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|
//! Helper for writing ELF files.
use alloc::string::String;
use alloc::vec::Vec;
use core::mem;
use crate::elf;
use crate::endian::*;
use crate::write::string::{StringId, StringTable};
use crate::write::util;
use crate::write::{Error, Result, WritableBuffer};
/// The index of an ELF section.
#[derive(Debug, Default, Clone, Copy, PartialEq, Eq, PartialOrd, Ord, Hash)]
pub struct SectionIndex(pub u32);
/// The index of an ELF symbol.
#[derive(Debug, Default, Clone, Copy, PartialEq, Eq, PartialOrd, Ord, Hash)]
pub struct SymbolIndex(pub u32);
/// A helper for writing ELF files.
///
/// Writing uses a two phase approach. The first phase builds up all of the information
/// that may need to be known ahead of time:
/// - build string tables
/// - reserve section indices
/// - reserve symbol indices
/// - reserve file ranges for headers and sections
///
/// Some of the information has ordering requirements. For example, strings must be added
/// to string tables before reserving the file range for the string table. Symbol indices
/// must be reserved after reserving the section indices they reference. There are debug
/// asserts to check some of these requirements.
///
/// The second phase writes everything out in order. Thus the caller must ensure writing
/// is in the same order that file ranges were reserved. There are debug asserts to assist
/// with checking this.
#[allow(missing_debug_implementations)]
pub struct Writer<'a> {
endian: Endianness,
is_64: bool,
is_mips64el: bool,
elf_align: usize,
buffer: &'a mut dyn WritableBuffer,
len: usize,
segment_offset: usize,
segment_num: u32,
section_offset: usize,
section_num: u32,
shstrtab: StringTable<'a>,
shstrtab_str_id: Option<StringId>,
shstrtab_index: SectionIndex,
shstrtab_offset: usize,
shstrtab_data: Vec<u8>,
need_strtab: bool,
strtab: StringTable<'a>,
strtab_str_id: Option<StringId>,
strtab_index: SectionIndex,
strtab_offset: usize,
strtab_data: Vec<u8>,
symtab_str_id: Option<StringId>,
symtab_index: SectionIndex,
symtab_offset: usize,
symtab_num: u32,
need_symtab_shndx: bool,
symtab_shndx_str_id: Option<StringId>,
symtab_shndx_offset: usize,
symtab_shndx_data: Vec<u8>,
need_dynstr: bool,
dynstr: StringTable<'a>,
dynstr_str_id: Option<StringId>,
dynstr_index: SectionIndex,
dynstr_offset: usize,
dynstr_data: Vec<u8>,
dynsym_str_id: Option<StringId>,
dynsym_index: SectionIndex,
dynsym_offset: usize,
dynsym_num: u32,
dynamic_str_id: Option<StringId>,
dynamic_offset: usize,
dynamic_num: usize,
hash_str_id: Option<StringId>,
hash_offset: usize,
hash_size: usize,
gnu_hash_str_id: Option<StringId>,
gnu_hash_offset: usize,
gnu_hash_size: usize,
gnu_versym_str_id: Option<StringId>,
gnu_versym_offset: usize,
gnu_verdef_str_id: Option<StringId>,
gnu_verdef_offset: usize,
gnu_verdef_size: usize,
gnu_verdef_count: u16,
gnu_verdef_remaining: u16,
gnu_verdaux_remaining: u16,
gnu_verneed_str_id: Option<StringId>,
gnu_verneed_offset: usize,
gnu_verneed_size: usize,
gnu_verneed_count: u16,
gnu_verneed_remaining: u16,
gnu_vernaux_remaining: u16,
}
impl<'a> Writer<'a> {
/// Create a new `Writer` for the given endianness and ELF class.
pub fn new(endian: Endianness, is_64: bool, buffer: &'a mut dyn WritableBuffer) -> Self {
let elf_align = if is_64 { 8 } else { 4 };
Writer {
endian,
is_64,
// Determined later.
is_mips64el: false,
elf_align,
buffer,
len: 0,
segment_offset: 0,
segment_num: 0,
section_offset: 0,
section_num: 0,
shstrtab: StringTable::default(),
shstrtab_str_id: None,
shstrtab_index: SectionIndex(0),
shstrtab_offset: 0,
shstrtab_data: Vec::new(),
need_strtab: false,
strtab: StringTable::default(),
strtab_str_id: None,
strtab_index: SectionIndex(0),
strtab_offset: 0,
strtab_data: Vec::new(),
symtab_str_id: None,
symtab_index: SectionIndex(0),
symtab_offset: 0,
symtab_num: 0,
need_symtab_shndx: false,
symtab_shndx_str_id: None,
symtab_shndx_offset: 0,
symtab_shndx_data: Vec::new(),
need_dynstr: false,
dynstr: StringTable::default(),
dynstr_str_id: None,
dynstr_index: SectionIndex(0),
dynstr_offset: 0,
dynstr_data: Vec::new(),
dynsym_str_id: None,
dynsym_index: SectionIndex(0),
dynsym_offset: 0,
dynsym_num: 0,
dynamic_str_id: None,
dynamic_offset: 0,
dynamic_num: 0,
hash_str_id: None,
hash_offset: 0,
hash_size: 0,
gnu_hash_str_id: None,
gnu_hash_offset: 0,
gnu_hash_size: 0,
gnu_versym_str_id: None,
gnu_versym_offset: 0,
gnu_verdef_str_id: None,
gnu_verdef_offset: 0,
gnu_verdef_size: 0,
gnu_verdef_count: 0,
gnu_verdef_remaining: 0,
gnu_verdaux_remaining: 0,
gnu_verneed_str_id: None,
gnu_verneed_offset: 0,
gnu_verneed_size: 0,
gnu_verneed_count: 0,
gnu_verneed_remaining: 0,
gnu_vernaux_remaining: 0,
}
}
/// Return the current file length that has been reserved.
pub fn reserved_len(&self) -> usize {
self.len
}
/// Return the current file length that has been written.
#[allow(clippy::len_without_is_empty)]
pub fn len(&self) -> usize {
self.buffer.len()
}
/// Reserve a file range with the given size and starting alignment.
///
/// Returns the aligned offset of the start of the range.
pub fn reserve(&mut self, len: usize, align_start: usize) -> usize {
if len == 0 {
return self.len;
}
self.len = util::align(self.len, align_start);
let offset = self.len;
self.len += len;
offset
}
/// Write alignment padding bytes.
pub fn write_align(&mut self, align_start: usize) {
util::write_align(self.buffer, align_start);
}
/// Write data.
///
/// This is typically used to write section data.
pub fn write(&mut self, data: &[u8]) {
self.buffer.write_bytes(data);
}
/// Reserve the file range up to the given file offset.
pub fn reserve_until(&mut self, offset: usize) {
debug_assert!(self.len <= offset);
self.len = offset;
}
/// Write padding up to the given file offset.
pub fn pad_until(&mut self, offset: usize) {
debug_assert!(self.buffer.len() <= offset);
self.buffer.resize(offset);
}
fn file_header_size(&self) -> usize {
if self.is_64 {
mem::size_of::<elf::FileHeader64<Endianness>>()
} else {
mem::size_of::<elf::FileHeader32<Endianness>>()
}
}
/// Reserve the range for the file header.
///
/// This must be at the start of the file.
pub fn reserve_file_header(&mut self) {
debug_assert_eq!(self.len, 0);
self.reserve(self.file_header_size(), 1);
}
/// Write the file header.
///
/// This must be at the start of the file.
///
/// Fields that can be derived from known information are automatically set by this function.
pub fn write_file_header(&mut self, header: &FileHeader) -> Result<()> {
debug_assert_eq!(self.buffer.len(), 0);
self.is_mips64el =
self.is_64 && self.endian.is_little_endian() && header.e_machine == elf::EM_MIPS;
// Start writing.
self.buffer
.reserve(self.len)
.map_err(|_| Error(String::from("Cannot allocate buffer")))?;
// Write file header.
let e_ident = elf::Ident {
magic: elf::ELFMAG,
class: if self.is_64 {
elf::ELFCLASS64
} else {
elf::ELFCLASS32
},
data: if self.endian.is_little_endian() {
elf::ELFDATA2LSB
} else {
elf::ELFDATA2MSB
},
version: elf::EV_CURRENT,
os_abi: header.os_abi,
abi_version: header.abi_version,
padding: [0; 7],
};
let e_ehsize = self.file_header_size() as u16;
let e_phoff = self.segment_offset as u64;
let e_phentsize = if self.segment_num == 0 {
0
} else {
self.program_header_size() as u16
};
// TODO: overflow
let e_phnum = self.segment_num as u16;
let e_shoff = self.section_offset as u64;
let e_shentsize = if self.section_num == 0 {
0
} else {
self.section_header_size() as u16
};
let e_shnum = if self.section_num >= elf::SHN_LORESERVE.into() {
0
} else {
self.section_num as u16
};
let e_shstrndx = if self.shstrtab_index.0 >= elf::SHN_LORESERVE.into() {
elf::SHN_XINDEX
} else {
self.shstrtab_index.0 as u16
};
let endian = self.endian;
if self.is_64 {
let file = elf::FileHeader64 {
e_ident,
e_type: U16::new(endian, header.e_type),
e_machine: U16::new(endian, header.e_machine),
e_version: U32::new(endian, elf::EV_CURRENT.into()),
e_entry: U64::new(endian, header.e_entry),
e_phoff: U64::new(endian, e_phoff),
e_shoff: U64::new(endian, e_shoff),
e_flags: U32::new(endian, header.e_flags),
e_ehsize: U16::new(endian, e_ehsize),
e_phentsize: U16::new(endian, e_phentsize),
e_phnum: U16::new(endian, e_phnum),
e_shentsize: U16::new(endian, e_shentsize),
e_shnum: U16::new(endian, e_shnum),
e_shstrndx: U16::new(endian, e_shstrndx),
};
self.buffer.write(&file)
} else {
let file = elf::FileHeader32 {
e_ident,
e_type: U16::new(endian, header.e_type),
e_machine: U16::new(endian, header.e_machine),
e_version: U32::new(endian, elf::EV_CURRENT.into()),
e_entry: U32::new(endian, header.e_entry as u32),
e_phoff: U32::new(endian, e_phoff as u32),
e_shoff: U32::new(endian, e_shoff as u32),
e_flags: U32::new(endian, header.e_flags),
e_ehsize: U16::new(endian, e_ehsize),
e_phentsize: U16::new(endian, e_phentsize),
e_phnum: U16::new(endian, e_phnum),
e_shentsize: U16::new(endian, e_shentsize),
e_shnum: U16::new(endian, e_shnum),
e_shstrndx: U16::new(endian, e_shstrndx),
};
self.buffer.write(&file);
}
Ok(())
}
fn program_header_size(&self) -> usize {
if self.is_64 {
mem::size_of::<elf::ProgramHeader64<Endianness>>()
} else {
mem::size_of::<elf::ProgramHeader32<Endianness>>()
}
}
/// Reserve the range for the program headers.
pub fn reserve_program_headers(&mut self, num: u32) {
debug_assert_eq!(self.segment_offset, 0);
if num == 0 {
return;
}
self.segment_num = num;
self.segment_offset =
self.reserve(num as usize * self.program_header_size(), self.elf_align);
}
/// Write alignment padding bytes prior to the program headers.
pub fn write_align_program_headers(&mut self) {
if self.segment_offset == 0 {
return;
}
util::write_align(self.buffer, self.elf_align);
debug_assert_eq!(self.segment_offset, self.buffer.len());
}
/// Write a program header.
pub fn write_program_header(&mut self, header: &ProgramHeader) {
let endian = self.endian;
if self.is_64 {
let header = elf::ProgramHeader64 {
p_type: U32::new(endian, header.p_type),
p_flags: U32::new(endian, header.p_flags),
p_offset: U64::new(endian, header.p_offset),
p_vaddr: U64::new(endian, header.p_vaddr),
p_paddr: U64::new(endian, header.p_paddr),
p_filesz: U64::new(endian, header.p_filesz),
p_memsz: U64::new(endian, header.p_memsz),
p_align: U64::new(endian, header.p_align),
};
self.buffer.write(&header);
} else {
let header = elf::ProgramHeader32 {
p_type: U32::new(endian, header.p_type),
p_offset: U32::new(endian, header.p_offset as u32),
p_vaddr: U32::new(endian, header.p_vaddr as u32),
p_paddr: U32::new(endian, header.p_paddr as u32),
p_filesz: U32::new(endian, header.p_filesz as u32),
p_memsz: U32::new(endian, header.p_memsz as u32),
p_flags: U32::new(endian, header.p_flags),
p_align: U32::new(endian, header.p_align as u32),
};
self.buffer.write(&header);
}
}
/// Reserve the section index for the null section header.
///
/// The null section header is usually automatically reserved,
/// but this can be used to force an empty section table.
///
/// This must be called before [`Self::reserve_section_headers`].
pub fn reserve_null_section_index(&mut self) -> SectionIndex {
debug_assert_eq!(self.section_num, 0);
if self.section_num == 0 {
self.section_num = 1;
}
SectionIndex(0)
}
/// Reserve a section table index.
///
/// Automatically also reserves the null section header if required.
///
/// This must be called before [`Self::reserve_section_headers`].
pub fn reserve_section_index(&mut self) -> SectionIndex {
debug_assert_eq!(self.section_offset, 0);
if self.section_num == 0 {
self.section_num = 1;
}
let index = self.section_num;
self.section_num += 1;
SectionIndex(index)
}
fn section_header_size(&self) -> usize {
if self.is_64 {
mem::size_of::<elf::SectionHeader64<Endianness>>()
} else {
mem::size_of::<elf::SectionHeader32<Endianness>>()
}
}
/// Reserve the range for the section headers.
///
/// This function does nothing if no sections were reserved.
/// This must be called after [`Self::reserve_section_index`]
/// and other functions that reserve section indices.
pub fn reserve_section_headers(&mut self) {
debug_assert_eq!(self.section_offset, 0);
if self.section_num == 0 {
return;
}
self.section_offset = self.reserve(
self.section_num as usize * self.section_header_size(),
self.elf_align,
);
}
/// Write the null section header.
///
/// This must be the first section header that is written.
/// This function does nothing if no sections were reserved.
pub fn write_null_section_header(&mut self) {
if self.section_num == 0 {
return;
}
util::write_align(self.buffer, self.elf_align);
debug_assert_eq!(self.section_offset, self.buffer.len());
self.write_section_header(&SectionHeader {
name: None,
sh_type: 0,
sh_flags: 0,
sh_addr: 0,
sh_offset: 0,
sh_size: if self.section_num >= elf::SHN_LORESERVE.into() {
self.section_num.into()
} else {
0
},
sh_link: if self.shstrtab_index.0 >= elf::SHN_LORESERVE.into() {
self.shstrtab_index.0
} else {
0
},
// TODO: e_phnum overflow
sh_info: 0,
sh_addralign: 0,
sh_entsize: 0,
});
}
/// Write a section header.
pub fn write_section_header(&mut self, section: &SectionHeader) {
let sh_name = if let Some(name) = section.name {
self.shstrtab.get_offset(name) as u32
} else {
0
};
let endian = self.endian;
if self.is_64 {
let section = elf::SectionHeader64 {
sh_name: U32::new(endian, sh_name),
sh_type: U32::new(endian, section.sh_type),
sh_flags: U64::new(endian, section.sh_flags),
sh_addr: U64::new(endian, section.sh_addr),
sh_offset: U64::new(endian, section.sh_offset),
sh_size: U64::new(endian, section.sh_size),
sh_link: U32::new(endian, section.sh_link),
sh_info: U32::new(endian, section.sh_info),
sh_addralign: U64::new(endian, section.sh_addralign),
sh_entsize: U64::new(endian, section.sh_entsize),
};
self.buffer.write(§ion);
} else {
let section = elf::SectionHeader32 {
sh_name: U32::new(endian, sh_name),
sh_type: U32::new(endian, section.sh_type),
sh_flags: U32::new(endian, section.sh_flags as u32),
sh_addr: U32::new(endian, section.sh_addr as u32),
sh_offset: U32::new(endian, section.sh_offset as u32),
sh_size: U32::new(endian, section.sh_size as u32),
sh_link: U32::new(endian, section.sh_link),
sh_info: U32::new(endian, section.sh_info),
sh_addralign: U32::new(endian, section.sh_addralign as u32),
sh_entsize: U32::new(endian, section.sh_entsize as u32),
};
self.buffer.write(§ion);
}
}
/// Add a section name to the section header string table.
///
/// This will be stored in the `.shstrtab` section.
///
/// This must be called before [`Self::reserve_shstrtab`].
pub fn add_section_name(&mut self, name: &'a [u8]) -> StringId {
debug_assert_eq!(self.shstrtab_offset, 0);
self.shstrtab.add(name)
}
/// Reserve the range for the section header string table.
///
/// This range is used for a section named `.shstrtab`.
///
/// This function does nothing if no sections were reserved.
/// This must be called after [`Self::add_section_name`].
/// and other functions that reserve section names and indices.
pub fn reserve_shstrtab(&mut self) {
debug_assert_eq!(self.shstrtab_offset, 0);
if self.section_num == 0 {
return;
}
// Start with null section name.
self.shstrtab_data = vec![0];
self.shstrtab.write(1, &mut self.shstrtab_data);
self.shstrtab_offset = self.reserve(self.shstrtab_data.len(), 1);
}
/// Write the section header string table.
///
/// This function does nothing if the section was not reserved.
pub fn write_shstrtab(&mut self) {
if self.shstrtab_offset == 0 {
return;
}
debug_assert_eq!(self.shstrtab_offset, self.buffer.len());
self.buffer.write_bytes(&self.shstrtab_data);
}
/// Reserve the section index for the section header string table.
///
/// This must be called before [`Self::reserve_shstrtab`]
/// and [`Self::reserve_section_headers`].
pub fn reserve_shstrtab_section_index(&mut self) -> SectionIndex {
debug_assert_eq!(self.shstrtab_index, SectionIndex(0));
self.shstrtab_str_id = Some(self.add_section_name(&b".shstrtab"[..]));
self.shstrtab_index = self.reserve_section_index();
self.shstrtab_index
}
/// Write the section header for the section header string table.
///
/// This function does nothing if the section index was not reserved.
pub fn write_shstrtab_section_header(&mut self) {
if self.shstrtab_index == SectionIndex(0) {
return;
}
self.write_section_header(&SectionHeader {
name: self.shstrtab_str_id,
sh_type: elf::SHT_STRTAB,
sh_flags: 0,
sh_addr: 0,
sh_offset: self.shstrtab_offset as u64,
sh_size: self.shstrtab_data.len() as u64,
sh_link: 0,
sh_info: 0,
sh_addralign: 1,
sh_entsize: 0,
});
}
/// Add a string to the string table.
///
/// This will be stored in the `.strtab` section.
///
/// This must be called before [`Self::reserve_strtab`].
pub fn add_string(&mut self, name: &'a [u8]) -> StringId {
debug_assert_eq!(self.strtab_offset, 0);
self.need_strtab = true;
self.strtab.add(name)
}
/// Return true if `.strtab` is needed.
pub fn strtab_needed(&self) -> bool {
self.need_strtab
}
/// Reserve the range for the string table.
///
/// This range is used for a section named `.strtab`.
///
/// This function does nothing if no strings or symbols were defined.
/// This must be called after [`Self::add_string`].
pub fn reserve_strtab(&mut self) {
debug_assert_eq!(self.strtab_offset, 0);
if !self.need_strtab {
return;
}
// Start with null string.
self.strtab_data = vec![0];
self.strtab.write(1, &mut self.strtab_data);
self.strtab_offset = self.reserve(self.strtab_data.len(), 1);
}
/// Write the string table.
///
/// This function does nothing if the section was not reserved.
pub fn write_strtab(&mut self) {
if self.strtab_offset == 0 {
return;
}
debug_assert_eq!(self.strtab_offset, self.buffer.len());
self.buffer.write_bytes(&self.strtab_data);
}
/// Reserve the section index for the string table.
///
/// This must be called before [`Self::reserve_section_headers`].
pub fn reserve_strtab_section_index(&mut self) -> SectionIndex {
debug_assert_eq!(self.strtab_index, SectionIndex(0));
self.strtab_str_id = Some(self.add_section_name(&b".strtab"[..]));
self.strtab_index = self.reserve_section_index();
self.strtab_index
}
/// Write the section header for the string table.
///
/// This function does nothing if the section index was not reserved.
pub fn write_strtab_section_header(&mut self) {
if self.strtab_index == SectionIndex(0) {
return;
}
self.write_section_header(&SectionHeader {
name: self.strtab_str_id,
sh_type: elf::SHT_STRTAB,
sh_flags: 0,
sh_addr: 0,
sh_offset: self.strtab_offset as u64,
sh_size: self.strtab_data.len() as u64,
sh_link: 0,
sh_info: 0,
sh_addralign: 1,
sh_entsize: 0,
});
}
/// Reserve the null symbol table entry.
///
/// This will be stored in the `.symtab` section.
///
/// The null symbol table entry is usually automatically reserved,
/// but this can be used to force an empty symbol table.
///
/// This must be called before [`Self::reserve_symtab`].
pub fn reserve_null_symbol_index(&mut self) -> SymbolIndex {
debug_assert_eq!(self.symtab_offset, 0);
debug_assert_eq!(self.symtab_num, 0);
self.symtab_num = 1;
// The symtab must link to a strtab.
self.need_strtab = true;
SymbolIndex(0)
}
/// Reserve a symbol table entry.
///
/// This will be stored in the `.symtab` section.
///
/// `section_index` is used to determine whether `.symtab_shndx` is required.
///
/// Automatically also reserves the null symbol if required.
/// Callers may assume that the returned indices will be sequential
/// starting at 1.
///
/// This must be called before [`Self::reserve_symtab`] and
/// [`Self::reserve_symtab_shndx`].
pub fn reserve_symbol_index(&mut self, section_index: Option<SectionIndex>) -> SymbolIndex {
debug_assert_eq!(self.symtab_offset, 0);
debug_assert_eq!(self.symtab_shndx_offset, 0);
if self.symtab_num == 0 {
self.symtab_num = 1;
// The symtab must link to a strtab.
self.need_strtab = true;
}
let index = self.symtab_num;
self.symtab_num += 1;
if let Some(section_index) = section_index {
if section_index.0 >= elf::SHN_LORESERVE.into() {
self.need_symtab_shndx = true;
}
}
SymbolIndex(index)
}
/// Return the number of reserved symbol table entries.
///
/// Includes the null symbol.
pub fn symbol_count(&self) -> u32 {
self.symtab_num
}
fn symbol_size(&self) -> usize {
if self.is_64 {
mem::size_of::<elf::Sym64<Endianness>>()
} else {
mem::size_of::<elf::Sym32<Endianness>>()
}
}
/// Reserve the range for the symbol table.
///
/// This range is used for a section named `.symtab`.
/// This function does nothing if no symbols were reserved.
/// This must be called after [`Self::reserve_symbol_index`].
pub fn reserve_symtab(&mut self) {
debug_assert_eq!(self.symtab_offset, 0);
if self.symtab_num == 0 {
return;
}
self.symtab_offset = self.reserve(
self.symtab_num as usize * self.symbol_size(),
self.elf_align,
);
}
/// Write the null symbol.
///
/// This must be the first symbol that is written.
/// This function does nothing if no symbols were reserved.
pub fn write_null_symbol(&mut self) {
if self.symtab_num == 0 {
return;
}
util::write_align(self.buffer, self.elf_align);
debug_assert_eq!(self.symtab_offset, self.buffer.len());
if self.is_64 {
self.buffer.write(&elf::Sym64::<Endianness>::default());
} else {
self.buffer.write(&elf::Sym32::<Endianness>::default());
}
if self.need_symtab_shndx {
self.symtab_shndx_data.write_pod(&U32::new(self.endian, 0));
}
}
/// Write a symbol.
pub fn write_symbol(&mut self, sym: &Sym) {
let st_name = if let Some(name) = sym.name {
self.strtab.get_offset(name) as u32
} else {
0
};
let st_shndx = if let Some(section) = sym.section {
if section.0 >= elf::SHN_LORESERVE as u32 {
elf::SHN_XINDEX
} else {
section.0 as u16
}
} else {
sym.st_shndx
};
let endian = self.endian;
if self.is_64 {
let sym = elf::Sym64 {
st_name: U32::new(endian, st_name),
st_info: sym.st_info,
st_other: sym.st_other,
st_shndx: U16::new(endian, st_shndx),
st_value: U64::new(endian, sym.st_value),
st_size: U64::new(endian, sym.st_size),
};
self.buffer.write(&sym);
} else {
let sym = elf::Sym32 {
st_name: U32::new(endian, st_name),
st_info: sym.st_info,
st_other: sym.st_other,
st_shndx: U16::new(endian, st_shndx),
st_value: U32::new(endian, sym.st_value as u32),
st_size: U32::new(endian, sym.st_size as u32),
};
self.buffer.write(&sym);
}
if self.need_symtab_shndx {
let section_index = sym.section.unwrap_or(SectionIndex(0));
self.symtab_shndx_data
.write_pod(&U32::new(self.endian, section_index.0));
}
}
/// Reserve the section index for the symbol table.
///
/// This must be called before [`Self::reserve_section_headers`].
pub fn reserve_symtab_section_index(&mut self) -> SectionIndex {
debug_assert_eq!(self.symtab_index, SectionIndex(0));
self.symtab_str_id = Some(self.add_section_name(&b".symtab"[..]));
self.symtab_index = self.reserve_section_index();
self.symtab_index
}
/// Return the section index of the symbol table.
pub fn symtab_index(&mut self) -> SectionIndex {
self.symtab_index
}
/// Write the section header for the symbol table.
///
/// This function does nothing if the section index was not reserved.
pub fn write_symtab_section_header(&mut self, num_local: u32) {
if self.symtab_index == SectionIndex(0) {
return;
}
self.write_section_header(&SectionHeader {
name: self.symtab_str_id,
sh_type: elf::SHT_SYMTAB,
sh_flags: 0,
sh_addr: 0,
sh_offset: self.symtab_offset as u64,
sh_size: self.symtab_num as u64 * self.symbol_size() as u64,
sh_link: self.strtab_index.0,
sh_info: num_local,
sh_addralign: self.elf_align as u64,
sh_entsize: self.symbol_size() as u64,
});
}
/// Return true if `.symtab_shndx` is needed.
pub fn symtab_shndx_needed(&self) -> bool {
self.need_symtab_shndx
}
/// Reserve the range for the extended section indices for the symbol table.
///
/// This range is used for a section named `.symtab_shndx`.
/// This also reserves a section index.
///
/// This function does nothing if extended section indices are not needed.
/// This must be called after [`Self::reserve_symbol_index`].
pub fn reserve_symtab_shndx(&mut self) {
debug_assert_eq!(self.symtab_shndx_offset, 0);
if !self.need_symtab_shndx {
return;
}
self.symtab_shndx_offset = self.reserve(self.symtab_num as usize * 4, 4);
self.symtab_shndx_data.reserve(self.symtab_num as usize * 4);
}
/// Write the extended section indices for the symbol table.
///
/// This function does nothing if the section was not reserved.
pub fn write_symtab_shndx(&mut self) {
if self.symtab_shndx_offset == 0 {
return;
}
debug_assert_eq!(self.symtab_shndx_offset, self.buffer.len());
debug_assert_eq!(self.symtab_num as usize * 4, self.symtab_shndx_data.len());
self.buffer.write_bytes(&self.symtab_shndx_data);
}
/// Reserve the section index for the extended section indices symbol table.
///
/// You should check [`Self::symtab_shndx_needed`] before calling this
/// unless you have other means of knowing if this section is needed.
///
/// This must be called before [`Self::reserve_section_headers`].
pub fn reserve_symtab_shndx_section_index(&mut self) -> SectionIndex {
debug_assert!(self.symtab_shndx_str_id.is_none());
self.symtab_shndx_str_id = Some(self.add_section_name(&b".symtab_shndx"[..]));
self.reserve_section_index()
}
/// Write the section header for the extended section indices for the symbol table.
///
/// This function does nothing if the section index was not reserved.
pub fn write_symtab_shndx_section_header(&mut self) {
if self.symtab_shndx_str_id.is_none() {
return;
}
let sh_size = if self.symtab_shndx_offset == 0 {
0
} else {
(self.symtab_num * 4) as u64
};
self.write_section_header(&SectionHeader {
name: self.symtab_shndx_str_id,
sh_type: elf::SHT_SYMTAB_SHNDX,
sh_flags: 0,
sh_addr: 0,
sh_offset: self.symtab_shndx_offset as u64,
sh_size,
sh_link: self.symtab_index.0,
sh_info: 0,
sh_addralign: 4,
sh_entsize: 4,
});
}
/// Add a string to the dynamic string table.
///
/// This will be stored in the `.dynstr` section.
///
/// This must be called before [`Self::reserve_dynstr`].
pub fn add_dynamic_string(&mut self, name: &'a [u8]) -> StringId {
debug_assert_eq!(self.dynstr_offset, 0);
self.need_dynstr = true;
self.dynstr.add(name)
}
/// Get a string that was previously added to the dynamic string table.
///
/// Panics if the string was not added.
pub fn get_dynamic_string(&self, name: &'a [u8]) -> StringId {
self.dynstr.get_id(name)
}
/// Return true if `.dynstr` is needed.
pub fn dynstr_needed(&self) -> bool {
self.need_dynstr
}
/// Reserve the range for the dynamic string table.
///
/// This range is used for a section named `.dynstr`.
///
/// This function does nothing if no dynamic strings or symbols were defined.
/// This must be called after [`Self::add_dynamic_string`].
pub fn reserve_dynstr(&mut self) {
debug_assert_eq!(self.dynstr_offset, 0);
if !self.need_dynstr {
return;
}
// Start with null string.
self.dynstr_data = vec![0];
self.dynstr.write(1, &mut self.dynstr_data);
self.dynstr_offset = self.reserve(self.dynstr_data.len(), 1);
}
/// Write the dynamic string table.
///
/// This function does nothing if the section was not reserved.
pub fn write_dynstr(&mut self) {
if self.dynstr_offset == 0 {
return;
}
debug_assert_eq!(self.dynstr_offset, self.buffer.len());
self.buffer.write_bytes(&self.dynstr_data);
}
/// Reserve the section index for the dynamic string table.
///
/// This must be called before [`Self::reserve_section_headers`].
pub fn reserve_dynstr_section_index(&mut self) -> SectionIndex {
debug_assert_eq!(self.dynstr_index, SectionIndex(0));
self.dynstr_str_id = Some(self.add_section_name(&b".dynstr"[..]));
self.dynstr_index = self.reserve_section_index();
self.dynstr_index
}
/// Return the section index of the dynamic string table.
pub fn dynstr_index(&mut self) -> SectionIndex {
self.dynstr_index
}
/// Write the section header for the dynamic string table.
///
/// This function does nothing if the section index was not reserved.
pub fn write_dynstr_section_header(&mut self, sh_addr: u64) {
if self.dynstr_index == SectionIndex(0) {
return;
}
self.write_section_header(&SectionHeader {
name: self.dynstr_str_id,
sh_type: elf::SHT_STRTAB,
sh_flags: elf::SHF_ALLOC.into(),
sh_addr,
sh_offset: self.dynstr_offset as u64,
sh_size: self.dynstr_data.len() as u64,
sh_link: 0,
sh_info: 0,
sh_addralign: 1,
sh_entsize: 0,
});
}
/// Reserve the null dynamic symbol table entry.
///
/// This will be stored in the `.dynsym` section.
///
/// The null dynamic symbol table entry is usually automatically reserved,
/// but this can be used to force an empty dynamic symbol table.
///
/// This must be called before [`Self::reserve_dynsym`].
pub fn reserve_null_dynamic_symbol_index(&mut self) -> SymbolIndex {
debug_assert_eq!(self.dynsym_offset, 0);
debug_assert_eq!(self.dynsym_num, 0);
self.dynsym_num = 1;
// The symtab must link to a strtab.
self.need_dynstr = true;
SymbolIndex(0)
}
/// Reserve a dynamic symbol table entry.
///
/// This will be stored in the `.dynsym` section.
///
/// Automatically also reserves the null symbol if required.
/// Callers may assume that the returned indices will be sequential
/// starting at 1.
///
/// This must be called before [`Self::reserve_dynsym`].
pub fn reserve_dynamic_symbol_index(&mut self) -> SymbolIndex {
debug_assert_eq!(self.dynsym_offset, 0);
if self.dynsym_num == 0 {
self.dynsym_num = 1;
// The symtab must link to a strtab.
self.need_dynstr = true;
}
let index = self.dynsym_num;
self.dynsym_num += 1;
SymbolIndex(index)
}
/// Return the number of reserved dynamic symbols.
///
/// Includes the null symbol.
pub fn dynamic_symbol_count(&mut self) -> u32 {
self.dynsym_num
}
/// Reserve the range for the dynamic symbol table.
///
/// This range is used for a section named `.dynsym`.
///
/// This function does nothing if no dynamic symbols were reserved.
/// This must be called after [`Self::reserve_dynamic_symbol_index`].
pub fn reserve_dynsym(&mut self) {
debug_assert_eq!(self.dynsym_offset, 0);
if self.dynsym_num == 0 {
return;
}
self.dynsym_offset = self.reserve(
self.dynsym_num as usize * self.symbol_size(),
self.elf_align,
);
}
/// Write the null dynamic symbol.
///
/// This must be the first dynamic symbol that is written.
/// This function does nothing if no dynamic symbols were reserved.
pub fn write_null_dynamic_symbol(&mut self) {
if self.dynsym_num == 0 {
return;
}
util::write_align(self.buffer, self.elf_align);
debug_assert_eq!(self.dynsym_offset, self.buffer.len());
if self.is_64 {
self.buffer.write(&elf::Sym64::<Endianness>::default());
} else {
self.buffer.write(&elf::Sym32::<Endianness>::default());
}
}
/// Write a dynamic symbol.
pub fn write_dynamic_symbol(&mut self, sym: &Sym) {
let st_name = if let Some(name) = sym.name {
self.dynstr.get_offset(name) as u32
} else {
0
};
let st_shndx = if let Some(section) = sym.section {
if section.0 >= elf::SHN_LORESERVE as u32 {
// TODO: we don't actually write out .dynsym_shndx yet.
// This is unlikely to be needed though.
elf::SHN_XINDEX
} else {
section.0 as u16
}
} else {
sym.st_shndx
};
let endian = self.endian;
if self.is_64 {
let sym = elf::Sym64 {
st_name: U32::new(endian, st_name),
st_info: sym.st_info,
st_other: sym.st_other,
st_shndx: U16::new(endian, st_shndx),
st_value: U64::new(endian, sym.st_value),
st_size: U64::new(endian, sym.st_size),
};
self.buffer.write(&sym);
} else {
let sym = elf::Sym32 {
st_name: U32::new(endian, st_name),
st_info: sym.st_info,
st_other: sym.st_other,
st_shndx: U16::new(endian, st_shndx),
st_value: U32::new(endian, sym.st_value as u32),
st_size: U32::new(endian, sym.st_size as u32),
};
self.buffer.write(&sym);
}
}
/// Reserve the section index for the dynamic symbol table.
///
/// This must be called before [`Self::reserve_section_headers`].
pub fn reserve_dynsym_section_index(&mut self) -> SectionIndex {
debug_assert_eq!(self.dynsym_index, SectionIndex(0));
self.dynsym_str_id = Some(self.add_section_name(&b".dynsym"[..]));
self.dynsym_index = self.reserve_section_index();
self.dynsym_index
}
/// Return the section index of the dynamic symbol table.
pub fn dynsym_index(&mut self) -> SectionIndex {
self.dynsym_index
}
/// Write the section header for the dynamic symbol table.
///
/// This function does nothing if the section index was not reserved.
pub fn write_dynsym_section_header(&mut self, sh_addr: u64, num_local: u32) {
if self.dynsym_index == SectionIndex(0) {
return;
}
self.write_section_header(&SectionHeader {
name: self.dynsym_str_id,
sh_type: elf::SHT_DYNSYM,
sh_flags: elf::SHF_ALLOC.into(),
sh_addr,
sh_offset: self.dynsym_offset as u64,
sh_size: self.dynsym_num as u64 * self.symbol_size() as u64,
sh_link: self.dynstr_index.0,
sh_info: num_local,
sh_addralign: self.elf_align as u64,
sh_entsize: self.symbol_size() as u64,
});
}
fn dyn_size(&self) -> usize {
if self.is_64 {
mem::size_of::<elf::Dyn64<Endianness>>()
} else {
mem::size_of::<elf::Dyn32<Endianness>>()
}
}
/// Reserve the range for the `.dynamic` section.
///
/// This function does nothing if `dynamic_num` is zero.
pub fn reserve_dynamic(&mut self, dynamic_num: usize) {
debug_assert_eq!(self.dynamic_offset, 0);
if dynamic_num == 0 {
return;
}
self.dynamic_num = dynamic_num;
self.dynamic_offset = self.reserve(dynamic_num * self.dyn_size(), self.elf_align);
}
/// Write alignment padding bytes prior to the `.dynamic` section.
///
/// This function does nothing if the section was not reserved.
pub fn write_align_dynamic(&mut self) {
if self.dynamic_offset == 0 {
return;
}
util::write_align(self.buffer, self.elf_align);
debug_assert_eq!(self.dynamic_offset, self.buffer.len());
}
/// Write a dynamic string entry.
pub fn write_dynamic_string(&mut self, tag: u32, id: StringId) {
self.write_dynamic(tag, self.dynstr.get_offset(id) as u64);
}
/// Write a dynamic value entry.
pub fn write_dynamic(&mut self, d_tag: u32, d_val: u64) {
debug_assert!(self.dynamic_offset <= self.buffer.len());
let endian = self.endian;
if self.is_64 {
let d = elf::Dyn64 {
d_tag: U64::new(endian, d_tag.into()),
d_val: U64::new(endian, d_val),
};
self.buffer.write(&d);
} else {
let d = elf::Dyn32 {
d_tag: U32::new(endian, d_tag),
d_val: U32::new(endian, d_val as u32),
};
self.buffer.write(&d);
}
debug_assert!(
self.dynamic_offset + self.dynamic_num * self.dyn_size() >= self.buffer.len()
);
}
/// Reserve the section index for the dynamic table.
pub fn reserve_dynamic_section_index(&mut self) -> SectionIndex {
debug_assert!(self.dynamic_str_id.is_none());
self.dynamic_str_id = Some(self.add_section_name(&b".dynamic"[..]));
self.reserve_section_index()
}
/// Write the section header for the dynamic table.
///
/// This function does nothing if the section index was not reserved.
pub fn write_dynamic_section_header(&mut self, sh_addr: u64) {
if self.dynamic_str_id.is_none() {
return;
}
self.write_section_header(&SectionHeader {
name: self.dynamic_str_id,
sh_type: elf::SHT_DYNAMIC,
sh_flags: (elf::SHF_WRITE | elf::SHF_ALLOC).into(),
sh_addr,
sh_offset: self.dynamic_offset as u64,
sh_size: (self.dynamic_num * self.dyn_size()) as u64,
sh_link: self.dynstr_index.0,
sh_info: 0,
sh_addralign: self.elf_align as u64,
sh_entsize: self.dyn_size() as u64,
});
}
fn rel_size(&self, is_rela: bool) -> usize {
if self.is_64 {
if is_rela {
mem::size_of::<elf::Rela64<Endianness>>()
} else {
mem::size_of::<elf::Rel64<Endianness>>()
}
} else {
if is_rela {
mem::size_of::<elf::Rela32<Endianness>>()
} else {
mem::size_of::<elf::Rel32<Endianness>>()
}
}
}
/// Reserve a file range for a SysV hash section.
///
/// `symbol_count` is the number of symbols in the hash,
/// not the total number of symbols.
pub fn reserve_hash(&mut self, bucket_count: u32, chain_count: u32) {
self.hash_size = mem::size_of::<elf::HashHeader<Endianness>>()
+ bucket_count as usize * 4
+ chain_count as usize * 4;
self.hash_offset = self.reserve(self.hash_size, self.elf_align);
}
/// Write a SysV hash section.
///
/// `chain_count` is the number of symbols in the hash.
/// The argument to `hash` will be in the range `0..chain_count`.
pub fn write_hash<F>(&mut self, bucket_count: u32, chain_count: u32, hash: F)
where
F: Fn(u32) -> Option<u32>,
{
let mut buckets = vec![U32::new(self.endian, 0); bucket_count as usize];
let mut chains = vec![U32::new(self.endian, 0); chain_count as usize];
for i in 0..chain_count {
if let Some(hash) = hash(i) {
let bucket = hash % bucket_count;
chains[i as usize] = buckets[bucket as usize];
buckets[bucket as usize] = U32::new(self.endian, i);
}
}
util::write_align(self.buffer, self.elf_align);
debug_assert_eq!(self.hash_offset, self.buffer.len());
self.buffer.write(&elf::HashHeader {
bucket_count: U32::new(self.endian, bucket_count),
chain_count: U32::new(self.endian, chain_count),
});
self.buffer.write_slice(&buckets);
self.buffer.write_slice(&chains);
}
/// Reserve the section index for the SysV hash table.
pub fn reserve_hash_section_index(&mut self) -> SectionIndex {
debug_assert!(self.hash_str_id.is_none());
self.hash_str_id = Some(self.add_section_name(&b".hash"[..]));
self.reserve_section_index()
}
/// Write the section header for the SysV hash table.
///
/// This function does nothing if the section index was not reserved.
pub fn write_hash_section_header(&mut self, sh_addr: u64) {
if self.hash_str_id.is_none() {
return;
}
self.write_section_header(&SectionHeader {
name: self.hash_str_id,
sh_type: elf::SHT_HASH,
sh_flags: elf::SHF_ALLOC.into(),
sh_addr,
sh_offset: self.hash_offset as u64,
sh_size: self.hash_size as u64,
sh_link: self.dynsym_index.0,
sh_info: 0,
sh_addralign: self.elf_align as u64,
sh_entsize: 4,
});
}
/// Reserve a file range for a GNU hash section.
///
/// `symbol_count` is the number of symbols in the hash,
/// not the total number of symbols.
pub fn reserve_gnu_hash(&mut self, bloom_count: u32, bucket_count: u32, symbol_count: u32) {
self.gnu_hash_size = mem::size_of::<elf::GnuHashHeader<Endianness>>()
+ bloom_count as usize * self.elf_align
+ bucket_count as usize * 4
+ symbol_count as usize * 4;
self.gnu_hash_offset = self.reserve(self.gnu_hash_size, self.elf_align);
}
/// Write a GNU hash section.
///
/// `symbol_count` is the number of symbols in the hash.
/// The argument to `hash` will be in the range `0..symbol_count`.
///
/// This requires that symbols are already sorted by bucket.
pub fn write_gnu_hash<F>(
&mut self,
symbol_base: u32,
bloom_shift: u32,
bloom_count: u32,
bucket_count: u32,
symbol_count: u32,
hash: F,
) where
F: Fn(u32) -> u32,
{
util::write_align(self.buffer, self.elf_align);
debug_assert_eq!(self.gnu_hash_offset, self.buffer.len());
self.buffer.write(&elf::GnuHashHeader {
bucket_count: U32::new(self.endian, bucket_count),
symbol_base: U32::new(self.endian, symbol_base),
bloom_count: U32::new(self.endian, bloom_count),
bloom_shift: U32::new(self.endian, bloom_shift),
});
// Calculate and write bloom filter.
if self.is_64 {
let mut bloom_filters = vec![0; bloom_count as usize];
for i in 0..symbol_count {
let h = hash(i);
bloom_filters[((h / 64) & (bloom_count - 1)) as usize] |=
1 << (h % 64) | 1 << ((h >> bloom_shift) % 64);
}
for bloom_filter in bloom_filters {
self.buffer.write(&U64::new(self.endian, bloom_filter));
}
} else {
let mut bloom_filters = vec![0; bloom_count as usize];
for i in 0..symbol_count {
let h = hash(i);
bloom_filters[((h / 32) & (bloom_count - 1)) as usize] |=
1 << (h % 32) | 1 << ((h >> bloom_shift) % 32);
}
for bloom_filter in bloom_filters {
self.buffer.write(&U32::new(self.endian, bloom_filter));
}
}
// Write buckets.
//
// This requires that symbols are already sorted by bucket.
let mut bucket = 0;
for i in 0..symbol_count {
let symbol_bucket = hash(i) % bucket_count;
while bucket < symbol_bucket {
self.buffer.write(&U32::new(self.endian, 0));
bucket += 1;
}
if bucket == symbol_bucket {
self.buffer.write(&U32::new(self.endian, symbol_base + i));
bucket += 1;
}
}
while bucket < bucket_count {
self.buffer.write(&U32::new(self.endian, 0));
bucket += 1;
}
// Write hash values.
for i in 0..symbol_count {
let mut h = hash(i);
if i == symbol_count - 1 || h % bucket_count != hash(i + 1) % bucket_count {
h |= 1;
} else {
h &= !1;
}
self.buffer.write(&U32::new(self.endian, h));
}
}
/// Reserve the section index for the GNU hash table.
pub fn reserve_gnu_hash_section_index(&mut self) -> SectionIndex {
debug_assert!(self.gnu_hash_str_id.is_none());
self.gnu_hash_str_id = Some(self.add_section_name(&b".gnu.hash"[..]));
self.reserve_section_index()
}
/// Write the section header for the GNU hash table.
///
/// This function does nothing if the section index was not reserved.
pub fn write_gnu_hash_section_header(&mut self, sh_addr: u64) {
if self.gnu_hash_str_id.is_none() {
return;
}
self.write_section_header(&SectionHeader {
name: self.gnu_hash_str_id,
sh_type: elf::SHT_GNU_HASH,
sh_flags: elf::SHF_ALLOC.into(),
sh_addr,
sh_offset: self.gnu_hash_offset as u64,
sh_size: self.gnu_hash_size as u64,
sh_link: self.dynsym_index.0,
sh_info: 0,
sh_addralign: self.elf_align as u64,
sh_entsize: 0,
});
}
/// Reserve the range for the `.gnu.version` section.
///
/// This function does nothing if no dynamic symbols were reserved.
pub fn reserve_gnu_versym(&mut self) {
debug_assert_eq!(self.gnu_versym_offset, 0);
if self.dynsym_num == 0 {
return;
}
self.gnu_versym_offset = self.reserve(self.dynsym_num as usize * 2, 2);
}
/// Write the null symbol version entry.
///
/// This must be the first symbol version that is written.
/// This function does nothing if no dynamic symbols were reserved.
pub fn write_null_gnu_versym(&mut self) {
if self.dynsym_num == 0 {
return;
}
util::write_align(self.buffer, 2);
debug_assert_eq!(self.gnu_versym_offset, self.buffer.len());
self.write_gnu_versym(0);
}
/// Write a symbol version entry.
pub fn write_gnu_versym(&mut self, versym: u16) {
self.buffer.write(&U16::new(self.endian, versym));
}
/// Reserve the section index for the `.gnu.version` section.
pub fn reserve_gnu_versym_section_index(&mut self) -> SectionIndex {
debug_assert!(self.gnu_versym_str_id.is_none());
self.gnu_versym_str_id = Some(self.add_section_name(&b".gnu.version"[..]));
self.reserve_section_index()
}
/// Write the section header for the `.gnu.version` section.
///
/// This function does nothing if the section index was not reserved.
pub fn write_gnu_versym_section_header(&mut self, sh_addr: u64) {
if self.gnu_versym_str_id.is_none() {
return;
}
self.write_section_header(&SectionHeader {
name: self.gnu_versym_str_id,
sh_type: elf::SHT_GNU_VERSYM,
sh_flags: elf::SHF_ALLOC.into(),
sh_addr,
sh_offset: self.gnu_versym_offset as u64,
sh_size: self.dynsym_num as u64 * 2,
sh_link: self.dynsym_index.0,
sh_info: 0,
sh_addralign: 2,
sh_entsize: 2,
});
}
/// Reserve the range for the `.gnu.version_d` section.
pub fn reserve_gnu_verdef(&mut self, verdef_count: usize, verdaux_count: usize) {
debug_assert_eq!(self.gnu_verdef_offset, 0);
if verdef_count == 0 {
return;
}
self.gnu_verdef_size = verdef_count * mem::size_of::<elf::Verdef<Endianness>>()
+ verdaux_count * mem::size_of::<elf::Verdaux<Endianness>>();
self.gnu_verdef_offset = self.reserve(self.gnu_verdef_size, self.elf_align);
self.gnu_verdef_count = verdef_count as u16;
self.gnu_verdef_remaining = self.gnu_verdef_count;
}
/// Write alignment padding bytes prior to a `.gnu.version_d` section.
pub fn write_align_gnu_verdef(&mut self) {
if self.gnu_verdef_offset == 0 {
return;
}
util::write_align(self.buffer, self.elf_align);
debug_assert_eq!(self.gnu_verdef_offset, self.buffer.len());
}
/// Write a version definition entry.
pub fn write_gnu_verdef(&mut self, verdef: &Verdef) {
debug_assert_ne!(self.gnu_verdef_remaining, 0);
self.gnu_verdef_remaining -= 1;
let vd_next = if self.gnu_verdef_remaining == 0 {
0
} else {
mem::size_of::<elf::Verdef<Endianness>>() as u32
+ verdef.aux_count as u32 * mem::size_of::<elf::Verdaux<Endianness>>() as u32
};
self.gnu_verdaux_remaining = verdef.aux_count;
let vd_aux = if verdef.aux_count == 0 {
0
} else {
mem::size_of::<elf::Verdef<Endianness>>() as u32
};
self.buffer.write(&elf::Verdef {
vd_version: U16::new(self.endian, verdef.version),
vd_flags: U16::new(self.endian, verdef.flags),
vd_ndx: U16::new(self.endian, verdef.index),
vd_cnt: U16::new(self.endian, verdef.aux_count),
vd_hash: U32::new(self.endian, elf::hash(self.dynstr.get_string(verdef.name))),
vd_aux: U32::new(self.endian, vd_aux),
vd_next: U32::new(self.endian, vd_next),
});
self.write_gnu_verdaux(verdef.name);
}
/// Write a version definition auxiliary entry.
pub fn write_gnu_verdaux(&mut self, name: StringId) {
debug_assert_ne!(self.gnu_verdaux_remaining, 0);
self.gnu_verdaux_remaining -= 1;
let vda_next = if self.gnu_verdaux_remaining == 0 {
0
} else {
mem::size_of::<elf::Verdaux<Endianness>>() as u32
};
self.buffer.write(&elf::Verdaux {
vda_name: U32::new(self.endian, self.dynstr.get_offset(name) as u32),
vda_next: U32::new(self.endian, vda_next),
});
}
/// Reserve the section index for the `.gnu.version_d` section.
pub fn reserve_gnu_verdef_section_index(&mut self) -> SectionIndex {
debug_assert!(self.gnu_verdef_str_id.is_none());
self.gnu_verdef_str_id = Some(self.add_section_name(&b".gnu.version_d"[..]));
self.reserve_section_index()
}
/// Write the section header for the `.gnu.version_d` section.
///
/// This function does nothing if the section index was not reserved.
pub fn write_gnu_verdef_section_header(&mut self, sh_addr: u64) {
if self.gnu_verdef_str_id.is_none() {
return;
}
self.write_section_header(&SectionHeader {
name: self.gnu_verdef_str_id,
sh_type: elf::SHT_GNU_VERDEF,
sh_flags: elf::SHF_ALLOC.into(),
sh_addr,
sh_offset: self.gnu_verdef_offset as u64,
sh_size: self.gnu_verdef_size as u64,
sh_link: self.dynstr_index.0,
sh_info: self.gnu_verdef_count.into(),
sh_addralign: self.elf_align as u64,
sh_entsize: 0,
});
}
/// Reserve the range for the `.gnu.version_r` section.
pub fn reserve_gnu_verneed(&mut self, verneed_count: usize, vernaux_count: usize) {
debug_assert_eq!(self.gnu_verneed_offset, 0);
if verneed_count == 0 {
return;
}
self.gnu_verneed_size = verneed_count * mem::size_of::<elf::Verneed<Endianness>>()
+ vernaux_count * mem::size_of::<elf::Vernaux<Endianness>>();
self.gnu_verneed_offset = self.reserve(self.gnu_verneed_size, self.elf_align);
self.gnu_verneed_count = verneed_count as u16;
self.gnu_verneed_remaining = self.gnu_verneed_count;
}
/// Write alignment padding bytes prior to a `.gnu.version_r` section.
pub fn write_align_gnu_verneed(&mut self) {
if self.gnu_verneed_offset == 0 {
return;
}
util::write_align(self.buffer, self.elf_align);
debug_assert_eq!(self.gnu_verneed_offset, self.buffer.len());
}
/// Write a version need entry.
pub fn write_gnu_verneed(&mut self, verneed: &Verneed) {
debug_assert_ne!(self.gnu_verneed_remaining, 0);
self.gnu_verneed_remaining -= 1;
let vn_next = if self.gnu_verneed_remaining == 0 {
0
} else {
mem::size_of::<elf::Verneed<Endianness>>() as u32
+ verneed.aux_count as u32 * mem::size_of::<elf::Vernaux<Endianness>>() as u32
};
self.gnu_vernaux_remaining = verneed.aux_count;
let vn_aux = if verneed.aux_count == 0 {
0
} else {
mem::size_of::<elf::Verneed<Endianness>>() as u32
};
self.buffer.write(&elf::Verneed {
vn_version: U16::new(self.endian, verneed.version),
vn_cnt: U16::new(self.endian, verneed.aux_count),
vn_file: U32::new(self.endian, self.dynstr.get_offset(verneed.file) as u32),
vn_aux: U32::new(self.endian, vn_aux),
vn_next: U32::new(self.endian, vn_next),
});
}
/// Write a version need auxiliary entry.
pub fn write_gnu_vernaux(&mut self, vernaux: &Vernaux) {
debug_assert_ne!(self.gnu_vernaux_remaining, 0);
self.gnu_vernaux_remaining -= 1;
let vna_next = if self.gnu_vernaux_remaining == 0 {
0
} else {
mem::size_of::<elf::Vernaux<Endianness>>() as u32
};
self.buffer.write(&elf::Vernaux {
vna_hash: U32::new(self.endian, elf::hash(self.dynstr.get_string(vernaux.name))),
vna_flags: U16::new(self.endian, vernaux.flags),
vna_other: U16::new(self.endian, vernaux.index),
vna_name: U32::new(self.endian, self.dynstr.get_offset(vernaux.name) as u32),
vna_next: U32::new(self.endian, vna_next),
});
}
/// Reserve the section index for the `.gnu.version_r` section.
pub fn reserve_gnu_verneed_section_index(&mut self) -> SectionIndex {
debug_assert!(self.gnu_verneed_str_id.is_none());
self.gnu_verneed_str_id = Some(self.add_section_name(&b".gnu.version_r"[..]));
self.reserve_section_index()
}
/// Write the section header for the `.gnu.version_r` section.
///
/// This function does nothing if the section index was not reserved.
pub fn write_gnu_verneed_section_header(&mut self, sh_addr: u64) {
if self.gnu_verneed_str_id.is_none() {
return;
}
self.write_section_header(&SectionHeader {
name: self.gnu_verneed_str_id,
sh_type: elf::SHT_GNU_VERNEED,
sh_flags: elf::SHF_ALLOC.into(),
sh_addr,
sh_offset: self.gnu_verneed_offset as u64,
sh_size: self.gnu_verneed_size as u64,
sh_link: self.dynstr_index.0,
sh_info: self.gnu_verneed_count.into(),
sh_addralign: self.elf_align as u64,
sh_entsize: 0,
});
}
/// Reserve a file range for the given number of relocations.
///
/// Returns the offset of the range.
pub fn reserve_relocations(&mut self, count: usize, is_rela: bool) -> usize {
self.reserve(count * self.rel_size(is_rela), self.elf_align)
}
/// Write alignment padding bytes prior to a relocation section.
pub fn write_align_relocation(&mut self) {
util::write_align(self.buffer, self.elf_align);
}
/// Write a relocation.
pub fn write_relocation(&mut self, is_rela: bool, rel: &Rel) {
let endian = self.endian;
if self.is_64 {
if is_rela {
let rel = elf::Rela64 {
r_offset: U64::new(endian, rel.r_offset),
r_info: elf::Rela64::r_info(endian, self.is_mips64el, rel.r_sym, rel.r_type),
r_addend: I64::new(endian, rel.r_addend),
};
self.buffer.write(&rel);
} else {
let rel = elf::Rel64 {
r_offset: U64::new(endian, rel.r_offset),
r_info: elf::Rel64::r_info(endian, rel.r_sym, rel.r_type),
};
self.buffer.write(&rel);
}
} else {
if is_rela {
let rel = elf::Rela32 {
r_offset: U32::new(endian, rel.r_offset as u32),
r_info: elf::Rel32::r_info(endian, rel.r_sym, rel.r_type as u8),
r_addend: I32::new(endian, rel.r_addend as i32),
};
self.buffer.write(&rel);
} else {
let rel = elf::Rel32 {
r_offset: U32::new(endian, rel.r_offset as u32),
r_info: elf::Rel32::r_info(endian, rel.r_sym, rel.r_type as u8),
};
self.buffer.write(&rel);
}
}
}
/// Write the section header for a relocation section.
///
/// `section` is the index of the section the relocations apply to,
/// or 0 if none.
///
/// `symtab` is the index of the symbol table the relocations refer to,
/// or 0 if none.
///
/// `offset` is the file offset of the relocations.
pub fn write_relocation_section_header(
&mut self,
name: StringId,
section: SectionIndex,
symtab: SectionIndex,
offset: usize,
count: usize,
is_rela: bool,
) {
self.write_section_header(&SectionHeader {
name: Some(name),
sh_type: if is_rela { elf::SHT_RELA } else { elf::SHT_REL },
sh_flags: elf::SHF_INFO_LINK.into(),
sh_addr: 0,
sh_offset: offset as u64,
sh_size: (count * self.rel_size(is_rela)) as u64,
sh_link: symtab.0,
sh_info: section.0,
sh_addralign: self.elf_align as u64,
sh_entsize: self.rel_size(is_rela) as u64,
});
}
/// Reserve a file range for a COMDAT section.
///
/// `count` is the number of sections in the COMDAT group.
///
/// Returns the offset of the range.
pub fn reserve_comdat(&mut self, count: usize) -> usize {
self.reserve((count + 1) * 4, 4)
}
/// Write `GRP_COMDAT` at the start of the COMDAT section.
pub fn write_comdat_header(&mut self) {
util::write_align(self.buffer, 4);
self.buffer.write(&U32::new(self.endian, elf::GRP_COMDAT));
}
/// Write an entry in a COMDAT section.
pub fn write_comdat_entry(&mut self, entry: SectionIndex) {
self.buffer.write(&U32::new(self.endian, entry.0));
}
/// Write the section header for a COMDAT section.
pub fn write_comdat_section_header(
&mut self,
name: StringId,
symtab: SectionIndex,
symbol: SymbolIndex,
offset: usize,
count: usize,
) {
self.write_section_header(&SectionHeader {
name: Some(name),
sh_type: elf::SHT_GROUP,
sh_flags: 0,
sh_addr: 0,
sh_offset: offset as u64,
sh_size: ((count + 1) * 4) as u64,
sh_link: symtab.0,
sh_info: symbol.0,
sh_addralign: 4,
sh_entsize: 4,
});
}
}
/// Native endian version of [`elf::FileHeader64`].
#[allow(missing_docs)]
#[derive(Debug, Clone)]
pub struct FileHeader {
pub os_abi: u8,
pub abi_version: u8,
pub e_type: u16,
pub e_machine: u16,
pub e_entry: u64,
pub e_flags: u32,
}
/// Native endian version of [`elf::ProgramHeader64`].
#[allow(missing_docs)]
#[derive(Debug, Clone)]
pub struct ProgramHeader {
pub p_type: u32,
pub p_flags: u32,
pub p_offset: u64,
pub p_vaddr: u64,
pub p_paddr: u64,
pub p_filesz: u64,
pub p_memsz: u64,
pub p_align: u64,
}
/// Native endian version of [`elf::SectionHeader64`].
#[allow(missing_docs)]
#[derive(Debug, Clone)]
pub struct SectionHeader {
pub name: Option<StringId>,
pub sh_type: u32,
pub sh_flags: u64,
pub sh_addr: u64,
pub sh_offset: u64,
pub sh_size: u64,
pub sh_link: u32,
pub sh_info: u32,
pub sh_addralign: u64,
pub sh_entsize: u64,
}
/// Native endian version of [`elf::Sym64`].
#[allow(missing_docs)]
#[derive(Debug, Clone)]
pub struct Sym {
pub name: Option<StringId>,
pub section: Option<SectionIndex>,
pub st_info: u8,
pub st_other: u8,
pub st_shndx: u16,
pub st_value: u64,
pub st_size: u64,
}
/// Unified native endian version of [`elf::Rel64`] and [`elf::Rela64`].
#[allow(missing_docs)]
#[derive(Debug, Clone)]
pub struct Rel {
pub r_offset: u64,
pub r_sym: u32,
pub r_type: u32,
pub r_addend: i64,
}
/// Information required for writing [`elf::Verdef`].
#[allow(missing_docs)]
#[derive(Debug, Clone)]
pub struct Verdef {
pub version: u16,
pub flags: u16,
pub index: u16,
pub aux_count: u16,
/// The name for the first [`elf::Verdaux`] entry.
pub name: StringId,
}
/// Information required for writing [`elf::Verneed`].
#[allow(missing_docs)]
#[derive(Debug, Clone)]
pub struct Verneed {
pub version: u16,
pub aux_count: u16,
pub file: StringId,
}
/// Information required for writing [`elf::Vernaux`].
#[allow(missing_docs)]
#[derive(Debug, Clone)]
pub struct Vernaux {
pub flags: u16,
pub index: u16,
pub name: StringId,
}
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