gecko-dev/intl/uconv/ucvcn/nsGBKToUnicode.cpp

293 строки
8.9 KiB
C++

/* -*- Mode: C; tab-width: 4; indent-tabs-mode: nil; c-basic-offset: 2 -*- */
/* This Source Code Form is subject to the terms of the Mozilla Public
* License, v. 2.0. If a copy of the MPL was not distributed with this
* file, You can obtain one at http://mozilla.org/MPL/2.0/. */
/**
* A character set converter from GBK to Unicode.
*
*
* @created 07/Sept/1999
* @author Yueheng Xu, Yueheng.Xu@intel.com
*/
#include "nsGBKToUnicode.h"
#include "gbku.h"
//------------------------------------------------------------
// nsGB18030Unique2BytesToUnicode
//------------------------------------------------------------
class nsGB18030Unique2BytesToUnicode : public nsTableDecoderSupport
{
public:
nsGB18030Unique2BytesToUnicode();
virtual ~nsGB18030Unique2BytesToUnicode()
{ }
protected:
};
static const uint16_t g_utGB18030Unique2Bytes[] = {
#include "gb18030uniq2b.ut"
};
nsGB18030Unique2BytesToUnicode::nsGB18030Unique2BytesToUnicode()
: nsTableDecoderSupport(u2BytesCharset, nullptr,
(uMappingTable*) &g_utGB18030Unique2Bytes, 1)
{
}
//------------------------------------------------------------
// nsGB18030Unique4BytesToUnicode
//------------------------------------------------------------
class nsGB18030Unique4BytesToUnicode : public nsTableDecoderSupport
{
public:
nsGB18030Unique4BytesToUnicode();
virtual ~nsGB18030Unique4BytesToUnicode()
{ }
protected:
};
static const uint16_t g_utGB18030Unique4Bytes[] = {
#include "gb180304bytes.ut"
};
nsGB18030Unique4BytesToUnicode::nsGB18030Unique4BytesToUnicode()
: nsTableDecoderSupport(u4BytesGB18030Charset, nullptr,
(uMappingTable*) &g_utGB18030Unique4Bytes, 1)
{
}
//----------------------------------------------------------------------
// Class nsGBKToUnicode [implementation]
//----------------------------------------------------------------------
// Subclassing of nsTablesDecoderSupport class [implementation]
#define LEGAL_GBK_MULTIBYTE_FIRST_BYTE(c) \
(UINT8_IN_RANGE(0x81, (c), 0xFE))
#define FIRST_BYTE_IS_SURROGATE(c) \
(UINT8_IN_RANGE(0x90, (c), 0xFE))
#define LEGAL_GBK_2BYTE_SECOND_BYTE(c) \
(UINT8_IN_RANGE(0x40, (c), 0x7E)|| UINT8_IN_RANGE(0x80, (c), 0xFE))
#define LEGAL_GBK_4BYTE_SECOND_BYTE(c) \
(UINT8_IN_RANGE(0x30, (c), 0x39))
#define LEGAL_GBK_4BYTE_THIRD_BYTE(c) \
(UINT8_IN_RANGE(0x81, (c), 0xFE))
#define LEGAL_GBK_4BYTE_FORTH_BYTE(c) \
(UINT8_IN_RANGE(0x30, (c), 0x39))
NS_IMETHODIMP nsGB18030ToUnicode::ConvertNoBuff(const char* aSrc,
int32_t * aSrcLength,
char16_t *aDest,
int32_t * aDestLength)
{
int32_t i=0;
int32_t iSrcLength = (*aSrcLength);
int32_t iDestlen = 0;
nsresult rv=NS_OK;
*aSrcLength = 0;
for (i=0;i<iSrcLength;i++)
{
if ( iDestlen >= (*aDestLength) )
{
rv = NS_OK_UDEC_MOREOUTPUT;
break;
}
// The valid range for the 1st byte is [0x81,0xFE]
if(LEGAL_GBK_MULTIBYTE_FIRST_BYTE(*aSrc))
{
if(i+1 >= iSrcLength)
{
rv = NS_OK_UDEC_MOREINPUT;
break;
}
// To make sure, the second byte has to be checked as well.
// In GBK, the second byte range is [0x40,0x7E] and [0x80,0XFE]
if(LEGAL_GBK_2BYTE_SECOND_BYTE(aSrc[1]))
{
// Valid GBK code
*aDest = mUtil.GBKCharToUnicode(aSrc[0], aSrc[1]);
if(UCS2_NO_MAPPING == *aDest)
{
// We cannot map in the common mapping, let's call the
// delegate 2 byte decoder to decode the gbk or gb18030 unique
// 2 byte mapping
if(! TryExtensionDecoder(aSrc, aDest))
{
*aDest = UCS2_NO_MAPPING;
}
}
aSrc += 2;
i++;
}
else if (LEGAL_GBK_4BYTE_SECOND_BYTE(aSrc[1]))
{
// from the first 2 bytes, it looks like a 4 byte GB18030
if(i+3 >= iSrcLength) // make sure we got 4 bytes
{
rv = NS_OK_UDEC_MOREINPUT;
break;
}
// 4 bytes patten
// [0x81-0xfe][0x30-0x39][0x81-0xfe][0x30-0x39]
// preset the
if (LEGAL_GBK_4BYTE_THIRD_BYTE(aSrc[2]) &&
LEGAL_GBK_4BYTE_FORTH_BYTE(aSrc[3]))
{
if ( ! FIRST_BYTE_IS_SURROGATE(aSrc[0]))
{
// let's call the delegated 4 byte gb18030 converter to convert it
if(! Try4BytesDecoder(aSrc, aDest))
*aDest = UCS2_NO_MAPPING;
} else {
// let's try supplement mapping
if ( (iDestlen+1) < (*aDestLength) )
{
if(DecodeToSurrogate(aSrc, aDest))
{
// surrogte two char16_t
iDestlen++;
aDest++;
} else {
*aDest = UCS2_NO_MAPPING;
}
} else {
if (*aDestLength < 2) {
NS_ERROR("insufficient space in output buffer");
*aDest = UCS2_NO_MAPPING;
} else {
rv = NS_OK_UDEC_MOREOUTPUT;
break;
}
}
}
aSrc += 4;
i += 3;
} else {
*aDest = UCS2_NO_MAPPING;
// If the third and fourth bytes are not in the legal ranges for
// a four-byte sequnce, resynchronize on the second byte
// (which we know is in the range of LEGAL_GBK_4BYTE_SECOND_BYTE,
// 0x30-0x39)
aSrc++;
}
}
else if ((uint8_t) aSrc[0] == (uint8_t)0xA0 )
{
// stand-alone (not followed by a valid second byte) 0xA0 !
// treat it as valid a la Netscape 4.x
*aDest = CAST_CHAR_TO_UNICHAR(*aSrc);
aSrc++;
} else {
// Invalid GBK code point (second byte should be 0x40 or higher)
*aDest = UCS2_NO_MAPPING;
aSrc++;
}
} else {
if(IS_ASCII(*aSrc))
{
// The source is an ASCII
*aDest = CAST_CHAR_TO_UNICHAR(*aSrc);
aSrc++;
} else {
if(IS_GBK_EURO(*aSrc)) {
*aDest = UCS2_EURO;
} else {
*aDest = UCS2_NO_MAPPING;
}
aSrc++;
}
}
iDestlen++;
aDest++;
*aSrcLength = i+1;
}
*aDestLength = iDestlen;
return rv;
}
void nsGB18030ToUnicode::CreateExtensionDecoder()
{
mExtensionDecoder = new nsGB18030Unique2BytesToUnicode();
}
void nsGB18030ToUnicode::Create4BytesDecoder()
{
m4BytesDecoder = new nsGB18030Unique4BytesToUnicode();
}
bool nsGB18030ToUnicode::DecodeToSurrogate(const char* aSrc, char16_t* aOut)
{
NS_ASSERTION(FIRST_BYTE_IS_SURROGATE(aSrc[0]), "illegal first byte");
NS_ASSERTION(LEGAL_GBK_4BYTE_SECOND_BYTE(aSrc[1]), "illegal second byte");
NS_ASSERTION(LEGAL_GBK_4BYTE_THIRD_BYTE(aSrc[2]), "illegal third byte");
NS_ASSERTION(LEGAL_GBK_4BYTE_FORTH_BYTE(aSrc[3]), "illegal forth byte");
if(! FIRST_BYTE_IS_SURROGATE(aSrc[0]))
return false;
if(! LEGAL_GBK_4BYTE_SECOND_BYTE(aSrc[1]))
return false;
if(! LEGAL_GBK_4BYTE_THIRD_BYTE(aSrc[2]))
return false;
if(! LEGAL_GBK_4BYTE_FORTH_BYTE(aSrc[3]))
return false;
uint8_t a1 = (uint8_t) aSrc[0];
uint8_t a2 = (uint8_t) aSrc[1];
uint8_t a3 = (uint8_t) aSrc[2];
uint8_t a4 = (uint8_t) aSrc[3];
a1 -= (uint8_t)0x90;
a2 -= (uint8_t)0x30;
a3 -= (uint8_t)0x81;
a4 -= (uint8_t)0x30;
uint32_t idx = (((a1 * 10 + a2 ) * 126 + a3) * 10) + a4;
// idx == ucs4Codepoint - 0x10000
if (idx > 0x000FFFFF)
return false;
*aOut++ = 0xD800 | (idx >> 10);
*aOut = 0xDC00 | (0x000003FF & idx);
return true;
}
bool nsGB18030ToUnicode::TryExtensionDecoder(const char* aSrc, char16_t* aOut)
{
if(!mExtensionDecoder)
CreateExtensionDecoder();
NS_ASSERTION(mExtensionDecoder, "cannot creqte 2 bytes unique converter");
if(mExtensionDecoder)
{
nsresult res = mExtensionDecoder->Reset();
NS_ASSERTION(NS_SUCCEEDED(res), "2 bytes unique conversoin reset failed");
int32_t len = 2;
int32_t dstlen = 1;
res = mExtensionDecoder->Convert(aSrc,&len, aOut, &dstlen);
NS_ASSERTION(NS_FAILED(res) || ((len==2) && (dstlen == 1)),
"some strange conversion result");
// if we failed, we then just use the 0xfffd
// therefore, we ignore the res here.
if(NS_SUCCEEDED(res))
return true;
}
return false;
}
bool nsGB18030ToUnicode::Try4BytesDecoder(const char* aSrc, char16_t* aOut)
{
if(!m4BytesDecoder)
Create4BytesDecoder();
if(m4BytesDecoder)
{
nsresult res = m4BytesDecoder->Reset();
NS_ASSERTION(NS_SUCCEEDED(res), "4 bytes unique conversoin reset failed");
int32_t len = 4;
int32_t dstlen = 1;
res = m4BytesDecoder->Convert(aSrc,&len, aOut, &dstlen);
NS_ASSERTION(NS_FAILED(res) || ((len==4) && (dstlen == 1)),
"some strange conversion result");
// if we failed, we then just use the 0xfffd
// therefore, we ignore the res here.
if(NS_SUCCEEDED(res))
return true;
}
return false;
}