPlace;
}
/**
Function to get local relocation
@return local relocation
@internalComponent
@released
*/
ElfRelocations& ElfExecutable::GetLocalRelocations()
{
return iLocalRelocations;
}
/**
Function to get code relocation
@return code relocation list
@internalComponent
@released
*/
ElfRelocations::RelocationList & ElfExecutable::GetCodeRelocations()
{
return GetLocalRelocations().GetCodeRelocations();
}
/**
Function to get data relocation
@return data relocation list
@internalComponent
@released
*/
ElfRelocations::RelocationList & ElfExecutable::GetDataRelocations()
{
return GetLocalRelocations().GetDataRelocations();
}
/**
Function to get RO base address
@return RO base virtual address
@internalComponent
@released
*/
Elf32_Word ElfExecutable::GetROBase()
{
if (iCodeSegmentHdr) return iCodeSegmentHdr->p_vaddr;
return 0;
}
/**
Function to get RO segment
@return code segment
@internalComponent
@released
*/
MemAddr ElfExecutable::GetRawROSegment()
{
return iCodeSegment;
}
/**
Function to get RW segment virtual address
@return RW base address
@internalComponent
@released
*/
Elf32_Word ElfExecutable::GetRWBase()
{
if (iDataSegmentHdr) return iDataSegmentHdr->p_vaddr;
return 0;
}
/**
Function to get Raw RW segment
@return data segment address
@internalComponent
@released
*/
MemAddr ElfExecutable::GetRawRWSegment()
{
return iDataSegment;
}
/**
Function to get RO segment size
@return code segment size
@internalComponent
@released
*/
size_t ElfExecutable::GetROSize()
{
return iCodeSegmentHdr->p_filesz;
}
/**
Function to get RW segment size
@return data segment size
@internalComponent
@released
*/
size_t ElfExecutable::GetRWSize()
{
if (iDataSegmentHdr)
return iDataSegmentHdr->p_filesz;;
return 0;
}
/**
Function to get Bss segment size
@return Bss segment size, if data segment, otherwise 0
@internalComponent
@released
*/
size_t ElfExecutable::GetBssSize()
{
if (iDataSegmentHdr)
return iDataSegmentHdr->p_memsz - iDataSegmentHdr->p_filesz;
return 0;
}
/**
Function returns entry point location in Elf image.
@return entry point offset if valid, warning if undefined, otherwise throw error
@internalComponent
@released
*/
Elf32_Word ElfExecutable::EntryPointOffset()
{
if (!(iElfHeader->e_entry) && !(iCodeSegmentHdr->p_vaddr))
{
MessageHandler::GetInstance()->ReportMessage(WARNING, UNDEFINEDENTRYPOINTERROR,(char*)iParameterListInterface->ElfInput());
return 0;
}
else if (!(iElfHeader->e_entry))
throw ELFFormatError(ENTRYPOINTNOTSETERROR, (char*)iParameterListInterface->ElfInput());
else
return iElfHeader->e_entry - iCodeSegmentHdr->p_vaddr;
}
/**
Function to check exception is present in the Elf image.
@return True if exception present, otherwise false
@internalComponent
@released
*/
bool ElfExecutable::ExeceptionsPresentP()
{
size_t nShdrs = iElfHeader->e_shnum;
if (nShdrs)
{
// Find the exception index table section
Elf32_Shdr * aShdr = ELF_ENTRY_PTR(Elf32_Shdr, iElfHeader, iElfHeader->e_shoff);
char * aShStrTab = ELF_ENTRY_PTR(char, iElfHeader, aShdr[iElfHeader->e_shstrndx].sh_offset);
for (PLUINT32 i = 0; i < nShdrs; i++)
{
if (aShdr[i].sh_type == SHT_ARM_EXIDX)
{
char * aSectionName = aShStrTab + aShdr[i].sh_name;
if (!strcmp(aSectionName, ".ARM.exidx"))
{
return true;
}
}
}
}
else
throw ELFFileError(NEEDSECTIONVIEWERROR, (char*)iParameterListInterface->ElfInput());
return false;
}
/**
Function to get the exports in ordinal number order.
@return ordered exports
@internalComponent
@released
*/
ElfExports::ExportList &ElfExecutable::GetExportsInOrdinalOrder() {
return iExports->GetExportsInOrdinalOrder();
}
/**
This function looks up for a symbol in the static symbol table.
@return Elf symbol.
@internalComponent
@released
*/
Elf32_Sym * ElfExecutable::LookupStaticSymbol(char * aName) {
size_t nShdrs = iElfHeader->e_shnum;
if (nShdrs)
{
// find the static symbol table and string table
Elf32_Shdr * aShdr = ELF_ENTRY_PTR(Elf32_Shdr, iElfHeader, iElfHeader->e_shoff);
char * aShStrTab = ELF_ENTRY_PTR(char, iElfHeader, aShdr[iElfHeader->e_shstrndx].sh_offset);
Elf32_Sym * aSymTab = 0;
Elf32_Sym * aLim = 0;
char * aStrTab = 0;
for (PLUINT32 i = 0; i < nShdrs; i++)
{
if (aShdr[i].sh_type == SHT_SYMTAB)
{
aSymTab = ELF_ENTRY_PTR(Elf32_Sym, iElfHeader, aShdr[i].sh_offset);
aLim = ELF_ENTRY_PTR(Elf32_Sym, aSymTab, aShdr[i].sh_size);
if (aStrTab) break;
}
else if (aShdr[i].sh_type == SHT_STRTAB)
{
char * aSectionName = aShStrTab + aShdr[i].sh_name;
if (!strcmp(aSectionName, ".strtab"))
{
aStrTab = ELF_ENTRY_PTR(char, iElfHeader, aShdr[i].sh_offset);
if (aSymTab) break;
}
}
}
/*if(aHashTbl && aSymTab && aStrTab)
{
PLULONG aHashVal = Util::elf_hash((const PLUCHAR*)aName);
Elf32_Sword* aBuckets = ELF_ENTRY_PTR(Elf32_Sword, aHashTbl, sizeof(Elf32_HashTable) );
Elf32_Sword* aChains = ELF_ENTRY_PTR(Elf32_Sword, aBuckets, sizeof(Elf32_Sword)*(aHashTbl->nBuckets) );
PLUINT32 aIdx = aHashVal % aHashTbl->nBuckets;
aIdx = aBuckets[aIdx];
char *aSymName;
do {
aSymName = ELF_ENTRY_PTR(char, aStrTab, aSymTab[aIdx].st_name);
if( !strcmp(aSymName, aName) ) {
return &aSymTab[aIdx];
}
aIdx = aChains[aIdx];
}while( aIdx > 0 );
return NULL;
}
else */
if (aSymTab && aStrTab)
{
for(; aSymTab < aLim; aSymTab++)
{
if (!aSymTab->st_name) continue;
char * aSymName = aStrTab + aSymTab->st_name;
if (!strcmp(aSymName, aName))
return aSymTab;
}
return 0;
}
else
{
throw ELFFileError(NOSTATICSYMBOLSERROR, (char*)iParameterListInterface->ElfInput());
}
}
else
{
throw ELFFileError(NOSTATICSYMBOLSERROR, (char*)iParameterListInterface->ElfInput());
}
}
/**
Function to get imports
@return imports
@internalComponent
@released
*/
ElfImports::ImportMap ElfExecutable::GetImports() {
return iImports.GetImports();
}
/**
Function to get exports
@return exports
@internalComponent
@released
*/
ElfExports* ElfExecutable::GetExports() {
return iExports;
}
/**
Function to get fixup location
@param aReloc - Instance of class ElfLocalRelocation
@param aPlace -
@return addres of position for relocation
@internalComponent
@released
*/
Elf32_Word* ElfExecutable::GetFixupLocation(ElfLocalRelocation* aReloc, Elf32_Addr aPlace)
{
Elf32_Phdr * aPhdr = aReloc->ExportTableReloc() ?
iCodeSegmentHdr :
Segment(aPlace);
Elf32_Word offset = aPhdr->p_offset + aPlace - aPhdr->p_vaddr;
return ELF_ENTRY_PTR(Elf32_Word, iElfHeader, offset);
}
/**
Function to get the segment type
@param aSym - Symbol
@return Segment type
@internalComponent
@released
*/
ESegmentType ElfExecutable::Segment(Elf32_Sym *aSym)
{
Elf32_Phdr * aHdr;
try {
bool limitSymbolFound = false;
// If Symbol is absolute then assume it came from linker and is a
// limit symbol.
if (aSym->st_shndx == SHN_ABS)
{
aHdr = SegmentFromAbs(aSym->st_value);
}
else
{
if( (iCodeSegmentHdr && aSym->st_value == (iCodeSegmentHdr->p_vaddr + iCodeSegmentHdr->p_memsz)) ||
(iDataSegmentHdr && aSym->st_value == (iDataSegmentHdr->p_vaddr + iDataSegmentHdr->p_memsz)) )
{
//If Symbol is a $$Limit symbol, then consider the open boundary.
String limitstr = iStringTable + aSym->st_name;
if (limitstr.rfind("$$Limit",limitstr.length()) != String::npos)
{
aHdr = SegmentFromAbs(aSym->st_value);
limitSymbolFound = true;
}
}
if(!limitSymbolFound )
{
aHdr = Segment(aSym->st_value);
}
}
if (aHdr == iCodeSegmentHdr)
{
return ESegmentRO;
}
else if (aHdr == iDataSegmentHdr)
{
return ESegmentRW;
}
}
catch(...)
{
}
return ESegmentUndefined;
}