Expand description
§pest. The Elegant Parser
pest is a general purpose parser written in Rust with a focus on accessibility, correctness, and performance. It uses parsing expression grammars (or PEG) as input, which are similar in spirit to regular expressions, but which offer the enhanced expressivity needed to parse complex languages.
§Getting started
The recommended way to start parsing with pest is to read the official book.
Other helpful resources:
- API reference on docs.rs
- play with grammars and share them on our fiddle
- leave feedback, ask questions, or greet us on Gitter
§.pest
files
Grammar definitions reside in custom .pest
files located in the src
directory. Their path is
relative to src
and is specified between the derive
attribute and empty struct
that
Parser
will be derived on.
#[derive(Parser)]
#[grammar = "path/to/my_grammar.pest"] // relative to src
struct MyParser;
§Inline grammars
Grammars can also be inlined by using the #[grammar_inline = "..."]
attribute.
§Grammar
A grammar is a series of rules separated by whitespace, possibly containing comments.
§Comments
Comments start with //
and end at the end of the line.
// a comment
§Rules
Rules have the following form:
name = optional_modifier { expression }
The name of the rule is formed from alphanumeric characters or _
with the condition that the
first character is not a digit and is used to create token pairs. When the rule starts being
parsed, the starting part of the token is being produced, with the ending part being produced
when the rule finishes parsing.
The following token pair notation a(b(), c())
denotes the tokens: start a
, start b
, end
b
, start c
, end c
, end a
.
§Modifiers
Modifiers are optional and can be one of _
, @
, $
, or !
. These modifiers change the
behavior of the rules.
-
Silent (
_
)Silent rules do not create token pairs during parsing, nor are they error-reported.
ⓘa = _{ "a" } b = { a ~ "b" }
Parsing
"ab"
produces the token pairb()
. -
Atomic (
@
)Atomic rules do not accept whitespace or comments within their expressions and have a cascading effect on any rule they call. I.e. rules that are not atomic but are called by atomic rules behave atomically.
Any rules called by atomic rules do not generate token pairs.
ⓘa = { "a" } b = @{ a ~ "b" } WHITESPACE = _{ " " }
Parsing
"ab"
produces the token pairb()
, while"a b"
produces an error. -
Compound-atomic (
$
)Compound-atomic are identical to atomic rules with the exception that rules called by them are not forbidden from generating token pairs.
ⓘa = { "a" } b = ${ a ~ "b" } WHITESPACE = _{ " " }
Parsing
"ab"
produces the token pairsb(a())
, while"a b"
produces an error. -
Non-atomic (
!
)Non-atomic are identical to normal rules with the exception that they stop the cascading effect of atomic and compound-atomic rules.
ⓘa = { "a" } b = !{ a ~ "b" } c = @{ b } WHITESPACE = _{ " " }
Parsing both
"ab"
and"a b"
produce the token pairsc(a())
.
§Expressions
Expressions can be either terminals or non-terminals.
-
Terminals
Terminal Usage "a"
matches the exact string "a"
^"a"
matches the exact string "a"
case insensitively (ASCII only)'a'..'z'
matches one character between 'a'
and'z'
a
matches rule a
Strings and characters follow
Rust’s escape mechanisms, while
identifiers can contain alpha-numeric characters and underscores (_
), as long as they do not
start with a digit.
-
Non-terminals
Non-terminal Usage (e)
matches e
e1 ~ e2
matches the sequence e1
e2
e1 | e2
matches either e1
ore2
e*
matches e
zero or more timese+
matches e
one or more timese{n}
matches e
exactlyn
timese{, n}
matches e
at mostn
timese{n,}
matches e
at leastn
timese{m, n}
matches e
betweenm
andn
times inclusivelye?
optionally matches e
&e
matches e
without making progress!e
matches if e
doesn’t match without making progressPUSH(e)
matches e
and pushes it’s captured string down the stackwhere
e
,e1
, ande2
are expressions.
Expressions can modify the stack only if they match the input. For example,
if e1
in the compound expression e1 | e2
does not match the input, then
it does not modify the stack, so e2
sees the stack in the same state as
e1
did. Repetitions and optionals (e*
, e+
, e{, n}
, e{n,}
,
e{m,n}
, e?
) can modify the stack each time e
matches. The !e
and &e
expressions are a special case; they never modify the stack.
§Special rules
Special rules can be called within the grammar. They are:
WHITESPACE
- runs between rules and sub-rulesCOMMENT
- runs between rules and sub-rulesANY
- matches exactly onechar
SOI
- (start-of-input) matches only when aParser
is still at the starting positionEOI
- (end-of-input) matches only when aParser
has reached its endPOP
- pops a string from the stack and matches itPOP_ALL
- pops the entire state of the stack and matches itPEEK
- peeks a string from the stack and matches itPEEK[a..b]
- peeks part of the stack and matches itPEEK_ALL
- peeks the entire state of the stack and matches itDROP
- drops the top of the stack (fails to match if the stack is empty)
WHITESPACE
and COMMENT
should be defined manually if needed. All other rules cannot be
overridden.
§WHITESPACE
and COMMENT
When defined, these rules get matched automatically in sequences (~
) and repetitions
(*
, +
) between expressions. Atomic rules and those rules called by atomic rules are exempt
from this behavior.
These rules should be defined so as to match one whitespace character and one comment only since they are run in repetitions.
If both WHITESPACE
and COMMENT
are defined, this grammar:
a = { b ~ c }
is effectively transformed into this one behind the scenes:
a = { b ~ WHITESPACE* ~ (COMMENT ~ WHITESPACE*)* ~ c }
§PUSH
, POP
, DROP
, and PEEK
PUSH(e)
simply pushes the captured string of the expression e
down a stack. This stack can
then later be used to match grammar based on its content with POP
and PEEK
.
PEEK
always matches the string at the top of stack. So, if the stack contains ["b", "a"]
("a"
being on top), this grammar:
a = { PEEK }
is effectively transformed into at parse time:
a = { "a" }
POP
works the same way with the exception that it pops the string off of the stack if the
match worked. With the stack from above, if POP
matches "a"
, the stack will be mutated
to ["b"]
.
DROP
makes it possible to remove the string at the top of the stack
without matching it. If the stack is nonempty, DROP
drops the top of the
stack. If the stack is empty, then DROP
fails to match.
§Advanced peeking
PEEK[start..end]
and PEEK_ALL
allow to peek deeper into the stack. The syntax works exactly
like Rust’s exclusive slice syntax. Additionally, negative indices can be used to indicate an
offset from the top. If the end lies before or at the start, the expression matches (as does
a PEEK_ALL
on an empty stack). With the stack ["c", "b", "a"]
("a"
on top):
fill = PUSH("c") ~ PUSH("b") ~ PUSH("a")
v = { PEEK_ALL } = { "a" ~ "b" ~ "c" } // top to bottom
w = { PEEK[..] } = { "c" ~ "b" ~ "a" } // bottom to top
x = { PEEK[1..2] } = { PEEK[1..-1] } = { "b" }
y = { PEEK[..-2] } = { PEEK[0..1] } = { "a" }
z = { PEEK[1..] } = { PEEK[-2..3] } = { "c" ~ "b" }
n = { PEEK[2..-2] } = { PEEK[2..1] } = { "" }
For historical reasons, PEEK_ALL
matches from top to bottom, while PEEK[start..end]
matches
from bottom to top. There is currectly no syntax to match a slice of the stack top to bottom.
§Rule
All rules defined or used in the grammar populate a generated enum
called Rule
. This
implements pest
’s RuleType
and can be used throughout the API.
§Built-in rules
Pest also comes with a number of built-in rules for convenience. They are:
ASCII_DIGIT
- matches a numeric character from 0..9ASCII_NONZERO_DIGIT
- matches a numeric character from 1..9ASCII_BIN_DIGIT
- matches a numeric character from 0..1ASCII_OCT_DIGIT
- matches a numeric character from 0..7ASCII_HEX_DIGIT
- matches a numeric character from 0..9 or a..f or A..FASCII_ALPHA_LOWER
- matches a character from a..zASCII_ALPHA_UPPER
- matches a character from A..ZASCII_ALPHA
- matches a character from a..z or A..ZASCII_ALPHANUMERIC
- matches a character from a..z or A..Z or 0..9ASCII
- matches a character from \x00..\x7fNEWLINE
- matches either “\n” or “\r\n” or “\r”