CMake/Source/cmELF.cxx

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Simplify CMake per-source license notices Per-source copyright/license notice headers that spell out copyright holder names and years are hard to maintain and often out-of-date or plain wrong. Precise contributor information is already maintained automatically by the version control tool. Ultimately it is the receiver of a file who is responsible for determining its licensing status, and per-source notices are merely a convenience. Therefore it is simpler and more accurate for each source to have a generic notice of the license name and references to more detailed information on copyright holders and full license terms. Our `Copyright.txt` file now contains a list of Contributors whose names appeared source-level copyright notices. It also references version control history for more precise information. Therefore we no longer need to spell out the list of Contributors in each source file notice. Replace CMake per-source copyright/license notice headers with a short description of the license and links to `Copyright.txt` and online information available from "https://cmake.org/licensing". The online URL also handles cases of modules being copied out of our source into other projects, so we can drop our notices about replacing links with full license text. Run the `Utilities/Scripts/filter-notices.bash` script to perform the majority of the replacements mechanically. Manually fix up shebang lines and trailing newlines in a few files. Manually update the notices in a few files that the script does not handle.
2016-09-27 19:01:08 +00:00
/* Distributed under the OSI-approved BSD 3-Clause License. See accompanying
file Copyright.txt or https://cmake.org/licensing for details. */
#include "cmELF.h"
#include "cmAlgorithms.h"
#include "cm_kwiml.h"
#include "cm_memory.hxx"
#include "cmsys/FStream.hxx"
#include <map>
#include <memory>
#include <sstream>
#include <stddef.h>
#include <utility>
#include <vector>
// Include the ELF format information system header.
#if defined(__OpenBSD__)
# include <elf_abi.h>
# include <stdint.h>
#elif defined(__HAIKU__)
# include <elf32.h>
# include <elf64.h>
using Elf32_Ehdr = struct Elf32_Ehdr;
using Elf32_Shdr = struct Elf32_Shdr;
using Elf32_Sym = struct Elf32_Sym;
using Elf32_Rel = struct Elf32_Rel;
using Elf32_Rela = struct Elf32_Rela;
# define ELFMAG0 0x7F
# define ELFMAG1 'E'
# define ELFMAG2 'L'
# define ELFMAG3 'F'
# define ET_NONE 0
# define ET_REL 1
# define ET_EXEC 2
# define ET_DYN 3
# define ET_CORE 4
# define EM_386 3
# define EM_SPARC 2
# define EM_PPC 20
#else
# include <elf.h>
#endif
#if defined(__sun)
# include <sys/link.h> // For dynamic section information
#endif
#ifdef _SCO_DS
# include <link.h> // For DT_SONAME etc.
#endif
#ifndef DT_RUNPATH
# define DT_RUNPATH 29
#endif
// Low-level byte swapping implementation.
template <size_t s>
struct cmELFByteSwapSize
{
};
void cmELFByteSwap(char* /*unused*/, cmELFByteSwapSize<1> /*unused*/)
{
}
void cmELFByteSwap(char* data, cmELFByteSwapSize<2> /*unused*/)
{
char one_byte;
one_byte = data[0];
data[0] = data[1];
data[1] = one_byte;
}
void cmELFByteSwap(char* data, cmELFByteSwapSize<4> /*unused*/)
{
char one_byte;
one_byte = data[0];
data[0] = data[3];
data[3] = one_byte;
one_byte = data[1];
data[1] = data[2];
data[2] = one_byte;
}
void cmELFByteSwap(char* data, cmELFByteSwapSize<8> /*unused*/)
{
char one_byte;
one_byte = data[0];
data[0] = data[7];
data[7] = one_byte;
one_byte = data[1];
data[1] = data[6];
data[6] = one_byte;
one_byte = data[2];
data[2] = data[5];
data[5] = one_byte;
one_byte = data[3];
data[3] = data[4];
data[4] = one_byte;
}
// Low-level byte swapping interface.
template <typename T>
void cmELFByteSwap(T& x)
{
cmELFByteSwap(reinterpret_cast<char*>(&x), cmELFByteSwapSize<sizeof(T)>());
}
class cmELFInternal
{
public:
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using StringEntry = cmELF::StringEntry;
enum ByteOrderType
{
ByteOrderMSB,
ByteOrderLSB
};
// Construct and take ownership of the file stream object.
cmELFInternal(cmELF* external, std::unique_ptr<std::istream> fin,
ByteOrderType order)
: External(external)
, Stream(std::move(fin))
, ByteOrder(order)
, ELFType(cmELF::FileTypeInvalid)
{
// In most cases the processor-specific byte order will match that
// of the target execution environment. If we choose wrong here
// it is fixed when the header is read.
#if KWIML_ABI_ENDIAN_ID == KWIML_ABI_ENDIAN_ID_LITTLE
this->NeedSwap = (this->ByteOrder == ByteOrderMSB);
#elif KWIML_ABI_ENDIAN_ID == KWIML_ABI_ENDIAN_ID_BIG
this->NeedSwap = (this->ByteOrder == ByteOrderLSB);
#else
this->NeedSwap = false; // Final decision is at runtime anyway.
#endif
// We have not yet loaded the section info.
this->DynamicSectionIndex = -1;
}
// Destruct and delete the file stream object.
virtual ~cmELFInternal() = default;
// Forward to the per-class implementation.
virtual unsigned int GetNumberOfSections() const = 0;
virtual unsigned long GetDynamicEntryPosition(int j) = 0;
virtual cmELF::DynamicEntryList GetDynamicEntries() = 0;
virtual std::vector<char> EncodeDynamicEntries(
const cmELF::DynamicEntryList&) = 0;
virtual StringEntry const* GetDynamicSectionString(unsigned int tag) = 0;
virtual void PrintInfo(std::ostream& os) const = 0;
// Lookup the SONAME in the DYNAMIC section.
StringEntry const* GetSOName()
{
return this->GetDynamicSectionString(DT_SONAME);
}
// Lookup the RPATH in the DYNAMIC section.
StringEntry const* GetRPath()
{
return this->GetDynamicSectionString(DT_RPATH);
}
// Lookup the RUNPATH in the DYNAMIC section.
StringEntry const* GetRunPath()
{
return this->GetDynamicSectionString(DT_RUNPATH);
}
// Return the recorded ELF type.
cmELF::FileType GetFileType() const { return this->ELFType; }
protected:
// Data common to all ELF class implementations.
// The external cmELF object.
cmELF* External;
// The stream from which to read.
std::unique_ptr<std::istream> Stream;
// The byte order of the ELF file.
ByteOrderType ByteOrder;
// The ELF file type.
cmELF::FileType ELFType;
// Whether we need to byte-swap structures read from the stream.
bool NeedSwap;
// The section header index of the DYNAMIC section (-1 if none).
int DynamicSectionIndex;
// Helper methods for subclasses.
void SetErrorMessage(const char* msg)
{
this->External->ErrorMessage = msg;
this->ELFType = cmELF::FileTypeInvalid;
}
// Store string table entry states.
std::map<unsigned int, StringEntry> DynamicSectionStrings;
};
// Configure the implementation template for 32-bit ELF files.
struct cmELFTypes32
{
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using ELF_Ehdr = Elf32_Ehdr;
using ELF_Shdr = Elf32_Shdr;
using ELF_Dyn = Elf32_Dyn;
using ELF_Half = Elf32_Half;
using tagtype = ::uint32_t;
static const char* GetName() { return "32-bit"; }
};
// Configure the implementation template for 64-bit ELF files.
#ifndef _SCO_DS
struct cmELFTypes64
{
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using ELF_Ehdr = Elf64_Ehdr;
using ELF_Shdr = Elf64_Shdr;
using ELF_Dyn = Elf64_Dyn;
using ELF_Half = Elf64_Half;
using tagtype = ::uint64_t;
static const char* GetName() { return "64-bit"; }
};
#endif
// Parser implementation template.
template <class Types>
class cmELFInternalImpl : public cmELFInternal
{
public:
// Copy the ELF file format types from our configuration parameter.
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using ELF_Ehdr = typename Types::ELF_Ehdr;
using ELF_Shdr = typename Types::ELF_Shdr;
using ELF_Dyn = typename Types::ELF_Dyn;
using ELF_Half = typename Types::ELF_Half;
using tagtype = typename Types::tagtype;
// Construct with a stream and byte swap indicator.
cmELFInternalImpl(cmELF* external, std::unique_ptr<std::istream> fin,
ByteOrderType order);
// Return the number of sections as specified by the ELF header.
unsigned int GetNumberOfSections() const override
{
return static_cast<unsigned int>(this->ELFHeader.e_shnum);
}
// Get the file position of a dynamic section entry.
unsigned long GetDynamicEntryPosition(int j) override;
cmELF::DynamicEntryList GetDynamicEntries() override;
std::vector<char> EncodeDynamicEntries(
const cmELF::DynamicEntryList&) override;
// Lookup a string from the dynamic section with the given tag.
StringEntry const* GetDynamicSectionString(unsigned int tag) override;
// Print information about the ELF file.
void PrintInfo(std::ostream& os) const override
{
os << "ELF " << Types::GetName();
if (this->ByteOrder == ByteOrderMSB) {
os << " MSB";
} else if (this->ByteOrder == ByteOrderLSB) {
os << " LSB";
}
switch (this->ELFType) {
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case cmELF::FileTypeInvalid:
os << " invalid file";
break;
case cmELF::FileTypeRelocatableObject:
os << " relocatable object";
break;
case cmELF::FileTypeExecutable:
os << " executable";
break;
case cmELF::FileTypeSharedLibrary:
os << " shared library";
break;
case cmELF::FileTypeCore:
os << " core file";
break;
case cmELF::FileTypeSpecificOS:
os << " os-specific type";
break;
case cmELF::FileTypeSpecificProc:
os << " processor-specific type";
break;
}
os << "\n";
}
private:
static_assert(sizeof(ELF_Dyn().d_un.d_val) == sizeof(ELF_Dyn().d_un.d_ptr),
"ByteSwap(ELF_Dyn) assumes d_val and d_ptr are the same size");
void ByteSwap(ELF_Ehdr& elf_header)
{
cmELFByteSwap(elf_header.e_type);
cmELFByteSwap(elf_header.e_machine);
cmELFByteSwap(elf_header.e_version);
cmELFByteSwap(elf_header.e_entry);
cmELFByteSwap(elf_header.e_phoff);
cmELFByteSwap(elf_header.e_shoff);
cmELFByteSwap(elf_header.e_flags);
cmELFByteSwap(elf_header.e_ehsize);
cmELFByteSwap(elf_header.e_phentsize);
cmELFByteSwap(elf_header.e_phnum);
cmELFByteSwap(elf_header.e_shentsize);
cmELFByteSwap(elf_header.e_shnum);
cmELFByteSwap(elf_header.e_shstrndx);
}
void ByteSwap(ELF_Shdr& sec_header)
{
cmELFByteSwap(sec_header.sh_name);
cmELFByteSwap(sec_header.sh_type);
cmELFByteSwap(sec_header.sh_flags);
cmELFByteSwap(sec_header.sh_addr);
cmELFByteSwap(sec_header.sh_offset);
cmELFByteSwap(sec_header.sh_size);
cmELFByteSwap(sec_header.sh_link);
cmELFByteSwap(sec_header.sh_info);
cmELFByteSwap(sec_header.sh_addralign);
cmELFByteSwap(sec_header.sh_entsize);
}
void ByteSwap(ELF_Dyn& dyn)
{
cmELFByteSwap(dyn.d_tag);
cmELFByteSwap(dyn.d_un.d_val);
}
bool FileTypeValid(ELF_Half et)
{
unsigned int eti = static_cast<unsigned int>(et);
if (eti == ET_NONE || eti == ET_REL || eti == ET_EXEC || eti == ET_DYN ||
eti == ET_CORE) {
return true;
}
#if defined(ET_LOOS) && defined(ET_HIOS)
if (eti >= ET_LOOS && eti <= ET_HIOS) {
return true;
}
#endif
#if defined(ET_LOPROC) && defined(ET_HIPROC)
if (eti >= ET_LOPROC && eti <= ET_HIPROC) {
return true;
}
#endif
return false;
}
bool Read(ELF_Ehdr& x)
{
// Read the header from the file.
if (!this->Stream->read(reinterpret_cast<char*>(&x), sizeof(x))) {
return false;
}
// The byte order of ELF header fields may not match that of the
// processor-specific data. The header fields are ordered to
// match the target execution environment, so we may need to
// memorize the order of all platforms based on the e_machine
// value. As a heuristic, if the type is invalid but its
// swapped value is okay then flip our swap mode.
ELF_Half et = x.e_type;
if (this->NeedSwap) {
cmELFByteSwap(et);
}
if (!this->FileTypeValid(et)) {
cmELFByteSwap(et);
if (this->FileTypeValid(et)) {
// The previous byte order guess was wrong. Flip it.
this->NeedSwap = !this->NeedSwap;
}
}
// Fix the byte order of the header.
if (this->NeedSwap) {
ByteSwap(x);
}
return true;
}
bool Read(ELF_Shdr& x)
{
if (this->Stream->read(reinterpret_cast<char*>(&x), sizeof(x)) &&
this->NeedSwap) {
ByteSwap(x);
}
return !this->Stream->fail();
}
bool Read(ELF_Dyn& x)
{
if (this->Stream->read(reinterpret_cast<char*>(&x), sizeof(x)) &&
this->NeedSwap) {
ByteSwap(x);
}
return !this->Stream->fail();
}
bool LoadSectionHeader(ELF_Half i)
{
// Read the section header from the file.
this->Stream->seekg(this->ELFHeader.e_shoff +
this->ELFHeader.e_shentsize * i);
if (!this->Read(this->SectionHeaders[i])) {
return false;
}
// Identify some important sections.
if (this->SectionHeaders[i].sh_type == SHT_DYNAMIC) {
this->DynamicSectionIndex = i;
}
return true;
}
bool LoadDynamicSection();
// Store the main ELF header.
ELF_Ehdr ELFHeader;
// Store all the section headers.
std::vector<ELF_Shdr> SectionHeaders;
// Store all entries of the DYNAMIC section.
std::vector<ELF_Dyn> DynamicSectionEntries;
};
template <class Types>
cmELFInternalImpl<Types>::cmELFInternalImpl(cmELF* external,
std::unique_ptr<std::istream> fin,
ByteOrderType order)
: cmELFInternal(external, std::move(fin), order)
{
// Read the main header.
if (!this->Read(this->ELFHeader)) {
this->SetErrorMessage("Failed to read main ELF header.");
return;
}
// Determine the ELF file type.
switch (this->ELFHeader.e_type) {
case ET_NONE:
this->SetErrorMessage("ELF file type is NONE.");
return;
case ET_REL:
this->ELFType = cmELF::FileTypeRelocatableObject;
break;
case ET_EXEC:
this->ELFType = cmELF::FileTypeExecutable;
break;
case ET_DYN:
this->ELFType = cmELF::FileTypeSharedLibrary;
break;
case ET_CORE:
this->ELFType = cmELF::FileTypeCore;
break;
default: {
unsigned int eti = static_cast<unsigned int>(this->ELFHeader.e_type);
#if defined(ET_LOOS) && defined(ET_HIOS)
if (eti >= ET_LOOS && eti <= ET_HIOS) {
this->ELFType = cmELF::FileTypeSpecificOS;
break;
}
#endif
#if defined(ET_LOPROC) && defined(ET_HIPROC)
if (eti >= ET_LOPROC && eti <= ET_HIPROC) {
this->ELFType = cmELF::FileTypeSpecificProc;
break;
}
#endif
std::ostringstream e;
e << "Unknown ELF file type " << eti;
this->SetErrorMessage(e.str().c_str());
return;
}
}
// Load the section headers.
this->SectionHeaders.resize(this->ELFHeader.e_shnum);
for (ELF_Half i = 0; i < this->ELFHeader.e_shnum; ++i) {
if (!this->LoadSectionHeader(i)) {
this->SetErrorMessage("Failed to load section headers.");
return;
}
}
}
template <class Types>
bool cmELFInternalImpl<Types>::LoadDynamicSection()
{
// If there is no dynamic section we are done.
if (this->DynamicSectionIndex < 0) {
return false;
}
// If the section was already loaded we are done.
if (!this->DynamicSectionEntries.empty()) {
return true;
}
// If there are no entries we are done.
ELF_Shdr const& sec = this->SectionHeaders[this->DynamicSectionIndex];
if (sec.sh_entsize == 0) {
return false;
}
// Allocate the dynamic section entries.
int n = static_cast<int>(sec.sh_size / sec.sh_entsize);
this->DynamicSectionEntries.resize(n);
// Read each entry.
for (int j = 0; j < n; ++j) {
// Seek to the beginning of the section entry.
this->Stream->seekg(sec.sh_offset + sec.sh_entsize * j);
ELF_Dyn& dyn = this->DynamicSectionEntries[j];
// Try reading the entry.
if (!this->Read(dyn)) {
this->SetErrorMessage("Error reading entry from DYNAMIC section.");
this->DynamicSectionIndex = -1;
return false;
}
}
return true;
}
template <class Types>
unsigned long cmELFInternalImpl<Types>::GetDynamicEntryPosition(int j)
{
if (!this->LoadDynamicSection()) {
return 0;
}
if (j < 0 || j >= static_cast<int>(this->DynamicSectionEntries.size())) {
return 0;
}
ELF_Shdr const& sec = this->SectionHeaders[this->DynamicSectionIndex];
return static_cast<unsigned long>(sec.sh_offset + sec.sh_entsize * j);
}
template <class Types>
cmELF::DynamicEntryList cmELFInternalImpl<Types>::GetDynamicEntries()
{
cmELF::DynamicEntryList result;
// Ensure entries have been read from file
if (!this->LoadDynamicSection()) {
return result;
}
// Copy into public array
result.reserve(this->DynamicSectionEntries.size());
for (ELF_Dyn& dyn : this->DynamicSectionEntries) {
result.emplace_back(dyn.d_tag, dyn.d_un.d_val);
}
return result;
}
template <class Types>
std::vector<char> cmELFInternalImpl<Types>::EncodeDynamicEntries(
const cmELF::DynamicEntryList& entries)
{
std::vector<char> result;
result.reserve(sizeof(ELF_Dyn) * entries.size());
for (auto const& entry : entries) {
// Store the entry in an ELF_Dyn, byteswap it, then serialize to chars
ELF_Dyn dyn;
dyn.d_tag = static_cast<tagtype>(entry.first);
dyn.d_un.d_val = static_cast<tagtype>(entry.second);
if (this->NeedSwap) {
ByteSwap(dyn);
}
char* pdyn = reinterpret_cast<char*>(&dyn);
cmAppend(result, pdyn, pdyn + sizeof(ELF_Dyn));
}
return result;
}
template <class Types>
cmELF::StringEntry const* cmELFInternalImpl<Types>::GetDynamicSectionString(
unsigned int tag)
{
// Short-circuit if already checked.
std::map<unsigned int, StringEntry>::iterator dssi =
this->DynamicSectionStrings.find(tag);
if (dssi != this->DynamicSectionStrings.end()) {
if (dssi->second.Position > 0) {
return &dssi->second;
}
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return nullptr;
}
// Create an entry for this tag. Assume it is missing until found.
StringEntry& se = this->DynamicSectionStrings[tag];
se.Position = 0;
se.Size = 0;
se.IndexInSection = -1;
// Try reading the dynamic section.
if (!this->LoadDynamicSection()) {
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return nullptr;
}
// Get the string table referenced by the DYNAMIC section.
ELF_Shdr const& sec = this->SectionHeaders[this->DynamicSectionIndex];
if (sec.sh_link >= this->SectionHeaders.size()) {
this->SetErrorMessage("Section DYNAMIC has invalid string table index.");
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return nullptr;
}
ELF_Shdr const& strtab = this->SectionHeaders[sec.sh_link];
// Look for the requested entry.
for (typename std::vector<ELF_Dyn>::iterator di =
this->DynamicSectionEntries.begin();
di != this->DynamicSectionEntries.end(); ++di) {
ELF_Dyn& dyn = *di;
if (static_cast<tagtype>(dyn.d_tag) == static_cast<tagtype>(tag)) {
// We found the tag requested.
// Make sure the position given is within the string section.
if (dyn.d_un.d_val >= strtab.sh_size) {
this->SetErrorMessage("Section DYNAMIC references string beyond "
"the end of its string section.");
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return nullptr;
}
// Seek to the position reported by the entry.
unsigned long first = static_cast<unsigned long>(dyn.d_un.d_val);
unsigned long last = first;
unsigned long end = static_cast<unsigned long>(strtab.sh_size);
this->Stream->seekg(strtab.sh_offset + first);
// Read the string. It may be followed by more than one NULL
// terminator. Count the total size of the region allocated to
// the string. This assumes that the next string in the table
// is non-empty, but the "chrpath" tool makes the same
// assumption.
bool terminated = false;
char c;
while (last != end && this->Stream->get(c) && !(terminated && c)) {
++last;
if (c) {
se.Value += c;
} else {
terminated = true;
}
}
// Make sure the whole value was read.
if (!(*this->Stream)) {
this->SetErrorMessage("Dynamic section specifies unreadable RPATH.");
se.Value = "";
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return nullptr;
}
// The value has been read successfully. Report it.
se.Position = static_cast<unsigned long>(strtab.sh_offset + first);
se.Size = last - first;
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se.IndexInSection =
static_cast<int>(di - this->DynamicSectionEntries.begin());
return &se;
}
}
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return nullptr;
}
//============================================================================
// External class implementation.
const long cmELF::TagRPath = DT_RPATH;
const long cmELF::TagRunPath = DT_RUNPATH;
#ifdef DT_MIPS_RLD_MAP_REL
const long cmELF::TagMipsRldMapRel = DT_MIPS_RLD_MAP_REL;
#else
const long cmELF::TagMipsRldMapRel = 0;
#endif
cmELF::cmELF(const char* fname)
{
// Try to open the file.
auto fin = cm::make_unique<cmsys::ifstream>(fname);
// Quit now if the file could not be opened.
if (!fin || !*fin) {
this->ErrorMessage = "Error opening input file.";
return;
}
// Read the ELF identification block.
char ident[EI_NIDENT];
if (!fin->read(ident, EI_NIDENT)) {
this->ErrorMessage = "Error reading ELF identification.";
return;
}
if (!fin->seekg(0)) {
this->ErrorMessage = "Error seeking to beginning of file.";
return;
}
// Verify the ELF identification.
if (!(ident[EI_MAG0] == ELFMAG0 && ident[EI_MAG1] == ELFMAG1 &&
ident[EI_MAG2] == ELFMAG2 && ident[EI_MAG3] == ELFMAG3)) {
this->ErrorMessage = "File does not have a valid ELF identification.";
return;
}
// Check the byte order in which the rest of the file is encoded.
cmELFInternal::ByteOrderType order;
if (ident[EI_DATA] == ELFDATA2LSB) {
// File is LSB.
order = cmELFInternal::ByteOrderLSB;
} else if (ident[EI_DATA] == ELFDATA2MSB) {
// File is MSB.
order = cmELFInternal::ByteOrderMSB;
} else {
this->ErrorMessage = "ELF file is not LSB or MSB encoded.";
return;
}
// Check the class of the file and construct the corresponding
// parser implementation.
if (ident[EI_CLASS] == ELFCLASS32) {
// 32-bit ELF
this->Internal = cm::make_unique<cmELFInternalImpl<cmELFTypes32>>(
this, std::move(fin), order);
}
#ifndef _SCO_DS
else if (ident[EI_CLASS] == ELFCLASS64) {
// 64-bit ELF
this->Internal = cm::make_unique<cmELFInternalImpl<cmELFTypes64>>(
this, std::move(fin), order);
}
#endif
else {
this->ErrorMessage = "ELF file class is not 32-bit or 64-bit.";
return;
}
}
cmELF::~cmELF() = default;
bool cmELF::Valid() const
{
return this->Internal && this->Internal->GetFileType() != FileTypeInvalid;
}
cmELF::FileType cmELF::GetFileType() const
{
if (this->Valid()) {
return this->Internal->GetFileType();
}
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return FileTypeInvalid;
}
unsigned int cmELF::GetNumberOfSections() const
{
if (this->Valid()) {
return this->Internal->GetNumberOfSections();
}
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return 0;
}
unsigned long cmELF::GetDynamicEntryPosition(int index) const
{
if (this->Valid()) {
return this->Internal->GetDynamicEntryPosition(index);
}
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return 0;
}
cmELF::DynamicEntryList cmELF::GetDynamicEntries() const
{
if (this->Valid()) {
return this->Internal->GetDynamicEntries();
}
return cmELF::DynamicEntryList();
}
std::vector<char> cmELF::EncodeDynamicEntries(
const cmELF::DynamicEntryList& dentries) const
{
if (this->Valid()) {
return this->Internal->EncodeDynamicEntries(dentries);
}
return std::vector<char>();
}
bool cmELF::GetSOName(std::string& soname)
{
if (StringEntry const* se = this->GetSOName()) {
soname = se->Value;
return true;
}
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return false;
}
cmELF::StringEntry const* cmELF::GetSOName()
{
if (this->Valid() &&
this->Internal->GetFileType() == cmELF::FileTypeSharedLibrary) {
return this->Internal->GetSOName();
}
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return nullptr;
}
cmELF::StringEntry const* cmELF::GetRPath()
{
if (this->Valid() &&
(this->Internal->GetFileType() == cmELF::FileTypeExecutable ||
this->Internal->GetFileType() == cmELF::FileTypeSharedLibrary)) {
return this->Internal->GetRPath();
}
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return nullptr;
}
cmELF::StringEntry const* cmELF::GetRunPath()
{
if (this->Valid() &&
(this->Internal->GetFileType() == cmELF::FileTypeExecutable ||
this->Internal->GetFileType() == cmELF::FileTypeSharedLibrary)) {
return this->Internal->GetRunPath();
}
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return nullptr;
}
void cmELF::PrintInfo(std::ostream& os) const
{
if (this->Valid()) {
this->Internal->PrintInfo(os);
} else {
os << "Not a valid ELF file.\n";
}
}