libsregex - A non-backtracking NFA/DFA-based Perl-compatible regex engine library for matching on large data streams
- Name
- Status
- Syntax Supported
- API
- Examples
- Installation
- Test Suite
- TODO
- Author
- Copyright and License
- See Also
This library is already quite usable and some people are already using it in production.
Nevertheless this library is still under heavy development. The API is still in flux and may be changed quickly without notice.
This is a pure C library that is designed to have zero dependencies.
No pathological regexes exist for this regex engine because it does not use a backtracking algorithm at all.
Already rewrote the code base of Russ Cox's re1 library using the nginx coding style (yes, I love it!), also incorporated a clone of the nginx memory pool into it for memory management.
Already ported the Thompson and Pike VM backends to sregex. The former is just for yes-or-no matching, and the latter also supports sub-match capturing.
Implemented the case-insensitive matching mode via the SRE_REGEX_CASELESS
flag.
The full streaming matching API for the sregex engine has already been implemented,
for both the Pike and Thompson regex VMs. The sub-match capturing also supports streaming processing.
When the state machine is yielded (that is, returning SRE_AGAIN
on the current input data chunk),
sregex will always output the current value range for the $&
sub-match capture in the user-supplied
ovector
array.
Almost all the relevant test cases for PCRE 8.32 and Perl 5.16.2 have been imported into sregex's test suite and all tests are passing right now.
Already implemented an API for assembling multiple user regexes and returning an ID indicating exactly which regex is matched (first), as well as the corresponding sub-match captures.
There is also a Just-in-Time (JIT) compiler targeting x86_64
for the Thompson VM.
The following Perl 5 regex syntax features have already been implemented.
^ match the beginning of lines
$ match the end of lines
\A match only at beginning of stream
\z match only at end of stream
\b match a word boundary
\B match except at a word boundary
. match any char
[ab0-9] character classes (positive)
[^ab0-9] character classes (negative)
\d match a digit character ([0-9])
\D match a non-digit character ([^0-9])
\s match a whitespace character ([ \f\n\r\t])
\S match a non-whitespace character ([^ \f\n\r\t])
\h match a horizontal whitespace character
\H match a character that isn't horizontal whitespace
\v match a vertical whitespace character
\V match a character that isn't vertical whitespace
\w match a "word" character ([A-Za-z0-9_])
\W match a non-"word" character ([^A-Za-z0-9_])
\cK control char (example: VT)
\N match a character that isn't a newline
ab concatenation; first match a, and then b
a|b alternation; match a or b
(a) capturing parentheses
(?:a) non-capturing parantheses
a? match 1 or 0 times, greedily
a* match 0 or more times, greedily
a+ match 1 or more times, greedily
a?? match 1 or 0 times, not greedily
a*? match 0 or more times, not greedily
a+? match 1 or more times, not greedily
a{n} match exactly n times
a{n,m} match at least n but not more than m times, greedily
a{n,} match at least n times, greedily
a{n}? match exactly n times, not greedily (redundant)
a{n,m}? match at least n but not more than m times, not greedily
a{n,}? match at least n times, not greedily
The following escaping sequences are supported:
\t tab
\n newline
\r return
\f form feed
\a alarm
\e escape
\b backspace (in character class only)
\x{}, \x00 character whose ordinal is the given hexadecimal number
\o{}, \000 character whose ordinal is the given octal number
Escaping a regex meta character yields the literal character itself, like \{
and \.
.
Only the octet mode is supported; no multi-byte character encoding love (yet).
This library provides a pure C API. This API is still in flux and may change in the near future without notice.
This library provides the following public constants for use in the various API functions.
SRE_OK
SRE_DECLINED
SRE_AGAIN
SRE_ERROR
The actual meanings of these constants depend on the concrete API functions using them.
This library utilizes a memory pool to simplify memory management. Most of the low-level API functions provided by this library does accept a memory pool pointer as an argument.
The operations on the memory pool on the user side are limited to
- creating a memory pool,
- destroying a memory pool, and
- resetting a memory pool.
sre_pool_t *sre_create_pool(size_t size);
Creates a memory pool with a page size of size
. Returns the pool as an opaque pointer type sre_pool_t
.
Usually the page size you specify should not be too large. Usually 1KB or 4KB should be sufficient. Optimal values depend on your actual regexes and input data pattern involved and should be tuned empirically.
The returned memory pool pointer is usually fed into other API functions provided by this library as an argument.
It is your responsibility to destroy the pool when you no longer need it via the sre_destroy_pool function. Failing to destroy the pool will result in memory leaks.
void sre_destroy_pool(sre_pool_t *pool);
Destroys the memory pool created by the sre_create_pool function.
void sre_reset_pool(sre_pool_t *pool);
Before running a regex (or set of multiple regexes), you need to parse and compile them first, such that you can run the compiled form of the regex(es) over and over again at maximum speed.
typedef uint8_t sre_char;
typedef uintptr_t sre_uint_t;
typedef intptr_t sre_int_t;
sre_regex_t *sre_regex_parse(sre_pool_t *pool, sre_char *regex,
sre_uint_t *ncaps, int flags, sre_int_t *err_offset);
Parses the string representation of the user regex specified by the regex
parameter (as a null-terminated string).
Returns a parsed regex object of the opaque pointer type sre_regex_t
if no error happens. Otherwise returns a NULL pointer and set the offset in the regex
string where the parse failure happens.
The parsed regex object pointer is an Abstract-Syntax-Tree (AST) representation of the string regex. It can later be fed into API function calls like sre_regex_compile as an argument.
The first parameter, pool
, is a memory pool created by the sre_create_pool API function.
The ncaps
parameter is used to output the number of sub-match captures found in the regex. This integer can later be used to extract sub-match captures.
The flags
parameter specifies additional regex compiling flags like below:
SRE_REGEX_CASELESS
case-insensitive matching mode.
typedef uint8_t sre_char;
typedef uintptr_t sre_uint_t;
typedef intptr_t sre_int_t;
sre_regex_t *sre_regex_parse_multi(sre_pool_t *pool, sre_char **regexes,
sre_int_t nregexes, sre_uint_t *max_ncaps, int *multi_flags,
sre_int_t *err_offset, sre_int_t *err_regex_id);
Similar to the sre_regex_parse API function but works on multiple regexes at once.
These regexes are specified by the C string array regexes
, whose size is determined by the nregexes
parameter.
All these input regexes are combined into a single parsed regex object, returned as the opaque
pointer of the type sre_regex_t
, just like sre_regex_parse. These regexes are
logically connected via the alternative regex operator (|
), so the order of these regexes determine
their relative precedence in a tie. Despite of being connected by |
logically, the
regex execution API can still signify which of these regexes is matched
by returning the regex ID which is the offset of the regex in the regexes
input array.
Upon failures, returns the NULL pointer and sets
- the output parameter
err_regex_id
for the number of regex having syntax errors (i.e., the 0-based offset of the regex in theregexes
input parameter array), and - the output parameter
err_offset
for the string offset in the guilty regex where the failure happens.
The output parameter max_ncaps
returns the maximum number of sub-match captures in all these regexes.
Note that, this is is the maximum instead of the sum.
The multi_flags
is an input array consisting of the regex flags for every regex specified in the regexes
array.
The size of this array must be no shorter than the size specified by nregexes
. For what
regex flags you can use, just check out the documentation for the sre_regex_parse API function.
sre_program_t *sre_regex_compile(sre_pool_t *pool, sre_regex_t *re);
Compiles the parsed regex object (returned by sre_regex_parse) into a bytecode
representation of the regex, of the opaque pointer type sre_program_t
.
Returns the NULL pointer in case of failures.
The memory pool specified by the pool
parameter does not have to be the same as the one used
by the earlier sre_regex_parse call. But you could use the same memory pool if you want.
The compiled regex form (or bytecode form) returned can be fed into one of the regex backend VMs provided by this library for execution. See regex execution API for more details.
The regex execution API provides various different virtual machines (VMs) for running the compiled regexes by different algorithms.
Currently the following VMs are supported:
The Thompson VM uses the Thompson NFA simulation algorithm to execute the compiled regex(es) by matching against an input string (or input stream).
sre_vm_thompson_ctx_t *sre_vm_thompson_create_ctx(sre_pool_t *pool,
sre_program_t *prog);
Creates and returns a context structure (of the opaque type sre_vm_thompson_ctx_t
) for
the Thompson VM. Returns NULL in case of failure (like running out of memory).
This return value can later be used by the sre_vm_thompson_exec function as an argument.
The prog
parameter accepts the compiled bytecode form of the regex(es) returned by the sre_regex_compile
function. This compiled regex(es) is embedded into the resulting context structure.
Accepts a memory pool created by the sre_create_pool function as the first argument. This memory pool does not have to be the same as the pool used for parsing or compiling the regex(es).
typedef intptr_t sre_int_t;
typedef uint8_t sre_char;
sre_int_t sre_vm_thompson_exec(sre_vm_thompson_ctx_t *ctx, sre_char *input,
size_t size, unsigned int eof);
Executes the compiled regex(es) on the input string data atop the Thompson VM (without Just-In-Time optimizations).
The ctx
argument value is returned by the sre_vm_thompson_create_ctx
function. The compiled (bytecode) form of the regex(es) are already embedded in this ctx
value.
This ctx
argument can be changed by this function call and must be preserved for all the sre_vm_thompson_exec
calls
on the same data stream. Different data streams MUST use different ctx
instances. When a data stream is completely processed, the corresponding ctx
instance MUST be discarded and cannot be reused again.
The input data is specified by a character data chunk in a data stream. The input
parameter specifies the starting address of the data
chunk, the size
parameter specifies the size of the chunk, while the eof
parameter identifies
whether this chunk is the last chunk in the stream. If you just want to match on a single
C string, then always specify 1 as the eof
argument and exclude the NULL string terminator in your C string while computing the size
argument value.
This function may return one of the following values:
SRE_OK
A match is found.SRE_DECLINED
No match can be found. This value can never be returned when theeof
parameter is unset (because a match MAY get found when seeing more input string data).SRE_AGAIN
More data (in a subsequent call) is needed to obtain a match. The current data chunk can be discarded after this call returns. This value can only be returned when theeof
parameter is not set.SRE_ERROR
A fatal error has occurred (like running out of memory).
This function does not return the regex ID of the matched regex when multiple regexes are specified at once via the sre_regex_parse_multi function is used. This may change in the future.
Sub-match captures are not supported in this Thompson VM by design. You should use the Pike VM instead if you want that.
The Thompson VM comes with a Just-In-Time compiler. Currently only the x86_64 architecture is supported. Support for other architectures may come in the future.
typedef intptr_t sre_int_t;
sre_int_t sre_vm_thompson_jit_compile(sre_pool_t *pool, sre_program_t *prog,
sre_vm_thompson_code_t **pcode);
Compiles the bytecode form of the regex(es) created by sre_regex_compile down into native code.
It returns one of the following values:
SRE_OK
Compilation is successful.SRE_DECLINED
The current architecture is not supported.SRE_ERROR
A fatal error occurs (like running out of memory).
The pool
parameter specifies a memory pool created by sre_create_pool.
This pool is used for the JIT compilation.
The prog
parameter is the compiled bytecode form of the regex(es) created by the sre_regex_compile
function call.
The resulting JIT compiled native code along with the runtime information is saved in the output
argument pcode
of the opaque type sre_vm_thompson_code_t
. This structure is allocated by this
function in the provided memory pool.
This sre_vm_thompson_code_t
object can later be executed by running the C function pointer
fetched from this object via the sre_vm_thompson_jit_get_handler call.
typedef uint8_t sre_char;
typedef intptr_t sre_int_t;
typedef sre_int_t (*sre_vm_thompson_exec_pt)(sre_vm_thompson_ctx_t *ctx,
sre_char *input, size_t size, unsigned int eof);
sre_vm_thompson_exec_pt sre_vm_thompson_jit_get_handler(
sre_vm_thompson_code_t *code);
Fetches a C function pointer from the JIT compiled form of the regex(es) generated via an earlier sre_vm_thompson_jit_compile.
The C function pointer is of the exactly same function prototype of the interpreter entry
function sre_vm_thompson_exec. The only difference is that the
sre_vm_thompson_ctx_t
object MUST be created via the sre_vm_thompson_jit_create_ctx
function instead of the sre_vm_thompson_create_ctx function. Despite that, the resulting C function pointer can be used as the same way as sre_vm_thompson_exec.
sre_vm_thompson_ctx_t *sre_vm_thompson_jit_create_ctx(sre_pool_t *pool,
sre_program_t *prog);
Allocates a context structure for executing the compiled native code form of the regex(s) generated by the Just-In-Time compiler of the Thompson VM.
This context object should only be used by the C function returned by the sre_vm_thompson_jit_get_handler function call. Use of this object in sre_vm_thompson_exec is prohibited.
The Pike VM uses an enhanced version of the Thompson NFA simulation algorithm that supports sub-match captures.
typedef intptr_t sre_int_t;
sre_vm_pike_ctx_t *sre_vm_pike_create_ctx(sre_pool_t *pool, sre_program_t *prog,
sre_int_t *ovector, size_t ovecsize);
Creates and returns a context structure (of the opaque type sre_vm_pike_ctx_t
) for the
Pike VM. Returns NULL in case of failure (like running out of memory).
This return value can later be used by the sre_vm_pike_exec function as an argument.
The prog
parameter accepts the compiled bytecode form of the regex(es) returned by the sre_regex_compile
function. This compiled regex(es) is embedded into the resulting context structure.
Accepts a memory pool created by the sre_create_pool function as the first argument. This memory pool does not have to be the same as the pool used for parsing or compiling the regex(es).
The ovector
parameter specifies an array for outputting the beginning and end offsets of the (sub-)match captures.
The elements of the array are used like below:
- The 1st element of the array holds the beginning offset of the whole match,
- the 2nd element holds the end offset of the whole match,
- the 3rd element holds the beginning offset of the 1st sub-match capture,
- the 4th element holds the end offset of the 1st sub-match capture,
- the 5rd element holds the beginning offset of the 2st sub-match capture,
- the 6th element holds the end offset of the 2st sub-match capture,
- and so on...
The size of the ovector
array is specified by the ovecsize
parameter, in bytes. The size of the array
can be computed as follows:
ovecsize = 2 * (ncaps + 1) * sizeof(sre_int_t)
where ncaps
is the value previously output by the sre_regex_parse
or sre_regex_parse_multi function.
The ovector
array is allocated by the caller and filled by this function call.
typedef uint8_t sre_char;
typedef intptr_t sre_int_t;
sre_int_t sre_vm_pike_exec(sre_vm_pike_ctx_t *ctx, sre_char *input, size_t size,
unsigned eof, sre_int_t **pending_matched);
Executes the compiled regex(es) on the input string data atop the Pike VM (without Just-In-Time optimizations).
The ctx
argument value is returned by the sre_vm_pike_create_ctx
function. The compiled (bytecode) form of the regex(es) are already embedded in this ctx
value.
This ctx
argument can be changed by this function call and must be preserved for all the sre_vm_pike_exec
calls
on the same data stream. Different data streams MUST use different ctx
instances. When a data stream is completely processed, the corresponding ctx
instance MUST be discarded and cannot be reused again.
The input data is specified by a character data chunk in a data stream. The input
parameter specifies the starting address of the data
chunk, the size
parameter specifies the size of the chunk, while the eof
parameter identifies
whether this chunk is the last chunk in the stream. If you just want to match on a single
C string, then always specify 1 as the eof
argument and exclude the NULL string terminator in your C string while computing the size
argument value.
The pending_matched
parameter outputs an array holding all the pending matched captures (whole-match only, no sub-matches) if
no complete matches have been found yet (i.e., this call returns SRE_AGAIN
).
This is very useful for doing regex substitutions on (large) data streams where the caller
can use the info in pending_matched
to decide exactly how much data in the current to-be-thrown data chunk needs to be buffered.
The caller should never allocate the space for this array, rather,
this function call takes care of it and just sets the (double) pointer to point to its internal (read-only) storage.
This function may return one of the following values:
- a non-negative value A match is found and the value is the ID of the (first) matched regex if multiple regexes are parsed at once via the sre_regex_parse_multi function. A regex ID is the 0-based index of the corresponding regex in the regexes array fed into the sre_regex_parse_multi function.
SRE_DECLINED
No match can be found. This value can never be returned when theeof
parameter is unset (because a match MAY get found when seeing more input string data).SRE_AGAIN
More data (in a subsequent call) is needed to obtain a match. The current data chunk can be discarded after this call returns. This value can only be returned when theeof
parameter is not set.SRE_ERROR
A fatal error has occurred (like running out of memory).
Please check out the sregex-cli command-line utility's source for usage:
https://github.com/agentzh/sregex/blob/master/src/sre_cli.c#L1
The sregex-cli
command-line interface can be used as a convenient way to exercise the engine:
./sregex-cli 'a|ab' 'blab'
It also supports the --flags
option which can be used to enable case-insensitive matching:
./sregex-cli --flags i 'A|AB' 'blab'
And also the --stdin
option for reading data chunks from stdin:
# one single data chunk to be matched:
perl -e '$s="foobar";print length($s),"\n$s"' \
| ./sregex-cli --stdin foo
# 3 data chunks (forming a single input stream) to be matched:
perl -e '$s="foobar";print length($s),"\n$s" for 1..3' \
| sregex-cli --stdin foo
A real-world application of this library is the ngx_replace_filter module:
https://github.com/agentzh/replace-filter-nginx-module
make
make install
Gnu make and gcc are required. (On operating systems like FreeBSD and Solaris, you should type gmake
instead of make
here.)
It will build libsregex.so
(or libsregex.dylib
on Mac OS X), libsregex.a
, and the command-line utility sregex-cli
and install
them into the prefix /usr/local/
by default.
If you want to install into a custom location, then just specify the PREFIX
variable like this:
make PREFIX=/opt/sregex
make install PREFIX=/opt/sregex
If you are building a binary package (like an RPM package), then
you will find the DESTDIR
variable handy, as in
make PREFIX=/opt/sregex
make install PREFIX=/opt/sregex DESTDIR=/path/to/my/build/root
If you run make distclean
before make
, then you also need bison 2.7+
for generating the regex parser files.
The test suite is driven by Perl 5.
To run the test suite
make test
Gnu make, perl 5.16.2, and the following Perl CPAN modules are required:
- Cwd
- IPC::Run3
- Test::Base
- Test::LongString
If you already have perl
installed in your system, you can use the following
command to install these CPAN modules (you may need to run it using root
):
cpan Cwd IPC::Run3 Test::Base Test::LongString
You can also run the test suite using the Valgrind Memcheck tool to check memory issues in sregex:
make valtest
Because we have a huge test suite, to run the test suite in parallel, you can specify
the parallelism level with the jobs
make
variable, as in
make test jobs=8
or similarly
make valtest jobs=8
So the test suite will run in 8 parallel jobs (assuming you have 8 CPU cores).
The streaming matching API is much more thoroughly excerised by the test suite of the ngx_replace_filter module.
- implement the
(?i)
and(?-i)
regex syntax. - implement a simplified version of the backreferences.
- implement the comment notation
(?#comment)
. - implement the POSIX character class notation.
- allow '\0' be used in both the regex and the subject string.
- add a bytecode optimizer to the regex VM (which also generates minimized DFAs for the Thompson VM).
- add a JIT compiler for the Pike VM targeting x86_64.
- port the existing x86_64 JIT compiler for the Thompson VM to other architectures like i386.
- implement the generalized look-around assertions like
(?=pattern)
,(?!pattern)
,(?<=pattern)
, and(?<!pattern)
. - implement the UTF-8, GBK, and Latin1 matching mode.
Yichun "agentzh" Zhang (章亦春) [email protected], OpenResty Inc.
Part of this code is from the NGINX open source project: http://nginx.org/LICENSE
This library is licensed under the BSD license.
Copyright (C) 2012-2017, by Yichun "agentzh" Zhang (章亦春), OpenResty Inc.
Copyright (C) 2007-2009 Russ Cox, Google Inc. All rights reserved.
All rights reserved.
Redistribution and use in source and binary forms, with or without modification, are permitted provided that the following conditions are met:
-
Redistributions of source code must retain the above copyright notice, this list of conditions and the following disclaimer.
-
Redistributions in binary form must reproduce the above copyright notice, this list of conditions and the following disclaimer in the documentation and/or other materials provided with the distribution.
-
Neither the name of Google, Inc. nor the names of its contributors may be used to endorse or promote products derived from this software without specific prior written permission.
THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT HOLDER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
- Slides for my talk "sregex: matching Perl 5 regexes on data streams": http://agentzh.org/misc/slides/yapc-na-2013-sregex.pdf
- The ngx_replace_filter module: https://github.com/agentzh/replace-filter-nginx-module
- "Implementing Regular Expressions" http://swtch.com/~rsc/regexp/
- The re1 project: http://code.google.com/p/re1/
- The re2 project: http://code.google.com/p/re2/