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android / platform / art / 1961b60 / . / compiler / elf_builder.h
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/*
* Copyright (C) 2014 The Android Open Source Project
*
* Licensed under the Apache License, Version 2.0 (the "License");
* you may not use this file except in compliance with the License.
* You may obtain a copy of the License at
*
* http://www.apache.org/licenses/LICENSE-2.0
*
* Unless required by applicable law or agreed to in writing, software
* distributed under the License is distributed on an "AS IS" BASIS,
* WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
* See the License for the specific language governing permissions and
* limitations under the License.
*/
#ifndef ART_COMPILER_ELF_BUILDER_H_
#define ART_COMPILER_ELF_BUILDER_H_
#include "arch/instruction_set.h"
#include "base/stl_util.h"
#include "base/value_object.h"
#include "buffered_output_stream.h"
#include "elf_utils.h"
#include "file_output_stream.h"
namespace art {
template <typename Elf_Word, typename Elf_Sword, typename Elf_Shdr>
class ElfSectionBuilder : public ValueObject {
public:
ElfSectionBuilder(const std::string& sec_name, Elf_Word type, Elf_Word flags,
const ElfSectionBuilder<Elf_Word, Elf_Sword, Elf_Shdr> *link, Elf_Word info,
Elf_Word align, Elf_Word entsize)
: section_index_(0), name_(sec_name), link_(link) {
memset(&section_, 0, sizeof(section_));
section_.sh_type = type;
section_.sh_flags = flags;
section_.sh_info = info;
section_.sh_addralign = align;
section_.sh_entsize = entsize;
}
ElfSectionBuilder(const ElfSectionBuilder&) = default;
~ElfSectionBuilder() {}
Elf_Word GetLink() const {
return (link_ != nullptr) ? link_->section_index_ : 0;
}
const Elf_Shdr* GetSection() const {
return &section_;
}
Elf_Shdr* GetSection() {
return &section_;
}
Elf_Word GetSectionIndex() const {
return section_index_;
}
void SetSectionIndex(Elf_Word section_index) {
section_index_ = section_index;
}
const std::string& GetName() const {
return name_;
}
private:
Elf_Shdr section_;
Elf_Word section_index_;
const std::string name_;
const ElfSectionBuilder* const link_;
};
template <typename Elf_Word, typename Elf_Sword, typename Elf_Dyn, typename Elf_Shdr>
class ElfDynamicBuilder FINAL : public ElfSectionBuilder<Elf_Word, Elf_Sword, Elf_Shdr> {
public:
void AddDynamicTag(Elf_Sword tag, Elf_Word d_un) {
if (tag == DT_NULL) {
return;
}
dynamics_.push_back({nullptr, tag, d_un});
}
void AddDynamicTag(Elf_Sword tag, Elf_Word d_un,
const ElfSectionBuilder<Elf_Word, Elf_Sword, Elf_Shdr>* section) {
if (tag == DT_NULL) {
return;
}
dynamics_.push_back({section, tag, d_un});
}
ElfDynamicBuilder(const std::string& sec_name,
ElfSectionBuilder<Elf_Word, Elf_Sword, Elf_Shdr> *link)
: ElfSectionBuilder<Elf_Word, Elf_Sword, Elf_Shdr>(sec_name, SHT_DYNAMIC, SHF_ALLOC | SHF_ALLOC,
link, 0, kPageSize, sizeof(Elf_Dyn)) {}
~ElfDynamicBuilder() {}
Elf_Word GetSize() const {
// Add 1 for the DT_NULL, 1 for DT_STRSZ, and 1 for DT_SONAME. All of
// these must be added when we actually put the file together because
// their values are very dependent on state.
return dynamics_.size() + 3;
}
// Create the actual dynamic vector. strsz should be the size of the .dynstr
// table and soname_off should be the offset of the soname in .dynstr.
// Since niether can be found prior to final layout we will wait until here
// to add them.
std::vector<Elf_Dyn> GetDynamics(Elf_Word strsz, Elf_Word soname) const {
std::vector<Elf_Dyn> ret;
for (auto it = dynamics_.cbegin(); it != dynamics_.cend(); ++it) {
if (it->section_ != nullptr) {
// We are adding an address relative to a section.
ret.push_back(
{it->tag_, {it->off_ + it->section_->GetSection()->sh_addr}});
} else {
ret.push_back({it->tag_, {it->off_}});
}
}
ret.push_back({DT_STRSZ, {strsz}});
ret.push_back({DT_SONAME, {soname}});
ret.push_back({DT_NULL, {0}});
return ret;
}
private:
struct ElfDynamicState {
const ElfSectionBuilder<Elf_Word, Elf_Sword, Elf_Shdr>* section_;
Elf_Sword tag_;
Elf_Word off_;
};
std::vector<ElfDynamicState> dynamics_;
};
template <typename Elf_Word, typename Elf_Sword, typename Elf_Shdr>
class ElfRawSectionBuilder FINAL : public ElfSectionBuilder<Elf_Word, Elf_Sword, Elf_Shdr> {
public:
ElfRawSectionBuilder(const std::string& sec_name, Elf_Word type, Elf_Word flags,
const ElfSectionBuilder<Elf_Word, Elf_Sword, Elf_Shdr>* link, Elf_Word info,
Elf_Word align, Elf_Word entsize)
: ElfSectionBuilder<Elf_Word, Elf_Sword, Elf_Shdr>(sec_name, type, flags, link, info, align,
entsize) {
}
ElfRawSectionBuilder(const ElfRawSectionBuilder&) = default;
~ElfRawSectionBuilder() {}
std::vector<uint8_t>* GetBuffer() {
return &buf_;
}
void SetBuffer(const std::vector<uint8_t>& buf) {
buf_ = buf;
}
private:
std::vector<uint8_t> buf_;
};
template <typename Elf_Word, typename Elf_Sword, typename Elf_Shdr>
class ElfOatSectionBuilder FINAL : public ElfSectionBuilder<Elf_Word, Elf_Sword, Elf_Shdr> {
public:
ElfOatSectionBuilder(const std::string& sec_name, Elf_Word size, Elf_Word offset,
Elf_Word type, Elf_Word flags)
: ElfSectionBuilder<Elf_Word, Elf_Sword, Elf_Shdr>(sec_name, type, flags, nullptr, 0, kPageSize,
0),
offset_(offset), size_(size) {
}
~ElfOatSectionBuilder() {}
Elf_Word GetOffset() const {
return offset_;
}
Elf_Word GetSize() const {
return size_;
}
private:
// Offset of the content within the file.
Elf_Word offset_;
// Size of the content within the file.
Elf_Word size_;
};
static inline constexpr uint8_t MakeStInfo(uint8_t binding, uint8_t type) {
return ((binding) << 4) + ((type) & 0xf);
}
// from bionic
static inline unsigned elfhash(const char *_name) {
const unsigned char *name = (const unsigned char *) _name;
unsigned h = 0, g;
while (*name) {
h = (h << 4) + *name++;
g = h & 0xf0000000;
h ^= g;
h ^= g >> 24;
}
return h;
}
template <typename Elf_Word, typename Elf_Sword, typename Elf_Addr, typename Elf_Sym,
typename Elf_Shdr>
class ElfSymtabBuilder FINAL : public ElfSectionBuilder<Elf_Word, Elf_Sword, Elf_Shdr> {
public:
// Add a symbol with given name to this symtab. The symbol refers to
// 'relative_addr' within the given section and has the given attributes.
void AddSymbol(const std::string& name,
const ElfSectionBuilder<Elf_Word, Elf_Sword, Elf_Shdr>* section,
Elf_Addr addr,
bool is_relative,
Elf_Word size,
uint8_t binding,
uint8_t type,
uint8_t other = 0) {
CHECK(section);
ElfSymtabBuilder::ElfSymbolState state {name, section, addr, size, is_relative,
MakeStInfo(binding, type), other, 0};
symbols_.push_back(state);
}
ElfSymtabBuilder(const std::string& sec_name, Elf_Word type,
const std::string& str_name, Elf_Word str_type, bool alloc)
: ElfSectionBuilder<Elf_Word, Elf_Sword, Elf_Shdr>(sec_name, type, ((alloc) ? SHF_ALLOC : 0U),
&strtab_, 0, sizeof(Elf_Word),
sizeof(Elf_Sym)), str_name_(str_name),
str_type_(str_type),
strtab_(str_name,
str_type,
((alloc) ? SHF_ALLOC : 0U),
nullptr, 0, 1, 1) {
}
~ElfSymtabBuilder() {}
std::vector<Elf_Word> GenerateHashContents() const {
// Here is how The ELF hash table works.
// There are 3 arrays to worry about.
// * The symbol table where the symbol information is.
// * The bucket array which is an array of indexes into the symtab and chain.
// * The chain array which is also an array of indexes into the symtab and chain.
//
// Lets say the state is something like this.
// +--------+ +--------+ +-----------+
// | symtab | | bucket | | chain |
// | null | | 1 | | STN_UNDEF |
// | <sym1> | | 4 | | 2 |
// | <sym2> | | | | 5 |
// | <sym3> | | | | STN_UNDEF |
// | <sym4> | | | | 3 |
// | <sym5> | | | | STN_UNDEF |
// +--------+ +--------+ +-----------+
//
// The lookup process (in python psudocode) is
//
// def GetSym(name):
// # NB STN_UNDEF == 0
// indx = bucket[elfhash(name) % num_buckets]
// while indx != STN_UNDEF:
// if GetSymbolName(symtab[indx]) == name:
// return symtab[indx]
// indx = chain[indx]
// return SYMBOL_NOT_FOUND
//
// Between bucket and chain arrays every symtab index must be present exactly
// once (except for STN_UNDEF, which must be present 1 + num_bucket times).
// Select number of buckets.
// This is essentially arbitrary.
Elf_Word nbuckets;
Elf_Word chain_size = GetSize();
if (symbols_.size() < 8) {
nbuckets = 2;
} else if (symbols_.size() < 32) {
nbuckets = 4;
} else if (symbols_.size() < 256) {
nbuckets = 16;
} else {
// Have about 32 ids per bucket.
nbuckets = RoundUp(symbols_.size()/32, 2);
}
std::vector<Elf_Word> hash;
hash.push_back(nbuckets);
hash.push_back(chain_size);
uint32_t bucket_offset = hash.size();
uint32_t chain_offset = bucket_offset + nbuckets;
hash.resize(hash.size() + nbuckets + chain_size, 0);
Elf_Word* buckets = hash.data() + bucket_offset;
Elf_Word* chain = hash.data() + chain_offset;
// Set up the actual hash table.
for (Elf_Word i = 0; i < symbols_.size(); i++) {
// Add 1 since we need to have the null symbol that is not in the symbols
// list.
Elf_Word index = i + 1;
Elf_Word hash_val = static_cast<Elf_Word>(elfhash(symbols_[i].name_.c_str())) % nbuckets;
if (buckets[hash_val] == 0) {
buckets[hash_val] = index;
} else {
hash_val = buckets[hash_val];
CHECK_LT(hash_val, chain_size);
while (chain[hash_val] != 0) {
hash_val = chain[hash_val];
CHECK_LT(hash_val, chain_size);
}
chain[hash_val] = index;
// Check for loops. Works because if this is non-empty then there must be
// another cell which already contains the same symbol index as this one,
// which means some symbol has more then one name, which isn't allowed.
CHECK_EQ(chain[index], static_cast<Elf_Word>(0));
}
}
return hash;
}
std::string GenerateStrtab() {
std::string tab;
tab += '\0';
for (auto it = symbols_.begin(); it != symbols_.end(); ++it) {
it->name_idx_ = tab.size();
tab += it->name_;
tab += '\0';
}
strtab_.GetSection()->sh_size = tab.size();
return tab;
}
std::vector<Elf_Sym> GenerateSymtab() {
std::vector<Elf_Sym> ret;
Elf_Sym undef_sym;
memset(&undef_sym, 0, sizeof(undef_sym));
undef_sym.st_shndx = SHN_UNDEF;
ret.push_back(undef_sym);
for (auto it = symbols_.cbegin(); it != symbols_.cend(); ++it) {
Elf_Sym sym;
memset(&sym, 0, sizeof(sym));
sym.st_name = it->name_idx_;
if (it->is_relative_) {
sym.st_value = it->addr_ + it->section_->GetSection()->sh_offset;
} else {
sym.st_value = it->addr_;
}
sym.st_size = it->size_;
sym.st_other = it->other_;
sym.st_shndx = it->section_->GetSectionIndex();
sym.st_info = it->info_;
ret.push_back(sym);
}
return ret;
}
Elf_Word GetSize() const {
// 1 is for the implicit NULL symbol.
return symbols_.size() + 1;
}
ElfSectionBuilder<Elf_Word, Elf_Sword, Elf_Shdr>* GetStrTab() {
return &strtab_;
}
private:
struct ElfSymbolState {
const std::string name_;
const ElfSectionBuilder<Elf_Word, Elf_Sword, Elf_Shdr>* section_;
Elf_Addr addr_;
Elf_Word size_;
bool is_relative_;
uint8_t info_;
uint8_t other_;
// Used during Write() to temporarially hold name index in the strtab.
Elf_Word name_idx_;
};
// Information for the strsym for dynstr sections.
const std::string str_name_;
Elf_Word str_type_;
// The symbols in the same order they will be in the symbol table.
std::vector<ElfSymbolState> symbols_;
ElfSectionBuilder<Elf_Word, Elf_Sword, Elf_Shdr> strtab_;
};
template <typename Elf_Word>
class ElfFilePiece {
public:
virtual ~ElfFilePiece() {}
virtual bool Write(File* elf_file) {
if (static_cast<off_t>(offset_) != lseek(elf_file->Fd(), offset_, SEEK_SET)) {
PLOG(ERROR) << "Failed to seek to " << GetDescription() << " offset " << offset_ << " for "
<< elf_file->GetPath();
return false;
}
return DoActualWrite(elf_file);
}
static bool Compare(ElfFilePiece* a, ElfFilePiece* b) {
return a->offset_ < b->offset_;
}
protected:
explicit ElfFilePiece(Elf_Word offset) : offset_(offset) {}
Elf_Word GetOffset() const {
return offset_;
}
virtual const char* GetDescription() const = 0;
virtual bool DoActualWrite(File* elf_file) = 0;
private:
const Elf_Word offset_;
DISALLOW_COPY_AND_ASSIGN(ElfFilePiece);
};
template <typename Elf_Word>
class ElfFileMemoryPiece FINAL : public ElfFilePiece<Elf_Word> {
public:
ElfFileMemoryPiece(const std::string& name, Elf_Word offset, const void* data, Elf_Word size)
: ElfFilePiece<Elf_Word>(offset), dbg_name_(name), data_(data), size_(size) {}
protected:
bool DoActualWrite(File* elf_file) OVERRIDE {
DCHECK(data_ != nullptr || size_ == 0U) << dbg_name_ << " " << size_;
if (!elf_file->WriteFully(data_, size_)) {
PLOG(ERROR) << "Failed to write " << dbg_name_ << " for " << elf_file->GetPath();
return false;
}
return true;
}
const char* GetDescription() const OVERRIDE {
return dbg_name_.c_str();
}
private:
const std::string& dbg_name_;
const void *data_;
Elf_Word size_;
};
class CodeOutput {
public:
virtual void SetCodeOffset(size_t offset) = 0;
virtual bool Write(OutputStream* out) = 0;
virtual ~CodeOutput() {}
};
template <typename Elf_Word>
class ElfFileRodataPiece FINAL : public ElfFilePiece<Elf_Word> {
public:
ElfFileRodataPiece(Elf_Word offset, CodeOutput* output) : ElfFilePiece<Elf_Word>(offset),
output_(output) {}
protected:
bool DoActualWrite(File* elf_file) OVERRIDE {
output_->SetCodeOffset(this->GetOffset());
std::unique_ptr<BufferedOutputStream> output_stream(
new BufferedOutputStream(new FileOutputStream(elf_file)));
if (!output_->Write(output_stream.get())) {
PLOG(ERROR) << "Failed to write .rodata and .text for " << elf_file->GetPath();
return false;
}
return true;
}
const char* GetDescription() const OVERRIDE {
return ".rodata";
}
private:
CodeOutput* const output_;
DISALLOW_COPY_AND_ASSIGN(ElfFileRodataPiece);
};
template <typename Elf_Word>
class ElfFileOatTextPiece FINAL : public ElfFilePiece<Elf_Word> {
public:
ElfFileOatTextPiece(Elf_Word offset, CodeOutput* output) : ElfFilePiece<Elf_Word>(offset),
output_(output) {}
protected:
bool DoActualWrite(File* elf_file ATTRIBUTE_UNUSED) OVERRIDE {
// All data is written by the ElfFileRodataPiece right now, as the oat writer writes in one
// piece. This is for future flexibility.
UNUSED(output_);
return true;
}
const char* GetDescription() const OVERRIDE {
return ".text";
}
private:
CodeOutput* const output_;
DISALLOW_COPY_AND_ASSIGN(ElfFileOatTextPiece);
};
template <typename Elf_Word>
static bool WriteOutFile(const std::vector<ElfFilePiece<Elf_Word>*>& pieces, File* elf_file) {
// TODO It would be nice if this checked for overlap.
for (auto it = pieces.begin(); it != pieces.end(); ++it) {
if (!(*it)->Write(elf_file)) {
return false;
}
}
return true;
}
template <typename Elf_Word, typename Elf_Shdr>
static inline constexpr Elf_Word NextOffset(const Elf_Shdr& cur, const Elf_Shdr& prev) {
return RoundUp(prev.sh_size + prev.sh_offset, cur.sh_addralign);
}
template <typename Elf_Word, typename Elf_Sword, typename Elf_Addr, typename Elf_Dyn,
typename Elf_Sym, typename Elf_Ehdr, typename Elf_Phdr, typename Elf_Shdr>
class ElfBuilder FINAL {
public:
ElfBuilder(CodeOutput* oat_writer,
File* elf_file,
InstructionSet isa,
Elf_Word rodata_relative_offset,
Elf_Word rodata_size,
Elf_Word text_relative_offset,
Elf_Word text_size,
Elf_Word bss_relative_offset,
Elf_Word bss_size,
const bool add_symbols,
bool debug = false)
: oat_writer_(oat_writer),
elf_file_(elf_file),
add_symbols_(add_symbols),
debug_logging_(debug),
text_builder_(".text", text_size, text_relative_offset, SHT_PROGBITS,
SHF_ALLOC | SHF_EXECINSTR),
rodata_builder_(".rodata", rodata_size, rodata_relative_offset, SHT_PROGBITS, SHF_ALLOC),
bss_builder_(".bss", bss_size, bss_relative_offset, SHT_NOBITS, SHF_ALLOC),
dynsym_builder_(".dynsym", SHT_DYNSYM, ".dynstr", SHT_STRTAB, true),
symtab_builder_(".symtab", SHT_SYMTAB, ".strtab", SHT_STRTAB, false),
hash_builder_(".hash", SHT_HASH, SHF_ALLOC, &dynsym_builder_, 0, sizeof(Elf_Word),
sizeof(Elf_Word)),
dynamic_builder_(".dynamic", &dynsym_builder_),
shstrtab_builder_(".shstrtab", SHT_STRTAB, 0, NULL, 0, 1, 1) {
SetupEhdr();
SetupDynamic();
SetupRequiredSymbols();
SetISA(isa);
}
~ElfBuilder() {}
const ElfOatSectionBuilder<Elf_Word, Elf_Sword, Elf_Shdr>& GetTextBuilder() const {
return text_builder_;
}
ElfSymtabBuilder<Elf_Word, Elf_Sword, Elf_Addr, Elf_Sym, Elf_Shdr>* GetSymtabBuilder() {
return &symtab_builder_;
}
bool Init() {
// Since the .text section of an oat file contains relative references to .rodata
// and (optionally) .bss, we keep these 2 or 3 sections together. This creates
// a non-traditional layout where the .bss section is mapped independently of the
// .dynamic section and needs its own program header with LOAD RW.
//
// The basic layout of the elf file. Order may be different in final output.
// +-------------------------+
// | Elf_Ehdr |
// +-------------------------+
// | Elf_Phdr PHDR |
// | Elf_Phdr LOAD R | .dynsym .dynstr .hash .rodata
// | Elf_Phdr LOAD R X | .text
// | Elf_Phdr LOAD RW | .bss (Optional)
// | Elf_Phdr LOAD RW | .dynamic
// | Elf_Phdr DYNAMIC | .dynamic
// +-------------------------+
// | .dynsym |
// | Elf_Sym STN_UNDEF |
// | Elf_Sym oatdata |
// | Elf_Sym oatexec |
// | Elf_Sym oatlastword |
// | Elf_Sym oatbss | (Optional)
// | Elf_Sym oatbsslastword | (Optional)
// +-------------------------+
// | .dynstr |
// | \0 |
// | oatdata\0 |
// | oatexec\0 |
// | oatlastword\0 |
// | boot.oat\0 |
// +-------------------------+
// | .hash |
// | Elf_Word nbucket = b |
// | Elf_Word nchain = c |
// | Elf_Word bucket[0] |
// | ... |
// | Elf_Word bucket[b - 1] |
// | Elf_Word chain[0] |
// | ... |
// | Elf_Word chain[c - 1] |
// +-------------------------+
// | .rodata |
// | oatdata..oatexec-4 |
// +-------------------------+
// | .text |
// | oatexec..oatlastword |
// +-------------------------+
// | .dynamic |
// | Elf_Dyn DT_SONAME |
// | Elf_Dyn DT_HASH |
// | Elf_Dyn DT_SYMTAB |
// | Elf_Dyn DT_SYMENT |
// | Elf_Dyn DT_STRTAB |
// | Elf_Dyn DT_STRSZ |
// | Elf_Dyn DT_NULL |
// +-------------------------+ (Optional)
// | .strtab | (Optional)
// | program symbol names | (Optional)
// +-------------------------+ (Optional)
// | .symtab | (Optional)
// | program symbols | (Optional)
// +-------------------------+
// | .shstrtab |
// | \0 |
// | .dynamic\0 |
// | .dynsym\0 |
// | .dynstr\0 |
// | .hash\0 |
// | .rodata\0 |
// | .text\0 |
// | .bss\0 | (Optional)
// | .shstrtab\0 |
// | .symtab\0 | (Optional)
// | .strtab\0 | (Optional)
// | .debug_str\0 | (Optional)
// | .debug_info\0 | (Optional)
// | .eh_frame\0 | (Optional)
// | .debug_line\0 | (Optional)
// | .debug_abbrev\0 | (Optional)
// +-------------------------+ (Optional)
// | .debug_info | (Optional)
// +-------------------------+ (Optional)
// | .debug_abbrev | (Optional)
// +-------------------------+ (Optional)
// | .eh_frame | (Optional)
// +-------------------------+ (Optional)
// | .debug_line | (Optional)
// +-------------------------+ (Optional)
// | .debug_str | (Optional)
// +-------------------------+ (Optional)
// | Elf_Shdr NULL |
// | Elf_Shdr .dynsym |
// | Elf_Shdr .dynstr |
// | Elf_Shdr .hash |
// | Elf_Shdr .rodata |
// | Elf_Shdr .text |
// | Elf_Shdr .bss | (Optional)
// | Elf_Shdr .dynamic |
// | Elf_Shdr .shstrtab |
// | Elf_Shdr .debug_info | (Optional)
// | Elf_Shdr .debug_abbrev | (Optional)
// | Elf_Shdr .eh_frame | (Optional)
// | Elf_Shdr .debug_line | (Optional)
// | Elf_Shdr .debug_str | (Optional)
// +-------------------------+
if (fatal_error_) {
return false;
}
// Step 1. Figure out all the offsets.
if (debug_logging_) {
LOG(INFO) << "phdr_offset=" << PHDR_OFFSET << std::hex << " " << PHDR_OFFSET;
LOG(INFO) << "phdr_size=" << PHDR_SIZE << std::hex << " " << PHDR_SIZE;
}
memset(&program_headers_, 0, sizeof(program_headers_));
program_headers_[PH_PHDR].p_type = PT_PHDR;
program_headers_[PH_PHDR].p_offset = PHDR_OFFSET;
program_headers_[PH_PHDR].p_vaddr = PHDR_OFFSET;
program_headers_[PH_PHDR].p_paddr = PHDR_OFFSET;
program_headers_[PH_PHDR].p_filesz = sizeof(program_headers_);
program_headers_[PH_PHDR].p_memsz = sizeof(program_headers_);
program_headers_[PH_PHDR].p_flags = PF_R;
program_headers_[PH_PHDR].p_align = sizeof(Elf_Word);
program_headers_[PH_LOAD_R__].p_type = PT_LOAD;
program_headers_[PH_LOAD_R__].p_offset = 0;
program_headers_[PH_LOAD_R__].p_vaddr = 0;
program_headers_[PH_LOAD_R__].p_paddr = 0;
program_headers_[PH_LOAD_R__].p_flags = PF_R;
program_headers_[PH_LOAD_R_X].p_type = PT_LOAD;
program_headers_[PH_LOAD_R_X].p_flags = PF_R | PF_X;
program_headers_[PH_LOAD_RW_BSS].p_type = PT_LOAD;
program_headers_[PH_LOAD_RW_BSS].p_flags = PF_R | PF_W;
program_headers_[PH_LOAD_RW_DYNAMIC].p_type = PT_LOAD;
program_headers_[PH_LOAD_RW_DYNAMIC].p_flags = PF_R | PF_W;
program_headers_[PH_DYNAMIC].p_type = PT_DYNAMIC;
program_headers_[PH_DYNAMIC].p_flags = PF_R | PF_W;
// Get the dynstr string.
dynstr_ = dynsym_builder_.GenerateStrtab();
// Add the SONAME to the dynstr.
dynstr_soname_offset_ = dynstr_.size();
std::string file_name(elf_file_->GetPath());
size_t directory_separator_pos = file_name.rfind('/');
if (directory_separator_pos != std::string::npos) {
file_name = file_name.substr(directory_separator_pos + 1);
}
dynstr_ += file_name;
dynstr_ += '\0';
if (debug_logging_) {
LOG(INFO) << "dynstr size (bytes) =" << dynstr_.size()
<< std::hex << " " << dynstr_.size();
LOG(INFO) << "dynsym size (elements)=" << dynsym_builder_.GetSize()
<< std::hex << " " << dynsym_builder_.GetSize();
}
// Get the section header string table.
shstrtab_ += '\0';
// Setup sym_undef
memset(&null_hdr_, 0, sizeof(null_hdr_));
null_hdr_.sh_type = SHT_NULL;
null_hdr_.sh_link = SHN_UNDEF;
section_ptrs_.push_back(&null_hdr_);
section_index_ = 1;
// setup .dynsym
section_ptrs_.push_back(dynsym_builder_.GetSection());
AssignSectionStr(&dynsym_builder_, &shstrtab_);
dynsym_builder_.SetSectionIndex(section_index_);
section_index_++;
// Setup .dynstr
section_ptrs_.push_back(dynsym_builder_.GetStrTab()->GetSection());
AssignSectionStr(dynsym_builder_.GetStrTab(), &shstrtab_);
dynsym_builder_.GetStrTab()->SetSectionIndex(section_index_);
section_index_++;
// Setup .hash
section_ptrs_.push_back(hash_builder_.GetSection());
AssignSectionStr(&hash_builder_, &shstrtab_);
hash_builder_.SetSectionIndex(section_index_);
section_index_++;
// Setup .rodata
section_ptrs_.push_back(rodata_builder_.GetSection());
AssignSectionStr(&rodata_builder_, &shstrtab_);
rodata_builder_.SetSectionIndex(section_index_);
section_index_++;
// Setup .text
section_ptrs_.push_back(text_builder_.GetSection());
AssignSectionStr(&text_builder_, &shstrtab_);
text_builder_.SetSectionIndex(section_index_);
section_index_++;
// Setup .bss
if (bss_builder_.GetSize() != 0u) {
section_ptrs_.push_back(bss_builder_.GetSection());
AssignSectionStr(&bss_builder_, &shstrtab_);
bss_builder_.SetSectionIndex(section_index_);
section_index_++;
}
// Setup .dynamic
section_ptrs_.push_back(dynamic_builder_.GetSection());
AssignSectionStr(&dynamic_builder_, &shstrtab_);
dynamic_builder_.SetSectionIndex(section_index_);
section_index_++;
// Fill in the hash section.
hash_ = dynsym_builder_.GenerateHashContents();
if (debug_logging_) {
LOG(INFO) << ".hash size (bytes)=" << hash_.size() * sizeof(Elf_Word)
<< std::hex << " " << hash_.size() * sizeof(Elf_Word);
}
Elf_Word base_offset = sizeof(Elf_Ehdr) + sizeof(program_headers_);
// Get the layout in the sections.
//
// Get the layout of the dynsym section.
dynsym_builder_.GetSection()->sh_offset =
RoundUp(base_offset, dynsym_builder_.GetSection()->sh_addralign);
dynsym_builder_.GetSection()->sh_addr = dynsym_builder_.GetSection()->sh_offset;
dynsym_builder_.GetSection()->sh_size = dynsym_builder_.GetSize() * sizeof(Elf_Sym);
dynsym_builder_.GetSection()->sh_link = dynsym_builder_.GetLink();
// Get the layout of the dynstr section.
dynsym_builder_.GetStrTab()->GetSection()->sh_offset =
NextOffset<Elf_Word, Elf_Shdr>(*dynsym_builder_.GetStrTab()->GetSection(),
*dynsym_builder_.GetSection());
dynsym_builder_.GetStrTab()->GetSection()->sh_addr =
dynsym_builder_.GetStrTab()->GetSection()->sh_offset;
dynsym_builder_.GetStrTab()->GetSection()->sh_size = dynstr_.size();
dynsym_builder_.GetStrTab()->GetSection()->sh_link = dynsym_builder_.GetStrTab()->GetLink();
// Get the layout of the hash section
hash_builder_.GetSection()->sh_offset =
NextOffset<Elf_Word, Elf_Shdr>(*hash_builder_.GetSection(),
*dynsym_builder_.GetStrTab()->GetSection());
hash_builder_.GetSection()->sh_addr = hash_builder_.GetSection()->sh_offset;
hash_builder_.GetSection()->sh_size = hash_.size() * sizeof(Elf_Word);
hash_builder_.GetSection()->sh_link = hash_builder_.GetLink();
// Get the layout of the rodata section.
rodata_builder_.GetSection()->sh_offset =
NextOffset<Elf_Word, Elf_Shdr>(*rodata_builder_.GetSection(),
*hash_builder_.GetSection());
rodata_builder_.GetSection()->sh_addr = rodata_builder_.GetSection()->sh_offset;
rodata_builder_.GetSection()->sh_size = rodata_builder_.GetSize();
rodata_builder_.GetSection()->sh_link = rodata_builder_.GetLink();
// Get the layout of the text section.
text_builder_.GetSection()->sh_offset =
NextOffset<Elf_Word, Elf_Shdr>(*text_builder_.GetSection(),
*rodata_builder_.GetSection());
text_builder_.GetSection()->sh_addr = text_builder_.GetSection()->sh_offset;
text_builder_.GetSection()->sh_size = text_builder_.GetSize();
text_builder_.GetSection()->sh_link = text_builder_.GetLink();
CHECK_ALIGNED(rodata_builder_.GetSection()->sh_offset +
rodata_builder_.GetSection()->sh_size, kPageSize);
// Get the layout of the .bss section.
bss_builder_.GetSection()->sh_offset =
NextOffset<Elf_Word, Elf_Shdr>(*bss_builder_.GetSection(),
*text_builder_.GetSection());
bss_builder_.GetSection()->sh_addr = bss_builder_.GetSection()->sh_offset;
bss_builder_.GetSection()->sh_size = bss_builder_.GetSize();
bss_builder_.GetSection()->sh_link = bss_builder_.GetLink();
// Get the layout of the dynamic section.
CHECK(IsAlignedParam(bss_builder_.GetSection()->sh_offset,
dynamic_builder_.GetSection()->sh_addralign));
dynamic_builder_.GetSection()->sh_offset = bss_builder_.GetSection()->sh_offset;
dynamic_builder_.GetSection()->sh_addr =
NextOffset<Elf_Word, Elf_Shdr>(*dynamic_builder_.GetSection(), *bss_builder_.GetSection());
dynamic_builder_.GetSection()->sh_size = dynamic_builder_.GetSize() * sizeof(Elf_Dyn);
dynamic_builder_.GetSection()->sh_link = dynamic_builder_.GetLink();
if (debug_logging_) {
LOG(INFO) << "dynsym off=" << dynsym_builder_.GetSection()->sh_offset
<< " dynsym size=" << dynsym_builder_.GetSection()->sh_size;
LOG(INFO) << "dynstr off=" << dynsym_builder_.GetStrTab()->GetSection()->sh_offset
<< " dynstr size=" << dynsym_builder_.GetStrTab()->GetSection()->sh_size;
LOG(INFO) << "hash off=" << hash_builder_.GetSection()->sh_offset
<< " hash size=" << hash_builder_.GetSection()->sh_size;
LOG(INFO) << "rodata off=" << rodata_builder_.GetSection()->sh_offset
<< " rodata size=" << rodata_builder_.GetSection()->sh_size;
LOG(INFO) << "text off=" << text_builder_.GetSection()->sh_offset
<< " text size=" << text_builder_.GetSection()->sh_size;
LOG(INFO) << "dynamic off=" << dynamic_builder_.GetSection()->sh_offset
<< " dynamic size=" << dynamic_builder_.GetSection()->sh_size;
}
return true;
}
bool Write() {
std::vector<ElfFilePiece<Elf_Word>*> pieces;
Elf_Shdr* prev = dynamic_builder_.GetSection();
std::string strtab;
if (IncludingDebugSymbols()) {
// Setup .symtab
section_ptrs_.push_back(symtab_builder_.GetSection());
AssignSectionStr(&symtab_builder_, &shstrtab_);
symtab_builder_.SetSectionIndex(section_index_);
section_index_++;
// Setup .strtab
section_ptrs_.push_back(symtab_builder_.GetStrTab()->GetSection());
AssignSectionStr(symtab_builder_.GetStrTab(), &shstrtab_);
symtab_builder_.GetStrTab()->SetSectionIndex(section_index_);
section_index_++;
strtab = symtab_builder_.GenerateStrtab();
if (debug_logging_) {
LOG(INFO) << "strtab size (bytes) =" << strtab.size()
<< std::hex << " " << strtab.size();
LOG(INFO) << "symtab size (elements) =" << symtab_builder_.GetSize()
<< std::hex << " " << symtab_builder_.GetSize();
}
}
// Setup all the other sections.
for (ElfRawSectionBuilder<Elf_Word, Elf_Sword, Elf_Shdr> *builder = other_builders_.data(),
*end = builder + other_builders_.size();
builder != end; ++builder) {
section_ptrs_.push_back(builder->GetSection());
AssignSectionStr(builder, &shstrtab_);
builder->SetSectionIndex(section_index_);
section_index_++;
}
// Setup shstrtab
section_ptrs_.push_back(shstrtab_builder_.GetSection());
AssignSectionStr(&shstrtab_builder_, &shstrtab_);
shstrtab_builder_.SetSectionIndex(section_index_);
section_index_++;
if (debug_logging_) {
LOG(INFO) << ".shstrtab size (bytes) =" << shstrtab_.size()
<< std::hex << " " << shstrtab_.size();
LOG(INFO) << "section list size (elements)=" << section_ptrs_.size()
<< std::hex << " " << section_ptrs_.size();
}
if (IncludingDebugSymbols()) {
// Get the layout of the symtab section.
symtab_builder_.GetSection()->sh_offset =
NextOffset<Elf_Word, Elf_Shdr>(*symtab_builder_.GetSection(),
*dynamic_builder_.GetSection());
symtab_builder_.GetSection()->sh_addr = 0;
// Add to leave space for the null symbol.
symtab_builder_.GetSection()->sh_size = symtab_builder_.GetSize() * sizeof(Elf_Sym);
symtab_builder_.GetSection()->sh_link = symtab_builder_.GetLink();
// Get the layout of the dynstr section.
symtab_builder_.GetStrTab()->GetSection()->sh_offset =
NextOffset<Elf_Word, Elf_Shdr>(*symtab_builder_.GetStrTab()->GetSection(),
*symtab_builder_.GetSection());
symtab_builder_.GetStrTab()->GetSection()->sh_addr = 0;
symtab_builder_.GetStrTab()->GetSection()->sh_size = strtab.size();
symtab_builder_.GetStrTab()->GetSection()->sh_link = symtab_builder_.GetStrTab()->GetLink();
prev = symtab_builder_.GetStrTab()->GetSection();
if (debug_logging_) {
LOG(INFO) << "symtab off=" << symtab_builder_.GetSection()->sh_offset
<< " symtab size=" << symtab_builder_.GetSection()->sh_size;
LOG(INFO) << "strtab off=" << symtab_builder_.GetStrTab()->GetSection()->sh_offset
<< " strtab size=" << symtab_builder_.GetStrTab()->GetSection()->sh_size;
}
}
// Get the layout of the extra sections. (This will deal with the debug
// sections if they are there)
for (auto it = other_builders_.begin(); it != other_builders_.end(); ++it) {
it->GetSection()->sh_offset = NextOffset<Elf_Word, Elf_Shdr>(*it->GetSection(), *prev);
it->GetSection()->sh_addr = 0;
it->GetSection()->sh_size = it->GetBuffer()->size();
it->GetSection()->sh_link = it->GetLink();
// We postpone adding an ElfFilePiece to keep the order in "pieces."
prev = it->GetSection();
if (debug_logging_) {
LOG(INFO) << it->GetName() << " off=" << it->GetSection()->sh_offset
<< " size=" << it->GetSection()->sh_size;
}
}
// Get the layout of the shstrtab section
shstrtab_builder_.GetSection()->sh_offset =
NextOffset<Elf_Word, Elf_Shdr>(*shstrtab_builder_.GetSection(), *prev);
shstrtab_builder_.GetSection()->sh_addr = 0;
shstrtab_builder_.GetSection()->sh_size = shstrtab_.size();
shstrtab_builder_.GetSection()->sh_link = shstrtab_builder_.GetLink();
if (debug_logging_) {
LOG(INFO) << "shstrtab off=" << shstrtab_builder_.GetSection()->sh_offset
<< " shstrtab size=" << shstrtab_builder_.GetSection()->sh_size;
}
// The section list comes after come after.
Elf_Word sections_offset = RoundUp(
shstrtab_builder_.GetSection()->sh_offset + shstrtab_builder_.GetSection()->sh_size,
sizeof(Elf_Word));
// Setup the actual symbol arrays.
std::vector<Elf_Sym> dynsym = dynsym_builder_.GenerateSymtab();
CHECK_EQ(dynsym.size() * sizeof(Elf_Sym), dynsym_builder_.GetSection()->sh_size);
std::vector<Elf_Sym> symtab;
if (IncludingDebugSymbols()) {
symtab = symtab_builder_.GenerateSymtab();
CHECK_EQ(symtab.size() * sizeof(Elf_Sym), symtab_builder_.GetSection()->sh_size);
}
// Setup the dynamic section.
// This will add the 2 values we cannot know until now time, namely the size
// and the soname_offset.
std::vector<Elf_Dyn> dynamic = dynamic_builder_.GetDynamics(dynstr_.size(),
dynstr_soname_offset_);
CHECK_EQ(dynamic.size() * sizeof(Elf_Dyn), dynamic_builder_.GetSection()->sh_size);
// Finish setup of the program headers now that we know the layout of the
// whole file.
Elf_Word load_r_size =
rodata_builder_.GetSection()->sh_offset + rodata_builder_.GetSection()->sh_size;
program_headers_[PH_LOAD_R__].p_filesz = load_r_size;
program_headers_[PH_LOAD_R__].p_memsz = load_r_size;
program_headers_[PH_LOAD_R__].p_align = rodata_builder_.GetSection()->sh_addralign;
Elf_Word load_rx_size = text_builder_.GetSection()->sh_size;
program_headers_[PH_LOAD_R_X].p_offset = text_builder_.GetSection()->sh_offset;
program_headers_[PH_LOAD_R_X].p_vaddr = text_builder_.GetSection()->sh_offset;
program_headers_[PH_LOAD_R_X].p_paddr = text_builder_.GetSection()->sh_offset;
program_headers_[PH_LOAD_R_X].p_filesz = load_rx_size;
program_headers_[PH_LOAD_R_X].p_memsz = load_rx_size;
program_headers_[PH_LOAD_R_X].p_align = text_builder_.GetSection()->sh_addralign;
program_headers_[PH_LOAD_RW_BSS].p_offset = bss_builder_.GetSection()->sh_offset;
program_headers_[PH_LOAD_RW_BSS].p_vaddr = bss_builder_.GetSection()->sh_offset;
program_headers_[PH_LOAD_RW_BSS].p_paddr = bss_builder_.GetSection()->sh_offset;
program_headers_[PH_LOAD_RW_BSS].p_filesz = 0;
program_headers_[PH_LOAD_RW_BSS].p_memsz = bss_builder_.GetSection()->sh_size;
program_headers_[PH_LOAD_RW_BSS].p_align = bss_builder_.GetSection()->sh_addralign;
program_headers_[PH_LOAD_RW_DYNAMIC].p_offset = dynamic_builder_.GetSection()->sh_offset;
program_headers_[PH_LOAD_RW_DYNAMIC].p_vaddr = dynamic_builder_.GetSection()->sh_addr;
program_headers_[PH_LOAD_RW_DYNAMIC].p_paddr = dynamic_builder_.GetSection()->sh_addr;
program_headers_[PH_LOAD_RW_DYNAMIC].p_filesz = dynamic_builder_.GetSection()->sh_size;
program_headers_[PH_LOAD_RW_DYNAMIC].p_memsz = dynamic_builder_.GetSection()->sh_size;
program_headers_[PH_LOAD_RW_DYNAMIC].p_align = dynamic_builder_.GetSection()->sh_addralign;
program_headers_[PH_DYNAMIC].p_offset = dynamic_builder_.GetSection()->sh_offset;
program_headers_[PH_DYNAMIC].p_vaddr = dynamic_builder_.GetSection()->sh_addr;
program_headers_[PH_DYNAMIC].p_paddr = dynamic_builder_.GetSection()->sh_addr;
program_headers_[PH_DYNAMIC].p_filesz = dynamic_builder_.GetSection()->sh_size;
program_headers_[PH_DYNAMIC].p_memsz = dynamic_builder_.GetSection()->sh_size;
program_headers_[PH_DYNAMIC].p_align = dynamic_builder_.GetSection()->sh_addralign;
// Finish setup of the Ehdr values.
elf_header_.e_phoff = PHDR_OFFSET;
elf_header_.e_shoff = sections_offset;
elf_header_.e_phnum = (bss_builder_.GetSection()->sh_size != 0u) ? PH_NUM : PH_NUM - 1;
elf_header_.e_shnum = section_ptrs_.size();
elf_header_.e_shstrndx = shstrtab_builder_.GetSectionIndex();
// Add the rest of the pieces to the list.
pieces.push_back(new ElfFileMemoryPiece<Elf_Word>("Elf Header", 0, &elf_header_,
sizeof(elf_header_)));
if (bss_builder_.GetSection()->sh_size != 0u) {
pieces.push_back(new ElfFileMemoryPiece<Elf_Word>("Program headers", PHDR_OFFSET,
&program_headers_[0],
elf_header_.e_phnum * sizeof(Elf_Phdr)));
} else {
// Skip PH_LOAD_RW_BSS.
Elf_Word part1_size = PH_LOAD_RW_BSS * sizeof(Elf_Phdr);
Elf_Word part2_size = (PH_NUM - PH_LOAD_RW_BSS - 1) * sizeof(Elf_Phdr);
CHECK_EQ(part1_size + part2_size, elf_header_.e_phnum * sizeof(Elf_Phdr));
pieces.push_back(new ElfFileMemoryPiece<Elf_Word>("Program headers", PHDR_OFFSET,
&program_headers_[0], part1_size));
pieces.push_back(new ElfFileMemoryPiece<Elf_Word>("Program headers part 2",
PHDR_OFFSET + part1_size,
&program_headers_[PH_LOAD_RW_BSS + 1],
part2_size));
}
pieces.push_back(new ElfFileMemoryPiece<Elf_Word>(".dynamic",
dynamic_builder_.GetSection()->sh_offset,
dynamic.data(),
dynamic_builder_.GetSection()->sh_size));
pieces.push_back(new ElfFileMemoryPiece<Elf_Word>(".dynsym", dynsym_builder_.GetSection()->sh_offset,
dynsym.data(),
dynsym.size() * sizeof(Elf_Sym)));
pieces.push_back(new ElfFileMemoryPiece<Elf_Word>(".dynstr",
dynsym_builder_.GetStrTab()->GetSection()->sh_offset,
dynstr_.c_str(), dynstr_.size()));
pieces.push_back(new ElfFileMemoryPiece<Elf_Word>(".hash", hash_builder_.GetSection()->sh_offset,
hash_.data(),
hash_.size() * sizeof(Elf_Word)));
pieces.push_back(new ElfFileRodataPiece<Elf_Word>(rodata_builder_.GetSection()->sh_offset,
oat_writer_));
pieces.push_back(new ElfFileOatTextPiece<Elf_Word>(text_builder_.GetSection()->sh_offset,
oat_writer_));
if (IncludingDebugSymbols()) {
pieces.push_back(new ElfFileMemoryPiece<Elf_Word>(".symtab",
symtab_builder_.GetSection()->sh_offset,
symtab.data(),
symtab.size() * sizeof(Elf_Sym)));
pieces.push_back(new ElfFileMemoryPiece<Elf_Word>(".strtab",
symtab_builder_.GetStrTab()->GetSection()->sh_offset,
strtab.c_str(), strtab.size()));
}
pieces.push_back(new ElfFileMemoryPiece<Elf_Word>(".shstrtab",
shstrtab_builder_.GetSection()->sh_offset,
&shstrtab_[0], shstrtab_.size()));
for (uint32_t i = 0; i < section_ptrs_.size(); ++i) {
// Just add all the sections in induvidually since they are all over the
// place on the heap/stack.
Elf_Word cur_off = sections_offset + i * sizeof(Elf_Shdr);
pieces.push_back(new ElfFileMemoryPiece<Elf_Word>("section table piece", cur_off,
section_ptrs_[i], sizeof(Elf_Shdr)));
}
// Postponed debug info.
for (auto it = other_builders_.begin(); it != other_builders_.end(); ++it) {
pieces.push_back(new ElfFileMemoryPiece<Elf_Word>(it->GetName(), it->GetSection()->sh_offset,
it->GetBuffer()->data(),
it->GetBuffer()->size()));
}
if (!WriteOutFile(pieces)) {
LOG(ERROR) << "Unable to write to file " << elf_file_->GetPath();
STLDeleteElements(&pieces); // Have to manually clean pieces.
return false;
}
STLDeleteElements(&pieces); // Have to manually clean pieces.
return true;
}
// Adds the given raw section to the builder. This will copy it. The caller
// is responsible for deallocating their copy.
void RegisterRawSection(ElfRawSectionBuilder<Elf_Word, Elf_Sword, Elf_Shdr> bld) {
other_builders_.push_back(bld);
}
private:
void SetISA(InstructionSet isa) {
switch (isa) {
case kArm:
// Fall through.
case kThumb2: {
elf_header_.e_machine = EM_ARM;
elf_header_.e_flags = EF_ARM_EABI_VER5;
break;
}
case kArm64: {
elf_header_.e_machine = EM_AARCH64;
elf_header_.e_flags = 0;
break;
}
case kX86: {
elf_header_.e_machine = EM_386;
elf_header_.e_flags = 0;
break;
}
case kX86_64: {
elf_header_.e_machine = EM_X86_64;
elf_header_.e_flags = 0;
break;
}
case kMips: {
elf_header_.e_machine = EM_MIPS;
elf_header_.e_flags = (EF_MIPS_NOREORDER |
EF_MIPS_PIC |
EF_MIPS_CPIC |
EF_MIPS_ABI_O32 |
EF_MIPS_ARCH_32R2);
break;
}
case kMips64: {
elf_header_.e_machine = EM_MIPS;
elf_header_.e_flags = (EF_MIPS_NOREORDER |
EF_MIPS_PIC |
EF_MIPS_CPIC |
EF_MIPS_ARCH_64R6);
break;
}
default: {
fatal_error_ = true;
LOG(FATAL) << "Unknown instruction set: " << isa;
break;
}
}
}
void SetupEhdr() {
memset(&elf_header_, 0, sizeof(elf_header_));
elf_header_.e_ident[EI_MAG0] = ELFMAG0;
elf_header_.e_ident[EI_MAG1] = ELFMAG1;
elf_header_.e_ident[EI_MAG2] = ELFMAG2;
elf_header_.e_ident[EI_MAG3] = ELFMAG3;
elf_header_.e_ident[EI_CLASS] = (sizeof(Elf_Addr) == sizeof(Elf32_Addr))
? ELFCLASS32 : ELFCLASS64;;
elf_header_.e_ident[EI_DATA] = ELFDATA2LSB;
elf_header_.e_ident[EI_VERSION] = EV_CURRENT;
elf_header_.e_ident[EI_OSABI] = ELFOSABI_LINUX;
elf_header_.e_ident[EI_ABIVERSION] = 0;
elf_header_.e_type = ET_DYN;
elf_header_.e_version = 1;
elf_header_.e_entry = 0;
elf_header_.e_ehsize = sizeof(Elf_Ehdr);
elf_header_.e_phentsize = sizeof(Elf_Phdr);
elf_header_.e_shentsize = sizeof(Elf_Shdr);
elf_header_.e_phoff = sizeof(Elf_Ehdr);
}
// Sets up a bunch of the required Dynamic Section entries.
// Namely it will initialize all the mandatory ones that it can.
// Specifically:
// DT_HASH
// DT_STRTAB
// DT_SYMTAB
// DT_SYMENT
//
// Some such as DT_SONAME, DT_STRSZ and DT_NULL will be put in later.
void SetupDynamic() {
dynamic_builder_.AddDynamicTag(DT_HASH, 0, &hash_builder_);
dynamic_builder_.AddDynamicTag(DT_STRTAB, 0, dynsym_builder_.GetStrTab());
dynamic_builder_.AddDynamicTag(DT_SYMTAB, 0, &dynsym_builder_);
dynamic_builder_.AddDynamicTag(DT_SYMENT, sizeof(Elf_Sym));
}
// Sets up the basic dynamic symbols that are needed, namely all those we
// can know already.
//
// Specifically adds:
// oatdata
// oatexec
// oatlastword
void SetupRequiredSymbols() {
dynsym_builder_.AddSymbol("oatdata", &rodata_builder_, 0, true,
rodata_builder_.GetSize(), STB_GLOBAL, STT_OBJECT);
dynsym_builder_.AddSymbol("oatexec", &text_builder_, 0, true,
text_builder_.GetSize(), STB_GLOBAL, STT_OBJECT);
dynsym_builder_.AddSymbol("oatlastword", &text_builder_, text_builder_.GetSize() - 4,
true, 4, STB_GLOBAL, STT_OBJECT);
if (bss_builder_.GetSize() != 0u) {
dynsym_builder_.AddSymbol("oatbss", &bss_builder_, 0, true,
bss_builder_.GetSize(), STB_GLOBAL, STT_OBJECT);
dynsym_builder_.AddSymbol("oatbsslastword", &bss_builder_, bss_builder_.GetSize() - 4,
true, 4, STB_GLOBAL, STT_OBJECT);
}
}
void AssignSectionStr(ElfSectionBuilder<Elf_Word, Elf_Sword, Elf_Shdr>* builder,
std::string* strtab) {
builder->GetSection()->sh_name = strtab->size();
*strtab += builder->GetName();
*strtab += '\0';
if (debug_logging_) {
LOG(INFO) << "adding section name \"" << builder->GetName() << "\" "
<< "to shstrtab at offset " << builder->GetSection()->sh_name;
}
}
// Write each of the pieces out to the file.
bool WriteOutFile(const std::vector<ElfFilePiece<Elf_Word>*>& pieces) {
for (auto it = pieces.begin(); it != pieces.end(); ++it) {
if (!(*it)->Write(elf_file_)) {
return false;
}
}
return true;
}
bool IncludingDebugSymbols() const {
return add_symbols_ && symtab_builder_.GetSize() > 1;
}
CodeOutput* const oat_writer_;
File* const elf_file_;
const bool add_symbols_;
const bool debug_logging_;
bool fatal_error_ = false;
// What phdr is.
static const uint32_t PHDR_OFFSET = sizeof(Elf_Ehdr);
enum : uint8_t {
PH_PHDR = 0,
PH_LOAD_R__ = 1,
PH_LOAD_R_X = 2,
PH_LOAD_RW_BSS = 3,
PH_LOAD_RW_DYNAMIC = 4,
PH_DYNAMIC = 5,
PH_NUM = 6,
};
static const uint32_t PHDR_SIZE = sizeof(Elf_Phdr) * PH_NUM;
Elf_Phdr program_headers_[PH_NUM];
Elf_Ehdr elf_header_;
Elf_Shdr null_hdr_;
std::string shstrtab_;
// The index of the current section being built. The first being 1.
uint32_t section_index_;
std::string dynstr_;
uint32_t dynstr_soname_offset_;
std::vector<const Elf_Shdr*> section_ptrs_;
std::vector<Elf_Word> hash_;
ElfOatSectionBuilder<Elf_Word, Elf_Sword, Elf_Shdr> text_builder_;
ElfOatSectionBuilder<Elf_Word, Elf_Sword, Elf_Shdr> rodata_builder_;
ElfOatSectionBuilder<Elf_Word, Elf_Sword, Elf_Shdr> bss_builder_;
ElfSymtabBuilder<Elf_Word, Elf_Sword, Elf_Addr, Elf_Sym, Elf_Shdr> dynsym_builder_;
ElfSymtabBuilder<Elf_Word, Elf_Sword, Elf_Addr, Elf_Sym, Elf_Shdr> symtab_builder_;
ElfSectionBuilder<Elf_Word, Elf_Sword, Elf_Shdr> hash_builder_;
ElfDynamicBuilder<Elf_Word, Elf_Sword, Elf_Dyn, Elf_Shdr> dynamic_builder_;
ElfSectionBuilder<Elf_Word, Elf_Sword, Elf_Shdr> shstrtab_builder_;
std::vector<ElfRawSectionBuilder<Elf_Word, Elf_Sword, Elf_Shdr>> other_builders_;
DISALLOW_COPY_AND_ASSIGN(ElfBuilder);
};
} // namespace art
#endif // ART_COMPILER_ELF_BUILDER_H_