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-rw-r--r--vendor/object/src/write/coff/mod.rs10
-rw-r--r--vendor/object/src/write/coff/object.rs583
-rw-r--r--vendor/object/src/write/coff/writer.rs518
-rw-r--r--vendor/object/src/write/elf/mod.rs9
-rw-r--r--vendor/object/src/write/elf/object.rs907
-rw-r--r--vendor/object/src/write/elf/writer.rs2143
-rw-r--r--vendor/object/src/write/macho.rs1095
-rw-r--r--vendor/object/src/write/mod.rs961
-rw-r--r--vendor/object/src/write/pe.rs847
-rw-r--r--vendor/object/src/write/string.rs159
-rw-r--r--vendor/object/src/write/util.rs260
-rw-r--r--vendor/object/src/write/xcoff.rs556
12 files changed, 8048 insertions, 0 deletions
diff --git a/vendor/object/src/write/coff/mod.rs b/vendor/object/src/write/coff/mod.rs
new file mode 100644
index 0000000..6e0f5ed
--- /dev/null
+++ b/vendor/object/src/write/coff/mod.rs
@@ -0,0 +1,10 @@
+//! Support for writing COFF files.
+//!
+//! Provides [`Writer`] for low level writing of COFF files.
+//! This is also used to provide COFF support for [`write::Object`](crate::write::Object).
+
+mod object;
+pub use self::object::*;
+
+mod writer;
+pub use writer::*;
diff --git a/vendor/object/src/write/coff/object.rs b/vendor/object/src/write/coff/object.rs
new file mode 100644
index 0000000..5229665
--- /dev/null
+++ b/vendor/object/src/write/coff/object.rs
@@ -0,0 +1,583 @@
+use alloc::vec::Vec;
+
+use crate::pe as coff;
+use crate::write::coff::writer;
+use crate::write::util::*;
+use crate::write::*;
+
+#[derive(Default, Clone, Copy)]
+struct SectionOffsets {
+ name: writer::Name,
+ offset: u32,
+ reloc_offset: u32,
+ selection: u8,
+ associative_section: u32,
+}
+
+#[derive(Default, Clone, Copy)]
+struct SymbolOffsets {
+ name: writer::Name,
+ index: u32,
+ aux_count: u8,
+}
+
+/// Internal format to use for the `.drectve` section containing linker
+/// directives for symbol exports.
+#[derive(Clone, Copy, Debug, PartialEq, Eq)]
+pub enum CoffExportStyle {
+ /// MSVC format supported by link.exe and LLD.
+ Msvc,
+ /// Gnu format supported by GNU LD and LLD.
+ Gnu,
+}
+
+impl<'a> Object<'a> {
+ pub(crate) fn coff_section_info(
+ &self,
+ section: StandardSection,
+ ) -> (&'static [u8], &'static [u8], SectionKind, SectionFlags) {
+ match section {
+ StandardSection::Text => (&[], &b".text"[..], SectionKind::Text, SectionFlags::None),
+ StandardSection::Data => (&[], &b".data"[..], SectionKind::Data, SectionFlags::None),
+ StandardSection::ReadOnlyData
+ | StandardSection::ReadOnlyDataWithRel
+ | StandardSection::ReadOnlyString => (
+ &[],
+ &b".rdata"[..],
+ SectionKind::ReadOnlyData,
+ SectionFlags::None,
+ ),
+ StandardSection::UninitializedData => (
+ &[],
+ &b".bss"[..],
+ SectionKind::UninitializedData,
+ SectionFlags::None,
+ ),
+ // TLS sections are data sections with a special name.
+ StandardSection::Tls => (&[], &b".tls$"[..], SectionKind::Data, SectionFlags::None),
+ StandardSection::UninitializedTls => {
+ // Unsupported section.
+ (&[], &[], SectionKind::UninitializedTls, SectionFlags::None)
+ }
+ StandardSection::TlsVariables => {
+ // Unsupported section.
+ (&[], &[], SectionKind::TlsVariables, SectionFlags::None)
+ }
+ StandardSection::Common => {
+ // Unsupported section.
+ (&[], &[], SectionKind::Common, SectionFlags::None)
+ }
+ StandardSection::GnuProperty => {
+ // Unsupported section.
+ (&[], &[], SectionKind::Note, SectionFlags::None)
+ }
+ }
+ }
+
+ pub(crate) fn coff_subsection_name(&self, section: &[u8], value: &[u8]) -> Vec<u8> {
+ let mut name = section.to_vec();
+ name.push(b'$');
+ name.extend_from_slice(value);
+ name
+ }
+
+ pub(crate) fn coff_fixup_relocation(&mut self, relocation: &mut Relocation) -> i64 {
+ if relocation.kind == RelocationKind::GotRelative {
+ // Use a stub symbol for the relocation instead.
+ // This isn't really a GOT, but it's a similar purpose.
+ // TODO: need to handle DLL imports differently?
+ relocation.kind = RelocationKind::Relative;
+ relocation.symbol = self.coff_add_stub_symbol(relocation.symbol);
+ } else if relocation.kind == RelocationKind::PltRelative {
+ // Windows doesn't need a separate relocation type for
+ // references to functions in import libraries.
+ // For convenience, treat this the same as Relative.
+ relocation.kind = RelocationKind::Relative;
+ }
+
+ let constant = match self.architecture {
+ Architecture::I386 | Architecture::Arm | Architecture::Aarch64 => match relocation.kind
+ {
+ RelocationKind::Relative => {
+ // IMAGE_REL_I386_REL32, IMAGE_REL_ARM_REL32, IMAGE_REL_ARM64_REL32
+ relocation.addend + 4
+ }
+ _ => relocation.addend,
+ },
+ Architecture::X86_64 => match relocation.kind {
+ RelocationKind::Relative => {
+ // IMAGE_REL_AMD64_REL32 through to IMAGE_REL_AMD64_REL32_5
+ if relocation.addend <= -4 && relocation.addend >= -9 {
+ 0
+ } else {
+ relocation.addend + 4
+ }
+ }
+ _ => relocation.addend,
+ },
+ _ => unimplemented!(),
+ };
+ relocation.addend -= constant;
+ constant
+ }
+
+ fn coff_add_stub_symbol(&mut self, symbol_id: SymbolId) -> SymbolId {
+ if let Some(stub_id) = self.stub_symbols.get(&symbol_id) {
+ return *stub_id;
+ }
+ let stub_size = self.architecture.address_size().unwrap().bytes();
+
+ let name = b".rdata$.refptr".to_vec();
+ let section_id = self.add_section(Vec::new(), name, SectionKind::ReadOnlyData);
+ let section = self.section_mut(section_id);
+ section.set_data(vec![0; stub_size as usize], u64::from(stub_size));
+ section.relocations = vec![Relocation {
+ offset: 0,
+ size: stub_size * 8,
+ kind: RelocationKind::Absolute,
+ encoding: RelocationEncoding::Generic,
+ symbol: symbol_id,
+ addend: 0,
+ }];
+
+ let mut name = b".refptr.".to_vec();
+ name.extend_from_slice(&self.symbol(symbol_id).name);
+ let stub_id = self.add_raw_symbol(Symbol {
+ name,
+ value: 0,
+ size: u64::from(stub_size),
+ kind: SymbolKind::Data,
+ scope: SymbolScope::Compilation,
+ weak: false,
+ section: SymbolSection::Section(section_id),
+ flags: SymbolFlags::None,
+ });
+ self.stub_symbols.insert(symbol_id, stub_id);
+
+ stub_id
+ }
+
+ /// Appends linker directives to the `.drectve` section to tell the linker
+ /// to export all symbols with `SymbolScope::Dynamic`.
+ ///
+ /// This must be called after all symbols have been defined.
+ pub fn add_coff_exports(&mut self, style: CoffExportStyle) {
+ assert_eq!(self.format, BinaryFormat::Coff);
+
+ let mut directives = vec![];
+ for symbol in &self.symbols {
+ if symbol.scope == SymbolScope::Dynamic {
+ match style {
+ CoffExportStyle::Msvc => directives.extend(b" /EXPORT:\""),
+ CoffExportStyle::Gnu => directives.extend(b" -export:\""),
+ }
+ directives.extend(&symbol.name);
+ directives.extend(b"\"");
+ if symbol.kind != SymbolKind::Text {
+ match style {
+ CoffExportStyle::Msvc => directives.extend(b",DATA"),
+ CoffExportStyle::Gnu => directives.extend(b",data"),
+ }
+ }
+ }
+ }
+ let drectve = self.add_section(vec![], b".drectve".to_vec(), SectionKind::Linker);
+ self.append_section_data(drectve, &directives, 1);
+ }
+
+ pub(crate) fn coff_write(&self, buffer: &mut dyn WritableBuffer) -> Result<()> {
+ let mut writer = writer::Writer::new(buffer);
+
+ // Add section strings to strtab.
+ let mut section_offsets = vec![SectionOffsets::default(); self.sections.len()];
+ for (index, section) in self.sections.iter().enumerate() {
+ section_offsets[index].name = writer.add_name(&section.name);
+ }
+
+ // Set COMDAT flags.
+ for comdat in &self.comdats {
+ let symbol = &self.symbols[comdat.symbol.0];
+ let comdat_section = match symbol.section {
+ SymbolSection::Section(id) => id.0,
+ _ => {
+ return Err(Error(format!(
+ "unsupported COMDAT symbol `{}` section {:?}",
+ symbol.name().unwrap_or(""),
+ symbol.section
+ )));
+ }
+ };
+ section_offsets[comdat_section].selection = match comdat.kind {
+ ComdatKind::NoDuplicates => coff::IMAGE_COMDAT_SELECT_NODUPLICATES,
+ ComdatKind::Any => coff::IMAGE_COMDAT_SELECT_ANY,
+ ComdatKind::SameSize => coff::IMAGE_COMDAT_SELECT_SAME_SIZE,
+ ComdatKind::ExactMatch => coff::IMAGE_COMDAT_SELECT_EXACT_MATCH,
+ ComdatKind::Largest => coff::IMAGE_COMDAT_SELECT_LARGEST,
+ ComdatKind::Newest => coff::IMAGE_COMDAT_SELECT_NEWEST,
+ ComdatKind::Unknown => {
+ return Err(Error(format!(
+ "unsupported COMDAT symbol `{}` kind {:?}",
+ symbol.name().unwrap_or(""),
+ comdat.kind
+ )));
+ }
+ };
+ for id in &comdat.sections {
+ let section = &self.sections[id.0];
+ if section.symbol.is_none() {
+ return Err(Error(format!(
+ "missing symbol for COMDAT section `{}`",
+ section.name().unwrap_or(""),
+ )));
+ }
+ if id.0 != comdat_section {
+ section_offsets[id.0].selection = coff::IMAGE_COMDAT_SELECT_ASSOCIATIVE;
+ section_offsets[id.0].associative_section = comdat_section as u32 + 1;
+ }
+ }
+ }
+
+ // Reserve symbol indices and add symbol strings to strtab.
+ let mut symbol_offsets = vec![SymbolOffsets::default(); self.symbols.len()];
+ for (index, symbol) in self.symbols.iter().enumerate() {
+ symbol_offsets[index].index = writer.reserve_symbol_index();
+ let mut name = &*symbol.name;
+ match symbol.kind {
+ SymbolKind::File => {
+ // Name goes in auxiliary symbol records.
+ symbol_offsets[index].aux_count = writer.reserve_aux_file_name(&symbol.name);
+ name = b".file";
+ }
+ SymbolKind::Section if symbol.section.id().is_some() => {
+ symbol_offsets[index].aux_count = writer.reserve_aux_section();
+ }
+ _ => {}
+ };
+ symbol_offsets[index].name = writer.add_name(name);
+ }
+
+ // Reserve file ranges.
+ writer.reserve_file_header();
+ writer.reserve_section_headers(self.sections.len() as u16);
+ for (index, section) in self.sections.iter().enumerate() {
+ section_offsets[index].offset = writer.reserve_section(section.data.len());
+ section_offsets[index].reloc_offset =
+ writer.reserve_relocations(section.relocations.len());
+ }
+ writer.reserve_symtab_strtab();
+
+ // Start writing.
+ writer.write_file_header(writer::FileHeader {
+ machine: match (self.architecture, self.sub_architecture) {
+ (Architecture::Arm, None) => coff::IMAGE_FILE_MACHINE_ARMNT,
+ (Architecture::Aarch64, None) => coff::IMAGE_FILE_MACHINE_ARM64,
+ (Architecture::Aarch64, Some(SubArchitecture::Arm64EC)) => {
+ coff::IMAGE_FILE_MACHINE_ARM64EC
+ }
+ (Architecture::I386, None) => coff::IMAGE_FILE_MACHINE_I386,
+ (Architecture::X86_64, None) => coff::IMAGE_FILE_MACHINE_AMD64,
+ _ => {
+ return Err(Error(format!(
+ "unimplemented architecture {:?} with sub-architecture {:?}",
+ self.architecture, self.sub_architecture
+ )));
+ }
+ },
+ time_date_stamp: 0,
+ characteristics: match self.flags {
+ FileFlags::Coff { characteristics } => characteristics,
+ _ => 0,
+ },
+ })?;
+
+ // Write section headers.
+ for (index, section) in self.sections.iter().enumerate() {
+ let mut characteristics = if let SectionFlags::Coff {
+ characteristics, ..
+ } = section.flags
+ {
+ characteristics
+ } else {
+ match section.kind {
+ SectionKind::Text => {
+ coff::IMAGE_SCN_CNT_CODE
+ | coff::IMAGE_SCN_MEM_EXECUTE
+ | coff::IMAGE_SCN_MEM_READ
+ }
+ SectionKind::Data => {
+ coff::IMAGE_SCN_CNT_INITIALIZED_DATA
+ | coff::IMAGE_SCN_MEM_READ
+ | coff::IMAGE_SCN_MEM_WRITE
+ }
+ SectionKind::UninitializedData => {
+ coff::IMAGE_SCN_CNT_UNINITIALIZED_DATA
+ | coff::IMAGE_SCN_MEM_READ
+ | coff::IMAGE_SCN_MEM_WRITE
+ }
+ SectionKind::ReadOnlyData
+ | SectionKind::ReadOnlyDataWithRel
+ | SectionKind::ReadOnlyString => {
+ coff::IMAGE_SCN_CNT_INITIALIZED_DATA | coff::IMAGE_SCN_MEM_READ
+ }
+ SectionKind::Debug | SectionKind::Other | SectionKind::OtherString => {
+ coff::IMAGE_SCN_CNT_INITIALIZED_DATA
+ | coff::IMAGE_SCN_MEM_READ
+ | coff::IMAGE_SCN_MEM_DISCARDABLE
+ }
+ SectionKind::Linker => coff::IMAGE_SCN_LNK_INFO | coff::IMAGE_SCN_LNK_REMOVE,
+ SectionKind::Common
+ | SectionKind::Tls
+ | SectionKind::UninitializedTls
+ | SectionKind::TlsVariables
+ | SectionKind::Note
+ | SectionKind::Unknown
+ | SectionKind::Metadata
+ | SectionKind::Elf(_) => {
+ return Err(Error(format!(
+ "unimplemented section `{}` kind {:?}",
+ section.name().unwrap_or(""),
+ section.kind
+ )));
+ }
+ }
+ };
+ if section_offsets[index].selection != 0 {
+ characteristics |= coff::IMAGE_SCN_LNK_COMDAT;
+ };
+ if section.relocations.len() > 0xffff {
+ characteristics |= coff::IMAGE_SCN_LNK_NRELOC_OVFL;
+ }
+ characteristics |= match section.align {
+ 1 => coff::IMAGE_SCN_ALIGN_1BYTES,
+ 2 => coff::IMAGE_SCN_ALIGN_2BYTES,
+ 4 => coff::IMAGE_SCN_ALIGN_4BYTES,
+ 8 => coff::IMAGE_SCN_ALIGN_8BYTES,
+ 16 => coff::IMAGE_SCN_ALIGN_16BYTES,
+ 32 => coff::IMAGE_SCN_ALIGN_32BYTES,
+ 64 => coff::IMAGE_SCN_ALIGN_64BYTES,
+ 128 => coff::IMAGE_SCN_ALIGN_128BYTES,
+ 256 => coff::IMAGE_SCN_ALIGN_256BYTES,
+ 512 => coff::IMAGE_SCN_ALIGN_512BYTES,
+ 1024 => coff::IMAGE_SCN_ALIGN_1024BYTES,
+ 2048 => coff::IMAGE_SCN_ALIGN_2048BYTES,
+ 4096 => coff::IMAGE_SCN_ALIGN_4096BYTES,
+ 8192 => coff::IMAGE_SCN_ALIGN_8192BYTES,
+ _ => {
+ return Err(Error(format!(
+ "unimplemented section `{}` align {}",
+ section.name().unwrap_or(""),
+ section.align
+ )));
+ }
+ };
+ writer.write_section_header(writer::SectionHeader {
+ name: section_offsets[index].name,
+ size_of_raw_data: section.size as u32,
+ pointer_to_raw_data: section_offsets[index].offset,
+ pointer_to_relocations: section_offsets[index].reloc_offset,
+ pointer_to_linenumbers: 0,
+ number_of_relocations: section.relocations.len() as u32,
+ number_of_linenumbers: 0,
+ characteristics,
+ });
+ }
+
+ // Write section data and relocations.
+ for section in &self.sections {
+ writer.write_section(&section.data);
+
+ if !section.relocations.is_empty() {
+ //debug_assert_eq!(section_offsets[index].reloc_offset, buffer.len());
+ writer.write_relocations_count(section.relocations.len());
+ for reloc in &section.relocations {
+ //assert!(reloc.implicit_addend);
+ let typ = match self.architecture {
+ Architecture::I386 => match (reloc.kind, reloc.size, reloc.addend) {
+ (RelocationKind::Absolute, 16, 0) => coff::IMAGE_REL_I386_DIR16,
+ (RelocationKind::Relative, 16, 0) => coff::IMAGE_REL_I386_REL16,
+ (RelocationKind::Absolute, 32, 0) => coff::IMAGE_REL_I386_DIR32,
+ (RelocationKind::ImageOffset, 32, 0) => coff::IMAGE_REL_I386_DIR32NB,
+ (RelocationKind::SectionIndex, 16, 0) => coff::IMAGE_REL_I386_SECTION,
+ (RelocationKind::SectionOffset, 32, 0) => coff::IMAGE_REL_I386_SECREL,
+ (RelocationKind::SectionOffset, 7, 0) => coff::IMAGE_REL_I386_SECREL7,
+ (RelocationKind::Relative, 32, -4) => coff::IMAGE_REL_I386_REL32,
+ (RelocationKind::Coff(x), _, _) => x,
+ _ => {
+ return Err(Error(format!("unimplemented relocation {:?}", reloc)));
+ }
+ },
+ Architecture::X86_64 => match (reloc.kind, reloc.size, reloc.addend) {
+ (RelocationKind::Absolute, 64, 0) => coff::IMAGE_REL_AMD64_ADDR64,
+ (RelocationKind::Absolute, 32, 0) => coff::IMAGE_REL_AMD64_ADDR32,
+ (RelocationKind::ImageOffset, 32, 0) => coff::IMAGE_REL_AMD64_ADDR32NB,
+ (RelocationKind::Relative, 32, -4) => coff::IMAGE_REL_AMD64_REL32,
+ (RelocationKind::Relative, 32, -5) => coff::IMAGE_REL_AMD64_REL32_1,
+ (RelocationKind::Relative, 32, -6) => coff::IMAGE_REL_AMD64_REL32_2,
+ (RelocationKind::Relative, 32, -7) => coff::IMAGE_REL_AMD64_REL32_3,
+ (RelocationKind::Relative, 32, -8) => coff::IMAGE_REL_AMD64_REL32_4,
+ (RelocationKind::Relative, 32, -9) => coff::IMAGE_REL_AMD64_REL32_5,
+ (RelocationKind::SectionIndex, 16, 0) => coff::IMAGE_REL_AMD64_SECTION,
+ (RelocationKind::SectionOffset, 32, 0) => coff::IMAGE_REL_AMD64_SECREL,
+ (RelocationKind::SectionOffset, 7, 0) => coff::IMAGE_REL_AMD64_SECREL7,
+ (RelocationKind::Coff(x), _, _) => x,
+ _ => {
+ return Err(Error(format!("unimplemented relocation {:?}", reloc)));
+ }
+ },
+ Architecture::Arm => match (reloc.kind, reloc.size, reloc.addend) {
+ (RelocationKind::Absolute, 32, 0) => coff::IMAGE_REL_ARM_ADDR32,
+ (RelocationKind::ImageOffset, 32, 0) => coff::IMAGE_REL_ARM_ADDR32NB,
+ (RelocationKind::Relative, 32, -4) => coff::IMAGE_REL_ARM_REL32,
+ (RelocationKind::SectionIndex, 16, 0) => coff::IMAGE_REL_ARM_SECTION,
+ (RelocationKind::SectionOffset, 32, 0) => coff::IMAGE_REL_ARM_SECREL,
+ (RelocationKind::Coff(x), _, _) => x,
+ _ => {
+ return Err(Error(format!("unimplemented relocation {:?}", reloc)));
+ }
+ },
+ Architecture::Aarch64 => match (reloc.kind, reloc.size, reloc.addend) {
+ (RelocationKind::Absolute, 32, 0) => coff::IMAGE_REL_ARM64_ADDR32,
+ (RelocationKind::ImageOffset, 32, 0) => coff::IMAGE_REL_ARM64_ADDR32NB,
+ (RelocationKind::SectionIndex, 16, 0) => coff::IMAGE_REL_ARM64_SECTION,
+ (RelocationKind::SectionOffset, 32, 0) => coff::IMAGE_REL_ARM64_SECREL,
+ (RelocationKind::Absolute, 64, 0) => coff::IMAGE_REL_ARM64_ADDR64,
+ (RelocationKind::Relative, 32, -4) => coff::IMAGE_REL_ARM64_REL32,
+ (RelocationKind::Coff(x), _, _) => x,
+ _ => {
+ return Err(Error(format!("unimplemented relocation {:?}", reloc)));
+ }
+ },
+ _ => {
+ return Err(Error(format!(
+ "unimplemented architecture {:?}",
+ self.architecture
+ )));
+ }
+ };
+ writer.write_relocation(writer::Relocation {
+ virtual_address: reloc.offset as u32,
+ symbol: symbol_offsets[reloc.symbol.0].index,
+ typ,
+ });
+ }
+ }
+ }
+
+ // Write symbols.
+ for (index, symbol) in self.symbols.iter().enumerate() {
+ let section_number = match symbol.section {
+ SymbolSection::None => {
+ debug_assert_eq!(symbol.kind, SymbolKind::File);
+ coff::IMAGE_SYM_DEBUG as u16
+ }
+ SymbolSection::Undefined => coff::IMAGE_SYM_UNDEFINED as u16,
+ SymbolSection::Absolute => coff::IMAGE_SYM_ABSOLUTE as u16,
+ SymbolSection::Common => coff::IMAGE_SYM_UNDEFINED as u16,
+ SymbolSection::Section(id) => id.0 as u16 + 1,
+ };
+ let typ = if symbol.kind == SymbolKind::Text {
+ coff::IMAGE_SYM_DTYPE_FUNCTION << coff::IMAGE_SYM_DTYPE_SHIFT
+ } else {
+ coff::IMAGE_SYM_TYPE_NULL
+ };
+ let storage_class = match symbol.kind {
+ SymbolKind::File => coff::IMAGE_SYM_CLASS_FILE,
+ SymbolKind::Section => {
+ if symbol.section.id().is_some() {
+ coff::IMAGE_SYM_CLASS_STATIC
+ } else {
+ coff::IMAGE_SYM_CLASS_SECTION
+ }
+ }
+ SymbolKind::Label => coff::IMAGE_SYM_CLASS_LABEL,
+ SymbolKind::Text | SymbolKind::Data | SymbolKind::Tls => {
+ match symbol.section {
+ SymbolSection::None => {
+ return Err(Error(format!(
+ "missing section for symbol `{}`",
+ symbol.name().unwrap_or("")
+ )));
+ }
+ SymbolSection::Undefined | SymbolSection::Common => {
+ coff::IMAGE_SYM_CLASS_EXTERNAL
+ }
+ SymbolSection::Absolute | SymbolSection::Section(_) => {
+ match symbol.scope {
+ // TODO: does this need aux symbol records too?
+ _ if symbol.weak => coff::IMAGE_SYM_CLASS_WEAK_EXTERNAL,
+ SymbolScope::Unknown => {
+ return Err(Error(format!(
+ "unimplemented symbol `{}` scope {:?}",
+ symbol.name().unwrap_or(""),
+ symbol.scope
+ )));
+ }
+ SymbolScope::Compilation => coff::IMAGE_SYM_CLASS_STATIC,
+ SymbolScope::Linkage | SymbolScope::Dynamic => {
+ coff::IMAGE_SYM_CLASS_EXTERNAL
+ }
+ }
+ }
+ }
+ }
+ SymbolKind::Unknown | SymbolKind::Null => {
+ return Err(Error(format!(
+ "unimplemented symbol `{}` kind {:?}",
+ symbol.name().unwrap_or(""),
+ symbol.kind
+ )));
+ }
+ };
+ let number_of_aux_symbols = symbol_offsets[index].aux_count;
+ let value = if symbol.section == SymbolSection::Common {
+ symbol.size as u32
+ } else {
+ symbol.value as u32
+ };
+ writer.write_symbol(writer::Symbol {
+ name: symbol_offsets[index].name,
+ value,
+ section_number,
+ typ,
+ storage_class,
+ number_of_aux_symbols,
+ });
+
+ // Write auxiliary symbols.
+ match symbol.kind {
+ SymbolKind::File => {
+ writer.write_aux_file_name(&symbol.name, number_of_aux_symbols);
+ }
+ SymbolKind::Section if symbol.section.id().is_some() => {
+ debug_assert_eq!(number_of_aux_symbols, 1);
+ let section_index = symbol.section.id().unwrap().0;
+ let section = &self.sections[section_index];
+ writer.write_aux_section(writer::AuxSymbolSection {
+ length: section.size as u32,
+ number_of_relocations: section.relocations.len() as u32,
+ number_of_linenumbers: 0,
+ check_sum: checksum(section.data()),
+ number: section_offsets[section_index].associative_section,
+ selection: section_offsets[section_index].selection,
+ });
+ }
+ _ => {
+ debug_assert_eq!(number_of_aux_symbols, 0);
+ }
+ }
+ }
+
+ writer.write_strtab();
+
+ debug_assert_eq!(writer.reserved_len(), writer.len());
+
+ Ok(())
+ }
+}
+
+// JamCRC
+fn checksum(data: &[u8]) -> u32 {
+ let mut hasher = crc32fast::Hasher::new_with_initial(0xffff_ffff);
+ hasher.update(data);
+ !hasher.finalize()
+}
diff --git a/vendor/object/src/write/coff/writer.rs b/vendor/object/src/write/coff/writer.rs
new file mode 100644
index 0000000..8c7ada3
--- /dev/null
+++ b/vendor/object/src/write/coff/writer.rs
@@ -0,0 +1,518 @@
+//! Helper for writing COFF files.
+use alloc::string::String;
+use alloc::vec::Vec;
+use core::mem;
+
+use crate::endian::{LittleEndian as LE, U16Bytes, U32Bytes, U16, U32};
+use crate::pe;
+use crate::write::string::{StringId, StringTable};
+use crate::write::util;
+use crate::write::{Error, Result, WritableBuffer};
+
+/// A helper for writing COFF 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 table
+/// - 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 the string table before reserving the file range for the string table. 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> {
+ buffer: &'a mut dyn WritableBuffer,
+ len: usize,
+
+ section_num: u16,
+
+ symtab_offset: u32,
+ symtab_num: u32,
+
+ strtab: StringTable<'a>,
+ strtab_len: usize,
+ strtab_offset: u32,
+ strtab_data: Vec<u8>,
+}
+
+impl<'a> Writer<'a> {
+ /// Create a new `Writer`.
+ pub fn new(buffer: &'a mut dyn WritableBuffer) -> Self {
+ Writer {
+ buffer,
+ len: 0,
+
+ section_num: 0,
+
+ symtab_offset: 0,
+ symtab_num: 0,
+
+ strtab: StringTable::default(),
+ strtab_len: 0,
+ strtab_offset: 0,
+ strtab_data: Vec::new(),
+ }
+ }
+
+ /// 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) -> u32 {
+ if align_start > 1 {
+ self.len = util::align(self.len, align_start);
+ }
+ let offset = self.len;
+ self.len += len;
+ offset as u32
+ }
+
+ /// Write alignment padding bytes.
+ pub fn write_align(&mut self, align_start: usize) {
+ if align_start > 1 {
+ util::write_align(self.buffer, align_start);
+ }
+ }
+
+ /// Write 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);
+ }
+
+ /// 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(mem::size_of::<pe::ImageFileHeader>(), 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);
+
+ // Start writing.
+ self.buffer
+ .reserve(self.len)
+ .map_err(|_| Error(String::from("Cannot allocate buffer")))?;
+
+ // Write file header.
+ let header = pe::ImageFileHeader {
+ machine: U16::new(LE, header.machine),
+ number_of_sections: U16::new(LE, self.section_num),
+ time_date_stamp: U32::new(LE, header.time_date_stamp),
+ pointer_to_symbol_table: U32::new(LE, self.symtab_offset),
+ number_of_symbols: U32::new(LE, self.symtab_num),
+ size_of_optional_header: U16::default(),
+ characteristics: U16::new(LE, header.characteristics),
+ };
+ self.buffer.write(&header);
+
+ Ok(())
+ }
+
+ /// Reserve the range for the section headers.
+ pub fn reserve_section_headers(&mut self, section_num: u16) {
+ debug_assert_eq!(self.section_num, 0);
+ self.section_num = section_num;
+ self.reserve(
+ section_num as usize * mem::size_of::<pe::ImageSectionHeader>(),
+ 1,
+ );
+ }
+
+ /// Write a section header.
+ pub fn write_section_header(&mut self, section: SectionHeader) {
+ let mut coff_section = pe::ImageSectionHeader {
+ name: [0; 8],
+ virtual_size: U32::default(),
+ virtual_address: U32::default(),
+ size_of_raw_data: U32::new(LE, section.size_of_raw_data),
+ pointer_to_raw_data: U32::new(LE, section.pointer_to_raw_data),
+ pointer_to_relocations: U32::new(LE, section.pointer_to_relocations),
+ pointer_to_linenumbers: U32::new(LE, section.pointer_to_linenumbers),
+ number_of_relocations: if section.number_of_relocations > 0xffff {
+ U16::new(LE, 0xffff)
+ } else {
+ U16::new(LE, section.number_of_relocations as u16)
+ },
+ number_of_linenumbers: U16::default(),
+ characteristics: U32::new(LE, section.characteristics),
+ };
+ match section.name {
+ Name::Short(name) => coff_section.name = name,
+ Name::Long(str_id) => {
+ let mut str_offset = self.strtab.get_offset(str_id);
+ if str_offset <= 9_999_999 {
+ let mut name = [0; 7];
+ let mut len = 0;
+ if str_offset == 0 {
+ name[6] = b'0';
+ len = 1;
+ } else {
+ while str_offset != 0 {
+ let rem = (str_offset % 10) as u8;
+ str_offset /= 10;
+ name[6 - len] = b'0' + rem;
+ len += 1;
+ }
+ }
+ coff_section.name = [0; 8];
+ coff_section.name[0] = b'/';
+ coff_section.name[1..][..len].copy_from_slice(&name[7 - len..]);
+ } else {
+ debug_assert!(str_offset as u64 <= 0xf_ffff_ffff);
+ coff_section.name[0] = b'/';
+ coff_section.name[1] = b'/';
+ for i in 0..6 {
+ let rem = (str_offset % 64) as u8;
+ str_offset /= 64;
+ let c = match rem {
+ 0..=25 => b'A' + rem,
+ 26..=51 => b'a' + rem - 26,
+ 52..=61 => b'0' + rem - 52,
+ 62 => b'+',
+ 63 => b'/',
+ _ => unreachable!(),
+ };
+ coff_section.name[7 - i] = c;
+ }
+ }
+ }
+ }
+ self.buffer.write(&coff_section);
+ }
+
+ /// Reserve the range for the section data.
+ ///
+ /// Returns the aligned offset of the start of the range.
+ /// Does nothing and returns 0 if the length is zero.
+ pub fn reserve_section(&mut self, len: usize) -> u32 {
+ if len == 0 {
+ return 0;
+ }
+ // TODO: not sure what alignment is required here, but this seems to match LLVM
+ self.reserve(len, 4)
+ }
+
+ /// Write the alignment bytes prior to section data.
+ ///
+ /// This is unneeded if you are using `write_section` or `write_section_zeroes`
+ /// for the data.
+ pub fn write_section_align(&mut self) {
+ util::write_align(self.buffer, 4);
+ }
+
+ /// Write the section data.
+ ///
+ /// Writes alignment bytes prior to the data.
+ /// Does nothing if the data is empty.
+ pub fn write_section(&mut self, data: &[u8]) {
+ if data.is_empty() {
+ return;
+ }
+ self.write_section_align();
+ self.buffer.write_bytes(data);
+ }
+
+ /// Write the section data using zero bytes.
+ ///
+ /// Writes alignment bytes prior to the data.
+ /// Does nothing if the length is zero.
+ pub fn write_section_zeroes(&mut self, len: usize) {
+ if len == 0 {
+ return;
+ }
+ self.write_section_align();
+ self.buffer.resize(self.buffer.len() + len);
+ }
+
+ /// Reserve a file range for the given number of relocations.
+ ///
+ /// This will automatically reserve an extra relocation if there are more than 0xffff.
+ ///
+ /// Returns the offset of the range.
+ /// Does nothing and returns 0 if the count is zero.
+ pub fn reserve_relocations(&mut self, mut count: usize) -> u32 {
+ if count == 0 {
+ return 0;
+ }
+ if count > 0xffff {
+ count += 1;
+ }
+ self.reserve(count * mem::size_of::<pe::ImageRelocation>(), 1)
+ }
+
+ /// Write a relocation containing the count if required.
+ ///
+ /// This should be called before writing the first relocation for a section.
+ pub fn write_relocations_count(&mut self, count: usize) {
+ if count > 0xffff {
+ let coff_relocation = pe::ImageRelocation {
+ virtual_address: U32Bytes::new(LE, count as u32 + 1),
+ symbol_table_index: U32Bytes::new(LE, 0),
+ typ: U16Bytes::new(LE, 0),
+ };
+ self.buffer.write(&coff_relocation);
+ }
+ }
+
+ /// Write a relocation.
+ pub fn write_relocation(&mut self, reloc: Relocation) {
+ let coff_relocation = pe::ImageRelocation {
+ virtual_address: U32Bytes::new(LE, reloc.virtual_address),
+ symbol_table_index: U32Bytes::new(LE, reloc.symbol),
+ typ: U16Bytes::new(LE, reloc.typ),
+ };
+ self.buffer.write(&coff_relocation);
+ }
+
+ /// Reserve a symbol table entry.
+ ///
+ /// This must be called before [`Self::reserve_symtab_strtab`].
+ pub fn reserve_symbol_index(&mut self) -> u32 {
+ debug_assert_eq!(self.symtab_offset, 0);
+ let index = self.symtab_num;
+ self.symtab_num += 1;
+ index
+ }
+
+ /// Reserve a number of symbol table entries.
+ pub fn reserve_symbol_indices(&mut self, count: u32) {
+ debug_assert_eq!(self.symtab_offset, 0);
+ self.symtab_num += count;
+ }
+
+ /// Write a symbol table entry.
+ pub fn write_symbol(&mut self, symbol: Symbol) {
+ let mut coff_symbol = pe::ImageSymbol {
+ name: [0; 8],
+ value: U32Bytes::new(LE, symbol.value),
+ section_number: U16Bytes::new(LE, symbol.section_number),
+ typ: U16Bytes::new(LE, symbol.typ),
+ storage_class: symbol.storage_class,
+ number_of_aux_symbols: symbol.number_of_aux_symbols,
+ };
+ match symbol.name {
+ Name::Short(name) => coff_symbol.name = name,
+ Name::Long(str_id) => {
+ let str_offset = self.strtab.get_offset(str_id);
+ coff_symbol.name[4..8].copy_from_slice(&u32::to_le_bytes(str_offset as u32));
+ }
+ }
+ self.buffer.write(&coff_symbol);
+ }
+
+ /// Reserve auxiliary symbols for a file name.
+ ///
+ /// Returns the number of auxiliary symbols required.
+ ///
+ /// This must be called before [`Self::reserve_symtab_strtab`].
+ pub fn reserve_aux_file_name(&mut self, name: &[u8]) -> u8 {
+ debug_assert_eq!(self.symtab_offset, 0);
+ let aux_count = (name.len() + pe::IMAGE_SIZEOF_SYMBOL - 1) / pe::IMAGE_SIZEOF_SYMBOL;
+ self.symtab_num += aux_count as u32;
+ aux_count as u8
+ }
+
+ /// Write auxiliary symbols for a file name.
+ pub fn write_aux_file_name(&mut self, name: &[u8], aux_count: u8) {
+ let aux_len = aux_count as usize * pe::IMAGE_SIZEOF_SYMBOL;
+ debug_assert!(aux_len >= name.len());
+ let old_len = self.buffer.len();
+ self.buffer.write_bytes(name);
+ self.buffer.resize(old_len + aux_len);
+ }
+
+ /// Reserve an auxiliary symbol for a section.
+ ///
+ /// Returns the number of auxiliary symbols required.
+ ///
+ /// This must be called before [`Self::reserve_symtab_strtab`].
+ pub fn reserve_aux_section(&mut self) -> u8 {
+ debug_assert_eq!(self.symtab_offset, 0);
+ self.symtab_num += 1;
+ 1
+ }
+
+ /// Write an auxiliary symbol for a section.
+ pub fn write_aux_section(&mut self, section: AuxSymbolSection) {
+ let aux = pe::ImageAuxSymbolSection {
+ length: U32Bytes::new(LE, section.length),
+ number_of_relocations: if section.number_of_relocations > 0xffff {
+ U16Bytes::new(LE, 0xffff)
+ } else {
+ U16Bytes::new(LE, section.number_of_relocations as u16)
+ },
+ number_of_linenumbers: U16Bytes::new(LE, section.number_of_linenumbers),
+ check_sum: U32Bytes::new(LE, section.check_sum),
+ number: U16Bytes::new(LE, section.number as u16),
+ selection: section.selection,
+ reserved: 0,
+ high_number: U16Bytes::new(LE, (section.number >> 16) as u16),
+ };
+ self.buffer.write(&aux);
+ }
+
+ /// Return the number of reserved symbol table entries.
+ pub fn symbol_count(&self) -> u32 {
+ self.symtab_num
+ }
+
+ /// Add a string to the string table.
+ ///
+ /// This must be called before [`Self::reserve_symtab_strtab`].
+ pub fn add_string(&mut self, name: &'a [u8]) -> StringId {
+ debug_assert_eq!(self.strtab_offset, 0);
+ self.strtab.add(name)
+ }
+
+ /// Add a section or symbol name to the string table if required.
+ ///
+ /// This must be called before [`Self::reserve_symtab_strtab`].
+ pub fn add_name(&mut self, name: &'a [u8]) -> Name {
+ if name.len() > 8 {
+ Name::Long(self.add_string(name))
+ } else {
+ let mut short_name = [0; 8];
+ short_name[..name.len()].copy_from_slice(name);
+ Name::Short(short_name)
+ }
+ }
+
+ /// Reserve the range for the symbol table and string table.
+ ///
+ /// This must be called after functions that reserve symbol
+ /// indices or add strings.
+ pub fn reserve_symtab_strtab(&mut self) {
+ debug_assert_eq!(self.symtab_offset, 0);
+ self.symtab_offset = self.reserve(self.symtab_num as usize * pe::IMAGE_SIZEOF_SYMBOL, 1);
+
+ debug_assert_eq!(self.strtab_offset, 0);
+ // First 4 bytes of strtab are the length.
+ self.strtab.write(4, &mut self.strtab_data);
+ self.strtab_len = self.strtab_data.len() + 4;
+ self.strtab_offset = self.reserve(self.strtab_len, 1);
+ }
+
+ /// Write the string table.
+ pub fn write_strtab(&mut self) {
+ debug_assert_eq!(self.strtab_offset, self.buffer.len() as u32);
+ self.buffer
+ .write_bytes(&u32::to_le_bytes(self.strtab_len as u32));
+ self.buffer.write_bytes(&self.strtab_data);
+ }
+}
+
+/// Shortened and native endian version of [`pe::ImageFileHeader`].
+#[allow(missing_docs)]
+#[derive(Debug, Default, Clone)]
+pub struct FileHeader {
+ pub machine: u16,
+ pub time_date_stamp: u32,
+ pub characteristics: u16,
+}
+
+/// A section or symbol name.
+#[derive(Debug, Clone, Copy)]
+pub enum Name {
+ /// An inline name.
+ Short([u8; 8]),
+ /// An id of a string table entry.
+ Long(StringId),
+}
+
+impl Default for Name {
+ fn default() -> Name {
+ Name::Short([0; 8])
+ }
+}
+
+// From isn't useful.
+#[allow(clippy::from_over_into)]
+impl<'a> Into<Name> for &'a [u8; 8] {
+ fn into(self) -> Name {
+ Name::Short(*self)
+ }
+}
+
+/// Native endian version of [`pe::ImageSectionHeader`].
+#[allow(missing_docs)]
+#[derive(Debug, Default, Clone)]
+pub struct SectionHeader {
+ pub name: Name,
+ pub size_of_raw_data: u32,
+ pub pointer_to_raw_data: u32,
+ pub pointer_to_relocations: u32,
+ pub pointer_to_linenumbers: u32,
+ /// This will automatically be clamped if there are more than 0xffff.
+ pub number_of_relocations: u32,
+ pub number_of_linenumbers: u16,
+ pub characteristics: u32,
+}
+
+/// Native endian version of [`pe::ImageSymbol`].
+#[allow(missing_docs)]
+#[derive(Debug, Default, Clone)]
+pub struct Symbol {
+ pub name: Name,
+ pub value: u32,
+ pub section_number: u16,
+ pub typ: u16,
+ pub storage_class: u8,
+ pub number_of_aux_symbols: u8,
+}
+
+/// Native endian version of [`pe::ImageAuxSymbolSection`].
+#[allow(missing_docs)]
+#[derive(Debug, Default, Clone)]
+pub struct AuxSymbolSection {
+ pub length: u32,
+ /// This will automatically be clamped if there are more than 0xffff.
+ pub number_of_relocations: u32,
+ pub number_of_linenumbers: u16,
+ pub check_sum: u32,
+ pub number: u32,
+ pub selection: u8,
+}
+
+/// Native endian version of [`pe::ImageRelocation`].
+#[allow(missing_docs)]
+#[derive(Debug, Default, Clone)]
+pub struct Relocation {
+ pub virtual_address: u32,
+ pub symbol: u32,
+ pub typ: u16,
+}
diff --git a/vendor/object/src/write/elf/mod.rs b/vendor/object/src/write/elf/mod.rs
new file mode 100644
index 0000000..3a4f371
--- /dev/null
+++ b/vendor/object/src/write/elf/mod.rs
@@ -0,0 +1,9 @@
+//! Support for writing ELF files.
+//!
+//! Provides [`Writer`] for low level writing of ELF files.
+//! This is also used to provide ELF support for [`write::Object`](crate::write::Object).
+
+mod object;
+
+mod writer;
+pub use writer::*;
diff --git a/vendor/object/src/write/elf/object.rs b/vendor/object/src/write/elf/object.rs
new file mode 100644
index 0000000..5d7a93e
--- /dev/null
+++ b/vendor/object/src/write/elf/object.rs
@@ -0,0 +1,907 @@
+use alloc::vec::Vec;
+
+use crate::write::elf::writer::*;
+use crate::write::string::StringId;
+use crate::write::*;
+use crate::AddressSize;
+use crate::{elf, pod};
+
+#[derive(Clone, Copy)]
+struct ComdatOffsets {
+ offset: usize,
+ str_id: StringId,
+}
+
+#[derive(Clone, Copy)]
+struct SectionOffsets {
+ index: SectionIndex,
+ offset: usize,
+ str_id: StringId,
+ reloc_offset: usize,
+ reloc_str_id: Option<StringId>,
+}
+
+#[derive(Default, Clone, Copy)]
+struct SymbolOffsets {
+ index: SymbolIndex,
+ str_id: Option<StringId>,
+}
+
+// Public methods.
+impl<'a> Object<'a> {
+ /// Add a property with a u32 value to the ELF ".note.gnu.property" section.
+ ///
+ /// Requires `feature = "elf"`.
+ pub fn add_elf_gnu_property_u32(&mut self, property: u32, value: u32) {
+ if self.format != BinaryFormat::Elf {
+ return;
+ }
+
+ let align = if self.elf_is_64() { 8 } else { 4 };
+ let mut data = Vec::with_capacity(32);
+ let n_name = b"GNU\0";
+ data.extend_from_slice(pod::bytes_of(&elf::NoteHeader32 {
+ n_namesz: U32::new(self.endian, n_name.len() as u32),
+ n_descsz: U32::new(self.endian, util::align(3 * 4, align) as u32),
+ n_type: U32::new(self.endian, elf::NT_GNU_PROPERTY_TYPE_0),
+ }));
+ data.extend_from_slice(n_name);
+ // This happens to already be aligned correctly.
+ debug_assert_eq!(util::align(data.len(), align), data.len());
+ data.extend_from_slice(pod::bytes_of(&U32::new(self.endian, property)));
+ // Value size
+ data.extend_from_slice(pod::bytes_of(&U32::new(self.endian, 4)));
+ data.extend_from_slice(pod::bytes_of(&U32::new(self.endian, value)));
+ util::write_align(&mut data, align);
+
+ let section = self.section_id(StandardSection::GnuProperty);
+ self.append_section_data(section, &data, align as u64);
+ }
+}
+
+// Private methods.
+impl<'a> Object<'a> {
+ pub(crate) fn elf_section_info(
+ &self,
+ section: StandardSection,
+ ) -> (&'static [u8], &'static [u8], SectionKind, SectionFlags) {
+ match section {
+ StandardSection::Text => (&[], &b".text"[..], SectionKind::Text, SectionFlags::None),
+ StandardSection::Data => (&[], &b".data"[..], SectionKind::Data, SectionFlags::None),
+ StandardSection::ReadOnlyData | StandardSection::ReadOnlyString => (
+ &[],
+ &b".rodata"[..],
+ SectionKind::ReadOnlyData,
+ SectionFlags::None,
+ ),
+ StandardSection::ReadOnlyDataWithRel => (
+ &[],
+ b".data.rel.ro",
+ SectionKind::ReadOnlyDataWithRel,
+ SectionFlags::None,
+ ),
+ StandardSection::UninitializedData => (
+ &[],
+ &b".bss"[..],
+ SectionKind::UninitializedData,
+ SectionFlags::None,
+ ),
+ StandardSection::Tls => (&[], &b".tdata"[..], SectionKind::Tls, SectionFlags::None),
+ StandardSection::UninitializedTls => (
+ &[],
+ &b".tbss"[..],
+ SectionKind::UninitializedTls,
+ SectionFlags::None,
+ ),
+ StandardSection::TlsVariables => {
+ // Unsupported section.
+ (&[], &[], SectionKind::TlsVariables, SectionFlags::None)
+ }
+ StandardSection::Common => {
+ // Unsupported section.
+ (&[], &[], SectionKind::Common, SectionFlags::None)
+ }
+ StandardSection::GnuProperty => (
+ &[],
+ &b".note.gnu.property"[..],
+ SectionKind::Note,
+ SectionFlags::Elf {
+ sh_flags: u64::from(elf::SHF_ALLOC),
+ },
+ ),
+ }
+ }
+
+ pub(crate) fn elf_subsection_name(&self, section: &[u8], value: &[u8]) -> Vec<u8> {
+ let mut name = section.to_vec();
+ name.push(b'.');
+ name.extend_from_slice(value);
+ name
+ }
+
+ fn elf_has_relocation_addend(&self) -> Result<bool> {
+ Ok(match self.architecture {
+ Architecture::Aarch64 => true,
+ Architecture::Aarch64_Ilp32 => true,
+ Architecture::Arm => false,
+ Architecture::Avr => true,
+ Architecture::Bpf => false,
+ Architecture::Csky => true,
+ Architecture::I386 => false,
+ Architecture::X86_64 => true,
+ Architecture::X86_64_X32 => true,
+ Architecture::Hexagon => true,
+ Architecture::LoongArch64 => true,
+ Architecture::Mips => false,
+ Architecture::Mips64 => true,
+ Architecture::Msp430 => true,
+ Architecture::PowerPc => true,
+ Architecture::PowerPc64 => true,
+ Architecture::Riscv64 => true,
+ Architecture::Riscv32 => true,
+ Architecture::S390x => true,
+ Architecture::Sbf => false,
+ Architecture::Sharc => true,
+ Architecture::Sparc64 => true,
+ Architecture::Xtensa => true,
+ _ => {
+ return Err(Error(format!(
+ "unimplemented architecture {:?}",
+ self.architecture
+ )));
+ }
+ })
+ }
+
+ pub(crate) fn elf_fixup_relocation(&mut self, relocation: &mut Relocation) -> Result<i64> {
+ // Determine whether the addend is stored in the relocation or the data.
+ if self.elf_has_relocation_addend()? {
+ Ok(0)
+ } else {
+ let constant = relocation.addend;
+ relocation.addend = 0;
+ Ok(constant)
+ }
+ }
+
+ pub(crate) fn elf_is_64(&self) -> bool {
+ match self.architecture.address_size().unwrap() {
+ AddressSize::U8 | AddressSize::U16 | AddressSize::U32 => false,
+ AddressSize::U64 => true,
+ }
+ }
+
+ pub(crate) fn elf_write(&self, buffer: &mut dyn WritableBuffer) -> Result<()> {
+ // Create reloc section header names so we can reference them.
+ let is_rela = self.elf_has_relocation_addend()?;
+ let reloc_names: Vec<_> = self
+ .sections
+ .iter()
+ .map(|section| {
+ let mut reloc_name = Vec::with_capacity(
+ if is_rela { ".rela".len() } else { ".rel".len() } + section.name.len(),
+ );
+ if !section.relocations.is_empty() {
+ reloc_name.extend_from_slice(if is_rela {
+ &b".rela"[..]
+ } else {
+ &b".rel"[..]
+ });
+ reloc_name.extend_from_slice(&section.name);
+ }
+ reloc_name
+ })
+ .collect();
+
+ // Start calculating offsets of everything.
+ let mut writer = Writer::new(self.endian, self.elf_is_64(), buffer);
+ writer.reserve_file_header();
+
+ // Calculate size of section data.
+ let mut comdat_offsets = Vec::with_capacity(self.comdats.len());
+ for comdat in &self.comdats {
+ if comdat.kind != ComdatKind::Any {
+ return Err(Error(format!(
+ "unsupported COMDAT symbol `{}` kind {:?}",
+ self.symbols[comdat.symbol.0].name().unwrap_or(""),
+ comdat.kind
+ )));
+ }
+
+ writer.reserve_section_index();
+ let offset = writer.reserve_comdat(comdat.sections.len());
+ let str_id = writer.add_section_name(b".group");
+ comdat_offsets.push(ComdatOffsets { offset, str_id });
+ }
+ let mut section_offsets = Vec::with_capacity(self.sections.len());
+ for (section, reloc_name) in self.sections.iter().zip(reloc_names.iter()) {
+ let index = writer.reserve_section_index();
+ let offset = writer.reserve(section.data.len(), section.align as usize);
+ let str_id = writer.add_section_name(&section.name);
+ let mut reloc_str_id = None;
+ if !section.relocations.is_empty() {
+ writer.reserve_section_index();
+ reloc_str_id = Some(writer.add_section_name(reloc_name));
+ }
+ section_offsets.push(SectionOffsets {
+ index,
+ offset,
+ str_id,
+ // Relocation data is reserved later.
+ reloc_offset: 0,
+ reloc_str_id,
+ });
+ }
+
+ // Calculate index of symbols and add symbol strings to strtab.
+ let mut symbol_offsets = vec![SymbolOffsets::default(); self.symbols.len()];
+ writer.reserve_null_symbol_index();
+ // Local symbols must come before global.
+ for (index, symbol) in self.symbols.iter().enumerate() {
+ if symbol.is_local() {
+ let section_index = symbol.section.id().map(|s| section_offsets[s.0].index);
+ symbol_offsets[index].index = writer.reserve_symbol_index(section_index);
+ }
+ }
+ let symtab_num_local = writer.symbol_count();
+ for (index, symbol) in self.symbols.iter().enumerate() {
+ if !symbol.is_local() {
+ let section_index = symbol.section.id().map(|s| section_offsets[s.0].index);
+ symbol_offsets[index].index = writer.reserve_symbol_index(section_index);
+ }
+ }
+ for (index, symbol) in self.symbols.iter().enumerate() {
+ if symbol.kind != SymbolKind::Section && !symbol.name.is_empty() {
+ symbol_offsets[index].str_id = Some(writer.add_string(&symbol.name));
+ }
+ }
+
+ // Calculate size of symbols.
+ writer.reserve_symtab_section_index();
+ writer.reserve_symtab();
+ if writer.symtab_shndx_needed() {
+ writer.reserve_symtab_shndx_section_index();
+ }
+ writer.reserve_symtab_shndx();
+ writer.reserve_strtab_section_index();
+ writer.reserve_strtab();
+
+ // Calculate size of relocations.
+ for (index, section) in self.sections.iter().enumerate() {
+ let count = section.relocations.len();
+ if count != 0 {
+ section_offsets[index].reloc_offset = writer.reserve_relocations(count, is_rela);
+ }
+ }
+
+ // Calculate size of section headers.
+ writer.reserve_shstrtab_section_index();
+ writer.reserve_shstrtab();
+ writer.reserve_section_headers();
+
+ // Start writing.
+ let e_type = elf::ET_REL;
+ let e_machine = match (self.architecture, self.sub_architecture) {
+ (Architecture::Aarch64, None) => elf::EM_AARCH64,
+ (Architecture::Aarch64_Ilp32, None) => elf::EM_AARCH64,
+ (Architecture::Arm, None) => elf::EM_ARM,
+ (Architecture::Avr, None) => elf::EM_AVR,
+ (Architecture::Bpf, None) => elf::EM_BPF,
+ (Architecture::Csky, None) => elf::EM_CSKY,
+ (Architecture::I386, None) => elf::EM_386,
+ (Architecture::X86_64, None) => elf::EM_X86_64,
+ (Architecture::X86_64_X32, None) => elf::EM_X86_64,
+ (Architecture::Hexagon, None) => elf::EM_HEXAGON,
+ (Architecture::LoongArch64, None) => elf::EM_LOONGARCH,
+ (Architecture::Mips, None) => elf::EM_MIPS,
+ (Architecture::Mips64, None) => elf::EM_MIPS,
+ (Architecture::Msp430, None) => elf::EM_MSP430,
+ (Architecture::PowerPc, None) => elf::EM_PPC,
+ (Architecture::PowerPc64, None) => elf::EM_PPC64,
+ (Architecture::Riscv32, None) => elf::EM_RISCV,
+ (Architecture::Riscv64, None) => elf::EM_RISCV,
+ (Architecture::S390x, None) => elf::EM_S390,
+ (Architecture::Sbf, None) => elf::EM_SBF,
+ (Architecture::Sharc, None) => elf::EM_SHARC,
+ (Architecture::Sparc64, None) => elf::EM_SPARCV9,
+ (Architecture::Xtensa, None) => elf::EM_XTENSA,
+ _ => {
+ return Err(Error(format!(
+ "unimplemented architecture {:?} with sub-architecture {:?}",
+ self.architecture, self.sub_architecture
+ )));
+ }
+ };
+ let (os_abi, abi_version, e_flags) = if let FileFlags::Elf {
+ os_abi,
+ abi_version,
+ e_flags,
+ } = self.flags
+ {
+ (os_abi, abi_version, e_flags)
+ } else {
+ (elf::ELFOSABI_NONE, 0, 0)
+ };
+ writer.write_file_header(&FileHeader {
+ os_abi,
+ abi_version,
+ e_type,
+ e_machine,
+ e_entry: 0,
+ e_flags,
+ })?;
+
+ // Write section data.
+ for comdat in &self.comdats {
+ writer.write_comdat_header();
+ for section in &comdat.sections {
+ writer.write_comdat_entry(section_offsets[section.0].index);
+ }
+ }
+ for (index, section) in self.sections.iter().enumerate() {
+ writer.write_align(section.align as usize);
+ debug_assert_eq!(section_offsets[index].offset, writer.len());
+ writer.write(&section.data);
+ }
+
+ // Write symbols.
+ writer.write_null_symbol();
+ let mut write_symbol = |index: usize, symbol: &Symbol| -> Result<()> {
+ let st_info = if let SymbolFlags::Elf { st_info, .. } = symbol.flags {
+ st_info
+ } else {
+ let st_type = match symbol.kind {
+ SymbolKind::Null => elf::STT_NOTYPE,
+ SymbolKind::Text => {
+ if symbol.is_undefined() {
+ elf::STT_NOTYPE
+ } else {
+ elf::STT_FUNC
+ }
+ }
+ SymbolKind::Data => {
+ if symbol.is_undefined() {
+ elf::STT_NOTYPE
+ } else if symbol.is_common() {
+ elf::STT_COMMON
+ } else {
+ elf::STT_OBJECT
+ }
+ }
+ SymbolKind::Section => elf::STT_SECTION,
+ SymbolKind::File => elf::STT_FILE,
+ SymbolKind::Tls => elf::STT_TLS,
+ SymbolKind::Label => elf::STT_NOTYPE,
+ SymbolKind::Unknown => {
+ if symbol.is_undefined() {
+ elf::STT_NOTYPE
+ } else {
+ return Err(Error(format!(
+ "unimplemented symbol `{}` kind {:?}",
+ symbol.name().unwrap_or(""),
+ symbol.kind
+ )));
+ }
+ }
+ };
+ let st_bind = if symbol.weak {
+ elf::STB_WEAK
+ } else if symbol.is_undefined() {
+ elf::STB_GLOBAL
+ } else if symbol.is_local() {
+ elf::STB_LOCAL
+ } else {
+ elf::STB_GLOBAL
+ };
+ (st_bind << 4) + st_type
+ };
+ let st_other = if let SymbolFlags::Elf { st_other, .. } = symbol.flags {
+ st_other
+ } else if symbol.scope == SymbolScope::Linkage {
+ elf::STV_HIDDEN
+ } else {
+ elf::STV_DEFAULT
+ };
+ let (st_shndx, section) = match symbol.section {
+ SymbolSection::None => {
+ debug_assert_eq!(symbol.kind, SymbolKind::File);
+ (elf::SHN_ABS, None)
+ }
+ SymbolSection::Undefined => (elf::SHN_UNDEF, None),
+ SymbolSection::Absolute => (elf::SHN_ABS, None),
+ SymbolSection::Common => (elf::SHN_COMMON, None),
+ SymbolSection::Section(id) => (0, Some(section_offsets[id.0].index)),
+ };
+ writer.write_symbol(&Sym {
+ name: symbol_offsets[index].str_id,
+ section,
+ st_info,
+ st_other,
+ st_shndx,
+ st_value: symbol.value,
+ st_size: symbol.size,
+ });
+ Ok(())
+ };
+ for (index, symbol) in self.symbols.iter().enumerate() {
+ if symbol.is_local() {
+ write_symbol(index, symbol)?;
+ }
+ }
+ for (index, symbol) in self.symbols.iter().enumerate() {
+ if !symbol.is_local() {
+ write_symbol(index, symbol)?;
+ }
+ }
+ writer.write_symtab_shndx();
+ writer.write_strtab();
+
+ // Write relocations.
+ for (index, section) in self.sections.iter().enumerate() {
+ if !section.relocations.is_empty() {
+ writer.write_align_relocation();
+ debug_assert_eq!(section_offsets[index].reloc_offset, writer.len());
+ for reloc in &section.relocations {
+ let r_type = match self.architecture {
+ Architecture::Aarch64 => match (reloc.kind, reloc.encoding, reloc.size) {
+ (RelocationKind::Absolute, RelocationEncoding::Generic, 64) => {
+ elf::R_AARCH64_ABS64
+ }
+ (RelocationKind::Absolute, RelocationEncoding::Generic, 32) => {
+ elf::R_AARCH64_ABS32
+ }
+ (RelocationKind::Absolute, RelocationEncoding::Generic, 16) => {
+ elf::R_AARCH64_ABS16
+ }
+ (RelocationKind::Relative, RelocationEncoding::Generic, 64) => {
+ elf::R_AARCH64_PREL64
+ }
+ (RelocationKind::Relative, RelocationEncoding::Generic, 32) => {
+ elf::R_AARCH64_PREL32
+ }
+ (RelocationKind::Relative, RelocationEncoding::Generic, 16) => {
+ elf::R_AARCH64_PREL16
+ }
+ (RelocationKind::Relative, RelocationEncoding::AArch64Call, 26)
+ | (RelocationKind::PltRelative, RelocationEncoding::AArch64Call, 26) => {
+ elf::R_AARCH64_CALL26
+ }
+ (RelocationKind::Elf(x), _, _) => x,
+ _ => {
+ return Err(Error(format!("unimplemented relocation {:?}", reloc)));
+ }
+ },
+ Architecture::Aarch64_Ilp32 => {
+ match (reloc.kind, reloc.encoding, reloc.size) {
+ (RelocationKind::Absolute, RelocationEncoding::Generic, 32) => {
+ elf::R_AARCH64_P32_ABS32
+ }
+ (RelocationKind::Elf(x), _, _) => x,
+ _ => {
+ return Err(Error(format!(
+ "unimplemented relocation {:?}",
+ reloc
+ )));
+ }
+ }
+ }
+ Architecture::Arm => match (reloc.kind, reloc.encoding, reloc.size) {
+ (RelocationKind::Absolute, _, 32) => elf::R_ARM_ABS32,
+ (RelocationKind::Elf(x), _, _) => x,
+ _ => {
+ return Err(Error(format!("unimplemented relocation {:?}", reloc)));
+ }
+ },
+ Architecture::Avr => match (reloc.kind, reloc.encoding, reloc.size) {
+ (RelocationKind::Absolute, _, 32) => elf::R_AVR_32,
+ (RelocationKind::Absolute, _, 16) => elf::R_AVR_16,
+ (RelocationKind::Elf(x), _, _) => x,
+ _ => {
+ return Err(Error(format!("unimplemented relocation {:?}", reloc)));
+ }
+ },
+ Architecture::Bpf => match (reloc.kind, reloc.encoding, reloc.size) {
+ (RelocationKind::Absolute, _, 64) => elf::R_BPF_64_64,
+ (RelocationKind::Absolute, _, 32) => elf::R_BPF_64_32,
+ (RelocationKind::Elf(x), _, _) => x,
+ _ => {
+ return Err(Error(format!("unimplemented relocation {:?}", reloc)));
+ }
+ },
+ Architecture::Csky => match (reloc.kind, reloc.encoding, reloc.size) {
+ (RelocationKind::Absolute, _, 32) => elf::R_CKCORE_ADDR32,
+ (RelocationKind::Relative, RelocationEncoding::Generic, 32) => {
+ elf::R_CKCORE_PCREL32
+ }
+ (RelocationKind::Elf(x), _, _) => x,
+ _ => {
+ return Err(Error(format!("unimplemented relocation {:?}", reloc)));
+ }
+ },
+ Architecture::I386 => match (reloc.kind, reloc.size) {
+ (RelocationKind::Absolute, 32) => elf::R_386_32,
+ (RelocationKind::Relative, 32) => elf::R_386_PC32,
+ (RelocationKind::Got, 32) => elf::R_386_GOT32,
+ (RelocationKind::PltRelative, 32) => elf::R_386_PLT32,
+ (RelocationKind::GotBaseOffset, 32) => elf::R_386_GOTOFF,
+ (RelocationKind::GotBaseRelative, 32) => elf::R_386_GOTPC,
+ (RelocationKind::Absolute, 16) => elf::R_386_16,
+ (RelocationKind::Relative, 16) => elf::R_386_PC16,
+ (RelocationKind::Absolute, 8) => elf::R_386_8,
+ (RelocationKind::Relative, 8) => elf::R_386_PC8,
+ (RelocationKind::Elf(x), _) => x,
+ _ => {
+ return Err(Error(format!("unimplemented relocation {:?}", reloc)));
+ }
+ },
+ Architecture::X86_64 | Architecture::X86_64_X32 => {
+ match (reloc.kind, reloc.encoding, reloc.size) {
+ (RelocationKind::Absolute, RelocationEncoding::Generic, 64) => {
+ elf::R_X86_64_64
+ }
+ (RelocationKind::Relative, RelocationEncoding::X86Branch, 32) => {
+ elf::R_X86_64_PLT32
+ }
+ (RelocationKind::Relative, _, 32) => elf::R_X86_64_PC32,
+ (RelocationKind::Got, _, 32) => elf::R_X86_64_GOT32,
+ (RelocationKind::PltRelative, _, 32) => elf::R_X86_64_PLT32,
+ (RelocationKind::GotRelative, _, 32) => elf::R_X86_64_GOTPCREL,
+ (RelocationKind::Absolute, RelocationEncoding::Generic, 32) => {
+ elf::R_X86_64_32
+ }
+ (RelocationKind::Absolute, RelocationEncoding::X86Signed, 32) => {
+ elf::R_X86_64_32S
+ }
+ (RelocationKind::Absolute, _, 16) => elf::R_X86_64_16,
+ (RelocationKind::Relative, _, 16) => elf::R_X86_64_PC16,
+ (RelocationKind::Absolute, _, 8) => elf::R_X86_64_8,
+ (RelocationKind::Relative, _, 8) => elf::R_X86_64_PC8,
+ (RelocationKind::Elf(x), _, _) => x,
+ _ => {
+ return Err(Error(format!(
+ "unimplemented relocation {:?}",
+ reloc
+ )));
+ }
+ }
+ }
+ Architecture::Hexagon => match (reloc.kind, reloc.encoding, reloc.size) {
+ (RelocationKind::Absolute, _, 32) => elf::R_HEX_32,
+ (RelocationKind::Elf(x), _, _) => x,
+ _ => {
+ return Err(Error(format!("unimplemented relocation {:?}", reloc)));
+ }
+ },
+ Architecture::LoongArch64 => match (reloc.kind, reloc.encoding, reloc.size)
+ {
+ (RelocationKind::Absolute, _, 32) => elf::R_LARCH_32,
+ (RelocationKind::Absolute, _, 64) => elf::R_LARCH_64,
+ (RelocationKind::Relative, _, 32) => elf::R_LARCH_32_PCREL,
+ (RelocationKind::Relative, _, 64) => elf::R_LARCH_64_PCREL,
+ (RelocationKind::Relative, RelocationEncoding::LoongArchBranch, 16)
+ | (
+ RelocationKind::PltRelative,
+ RelocationEncoding::LoongArchBranch,
+ 16,
+ ) => elf::R_LARCH_B16,
+ (RelocationKind::Relative, RelocationEncoding::LoongArchBranch, 21)
+ | (
+ RelocationKind::PltRelative,
+ RelocationEncoding::LoongArchBranch,
+ 21,
+ ) => elf::R_LARCH_B21,
+ (RelocationKind::Relative, RelocationEncoding::LoongArchBranch, 26)
+ | (
+ RelocationKind::PltRelative,
+ RelocationEncoding::LoongArchBranch,
+ 26,
+ ) => elf::R_LARCH_B26,
+ (RelocationKind::Elf(x), _, _) => x,
+ _ => {
+ return Err(Error(format!("unimplemented relocation {:?}", reloc)));
+ }
+ },
+ Architecture::Mips | Architecture::Mips64 => {
+ match (reloc.kind, reloc.encoding, reloc.size) {
+ (RelocationKind::Absolute, _, 16) => elf::R_MIPS_16,
+ (RelocationKind::Absolute, _, 32) => elf::R_MIPS_32,
+ (RelocationKind::Absolute, _, 64) => elf::R_MIPS_64,
+ (RelocationKind::Elf(x), _, _) => x,
+ _ => {
+ return Err(Error(format!(
+ "unimplemented relocation {:?}",
+ reloc
+ )));
+ }
+ }
+ }
+ Architecture::Msp430 => match (reloc.kind, reloc.encoding, reloc.size) {
+ (RelocationKind::Absolute, _, 32) => elf::R_MSP430_32,
+ (RelocationKind::Absolute, _, 16) => elf::R_MSP430_16_BYTE,
+ (RelocationKind::Elf(x), _, _) => x,
+ _ => {
+ return Err(Error(format!("unimplemented relocation {:?}", reloc)));
+ }
+ },
+ Architecture::PowerPc => match (reloc.kind, reloc.encoding, reloc.size) {
+ (RelocationKind::Absolute, _, 32) => elf::R_PPC_ADDR32,
+ (RelocationKind::Elf(x), _, _) => x,
+ _ => {
+ return Err(Error(format!("unimplemented relocation {:?}", reloc)));
+ }
+ },
+ Architecture::PowerPc64 => match (reloc.kind, reloc.encoding, reloc.size) {
+ (RelocationKind::Absolute, _, 32) => elf::R_PPC64_ADDR32,
+ (RelocationKind::Absolute, _, 64) => elf::R_PPC64_ADDR64,
+ (RelocationKind::Elf(x), _, _) => x,
+ _ => {
+ return Err(Error(format!("unimplemented relocation {:?}", reloc)));
+ }
+ },
+ Architecture::Riscv32 | Architecture::Riscv64 => {
+ match (reloc.kind, reloc.encoding, reloc.size) {
+ (RelocationKind::Absolute, _, 32) => elf::R_RISCV_32,
+ (RelocationKind::Absolute, _, 64) => elf::R_RISCV_64,
+ (RelocationKind::Relative, RelocationEncoding::Generic, 32) => {
+ elf::R_RISCV_32_PCREL
+ }
+ (RelocationKind::Elf(x), _, _) => x,
+ _ => {
+ return Err(Error(format!(
+ "unimplemented relocation {:?}",
+ reloc
+ )));
+ }
+ }
+ }
+ Architecture::S390x => match (reloc.kind, reloc.encoding, reloc.size) {
+ (RelocationKind::Absolute, RelocationEncoding::Generic, 8) => {
+ elf::R_390_8
+ }
+ (RelocationKind::Absolute, RelocationEncoding::Generic, 16) => {
+ elf::R_390_16
+ }
+ (RelocationKind::Absolute, RelocationEncoding::Generic, 32) => {
+ elf::R_390_32
+ }
+ (RelocationKind::Absolute, RelocationEncoding::Generic, 64) => {
+ elf::R_390_64
+ }
+ (RelocationKind::Relative, RelocationEncoding::Generic, 16) => {
+ elf::R_390_PC16
+ }
+ (RelocationKind::Relative, RelocationEncoding::Generic, 32) => {
+ elf::R_390_PC32
+ }
+ (RelocationKind::Relative, RelocationEncoding::Generic, 64) => {
+ elf::R_390_PC64
+ }
+ (RelocationKind::Relative, RelocationEncoding::S390xDbl, 16) => {
+ elf::R_390_PC16DBL
+ }
+ (RelocationKind::Relative, RelocationEncoding::S390xDbl, 32) => {
+ elf::R_390_PC32DBL
+ }
+ (RelocationKind::PltRelative, RelocationEncoding::S390xDbl, 16) => {
+ elf::R_390_PLT16DBL
+ }
+ (RelocationKind::PltRelative, RelocationEncoding::S390xDbl, 32) => {
+ elf::R_390_PLT32DBL
+ }
+ (RelocationKind::Got, RelocationEncoding::Generic, 16) => {
+ elf::R_390_GOT16
+ }
+ (RelocationKind::Got, RelocationEncoding::Generic, 32) => {
+ elf::R_390_GOT32
+ }
+ (RelocationKind::Got, RelocationEncoding::Generic, 64) => {
+ elf::R_390_GOT64
+ }
+ (RelocationKind::GotRelative, RelocationEncoding::S390xDbl, 32) => {
+ elf::R_390_GOTENT
+ }
+ (RelocationKind::GotBaseOffset, RelocationEncoding::Generic, 16) => {
+ elf::R_390_GOTOFF16
+ }
+ (RelocationKind::GotBaseOffset, RelocationEncoding::Generic, 32) => {
+ elf::R_390_GOTOFF32
+ }
+ (RelocationKind::GotBaseOffset, RelocationEncoding::Generic, 64) => {
+ elf::R_390_GOTOFF64
+ }
+ (RelocationKind::GotBaseRelative, RelocationEncoding::Generic, 64) => {
+ elf::R_390_GOTPC
+ }
+ (RelocationKind::GotBaseRelative, RelocationEncoding::S390xDbl, 32) => {
+ elf::R_390_GOTPCDBL
+ }
+ (RelocationKind::Elf(x), _, _) => x,
+ _ => {
+ return Err(Error(format!("unimplemented relocation {:?}", reloc)));
+ }
+ },
+ Architecture::Sbf => match (reloc.kind, reloc.encoding, reloc.size) {
+ (RelocationKind::Absolute, _, 64) => elf::R_SBF_64_64,
+ (RelocationKind::Absolute, _, 32) => elf::R_SBF_64_32,
+ (RelocationKind::Elf(x), _, _) => x,
+ _ => {
+ return Err(Error(format!("unimplemented relocation {:?}", reloc)));
+ }
+ },
+ Architecture::Sharc => match (reloc.kind, reloc.encoding, reloc.size) {
+ (RelocationKind::Absolute, RelocationEncoding::SharcTypeA, 32) => {
+ elf::R_SHARC_ADDR32_V3
+ }
+ (RelocationKind::Absolute, RelocationEncoding::Generic, 32) => {
+ elf::R_SHARC_ADDR_VAR_V3
+ }
+ (RelocationKind::Relative, RelocationEncoding::SharcTypeA, 24) => {
+ elf::R_SHARC_PCRLONG_V3
+ }
+ (RelocationKind::Relative, RelocationEncoding::SharcTypeA, 6) => {
+ elf::R_SHARC_PCRSHORT_V3
+ }
+ (RelocationKind::Relative, RelocationEncoding::SharcTypeB, 6) => {
+ elf::R_SHARC_PCRSHORT_V3
+ }
+ (RelocationKind::Absolute, RelocationEncoding::Generic, 16) => {
+ elf::R_SHARC_ADDR_VAR16_V3
+ }
+ (RelocationKind::Absolute, RelocationEncoding::SharcTypeA, 16) => {
+ elf::R_SHARC_DATA16_V3
+ }
+ (RelocationKind::Absolute, RelocationEncoding::SharcTypeB, 16) => {
+ elf::R_SHARC_DATA16_VISA_V3
+ }
+ (RelocationKind::Absolute, RelocationEncoding::SharcTypeA, 24) => {
+ elf::R_SHARC_ADDR24_V3
+ }
+ (RelocationKind::Absolute, RelocationEncoding::SharcTypeA, 6) => {
+ elf::R_SHARC_DATA6_V3
+ }
+ (RelocationKind::Absolute, RelocationEncoding::SharcTypeB, 6) => {
+ elf::R_SHARC_DATA6_VISA_V3
+ }
+ (RelocationKind::Absolute, RelocationEncoding::SharcTypeB, 7) => {
+ elf::R_SHARC_DATA7_VISA_V3
+ }
+ (RelocationKind::Elf(x), _, _) => x,
+ _ => {
+ return Err(Error(format!("unimplemented relocation {:?}", reloc)));
+ }
+ },
+ Architecture::Sparc64 => match (reloc.kind, reloc.encoding, reloc.size) {
+ // TODO: use R_SPARC_32/R_SPARC_64 if aligned.
+ (RelocationKind::Absolute, _, 32) => elf::R_SPARC_UA32,
+ (RelocationKind::Absolute, _, 64) => elf::R_SPARC_UA64,
+ (RelocationKind::Elf(x), _, _) => x,
+ _ => {
+ return Err(Error(format!("unimplemented relocation {:?}", reloc)));
+ }
+ },
+ Architecture::Xtensa => match (reloc.kind, reloc.encoding, reloc.size) {
+ (RelocationKind::Absolute, _, 32) => elf::R_XTENSA_32,
+ (RelocationKind::Relative, RelocationEncoding::Generic, 32) => {
+ elf::R_XTENSA_32_PCREL
+ }
+ (RelocationKind::Elf(x), _, _) => x,
+ _ => {
+ return Err(Error(format!("unimplemented relocation {:?}", reloc)));
+ }
+ },
+ _ => {
+ if let RelocationKind::Elf(x) = reloc.kind {
+ x
+ } else {
+ return Err(Error(format!("unimplemented relocation {:?}", reloc)));
+ }
+ }
+ };
+ let r_sym = symbol_offsets[reloc.symbol.0].index.0;
+ writer.write_relocation(
+ is_rela,
+ &Rel {
+ r_offset: reloc.offset,
+ r_sym,
+ r_type,
+ r_addend: reloc.addend,
+ },
+ );
+ }
+ }
+ }
+
+ writer.write_shstrtab();
+
+ // Write section headers.
+ writer.write_null_section_header();
+
+ let symtab_index = writer.symtab_index();
+ for (comdat, comdat_offset) in self.comdats.iter().zip(comdat_offsets.iter()) {
+ writer.write_comdat_section_header(
+ comdat_offset.str_id,
+ symtab_index,
+ symbol_offsets[comdat.symbol.0].index,
+ comdat_offset.offset,
+ comdat.sections.len(),
+ );
+ }
+ for (index, section) in self.sections.iter().enumerate() {
+ let sh_type = match section.kind {
+ SectionKind::UninitializedData | SectionKind::UninitializedTls => elf::SHT_NOBITS,
+ SectionKind::Note => elf::SHT_NOTE,
+ SectionKind::Elf(sh_type) => sh_type,
+ _ => elf::SHT_PROGBITS,
+ };
+ let sh_flags = if let SectionFlags::Elf { sh_flags } = section.flags {
+ sh_flags
+ } else {
+ match section.kind {
+ SectionKind::Text => elf::SHF_ALLOC | elf::SHF_EXECINSTR,
+ SectionKind::Data | SectionKind::ReadOnlyDataWithRel => {
+ elf::SHF_ALLOC | elf::SHF_WRITE
+ }
+ SectionKind::Tls => elf::SHF_ALLOC | elf::SHF_WRITE | elf::SHF_TLS,
+ SectionKind::UninitializedData => elf::SHF_ALLOC | elf::SHF_WRITE,
+ SectionKind::UninitializedTls => elf::SHF_ALLOC | elf::SHF_WRITE | elf::SHF_TLS,
+ SectionKind::ReadOnlyData => elf::SHF_ALLOC,
+ SectionKind::ReadOnlyString => {
+ elf::SHF_ALLOC | elf::SHF_STRINGS | elf::SHF_MERGE
+ }
+ SectionKind::OtherString => elf::SHF_STRINGS | elf::SHF_MERGE,
+ SectionKind::Other
+ | SectionKind::Debug
+ | SectionKind::Metadata
+ | SectionKind::Linker
+ | SectionKind::Note
+ | SectionKind::Elf(_) => 0,
+ SectionKind::Unknown | SectionKind::Common | SectionKind::TlsVariables => {
+ return Err(Error(format!(
+ "unimplemented section `{}` kind {:?}",
+ section.name().unwrap_or(""),
+ section.kind
+ )));
+ }
+ }
+ .into()
+ };
+ // TODO: not sure if this is correct, maybe user should determine this
+ let sh_entsize = match section.kind {
+ SectionKind::ReadOnlyString | SectionKind::OtherString => 1,
+ _ => 0,
+ };
+ writer.write_section_header(&SectionHeader {
+ name: Some(section_offsets[index].str_id),
+ sh_type,
+ sh_flags,
+ sh_addr: 0,
+ sh_offset: section_offsets[index].offset as u64,
+ sh_size: section.size,
+ sh_link: 0,
+ sh_info: 0,
+ sh_addralign: section.align,
+ sh_entsize,
+ });
+
+ if !section.relocations.is_empty() {
+ writer.write_relocation_section_header(
+ section_offsets[index].reloc_str_id.unwrap(),
+ section_offsets[index].index,
+ symtab_index,
+ section_offsets[index].reloc_offset,
+ section.relocations.len(),
+ is_rela,
+ );
+ }
+ }
+
+ writer.write_symtab_section_header(symtab_num_local);
+ writer.write_symtab_shndx_section_header();
+ writer.write_strtab_section_header();
+ writer.write_shstrtab_section_header();
+
+ debug_assert_eq!(writer.reserved_len(), writer.len());
+
+ Ok(())
+ }
+}
diff --git a/vendor/object/src/write/elf/writer.rs b/vendor/object/src/write/elf/writer.rs
new file mode 100644
index 0000000..9750924
--- /dev/null
+++ b/vendor/object/src/write/elf/writer.rs
@@ -0,0 +1,2143 @@
+//! Helper for writing ELF files.
+use alloc::string::String;
+use alloc::vec::Vec;
+use core::mem;
+
+use crate::elf;
+use crate::endian::*;
+use crate::pod;
+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,
+
+ gnu_attributes_str_id: Option<StringId>,
+ gnu_attributes_offset: usize,
+ gnu_attributes_size: usize,
+}
+
+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,
+
+ gnu_attributes_str_id: None,
+ gnu_attributes_offset: 0,
+ gnu_attributes_size: 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 align_start > 1 {
+ 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) {
+ if align_start > 1 {
+ 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(&section);
+ } 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(&section);
+ }
+ }
+
+ /// 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 the section index for the `.gnu.attributes` section.
+ pub fn reserve_gnu_attributes_section_index(&mut self) -> SectionIndex {
+ debug_assert!(self.gnu_attributes_str_id.is_none());
+ self.gnu_attributes_str_id = Some(self.add_section_name(&b".gnu.attributes"[..]));
+ self.reserve_section_index()
+ }
+
+ /// Reserve the range for the `.gnu.attributes` section.
+ pub fn reserve_gnu_attributes(&mut self, gnu_attributes_size: usize) {
+ debug_assert_eq!(self.gnu_attributes_offset, 0);
+ if gnu_attributes_size == 0 {
+ return;
+ }
+ self.gnu_attributes_size = gnu_attributes_size;
+ self.gnu_attributes_offset = self.reserve(self.gnu_attributes_size, self.elf_align);
+ }
+
+ /// Write the section header for the `.gnu.attributes` section.
+ ///
+ /// This function does nothing if the section index was not reserved.
+ pub fn write_gnu_attributes_section_header(&mut self) {
+ if self.gnu_attributes_str_id.is_none() {
+ return;
+ }
+ self.write_section_header(&SectionHeader {
+ name: self.gnu_attributes_str_id,
+ sh_type: elf::SHT_GNU_ATTRIBUTES,
+ sh_flags: 0,
+ sh_addr: 0,
+ sh_offset: self.gnu_attributes_offset as u64,
+ sh_size: self.gnu_attributes_size as u64,
+ sh_link: self.dynstr_index.0,
+ sh_info: 0, // TODO
+ sh_addralign: self.elf_align as u64,
+ sh_entsize: 0,
+ });
+ }
+
+ /// Write the data for the `.gnu.attributes` section.
+ pub fn write_gnu_attributes(&mut self, data: &[u8]) {
+ if self.gnu_attributes_offset == 0 {
+ return;
+ }
+ util::write_align(self.buffer, self.elf_align);
+ debug_assert_eq!(self.gnu_attributes_offset, self.buffer.len());
+ self.buffer.write_bytes(data);
+ }
+
+ /// 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,
+ });
+ }
+
+ /// Return a helper for writing an attributes section.
+ pub fn attributes_writer(&self) -> AttributesWriter {
+ AttributesWriter::new(self.endian)
+ }
+}
+
+/// A helper for writing an attributes section.
+///
+/// Attributes have a variable length encoding, so it is awkward to write them in a
+/// single pass. Instead, we build the entire attributes section data in memory, using
+/// placeholders for unknown lengths that are filled in later.
+#[allow(missing_debug_implementations)]
+pub struct AttributesWriter {
+ endian: Endianness,
+ data: Vec<u8>,
+ subsection_offset: usize,
+ subsubsection_offset: usize,
+}
+
+impl AttributesWriter {
+ /// Create a new `AttributesWriter` for the given endianness.
+ pub fn new(endian: Endianness) -> Self {
+ AttributesWriter {
+ endian,
+ data: vec![0x41],
+ subsection_offset: 0,
+ subsubsection_offset: 0,
+ }
+ }
+
+ /// Start a new subsection with the given vendor name.
+ pub fn start_subsection(&mut self, vendor: &[u8]) {
+ debug_assert_eq!(self.subsection_offset, 0);
+ debug_assert_eq!(self.subsubsection_offset, 0);
+ self.subsection_offset = self.data.len();
+ self.data.extend_from_slice(&[0; 4]);
+ self.data.extend_from_slice(vendor);
+ self.data.push(0);
+ }
+
+ /// End the subsection.
+ ///
+ /// The subsection length is automatically calculated and written.
+ pub fn end_subsection(&mut self) {
+ debug_assert_ne!(self.subsection_offset, 0);
+ debug_assert_eq!(self.subsubsection_offset, 0);
+ let length = self.data.len() - self.subsection_offset;
+ self.data[self.subsection_offset..][..4]
+ .copy_from_slice(pod::bytes_of(&U32::new(self.endian, length as u32)));
+ self.subsection_offset = 0;
+ }
+
+ /// Start a new sub-subsection with the given tag.
+ pub fn start_subsubsection(&mut self, tag: u8) {
+ debug_assert_ne!(self.subsection_offset, 0);
+ debug_assert_eq!(self.subsubsection_offset, 0);
+ self.subsubsection_offset = self.data.len();
+ self.data.push(tag);
+ self.data.extend_from_slice(&[0; 4]);
+ }
+
+ /// Write a section or symbol index to the sub-subsection.
+ ///
+ /// The user must also call this function to write the terminating 0 index.
+ pub fn write_subsubsection_index(&mut self, index: u32) {
+ debug_assert_ne!(self.subsection_offset, 0);
+ debug_assert_ne!(self.subsubsection_offset, 0);
+ util::write_uleb128(&mut self.data, u64::from(index));
+ }
+
+ /// Write raw index data to the sub-subsection.
+ ///
+ /// The terminating 0 index is automatically written.
+ pub fn write_subsubsection_indices(&mut self, indices: &[u8]) {
+ debug_assert_ne!(self.subsection_offset, 0);
+ debug_assert_ne!(self.subsubsection_offset, 0);
+ self.data.extend_from_slice(indices);
+ self.data.push(0);
+ }
+
+ /// Write an attribute tag to the sub-subsection.
+ pub fn write_attribute_tag(&mut self, tag: u64) {
+ debug_assert_ne!(self.subsection_offset, 0);
+ debug_assert_ne!(self.subsubsection_offset, 0);
+ util::write_uleb128(&mut self.data, tag);
+ }
+
+ /// Write an attribute integer value to the sub-subsection.
+ pub fn write_attribute_integer(&mut self, value: u64) {
+ debug_assert_ne!(self.subsection_offset, 0);
+ debug_assert_ne!(self.subsubsection_offset, 0);
+ util::write_uleb128(&mut self.data, value);
+ }
+
+ /// Write an attribute string value to the sub-subsection.
+ ///
+ /// The value must not include the null terminator.
+ pub fn write_attribute_string(&mut self, value: &[u8]) {
+ debug_assert_ne!(self.subsection_offset, 0);
+ debug_assert_ne!(self.subsubsection_offset, 0);
+ self.data.extend_from_slice(value);
+ self.data.push(0);
+ }
+
+ /// Write raw attribute data to the sub-subsection.
+ pub fn write_subsubsection_attributes(&mut self, attributes: &[u8]) {
+ debug_assert_ne!(self.subsection_offset, 0);
+ debug_assert_ne!(self.subsubsection_offset, 0);
+ self.data.extend_from_slice(attributes);
+ }
+
+ /// End the sub-subsection.
+ ///
+ /// The sub-subsection length is automatically calculated and written.
+ pub fn end_subsubsection(&mut self) {
+ debug_assert_ne!(self.subsection_offset, 0);
+ debug_assert_ne!(self.subsubsection_offset, 0);
+ let length = self.data.len() - self.subsubsection_offset;
+ self.data[self.subsubsection_offset + 1..][..4]
+ .copy_from_slice(pod::bytes_of(&U32::new(self.endian, length as u32)));
+ self.subsubsection_offset = 0;
+ }
+
+ /// Return the completed section data.
+ pub fn data(self) -> Vec<u8> {
+ debug_assert_eq!(self.subsection_offset, 0);
+ debug_assert_eq!(self.subsubsection_offset, 0);
+ self.data
+ }
+}
+
+/// 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,
+}
diff --git a/vendor/object/src/write/macho.rs b/vendor/object/src/write/macho.rs
new file mode 100644
index 0000000..1c61523
--- /dev/null
+++ b/vendor/object/src/write/macho.rs
@@ -0,0 +1,1095 @@
+use core::mem;
+
+use crate::endian::*;
+use crate::macho;
+use crate::write::string::*;
+use crate::write::util::*;
+use crate::write::*;
+use crate::AddressSize;
+
+#[derive(Default, Clone, Copy)]
+struct SectionOffsets {
+ index: usize,
+ offset: usize,
+ address: u64,
+ reloc_offset: usize,
+ reloc_count: usize,
+}
+
+#[derive(Default, Clone, Copy)]
+struct SymbolOffsets {
+ index: usize,
+ str_id: Option<StringId>,
+}
+
+/// The customizable portion of a [`macho::BuildVersionCommand`].
+#[derive(Debug, Default, Clone, Copy)]
+#[non_exhaustive] // May want to add the tool list?
+pub struct MachOBuildVersion {
+ /// One of the `PLATFORM_` constants (for example,
+ /// [`object::macho::PLATFORM_MACOS`](macho::PLATFORM_MACOS)).
+ pub platform: u32,
+ /// The minimum OS version, where `X.Y.Z` is encoded in nibbles as
+ /// `xxxx.yy.zz`.
+ pub minos: u32,
+ /// The SDK version as `X.Y.Z`, where `X.Y.Z` is encoded in nibbles as
+ /// `xxxx.yy.zz`.
+ pub sdk: u32,
+}
+
+impl MachOBuildVersion {
+ fn cmdsize(&self) -> u32 {
+ // Same size for both endianness, and we don't have `ntools`.
+ let sz = mem::size_of::<macho::BuildVersionCommand<Endianness>>();
+ debug_assert!(sz <= u32::MAX as usize);
+ sz as u32
+ }
+}
+
+// Public methods.
+impl<'a> Object<'a> {
+ /// Specify the Mach-O CPU subtype.
+ ///
+ /// Requires `feature = "macho"`.
+ #[inline]
+ pub fn set_macho_cpu_subtype(&mut self, cpu_subtype: u32) {
+ self.macho_cpu_subtype = Some(cpu_subtype);
+ }
+
+ /// Specify information for a Mach-O `LC_BUILD_VERSION` command.
+ ///
+ /// Requires `feature = "macho"`.
+ #[inline]
+ pub fn set_macho_build_version(&mut self, info: MachOBuildVersion) {
+ self.macho_build_version = Some(info);
+ }
+}
+
+// Private methods.
+impl<'a> Object<'a> {
+ pub(crate) fn macho_set_subsections_via_symbols(&mut self) {
+ let flags = match self.flags {
+ FileFlags::MachO { flags } => flags,
+ _ => 0,
+ };
+ self.flags = FileFlags::MachO {
+ flags: flags | macho::MH_SUBSECTIONS_VIA_SYMBOLS,
+ };
+ }
+
+ pub(crate) fn macho_segment_name(&self, segment: StandardSegment) -> &'static [u8] {
+ match segment {
+ StandardSegment::Text => &b"__TEXT"[..],
+ StandardSegment::Data => &b"__DATA"[..],
+ StandardSegment::Debug => &b"__DWARF"[..],
+ }
+ }
+
+ pub(crate) fn macho_section_info(
+ &self,
+ section: StandardSection,
+ ) -> (&'static [u8], &'static [u8], SectionKind, SectionFlags) {
+ match section {
+ StandardSection::Text => (
+ &b"__TEXT"[..],
+ &b"__text"[..],
+ SectionKind::Text,
+ SectionFlags::None,
+ ),
+ StandardSection::Data => (
+ &b"__DATA"[..],
+ &b"__data"[..],
+ SectionKind::Data,
+ SectionFlags::None,
+ ),
+ StandardSection::ReadOnlyData => (
+ &b"__TEXT"[..],
+ &b"__const"[..],
+ SectionKind::ReadOnlyData,
+ SectionFlags::None,
+ ),
+ StandardSection::ReadOnlyDataWithRel => (
+ &b"__DATA"[..],
+ &b"__const"[..],
+ SectionKind::ReadOnlyDataWithRel,
+ SectionFlags::None,
+ ),
+ StandardSection::ReadOnlyString => (
+ &b"__TEXT"[..],
+ &b"__cstring"[..],
+ SectionKind::ReadOnlyString,
+ SectionFlags::None,
+ ),
+ StandardSection::UninitializedData => (
+ &b"__DATA"[..],
+ &b"__bss"[..],
+ SectionKind::UninitializedData,
+ SectionFlags::None,
+ ),
+ StandardSection::Tls => (
+ &b"__DATA"[..],
+ &b"__thread_data"[..],
+ SectionKind::Tls,
+ SectionFlags::None,
+ ),
+ StandardSection::UninitializedTls => (
+ &b"__DATA"[..],
+ &b"__thread_bss"[..],
+ SectionKind::UninitializedTls,
+ SectionFlags::None,
+ ),
+ StandardSection::TlsVariables => (
+ &b"__DATA"[..],
+ &b"__thread_vars"[..],
+ SectionKind::TlsVariables,
+ SectionFlags::None,
+ ),
+ StandardSection::Common => (
+ &b"__DATA"[..],
+ &b"__common"[..],
+ SectionKind::Common,
+ SectionFlags::None,
+ ),
+ StandardSection::GnuProperty => {
+ // Unsupported section.
+ (&[], &[], SectionKind::Note, SectionFlags::None)
+ }
+ }
+ }
+
+ fn macho_tlv_bootstrap(&mut self) -> SymbolId {
+ match self.tlv_bootstrap {
+ Some(id) => id,
+ None => {
+ let id = self.add_symbol(Symbol {
+ name: b"_tlv_bootstrap".to_vec(),
+ value: 0,
+ size: 0,
+ kind: SymbolKind::Text,
+ scope: SymbolScope::Dynamic,
+ weak: false,
+ section: SymbolSection::Undefined,
+ flags: SymbolFlags::None,
+ });
+ self.tlv_bootstrap = Some(id);
+ id
+ }
+ }
+ }
+
+ /// Create the `__thread_vars` entry for a TLS variable.
+ ///
+ /// The symbol given by `symbol_id` will be updated to point to this entry.
+ ///
+ /// A new `SymbolId` will be returned. The caller must update this symbol
+ /// to point to the initializer.
+ ///
+ /// If `symbol_id` is not for a TLS variable, then it is returned unchanged.
+ pub(crate) fn macho_add_thread_var(&mut self, symbol_id: SymbolId) -> SymbolId {
+ let symbol = self.symbol_mut(symbol_id);
+ if symbol.kind != SymbolKind::Tls {
+ return symbol_id;
+ }
+
+ // Create the initializer symbol.
+ let mut name = symbol.name.clone();
+ name.extend_from_slice(b"$tlv$init");
+ let init_symbol_id = self.add_raw_symbol(Symbol {
+ name,
+ value: 0,
+ size: 0,
+ kind: SymbolKind::Tls,
+ scope: SymbolScope::Compilation,
+ weak: false,
+ section: SymbolSection::Undefined,
+ flags: SymbolFlags::None,
+ });
+
+ // Add the tlv entry.
+ // Three pointers in size:
+ // - __tlv_bootstrap - used to make sure support exists
+ // - spare pointer - used when mapped by the runtime
+ // - pointer to symbol initializer
+ let section = self.section_id(StandardSection::TlsVariables);
+ let address_size = self.architecture.address_size().unwrap().bytes();
+ let size = u64::from(address_size) * 3;
+ let data = vec![0; size as usize];
+ let offset = self.append_section_data(section, &data, u64::from(address_size));
+
+ let tlv_bootstrap = self.macho_tlv_bootstrap();
+ self.add_relocation(
+ section,
+ Relocation {
+ offset,
+ size: address_size * 8,
+ kind: RelocationKind::Absolute,
+ encoding: RelocationEncoding::Generic,
+ symbol: tlv_bootstrap,
+ addend: 0,
+ },
+ )
+ .unwrap();
+ self.add_relocation(
+ section,
+ Relocation {
+ offset: offset + u64::from(address_size) * 2,
+ size: address_size * 8,
+ kind: RelocationKind::Absolute,
+ encoding: RelocationEncoding::Generic,
+ symbol: init_symbol_id,
+ addend: 0,
+ },
+ )
+ .unwrap();
+
+ // Update the symbol to point to the tlv.
+ let symbol = self.symbol_mut(symbol_id);
+ symbol.value = offset;
+ symbol.size = size;
+ symbol.section = SymbolSection::Section(section);
+
+ init_symbol_id
+ }
+
+ pub(crate) fn macho_fixup_relocation(&mut self, relocation: &mut Relocation) -> i64 {
+ let relative = match relocation.kind {
+ RelocationKind::Relative
+ | RelocationKind::GotRelative
+ | RelocationKind::PltRelative
+ | RelocationKind::MachO { relative: true, .. } => true,
+ _ => false,
+ };
+ if relative {
+ // For PC relative relocations on some architectures, the
+ // addend does not include the offset required due to the
+ // PC being different from the place of the relocation.
+ // This differs from other file formats, so adjust the
+ // addend here to account for this.
+ let pcrel_offset = match self.architecture {
+ Architecture::I386 => 4,
+ Architecture::X86_64 => match relocation.kind {
+ RelocationKind::MachO {
+ value: macho::X86_64_RELOC_SIGNED_1,
+ ..
+ } => 5,
+ RelocationKind::MachO {
+ value: macho::X86_64_RELOC_SIGNED_2,
+ ..
+ } => 6,
+ RelocationKind::MachO {
+ value: macho::X86_64_RELOC_SIGNED_4,
+ ..
+ } => 8,
+ _ => 4,
+ },
+ // TODO: maybe missing support for some architectures and relocations
+ _ => 0,
+ };
+ relocation.addend += pcrel_offset;
+ }
+ // Aarch64 relocs of these sizes act as if they are double-word length
+ if self.architecture == Architecture::Aarch64 && matches!(relocation.size, 12 | 21 | 26) {
+ relocation.size = 32;
+ }
+ // Check for relocations that use an explicit addend.
+ if self.architecture == Architecture::Aarch64 {
+ if relocation.encoding == RelocationEncoding::AArch64Call {
+ return 0;
+ }
+ if let RelocationKind::MachO { value, .. } = relocation.kind {
+ match value {
+ macho::ARM64_RELOC_BRANCH26
+ | macho::ARM64_RELOC_PAGE21
+ | macho::ARM64_RELOC_PAGEOFF12 => return 0,
+ _ => {}
+ }
+ }
+ }
+ // Signify implicit addend.
+ let constant = relocation.addend;
+ relocation.addend = 0;
+ constant
+ }
+
+ pub(crate) fn macho_write(&self, buffer: &mut dyn WritableBuffer) -> Result<()> {
+ let address_size = self.architecture.address_size().unwrap();
+ let endian = self.endian;
+ let macho32 = MachO32 { endian };
+ let macho64 = MachO64 { endian };
+ let macho: &dyn MachO = match address_size {
+ AddressSize::U8 | AddressSize::U16 | AddressSize::U32 => &macho32,
+ AddressSize::U64 => &macho64,
+ };
+ let pointer_align = address_size.bytes() as usize;
+
+ // Calculate offsets of everything, and build strtab.
+ let mut offset = 0;
+
+ // Calculate size of Mach-O header.
+ offset += macho.mach_header_size();
+
+ // Calculate size of commands.
+ let mut ncmds = 0;
+ let command_offset = offset;
+
+ // Calculate size of segment command and section headers.
+ let segment_command_offset = offset;
+ let segment_command_len =
+ macho.segment_command_size() + self.sections.len() * macho.section_header_size();
+ offset += segment_command_len;
+ ncmds += 1;
+
+ // Calculate size of build version.
+ let build_version_offset = offset;
+ if let Some(version) = &self.macho_build_version {
+ offset += version.cmdsize() as usize;
+ ncmds += 1;
+ }
+
+ // Calculate size of symtab command.
+ let symtab_command_offset = offset;
+ let symtab_command_len = mem::size_of::<macho::SymtabCommand<Endianness>>();
+ offset += symtab_command_len;
+ ncmds += 1;
+
+ // Calculate size of dysymtab command.
+ let dysymtab_command_offset = offset;
+ let dysymtab_command_len = mem::size_of::<macho::DysymtabCommand<Endianness>>();
+ offset += dysymtab_command_len;
+ ncmds += 1;
+
+ let sizeofcmds = offset - command_offset;
+
+ // Calculate size of section data.
+ // Section data can immediately follow the load commands without any alignment padding.
+ let segment_file_offset = offset;
+ let mut section_offsets = vec![SectionOffsets::default(); self.sections.len()];
+ let mut address = 0;
+ for (index, section) in self.sections.iter().enumerate() {
+ section_offsets[index].index = 1 + index;
+ if !section.is_bss() {
+ address = align_u64(address, section.align);
+ section_offsets[index].address = address;
+ section_offsets[index].offset = segment_file_offset + address as usize;
+ address += section.size;
+ }
+ }
+ let segment_file_size = address as usize;
+ offset += address as usize;
+ for (index, section) in self.sections.iter().enumerate() {
+ if section.is_bss() {
+ debug_assert!(section.data.is_empty());
+ address = align_u64(address, section.align);
+ section_offsets[index].address = address;
+ address += section.size;
+ }
+ }
+
+ // Partition symbols and add symbol strings to strtab.
+ let mut strtab = StringTable::default();
+ let mut symbol_offsets = vec![SymbolOffsets::default(); self.symbols.len()];
+ let mut local_symbols = vec![];
+ let mut external_symbols = vec![];
+ let mut undefined_symbols = vec![];
+ for (index, symbol) in self.symbols.iter().enumerate() {
+ // The unified API allows creating symbols that we don't emit, so filter
+ // them out here.
+ //
+ // Since we don't actually emit the symbol kind, we validate it here too.
+ match symbol.kind {
+ SymbolKind::Text | SymbolKind::Data | SymbolKind::Tls | SymbolKind::Unknown => {}
+ SymbolKind::File | SymbolKind::Section => continue,
+ SymbolKind::Null | SymbolKind::Label => {
+ return Err(Error(format!(
+ "unimplemented symbol `{}` kind {:?}",
+ symbol.name().unwrap_or(""),
+ symbol.kind
+ )));
+ }
+ }
+ if !symbol.name.is_empty() {
+ symbol_offsets[index].str_id = Some(strtab.add(&symbol.name));
+ }
+ if symbol.is_undefined() {
+ undefined_symbols.push(index);
+ } else if symbol.is_local() {
+ local_symbols.push(index);
+ } else {
+ external_symbols.push(index);
+ }
+ }
+
+ external_symbols.sort_by_key(|index| &*self.symbols[*index].name);
+ undefined_symbols.sort_by_key(|index| &*self.symbols[*index].name);
+
+ // Count symbols.
+ let mut nsyms = 0;
+ for index in local_symbols
+ .iter()
+ .copied()
+ .chain(external_symbols.iter().copied())
+ .chain(undefined_symbols.iter().copied())
+ {
+ symbol_offsets[index].index = nsyms;
+ nsyms += 1;
+ }
+
+ // Calculate size of relocations.
+ for (index, section) in self.sections.iter().enumerate() {
+ let count: usize = section
+ .relocations
+ .iter()
+ .map(|reloc| 1 + usize::from(reloc.addend != 0))
+ .sum();
+ if count != 0 {
+ offset = align(offset, pointer_align);
+ section_offsets[index].reloc_offset = offset;
+ section_offsets[index].reloc_count = count;
+ let len = count * mem::size_of::<macho::Relocation<Endianness>>();
+ offset += len;
+ }
+ }
+
+ // Calculate size of symtab.
+ offset = align(offset, pointer_align);
+ let symtab_offset = offset;
+ let symtab_len = nsyms * macho.nlist_size();
+ offset += symtab_len;
+
+ // Calculate size of strtab.
+ let strtab_offset = offset;
+ // Start with null name.
+ let mut strtab_data = vec![0];
+ strtab.write(1, &mut strtab_data);
+ write_align(&mut strtab_data, pointer_align);
+ offset += strtab_data.len();
+
+ // Start writing.
+ buffer
+ .reserve(offset)
+ .map_err(|_| Error(String::from("Cannot allocate buffer")))?;
+
+ // Write file header.
+ let (cputype, mut cpusubtype) = match (self.architecture, self.sub_architecture) {
+ (Architecture::Arm, None) => (macho::CPU_TYPE_ARM, macho::CPU_SUBTYPE_ARM_ALL),
+ (Architecture::Aarch64, None) => (macho::CPU_TYPE_ARM64, macho::CPU_SUBTYPE_ARM64_ALL),
+ (Architecture::Aarch64, Some(SubArchitecture::Arm64E)) => {
+ (macho::CPU_TYPE_ARM64, macho::CPU_SUBTYPE_ARM64E)
+ }
+ (Architecture::Aarch64_Ilp32, None) => {
+ (macho::CPU_TYPE_ARM64_32, macho::CPU_SUBTYPE_ARM64_32_V8)
+ }
+ (Architecture::I386, None) => (macho::CPU_TYPE_X86, macho::CPU_SUBTYPE_I386_ALL),
+ (Architecture::X86_64, None) => (macho::CPU_TYPE_X86_64, macho::CPU_SUBTYPE_X86_64_ALL),
+ (Architecture::PowerPc, None) => {
+ (macho::CPU_TYPE_POWERPC, macho::CPU_SUBTYPE_POWERPC_ALL)
+ }
+ (Architecture::PowerPc64, None) => {
+ (macho::CPU_TYPE_POWERPC64, macho::CPU_SUBTYPE_POWERPC_ALL)
+ }
+ _ => {
+ return Err(Error(format!(
+ "unimplemented architecture {:?} with sub-architecture {:?}",
+ self.architecture, self.sub_architecture
+ )));
+ }
+ };
+
+ if let Some(cpu_subtype) = self.macho_cpu_subtype {
+ cpusubtype = cpu_subtype;
+ }
+
+ let flags = match self.flags {
+ FileFlags::MachO { flags } => flags,
+ _ => 0,
+ };
+ macho.write_mach_header(
+ buffer,
+ MachHeader {
+ cputype,
+ cpusubtype,
+ filetype: macho::MH_OBJECT,
+ ncmds,
+ sizeofcmds: sizeofcmds as u32,
+ flags,
+ },
+ );
+
+ // Write segment command.
+ debug_assert_eq!(segment_command_offset, buffer.len());
+ macho.write_segment_command(
+ buffer,
+ SegmentCommand {
+ cmdsize: segment_command_len as u32,
+ segname: [0; 16],
+ vmaddr: 0,
+ vmsize: address,
+ fileoff: segment_file_offset as u64,
+ filesize: segment_file_size as u64,
+ maxprot: macho::VM_PROT_READ | macho::VM_PROT_WRITE | macho::VM_PROT_EXECUTE,
+ initprot: macho::VM_PROT_READ | macho::VM_PROT_WRITE | macho::VM_PROT_EXECUTE,
+ nsects: self.sections.len() as u32,
+ flags: 0,
+ },
+ );
+
+ // Write section headers.
+ for (index, section) in self.sections.iter().enumerate() {
+ let mut sectname = [0; 16];
+ sectname
+ .get_mut(..section.name.len())
+ .ok_or_else(|| {
+ Error(format!(
+ "section name `{}` is too long",
+ section.name().unwrap_or(""),
+ ))
+ })?
+ .copy_from_slice(&section.name);
+ let mut segname = [0; 16];
+ segname
+ .get_mut(..section.segment.len())
+ .ok_or_else(|| {
+ Error(format!(
+ "segment name `{}` is too long",
+ section.segment().unwrap_or(""),
+ ))
+ })?
+ .copy_from_slice(&section.segment);
+ let flags = if let SectionFlags::MachO { flags } = section.flags {
+ flags
+ } else {
+ match section.kind {
+ SectionKind::Text => {
+ macho::S_ATTR_PURE_INSTRUCTIONS | macho::S_ATTR_SOME_INSTRUCTIONS
+ }
+ SectionKind::Data => 0,
+ SectionKind::ReadOnlyData | SectionKind::ReadOnlyDataWithRel => 0,
+ SectionKind::ReadOnlyString => macho::S_CSTRING_LITERALS,
+ SectionKind::UninitializedData | SectionKind::Common => macho::S_ZEROFILL,
+ SectionKind::Tls => macho::S_THREAD_LOCAL_REGULAR,
+ SectionKind::UninitializedTls => macho::S_THREAD_LOCAL_ZEROFILL,
+ SectionKind::TlsVariables => macho::S_THREAD_LOCAL_VARIABLES,
+ SectionKind::Debug => macho::S_ATTR_DEBUG,
+ SectionKind::OtherString => macho::S_CSTRING_LITERALS,
+ SectionKind::Other | SectionKind::Linker | SectionKind::Metadata => 0,
+ SectionKind::Note | SectionKind::Unknown | SectionKind::Elf(_) => {
+ return Err(Error(format!(
+ "unimplemented section `{}` kind {:?}",
+ section.name().unwrap_or(""),
+ section.kind
+ )));
+ }
+ }
+ };
+ macho.write_section(
+ buffer,
+ SectionHeader {
+ sectname,
+ segname,
+ addr: section_offsets[index].address,
+ size: section.size,
+ offset: section_offsets[index].offset as u32,
+ align: section.align.trailing_zeros(),
+ reloff: section_offsets[index].reloc_offset as u32,
+ nreloc: section_offsets[index].reloc_count as u32,
+ flags,
+ },
+ );
+ }
+
+ // Write build version.
+ if let Some(version) = &self.macho_build_version {
+ debug_assert_eq!(build_version_offset, buffer.len());
+ buffer.write(&macho::BuildVersionCommand {
+ cmd: U32::new(endian, macho::LC_BUILD_VERSION),
+ cmdsize: U32::new(endian, version.cmdsize()),
+ platform: U32::new(endian, version.platform),
+ minos: U32::new(endian, version.minos),
+ sdk: U32::new(endian, version.sdk),
+ ntools: U32::new(endian, 0),
+ });
+ }
+
+ // Write symtab command.
+ debug_assert_eq!(symtab_command_offset, buffer.len());
+ let symtab_command = macho::SymtabCommand {
+ cmd: U32::new(endian, macho::LC_SYMTAB),
+ cmdsize: U32::new(endian, symtab_command_len as u32),
+ symoff: U32::new(endian, symtab_offset as u32),
+ nsyms: U32::new(endian, nsyms as u32),
+ stroff: U32::new(endian, strtab_offset as u32),
+ strsize: U32::new(endian, strtab_data.len() as u32),
+ };
+ buffer.write(&symtab_command);
+
+ // Write dysymtab command.
+ debug_assert_eq!(dysymtab_command_offset, buffer.len());
+ let dysymtab_command = macho::DysymtabCommand {
+ cmd: U32::new(endian, macho::LC_DYSYMTAB),
+ cmdsize: U32::new(endian, dysymtab_command_len as u32),
+ ilocalsym: U32::new(endian, 0),
+ nlocalsym: U32::new(endian, local_symbols.len() as u32),
+ iextdefsym: U32::new(endian, local_symbols.len() as u32),
+ nextdefsym: U32::new(endian, external_symbols.len() as u32),
+ iundefsym: U32::new(
+ endian,
+ local_symbols.len() as u32 + external_symbols.len() as u32,
+ ),
+ nundefsym: U32::new(endian, undefined_symbols.len() as u32),
+ tocoff: U32::default(),
+ ntoc: U32::default(),
+ modtaboff: U32::default(),
+ nmodtab: U32::default(),
+ extrefsymoff: U32::default(),
+ nextrefsyms: U32::default(),
+ indirectsymoff: U32::default(),
+ nindirectsyms: U32::default(),
+ extreloff: U32::default(),
+ nextrel: U32::default(),
+ locreloff: U32::default(),
+ nlocrel: U32::default(),
+ };
+ buffer.write(&dysymtab_command);
+
+ // Write section data.
+ for (index, section) in self.sections.iter().enumerate() {
+ if !section.is_bss() {
+ buffer.resize(section_offsets[index].offset);
+ buffer.write_bytes(&section.data);
+ }
+ }
+ debug_assert_eq!(segment_file_offset + segment_file_size, buffer.len());
+
+ // Write relocations.
+ for (index, section) in self.sections.iter().enumerate() {
+ if !section.relocations.is_empty() {
+ write_align(buffer, pointer_align);
+ debug_assert_eq!(section_offsets[index].reloc_offset, buffer.len());
+ for reloc in &section.relocations {
+ let r_length = match reloc.size {
+ 8 => 0,
+ 16 => 1,
+ 32 => 2,
+ 64 => 3,
+ _ => return Err(Error(format!("unimplemented reloc size {:?}", reloc))),
+ };
+
+ // Write explicit addend.
+ if reloc.addend != 0 {
+ let r_type = match self.architecture {
+ Architecture::Aarch64 | Architecture::Aarch64_Ilp32 => {
+ macho::ARM64_RELOC_ADDEND
+ }
+ _ => {
+ return Err(Error(format!("unimplemented relocation {:?}", reloc)))
+ }
+ };
+
+ let reloc_info = macho::RelocationInfo {
+ r_address: reloc.offset as u32,
+ r_symbolnum: reloc.addend as u32,
+ r_pcrel: false,
+ r_length,
+ r_extern: false,
+ r_type,
+ };
+ buffer.write(&reloc_info.relocation(endian));
+ }
+
+ let r_extern;
+ let r_symbolnum;
+ let symbol = &self.symbols[reloc.symbol.0];
+ if symbol.kind == SymbolKind::Section {
+ r_symbolnum = section_offsets[symbol.section.id().unwrap().0].index as u32;
+ r_extern = false;
+ } else {
+ r_symbolnum = symbol_offsets[reloc.symbol.0].index as u32;
+ r_extern = true;
+ }
+ let (r_pcrel, r_type) = match self.architecture {
+ Architecture::I386 => match reloc.kind {
+ RelocationKind::Absolute => (false, macho::GENERIC_RELOC_VANILLA),
+ _ => {
+ return Err(Error(format!("unimplemented relocation {:?}", reloc)));
+ }
+ },
+ Architecture::X86_64 => match (reloc.kind, reloc.encoding) {
+ (RelocationKind::Absolute, RelocationEncoding::Generic) => {
+ (false, macho::X86_64_RELOC_UNSIGNED)
+ }
+ (RelocationKind::Relative, RelocationEncoding::Generic) => {
+ (true, macho::X86_64_RELOC_SIGNED)
+ }
+ (RelocationKind::Relative, RelocationEncoding::X86RipRelative) => {
+ (true, macho::X86_64_RELOC_SIGNED)
+ }
+ (RelocationKind::Relative, RelocationEncoding::X86Branch) => {
+ (true, macho::X86_64_RELOC_BRANCH)
+ }
+ (RelocationKind::PltRelative, RelocationEncoding::X86Branch) => {
+ (true, macho::X86_64_RELOC_BRANCH)
+ }
+ (RelocationKind::GotRelative, RelocationEncoding::Generic) => {
+ (true, macho::X86_64_RELOC_GOT)
+ }
+ (
+ RelocationKind::GotRelative,
+ RelocationEncoding::X86RipRelativeMovq,
+ ) => (true, macho::X86_64_RELOC_GOT_LOAD),
+ (RelocationKind::MachO { value, relative }, _) => (relative, value),
+ _ => {
+ return Err(Error(format!("unimplemented relocation {:?}", reloc)));
+ }
+ },
+ Architecture::Aarch64 | Architecture::Aarch64_Ilp32 => {
+ match (reloc.kind, reloc.encoding) {
+ (RelocationKind::Absolute, RelocationEncoding::Generic) => {
+ (false, macho::ARM64_RELOC_UNSIGNED)
+ }
+ (RelocationKind::Relative, RelocationEncoding::AArch64Call) => {
+ (true, macho::ARM64_RELOC_BRANCH26)
+ }
+ (
+ RelocationKind::MachO { value, relative },
+ RelocationEncoding::Generic,
+ ) => (relative, value),
+ _ => {
+ return Err(Error(format!(
+ "unimplemented relocation {:?}",
+ reloc
+ )));
+ }
+ }
+ }
+ _ => {
+ if let RelocationKind::MachO { value, relative } = reloc.kind {
+ (relative, value)
+ } else {
+ return Err(Error(format!("unimplemented relocation {:?}", reloc)));
+ }
+ }
+ };
+ let reloc_info = macho::RelocationInfo {
+ r_address: reloc.offset as u32,
+ r_symbolnum,
+ r_pcrel,
+ r_length,
+ r_extern,
+ r_type,
+ };
+ buffer.write(&reloc_info.relocation(endian));
+ }
+ }
+ }
+
+ // Write symtab.
+ write_align(buffer, pointer_align);
+ debug_assert_eq!(symtab_offset, buffer.len());
+ for index in local_symbols
+ .iter()
+ .copied()
+ .chain(external_symbols.iter().copied())
+ .chain(undefined_symbols.iter().copied())
+ {
+ let symbol = &self.symbols[index];
+ // TODO: N_STAB
+ let (mut n_type, n_sect) = match symbol.section {
+ SymbolSection::Undefined => (macho::N_UNDF | macho::N_EXT, 0),
+ SymbolSection::Absolute => (macho::N_ABS, 0),
+ SymbolSection::Section(id) => (macho::N_SECT, id.0 + 1),
+ SymbolSection::None | SymbolSection::Common => {
+ return Err(Error(format!(
+ "unimplemented symbol `{}` section {:?}",
+ symbol.name().unwrap_or(""),
+ symbol.section
+ )));
+ }
+ };
+ match symbol.scope {
+ SymbolScope::Unknown | SymbolScope::Compilation => {}
+ SymbolScope::Linkage => {
+ n_type |= macho::N_EXT | macho::N_PEXT;
+ }
+ SymbolScope::Dynamic => {
+ n_type |= macho::N_EXT;
+ }
+ }
+
+ let n_desc = if let SymbolFlags::MachO { n_desc } = symbol.flags {
+ n_desc
+ } else {
+ let mut n_desc = 0;
+ if symbol.weak {
+ if symbol.is_undefined() {
+ n_desc |= macho::N_WEAK_REF;
+ } else {
+ n_desc |= macho::N_WEAK_DEF;
+ }
+ }
+ n_desc
+ };
+
+ let n_value = match symbol.section.id() {
+ Some(section) => section_offsets[section.0].address + symbol.value,
+ None => symbol.value,
+ };
+
+ let n_strx = symbol_offsets[index]
+ .str_id
+ .map(|id| strtab.get_offset(id))
+ .unwrap_or(0);
+
+ macho.write_nlist(
+ buffer,
+ Nlist {
+ n_strx: n_strx as u32,
+ n_type,
+ n_sect: n_sect as u8,
+ n_desc,
+ n_value,
+ },
+ );
+ }
+
+ // Write strtab.
+ debug_assert_eq!(strtab_offset, buffer.len());
+ buffer.write_bytes(&strtab_data);
+
+ debug_assert_eq!(offset, buffer.len());
+
+ Ok(())
+ }
+}
+
+struct MachHeader {
+ cputype: u32,
+ cpusubtype: u32,
+ filetype: u32,
+ ncmds: u32,
+ sizeofcmds: u32,
+ flags: u32,
+}
+
+struct SegmentCommand {
+ cmdsize: u32,
+ segname: [u8; 16],
+ vmaddr: u64,
+ vmsize: u64,
+ fileoff: u64,
+ filesize: u64,
+ maxprot: u32,
+ initprot: u32,
+ nsects: u32,
+ flags: u32,
+}
+
+pub struct SectionHeader {
+ sectname: [u8; 16],
+ segname: [u8; 16],
+ addr: u64,
+ size: u64,
+ offset: u32,
+ align: u32,
+ reloff: u32,
+ nreloc: u32,
+ flags: u32,
+}
+
+struct Nlist {
+ n_strx: u32,
+ n_type: u8,
+ n_sect: u8,
+ n_desc: u16,
+ n_value: u64,
+}
+
+trait MachO {
+ fn mach_header_size(&self) -> usize;
+ fn segment_command_size(&self) -> usize;
+ fn section_header_size(&self) -> usize;
+ fn nlist_size(&self) -> usize;
+ fn write_mach_header(&self, buffer: &mut dyn WritableBuffer, section: MachHeader);
+ fn write_segment_command(&self, buffer: &mut dyn WritableBuffer, segment: SegmentCommand);
+ fn write_section(&self, buffer: &mut dyn WritableBuffer, section: SectionHeader);
+ fn write_nlist(&self, buffer: &mut dyn WritableBuffer, nlist: Nlist);
+}
+
+struct MachO32<E> {
+ endian: E,
+}
+
+impl<E: Endian> MachO for MachO32<E> {
+ fn mach_header_size(&self) -> usize {
+ mem::size_of::<macho::MachHeader32<E>>()
+ }
+
+ fn segment_command_size(&self) -> usize {
+ mem::size_of::<macho::SegmentCommand32<E>>()
+ }
+
+ fn section_header_size(&self) -> usize {
+ mem::size_of::<macho::Section32<E>>()
+ }
+
+ fn nlist_size(&self) -> usize {
+ mem::size_of::<macho::Nlist32<E>>()
+ }
+
+ fn write_mach_header(&self, buffer: &mut dyn WritableBuffer, header: MachHeader) {
+ let endian = self.endian;
+ let magic = if endian.is_big_endian() {
+ macho::MH_MAGIC
+ } else {
+ macho::MH_CIGAM
+ };
+ let header = macho::MachHeader32 {
+ magic: U32::new(BigEndian, magic),
+ cputype: U32::new(endian, header.cputype),
+ cpusubtype: U32::new(endian, header.cpusubtype),
+ filetype: U32::new(endian, header.filetype),
+ ncmds: U32::new(endian, header.ncmds),
+ sizeofcmds: U32::new(endian, header.sizeofcmds),
+ flags: U32::new(endian, header.flags),
+ };
+ buffer.write(&header);
+ }
+
+ fn write_segment_command(&self, buffer: &mut dyn WritableBuffer, segment: SegmentCommand) {
+ let endian = self.endian;
+ let segment = macho::SegmentCommand32 {
+ cmd: U32::new(endian, macho::LC_SEGMENT),
+ cmdsize: U32::new(endian, segment.cmdsize),
+ segname: segment.segname,
+ vmaddr: U32::new(endian, segment.vmaddr as u32),
+ vmsize: U32::new(endian, segment.vmsize as u32),
+ fileoff: U32::new(endian, segment.fileoff as u32),
+ filesize: U32::new(endian, segment.filesize as u32),
+ maxprot: U32::new(endian, segment.maxprot),
+ initprot: U32::new(endian, segment.initprot),
+ nsects: U32::new(endian, segment.nsects),
+ flags: U32::new(endian, segment.flags),
+ };
+ buffer.write(&segment);
+ }
+
+ fn write_section(&self, buffer: &mut dyn WritableBuffer, section: SectionHeader) {
+ let endian = self.endian;
+ let section = macho::Section32 {
+ sectname: section.sectname,
+ segname: section.segname,
+ addr: U32::new(endian, section.addr as u32),
+ size: U32::new(endian, section.size as u32),
+ offset: U32::new(endian, section.offset),
+ align: U32::new(endian, section.align),
+ reloff: U32::new(endian, section.reloff),
+ nreloc: U32::new(endian, section.nreloc),
+ flags: U32::new(endian, section.flags),
+ reserved1: U32::default(),
+ reserved2: U32::default(),
+ };
+ buffer.write(&section);
+ }
+
+ fn write_nlist(&self, buffer: &mut dyn WritableBuffer, nlist: Nlist) {
+ let endian = self.endian;
+ let nlist = macho::Nlist32 {
+ n_strx: U32::new(endian, nlist.n_strx),
+ n_type: nlist.n_type,
+ n_sect: nlist.n_sect,
+ n_desc: U16::new(endian, nlist.n_desc),
+ n_value: U32::new(endian, nlist.n_value as u32),
+ };
+ buffer.write(&nlist);
+ }
+}
+
+struct MachO64<E> {
+ endian: E,
+}
+
+impl<E: Endian> MachO for MachO64<E> {
+ fn mach_header_size(&self) -> usize {
+ mem::size_of::<macho::MachHeader64<E>>()
+ }
+
+ fn segment_command_size(&self) -> usize {
+ mem::size_of::<macho::SegmentCommand64<E>>()
+ }
+
+ fn section_header_size(&self) -> usize {
+ mem::size_of::<macho::Section64<E>>()
+ }
+
+ fn nlist_size(&self) -> usize {
+ mem::size_of::<macho::Nlist64<E>>()
+ }
+
+ fn write_mach_header(&self, buffer: &mut dyn WritableBuffer, header: MachHeader) {
+ let endian = self.endian;
+ let magic = if endian.is_big_endian() {
+ macho::MH_MAGIC_64
+ } else {
+ macho::MH_CIGAM_64
+ };
+ let header = macho::MachHeader64 {
+ magic: U32::new(BigEndian, magic),
+ cputype: U32::new(endian, header.cputype),
+ cpusubtype: U32::new(endian, header.cpusubtype),
+ filetype: U32::new(endian, header.filetype),
+ ncmds: U32::new(endian, header.ncmds),
+ sizeofcmds: U32::new(endian, header.sizeofcmds),
+ flags: U32::new(endian, header.flags),
+ reserved: U32::default(),
+ };
+ buffer.write(&header);
+ }
+
+ fn write_segment_command(&self, buffer: &mut dyn WritableBuffer, segment: SegmentCommand) {
+ let endian = self.endian;
+ let segment = macho::SegmentCommand64 {
+ cmd: U32::new(endian, macho::LC_SEGMENT_64),
+ cmdsize: U32::new(endian, segment.cmdsize),
+ segname: segment.segname,
+ vmaddr: U64::new(endian, segment.vmaddr),
+ vmsize: U64::new(endian, segment.vmsize),
+ fileoff: U64::new(endian, segment.fileoff),
+ filesize: U64::new(endian, segment.filesize),
+ maxprot: U32::new(endian, segment.maxprot),
+ initprot: U32::new(endian, segment.initprot),
+ nsects: U32::new(endian, segment.nsects),
+ flags: U32::new(endian, segment.flags),
+ };
+ buffer.write(&segment);
+ }
+
+ fn write_section(&self, buffer: &mut dyn WritableBuffer, section: SectionHeader) {
+ let endian = self.endian;
+ let section = macho::Section64 {
+ sectname: section.sectname,
+ segname: section.segname,
+ addr: U64::new(endian, section.addr),
+ size: U64::new(endian, section.size),
+ offset: U32::new(endian, section.offset),
+ align: U32::new(endian, section.align),
+ reloff: U32::new(endian, section.reloff),
+ nreloc: U32::new(endian, section.nreloc),
+ flags: U32::new(endian, section.flags),
+ reserved1: U32::default(),
+ reserved2: U32::default(),
+ reserved3: U32::default(),
+ };
+ buffer.write(&section);
+ }
+
+ fn write_nlist(&self, buffer: &mut dyn WritableBuffer, nlist: Nlist) {
+ let endian = self.endian;
+ let nlist = macho::Nlist64 {
+ n_strx: U32::new(endian, nlist.n_strx),
+ n_type: nlist.n_type,
+ n_sect: nlist.n_sect,
+ n_desc: U16::new(endian, nlist.n_desc),
+ n_value: U64Bytes::new(endian, nlist.n_value),
+ };
+ buffer.write(&nlist);
+ }
+}
diff --git a/vendor/object/src/write/mod.rs b/vendor/object/src/write/mod.rs
new file mode 100644
index 0000000..cea4d2e
--- /dev/null
+++ b/vendor/object/src/write/mod.rs
@@ -0,0 +1,961 @@
+//! Interface for writing object files.
+
+use alloc::borrow::Cow;
+use alloc::string::String;
+use alloc::vec::Vec;
+use core::{fmt, result, str};
+#[cfg(not(feature = "std"))]
+use hashbrown::HashMap;
+#[cfg(feature = "std")]
+use std::{boxed::Box, collections::HashMap, error, io};
+
+use crate::endian::{Endianness, U32, U64};
+use crate::{
+ Architecture, BinaryFormat, ComdatKind, FileFlags, RelocationEncoding, RelocationKind,
+ SectionFlags, SectionKind, SubArchitecture, SymbolFlags, SymbolKind, SymbolScope,
+};
+
+#[cfg(feature = "coff")]
+pub mod coff;
+#[cfg(feature = "coff")]
+pub use coff::CoffExportStyle;
+
+#[cfg(feature = "elf")]
+pub mod elf;
+
+#[cfg(feature = "macho")]
+mod macho;
+#[cfg(feature = "macho")]
+pub use macho::MachOBuildVersion;
+
+#[cfg(feature = "pe")]
+pub mod pe;
+
+#[cfg(feature = "xcoff")]
+mod xcoff;
+
+mod string;
+pub use string::StringId;
+
+mod util;
+pub use util::*;
+
+/// The error type used within the write module.
+#[derive(Debug, Clone, PartialEq, Eq)]
+pub struct Error(String);
+
+impl fmt::Display for Error {
+ #[inline]
+ fn fmt(&self, f: &mut fmt::Formatter<'_>) -> fmt::Result {
+ f.write_str(&self.0)
+ }
+}
+
+#[cfg(feature = "std")]
+impl error::Error for Error {}
+
+/// The result type used within the write module.
+pub type Result<T> = result::Result<T, Error>;
+
+/// A writable relocatable object file.
+#[derive(Debug)]
+pub struct Object<'a> {
+ format: BinaryFormat,
+ architecture: Architecture,
+ sub_architecture: Option<SubArchitecture>,
+ endian: Endianness,
+ sections: Vec<Section<'a>>,
+ standard_sections: HashMap<StandardSection, SectionId>,
+ symbols: Vec<Symbol>,
+ symbol_map: HashMap<Vec<u8>, SymbolId>,
+ stub_symbols: HashMap<SymbolId, SymbolId>,
+ comdats: Vec<Comdat>,
+ /// File flags that are specific to each file format.
+ pub flags: FileFlags,
+ /// The symbol name mangling scheme.
+ pub mangling: Mangling,
+ /// Mach-O "_tlv_bootstrap" symbol.
+ tlv_bootstrap: Option<SymbolId>,
+ /// Mach-O CPU subtype.
+ #[cfg(feature = "macho")]
+ macho_cpu_subtype: Option<u32>,
+ #[cfg(feature = "macho")]
+ macho_build_version: Option<MachOBuildVersion>,
+}
+
+impl<'a> Object<'a> {
+ /// Create an empty object file.
+ pub fn new(format: BinaryFormat, architecture: Architecture, endian: Endianness) -> Object<'a> {
+ Object {
+ format,
+ architecture,
+ sub_architecture: None,
+ endian,
+ sections: Vec::new(),
+ standard_sections: HashMap::new(),
+ symbols: Vec::new(),
+ symbol_map: HashMap::new(),
+ stub_symbols: HashMap::new(),
+ comdats: Vec::new(),
+ flags: FileFlags::None,
+ mangling: Mangling::default(format, architecture),
+ tlv_bootstrap: None,
+ #[cfg(feature = "macho")]
+ macho_cpu_subtype: None,
+ #[cfg(feature = "macho")]
+ macho_build_version: None,
+ }
+ }
+
+ /// Return the file format.
+ #[inline]
+ pub fn format(&self) -> BinaryFormat {
+ self.format
+ }
+
+ /// Return the architecture.
+ #[inline]
+ pub fn architecture(&self) -> Architecture {
+ self.architecture
+ }
+
+ /// Return the sub-architecture.
+ #[inline]
+ pub fn sub_architecture(&self) -> Option<SubArchitecture> {
+ self.sub_architecture
+ }
+
+ /// Specify the sub-architecture.
+ pub fn set_sub_architecture(&mut self, sub_architecture: Option<SubArchitecture>) {
+ self.sub_architecture = sub_architecture;
+ }
+
+ /// Return the current mangling setting.
+ #[inline]
+ pub fn mangling(&self) -> Mangling {
+ self.mangling
+ }
+
+ /// Specify the mangling setting.
+ #[inline]
+ pub fn set_mangling(&mut self, mangling: Mangling) {
+ self.mangling = mangling;
+ }
+
+ /// Return the name for a standard segment.
+ ///
+ /// This will vary based on the file format.
+ #[allow(unused_variables)]
+ pub fn segment_name(&self, segment: StandardSegment) -> &'static [u8] {
+ match self.format {
+ #[cfg(feature = "coff")]
+ BinaryFormat::Coff => &[],
+ #[cfg(feature = "elf")]
+ BinaryFormat::Elf => &[],
+ #[cfg(feature = "macho")]
+ BinaryFormat::MachO => self.macho_segment_name(segment),
+ _ => unimplemented!(),
+ }
+ }
+
+ /// Get the section with the given `SectionId`.
+ #[inline]
+ pub fn section(&self, section: SectionId) -> &Section<'a> {
+ &self.sections[section.0]
+ }
+
+ /// Mutably get the section with the given `SectionId`.
+ #[inline]
+ pub fn section_mut(&mut self, section: SectionId) -> &mut Section<'a> {
+ &mut self.sections[section.0]
+ }
+
+ /// Set the data for an existing section.
+ ///
+ /// Must not be called for sections that already have data, or that contain uninitialized data.
+ pub fn set_section_data<T>(&mut self, section: SectionId, data: T, align: u64)
+ where
+ T: Into<Cow<'a, [u8]>>,
+ {
+ self.sections[section.0].set_data(data, align)
+ }
+
+ /// Append data to an existing section. Returns the section offset of the data.
+ pub fn append_section_data(&mut self, section: SectionId, data: &[u8], align: u64) -> u64 {
+ self.sections[section.0].append_data(data, align)
+ }
+
+ /// Append zero-initialized data to an existing section. Returns the section offset of the data.
+ pub fn append_section_bss(&mut self, section: SectionId, size: u64, align: u64) -> u64 {
+ self.sections[section.0].append_bss(size, align)
+ }
+
+ /// Return the `SectionId` of a standard section.
+ ///
+ /// If the section doesn't already exist then it is created.
+ pub fn section_id(&mut self, section: StandardSection) -> SectionId {
+ self.standard_sections
+ .get(&section)
+ .cloned()
+ .unwrap_or_else(|| {
+ let (segment, name, kind, flags) = self.section_info(section);
+ let id = self.add_section(segment.to_vec(), name.to_vec(), kind);
+ self.section_mut(id).flags = flags;
+ id
+ })
+ }
+
+ /// Add a new section and return its `SectionId`.
+ ///
+ /// This also creates a section symbol.
+ pub fn add_section(&mut self, segment: Vec<u8>, name: Vec<u8>, kind: SectionKind) -> SectionId {
+ let id = SectionId(self.sections.len());
+ self.sections.push(Section {
+ segment,
+ name,
+ kind,
+ size: 0,
+ align: 1,
+ data: Cow::Borrowed(&[]),
+ relocations: Vec::new(),
+ symbol: None,
+ flags: SectionFlags::None,
+ });
+
+ // Add to self.standard_sections if required. This may match multiple standard sections.
+ let section = &self.sections[id.0];
+ for standard_section in StandardSection::all() {
+ if !self.standard_sections.contains_key(standard_section) {
+ let (segment, name, kind, _flags) = self.section_info(*standard_section);
+ if segment == &*section.segment && name == &*section.name && kind == section.kind {
+ self.standard_sections.insert(*standard_section, id);
+ }
+ }
+ }
+
+ id
+ }
+
+ fn section_info(
+ &self,
+ section: StandardSection,
+ ) -> (&'static [u8], &'static [u8], SectionKind, SectionFlags) {
+ match self.format {
+ #[cfg(feature = "coff")]
+ BinaryFormat::Coff => self.coff_section_info(section),
+ #[cfg(feature = "elf")]
+ BinaryFormat::Elf => self.elf_section_info(section),
+ #[cfg(feature = "macho")]
+ BinaryFormat::MachO => self.macho_section_info(section),
+ #[cfg(feature = "xcoff")]
+ BinaryFormat::Xcoff => self.xcoff_section_info(section),
+ _ => unimplemented!(),
+ }
+ }
+
+ /// Add a subsection. Returns the `SectionId` and section offset of the data.
+ pub fn add_subsection(
+ &mut self,
+ section: StandardSection,
+ name: &[u8],
+ data: &[u8],
+ align: u64,
+ ) -> (SectionId, u64) {
+ let section_id = if self.has_subsections_via_symbols() {
+ self.set_subsections_via_symbols();
+ self.section_id(section)
+ } else {
+ let (segment, name, kind, flags) = self.subsection_info(section, name);
+ let id = self.add_section(segment.to_vec(), name, kind);
+ self.section_mut(id).flags = flags;
+ id
+ };
+ let offset = self.append_section_data(section_id, data, align);
+ (section_id, offset)
+ }
+
+ fn has_subsections_via_symbols(&self) -> bool {
+ match self.format {
+ BinaryFormat::Coff | BinaryFormat::Elf | BinaryFormat::Xcoff => false,
+ BinaryFormat::MachO => true,
+ _ => unimplemented!(),
+ }
+ }
+
+ fn set_subsections_via_symbols(&mut self) {
+ match self.format {
+ #[cfg(feature = "macho")]
+ BinaryFormat::MachO => self.macho_set_subsections_via_symbols(),
+ _ => unimplemented!(),
+ }
+ }
+
+ fn subsection_info(
+ &self,
+ section: StandardSection,
+ value: &[u8],
+ ) -> (&'static [u8], Vec<u8>, SectionKind, SectionFlags) {
+ let (segment, section, kind, flags) = self.section_info(section);
+ let name = self.subsection_name(section, value);
+ (segment, name, kind, flags)
+ }
+
+ #[allow(unused_variables)]
+ fn subsection_name(&self, section: &[u8], value: &[u8]) -> Vec<u8> {
+ debug_assert!(!self.has_subsections_via_symbols());
+ match self.format {
+ #[cfg(feature = "coff")]
+ BinaryFormat::Coff => self.coff_subsection_name(section, value),
+ #[cfg(feature = "elf")]
+ BinaryFormat::Elf => self.elf_subsection_name(section, value),
+ _ => unimplemented!(),
+ }
+ }
+
+ /// Get the COMDAT section group with the given `ComdatId`.
+ #[inline]
+ pub fn comdat(&self, comdat: ComdatId) -> &Comdat {
+ &self.comdats[comdat.0]
+ }
+
+ /// Mutably get the COMDAT section group with the given `ComdatId`.
+ #[inline]
+ pub fn comdat_mut(&mut self, comdat: ComdatId) -> &mut Comdat {
+ &mut self.comdats[comdat.0]
+ }
+
+ /// Add a new COMDAT section group and return its `ComdatId`.
+ pub fn add_comdat(&mut self, comdat: Comdat) -> ComdatId {
+ let comdat_id = ComdatId(self.comdats.len());
+ self.comdats.push(comdat);
+ comdat_id
+ }
+
+ /// Get the `SymbolId` of the symbol with the given name.
+ pub fn symbol_id(&self, name: &[u8]) -> Option<SymbolId> {
+ self.symbol_map.get(name).cloned()
+ }
+
+ /// Get the symbol with the given `SymbolId`.
+ #[inline]
+ pub fn symbol(&self, symbol: SymbolId) -> &Symbol {
+ &self.symbols[symbol.0]
+ }
+
+ /// Mutably get the symbol with the given `SymbolId`.
+ #[inline]
+ pub fn symbol_mut(&mut self, symbol: SymbolId) -> &mut Symbol {
+ &mut self.symbols[symbol.0]
+ }
+
+ /// Add a new symbol and return its `SymbolId`.
+ pub fn add_symbol(&mut self, mut symbol: Symbol) -> SymbolId {
+ // Defined symbols must have a scope.
+ debug_assert!(symbol.is_undefined() || symbol.scope != SymbolScope::Unknown);
+ if symbol.kind == SymbolKind::Section {
+ // There can only be one section symbol, but update its flags, since
+ // the automatically generated section symbol will have none.
+ let symbol_id = self.section_symbol(symbol.section.id().unwrap());
+ if symbol.flags != SymbolFlags::None {
+ self.symbol_mut(symbol_id).flags = symbol.flags;
+ }
+ return symbol_id;
+ }
+ if !symbol.name.is_empty()
+ && (symbol.kind == SymbolKind::Text
+ || symbol.kind == SymbolKind::Data
+ || symbol.kind == SymbolKind::Tls)
+ {
+ let unmangled_name = symbol.name.clone();
+ if let Some(prefix) = self.mangling.global_prefix() {
+ symbol.name.insert(0, prefix);
+ }
+ let symbol_id = self.add_raw_symbol(symbol);
+ self.symbol_map.insert(unmangled_name, symbol_id);
+ symbol_id
+ } else {
+ self.add_raw_symbol(symbol)
+ }
+ }
+
+ fn add_raw_symbol(&mut self, symbol: Symbol) -> SymbolId {
+ let symbol_id = SymbolId(self.symbols.len());
+ self.symbols.push(symbol);
+ symbol_id
+ }
+
+ /// Return true if the file format supports `StandardSection::UninitializedTls`.
+ #[inline]
+ pub fn has_uninitialized_tls(&self) -> bool {
+ self.format != BinaryFormat::Coff
+ }
+
+ /// Return true if the file format supports `StandardSection::Common`.
+ #[inline]
+ pub fn has_common(&self) -> bool {
+ self.format == BinaryFormat::MachO
+ }
+
+ /// Add a new common symbol and return its `SymbolId`.
+ ///
+ /// For Mach-O, this appends the symbol to the `__common` section.
+ pub fn add_common_symbol(&mut self, mut symbol: Symbol, size: u64, align: u64) -> SymbolId {
+ if self.has_common() {
+ let symbol_id = self.add_symbol(symbol);
+ let section = self.section_id(StandardSection::Common);
+ self.add_symbol_bss(symbol_id, section, size, align);
+ symbol_id
+ } else {
+ symbol.section = SymbolSection::Common;
+ symbol.size = size;
+ self.add_symbol(symbol)
+ }
+ }
+
+ /// Add a new file symbol and return its `SymbolId`.
+ pub fn add_file_symbol(&mut self, name: Vec<u8>) -> SymbolId {
+ self.add_raw_symbol(Symbol {
+ name,
+ value: 0,
+ size: 0,
+ kind: SymbolKind::File,
+ scope: SymbolScope::Compilation,
+ weak: false,
+ section: SymbolSection::None,
+ flags: SymbolFlags::None,
+ })
+ }
+
+ /// Get the symbol for a section.
+ pub fn section_symbol(&mut self, section_id: SectionId) -> SymbolId {
+ let section = &mut self.sections[section_id.0];
+ if let Some(symbol) = section.symbol {
+ return symbol;
+ }
+ let name = if self.format == BinaryFormat::Coff {
+ section.name.clone()
+ } else {
+ Vec::new()
+ };
+ let symbol_id = SymbolId(self.symbols.len());
+ self.symbols.push(Symbol {
+ name,
+ value: 0,
+ size: 0,
+ kind: SymbolKind::Section,
+ scope: SymbolScope::Compilation,
+ weak: false,
+ section: SymbolSection::Section(section_id),
+ flags: SymbolFlags::None,
+ });
+ section.symbol = Some(symbol_id);
+ symbol_id
+ }
+
+ /// Append data to an existing section, and update a symbol to refer to it.
+ ///
+ /// For Mach-O, this also creates a `__thread_vars` entry for TLS symbols, and the
+ /// symbol will indirectly point to the added data via the `__thread_vars` entry.
+ ///
+ /// Returns the section offset of the data.
+ pub fn add_symbol_data(
+ &mut self,
+ symbol_id: SymbolId,
+ section: SectionId,
+ data: &[u8],
+ align: u64,
+ ) -> u64 {
+ let offset = self.append_section_data(section, data, align);
+ self.set_symbol_data(symbol_id, section, offset, data.len() as u64);
+ offset
+ }
+
+ /// Append zero-initialized data to an existing section, and update a symbol to refer to it.
+ ///
+ /// For Mach-O, this also creates a `__thread_vars` entry for TLS symbols, and the
+ /// symbol will indirectly point to the added data via the `__thread_vars` entry.
+ ///
+ /// Returns the section offset of the data.
+ pub fn add_symbol_bss(
+ &mut self,
+ symbol_id: SymbolId,
+ section: SectionId,
+ size: u64,
+ align: u64,
+ ) -> u64 {
+ let offset = self.append_section_bss(section, size, align);
+ self.set_symbol_data(symbol_id, section, offset, size);
+ offset
+ }
+
+ /// Update a symbol to refer to the given data within a section.
+ ///
+ /// For Mach-O, this also creates a `__thread_vars` entry for TLS symbols, and the
+ /// symbol will indirectly point to the data via the `__thread_vars` entry.
+ #[allow(unused_mut)]
+ pub fn set_symbol_data(
+ &mut self,
+ mut symbol_id: SymbolId,
+ section: SectionId,
+ offset: u64,
+ size: u64,
+ ) {
+ // Defined symbols must have a scope.
+ debug_assert!(self.symbol(symbol_id).scope != SymbolScope::Unknown);
+ match self.format {
+ #[cfg(feature = "macho")]
+ BinaryFormat::MachO => symbol_id = self.macho_add_thread_var(symbol_id),
+ _ => {}
+ }
+ let symbol = self.symbol_mut(symbol_id);
+ symbol.value = offset;
+ symbol.size = size;
+ symbol.section = SymbolSection::Section(section);
+ }
+
+ /// Convert a symbol to a section symbol and offset.
+ ///
+ /// Returns `None` if the symbol does not have a section.
+ pub fn symbol_section_and_offset(&mut self, symbol_id: SymbolId) -> Option<(SymbolId, u64)> {
+ let symbol = self.symbol(symbol_id);
+ if symbol.kind == SymbolKind::Section {
+ return Some((symbol_id, 0));
+ }
+ let symbol_offset = symbol.value;
+ let section = symbol.section.id()?;
+ let section_symbol = self.section_symbol(section);
+ Some((section_symbol, symbol_offset))
+ }
+
+ /// Add a relocation to a section.
+ ///
+ /// Relocations must only be added after the referenced symbols have been added
+ /// and defined (if applicable).
+ pub fn add_relocation(&mut self, section: SectionId, mut relocation: Relocation) -> Result<()> {
+ let addend = match self.format {
+ #[cfg(feature = "coff")]
+ BinaryFormat::Coff => self.coff_fixup_relocation(&mut relocation),
+ #[cfg(feature = "elf")]
+ BinaryFormat::Elf => self.elf_fixup_relocation(&mut relocation)?,
+ #[cfg(feature = "macho")]
+ BinaryFormat::MachO => self.macho_fixup_relocation(&mut relocation),
+ #[cfg(feature = "xcoff")]
+ BinaryFormat::Xcoff => self.xcoff_fixup_relocation(&mut relocation),
+ _ => unimplemented!(),
+ };
+ if addend != 0 {
+ self.write_relocation_addend(section, &relocation, addend)?;
+ }
+ self.sections[section.0].relocations.push(relocation);
+ Ok(())
+ }
+
+ fn write_relocation_addend(
+ &mut self,
+ section: SectionId,
+ relocation: &Relocation,
+ addend: i64,
+ ) -> Result<()> {
+ let data = self.sections[section.0].data_mut();
+ let offset = relocation.offset as usize;
+ match relocation.size {
+ 32 => data.write_at(offset, &U32::new(self.endian, addend as u32)),
+ 64 => data.write_at(offset, &U64::new(self.endian, addend as u64)),
+ _ => {
+ return Err(Error(format!(
+ "unimplemented relocation addend {:?}",
+ relocation
+ )));
+ }
+ }
+ .map_err(|_| {
+ Error(format!(
+ "invalid relocation offset {}+{} (max {})",
+ relocation.offset,
+ relocation.size,
+ data.len()
+ ))
+ })
+ }
+
+ /// Write the object to a `Vec`.
+ pub fn write(&self) -> Result<Vec<u8>> {
+ let mut buffer = Vec::new();
+ self.emit(&mut buffer)?;
+ Ok(buffer)
+ }
+
+ /// Write the object to a `Write` implementation.
+ ///
+ /// Also flushes the writer.
+ ///
+ /// It is advisable to use a buffered writer like [`BufWriter`](std::io::BufWriter)
+ /// instead of an unbuffered writer like [`File`](std::fs::File).
+ #[cfg(feature = "std")]
+ pub fn write_stream<W: io::Write>(&self, w: W) -> result::Result<(), Box<dyn error::Error>> {
+ let mut stream = StreamingBuffer::new(w);
+ self.emit(&mut stream)?;
+ stream.result()?;
+ stream.into_inner().flush()?;
+ Ok(())
+ }
+
+ /// Write the object to a `WritableBuffer`.
+ pub fn emit(&self, buffer: &mut dyn WritableBuffer) -> Result<()> {
+ match self.format {
+ #[cfg(feature = "coff")]
+ BinaryFormat::Coff => self.coff_write(buffer),
+ #[cfg(feature = "elf")]
+ BinaryFormat::Elf => self.elf_write(buffer),
+ #[cfg(feature = "macho")]
+ BinaryFormat::MachO => self.macho_write(buffer),
+ #[cfg(feature = "xcoff")]
+ BinaryFormat::Xcoff => self.xcoff_write(buffer),
+ _ => unimplemented!(),
+ }
+ }
+}
+
+/// A standard segment kind.
+#[allow(missing_docs)]
+#[derive(Debug, Clone, Copy, PartialEq, Eq, PartialOrd, Ord, Hash)]
+#[non_exhaustive]
+pub enum StandardSegment {
+ Text,
+ Data,
+ Debug,
+}
+
+/// A standard section kind.
+#[allow(missing_docs)]
+#[derive(Debug, Clone, Copy, PartialEq, Eq, PartialOrd, Ord, Hash)]
+#[non_exhaustive]
+pub enum StandardSection {
+ Text,
+ Data,
+ ReadOnlyData,
+ ReadOnlyDataWithRel,
+ ReadOnlyString,
+ UninitializedData,
+ Tls,
+ /// Zero-fill TLS initializers. Unsupported for COFF.
+ UninitializedTls,
+ /// TLS variable structures. Only supported for Mach-O.
+ TlsVariables,
+ /// Common data. Only supported for Mach-O.
+ Common,
+ /// Notes for GNU properties. Only supported for ELF.
+ GnuProperty,
+}
+
+impl StandardSection {
+ /// Return the section kind of a standard section.
+ pub fn kind(self) -> SectionKind {
+ match self {
+ StandardSection::Text => SectionKind::Text,
+ StandardSection::Data => SectionKind::Data,
+ StandardSection::ReadOnlyData => SectionKind::ReadOnlyData,
+ StandardSection::ReadOnlyDataWithRel => SectionKind::ReadOnlyDataWithRel,
+ StandardSection::ReadOnlyString => SectionKind::ReadOnlyString,
+ StandardSection::UninitializedData => SectionKind::UninitializedData,
+ StandardSection::Tls => SectionKind::Tls,
+ StandardSection::UninitializedTls => SectionKind::UninitializedTls,
+ StandardSection::TlsVariables => SectionKind::TlsVariables,
+ StandardSection::Common => SectionKind::Common,
+ StandardSection::GnuProperty => SectionKind::Note,
+ }
+ }
+
+ // TODO: remembering to update this is error-prone, can we do better?
+ fn all() -> &'static [StandardSection] {
+ &[
+ StandardSection::Text,
+ StandardSection::Data,
+ StandardSection::ReadOnlyData,
+ StandardSection::ReadOnlyDataWithRel,
+ StandardSection::ReadOnlyString,
+ StandardSection::UninitializedData,
+ StandardSection::Tls,
+ StandardSection::UninitializedTls,
+ StandardSection::TlsVariables,
+ StandardSection::Common,
+ StandardSection::GnuProperty,
+ ]
+ }
+}
+
+/// An identifier used to reference a section.
+#[derive(Debug, Clone, Copy, PartialEq, Eq, PartialOrd, Ord, Hash)]
+pub struct SectionId(usize);
+
+/// A section in an object file.
+#[derive(Debug)]
+pub struct Section<'a> {
+ segment: Vec<u8>,
+ name: Vec<u8>,
+ kind: SectionKind,
+ size: u64,
+ align: u64,
+ data: Cow<'a, [u8]>,
+ relocations: Vec<Relocation>,
+ symbol: Option<SymbolId>,
+ /// Section flags that are specific to each file format.
+ pub flags: SectionFlags,
+}
+
+impl<'a> Section<'a> {
+ /// Try to convert the name to a utf8 string.
+ #[inline]
+ pub fn name(&self) -> Option<&str> {
+ str::from_utf8(&self.name).ok()
+ }
+
+ /// Try to convert the segment to a utf8 string.
+ #[inline]
+ pub fn segment(&self) -> Option<&str> {
+ str::from_utf8(&self.segment).ok()
+ }
+
+ /// Return true if this section contains zerofill data.
+ #[inline]
+ pub fn is_bss(&self) -> bool {
+ self.kind.is_bss()
+ }
+
+ /// Set the data for a section.
+ ///
+ /// Must not be called for sections that already have data, or that contain uninitialized data.
+ pub fn set_data<T>(&mut self, data: T, align: u64)
+ where
+ T: Into<Cow<'a, [u8]>>,
+ {
+ debug_assert!(!self.is_bss());
+ debug_assert_eq!(align & (align - 1), 0);
+ debug_assert!(self.data.is_empty());
+ self.data = data.into();
+ self.size = self.data.len() as u64;
+ self.align = align;
+ }
+
+ /// Append data to a section.
+ ///
+ /// Must not be called for sections that contain uninitialized data.
+ pub fn append_data(&mut self, append_data: &[u8], align: u64) -> u64 {
+ debug_assert!(!self.is_bss());
+ debug_assert_eq!(align & (align - 1), 0);
+ if self.align < align {
+ self.align = align;
+ }
+ let align = align as usize;
+ let data = self.data.to_mut();
+ let mut offset = data.len();
+ if offset & (align - 1) != 0 {
+ offset += align - (offset & (align - 1));
+ data.resize(offset, 0);
+ }
+ data.extend_from_slice(append_data);
+ self.size = data.len() as u64;
+ offset as u64
+ }
+
+ /// Append uninitialized data to a section.
+ ///
+ /// Must not be called for sections that contain initialized data.
+ pub fn append_bss(&mut self, size: u64, align: u64) -> u64 {
+ debug_assert!(self.is_bss());
+ debug_assert_eq!(align & (align - 1), 0);
+ if self.align < align {
+ self.align = align;
+ }
+ let mut offset = self.size;
+ if offset & (align - 1) != 0 {
+ offset += align - (offset & (align - 1));
+ self.size = offset;
+ }
+ self.size += size;
+ offset
+ }
+
+ /// Returns the section as-built so far.
+ ///
+ /// This requires that the section is not a bss section.
+ pub fn data(&self) -> &[u8] {
+ debug_assert!(!self.is_bss());
+ &self.data
+ }
+
+ /// Returns the section as-built so far.
+ ///
+ /// This requires that the section is not a bss section.
+ pub fn data_mut(&mut self) -> &mut [u8] {
+ debug_assert!(!self.is_bss());
+ self.data.to_mut()
+ }
+}
+
+/// The section where a symbol is defined.
+#[derive(Debug, Clone, Copy, PartialEq, Eq, Hash)]
+#[non_exhaustive]
+pub enum SymbolSection {
+ /// The section is not applicable for this symbol (such as file symbols).
+ None,
+ /// The symbol is undefined.
+ Undefined,
+ /// The symbol has an absolute value.
+ Absolute,
+ /// The symbol is a zero-initialized symbol that will be combined with duplicate definitions.
+ Common,
+ /// The symbol is defined in the given section.
+ Section(SectionId),
+}
+
+impl SymbolSection {
+ /// Returns the section id for the section where the symbol is defined.
+ ///
+ /// May return `None` if the symbol is not defined in a section.
+ #[inline]
+ pub fn id(self) -> Option<SectionId> {
+ if let SymbolSection::Section(id) = self {
+ Some(id)
+ } else {
+ None
+ }
+ }
+}
+
+/// An identifier used to reference a symbol.
+#[derive(Debug, Clone, Copy, PartialEq, Eq, PartialOrd, Ord, Hash)]
+pub struct SymbolId(usize);
+
+/// A symbol in an object file.
+#[derive(Debug)]
+pub struct Symbol {
+ /// The name of the symbol.
+ pub name: Vec<u8>,
+ /// The value of the symbol.
+ ///
+ /// If the symbol defined in a section, then this is the section offset of the symbol.
+ pub value: u64,
+ /// The size of the symbol.
+ pub size: u64,
+ /// The kind of the symbol.
+ pub kind: SymbolKind,
+ /// The scope of the symbol.
+ pub scope: SymbolScope,
+ /// Whether the symbol has weak binding.
+ pub weak: bool,
+ /// The section containing the symbol.
+ pub section: SymbolSection,
+ /// Symbol flags that are specific to each file format.
+ pub flags: SymbolFlags<SectionId, SymbolId>,
+}
+
+impl Symbol {
+ /// Try to convert the name to a utf8 string.
+ #[inline]
+ pub fn name(&self) -> Option<&str> {
+ str::from_utf8(&self.name).ok()
+ }
+
+ /// Return true if the symbol is undefined.
+ #[inline]
+ pub fn is_undefined(&self) -> bool {
+ self.section == SymbolSection::Undefined
+ }
+
+ /// Return true if the symbol is common data.
+ ///
+ /// Note: does not check for `SymbolSection::Section` with `SectionKind::Common`.
+ #[inline]
+ pub fn is_common(&self) -> bool {
+ self.section == SymbolSection::Common
+ }
+
+ /// Return true if the symbol scope is local.
+ #[inline]
+ pub fn is_local(&self) -> bool {
+ self.scope == SymbolScope::Compilation
+ }
+}
+
+/// A relocation in an object file.
+#[derive(Debug)]
+pub struct Relocation {
+ /// The section offset of the place of the relocation.
+ pub offset: u64,
+ /// The size in bits of the place of relocation.
+ pub size: u8,
+ /// The operation used to calculate the result of the relocation.
+ pub kind: RelocationKind,
+ /// Information about how the result of the relocation operation is encoded in the place.
+ pub encoding: RelocationEncoding,
+ /// The symbol referred to by the relocation.
+ ///
+ /// This may be a section symbol.
+ pub symbol: SymbolId,
+ /// The addend to use in the relocation calculation.
+ ///
+ /// This may be in addition to an implicit addend stored at the place of the relocation.
+ pub addend: i64,
+}
+
+/// An identifier used to reference a COMDAT section group.
+#[derive(Debug, Clone, Copy, PartialEq, Eq, PartialOrd, Ord, Hash)]
+pub struct ComdatId(usize);
+
+/// A COMDAT section group.
+#[derive(Debug)]
+pub struct Comdat {
+ /// The COMDAT selection kind.
+ ///
+ /// This determines the way in which the linker resolves multiple definitions of the COMDAT
+ /// sections.
+ pub kind: ComdatKind,
+ /// The COMDAT symbol.
+ ///
+ /// If this symbol is referenced, then all sections in the group will be included by the
+ /// linker.
+ pub symbol: SymbolId,
+ /// The sections in the group.
+ pub sections: Vec<SectionId>,
+}
+
+/// The symbol name mangling scheme.
+#[derive(Debug, Clone, Copy, PartialEq, Eq, Hash)]
+#[non_exhaustive]
+pub enum Mangling {
+ /// No symbol mangling.
+ None,
+ /// Windows COFF symbol mangling.
+ Coff,
+ /// Windows COFF i386 symbol mangling.
+ CoffI386,
+ /// ELF symbol mangling.
+ Elf,
+ /// Mach-O symbol mangling.
+ MachO,
+ /// Xcoff symbol mangling.
+ Xcoff,
+}
+
+impl Mangling {
+ /// Return the default symboling mangling for the given format and architecture.
+ pub fn default(format: BinaryFormat, architecture: Architecture) -> Self {
+ match (format, architecture) {
+ (BinaryFormat::Coff, Architecture::I386) => Mangling::CoffI386,
+ (BinaryFormat::Coff, _) => Mangling::Coff,
+ (BinaryFormat::Elf, _) => Mangling::Elf,
+ (BinaryFormat::MachO, _) => Mangling::MachO,
+ (BinaryFormat::Xcoff, _) => Mangling::Xcoff,
+ _ => Mangling::None,
+ }
+ }
+
+ /// Return the prefix to use for global symbols.
+ pub fn global_prefix(self) -> Option<u8> {
+ match self {
+ Mangling::None | Mangling::Elf | Mangling::Coff | Mangling::Xcoff => None,
+ Mangling::CoffI386 | Mangling::MachO => Some(b'_'),
+ }
+ }
+}
diff --git a/vendor/object/src/write/pe.rs b/vendor/object/src/write/pe.rs
new file mode 100644
index 0000000..70da3a0
--- /dev/null
+++ b/vendor/object/src/write/pe.rs
@@ -0,0 +1,847 @@
+//! Helper for writing PE files.
+use alloc::string::String;
+use alloc::vec::Vec;
+use core::mem;
+
+use crate::endian::{LittleEndian as LE, *};
+use crate::pe;
+use crate::write::util;
+use crate::write::{Error, Result, WritableBuffer};
+
+/// A helper for writing PE files.
+///
+/// Writing uses a two phase approach. The first phase reserves file ranges and virtual
+/// address ranges for everything in the order that they will be written.
+///
+/// The second phase writes everything out in order. Thus the caller must ensure writing
+/// is in the same order that file ranges were reserved.
+#[allow(missing_debug_implementations)]
+pub struct Writer<'a> {
+ is_64: bool,
+ section_alignment: u32,
+ file_alignment: u32,
+
+ buffer: &'a mut dyn WritableBuffer,
+ len: u32,
+ virtual_len: u32,
+ headers_len: u32,
+
+ code_address: u32,
+ data_address: u32,
+ code_len: u32,
+ data_len: u32,
+ bss_len: u32,
+
+ nt_headers_offset: u32,
+ data_directories: Vec<DataDirectory>,
+ section_header_num: u16,
+ sections: Vec<Section>,
+
+ symbol_offset: u32,
+ symbol_num: u32,
+
+ reloc_blocks: Vec<RelocBlock>,
+ relocs: Vec<U16<LE>>,
+ reloc_offset: u32,
+}
+
+impl<'a> Writer<'a> {
+ /// Create a new `Writer`.
+ pub fn new(
+ is_64: bool,
+ section_alignment: u32,
+ file_alignment: u32,
+ buffer: &'a mut dyn WritableBuffer,
+ ) -> Self {
+ Writer {
+ is_64,
+ section_alignment,
+ file_alignment,
+
+ buffer,
+ len: 0,
+ virtual_len: 0,
+ headers_len: 0,
+
+ code_address: 0,
+ data_address: 0,
+ code_len: 0,
+ data_len: 0,
+ bss_len: 0,
+
+ nt_headers_offset: 0,
+ data_directories: Vec::new(),
+ section_header_num: 0,
+ sections: Vec::new(),
+
+ symbol_offset: 0,
+ symbol_num: 0,
+
+ reloc_blocks: Vec::new(),
+ relocs: Vec::new(),
+ reloc_offset: 0,
+ }
+ }
+
+ /// Return the current virtual address size that has been reserved.
+ ///
+ /// This is only valid after section headers have been reserved.
+ pub fn virtual_len(&self) -> u32 {
+ self.virtual_len
+ }
+
+ /// Reserve a virtual address range with the given size.
+ ///
+ /// The reserved length will be increased to match the section alignment.
+ ///
+ /// Returns the aligned offset of the start of the range.
+ pub fn reserve_virtual(&mut self, len: u32) -> u32 {
+ let offset = self.virtual_len;
+ self.virtual_len += len;
+ self.virtual_len = util::align_u32(self.virtual_len, self.section_alignment);
+ offset
+ }
+
+ /// Reserve up to the given virtual address.
+ ///
+ /// The reserved length will be increased to match the section alignment.
+ pub fn reserve_virtual_until(&mut self, address: u32) {
+ debug_assert!(self.virtual_len <= address);
+ self.virtual_len = util::align_u32(address, self.section_alignment);
+ }
+
+ /// Return the current file length that has been reserved.
+ pub fn reserved_len(&self) -> u32 {
+ 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: u32, align_start: u32) -> u32 {
+ if len == 0 {
+ return self.len;
+ }
+ self.reserve_align(align_start);
+ let offset = self.len;
+ self.len += len;
+ offset
+ }
+
+ /// Reserve a file range with the given size and using the file alignment.
+ ///
+ /// Returns the aligned offset of the start of the range.
+ pub fn reserve_file(&mut self, len: u32) -> u32 {
+ self.reserve(len, self.file_alignment)
+ }
+
+ /// Write data.
+ pub fn write(&mut self, data: &[u8]) {
+ self.buffer.write_bytes(data);
+ }
+
+ /// Reserve alignment padding bytes.
+ pub fn reserve_align(&mut self, align_start: u32) {
+ self.len = util::align_u32(self.len, align_start);
+ }
+
+ /// Write alignment padding bytes.
+ pub fn write_align(&mut self, align_start: u32) {
+ util::write_align(self.buffer, align_start as usize);
+ }
+
+ /// Write padding up to the next multiple of file alignment.
+ pub fn write_file_align(&mut self) {
+ self.write_align(self.file_alignment);
+ }
+
+ /// Reserve the file range up to the given file offset.
+ pub fn reserve_until(&mut self, offset: u32) {
+ debug_assert!(self.len <= offset);
+ self.len = offset;
+ }
+
+ /// Write padding up to the given file offset.
+ pub fn pad_until(&mut self, offset: u32) {
+ debug_assert!(self.buffer.len() <= offset as usize);
+ self.buffer.resize(offset as usize);
+ }
+
+ /// Reserve the range for the DOS header.
+ ///
+ /// This must be at the start of the file.
+ ///
+ /// When writing, you may use `write_custom_dos_header` or `write_empty_dos_header`.
+ pub fn reserve_dos_header(&mut self) {
+ debug_assert_eq!(self.len, 0);
+ self.reserve(mem::size_of::<pe::ImageDosHeader>() as u32, 1);
+ }
+
+ /// Write a custom DOS header.
+ ///
+ /// This must be at the start of the file.
+ pub fn write_custom_dos_header(&mut self, dos_header: &pe::ImageDosHeader) -> Result<()> {
+ debug_assert_eq!(self.buffer.len(), 0);
+
+ // Start writing.
+ self.buffer
+ .reserve(self.len as usize)
+ .map_err(|_| Error(String::from("Cannot allocate buffer")))?;
+
+ self.buffer.write(dos_header);
+ Ok(())
+ }
+
+ /// Write the DOS header for a file without a stub.
+ ///
+ /// This must be at the start of the file.
+ ///
+ /// Uses default values for all fields.
+ pub fn write_empty_dos_header(&mut self) -> Result<()> {
+ self.write_custom_dos_header(&pe::ImageDosHeader {
+ e_magic: U16::new(LE, pe::IMAGE_DOS_SIGNATURE),
+ e_cblp: U16::new(LE, 0),
+ e_cp: U16::new(LE, 0),
+ e_crlc: U16::new(LE, 0),
+ e_cparhdr: U16::new(LE, 0),
+ e_minalloc: U16::new(LE, 0),
+ e_maxalloc: U16::new(LE, 0),
+ e_ss: U16::new(LE, 0),
+ e_sp: U16::new(LE, 0),
+ e_csum: U16::new(LE, 0),
+ e_ip: U16::new(LE, 0),
+ e_cs: U16::new(LE, 0),
+ e_lfarlc: U16::new(LE, 0),
+ e_ovno: U16::new(LE, 0),
+ e_res: [U16::new(LE, 0); 4],
+ e_oemid: U16::new(LE, 0),
+ e_oeminfo: U16::new(LE, 0),
+ e_res2: [U16::new(LE, 0); 10],
+ e_lfanew: U32::new(LE, self.nt_headers_offset),
+ })
+ }
+
+ /// Reserve a fixed DOS header and stub.
+ ///
+ /// Use `reserve_dos_header` and `reserve` if you need a custom stub.
+ pub fn reserve_dos_header_and_stub(&mut self) {
+ self.reserve_dos_header();
+ self.reserve(64, 1);
+ }
+
+ /// Write a fixed DOS header and stub.
+ ///
+ /// Use `write_custom_dos_header` and `write` if you need a custom stub.
+ pub fn write_dos_header_and_stub(&mut self) -> Result<()> {
+ self.write_custom_dos_header(&pe::ImageDosHeader {
+ e_magic: U16::new(LE, pe::IMAGE_DOS_SIGNATURE),
+ e_cblp: U16::new(LE, 0x90),
+ e_cp: U16::new(LE, 3),
+ e_crlc: U16::new(LE, 0),
+ e_cparhdr: U16::new(LE, 4),
+ e_minalloc: U16::new(LE, 0),
+ e_maxalloc: U16::new(LE, 0xffff),
+ e_ss: U16::new(LE, 0),
+ e_sp: U16::new(LE, 0xb8),
+ e_csum: U16::new(LE, 0),
+ e_ip: U16::new(LE, 0),
+ e_cs: U16::new(LE, 0),
+ e_lfarlc: U16::new(LE, 0x40),
+ e_ovno: U16::new(LE, 0),
+ e_res: [U16::new(LE, 0); 4],
+ e_oemid: U16::new(LE, 0),
+ e_oeminfo: U16::new(LE, 0),
+ e_res2: [U16::new(LE, 0); 10],
+ e_lfanew: U32::new(LE, self.nt_headers_offset),
+ })?;
+
+ #[rustfmt::skip]
+ self.buffer.write_bytes(&[
+ 0x0e, 0x1f, 0xba, 0x0e, 0x00, 0xb4, 0x09, 0xcd,
+ 0x21, 0xb8, 0x01, 0x4c, 0xcd, 0x21, 0x54, 0x68,
+ 0x69, 0x73, 0x20, 0x70, 0x72, 0x6f, 0x67, 0x72,
+ 0x61, 0x6d, 0x20, 0x63, 0x61, 0x6e, 0x6e, 0x6f,
+ 0x74, 0x20, 0x62, 0x65, 0x20, 0x72, 0x75, 0x6e,
+ 0x20, 0x69, 0x6e, 0x20, 0x44, 0x4f, 0x53, 0x20,
+ 0x6d, 0x6f, 0x64, 0x65, 0x2e, 0x0d, 0x0d, 0x0a,
+ 0x24, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00,
+ ]);
+
+ Ok(())
+ }
+
+ fn nt_headers_size(&self) -> u32 {
+ if self.is_64 {
+ mem::size_of::<pe::ImageNtHeaders64>() as u32
+ } else {
+ mem::size_of::<pe::ImageNtHeaders32>() as u32
+ }
+ }
+
+ fn optional_header_size(&self) -> u32 {
+ let size = if self.is_64 {
+ mem::size_of::<pe::ImageOptionalHeader64>() as u32
+ } else {
+ mem::size_of::<pe::ImageOptionalHeader32>() as u32
+ };
+ size + self.data_directories.len() as u32 * mem::size_of::<pe::ImageDataDirectory>() as u32
+ }
+
+ /// Return the offset of the NT headers, if reserved.
+ pub fn nt_headers_offset(&self) -> u32 {
+ self.nt_headers_offset
+ }
+
+ /// Reserve the range for the NT headers.
+ pub fn reserve_nt_headers(&mut self, data_directory_num: usize) {
+ debug_assert_eq!(self.nt_headers_offset, 0);
+ self.nt_headers_offset = self.reserve(self.nt_headers_size(), 8);
+ self.data_directories = vec![DataDirectory::default(); data_directory_num];
+ self.reserve(
+ data_directory_num as u32 * mem::size_of::<pe::ImageDataDirectory>() as u32,
+ 1,
+ );
+ }
+
+ /// Set the virtual address and size of a data directory.
+ pub fn set_data_directory(&mut self, index: usize, virtual_address: u32, size: u32) {
+ self.data_directories[index] = DataDirectory {
+ virtual_address,
+ size,
+ }
+ }
+
+ /// Write the NT headers.
+ pub fn write_nt_headers(&mut self, nt_headers: NtHeaders) {
+ self.pad_until(self.nt_headers_offset);
+ self.buffer.write(&U32::new(LE, pe::IMAGE_NT_SIGNATURE));
+ let file_header = pe::ImageFileHeader {
+ machine: U16::new(LE, nt_headers.machine),
+ number_of_sections: U16::new(LE, self.section_header_num),
+ time_date_stamp: U32::new(LE, nt_headers.time_date_stamp),
+ pointer_to_symbol_table: U32::new(LE, self.symbol_offset),
+ number_of_symbols: U32::new(LE, self.symbol_num),
+ size_of_optional_header: U16::new(LE, self.optional_header_size() as u16),
+ characteristics: U16::new(LE, nt_headers.characteristics),
+ };
+ self.buffer.write(&file_header);
+ if self.is_64 {
+ let optional_header = pe::ImageOptionalHeader64 {
+ magic: U16::new(LE, pe::IMAGE_NT_OPTIONAL_HDR64_MAGIC),
+ major_linker_version: nt_headers.major_linker_version,
+ minor_linker_version: nt_headers.minor_linker_version,
+ size_of_code: U32::new(LE, self.code_len),
+ size_of_initialized_data: U32::new(LE, self.data_len),
+ size_of_uninitialized_data: U32::new(LE, self.bss_len),
+ address_of_entry_point: U32::new(LE, nt_headers.address_of_entry_point),
+ base_of_code: U32::new(LE, self.code_address),
+ image_base: U64::new(LE, nt_headers.image_base),
+ section_alignment: U32::new(LE, self.section_alignment),
+ file_alignment: U32::new(LE, self.file_alignment),
+ major_operating_system_version: U16::new(
+ LE,
+ nt_headers.major_operating_system_version,
+ ),
+ minor_operating_system_version: U16::new(
+ LE,
+ nt_headers.minor_operating_system_version,
+ ),
+ major_image_version: U16::new(LE, nt_headers.major_image_version),
+ minor_image_version: U16::new(LE, nt_headers.minor_image_version),
+ major_subsystem_version: U16::new(LE, nt_headers.major_subsystem_version),
+ minor_subsystem_version: U16::new(LE, nt_headers.minor_subsystem_version),
+ win32_version_value: U32::new(LE, 0),
+ size_of_image: U32::new(LE, self.virtual_len),
+ size_of_headers: U32::new(LE, self.headers_len),
+ check_sum: U32::new(LE, 0),
+ subsystem: U16::new(LE, nt_headers.subsystem),
+ dll_characteristics: U16::new(LE, nt_headers.dll_characteristics),
+ size_of_stack_reserve: U64::new(LE, nt_headers.size_of_stack_reserve),
+ size_of_stack_commit: U64::new(LE, nt_headers.size_of_stack_commit),
+ size_of_heap_reserve: U64::new(LE, nt_headers.size_of_heap_reserve),
+ size_of_heap_commit: U64::new(LE, nt_headers.size_of_heap_commit),
+ loader_flags: U32::new(LE, 0),
+ number_of_rva_and_sizes: U32::new(LE, self.data_directories.len() as u32),
+ };
+ self.buffer.write(&optional_header);
+ } else {
+ let optional_header = pe::ImageOptionalHeader32 {
+ magic: U16::new(LE, pe::IMAGE_NT_OPTIONAL_HDR32_MAGIC),
+ major_linker_version: nt_headers.major_linker_version,
+ minor_linker_version: nt_headers.minor_linker_version,
+ size_of_code: U32::new(LE, self.code_len),
+ size_of_initialized_data: U32::new(LE, self.data_len),
+ size_of_uninitialized_data: U32::new(LE, self.bss_len),
+ address_of_entry_point: U32::new(LE, nt_headers.address_of_entry_point),
+ base_of_code: U32::new(LE, self.code_address),
+ base_of_data: U32::new(LE, self.data_address),
+ image_base: U32::new(LE, nt_headers.image_base as u32),
+ section_alignment: U32::new(LE, self.section_alignment),
+ file_alignment: U32::new(LE, self.file_alignment),
+ major_operating_system_version: U16::new(
+ LE,
+ nt_headers.major_operating_system_version,
+ ),
+ minor_operating_system_version: U16::new(
+ LE,
+ nt_headers.minor_operating_system_version,
+ ),
+ major_image_version: U16::new(LE, nt_headers.major_image_version),
+ minor_image_version: U16::new(LE, nt_headers.minor_image_version),
+ major_subsystem_version: U16::new(LE, nt_headers.major_subsystem_version),
+ minor_subsystem_version: U16::new(LE, nt_headers.minor_subsystem_version),
+ win32_version_value: U32::new(LE, 0),
+ size_of_image: U32::new(LE, self.virtual_len),
+ size_of_headers: U32::new(LE, self.headers_len),
+ check_sum: U32::new(LE, 0),
+ subsystem: U16::new(LE, nt_headers.subsystem),
+ dll_characteristics: U16::new(LE, nt_headers.dll_characteristics),
+ size_of_stack_reserve: U32::new(LE, nt_headers.size_of_stack_reserve as u32),
+ size_of_stack_commit: U32::new(LE, nt_headers.size_of_stack_commit as u32),
+ size_of_heap_reserve: U32::new(LE, nt_headers.size_of_heap_reserve as u32),
+ size_of_heap_commit: U32::new(LE, nt_headers.size_of_heap_commit as u32),
+ loader_flags: U32::new(LE, 0),
+ number_of_rva_and_sizes: U32::new(LE, self.data_directories.len() as u32),
+ };
+ self.buffer.write(&optional_header);
+ }
+
+ for dir in &self.data_directories {
+ self.buffer.write(&pe::ImageDataDirectory {
+ virtual_address: U32::new(LE, dir.virtual_address),
+ size: U32::new(LE, dir.size),
+ })
+ }
+ }
+
+ /// Reserve the section headers.
+ ///
+ /// The number of reserved section headers must be the same as the number of sections that
+ /// are later reserved.
+ // TODO: change this to a maximum number of sections?
+ pub fn reserve_section_headers(&mut self, section_header_num: u16) {
+ debug_assert_eq!(self.section_header_num, 0);
+ self.section_header_num = section_header_num;
+ self.reserve(
+ u32::from(section_header_num) * mem::size_of::<pe::ImageSectionHeader>() as u32,
+ 1,
+ );
+ // Padding before sections must be included in headers_len.
+ self.reserve_align(self.file_alignment);
+ self.headers_len = self.len;
+ self.reserve_virtual(self.len);
+ }
+
+ /// Write the section headers.
+ ///
+ /// This uses information that was recorded when the sections were reserved.
+ pub fn write_section_headers(&mut self) {
+ debug_assert_eq!(self.section_header_num as usize, self.sections.len());
+ for section in &self.sections {
+ let section_header = pe::ImageSectionHeader {
+ name: section.name,
+ virtual_size: U32::new(LE, section.range.virtual_size),
+ virtual_address: U32::new(LE, section.range.virtual_address),
+ size_of_raw_data: U32::new(LE, section.range.file_size),
+ pointer_to_raw_data: U32::new(LE, section.range.file_offset),
+ pointer_to_relocations: U32::new(LE, 0),
+ pointer_to_linenumbers: U32::new(LE, 0),
+ number_of_relocations: U16::new(LE, 0),
+ number_of_linenumbers: U16::new(LE, 0),
+ characteristics: U32::new(LE, section.characteristics),
+ };
+ self.buffer.write(&section_header);
+ }
+ }
+
+ /// Reserve a section.
+ ///
+ /// Returns the file range and virtual address range that are reserved
+ /// for the section.
+ pub fn reserve_section(
+ &mut self,
+ name: [u8; 8],
+ characteristics: u32,
+ virtual_size: u32,
+ data_size: u32,
+ ) -> SectionRange {
+ let virtual_address = self.reserve_virtual(virtual_size);
+
+ // Padding after section must be included in section file size.
+ let file_size = util::align_u32(data_size, self.file_alignment);
+ let file_offset = if file_size != 0 {
+ self.reserve(file_size, self.file_alignment)
+ } else {
+ 0
+ };
+
+ // Sizes in optional header use the virtual size with the file alignment.
+ let aligned_virtual_size = util::align_u32(virtual_size, self.file_alignment);
+ if characteristics & pe::IMAGE_SCN_CNT_CODE != 0 {
+ if self.code_address == 0 {
+ self.code_address = virtual_address;
+ }
+ self.code_len += aligned_virtual_size;
+ } else if characteristics & pe::IMAGE_SCN_CNT_INITIALIZED_DATA != 0 {
+ if self.data_address == 0 {
+ self.data_address = virtual_address;
+ }
+ self.data_len += aligned_virtual_size;
+ } else if characteristics & pe::IMAGE_SCN_CNT_UNINITIALIZED_DATA != 0 {
+ if self.data_address == 0 {
+ self.data_address = virtual_address;
+ }
+ self.bss_len += aligned_virtual_size;
+ }
+
+ let range = SectionRange {
+ virtual_address,
+ virtual_size,
+ file_offset,
+ file_size,
+ };
+ self.sections.push(Section {
+ name,
+ characteristics,
+ range,
+ });
+ range
+ }
+
+ /// Write the data for a section.
+ pub fn write_section(&mut self, offset: u32, data: &[u8]) {
+ if data.is_empty() {
+ return;
+ }
+ self.pad_until(offset);
+ self.write(data);
+ self.write_align(self.file_alignment);
+ }
+
+ /// Reserve a `.text` section.
+ ///
+ /// Contains executable code.
+ pub fn reserve_text_section(&mut self, size: u32) -> SectionRange {
+ self.reserve_section(
+ *b".text\0\0\0",
+ pe::IMAGE_SCN_CNT_CODE | pe::IMAGE_SCN_MEM_EXECUTE | pe::IMAGE_SCN_MEM_READ,
+ size,
+ size,
+ )
+ }
+
+ /// Reserve a `.data` section.
+ ///
+ /// Contains initialized data.
+ ///
+ /// May also contain uninitialized data if `virtual_size` is greater than `data_size`.
+ pub fn reserve_data_section(&mut self, virtual_size: u32, data_size: u32) -> SectionRange {
+ self.reserve_section(
+ *b".data\0\0\0",
+ pe::IMAGE_SCN_CNT_INITIALIZED_DATA | pe::IMAGE_SCN_MEM_READ | pe::IMAGE_SCN_MEM_WRITE,
+ virtual_size,
+ data_size,
+ )
+ }
+
+ /// Reserve a `.rdata` section.
+ ///
+ /// Contains read-only initialized data.
+ pub fn reserve_rdata_section(&mut self, size: u32) -> SectionRange {
+ self.reserve_section(
+ *b".rdata\0\0",
+ pe::IMAGE_SCN_CNT_INITIALIZED_DATA | pe::IMAGE_SCN_MEM_READ,
+ size,
+ size,
+ )
+ }
+
+ /// Reserve a `.bss` section.
+ ///
+ /// Contains uninitialized data.
+ pub fn reserve_bss_section(&mut self, size: u32) -> SectionRange {
+ self.reserve_section(
+ *b".bss\0\0\0\0",
+ pe::IMAGE_SCN_CNT_UNINITIALIZED_DATA | pe::IMAGE_SCN_MEM_READ | pe::IMAGE_SCN_MEM_WRITE,
+ size,
+ 0,
+ )
+ }
+
+ /// Reserve an `.idata` section.
+ ///
+ /// Contains import tables. Note that it is permissible to store import tables in a different
+ /// section.
+ ///
+ /// This also sets the `pe::IMAGE_DIRECTORY_ENTRY_IMPORT` data directory.
+ pub fn reserve_idata_section(&mut self, size: u32) -> SectionRange {
+ let range = self.reserve_section(
+ *b".idata\0\0",
+ pe::IMAGE_SCN_CNT_INITIALIZED_DATA | pe::IMAGE_SCN_MEM_READ | pe::IMAGE_SCN_MEM_WRITE,
+ size,
+ size,
+ );
+ let dir = &mut self.data_directories[pe::IMAGE_DIRECTORY_ENTRY_IMPORT];
+ debug_assert_eq!(dir.virtual_address, 0);
+ *dir = DataDirectory {
+ virtual_address: range.virtual_address,
+ size,
+ };
+ range
+ }
+
+ /// Reserve an `.edata` section.
+ ///
+ /// Contains export tables.
+ ///
+ /// This also sets the `pe::IMAGE_DIRECTORY_ENTRY_EXPORT` data directory.
+ pub fn reserve_edata_section(&mut self, size: u32) -> SectionRange {
+ let range = self.reserve_section(
+ *b".edata\0\0",
+ pe::IMAGE_SCN_CNT_INITIALIZED_DATA | pe::IMAGE_SCN_MEM_READ,
+ size,
+ size,
+ );
+ let dir = &mut self.data_directories[pe::IMAGE_DIRECTORY_ENTRY_EXPORT];
+ debug_assert_eq!(dir.virtual_address, 0);
+ *dir = DataDirectory {
+ virtual_address: range.virtual_address,
+ size,
+ };
+ range
+ }
+
+ /// Reserve a `.pdata` section.
+ ///
+ /// Contains exception information.
+ ///
+ /// This also sets the `pe::IMAGE_DIRECTORY_ENTRY_EXCEPTION` data directory.
+ pub fn reserve_pdata_section(&mut self, size: u32) -> SectionRange {
+ let range = self.reserve_section(
+ *b".pdata\0\0",
+ pe::IMAGE_SCN_CNT_INITIALIZED_DATA | pe::IMAGE_SCN_MEM_READ,
+ size,
+ size,
+ );
+ let dir = &mut self.data_directories[pe::IMAGE_DIRECTORY_ENTRY_EXCEPTION];
+ debug_assert_eq!(dir.virtual_address, 0);
+ *dir = DataDirectory {
+ virtual_address: range.virtual_address,
+ size,
+ };
+ range
+ }
+
+ /// Reserve a `.xdata` section.
+ ///
+ /// Contains exception information.
+ pub fn reserve_xdata_section(&mut self, size: u32) -> SectionRange {
+ self.reserve_section(
+ *b".xdata\0\0",
+ pe::IMAGE_SCN_CNT_INITIALIZED_DATA | pe::IMAGE_SCN_MEM_READ,
+ size,
+ size,
+ )
+ }
+
+ /// Reserve a `.rsrc` section.
+ ///
+ /// Contains the resource directory.
+ ///
+ /// This also sets the `pe::IMAGE_DIRECTORY_ENTRY_RESOURCE` data directory.
+ pub fn reserve_rsrc_section(&mut self, size: u32) -> SectionRange {
+ let range = self.reserve_section(
+ *b".rsrc\0\0\0",
+ pe::IMAGE_SCN_CNT_INITIALIZED_DATA | pe::IMAGE_SCN_MEM_READ,
+ size,
+ size,
+ );
+ let dir = &mut self.data_directories[pe::IMAGE_DIRECTORY_ENTRY_RESOURCE];
+ debug_assert_eq!(dir.virtual_address, 0);
+ *dir = DataDirectory {
+ virtual_address: range.virtual_address,
+ size,
+ };
+ range
+ }
+
+ /// Add a base relocation.
+ ///
+ /// `typ` must be one of the `IMAGE_REL_BASED_*` constants.
+ pub fn add_reloc(&mut self, mut virtual_address: u32, typ: u16) {
+ let reloc = U16::new(LE, typ << 12 | (virtual_address & 0xfff) as u16);
+ virtual_address &= !0xfff;
+ if let Some(block) = self.reloc_blocks.last_mut() {
+ if block.virtual_address == virtual_address {
+ self.relocs.push(reloc);
+ block.count += 1;
+ return;
+ }
+ // Blocks must have an even number of relocations.
+ if block.count & 1 != 0 {
+ self.relocs.push(U16::new(LE, 0));
+ block.count += 1;
+ }
+ debug_assert!(block.virtual_address < virtual_address);
+ }
+ self.relocs.push(reloc);
+ self.reloc_blocks.push(RelocBlock {
+ virtual_address,
+ count: 1,
+ });
+ }
+
+ /// Return true if a base relocation has been added.
+ pub fn has_relocs(&mut self) -> bool {
+ !self.relocs.is_empty()
+ }
+
+ /// Reserve a `.reloc` section.
+ ///
+ /// This contains the base relocations that were added with `add_reloc`.
+ ///
+ /// This also sets the `pe::IMAGE_DIRECTORY_ENTRY_BASERELOC` data directory.
+ pub fn reserve_reloc_section(&mut self) -> SectionRange {
+ if let Some(block) = self.reloc_blocks.last_mut() {
+ // Blocks must have an even number of relocations.
+ if block.count & 1 != 0 {
+ self.relocs.push(U16::new(LE, 0));
+ block.count += 1;
+ }
+ }
+ let size = self.reloc_blocks.iter().map(RelocBlock::size).sum();
+ let range = self.reserve_section(
+ *b".reloc\0\0",
+ pe::IMAGE_SCN_CNT_INITIALIZED_DATA
+ | pe::IMAGE_SCN_MEM_READ
+ | pe::IMAGE_SCN_MEM_DISCARDABLE,
+ size,
+ size,
+ );
+ let dir = &mut self.data_directories[pe::IMAGE_DIRECTORY_ENTRY_BASERELOC];
+ debug_assert_eq!(dir.virtual_address, 0);
+ *dir = DataDirectory {
+ virtual_address: range.virtual_address,
+ size,
+ };
+ self.reloc_offset = range.file_offset;
+ range
+ }
+
+ /// Write a `.reloc` section.
+ ///
+ /// This contains the base relocations that were added with `add_reloc`.
+ pub fn write_reloc_section(&mut self) {
+ if self.reloc_offset == 0 {
+ return;
+ }
+ self.pad_until(self.reloc_offset);
+
+ let mut total = 0;
+ for block in &self.reloc_blocks {
+ self.buffer.write(&pe::ImageBaseRelocation {
+ virtual_address: U32::new(LE, block.virtual_address),
+ size_of_block: U32::new(LE, block.size()),
+ });
+ self.buffer
+ .write_slice(&self.relocs[total..][..block.count as usize]);
+ total += block.count as usize;
+ }
+ debug_assert_eq!(total, self.relocs.len());
+
+ self.write_align(self.file_alignment);
+ }
+
+ /// Reserve the certificate table.
+ ///
+ /// This also sets the `pe::IMAGE_DIRECTORY_ENTRY_SECURITY` data directory.
+ // TODO: reserve individual certificates
+ pub fn reserve_certificate_table(&mut self, size: u32) {
+ let size = util::align_u32(size, 8);
+ let offset = self.reserve(size, 8);
+ let dir = &mut self.data_directories[pe::IMAGE_DIRECTORY_ENTRY_SECURITY];
+ debug_assert_eq!(dir.virtual_address, 0);
+ *dir = DataDirectory {
+ virtual_address: offset,
+ size,
+ };
+ }
+
+ /// Write the certificate table.
+ // TODO: write individual certificates
+ pub fn write_certificate_table(&mut self, data: &[u8]) {
+ let dir = self.data_directories[pe::IMAGE_DIRECTORY_ENTRY_SECURITY];
+ self.pad_until(dir.virtual_address);
+ self.write(data);
+ self.pad_until(dir.virtual_address + dir.size);
+ }
+}
+
+/// Information required for writing [`pe::ImageNtHeaders32`] or [`pe::ImageNtHeaders64`].
+#[allow(missing_docs)]
+#[derive(Debug, Clone)]
+pub struct NtHeaders {
+ // ImageFileHeader
+ pub machine: u16,
+ pub time_date_stamp: u32,
+ pub characteristics: u16,
+ // ImageOptionalHeader
+ pub major_linker_version: u8,
+ pub minor_linker_version: u8,
+ pub address_of_entry_point: u32,
+ pub image_base: u64,
+ pub major_operating_system_version: u16,
+ pub minor_operating_system_version: u16,
+ pub major_image_version: u16,
+ pub minor_image_version: u16,
+ pub major_subsystem_version: u16,
+ pub minor_subsystem_version: u16,
+ pub subsystem: u16,
+ pub dll_characteristics: u16,
+ pub size_of_stack_reserve: u64,
+ pub size_of_stack_commit: u64,
+ pub size_of_heap_reserve: u64,
+ pub size_of_heap_commit: u64,
+}
+
+#[derive(Default, Clone, Copy)]
+struct DataDirectory {
+ virtual_address: u32,
+ size: u32,
+}
+
+/// Information required for writing [`pe::ImageSectionHeader`].
+#[allow(missing_docs)]
+#[derive(Debug, Clone)]
+pub struct Section {
+ pub name: [u8; pe::IMAGE_SIZEOF_SHORT_NAME],
+ pub characteristics: u32,
+ pub range: SectionRange,
+}
+
+/// The file range and virtual address range for a section.
+#[allow(missing_docs)]
+#[derive(Debug, Default, Clone, Copy)]
+pub struct SectionRange {
+ pub virtual_address: u32,
+ pub virtual_size: u32,
+ pub file_offset: u32,
+ pub file_size: u32,
+}
+
+struct RelocBlock {
+ virtual_address: u32,
+ count: u32,
+}
+
+impl RelocBlock {
+ fn size(&self) -> u32 {
+ mem::size_of::<pe::ImageBaseRelocation>() as u32 + self.count * mem::size_of::<u16>() as u32
+ }
+}
diff --git a/vendor/object/src/write/string.rs b/vendor/object/src/write/string.rs
new file mode 100644
index 0000000..b23274a
--- /dev/null
+++ b/vendor/object/src/write/string.rs
@@ -0,0 +1,159 @@
+use alloc::vec::Vec;
+
+#[cfg(feature = "std")]
+type IndexSet<K> = indexmap::IndexSet<K>;
+#[cfg(not(feature = "std"))]
+type IndexSet<K> = indexmap::IndexSet<K, hashbrown::hash_map::DefaultHashBuilder>;
+
+/// An identifier for an entry in a string table.
+#[derive(Debug, Clone, Copy, PartialEq, Eq)]
+pub struct StringId(usize);
+
+#[derive(Debug, Default)]
+pub(crate) struct StringTable<'a> {
+ strings: IndexSet<&'a [u8]>,
+ offsets: Vec<usize>,
+}
+
+impl<'a> StringTable<'a> {
+ /// Add a string to the string table.
+ ///
+ /// Panics if the string table has already been written, or
+ /// if the string contains a null byte.
+ pub fn add(&mut self, string: &'a [u8]) -> StringId {
+ assert!(self.offsets.is_empty());
+ assert!(!string.contains(&0));
+ let id = self.strings.insert_full(string).0;
+ StringId(id)
+ }
+
+ /// Return the id of the given string.
+ ///
+ /// Panics if the string is not in the string table.
+ pub fn get_id(&self, string: &[u8]) -> StringId {
+ let id = self.strings.get_index_of(string).unwrap();
+ StringId(id)
+ }
+
+ /// Return the string for the given id.
+ ///
+ /// Panics if the string is not in the string table.
+ pub fn get_string(&self, id: StringId) -> &'a [u8] {
+ self.strings.get_index(id.0).unwrap()
+ }
+
+ /// Return the offset of the given string.
+ ///
+ /// Panics if the string table has not been written, or
+ /// if the string is not in the string table.
+ pub fn get_offset(&self, id: StringId) -> usize {
+ self.offsets[id.0]
+ }
+
+ /// Append the string table to the given `Vec`, and
+ /// calculate the list of string offsets.
+ ///
+ /// `base` is the initial string table offset. For example,
+ /// this should be 1 for ELF, to account for the initial
+ /// null byte (which must have been written by the caller).
+ pub fn write(&mut self, base: usize, w: &mut Vec<u8>) {
+ assert!(self.offsets.is_empty());
+
+ let mut ids: Vec<_> = (0..self.strings.len()).collect();
+ sort(&mut ids, 1, &self.strings);
+
+ self.offsets = vec![0; ids.len()];
+ let mut offset = base;
+ let mut previous = &[][..];
+ for id in ids {
+ let string = self.strings.get_index(id).unwrap();
+ if previous.ends_with(string) {
+ self.offsets[id] = offset - string.len() - 1;
+ } else {
+ self.offsets[id] = offset;
+ w.extend_from_slice(string);
+ w.push(0);
+ offset += string.len() + 1;
+ previous = string;
+ }
+ }
+ }
+}
+
+// Multi-key quicksort.
+//
+// Ordering is such that if a string is a suffix of at least one other string,
+// then it is placed immediately after one of those strings. That is:
+// - comparison starts at the end of the string
+// - shorter strings come later
+//
+// Based on the implementation in LLVM.
+fn sort(mut ids: &mut [usize], mut pos: usize, strings: &IndexSet<&[u8]>) {
+ loop {
+ if ids.len() <= 1 {
+ return;
+ }
+
+ let pivot = byte(ids[0], pos, strings);
+ let mut lower = 0;
+ let mut upper = ids.len();
+ let mut i = 1;
+ while i < upper {
+ let b = byte(ids[i], pos, strings);
+ if b > pivot {
+ ids.swap(lower, i);
+ lower += 1;
+ i += 1;
+ } else if b < pivot {
+ upper -= 1;
+ ids.swap(upper, i);
+ } else {
+ i += 1;
+ }
+ }
+
+ sort(&mut ids[..lower], pos, strings);
+ sort(&mut ids[upper..], pos, strings);
+
+ if pivot == 0 {
+ return;
+ }
+ ids = &mut ids[lower..upper];
+ pos += 1;
+ }
+}
+
+fn byte(id: usize, pos: usize, strings: &IndexSet<&[u8]>) -> u8 {
+ let string = strings.get_index(id).unwrap();
+ let len = string.len();
+ if len >= pos {
+ string[len - pos]
+ } else {
+ // We know the strings don't contain null bytes.
+ 0
+ }
+}
+
+#[cfg(test)]
+mod tests {
+ use super::*;
+
+ #[test]
+ fn string_table() {
+ let mut table = StringTable::default();
+ let id0 = table.add(b"");
+ let id1 = table.add(b"foo");
+ let id2 = table.add(b"bar");
+ let id3 = table.add(b"foobar");
+
+ let mut data = Vec::new();
+ data.push(0);
+ table.write(1, &mut data);
+ assert_eq!(data, b"\0foobar\0foo\0");
+
+ assert_eq!(table.get_offset(id0), 11);
+ assert_eq!(table.get_offset(id1), 8);
+ assert_eq!(table.get_offset(id2), 4);
+ assert_eq!(table.get_offset(id3), 1);
+ }
+}
diff --git a/vendor/object/src/write/util.rs b/vendor/object/src/write/util.rs
new file mode 100644
index 0000000..f7ee2f4
--- /dev/null
+++ b/vendor/object/src/write/util.rs
@@ -0,0 +1,260 @@
+use alloc::vec::Vec;
+#[cfg(feature = "std")]
+use std::{io, mem};
+
+use crate::pod::{bytes_of, bytes_of_slice, Pod};
+
+/// Trait for writable buffer.
+#[allow(clippy::len_without_is_empty)]
+pub trait WritableBuffer {
+ /// Returns position/offset for data to be written at.
+ ///
+ /// Should only be used in debug assertions
+ fn len(&self) -> usize;
+
+ /// Reserves specified number of bytes in the buffer.
+ ///
+ /// This will be called exactly once before writing anything to the buffer,
+ /// and the given size is the exact total number of bytes that will be written.
+ fn reserve(&mut self, size: usize) -> Result<(), ()>;
+
+ /// Writes zero bytes at the end of the buffer until the buffer
+ /// has the specified length.
+ fn resize(&mut self, new_len: usize);
+
+ /// Writes the specified slice of bytes at the end of the buffer.
+ fn write_bytes(&mut self, val: &[u8]);
+
+ /// Writes the specified `Pod` type at the end of the buffer.
+ fn write_pod<T: Pod>(&mut self, val: &T)
+ where
+ Self: Sized,
+ {
+ self.write_bytes(bytes_of(val))
+ }
+
+ /// Writes the specified `Pod` slice at the end of the buffer.
+ fn write_pod_slice<T: Pod>(&mut self, val: &[T])
+ where
+ Self: Sized,
+ {
+ self.write_bytes(bytes_of_slice(val))
+ }
+}
+
+impl<'a> dyn WritableBuffer + 'a {
+ /// Writes the specified `Pod` type at the end of the buffer.
+ pub fn write<T: Pod>(&mut self, val: &T) {
+ self.write_bytes(bytes_of(val))
+ }
+
+ /// Writes the specified `Pod` slice at the end of the buffer.
+ pub fn write_slice<T: Pod>(&mut self, val: &[T]) {
+ self.write_bytes(bytes_of_slice(val))
+ }
+}
+
+impl WritableBuffer for Vec<u8> {
+ #[inline]
+ fn len(&self) -> usize {
+ self.len()
+ }
+
+ #[inline]
+ fn reserve(&mut self, size: usize) -> Result<(), ()> {
+ debug_assert!(self.is_empty());
+ self.reserve(size);
+ Ok(())
+ }
+
+ #[inline]
+ fn resize(&mut self, new_len: usize) {
+ debug_assert!(new_len >= self.len());
+ self.resize(new_len, 0);
+ }
+
+ #[inline]
+ fn write_bytes(&mut self, val: &[u8]) {
+ debug_assert!(self.len() + val.len() <= self.capacity());
+ self.extend_from_slice(val)
+ }
+}
+
+/// A [`WritableBuffer`] that streams data to a [`Write`](std::io::Write) implementation.
+///
+/// [`Self::result`] must be called to determine if an I/O error occurred during writing.
+///
+/// It is advisable to use a buffered writer like [`BufWriter`](std::io::BufWriter)
+/// instead of an unbuffered writer like [`File`](std::fs::File).
+#[cfg(feature = "std")]
+#[derive(Debug)]
+pub struct StreamingBuffer<W> {
+ writer: W,
+ len: usize,
+ result: Result<(), io::Error>,
+}
+
+#[cfg(feature = "std")]
+impl<W> StreamingBuffer<W> {
+ /// Create a new `StreamingBuffer` backed by the given writer.
+ pub fn new(writer: W) -> Self {
+ StreamingBuffer {
+ writer,
+ len: 0,
+ result: Ok(()),
+ }
+ }
+
+ /// Unwraps this [`StreamingBuffer`] giving back the original writer.
+ pub fn into_inner(self) -> W {
+ self.writer
+ }
+
+ /// Returns any error that occurred during writing.
+ pub fn result(&mut self) -> Result<(), io::Error> {
+ mem::replace(&mut self.result, Ok(()))
+ }
+}
+
+#[cfg(feature = "std")]
+impl<W: io::Write> WritableBuffer for StreamingBuffer<W> {
+ #[inline]
+ fn len(&self) -> usize {
+ self.len
+ }
+
+ #[inline]
+ fn reserve(&mut self, _size: usize) -> Result<(), ()> {
+ Ok(())
+ }
+
+ #[inline]
+ fn resize(&mut self, new_len: usize) {
+ debug_assert!(self.len <= new_len);
+ while self.len < new_len {
+ let write_amt = (new_len - self.len - 1) % 1024 + 1;
+ self.write_bytes(&[0; 1024][..write_amt]);
+ }
+ }
+
+ #[inline]
+ fn write_bytes(&mut self, val: &[u8]) {
+ if self.result.is_ok() {
+ self.result = self.writer.write_all(val);
+ }
+ self.len += val.len();
+ }
+}
+
+/// A trait for mutable byte slices.
+///
+/// It provides convenience methods for `Pod` types.
+pub(crate) trait BytesMut {
+ fn write_at<T: Pod>(self, offset: usize, val: &T) -> Result<(), ()>;
+}
+
+impl<'a> BytesMut for &'a mut [u8] {
+ #[inline]
+ fn write_at<T: Pod>(self, offset: usize, val: &T) -> Result<(), ()> {
+ let src = bytes_of(val);
+ let dest = self.get_mut(offset..).ok_or(())?;
+ let dest = dest.get_mut(..src.len()).ok_or(())?;
+ dest.copy_from_slice(src);
+ Ok(())
+ }
+}
+
+/// Write an unsigned number using the LEB128 encoding to a buffer.
+///
+/// Returns the number of bytes written.
+pub(crate) fn write_uleb128(buf: &mut Vec<u8>, mut val: u64) -> usize {
+ let mut len = 0;
+ loop {
+ let mut byte = (val & 0x7f) as u8;
+ val >>= 7;
+ let done = val == 0;
+ if !done {
+ byte |= 0x80;
+ }
+
+ buf.push(byte);
+ len += 1;
+
+ if done {
+ return len;
+ }
+ }
+}
+
+/// Write a signed number using the LEB128 encoding to a buffer.
+///
+/// Returns the number of bytes written.
+#[allow(dead_code)]
+pub(crate) fn write_sleb128(buf: &mut Vec<u8>, mut val: i64) -> usize {
+ let mut len = 0;
+ loop {
+ let mut byte = val as u8;
+ // Keep the sign bit for testing
+ val >>= 6;
+ let done = val == 0 || val == -1;
+ if done {
+ byte &= !0x80;
+ } else {
+ // Remove the sign bit
+ val >>= 1;
+ byte |= 0x80;
+ }
+
+ buf.push(byte);
+ len += 1;
+
+ if done {
+ return len;
+ }
+ }
+}
+
+pub(crate) fn align(offset: usize, size: usize) -> usize {
+ (offset + (size - 1)) & !(size - 1)
+}
+
+#[allow(dead_code)]
+pub(crate) fn align_u32(offset: u32, size: u32) -> u32 {
+ (offset + (size - 1)) & !(size - 1)
+}
+
+#[allow(dead_code)]
+pub(crate) fn align_u64(offset: u64, size: u64) -> u64 {
+ (offset + (size - 1)) & !(size - 1)
+}
+
+pub(crate) fn write_align(buffer: &mut dyn WritableBuffer, size: usize) {
+ let new_len = align(buffer.len(), size);
+ buffer.resize(new_len);
+}
+
+#[cfg(test)]
+mod tests {
+ use super::*;
+
+ #[test]
+ fn bytes_mut() {
+ let data = vec![0x01, 0x23, 0x45, 0x67];
+
+ let mut bytes = data.clone();
+ bytes.extend_from_slice(bytes_of(&u16::to_be(0x89ab)));
+ assert_eq!(bytes, [0x01, 0x23, 0x45, 0x67, 0x89, 0xab]);
+
+ let mut bytes = data.clone();
+ assert_eq!(bytes.write_at(0, &u16::to_be(0x89ab)), Ok(()));
+ assert_eq!(bytes, [0x89, 0xab, 0x45, 0x67]);
+
+ let mut bytes = data.clone();
+ assert_eq!(bytes.write_at(2, &u16::to_be(0x89ab)), Ok(()));
+ assert_eq!(bytes, [0x01, 0x23, 0x89, 0xab]);
+
+ assert_eq!(bytes.write_at(3, &u16::to_be(0x89ab)), Err(()));
+ assert_eq!(bytes.write_at(4, &u16::to_be(0x89ab)), Err(()));
+ assert_eq!(vec![].write_at(0, &u32::to_be(0x89ab)), Err(()));
+ }
+}
diff --git a/vendor/object/src/write/xcoff.rs b/vendor/object/src/write/xcoff.rs
new file mode 100644
index 0000000..fc58886
--- /dev/null
+++ b/vendor/object/src/write/xcoff.rs
@@ -0,0 +1,556 @@
+use core::mem;
+
+use crate::endian::{BigEndian as BE, I16, U16, U32};
+use crate::write::string::*;
+use crate::write::util::*;
+use crate::write::*;
+
+use crate::{xcoff, AddressSize};
+
+#[derive(Default, Clone, Copy)]
+struct SectionOffsets {
+ address: u64,
+ data_offset: usize,
+ reloc_offset: usize,
+}
+
+#[derive(Default, Clone, Copy)]
+struct SymbolOffsets {
+ index: usize,
+ str_id: Option<StringId>,
+ aux_count: u8,
+ storage_class: u8,
+}
+
+impl<'a> Object<'a> {
+ pub(crate) fn xcoff_section_info(
+ &self,
+ section: StandardSection,
+ ) -> (&'static [u8], &'static [u8], SectionKind, SectionFlags) {
+ match section {
+ StandardSection::Text => (&[], &b".text"[..], SectionKind::Text, SectionFlags::None),
+ StandardSection::Data => (&[], &b".data"[..], SectionKind::Data, SectionFlags::None),
+ StandardSection::ReadOnlyData
+ | StandardSection::ReadOnlyDataWithRel
+ | StandardSection::ReadOnlyString => (
+ &[],
+ &b".rdata"[..],
+ SectionKind::ReadOnlyData,
+ SectionFlags::None,
+ ),
+ StandardSection::UninitializedData => (
+ &[],
+ &b".bss"[..],
+ SectionKind::UninitializedData,
+ SectionFlags::None,
+ ),
+ StandardSection::Tls => (&[], &b".tdata"[..], SectionKind::Tls, SectionFlags::None),
+ StandardSection::UninitializedTls => (
+ &[],
+ &b".tbss"[..],
+ SectionKind::UninitializedTls,
+ SectionFlags::None,
+ ),
+ StandardSection::TlsVariables => {
+ // Unsupported section.
+ (&[], &[], SectionKind::TlsVariables, SectionFlags::None)
+ }
+ StandardSection::Common => {
+ // Unsupported section.
+ (&[], &[], SectionKind::Common, SectionFlags::None)
+ }
+ StandardSection::GnuProperty => {
+ // Unsupported section.
+ (&[], &[], SectionKind::Note, SectionFlags::None)
+ }
+ }
+ }
+
+ pub(crate) fn xcoff_fixup_relocation(&mut self, relocation: &mut Relocation) -> i64 {
+ let constant = match relocation.kind {
+ RelocationKind::Relative => relocation.addend + 4,
+ _ => relocation.addend,
+ };
+ relocation.addend -= constant;
+ constant
+ }
+
+ pub(crate) fn xcoff_write(&self, buffer: &mut dyn WritableBuffer) -> Result<()> {
+ let is_64 = match self.architecture.address_size().unwrap() {
+ AddressSize::U8 | AddressSize::U16 | AddressSize::U32 => false,
+ AddressSize::U64 => true,
+ };
+
+ let (hdr_size, sechdr_size, rel_size, sym_size) = if is_64 {
+ (
+ mem::size_of::<xcoff::FileHeader64>(),
+ mem::size_of::<xcoff::SectionHeader64>(),
+ mem::size_of::<xcoff::Rel64>(),
+ mem::size_of::<xcoff::Symbol64>(),
+ )
+ } else {
+ (
+ mem::size_of::<xcoff::FileHeader32>(),
+ mem::size_of::<xcoff::SectionHeader32>(),
+ mem::size_of::<xcoff::Rel32>(),
+ mem::size_of::<xcoff::Symbol32>(),
+ )
+ };
+
+ // Calculate offsets and build strtab.
+ let mut offset = 0;
+ let mut strtab = StringTable::default();
+ // We place the shared address 0 immediately after the section header table.
+ let mut address = 0;
+
+ // XCOFF file header.
+ offset += hdr_size;
+ // Section headers.
+ offset += self.sections.len() * sechdr_size;
+
+ // Calculate size of section data.
+ let mut section_offsets = vec![SectionOffsets::default(); self.sections.len()];
+ for (index, section) in self.sections.iter().enumerate() {
+ let len = section.data.len();
+ let sectype = section.kind;
+ // Section address should be 0 for all sections except the .text, .data, and .bss sections.
+ if sectype == SectionKind::Data
+ || sectype == SectionKind::Text
+ || sectype == SectionKind::UninitializedData
+ {
+ section_offsets[index].address = address as u64;
+ address += len;
+ address = align(address, 4);
+ } else {
+ section_offsets[index].address = 0;
+ }
+ if len != 0 {
+ // Set the default section alignment as 4.
+ offset = align(offset, 4);
+ section_offsets[index].data_offset = offset;
+ offset += len;
+ } else {
+ section_offsets[index].data_offset = 0;
+ }
+ }
+
+ // Calculate size of relocations.
+ for (index, section) in self.sections.iter().enumerate() {
+ let count = section.relocations.len();
+ if count != 0 {
+ section_offsets[index].reloc_offset = offset;
+ offset += count * rel_size;
+ } else {
+ section_offsets[index].reloc_offset = 0;
+ }
+ }
+
+ // Calculate size of symbols.
+ let mut file_str_id = None;
+ let mut symbol_offsets = vec![SymbolOffsets::default(); self.symbols.len()];
+ let mut symtab_count = 0;
+ for (index, symbol) in self.symbols.iter().enumerate() {
+ symbol_offsets[index].index = symtab_count;
+ symtab_count += 1;
+
+ let storage_class = if let SymbolFlags::Xcoff { n_sclass, .. } = symbol.flags {
+ n_sclass
+ } else {
+ match symbol.kind {
+ SymbolKind::Null => xcoff::C_NULL,
+ SymbolKind::File => xcoff::C_FILE,
+ SymbolKind::Text | SymbolKind::Data | SymbolKind::Tls => {
+ if symbol.is_local() {
+ xcoff::C_STAT
+ } else if symbol.weak {
+ xcoff::C_WEAKEXT
+ } else {
+ xcoff::C_EXT
+ }
+ }
+ SymbolKind::Section | SymbolKind::Label | SymbolKind::Unknown => {
+ return Err(Error(format!(
+ "unimplemented symbol `{}` kind {:?}",
+ symbol.name().unwrap_or(""),
+ symbol.kind
+ )));
+ }
+ }
+ };
+ symbol_offsets[index].storage_class = storage_class;
+
+ if storage_class == xcoff::C_FILE {
+ if is_64 && file_str_id.is_none() {
+ file_str_id = Some(strtab.add(b".file"));
+ }
+ if symbol.name.len() > 8 {
+ symbol_offsets[index].str_id = Some(strtab.add(&symbol.name));
+ }
+ } else if is_64 || symbol.name.len() > 8 {
+ symbol_offsets[index].str_id = Some(strtab.add(&symbol.name));
+ }
+
+ symbol_offsets[index].aux_count = 0;
+ match storage_class {
+ xcoff::C_FILE => {
+ symbol_offsets[index].aux_count = 1;
+ symtab_count += 1;
+ }
+ xcoff::C_EXT | xcoff::C_WEAKEXT | xcoff::C_HIDEXT => {
+ symbol_offsets[index].aux_count = 1;
+ symtab_count += 1;
+ }
+ // TODO: support auxiliary entry for other types of symbol.
+ _ => {}
+ }
+ }
+ let symtab_offset = offset;
+ let symtab_len = symtab_count * sym_size;
+ offset += symtab_len;
+
+ // Calculate size of strtab.
+ let strtab_offset = offset;
+ let mut strtab_data = Vec::new();
+ // First 4 bytes of strtab are the length.
+ strtab.write(4, &mut strtab_data);
+ let strtab_len = strtab_data.len() + 4;
+ offset += strtab_len;
+
+ // Start writing.
+ buffer
+ .reserve(offset)
+ .map_err(|_| Error(String::from("Cannot allocate buffer")))?;
+
+ // Write file header.
+ if is_64 {
+ let header = xcoff::FileHeader64 {
+ f_magic: U16::new(BE, xcoff::MAGIC_64),
+ f_nscns: U16::new(BE, self.sections.len() as u16),
+ f_timdat: U32::new(BE, 0),
+ f_symptr: U64::new(BE, symtab_offset as u64),
+ f_nsyms: U32::new(BE, symtab_count as u32),
+ f_opthdr: U16::new(BE, 0),
+ f_flags: match self.flags {
+ FileFlags::Xcoff { f_flags } => U16::new(BE, f_flags),
+ _ => U16::default(),
+ },
+ };
+ buffer.write(&header);
+ } else {
+ let header = xcoff::FileHeader32 {
+ f_magic: U16::new(BE, xcoff::MAGIC_32),
+ f_nscns: U16::new(BE, self.sections.len() as u16),
+ f_timdat: U32::new(BE, 0),
+ f_symptr: U32::new(BE, symtab_offset as u32),
+ f_nsyms: U32::new(BE, symtab_count as u32),
+ f_opthdr: U16::new(BE, 0),
+ f_flags: match self.flags {
+ FileFlags::Xcoff { f_flags } => U16::new(BE, f_flags),
+ _ => U16::default(),
+ },
+ };
+ buffer.write(&header);
+ }
+
+ // Write section headers.
+ for (index, section) in self.sections.iter().enumerate() {
+ let mut sectname = [0; 8];
+ sectname
+ .get_mut(..section.name.len())
+ .ok_or_else(|| {
+ Error(format!(
+ "section name `{}` is too long",
+ section.name().unwrap_or(""),
+ ))
+ })?
+ .copy_from_slice(&section.name);
+ let flags = if let SectionFlags::Xcoff { s_flags } = section.flags {
+ s_flags
+ } else {
+ match section.kind {
+ SectionKind::Text
+ | SectionKind::ReadOnlyData
+ | SectionKind::ReadOnlyString
+ | SectionKind::ReadOnlyDataWithRel => xcoff::STYP_TEXT,
+ SectionKind::Data => xcoff::STYP_DATA,
+ SectionKind::UninitializedData => xcoff::STYP_BSS,
+ SectionKind::Tls => xcoff::STYP_TDATA,
+ SectionKind::UninitializedTls => xcoff::STYP_TBSS,
+ SectionKind::OtherString => xcoff::STYP_INFO,
+ SectionKind::Debug => xcoff::STYP_DEBUG,
+ SectionKind::Other | SectionKind::Metadata => 0,
+ SectionKind::Note
+ | SectionKind::Linker
+ | SectionKind::Common
+ | SectionKind::Unknown
+ | SectionKind::TlsVariables
+ | SectionKind::Elf(_) => {
+ return Err(Error(format!(
+ "unimplemented section `{}` kind {:?}",
+ section.name().unwrap_or(""),
+ section.kind
+ )));
+ }
+ }
+ .into()
+ };
+ if is_64 {
+ let section_header = xcoff::SectionHeader64 {
+ s_name: sectname,
+ s_paddr: U64::new(BE, section_offsets[index].address),
+ // This field has the same value as the s_paddr field.
+ s_vaddr: U64::new(BE, section_offsets[index].address),
+ s_size: U64::new(BE, section.data.len() as u64),
+ s_scnptr: U64::new(BE, section_offsets[index].data_offset as u64),
+ s_relptr: U64::new(BE, section_offsets[index].reloc_offset as u64),
+ s_lnnoptr: U64::new(BE, 0),
+ s_nreloc: U32::new(BE, section.relocations.len() as u32),
+ s_nlnno: U32::new(BE, 0),
+ s_flags: U32::new(BE, flags),
+ s_reserve: U32::new(BE, 0),
+ };
+ buffer.write(&section_header);
+ } else {
+ let section_header = xcoff::SectionHeader32 {
+ s_name: sectname,
+ s_paddr: U32::new(BE, section_offsets[index].address as u32),
+ // This field has the same value as the s_paddr field.
+ s_vaddr: U32::new(BE, section_offsets[index].address as u32),
+ s_size: U32::new(BE, section.data.len() as u32),
+ s_scnptr: U32::new(BE, section_offsets[index].data_offset as u32),
+ s_relptr: U32::new(BE, section_offsets[index].reloc_offset as u32),
+ s_lnnoptr: U32::new(BE, 0),
+ // TODO: If more than 65,534 relocation entries are required, the field
+ // value will be 65535, and an STYP_OVRFLO section header will contain
+ // the actual count of relocation entries in the s_paddr field.
+ s_nreloc: U16::new(BE, section.relocations.len() as u16),
+ s_nlnno: U16::new(BE, 0),
+ s_flags: U32::new(BE, flags),
+ };
+ buffer.write(&section_header);
+ }
+ }
+
+ // Write section data.
+ for (index, section) in self.sections.iter().enumerate() {
+ let len = section.data.len();
+ if len != 0 {
+ write_align(buffer, 4);
+ debug_assert_eq!(section_offsets[index].data_offset, buffer.len());
+ buffer.write_bytes(&section.data);
+ }
+ }
+
+ // Write relocations.
+ for (index, section) in self.sections.iter().enumerate() {
+ if !section.relocations.is_empty() {
+ debug_assert_eq!(section_offsets[index].reloc_offset, buffer.len());
+ for reloc in &section.relocations {
+ let rtype = match reloc.kind {
+ RelocationKind::Absolute => xcoff::R_POS,
+ RelocationKind::Relative => xcoff::R_REL,
+ RelocationKind::Got => xcoff::R_TOC,
+ RelocationKind::Xcoff(x) => x,
+ _ => {
+ return Err(Error(format!("unimplemented relocation {:?}", reloc)));
+ }
+ };
+ if is_64 {
+ let xcoff_rel = xcoff::Rel64 {
+ r_vaddr: U64::new(BE, reloc.offset),
+ r_symndx: U32::new(BE, symbol_offsets[reloc.symbol.0].index as u32),
+ // Specifies the bit length of the relocatable reference minus one.
+ r_rsize: (reloc.size - 1),
+ r_rtype: rtype,
+ };
+ buffer.write(&xcoff_rel);
+ } else {
+ let xcoff_rel = xcoff::Rel32 {
+ r_vaddr: U32::new(BE, reloc.offset as u32),
+ r_symndx: U32::new(BE, symbol_offsets[reloc.symbol.0].index as u32),
+ r_rsize: (reloc.size - 1),
+ r_rtype: rtype,
+ };
+ buffer.write(&xcoff_rel);
+ }
+ }
+ }
+ }
+
+ // Write symbols.
+ debug_assert_eq!(symtab_offset, buffer.len());
+ for (index, symbol) in self.symbols.iter().enumerate() {
+ let (n_value, section_kind) = if let SymbolSection::Section(id) = symbol.section {
+ (
+ section_offsets[id.0].address + symbol.value,
+ self.sections[id.0].kind,
+ )
+ } else {
+ (symbol.value, SectionKind::Unknown)
+ };
+ let n_scnum = match symbol.section {
+ SymbolSection::None => {
+ debug_assert_eq!(symbol.kind, SymbolKind::File);
+ xcoff::N_DEBUG
+ }
+ SymbolSection::Undefined | SymbolSection::Common => xcoff::N_UNDEF,
+ SymbolSection::Absolute => xcoff::N_ABS,
+ SymbolSection::Section(id) => id.0 as i16 + 1,
+ };
+ let n_sclass = symbol_offsets[index].storage_class;
+ let n_type = if (symbol.scope == SymbolScope::Linkage)
+ && (n_sclass == xcoff::C_EXT
+ || n_sclass == xcoff::C_WEAKEXT
+ || n_sclass == xcoff::C_HIDEXT)
+ {
+ xcoff::SYM_V_HIDDEN
+ } else {
+ 0
+ };
+ let n_numaux = symbol_offsets[index].aux_count;
+ if is_64 {
+ let str_id = if n_sclass == xcoff::C_FILE {
+ file_str_id.unwrap()
+ } else {
+ symbol_offsets[index].str_id.unwrap()
+ };
+ let xcoff_sym = xcoff::Symbol64 {
+ n_value: U64::new(BE, n_value),
+ n_offset: U32::new(BE, strtab.get_offset(str_id) as u32),
+ n_scnum: I16::new(BE, n_scnum),
+ n_type: U16::new(BE, n_type),
+ n_sclass,
+ n_numaux,
+ };
+ buffer.write(&xcoff_sym);
+ } else {
+ let mut sym_name = [0; 8];
+ if n_sclass == xcoff::C_FILE {
+ sym_name[..5].copy_from_slice(b".file");
+ } else if symbol.name.len() <= 8 {
+ sym_name[..symbol.name.len()].copy_from_slice(&symbol.name[..]);
+ } else {
+ let str_offset = strtab.get_offset(symbol_offsets[index].str_id.unwrap());
+ sym_name[4..8].copy_from_slice(&u32::to_be_bytes(str_offset as u32));
+ }
+ let xcoff_sym = xcoff::Symbol32 {
+ n_name: sym_name,
+ n_value: U32::new(BE, n_value as u32),
+ n_scnum: I16::new(BE, n_scnum),
+ n_type: U16::new(BE, n_type),
+ n_sclass,
+ n_numaux,
+ };
+ buffer.write(&xcoff_sym);
+ }
+ // Generate auxiliary entries.
+ if n_sclass == xcoff::C_FILE {
+ debug_assert_eq!(n_numaux, 1);
+ let mut x_fname = [0; 8];
+ if symbol.name.len() <= 8 {
+ x_fname[..symbol.name.len()].copy_from_slice(&symbol.name[..]);
+ } else {
+ let str_offset = strtab.get_offset(symbol_offsets[index].str_id.unwrap());
+ x_fname[4..8].copy_from_slice(&u32::to_be_bytes(str_offset as u32));
+ }
+ if is_64 {
+ let file_aux = xcoff::FileAux64 {
+ x_fname,
+ x_fpad: Default::default(),
+ x_ftype: xcoff::XFT_FN,
+ x_freserve: Default::default(),
+ x_auxtype: xcoff::AUX_FILE,
+ };
+ buffer.write(&file_aux);
+ } else {
+ let file_aux = xcoff::FileAux32 {
+ x_fname,
+ x_fpad: Default::default(),
+ x_ftype: xcoff::XFT_FN,
+ x_freserve: Default::default(),
+ };
+ buffer.write(&file_aux);
+ }
+ } else if n_sclass == xcoff::C_EXT
+ || n_sclass == xcoff::C_WEAKEXT
+ || n_sclass == xcoff::C_HIDEXT
+ {
+ debug_assert_eq!(n_numaux, 1);
+ let (x_smtyp, x_smclas) = if let SymbolFlags::Xcoff {
+ x_smtyp, x_smclas, ..
+ } = symbol.flags
+ {
+ (x_smtyp, x_smclas)
+ } else {
+ match symbol.kind {
+ SymbolKind::Text => (xcoff::XTY_SD, xcoff::XMC_PR),
+ SymbolKind::Data => {
+ if section_kind == SectionKind::UninitializedData {
+ (xcoff::XTY_CM, xcoff::XMC_BS)
+ } else if section_kind == SectionKind::ReadOnlyData {
+ (xcoff::XTY_SD, xcoff::XMC_RO)
+ } else {
+ (xcoff::XTY_SD, xcoff::XMC_RW)
+ }
+ }
+ SymbolKind::Tls => {
+ if section_kind == SectionKind::UninitializedTls {
+ (xcoff::XTY_CM, xcoff::XMC_UL)
+ } else {
+ (xcoff::XTY_SD, xcoff::XMC_TL)
+ }
+ }
+ _ => {
+ return Err(Error(format!(
+ "unimplemented symbol `{}` kind {:?}",
+ symbol.name().unwrap_or(""),
+ symbol.kind
+ )));
+ }
+ }
+ };
+ let scnlen = if let SymbolFlags::Xcoff {
+ containing_csect: Some(containing_csect),
+ ..
+ } = symbol.flags
+ {
+ symbol_offsets[containing_csect.0].index as u64
+ } else {
+ symbol.size
+ };
+ if is_64 {
+ let csect_aux = xcoff::CsectAux64 {
+ x_scnlen_lo: U32::new(BE, (scnlen & 0xFFFFFFFF) as u32),
+ x_scnlen_hi: U32::new(BE, ((scnlen >> 32) & 0xFFFFFFFF) as u32),
+ x_parmhash: U32::new(BE, 0),
+ x_snhash: U16::new(BE, 0),
+ x_smtyp,
+ x_smclas,
+ pad: 0,
+ x_auxtype: xcoff::AUX_CSECT,
+ };
+ buffer.write(&csect_aux);
+ } else {
+ let csect_aux = xcoff::CsectAux32 {
+ x_scnlen: U32::new(BE, scnlen as u32),
+ x_parmhash: U32::new(BE, 0),
+ x_snhash: U16::new(BE, 0),
+ x_smtyp,
+ x_smclas,
+ x_stab: U32::new(BE, 0),
+ x_snstab: U16::new(BE, 0),
+ };
+ buffer.write(&csect_aux);
+ }
+ }
+ }
+
+ // Write string table.
+ debug_assert_eq!(strtab_offset, buffer.len());
+ buffer.write_bytes(&u32::to_be_bytes(strtab_len as u32));
+ buffer.write_bytes(&strtab_data);
+
+ debug_assert_eq!(offset, buffer.len());
+ Ok(())
+ }
+}