/*
* Copyright (c) 2019-2020, Andrew Kaster <akaster@serenityos.org>
* Copyright (c) 2020, Itamar S. <itamar8910@gmail.com>
* Copyright (c) 2022, the SerenityOS developers.
*
* SPDX-License-Identifier: BSD-2-Clause
*/
#pragma once
#include <AK/Assertions.h>
#include <AK/ByteString.h>
#include <AK/Concepts.h>
#include <AK/RefCounted.h>
#include <Kernel/Memory/VirtualAddress.h>
#include <LibELF/Arch/GenericDynamicRelocationType.h>
#include <LibELF/ELFABI.h>
#include <link.h>
namespace ELF {
class DynamicObject : public RefCounted<DynamicObject> {
public:
static NonnullRefPtr<DynamicObject> create(ByteString const& filepath, VirtualAddress base_address, VirtualAddress dynamic_section_address);
static char const* name_for_dtag(Elf_Sword d_tag);
~DynamicObject();
void dump() const;
class DynamicEntry;
class Section;
class RelocationSection;
class Symbol;
class Relocation;
class HashSection;
class DynamicEntry {
public:
explicit DynamicEntry(Elf_Dyn const& dyn)
: m_dyn(dyn)
{
}
~DynamicEntry() = default;
Elf_Sword tag() const { return m_dyn.d_tag; }
Elf_Addr ptr() const { return m_dyn.d_un.d_ptr; }
Elf_Word val() const { return m_dyn.d_un.d_val; }
private:
Elf_Dyn const& m_dyn;
};
class Symbol {
public:
Symbol(DynamicObject const& dynamic, unsigned index, Elf_Sym const& sym)
: m_dynamic(dynamic)
, m_sym(sym)
, m_index(index)
{
}
StringView name() const { return m_dynamic.symbol_string_table_string(m_sym.st_name); }
char const* raw_name() const { return m_dynamic.raw_symbol_string_table_string(m_sym.st_name); }
unsigned section_index() const { return m_sym.st_shndx; }
FlatPtr value() const { return m_sym.st_value; }
size_t size() const { return m_sym.st_size; }
unsigned index() const { return m_index; }
unsigned type() const
{
return ELF64_ST_TYPE(m_sym.st_info);
}
unsigned bind() const { return ELF64_ST_BIND(m_sym.st_info); }
bool is_undefined() const
{
return section_index() == 0;
}
VirtualAddress address() const
{
if (m_dynamic.elf_is_dynamic())
return m_dynamic.base_address().offset(value());
return VirtualAddress { value() };
}
DynamicObject const& object() const { return m_dynamic; }
// This might return false even if the two Symbol objects resolve to the same thing.
bool definitely_equals(Symbol const& other) const
{
return &m_dynamic == &other.m_dynamic && &m_sym == &other.m_sym && m_index == other.m_index;
}
private:
DynamicObject const& m_dynamic;
Elf_Sym const& m_sym;
unsigned const m_index;
};
class Section {
public:
Section(DynamicObject const& dynamic, unsigned section_offset, unsigned section_size_bytes, unsigned entry_size, StringView name)
: m_dynamic(dynamic)
, m_section_offset(section_offset)
, m_section_size_bytes(section_size_bytes)
, m_entry_size(entry_size)
, m_name(name)
{
}
~Section() = default;
StringView name() const { return m_name; }
unsigned offset() const { return m_section_offset; }
unsigned size() const { return m_section_size_bytes; }
unsigned entry_size() const { return m_entry_size; }
unsigned entry_count() const
{
return !entry_size() ? 0 : size() / entry_size();
}
VirtualAddress address() const
{
return m_dynamic.base_address().offset(m_section_offset);
}
protected:
friend class RelocationSection;
friend class HashSection;
DynamicObject const& m_dynamic;
unsigned m_section_offset;
unsigned m_section_size_bytes;
unsigned m_entry_size;
StringView m_name;
};
class RelocationSection : public Section {
public:
explicit RelocationSection(Section const& section, bool addend_used)
: Section(section.m_dynamic, section.m_section_offset, section.m_section_size_bytes, section.m_entry_size, section.m_name)
, m_addend_used(addend_used)
{
}
unsigned relocation_count() const { return entry_count(); }
Relocation relocation(unsigned index) const;
Relocation relocation_at_offset(unsigned offset) const;
template<IteratorFunction<DynamicObject::Relocation&> F>
void for_each_relocation(F) const;
template<VoidFunction<DynamicObject::Relocation&> F>
void for_each_relocation(F func) const;
private:
bool const m_addend_used;
};
class Relocation {
public:
Relocation(DynamicObject const& dynamic, Elf_Rela const& rel, unsigned offset_in_section, bool addend_used)
: m_dynamic(dynamic)
, m_rel(rel)
, m_offset_in_section(offset_in_section)
, m_addend_used(addend_used)
{
}
~Relocation() = default;
unsigned offset_in_section() const { return m_offset_in_section; }
unsigned offset() const { return m_rel.r_offset; }
unsigned type() const
{
return ELF64_R_TYPE(m_rel.r_info);
}
unsigned symbol_index() const { return ELF64_R_SYM(m_rel.r_info); }
unsigned addend() const
{
VERIFY(m_addend_used);
return m_rel.r_addend;
}
bool addend_used() const { return m_addend_used; }
Symbol symbol() const
{
return m_dynamic.symbol(symbol_index());
}
VirtualAddress address() const
{
if (m_dynamic.elf_is_dynamic())
return m_dynamic.base_address().offset(offset());
return VirtualAddress { offset() };
}
[[nodiscard]] DynamicObject const& dynamic_object() const { return m_dynamic; }
private:
DynamicObject const& m_dynamic;
Elf_Rela const& m_rel;
unsigned const m_offset_in_section;
bool const m_addend_used;
};
enum class HashType {
SYSV,
GNU
};
class HashSymbol {
public:
HashSymbol(StringView name)
: m_name(name)
{
}
StringView name() const { return m_name; }
u32 gnu_hash() const;
u32 sysv_hash() const;
private:
StringView m_name;
mutable Optional<u32> m_gnu_hash;
mutable Optional<u32> m_sysv_hash;
};
class HashSection : public Section {
public:
HashSection(Section const& section, HashType hash_type)
: Section(section.m_dynamic, section.m_section_offset, section.m_section_size_bytes, section.m_entry_size, section.m_name)
, m_hash_type(hash_type)
{
}
Optional<Symbol> lookup_symbol(HashSymbol const& symbol) const
{
if (m_hash_type == HashType::SYSV)
return lookup_sysv_symbol(symbol.name(), symbol.sysv_hash());
return lookup_gnu_symbol(symbol.name(), symbol.gnu_hash());
}
private:
Optional<Symbol> lookup_sysv_symbol(StringView name, u32 hash_value) const;
Optional<Symbol> lookup_gnu_symbol(StringView name, u32 hash) const;
HashType m_hash_type {};
};
unsigned symbol_count() const { return m_symbol_count; }
Symbol symbol(unsigned) const;
typedef void (*InitializationFunction)();
typedef void (*FinalizationFunction)();
typedef Elf_Addr (*IfuncResolver)();
bool has_init_section() const { return m_init_offset != 0; }
bool has_init_array_section() const { return m_init_array_offset != 0; }
Section init_section() const;
InitializationFunction init_section_function() const;
Section init_array_section() const;
bool is_pie() const { return m_is_pie; }
bool has_fini_section() const { return m_fini_offset != 0; }
bool has_fini_array_section() const { return m_fini_array_offset != 0; }
Section fini_section() const;
FinalizationFunction fini_section_function() const;
Section fini_array_section() const;
HashSection hash_section() const
{
auto section_name = m_hash_type == HashType::SYSV ? "DT_HASH"sv : "DT_GNU_HASH"sv;
return HashSection(Section(*this, m_hash_table_offset, 0, 0, section_name), m_hash_type);
}
RelocationSection relocation_section() const;
RelocationSection plt_relocation_section() const;
Section relr_relocation_section() const;
bool should_process_origin() const { return m_dt_flags & DF_ORIGIN; }
bool requires_symbolic_symbol_resolution() const { return m_dt_flags & DF_SYMBOLIC; }
// Text relocations meaning: we need to edit the .text section which is normally mapped PROT_READ
bool has_text_relocations() const { return m_dt_flags & DF_TEXTREL; }
bool must_bind_now() const { return m_dt_flags & DF_BIND_NOW; }
bool has_static_thread_local_storage() const { return m_dt_flags & DF_STATIC_TLS; }
bool has_plt() const { return m_procedure_linkage_table_offset.has_value(); }
VirtualAddress plt_got_base_address() const { return m_base_address.offset(m_procedure_linkage_table_offset.value()); }
VirtualAddress base_address() const { return m_base_address; }
ByteString const& filepath() const { return m_filepath; }
StringView rpath() const { return m_has_rpath ? symbol_string_table_string(m_rpath_index) : StringView {}; }
StringView runpath() const { return m_has_runpath ? symbol_string_table_string(m_runpath_index) : StringView {}; }
StringView soname() const { return m_has_soname ? symbol_string_table_string(m_soname_index) : StringView {}; }
Optional<FlatPtr> tls_offset() const { return m_tls_offset; }
Optional<FlatPtr> tls_size() const { return m_tls_size; }
void set_tls_offset(FlatPtr offset) { m_tls_offset = offset; }
void set_tls_size(FlatPtr size) { m_tls_size = size; }
Elf_Half program_header_count() const;
Elf_Phdr const* program_headers() const;
template<VoidFunction<StringView> F>
void for_each_needed_library(F) const;
template<VoidFunction<InitializationFunction&> F>
void for_each_initialization_array_function(F f) const;
template<IteratorFunction<DynamicEntry&> F>
void for_each_dynamic_entry(F) const;
template<VoidFunction<DynamicEntry&> F>
void for_each_dynamic_entry(F func) const;
template<VoidFunction<Symbol&> F>
void for_each_symbol(F) const;
template<typename F>
void for_each_relr_relocation(F) const;
struct SymbolLookupResult {
FlatPtr value { 0 };
size_t size { 0 };
VirtualAddress address;
unsigned bind { STB_LOCAL };
unsigned type { STT_FUNC };
const ELF::DynamicObject* dynamic_object { nullptr }; // The object in which the symbol is defined
};
Optional<SymbolLookupResult> lookup_symbol(StringView name) const;
Optional<SymbolLookupResult> lookup_symbol(HashSymbol const& symbol) const;
bool elf_is_dynamic() const { return m_is_elf_dynamic; }
void* symbol_for_name(StringView name);
private:
explicit DynamicObject(ByteString const& filepath, VirtualAddress base_address, VirtualAddress dynamic_section_address);
StringView symbol_string_table_string(Elf_Word) const;
char const* raw_symbol_string_table_string(Elf_Word) const;
void parse();
ByteString m_filepath;
VirtualAddress m_base_address;
VirtualAddress m_dynamic_address;
VirtualAddress m_elf_base_address;
unsigned m_symbol_count { 0 };
// Begin Section information collected from DT_* entries
FlatPtr m_init_offset { 0 };
FlatPtr m_fini_offset { 0 };
FlatPtr m_init_array_offset { 0 };
size_t m_init_array_size { 0 };
FlatPtr m_fini_array_offset { 0 };
size_t m_fini_array_size { 0 };
FlatPtr m_hash_table_offset { 0 };
HashType m_hash_type { HashType::SYSV };
FlatPtr m_string_table_offset { 0 };
size_t m_size_of_string_table { 0 };
FlatPtr m_symbol_table_offset { 0 };
size_t m_size_of_symbol_table_entry { 0 };
Elf_Sword m_procedure_linkage_table_relocation_type { -1 };
FlatPtr m_plt_relocation_offset_location { 0 }; // offset of PLT relocations, at end of relocations
size_t m_size_of_plt_relocation_entry_list { 0 };
Optional<FlatPtr> m_procedure_linkage_table_offset;
// NOTE: We'll only ever either RELA or REL entries, not both (thank god)
// NOTE: The x86 ABI will only ever genrerate REL entries.
size_t m_number_of_relocations { 0 };
size_t m_size_of_relocation_entry { 0 };
size_t m_size_of_relocation_table { 0 };
bool m_addend_used { false };
FlatPtr m_relocation_table_offset { 0 };
size_t m_size_of_relr_relocations_entry { 0 };
size_t m_size_of_relr_relocation_table { 0 };
FlatPtr m_relr_relocation_table_offset { 0 };
bool m_is_elf_dynamic { false };
bool m_is_pie { false };
// DT_FLAGS
Elf_Word m_dt_flags { 0 };
bool m_has_soname { false };
Elf_Word m_soname_index { 0 }; // Index into dynstr table for SONAME
bool m_has_rpath { false };
Elf_Word m_rpath_index { 0 }; // Index into dynstr table for RPATH
bool m_has_runpath { false };
Elf_Word m_runpath_index { 0 }; // Index into dynstr table for RUNPATH
Optional<FlatPtr> m_tls_offset;
Optional<FlatPtr> m_tls_size;
// End Section information from DT_* entries
};
template<IteratorFunction<DynamicObject::Relocation&> F>
inline void DynamicObject::RelocationSection::for_each_relocation(F func) const
{
for (unsigned i = 0; i < relocation_count(); ++i) {
auto const reloc = relocation(i);
if (static_cast<GenericDynamicRelocationType>(reloc.type()) == GenericDynamicRelocationType::NONE)
continue;
if (func(reloc) == IterationDecision::Break)
break;
}
}
template<VoidFunction<DynamicObject::Relocation&> F>
inline void DynamicObject::RelocationSection::for_each_relocation(F func) const
{
for_each_relocation([&](auto& reloc) {
func(reloc);
return IterationDecision::Continue;
});
}
template<typename F>
inline void DynamicObject::for_each_relr_relocation(F f) const
{
auto section = relr_relocation_section();
if (section.entry_count() == 0)
return;
VERIFY(section.entry_size() == sizeof(FlatPtr));
VERIFY(section.size() >= section.entry_size() * section.entry_count());
auto* entries = reinterpret_cast<Elf_Relr*>(section.address().get());
auto base = base_address().get();
FlatPtr patch_addr = 0;
for (unsigned i = 0; i < section.entry_count(); ++i) {
if ((entries[i] & 1u) == 0) {
patch_addr = base + entries[i];
f(patch_addr);
patch_addr += sizeof(FlatPtr);
} else {
unsigned j = 0;
for (auto bitmap = entries[i]; (bitmap >>= 1u) != 0; ++j)
if (bitmap & 1u)
f(patch_addr + j * sizeof(FlatPtr));
patch_addr += (8 * sizeof(FlatPtr) - 1) * sizeof(FlatPtr);
}
}
}
template<VoidFunction<DynamicObject::Symbol&> F>
inline void DynamicObject::for_each_symbol(F func) const
{
for (unsigned i = 0; i < symbol_count(); ++i) {
func(symbol(i));
}
}
template<IteratorFunction<DynamicObject::DynamicEntry&> F>
inline void DynamicObject::for_each_dynamic_entry(F func) const
{
auto* dyns = reinterpret_cast<Elf_Dyn const*>(m_dynamic_address.as_ptr());
for (unsigned i = 0;; ++i) {
auto&& dyn = DynamicEntry(dyns[i]);
if (dyn.tag() == DT_NULL)
break;
if (func(dyn) == IterationDecision::Break)
break;
}
}
template<VoidFunction<DynamicObject::DynamicEntry&> F>
inline void DynamicObject::for_each_dynamic_entry(F func) const
{
for_each_dynamic_entry([&](auto& dyn) {
func(dyn);
return IterationDecision::Continue;
});
}
template<VoidFunction<StringView> F>
inline void DynamicObject::for_each_needed_library(F func) const
{
for_each_dynamic_entry([func, this](auto entry) {
if (entry.tag() != DT_NEEDED)
return;
Elf_Word offset = entry.val();
func(symbol_string_table_string(offset));
});
}
template<VoidFunction<DynamicObject::InitializationFunction&> F>
void DynamicObject::for_each_initialization_array_function(F f) const
{
if (!has_init_array_section())
return;
FlatPtr init_array = (FlatPtr)init_array_section().address().as_ptr();
for (size_t i = 0; i < (m_init_array_size / sizeof(void*)); ++i) {
InitializationFunction current = ((InitializationFunction*)(init_array))[i];
f(current);
}
}
} // end namespace ELF