use super::symbol_export; use super::command::Command; use super::archive; use rustc_data_structures::fx::FxHashMap; use std::ffi::{OsStr, OsString}; use std::fs::{self, File}; use std::io::prelude::*; use std::io::{self, BufWriter}; use std::path::{Path, PathBuf}; use rustc::hir::def_id::{LOCAL_CRATE, CrateNum}; use rustc::middle::dependency_format::Linkage; use rustc::session::Session; use rustc::session::config::{self, CrateType, OptLevel, DebugInfo, LinkerPluginLto, Lto}; use rustc::ty::TyCtxt; use rustc_target::spec::{LinkerFlavor, LldFlavor}; use rustc_serialize::{json, Encoder}; /// For all the linkers we support, and information they might /// need out of the shared crate context before we get rid of it. pub struct LinkerInfo { exports: FxHashMap>, } impl LinkerInfo { pub fn new(tcx: TyCtxt<'_>) -> LinkerInfo { LinkerInfo { exports: tcx.sess.crate_types.borrow().iter().map(|&c| { (c, exported_symbols(tcx, c)) }).collect(), } } pub fn to_linker<'a>( &'a self, cmd: Command, sess: &'a Session, flavor: LinkerFlavor, target_cpu: &'a str, ) -> Box { match flavor { LinkerFlavor::Lld(LldFlavor::Link) | LinkerFlavor::Msvc => { Box::new(MsvcLinker { cmd, sess, info: self }) as Box } LinkerFlavor::Em => { Box::new(EmLinker { cmd, sess, info: self }) as Box } LinkerFlavor::Gcc => { Box::new(GccLinker { cmd, sess, info: self, hinted_static: false, is_ld: false, target_cpu, }) as Box } LinkerFlavor::Lld(LldFlavor::Ld) | LinkerFlavor::Lld(LldFlavor::Ld64) | LinkerFlavor::Ld => { Box::new(GccLinker { cmd, sess, info: self, hinted_static: false, is_ld: true, target_cpu, }) as Box } LinkerFlavor::Lld(LldFlavor::Wasm) => { Box::new(WasmLd::new(cmd, sess, self)) as Box } LinkerFlavor::PtxLinker => { Box::new(PtxLinker { cmd, sess }) as Box } } } } /// Linker abstraction used by `back::link` to build up the command to invoke a /// linker. /// /// This trait is the total list of requirements needed by `back::link` and /// represents the meaning of each option being passed down. This trait is then /// used to dispatch on whether a GNU-like linker (generally `ld.exe`) or an /// MSVC linker (e.g., `link.exe`) is being used. pub trait Linker { fn link_dylib(&mut self, lib: &str); fn link_rust_dylib(&mut self, lib: &str, path: &Path); fn link_framework(&mut self, framework: &str); fn link_staticlib(&mut self, lib: &str); fn link_rlib(&mut self, lib: &Path); fn link_whole_rlib(&mut self, lib: &Path); fn link_whole_staticlib(&mut self, lib: &str, search_path: &[PathBuf]); fn include_path(&mut self, path: &Path); fn framework_path(&mut self, path: &Path); fn output_filename(&mut self, path: &Path); fn add_object(&mut self, path: &Path); fn gc_sections(&mut self, keep_metadata: bool); fn position_independent_executable(&mut self); fn no_position_independent_executable(&mut self); fn full_relro(&mut self); fn partial_relro(&mut self); fn no_relro(&mut self); fn optimize(&mut self); fn pgo_gen(&mut self); fn debuginfo(&mut self); fn no_default_libraries(&mut self); fn build_dylib(&mut self, out_filename: &Path); fn build_static_executable(&mut self); fn args(&mut self, args: &[String]); fn export_symbols(&mut self, tmpdir: &Path, crate_type: CrateType); fn subsystem(&mut self, subsystem: &str); fn group_start(&mut self); fn group_end(&mut self); fn linker_plugin_lto(&mut self); // Should have been finalize(self), but we don't support self-by-value on trait objects (yet?). fn finalize(&mut self) -> Command; } pub struct GccLinker<'a> { cmd: Command, sess: &'a Session, info: &'a LinkerInfo, hinted_static: bool, // Keeps track of the current hinting mode. // Link as ld is_ld: bool, target_cpu: &'a str, } impl<'a> GccLinker<'a> { /// Argument that must be passed *directly* to the linker /// /// These arguments need to be prepended with `-Wl`, when a GCC-style linker is used. fn linker_arg(&mut self, arg: S) -> &mut Self where S: AsRef { if !self.is_ld { let mut os = OsString::from("-Wl,"); os.push(arg.as_ref()); self.cmd.arg(os); } else { self.cmd.arg(arg); } self } fn takes_hints(&self) -> bool { // Really this function only returns true if the underlying linker // configured for a compiler is binutils `ld.bfd` and `ld.gold`. We // don't really have a foolproof way to detect that, so rule out some // platforms where currently this is guaranteed to *not* be the case: // // * On OSX they have their own linker, not binutils' // * For WebAssembly the only functional linker is LLD, which doesn't // support hint flags !self.sess.target.target.options.is_like_osx && self.sess.target.target.arch != "wasm32" } // Some platforms take hints about whether a library is static or dynamic. // For those that support this, we ensure we pass the option if the library // was flagged "static" (most defaults are dynamic) to ensure that if // libfoo.a and libfoo.so both exist that the right one is chosen. fn hint_static(&mut self) { if !self.takes_hints() { return } if !self.hinted_static { self.linker_arg("-Bstatic"); self.hinted_static = true; } } fn hint_dynamic(&mut self) { if !self.takes_hints() { return } if self.hinted_static { self.linker_arg("-Bdynamic"); self.hinted_static = false; } } fn push_linker_plugin_lto_args(&mut self, plugin_path: Option<&OsStr>) { if let Some(plugin_path) = plugin_path { let mut arg = OsString::from("-plugin="); arg.push(plugin_path); self.linker_arg(&arg); } let opt_level = match self.sess.opts.optimize { config::OptLevel::No => "O0", config::OptLevel::Less => "O1", config::OptLevel::Default => "O2", config::OptLevel::Aggressive => "O3", config::OptLevel::Size => "Os", config::OptLevel::SizeMin => "Oz", }; self.linker_arg(&format!("-plugin-opt={}", opt_level)); let target_cpu = self.target_cpu; self.linker_arg(&format!("-plugin-opt=mcpu={}", target_cpu)); } } impl<'a> Linker for GccLinker<'a> { fn link_dylib(&mut self, lib: &str) { self.hint_dynamic(); self.cmd.arg(format!("-l{}", lib)); } fn link_staticlib(&mut self, lib: &str) { self.hint_static(); self.cmd.arg(format!("-l{}", lib)); } fn link_rlib(&mut self, lib: &Path) { self.hint_static(); self.cmd.arg(lib); } fn include_path(&mut self, path: &Path) { self.cmd.arg("-L").arg(path); } fn framework_path(&mut self, path: &Path) { self.cmd.arg("-F").arg(path); } fn output_filename(&mut self, path: &Path) { self.cmd.arg("-o").arg(path); } fn add_object(&mut self, path: &Path) { self.cmd.arg(path); } fn position_independent_executable(&mut self) { self.cmd.arg("-pie"); } fn no_position_independent_executable(&mut self) { self.cmd.arg("-no-pie"); } fn full_relro(&mut self) { self.linker_arg("-zrelro"); self.linker_arg("-znow"); } fn partial_relro(&mut self) { self.linker_arg("-zrelro"); } fn no_relro(&mut self) { self.linker_arg("-znorelro"); } fn build_static_executable(&mut self) { self.cmd.arg("-static"); } fn args(&mut self, args: &[String]) { self.cmd.args(args); } fn link_rust_dylib(&mut self, lib: &str, _path: &Path) { self.hint_dynamic(); self.cmd.arg(format!("-l{}", lib)); } fn link_framework(&mut self, framework: &str) { self.hint_dynamic(); self.cmd.arg("-framework").arg(framework); } // Here we explicitly ask that the entire archive is included into the // result artifact. For more details see #15460, but the gist is that // the linker will strip away any unused objects in the archive if we // don't otherwise explicitly reference them. This can occur for // libraries which are just providing bindings, libraries with generic // functions, etc. fn link_whole_staticlib(&mut self, lib: &str, search_path: &[PathBuf]) { self.hint_static(); let target = &self.sess.target.target; if !target.options.is_like_osx { self.linker_arg("--whole-archive").cmd.arg(format!("-l{}", lib)); self.linker_arg("--no-whole-archive"); } else { // -force_load is the macOS equivalent of --whole-archive, but it // involves passing the full path to the library to link. self.linker_arg("-force_load"); let lib = archive::find_library(lib, search_path, &self.sess); self.linker_arg(&lib); } } fn link_whole_rlib(&mut self, lib: &Path) { self.hint_static(); if self.sess.target.target.options.is_like_osx { self.linker_arg("-force_load"); self.linker_arg(&lib); } else { self.linker_arg("--whole-archive").cmd.arg(lib); self.linker_arg("--no-whole-archive"); } } fn gc_sections(&mut self, keep_metadata: bool) { // The dead_strip option to the linker specifies that functions and data // unreachable by the entry point will be removed. This is quite useful // with Rust's compilation model of compiling libraries at a time into // one object file. For example, this brings hello world from 1.7MB to // 458K. // // Note that this is done for both executables and dynamic libraries. We // won't get much benefit from dylibs because LLVM will have already // stripped away as much as it could. This has not been seen to impact // link times negatively. // // -dead_strip can't be part of the pre_link_args because it's also used // for partial linking when using multiple codegen units (-r). So we // insert it here. if self.sess.target.target.options.is_like_osx { self.linker_arg("-dead_strip"); } else if self.sess.target.target.options.is_like_solaris { self.linker_arg("-zignore"); // If we're building a dylib, we don't use --gc-sections because LLVM // has already done the best it can do, and we also don't want to // eliminate the metadata. If we're building an executable, however, // --gc-sections drops the size of hello world from 1.8MB to 597K, a 67% // reduction. } else if !keep_metadata { self.linker_arg("--gc-sections"); } } fn optimize(&mut self) { if !self.sess.target.target.options.linker_is_gnu { return } // GNU-style linkers support optimization with -O. GNU ld doesn't // need a numeric argument, but other linkers do. if self.sess.opts.optimize == config::OptLevel::Default || self.sess.opts.optimize == config::OptLevel::Aggressive { self.linker_arg("-O1"); } } fn pgo_gen(&mut self) { if !self.sess.target.target.options.linker_is_gnu { return } // If we're doing PGO generation stuff and on a GNU-like linker, use the // "-u" flag to properly pull in the profiler runtime bits. // // This is because LLVM otherwise won't add the needed initialization // for us on Linux (though the extra flag should be harmless if it // does). // // See https://reviews.llvm.org/D14033 and https://reviews.llvm.org/D14030. // // Though it may be worth to try to revert those changes upstream, since // the overhead of the initialization should be minor. self.cmd.arg("-u"); self.cmd.arg("__llvm_profile_runtime"); } fn debuginfo(&mut self) { if let DebugInfo::None = self.sess.opts.debuginfo { // If we are building without debuginfo enabled and we were called with // `-Zstrip-debuginfo-if-disabled=yes`, tell the linker to strip any debuginfo // found when linking to get rid of symbols from libstd. if let Some(true) = self.sess.opts.debugging_opts.strip_debuginfo_if_disabled { self.linker_arg("-S"); } }; } fn no_default_libraries(&mut self) { if !self.is_ld { self.cmd.arg("-nodefaultlibs"); } } fn build_dylib(&mut self, out_filename: &Path) { // On mac we need to tell the linker to let this library be rpathed if self.sess.target.target.options.is_like_osx { self.cmd.arg("-dynamiclib"); self.linker_arg("-dylib"); // Note that the `osx_rpath_install_name` option here is a hack // purely to support rustbuild right now, we should get a more // principled solution at some point to force the compiler to pass // the right `-Wl,-install_name` with an `@rpath` in it. if self.sess.opts.cg.rpath || self.sess.opts.debugging_opts.osx_rpath_install_name { self.linker_arg("-install_name"); let mut v = OsString::from("@rpath/"); v.push(out_filename.file_name().unwrap()); self.linker_arg(&v); } } else { self.cmd.arg("-shared"); if self.sess.target.target.options.is_like_windows { // The output filename already contains `dll_suffix` so // the resulting import library will have a name in the // form of libfoo.dll.a let implib_name = out_filename .file_name() .and_then(|file| file.to_str()) .map(|file| format!("{}{}{}", self.sess.target.target.options.staticlib_prefix, file, self.sess.target.target.options.staticlib_suffix)); if let Some(implib_name) = implib_name { let implib = out_filename .parent() .map(|dir| dir.join(&implib_name)); if let Some(implib) = implib { self.linker_arg(&format!("--out-implib,{}", (*implib).to_str().unwrap())); } } } } } fn export_symbols(&mut self, tmpdir: &Path, crate_type: CrateType) { // Symbol visibility in object files typically takes care of this. if crate_type == CrateType::Executable { return; } // We manually create a list of exported symbols to ensure we don't expose any more. // The object files have far more public symbols than we actually want to export, // so we hide them all here. if !self.sess.target.target.options.limit_rdylib_exports { return; } if crate_type == CrateType::ProcMacro { return } let mut arg = OsString::new(); let path = tmpdir.join("list"); debug!("EXPORTED SYMBOLS:"); if self.sess.target.target.options.is_like_osx { // Write a plain, newline-separated list of symbols let res: io::Result<()> = try { let mut f = BufWriter::new(File::create(&path)?); for sym in self.info.exports[&crate_type].iter() { debug!(" _{}", sym); writeln!(f, "_{}", sym)?; } }; if let Err(e) = res { self.sess.fatal(&format!("failed to write lib.def file: {}", e)); } } else { // Write an LD version script let res: io::Result<()> = try { let mut f = BufWriter::new(File::create(&path)?); writeln!(f, "{{")?; if !self.info.exports[&crate_type].is_empty() { writeln!(f, " global:")?; for sym in self.info.exports[&crate_type].iter() { debug!(" {};", sym); writeln!(f, " {};", sym)?; } } writeln!(f, "\n local:\n *;\n}};")?; }; if let Err(e) = res { self.sess.fatal(&format!("failed to write version script: {}", e)); } } if self.sess.target.target.options.is_like_osx { if !self.is_ld { arg.push("-Wl,") } arg.push("-exported_symbols_list,"); } else if self.sess.target.target.options.is_like_solaris { if !self.is_ld { arg.push("-Wl,") } arg.push("-M,"); } else { if !self.is_ld { arg.push("-Wl,") } arg.push("--version-script="); } arg.push(&path); self.cmd.arg(arg); } fn subsystem(&mut self, subsystem: &str) { self.linker_arg("--subsystem"); self.linker_arg(&subsystem); } fn finalize(&mut self) -> Command { self.hint_dynamic(); // Reset to default before returning the composed command line. ::std::mem::replace(&mut self.cmd, Command::new("")) } fn group_start(&mut self) { if self.takes_hints() { self.linker_arg("--start-group"); } } fn group_end(&mut self) { if self.takes_hints() { self.linker_arg("--end-group"); } } fn linker_plugin_lto(&mut self) { match self.sess.opts.cg.linker_plugin_lto { LinkerPluginLto::Disabled => { // Nothing to do } LinkerPluginLto::LinkerPluginAuto => { self.push_linker_plugin_lto_args(None); } LinkerPluginLto::LinkerPlugin(ref path) => { self.push_linker_plugin_lto_args(Some(path.as_os_str())); } } } } pub struct MsvcLinker<'a> { cmd: Command, sess: &'a Session, info: &'a LinkerInfo } impl<'a> Linker for MsvcLinker<'a> { fn link_rlib(&mut self, lib: &Path) { self.cmd.arg(lib); } fn add_object(&mut self, path: &Path) { self.cmd.arg(path); } fn args(&mut self, args: &[String]) { self.cmd.args(args); } fn build_dylib(&mut self, out_filename: &Path) { self.cmd.arg("/DLL"); let mut arg: OsString = "/IMPLIB:".into(); arg.push(out_filename.with_extension("dll.lib")); self.cmd.arg(arg); } fn build_static_executable(&mut self) { // noop } fn gc_sections(&mut self, _keep_metadata: bool) { // MSVC's ICF (Identical COMDAT Folding) link optimization is // slow for Rust and thus we disable it by default when not in // optimization build. if self.sess.opts.optimize != config::OptLevel::No { self.cmd.arg("/OPT:REF,ICF"); } else { // It is necessary to specify NOICF here, because /OPT:REF // implies ICF by default. self.cmd.arg("/OPT:REF,NOICF"); } } fn link_dylib(&mut self, lib: &str) { self.cmd.arg(&format!("{}.lib", lib)); } fn link_rust_dylib(&mut self, lib: &str, path: &Path) { // When producing a dll, the MSVC linker may not actually emit a // `foo.lib` file if the dll doesn't actually export any symbols, so we // check to see if the file is there and just omit linking to it if it's // not present. let name = format!("{}.dll.lib", lib); if fs::metadata(&path.join(&name)).is_ok() { self.cmd.arg(name); } } fn link_staticlib(&mut self, lib: &str) { self.cmd.arg(&format!("{}.lib", lib)); } fn position_independent_executable(&mut self) { // noop } fn no_position_independent_executable(&mut self) { // noop } fn full_relro(&mut self) { // noop } fn partial_relro(&mut self) { // noop } fn no_relro(&mut self) { // noop } fn no_default_libraries(&mut self) { // Currently we don't pass the /NODEFAULTLIB flag to the linker on MSVC // as there's been trouble in the past of linking the C++ standard // library required by LLVM. This likely needs to happen one day, but // in general Windows is also a more controlled environment than // Unix, so it's not necessarily as critical that this be implemented. // // Note that there are also some licensing worries about statically // linking some libraries which require a specific agreement, so it may // not ever be possible for us to pass this flag. } fn include_path(&mut self, path: &Path) { let mut arg = OsString::from("/LIBPATH:"); arg.push(path); self.cmd.arg(&arg); } fn output_filename(&mut self, path: &Path) { let mut arg = OsString::from("/OUT:"); arg.push(path); self.cmd.arg(&arg); } fn framework_path(&mut self, _path: &Path) { bug!("frameworks are not supported on windows") } fn link_framework(&mut self, _framework: &str) { bug!("frameworks are not supported on windows") } fn link_whole_staticlib(&mut self, lib: &str, _search_path: &[PathBuf]) { // not supported? self.link_staticlib(lib); } fn link_whole_rlib(&mut self, path: &Path) { // not supported? self.link_rlib(path); } fn optimize(&mut self) { // Needs more investigation of `/OPT` arguments } fn pgo_gen(&mut self) { // Nothing needed here. } fn debuginfo(&mut self) { // This will cause the Microsoft linker to generate a PDB file // from the CodeView line tables in the object files. self.cmd.arg("/DEBUG"); // This will cause the Microsoft linker to embed .natvis info into the PDB file let natvis_dir_path = self.sess.sysroot.join("lib\\rustlib\\etc"); if let Ok(natvis_dir) = fs::read_dir(&natvis_dir_path) { for entry in natvis_dir { match entry { Ok(entry) => { let path = entry.path(); if path.extension() == Some("natvis".as_ref()) { let mut arg = OsString::from("/NATVIS:"); arg.push(path); self.cmd.arg(arg); } }, Err(err) => { self.sess.warn(&format!("error enumerating natvis directory: {}", err)); }, } } } } // Currently the compiler doesn't use `dllexport` (an LLVM attribute) to // export symbols from a dynamic library. When building a dynamic library, // however, we're going to want some symbols exported, so this function // generates a DEF file which lists all the symbols. // // The linker will read this `*.def` file and export all the symbols from // the dynamic library. Note that this is not as simple as just exporting // all the symbols in the current crate (as specified by `codegen.reachable`) // but rather we also need to possibly export the symbols of upstream // crates. Upstream rlibs may be linked statically to this dynamic library, // in which case they may continue to transitively be used and hence need // their symbols exported. fn export_symbols(&mut self, tmpdir: &Path, crate_type: CrateType) { // Symbol visibility takes care of this typically if crate_type == CrateType::Executable { return; } let path = tmpdir.join("lib.def"); let res: io::Result<()> = try { let mut f = BufWriter::new(File::create(&path)?); // Start off with the standard module name header and then go // straight to exports. writeln!(f, "LIBRARY")?; writeln!(f, "EXPORTS")?; for symbol in self.info.exports[&crate_type].iter() { debug!(" _{}", symbol); writeln!(f, " {}", symbol)?; } }; if let Err(e) = res { self.sess.fatal(&format!("failed to write lib.def file: {}", e)); } let mut arg = OsString::from("/DEF:"); arg.push(path); self.cmd.arg(&arg); } fn subsystem(&mut self, subsystem: &str) { // Note that previous passes of the compiler validated this subsystem, // so we just blindly pass it to the linker. self.cmd.arg(&format!("/SUBSYSTEM:{}", subsystem)); // Windows has two subsystems we're interested in right now, the console // and windows subsystems. These both implicitly have different entry // points (starting symbols). The console entry point starts with // `mainCRTStartup` and the windows entry point starts with // `WinMainCRTStartup`. These entry points, defined in system libraries, // will then later probe for either `main` or `WinMain`, respectively to // start the application. // // In Rust we just always generate a `main` function so we want control // to always start there, so we force the entry point on the windows // subsystem to be `mainCRTStartup` to get everything booted up // correctly. // // For more information see RFC #1665 if subsystem == "windows" { self.cmd.arg("/ENTRY:mainCRTStartup"); } } fn finalize(&mut self) -> Command { ::std::mem::replace(&mut self.cmd, Command::new("")) } // MSVC doesn't need group indicators fn group_start(&mut self) {} fn group_end(&mut self) {} fn linker_plugin_lto(&mut self) { // Do nothing } } pub struct EmLinker<'a> { cmd: Command, sess: &'a Session, info: &'a LinkerInfo } impl<'a> Linker for EmLinker<'a> { fn include_path(&mut self, path: &Path) { self.cmd.arg("-L").arg(path); } fn link_staticlib(&mut self, lib: &str) { self.cmd.arg("-l").arg(lib); } fn output_filename(&mut self, path: &Path) { self.cmd.arg("-o").arg(path); } fn add_object(&mut self, path: &Path) { self.cmd.arg(path); } fn link_dylib(&mut self, lib: &str) { // Emscripten always links statically self.link_staticlib(lib); } fn link_whole_staticlib(&mut self, lib: &str, _search_path: &[PathBuf]) { // not supported? self.link_staticlib(lib); } fn link_whole_rlib(&mut self, lib: &Path) { // not supported? self.link_rlib(lib); } fn link_rust_dylib(&mut self, lib: &str, _path: &Path) { self.link_dylib(lib); } fn link_rlib(&mut self, lib: &Path) { self.add_object(lib); } fn position_independent_executable(&mut self) { // noop } fn no_position_independent_executable(&mut self) { // noop } fn full_relro(&mut self) { // noop } fn partial_relro(&mut self) { // noop } fn no_relro(&mut self) { // noop } fn args(&mut self, args: &[String]) { self.cmd.args(args); } fn framework_path(&mut self, _path: &Path) { bug!("frameworks are not supported on Emscripten") } fn link_framework(&mut self, _framework: &str) { bug!("frameworks are not supported on Emscripten") } fn gc_sections(&mut self, _keep_metadata: bool) { // noop } fn optimize(&mut self) { // Emscripten performs own optimizations self.cmd.arg(match self.sess.opts.optimize { OptLevel::No => "-O0", OptLevel::Less => "-O1", OptLevel::Default => "-O2", OptLevel::Aggressive => "-O3", OptLevel::Size => "-Os", OptLevel::SizeMin => "-Oz" }); // Unusable until https://github.com/rust-lang/rust/issues/38454 is resolved self.cmd.args(&["--memory-init-file", "0"]); } fn pgo_gen(&mut self) { // noop, but maybe we need something like the gnu linker? } fn debuginfo(&mut self) { // Preserve names or generate source maps depending on debug info self.cmd.arg(match self.sess.opts.debuginfo { DebugInfo::None => "-g0", DebugInfo::Limited => "-g3", DebugInfo::Full => "-g4" }); } fn no_default_libraries(&mut self) { self.cmd.args(&["-s", "DEFAULT_LIBRARY_FUNCS_TO_INCLUDE=[]"]); } fn build_dylib(&mut self, _out_filename: &Path) { bug!("building dynamic library is unsupported on Emscripten") } fn build_static_executable(&mut self) { // noop } fn export_symbols(&mut self, _tmpdir: &Path, crate_type: CrateType) { let symbols = &self.info.exports[&crate_type]; debug!("EXPORTED SYMBOLS:"); self.cmd.arg("-s"); let mut arg = OsString::from("EXPORTED_FUNCTIONS="); let mut encoded = String::new(); { let mut encoder = json::Encoder::new(&mut encoded); let res = encoder.emit_seq(symbols.len(), |encoder| { for (i, sym) in symbols.iter().enumerate() { encoder.emit_seq_elt(i, |encoder| { encoder.emit_str(&("_".to_owned() + sym)) })?; } Ok(()) }); if let Err(e) = res { self.sess.fatal(&format!("failed to encode exported symbols: {}", e)); } } debug!("{}", encoded); arg.push(encoded); self.cmd.arg(arg); } fn subsystem(&mut self, _subsystem: &str) { // noop } fn finalize(&mut self) -> Command { ::std::mem::replace(&mut self.cmd, Command::new("")) } // Appears not necessary on Emscripten fn group_start(&mut self) {} fn group_end(&mut self) {} fn linker_plugin_lto(&mut self) { // Do nothing } } pub struct WasmLd<'a> { cmd: Command, sess: &'a Session, info: &'a LinkerInfo, } impl<'a> WasmLd<'a> { fn new(mut cmd: Command, sess: &'a Session, info: &'a LinkerInfo) -> WasmLd<'a> { // If the atomics feature is enabled for wasm then we need a whole bunch // of flags: // // * `--shared-memory` - the link won't even succeed without this, flags // the one linear memory as `shared` // // * `--max-memory=1G` - when specifying a shared memory this must also // be specified. We conservatively choose 1GB but users should be able // to override this with `-C link-arg`. // // * `--import-memory` - it doesn't make much sense for memory to be // exported in a threaded module because typically you're // sharing memory and instantiating the module multiple times. As a // result if it were exported then we'd just have no sharing. // // * `--passive-segments` - all memory segments should be passive to // prevent each module instantiation from reinitializing memory. // // * `--export=__wasm_init_memory` - when using `--passive-segments` the // linker will synthesize this function, and so we need to make sure // that our usage of `--export` below won't accidentally cause this // function to get deleted. // // * `--export=*tls*` - when `#[thread_local]` symbols are used these // symbols are how the TLS segments are initialized and configured. let atomics = sess.opts.cg.target_feature.contains("+atomics") || sess.target.target.options.features.contains("+atomics"); if atomics { cmd.arg("--shared-memory"); cmd.arg("--max-memory=1073741824"); cmd.arg("--import-memory"); cmd.arg("--passive-segments"); cmd.arg("--export=__wasm_init_memory"); cmd.arg("--export=__wasm_init_tls"); cmd.arg("--export=__tls_size"); cmd.arg("--export=__tls_align"); cmd.arg("--export=__tls_base"); } WasmLd { cmd, sess, info } } } impl<'a> Linker for WasmLd<'a> { fn link_dylib(&mut self, lib: &str) { self.cmd.arg("-l").arg(lib); } fn link_staticlib(&mut self, lib: &str) { self.cmd.arg("-l").arg(lib); } fn link_rlib(&mut self, lib: &Path) { self.cmd.arg(lib); } fn include_path(&mut self, path: &Path) { self.cmd.arg("-L").arg(path); } fn framework_path(&mut self, _path: &Path) { panic!("frameworks not supported") } fn output_filename(&mut self, path: &Path) { self.cmd.arg("-o").arg(path); } fn add_object(&mut self, path: &Path) { self.cmd.arg(path); } fn position_independent_executable(&mut self) { } fn full_relro(&mut self) { } fn partial_relro(&mut self) { } fn no_relro(&mut self) { } fn build_static_executable(&mut self) { } fn args(&mut self, args: &[String]) { self.cmd.args(args); } fn link_rust_dylib(&mut self, lib: &str, _path: &Path) { self.cmd.arg("-l").arg(lib); } fn link_framework(&mut self, _framework: &str) { panic!("frameworks not supported") } fn link_whole_staticlib(&mut self, lib: &str, _search_path: &[PathBuf]) { self.cmd.arg("-l").arg(lib); } fn link_whole_rlib(&mut self, lib: &Path) { self.cmd.arg(lib); } fn gc_sections(&mut self, _keep_metadata: bool) { self.cmd.arg("--gc-sections"); } fn optimize(&mut self) { self.cmd.arg(match self.sess.opts.optimize { OptLevel::No => "-O0", OptLevel::Less => "-O1", OptLevel::Default => "-O2", OptLevel::Aggressive => "-O3", // Currently LLD doesn't support `Os` and `Oz`, so pass through `O2` // instead. OptLevel::Size => "-O2", OptLevel::SizeMin => "-O2" }); } fn pgo_gen(&mut self) { } fn debuginfo(&mut self) { } fn no_default_libraries(&mut self) { } fn build_dylib(&mut self, _out_filename: &Path) { self.cmd.arg("--no-entry"); } fn export_symbols(&mut self, _tmpdir: &Path, crate_type: CrateType) { for sym in self.info.exports[&crate_type].iter() { self.cmd.arg("--export").arg(&sym); } // LLD will hide these otherwise-internal symbols since our `--export` // list above is a whitelist of what to export. Various bits and pieces // of tooling use this, so be sure these symbols make their way out of // the linker as well. self.cmd.arg("--export=__heap_base"); self.cmd.arg("--export=__data_end"); } fn subsystem(&mut self, _subsystem: &str) { } fn no_position_independent_executable(&mut self) { } fn finalize(&mut self) -> Command { ::std::mem::replace(&mut self.cmd, Command::new("")) } // Not needed for now with LLD fn group_start(&mut self) {} fn group_end(&mut self) {} fn linker_plugin_lto(&mut self) { // Do nothing for now } } fn exported_symbols(tcx: TyCtxt<'_>, crate_type: CrateType) -> Vec { if let Some(ref exports) = tcx.sess.target.target.options.override_export_symbols { return exports.clone() } let mut symbols = Vec::new(); let export_threshold = symbol_export::crates_export_threshold(&[crate_type]); for &(symbol, level) in tcx.exported_symbols(LOCAL_CRATE).iter() { if level.is_below_threshold(export_threshold) { symbols.push(symbol.symbol_name(tcx).to_string()); } } let formats = tcx.sess.dependency_formats.borrow(); let deps = formats[&crate_type].iter(); for (index, dep_format) in deps.enumerate() { let cnum = CrateNum::new(index + 1); // For each dependency that we are linking to statically ... if *dep_format == Linkage::Static { // ... we add its symbol list to our export list. for &(symbol, level) in tcx.exported_symbols(cnum).iter() { if level.is_below_threshold(export_threshold) { symbols.push(symbol.symbol_name(tcx).to_string()); } } } } symbols } /// Much simplified and explicit CLI for the NVPTX linker. The linker operates /// with bitcode and uses LLVM backend to generate a PTX assembly. pub struct PtxLinker<'a> { cmd: Command, sess: &'a Session, } impl<'a> Linker for PtxLinker<'a> { fn link_rlib(&mut self, path: &Path) { self.cmd.arg("--rlib").arg(path); } fn link_whole_rlib(&mut self, path: &Path) { self.cmd.arg("--rlib").arg(path); } fn include_path(&mut self, path: &Path) { self.cmd.arg("-L").arg(path); } fn debuginfo(&mut self) { self.cmd.arg("--debug"); } fn add_object(&mut self, path: &Path) { self.cmd.arg("--bitcode").arg(path); } fn args(&mut self, args: &[String]) { self.cmd.args(args); } fn optimize(&mut self) { match self.sess.lto() { Lto::Thin | Lto::Fat | Lto::ThinLocal => { self.cmd.arg("-Olto"); }, Lto::No => { }, }; } fn output_filename(&mut self, path: &Path) { self.cmd.arg("-o").arg(path); } fn finalize(&mut self) -> Command { // Provide the linker with fallback to internal `target-cpu`. self.cmd.arg("--fallback-arch").arg(match self.sess.opts.cg.target_cpu { Some(ref s) => s, None => &self.sess.target.target.options.cpu }); ::std::mem::replace(&mut self.cmd, Command::new("")) } fn link_dylib(&mut self, _lib: &str) { panic!("external dylibs not supported") } fn link_rust_dylib(&mut self, _lib: &str, _path: &Path) { panic!("external dylibs not supported") } fn link_staticlib(&mut self, _lib: &str) { panic!("staticlibs not supported") } fn link_whole_staticlib(&mut self, _lib: &str, _search_path: &[PathBuf]) { panic!("staticlibs not supported") } fn framework_path(&mut self, _path: &Path) { panic!("frameworks not supported") } fn link_framework(&mut self, _framework: &str) { panic!("frameworks not supported") } fn position_independent_executable(&mut self) { } fn full_relro(&mut self) { } fn partial_relro(&mut self) { } fn no_relro(&mut self) { } fn build_static_executable(&mut self) { } fn gc_sections(&mut self, _keep_metadata: bool) { } fn pgo_gen(&mut self) { } fn no_default_libraries(&mut self) { } fn build_dylib(&mut self, _out_filename: &Path) { } fn export_symbols(&mut self, _tmpdir: &Path, _crate_type: CrateType) { } fn subsystem(&mut self, _subsystem: &str) { } fn no_position_independent_executable(&mut self) { } fn group_start(&mut self) { } fn group_end(&mut self) { } fn linker_plugin_lto(&mut self) { } }