997 lines
42 KiB
HTML
997 lines
42 KiB
HTML
<!DOCTYPE HTML PUBLIC "-//W3C//DTD HTML 4.0 Frameset//EN" "http://www.w3.org/TR/REC-html40/frameset.dtd">
|
|
<HTML>
|
|
<HEAD>
|
|
<META name="generator" content="mm2html (AT&T Research) 2010-09-10">
|
|
<META name="keywords" content="regex regular expression standard interpretation">
|
|
<TITLE> ../re/re-interpretation.mm mm document </TITLE>
|
|
<META name="author" content="gsf">
|
|
</HEAD>
|
|
<BODY bgcolor=white link=slateblue vlink=teal >
|
|
<TABLE border=0 align=center width=96%>
|
|
<TBODY><TR><TD valign=top align=left>
|
|
<!--INDEX--><!--/INDEX-->
|
|
<B><FONT size=-1 face="verdana,arial,helvetica,geneva,sans-serif">
|
|
<TABLE align=center cellpadding=2 border=4 bgcolor=lightgrey><TR>
|
|
<TD><A href="re-interpretation.html#Abstract">Abstract</A></TD>
|
|
<TD><A href="re-interpretation.html#Background">Background</A></TD>
|
|
<TD><A href="re-interpretation.html#Notation">Notation</A></TD>
|
|
<TD><A href="re-interpretation.html#regex Glossary">regex Glossary</A></TD>
|
|
<TD><A href="re-interpretation.html#A subexpression is ">A subexpression is </A></TD>
|
|
<TD><A href="re-interpretation.html#A subpattern is ">A subpattern is </A></TD>
|
|
<TD><A href="re-interpretation.html#The Dark Corners ">The Dark Corners </A></TD>
|
|
<TD><A href="re-interpretation.html#Conclusion">Conclusion</A></TD>
|
|
</TR></TABLE>
|
|
</FONT></B>
|
|
<P>
|
|
<HR>
|
|
<CENTER>
|
|
<H3><CENTER><FONT color=red><FONT face=courier>An Interpretation of the POSIX regex Standard</FONT></FONT></CENTER></H3>
|
|
<BR>Glenn Fowler <SMALL><<A href=mailto:gsf@research.att.com>gsf@research.att.com</A>></SMALL>
|
|
<P><I>AT&T Research - Florham Park NJ</I>
|
|
</CENTER>
|
|
<P>
|
|
<CENTER><FONT color=red><FONT face=courier><H3 align=center><A name="Abstract">Abstract</A></H3></FONT></FONT></CENTER>
|
|
Many passages in the POSIX
|
|
<STRONG>regex</STRONG>
|
|
standard seem to be open for interpretation.
|
|
Differences between several published
|
|
<A href="http://www.research.att.com/~gsf/testregex/" target=_top>implementations</A>
|
|
of the
|
|
<STRONG>regex</STRONG>
|
|
API bear this out.
|
|
Instead of relegating these differences to the
|
|
<EM>undefined behavior</EM>
|
|
bucket, this paper proposes a resolution to each
|
|
by direct application of the standard text.
|
|
|
|
<P>
|
|
<P><HR><CENTER><FONT color=red><FONT face=courier><H3><A name="Background">Background</A></H3></FONT></FONT></CENTER>
|
|
The POSIX
|
|
<STRONG>regex</STRONG>
|
|
standard is spread across four documents:
|
|
<P></P><TABLE border=0 frame=void rules=none width=100%><TBODY><TR><TD>
|
|
<TABLE align=center bgcolor=papayawhip border=0 bordercolor=white cellpadding=2 cellspacing=2 >
|
|
<TBODY>
|
|
<TR><TD align=right>
|
|
glossary </TD><TD align=center> G </TD><TD align=left> <A href="http://www.opengroup.org/onlinepubs/007904975/basedefs/xbd_chap03.html" target=_top>http://www.opengroup.org/onlinepubs/007904975/basedefs/xbd_chap03.html</A></TD></TR>
|
|
<TR><TD align=right>
|
|
api </TD><TD align=center> A </TD><TD align=left> <A href="http://www.opengroup.org/onlinepubs/007904975/functions/regcomp.html" target=_top>http://www.opengroup.org/onlinepubs/007904975/functions/regcomp.html</A></TD></TR>
|
|
<TR><TD align=right>
|
|
definition </TD><TD align=center> D </TD><TD align=left> <A href="http://www.opengroup.org/onlinepubs/007904975/basedefs/xbd_chap09.html" target=_top>http://www.opengroup.org/onlinepubs/007904975/basedefs/xbd_chap09.html</A></TD></TR>
|
|
<TR><TD align=right>
|
|
rationale </TD><TD align=center> R </TD><TD align=left> <A href="http://www.opengroup.org/onlinepubs/007904975/xrat/xbd_chap09.html" target=_top>http://www.opengroup.org/onlinepubs/007904975/xrat/xbd_chap09.html</A></TD></TR>
|
|
</TBODY></TABLE></TD></TR></TBODY></TABLE>
|
|
<P>
|
|
It describes
|
|
<STRONG>BRE</STRONG>s
|
|
(basic regular expressions, a.k.a.,
|
|
<NOBR><A href="http://web.archive.org/~gsf/man/man1/grep.html"><STRONG>grep</STRONG></A>(1)</NOBR>
|
|
style) and
|
|
<STRONG>ERE</STRONG>s
|
|
(extended regular expressions, a.k.a.,
|
|
<NOBR><A href="http://web.archive.org/~gsf/man/man1/egrep.html"><STRONG>egrep</STRONG></A>(1)</NOBR>
|
|
style)
|
|
and how an RE of each type matches subject strings.
|
|
The standard also provides an API:
|
|
<NOBR><A href="http://web.archive.org/~gsf/man/man3/regcomp.html"><STRONG>regcomp</STRONG></A>(3)</NOBR>
|
|
for compiling an RE, and
|
|
<NOBR><A href="http://web.archive.org/~gsf/man/man3/regexec.html"><STRONG>regexec</STRONG></A>(3)</NOBR>
|
|
for matching a compiled RE against a subject string.
|
|
The
|
|
<STRONG>regexec</STRONG>
|
|
API
|
|
<DIV style="padding-left:16px;text-indent:0px">
|
|
<PRE>
|
|
int regexec(const regex_t* restrict preg, const char* restrict string,
|
|
size_t nmatch, regmatch_t pmatch[restrict], int eflags);
|
|
</DIV>
|
|
</PRE>
|
|
is at the center of multiple, conflicting interpretations of the standard.
|
|
These interpretations differ on the setting of the
|
|
<TT>pmatch[]</TT>
|
|
array for index values > 0.
|
|
This note presents examples that demonstrate interpretation conflicts,
|
|
and then provides standard references that,
|
|
<EM>when taken as a whole</EM>,
|
|
resolve the conflicts.
|
|
|
|
<P>
|
|
<P><HR><CENTER><FONT color=red><FONT face=courier><H3><A name="Notation">Notation</A></H3></FONT></FONT></CENTER>
|
|
Standard references use the notation
|
|
[<EM>document</EM>:<EM>begin</EM>[-<EM>end</EM>]]
|
|
where
|
|
<EM>document</EM>
|
|
is the document letter, { A D G R }, from the table above,
|
|
<EM>begin</EM>
|
|
is the beginning line number, and
|
|
<EM>end</EM>
|
|
is the ending line number.
|
|
Line numbers are taken from the 2001 X/Open printing.
|
|
Unfortunately the online links do not display line numbers.
|
|
For example, [A:37179-37180] is the reference for the
|
|
<STRONG>regexec</STRONG>
|
|
API prototype above.
|
|
<P>
|
|
Example patterns, subject strings, and
|
|
<TT>pmatch[]</TT>
|
|
array values use the regression test notation of
|
|
<A href="http://www.research.att.com/~gsf/testregex/" target=_top>testregex.</A>
|
|
You can download the source and compile it against your favorite regex
|
|
implementation.
|
|
All of the examples in this note have been placed in the file
|
|
<A href="http://www.research.att.com/~gsf/testregex/interpretation.dat" target=_top>interpretation.dat;</A>
|
|
you can download this file and use it as input to
|
|
<STRONG>testregex</STRONG>.
|
|
For example, the
|
|
<STRONG>testregex</STRONG>
|
|
input
|
|
<DIV style="padding-left:16px;text-indent:0px">
|
|
<PRE>
|
|
:RE#01:E a+ xaax (1,3)
|
|
</DIV>
|
|
</PRE>
|
|
specifies that the ERE pattern "a+" matched against the
|
|
subject string "xaax" yields
|
|
<TT>pmatch[0].rm_so==1</TT>
|
|
and
|
|
<TT>pmatch[0].rm_eo==3</TT>.
|
|
The example is labeled RE#01 for indexing and referencing.
|
|
<DIV style="padding-left:16px;text-indent:0px">
|
|
<PRE>
|
|
:RE#02:B .\(a*\). xaax (0,4)(1,3)
|
|
</DIV>
|
|
</PRE>
|
|
specifies that the BRE pattern ".\(a*\)." matched against the subject
|
|
string "xaax" yields
|
|
<TT>pmatch[0].rm_so==0</TT>,
|
|
<TT>pmatch[0].rm_eo==4</TT>,
|
|
<TT>pmatch[1].rm_so==1</TT>,
|
|
<TT>pmatch[1].rm_eo==3</TT>.
|
|
(?,?) denotes
|
|
<TT>rm_so</TT>
|
|
and
|
|
<TT>rm_eo</TT>
|
|
values of -1, i.e., a non-match.
|
|
The first field allows additional flags that exercise all of the
|
|
<STRONG>REG_*</STRONG>
|
|
<STRONG>regcomp</STRONG>
|
|
and
|
|
<STRONG>regexec</STRONG>
|
|
flags; see
|
|
<NOBR><A href="http://web.archive.org/~gsf/man/man1/testregex.html"><STRONG>testregex</STRONG></A>(1)</NOBR>
|
|
or
|
|
<STRONG>testregex --man</STRONG>
|
|
for details.
|
|
Note that
|
|
<STRONG>tab</STRONG>
|
|
is the field separator in the
|
|
<STRONG>testregex</STRONG>
|
|
syntax; if you mouse snarf then make sure that
|
|
<STRONG>tabs</STRONG>
|
|
are preserved.
|
|
|
|
<P>
|
|
<P><HR><CENTER><FONT color=red><FONT face=courier><H3><A name="regex Glossary">regex Glossary</A></H3></FONT></FONT></CENTER>
|
|
<DIV style="padding-left:16px;text-indent:0px">
|
|
<DL COMPACT>
|
|
<DT>[G:41]<STRONG>Basic Regular Expression (BRE)</STRONG><DD>
|
|
A regular expression used by the majority of utilities that select strings
|
|
from a set of character strings.
|
|
<DT>[G:148]<STRONG>Entire Regular Expression</STRONG><DD>
|
|
The concatenated set of one or more basic regular expressions or extended
|
|
regular expressions that make up the pattern specified for string selection.
|
|
<DT>[G:158]<STRONG>Extended Regular Expression (ERE)</STRONG><DD>
|
|
A regular expression that is an alternative to the Basic Regular
|
|
Expression using a more extensive syntax, occasionally used by some utilities.
|
|
<DT>[G:269]<STRONG>Pattern</STRONG><DD>
|
|
A sequence of characters used either with regular expression notation or for
|
|
pathname expansion, as a means of selecting various character strings or
|
|
pathnames, respectively.
|
|
<DT>[G:316]<STRONG>Regular Expression</STRONG><DD>
|
|
A pattern that selects specific strings from a set of character strings.
|
|
</DL>
|
|
</DIV>
|
|
|
|
<P>
|
|
<P><HR><CENTER><FONT color=red><FONT face=courier><H3><A name="A subexpression is ">A subexpression is </A></H3></FONT></FONT></CENTER>
|
|
The
|
|
<STRONG>regex</STRONG>
|
|
standard is surprisingly cavalier with terminology:
|
|
some terms are used interchangeably, some are used in a general context
|
|
in one section and a specific context in another, and some are
|
|
used without any definition whatsoever.
|
|
Acutely subject to this abuse are:
|
|
<EM>RE</EM>,
|
|
<EM>pattern</EM>,
|
|
<EM>subpattern</EM>,
|
|
<EM>expression</EM>,
|
|
and
|
|
<EM>subexpression</EM>.
|
|
In particular,
|
|
<EM>subpattern</EM>
|
|
and
|
|
<EM>subexpression</EM>
|
|
are central to the description of the matching algorithm and how
|
|
<TT>pmatch[]</TT>
|
|
is assigned.
|
|
Any interpretation of the
|
|
<STRONG>regex</STRONG>
|
|
standard involving these terms, absent a precise and accurate definition
|
|
for each, is useless.
|
|
<P>
|
|
<EM>subexpression</EM>
|
|
appears 70 times, and each reference is in the context of parenthesis grouping:
|
|
<DIV style="padding-left:16px;text-indent:0px">
|
|
<DL COMPACT>
|
|
<DT>[D:5909-5911]<DD>
|
|
For example, matching the BRE "\(.*\).*" against "abcdef" , the
|
|
subexpression "(\1)" is "abcdef" , and matching the BRE
|
|
"\(a*\)*" against "bc" , the subexpression "(\1)" is the null
|
|
string.
|
|
<DT>[D:5984-5988]<DD>
|
|
The asterisk shall be special except when used: As the first
|
|
character of a subexpression (after an initial '^' , if any);
|
|
<DT>[D:6094-6097]<DD>
|
|
A subexpression can be defined within a BRE by enclosing it
|
|
between the character pairs "\(" and "\)" . Subexpressions can
|
|
be arbitrarily nested.
|
|
<DT>[D:6100-6109]<DD>
|
|
The character 'n' shall be a digit from 1 through 9, specifying
|
|
the nth subexpression (the one that begins with the nth "\("
|
|
from the beginning of the pattern and ends with the
|
|
corresponding paired "\)" ). The expression is invalid if less
|
|
than n subexpressions precede the '\n' . For example, the
|
|
expression "\(.*\)\1$" matches a line consisting of two
|
|
adjacent appearances of the same string, and the expression
|
|
"\(a\)*\1" fails to match 'a' . When the referenced
|
|
subexpression matched more than one string, the back-referenced
|
|
expression shall refer to the last matched string. If the
|
|
subexpression referenced by the back-reference matches more
|
|
than one string because of an asterisk ( '*' ) or an interval
|
|
expression (see item (5)), the back-reference shall match the
|
|
last (rightmost) of these strings.
|
|
<DT>[D:6110-6112]<DD>
|
|
When a BRE matching a single character, a subexpression, or a
|
|
back-reference is followed by the special character asterisk ('*' ),
|
|
together with that asterisk it shall match what zero or
|
|
more consecutive occurrences of the BRE would match.
|
|
<DT>[D:6114-6117]<DD>
|
|
When a BRE matching a single character, a subexpression, or a
|
|
back-reference is followed by an interval expression of the
|
|
format "\{m\}" , "\{m,\}" , or "\{m,n\}" , together with that
|
|
interval expression it shall match what repeated consecutive
|
|
occurrences of the BRE would match. "\{m,n\}" , together with
|
|
that interval expression it shall match what repeated
|
|
consecutive occurrences of the BRE would match.
|
|
<DT>[D:6127-6129]<DD>
|
|
A subexpression repeated by an asterisk ('*') or an interval expression
|
|
shall not match a null expression unless this is the only match for the
|
|
repetition or it is necessary to satisfy the exact or minimum number of
|
|
occurrences for the interval expression.
|
|
<DT>[D:6136]<DD>
|
|
Subexpressions/back-references \(\) \n
|
|
<DT>[D:6145-6151]<DD>
|
|
The implementation may treat the circumflex as an anchor when
|
|
used as the first character of a subexpression. The circumflex
|
|
shall anchor the
|
|
expression (or optionally subexpression) to the beginning of a
|
|
string; only sequences starting at the first character of a
|
|
string shall be matched by the BRE. For example, the BRE "^ab"
|
|
matches "ab" in the string "abcdef" , but fails to match in the
|
|
string "cdefab" . The BRE "\(^ab\)" may match the former
|
|
string. A portable BRE shall escape a leading circumflex in a
|
|
subexpression to match a literal circumflex.
|
|
<DT>[D:6152-6156]<DD>
|
|
A dollar sign ( '$' ) shall be an anchor when used as the last
|
|
character of an entire BRE. The implementation may treat a
|
|
dollar sign as an anchor when used as the last character of a
|
|
subexpression. The dollar sign shall anchor the expression (or
|
|
optionally subexpression) to the end of the string being matched;
|
|
the dollar sign can be said to match the end-of-string following
|
|
the last character.
|
|
<DT>[D:6265-6270]<DD>
|
|
A circumflex ( '^' ) outside a bracket expression shall anchor
|
|
the expression or subexpression it begins to the beginning of a
|
|
string; such an expression or subexpression can match only a
|
|
sequence starting at the first character of a string. For
|
|
example, the EREs "^ab" and "(^ab)" match "ab" in the string
|
|
"abcdef" , but fail to match in the string "cdefab" , and the
|
|
ERE "a^b" is valid, but can never match because the 'a'
|
|
prevents the expression "^b" from matching starting at the
|
|
first character.
|
|
<DT>[D:6271-6276]<DD>
|
|
A dollar sign ( '$' ) outside a bracket expression shall anchor
|
|
the expression or subexpression it ends to the end of a string;
|
|
such an expression or subexpression can match only a sequence
|
|
ending at the last character of a string. For example, the EREs
|
|
"ef$" and "(ef$)" match "ef" in the string "abcdef" , but fail
|
|
to match in the string "cdefab" , and the ERE "e$f" is valid,
|
|
but can never match because the 'f' prevents the expression
|
|
"e$" from matching ending at the last character.
|
|
<DT>[R:2359-2370]<DD>
|
|
It is possible to determine what strings correspond to
|
|
subexpressions by recursively applying the leftmost longest
|
|
rule to each subexpression, but only with the proviso that the
|
|
overall match is leftmost longest. For example, matching
|
|
"\(ac*\)c*d[ac]*\1" against acdacaaa matches acdacaaa (with
|
|
\1=a); simply matching the longest match for "\(ac*\)" would
|
|
yield \1=ac, but the overall match would be smaller (acdac).
|
|
Conceptually, the implementation must examine every possible
|
|
match and among those that yield the leftmost longest total
|
|
matches, pick the one that does the longest match for the
|
|
leftmost subexpression, and so on. Note that this means that
|
|
matching by subexpressions is context-dependent: a
|
|
subexpression within a larger RE may match a different string
|
|
from the one it would match as an independent RE, and two
|
|
instances of the same subexpression within the same larger RE
|
|
may match different lengths even in similar sequences of
|
|
characters. For example, in the ERE "(a.*b)(a.*b)" , the two
|
|
identical subexpressions would match four and six characters,
|
|
respectively, of accbaccccb.
|
|
<DT>[R:2512-2520]<DD>
|
|
The limit of nine back-references to subexpressions in the RE
|
|
is based on the use of a single-digit identifier; increasing
|
|
this to multiple digits would break historical applications.
|
|
This does not imply that only nine subexpressions are allowed
|
|
in REs. The following is a valid BRE with ten subexpressions:
|
|
<DIV style="padding-left:16px;text-indent:0px">
|
|
<PRE>
|
|
\(\(\(ab\)*c\)*d\)\(ef\)*\(gh\)\{2\}\(ij\)*\(kl\)*\(mn\)*\(op\)*\(qr\)*
|
|
</DIV>
|
|
</PRE>
|
|
The standard developers regarded the common historical
|
|
behavior, which supported "\n*" , but not "\n\{min,max\}" ,
|
|
"\(...\)*" , or "\(...\)\{min,max\}" , as a non-intentional
|
|
result of a specific implementation, and they supported both
|
|
duplication and interval expressions following subexpressions
|
|
and back-references.
|
|
<DT>[R:2537-2544]<DD>
|
|
However, one relatively uncommon case was changed to allow an
|
|
extension used on some implementations. Historically, the BREs
|
|
"^foo" and "\(^foo\)" did not match the same string, despite
|
|
the general rule that subexpressions and entire BREs match the
|
|
same strings. To increase consensus, IEEE Std 1003.1-2001 has
|
|
allowed an extension on some implementations to treat these two
|
|
cases in the same way by declaring that anchoring may occur at
|
|
the beginning or end of a subexpression. Therefore, portable
|
|
BREs that require a literal circumflex at the beginning or a
|
|
dollar sign at the end of a subexpression must escape them.
|
|
Note that a BRE such as "a\(^bc\)" will either match "a^bc" or
|
|
nothing on different systems under the rules.
|
|
<DT>[R:2549-2554]<DD>
|
|
Some implementations have extended the BRE syntax to add
|
|
alternation. For example, the subexpression "\(foo$\|bar\)"
|
|
would match either "foo" at the end of the string or "bar"
|
|
anywhere. The extension is triggered by the use of the
|
|
undefined "\|" sequence. Because the BRE is undefined for
|
|
portable scripts, the extending system is free to make other
|
|
assumptions, such that the '$' represents the end-of-line
|
|
anchor in the middle of a subexpression. If it were not for the
|
|
extension, the '$' would match a literal dollar sign under the
|
|
rules.
|
|
<DT>[R:2617-2620]<DD>
|
|
The removal of the Back_open_paren Back_close_paren option from
|
|
the nondupl_RE specification is the result of PASC
|
|
Interpretation 1003.2-92 #43 submitted for the ISO POSIX-2:1993
|
|
standard. Although the grammar required support for null
|
|
subexpressions, this section does not describe the meaning of,
|
|
and historical practice did not support, this construct.
|
|
<DT>[A:37188]<DD>
|
|
size_t re_nsub Number of parenthesized subexpressions
|
|
<DT>[A:37206-37208]<DD>
|
|
If the REG_NOSUB flag was not set in cflags, then regcomp()
|
|
shall set re_nsub to the number of parenthesized subexpressions
|
|
(delimited by "\(\)" in basic regular expressions or "()" in
|
|
extended regular expressions) found in pattern.
|
|
<DT>[A:37220-37257]<DD>
|
|
If nmatch is 0 or REG_NOSUB was set in the cflags argument to
|
|
regcomp(), then regexec() shall ignore the pmatch argument.
|
|
Otherwise, the application shall ensure that the pmatch
|
|
argument points to an array with at least nmatch elements, and
|
|
regexec() shall fill in the elements of that array with offsets
|
|
of the substrings of string that correspond to the
|
|
parenthesized subexpressions of pattern: pmatch[i].rm_so
|
|
shall be the byte offset of the beginning and pmatch[i].rm_eo
|
|
shall be one greater than the byte offset of the end of
|
|
substring i. (Subexpression i begins at the ith matched open
|
|
parenthesis, counting from 1.) Offsets in pmatch[0] identify
|
|
the substring that corresponds to the entire regular
|
|
expression. Unused elements of pmatch up to pmatch[nmatch-1]
|
|
shall be filled with -1. If there are more than nmatch
|
|
subexpressions in pattern ( pattern itself counts as a
|
|
subexpression), then regexec() shall still do the match, but
|
|
shall record only the first nmatch substrings.
|
|
<P>
|
|
When matching a basic or extended regular expression, any given
|
|
parenthesized subexpression of pattern might participate in the
|
|
match of several different substrings of string, or it might
|
|
not match any substring even though the pattern as a whole did
|
|
match. The following rules shall be used to determine which
|
|
substrings to report in pmatch when matching regular
|
|
expressions:
|
|
<DIV style="padding-left:16px;text-indent:0px">
|
|
<OL>
|
|
<LI>
|
|
If subexpression i in a regular expression is not contained
|
|
within another subexpression, and it participated in the match
|
|
several times, then the byte offsets in pmatch[i] shall
|
|
delimit the last such match.
|
|
<LI>
|
|
If subexpression i is not contained within another
|
|
subexpression, and it did not participate in an otherwise
|
|
successful match, the byte offsets in pmatch[i] shall be -1. A
|
|
subexpression does not participate in the match when:
|
|
<PRE>
|
|
'*' or "\{\}" appears immediately after the
|
|
subexpression in a basic regular expression, or '*' ,
|
|
'?' , or "{}" appears immediately after the
|
|
subexpression in an extended regular expression, and
|
|
the subexpression did not match (matched 0 times)
|
|
<P>
|
|
or:
|
|
<P>
|
|
'|' is used in an extended regular expression to select
|
|
this subexpression or another, and the other
|
|
subexpression matched.
|
|
</PRE>
|
|
<LI>
|
|
If subexpression i is contained within another subexpression
|
|
j, and i is not contained within any other subexpression that
|
|
is contained within j, and a match of subexpression j is
|
|
reported in pmatch[j], then the match or non-match of
|
|
subexpression i reported in pmatch[i] shall be as described in
|
|
1. and 2. above, but within the substring reported in pmatch[
|
|
j] rather than the whole string. The offsets in pmatch[i] are
|
|
still relative to the start of string.
|
|
<LI>
|
|
If subexpression i is contained in subexpression j, and the
|
|
byte offsets in pmatch[j] are -1, then the pointers in pmatch[
|
|
i] shall also be -1.
|
|
<LI>
|
|
If subexpression i matched a zero-length string, then both
|
|
byte offsets in pmatch[i] shall be the byte offset of the
|
|
character or null terminator immediately following the
|
|
zero-length string.
|
|
</OL>
|
|
</DIV>
|
|
<DT>[A:37363-37366]<DD>
|
|
The regexec() function must fill in all nmatch elements of
|
|
pmatch, where nmatch and pmatch are supplied by the
|
|
application, even if some elements of pmatch do not correspond
|
|
to subexpressions in pattern. The application writer should
|
|
note that there is probably no reason for using a value of
|
|
nmatch that is larger than preg-> re_nsub+1.
|
|
<DT>[A:37407-37413]<DD>
|
|
The number of subexpressions in the RE is reported in re_nsub
|
|
in preg. With this change to regexec(), consideration was given
|
|
to dropping the REG_NOSUB flag since the user can now specify
|
|
this with a zero nmatch argument to regexec(). However, keeping
|
|
REG_NOSUB allows an implementation to use a different (perhaps
|
|
more efficient) algorithm if it knows in regcomp() that no
|
|
subexpressions need be reported. The implementation is only
|
|
required to fill in pmatch if nmatch is not zero and if
|
|
REG_NOSUB is not specified.
|
|
</DL>
|
|
</DIV>
|
|
<P>
|
|
This sentence is as close as the standard gets to a definition:
|
|
<DIV style="padding-left:16px;text-indent:0px">
|
|
<DL COMPACT>
|
|
<DT>[A:37225-37226]<DD>
|
|
Subexpression i begins at the ith matched open parenthesis, counting from 1.
|
|
</DL>
|
|
</DIV>
|
|
<P>
|
|
Using nonterminals from the BRE [D:6371-6731] and ERE [D:6452-6452] grammar
|
|
productions (text not listed in this document) yields the following:
|
|
<DIV style="padding-left:16px;text-indent:0px">
|
|
<DL COMPACT>
|
|
<DT><STRONG>DEFINITION</STRONG><DD>
|
|
A
|
|
<EM>subexpression</EM>
|
|
corresponds to the
|
|
<TT>Back_open_paren RE_expression Back_close_paren</TT>
|
|
form of the
|
|
<TT>nondupl_RE</TT>
|
|
BRE grammar production or
|
|
the
|
|
<TT>'(' extended_reg_exp ')'</TT>
|
|
form of the
|
|
<TT>ERE_expression</TT>
|
|
ERE grammar production.
|
|
Subexpression i begins at the ith matched open parenthesis
|
|
(<TT>Back_open_paren</TT>
|
|
for BREs and '(' for EREs),
|
|
starting from the left and counting from 1.
|
|
Subexpression 0 is the entire RE.
|
|
</DL>
|
|
</DIV>
|
|
<P>
|
|
This definition and the subexpression match rule [R:2359-2370] can be used to
|
|
to examine a class of EREs where the top level catenation operands are
|
|
subexpressions.
|
|
(A top level subexpression is not contained in any other subexpression
|
|
except subexpression 0.)
|
|
The subexpression match rule in pseudo code is:
|
|
<UL type=square>
|
|
<LI>
|
|
determine the longest of the leftmost matches for subexpression-0
|
|
[R:2359-2361]
|
|
<LI>
|
|
for 1<=<EM>i</EM><=<STRONG>re_nsub</STRONG>
|
|
determine the longest match for
|
|
subexpression-<EM>i</EM>
|
|
consistent with the matches already determined for
|
|
subexpression-<EM>j,</EM>
|
|
0<=<EM>j</EM><<EM>i</EM>.
|
|
[R:2359-2370] [A:37235-37257]
|
|
</UL>
|
|
For example, given
|
|
<DIV style="padding-left:16px;text-indent:0px">
|
|
<PRE>
|
|
:RE#03:E (a?)((ab)?) ab (0,2)(0,0)(0,2)(0,2)
|
|
</DIV>
|
|
</PRE>
|
|
the subexpressions are:
|
|
<DIV style="padding-left:16px;text-indent:0px">
|
|
<PRE>
|
|
subexpression-0 (a?)((ab)?)
|
|
subexpression-1 (a?)
|
|
subexpression-2 ((ab)?)
|
|
subexpression-3 (ab)
|
|
</DIV>
|
|
</PRE>
|
|
The longest of the leftmost matches for subexpression-0 is (0,2).
|
|
The longest match for subexpression-1, consistent with the match
|
|
for subexpression-0, is (0,0); otherwise if it had matched (0,1) then
|
|
subexpression-2 would not match and the subexpression-0 match would be
|
|
limited to (0,1).
|
|
The longest match for subexpression-2, consistent with the matches
|
|
for subexpression-0 and subexpression-1, is (0,2).
|
|
The longest match for subexpression-3, consistent with the matches
|
|
for subexpression-0, subexpression-1 and subexpression-2, is (0,2).
|
|
This table illustrates the matching:
|
|
<DIV style="padding-left:16px;text-indent:0px">
|
|
<PRE>
|
|
subexpr pattern match
|
|
0 (a?)((ab)?) (0,2)
|
|
1 (a?) (0,0)
|
|
2 ((ab)?) (0,2)
|
|
3 (ab) (0,2)
|
|
</DIV>
|
|
</PRE>
|
|
RE#04 is a similar example that exposes the associativity of subexpression
|
|
concatenation:
|
|
<DIV style="padding-left:16px;text-indent:0px">
|
|
<PRE>
|
|
:RE#04:E (a?)((ab)?)(b?) ab (0,2)(0,1)(1,1)(?,?)(1,2)
|
|
|
|
subexpr pattern match
|
|
0 (a?)((ab)?)(b?) (0,2)
|
|
1 (a?) (0,1)
|
|
2 ((ab)?) (1,1)
|
|
3 (ab) (?,?)
|
|
4 (b?) (1,2)
|
|
</DIV>
|
|
</PRE>
|
|
[R:2363-2365] also shows that parenthesis can be used to alter the
|
|
order of matching:
|
|
<DIV style="padding-left:16px;text-indent:0px">
|
|
<PRE>
|
|
:RE#05:E ((a?)((ab)?))(b?) ab (0,2)(0,2)(0,0)(0,2)(0,2)(2,2)
|
|
|
|
subexpr pattern match
|
|
0 ((a?)((ab)?))(b?) (0,2)
|
|
1 ((a?)((ab)?)) (0,2)
|
|
2 (a?) (0,0)
|
|
3 ((ab)?) (0,2)
|
|
4 (ab) (0,2)
|
|
5 (b?) (2,2)
|
|
</DIV>
|
|
</PRE>
|
|
In RE#05 the extra parenthesis (around subexpression-1 and subexpression-2 in
|
|
RE#04) form a new subexpression-1, and change the
|
|
match for the last subexpression
|
|
<TT>(b?)</TT>
|
|
to (2,2) (from (1,2) in RE#04.)
|
|
<DIV style="padding-left:16px;text-indent:0px">
|
|
<PRE>
|
|
:RE#06:E (a?)(((ab)?)(b?)) ab (0,2)(0,1)(1,2)(1,1)(?,?)(1,2)
|
|
|
|
subexpr pattern match
|
|
0 (a?)(((ab)?)(b?)) (0,2)
|
|
1 (a?) (0,1)
|
|
2 (((ab)?)(b?)) (1,2)
|
|
3 ((ab)?) (1,1)
|
|
4 (ab) (?,?)
|
|
5 (b?) (1,2)
|
|
</DIV>
|
|
</PRE>
|
|
In RE#06 the extra parenthesis pair forces right associativity and results
|
|
in the same match of (1,2) for the last subexpression
|
|
<TT>(b?)</TT>
|
|
as in RE#04.
|
|
These examples show that:
|
|
<DIV style="padding-left:16px;text-indent:0px">
|
|
<DL COMPACT>
|
|
<DT><STRONG>PROPERTY</STRONG><DD>
|
|
Subexpression grouping can alter the precedence of concatenation.
|
|
<DT><STRONG>PROPERTY</STRONG><DD>
|
|
Subexpression concatenation is right associative.
|
|
</DL>
|
|
</DIV>
|
|
<P>
|
|
The following examples examine replicated subexpressions.
|
|
<DIV style="padding-left:16px;text-indent:0px">
|
|
<PRE>
|
|
:RE#07:E (.?) x (0,1)(0,1)
|
|
:RE#08:E (.?){1} x (0,1)(0,1)
|
|
:RE#09:E (.?)(.?) x (0,1)(0,1)(1,1)
|
|
:RE#10:E (.?){2} x (0,1)(1,1)
|
|
:RE#11:E (.?)* x (0,1)(0,1)
|
|
</DIV>
|
|
</PRE>
|
|
[D:6227-6234] specifies that RE#07 and RE#08 are equivalent, and that
|
|
RE#09 and RE#10 are equivalent, and
|
|
[D:6217-6219] specifies that RE#09 and RE#11 are equivalent.
|
|
<DIV style="padding-left:16px;text-indent:0px">
|
|
<DL COMPACT>
|
|
<DT>[D:6227-6234]<DD>
|
|
When an ERE matching a single character or an ERE enclosed in
|
|
parentheses is followed by an interval expression of the format "{m}" ,
|
|
"{m,}" , or "{m,n}" , together with that interval expression it shall
|
|
match what repeated consecutive occurrences of the ERE would match. The
|
|
values of m and n are decimal integers in the range 0 <= m<= n<=
|
|
{RE_DUP_MAX}, where m specifies the exact or minimum number of
|
|
occurrences and n specifies the maximum number of occurrences. The
|
|
expression "{m}" matches exactly m occurrences of the preceding ERE,
|
|
"{m,}" matches at least m occurrences, and "{m,n}" matches any number
|
|
of occurrences between m and n, inclusive.
|
|
<DT>[D:6217-6219]<DD>
|
|
When an ERE matching a single character or an ERE enclosed in
|
|
parentheses is followed by the special character asterisk ( '*' ),
|
|
together with that asterisk it shall match what zero or more
|
|
consecutive occurrences of the ERE would match.
|
|
</DL>
|
|
</DIV>
|
|
In RE#09 subexpression-1 matches (0,1), leaving the null string at (1,1) for
|
|
subexpression-2.
|
|
In RE#10 the first iteration of subexpression-1 matches (0,1), the same
|
|
as subexpression-1 in RE#09, and the second iteration of subexpression-1
|
|
matches (1,1), the same as subexpression-2 in RE#09.
|
|
RE#07 and RE#08 show that only one iteration is needed to match the subject
|
|
string, so the match in RE#11 requires only one iteration, and as such is the
|
|
last iteration of [D:6107-6109] [A:37235-37237].
|
|
RE#10 and RE#11 also illustrate [D:6127-6129] [D:6239-6241], which
|
|
specify that a repeated RE matches the null string only if it is the only
|
|
match (not this case) or if it is necessary to satisfy an interval expression
|
|
minimum (2 in this case.)
|
|
<DIV style="padding-left:16px;text-indent:0px">
|
|
<DL COMPACT>
|
|
<DT>[D:6239-6241]<DD>
|
|
An ERE matching a single character repeated by an '*' , '?' , or an
|
|
interval expression shall not match a null expression unless this is
|
|
the only match for the repetition or it is necessary to satisfy the
|
|
exact or minimum number of occurrences for the interval expression.
|
|
</DL>
|
|
</DIV>
|
|
<P>
|
|
The following examples dig deeper into replicated subexpressions.
|
|
<DIV style="padding-left:16px;text-indent:0px">
|
|
<PRE>
|
|
:RE#12:E (.?.?) xxx (0,2)(0,2)
|
|
:RE#13:E (.?.?){1} xxx (0,2)(0,2)
|
|
:RE#14:E (.?.?)(.?.?) xxx (0,3)(0,2)(2,3)
|
|
:RE#15:E (.?.?){2} xxx (0,3)(2,3)
|
|
:RE#16:E (.?.?)(.?.?)(.?.?) xxx (0,3)(0,2)(2,3)(3,3)
|
|
:RE#17:E (.?.?){3} xxx (0,3)(3,3)
|
|
:RE#18:E (.?.?)* xxx (0,3)(2,3)
|
|
</DIV>
|
|
</PRE>
|
|
Here RE#14 shows that only two iterations are needed for a complete match,
|
|
making the last iteration match for RE#18 (2,3), since the first
|
|
iteration matched (0,2), as in RE#14.
|
|
|
|
<P>
|
|
<P><HR><CENTER><FONT color=red><FONT face=courier><H3><A name="A subpattern is ">A subpattern is </A></H3></FONT></FONT></CENTER>
|
|
The term
|
|
<EM>subpattern</EM>
|
|
appears exactly once:
|
|
<DIV style="padding-left:16px;text-indent:0px">
|
|
<DL COMPACT>
|
|
<DT>[D:5907-5908]<DD>
|
|
Consistent with the whole match being the longest of the leftmost matches,
|
|
each subpattern, from left to right, shall match the longest possible string.
|
|
</DL>
|
|
</DIV>
|
|
Consider RE#04 and RE#05 again:
|
|
<DIV style="padding-left:16px;text-indent:0px">
|
|
<PRE>
|
|
:RE#04:E (a?)((ab)?)(b?) ab (0,2)(0,1)(1,1)(?,?)(1,2)
|
|
:RE#05:E ((a?)((ab)?))(b?) ab (0,2)(0,2)(0,0)(0,2)(0,2)(2,2)
|
|
</DIV>
|
|
</PRE>
|
|
If a subpattern were an entity that combined adjacent subexpressions,
|
|
e.g.,
|
|
<TT>(a?)((ab)?)</TT>
|
|
in RE#04, then [D:5907-5908] would violate [R:2359-2370].
|
|
Similarly, if a subpattern were an entity that "went inside" subexpressions,
|
|
e.g.,
|
|
<TT>(a?)</TT>
|
|
in RE#05, then again [D:5907-5908] would violate [R:2359-2370].
|
|
In other words, a subpattern can be neither larger than nor smaller than
|
|
a subexpression;
|
|
a subpattern must be a grammatical entity equivalent to a subexpression.
|
|
This corresponds to the nonterminal
|
|
<TT>nondupl_RE</TT>
|
|
in the BRE grammar; there is no direct correspondence to a nonterminal
|
|
in the ERE grammar.
|
|
However, if the optional duplication operator (*,+,?,range) is included then
|
|
subpattern corresponds to
|
|
<TT>simple_RE</TT>
|
|
in the BRE grammar and
|
|
<TT>ERE_expression</TT>
|
|
in the ERE grammar, and both [D:5907-5908] and [R:2359-2370] are satisfied.
|
|
<DIV style="padding-left:16px;text-indent:0px">
|
|
<DL COMPACT>
|
|
<DT><STRONG>DEFINITION</STRONG><DD>
|
|
A
|
|
<EM>subpattern</EM>
|
|
corresponds to the
|
|
<TT>simple_RE</TT>
|
|
nonterminal in the BRE grammar or the
|
|
<TT>ERE_expression</TT>
|
|
nonterminal in the ERE grammar.
|
|
</DL>
|
|
</DIV>
|
|
This means that subexpressions and subpatterns are of equal importance
|
|
in RE matching.
|
|
Also note that any other definition for subpattern will put
|
|
[D:5907-5908] in direct conflict with [R:2359-2370].
|
|
<P>
|
|
RE#19, RE#20 and RE#21 examine the relationship between subexpression
|
|
and subpattern:
|
|
<DIV style="padding-left:16px;text-indent:0px">
|
|
<PRE>
|
|
:RE#19:E a?((ab)?)(b?) ab (0,2)(1,1)(?,?)(1,2)
|
|
:RE#20:E (a?)((ab)?)b? ab (0,2)(0,1)(1,1)(?,?)
|
|
:RE#21:E a?((ab)?)b? ab (0,2)(1,1)(?,?)
|
|
</DIV>
|
|
</PRE>
|
|
<P>
|
|
These are all variations of RE#04.
|
|
Other than subexpression renumbering, the match for the subexpression
|
|
<TT>((ab)?)</TT>
|
|
must be the same in RE#04, RE#19, RE#20 and RE#21.
|
|
<TT>a?</TT>
|
|
is a subpattern in RE#19 and RE#21, of equal matching importance to
|
|
<TT>(a?)</TT>
|
|
in RE#04, and
|
|
<TT>b?</TT>
|
|
is a subpattern in RE#20 and RE#21, of equal matching
|
|
importance to
|
|
<TT>(b?)</TT>
|
|
in RE#04.
|
|
|
|
<P>
|
|
<P><HR><CENTER><FONT color=red><FONT face=courier><H3><A name="The Dark Corners ">The Dark Corners </A></H3></FONT></FONT></CENTER>
|
|
The remaining examples explore dark corners of the standard
|
|
and implementations.
|
|
Although the differences between some of the examples are subtle,
|
|
for some implementations it may mean the difference between an answer and
|
|
a core dump.
|
|
<P>
|
|
In RE#22 subexpression
|
|
<TT>(a*)</TT>
|
|
matches the null string at (0,0), and continues to match at that position
|
|
until the minimal range count is satisfied.
|
|
<DIV style="padding-left:16px;text-indent:0px">
|
|
<PRE>
|
|
:RE#22:E (a*){2} xxxxx (0,0)(0,0)
|
|
</DIV>
|
|
</PRE>
|
|
RE#23 through RE#27 expose implementations that sometimes do
|
|
<EM>first match</EM>
|
|
for alternation within subexpressions.
|
|
Some implementations erroneously match the first iteration of
|
|
subexpression-1 in RE#24 through RE#27 to (0,1).
|
|
RE#27 is equivalent to RE#26; the match requires two iterations, the first
|
|
matching (0,2) and the last matching (2,3).
|
|
<DIV style="padding-left:16px;text-indent:0px">
|
|
<PRE>
|
|
:RE#23:E (ab?)(b?a) aba (0,3)(0,2)(2,3)
|
|
:RE#24:E (a|ab)(ba|a) aba (0,3)(0,2)(2,3)
|
|
:RE#25:E (a|ab|ba) aba (0,2)(0,2)
|
|
:RE#26:E (a|ab|ba)(a|ab|ba) aba (0,3)(0,2)(2,3)
|
|
:RE#27:E (a|ab|ba)* aba (0,3)(2,3)
|
|
</DIV>
|
|
</PRE>
|
|
RE#28 through RE#33 expose implementations that report short matches
|
|
for some repeated subexpressions.
|
|
Some implementations report incorrect matches for
|
|
subexpression-1 in RE#30 and RE#33.
|
|
<DIV style="padding-left:16px;text-indent:0px">
|
|
<PRE>
|
|
:RE#28:E (aba|a*b) ababa (0,3)(0,3)
|
|
:RE#29:E (aba|a*b)(aba|a*b) ababa (0,5)(0,2)(2,5)
|
|
:RE#30:E (aba|a*b)* ababa (0,5)(2,5)
|
|
:RE#31:E (aba|ab|a) ababa (0,3)(0,3)
|
|
:RE#32:E (aba|ab|a)(aba|ab|a) ababa (0,5)(0,2)(2,5)
|
|
:RE#33:E (aba|ab|a)* ababa (0,5)(2,5)
|
|
</DIV>
|
|
</PRE>
|
|
RE#34 through RE#36 expose implementations that report subexpression matches
|
|
for earlier iterations of the subexpression.
|
|
Some implementations report a match for subexpression-2 in RE#36
|
|
while reporting the (2,3) match for subexpression-1: clearly a bug.
|
|
<DIV style="padding-left:16px;text-indent:0px">
|
|
<PRE>
|
|
:RE#34:E (a(b)?) aba (0,2)(0,2)(1,2)
|
|
:RE#35:E (a(b)?)(a(b)?) aba (0,3)(0,2)(1,2)(2,3)(?,?)
|
|
:RE#36:E (a(b)?)+ aba (0,3)(2,3)(?,?)
|
|
</DIV>
|
|
</PRE>
|
|
RE#37 and RE#38 expose implementations that give priority to subexpression
|
|
matching over subpattern matching.
|
|
<DIV style="padding-left:16px;text-indent:0px">
|
|
<PRE>
|
|
:RE#37:E (.*)(.*) xx (0,2)(0,2)(2,2)
|
|
:RE#38:E .*(.*) xx (0,2)(2,2)
|
|
</DIV>
|
|
</PRE>
|
|
RE#39 through RE#41 expose implementations that treat explicit vs. implicit
|
|
subexpression repetition differently.
|
|
This is a theme common to many of the previous examples.
|
|
Again, the subexpression in RE#41 requires two iterations to match,
|
|
and the second iteration matches (5,7), as illustrated by RE#40.
|
|
<DIV style="padding-left:16px;text-indent:0px">
|
|
<PRE>
|
|
:RE#39:E (a.*z|b.*y) azbazby (0,5)(0,5)
|
|
:RE#40:E (a.*z|b.*y)(a.*z|b.*y) azbazby (0,7)(0,5)(5,7)
|
|
:RE#41:E (a.*z|b.*y)* azbazby (0,7)(5,7)
|
|
</DIV>
|
|
</PRE>
|
|
RE#42 is another
|
|
<EM>first match</EM>
|
|
test.
|
|
Some implementations erroneously report a match of (0,1) for subexpression-1.
|
|
<DIV style="padding-left:16px;text-indent:0px">
|
|
<PRE>
|
|
:RE#42:E (.|..)(.*) ab (0,2)(0,2)(2,2)
|
|
</DIV>
|
|
</PRE>
|
|
RE#43 through RE#45 require only one iteration of subexpression-1 to
|
|
match the entire subject string.
|
|
RE#45 exposes three separate bugs in the implementations that were tested.
|
|
The most common was
|
|
<EM>over iteration</EM>,
|
|
where subexpression-1 is matched for a second iteration to the null string
|
|
at (3,3).
|
|
<DIV style="padding-left:16px;text-indent:0px">
|
|
<PRE>
|
|
:RE#43:E ((..)*(...)*) xxx (0,3)(0,3)(?,?)(0,3)
|
|
:RE#44:E ((..)*(...)*)((..)*(...)*) xxx (0,3)(0,3)(?,?)(0,3)(3,3)(?,?)(?,?)
|
|
:RE#45:E ((..)*(...)*)* xxx (0,3)(0,3)(?,?)(0,3)
|
|
</DIV>
|
|
</PRE>
|
|
RE#46 through RE#82 are nasty;
|
|
backreferences are intuitive neither for the implementor nor the user.
|
|
<P>
|
|
RE#49, RE#53, RE#67 and RE#68 illustrate the second part of the
|
|
<EM>subpattern</EM>
|
|
rule:
|
|
<DIV style="padding-left:16px;text-indent:0px">
|
|
<DL COMPACT>
|
|
<DT>[D:5908-5909]<DD>
|
|
For this purpose, a null string shall be considered to be longer than
|
|
no match at all.
|
|
</DL>
|
|
</DIV>
|
|
RE#53 requires close examination to see why the match is (0,2)(1,1)(2,2)
|
|
instead of (0,2)(0,1)(?,?).
|
|
The match of (0,1) for subexpression-1 is longer than (1,1), but
|
|
subexpression-1 can be repeated, and that second iteration allows
|
|
subexpression-2 to match (2,2), which is longer than (?,?) by [D:5908-5909].
|
|
<DIV style="padding-left:16px;text-indent:0px">
|
|
<PRE>
|
|
:RE#46:B \(a\{0,1\}\)*b\1 ab (0,2)(1,1)
|
|
:RE#47:B \(a*\)*b\1 ab (0,2)(1,1)
|
|
:RE#48:B \(a*\)b\1* ab (0,2)(0,1)
|
|
:RE#49:B \(a*\)*b\1* ab (0,2)(1,1)
|
|
:RE#50:B \(a\{0,1\}\)*b\(\1\) ab (0,2)(1,1)(2,2)
|
|
:RE#51:B \(a*\)*b\(\1\) ab (0,2)(1,1)(2,2)
|
|
:RE#52:B \(a*\)b\(\1\)* ab (0,2)(0,1)(?,?)
|
|
:RE#53:B \(a*\)*b\(\1\)* ab (0,2)(1,1)(2,2)
|
|
:RE#54:B \(a\{0,1\}\)*b\1 aba (0,3)(0,1)
|
|
:RE#55:B \(a*\)*b\1 aba (0,3)(0,1)
|
|
:RE#56:B \(a*\)b\1* aba (0,3)(0,1)
|
|
:RE#57:B \(a*\)*b\1* aba (0,3)(0,1)
|
|
:RE#58:B \(a*\)*b\(\1\)* aba (0,3)(0,1)(2,3)
|
|
:RE#59:B \(a\{0,1\}\)*b\1 abaa (0,3)(0,1)
|
|
:RE#60:B \(a*\)*b\1 abaa (0,3)(0,1)
|
|
:RE#61:B \(a*\)b\1* abaa (0,4)(0,1)
|
|
:RE#62:B \(a*\)*b\1* abaa (0,4)(0,1)
|
|
:RE#63:B \(a*\)*b\(\1\)* abaa (0,4)(0,1)(3,4)
|
|
:RE#64:B \(a\{0,1\}\)*b\1 aab (0,3)(2,2)
|
|
:RE#65:B \(a*\)*b\1 aab (0,3)(2,2)
|
|
:RE#66:B \(a*\)b\1* aab (0,3)(0,2)
|
|
:RE#67:B \(a*\)*b\1* aab (0,3)(2,2)
|
|
:RE#68:B \(a*\)*b\(\1\)* aab (0,3)(2,2)(3,3)
|
|
:RE#69:B \(a\{0,1\}\)*b\1 aaba (0,4)(1,2)
|
|
:RE#70:B \(a*\)*b\1 aaba (0,4)(1,2)
|
|
:RE#71:B \(a*\)b\1* aaba (0,3)(0,2)
|
|
:RE#72:B \(a*\)*b\1* aaba (0,4)(1,2)
|
|
:RE#73:B \(a*\)*b\(\1\)* aaba (0,4)(1,2)(3,4)
|
|
:RE#74:B \(a\{0,1\}\)*b\1 aabaa (0,4)(1,2)
|
|
:RE#75:B \(a*\)*b\1 aabaa (0,5)(0,2)
|
|
:RE#76:B \(a*\)b\1* aabaa (0,5)(0,2)
|
|
:RE#77:B \(a*\)*b\1* aabaa (0,5)(0,2)
|
|
:RE#78:B \(a*\)*b\(\1\)* aabaa (0,5)(0,2)(3,5)
|
|
:RE#79:B \(x\)*a\1 a NOMATCH
|
|
:RE#80:B \(x\)*a\1* a (0,1)(?,?)
|
|
:RE#81:B \(x\)*a\(\1\) a NOMATCH
|
|
:RE#82:B \(x\)*a\(\1\)* a (0,1)(?,?)(?,?)
|
|
:RE#83:E (aa(b(b))?)+ aabbaa (0,6)(4,6)(?,?)(?,?)
|
|
:RE#84:E (a(b)?)+ aba (0,3)(2,3)(?,?)
|
|
:RE#85:E ([ab]+)([bc]+)([cd]*) abcd (0,4)(0,2)(2,3)(3,4)
|
|
:RE#86:B \([ab]*\)\([bc]*\)\([cd]*\)\1 abcdaa (0,5)(0,1)(1,3)(3,4)
|
|
:RE#87:B \([ab]*\)\([bc]*\)\([cd]*\)\1 abcdab (0,6)(0,2)(2,3)(3,4)
|
|
:RE#88:B \([ab]*\)\([bc]*\)\([cd]*\)\1* abcdaa (0,6)(0,1)(1,3)(3,4)
|
|
:RE#89:B \([ab]*\)\([bc]*\)\([cd]*\)\1* abcdab (0,6)(0,2)(2,3)(3,4)
|
|
:RE#90:E ^(A([^B]*))?(B(.*))? Aa (0,2)(0,2)(1,2)
|
|
:RE#91:E ^(A([^B]*))?(B(.*))? Bb (0,2)(?,?)(?,?)(0,2)(1,2)
|
|
:RE#92:B .*\([AB]\).*\1 ABA (0,3)(0,1)
|
|
:RE#93:B$ [^A]*A \nA (0,2)
|
|
</DIV>
|
|
</PRE>
|
|
|
|
<P>
|
|
<P><HR><CENTER><FONT color=red><FONT face=courier><H3><A name="Conclusion">Conclusion</A></H3></FONT></FONT></CENTER>
|
|
It is possible to use the 2001 issue of the POSIX
|
|
<STRONG>regex</STRONG>
|
|
standard,
|
|
<EM>with the addition of one sentence</EM>,
|
|
to resolve the interpretation differences that have surfaced since 1995.
|
|
That key sentence is a precise and consistent definition for the term
|
|
<EM>subpattern</EM>.
|
|
By noting the relationship between
|
|
<EM>subpatterns</EM>
|
|
and
|
|
<EM>subexpressions</EM>,
|
|
the proposed definition is shown to be the only one that can be
|
|
consistent with all parts of the standard.
|
|
<P>
|
|
<HR>
|
|
<TABLE border=0 align=center width=96%>
|
|
<TR>
|
|
<TD align=left></TD>
|
|
<TD align=center></TD>
|
|
<TD align=right><A href="mailto:gsf@research.att.com?subject= ../re/re-interpretation.mm mm document">Glenn Fowler</A></TD>
|
|
</TR>
|
|
<TR>
|
|
<TD align=left></TD>
|
|
<TD align=center></TD>
|
|
<TD align=right>Information and Software Systems Research</TD>
|
|
</TR>
|
|
<TR>
|
|
<TD align=left></TD>
|
|
<TD align=center></TD>
|
|
<TD align=right>AT&T Labs Research</TD>
|
|
</TR>
|
|
<TR>
|
|
<TD align=left></TD>
|
|
<TD align=center></TD>
|
|
<TD align=right>Florham Park NJ</TD>
|
|
</TR>
|
|
<TR>
|
|
<TD align=left></TD>
|
|
<TD align=center></TD>
|
|
<TD align=right>January 2003</TD>
|
|
</TR>
|
|
</TABLE>
|
|
<P>
|
|
|
|
</TD></TR></TBODY></TABLE>
|
|
|
|
</BODY>
|
|
</HTML>
|