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1 .TH REGEX 7 "25 Oct 1995"
2 .BY "Henry Spencer"
3 .SH NAME
4 regex \- POSIX 1003.2 regular expressions
5 .SH DESCRIPTION
6 Regular expressions (``RE''s),
7 as defined in POSIX 1003.2, come in two forms:
8 modern REs (roughly those of
9 .IR egrep ;
10 1003.2 calls these ``extended'' REs)
11 and obsolete REs (roughly those of
12 .IR ed ;
13 1003.2 ``basic'' REs).
14 Obsolete REs mostly exist for backward compatibility in some old programs;
15 they will be discussed at the end.
16 1003.2 leaves some aspects of RE syntax and semantics open;
17 `\(dg' marks decisions on these aspects that
18 may not be fully portable to other 1003.2 implementations.
19 .PP
20 A (modern) RE is one\(dg or more non-empty\(dg \fIbranches\fR,
21 separated by `|'.
22 It matches anything that matches one of the branches.
23 .PP
24 A branch is one\(dg or more \fIpieces\fR, concatenated.
25 It matches a match for the first, followed by a match for the second, etc.
26 .PP
27 A piece is an \fIatom\fR possibly followed
28 by a single\(dg `*', `+', `?', or \fIbound\fR.
29 An atom followed by `*' matches a sequence of 0 or more matches of the atom.
30 An atom followed by `+' matches a sequence of 1 or more matches of the atom.
31 An atom followed by `?' matches a sequence of 0 or 1 matches of the atom.
32 .PP
33 A \fIbound\fR is `{' followed by an unsigned decimal integer,
34 possibly followed by `,'
35 possibly followed by another unsigned decimal integer,
36 always followed by `}'.
37 The integers must lie between 0 and RE_DUP_MAX (255\(dg) inclusive,
38 and if there are two of them, the first may not exceed the second.
39 An atom followed by a bound containing one integer \fIi\fR
40 and no comma matches
41 a sequence of exactly \fIi\fR matches of the atom.
42 An atom followed by a bound
43 containing one integer \fIi\fR and a comma matches
44 a sequence of \fIi\fR or more matches of the atom.
45 An atom followed by a bound
46 containing two integers \fIi\fR and \fIj\fR matches
47 a sequence of \fIi\fR through \fIj\fR (inclusive) matches of the atom.
48 .PP
49 An atom is a regular expression enclosed in `()' (matching a match for the
50 regular expression),
51 an empty set of `()' (matching the null string)\(dg,
52 a \fIbracket expression\fR (see below), `.'
53 (matching any single character), `^' (matching the null string at the
54 beginning of a line), `$' (matching the null string at the
55 end of a line), a `\e' followed by one of the characters
56 `^.[$()|*+?{\e'
57 (matching that character taken as an ordinary character),
58 a `\e' followed by any other character\(dg
59 (matching that character taken as an ordinary character,
60 as if the `\e' had not been present\(dg),
61 or a single character with no other significance (matching that character).
62 A `{' followed by a character other than a digit is an ordinary
63 character, not the beginning of a bound\(dg.
64 It is illegal to end an RE with `\e'.
65 .PP
66 A \fIbracket expression\fR is a list of characters enclosed in `[]'.
67 It normally matches any single character from the list (but see below).
68 If the list begins with `^',
69 it matches any single character
70 (but see below) \fInot\fR from the rest of the list.
71 If two characters in the list are separated by `\-', this is shorthand
72 for the full \fIrange\fR of characters between those two (inclusive) in the
73 collating sequence,
74 e.g. `[0\-9]' in ASCII matches any decimal digit.
75 It is illegal\(dg for two ranges to share an
76 endpoint, e.g. `a\-c\-e'.
77 Ranges are very collating-sequence-dependent,
78 and portable programs should avoid relying on them.
79 .PP
80 To include a literal `]' in the list, make it the first character
81 (following a possible `^').
82 To include a literal `\-', make it the first or last character,
83 or the second endpoint of a range.
84 To use a literal `\-' as the first endpoint of a range,
85 enclose it in `[.' and `.]' to make it a collating element (see below).
86 With the exception of these and some combinations using `[' (see next
87 paragraphs), all other special characters, including `\e', lose their
88 special significance within a bracket expression.
89 .PP
90 Within a bracket expression, a collating element (a character,
91 a multi-character sequence that collates as if it were a single character,
92 or a collating-sequence name for either)
93 enclosed in `[.' and `.]' stands for the
94 sequence of characters of that collating element.
95 The sequence is a single element of the bracket expression's list.
96 A bracket expression containing a multi-character collating element
97 can thus match more than one character,
98 e.g. if the collating sequence includes a `ch' collating element,
99 then the RE `[[.ch.]]*c' matches the first five characters
100 of `chchcc'.
101 .PP
102 Within a bracket expression, a collating element enclosed in `[=' and
103 `=]' is an equivalence class, standing for the sequences of characters
104 of all collating elements equivalent to that one, including itself.
105 (If there are no other equivalent collating elements,
106 the treatment is as if the enclosing delimiters were `[.' and `.]'.)
107 For example, if o and \o'o^' are the members of an equivalence class,
108 then `[[=o=]]', `[[=\o'o^'=]]', and `[o\o'o^']' are all synonymous.
109 An equivalence class may not\(dg be an endpoint
110 of a range.
111 .PP
112 Within a bracket expression, the name of a \fIcharacter class\fR enclosed
113 in `[:' and `:]' stands for the list of all characters belonging to that
114 class.
115 Standard character class names are:
116 .PP
117 .RS
118 .nf
119 .ta 3c 6c 9c
120 alnum digit punct
121 alpha graph space
122 blank lower upper
123 cntrl print xdigit
124 .fi
125 .RE
126 .PP
127 These stand for the character classes defined in
128 .IR ctype (3).
129 A locale may provide others.
130 A character class may not be used as an endpoint of a range.
131 .PP
132 There are two special cases\(dg of bracket expressions:
133 the bracket expressions `[[:<:]]' and `[[:>:]]' match the null string at
134 the beginning and end of a word respectively.
135 A word is defined as a sequence of
136 word characters
137 which is neither preceded nor followed by
138 word characters.
139 A word character is an
140 .I alnum
141 character (as defined by
142 .IR ctype (3))
143 or an underscore.
144 This is an extension,
145 compatible with but not specified by POSIX 1003.2,
146 and should be used with
147 caution in software intended to be portable to other systems.
148 .PP
149 In the event that an RE could match more than one substring of a given
150 string,
151 the RE matches the one starting earliest in the string.
152 If the RE could match more than one substring starting at that point,
153 it matches the longest.
154 Subexpressions also match the longest possible substrings, subject to
155 the constraint that the whole match be as long as possible,
156 with subexpressions starting earlier in the RE taking priority over
157 ones starting later.
158 Note that higher-level subexpressions thus take priority over
159 their lower-level component subexpressions.
160 .PP
161 Match lengths are measured in characters, not collating elements.
162 A null string is considered longer than no match at all.
163 For example,
164 `bb*' matches the three middle characters of `abbbc',
165 `(wee|week)(knights|nights)' matches all ten characters of `weeknights',
166 when `(.*).*' is matched against `abc' the parenthesized subexpression
167 matches all three characters, and
168 when `(a*)*' is matched against `bc' both the whole RE and the parenthesized
169 subexpression match the null string.
170 .PP
171 If case-independent matching is specified,
172 the effect is much as if all case distinctions had vanished from the
173 alphabet.
174 When an alphabetic that exists in multiple cases appears as an
175 ordinary character outside a bracket expression, it is effectively
176 transformed into a bracket expression containing both cases,
177 e.g. `x' becomes `[xX]'.
178 When it appears inside a bracket expression, all case counterparts
179 of it are added to the bracket expression, so that (e.g.) `[x]'
180 becomes `[xX]' and `[^x]' becomes `[^xX]'.
181 .PP
182 No particular limit is imposed on the length of REs\(dg.
183 Programs intended to be portable should not employ REs longer
184 than 256 bytes,
185 as an implementation can refuse to accept such REs and remain
186 POSIX-compliant.
187 .PP
188 Obsolete (``basic'') regular expressions differ in several respects.
189 `|', `+', and `?' are ordinary characters and there is no equivalent
190 for their functionality.
191 The delimiters for bounds are `\e{' and `\e}',
192 with `{' and `}' by themselves ordinary characters.
193 The parentheses for nested subexpressions are `\e(' and `\e)',
194 with `(' and `)' by themselves ordinary characters.
195 `^' is an ordinary character except at the beginning of the
196 RE or\(dg the beginning of a parenthesized subexpression,
197 `$' is an ordinary character except at the end of the
198 RE or\(dg the end of a parenthesized subexpression,
199 and `*' is an ordinary character if it appears at the beginning of the
200 RE or the beginning of a parenthesized subexpression
201 (after a possible leading `^').
202 Finally, there is one new type of atom, a \fIback reference\fR:
203 `\e' followed by a non-zero decimal digit \fId\fR
204 matches the same sequence of characters
205 matched by the \fId\fRth parenthesized subexpression
206 (numbering subexpressions by the positions of their opening parentheses,
207 left to right),
208 so that (e.g.) `\e([bc]\e)\e1' matches `bb' or `cc' but not `bc'.
209 .SH SEE ALSO
210 regex(3)
211 .PP
212 POSIX 1003.2, section 2.8 (Regular Expression Notation).
213 .SH HISTORY
214 Written by Henry Spencer, based on the 1003.2 spec.
215 .SH BUGS
216 Having two kinds of REs is a botch.
217 .PP
218 The current 1003.2 spec says that `)' is an ordinary character in
219 the absence of an unmatched `(';
220 this was an unintentional result of a wording error,
221 and change is likely.
222 Avoid relying on it.
223 .PP
224 Back references are a dreadful botch,
225 posing major problems for efficient implementations.
226 They are also somewhat vaguely defined
227 (does
228 `a\e(\e(b\e)*\e2\e)*d' match `abbbd'?).
229 Avoid using them.
230 .PP
231 1003.2's specification of case-independent matching is vague.
232 The ``one case implies all cases'' definition given above
233 is current consensus among implementors as to the right interpretation.
234 .PP
235 The syntax for word boundaries is incredibly ugly.