comm-central/third_party/rust/syn/src/meta.rs

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//! Facility for interpreting structured content inside of an `Attribute`.
use crate::ext::IdentExt as _;
use crate::lit::Lit;
use crate::parse::{Error, ParseStream, Parser, Result};
use crate::path::{Path, PathSegment};
use crate::punctuated::Punctuated;
use proc_macro2::Ident;
use std::fmt::Display;
/// Make a parser that is usable with `parse_macro_input!` in a
/// `#[proc_macro_attribute]` macro.
///
/// *Warning:* When parsing attribute args **other than** the
/// `proc_macro::TokenStream` input of a `proc_macro_attribute`, you do **not**
/// need this function. In several cases your callers will get worse error
/// messages if you use this function, because the surrounding delimiter's span
/// is concealed from attribute macros by rustc. Use
/// [`Attribute::parse_nested_meta`] instead.
///
/// [`Attribute::parse_nested_meta`]: crate::Attribute::parse_nested_meta
///
/// # Example
///
/// This example implements an attribute macro whose invocations look like this:
///
/// ```
/// # const IGNORE: &str = stringify! {
/// #[tea(kind = "EarlGrey", hot)]
/// struct Picard {...}
/// # };
/// ```
///
/// The "parameters" supported by the attribute are:
///
/// - `kind = "..."`
/// - `hot`
/// - `with(sugar, milk, ...)`, a comma-separated list of ingredients
///
/// ```
/// # extern crate proc_macro;
/// #
/// use proc_macro::TokenStream;
/// use syn::{parse_macro_input, LitStr, Path};
///
/// # const IGNORE: &str = stringify! {
/// #[proc_macro_attribute]
/// # };
/// pub fn tea(args: TokenStream, input: TokenStream) -> TokenStream {
/// let mut kind: Option<LitStr> = None;
/// let mut hot: bool = false;
/// let mut with: Vec<Path> = Vec::new();
/// let tea_parser = syn::meta::parser(|meta| {
/// if meta.path.is_ident("kind") {
/// kind = Some(meta.value()?.parse()?);
/// Ok(())
/// } else if meta.path.is_ident("hot") {
/// hot = true;
/// Ok(())
/// } else if meta.path.is_ident("with") {
/// meta.parse_nested_meta(|meta| {
/// with.push(meta.path);
/// Ok(())
/// })
/// } else {
/// Err(meta.error("unsupported tea property"))
/// }
/// });
///
/// parse_macro_input!(args with tea_parser);
/// eprintln!("kind={kind:?} hot={hot} with={with:?}");
///
/// /* ... */
/// # TokenStream::new()
/// }
/// ```
///
/// The `syn::meta` library will take care of dealing with the commas including
/// trailing commas, and producing sensible error messages on unexpected input.
///
/// ```console
/// error: expected `,`
/// --> src/main.rs:3:37
/// |
/// 3 | #[tea(kind = "EarlGrey", with(sugar = "lol", milk))]
/// | ^
/// ```
///
/// # Example
///
/// Same as above but we factor out most of the logic into a separate function.
///
/// ```
/// # extern crate proc_macro;
/// #
/// use proc_macro::TokenStream;
/// use syn::meta::ParseNestedMeta;
/// use syn::parse::{Parser, Result};
/// use syn::{parse_macro_input, LitStr, Path};
///
/// # const IGNORE: &str = stringify! {
/// #[proc_macro_attribute]
/// # };
/// pub fn tea(args: TokenStream, input: TokenStream) -> TokenStream {
/// let mut attrs = TeaAttributes::default();
/// let tea_parser = syn::meta::parser(|meta| attrs.parse(meta));
/// parse_macro_input!(args with tea_parser);
///
/// /* ... */
/// # TokenStream::new()
/// }
///
/// #[derive(Default)]
/// struct TeaAttributes {
/// kind: Option<LitStr>,
/// hot: bool,
/// with: Vec<Path>,
/// }
///
/// impl TeaAttributes {
/// fn parse(&mut self, meta: ParseNestedMeta) -> Result<()> {
/// if meta.path.is_ident("kind") {
/// self.kind = Some(meta.value()?.parse()?);
/// Ok(())
/// } else /* just like in last example */
/// # { unimplemented!() }
///
/// }
/// }
/// ```
pub fn parser(logic: impl FnMut(ParseNestedMeta) -> Result<()>) -> impl Parser<Output = ()> {
|input: ParseStream| {
if input.is_empty() {
Ok(())
} else {
parse_nested_meta(input, logic)
}
}
}
/// Context for parsing a single property in the conventional syntax for
/// structured attributes.
///
/// # Examples
///
/// Refer to usage examples on the following two entry-points:
///
/// - [`Attribute::parse_nested_meta`] if you have an entire `Attribute` to
/// parse. Always use this if possible. Generally this is able to produce
/// better error messages because `Attribute` holds span information for all
/// of the delimiters therein.
///
/// - [`syn::meta::parser`] if you are implementing a `proc_macro_attribute`
/// macro and parsing the arguments to the attribute macro, i.e. the ones
/// written in the same attribute that dispatched the macro invocation. Rustc
/// does not pass span information for the surrounding delimiters into the
/// attribute macro invocation in this situation, so error messages might be
/// less precise.
///
/// [`Attribute::parse_nested_meta`]: crate::Attribute::parse_nested_meta
/// [`syn::meta::parser`]: crate::meta::parser
#[non_exhaustive]
pub struct ParseNestedMeta<'a> {
pub path: Path,
pub input: ParseStream<'a>,
}
impl<'a> ParseNestedMeta<'a> {
/// Used when parsing `key = "value"` syntax.
///
/// All it does is advance `meta.input` past the `=` sign in the input. You
/// could accomplish the same effect by writing
/// `meta.parse::<Token![=]>()?`, so at most it is a minor convenience to
/// use `meta.value()?`.
///
/// # Example
///
/// ```
/// use syn::{parse_quote, Attribute, LitStr};
///
/// let attr: Attribute = parse_quote! {
/// #[tea(kind = "EarlGrey")]
/// };
/// // conceptually:
/// if attr.path().is_ident("tea") { // this parses the `tea`
/// attr.parse_nested_meta(|meta| { // this parses the `(`
/// if meta.path.is_ident("kind") { // this parses the `kind`
/// let value = meta.value()?; // this parses the `=`
/// let s: LitStr = value.parse()?; // this parses `"EarlGrey"`
/// if s.value() == "EarlGrey" {
/// // ...
/// }
/// Ok(())
/// } else {
/// Err(meta.error("unsupported attribute"))
/// }
/// })?;
/// }
/// # anyhow::Ok(())
/// ```
pub fn value(&self) -> Result<ParseStream<'a>> {
self.input.parse::<Token![=]>()?;
Ok(self.input)
}
/// Used when parsing `list(...)` syntax **if** the content inside the
/// nested parentheses is also expected to conform to Rust's structured
/// attribute convention.
///
/// # Example
///
/// ```
/// use syn::{parse_quote, Attribute};
///
/// let attr: Attribute = parse_quote! {
/// #[tea(with(sugar, milk))]
/// };
///
/// if attr.path().is_ident("tea") {
/// attr.parse_nested_meta(|meta| {
/// if meta.path.is_ident("with") {
/// meta.parse_nested_meta(|meta| { // <---
/// if meta.path.is_ident("sugar") {
/// // Here we can go even deeper if needed.
/// Ok(())
/// } else if meta.path.is_ident("milk") {
/// Ok(())
/// } else {
/// Err(meta.error("unsupported ingredient"))
/// }
/// })
/// } else {
/// Err(meta.error("unsupported tea property"))
/// }
/// })?;
/// }
/// # anyhow::Ok(())
/// ```
///
/// # Counterexample
///
/// If you don't need `parse_nested_meta`'s help in parsing the content
/// written within the nested parentheses, keep in mind that you can always
/// just parse it yourself from the exposed ParseStream. Rust syntax permits
/// arbitrary tokens within those parentheses so for the crazier stuff,
/// `parse_nested_meta` is not what you want.
///
/// ```
/// use syn::{parenthesized, parse_quote, Attribute, LitInt};
///
/// let attr: Attribute = parse_quote! {
/// #[repr(align(32))]
/// };
///
/// let mut align: Option<LitInt> = None;
/// if attr.path().is_ident("repr") {
/// attr.parse_nested_meta(|meta| {
/// if meta.path.is_ident("align") {
/// let content;
/// parenthesized!(content in meta.input);
/// align = Some(content.parse()?);
/// Ok(())
/// } else {
/// Err(meta.error("unsupported repr"))
/// }
/// })?;
/// }
/// # anyhow::Ok(())
/// ```
pub fn parse_nested_meta(
&self,
logic: impl FnMut(ParseNestedMeta) -> Result<()>,
) -> Result<()> {
let content;
parenthesized!(content in self.input);
parse_nested_meta(&content, logic)
}
/// Report that the attribute's content did not conform to expectations.
///
/// The span of the resulting error will cover `meta.path` *and* everything
/// that has been parsed so far since it.
///
/// There are 2 ways you might call this. First, if `meta.path` is not
/// something you recognize:
///
/// ```
/// # use syn::Attribute;
/// #
/// # fn example(attr: &Attribute) -> syn::Result<()> {
/// attr.parse_nested_meta(|meta| {
/// if meta.path.is_ident("kind") {
/// // ...
/// Ok(())
/// } else {
/// Err(meta.error("unsupported tea property"))
/// }
/// })?;
/// # Ok(())
/// # }
/// ```
///
/// In this case, it behaves exactly like
/// `syn::Error::new_spanned(&meta.path, "message...")`.
///
/// ```console
/// error: unsupported tea property
/// --> src/main.rs:3:26
/// |
/// 3 | #[tea(kind = "EarlGrey", wat = "foo")]
/// | ^^^
/// ```
///
/// More usefully, the second place is if you've already parsed a value but
/// have decided not to accept the value:
///
/// ```
/// # use syn::Attribute;
/// #
/// # fn example(attr: &Attribute) -> syn::Result<()> {
/// use syn::Expr;
///
/// attr.parse_nested_meta(|meta| {
/// if meta.path.is_ident("kind") {
/// let expr: Expr = meta.value()?.parse()?;
/// match expr {
/// Expr::Lit(expr) => /* ... */
/// # unimplemented!(),
/// Expr::Path(expr) => /* ... */
/// # unimplemented!(),
/// Expr::Macro(expr) => /* ... */
/// # unimplemented!(),
/// _ => Err(meta.error("tea kind must be a string literal, path, or macro")),
/// }
/// } else /* as above */
/// # { unimplemented!() }
///
/// })?;
/// # Ok(())
/// # }
/// ```
///
/// ```console
/// error: tea kind must be a string literal, path, or macro
/// --> src/main.rs:3:7
/// |
/// 3 | #[tea(kind = async { replicator.await })]
/// | ^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^
/// ```
///
/// Often you may want to use `syn::Error::new_spanned` even in this
/// situation. In the above code, that would be:
///
/// ```
/// # use syn::{Error, Expr};
/// #
/// # fn example(expr: Expr) -> syn::Result<()> {
/// match expr {
/// Expr::Lit(expr) => /* ... */
/// # unimplemented!(),
/// Expr::Path(expr) => /* ... */
/// # unimplemented!(),
/// Expr::Macro(expr) => /* ... */
/// # unimplemented!(),
/// _ => Err(Error::new_spanned(expr, "unsupported expression type for `kind`")),
/// }
/// # }
/// ```
///
/// ```console
/// error: unsupported expression type for `kind`
/// --> src/main.rs:3:14
/// |
/// 3 | #[tea(kind = async { replicator.await })]
/// | ^^^^^^^^^^^^^^^^^^^^^^^^^^
/// ```
pub fn error(&self, msg: impl Display) -> Error {
let start_span = self.path.segments[0].ident.span();
let end_span = self.input.cursor().prev_span();
crate::error::new2(start_span, end_span, msg)
}
}
pub(crate) fn parse_nested_meta(
input: ParseStream,
mut logic: impl FnMut(ParseNestedMeta) -> Result<()>,
) -> Result<()> {
loop {
let path = input.call(parse_meta_path)?;
logic(ParseNestedMeta { path, input })?;
if input.is_empty() {
return Ok(());
}
input.parse::<Token![,]>()?;
if input.is_empty() {
return Ok(());
}
}
}
// Like Path::parse_mod_style, but accepts keywords in the path.
fn parse_meta_path(input: ParseStream) -> Result<Path> {
Ok(Path {
leading_colon: input.parse()?,
segments: {
let mut segments = Punctuated::new();
if input.peek(Ident::peek_any) {
let ident = Ident::parse_any(input)?;
segments.push_value(PathSegment::from(ident));
} else if input.is_empty() {
return Err(input.error("expected nested attribute"));
} else if input.peek(Lit) {
return Err(input.error("unexpected literal in nested attribute, expected ident"));
} else {
return Err(input.error("unexpected token in nested attribute, expected ident"));
}
while input.peek(Token![::]) {
let punct = input.parse()?;
segments.push_punct(punct);
let ident = Ident::parse_any(input)?;
segments.push_value(PathSegment::from(ident));
}
segments
},
})
}