scuffed-code/icu4c/source/common/ucnv_lmb.c
2000-03-31 16:53:09 +00:00

871 lines
28 KiB
C

/*
**********************************************************************
* Copyright (C) 2000, International Business Machines
* Corporation and others. All Rights Reserved.
**********************************************************************
* file name: ucnv_lmb.cpp
* encoding: US-ASCII
* tab size: 4 (not used)
* indentation:4
*
* created on: 2000feb09
* created by: Brendan Murray
*/
#include "unicode/utypes.h"
#include "cmemory.h"
#include "ucmp16.h"
#include "ucmp8.h"
#include "unicode/ucnv_bld.h"
#include "unicode/ucnv.h"
#include "ucnv_cnv.h"
/* LMBCS -------------------------------------------------------------------- */
/* Group bytes, and things that look like group bytes, should always be 8-bits */
typedef uint8_t ulmbcs_grp_t;
/* Define some constants instead of using literals */
/* LMBCS groups */
#define ULMBCS_GRP_EXCEPT 0x00 /* placeholder index for 'oddballs' XY, where Y<0x80 */
#define ULMBCS_GRP_L1 0x01 /* Latin-1 */
#define ULMBCS_GRP_GR 0x02 /* Greek */
#define ULMBCS_GRP_HE 0x03 /* Hebrew */
#define ULMBCS_GRP_AR 0x04 /* Arabic */
#define ULMBCS_GRP_RU 0x05 /* Cyrillic */
#define ULMBCS_GRP_L2 0x06 /* Latin-2 */
#define ULMBCS_GRP_TR 0x08 /* Turkish */
#define ULMBCS_GRP_TH 0x0B /* Thai */
#define ULMBCS_GRP_CTRL 0x0F /* C0/C1 controls */
#define ULMBCS_GRP_JA 0x10 /* Japanese */
#define ULMBCS_GRP_KO 0x11 /* Korean */
#define ULMBCS_GRP_CN 0x12 /* Chinese PRC */
#define ULMBCS_GRP_TW 0x13 /* Chinese Taiwan */
#define ULMBCS_GRP_UNICODE 0x14 /* Unicode compatibility group */
#define ULMBCS_GRP_LAST 0x14 /* last LMBCS group that means anything */
/* some special values that can appear in place of optimization groups */
#define ULMBCS_HT 0x09 /* Fixed control char - Horizontal Tab */
#define ULMBCS_LF 0x0A /* Fixed control char - Line Feed */
#define ULMBCS_CR 0x0D /* Fixed control char - Carriage Return */
#define ULMBCS_123SYSTEMRANGE 0x19 /* Fixed control char for 1-2-3 file data: start system range name */
#define ULMBCS_DEFAULTOPTGROUP 0x1 /* default optimization group for LMBCS */
#define ULMBCS_DOUBLEOPTGROUP 0x10 /* start of double-byte optimization groups */
/* parts of LMBCS values, or ranges for LMBCS data */
#define ULMBCS_UNICOMPATZERO 0xF6 /* PUA range for Unicode chars containing LSB = 0 */
#define ULMBCS_CTRLOFFSET 0x20 /* Offset of control range in group 0x0F */
#define ULMBCS_C1START 0x80 /* Start of 'C1' upper ascii range in ANSI code pages */
#define ULMBCS_C0END 0x1F /* last of the 'C0' lower ascii contraol range in ANSI code pages */
#define ULMBCS_INVALIDCHAR 0xFFFF /* Invalid character value = convert failed */
/* special return values for FindLMBCSUniRange */
#define ULMBCS_AMBIGUOUS_SBCS 0x80 // could fit in more than one
// LMBCS sbcs native encoding (example: most accented latin)
#define ULMBCS_AMBIGUOUS_MBCS 0x81 // could fit in more than one
//LMBCS mbcs native encoding (example: Unihan)
/* macro to check compatibility of groups */
#define ULMBCS_AMBIGUOUS_MATCH(agroup, xgroup) \
((((agroup) == ULMBCS_AMBIGUOUS_SBCS) && \
(xgroup) < ULMBCS_DOUBLEOPTGROUP) || \
(((agroup) == ULMBCS_AMBIGUOUS_MBCS) && \
(xgroup) >= ULMBCS_DOUBLEOPTGROUP))
/* Max size for 1 LMBCS char */
#define ULMBCS_CHARSIZE_MAX 3
/* JSGTODO: what is ICU standard debug assertion method?
Invent an all-crash stop here, for now */
#if 1
#define MyAssert(b) {if (!(b)) {*(char *)0 = 1;}}
#else
#define MyAssert(b)
#endif
/* Map Optimization group byte to converter name. Note the following:
0x00 is dummy, and contains the name of the exceptions converter.
0x02 is currently unavailable: NLTC have been asked to provide.
0x0F and 0x14 are algorithmically calculated
0x09, 0x0A, 0x0D are data bytes (HT, LF, CR)
0x07, 0x0C and 0x0E are unused
*/
static const char * OptGroupByteToCPName[ULMBCS_CTRLOFFSET] = {
/* 0x0000 */ "lmb-excp", /* No zero opt group: for non-standard entries */
/* 0x0001 */ "ibm-850",
/* 0x0002 */ "ibm-851",
/* 0x0003 */ "ibm-1255",
/* 0x0004 */ "ibm-1256",
/* 0x0005 */ "ibm-1251",
/* 0x0006 */ "ibm-852",
/* 0x0007 */ NULL, /* Unused */
/* 0x0008 */ "ibm-1254",
/* 0x0009 */ NULL, /* Control char HT */
/* 0x000A */ NULL, /* Control char LF */
/* 0x000B */ "ibm-874",
/* 0x000C */ NULL, /* Unused */
/* 0x000D */ NULL, /* Control char CR */
/* 0x000E */ NULL, /* Unused */
/* 0x000F */ NULL, /* Control chars: 0x0F20 + C0/C1 character: algorithmic */
/* 0x0010 */ "ibm-943",
/* 0x0011 */ "ibm-1361",
/* 0x0012 */ "ibm-950",
/* 0x0013 */ "ibm-1386"
/* The rest are null, including the 0x0014 Unicode compatibility region
and 0x0019, the 1-2-3 system range control char */
};
/* map UNICODE ranges to converter indexes (or special values) */
ulmbcs_grp_t FindLMBCSUniRange(UChar uniChar, UErrorCode* err);
struct _UniLMBCSGrpMap
{
UChar uniStartRange;
UChar uniEndRange;
ulmbcs_grp_t GrpType;
} UniLMBCSGrpMap[]
=
{
0x0001, 0x001F, ULMBCS_GRP_CTRL,
0x0080, 0x009F, ULMBCS_GRP_CTRL,
0x00A0, 0x0113, ULMBCS_AMBIGUOUS_SBCS,
0x0115, 0x0120, ULMBCS_AMBIGUOUS_SBCS,
0x0120, 0x012B, ULMBCS_GRP_EXCEPT,
0x012C, 0x01CD, ULMBCS_AMBIGUOUS_SBCS,
0x01CE, 0x01CE, ULMBCS_AMBIGUOUS_MBCS,
0x01CF, 0x1FFF, ULMBCS_AMBIGUOUS_SBCS,
0x2000, 0xFFFD, ULMBCS_AMBIGUOUS_MBCS,
0xFFFF, 0xFFFF,
};
ulmbcs_grp_t FindLMBCSUniRange(UChar uniChar, UErrorCode* err)
{
struct _UniLMBCSGrpMap * pTable = UniLMBCSGrpMap;
while (uniChar > pTable->uniEndRange)
{
pTable++;
}
if (uniChar >= pTable->uniStartRange)
{
return pTable->GrpType;
}
if (pTable->uniStartRange == 0xFFFF)
{
*err = ULMBCS_INVALIDCHAR;
}
return ULMBCS_GRP_UNICODE;
}
#if 0
// JSGTODO (by Brendan?) some incomplete source data from Brendan to be integrated
0xFE30, ULMBCS_GRP_JA, ULMBCS_FLAGS_CONTINUE,
0xFA2E, ULMBCS_GRP_UNICODE, ULMBCS_FLAGS_UNICODE,
0xF8FF, ULMBCS_GRP_JA, ULMBCS_FLAGS_CONTINUE,
0xD7FF, ULMBCS_GRP_UNICODE, ULMBCS_FLAGS_UNICODE,
0xABFF, ULMBCS_GRP_KO, ULMBCS_FLAGS_UNICODE,
0x9FFF, ULMBCS_GRP_UNICODE, ULMBCS_FLAGS_UNICODE,
0x31FF, ULMBCS_GRP_JA, ULMBCS_FLAGS_CONTINUE,
0x318F, ULMBCS_GRP_CN, ULMBCS_FLAGS_CONTINUE,
0x3130, ULMBCS_GRP_KO, ULMBCS_FLAGS_UNICODE,
0x3100, ULMBCS_GRP_CN, ULMBCS_FLAGS_CONTINUE,
0x313F, ULMBCS_GRP_JA, ULMBCS_FLAGS_UNICODE,
0x2FFF, ULMBCS_GRP_JA, ULMBCS_FLAGS_CONTINUE,
0x2714, ULMBCS_GRP_UNICODE, ULMBCS_FLAGS_UNICODE,
0x2000, ULMBCS_GRP_L1, ULMBCS_FLAGS_CONTINUE,
0x0E5C, ULMBCS_GRP_UNICODE, ULMBCS_FLAGS_UNICODE,
0x0E00, ULMBCS_GRP_TH, ULMBCS_FLAGS_UNICODE,
0x06FF, ULMBCS_GRP_UNICODE, ULMBCS_FLAGS_UNICODE,
0x0600, ULMBCS_GRP_AR, ULMBCS_FLAGS_UNICODE,
0x0500, ULMBCS_GRP_HE, ULMBCS_FLAGS_UNICODE,
0x0400, ULMBCS_GRP_RU, ULMBCS_FLAGS_UNICODE,
0x0300, ULMBCS_GRP_GR, ULMBCS_FLAGS_UNICODE,
0x001F, ULMBCS_GRP_L1, ULMBCS_FLAGS_CONTINUE,
0x0000, ULMBCS_GRP_CTRL, ULMBCS_FLAGS_UNICODE
#endif
int LMBCSConversionWorker (
UConverterDataLMBCS * extraInfo, ulmbcs_grp_t group,
uint8_t * pStartLMBCS, UChar * pUniChar,
ulmbcs_grp_t * lastConverterIndex, bool_t * groups_tried,
UErrorCode* err);
int LMBCSConversionWorker (
UConverterDataLMBCS * extraInfo, ulmbcs_grp_t group,
uint8_t * pStartLMBCS, UChar * pUniChar,
ulmbcs_grp_t * lastConverterIndex, bool_t * groups_tried,
UErrorCode * err)
{
uint8_t * pLMBCS = pStartLMBCS;
UConverter * xcnv = extraInfo->OptGrpConverter[group];
uint8_t mbChar [ULMBCS_CHARSIZE_MAX];
uint8_t * pmbChar = mbChar;
bool_t isDoubleByteGroup = (group >= ULMBCS_DOUBLEOPTGROUP) ? TRUE : FALSE;
UErrorCode localErr = 0;
int bytesConverted =0;
MyAssert(xcnv);
MyAssert(group<ULMBCS_GRP_UNICODE);
ucnv_fromUnicode(xcnv, (char **)&pmbChar,(char *)mbChar+sizeof(mbChar),&pUniChar,pUniChar+1,NULL,TRUE,&localErr);
bytesConverted = pmbChar - mbChar;
pmbChar = mbChar;
/* most common failure mode is the sub-converter using the substitution char (0x7f for our converters)
*/
if (*mbChar == xcnv->subChar[0] || U_FAILURE(localErr) || !bytesConverted )
{
// JSGTODO: are there some local failure modes that ought to be bubbled up in some other way?
groups_tried[group] = TRUE;
return 0;
}
*lastConverterIndex = group;
/* All initial byte values in lower ascii range should have been caught by now,
except with the exception group.
Uncomment this assert to find them.
*/
// MyAssert((*pmbChar <= ULMBCS_C0END) || (*pmbChar >= ULMBCS_C1START) || (group == ULMBCS_GRP_EXCEPT));
/* use converted data: first write 0, 1 or two group bytes */
if (group != ULMBCS_GRP_EXCEPT && extraInfo->OptGroup != group)
{
*pLMBCS++ = group;
if (bytesConverted == 1 && isDoubleByteGroup)
{
*pLMBCS++ = group;
}
}
/* then move over the converted data */
do
{
*pLMBCS++ = *pmbChar++;
}
while(--bytesConverted);
return (pLMBCS - pStartLMBCS);
}
/* Convert Unicode string to LMBCS */
void _LMBCSFromUnicode(UConverter* _this,
char** target,
const char* targetLimit,
const UChar** source,
const UChar* sourceLimit,
int32_t * offsets,
bool_t flush,
UErrorCode* err)
{
ulmbcs_grp_t lastConverterIndex = 0;
UChar uniChar;
uint8_t LMBCS[ULMBCS_CHARSIZE_MAX];
uint8_t * pLMBCS;
int bytes_written;
bool_t groups_tried[ULMBCS_GRP_LAST];
UConverterDataLMBCS * extraInfo = (UConverterDataLMBCS *) _this->extraInfo;
/* Arguments Check */
if (!err || U_FAILURE(*err))
{
return;
}
if (sourceLimit < *source)
{
*err = U_ILLEGAL_ARGUMENT_ERROR;
return;
}
do
{
uniChar = *(*source)++;
bytes_written = 0;
pLMBCS = LMBCS;
/* single byte matches */
if (uniChar == 0 || uniChar == ULMBCS_HT || uniChar == ULMBCS_CR ||
uniChar == ULMBCS_LF || uniChar == ULMBCS_123SYSTEMRANGE ||
((uniChar >= ULMBCS_CTRLOFFSET) && (uniChar < ULMBCS_C1START)))
{
*pLMBCS++ = (uint8_t) uniChar;
bytes_written = 1;
}
if (!bytes_written)
{
/* Check by UNICODE range */
ulmbcs_grp_t group = FindLMBCSUniRange(uniChar,err);
if (group == ULMBCS_GRP_UNICODE)
{
/* encode into LMBCS Unicode range */
uint8_t LowCh = (uint8_t) (uniChar & 0x00FF);
uint8_t HighCh = (uint8_t)(uniChar >> 8);
*pLMBCS++ = ULMBCS_GRP_UNICODE;
if (LowCh == 0)
{
*pLMBCS++ = ULMBCS_UNICOMPATZERO;
*pLMBCS++ = HighCh;
}
else
{
*pLMBCS++ = HighCh;
*pLMBCS++ = LowCh;
}
bytes_written = pLMBCS - LMBCS;
}
else if (group == ULMBCS_GRP_CTRL)
{
/* Handle control characters here */
if (uniChar <= ULMBCS_C0END)
{
*pLMBCS++ = ULMBCS_GRP_CTRL;
*pLMBCS++ = ULMBCS_CTRLOFFSET + (uint8_t) uniChar;
}
else if (uniChar >= ULMBCS_C1START && uniChar <= ULMBCS_C1START + ULMBCS_CTRLOFFSET)
{
*pLMBCS++ = ULMBCS_GRP_CTRL;
*pLMBCS++ = (uint8_t) (uniChar & 0x00FF);
}
bytes_written = pLMBCS - LMBCS;
}
else if (group < ULMBCS_GRP_UNICODE)
{
/* a specific converter has been identified - use it */
bytes_written = LMBCSConversionWorker (
extraInfo, group, pLMBCS, &uniChar,
&lastConverterIndex, groups_tried, err);
MyAssert(bytes_written); /* table should never return unusable group */
}
else /* the ambiguous group cases */
{
memset(groups_tried, 0, sizeof(groups_tried));
/* check for non-default optimization group */
if (extraInfo->OptGroup != 1
&& ULMBCS_AMBIGUOUS_MATCH(group, extraInfo->OptGroup))
{
bytes_written = LMBCSConversionWorker (extraInfo,
extraInfo->OptGroup, pLMBCS, &uniChar,
&lastConverterIndex, groups_tried, err);
}
/* check for locale optimization group */
if (!bytes_written
&& (extraInfo->localeConverterIndex)
&& (ULMBCS_AMBIGUOUS_MATCH(group, extraInfo->localeConverterIndex)))
{
bytes_written = LMBCSConversionWorker (extraInfo,
extraInfo->localeConverterIndex, pLMBCS, &uniChar,
&lastConverterIndex, groups_tried, err);
}
/* check for last optimization group used for this string */
if (!bytes_written
&& (lastConverterIndex)
&& (ULMBCS_AMBIGUOUS_MATCH(group, lastConverterIndex)))
{
bytes_written = LMBCSConversionWorker (extraInfo,
lastConverterIndex, pLMBCS, &uniChar,
&lastConverterIndex, groups_tried, err);
}
if (!bytes_written)
{
/* just check every matching converter */
ulmbcs_grp_t grp_start;
ulmbcs_grp_t grp_end;
ulmbcs_grp_t grp_ix;
grp_start = (group == ULMBCS_AMBIGUOUS_MBCS)
? ULMBCS_DOUBLEOPTGROUP
: ULMBCS_GRP_L1;
grp_end = (group == ULMBCS_AMBIGUOUS_MBCS)
? ULMBCS_GRP_LAST-1
: ULMBCS_GRP_TH;
for (grp_ix = grp_start;
grp_ix <= grp_end && !bytes_written;
grp_ix++)
{
if (extraInfo->OptGrpConverter [grp_ix] && !groups_tried [grp_ix])
{
bytes_written = LMBCSConversionWorker (extraInfo,
grp_ix, pLMBCS, &uniChar,
&lastConverterIndex, groups_tried, err);
}
}
/* a final conversion fallback for sbcs to the exceptions group */
if (!bytes_written && group == ULMBCS_AMBIGUOUS_SBCS)
{
bytes_written = LMBCSConversionWorker (extraInfo,
ULMBCS_GRP_EXCEPT, pLMBCS, &uniChar,
&lastConverterIndex, groups_tried, err);
}
/* all of our strategies failed. Fallback to Unicode. Consider adding these to table */
if (!bytes_written)
{
/* encode into LMBCS Unicode range */
uint8_t LowCh = (uint8_t) uniChar;
uint8_t HighCh = (uint8_t)(uniChar >> 8);
*pLMBCS++ = ULMBCS_GRP_UNICODE;
if (LowCh == 0)
{
*pLMBCS++ = ULMBCS_UNICOMPATZERO;
*pLMBCS++ = HighCh;
}
else
{
*pLMBCS++ = HighCh;
*pLMBCS++ = LowCh;
}
bytes_written = pLMBCS - LMBCS;
}
}
}
}
if (*target + bytes_written > targetLimit)
{
/* JSGTODO deal with buffer running out here */
}
/* now that we are sure it all fits, move it in */
for(pLMBCS = LMBCS; bytes_written--; *(*target)++ = *pLMBCS++)
{ };
}
while (*source<= sourceLimit &&
*target <= targetLimit &&
!U_FAILURE(*err));
/* JSGTODO Check the various exit conditions */
}
/* Return the Unicode representation for the current LMBCS character */
UChar _LMBCSGetNextUChar(UConverter* _this,
const char** source,
const char* sourceLimit,
UErrorCode* err)
{
uint8_t CurByte; // A byte from the input stream
UChar uniChar; // an output UNICODE char
UChar mbChar; // an intermediate multi-byte value (mbcs or LMBCS)
CompactShortArray *MyCArray = NULL;
UConverterDataLMBCS * extraInfo = (UConverterDataLMBCS *) _this->extraInfo;
ulmbcs_grp_t group = 0;
UConverter* cnv = 0;
/* Opt Group (or first data byte) */
CurByte = *((uint8_t *) (*source)++);
uniChar = 0;
// at entry of each if clause:
// 1. 'CurByte' points at the first byte of a LMBCS character
// 2. '*source'points to the next byte of the source stream after 'CurByte'
// the job of each if clause is:
// 1. set '*source' to point at the beginning of next char (nop if LMBCS char is only 1 byte)
// 2. set 'uniChar' up with the right Unicode value, or set 'err' appropriately
// First lets check the simple fixed values.
if (CurByte == 0 || CurByte == ULMBCS_HT || CurByte == ULMBCS_CR ||
CurByte == ULMBCS_LF || CurByte == ULMBCS_123SYSTEMRANGE ||
((CurByte >= ULMBCS_CTRLOFFSET) && (CurByte < ULMBCS_C1START)))
{
uniChar = CurByte;
}
else
if (CurByte == ULMBCS_GRP_CTRL) /* Control character group - no opt group update */
{
if (*source >= sourceLimit)
{
*err = U_TRUNCATED_CHAR_FOUND;
}
else
{
uint8_t C0C1byte = *(*source)++;
uniChar = (C0C1byte < ULMBCS_C1START) ? C0C1byte - ULMBCS_CTRLOFFSET : C0C1byte;
}
}
else
if (CurByte == ULMBCS_GRP_UNICODE) /* Unicode compatibility group: BE as is */
{
uint8_t HighCh, LowCh;
HighCh = *(*source)++; /* Big-endian Unicode in LMBCs compatibility group*/
LowCh = *(*source)++;
if (HighCh == ULMBCS_UNICOMPATZERO )
{
HighCh = LowCh;
LowCh = 0; /* zero-byte in LSB special character */
}
uniChar = (HighCh << 8) | LowCh;
}
else if (CurByte <= ULMBCS_CTRLOFFSET)
{
group = CurByte; /* group byte is in the source */
cnv = extraInfo->OptGrpConverter[group];
if (!cnv)
{
/* this is not a valid group byte - no converter*/
*err = U_INVALID_CHAR_FOUND;
}
else if (group >= ULMBCS_DOUBLEOPTGROUP) /* double byte conversion */
{
uint8_t HighCh, LowCh;
HighCh = *(*source)++;
LowCh = *(*source)++;
/* check for LMBCS doubled-group-byte case */
mbChar = (HighCh == group) ? LowCh : (HighCh<<8) | LowCh;
MyCArray = cnv->sharedData->table->mbcs.toUnicode;
uniChar = (UChar) ucmp16_getu (MyCArray, mbChar);
}
else /* single byte conversion */
{
CurByte = *(*source)++;
if (CurByte >= ULMBCS_C1START)
{
uniChar = cnv->sharedData->table->sbcs.toUnicode[CurByte];
}
else
{
/* The non-optimizable oddballs where there is an explicit byte
* AND the second byte is not in the upper ascii range
*/
cnv = extraInfo->OptGrpConverter [ULMBCS_GRP_EXCEPT];
/* Lookup value must include opt group */
mbChar = (UChar)(group << 8) | (UChar) CurByte;
MyCArray = cnv->sharedData->table->mbcs.toUnicode;
uniChar = (UChar) ucmp16_getu(MyCArray, mbChar);
}
}
}
else if (CurByte >= ULMBCS_C1START) /* group byte is implicit */
{
group = extraInfo->OptGroup;
cnv = extraInfo->OptGrpConverter[group];
if (group >= ULMBCS_DOUBLEOPTGROUP) /* double byte conversion */
{
uint8_t HighCh, LowCh;
// JSGTODO need to deal with case of single byte G1
// chars in mbcs groups
HighCh = CurByte;
LowCh = *(*source)++;
mbChar = (HighCh<<8) | LowCh;
MyCArray = cnv->sharedData->table->mbcs.toUnicode;
uniChar = (UChar) ucmp16_getu (MyCArray, mbChar);
(*source) += sizeof(UChar);
}
else /* single byte conversion */
{
uniChar = cnv->sharedData->table->sbcs.toUnicode[CurByte];
}
}
else
{
#if DEBUG
// JSGTODO: assert here: we should never get here.
#endif
}
// JSGTODO: need to correctly deal with partial chars
return uniChar;
}
void _LMBCSToUnicodeWithOffsets(UConverter* _this,
UChar** target,
const UChar* targetLimit,
const char** source,
const char* sourceLimit,
int32_t* offsets,
bool_t flush,
UErrorCode* err)
{
UChar uniChar; // an output UNICODE char
CompactShortArray *MyCArray = NULL;
UConverterDataLMBCS * extraInfo = (UConverterDataLMBCS *) _this->extraInfo;
ulmbcs_grp_t group = 0;
UConverter* cnv = 0;
const char * pStartLMBCS = *source;
if (!err || U_FAILURE(*err))
{
return;
}
if ((_this == NULL) || (targetLimit < *target) || (sourceLimit < *source))
{
*err = U_ILLEGAL_ARGUMENT_ERROR;
return;
}
#if 0 // JSGTODOD - restore incomplete char handling
/* Have we arrived here from a prior conversion ending with a partial char?
The only possible configurations are:
1. mode contains the group byte of SBCS LMBCS char;
2. mode contains the group byte of MBCS LMBCS char
For both continue with next char in input buffer
3. mode contains group byte + 1st data byte of MBCS LMBCS char
Partially process & get the second data byte
4. mode contains both group bytes of double group-byte MBCS LMBCS char
Nuke contents after setting up converter & continue with buffer data
*/
if (_this->toUnicodeStatus)
{
mbChar = (UChar) _this->mode; /* Restore the previously calculated char */
_this->toUnicodeStatus = 0; /* Reset other fields*/
_this->invalidCharLength = 0;
/* Check if this is a partial MBCS char (fall through if SBCS) */
if (mbChar > 0xFF)
{
/* Select the correct converter */
group = (mbChar >> 8) & 0x00FF;
cnv = extraInfo->OptGrpConverter[group];
/* Pick up the converter table */
MyCArray = cnv->sharedData->table->mbcs.toUnicode;
/* Use only data byte: NULL if the character has pair of group-bytes */
if (mbChar & 0x00FF < ULMBCS_MAXGRPBYTE)
CurByte = 0;
else
CurByte = ((mbChar & 0x00FF) << 8);
/* Add the current char from the buffer */
CurByte |= *((uint8_t *) (*source)++);
goto continueWithPartialMBCSChar;
}
else
{
goto continueWithPartialChar;
}
}
#endif
/* Process from source to limit */
while (!*err && sourceLimit > *source && targetLimit > *target)
{
if(offsets)
{
*offsets = (*source) - pStartLMBCS;
}
uniChar = _LMBCSGetNextUChar(_this, source, sourceLimit, err);
// last step is always to move the new value into the buffer
if (U_SUCCESS(*err) && uniChar != missingUCharMarker)
{
// JSGTODO deal with missingUCharMarker case for error/info reporting.
*(*target)++ = uniChar;
if(offsets)
{
offsets++;
}
}
}
#if 0
// JSGTODO restore partial char handling
/* Check to see if we've fallen through because of a partial char */
if (*err == U_TRUNCATED_CHAR_FOUND)
{
_this->mode = mbChar; /* Save current partial char */
}
#endif
}
/* Convert LMBCS string to Unicode */
void _LMBCSToUnicode(UConverter* _this,
UChar** target,
const UChar* targetLimit,
const char** source,
const char* sourceLimit,
int32_t* offsets,
bool_t flush,
UErrorCode* err)
{
_LMBCSToUnicodeWithOffsets(_this, target, targetLimit, source, sourceLimit, offsets, flush,err);
}
static void _LMBCSOpenWorker(UConverter* _this,
const char* name,
const char* locale,
UErrorCode* err,
ulmbcs_grp_t OptGroup
)
{
UConverterDataLMBCS * extraInfo = uprv_malloc (sizeof (UConverterDataLMBCS));
if(extraInfo != NULL)
{
ulmbcs_grp_t i;
ulmbcs_grp_t imax;
imax = sizeof(extraInfo->OptGrpConverter)/sizeof(extraInfo->OptGrpConverter[0]);
for (i=0; i < imax; i++)
{
extraInfo->OptGrpConverter[i] =
(OptGroupByteToCPName[i] != NULL) ?
ucnv_open(OptGroupByteToCPName[i], err) : NULL;
}
extraInfo->OptGroup = OptGroup;
/* JSGTODO: add LocaleConverterIndex logic here */
extraInfo->localeConverterIndex = 0;
}
else
{
*err = U_MEMORY_ALLOCATION_ERROR;
}
_this->extraInfo = extraInfo;
}
static void _LMBCSClose(UConverter * _this)
{
if (_this->extraInfo != NULL)
{
ulmbcs_grp_t Ix;
for (Ix=0; Ix < ULMBCS_GRP_UNICODE; Ix++)
{
UConverterDataLMBCS * extraInfo = (UConverterDataLMBCS *) _this->extraInfo;
if (extraInfo->OptGrpConverter[Ix] != NULL)
ucnv_close (extraInfo->OptGrpConverter[Ix]);
}
uprv_free (_this->extraInfo);
}
}
#define DEFINE_LMBCS_OPEN(n) \
static void _LMBCSOpen##n(UConverter* _this,const char* name,const char* locale,UErrorCode* err) \
{ _LMBCSOpenWorker(_this, name,locale, err, n);} \
DEFINE_LMBCS_OPEN(1)
DEFINE_LMBCS_OPEN(2)
DEFINE_LMBCS_OPEN(3)
DEFINE_LMBCS_OPEN(4)
DEFINE_LMBCS_OPEN(5)
DEFINE_LMBCS_OPEN(6)
DEFINE_LMBCS_OPEN(8)
DEFINE_LMBCS_OPEN(11)
DEFINE_LMBCS_OPEN(16)
DEFINE_LMBCS_OPEN(17)
DEFINE_LMBCS_OPEN(18)
DEFINE_LMBCS_OPEN(19)
#define DECLARE_LMBCS_DATA(n) \
static const UConverterImpl _LMBCSImpl##n={\
UCNV_LMBCS_##n,\
NULL,NULL,\
_LMBCSOpen##n,\
_LMBCSClose,\
NULL,\
_LMBCSToUnicode,\
_LMBCSToUnicodeWithOffsets,\
_LMBCSFromUnicode,\
NULL,\
_LMBCSGetNextUChar,\
NULL\
};\
extern const UConverterSharedData _LMBCSData##n={\
sizeof(UConverterSharedData), ~0,\
NULL, NULL, &_LMBCSImpl##n, "LMBCS_" ## #n,\
0, UCNV_IBM, UCNV_LMBCS_1, 1, 1,\
{ 0, 1, 0x3f, 0, 0, 0 }\
};
DECLARE_LMBCS_DATA(1)
DECLARE_LMBCS_DATA(2)
DECLARE_LMBCS_DATA(3)
DECLARE_LMBCS_DATA(4)
DECLARE_LMBCS_DATA(5)
DECLARE_LMBCS_DATA(6)
DECLARE_LMBCS_DATA(8)
DECLARE_LMBCS_DATA(11)
DECLARE_LMBCS_DATA(16)
DECLARE_LMBCS_DATA(17)
DECLARE_LMBCS_DATA(18)
DECLARE_LMBCS_DATA(19)