lyx_mirror/src/support/unicode.cpp
Peter Kümmel b5216b25f7 update other build systems, use lyx::Mutex
git-svn-id: svn://svn.lyx.org/lyx/lyx-devel/trunk@37223 a592a061-630c-0410-9148-cb99ea01b6c8
2011-01-15 21:40:09 +00:00

402 lines
9.8 KiB
C++

/**
* \file unicode.cpp
* This file is part of LyX, the document processor.
* Licence details can be found in the file COPYING.
*
* \author Lars Gullik Bjønnes
*
* Full author contact details are available in file CREDITS.
*
* A collection of unicode conversion functions, using iconv.
*/
#include <config.h>
#include "support/unicode.h"
#include "support/debug.h"
#include "support/mutex.h"
#include <iconv.h>
#include <boost/cstdint.hpp>
#include <cerrno>
#include <iomanip>
#include <map>
#include <ostream>
#include <string>
using namespace std;
namespace {
#ifdef WORDS_BIGENDIAN
char const * utf16_codeset = "UTF16-BE";
#else
char const * utf16_codeset = "UTF16-LE";
#endif
}
namespace lyx {
#ifdef WORDS_BIGENDIAN
char const * ucs4_codeset = "UCS-4BE";
#else
char const * ucs4_codeset = "UCS-4LE";
#endif
static const iconv_t invalid_cd = (iconv_t)(-1);
struct IconvProcessor::Impl
{
Impl(string const & to, string const & from)
: cd(invalid_cd), tocode_(to), fromcode_(from)
{}
~Impl()
{
if (cd != invalid_cd && iconv_close(cd) == -1)
LYXERR0("Error returned from iconv_close(" << errno << ")");
}
iconv_t cd;
string tocode_;
string fromcode_;
Mutex mutex_; // iconv() is not thread save, see #7240
};
IconvProcessor::IconvProcessor(char const * tocode, char const * fromcode)
: pimpl_(new IconvProcessor::Impl(tocode, fromcode))
{
}
IconvProcessor::IconvProcessor(IconvProcessor const & other)
: pimpl_(new IconvProcessor::Impl(other.pimpl_->tocode_, other.pimpl_->fromcode_))
{
}
IconvProcessor::~IconvProcessor()
{
delete pimpl_;
}
void IconvProcessor::operator=(IconvProcessor const & other)
{
if (&other != this)
pimpl_ = new Impl(other.pimpl_->tocode_, other.pimpl_->fromcode_);
}
bool IconvProcessor::init()
{
if (pimpl_->cd != invalid_cd)
return true;
pimpl_->cd = iconv_open(pimpl_->tocode_.c_str(), pimpl_->fromcode_.c_str());
if (pimpl_->cd != invalid_cd)
return true;
lyxerr << "Error returned from iconv_open" << endl;
switch (errno) {
case EINVAL:
lyxerr << "EINVAL The conversion from " << pimpl_->fromcode_
<< " to " << pimpl_->tocode_
<< " is not supported by the implementation."
<< endl;
break;
default:
lyxerr << "\tSome other error: " << errno << endl;
break;
}
return false;
}
int IconvProcessor::convert(char const * buf, size_t buflen,
char * outbuf, size_t maxoutsize)
{
Mutex::Locker lock(&pimpl_->mutex_);
if (buflen == 0)
return 0;
if (pimpl_->cd == invalid_cd) {
if (!init())
return -1;
}
char ICONV_CONST * inbuf = const_cast<char ICONV_CONST *>(buf);
size_t inbytesleft = buflen;
size_t outbytesleft = maxoutsize;
int res = iconv(pimpl_->cd, &inbuf, &inbytesleft, &outbuf, &outbytesleft);
// flush out remaining data. This is needed because iconv sometimes
// holds back chars in the stream, waiting for a combination character
// (see e.g. http://sources.redhat.com/bugzilla/show_bug.cgi?id=1124)
iconv(pimpl_->cd, NULL, NULL, &outbuf, &outbytesleft);
//lyxerr << dec;
//lyxerr << "Inbytesleft: " << inbytesleft << endl;
//lyxerr << "Outbytesleft: " << outbytesleft << endl;
if (res != -1)
// Everything went well.
return maxoutsize - outbytesleft;
// There are some errors in the conversion
lyxerr << "Error returned from iconv" << endl;
switch (errno) {
case E2BIG:
lyxerr << "E2BIG There is not sufficient room at *outbuf." << endl;
break;
case EILSEQ:
lyxerr << "EILSEQ An invalid multibyte sequence"
<< " has been encountered in the input.\n"
<< "When converting from " << pimpl_->fromcode_
<< " to " << pimpl_->tocode_ << ".\n";
lyxerr << "Input:" << hex;
for (size_t i = 0; i < buflen; ++i) {
// char may be signed, avoid output of
// something like 0xffffffc2
boost::uint32_t const b =
*reinterpret_cast<unsigned char const *>(buf + i);
lyxerr << " 0x" << (unsigned int)b;
}
lyxerr << dec << endl;
break;
case EINVAL:
lyxerr << "EINVAL An incomplete multibyte sequence"
<< " has been encountered in the input.\n"
<< "When converting from " << pimpl_->fromcode_
<< " to " << pimpl_->tocode_ << ".\n";
lyxerr << "Input:" << hex;
for (size_t i = 0; i < buflen; ++i) {
// char may be signed, avoid output of
// something like 0xffffffc2
boost::uint32_t const b =
*reinterpret_cast<unsigned char const *>(buf + i);
lyxerr << " 0x" << (unsigned int)b;
}
lyxerr << dec << endl;
break;
default:
lyxerr << "\tSome other error: " << errno << endl;
break;
}
// We got an error so we close down the conversion engine
if (iconv_close(pimpl_->cd) == -1) {
lyxerr << "Error returned from iconv_close("
<< errno << ")" << endl;
}
pimpl_->cd = invalid_cd;
return -1;
}
std::string IconvProcessor::from() const
{
return pimpl_->fromcode_;
}
std::string IconvProcessor::to() const
{
return pimpl_->tocode_;
}
namespace {
template<typename RetType, typename InType>
vector<RetType>
iconv_convert(IconvProcessor & processor, InType const * buf, size_t buflen)
{
if (buflen == 0)
return vector<RetType>();
char const * inbuf = reinterpret_cast<char const *>(buf);
size_t inbytesleft = buflen * sizeof(InType);
static std::vector<char> outbuf(32768);
// The number of UCS4 code points in buf is at most inbytesleft.
// The output encoding will use at most
// max_encoded_bytes(pimpl_->tocode_) per UCS4 code point.
size_t maxoutbufsize = max_encoded_bytes(processor.to()) * inbytesleft;
if (outbuf.size() < maxoutbufsize)
outbuf.resize(maxoutbufsize);
int bytes = processor.convert(inbuf, inbytesleft, &outbuf[0], outbuf.size());
if (bytes <= 0)
// Conversion failed
// FIXME Maybe throw an exception and handle that in the caller?
return vector<RetType>();
RetType const * tmp = reinterpret_cast<RetType const *>(&outbuf[0]);
return vector<RetType>(tmp, tmp + bytes / sizeof(RetType));
}
} // anon namespace
vector<char_type> utf8_to_ucs4(vector<char> const & utf8str)
{
if (utf8str.empty())
return vector<char_type>();
return utf8_to_ucs4(&utf8str[0], utf8str.size());
}
vector<char_type>
utf8_to_ucs4(char const * utf8str, size_t ls)
{
static IconvProcessor processor(ucs4_codeset, "UTF-8");
return iconv_convert<char_type>(processor, utf8str, ls);
}
vector<char_type>
utf16_to_ucs4(unsigned short const * s, size_t ls)
{
static IconvProcessor processor(ucs4_codeset, utf16_codeset);
return iconv_convert<char_type>(processor, s, ls);
}
vector<unsigned short>
ucs4_to_utf16(char_type const * s, size_t ls)
{
static IconvProcessor processor(utf16_codeset, ucs4_codeset);
return iconv_convert<unsigned short>(processor, s, ls);
}
vector<char>
ucs4_to_utf8(char_type c)
{
static IconvProcessor processor("UTF-8", ucs4_codeset);
return iconv_convert<char>(processor, &c, 1);
}
vector<char>
ucs4_to_utf8(vector<char_type> const & ucs4str)
{
if (ucs4str.empty())
return vector<char>();
return ucs4_to_utf8(&ucs4str[0], ucs4str.size());
}
vector<char>
ucs4_to_utf8(char_type const * ucs4str, size_t ls)
{
static IconvProcessor processor("UTF-8", ucs4_codeset);
return iconv_convert<char>(processor, ucs4str, ls);
}
vector<char_type>
eightbit_to_ucs4(char const * s, size_t ls, string const & encoding)
{
static map<string, IconvProcessor> processors;
if (processors.find(encoding) == processors.end()) {
IconvProcessor processor(ucs4_codeset, encoding.c_str());
processors.insert(make_pair(encoding, processor));
}
return iconv_convert<char_type>(processors[encoding], s, ls);
}
vector<char>
ucs4_to_eightbit(char_type const * ucs4str, size_t ls, string const & encoding)
{
static map<string, IconvProcessor> processors;
if (processors.find(encoding) == processors.end()) {
IconvProcessor processor(encoding.c_str(), ucs4_codeset);
processors.insert(make_pair(encoding, processor));
}
return iconv_convert<char>(processors[encoding], ucs4str, ls);
}
char ucs4_to_eightbit(char_type ucs4, string const & encoding)
{
static map<string, IconvProcessor> processors;
map<string, IconvProcessor>::iterator it = processors.find(encoding);
if (it == processors.end()) {
IconvProcessor processor(encoding.c_str(), ucs4_codeset);
it = processors.insert(make_pair(encoding, processor)).first;
}
char out;
int const bytes = it->second.convert((char *)(&ucs4), 4, &out, 1);
if (bytes > 0)
return out;
return 0;
}
void ucs4_to_multibytes(char_type ucs4, vector<char> & out,
string const & encoding)
{
static map<string, IconvProcessor> processors;
map<string, IconvProcessor>::iterator it = processors.find(encoding);
if (it == processors.end()) {
IconvProcessor processor(encoding.c_str(), ucs4_codeset);
it = processors.insert(make_pair(encoding, processor)).first;
}
out.resize(4);
int bytes = it->second.convert((char *)(&ucs4), 4, &out[0], 4);
if (bytes > 0)
out.resize(bytes);
else
out.clear();
}
int max_encoded_bytes(std::string const & encoding)
{
// FIXME: this information should be transferred to lib/encodings
// UTF8 uses at most 4 bytes to represent one UCS4 code point
// (see RFC 3629). RFC 2279 specifies 6 bytes, but that
// information is outdated, and RFC 2279 has been superseded by
// RFC 3629.
// The CJK encodings use (different) multibyte representation as well.
// All other encodings encode one UCS4 code point in one byte
// (and can therefore only encode a subset of UCS4)
// Note that BIG5 and SJIS do not work with LaTeX (see lib/encodings).
// Furthermore, all encodings that use shifting (like SJIS) do not work with
// iconv_codecvt_facet.
if (encoding == "UTF-8" ||
encoding == "GB" ||
encoding == "EUC-TW")
return 4;
else if (encoding == "EUC-JP")
return 3;
else if (encoding == "ISO-2022-JP")
return 8;
else if (encoding == "BIG5" ||
encoding == "EUC-KR" ||
encoding == "EUC-CN" ||
encoding == "SJIS" ||
encoding == "GBK")
return 2;
else
return 1;
}
} // namespace lyx