mikros/rust
1
0
Fork 0
Code Issues Pull Requests Packages Projects Releases Wiki Activity
a2a0f21ba1
rust/src/bootstrap/lib.rs
Alex Crichton faebcc1087 rustbuild: Fail the build if we build Cargo twice 
This commit updates the `ToolBuild` step to stream Cargo's JSON messages, parse
them, and record all libraries built. If we build anything twice (aka Cargo)
it'll most likely happen due to dependencies being recompiled which is caught by
this check.
2018-03-26 13:07:12 -07:00

1003 lines
35 KiB
Rust
Raw Blame History

// 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 rustbuild, the Rust build system.
//!
//! This module, and its descendants, are the implementation of the Rust build
//! system. Most of this build system is backed by Cargo but the outer layer
//! here serves as the ability to orchestrate calling Cargo, sequencing Cargo
//! builds, building artifacts like LLVM, etc. The goals of rustbuild are:
//!
//! * To be an easily understandable, easily extensible, and maintainable build
//! system.
//! * Leverage standard tools in the Rust ecosystem to build the compiler, aka
//! crates.io and Cargo.
//! * A standard interface to build across all platforms, including MSVC
//!
//! ## Architecture
//!
//! The build system defers most of the complicated logic managing invocations
//! of rustc and rustdoc to Cargo itself. However, moving through various stages
//! and copying artifacts is still necessary for it to do. Each time rustbuild
//! is invoked, it will iterate through the list of predefined steps and execute
//! each serially in turn if it matches the paths passed or is a default rule.
//! For each step rustbuild relies on the step internally being incremental and
//! parallel. Note, though, that the `-j` parameter to rustbuild gets forwarded
//! to appropriate test harnesses and such.
//!
//! Most of the "meaty" steps that matter are backed by Cargo, which does indeed
//! have its own parallelism and incremental management. Later steps, like
//! tests, aren't incremental and simply run the entire suite currently.
//! However, compiletest itself tries to avoid running tests when the artifacts
//! that are involved (mainly the compiler) haven't changed.
//!
//! When you execute `x.py build`, the steps which are executed are:
//!
//! * First, the python script is run. This will automatically download the
//! stage0 rustc and cargo according to `src/stage0.txt`, or use the cached
//! versions if they're available. These are then used to compile rustbuild
//! itself (using Cargo). Finally, control is then transferred to rustbuild.
//!
//! * Rustbuild takes over, performs sanity checks, probes the environment,
//! reads configuration, and starts executing steps as it reads the command
//! line arguments (paths) or going through the default rules.
//!
//! The build output will be something like the following:
//!
//! Building stage0 std artifacts
//! Copying stage0 std
//! Building stage0 test artifacts
//! Copying stage0 test
//! Building stage0 compiler artifacts
//! Copying stage0 rustc
//! Assembling stage1 compiler
//! Building stage1 std artifacts
//! Copying stage1 std
//! Building stage1 test artifacts
//! Copying stage1 test
//! Building stage1 compiler artifacts
//! Copying stage1 rustc
//! Assembling stage2 compiler
//! Uplifting stage1 std
//! Uplifting stage1 test
//! Uplifting stage1 rustc
//!
//! Let's disect that a little:
//!
//! ## Building stage0 {std,test,compiler} artifacts
//!
//! These steps use the provided (downloaded, usually) compiler to compile the
//! local Rust source into libraries we can use.
//!
//! ## Copying stage0 {std,test,rustc}
//!
//! This copies the build output from Cargo into
//! `build/$HOST/stage0-sysroot/lib/rustlib/$ARCH/lib`. FIXME: This step's
//! documentation should be expanded -- the information already here may be
//! incorrect.
//!
//! ## Assembling stage1 compiler
//!
//! This copies the libraries we built in "building stage0 ... artifacts" into
//! the stage1 compiler's lib directory. These are the host libraries that the
//! compiler itself uses to run. These aren't actually used by artifacts the new
//! compiler generates. This step also copies the rustc and rustdoc binaries we
//! generated into build/$HOST/stage/bin.
//!
//! The stage1/bin/rustc is a fully functional compiler, but it doesn't yet have
//! any libraries to link built binaries or libraries to. The next 3 steps will
//! provide those libraries for it; they are mostly equivalent to constructing
//! the stage1/bin compiler so we don't go through them individually.
//!
//! ## Uplifting stage1 {std,test,rustc}
//!
//! This step copies the libraries from the stage1 compiler sysroot into the
//! stage2 compiler. This is done to avoid rebuilding the compiler; libraries
//! we'd build in this step should be identical (in function, if not necessarily
//! identical on disk) so there's no need to recompile the compiler again. Note
//! that if you want to, you can enable the full-bootstrap option to change this
//! behavior.
//!
//! Each step is driven by a separate Cargo project and rustbuild orchestrates
//! copying files between steps and otherwise preparing for Cargo to run.
//!
//! ## Further information
//!
//! More documentation can be found in each respective module below, and you can
//! also check out the `src/bootstrap/README.md` file for more information.
#![deny(warnings)]
#![feature(core_intrinsics)]
#![feature(slice_concat_ext)]
#[macro_use]
extern crate build_helper;
#[macro_use]
extern crate serde_derive;
#[macro_use]
extern crate lazy_static;
extern crate serde_json;
extern crate cmake;
extern crate filetime;
extern crate cc;
extern crate getopts;
extern crate num_cpus;
extern crate toml;
extern crate time;
#[cfg(unix)]
extern crate libc;
use std::cell::{RefCell, Cell};
use std::collections::{HashSet, HashMap};
use std::env;
use std::fs::{self, File};
use std::io::Read;
use std::path::{PathBuf, Path};
use std::process::{self, Command};
use std::slice;
use build_helper::{run_silent, run_suppressed, try_run_silent, try_run_suppressed, output, mtime};
use util::{exe, libdir, OutputFolder, CiEnv};
mod cc_detect;
mod channel;
mod check;
mod test;
mod clean;
mod compile;
mod metadata;
mod config;
mod dist;
mod doc;
mod flags;
mod install;
mod native;
mod sanity;
pub mod util;
mod builder;
mod cache;
mod tool;
mod toolstate;
#[cfg(windows)]
mod job;
#[cfg(unix)]
mod job {
use libc;
pub unsafe fn setup(build: &mut ::Build) {
if build.config.low_priority {
libc::setpriority(libc::PRIO_PGRP as _, 0, 10);
}
}
}
#[cfg(not(any(unix, windows)))]
mod job {
pub unsafe fn setup(_build: &mut ::Build) {
}
}
pub use config::Config;
use flags::Subcommand;
use cache::{Interned, INTERNER};
use toolstate::ToolState;
/// A structure representing a Rust compiler.
///
/// Each compiler has a `stage` that it is associated with and a `host` that
/// corresponds to the platform the compiler runs on. This structure is used as
/// a parameter to many methods below.
#[derive(Eq, PartialEq, Clone, Copy, Hash, Debug)]
pub struct Compiler {
stage: u32,
host: Interned<String>,
}
/// Global configuration for the build system.
///
/// This structure transitively contains all configuration for the build system.
/// All filesystem-encoded configuration is in `config`, all flags are in
/// `flags`, and then parsed or probed information is listed in the keys below.
///
/// This structure is a parameter of almost all methods in the build system,
/// although most functions are implemented as free functions rather than
/// methods specifically on this structure itself (to make it easier to
/// organize).
pub struct Build {
// User-specified configuration via config.toml
config: Config,
// Derived properties from the above two configurations
src: PathBuf,
out: PathBuf,
rust_info: channel::GitInfo,
cargo_info: channel::GitInfo,
rls_info: channel::GitInfo,
rustfmt_info: channel::GitInfo,
local_rebuild: bool,
fail_fast: bool,
doc_tests: bool,
verbosity: usize,
// Targets for which to build.
build: Interned<String>,
hosts: Vec<Interned<String>>,
targets: Vec<Interned<String>>,
// Stage 0 (downloaded) compiler and cargo or their local rust equivalents.
initial_rustc: PathBuf,
initial_cargo: PathBuf,
// Probed tools at runtime
lldb_version: Option<String>,
lldb_python_dir: Option<String>,
// Runtime state filled in later on
// C/C++ compilers and archiver for all targets
cc: HashMap<Interned<String>, cc::Tool>,
cxx: HashMap<Interned<String>, cc::Tool>,
ar: HashMap<Interned<String>, PathBuf>,
// Misc
crates: HashMap<Interned<String>, Crate>,
is_sudo: bool,
ci_env: CiEnv,
delayed_failures: RefCell<Vec<String>>,
prerelease_version: Cell<Option<u32>>,
tool_artifacts: RefCell<HashMap<
Interned<String>,
HashMap<String, (&'static str, PathBuf, Vec<String>)>
>>,
}
#[derive(Debug)]
struct Crate {
name: Interned<String>,
version: String,
deps: Vec<Interned<String>>,
path: PathBuf,
doc_step: String,
build_step: String,
test_step: String,
bench_step: String,
}
impl Crate {
fn is_local(&self, build: &Build) -> bool {
self.path.starts_with(&build.config.src) &&
!self.path.to_string_lossy().ends_with("_shim")
}
fn local_path(&self, build: &Build) -> PathBuf {
assert!(self.is_local(build));
self.path.strip_prefix(&build.config.src).unwrap().into()
}
}
/// The various "modes" of invoking Cargo.
///
/// These entries currently correspond to the various output directories of the
/// build system, with each mod generating output in a different directory.
#[derive(Debug, Hash, Clone, Copy, PartialEq, Eq)]
pub enum Mode {
/// Build the standard library, placing output in the "stageN-std" directory.
Libstd,
/// Build libtest, placing output in the "stageN-test" directory.
Libtest,
/// Build librustc and compiler libraries, placing output in the "stageN-rustc" directory.
Librustc,
/// Build some tool, placing output in the "stageN-tools" directory.
Tool,
}
impl Build {
/// Creates a new set of build configuration from the `flags` on the command
/// line and the filesystem `config`.
///
/// By default all build output will be placed in the current directory.
pub fn new(config: Config) -> Build {
let cwd = t!(env::current_dir());
let src = config.src.clone();
let out = cwd.join("build");
let is_sudo = match env::var_os("SUDO_USER") {
Some(sudo_user) => {
match env::var_os("USER") {
Some(user) => user != sudo_user,
None => false,
}
}
None => false,
};
let rust_info = channel::GitInfo::new(&config, &src);
let cargo_info = channel::GitInfo::new(&config, &src.join("src/tools/cargo"));
let rls_info = channel::GitInfo::new(&config, &src.join("src/tools/rls"));
let rustfmt_info = channel::GitInfo::new(&config, &src.join("src/tools/rustfmt"));
Build {
initial_rustc: config.initial_rustc.clone(),
initial_cargo: config.initial_cargo.clone(),
local_rebuild: config.local_rebuild,
fail_fast: config.cmd.fail_fast(),
doc_tests: config.cmd.doc_tests(),
verbosity: config.verbose,
build: config.build,
hosts: config.hosts.clone(),
targets: config.targets.clone(),
config,
src,
out,
rust_info,
cargo_info,
rls_info,
rustfmt_info,
cc: HashMap::new(),
cxx: HashMap::new(),
ar: HashMap::new(),
crates: HashMap::new(),
lldb_version: None,
lldb_python_dir: None,
is_sudo,
ci_env: CiEnv::current(),
delayed_failures: RefCell::new(Vec::new()),
prerelease_version: Cell::new(None),
tool_artifacts: Default::default(),
}
}
pub fn build_triple(&self) -> &[Interned<String>] {
unsafe {
slice::from_raw_parts(&self.build, 1)
}
}
/// Executes the entire build, as configured by the flags and configuration.
pub fn build(&mut self) {
unsafe {
job::setup(self);
}
if let Subcommand::Clean { all } = self.config.cmd {
return clean::clean(self, all);
}
self.verbose("finding compilers");
cc_detect::find(self);
self.verbose("running sanity check");
sanity::check(self);
// If local-rust is the same major.minor as the current version, then force a local-rebuild
let local_version_verbose = output(
Command::new(&self.initial_rustc).arg("--version").arg("--verbose"));
let local_release = local_version_verbose
.lines().filter(|x| x.starts_with("release:"))
.next().unwrap().trim_left_matches("release:").trim();
let my_version = channel::CFG_RELEASE_NUM;
if local_release.split('.').take(2).eq(my_version.split('.').take(2)) {
self.verbose(&format!("auto-detected local-rebuild {}", local_release));
self.local_rebuild = true;
}
self.verbose("learning about cargo");
metadata::build(self);
builder::Builder::run(&self);
// Check for postponed failures from `test --no-fail-fast`.
let failures = self.delayed_failures.borrow();
if failures.len() > 0 {
println!("\n{} command(s) did not execute successfully:\n", failures.len());
for failure in failures.iter() {
println!(" - {}\n", failure);
}
process::exit(1);
}
}
/// Clear out `dir` if `input` is newer.
///
/// After this executes, it will also ensure that `dir` exists.
fn clear_if_dirty(&self, dir: &Path, input: &Path) -> bool {
let stamp = dir.join(".stamp");
let mut cleared = false;
if mtime(&stamp) < mtime(input) {
self.verbose(&format!("Dirty - {}", dir.display()));
let _ = fs::remove_dir_all(dir);
cleared = true;
} else if stamp.exists() {
return cleared;
}
t!(fs::create_dir_all(dir));
t!(File::create(stamp));
cleared
}
/// Get the space-separated set of activated features for the standard
/// library.
fn std_features(&self) -> String {
let mut features = "panic-unwind".to_string();
if self.config.debug_jemalloc {
features.push_str(" debug-jemalloc");
}
if self.config.use_jemalloc {
features.push_str(" jemalloc");
}
if self.config.backtrace {
features.push_str(" backtrace");
}
if self.config.profiler {
features.push_str(" profiler");
}
if self.config.wasm_syscall {
features.push_str(" wasm_syscall");
}
features
}
/// Get the space-separated set of activated features for the compiler.
fn rustc_features(&self) -> String {
let mut features = String::new();
if self.config.use_jemalloc {
features.push_str(" jemalloc");
}
features
}
/// Component directory that Cargo will produce output into (e.g.
/// release/debug)
fn cargo_dir(&self) -> &'static str {
if self.config.rust_optimize {"release"} else {"debug"}
}
fn tools_dir(&self, compiler: Compiler) -> PathBuf {
let out = self.out.join(&*compiler.host).join(format!("stage{}-tools-bin", compiler.stage));
t!(fs::create_dir_all(&out));
out
}
/// Returns the root directory for all output generated in a particular
/// stage when running with a particular host compiler.
///
/// The mode indicates what the root directory is for.
fn stage_out(&self, compiler: Compiler, mode: Mode) -> PathBuf {
let suffix = match mode {
Mode::Libstd => "-std",
Mode::Libtest => "-test",
Mode::Tool => "-tools",
Mode::Librustc => "-rustc",
};
self.out.join(&*compiler.host)
.join(format!("stage{}{}", compiler.stage, suffix))
}
/// Returns the root output directory for all Cargo output in a given stage,
/// running a particular compiler, whether or not we're building the
/// standard library, and targeting the specified architecture.
fn cargo_out(&self,
compiler: Compiler,
mode: Mode,
target: Interned<String>) -> PathBuf {
self.stage_out(compiler, mode).join(&*target).join(self.cargo_dir())
}
/// Root output directory for LLVM compiled for `target`
///
/// Note that if LLVM is configured externally then the directory returned
/// will likely be empty.
fn llvm_out(&self, target: Interned<String>) -> PathBuf {
self.out.join(&*target).join("llvm")
}
fn emscripten_llvm_out(&self, target: Interned<String>) -> PathBuf {
self.out.join(&*target).join("llvm-emscripten")
}
fn lld_out(&self, target: Interned<String>) -> PathBuf {
self.out.join(&*target).join("lld")
}
/// Output directory for all documentation for a target
fn doc_out(&self, target: Interned<String>) -> PathBuf {
self.out.join(&*target).join("doc")
}
/// Output directory for all documentation for a target
fn compiler_doc_out(&self, target: Interned<String>) -> PathBuf {
self.out.join(&*target).join("compiler-doc")
}
/// Output directory for some generated md crate documentation for a target (temporary)
fn md_doc_out(&self, target: Interned<String>) -> Interned<PathBuf> {
INTERNER.intern_path(self.out.join(&*target).join("md-doc"))
}
/// Output directory for all crate documentation for a target (temporary)
///
/// The artifacts here are then copied into `doc_out` above.
fn crate_doc_out(&self, target: Interned<String>) -> PathBuf {
self.out.join(&*target).join("crate-docs")
}
/// Returns true if no custom `llvm-config` is set for the specified target.
///
/// If no custom `llvm-config` was specified then Rust's llvm will be used.
fn is_rust_llvm(&self, target: Interned<String>) -> bool {
match self.config.target_config.get(&target) {
Some(ref c) => c.llvm_config.is_none(),
None => true
}
}
/// Returns the path to `FileCheck` binary for the specified target
fn llvm_filecheck(&self, target: Interned<String>) -> PathBuf {
let target_config = self.config.target_config.get(&target);
if let Some(s) = target_config.and_then(|c| c.llvm_config.as_ref()) {
let llvm_bindir = output(Command::new(s).arg("--bindir"));
Path::new(llvm_bindir.trim()).join(exe("FileCheck", &*target))
} else {
let base = self.llvm_out(self.config.build).join("build");
let exe = exe("FileCheck", &*target);
if !self.config.ninja && self.config.build.contains("msvc") {
base.join("Release/bin").join(exe)
} else {
base.join("bin").join(exe)
}
}
}
/// Directory for libraries built from C/C++ code and shared between stages.
fn native_dir(&self, target: Interned<String>) -> PathBuf {
self.out.join(&*target).join("native")
}
/// Root output directory for rust_test_helpers library compiled for
/// `target`
fn test_helpers_out(&self, target: Interned<String>) -> PathBuf {
self.native_dir(target).join("rust-test-helpers")
}
/// Adds the `RUST_TEST_THREADS` env var if necessary
fn add_rust_test_threads(&self, cmd: &mut Command) {
if env::var_os("RUST_TEST_THREADS").is_none() {
cmd.env("RUST_TEST_THREADS", self.jobs().to_string());
}
}
/// Returns the libdir of the snapshot compiler.
fn rustc_snapshot_libdir(&self) -> PathBuf {
self.initial_rustc.parent().unwrap().parent().unwrap()
.join(libdir(&self.config.build))
}
/// Runs a command, printing out nice contextual information if it fails.
fn run(&self, cmd: &mut Command) {
self.verbose(&format!("running: {:?}", cmd));
run_silent(cmd)
}
/// Runs a command, printing out nice contextual information if it fails.
fn run_quiet(&self, cmd: &mut Command) {
self.verbose(&format!("running: {:?}", cmd));
run_suppressed(cmd)
}
/// Runs a command, printing out nice contextual information if it fails.
/// Exits if the command failed to execute at all, otherwise returns its
/// `status.success()`.
fn try_run(&self, cmd: &mut Command) -> bool {
self.verbose(&format!("running: {:?}", cmd));
try_run_silent(cmd)
}
/// Runs a command, printing out nice contextual information if it fails.
/// Exits if the command failed to execute at all, otherwise returns its
/// `status.success()`.
fn try_run_quiet(&self, cmd: &mut Command) -> bool {
self.verbose(&format!("running: {:?}", cmd));
try_run_suppressed(cmd)
}
pub fn is_verbose(&self) -> bool {
self.verbosity > 0
}
/// Prints a message if this build is configured in verbose mode.
fn verbose(&self, msg: &str) {
if self.is_verbose() {
println!("{}", msg);
}
}
/// Returns the number of parallel jobs that have been configured for this
/// build.
fn jobs(&self) -> u32 {
self.config.jobs.unwrap_or_else(|| num_cpus::get() as u32)
}
/// Returns the path to the C compiler for the target specified.
fn cc(&self, target: Interned<String>) -> &Path {
self.cc[&target].path()
}
/// Returns a list of flags to pass to the C compiler for the target
/// specified.
fn cflags(&self, target: Interned<String>) -> Vec<String> {
// Filter out -O and /O (the optimization flags) that we picked up from
// cc-rs because the build scripts will determine that for themselves.
let mut base = self.cc[&target].args().iter()
.map(|s| s.to_string_lossy().into_owned())
.filter(|s| !s.starts_with("-O") && !s.starts_with("/O"))
.collect::<Vec<_>>();
// If we're compiling on macOS then we add a few unconditional flags
// indicating that we want libc++ (more filled out than libstdc++) and
// we want to compile for 10.7. This way we can ensure that
// LLVM/jemalloc/etc are all properly compiled.
if target.contains("apple-darwin") {
base.push("-stdlib=libc++".into());
}
// Work around an apparently bad MinGW / GCC optimization,
// See: http://lists.llvm.org/pipermail/cfe-dev/2016-December/051980.html
// See: https://gcc.gnu.org/bugzilla/show_bug.cgi?id=78936
if &*target == "i686-pc-windows-gnu" {
base.push("-fno-omit-frame-pointer".into());
}
base
}
/// Returns the path to the `ar` archive utility for the target specified.
fn ar(&self, target: Interned<String>) -> Option<&Path> {
self.ar.get(&target).map(|p| &**p)
}
/// Returns the path to the C++ compiler for the target specified.
fn cxx(&self, target: Interned<String>) -> Result<&Path, String> {
match self.cxx.get(&target) {
Some(p) => Ok(p.path()),
None => Err(format!(
"target `{}` is not configured as a host, only as a target",
target))
}
}
/// Returns the path to the linker for the given target if it needs to be overridden.
fn linker(&self, target: Interned<String>) -> Option<&Path> {
if let Some(linker) = self.config.target_config.get(&target)
.and_then(|c| c.linker.as_ref()) {
Some(linker)
} else if target != self.config.build &&
!target.contains("msvc") &&
!target.contains("emscripten") &&
!target.contains("wasm32") {
Some(self.cc(target))
} else {
None
}
}
/// Returns if this target should statically link the C runtime, if specified
fn crt_static(&self, target: Interned<String>) -> Option<bool> {
if target.contains("pc-windows-msvc") {
Some(true)
} else {
self.config.target_config.get(&target)
.and_then(|t| t.crt_static)
}
}
/// Returns the "musl root" for this `target`, if defined
fn musl_root(&self, target: Interned<String>) -> Option<&Path> {
self.config.target_config.get(&target)
.and_then(|t| t.musl_root.as_ref())
.or(self.config.musl_root.as_ref())
.map(|p| &**p)
}
/// Returns whether the target will be tested using the `remote-test-client`
/// and `remote-test-server` binaries.
fn remote_tested(&self, target: Interned<String>) -> bool {
self.qemu_rootfs(target).is_some() || target.contains("android") ||
env::var_os("TEST_DEVICE_ADDR").is_some()
}
/// Returns the root of the "rootfs" image that this target will be using,
/// if one was configured.
///
/// If `Some` is returned then that means that tests for this target are
/// emulated with QEMU and binaries will need to be shipped to the emulator.
fn qemu_rootfs(&self, target: Interned<String>) -> Option<&Path> {
self.config.target_config.get(&target)
.and_then(|t| t.qemu_rootfs.as_ref())
.map(|p| &**p)
}
/// Path to the python interpreter to use
fn python(&self) -> &Path {
self.config.python.as_ref().unwrap()
}
/// Temporary directory that extended error information is emitted to.
fn extended_error_dir(&self) -> PathBuf {
self.out.join("tmp/extended-error-metadata")
}
/// Tests whether the `compiler` compiling for `target` should be forced to
/// use a stage1 compiler instead.
///
/// Currently, by default, the build system does not perform a "full
/// bootstrap" by default where we compile the compiler three times.
/// Instead, we compile the compiler two times. The final stage (stage2)
/// just copies the libraries from the previous stage, which is what this
/// method detects.
///
/// Here we return `true` if:
///
/// * The build isn't performing a full bootstrap
/// * The `compiler` is in the final stage, 2
/// * We're not cross-compiling, so the artifacts are already available in
/// stage1
///
/// When all of these conditions are met the build will lift artifacts from
/// the previous stage forward.
fn force_use_stage1(&self, compiler: Compiler, target: Interned<String>) -> bool {
!self.config.full_bootstrap &&
compiler.stage >= 2 &&
(self.hosts.iter().any(|h| *h == target) || target == self.build)
}
/// Returns the directory that OpenSSL artifacts are compiled into if
/// configured to do so.
fn openssl_dir(&self, target: Interned<String>) -> Option<PathBuf> {
// OpenSSL not used on Windows
if target.contains("windows") {
None
} else if self.config.openssl_static {
Some(self.out.join(&*target).join("openssl"))
} else {
None
}
}
/// Returns the directory that OpenSSL artifacts are installed into if
/// configured as such.
fn openssl_install_dir(&self, target: Interned<String>) -> Option<PathBuf> {
self.openssl_dir(target).map(|p| p.join("install"))
}
/// Given `num` in the form "a.b.c" return a "release string" which
/// describes the release version number.
///
/// For example on nightly this returns "a.b.c-nightly", on beta it returns
/// "a.b.c-beta.1" and on stable it just returns "a.b.c".
fn release(&self, num: &str) -> String {
match &self.config.channel[..] {
"stable" => num.to_string(),
"beta" => if self.rust_info.is_git() {
format!("{}-beta.{}", num, self.beta_prerelease_version())
} else {
format!("{}-beta", num)
},
"nightly" => format!("{}-nightly", num),
_ => format!("{}-dev", num),
}
}
fn beta_prerelease_version(&self) -> u32 {
if let Some(s) = self.prerelease_version.get() {
return s
}
let beta = output(
Command::new("git")
.arg("ls-remote")
.arg("origin")
.arg("beta")
.current_dir(&self.src)
);
let beta = beta.trim().split_whitespace().next().unwrap();
let master = output(
Command::new("git")
.arg("ls-remote")
.arg("origin")
.arg("master")
.current_dir(&self.src)
);
let master = master.trim().split_whitespace().next().unwrap();
// Figure out where the current beta branch started.
let base = output(
Command::new("git")
.arg("merge-base")
.arg(beta)
.arg(master)
.current_dir(&self.src),
);
let base = base.trim();
// Next figure out how many merge commits happened since we branched off
// beta. That's our beta number!
let count = output(
Command::new("git")
.arg("rev-list")
.arg("--count")
.arg("--merges")
.arg(format!("{}...HEAD", base))
.current_dir(&self.src),
);
let n = count.trim().parse().unwrap();
self.prerelease_version.set(Some(n));
n
}
/// Returns the value of `release` above for Rust itself.
fn rust_release(&self) -> String {
self.release(channel::CFG_RELEASE_NUM)
}
/// Returns the "package version" for a component given the `num` release
/// number.
///
/// The package version is typically what shows up in the names of tarballs.
/// For channels like beta/nightly it's just the channel name, otherwise
/// it's the `num` provided.
fn package_vers(&self, num: &str) -> String {
match &self.config.channel[..] {
"stable" => num.to_string(),
"beta" => "beta".to_string(),
"nightly" => "nightly".to_string(),
_ => format!("{}-dev", num),
}
}
/// Returns the value of `package_vers` above for Rust itself.
fn rust_package_vers(&self) -> String {
self.package_vers(channel::CFG_RELEASE_NUM)
}
/// Returns the value of `package_vers` above for Cargo
fn cargo_package_vers(&self) -> String {
self.package_vers(&self.release_num("cargo"))
}
/// Returns the value of `package_vers` above for rls
fn rls_package_vers(&self) -> String {
self.package_vers(&self.release_num("rls"))
}
/// Returns the value of `package_vers` above for rustfmt
fn rustfmt_package_vers(&self) -> String {
self.package_vers(&self.release_num("rustfmt"))
}
/// Returns the `version` string associated with this compiler for Rust
/// itself.
///
/// Note that this is a descriptive string which includes the commit date,
/// sha, version, etc.
fn rust_version(&self) -> String {
self.rust_info.version(self, channel::CFG_RELEASE_NUM)
}
/// Return the full commit hash
fn rust_sha(&self) -> Option<&str> {
self.rust_info.sha()
}
/// Returns the `a.b.c` version that the given package is at.
fn release_num(&self, package: &str) -> String {
let mut toml = String::new();
let toml_file_name = self.src.join(&format!("src/tools/{}/Cargo.toml", package));
t!(t!(File::open(toml_file_name)).read_to_string(&mut toml));
for line in toml.lines() {
let prefix = "version = \"";
let suffix = "\"";
if line.starts_with(prefix) && line.ends_with(suffix) {
return line[prefix.len()..line.len() - suffix.len()].to_string()
}
}
panic!("failed to find version in {}'s Cargo.toml", package)
}
/// Returns whether unstable features should be enabled for the compiler
/// we're building.
fn unstable_features(&self) -> bool {
match &self.config.channel[..] {
"stable" | "beta" => false,
"nightly" | _ => true,
}
}
/// Fold the output of the commands after this method into a group. The fold
/// ends when the returned object is dropped. Folding can only be used in
/// the Travis CI environment.
pub fn fold_output<D, F>(&self, name: F) -> Option<OutputFolder>
where D: Into<String>, F: FnOnce() -> D
{
if self.ci_env == CiEnv::Travis {
Some(OutputFolder::new(name().into()))
} else {
None
}
}
/// Updates the actual toolstate of a tool.
///
/// The toolstates are saved to the file specified by the key
/// `rust.save-toolstates` in `config.toml`. If unspecified, nothing will be
/// done. The file is updated immediately after this function completes.
pub fn save_toolstate(&self, tool: &str, state: ToolState) {
use std::io::{Seek, SeekFrom};
if let Some(ref path) = self.config.save_toolstates {
let mut file = t!(fs::OpenOptions::new()
.create(true)
.read(true)
.write(true)
.open(path));
let mut current_toolstates: HashMap<Box<str>, ToolState> =
serde_json::from_reader(&mut file).unwrap_or_default();
current_toolstates.insert(tool.into(), state);
t!(file.seek(SeekFrom::Start(0)));
t!(file.set_len(0));
t!(serde_json::to_writer(file, &current_toolstates));
}
}
fn in_tree_crates(&self, root: &str) -> Vec<&Crate> {
let mut ret = Vec::new();
let mut list = vec![INTERNER.intern_str(root)];
let mut visited = HashSet::new();
while let Some(krate) = list.pop() {
let krate = &self.crates[&krate];
if krate.is_local(self) {
ret.push(krate);
for dep in &krate.deps {
if visited.insert(dep) && dep != "build_helper" {
list.push(*dep);
}
}
}
}
ret
}
}
impl<'a> Compiler {
pub fn with_stage(mut self, stage: u32) -> Compiler {
self.stage = stage;
self
}
/// Returns whether this is a snapshot compiler for `build`'s configuration
pub fn is_snapshot(&self, build: &Build) -> bool {
self.stage == 0 && self.host == build.build
}
/// Returns if this compiler should be treated as a final stage one in the
/// current build session.
/// This takes into account whether we're performing a full bootstrap or
/// not; don't directly compare the stage with `2`!
pub fn is_final_stage(&self, build: &Build) -> bool {
let final_stage = if build.config.full_bootstrap { 2 } else { 1 };
self.stage >= final_stage
}
}
Reference in New Issue View Git Blame Copy Permalink