use autocfg::AutoCfg; const CONST_THREAD_LOCAL_PROBE: &str = r#" { thread_local! { static MY_PROBE: usize = const { 10 }; } MY_PROBE.with(|val| *val) } "#; const ADDR_OF_PROBE: &str = r#" { let my_var = 10; ::std::ptr::addr_of!(my_var) } "#; const CONST_MUTEX_NEW_PROBE: &str = r#" { static MY_MUTEX: ::std::sync::Mutex = ::std::sync::Mutex::new(1); *MY_MUTEX.lock().unwrap() } "#; const TARGET_HAS_ATOMIC_PROBE: &str = r#" { #[cfg(target_has_atomic = "ptr")] let _ = (); } "#; const TARGET_ATOMIC_U64_PROBE: &str = r#" { #[allow(unused_imports)] use std::sync::atomic::AtomicU64 as _; } "#; fn main() { let mut enable_const_thread_local = false; let mut enable_addr_of = false; let mut enable_target_has_atomic = false; let mut enable_const_mutex_new = false; let mut target_needs_atomic_u64_fallback = false; match AutoCfg::new() { Ok(ac) => { // These checks prefer to call only `probe_rustc_version` if that is // enough to determine whether the feature is supported. This is // because the `probe_expression` call involves a call to rustc, // which the `probe_rustc_version` call avoids. // Const-initialized thread locals were stabilized in 1.59. if ac.probe_rustc_version(1, 60) { enable_const_thread_local = true; } else if ac.probe_rustc_version(1, 59) { // This compiler claims to be 1.59, but there are some nightly // compilers that claim to be 1.59 without supporting the // feature. Explicitly probe to check if code using them // compiles. // // The oldest nightly that supports the feature is 2021-12-06. if ac.probe_expression(CONST_THREAD_LOCAL_PROBE) { enable_const_thread_local = true; } } // The `addr_of` and `addr_of_mut` macros were stabilized in 1.51. if ac.probe_rustc_version(1, 52) { enable_addr_of = true; } else if ac.probe_rustc_version(1, 51) { // This compiler claims to be 1.51, but there are some nightly // compilers that claim to be 1.51 without supporting the // feature. Explicitly probe to check if code using them // compiles. // // The oldest nightly that supports the feature is 2021-01-31. if ac.probe_expression(ADDR_OF_PROBE) { enable_addr_of = true; } } // The `target_has_atomic` cfg was stabilized in 1.60. if ac.probe_rustc_version(1, 61) { enable_target_has_atomic = true; } else if ac.probe_rustc_version(1, 60) { // This compiler claims to be 1.60, but there are some nightly // compilers that claim to be 1.60 without supporting the // feature. Explicitly probe to check if code using them // compiles. // // The oldest nightly that supports the feature is 2022-02-11. if ac.probe_expression(TARGET_HAS_ATOMIC_PROBE) { enable_target_has_atomic = true; } } // If we can't tell using `target_has_atomic`, tell if the target // has `AtomicU64` by trying to use it. if !enable_target_has_atomic && !ac.probe_expression(TARGET_ATOMIC_U64_PROBE) { target_needs_atomic_u64_fallback = true; } // The `Mutex::new` method was made const in 1.63. if ac.probe_rustc_version(1, 64) { enable_const_mutex_new = true; } else if ac.probe_rustc_version(1, 63) { // This compiler claims to be 1.63, but there are some nightly // compilers that claim to be 1.63 without supporting the // feature. Explicitly probe to check if code using them // compiles. // // The oldest nightly that supports the feature is 2022-06-20. if ac.probe_expression(CONST_MUTEX_NEW_PROBE) { enable_const_mutex_new = true; } } } Err(e) => { // If we couldn't detect the compiler version and features, just // print a warning. This isn't a fatal error: we can still build // Tokio, we just can't enable cfgs automatically. println!( "cargo:warning=tokio: failed to detect compiler features: {}", e ); } } if !enable_const_thread_local { // To disable this feature on compilers that support it, you can // explicitly pass this flag with the following environment variable: // // RUSTFLAGS="--cfg tokio_no_const_thread_local" autocfg::emit("tokio_no_const_thread_local") } if !enable_addr_of { // To disable this feature on compilers that support it, you can // explicitly pass this flag with the following environment variable: // // RUSTFLAGS="--cfg tokio_no_addr_of" autocfg::emit("tokio_no_addr_of") } if !enable_target_has_atomic { // To disable this feature on compilers that support it, you can // explicitly pass this flag with the following environment variable: // // RUSTFLAGS="--cfg tokio_no_target_has_atomic" autocfg::emit("tokio_no_target_has_atomic") } if !enable_const_mutex_new { // To disable this feature on compilers that support it, you can // explicitly pass this flag with the following environment variable: // // RUSTFLAGS="--cfg tokio_no_const_mutex_new" autocfg::emit("tokio_no_const_mutex_new") } if target_needs_atomic_u64_fallback { // To disable this feature on compilers that support it, you can // explicitly pass this flag with the following environment variable: // // RUSTFLAGS="--cfg tokio_no_atomic_u64" autocfg::emit("tokio_no_atomic_u64") } let target = ::std::env::var("TARGET").unwrap_or_default(); // We emit cfgs instead of using `target_family = "wasm"` that requires Rust 1.54. // Note that these cfgs are unavailable in `Cargo.toml`. if target.starts_with("wasm") { autocfg::emit("tokio_wasm"); if target.contains("wasi") { autocfg::emit("tokio_wasi_wasmedge"); } else { autocfg::emit("tokio_wasm_not_wasi"); } } }