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//! Reading of the rustc metadata for rlibs and dylibs
use std::fs::File;
use std::io::Write;
use std::path::Path;
use object::write::{self, StandardSegment, Symbol, SymbolSection};
use object::{
elf, pe, Architecture, BinaryFormat, Endianness, FileFlags, Object, ObjectSection,
SectionFlags, SectionKind, SymbolFlags, SymbolKind, SymbolScope,
};
use snap::write::FrameEncoder;
use rustc_data_structures::memmap::Mmap;
use rustc_data_structures::owning_ref::OwningRef;
use rustc_data_structures::rustc_erase_owner;
use rustc_data_structures::sync::MetadataRef;
use rustc_metadata::fs::METADATA_FILENAME;
use rustc_metadata::EncodedMetadata;
use rustc_session::cstore::MetadataLoader;
use rustc_session::Session;
use rustc_target::abi::Endian;
use rustc_target::spec::{RelocModel, Target};
/// The default metadata loader. This is used by cg_llvm and cg_clif.
///
/// # Metadata location
///
/// <dl>
/// <dt>rlib</dt>
/// <dd>The metadata can be found in the `lib.rmeta` file inside of the ar archive.</dd>
/// <dt>dylib</dt>
/// <dd>The metadata can be found in the `.rustc` section of the shared library.</dd>
/// </dl>
pub struct DefaultMetadataLoader;
fn load_metadata_with(
path: &Path,
f: impl for<'a> FnOnce(&'a [u8]) -> Result<&'a [u8], String>,
) -> Result<MetadataRef, String> {
let file =
File::open(path).map_err(|e| format!("failed to open file '{}': {}", path.display(), e))?;
let data = unsafe { Mmap::map(file) }
.map_err(|e| format!("failed to mmap file '{}': {}", path.display(), e))?;
let metadata = OwningRef::new(data).try_map(f)?;
return Ok(rustc_erase_owner!(metadata.map_owner_box()));
}
impl MetadataLoader for DefaultMetadataLoader {
fn get_rlib_metadata(&self, _target: &Target, path: &Path) -> Result<MetadataRef, String> {
load_metadata_with(path, |data| {
let archive = object::read::archive::ArchiveFile::parse(&*data)
.map_err(|e| format!("failed to parse rlib '{}': {}", path.display(), e))?;
for entry_result in archive.members() {
let entry = entry_result
.map_err(|e| format!("failed to parse rlib '{}': {}", path.display(), e))?;
if entry.name() == METADATA_FILENAME.as_bytes() {
let data = entry
.data(data)
.map_err(|e| format!("failed to parse rlib '{}': {}", path.display(), e))?;
return search_for_metadata(path, data, ".rmeta");
}
}
Err(format!("metadata not found in rlib '{}'", path.display()))
})
}
fn get_dylib_metadata(&self, _target: &Target, path: &Path) -> Result<MetadataRef, String> {
load_metadata_with(path, |data| search_for_metadata(path, data, ".rustc"))
}
}
fn search_for_metadata<'a>(
path: &Path,
bytes: &'a [u8],
section: &str,
) -> Result<&'a [u8], String> {
let Ok(file) = object::File::parse(bytes) else {
// The parse above could fail for odd reasons like corruption, but for
// now we just interpret it as this target doesn't support metadata
// emission in object files so the entire byte slice itself is probably
// a metadata file. Ideally though if necessary we could at least check
// the prefix of bytes to see if it's an actual metadata object and if
// not forward the error along here.
return Ok(bytes);
};
file.section_by_name(section)
.ok_or_else(|| format!("no `{}` section in '{}'", section, path.display()))?
.data()
.map_err(|e| format!("failed to read {} section in '{}': {}", section, path.display(), e))
}
pub(crate) fn create_object_file(sess: &Session) -> Option<write::Object<'static>> {
let endianness = match sess.target.options.endian {
Endian::Little => Endianness::Little,
Endian::Big => Endianness::Big,
};
let architecture = match &sess.target.arch[..] {
"arm" => Architecture::Arm,
"aarch64" => Architecture::Aarch64,
"x86" => Architecture::I386,
"s390x" => Architecture::S390x,
"mips" => Architecture::Mips,
"mips64" => Architecture::Mips64,
"x86_64" => {
if sess.target.pointer_width == 32 {
Architecture::X86_64_X32
} else {
Architecture::X86_64
}
}
"powerpc" => Architecture::PowerPc,
"powerpc64" => Architecture::PowerPc64,
"riscv32" => Architecture::Riscv32,
"riscv64" => Architecture::Riscv64,
"sparc64" => Architecture::Sparc64,
"avr" => Architecture::Avr,
"msp430" => Architecture::Msp430,
"hexagon" => Architecture::Hexagon,
"bpf" => Architecture::Bpf,
// Unsupported architecture.
_ => return None,
};
let binary_format = if sess.target.is_like_osx {
BinaryFormat::MachO
} else if sess.target.is_like_windows {
BinaryFormat::Coff
} else {
BinaryFormat::Elf
};
let mut file = write::Object::new(binary_format, architecture, endianness);
let e_flags = match architecture {
Architecture::Mips => {
let arch = match sess.target.options.cpu.as_ref() {
"mips1" => elf::EF_MIPS_ARCH_1,
"mips2" => elf::EF_MIPS_ARCH_2,
"mips3" => elf::EF_MIPS_ARCH_3,
"mips4" => elf::EF_MIPS_ARCH_4,
"mips5" => elf::EF_MIPS_ARCH_5,
s if s.contains("r6") => elf::EF_MIPS_ARCH_32R6,
_ => elf::EF_MIPS_ARCH_32R2,
};
// The only ABI LLVM supports for 32-bit MIPS CPUs is o32.
let mut e_flags = elf::EF_MIPS_CPIC | elf::EF_MIPS_ABI_O32 | arch;
if sess.target.options.relocation_model != RelocModel::Static {
e_flags |= elf::EF_MIPS_PIC;
}
if sess.target.options.cpu.contains("r6") {
e_flags |= elf::EF_MIPS_NAN2008;
}
e_flags
}
Architecture::Mips64 => {
// copied from `mips64el-linux-gnuabi64-gcc foo.c -c`
let e_flags = elf::EF_MIPS_CPIC
| elf::EF_MIPS_PIC
| if sess.target.options.cpu.contains("r6") {
elf::EF_MIPS_ARCH_64R6 | elf::EF_MIPS_NAN2008
} else {
elf::EF_MIPS_ARCH_64R2
};
e_flags
}
Architecture::Riscv64 if sess.target.options.features.contains("+d") => {
// copied from `riscv64-linux-gnu-gcc foo.c -c`, note though
// that the `+d` target feature represents whether the double
// float abi is enabled.
let e_flags = elf::EF_RISCV_RVC | elf::EF_RISCV_FLOAT_ABI_DOUBLE;
e_flags
}
_ => 0,
};
// adapted from LLVM's `MCELFObjectTargetWriter::getOSABI`
let os_abi = match sess.target.options.os.as_ref() {
"hermit" => elf::ELFOSABI_STANDALONE,
"freebsd" => elf::ELFOSABI_FREEBSD,
"solaris" => elf::ELFOSABI_SOLARIS,
_ => elf::ELFOSABI_NONE,
};
let abi_version = 0;
file.flags = FileFlags::Elf { os_abi, abi_version, e_flags };
Some(file)
}
pub enum MetadataPosition {
First,
Last,
}
// For rlibs we "pack" rustc metadata into a dummy object file.
//
// Historically it was needed because rustc linked rlibs as whole-archive in some cases.
// In that case linkers try to include all files located in an archive, so if metadata is stored
// in an archive then it needs to be of a form that the linker is able to process.
// Now it's not clear whether metadata still needs to be wrapped into an object file or not.
//
// Note, though, that we don't actually want this metadata to show up in any
// final output of the compiler. Instead this is purely for rustc's own
// metadata tracking purposes.
//
// With the above in mind, each "flavor" of object format gets special
// handling here depending on the target:
//
// * MachO - macos-like targets will insert the metadata into a section that
// is sort of fake dwarf debug info. Inspecting the source of the macos
// linker this causes these sections to be skipped automatically because
// it's not in an allowlist of otherwise well known dwarf section names to
// go into the final artifact.
//
// * WebAssembly - we actually don't have any container format for this
// target. WebAssembly doesn't support the `dylib` crate type anyway so
// there's no need for us to support this at this time. Consequently the
// metadata bytes are simply stored as-is into an rlib.
//
// * COFF - Windows-like targets create an object with a section that has
// the `IMAGE_SCN_LNK_REMOVE` flag set which ensures that if the linker
// ever sees the section it doesn't process it and it's removed.
//
// * ELF - All other targets are similar to Windows in that there's a
// `SHF_EXCLUDE` flag we can set on sections in an object file to get
// automatically removed from the final output.
pub fn create_rmeta_file(sess: &Session, metadata: &[u8]) -> (Vec<u8>, MetadataPosition) {
let Some(mut file) = create_object_file(sess) else {
// This is used to handle all "other" targets. This includes targets
// in two categories:
//
// * Some targets don't have support in the `object` crate just yet
// to write an object file. These targets are likely to get filled
// out over time.
//
// * Targets like WebAssembly don't support dylibs, so the purpose
// of putting metadata in object files, to support linking rlibs
// into dylibs, is moot.
//
// In both of these cases it means that linking into dylibs will
// not be supported by rustc. This doesn't matter for targets like
// WebAssembly and for targets not supported by the `object` crate
// yet it means that work will need to be done in the `object` crate
// to add a case above.
return (metadata.to_vec(), MetadataPosition::Last);
};
let section = file.add_section(
file.segment_name(StandardSegment::Debug).to_vec(),
b".rmeta".to_vec(),
SectionKind::Debug,
);
match file.format() {
BinaryFormat::Coff => {
file.section_mut(section).flags =
SectionFlags::Coff { characteristics: pe::IMAGE_SCN_LNK_REMOVE };
}
BinaryFormat::Elf => {
file.section_mut(section).flags =
SectionFlags::Elf { sh_flags: elf::SHF_EXCLUDE as u64 };
}
_ => {}
};
file.append_section_data(section, metadata, 1);
(file.write().unwrap(), MetadataPosition::First)
}
// Historical note:
//
// When using link.exe it was seen that the section name `.note.rustc`
// was getting shortened to `.note.ru`, and according to the PE and COFF
// specification:
//
// > Executable images do not use a string table and do not support
// > section names longer than 8 characters
//
// https://docs.microsoft.com/en-us/windows/win32/debug/pe-format
//
// As a result, we choose a slightly shorter name! As to why
// `.note.rustc` works on MinGW, see
// https://github.com/llvm/llvm-project/blob/llvmorg-12.0.0/lld/COFF/Writer.cpp#L1190-L1197
pub fn create_compressed_metadata_file(
sess: &Session,
metadata: &EncodedMetadata,
symbol_name: &str,
) -> Vec<u8> {
let mut compressed = rustc_metadata::METADATA_HEADER.to_vec();
FrameEncoder::new(&mut compressed).write_all(metadata.raw_data()).unwrap();
let Some(mut file) = create_object_file(sess) else {
return compressed.to_vec();
};
let section = file.add_section(
file.segment_name(StandardSegment::Data).to_vec(),
b".rustc".to_vec(),
SectionKind::ReadOnlyData,
);
match file.format() {
BinaryFormat::Elf => {
// Explicitly set no flags to avoid SHF_ALLOC default for data section.
file.section_mut(section).flags = SectionFlags::Elf { sh_flags: 0 };
}
_ => {}
};
let offset = file.append_section_data(section, &compressed, 1);
// For MachO and probably PE this is necessary to prevent the linker from throwing away the
// .rustc section. For ELF this isn't necessary, but it also doesn't harm.
file.add_symbol(Symbol {
name: symbol_name.as_bytes().to_vec(),
value: offset,
size: compressed.len() as u64,
kind: SymbolKind::Data,
scope: SymbolScope::Dynamic,
weak: false,
section: SymbolSection::Section(section),
flags: SymbolFlags::None,
});
file.write().unwrap()
}
|