/* ******************************************************************************* * * Copyright (C) 2000-2001, International Business Machines * Corporation and others. All Rights Reserved. * ******************************************************************************* * file name: genuca.cpp * encoding: US-ASCII * tab size: 8 (not used) * indentation:4 * * created at the end of XX century * created by: Vladimir Weinstein * * This program reads the Franctional UCA table and generates * internal format for UCA table as well as inverse UCA table. * It then writes binary files containing the data: ucadata.dat * & invuca.dat * Change history: * 02/23/2001 grhoten Made it into a tool * 02/23/2001 weiv Moved element & table handling code to i18n * 05/09/2001 weiv Case bits are now in the CEs, not in front */ #include "genuca.h" #include "uoptions.h" #include "toolutil.h" #include "cstring.h" #include "cmemory.h" UCAElements le; /* * Global - verbosity */ UBool VERBOSE = FALSE; int32_t readElement(char **from, char *to, char separator, UErrorCode *status) { if(U_FAILURE(*status)) { return 0; } char buffer[1024]; int32_t i = 0; while(**from != separator) { if(**from != ' ') { *(buffer+i++) = **from; } (*from)++; } (*from)++; *(buffer + i) = 0; //*to = (char *)malloc(strlen(buffer)+1); strcpy(to, buffer); return i/2; } uint32_t getSingleCEValue(char *primary, char *secondary, char *tertiary, UErrorCode *status) { if(U_FAILURE(*status)) { return 0; } uint32_t value = 0; char primsave = '\0'; char secsave = '\0'; char tersave = '\0'; char *primend = primary+4; if(strlen(primary) > 4) { primsave = *primend; *primend = '\0'; } char *secend = secondary+2; if(strlen(secondary) > 2) { secsave = *secend; *secend = '\0'; } char *terend = tertiary+2; if(strlen(tertiary) > 2) { tersave = *terend; *terend = '\0'; } uint32_t primvalue = (uint32_t)((*primary!='\0')?strtoul(primary, &primend, 16):0); uint32_t secvalue = (uint32_t)((*secondary!='\0')?strtoul(secondary, &secend, 16):0); uint32_t tervalue = (uint32_t)((*tertiary!='\0')?strtoul(tertiary, &terend, 16):0); if(primvalue <= 0xFF) { primvalue <<= 8; } value = ((primvalue<CEs[1])) { //fprintf(stdout, "+"); } inversePos++; inverseTable[inversePos][0] = element->CEs[0]; if(element->noOfCEs > 1 && isContinuation(element->CEs[1])) { inverseTable[inversePos][1] = element->CEs[1]; } else { inverseTable[inversePos][1] = 0; } if(element->cSize < 2) { inverseTable[inversePos][2] = element->cPoints[0]; } else { /* add a new store of cruft */ inverseTable[inversePos][2] = ((element->cSize+1) << UCOL_INV_SHIFTVALUE) | sContPos; memcpy(stringContinue+sContPos, element->cPoints, element->cSize*sizeof(UChar)); sContPos += element->cSize+1; } } static void insertInverse(UCAElements *element, uint32_t position, UErrorCode *status) { if(U_FAILURE(*status)) { return; } if(VERBOSE && isContinuation(element->CEs[1])) { //fprintf(stdout, "+"); } if(position <= inversePos) { /*move stuff around */ uint32_t amountToMove = (inversePos - position+1)*sizeof(inverseTable[0]); uprv_memmove(inverseTable[position+1], inverseTable[position], amountToMove); } inverseTable[position][0] = element->CEs[0]; if(element->noOfCEs > 1 && isContinuation(element->CEs[1])) { inverseTable[position][1] = element->CEs[1]; } else { inverseTable[position][1] = 0; } if(element->cSize < 2) { inverseTable[position][2] = element->cPoints[0]; } else { /* add a new store of cruft */ inverseTable[position][2] = ((element->cSize+1) << UCOL_INV_SHIFTVALUE) | sContPos; memcpy(stringContinue+sContPos, element->cPoints, element->cSize*sizeof(UChar)); sContPos += element->cSize+1; } inversePos++; } static void addToExistingInverse(UCAElements *element, uint32_t position, UErrorCode *status) { if(U_FAILURE(*status)) { return; } if((inverseTable[position][2] & UCOL_INV_SIZEMASK) == 0) { /* single element, have to make new extension place and put both guys there */ stringContinue[sContPos] = (UChar)inverseTable[position][2]; inverseTable[position][2] = ((element->cSize+3) << UCOL_INV_SHIFTVALUE) | sContPos; sContPos++; stringContinue[sContPos++] = 0xFFFF; memcpy(stringContinue+sContPos, element->cPoints, element->cSize*sizeof(UChar)); sContPos += element->cSize; stringContinue[sContPos++] = 0xFFFE; } else { /* adding to the already existing continuing table */ uint32_t contIndex = inverseTable[position][2] & UCOL_INV_OFFSETMASK; uint32_t contSize = (inverseTable[position][2] & UCOL_INV_SIZEMASK) >> UCOL_INV_SHIFTVALUE; if(contIndex+contSize < sContPos) { /*fprintf(stderr, ".", sContPos, contIndex+contSize);*/ memcpy(stringContinue+contIndex+contSize+element->cSize+1, stringContinue+contIndex+contSize, (element->cSize+1)*sizeof(UChar)); } stringContinue[contIndex+contSize-1] = 0xFFFF; memcpy(stringContinue+contIndex+contSize, element->cPoints, element->cSize*sizeof(UChar)); sContPos += element->cSize+1; stringContinue[contIndex+contSize+element->cSize] = 0xFFFE; inverseTable[position][2] = ((contSize+element->cSize+1) << UCOL_INV_SHIFTVALUE) | contIndex; } } static uint32_t addToInverse(UCAElements *element, UErrorCode *status) { uint32_t comp = 0; uint32_t position = inversePos; uint32_t saveElement = element->CEs[0]; element->CEs[0] &= 0xFFFFFF3F; if(element->noOfCEs == 1) { element->CEs[1] = 0; } if(inversePos == 0) { inverseTable[0][0] = inverseTable[0][1] = inverseTable[0][2] = 0; addNewInverse(element, status); } else if(inverseTable[inversePos][0] > element->CEs[0]) { while(inverseTable[--position][0] > element->CEs[0]) {} if(VERBOSE) { fprintf(stdout, "p:%i ", position); } if(inverseTable[position][0] == element->CEs[0]) { if(isContinuation(element->CEs[1])) { comp = element->CEs[1]; } else { comp = 0; } if(inverseTable[position][1] > comp) { while(inverseTable[--position][1] > comp) {} } if(inverseTable[position][1] == comp) { addToExistingInverse(element, position, status); } else { insertInverse(element, position+1, status); } } else { if(VERBOSE) { fprintf(stdout, "ins"); } insertInverse(element, position+1, status); } } else if(inverseTable[inversePos][0] == element->CEs[0]) { if(element->noOfCEs > 1 && isContinuation(element->CEs[1])) { comp = element->CEs[1]; if(inverseTable[position][1] > comp) { while(inverseTable[--position][1] > comp) {} } if(inverseTable[position][1] == comp) { addToExistingInverse(element, position, status); } else { insertInverse(element, position+1, status); } } else { addToExistingInverse(element, inversePos, status); } } else { addNewInverse(element, status); } element->CEs[0] = saveElement; if(VERBOSE) { fprintf(stdout, "+"); } return inversePos; } static InverseTableHeader *assembleInverseTable(UErrorCode *status) { InverseTableHeader *result = NULL; uint32_t headerByteSize = paddedsize(sizeof(InverseTableHeader)); uint32_t inverseTableByteSize = (inversePos+2)*sizeof(uint32_t)*3; uint32_t contsByteSize = sContPos * sizeof(UChar); uint32_t i = 0; result = (InverseTableHeader *)uprv_malloc(headerByteSize + inverseTableByteSize + contsByteSize); if(result != NULL) { result->byteSize = headerByteSize + inverseTableByteSize + contsByteSize; inversePos++; inverseTable[inversePos][0] = 0xFFFFFFFF; inverseTable[inversePos][1] = 0xFFFFFFFF; inverseTable[inversePos][2] = 0x0000FFFF; inversePos++; for(i = 2; i inverseTable[i][0]) { fprintf(stderr, "Error at %i: %08X & %08X\n", i, inverseTable[i-1][0], inverseTable[i][0]); } else if(inverseTable[i-1][0] == inverseTable[i][0] && !(inverseTable[i-1][1] < inverseTable[i][1])) { fprintf(stderr, "Continuation error at %i: %08X %08X & %08X %08X\n", i, inverseTable[i-1][0], inverseTable[i-1][1], inverseTable[i][0], inverseTable[i][1]); } } result->tableSize = inversePos; result->contsSize = sContPos; result->table = headerByteSize; result->conts = headerByteSize + inverseTableByteSize; memcpy((uint8_t *)result + result->table, inverseTable, inverseTableByteSize); memcpy((uint8_t *)result + result->conts, stringContinue, contsByteSize); } else { *status = U_MEMORY_ALLOCATION_ERROR; return NULL; } return result; } static void writeOutInverseData(InverseTableHeader *data, const char *outputDir, const char *copyright, UErrorCode *status) { UNewDataMemory *pData; long dataLength; pData=udata_create(outputDir, INVC_DATA_TYPE, U_ICUDATA_NAME "_" INVC_DATA_NAME, &invUcaDataInfo, copyright, status); if(U_FAILURE(*status)) { fprintf(stderr, "Error: unable to create data memory, error %d\n", *status); return; } /* write the data to the file */ if (VERBOSE) { fprintf(stdout, "Writing out inverse UCA table: %s%c%s.%s\n", outputDir, U_FILE_SEP_CHAR, U_ICUDATA_NAME "_" INVC_DATA_NAME, INVC_DATA_TYPE); } udata_writeBlock(pData, data, data->byteSize); /* finish up */ dataLength=udata_finish(pData, status); if(U_FAILURE(*status)) { fprintf(stderr, "Error: error %d writing the output file\n", *status); return; } } static int32_t hex2num(char hex) { if(hex>='0' && hex <='9') { return hex-'0'; } else if(hex>='a' && hex<='f') { return hex-'a'+10; } else if(hex>='A' && hex<='F') { return hex-'A'+10; } else { return 0; } } UCAElements *readAnElement(FILE *data, tempUCATable *t, UCAConstants *consts, UErrorCode *status) { char buffer[2048], primary[100], secondary[100], tertiary[100]; UBool detectedContraction; int32_t i = 0; unsigned int theValue; char *pointer = NULL; char *commentStart = NULL; char *startCodePoint = NULL; char *endCodePoint = NULL; char *spacePointer = NULL; char *result = fgets(buffer, 2048, data); int32_t buflen = uprv_strlen(buffer); if(U_FAILURE(*status)) { return 0; } *primary = *secondary = *tertiary = '\0'; if(result == NULL) { if(feof(data)) { return NULL; } else { fprintf(stderr, "empty line but no EOF!\n"); *status = U_INVALID_FORMAT_ERROR; return NULL; } } while(buflen>0 && (buffer[buflen-1] == '\r' || buffer[buflen-1] == '\n')) { buffer[--buflen] = 0; } if(buffer[0] == 0 || buffer[0] == '#') { return NULL; // just a comment, skip whole line } UCAElements *element = ≤ //(UCAElements *)malloc(sizeof(UCAElements)); enum ActionType { READCE, READHEX }; // Directives. if(buffer[0] == '[') { uint32_t cnt = 0; struct { char name[256]; uint32_t *what; ActionType what_to_do; } vt[] = { {"[first tertiary ignorable", consts->UCA_FIRST_TERTIARY_IGNORABLE, READCE}, {"[last tertiary ignorable", consts->UCA_LAST_TERTIARY_IGNORABLE, READCE}, {"[first secondary ignorable", consts->UCA_FIRST_SECONDARY_IGNORABLE, READCE}, {"[last secondary ignorable", consts->UCA_LAST_SECONDARY_IGNORABLE, READCE}, {"[first primary ignorable", consts->UCA_FIRST_PRIMARY_IGNORABLE, READCE}, {"[last primary ignorable", consts->UCA_LAST_PRIMARY_IGNORABLE, READCE}, {"[first variable", consts->UCA_FIRST_VARIABLE, READCE}, {"[last variable", consts->UCA_LAST_VARIABLE, READCE}, {"[first regular", consts->UCA_FIRST_NON_VARIABLE, READCE}, {"[last regular", consts->UCA_LAST_NON_VARIABLE, READCE}, {"[first implicit", consts->UCA_FIRST_IMPLICIT, READCE}, {"[last implicit", consts->UCA_LAST_IMPLICIT, READCE}, {"[first trailing", consts->UCA_FIRST_TRAILING, READCE}, {"[last trailing", consts->UCA_LAST_TRAILING, READCE}, {"[fixed top", &consts->UCA_PRIMARY_TOP_MIN, READHEX}, {"[fixed first implicit byte", &consts->UCA_PRIMARY_IMPLICIT_MIN, READHEX}, {"[fixed last implicit byte", &consts->UCA_PRIMARY_IMPLICIT_MAX, READHEX}, {"[fixed first trail byte", &consts->UCA_PRIMARY_TRAILING_MIN, READHEX}, {"[fixed last trail byte", &consts->UCA_PRIMARY_TRAILING_MAX, READHEX}, {"[fixed first special byte", &consts->UCA_PRIMARY_SPECIAL_MIN, READHEX}, {"[fixed last special byte", &consts->UCA_PRIMARY_SPECIAL_MAX, READHEX}, {"[variable top = ", &t->options->variableTopValue, READHEX}, }; for (cnt = 0; cntvariableTop = TRUE; if(vt[cnt].what_to_do == READHEX) { if(sscanf(buffer+vtLen, "%4x", &theValue) != 1) /* read first code point */ { fprintf(stderr, " scanf(hex) failed on !\n "); } *(vt[cnt].what) = (UChar)theValue; //if(cnt == 1) { // first implicit // we need to set the value for top next //uint32_t nextTop = ucol_prv_calculateImplicitPrimary(0x4E00); // CJK base //consts->UCA_NEXT_TOP_VALUE = theValue<<24 | 0x030303; //} } else { /* vt[cnt].what_to_do == READCE */ pointer = strchr(buffer+vtLen, '['); if(pointer) { pointer++; element->sizePrim[0]=readElement(&pointer, primary, ',', status); element->sizeSec[0]=readElement(&pointer, secondary, ',', status); element->sizeTer[0]=readElement(&pointer, tertiary, ']', status); vt[cnt].what[0] = getSingleCEValue(primary, secondary, tertiary, status); if(element->sizePrim[0] > 2 || element->sizeSec[0] > 1 || element->sizeTer[0] > 1) { uint32_t CEi = 1; uint32_t value = UCOL_CONTINUATION_MARKER; /* Continuation marker */ if(2*CEisizePrim[i]) { value |= ((hex2num(*(primary+4*CEi))&0xF)<<28); value |= ((hex2num(*(primary+4*CEi+1))&0xF)<<24); } if(2*CEi+1sizePrim[i]) { value |= ((hex2num(*(primary+4*CEi+2))&0xF)<<20); value |= ((hex2num(*(primary+4*CEi+3))&0xF)<<16); } if(CEisizeSec[i]) { value |= ((hex2num(*(secondary+2*CEi))&0xF)<<12); value |= ((hex2num(*(secondary+2*CEi+1))&0xF)<<8); } if(CEisizeTer[i]) { value |= ((hex2num(*(tertiary+2*CEi))&0x3)<<4); value |= (hex2num(*(tertiary+2*CEi+1))&0xF); } CEi++; vt[cnt].what[1] = value; //element->CEs[CEindex++] = value; } else { vt[cnt].what[1] = 0; } } else { fprintf(stderr, "Failed to read a CE from line %s\n", buffer); } } //element->cPoints[0] = (UChar)theValue; //return element; return NULL; } } fprintf(stderr, "Warning: unrecognized option: %s\n", buffer); //*status = U_INVALID_FORMAT_ERROR; return NULL; } element->variableTop = FALSE; startCodePoint = buffer; endCodePoint = strchr(startCodePoint, ';'); if(endCodePoint == 0) { fprintf(stderr, "error - line with no code point!\n"); *status = U_INVALID_FORMAT_ERROR; /* No code point - could be an error, but probably only an empty line */ return NULL; } else { *(endCodePoint) = 0; } if(element != NULL) { memset(element, 0, sizeof(*element)); } else { *status = U_MEMORY_ALLOCATION_ERROR; return NULL; } element->cPoints = element->uchars; spacePointer = strchr(buffer, ' '); if(sscanf(buffer, "%4x", &theValue) != 1) /* read first code point */ { fprintf(stderr, " scanf(hex) failed!\n "); } element->cPoints[0] = (UChar)theValue; if(spacePointer == 0) { detectedContraction = FALSE; element->cSize = 1; } else { i = 1; detectedContraction = TRUE; while(spacePointer != NULL) { sscanf(spacePointer+1, "%4x", &theValue); element->cPoints[i++] = (UChar)theValue; spacePointer = strchr(spacePointer+1, ' '); } element->cSize = i; //fprintf(stderr, "Number of codepoints in contraction: %i\n", i); } startCodePoint = endCodePoint+1; commentStart = strchr(startCodePoint, '#'); if(commentStart == NULL) { commentStart = strlen(startCodePoint) + startCodePoint; } i = 0; uint32_t CEindex = 0; element->noOfCEs = 0; for(;;) { endCodePoint = strchr(startCodePoint, ']'); if(endCodePoint == NULL || endCodePoint >= commentStart) { break; } pointer = strchr(startCodePoint, '['); pointer++; element->sizePrim[i]=readElement(&pointer, primary, ',', status); element->sizeSec[i]=readElement(&pointer, secondary, ',', status); element->sizeTer[i]=readElement(&pointer, tertiary, ']', status); /* I want to get the CEs entered right here, including continuation */ element->CEs[CEindex++] = getSingleCEValue(primary, secondary, tertiary, status); uint32_t CEi = 1; while(2*CEisizePrim[i] || CEisizeSec[i] || CEisizeTer[i]) { uint32_t value = UCOL_CONTINUATION_MARKER; /* Continuation marker */ if(2*CEisizePrim[i]) { value |= ((hex2num(*(primary+4*CEi))&0xF)<<28); value |= ((hex2num(*(primary+4*CEi+1))&0xF)<<24); } if(2*CEi+1sizePrim[i]) { value |= ((hex2num(*(primary+4*CEi+2))&0xF)<<20); value |= ((hex2num(*(primary+4*CEi+3))&0xF)<<16); } if(CEisizeSec[i]) { value |= ((hex2num(*(secondary+2*CEi))&0xF)<<12); value |= ((hex2num(*(secondary+2*CEi+1))&0xF)<<8); } if(CEisizeTer[i]) { value |= ((hex2num(*(tertiary+2*CEi))&0x3)<<4); value |= (hex2num(*(tertiary+2*CEi+1))&0xF); } CEi++; element->CEs[CEindex++] = value; } startCodePoint = endCodePoint+1; i++; } element->noOfCEs = CEindex; element->isThai = UCOL_ISTHAIPREVOWEL(element->cPoints[0]); // we don't want any strange stuff after useful data! while(pointer < commentStart) { if(*pointer != ' ') { *status=U_INVALID_FORMAT_ERROR; break; } pointer++; } if(U_FAILURE(*status)) { fprintf(stderr, "problem putting stuff in hash table\n"); *status = U_INTERNAL_PROGRAM_ERROR; return NULL; } return element; } void writeOutData(UCATableHeader *data, UCAConstants *consts, UChar contractions[][3], uint32_t noOfcontractions, const char *outputDir, const char *copyright, UErrorCode *status) { if(U_FAILURE(*status)) { return; } uint32_t size = data->size; if(noOfcontractions != 0) { contractions[noOfcontractions][0] = 0; contractions[noOfcontractions][1] = 0; contractions[noOfcontractions][2] = 0; noOfcontractions++; data->UCAConsts = data->size; data->size += paddedsize(sizeof(UCAConstants)); data->contractionUCACombos = data->size; data->size += paddedsize((noOfcontractions*3*sizeof(UChar))); } UNewDataMemory *pData; long dataLength; pData=udata_create(outputDir, UCA_DATA_TYPE, U_ICUDATA_NAME "_" UCA_DATA_NAME, &ucaDataInfo, copyright, status); if(U_FAILURE(*status)) { fprintf(stderr, "Error: unable to create data memory, error %d\n", *status); return; } /* write the data to the file */ if (VERBOSE) { fprintf(stdout, "Writing out UCA table: %s%c%s.%s\n", outputDir, U_FILE_SEP_CHAR, U_ICUDATA_NAME "_" UCA_DATA_NAME, UCA_DATA_TYPE); } udata_writeBlock(pData, data, size); // output the constants here udata_writeBlock(pData, consts, sizeof(UCAConstants)); if(noOfcontractions != 0) { udata_writeBlock(pData, contractions, noOfcontractions*3*sizeof(UChar)); udata_writePadding(pData, paddedsize((noOfcontractions*3*sizeof(UChar))) - noOfcontractions*3*sizeof(uint16_t)); } /* finish up */ dataLength=udata_finish(pData, status); if(U_FAILURE(*status)) { fprintf(stderr, "Error: error %d writing the output file\n", *status); return; } } static int32_t write_uca_table(const char *filename, const char *outputDir, const char *copyright, UErrorCode *status) { FILE *data = fopen(filename, "r"); uint32_t line = 0; UCAElements *element = NULL; UChar variableTopValue = 0; UCATableHeader *myD = (UCATableHeader *)uprv_malloc(sizeof(UCATableHeader)); /* test for NULL */ if(myD == NULL) { *status = U_MEMORY_ALLOCATION_ERROR; fclose(data); return 0; } UColOptionSet *opts = (UColOptionSet *)uprv_malloc(sizeof(UColOptionSet)); /* test for NULL */ if(opts == NULL) { *status = U_MEMORY_ALLOCATION_ERROR; uprv_free(myD); fclose(data); return 0; } UChar contractionCEs[256][3]; uint32_t noOfContractions = 0; UCAConstants consts; #if 0 UCAConstants consts = { UCOL_RESET_TOP_VALUE, UCOL_FIRST_PRIMARY_IGNORABLE, UCOL_LAST_PRIMARY_IGNORABLE, UCOL_LAST_PRIMARY_IGNORABLE_CONT, UCOL_FIRST_SECONDARY_IGNORABLE, UCOL_LAST_SECONDARY_IGNORABLE, UCOL_FIRST_TERTIARY_IGNORABLE, UCOL_LAST_TERTIARY_IGNORABLE, UCOL_FIRST_VARIABLE, UCOL_LAST_VARIABLE, UCOL_FIRST_NON_VARIABLE, UCOL_LAST_NON_VARIABLE, UCOL_NEXT_TOP_VALUE, /* UCOL_NEXT_FIRST_PRIMARY_IGNORABLE, UCOL_NEXT_LAST_PRIMARY_IGNORABLE, UCOL_NEXT_FIRST_SECONDARY_IGNORABLE, UCOL_NEXT_LAST_SECONDARY_IGNORABLE, UCOL_NEXT_FIRST_TERTIARY_IGNORABLE, UCOL_NEXT_LAST_TERTIARY_IGNORABLE, UCOL_NEXT_FIRST_VARIABLE, UCOL_NEXT_LAST_VARIABLE, */ PRIMARY_IMPLICIT_MIN, PRIMARY_IMPLICIT_MAX }; #endif if(data == NULL) { fprintf(stderr, "Couldn't open file: %s\n", filename); return -1; } memset(inverseTable, 0xDA, sizeof(int32_t)*3*0xFFFF); opts->variableTopValue = variableTopValue; opts->strength = UCOL_TERTIARY; opts->frenchCollation = UCOL_OFF; opts->alternateHandling = UCOL_NON_IGNORABLE; /* attribute for handling variable elements*/ opts->caseFirst = UCOL_OFF; /* who goes first, lower case or uppercase */ opts->caseLevel = UCOL_OFF; /* do we have an extra case level */ opts->normalizationMode = UCOL_OFF; /* attribute for normalization */ opts->hiraganaQ = UCOL_OFF; /* attribute for JIS X 4061, used only in Japanese */ /* populate the version info struct with version info*/ myD->version[0] = UCOL_BUILDER_VERSION; /*TODO:The fractional rules version should be taken from FractionalUCA.txt*/ myD->version[1] = UCOL_FRACTIONAL_UCA_VERSION; myD->jamoSpecial = FALSE; tempUCATable *t = uprv_uca_initTempTable(myD, opts, NULL, IMPLICIT_TAG, status); if(U_FAILURE(*status)) { fprintf(stderr, "Failed to init UCA temp table: %s\n", u_errorName(*status)); return -1; } #if 0 IMPLICIT_TAG = 9, /* ***************************************************************************************** * NON_CHARACTER FDD0 - FDEF, FFFE, FFFF, 1FFFE, 1FFFF, 2FFFE, 2FFFF,...e.g. **FFFE, **FFFF ****************************************************************************************** */ #endif // * set to zero struct { UChar32 start; UChar32 end; int32_t value; } ranges[] = { #if 0 {0xAC00, 0xD7AF, UCOL_SPECIAL_FLAG | (HANGUL_SYLLABLE_TAG << 24) }, //0 HANGUL_SYLLABLE_TAG,/* AC00-D7AF*/ {0xD800, 0xDBFF, UCOL_SPECIAL_FLAG | (LEAD_SURROGATE_TAG << 24) }, //1 LEAD_SURROGATE_TAG, /* D800-DBFF*/ {0xDC00, 0xDFFF, UCOL_SPECIAL_FLAG | (TRAIL_SURROGATE_TAG << 24) }, //2 TRAIL_SURROGATE DC00-DFFF {0x3400, 0x4DB5, UCOL_SPECIAL_FLAG | (CJK_IMPLICIT_TAG << 24) }, //3 CJK_IMPLICIT_TAG, /* 0x3400-0x4DB5*/ {0x4E00, 0x9FA5, UCOL_SPECIAL_FLAG | (CJK_IMPLICIT_TAG << 24) }, //4 CJK_IMPLICIT_TAG, /* 0x4E00-0x9FA5*/ {0xF900, 0xFA2D, UCOL_SPECIAL_FLAG | (CJK_IMPLICIT_TAG << 24) }, //5 CJK_IMPLICIT_TAG, /* 0xF900-0xFA2D*/ {0x20000, 0x2A6D6, UCOL_SPECIAL_FLAG | (CJK_IMPLICIT_TAG << 24) }, //6 CJK_IMPLICIT_TAG, /* 0x20000-0x2A6D6*/ {0x2F800, 0x2FA1D, UCOL_SPECIAL_FLAG | (CJK_IMPLICIT_TAG << 24) }, //7 CJK_IMPLICIT_TAG, /* 0x2F800-0x2FA1D*/ #endif {0xAC00, 0xD7B0, UCOL_SPECIAL_FLAG | (HANGUL_SYLLABLE_TAG << 24) }, //0 HANGUL_SYLLABLE_TAG,/* AC00-D7AF*/ {0xD800, 0xDC00, UCOL_SPECIAL_FLAG | (LEAD_SURROGATE_TAG << 24) }, //1 LEAD_SURROGATE_TAG, /* D800-DBFF*/ {0xDC00, 0xE000, UCOL_SPECIAL_FLAG | (TRAIL_SURROGATE_TAG << 24) }, //2 TRAIL_SURROGATE DC00-DFFF // Now directly handled in the collation code by the swapCJK function. //{0x3400, 0x4DB6, UCOL_SPECIAL_FLAG | (CJK_IMPLICIT_TAG << 24) }, //3 CJK_IMPLICIT_TAG, /* 0x3400-0x4DB5*/ //{0x4E00, 0x9FA6, UCOL_SPECIAL_FLAG | (CJK_IMPLICIT_TAG << 24) }, //4 CJK_IMPLICIT_TAG, /* 0x4E00-0x9FA5*/ //{0xF900, 0xFA2E, UCOL_SPECIAL_FLAG | (CJK_IMPLICIT_TAG << 24) }, //5 CJK_IMPLICIT_TAG, /* 0xF900-0xFA2D*/ //{0x20000, 0x2A6D7, UCOL_SPECIAL_FLAG | (CJK_IMPLICIT_TAG << 24) }, //6 CJK_IMPLICIT_TAG, /* 0x20000-0x2A6D6*/ //{0x2F800, 0x2FA1E, UCOL_SPECIAL_FLAG | (CJK_IMPLICIT_TAG << 24) }, //7 CJK_IMPLICIT_TAG, /* 0x2F800-0x2FA1D*/ }; uint32_t i = 0; for(i = 0; imapping, ranges[i].start, ranges[i].end, ranges[i].value); */ utrie_setRange32(t->mapping, ranges[i].start, ranges[i].end, ranges[i].value, TRUE); } int32_t surrogateCount = 0; while(!feof(data)) { if(U_FAILURE(*status)) { fprintf(stderr, "Something returned an error %i (%s) while processing line %i of %s. Exiting...\n", *status, u_errorName(*status), line, filename); exit(*status); } element = readAnElement(data, t, &consts, status); line++; if(VERBOSE) { fprintf(stdout, "%i ", line); } if(element != NULL) { // we have read the line, now do something sensible with the read data! // Below stuff was taken care of in readAnElement //if(element->variableTop == TRUE && variableTopValue == 0) { // t->options->variableTopValue = element->cPoints[0]; //} // if element is a contraction, we want to add it to contractions if(element->cSize > 1 && element->cPoints[0] != 0xFDD0) { // this is a contraction if(UTF_IS_LEAD(element->cPoints[0]) && UTF_IS_TRAIL(element->cPoints[1]) && element->cSize == 2) { surrogateCount++; } else { contractionCEs[noOfContractions][0] = element->cPoints[0]; contractionCEs[noOfContractions][1] = element->cPoints[1]; if(element->cSize > 2) { // the third one contractionCEs[noOfContractions][2] = element->cPoints[2]; } else { contractionCEs[noOfContractions][2] = 0; } noOfContractions++; } } /* we're first adding to inverse, because addAnElement will reverse the order */ /* of code points and stuff... we don't want that to happen */ addToInverse(element, status); if(!(element->cSize > 1 && element->cPoints[0] == 0xFDD0)) { uprv_uca_addAnElement(t, element, status); } } } if (VERBOSE) { fprintf(stdout, "\nLines read: %i\n", line); fprintf(stdout, "Surrogate count: %i\n", surrogateCount); fprintf(stdout, "Raw data breakdown:\n"); /*fprintf(stdout, "Compact array stage1 top: %i, stage2 top: %i\n", t->mapping->stage1Top, t->mapping->stage2Top);*/ fprintf(stdout, "Number of contractions: %i\n", noOfContractions); fprintf(stdout, "Contraction image size: %i\n", t->image->contractionSize); fprintf(stdout, "Expansions size: %i\n", t->expansions->position); } /* produce canonical closure for table */ /* first set up constants for implicit calculation */ uprv_uca_initImplicitConstants(consts.UCA_PRIMARY_IMPLICIT_MIN); /* do the closure */ int32_t noOfClosures = uprv_uca_canonicalClosure(t, status); if(noOfClosures != 0) { fprintf(stderr, "Warning: %i canonical closures occured!\n", noOfClosures); } /* test */ UCATableHeader *myData = uprv_uca_assembleTable(t, status); if (VERBOSE) { fprintf(stdout, "Compacted data breakdown:\n"); /*fprintf(stdout, "Compact array stage1 top: %i, stage2 top: %i\n", t->mapping->stage1Top, t->mapping->stage2Top);*/ fprintf(stdout, "Number of contractions: %i\n", noOfContractions); fprintf(stdout, "Contraction image size: %i\n", t->image->contractionSize); fprintf(stdout, "Expansions size: %i\n", t->expansions->position); } writeOutData(myData, &consts, contractionCEs, noOfContractions, outputDir, copyright, status); InverseTableHeader *inverse = assembleInverseTable(status); writeOutInverseData(inverse, outputDir, copyright, status); uprv_uca_closeTempTable(t); uprv_free(myD); uprv_free(opts); uprv_free(myData); uprv_free(inverse); fclose(data); return 0; } static UOption options[]={ UOPTION_HELP_H, /* 0 Numbers for those who*/ UOPTION_HELP_QUESTION_MARK, /* 1 can't count. */ UOPTION_COPYRIGHT, /* 2 */ UOPTION_VERSION, /* 3 */ UOPTION_DESTDIR, /* 4 */ UOPTION_SOURCEDIR, /* 5 */ UOPTION_VERBOSE, /* 6 */ UOPTION_ICUDATADIR /* 7 */ /* weiv can't count :))))) */ }; int main(int argc, char* argv[]) { UErrorCode status = U_ZERO_ERROR; const char* destdir = NULL; const char* srcDir = NULL; char filename[300]; char *basename = NULL; const char *copyright = NULL; U_MAIN_INIT_ARGS(argc, argv); /* preset then read command line options */ options[4].value=u_getDataDirectory(); options[5].value=""; argc=u_parseArgs(argc, argv, sizeof(options)/sizeof(options[0]), options); /* error handling, printing usage message */ if(argc<0) { fprintf(stderr, "error in command line argument \"%s\"\n", argv[-argc]); } else if(argc<2) { argc=-1; } if(options[0].doesOccur || options[1].doesOccur) { fprintf(stderr, "usage: %s [-options] file\n" "\tRead in UCA collation text data and write out the binary collation data\n" "options:\n" "\t-h or -? or --help this usage text\n" "\t-V or --version show a version message\n" "\t-c or --copyright include a copyright notice\n" "\t-d or --destdir destination directory, followed by the path\n" "\t-s or --sourcedir source directory, followed by the path\n" "\t-v or --verbose turn on verbose output\n" "\t-i or --icudatadir directory for locating any needed intermediate data files,\n" "\t followed by path, defaults to %s\n", argv[0], u_getDataDirectory()); return argc<0 ? U_ILLEGAL_ARGUMENT_ERROR : U_ZERO_ERROR; } if(options[3].doesOccur) { fprintf(stdout, "genuca version %hu.%hu, ICU tool to read UCA text data and create UCA data tables for collation.\n", ucaDataInfo.formatVersion[0], ucaDataInfo.formatVersion[1]); fprintf(stdout, "Copyright (C) 2000-2001, International Business Machines\n"); fprintf(stdout, "Corporation and others. All Rights Reserved.\n"); exit(0); } /* get the options values */ destdir = options[4].value; srcDir = options[5].value; VERBOSE = options[6].doesOccur; if (options[2].doesOccur) { copyright = U_COPYRIGHT_STRING; } if (options[7].doesOccur) { u_setDataDirectory(options[7].value); } /* prepare the filename beginning with the source dir */ uprv_strcpy(filename, srcDir); basename=filename+uprv_strlen(filename); if(basename>filename && *(basename-1)!=U_FILE_SEP_CHAR) { *basename++ = U_FILE_SEP_CHAR; } if(argc < 0) { uprv_strcpy(basename, "FractionalUCA.txt"); } else { argv++; uprv_strcpy(basename, getLongPathname(*argv)); } #if 0 if(u_getCombiningClass(0x0053) == 0) { fprintf(stderr, "SEVERE ERROR: Normalization data is not functioning! Bailing out. Was not able to load unorm.dat.\n"); exit(1); } #endif return write_uca_table(filename, destdir, copyright, &status); } /* * Hey, Emacs, please set the following: * * Local Variables: * indent-tabs-mode: nil * End: * */