lr-parser-typescript
v1.2.0
Published
`lr-parser-typescript` is a parsing library that offers a user-friendly formalism for specifying grammars, and a simple API for parsing strings, written in TypeScript.
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A minimal LR parsing library written in TypeScript
lr-parser-typescript
is a parsing library that offers a
user-friendly formalism for specifying grammars, and a simple API
for parsing strings, written in TypeScript.
Under the hood, lr-parser-typescript
uses a minimal LR(1) parser
algorithm described by David Pager in [0]. A minimal LR(1) parser
has the full power of the classic LR(1) parser, while producing
parser tables with sizes close to the corresponding LR(0) tables.
Installation
# Using npm:
npm install lr-parser-typescript
# Using yarn:
yarn add lr-parser-typescript
Example and tutorial
Note: this README is more of a reference than a tutorial. There is an introductory tutorial in the docs.
import { Caten, Match, Maybe, Parser, SyntaxTreeNode, Token } from "lr-parser-typescript";
class B extends SyntaxTreeNode {
token!: Token<'b'> | null;
static pattern = new Maybe(
new Match('token', 'b'),
);
}
class C extends SyntaxTreeNode {
static pattern = 'c';
}
class StartingSymbol extends SyntaxTreeNode {
childNode!: B;
static pattern = new Caten( // "Caten" stands for "concatenate".
'a',
new Match('childNode', B),
new Match(null, C),
'd'
);
}
const parser = new Parser(StartingSymbol);
const abcd = parser.parse('abcd')
console.log(abcd instanceof StartingSymbol); // true
Tokens
Before a string is parsed, it is tokenized -- turned into a sequence
of instances of Token
. The default tokenizer splits the string
into single-character tokens. If you want a more sophisticated
tokenizer, you need to create your own. You can have a look at
an example tokenizer from the docs.
The Token<Kind extends string | null>
class
Constructor parameters:
public kind: Kind
public start: SrcPosition
public end: SrcPosition
The kind "null" should be reserved for "end of input" tokens.
Methods:
traverse<T>(this: T, fn: (node: T) => boolean | void)
Calls the function
fn
withthis
as an argument. Traversing makes more sense on instances of SyntaxTreeNode, a class that is mentioned below.
Patterns
A pattern is either a string, or an instance of one of the classes
described below. A string pattern matches a token whose kind
property is equal to the string.
Caten
Constructor parameters:
...patterns: Pattern[]
Caten
is short for "concatenate". new Caten(p0, p1, p2)
matches
a sequence of tokens s
iff s
can be split into three subsequences
s0
, s1
, s2
such that pX
matches sX
(for X = 0, 1, 2
).
Or
Constructor parameters:
...patterns: (Pattern | { patternName: string })[]
Or
matches a token sequence iff at least one of its arguments does.
At most one of the arguments can be an object with a patternName
property. See the section Pattern caching for
more about naming patterns.
Maybe
Constructor parameters:
pattern: Pattern
name: string | null = null
Maybe
matches a token sequence iff its argument matches, or the
token sequence is empty. It is just a syntactic sugar for
new Or(new Caten(), pattern)
.
Match, MatchArr
See examples in the docs.
Constructor parameters:
prop: [class is Match] ? string | null : string
match: SyntaxTreeClass | Pattern
name: string | null = null
A Match
is used to:
0. capture the result of a pattern match into a property of a
syntax tree node, or
- use a syntax tree class in the pattern of another syntax tree class.
match
is the pattern that will be matched, and stored into
the property prop
(if not null).
Assuming the input that is being parsed matches the pattern, the following holds:
- If
match
is a string, then the property will be assigned a token. - If
match
is a syntax tree class, then the property will be assigned an instance of that class. - If
match
is a non-string pattern, then the property will be assigned an array of tokens that matched the pattern.
If the Match
is not matched (eg. if it is inside a Maybe
or
a non-matching branch of an Or
), then the property will be
assigned null
.
A Match
cannot be used in a way that would potentially lead to
the same property being assigned to more than once. In contrast,
MatchArr
can be used any number of times, and always captures
an array of what Match
would capture. Match
and MatchArr
cannot be used together on the same property.
Repeat
Constructor parameters:
pattern: Pattern
the repeating patternoptions?: RepeatOptions
// Default values in comments.
type RepeatOptions = {
delimiter: Pattern, // new Caten()
trailingDelimiter: Pattern | boolean, // false
lowerBound: number, // 0
upperBound: number, // Infinity
name: string | null, // null
}
Repeat
matches token sequences matched by A B A B ... A
, where
A
is the repeating pattern, B
is the delimiter and the number of
occurrences of A
is within lowerBound
(inclusive) and upperBound
(exclusive).
If a trailing delimiter is provided, additionally matches sequences
matched by A B A B ... A T
, with the additional constraint that
the trailing delimiter must follow an A
. (Ie. a Repeat
does
not match a sequence matched by just T
unless A
can match the
empty sequence.)
Passing true as the trailing delimiter to the constructor means the trailing delimiter is the same as the delimiter.
SyntaxTreeNode
SyntaxTreeNode
is the superclass of all syntax tree nodes. Every
class that extends SyntaxTreeNode
must have a static property
pattern
of type Pattern
.
A syntax tree class may have a static boolean property hidden
.
If true, the class must have a property called value
. When
another class uses a Match
with a hidden class as the pattern,
the hidden class will not be instantiated during parsing, and its
would-be instance will be replaced by the value of its value
property.
If a hidden class uses MatchArr
to capture its value
, then such
a class must also be matched using MatchArr
. Matching an array-
capturing hidden class several times concatenates the respective
matched arrays.
Example hidden class:
class Hidden extends SyntaxTreeNode {
static hidden = true as true;
value: Token<'a' | 'b'>
static pattern = new Or(
new Match('value', 'a'),
new Match('value', 'b'),
);
}
class StartingSymbol {
// Notice `aOrB` is an instance of `Hidden['value']`, not `Hidden`.
aOrB: Token<'a' | 'b'>;
static pattern = new Match('aOrB', Hidden);
}
SyntaxTreeClass
A type of classes that extend SyntaxTreeNode
.
The Parser<Stc extends SyntaxTreeClass
class
Constructor parameters:
public stc: Stc
the starting symboloptions: ParserOptions
// Default values in comments.
type ParserOptions = {
tokenizer: Tokenizer, // Parser.defaultTokenizer
serializedParserTable: [opaque] | null, // null
logLevel: LogLevel, // LogLevel.problemsOnly (more or less)
}
The parse
method
Parameters:
word: string
Return type: InstanceType<Stc> | TokenizationError | ParseError
The parse
method takes a string and returns the result of parsing
it. If the string matches the pattern of Stc
, then the result is
an instance of Stc
. If the string does not match, ParseError
is returned. If the tokenizer returns an instance of
TokenizationError
, then it is returned.
If Stc
is a hidden class, then parse
returns the value of its
value
property, so the return type is actually Stc['value'] | ...
.
However, TypeScript is only able to infer the return type properly
if the hidden
property's type is true
, not boolean
. You can
declare the hidden
property as true as true
to make TypeScript
happy.
The saveParserTable
method
Parameters:
path: string
minifyParserTable: boolean = true
Return type: Promise<void>
Saves the parser table to the file at path
as JSON. The file
may then be imported and passed to the Parser
constructor using
the serializedParserTable
option.
Unless a parser is initialized with a serialized parser table, it will have to construct the parser table from scratch. This may be fine during development of a grammar, or for small grammars, but for larger grammars, it may be too slow.
minifyParserTable
determines whether to use a smaller, but hard
to read parser table format, and is true by default.
Example usage:
import { Parser } from 'lr-parser-typescript';
import StartingSymbol from './starting-symbol';
import parserTable from './parser-table.json';
// Set to true to recompute the parser table. May be initialized
// eg. from a CLI flag (or just change the code).
const recomputeTable = false as boolean;
const parser = new Parser(StartingSymbol, {
serializedParserTable: recomputeTable ? null : parserTable,
});
if (recomputeTable) (async () => {
// Note: if your code is compiled to a different location,
// you may need to adjust the path.
await parser.saveParserTable('./parser-table.json');
console.log('Parser table saved.');
})();
The static defaultTokenizer
property
The default tokenizer. It will turn a string into a sequence of single-character tokens.
Reference (everything else)
These are the exported members of the library.
SrcPosition (class)
Constructor parameters:
public line: number
public col: number
public i: number
All three arguments use proper indexing -- ie. from zero.
Tokenizer (type)
type Tokenizer =
(str: string) =>
Iterator<
Token<string>,
Token<null> | TokenizationError
>
TokenizationError (class)
Constructor parameters:
public at: SrcPosition
You may extend this class to provide more information about the error.
ParseError (class)
Constructor parameters:
public token: Token<string | null>
public expected: (string | null)[]
Pattern caching
In the background, lr-parser-typescript
converts patterns into
a formal grammar, and then constructs a parser table for that
grammar.
It is possible (though not recommended) to use the same pattern
in multiple places. lr-parser-typescript
makes sure such patterns
are only converted into a grammar rule once. This applies to those
patterns that create their own nonterminals -- ie. Match
, Maybe
,
Or
and Repeat
.
Every pattern of the above classes (but not their subclasses) that
is used at multiple places must be given an explicit name. Those
patterns that are used only once are given implicit names like
ClassName.Caten[0].Or[1].Match
.
Pattern names are used to print the grammar and the parser table
in a human-readable form, either if the logLevel
option is set
to LogLevel.verbose
, or if there is a grammar conflict.
Debugging grammar conflicts
A basic understanding of LR parsing is required to understand
grammar conflicts and why they happen. When a grammar conflict
occurs, lr-parser-typescript
will print the grammar and the
parser table generated up to that point, in a human-readable form.
Circular grammars
Due to the limitations of JavaScript, classes cannot be referenced before they are defined. This means we need to be a bit careful when defining circular grammars.
// A good convention is `match[propName][className]`.
const matchBarBar = new Match('bar', null!);
class Foo extends SyntaxTreeNode {
bar!: Bar | null;
static pattern = new Caten(
'foo',
new Maybe(
matchBarBar,
),
);
}
class Bar extends SyntaxTreeNode {
foo!: Foo | null;
static pattern = new Caten(
'bar',
new Maybe(
new Match('foo', Foo),
),
);
}
// This is safe as long as it happens before we instantiate the
// parser.
matchBarBar.match = Bar;
References
- A practical general method for constructing LR(k) parsers, David Pager, 1977.