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fuchsia / third_party / rust / 9f7b58f3c94708f344237f826b4f96a659b5fc82 / . / src / bootstrap / lib.rs
blob: 1fee3fd9ac1d26038726a25287061fd75e7ade5e [file] [log] [blame]
//! 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 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.
#![feature(core_intrinsics)]
#![feature(drain_filter)]
use std::cell::{Cell, RefCell};
use std::collections::{HashMap, HashSet};
use std::env;
use std::fs::{self, File, OpenOptions};
use std::io::{Read, Seek, SeekFrom, Write};
use std::path::{Path, PathBuf};
use std::process::{self, Command};
use std::slice;
use std::str;
#[cfg(unix)]
use std::os::unix::fs::symlink as symlink_file;
#[cfg(windows)]
use std::os::windows::fs::symlink_file;
use build_helper::{mtime, output, run, run_suppressed, t, try_run, try_run_suppressed};
use filetime::FileTime;
use crate::util::{exe, libdir, CiEnv};
mod builder;
mod cache;
mod cc_detect;
mod channel;
mod check;
mod clean;
mod compile;
mod config;
mod dist;
mod doc;
mod flags;
mod format;
mod install;
mod metadata;
mod native;
mod sanity;
mod test;
mod tool;
mod toolstate;
pub mod util;
#[cfg(windows)]
mod job;
#[cfg(all(unix, not(target_os = "haiku")))]
mod job {
pub unsafe fn setup(build: &mut crate::Build) {
if build.config.low_priority {
libc::setpriority(libc::PRIO_PGRP as _, 0, 10);
}
}
}
#[cfg(any(target_os = "haiku", target_os = "hermit", not(any(unix, windows))))]
mod job {
pub unsafe fn setup(_build: &mut crate::Build) {}
}
use crate::cache::{Interned, INTERNER};
pub use crate::config::Config;
use crate::flags::Subcommand;
const LLVM_TOOLS: &[&str] = &[
"llvm-nm", // used to inspect binaries; it shows symbol names, their sizes and visibility
"llvm-objcopy", // used to transform ELFs into binary format which flashing tools consume
"llvm-objdump", // used to disassemble programs
"llvm-profdata", // used to inspect and merge files generated by profiles
"llvm-readobj", // used to get information from ELFs/objects that the other tools don't provide
"llvm-size", // used to prints the size of the linker sections of a program
"llvm-strip", // used to discard symbols from binary files to reduce their size
"llvm-ar", // used for creating and modifying archive files
];
/// 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, PartialOrd, Ord, PartialEq, Clone, Copy, Hash, Debug)]
pub struct Compiler {
stage: u32,
host: Interned<String>,
}
#[derive(PartialEq, Eq, Copy, Clone, Debug)]
pub enum DocTests {
/// Run normal tests and doc tests (default).
Yes,
/// Do not run any doc tests.
No,
/// Only run doc tests.
Only,
}
pub enum GitRepo {
Rustc,
Llvm,
}
/// 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 from `config.toml`.
config: Config,
// Properties derived from the above configuration
src: PathBuf,
out: PathBuf,
rust_info: channel::GitInfo,
cargo_info: channel::GitInfo,
rls_info: channel::GitInfo,
clippy_info: channel::GitInfo,
miri_info: channel::GitInfo,
rustfmt_info: channel::GitInfo,
in_tree_llvm_info: channel::GitInfo,
local_rebuild: bool,
fail_fast: bool,
doc_tests: DocTests,
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,
// 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>,
ranlib: HashMap<Interned<String>, PathBuf>,
// Miscellaneous
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>,
deps: HashSet<Interned<String>>,
id: String,
path: PathBuf,
}
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, PartialOrd, Ord)]
pub enum Mode {
/// Build the standard library, placing output in the "stageN-std" directory.
Std,
/// Build librustc, and compiler libraries, placing output in the "stageN-rustc" directory.
Rustc,
/// Build codegen libraries, placing output in the "stageN-codegen" directory
Codegen,
/// Build some tools, placing output in the "stageN-tools" directory. The
/// "other" here is for miscellaneous sets of tools that are built using the
/// bootstrap compiler in its entirety (target libraries and all).
/// Typically these tools compile with stable Rust.
ToolBootstrap,
/// Compile a tool which uses all libraries we compile (up to rustc).
/// Doesn't use the stage0 compiler libraries like "other", and includes
/// tools like rustdoc, cargo, rls, etc.
ToolStd,
ToolRustc,
}
impl Mode {
pub fn is_tool(&self) -> bool {
match self {
Mode::ToolBootstrap | Mode::ToolRustc | Mode::ToolStd => true,
_ => false,
}
}
}
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 src = config.src.clone();
let out = config.out.clone();
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 ignore_git = config.ignore_git;
let rust_info = channel::GitInfo::new(ignore_git, &src);
let cargo_info = channel::GitInfo::new(ignore_git, &src.join("src/tools/cargo"));
let rls_info = channel::GitInfo::new(ignore_git, &src.join("src/tools/rls"));
let clippy_info = channel::GitInfo::new(ignore_git, &src.join("src/tools/clippy"));
let miri_info = channel::GitInfo::new(ignore_git, &src.join("src/tools/miri"));
let rustfmt_info = channel::GitInfo::new(ignore_git, &src.join("src/tools/rustfmt"));
// we always try to use git for LLVM builds
let in_tree_llvm_info = channel::GitInfo::new(false, &src.join("src/llvm-project"));
let mut build = 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,
clippy_info,
miri_info,
rustfmt_info,
in_tree_llvm_info,
cc: HashMap::new(),
cxx: HashMap::new(),
ar: HashMap::new(),
ranlib: HashMap::new(),
crates: HashMap::new(),
is_sudo,
ci_env: CiEnv::current(),
delayed_failures: RefCell::new(Vec::new()),
prerelease_version: Cell::new(None),
tool_artifacts: Default::default(),
};
build.verbose("finding compilers");
cc_detect::find(&mut build);
build.verbose("running sanity check");
sanity::check(&mut build);
// If local-rust is the same major.minor as the current version, then force a
// local-rebuild
let local_version_verbose =
output(Command::new(&build.initial_rustc).arg("--version").arg("--verbose"));
let local_release = local_version_verbose
.lines()
.filter(|x| x.starts_with("release:"))
.next()
.unwrap()
.trim_start_matches("release:")
.trim();
let my_version = channel::CFG_RELEASE_NUM;
if local_release.split('.').take(2).eq(my_version.split('.').take(2)) {
build.verbose(&format!("auto-detected local-rebuild {}", local_release));
build.local_rebuild = true;
}
build.verbose("learning about cargo");
metadata::build(&mut build);
build
}
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::Format { check } = self.config.cmd {
return format::format(self, check);
}
if let Subcommand::Clean { all } = self.config.cmd {
return clean::clean(self, all);
}
{
let builder = builder::Builder::new(&self);
if let Some(path) = builder.paths.get(0) {
if path == Path::new("nonexistent/path/to/trigger/cargo/metadata") {
return;
}
}
}
if !self.config.dry_run {
{
self.config.dry_run = true;
let builder = builder::Builder::new(&self);
builder.execute_cli();
}
self.config.dry_run = false;
let builder = builder::Builder::new(&self);
builder.execute_cli();
} else {
let builder = builder::Builder::new(&self);
let _ = builder.execute_cli();
}
// 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
}
/// Gets 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.llvm_libunwind {
features.push_str(" llvm-libunwind");
}
if self.config.backtrace {
features.push_str(" backtrace");
}
if self.config.profiler {
features.push_str(" profiler");
}
features
}
/// Gets the space-separated set of activated features for the compiler.
fn rustc_features(&self) -> String {
let mut features = String::new();
if self.config.jemalloc {
features.push_str("jemalloc");
}
if self.config.llvm_enabled() {
features.push_str(" llvm");
}
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::Std => "-std",
Mode::Rustc => "-rustc",
Mode::Codegen => "-codegen",
Mode::ToolBootstrap => "-bootstrap-tools",
Mode::ToolStd | Mode::ToolRustc => "-tools",
};
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 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_filecheck.as_ref()) {
s.to_path_buf()
} else if let Some(s) = target_config.and_then(|c| c.llvm_config.as_ref()) {
let llvm_bindir = output(Command::new(s).arg("--bindir"));
let filecheck = Path::new(llvm_bindir.trim()).join(exe("FileCheck", &*target));
if filecheck.exists() {
filecheck
} else {
// On Fedora the system LLVM installs FileCheck in the
// llvm subdirectory of the libdir.
let llvm_libdir = output(Command::new(s).arg("--libdir"));
let lib_filecheck =
Path::new(llvm_libdir.trim()).join("llvm").join(exe("FileCheck", &*target));
if lib_filecheck.exists() {
lib_filecheck
} else {
// Return the most normal file name, even though
// it doesn't exist, so that any error message
// refers to that.
filecheck
}
}
} else {
let base = self.llvm_out(self.config.build).join("build");
let base = if !self.config.ninja && self.config.build.contains("msvc") {
if self.config.llvm_optimize {
if self.config.llvm_release_debuginfo {
base.join("RelWithDebInfo")
} else {
base.join("Release")
}
} else {
base.join("Debug")
}
} else {
base
};
base.join("bin").join(exe("FileCheck", &*target))
}
}
/// 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.rustc_snapshot_sysroot().join(libdir(&self.config.build))
}
/// Returns the sysroot of the snapshot compiler.
fn rustc_snapshot_sysroot(&self) -> &Path {
self.initial_rustc.parent().unwrap().parent().unwrap()
}
/// Runs a command, printing out nice contextual information if it fails.
fn run(&self, cmd: &mut Command) {
if self.config.dry_run {
return;
}
self.verbose(&format!("running: {:?}", cmd));
run(cmd)
}
/// Runs a command, printing out nice contextual information if it fails.
fn run_quiet(&self, cmd: &mut Command) {
if self.config.dry_run {
return;
}
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 {
if self.config.dry_run {
return true;
}
self.verbose(&format!("running: {:?}", cmd));
try_run(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 {
if self.config.dry_run {
return true;
}
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);
}
}
pub fn is_verbose_than(&self, level: usize) -> bool {
self.verbosity > level
}
/// Prints a message if this build is configured in more verbose mode than `level`.
fn verbose_than(&self, level: usize, msg: &str) {
if self.is_verbose_than(level) {
println!("{}", msg);
}
}
fn info(&self, msg: &str) {
if self.config.dry_run {
return;
}
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)
}
fn debuginfo_map(&self, which: GitRepo) -> Option<String> {
if !self.config.rust_remap_debuginfo {
return None;
}
let path = match which {
GitRepo::Rustc => {
let sha = self.rust_sha().unwrap_or(channel::CFG_RELEASE_NUM);
format!("/rustc/{}", sha)
}
GitRepo::Llvm => String::from("/rustc/llvm"),
};
Some(format!("{}={}", self.src.display(), path))
}
/// 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>, which: GitRepo) -> 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<String>>();
// 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/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());
}
if let Some(map) = self.debuginfo_map(which) {
let cc = self.cc(target);
if cc.ends_with("clang") || cc.ends_with("gcc") {
base.push(format!("-fdebug-prefix-map={}", map));
} else if cc.ends_with("clang-cl.exe") {
base.push("-Xclang".into());
base.push(format!("-fdebug-prefix-map={}", map));
}
}
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 `ranlib` utility for the target specified.
fn ranlib(&self, target: Interned<String>) -> Option<&Path> {
self.ranlib.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
&& util::use_host_linker(&target)
&& !target.contains("msvc")
{
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 the sysroot for the wasi target, if defined
fn wasi_root(&self, target: Interned<String>) -> Option<&Path> {
self.config.target_config.get(&target).and_then(|t| t.wasi_root.as_ref()).map(|p| &**p)
}
/// Returns `true` if this is a no-std `target`, if defined
fn no_std(&self, target: Interned<String>) -> Option<bool> {
self.config.target_config.get(&target).map(|t| t.no_std)
}
/// Returns `true` if 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)
}
/// 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 clippy
fn clippy_package_vers(&self) -> String {
self.package_vers(&self.release_num("clippy"))
}
/// Returns the value of `package_vers` above for miri
fn miri_package_vers(&self) -> String {
self.package_vers(&self.release_num("miri"))
}
/// Returns the value of `package_vers` above for rustfmt
fn rustfmt_package_vers(&self) -> String {
self.package_vers(&self.release_num("rustfmt"))
}
fn llvm_tools_package_vers(&self) -> String {
self.package_vers(channel::CFG_RELEASE_NUM)
}
fn llvm_tools_vers(&self) -> String {
self.rust_version()
}
fn lldb_package_vers(&self) -> String {
self.package_vers(channel::CFG_RELEASE_NUM)
}
fn lldb_vers(&self) -> String {
self.rust_version()
}
fn llvm_link_tools_dynamically(&self, target: Interned<String>) -> bool {
(target.contains("linux-gnu") || target.contains("apple-darwin"))
}
/// 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)
}
/// Returns 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 toml_file_name = self.src.join(&format!("src/tools/{}/Cargo.toml", package));
let toml = t!(fs::read_to_string(&toml_file_name));
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 `true` if 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,
}
}
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
}
fn read_stamp_file(&self, stamp: &Path) -> Vec<(PathBuf, bool)> {
if self.config.dry_run {
return Vec::new();
}
let mut paths = Vec::new();
let contents = t!(fs::read(stamp), &stamp);
// This is the method we use for extracting paths from the stamp file passed to us. See
// run_cargo for more information (in compile.rs).
for part in contents.split(|b| *b == 0) {
if part.is_empty() {
continue;
}
let host = part[0] as char == 'h';
let path = PathBuf::from(t!(str::from_utf8(&part[1..])));
paths.push((path, host));
}
paths
}
/// Copies a file from `src` to `dst`
pub fn copy(&self, src: &Path, dst: &Path) {
if self.config.dry_run {
return;
}
self.verbose_than(1, &format!("Copy {:?} to {:?}", src, dst));
if src == dst {
return;
}
let _ = fs::remove_file(&dst);
let metadata = t!(src.symlink_metadata());
if metadata.file_type().is_symlink() {
let link = t!(fs::read_link(src));
t!(symlink_file(link, dst));
} else if let Ok(()) = fs::hard_link(src, dst) {
// Attempt to "easy copy" by creating a hard link
// (symlinks don't work on windows), but if that fails
// just fall back to a slow `copy` operation.
} else {
if let Err(e) = fs::copy(src, dst) {
panic!("failed to copy `{}` to `{}`: {}", src.display(), dst.display(), e)
}
t!(fs::set_permissions(dst, metadata.permissions()));
let atime = FileTime::from_last_access_time(&metadata);
let mtime = FileTime::from_last_modification_time(&metadata);
t!(filetime::set_file_times(dst, atime, mtime));
}
}
/// Search-and-replaces within a file. (Not maximally efficiently: allocates a
/// new string for each replacement.)
pub fn replace_in_file(&self, path: &Path, replacements: &[(&str, &str)]) {
if self.config.dry_run {
return;
}
let mut contents = String::new();
let mut file = t!(OpenOptions::new().read(true).write(true).open(path));
t!(file.read_to_string(&mut contents));
for &(target, replacement) in replacements {
contents = contents.replace(target, replacement);
}
t!(file.seek(SeekFrom::Start(0)));
t!(file.set_len(0));
t!(file.write_all(contents.as_bytes()));
}
/// Copies the `src` directory recursively to `dst`. Both are assumed to exist
/// when this function is called.
pub fn cp_r(&self, src: &Path, dst: &Path) {
if self.config.dry_run {
return;
}
for f in self.read_dir(src) {
let path = f.path();
let name = path.file_name().unwrap();
let dst = dst.join(name);
if t!(f.file_type()).is_dir() {
t!(fs::create_dir_all(&dst));
self.cp_r(&path, &dst);
} else {
let _ = fs::remove_file(&dst);
self.copy(&path, &dst);
}
}
}
/// Copies the `src` directory recursively to `dst`. Both are assumed to exist
/// when this function is called. Unwanted files or directories can be skipped
/// by returning `false` from the filter function.
pub fn cp_filtered(&self, src: &Path, dst: &Path, filter: &dyn Fn(&Path) -> bool) {
// Immediately recurse with an empty relative path
self.recurse_(src, dst, Path::new(""), filter)
}
// Inner function does the actual work
fn recurse_(&self, src: &Path, dst: &Path, relative: &Path, filter: &dyn Fn(&Path) -> bool) {
for f in self.read_dir(src) {
let path = f.path();
let name = path.file_name().unwrap();
let dst = dst.join(name);
let relative = relative.join(name);
// Only copy file or directory if the filter function returns true
if filter(&relative) {
if t!(f.file_type()).is_dir() {
let _ = fs::remove_dir_all(&dst);
self.create_dir(&dst);
self.recurse_(&path, &dst, &relative, filter);
} else {
let _ = fs::remove_file(&dst);
self.copy(&path, &dst);
}
}
}
}
fn copy_to_folder(&self, src: &Path, dest_folder: &Path) {
let file_name = src.file_name().unwrap();
let dest = dest_folder.join(file_name);
self.copy(src, &dest);
}
fn install(&self, src: &Path, dstdir: &Path, perms: u32) {
if self.config.dry_run {
return;
}
let dst = dstdir.join(src.file_name().unwrap());
self.verbose_than(1, &format!("Install {:?} to {:?}", src, dst));
t!(fs::create_dir_all(dstdir));
drop(fs::remove_file(&dst));
{
if !src.exists() {
panic!("Error: File \"{}\" not found!", src.display());
}
let metadata = t!(src.symlink_metadata());
if let Err(e) = fs::copy(&src, &dst) {
panic!("failed to copy `{}` to `{}`: {}", src.display(), dst.display(), e)
}
t!(fs::set_permissions(&dst, metadata.permissions()));
let atime = FileTime::from_last_access_time(&metadata);
let mtime = FileTime::from_last_modification_time(&metadata);
t!(filetime::set_file_times(&dst, atime, mtime));
}
chmod(&dst, perms);
}
fn create(&self, path: &Path, s: &str) {
if self.config.dry_run {
return;
}
t!(fs::write(path, s));
}
fn read(&self, path: &Path) -> String {
if self.config.dry_run {
return String::new();
}
t!(fs::read_to_string(path))
}
fn create_dir(&self, dir: &Path) {
if self.config.dry_run {
return;
}
t!(fs::create_dir_all(dir))
}
fn remove_dir(&self, dir: &Path) {
if self.config.dry_run {
return;
}
t!(fs::remove_dir_all(dir))
}
fn read_dir(&self, dir: &Path) -> impl Iterator<Item = fs::DirEntry> {
let iter = match fs::read_dir(dir) {
Ok(v) => v,
Err(_) if self.config.dry_run => return vec![].into_iter(),
Err(err) => panic!("could not read dir {:?}: {:?}", dir, err),
};
iter.map(|e| t!(e)).collect::<Vec<_>>().into_iter()
}
fn remove(&self, f: &Path) {
if self.config.dry_run {
return;
}
fs::remove_file(f).unwrap_or_else(|_| panic!("failed to remove {:?}", f));
}
}
#[cfg(unix)]
fn chmod(path: &Path, perms: u32) {
use std::os::unix::fs::*;
t!(fs::set_permissions(path, fs::Permissions::from_mode(perms)));
}
#[cfg(windows)]
fn chmod(_path: &Path, _perms: u32) {}
impl Compiler {
pub fn with_stage(mut self, stage: u32) -> Compiler {
self.stage = stage;
self
}
/// Returns `true` if 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
}
}
fn envify(s: &str) -> String {
s.chars()
.map(|c| match c {
'-' => '_',
c => c,
})
.flat_map(|c| c.to_uppercase())
.collect()
}