799 lines
36 KiB
Plaintext
799 lines
36 KiB
Plaintext
Technical Notes about PCRE2
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---------------------------
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These are very rough technical notes that record potentially useful information
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about PCRE2 internals. PCRE2 is a library based on the original PCRE library,
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but with a revised (and incompatible) API. To avoid confusion, the original
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library is referred to as PCRE1 below. For information about testing PCRE2, see
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the pcre2test documentation and the comment at the head of the RunTest file.
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PCRE1 releases were up to 8.3x when PCRE2 was developed, and later bug fix
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releases remain in the 8.xx series. PCRE2 releases started at 10.00 to avoid
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confusion with PCRE1.
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Historical note 1
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-----------------
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Many years ago I implemented some regular expression functions to an algorithm
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suggested by Martin Richards. The rather simple patterns were not Unix-like in
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form, and were quite restricted in what they could do by comparison with Perl.
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The interesting part about the algorithm was that the amount of space required
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to hold the compiled form of an expression was known in advance. The code to
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apply an expression did not operate by backtracking, as the original Henry
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Spencer code and current PCRE2 and Perl code does, but instead checked all
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possibilities simultaneously by keeping a list of current states and checking
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all of them as it advanced through the subject string. In the terminology of
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Jeffrey Friedl's book, it was a "DFA algorithm", though it was not a
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traditional Finite State Machine (FSM). When the pattern was all used up, all
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remaining states were possible matches, and the one matching the longest subset
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of the subject string was chosen. This did not necessarily maximize the
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individual wild portions of the pattern, as is expected in Unix and Perl-style
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regular expressions.
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Historical note 2
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-----------------
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By contrast, the code originally written by Henry Spencer (which was
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subsequently heavily modified for Perl) compiles the expression twice: once in
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a dummy mode in order to find out how much store will be needed, and then for
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real. (The Perl version probably doesn't do this any more; I'm talking about
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the original library.) The execution function operates by backtracking and
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maximizing (or, optionally, minimizing, in Perl) the amount of the subject that
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matches individual wild portions of the pattern. This is an "NFA algorithm" in
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Friedl's terminology.
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OK, here's the real stuff
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-------------------------
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For the set of functions that formed the original PCRE1 library (which are
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unrelated to those mentioned above), I tried at first to invent an algorithm
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that used an amount of store bounded by a multiple of the number of characters
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in the pattern, to save on compiling time. However, because of the greater
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complexity in Perl regular expressions, I couldn't do this. In any case, a
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first pass through the pattern is helpful for other reasons.
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Support for 16-bit and 32-bit data strings
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-------------------------------------------
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The library can be compiled in any combination of 8-bit, 16-bit or 32-bit
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modes, creating up to three different libraries. In the description that
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follows, the word "short" is used for a 16-bit data quantity, and the phrase
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"code unit" is used for a quantity that is a byte in 8-bit mode, a short in
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16-bit mode and a 32-bit word in 32-bit mode. The names of PCRE2 functions are
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given in generic form, without the _8, _16, or _32 suffix.
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Computing the memory requirement: how it was
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--------------------------------------------
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Up to and including release 6.7, PCRE1 worked by running a very degenerate
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first pass to calculate a maximum memory requirement, and then a second pass to
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do the real compile - which might use a bit less than the predicted amount of
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memory. The idea was that this would turn out faster than the Henry Spencer
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code because the first pass is degenerate and the second pass can just store
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stuff straight into memory, which it knows is big enough.
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Computing the memory requirement: how it is
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-------------------------------------------
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By the time I was working on a potential 6.8 release, the degenerate first pass
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had become very complicated and hard to maintain. Indeed one of the early
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things I did for 6.8 was to fix Yet Another Bug in the memory computation. Then
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I had a flash of inspiration as to how I could run the real compile function in
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a "fake" mode that enables it to compute how much memory it would need, while
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in most cases only ever using a small amount of working memory, and without too
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many tests of the mode that might slow it down. So I refactored the compiling
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functions to work this way. This got rid of about 600 lines of source. It
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should make future maintenance and development easier. As this was such a major
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change, I never released 6.8, instead upping the number to 7.0 (other quite
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major changes were also present in the 7.0 release).
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A side effect of this work was that the previous limit of 200 on the nesting
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depth of parentheses was removed. However, there was a downside: compiling ran
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more slowly than before (30% or more, depending on the pattern) because it now
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did a full analysis of the pattern. My hope was that this would not be a big
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issue, and in the event, nobody has commented on it.
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At release 8.34, a limit on the nesting depth of parentheses was re-introduced
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(default 250, settable at build time) so as to put a limit on the amount of
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system stack used by the compile function, which uses recursive function calls
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for nested parenthesized groups. This is a safety feature for environments with
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small stacks where the patterns are provided by users.
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Yet another pattern scan
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------------------------
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History repeated itself for PCRE2 release 10.20. A number of bugs relating to
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named subpatterns had been discovered by fuzzers. Most of these were related to
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the handling of forward references when it was not known if the named group was
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unique. (References to non-unique names use a different opcode and more
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memory.) The use of duplicate group numbers (the (?| facility) also caused
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issues.
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To get around these problems I adopted a new approach by adding a third pass
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over the pattern (really a "pre-pass"), which did nothing other than identify
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all the named subpatterns and their corresponding group numbers. This means
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that the actual compile (both the memory-computing dummy run and the real
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compile) has full knowledge of group names and numbers throughout. Several
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dozen lines of messy code were eliminated, though the new pre-pass was not
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short. In particular, parsing and skipping over [] classes is complicated.
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While working on 10.22 I realized that I could simplify yet again by moving
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more of the parsing into the pre-pass, thus avoiding doing it in two places, so
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after 10.22 was released, the code underwent yet another big refactoring. This
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is how it is from 10.23 onwards:
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The function called parse_regex() scans the pattern characters, parsing them
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into literal data and meta characters. It converts escapes such as \x{123}
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into literals, handles \Q...\E, and skips over comments and non-significant
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white space. The result of the scanning is put into a vector of 32-bit unsigned
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integers. Values less than 0x80000000 are literal data. Higher values represent
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meta-characters. The top 16-bits of such values identify the meta-character,
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and these are given names such as META_CAPTURE. The lower 16-bits are available
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for data, for example, the capturing group number. The only situation in which
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literal data values greater than 0x7fffffff can appear is when the 32-bit
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library is running in non-UTF mode. This is handled by having a special
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meta-character that is followed by the 32-bit data value.
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The size of the parsed pattern vector, when auto-callouts are not enabled, is
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bounded by the length of the pattern (with one exception). The code is written
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so that each item in the pattern uses no more vector elements than the number
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of code units in the item itself. The exception is the aforementioned large
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32-bit number handling. For this reason, 32-bit non-UTF patterns are scanned in
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advance to check for such values. When auto-callouts are enabled, the generous
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assumption is made that there will be a callout for each pattern code unit
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(which of course is only actually true if all code units are literals) plus one
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at the end. There is a default parsed pattern vector on the stack, but if this
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is not big enough, heap memory is used.
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As before, the actual compiling function is run twice, the first time to
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determine the amount of memory needed for the final compiled pattern. It
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now processes the parsed pattern vector, not the pattern itself, although some
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of the parsed items refer to strings in the pattern - for example, group
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names. As escapes and comments have already been processed, the code is a bit
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simpler than before.
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Most errors can be diagnosed during the parsing scan. For those that cannot
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(for example, "lookbehind assertion is not fixed length"), the parsed code
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contains offsets into the pattern so that the actual compiling code can
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identify where errors occur.
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The elements of the parsed pattern vector
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-----------------------------------------
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The word "offset" below means a code unit offset into the pattern. When
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PCRE2_SIZE (which is usually size_t) is no bigger than uint32_t, an offset is
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stored in a single parsed pattern element. Otherwise (typically on 64-bit
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systems) it occupies two elements. The following meta items occupy just one
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element, with no data:
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META_ACCEPT (*ACCEPT)
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META_ASTERISK *
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META_ASTERISK_PLUS *+
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META_ASTERISK_QUERY *?
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META_ATOMIC (?> start of atomic group
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META_CIRCUMFLEX ^ metacharacter
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META_CLASS [ start of non-empty class
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META_CLASS_EMPTY [] empty class - only with PCRE2_ALLOW_EMPTY_CLASS
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META_CLASS_EMPTY_NOT [^] negative empty class - ditto
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META_CLASS_END ] end of non-empty class
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META_CLASS_NOT [^ start non-empty negative class
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META_COMMIT (*COMMIT)
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META_COND_ASSERT (?(?assertion)
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META_DOLLAR $ metacharacter
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META_DOT . metacharacter
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META_END End of pattern (this value is 0x80000000)
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META_FAIL (*FAIL)
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META_KET ) closing parenthesis
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META_LOOKAHEAD (?= start of lookahead
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META_LOOKAHEADNOT (?! start of negative lookahead
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META_NOCAPTURE (?: no capture parens
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META_PLUS +
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META_PLUS_PLUS ++
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META_PLUS_QUERY +?
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META_PRUNE (*PRUNE) - no argument
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META_QUERY ?
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META_QUERY_PLUS ?+
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META_QUERY_QUERY ??
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META_RANGE_ESCAPED hyphen in class range with at least one escape
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META_RANGE_LITERAL hyphen in class range defined literally
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META_SKIP (*SKIP) - no argument
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META_THEN (*THEN) - no argument
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The two RANGE values occur only in character classes. They are positioned
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between two literals that define the start and end of the range. In an EBCDIC
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evironment it is necessary to know whether either of the range values was
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specified as an escape. In an ASCII/Unicode environment the distinction is not
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relevant.
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The following have data in the lower 16 bits, and may be followed by other data
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elements:
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META_ALT | alternation
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META_BACKREF
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META_CAPTURE
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META_ESCAPE
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META_RECURSE
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If the data for META_ALT is non-zero, it is inside a lookbehind, and the data
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is the length of its branch, for which OP_REVERSE must be generated.
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META_BACKREF, META_CAPTURE, and META_RECURSE have the capture group number as
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their data in the lower 16 bits of the element.
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META_BACKREF is followed by an offset if the back reference group number is 10
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or more. The offsets of the first ocurrences of references to groups whose
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numbers are less than 10 are put in cb->small_ref_offset[] (only the first
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occurrence is useful). On 64-bit systems this avoids using more than two parsed
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pattern elements for items such as \3. The offset is used when an error is
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given for a reference to a non-existent group.
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META_RECURSE is always followed by an offset, for use in error messages.
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META_ESCAPE has an ESC_xxx value as its data. For ESC_P and ESC_p, the next
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element contains the 16-bit type and data property values, packed together.
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ESC_g and ESC_k are used only for named references - numerical ones are turned
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into META_RECURSE or META_BACKREF as appropriate. ESC_g and ESC_k are followed
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by a length and an offset into the pattern to specify the name.
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The following have one data item that follows in the next vector element:
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META_BIGVALUE Next is a literal >= META_END
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META_OPTIONS (?i) and friends (data is new option bits)
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META_POSIX POSIX class item (data identifies the class)
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META_POSIX_NEG negative POSIX class item (ditto)
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The following are followed by a length element, then a number of character code
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values (which should match with the length):
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META_MARK (*MARK:xxxx)
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META_PRUNE_ARG (*PRUNE:xxx)
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META_SKIP_ARG (*SKIP:xxxx)
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META_THEN_ARG (*THEN:xxxx)
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The following are followed by a length element, then an offset in the pattern
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that identifies the name:
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META_COND_NAME (?(<name>) or (?('name') or (?(name)
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META_COND_RNAME (?(R&name)
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META_COND_RNUMBER (?(Rdigits)
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META_RECURSE_BYNAME (?&name)
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META_BACKREF_BYNAME \k'name'
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META_COND_RNUMBER is used for names that start with R and continue with digits,
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because this is an ambiguous case. It could be a back reference to a group with
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that name, or it could be a recursion test on a numbered group.
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This one is followed by an offset, for use in error messages, then a number:
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META_COND_NUMBER (?([+-]digits)
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The following is followed just by an offset, for use in error messages:
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META_COND_DEFINE (?(DEFINE)
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The following are also followed just by an offset, but also the lower 16 bits
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of the main word contain the length of the first branch of the lookbehind
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group; this is used when generating OP_REVERSE for that branch.
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META_LOOKBEHIND (?<=
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META_LOOKBEHINDNOT (?<!
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The following are followed by two values, the minimum and maximum. Repeat
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values are limited to 65535 (MAX_REPEAT). A maximum value of "unlimited" is
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represented by UNLIMITED_REPEAT, which is bigger than MAX_REPEAT:
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META_MINMAX {n,m} repeat
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META_MINMAX_PLUS {n,m}+ repeat
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META_MINMAX_QUERY {n,m}? repeat
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This one is followed by three elements. The first is 0 for '>' and 1 for '>=';
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the next two are the major and minor numbers:
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META_COND_VERSION (?(VERSION<op>x.y)
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Callouts are converted into one of two items:
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META_CALLOUT_NUMBER (?C with numerical argument
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META_CALLOUT_STRING (?C with string argument
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In both cases, the next two elements contain the offset and length of the next
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item in the pattern. Then there is either one callout number, or a length and
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an offset for the string argument. The length includes both delimiters.
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Traditional matching function
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-----------------------------
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The "traditional", and original, matching function is called pcre2_match(), and
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it implements an NFA algorithm, similar to the original Henry Spencer algorithm
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and the way that Perl works. This is not surprising, since it is intended to be
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as compatible with Perl as possible. This is the function most users of PCRE2
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will use most of the time. If PCRE2 is compiled with just-in-time (JIT)
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support, and studying a compiled pattern with JIT is successful, the JIT code
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is run instead of the normal pcre2_match() code, but the result is the same.
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Supplementary matching function
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-------------------------------
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There is also a supplementary matching function called pcre2_dfa_match(). This
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implements a DFA matching algorithm that searches simultaneously for all
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possible matches that start at one point in the subject string. (Going back to
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my roots: see Historical Note 1 above.) This function intreprets the same
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compiled pattern data as pcre2_match(); however, not all the facilities are
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available, and those that are do not always work in quite the same way. See the
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user documentation for details.
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The algorithm that is used for pcre2_dfa_match() is not a traditional FSM,
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because it may have a number of states active at one time. More work would be
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needed at compile time to produce a traditional FSM where only one state is
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ever active at once. I believe some other regex matchers work this way. JIT
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support is not available for this kind of matching.
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Changeable options
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------------------
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The /i, /m, or /s options (PCRE2_CASELESS, PCRE2_MULTILINE, PCRE2_DOTALL, and
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some others) may change in the middle of patterns. Their processing is handled
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entirely at compile time by generating different opcodes for the different
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settings. The runtime functions do not need to keep track of an options state.
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Format of compiled patterns
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---------------------------
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The compiled form of a pattern is a vector of unsigned code units (bytes in
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8-bit mode, shorts in 16-bit mode, 32-bit words in 32-bit mode), containing
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items of variable length. The first code unit in an item contains an opcode,
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and the length of the item is either implicit in the opcode or contained in the
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data that follows it.
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In many cases listed below, LINK_SIZE data values are specified for offsets
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within the compiled pattern. LINK_SIZE always specifies a number of bytes. The
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default value for LINK_SIZE is 2, except for the 32-bit library, where it can
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only be 4. The 8-bit library can be compiled to used 3-byte or 4-byte values,
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and the 16-bit library can be compiled to use 4-byte values, though this
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impairs performance. Specifing a LINK_SIZE larger than 2 for these libraries is
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necessary only when patterns whose compiled length is greater than 64K code
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units are going to be processed. When a LINK_SIZE value uses more than one code
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unit, the most significant unit is first.
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In this description, we assume the "normal" compilation options. Data values
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that are counts (e.g. quantifiers) are always two bytes long in 8-bit mode
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(most significant byte first), or one code unit in 16-bit and 32-bit modes.
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Opcodes with no following data
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------------------------------
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These items are all just one unit long
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OP_END end of pattern
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OP_ANY match any one character other than newline
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OP_ALLANY match any one character, including newline
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OP_ANYBYTE match any single code unit, even in UTF-8/16 mode
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OP_SOD match start of data: \A
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OP_SOM, start of match (subject + offset): \G
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OP_SET_SOM, set start of match (\K)
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OP_CIRC ^ (start of data)
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OP_CIRCM ^ multiline mode (start of data or after newline)
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OP_NOT_WORD_BOUNDARY \W
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OP_WORD_BOUNDARY \w
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OP_NOT_DIGIT \D
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OP_DIGIT \d
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OP_NOT_HSPACE \H
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OP_HSPACE \h
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OP_NOT_WHITESPACE \S
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OP_WHITESPACE \s
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OP_NOT_VSPACE \V
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OP_VSPACE \v
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OP_NOT_WORDCHAR \W
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OP_WORDCHAR \w
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OP_EODN match end of data or newline at end: \Z
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OP_EOD match end of data: \z
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OP_DOLL $ (end of data, or before final newline)
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OP_DOLLM $ multiline mode (end of data or before newline)
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OP_EXTUNI match an extended Unicode grapheme cluster
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OP_ANYNL match any Unicode newline sequence
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OP_ASSERT_ACCEPT )
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OP_ACCEPT ) These are Perl 5.10's "backtracking control
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OP_COMMIT ) verbs". If OP_ACCEPT is inside capturing
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OP_FAIL ) parentheses, it may be preceded by one or more
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OP_PRUNE ) OP_CLOSE, each followed by a count that
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OP_SKIP ) indicates which parentheses must be closed.
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OP_THEN )
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OP_ASSERT_ACCEPT is used when (*ACCEPT) is encountered within an assertion.
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This ends the assertion, not the entire pattern match. The assertion (?!) is
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always optimized to OP_FAIL.
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OP_ALLANY is used for '.' when PCRE2_DOTALL is set. It is also used for \C in
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non-UTF modes and in UTF-32 mode (since one code unit still equals one
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character). Another use is for [^] when empty classes are permitted
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(PCRE2_ALLOW_EMPTY_CLASS is set).
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Backtracking control verbs with optional data
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---------------------------------------------
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(*THEN) without an argument generates the opcode OP_THEN and no following data.
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OP_MARK is followed by the mark name, preceded by a length in one code unit,
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and followed by a binary zero. For (*PRUNE), (*SKIP), and (*THEN) with
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arguments, the opcodes OP_PRUNE_ARG, OP_SKIP_ARG, and OP_THEN_ARG are used,
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with the name following in the same format as OP_MARK.
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Matching literal characters
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---------------------------
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The OP_CHAR opcode is followed by a single character that is to be matched
|
|
casefully. For caseless matching, OP_CHARI is used. In UTF-8 or UTF-16 modes,
|
|
the character may be more than one code unit long. In UTF-32 mode, characters
|
|
are always exactly one code unit long.
|
|
|
|
If there is only one character in a character class, OP_CHAR or OP_CHARI is
|
|
used for a positive class, and OP_NOT or OP_NOTI for a negative one (that is,
|
|
for something like [^a]).
|
|
|
|
|
|
Repeating single characters
|
|
---------------------------
|
|
|
|
The common repeats (*, +, ?), when applied to a single character, use the
|
|
following opcodes, which come in caseful and caseless versions:
|
|
|
|
Caseful Caseless
|
|
OP_STAR OP_STARI
|
|
OP_MINSTAR OP_MINSTARI
|
|
OP_POSSTAR OP_POSSTARI
|
|
OP_PLUS OP_PLUSI
|
|
OP_MINPLUS OP_MINPLUSI
|
|
OP_POSPLUS OP_POSPLUSI
|
|
OP_QUERY OP_QUERYI
|
|
OP_MINQUERY OP_MINQUERYI
|
|
OP_POSQUERY OP_POSQUERYI
|
|
|
|
Each opcode is followed by the character that is to be repeated. In ASCII or
|
|
UTF-32 modes, these are two-code-unit items; in UTF-8 or UTF-16 modes, the
|
|
length is variable. Those with "MIN" in their names are the minimizing
|
|
versions. Those with "POS" in their names are possessive versions. Other kinds
|
|
of repeat make use of these opcodes:
|
|
|
|
Caseful Caseless
|
|
OP_UPTO OP_UPTOI
|
|
OP_MINUPTO OP_MINUPTOI
|
|
OP_POSUPTO OP_POSUPTOI
|
|
OP_EXACT OP_EXACTI
|
|
|
|
Each of these is followed by a count and then the repeated character. The count
|
|
is two bytes long in 8-bit mode (most significant byte first), or one code unit
|
|
in 16-bit and 32-bit modes.
|
|
|
|
OP_UPTO matches from 0 to the given number. A repeat with a non-zero minimum
|
|
and a fixed maximum is coded as an OP_EXACT followed by an OP_UPTO (or
|
|
OP_MINUPTO or OPT_POSUPTO).
|
|
|
|
Another set of matching repeating opcodes (called OP_NOTSTAR, OP_NOTSTARI,
|
|
etc.) are used for repeated, negated, single-character classes such as [^a]*.
|
|
The normal single-character opcodes (OP_STAR, etc.) are used for repeated
|
|
positive single-character classes.
|
|
|
|
|
|
Repeating character types
|
|
-------------------------
|
|
|
|
Repeats of things like \d are done exactly as for single characters, except
|
|
that instead of a character, the opcode for the type (e.g. OP_DIGIT) is stored
|
|
in the next code unit. The opcodes are:
|
|
|
|
OP_TYPESTAR
|
|
OP_TYPEMINSTAR
|
|
OP_TYPEPOSSTAR
|
|
OP_TYPEPLUS
|
|
OP_TYPEMINPLUS
|
|
OP_TYPEPOSPLUS
|
|
OP_TYPEQUERY
|
|
OP_TYPEMINQUERY
|
|
OP_TYPEPOSQUERY
|
|
OP_TYPEUPTO
|
|
OP_TYPEMINUPTO
|
|
OP_TYPEPOSUPTO
|
|
OP_TYPEEXACT
|
|
|
|
|
|
Match by Unicode property
|
|
-------------------------
|
|
|
|
OP_PROP and OP_NOTPROP are used for positive and negative matches of a
|
|
character by testing its Unicode property (the \p and \P escape sequences).
|
|
Each is followed by two code units that encode the desired property as a type
|
|
and a value. The types are a set of #defines of the form PT_xxx, and the values
|
|
are enumerations of the form ucp_xx, defined in the pcre2_ucp.h source file.
|
|
The value is relevant only for PT_GC (General Category), PT_PC (Particular
|
|
Category), and PT_SC (Script).
|
|
|
|
Repeats of these items use the OP_TYPESTAR etc. set of opcodes, followed by
|
|
three code units: OP_PROP or OP_NOTPROP, and then the desired property type and
|
|
value.
|
|
|
|
|
|
Character classes
|
|
-----------------
|
|
|
|
If there is only one character in a class, OP_CHAR or OP_CHARI is used for a
|
|
positive class, and OP_NOT or OP_NOTI for a negative one (that is, for
|
|
something like [^a]).
|
|
|
|
A set of repeating opcodes (called OP_NOTSTAR etc.) are used for repeated,
|
|
negated, single-character classes. The normal single-character opcodes
|
|
(OP_STAR, etc.) are used for repeated positive single-character classes.
|
|
|
|
When there is more than one character in a class, and all the code points are
|
|
less than 256, OP_CLASS is used for a positive class, and OP_NCLASS for a
|
|
negative one. In either case, the opcode is followed by a 32-byte (16-short,
|
|
8-word) bit map containing a 1 bit for every character that is acceptable. The
|
|
bits are counted from the least significant end of each unit. In caseless mode,
|
|
bits for both cases are set.
|
|
|
|
The reason for having both OP_CLASS and OP_NCLASS is so that, in UTF-8 and
|
|
16-bit and 32-bit modes, subject characters with values greater than 255 can be
|
|
handled correctly. For OP_CLASS they do not match, whereas for OP_NCLASS they
|
|
do.
|
|
|
|
For classes containing characters with values greater than 255 or that contain
|
|
\p or \P, OP_XCLASS is used. It optionally uses a bit map if any acceptable
|
|
code points are less than 256, followed by a list of pairs (for a range) and/or
|
|
single characters and/or properties. In caseless mode, both cases are
|
|
explicitly listed.
|
|
|
|
OP_XCLASS is followed by a LINK_SIZE value containing the total length of the
|
|
opcode and its data. This is followed by a code unit containing flag bits:
|
|
XCL_NOT indicates that this is a negative class, and XCL_MAP indicates that a
|
|
bit map is present. There follows the bit map, if XCL_MAP is set, and then a
|
|
sequence of items coded as follows:
|
|
|
|
XCL_END marks the end of the list
|
|
XCL_SINGLE one character follows
|
|
XCL_RANGE two characters follow
|
|
XCL_PROP a Unicode property (type, value) follows
|
|
XCL_NOTPROP a Unicode property (type, value) follows
|
|
|
|
If a range starts with a code point less than 256 and ends with one greater
|
|
than 255, it is split into two ranges, with characters less than 256 being
|
|
indicated in the bit map, and the rest with XCL_RANGE.
|
|
|
|
When XCL_NOT is set, the bit map, if present, contains bits for characters that
|
|
are allowed (exactly as for OP_NCLASS), but the list of items that follow it
|
|
specifies characters and properties that are not allowed.
|
|
|
|
|
|
Back references
|
|
---------------
|
|
|
|
OP_REF (caseful) or OP_REFI (caseless) is followed by a count containing the
|
|
reference number when the reference is to a unique capturing group (either by
|
|
number or by name). When named groups are used, there may be more than one
|
|
group with the same name. In this case, a reference to such a group by name
|
|
generates OP_DNREF or OP_DNREFI. These are followed by two counts: the index
|
|
(not the byte offset) in the group name table of the first entry for the
|
|
required name, followed by the number of groups with the same name. The
|
|
matching code can then search for the first one that is set.
|
|
|
|
|
|
Repeating character classes and back references
|
|
-----------------------------------------------
|
|
|
|
Single-character classes are handled specially (see above). This section
|
|
applies to other classes and also to back references. In both cases, the repeat
|
|
information follows the base item. The matching code looks at the following
|
|
opcode to see if it is one of these:
|
|
|
|
OP_CRSTAR
|
|
OP_CRMINSTAR
|
|
OP_CRPOSSTAR
|
|
OP_CRPLUS
|
|
OP_CRMINPLUS
|
|
OP_CRPOSPLUS
|
|
OP_CRQUERY
|
|
OP_CRMINQUERY
|
|
OP_CRPOSQUERY
|
|
OP_CRRANGE
|
|
OP_CRMINRANGE
|
|
OP_CRPOSRANGE
|
|
|
|
All but the last three are single-code-unit items, with no data. The others are
|
|
followed by the minimum and maximum repeat counts.
|
|
|
|
|
|
Brackets and alternation
|
|
------------------------
|
|
|
|
A pair of non-capturing round brackets is wrapped round each expression at
|
|
compile time, so alternation always happens in the context of brackets.
|
|
|
|
[Note for North Americans: "bracket" to some English speakers, including
|
|
myself, can be round, square, curly, or pointy. Hence this usage rather than
|
|
"parentheses".]
|
|
|
|
Non-capturing brackets use the opcode OP_BRA, capturing brackets use OP_CBRA. A
|
|
bracket opcode is followed by a LINK_SIZE value which gives the offset to the
|
|
next alternative OP_ALT or, if there aren't any branches, to the matching
|
|
OP_KET opcode. Each OP_ALT is followed by a LINK_SIZE value giving the offset
|
|
to the next one, or to the OP_KET opcode. For capturing brackets, the bracket
|
|
number is a count that immediately follows the offset.
|
|
|
|
OP_KET is used for subpatterns that do not repeat indefinitely, and OP_KETRMIN
|
|
and OP_KETRMAX are used for indefinite repetitions, minimally or maximally
|
|
respectively (see below for possessive repetitions). All three are followed by
|
|
a LINK_SIZE value giving (as a positive number) the offset back to the matching
|
|
bracket opcode.
|
|
|
|
If a subpattern is quantified such that it is permitted to match zero times, it
|
|
is preceded by one of OP_BRAZERO, OP_BRAMINZERO, or OP_SKIPZERO. These are
|
|
single-unit opcodes that tell the matcher that skipping the following
|
|
subpattern entirely is a valid match. In the case of the first two, not
|
|
skipping the pattern is also valid (greedy and non-greedy). The third is used
|
|
when a pattern has the quantifier {0,0}. It cannot be entirely discarded,
|
|
because it may be called as a subroutine from elsewhere in the pattern.
|
|
|
|
A subpattern with an indefinite maximum repetition is replicated in the
|
|
compiled data its minimum number of times (or once with OP_BRAZERO if the
|
|
minimum is zero), with the final copy terminating with OP_KETRMIN or OP_KETRMAX
|
|
as appropriate.
|
|
|
|
A subpattern with a bounded maximum repetition is replicated in a nested
|
|
fashion up to the maximum number of times, with OP_BRAZERO or OP_BRAMINZERO
|
|
before each replication after the minimum, so that, for example, (abc){2,5} is
|
|
compiled as (abc)(abc)((abc)((abc)(abc)?)?)?, except that each bracketed group
|
|
has the same number.
|
|
|
|
When a repeated subpattern has an unbounded upper limit, it is checked to see
|
|
whether it could match an empty string. If this is the case, the opcode in the
|
|
final replication is changed to OP_SBRA or OP_SCBRA. This tells the matcher
|
|
that it needs to check for matching an empty string when it hits OP_KETRMIN or
|
|
OP_KETRMAX, and if so, to break the loop.
|
|
|
|
|
|
Possessive brackets
|
|
-------------------
|
|
|
|
When a repeated group (capturing or non-capturing) is marked as possessive by
|
|
the "+" notation, e.g. (abc)++, different opcodes are used. Their names all
|
|
have POS on the end, e.g. OP_BRAPOS instead of OP_BRA and OP_SCBRAPOS instead
|
|
of OP_SCBRA. The end of such a group is marked by OP_KETRPOS. If the minimum
|
|
repetition is zero, the group is preceded by OP_BRAPOSZERO.
|
|
|
|
|
|
Once-only (atomic) groups
|
|
-------------------------
|
|
|
|
These are just like other subpatterns, but they start with the opcode
|
|
OP_ONCE or OP_ONCE_NC. The former is used when there are no capturing brackets
|
|
within the atomic group; the latter when there are. The distinction is needed
|
|
for when there is a backtrack to before the group - any captures within the
|
|
group must be reset, so it is necessary to retain backtracking points inside
|
|
the group, even after it is complete, in order to do this. When there are no
|
|
captures in an atomic group, all the backtracking can be discarded when it is
|
|
complete. This is more efficient, and also uses less stack.
|
|
|
|
The check for matching an empty string in an unbounded repeat is handled
|
|
entirely at runtime, so there are just these two opcodes for atomic groups.
|
|
|
|
|
|
Assertions
|
|
----------
|
|
|
|
Forward assertions are also just like other subpatterns, but starting with one
|
|
of the opcodes OP_ASSERT or OP_ASSERT_NOT. Backward assertions use the opcodes
|
|
OP_ASSERTBACK and OP_ASSERTBACK_NOT, and the first opcode inside the assertion
|
|
is OP_REVERSE, followed by a count of the number of characters to move back the
|
|
pointer in the subject string. In ASCII or UTF-32 mode, the count is also the
|
|
number of code units, but in UTF-8/16 mode each character may occupy more than
|
|
one code unit. A separate count is present in each alternative of a lookbehind
|
|
assertion, allowing them to have different (but fixed) lengths.
|
|
|
|
|
|
Conditional subpatterns
|
|
-----------------------
|
|
|
|
These are like other subpatterns, but they start with the opcode OP_COND, or
|
|
OP_SCOND for one that might match an empty string in an unbounded repeat.
|
|
|
|
If the condition is a back reference, this is stored at the start of the
|
|
subpattern using the opcode OP_CREF followed by a count containing the
|
|
reference number, provided that the reference is to a unique capturing group.
|
|
If the reference was by name and there is more than one group with that name,
|
|
OP_DNCREF is used instead. It is followed by two counts: the index in the group
|
|
names table, and the number of groups with the same name. The allows the
|
|
matcher to check if any group with the given name is set.
|
|
|
|
If the condition is "in recursion" (coded as "(?(R)"), or "in recursion of
|
|
group x" (coded as "(?(Rx)"), the group number is stored at the start of the
|
|
subpattern using the opcode OP_RREF (with a value of RREF_ANY (0xffff) for "the
|
|
whole pattern") or OP_DNRREF (with data as for OP_DNCREF).
|
|
|
|
For a DEFINE condition, OP_FALSE is used (with no associated data). During
|
|
compilation, however, a DEFINE condition is coded as OP_DEFINE so that, when
|
|
the conditional group is complete, there can be a check to ensure that it
|
|
contains only one top-level branch. Once this has happened, the opcode is
|
|
changed to OP_FALSE, so the matcher never sees OP_DEFINE.
|
|
|
|
There is a special PCRE2-specific condition of the form (VERSION[>]=x.y), which
|
|
tests the PCRE2 version number. This compiles into one of the opcodes OP_TRUE
|
|
or OP_FALSE.
|
|
|
|
If a condition is not a back reference, recursion test, DEFINE, or VERSION, it
|
|
must start with an assertion, whose opcode normally immediately follows OP_COND
|
|
or OP_SCOND. However, if automatic callouts are enabled, a callout is inserted
|
|
immediately before the assertion. It is also possible to insert a manual
|
|
callout at this point. Only assertion conditions may have callouts preceding
|
|
the condition.
|
|
|
|
A condition that is the negative assertion (?!) is optimized to OP_FAIL in all
|
|
parts of the pattern, so this is another opcode that may appear as a condition.
|
|
It is treated the same as OP_FALSE.
|
|
|
|
|
|
Recursion
|
|
---------
|
|
|
|
Recursion either matches the current pattern, or some subexpression. The opcode
|
|
OP_RECURSE is followed by a LINK_SIZE value that is the offset to the starting
|
|
bracket from the start of the whole pattern. OP_RECURSE is also used for
|
|
"subroutine" calls, even though they are not strictly a recursion. Repeated
|
|
recursions are automatically wrapped inside OP_ONCE brackets, because otherwise
|
|
some patterns broke them. A non-repeated recursion is not wrapped in OP_ONCE
|
|
brackets, but it is nevertheless still treated as an atomic group.
|
|
|
|
|
|
Callout
|
|
-------
|
|
|
|
A callout can nowadays have either a numerical argument or a string argument.
|
|
These use OP_CALLOUT or OP_CALLOUT_STR, respectively. In each case these are
|
|
followed by two LINK_SIZE values giving the offset in the pattern string to the
|
|
start of the following item, and another count giving the length of this item.
|
|
These values make it possible for pcre2test to output useful tracing
|
|
information using callouts.
|
|
|
|
In the case of a numeric callout, after these two values there is a single code
|
|
unit containing the callout number, in the range 0-255, with 255 being used for
|
|
callouts that are automatically inserted as a result of the PCRE2_AUTO_CALLOUT
|
|
option. Thus, this opcode item is of fixed length:
|
|
|
|
[OP_CALLOUT] [PATTERN_OFFSET] [PATTERN_LENGTH] [NUMBER]
|
|
|
|
For callouts with string arguments, OP_CALLOUT_STR has three more data items:
|
|
a LINK_SIZE value giving the complete length of the entire opcode item, a
|
|
LINK_SIZE item containing the offset within the pattern string to the start of
|
|
the string argument, and the string itself, preceded by its starting delimiter
|
|
and followed by a binary zero. When a callout function is called, a pointer to
|
|
the actual string is passed, but the delimiter can be accessed as string[-1] if
|
|
the application needs it. In the 8-bit library, the callout in /X(?C'abc')Y/ is
|
|
compiled as the following bytes (decimal numbers represent binary values):
|
|
|
|
[OP_CALLOUT_STR] [0] [10] [0] [1] [0] [14] [0] [5] ['] [a] [b] [c] [0]
|
|
-------- ------- -------- -------
|
|
| | | |
|
|
------- LINK_SIZE items ------
|
|
|
|
Opcode table checking
|
|
---------------------
|
|
|
|
The last opcode that is defined in pcre2_internal.h is OP_TABLE_LENGTH. This is
|
|
not a real opcode, but is used to check that tables indexed by opcode are the
|
|
correct length, in order to catch updating errors.
|
|
|
|
Philip Hazel
|
|
November 2016
|