//! # proc-macro-error //! //! This crate aims to make error reporting in proc-macros simple and easy to use. //! Migrate from `panic!`-based errors for as little effort as possible! //! //! (Also, you can explicitly [append a dummy token stream](dummy/index.html) to your errors). //! //! To achieve his, this crate serves as a tiny shim around `proc_macro::Diagnostic` and //! `compile_error!`. It detects the best way of emitting available based on compiler's version. //! When the underlying diagnostic type is finally stabilized, this crate will simply be //! delegating to it requiring no changes in your code! //! //! So you can just use this crate and have *both* some of `proc_macro::Diagnostic` functionality //! available on stable ahead of time *and* your error-reporting code future-proof. //! //! ## Cargo features //! //! This crate provides *enabled by default* `syn-error` feature that gates //! `impl From for Diagnostic` conversion. If you don't use `syn` and want //! to cut off some of compilation time, you can disable it via //! //! ```toml //! [dependencies] //! proc-macro-error = { version = "1", default-features = false } //! ``` //! //! ***Please note that disabling this feature makes sense only if you don't depend on `syn` //! directly or indirectly, and you very likely do.** //! //! ## Real world examples //! //! * [`structopt-derive`](https://github.com/TeXitoi/structopt/tree/master/structopt-derive) //! (abort-like usage) //! * [`auto-impl`](https://github.com/auto-impl-rs/auto_impl/) (emit-like usage) //! //! ## Limitations //! //! - Warnings are emitted only on nightly, they are ignored on stable. //! - "help" suggestions can't have their own span info on stable, //! (essentially inheriting the parent span). //! - If a panic occurs somewhere in your macro no errors will be displayed. This is not a //! technical limitation but rather intentional design. `panic` is not for error reporting. //! //! ### `#[proc_macro_error]` attribute //! //! **This attribute MUST be present on the top level of your macro** (the function //! annotated with any of `#[proc_macro]`, `#[proc_macro_derive]`, `#[proc_macro_attribute]`). //! //! This attribute performs the setup and cleanup necessary to make things work. //! //! In most cases you'll need the simple `#[proc_macro_error]` form without any //! additional settings. Feel free to [skip the "Syntax" section](#macros). //! //! #### Syntax //! //! `#[proc_macro_error]` or `#[proc_macro_error(settings...)]`, where `settings...` //! is a comma-separated list of: //! //! - `proc_macro_hack`: //! //! In order to correctly cooperate with `#[proc_macro_hack]`, `#[proc_macro_error]` //! attribute must be placed *before* (above) it, like this: //! //! ```no_run //! # use proc_macro2::TokenStream; //! # const IGNORE: &str = " //! #[proc_macro_error] //! #[proc_macro_hack] //! #[proc_macro] //! # "; //! fn my_macro(input: TokenStream) -> TokenStream { //! unimplemented!() //! } //! ``` //! //! If, for some reason, you can't place it like that you can use //! `#[proc_macro_error(proc_macro_hack)]` instead. //! //! # Note //! //! If `proc-macro-hack` was detected (by any means) `allow_not_macro` //! and `assert_unwind_safe` will be applied automatically. //! //! - `allow_not_macro`: //! //! By default, the attribute checks that it's applied to a proc-macro. //! If none of `#[proc_macro]`, `#[proc_macro_derive]` nor `#[proc_macro_attribute]` are //! present it will panic. It's the intention - this crate is supposed to be used only with //! proc-macros. //! //! This setting is made to bypass the check, useful in certain circumstances. //! //! Pay attention: the function this attribute is applied to must return //! `proc_macro::TokenStream`. //! //! This setting is implied if `proc-macro-hack` was detected. //! //! - `assert_unwind_safe`: //! //! By default, your code must be [unwind safe]. If your code is not unwind safe, //! but you believe it's correct, you can use this setting to bypass the check. //! You would need this for code that uses `lazy_static` or `thread_local` with //! `Cell/RefCell` inside (and the like). //! //! This setting is implied if `#[proc_macro_error]` is applied to a function //! marked as `#[proc_macro]`, `#[proc_macro_derive]` or `#[proc_macro_attribute]`. //! //! This setting is also implied if `proc-macro-hack` was detected. //! //! ## Macros //! //! Most of the time you want to use the macros. Syntax is described in the next section below. //! //! You'll need to decide how you want to emit errors: //! //! * Emit the error and abort. Very much panic-like usage. Served by [`abort!`] and //! [`abort_call_site!`]. //! * Emit the error but do not abort right away, looking for other errors to report. //! Served by [`emit_error!`] and [`emit_call_site_error!`]. //! //! You **can** mix these usages. //! //! `abort` and `emit_error` take a "source span" as the first argument. This source //! will be used to highlight the place the error originates from. It must be one of: //! //! * *Something* that implements [`ToTokens`] (most types in `syn` and `proc-macro2` do). //! This source is the preferable one since it doesn't lose span information on multi-token //! spans, see [this issue](https://gitlab.com/CreepySkeleton/proc-macro-error/-/issues/6) //! for details. //! * [`proc_macro::Span`] //! * [`proc-macro2::Span`] //! //! The rest is your message in format-like style. //! //! See [the next section](#syntax-1) for detailed syntax. //! //! - [`abort!`]: //! //! Very much panic-like usage - abort right away and show the error. //! Expands to [`!`] (never type). //! //! - [`abort_call_site!`]: //! //! Shortcut for `abort!(Span::call_site(), ...)`. Expands to [`!`] (never type). //! //! - [`emit_error!`]: //! //! [`proc_macro::Diagnostic`]-like usage - emit the error but keep going, //! looking for other errors to report. //! The compilation will fail nonetheless. Expands to [`()`] (unit type). //! //! - [`emit_call_site_error!`]: //! //! Shortcut for `emit_error!(Span::call_site(), ...)`. Expands to [`()`] (unit type). //! //! - [`emit_warning!`]: //! //! Like `emit_error!` but emit a warning instead of error. The compilation won't fail //! because of warnings. //! Expands to [`()`] (unit type). //! //! **Beware**: warnings are nightly only, they are completely ignored on stable. //! //! - [`emit_call_site_warning!`]: //! //! Shortcut for `emit_warning!(Span::call_site(), ...)`. Expands to [`()`] (unit type). //! //! - [`diagnostic`]: //! //! Build an instance of `Diagnostic` in format-like style. //! //! #### Syntax //! //! All the macros have pretty much the same syntax: //! //! 1. ```ignore //! abort!(single_expr) //! ``` //! Shortcut for `Diagnostic::from(expr).abort()`. //! //! 2. ```ignore //! abort!(span, message) //! ``` //! The first argument is an expression the span info should be taken from. //! //! The second argument is the error message, it must implement [`ToString`]. //! //! 3. ```ignore //! abort!(span, format_literal, format_args...) //! ``` //! //! This form is pretty much the same as 2, except `format!(format_literal, format_args...)` //! will be used to for the message instead of [`ToString`]. //! //! That's it. `abort!`, `emit_warning`, `emit_error` share this exact syntax. //! //! `abort_call_site!`, `emit_call_site_warning`, `emit_call_site_error` lack 1 form //! and do not take span in 2'th and 3'th forms. Those are essentially shortcuts for //! `macro!(Span::call_site(), args...)`. //! //! `diagnostic!` requires a [`Level`] instance between `span` and second argument //! (1'th form is the same). //! //! > **Important!** //! > //! > If you have some type from `proc_macro` or `syn` to point to, do not call `.span()` //! > on it but rather use it directly: //! > ```no_run //! > # use proc_macro_error::abort; //! > # let input = proc_macro2::TokenStream::new(); //! > let ty: syn::Type = syn::parse2(input).unwrap(); //! > abort!(ty, "BOOM"); //! > // ^^ <-- avoid .span() //! > ``` //! > //! > `.span()` calls work too, but you may experience regressions in message quality. //! //! #### Note attachments //! //! 3. Every macro can have "note" attachments (only 2 and 3 form). //! ```ignore //! let opt_help = if have_some_info { Some("did you mean `this`?") } else { None }; //! //! abort!( //! span, message; // <--- attachments start with `;` (semicolon) //! //! help = "format {} {}", "arg1", "arg2"; // <--- every attachment ends with `;`, //! // maybe except the last one //! //! note = "to_string"; // <--- one arg uses `.to_string()` instead of `format!()` //! //! yay = "I see what {} did here", "you"; // <--- "help =" and "hint =" are mapped //! // to Diagnostic::help, //! // anything else is Diagnostic::note //! //! wow = note_span => "custom span"; // <--- attachments can have their own span //! // it takes effect only on nightly though //! //! hint =? opt_help; // <-- "optional" attachment, get displayed only if `Some` //! // must be single `Option` expression //! //! note =? note_span => opt_help // <-- optional attachments can have custom spans too //! ); //! ``` //! //! ### Diagnostic type //! //! [`Diagnostic`] type is intentionally designed to be API compatible with [`proc_macro::Diagnostic`]. //! Not all API is implemented, only the part that can be reasonably implemented on stable. //! //! //! [`abort!`]: macro.abort.html //! [`abort_call_site!`]: macro.abort_call_site.html //! [`emit_warning!`]: macro.emit_warning.html //! [`emit_error!`]: macro.emit_error.html //! [`emit_call_site_warning!`]: macro.emit_call_site_error.html //! [`emit_call_site_error!`]: macro.emit_call_site_warning.html //! [`diagnostic!`]: macro.diagnostic.html //! [`Diagnostic`]: struct.Diagnostic.html //! //! [`proc_macro::Span`]: https://doc.rust-lang.org/proc_macro/struct.Span.html //! [`proc_macro::Diagnostic`]: https://doc.rust-lang.org/proc_macro/struct.Diagnostic.html //! //! [unwind safe]: https://doc.rust-lang.org/std/panic/trait.UnwindSafe.html#what-is-unwind-safety //! [`!`]: https://doc.rust-lang.org/std/primitive.never.html //! [`()`]: https://doc.rust-lang.org/std/primitive.unit.html //! [`ToString`]: https://doc.rust-lang.org/std/string/trait.ToString.html //! //! [`proc-macro2::Span`]: https://docs.rs/proc-macro2/1.0.10/proc_macro2/struct.Span.html //! [`ToTokens`]: https://docs.rs/quote/1.0.3/quote/trait.ToTokens.html //! #![cfg_attr(not(use_fallback), feature(proc_macro_diagnostic))] #![forbid(unsafe_code)] #![allow(clippy::needless_doctest_main)] extern crate proc_macro; pub use crate::{ diagnostic::{Diagnostic, DiagnosticExt, Level}, dummy::{append_dummy, set_dummy}, }; pub use proc_macro_error_attr::proc_macro_error; use proc_macro2::Span; use quote::{quote, ToTokens}; use std::cell::Cell; use std::panic::{catch_unwind, resume_unwind, UnwindSafe}; pub mod dummy; mod diagnostic; mod macros; mod sealed; #[cfg(use_fallback)] #[path = "imp/fallback.rs"] mod imp; #[cfg(not(use_fallback))] #[path = "imp/delegate.rs"] mod imp; #[derive(Debug, Clone, Copy)] pub struct SpanRange { pub first: Span, pub last: Span, } impl SpanRange { /// Create a range with the `first` and `last` spans being the same. pub fn single_span(span: Span) -> Self { SpanRange { first: span, last: span, } } /// Create a `SpanRange` resolving at call site. pub fn call_site() -> Self { SpanRange::single_span(Span::call_site()) } /// Construct span range from a `TokenStream`. This method always preserves all the /// range. /// /// ### Note /// /// If the stream is empty, the result is `SpanRange::call_site()`. If the stream /// consists of only one `TokenTree`, the result is `SpanRange::single_span(tt.span())` /// that doesn't lose anything. pub fn from_tokens(ts: &dyn ToTokens) -> Self { let mut spans = ts.to_token_stream().into_iter().map(|tt| tt.span()); let first = spans.next().unwrap_or_else(|| Span::call_site()); let last = spans.last().unwrap_or(first); SpanRange { first, last } } /// Join two span ranges. The resulting range will start at `self.first` and end at /// `other.last`. pub fn join_range(self, other: SpanRange) -> Self { SpanRange { first: self.first, last: other.last, } } /// Collapse the range into single span, preserving as much information as possible. pub fn collapse(self) -> Span { self.first.join(self.last).unwrap_or(self.first) } } /// This traits expands `Result>` with some handy shortcuts. pub trait ResultExt { type Ok; /// Behaves like `Result::unwrap`: if self is `Ok` yield the contained value, /// otherwise abort macro execution via `abort!`. fn unwrap_or_abort(self) -> Self::Ok; /// Behaves like `Result::expect`: if self is `Ok` yield the contained value, /// otherwise abort macro execution via `abort!`. /// If it aborts then resulting error message will be preceded with `message`. fn expect_or_abort(self, msg: &str) -> Self::Ok; } /// This traits expands `Option` with some handy shortcuts. pub trait OptionExt { type Some; /// Behaves like `Option::expect`: if self is `Some` yield the contained value, /// otherwise abort macro execution via `abort_call_site!`. /// If it aborts the `message` will be used for [`compile_error!`][compl_err] invocation. /// /// [compl_err]: https://doc.rust-lang.org/std/macro.compile_error.html fn expect_or_abort(self, msg: &str) -> Self::Some; } /// Abort macro execution and display all the emitted errors, if any. /// /// Does nothing if no errors were emitted (warnings do not count). pub fn abort_if_dirty() { imp::abort_if_dirty(); } impl> ResultExt for Result { type Ok = T; fn unwrap_or_abort(self) -> T { match self { Ok(res) => res, Err(e) => e.into().abort(), } } fn expect_or_abort(self, message: &str) -> T { match self { Ok(res) => res, Err(e) => { let mut e = e.into(); e.msg = format!("{}: {}", message, e.msg); e.abort() } } } } impl OptionExt for Option { type Some = T; fn expect_or_abort(self, message: &str) -> T { match self { Some(res) => res, None => abort_call_site!(message), } } } /// This is the entry point for a proc-macro. /// /// **NOT PUBLIC API, SUBJECT TO CHANGE WITHOUT ANY NOTICE** #[doc(hidden)] pub fn entry_point(f: F, proc_macro_hack: bool) -> proc_macro::TokenStream where F: FnOnce() -> proc_macro::TokenStream + UnwindSafe, { ENTERED_ENTRY_POINT.with(|flag| flag.set(flag.get() + 1)); let caught = catch_unwind(f); let dummy = dummy::cleanup(); let err_storage = imp::cleanup(); ENTERED_ENTRY_POINT.with(|flag| flag.set(flag.get() - 1)); let gen_error = || { if proc_macro_hack { quote! {{ macro_rules! proc_macro_call { () => ( unimplemented!() ) } #(#err_storage)* #dummy unimplemented!() }} } else { quote!( #(#err_storage)* #dummy ) } }; match caught { Ok(ts) => { if err_storage.is_empty() { ts } else { gen_error().into() } } Err(boxed) => match boxed.downcast::() { Ok(_) => gen_error().into(), Err(boxed) => resume_unwind(boxed), }, } } fn abort_now() -> ! { check_correctness(); panic!(AbortNow) } thread_local! { static ENTERED_ENTRY_POINT: Cell = Cell::new(0); } struct AbortNow; fn check_correctness() { if ENTERED_ENTRY_POINT.with(|flag| flag.get()) == 0 { panic!( "proc-macro-error API cannot be used outside of `entry_point` invocation, \ perhaps you forgot to annotate your #[proc_macro] function with `#[proc_macro_error]" ); } } /// **ALL THE STUFF INSIDE IS NOT PUBLIC API!!!** #[doc(hidden)] pub mod __export { // reexports for use in macros pub extern crate proc_macro; pub extern crate proc_macro2; use proc_macro2::Span; use quote::ToTokens; use crate::SpanRange; // inspired by // https://github.com/dtolnay/case-studies/blob/master/autoref-specialization/README.md#simple-application pub trait SpanAsSpanRange { #[allow(non_snake_case)] fn FIRST_ARG_MUST_EITHER_BE_Span_OR_IMPLEMENT_ToTokens_OR_BE_SpanRange(&self) -> SpanRange; } pub trait Span2AsSpanRange { #[allow(non_snake_case)] fn FIRST_ARG_MUST_EITHER_BE_Span_OR_IMPLEMENT_ToTokens_OR_BE_SpanRange(&self) -> SpanRange; } pub trait ToTokensAsSpanRange { #[allow(non_snake_case)] fn FIRST_ARG_MUST_EITHER_BE_Span_OR_IMPLEMENT_ToTokens_OR_BE_SpanRange(&self) -> SpanRange; } pub trait SpanRangeAsSpanRange { #[allow(non_snake_case)] fn FIRST_ARG_MUST_EITHER_BE_Span_OR_IMPLEMENT_ToTokens_OR_BE_SpanRange(&self) -> SpanRange; } impl ToTokensAsSpanRange for &T { fn FIRST_ARG_MUST_EITHER_BE_Span_OR_IMPLEMENT_ToTokens_OR_BE_SpanRange(&self) -> SpanRange { let mut ts = self.to_token_stream().into_iter(); let first = ts .next() .map(|tt| tt.span()) .unwrap_or_else(Span::call_site); let last = ts.last().map(|tt| tt.span()).unwrap_or(first); SpanRange { first, last } } } impl Span2AsSpanRange for Span { fn FIRST_ARG_MUST_EITHER_BE_Span_OR_IMPLEMENT_ToTokens_OR_BE_SpanRange(&self) -> SpanRange { SpanRange { first: *self, last: *self, } } } impl SpanAsSpanRange for proc_macro::Span { fn FIRST_ARG_MUST_EITHER_BE_Span_OR_IMPLEMENT_ToTokens_OR_BE_SpanRange(&self) -> SpanRange { SpanRange { first: self.clone().into(), last: self.clone().into(), } } } impl SpanRangeAsSpanRange for SpanRange { fn FIRST_ARG_MUST_EITHER_BE_Span_OR_IMPLEMENT_ToTokens_OR_BE_SpanRange(&self) -> SpanRange { *self } } }