kolibrios-fun/programs/develop/objconv/elf.cpp

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/**************************** elf.cpp *********************************
* Author: Agner Fog
* Date created: 2006-07-18
* Last modified: 2017-10-18
* Project: objconv
* Module: elf.cpp
* Description:
* Module for reading ELF files
*
* Class CELF is used for reading, interpreting and dumping ELF files.
*
* Copyright 2006-2017 GNU General Public License http://www.gnu.org/licenses
*****************************************************************************/
#include "stdafx.h"
// All functions in this module are templated to make two versions: 32 and 64 bits.
// See instantiations at the end of this file.
// File class names
SIntTxt ELFFileClassNames[] = {
{ELFCLASSNONE, "None"},
{ELFCLASS32, "32-bit object"},
{ELFCLASS64, "64-bit object"}
};
// Data encoding names
SIntTxt ELFDataEncodeNames[] = {
{ELFDATANONE, "None"},
{ELFDATA2LSB, "Little Endian"},
{ELFDATA2MSB, "Big Endian"}
};
// ABI names
SIntTxt ELFABINames[] = {
{ELFOSABI_SYSV, "System V"},
{ELFOSABI_HPUX, "HP-UX"},
{ELFOSABI_ARM, "ARM"},
{ELFOSABI_STANDALONE,"Embedded"},
};
// File type names
SIntTxt ELFFileTypeNames[] = {
{ET_NONE, "None"},
{ET_REL, "Relocatable"},
{ET_EXEC, "Executable"},
{ET_DYN, "Shared object"},
{ET_CORE, "Core file"}
};
// Section type names
SIntTxt ELFSectionTypeNames[] = {
{SHT_NULL, "None"},
{SHT_PROGBITS, "Program data"},
{SHT_SYMTAB, "Symbol table"},
{SHT_STRTAB, "String table"},
{SHT_RELA, "Relocation w addends"},
{SHT_HASH, "Symbol hash table"},
{SHT_DYNAMIC, "Dynamic linking info"},
{SHT_NOTE, "Notes"},
{SHT_NOBITS, "bss"},
{SHT_REL, "Relocation entries"},
{SHT_SHLIB, "Reserved"},
{SHT_DYNSYM, "Dynamic linker symbol table"},
{SHT_INIT_ARRAY, "Array of constructors"},
{SHT_FINI_ARRAY, "Array of destructors"},
{SHT_PREINIT_ARRAY, "Array of pre-constructors"},
{SHT_GROUP, "Section group"},
{SHT_SYMTAB_SHNDX, "Extended section indices"}
};
// Section flag names
SIntTxt ELFSectionFlagNames[] = {
{SHF_WRITE, "Writeable"},
{SHF_ALLOC, "Allocate"},
{SHF_EXECINSTR, "Executable"},
{SHF_MERGE, "Merge"},
{SHF_STRINGS, "Strings"},
{SHF_INFO_LINK, "sh_info"},
{SHF_LINK_ORDER, "Preserve order"},
{SHF_OS_NONCONFORMING,"OS specific"}
};
// Symbol binding names
SIntTxt ELFSymbolBindingNames[] = {
{STB_LOCAL, "Local"},
{STB_GLOBAL, "Global"},
{STB_WEAK, "Weak"}
};
// Symbol Type names
SIntTxt ELFSymbolTypeNames[] = {
{STT_NOTYPE, "None"},
{STT_OBJECT, "Object"},
{STT_FUNC, "Function"},
{STT_SECTION, "Section"},
{STT_FILE, "File"},
{STT_COMMON, "Common"},
{STT_GNU_IFUNC, "Indirect function/dispatcher"}
};
// Relocation type names x86 32 bit
SIntTxt ELF32RelocationNames[] = {
{R_386_NONE, "None"},
{R_386_32, "Absolute 32 bit"},
{R_386_PC32, "Self-relative 32 bit"},
{R_386_GOT32, "32 bit GOT entry"},
{R_386_PLT32, "32 bit PLT address"},
{R_386_COPY, "Copy symbol at runtime"},
{R_386_GLOB_DAT, "Create GOT entry"},
{R_386_JMP_SLOT, "Create PLT entry"},
{R_386_RELATIVE, "Adjust by image base"},
{R_386_GOTOFF, "32 bit offset to GOT"},
{R_386_GOTPC, "32 bit PC relative offset to GOT"},
{R_386_IRELATIVE, "32 bit ref. to indirect function PLT"}
};
// Relocation type names x86 64 bit
SIntTxt ELF64RelocationNames[] = {
{R_X86_64_NONE, "None"},
{R_X86_64_64, "Direct 64 bit"},
{R_X86_64_PC32, "Self relative 32 bit signed"},
{R_X86_64_GOT32, "32 bit GOT entry"},
{R_X86_64_PLT32, "32 bit PLT address"},
{R_X86_64_COPY, "Copy symbol at runtime"},
{R_X86_64_GLOB_DAT, "Create GOT entry"},
{R_X86_64_JUMP_SLOT, "Create PLT entry"},
{R_X86_64_RELATIVE, "Adjust by program base"},
{R_X86_64_GOTPCREL, "32 bit signed pc relative offset to GOT"},
{R_X86_64_32, "Direct 32 bit zero extended"},
{R_X86_64_32S, "Direct 32 bit sign extended"},
{R_X86_64_16, "Direct 16 bit zero extended"},
{R_X86_64_PC16, "16 bit sign extended pc relative"},
{R_X86_64_8, "Direct 8 bit sign extended"},
{R_X86_64_PC8, "8 bit sign extended pc relative"},
{R_X86_64_IRELATIVE, "32 bit ref. to indirect function PLT"}
};
// Machine names
SIntTxt ELFMachineNames[] = {
{EM_NONE, "None"}, // No machine
{EM_M32, "AT&T WE 32100"},
{EM_SPARC, "SPARC"},
{EM_386, "Intel x86"},
{EM_68K, "Motorola m68k"},
{EM_88K, "Motorola m88k"},
{EM_860, "MIPS R3000 big-endian"},
{EM_MIPS, "MIPS R3000 big-endian"},
{EM_S370, "IBM System/370"},
{EM_MIPS_RS3_LE, "NMIPS R3000 little-endianone"},
{EM_PARISC, "HPPA"},
{EM_VPP500, "Fujitsu VPP500"},
{EM_SPARC32PLUS, "Sun v8plus"},
{EM_960, "Intel 80960"},
{EM_PPC, "PowerPC"},
{EM_PPC64, "PowerPC 64-bit"},
{EM_S390, "IBM S390"},
{EM_V800, "NEC V800"},
{EM_FR20, "Fujitsu FR20"},
{EM_RH32, "TRW RH-32"},
{EM_RCE, "Motorola RCE"},
{EM_ARM, "ARM"},
{EM_FAKE_ALPHA, "Digital Alpha"},
{EM_SH, "Hitachi SH"},
{EM_SPARCV9, "SPARC v9 64-bit"},
{EM_TRICORE, "Siemens Tricore"},
{EM_ARC, "Argonaut RISC"},
{EM_H8_300, "Hitachi H8/300"},
{EM_H8_300H, "Hitachi H8/300H"},
{EM_H8S, "Hitachi H8S"},
{EM_H8_500, "EM_H8_500"},
{EM_IA_64, "Intel IA64"},
{EM_MIPS_X, "Stanford MIPS-X"},
{EM_COLDFIRE, "Motorola Coldfire"},
{EM_68HC12, "Motorola M68HC12"},
{EM_MMA, "Fujitsu MMA"},
{EM_PCP, "Siemens PCP"},
{EM_NCPU, "Sony nCPU"},
{EM_NDR1, "Denso NDR1"},
{EM_STARCORE, "Motorola Start*Core"},
{EM_ME16, "Toyota ME16"},
{EM_ST100, "ST100"},
{EM_TINYJ, "Tinyj"},
{EM_X86_64, "x86-64"},
{EM_PDSP, "Sony DSP"},
{EM_FX66, "Siemens FX66"},
{EM_ST9PLUS, "ST9+ 8/16"},
{EM_ST7, "ST7 8"},
{EM_68HC16, "MC68HC16"},
{EM_68HC11, "MC68HC11"},
{EM_68HC08, "MC68HC08"},
{EM_68HC05, "MC68HC05"},
{EM_SVX, "SVx"},
{EM_AT19, "ST19"},
{EM_VAX, "VAX"},
{EM_CRIS, "Axis"},
{EM_JAVELIN, "Infineon"},
{EM_FIREPATH, "Element 14"},
{EM_ZSP, "LSI Logic"},
{EM_HUANY, "Harvard"},
{EM_PRISM, "SiTera Prism"},
{EM_AVR, "Atmel AVR"},
{EM_FR30, "FR30"},
{EM_D10V, "D10V"},
{EM_D30V, "D30V"},
{EM_V850, "NEC v850"},
{EM_M32R, "M32R"},
{EM_MN10300, "MN10300"},
{EM_MN10200, "MN10200"},
{EM_PJ, "picoJava"},
{EM_ALPHA, "Alpha"}
};
// Program header type names
SIntTxt ELFPTypeNames[] = {
{PT_NULL, "Unused"},
{PT_LOAD, "Loadable program segment"},
{PT_DYNAMIC, "Dynamic linking information"},
{PT_INTERP, "Program interpreter"},
{PT_NOTE, "Auxiliary information"},
{PT_SHLIB, "Reserved"},
{PT_PHDR, "Entry for header table itself"}
};
// Class CELF members:
// Constructor
template <class TELF_Header, class TELF_SectionHeader, class TELF_Symbol, class TELF_Relocation>
CELF<ELFSTRUCTURES>::CELF() {
memset(this, 0, sizeof(*this));
}
// ParseFile
template <class TELF_Header, class TELF_SectionHeader, class TELF_Symbol, class TELF_Relocation>
void CELF<ELFSTRUCTURES>::ParseFile(){
// Load and parse file buffer
uint32 i;
FileHeader = *(TELF_Header*)Buf(); // Copy file header
NSections = FileHeader.e_shnum;
SectionHeaders.SetNum(NSections); // Allocate space for section headers
SectionHeaders.SetZero();
uint32 Symtabi = 0; // Index to symbol table
// check header integrity
if (FileHeader.e_phoff > GetDataSize() || FileHeader.e_phoff + FileHeader.e_phentsize > GetDataSize()) err.submit(2035);
if (FileHeader.e_shoff > GetDataSize() || FileHeader.e_shoff + FileHeader.e_shentsize > GetDataSize()) err.submit(2035);
// Find section headers
SectionHeaderSize = FileHeader.e_shentsize;
if (SectionHeaderSize <= 0) err.submit(2033);
uint32 SectionOffset = uint32(FileHeader.e_shoff);
for (i = 0; i < NSections; i++) {
SectionHeaders[i] = Get<TELF_SectionHeader>(SectionOffset);
// check section header integrity
if (SectionHeaders[i].sh_type != SHT_NOBITS && (SectionHeaders[i].sh_offset > GetDataSize()
|| SectionHeaders[i].sh_offset + SectionHeaders[i].sh_size > GetDataSize()
|| SectionHeaders[i].sh_offset + SectionHeaders[i].sh_entsize > GetDataSize())) {
err.submit(2035);
}
SectionOffset += SectionHeaderSize;
if (SectionHeaders[i].sh_type == SHT_SYMTAB) {
// Symbol table found
Symtabi = i;
}
}
// if (Buf() && GetNumEntries()) {
if (Buf() && GetDataSize()) {
SecStringTable = Buf() + uint32(SectionHeaders[FileHeader.e_shstrndx].sh_offset);
SecStringTableLen = uint32(SectionHeaders[FileHeader.e_shstrndx].sh_size);
}
if (SectionOffset > GetDataSize()) {
err.submit(2110); // Section table points to outside file
}
if (Symtabi) {
// Save offset to symbol table
SymbolTableOffset = (uint32)(SectionHeaders[Symtabi].sh_offset);
SymbolTableEntrySize = (uint32)(SectionHeaders[Symtabi].sh_entsize); // Entry size of symbol table
if (SymbolTableEntrySize == 0) {err.submit(2034); return;} // Avoid division by zero
SymbolTableEntries = uint32(SectionHeaders[Symtabi].sh_size) / SymbolTableEntrySize;
// Find associated string table
uint32 Stringtabi = SectionHeaders[Symtabi].sh_link;
if (Stringtabi < NSections) {
SymbolStringTableOffset = (uint32)(SectionHeaders[Stringtabi].sh_offset);
SymbolStringTableSize = (uint32)(SectionHeaders[Stringtabi].sh_size);
}
else {
Symtabi = 0; // Error
}
}
}
// Dump
template <class TELF_Header, class TELF_SectionHeader, class TELF_Symbol, class TELF_Relocation>
void CELF<ELFSTRUCTURES>::Dump(int options) {
uint32 i;
if (options & DUMP_FILEHDR) {
// File header
printf("\nDump of ELF file %s", FileName);
printf("\n-----------------------------------------------");
printf("\nFile size: %i", GetDataSize());
printf("\nFile header:");
printf("\nFile class: %s, Data encoding: %s, ELF version %i, ABI: %s, ABI version %i",
Lookup(ELFFileClassNames, FileHeader.e_ident[EI_CLASS]),
Lookup(ELFDataEncodeNames, FileHeader.e_ident[EI_DATA]),
FileHeader.e_ident[EI_VERSION],
Lookup(ELFABINames, FileHeader.e_ident[EI_OSABI]),
FileHeader.e_ident[EI_ABIVERSION]);
printf("\nFile type: %s, Machine: %s, version: %i",
Lookup(ELFFileTypeNames, FileHeader.e_type),
Lookup(ELFMachineNames, FileHeader.e_machine),
FileHeader.e_version);
printf("\nNumber of sections: %2i, Processor flags: 0x%X",
NSections, FileHeader.e_flags);
}
if ((options & DUMP_SECTHDR) && FileHeader.e_phnum) {
// Dump program headers
uint32 nProgramHeaders = FileHeader.e_phnum;
uint32 programHeaderSize = FileHeader.e_phentsize;
if (programHeaderSize <= 0) err.submit(2033);
uint32 programHeaderOffset = (uint32)FileHeader.e_phoff;
Elf64_Phdr pHeader;
for (i = 0; i < nProgramHeaders; i++) {
if (WordSize == 32) {
Elf32_Phdr pHeader32 = Get<Elf32_Phdr>(programHeaderOffset);
pHeader.p_type = pHeader32.p_type;
pHeader.p_offset = pHeader32.p_offset;
pHeader.p_vaddr = pHeader32.p_vaddr;
pHeader.p_paddr = pHeader32.p_paddr;
pHeader.p_filesz = pHeader32.p_filesz;
pHeader.p_memsz = pHeader32.p_memsz;
pHeader.p_flags = pHeader32.p_flags;
pHeader.p_align = pHeader32.p_align;
}
else {
pHeader = Get<Elf64_Phdr>(programHeaderOffset);
}
printf("\nProgram header Type: %s, flags 0x%X",
Lookup(ELFPTypeNames, (uint32)pHeader.p_type), (uint32)pHeader.p_flags);
printf("\noffset = 0x%X, vaddr = 0x%X, paddr = 0x%X, filesize = 0x%X, memsize = 0x%X, align = 0x%X",
(uint32)pHeader.p_offset, (uint32)pHeader.p_vaddr, (uint32)pHeader.p_paddr, (uint32)pHeader.p_filesz, (uint32)pHeader.p_memsz, (uint32)pHeader.p_align);
programHeaderOffset += programHeaderSize;
if (pHeader.p_filesz < 0x100 && (int32)pHeader.p_offset < GetDataSize() && memchr(Buf()+pHeader.p_offset, 0, (uint32)pHeader.p_filesz)) {
printf("\nContents: %s", Buf()+(int32)pHeader.p_offset);
}
}
}
if (options & DUMP_SECTHDR) {
// Dump section headers
printf("\n\nSection headers:");
for (uint32 sc = 0; sc < NSections; sc++) {
// Get copy of 32-bit header or converted 64-bit header
TELF_SectionHeader sheader = SectionHeaders[sc];
uint32 entrysize = (uint32)(sheader.sh_entsize);
uint32 namei = sheader.sh_name;
if (namei >= SecStringTableLen) {err.submit(2112); break;}
printf("\n%2i Name: %-18s Type: %s", sc, SecStringTable + namei,
Lookup(ELFSectionTypeNames, sheader.sh_type));
if (sheader.sh_flags) {
printf("\n Flags: 0x%X:", uint32(sheader.sh_flags));
for (int fi = 1; fi < (1 << 30); fi <<= 1) {
if (uint32(sheader.sh_flags) & fi) {
printf(" %s", Lookup(ELFSectionFlagNames,fi));
}
}
}
if (sheader.sh_addr) {
printf("\n Address: 0x%X", uint32(sheader.sh_addr));
}
if (sheader.sh_offset || sheader.sh_size) {
printf("\n FileOffset: 0x%X, Size: 0x%X",
uint32(sheader.sh_offset), uint32(sheader.sh_size));
}
if (sheader.sh_addralign) {
printf("\n Alignment: 0x%X", uint32(sheader.sh_addralign));
}
if (sheader.sh_entsize) {
printf("\n Entry size: 0x%X", uint32(sheader.sh_entsize));
switch (sheader.sh_type) {
case SHT_DYNAMIC:
printf("\n String table: %i", sheader.sh_link);
break;
case SHT_HASH:
printf("\n Symbol table: %i", sheader.sh_link);
break;
case SHT_REL: case SHT_RELA:
printf("\n Symbol table: %i, Reloc. section: %i",
sheader.sh_link, sheader.sh_info);
break;
case SHT_SYMTAB: case SHT_DYNSYM:
printf("\n Symbol string table: %i, First global symbol: %i",
sheader.sh_link, sheader.sh_info);
break;
default:
if (sheader.sh_link) {
printf("\n Link: %i", sheader.sh_link);
}
if (sheader.sh_info) {
printf("\n Info: %i", sheader.sh_info);
}
}
}
if (sheader.sh_type == SHT_STRTAB && (options & DUMP_STRINGTB)) {
// Print string table
printf("\n String table:");
char * p = Buf() + uint32(sheader.sh_offset) + 1;
uint32 nread = 1, len;
while (nread < uint32(sheader.sh_size)) {
len = (uint32)strlen(p);
printf(" >>%s<<", p);
nread += len + 1;
p += len + 1;
}
}
if ((sheader.sh_type==SHT_SYMTAB || sheader.sh_type==SHT_DYNSYM) && (options & DUMP_SYMTAB)) {
// Dump symbol table
// Find associated string table
if (sheader.sh_link >= (uint32)NSections) {err.submit(2035); sheader.sh_link = 0;}
int8 * strtab = Buf() + uint32(SectionHeaders[sheader.sh_link].sh_offset);
// Find symbol table
uint32 symtabsize = (uint32)(sheader.sh_size);
int8 * symtab = Buf() + uint32(sheader.sh_offset);
int8 * symtabend = symtab + symtabsize;
if (entrysize < sizeof(TELF_Symbol)) {err.submit(2033); entrysize = sizeof(TELF_Symbol);}
printf("\n Symbols:");
// Loop through symbol table
int symi; // Symbol number
for (symi = 0; symtab < symtabend; symtab += entrysize, symi++) {
// Copy 32 bit symbol table entry or convert 64 bit entry
TELF_Symbol sym = *(TELF_Symbol*)symtab;
int type = sym.st_type;
int binding = sym.st_bind;
if (*(strtab + sym.st_name)) {
printf("\n %2i Name: %s,", symi, strtab + sym.st_name);}
else {
printf("\n %2i Unnamed,", symi);}
if (sym.st_value || type == STT_OBJECT || type == STT_FUNC || type == STT_GNU_IFUNC || int16(sym.st_shndx) < 0)
printf(" Value: 0x%X", uint32(sym.st_value));
if (sym.st_size) printf(" Size: %i", uint32(sym.st_size));
if (sym.st_other) printf(" Other: 0x%X", sym.st_other);
if (int16(sym.st_shndx) >= 0) printf(" Section: %i", sym.st_shndx);
else { // Special segment values
switch (int16(sym.st_shndx)) {
case SHN_ABS:
printf(" Absolute,"); break;
case SHN_COMMON:
printf(" Common,"); break;
case SHN_XINDEX:
printf(" Index in extra table,"); break;
default:
printf(" Section: 0x%X", sym.st_shndx);
}
}
if (sym.st_type || sym.st_bind) {
printf(" Type: %s, Binding: %s",
Lookup(ELFSymbolTypeNames, type),
Lookup(ELFSymbolBindingNames, binding));
}
}
}
if ((sheader.sh_type==SHT_REL || sheader.sh_type==SHT_RELA ) && (options & DUMP_RELTAB)) {
printf("\n Relocations:");
int8 * reltab = Buf() + uint32(sheader.sh_offset);
int8 * reltabend = reltab + uint32(sheader.sh_size);
uint32 expectedentrysize = sheader.sh_type == SHT_RELA ?
sizeof(TELF_Relocation) : // Elf32_Rela, Elf64_Rela
sizeof(TELF_Relocation) - WordSize/8; // Elf32_Rel, Elf64_Rel
if (entrysize < expectedentrysize) {err.submit(2033); entrysize = expectedentrysize;}
// Loop through entries
for (; reltab < reltabend; reltab += entrysize) {
// Copy relocation table entry with or without addend
TELF_Relocation rel; rel.r_addend = 0;
memcpy(&rel, reltab, entrysize);
printf ("\n Offset: 0x%X, Symbol: %i, Name: %s\n Type: %s",
uint32(rel.r_offset), rel.r_sym, SymbolName(rel.r_sym),
(WordSize == 32) ?
Lookup (ELF32RelocationNames, rel.r_type) :
Lookup (ELF64RelocationNames, rel.r_type));
if (rel.r_addend) printf (", Addend: 0x%X", uint32(rel.r_addend));
// Find inline addend
TELF_SectionHeader relsheader = SectionHeaders[sheader.sh_info];
uint32 relsoffset = uint32(relsheader.sh_offset);
if (relsoffset+rel.r_offset < GetDataSize()) {
int32 * piaddend = (int32*)(Buf()+relsoffset+rel.r_offset);
if (* piaddend) printf (", Inline addend: 0x%X", * piaddend);
}
}
}
}
}
}
// PublicNames
template <class TELF_Header, class TELF_SectionHeader, class TELF_Symbol, class TELF_Relocation>
void CELF<ELFSTRUCTURES>::PublicNames(CMemoryBuffer * Strings, CSList<SStringEntry> * Index, int m) {
// Make list of public names
// Interpret header:
ParseFile();
// Loop through section headers
for (uint32 sc = 0; sc < NSections; sc++) {
// Get copy of 32-bit header or converted 64-bit header
TELF_SectionHeader sheader = SectionHeaders[sc];
uint32 entrysize = uint32(sheader.sh_entsize);
if (sheader.sh_type==SHT_SYMTAB || sheader.sh_type==SHT_DYNSYM) {
// Dump symbol table
// Find associated string table
if (sheader.sh_link >= (uint32)NSections) {err.submit(2035); sheader.sh_link = 0;}
int8 * strtab = Buf() + uint32(SectionHeaders[sheader.sh_link].sh_offset);
// Find symbol table
uint32 symtabsize = uint32(sheader.sh_size);
int8 * symtab = Buf() + uint32(sheader.sh_offset);
int8 * symtabend = symtab + symtabsize;
if (entrysize < sizeof(TELF_Symbol)) {err.submit(2033); entrysize = sizeof(TELF_Symbol);}
// Loop through symbol table
for (int symi = 0; symtab < symtabend; symtab += entrysize, symi++) {
// Copy 32 bit symbol table entry or convert 64 bit entry
TELF_Symbol sym = *(TELF_Symbol*)symtab;
int type = sym.st_type;
int binding = sym.st_bind;
if (int16(sym.st_shndx) > 0
&& type != STT_SECTION && type != STT_FILE
&& (binding == STB_GLOBAL || binding == STB_WEAK)) {
// Public symbol found
SStringEntry se;
se.Member = m;
// Store name
se.String = Strings->PushString(strtab + sym.st_name);
// Store name index
Index->Push(se);
}
}
}
}
}
// SymbolName
template <class TELF_Header, class TELF_SectionHeader, class TELF_Symbol, class TELF_Relocation>
const char * CELF<ELFSTRUCTURES>::SymbolName(uint32 index) {
// Get name of symbol. (ParseFile() must be called first)
const char * symname = "?"; // Symbol name
uint32 symi; // Symbol index
uint32 stri; // String index
if (SymbolTableOffset) {
symi = SymbolTableOffset + index * SymbolTableEntrySize;
if (symi < GetDataSize()) {
stri = Get<TELF_Symbol>(symi).st_name;
if (stri < SymbolStringTableSize) {
symname = Buf() + SymbolStringTableOffset + stri;
}
}
}
return symname;
}
// Make template instances for 32 and 64 bits
template class CELF<ELF32STRUCTURES>;
template class CELF<ELF64STRUCTURES>;