scuffed-code/icu4c/source/tools/genprops/genprops.c

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/*
*******************************************************************************
*
* Copyright (C) 1999-2001, International Business Machines
* Corporation and others. All Rights Reserved.
*
*******************************************************************************
* file name: genprops.c
* encoding: US-ASCII
* tab size: 8 (not used)
* indentation:4
*
* created on: 1999dec08
* created by: Markus W. Scherer
*
* This program reads the Unicode character database text file,
* parses it, and extracts most of the properties for each character.
* It then writes a binary file containing the properties
* that is designed to be used directly for random-access to
* the properties of each Unicode character.
*/
#include <stdio.h>
#include <stdlib.h>
#include "unicode/utypes.h"
#include "unicode/uchar.h"
#include "unicode/putil.h"
#include "cmemory.h"
#include "cstring.h"
#include "unicode/udata.h"
#include "unewdata.h"
#include "uoptions.h"
#include "uparse.h"
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U_CDECL_BEGIN
#include "genprops.h"
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U_CDECL_END
UBool beVerbose=FALSE, haveCopyright=TRUE;
/* prototypes --------------------------------------------------------------- */
static void
parseMirror(const char *filename, UErrorCode *pErrorCode);
static void
parseSpecialCasing(const char *filename, UErrorCode *pErrorCode);
static void
parseCaseFolding(const char *filename, UErrorCode *pErrorCode);
static void
parseDB(const char *filename, UErrorCode *pErrorCode);
/* -------------------------------------------------------------------------- */
static UOption options[]={
UOPTION_HELP_H,
UOPTION_HELP_QUESTION_MARK,
UOPTION_VERBOSE,
UOPTION_COPYRIGHT,
UOPTION_DESTDIR,
UOPTION_SOURCEDIR,
{ "unicode", NULL, NULL, NULL, 'u', UOPT_REQUIRES_ARG, 0 }
};
extern int
main(int argc, char* argv[]) {
char filename[300];
const char *srcDir=NULL, *destDir=NULL, *suffix=NULL;
char *basename=NULL;
UErrorCode errorCode=U_ZERO_ERROR;
/* preset then read command line options */
options[4].value=u_getDataDirectory();
options[5].value="";
options[6].value="3.0.0";
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]);
}
if(argc<0 || options[0].doesOccur || options[1].doesOccur) {
fprintf(stderr,
"usage: %s [-options] [suffix]\n"
"\tread the UnicodeData.txt file and other Unicode properties files and\n"
"\tcreate a binary file " DATA_NAME "." DATA_TYPE " with the character properties\n"
"\toptions:\n"
"\t\t-h or -? or --help this usage text\n"
"\t\t-v or --verbose verbose output\n"
"\t\t-c or --copyright include a copyright notice\n"
"\t\t-d or --destdir destination directory, followed by the path\n"
"\t\t-s or --sourcedir source directory, followed by the path\n"
"\t\t-u or --unicode Unicode version, followed by the version like 3.0.0\n"
"\t\tsuffix suffix that is to be appended with a '-'\n"
"\t\t to the source file basenames before opening;\n"
"\t\t 'genprops new' will read UnicodeData-new.txt etc.\n",
argv[0]);
return argc<0 ? U_ILLEGAL_ARGUMENT_ERROR : U_ZERO_ERROR;
}
/* get the options values */
beVerbose=options[2].doesOccur;
haveCopyright=options[3].doesOccur;
srcDir=options[5].value;
destDir=options[4].value;
if(argc>=2) {
suffix=argv[1];
} else {
suffix=NULL;
}
setUnicodeVersion(options[6].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;
}
/* initialize */
initStore();
/* process Mirror.txt */
if(suffix==NULL) {
uprv_strcpy(basename, "Mirror.txt");
} else {
uprv_strcpy(basename, "Mirror");
basename[6]='-';
uprv_strcpy(basename+7, suffix);
uprv_strcat(basename+7, ".txt");
}
parseMirror(filename, &errorCode);
/* process SpecialCasing.txt */
if(suffix==NULL) {
uprv_strcpy(basename, "SpecialCasing.txt");
} else {
uprv_strcpy(basename, "SpecialCasing");
basename[13]='-';
uprv_strcpy(basename+14, suffix);
uprv_strcat(basename+14, ".txt");
}
parseSpecialCasing(filename, &errorCode);
/* process CaseFolding.txt */
if(suffix==NULL) {
uprv_strcpy(basename, "CaseFolding.txt");
} else {
uprv_strcpy(basename, "CaseFolding");
basename[11]='-';
uprv_strcpy(basename+12, suffix);
uprv_strcat(basename+12, ".txt");
}
parseCaseFolding(filename, &errorCode);
/* process UnicodeData.txt */
if(suffix==NULL) {
uprv_strcpy(basename, "UnicodeData.txt");
} else {
uprv_strcpy(basename, "UnicodeData");
basename[11]='-';
uprv_strcpy(basename+12, suffix);
uprv_strcat(basename+12, ".txt");
}
parseDB(filename, &errorCode);
/* process parsed data */
if(U_SUCCESS(errorCode)) {
compactProps();
compactStage3();
compactStage2();
/* write the properties data file */
generateData(destDir);
}
return errorCode;
}
static const char *
skipWhitespace(const char *s) {
while(*s==' ' || *s=='\t') {
++s;
}
return s;
}
/*
* parse a list of code points
* store them as a string in dest[destSize] with the string length in dest[0]
* set the first code point in *pFirst
* return the number of code points
*/
static int32_t
parseCodePoints(const char *s,
UChar *dest, int32_t destSize,
uint32_t *pFirst,
UErrorCode *pErrorCode) {
char *end;
uint32_t value;
int32_t i, count;
if(pFirst!=NULL) {
*pFirst=0xffff;
}
count=0;
i=1; /* leave dest[0] for the length value */
for(;;) {
s=skipWhitespace(s);
if(*s==';' || *s==0) {
dest[0]=(UChar)(i-1);
return count;
}
/* read one code point */
value=uprv_strtoul(s, &end, 16);
if(end<=s || (*end!=' ' && *end!='\t' && *end!=';') || value>=0x110000) {
fprintf(stderr, "genprops: syntax error parsing code point at %s\n", s);
*pErrorCode=U_PARSE_ERROR;
return -1;
}
/* store the first code point */
if(++count==1 && pFirst!=NULL) {
*pFirst=value;
}
/* append it to the destination array */
UTF_APPEND_CHAR(dest, i, destSize, value);
/* overflow? */
if(i>=destSize) {
fprintf(stderr, "genprops: code point sequence too long at at %s\n", s);
*pErrorCode=U_INDEX_OUTOFBOUNDS_ERROR;
return -1;
}
/* go to the following characters */
s=end;
}
}
/* parser for Mirror.txt ---------------------------------------------------- */
#define MAX_MIRROR_COUNT 2000
static uint32_t mirrorMappings[MAX_MIRROR_COUNT][2];
static int32_t mirrorCount=0;
static void
mirrorLineFn(void *context,
char *fields[][2], int32_t fieldCount,
UErrorCode *pErrorCode) {
char *end;
mirrorMappings[mirrorCount][0]=uprv_strtoul(fields[0][0], &end, 16);
if(end<=fields[0][0] || end!=fields[0][1]) {
fprintf(stderr, "genprops: syntax error in Mirror.txt field 0 at %s\n", fields[0][0]);
*pErrorCode=U_PARSE_ERROR;
exit(U_PARSE_ERROR);
}
mirrorMappings[mirrorCount][1]=uprv_strtoul(fields[1][0], &end, 16);
if(end<=fields[1][0] || end!=fields[1][1]) {
fprintf(stderr, "genprops: syntax error in Mirror.txt field 1 at %s\n", fields[1][0]);
*pErrorCode=U_PARSE_ERROR;
exit(U_PARSE_ERROR);
}
if(++mirrorCount==MAX_MIRROR_COUNT) {
fprintf(stderr, "genprops: too many mirror mappings\n");
*pErrorCode=U_INDEX_OUTOFBOUNDS_ERROR;
exit(U_INDEX_OUTOFBOUNDS_ERROR);
}
}
static void
parseMirror(const char *filename, UErrorCode *pErrorCode) {
char *fields[2][2];
if(pErrorCode==NULL || U_FAILURE(*pErrorCode)) {
return;
}
u_parseDelimitedFile(filename, ';', fields, 2, mirrorLineFn, NULL, pErrorCode);
}
/* parser for SpecialCasing.txt --------------------------------------------- */
#define MAX_SPECIAL_CASING_COUNT 500
static SpecialCasing specialCasings[MAX_SPECIAL_CASING_COUNT];
static int32_t specialCasingCount=0;
static void
specialCasingLineFn(void *context,
char *fields[][2], int32_t fieldCount,
UErrorCode *pErrorCode) {
char *end;
/* get code point */
specialCasings[specialCasingCount].code=uprv_strtoul(skipWhitespace(fields[0][0]), &end, 16);
end=(char *)skipWhitespace(end);
if(end<=fields[0][0] || end!=fields[0][1]) {
fprintf(stderr, "genprops: syntax error in SpecialCasing.txt field 0 at %s\n", fields[0][0]);
*pErrorCode=U_PARSE_ERROR;
exit(U_PARSE_ERROR);
}
/* is this a complex mapping? */
if(*skipWhitespace(fields[4][0])!=0) {
/* there is some condition text in the fifth field */
specialCasings[specialCasingCount].isComplex=TRUE;
/* do not store any actual mappings for this */
specialCasings[specialCasingCount].lowerCase[0]=0;
specialCasings[specialCasingCount].upperCase[0]=0;
specialCasings[specialCasingCount].titleCase[0]=0;
} else {
/* just set the "complex" flag and get the case mappings */
specialCasings[specialCasingCount].isComplex=FALSE;
parseCodePoints(fields[1][0], specialCasings[specialCasingCount].lowerCase, 32, NULL, pErrorCode);
parseCodePoints(fields[3][0], specialCasings[specialCasingCount].upperCase, 32, NULL, pErrorCode);
parseCodePoints(fields[2][0], specialCasings[specialCasingCount].titleCase, 32, NULL, pErrorCode);
if(U_FAILURE(*pErrorCode)) {
fprintf(stderr, "genprops: error parsing special casing at %s\n", fields[0][0]);
exit(*pErrorCode);
}
}
if(++specialCasingCount==MAX_SPECIAL_CASING_COUNT) {
fprintf(stderr, "genprops: too many special casing mappings\n");
*pErrorCode=U_INDEX_OUTOFBOUNDS_ERROR;
exit(U_INDEX_OUTOFBOUNDS_ERROR);
}
}
static int
compareSpecialCasings(const void *left, const void *right) {
return ((const SpecialCasing *)left)->code-((const SpecialCasing *)right)->code;
}
static void
parseSpecialCasing(const char *filename, UErrorCode *pErrorCode) {
char *fields[5][2];
int32_t i, j;
if(pErrorCode==NULL || U_FAILURE(*pErrorCode)) {
return;
}
u_parseDelimitedFile(filename, ';', fields, 5, specialCasingLineFn, NULL, pErrorCode);
/* sort the special casing entries by code point */
if(specialCasingCount>0) {
qsort(specialCasings, specialCasingCount, sizeof(SpecialCasing), compareSpecialCasings);
}
/* replace multiple entries for any code point by one "complex" one */
j=0;
for(i=1; i<specialCasingCount; ++i) {
if(specialCasings[i-1].code==specialCasings[i].code) {
/* there is a duplicate code point */
specialCasings[i-1].code=0x7fffffff; /* remove this entry in the following qsort */
specialCasings[i].isComplex=TRUE; /* make the following one complex */
specialCasings[i].lowerCase[0]=0;
specialCasings[i].upperCase[0]=0;
specialCasings[i].titleCase[0]=0;
++j;
}
}
/* if some entries just were removed, then re-sort */
if(j>0) {
qsort(specialCasings, specialCasingCount, sizeof(SpecialCasing), compareSpecialCasings);
specialCasingCount-=j;
}
}
/* parser for CaseFolding.txt ----------------------------------------------- */
#define MAX_CASE_FOLDING_COUNT 500
static CaseFolding caseFoldings[MAX_CASE_FOLDING_COUNT];
static int32_t caseFoldingCount=0;
static void
caseFoldingLineFn(void *context,
char *fields[][2], int32_t fieldCount,
UErrorCode *pErrorCode) {
char *end;
int32_t count;
char status;
/* get code point */
caseFoldings[caseFoldingCount].code=uprv_strtoul(skipWhitespace(fields[0][0]), &end, 16);
end=(char *)skipWhitespace(end);
if(end<=fields[0][0] || end!=fields[0][1]) {
fprintf(stderr, "genprops: syntax error in CaseFolding.txt field 0 at %s\n", fields[0][0]);
*pErrorCode=U_PARSE_ERROR;
exit(U_PARSE_ERROR);
}
/* get the status of this mapping */
caseFoldings[caseFoldingCount].status=status=*skipWhitespace(fields[1][0]);
if(status!='L' && status!='E' && status!='C' && status!='S' && status!='F' && status!='I') {
fprintf(stderr, "genprops: unrecognized status field in CaseFolding.txt at %s\n", fields[0][0]);
*pErrorCode=U_PARSE_ERROR;
exit(U_PARSE_ERROR);
}
/* ignore all case folding mappings that are the same as the UnicodeData.txt lowercase mappings */
if(status=='L') {
return;
}
/* get the mapping */
count=parseCodePoints(fields[2][0], caseFoldings[caseFoldingCount].full, 32, &caseFoldings[caseFoldingCount].simple, pErrorCode);
if(U_FAILURE(*pErrorCode)) {
fprintf(stderr, "genprops: error parsing CaseFolding.txt mapping at %s\n", fields[0][0]);
exit(*pErrorCode);
}
/* there is a simple mapping only if there is exactly one code point */
if(count!=1) {
caseFoldings[caseFoldingCount].simple=0;
}
/* check the status */
if(status=='S') {
/* check if there was a full mapping for this code point before */
if( caseFoldingCount>0 &&
caseFoldings[caseFoldingCount-1].code==caseFoldings[caseFoldingCount].code &&
caseFoldings[caseFoldingCount-1].status=='F'
) {
/* merge the two entries */
caseFoldings[caseFoldingCount-1].simple=caseFoldings[caseFoldingCount].simple;
return;
}
} else if(status=='F') {
/* check if there was a simple mapping for this code point before */
if( caseFoldingCount>0 &&
caseFoldings[caseFoldingCount-1].code==caseFoldings[caseFoldingCount].code &&
caseFoldings[caseFoldingCount-1].status=='S'
) {
/* merge the two entries */
uprv_memcpy(caseFoldings[caseFoldingCount-1].full, caseFoldings[caseFoldingCount].full, 32*U_SIZEOF_UCHAR);
return;
}
} else if(status=='I') {
/* store only a marker for special handling for cases like dotless i */
caseFoldings[caseFoldingCount].simple=0;
caseFoldings[caseFoldingCount].full[0]=0;
}
if(++caseFoldingCount==MAX_CASE_FOLDING_COUNT) {
fprintf(stderr, "genprops: too many case folding mappings\n");
*pErrorCode=U_INDEX_OUTOFBOUNDS_ERROR;
exit(U_INDEX_OUTOFBOUNDS_ERROR);
}
}
static void
parseCaseFolding(const char *filename, UErrorCode *pErrorCode) {
char *fields[3][2];
if(pErrorCode==NULL || U_FAILURE(*pErrorCode)) {
return;
}
u_parseDelimitedFile(filename, ';', fields, 3, caseFoldingLineFn, NULL, pErrorCode);
}
/* parser for UnicodeData.txt ----------------------------------------------- */
/* general categories */
const char *const
genCategoryNames[U_CHAR_CATEGORY_COUNT]={
NULL,
"Lu", "Ll", "Lt", "Lm", "Lo", "Mn", "Me",
"Mc", "Nd", "Nl", "No",
"Zs", "Zl", "Zp",
"Cc", "Cf", "Co", "Cs",
"Pd", "Ps", "Pe", "Pc", "Po",
"Sm", "Sc", "Sk", "So",
"Pi", "Pf",
"Cn"
};
const char *const
bidiNames[U_CHAR_DIRECTION_COUNT]={
"L", "R", "EN", "ES", "ET", "AN", "CS", "B", "S",
"WS", "ON", "LRE", "LRO", "AL", "RLE", "RLO", "PDF", "NSM", "BN"
};
/* control code properties */
static const struct {
uint32_t code;
uint8_t generalCategory;
} controlProps[]={
/* TAB */ {0x9, U_SPACE_SEPARATOR},
/* VT */ {0xb, U_SPACE_SEPARATOR},
/* LF */ {0xa, U_PARAGRAPH_SEPARATOR},
/* FF */ {0xc, U_LINE_SEPARATOR},
/* CR */ {0xd, U_PARAGRAPH_SEPARATOR},
/* FS */ {0x1c, U_PARAGRAPH_SEPARATOR},
/* GS */ {0x1d, U_PARAGRAPH_SEPARATOR},
/* RS */ {0x1e, U_PARAGRAPH_SEPARATOR},
/* US */ {0x1f, U_SPACE_SEPARATOR},
/* NL */ {0x85, U_PARAGRAPH_SEPARATOR}
};
static struct {
uint32_t first, last, props;
char name[80];
} unicodeAreas[32];
static int32_t unicodeAreaIndex=0;
static void
unicodeDataLineFn(void *context,
char *fields[][2], int32_t fieldCount,
UErrorCode *pErrorCode) {
static int32_t mirrorIndex=0, specialCasingIndex=0, caseFoldingIndex=0;
Props p;
char *end;
uint32_t value;
int i;
/* reset the properties */
uprv_memset(&p, 0, sizeof(Props));
p.decimalDigitValue=p.digitValue=-1;
p.numericValue=0x80000000;
/* get the character code, field 0 */
p.code=uprv_strtoul(fields[0][0], &end, 16);
if(end<=fields[0][0] || end!=fields[0][1]) {
fprintf(stderr, "genprops: syntax error in field 0 at %s\n", fields[0][0]);
*pErrorCode=U_PARSE_ERROR;
exit(U_PARSE_ERROR);
}
/* get general category, field 2 */
*fields[2][1]=0;
for(i=1;;) {
if(uprv_strcmp(fields[2][0], genCategoryNames[i])==0) {
p.generalCategory=(uint8_t)i;
break;
}
if(++i==U_CHAR_CATEGORY_COUNT) {
fprintf(stderr, "genprops: unknown general category \"%s\" at code 0x%lx\n",
fields[2][0], (unsigned long)p.code);
*pErrorCode=U_PARSE_ERROR;
exit(U_PARSE_ERROR);
}
}
/* get canonical combining class, field 3 */
p.canonicalCombining=(uint8_t)uprv_strtoul(fields[3][0], &end, 10);
if(end<=fields[3][0] || end!=fields[3][1]) {
fprintf(stderr, "genprops: syntax error in field 3 at code 0x%lx\n",
(unsigned long)p.code);
*pErrorCode=U_PARSE_ERROR;
exit(U_PARSE_ERROR);
}
/* get BiDi category, field 4 */
*fields[4][1]=0;
for(i=0;;) {
if(uprv_strcmp(fields[4][0], bidiNames[i])==0) {
p.bidi=(uint8_t)i;
break;
}
if(++i==U_CHAR_DIRECTION_COUNT) {
fprintf(stderr, "genprops: unknown BiDi category \"%s\" at code 0x%lx\n",
fields[4][0], (unsigned long)p.code);
*pErrorCode=U_PARSE_ERROR;
exit(U_PARSE_ERROR);
}
}
/* decimal digit value, field 6 */
if(fields[6][0]<fields[6][1]) {
value=uprv_strtoul(fields[6][0], &end, 10);
if(end!=fields[6][1] || value>0x7fff) {
fprintf(stderr, "genprops: syntax error in field 6 at code 0x%lx\n",
(unsigned long)p.code);
*pErrorCode=U_PARSE_ERROR;
exit(U_PARSE_ERROR);
}
p.decimalDigitValue=(int16_t)value;
}
/* digit value, field 7 */
if(fields[7][0]<fields[7][1]) {
value=uprv_strtoul(fields[7][0], &end, 10);
if(end!=fields[7][1] || value>0x7fff) {
fprintf(stderr, "genprops: syntax error in field 7 at code 0x%lx\n",
(unsigned long)p.code);
*pErrorCode=U_PARSE_ERROR;
exit(U_PARSE_ERROR);
}
p.digitValue=(int16_t)value;
}
/* numeric value, field 8 */
if(fields[8][0]<fields[8][1]) {
char *s=fields[8][0];
UBool isNegative;
/* get a possible minus sign */
if(*s=='-') {
isNegative=TRUE;
++s;
} else {
isNegative=FALSE;
}
value=uprv_strtoul(s, &end, 10);
if(value>0 && *end=='/') {
/* field 8 may contain a fractional value, get the denominator */
p.denominator=uprv_strtoul(end+1, &end, 10);
if(p.denominator==0) {
fprintf(stderr, "genprops: denominator is 0 in field 8 at code 0x%lx\n",
(unsigned long)p.code);
*pErrorCode=U_PARSE_ERROR;
exit(U_PARSE_ERROR);
}
}
if(end!=fields[8][1] || value>0x7fffffff) {
fprintf(stderr, "genprops: syntax error in field 8 at code 0x%lx\n",
(unsigned long)p.code);
*pErrorCode=U_PARSE_ERROR;
exit(U_PARSE_ERROR);
}
if(isNegative) {
p.numericValue=-(int32_t)value;
} else {
p.numericValue=(int32_t)value;
}
p.hasNumericValue=TRUE;
}
/* get Mirrored flag, field 9 */
if(*fields[9][0]=='Y') {
p.isMirrored=1;
} else if(fields[9][1]-fields[9][0]!=1 || *fields[9][0]!='N') {
fprintf(stderr, "genprops: syntax error in field 9 at code 0x%lx\n",
(unsigned long)p.code);
*pErrorCode=U_PARSE_ERROR;
exit(U_PARSE_ERROR);
}
/* get uppercase mapping, field 12 */
value=uprv_strtoul(fields[12][0], &end, 16);
if(end!=fields[12][1]) {
fprintf(stderr, "genprops: syntax error in field 12 at code 0x%lx\n",
(unsigned long)p.code);
*pErrorCode=U_PARSE_ERROR;
exit(U_PARSE_ERROR);
}
p.upperCase=value;
/* get lowercase value, field 13 */
value=uprv_strtoul(fields[13][0], &end, 16);
if(end!=fields[13][1]) {
fprintf(stderr, "genprops: syntax error in field 13 at code 0x%lx\n",
(unsigned long)p.code);
*pErrorCode=U_PARSE_ERROR;
exit(U_PARSE_ERROR);
}
p.lowerCase=value;
/* get titlecase value, field 14 */
value=uprv_strtoul(fields[14][0], &end, 16);
if(end!=fields[14][1]) {
fprintf(stderr, "genprops: syntax error in field 14 at code 0x%lx\n",
(unsigned long)p.code);
*pErrorCode=U_PARSE_ERROR;
exit(U_PARSE_ERROR);
}
p.titleCase=value;
/* override properties for some common control characters */
if(p.generalCategory==U_CONTROL_CHAR) {
for(i=0; i<sizeof(controlProps)/sizeof(controlProps[0]); ++i) {
if(controlProps[i].code==p.code) {
p.generalCategory=controlProps[i].generalCategory;
}
}
}
/* set additional properties from previously parsed files */
if(mirrorIndex<mirrorCount && p.code==mirrorMappings[mirrorIndex][0]) {
p.mirrorMapping=mirrorMappings[mirrorIndex++][1];
}
if(specialCasingIndex<specialCasingCount && p.code==specialCasings[specialCasingIndex].code) {
p.specialCasing=specialCasings+specialCasingIndex++;
} else {
p.specialCasing=NULL;
}
if(caseFoldingIndex<caseFoldingCount && p.code==caseFoldings[caseFoldingIndex].code) {
p.caseFolding=caseFoldings+caseFoldingIndex++;
/* ignore "Common" mappings (simple==full) that map to the same code point as the regular lowercase mapping */
if( p.caseFolding->status=='C' &&
p.caseFolding->simple==p.lowerCase
) {
p.caseFolding=NULL;
}
} else {
p.caseFolding=NULL;
}
value=makeProps(&p);
if(*fields[1][0]=='<') {
/* first or last entry of a Unicode area */
size_t length=fields[1][1]-fields[1][0];
if(length<9) {
/* name too short for an area name */
} else if(0==uprv_memcmp(", First>", fields[1][1]-8, 8)) {
/* set the current area */
if(unicodeAreas[unicodeAreaIndex].first==0xffffffff) {
length-=9;
unicodeAreas[unicodeAreaIndex].first=p.code;
unicodeAreas[unicodeAreaIndex].props=value;
uprv_memcpy(unicodeAreas[unicodeAreaIndex].name, fields[1][0]+1, length);
unicodeAreas[unicodeAreaIndex].name[length]=0;
} else {
/* error: a previous area is incomplete */
fprintf(stderr, "genprops: error - area \"%s\" is incomplete\n", unicodeAreas[unicodeAreaIndex].name);
*pErrorCode=U_PARSE_ERROR;
exit(U_PARSE_ERROR);
}
return;
} else if(0==uprv_memcmp(", Last>", fields[1][1]-7, 7)) {
/* check that the current area matches, and complete it with the last code point */
length-=8;
if( unicodeAreas[unicodeAreaIndex].props==value &&
0==uprv_memcmp(unicodeAreas[unicodeAreaIndex].name, fields[1][0]+1, length) &&
unicodeAreas[unicodeAreaIndex].name[length]==0 &&
unicodeAreas[unicodeAreaIndex].first<p.code
) {
unicodeAreas[unicodeAreaIndex].last=p.code;
if(beVerbose) {
printf("Unicode area U+%04lx..U+%04lx \"%s\"\n",
(unsigned long)unicodeAreas[unicodeAreaIndex].first,
(unsigned long)unicodeAreas[unicodeAreaIndex].last,
unicodeAreas[unicodeAreaIndex].name);
}
unicodeAreas[++unicodeAreaIndex].first=0xffffffff;
} else {
/* error: different properties between first & last, different area name, first>=last */
fprintf(stderr, "genprops: error - Last of area \"%s\" is incorrect\n", unicodeAreas[unicodeAreaIndex].name);
*pErrorCode=U_PARSE_ERROR;
exit(U_PARSE_ERROR);
}
return;
} else {
/* not an area name */
}
}
/* properties for a single code point */
/* ### TODO: check that the code points (p.code) are in ascending order */
addProps(p.code, value);
}
/* set repeated properties for the areas */
static void
repeatAreaProps() {
uint32_t puaProps;
int32_t i;
UBool hasPlane15PUA, hasPlane16PUA;
/*
* UnicodeData.txt before 3.0.1 did not contain the PUAs on
* planes 15 and 16.
* If that is the case, then we add them here, using the properties
* from the BMP PUA.
*/
puaProps=0;
hasPlane15PUA=hasPlane16PUA=FALSE;
for(i=0; i<unicodeAreaIndex; ++i) {
repeatProps(unicodeAreas[i].first,
unicodeAreas[i].last,
unicodeAreas[i].props);
if(unicodeAreas[i].first==0xe000) {
puaProps=unicodeAreas[i].props;
} else if(unicodeAreas[i].first==0xf0000) {
hasPlane15PUA=TRUE;
} else if(unicodeAreas[i].first==0x100000) {
hasPlane16PUA=TRUE;
}
}
if(puaProps!=0) {
if(!hasPlane15PUA) {
repeatProps(0xf0000, 0xffffd, puaProps);
}
if(!hasPlane16PUA) {
repeatProps(0x100000, 0x10fffd, puaProps);
}
}
}
static void
parseDB(const char *filename, UErrorCode *pErrorCode) {
char *fields[15][2];
if(pErrorCode==NULL || U_FAILURE(*pErrorCode)) {
return;
}
/* while unicodeAreas[unicodeAreaIndex] is unused, set its first to a bogus value */
unicodeAreas[0].first=0xffffffff;
u_parseDelimitedFile(filename, ';', fields, 15, unicodeDataLineFn, NULL, pErrorCode);
if(unicodeAreas[unicodeAreaIndex].first!=0xffffffff) {
fprintf(stderr, "genprops: error - the last area \"%s\" from U+%04lx is incomplete\n",
unicodeAreas[unicodeAreaIndex].name,
(unsigned long)unicodeAreas[unicodeAreaIndex].first);
*pErrorCode=U_PARSE_ERROR;
exit(U_PARSE_ERROR);
}
repeatAreaProps();
}
/*
* Hey, Emacs, please set the following:
*
* Local Variables:
* indent-tabs-mode: nil
* End:
*
*/