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 /*

 **********************************************************************

 *   Copyright (C) 2010-2012, International Business Machines

 *   Corporation and others.  All Rights Reserved.

 **********************************************************************

 *   file name:  ucnv_ct.c

 *   encoding:   US-ASCII

 *   tab size:   8 (not used)

 *   indentation:4

 *

 *   created on: 2010Dec09

 *   created by: Michael Ow

 */

 #include "unicode/utypes.h"

 #if !UCONFIG_NO_CONVERSION && !UCONFIG_NO_LEGACY_CONVERSION

 #include "unicode/ucnv.h"

 #include "unicode/uset.h"

 #include "unicode/ucnv_err.h"

 #include "unicode/ucnv_cb.h"

 #include "unicode/utf16.h"

 #include "ucnv_imp.h"

 #include "ucnv_bld.h"

 #include "ucnv_cnv.h"

 #include "ucnvmbcs.h"

 #include "cstring.h"

 #include "cmemory.h"

 #define LENGTHOF(array) (int32_t)(sizeof(array)/sizeof((array)[0]))

 typedef enum {

     INVALID = -2,

     DO_SEARCH = -1,

     COMPOUND_TEXT_SINGLE_0 = 0,

     COMPOUND_TEXT_SINGLE_1 = 1,

     COMPOUND_TEXT_SINGLE_2 = 2,

     COMPOUND_TEXT_SINGLE_3 = 3,

     COMPOUND_TEXT_DOUBLE_1 = 4,

     COMPOUND_TEXT_DOUBLE_2 = 5,

     COMPOUND_TEXT_DOUBLE_3 = 6,

     COMPOUND_TEXT_DOUBLE_4 = 7,

     COMPOUND_TEXT_DOUBLE_5 = 8,

     COMPOUND_TEXT_DOUBLE_6 = 9,

     COMPOUND_TEXT_DOUBLE_7 = 10,

     COMPOUND_TEXT_TRIPLE_DOUBLE = 11,

     IBM_915 = 12,

     IBM_916 = 13,

     IBM_914 = 14,

     IBM_874 = 15,

     IBM_912 = 16,

     IBM_913 = 17,

     ISO_8859_14 = 18,

     IBM_923 = 19,

     NUM_OF_CONVERTERS = 20

 } COMPOUND_TEXT_CONVERTERS;

 #define SEARCH_LENGTH 12

 static const uint8_t escSeqCompoundText[NUM_OF_CONVERTERS][5] = {

     /* Single */

     { 0x1B, 0x2D, 0x41, 0, 0 },

     { 0x1B, 0x2D, 0x4D, 0, 0 },

     { 0x1B, 0x2D, 0x46, 0, 0 },

     { 0x1B, 0x2D, 0x47, 0, 0 },

     /* Double */

     { 0x1B, 0x24, 0x29, 0x41, 0 },

     { 0x1B, 0x24, 0x29, 0x42, 0 },

     { 0x1B, 0x24, 0x29, 0x43, 0 },

     { 0x1B, 0x24, 0x29, 0x44, 0 },

     { 0x1B, 0x24, 0x29, 0x47, 0 },

     { 0x1B, 0x24, 0x29, 0x48, 0 },

     { 0x1B, 0x24, 0x29, 0x49, 0 },

     /* Triple/Double */

     { 0x1B, 0x25, 0x47, 0, 0 },

     /*IBM-915*/

     { 0x1B, 0x2D, 0x4C, 0, 0 },

     /*IBM-916*/

     { 0x1B, 0x2D, 0x48, 0, 0 },

     /*IBM-914*/

     { 0x1B, 0x2D, 0x44, 0, 0 },

     /*IBM-874*/

     { 0x1B, 0x2D, 0x54, 0, 0 },

     /*IBM-912*/

     { 0x1B, 0x2D, 0x42, 0, 0 },

     /* IBM-913 */

     { 0x1B, 0x2D, 0x43, 0, 0 },

     /* ISO-8859_14 */

     { 0x1B, 0x2D, 0x5F, 0, 0 },

     /* IBM-923 */

     { 0x1B, 0x2D, 0x62, 0, 0 },

 };

 #define ESC_START 0x1B

 #define isASCIIRange(codepoint) \

         ((codepoint == 0x0000) || (codepoint == 0x0009) || (codepoint == 0x000A) || \

          (codepoint >= 0x0020 && codepoint <= 0x007f) || (codepoint >= 0x00A0 && codepoint <= 0x00FF))

 #define isIBM915(codepoint) \

         ((codepoint >= 0x0401 && codepoint <= 0x045F) || (codepoint == 0x2116))

 #define isIBM916(codepoint) \

         ((codepoint >= 0x05D0 && codepoint <= 0x05EA) || (codepoint == 0x2017) || (codepoint == 0x203E))

 #define isCompoundS3(codepoint) \

         ((codepoint == 0x060C) || (codepoint == 0x061B) || (codepoint == 0x061F) || (codepoint >= 0x0621 && codepoint <= 0x063A) || \

          (codepoint >= 0x0640 && codepoint <= 0x0652) || (codepoint >= 0x0660 && codepoint <= 0x066D) || (codepoint == 0x200B) || \

          (codepoint >= 0x0FE70 && codepoint <= 0x0FE72) || (codepoint == 0x0FE74) || (codepoint >= 0x0FE76 && codepoint <= 0x0FEBE))

 #define isCompoundS2(codepoint) \

         ((codepoint == 0x02BC) || (codepoint == 0x02BD) || (codepoint >= 0x0384 && codepoint <= 0x03CE) || (codepoint == 0x2015))

 #define isIBM914(codepoint) \

         ((codepoint == 0x0100) || (codepoint == 0x0101) || (codepoint == 0x0112) || (codepoint == 0x0113) || (codepoint == 0x0116) || (codepoint == 0x0117) || \

          (codepoint == 0x0122) || (codepoint == 0x0123) || (codepoint >= 0x0128 && codepoint <= 0x012B) || (codepoint == 0x012E) || (codepoint == 0x012F) || \

          (codepoint >= 0x0136 && codepoint <= 0x0138) || (codepoint == 0x013B) || (codepoint == 0x013C) || (codepoint == 0x0145) || (codepoint ==  0x0146) || \

          (codepoint >= 0x014A && codepoint <= 0x014D) || (codepoint == 0x0156) || (codepoint == 0x0157) || (codepoint >= 0x0166 && codepoint <= 0x016B) || \

          (codepoint == 0x0172) || (codepoint == 0x0173))

 #define isIBM874(codepoint) \

         ((codepoint >= 0x0E01 && codepoint <= 0x0E3A) || (codepoint >= 0x0E3F && codepoint <= 0x0E5B))

 #define isIBM912(codepoint) \

         ((codepoint >= 0x0102 && codepoint <= 0x0107) || (codepoint >= 0x010C && codepoint <= 0x0111) || (codepoint >= 0x0118 && codepoint <= 0x011B) || \

          (codepoint == 0x0139) || (codepoint == 0x013A) || (codepoint == 0x013D) || (codepoint == 0x013E) || (codepoint >= 0x0141 && codepoint <= 0x0144) || \

          (codepoint == 0x0147) || (codepoint == 0x0147) || (codepoint == 0x0150) || (codepoint == 0x0151) || (codepoint == 0x0154) || (codepoint == 0x0155) || \

          (codepoint >= 0x0158 && codepoint <= 0x015B) || (codepoint == 0x015E) || (codepoint == 0x015F) || (codepoint >= 0x0160 && codepoint <= 0x0165) || \

          (codepoint == 0x016E) || (codepoint == 0x016F) || (codepoint == 0x0170) || (codepoint ==  0x0171) || (codepoint >= 0x0179 && codepoint <= 0x017E) || \

          (codepoint == 0x02C7) || (codepoint == 0x02D8) || (codepoint == 0x02D9) || (codepoint == 0x02DB) || (codepoint == 0x02DD))

 #define isIBM913(codepoint) \

         ((codepoint >= 0x0108 && codepoint <= 0x010B) || (codepoint == 0x011C) || \

          (codepoint == 0x011D) || (codepoint == 0x0120) || (codepoint == 0x0121) || \

          (codepoint >= 0x0124 && codepoint <= 0x0127) || (codepoint == 0x0134) || (codepoint == 0x0135) || \

          (codepoint == 0x015C) || (codepoint == 0x015D) || (codepoint == 0x016C) || (codepoint ==  0x016D))

 #define isCompoundS1(codepoint) \

         ((codepoint == 0x011E) || (codepoint == 0x011F) || (codepoint == 0x0130) || \

          (codepoint == 0x0131) || (codepoint >= 0x0218 && codepoint <= 0x021B))

 #define isISO8859_14(codepoint) \

         ((codepoint >= 0x0174 && codepoint <= 0x0177) || (codepoint == 0x1E0A) || \

          (codepoint == 0x1E0B) || (codepoint == 0x1E1E) || (codepoint == 0x1E1F) || \

          (codepoint == 0x1E40) || (codepoint == 0x1E41) || (codepoint == 0x1E56) || \

          (codepoint == 0x1E57) || (codepoint == 0x1E60) || (codepoint == 0x1E61) || \

          (codepoint == 0x1E6A) || (codepoint == 0x1E6B) || (codepoint == 0x1EF2) || \

          (codepoint == 0x1EF3) || (codepoint >= 0x1E80 && codepoint <= 0x1E85))

 #define isIBM923(codepoint) \

         ((codepoint == 0x0152) || (codepoint == 0x0153) || (codepoint == 0x0178) || (codepoint == 0x20AC))

 typedef struct{

     UConverterSharedData *myConverterArray[NUM_OF_CONVERTERS];

     COMPOUND_TEXT_CONVERTERS state;

 } UConverterDataCompoundText;

 /*********** Compound Text Converter Protos ***********/

 static void

 _CompoundTextOpen(UConverter *cnv, UConverterLoadArgs *pArgs, UErrorCode *errorCode);

 static void

  _CompoundTextClose(UConverter *converter);

 static void

 _CompoundTextReset(UConverter *converter, UConverterResetChoice choice);

 static const char*

 _CompoundTextgetName(const UConverter* cnv);

 static int32_t findNextEsc(const char *source, const char *sourceLimit) {

     int32_t length = sourceLimit - source;

     int32_t i;

     for (i = 1; i < length; i++) {

         if (*(source + i) == 0x1B) {

             return i;

         }

     }

     return length;

 }

 static COMPOUND_TEXT_CONVERTERS getState(int codepoint) {

     COMPOUND_TEXT_CONVERTERS state = DO_SEARCH;

     if (isASCIIRange(codepoint)) {

         state = COMPOUND_TEXT_SINGLE_0;

     } else if (isIBM912(codepoint)) {

         state = IBM_912;

     }else if (isIBM913(codepoint)) {

         state = IBM_913;

     } else if (isISO8859_14(codepoint)) {

         state = ISO_8859_14;

     } else if (isIBM923(codepoint)) {

         state = IBM_923;

     } else if (isIBM874(codepoint)) {

         state = IBM_874;

     } else if (isIBM914(codepoint)) {

         state = IBM_914;

     } else if (isCompoundS2(codepoint)) {

         state = COMPOUND_TEXT_SINGLE_2;

     } else if (isCompoundS3(codepoint)) {

         state = COMPOUND_TEXT_SINGLE_3;

     } else if (isIBM916(codepoint)) {

         state = IBM_916;

     } else if (isIBM915(codepoint)) {

         state = IBM_915;

     } else if (isCompoundS1(codepoint)) {

         state = COMPOUND_TEXT_SINGLE_1;

     }

     return state;

 }

 static COMPOUND_TEXT_CONVERTERS findStateFromEscSeq(const char* source, const char* sourceLimit, const uint8_t* toUBytesBuffer, int32_t toUBytesBufferLength, UErrorCode *err) {

     COMPOUND_TEXT_CONVERTERS state = INVALID;

     UBool matchFound = FALSE;

     int32_t i, n, offset = toUBytesBufferLength;

     for (i = 0; i < NUM_OF_CONVERTERS; i++) {

         matchFound = TRUE;

         for (n = 0; escSeqCompoundText[i][n] != 0; n++) {

             if (n < toUBytesBufferLength) {

                 if (toUBytesBuffer[n] != escSeqCompoundText[i][n]) {

                     matchFound = FALSE;

                     break;

                 }

             } else if ((source + (n - offset)) >= sourceLimit) {

                 *err = U_TRUNCATED_CHAR_FOUND;

                 matchFound = FALSE;

                 break;

             } else if (*(source + (n - offset)) != escSeqCompoundText[i][n]) {

                 matchFound = FALSE;

                 break;

             }

         }

         if (matchFound) {

             break;

         }

     }

     if (matchFound) {

         state = (COMPOUND_TEXT_CONVERTERS)i;

     }

     return state;

 }

 static void

 _CompoundTextOpen(UConverter *cnv, UConverterLoadArgs *pArgs, UErrorCode *errorCode){

     cnv->extraInfo = uprv_malloc (sizeof (UConverterDataCompoundText));

     if (cnv->extraInfo != NULL) {

         UConverterDataCompoundText *myConverterData = (UConverterDataCompoundText *) cnv->extraInfo;

         UConverterNamePieces stackPieces;

         UConverterLoadArgs stackArgs={ (int32_t)sizeof(UConverterLoadArgs) };

         myConverterData->myConverterArray[COMPOUND_TEXT_SINGLE_0] = NULL;

         myConverterData->myConverterArray[COMPOUND_TEXT_SINGLE_1] = ucnv_loadSharedData("icu-internal-compound-s1", &stackPieces, &stackArgs, errorCode);

         myConverterData->myConverterArray[COMPOUND_TEXT_SINGLE_2] = ucnv_loadSharedData("icu-internal-compound-s2", &stackPieces, &stackArgs, errorCode);

         myConverterData->myConverterArray[COMPOUND_TEXT_SINGLE_3] = ucnv_loadSharedData("icu-internal-compound-s3", &stackPieces, &stackArgs, errorCode);

         myConverterData->myConverterArray[COMPOUND_TEXT_DOUBLE_1] = ucnv_loadSharedData("icu-internal-compound-d1", &stackPieces, &stackArgs, errorCode);

         myConverterData->myConverterArray[COMPOUND_TEXT_DOUBLE_2] = ucnv_loadSharedData("icu-internal-compound-d2", &stackPieces, &stackArgs, errorCode);

         myConverterData->myConverterArray[COMPOUND_TEXT_DOUBLE_3] = ucnv_loadSharedData("icu-internal-compound-d3", &stackPieces, &stackArgs, errorCode);

         myConverterData->myConverterArray[COMPOUND_TEXT_DOUBLE_4] = ucnv_loadSharedData("icu-internal-compound-d4", &stackPieces, &stackArgs, errorCode);

         myConverterData->myConverterArray[COMPOUND_TEXT_DOUBLE_5] = ucnv_loadSharedData("icu-internal-compound-d5", &stackPieces, &stackArgs, errorCode);

         myConverterData->myConverterArray[COMPOUND_TEXT_DOUBLE_6] = ucnv_loadSharedData("icu-internal-compound-d6", &stackPieces, &stackArgs, errorCode);

         myConverterData->myConverterArray[COMPOUND_TEXT_DOUBLE_7] = ucnv_loadSharedData("icu-internal-compound-d7", &stackPieces, &stackArgs, errorCode);

         myConverterData->myConverterArray[COMPOUND_TEXT_TRIPLE_DOUBLE] = ucnv_loadSharedData("icu-internal-compound-t", &stackPieces, &stackArgs, errorCode);

         myConverterData->myConverterArray[IBM_915] = ucnv_loadSharedData("ibm-915_P100-1995", &stackPieces, &stackArgs, errorCode);

         myConverterData->myConverterArray[IBM_916] = ucnv_loadSharedData("ibm-916_P100-1995", &stackPieces, &stackArgs, errorCode);

         myConverterData->myConverterArray[IBM_914] = ucnv_loadSharedData("ibm-914_P100-1995", &stackPieces, &stackArgs, errorCode);

         myConverterData->myConverterArray[IBM_874] = ucnv_loadSharedData("ibm-874_P100-1995", &stackPieces, &stackArgs, errorCode);

         myConverterData->myConverterArray[IBM_912] = ucnv_loadSharedData("ibm-912_P100-1995", &stackPieces, &stackArgs, errorCode);

         myConverterData->myConverterArray[IBM_913] = ucnv_loadSharedData("ibm-913_P100-2000", &stackPieces, &stackArgs, errorCode);

         myConverterData->myConverterArray[ISO_8859_14] = ucnv_loadSharedData("iso-8859_14-1998", &stackPieces, &stackArgs, errorCode);

         myConverterData->myConverterArray[IBM_923] = ucnv_loadSharedData("ibm-923_P100-1998", &stackPieces, &stackArgs, errorCode);

         if (U_FAILURE(*errorCode) || pArgs->onlyTestIsLoadable) {

             _CompoundTextClose(cnv);

             return;

         }

         myConverterData->state = (COMPOUND_TEXT_CONVERTERS)0;

     } else {

         *errorCode = U_MEMORY_ALLOCATION_ERROR;

     }

 }

 static void

 _CompoundTextClose(UConverter *converter) {

     UConverterDataCompoundText* myConverterData = (UConverterDataCompoundText*)(converter->extraInfo);

     int32_t i;

     if (converter->extraInfo != NULL) {

         /*close the array of converter pointers and free the memory*/

         for (i = 0; i < NUM_OF_CONVERTERS; i++) {

             if (myConverterData->myConverterArray[i] != NULL) {

                 ucnv_unloadSharedDataIfReady(myConverterData->myConverterArray[i]);

             }

         }

         uprv_free(converter->extraInfo);

     }

 }

 static void

 _CompoundTextReset(UConverter *converter, UConverterResetChoice choice) {

 }

 static const char*

 _CompoundTextgetName(const UConverter* cnv){

     return "x11-compound-text";

 }

 static void

 UConverter_fromUnicode_CompoundText_OFFSETS(UConverterFromUnicodeArgs* args, UErrorCode* err){

     UConverter *cnv = args->converter;

     uint8_t *target = (uint8_t *) args->target;

     const uint8_t *targetLimit = (const uint8_t *) args->targetLimit;

     const UChar* source = args->source;

     const UChar* sourceLimit = args->sourceLimit;

     /* int32_t* offsets = args->offsets; */

     UChar32 sourceChar;

     UBool useFallback = cnv->useFallback;

     uint8_t tmpTargetBuffer[7];

     int32_t tmpTargetBufferLength = 0;

     COMPOUND_TEXT_CONVERTERS currentState, tmpState;

     uint32_t pValue;

     int32_t pValueLength = 0;

     int32_t i, n, j;

     UConverterDataCompoundText *myConverterData = (UConverterDataCompoundText *) cnv->extraInfo;

     currentState = myConverterData->state;

     /* check if the last codepoint of previous buffer was a lead surrogate*/

     if((sourceChar = cnv->fromUChar32)!=0 && target< targetLimit) {

         goto getTrail;

     }

     while( source < sourceLimit){

         if(target < targetLimit){

             sourceChar  = *(source++);

             /*check if the char is a First surrogate*/

              if(U16_IS_SURROGATE(sourceChar)) {

                 if(U16_IS_SURROGATE_LEAD(sourceChar)) {

 getTrail:

                     /*look ahead to find the trail surrogate*/

                     if(source < sourceLimit) {

                         /* test the following code unit */

                         UChar trail=(UChar) *source;

                         if(U16_IS_TRAIL(trail)) {

                             source++;

                             sourceChar=U16_GET_SUPPLEMENTARY(sourceChar, trail);

                             cnv->fromUChar32=0x00;

                             /* convert this supplementary code point */

                             /* exit this condition tree */

                         } else {

                             /* this is an unmatched lead code unit (1st surrogate) */

                             /* callback(illegal) */

                             *err=U_ILLEGAL_CHAR_FOUND;

                             cnv->fromUChar32=sourceChar;

                             break;

                         }

                     } else {

                         /* no more input */

                         cnv->fromUChar32=sourceChar;

                         break;

                     }

                 } else {

                     /* this is an unmatched trail code unit (2nd surrogate) */

                     /* callback(illegal) */

                     *err=U_ILLEGAL_CHAR_FOUND;

                     cnv->fromUChar32=sourceChar;

                     break;

                 }

             }

              tmpTargetBufferLength = 0;

              tmpState = getState(sourceChar);

              if (tmpState != DO_SEARCH && currentState != tmpState) {

                  /* Get escape sequence if necessary */

                  currentState = tmpState;

                  for (i = 0; escSeqCompoundText[currentState][i] != 0; i++) {

                      tmpTargetBuffer[tmpTargetBufferLength++] = escSeqCompoundText[currentState][i];

                  }

              }

              if (tmpState == DO_SEARCH) {

                  /* Test all available converters */

                  for (i = 1; i < SEARCH_LENGTH; i++) {

                      pValueLength = ucnv_MBCSFromUChar32(myConverterData->myConverterArray[i], sourceChar, &pValue, useFallback);

                      if (pValueLength > 0) {

                          tmpState = (COMPOUND_TEXT_CONVERTERS)i;

                          if (currentState != tmpState) {

                              currentState = tmpState;

                              for (j = 0; escSeqCompoundText[currentState][j] != 0; j++) {

                                  tmpTargetBuffer[tmpTargetBufferLength++] = escSeqCompoundText[currentState][j];

                              }

                          }

                          for (n = (pValueLength - 1); n >= 0; n--) {

                              tmpTargetBuffer[tmpTargetBufferLength++] = (uint8_t)(pValue >> (n * 8));

                          }

                          break;

                      }

                  }

              } else if (tmpState == COMPOUND_TEXT_SINGLE_0) {

                  tmpTargetBuffer[tmpTargetBufferLength++] = (uint8_t)sourceChar;

              } else {

                  pValueLength = ucnv_MBCSFromUChar32(myConverterData->myConverterArray[currentState], sourceChar, &pValue, useFallback);

                  if (pValueLength > 0) {

                      for (n = (pValueLength - 1); n >= 0; n--) {

                          tmpTargetBuffer[tmpTargetBufferLength++] = (uint8_t)(pValue >> (n * 8));

                      }

                  }

              }

              for (i = 0; i < tmpTargetBufferLength; i++) {

                  if (target < targetLimit) {

                      *target++ = tmpTargetBuffer[i];

                  } else {

                      *err = U_BUFFER_OVERFLOW_ERROR;

                      break;

                  }

              }

              if (*err == U_BUFFER_OVERFLOW_ERROR) {

                  for (; i < tmpTargetBufferLength; i++) {

                      args->converter->charErrorBuffer[args->converter->charErrorBufferLength++] = tmpTargetBuffer[i];

                  }

              }

         } else {

             *err = U_BUFFER_OVERFLOW_ERROR;

             break;

         }

     }

     /*save the state and return */

     myConverterData->state = currentState;

     args->source = source;

     args->target = (char*)target;

 }

 static void

 UConverter_toUnicode_CompoundText_OFFSETS(UConverterToUnicodeArgs *args,

                                                UErrorCode* err){

     const char *mySource = (char *) args->source;

     UChar *myTarget = args->target;

     const char *mySourceLimit = args->sourceLimit;

     const char *tmpSourceLimit = mySourceLimit;

     uint32_t mySourceChar = 0x0000;

     COMPOUND_TEXT_CONVERTERS currentState, tmpState;

     int32_t sourceOffset = 0;

     UConverterDataCompoundText *myConverterData = (UConverterDataCompoundText *) args->converter->extraInfo;

     UConverterSharedData* savedSharedData = NULL;

     UConverterToUnicodeArgs subArgs;

     int32_t minArgsSize;

     /* set up the subconverter arguments */

     if(args->size<sizeof(UConverterToUnicodeArgs)) {

         minArgsSize = args->size;

     } else {

         minArgsSize = (int32_t)sizeof(UConverterToUnicodeArgs);

     }

     uprv_memcpy(&subArgs, args, minArgsSize);

     subArgs.size = (uint16_t)minArgsSize;

     currentState = tmpState =  myConverterData->state;

     while(mySource < mySourceLimit){

         if(myTarget < args->targetLimit){

             if (args->converter->toULength > 0) {

                 mySourceChar = args->converter->toUBytes[0];

             } else {

                 mySourceChar = (uint8_t)*mySource;

             }

             if (mySourceChar == ESC_START) {

                 tmpState = findStateFromEscSeq(mySource, mySourceLimit, args->converter->toUBytes, args->converter->toULength, err);

                 if (*err == U_TRUNCATED_CHAR_FOUND) {

                     for (; mySource < mySourceLimit;) {

                         args->converter->toUBytes[args->converter->toULength++] = *mySource++;

                     }

                     *err = U_ZERO_ERROR;

                     break;

                 } else if (tmpState == INVALID) {

                     if (args->converter->toULength == 0) {

                         mySource++; /* skip over the 0x1b byte */

                     }

                     *err = U_ILLEGAL_CHAR_FOUND;

                     break;

                 }

                 if (tmpState != currentState) {

                     currentState = tmpState;

                 }

                 sourceOffset = uprv_strlen((char*)escSeqCompoundText[currentState]) - args->converter->toULength;

                 mySource += sourceOffset;

                 args->converter->toULength = 0;

             }

             if (currentState == COMPOUND_TEXT_SINGLE_0) {

                 while (mySource < mySourceLimit) {

                     if (*mySource == ESC_START) {

                         break;

                     }

                     if (myTarget < args->targetLimit) {

                         *myTarget++ = 0x00ff&(*mySource++);

                     } else {

                         *err = U_BUFFER_OVERFLOW_ERROR;

                         break;

                     }

                 }

             } else if (mySource < mySourceLimit){

                 sourceOffset = findNextEsc(mySource, mySourceLimit);

                 tmpSourceLimit = mySource + sourceOffset;

                 subArgs.source = mySource;

                 subArgs.sourceLimit = tmpSourceLimit;

                 subArgs.target = myTarget;

                 savedSharedData = subArgs.converter->sharedData;

                 subArgs.converter->sharedData = myConverterData->myConverterArray[currentState];

                 ucnv_MBCSToUnicodeWithOffsets(&subArgs, err);

                 subArgs.converter->sharedData = savedSharedData;

                 mySource = subArgs.source;

                 myTarget = subArgs.target;

                 if (U_FAILURE(*err)) {

                     if(*err == U_BUFFER_OVERFLOW_ERROR) {

                         if(subArgs.converter->UCharErrorBufferLength > 0) {

                             uprv_memcpy(args->converter->UCharErrorBuffer, subArgs.converter->UCharErrorBuffer,

                                         subArgs.converter->UCharErrorBufferLength);

                         }

                         args->converter->UCharErrorBufferLength=subArgs.converter->UCharErrorBufferLength;

                         subArgs.converter->UCharErrorBufferLength = 0;

                     }

                     break;

                 }

             }

         } else {

             *err = U_BUFFER_OVERFLOW_ERROR;

             break;

         }

     }

     myConverterData->state = currentState;

     args->target = myTarget;

     args->source = mySource;

 }

 static void

 _CompoundText_GetUnicodeSet(const UConverter *cnv,

                     const USetAdder *sa,

                     UConverterUnicodeSet which,

                     UErrorCode *pErrorCode) {

     UConverterDataCompoundText *myConverterData = (UConverterDataCompoundText *)cnv->extraInfo;

     int32_t i;

     for (i = 1; i < NUM_OF_CONVERTERS; i++) {

         ucnv_MBCSGetUnicodeSetForUnicode(myConverterData->myConverterArray[i], sa, which, pErrorCode);

     }

     sa->add(sa->set, 0x0000);

     sa->add(sa->set, 0x0009);

     sa->add(sa->set, 0x000A);

     sa->addRange(sa->set, 0x0020, 0x007F);

     sa->addRange(sa->set, 0x00A0, 0x00FF);

 }

 static const UConverterImpl _CompoundTextImpl = {

     UCNV_COMPOUND_TEXT,

     NULL,

     NULL,

     _CompoundTextOpen,

     _CompoundTextClose,

     _CompoundTextReset,

     UConverter_toUnicode_CompoundText_OFFSETS,

     UConverter_toUnicode_CompoundText_OFFSETS,

     UConverter_fromUnicode_CompoundText_OFFSETS,

     UConverter_fromUnicode_CompoundText_OFFSETS,

     NULL,

     NULL,

     _CompoundTextgetName,

     NULL,

     NULL,

     _CompoundText_GetUnicodeSet

 };

 static const UConverterStaticData _CompoundTextStaticData = {

     sizeof(UConverterStaticData),

     "COMPOUND_TEXT",

     0,

     UCNV_IBM,

     UCNV_COMPOUND_TEXT,

     1,

     6,

     { 0xef, 0, 0, 0 },

     1,

     FALSE,

     FALSE,

     0,

     0,

     { 0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0 } /* reserved */

 };

 const UConverterSharedData _CompoundTextData = {

     sizeof(UConverterSharedData),

     ~((uint32_t) 0),

     NULL,

     NULL,

     &_CompoundTextStaticData,

     FALSE,

     &_CompoundTextImpl,

     0

 };

 #endif /* #if !UCONFIG_NO_LEGACY_CONVERSION */