rust/src/bootstrap/compile.rs

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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::collections::HashMap;
use std::fs;
use std::path::{Path, PathBuf};
use std::process::Command;
use build_helper::output;
use util::{exe, staticlib, libdir, mtime, is_dylib, copy};
use {Build, Compiler, Mode};
/// 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.
pub fn std<'a>(build: &'a Build, target: &str, compiler: &Compiler<'a>) {
println!("Building stage{} std artifacts ({} -> {})", compiler.stage,
compiler.host, target);
// Move compiler-rt into place as it'll be required by the compiler when
// building the standard library to link the dylib of libstd
let libdir = build.sysroot_libdir(compiler, target);
let _ = fs::remove_dir_all(&libdir);
t!(fs::create_dir_all(&libdir));
copy(&build.compiler_rt_built.borrow()[target],
&libdir.join(staticlib("compiler-rt", target)));
// Some platforms have startup objects that may be required to produce the
// libstd dynamic library, for example.
build_startup_objects(build, target, &libdir);
let out_dir = build.cargo_out(compiler, Mode::Libstd, target);
build.clear_if_dirty(&out_dir, &build.compiler_path(compiler));
let mut cargo = build.cargo(compiler, Mode::Libstd, target, "build");
cargo.arg("--features").arg(build.std_features())
.arg("--manifest-path")
.arg(build.src.join("src/rustc/std_shim/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 let Some(ref p) = build.config.musl_root {
if target.contains("musl") {
cargo.env("MUSL_ROOT", p);
}
}
build.run(&mut cargo);
std_link(build, target, compiler, compiler.host);
}
/// Link all libstd rlibs/dylibs into the sysroot location.
///
/// Links those artifacts generated in the given `stage` for `target` produced
/// by `compiler` into `host`'s sysroot.
pub fn std_link(build: &Build,
target: &str,
compiler: &Compiler,
host: &str) {
let target_compiler = Compiler::new(compiler.stage, host);
let libdir = build.sysroot_libdir(&target_compiler, target);
let out_dir = build.cargo_out(compiler, Mode::Libstd, target);
// If we're linking one compiler host's output into another, then we weren't
// called from the `std` method above. In that case we clean out what's
// already there and then also link compiler-rt into place.
if host != compiler.host {
let _ = fs::remove_dir_all(&libdir);
t!(fs::create_dir_all(&libdir));
copy(&build.compiler_rt_built.borrow()[target],
&libdir.join(staticlib("compiler-rt", target)));
}
add_to_sysroot(&out_dir, &libdir);
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if target.contains("musl") && !target.contains("mips") {
copy_third_party_objects(build, &libdir);
}
}
/// Copies the crt(1,i,n).o startup objects
///
/// Only required for musl targets that statically link to libc
fn copy_third_party_objects(build: &Build, into: &Path) {
for &obj in &["crt1.o", "crti.o", "crtn.o"] {
copy(&build.config.musl_root.as_ref().unwrap().join("lib").join(obj), &into.join(obj));
}
}
/// 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 build_startup_objects(build: &Build, target: &str, into: &Path) {
if !target.contains("pc-windows-gnu") {
return
}
let compiler = Compiler::new(0, &build.config.build);
let compiler = build.compiler_path(&compiler);
for file in t!(fs::read_dir(build.src.join("src/rtstartup"))) {
let file = t!(file);
build.run(Command::new(&compiler)
.arg("--emit=obj")
.arg("--out-dir").arg(into)
.arg(file.path()));
}
for obj in ["crt2.o", "dllcrt2.o"].iter() {
copy(&compiler_file(build.cc(target), obj), &into.join(obj));
}
}
rustbuild: Fix dist for non-host targets The `rust-std` package that we produce is expected to have not only the standard library but also libtest for compiling unit tests. Unfortunately this does not currently happen due to the way rustbuild is structured. There are currently two main stages of compilation in rustbuild, one for the standard library and one for the compiler. This is primarily done to allow us to fill in the sysroot right after the standard library has finished compiling to continue compiling the rest of the crates. Consequently the entire compiler does not have to explicitly depend on the standard library, and this also should allow us to pull in crates.io dependencies into the build in the future because they'll just naturally build against the std we just produced. These phases, however, do not represent a cross-compiled build. Target-only builds also require libtest, and libtest is currently part of the all-encompassing "compiler build". There's unfortunately no way to learn about just libtest and its dependencies (in a great and robust fashion) so to ensure that we can copy the right artifacts over this commit introduces a new build step, libtest. The new libtest build step has documentation, dist, and link steps as std/rustc already do. The compiler now depends on libtest instead of libstd, and all compiler crates can now assume that test and its dependencies are implicitly part of the sysroot (hence explicit dependencies being removed). This makes the build a tad less parallel as in theory many rustc crates can be compiled in parallel with libtest, but this likely isn't where we really need parallelism either (all the time is still spent in the compiler). All in all this allows the `dist-std` step to depend on both libstd and libtest, so `rust-std` packages produced by rustbuild should start having both the standard library and libtest. Closes #32523
2016-03-28 00:28:10 -05:00
/// 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.
pub fn test<'a>(build: &'a Build, target: &str, compiler: &Compiler<'a>) {
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_shim(build, compiler, target));
let mut cargo = build.cargo(compiler, Mode::Libtest, target, "build");
cargo.arg("--manifest-path")
.arg(build.src.join("src/rustc/test_shim/Cargo.toml"));
build.run(&mut cargo);
test_link(build, target, compiler, compiler.host);
}
/// Link all libtest rlibs/dylibs into the sysroot location.
///
/// Links those artifacts generated in the given `stage` for `target` produced
/// by `compiler` into `host`'s sysroot.
pub fn test_link(build: &Build,
target: &str,
compiler: &Compiler,
host: &str) {
let target_compiler = Compiler::new(compiler.stage, host);
let libdir = build.sysroot_libdir(&target_compiler, target);
let out_dir = build.cargo_out(compiler, Mode::Libtest, target);
add_to_sysroot(&out_dir, &libdir);
}
/// 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.
pub fn rustc<'a>(build: &'a Build, target: &str, compiler: &Compiler<'a>) {
println!("Building stage{} compiler artifacts ({} -> {})",
compiler.stage, compiler.host, target);
let out_dir = build.cargo_out(compiler, Mode::Librustc, target);
rustbuild: Fix dist for non-host targets The `rust-std` package that we produce is expected to have not only the standard library but also libtest for compiling unit tests. Unfortunately this does not currently happen due to the way rustbuild is structured. There are currently two main stages of compilation in rustbuild, one for the standard library and one for the compiler. This is primarily done to allow us to fill in the sysroot right after the standard library has finished compiling to continue compiling the rest of the crates. Consequently the entire compiler does not have to explicitly depend on the standard library, and this also should allow us to pull in crates.io dependencies into the build in the future because they'll just naturally build against the std we just produced. These phases, however, do not represent a cross-compiled build. Target-only builds also require libtest, and libtest is currently part of the all-encompassing "compiler build". There's unfortunately no way to learn about just libtest and its dependencies (in a great and robust fashion) so to ensure that we can copy the right artifacts over this commit introduces a new build step, libtest. The new libtest build step has documentation, dist, and link steps as std/rustc already do. The compiler now depends on libtest instead of libstd, and all compiler crates can now assume that test and its dependencies are implicitly part of the sysroot (hence explicit dependencies being removed). This makes the build a tad less parallel as in theory many rustc crates can be compiled in parallel with libtest, but this likely isn't where we really need parallelism either (all the time is still spent in the compiler). All in all this allows the `dist-std` step to depend on both libstd and libtest, so `rust-std` packages produced by rustbuild should start having both the standard library and libtest. Closes #32523
2016-03-28 00:28:10 -05:00
build.clear_if_dirty(&out_dir, &libtest_shim(build, compiler, target));
let mut cargo = build.cargo(compiler, Mode::Librustc, target, "build");
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.release)
.env("CFG_RELEASE_CHANNEL", &build.config.channel)
.env("CFG_VERSION", &build.version)
.env("CFG_BOOTSTRAP_KEY", &build.bootstrap_key)
.env("CFG_PREFIX", build.config.prefix.clone().unwrap_or(String::new()))
.env("CFG_LIBDIR_RELATIVE", "lib");
if let Some(ref ver_date) = build.ver_date {
cargo.env("CFG_VER_DATE", ver_date);
}
if let Some(ref ver_hash) = build.ver_hash {
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));
if build.config.llvm_static_stdcpp {
cargo.env("LLVM_STATIC_STDCPP",
compiler_file(build.cxx(target), "libstdc++.a"));
}
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);
}
build.run(&mut cargo);
rustc_link(build, target, compiler, compiler.host);
}
/// Link all librustc rlibs/dylibs into the sysroot location.
///
/// Links those artifacts generated in the given `stage` for `target` produced
/// by `compiler` into `host`'s sysroot.
pub fn rustc_link(build: &Build,
target: &str,
compiler: &Compiler,
host: &str) {
let target_compiler = Compiler::new(compiler.stage, host);
let libdir = build.sysroot_libdir(&target_compiler, target);
let out_dir = build.cargo_out(compiler, Mode::Librustc, target);
add_to_sysroot(&out_dir, &libdir);
}
/// Cargo's output path for the standard library in a given stage, compiled
/// by a particular compiler for the specified target.
fn libstd_shim(build: &Build, compiler: &Compiler, target: &str) -> PathBuf {
build.cargo_out(compiler, Mode::Libstd, target).join("libstd_shim.rlib")
}
rustbuild: Fix dist for non-host targets The `rust-std` package that we produce is expected to have not only the standard library but also libtest for compiling unit tests. Unfortunately this does not currently happen due to the way rustbuild is structured. There are currently two main stages of compilation in rustbuild, one for the standard library and one for the compiler. This is primarily done to allow us to fill in the sysroot right after the standard library has finished compiling to continue compiling the rest of the crates. Consequently the entire compiler does not have to explicitly depend on the standard library, and this also should allow us to pull in crates.io dependencies into the build in the future because they'll just naturally build against the std we just produced. These phases, however, do not represent a cross-compiled build. Target-only builds also require libtest, and libtest is currently part of the all-encompassing "compiler build". There's unfortunately no way to learn about just libtest and its dependencies (in a great and robust fashion) so to ensure that we can copy the right artifacts over this commit introduces a new build step, libtest. The new libtest build step has documentation, dist, and link steps as std/rustc already do. The compiler now depends on libtest instead of libstd, and all compiler crates can now assume that test and its dependencies are implicitly part of the sysroot (hence explicit dependencies being removed). This makes the build a tad less parallel as in theory many rustc crates can be compiled in parallel with libtest, but this likely isn't where we really need parallelism either (all the time is still spent in the compiler). All in all this allows the `dist-std` step to depend on both libstd and libtest, so `rust-std` packages produced by rustbuild should start having both the standard library and libtest. Closes #32523
2016-03-28 00:28:10 -05:00
/// Cargo's output path for libtest in a given stage, compiled by a particular
/// compiler for the specified target.
fn libtest_shim(build: &Build, compiler: &Compiler, target: &str) -> PathBuf {
build.cargo_out(compiler, Mode::Libtest, target).join("libtest_shim.rlib")
}
fn compiler_file(compiler: &Path, file: &str) -> PathBuf {
let out = output(Command::new(compiler)
.arg(format!("-print-file-name={}", file)));
PathBuf::from(out.trim())
}
/// 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.config.build
/// compiler.
pub fn assemble_rustc(build: &Build, stage: u32, host: &str) {
assert!(stage > 0, "the stage0 compiler isn't assembled, it's downloaded");
// The compiler that we're assembling
let target_compiler = Compiler::new(stage, host);
// The compiler that compiled the compiler we're assembling
let build_compiler = Compiler::new(stage - 1, &build.config.build);
// Clear out old files
let sysroot = build.sysroot(&target_compiler);
let _ = fs::remove_dir_all(&sysroot);
t!(fs::create_dir_all(&sysroot));
// Link in all dylibs to the libdir
let sysroot_libdir = sysroot.join(libdir(host));
t!(fs::create_dir_all(&sysroot_libdir));
let src_libdir = build.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 = build.compiler_path(&Compiler::new(stage, host));
let _ = fs::remove_file(&compiler);
copy(&rustc, &compiler);
// See if rustdoc exists to link it into place
let rustdoc = exe("rustdoc", host);
let rustdoc_src = out_dir.join(&rustdoc);
let rustdoc_dst = bindir.join(&rustdoc);
if fs::metadata(&rustdoc_src).is_ok() {
let _ = fs::remove_file(&rustdoc_dst);
copy(&rustdoc_src, &rustdoc_dst);
}
}
/// Link some files into a rustc sysroot.
///
/// For a particular stage this will link all of the contents of `out_dir`
/// into the sysroot of the `host` compiler, assuming the artifacts are
/// compiled for the specified `target`.
fn add_to_sysroot(out_dir: &Path, sysroot_dst: &Path) {
// Collect the set of all files in the dependencies directory, keyed
// off the name of the library. We assume everything is of the form
// `foo-<hash>.{rlib,so,...}`, and there could be multiple different
// `<hash>` values for the same name (of old builds).
let mut map = HashMap::new();
for file in t!(fs::read_dir(out_dir.join("deps"))).map(|f| t!(f)) {
let filename = file.file_name().into_string().unwrap();
// We're only interested in linking rlibs + dylibs, other things like
// unit tests don't get linked in
if !filename.ends_with(".rlib") &&
!filename.ends_with(".lib") &&
!is_dylib(&filename) {
continue
}
let file = file.path();
let dash = filename.find("-").unwrap();
let key = (filename[..dash].to_string(),
file.extension().unwrap().to_owned());
map.entry(key).or_insert(Vec::new())
.push(file.clone());
}
// For all hash values found, pick the most recent one to move into the
// sysroot, that should be the one we just built.
for (_, paths) in map {
let (_, path) = paths.iter().map(|path| {
(mtime(&path).seconds(), path)
}).max().unwrap();
copy(&path, &sysroot_dst.join(path.file_name().unwrap()));
}
}
/// Build a tool in `src/tools`
///
/// This will build the specified tool with the specified `host` compiler in
/// `stage` into the normal cargo output directory.
pub fn tool(build: &Build, stage: u32, host: &str, tool: &str) {
println!("Building stage{} tool {} ({})", stage, tool, host);
let compiler = Compiler::new(stage, host);
// FIXME: need to clear out previous tool and ideally deps, may require
// isolating output directories or require a pseudo shim step to
// clear out all the info.
//
// Maybe when libstd is compiled it should clear out the rustc of the
// corresponding stage?
// let out_dir = build.cargo_out(stage, &host, Mode::Librustc, target);
// build.clear_if_dirty(&out_dir, &libstd_shim(build, stage, &host, target));
let mut cargo = build.cargo(&compiler, Mode::Tool, host, "build");
cargo.arg("--manifest-path")
.arg(build.src.join(format!("src/tools/{}/Cargo.toml", tool)));
build.run(&mut cargo);
}