pcre2el
or rxt
(RegeXp Translator or RegeXp Tools) is a utility
for working with regular expressions in Emacs, based on a
recursive-descent parser for regexp syntax. In addition to
converting (a subset of) PCRE syntax into its Emacs equivalent, it
can do the following:
- convert Emacs syntax to PCRE
- convert either syntax to
rx
, an S-expression based regexp syntax - untangle complex regexps by showing the parse tree in
rx
form and highlighting the corresponding chunks of code - show the complete list of strings (productions) matching a regexp, provided the list is finite
- provide live font-locking of regexp syntax (so far only for Elisp buffers – other modes on the TODO list)
Enable rxt-mode
or its global equivalent rxt-global-mode
to get the default key-bindings. There are three sets of commands:
commands that take a PCRE regexp, commands which take an Emacs
regexp, and commands that try to do the right thing based on the
current mode. Currently, this means Emacs syntax in
emacs-lisp-mode
and lisp-interaction-mode
, and PCRE syntax
everywhere else.
The default key bindings all begin with C-c /
and have a mnemonic
structure: C-c / <source> <target>
, or just C-c / <target>
for
the “do what I mean” commands. The complete list of key bindings is
given here and explained in more detail below:
- “Do-what-I-mean” commands:
C-c / /
rxt-explain
C-c / c
rxt-convert-syntax
C-c / x
rxt-convert-to-rx
C-c / ′
rxt-convert-to-strings
- Commands that work on a PCRE regexp:
C-c / p e
rxt-pcre-to-elisp
C-c / %
pcre-query-replace-regexp
C-c / p x
rxt-pcre-to-rx
C-c / p s
rxt-pcre-to-sre
C-c / p ′
rxt-pcre-to-strings
C-c / p /
rxt-explain-pcre
- Commands that work on an Emacs regexp:
C-c / e /
rxt-explain-elisp
C-c / e p
rxt-elisp-to-pcre
C-c / e x
rxt-elisp-to-rx
C-c / e s
rxt-elisp-to-sre
C-c / e ′
rxt-elisp-to-strings
C-c / e t
rxt-toggle-elisp-rx
C-c / t
rxt-toggle-elisp-rx
When used interactively, the conversion commands can read a regexp either from the current buffer or from the minibuffer. The output is displayed in the minibuffer and copied to the kill-ring.
- When called with a prefix argument (
C-u
), they read a regular expression from the minibuffer literally, without further processing – meaning there’s no need to double the backslashes if it’s an Emacs regexp. This is the same way commands likequery-replace-regexp
read input. - When the region is active, they use they the region contents, again literally (without any translation of string syntax).
- With neither a prefix arg nor an active region, the behavior
depends on whether the command expects an Emacs regexp or
a PCRE one.
Commands that take an Emacs regexp behave like
C-x C-e
: they evaluate the sexp before point (which could be simply a string literal) and use its value. This is designed for use in Elisp buffers. As a special case, if point is inside a string, it’s first moved to the string end, so in practice they should work as long as point is somewhere within the regexp literal.Commands that take a PCRE regexp try to read a Perl-style delimited regex literal after point in the current buffer, including its flags. For example, putting point before the
m
in the following example and doingC-c / p e
(rxt-pcre-to-elisp
) displays\(?:bar\|foo\)
, correctly stripping out the whitespace and comment:$x =~ m/ foo | (?# comment) bar /x
The PCRE reader currently only works with
/ ... /
delimiters. It will ignore any precedingm
,s
, orqr
operator, as well as the replacement part of ans
construction.Readers for other PCRE-using languages are on the TODO list.
The translation functions display their result in the minibuffer
and copy it to the kill ring. When translating something into
Elisp syntax, you might need to use the result either literally
(e.g. for interactive input to a command like
query-replace-regexp
), or as a string to paste into Lisp code.
To allow both uses, rxt-pcre-to-elisp
copies both versions
successively to the kill-ring. The literal regexp without string
quoting is the top element of the kill-ring, while the Lisp string
is the second-from-top. You can paste the literal regexp somewhere
by doing C-y
, or the Lisp string by C-y M-y
.
rxt-convert-syntax
(C-c / c
) converts between Emacs and PCRE
syntax, depending on the major mode in effect when called.
Alternatively, you can specify the conversion direction explicitly
by using either rxt-pcre-to-elisp
(C-c / p e
) or
rxt-elisp-to-pcre
(C-c / e p
).
Similarly, rxt-convert-to-rx
(C-c / x
) converts either kind of
syntax to rx
form, while rxt-convert-pcre-to-rx
(C-c / p x
)
and rxt-convert-elisp-to-rx
(C-c / e x
) convert to rx
from a
specified source type.
In Elisp buffers, you can use rxt-toggle-elisp-rx
(C-c / t
or
C-c / e t
) to switch the regexp at point back and forth between
string and rx
syntax. Point should either be within an rx
or
rx-to-string
form or a string literal for this to work.
If you want to use emulated PCRE regexp syntax in all Emacs
commands, try pcre-mode
, which uses Emacs’s advice system to
make all commands that read regexps using the minibuffer use
emulated PCRE syntax. It should also work with Isearch.
This feature is still fairly experimental. It may fail to work or do the wrong thing with certain commands. Please report bugs.
pcre-query-replace-regexp
was originally defined to do
query-replace using emulated PCRE regexps, and is now made
somewhat obsolete by pcre-mode
. It is bound to C-c / %
by
default, by analogy with M-%
. Put the following in your
.emacs
if you want to use PCRE-style query replacement
everywhere:
(global-set-key [(meta %)] 'pcre-query-replace-regexp)
When syntax-highlighting isn’t enough to untangle some gnarly
regexp you find in the wild, try the ‘explain’ commands:
rxt-explain
(C-c / /
), rxt-explain-pcre
(C-c / p
) and
rxt-explain-elisp
(C-c / e
). These display the original regexp
along with its pretty-printed rx
equivalent in a new buffer.
Moving point around either in the original regexp or the rx
translation highlights corresponding pieces of syntax, which can
aid in seeing things like the scope of quantifiers.
I call them “explain” commands because the rx
form is close to a
plain syntax tree, and this plus the wordiness of the operators
usually helps to clarify what is going on. People who dislike
Lisp syntax might disagree with this assessment.
Occasionally you come across a regexp which is designed to match a
finite set of strings, e.g. a set of keywords, and it would be
useful to recover the original set. (In Emacs you can generate
such regexps using regexp-opt
). The commands
rxt-convert-to-strings
(C-c / ′
), rxt-pcre-to-strings
(C-c
/ p ′
) or rxt-elisp-to-strings
(C-c / e ′
) accomplish this by
generating all the matching strings (“productions”) of a regexp.
(The productions are copied to the kill ring as a Lisp list).
An example in Lisp code:
(regexp-opt '("cat" "caterpillar" "catatonic")) ;; => "\\(?:cat\\(?:atonic\\|erpillar\\)?\\)" (rxt-elisp-to-strings "\\(?:cat\\(?:atonic\\|erpillar\\)?\\)") ;; => '("cat" "caterpillar" "catatonic")
For obvious reasons, these commands only work with regexps that
don’t include any unbounded quantifiers like +
or *
. They also
can’t enumerate all the characters that match a named character
class like [[:alnum:]]
. In either case they will give a (hopefully
meaningful) error message. Due to the nature of permutations, it’s
still possible for a finite regexp to generate a huge number of
productions, which will eat memory and slow down your Emacs. Be
ready with C-g
if necessary.
The Emacs RE-Builder is a useful visual tool which allows using
several different built-in syntaxes via reb-change-syntax
(C-c
TAB
). It supports Elisp read and literal syntax and rx
, but it
can only convert from the symbolic forms to Elisp, not the other
way. This package hacks the RE-Builder to also work with emulated
PCRE syntax, and to convert transparently between Elisp, PCRE and
rx syntaxes. PCRE mode reads a delimited Perl-like literal of the
form / ... /
, and it should correctly support using the x
and
s
flags.
Example of using the conversion functions:
(rxt-pcre-to-elisp "(abc|def)\\w+\\d+") ;; => "\\(\\(?:abc\\|def\\)\\)[_[:alnum:]]+[[:digit:]]+"
All the conversion functions take a single string argument, the regexp to translate:
rxt-pcre-to-elisp
rxt-pcre-to-rx
rxt-pcre-to-sre
rxt-pcre-to-strings
rxt-elisp-to-pcre
rxt-elisp-to-rx
rxt-elisp-to-sre
rxt-elisp-to-strings
PCRE has a complicated syntax and semantics, only some of which can be translated into Elisp. The following subset of PCRE should be correctly parsed and converted:
- parenthesis grouping
( .. )
, including shy matches(?: ... )
- backreferences (various syntaxes), but only up to 9 per expression
- alternation
|
- greedy and non-greedy quantifiers
*
,*?
,+
,+?
,?
and??
(all of which are the same in Elisp as in PCRE) - numerical quantifiers
{M,N}
- beginning/end of string
\A
,\Z
- string quoting
\Q .. \E
- word boundaries
\b
,\B
(these are the same in Elisp) - single character escapes
\a
,\c
,\e
,\f
,\n
,\r
,\t
,\x
, and\octal digits
(but see below about non-ASCII characters) - character classes
[...]
including Posix escapes - character classes
\d
,\D
,\h
,\H
,\s
,\S
,\v
,\V
both within character class brackets and outside - word and non-word characters
\w
and\W
(Emacs has the same syntax, but its meaning is different) s
(single line) andx
(extended syntax) flags, in regexp literals, or set within the expression via(?xs-xs)
or(?xs-xs: .... )
syntax- comments
(?# ... )
Most of the more esoteric PCRE features can’t really be supported
by simple translation to Elisp regexps. These include the
different lookaround assertions, conditionals, and the
“backtracking control verbs” (* ...)
. OTOH, there are a few
other syntaxes which are currently unsupported and possibly could be:
\L
,\U
,\l
,\u
case modifiers\g{...}
backreferences
- The order of alternatives and characters in char classes sometimes gets shifted around, which is annoying.
- Although the string parser tries to interpret PCRE’s octal and
hexadecimal escapes correctly, there are problems with matching
8-bit characters that I don’t use enough to properly understand,
e.g.:
(string-match-p (rxt-pcre-to-elisp "\\377") "\377") => nil
A fix for this would be welcome.
- Most of PCRE’s rules for how
^
,\A
,$
and\Z
interact with newlines are not implemented, since they seem less relevant to Emacs’s buffer-oriented rather than line-oriented model. However, the different meanings of the.
metacharacter are implemented (it matches newlines with the/s
flag, but not otherwise). - Not currently namespace clean (both
rxt-
and a couple ofpcre-
functions).
- Python-specific extensions to PCRE?
- Language-specific stuff to enable regexp font-locking and
explaining in different modes. Each language would need two
functions, which could be kept in an alist:
- A function to read PCRE regexps, taking the string syntax into
account. E.g., Python has single-quoted, double-quoted and raw
strings, each with different quoting rules. PHP has the kind
of belt-and-suspenders solution you would expect: regexps are
in strings, and you have to include the
/ ... /
delimiters! Duh. - A function to copy faces back from the parsed string to the original buffer text. This has to recognize any escape sequences so they can be treated as a single character.
- A function to read PCRE regexps, taking the string syntax into
account. E.g., Python has single-quoted, double-quoted and raw
strings, each with different quoting rules. PHP has the kind
of belt-and-suspenders solution you would expect: regexps are
in strings, and you have to include the
Internally, rxt
defines an abstract syntax tree data type for
regular expressions, parsers for Elisp and PCRE syntax, and
“unparsers” from to PCRE, rx, and SRE syntax. Converting from a
parsed syntax tree to Elisp syntax is a two-step process: first
convert to rx
form, then let rx-to-string
do the heavy lifting.
See rxt-parse-re
, rxt-adt->pcre
, rxt-adt->rx
, and
rxt-adt->sre
, and the section beginning “Regexp ADT” in
pcre2el.el for details.
This code is partially based on Olin Shivers’ reference SRE
implementation in scsh, although it is simplified in some respects
and extended in others. See scsh/re.scm
, scsh/spencer.scm
and
scsh/posixstr.scm
in the scsh
source tree for details. In
particular, pcre2el
steals the idea of an abstract data type for
regular expressions and the general structure of the string regexp
parser and unparser. The data types for character sets are extended
in order to support symbolic translation between character set
expressions without assuming a small (Latin1) character set. The
string parser is also extended to parse a bigger variety of
constructions, including POSIX character classes and various Emacs
and Perl regexp assertions. Otherwise, only the bare minimum of
scsh’s abstract data type is implemented.
Emacs regexps have their annoyances, but it is worth getting used
to them. The Emacs assertions for word boundaries, symbol
boundaries, and syntax classes depending on the syntax of the mode
in effect are especially useful. (PCRE has \b
for word-boundary,
but AFAIK it doesn’t have separate assertions for beginning-of-word
and end-of-word). Other things that might be done with huge regexps
in other languages can be expressed more understandably in Elisp
using combinations of `save-excursion’ with the various searches
(regexp, literal, skip-syntax-forward, sexp-movement functions,
etc.).
There’s not much point in using rxt-pcre-to-elisp
to use PCRE
notation in a Lisp program you’re going to maintain, since you
still have to double all the backslashes. Better to just use the
converted result (or better yet, the rx
form).
This was originally created out of an answer to a stackoverflow question: http://stackoverflow.com/questions/9118183/elisp-mechanism-for-converting-pcre-regexps-to-emacs-regexps
Thanks to:
- Wes Hardaker (hardaker) for the initial inspiration and subsequent hacking
- priyadarshan for requesting RX/SRE support
- Daniel Colascione (dcolascione) for a patch to support Emacs’s explicitly-numbered match groups
- Aaron Meurer (asmeurer) for requesting Isearch support
- Philippe Vaucher (silex) for a patch to support
ibuffer-do-replace-regexp
in PCRE mode