Parakeet is a text parsing library written in C#. Parakeet is the parsing library being used by the Plato programming language project to Parse both Plato and C# source code.
Parakeet is a recursive descent (RD) parsing library based on the parsing expression grammar (PEG) formalization introduced by Bryan Ford. Parakeet parsers are defined directly in C# using operator overloading. Parakeet combines both lexical analysis (aka tokenization) and syntactic analysis in a single pass.
See this CodeProject article for an introduction to the core concepts of Parakeet.
Parakeet was designed primarily for the challenge of parsing programming languages. It can be used in different contexts of course.
Parakeet supports:
- Parsing error recovery
- Run-time detection of stuck parsers
- Line number and column number reporting
- Immutable data structures
- Operator overloading
- Fluent API syntax (aka method chaining)
- Automated creation of untyped parse trees
- Code generation for converting untyped parse trees into a strongly typed concrete syntax tree (CST).
- Define a grammar in code: a class with a set of properties that map to rules
- Convert the input text into a parser input object
- Choose the starting rule of the grammar
- Call the match function of the starting rule
- Examine the resulting
ParserState
object - If the result is
null
the parser failed to match, and failed to recover- Consider adding
OnError
to your grammar
- Consider adding
- Convert
ParserInput
- Wraps a string with convenience functions to retrieve row/column, and potentially the source file name. Can be implicitly converted from a stringParserState
- Represents a position in the input and a pointer to the most recently created parse node.ParserRange
- Contains twoParserState
objects, one representing the beginning of a range of input and the other the end.ParserNode
- A named node in parse node list.ParserTree
- A tree structure created from a linked list ofParserNode
objectsParserCache
- Stores parser errors, and successful parse results to accelerated future lookups.Rule
- Base class of a parser, provides a match function that accepts a ParserState and a ParserCache.Grammar
- Base class of a collection of parsing rules, usually defined as properties.CstNode
- Base class of typed parse trees generated fromGrammar
objects.CstClassBuilder
- Static class with functions for generatingAstNode
classes and factory functions fromParserTree
objects.ParserError
- An error created when aSequence
fails to match a child rule after anOnError
rule.ParserException
- This represents an internal parser error which usually results from a grammar mistake.
A Grammar
is the base class for collections of parsing rules. Usually each parse rule in a grammar is defined
as a computed property that either returns a NodeRule
or a TokenRule
. By using the functions Node
and Token
to wrap rule definitions, names are automatically assigned to each rule.
The GrammarExtensions.cs
file contains a number of helper functions for outputting the definitions of grammars
or to simplify parsing rules.
When defining rules it is important that any cyclical reference from a rule to itself uses at least one RecursiveRule
in the relationship chain. This prevents stack overflow errors from occuring.
A Parakeet parser is defined by a class deriving from Rule
. Some rules are defined by combining rules.
Those combining rules are called "combinators".
Ever rule has a single function:
public ParserState Match(ParserState state, ParserCache cache)
The Match
will return null
if the Rule failed to match, or a ParserState
object if successful.
Rules can be combined using a fluent syntax (aka method chaining).
rule.At()
=>new At(rule)
rule.NotAt()
=>new NotAt(rule)
rule1.Then(rule2)
=>new Sequence(rule1, rule2)
rule1.ThenNot(rule2)
=>new Sequence(rule, rule2.NotAt())
rule.Optional()
=>new Optional(rule)
rule1.Or(rule2)
=>new Choice(rule1, rule2)
rule1.Except(rule2)
=>new Sequence(rule2.NotAt(), rule1)
rule.ZeroOrMore()
=>new ZeroOrMore(rule)
rule.OneOrMore()
=>new Sequence(rule, rule.ZeroOrMoree)
char1.To(char2)
=>new CharRangeRule(char1, char2)
Rules can be combined using the following overloaded operators.
rule1 + rule2
=>new SequenceRule(rule1, rule2)
rule1 | rule2
=>new ChoiceRule(rule1, rule2)
!rule
=>new NotAt(rule)
The following implicit casts are defined for Rules:
Rule(string s)
=>new StringMatchRule(s)
Rule(char c)
=>new CharMatchRule(c)
Rule(char[] cs)
=>new CharSetRule(cs)
Rule(string[] xs)
=>new Choice(xs.Select(x => (Rule)x))
StringMatchRule
- Matches a stringAnyCharRule
- Matches any character, but fails at end of the fileCharRangeRule
- Matches any character within a rangeCharSetRule
- Matches any character within a setCharMatchRule
- Matches a specific character
Rule combinators combine zero or more rules.
ZeroOrMore
- Tries to match a child rule as many times as possible, returning the originalParserState
if not successful at least once.Optional
- Tries to match a child rule exactly once, returning the originalParserState
if the child rule fails.Sequence
- Matches a sequence of rules one by one, returningnull
if not successful.Choice
- Matches a collection of rules one by one, until one succeeeds, ornull
if not successful.RecursiveRule
- Matches a child rule defined by a lambda, thus allowing Rule definitions to have cycles.TokenRule
- A rule that just matches it child without creating a node. Used for defining grammars.NodeRule
- Creates a newParserNode
and adds it to theParserState
. May also eat whitespace (true by default).
Several rules never advance the parser state:
At
- Returns the original parser state if the child rule succeeds, or null otherwiseNotAt
- Returns the original parser state if the child rule fails, or null otherwiseEndOfInput
- Returns the parser state if at the end of input, or null otherwise
OnFail
- Used only withinSequence
rules. Contains a child rule called the recovery rule. Will always succeed and return theParserState
when matched. If a sequence encounters anOnFail
error and one of the subsequent child rules fails, the parser will then use the recovery rule to try to advance to a place where it is likely to be able to continue parsing successfully (e.g. the end of a statement).
Parse trees generated from Parakeet are untyped. A parse node is created whenever a NodeRule
rule
successfully matches its child rule against the input. After parsing the list of parse nodes
is converted into a tree structure.
A set of classes representing a strongly typed parse tree can be created automatically from a Parakeet grammar. This is called the
Concrete Syntax Tree. Concrete syntax trees are generated from the Ara3D.Parakeet.Grammars
project using one of the
functions in the Ara3d.Parakeet.Tests
project.
The following projects use Parakeet:
- https://github.com/ara3d/ara3d/tree/main/src/Ara3D.Parsing.Markdown
- https://github.com/cdiggins/Plato
Parakeet evolved from the Jigsaw parser and applies lessons learned when writing the Myna parsing library in TypeScript as well as my first parsing library [YARD](https://www.codeproject.com/Articles/9121/Parsing-XML-in-C-using-the-YARD-Parser Parakeet is designed to be as fast as possible while retaining a clean and elegant grammar description.
- https://github.com/benjamin-hodgson/Pidgin
- https://github.com/sprache/Sprache
- https://github.com/plioi/parsley
- https://github.com/datalust/superpower
- https://github.com/IronyProject/Irony
- https://github.com/teo-tsirpanis/Farkle
- https://github.com/takahisa/parseq
- https://github.com/picoe/Eto.Parse
- https://github.com/b3b00/CSLY
- https://github.com/stephan-tolksdorf/fparsec
- https://github.com/dbremner/peg-sharp
- https://github.com/SickheadGames/TinyPG
- https://github.com/otac0n/Pegasus
- https://github.com/qwertie/LLLPG-Samples
- https://github.com/antlr
- https://en.wikipedia.org/wiki/Parser_combinator
- https://en.wikipedia.org/wiki/Parsing_expression_grammar
- https://pdos.csail.mit.edu/~baford/packrat/icfp02/packrat-icfp02.pdf
Q: Isn't a parse tree and concrete syntax tree (CST) the same thing?
Yes. Parakeet uses the term parse tree to refer to untyped parse tree, and CST to refer to the typed parse tree.
Q: What is the difference between a CST and an AST?
The CST is generated from parsing the input text as is. An AST is the result of transforming the CST into a form that has the same semantic meaning but is presumably simpler and easier.
Q: Why isn't Parakeet a code generator from the beginning
I find it easier to learn, understand, use, and debug libraries that aren't generated. Writing an extension to Parakeet that generates parser code would not be very hard.
Q: So why is the CST code generated?
Having a strongly typed CST is very beneficial when writing analysis and transformation tools especially for non-trivial grammars like those of programming languages. I don't know of any other way in C# to generate strongly typed libraries other than generating code.
Q: Isn't parsing library X faster?
Maybe. I designed Parakeet to be fast enough for my needs, but I prioritized making it robust and (hopefully) easy to use. See the related work section for other parsing libraries to consider.
Q: Can you provide some benchmarks? Or implement grammar X?
I'm kind of busy getting work done. If you are willing to fund this project, then we should talk: email me at cdiggins@gmail.com.