rust/macros/helpers.rs - linux - Git at Google

 // SPDX-License-Identifier: GPL-2.0

 use proc_macro::{token_stream, Group, TokenStream, TokenTree};

 pub(crate) fn try_ident(it: &mut token_stream::IntoIter) -> Option<String> {
     if let Some(TokenTree::Ident(ident)) = it.next() {
         Some(ident.to_string())
     } else {
         None
     }
 }

 pub(crate) fn try_literal(it: &mut token_stream::IntoIter) -> Option<String> {
     if let Some(TokenTree::Literal(literal)) = it.next() {
         Some(literal.to_string())
     } else {
         None
     }
 }

 pub(crate) fn try_string(it: &mut token_stream::IntoIter) -> Option<String> {
     try_literal(it).and_then(|string| {
         if string.starts_with('\"') && string.ends_with('\"') {
             let content = &string[1..string.len() - 1];
             if content.contains('\\') {
                 panic!("Escape sequences in string literals not yet handled");
             }
             Some(content.to_string())
         } else if string.starts_with("r\"") {
             panic!("Raw string literals are not yet handled");
         } else {
             None
         }
     })
 }

 pub(crate) fn expect_ident(it: &mut token_stream::IntoIter) -> String {
     try_ident(it).expect("Expected Ident")
 }

 pub(crate) fn expect_punct(it: &mut token_stream::IntoIter) -> char {
     if let TokenTree::Punct(punct) = it.next().expect("Reached end of token stream for Punct") {
         punct.as_char()
     } else {
         panic!("Expected Punct");
     }
 }

 pub(crate) fn expect_string(it: &mut token_stream::IntoIter) -> String {
     try_string(it).expect("Expected string")
 }

 pub(crate) fn expect_string_ascii(it: &mut token_stream::IntoIter) -> String {
     let string = try_string(it).expect("Expected string");
     assert!(string.is_ascii(), "Expected ASCII string");
     string
 }

 pub(crate) fn expect_group(it: &mut token_stream::IntoIter) -> Group {
     if let TokenTree::Group(group) = it.next().expect("Reached end of token stream for Group") {
         group
     } else {
         panic!("Expected Group");
     }
 }

 pub(crate) fn expect_end(it: &mut token_stream::IntoIter) {
     if it.next().is_some() {
         panic!("Expected end");
     }
 }

 /// Parsed generics.
 ///
 /// See the field documentation for an explanation what each of the fields represents.
 ///
 /// # Examples
 ///
 /// ```rust,ignore
 /// # let input = todo!();
 /// let (Generics { decl_generics, impl_generics, ty_generics }, rest) = parse_generics(input);
 /// quote! {
 ///     struct Foo<$($decl_generics)*> {
 ///         // ...
 ///     }
 ///
 ///     impl<$impl_generics> Foo<$ty_generics> {
 ///         fn foo() {
 ///             // ...
 ///         }
 ///     }
 /// }
 /// ```
 pub(crate) struct Generics {
     /// The generics with bounds and default values (e.g. `T: Clone, const N: usize = 0`).
     ///
     /// Use this on type definitions e.g. `struct Foo<$decl_generics> ...` (or `union`/`enum`).
     pub(crate) decl_generics: Vec<TokenTree>,
     /// The generics with bounds (e.g. `T: Clone, const N: usize`).
     ///
     /// Use this on `impl` blocks e.g. `impl<$impl_generics> Trait for ...`.
     pub(crate) impl_generics: Vec<TokenTree>,
     /// The generics without bounds and without default values (e.g. `T, N`).
     ///
     /// Use this when you use the type that is declared with these generics e.g.
     /// `Foo<$ty_generics>`.
     pub(crate) ty_generics: Vec<TokenTree>,
 }

 /// Parses the given `TokenStream` into `Generics` and the rest.
 ///
 /// The generics are not present in the rest, but a where clause might remain.
 pub(crate) fn parse_generics(input: TokenStream) -> (Generics, Vec<TokenTree>) {
     // The generics with bounds and default values.
     let mut decl_generics = vec![];
     // `impl_generics`, the declared generics with their bounds.
     let mut impl_generics = vec![];
     // Only the names of the generics, without any bounds.
     let mut ty_generics = vec![];
     // Tokens not related to the generics e.g. the `where` token and definition.
     let mut rest = vec![];
     // The current level of `<`.
     let mut nesting = 0;
     let mut toks = input.into_iter();
     // If we are at the beginning of a generic parameter.
     let mut at_start = true;
     let mut skip_until_comma = false;
     while let Some(tt) = toks.next() {
         if nesting == 1 && matches!(&tt, TokenTree::Punct(p) if p.as_char() == '>') {
             // Found the end of the generics.
             break;
         } else if nesting >= 1 {
             decl_generics.push(tt.clone());
         }
         match tt.clone() {
             TokenTree::Punct(p) if p.as_char() == '<' => {
                 if nesting >= 1 && !skip_until_comma {
                     // This is inside of the generics and part of some bound.
                     impl_generics.push(tt);
                 }
                 nesting += 1;
             }
             TokenTree::Punct(p) if p.as_char() == '>' => {
                 // This is a parsing error, so we just end it here.
                 if nesting == 0 {
                     break;
                 } else {
                     nesting -= 1;
                     if nesting >= 1 && !skip_until_comma {
                         // We are still inside of the generics and part of some bound.
                         impl_generics.push(tt);
                     }
                 }
             }
             TokenTree::Punct(p) if skip_until_comma && p.as_char() == ',' => {
                 if nesting == 1 {
                     impl_generics.push(tt.clone());
                     impl_generics.push(tt);
                     skip_until_comma = false;
                 }
             }
             _ if !skip_until_comma => {
                 match nesting {
                     // If we haven't entered the generics yet, we still want to keep these tokens.
                     0 => rest.push(tt),
                     1 => {
                         // Here depending on the token, it might be a generic variable name.
                         match tt.clone() {
                             TokenTree::Ident(i) if at_start && i.to_string() == "const" => {
                                 let Some(name) = toks.next() else {
                                     // Parsing error.
                                     break;
                                 };
                                 impl_generics.push(tt);
                                 impl_generics.push(name.clone());
                                 ty_generics.push(name.clone());
                                 decl_generics.push(name);
                                 at_start = false;
                             }
                             TokenTree::Ident(_) if at_start => {
                                 impl_generics.push(tt.clone());
                                 ty_generics.push(tt);
                                 at_start = false;
                             }
                             TokenTree::Punct(p) if p.as_char() == ',' => {
                                 impl_generics.push(tt.clone());
                                 ty_generics.push(tt);
                                 at_start = true;
                             }
                             // Lifetimes begin with `'`.
                             TokenTree::Punct(p) if p.as_char() == '\'' && at_start => {
                                 impl_generics.push(tt.clone());
                                 ty_generics.push(tt);
                             }
                             // Generics can have default values, we skip these.
                             TokenTree::Punct(p) if p.as_char() == '=' => {
                                 skip_until_comma = true;
                             }
                             _ => impl_generics.push(tt),
                         }
                     }
                     _ => impl_generics.push(tt),
                 }
             }
             _ => {}
         }
     }
     rest.extend(toks);
     (
         Generics {
             impl_generics,
             decl_generics,
             ty_generics,
         },
         rest,
     )
 }
	// SPDX-License-Identifier: GPL-2.0

	use proc_macro::{token_stream, Group, TokenStream, TokenTree};

	pub(crate) fn try_ident(it: &mut token_stream::IntoIter) -> Option<String> {
	if let Some(TokenTree::Ident(ident)) = it.next() {
	Some(ident.to_string())
	} else {
	None
	}
	}

	pub(crate) fn try_literal(it: &mut token_stream::IntoIter) -> Option<String> {
	if let Some(TokenTree::Literal(literal)) = it.next() {
	Some(literal.to_string())
	} else {
	None
	}
	}

	pub(crate) fn try_string(it: &mut token_stream::IntoIter) -> Option<String> {
	try_literal(it).and_then(\|string\| {
	if string.starts_with('\"') && string.ends_with('\"') {
	let content = &string[1..string.len() - 1];
	if content.contains('\\') {
	panic!("Escape sequences in string literals not yet handled");
	}
	Some(content.to_string())
	} else if string.starts_with("r\"") {
	panic!("Raw string literals are not yet handled");
	} else {
	None
	}
	})
	}

	pub(crate) fn expect_ident(it: &mut token_stream::IntoIter) -> String {
	try_ident(it).expect("Expected Ident")
	}

	pub(crate) fn expect_punct(it: &mut token_stream::IntoIter) -> char {
	if let TokenTree::Punct(punct) = it.next().expect("Reached end of token stream for Punct") {
	punct.as_char()
	} else {
	panic!("Expected Punct");
	}
	}

	pub(crate) fn expect_string(it: &mut token_stream::IntoIter) -> String {
	try_string(it).expect("Expected string")
	}

	pub(crate) fn expect_string_ascii(it: &mut token_stream::IntoIter) -> String {
	let string = try_string(it).expect("Expected string");
	assert!(string.is_ascii(), "Expected ASCII string");
	string
	}

	pub(crate) fn expect_group(it: &mut token_stream::IntoIter) -> Group {
	if let TokenTree::Group(group) = it.next().expect("Reached end of token stream for Group") {
	group
	} else {
	panic!("Expected Group");
	}
	}

	pub(crate) fn expect_end(it: &mut token_stream::IntoIter) {
	if it.next().is_some() {
	panic!("Expected end");
	}
	}

	/// Parsed generics.
	///
	/// See the field documentation for an explanation what each of the fields represents.
	///
	/// # Examples
	///
	/// ```rust,ignore
	/// # let input = todo!();
	/// let (Generics { decl_generics, impl_generics, ty_generics }, rest) = parse_generics(input);
	/// quote! {
	/// struct Foo<$($decl_generics)*> {
	/// // ...
	/// }
	///
	/// impl<$impl_generics> Foo<$ty_generics> {
	/// fn foo() {
	/// // ...
	/// }
	/// }
	/// }
	/// ```
	pub(crate) struct Generics {
	/// The generics with bounds and default values (e.g. `T: Clone, const N: usize = 0`).
	///
	/// Use this on type definitions e.g. `struct Foo<$decl_generics> ...` (or `union`/`enum`).
	pub(crate) decl_generics: Vec<TokenTree>,
	/// The generics with bounds (e.g. `T: Clone, const N: usize`).
	///
	/// Use this on `impl` blocks e.g. `impl<$impl_generics> Trait for ...`.
	pub(crate) impl_generics: Vec<TokenTree>,
	/// The generics without bounds and without default values (e.g. `T, N`).
	///
	/// Use this when you use the type that is declared with these generics e.g.
	/// `Foo<$ty_generics>`.
	pub(crate) ty_generics: Vec<TokenTree>,
	}

	/// Parses the given `TokenStream` into `Generics` and the rest.
	///
	/// The generics are not present in the rest, but a where clause might remain.
	pub(crate) fn parse_generics(input: TokenStream) -> (Generics, Vec<TokenTree>) {
	// The generics with bounds and default values.
	let mut decl_generics = vec![];
	// `impl_generics`, the declared generics with their bounds.
	let mut impl_generics = vec![];
	// Only the names of the generics, without any bounds.
	let mut ty_generics = vec![];
	// Tokens not related to the generics e.g. the `where` token and definition.
	let mut rest = vec![];
	// The current level of `<`.
	let mut nesting = 0;
	let mut toks = input.into_iter();
	// If we are at the beginning of a generic parameter.
	let mut at_start = true;
	let mut skip_until_comma = false;
	while let Some(tt) = toks.next() {
	if nesting == 1 && matches!(&tt, TokenTree::Punct(p) if p.as_char() == '>') {
	// Found the end of the generics.
	break;
	} else if nesting >= 1 {
	decl_generics.push(tt.clone());
	}
	match tt.clone() {
	TokenTree::Punct(p) if p.as_char() == '<' => {
	if nesting >= 1 && !skip_until_comma {
	// This is inside of the generics and part of some bound.
	impl_generics.push(tt);
	}
	nesting += 1;
	}
	TokenTree::Punct(p) if p.as_char() == '>' => {
	// This is a parsing error, so we just end it here.
	if nesting == 0 {
	break;
	} else {
	nesting -= 1;
	if nesting >= 1 && !skip_until_comma {
	// We are still inside of the generics and part of some bound.
	impl_generics.push(tt);
	}
	}
	}
	TokenTree::Punct(p) if skip_until_comma && p.as_char() == ',' => {
	if nesting == 1 {
	impl_generics.push(tt.clone());
	impl_generics.push(tt);
	skip_until_comma = false;
	}
	}
	_ if !skip_until_comma => {
	match nesting {
	// If we haven't entered the generics yet, we still want to keep these tokens.
	0 => rest.push(tt),
	1 => {
	// Here depending on the token, it might be a generic variable name.
	match tt.clone() {
	TokenTree::Ident(i) if at_start && i.to_string() == "const" => {
	let Some(name) = toks.next() else {
	// Parsing error.
	break;
	};
	impl_generics.push(tt);
	impl_generics.push(name.clone());
	ty_generics.push(name.clone());
	decl_generics.push(name);
	at_start = false;
	}
	TokenTree::Ident(_) if at_start => {
	impl_generics.push(tt.clone());
	ty_generics.push(tt);
	at_start = false;
	}
	TokenTree::Punct(p) if p.as_char() == ',' => {
	impl_generics.push(tt.clone());
	ty_generics.push(tt);
	at_start = true;
	}
	// Lifetimes begin with `'`.
	TokenTree::Punct(p) if p.as_char() == '\'' && at_start => {
	impl_generics.push(tt.clone());
	ty_generics.push(tt);
	}
	// Generics can have default values, we skip these.
	TokenTree::Punct(p) if p.as_char() == '=' => {
	skip_until_comma = true;
	}
	_ => impl_generics.push(tt),
	}
	}
	_ => impl_generics.push(tt),
	}
	}
	_ => {}
	}
	}
	rest.extend(toks);
	(
	Generics {
	impl_generics,
	decl_generics,
	ty_generics,
	},
	rest,
	)
	}