Citrus :: Parsing Expressions for Ruby
Citrus is a compact and powerful parsing library for Ruby that combines the elegance and expressiveness of the language with the simplicity and power of parsing expressions.
Via RubyGems:
$ gem install citrus
From a local copy:
$ git clone git://github.com/mjackson/citrus.git
$ cd citrus
$ rake package install
In order to be able to use Citrus effectively, you must first understand the difference between syntax and semantics. Syntax is a set of rules that govern the way letters and punctuation may be used in a language. For example, English syntax dictates that proper nouns should start with a capital letter and that sentences should end with a period.
Semantics are the rules by which meaning may be derived in a language. For example, as you read a book you are able to make some sense of the particular way in which words on a page are combined to form thoughts and express ideas because you understand what the words themselves mean and you understand what they mean collectively.
Computers use a similar process when interpreting code. First, the code must be parsed into recognizable symbols or tokens. These tokens may then be passed to an interpreter which is responsible for forming actual instructions from them.
Citrus is a pure Ruby library that allows you to perform both lexical analysis and semantic interpretation quickly and easily. Using Citrus you can write powerful parsers that are simple to understand and easy to create and maintain.
In Citrus, there are three main types of objects: rules, grammars, and matches.
A Rule is an object that specifies some matching behavior on a string. There are two types of rules: terminals and non-terminals. Terminals can be either Ruby strings or regular expressions that specify some input to match. For example, a terminal created from the string "end" would match any sequence of the characters "e", "n", and "d", in that order. Terminals created from regular expressions may match any sequence of characters that can be generated from that expression.
Non-terminals are rules that may contain other rules but do not themselves match directly on the input. For example, a Repeat is a non-terminal that may contain one other rule that will try and match a certain number of times. Several other types of non-terminals are available that will be discussed later.
Rule objects may also have semantic information associated with them in the form of Ruby modules. Rules use these modules to extend the matches they create.
A Grammar is a container for rules. Usually the rules in a grammar collectively form a complete specification for some language, or a well-defined subset thereof.
A Citrus grammar is really just a souped-up Ruby
module. These modules may be
included in other grammar modules in the same way that Ruby modules are normally
used. This property allows you to divide a complex grammar into more manageable,
reusable pieces that may be combined at runtime. Any rule with the same name as
a rule in an included grammar may access that rule with a mechanism similar to
Ruby's super
keyword.
A Match object represents a successful recognition of some piece of the input. Matches are created by rule objects during a parse.
Matches are arranged in a tree structure where any match may contain any number of other matches. Each match contains information about its own subtree. The structure of the tree is determined by the way in which the rule that generated each match is used in the grammar. For example, a match that is created from a nonterminal rule that contains several other terminals will likewise contain several matches, one for each terminal. However, this is an implementation detail and should be relatively transparent to the user.
Match objects may be extended with semantic information in the form of methods. These methods should provide various interpretations for the semantic value of a match.
The most straightforward way to compose a Citrus grammar is to use Citrus' own custom grammar syntax. This syntax borrows heavily from Ruby, so it should already be familiar to Ruby programmers.
Terminals may be represented by a string or a regular expression. Both follow the same rules as Ruby string and regular expression literals.
'abc' # match "abc"
"abc\n" # match "abc\n"
/abc/i # match "abc" in any case
/\xFF/ # match "\xFF"
Character classes and the dot (match anything) symbol are supported as well for compatibility with other parsing expression implementations.
[a-z0-9] # match any lowercase letter or digit
[\x00-\xFF] # match any octet
. # match any single character, including new lines
Also, strings may use backticks instead of quotes to indicate that they should match in a case-insensitive manner.
`abc` # match "abc" in any case
Besides case sensitivity, case-insensitive strings have the same behavior as double quoted strings.
See Terminal and StringTerminal for more information.
Quantifiers may be used after any expression to specify a number of times it
must match. The universal form of a quantifier is N*M
where N
is the minimum
and M
is the maximum number of times the expression may match.
'abc'1*2 # match "abc" a minimum of one, maximum of two times
'abc'1* # match "abc" at least once
'abc'*2 # match "abc" a maximum of twice
Additionally, the minimum and maximum may be omitted entirely to specify that an expression may match zero or more times.
'abc'* # match "abc" zero or more times
The +
and ?
operators are supported as well for the common cases of 1*
and
*1
respectively.
'abc'+ # match "abc" one or more times
'abc'? # match "abc" zero or one time
See Repeat for more information.
Both positive and negative lookahead are supported in Citrus. Use the &
and
!
operators to indicate that an expression either should or should not match.
In neither case is any input consumed.
'a' &'b' # match an "a" that is followed by a "b"
'a' !'b' # match an "a" that is not followed by a "b"
!'a' . # match any character except for "a"
A special form of lookahead is also supported which will match any character that does not match a given expression.
~'a' # match all characters until an "a"
~/xyz/ # match all characters until /xyz/ matches
When using this operator (the tilde), at least one character must be consumed for the rule to succeed.
See AndPredicate, NotPredicate, and ButPredicate for more information.
Sequences of expressions may be separated by a space to indicate that the rules should match in that order.
'a' 'b' 'c' # match "a", then "b", then "c"
'a' [0-9] # match "a", then a numeric digit
See Sequence for more information.
Ordered choice is indicated by a vertical bar that separates two expressions. When using choice, each expression is tried in order. When one matches, the rule returns the match immediately without trying the remaining rules.
'a' | 'b' # match "a" or "b"
'a' 'b' | 'c' # match "a" then "b" (in sequence), or "c"
It is important to note when using ordered choice that any operator binds more tightly than the vertical bar. A full chart of operators and their respective levels of precedence is below.
See Choice for more information.
Match objects may be referred to by a different name than the rule that originally generated them. Labels are added by placing the label and a colon immediately preceding any expression.
chars:/[a-z]+/ # the characters matched by the regular expression
# may be referred to as "chars" in an extension
# method
Extensions may be specified using either "module" or "block" syntax. When using module syntax, specify the name of a module that is used to extend match objects in between less than and greater than symbols.
[a-z0-9]5*9 <CouponCode> # match a string that consists of any lower
# cased letter or digit between 5 and 9
# times and extend the match with the
# CouponCode module
Additionally, extensions may be specified inline using curly braces. When using
this method, the code inside the curly braces may be invoked by calling the
value
method on the match object.
[0-9] { to_str.to_i } # match any digit and return its integer value when
# calling the #value method on the match object
Note that when using the inline block method you may also specify arguments in between vertical bars immediately following the opening curly brace, just like in Ruby blocks.
When including a grammar inside another, all rules in the child that have the
same name as a rule in the parent also have access to the super
keyword to
invoke the parent rule.
grammar Number
rule number
[0-9]+
end
end
grammar FloatingPoint
include Number
rule number
super ('.' super)?
end
end
In the example above, the FloatingPoint
grammar includes Number
. Both have a
rule named number
, so FloatingPoint#number
has access to Number#number
by
means of using super
.
See Super for more information.
The following table contains a list of all Citrus symbols and operators and their precedence. A higher precedence indicates tighter binding.
Operator | Name | Precedence |
---|---|---|
'' |
String (single quoted) | 7 |
"" |
String (double quoted) | 7 |
`` |
String (case insensitive) | 7 |
[] |
Character class | 7 |
. |
Dot (any character) | 7 |
// |
Regular expression | 7 |
() |
Grouping | 7 |
* |
Repetition (arbitrary) | 6 |
+ |
Repetition (one or more) | 6 |
? |
Repetition (zero or one) | 6 |
& |
And predicate | 5 |
! |
Not predicate | 5 |
~ |
But predicate | 5 |
<> |
Extension (module name) | 4 |
{} |
Extension (literal) | 4 |
: |
Label | 3 |
e1 e2 |
Sequence | 2 |
e1 | e2 |
Ordered choice | 1 |
As is common in many programming languages, parentheses may be used to override
the normal binding order of operators. In the following example parentheses are
used to make the vertical bar between 'b'
and 'c'
bind tighter than the
space between 'a'
and 'b'
.
'a' ('b' | 'c') # match "a", then "b" or "c"
Below is an example of a simple grammar that is able to parse strings of
integers separated by any amount of white space and a +
symbol.
grammar Addition
rule additive
number plus (additive | number)
end
rule number
[0-9]+ space
end
rule plus
'+' space
end
rule space
[ \t]*
end
end
Several things to note about the above example:
- Grammar and rule declarations end with the
end
keyword - A sequence of rules is created by separating expressions with a space
- Likewise, ordered choice is represented with a vertical bar
- Parentheses may be used to override the natural binding order
- Rules may refer to other rules in their own definitions simply by using the other rule's name
- Any expression may be followed by a quantifier
The grammar above is able to parse simple mathematical expressions such as "1+2" and "1 + 2+3", but it does not have enough semantic information to be able to actually interpret these expressions.
At this point, when the grammar parses a string it generates a tree of Match objects. Each match is created by a rule and may itself be comprised of any number of submatches.
Submatches are created whenever a rule contains another rule. For example, in
the grammar above number
matches a string of digits followed by white space.
Thus, a match generated by this rule will contain two submatches.
We can define a method inside a set of curly braces that will be used to extend
a particular rule's matches. This works in similar fashion to using Ruby's
blocks. Let's extend the Addition
grammar using this technique.
grammar Addition
rule additive
(number plus term:(additive | number)) {
capture(:number).value + capture(:term).value
}
end
rule number
([0-9]+ space) {
to_str.to_i
}
end
rule plus
'+' space
end
rule space
[ \t]*
end
end
In this version of the grammar we have added two semantic blocks, one each for
the additive
and number
rules. These blocks contain code that we can
execute by calling value
on match objects that result from those rules. It's
easiest to explain what is going on here by starting with the lowest level
block, which is defined within number
.
Inside this block we see a call to another method, namely to_str
. When called
in the context of a match object, this method returns the match's internal
string object. Thus, the call to to_str.to_i
should return the integer value
of the match.
Similarly, matches created by additive
will also have a value
method. Notice
the use of the term
label within the rule definition. This label allows the
match that is created by the choice between additive
and number
to be
retrieved using capture(:term)
. The value of an additive match is determined
to be the values of its number
and term
matches added together using Ruby's
addition operator. Note that the plural form captures(:term)
can be used to
get an array of matches for a given label (e.g. when the label belongs to a
repetition).
Since additive
is the first rule defined in the grammar, any match that
results from parsing a string with this grammar will have a value
method that
can be used to recursively calculate the collective value of the entire match
tree.
To give it a try, save the code for the Addition
grammar in a file called
addition.citrus. Next, assuming you have the Citrus
gem installed, try the following sequence of
commands in a terminal.
$ irb
> require 'citrus'
=> true
> Citrus.load 'addition'
=> [Addition]
> m = Addition.parse '1 + 2 + 3'
=> #<Citrus::Match ...
> m.value
=> 6
Congratulations! You just ran your first piece of Citrus code.
One interesting thing to notice about the above sequence of commands is the
return value of Citrus#load.
When you use Citrus.load
to load a grammar file (and likewise
Citrus#eval to
evaluate a raw string of grammar code), the return value is an array of all the
grammars present in that file.
Take a look at calc.citrus for an example of a calculator that is able to parse and evaluate more complex mathematical expressions.
If you need more than just a value
method on your match object, you can attach
additional methods as well. There are two ways to do this. The first lets you
define additional methods inline in your semantic block. This block will be used
to create a new Module using Module#new.
Using the Addition
example above, we might refactor the additive
rule to
look like this:
rule additive
(number plus term:(additive | number)) {
def lhs
capture(:number).value
end
def rhs
capture(:term).value
end
def value
lhs + rhs
end
}
end
Now, in addition to having a value
method, matches that result from the
additive
rule will have a lhs
and a rhs
method as well. Although not
particularly useful in this example, this technique can be useful when unit
testing more complex rules. For example, using this method you might make the
following assertions in a unit test:
match = Addition.parse('1 + 4')
assert_equal(1, match.lhs)
assert_equal(4, match.rhs)
assert_equal(5, match.value)
If you would like to abstract away the code in a semantic block, simply create a separate Ruby module (in another file) that contains the extension methods you want and use the angle bracket notation to indicate that a rule should use that module when extending matches.
To demonstrate this method with the above example, in a Ruby file you would define the following module.
module Additive
def lhs
capture(:number).value
end
def rhs
capture(:term).value
end
def value
lhs + rhs
end
end
Then, in your Citrus grammar file the rule definition would look like this:
rule additive
(number plus term:(additive | number)) <Additive>
end
This method of defining extensions can help keep your grammar files cleaner.
However, you do need to make sure that your extension modules are already loaded
before using Citrus.load
to load your grammar file.
Citrus was designed to facilitate simple and powerful testing of grammars. To
demonstrate how this is to be done, we'll use the Addition
grammar from our
previous example. The following code demonstrates a simple test
case that could be used to test that our grammar works properly.
class AdditionTest < Test::Unit::TestCase
def test_additive
match = Addition.parse('23 + 12', :root => :additive)
assert(match)
assert_equal('23 + 12', match)
assert_equal(35, match.value)
end
def test_number
match = Addition.parse('23', :root => :number)
assert(match)
assert_equal('23', match)
assert_equal(23, match.value)
end
end
The key here is using the :root
option when performing the parse to specify
the name of the rule at which the parse should start. In test_number
, since
:number
was given the parse will start at that rule as if it were the root
rule of the entire grammar. The ability to change the root rule on the fly like
this enables easy unit testing of the entire grammar.
Also note that because match objects are themselves strings, assertions may be made to test equality of match objects with string values.
When a parse fails, a ParseError object is generated which provides a wealth of information about exactly where the parse failed including the offset, line number, line text, and line offset. Using this object, you could possibly provide some useful feedback to the user about why the input was bad. The following code demonstrates one way to do this.
def parse_some_stuff(stuff)
match = StuffGrammar.parse(stuff)
rescue Citrus::ParseError => e
raise ArgumentError, "Invalid stuff on line %d, offset %d!" %
[e.line_number, e.line_offset]
end
In addition to useful error objects, Citrus also includes a means of visualizing
match trees in the console via Match#dump
. This can help when determining
which rules are generating which matches and how they are organized in the
match tree.
Several files are included in the Citrus repository that make it easier to work with grammar files in various editors.
To install the Citrus TextMate bundle, simply
double-click on the Citrus.tmbundle
file in the extras
directory.
To install the Vim scripts, copy the files in
extras/vim
to a directory in Vim's
runtimepath.
The project source directory contains several example scripts that demonstrate how grammars are to be constructed and used. Each Citrus file in the examples directory has an accompanying Ruby file that contains a suite of tests for that particular file.
The best way to run any of these examples is to pass the name of the Ruby file directly to the Ruby interpreter on the command line, e.g.:
$ ruby -Ilib examples/calc_test.rb
This particular invocation uses the -I
flag to ensure that you are using the
version of Citrus that was bundled with that particular example file (i.e. the
version that is contained in the lib
directory).
Discussion around Citrus happens on the citrus-users Google group.
The primary resource for all things to do with parsing expressions can be found on the original Packrat and Parsing Expression Grammars page at MIT.
Also, a useful summary of parsing expression grammars can be found on Wikipedia.
Citrus draws inspiration from another Ruby library for writing parsing expression grammars, Treetop. While Citrus' syntax is similar to that of Treetop, it's not identical. The link is included here for those who may wish to explore an alternative implementation.
Copyright 2010-2011 Michael Jackson
Permission is hereby granted, free of charge, to any person obtaining a copy of this software and associated documentation files (the "Software"), to deal in the Software without restriction, including without limitation the rights to use, copy, modify, merge, publish, distribute, sublicense, and/or sell copies of the Software, and to permit persons to whom the Software is furnished to do so, subject to the following conditions:
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