/* -*- Mode: C++; tab-width: 4; indent-tabs-mode: nil; c-basic-offset: 4 -*- */ /* * This file is part of the LibreOffice project. * * This Source Code Form is subject to the terms of the Mozilla Public * License, v. 2.0. If a copy of the MPL was not distributed with this * file, You can obtain one at http://mozilla.org/MPL/2.0/. * * This file incorporates work covered by the following license notice: * * Licensed to the Apache Software Foundation (ASF) under one or more * contributor license agreements. See the NOTICE file distributed * with this work for additional information regarding copyright * ownership. The ASF licenses this file to you under the Apache * License, Version 2.0 (the "License"); you may not use this file * except in compliance with the License. You may obtain a copy of * the License at http://www.apache.org/licenses/LICENSE-2.0 . */ #include #include #include #include #include #include #include #include #include void make_hhc_char(FILE *sfp, FILE *cfp); void make_stc_char(FILE *sfp, FILE *cfp); void make_stc_word(FILE *sfp, FILE *cfp); /* Main Procedure */ SAL_IMPLEMENT_MAIN_WITH_ARGS(argc, argv) { FILE *sfp, *cfp; if (argc < 4) exit(-1); sfp = fopen(argv[2], "rb"); // open the source file for read; if (sfp == NULL) { fprintf(stderr, "Opening the dictionary source file %s for reading failed: %s\n", argv[1], strerror(errno)); exit(1); } // create the C source file to write cfp = fopen(argv[3], "wb"); if (cfp == NULL) { fclose(sfp); fprintf(stderr, "Opening %s for writing failed: %s\n", argv[3], strerror(errno)); exit(1); } fprintf(cfp, "/*\n"); fprintf(cfp, " * Copyright(c) 1999 - 2000, Sun Microsystems, Inc.\n"); fprintf(cfp, " * All Rights Reserved.\n"); fprintf(cfp, " */\n\n"); fprintf(cfp, "/* !!!The file is generated automatically. DONOT edit the file manually!!! */\n\n"); fprintf(cfp, "#include \n"); fprintf(cfp, "#include \n"); fprintf(cfp, "\nextern \"C\" {\n"); if (strcmp(argv[1], "hhc_char") == 0) make_hhc_char(sfp, cfp); else if (strcmp(argv[1], "stc_char") == 0) make_stc_char(sfp, cfp); else if (strcmp(argv[1], "stc_word") == 0) make_stc_word(sfp, cfp); fprintf (cfp, "}\n"); fclose(sfp); fclose(cfp); return 0; } // end of main // Hangul/Hanja character conversion void make_hhc_char(FILE *sfp, FILE *cfp) { sal_Int32 count, address, i, j, k; sal_Unicode Hanja2HangulData[0x10000]; for (i = 0; i < 0x10000; i++) { Hanja2HangulData[i] = 0; } sal_uInt16 Hangul2HanjaData[10000][3]; // generate main dict. data array fprintf(cfp, "\nstatic const sal_Unicode Hangul2HanjaData[] = {"); sal_Char Cstr[1024]; count = 0; address = 0; while (fgets(Cstr, 1024, sfp)) { // input file is in UTF-8 encoding (Hangul:Hanja) // don't convert last new line character to Ostr. OUString Ostr(Cstr, strlen(Cstr) - 1, RTL_TEXTENCODING_UTF8); const sal_Unicode *Ustr = Ostr.getStr(); sal_Int32 len = Ostr.getLength(); Hangul2HanjaData[count][0] = Ustr[0]; Hangul2HanjaData[count][1] = sal::static_int_cast( address ); Hangul2HanjaData[count][2] = sal::static_int_cast( len - 2 ); count++; for (i = 2; i < len; i++) { Hanja2HangulData[Ustr[i]] = Ustr[0]; if (address++ % 16 == 0) fprintf(cfp, "\n\t"); fprintf(cfp, "0x%04x, ", Ustr[i]); } } fprintf(cfp, "\n};\n"); fprintf(cfp, "\nstatic const com::sun::star::i18n::Hangul_Index Hangul2HanjaIndex[] = {\n"); for (i = 0; i < count; i++) fprintf(cfp, "\t{ 0x%04x, 0x%04x, 0x%02x },\n", Hangul2HanjaData[i][0], Hangul2HanjaData[i][1], Hangul2HanjaData[i][2]); fprintf(cfp, "};\n"); fprintf(cfp, "\nstatic const sal_uInt16 Hanja2HangulIndex[] = {"); address=0; for (i = 0; i < 0x10; i++) { fprintf(cfp, "\n\t"); for (j = 0; j < 0x10; j++) { for (k = 0; k < 0x100; k++) { if (Hanja2HangulData[((i*0x10)+j)*0x100+k] != 0) break; } fprintf( cfp, "0x%04lx, ", sal::static_int_cast< unsigned long >( k < 0x100 ? (address++)*0x100 : 0xFFFF)); } } fprintf(cfp, "\n};\n"); fprintf(cfp, "\nstatic const sal_Unicode Hanja2HangulData[] = {"); for (i = 0; i < 0x100; i++) { for (j = 0; j < 0x100; j++) { if (Hanja2HangulData[i*0x100+j] != 0) break; } if (j < 0x100) { for (j = 0; j < 0x10; j++) { fprintf(cfp, "\n\t"); for (k = 0; k < 0x10; k++) { sal_Unicode c = Hanja2HangulData[((i*0x10+j)*0x10)+k]; fprintf(cfp, "0x%04x, ", c ? c : 0xFFFF); } } } } fprintf(cfp, "\n};\n"); // create function to return arrays fprintf (cfp, "\tconst sal_Unicode* getHangul2HanjaData() { return Hangul2HanjaData; }\n"); fprintf (cfp, "\tconst com::sun::star::i18n::Hangul_Index* getHangul2HanjaIndex() { return Hangul2HanjaIndex; }\n"); fprintf (cfp, "\tsal_Int16 getHangul2HanjaIndexCount() { return sizeof(Hangul2HanjaIndex) / sizeof(com::sun::star::i18n::Hangul_Index); }\n"); fprintf (cfp, "\tconst sal_uInt16* getHanja2HangulIndex() { return Hanja2HangulIndex; }\n"); fprintf (cfp, "\tconst sal_Unicode* getHanja2HangulData() { return Hanja2HangulData; }\n"); } // Simplified/Traditional Chinese character conversion void make_stc_char(FILE *sfp, FILE *cfp) { sal_Int32 address, i, j, k; sal_Unicode SChinese2TChineseData[0x10000]; sal_Unicode SChinese2VChineseData[0x10000]; sal_Unicode TChinese2SChineseData[0x10000]; for (i = 0; i < 0x10000; i++) { SChinese2TChineseData[i] = 0; SChinese2VChineseData[i] = 0; TChinese2SChineseData[i] = 0; } sal_Char Cstr[1024]; while (fgets(Cstr, 1024, sfp)) { // input file is in UTF-8 encoding (SChinese:TChinese) // don't convert last new line character to Ostr. OUString Ostr(Cstr, strlen(Cstr) - 1, RTL_TEXTENCODING_UTF8); const sal_Unicode *Ustr = Ostr.getStr(); sal_Int32 len = Ostr.getLength(); if (Ustr[1] == 'v') SChinese2VChineseData[Ustr[0]] = Ustr[2]; else { SChinese2TChineseData[Ustr[0]] = Ustr[2]; if (SChinese2VChineseData[Ustr[0]] == 0) SChinese2VChineseData[Ustr[0]] = Ustr[2]; } for (i = 2; i < len; i++) TChinese2SChineseData[Ustr[i]] = Ustr[0]; } fprintf(cfp, "\nstatic const sal_uInt16 STC_CharIndex_S2T[] = {"); address=0; for (i = 0; i < 0x10; i++) { fprintf(cfp, "\n\t"); for (j = 0; j < 0x10; j++) { for (k = 0; k < 0x100; k++) { if (SChinese2TChineseData[((i*0x10)+j)*0x100+k] != 0) break; } fprintf( cfp, "0x%04lx, ", sal::static_int_cast< unsigned long >( k < 0x100 ? (address++)*0x100 : 0xFFFF)); } } fprintf(cfp, "\n};\n"); fprintf(cfp, "\nstatic const sal_Unicode STC_CharData_S2T[] = {"); for (i = 0; i < 0x100; i++) { for (j = 0; j < 0x100; j++) { if (SChinese2TChineseData[i*0x100+j] != 0) break; } if (j < 0x100) { for (j = 0; j < 0x10; j++) { fprintf(cfp, "\n\t"); for (k = 0; k < 0x10; k++) { sal_Unicode c = SChinese2TChineseData[((i*0x10+j)*0x10)+k]; fprintf(cfp, "0x%04x, ", c ? c : 0xFFFF); } } } } fprintf(cfp, "\n};\n"); fprintf(cfp, "\nstatic const sal_uInt16 STC_CharIndex_S2V[] = {"); address=0; for (i = 0; i < 0x10; i++) { fprintf(cfp, "\n\t"); for (j = 0; j < 0x10; j++) { for (k = 0; k < 0x100; k++) { if (SChinese2VChineseData[((i*0x10)+j)*0x100+k] != 0) break; } fprintf( cfp, "0x%04lx, ", sal::static_int_cast< unsigned long >( k < 0x100 ? (address++)*0x100 : 0xFFFF)); } } fprintf(cfp, "\n};\n"); fprintf(cfp, "\nstatic const sal_Unicode STC_CharData_S2V[] = {"); for (i = 0; i < 0x100; i++) { for (j = 0; j < 0x100; j++) { if (SChinese2VChineseData[i*0x100+j] != 0) break; } if (j < 0x100) { for (j = 0; j < 0x10; j++) { fprintf(cfp, "\n\t"); for (k = 0; k < 0x10; k++) { sal_Unicode c = SChinese2VChineseData[((i*0x10+j)*0x10)+k]; fprintf(cfp, "0x%04x, ", c ? c : 0xFFFF); } } } } fprintf(cfp, "\n};\n"); fprintf(cfp, "\nstatic const sal_uInt16 STC_CharIndex_T2S[] = {"); address=0; for (i = 0; i < 0x10; i++) { fprintf(cfp, "\n\t"); for (j = 0; j < 0x10; j++) { for (k = 0; k < 0x100; k++) { if (TChinese2SChineseData[((i*0x10)+j)*0x100+k] != 0) break; } fprintf( cfp, "0x%04lx, ", sal::static_int_cast< unsigned long >( k < 0x100 ? (address++)*0x100 : 0xFFFF)); } } fprintf(cfp, "\n};\n"); fprintf(cfp, "\nstatic const sal_Unicode STC_CharData_T2S[] = {"); for (i = 0; i < 0x100; i++) { for (j = 0; j < 0x100; j++) { if (TChinese2SChineseData[i*0x100+j] != 0) break; } if (j < 0x100) { for (j = 0; j < 0x10; j++) { fprintf(cfp, "\n\t"); for (k = 0; k < 0x10; k++) { sal_Unicode c = TChinese2SChineseData[((i*0x10+j)*0x10)+k]; fprintf(cfp, "0x%04x, ", c ? c : 0xFFFF); } } } } fprintf(cfp, "\n};\n"); // create function to return arrays fprintf (cfp, "\tconst sal_uInt16* getSTC_CharIndex_S2T() { return STC_CharIndex_S2T; }\n"); fprintf (cfp, "\tconst sal_Unicode* getSTC_CharData_S2T() { return STC_CharData_S2T; }\n"); fprintf (cfp, "\tconst sal_uInt16* getSTC_CharIndex_S2V() { return STC_CharIndex_S2V; }\n"); fprintf (cfp, "\tconst sal_Unicode* getSTC_CharData_S2V() { return STC_CharData_S2V; }\n"); fprintf (cfp, "\tconst sal_uInt16* getSTC_CharIndex_T2S() { return STC_CharIndex_T2S; }\n"); fprintf (cfp, "\tconst sal_Unicode* getSTC_CharData_T2S() { return STC_CharData_T2S; }\n"); } typedef struct { sal_uInt16 address; sal_Int32 len; sal_Unicode *data; } Index; extern "C" { int Index_comp(const void* s1, const void* s2) { Index const *p1 = static_cast(s1), *p2 = static_cast(s2); int result = p1->len - p2->len; for (int i = 0; result == 0 && i < p1->len; i++) result = *(p1->data+i) - *(p2->data+i); return result; } } // Simplified/Traditional Chinese word conversion void make_stc_word(FILE *sfp, FILE *cfp) { sal_Int32 count, i, length; sal_Unicode STC_WordData[0x10000]; std::vector STC_WordEntry_S2T(0x10000); std::vector STC_WordEntry_T2S(0x10000); sal_Int32 count_S2T = 0, count_T2S = 0; sal_Int32 line = 0, char_total = 0; sal_Char Cstr[1024]; while (fgets(Cstr, 1024, sfp)) { // input file is in UTF-8 encoding (SChinese:TChinese) // don't convert last new line character to Ostr. OUString Ostr(Cstr, strlen(Cstr) - 1, RTL_TEXTENCODING_UTF8); sal_Int32 len = Ostr.getLength(); if (char_total + len + 1 > 0xFFFF) { fprintf(stderr, "Word Dictionary stc_word.dic is too big (line %ld)", sal::static_int_cast< long >(line)); return; } sal_Int32 sep=-1, eq=-1, gt=-1, lt=-1; if (((sep = eq = Ostr.indexOf('=')) > 0) || ((sep = gt = Ostr.indexOf('>')) > 0) || ((sep = lt = Ostr.indexOf('<')) > 0)) { if (eq > 0 || gt > 0) { STC_WordEntry_S2T[count_S2T].address = sal::static_int_cast( char_total ); STC_WordEntry_S2T[count_S2T].len = sep; STC_WordEntry_S2T[count_S2T++].data = &STC_WordData[char_total]; } if (eq > 0 || lt > 0) { STC_WordEntry_T2S[count_T2S].address = sal::static_int_cast( char_total + sep + 1 ); STC_WordEntry_T2S[count_T2S].len = len - sep - 1; STC_WordEntry_T2S[count_T2S++].data = &STC_WordData[char_total + sep + 1]; } for (i = 0; i < len; i++) STC_WordData[char_total++] = (i == sep) ? 0 : Ostr[i]; STC_WordData[char_total++] = 0; } else { fprintf(stderr, "Invalid entry in stc_word.dic (line %ld)", sal::static_int_cast< long >(line)); return; } line++; } if (char_total > 0) { fprintf(cfp, "\nstatic const sal_Unicode STC_WordData[] = {"); for (i = 0; i < char_total; i++) { if (i % 32 == 0) fprintf(cfp, "\n\t"); fprintf(cfp, "0x%04x, ", STC_WordData[i]); } fprintf(cfp, "\n};\n"); fprintf(cfp, "\nstatic sal_Int32 STC_WordData_Count = %ld;\n", sal::static_int_cast< long >(char_total)); // create function to return arrays fprintf (cfp, "\tconst sal_Unicode* getSTC_WordData(sal_Int32& count) { count = STC_WordData_Count; return STC_WordData; }\n"); } else { fprintf (cfp, "\tconst sal_Unicode* getSTC_WordData(sal_Int32& count) { count = 0; return NULL; }\n"); } sal_uInt16 STC_WordIndex[0x100]; if (count_S2T > 0) { qsort(&STC_WordEntry_S2T[0], count_S2T, sizeof(Index), Index_comp); fprintf(cfp, "\nstatic const sal_uInt16 STC_WordEntry_S2T[] = {"); count = 0; length = 0; for (i = 0; i < count_S2T; i++) { if (i % 32 == 0) fprintf(cfp, "\n\t"); fprintf(cfp, "0x%04x, ", STC_WordEntry_S2T[i].address); if (STC_WordEntry_S2T[i].len != length) { length = STC_WordEntry_S2T[i].len; while (count <= length) STC_WordIndex[count++] = sal::static_int_cast(i); } } fprintf(cfp, "\n};\n"); STC_WordIndex[count++] = sal::static_int_cast(i); fprintf(cfp, "\nstatic const sal_uInt16 STC_WordIndex_S2T[] = {"); for (i = 0; i < count; i++) { if (i % 16 == 0) fprintf(cfp, "\n\t"); fprintf(cfp, "0x%04x, ", STC_WordIndex[i]); } fprintf(cfp, "\n};\n"); fprintf(cfp, "\nstatic sal_Int32 STC_WordIndex_S2T_Count = %ld;\n", sal::static_int_cast< long >(length)); fprintf (cfp, "\tconst sal_uInt16* getSTC_WordEntry_S2T() { return STC_WordEntry_S2T; }\n"); fprintf (cfp, "\tconst sal_uInt16* getSTC_WordIndex_S2T(sal_Int32& count) { count = STC_WordIndex_S2T_Count; return STC_WordIndex_S2T; }\n"); } else { fprintf (cfp, "\tconst sal_uInt16* getSTC_WordEntry_S2T() { return NULL; }\n"); fprintf (cfp, "\tconst sal_uInt16* getSTC_WordIndex_S2T(sal_Int32& count) { count = 0; return NULL; }\n"); } if (count_T2S > 0) { qsort(&STC_WordEntry_T2S[0], count_T2S, sizeof(Index), Index_comp); fprintf(cfp, "\nstatic const sal_uInt16 STC_WordEntry_T2S[] = {"); count = 0; length = 0; for (i = 0; i < count_T2S; i++) { if (i % 32 == 0) fprintf(cfp, "\n\t"); fprintf(cfp, "0x%04x, ", STC_WordEntry_T2S[i].address); if (STC_WordEntry_T2S[i].len != length) { length = STC_WordEntry_T2S[i].len; while (count <= length) STC_WordIndex[count++] = sal::static_int_cast(i); } } STC_WordIndex[count++] = sal::static_int_cast(i); fprintf(cfp, "\n};\n"); fprintf(cfp, "\nstatic const sal_uInt16 STC_WordIndex_T2S[] = {"); for (i = 0; i < count; i++) { if (i % 16 == 0) fprintf(cfp, "\n\t"); fprintf(cfp, "0x%04x, ", STC_WordIndex[i]); } fprintf(cfp, "\n};\n"); fprintf(cfp, "\nstatic sal_Int32 STC_WordIndex_T2S_Count = %ld;\n\n", sal::static_int_cast< long >(length)); fprintf (cfp, "\tconst sal_uInt16* getSTC_WordEntry_T2S() { return STC_WordEntry_T2S; }\n"); fprintf (cfp, "\tconst sal_uInt16* getSTC_WordIndex_T2S(sal_Int32& count) { count = STC_WordIndex_T2S_Count; return STC_WordIndex_T2S; }\n"); } else { fprintf (cfp, "\tconst sal_uInt16* getSTC_WordEntry_T2S() { return NULL; }\n"); fprintf (cfp, "\tconst sal_uInt16* getSTC_WordIndex_T2S(sal_Int32& count) { count = 0; return NULL; }\n"); } } /* vim:set shiftwidth=4 softtabstop=4 expandtab: */