//! Interface for reading object files. use alloc::borrow::Cow; use alloc::vec::Vec; use core::{fmt, result}; use crate::common::*; mod read_ref; pub use read_ref::*; #[cfg(feature = "std")] mod read_cache; #[cfg(feature = "std")] pub use read_cache::*; mod util; pub use util::*; #[cfg(any( feature = "coff", feature = "elf", feature = "macho", feature = "pe", feature = "wasm", feature = "xcoff" ))] mod any; #[cfg(any( feature = "coff", feature = "elf", feature = "macho", feature = "pe", feature = "wasm", feature = "xcoff" ))] pub use any::*; #[cfg(feature = "archive")] pub mod archive; #[cfg(feature = "coff")] pub mod coff; #[cfg(feature = "elf")] pub mod elf; #[cfg(feature = "macho")] pub mod macho; #[cfg(feature = "pe")] pub mod pe; #[cfg(feature = "wasm")] pub mod wasm; #[cfg(feature = "xcoff")] pub mod xcoff; mod traits; pub use traits::*; mod private { pub trait Sealed {} } /// The error type used within the read module. #[derive(Debug, Clone, Copy, PartialEq, Eq)] pub struct Error(&'static str); impl fmt::Display for Error { #[inline] fn fmt(&self, f: &mut fmt::Formatter<'_>) -> fmt::Result { f.write_str(self.0) } } #[cfg(feature = "std")] impl std::error::Error for Error {} /// The result type used within the read module. pub type Result = result::Result; trait ReadError { fn read_error(self, error: &'static str) -> Result; } impl ReadError for result::Result { fn read_error(self, error: &'static str) -> Result { self.map_err(|()| Error(error)) } } impl ReadError for result::Result { fn read_error(self, error: &'static str) -> Result { self.map_err(|_| Error(error)) } } impl ReadError for Option { fn read_error(self, error: &'static str) -> Result { self.ok_or(Error(error)) } } /// The native executable file for the target platform. #[cfg(all( unix, not(target_os = "macos"), target_pointer_width = "32", feature = "elf" ))] pub type NativeFile<'data, R = &'data [u8]> = elf::ElfFile32<'data, crate::Endianness, R>; /// The native executable file for the target platform. #[cfg(all( unix, not(target_os = "macos"), target_pointer_width = "64", feature = "elf" ))] pub type NativeFile<'data, R = &'data [u8]> = elf::ElfFile64<'data, crate::Endianness, R>; /// The native executable file for the target platform. #[cfg(all(target_os = "macos", target_pointer_width = "32", feature = "macho"))] pub type NativeFile<'data, R = &'data [u8]> = macho::MachOFile32<'data, crate::Endianness, R>; /// The native executable file for the target platform. #[cfg(all(target_os = "macos", target_pointer_width = "64", feature = "macho"))] pub type NativeFile<'data, R = &'data [u8]> = macho::MachOFile64<'data, crate::Endianness, R>; /// The native executable file for the target platform. #[cfg(all(target_os = "windows", target_pointer_width = "32", feature = "pe"))] pub type NativeFile<'data, R = &'data [u8]> = pe::PeFile32<'data, R>; /// The native executable file for the target platform. #[cfg(all(target_os = "windows", target_pointer_width = "64", feature = "pe"))] pub type NativeFile<'data, R = &'data [u8]> = pe::PeFile64<'data, R>; /// The native executable file for the target platform. #[cfg(all(feature = "wasm", target_arch = "wasm32", feature = "wasm"))] pub type NativeFile<'data, R = &'data [u8]> = wasm::WasmFile<'data, R>; /// A file format kind. #[derive(Debug, Clone, Copy, PartialEq, Eq, Hash)] #[non_exhaustive] pub enum FileKind { /// A Unix archive. #[cfg(feature = "archive")] Archive, /// A COFF object file. #[cfg(feature = "coff")] Coff, /// A COFF bigobj object file. /// /// This supports a larger number of sections. #[cfg(feature = "coff")] CoffBig, /// A dyld cache file containing Mach-O images. #[cfg(feature = "macho")] DyldCache, /// A 32-bit ELF file. #[cfg(feature = "elf")] Elf32, /// A 64-bit ELF file. #[cfg(feature = "elf")] Elf64, /// A 32-bit Mach-O file. #[cfg(feature = "macho")] MachO32, /// A 64-bit Mach-O file. #[cfg(feature = "macho")] MachO64, /// A 32-bit Mach-O fat binary. #[cfg(feature = "macho")] MachOFat32, /// A 64-bit Mach-O fat binary. #[cfg(feature = "macho")] MachOFat64, /// A 32-bit PE file. #[cfg(feature = "pe")] Pe32, /// A 64-bit PE file. #[cfg(feature = "pe")] Pe64, /// A Wasm file. #[cfg(feature = "wasm")] Wasm, /// A 32-bit XCOFF file. #[cfg(feature = "xcoff")] Xcoff32, /// A 64-bit XCOFF file. #[cfg(feature = "xcoff")] Xcoff64, } impl FileKind { /// Determine a file kind by parsing the start of the file. pub fn parse<'data, R: ReadRef<'data>>(data: R) -> Result { Self::parse_at(data, 0) } /// Determine a file kind by parsing at the given offset. pub fn parse_at<'data, R: ReadRef<'data>>(data: R, offset: u64) -> Result { let magic = data .read_bytes_at(offset, 16) .read_error("Could not read file magic")?; if magic.len() < 16 { return Err(Error("File too short")); } let kind = match [magic[0], magic[1], magic[2], magic[3], magic[4], magic[5], magic[6], magic[7]] { #[cfg(feature = "archive")] [b'!', b'<', b'a', b'r', b'c', b'h', b'>', b'\n'] => FileKind::Archive, #[cfg(feature = "macho")] [b'd', b'y', b'l', b'd', b'_', b'v', b'1', b' '] => FileKind::DyldCache, #[cfg(feature = "elf")] [0x7f, b'E', b'L', b'F', 1, ..] => FileKind::Elf32, #[cfg(feature = "elf")] [0x7f, b'E', b'L', b'F', 2, ..] => FileKind::Elf64, #[cfg(feature = "macho")] [0xfe, 0xed, 0xfa, 0xce, ..] | [0xce, 0xfa, 0xed, 0xfe, ..] => FileKind::MachO32, #[cfg(feature = "macho")] | [0xfe, 0xed, 0xfa, 0xcf, ..] | [0xcf, 0xfa, 0xed, 0xfe, ..] => FileKind::MachO64, #[cfg(feature = "macho")] [0xca, 0xfe, 0xba, 0xbe, ..] => FileKind::MachOFat32, #[cfg(feature = "macho")] [0xca, 0xfe, 0xba, 0xbf, ..] => FileKind::MachOFat64, #[cfg(feature = "wasm")] [0x00, b'a', b's', b'm', ..] => FileKind::Wasm, #[cfg(feature = "pe")] [b'M', b'Z', ..] if offset == 0 => { match pe::optional_header_magic(data) { Ok(crate::pe::IMAGE_NT_OPTIONAL_HDR32_MAGIC) => { FileKind::Pe32 } Ok(crate::pe::IMAGE_NT_OPTIONAL_HDR64_MAGIC) => { FileKind::Pe64 } _ => return Err(Error("Unknown MS-DOS file")), } } // TODO: more COFF machines #[cfg(feature = "coff")] // COFF arm [0xc4, 0x01, ..] // COFF arm64 | [0x64, 0xaa, ..] // COFF x86 | [0x4c, 0x01, ..] // COFF x86-64 | [0x64, 0x86, ..] => FileKind::Coff, #[cfg(feature = "coff")] [0x00, 0x00, 0xff, 0xff, 0x02, 0x00, ..] if offset == 0 => { match coff::anon_object_class_id(data) { Ok(crate::pe::ANON_OBJECT_HEADER_BIGOBJ_CLASS_ID) => FileKind::CoffBig, _ => return Err(Error("Unknown anon object file")), } } #[cfg(feature = "xcoff")] [0x01, 0xDF, ..] => FileKind::Xcoff32, #[cfg(feature = "xcoff")] [0x01, 0xF7, ..] => FileKind::Xcoff64, _ => return Err(Error("Unknown file magic")), }; Ok(kind) } } /// An object kind. #[derive(Debug, Clone, Copy, PartialEq, Eq, Hash)] #[non_exhaustive] pub enum ObjectKind { /// The object kind is unknown. Unknown, /// Relocatable object. Relocatable, /// Executable. Executable, /// Dynamic shared object. Dynamic, /// Core. Core, } /// The index used to identify a section of a file. #[derive(Debug, Clone, Copy, PartialEq, Eq, Hash)] pub struct SectionIndex(pub usize); /// The index used to identify a symbol of a file. #[derive(Debug, Clone, Copy, PartialEq, Eq, Hash)] pub struct SymbolIndex(pub usize); /// The section where a symbol is defined. #[derive(Debug, Clone, Copy, PartialEq, Eq, Hash)] #[non_exhaustive] pub enum SymbolSection { /// The section is unknown. Unknown, /// 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(SectionIndex), } impl SymbolSection { /// Returns the section index for the section where the symbol is defined. /// /// May return `None` if the symbol is not defined in a section. #[inline] pub fn index(self) -> Option { if let SymbolSection::Section(index) = self { Some(index) } else { None } } } /// An entry in a `SymbolMap`. pub trait SymbolMapEntry { /// The symbol address. fn address(&self) -> u64; } /// A map from addresses to symbols. #[derive(Debug, Default, Clone)] pub struct SymbolMap { symbols: Vec, } impl SymbolMap { /// Construct a new symbol map. /// /// This function will sort the symbols by address. pub fn new(mut symbols: Vec) -> Self { symbols.sort_unstable_by_key(|s| s.address()); SymbolMap { symbols } } /// Get the symbol before the given address. pub fn get(&self, address: u64) -> Option<&T> { let index = match self .symbols .binary_search_by_key(&address, |symbol| symbol.address()) { Ok(index) => index, Err(index) => index.checked_sub(1)?, }; self.symbols.get(index) } /// Get all symbols in the map. #[inline] pub fn symbols(&self) -> &[T] { &self.symbols } } /// A `SymbolMap` entry for symbol names. #[derive(Debug, Clone, Copy, PartialEq, Eq, Hash)] pub struct SymbolMapName<'data> { address: u64, name: &'data str, } impl<'data> SymbolMapName<'data> { /// Construct a `SymbolMapName`. pub fn new(address: u64, name: &'data str) -> Self { SymbolMapName { address, name } } /// The symbol address. #[inline] pub fn address(&self) -> u64 { self.address } /// The symbol name. #[inline] pub fn name(&self) -> &'data str { self.name } } impl<'data> SymbolMapEntry for SymbolMapName<'data> { #[inline] fn address(&self) -> u64 { self.address } } /// A map from addresses to symbol names and object files. /// /// This is derived from STAB entries in Mach-O files. #[derive(Debug, Default, Clone)] pub struct ObjectMap<'data> { symbols: SymbolMap>, objects: Vec<&'data [u8]>, } impl<'data> ObjectMap<'data> { /// Get the entry containing the given address. pub fn get(&self, address: u64) -> Option<&ObjectMapEntry<'data>> { self.symbols .get(address) .filter(|entry| entry.size == 0 || address.wrapping_sub(entry.address) < entry.size) } /// Get all symbols in the map. #[inline] pub fn symbols(&self) -> &[ObjectMapEntry<'data>] { self.symbols.symbols() } /// Get all objects in the map. #[inline] pub fn objects(&self) -> &[&'data [u8]] { &self.objects } } /// A `ObjectMap` entry. #[derive(Debug, Default, Clone, Copy, PartialEq, Eq, Hash)] pub struct ObjectMapEntry<'data> { address: u64, size: u64, name: &'data [u8], object: usize, } impl<'data> ObjectMapEntry<'data> { /// Get the symbol address. #[inline] pub fn address(&self) -> u64 { self.address } /// Get the symbol size. /// /// This may be 0 if the size is unknown. #[inline] pub fn size(&self) -> u64 { self.size } /// Get the symbol name. #[inline] pub fn name(&self) -> &'data [u8] { self.name } /// Get the index of the object file name. #[inline] pub fn object_index(&self) -> usize { self.object } /// Get the object file name. #[inline] pub fn object(&self, map: &ObjectMap<'data>) -> &'data [u8] { map.objects[self.object] } } impl<'data> SymbolMapEntry for ObjectMapEntry<'data> { #[inline] fn address(&self) -> u64 { self.address } } /// An imported symbol. #[derive(Debug, Clone, Copy, PartialEq, Eq)] pub struct Import<'data> { library: ByteString<'data>, // TODO: or ordinal name: ByteString<'data>, } impl<'data> Import<'data> { /// The symbol name. #[inline] pub fn name(&self) -> &'data [u8] { self.name.0 } /// The name of the library to import the symbol from. #[inline] pub fn library(&self) -> &'data [u8] { self.library.0 } } /// An exported symbol. #[derive(Debug, Clone, Copy, PartialEq, Eq)] pub struct Export<'data> { // TODO: and ordinal? name: ByteString<'data>, address: u64, } impl<'data> Export<'data> { /// The symbol name. #[inline] pub fn name(&self) -> &'data [u8] { self.name.0 } /// The virtual address of the symbol. #[inline] pub fn address(&self) -> u64 { self.address } } /// PDB Information #[derive(Debug, Clone, Copy, PartialEq, Eq)] pub struct CodeView<'data> { guid: [u8; 16], path: ByteString<'data>, age: u32, } impl<'data> CodeView<'data> { /// The path to the PDB as stored in CodeView #[inline] pub fn path(&self) -> &'data [u8] { self.path.0 } /// The age of the PDB #[inline] pub fn age(&self) -> u32 { self.age } /// The GUID of the PDB. #[inline] pub fn guid(&self) -> [u8; 16] { self.guid } } /// The target referenced by a relocation. #[derive(Debug, Clone, Copy, PartialEq, Eq, Hash)] #[non_exhaustive] pub enum RelocationTarget { /// The target is a symbol. Symbol(SymbolIndex), /// The target is a section. Section(SectionIndex), /// The offset is an absolute address. Absolute, } /// A relocation entry. #[derive(Debug)] pub struct Relocation { kind: RelocationKind, encoding: RelocationEncoding, size: u8, target: RelocationTarget, addend: i64, implicit_addend: bool, } impl Relocation { /// The operation used to calculate the result of the relocation. #[inline] pub fn kind(&self) -> RelocationKind { self.kind } /// Information about how the result of the relocation operation is encoded in the place. #[inline] pub fn encoding(&self) -> RelocationEncoding { self.encoding } /// The size in bits of the place of the relocation. /// /// If 0, then the size is determined by the relocation kind. #[inline] pub fn size(&self) -> u8 { self.size } /// The target of the relocation. #[inline] pub fn target(&self) -> RelocationTarget { self.target } /// The addend to use in the relocation calculation. #[inline] pub fn addend(&self) -> i64 { self.addend } /// Set the addend to use in the relocation calculation. #[inline] pub fn set_addend(&mut self, addend: i64) { self.addend = addend } /// Returns true if there is an implicit addend stored in the data at the offset /// to be relocated. #[inline] pub fn has_implicit_addend(&self) -> bool { self.implicit_addend } } /// A data compression format. #[derive(Debug, Clone, Copy, PartialEq, Eq, Hash)] #[non_exhaustive] pub enum CompressionFormat { /// The data is uncompressed. None, /// The data is compressed, but the compression format is unknown. Unknown, /// ZLIB/DEFLATE. /// /// Used for ELF compression and GNU compressed debug information. Zlib, /// Zstandard. /// /// Used for ELF compression. Zstandard, } /// A range in a file that may be compressed. #[derive(Debug, Clone, Copy, PartialEq, Eq, Hash)] pub struct CompressedFileRange { /// The data compression format. pub format: CompressionFormat, /// The file offset of the compressed data. pub offset: u64, /// The compressed data size. pub compressed_size: u64, /// The uncompressed data size. pub uncompressed_size: u64, } impl CompressedFileRange { /// Data that is uncompressed. #[inline] pub fn none(range: Option<(u64, u64)>) -> Self { if let Some((offset, size)) = range { CompressedFileRange { format: CompressionFormat::None, offset, compressed_size: size, uncompressed_size: size, } } else { CompressedFileRange { format: CompressionFormat::None, offset: 0, compressed_size: 0, uncompressed_size: 0, } } } /// Convert to `CompressedData` by reading from the file. pub fn data<'data, R: ReadRef<'data>>(self, file: R) -> Result> { let data = file .read_bytes_at(self.offset, self.compressed_size) .read_error("Invalid compressed data size or offset")?; Ok(CompressedData { format: self.format, data, uncompressed_size: self.uncompressed_size, }) } } /// Data that may be compressed. #[derive(Debug, Clone, Copy, PartialEq, Eq, Hash)] pub struct CompressedData<'data> { /// The data compression format. pub format: CompressionFormat, /// The compressed data. pub data: &'data [u8], /// The uncompressed data size. pub uncompressed_size: u64, } impl<'data> CompressedData<'data> { /// Data that is uncompressed. #[inline] pub fn none(data: &'data [u8]) -> Self { CompressedData { format: CompressionFormat::None, data, uncompressed_size: data.len() as u64, } } /// Return the uncompressed data. /// /// Returns an error for invalid data or unsupported compression. /// This includes if the data is compressed but the `compression` feature /// for this crate is disabled. pub fn decompress(self) -> Result> { match self.format { CompressionFormat::None => Ok(Cow::Borrowed(self.data)), #[cfg(feature = "compression")] CompressionFormat::Zlib => { use core::convert::TryInto; let size = self .uncompressed_size .try_into() .ok() .read_error("Uncompressed data size is too large.")?; let mut decompressed = Vec::with_capacity(size); let mut decompress = flate2::Decompress::new(true); decompress .decompress_vec( self.data, &mut decompressed, flate2::FlushDecompress::Finish, ) .ok() .read_error("Invalid zlib compressed data")?; Ok(Cow::Owned(decompressed)) } #[cfg(feature = "compression")] CompressionFormat::Zstandard => { use core::convert::TryInto; use std::io::Read; let size = self .uncompressed_size .try_into() .ok() .read_error("Uncompressed data size is too large.")?; let mut decompressed = Vec::with_capacity(size); let mut decoder = ruzstd::StreamingDecoder::new(self.data) .ok() .read_error("Invalid zstd compressed data")?; decoder .read_to_end(&mut decompressed) .ok() .read_error("Invalid zstd compressed data")?; Ok(Cow::Owned(decompressed)) } _ => Err(Error("Unsupported compressed data.")), } } }