Difference between revisions of "Lttoolbox API"
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[[Application lttoolbox|En français]] |
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{{TOCD}} |
{{TOCD}} |
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You can use [[lttoolbox]] as a library in C++ by with <code>#include <lttoolbox/fst_processor.h></code>, and with a bit more work, you can also use it from Python. |
You can use [[lttoolbox]] as a library in C++ by with <code>#include <lttoolbox/fst_processor.h></code>, and with a bit more work, you can also use it from Python. |
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#include <lttoolbox/fst_processor.h> |
#include <lttoolbox/fst_processor.h> |
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#include <lttoolbox/lt_locale.h> |
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#include <lttoolbox/ltstr.h> |
#include <lttoolbox/ltstr.h> |
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} |
} |
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LtLocale::tryToSetLocale(); |
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FILE *t_rl = fopen(argv[1], "r"); |
FILE *t_rl = fopen(argv[1], "r"); |
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==Using as a module from Python== |
==Using as a module from Python== |
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This example is based on how [[libvoikko]] uses lttoolbox for analysis. We make a C++ library that exposes whatever lttoolbox functions we need to Python, and a little Python class that makes calling those functions a bit more pythonic.<ref>An alternative might be to include Python.h in the C++ code, and define a full Python class from there, like how [https://launchpad.net/pylibtextcat pylibtextcat]/[https://github.com/bbqsrc/pylibtextcat py3libtextcat] creates a Python class for a C library.</ref> |
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(This example is based on how [[libvoikko]] uses lttoolbox for analysis) |
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Write the following files: |
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libltpy.hpp: |
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ltpy.h: |
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<pre> |
<pre> |
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#include <lttoolbox/fst_processor.h> |
#include <lttoolbox/fst_processor.h> |
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</pre> |
</pre> |
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libltpy.cpp: |
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ltpy.cc: |
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<pre> |
<pre> |
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#include " |
#include "libltpy.hpp" |
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#include <lttoolbox/fst_processor.h> |
#include <lttoolbox/fst_processor.h> |
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#include <lttoolbox/lt_locale.h> |
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using namespace std; |
using namespace std; |
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Analyser::Analyser(const string & analyserpath) throw(exception) { |
Analyser::Analyser(const string & analyserpath) throw(exception) { |
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cerr << "analyser: " << analyserpath << endl; |
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FILE * file = fopen(analyserpath.c_str(), "r"); |
FILE * file = fopen(analyserpath.c_str(), "r"); |
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if (!file) { |
if (!file) { |
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cerr << "Couldn't open analyser file " << analyserpath << endl; |
cerr << "Couldn't open analyser file " << analyserpath << endl; |
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//throw LoadException("Couldn't open analyser file"); |
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throw exception(); |
throw exception(); |
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} |
} |
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wstring Analyser::analyse(wstring const &word) { |
wstring Analyser::analyse(wstring const &word) { |
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pair <wstring,int> analysis = fst.biltransWithQueue(word, false); |
pair <wstring,int> analysis = fst.biltransWithQueue(word, false); |
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⚫ | |||
// or fst.biltrans, which just returns the string. The 'false' |
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⚫ | |||
if (analysis.second == 0) { |
if (analysis.second == 0) { |
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return analysis.first; |
return analysis.first; |
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else { |
else { |
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// a partial match: |
// a partial match: |
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return L"@"+ |
return L"@"+word; |
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} |
} |
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} |
} |
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extern "C" wstring * analyse(Analyser * a, const wchar_t * word) { |
extern "C" wstring * analyse(Analyser * a, const wchar_t * word) { |
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// |
// It seems Python can only send wchar_t*, but we need a wstring |
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size_t wlen = wcslen(word); |
size_t wlen = wcslen(word); |
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if (wlen == 0) { |
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// avoid a bug in biltransWithQueue: |
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return 0; |
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} |
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wstring inputString = L""; |
wstring inputString = L""; |
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for (size_t i = 0; i < wlen; i++) { |
for (size_t i = 0; i < wlen; i++) { |
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wstring * out = new wstring(a->analyse(inputString)); |
wstring * out = new wstring(a->analyse(inputString)); |
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return out; |
return out; |
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} |
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extern "C" void free_analyses(wstring * analyses) { |
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delete analyses; |
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} |
} |
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extern "C" Analyser * init(const char ** error, const char * path) { |
extern "C" Analyser * init(const char ** error, const char * path) { |
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LtLocale::tryToSetLocale(); |
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Analyser * a = 0; |
Analyser * a = 0; |
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try { |
try { |
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if error.value != None: |
if error.value != None: |
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self.__handle = 0 |
self.__handle = 0 |
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raise Exception(u" |
raise Exception(u"Initialisation of fst failed: " + unicode(error.value, "UTF-8")) |
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def __del__(self): |
def __del__(self): |
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def analyse(self, word): |
def analyse(self, word): |
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ana_p = self.__lib.analyse(self.__handle, word) |
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if ana_p: |
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analysis = ana_p.contents.value |
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else: |
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analysis = "" |
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self.__lib.free_analyses(ana_p) |
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return analysis |
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</pre> |
</pre> |
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Compile the C++ files so you get a file like |
Compile the C++ files so you get a file like libltpy.so. The following commands worked for me: |
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<pre> |
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g++ -DGCC_VISIBILITY=1 -g -O2 -fvisibility=hidden -I/usr/local/include/lttoolbox-3.2 -I/usr/local/lib/lttoolbox-3.2/include -c libltpy.cpp -fPIC -DPIC -o libltpy.o |
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g++ -fPIC -DPIC -shared libltpy.o -Wl,-rpath -Wl,/usr/local/lib -Wl,-rpath -Wl,/usr/local/lib -L/usr/local/lib /usr/local/lib/liblttoolbox3.so -Wl,-soname -Wl,libltpy.so.0 -o libltpy.so |
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</pre> |
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However, if you use autotools, you typically just need the following in your Makefile.am: |
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<pre> |
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lib_LTLIBRARIES = libltpy.la |
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libltpy_la_SOURCES = libltpy.cpp |
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libltpy_la_LDFLAGS = $(LTTOOLBOX_LIBS) |
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</pre> |
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then <code>autogen.sh</code> and <code>make libltpy.la</code> (see [[#Real-world examples]]). |
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Then use it like: |
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<pre> |
<pre> |
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import lt |
import lt |
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fst = lt.FST(" |
fst = lt.FST("libltpy.so", "analyser.bin") |
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print fst.analyse(u"cars") # should print car<n><pl> |
print fst.analyse(u"cars") # should print car<n><pl> |
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</pre> |
</pre> |
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==Real-world examples |
==Real-world examples== |
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* apertium-transfer uses lttoolbox from C++ to look up words in the bidix |
* apertium-transfer uses lttoolbox from C++ to look up words in the bidix |
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** http://sourceforge.net/apps/trac/voikko/browser/trunk/libvoikko/python/libvoikko.py |
** http://sourceforge.net/apps/trac/voikko/browser/trunk/libvoikko/python/libvoikko.py |
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==Footnotes== |
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<references/> |
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[[Category:lttoolbox]] |
[[Category:lttoolbox]] |
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[[Category:Morphological analysers]] |
[[Category:Morphological analysers]] |
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[[Category:Development]] |
[[Category:Development]] |
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[[Category:Documentation in English]] |
Latest revision as of 13:19, 10 March 2017
You can use lttoolbox as a library in C++ by with #include <lttoolbox/fst_processor.h>
, and with a bit more work, you can also use it from Python.
Using as a library in C++[edit]
For this example you will need two files, test.dix
:
<dictionary> <alphabet/> <sdefs> <sdef n="n"/> <sdef n="pl"/> </sdefs> <section id="main" type="standard"> <e><p><l>cars</l><r>car<s n="n"/><s n="pl"/></r></p></e> </section> </dictionary>
And test.cc
:
#include <stdio.h> #include <string> #include <iostream> #include <lttoolbox/fst_processor.h> #include <lttoolbox/lt_locale.h> #include <lttoolbox/ltstr.h> using namespace std; FSTProcessor fstp; int main(int argc, char **argv) { if(argc < 2) { wcout << L"Please specify a transducer" << endl; exit(-1); } LtLocale::tryToSetLocale(); FILE *t_rl = fopen(argv[1], "r"); fstp.load(t_rl); fclose(t_rl); fstp.initBiltrans(); wstring input = L"^car<n><pl>$"; wstring trad = fstp.biltrans(input); wcout << input << L" --> " << trad << endl; return 0; }
Compile both of the files:
$ lt-comp rl test.dix test_rl.bin main@standard 6 5 $ g++ -Wall test.cc -o test -llttoolbox3
And then test:
$ ./test test_rl.bin ^car<n><pl>$ --> ^cars$
Using as a module from Python[edit]
This example is based on how libvoikko uses lttoolbox for analysis. We make a C++ library that exposes whatever lttoolbox functions we need to Python, and a little Python class that makes calling those functions a bit more pythonic.[1]
Write the following files:
libltpy.hpp:
#include <lttoolbox/fst_processor.h> class Analyser { public: Analyser(const std::string & directoryName) throw(exception); wstring analyse(wstring const &word); private: FSTProcessor fst; };
libltpy.cpp:
#include "libltpy.hpp" #include <lttoolbox/fst_processor.h> #include <lttoolbox/lt_locale.h> using namespace std; Analyser::Analyser(const string & analyserpath) throw(exception) { FILE * file = fopen(analyserpath.c_str(), "r"); if (!file) { cerr << "Couldn't open analyser file " << analyserpath << endl; throw exception(); } fst.load(file); fclose(file); fst.setCaseSensitiveMode(false); fst.setDictionaryCaseMode(true); fst.initBiltrans(); } wstring Analyser::analyse(wstring const &word) { pair <wstring,int> analysis = fst.biltransWithQueue(word, false); // The 'false' means we require no ^ or $ in input/output if (analysis.second == 0) { return analysis.first; } else { // a partial match: return L"@"+word; } } extern "C" wstring * analyse(Analyser * a, const wchar_t * word) { // It seems Python can only send wchar_t*, but we need a wstring size_t wlen = wcslen(word); if (wlen == 0) { // avoid a bug in biltransWithQueue: return 0; } wstring inputString = L""; for (size_t i = 0; i < wlen; i++) { inputString.append(1, word[i]); } wstring * out = new wstring(a->analyse(inputString)); return out; } extern "C" void free_analyses(wstring * analyses) { delete analyses; } extern "C" Analyser * init(const char ** error, const char * path) { LtLocale::tryToSetLocale(); Analyser * a = 0; try { a = new Analyser(path); } catch (exception & e) { delete a; a = 0; *error = e.what(); return 0; } *error = 0; return a; } extern "C" void terminate(Analyser * a) { delete a; }
lt.py:
# -*- coding: utf-8 -*- from ctypes import byref, CDLL, c_char_p, c_wchar_p, c_void_p, POINTER class FST(object): def __init__(self, libpath, fstpath): self.__lib = CDLL(libpath) self.__lib.init.argtypes = [POINTER(c_char_p), c_char_p] self.__lib.init.restype = c_void_p self.__lib.terminate.argtypes = [c_void_p] self.__lib.terminate.restype = None self.__lib.analyse.argtypes = [c_void_p, c_wchar_p] self.__lib.analyse.restype = POINTER(c_wchar_p) error = c_char_p() self.__handle = self.__lib.init(byref(error), fstpath) if error.value != None: self.__handle = 0 raise Exception(u"Initialisation of fst failed: " + unicode(error.value, "UTF-8")) def __del__(self): if (self.__handle != 0): self.__handle = 0 class DummyLib: def __getattr__(obj, name): raise Exception("Attempt to use library after terminate() was called") self.__lib = DummyLib() def analyse(self, word): ana_p = self.__lib.analyse(self.__handle, word) if ana_p: analysis = ana_p.contents.value else: analysis = "" self.__lib.free_analyses(ana_p) return analysis
Compile the C++ files so you get a file like libltpy.so. The following commands worked for me:
g++ -DGCC_VISIBILITY=1 -g -O2 -fvisibility=hidden -I/usr/local/include/lttoolbox-3.2 -I/usr/local/lib/lttoolbox-3.2/include -c libltpy.cpp -fPIC -DPIC -o libltpy.o g++ -fPIC -DPIC -shared libltpy.o -Wl,-rpath -Wl,/usr/local/lib -Wl,-rpath -Wl,/usr/local/lib -L/usr/local/lib /usr/local/lib/liblttoolbox3.so -Wl,-soname -Wl,libltpy.so.0 -o libltpy.so
However, if you use autotools, you typically just need the following in your Makefile.am:
lib_LTLIBRARIES = libltpy.la libltpy_la_SOURCES = libltpy.cpp libltpy_la_LDFLAGS = $(LTTOOLBOX_LIBS)
then autogen.sh
and make libltpy.la
(see #Real-world examples).
Then use it like:
import lt fst = lt.FST("libltpy.so", "analyser.bin") print fst.analyse(u"cars") # should print car<n><pl>
Real-world examples[edit]
- apertium-transfer uses lttoolbox from C++ to look up words in the bidix
- libvoikko uses lttoolbox from C++ to analyse words, and also makes a Python module:
Footnotes[edit]
- ↑ An alternative might be to include Python.h in the C++ code, and define a full Python class from there, like how pylibtextcat/py3libtextcat creates a Python class for a C library.