Core Single Parsers
The core single parsers are all generic on the type of input they accept. For a list of additional parsers which are related strictly to parsing strings with character input sequences, see the String/Character Parsers page. In addition, there are several specialty parsers related to parsing common patterns from programming languages, which also take character input sequences. You can find these in the Programming Parsers page.
Throughout the descriptions of these parsers, examples will be shown where one parser is functionally or logically equivalent to a combination of other parsers. This is done to give multiple possible ways to understand some of the trickier concepts.
The best way to access these core parsers is through the static factory methods. Add this to the top of your C# file:
using ParserObjects;
using static ParserObjects.ParserMethods<char>;
(Replace <char>
with whatever your input type is.)
Declaration Styles
There are two basic styles of declaring parsers. The first is to use the static factory methods to create parsers:
using static ParserObjects.ParserMethods<char>;
var parser = List(
Any()
);
The second is to use monadic extension methods to combine them:
using static ParserObjects.ParserMethods<char>;
var parser = Any().List();
In a few cases there are tuple syntaxes available as well. These will be noted in the appropriate sections.
Do not use parser class names directly from the ParserObjects.Parsers
namespace. These class names are not designed for easy discovery or use, and they may change between releases to better describe what they are and how they operate. The Function and Method names described above will stay the same between releases, even if the ways they are implemented may change.
Fundamental Parser Types
These parsers represent the theoretical core of the parsing library. To use these, import the methods you’re using (replace <char>
with whatever input type you are using):
using ParserObjects;
using static ParserObjects.ParserMethods<char>;
Any Parser
The Any
parser matches any single input value and returns it directly. It consumes one item of input, and only fails when the sequence is at the end.
var anyParser = Any();
It is functionally equivalent to the match predicate parser, though simpler and faster (described below):
var anyParser = Match(_ => true);
Bool Parser
The Bool
parser invokes a parser and returns true
if the inner parser succeeds, false
otherwise. It is useful if you want to know whether something matches, but don’t care what the result value is, or if you want to convert IParser<TInput>
to IParser<TInput, bool>
.
var parser = Bool(innerParser);
Chain Parser
The Chain
parser invokes an initial parser to obtain a prefix value, then uses that prefix value to select the next parser to invoke.
var parser = Chain(initial, result => {
if (!result.Success)
return new HandleFailureParser();
if (result.Value == 'a')
return new AParser();
if (result.Value == 'b')
return new BParser();
});
var parser = initial.Chain(result => {
if (!result.Success)
return new HandleFailureParser();
if (result.Value == 'a')
return new AParser();
if (result.Value == 'b')
return new BParser();
});
The Chain parser will throw an InvalidOperationException
if the callback method returns a null
value.
Chain With Parser
The ChainWith
parser is related to the Chain
parser but uses a different fluent syntax for selecting a value.
var parser = ChainWith(config => config
.When(x => x == 'a', new AParser())
.When(x => x == 'b', new BParser())
);
Choose Parser
The Choose
parser invokes an initial parser to parse a prefix value without consuming any input, then uses that prefix value to select the next parser to invoke.
var parser = Choose(initial, result => {
if (!result.Success)
return new HandleFailureParser();
if (result.Value == 'a')
return new AParser();
if (result.Value == 'b')
return new BParser();
});
var parser = initial.Choose(result => {
if (!result.Success)
return new HandleFailureParser();
if (result.Value == 'a')
return new AParser();
if (result.Value == 'b')
return new BParser();
});
The Choose
parser is implemented using the Chain
parser internally and is equivalent to a combination of the Chain
and None
parsers:
var parser = initial
.None()
.Chain(result => ...);
Combine Parser
The Combine
parser takes a list of parsers, parses each in sequence, and returns a list of object
results. You can transform or filter these results as appropriate for your application.
var parser = Combine(p1, p2, p3, ...);
Empty Parser
The Empty
parser consumes no input and always returns success with a default value, even when the input sequence is at end. It consumes no input and returns no value.
var parser = Empty();
End Parser
The End
parser returns success if the stream is at the end, failure otherwise. It consumes no input and returns no value.
var parser = End();
Examine Parser
The Examine
parser allows inserting callbacks before or after any other parser, and is primarily used for debugging. You can also use the Examine parser to make adjustments to the input stream or state data before the parse, and augment the result after a parse.
var parser = inner.Examine(
before: c => { ... },
after: c => { ... }
);
Fail Parser
The Fail
parser returns failure unconditionally. It can be used to explicitly insert failure conditions into your parser graph, to provide error messages which are more helpful than the default error messages, or to serve as a placeholder for replacement operations. The Fail parser has an output type so it can be inserted into places in your parser graph that expect an output type to be specified.
var parser = Fail<char>("helpful error message");
var parser = Fail("helpful error message");
If the output type is not specified, it returns the same as the input type.
First Parser
The First
parser takes a list of parsers. Each parser is attempted in order, and the result is returned as soon as any parser succeeds. If none of the parsers succeed, the First
parser fails. The First parser can also be written as an extension method on a tuple of parsers.
var parser = First(
parser1,
parser2,
parser3
);
var parser = (parser1, parser2, parser3).First();
The tuple variant of this parser is limited up to 9 child parsers. The other variants can take any number of child parsers.
Function Parser
The Function
parser takes a callback function to perform the parse. The callback takes success
and fail
arguments, which are functions to generate the correct result object with filled-in metadata. It will automatically rewind the input sequence on failure, so you do not need to cleanup manually. It will also automatically report the correct number of consumed input tokens so you do not need to track it yourself.
var parser = Function((t, success, fail) => {
// for success
return success("ok");
// for failure
return fail("parse failed");
});
The Function parser is very similar to the Sequential
parser. Both use a callback to execute the parse. The Function parser is almost completely free from structure and does not assume that the parse internally is performed using IParser
instances. The Sequential parser, on the other hand provides a state object which should be used to perform parses, and expects that the parsing internally will be done using IParser
instances.
List Parser
The List
parser attempts to parse the inner parser repeatedly until it fails, and returns an enumeration of the results. The List parser takes optional minimum
and maximum
values, to control the number of items matched. If you specify a minimum, the list will fail unless that number of items has been matched. If you do not specify a minimum, the list may return success if no items are matched, and return an empty list as a result. If a maximum number is specified, the list will continue matching only until that maximum number is reached then it will stop.
var parser = List(innerParser);
var parser = List(innerParser, 3, 5);
// same as List(innerParser, minimum: 1);
var parser = List(innerParser, true);
var parser = innerParser.List();
var parser = innerParser.List(3, 5);
// Same as innerParser.List(minimum: 1);
var parser = innerParser.List(true);
If the inner parser returns success but consumes zero input, the List parser will break the loop and return only a single item. If a minimum number is set, the List parser will loop only until the minimum value and then break, returning success with a list with the correct number of items. This is a precaution to prevent the list parser from getting into an infinite loop when no input is being consumed.
Match Predicate Parser
The MatchPredicateParser
examines the next input item and returns it if it matches a predicate.
var parser = Match(c => ...);
None Parser
The None
parser evaluates an inner parser and the rewinds the input sequence to ensure no data has been consumed.
var parser = None(Any());
var parser = Any().None();
Optional Parser
The Optional
parser attempts to invoke the inner parser, but returns success no matter the result. The Optional parser takes a callback argument to return a default value if the parse fails. If the default value callback is not provided, the Optional parser will return an IOption
object which will report on success or failure of the inner parser.
var parser = Optional(innerParser);
var parser = Optional(innerParser, () => defaultValue);
var parser = innerParser.Optional();
var parser = innerParser.Optional(() => defaultValue);
The Optional parser is functionally equivalent to a combination of First
and Produce
parsers:
var parser = First(
innerParser,
Produce(() => defaultValue)
);
Peek Parser
The Peek
parser peeks at the next value of input, but does not consume it. It returns failure when the input sequence is at end, success otherwise.
var parser = new PeekParser<char>();
var parser = Peek();
This parser is functionally equivalent to the Any
and None
parsers:
var parser = Any().None();
Predict Parser
The Predict
parser peeks at a lookahead value in the input stream, and uses that value to determine what parser to invoke next.
var parser = Predict(config => config
.When(c => c == 'a', new AParser())
.When(c => c == 'b', new BParser())
);
If no matching value is found, the Predict parser returns failure. The Predict
parser is implemented internally using the Chain
parser and the Peek
parser. It is logically equivalent, though nicer syntax, to:
var parser = Peek().Chain(r => ...);
Produce Parser
The Produce
parser produces a value but consumes no input. It always returns success.
var parser = Produce(() => "abcd");
var parser = Produce((input, data) => "abcd");
The produce parser may be used to construct synthetic values at parse time. It can return a constant value or create a new value on every call, the value will not be cached. It may look at and consume input from the input sequence. It may use values from the contextual state data.
The simple case of the Produce parser is functionally equivalent to a combination of the Empty
and Transform
parsers:
var parser = Empty().Transform(_ => "abcd");
Rule Parser
The Rule
parser attempts to execute a list of parsers, and then return a combined result. If any parser in the list fails, the input is rewound and the whole parser fails. You can create rule parsers by using the .Produce()
extension method on a Tuple
or ValueTuple
of parser objects, which may be cleaner to read and write in some situations
var parser = Rule(
parser1,
parser2,
parser3,
(r1, r2, r3) => ...
);
var parser = (parser1, parser2, parser3).Produce((r1, r2, r3) => ...);
The Rule()
method and tuple variants are both limited to 9 parsers at most. If you need to combine the results of more than 9 parsers, use the Combine
parser instead.
Separated List
The SeparatedList
parser is similar to a List
parser except the items have separators between them. Like the List parser, the Separated List may take minimum and maximum values to control how many items are matched.
var parser = SeparatedList(item, separator);
var parser = SeparatedList(item, separator, 3, 5);
// Same as SeparatedList(item, separator, minimum: 1);
var parser = SeparatedList(item, separator, true);
This parser is implemented as a combination of several other parser types including List, Rule, First and Combine.
Sequential Parser
The Sequential
parser allows turning a parser graph into a block of sequential code. This allows you to use procedural logic to aid in parsing and to set breakpoints between parsers to get maximum debuggability. Some grammars are best parsed using a stack or other mechanism, instead of the recursive descent algorithm used by ParserObjects, so the Sequential parser allows you to use those algorithms instead. The downside is that the Sequential Parser does not work with some features like BNF stringification or .Replace()
/.ReplaceChild()
operations.
var parser = Sequential(t =>
{
var type = t.Parse(Word());
if (type == 'decimal')
{
var colon = t.Parse(Match(':'));
var value = t.Parse(Integer());
return value;
}
if (type == 'hex')
{
var colon = t.Parse(Match(':'));
var value = t.Parse(HexadecimalInteger());
return value;
}
return 0;
});
The t
object assists in performing the parse and it has ability to handle errors by causing the whole Sequential
parser to fail if any of the child parsers fail.
Try Parser
The Try
parser catches user-thrown exceptions from within the parse and handles them. When an exception is caught, the input sequence is rewound to the location where the Try
parser began.
var parser = Try(innerParser, ex => {...}, bubble: true);
The second parameter is a callback to allow examining the exception when it is received. This can be a useful place to set a breakpoint during debugging. The third parameter bubble
tells whether to rethrow the exception (true
) or to handle the exception and return a failure result (false
).
Matching Parsers
These parsers help to simplify matching of literal patterns.
Match Pattern Parser
The MatchPatternParser
takes a literal list of values, and attempts to match these against the input sequence. If all input items match, in order, the values will be returned as a list. (some of the below examples take advantage of the fact that a string
is an IEnumerable<char>
to help simplify)
var parser = Match(new char[] { 'a', 'b', 'c', 'd' });
var parser = Match("abcd");
This is functionally equivalent (though faster and more succinct) to a combination of the Rule
and MatchPredicate
parsers:
var parser = Rule(
Match(c => c == 'a'),
Match(c => c == 'b'),
Match(c => c == 'c'),
Match(c => c == 'd')
(a, b, c, d) => new [] { a, b, c, d }
);
Trie Parser
The Trie
parser uses a trie to find the longest match in a list of possible literal sequences. This is a useful optimization for keyword and operator literals, where individual patterns may have overlapping prefixes. The ParserObjects library provides IReadOnlyTrie<TKey, TResult>
and IInsertableTrie<TKey, TResult>
abstractions for this purpose.
var parser = Trie(trie);
var parser = trie.ToParser();
var parser = Trie(trie => trie.Add(...));
var parser = MatchAny("value", "value2", "value3");
The MatchAny
parser is implemented using the Trie
mechanism internally, and works only on char
input, string
output scenarios.
Transforming parsers
These parsers exist to transform results from one form to another.
Transform Parser
The Transform
parser transforms the output of an inner parser. If the inner parser fails the Transform
parser fails. If the inner parser succeeds, the Transform
parser will return a transformed result.
var parser = Transform(innerParser, r => ...);
var parser = innerParser.Transform(r => ...);
Transform Result Parser
The TransformResult
parser has an opportunity to transform the entire result, including all metadata, and it operates even when the result is a failure result.
var parser = TransformResult(inner, (state, result) => { ... });
Transform Error Parser
The TransformError
parser is implemented by the TransformResult
parser, but the callback only executes when the result is a failure. This is used to transform the result to, for example, provide a better error message.
var parser = TransformError(parser, (state, errorResult) => { ... });
Recursive Parsers
These parsers exist to help simplify certain recursion scenarios, especially in parsing equations and mathematical expressions. They are not helpful in all recursion scenarios.
Left Apply Parser
The LeftApplyParser
is a parser for left-associative parsing. The left value is parsed first and the value of it is applied to the right side production rule. The value of the right parser will then be used as the new left value and it will attempt to continue until a right parser does not match. The pseudo-BNF for it is:
self := <self> <right> | <item>
var parser = LeftApply(
itemParser,
left => Rule(
left,
...
)
);
Right Apply Parser
The RightApply
is for right-associative recursion. It is conceptually similar to the LeftApply
parser, but with right-recursion instead. It parses an item and then attempts to parse a separator followed by a recursion to itself. The pseudo-BNF for it is:
self := <item> (<middle> <self>)?
var parser = RightApply(item, middle, (l, m, r) => ...);
This same recursive functionality can be reproduced by a combination of Deferred
, First
, and Rule
:
IParser<char, string> parserCore = null;
var parser = Deferred(() => parserCore);
parserCore = First(
Rule(
item,
middle,
parser,
(l, m, r) => ...
),
item
);
Pratt Parser
The Pratt
parser is an implementation of the Pratt parsing algorithm, which may be particularly helpful with parsing mathematical expressions.
var parser = Pratt(config => { ... });
For detailed information about configuring and using the Pratt
parser, see the Pratt Parser page. It may be simpler to use in many situations than the LeftApply
and RightApply
parsers are.
Referencing Parsers
These parsers exist to help with referencing issues, to help resolve circular dependencies or decide on which parser to use at parse-time.
Create Parser
The Create
parser creates a parser at parse time using information available in the current parse state. Create parser looks similar to the Deferred
parser, though has a few important semantic differences: The create callback takes the ParseState
, and it cannot be used with find/replace operations. The Create parser is expected to create new parser instances at different times, so it is not considered to have “children”. This means that the parser returns by the Create parser will not be visible to Visitors.
var parser = new CreateParser<TInput, TOutput>(state => { ... });
var parser = Create(state => { ... });
Deferred Parser
The Deferred
parser references another parser and resolves the reference at parse time instead of at declaration time. This allows your parser to handle recursion and circular references. The parser returned from the Deferred parser is expected by the system to be the same throughout the entire parse and may be cached after first access. Because the parser returned by Deferred is expected to be static and available at any time after the parser graph is created, the parser can be used with find/replace operations and should correctly work with BNF stringification.
var parser = new DeferredParser<TInput, TOutput>(() => targetParser);
var parser = Deferred(() => targetParser);
Replaceable Parser
The Replaceable
parser references an inner parser and invokes it transparently. However, the replaceable parser allows the inner parser to be replaced in-place without cloning. This is useful in cases where you want to make modifications to the parser tree without creating a whole new tree.
var parser = Replaceable(innerParser);
var parser = innerParser.Replaceable();
If an inner parser is not explicitly specified, the inner parser will be a Fail
parser. These two lines are equivalent:
var parser = Replaceable<TOutput>();
var parser = Replaceable(Fail<TOutput>());
It is extremely helpful to name your replaceable parsers so you can quickly find and replace values by name.