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<!DOCTYPE html PUBLIC "-//W3C//DTD XHTML 1.0 Strict//EN" "http://www.w3.org/TR/xhtml1/DTD/xhtml1-strict.dtd"> <html xmlns="http://www.w3.org/1999/xhtml" xml:lang="en" lang="en"> <head> <title>LPeg - Parsing Expression Grammars For Lua</title> <link rel="stylesheet" href="http://www.inf.puc-rio.br/~roberto/lpeg/doc.css" type="text/css"/> <meta http-equiv="Content-Type" content="text/html; charset=UTF-8"/> </head> <body> <!-- $Id: lpeg.html $ --> <div id="container"> <div id="product"> <div id="product_logo"> <a href="http://www.inf.puc-rio.br/~roberto/lpeg/"> <img alt="LPeg logo" src="lpeg-128.gif"/></a> </div> <div id="product_name"><big><strong>LPeg</strong></big></div> <div id="product_description"> Parsing Expression Grammars For Lua, version 1.0 </div> </div> <!-- id="product" --> <div id="main"> <div id="navigation"> <h1>LPeg</h1> <ul> <li><strong>Home</strong> <ul> <li><a href="#intro">Introduction</a></li> <li><a href="#func">Functions</a></li> <li><a href="#basic">Basic Constructions</a></li> <li><a href="#grammar">Grammars</a></li> <li><a href="#captures">Captures</a></li> <li><a href="#ex">Some Examples</a></li> <li><a href="re.html">The <code>re</code> Module</a></li> <li><a href="#download">Download</a></li> <li><a href="#license">License</a></li> </ul> </li> </ul> </div> <!-- id="navigation" --> <div id="content"> <h2><a name="intro">Introduction</a></h2> <p> <em>LPeg</em> is a new pattern-matching library for Lua, based on <a href="http://pdos.csail.mit.edu/%7Ebaford/packrat/"> Parsing Expression Grammars</a> (PEGs). This text is a reference manual for the library. For a more formal treatment of LPeg, as well as some discussion about its implementation, see <a href="http://www.inf.puc-rio.br/~roberto/docs/peg.pdf"> A Text Pattern-Matching Tool based on Parsing Expression Grammars</a>. (You may also be interested in my <a href="http://vimeo.com/1485123">talk about LPeg</a> given at the III Lua Workshop.) </p> <p> Following the Snobol tradition, LPeg defines patterns as first-class objects. That is, patterns are regular Lua values (represented by userdata). The library offers several functions to create and compose patterns. With the use of metamethods, several of these functions are provided as infix or prefix operators. On the one hand, the result is usually much more verbose than the typical encoding of patterns using the so called <em>regular expressions</em> (which typically are not regular expressions in the formal sense). On the other hand, first-class patterns allow much better documentation (as it is easy to comment the code, to break complex definitions in smaller parts, etc.) and are extensible, as we can define new functions to create and compose patterns. </p> <p> For a quick glance of the library, the following table summarizes its basic operations for creating patterns: </p> <table border="1"> <tbody><tr><td><b>Operator</b></td><td><b>Description</b></td></tr> <tr><td><a href="#op-p"><code>lpeg.P(string)</code></a></td> <td>Matches <code>string</code> literally</td></tr> <tr><td><a href="#op-p"><code>lpeg.P(n)</code></a></td> <td>Matches exactly <code>n</code> characters</td></tr> <tr><td><a href="#op-s"><code>lpeg.S(string)</code></a></td> <td>Matches any character in <code>string</code> (Set)</td></tr> <tr><td><a href="#op-r"><code>lpeg.R("<em>xy</em>")</code></a></td> <td>Matches any character between <em>x</em> and <em>y</em> (Range)</td></tr> <tr><td><a href="#op-pow"><code>patt^n</code></a></td> <td>Matches at least <code>n</code> repetitions of <code>patt</code></td></tr> <tr><td><a href="#op-pow"><code>patt^-n</code></a></td> <td>Matches at most <code>n</code> repetitions of <code>patt</code></td></tr> <tr><td><a href="#op-mul"><code>patt1 * patt2</code></a></td> <td>Matches <code>patt1</code> followed by <code>patt2</code></td></tr> <tr><td><a href="#op-add"><code>patt1 + patt2</code></a></td> <td>Matches <code>patt1</code> or <code>patt2</code> (ordered choice)</td></tr> <tr><td><a href="#op-sub"><code>patt1 - patt2</code></a></td> <td>Matches <code>patt1</code> if <code>patt2</code> does not match</td></tr> <tr><td><a href="#op-unm"><code>-patt</code></a></td> <td>Equivalent to <code>("" - patt)</code></td></tr> <tr><td><a href="#op-len"><code>#patt</code></a></td> <td>Matches <code>patt</code> but consumes no input</td></tr> <tr><td><a href="#op-behind"><code>lpeg.B(patt)</code></a></td> <td>Matches <code>patt</code> behind the current position, consuming no input</td></tr> </tbody></table> <p>As a very simple example, <code>lpeg.R("09")^1</code> creates a pattern that matches a non-empty sequence of digits. As a not so simple example, <code>-lpeg.P(1)</code> (which can be written as <code>lpeg.P(-1)</code>, or simply <code>-1</code> for operations expecting a pattern) matches an empty string only if it cannot match a single character; so, it succeeds only at the end of the subject. </p> <p> LPeg also offers the <a href="re.html"><code>re</code> module</a>, which implements patterns following a regular-expression style (e.g., <code>[09]+</code>). (This module is 260 lines of Lua code, and of course it uses LPeg to parse regular expressions and translate them to regular LPeg patterns.) </p> <h2><a name="func">Functions</a></h2> <h3><a name="f-match"></a><code>lpeg.match (pattern, subject [, init])</code></h3> <p> The matching function. It attempts to match the given pattern against the subject string. If the match succeeds, returns the index in the subject of the first character after the match, or the <a href="#captures">captured values</a> (if the pattern captured any value). </p> <p> An optional numeric argument <code>init</code> makes the match start at that position in the subject string. As usual in Lua libraries, a negative value counts from the end. </p> <p> Unlike typical pattern-matching functions, <code>match</code> works only in <em>anchored</em> mode; that is, it tries to match the pattern with a prefix of the given subject string (at position <code>init</code>), not with an arbitrary substring of the subject. So, if we want to find a pattern anywhere in a string, we must either write a loop in Lua or write a pattern that matches anywhere. This second approach is easy and quite efficient; see <a href="#ex">examples</a>. </p> <h3><a name="f-type"></a><code>lpeg.type (value)</code></h3> <p> If the given value is a pattern, returns the string <code>"pattern"</code>. Otherwise returns nil. </p> <h3><a name="f-version"></a><code>lpeg.version ()</code></h3> <p> Returns a string with the running version of LPeg. </p> <h3><a name="f-setstack"></a><code>lpeg.setmaxstack (max)</code></h3> <p> Sets a limit for the size of the backtrack stack used by LPeg to track calls and choices. (The default limit is 400.) Most well-written patterns need little backtrack levels and therefore you seldom need to change this limit; before changing it you should try to rewrite your pattern to avoid the need for extra space. Nevertheless, a few useful patterns may overflow. Also, with recursive grammars, subjects with deep recursion may also need larger limits. </p> <h2><a name="basic">Basic Constructions</a></h2> <p> The following operations build patterns. All operations that expect a pattern as an argument may receive also strings, tables, numbers, booleans, or functions, which are translated to patterns according to the rules of function <a href="#op-p"><code>lpeg.P</code></a>. </p> <h3><a name="op-p"></a><code>lpeg.P (value)</code></h3> <p> Converts the given value into a proper pattern, according to the following rules: </p> <ul> <li><p> If the argument is a pattern, it is returned unmodified. </p></li> <li><p> If the argument is a string, it is translated to a pattern that matches the string literally. </p></li> <li><p> If the argument is a non-negative number <em>n</em>, the result is a pattern that matches exactly <em>n</em> characters. </p></li> <li><p> If the argument is a negative number <em>-n</em>, the result is a pattern that succeeds only if the input string has less than <em>n</em> characters left: <code>lpeg.P(-n)</code> is equivalent to <code>-lpeg.P(n)</code> (see the <a href="#op-unm">unary minus operation</a>). </p></li> <li><p> If the argument is a boolean, the result is a pattern that always succeeds or always fails (according to the boolean value), without consuming any input. </p></li> <li><p> If the argument is a table, it is interpreted as a grammar (see <a href="#grammar">Grammars</a>). </p></li> <li><p> If the argument is a function, returns a pattern equivalent to a <a href="#matchtime">match-time capture</a> over the empty string. </p></li> </ul> <h3><a name="op-behind"></a><code>lpeg.B(patt)</code></h3> <p> Returns a pattern that matches only if the input string at the current position is preceded by <code>patt</code>. Pattern <code>patt</code> must match only strings with some fixed length, and it cannot contain captures. </p> <p> Like the <a href="#op-len">and predicate</a>, this pattern never consumes any input, independently of success or failure. </p> <h3><a name="op-r"></a><code>lpeg.R ({range})</code></h3> <p> Returns a pattern that matches any single character belonging to one of the given <em>ranges</em>. Each <code>range</code> is a string <em>xy</em> of length 2, representing all characters with code between the codes of <em>x</em> and <em>y</em> (both inclusive). </p> <p> As an example, the pattern <code>lpeg.R("09")</code> matches any digit, and <code>lpeg.R("az", "AZ")</code> matches any ASCII letter. </p> <h3><a name="op-s"></a><code>lpeg.S (string)</code></h3> <p> Returns a pattern that matches any single character that appears in the given string. (The <code>S</code> stands for <em>Set</em>.) </p> <p> As an example, the pattern <code>lpeg.S("+-*/")</code> matches any arithmetic operator. </p> <p> Note that, if <code>s</code> is a character (that is, a string of length 1), then <code>lpeg.P(s)</code> is equivalent to <code>lpeg.S(s)</code> which is equivalent to <code>lpeg.R(s..s)</code>. Note also that both <code>lpeg.S("")</code> and <code>lpeg.R()</code> are patterns that always fail. </p> <h3><a name="op-v"></a><code>lpeg.V (v)</code></h3> <p> This operation creates a non-terminal (a <em>variable</em>) for a grammar. The created non-terminal refers to the rule indexed by <code>v</code> in the enclosing grammar. (See <a href="#grammar">Grammars</a> for details.) </p> <h3><a name="op-locale"></a><code>lpeg.locale ([table])</code></h3> <p> Returns a table with patterns for matching some character classes according to the current locale. The table has fields named <code>alnum</code>, <code>alpha</code>, <code>cntrl</code>, <code>digit</code>, <code>graph</code>, <code>lower</code>, <code>print</code>, <code>punct</code>, <code>space</code>, <code>upper</code>, and <code>xdigit</code>, each one containing a correspondent pattern. Each pattern matches any single character that belongs to its class. </p> <p> If called with an argument <code>table</code>, then it creates those fields inside the given table and returns that table. </p> <h3><a name="op-len"></a><code>#patt</code></h3> <p> Returns a pattern that matches only if the input string matches <code>patt</code>, but without consuming any input, independently of success or failure. (This pattern is called an <em>and predicate</em> and it is equivalent to <em>&patt</em> in the original PEG notation.) </p> <p> This pattern never produces any capture. </p> <h3><a name="op-unm"></a><code>-patt</code></h3> <p> Returns a pattern that matches only if the input string does not match <code>patt</code>. It does not consume any input, independently of success or failure. (This pattern is equivalent to <em>!patt</em> in the original PEG notation.) </p> <p> As an example, the pattern <code>-lpeg.P(1)</code> matches only the end of string. </p> <p> This pattern never produces any captures, because either <code>patt</code> fails or <code>-patt</code> fails. (A failing pattern never produces captures.) </p> <h3><a name="op-add"></a><code>patt1 + patt2</code></h3> <p> Returns a pattern equivalent to an <em>ordered choice</em> of <code>patt1</code> and <code>patt2</code>. (This is denoted by <em>patt1 / patt2</em> in the original PEG notation, not to be confused with the <code>/</code> operation in LPeg.) It matches either <code>patt1</code> or <code>patt2</code>, with no backtracking once one of them succeeds. The identity element for this operation is the pattern <code>lpeg.P(false)</code>, which always fails. </p> <p> If both <code>patt1</code> and <code>patt2</code> are character sets, this operation is equivalent to set union. </p> <pre class="example"> lower = lpeg.R("az") upper = lpeg.R("AZ") letter = lower + upper </pre> <h3><a name="op-sub"></a><code>patt1 - patt2</code></h3> <p> Returns a pattern equivalent to <em>!patt2 patt1</em>. This pattern asserts that the input does not match <code>patt2</code> and then matches <code>patt1</code>. </p> <p> When successful, this pattern produces all captures from <code>patt1</code>. It never produces any capture from <code>patt2</code> (as either <code>patt2</code> fails or <code>patt1 - patt2</code> fails). </p> <p> If both <code>patt1</code> and <code>patt2</code> are character sets, this operation is equivalent to set difference. Note that <code>-patt</code> is equivalent to <code>"" - patt</code> (or <code>0 - patt</code>). If <code>patt</code> is a character set, <code>1 - patt</code> is its complement. </p> <h3><a name="op-mul"></a><code>patt1 * patt2</code></h3> <p> Returns a pattern that matches <code>patt1</code> and then matches <code>patt2</code>, starting where <code>patt1</code> finished. The identity element for this operation is the pattern <code>lpeg.P(true)</code>, which always succeeds. </p> <p> (LPeg uses the <code>*</code> operator [instead of the more obvious <code>..</code>] both because it has the right priority and because in formal languages it is common to use a dot for denoting concatenation.) </p> <h3><a name="op-pow"></a><code>patt^n</code></h3> <p> If <code>n</code> is nonnegative, this pattern is equivalent to <em>patt<sup>n</sup> patt*</em>: It matches <code>n</code> or more occurrences of <code>patt</code>. </p> <p> Otherwise, when <code>n</code> is negative, this pattern is equivalent to <em>(patt?)<sup>-n</sup></em>: It matches at most <code>|n|</code> occurrences of <code>patt</code>. </p> <p> In particular, <code>patt^0</code> is equivalent to <em>patt*</em>, <code>patt^1</code> is equivalent to <em>patt+</em>, and <code>patt^-1</code> is equivalent to <em>patt?</em> in the original PEG notation. </p> <p> In all cases, the resulting pattern is greedy with no backtracking (also called a <em>possessive</em> repetition). That is, it matches only the longest possible sequence of matches for <code>patt</code>. </p> <h2><a name="grammar">Grammars</a></h2> <p> With the use of Lua variables, it is possible to define patterns incrementally, with each new pattern using previously defined ones. However, this technique does not allow the definition of recursive patterns. For recursive patterns, we need real grammars. </p> <p> LPeg represents grammars with tables, where each entry is a rule. </p> <p> The call <code>lpeg.V(v)</code> creates a pattern that represents the nonterminal (or <em>variable</em>) with index <code>v</code> in a grammar. Because the grammar still does not exist when this function is evaluated, the result is an <em>open reference</em> to the respective rule. </p> <p> A table is <em>fixed</em> when it is converted to a pattern (either by calling <code>lpeg.P</code> or by using it wherein a pattern is expected). Then every open reference created by <code>lpeg.V(v)</code> is corrected to refer to the rule indexed by <code>v</code> in the table. </p> <p> When a table is fixed, the result is a pattern that matches its <em>initial rule</em>. The entry with index 1 in the table defines its initial rule. If that entry is a string, it is assumed to be the name of the initial rule. Otherwise, LPeg assumes that the entry 1 itself is the initial rule. </p> <p> As an example, the following grammar matches strings of a's and b's that have the same number of a's and b's: </p> <pre class="example"> equalcount = lpeg.P{ "S"; -- initial rule name S = "a" * lpeg.V"B" + "b" * lpeg.V"A" + "", A = "a" * lpeg.V"S" + "b" * lpeg.V"A" * lpeg.V"A", B = "b" * lpeg.V"S" + "a" * lpeg.V"B" * lpeg.V"B", } * -1 </pre> <p> It is equivalent to the following grammar in standard PEG notation: </p> <pre class="example"> S <- 'a' B / 'b' A / '' A <- 'a' S / 'b' A A B <- 'b' S / 'a' B B </pre> <h2><a name="captures">Captures</a></h2> <p> A <em>capture</em> is a pattern that produces values (the so called <em>semantic information</em>) according to what it matches. LPeg offers several kinds of captures, which produces values based on matches and combine these values to produce new values. Each capture may produce zero or more values. </p> <p> The following table summarizes the basic captures: </p> <table border="1"> <tbody><tr><td><b>Operation</b></td><td><b>What it Produces</b></td></tr> <tr><td><a href="#cap-c"><code>lpeg.C(patt)</code></a></td> <td>the match for <code>patt</code> plus all captures made by <code>patt</code></td></tr> <tr><td><a href="#cap-arg"><code>lpeg.Carg(n)</code></a></td> <td>the value of the n<sup>th</sup> extra argument to <code>lpeg.match</code> (matches the empty string)</td></tr> <tr><td><a href="#cap-b"><code>lpeg.Cb(name)</code></a></td> <td>the values produced by the previous group capture named <code>name</code> (matches the empty string)</td></tr> <tr><td><a href="#cap-cc"><code>lpeg.Cc(values)</code></a></td> <td>the given values (matches the empty string)</td></tr> <tr><td><a href="#cap-f"><code>lpeg.Cf(patt, func)</code></a></td> <td>a <em>folding</em> of the captures from <code>patt</code></td></tr> <tr><td><a href="#cap-g"><code>lpeg.Cg(patt [, name])</code></a></td> <td>the values produced by <code>patt</code>, optionally tagged with <code>name</code></td></tr> <tr><td><a href="#cap-p"><code>lpeg.Cp()</code></a></td> <td>the current position (matches the empty string)</td></tr> <tr><td><a href="#cap-s"><code>lpeg.Cs(patt)</code></a></td> <td>the match for <code>patt</code> with the values from nested captures replacing their matches</td></tr> <tr><td><a href="#cap-t"><code>lpeg.Ct(patt)</code></a></td> <td>a table with all captures from <code>patt</code></td></tr> <tr><td><a href="#cap-string"><code>patt / string</code></a></td> <td><code>string</code>, with some marks replaced by captures of <code>patt</code></td></tr> <tr><td><a href="#cap-num"><code>patt / number</code></a></td> <td>the n-th value captured by <code>patt</code>, or no value when <code>number</code> is zero.</td></tr> <tr><td><a href="#cap-query"><code>patt / table</code></a></td> <td><code>table[c]</code>, where <code>c</code> is the (first) capture of <code>patt</code></td></tr> <tr><td><a href="#cap-func"><code>patt / function</code></a></td> <td>the returns of <code>function</code> applied to the captures of <code>patt</code></td></tr> <tr><td><a href="#matchtime"><code>lpeg.Cmt(patt, function)</code></a></td> <td>the returns of <code>function</code> applied to the captures of <code>patt</code>; the application is done at match time</td></tr> </tbody></table> <p> A capture pattern produces its values only when it succeeds. For instance, the pattern <code>lpeg.C(lpeg.P"a"^-1)</code> produces the empty string when there is no <code>"a"</code> (because the pattern <code>"a"?</code> succeeds), while the pattern <code>lpeg.C("a")^-1</code> does not produce any value when there is no <code>"a"</code> (because the pattern <code>"a"</code> fails). A pattern inside a loop or inside a recursive structure produces values for each match. </p> <p> Usually, LPeg does not specify when (and if) it evaluates its captures. (As an example, consider the pattern <code>lpeg.P"a" / func / 0</code>. Because the "division" by 0 instructs LPeg to throw away the results from the pattern, LPeg may or may not call <code>func</code>.) Therefore, captures should avoid side effects. Moreover, most captures cannot affect the way a pattern matches a subject. The only exception to this rule is the so-called <a href="#matchtime"><em>match-time capture</em></a>. When a match-time capture matches, it forces the immediate evaluation of all its nested captures and then calls its corresponding function, which defines whether the match succeeds and also what values are produced. </p> <h3><a name="cap-c"></a><code>lpeg.C (patt)</code></h3> <p> Creates a <em>simple capture</em>, which captures the substring of the subject that matches <code>patt</code>. The captured value is a string. If <code>patt</code> has other captures, their values are returned after this one. </p> <h3><a name="cap-arg"></a><code>lpeg.Carg (n)</code></h3> <p> Creates an <em>argument capture</em>. This pattern matches the empty string and produces the value given as the n<sup>th</sup> extra argument given in the call to <code>lpeg.match</code>. </p> <h3><a name="cap-b"></a><code>lpeg.Cb (name)</code></h3> <p> Creates a <em>back capture</em>. This pattern matches the empty string and produces the values produced by the <em>most recent</em> <a href="#cap-g">group capture</a> named <code>name</code> (where <code>name</code> can be any Lua value). </p> <p> <em>Most recent</em> means the last <em>complete</em> <em>outermost</em> group capture with the given name. A <em>Complete</em> capture means that the entire pattern corresponding to the capture has matched. An <em>Outermost</em> capture means that the capture is not inside another complete capture. </p> <p> In the same way that LPeg does not specify when it evaluates captures, it does not specify whether it reuses values previously produced by the group or re-evaluates them. </p> <h3><a name="cap-cc"></a><code>lpeg.Cc ([value, ...])</code></h3> <p> Creates a <em>constant capture</em>. This pattern matches the empty string and produces all given values as its captured values. </p> <h3><a name="cap-f"></a><code>lpeg.Cf (patt, func)</code></h3> <p> Creates a <em>fold capture</em>. If <code>patt</code> produces a list of captures <em>C<sub>1</sub> C<sub>2</sub> ... C<sub>n</sub></em>, this capture will produce the value <em>func(...func(func(C<sub>1</sub>, C<sub>2</sub>), C<sub>3</sub>)..., C<sub>n</sub>)</em>, that is, it will <em>fold</em> (or <em>accumulate</em>, or <em>reduce</em>) the captures from <code>patt</code> using function <code>func</code>. </p> <p> This capture assumes that <code>patt</code> should produce at least one capture with at least one value (of any type), which becomes the initial value of an <em>accumulator</em>. (If you need a specific initial value, you may prefix a <a href="#cap-cc">constant capture</a> to <code>patt</code>.) For each subsequent capture, LPeg calls <code>func</code> with this accumulator as the first argument and all values produced by the capture as extra arguments; the first result from this call becomes the new value for the accumulator. The final value of the accumulator becomes the captured value. </p> <p> As an example, the following pattern matches a list of numbers separated by commas and returns their addition: </p> <pre class="example"> -- matches a numeral and captures its numerical value number = lpeg.R"09"^1 / tonumber -- matches a list of numbers, capturing their values list = number * ("," * number)^0 -- auxiliary function to add two numbers function add (acc, newvalue) return acc + newvalue end -- folds the list of numbers adding them sum = lpeg.Cf(list, add) -- example of use print(sum:match("10,30,43")) --> 83 </pre> <h3><a name="cap-g"></a><code>lpeg.Cg (patt [, name])</code></h3> <p> Creates a <em>group capture</em>. It groups all values returned by <code>patt</code> into a single capture. The group may be anonymous (if no name is given) or named with the given name (which can be any non-nil Lua value). </p> <p> An anonymous group serves to join values from several captures into a single capture. A named group has a different behavior. In most situations, a named group returns no values at all. Its values are only relevant for a following <a href="#cap-b">back capture</a> or when used inside a <a href="#cap-t">table capture</a>. </p> <h3><a name="cap-p"></a><code>lpeg.Cp ()</code></h3> <p> Creates a <em>position capture</em>. It matches the empty string and captures the position in the subject where the match occurs. The captured value is a number. </p> <h3><a name="cap-s"></a><code>lpeg.Cs (patt)</code></h3> <p> Creates a <em>substitution capture</em>, which captures the substring of the subject that matches <code>patt</code>, with <em>substitutions</em>. For any capture inside <code>patt</code> with a value, the substring that matched the capture is replaced by the capture value (which should be a string). The final captured value is the string resulting from all replacements. </p> <h3><a name="cap-t"></a><code>lpeg.Ct (patt)</code></h3> <p> Creates a <em>table capture</em>. This capture returns a table with all values from all anonymous captures made by <code>patt</code> inside this table in successive integer keys, starting at 1. Moreover, for each named capture group created by <code>patt</code>, the first value of the group is put into the table with the group name as its key. The captured value is only the table. </p> <h3><a name="cap-string"></a><code>patt / string</code></h3> <p> Creates a <em>string capture</em>. It creates a capture string based on <code>string</code>. The captured value is a copy of <code>string</code>, except that the character <code>%</code> works as an escape character: any sequence in <code>string</code> of the form <code>%<em>n</em></code>, with <em>n</em> between 1 and 9, stands for the match of the <em>n</em>-th capture in <code>patt</code>. The sequence <code>%0</code> stands for the whole match. The sequence <code>%%</code> stands for a single <code>%</code>. </p> <h3><a name="cap-num"></a><code>patt / number</code></h3> <p> Creates a <em>numbered capture</em>. For a non-zero number, the captured value is the n-th value captured by <code>patt</code>. When <code>number</code> is zero, there are no captured values. </p> <h3><a name="cap-query"></a><code>patt / table</code></h3> <p> Creates a <em>query capture</em>. It indexes the given table using as key the first value captured by <code>patt</code>, or the whole match if <code>patt</code> produced no value. The value at that index is the final value of the capture. If the table does not have that key, there is no captured value. </p> <h3><a name="cap-func"></a><code>patt / function</code></h3> <p> Creates a <em>function capture</em>. It calls the given function passing all captures made by <code>patt</code> as arguments, or the whole match if <code>patt</code> made no capture. The values returned by the function are the final values of the capture. In particular, if <code>function</code> returns no value, there is no captured value. </p> <h3><a name="matchtime"></a><code>lpeg.Cmt(patt, function)</code></h3> <p> Creates a <em>match-time capture</em>. Unlike all other captures, this one is evaluated immediately when a match occurs (even if it is part of a larger pattern that fails later). It forces the immediate evaluation of all its nested captures and then calls <code>function</code>. </p> <p> The given function gets as arguments the entire subject, the current position (after the match of <code>patt</code>), plus any capture values produced by <code>patt</code>. </p> <p> The first value returned by <code>function</code> defines how the match happens. If the call returns a number, the match succeeds and the returned number becomes the new current position. (Assuming a subject <em>s</em> and current position <em>i</em>, the returned number must be in the range <em>[i, len(s) + 1]</em>.) If the call returns <b>true</b>, the match succeeds without consuming any input. (So, to return <b>true</b> is equivalent to return <em>i</em>.) If the call returns <b>false</b>, <b>nil</b>, or no value, the match fails. </p> <p> Any extra values returned by the function become the values produced by the capture. </p> <h2><a name="ex">Some Examples</a></h2> <h3>Using a Pattern</h3> <p> This example shows a very simple but complete program that builds and uses a pattern: </p> <pre class="example"> local lpeg = require "lpeg" -- matches a word followed by end-of-string p = lpeg.R"az"^1 * -1 print(p:match("hello")) --> 6 print(lpeg.match(p, "hello")) --> 6 print(p:match("1 hello")) --> nil </pre> <p> The pattern is simply a sequence of one or more lower-case letters followed by the end of string (-1). The program calls <code>match</code> both as a method and as a function. In both sucessful cases, the match returns the index of the first character after the match, which is the string length plus one. </p> <h3>Name-value lists</h3> <p> This example parses a list of name-value pairs and returns a table with those pairs: </p> <pre class="example"> lpeg.locale(lpeg) -- adds locale entries into 'lpeg' table local space = lpeg.space^0 local name = lpeg.C(lpeg.alpha^1) * space local sep = lpeg.S(",;") * space local pair = lpeg.Cg(name * "=" * space * name) * sep^-1 local list = lpeg.Cf(lpeg.Ct("") * pair^0, rawset) t = list:match("a=b, c = hi; next = pi") --> { a = "b", c = "hi", next = "pi" } </pre> <p> Each pair has the format <code>name = name</code> followed by an optional separator (a comma or a semicolon). The <code>pair</code> pattern encloses the pair in a group pattern, so that the names become the values of a single capture. The <code>list</code> pattern then folds these captures. It starts with an empty table, created by a table capture matching an empty string; then for each capture (a pair of names) it applies <code>rawset</code> over the accumulator (the table) and the capture values (the pair of names). <code>rawset</code> returns the table itself, so the accumulator is always the table. </p> <h3>Splitting a string</h3> <p> The following code builds a pattern that splits a string using a given pattern <code>sep</code> as a separator: </p> <pre class="example"> function split (s, sep) sep = lpeg.P(sep) local elem = lpeg.C((1 - sep)^0) local p = elem * (sep * elem)^0 return lpeg.match(p, s) end </pre> <p> First the function ensures that <code>sep</code> is a proper pattern. The pattern <code>elem</code> is a repetition of zero of more arbitrary characters as long as there is not a match against the separator. It also captures its match. The pattern <code>p</code> matches a list of elements separated by <code>sep</code>. </p> <p> If the split results in too many values, it may overflow the maximum number of values that can be returned by a Lua function. In this case, we can collect these values in a table: </p> <pre class="example"> function split (s, sep) sep = lpeg.P(sep) local elem = lpeg.C((1 - sep)^0) local p = lpeg.Ct(elem * (sep * elem)^0) -- make a table capture return lpeg.match(p, s) end </pre> <h3>Searching for a pattern</h3> <p> The primitive <code>match</code> works only in anchored mode. If we want to find a pattern anywhere in a string, we must write a pattern that matches anywhere. </p> <p> Because patterns are composable, we can write a function that, given any arbitrary pattern <code>p</code>, returns a new pattern that searches for <code>p</code> anywhere in a string. There are several ways to do the search. One way is like this: </p> <pre class="example"> function anywhere (p) return lpeg.P{ p + 1 * lpeg.V(1) } end </pre> <p> This grammar has a straight reading: it matches <code>p</code> or skips one character and tries again. </p> <p> If we want to know where the pattern is in the string (instead of knowing only that it is there somewhere), we can add position captures to the pattern: </p> <pre class="example"> local I = lpeg.Cp() function anywhere (p) return lpeg.P{ I * p * I + 1 * lpeg.V(1) } end print(anywhere("world"):match("hello world!")) -> 7 12 </pre> <p> Another option for the search is like this: </p> <pre class="example"> local I = lpeg.Cp() function anywhere (p) return (1 - lpeg.P(p))^0 * I * p * I end </pre> <p> Again the pattern has a straight reading: it skips as many characters as possible while not matching <code>p</code>, and then matches <code>p</code> (plus appropriate captures). </p> <p> If we want to look for a pattern only at word boundaries, we can use the following transformer: </p> <pre class="example"> local t = lpeg.locale() function atwordboundary (p) return lpeg.P{ [1] = p + t.alpha^0 * (1 - t.alpha)^1 * lpeg.V(1) } end </pre> <h3><a name="balanced"></a>Balanced parentheses</h3> <p> The following pattern matches only strings with balanced parentheses: </p> <pre class="example"> b = lpeg.P{ "(" * ((1 - lpeg.S"()") + lpeg.V(1))^0 * ")" } </pre> <p> Reading the first (and only) rule of the given grammar, we have that a balanced string is an open parenthesis, followed by zero or more repetitions of either a non-parenthesis character or a balanced string (<code>lpeg.V(1)</code>), followed by a closing parenthesis. </p> <h3>Global substitution</h3> <p> The next example does a job somewhat similar to <code>string.gsub</code>. It receives a pattern and a replacement value, and substitutes the replacement value for all occurrences of the pattern in a given string: </p> <pre class="example"> function gsub (s, patt, repl) patt = lpeg.P(patt) patt = lpeg.Cs((patt / repl + 1)^0) return lpeg.match(patt, s) end </pre> <p> As in <code>string.gsub</code>, the replacement value can be a string, a function, or a table. </p> <h3><a name="CSV"></a>Comma-Separated Values (CSV)</h3> <p> This example breaks a string into comma-separated values, returning all fields: </p> <pre class="example"> local field = '"' * lpeg.Cs(((lpeg.P(1) - '"') + lpeg.P'""' / '"')^0) * '"' + lpeg.C((1 - lpeg.S',\n"')^0) local record = field * (',' * field)^0 * (lpeg.P'\n' + -1) function csv (s) return lpeg.match(record, s) end </pre> <p> A field is either a quoted field (which may contain any character except an individual quote, which may be written as two quotes that are replaced by one) or an unquoted field (which cannot contain commas, newlines, or quotes). A record is a list of fields separated by commas, ending with a newline or the string end (-1). </p> <p> As it is, the previous pattern returns each field as a separated result. If we add a table capture in the definition of <code>record</code>, the pattern will return instead a single table containing all fields: </p> <pre> local record = lpeg.Ct(field * (',' * field)^0) * (lpeg.P'\n' + -1) </pre> <h3>UTF-8 and Latin 1</h3> <p> It is not difficult to use LPeg to convert a string from UTF-8 encoding to Latin 1 (ISO 8859-1): </p> <pre class="example"> -- convert a two-byte UTF-8 sequence to a Latin 1 character local function f2 (s) local c1, c2 = string.byte(s, 1, 2) return string.char(c1 * 64 + c2 - 12416) end local utf8 = lpeg.R("\0\127") + lpeg.R("\194\195") * lpeg.R("\128\191") / f2 local decode_pattern = lpeg.Cs(utf8^0) * -1 </pre> <p> In this code, the definition of UTF-8 is already restricted to the Latin 1 range (from 0 to 255). Any encoding outside this range (as well as any invalid encoding) will not match that pattern. </p> <p> As the definition of <code>decode_pattern</code> demands that the pattern matches the whole input (because of the -1 at its end), any invalid string will simply fail to match, without any useful information about the problem. We can improve this situation redefining <code>decode_pattern</code> as follows: </p> <pre class="example"> local function er (_, i) error("invalid encoding at position " .. i) end local decode_pattern = lpeg.Cs(utf8^0) * (-1 + lpeg.P(er)) </pre> <p> Now, if the pattern <code>utf8^0</code> stops before the end of the string, an appropriate error function is called. </p> <h3>UTF-8 and Unicode</h3> <p> We can extend the previous patterns to handle all Unicode code points. Of course, we cannot translate them to Latin 1 or any other one-byte encoding. Instead, our translation results in a array with the code points represented as numbers. The full code is here: </p> <pre class="example"> -- decode a two-byte UTF-8 sequence local function f2 (s) local c1, c2 = string.byte(s, 1, 2) return c1 * 64 + c2 - 12416 end -- decode a three-byte UTF-8 sequence local function f3 (s) local c1, c2, c3 = string.byte(s, 1, 3) return (c1 * 64 + c2) * 64 + c3 - 925824 end -- decode a four-byte UTF-8 sequence local function f4 (s) local c1, c2, c3, c4 = string.byte(s, 1, 4) return ((c1 * 64 + c2) * 64 + c3) * 64 + c4 - 63447168 end local cont = lpeg.R("\128\191") -- continuation byte local utf8 = lpeg.R("\0\127") / string.byte + lpeg.R("\194\223") * cont / f2 + lpeg.R("\224\239") * cont * cont / f3 + lpeg.R("\240\244") * cont * cont * cont / f4 local decode_pattern = lpeg.Ct(utf8^0) * -1 </pre> <h3>Lua's long strings</h3> <p> A long string in Lua starts with the pattern <code>[=*[</code> and ends at the first occurrence of <code>]=*]</code> with exactly the same number of equal signs. If the opening brackets are followed by a newline, this newline is discarded (that is, it is not part of the string). </p> <p> To match a long string in Lua, the pattern must capture the first repetition of equal signs and then, whenever it finds a candidate for closing the string, check whether it has the same number of equal signs. </p> <pre class="example"> equals = lpeg.P"="^0 open = "[" * lpeg.Cg(equals, "init") * "[" * lpeg.P"\n"^-1 close = "]" * lpeg.C(equals) * "]" closeeq = lpeg.Cmt(close * lpeg.Cb("init"), function (s, i, a, b) return a == b end) string = open * lpeg.C((lpeg.P(1) - closeeq)^0) * close / 1 </pre> <p> The <code>open</code> pattern matches <code>[=*[</code>, capturing the repetitions of equal signs in a group named <code>init</code>; it also discharges an optional newline, if present. The <code>close</code> pattern matches <code>]=*]</code>, also capturing the repetitions of equal signs. The <code>closeeq</code> pattern first matches <code>close</code>; then it uses a back capture to recover the capture made by the previous <code>open</code>, which is named <code>init</code>; finally it uses a match-time capture to check whether both captures are equal. The <code>string</code> pattern starts with an <code>open</code>, then it goes as far as possible until matching <code>closeeq</code>, and then matches the final <code>close</code>. The final numbered capture simply discards the capture made by <code>close</code>. </p> <h3>Arithmetic expressions</h3> <p> This example is a complete parser and evaluator for simple arithmetic expressions. We write it in two styles. The first approach first builds a syntax tree and then traverses this tree to compute the expression value: </p> <pre class="example"> -- Lexical Elements local Space = lpeg.S(" \n\t")^0 local Number = lpeg.C(lpeg.P"-"^-1 * lpeg.R("09")^1) * Space local TermOp = lpeg.C(lpeg.S("+-")) * Space local FactorOp = lpeg.C(lpeg.S("*/")) * Space local Open = "(" * Space local Close = ")" * Space -- Grammar local Exp, Term, Factor = lpeg.V"Exp", lpeg.V"Term", lpeg.V"Factor" G = lpeg.P{ Exp, Exp = lpeg.Ct(Term * (TermOp * Term)^0); Term = lpeg.Ct(Factor * (FactorOp * Factor)^0); Factor = Number + Open * Exp * Close; } G = Space * G * -1 -- Evaluator function eval (x) if type(x) == "string" then return tonumber(x) else local op1 = eval(x[1]) for i = 2, #x, 2 do local op = x[i] local op2 = eval(x[i + 1]) if (op == "+") then op1 = op1 + op2 elseif (op == "-") then op1 = op1 - op2 elseif (op == "*") then op1 = op1 * op2 elseif (op == "/") then op1 = op1 / op2 end end return op1 end end -- Parser/Evaluator function evalExp (s) local t = lpeg.match(G, s) if not t then error("syntax error", 2) end return eval(t) end -- small example print(evalExp"3 + 5*9 / (1+1) - 12") --> 13.5 </pre> <p> The second style computes the expression value on the fly, without building the syntax tree. The following grammar takes this approach. (It assumes the same lexical elements as before.) </p> <pre class="example"> -- Auxiliary function function eval (v1, op, v2) if (op == "+") then return v1 + v2 elseif (op == "-") then return v1 - v2 elseif (op == "*") then return v1 * v2 elseif (op == "/") then return v1 / v2 end end -- Grammar local V = lpeg.V G = lpeg.P{ "Exp", Exp = lpeg.Cf(V"Term" * lpeg.Cg(TermOp * V"Term")^0, eval); Term = lpeg.Cf(V"Factor" * lpeg.Cg(FactorOp * V"Factor")^0, eval); Factor = Number / tonumber + Open * V"Exp" * Close; } -- small example print(lpeg.match(G, "3 + 5*9 / (1+1) - 12")) --> 13.5 </pre> <p> Note the use of the fold (accumulator) capture. To compute the value of an expression, the accumulator starts with the value of the first term, and then applies <code>eval</code> over the accumulator, the operator, and the new term for each repetition. </p> <h2><a name="download"></a>Download</h2> <p>LPeg <a href="http://www.inf.puc-rio.br/~roberto/lpeg/lpeg-1.0.2.tar.gz">source code</a>.</p> <h2><a name="license">License</a></h2> <p> Copyright © 2007-2019 Lua.org, PUC-Rio. </p> <p> 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: </p> <p> The above copyright notice and this permission notice shall be included in all copies or substantial portions of the Software. </p> <p> THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE. </p> </div> <!-- id="content" --> </div> <!-- id="main" --> </div> <!-- id="container" --> </body> </html>