use std::env::var; use std::io::Write; /// The directory for inline asm. const ASM_PATH: &str = "src/backend/linux_raw/arch/asm"; fn main() { // Don't rerun this on changes other than build.rs, as we only depend on // the rustc version. println!("cargo:rerun-if-changed=build.rs"); // Gather target information. let arch = var("CARGO_CFG_TARGET_ARCH").unwrap(); let env = var("CARGO_CFG_TARGET_ENV").unwrap(); let inline_asm_name = format!("{}/{}.rs", ASM_PATH, arch); let inline_asm_name_present = std::fs::metadata(inline_asm_name).is_ok(); let os = var("CARGO_CFG_TARGET_OS").unwrap(); let pointer_width = var("CARGO_CFG_TARGET_POINTER_WIDTH").unwrap(); let endian = var("CARGO_CFG_TARGET_ENDIAN").unwrap(); // Check for special target variants. let is_x32 = arch == "x86_64" && pointer_width == "32"; let is_arm64_ilp32 = arch == "aarch64" && pointer_width == "32"; let is_powerpc64be = arch == "powerpc64" && endian == "big"; let is_mipseb = (arch == "mips" || arch == "mips32r6") && endian == "big"; let is_mips64eb = arch.contains("mips64") && endian == "big"; let is_unsupported_abi = is_x32 || is_arm64_ilp32 || is_powerpc64be || is_mipseb || is_mips64eb; // Check for `--features=use-libc`. This allows crate users to enable the // libc backend. let feature_use_libc = var("CARGO_FEATURE_USE_LIBC").is_ok(); // Check for `RUSTFLAGS=--cfg=rustix_use_libc`. This allows end users to // enable the libc backend even if rustix is depended on transitively. let cfg_use_libc = var("CARGO_CFG_RUSTIX_USE_LIBC").is_ok(); // Check for eg. `RUSTFLAGS=--cfg=rustix_use_experimental_features`. This // is a rustc flag rather than a cargo feature flag because it's // experimental and not something we want accidentally enabled via // `--all-features`. let rustix_use_experimental_features = var("CARGO_CFG_RUSTIX_USE_EXPERIMENTAL_FEATURES").is_ok(); // Check for eg. `RUSTFLAGS=--cfg=rustix_use_experimental_asm`. This is a // rustc flag rather than a cargo feature flag because it's experimental // and not something we want accidentally enabled via `--all-features`. let rustix_use_experimental_asm = var("CARGO_CFG_RUSTIX_USE_EXPERIMENTAL_ASM").is_ok(); // Miri doesn't support inline asm, and has builtin support for recognizing // libc FFI calls, so if we're running under miri, use the libc backend. let miri = var("CARGO_CFG_MIRI").is_ok(); // If experimental features are enabled, auto-detect and use available // features. if rustix_use_experimental_features { use_feature_or_nothing("rustc_attrs"); use_feature_or_nothing("core_intrinsics"); } // Features needed only in no-std configurations. #[cfg(not(feature = "std"))] { use_feature_or_nothing("core_c_str"); use_feature_or_nothing("core_ffi_c"); use_feature_or_nothing("alloc_c_string"); use_feature_or_nothing("alloc_ffi"); } // Feature needed for testing. if use_static_assertions() { use_feature("static_assertions"); } // If the libc backend is requested, or if we're not on a platform for // which we have linux_raw support, use the libc backend. // // For now Android uses the libc backend; in theory it could use the // linux_raw backend, but to do that we'll need to figure out how to // install the toolchain for it. let libc = feature_use_libc || cfg_use_libc || os != "linux" || !inline_asm_name_present || is_unsupported_abi || miri || ((arch == "powerpc64" || arch == "mips" || arch == "mips64" || arch == "mips64r6") && !rustix_use_experimental_asm); if libc { // Use the libc backend. use_feature("libc"); } else { // Use the linux_raw backend. use_feature("linux_raw"); if rustix_use_experimental_asm { use_feature("asm_experimental_arch"); } } // Detect whether the compiler requires us to use thumb mode on ARM. if arch == "arm" && use_thumb_mode() { use_feature("thumb_mode"); } // Rust's libc crate groups some OS's together which have similar APIs; // create similarly-named features to make `cfg` tests more concise. let freebsdlike = os == "freebsd" || os == "dragonfly"; if freebsdlike { use_feature("freebsdlike"); } let netbsdlike = os == "openbsd" || os == "netbsd"; if netbsdlike { use_feature("netbsdlike"); } let apple = os == "macos" || os == "ios" || os == "tvos" || os == "watchos"; if apple { use_feature("apple"); } if os == "linux" || os == "l4re" || os == "android" || os == "emscripten" { use_feature("linux_like"); } if os == "solaris" || os == "illumos" { use_feature("solarish"); } if apple || freebsdlike || netbsdlike { use_feature("bsd"); } // Add some additional common target combinations. // Android and "regular" Linux both use the Linux kernel. if os == "android" || os == "linux" { use_feature("linux_kernel"); } // These platforms have a 32-bit `time_t`. if libc && (arch == "arm" || arch == "mips" || arch == "sparc" || arch == "x86" || (arch == "wasm32" && os == "emscripten")) && (apple || os == "android" || os == "emscripten" || os == "haiku" || env == "gnu" || (env == "musl" && arch == "x86")) { use_feature("fix_y2038"); } println!("cargo:rerun-if-env-changed=CARGO_CFG_RUSTIX_USE_EXPERIMENTAL_ASM"); println!("cargo:rerun-if-env-changed=CARGO_CFG_RUSTIX_USE_LIBC"); // Rerun this script if any of our features or configuration flags change, // or if the toolchain we used for feature detection changes. println!("cargo:rerun-if-env-changed=CARGO_FEATURE_USE_LIBC"); println!("cargo:rerun-if-env-changed=CARGO_FEATURE_RUSTC_DEP_OF_STD"); println!("cargo:rerun-if-env-changed=CARGO_CFG_MIRI"); } fn use_static_assertions() -> bool { // `offset_from` was made const in Rust 1.65. can_compile("const unsafe fn foo(p: *const u8) -> isize { p.offset_from(p) }") } fn use_thumb_mode() -> bool { // In thumb mode, r7 is reserved. !can_compile("pub unsafe fn f() { core::arch::asm!(\"udf #16\", in(\"r7\") 0); }") } fn use_feature_or_nothing(feature: &str) { if has_feature(feature) { use_feature(feature); } } fn use_feature(feature: &str) { println!("cargo:rustc-cfg={}", feature); } /// Test whether the rustc at `var("RUSTC")` supports the given feature. fn has_feature(feature: &str) -> bool { can_compile(format!( "#![allow(stable_features)]\n#![feature({})]", feature )) } /// Test whether the rustc at `var("RUSTC")` can compile the given code. fn can_compile>(test: T) -> bool { use std::process::Stdio; let out_dir = var("OUT_DIR").unwrap(); let rustc = var("RUSTC").unwrap(); let target = var("TARGET").unwrap(); // Use `RUSTC_WRAPPER` if it's set, unless it's set to an empty string, as // documented [here]. // [here]: https://doc.rust-lang.org/cargo/reference/environment-variables.html#environment-variables-cargo-reads let wrapper = var("RUSTC_WRAPPER") .ok() .and_then(|w| if w.is_empty() { None } else { Some(w) }); let mut cmd = if let Some(wrapper) = wrapper { let mut cmd = std::process::Command::new(wrapper); // The wrapper's first argument is supposed to be the path to rustc. cmd.arg(rustc); cmd } else { std::process::Command::new(rustc) }; cmd.arg("--crate-type=rlib") // Don't require `main`. .arg("--emit=metadata") // Do as little as possible but still parse. .arg("--target") .arg(target) .arg("--out-dir") .arg(out_dir); // Put the output somewhere inconsequential. // If Cargo wants to set RUSTFLAGS, use that. if let Ok(rustflags) = var("CARGO_ENCODED_RUSTFLAGS") { if !rustflags.is_empty() { for arg in rustflags.split('\x1f') { cmd.arg(arg); } } } let mut child = cmd .arg("-") // Read from stdin. .stdin(Stdio::piped()) // Stdin is a pipe. .stderr(Stdio::null()) // Errors from feature detection aren't interesting and can be confusing. .spawn() .unwrap(); writeln!(child.stdin.take().unwrap(), "{}", test.as_ref()).unwrap(); child.wait().unwrap().success() }