//! A Rust library for build scripts to automatically configure code based on //! compiler support. Code snippets are dynamically tested to see if the `rustc` //! will accept them, rather than hard-coding specific version support. //! //! //! ## Usage //! //! Add this to your `Cargo.toml`: //! //! ```toml //! [build-dependencies] //! autocfg = "1" //! ``` //! //! Then use it in your `build.rs` script to detect compiler features. For //! example, to test for 128-bit integer support, it might look like: //! //! ```rust //! extern crate autocfg; //! //! fn main() { //! # // Normally, cargo will set `OUT_DIR` for build scripts. //! # std::env::set_var("OUT_DIR", "target"); //! let ac = autocfg::new(); //! ac.emit_has_type("i128"); //! //! // (optional) We don't need to rerun for anything external. //! autocfg::rerun_path("build.rs"); //! } //! ``` //! //! If the type test succeeds, this will write a `cargo:rustc-cfg=has_i128` line //! for Cargo, which translates to Rust arguments `--cfg has_i128`. Then in the //! rest of your Rust code, you can add `#[cfg(has_i128)]` conditions on code that //! should only be used when the compiler supports it. //! //! ## Caution //! //! Many of the probing methods of `AutoCfg` document the particular template they //! use, **subject to change**. The inputs are not validated to make sure they are //! semantically correct for their expected use, so it's _possible_ to escape and //! inject something unintended. However, such abuse is unsupported and will not //! be considered when making changes to the templates. #![deny(missing_debug_implementations)] #![deny(missing_docs)] // allow future warnings that can't be fixed while keeping 1.0 compatibility #![allow(unknown_lints)] #![allow(bare_trait_objects)] #![allow(ellipsis_inclusive_range_patterns)] /// Local macro to avoid `std::try!`, deprecated in Rust 1.39. macro_rules! try { ($result:expr) => { match $result { Ok(value) => value, Err(error) => return Err(error), } }; } use std::env; use std::ffi::OsString; use std::fs; use std::io::{stderr, Write}; use std::path::PathBuf; use std::process::{Command, Stdio}; #[allow(deprecated)] use std::sync::atomic::ATOMIC_USIZE_INIT; use std::sync::atomic::{AtomicUsize, Ordering}; mod error; pub use error::Error; mod version; use version::Version; #[cfg(test)] mod tests; /// Helper to detect compiler features for `cfg` output in build scripts. #[derive(Clone, Debug)] pub struct AutoCfg { out_dir: PathBuf, rustc: PathBuf, rustc_version: Version, target: Option, no_std: bool, rustflags: Option>, } /// Writes a config flag for rustc on standard out. /// /// This looks like: `cargo:rustc-cfg=CFG` /// /// Cargo will use this in arguments to rustc, like `--cfg CFG`. pub fn emit(cfg: &str) { println!("cargo:rustc-cfg={}", cfg); } /// Writes a line telling Cargo to rerun the build script if `path` changes. /// /// This looks like: `cargo:rerun-if-changed=PATH` /// /// This requires at least cargo 0.7.0, corresponding to rustc 1.6.0. Earlier /// versions of cargo will simply ignore the directive. pub fn rerun_path(path: &str) { println!("cargo:rerun-if-changed={}", path); } /// Writes a line telling Cargo to rerun the build script if the environment /// variable `var` changes. /// /// This looks like: `cargo:rerun-if-env-changed=VAR` /// /// This requires at least cargo 0.21.0, corresponding to rustc 1.20.0. Earlier /// versions of cargo will simply ignore the directive. pub fn rerun_env(var: &str) { println!("cargo:rerun-if-env-changed={}", var); } /// Create a new `AutoCfg` instance. /// /// # Panics /// /// Panics if `AutoCfg::new()` returns an error. pub fn new() -> AutoCfg { AutoCfg::new().unwrap() } impl AutoCfg { /// Create a new `AutoCfg` instance. /// /// # Common errors /// /// - `rustc` can't be executed, from `RUSTC` or in the `PATH`. /// - The version output from `rustc` can't be parsed. /// - `OUT_DIR` is not set in the environment, or is not a writable directory. /// pub fn new() -> Result { match env::var_os("OUT_DIR") { Some(d) => Self::with_dir(d), None => Err(error::from_str("no OUT_DIR specified!")), } } /// Create a new `AutoCfg` instance with the specified output directory. /// /// # Common errors /// /// - `rustc` can't be executed, from `RUSTC` or in the `PATH`. /// - The version output from `rustc` can't be parsed. /// - `dir` is not a writable directory. /// pub fn with_dir>(dir: T) -> Result { let rustc = env::var_os("RUSTC").unwrap_or_else(|| "rustc".into()); let rustc: PathBuf = rustc.into(); let rustc_version = try!(Version::from_rustc(&rustc)); let target = env::var_os("TARGET"); // Sanity check the output directory let dir = dir.into(); let meta = try!(fs::metadata(&dir).map_err(error::from_io)); if !meta.is_dir() || meta.permissions().readonly() { return Err(error::from_str("output path is not a writable directory")); } // Cargo only applies RUSTFLAGS for building TARGET artifact in // cross-compilation environment. Sadly, we don't have a way to detect // when we're building HOST artifact in a cross-compilation environment, // so for now we only apply RUSTFLAGS when cross-compiling an artifact. // // See https://github.com/cuviper/autocfg/pull/10#issuecomment-527575030. let rustflags = if target != env::var_os("HOST") || dir_contains_target(&target, &dir, env::var_os("CARGO_TARGET_DIR")) { env::var("RUSTFLAGS").ok().map(|rustflags| { // This is meant to match how cargo handles the RUSTFLAG environment // variable. // See https://github.com/rust-lang/cargo/blob/69aea5b6f69add7c51cca939a79644080c0b0ba0/src/cargo/core/compiler/build_context/target_info.rs#L434-L441 rustflags .split(' ') .map(str::trim) .filter(|s| !s.is_empty()) .map(str::to_string) .collect::>() }) } else { None }; let mut ac = AutoCfg { out_dir: dir, rustc: rustc, rustc_version: rustc_version, target: target, no_std: false, rustflags: rustflags, }; // Sanity check with and without `std`. if !ac.probe("").unwrap_or(false) { ac.no_std = true; if !ac.probe("").unwrap_or(false) { // Neither worked, so assume nothing... ac.no_std = false; let warning = b"warning: autocfg could not probe for `std`\n"; stderr().write_all(warning).ok(); } } Ok(ac) } /// Test whether the current `rustc` reports a version greater than /// or equal to "`major`.`minor`". pub fn probe_rustc_version(&self, major: usize, minor: usize) -> bool { self.rustc_version >= Version::new(major, minor, 0) } /// Sets a `cfg` value of the form `rustc_major_minor`, like `rustc_1_29`, /// if the current `rustc` is at least that version. pub fn emit_rustc_version(&self, major: usize, minor: usize) { if self.probe_rustc_version(major, minor) { emit(&format!("rustc_{}_{}", major, minor)); } } fn probe>(&self, code: T) -> Result { #[allow(deprecated)] static ID: AtomicUsize = ATOMIC_USIZE_INIT; let id = ID.fetch_add(1, Ordering::Relaxed); let mut command = Command::new(&self.rustc); command .arg("--crate-name") .arg(format!("probe{}", id)) .arg("--crate-type=lib") .arg("--out-dir") .arg(&self.out_dir) .arg("--emit=llvm-ir"); if let &Some(ref rustflags) = &self.rustflags { command.args(rustflags); } if let Some(target) = self.target.as_ref() { command.arg("--target").arg(target); } command.arg("-").stdin(Stdio::piped()).stderr(Stdio::null()); let mut child = try!(command.spawn().map_err(error::from_io)); let mut stdin = child.stdin.take().expect("rustc stdin"); if self.no_std { try!(stdin.write_all(b"#![no_std]\n").map_err(error::from_io)); } try!(stdin.write_all(code.as_ref()).map_err(error::from_io)); drop(stdin); let status = try!(child.wait().map_err(error::from_io)); Ok(status.success()) } /// Tests whether the given sysroot crate can be used. /// /// The test code is subject to change, but currently looks like: /// /// ```ignore /// extern crate CRATE as probe; /// ``` pub fn probe_sysroot_crate(&self, name: &str) -> bool { self.probe(format!("extern crate {} as probe;", name)) // `as _` wasn't stabilized until Rust 1.33 .unwrap_or(false) } /// Emits a config value `has_CRATE` if `probe_sysroot_crate` returns true. pub fn emit_sysroot_crate(&self, name: &str) { if self.probe_sysroot_crate(name) { emit(&format!("has_{}", mangle(name))); } } /// Tests whether the given path can be used. /// /// The test code is subject to change, but currently looks like: /// /// ```ignore /// pub use PATH; /// ``` pub fn probe_path(&self, path: &str) -> bool { self.probe(format!("pub use {};", path)).unwrap_or(false) } /// Emits a config value `has_PATH` if `probe_path` returns true. /// /// Any non-identifier characters in the `path` will be replaced with /// `_` in the generated config value. pub fn emit_has_path(&self, path: &str) { if self.probe_path(path) { emit(&format!("has_{}", mangle(path))); } } /// Emits the given `cfg` value if `probe_path` returns true. pub fn emit_path_cfg(&self, path: &str, cfg: &str) { if self.probe_path(path) { emit(cfg); } } /// Tests whether the given trait can be used. /// /// The test code is subject to change, but currently looks like: /// /// ```ignore /// pub trait Probe: TRAIT + Sized {} /// ``` pub fn probe_trait(&self, name: &str) -> bool { self.probe(format!("pub trait Probe: {} + Sized {{}}", name)) .unwrap_or(false) } /// Emits a config value `has_TRAIT` if `probe_trait` returns true. /// /// Any non-identifier characters in the trait `name` will be replaced with /// `_` in the generated config value. pub fn emit_has_trait(&self, name: &str) { if self.probe_trait(name) { emit(&format!("has_{}", mangle(name))); } } /// Emits the given `cfg` value if `probe_trait` returns true. pub fn emit_trait_cfg(&self, name: &str, cfg: &str) { if self.probe_trait(name) { emit(cfg); } } /// Tests whether the given type can be used. /// /// The test code is subject to change, but currently looks like: /// /// ```ignore /// pub type Probe = TYPE; /// ``` pub fn probe_type(&self, name: &str) -> bool { self.probe(format!("pub type Probe = {};", name)) .unwrap_or(false) } /// Emits a config value `has_TYPE` if `probe_type` returns true. /// /// Any non-identifier characters in the type `name` will be replaced with /// `_` in the generated config value. pub fn emit_has_type(&self, name: &str) { if self.probe_type(name) { emit(&format!("has_{}", mangle(name))); } } /// Emits the given `cfg` value if `probe_type` returns true. pub fn emit_type_cfg(&self, name: &str, cfg: &str) { if self.probe_type(name) { emit(cfg); } } /// Tests whether the given expression can be used. /// /// The test code is subject to change, but currently looks like: /// /// ```ignore /// pub fn probe() { let _ = EXPR; } /// ``` pub fn probe_expression(&self, expr: &str) -> bool { self.probe(format!("pub fn probe() {{ let _ = {}; }}", expr)) .unwrap_or(false) } /// Emits the given `cfg` value if `probe_expression` returns true. pub fn emit_expression_cfg(&self, expr: &str, cfg: &str) { if self.probe_expression(expr) { emit(cfg); } } /// Tests whether the given constant expression can be used. /// /// The test code is subject to change, but currently looks like: /// /// ```ignore /// pub const PROBE: () = ((), EXPR).0; /// ``` pub fn probe_constant(&self, expr: &str) -> bool { self.probe(format!("pub const PROBE: () = ((), {}).0;", expr)) .unwrap_or(false) } /// Emits the given `cfg` value if `probe_constant` returns true. pub fn emit_constant_cfg(&self, expr: &str, cfg: &str) { if self.probe_constant(expr) { emit(cfg); } } } fn mangle(s: &str) -> String { s.chars() .map(|c| match c { 'A'...'Z' | 'a'...'z' | '0'...'9' => c, _ => '_', }) .collect() } fn dir_contains_target( target: &Option, dir: &PathBuf, cargo_target_dir: Option, ) -> bool { target .as_ref() .and_then(|target| { dir.to_str().and_then(|dir| { let mut cargo_target_dir = cargo_target_dir .map(PathBuf::from) .unwrap_or_else(|| PathBuf::from("target")); cargo_target_dir.push(target); cargo_target_dir .to_str() .map(|cargo_target_dir| dir.contains(&cargo_target_dir)) }) }) .unwrap_or(false) }