[−][src]Crate peg
rust-peg
is a simple yet flexible parser generator that makes it easy to
write robust parsers. Based on the Parsing Expression
Grammar formalism, it provides a Rust macro that builds a
recursive descent parser from a concise definition of the grammar.
Features
- Parse input from
&str
,&[u8]
,&[T]
or custom types implementing traits - Customizable reporting of parse errors
- Rules can accept arguments to create reusable rule templates
- Precedence climbing for prefix/postfix/infix expressions
- Helpful
rustc
error messages for errors in the grammar definition or the Rust code embedded within it - Rule-level tracing to debug grammars
Overview
The peg::parser!{}
macro encloses a grammar NAME() for INPUT_TYPE { ... }
definition containing a set of rules which match components of your
language.
Rules are defined with rule NAME(PARAMETERS) -> RETURN_TYPE = PEG_EXPR
.
The body of the rule, following the =
, is a PEG expression, definining how
the input is matched to produce a value.
PEG expressions are evaluated at a particular position of the input. When an expression matches, it advances the position and optionally returns a value. The expression syntax and behavior is documented below.
The macro expands to a Rust mod
containing a function for each rule marked
pub
in the grammar. To parse an input sequence, call one of these
functions. The call returns a Result<T, ParseError>
carrying either the
successfully parsed value returned by the rule, or a ParseError
containing
the failure position and the set of tokens expected there.
Example
Parse a comma-separated list of numbers surrounded by brackets into a Vec<u32>
:
peg::parser!{ grammar list_parser() for str { rule number() -> u32 = n:$(['0'..='9']+) { n.parse().unwrap() } pub rule list() -> Vec<u32> = "[" l:number() ** "," "]" { l } } } pub fn main() { assert_eq!(list_parser::list("[1,1,2,3,5,8]"), Ok(vec![1, 1, 2, 3, 5, 8])); }
Expression Reference
Atoms
"keyword"
- Literal: match a literal string.['0'..='9']
- Pattern: match a single element that matches a Rustmatch
-style pattern. (details)some_rule()
- Rule: match a rule defined elsewhere in the grammar and return its result. Arguments in the parentheses are Rust expressions._
or__
or___
- Rule (underscore): As a special case, rule names consisting of underscores are invoked without parentheses. These are conventionally used to match whitespace between tokens.(e)
- Parentheses: wrap an expression into a group to override normal precedence. Returns the same value as the inner expression. (Use an Action block to set the return value for a sequence).
Combining
e1 e2 e3
- Sequence: match expressions in sequence (e1
followed bye2
followed bye3
), ignoring the return values.a:e1 e2 b:e3 c:e4 { rust }
- Action: matche1
,e2
,e3
,e4
in sequence, like above. If they match successfully, run the Rust code in the block and return its return value. The variable names before the colons in the sequence are bound to the results of the corresponding expressions. It is important that the Rust code embedded in the grammar is deterministic and free of side effects, as it may be called multiple times.a:e1 b:e2 c:e3 {? rust }
- Conditional action: Like above, but the Rust block returns aResult<T, &str>
instead of a value directly. OnOk(v)
, it matches successfully and returnsv
. OnErr(e)
, the match of the entire expression fails and it tries alternatives or reports a parse error with the&str
e
.e1 / e2 / e3
- Ordered choice: try to matche1
. If the match succeeds, return its result, otherwise trye2
, and so on.
Repetition
expression?
- Optional: match zero or one repetitions ofexpression
. Returns anOption
.expression*
- Repeat: match zero or more repetitions ofexpression
and return the results as aVec
.expression+
- One-or-more: match one or more repetitions ofexpression
and return the results as aVec
.expression*<n,m>
- Range repeat: match betweenn
andm
repetitions ofexpression
return the results as aVec
. (details)expression ** delim
- Delimited repeat: match zero or more repetitions ofexpression
delimited withdelim
and return the results as aVec
.
Special
$(e)
- Slice: match the expressione
, and return the slice of the input corresponding to the match.&e
- Positive lookahead: Match only ife
matches at this position, without consuming any characters.!e
- Negative lookahead: Match only ife
does not match at this position, without consuming any characters.position!()
- return ausize
representing the current offset into the input without consuming anything.quiet!{ e }
- match the expressione
, but don't report literals within it as "expected" in error messages.expected!("something")
- fail to match, and report the specified string as expected at the current location.precedence!{ ... }
- Parse infix, prefix, or postfix expressions by precedence climbing. (details)
Expression details
Pattern expressions
The [pat]
syntax expands into a Rust match
pattern against the next character
(or element) of the input.
To match sets of characters, use Rust's ..=
inclusive range pattern
syntax and |
to match multiple patterns. For example ['a'..='z' | 'A'..='Z']
matches an
upper or lower case ASCII alphabet character.
If your input type is a slice of an enum type, a pattern could match an enum variant like
[Token::Operator('+')]
.
[_]
matches any single element. As this always matches except at end-of-file, combining it
with negative lookahead as ![_]
is the idiom for matching EOF in PEG.
Repeat ranges
The repeat operators *
and **
can be followed by an optional range specification of the
form <n>
(exact), <n,>
(min), <,m>
(max) or <n,m>
(range), where n
and m
are either
integers, or a Rust usize
expression enclosed in {}
.
Precedence climbing
precedence!{ rules... }
provides a convenient way to parse infix, prefix, and postfix
operators using the precedence
climbing
algorithm.
pub rule arithmetic() -> i64 = precedence!{ x:(@) "+" y:@ { x + y } x:(@) "-" y:@ { x - y } -- x:(@) "*" y:@ { x * y } x:(@) "/" y:@ { x / y } -- x:@ "^" y:(@) { x.pow(y as u32) } -- n:number() { n } "(" e:arithmetic() ")" { e } }
Each --
introduces a new precedence level that binds more tightly than previous precedence
levels. The levels consist of one or more operator rules each followed by a Rust action
expression.
The (@)
and @
are the operands, and the parentheses indicate associativity. An operator
rule beginning and ending with @
is an infix expression. Prefix and postfix rules have one
@
at the beginning or end, and atoms do not include @
.
Input types
The first line of the grammar declares an input type. This is normally
str
, but rust-peg
handles input types through a series of traits. The
library comes with implementations for str
, [u8]
, and [T]
. Define the
traits below to use your own types as input to peg
grammars:
Parse
is the base trait required for all inputs. The others are only required to use the corresponding expressions.ParseElem
implements the[_]
pattern operator, with a method returning the next item of the input to match.ParseLiteral
implements matching against a"string"
literal.ParseSlice
implements the$()
operator, returning a slice from a span of indexes.
As a more complex example, the body of the peg::parser!{}
macro itself is
parsed with peg
, using a definition of these traits
for a type that wraps Rust's TokenTree
.
Error reporting
When a match fails, position information is automatically recorded to report a set of "expected" tokens that would have allowed the parser to advance further.
Some rules should never appear in error messages, and can be suppressed with quiet!{e}
:
rule whitespace() = quiet!{[' ' | '\n' | '\t']+}
If you want the "expected" set to contain a more helpful string instead of character sets, you
can use quiet!{}
and expected!()
together:
rule identifier() = quiet!{[ 'a'..='z' | 'A'..='Z']['a'..='z' | 'A'..='Z' | '0'..='9' ]+} / expected!("identifier")
Imports
mod ast { pub struct Expr; } peg::parser!{grammar doc() for str { use self::ast::Expr; }}
The grammar may begin with a series of use
declarations, just like in Rust, which are
included in the generated module. Unlike normal mod {}
blocks, use super::*
is inserted by
default, so you don't have to deal with this most of the time.
Rustdoc comments
rustdoc
comments with ///
before a grammar
or pub rule
are propagated to the resulting
module or function:
/// Parse an array expression. pub rule array() -> Vec<i32> = "[...]" { vec![] }
As with all procedural macros, non-doc comments are ignored by the lexer and can be used like in any other Rust code.
Caching
A rule
without parameters can be prefixed with #[cache]
if it is likely
to be checked repeatedly in the same position. This memoizes the rule result
as a function of input position, in the style of a packrat
parser.
However, idiomatic code avoids structures that parse the same input
repeatedly, so the use of #[cache]
is often not a performance win. Simple
rules may also be faster to re-match than the additional cost of the hash
table lookup and insert.
For example, a complex rule called expr
might benefit from caching if used
like expr "x" / expr "y" / expr "z"
, but this could be rewritten to
expr ("x" / "y" / "z")
which would be even faster.
The precedence!{}
syntax is another way to avoid repeatedly matching
an expression rule.
Tracing
If you pass the peg/trace
feature to Cargo when building your project, a
trace of the rules attempted and matched will be printed to stdout when
parsing. For example,
$ cargo run --features peg/trace
...
[PEG_TRACE] Matched rule type at 8:5
[PEG_TRACE] Attempting to match rule ident at 8:12
[PEG_TRACE] Attempting to match rule letter at 8:12
[PEG_TRACE] Failed to match rule letter at 8:12
...
Modules
error | Parse error reporting |
str | Utilities for |
Macros
parser | The main macro for creating a PEG parser. |
Enums
RuleResult | The result type used internally in the parser. |
Traits
Parse | A type that can be used as input to a parser. |
ParseElem | A parser input type supporting the |
ParseLiteral | A parser input type supporting the |
ParseSlice | A parser input type supporting the |