1 //! Implementation of compiling various phases of the compiler and standard
4 //! This module contains some of the real meat in the rustbuild build system
5 //! which is where Cargo is used to compile the standard library, libtest, and
6 //! the compiler. This module is also responsible for assembling the sysroot as it
7 //! goes along from the output of the previous stage.
10 use std::collections::HashSet;
13 use std::io::prelude::*;
14 use std::io::BufReader;
15 use std::path::{Path, PathBuf};
16 use std::process::{Command, Stdio};
19 use serde::Deserialize;
21 use crate::builder::Cargo;
22 use crate::builder::{Builder, Kind, RunConfig, ShouldRun, Step};
23 use crate::cache::{Interned, INTERNER};
24 use crate::config::{LlvmLibunwind, TargetSelection};
27 use crate::tool::SourceType;
28 use crate::util::get_clang_cl_resource_dir;
29 use crate::util::{exe, is_debug_info, is_dylib, output, symlink_dir, t, up_to_date};
30 use crate::LLVM_TOOLS;
31 use crate::{CLang, Compiler, DependencyType, GitRepo, Mode};
33 #[derive(Debug, Copy, Clone, PartialEq, Eq, PartialOrd, Ord, Hash)]
35 pub target: TargetSelection,
36 pub compiler: Compiler,
37 /// Whether to build only a subset of crates in the standard library.
39 /// This shouldn't be used from other steps; see the comment on [`Rustc`].
40 crates: Interned<Vec<String>>,
44 pub fn new(compiler: Compiler, target: TargetSelection) -> Self {
45 Self { target, compiler, crates: Default::default() }
49 /// Return a `-p=x -p=y` string suitable for passing to a cargo invocation.
50 fn build_crates_in_set(run: &RunConfig<'_>) -> Interned<Vec<String>> {
51 let mut crates = Vec::new();
52 for krate in &run.paths {
53 let path = krate.assert_single_path();
54 let crate_name = run.builder.crate_paths[&path.path];
55 crates.push(format!("-p={crate_name}"));
57 INTERNER.intern_list(crates)
62 const DEFAULT: bool = true;
64 fn should_run(run: ShouldRun<'_>) -> ShouldRun<'_> {
65 // When downloading stage1, the standard library has already been copied to the sysroot, so
66 // there's no need to rebuild it.
67 let builder = run.builder;
68 run.crate_or_deps("test")
70 .lazy_default_condition(Box::new(|| !builder.download_rustc()))
73 fn make_run(run: RunConfig<'_>) {
74 // Normally, people will pass *just* library if they pass it.
75 // But it's possible (although strange) to pass something like `library std core`.
76 // Build all crates anyway, as if they hadn't passed the other args.
78 run.paths.iter().any(|set| set.assert_single_path().path.ends_with("library"));
79 let crates = if has_library { Default::default() } else { build_crates_in_set(&run) };
80 run.builder.ensure(Std {
81 compiler: run.builder.compiler(run.builder.top_stage, run.build_triple()),
87 /// Builds the standard library.
89 /// This will build the standard library for a particular stage of the build
90 /// using the `compiler` targeting the `target` architecture. The artifacts
91 /// created will also be linked into the sysroot directory.
92 fn run(self, builder: &Builder<'_>) {
93 let target = self.target;
94 let compiler = self.compiler;
96 // These artifacts were already copied (in `impl Step for Sysroot`).
97 // Don't recompile them.
98 // NOTE: the ABI of the beta compiler is different from the ABI of the downloaded compiler,
99 // so its artifacts can't be reused.
100 if builder.download_rustc() && compiler.stage != 0 {
104 if builder.config.keep_stage.contains(&compiler.stage)
105 || builder.config.keep_stage_std.contains(&compiler.stage)
107 builder.info("Warning: Using a potentially old libstd. This may not behave well.");
108 builder.ensure(StdLink::from_std(self, compiler));
112 builder.update_submodule(&Path::new("library").join("stdarch"));
114 // Profiler information requires LLVM's compiler-rt
115 if builder.config.profiler {
116 builder.update_submodule(&Path::new("src/llvm-project"));
119 let mut target_deps = builder.ensure(StartupObjects { compiler, target });
121 let compiler_to_use = builder.compiler_for(compiler.stage, compiler.host, target);
122 if compiler_to_use != compiler {
123 builder.ensure(Std::new(compiler_to_use, target));
124 builder.info(&format!("Uplifting stage1 std ({} -> {})", compiler_to_use.host, target));
126 // Even if we're not building std this stage, the new sysroot must
127 // still contain the third party objects needed by various targets.
128 copy_third_party_objects(builder, &compiler, target);
129 copy_self_contained_objects(builder, &compiler, target);
131 builder.ensure(StdLink::from_std(self, compiler_to_use));
135 target_deps.extend(copy_third_party_objects(builder, &compiler, target));
136 target_deps.extend(copy_self_contained_objects(builder, &compiler, target));
138 let mut cargo = builder.cargo(compiler, Mode::Std, SourceType::InTree, target, "build");
139 std_cargo(builder, target, compiler.stage, &mut cargo);
141 builder.info(&format!(
142 "Building stage{} std artifacts ({} -> {})",
143 compiler.stage, &compiler.host, target
148 self.crates.to_vec(),
149 &libstd_stamp(builder, compiler, target),
154 builder.ensure(StdLink::from_std(
156 builder.compiler(compiler.stage, builder.config.build),
162 builder: &Builder<'_>,
166 target_deps: &mut Vec<(PathBuf, DependencyType)>,
167 dependency_type: DependencyType,
169 let target = libdir.join(name);
170 builder.copy(&sourcedir.join(name), &target);
172 target_deps.push((target, dependency_type));
175 fn copy_llvm_libunwind(builder: &Builder<'_>, target: TargetSelection, libdir: &Path) -> PathBuf {
176 let libunwind_path = builder.ensure(native::Libunwind { target });
177 let libunwind_source = libunwind_path.join("libunwind.a");
178 let libunwind_target = libdir.join("libunwind.a");
179 builder.copy(&libunwind_source, &libunwind_target);
183 /// Copies third party objects needed by various targets.
184 fn copy_third_party_objects(
185 builder: &Builder<'_>,
187 target: TargetSelection,
188 ) -> Vec<(PathBuf, DependencyType)> {
189 let mut target_deps = vec![];
191 // FIXME: remove this in 2021
192 if target == "x86_64-fortanix-unknown-sgx" {
193 if env::var_os("X86_FORTANIX_SGX_LIBS").is_some() {
194 builder.info("Warning: X86_FORTANIX_SGX_LIBS environment variable is ignored, libunwind is now compiled as part of rustbuild");
198 if builder.config.sanitizers_enabled(target) && compiler.stage != 0 {
199 // The sanitizers are only copied in stage1 or above,
200 // to avoid creating dependency on LLVM.
202 copy_sanitizers(builder, &compiler, target)
204 .map(|d| (d, DependencyType::Target)),
208 if target == "x86_64-fortanix-unknown-sgx"
209 || target.contains("pc-windows-gnullvm")
210 || builder.config.llvm_libunwind(target) == LlvmLibunwind::InTree
211 && (target.contains("linux") || target.contains("fuchsia"))
214 copy_llvm_libunwind(builder, target, &builder.sysroot_libdir(*compiler, target));
215 target_deps.push((libunwind_path, DependencyType::Target));
221 /// Copies third party objects needed by various targets for self-contained linkage.
222 fn copy_self_contained_objects(
223 builder: &Builder<'_>,
225 target: TargetSelection,
226 ) -> Vec<(PathBuf, DependencyType)> {
227 let libdir_self_contained = builder.sysroot_libdir(*compiler, target).join("self-contained");
228 t!(fs::create_dir_all(&libdir_self_contained));
229 let mut target_deps = vec![];
231 // Copies the libc and CRT objects.
233 // rustc historically provides a more self-contained installation for musl targets
234 // not requiring the presence of a native musl toolchain. For example, it can fall back
235 // to using gcc from a glibc-targeting toolchain for linking.
236 // To do that we have to distribute musl startup objects as a part of Rust toolchain
237 // and link with them manually in the self-contained mode.
238 if target.contains("musl") {
239 let srcdir = builder.musl_libdir(target).unwrap_or_else(|| {
240 panic!("Target {:?} does not have a \"musl-libdir\" key", target.triple)
242 for &obj in &["libc.a", "crt1.o", "Scrt1.o", "rcrt1.o", "crti.o", "crtn.o"] {
245 &libdir_self_contained,
249 DependencyType::TargetSelfContained,
252 let crt_path = builder.ensure(native::CrtBeginEnd { target });
253 for &obj in &["crtbegin.o", "crtbeginS.o", "crtend.o", "crtendS.o"] {
254 let src = crt_path.join(obj);
255 let target = libdir_self_contained.join(obj);
256 builder.copy(&src, &target);
257 target_deps.push((target, DependencyType::TargetSelfContained));
260 if !target.starts_with("s390x") {
261 let libunwind_path = copy_llvm_libunwind(builder, target, &libdir_self_contained);
262 target_deps.push((libunwind_path, DependencyType::TargetSelfContained));
264 } else if target.ends_with("-wasi") {
268 panic!("Target {:?} does not have a \"wasi-root\" key", target.triple)
270 .join("lib/wasm32-wasi");
271 for &obj in &["libc.a", "crt1-command.o", "crt1-reactor.o"] {
274 &libdir_self_contained,
278 DependencyType::TargetSelfContained,
281 } else if target.ends_with("windows-gnu") {
282 for obj in ["crt2.o", "dllcrt2.o"].iter() {
283 let src = compiler_file(builder, builder.cc(target), target, CLang::C, obj);
284 let target = libdir_self_contained.join(obj);
285 builder.copy(&src, &target);
286 target_deps.push((target, DependencyType::TargetSelfContained));
293 /// Configure cargo to compile the standard library, adding appropriate env vars
295 pub fn std_cargo(builder: &Builder<'_>, target: TargetSelection, stage: u32, cargo: &mut Cargo) {
296 if let Some(target) = env::var_os("MACOSX_STD_DEPLOYMENT_TARGET") {
297 cargo.env("MACOSX_DEPLOYMENT_TARGET", target);
300 // Determine if we're going to compile in optimized C intrinsics to
301 // the `compiler-builtins` crate. These intrinsics live in LLVM's
302 // `compiler-rt` repository.
304 // Note that this shouldn't affect the correctness of `compiler-builtins`,
305 // but only its speed. Some intrinsics in C haven't been translated to Rust
306 // yet but that's pretty rare. Other intrinsics have optimized
307 // implementations in C which have only had slower versions ported to Rust,
308 // so we favor the C version where we can, but it's not critical.
310 // If `compiler-rt` is available ensure that the `c` feature of the
311 // `compiler-builtins` crate is enabled and it's configured to learn where
312 // `compiler-rt` is located.
313 let compiler_builtins_c_feature = if builder.config.optimized_compiler_builtins {
314 if !builder.is_rust_llvm(target) {
316 "need a managed LLVM submodule for optimized intrinsics support; unset `llvm-config` or `optimized-compiler-builtins`"
320 builder.update_submodule(&Path::new("src").join("llvm-project"));
321 let compiler_builtins_root = builder.src.join("src/llvm-project/compiler-rt");
322 // Note that `libprofiler_builtins/build.rs` also computes this so if
323 // you're changing something here please also change that.
324 cargo.env("RUST_COMPILER_RT_ROOT", &compiler_builtins_root);
325 " compiler-builtins-c"
330 if builder.no_std(target) == Some(true) {
331 let mut features = "compiler-builtins-mem".to_string();
332 if !target.starts_with("bpf") {
333 features.push_str(compiler_builtins_c_feature);
336 // for no-std targets we only compile a few no_std crates
338 .args(&["-p", "alloc"])
339 .arg("--manifest-path")
340 .arg(builder.src.join("library/alloc/Cargo.toml"))
344 let mut features = builder.std_features(target);
345 features.push_str(compiler_builtins_c_feature);
350 .arg("--manifest-path")
351 .arg(builder.src.join("library/test/Cargo.toml"));
353 // Help the libc crate compile by assisting it in finding various
354 // sysroot native libraries.
355 if target.contains("musl") {
356 if let Some(p) = builder.musl_libdir(target) {
357 let root = format!("native={}", p.to_str().unwrap());
358 cargo.rustflag("-L").rustflag(&root);
362 if target.ends_with("-wasi") {
363 if let Some(p) = builder.wasi_root(target) {
364 let root = format!("native={}/lib/wasm32-wasi", p.to_str().unwrap());
365 cargo.rustflag("-L").rustflag(&root);
370 // By default, rustc uses `-Cembed-bitcode=yes`, and Cargo overrides that
371 // with `-Cembed-bitcode=no` for non-LTO builds. However, libstd must be
372 // built with bitcode so that the produced rlibs can be used for both LTO
373 // builds (which use bitcode) and non-LTO builds (which use object code).
374 // So we override the override here!
376 // But we don't bother for the stage 0 compiler because it's never used
379 cargo.rustflag("-Cembed-bitcode=yes");
382 // By default, rustc does not include unwind tables unless they are required
383 // for a particular target. They are not required by RISC-V targets, but
384 // compiling the standard library with them means that users can get
385 // backtraces without having to recompile the standard library themselves.
387 // This choice was discussed in https://github.com/rust-lang/rust/pull/69890
388 if target.contains("riscv") {
389 cargo.rustflag("-Cforce-unwind-tables=yes");
393 format!("-Zcrate-attr=doc(html_root_url=\"{}/\")", builder.doc_rust_lang_org_channel(),);
394 cargo.rustflag(&html_root);
395 cargo.rustdocflag(&html_root);
398 #[derive(Debug, Copy, Clone, PartialEq, Eq, Hash)]
400 pub compiler: Compiler,
401 pub target_compiler: Compiler,
402 pub target: TargetSelection,
403 /// Not actually used; only present to make sure the cache invalidation is correct.
404 crates: Interned<Vec<String>>,
408 fn from_std(std: Std, host_compiler: Compiler) -> Self {
410 compiler: host_compiler,
411 target_compiler: std.compiler,
418 impl Step for StdLink {
421 fn should_run(run: ShouldRun<'_>) -> ShouldRun<'_> {
425 /// Link all libstd rlibs/dylibs into the sysroot location.
427 /// Links those artifacts generated by `compiler` to the `stage` compiler's
428 /// sysroot for the specified `host` and `target`.
430 /// Note that this assumes that `compiler` has already generated the libstd
431 /// libraries for `target`, and this method will find them in the relevant
432 /// output directory.
433 fn run(self, builder: &Builder<'_>) {
434 let compiler = self.compiler;
435 let target_compiler = self.target_compiler;
436 let target = self.target;
437 builder.info(&format!(
438 "Copying stage{} std from stage{} ({} -> {} / {})",
439 target_compiler.stage, compiler.stage, &compiler.host, target_compiler.host, target
441 let libdir = builder.sysroot_libdir(target_compiler, target);
442 let hostdir = builder.sysroot_libdir(target_compiler, compiler.host);
443 add_to_sysroot(builder, &libdir, &hostdir, &libstd_stamp(builder, compiler, target));
447 /// Copies sanitizer runtime libraries into target libdir.
449 builder: &Builder<'_>,
451 target: TargetSelection,
453 let runtimes: Vec<native::SanitizerRuntime> = builder.ensure(native::Sanitizers { target });
455 if builder.config.dry_run {
459 let mut target_deps = Vec::new();
460 let libdir = builder.sysroot_libdir(*compiler, target);
462 for runtime in &runtimes {
463 let dst = libdir.join(&runtime.name);
464 builder.copy(&runtime.path, &dst);
466 if target == "x86_64-apple-darwin" || target == "aarch64-apple-darwin" {
467 // Update the library’s install name to reflect that it has has been renamed.
468 apple_darwin_update_library_name(&dst, &format!("@rpath/{}", &runtime.name));
469 // Upon renaming the install name, the code signature of the file will invalidate,
470 // so we will sign it again.
471 apple_darwin_sign_file(&dst);
474 target_deps.push(dst);
480 fn apple_darwin_update_library_name(library_path: &Path, new_name: &str) {
481 let status = Command::new("install_name_tool")
486 .expect("failed to execute `install_name_tool`");
487 assert!(status.success());
490 fn apple_darwin_sign_file(file_path: &Path) {
491 let status = Command::new("codesign")
492 .arg("-f") // Force to rewrite the existing signature
497 .expect("failed to execute `codesign`");
498 assert!(status.success());
501 #[derive(Debug, Copy, Clone, PartialEq, Eq, Hash)]
502 pub struct StartupObjects {
503 pub compiler: Compiler,
504 pub target: TargetSelection,
507 impl Step for StartupObjects {
508 type Output = Vec<(PathBuf, DependencyType)>;
510 fn should_run(run: ShouldRun<'_>) -> ShouldRun<'_> {
511 run.path("library/rtstartup")
514 fn make_run(run: RunConfig<'_>) {
515 run.builder.ensure(StartupObjects {
516 compiler: run.builder.compiler(run.builder.top_stage, run.build_triple()),
521 /// Builds and prepare startup objects like rsbegin.o and rsend.o
523 /// These are primarily used on Windows right now for linking executables/dlls.
524 /// They don't require any library support as they're just plain old object
525 /// files, so we just use the nightly snapshot compiler to always build them (as
526 /// no other compilers are guaranteed to be available).
527 fn run(self, builder: &Builder<'_>) -> Vec<(PathBuf, DependencyType)> {
528 let for_compiler = self.compiler;
529 let target = self.target;
530 if !target.ends_with("windows-gnu") {
534 let mut target_deps = vec![];
536 let src_dir = &builder.src.join("library").join("rtstartup");
537 let dst_dir = &builder.native_dir(target).join("rtstartup");
538 let sysroot_dir = &builder.sysroot_libdir(for_compiler, target);
539 t!(fs::create_dir_all(dst_dir));
541 for file in &["rsbegin", "rsend"] {
542 let src_file = &src_dir.join(file.to_string() + ".rs");
543 let dst_file = &dst_dir.join(file.to_string() + ".o");
544 if !up_to_date(src_file, dst_file) {
545 let mut cmd = Command::new(&builder.initial_rustc);
546 cmd.env("RUSTC_BOOTSTRAP", "1");
547 if !builder.local_rebuild {
548 // a local_rebuild compiler already has stage1 features
549 cmd.arg("--cfg").arg("bootstrap");
553 .arg(target.rustc_target_arg())
561 let target = sysroot_dir.join((*file).to_string() + ".o");
562 builder.copy(dst_file, &target);
563 target_deps.push((target, DependencyType::Target));
570 #[derive(Debug, PartialOrd, Ord, Copy, Clone, PartialEq, Eq, Hash)]
572 pub target: TargetSelection,
573 pub compiler: Compiler,
574 /// Whether to build a subset of crates, rather than the whole compiler.
576 /// This should only be requested by the user, not used within rustbuild itself.
577 /// Using it within rustbuild can lead to confusing situation where lints are replayed
578 /// in two different steps.
579 crates: Interned<Vec<String>>,
583 pub fn new(compiler: Compiler, target: TargetSelection) -> Self {
584 Self { target, compiler, crates: Default::default() }
588 impl Step for Rustc {
590 const ONLY_HOSTS: bool = true;
591 const DEFAULT: bool = false;
593 fn should_run(run: ShouldRun<'_>) -> ShouldRun<'_> {
594 let mut crates = run.builder.in_tree_crates("rustc-main", None);
595 for (i, krate) in crates.iter().enumerate() {
596 if krate.name == "rustc-main" {
597 crates.swap_remove(i);
604 fn make_run(run: RunConfig<'_>) {
605 let crates = build_crates_in_set(&run);
606 run.builder.ensure(Rustc {
607 compiler: run.builder.compiler(run.builder.top_stage, run.build_triple()),
613 /// Builds the compiler.
615 /// This will build the compiler for a particular stage of the build using
616 /// the `compiler` targeting the `target` architecture. The artifacts
617 /// created will also be linked into the sysroot directory.
618 fn run(self, builder: &Builder<'_>) {
619 let compiler = self.compiler;
620 let target = self.target;
622 // NOTE: the ABI of the beta compiler is different from the ABI of the downloaded compiler,
623 // so its artifacts can't be reused.
624 if builder.download_rustc() && compiler.stage != 0 {
625 // Copy the existing artifacts instead of rebuilding them.
626 // NOTE: this path is only taken for tools linking to rustc-dev.
627 builder.ensure(Sysroot { compiler });
631 builder.ensure(Std::new(compiler, target));
633 if builder.config.keep_stage.contains(&compiler.stage) {
634 builder.info("Warning: Using a potentially old librustc. This may not behave well.");
635 builder.info("Warning: Use `--keep-stage-std` if you want to rebuild the compiler when it changes");
636 builder.ensure(RustcLink::from_rustc(self, compiler));
640 let compiler_to_use = builder.compiler_for(compiler.stage, compiler.host, target);
641 if compiler_to_use != compiler {
642 builder.ensure(Rustc::new(compiler_to_use, target));
644 .info(&format!("Uplifting stage1 rustc ({} -> {})", builder.config.build, target));
645 builder.ensure(RustcLink::from_rustc(self, compiler_to_use));
649 // Ensure that build scripts and proc macros have a std / libproc_macro to link against.
650 builder.ensure(Std::new(
651 builder.compiler(self.compiler.stage, builder.config.build),
652 builder.config.build,
655 let mut cargo = builder.cargo(compiler, Mode::Rustc, SourceType::InTree, target, "build");
656 rustc_cargo(builder, &mut cargo, target);
658 if builder.config.rust_profile_use.is_some()
659 && builder.config.rust_profile_generate.is_some()
661 panic!("Cannot use and generate PGO profiles at the same time");
664 // With LLD, we can use ICF (identical code folding) to reduce the executable size
665 // of librustc_driver/rustc and to improve i-cache utilization.
667 // -Wl,[link options] doesn't work on MSVC. However, /OPT:ICF (technically /OPT:REF,ICF)
668 // is already on by default in MSVC optimized builds, which is interpreted as --icf=all:
669 // https://github.com/llvm/llvm-project/blob/3329cec2f79185bafd678f310fafadba2a8c76d2/lld/COFF/Driver.cpp#L1746
670 // https://github.com/rust-lang/rust/blob/f22819bcce4abaff7d1246a56eec493418f9f4ee/compiler/rustc_codegen_ssa/src/back/linker.rs#L827
671 if builder.config.use_lld && !compiler.host.contains("msvc") {
672 cargo.rustflag("-Clink-args=-Wl,--icf=all");
675 let is_collecting = if let Some(path) = &builder.config.rust_profile_generate {
676 if compiler.stage == 1 {
677 cargo.rustflag(&format!("-Cprofile-generate={}", path));
678 // Apparently necessary to avoid overflowing the counters during
679 // a Cargo build profile
680 cargo.rustflag("-Cllvm-args=-vp-counters-per-site=4");
685 } else if let Some(path) = &builder.config.rust_profile_use {
686 if compiler.stage == 1 {
687 cargo.rustflag(&format!("-Cprofile-use={}", path));
688 cargo.rustflag("-Cllvm-args=-pgo-warn-missing-function");
697 // Ensure paths to Rust sources are relative, not absolute.
698 cargo.rustflag(&format!(
699 "-Cllvm-args=-static-func-strip-dirname-prefix={}",
700 builder.config.src.components().count()
704 builder.info(&format!(
705 "Building stage{} compiler artifacts ({} -> {})",
706 compiler.stage, &compiler.host, target
711 self.crates.to_vec(),
712 &librustc_stamp(builder, compiler, target),
717 builder.ensure(RustcLink::from_rustc(
719 builder.compiler(compiler.stage, builder.config.build),
724 pub fn rustc_cargo(builder: &Builder<'_>, cargo: &mut Cargo, target: TargetSelection) {
727 .arg(builder.rustc_features(builder.kind))
728 .arg("--manifest-path")
729 .arg(builder.src.join("compiler/rustc/Cargo.toml"));
730 rustc_cargo_env(builder, cargo, target);
733 pub fn rustc_cargo_env(builder: &Builder<'_>, cargo: &mut Cargo, target: TargetSelection) {
734 // Set some configuration variables picked up by build scripts and
735 // the compiler alike
737 .env("CFG_RELEASE", builder.rust_release())
738 .env("CFG_RELEASE_CHANNEL", &builder.config.channel)
739 .env("CFG_VERSION", builder.rust_version());
741 if let Some(backend) = builder.config.rust_codegen_backends.get(0) {
742 cargo.env("CFG_DEFAULT_CODEGEN_BACKEND", backend);
745 let libdir_relative = builder.config.libdir_relative().unwrap_or_else(|| Path::new("lib"));
746 let target_config = builder.config.target_config.get(&target);
748 cargo.env("CFG_LIBDIR_RELATIVE", libdir_relative);
750 if let Some(ref ver_date) = builder.rust_info.commit_date() {
751 cargo.env("CFG_VER_DATE", ver_date);
753 if let Some(ref ver_hash) = builder.rust_info.sha() {
754 cargo.env("CFG_VER_HASH", ver_hash);
756 if !builder.unstable_features() {
757 cargo.env("CFG_DISABLE_UNSTABLE_FEATURES", "1");
760 // Prefer the current target's own default_linker, else a globally
762 if let Some(s) = target_config.and_then(|c| c.default_linker.as_ref()) {
763 cargo.env("CFG_DEFAULT_LINKER", s);
764 } else if let Some(ref s) = builder.config.rustc_default_linker {
765 cargo.env("CFG_DEFAULT_LINKER", s);
768 if builder.config.rustc_parallel {
769 // keep in sync with `bootstrap/lib.rs:Build::rustc_features`
770 // `cfg` option for rustc, `features` option for cargo, for conditional compilation
771 cargo.rustflag("--cfg=parallel_compiler");
772 cargo.rustdocflag("--cfg=parallel_compiler");
774 if builder.config.rust_verify_llvm_ir {
775 cargo.env("RUSTC_VERIFY_LLVM_IR", "1");
778 // Pass down configuration from the LLVM build into the build of
779 // rustc_llvm and rustc_codegen_llvm.
781 // Note that this is disabled if LLVM itself is disabled or we're in a check
782 // build. If we are in a check build we still go ahead here presuming we've
783 // detected that LLVM is already built and good to go which helps prevent
784 // busting caches (e.g. like #71152).
785 if builder.config.llvm_enabled()
786 && (builder.kind != Kind::Check
787 || crate::native::prebuilt_llvm_config(builder, target).is_ok())
789 if builder.is_rust_llvm(target) {
790 cargo.env("LLVM_RUSTLLVM", "1");
792 let llvm_config = builder.ensure(native::Llvm { target });
793 cargo.env("LLVM_CONFIG", &llvm_config);
794 if let Some(s) = target_config.and_then(|c| c.llvm_config.as_ref()) {
795 cargo.env("CFG_LLVM_ROOT", s);
798 // Some LLVM linker flags (-L and -l) may be needed to link `rustc_llvm`. Its build script
799 // expects these to be passed via the `LLVM_LINKER_FLAGS` env variable, separated by
803 // - on windows, when `clang-cl` is used with instrumentation, we need to manually add
804 // clang's runtime library resource directory so that the profiler runtime library can be
805 // found. This is to avoid the linker errors about undefined references to
806 // `__llvm_profile_instrument_memop` when linking `rustc_driver`.
807 let mut llvm_linker_flags = String::new();
808 if builder.config.llvm_profile_generate && target.contains("msvc") {
809 if let Some(ref clang_cl_path) = builder.config.llvm_clang_cl {
810 // Add clang's runtime library directory to the search path
811 let clang_rt_dir = get_clang_cl_resource_dir(clang_cl_path);
812 llvm_linker_flags.push_str(&format!("-L{}", clang_rt_dir.display()));
816 // The config can also specify its own llvm linker flags.
817 if let Some(ref s) = builder.config.llvm_ldflags {
818 if !llvm_linker_flags.is_empty() {
819 llvm_linker_flags.push_str(" ");
821 llvm_linker_flags.push_str(s);
824 // Set the linker flags via the env var that `rustc_llvm`'s build script will read.
825 if !llvm_linker_flags.is_empty() {
826 cargo.env("LLVM_LINKER_FLAGS", llvm_linker_flags);
829 // Building with a static libstdc++ is only supported on linux right now,
830 // not for MSVC or macOS
831 if builder.config.llvm_static_stdcpp
832 && !target.contains("freebsd")
833 && !target.contains("msvc")
834 && !target.contains("apple")
835 && !target.contains("solaris")
837 let file = compiler_file(
839 builder.cxx(target).unwrap(),
844 cargo.env("LLVM_STATIC_STDCPP", file);
846 if builder.llvm_link_shared() {
847 cargo.env("LLVM_LINK_SHARED", "1");
849 if builder.config.llvm_use_libcxx {
850 cargo.env("LLVM_USE_LIBCXX", "1");
852 if builder.config.llvm_optimize && !builder.config.llvm_release_debuginfo {
853 cargo.env("LLVM_NDEBUG", "1");
858 #[derive(Debug, Copy, Clone, PartialEq, Eq, Hash)]
860 pub compiler: Compiler,
861 pub target_compiler: Compiler,
862 pub target: TargetSelection,
863 /// Not actually used; only present to make sure the cache invalidation is correct.
864 crates: Interned<Vec<String>>,
868 fn from_rustc(rustc: Rustc, host_compiler: Compiler) -> Self {
870 compiler: host_compiler,
871 target_compiler: rustc.compiler,
872 target: rustc.target,
873 crates: rustc.crates,
878 impl Step for RustcLink {
881 fn should_run(run: ShouldRun<'_>) -> ShouldRun<'_> {
885 /// Same as `std_link`, only for librustc
886 fn run(self, builder: &Builder<'_>) {
887 let compiler = self.compiler;
888 let target_compiler = self.target_compiler;
889 let target = self.target;
890 builder.info(&format!(
891 "Copying stage{} rustc from stage{} ({} -> {} / {})",
892 target_compiler.stage, compiler.stage, &compiler.host, target_compiler.host, target
896 &builder.sysroot_libdir(target_compiler, target),
897 &builder.sysroot_libdir(target_compiler, compiler.host),
898 &librustc_stamp(builder, compiler, target),
903 #[derive(Debug, Copy, Clone, PartialEq, Eq, Hash)]
904 pub struct CodegenBackend {
905 pub target: TargetSelection,
906 pub compiler: Compiler,
907 pub backend: Interned<String>,
910 impl Step for CodegenBackend {
912 const ONLY_HOSTS: bool = true;
913 // Only the backends specified in the `codegen-backends` entry of `config.toml` are built.
914 const DEFAULT: bool = true;
916 fn should_run(run: ShouldRun<'_>) -> ShouldRun<'_> {
917 run.paths(&["compiler/rustc_codegen_cranelift", "compiler/rustc_codegen_gcc"])
920 fn make_run(run: RunConfig<'_>) {
921 for &backend in &run.builder.config.rust_codegen_backends {
922 if backend == "llvm" {
923 continue; // Already built as part of rustc
926 run.builder.ensure(CodegenBackend {
928 compiler: run.builder.compiler(run.builder.top_stage, run.build_triple()),
934 fn run(self, builder: &Builder<'_>) {
935 let compiler = self.compiler;
936 let target = self.target;
937 let backend = self.backend;
939 builder.ensure(Rustc::new(compiler, target));
941 if builder.config.keep_stage.contains(&compiler.stage) {
943 "Warning: Using a potentially old codegen backend. \
944 This may not behave well.",
946 // Codegen backends are linked separately from this step today, so we don't do
951 let compiler_to_use = builder.compiler_for(compiler.stage, compiler.host, target);
952 if compiler_to_use != compiler {
953 builder.ensure(CodegenBackend { compiler: compiler_to_use, target, backend });
957 let out_dir = builder.cargo_out(compiler, Mode::Codegen, target);
959 let mut cargo = builder.cargo(compiler, Mode::Codegen, SourceType::InTree, target, "build");
961 .arg("--manifest-path")
962 .arg(builder.src.join(format!("compiler/rustc_codegen_{}/Cargo.toml", backend)));
963 rustc_cargo_env(builder, &mut cargo, target);
965 let tmp_stamp = out_dir.join(".tmp.stamp");
967 builder.info(&format!(
968 "Building stage{} codegen backend {} ({} -> {})",
969 compiler.stage, backend, &compiler.host, target
971 let files = run_cargo(builder, cargo, vec![], &tmp_stamp, vec![], false);
972 if builder.config.dry_run {
975 let mut files = files.into_iter().filter(|f| {
976 let filename = f.file_name().unwrap().to_str().unwrap();
977 is_dylib(filename) && filename.contains("rustc_codegen_")
979 let codegen_backend = match files.next() {
981 None => panic!("no dylibs built for codegen backend?"),
983 if let Some(f) = files.next() {
985 "codegen backend built two dylibs:\n{}\n{}",
986 codegen_backend.display(),
990 let stamp = codegen_backend_stamp(builder, compiler, target, backend);
991 let codegen_backend = codegen_backend.to_str().unwrap();
992 t!(fs::write(&stamp, &codegen_backend));
996 /// Creates the `codegen-backends` folder for a compiler that's about to be
997 /// assembled as a complete compiler.
999 /// This will take the codegen artifacts produced by `compiler` and link them
1000 /// into an appropriate location for `target_compiler` to be a functional
1002 fn copy_codegen_backends_to_sysroot(
1003 builder: &Builder<'_>,
1005 target_compiler: Compiler,
1007 let target = target_compiler.host;
1009 // Note that this step is different than all the other `*Link` steps in
1010 // that it's not assembling a bunch of libraries but rather is primarily
1011 // moving the codegen backend into place. The codegen backend of rustc is
1012 // not linked into the main compiler by default but is rather dynamically
1013 // selected at runtime for inclusion.
1015 // Here we're looking for the output dylib of the `CodegenBackend` step and
1016 // we're copying that into the `codegen-backends` folder.
1017 let dst = builder.sysroot_codegen_backends(target_compiler);
1018 t!(fs::create_dir_all(&dst), dst);
1020 if builder.config.dry_run {
1024 for backend in builder.config.rust_codegen_backends.iter() {
1025 if backend == "llvm" {
1026 continue; // Already built as part of rustc
1029 let stamp = codegen_backend_stamp(builder, compiler, target, *backend);
1030 let dylib = t!(fs::read_to_string(&stamp));
1031 let file = Path::new(&dylib);
1032 let filename = file.file_name().unwrap().to_str().unwrap();
1033 // change `librustc_codegen_cranelift-xxxxxx.so` to
1034 // `librustc_codegen_cranelift-release.so`
1035 let target_filename = {
1036 let dash = filename.find('-').unwrap();
1037 let dot = filename.find('.').unwrap();
1038 format!("{}-{}{}", &filename[..dash], builder.rust_release(), &filename[dot..])
1040 builder.copy(&file, &dst.join(target_filename));
1044 /// Cargo's output path for the standard library in a given stage, compiled
1045 /// by a particular compiler for the specified target.
1046 pub fn libstd_stamp(builder: &Builder<'_>, compiler: Compiler, target: TargetSelection) -> PathBuf {
1047 builder.cargo_out(compiler, Mode::Std, target).join(".libstd.stamp")
1050 /// Cargo's output path for librustc in a given stage, compiled by a particular
1051 /// compiler for the specified target.
1052 pub fn librustc_stamp(
1053 builder: &Builder<'_>,
1055 target: TargetSelection,
1057 builder.cargo_out(compiler, Mode::Rustc, target).join(".librustc.stamp")
1060 /// Cargo's output path for librustc_codegen_llvm in a given stage, compiled by a particular
1061 /// compiler for the specified target and backend.
1062 fn codegen_backend_stamp(
1063 builder: &Builder<'_>,
1065 target: TargetSelection,
1066 backend: Interned<String>,
1069 .cargo_out(compiler, Mode::Codegen, target)
1070 .join(format!(".librustc_codegen_{}.stamp", backend))
1073 pub fn compiler_file(
1074 builder: &Builder<'_>,
1076 target: TargetSelection,
1080 let mut cmd = Command::new(compiler);
1081 cmd.args(builder.cflags(target, GitRepo::Rustc, c));
1082 cmd.arg(format!("-print-file-name={}", file));
1083 let out = output(&mut cmd);
1084 PathBuf::from(out.trim())
1087 #[derive(Debug, Copy, Clone, PartialEq, Eq, Hash)]
1088 pub struct Sysroot {
1089 pub compiler: Compiler,
1092 impl Step for Sysroot {
1093 type Output = Interned<PathBuf>;
1095 fn should_run(run: ShouldRun<'_>) -> ShouldRun<'_> {
1099 /// Returns the sysroot for the `compiler` specified that *this build system
1102 /// That is, the sysroot for the stage0 compiler is not what the compiler
1103 /// thinks it is by default, but it's the same as the default for stages
1105 fn run(self, builder: &Builder<'_>) -> Interned<PathBuf> {
1106 let compiler = self.compiler;
1107 let sysroot = if compiler.stage == 0 {
1108 builder.out.join(&compiler.host.triple).join("stage0-sysroot")
1110 builder.out.join(&compiler.host.triple).join(format!("stage{}", compiler.stage))
1112 let _ = fs::remove_dir_all(&sysroot);
1113 t!(fs::create_dir_all(&sysroot));
1115 // If we're downloading a compiler from CI, we can use the same compiler for all stages other than 0.
1116 if builder.download_rustc() && compiler.stage != 0 {
1118 builder.config.build, compiler.host,
1119 "Cross-compiling is not yet supported with `download-rustc`",
1121 // Copy the compiler into the correct sysroot.
1123 builder.config.out.join(&*builder.config.build.triple).join("ci-rustc");
1124 builder.cp_r(&ci_rustc_dir, &sysroot);
1125 return INTERNER.intern_path(sysroot);
1128 // Symlink the source root into the same location inside the sysroot,
1129 // where `rust-src` component would go (`$sysroot/lib/rustlib/src/rust`),
1130 // so that any tools relying on `rust-src` also work for local builds,
1131 // and also for translating the virtual `/rustc/$hash` back to the real
1132 // directory (for running tests with `rust.remap-debuginfo = true`).
1133 let sysroot_lib_rustlib_src = sysroot.join("lib/rustlib/src");
1134 t!(fs::create_dir_all(&sysroot_lib_rustlib_src));
1135 let sysroot_lib_rustlib_src_rust = sysroot_lib_rustlib_src.join("rust");
1136 if let Err(e) = symlink_dir(&builder.config, &builder.src, &sysroot_lib_rustlib_src_rust) {
1138 "warning: creating symbolic link `{}` to `{}` failed with {}",
1139 sysroot_lib_rustlib_src_rust.display(),
1140 builder.src.display(),
1143 if builder.config.rust_remap_debuginfo {
1145 "warning: some `src/test/ui` tests will fail when lacking `{}`",
1146 sysroot_lib_rustlib_src_rust.display(),
1151 INTERNER.intern_path(sysroot)
1155 #[derive(Debug, Copy, PartialOrd, Ord, Clone, PartialEq, Eq, Hash)]
1156 pub struct Assemble {
1157 /// The compiler which we will produce in this step. Assemble itself will
1158 /// take care of ensuring that the necessary prerequisites to do so exist,
1159 /// that is, this target can be a stage2 compiler and Assemble will build
1160 /// previous stages for you.
1161 pub target_compiler: Compiler,
1164 impl Step for Assemble {
1165 type Output = Compiler;
1166 const ONLY_HOSTS: bool = true;
1168 fn should_run(run: ShouldRun<'_>) -> ShouldRun<'_> {
1169 run.path("compiler/rustc").path("compiler")
1172 fn make_run(run: RunConfig<'_>) {
1173 run.builder.ensure(Assemble {
1174 target_compiler: run.builder.compiler(run.builder.top_stage + 1, run.target),
1178 /// Prepare a new compiler from the artifacts in `stage`
1180 /// This will assemble a compiler in `build/$host/stage$stage`. The compiler
1181 /// must have been previously produced by the `stage - 1` builder.build
1183 fn run(self, builder: &Builder<'_>) -> Compiler {
1184 let target_compiler = self.target_compiler;
1186 if target_compiler.stage == 0 {
1188 builder.config.build, target_compiler.host,
1189 "Cannot obtain compiler for non-native build triple at stage 0"
1191 // The stage 0 compiler for the build triple is always pre-built.
1192 return target_compiler;
1195 // Get the compiler that we'll use to bootstrap ourselves.
1197 // Note that this is where the recursive nature of the bootstrap
1198 // happens, as this will request the previous stage's compiler on
1199 // downwards to stage 0.
1201 // Also note that we're building a compiler for the host platform. We
1202 // only assume that we can run `build` artifacts, which means that to
1203 // produce some other architecture compiler we need to start from
1204 // `build` to get there.
1206 // FIXME: It may be faster if we build just a stage 1 compiler and then
1207 // use that to bootstrap this compiler forward.
1208 let build_compiler = builder.compiler(target_compiler.stage - 1, builder.config.build);
1210 // If we're downloading a compiler from CI, we can use the same compiler for all stages other than 0.
1211 if builder.download_rustc() {
1212 builder.ensure(Sysroot { compiler: target_compiler });
1213 return target_compiler;
1216 // Build the libraries for this compiler to link to (i.e., the libraries
1217 // it uses at runtime). NOTE: Crates the target compiler compiles don't
1218 // link to these. (FIXME: Is that correct? It seems to be correct most
1219 // of the time but I think we do link to these for stage2/bin compilers
1220 // when not performing a full bootstrap).
1221 builder.ensure(Rustc::new(build_compiler, target_compiler.host));
1223 for &backend in builder.config.rust_codegen_backends.iter() {
1224 if backend == "llvm" {
1225 continue; // Already built as part of rustc
1228 builder.ensure(CodegenBackend {
1229 compiler: build_compiler,
1230 target: target_compiler.host,
1235 let lld_install = if builder.config.lld_enabled {
1236 Some(builder.ensure(native::Lld { target: target_compiler.host }))
1241 let stage = target_compiler.stage;
1242 let host = target_compiler.host;
1243 builder.info(&format!("Assembling stage{} compiler ({})", stage, host));
1245 // Link in all dylibs to the libdir
1246 let stamp = librustc_stamp(builder, build_compiler, target_compiler.host);
1247 let proc_macros = builder
1248 .read_stamp_file(&stamp)
1250 .filter_map(|(path, dependency_type)| {
1251 if dependency_type == DependencyType::Host {
1252 Some(path.file_name().unwrap().to_owned().into_string().unwrap())
1257 .collect::<HashSet<_>>();
1259 let sysroot = builder.sysroot(target_compiler);
1260 let rustc_libdir = builder.rustc_libdir(target_compiler);
1261 t!(fs::create_dir_all(&rustc_libdir));
1262 let src_libdir = builder.sysroot_libdir(build_compiler, host);
1263 for f in builder.read_dir(&src_libdir) {
1264 let filename = f.file_name().into_string().unwrap();
1265 if (is_dylib(&filename) || is_debug_info(&filename)) && !proc_macros.contains(&filename)
1267 builder.copy(&f.path(), &rustc_libdir.join(&filename));
1271 copy_codegen_backends_to_sysroot(builder, build_compiler, target_compiler);
1273 // We prepend this bin directory to the user PATH when linking Rust binaries. To
1274 // avoid shadowing the system LLD we rename the LLD we provide to `rust-lld`.
1275 let libdir = builder.sysroot_libdir(target_compiler, target_compiler.host);
1276 let libdir_bin = libdir.parent().unwrap().join("bin");
1277 t!(fs::create_dir_all(&libdir_bin));
1278 if let Some(lld_install) = lld_install {
1279 let src_exe = exe("lld", target_compiler.host);
1280 let dst_exe = exe("rust-lld", target_compiler.host);
1281 builder.copy(&lld_install.join("bin").join(&src_exe), &libdir_bin.join(&dst_exe));
1282 // for `-Z gcc-ld=lld`
1283 let gcc_ld_dir = libdir_bin.join("gcc-ld");
1284 t!(fs::create_dir(&gcc_ld_dir));
1285 let lld_wrapper_exe = builder.ensure(crate::tool::LldWrapper {
1286 compiler: build_compiler,
1287 target: target_compiler.host,
1289 for name in crate::LLD_FILE_NAMES {
1290 builder.copy(&lld_wrapper_exe, &gcc_ld_dir.join(exe(name, target_compiler.host)));
1294 if builder.config.rust_codegen_backends.contains(&INTERNER.intern_str("llvm")) {
1295 let llvm_config_bin = builder.ensure(native::Llvm { target: target_compiler.host });
1296 if !builder.config.dry_run {
1297 let llvm_bin_dir = output(Command::new(llvm_config_bin).arg("--bindir"));
1298 let llvm_bin_dir = Path::new(llvm_bin_dir.trim());
1300 // Since we've already built the LLVM tools, install them to the sysroot.
1301 // This is the equivalent of installing the `llvm-tools-preview` component via
1302 // rustup, and lets developers use a locally built toolchain to
1303 // build projects that expect llvm tools to be present in the sysroot
1304 // (e.g. the `bootimage` crate).
1305 for tool in LLVM_TOOLS {
1306 let tool_exe = exe(tool, target_compiler.host);
1307 let src_path = llvm_bin_dir.join(&tool_exe);
1308 // When using `download-ci-llvm`, some of the tools
1309 // may not exist, so skip trying to copy them.
1310 if src_path.exists() {
1311 builder.copy(&src_path, &libdir_bin.join(&tool_exe));
1317 // Ensure that `libLLVM.so` ends up in the newly build compiler directory,
1318 // so that it can be found when the newly built `rustc` is run.
1319 dist::maybe_install_llvm_runtime(builder, target_compiler.host, &sysroot);
1320 dist::maybe_install_llvm_target(builder, target_compiler.host, &sysroot);
1322 // Link the compiler binary itself into place
1323 let out_dir = builder.cargo_out(build_compiler, Mode::Rustc, host);
1324 let rustc = out_dir.join(exe("rustc-main", host));
1325 let bindir = sysroot.join("bin");
1326 t!(fs::create_dir_all(&bindir));
1327 let compiler = builder.rustc(target_compiler);
1328 builder.copy(&rustc, &compiler);
1334 /// Link some files into a rustc sysroot.
1336 /// For a particular stage this will link the file listed in `stamp` into the
1337 /// `sysroot_dst` provided.
1338 pub fn add_to_sysroot(
1339 builder: &Builder<'_>,
1341 sysroot_host_dst: &Path,
1344 let self_contained_dst = &sysroot_dst.join("self-contained");
1345 t!(fs::create_dir_all(&sysroot_dst));
1346 t!(fs::create_dir_all(&sysroot_host_dst));
1347 t!(fs::create_dir_all(&self_contained_dst));
1348 for (path, dependency_type) in builder.read_stamp_file(stamp) {
1349 let dst = match dependency_type {
1350 DependencyType::Host => sysroot_host_dst,
1351 DependencyType::Target => sysroot_dst,
1352 DependencyType::TargetSelfContained => self_contained_dst,
1354 builder.copy(&path, &dst.join(path.file_name().unwrap()));
1359 builder: &Builder<'_>,
1361 tail_args: Vec<String>,
1363 additional_target_deps: Vec<(PathBuf, DependencyType)>,
1366 if builder.config.dry_run {
1370 // `target_root_dir` looks like $dir/$target/release
1371 let target_root_dir = stamp.parent().unwrap();
1372 // `target_deps_dir` looks like $dir/$target/release/deps
1373 let target_deps_dir = target_root_dir.join("deps");
1374 // `host_root_dir` looks like $dir/release
1375 let host_root_dir = target_root_dir
1377 .unwrap() // chop off `release`
1379 .unwrap() // chop off `$target`
1380 .join(target_root_dir.file_name().unwrap());
1382 // Spawn Cargo slurping up its JSON output. We'll start building up the
1383 // `deps` array of all files it generated along with a `toplevel` array of
1384 // files we need to probe for later.
1385 let mut deps = Vec::new();
1386 let mut toplevel = Vec::new();
1387 let ok = stream_cargo(builder, cargo, tail_args, &mut |msg| {
1388 let (filenames, crate_types) = match msg {
1389 CargoMessage::CompilerArtifact {
1391 target: CargoTarget { crate_types },
1393 } => (filenames, crate_types),
1396 for filename in filenames {
1397 // Skip files like executables
1398 if !(filename.ends_with(".rlib")
1399 || filename.ends_with(".lib")
1400 || filename.ends_with(".a")
1401 || is_debug_info(&filename)
1402 || is_dylib(&filename)
1403 || (is_check && filename.ends_with(".rmeta")))
1408 let filename = Path::new(&*filename);
1410 // If this was an output file in the "host dir" we don't actually
1411 // worry about it, it's not relevant for us
1412 if filename.starts_with(&host_root_dir) {
1413 // Unless it's a proc macro used in the compiler
1414 if crate_types.iter().any(|t| t == "proc-macro") {
1415 deps.push((filename.to_path_buf(), DependencyType::Host));
1420 // If this was output in the `deps` dir then this is a precise file
1421 // name (hash included) so we start tracking it.
1422 if filename.starts_with(&target_deps_dir) {
1423 deps.push((filename.to_path_buf(), DependencyType::Target));
1427 // Otherwise this was a "top level artifact" which right now doesn't
1428 // have a hash in the name, but there's a version of this file in
1429 // the `deps` folder which *does* have a hash in the name. That's
1430 // the one we'll want to we'll probe for it later.
1432 // We do not use `Path::file_stem` or `Path::extension` here,
1433 // because some generated files may have multiple extensions e.g.
1434 // `std-<hash>.dll.lib` on Windows. The aforementioned methods only
1435 // split the file name by the last extension (`.lib`) while we need
1436 // to split by all extensions (`.dll.lib`).
1437 let expected_len = t!(filename.metadata()).len();
1438 let filename = filename.file_name().unwrap().to_str().unwrap();
1439 let mut parts = filename.splitn(2, '.');
1440 let file_stem = parts.next().unwrap().to_owned();
1441 let extension = parts.next().unwrap().to_owned();
1443 toplevel.push((file_stem, extension, expected_len));
1448 crate::detail_exit(1);
1451 // Ok now we need to actually find all the files listed in `toplevel`. We've
1452 // got a list of prefix/extensions and we basically just need to find the
1453 // most recent file in the `deps` folder corresponding to each one.
1454 let contents = t!(target_deps_dir.read_dir())
1456 .map(|e| (e.path(), e.file_name().into_string().unwrap(), t!(e.metadata())))
1457 .collect::<Vec<_>>();
1458 for (prefix, extension, expected_len) in toplevel {
1459 let candidates = contents.iter().filter(|&&(_, ref filename, ref meta)| {
1460 meta.len() == expected_len
1462 .strip_prefix(&prefix[..])
1463 .map(|s| s.starts_with('-') && s.ends_with(&extension[..]))
1466 let max = candidates.max_by_key(|&&(_, _, ref metadata)| {
1467 metadata.modified().expect("mtime should be available on all relevant OSes")
1469 let path_to_add = match max {
1470 Some(triple) => triple.0.to_str().unwrap(),
1471 None => panic!("no output generated for {:?} {:?}", prefix, extension),
1473 if is_dylib(path_to_add) {
1474 let candidate = format!("{}.lib", path_to_add);
1475 let candidate = PathBuf::from(candidate);
1476 if candidate.exists() {
1477 deps.push((candidate, DependencyType::Target));
1480 deps.push((path_to_add.into(), DependencyType::Target));
1483 deps.extend(additional_target_deps);
1485 let mut new_contents = Vec::new();
1486 for (dep, dependency_type) in deps.iter() {
1487 new_contents.extend(match *dependency_type {
1488 DependencyType::Host => b"h",
1489 DependencyType::Target => b"t",
1490 DependencyType::TargetSelfContained => b"s",
1492 new_contents.extend(dep.to_str().unwrap().as_bytes());
1493 new_contents.extend(b"\0");
1495 t!(fs::write(&stamp, &new_contents));
1496 deps.into_iter().map(|(d, _)| d).collect()
1499 pub fn stream_cargo(
1500 builder: &Builder<'_>,
1502 tail_args: Vec<String>,
1503 cb: &mut dyn FnMut(CargoMessage<'_>),
1505 let mut cargo = Command::from(cargo);
1506 if builder.config.dry_run {
1509 // Instruct Cargo to give us json messages on stdout, critically leaving
1510 // stderr as piped so we can get those pretty colors.
1511 let mut message_format = if builder.config.json_output {
1512 String::from("json")
1514 String::from("json-render-diagnostics")
1516 if let Some(s) = &builder.config.rustc_error_format {
1517 message_format.push_str(",json-diagnostic-");
1518 message_format.push_str(s);
1520 cargo.arg("--message-format").arg(message_format).stdout(Stdio::piped());
1522 for arg in tail_args {
1526 builder.verbose(&format!("running: {:?}", cargo));
1527 let mut child = match cargo.spawn() {
1529 Err(e) => panic!("failed to execute command: {:?}\nerror: {}", cargo, e),
1532 // Spawn Cargo slurping up its JSON output. We'll start building up the
1533 // `deps` array of all files it generated along with a `toplevel` array of
1534 // files we need to probe for later.
1535 let stdout = BufReader::new(child.stdout.take().unwrap());
1536 for line in stdout.lines() {
1537 let line = t!(line);
1538 match serde_json::from_str::<CargoMessage<'_>>(&line) {
1540 if builder.config.json_output {
1541 // Forward JSON to stdout.
1542 println!("{}", line);
1546 // If this was informational, just print it out and continue
1547 Err(_) => println!("{}", line),
1551 // Make sure Cargo actually succeeded after we read all of its stdout.
1552 let status = t!(child.wait());
1553 if builder.is_verbose() && !status.success() {
1555 "command did not execute successfully: {:?}\n\
1556 expected success, got: {}",
1563 #[derive(Deserialize)]
1564 pub struct CargoTarget<'a> {
1565 crate_types: Vec<Cow<'a, str>>,
1568 #[derive(Deserialize)]
1569 #[serde(tag = "reason", rename_all = "kebab-case")]
1570 pub enum CargoMessage<'a> {
1572 package_id: Cow<'a, str>,
1573 features: Vec<Cow<'a, str>>,
1574 filenames: Vec<Cow<'a, str>>,
1575 target: CargoTarget<'a>,
1577 BuildScriptExecuted {
1578 package_id: Cow<'a, str>,