/* This Source Code Form is subject to the terms of the Mozilla Public * License, v. 2.0. If a copy of the MPL was not distributed with this * file, You can obtain one at http://mozilla.org/MPL/2.0/. */ #undef NDEBUG #include #include #include "elfxx.h" template void Elf_Ehdr_Traits::swap(T& t, R& r) { memcpy(r.e_ident, t.e_ident, sizeof(r.e_ident)); r.e_type = endian::swap(t.e_type); r.e_machine = endian::swap(t.e_machine); r.e_version = endian::swap(t.e_version); r.e_entry = endian::swap(t.e_entry); r.e_phoff = endian::swap(t.e_phoff); r.e_shoff = endian::swap(t.e_shoff); r.e_flags = endian::swap(t.e_flags); r.e_ehsize = endian::swap(t.e_ehsize); r.e_phentsize = endian::swap(t.e_phentsize); r.e_phnum = endian::swap(t.e_phnum); r.e_shentsize = endian::swap(t.e_shentsize); r.e_shnum = endian::swap(t.e_shnum); r.e_shstrndx = endian::swap(t.e_shstrndx); } template void Elf_Phdr_Traits::swap(T& t, R& r) { r.p_type = endian::swap(t.p_type); r.p_offset = endian::swap(t.p_offset); r.p_vaddr = endian::swap(t.p_vaddr); r.p_paddr = endian::swap(t.p_paddr); r.p_filesz = endian::swap(t.p_filesz); r.p_memsz = endian::swap(t.p_memsz); r.p_flags = endian::swap(t.p_flags); r.p_align = endian::swap(t.p_align); } template void Elf_Shdr_Traits::swap(T& t, R& r) { r.sh_name = endian::swap(t.sh_name); r.sh_type = endian::swap(t.sh_type); r.sh_flags = endian::swap(t.sh_flags); r.sh_addr = endian::swap(t.sh_addr); r.sh_offset = endian::swap(t.sh_offset); r.sh_size = endian::swap(t.sh_size); r.sh_link = endian::swap(t.sh_link); r.sh_info = endian::swap(t.sh_info); r.sh_addralign = endian::swap(t.sh_addralign); r.sh_entsize = endian::swap(t.sh_entsize); } template void Elf_Dyn_Traits::swap(T& t, R& r) { r.d_tag = endian::swap(t.d_tag); r.d_un.d_val = endian::swap(t.d_un.d_val); } template void Elf_Sym_Traits::swap(T& t, R& r) { r.st_name = endian::swap(t.st_name); r.st_value = endian::swap(t.st_value); r.st_size = endian::swap(t.st_size); r.st_info = t.st_info; r.st_other = t.st_other; r.st_shndx = endian::swap(t.st_shndx); } template struct _Rel_info { static inline void swap(Elf32_Word& t, Elf32_Word& r) { r = endian::swap(t); } static inline void swap(Elf64_Xword& t, Elf64_Xword& r) { r = endian::swap(t); } static inline void swap(Elf64_Xword& t, Elf32_Word& r) { r = endian::swap(ELF32_R_INFO(ELF64_R_SYM(t), ELF64_R_TYPE(t))); } static inline void swap(Elf32_Word& t, Elf64_Xword& r) { r = endian::swap(ELF64_R_INFO(ELF32_R_SYM(t), ELF32_R_TYPE(t))); } }; template void Elf_Rel_Traits::swap(T& t, R& r) { r.r_offset = endian::swap(t.r_offset); _Rel_info::swap(t.r_info, r.r_info); } template void Elf_Rela_Traits::swap(T& t, R& r) { r.r_offset = endian::swap(t.r_offset); _Rel_info::swap(t.r_info, r.r_info); r.r_addend = endian::swap(t.r_addend); } static const Elf32_Shdr null32_section = {0, SHT_NULL, 0, 0, 0, 0, SHN_UNDEF, 0, 0, 0}; Elf_Shdr null_section(null32_section); Elf_Ehdr::Elf_Ehdr(std::ifstream& file, char ei_class, char ei_data) : serializable(file, ei_class, ei_data), ElfSection(null_section, nullptr, nullptr) { shdr.sh_size = Elf_Ehdr::size(ei_class); } Elf::Elf(std::ifstream& file) { if (!file.is_open()) throw std::runtime_error("Error opening file"); file.exceptions(std::ifstream::eofbit | std::ifstream::failbit | std::ifstream::badbit); // Read ELF magic number and identification information char e_ident[EI_VERSION]; file.seekg(0); file.read(e_ident, sizeof(e_ident)); file.seekg(0); ehdr = new Elf_Ehdr(file, e_ident[EI_CLASS], e_ident[EI_DATA]); // ELFOSABI_LINUX is kept unsupported because I haven't looked whether // STB_GNU_UNIQUE or STT_GNU_IFUNC would need special casing. if ((ehdr->e_ident[EI_OSABI] != ELFOSABI_NONE) && (ehdr->e_ident[EI_ABIVERSION] != 0)) throw std::runtime_error("unsupported ELF ABI"); if (ehdr->e_version != 1) throw std::runtime_error("unsupported ELF version"); // Sanity checks if (ehdr->e_shnum == 0) throw std::runtime_error("sstripped ELF files aren't supported"); if (ehdr->e_ehsize != Elf_Ehdr::size(e_ident[EI_CLASS])) throw std::runtime_error( "unsupported ELF inconsistency: ehdr.e_ehsize != sizeof(ehdr)"); if (ehdr->e_shentsize != Elf_Shdr::size(e_ident[EI_CLASS])) throw std::runtime_error( "unsupported ELF inconsistency: ehdr.e_shentsize != sizeof(shdr)"); if (ehdr->e_phnum == 0) { if (ehdr->e_phoff != 0) throw std::runtime_error( "unsupported ELF inconsistency: e_phnum == 0 && e_phoff != 0"); if (ehdr->e_phentsize != 0) throw std::runtime_error( "unsupported ELF inconsistency: e_phnum == 0 && e_phentsize != 0"); } else if (ehdr->e_phoff != ehdr->e_ehsize) throw std::runtime_error( "unsupported ELF inconsistency: ehdr->e_phoff != ehdr->e_ehsize"); else if (ehdr->e_phentsize != Elf_Phdr::size(e_ident[EI_CLASS])) throw std::runtime_error( "unsupported ELF inconsistency: ehdr->e_phentsize != sizeof(phdr)"); // Read section headers Elf_Shdr** shdr = new Elf_Shdr*[ehdr->e_shnum]; file.seekg(ehdr->e_shoff); for (int i = 0; i < ehdr->e_shnum; i++) shdr[i] = new Elf_Shdr(file, e_ident[EI_CLASS], e_ident[EI_DATA]); // Sanity check in section header for index 0 if ((shdr[0]->sh_name != 0) || (shdr[0]->sh_type != SHT_NULL) || (shdr[0]->sh_flags != 0) || (shdr[0]->sh_addr != 0) || (shdr[0]->sh_offset != 0) || (shdr[0]->sh_size != 0) || (shdr[0]->sh_link != SHN_UNDEF) || (shdr[0]->sh_info != 0) || (shdr[0]->sh_addralign != 0) || (shdr[0]->sh_entsize != 0)) throw std::runtime_error( "Section header for index 0 contains unsupported values"); if ((shdr[ehdr->e_shstrndx]->sh_link != 0) || (shdr[ehdr->e_shstrndx]->sh_info != 0)) throw std::runtime_error( "unsupported ELF content: string table with sh_link != 0 || sh_info != " "0"); // Store these temporarily tmp_shdr = shdr; tmp_file = &file; // Fill sections list sections = new ElfSection*[ehdr->e_shnum]; for (int i = 0; i < ehdr->e_shnum; i++) sections[i] = nullptr; for (int i = 1; i < ehdr->e_shnum; i++) { // The .dynamic section is going to have references to other sections, // so it's better to start with that one and recursively initialize those // other sections first, to avoid possible infinite recursion (bug 1606739). if (tmp_shdr[i]->sh_type == SHT_DYNAMIC) { getSection(i); } } for (int i = 1; i < ehdr->e_shnum; i++) { if (sections[i] != nullptr) continue; getSection(i); } Elf_Shdr s; s.sh_name = 0; s.sh_type = SHT_NULL; s.sh_flags = 0; s.sh_addr = 0; s.sh_offset = ehdr->e_shoff; s.sh_entsize = Elf_Shdr::size(e_ident[EI_CLASS]); s.sh_size = s.sh_entsize * ehdr->e_shnum; s.sh_link = 0; s.sh_info = 0; s.sh_addralign = (e_ident[EI_CLASS] == ELFCLASS32) ? 4 : 8; shdr_section = new ElfSection(s, nullptr, nullptr); // Fake section for program headers s.sh_offset = ehdr->e_phoff; s.sh_addr = ehdr->e_phoff; s.sh_entsize = Elf_Phdr::size(e_ident[EI_CLASS]); s.sh_size = s.sh_entsize * ehdr->e_phnum; phdr_section = new ElfSection(s, nullptr, nullptr); phdr_section->insertAfter(ehdr, false); sections[1]->insertAfter(phdr_section, false); for (int i = 2; i < ehdr->e_shnum; i++) { // TODO: this should be done in a better way if ((shdr_section->getPrevious() == nullptr) && (shdr[i]->sh_offset > ehdr->e_shoff)) { shdr_section->insertAfter(sections[i - 1], false); sections[i]->insertAfter(shdr_section, false); } else sections[i]->insertAfter(sections[i - 1], false); } if (shdr_section->getPrevious() == nullptr) shdr_section->insertAfter(sections[ehdr->e_shnum - 1], false); tmp_file = nullptr; tmp_shdr = nullptr; for (int i = 0; i < ehdr->e_shnum; i++) delete shdr[i]; delete[] shdr; eh_shstrndx = (ElfStrtab_Section*)sections[ehdr->e_shstrndx]; // Skip reading program headers if there aren't any if (ehdr->e_phnum == 0) return; bool adjusted_phdr_section = false; // Read program headers file.seekg(ehdr->e_phoff); for (int i = 0; i < ehdr->e_phnum; i++) { Elf_Phdr phdr(file, e_ident[EI_CLASS], e_ident[EI_DATA]); if (phdr.p_type == PT_LOAD) { // Default alignment for PT_LOAD on x86-64 prevents elfhack from // doing anything useful. However, the system doesn't actually // require such a big alignment, so in order for elfhack to work // efficiently, reduce alignment when it's originally the default // one. if ((ehdr->e_machine == EM_X86_64) && (phdr.p_align == 0x200000)) phdr.p_align = 0x1000; } ElfSegment* segment = new ElfSegment(&phdr); // Some segments aren't entirely filled (if at all) by sections // For those, we use fake sections if ((phdr.p_type == PT_LOAD) && (phdr.p_offset == 0)) { // Use a fake section for ehdr and phdr ehdr->getShdr().sh_addr = phdr.p_vaddr; if (!adjusted_phdr_section) { phdr_section->getShdr().sh_addr += phdr.p_vaddr; adjusted_phdr_section = true; } segment->addSection(ehdr); segment->addSection(phdr_section); } if (phdr.p_type == PT_PHDR) { if (!adjusted_phdr_section) { phdr_section->getShdr().sh_addr = phdr.p_vaddr; adjusted_phdr_section = true; } segment->addSection(phdr_section); } for (int j = 1; j < ehdr->e_shnum; j++) if (phdr.contains(sections[j])) segment->addSection(sections[j]); // Make sure that our view of segments corresponds to the original // ELF file. // GNU gold likes to start some segments before the first section // they contain. https://sourceware.org/bugzilla/show_bug.cgi?id=19392 unsigned int gold_adjustment = segment->getAddr() - phdr.p_vaddr; assert(segment->getFileSize() == phdr.p_filesz - gold_adjustment); // gold makes TLS segments end on an aligned virtual address, even // when the underlying section ends before that, while bfd ld // doesn't. It's fine if we don't keep that alignment. unsigned int memsize = segment->getMemSize(); if (phdr.p_type == PT_TLS && memsize != phdr.p_memsz) { unsigned int align = segment->getAlign(); memsize = (memsize + align - 1) & ~(align - 1); } assert(memsize == phdr.p_memsz - gold_adjustment); segments.push_back(segment); } new (&eh_entry) ElfLocation(ehdr->e_entry, this); } Elf::~Elf() { for (std::vector::iterator seg = segments.begin(); seg != segments.end(); seg++) delete *seg; delete[] sections; ElfSection* section = ehdr; while (section != nullptr) { ElfSection* next = section->getNext(); delete section; section = next; } } // TODO: This shouldn't fail after inserting sections ElfSection* Elf::getSection(int index) { if ((index < -1) || (index >= ehdr->e_shnum)) throw std::runtime_error("Section index out of bounds"); if (index == -1) index = ehdr->e_shstrndx; // TODO: should be fixed to use the actual // current number // Special case: the section at index 0 is void if (index == 0) return nullptr; // Infinite recursion guard if (sections[index] == (ElfSection*)this) return nullptr; if (sections[index] == nullptr) { sections[index] = (ElfSection*)this; switch (tmp_shdr[index]->sh_type) { case SHT_DYNAMIC: sections[index] = new ElfDynamic_Section(*tmp_shdr[index], tmp_file, this); break; case SHT_REL: sections[index] = new ElfRel_Section(*tmp_shdr[index], tmp_file, this); break; case SHT_RELA: sections[index] = new ElfRel_Section(*tmp_shdr[index], tmp_file, this); break; case SHT_DYNSYM: case SHT_SYMTAB: sections[index] = new ElfSymtab_Section(*tmp_shdr[index], tmp_file, this); break; case SHT_STRTAB: sections[index] = new ElfStrtab_Section(*tmp_shdr[index], tmp_file, this); break; default: sections[index] = new ElfSection(*tmp_shdr[index], tmp_file, this); } } return sections[index]; } ElfSection* Elf::getSectionAt(unsigned int offset) { for (int i = 1; i < ehdr->e_shnum; i++) { ElfSection* section = getSection(i); if ((section != nullptr) && (section->getFlags() & SHF_ALLOC) && !(section->getFlags() & SHF_TLS) && (offset >= section->getAddr()) && (offset < section->getAddr() + section->getSize())) return section; } return nullptr; } ElfSegment* Elf::getSegmentByType(unsigned int type, ElfSegment* last) { std::vector::iterator seg; if (last) { seg = std::find(segments.begin(), segments.end(), last); ++seg; } else seg = segments.begin(); for (; seg != segments.end(); seg++) if ((*seg)->getType() == type) return *seg; return nullptr; } void Elf::removeSegment(ElfSegment* segment) { if (!segment) return; std::vector::iterator seg; seg = std::find(segments.begin(), segments.end(), segment); if (seg == segments.end()) return; segment->clear(); segments.erase(seg); } ElfDynamic_Section* Elf::getDynSection() { for (std::vector::iterator seg = segments.begin(); seg != segments.end(); seg++) if (((*seg)->getType() == PT_DYNAMIC) && ((*seg)->getFirstSection() != nullptr) && (*seg)->getFirstSection()->getType() == SHT_DYNAMIC) return (ElfDynamic_Section*)(*seg)->getFirstSection(); return nullptr; } void Elf::normalize() { // fixup section headers sh_name; TODO: that should be done by sections // themselves for (ElfSection* section = ehdr; section != nullptr; section = section->getNext()) { if (section->getIndex() == 0) continue; else ehdr->e_shnum = section->getIndex() + 1; section->getShdr().sh_name = eh_shstrndx->getStrIndex(section->getName()); } ehdr->markDirty(); // Check segments consistency int i = 0; for (std::vector::iterator seg = segments.begin(); seg != segments.end(); seg++, i++) { std::list::iterator it = (*seg)->begin(); for (ElfSection* last = *(it++); it != (*seg)->end(); last = *(it++)) { if (((*it)->getType() != SHT_NOBITS) && ((*it)->getAddr() - last->getAddr()) != ((*it)->getOffset() - last->getOffset())) { throw std::runtime_error("Segments inconsistency"); } } } ElfSegment* prevLoad = nullptr; for (auto& it : segments) { if (it->getType() == PT_LOAD) { if (prevLoad) { size_t alignedPrevEnd = (prevLoad->getAddr() + prevLoad->getMemSize() + prevLoad->getAlign() - 1) & ~(prevLoad->getAlign() - 1); size_t alignedStart = it->getAddr() & ~(it->getAlign() - 1); if (alignedPrevEnd > alignedStart) { throw std::runtime_error("Segments overlap"); } } prevLoad = it; } } // fixup ehdr before writing if (ehdr->e_phnum != segments.size()) { ehdr->e_phnum = segments.size(); phdr_section->getShdr().sh_size = segments.size() * Elf_Phdr::size(ehdr->e_ident[EI_CLASS]); phdr_section->getNext()->markDirty(); } // fixup shdr before writing if (ehdr->e_shnum != shdr_section->getSize() / shdr_section->getEntSize()) shdr_section->getShdr().sh_size = ehdr->e_shnum * Elf_Shdr::size(ehdr->e_ident[EI_CLASS]); ehdr->e_shoff = shdr_section->getOffset(); ehdr->e_entry = eh_entry.getValue(); ehdr->e_shstrndx = eh_shstrndx->getIndex(); // Check sections consistency unsigned int minOffset = 0; for (ElfSection* section = ehdr; section != nullptr; section = section->getNext()) { unsigned int offset = section->getOffset(); if (offset < minOffset) { throw std::runtime_error("Sections overlap"); } if (section->getType() != SHT_NOBITS) { minOffset = offset + section->getSize(); } } } void Elf::write(std::ofstream& file) { normalize(); for (ElfSection* section = ehdr; section != nullptr; section = section->getNext()) { file.seekp(section->getOffset()); if (section == phdr_section) { for (std::vector::iterator seg = segments.begin(); seg != segments.end(); seg++) { Elf_Phdr phdr; phdr.p_type = (*seg)->getType(); phdr.p_flags = (*seg)->getFlags(); phdr.p_offset = (*seg)->getOffset(); phdr.p_vaddr = (*seg)->getAddr(); phdr.p_paddr = phdr.p_vaddr + (*seg)->getVPDiff(); phdr.p_filesz = (*seg)->getFileSize(); phdr.p_memsz = (*seg)->getMemSize(); phdr.p_align = (*seg)->getAlign(); phdr.serialize(file, ehdr->e_ident[EI_CLASS], ehdr->e_ident[EI_DATA]); } } else if (section == shdr_section) { null_section.serialize(file, ehdr->e_ident[EI_CLASS], ehdr->e_ident[EI_DATA]); for (ElfSection* sec = ehdr; sec != nullptr; sec = sec->getNext()) { if (sec->getType() != SHT_NULL) sec->getShdr().serialize(file, ehdr->e_ident[EI_CLASS], ehdr->e_ident[EI_DATA]); } } else section->serialize(file, ehdr->e_ident[EI_CLASS], ehdr->e_ident[EI_DATA]); } } ElfSection::ElfSection(Elf_Shdr& s, std::ifstream* file, Elf* parent) : shdr(s), link(shdr.sh_link == SHN_UNDEF ? nullptr : parent->getSection(shdr.sh_link)), next(nullptr), previous(nullptr), index(-1) { if ((file == nullptr) || (shdr.sh_type == SHT_NULL) || (shdr.sh_type == SHT_NOBITS)) data = nullptr; else { data = static_cast(malloc(shdr.sh_size)); if (!data) { throw std::runtime_error("Could not malloc ElfSection data"); } auto pos = file->tellg(); file->seekg(shdr.sh_offset); file->read(data, shdr.sh_size); file->seekg(pos); } if (shdr.sh_name == 0) name = nullptr; else { ElfStrtab_Section* strtab = (ElfStrtab_Section*)parent->getSection(-1); // Special case (see elfgeneric.cpp): if strtab is nullptr, the // section being created is the strtab. if (strtab == nullptr) name = &data[shdr.sh_name]; else name = strtab->getStr(shdr.sh_name); } // Only SHT_REL/SHT_RELA sections use sh_info to store a section // number. if ((shdr.sh_type == SHT_REL) || (shdr.sh_type == SHT_RELA)) info.section = shdr.sh_info ? parent->getSection(shdr.sh_info) : nullptr; else info.index = shdr.sh_info; } unsigned int ElfSection::getAddr() { if (shdr.sh_addr != (Elf32_Word)-1) return shdr.sh_addr; // It should be safe to adjust sh_addr for all allocated sections that // are neither SHT_NOBITS nor SHT_PROGBITS if ((previous != nullptr) && isRelocatable()) { unsigned int addr = previous->getAddr(); if (previous->getType() != SHT_NOBITS) addr += previous->getSize(); if (addr & (getAddrAlign() - 1)) addr = (addr | (getAddrAlign() - 1)) + 1; return (shdr.sh_addr = addr); } return shdr.sh_addr; } unsigned int ElfSection::getOffset() { if (shdr.sh_offset != (Elf32_Word)-1) return shdr.sh_offset; if (previous == nullptr) return (shdr.sh_offset = 0); unsigned int offset = previous->getOffset(); ElfSegment* ptload = getSegmentByType(PT_LOAD); ElfSegment* prev_ptload = previous->getSegmentByType(PT_LOAD); if (ptload && (ptload == prev_ptload)) { offset += getAddr() - previous->getAddr(); return (shdr.sh_offset = offset); } if (previous->getType() != SHT_NOBITS) offset += previous->getSize(); Elf32_Word align = 0x1000; for (std::vector::iterator seg = segments.begin(); seg != segments.end(); seg++) align = std::max(align, (*seg)->getAlign()); Elf32_Word mask = align - 1; // SHF_TLS is used for .tbss which is some kind of special case. if (((getType() != SHT_NOBITS) || (getFlags() & SHF_TLS)) && (getFlags() & SHF_ALLOC)) { if ((getAddr() & mask) < (offset & mask)) offset = (offset | mask) + (getAddr() & mask) + 1; else offset = (offset & ~mask) + (getAddr() & mask); } if ((getType() != SHT_NOBITS) && (offset & (getAddrAlign() - 1))) offset = (offset | (getAddrAlign() - 1)) + 1; return (shdr.sh_offset = offset); } int ElfSection::getIndex() { if (index != -1) return index; if (getType() == SHT_NULL) return (index = 0); ElfSection* reference; for (reference = previous; (reference != nullptr) && (reference->getType() == SHT_NULL); reference = reference->getPrevious()) ; if (reference == nullptr) return (index = 1); return (index = reference->getIndex() + 1); } Elf_Shdr& ElfSection::getShdr() { getOffset(); if (shdr.sh_link == (Elf32_Word)-1) shdr.sh_link = getLink() ? getLink()->getIndex() : 0; if (shdr.sh_info == (Elf32_Word)-1) shdr.sh_info = ((getType() == SHT_REL) || (getType() == SHT_RELA)) ? (getInfo().section ? getInfo().section->getIndex() : 0) : getInfo().index; return shdr; } ElfSegment::ElfSegment(Elf_Phdr* phdr) : type(phdr->p_type), v_p_diff(phdr->p_paddr - phdr->p_vaddr), flags(phdr->p_flags), align(phdr->p_align), vaddr(phdr->p_vaddr), filesz(phdr->p_filesz), memsz(phdr->p_memsz) {} void ElfSegment::addSection(ElfSection* section) { // Make sure all sections in PT_GNU_RELRO won't be moved by elfhack assert(!((type == PT_GNU_RELRO) && (section->isRelocatable()))); // TODO: Check overlapping sections std::list::iterator i; for (i = sections.begin(); i != sections.end(); ++i) if ((*i)->getAddr() > section->getAddr()) break; sections.insert(i, section); section->addToSegment(this); } void ElfSegment::removeSection(ElfSection* section) { sections.remove(section); section->removeFromSegment(this); } unsigned int ElfSegment::getFileSize() { if (type == PT_GNU_RELRO) return filesz; if (sections.empty()) return 0; // Search the last section that is not SHT_NOBITS std::list::reverse_iterator i; for (i = sections.rbegin(); (i != sections.rend()) && ((*i)->getType() == SHT_NOBITS); ++i) ; // All sections are SHT_NOBITS if (i == sections.rend()) return 0; unsigned int end = (*i)->getAddr() + (*i)->getSize(); return end - sections.front()->getAddr(); } unsigned int ElfSegment::getMemSize() { if (type == PT_GNU_RELRO) return memsz; if (sections.empty()) return 0; unsigned int end = sections.back()->getAddr() + sections.back()->getSize(); return end - sections.front()->getAddr(); } unsigned int ElfSegment::getOffset() { if ((type == PT_GNU_RELRO) && !sections.empty() && (sections.front()->getAddr() != vaddr)) throw std::runtime_error( "PT_GNU_RELRO segment doesn't start on a section start"); return sections.empty() ? 0 : sections.front()->getOffset(); } unsigned int ElfSegment::getAddr() { if ((type == PT_GNU_RELRO) && !sections.empty() && (sections.front()->getAddr() != vaddr)) throw std::runtime_error( "PT_GNU_RELRO segment doesn't start on a section start"); return sections.empty() ? 0 : sections.front()->getAddr(); } void ElfSegment::clear() { for (std::list::iterator i = sections.begin(); i != sections.end(); ++i) (*i)->removeFromSegment(this); sections.clear(); } ElfValue* ElfDynamic_Section::getValueForType(unsigned int tag) { for (unsigned int i = 0; i < shdr.sh_size / shdr.sh_entsize; i++) if (dyns[i].tag == tag) return dyns[i].value; return nullptr; } ElfSection* ElfDynamic_Section::getSectionForType(unsigned int tag) { ElfValue* value = getValueForType(tag); return value ? value->getSection() : nullptr; } bool ElfDynamic_Section::setValueForType(unsigned int tag, ElfValue* val) { unsigned int i; unsigned int shnum = shdr.sh_size / shdr.sh_entsize; for (i = 0; (i < shnum) && (dyns[i].tag != DT_NULL); i++) if (dyns[i].tag == tag) { delete dyns[i].value; dyns[i].value = val; return true; } // If we get here, this means we didn't match for the given tag // Most of the time, there are a few DT_NULL entries, that we can // use to add our value, but if we are on the last entry, we can't. if (i >= shnum - 1) return false; dyns[i].tag = tag; dyns[i].value = val; return true; } ElfDynamic_Section::ElfDynamic_Section(Elf_Shdr& s, std::ifstream* file, Elf* parent) : ElfSection(s, file, parent) { auto pos = file->tellg(); dyns.resize(s.sh_size / s.sh_entsize); file->seekg(shdr.sh_offset); // Here we assume tags refer to only one section (e.g. DT_RELSZ accounts // for .rel.dyn size) for (unsigned int i = 0; i < s.sh_size / s.sh_entsize; i++) { Elf_Dyn dyn(*file, parent->getClass(), parent->getData()); dyns[i].tag = dyn.d_tag; switch (dyn.d_tag) { case DT_NULL: case DT_SYMBOLIC: case DT_TEXTREL: case DT_BIND_NOW: dyns[i].value = new ElfValue(); break; case DT_NEEDED: case DT_SONAME: case DT_RPATH: case DT_PLTREL: case DT_RUNPATH: case DT_FLAGS: case DT_RELACOUNT: case DT_RELCOUNT: case DT_VERDEFNUM: case DT_VERNEEDNUM: dyns[i].value = new ElfPlainValue(dyn.d_un.d_val); break; case DT_PLTGOT: case DT_HASH: case DT_STRTAB: case DT_SYMTAB: case DT_RELA: case DT_INIT: case DT_FINI: case DT_REL: case DT_JMPREL: case DT_INIT_ARRAY: case DT_FINI_ARRAY: case DT_GNU_HASH: case DT_VERSYM: case DT_VERNEED: case DT_VERDEF: dyns[i].value = new ElfLocation(dyn.d_un.d_ptr, parent); break; default: dyns[i].value = nullptr; } } // Another loop to get the section sizes for (unsigned int i = 0; i < s.sh_size / s.sh_entsize; i++) switch (dyns[i].tag) { case DT_PLTRELSZ: dyns[i].value = new ElfSize(getSectionForType(DT_JMPREL)); break; case DT_RELASZ: dyns[i].value = new ElfSize(getSectionForType(DT_RELA)); break; case DT_STRSZ: dyns[i].value = new ElfSize(getSectionForType(DT_STRTAB)); break; case DT_RELSZ: dyns[i].value = new ElfSize(getSectionForType(DT_REL)); break; case DT_INIT_ARRAYSZ: dyns[i].value = new ElfSize(getSectionForType(DT_INIT_ARRAY)); break; case DT_FINI_ARRAYSZ: dyns[i].value = new ElfSize(getSectionForType(DT_FINI_ARRAY)); break; case DT_RELAENT: dyns[i].value = new ElfEntSize(getSectionForType(DT_RELA)); break; case DT_SYMENT: dyns[i].value = new ElfEntSize(getSectionForType(DT_SYMTAB)); break; case DT_RELENT: dyns[i].value = new ElfEntSize(getSectionForType(DT_REL)); break; } file->seekg(pos); } ElfDynamic_Section::~ElfDynamic_Section() { for (unsigned int i = 0; i < shdr.sh_size / shdr.sh_entsize; i++) delete dyns[i].value; } void ElfDynamic_Section::serialize(std::ofstream& file, char ei_class, char ei_data) { for (unsigned int i = 0; i < shdr.sh_size / shdr.sh_entsize; i++) { Elf_Dyn dyn; dyn.d_tag = dyns[i].tag; dyn.d_un.d_val = (dyns[i].value != nullptr) ? dyns[i].value->getValue() : 0; dyn.serialize(file, ei_class, ei_data); } } ElfSymtab_Section::ElfSymtab_Section(Elf_Shdr& s, std::ifstream* file, Elf* parent) : ElfSection(s, file, parent) { auto pos = file->tellg(); syms.resize(s.sh_size / s.sh_entsize); ElfStrtab_Section* strtab = (ElfStrtab_Section*)getLink(); file->seekg(shdr.sh_offset); for (unsigned int i = 0; i < shdr.sh_size / shdr.sh_entsize; i++) { Elf_Sym sym(*file, parent->getClass(), parent->getData()); syms[i].name = strtab->getStr(sym.st_name); syms[i].info = sym.st_info; syms[i].other = sym.st_other; ElfSection* section = (sym.st_shndx == SHN_ABS) ? nullptr : parent->getSection(sym.st_shndx); new (&syms[i].value) ElfLocation(section, sym.st_value, ElfLocation::ABSOLUTE); syms[i].size = sym.st_size; syms[i].defined = (sym.st_shndx != SHN_UNDEF); } file->seekg(pos); } void ElfSymtab_Section::serialize(std::ofstream& file, char ei_class, char ei_data) { ElfStrtab_Section* strtab = (ElfStrtab_Section*)getLink(); for (unsigned int i = 0; i < shdr.sh_size / shdr.sh_entsize; i++) { Elf_Sym sym; sym.st_name = strtab->getStrIndex(syms[i].name); sym.st_info = syms[i].info; sym.st_other = syms[i].other; sym.st_value = syms[i].value.getValue(); ElfSection* section = syms[i].value.getSection(); if (syms[i].defined) sym.st_shndx = section ? section->getIndex() : SHN_ABS; else sym.st_shndx = SHN_UNDEF; sym.st_size = syms[i].size; sym.serialize(file, ei_class, ei_data); } } Elf_SymValue* ElfSymtab_Section::lookup(const char* name, unsigned int type_filter) { for (std::vector::iterator sym = syms.begin(); sym != syms.end(); sym++) { if ((type_filter & (1 << ELF32_ST_TYPE(sym->info))) && (strcmp(sym->name, name) == 0)) { return &*sym; } } return nullptr; } const char* ElfStrtab_Section::getStr(unsigned int index) { for (std::vector::iterator t = table.begin(); t != table.end(); t++) { if (index < t->used) return t->buf + index; index -= t->used; } assert(1 == 0); return nullptr; } const char* ElfStrtab_Section::getStr(const char* string) { if (string == nullptr) return nullptr; // If the given string is within the section, return it for (std::vector::iterator t = table.begin(); t != table.end(); t++) if ((string >= t->buf) && (string < t->buf + t->used)) return string; // TODO: should scan in the section to find an existing string // If not, we need to allocate the string in the section size_t len = strlen(string) + 1; if (table.back().size - table.back().used < len) table.resize(table.size() + 1); char* alloc_str = table.back().buf + table.back().used; memcpy(alloc_str, string, len); table.back().used += len; shdr.sh_size += len; markDirty(); return alloc_str; } unsigned int ElfStrtab_Section::getStrIndex(const char* string) { if (string == nullptr) return 0; unsigned int index = 0; string = getStr(string); for (std::vector::iterator t = table.begin(); t != table.end(); t++) { if ((string >= t->buf) && (string < t->buf + t->used)) return index + (string - t->buf); index += t->used; } assert(1 == 0); return 0; } void ElfStrtab_Section::serialize(std::ofstream& file, char ei_class, char ei_data) { file.seekp(getOffset()); for (std::vector::iterator t = table.begin(); t != table.end(); t++) file.write(t->buf, t->used); }