992 lines
36 KiB
Rust
992 lines
36 KiB
Rust
//! Implementation of compiling various phases of the compiler and standard
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//! library.
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//!
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//! This module contains some of the real meat in the rustbuild build system
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//! which is where Cargo is used to compiler the standard library, libtest, and
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//! compiler. This module is also responsible for assembling the sysroot as it
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//! goes along from the output of the previous stage.
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use std::borrow::Cow;
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use std::env;
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use std::fs;
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use std::io::BufReader;
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use std::io::prelude::*;
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use std::path::{Path, PathBuf};
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use std::process::{Command, Stdio, exit};
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use std::str;
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use build_helper::{output, t, up_to_date};
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use filetime::FileTime;
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use serde::Deserialize;
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use serde_json;
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use crate::dist;
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use crate::builder::Cargo;
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use crate::util::{exe, is_dylib};
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use crate::{Compiler, Mode, GitRepo};
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use crate::native;
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use crate::cache::{INTERNER, Interned};
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use crate::builder::{Step, RunConfig, ShouldRun, Builder, Kind};
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#[derive(Debug, PartialOrd, Ord, Copy, Clone, PartialEq, Eq, Hash)]
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pub struct Std {
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pub target: Interned<String>,
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pub compiler: Compiler,
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}
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impl Step for Std {
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type Output = ();
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const DEFAULT: bool = true;
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fn should_run(run: ShouldRun<'_>) -> ShouldRun<'_> {
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run.all_krates("test")
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}
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fn make_run(run: RunConfig<'_>) {
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run.builder.ensure(Std {
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compiler: run.builder.compiler(run.builder.top_stage, run.host),
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target: run.target,
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});
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}
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/// Builds the standard library.
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///
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/// This will build the standard library for a particular stage of the build
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/// using the `compiler` targeting the `target` architecture. The artifacts
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/// created will also be linked into the sysroot directory.
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fn run(self, builder: &Builder<'_>) {
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let target = self.target;
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let compiler = self.compiler;
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if builder.config.keep_stage.contains(&compiler.stage) {
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builder.info("Warning: Using a potentially old libstd. This may not behave well.");
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builder.ensure(StdLink {
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compiler,
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target_compiler: compiler,
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target,
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});
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return;
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}
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let mut target_deps = builder.ensure(StartupObjects { compiler, target });
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let compiler_to_use = builder.compiler_for(compiler.stage, compiler.host, target);
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if compiler_to_use != compiler {
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builder.ensure(Std {
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compiler: compiler_to_use,
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target,
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});
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builder.info(&format!("Uplifting stage1 std ({} -> {})", compiler_to_use.host, target));
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// Even if we're not building std this stage, the new sysroot must
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// still contain the third party objects needed by various targets.
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copy_third_party_objects(builder, &compiler, target);
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builder.ensure(StdLink {
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compiler: compiler_to_use,
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target_compiler: compiler,
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target,
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});
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return;
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}
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target_deps.extend(copy_third_party_objects(builder, &compiler, target).into_iter());
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let mut cargo = builder.cargo(compiler, Mode::Std, target, "build");
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std_cargo(builder, &compiler, target, &mut cargo);
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builder.info(&format!("Building stage{} std artifacts ({} -> {})", compiler.stage,
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&compiler.host, target));
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run_cargo(builder,
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cargo,
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vec![],
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&libstd_stamp(builder, compiler, target),
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target_deps,
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false);
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builder.ensure(StdLink {
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compiler: builder.compiler(compiler.stage, builder.config.build),
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target_compiler: compiler,
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target,
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});
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}
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}
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/// Copies third party objects needed by various targets.
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fn copy_third_party_objects(builder: &Builder<'_>, compiler: &Compiler, target: Interned<String>)
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-> Vec<PathBuf>
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{
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let libdir = builder.sysroot_libdir(*compiler, target);
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let mut target_deps = vec![];
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let mut copy_and_stamp = |sourcedir: &Path, name: &str| {
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let target = libdir.join(name);
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builder.copy(
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&sourcedir.join(name),
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&target,
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);
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target_deps.push(target);
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};
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// Copies the crt(1,i,n).o startup objects
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//
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// Since musl supports fully static linking, we can cross link for it even
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// with a glibc-targeting toolchain, given we have the appropriate startup
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// files. As those shipped with glibc won't work, copy the ones provided by
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// musl so we have them on linux-gnu hosts.
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if target.contains("musl") {
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let srcdir = builder.musl_root(target).unwrap().join("lib");
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for &obj in &["crt1.o", "crti.o", "crtn.o"] {
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copy_and_stamp(&srcdir, obj);
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}
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} else if target.ends_with("-wasi") {
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let srcdir = builder.wasi_root(target).unwrap().join("lib/wasm32-wasi");
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copy_and_stamp(&srcdir, "crt1.o");
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}
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// Copies libunwind.a compiled to be linked wit x86_64-fortanix-unknown-sgx.
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//
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// This target needs to be linked to Fortanix's port of llvm's libunwind.
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// libunwind requires support for rwlock and printing to stderr,
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// which is provided by std for this target.
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if target == "x86_64-fortanix-unknown-sgx" {
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let src_path_env = "X86_FORTANIX_SGX_LIBS";
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let src = env::var(src_path_env).expect(&format!("{} not found in env", src_path_env));
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copy_and_stamp(Path::new(&src), "libunwind.a");
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}
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target_deps
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}
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/// Configure cargo to compile the standard library, adding appropriate env vars
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/// and such.
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pub fn std_cargo(builder: &Builder<'_>,
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compiler: &Compiler,
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target: Interned<String>,
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cargo: &mut Cargo) {
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if let Some(target) = env::var_os("MACOSX_STD_DEPLOYMENT_TARGET") {
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cargo.env("MACOSX_DEPLOYMENT_TARGET", target);
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}
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// Determine if we're going to compile in optimized C intrinsics to
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// the `compiler-builtins` crate. These intrinsics live in LLVM's
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// `compiler-rt` repository, but our `src/llvm-project` submodule isn't
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// always checked out, so we need to conditionally look for this. (e.g. if
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// an external LLVM is used we skip the LLVM submodule checkout).
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//
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// Note that this shouldn't affect the correctness of `compiler-builtins`,
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// but only its speed. Some intrinsics in C haven't been translated to Rust
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// yet but that's pretty rare. Other intrinsics have optimized
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// implementations in C which have only had slower versions ported to Rust,
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// so we favor the C version where we can, but it's not critical.
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//
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// If `compiler-rt` is available ensure that the `c` feature of the
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// `compiler-builtins` crate is enabled and it's configured to learn where
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// `compiler-rt` is located.
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let compiler_builtins_root = builder.src.join("src/llvm-project/compiler-rt");
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let compiler_builtins_c_feature = if compiler_builtins_root.exists() {
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cargo.env("RUST_COMPILER_RT_ROOT", &compiler_builtins_root);
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" compiler-builtins-c".to_string()
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} else {
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String::new()
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};
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if builder.no_std(target) == Some(true) {
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let mut features = "compiler-builtins-mem".to_string();
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features.push_str(&compiler_builtins_c_feature);
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// for no-std targets we only compile a few no_std crates
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cargo
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.args(&["-p", "alloc"])
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.arg("--manifest-path")
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.arg(builder.src.join("src/liballoc/Cargo.toml"))
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.arg("--features")
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.arg("compiler-builtins-mem compiler-builtins-c");
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} else {
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let mut features = builder.std_features();
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features.push_str(&compiler_builtins_c_feature);
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if compiler.stage != 0 && builder.config.sanitizers {
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// This variable is used by the sanitizer runtime crates, e.g.
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// rustc_lsan, to build the sanitizer runtime from C code
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// When this variable is missing, those crates won't compile the C code,
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// so we don't set this variable during stage0 where llvm-config is
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// missing
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// We also only build the runtimes when --enable-sanitizers (or its
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// config.toml equivalent) is used
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let llvm_config = builder.ensure(native::Llvm {
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target: builder.config.build,
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});
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cargo.env("LLVM_CONFIG", llvm_config);
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cargo.env("RUSTC_BUILD_SANITIZERS", "1");
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}
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cargo.arg("--features").arg(features)
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.arg("--manifest-path")
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.arg(builder.src.join("src/libtest/Cargo.toml"));
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// Help the libc crate compile by assisting it in finding various
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// sysroot native libraries.
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if target.contains("musl") {
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if let Some(p) = builder.musl_root(target) {
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let root = format!("native={}/lib", p.to_str().unwrap());
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cargo.rustflag("-L").rustflag(&root);
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}
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}
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if target.ends_with("-wasi") {
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if let Some(p) = builder.wasi_root(target) {
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let root = format!("native={}/lib/wasm32-wasi", p.to_str().unwrap());
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cargo.rustflag("-L").rustflag(&root);
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}
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}
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}
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}
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#[derive(Debug, Copy, Clone, PartialEq, Eq, Hash)]
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struct StdLink {
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pub compiler: Compiler,
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pub target_compiler: Compiler,
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pub target: Interned<String>,
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}
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impl Step for StdLink {
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type Output = ();
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fn should_run(run: ShouldRun<'_>) -> ShouldRun<'_> {
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run.never()
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}
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/// Link all libstd rlibs/dylibs into the sysroot location.
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///
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/// Links those artifacts generated by `compiler` to the `stage` compiler's
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/// sysroot for the specified `host` and `target`.
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///
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/// Note that this assumes that `compiler` has already generated the libstd
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/// libraries for `target`, and this method will find them in the relevant
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/// output directory.
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fn run(self, builder: &Builder<'_>) {
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let compiler = self.compiler;
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let target_compiler = self.target_compiler;
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let target = self.target;
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builder.info(&format!("Copying stage{} std from stage{} ({} -> {} / {})",
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target_compiler.stage,
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compiler.stage,
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&compiler.host,
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target_compiler.host,
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target));
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let libdir = builder.sysroot_libdir(target_compiler, target);
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let hostdir = builder.sysroot_libdir(target_compiler, compiler.host);
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add_to_sysroot(builder, &libdir, &hostdir, &libstd_stamp(builder, compiler, target));
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if builder.config.sanitizers && compiler.stage != 0 && target == "x86_64-apple-darwin" {
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// The sanitizers are only built in stage1 or above, so the dylibs will
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// be missing in stage0 and causes panic. See the `std()` function above
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// for reason why the sanitizers are not built in stage0.
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copy_apple_sanitizer_dylibs(builder, &builder.native_dir(target), "osx", &libdir);
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}
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}
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}
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fn copy_apple_sanitizer_dylibs(
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builder: &Builder<'_>,
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native_dir: &Path,
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platform: &str,
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into: &Path,
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) {
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for &sanitizer in &["asan", "tsan"] {
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let filename = format!("lib__rustc__clang_rt.{}_{}_dynamic.dylib", sanitizer, platform);
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let mut src_path = native_dir.join(sanitizer);
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src_path.push("build");
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src_path.push("lib");
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src_path.push("darwin");
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src_path.push(&filename);
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builder.copy(&src_path, &into.join(filename));
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}
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}
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#[derive(Debug, Copy, Clone, PartialEq, Eq, Hash)]
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pub struct StartupObjects {
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pub compiler: Compiler,
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pub target: Interned<String>,
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}
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impl Step for StartupObjects {
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type Output = Vec<PathBuf>;
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fn should_run(run: ShouldRun<'_>) -> ShouldRun<'_> {
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run.path("src/rtstartup")
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}
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fn make_run(run: RunConfig<'_>) {
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run.builder.ensure(StartupObjects {
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compiler: run.builder.compiler(run.builder.top_stage, run.host),
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target: run.target,
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});
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}
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/// Builds and prepare startup objects like rsbegin.o and rsend.o
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///
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/// These are primarily used on Windows right now for linking executables/dlls.
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/// They don't require any library support as they're just plain old object
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/// files, so we just use the nightly snapshot compiler to always build them (as
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/// no other compilers are guaranteed to be available).
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fn run(self, builder: &Builder<'_>) -> Vec<PathBuf> {
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let for_compiler = self.compiler;
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let target = self.target;
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if !target.contains("windows-gnu") {
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return vec![]
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}
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let mut target_deps = vec![];
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let src_dir = &builder.src.join("src/rtstartup");
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let dst_dir = &builder.native_dir(target).join("rtstartup");
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let sysroot_dir = &builder.sysroot_libdir(for_compiler, target);
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t!(fs::create_dir_all(dst_dir));
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for file in &["rsbegin", "rsend"] {
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let src_file = &src_dir.join(file.to_string() + ".rs");
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let dst_file = &dst_dir.join(file.to_string() + ".o");
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if !up_to_date(src_file, dst_file) {
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let mut cmd = Command::new(&builder.initial_rustc);
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builder.run(cmd.env("RUSTC_BOOTSTRAP", "1")
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.arg("--cfg").arg("bootstrap")
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.arg("--target").arg(target)
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.arg("--emit=obj")
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.arg("-o").arg(dst_file)
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.arg(src_file));
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}
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let target = sysroot_dir.join(file.to_string() + ".o");
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builder.copy(dst_file, &target);
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target_deps.push(target);
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}
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for obj in ["crt2.o", "dllcrt2.o"].iter() {
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let src = compiler_file(builder,
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builder.cc(target),
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target,
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obj);
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let target = sysroot_dir.join(obj);
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builder.copy(&src, &target);
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target_deps.push(target);
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}
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target_deps
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}
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}
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#[derive(Debug, PartialOrd, Ord, Copy, Clone, PartialEq, Eq, Hash)]
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pub struct Rustc {
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pub target: Interned<String>,
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pub compiler: Compiler,
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}
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impl Step for Rustc {
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type Output = ();
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const ONLY_HOSTS: bool = true;
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const DEFAULT: bool = true;
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fn should_run(run: ShouldRun<'_>) -> ShouldRun<'_> {
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run.all_krates("rustc-main")
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}
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fn make_run(run: RunConfig<'_>) {
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run.builder.ensure(Rustc {
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compiler: run.builder.compiler(run.builder.top_stage, run.host),
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target: run.target,
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});
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}
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/// Builds the compiler.
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///
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/// This will build the compiler for a particular stage of the build using
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/// the `compiler` targeting the `target` architecture. The artifacts
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/// created will also be linked into the sysroot directory.
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fn run(self, builder: &Builder<'_>) {
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let compiler = self.compiler;
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let target = self.target;
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builder.ensure(Std { compiler, target });
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if builder.config.keep_stage.contains(&compiler.stage) {
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builder.info("Warning: Using a potentially old librustc. This may not behave well.");
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builder.ensure(RustcLink {
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compiler,
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target_compiler: compiler,
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target,
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});
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return;
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}
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let compiler_to_use = builder.compiler_for(compiler.stage, compiler.host, target);
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if compiler_to_use != compiler {
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builder.ensure(Rustc {
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compiler: compiler_to_use,
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target,
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});
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builder.info(&format!("Uplifting stage1 rustc ({} -> {})",
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builder.config.build, target));
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builder.ensure(RustcLink {
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compiler: compiler_to_use,
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target_compiler: compiler,
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target,
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});
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return;
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}
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|
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// Ensure that build scripts and proc macros have a std / libproc_macro to link against.
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builder.ensure(Std {
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compiler: builder.compiler(self.compiler.stage, builder.config.build),
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target: builder.config.build,
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});
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let mut cargo = builder.cargo(compiler, Mode::Rustc, target, "build");
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rustc_cargo(builder, &mut cargo, target);
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builder.info(&format!("Building stage{} compiler artifacts ({} -> {})",
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compiler.stage, &compiler.host, target));
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run_cargo(builder,
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cargo,
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vec![],
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&librustc_stamp(builder, compiler, target),
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vec![],
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false);
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builder.ensure(RustcLink {
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compiler: builder.compiler(compiler.stage, builder.config.build),
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target_compiler: compiler,
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target,
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});
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}
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}
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pub fn rustc_cargo(builder: &Builder<'_>, cargo: &mut Cargo, target: Interned<String>) {
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cargo.arg("--features").arg(builder.rustc_features())
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.arg("--manifest-path")
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.arg(builder.src.join("src/rustc/Cargo.toml"));
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rustc_cargo_env(builder, cargo, target);
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}
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pub fn rustc_cargo_env(builder: &Builder<'_>, cargo: &mut Cargo, target: Interned<String>) {
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// Set some configuration variables picked up by build scripts and
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// the compiler alike
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cargo.env("CFG_RELEASE", builder.rust_release())
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.env("CFG_RELEASE_CHANNEL", &builder.config.channel)
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.env("CFG_VERSION", builder.rust_version())
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.env("CFG_PREFIX", builder.config.prefix.clone().unwrap_or_default());
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let libdir_relative = builder.config.libdir_relative().unwrap_or(Path::new("lib"));
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cargo.env("CFG_LIBDIR_RELATIVE", libdir_relative);
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if let Some(ref ver_date) = builder.rust_info.commit_date() {
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cargo.env("CFG_VER_DATE", ver_date);
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}
|
|
if let Some(ref ver_hash) = builder.rust_info.sha() {
|
|
cargo.env("CFG_VER_HASH", ver_hash);
|
|
}
|
|
if !builder.unstable_features() {
|
|
cargo.env("CFG_DISABLE_UNSTABLE_FEATURES", "1");
|
|
}
|
|
if let Some(ref s) = builder.config.rustc_default_linker {
|
|
cargo.env("CFG_DEFAULT_LINKER", s);
|
|
}
|
|
if builder.config.rustc_parallel {
|
|
cargo.rustflag("--cfg=parallel_compiler");
|
|
}
|
|
if builder.config.rust_verify_llvm_ir {
|
|
cargo.env("RUSTC_VERIFY_LLVM_IR", "1");
|
|
}
|
|
|
|
// Pass down configuration from the LLVM build into the build of
|
|
// librustc_llvm and librustc_codegen_llvm.
|
|
//
|
|
// Note that this is disabled if LLVM itself is disabled or we're in a check
|
|
// build, where if we're in a check build there's no need to build all of
|
|
// LLVM and such.
|
|
if builder.config.llvm_enabled() && builder.kind != Kind::Check {
|
|
if builder.is_rust_llvm(target) {
|
|
cargo.env("LLVM_RUSTLLVM", "1");
|
|
}
|
|
let llvm_config = builder.ensure(native::Llvm { target });
|
|
cargo.env("LLVM_CONFIG", &llvm_config);
|
|
let target_config = builder.config.target_config.get(&target);
|
|
if let Some(s) = target_config.and_then(|c| c.llvm_config.as_ref()) {
|
|
cargo.env("CFG_LLVM_ROOT", s);
|
|
}
|
|
// Some LLVM linker flags (-L and -l) may be needed to link librustc_llvm.
|
|
if let Some(ref s) = builder.config.llvm_ldflags {
|
|
cargo.env("LLVM_LINKER_FLAGS", s);
|
|
}
|
|
// Building with a static libstdc++ is only supported on linux right now,
|
|
// not for MSVC or macOS
|
|
if builder.config.llvm_static_stdcpp &&
|
|
!target.contains("freebsd") &&
|
|
!target.contains("windows") &&
|
|
!target.contains("apple") {
|
|
let file = compiler_file(builder,
|
|
builder.cxx(target).unwrap(),
|
|
target,
|
|
"libstdc++.a");
|
|
cargo.env("LLVM_STATIC_STDCPP", file);
|
|
}
|
|
if builder.config.llvm_link_shared || builder.config.llvm_thin_lto {
|
|
cargo.env("LLVM_LINK_SHARED", "1");
|
|
}
|
|
if builder.config.llvm_use_libcxx {
|
|
cargo.env("LLVM_USE_LIBCXX", "1");
|
|
}
|
|
if builder.config.llvm_optimize && !builder.config.llvm_release_debuginfo {
|
|
cargo.env("LLVM_NDEBUG", "1");
|
|
}
|
|
}
|
|
}
|
|
|
|
#[derive(Debug, Copy, Clone, PartialEq, Eq, Hash)]
|
|
struct RustcLink {
|
|
pub compiler: Compiler,
|
|
pub target_compiler: Compiler,
|
|
pub target: Interned<String>,
|
|
}
|
|
|
|
impl Step for RustcLink {
|
|
type Output = ();
|
|
|
|
fn should_run(run: ShouldRun<'_>) -> ShouldRun<'_> {
|
|
run.never()
|
|
}
|
|
|
|
/// Same as `std_link`, only for librustc
|
|
fn run(self, builder: &Builder<'_>) {
|
|
let compiler = self.compiler;
|
|
let target_compiler = self.target_compiler;
|
|
let target = self.target;
|
|
builder.info(&format!("Copying stage{} rustc from stage{} ({} -> {} / {})",
|
|
target_compiler.stage,
|
|
compiler.stage,
|
|
&compiler.host,
|
|
target_compiler.host,
|
|
target));
|
|
add_to_sysroot(
|
|
builder,
|
|
&builder.sysroot_libdir(target_compiler, target),
|
|
&builder.sysroot_libdir(target_compiler, compiler.host),
|
|
&librustc_stamp(builder, compiler, target)
|
|
);
|
|
}
|
|
}
|
|
|
|
fn copy_lld_to_sysroot(builder: &Builder<'_>,
|
|
target_compiler: Compiler,
|
|
lld_install_root: &Path) {
|
|
let target = target_compiler.host;
|
|
|
|
let dst = builder.sysroot_libdir(target_compiler, target)
|
|
.parent()
|
|
.unwrap()
|
|
.join("bin");
|
|
t!(fs::create_dir_all(&dst));
|
|
|
|
let src_exe = exe("lld", &target);
|
|
let dst_exe = exe("rust-lld", &target);
|
|
// we prepend this bin directory to the user PATH when linking Rust binaries. To
|
|
// avoid shadowing the system LLD we rename the LLD we provide to `rust-lld`.
|
|
builder.copy(&lld_install_root.join("bin").join(&src_exe), &dst.join(&dst_exe));
|
|
}
|
|
|
|
/// Cargo's output path for the standard library in a given stage, compiled
|
|
/// by a particular compiler for the specified target.
|
|
pub fn libstd_stamp(
|
|
builder: &Builder<'_>,
|
|
compiler: Compiler,
|
|
target: Interned<String>,
|
|
) -> PathBuf {
|
|
builder.cargo_out(compiler, Mode::Std, target).join(".libstd.stamp")
|
|
}
|
|
|
|
/// Cargo's output path for librustc in a given stage, compiled by a particular
|
|
/// compiler for the specified target.
|
|
pub fn librustc_stamp(
|
|
builder: &Builder<'_>,
|
|
compiler: Compiler,
|
|
target: Interned<String>,
|
|
) -> PathBuf {
|
|
builder.cargo_out(compiler, Mode::Rustc, target).join(".librustc.stamp")
|
|
}
|
|
|
|
pub fn compiler_file(
|
|
builder: &Builder<'_>,
|
|
compiler: &Path,
|
|
target: Interned<String>,
|
|
file: &str,
|
|
) -> PathBuf {
|
|
let mut cmd = Command::new(compiler);
|
|
cmd.args(builder.cflags(target, GitRepo::Rustc));
|
|
cmd.arg(format!("-print-file-name={}", file));
|
|
let out = output(&mut cmd);
|
|
PathBuf::from(out.trim())
|
|
}
|
|
|
|
#[derive(Debug, Copy, Clone, PartialEq, Eq, Hash)]
|
|
pub struct Sysroot {
|
|
pub compiler: Compiler,
|
|
}
|
|
|
|
impl Step for Sysroot {
|
|
type Output = Interned<PathBuf>;
|
|
|
|
fn should_run(run: ShouldRun<'_>) -> ShouldRun<'_> {
|
|
run.never()
|
|
}
|
|
|
|
/// Returns the sysroot for the `compiler` specified that *this build system
|
|
/// generates*.
|
|
///
|
|
/// That is, the sysroot for the stage0 compiler is not what the compiler
|
|
/// thinks it is by default, but it's the same as the default for stages
|
|
/// 1-3.
|
|
fn run(self, builder: &Builder<'_>) -> Interned<PathBuf> {
|
|
let compiler = self.compiler;
|
|
let sysroot = if compiler.stage == 0 {
|
|
builder.out.join(&compiler.host).join("stage0-sysroot")
|
|
} else {
|
|
builder.out.join(&compiler.host).join(format!("stage{}", compiler.stage))
|
|
};
|
|
let _ = fs::remove_dir_all(&sysroot);
|
|
t!(fs::create_dir_all(&sysroot));
|
|
INTERNER.intern_path(sysroot)
|
|
}
|
|
}
|
|
|
|
#[derive(Debug, Copy, PartialOrd, Ord, Clone, PartialEq, Eq, Hash)]
|
|
pub struct Assemble {
|
|
/// The compiler which we will produce in this step. Assemble itself will
|
|
/// take care of ensuring that the necessary prerequisites to do so exist,
|
|
/// that is, this target can be a stage2 compiler and Assemble will build
|
|
/// previous stages for you.
|
|
pub target_compiler: Compiler,
|
|
}
|
|
|
|
impl Step for Assemble {
|
|
type Output = Compiler;
|
|
|
|
fn should_run(run: ShouldRun<'_>) -> ShouldRun<'_> {
|
|
run.never()
|
|
}
|
|
|
|
/// Prepare a new compiler from the artifacts in `stage`
|
|
///
|
|
/// This will assemble a compiler in `build/$host/stage$stage`. The compiler
|
|
/// must have been previously produced by the `stage - 1` builder.build
|
|
/// compiler.
|
|
fn run(self, builder: &Builder<'_>) -> Compiler {
|
|
let target_compiler = self.target_compiler;
|
|
|
|
if target_compiler.stage == 0 {
|
|
assert_eq!(builder.config.build, target_compiler.host,
|
|
"Cannot obtain compiler for non-native build triple at stage 0");
|
|
// The stage 0 compiler for the build triple is always pre-built.
|
|
return target_compiler;
|
|
}
|
|
|
|
// Get the compiler that we'll use to bootstrap ourselves.
|
|
//
|
|
// Note that this is where the recursive nature of the bootstrap
|
|
// happens, as this will request the previous stage's compiler on
|
|
// downwards to stage 0.
|
|
//
|
|
// Also note that we're building a compiler for the host platform. We
|
|
// only assume that we can run `build` artifacts, which means that to
|
|
// produce some other architecture compiler we need to start from
|
|
// `build` to get there.
|
|
//
|
|
// FIXME: Perhaps we should download those libraries?
|
|
// It would make builds faster...
|
|
//
|
|
// FIXME: It may be faster if we build just a stage 1 compiler and then
|
|
// use that to bootstrap this compiler forward.
|
|
let build_compiler =
|
|
builder.compiler(target_compiler.stage - 1, builder.config.build);
|
|
|
|
// Build the libraries for this compiler to link to (i.e., the libraries
|
|
// it uses at runtime). NOTE: Crates the target compiler compiles don't
|
|
// link to these. (FIXME: Is that correct? It seems to be correct most
|
|
// of the time but I think we do link to these for stage2/bin compilers
|
|
// when not performing a full bootstrap).
|
|
builder.ensure(Rustc {
|
|
compiler: build_compiler,
|
|
target: target_compiler.host,
|
|
});
|
|
|
|
let lld_install = if builder.config.lld_enabled {
|
|
Some(builder.ensure(native::Lld {
|
|
target: target_compiler.host,
|
|
}))
|
|
} else {
|
|
None
|
|
};
|
|
|
|
let stage = target_compiler.stage;
|
|
let host = target_compiler.host;
|
|
builder.info(&format!("Assembling stage{} compiler ({})", stage, host));
|
|
|
|
// Link in all dylibs to the libdir
|
|
let sysroot = builder.sysroot(target_compiler);
|
|
let rustc_libdir = builder.rustc_libdir(target_compiler);
|
|
t!(fs::create_dir_all(&rustc_libdir));
|
|
let src_libdir = builder.sysroot_libdir(build_compiler, host);
|
|
for f in builder.read_dir(&src_libdir) {
|
|
let filename = f.file_name().into_string().unwrap();
|
|
if is_dylib(&filename) {
|
|
builder.copy(&f.path(), &rustc_libdir.join(&filename));
|
|
}
|
|
}
|
|
|
|
if let Some(lld_install) = lld_install {
|
|
copy_lld_to_sysroot(builder, target_compiler, &lld_install);
|
|
}
|
|
|
|
dist::maybe_install_llvm_dylib(builder, target_compiler.host, &sysroot);
|
|
|
|
// Link the compiler binary itself into place
|
|
let out_dir = builder.cargo_out(build_compiler, Mode::Rustc, host);
|
|
let rustc = out_dir.join(exe("rustc_binary", &*host));
|
|
let bindir = sysroot.join("bin");
|
|
t!(fs::create_dir_all(&bindir));
|
|
let compiler = builder.rustc(target_compiler);
|
|
let _ = fs::remove_file(&compiler);
|
|
builder.copy(&rustc, &compiler);
|
|
|
|
target_compiler
|
|
}
|
|
}
|
|
|
|
/// Link some files into a rustc sysroot.
|
|
///
|
|
/// For a particular stage this will link the file listed in `stamp` into the
|
|
/// `sysroot_dst` provided.
|
|
pub fn add_to_sysroot(
|
|
builder: &Builder<'_>,
|
|
sysroot_dst: &Path,
|
|
sysroot_host_dst: &Path,
|
|
stamp: &Path
|
|
) {
|
|
t!(fs::create_dir_all(&sysroot_dst));
|
|
t!(fs::create_dir_all(&sysroot_host_dst));
|
|
for (path, host) in builder.read_stamp_file(stamp) {
|
|
if host {
|
|
builder.copy(&path, &sysroot_host_dst.join(path.file_name().unwrap()));
|
|
} else {
|
|
builder.copy(&path, &sysroot_dst.join(path.file_name().unwrap()));
|
|
}
|
|
}
|
|
}
|
|
|
|
pub fn run_cargo(builder: &Builder<'_>,
|
|
cargo: Cargo,
|
|
tail_args: Vec<String>,
|
|
stamp: &Path,
|
|
additional_target_deps: Vec<PathBuf>,
|
|
is_check: bool)
|
|
-> Vec<PathBuf>
|
|
{
|
|
if builder.config.dry_run {
|
|
return Vec::new();
|
|
}
|
|
|
|
// `target_root_dir` looks like $dir/$target/release
|
|
let target_root_dir = stamp.parent().unwrap();
|
|
// `target_deps_dir` looks like $dir/$target/release/deps
|
|
let target_deps_dir = target_root_dir.join("deps");
|
|
// `host_root_dir` looks like $dir/release
|
|
let host_root_dir = target_root_dir.parent().unwrap() // chop off `release`
|
|
.parent().unwrap() // chop off `$target`
|
|
.join(target_root_dir.file_name().unwrap());
|
|
|
|
// Spawn Cargo slurping up its JSON output. We'll start building up the
|
|
// `deps` array of all files it generated along with a `toplevel` array of
|
|
// files we need to probe for later.
|
|
let mut deps = Vec::new();
|
|
let mut toplevel = Vec::new();
|
|
let ok = stream_cargo(builder, cargo, tail_args, &mut |msg| {
|
|
let (filenames, crate_types) = match msg {
|
|
CargoMessage::CompilerArtifact {
|
|
filenames,
|
|
target: CargoTarget {
|
|
crate_types,
|
|
},
|
|
..
|
|
} => (filenames, crate_types),
|
|
_ => return,
|
|
};
|
|
for filename in filenames {
|
|
// Skip files like executables
|
|
if !filename.ends_with(".rlib") &&
|
|
!filename.ends_with(".lib") &&
|
|
!filename.ends_with(".a") &&
|
|
!is_dylib(&filename) &&
|
|
!(is_check && filename.ends_with(".rmeta")) {
|
|
continue;
|
|
}
|
|
|
|
let filename = Path::new(&*filename);
|
|
|
|
// If this was an output file in the "host dir" we don't actually
|
|
// worry about it, it's not relevant for us
|
|
if filename.starts_with(&host_root_dir) {
|
|
// Unless it's a proc macro used in the compiler
|
|
if crate_types.iter().any(|t| t == "proc-macro") {
|
|
deps.push((filename.to_path_buf(), true));
|
|
}
|
|
continue;
|
|
}
|
|
|
|
// If this was output in the `deps` dir then this is a precise file
|
|
// name (hash included) so we start tracking it.
|
|
if filename.starts_with(&target_deps_dir) {
|
|
deps.push((filename.to_path_buf(), false));
|
|
continue;
|
|
}
|
|
|
|
// Otherwise this was a "top level artifact" which right now doesn't
|
|
// have a hash in the name, but there's a version of this file in
|
|
// the `deps` folder which *does* have a hash in the name. That's
|
|
// the one we'll want to we'll probe for it later.
|
|
//
|
|
// We do not use `Path::file_stem` or `Path::extension` here,
|
|
// because some generated files may have multiple extensions e.g.
|
|
// `std-<hash>.dll.lib` on Windows. The aforementioned methods only
|
|
// split the file name by the last extension (`.lib`) while we need
|
|
// to split by all extensions (`.dll.lib`).
|
|
let expected_len = t!(filename.metadata()).len();
|
|
let filename = filename.file_name().unwrap().to_str().unwrap();
|
|
let mut parts = filename.splitn(2, '.');
|
|
let file_stem = parts.next().unwrap().to_owned();
|
|
let extension = parts.next().unwrap().to_owned();
|
|
|
|
toplevel.push((file_stem, extension, expected_len));
|
|
}
|
|
});
|
|
|
|
if !ok {
|
|
exit(1);
|
|
}
|
|
|
|
// Ok now we need to actually find all the files listed in `toplevel`. We've
|
|
// got a list of prefix/extensions and we basically just need to find the
|
|
// most recent file in the `deps` folder corresponding to each one.
|
|
let contents = t!(target_deps_dir.read_dir())
|
|
.map(|e| t!(e))
|
|
.map(|e| (e.path(), e.file_name().into_string().unwrap(), t!(e.metadata())))
|
|
.collect::<Vec<_>>();
|
|
for (prefix, extension, expected_len) in toplevel {
|
|
let candidates = contents.iter().filter(|&&(_, ref filename, ref meta)| {
|
|
filename.starts_with(&prefix[..]) &&
|
|
filename[prefix.len()..].starts_with("-") &&
|
|
filename.ends_with(&extension[..]) &&
|
|
meta.len() == expected_len
|
|
});
|
|
let max = candidates.max_by_key(|&&(_, _, ref metadata)| {
|
|
FileTime::from_last_modification_time(metadata)
|
|
});
|
|
let path_to_add = match max {
|
|
Some(triple) => triple.0.to_str().unwrap(),
|
|
None => panic!("no output generated for {:?} {:?}", prefix, extension),
|
|
};
|
|
if is_dylib(path_to_add) {
|
|
let candidate = format!("{}.lib", path_to_add);
|
|
let candidate = PathBuf::from(candidate);
|
|
if candidate.exists() {
|
|
deps.push((candidate, false));
|
|
}
|
|
}
|
|
deps.push((path_to_add.into(), false));
|
|
}
|
|
|
|
deps.extend(additional_target_deps.into_iter().map(|d| (d, false)));
|
|
deps.sort();
|
|
let mut new_contents = Vec::new();
|
|
for (dep, proc_macro) in deps.iter() {
|
|
new_contents.extend(if *proc_macro { b"h" } else { b"t" });
|
|
new_contents.extend(dep.to_str().unwrap().as_bytes());
|
|
new_contents.extend(b"\0");
|
|
}
|
|
t!(fs::write(&stamp, &new_contents));
|
|
deps.into_iter().map(|(d, _)| d).collect()
|
|
}
|
|
|
|
pub fn stream_cargo(
|
|
builder: &Builder<'_>,
|
|
cargo: Cargo,
|
|
tail_args: Vec<String>,
|
|
cb: &mut dyn FnMut(CargoMessage<'_>),
|
|
) -> bool {
|
|
let mut cargo = Command::from(cargo);
|
|
if builder.config.dry_run {
|
|
return true;
|
|
}
|
|
// Instruct Cargo to give us json messages on stdout, critically leaving
|
|
// stderr as piped so we can get those pretty colors.
|
|
let mut message_format = String::from("json-render-diagnostics");
|
|
if let Some(s) = &builder.config.rustc_error_format {
|
|
message_format.push_str(",json-diagnostic-");
|
|
message_format.push_str(s);
|
|
}
|
|
cargo.arg("--message-format").arg(message_format).stdout(Stdio::piped());
|
|
|
|
for arg in tail_args {
|
|
cargo.arg(arg);
|
|
}
|
|
|
|
builder.verbose(&format!("running: {:?}", cargo));
|
|
let mut child = match cargo.spawn() {
|
|
Ok(child) => child,
|
|
Err(e) => panic!("failed to execute command: {:?}\nerror: {}", cargo, e),
|
|
};
|
|
|
|
// Spawn Cargo slurping up its JSON output. We'll start building up the
|
|
// `deps` array of all files it generated along with a `toplevel` array of
|
|
// files we need to probe for later.
|
|
let stdout = BufReader::new(child.stdout.take().unwrap());
|
|
for line in stdout.lines() {
|
|
let line = t!(line);
|
|
match serde_json::from_str::<CargoMessage<'_>>(&line) {
|
|
Ok(msg) => cb(msg),
|
|
// If this was informational, just print it out and continue
|
|
Err(_) => println!("{}", line)
|
|
}
|
|
}
|
|
|
|
// Make sure Cargo actually succeeded after we read all of its stdout.
|
|
let status = t!(child.wait());
|
|
if !status.success() {
|
|
eprintln!("command did not execute successfully: {:?}\n\
|
|
expected success, got: {}",
|
|
cargo,
|
|
status);
|
|
}
|
|
status.success()
|
|
}
|
|
|
|
#[derive(Deserialize)]
|
|
pub struct CargoTarget<'a> {
|
|
crate_types: Vec<Cow<'a, str>>,
|
|
}
|
|
|
|
#[derive(Deserialize)]
|
|
#[serde(tag = "reason", rename_all = "kebab-case")]
|
|
pub enum CargoMessage<'a> {
|
|
CompilerArtifact {
|
|
package_id: Cow<'a, str>,
|
|
features: Vec<Cow<'a, str>>,
|
|
filenames: Vec<Cow<'a, str>>,
|
|
target: CargoTarget<'a>,
|
|
},
|
|
BuildScriptExecuted {
|
|
package_id: Cow<'a, str>,
|
|
},
|
|
}
|