llvm/lib/Object/COFFObjectFile.cpp
Rafael Espindola 5954faae4d Return ErrorOr from getSymbolAddress.
It can fail trying to get the section on ELF and COFF. This makes sure the
error is handled.

git-svn-id: https://llvm.org/svn/llvm-project/llvm/trunk@241366 91177308-0d34-0410-b5e6-96231b3b80d8
2015-07-03 18:19:00 +00:00

1427 lines
48 KiB
C++

//===- COFFObjectFile.cpp - COFF object file implementation -----*- C++ -*-===//
//
// The LLVM Compiler Infrastructure
//
// This file is distributed under the University of Illinois Open Source
// License. See LICENSE.TXT for details.
//
//===----------------------------------------------------------------------===//
//
// This file declares the COFFObjectFile class.
//
//===----------------------------------------------------------------------===//
#include "llvm/Object/COFF.h"
#include "llvm/ADT/ArrayRef.h"
#include "llvm/ADT/SmallString.h"
#include "llvm/ADT/StringSwitch.h"
#include "llvm/ADT/Triple.h"
#include "llvm/ADT/iterator_range.h"
#include "llvm/Support/COFF.h"
#include "llvm/Support/Debug.h"
#include "llvm/Support/raw_ostream.h"
#include <cctype>
#include <limits>
using namespace llvm;
using namespace object;
using support::ulittle16_t;
using support::ulittle32_t;
using support::ulittle64_t;
using support::little16_t;
// Returns false if size is greater than the buffer size. And sets ec.
static bool checkSize(MemoryBufferRef M, std::error_code &EC, uint64_t Size) {
if (M.getBufferSize() < Size) {
EC = object_error::unexpected_eof;
return false;
}
return true;
}
static std::error_code checkOffset(MemoryBufferRef M, uintptr_t Addr,
const uint64_t Size) {
if (Addr + Size < Addr || Addr + Size < Size ||
Addr + Size > uintptr_t(M.getBufferEnd()) ||
Addr < uintptr_t(M.getBufferStart())) {
return object_error::unexpected_eof;
}
return std::error_code();
}
// Sets Obj unless any bytes in [addr, addr + size) fall outsize of m.
// Returns unexpected_eof if error.
template <typename T>
static std::error_code getObject(const T *&Obj, MemoryBufferRef M,
const void *Ptr,
const uint64_t Size = sizeof(T)) {
uintptr_t Addr = uintptr_t(Ptr);
if (std::error_code EC = checkOffset(M, Addr, Size))
return EC;
Obj = reinterpret_cast<const T *>(Addr);
return std::error_code();
}
// Decode a string table entry in base 64 (//AAAAAA). Expects \arg Str without
// prefixed slashes.
static bool decodeBase64StringEntry(StringRef Str, uint32_t &Result) {
assert(Str.size() <= 6 && "String too long, possible overflow.");
if (Str.size() > 6)
return true;
uint64_t Value = 0;
while (!Str.empty()) {
unsigned CharVal;
if (Str[0] >= 'A' && Str[0] <= 'Z') // 0..25
CharVal = Str[0] - 'A';
else if (Str[0] >= 'a' && Str[0] <= 'z') // 26..51
CharVal = Str[0] - 'a' + 26;
else if (Str[0] >= '0' && Str[0] <= '9') // 52..61
CharVal = Str[0] - '0' + 52;
else if (Str[0] == '+') // 62
CharVal = 62;
else if (Str[0] == '/') // 63
CharVal = 63;
else
return true;
Value = (Value * 64) + CharVal;
Str = Str.substr(1);
}
if (Value > std::numeric_limits<uint32_t>::max())
return true;
Result = static_cast<uint32_t>(Value);
return false;
}
template <typename coff_symbol_type>
const coff_symbol_type *COFFObjectFile::toSymb(DataRefImpl Ref) const {
const coff_symbol_type *Addr =
reinterpret_cast<const coff_symbol_type *>(Ref.p);
assert(!checkOffset(Data, uintptr_t(Addr), sizeof(*Addr)));
#ifndef NDEBUG
// Verify that the symbol points to a valid entry in the symbol table.
uintptr_t Offset = uintptr_t(Addr) - uintptr_t(base());
assert((Offset - getPointerToSymbolTable()) % sizeof(coff_symbol_type) == 0 &&
"Symbol did not point to the beginning of a symbol");
#endif
return Addr;
}
const coff_section *COFFObjectFile::toSec(DataRefImpl Ref) const {
const coff_section *Addr = reinterpret_cast<const coff_section*>(Ref.p);
# ifndef NDEBUG
// Verify that the section points to a valid entry in the section table.
if (Addr < SectionTable || Addr >= (SectionTable + getNumberOfSections()))
report_fatal_error("Section was outside of section table.");
uintptr_t Offset = uintptr_t(Addr) - uintptr_t(SectionTable);
assert(Offset % sizeof(coff_section) == 0 &&
"Section did not point to the beginning of a section");
# endif
return Addr;
}
void COFFObjectFile::moveSymbolNext(DataRefImpl &Ref) const {
auto End = reinterpret_cast<uintptr_t>(StringTable);
if (SymbolTable16) {
const coff_symbol16 *Symb = toSymb<coff_symbol16>(Ref);
Symb += 1 + Symb->NumberOfAuxSymbols;
Ref.p = std::min(reinterpret_cast<uintptr_t>(Symb), End);
} else if (SymbolTable32) {
const coff_symbol32 *Symb = toSymb<coff_symbol32>(Ref);
Symb += 1 + Symb->NumberOfAuxSymbols;
Ref.p = std::min(reinterpret_cast<uintptr_t>(Symb), End);
} else {
llvm_unreachable("no symbol table pointer!");
}
}
ErrorOr<StringRef> COFFObjectFile::getSymbolName(DataRefImpl Ref) const {
COFFSymbolRef Symb = getCOFFSymbol(Ref);
StringRef Result;
std::error_code EC = getSymbolName(Symb, Result);
if (EC)
return EC;
return Result;
}
uint64_t COFFObjectFile::getSymbolValue(DataRefImpl Ref) const {
COFFSymbolRef Sym = getCOFFSymbol(Ref);
if (Sym.isAnyUndefined() || Sym.isCommon())
return UnknownAddress;
return Sym.getValue();
}
ErrorOr<uint64_t> COFFObjectFile::getSymbolAddress(DataRefImpl Ref) const {
uint64_t Result = getSymbolValue(Ref);
COFFSymbolRef Symb = getCOFFSymbol(Ref);
int32_t SectionNumber = Symb.getSectionNumber();
if (Symb.isAnyUndefined() || Symb.isCommon() ||
COFF::isReservedSectionNumber(SectionNumber))
return Result;
const coff_section *Section = nullptr;
if (std::error_code EC = getSection(SectionNumber, Section))
return EC;
Result += Section->VirtualAddress;
return Result;
}
SymbolRef::Type COFFObjectFile::getSymbolType(DataRefImpl Ref) const {
COFFSymbolRef Symb = getCOFFSymbol(Ref);
int32_t SectionNumber = Symb.getSectionNumber();
if (Symb.isAnyUndefined())
return SymbolRef::ST_Unknown;
if (Symb.isFunctionDefinition())
return SymbolRef::ST_Function;
if (Symb.isCommon())
return SymbolRef::ST_Data;
if (Symb.isFileRecord())
return SymbolRef::ST_File;
// TODO: perhaps we need a new symbol type ST_Section.
if (SectionNumber == COFF::IMAGE_SYM_DEBUG || Symb.isSectionDefinition())
return SymbolRef::ST_Debug;
if (!COFF::isReservedSectionNumber(SectionNumber))
return SymbolRef::ST_Data;
return SymbolRef::ST_Other;
}
uint32_t COFFObjectFile::getSymbolFlags(DataRefImpl Ref) const {
COFFSymbolRef Symb = getCOFFSymbol(Ref);
uint32_t Result = SymbolRef::SF_None;
if (Symb.isExternal() || Symb.isWeakExternal())
Result |= SymbolRef::SF_Global;
if (Symb.isWeakExternal())
Result |= SymbolRef::SF_Weak;
if (Symb.getSectionNumber() == COFF::IMAGE_SYM_ABSOLUTE)
Result |= SymbolRef::SF_Absolute;
if (Symb.isFileRecord())
Result |= SymbolRef::SF_FormatSpecific;
if (Symb.isSectionDefinition())
Result |= SymbolRef::SF_FormatSpecific;
if (Symb.isCommon())
Result |= SymbolRef::SF_Common;
if (Symb.isAnyUndefined())
Result |= SymbolRef::SF_Undefined;
return Result;
}
uint64_t COFFObjectFile::getCommonSymbolSizeImpl(DataRefImpl Ref) const {
COFFSymbolRef Symb = getCOFFSymbol(Ref);
return Symb.getValue();
}
std::error_code
COFFObjectFile::getSymbolSection(DataRefImpl Ref,
section_iterator &Result) const {
COFFSymbolRef Symb = getCOFFSymbol(Ref);
if (COFF::isReservedSectionNumber(Symb.getSectionNumber())) {
Result = section_end();
} else {
const coff_section *Sec = nullptr;
if (std::error_code EC = getSection(Symb.getSectionNumber(), Sec))
return EC;
DataRefImpl Ref;
Ref.p = reinterpret_cast<uintptr_t>(Sec);
Result = section_iterator(SectionRef(Ref, this));
}
return std::error_code();
}
unsigned COFFObjectFile::getSymbolSectionID(SymbolRef Sym) const {
COFFSymbolRef Symb = getCOFFSymbol(Sym.getRawDataRefImpl());
return Symb.getSectionNumber();
}
void COFFObjectFile::moveSectionNext(DataRefImpl &Ref) const {
const coff_section *Sec = toSec(Ref);
Sec += 1;
Ref.p = reinterpret_cast<uintptr_t>(Sec);
}
std::error_code COFFObjectFile::getSectionName(DataRefImpl Ref,
StringRef &Result) const {
const coff_section *Sec = toSec(Ref);
return getSectionName(Sec, Result);
}
uint64_t COFFObjectFile::getSectionAddress(DataRefImpl Ref) const {
const coff_section *Sec = toSec(Ref);
return Sec->VirtualAddress;
}
uint64_t COFFObjectFile::getSectionSize(DataRefImpl Ref) const {
return getSectionSize(toSec(Ref));
}
std::error_code COFFObjectFile::getSectionContents(DataRefImpl Ref,
StringRef &Result) const {
const coff_section *Sec = toSec(Ref);
ArrayRef<uint8_t> Res;
std::error_code EC = getSectionContents(Sec, Res);
Result = StringRef(reinterpret_cast<const char*>(Res.data()), Res.size());
return EC;
}
uint64_t COFFObjectFile::getSectionAlignment(DataRefImpl Ref) const {
const coff_section *Sec = toSec(Ref);
return uint64_t(1) << (((Sec->Characteristics & 0x00F00000) >> 20) - 1);
}
bool COFFObjectFile::isSectionText(DataRefImpl Ref) const {
const coff_section *Sec = toSec(Ref);
return Sec->Characteristics & COFF::IMAGE_SCN_CNT_CODE;
}
bool COFFObjectFile::isSectionData(DataRefImpl Ref) const {
const coff_section *Sec = toSec(Ref);
return Sec->Characteristics & COFF::IMAGE_SCN_CNT_INITIALIZED_DATA;
}
bool COFFObjectFile::isSectionBSS(DataRefImpl Ref) const {
const coff_section *Sec = toSec(Ref);
const uint32_t BssFlags = COFF::IMAGE_SCN_CNT_UNINITIALIZED_DATA |
COFF::IMAGE_SCN_MEM_READ |
COFF::IMAGE_SCN_MEM_WRITE;
return (Sec->Characteristics & BssFlags) == BssFlags;
}
unsigned COFFObjectFile::getSectionID(SectionRef Sec) const {
uintptr_t Offset =
uintptr_t(Sec.getRawDataRefImpl().p) - uintptr_t(SectionTable);
assert((Offset % sizeof(coff_section)) == 0);
return (Offset / sizeof(coff_section)) + 1;
}
bool COFFObjectFile::isSectionVirtual(DataRefImpl Ref) const {
const coff_section *Sec = toSec(Ref);
// In COFF, a virtual section won't have any in-file
// content, so the file pointer to the content will be zero.
return Sec->PointerToRawData == 0;
}
static uint32_t getNumberOfRelocations(const coff_section *Sec,
MemoryBufferRef M, const uint8_t *base) {
// The field for the number of relocations in COFF section table is only
// 16-bit wide. If a section has more than 65535 relocations, 0xFFFF is set to
// NumberOfRelocations field, and the actual relocation count is stored in the
// VirtualAddress field in the first relocation entry.
if (Sec->hasExtendedRelocations()) {
const coff_relocation *FirstReloc;
if (getObject(FirstReloc, M, reinterpret_cast<const coff_relocation*>(
base + Sec->PointerToRelocations)))
return 0;
// -1 to exclude this first relocation entry.
return FirstReloc->VirtualAddress - 1;
}
return Sec->NumberOfRelocations;
}
static const coff_relocation *
getFirstReloc(const coff_section *Sec, MemoryBufferRef M, const uint8_t *Base) {
uint64_t NumRelocs = getNumberOfRelocations(Sec, M, Base);
if (!NumRelocs)
return nullptr;
auto begin = reinterpret_cast<const coff_relocation *>(
Base + Sec->PointerToRelocations);
if (Sec->hasExtendedRelocations()) {
// Skip the first relocation entry repurposed to store the number of
// relocations.
begin++;
}
if (checkOffset(M, uintptr_t(begin), sizeof(coff_relocation) * NumRelocs))
return nullptr;
return begin;
}
relocation_iterator COFFObjectFile::section_rel_begin(DataRefImpl Ref) const {
const coff_section *Sec = toSec(Ref);
const coff_relocation *begin = getFirstReloc(Sec, Data, base());
DataRefImpl Ret;
Ret.p = reinterpret_cast<uintptr_t>(begin);
return relocation_iterator(RelocationRef(Ret, this));
}
relocation_iterator COFFObjectFile::section_rel_end(DataRefImpl Ref) const {
const coff_section *Sec = toSec(Ref);
const coff_relocation *I = getFirstReloc(Sec, Data, base());
if (I)
I += getNumberOfRelocations(Sec, Data, base());
DataRefImpl Ret;
Ret.p = reinterpret_cast<uintptr_t>(I);
return relocation_iterator(RelocationRef(Ret, this));
}
// Initialize the pointer to the symbol table.
std::error_code COFFObjectFile::initSymbolTablePtr() {
if (COFFHeader)
if (std::error_code EC = getObject(
SymbolTable16, Data, base() + getPointerToSymbolTable(),
(uint64_t)getNumberOfSymbols() * getSymbolTableEntrySize()))
return EC;
if (COFFBigObjHeader)
if (std::error_code EC = getObject(
SymbolTable32, Data, base() + getPointerToSymbolTable(),
(uint64_t)getNumberOfSymbols() * getSymbolTableEntrySize()))
return EC;
// Find string table. The first four byte of the string table contains the
// total size of the string table, including the size field itself. If the
// string table is empty, the value of the first four byte would be 4.
uint32_t StringTableOffset = getPointerToSymbolTable() +
getNumberOfSymbols() * getSymbolTableEntrySize();
const uint8_t *StringTableAddr = base() + StringTableOffset;
const ulittle32_t *StringTableSizePtr;
if (std::error_code EC = getObject(StringTableSizePtr, Data, StringTableAddr))
return EC;
StringTableSize = *StringTableSizePtr;
if (std::error_code EC =
getObject(StringTable, Data, StringTableAddr, StringTableSize))
return EC;
// Treat table sizes < 4 as empty because contrary to the PECOFF spec, some
// tools like cvtres write a size of 0 for an empty table instead of 4.
if (StringTableSize < 4)
StringTableSize = 4;
// Check that the string table is null terminated if has any in it.
if (StringTableSize > 4 && StringTable[StringTableSize - 1] != 0)
return object_error::parse_failed;
return std::error_code();
}
// Returns the file offset for the given VA.
std::error_code COFFObjectFile::getVaPtr(uint64_t Addr, uintptr_t &Res) const {
uint64_t ImageBase = PE32Header ? (uint64_t)PE32Header->ImageBase
: (uint64_t)PE32PlusHeader->ImageBase;
uint64_t Rva = Addr - ImageBase;
assert(Rva <= UINT32_MAX);
return getRvaPtr((uint32_t)Rva, Res);
}
// Returns the file offset for the given RVA.
std::error_code COFFObjectFile::getRvaPtr(uint32_t Addr, uintptr_t &Res) const {
for (const SectionRef &S : sections()) {
const coff_section *Section = getCOFFSection(S);
uint32_t SectionStart = Section->VirtualAddress;
uint32_t SectionEnd = Section->VirtualAddress + Section->VirtualSize;
if (SectionStart <= Addr && Addr < SectionEnd) {
uint32_t Offset = Addr - SectionStart;
Res = uintptr_t(base()) + Section->PointerToRawData + Offset;
return std::error_code();
}
}
return object_error::parse_failed;
}
// Returns hint and name fields, assuming \p Rva is pointing to a Hint/Name
// table entry.
std::error_code COFFObjectFile::getHintName(uint32_t Rva, uint16_t &Hint,
StringRef &Name) const {
uintptr_t IntPtr = 0;
if (std::error_code EC = getRvaPtr(Rva, IntPtr))
return EC;
const uint8_t *Ptr = reinterpret_cast<const uint8_t *>(IntPtr);
Hint = *reinterpret_cast<const ulittle16_t *>(Ptr);
Name = StringRef(reinterpret_cast<const char *>(Ptr + 2));
return std::error_code();
}
// Find the import table.
std::error_code COFFObjectFile::initImportTablePtr() {
// First, we get the RVA of the import table. If the file lacks a pointer to
// the import table, do nothing.
const data_directory *DataEntry;
if (getDataDirectory(COFF::IMPORT_TABLE, DataEntry))
return std::error_code();
// Do nothing if the pointer to import table is NULL.
if (DataEntry->RelativeVirtualAddress == 0)
return std::error_code();
uint32_t ImportTableRva = DataEntry->RelativeVirtualAddress;
// -1 because the last entry is the null entry.
NumberOfImportDirectory = DataEntry->Size /
sizeof(import_directory_table_entry) - 1;
// Find the section that contains the RVA. This is needed because the RVA is
// the import table's memory address which is different from its file offset.
uintptr_t IntPtr = 0;
if (std::error_code EC = getRvaPtr(ImportTableRva, IntPtr))
return EC;
ImportDirectory = reinterpret_cast<
const import_directory_table_entry *>(IntPtr);
return std::error_code();
}
// Initializes DelayImportDirectory and NumberOfDelayImportDirectory.
std::error_code COFFObjectFile::initDelayImportTablePtr() {
const data_directory *DataEntry;
if (getDataDirectory(COFF::DELAY_IMPORT_DESCRIPTOR, DataEntry))
return std::error_code();
if (DataEntry->RelativeVirtualAddress == 0)
return std::error_code();
uint32_t RVA = DataEntry->RelativeVirtualAddress;
NumberOfDelayImportDirectory = DataEntry->Size /
sizeof(delay_import_directory_table_entry) - 1;
uintptr_t IntPtr = 0;
if (std::error_code EC = getRvaPtr(RVA, IntPtr))
return EC;
DelayImportDirectory = reinterpret_cast<
const delay_import_directory_table_entry *>(IntPtr);
return std::error_code();
}
// Find the export table.
std::error_code COFFObjectFile::initExportTablePtr() {
// First, we get the RVA of the export table. If the file lacks a pointer to
// the export table, do nothing.
const data_directory *DataEntry;
if (getDataDirectory(COFF::EXPORT_TABLE, DataEntry))
return std::error_code();
// Do nothing if the pointer to export table is NULL.
if (DataEntry->RelativeVirtualAddress == 0)
return std::error_code();
uint32_t ExportTableRva = DataEntry->RelativeVirtualAddress;
uintptr_t IntPtr = 0;
if (std::error_code EC = getRvaPtr(ExportTableRva, IntPtr))
return EC;
ExportDirectory =
reinterpret_cast<const export_directory_table_entry *>(IntPtr);
return std::error_code();
}
std::error_code COFFObjectFile::initBaseRelocPtr() {
const data_directory *DataEntry;
if (getDataDirectory(COFF::BASE_RELOCATION_TABLE, DataEntry))
return std::error_code();
if (DataEntry->RelativeVirtualAddress == 0)
return std::error_code();
uintptr_t IntPtr = 0;
if (std::error_code EC = getRvaPtr(DataEntry->RelativeVirtualAddress, IntPtr))
return EC;
BaseRelocHeader = reinterpret_cast<const coff_base_reloc_block_header *>(
IntPtr);
BaseRelocEnd = reinterpret_cast<coff_base_reloc_block_header *>(
IntPtr + DataEntry->Size);
return std::error_code();
}
COFFObjectFile::COFFObjectFile(MemoryBufferRef Object, std::error_code &EC)
: ObjectFile(Binary::ID_COFF, Object), COFFHeader(nullptr),
COFFBigObjHeader(nullptr), PE32Header(nullptr), PE32PlusHeader(nullptr),
DataDirectory(nullptr), SectionTable(nullptr), SymbolTable16(nullptr),
SymbolTable32(nullptr), StringTable(nullptr), StringTableSize(0),
ImportDirectory(nullptr), NumberOfImportDirectory(0),
DelayImportDirectory(nullptr), NumberOfDelayImportDirectory(0),
ExportDirectory(nullptr), BaseRelocHeader(nullptr),
BaseRelocEnd(nullptr) {
// Check that we at least have enough room for a header.
if (!checkSize(Data, EC, sizeof(coff_file_header)))
return;
// The current location in the file where we are looking at.
uint64_t CurPtr = 0;
// PE header is optional and is present only in executables. If it exists,
// it is placed right after COFF header.
bool HasPEHeader = false;
// Check if this is a PE/COFF file.
if (checkSize(Data, EC, sizeof(dos_header) + sizeof(COFF::PEMagic))) {
// PE/COFF, seek through MS-DOS compatibility stub and 4-byte
// PE signature to find 'normal' COFF header.
const auto *DH = reinterpret_cast<const dos_header *>(base());
if (DH->Magic[0] == 'M' && DH->Magic[1] == 'Z') {
CurPtr = DH->AddressOfNewExeHeader;
// Check the PE magic bytes. ("PE\0\0")
if (memcmp(base() + CurPtr, COFF::PEMagic, sizeof(COFF::PEMagic)) != 0) {
EC = object_error::parse_failed;
return;
}
CurPtr += sizeof(COFF::PEMagic); // Skip the PE magic bytes.
HasPEHeader = true;
}
}
if ((EC = getObject(COFFHeader, Data, base() + CurPtr)))
return;
// It might be a bigobj file, let's check. Note that COFF bigobj and COFF
// import libraries share a common prefix but bigobj is more restrictive.
if (!HasPEHeader && COFFHeader->Machine == COFF::IMAGE_FILE_MACHINE_UNKNOWN &&
COFFHeader->NumberOfSections == uint16_t(0xffff) &&
checkSize(Data, EC, sizeof(coff_bigobj_file_header))) {
if ((EC = getObject(COFFBigObjHeader, Data, base() + CurPtr)))
return;
// Verify that we are dealing with bigobj.
if (COFFBigObjHeader->Version >= COFF::BigObjHeader::MinBigObjectVersion &&
std::memcmp(COFFBigObjHeader->UUID, COFF::BigObjMagic,
sizeof(COFF::BigObjMagic)) == 0) {
COFFHeader = nullptr;
CurPtr += sizeof(coff_bigobj_file_header);
} else {
// It's not a bigobj.
COFFBigObjHeader = nullptr;
}
}
if (COFFHeader) {
// The prior checkSize call may have failed. This isn't a hard error
// because we were just trying to sniff out bigobj.
EC = std::error_code();
CurPtr += sizeof(coff_file_header);
if (COFFHeader->isImportLibrary())
return;
}
if (HasPEHeader) {
const pe32_header *Header;
if ((EC = getObject(Header, Data, base() + CurPtr)))
return;
const uint8_t *DataDirAddr;
uint64_t DataDirSize;
if (Header->Magic == COFF::PE32Header::PE32) {
PE32Header = Header;
DataDirAddr = base() + CurPtr + sizeof(pe32_header);
DataDirSize = sizeof(data_directory) * PE32Header->NumberOfRvaAndSize;
} else if (Header->Magic == COFF::PE32Header::PE32_PLUS) {
PE32PlusHeader = reinterpret_cast<const pe32plus_header *>(Header);
DataDirAddr = base() + CurPtr + sizeof(pe32plus_header);
DataDirSize = sizeof(data_directory) * PE32PlusHeader->NumberOfRvaAndSize;
} else {
// It's neither PE32 nor PE32+.
EC = object_error::parse_failed;
return;
}
if ((EC = getObject(DataDirectory, Data, DataDirAddr, DataDirSize)))
return;
CurPtr += COFFHeader->SizeOfOptionalHeader;
}
if ((EC = getObject(SectionTable, Data, base() + CurPtr,
(uint64_t)getNumberOfSections() * sizeof(coff_section))))
return;
// Initialize the pointer to the symbol table.
if (getPointerToSymbolTable() != 0) {
if ((EC = initSymbolTablePtr()))
return;
} else {
// We had better not have any symbols if we don't have a symbol table.
if (getNumberOfSymbols() != 0) {
EC = object_error::parse_failed;
return;
}
}
// Initialize the pointer to the beginning of the import table.
if ((EC = initImportTablePtr()))
return;
if ((EC = initDelayImportTablePtr()))
return;
// Initialize the pointer to the export table.
if ((EC = initExportTablePtr()))
return;
// Initialize the pointer to the base relocation table.
if ((EC = initBaseRelocPtr()))
return;
EC = std::error_code();
}
basic_symbol_iterator COFFObjectFile::symbol_begin_impl() const {
DataRefImpl Ret;
Ret.p = getSymbolTable();
return basic_symbol_iterator(SymbolRef(Ret, this));
}
basic_symbol_iterator COFFObjectFile::symbol_end_impl() const {
// The symbol table ends where the string table begins.
DataRefImpl Ret;
Ret.p = reinterpret_cast<uintptr_t>(StringTable);
return basic_symbol_iterator(SymbolRef(Ret, this));
}
import_directory_iterator COFFObjectFile::import_directory_begin() const {
return import_directory_iterator(
ImportDirectoryEntryRef(ImportDirectory, 0, this));
}
import_directory_iterator COFFObjectFile::import_directory_end() const {
return import_directory_iterator(
ImportDirectoryEntryRef(ImportDirectory, NumberOfImportDirectory, this));
}
delay_import_directory_iterator
COFFObjectFile::delay_import_directory_begin() const {
return delay_import_directory_iterator(
DelayImportDirectoryEntryRef(DelayImportDirectory, 0, this));
}
delay_import_directory_iterator
COFFObjectFile::delay_import_directory_end() const {
return delay_import_directory_iterator(
DelayImportDirectoryEntryRef(
DelayImportDirectory, NumberOfDelayImportDirectory, this));
}
export_directory_iterator COFFObjectFile::export_directory_begin() const {
return export_directory_iterator(
ExportDirectoryEntryRef(ExportDirectory, 0, this));
}
export_directory_iterator COFFObjectFile::export_directory_end() const {
if (!ExportDirectory)
return export_directory_iterator(ExportDirectoryEntryRef(nullptr, 0, this));
ExportDirectoryEntryRef Ref(ExportDirectory,
ExportDirectory->AddressTableEntries, this);
return export_directory_iterator(Ref);
}
section_iterator COFFObjectFile::section_begin() const {
DataRefImpl Ret;
Ret.p = reinterpret_cast<uintptr_t>(SectionTable);
return section_iterator(SectionRef(Ret, this));
}
section_iterator COFFObjectFile::section_end() const {
DataRefImpl Ret;
int NumSections =
COFFHeader && COFFHeader->isImportLibrary() ? 0 : getNumberOfSections();
Ret.p = reinterpret_cast<uintptr_t>(SectionTable + NumSections);
return section_iterator(SectionRef(Ret, this));
}
base_reloc_iterator COFFObjectFile::base_reloc_begin() const {
return base_reloc_iterator(BaseRelocRef(BaseRelocHeader, this));
}
base_reloc_iterator COFFObjectFile::base_reloc_end() const {
return base_reloc_iterator(BaseRelocRef(BaseRelocEnd, this));
}
uint8_t COFFObjectFile::getBytesInAddress() const {
return getArch() == Triple::x86_64 ? 8 : 4;
}
StringRef COFFObjectFile::getFileFormatName() const {
switch(getMachine()) {
case COFF::IMAGE_FILE_MACHINE_I386:
return "COFF-i386";
case COFF::IMAGE_FILE_MACHINE_AMD64:
return "COFF-x86-64";
case COFF::IMAGE_FILE_MACHINE_ARMNT:
return "COFF-ARM";
default:
return "COFF-<unknown arch>";
}
}
unsigned COFFObjectFile::getArch() const {
switch (getMachine()) {
case COFF::IMAGE_FILE_MACHINE_I386:
return Triple::x86;
case COFF::IMAGE_FILE_MACHINE_AMD64:
return Triple::x86_64;
case COFF::IMAGE_FILE_MACHINE_ARMNT:
return Triple::thumb;
default:
return Triple::UnknownArch;
}
}
iterator_range<import_directory_iterator>
COFFObjectFile::import_directories() const {
return make_range(import_directory_begin(), import_directory_end());
}
iterator_range<delay_import_directory_iterator>
COFFObjectFile::delay_import_directories() const {
return make_range(delay_import_directory_begin(),
delay_import_directory_end());
}
iterator_range<export_directory_iterator>
COFFObjectFile::export_directories() const {
return make_range(export_directory_begin(), export_directory_end());
}
iterator_range<base_reloc_iterator> COFFObjectFile::base_relocs() const {
return make_range(base_reloc_begin(), base_reloc_end());
}
std::error_code COFFObjectFile::getPE32Header(const pe32_header *&Res) const {
Res = PE32Header;
return std::error_code();
}
std::error_code
COFFObjectFile::getPE32PlusHeader(const pe32plus_header *&Res) const {
Res = PE32PlusHeader;
return std::error_code();
}
std::error_code
COFFObjectFile::getDataDirectory(uint32_t Index,
const data_directory *&Res) const {
// Error if if there's no data directory or the index is out of range.
if (!DataDirectory) {
Res = nullptr;
return object_error::parse_failed;
}
assert(PE32Header || PE32PlusHeader);
uint32_t NumEnt = PE32Header ? PE32Header->NumberOfRvaAndSize
: PE32PlusHeader->NumberOfRvaAndSize;
if (Index >= NumEnt) {
Res = nullptr;
return object_error::parse_failed;
}
Res = &DataDirectory[Index];
return std::error_code();
}
std::error_code COFFObjectFile::getSection(int32_t Index,
const coff_section *&Result) const {
Result = nullptr;
if (COFF::isReservedSectionNumber(Index))
return std::error_code();
if (static_cast<uint32_t>(Index) <= getNumberOfSections()) {
// We already verified the section table data, so no need to check again.
Result = SectionTable + (Index - 1);
return std::error_code();
}
return object_error::parse_failed;
}
std::error_code COFFObjectFile::getString(uint32_t Offset,
StringRef &Result) const {
if (StringTableSize <= 4)
// Tried to get a string from an empty string table.
return object_error::parse_failed;
if (Offset >= StringTableSize)
return object_error::unexpected_eof;
Result = StringRef(StringTable + Offset);
return std::error_code();
}
std::error_code COFFObjectFile::getSymbolName(COFFSymbolRef Symbol,
StringRef &Res) const {
return getSymbolName(Symbol.getGeneric(), Res);
}
std::error_code COFFObjectFile::getSymbolName(const coff_symbol_generic *Symbol,
StringRef &Res) const {
// Check for string table entry. First 4 bytes are 0.
if (Symbol->Name.Offset.Zeroes == 0) {
if (std::error_code EC = getString(Symbol->Name.Offset.Offset, Res))
return EC;
return std::error_code();
}
if (Symbol->Name.ShortName[COFF::NameSize - 1] == 0)
// Null terminated, let ::strlen figure out the length.
Res = StringRef(Symbol->Name.ShortName);
else
// Not null terminated, use all 8 bytes.
Res = StringRef(Symbol->Name.ShortName, COFF::NameSize);
return std::error_code();
}
ArrayRef<uint8_t>
COFFObjectFile::getSymbolAuxData(COFFSymbolRef Symbol) const {
const uint8_t *Aux = nullptr;
size_t SymbolSize = getSymbolTableEntrySize();
if (Symbol.getNumberOfAuxSymbols() > 0) {
// AUX data comes immediately after the symbol in COFF
Aux = reinterpret_cast<const uint8_t *>(Symbol.getRawPtr()) + SymbolSize;
# ifndef NDEBUG
// Verify that the Aux symbol points to a valid entry in the symbol table.
uintptr_t Offset = uintptr_t(Aux) - uintptr_t(base());
if (Offset < getPointerToSymbolTable() ||
Offset >=
getPointerToSymbolTable() + (getNumberOfSymbols() * SymbolSize))
report_fatal_error("Aux Symbol data was outside of symbol table.");
assert((Offset - getPointerToSymbolTable()) % SymbolSize == 0 &&
"Aux Symbol data did not point to the beginning of a symbol");
# endif
}
return makeArrayRef(Aux, Symbol.getNumberOfAuxSymbols() * SymbolSize);
}
std::error_code COFFObjectFile::getSectionName(const coff_section *Sec,
StringRef &Res) const {
StringRef Name;
if (Sec->Name[COFF::NameSize - 1] == 0)
// Null terminated, let ::strlen figure out the length.
Name = Sec->Name;
else
// Not null terminated, use all 8 bytes.
Name = StringRef(Sec->Name, COFF::NameSize);
// Check for string table entry. First byte is '/'.
if (Name.startswith("/")) {
uint32_t Offset;
if (Name.startswith("//")) {
if (decodeBase64StringEntry(Name.substr(2), Offset))
return object_error::parse_failed;
} else {
if (Name.substr(1).getAsInteger(10, Offset))
return object_error::parse_failed;
}
if (std::error_code EC = getString(Offset, Name))
return EC;
}
Res = Name;
return std::error_code();
}
uint64_t COFFObjectFile::getSectionSize(const coff_section *Sec) const {
// SizeOfRawData and VirtualSize change what they represent depending on
// whether or not we have an executable image.
//
// For object files, SizeOfRawData contains the size of section's data;
// VirtualSize is always zero.
//
// For executables, SizeOfRawData *must* be a multiple of FileAlignment; the
// actual section size is in VirtualSize. It is possible for VirtualSize to
// be greater than SizeOfRawData; the contents past that point should be
// considered to be zero.
uint32_t SectionSize;
if (Sec->VirtualSize)
SectionSize = std::min(Sec->VirtualSize, Sec->SizeOfRawData);
else
SectionSize = Sec->SizeOfRawData;
return SectionSize;
}
std::error_code
COFFObjectFile::getSectionContents(const coff_section *Sec,
ArrayRef<uint8_t> &Res) const {
// PointerToRawData and SizeOfRawData won't make sense for BSS sections,
// don't do anything interesting for them.
assert((Sec->Characteristics & COFF::IMAGE_SCN_CNT_UNINITIALIZED_DATA) == 0 &&
"BSS sections don't have contents!");
// The only thing that we need to verify is that the contents is contained
// within the file bounds. We don't need to make sure it doesn't cover other
// data, as there's nothing that says that is not allowed.
uintptr_t ConStart = uintptr_t(base()) + Sec->PointerToRawData;
uint32_t SectionSize = getSectionSize(Sec);
if (checkOffset(Data, ConStart, SectionSize))
return object_error::parse_failed;
Res = makeArrayRef(reinterpret_cast<const uint8_t *>(ConStart), SectionSize);
return std::error_code();
}
const coff_relocation *COFFObjectFile::toRel(DataRefImpl Rel) const {
return reinterpret_cast<const coff_relocation*>(Rel.p);
}
void COFFObjectFile::moveRelocationNext(DataRefImpl &Rel) const {
Rel.p = reinterpret_cast<uintptr_t>(
reinterpret_cast<const coff_relocation*>(Rel.p) + 1);
}
ErrorOr<uint64_t> COFFObjectFile::getRelocationAddress(DataRefImpl Rel) const {
report_fatal_error("getRelocationAddress not implemented in COFFObjectFile");
}
uint64_t COFFObjectFile::getRelocationOffset(DataRefImpl Rel) const {
const coff_relocation *R = toRel(Rel);
return R->VirtualAddress;
}
symbol_iterator COFFObjectFile::getRelocationSymbol(DataRefImpl Rel) const {
const coff_relocation *R = toRel(Rel);
DataRefImpl Ref;
if (R->SymbolTableIndex >= getNumberOfSymbols())
return symbol_end();
if (SymbolTable16)
Ref.p = reinterpret_cast<uintptr_t>(SymbolTable16 + R->SymbolTableIndex);
else if (SymbolTable32)
Ref.p = reinterpret_cast<uintptr_t>(SymbolTable32 + R->SymbolTableIndex);
else
llvm_unreachable("no symbol table pointer!");
return symbol_iterator(SymbolRef(Ref, this));
}
uint64_t COFFObjectFile::getRelocationType(DataRefImpl Rel) const {
const coff_relocation* R = toRel(Rel);
return R->Type;
}
const coff_section *
COFFObjectFile::getCOFFSection(const SectionRef &Section) const {
return toSec(Section.getRawDataRefImpl());
}
COFFSymbolRef COFFObjectFile::getCOFFSymbol(const DataRefImpl &Ref) const {
if (SymbolTable16)
return toSymb<coff_symbol16>(Ref);
if (SymbolTable32)
return toSymb<coff_symbol32>(Ref);
llvm_unreachable("no symbol table pointer!");
}
COFFSymbolRef COFFObjectFile::getCOFFSymbol(const SymbolRef &Symbol) const {
return getCOFFSymbol(Symbol.getRawDataRefImpl());
}
const coff_relocation *
COFFObjectFile::getCOFFRelocation(const RelocationRef &Reloc) const {
return toRel(Reloc.getRawDataRefImpl());
}
iterator_range<const coff_relocation *>
COFFObjectFile::getRelocations(const coff_section *Sec) const {
const coff_relocation *I = getFirstReloc(Sec, Data, base());
const coff_relocation *E = I;
if (I)
E += getNumberOfRelocations(Sec, Data, base());
return make_range(I, E);
}
#define LLVM_COFF_SWITCH_RELOC_TYPE_NAME(reloc_type) \
case COFF::reloc_type: \
Res = #reloc_type; \
break;
void COFFObjectFile::getRelocationTypeName(
DataRefImpl Rel, SmallVectorImpl<char> &Result) const {
const coff_relocation *Reloc = toRel(Rel);
StringRef Res;
switch (getMachine()) {
case COFF::IMAGE_FILE_MACHINE_AMD64:
switch (Reloc->Type) {
LLVM_COFF_SWITCH_RELOC_TYPE_NAME(IMAGE_REL_AMD64_ABSOLUTE);
LLVM_COFF_SWITCH_RELOC_TYPE_NAME(IMAGE_REL_AMD64_ADDR64);
LLVM_COFF_SWITCH_RELOC_TYPE_NAME(IMAGE_REL_AMD64_ADDR32);
LLVM_COFF_SWITCH_RELOC_TYPE_NAME(IMAGE_REL_AMD64_ADDR32NB);
LLVM_COFF_SWITCH_RELOC_TYPE_NAME(IMAGE_REL_AMD64_REL32);
LLVM_COFF_SWITCH_RELOC_TYPE_NAME(IMAGE_REL_AMD64_REL32_1);
LLVM_COFF_SWITCH_RELOC_TYPE_NAME(IMAGE_REL_AMD64_REL32_2);
LLVM_COFF_SWITCH_RELOC_TYPE_NAME(IMAGE_REL_AMD64_REL32_3);
LLVM_COFF_SWITCH_RELOC_TYPE_NAME(IMAGE_REL_AMD64_REL32_4);
LLVM_COFF_SWITCH_RELOC_TYPE_NAME(IMAGE_REL_AMD64_REL32_5);
LLVM_COFF_SWITCH_RELOC_TYPE_NAME(IMAGE_REL_AMD64_SECTION);
LLVM_COFF_SWITCH_RELOC_TYPE_NAME(IMAGE_REL_AMD64_SECREL);
LLVM_COFF_SWITCH_RELOC_TYPE_NAME(IMAGE_REL_AMD64_SECREL7);
LLVM_COFF_SWITCH_RELOC_TYPE_NAME(IMAGE_REL_AMD64_TOKEN);
LLVM_COFF_SWITCH_RELOC_TYPE_NAME(IMAGE_REL_AMD64_SREL32);
LLVM_COFF_SWITCH_RELOC_TYPE_NAME(IMAGE_REL_AMD64_PAIR);
LLVM_COFF_SWITCH_RELOC_TYPE_NAME(IMAGE_REL_AMD64_SSPAN32);
default:
Res = "Unknown";
}
break;
case COFF::IMAGE_FILE_MACHINE_ARMNT:
switch (Reloc->Type) {
LLVM_COFF_SWITCH_RELOC_TYPE_NAME(IMAGE_REL_ARM_ABSOLUTE);
LLVM_COFF_SWITCH_RELOC_TYPE_NAME(IMAGE_REL_ARM_ADDR32);
LLVM_COFF_SWITCH_RELOC_TYPE_NAME(IMAGE_REL_ARM_ADDR32NB);
LLVM_COFF_SWITCH_RELOC_TYPE_NAME(IMAGE_REL_ARM_BRANCH24);
LLVM_COFF_SWITCH_RELOC_TYPE_NAME(IMAGE_REL_ARM_BRANCH11);
LLVM_COFF_SWITCH_RELOC_TYPE_NAME(IMAGE_REL_ARM_TOKEN);
LLVM_COFF_SWITCH_RELOC_TYPE_NAME(IMAGE_REL_ARM_BLX24);
LLVM_COFF_SWITCH_RELOC_TYPE_NAME(IMAGE_REL_ARM_BLX11);
LLVM_COFF_SWITCH_RELOC_TYPE_NAME(IMAGE_REL_ARM_SECTION);
LLVM_COFF_SWITCH_RELOC_TYPE_NAME(IMAGE_REL_ARM_SECREL);
LLVM_COFF_SWITCH_RELOC_TYPE_NAME(IMAGE_REL_ARM_MOV32A);
LLVM_COFF_SWITCH_RELOC_TYPE_NAME(IMAGE_REL_ARM_MOV32T);
LLVM_COFF_SWITCH_RELOC_TYPE_NAME(IMAGE_REL_ARM_BRANCH20T);
LLVM_COFF_SWITCH_RELOC_TYPE_NAME(IMAGE_REL_ARM_BRANCH24T);
LLVM_COFF_SWITCH_RELOC_TYPE_NAME(IMAGE_REL_ARM_BLX23T);
default:
Res = "Unknown";
}
break;
case COFF::IMAGE_FILE_MACHINE_I386:
switch (Reloc->Type) {
LLVM_COFF_SWITCH_RELOC_TYPE_NAME(IMAGE_REL_I386_ABSOLUTE);
LLVM_COFF_SWITCH_RELOC_TYPE_NAME(IMAGE_REL_I386_DIR16);
LLVM_COFF_SWITCH_RELOC_TYPE_NAME(IMAGE_REL_I386_REL16);
LLVM_COFF_SWITCH_RELOC_TYPE_NAME(IMAGE_REL_I386_DIR32);
LLVM_COFF_SWITCH_RELOC_TYPE_NAME(IMAGE_REL_I386_DIR32NB);
LLVM_COFF_SWITCH_RELOC_TYPE_NAME(IMAGE_REL_I386_SEG12);
LLVM_COFF_SWITCH_RELOC_TYPE_NAME(IMAGE_REL_I386_SECTION);
LLVM_COFF_SWITCH_RELOC_TYPE_NAME(IMAGE_REL_I386_SECREL);
LLVM_COFF_SWITCH_RELOC_TYPE_NAME(IMAGE_REL_I386_TOKEN);
LLVM_COFF_SWITCH_RELOC_TYPE_NAME(IMAGE_REL_I386_SECREL7);
LLVM_COFF_SWITCH_RELOC_TYPE_NAME(IMAGE_REL_I386_REL32);
default:
Res = "Unknown";
}
break;
default:
Res = "Unknown";
}
Result.append(Res.begin(), Res.end());
}
#undef LLVM_COFF_SWITCH_RELOC_TYPE_NAME
bool COFFObjectFile::isRelocatableObject() const {
return !DataDirectory;
}
bool ImportDirectoryEntryRef::
operator==(const ImportDirectoryEntryRef &Other) const {
return ImportTable == Other.ImportTable && Index == Other.Index;
}
void ImportDirectoryEntryRef::moveNext() {
++Index;
}
std::error_code ImportDirectoryEntryRef::getImportTableEntry(
const import_directory_table_entry *&Result) const {
Result = ImportTable + Index;
return std::error_code();
}
static imported_symbol_iterator
makeImportedSymbolIterator(const COFFObjectFile *Object,
uintptr_t Ptr, int Index) {
if (Object->getBytesInAddress() == 4) {
auto *P = reinterpret_cast<const import_lookup_table_entry32 *>(Ptr);
return imported_symbol_iterator(ImportedSymbolRef(P, Index, Object));
}
auto *P = reinterpret_cast<const import_lookup_table_entry64 *>(Ptr);
return imported_symbol_iterator(ImportedSymbolRef(P, Index, Object));
}
static imported_symbol_iterator
importedSymbolBegin(uint32_t RVA, const COFFObjectFile *Object) {
uintptr_t IntPtr = 0;
Object->getRvaPtr(RVA, IntPtr);
return makeImportedSymbolIterator(Object, IntPtr, 0);
}
static imported_symbol_iterator
importedSymbolEnd(uint32_t RVA, const COFFObjectFile *Object) {
uintptr_t IntPtr = 0;
Object->getRvaPtr(RVA, IntPtr);
// Forward the pointer to the last entry which is null.
int Index = 0;
if (Object->getBytesInAddress() == 4) {
auto *Entry = reinterpret_cast<ulittle32_t *>(IntPtr);
while (*Entry++)
++Index;
} else {
auto *Entry = reinterpret_cast<ulittle64_t *>(IntPtr);
while (*Entry++)
++Index;
}
return makeImportedSymbolIterator(Object, IntPtr, Index);
}
imported_symbol_iterator
ImportDirectoryEntryRef::imported_symbol_begin() const {
return importedSymbolBegin(ImportTable[Index].ImportLookupTableRVA,
OwningObject);
}
imported_symbol_iterator
ImportDirectoryEntryRef::imported_symbol_end() const {
return importedSymbolEnd(ImportTable[Index].ImportLookupTableRVA,
OwningObject);
}
iterator_range<imported_symbol_iterator>
ImportDirectoryEntryRef::imported_symbols() const {
return make_range(imported_symbol_begin(), imported_symbol_end());
}
std::error_code ImportDirectoryEntryRef::getName(StringRef &Result) const {
uintptr_t IntPtr = 0;
if (std::error_code EC =
OwningObject->getRvaPtr(ImportTable[Index].NameRVA, IntPtr))
return EC;
Result = StringRef(reinterpret_cast<const char *>(IntPtr));
return std::error_code();
}
std::error_code
ImportDirectoryEntryRef::getImportLookupTableRVA(uint32_t &Result) const {
Result = ImportTable[Index].ImportLookupTableRVA;
return std::error_code();
}
std::error_code
ImportDirectoryEntryRef::getImportAddressTableRVA(uint32_t &Result) const {
Result = ImportTable[Index].ImportAddressTableRVA;
return std::error_code();
}
std::error_code ImportDirectoryEntryRef::getImportLookupEntry(
const import_lookup_table_entry32 *&Result) const {
uintptr_t IntPtr = 0;
uint32_t RVA = ImportTable[Index].ImportLookupTableRVA;
if (std::error_code EC = OwningObject->getRvaPtr(RVA, IntPtr))
return EC;
Result = reinterpret_cast<const import_lookup_table_entry32 *>(IntPtr);
return std::error_code();
}
bool DelayImportDirectoryEntryRef::
operator==(const DelayImportDirectoryEntryRef &Other) const {
return Table == Other.Table && Index == Other.Index;
}
void DelayImportDirectoryEntryRef::moveNext() {
++Index;
}
imported_symbol_iterator
DelayImportDirectoryEntryRef::imported_symbol_begin() const {
return importedSymbolBegin(Table[Index].DelayImportNameTable,
OwningObject);
}
imported_symbol_iterator
DelayImportDirectoryEntryRef::imported_symbol_end() const {
return importedSymbolEnd(Table[Index].DelayImportNameTable,
OwningObject);
}
iterator_range<imported_symbol_iterator>
DelayImportDirectoryEntryRef::imported_symbols() const {
return make_range(imported_symbol_begin(), imported_symbol_end());
}
std::error_code DelayImportDirectoryEntryRef::getName(StringRef &Result) const {
uintptr_t IntPtr = 0;
if (std::error_code EC = OwningObject->getRvaPtr(Table[Index].Name, IntPtr))
return EC;
Result = StringRef(reinterpret_cast<const char *>(IntPtr));
return std::error_code();
}
std::error_code DelayImportDirectoryEntryRef::
getDelayImportTable(const delay_import_directory_table_entry *&Result) const {
Result = Table;
return std::error_code();
}
std::error_code DelayImportDirectoryEntryRef::
getImportAddress(int AddrIndex, uint64_t &Result) const {
uint32_t RVA = Table[Index].DelayImportAddressTable +
AddrIndex * (OwningObject->is64() ? 8 : 4);
uintptr_t IntPtr = 0;
if (std::error_code EC = OwningObject->getRvaPtr(RVA, IntPtr))
return EC;
if (OwningObject->is64())
Result = *reinterpret_cast<const ulittle64_t *>(IntPtr);
else
Result = *reinterpret_cast<const ulittle32_t *>(IntPtr);
return std::error_code();
}
bool ExportDirectoryEntryRef::
operator==(const ExportDirectoryEntryRef &Other) const {
return ExportTable == Other.ExportTable && Index == Other.Index;
}
void ExportDirectoryEntryRef::moveNext() {
++Index;
}
// Returns the name of the current export symbol. If the symbol is exported only
// by ordinal, the empty string is set as a result.
std::error_code ExportDirectoryEntryRef::getDllName(StringRef &Result) const {
uintptr_t IntPtr = 0;
if (std::error_code EC =
OwningObject->getRvaPtr(ExportTable->NameRVA, IntPtr))
return EC;
Result = StringRef(reinterpret_cast<const char *>(IntPtr));
return std::error_code();
}
// Returns the starting ordinal number.
std::error_code
ExportDirectoryEntryRef::getOrdinalBase(uint32_t &Result) const {
Result = ExportTable->OrdinalBase;
return std::error_code();
}
// Returns the export ordinal of the current export symbol.
std::error_code ExportDirectoryEntryRef::getOrdinal(uint32_t &Result) const {
Result = ExportTable->OrdinalBase + Index;
return std::error_code();
}
// Returns the address of the current export symbol.
std::error_code ExportDirectoryEntryRef::getExportRVA(uint32_t &Result) const {
uintptr_t IntPtr = 0;
if (std::error_code EC =
OwningObject->getRvaPtr(ExportTable->ExportAddressTableRVA, IntPtr))
return EC;
const export_address_table_entry *entry =
reinterpret_cast<const export_address_table_entry *>(IntPtr);
Result = entry[Index].ExportRVA;
return std::error_code();
}
// Returns the name of the current export symbol. If the symbol is exported only
// by ordinal, the empty string is set as a result.
std::error_code
ExportDirectoryEntryRef::getSymbolName(StringRef &Result) const {
uintptr_t IntPtr = 0;
if (std::error_code EC =
OwningObject->getRvaPtr(ExportTable->OrdinalTableRVA, IntPtr))
return EC;
const ulittle16_t *Start = reinterpret_cast<const ulittle16_t *>(IntPtr);
uint32_t NumEntries = ExportTable->NumberOfNamePointers;
int Offset = 0;
for (const ulittle16_t *I = Start, *E = Start + NumEntries;
I < E; ++I, ++Offset) {
if (*I != Index)
continue;
if (std::error_code EC =
OwningObject->getRvaPtr(ExportTable->NamePointerRVA, IntPtr))
return EC;
const ulittle32_t *NamePtr = reinterpret_cast<const ulittle32_t *>(IntPtr);
if (std::error_code EC = OwningObject->getRvaPtr(NamePtr[Offset], IntPtr))
return EC;
Result = StringRef(reinterpret_cast<const char *>(IntPtr));
return std::error_code();
}
Result = "";
return std::error_code();
}
bool ImportedSymbolRef::
operator==(const ImportedSymbolRef &Other) const {
return Entry32 == Other.Entry32 && Entry64 == Other.Entry64
&& Index == Other.Index;
}
void ImportedSymbolRef::moveNext() {
++Index;
}
std::error_code
ImportedSymbolRef::getSymbolName(StringRef &Result) const {
uint32_t RVA;
if (Entry32) {
// If a symbol is imported only by ordinal, it has no name.
if (Entry32[Index].isOrdinal())
return std::error_code();
RVA = Entry32[Index].getHintNameRVA();
} else {
if (Entry64[Index].isOrdinal())
return std::error_code();
RVA = Entry64[Index].getHintNameRVA();
}
uintptr_t IntPtr = 0;
if (std::error_code EC = OwningObject->getRvaPtr(RVA, IntPtr))
return EC;
// +2 because the first two bytes is hint.
Result = StringRef(reinterpret_cast<const char *>(IntPtr + 2));
return std::error_code();
}
std::error_code ImportedSymbolRef::getOrdinal(uint16_t &Result) const {
uint32_t RVA;
if (Entry32) {
if (Entry32[Index].isOrdinal()) {
Result = Entry32[Index].getOrdinal();
return std::error_code();
}
RVA = Entry32[Index].getHintNameRVA();
} else {
if (Entry64[Index].isOrdinal()) {
Result = Entry64[Index].getOrdinal();
return std::error_code();
}
RVA = Entry64[Index].getHintNameRVA();
}
uintptr_t IntPtr = 0;
if (std::error_code EC = OwningObject->getRvaPtr(RVA, IntPtr))
return EC;
Result = *reinterpret_cast<const ulittle16_t *>(IntPtr);
return std::error_code();
}
ErrorOr<std::unique_ptr<COFFObjectFile>>
ObjectFile::createCOFFObjectFile(MemoryBufferRef Object) {
std::error_code EC;
std::unique_ptr<COFFObjectFile> Ret(new COFFObjectFile(Object, EC));
if (EC)
return EC;
return std::move(Ret);
}
bool BaseRelocRef::operator==(const BaseRelocRef &Other) const {
return Header == Other.Header && Index == Other.Index;
}
void BaseRelocRef::moveNext() {
// Header->BlockSize is the size of the current block, including the
// size of the header itself.
uint32_t Size = sizeof(*Header) +
sizeof(coff_base_reloc_block_entry) * (Index + 1);
if (Size == Header->BlockSize) {
// .reloc contains a list of base relocation blocks. Each block
// consists of the header followed by entries. The header contains
// how many entories will follow. When we reach the end of the
// current block, proceed to the next block.
Header = reinterpret_cast<const coff_base_reloc_block_header *>(
reinterpret_cast<const uint8_t *>(Header) + Size);
Index = 0;
} else {
++Index;
}
}
std::error_code BaseRelocRef::getType(uint8_t &Type) const {
auto *Entry = reinterpret_cast<const coff_base_reloc_block_entry *>(Header + 1);
Type = Entry[Index].getType();
return std::error_code();
}
std::error_code BaseRelocRef::getRVA(uint32_t &Result) const {
auto *Entry = reinterpret_cast<const coff_base_reloc_block_entry *>(Header + 1);
Result = Header->PageRVA + Entry[Index].getOffset();
return std::error_code();
}