third_party/rust_crates/vendor/syn/src/op.rs - fuchsia - Git at Google

 ast_enum! {
     /// A binary operator: `+`, `+=`, `&`.
     ///
     /// *This type is available only if Syn is built with the `"derive"` or `"full"`
     /// feature.*
     pub enum BinOp {
         /// The `+` operator (addition)
         Add(Token![+]),
         /// The `-` operator (subtraction)
         Sub(Token![-]),
         /// The `*` operator (multiplication)
         Mul(Token![*]),
         /// The `/` operator (division)
         Div(Token![/]),
         /// The `%` operator (modulus)
         Rem(Token![%]),
         /// The `&&` operator (logical and)
         And(Token![&&]),
         /// The `||` operator (logical or)
         Or(Token![||]),
         /// The `^` operator (bitwise xor)
         BitXor(Token![^]),
         /// The `&` operator (bitwise and)
         BitAnd(Token![&]),
         /// The `|` operator (bitwise or)
         BitOr(Token![|]),
         /// The `<<` operator (shift left)
         Shl(Token![<<]),
         /// The `>>` operator (shift right)
         Shr(Token![>>]),
         /// The `==` operator (equality)
         Eq(Token![==]),
         /// The `<` operator (less than)
         Lt(Token![<]),
         /// The `<=` operator (less than or equal to)
         Le(Token![<=]),
         /// The `!=` operator (not equal to)
         Ne(Token![!=]),
         /// The `>=` operator (greater than or equal to)
         Ge(Token![>=]),
         /// The `>` operator (greater than)
         Gt(Token![>]),
         /// The `+=` operator
         AddEq(Token![+=]),
         /// The `-=` operator
         SubEq(Token![-=]),
         /// The `*=` operator
         MulEq(Token![*=]),
         /// The `/=` operator
         DivEq(Token![/=]),
         /// The `%=` operator
         RemEq(Token![%=]),
         /// The `^=` operator
         BitXorEq(Token![^=]),
         /// The `&=` operator
         BitAndEq(Token![&=]),
         /// The `|=` operator
         BitOrEq(Token![|=]),
         /// The `<<=` operator
         ShlEq(Token![<<=]),
         /// The `>>=` operator
         ShrEq(Token![>>=]),
     }
 }

 ast_enum! {
     /// A unary operator: `*`, `!`, `-`.
     ///
     /// *This type is available only if Syn is built with the `"derive"` or `"full"`
     /// feature.*
     pub enum UnOp {
         /// The `*` operator for dereferencing
         Deref(Token![*]),
         /// The `!` operator for logical inversion
         Not(Token![!]),
         /// The `-` operator for negation
         Neg(Token![-]),
     }
 }

 #[cfg(feature = "parsing")]
 pub mod parsing {
     use super::*;
     use crate::parse::{Parse, ParseStream, Result};

     fn parse_binop(input: ParseStream) -> Result<BinOp> {
         if input.peek(Token![&&]) {
             input.parse().map(BinOp::And)
         } else if input.peek(Token![||]) {
             input.parse().map(BinOp::Or)
         } else if input.peek(Token![<<]) {
             input.parse().map(BinOp::Shl)
         } else if input.peek(Token![>>]) {
             input.parse().map(BinOp::Shr)
         } else if input.peek(Token![==]) {
             input.parse().map(BinOp::Eq)
         } else if input.peek(Token![<=]) {
             input.parse().map(BinOp::Le)
         } else if input.peek(Token![!=]) {
             input.parse().map(BinOp::Ne)
         } else if input.peek(Token![>=]) {
             input.parse().map(BinOp::Ge)
         } else if input.peek(Token![+]) {
             input.parse().map(BinOp::Add)
         } else if input.peek(Token![-]) {
             input.parse().map(BinOp::Sub)
         } else if input.peek(Token![*]) {
             input.parse().map(BinOp::Mul)
         } else if input.peek(Token![/]) {
             input.parse().map(BinOp::Div)
         } else if input.peek(Token![%]) {
             input.parse().map(BinOp::Rem)
         } else if input.peek(Token![^]) {
             input.parse().map(BinOp::BitXor)
         } else if input.peek(Token![&]) {
             input.parse().map(BinOp::BitAnd)
         } else if input.peek(Token![|]) {
             input.parse().map(BinOp::BitOr)
         } else if input.peek(Token![<]) {
             input.parse().map(BinOp::Lt)
         } else if input.peek(Token![>]) {
             input.parse().map(BinOp::Gt)
         } else {
             Err(input.error("expected binary operator"))
         }
     }

     impl Parse for BinOp {
         #[cfg(not(feature = "full"))]
         fn parse(input: ParseStream) -> Result<Self> {
             parse_binop(input)
         }

         #[cfg(feature = "full")]
         fn parse(input: ParseStream) -> Result<Self> {
             if input.peek(Token![+=]) {
                 input.parse().map(BinOp::AddEq)
             } else if input.peek(Token![-=]) {
                 input.parse().map(BinOp::SubEq)
             } else if input.peek(Token![*=]) {
                 input.parse().map(BinOp::MulEq)
             } else if input.peek(Token![/=]) {
                 input.parse().map(BinOp::DivEq)
             } else if input.peek(Token![%=]) {
                 input.parse().map(BinOp::RemEq)
             } else if input.peek(Token![^=]) {
                 input.parse().map(BinOp::BitXorEq)
             } else if input.peek(Token![&=]) {
                 input.parse().map(BinOp::BitAndEq)
             } else if input.peek(Token![|=]) {
                 input.parse().map(BinOp::BitOrEq)
             } else if input.peek(Token![<<=]) {
                 input.parse().map(BinOp::ShlEq)
             } else if input.peek(Token![>>=]) {
                 input.parse().map(BinOp::ShrEq)
             } else {
                 parse_binop(input)
             }
         }
     }

     impl Parse for UnOp {
         fn parse(input: ParseStream) -> Result<Self> {
             let lookahead = input.lookahead1();
             if lookahead.peek(Token![*]) {
                 input.parse().map(UnOp::Deref)
             } else if lookahead.peek(Token![!]) {
                 input.parse().map(UnOp::Not)
             } else if lookahead.peek(Token![-]) {
                 input.parse().map(UnOp::Neg)
             } else {
                 Err(lookahead.error())
             }
         }
     }
 }

 #[cfg(feature = "printing")]
 mod printing {
     use super::*;
     use proc_macro2::TokenStream;
     use quote::ToTokens;

     impl ToTokens for BinOp {
         fn to_tokens(&self, tokens: &mut TokenStream) {
             match self {
                 BinOp::Add(t) => t.to_tokens(tokens),
                 BinOp::Sub(t) => t.to_tokens(tokens),
                 BinOp::Mul(t) => t.to_tokens(tokens),
                 BinOp::Div(t) => t.to_tokens(tokens),
                 BinOp::Rem(t) => t.to_tokens(tokens),
                 BinOp::And(t) => t.to_tokens(tokens),
                 BinOp::Or(t) => t.to_tokens(tokens),
                 BinOp::BitXor(t) => t.to_tokens(tokens),
                 BinOp::BitAnd(t) => t.to_tokens(tokens),
                 BinOp::BitOr(t) => t.to_tokens(tokens),
                 BinOp::Shl(t) => t.to_tokens(tokens),
                 BinOp::Shr(t) => t.to_tokens(tokens),
                 BinOp::Eq(t) => t.to_tokens(tokens),
                 BinOp::Lt(t) => t.to_tokens(tokens),
                 BinOp::Le(t) => t.to_tokens(tokens),
                 BinOp::Ne(t) => t.to_tokens(tokens),
                 BinOp::Ge(t) => t.to_tokens(tokens),
                 BinOp::Gt(t) => t.to_tokens(tokens),
                 BinOp::AddEq(t) => t.to_tokens(tokens),
                 BinOp::SubEq(t) => t.to_tokens(tokens),
                 BinOp::MulEq(t) => t.to_tokens(tokens),
                 BinOp::DivEq(t) => t.to_tokens(tokens),
                 BinOp::RemEq(t) => t.to_tokens(tokens),
                 BinOp::BitXorEq(t) => t.to_tokens(tokens),
                 BinOp::BitAndEq(t) => t.to_tokens(tokens),
                 BinOp::BitOrEq(t) => t.to_tokens(tokens),
                 BinOp::ShlEq(t) => t.to_tokens(tokens),
                 BinOp::ShrEq(t) => t.to_tokens(tokens),
             }
         }
     }

     impl ToTokens for UnOp {
         fn to_tokens(&self, tokens: &mut TokenStream) {
             match self {
                 UnOp::Deref(t) => t.to_tokens(tokens),
                 UnOp::Not(t) => t.to_tokens(tokens),
                 UnOp::Neg(t) => t.to_tokens(tokens),
             }
         }
     }
 }
	ast_enum! {
	/// A binary operator: `+`, `+=`, `&`.
	///
	/// *This type is available only if Syn is built with the `"derive"` or `"full"`
	/// feature.*
	pub enum BinOp {
	/// The `+` operator (addition)
	Add(Token![+]),
	/// The `-` operator (subtraction)
	Sub(Token![-]),
	/// The `*` operator (multiplication)
	Mul(Token![*]),
	/// The `/` operator (division)
	Div(Token![/]),
	/// The `%` operator (modulus)
	Rem(Token![%]),
	/// The `&&` operator (logical and)
	And(Token![&&]),
	/// The `\|\|` operator (logical or)
	Or(Token![\|\|]),
	/// The `^` operator (bitwise xor)
	BitXor(Token![^]),
	/// The `&` operator (bitwise and)
	BitAnd(Token![&]),
	/// The `\|` operator (bitwise or)
	BitOr(Token![\|]),
	/// The `<<` operator (shift left)
	Shl(Token![<<]),
	/// The `>>` operator (shift right)
	Shr(Token![>>]),
	/// The `==` operator (equality)
	Eq(Token![==]),
	/// The `<` operator (less than)
	Lt(Token![<]),
	/// The `<=` operator (less than or equal to)
	Le(Token![<=]),
	/// The `!=` operator (not equal to)
	Ne(Token![!=]),
	/// The `>=` operator (greater than or equal to)
	Ge(Token![>=]),
	/// The `>` operator (greater than)
	Gt(Token![>]),
	/// The `+=` operator
	AddEq(Token![+=]),
	/// The `-=` operator
	SubEq(Token![-=]),
	/// The `*=` operator
	MulEq(Token![*=]),
	/// The `/=` operator
	DivEq(Token![/=]),
	/// The `%=` operator
	RemEq(Token![%=]),
	/// The `^=` operator
	BitXorEq(Token![^=]),
	/// The `&=` operator
	BitAndEq(Token![&=]),
	/// The `\|=` operator
	BitOrEq(Token![\|=]),
	/// The `<<=` operator
	ShlEq(Token![<<=]),
	/// The `>>=` operator
	ShrEq(Token![>>=]),
	}
	}

	ast_enum! {
	/// A unary operator: `*`, `!`, `-`.
	///
	/// *This type is available only if Syn is built with the `"derive"` or `"full"`
	/// feature.*
	pub enum UnOp {
	/// The `*` operator for dereferencing
	Deref(Token![*]),
	/// The `!` operator for logical inversion
	Not(Token![!]),
	/// The `-` operator for negation
	Neg(Token![-]),
	}
	}

	#[cfg(feature = "parsing")]
	pub mod parsing {
	use super::*;
	use crate::parse::{Parse, ParseStream, Result};

	fn parse_binop(input: ParseStream) -> Result<BinOp> {
	if input.peek(Token![&&]) {
	input.parse().map(BinOp::And)
	} else if input.peek(Token![\|\|]) {
	input.parse().map(BinOp::Or)
	} else if input.peek(Token![<<]) {
	input.parse().map(BinOp::Shl)
	} else if input.peek(Token![>>]) {
	input.parse().map(BinOp::Shr)
	} else if input.peek(Token![==]) {
	input.parse().map(BinOp::Eq)
	} else if input.peek(Token![<=]) {
	input.parse().map(BinOp::Le)
	} else if input.peek(Token![!=]) {
	input.parse().map(BinOp::Ne)
	} else if input.peek(Token![>=]) {
	input.parse().map(BinOp::Ge)
	} else if input.peek(Token![+]) {
	input.parse().map(BinOp::Add)
	} else if input.peek(Token![-]) {
	input.parse().map(BinOp::Sub)
	} else if input.peek(Token![*]) {
	input.parse().map(BinOp::Mul)
	} else if input.peek(Token![/]) {
	input.parse().map(BinOp::Div)
	} else if input.peek(Token![%]) {
	input.parse().map(BinOp::Rem)
	} else if input.peek(Token![^]) {
	input.parse().map(BinOp::BitXor)
	} else if input.peek(Token![&]) {
	input.parse().map(BinOp::BitAnd)
	} else if input.peek(Token![\|]) {
	input.parse().map(BinOp::BitOr)
	} else if input.peek(Token![<]) {
	input.parse().map(BinOp::Lt)
	} else if input.peek(Token![>]) {
	input.parse().map(BinOp::Gt)
	} else {
	Err(input.error("expected binary operator"))
	}
	}

	impl Parse for BinOp {
	#[cfg(not(feature = "full"))]
	fn parse(input: ParseStream) -> Result<Self> {
	parse_binop(input)
	}

	#[cfg(feature = "full")]
	fn parse(input: ParseStream) -> Result<Self> {
	if input.peek(Token![+=]) {
	input.parse().map(BinOp::AddEq)
	} else if input.peek(Token![-=]) {
	input.parse().map(BinOp::SubEq)
	} else if input.peek(Token![*=]) {
	input.parse().map(BinOp::MulEq)
	} else if input.peek(Token![/=]) {
	input.parse().map(BinOp::DivEq)
	} else if input.peek(Token![%=]) {
	input.parse().map(BinOp::RemEq)
	} else if input.peek(Token![^=]) {
	input.parse().map(BinOp::BitXorEq)
	} else if input.peek(Token![&=]) {
	input.parse().map(BinOp::BitAndEq)
	} else if input.peek(Token![\|=]) {
	input.parse().map(BinOp::BitOrEq)
	} else if input.peek(Token![<<=]) {
	input.parse().map(BinOp::ShlEq)
	} else if input.peek(Token![>>=]) {
	input.parse().map(BinOp::ShrEq)
	} else {
	parse_binop(input)
	}
	}
	}

	impl Parse for UnOp {
	fn parse(input: ParseStream) -> Result<Self> {
	let lookahead = input.lookahead1();
	if lookahead.peek(Token![*]) {
	input.parse().map(UnOp::Deref)
	} else if lookahead.peek(Token![!]) {
	input.parse().map(UnOp::Not)
	} else if lookahead.peek(Token![-]) {
	input.parse().map(UnOp::Neg)
	} else {
	Err(lookahead.error())
	}
	}
	}
	}

	#[cfg(feature = "printing")]
	mod printing {
	use super::*;
	use proc_macro2::TokenStream;
	use quote::ToTokens;

	impl ToTokens for BinOp {
	fn to_tokens(&self, tokens: &mut TokenStream) {
	match self {
	BinOp::Add(t) => t.to_tokens(tokens),
	BinOp::Sub(t) => t.to_tokens(tokens),
	BinOp::Mul(t) => t.to_tokens(tokens),
	BinOp::Div(t) => t.to_tokens(tokens),
	BinOp::Rem(t) => t.to_tokens(tokens),
	BinOp::And(t) => t.to_tokens(tokens),
	BinOp::Or(t) => t.to_tokens(tokens),
	BinOp::BitXor(t) => t.to_tokens(tokens),
	BinOp::BitAnd(t) => t.to_tokens(tokens),
	BinOp::BitOr(t) => t.to_tokens(tokens),
	BinOp::Shl(t) => t.to_tokens(tokens),
	BinOp::Shr(t) => t.to_tokens(tokens),
	BinOp::Eq(t) => t.to_tokens(tokens),
	BinOp::Lt(t) => t.to_tokens(tokens),
	BinOp::Le(t) => t.to_tokens(tokens),
	BinOp::Ne(t) => t.to_tokens(tokens),
	BinOp::Ge(t) => t.to_tokens(tokens),
	BinOp::Gt(t) => t.to_tokens(tokens),
	BinOp::AddEq(t) => t.to_tokens(tokens),
	BinOp::SubEq(t) => t.to_tokens(tokens),
	BinOp::MulEq(t) => t.to_tokens(tokens),
	BinOp::DivEq(t) => t.to_tokens(tokens),
	BinOp::RemEq(t) => t.to_tokens(tokens),
	BinOp::BitXorEq(t) => t.to_tokens(tokens),
	BinOp::BitAndEq(t) => t.to_tokens(tokens),
	BinOp::BitOrEq(t) => t.to_tokens(tokens),
	BinOp::ShlEq(t) => t.to_tokens(tokens),
	BinOp::ShrEq(t) => t.to_tokens(tokens),
	}
	}
	}

	impl ToTokens for UnOp {
	fn to_tokens(&self, tokens: &mut TokenStream) {
	match self {
	UnOp::Deref(t) => t.to_tokens(tokens),
	UnOp::Not(t) => t.to_tokens(tokens),
	UnOp::Neg(t) => t.to_tokens(tokens),
	}
	}
	}
	}