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rust/src/bootstrap/compile.rs
Mark Simulacrum cec68167fd Clean tools after building libstd/libtest/librustc. 
This fixes the bug we previously had where we'd build a libtest tool
after building a libstd tool and clear out the libstd tool. Since we
clear out all tools for a given stage on invocations of CleanTools after
lib{std, test, rustc} change, we need to make sure that all tools built
with that stage will be built after the clearing is done.

The fix contained here technically isn't perfect; there is still an edge
case of compiling a libstd tool, then compiling libtest, which will
clear out the libstd tool and it won't ever get rebuilt within that
session of rustbuild. This is where the caching system used today shows
it's problems -- in effect, all tools depend on a global counter of the
stage being cleared out. We can implement such a counter in a future
patch to ensure that tools are rebuilt as needed, but it is deemed
unlikely that it will be required in practice, since most if not all
tools are built after the relevant stage's std/test/rustc are built,
though this is only an opinion and hasn't been verified.
2017-08-13 05:15:43 +05:00

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// Copyright 2015 The Rust Project Developers. See the COPYRIGHT
// file at the top-level directory of this distribution and at
// http://rust-lang.org/COPYRIGHT.
//
// Licensed under the Apache License, Version 2.0 <LICENSE-APACHE or
// http://www.apache.org/licenses/LICENSE-2.0> or the MIT license
// <LICENSE-MIT or http://opensource.org/licenses/MIT>, at your
// option. This file may not be copied, modified, or distributed
// except according to those terms.
//! Implementation of compiling various phases of the compiler and standard
//! library.
//!
//! This module contains some of the real meat in the rustbuild build system
//! which is where Cargo is used to compiler the standard library, libtest, and
//! compiler. This module is also responsible for assembling the sysroot as it
//! goes along from the output of the previous stage.
use std::env;
use std::fs::{self, File};
use std::io::BufReader;
use std::io::prelude::*;
use std::path::{Path, PathBuf};
use std::process::{Command, Stdio};
use std::str;
use std::cmp::min;
use build_helper::{output, mtime, up_to_date};
use filetime::FileTime;
use serde_json;
use util::{exe, libdir, is_dylib, copy};
use {Build, Compiler, Mode};
use native;
use tool;
use cache::{INTERNER, Interned};
use builder::{Step, RunConfig, ShouldRun, Builder};
#[derive(Debug, Copy, Clone, PartialEq, Eq, Hash)]
pub struct Std {
pub target: Interned<String>,
pub compiler: Compiler,
}
impl Step for Std {
type Output = ();
const DEFAULT: bool = true;
fn should_run(run: ShouldRun) -> ShouldRun {
run.path("src/libstd").krate("std")
}
fn make_run(run: RunConfig) {
run.builder.ensure(Std {
compiler: run.builder.compiler(run.builder.top_stage, run.host),
target: run.target,
});
}
/// Build the standard library.
///
/// This will build the standard library for a particular stage of the build
/// using the `compiler` targeting the `target` architecture. The artifacts
/// created will also be linked into the sysroot directory.
fn run(self, builder: &Builder) {
let build = builder.build;
let target = self.target;
let compiler = self.compiler;
builder.ensure(StartupObjects { compiler, target });
if build.force_use_stage1(compiler, target) {
let from = builder.compiler(1, build.build);
builder.ensure(Std {
compiler: from,
target: target,
});
println!("Uplifting stage1 std ({} -> {})", from.host, target);
builder.ensure(StdLink {
compiler: from,
target_compiler: compiler,
target: target,
});
return;
}
let _folder = build.fold_output(|| format!("stage{}-std", compiler.stage));
println!("Building stage{} std artifacts ({} -> {})", compiler.stage,
&compiler.host, target);
let out_dir = build.cargo_out(compiler, Mode::Libstd, target);
build.clear_if_dirty(&out_dir, &builder.rustc(compiler));
let mut cargo = builder.cargo(compiler, Mode::Libstd, target, "build");
std_cargo(build, &compiler, target, &mut cargo);
run_cargo(build,
&mut cargo,
&libstd_stamp(build, compiler, target));
builder.ensure(StdLink {
compiler: builder.compiler(compiler.stage, build.build),
target_compiler: compiler,
target: target,
});
}
}
/// Configure cargo to compile the standard library, adding appropriate env vars
/// and such.
pub fn std_cargo(build: &Build,
compiler: &Compiler,
target: Interned<String>,
cargo: &mut Command) {
let mut features = build.std_features();
if let Some(target) = env::var_os("MACOSX_STD_DEPLOYMENT_TARGET") {
cargo.env("MACOSX_DEPLOYMENT_TARGET", target);
}
// When doing a local rebuild we tell cargo that we're stage1 rather than
// stage0. This works fine if the local rust and being-built rust have the
// same view of what the default allocator is, but fails otherwise. Since
// we don't have a way to express an allocator preference yet, work
// around the issue in the case of a local rebuild with jemalloc disabled.
if compiler.stage == 0 && build.local_rebuild && !build.config.use_jemalloc {
features.push_str(" force_alloc_system");
}
if compiler.stage != 0 && build.config.sanitizers {
// This variable is used by the sanitizer runtime crates, e.g.
// rustc_lsan, to build the sanitizer runtime from C code
// When this variable is missing, those crates won't compile the C code,
// so we don't set this variable during stage0 where llvm-config is
// missing
// We also only build the runtimes when --enable-sanitizers (or its
// config.toml equivalent) is used
cargo.env("LLVM_CONFIG", build.llvm_config(target));
}
cargo.arg("--features").arg(features)
.arg("--manifest-path")
.arg(build.src.join("src/libstd/Cargo.toml"));
if let Some(target) = build.config.target_config.get(&target) {
if let Some(ref jemalloc) = target.jemalloc {
cargo.env("JEMALLOC_OVERRIDE", jemalloc);
}
}
if target.contains("musl") {
if let Some(p) = build.musl_root(target) {
cargo.env("MUSL_ROOT", p);
}
}
}
#[derive(Debug, Copy, Clone, PartialEq, Eq, Hash)]
struct StdLink {
pub compiler: Compiler,
pub target_compiler: Compiler,
pub target: Interned<String>,
}
impl Step for StdLink {
type Output = ();
fn should_run(run: ShouldRun) -> ShouldRun {
run.never()
}
/// Link all libstd rlibs/dylibs into the sysroot location.
///
/// Links those artifacts generated by `compiler` to a the `stage` compiler's
/// sysroot for the specified `host` and `target`.
///
/// Note that this assumes that `compiler` has already generated the libstd
/// libraries for `target`, and this method will find them in the relevant
/// output directory.
fn run(self, builder: &Builder) {
let build = builder.build;
let compiler = self.compiler;
let target_compiler = self.target_compiler;
let target = self.target;
println!("Copying stage{} std from stage{} ({} -> {} / {})",
target_compiler.stage,
compiler.stage,
&compiler.host,
target_compiler.host,
target);
let libdir = builder.sysroot_libdir(target_compiler, target);
add_to_sysroot(&libdir, &libstd_stamp(build, compiler, target));
if target.contains("musl") && !target.contains("mips") {
copy_musl_third_party_objects(build, target, &libdir);
}
if build.config.sanitizers && compiler.stage != 0 && target == "x86_64-apple-darwin" {
// The sanitizers are only built in stage1 or above, so the dylibs will
// be missing in stage0 and causes panic. See the `std()` function above
// for reason why the sanitizers are not built in stage0.
copy_apple_sanitizer_dylibs(&build.native_dir(target), "osx", &libdir);
}
builder.ensure(tool::CleanTools {
compiler: target_compiler,
target: target,
mode: Mode::Libstd,
});
}
}
/// Copies the crt(1,i,n).o startup objects
///
/// Only required for musl targets that statically link to libc
fn copy_musl_third_party_objects(build: &Build, target: Interned<String>, into: &Path) {
for &obj in &["crt1.o", "crti.o", "crtn.o"] {
copy(&build.musl_root(target).unwrap().join("lib").join(obj), &into.join(obj));
}
}
fn copy_apple_sanitizer_dylibs(native_dir: &Path, platform: &str, into: &Path) {
for &sanitizer in &["asan", "tsan"] {
let filename = format!("libclang_rt.{}_{}_dynamic.dylib", sanitizer, platform);
let mut src_path = native_dir.join(sanitizer);
src_path.push("build");
src_path.push("lib");
src_path.push("darwin");
src_path.push(&filename);
copy(&src_path, &into.join(filename));
}
}
#[derive(Debug, Copy, Clone, PartialEq, Eq, Hash)]
pub struct StartupObjects {
pub compiler: Compiler,
pub target: Interned<String>,
}
impl Step for StartupObjects {
type Output = ();
fn should_run(run: ShouldRun) -> ShouldRun {
run.path("src/rtstartup")
}
fn make_run(run: RunConfig) {
run.builder.ensure(StartupObjects {
compiler: run.builder.compiler(run.builder.top_stage, run.host),
target: run.target,
});
}
/// Build and prepare startup objects like rsbegin.o and rsend.o
///
/// These are primarily used on Windows right now for linking executables/dlls.
/// They don't require any library support as they're just plain old object
/// files, so we just use the nightly snapshot compiler to always build them (as
/// no other compilers are guaranteed to be available).
fn run(self, builder: &Builder) {
let build = builder.build;
let for_compiler = self.compiler;
let target = self.target;
if !target.contains("pc-windows-gnu") {
return
}
let src_dir = &build.src.join("src/rtstartup");
let dst_dir = &build.native_dir(target).join("rtstartup");
let sysroot_dir = &builder.sysroot_libdir(for_compiler, target);
t!(fs::create_dir_all(dst_dir));
for file in &["rsbegin", "rsend"] {
let src_file = &src_dir.join(file.to_string() + ".rs");
let dst_file = &dst_dir.join(file.to_string() + ".o");
if !up_to_date(src_file, dst_file) {
let mut cmd = Command::new(&build.initial_rustc);
build.run(cmd.env("RUSTC_BOOTSTRAP", "1")
.arg("--cfg").arg("stage0")
.arg("--target").arg(target)
.arg("--emit=obj")
.arg("-o").arg(dst_file)
.arg(src_file));
}
copy(dst_file, &sysroot_dir.join(file.to_string() + ".o"));
}
for obj in ["crt2.o", "dllcrt2.o"].iter() {
copy(&compiler_file(build.cc(target), obj), &sysroot_dir.join(obj));
}
}
}
#[derive(Debug, Copy, Clone, PartialEq, Eq, Hash)]
pub struct Test {
pub compiler: Compiler,
pub target: Interned<String>,
}
impl Step for Test {
type Output = ();
const DEFAULT: bool = true;
fn should_run(run: ShouldRun) -> ShouldRun {
run.path("src/libtest").krate("test")
}
fn make_run(run: RunConfig) {
run.builder.ensure(Test {
compiler: run.builder.compiler(run.builder.top_stage, run.host),
target: run.target,
});
}
/// Build libtest.
///
/// This will build libtest and supporting libraries for a particular stage of
/// the build using the `compiler` targeting the `target` architecture. The
/// artifacts created will also be linked into the sysroot directory.
fn run(self, builder: &Builder) {
let build = builder.build;
let target = self.target;
let compiler = self.compiler;
builder.ensure(Std { compiler, target });
if build.force_use_stage1(compiler, target) {
builder.ensure(Test {
compiler: builder.compiler(1, build.build),
target: target,
});
println!("Uplifting stage1 test ({} -> {})", &build.build, target);
builder.ensure(TestLink {
compiler: builder.compiler(1, build.build),
target_compiler: compiler,
target: target,
});
return;
}
let _folder = build.fold_output(|| format!("stage{}-test", compiler.stage));
println!("Building stage{} test artifacts ({} -> {})", compiler.stage,
&compiler.host, target);
let out_dir = build.cargo_out(compiler, Mode::Libtest, target);
build.clear_if_dirty(&out_dir, &libstd_stamp(build, compiler, target));
let mut cargo = builder.cargo(compiler, Mode::Libtest, target, "build");
test_cargo(build, &compiler, target, &mut cargo);
run_cargo(build,
&mut cargo,
&libtest_stamp(build, compiler, target));
builder.ensure(TestLink {
compiler: builder.compiler(compiler.stage, build.build),
target_compiler: compiler,
target: target,
});
}
}
/// Same as `std_cargo`, but for libtest
pub fn test_cargo(build: &Build,
_compiler: &Compiler,
_target: Interned<String>,
cargo: &mut Command) {
if let Some(target) = env::var_os("MACOSX_STD_DEPLOYMENT_TARGET") {
cargo.env("MACOSX_DEPLOYMENT_TARGET", target);
}
cargo.arg("--manifest-path")
.arg(build.src.join("src/libtest/Cargo.toml"));
}
#[derive(Debug, Copy, Clone, PartialEq, Eq, Hash)]
pub struct TestLink {
pub compiler: Compiler,
pub target_compiler: Compiler,
pub target: Interned<String>,
}
impl Step for TestLink {
type Output = ();
fn should_run(run: ShouldRun) -> ShouldRun {
run.never()
}
/// Same as `std_link`, only for libtest
fn run(self, builder: &Builder) {
let build = builder.build;
let compiler = self.compiler;
let target_compiler = self.target_compiler;
let target = self.target;
println!("Copying stage{} test from stage{} ({} -> {} / {})",
target_compiler.stage,
compiler.stage,
&compiler.host,
target_compiler.host,
target);
add_to_sysroot(&builder.sysroot_libdir(target_compiler, target),
&libtest_stamp(build, compiler, target));
builder.ensure(tool::CleanTools {
compiler: target_compiler,
target: target,
mode: Mode::Libtest,
});
}
}
#[derive(Debug, Copy, Clone, PartialEq, Eq, Hash)]
pub struct Rustc {
pub compiler: Compiler,
pub target: Interned<String>,
}
impl Step for Rustc {
type Output = ();
const ONLY_HOSTS: bool = true;
const DEFAULT: bool = true;
fn should_run(run: ShouldRun) -> ShouldRun {
run.path("src/librustc").krate("rustc-main")
}
fn make_run(run: RunConfig) {
run.builder.ensure(Rustc {
compiler: run.builder.compiler(run.builder.top_stage, run.host),
target: run.target,
});
}
/// Build the compiler.
///
/// This will build the compiler for a particular stage of the build using
/// the `compiler` targeting the `target` architecture. The artifacts
/// created will also be linked into the sysroot directory.
fn run(self, builder: &Builder) {
let build = builder.build;
let compiler = self.compiler;
let target = self.target;
builder.ensure(Test { compiler, target });
// Build LLVM for our target. This will implicitly build the host LLVM
// if necessary.
builder.ensure(native::Llvm { target });
if build.force_use_stage1(compiler, target) {
builder.ensure(Rustc {
compiler: builder.compiler(1, build.build),
target: target,
});
println!("Uplifting stage1 rustc ({} -> {})", &build.build, target);
builder.ensure(RustcLink {
compiler: builder.compiler(1, build.build),
target_compiler: compiler,
target,
});
return;
}
// Ensure that build scripts have a std to link against.
builder.ensure(Std {
compiler: builder.compiler(self.compiler.stage, build.build),
target: build.build,
});
let _folder = build.fold_output(|| format!("stage{}-rustc", compiler.stage));
println!("Building stage{} compiler artifacts ({} -> {})",
compiler.stage, &compiler.host, target);
let out_dir = build.cargo_out(compiler, Mode::Librustc, target);
build.clear_if_dirty(&out_dir, &libtest_stamp(build, compiler, target));
let mut cargo = builder.cargo(compiler, Mode::Librustc, target, "build");
rustc_cargo(build, &compiler, target, &mut cargo);
run_cargo(build,
&mut cargo,
&librustc_stamp(build, compiler, target));
builder.ensure(RustcLink {
compiler: builder.compiler(compiler.stage, build.build),
target_compiler: compiler,
target,
});
}
}
/// Same as `std_cargo`, but for libtest
pub fn rustc_cargo(build: &Build,
compiler: &Compiler,
target: Interned<String>,
cargo: &mut Command) {
cargo.arg("--features").arg(build.rustc_features())
.arg("--manifest-path")
.arg(build.src.join("src/rustc/Cargo.toml"));
// Set some configuration variables picked up by build scripts and
// the compiler alike
cargo.env("CFG_RELEASE", build.rust_release())
.env("CFG_RELEASE_CHANNEL", &build.config.channel)
.env("CFG_VERSION", build.rust_version())
.env("CFG_PREFIX", build.config.prefix.clone().unwrap_or_default());
if compiler.stage == 0 {
cargo.env("CFG_LIBDIR_RELATIVE", "lib");
} else {
let libdir_relative =
build.config.libdir_relative.clone().unwrap_or(PathBuf::from("lib"));
cargo.env("CFG_LIBDIR_RELATIVE", libdir_relative);
}
// If we're not building a compiler with debugging information then remove
// these two env vars which would be set otherwise.
if build.config.rust_debuginfo_only_std {
cargo.env_remove("RUSTC_DEBUGINFO");
cargo.env_remove("RUSTC_DEBUGINFO_LINES");
}
if let Some(ref ver_date) = build.rust_info.commit_date() {
cargo.env("CFG_VER_DATE", ver_date);
}
if let Some(ref ver_hash) = build.rust_info.sha() {
cargo.env("CFG_VER_HASH", ver_hash);
}
if !build.unstable_features() {
cargo.env("CFG_DISABLE_UNSTABLE_FEATURES", "1");
}
// Flag that rust llvm is in use
if build.is_rust_llvm(target) {
cargo.env("LLVM_RUSTLLVM", "1");
}
cargo.env("LLVM_CONFIG", build.llvm_config(target));
let target_config = build.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);
}
// Building with a static libstdc++ is only supported on linux right now,
// not for MSVC or macOS
if build.config.llvm_static_stdcpp &&
!target.contains("windows") &&
!target.contains("apple") {
cargo.env("LLVM_STATIC_STDCPP",
compiler_file(build.cxx(target).unwrap(), "libstdc++.a"));
}
if build.config.llvm_link_shared {
cargo.env("LLVM_LINK_SHARED", "1");
}
if let Some(ref s) = build.config.rustc_default_linker {
cargo.env("CFG_DEFAULT_LINKER", s);
}
if let Some(ref s) = build.config.rustc_default_ar {
cargo.env("CFG_DEFAULT_AR", s);
}
}
#[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 build = builder.build;
let compiler = self.compiler;
let target_compiler = self.target_compiler;
let target = self.target;
println!("Copying stage{} rustc from stage{} ({} -> {} / {})",
target_compiler.stage,
compiler.stage,
&compiler.host,
target_compiler.host,
target);
add_to_sysroot(&builder.sysroot_libdir(target_compiler, target),
&librustc_stamp(build, compiler, target));
builder.ensure(tool::CleanTools {
compiler: target_compiler,
target: target,
mode: Mode::Librustc,
});
}
}
/// 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(build: &Build, compiler: Compiler, target: Interned<String>) -> PathBuf {
build.cargo_out(compiler, Mode::Libstd, target).join(".libstd.stamp")
}
/// Cargo's output path for libtest in a given stage, compiled by a particular
/// compiler for the specified target.
pub fn libtest_stamp(build: &Build, compiler: Compiler, target: Interned<String>) -> PathBuf {
build.cargo_out(compiler, Mode::Libtest, target).join(".libtest.stamp")
}
/// Cargo's output path for librustc in a given stage, compiled by a particular
/// compiler for the specified target.
pub fn librustc_stamp(build: &Build, compiler: Compiler, target: Interned<String>) -> PathBuf {
build.cargo_out(compiler, Mode::Librustc, target).join(".librustc.stamp")
}
fn compiler_file(compiler: &Path, file: &str) -> PathBuf {
let out = output(Command::new(compiler)
.arg(format!("-print-file-name={}", file)));
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 build = builder.build;
let compiler = self.compiler;
let sysroot = if compiler.stage == 0 {
build.out.join(&compiler.host).join("stage0-sysroot")
} else {
build.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, 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.path("src/rustc")
}
/// 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` build.build
/// compiler.
fn run(self, builder: &Builder) -> Compiler {
let build = builder.build;
let target_compiler = self.target_compiler;
if target_compiler.stage == 0 {
assert_eq!(build.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.
let build_compiler = if target_compiler.host != build.build {
// Build a compiler for the host platform. We cannot use the stage0
// compiler for the host platform for this because it doesn't have
// the libraries we need. 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.
builder.compiler(target_compiler.stage - 1, build.build)
} else {
// Build the compiler we'll use to build the stage requested. This
// may build more than one compiler (going down to stage 0).
builder.compiler(target_compiler.stage - 1, target_compiler.host)
};
// 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).
if builder.build.config.keep_stage.map_or(false, |s| target_compiler.stage <= s) {
builder.verbose("skipping compilation of compiler due to --keep-stage");
let compiler = build_compiler;
for stage in 0..min(target_compiler.stage, builder.config.keep_stage.unwrap()) {
let target_compiler = builder.compiler(stage, target_compiler.host);
let target = target_compiler.host;
builder.ensure(StdLink { compiler, target_compiler, target });
builder.ensure(TestLink { compiler, target_compiler, target });
builder.ensure(RustcLink { compiler, target_compiler, target });
}
} else {
builder.ensure(Rustc { compiler: build_compiler, target: target_compiler.host });
}
let stage = target_compiler.stage;
let host = target_compiler.host;
println!("Assembling stage{} compiler ({})", stage, host);
// Link in all dylibs to the libdir
let sysroot = builder.sysroot(target_compiler);
let sysroot_libdir = sysroot.join(libdir(&*host));
t!(fs::create_dir_all(&sysroot_libdir));
let src_libdir = builder.sysroot_libdir(build_compiler, host);
for f in t!(fs::read_dir(&src_libdir)).map(|f| t!(f)) {
let filename = f.file_name().into_string().unwrap();
if is_dylib(&filename) {
copy(&f.path(), &sysroot_libdir.join(&filename));
}
}
let out_dir = build.cargo_out(build_compiler, Mode::Librustc, host);
// Link the compiler binary itself into place
let rustc = out_dir.join(exe("rustc", &*host));
let bindir = sysroot.join("bin");
t!(fs::create_dir_all(&bindir));
let compiler = builder.rustc(target_compiler);
let _ = fs::remove_file(&compiler);
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.
fn add_to_sysroot(sysroot_dst: &Path, stamp: &Path) {
t!(fs::create_dir_all(&sysroot_dst));
let mut contents = Vec::new();
t!(t!(File::open(stamp)).read_to_end(&mut contents));
// This is the method we use for extracting paths from the stamp file passed to us. See
// run_cargo for more information (in this file).
for part in contents.split(|b| *b == 0) {
if part.is_empty() {
continue
}
let path = Path::new(t!(str::from_utf8(part)));
copy(&path, &sysroot_dst.join(path.file_name().unwrap()));
}
}
// Avoiding a dependency on winapi to keep compile times down
#[cfg(unix)]
fn stderr_isatty() -> bool {
use libc;
unsafe { libc::isatty(libc::STDERR_FILENO) != 0 }
}
#[cfg(windows)]
fn stderr_isatty() -> bool {
type DWORD = u32;
type BOOL = i32;
type HANDLE = *mut u8;
const STD_ERROR_HANDLE: DWORD = -12i32 as DWORD;
extern "system" {
fn GetStdHandle(which: DWORD) -> HANDLE;
fn GetConsoleMode(hConsoleHandle: HANDLE, lpMode: *mut DWORD) -> BOOL;
}
unsafe {
let handle = GetStdHandle(STD_ERROR_HANDLE);
let mut out = 0;
GetConsoleMode(handle, &mut out) != 0
}
}
fn run_cargo(build: &Build, cargo: &mut Command, stamp: &Path) {
// Instruct Cargo to give us json messages on stdout, critically leaving
// stderr as piped so we can get those pretty colors.
cargo.arg("--message-format").arg("json")
.stdout(Stdio::piped());
if stderr_isatty() {
// since we pass message-format=json to cargo, we need to tell the rustc
// wrapper to give us colored output if necessary. This is because we
// only want Cargo's JSON output, not rustcs.
cargo.env("RUSTC_COLOR", "1");
}
build.verbose(&format!("running: {:?}", cargo));
let mut child = match cargo.spawn() {
Ok(child) => child,
Err(e) => panic!("failed to execute command: {:?}\nerror: {}", cargo, e),
};
// `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 stdout = BufReader::new(child.stdout.take().unwrap());
for line in stdout.lines() {
let line = t!(line);
let json: serde_json::Value = if line.starts_with("{") {
t!(serde_json::from_str(&line))
} else {
// If this was informational, just print it out and continue
println!("{}", line);
continue
};
if json["reason"].as_str() != Some("compiler-artifact") {
continue
}
for filename in json["filenames"].as_array().unwrap() {
let filename = filename.as_str().unwrap();
// Skip files like executables
if !filename.ends_with(".rlib") &&
!filename.ends_with(".lib") &&
!is_dylib(&filename) {
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) {
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());
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.
toplevel.push((filename.file_stem().unwrap()
.to_str().unwrap().to_string(),
filename.extension().unwrap().to_owned()
.to_str().unwrap().to_string()));
}
}
// Make sure Cargo actually succeeded after we read all of its stdout.
let status = t!(child.wait());
if !status.success() {
panic!("command did not execute successfully: {:?}\n\
expected success, got: {}",
cargo,
status);
}
// 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) in toplevel {
let candidates = contents.iter().filter(|&&(_, ref filename, _)| {
filename.starts_with(&prefix[..]) &&
filename[prefix.len()..].starts_with("-") &&
filename.ends_with(&extension[..])
});
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);
}
}
deps.push(path_to_add.into());
}
// Now we want to update the contents of the stamp file, if necessary. First
// we read off the previous contents along with its mtime. If our new
// contents (the list of files to copy) is different or if any dep's mtime
// is newer then we rewrite the stamp file.
deps.sort();
let mut stamp_contents = Vec::new();
if let Ok(mut f) = File::open(stamp) {
t!(f.read_to_end(&mut stamp_contents));
}
let stamp_mtime = mtime(&stamp);
let mut new_contents = Vec::new();
let mut max = None;
let mut max_path = None;
for dep in deps {
let mtime = mtime(&dep);
if Some(mtime) > max {
max = Some(mtime);
max_path = Some(dep.clone());
}
new_contents.extend(dep.to_str().unwrap().as_bytes());
new_contents.extend(b"\0");
}
let max = max.unwrap();
let max_path = max_path.unwrap();
if stamp_contents == new_contents && max <= stamp_mtime {
return
}
if max > stamp_mtime {
build.verbose(&format!("updating {:?} as {:?} changed", stamp, max_path));
} else {
build.verbose(&format!("updating {:?} as deps changed", stamp));
}
t!(t!(File::create(stamp)).write_all(&new_contents));
}
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