/* ******************************************************************************* * * Copyright (C) 2000-2003, International Business Machines * Corporation and others. All Rights Reserved. * ******************************************************************************* * * File reslist.c * * Modification History: * * Date Name Description * 02/21/00 weiv Creation. ******************************************************************************* */ #include #include #include "reslist.h" #include "unewdata.h" #include "unicode/ures.h" #include "errmsg.h" #define BIN_ALIGNMENT 16 static UBool gIncludeCopyright = FALSE; uint32_t res_write(UNewDataMemory *mem, struct SResource *res, uint32_t usedOffset, UErrorCode *status); static const UDataInfo dataInfo= { sizeof(UDataInfo), 0, U_IS_BIG_ENDIAN, U_CHARSET_FAMILY, sizeof(UChar), 0, {0x52, 0x65, 0x73, 0x42}, /* dataFormat="resb" */ {1, 1, 0, 0}, /* formatVersion */ {1, 4, 0, 0} /* dataVersion take a look at version inside parsed resb*/ }; static uint8_t calcPadding(uint32_t size) { /* returns space we need to pad */ return (uint8_t) ((size % sizeof(uint32_t)) ? (sizeof(uint32_t) - (size % sizeof(uint32_t))) : 0); } void setIncludeCopyright(UBool val){ gIncludeCopyright=val; } UBool getIncludeCopyright(void){ return gIncludeCopyright; } /* Writing Functions */ static uint32_t string_write(UNewDataMemory *mem, struct SResource *res, uint32_t usedOffset, UErrorCode *status) { udata_write32(mem, res->u.fString.fLength); udata_writeUString(mem, res->u.fString.fChars, res->u.fString.fLength + 1); udata_writePadding(mem, calcPadding(res->fSize)); return usedOffset; } /* Writing Functions */ static uint32_t alias_write(UNewDataMemory *mem, struct SResource *res, uint32_t usedOffset, UErrorCode *status) { udata_write32(mem, res->u.fString.fLength); udata_writeUString(mem, res->u.fString.fChars, res->u.fString.fLength + 1); udata_writePadding(mem, calcPadding(res->fSize)); return usedOffset; } static uint32_t array_write(UNewDataMemory *mem, struct SResource *res, uint32_t usedOffset, UErrorCode *status) { uint32_t *resources = NULL; uint32_t i = 0; struct SResource *current = NULL; if (U_FAILURE(*status)) { return 0; } if (res->u.fArray.fCount > 0) { resources = (uint32_t *) uprv_malloc(sizeof(uint32_t) * res->u.fArray.fCount); if (resources == NULL) { *status = U_MEMORY_ALLOCATION_ERROR; return 0; } current = res->u.fArray.fFirst; i = 0; while (current != NULL) { if (current->fType == URES_INT) { resources[i] = (current->fType << 28) | (current->u.fIntValue.fValue & 0xFFFFFFF); } else if (current->fType == URES_BINARY) { uint32_t uo = usedOffset; usedOffset = res_write(mem, current, usedOffset, status); resources[i] = (current->fType << 28) | (usedOffset >> 2); usedOffset += current->fSize + calcPadding(current->fSize) - (usedOffset - uo); } else { usedOffset = res_write(mem, current, usedOffset, status); resources[i] = (current->fType << 28) | (usedOffset >> 2); usedOffset += current->fSize + calcPadding(current->fSize); } i++; current = current->fNext; } /* usedOffset += res->fSize + pad; */ udata_write32(mem, res->u.fArray.fCount); udata_writeBlock(mem, resources, sizeof(uint32_t) * res->u.fArray.fCount); uprv_free(resources); } else { /* array is empty */ udata_write32(mem, 0); } return usedOffset; } static uint32_t intvector_write(UNewDataMemory *mem, struct SResource *res, uint32_t usedOffset, UErrorCode *status) { uint32_t i = 0; udata_write32(mem, res->u.fIntVector.fCount); for(i = 0; iu.fIntVector.fCount; i++) { udata_write32(mem, res->u.fIntVector.fArray[i]); } return usedOffset; } static uint32_t bin_write(UNewDataMemory *mem, struct SResource *res, uint32_t usedOffset, UErrorCode *status) { uint32_t pad = 0; uint32_t extrapad = calcPadding(res->fSize); uint32_t dataStart = usedOffset + sizeof(res->u.fBinaryValue.fLength); if (dataStart % BIN_ALIGNMENT) { pad = (BIN_ALIGNMENT - dataStart % BIN_ALIGNMENT); udata_writePadding(mem, pad); usedOffset += pad; } udata_write32(mem, res->u.fBinaryValue.fLength); if (res->u.fBinaryValue.fLength > 0) { udata_writeBlock(mem, res->u.fBinaryValue.fData, res->u.fBinaryValue.fLength); } udata_writePadding(mem, (BIN_ALIGNMENT - pad + extrapad)); return usedOffset; } static uint32_t int_write(UNewDataMemory *mem, struct SResource *res, uint32_t usedOffset, UErrorCode *status) { return usedOffset; } static uint32_t table_write(UNewDataMemory *mem, struct SResource *res, uint32_t usedOffset, UErrorCode *status) { uint8_t pad = 0; uint32_t i = 0; uint16_t *keys16 = NULL; int32_t *keys32 = NULL; uint32_t *resources = NULL; struct SResource *current = NULL; if (U_FAILURE(*status)) { return 0; } pad = calcPadding(res->fSize); if (res->u.fTable.fCount > 0) { if(res->fType == URES_TABLE) { keys16 = (uint16_t *) uprv_malloc(sizeof(uint16_t) * res->u.fTable.fCount); if (keys16 == NULL) { *status = U_MEMORY_ALLOCATION_ERROR; return 0; } } else { keys32 = (int32_t *) uprv_malloc(sizeof(int32_t) * res->u.fTable.fCount); if (keys32 == NULL) { *status = U_MEMORY_ALLOCATION_ERROR; return 0; } } resources = (uint32_t *) uprv_malloc(sizeof(uint32_t) * res->u.fTable.fCount); if (resources == NULL) { uprv_free(keys16); uprv_free(keys32); *status = U_MEMORY_ALLOCATION_ERROR; return 0; } current = res->u.fTable.fFirst; i = 0; while (current != NULL) { assert(i < res->u.fTable.fCount); /* where the key is */ if(res->fType == URES_TABLE) { keys16[i] = (uint16_t) current->fKey; } else { keys32[i] = current->fKey; } if (current->fType == URES_INT) { resources[i] = (current->fType << 28) | (current->u.fIntValue.fValue & 0xFFFFFFF); } else if (current->fType == URES_BINARY) { uint32_t uo = usedOffset; usedOffset = res_write(mem, current, usedOffset, status); resources[i] = (current->fType << 28) | (usedOffset >> 2); usedOffset += current->fSize + calcPadding(current->fSize) - (usedOffset - uo); } else { usedOffset = res_write(mem, current, usedOffset, status); resources[i] = (current->fType << 28) | (usedOffset >> 2); usedOffset += current->fSize + calcPadding(current->fSize); } i++; current = current->fNext; } if(res->fType == URES_TABLE) { udata_write16(mem, (uint16_t)res->u.fTable.fCount); udata_writeBlock(mem, keys16, sizeof(uint16_t) * res->u.fTable.fCount); udata_writePadding(mem, pad); } else { udata_write32(mem, res->u.fTable.fCount); udata_writeBlock(mem, keys32, sizeof(int32_t) * res->u.fTable.fCount); } udata_writeBlock(mem, resources, sizeof(uint32_t) * res->u.fTable.fCount); uprv_free(keys16); uprv_free(keys32); uprv_free(resources); } else { /* table is empty */ if(res->fType == URES_TABLE) { udata_write16(mem, 0); udata_writePadding(mem, pad); } else { udata_write32(mem, 0); } } return usedOffset; } uint32_t res_write(UNewDataMemory *mem, struct SResource *res, uint32_t usedOffset, UErrorCode *status) { if (U_FAILURE(*status)) { return 0; } if (res != NULL) { switch (res->fType) { case URES_STRING: return string_write (mem, res, usedOffset, status); case URES_ALIAS: return alias_write (mem, res, usedOffset, status); case URES_INT_VECTOR: return intvector_write (mem, res, usedOffset, status); case URES_BINARY: return bin_write (mem, res, usedOffset, status); case URES_INT: return int_write (mem, res, usedOffset, status); case URES_ARRAY: return array_write (mem, res, usedOffset, status); case URES_TABLE: case URES_TABLE32: return table_write (mem, res, usedOffset, status); default: break; } } *status = U_INTERNAL_PROGRAM_ERROR; return 0; } void bundle_write(struct SRBRoot *bundle, const char *outputDir, const char *outputPkg, char *writtenFilename, int writtenFilenameLen, UErrorCode *status) { UNewDataMemory *mem = NULL; uint8_t pad = 0; uint32_t root = 0; uint32_t usedOffset = 0; uint32_t top, size; char dataName[1024]; int32_t indexes[URES_INDEX_TOP]; if (writtenFilename && writtenFilenameLen) { *writtenFilename = 0; } if (U_FAILURE(*status)) { return; } if (writtenFilename) { int32_t off = 0, len = 0; if (outputDir) { len = (int32_t)uprv_strlen(outputDir); if (len > writtenFilenameLen) { len = writtenFilenameLen; } uprv_strncpy(writtenFilename, outputDir, len); } if (writtenFilenameLen -= len) { off += len; writtenFilename[off] = U_FILE_SEP_CHAR; if (--writtenFilenameLen) { ++off; if(outputPkg != NULL) { uprv_strcpy(writtenFilename+off, outputPkg); off += (int32_t)uprv_strlen(outputPkg); writtenFilename[off] = '_'; ++off; } len = (int32_t)uprv_strlen(bundle->fLocale); if (len > writtenFilenameLen) { len = writtenFilenameLen; } uprv_strncpy(writtenFilename + off, bundle->fLocale, len); if (writtenFilenameLen -= len) { off += len; len = 5; if (len > writtenFilenameLen) { len = writtenFilenameLen; } uprv_strncpy(writtenFilename + off, ".res", len); } } } } if(outputPkg) { uprv_strcpy(dataName, outputPkg); uprv_strcat(dataName, "_"); uprv_strcat(dataName, bundle->fLocale); } else { uprv_strcpy(dataName, bundle->fLocale); } mem = udata_create(outputDir, "res", dataName, &dataInfo, (gIncludeCopyright==TRUE)? U_COPYRIGHT_STRING:NULL, status); if(U_FAILURE(*status)){ return; } pad = calcPadding(bundle->fKeyPoint); usedOffset = bundle->fKeyPoint + pad ; /* top of the strings */ /* we're gonna put the main table at the end */ top = usedOffset + bundle->fRoot->u.fTable.fChildrenSize; root = (top) >> 2 | (bundle->fRoot->fType << 28); /* write the root item */ udata_write32(mem, root); /* add to top the size of the root item */ top += bundle->fRoot->fSize; top += calcPadding(top); /* * formatVersion 1.1 (ICU 2.8): * write int32_t indexes[] after root and before the strings * to make it easier to parse resource bundles in icuswap or from Java etc. */ indexes[URES_INDEX_LENGTH]= URES_INDEX_TOP; indexes[URES_INDEX_STRINGS_TOP]= (int32_t)(usedOffset>>2); indexes[URES_INDEX_RESOURCES_TOP]= (int32_t)(top>>2); indexes[URES_INDEX_BUNDLE_TOP]= indexes[URES_INDEX_RESOURCES_TOP]; indexes[URES_INDEX_MAX_TABLE_LENGTH]= bundle->fMaxTableLength; /* write the indexes[] */ udata_writeBlock(mem, indexes, sizeof(indexes)); /* write the table key strings */ udata_writeBlock(mem, bundle->fKeys+URES_STRINGS_BOTTOM, bundle->fKeyPoint-URES_STRINGS_BOTTOM); /* write the padding bytes after the table key strings */ udata_writePadding(mem, pad); /* write all of the bundle contents: the root item and its children */ usedOffset = res_write(mem, bundle->fRoot, usedOffset, status); size = udata_finish(mem, status); if(top != size) { fprintf(stderr, "genrb error: wrote %u bytes but counted %u\n", size, top); *status = U_INTERNAL_PROGRAM_ERROR; } } /* Opening Functions */ struct SResource* res_open(const struct UString* comment, UErrorCode* status){ struct SResource *res; if (U_FAILURE(*status)) { return NULL; } res = (struct SResource *) uprv_malloc(sizeof(struct SResource)); if (res == NULL) { *status = U_MEMORY_ALLOCATION_ERROR; return NULL; } uprv_memset(res, 0, sizeof(struct SResource)); res->fComment = NULL; if(comment != NULL){ res->fComment = (struct UString *) uprv_malloc(sizeof(struct UString)); if(res->fComment == NULL){ *status = U_MEMORY_ALLOCATION_ERROR; return NULL; } ustr_init(res->fComment); ustr_cpy(res->fComment, comment, status); } return res; } struct SResource* table_open(struct SRBRoot *bundle, char *tag, const struct UString* comment, UErrorCode *status) { struct SResource *res = res_open(comment, status); res->fKey = bundle_addtag(bundle, tag, status); if (U_FAILURE(*status)) { uprv_free(res->fComment); uprv_free(res); return NULL; } res->fNext = NULL; /* * always open a table not a table32 in case it remains empty - * try to use table32 only when necessary */ res->fType = URES_TABLE; res->fSize = sizeof(uint16_t); res->u.fTable.fCount = 0; res->u.fTable.fChildrenSize = 0; res->u.fTable.fFirst = NULL; res->u.fTable.fRoot = bundle; return res; } struct SResource* array_open(struct SRBRoot *bundle, char *tag, const struct UString* comment, UErrorCode *status) { struct SResource *res = res_open(comment, status); if (U_FAILURE(*status)) { return NULL; } res->fType = URES_ARRAY; res->fKey = bundle_addtag(bundle, tag, status); if (U_FAILURE(*status)) { uprv_free(res->fComment); uprv_free(res); return NULL; } res->fNext = NULL; res->fSize = sizeof(int32_t); res->u.fArray.fCount = 0; res->u.fArray.fChildrenSize = 0; res->u.fArray.fFirst = NULL; res->u.fArray.fLast = NULL; return res; } struct SResource *string_open(struct SRBRoot *bundle, char *tag, const UChar *value, int32_t len, const struct UString* comment, UErrorCode *status) { struct SResource *res = res_open(comment, status); if (U_FAILURE(*status)) { return NULL; } res->fType = URES_STRING; res->fKey = bundle_addtag(bundle, tag, status); if (U_FAILURE(*status)) { uprv_free(res->fComment); uprv_free(res); return NULL; } res->fNext = NULL; res->u.fString.fLength = len; res->u.fString.fChars = (UChar *) uprv_malloc(sizeof(UChar) * (len + 1)); if (res->u.fString.fChars == NULL) { *status = U_MEMORY_ALLOCATION_ERROR; uprv_free(res); return NULL; } uprv_memcpy(res->u.fString.fChars, value, sizeof(UChar) * (len + 1)); res->fSize = sizeof(int32_t) + sizeof(UChar) * (len+1); return res; } /* TODO: make alias_open and string_open use the same code */ struct SResource *alias_open(struct SRBRoot *bundle, char *tag, UChar *value, int32_t len, const struct UString* comment, UErrorCode *status) { struct SResource *res = res_open(comment, status); if (U_FAILURE(*status)) { return NULL; } res->fType = URES_ALIAS; res->fKey = bundle_addtag(bundle, tag, status); if (U_FAILURE(*status)) { uprv_free(res->fComment); uprv_free(res); return NULL; } res->fNext = NULL; res->u.fString.fLength = len; res->u.fString.fChars = (UChar *) uprv_malloc(sizeof(UChar) * (len + 1)); if (res->u.fString.fChars == NULL) { *status = U_MEMORY_ALLOCATION_ERROR; uprv_free(res); return NULL; } uprv_memcpy(res->u.fString.fChars, value, sizeof(UChar) * (len + 1)); res->fSize = sizeof(int32_t) + sizeof(UChar) * (len + 1); return res; } struct SResource* intvector_open(struct SRBRoot *bundle, char *tag, const struct UString* comment, UErrorCode *status) { struct SResource *res = res_open(comment, status); if (U_FAILURE(*status)) { return NULL; } res->fType = URES_INT_VECTOR; res->fKey = bundle_addtag(bundle, tag, status); if (U_FAILURE(*status)) { uprv_free(res->fComment); uprv_free(res); return NULL; } res->fNext = NULL; res->fSize = sizeof(int32_t); res->u.fIntVector.fCount = 0; res->u.fIntVector.fArray = (uint32_t *) uprv_malloc(sizeof(uint32_t) * RESLIST_MAX_INT_VECTOR); if (res->u.fIntVector.fArray == NULL) { *status = U_MEMORY_ALLOCATION_ERROR; uprv_free(res); return NULL; } return res; } struct SResource *int_open(struct SRBRoot *bundle, char *tag, int32_t value, const struct UString* comment, UErrorCode *status) { struct SResource *res = res_open(comment, status); if (U_FAILURE(*status)) { return NULL; } res->fType = URES_INT; res->fKey = bundle_addtag(bundle, tag, status); if (U_FAILURE(*status)) { uprv_free(res->fComment); uprv_free(res); return NULL; } res->fSize = 0; res->fNext = NULL; res->u.fIntValue.fValue = value; return res; } struct SResource *bin_open(struct SRBRoot *bundle, const char *tag, uint32_t length, uint8_t *data, const char* fileName, const struct UString* comment, UErrorCode *status) { struct SResource *res = res_open(comment, status); if (U_FAILURE(*status)) { return NULL; } res->fType = URES_BINARY; res->fKey = bundle_addtag(bundle, tag, status); if (U_FAILURE(*status)) { uprv_free(res->fComment); uprv_free(res); return NULL; } res->fNext = NULL; res->u.fBinaryValue.fLength = length; res->u.fBinaryValue.fFileName = NULL; if(fileName!=NULL && uprv_strcmp(fileName, "") !=0){ res->u.fBinaryValue.fFileName = (char*) uprv_malloc(sizeof(char) * (uprv_strlen(fileName)+1)); uprv_strcpy(res->u.fBinaryValue.fFileName,fileName); } if (length > 0) { res->u.fBinaryValue.fData = (uint8_t *) uprv_malloc(sizeof(uint8_t) * length); if (res->u.fBinaryValue.fData == NULL) { *status = U_MEMORY_ALLOCATION_ERROR; uprv_free(res); return NULL; } uprv_memcpy(res->u.fBinaryValue.fData, data, length); } else { res->u.fBinaryValue.fData = NULL; } res->fSize = sizeof(int32_t) + sizeof(uint8_t) * length + BIN_ALIGNMENT; return res; } struct SRBRoot *bundle_open(const struct UString* comment, UErrorCode *status) { struct SRBRoot *bundle = NULL; if (U_FAILURE(*status)) { return NULL; } bundle = (struct SRBRoot *) uprv_malloc(sizeof(struct SRBRoot)); if (bundle == NULL) { *status = U_MEMORY_ALLOCATION_ERROR; return 0; } uprv_memset(bundle, 0, sizeof(struct SRBRoot)); bundle->fLocale = NULL; bundle->fKeys = (char *) uprv_malloc(sizeof(char) * KEY_SPACE_SIZE); bundle->fKeysCapacity = KEY_SPACE_SIZE; if(comment != NULL){ } if (bundle->fKeys == NULL) { *status = U_MEMORY_ALLOCATION_ERROR; uprv_free(bundle); return NULL; } /* formatVersion 1.1: start fKeyPoint after the root item and indexes[] */ bundle->fKeyPoint = URES_STRINGS_BOTTOM; uprv_memset(bundle->fKeys, 0, URES_STRINGS_BOTTOM); bundle->fCount = 0; bundle->fRoot = table_open(bundle, NULL, comment, status); if (bundle->fRoot == NULL || U_FAILURE(*status)) { if (U_SUCCESS(*status)) { *status = U_MEMORY_ALLOCATION_ERROR; } uprv_free(bundle->fKeys); uprv_free(bundle); return NULL; } return bundle; } /* Closing Functions */ void table_close(struct SResource *table, UErrorCode *status) { struct SResource *current = NULL; struct SResource *prev = NULL; current = table->u.fTable.fFirst; while (current != NULL) { prev = current; current = current->fNext; res_close(prev, status); } table->u.fTable.fFirst = NULL; } void array_close(struct SResource *array, UErrorCode *status) { struct SResource *current = NULL; struct SResource *prev = NULL; current = array->u.fArray.fFirst; while (current != NULL) { prev = current; current = current->fNext; res_close(prev, status); } array->u.fArray.fFirst = NULL; } void string_close(struct SResource *string, UErrorCode *status) { if (string->u.fString.fChars != NULL) { uprv_free(string->u.fString.fChars); string->u.fString.fChars =NULL; } } void alias_close(struct SResource *alias, UErrorCode *status) { if (alias->u.fString.fChars != NULL) { uprv_free(alias->u.fString.fChars); alias->u.fString.fChars =NULL; } } void intvector_close(struct SResource *intvector, UErrorCode *status) { if (intvector->u.fIntVector.fArray != NULL) { uprv_free(intvector->u.fIntVector.fArray); intvector->u.fIntVector.fArray =NULL; } } void int_close(struct SResource *intres, UErrorCode *status) { /* Intentionally left blank */ } void bin_close(struct SResource *binres, UErrorCode *status) { if (binres->u.fBinaryValue.fData != NULL) { uprv_free(binres->u.fBinaryValue.fData); binres->u.fBinaryValue.fData = NULL; } } void res_close(struct SResource *res, UErrorCode *status) { if (res != NULL) { switch(res->fType) { case URES_STRING: string_close(res, status); break; case URES_ALIAS: alias_close(res, status); break; case URES_INT_VECTOR: intvector_close(res, status); break; case URES_BINARY: bin_close(res, status); break; case URES_INT: int_close(res, status); break; case URES_ARRAY: array_close(res, status); break; case URES_TABLE: case URES_TABLE32: table_close(res, status); break; default: /* Shouldn't happen */ break; } uprv_free(res); } } void bundle_close(struct SRBRoot *bundle, UErrorCode *status) { struct SResource *current = NULL; struct SResource *prev = NULL; if (bundle->fRoot != NULL) { current = bundle->fRoot->u.fTable.fFirst; while (current != NULL) { prev = current; current = current->fNext; res_close(prev, status); } uprv_free(bundle->fRoot); } if (bundle->fLocale != NULL) { uprv_free(bundle->fLocale); } if (bundle->fKeys != NULL) { uprv_free(bundle->fKeys); } uprv_free(bundle); } /* Adding Functions */ void table_add(struct SResource *table, struct SResource *res, int linenumber, UErrorCode *status) { struct SResource *current = NULL; struct SResource *prev = NULL; struct SResTable *list; if (U_FAILURE(*status)) { return; } /* remember this linenumber to report to the user if there is a duplicate key */ res->line = linenumber; /* here we need to traverse the list */ list = &(table->u.fTable); if(table->fType == URES_TABLE && res->fKey > 0xffff) { /* this table straddles the 64k strings boundary, update to a table32 */ table->fType = URES_TABLE32; /* * increase the size because count and each string offset * increase from uint16_t to int32_t */ table->fSize += (1 + list->fCount) * 2; } ++(list->fCount); if(list->fCount > (uint32_t)list->fRoot->fMaxTableLength) { list->fRoot->fMaxTableLength = list->fCount; } /* * URES_TABLE: 6 bytes = 1 uint16_t key string offset + 1 uint32_t Resource * URES_TABLE32: 8 bytes = 1 int32_t key string offset + 1 uint32_t Resource */ table->fSize += table->fType == URES_TABLE ? 6 : 8; table->u.fTable.fChildrenSize += res->fSize + calcPadding(res->fSize); if (res->fType == URES_TABLE || res->fType == URES_TABLE32) { table->u.fTable.fChildrenSize += res->u.fTable.fChildrenSize; } else if (res->fType == URES_ARRAY) { table->u.fTable.fChildrenSize += res->u.fArray.fChildrenSize; } /* is list still empty? */ if (list->fFirst == NULL) { list->fFirst = res; res->fNext = NULL; return; } current = list->fFirst; while (current != NULL) { if (uprv_strcmp(((list->fRoot->fKeys) + (current->fKey)), ((list->fRoot->fKeys) + (res->fKey))) < 0) { prev = current; current = current->fNext; } else if (uprv_strcmp(((list->fRoot->fKeys) + (current->fKey)), ((list->fRoot->fKeys) + (res->fKey))) > 0) { /* we're either in front of list, or in middle */ if (prev == NULL) { /* front of the list */ list->fFirst = res; } else { /* middle of the list */ prev->fNext = res; } res->fNext = current; return; } else { /* Key already exists! ERROR! */ error(linenumber, "duplicate key '%s' in table, first appeared at line %d", list->fRoot->fKeys + current->fKey, current->line); *status = U_UNSUPPORTED_ERROR; return; } } /* end of list */ prev->fNext = res; res->fNext = NULL; } void array_add(struct SResource *array, struct SResource *res, UErrorCode *status) { if (U_FAILURE(*status)) { return; } if (array->u.fArray.fFirst == NULL) { array->u.fArray.fFirst = res; array->u.fArray.fLast = res; } else { array->u.fArray.fLast->fNext = res; array->u.fArray.fLast = res; } (array->u.fArray.fCount)++; array->fSize += sizeof(uint32_t); array->u.fArray.fChildrenSize += res->fSize + calcPadding(res->fSize); if (res->fType == URES_TABLE || res->fType == URES_TABLE32) { array->u.fArray.fChildrenSize += res->u.fTable.fChildrenSize; } else if (res->fType == URES_ARRAY) { array->u.fArray.fChildrenSize += res->u.fArray.fChildrenSize; } } void intvector_add(struct SResource *intvector, int32_t value, UErrorCode *status) { if (U_FAILURE(*status)) { return; } *(intvector->u.fIntVector.fArray + intvector->u.fIntVector.fCount) = value; intvector->u.fIntVector.fCount++; intvector->fSize += sizeof(uint32_t); } /* Misc Functions */ void bundle_setlocale(struct SRBRoot *bundle, UChar *locale, UErrorCode *status) { if(U_FAILURE(*status)) { return; } if (bundle->fLocale!=NULL) { uprv_free(bundle->fLocale); } bundle->fLocale= (char*) uprv_malloc(sizeof(char) * (u_strlen(locale)+1)); if(bundle->fLocale == NULL) { *status = U_MEMORY_ALLOCATION_ERROR; return; } /*u_strcpy(bundle->fLocale, locale);*/ u_UCharsToChars(locale, bundle->fLocale, u_strlen(locale)+1); } int32_t bundle_addtag(struct SRBRoot *bundle, const char *tag, UErrorCode *status) { int32_t keypos, length; if (U_FAILURE(*status)) { return -1; } if (tag == NULL) { /* do not set an error: the root table has a NULL tag */ return -1; } keypos = bundle->fKeyPoint; bundle->fKeyPoint += length = (int32_t) (uprv_strlen(tag) + 1); if (bundle->fKeyPoint >= bundle->fKeysCapacity) { /* overflow - resize the keys buffer */ bundle->fKeysCapacity += KEY_SPACE_SIZE; bundle->fKeys = uprv_realloc(bundle->fKeys, bundle->fKeysCapacity); if(bundle->fKeys == NULL) { *status = U_MEMORY_ALLOCATION_ERROR; return -1; } } uprv_memcpy(bundle->fKeys + keypos, tag, length); return keypos; }