wut/tools/elf2rpl/main.cpp

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#include <algorithm>
#include <fstream>
#include <iterator>
#include <iostream>
#include <string>
#include <vector>
#include <memory>
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#include <zlib.h>
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#include "elf.h"
#pragma pack(push, 1)
struct RplLibsDef
{
be_val<uint32_t> name;
be_val<uint32_t> stubStart;
be_val<uint32_t> stubEnd;
};
#pragma pack(pop)
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static const uint32_t LoadAddress = 0x01000000u;
static const uint32_t CodeAddress = 0x02000000u;
static const uint32_t DataAddress = 0x10000000u;
static const uint32_t WiiuLoadAddress = 0xC0000000u;
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struct ElfFile
{
struct Symbol
{
std::string name;
uint32_t address;
uint32_t size;
elf::SymbolType type;
elf::SymbolBinding binding;
uint32_t outNamePos;
};
struct Relocation
{
uint32_t target;
elf::RelocationType type;
Symbol *symbol;
uint32_t addend;
};
struct DataSection
{
std::string name;
uint32_t address;
elf::SectionType type;
elf::SectionFlags flags;
// Data used if type == SHT_PROGBITS
std::vector<char> data;
// Size used if type == SHT_NOBITS
uint32_t size;
};
struct RplImport
{
Symbol *trampSymbol;
Symbol *stubSymbol;
uint32_t stubAddr;
uint32_t trampAddr;
};
struct RplImportLibrary
{
std::string name;
std::vector<std::unique_ptr<RplImport>> imports;
};
uint32_t entryPoint;
std::vector<std::unique_ptr<DataSection>> dataSections;
std::vector<std::unique_ptr<Symbol>> symbols;
std::vector<std::unique_ptr<Relocation>> relocations;
std::vector<std::unique_ptr<RplImportLibrary>> rplImports;
};
struct InputSection
{
elf::SectionHeader header;
std::vector<char> data;
};
static ElfFile::Symbol *
findSymbol(ElfFile &file, uint32_t address)
{
for (auto &symbol : file.symbols) {
if (symbol->address == address && symbol->type != elf::STT_NOTYPE) {
return symbol.get();
}
}
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for (auto &symbol : file.symbols) {
if (symbol->address == address) {
return symbol.get();
}
}
return nullptr;
}
static ElfFile::RplImport *
findImport(ElfFile &file, uint32_t address)
{
for (auto &lib : file.rplImports) {
for (auto &import : lib->imports) {
if (import->stubAddr == address || import->trampAddr == address) {
return import.get();
}
}
}
return nullptr;
}
template<typename Type>
static Type *
getLoaderDataPtr(std::vector<InputSection> &inSections, uint32_t address)
{
for (auto &section : inSections) {
auto start = section.header.addr;
auto end = start + section.data.size();
if (start <= address && end > address) {
auto offset = address - start;
return reinterpret_cast<Type *>(section.data.data() + offset);
}
}
return nullptr;
}
static elf::Symbol *
getSectionSymbol(InputSection &section, size_t index)
{
auto symbols = reinterpret_cast<elf::Symbol *>(section.data.data());
return &symbols[index];
};
static bool
read(ElfFile &file, const std::string &filename)
{
std::ifstream in { filename, std::ifstream::binary };
std::vector<InputSection> inSections;
if (!in.is_open()) {
std::cout << "Could not open " << filename << " for reading" << std::endl;
return false;
}
// Read header
elf::Header header;
in.read(reinterpret_cast<char *>(&header), sizeof(elf::Header));
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if (header.magic != elf::HeaderMagic) {
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std::cout << "Invalid ELF magic header" << std::endl;
return false;
}
if (header.fileClass != elf::ELFCLASS32) {
std::cout << "Unexpected ELF file class" << std::endl;
return false;
}
if (header.encoding != elf::ELFDATA2MSB) {
std::cout << "Unexpected ELF encoding" << std::endl;
return false;
}
if (header.machine != elf::EM_PPC) {
std::cout << "Unexpected ELF machine type" << std::endl;
return false;
}
if (header.elfVersion != elf::EV_CURRENT) {
std::cout << "Unexpected ELF version" << std::endl;
return false;
}
file.entryPoint = header.entry;
// Read section headers and data
in.seekg(static_cast<size_t>(header.shoff));
inSections.resize(header.shnum);
for (auto &section : inSections) {
in.read(reinterpret_cast<char *>(&section.header), sizeof(elf::SectionHeader));
if (!section.header.size || section.header.type == elf::SHT_NOBITS) {
continue;
}
auto pos = in.tellg();
in.seekg(static_cast<size_t>(section.header.offset));
section.data.resize(section.header.size);
in.read(section.data.data(), section.data.size());
in.seekg(pos);
}
auto shStrTab = inSections[header.shstrndx].data.data();
// Process any loader relocations
for (auto &section : inSections) {
if (section.header.type != elf::SHT_RELA) {
continue;
}
auto name = std::string { shStrTab + section.header.name };
if (name.compare(".rela.dyn") != 0) {
continue;
}
auto symSection = inSections[section.header.link];
auto relas = reinterpret_cast<elf::Rela *>(section.data.data());
auto count = section.data.size() / sizeof(elf::Rela);
for (auto i = 0u; i < count; ++i) {
auto &rela = relas[i];
auto index = rela.info >> 8;
auto symbol = getSectionSymbol(symSection, index);
auto addr = symbol->value + rela.addend;
auto type = rela.info & 0xff;
auto ptr = getLoaderDataPtr<uint32_t>(inSections, rela.offset);
if (!ptr) {
std::cout << "Unexpected relocation offset in .rela.dyn section" << std::endl;
return false;
}
switch (type) {
case elf::R_PPC_RELATIVE:
*ptr = byte_swap(addr);
break;
default:
std::cout << "Unexpected relocation type in .rela.dyn section" << std::endl;
return false;
}
}
}
// Read text/data sections
for (auto &section : inSections) {
if (section.header.addr >= LoadAddress && section.header.addr < CodeAddress) {
// Skip any load sections
continue;
}
auto name = std::string { shStrTab + section.header.name };
if (section.header.type == elf::SHT_PROGBITS) {
auto data = new ElfFile::DataSection();
data->type = elf::SHT_PROGBITS;
data->flags = static_cast<elf::SectionFlags>(section.header.flags.value());
data->name = shStrTab + section.header.name;
data->address = section.header.addr;
data->data = section.data;
file.dataSections.emplace_back(data);
} else if (section.header.type == elf::SHT_NOBITS) {
auto bss = new ElfFile::DataSection();
bss->type = elf::SHT_NOBITS;
bss->flags = static_cast<elf::SectionFlags>(section.header.flags.value());
bss->name = shStrTab + section.header.name;
bss->address = section.header.addr;
bss->size = section.header.size;
file.dataSections.emplace_back(bss);
}
}
// Default symbols
auto symNull = new ElfFile::Symbol();
symNull->address = 0;
symNull->size = 0;
symNull->type = elf::STT_NOTYPE;
symNull->binding = elf::STB_LOCAL;
file.symbols.emplace_back(symNull);
auto symText = new ElfFile::Symbol();
symText->name = "$TEXT";
symText->address = CodeAddress;
symText->size = 0;
symText->type = elf::STT_SECTION;
symText->binding = elf::STB_LOCAL;
file.symbols.emplace_back(symText);
auto symData = new ElfFile::Symbol();
symData->name = "$DATA";
symData->address = DataAddress;
symData->size = 0;
symData->type = elf::STT_SECTION;
symData->binding = elf::STB_LOCAL;
file.symbols.emplace_back(symData);
auto symUndef = new ElfFile::Symbol();
symUndef->name = "$UNDEF";
symUndef->address = 0;
symUndef->size = 0;
symUndef->type = elf::STT_OBJECT;
symUndef->binding = elf::STB_GLOBAL;
file.symbols.emplace_back(symUndef);
// Read symbols
for (auto &section : inSections) {
if (section.header.type != elf::SHT_SYMTAB) {
continue;
}
auto name = std::string { shStrTab + section.header.name };
if (name.compare(".symtab") != 0) {
std::cout << "Unexpected symbol section " << name << std::endl;
return false;
}
auto strTab = inSections[section.header.link].data.data();
auto symTab = reinterpret_cast<elf::Symbol *>(section.data.data());
auto count = section.data.size() / sizeof(elf::Symbol);
for (auto i = 0u; i < count; ++i) {
auto &sym = symTab[i];
if (sym.value >= LoadAddress && sym.value < CodeAddress) {
// Skip any load symbols
continue;
}
auto type = static_cast<elf::SymbolType>(sym.info & 0xF);
auto binding = static_cast<elf::SymbolBinding>((sym.info >> 4) & 0xF);
if (type == elf::STT_NOTYPE && sym.value == 0) {
// Skip null symbol
continue;
}
if (type == elf::STT_FILE || type == elf::STT_SECTION) {
// Skip file, section symbols
continue;
}
auto symbol = new ElfFile::Symbol();
symbol->name = strTab + sym.name;
symbol->address = sym.value;
symbol->size = sym.size;
symbol->type = type;
symbol->binding = binding;
file.symbols.emplace_back(symbol);
}
}
// Read RPL imports
for (auto &section : inSections) {
auto name = std::string { shStrTab + section.header.name };
if (name.compare(".lib.rplLibs") != 0) {
continue;
}
auto rplTab = reinterpret_cast<RplLibsDef *>(section.data.data());
auto count = section.data.size() / sizeof(RplLibsDef);
for (auto i = 0u; i < count; ++i) {
auto &rpl = rplTab[i];
auto lib = new ElfFile::RplImportLibrary();
lib->name = getLoaderDataPtr<char>(inSections, rpl.name);
for (auto stubAddr = rpl.stubStart; stubAddr < rpl.stubEnd; stubAddr += 4) {
auto import = new ElfFile::RplImport();
import->trampAddr = byte_swap(*getLoaderDataPtr<uint32_t>(inSections, stubAddr));
import->stubAddr = stubAddr;
// Get the tramp symbol
import->trampSymbol = findSymbol(file, import->trampAddr);
// Create a new symbol to use for the import
auto stubSymbol = new ElfFile::Symbol();
import->stubSymbol = stubSymbol;
stubSymbol->name = import->trampSymbol->name;
stubSymbol->address = 0;
stubSymbol->size = 0;
stubSymbol->binding = elf::STB_GLOBAL;
stubSymbol->type = elf::STT_FUNC;
file.symbols.emplace_back(stubSymbol);
// Rename tramp symbol
import->trampSymbol->name += "_tramp";
lib->imports.emplace_back(import);
}
file.rplImports.emplace_back(lib);
}
}
// Read relocations
for (auto &section : inSections) {
if (section.header.type != elf::SHT_RELA) {
continue;
}
auto name = std::string { shStrTab + section.header.name };
if (name.compare(".rela.dyn") == 0) {
// Skip dyn relocations
continue;
}
auto symTab = reinterpret_cast<elf::Symbol *>(inSections[section.header.link].data.data());
auto relTab = reinterpret_cast<elf::Rela *>(section.data.data());
auto count = section.data.size() / sizeof(elf::Rela);
for (auto i = 0u; i < count; ++i) {
auto relocation = new ElfFile::Relocation();
auto &rela = relTab[i];
auto type = rela.info & 0xff;
auto index = rela.info >> 8;
auto &sym = symTab[index];
auto symType = sym.info & 0xf;
if (symType == elf::STT_SECTION && sym.value == CodeAddress) {
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if (rela.offset < CodeAddress || rela.offset >= DataAddress) {
std::cout << "Unexpected symbol referenced in relocation section " << name << std::endl;
return false;
}
}
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auto addend = static_cast<uint32_t>(rela.addend);
if (auto import = findImport(file, addend)) {
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relocation->symbol = import->stubSymbol;
relocation->addend = 0;
} else if (auto symbol = findSymbol(file, addend)) {
relocation->symbol = symbol;
relocation->addend = 0;
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} else if (addend >= DataAddress && addend < WiiuLoadAddress) {
relocation->symbol = findSymbol(file, DataAddress);
relocation->addend = addend - DataAddress;
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} else {
// If we can't find a proper symbol, write the addend in and hope for the best
auto ptr = getLoaderDataPtr<uint32_t>(inSections, rela.offset);
*ptr = addend;
std::cout << "Unexpected addend " << std::hex << addend << " referenced in relocation section " << name << ", continuing." << std::endl;
continue;
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}
relocation->target = rela.offset;
relocation->type = static_cast<elf::RelocationType>(type);
file.relocations.emplace_back(relocation);
}
}
// Read dyn relocations
for (auto &section : inSections) {
if (section.header.type != elf::SHT_RELA) {
continue;
}
auto name = std::string { shStrTab + section.header.name };
if (name.compare(".rela.dyn") != 0) {
continue;
}
auto symSection = inSections[section.header.link];
auto relas = reinterpret_cast<elf::Rela *>(section.data.data());
auto count = section.data.size() / sizeof(elf::Rela);
for (auto i = 0u; i < count; ++i) {
auto relocation = new ElfFile::Relocation();
auto &rela = relas[i];
auto type = rela.info & 0xff;
auto index = rela.info >> 8;
auto symbol = getSectionSymbol(symSection, index);
auto addr = symbol->value + rela.addend;
if(index == 0)
{
auto addend = static_cast<uint32_t>(rela.addend);
if (auto import = findImport(file, addend)) {
relocation->symbol = import->stubSymbol;
relocation->addend = 0;
} else if (auto symbol = findSymbol(file, addend)) {
relocation->symbol = symbol;
relocation->addend = 0;
} else if (addr >= CodeAddress && addr < DataAddress) {
index = 1;
relocation->symbol = findSymbol(file, CodeAddress);
relocation->addend = rela.addend - CodeAddress;
} else if (addr >= DataAddress && addr < WiiuLoadAddress) {
index = 2;
relocation->symbol = findSymbol(file, DataAddress);
relocation->addend = rela.addend - DataAddress;
} else {
std::cout << "Unexpected symbol address in .rela.dyn section" << std::endl;
return false;
}
}
switch (type) {
case elf::R_PPC_RELATIVE:
type = elf::R_PPC_ADDR32;
break;
default:
std::cout << "Unexpected relocation type in .rela.dyn section" << std::endl;
return false;
}
relocation->target = rela.offset;
relocation->type = static_cast<elf::RelocationType>(type);
// Scrap any compiler/linker garbage
if(relocation->target >= CodeAddress && relocation->target < WiiuLoadAddress)
file.relocations.emplace_back(relocation);
}
}
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return true;
}
struct OutputSection
{
std::string name;
elf::SectionHeader header;
std::vector<char> data;
OutputSection *relocationSection = nullptr;
ElfFile::Symbol *sectionSymbol = nullptr;
};
template<typename SymbolIterator>
SymbolIterator addSection(ElfFile &file, std::vector<OutputSection *> &outSections, SymbolIterator symbolIterator, OutputSection *section)
{
auto sectionSymbol = new ElfFile::Symbol();
sectionSymbol->name = section->name;
sectionSymbol->address = section->header.addr;
sectionSymbol->size = -1;
sectionSymbol->type = elf::STT_SECTION;
sectionSymbol->binding = elf::STB_LOCAL;
section->sectionSymbol = sectionSymbol;
outSections.push_back(section);
return file.symbols.insert(symbolIterator, std::unique_ptr<ElfFile::Symbol> { sectionSymbol }) + 1;
};
static uint32_t
getSectionIndex(std::vector<OutputSection *> &outSections, uint32_t address)
{
for (auto i = 0u; i < outSections.size(); ++i) {
auto &section = outSections[i];
auto start = section->header.addr;
auto end = start + section->header.size;
if (address >= start && address < end) {
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return i;
}
}
return -1;
}
static uint32_t
getSectionIndex(std::vector<OutputSection *> &outSections, const std::string &name)
{
for (auto i = 0u; i < outSections.size(); ++i) {
auto &section = outSections[i];
if (section->name.compare(name) == 0) {
return i;
}
}
return -1;
}
static bool
write(ElfFile &file, const std::string &filename)
{
std::vector<OutputSection *> outSections;
auto sectionSymbolItr = file.symbols.begin() + 4;
// Create NULL section
auto nullSection = new OutputSection();
memset(&nullSection->header, 0, sizeof(elf::SectionHeader));
outSections.push_back(nullSection);
// Create text/data sections
for (auto &section : file.dataSections) {
auto out = new OutputSection();
out->header.name = -1;
out->header.type = section->type;
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out->header.flags = section->flags;
out->header.addr = section->address;
out->header.offset = -1;
if (section->type == elf::SHT_NOBITS) {
out->header.size = section->size;
} else {
out->header.size = section->data.size();
}
out->header.link = 0;
out->header.info = 0;
if (section->address == DataAddress) {
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out->header.addralign = 4096;
out->header.flags |= elf::SHF_WRITE; // .rodata needs to be writable?
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} else {
out->header.addralign = 256;
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}
out->header.entsize = 0;
// Add section
out->name = section->name;
out->data = section->data;
sectionSymbolItr = addSection(file, outSections, sectionSymbolItr, out);
}
// Create relocation sections
for (auto &relocation : file.relocations) {
OutputSection *targetSection = nullptr;
for (auto &section : outSections) {
auto start = section->header.addr;
auto end = start + section->header.size;
if (relocation->target >= start && relocation->target < end) {
targetSection = section;
break;
}
}
if (!targetSection) {
std::cout << "Error could not find section for relocation" << std::endl;
return false;
}
if (!targetSection->relocationSection) {
// Create new relocation section
auto out = new OutputSection();
out->header.name = -1;
out->header.type = elf::SHT_RELA;
out->header.flags = 0;
out->header.addr = 0;
out->header.offset = -1;
out->header.size = -1;
out->header.link = -1;
out->header.info = getSectionIndex(outSections, targetSection->header.addr);
out->header.addralign = 4;
out->header.entsize = sizeof(elf::Rela);
// Add section
out->name = ".rela" + targetSection->name;
sectionSymbolItr = addSection(file, outSections, sectionSymbolItr, out);
targetSection->relocationSection = out;
}
}
// Calculate sizes of symbol/string tables so RPL imports are placed after them
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auto loadAddress = 0xC0000000;
auto predictStrTabSize = 1;
auto predictSymTabSize = 1;
auto predictShstrTabSize = 1;
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for (auto &symbol : file.symbols) {
predictStrTabSize += symbol->name.size() + 1;
predictSymTabSize += sizeof(elf::Symbol);
}
for (auto &section : outSections) {
predictShstrTabSize += section->name.size() + 1;
}
predictStrTabSize = align_up(predictStrTabSize, 0x10);
predictSymTabSize = align_up(predictSymTabSize, 0x10);
predictShstrTabSize = align_up(predictShstrTabSize, 0x10);
loadAddress += predictStrTabSize + predictSymTabSize + predictShstrTabSize;
// Create RPL import sections, .fimport_*, .dimport_*
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for (auto &lib : file.rplImports) {
auto out = new OutputSection();
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out->header.name = -1;
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out->header.type = elf::SHT_RPL_IMPORTS;
out->header.flags = elf::SHF_ALLOC | elf::SHF_EXECINSTR;
out->header.addr = loadAddress;
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out->header.offset = -1;
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out->header.link = 0;
out->header.info = 0;
out->header.addralign = 4;
out->header.entsize = 0;
out->name = ".fimport_" + lib->name;
// Calculate size
auto nameSize = align_up(8 + lib->name.size(), 8);
auto stubSize = 8 + 8 * lib->imports.size();
out->header.size = std::max(nameSize, stubSize);
out->data.resize(out->header.size);
// Setup data
auto imports = reinterpret_cast<elf::RplImport*>(out->data.data());
imports->count = lib->imports.size();
imports->signature = crc32(0, Z_NULL, 0);
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memcpy(imports->name, lib->name.data(), lib->name.size());
imports->name[lib->name.size()] = 0;
// Update address of import symbols
for (auto i = 0u; i < lib->imports.size(); ++i) {
lib->imports[i]->stubSymbol->address = loadAddress + 8 + i * 8;
}
loadAddress = align_up(loadAddress + out->header.size, 4);
// Add section
sectionSymbolItr = addSection(file, outSections, sectionSymbolItr, out);
}
// Prune out unneeded symbols
for (auto i = 0u; i < file.symbols.size(); ++i) {
if (!file.symbols[i]->name.empty() && file.symbols[i]->type == elf::STT_NOTYPE && file.symbols[i]->size == 0) {
file.symbols.erase(file.symbols.begin() + i);
i--;
}
}
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// NOTICE: FROM NOW ON DO NOT MODIFY mSymbols
// Convert relocations
for (auto &relocation : file.relocations) {
OutputSection *targetSection = nullptr;
for (auto &section : outSections) {
auto start = section->header.addr;
auto end = start + section->header.size;
if (relocation->target >= start && relocation->target < end) {
targetSection = section;
break;
}
}
if (!targetSection || !targetSection->relocationSection) {
std::cout << "Error could not find section for relocation" << std::endl;
return false;
}
// Get address of relocation->target
auto relocationSection = targetSection->relocationSection;
// Find symbol this relocation points to
auto itr = std::find_if(file.symbols.begin(), file.symbols.end(), [&relocation](auto &val) {
return val.get() == relocation->symbol;
});
auto idx = itr - file.symbols.begin();
// If the symbol doesn't exist but it is within DATA or TEXT, use those symbols + an addend
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if (itr == file.symbols.end()) {
if (relocation->symbol->address >= CodeAddress && relocation->symbol->address < DataAddress) {
idx = 1;
relocation->addend = relocation->symbol->address - CodeAddress;
relocation->symbol = findSymbol(file, CodeAddress);
} else if (relocation->symbol->address >= DataAddress && relocation->symbol->address < WiiuLoadAddress) {
idx = 2;
relocation->addend = relocation->symbol->address - DataAddress;
relocation->symbol = findSymbol(file, DataAddress);
} else {
std::cout << "Could not find matching symbol for relocation" << std::endl;
return false;
}
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}
// Create relocation
elf::Rela rela;
rela.info = relocation->type | idx << 8;
if(relocation->type == elf::R_PPC_RELATIVE) {
rela.info = elf::R_PPC_ADDR32 | idx << 8;
}
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rela.addend = relocation->addend;
rela.offset = relocation->target;
// Append to relocation section data
char *relaData = reinterpret_cast<char *>(&rela);
relocationSection->data.insert(relocationSection->data.end(), relaData, relaData + sizeof(elf::Rela));
}
// String + Symbol sections
auto symTabSection = new OutputSection();
auto strTabSection = new OutputSection();
auto shStrTabSection = new OutputSection();
symTabSection->name = ".symtab";
strTabSection->name = ".strtab";
shStrTabSection->name = ".shstrtab";
auto symTabIndex = outSections.size();
outSections.push_back(symTabSection);
auto strTabIndex = outSections.size();
outSections.push_back(strTabSection);
auto shStrTabIndex = outSections.size();
outSections.push_back(shStrTabSection);
// Update relocation sections to link to symtab
for (auto &section : outSections) {
if (section->header.type == elf::SHT_RELA) {
section->header.link = symTabIndex;
}
if (section->header.type != elf::SHT_NOBITS) {
section->header.size = section->data.size();
}
if (section->sectionSymbol) {
section->sectionSymbol->address = section->header.addr;
section->sectionSymbol->size = section->header.size;
}
}
// Create .strtab
strTabSection->header.name = 0;
strTabSection->header.type = elf::SHT_STRTAB;
strTabSection->header.flags = elf::SHF_ALLOC;
strTabSection->header.addr = 0;
strTabSection->header.offset = -1;
strTabSection->header.size = -1;
strTabSection->header.link = 0;
strTabSection->header.info = 0;
strTabSection->header.addralign = 1;
strTabSection->header.entsize = 0;
// Add all symbol names to data, update symbol->outNamePos
strTabSection->data.push_back(0);
for (auto &symbol : file.symbols) {
if (symbol->name.empty()) {
symbol->outNamePos = 0;
} else {
symbol->outNamePos = static_cast<uint32_t>(strTabSection->data.size());
std::copy(symbol->name.begin(), symbol->name.end(), std::back_inserter(strTabSection->data));
strTabSection->data.push_back(0);
}
}
// Create .symtab
symTabSection->header.name = 0;
symTabSection->header.type = elf::SHT_SYMTAB;
symTabSection->header.flags = elf::SHF_ALLOC;
symTabSection->header.addr = 0;
symTabSection->header.offset = -1;
symTabSection->header.size = -1;
symTabSection->header.link = strTabIndex;
symTabSection->header.info = 0;
symTabSection->header.addralign = 4;
symTabSection->header.entsize = sizeof(elf::Symbol);
for (auto &symbol : file.symbols) {
elf::Symbol sym;
auto shndx = getSectionIndex(outSections, symbol->address);
if (symbol->type == elf::STT_SECTION && symbol->address == 0) {
shndx = getSectionIndex(outSections, symbol->name);
}
if (shndx == -1) {
std::cout << "Could not find section for symbol" << std::endl;
return false;
}
sym.name = symbol->outNamePos;
sym.value = symbol->address;
sym.size = symbol->size;
sym.info = symbol->type | (symbol->binding << 4);
sym.other = 0;
sym.shndx = shndx;
//Compound symbol crc into section crc
auto crcSection = outSections[shndx];
if(crcSection->header.type == elf::SHT_RPL_IMPORTS && symbol->type != elf::STT_SECTION) {
auto rplImport = reinterpret_cast<elf::RplImport*>(crcSection->data.data());
rplImport->signature = crc32(rplImport->signature, reinterpret_cast<Bytef *>(strTabSection->data.data() + sym.name),strlen(strTabSection->data.data() + sym.name)+1);
}
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// Append to symtab data
char *symData = reinterpret_cast<char *>(&sym);
symTabSection->data.insert(symTabSection->data.end(), symData, symData + sizeof(elf::Symbol));
}
//Finish SHT_RPL_IMPORTS signatures
Bytef *zero_buffer = reinterpret_cast<Bytef *>(calloc(0x10, 1));
for (auto &section : outSections) {
if(section->header.type == elf::SHT_RPL_IMPORTS) {
auto rplImport = reinterpret_cast<elf::RplImport*>(section->data.data());
rplImport->signature = crc32(rplImport->signature, zero_buffer, 0xE);
}
}
free(zero_buffer);
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// Create .shstrtab
shStrTabSection->header.name = 0;
shStrTabSection->header.type = elf::SHT_STRTAB;
shStrTabSection->header.flags = elf::SHF_ALLOC;
shStrTabSection->header.addr = 0;
shStrTabSection->header.offset = -1;
shStrTabSection->header.size = -1;
shStrTabSection->header.link = 0;
shStrTabSection->header.info = 0;
shStrTabSection->header.addralign = 1;
shStrTabSection->header.entsize = 0;
// Add all section header names to data, update section->header.name
shStrTabSection->data.push_back(0);
for (auto &section : outSections) {
if (section->name.empty()) {
section->header.name = 0;
} else {
section->header.name = shStrTabSection->data.size();
std::copy(section->name.begin(), section->name.end(), std::back_inserter(shStrTabSection->data));
shStrTabSection->data.push_back(0);
}
}
loadAddress = 0xC0000000;
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// Update symtab, strtab, shstrtab section addresses
symTabSection->header.addr = loadAddress;
symTabSection->header.size = symTabSection->data.size();
loadAddress = align_up(symTabSection->header.addr + predictSymTabSize, 16);
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strTabSection->header.addr = loadAddress;
strTabSection->header.size = strTabSection->data.size();
loadAddress = align_up(strTabSection->header.addr + predictStrTabSize, 16);
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shStrTabSection->header.addr = loadAddress;
shStrTabSection->header.size = shStrTabSection->data.size();
// Create SHT_RPL_FILEINFO section
auto fileInfoSection = new OutputSection();
fileInfoSection->header.name = 0;
fileInfoSection->header.type = elf::SHT_RPL_FILEINFO;
fileInfoSection->header.flags = 0;
fileInfoSection->header.addr = 0;
fileInfoSection->header.offset = -1;
fileInfoSection->header.size = -1;
fileInfoSection->header.link = 0;
fileInfoSection->header.info = 0;
fileInfoSection->header.addralign = 4;
fileInfoSection->header.entsize = 0;
elf::RplFileInfo fileInfo;
fileInfo.version = 0xCAFE0402;
fileInfo.textSize = 0;
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fileInfo.textAlign = 32;
fileInfo.dataSize = 0;
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fileInfo.dataAlign = 4096;
fileInfo.loadSize = 0;
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fileInfo.loadAlign = 4;
fileInfo.tempSize = 0;
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fileInfo.trampAdjust = 0;
fileInfo.trampAddition = 0;
fileInfo.sdaBase = 0;
fileInfo.sda2Base = 0;
fileInfo.stackSize = 0x10000;
fileInfo.heapSize = 0x8000;
fileInfo.filename = 0;
fileInfo.flags = elf::RPL_IS_RPX;
fileInfo.minVersion = 0x5078;
fileInfo.compressionLevel = -1;
fileInfo.fileInfoPad = 0;
fileInfo.cafeSdkVersion = 0x51BA;
fileInfo.cafeSdkRevision = 0xCCD1;
fileInfo.tlsAlignShift = 0;
fileInfo.tlsModuleIndex = 0;
fileInfo.runtimeFileInfoSize = 0;
fileInfo.tagOffset = 0;
// Count file info textSize, dataSize, loadSize
for (auto &section : outSections) {
auto size = section->data.size();
if (section->header.type == elf::SHT_NOBITS) {
size = section->header.size;
}
if (section->header.addr >= CodeAddress && section->header.addr < DataAddress) {
auto val = section->header.addr.value() + section->header.size.value() - CodeAddress;
if(val > fileInfo.textSize) {
fileInfo.textSize = val;
}
} else if (section->header.addr >= DataAddress && section->header.addr < WiiuLoadAddress) {
auto val = section->header.addr.value() + section->header.size.value() - DataAddress;
if(val > fileInfo.dataSize) {
fileInfo.dataSize = val;
}
} else if (section->header.addr >= WiiuLoadAddress) {
auto val = section->header.addr.value() + section->header.size.value() - WiiuLoadAddress;
if(val > fileInfo.loadSize) {
fileInfo.loadSize = val;
}
} else if (section->header.addr == 0 && section->header.type != elf::SHT_RPL_CRCS && section->header.type != elf::SHT_RPL_FILEINFO) {
fileInfo.tempSize += (size + 128);
}
}
//TODO: These were calculated based on observation, however some games differ.
fileInfo.sdaBase = align_up(DataAddress + fileInfo.dataSize + fileInfo.heapSize, 64);
fileInfo.sda2Base = align_up(DataAddress + fileInfo.heapSize, 64);
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char *fileInfoData = reinterpret_cast<char *>(&fileInfo);
fileInfoSection->data.insert(fileInfoSection->data.end(), fileInfoData, fileInfoData + sizeof(elf::RplFileInfo));
// Create SHT_RPL_CRCS section
auto crcSection = new OutputSection();
crcSection->header.name = 0;
crcSection->header.type = elf::SHT_RPL_CRCS;
crcSection->header.flags = 0;
crcSection->header.addr = 0;
crcSection->header.offset = -1;
crcSection->header.size = -1;
crcSection->header.link = 0;
crcSection->header.info = 0;
crcSection->header.addralign = 4;
crcSection->header.entsize = 4;
outSections.push_back(crcSection);
outSections.push_back(fileInfoSection);
std::vector<uint32_t> sectionCRCs;
for (auto &section : outSections) {
auto crc = 0u;
if (!section->data.empty()) {
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crc = crc32(0, Z_NULL, 0);
crc = crc32(crc, reinterpret_cast<Bytef *>(section->data.data()), section->data.size());
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}
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sectionCRCs.push_back(byte_swap(crc));
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}
char *crcData = reinterpret_cast<char *>(sectionCRCs.data());
crcSection->data.insert(crcSection->data.end(), crcData, crcData + sizeof(uint32_t) * sectionCRCs.size());
// Update section sizes and offsets
auto shoff = align_up(sizeof(elf::Header), 64);
auto dataOffset = align_up(shoff + outSections.size() * sizeof(elf::SectionHeader), 64);
// Add CRC and FileInfo sections first
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for (auto &section : outSections) {
if (section->header.type != elf::SHT_RPL_CRCS && section->header.type != elf::SHT_RPL_FILEINFO) {
continue;
}
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if (section->header.type != elf::SHT_NOBITS) {
section->header.size = section->data.size();
}
if (!section->data.empty()) {
section->header.offset = dataOffset;
dataOffset = align_up(section->header.offset + section->data.size(), 64);
} else {
section->header.offset = 0;
}
}
// Add data sections next
for (auto &section : outSections) {
if(section->header.offset != -1) {
continue;
}
if (section->header.addr < DataAddress || section->header.addr >= WiiuLoadAddress) {
continue;
}
if (section->header.type != elf::SHT_NOBITS) {
section->header.size = section->data.size();
}
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if (!section->data.empty()) {
section->header.offset = dataOffset;
dataOffset = align_up(section->header.offset + section->data.size(), 64);
} else {
section->header.offset = 0;
}
}
// Add load sections next
for (auto &section : outSections) {
if(section->header.offset != -1) {
continue;
}
if (section->header.addr < WiiuLoadAddress) {
continue;
}
if (section->header.type != elf::SHT_NOBITS) {
section->header.size = section->data.size();
}
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if (!section->data.empty()) {
section->header.offset = dataOffset;
dataOffset = align_up(section->header.offset + section->data.size(), 64);
} else {
section->header.offset = 0;
}
}
// Everything else
for (auto &section : outSections) {
if(section->header.offset != -1) {
continue;
}
if (section->header.type != elf::SHT_NOBITS) {
section->header.size = section->data.size();
}
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if (!section->data.empty()) {
section->header.offset = dataOffset;
dataOffset = align_up(section->header.offset + section->data.size(), 64);
} else {
section->header.offset = 0;
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}
}
// Write to file
std::ofstream out { filename, std::ofstream::binary };
std::vector<char> padding;
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if (!out.is_open()) {
std::cout << "Could not open " << filename << " for writing" << std::endl;
return false;
}
elf::Header header;
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header.magic = elf::HeaderMagic;
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header.fileClass = 1;
header.encoding = elf::ELFDATA2MSB;
header.elfVersion = elf::EV_CURRENT;
header.abi = elf::EABI_CAFE;
memset(&header.pad, 0, 7);
header.type = 0xFE01;
header.machine = elf::EM_PPC;
header.version = 1;
header.entry = file.entryPoint;
header.phoff = 0;
header.phentsize = 0;
header.phnum = 0;
header.shoff = shoff;
header.shnum = outSections.size();
header.shentsize = sizeof(elf::SectionHeader);
header.flags = 0;
header.ehsize = sizeof(elf::Header);
header.shstrndx = shStrTabIndex;
out.write(reinterpret_cast<char *>(&header), sizeof(elf::Header));
// Write section headers
out.seekp(header.shoff.value());
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for (auto &section : outSections) {
out.write(reinterpret_cast<char *>(&section->header), sizeof(elf::SectionHeader));
}
// Write section data
for (auto &section : outSections) {
if (!section->data.empty()) {
out.seekp(section->header.offset.value());
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out.write(section->data.data(), section->data.size());
}
}
return true;
}
int main(int argc, char **argv)
{
if (argc < 3) {
std::cout << "Usage: " << argv[0] << " <src> <dst>" << std::endl;
return -1;
}
ElfFile elf;
auto src = argv[1];
auto dst = argv[2];
if (!read(elf, src)) {
return -1;
}
if (!write(elf, dst)) {
return -1;
}
return 0;
}