scuffed-code/icu4c/source/test/cintltst/nucnvtst.c
2000-07-13 15:35:39 +00:00

1874 lines
65 KiB
C

/********************************************************************
* COPYRIGHT:
* Copyright (c) 1997-1999, International Business Machines Corporation and
* others. All Rights Reserved.
********************************************************************/
/********************************************************************************
*
* File CCONVTST.C
*
* Modification History:
* Name Description
* Steven R. Loomis 7/8/1999 Adding input buffer test
*********************************************************************************
*/
#include <stdio.h>
#include <stdlib.h>
#include <string.h>
#include <ctype.h>
#include "unicode/uloc.h"
#include "unicode/ucnv.h"
#include "unicode/ucnv_err.h"
#include "cintltst.h"
#include "unicode/utypes.h"
#include "unicode/ustring.h"
static void printSeq(const unsigned char* a, int len);
static void printUSeq(const UChar* a, int len);
static void TestNextUChar(UConverter* cnv, const char* source, const char* limit, const uint32_t results[], const char* message);
static void TestNextUCharError(UConverter* cnv, const char* source, const char* limit, UErrorCode expected, const char* message);
void TestNewConvertWithBufferSizes(int32_t osize, int32_t isize) ;
void TestConverterTypesAndStarters(void);
void TestAmbiguous(void);
void TestUTF8(void);
void TestUTF16BE(void);
void TestUTF16LE(void);
void TestLATIN1(void);
void TestSBCS(void);
void TestDBCS(void);
void TestMBCS(void);
void TestISO_2022(void);
void TestEBCDIC_STATEFUL(void);
void TestLMBCS(void);
void TestJitterbug255(void);
void TestEBCDICUS4XML(void);
#define NEW_MAX_BUFFER 999
static int32_t gInBufferSize = 0;
static int32_t gOutBufferSize = 0;
static char gNuConvTestName[1024];
#define nct_min(x,y) ((x<y) ? x : y)
void printSeq(const unsigned char* a, int len)
{
int i=0;
log_verbose("{");
while (i<len) log_verbose("%2x ", a[i++]);
log_verbose("}\n");
}
void printUSeq(const UChar* a, int len)
{
int i=0;
log_verbose("{U+");
while (i<len) log_verbose("%4x ", a[i++]);
log_verbose("}\n");
}
void printSeqErr(const unsigned char* a, int len)
{
int i=0;
fprintf(stderr, "{");
while (i<len) fprintf(stderr, "%2x ", a[i++]);
fprintf(stderr, "}\n");
}
void printUSeqErr(const UChar* a, int len)
{
int i=0;
fprintf(stderr, "{U+");
while (i<len) fprintf(stderr, "%4x ", a[i++]);
fprintf(stderr,"}\n");
}
void
TestNextUChar(UConverter* cnv, const char* source, const char* limit, const uint32_t results[], const char* message)
{
const char* s0;
const char* s=(char*)source;
const uint32_t *r=results;
UErrorCode errorCode=U_ZERO_ERROR;
uint32_t c;
while(s<limit) {
s0=s;
c=ucnv_getNextUChar(cnv, &s, limit, &errorCode);
if(U_FAILURE(errorCode)) {
log_err("%s ucnv_getNextUChar() failed: %s\n", message, u_errorName(errorCode));
break;
} else if((uint32_t)(s-s0)!=*r || c!=(UChar32)*(r+1)) {
log_err("%s ucnv_getNextUChar() result %lx from %d bytes, should have been %lx from %d bytes.\n",
message, c, (s-s0), *(r+1), *r);
break;
}
r+=2;
}
}
void
TestNextUCharError(UConverter* cnv, const char* source, const char* limit, UErrorCode expected, const char* message)
{
const char* s=(char*)source;
UErrorCode errorCode=U_ZERO_ERROR;
uint32_t c;
c=ucnv_getNextUChar(cnv, &s, limit, &errorCode);
if(errorCode != expected){
log_err("FAIL: Expected:%s when %s-----Got:%s\n", myErrorName(expected), message, myErrorName(errorCode));
}
if(c != 0xFFFD && c != 0xffff){
log_err("FAIL: Expected return value of 0xfffd or 0xffff when %s-----Got 0x%lx\n", message, c);
}
}
void TestInBufSizes(void)
{
TestNewConvertWithBufferSizes(NEW_MAX_BUFFER,1);
#if 1
TestNewConvertWithBufferSizes(NEW_MAX_BUFFER,2);
TestNewConvertWithBufferSizes(NEW_MAX_BUFFER,3);
TestNewConvertWithBufferSizes(NEW_MAX_BUFFER,4);
TestNewConvertWithBufferSizes(NEW_MAX_BUFFER,5);
TestNewConvertWithBufferSizes(NEW_MAX_BUFFER,6);
TestNewConvertWithBufferSizes(1,1);
TestNewConvertWithBufferSizes(2,3);
TestNewConvertWithBufferSizes(3,2);
#endif
}
void TestOutBufSizes(void)
{
#if 1
TestNewConvertWithBufferSizes(NEW_MAX_BUFFER,NEW_MAX_BUFFER);
TestNewConvertWithBufferSizes(1,NEW_MAX_BUFFER);
TestNewConvertWithBufferSizes(2,NEW_MAX_BUFFER);
TestNewConvertWithBufferSizes(3,NEW_MAX_BUFFER);
TestNewConvertWithBufferSizes(4,NEW_MAX_BUFFER);
TestNewConvertWithBufferSizes(5,NEW_MAX_BUFFER);
#endif
}
void addTestNewConvert(TestNode** root)
{
addTest(root, &TestInBufSizes, "tsconv/nucnvtst/TestInBufSizes");
addTest(root, &TestOutBufSizes, "tsconv/nucnvtst/TestOutBufSizes");
addTest(root, &TestConverterTypesAndStarters, "tsconv/nucnvtst/TestConverterTypesAndStarters");
addTest(root, &TestAmbiguous, "tsconv/nucnvtst/TestAmbiguous");
addTest(root, &TestUTF8, "tsconv/nucnvtst/TestUTF8");
addTest(root, &TestUTF16BE, "tsconv/nucnvtst/TestUTF16BE");
addTest(root, &TestUTF16LE, "tsconv/nucnvtst/TestUTF16LE");
addTest(root, &TestLATIN1, "tsconv/nucnvtst/TestLATIN1");
addTest(root, &TestSBCS, "tsconv/nucnvtst/TestSBCS");
addTest(root, &TestDBCS, "tsconv/nucnvtst/TestDBCS");
addTest(root, &TestMBCS, "tsconv/nucnvtst/TestMBCS");
addTest(root, &TestISO_2022, "tsconv/nucnvtst/TestISO_2022");
addTest(root, &TestEBCDIC_STATEFUL, "tsconv/nucnvtst/TestEBCDIC_STATEFUL");
addTest(root, &TestLMBCS, "tsconv/nucnvtst/TestLMBCS");
addTest(root, &TestJitterbug255, "tsconv/nucnvtst/TestJitterbug255");
addTest(root, &TestEBCDICUS4XML, "tsconv/nucnvtst/TestEBCDICUS4XML");
}
/* Note that this test already makes use of statics, so it's not really
multithread safe.
This convenience function lets us make the error messages actually useful.
*/
void setNuConvTestName(const char *codepage, const char *direction)
{
sprintf(gNuConvTestName, "[Testing %s %s Unicode, InputBufSiz=%d, OutputBufSiz=%d]",
codepage,
direction,
gInBufferSize,
gOutBufferSize);
}
UBool testConvertFromU( const UChar *source, int sourceLen, const char *expect, int expectLen,
const char *codepage, int32_t *expectOffsets)
{
UErrorCode status = U_ZERO_ERROR;
UConverter *conv = 0;
char junkout[NEW_MAX_BUFFER]; /* FIX */
int32_t junokout[NEW_MAX_BUFFER]; /* FIX */
char *p;
const UChar *src;
char *end;
char *targ;
int32_t *offs;
int i;
int32_t realBufferSize;
char *realBufferEnd;
const UChar *realSourceEnd;
const UChar *sourceLimit;
UBool checkOffsets = TRUE;
UBool doFlush;
for(i=0;i<NEW_MAX_BUFFER;i++)
junkout[i] = (char)0xF0;
for(i=0;i<NEW_MAX_BUFFER;i++)
junokout[i] = 0xFF;
setNuConvTestName(codepage, "FROM");
log_verbose("\n========= %s\n", gNuConvTestName);
conv = ucnv_open(codepage, &status);
if(U_FAILURE(status))
{
log_err("Couldn't open converter %s\n",codepage);
return FALSE;
}
log_verbose("Converter opened..\n");
src = source;
targ = junkout;
offs = junokout;
realBufferSize = (sizeof(junkout)/sizeof(junkout[0]));
realBufferEnd = junkout + realBufferSize;
realSourceEnd = source + sourceLen;
if ( gOutBufferSize != realBufferSize )
checkOffsets = FALSE;
if( gInBufferSize != NEW_MAX_BUFFER )
checkOffsets = FALSE;
do
{
end = nct_min(targ + gOutBufferSize, realBufferEnd);
sourceLimit = nct_min(src + gInBufferSize, realSourceEnd);
doFlush = (sourceLimit == realSourceEnd);
if(targ == realBufferEnd)
{
log_err("Error, overflowed the real buffer while about to call fromUnicode! targ=%08lx %s", targ, gNuConvTestName);
return FALSE;
}
log_verbose("calling fromUnicode @ SOURCE:%08lx to %08lx TARGET: %08lx to %08lx, flush=%s\n", src,sourceLimit, targ,end, doFlush?"TRUE":"FALSE");
status = U_ZERO_ERROR;
ucnv_fromUnicode (conv,
&targ,
end,
&src,
sourceLimit,
checkOffsets ? offs : NULL,
doFlush, /* flush if we're at the end of the input data */
&status);
/* verify that any partial char is as expected (need offsets for this test) */
if (status == U_INDEX_OUTOFBOUNDS_ERROR && expectOffsets)
{
char errBytes [UCNV_MAX_SUBCHAR_LEN];
int8_t len = sizeof(errBytes);
UErrorCode localStatus = U_ZERO_ERROR;
ucnv_getInvalidChars (conv, errBytes, &len, &localStatus);
if (U_FAILURE(localStatus))
{
log_err("Error from ucnv_getInvalidChars");
}
else
{
/* use offsets to figure out how big partial char should be */
int targIndex = targ - junkout;
int32_t * pOffset = expectOffsets + targIndex;
int32_t startOffset = *pOffset;
int expectLen;
if (startOffset == pOffset[-1]) /* we have a partial char: how big? */
{
for (pOffset++, expectLen=1; *pOffset == startOffset; ++pOffset, ++expectLen)
;
}
else
{
expectLen = 0; /* targ buffer ran out at char boundary */
}
if (expectLen != len)
{
log_err("charErrorBufferLength expected %d got %d %s\n", expectLen,(int)len, gNuConvTestName);
}
if ((len != 0) && memcmp(errBytes, expect+targIndex, len))
{
log_err("charErrorBuffer bytes do not match expected in %s", gNuConvTestName);
printSeqErr(errBytes, len);
printSeqErr(expect+targIndex, len);
}
}
}
} while ( (status == U_INDEX_OUTOFBOUNDS_ERROR) || (sourceLimit < realSourceEnd) );
if(U_FAILURE(status))
{
log_err("Problem doing fromUnicode, errcode %d %s\n", codepage, status, gNuConvTestName);
return FALSE;
}
log_verbose("\nConversion done [%d uchars in -> %d chars out]. \nResult :",
sourceLen, targ-junkout);
if(VERBOSITY)
{
char junk[9999];
char offset_str[9999];
char *p;
junk[0] = 0;
offset_str[0] = 0;
for(p = junkout;p<targ;p++)
{
sprintf(junk + strlen(junk), "0x%02x, ", (0xFF) & (unsigned int)*p);
sprintf(offset_str + strlen(offset_str), "0x%02x, ", (0xFF) & (unsigned int)junokout[p-junkout]);
}
log_verbose(junk);
printSeq((const unsigned char *)expect, expectLen);
if ( checkOffsets )
{
log_verbose("\nOffsets:");
log_verbose(offset_str);
}
log_verbose("\n");
}
ucnv_close(conv);
if(expectLen != targ-junkout)
{
log_err("Expected %d chars out, got %d %s\n", expectLen, targ-junkout, gNuConvTestName);
log_verbose("Expected %d chars out, got %d %s\n", expectLen, targ-junkout, gNuConvTestName);
printSeqErr(junkout, targ-junkout);
printSeqErr(expect, expectLen);
return FALSE;
}
if (checkOffsets && (expectOffsets != 0) )
{
log_verbose("comparing %d offsets..\n", targ-junkout);
if(memcmp(junokout,expectOffsets,(targ-junkout) * sizeof(int32_t) )){
log_err("did not get the expected offsets. %s", gNuConvTestName);
log_err("Got : ");
printSeqErr(junkout, targ-junkout);
for(p=junkout;p<targ;p++)
log_err("%d, ", junokout[p-junkout]);
log_err("\nExpected: ");
for(i=0; i<(targ-junkout); i++)
log_err("%d,", expectOffsets[i]);
}
}
log_verbose("comparing..\n");
if(!memcmp(junkout, expect, expectLen))
{
log_verbose("Matches!\n");
return TRUE;
}
else
{
log_err("String does not match. %s\n", gNuConvTestName);
printUSeqErr(source, sourceLen);
printSeqErr((const unsigned char *)junkout, expectLen);
printSeqErr((const unsigned char *)expect, expectLen);
return FALSE;
}
}
UBool testConvertToU( const char *source, int sourcelen, const UChar *expect, int expectlen,
const char *codepage, int32_t *expectOffsets)
{
UErrorCode status = U_ZERO_ERROR;
UConverter *conv = 0;
UChar junkout[NEW_MAX_BUFFER]; /* FIX */
int32_t junokout[NEW_MAX_BUFFER]; /* FIX */
const char *src;
const char *realSourceEnd;
const char *srcLimit;
UChar *p;
UChar *targ;
UChar *end;
int32_t *offs;
int i;
UBool checkOffsets = TRUE;
int32_t realBufferSize;
UChar *realBufferEnd;
for(i=0;i<NEW_MAX_BUFFER;i++)
junkout[i] = 0xFFFE;
for(i=0;i<NEW_MAX_BUFFER;i++)
junokout[i] = -1;
setNuConvTestName(codepage, "TO");
log_verbose("\n========= %s\n", gNuConvTestName);
conv = ucnv_open(codepage, &status);
if(U_FAILURE(status))
{
log_err("Couldn't open converter %s\n",gNuConvTestName);
return FALSE;
}
log_verbose("Converter opened..\n");
src = source;
targ = junkout;
offs = junokout;
realBufferSize = (sizeof(junkout)/sizeof(junkout[0]));
realBufferEnd = junkout + realBufferSize;
realSourceEnd = src + sourcelen;
if ( gOutBufferSize != realBufferSize )
checkOffsets = FALSE;
if( gInBufferSize != NEW_MAX_BUFFER )
checkOffsets = FALSE;
do
{
end = nct_min( targ + gOutBufferSize, realBufferEnd);
srcLimit = nct_min(realSourceEnd, src + gInBufferSize);
if(targ == realBufferEnd)
{
log_err("Error, the end would overflow the real output buffer while about to call toUnicode! tarjey=%08lx %s",targ,gNuConvTestName);
return FALSE;
}
log_verbose("calling toUnicode @ %08lx to %08lx\n", targ,end);
/* oldTarg = targ; */
status = U_ZERO_ERROR;
ucnv_toUnicode (conv,
&targ,
end,
&src,
srcLimit,
checkOffsets ? offs : NULL,
(UBool)(srcLimit == realSourceEnd), /* flush if we're at the end of hte source data */
&status);
/* offs += (targ-oldTarg); */
} while ( (status == U_INDEX_OUTOFBOUNDS_ERROR) || (srcLimit < realSourceEnd) ); /* while we just need another buffer */
if(U_FAILURE(status))
{
log_err("Problem doing toUnicode, errcode %d %s\n", status, gNuConvTestName);
return FALSE;
}
log_verbose("\nConversion done. %d bytes -> %d chars.\nResult :",
sourcelen, targ-junkout);
if(VERBOSITY)
{
char junk[9999];
char offset_str[9999];
UChar *p;
junk[0] = 0;
offset_str[0] = 0;
for(p = junkout;p<targ;p++)
{
sprintf(junk + strlen(junk), "0x%04x, ", (0xFFFF) & (unsigned int)*p);
sprintf(offset_str + strlen(offset_str), "0x%04x, ", (0xFFFF) & (unsigned int)junokout[p-junkout]);
}
log_verbose(junk);
if ( checkOffsets )
{
log_verbose("\nOffsets:");
log_verbose(offset_str);
}
log_verbose("\n");
}
ucnv_close(conv);
log_verbose("comparing %d uchars (%d bytes)..\n",expectlen,expectlen*2);
if (checkOffsets && (expectOffsets != 0))
{
if(memcmp(junokout,expectOffsets,(targ-junkout) * sizeof(int32_t))){
log_err("did not get the expected offsets. %s",gNuConvTestName);
for(p=junkout;p<targ;p++)
log_err("%d, ", junokout[p-junkout]);
log_err("\nExpected: ");
for(i=0; i<(targ-junkout); i++)
log_err("%d,", expectOffsets[i]);
log_err("");
for(i=0; i<(targ-junkout); i++)
log_err("%X,", junkout[i]);
log_err("");
for(i=0; i<(src-source); i++)
log_err("%X,", (unsigned char)source[i]);
}
}
if(!memcmp(junkout, expect, expectlen*2))
{
log_verbose("Matches!\n");
return TRUE;
}
else
{
log_err("String does not match. %s\n", gNuConvTestName);
log_verbose("String does not match. %s\n", gNuConvTestName);
printUSeq(junkout, expectlen);
printUSeq(expect, expectlen);
return FALSE;
}
}
void TestNewConvertWithBufferSizes(int32_t outsize, int32_t insize )
{
/** test chars #1 */
/* 1 2 3 1Han 2Han 3Han . */
UChar sampleText[] =
{ 0x0031, 0x0032, 0x0033, 0x0000, 0x4e00, 0x4e8c, 0x4e09, 0x002E };
const char expectedUTF8[] =
{ (char)0x31, (char)0x32, (char)0x33, (char)0x00, (char)0xe4, (char)0xb8, (char)0x80, (char)0xe4, (char)0xba, (char)0x8c, (char)0xe4, (char)0xb8, (char)0x89, (char)0x2E };
int32_t toUTF8Offs[] =
{ (char)0x00, (char)0x01, (char)0x02, (char)0x03, (char)0x04, (char)0x04, (char)0x04, (char)0x05, (char)0x05, (char)0x05, (char)0x06, (char)0x06, (char)0x06, (char)0x07};
int32_t fmUTF8Offs[] =
{ 0x0000, 0x0001, 0x0002, 0x0003, 0x0004, 0x0007, 0x000a, 0x000d };
/* Same as UTF8, but with ^[%B preceeding */
const char expectedISO2022[] =
{ (char)0x1b, (char)0x25, (char)0x42, (char)0x31, (char)0x32, (char)0x33, (char)0x00, (char)0xe4, (char)0xb8, (char)0x80, (char)0xe4, (char)0xba, (char)0x8c, (char)0xe4, (char)0xb8, (char)0x89, (char)0x2E };
int32_t toISO2022Offs[] =
{ (char)0xff, (char)0xff, (char)0xff, (char)0x00, (char)0x01, (char)0x02, (char)0x03, (char)0x04, (char)0x04,
(char)0x04, (char)0x05, (char)0x05, (char)0x05, (char)0x06, (char)0x06, (char)0x06, (char)0x07 }; /* right? */
int32_t fmISO2022Offs[] =
{ 0x0003, 0x0004, 0x0005, 0x0006, 0x0007, 0x000a, 0x000d, 0x0010 }; /* is this right? */
/* 1 2 3 0, <SO> h1 h2 h3 <SI> . EBCDIC_STATEFUL */
const char expectedIBM930[] =
{ (char)0xF1, (char)0xF2, (char)0xF3, (char)0x00, (char)0x0E, (char)0x45, (char)0x41, (char)0x45, (char)0x42, (char)0x45, (char)0x43, (char)0x0F, (char)0x4B };
int32_t toIBM930Offs[] =
{ (char)0x00, (char)0x01, (char)0x02, (char)0x03, (char)0x04, (char)0x04, (char)0x04, (char)0x05, (char)0x05, (char)0x06, (char)0x06, (char)0x07, (char)0x07, };
int32_t fmIBM930Offs[] =
{ 0x0000, 0x0001, 0x0002, 0x0003, 0x0005, 0x0007, 0x0009, 0x000c};
/* 1 2 3 0 h1 h2 h3 . MBCS*/
const char expectedIBM943[] =
{ (char)0x31, (char)0x32, (char)0x33, (char)0x00, (char)0x88, (char)0xea, (char)0x93, (char)0xf1, (char)0x8e, (char)0x4f, (char)0x2e };
int32_t toIBM943Offs [] =
{ (char)0x00, (char)0x01, (char)0x02, (char)0x03, (char)0x04, (char)0x04, (char)0x05, (char)0x05, (char)0x06, (char)0x06, (char)0x07 };
int32_t fmIBM943Offs[] =
{ 0x0000, 0x0001, 0x0002, 0x0003, 0x0004, 0x0006, 0x0008, 0x000a};
/* 1 2 3 0 h1 h2 h3 . DBCS*/
const char expectedIBM835[] =
{ (char)0xfe, (char)0xfe, (char)0xfe, (char)0xfe, (char)0xfe, (char)0xfe, (char)0xfe, (char)0xfe, (char)0x4c, (char)0x41, (char)0x4c, (char)0x48, (char)0x4c, (char)0x55, (char)0xfe, (char)0xfe};
int32_t toIBM835Offs [] =
{ (char)0x00, (char)0x00, (char)0x01, (char)0x01, (char)0x02, (char)0x02, (char)0x03, (char)0x03, (char)0x04, (char)0x04, (char)0x05, (char)0x05, (char)0x06, (char)0x06, (char)0x07, (char)0x07};
/* 1 2 3 0 <?> <?> <?> . SBCS*/
const char expectedIBM920[] =
{ (char)0x31, (char)0x32, (char)0x33, (char)0x00, (char)0x1a, (char)0x1a, (char)0x1a, (char)0x2e };
int32_t toIBM920Offs [] =
{ (char)0x00, (char)0x01, (char)0x02, (char)0x03, (char)0x04, (char)0x05, (char)0x06, (char)0x07 };
/* 1 2 3 0 <?> <?> <?> . SBCS*/
const char expectedISO88593[] =
{ (char)0x31, (char)0x32, (char)0x33, (char)0x00, (char)0x1a, (char)0x1a, (char)0x1a, (char)0x2E };
int32_t toISO88593Offs[] =
{(char) 0x00, (char)0x01, (char)0x02, (char)0x03, (char)0x04, (char)0x05, (char)0x06, (char)0x07};
/* 1 2 3 0 <?> <?> <?> . LATIN_1*/
const char expectedLATIN1[] =
{ (char)0x31, (char)0x32, (char)0x33, (char)0x00, (char)0x1a, (char)0x1a, (char)0x1a, (char)0x2E };
int32_t toLATIN1Offs[] =
{(char) 0x00, (char)0x01, (char)0x02, (char)0x03, (char)0x04, (char)0x05, (char)0x06, (char)0x07};
/* etc */
const char expectedUTF16LE[] =
{ (char)0x31, (char)0x00, (char)0x32, (char)0x00, (char)0x33, (char)0x00, (char)0x00, (char)0x00, (char)0x00, (char)0x4e, (char)0x8c, (char)0x4e, (char)0x09, (char)0x4e, (char)0x2e, (char)0x00 };
int32_t toUTF16LEOffs[]=
{ (char)0x00, (char)0x00, (char)0x01, (char)0x01, (char)0x02, (char)0x02, (char)0x03, (char)0x03, (char)0x04, (char)0x04, (char)0x05, (char)0x05, (char)0x06, (char)0x06, (char)0x07, (char)0x07};
int32_t fmUTF16LEOffs[] =
{ 0x0000, 0x0002, 0x0004, 0x0006, 0x0008, 0x000a, 0x000c, 0x000e };
const char expectedUTF16BE[] =
{ (char)0x00, (char)0x31, (char)0x00, (char)0x32, (char)0x00, (char)0x33, (char)0x00, (char)0x00, (char)0x4e, (char)0x00, (char)0x4e, (char)0x8c, (char)0x4e, (char)0x09, (char)0x00, (char)0x2e };
int32_t toUTF16BEOffs[]=
{ (char)0x00, (char)0x00, (char)0x01, (char)0x01, (char)0x02, (char)0x02, (char)0x03, (char)0x03, (char)0x04, (char)0x04, (char)0x05, (char)0x05, (char)0x06, (char)0x06, (char)0x07, (char)0x07};
int32_t fmUTF16BEOffs[] =
{ 0x0000, 0x0002, 0x0004, 0x0006, 0x0008, 0x000a, 0x000c, 0x000e };
/** Test chars #2 **/
/* Sahha [health], slashed h's */
const UChar malteseUChars[] = { 0x0053, 0x0061, 0x0127, 0x0127, 0x0061 };
const char expectedMaltese913[] = { (char)0x53, (char)0x61, (char)0xB1, (char)0xB1, (char)0x61 };
/* LMBCS */
const UChar LMBCSUChars[] = { 0x0027, 0x010A, 0x0000, 0x0127, 0x2666 };
const char expectedLMBCS[] = { (char)0x27, (char)0x06, (char)0x04, (char)0x00, (char)0x01, (char)0x73, (char)0x01, (char)0x04 };
int32_t toLMBCSOffs[] = { (char)0x00, (char)0x01, (char)0x01, (char)0x02, (char)0x03, (char)0x03, (char)0x04, (char)0x04 };
int32_t fmLMBCSOffs[] = { 0x0000, 0x0001, 0x0003, 0x0004, 0x0006};
/*********************************** START OF CODE finally *************/
gInBufferSize = insize;
gOutBufferSize = outsize;
log_verbose("\n\n\nTesting conversions with InputBufferSize = %d, OutputBufferSize = %d\n", gInBufferSize, gOutBufferSize);
#if 1
/*UTF-8*/
if(!testConvertFromU(sampleText, sizeof(sampleText)/sizeof(sampleText[0]),
expectedUTF8, sizeof(expectedUTF8), "UTF8", toUTF8Offs ))
log_err("u-> UTF8 did not match.\n");
/*ISO-2022*/
if(!testConvertFromU(sampleText, sizeof(sampleText)/sizeof(sampleText[0]),
expectedISO2022, sizeof(expectedISO2022), "iso-2022", toISO2022Offs ))
log_err("u-> iso-2022 did not match.\n");
/*UTF16 LE*/
if(!testConvertFromU(sampleText, sizeof(sampleText)/sizeof(sampleText[0]),
expectedUTF16LE, sizeof(expectedUTF16LE), "utf-16le", toUTF16LEOffs ))
log_err("u-> utf-16le did not match.\n");
/*UTF16 BE*/
if(!testConvertFromU(sampleText, sizeof(sampleText)/sizeof(sampleText[0]),
expectedUTF16BE, sizeof(expectedUTF16BE), "utf-16be", toUTF16BEOffs ))
log_err("u-> utf-16be did not match.\n");
/*LATIN_1*/
if(!testConvertFromU(sampleText, sizeof(sampleText)/sizeof(sampleText[0]),
expectedLATIN1, sizeof(expectedLATIN1), "LATIN_1", toLATIN1Offs ))
log_err("u-> LATIN_1 did not match.\n");
/*EBCDIC_STATEFUL*/
if(!testConvertFromU(sampleText, sizeof(sampleText)/sizeof(sampleText[0]),
expectedIBM930, sizeof(expectedIBM930), "ibm-930", toIBM930Offs ))
log_err("u-> ibm-930 did not match.\n");
if(!testConvertFromU(sampleText, sizeof(sampleText)/sizeof(sampleText[0]),
expectedISO88593, sizeof(expectedISO88593), "iso-8859-3", toISO88593Offs ))
log_err("u-> iso-8859-3 did not match.\n");
/*MBCS*/
if(!testConvertFromU(sampleText, sizeof(sampleText)/sizeof(sampleText[0]),
expectedIBM943, sizeof(expectedIBM943), "ibm-943", toIBM943Offs ))
log_err("u-> ibm-943 [UCNV_MBCS] not match.\n");
/*DBCS*/
if(!testConvertFromU(sampleText, sizeof(sampleText)/sizeof(sampleText[0]),
expectedIBM835, sizeof(expectedIBM835), "ibm-835", toIBM835Offs ))
log_err("u-> ibm-835 [UCNV_DBCS] not match.\n");
/*SBCS*/
if(!testConvertFromU(sampleText, sizeof(sampleText)/sizeof(sampleText[0]),
expectedIBM920, sizeof(expectedIBM920), "ibm-920", toIBM920Offs ))
log_err("u-> ibm-920 [UCNV_SBCS] not match.\n");
/*SBCS*/
if(!testConvertFromU(sampleText, sizeof(sampleText)/sizeof(sampleText[0]),
expectedISO88593, sizeof(expectedISO88593), "iso-8859-3", toISO88593Offs ))
log_err("u-> iso-8859-3 did not match.\n");
/****/
#endif
#if 1
/*UTF-8*/
if(!testConvertToU(expectedUTF8, sizeof(expectedUTF8),
sampleText, sizeof(sampleText)/sizeof(sampleText[0]), "utf8", fmUTF8Offs ))
log_err("utf8 -> u did not match\n");
/*ISO-2022*/
if(!testConvertToU(expectedISO2022, sizeof(expectedISO2022),
sampleText, sizeof(sampleText)/sizeof(sampleText[0]), "iso-2022", fmISO2022Offs ))
log_err("iso-2022 -> u did not match");
/*UTF16 LE*/
if(!testConvertToU(expectedUTF16LE, sizeof(expectedUTF16LE),
sampleText, sizeof(sampleText)/sizeof(sampleText[0]), "utf-16le", fmUTF16LEOffs ))
log_err("utf-16le -> u did not match");
/*UTF16 BE*/
if(!testConvertToU(expectedUTF16BE, sizeof(expectedUTF16BE),
sampleText, sizeof(sampleText)/sizeof(sampleText[0]), "utf-16be", fmUTF16BEOffs ))
log_err("utf-16be -> u did not match");
/*EBCDIC_STATEFUL*/
if(!testConvertToU(expectedIBM930, sizeof(expectedIBM930),
sampleText, sizeof(sampleText)/sizeof(sampleText[0]), "ibm-930", fmIBM930Offs ))
log_err("ibm-930 -> u did not match");
/*MBCS*/
if(!testConvertToU(expectedIBM943, sizeof(expectedIBM943),
sampleText, sizeof(sampleText)/sizeof(sampleText[0]), "ibm-943", fmIBM943Offs ))
log_err("ibm-943 -> u did not match");
if(!testConvertToU(expectedUTF16LE, sizeof(expectedUTF16LE),
sampleText, sizeof(sampleText)/sizeof(sampleText[0]), "utf-16le", fmUTF16LEOffs ))
log_err("utf-16le -> u did not match");
if(!testConvertToU(expectedMaltese913, sizeof(expectedMaltese913),
malteseUChars, sizeof(malteseUChars)/sizeof(malteseUChars[0]), "latin3", NULL))
log_err("latin3[813] -> u did not match\n");
if(!testConvertFromU(malteseUChars, sizeof(malteseUChars)/sizeof(malteseUChars[0]),
expectedMaltese913, sizeof(expectedMaltese913), "iso-8859-3", NULL ))
log_err("u-> latin3[813] did not match.\n");
/*LMBCS*/
if(!testConvertFromU(LMBCSUChars, sizeof(LMBCSUChars)/sizeof(LMBCSUChars[0]),
expectedLMBCS, sizeof(expectedLMBCS), "LMBCS-1", toLMBCSOffs ))
log_err("u-> LMBCS-1 did not match.\n");
if(!testConvertToU(expectedLMBCS, sizeof(expectedLMBCS),
LMBCSUChars, sizeof(LMBCSUChars)/sizeof(LMBCSUChars[0]), "LMBCS-1", fmLMBCSOffs ))
log_err("LMBCS-1 -> u did not match");
}
void TestConverterTypesAndStarters()
{
UConverter* myConverter[3];
UErrorCode err = U_ZERO_ERROR;
UBool mystarters[256];
const UBool expectedKSCstarters[256] = {
FALSE, FALSE, FALSE, FALSE, FALSE, FALSE, FALSE, FALSE, FALSE, FALSE,
FALSE, FALSE, FALSE, FALSE, FALSE, FALSE, FALSE, FALSE, FALSE, FALSE,
FALSE, FALSE, FALSE, FALSE, FALSE, FALSE, FALSE, FALSE, FALSE, FALSE,
FALSE, FALSE, FALSE, FALSE, FALSE, FALSE, FALSE, FALSE, FALSE, FALSE,
FALSE, FALSE, FALSE, FALSE, FALSE, FALSE, FALSE, FALSE, FALSE, FALSE,
FALSE, FALSE, FALSE, FALSE, FALSE, FALSE, FALSE, FALSE, FALSE, FALSE,
FALSE, FALSE, FALSE, FALSE, FALSE, FALSE, FALSE, FALSE, FALSE, FALSE,
FALSE, FALSE, FALSE, FALSE, FALSE, FALSE, FALSE, FALSE, FALSE, FALSE,
FALSE, FALSE, FALSE, FALSE, FALSE, FALSE, FALSE, FALSE, FALSE, FALSE,
FALSE, FALSE, FALSE, FALSE, FALSE, FALSE, FALSE, FALSE, FALSE, FALSE,
FALSE, FALSE, FALSE, FALSE, FALSE, FALSE, FALSE, FALSE, FALSE, FALSE,
FALSE, FALSE, FALSE, FALSE, FALSE, FALSE, FALSE, FALSE, FALSE, FALSE,
FALSE, FALSE, FALSE, FALSE, FALSE, FALSE, FALSE, FALSE, FALSE, FALSE,
FALSE, FALSE, FALSE, FALSE, FALSE, FALSE, FALSE, FALSE, FALSE, FALSE,
FALSE, FALSE, FALSE, TRUE, TRUE, TRUE, TRUE, TRUE, TRUE, TRUE,
TRUE, TRUE, TRUE, TRUE, TRUE, TRUE, TRUE, TRUE, TRUE, TRUE,
TRUE, TRUE, TRUE, TRUE, TRUE, TRUE, TRUE, TRUE, TRUE, TRUE,
TRUE, TRUE, TRUE, FALSE, FALSE, TRUE, TRUE, TRUE, TRUE, TRUE,
TRUE, TRUE, TRUE, TRUE, TRUE, TRUE, TRUE, TRUE, TRUE, TRUE,
TRUE, TRUE, TRUE, TRUE, TRUE, TRUE, TRUE, TRUE, TRUE, TRUE,
TRUE, TRUE, TRUE, TRUE, TRUE, TRUE, TRUE, TRUE, TRUE, TRUE,
TRUE, TRUE, TRUE, TRUE, TRUE, TRUE, TRUE, TRUE, TRUE, TRUE,
TRUE, TRUE, TRUE, TRUE, TRUE, TRUE, TRUE, TRUE, TRUE, TRUE,
TRUE, TRUE, TRUE, TRUE, TRUE, TRUE, TRUE, TRUE, TRUE, TRUE,
TRUE, TRUE, TRUE, TRUE, TRUE, TRUE, TRUE, TRUE, TRUE, TRUE,
TRUE, TRUE, TRUE, TRUE, TRUE, TRUE};
log_verbose("Testing KSC, ibm-930, ibm-878 for starters and their conversion types.");
myConverter[0] = ucnv_open("ksc", &err);
if (U_FAILURE(err))
log_err("Failed to create an ibm-ksc converter\n");
else
{
if (ucnv_getType(myConverter[0])!=UCNV_MBCS) log_err("ucnv_getType Failed for ibm-949\n");
else log_verbose("ucnv_getType ibm-949 ok\n");
if(myConverter[0]!=NULL)
ucnv_getStarters(myConverter[0], mystarters, &err);
/*if (memcmp(expectedKSCstarters, mystarters, sizeof(expectedKSCstarters)))
log_err("Failed ucnv_getStarters for ksc\n");
else
log_verbose("ucnv_getStarters ok\n");*/
}
myConverter[1] = ucnv_open("ibm-930", &err);
if (U_FAILURE(err))
log_err("Failed to create an ibm-930 converter\n");
else
{
if (ucnv_getType(myConverter[1])!=UCNV_EBCDIC_STATEFUL) log_err("ucnv_getType Failed for ibm-930\n");
else log_verbose("ucnv_getType ibm-930 ok\n");
}
myConverter[2] = ucnv_open("ibm-878", &err);
if (U_FAILURE(err))
log_err("Failed to create an ibm-815 converter\n");
else
{
if (ucnv_getType(myConverter[2])!=UCNV_SBCS) log_err("ucnv_getType Failed for ibm-815\n");
else log_verbose("ucnv_getType ibm-815 ok\n");
}
ucnv_close(myConverter[0]);
ucnv_close(myConverter[1]);
ucnv_close(myConverter[2]);
}
void TestAmbiguous()
{
UErrorCode status = U_ZERO_ERROR;
UConverter *ascii_cnv = 0, *sjis_cnv = 0;
const char target[] = {
/* "\\usr\\local\\share\\data\\icutest.txt" */
0x5c, 0x75, 0x73, 0x72,
0x5c, 0x6c, 0x6f, 0x63, 0x61, 0x6c,
0x5c, 0x73, 0x68, 0x61, 0x72, 0x65,
0x5c, 0x64, 0x61, 0x74, 0x61,
0x5c, 0x69, 0x63, 0x75, 0x74, 0x65, 0x73, 0x74, 0x2e, 0x74, 0x78, 0x74,
0
};
UChar *asciiResult = 0, *sjisResult = 0;
int32_t asciiLength = 0, sjisLength = 0;
sjis_cnv = ucnv_open("SJIS", &status);
if (U_FAILURE(status))
{
log_err("Failed to create a SJIS converter\n");
return;
}
ascii_cnv = ucnv_open("LATIN-1", &status);
if (U_FAILURE(status))
{
log_err("Failed to create a SJIS converter\n");
ucnv_close(sjis_cnv);
return;
}
/* convert target from SJIS to Unicode */
sjisLength = ucnv_toUChars(sjis_cnv, sjisResult, 0, target, strlen(target), &status);
status = U_ZERO_ERROR;
sjisResult = (UChar*)malloc(sizeof(UChar)* sjisLength);
ucnv_toUChars(sjis_cnv, sjisResult, sjisLength, target, strlen(target), &status);
if (U_FAILURE(status))
{
log_err("Failed to convert the SJIS string.\n");
ucnv_close(sjis_cnv);
ucnv_close(ascii_cnv);
return;
}
/* convert target from Latin-1 to Unicode */
asciiLength = ucnv_toUChars(ascii_cnv, asciiResult, 0, target, strlen(target), &status);
status = U_ZERO_ERROR;
asciiResult = (UChar*)malloc(sizeof(UChar)* asciiLength);
ucnv_toUChars(ascii_cnv, asciiResult, asciiLength, target, strlen(target), &status);
if (U_FAILURE(status))
{
log_err("Failed to convert the Latin-1 string.\n");
free(sjisResult);
ucnv_close(sjis_cnv);
ucnv_close(ascii_cnv);
return;
}
if (!ucnv_isAmbiguous(sjis_cnv))
{
log_err("SJIS converter should contain ambiguous character mappings.\n");
free(sjisResult);
free(asciiResult);
ucnv_close(sjis_cnv);
ucnv_close(ascii_cnv);
return;
}
if (u_strcmp(sjisResult, asciiResult) == 0)
{
log_err("File separators for SJIS don't need to be fixed.\n");
}
ucnv_fixFileSeparator(sjis_cnv, sjisResult, sjisLength);
if (u_strcmp(sjisResult, asciiResult) != 0)
{
log_err("Fixing file separator for SJIS failed.\n");
}
free(sjisResult);
free(asciiResult);
ucnv_close(sjis_cnv);
ucnv_close(ascii_cnv);
}
void
TestUTF8() {
/* test input */
static const uint8_t in[]={
0x61,
0xc0, 0x80,
0xe0, 0x80, 0x80,
0xf0, 0x80, 0x80, 0x80,
0xf4, 0x84, 0x8c, 0xa1
};
/* expected test results */
static const uint32_t results[]={
/* number of bytes read, code point */
1, 0x61,
2, 0,
3, 0,
4, 0,
4, 0x104321
};
const char *source=(const char *)in,*limit=(const char *)in+sizeof(in);
UErrorCode errorCode=U_ZERO_ERROR;
UConverter *cnv=ucnv_open("UTF-8", &errorCode);
if(U_FAILURE(errorCode)) {
log_err("Unable to open a UTF-8 converter: %s\n", u_errorName(errorCode));
}
TestNextUChar(cnv, source, limit, results, "UTF-8");
/*Test the condition when source > sourceLimit*/
TestNextUCharError(cnv, source, source, U_INDEX_OUTOFBOUNDS_ERROR, "sourceLimit < source");
ucnv_close(cnv);
}
void
TestUTF16BE() {
/* test input */
static const uint8_t in[]={
0x00, 0x61,
0x00, 0xc0,
0x00, 0x31,
0x00, 0xf4,
0xce, 0xfe,
};
/* expected test results */
static const uint32_t results[]={
/* number of bytes read, code point */
2, 0x61,
2, 0xc0,
2, 0x31,
2, 0xf4,
2, 0xffcefe,
};
const char *source=(const char *)in, *limit=(const char *)in+sizeof(in);
UErrorCode errorCode=U_ZERO_ERROR;
UConverter *cnv=ucnv_open("utf-16be", &errorCode);
if(U_FAILURE(errorCode)) {
log_err("Unable to open a UTF16-BE converter: %s\n", u_errorName(errorCode));
}
TestNextUChar(cnv, source, limit, results, "UTF-16BE");
/*Test the condition when source > sourceLimit*/
TestNextUCharError(cnv, source, source, U_INDEX_OUTOFBOUNDS_ERROR, "sourceLimit < source");
/*Test for the condition where there is an invalid character*/
{
static const uint8_t source2[]={0x61};
TestNextUCharError(cnv, (const char*)source2, (const char*)source2+sizeof(source2), U_TRUNCATED_CHAR_FOUND, "an invalid character");
}
/*Test for the condition where there is a surrogate pair*/
{
/* static const uint8_t source2[]={};
TestNextUCharError(cnv, (const char*)source2, (const char*)source2+sizeof(source2), U_TRUNCATED_CHAR_FOUND, "an invalid character"); */
}
ucnv_close(cnv);
}
void
TestUTF16LE() {
/* test input */
static const uint8_t in[]={
0x61, 0x00,
0x31, 0x00,
0x4e, 0x2e,
0x4e, 0x00,
};
/* expected test results */
static const uint32_t results[]={
/* number of bytes read, code point */
2, 0x61,
2, 0x31,
2, 0x2e4e,
2, 0x4e,
};
const char *source=(const char *)in, *limit=(const char *)in+sizeof(in);
UErrorCode errorCode=U_ZERO_ERROR;
UConverter *cnv=ucnv_open("utf-16le", &errorCode);
if(U_FAILURE(errorCode)) {
log_err("Unable to open a UTF16-LE converter: %s\n", u_errorName(errorCode));
}
TestNextUChar(cnv, source, limit, results, "UTF-16LE");
/*Test the condition when source > sourceLimit*/
TestNextUCharError(cnv, source, source, U_INDEX_OUTOFBOUNDS_ERROR, "sourceLimit < source");
/*Test for the condition where there is an invalid character*/
{
static const uint8_t source2[]={0x61};
TestNextUCharError(cnv, (const char*)source2, (const char*)source2+sizeof(source2), U_TRUNCATED_CHAR_FOUND, "an invalid character");
}
ucnv_close(cnv);
}
void
TestLATIN1() {
/* test input */
static const uint8_t in[]={
0x61,
0x31,
0x32,
0xc0,
0xf0,
0xf4,
};
/* expected test results */
static const uint32_t results[]={
/* number of bytes read, code point */
1, 0x61,
1, 0x31,
1, 0x32,
1, 0xc0,
1, 0xf0,
1, 0xf4,
};
const char *source=(const char *)in;
const char *limit=(const char *)in+sizeof(in);
UErrorCode errorCode=U_ZERO_ERROR;
UConverter *cnv=ucnv_open("LATIN_1", &errorCode);
if(U_FAILURE(errorCode)) {
log_err("Unable to open a LATIN_1 converter: %s\n", u_errorName(errorCode));
}
TestNextUChar(cnv, source, limit, results, "LATIN_1");
/*Test the condition when source > sourceLimit*/
TestNextUCharError(cnv, source, source, U_INDEX_OUTOFBOUNDS_ERROR, "sourceLimit < source");
ucnv_close(cnv);
}
void
TestSBCS() {
/* test input */
static const uint8_t in[]={ 0x61, 0xc0, 0x80, 0xe0, 0xf0, 0xf4};
/* expected test results */
static const uint32_t results[]={
/* number of bytes read, code point */
1, 0x61,
1, 0xbf,
1, 0xc4,
1, 0x2021,
1, 0xf8fe,
1, 0x00d9
};
const char *source=(const char *)in, *limit=(const char *)in+sizeof(in);
UErrorCode errorCode=U_ZERO_ERROR;
UConverter *cnv=ucnv_open("ibm-1281", &errorCode);
if(U_FAILURE(errorCode)) {
log_err("Unable to open a SBCS(ibm-1281) converter: %s\n", u_errorName(errorCode));
}
TestNextUChar(cnv, source, limit, results, "SBCS(ibm-1281)");
/*Test the condition when source > sourceLimit*/
TestNextUCharError(cnv, source, source, U_INDEX_OUTOFBOUNDS_ERROR, "sourceLimit < source");
/*Test for Illegal character*//*
{
static const uint8_t input1[]={ 0xA1 };
const char* illegalsource=(const char*)input1;
TestNextUCharError(cnv, illegalsource, illegalsource+sizeof(illegalsource), U_INVALID_CHAR_FOUND, "source has a illegal characte");
}
*/
ucnv_close(cnv);
}
void
TestDBCS() {
/* test input */
static const uint8_t in[]={
0x44, 0x6a,
0xc4, 0x9c,
0x7a, 0x74,
0x46, 0xab,
0x42, 0x5b,
};
/* expected test results */
static const uint32_t results[]={
/* number of bytes read, code point */
2, 0x00a7,
2, 0xe1d2,
2, 0x6962,
2, 0xf842,
2, 0xffe5,
};
const char *source=(const char *)in, *limit=(const char *)in+sizeof(in);
UErrorCode errorCode=U_ZERO_ERROR;
UConverter *cnv=ucnv_open("ibm-9027", &errorCode);
if(U_FAILURE(errorCode)) {
log_err("Unable to open a DBCS(ibm-9027) converter: %s\n", u_errorName(errorCode));
}
TestNextUChar(cnv, source, limit, results, "DBCS(ibm-9027)");
/*Test the condition when source > sourceLimit*/
TestNextUCharError(cnv, source, source, U_INDEX_OUTOFBOUNDS_ERROR, "sourceLimit < source");
/*Test for the condition where we have a truncated char*/
{
static const uint8_t source1[]={0xc4};
TestNextUCharError(cnv, (const char*)source1, (const char*)source1+sizeof(source1), U_TRUNCATED_CHAR_FOUND, "a character is truncated");
}
/*Test for the condition where there is an invalid character*/
{
static const uint8_t source2[]={0x1a, 0x1b};
TestNextUCharError(cnv, (const char*)source2, (const char*)source2+sizeof(source2), U_ZERO_ERROR, "an invalid character");
}
ucnv_close(cnv);
}
void
TestMBCS() {
/* test input */
static const uint8_t in[]={
0x01,
0xa6, 0xa3,
0x00,
0xa6, 0xa1,
0x08,
0xc2, 0x76,
0xc2, 0x78,
};
/* expected test results */
static const uint32_t results[]={
/* number of bytes read, code point */
1, 0x0001,
2, 0x250c,
1, 0x0000,
2, 0x2500,
1, 0x0008,
2, 0xd60c,
2, 0xd60e
};
const char *source=(const char *)in, *limit=(const char *)in+sizeof(in);
UErrorCode errorCode=U_ZERO_ERROR;
UConverter *cnv=ucnv_open("ibm-1363", &errorCode);
if(U_FAILURE(errorCode)) {
log_err("Unable to open a MBCS(ibm-1363) converter: %s\n", u_errorName(errorCode));
}
TestNextUChar(cnv, source, limit, results, "MBCS(ibm-1363)");
/*Test the condition when source > sourceLimit*/
TestNextUCharError(cnv, source, source, U_INDEX_OUTOFBOUNDS_ERROR, "sourceLimit < source");
/*Test for the condition where we have a truncated char*/
{
static const uint8_t source1[]={0xc4};
TestNextUCharError(cnv, (const char*)source1, (const char*)source1+sizeof(source1), U_TRUNCATED_CHAR_FOUND, "a character is truncated");
}
/*Test for the condition where there is an invalid character*/
{
static const uint8_t source2[]={0xa1, 0x01};
TestNextUCharError(cnv, (const char*)source2, (const char*)source2+sizeof(source2), U_ZERO_ERROR, "an invalid character");
}
ucnv_close(cnv);
}
void
TestISO_2022() {
/* test input */
static const uint8_t in[]={
0x1b, 0x25, 0x42, 0x31,
0x32,
0x61,
0xc0, 0x80,
0xe0, 0x80, 0x80,
0xf0, 0x80, 0x80, 0x80
};
/* expected test results */
static const uint32_t results[]={
/* number of bytes read, code point */
4, 0x0031,
1, 0x0032,
1, 0x61,
2, 0,
3, 0,
4, 0,
};
const char *source=(const char *)in, *limit=(const char *)in+sizeof(in);
UErrorCode errorCode=U_ZERO_ERROR;
UConverter *cnv=ucnv_open("iso-2022", &errorCode);
if(U_FAILURE(errorCode)) {
log_err("Unable to open a iso-2022 converter: %s\n", u_errorName(errorCode));
}
TestNextUChar(cnv, source, limit, results, "iso-2022");
/*Test the condition when source > sourceLimit*/
TestNextUCharError(cnv, source, source-1, U_ILLEGAL_ARGUMENT_ERROR, "sourceLimit < source");
TestNextUCharError(cnv, source, source, U_INDEX_OUTOFBOUNDS_ERROR, "sourceLimit < source");
/*Test for the condition where we have a truncated char*/
{
static const uint8_t source1[]={0xc4};
TestNextUCharError(cnv, (const char*)source1, (const char*)source1+sizeof(source1), U_TRUNCATED_CHAR_FOUND, "a character is truncated");
}
/*Test for the condition where there is an invalid character*/
{
static const uint8_t source2[]={0xa1, 0x01};
TestNextUCharError(cnv, (const char*)source2, (const char*)source2+sizeof(source2), U_ZERO_ERROR, "an invalid character");
}
ucnv_close(cnv);
}
void
TestEBCDIC_STATEFUL() {
/* test input */
static const uint8_t in[]={
0x61,
0x1a,
0x0f, 0x4b,
0x42,
0x40,
0x36,
};
/* expected test results */
static const uint32_t results[]={
/* number of bytes read, code point */
1, 0x002f,
1, 0x0092,
2, 0x002e,
1, 0xff62,
1, 0x0020,
1, 0x0096,
};
const char *source=(const char *)in, *limit=(const char *)in+sizeof(in);
UErrorCode errorCode=U_ZERO_ERROR;
UConverter *cnv=ucnv_open("ibm-930", &errorCode);
if(U_FAILURE(errorCode)) {
log_err("Unable to open a EBCDIC_STATEFUL(ibm-930) converter: %s\n", u_errorName(errorCode));
}
TestNextUChar(cnv, source, limit, results, "EBCDIC_STATEFUL(ibm-930)");
/*Test the condition when source > sourceLimit*/
TestNextUCharError(cnv, source, source, U_INDEX_OUTOFBOUNDS_ERROR, "sourceLimit < source");
/*Test for the condition where source > sourcelimit after consuming the shift chracter */
{
static const uint8_t source1[]={0x0f};
TestNextUCharError(cnv, (const char*)source1, (const char*)source1+sizeof(source1), U_INDEX_OUTOFBOUNDS_ERROR, "a character is truncated");
}
/*Test for the condition where there is an invalid character*/
{
static const uint8_t source2[]={0x0f, 0xa1, 0x01};
TestNextUCharError(cnv, (const char*)source2, (const char*)source2+sizeof(source2), U_ZERO_ERROR, "an invalid character");
}
ucnv_close(cnv);
}
void
TestLMBCS() {
/* LMBCS-1 string */
static const uint8_t pszLMBCS[]={
0x61,
0x01, 0x29,
0x81,
0xA0,
0x0F, 0x27,
0x0F, 0x91,
0x14, 0x0a, 0x74,
0x14, 0xF6, 0x02,
0x14, 0xd8, 0x4d, 0x14, 0xdc, 0x56, /* UTF-16 surrogate pair */
0x10, 0x88, 0xA0,
};
/* Unicode UChar32 equivalents */
static const UChar32 pszUnicode32[]={
/* code point */
0x00000061,
0x00002013,
0x000000FC,
0x000000E1,
0x00000007,
0x00000091,
0x00000a74,
0x00000200,
0x00023456, /* code point for surrogate pair */
0x00005516
};
/* Unicode UChar equivalents */
static const UChar pszUnicode[]={
/* code point */
0x0061,
0x2013,
0x00FC,
0x00E1,
0x0007,
0x0091,
0x0a74,
0x0200,
0xD84D, /* low surrogate */
0xDC56, /* high surrogate */
0x5516
};
/* expected test results */
static const int offsets32[]={
/* number of bytes read, code point */
0,
1,
3,
4,
5,
7,
9,
12,
15,
21,
24
};
/* expected test results */
static const int offsets[]={
/* number of bytes read, code point */
0,
1,
3,
4,
5,
7,
9,
12,
15,
18,
21,
24
};
UConverter *cnv;
#define NAME_LMBCS_1 "LMBCS-1"
#define NAME_LMBCS_2 "LMBCS-2"
/* Some basic open/close/property tests on some LMBCS converters */
{
char expected_subchars[] = {0x3F}; /* ANSI Question Mark */
char new_subchars [] = {0x7F}; /* subst char used by SmartSuite..*/
char get_subchars [1];
const char * get_name;
UConverter *cnv1;
UConverter *cnv2;
int8_t len = sizeof(get_subchars);
UErrorCode errorCode=U_ZERO_ERROR;
/* Open */
cnv1=ucnv_open(NAME_LMBCS_1, &errorCode);
if(U_FAILURE(errorCode)) {
log_err("Unable to open a LMBCS-1 converter: %s\n", u_errorName(errorCode));
}
cnv2=ucnv_open(NAME_LMBCS_2, &errorCode);
if(U_FAILURE(errorCode)) {
log_err("Unable to open a LMBCS-2 converter: %s\n", u_errorName(errorCode));
}
/* Name */
get_name = ucnv_getName (cnv1, &errorCode);
if (strcmp(NAME_LMBCS_1,get_name)){
log_err("Unexpected converter name: %s\n", get_name);
}
get_name = ucnv_getName (cnv2, &errorCode);
if (strcmp(NAME_LMBCS_2,get_name)){
log_err("Unexpected converter name: %s\n", get_name);
}
/* substitution chars */
ucnv_getSubstChars (cnv1, get_subchars, &len, &errorCode);
if(U_FAILURE(errorCode)) {
log_err("Failure on get subst chars: %s\n", u_errorName(errorCode));
}
if (len!=1){
log_err("Unexpected length of sub chars\n");
}
if (get_subchars[0] != expected_subchars[0]){
log_err("Unexpected value of sub chars\n");
}
ucnv_setSubstChars (cnv2,new_subchars, len, &errorCode);
if(U_FAILURE(errorCode)) {
log_err("Failure on set subst chars: %s\n", u_errorName(errorCode));
}
ucnv_getSubstChars (cnv2, get_subchars, &len, &errorCode);
if(U_FAILURE(errorCode)) {
log_err("Failure on get subst chars: %s\n", u_errorName(errorCode));
}
if (len!=1){
log_err("Unexpected length of sub chars\n");
}
if (get_subchars[0] != new_subchars[0]){
log_err("Unexpected value of sub chars\n");
}
ucnv_close(cnv1);
ucnv_close(cnv2);
}
/* LMBCS to Unicode - offsets */
{
UErrorCode errorCode=U_ZERO_ERROR;
const char * pSource = pszLMBCS;
const char * sourceLimit = pszLMBCS + sizeof(pszLMBCS);
UChar Out [sizeof(pszUnicode)];
UChar * pOut = Out;
UChar * OutLimit = Out + sizeof(Out);
int off [sizeof(offsets)];
/* last 'offset' in expected results is just the final size.
(Makes other tests easier). Compensate here: */
off[(sizeof(offsets)/sizeof(offsets[0]))-1] = sizeof(pszLMBCS);
cnv=ucnv_open("lmbcs", &errorCode); /* use generic name for LMBCS-1 */
if(U_FAILURE(errorCode)) {
log_err("Unable to open a LMBCS converter: %s\n", u_errorName(errorCode));
}
ucnv_toUnicode (cnv,
&pOut,
OutLimit,
&pSource,
sourceLimit,
off,
TRUE,
&errorCode);
if (memcmp(off,offsets,sizeof(offsets)))
{
log_err("LMBCS->Uni: Calculated offsets do not match expected results\n");
}
if (memcmp(Out,pszUnicode,sizeof(pszUnicode)))
{
log_err("LMBCS->Uni: Calculated codepoints do not match expected results\n");
}
ucnv_close(cnv);
}
{
/* LMBCS to Unicode - getNextUChar */
const char * sourceStart;
const char *source=(const char *)pszLMBCS;
const char *limit=(const char *)pszLMBCS+sizeof(pszLMBCS);
const uint32_t *results= pszUnicode32;
const int *off = offsets32;
UErrorCode errorCode=U_ZERO_ERROR;
uint32_t uniChar;
cnv=ucnv_open("LMBCS-1", &errorCode);
if(U_FAILURE(errorCode)) {
log_err("Unable to open a LMBCS-1 converter: %s\n", u_errorName(errorCode));
}
else
{
while(source<limit) {
sourceStart=source;
uniChar=ucnv_getNextUChar(cnv, &source, source + (off[1] - off[0]), &errorCode);
if(U_FAILURE(errorCode)) {
log_err("LMBCS-1 ucnv_getNextUChar() failed: %s\n", u_errorName(errorCode));
break;
} else if(source-sourceStart != off[1] - off[0] || uniChar != *results) {
log_err("LMBCS-1 ucnv_getNextUChar() result %lx from %d bytes, should have been %lx from %d bytes.\n",
uniChar, (source-sourceStart), *results, *off);
break;
}
results++;
off++;
}
}
ucnv_close(cnv);
}
{ /* test locale & optimization group operations: Unicode to LMBCS */
UErrorCode errorCode=U_ZERO_ERROR;
UConverter *cnv16he = ucnv_open("LMBCS-16,locale=he", &errorCode);
UConverter *cnv16jp = ucnv_open("LMBCS-16,locale=ja_JP", &errorCode);
UConverter *cnv01us = ucnv_open("LMBCS-1,locale=us_EN", &errorCode);
UChar uniString [] = {0x0192}; /* Latin Small letter f with hook */
UChar * pUni = uniString;
char lmbcsString [4];
char * pLMBCS = lmbcsString;
/* 0192 (hook) converts to both group 3 & group 1. input locale should differentiate */
ucnv_fromUnicode (cnv16he,
&pLMBCS, pLMBCS + sizeof(lmbcsString)/sizeof(lmbcsString[0]),
&pUni, pUni + sizeof(uniString)/sizeof(uniString[0]),
NULL, 1, &errorCode);
if (lmbcsString[0] != (char)0x3 || lmbcsString[1] != (char)0x83)
{
log_err("LMBCS-16,locale=he gives unexpected translation\n");
}
pLMBCS=lmbcsString;
pUni = uniString;
ucnv_fromUnicode (cnv01us,
&pLMBCS, lmbcsString + sizeof(lmbcsString)/sizeof(lmbcsString[0]),
&pUni, pUni + sizeof(uniString)/sizeof(uniString[0]),
NULL, 1, &errorCode);
if (lmbcsString[0] != (char)0x9F)
{
log_err("LMBCS-1,locale=US gives unexpected translation\n");
}
/* single byte char from mbcs char set */
lmbcsString[0] = (char)0xAE; /* 1/2 width katakana letter small Yo */
pLMBCS = lmbcsString;
pUni = uniString;
ucnv_toUnicode (cnv16jp,
&pUni, pUni + 1,
&pLMBCS, pLMBCS + 1,
NULL, 1, &errorCode);
if (U_FAILURE(errorCode) || pLMBCS != lmbcsString+1 || pUni != uniString+1 || uniString[0] != 0xFF6E)
{
log_err("Unexpected results from LMBCS-16 single byte char\n");
}
/* convert to group 1: should be 3 bytes */
pLMBCS = lmbcsString;
pUni = uniString;
ucnv_fromUnicode (cnv01us,
&pLMBCS, pLMBCS + 3,
&pUni, pUni + 1,
NULL, 1, &errorCode);
if (U_FAILURE(errorCode) || pLMBCS != lmbcsString+3 || pUni != uniString+1
|| lmbcsString[0] != 0x10 || lmbcsString[1] != 0x10 || lmbcsString[2] != (char)0xAE)
{
log_err("Unexpected results to LMBCS-1 single byte mbcs char\n");
}
pLMBCS = lmbcsString;
pUni = uniString;
ucnv_toUnicode (cnv01us,
&pUni, pUni + 1,
&pLMBCS, pLMBCS + 3,
NULL, 1, &errorCode);
if (U_FAILURE(errorCode) || pLMBCS != lmbcsString+3 || pUni != uniString+1 || uniString[0] != 0xFF6E)
{
log_err("Unexpected results from LMBCS-1 single byte mbcs char\n");
}
pLMBCS = lmbcsString;
pUni = uniString;
ucnv_fromUnicode (cnv16jp,
&pLMBCS, pLMBCS + 1,
&pUni, pUni + 1,
NULL, 1, &errorCode);
if (U_FAILURE(errorCode) || pLMBCS != lmbcsString+1 || pUni != uniString+1 || lmbcsString[0] != (char)0xAE)
{
log_err("Unexpected results to LMBCS-16 single byte mbcs char\n");
}
ucnv_close(cnv16he);
ucnv_close(cnv16jp);
ucnv_close(cnv01us);
}
{
/* Small source buffer testing, LMBCS -> Unicode */
UErrorCode errorCode=U_ZERO_ERROR;
const char * pSource = pszLMBCS;
const char * sourceLimit = pszLMBCS + sizeof(pszLMBCS);
int codepointCount = 0;
UChar Out [sizeof(pszUnicode)];
UChar * pOut = Out;
UChar * OutLimit = Out + sizeof(Out);
cnv = ucnv_open(NAME_LMBCS_1, &errorCode);
if(U_FAILURE(errorCode)) {
log_err("Unable to open a LMBCS-1 converter: %s\n", u_errorName(errorCode));
}
while ((pSource < sourceLimit) && U_SUCCESS (errorCode))
{
ucnv_toUnicode (cnv,
&pOut,
OutLimit,
&pSource,
pSource+1, /* claim that this is a 1- byte buffer */
NULL,
FALSE, /* FALSE means there might be more chars in the next buffer */
&errorCode);
if (U_SUCCESS (errorCode))
{
if ((pSource - (const char *)pszLMBCS) == offsets [codepointCount+1])
{
/* we are on to the next code point: check value */
if (Out[0] != pszUnicode[codepointCount]){
log_err("LMBCS->Uni result %lx should have been %lx \n",
Out[0], pszUnicode[codepointCount]);
}
pOut = Out; /* reset for accumulating next code point */
codepointCount++;
}
}
else
{
log_err("Unexpected Error on toUnicode: %s\n", u_errorName(errorCode));
}
}
{
/* limits & surrogate error testing */
UErrorCode errorCode=U_ZERO_ERROR;
char LIn [sizeof(pszLMBCS)];
const char * pLIn = LIn;
char LOut [sizeof(pszLMBCS)];
char * pLOut = LOut;
UChar UOut [sizeof(pszUnicode)];
UChar * pUOut = UOut;
UChar UIn [sizeof(pszUnicode)];
const UChar * pUIn = UIn;
int off [sizeof(offsets)];
UChar32 uniChar;
/* negative source request should always return U_ILLEGAL_ARGUMENT_ERROR */
ucnv_fromUnicode(cnv, &pLOut,pLOut+1,&pUIn,pUIn-1,off,FALSE, &errorCode);
if (errorCode != U_ILLEGAL_ARGUMENT_ERROR)
{
log_err("Unexpected Error on negative source request to ucnv_fromUnicode: %s\n", u_errorName(errorCode));
}
errorCode=U_ZERO_ERROR;
ucnv_toUnicode(cnv, &pUOut,pUOut+1,&pLIn,pLIn-1,off,FALSE, &errorCode);
if (errorCode != U_ILLEGAL_ARGUMENT_ERROR)
{
log_err("Unexpected Error on negative source request to ucnv_toUnicode: %s\n", u_errorName(errorCode));
}
errorCode=U_ZERO_ERROR;
uniChar = ucnv_getNextUChar(cnv, &pLIn, pLIn-1, &errorCode);
if (errorCode != U_ILLEGAL_ARGUMENT_ERROR)
{
log_err("Unexpected Error on negative source request to ucnv_getNextUChar: %s\n", u_errorName(errorCode));
}
errorCode=U_ZERO_ERROR;
/* 0 byte source request - no error, no pointer movement */
ucnv_toUnicode(cnv, &pUOut,pUOut+1,&pLIn,pLIn,off,FALSE, &errorCode);
ucnv_fromUnicode(cnv, &pLOut,pLOut+1,&pUIn,pUIn,off,FALSE, &errorCode);
if(U_FAILURE(errorCode)) {
log_err("0 byte source request: unexpected error: %s\n", u_errorName(errorCode));
}
if ((pUOut != UOut) || (pUIn != UIn) || (pLOut != LOut) || (pLIn != LIn))
{
log_err("Unexpected pointer move in 0 byte source request \n");
}
/*0 byte source request - GetNextUChar : error & value == FFFD */
uniChar = ucnv_getNextUChar(cnv, &pLIn, pLIn, &errorCode);
if (errorCode != U_ILLEGAL_ARGUMENT_ERROR)
{
log_err("Unexpected Error on 0-byte source request to ucnv_getnextUChar: %s\n", u_errorName(errorCode));
}
if (uniChar != 0xFFFD) /* would like to use an exported define here */
{
log_err("Unexpected value on 0-byte source request to ucnv_getnextUChar \n");
}
errorCode = 0;
/* running out of target room : U_INDEX_OUTOFBOUNDS_ERROR*/
pUIn = pszUnicode;
ucnv_fromUnicode(cnv, &pLOut,pLOut+offsets[4],&pUIn,pUIn+sizeof(pszUnicode),off,FALSE, &errorCode);
if (errorCode != U_INDEX_OUTOFBOUNDS_ERROR || pLOut != LOut + offsets[4] || pUIn != pszUnicode+4 )
{
log_err("Unexpected results on out of target room to ucnv_fromUnicode\n");
}
errorCode = 0;
pLIn = pszLMBCS;
ucnv_toUnicode(cnv, &pUOut,pUOut+4,&pLIn,pLIn+sizeof(pszLMBCS),off,FALSE, &errorCode);
if (errorCode != U_INDEX_OUTOFBOUNDS_ERROR || pUOut != UOut + 4 || pLIn != pszLMBCS+offsets[4])
{
log_err("Unexpected results on out of target room to ucnv_toUnicode\n");
}
/* unpaired or chopped LMBCS surrogates */
/* OK high surrogate, Low surrogate is chopped */
LIn [0] = 0x14;
LIn [1] = (char)0xD8;
LIn [2] = 0x01;
LIn [3] = 0x14;
LIn [4] = (char)0xDC;
pLIn = LIn;
errorCode = 0;
pUOut = UOut;
ucnv_toUnicode(cnv, &pUOut,pUOut+sizeof(UOut),&pLIn,pLIn+5,off,TRUE, &errorCode);
if (UOut[0] != 0xD801 || errorCode != U_TRUNCATED_CHAR_FOUND || pUOut != UOut + 1 || pLIn != LIn + 3)
{
log_err("Unexpected results on chopped low surrogate\n");
}
/* chopped at surrogate boundary */
LIn [0] = 0x14;
LIn [1] = (char)0xD8;
LIn [2] = 0x01;
pLIn = LIn;
errorCode = 0;
pUOut = UOut;
ucnv_toUnicode(cnv, &pUOut,pUOut+sizeof(UOut),&pLIn,pLIn+3,off,TRUE, &errorCode);
if (UOut[0] != 0xD801 || U_FAILURE(errorCode) || pUOut != UOut + 1 || pLIn != LIn + 3)
{
log_err("Unexpected results on chopped at surrogate boundary \n");
}
/* unpaired surrogate plus valid Unichar */
LIn [0] = 0x14;
LIn [1] = (char)0xD8;
LIn [2] = 0x01;
LIn [3] = 0x14;
LIn [4] = (char)0xC9;
LIn [5] = (char)0xD0;
pLIn = LIn;
errorCode = 0;
pUOut = UOut;
ucnv_toUnicode(cnv, &pUOut,pUOut+sizeof(UOut),&pLIn,pLIn+6,off,TRUE, &errorCode);
if (UOut[0] != 0xD801 || UOut[1] != 0xC9D0 || U_FAILURE(errorCode) || pUOut != UOut + 2 || pLIn != LIn + 6)
{
log_err("Unexpected results after unpaired surrogate plus valid Unichar \n");
}
/* unpaired surrogate plus chopped Unichar */
LIn [0] = 0x14;
LIn [1] = (char)0xD8;
LIn [2] = 0x01;
LIn [3] = 0x14;
LIn [4] = (char)0xC9;
pLIn = LIn;
errorCode = 0;
pUOut = UOut;
ucnv_toUnicode(cnv, &pUOut,pUOut+sizeof(UOut),&pLIn,pLIn+5,off,TRUE, &errorCode);
if (UOut[0] != 0xD801 || errorCode != U_TRUNCATED_CHAR_FOUND || pUOut != UOut + 1 || pLIn != LIn + 3)
{
log_err("Unexpected results after unpaired surrogate plus chopped Unichar \n");
}
/* unpaired surrogate plus valid non-Unichar */
LIn [0] = 0x14;
LIn [1] = (char)0xD8;
LIn [2] = 0x01;
LIn [3] = 0x0F;
LIn [4] = 0x3B;
pLIn = LIn;
errorCode = 0;
pUOut = UOut;
ucnv_toUnicode(cnv, &pUOut,pUOut+sizeof(UOut),&pLIn,pLIn+5,off,TRUE, &errorCode);
if (UOut[0] != 0xD801 || UOut[1] != 0x1B || U_FAILURE(errorCode) || pUOut != UOut + 2 || pLIn != LIn + 5)
{
log_err("Unexpected results after unpaired surrogate plus valid non-Unichar\n");
}
/* unpaired surrogate plus chopped non-Unichar */
LIn [0] = 0x14;
LIn [1] = (char)0xD8;
LIn [2] = 0x01;
LIn [3] = 0x0F;
pLIn = LIn;
errorCode = 0;
pUOut = UOut;
ucnv_toUnicode(cnv, &pUOut,pUOut+sizeof(UOut),&pLIn,pLIn+4,off,TRUE, &errorCode);
if (UOut[0] != 0xD801 || errorCode != U_TRUNCATED_CHAR_FOUND || pUOut != UOut + 1 || pLIn != LIn + 3)
{
log_err("Unexpected results after unpaired surrogate plus chopped non-Unichar\n");
}
}
}
ucnv_close(cnv); /* final cleanup */
}
void TestJitterbug255()
{
const char testBytes[] = { (char)0x95, (char)0xcf, (char)0x8a,
(char)0xb7, (char)0x0d, (char)0x0a, 0x0000 };
const char *testBuffer = testBytes, *testEnd = testBytes+strlen(testBytes)+1;
UErrorCode status = U_ZERO_ERROR;
UChar32 result;
UConverter *cnv = 0;
cnv = ucnv_open("shift-jis", &status);
if (U_FAILURE(status) || cnv == 0) {
log_err("Failed to open the converter for SJIS.\n");
return;
}
while (testBuffer != testEnd)
{
result = ucnv_getNextUChar (cnv, (const char **)&testBuffer, testEnd , &status);
if (U_FAILURE(status))
{
log_err("Failed to convert the next UChar for SJIS.\n");
break;
}
}
ucnv_close(cnv);
}
void TestEBCDICUS4XML()
{
UChar unicodes_x[] = {0x0000, 0x0000, 0x0000, 0x0000};
const UChar toUnicodeMaps_x[] = {0x000A, 0x000A, 0x000D, 0x0000};
const char fromUnicodeMaps_x[] = {0x25, 0x25, 0x0D, 0x00};
const char newLines_x[] = {0x25, 0x15, 0x0D, 0x00};
char target_x[] = {0x00, 0x00, 0x00, 0x00};
UChar *unicodes = unicodes_x;
const UChar *toUnicodeMaps = toUnicodeMaps_x;
char *target = target_x;
const char* fromUnicodeMaps = fromUnicodeMaps_x, *newLines = newLines_x;
UErrorCode status = U_ZERO_ERROR;
UConverter *cnv = 0;
cnv = ucnv_open("ebcdic-xml-us", &status);
if (U_FAILURE(status) || cnv == 0) {
log_err("Failed to open the converter for EBCDIC-XML-US.\n");
return;
}
ucnv_toUnicode(cnv, &unicodes, unicodes+3, (const char**)&newLines, newLines+3, NULL, TRUE, &status);
if (U_FAILURE(status) || memcmp(unicodes_x, toUnicodeMaps, sizeof(UChar)*3) != 0) {
log_err("To Unicode conversion failed in EBCDICUS4XML test.\n");
}
ucnv_fromUnicode(cnv, &target, target+3, (const UChar**)&toUnicodeMaps, toUnicodeMaps+3, NULL, TRUE, &status);
if (U_FAILURE(status) || memcmp(target_x, fromUnicodeMaps, sizeof(char)*3) != 0) {
log_err("From Unicode conversion failed in EBCDICUS4XML test.\n");
}
ucnv_close(cnv);
}
#endif