scuffed-code/icu4c/source/tools/gennorm/store.c

1961 lines
62 KiB
C
Raw Normal View History

/*
*******************************************************************************
*
* Copyright (C) 1999-2003, International Business Machines
* Corporation and others. All Rights Reserved.
*
*******************************************************************************
* file name: store.c
* encoding: US-ASCII
* tab size: 8 (not used)
* indentation:4
*
* created on: 2001may25
* created by: Markus W. Scherer
*
* Store Unicode normalization data in a memory-mappable file.
*/
#include <stdio.h>
#include <stdlib.h>
#include "unicode/utypes.h"
#include "unicode/uchar.h"
#include "cmemory.h"
#include "cstring.h"
#include "filestrm.h"
#include "unicode/udata.h"
#include "utrie.h"
#include "unicode/uset.h"
#include "unewdata.h"
#include "unormimp.h"
#include "gennorm.h"
#ifdef WIN32
# pragma warning(disable: 4100)
#endif
#define DO_DEBUG_OUT 0
/*
* The new implementation of the normalization code loads its data from
* unorm.icu, which is generated with this gennorm tool.
* The format of that file is described in unormimp.h .
*/
/* file data ---------------------------------------------------------------- */
#if UCONFIG_NO_NORMALIZATION
/* dummy UDataInfo cf. udata.h */
static UDataInfo dataInfo = {
sizeof(UDataInfo),
0,
U_IS_BIG_ENDIAN,
U_CHARSET_FAMILY,
U_SIZEOF_UCHAR,
0,
{ 0, 0, 0, 0 }, /* dummy dataFormat */
{ 0, 0, 0, 0 }, /* dummy formatVersion */
{ 0, 0, 0, 0 } /* dummy dataVersion */
};
#else
/* UDataInfo cf. udata.h */
static UDataInfo dataInfo={
sizeof(UDataInfo),
0,
U_IS_BIG_ENDIAN,
U_CHARSET_FAMILY,
U_SIZEOF_UCHAR,
0,
{ 0x4e, 0x6f, 0x72, 0x6d }, /* dataFormat="Norm" */
{ 2, 2, UTRIE_SHIFT, UTRIE_INDEX_SHIFT }, /* formatVersion */
{ 3, 2, 0, 0 } /* dataVersion (Unicode version) */
};
extern void
setUnicodeVersion(const char *v) {
UVersionInfo version;
u_versionFromString(version, v);
uprv_memcpy(dataInfo.dataVersion, version, 4);
}
static int32_t indexes[_NORM_INDEX_TOP]={ 0 };
/* tool memory helper ------------------------------------------------------- */
/*
* UToolMemory is used for generic, custom memory management.
* It is allocated with enough space for count*size bytes starting
* at array.
* The array is declared with a union of large data types so
* that its base address is aligned for any types.
* If size is a multiple of a data type size, then such items
* can be safely allocated inside the array, at offsets that
* are themselves multiples of size.
*/
typedef struct UToolMemory {
char name[64];
uint32_t count, size, index;
union {
uint32_t u;
double d;
void *p;
} array[1];
} UToolMemory;
static UToolMemory *
utm_open(const char *name, uint32_t count, uint32_t size) {
UToolMemory *mem=(UToolMemory *)uprv_malloc(sizeof(UToolMemory)+count*size);
if(mem==NULL) {
fprintf(stderr, "error: %s - out of memory\n", name);
exit(U_MEMORY_ALLOCATION_ERROR);
}
uprv_strcpy(mem->name, name);
mem->count=count;
mem->size=size;
mem->index=0;
return mem;
}
static void
utm_close(UToolMemory *mem) {
if(mem!=NULL) {
uprv_free(mem);
}
}
static void *
utm_getStart(UToolMemory *mem) {
return (char *)mem->array;
}
static int32_t
utm_countItems(UToolMemory *mem) {
return mem->index;
}
static void *
utm_alloc(UToolMemory *mem) {
char *p=(char *)mem->array+mem->index*mem->size;
if(++mem->index<=mem->count) {
uprv_memset(p, 0, mem->size);
return p;
} else {
fprintf(stderr, "error: %s - trying to use more than %ld preallocated units\n",
mem->name, (long)mem->count);
exit(U_MEMORY_ALLOCATION_ERROR);
}
}
static void *
utm_allocN(UToolMemory *mem, int32_t n) {
char *p=(char *)mem->array+mem->index*mem->size;
if((mem->index+=(uint32_t)n)<=mem->count) {
uprv_memset(p, 0, n*mem->size);
return p;
} else {
fprintf(stderr, "error: %s - trying to use more than %ld preallocated units\n",
mem->name, (long)mem->count);
exit(U_MEMORY_ALLOCATION_ERROR);
}
}
/* builder data ------------------------------------------------------------- */
typedef void EnumTrieFn(void *context, uint32_t code, Norm *norm);
static UNewTrie
*normTrie,
*norm32Trie,
*fcdTrie,
*auxTrie;
static UToolMemory *normMem, *utf32Mem, *extraMem, *combiningTriplesMem;
static Norm *norms;
/*
* set a flag for each code point that was seen in decompositions -
* avoid to decompose ones that have not been used before
*/
static uint32_t haveSeenFlags[256];
/* see addCombiningCP() for details */
static uint32_t combiningCPs[2000];
/*
* after processCombining() this contains for each code point in combiningCPs[]
* the runtime combining index
*/
static uint16_t combiningIndexes[2000];
/* section limits for combiningCPs[], see addCombiningCP() */
static uint16_t combineFwdTop=0, combineBothTop=0, combineBackTop=0;
/**
* Structure for a triple of code points, stored in combiningTriplesMem.
* The lead and trail code points combine into the the combined one,
* i.e., there is a canonical decomposition of combined-> <lead, trail>.
*
* Before processCombining() is called, leadIndex and trailIndex are 0.
* After processCombining(), they contain the indexes of the lead and trail
* code point in the combiningCPs[] array.
* They are then sorted by leadIndex, then trailIndex.
* They are not sorted by code points.
*/
typedef struct CombiningTriple {
uint16_t leadIndex, trailIndex;
uint32_t lead, trail, combined;
} CombiningTriple;
/* 15b in the combining index -> <=0x8000 uint16_t values in the combining table */
static uint16_t combiningTable[0x8000];
static uint16_t combiningTableTop=0;
#define _NORM_MAX_SET_SEARCH_TABLE_LENGTH 0x4000
static uint16_t canonStartSets[_NORM_MAX_CANON_SETS+2*_NORM_MAX_SET_SEARCH_TABLE_LENGTH];
static int32_t canonStartSetsTop=_NORM_SET_INDEX_TOP;
static int32_t canonSetsCount=0;
extern void
init() {
uint16_t *p16;
normTrie = (UNewTrie *)uprv_malloc(sizeof(UNewTrie));
uprv_memset(normTrie, 0, sizeof(UNewTrie));
norm32Trie = (UNewTrie *)uprv_malloc(sizeof(UNewTrie));
uprv_memset(norm32Trie, 0, sizeof(UNewTrie));
fcdTrie = (UNewTrie *)uprv_malloc(sizeof(UNewTrie));
uprv_memset(fcdTrie, 0, sizeof(UNewTrie));
auxTrie = (UNewTrie *)uprv_malloc(sizeof(UNewTrie));
uprv_memset(auxTrie, 0, sizeof(UNewTrie));
/* initialize the two tries */
if(NULL==utrie_open(normTrie, NULL, 30000, 0, 0, FALSE)) {
fprintf(stderr, "error: failed to initialize tries\n");
exit(U_MEMORY_ALLOCATION_ERROR);
}
/* allocate Norm structures and reset the first one */
normMem=utm_open("gennorm normalization structs", 20000, sizeof(Norm));
norms=utm_alloc(normMem);
/* allocate UTF-32 string memory */
utf32Mem=utm_open("gennorm UTF-32 strings", 30000, 4);
/* reset all "have seen" flags */
uprv_memset(haveSeenFlags, 0, sizeof(haveSeenFlags));
/* allocate extra data memory for UTF-16 decomposition strings and other values */
extraMem=utm_open("gennorm extra 16-bit memory", _NORM_EXTRA_INDEX_TOP, 2);
/* initialize the extraMem counter for the top of FNC strings */
p16=(uint16_t *)utm_alloc(extraMem);
*p16=1;
/* allocate temporary memory for combining triples */
combiningTriplesMem=utm_open("gennorm combining triples", 0x4000, sizeof(CombiningTriple));
/* set the minimum code points for no/maybe quick check values to the end of the BMP */
indexes[_NORM_INDEX_MIN_NFC_NO_MAYBE]=0xffff;
indexes[_NORM_INDEX_MIN_NFKC_NO_MAYBE]=0xffff;
indexes[_NORM_INDEX_MIN_NFD_NO_MAYBE]=0xffff;
indexes[_NORM_INDEX_MIN_NFKD_NO_MAYBE]=0xffff;
/* preset the indexes portion of canonStartSets */
uprv_memset(canonStartSets, 0, _NORM_SET_INDEX_TOP*2);
}
/*
* get or create a Norm unit;
* get or create the intermediate trie entries for it as well
*/
static Norm *
createNorm(uint32_t code) {
Norm *p;
uint32_t i;
i=utrie_get32(normTrie, (UChar32)code, NULL);
if(i!=0) {
p=norms+i;
} else {
/* allocate Norm */
p=(Norm *)utm_alloc(normMem);
if(!utrie_set32(normTrie, (UChar32)code, (uint32_t)(p-norms))) {
fprintf(stderr, "error: too many normalization entries\n");
exit(U_BUFFER_OVERFLOW_ERROR);
}
}
return p;
}
/* get an existing Norm unit */
static Norm *
getNorm(uint32_t code) {
uint32_t i;
i=utrie_get32(normTrie, (UChar32)code, NULL);
if(i==0) {
return NULL;
}
return norms+i;
}
/* get the canonical combining class of a character */
static uint8_t
getCCFromCP(uint32_t code) {
Norm *norm=getNorm(code);
if(norm==NULL) {
return 0;
} else {
return norm->udataCC;
}
}
/*
* enumerate all code points with their Norm structs and call a function for each
* return the number of code points with data
*/
static uint32_t
enumTrie(EnumTrieFn *fn, void *context) {
uint32_t count, i;
UChar32 code;
UBool isInBlockZero;
count=0;
for(code=0; code<=0x10ffff;) {
i=utrie_get32(normTrie, code, &isInBlockZero);
if(isInBlockZero) {
code+=UTRIE_DATA_BLOCK_LENGTH;
} else {
if(i!=0) {
fn(context, (uint32_t)code, norms+i);
++count;
}
++code;
}
}
return count;
}
static void
setHaveSeenString(const uint32_t *s, int32_t length) {
uint32_t c;
while(length>0) {
c=*s++;
haveSeenFlags[(c>>5)&0xff]|=(1<<(c&0x1f));
--length;
}
}
#define HAVE_SEEN(c) (haveSeenFlags[((c)>>5)&0xff]&(1<<((c)&0x1f)))
/* handle combining data ---------------------------------------------------- */
/*
* Insert an entry into combiningCPs[] for the new code point code with its flags.
* The flags indicate if code combines forward, backward, or both.
*
* combiningCPs[] contains three sections:
* 1. code points that combine forward
* 2. code points that combine forward and backward
* 3. code points that combine backward
*
* Search for code in the entire array.
* If it is found and already is in the right section (old flags==new flags)
* then we are done.
* If it is found but the flags are different, then remove it,
* union the old and new flags, and reinsert it into its correct section.
* If it is not found, then just insert it.
*
* Within each section, the code points are not sorted.
*/
static void
addCombiningCP(uint32_t code, uint8_t flags) {
uint32_t newEntry;
uint16_t i;
newEntry=code|((uint32_t)flags<<24);
/* search for this code point */
for(i=0; i<combineBackTop; ++i) {
if(code==(combiningCPs[i]&0xffffff)) {
/* found it */
if(newEntry==combiningCPs[i]) {
return; /* no change */
}
/* combine the flags, remove the old entry from the old place, and insert the new one */
newEntry|=combiningCPs[i];
if(i!=--combineBackTop) {
uprv_memmove(combiningCPs+i, combiningCPs+i+1, (combineBackTop-i)*4);
}
if(i<combineBothTop) {
--combineBothTop;
}
if(i<combineFwdTop) {
--combineFwdTop;
}
break;
}
}
/* not found or modified, insert it */
if(combineBackTop>=sizeof(combiningCPs)/4) {
fprintf(stderr, "error: gennorm combining code points - trying to use more than %ld units\n",
(long)(sizeof(combiningCPs)/4));
exit(U_MEMORY_ALLOCATION_ERROR);
}
/* set i to the insertion point */
flags=(uint8_t)(newEntry>>24);
if(flags==1) {
i=combineFwdTop++;
++combineBothTop;
} else if(flags==3) {
i=combineBothTop++;
} else /* flags==2 */ {
i=combineBackTop;
}
/* move the following code points up one and insert newEntry at i */
if(i<combineBackTop) {
uprv_memmove(combiningCPs+i+1, combiningCPs+i, (combineBackTop-i)*4);
}
combiningCPs[i]=newEntry;
/* finally increment the total counter */
++combineBackTop;
}
/**
* Find the index in combiningCPs[] where code point code is stored.
* @param code code point to look for
* @param isLead is code a forward combining code point?
* @return index in combiningCPs[] where code is stored
*/
static uint16_t
findCombiningCP(uint32_t code, UBool isLead) {
uint16_t i, limit;
if(isLead) {
i=0;
limit=combineBothTop;
} else {
i=combineFwdTop;
limit=combineBackTop;
}
/* search for this code point */
for(; i<limit; ++i) {
if(code==(combiningCPs[i]&0xffffff)) {
/* found it */
return i;
}
}
/* not found */
return 0xffff;
}
static void
addCombiningTriple(uint32_t lead, uint32_t trail, uint32_t combined) {
CombiningTriple *triple;
/*
* set combiningFlags for the two code points
* do this after decomposition so that getNorm() above returns NULL
* if we do not have actual sub-decomposition data for the initial NFD here
*/
createNorm(lead)->combiningFlags|=1; /* combines forward */
createNorm(trail)->combiningFlags|=2; /* combines backward */
addCombiningCP(lead, 1);
addCombiningCP(trail, 2);
triple=(CombiningTriple *)utm_alloc(combiningTriplesMem);
triple->lead=lead;
triple->trail=trail;
triple->combined=combined;
}
static int
compareTriples(const void *l, const void *r) {
int diff;
diff=(int)((CombiningTriple *)l)->leadIndex-
(int)((CombiningTriple *)r)->leadIndex;
if(diff==0) {
diff=(int)((CombiningTriple *)l)->trailIndex-
(int)((CombiningTriple *)r)->trailIndex;
}
return diff;
}
static void
processCombining() {
CombiningTriple *triples;
uint16_t *p;
uint32_t combined;
uint16_t i, j, count, tableTop, finalIndex, combinesFwd;
triples=utm_getStart(combiningTriplesMem);
/* add lead and trail indexes to the triples for sorting */
count=(uint16_t)combiningTriplesMem->index;
for(i=0; i<count; ++i) {
/* findCombiningCP() must always find the code point */
triples[i].leadIndex=findCombiningCP(triples[i].lead, TRUE);
triples[i].trailIndex=findCombiningCP(triples[i].trail, FALSE);
}
/* sort them by leadIndex, trailIndex */
qsort(triples, count, sizeof(CombiningTriple), compareTriples);
/* calculate final combining indexes and store them in the Norm entries */
tableTop=0;
j=0; /* triples counter */
/* first, combining indexes of fwd/both characters are indexes into the combiningTable */
for(i=0; i<combineBothTop; ++i) {
/* start a new table */
/* assign combining index */
createNorm(combiningCPs[i]&0xffffff)->combiningIndex=combiningIndexes[i]=tableTop;
/* calculate the length of the combining data for this lead code point in the combiningTable */
while(j<count && i==triples[j].leadIndex) {
/* count 2 to 3 16-bit units per composition entry (back-index, code point) */
combined=triples[j++].combined;
if(combined<=0x1fff) {
tableTop+=2;
} else {
tableTop+=3;
}
}
}
/* second, combining indexes of back-only characters are simply incremented from here to be unique */
finalIndex=tableTop;
for(; i<combineBackTop; ++i) {
createNorm(combiningCPs[i]&0xffffff)->combiningIndex=combiningIndexes[i]=finalIndex++;
}
/* it must be finalIndex<=0x8000 because bit 15 is used in combiningTable as an end-for-this-lead marker */
if(finalIndex>0x8000) {
fprintf(stderr, "error: gennorm combining table - trying to use %u units, more than the %ld units available\n",
tableTop, (long)(sizeof(combiningTable)/4));
exit(U_MEMORY_ALLOCATION_ERROR);
}
combiningTableTop=tableTop;
/* store the combining data in the combiningTable, with the final indexes from above */
p=combiningTable;
j=0; /* triples counter */
/*
* this is essentially the same loop as above, but
* it writes the table data instead of calculating and setting the final indexes;
* it is necessary to have two passes so that all the final indexes are known before
* they are written into the table
*/
for(i=0; i<combineBothTop; ++i) {
/* start a new table */
combined=0; /* avoid compiler warning */
/* store the combining data for this lead code point in the combiningTable */
while(j<count && i==triples[j].leadIndex) {
finalIndex=combiningIndexes[triples[j].trailIndex];
combined=triples[j++].combined;
/* is combined a starter? (i.e., cc==0 && combines forward) */
combinesFwd=(uint16_t)((getNorm(combined)->combiningFlags&1)<<13);
*p++=finalIndex;
if(combined<=0x1fff) {
*p++=(uint16_t)(combinesFwd|combined);
} else if(combined<=0xffff) {
*p++=(uint16_t)(0x8000|combinesFwd);
*p++=(uint16_t)combined;
} else {
*p++=(uint16_t)(0xc000|combinesFwd|((combined-0x10000)>>10));
*p++=(uint16_t)(0xdc00|(combined&0x3ff));
}
}
/* set a marker on the last final trail index in this lead's table */
if(combined<=0x1fff) {
*(p-2)|=0x8000;
} else {
*(p-3)|=0x8000;
}
}
/* post condition: tableTop==(p-combiningTable) */
}
/* processing incoming normalization data ----------------------------------- */
/*
* Decompose Hangul syllables algorithmically and fill a pseudo-Norm struct.
* c must be a Hangul syllable code point.
*/
static void
getHangulDecomposition(uint32_t c, Norm *pHangulNorm, uint32_t hangulBuffer[3]) {
/* Hangul syllable: decompose algorithmically */
uint32_t c2;
uint8_t length;
uprv_memset(pHangulNorm, 0, sizeof(Norm));
c-=HANGUL_BASE;
c2=c%JAMO_T_COUNT;
c/=JAMO_T_COUNT;
if(c2>0) {
hangulBuffer[2]=JAMO_T_BASE+c2;
length=3;
} else {
hangulBuffer[2]=0;
length=2;
}
hangulBuffer[1]=JAMO_V_BASE+c%JAMO_V_COUNT;
hangulBuffer[0]=JAMO_L_BASE+c/JAMO_V_COUNT;
pHangulNorm->nfd=pHangulNorm->nfkd=hangulBuffer;
pHangulNorm->lenNFD=pHangulNorm->lenNFKD=length;
}
/*
* decompose the one decomposition further, may generate two decompositions
* apply all previous characters' decompositions to this one
*/
static void
decompStoreNewNF(uint32_t code, Norm *norm) {
uint32_t nfd[40], nfkd[40], hangulBuffer[3];
Norm hangulNorm;
uint32_t *s32;
Norm *p;
uint32_t c;
int32_t i, length;
uint8_t lenNFD=0, lenNFKD=0;
UBool changedNFD=FALSE, changedNFKD=FALSE;
if((length=norm->lenNFD)!=0) {
/* always allocate the original string */
changedNFD=TRUE;
s32=norm->nfd;
} else if((length=norm->lenNFKD)!=0) {
/* always allocate the original string */
changedNFKD=TRUE;
s32=norm->nfkd;
} else {
/* no decomposition here, nothing to do */
return;
}
/* decompose each code point */
for(i=0; i<length; ++i) {
c=s32[i];
p=getNorm(c);
if(p==NULL) {
if(HANGUL_BASE<=c && c<(HANGUL_BASE+HANGUL_COUNT)) {
getHangulDecomposition(c, &hangulNorm, hangulBuffer);
p=&hangulNorm;
} else {
/* no data, no decomposition */
nfd[lenNFD++]=c;
nfkd[lenNFKD++]=c;
continue;
}
}
/* canonically decompose c */
if(changedNFD) {
if(p->lenNFD!=0) {
uprv_memcpy(nfd+lenNFD, p->nfd, p->lenNFD*4);
lenNFD+=p->lenNFD;
} else {
nfd[lenNFD++]=c;
}
}
/* compatibility-decompose c */
if(p->lenNFKD!=0) {
uprv_memcpy(nfkd+lenNFKD, p->nfkd, p->lenNFKD*4);
lenNFKD+=p->lenNFKD;
changedNFKD=TRUE;
} else if(p->lenNFD!=0) {
uprv_memcpy(nfkd+lenNFKD, p->nfd, p->lenNFD*4);
lenNFKD+=p->lenNFD;
changedNFKD=TRUE;
} else {
nfkd[lenNFKD++]=c;
}
}
/* assume that norm->lenNFD==1 or ==2 */
if(norm->lenNFD==2 && !(norm->combiningFlags&0x80)) {
addCombiningTriple(s32[0], s32[1], code);
}
if(changedNFD) {
if(lenNFD!=0) {
s32=utm_allocN(utf32Mem, lenNFD);
uprv_memcpy(s32, nfd, lenNFD*4);
} else {
s32=NULL;
}
norm->lenNFD=lenNFD;
norm->nfd=s32;
setHaveSeenString(nfd, lenNFD);
}
if(changedNFKD) {
if(lenNFKD!=0) {
s32=utm_allocN(utf32Mem, lenNFKD);
uprv_memcpy(s32, nfkd, lenNFKD*4);
} else {
s32=NULL;
}
norm->lenNFKD=lenNFKD;
norm->nfkd=s32;
setHaveSeenString(nfkd, lenNFKD);
}
}
typedef struct DecompSingle {
uint32_t c;
Norm *norm;
} DecompSingle;
/*
* apply this one character's decompositions (there is at least one!) to
* all previous characters' decompositions to decompose them further
*/
static void
decompWithSingleFn(void *context, uint32_t code, Norm *norm) {
uint32_t nfd[40], nfkd[40];
uint32_t *s32;
DecompSingle *me=(DecompSingle *)context;
uint32_t c, myC;
int32_t i, length;
uint8_t lenNFD=0, lenNFKD=0, myLenNFD, myLenNFKD;
UBool changedNFD=FALSE, changedNFKD=FALSE;
/* get the new character's data */
myC=me->c;
myLenNFD=me->norm->lenNFD;
myLenNFKD=me->norm->lenNFKD;
/* assume that myC has at least one decomposition */
if((length=norm->lenNFD)!=0 && myLenNFD!=0) {
/* apply NFD(myC) to norm->nfd */
s32=norm->nfd;
for(i=0; i<length; ++i) {
c=s32[i];
if(c==myC) {
uprv_memcpy(nfd+lenNFD, me->norm->nfd, myLenNFD*4);
lenNFD+=myLenNFD;
changedNFD=TRUE;
} else {
nfd[lenNFD++]=c;
}
}
}
if((length=norm->lenNFKD)!=0) {
/* apply NFD(myC) and NFKD(myC) to norm->nfkd */
s32=norm->nfkd;
for(i=0; i<length; ++i) {
c=s32[i];
if(c==myC) {
if(myLenNFKD!=0) {
uprv_memcpy(nfkd+lenNFKD, me->norm->nfkd, myLenNFKD*4);
lenNFKD+=myLenNFKD;
} else /* assume myLenNFD!=0 */ {
uprv_memcpy(nfkd+lenNFKD, me->norm->nfd, myLenNFD*4);
lenNFKD+=myLenNFD;
}
changedNFKD=TRUE;
} else {
nfkd[lenNFKD++]=c;
}
}
} else if((length=norm->lenNFD)!=0 && myLenNFKD!=0) {
/* apply NFKD(myC) to norm->nfd, forming a new norm->nfkd */
s32=norm->nfd;
for(i=0; i<length; ++i) {
c=s32[i];
if(c==myC) {
uprv_memcpy(nfkd+lenNFKD, me->norm->nfkd, myLenNFKD*4);
lenNFKD+=myLenNFKD;
changedNFKD=TRUE;
} else {
nfkd[lenNFKD++]=c;
}
}
}
/* set the new decompositions, forget the old ones */
if(changedNFD) {
if(lenNFD!=0) {
if(lenNFD>norm->lenNFD) {
s32=utm_allocN(utf32Mem, lenNFD);
} else {
s32=norm->nfd;
}
uprv_memcpy(s32, nfd, lenNFD*4);
} else {
s32=NULL;
}
norm->lenNFD=lenNFD;
norm->nfd=s32;
}
if(changedNFKD) {
if(lenNFKD!=0) {
if(lenNFKD>norm->lenNFKD) {
s32=utm_allocN(utf32Mem, lenNFKD);
} else {
s32=norm->nfkd;
}
uprv_memcpy(s32, nfkd, lenNFKD*4);
} else {
s32=NULL;
}
norm->lenNFKD=lenNFKD;
norm->nfkd=s32;
}
}
/*
* process the data for one code point listed in UnicodeData;
* UnicodeData itself never maps a code point to both NFD and NFKD
*/
extern void
storeNorm(uint32_t code, Norm *norm) {
DecompSingle decompSingle;
Norm *p;
/* copy existing derived normalization properties */
p=createNorm(code);
norm->qcFlags=p->qcFlags;
norm->combiningFlags=p->combiningFlags;
norm->fncIndex=p->fncIndex;
/* process the decomposition if if there is at one here */
if((norm->lenNFD|norm->lenNFKD)!=0) {
/* decompose this one decomposition further, may generate two decompositions */
decompStoreNewNF(code, norm);
/* has this code point been used in previous decompositions? */
if(HAVE_SEEN(code)) {
/* use this decomposition to decompose other decompositions further */
decompSingle.c=code;
decompSingle.norm=norm;
enumTrie(decompWithSingleFn, &decompSingle);
}
}
/* store the data */
uprv_memcpy(p, norm, sizeof(Norm));
}
extern void
setQCFlags(uint32_t code, uint8_t qcFlags) {
createNorm(code)->qcFlags|=qcFlags;
/* adjust the minimum code point for quick check no/maybe */
if(code<0xffff) {
if((qcFlags&_NORM_QC_NFC) && (uint16_t)code<indexes[_NORM_INDEX_MIN_NFC_NO_MAYBE]) {
indexes[_NORM_INDEX_MIN_NFC_NO_MAYBE]=(uint16_t)code;
}
if((qcFlags&_NORM_QC_NFKC) && (uint16_t)code<indexes[_NORM_INDEX_MIN_NFKC_NO_MAYBE]) {
indexes[_NORM_INDEX_MIN_NFKC_NO_MAYBE]=(uint16_t)code;
}
if((qcFlags&_NORM_QC_NFD) && (uint16_t)code<indexes[_NORM_INDEX_MIN_NFD_NO_MAYBE]) {
indexes[_NORM_INDEX_MIN_NFD_NO_MAYBE]=(uint16_t)code;
}
if((qcFlags&_NORM_QC_NFKD) && (uint16_t)code<indexes[_NORM_INDEX_MIN_NFKD_NO_MAYBE]) {
indexes[_NORM_INDEX_MIN_NFKD_NO_MAYBE]=(uint16_t)code;
}
}
}
extern void
setCompositionExclusion(uint32_t code) {
createNorm(code)->combiningFlags|=0x80;
}
static void
setHangulJamoSpecials() {
Norm *norm;
uint32_t c, hangul;
/*
* Hangul syllables are algorithmically decomposed into Jamos,
* and Jamos are algorithmically composed into Hangul syllables.
* The quick check flags are parsed, except for Hangul.
*/
/* set Jamo L specials */
hangul=0xac00;
for(c=0x1100; c<=0x1112; ++c) {
norm=createNorm(c);
norm->specialTag=_NORM_EXTRA_INDEX_TOP+_NORM_EXTRA_JAMO_L;
norm->combiningFlags=1;
/* for each Jamo L create a set with its associated Hangul block */
norm->canonStart=uset_open(hangul, hangul+21*28-1);
hangul+=21*28;
}
/* set Jamo V specials */
for(c=0x1161; c<=0x1175; ++c) {
norm=createNorm(c);
norm->specialTag=_NORM_EXTRA_INDEX_TOP+_NORM_EXTRA_JAMO_V;
norm->combiningFlags=2;
norm->unsafeStart=TRUE;
}
/* set Jamo T specials */
for(c=0x11a8; c<=0x11c2; ++c) {
norm=createNorm(c);
norm->specialTag=_NORM_EXTRA_INDEX_TOP+_NORM_EXTRA_JAMO_T;
norm->combiningFlags=2;
norm->unsafeStart=TRUE;
}
/* set Hangul specials, precompacted */
norm=(Norm *)utm_alloc(normMem);
norm->specialTag=_NORM_EXTRA_INDEX_TOP+_NORM_EXTRA_HANGUL;
norm->qcFlags=_NORM_QC_NFD|_NORM_QC_NFKD;
if(!utrie_setRange32(normTrie, 0xac00, 0xd7a4, (uint32_t)(norm-norms), TRUE)) {
fprintf(stderr, "error: too many normalization entries (setting Hangul)\n");
exit(U_BUFFER_OVERFLOW_ERROR);
}
}
/*
* set FC-NFKC-Closure string
* s contains the closure string; s[0]==length, s[1..length] is the actual string
* may modify s[0]
*/
U_CFUNC void
setFNC(uint32_t c, UChar *s) {
uint16_t *p;
int32_t length, i, count;
UChar first;
count=utm_countItems(extraMem);
length=s[0];
first=s[1];
/* try to overlay single-unit strings with existing ones */
if(length==1 && first<0xff00) {
p=utm_getStart(extraMem);
for(i=1; i<count; ++i) {
if(first==p[i]) {
break;
}
}
} else {
i=count;
}
/* append the new string if it cannot be overlayed with an old one */
if(i==count) {
if(count>_NORM_AUX_MAX_FNC) {
fprintf(stderr, "gennorm error: too many FNC strings\n");
exit(U_INDEX_OUTOFBOUNDS_ERROR);
}
/* prepend 0xffxx with xx==length */
s[0]=(uint16_t)(0xff00+length);
++length;
p=(uint16_t *)utm_allocN(extraMem, length);
uprv_memcpy(p, s, length*2);
/* update the top index in extraMem[0] */
count+=length;
((uint16_t *)utm_getStart(extraMem))[0]=(uint16_t)count;
}
/* store the index to the string */
createNorm(c)->fncIndex=i;
}
/* build runtime structures ------------------------------------------------- */
/* canonically reorder a UTF-32 string; return { leadCC, trailCC } */
static uint16_t
reorderString(uint32_t *s, int32_t length) {
uint8_t ccs[40];
uint32_t c;
int32_t i, j;
uint8_t cc, prevCC;
if(length<=0) {
return 0;
}
for(i=0; i<length; ++i) {
/* get the i-th code point and its combining class */
c=s[i];
cc=getCCFromCP(c);
if(cc!=0 && i!=0) {
/* it is a combining mark, see if it needs to be moved back */
j=i;
do {
prevCC=ccs[j-1];
if(prevCC<=cc) {
break; /* found the right place */
}
/* move the previous code point here and go back */
s[j]=s[j-1];
ccs[j]=prevCC;
} while(--j!=0);
s[j]=c;
ccs[j]=cc;
} else {
/* just store the combining class */
ccs[i]=cc;
}
}
return (uint16_t)(((uint16_t)ccs[0]<<8)|ccs[length-1]);
}
static UBool combineAndQC[64]={ 0 };
/*
* canonically reorder the up to two decompositions
* and store the leading and trailing combining classes accordingly
*
* also process canonical decompositions for canonical closure
*/
static void
postParseFn(void *context, uint32_t code, Norm *norm) {
int32_t length;
/* canonically order the NFD */
length=norm->lenNFD;
if(length>0) {
norm->canonBothCCs=reorderString(norm->nfd, length);
}
/* canonically reorder the NFKD */
length=norm->lenNFKD;
if(length>0) {
norm->compatBothCCs=reorderString(norm->nfkd, length);
}
/* verify that code has a decomposition if and only if the quick check flags say "no" on NF(K)D */
if((norm->lenNFD!=0) != ((norm->qcFlags&_NORM_QC_NFD)!=0)) {
fprintf(stderr, "gennorm warning: U+%04lx has NFD[%d] but quick check 0x%02x\n", (long)code, norm->lenNFD, norm->qcFlags);
}
if(((norm->lenNFD|norm->lenNFKD)!=0) != ((norm->qcFlags&(_NORM_QC_NFD|_NORM_QC_NFKD))!=0)) {
fprintf(stderr, "gennorm warning: U+%04lx has NFD[%d] NFKD[%d] but quick check 0x%02x\n", (long)code, norm->lenNFD, norm->lenNFKD, norm->qcFlags);
}
/* see which combinations of combiningFlags and qcFlags are used for NFC/NFKC */
combineAndQC[(norm->qcFlags&0x33)|((norm->combiningFlags&3)<<2)]=1;
if(norm->combiningFlags&1) {
if(norm->udataCC!=0) {
/* illegal - data-derivable composition exclusion */
fprintf(stderr, "gennorm warning: U+%04lx combines forward but udataCC==%u\n", (long)code, norm->udataCC);
}
}
if(norm->combiningFlags&2) {
if((norm->qcFlags&0x11)==0) {
fprintf(stderr, "gennorm warning: U+%04lx combines backward but qcNF?C==0\n", (long)code);
}
#if 0
/* occurs sometimes, this one is ok (therefore #if 0) - still here for documentation */
if(norm->udataCC==0) {
printf("U+%04lx combines backward but udataCC==0\n", (long)code);
}
#endif
}
if((norm->combiningFlags&3)==3 && beVerbose) {
printf("U+%04lx combines both ways\n", (long)code);
}
/*
* process canonical decompositions for canonical closure
*
* in each canonical decomposition:
* add the current character (code) to the set of canonical starters of its norm->nfd[0]
* set the "unsafe starter" flag for each norm->nfd[1..]
*/
length=norm->lenNFD;
if(length>0) {
Norm *otherNorm;
UChar32 c;
int32_t i;
/* nfd[0].canonStart.add(code) */
c=norm->nfd[0];
otherNorm=createNorm(c);
if(otherNorm->canonStart==NULL) {
otherNorm->canonStart=uset_open(code, code);
if(otherNorm->canonStart==NULL) {
fprintf(stderr, "gennorm error: out of memory in uset_open()\n");
exit(U_MEMORY_ALLOCATION_ERROR);
}
} else {
uset_add(otherNorm->canonStart, code);
if(!uset_contains(otherNorm->canonStart, code)) {
fprintf(stderr, "gennorm error: uset_add(setOf(U+%4x), U+%4x)\n", c, code);
exit(U_INTERNAL_PROGRAM_ERROR);
}
}
/* for(i=1..length-1) nfd[i].unsafeStart=TRUE */
for(i=1; i<length; ++i) {
createNorm(norm->nfd[i])->unsafeStart=TRUE;
}
}
}
static uint32_t
make32BitNorm(Norm *norm) {
UChar extra[100];
const Norm *other;
uint32_t word;
int32_t i, length, beforeZero=0, count, start;
/*
* Check for assumptions:
*
* Test that if a "true starter" (cc==0 && NF*C_YES) decomposes,
* then the decomposition also begins with a true starter.
*/
if(norm->udataCC==0) {
/* this is a starter */
if((norm->qcFlags&_NORM_QC_NFC)==0 && norm->lenNFD>0) {
/* a "true" NFC starter with a canonical decomposition */
if( norm->canonBothCCs>=0x100 || /* lead cc!=0 or */
((other=getNorm(norm->nfd[0]))!=NULL && (other->qcFlags&_NORM_QC_NFC)!=0) /* nfd[0] not NFC_YES */
) {
fprintf(stderr,
"error: true NFC starter canonical decomposition[%u] does not begin\n"
" with a true NFC starter: U+%04lx U+%04lx%s\n",
norm->lenNFD, (long)norm->nfd[0], (long)norm->nfd[1],
norm->lenNFD<=2 ? "" : " ...");
exit(U_INVALID_TABLE_FILE);
}
}
if((norm->qcFlags&_NORM_QC_NFKC)==0) {
if(norm->lenNFKD>0) {
/* a "true" NFKC starter with a compatibility decomposition */
if( norm->compatBothCCs>=0x100 || /* lead cc!=0 or */
((other=getNorm(norm->nfkd[0]))!=NULL && (other->qcFlags&_NORM_QC_NFKC)!=0) /* nfkd[0] not NFC_YES */
) {
fprintf(stderr,
"error: true NFKC starter compatibility decomposition[%u] does not begin\n"
" with a true NFKC starter: U+%04lx U+%04lx%s\n",
norm->lenNFKD, (long)norm->nfkd[0], (long)norm->nfkd[1], norm->lenNFKD<=2 ? "" : " ...");
exit(U_INVALID_TABLE_FILE);
}
} else if(norm->lenNFD>0) {
/* a "true" NFKC starter with only a canonical decomposition */
if( norm->canonBothCCs>=0x100 || /* lead cc!=0 or */
((other=getNorm(norm->nfd[0]))!=NULL && (other->qcFlags&_NORM_QC_NFKC)!=0) /* nfd[0] not NFC_YES */
) {
fprintf(stderr,
"error: true NFKC starter canonical decomposition[%u] does not begin\n"
" with a true NFKC starter: U+%04lx U+%04lx%s\n",
norm->lenNFD, (long)norm->nfd[0], (long)norm->nfd[1],
norm->lenNFD<=2 ? "" : " ...");
exit(U_INVALID_TABLE_FILE);
}
}
}
}
/* reset the 32-bit word and set the quick check flags */
word=norm->qcFlags;
/* set the UnicodeData combining class */
word|=(uint32_t)norm->udataCC<<_NORM_CC_SHIFT;
/* set the combining flag and index */
if(norm->combiningFlags&3) {
word|=(uint32_t)(norm->combiningFlags&3)<<6;
}
/* set the combining index value into the extra data */
if(norm->combiningIndex!=0) {
extra[0]=norm->combiningIndex;
beforeZero=1;
}
count=beforeZero;
/* write the decompositions */
if((norm->lenNFD|norm->lenNFKD)!=0) {
extra[count++]=0; /* set the pieces when available, into extra[beforeZero] */
length=norm->lenNFD;
if(length>0) {
if(norm->canonBothCCs!=0) {
extra[beforeZero]|=0x80;
extra[count++]=norm->canonBothCCs;
}
start=count;
for(i=0; i<length; ++i) {
UTF_APPEND_CHAR_UNSAFE(extra, count, norm->nfd[i]);
}
extra[beforeZero]|=(UChar)(count-start); /* set the decomp length as the number of UTF-16 code units */
}
length=norm->lenNFKD;
if(length>0) {
if(norm->compatBothCCs!=0) {
extra[beforeZero]|=0x8000;
extra[count++]=norm->compatBothCCs;
}
start=count;
for(i=0; i<length; ++i) {
UTF_APPEND_CHAR_UNSAFE(extra, count, norm->nfkd[i]);
}
extra[beforeZero]|=(UChar)((count-start)<<8); /* set the decomp length as the number of UTF-16 code units */
}
}
/* allocate and copy the extra data */
if(count!=0) {
UChar *p;
if(norm->specialTag!=0) {
fprintf(stderr, "error: gennorm - illegal to have both extra data and a special tag (0x%x)\n", norm->specialTag);
exit(U_ILLEGAL_ARGUMENT_ERROR);
}
p=(UChar *)utm_allocN(extraMem, count);
uprv_memcpy(p, extra, count*2);
/* set the extra index, offset by beforeZero */
word|=(uint32_t)(beforeZero+(p-(UChar *)utm_getStart(extraMem)))<<_NORM_EXTRA_SHIFT;
} else if(norm->specialTag!=0) {
/* set a special tag instead of an extra index */
word|=(uint32_t)norm->specialTag<<_NORM_EXTRA_SHIFT;
}
return word;
}
/* turn all Norm structs into corresponding 32-bit norm values */
static void
makeAll32() {
uint32_t *pNormData;
uint32_t n;
int32_t i, normLength, count;
count=(int32_t)normMem->index;
for(i=0; i<count; ++i) {
norms[i].value32=make32BitNorm(norms+i);
}
pNormData=utrie_getData(norm32Trie, &normLength);
count=0;
for(i=0; i<normLength; ++i) {
n=pNormData[i];
if(0!=(pNormData[i]=norms[n].value32)) {
++count;
}
}
}
/*
* extract all Norm.canonBothCCs into the FCD table
* set 32-bit values to use the common fold and compact functions
*/
static void
makeFCD() {
uint32_t *pFCDData;
uint32_t n;
int32_t i, count, fcdLength;
uint16_t bothCCs;
count=(int32_t)normMem->index;
for(i=0; i<count; ++i) {
bothCCs=norms[i].canonBothCCs;
if(bothCCs==0) {
/* if there are no decomposition cc's then use the udataCC twice */
bothCCs=norms[i].udataCC;
bothCCs|=bothCCs<<8;
}
norms[i].value32=bothCCs;
}
pFCDData=utrie_getData(fcdTrie, &fcdLength);
for(i=0; i<fcdLength; ++i) {
n=pFCDData[i];
pFCDData[i]=norms[n].value32;
}
}
/**
* If the given set contains exactly one character, then return it.
* Otherwise return -1.
*/
static int32_t
usetContainsOne(const USet* set) {
if (uset_size(set) == 1) { /* ### faster to count ranges and check only range?! */
UChar32 start, end;
UErrorCode ec = U_ZERO_ERROR;
int32_t len = uset_getItem(set, 0, &start, &end, NULL, 0, &ec);
if (len == 0) return start;
}
return -1;
}
static void
makeCanonSetFn(void *context, uint32_t code, Norm *norm) {
if(norm->canonStart!=NULL && !uset_isEmpty(norm->canonStart)) {
uint16_t *table;
int32_t c, tableLength;
UErrorCode errorCode=U_ZERO_ERROR;
/* does the set contain exactly one code point? */
c=usetContainsOne(norm->canonStart); /* ### why? */
/* add an entry to the BMP or supplementary search table */
if(code<=0xffff) {
table=canonStartSets+_NORM_MAX_CANON_SETS;
tableLength=canonStartSets[_NORM_SET_INDEX_CANON_BMP_TABLE_LENGTH];
table[tableLength++]=(uint16_t)code;
if(c>=0 && c<=0xffff && (c&_NORM_CANON_SET_BMP_MASK)!=_NORM_CANON_SET_BMP_IS_INDEX) {
/* single-code point BMP result for BMP code point */
table[tableLength++]=(uint16_t)c;
} else {
table[tableLength++]=(uint16_t)(_NORM_CANON_SET_BMP_IS_INDEX|canonStartSetsTop);
c=-1;
}
canonStartSets[_NORM_SET_INDEX_CANON_BMP_TABLE_LENGTH]=(uint16_t)tableLength;
} else {
table=canonStartSets+_NORM_MAX_CANON_SETS+_NORM_MAX_SET_SEARCH_TABLE_LENGTH;
tableLength=canonStartSets[_NORM_SET_INDEX_CANON_SUPP_TABLE_LENGTH];
table[tableLength++]=(uint16_t)(code>>16);
table[tableLength++]=(uint16_t)code;
if(c>=0) {
/* single-code point result for supplementary code point */
table[tableLength-2]|=(uint16_t)(0x8000|((c>>8)&0x1f00)); /* ### how does this work again? */
table[tableLength++]=(uint16_t)c;
} else {
table[tableLength++]=(uint16_t)canonStartSetsTop;
}
canonStartSets[_NORM_SET_INDEX_CANON_SUPP_TABLE_LENGTH]=(uint16_t)tableLength;
}
if(c<0) {
/* write a USerializedSet */
++canonSetsCount;
canonStartSetsTop+=
uset_serialize(norm->canonStart,
canonStartSets+canonStartSetsTop,
_NORM_MAX_CANON_SETS-canonStartSetsTop,
&errorCode);
}
canonStartSets[_NORM_SET_INDEX_CANON_SETS_LENGTH]=(uint16_t)canonStartSetsTop;
if(U_FAILURE(errorCode)) {
fprintf(stderr, "gennorm error: uset_serialize()->%s (canonStartSetsTop=%d)\n", u_errorName(errorCode), canonStartSetsTop);
exit(errorCode);
}
if(tableLength>_NORM_MAX_SET_SEARCH_TABLE_LENGTH) {
fprintf(stderr, "gennorm error: search table for canonical starter sets too long\n");
exit(U_INDEX_OUTOFBOUNDS_ERROR);
}
}
}
/* for getSkippableFlags ---------------------------------------------------- */
/* combine the lead and trail code points; return <0 if they do not combine */
static int32_t
combine(uint32_t lead, uint32_t trail) {
CombiningTriple *triples;
uint32_t i, count;
/* search for all triples with c as lead code point */
triples=utm_getStart(combiningTriplesMem);
count=combiningTriplesMem->index;
/* triples are not sorted by code point but for each lead CP there is one contiguous block */
for(i=0; i<count && lead!=triples[i].lead; ++i) {}
/* check each triple for this code point */
for(; i<count && lead==triples[i].lead; ++i) {
if(trail==triples[i].trail) {
return (int32_t)triples[i].combined;
}
}
return -1;
}
/*
* Starting from the canonical decomposition s[0..length[ of a single code point,
* is the code point c consumed in an NFC/FCC recomposition?
*
* No need to handle discontiguous composition because that would not consume some
* intermediate character, so would not compose back to the original character.
* See comments in canChangeWithFollowing().
*
* No need to compose beyond where c canonically orders because if it is consumed
* then the result differs from the original anyway.
*
* Possible optimization:
* - Verify that there are no cases of the same combining mark stacking twice.
* - return FALSE right away if c inserts after a copy of itself
* without attempting to recompose; will happen because each mark in
* the decomposition will be enumerated and passed in as c.
* More complicated and fragile though than it is already.
*
* markus 2002nov04
*/
static UBool
doesComposeConsume(const uint32_t *s, int32_t length, uint32_t c, uint8_t cc) {
int32_t starter, i;
/* ignore trailing characters where cc<prevCC */
while(length>1 && cc<getCCFromCP(s[length-1])) {
--length;
}
/* start consuming/combining from the beginning */
starter=(int32_t)s[0];
for(i=1; i<length; ++i) {
starter=combine((uint32_t)starter, s[i]);
if(starter<0) {
fprintf(stderr, "error: unable to consume normal decomposition in doesComposeConsume(<%04x, %04x, ...>[%ld], U+%04lx, %u)\n",
s[0], s[1], (long)length, (long)c, cc);
exit(U_INTERNAL_PROGRAM_ERROR);
}
}
/* try to combine/consume c, return TRUE if it is consumed */
return combine((uint32_t)starter, c)>=0;
}
/* does the starter s[0] combine forward with another char that is below trailCC? */
static UBool
canChangeWithFollowing(const uint32_t *s, int32_t length, uint8_t trailCC) {
if(trailCC<=1) {
/* no character will combine ahead of the trailing char of the decomposition */
return FALSE;
}
/*
* We are only checking skippable condition (f).
* Therefore, the original character does not have quick check flag NFC_NO (c),
* i.e., the decomposition recomposes completely back into the original code point.
* So s[0] must be a true starter with cc==0 and
* combining with following code points.
*
* Similarly, length==1 is not possible because that would be a singleton
* decomposition which is marked with NFC_NO and does not pass (c).
*
* Only a character with cc<trailCC can change the composition.
* Reason: A char with cc>=trailCC would order after decomposition s[],
* composition would consume all of the decomposition, and here we know that
* the original char passed check d), i.e., it does not combine forward,
* therefore does not combine with anything after the decomposition is consumed.
*
* Now see if there is a character that
* 1. combines backward
* 2. has cc<trailCC
* 3. is consumed in recomposition
*
* length==2 is simple:
*
* Characters that fulfill these conditions are exactly the ones that combine directly
* with the starter c==s[0] because there is no intervening character after
* reordering.
* We can just enumerate all chars with which c combines (they all pass 1. and 3.)
* and see if one has cc<trailCC (passes 2.).
*
* length>2 is a little harder:
*
* Since we will get different starters during recomposition, we need to
* enumerate each backward-combining character (1.)
* with cc<trailCC (2.) and
* see if it gets consumed in recomposition. (3.)
* No need to enumerate both-ways combining characters because they must have cc==0.
*/
if(length==2) {
/* enumerate all chars that combine with this one and check their cc */
CombiningTriple *triples;
uint32_t c, i, count;
uint8_t cc;
/* search for all triples with c as lead code point */
triples=utm_getStart(combiningTriplesMem);
count=combiningTriplesMem->index;
c=s[0];
/* triples are not sorted by code point but for each lead CP there is one contiguous block */
for(i=0; i<count && c!=triples[i].lead; ++i) {}
/* check each triple for this code point */
for(; i<count && c==triples[i].lead; ++i) {
cc=getCCFromCP(triples[i].trail);
if(cc>0 && cc<trailCC) {
/* this trail code point combines with c and has cc<trailCC */
return TRUE;
}
}
} else {
/* enumerate all chars that combine backward */
uint32_t c2;
uint16_t i;
uint8_t cc;
for(i=combineBothTop; i<combineBackTop; ++i) {
c2=combiningCPs[i]&0xffffff;
cc=getCCFromCP(c2);
/* pass in length-1 because we already know that c2 will insert before the last character with trailCC */
if(cc>0 && cc<trailCC && doesComposeConsume(s, length-1, c2, cc)) {
return TRUE;
}
}
}
/* this decomposition is not modified by any appended character */
return FALSE;
}
/* see unormimp.h for details on NF*C Skippable flags */
static uint32_t
getSkippableFlags(const Norm *norm) {
/* ignore NF*D skippable properties because they are covered by norm32, test at runtime */
/* ignore Hangul, test those at runtime (LV Hangul are not skippable) */
if(norm->specialTag==_NORM_EXTRA_INDEX_TOP+_NORM_EXTRA_HANGUL) {
return 0;
}
/* ### check other data generation functions whether they should & do ignore Hangul/Jamo specials */
/*
* Note:
* This function returns a non-zero flag only if (a)..(e) indicate skippable but (f) does not.
*
* This means that (a)..(e) must always be derived from the runtime norm32 value,
* and (f) be checked from the auxTrie if the character is skippable per (a)..(e),
* the form is NF*C and there is a canonical decomposition (NFD_NO).
*
* (a) unassigned code points get "not skippable"==false because they
* don't have a Norm struct so they won't get here
*/
/* (b) not skippable if cc!=0 */
if(norm->udataCC!=0) {
return 0; /* non-zero flag for (f) only */
}
/*
* not NFC_Skippable if
* (c) quick check flag == NO or
* (d) combines forward or
* (e) combines back or
* (f) can change if another character is added
*
* for (f):
* For NF*C: Get corresponding decomposition, get its last starter (cc==0),
* check its composition list,
* see if any of the second code points in the list
* has cc less than the trailCC of the decomposition.
*
* For FCC: Test at runtime if the decomposition has a trailCC>1
* -> there are characters with cc==1, they would order before the trail char
* and prevent contiguous combination with the trail char.
*/
if( (norm->qcFlags&(_NORM_QC_NFC&_NORM_QC_ANY_NO))!=0 ||
(norm->combiningFlags&3)!=0) {
return 0; /* non-zero flag for (f) only */
}
if(norm->lenNFD!=0 && canChangeWithFollowing(norm->nfd, norm->lenNFD, (uint8_t)norm->canonBothCCs)) {
return _NORM_AUX_NFC_SKIP_F_MASK;
}
return 0; /* skippable */
}
static void
makeAux() {
Norm *norm;
uint32_t *pData;
int32_t i, length;
pData=utrie_getData(auxTrie, &length);
for(i=0; i<length; ++i) {
norm=norms+pData[i];
/*
* 16-bit auxiliary normalization properties
* see unormimp.h
*/
pData[i]=
((uint32_t)(norm->combiningFlags&0x80)<<(_NORM_AUX_COMP_EX_SHIFT-7))|
(uint32_t)norm->fncIndex;
if(norm->unsafeStart || norm->udataCC!=0) {
pData[i]|=_NORM_AUX_UNSAFE_MASK;
}
pData[i]|=getSkippableFlags(norm);
}
}
/* folding value for normalization: just store the offset (16 bits) if there is any non-0 entry */
static uint32_t U_CALLCONV
getFoldedNormValue(UNewTrie *trie, UChar32 start, int32_t offset) {
uint32_t value, leadNorm32=0;
UChar32 limit;
UBool inBlockZero;
limit=start+0x400;
while(start<limit) {
value=utrie_get32(trie, start, &inBlockZero);
if(inBlockZero) {
start+=UTRIE_DATA_BLOCK_LENGTH;
} else {
if(value!=0) {
leadNorm32|=value;
}
++start;
}
}
/* turn multi-bit fields into the worst-case value */
if(leadNorm32&_NORM_CC_MASK) {
leadNorm32|=_NORM_CC_MASK;
}
/* clean up unnecessarily ored bit fields */
leadNorm32&=~((uint32_t)0xffffffff<<_NORM_EXTRA_SHIFT);
if(leadNorm32==0) {
/* nothing to do (only composition exclusions?) */
return 0;
}
/* add the extra surrogate index, offset by the BMP top, for the new stage 1 location */
leadNorm32|=(
(uint32_t)_NORM_EXTRA_INDEX_TOP+
(uint32_t)((offset-UTRIE_BMP_INDEX_LENGTH)>>UTRIE_SURROGATE_BLOCK_BITS)
)<<_NORM_EXTRA_SHIFT;
return leadNorm32;
}
/* folding value for FCD: just store the offset (16 bits) if there is any non-0 entry */
static uint32_t U_CALLCONV
getFoldedFCDValue(UNewTrie *trie, UChar32 start, int32_t offset) {
uint32_t value;
UChar32 limit;
UBool inBlockZero;
limit=start+0x400;
while(start<limit) {
value=utrie_get32(trie, start, &inBlockZero);
if(inBlockZero) {
start+=UTRIE_DATA_BLOCK_LENGTH;
} else if(value!=0) {
return (uint32_t)offset;
} else {
++start;
}
}
return 0;
}
/*
* folding value for auxiliary data:
* store the non-zero offset in bits 9..0 (FNC bits)
* if there is any non-0 entry;
* "or" [verb!] together data bits 15..10 of all of the 1024 supplementary code points
*/
static uint32_t U_CALLCONV
getFoldedAuxValue(UNewTrie *trie, UChar32 start, int32_t offset) {
uint32_t value, oredValues;
UChar32 limit;
UBool inBlockZero;
oredValues=0;
limit=start+0x400;
while(start<limit) {
value=utrie_get32(trie, start, &inBlockZero);
if(inBlockZero) {
start+=UTRIE_DATA_BLOCK_LENGTH;
} else {
oredValues|=value;
++start;
}
}
if(oredValues!=0) {
/* move the 10 significant offset bits into bits 9..0 */
offset>>=UTRIE_SURROGATE_BLOCK_BITS;
if(offset>_NORM_AUX_FNC_MASK) {
fprintf(stderr, "gennorm error: folding offset too large (auxTrie)\n");
exit(U_INDEX_OUTOFBOUNDS_ERROR);
}
return (uint32_t)offset|(oredValues&~_NORM_AUX_FNC_MASK);
} else {
return 0;
}
}
extern void
processData() {
#if 0
uint16_t i;
#endif
processCombining();
/* canonically reorder decompositions and assign combining classes for decompositions */
enumTrie(postParseFn, NULL);
#if 0
for(i=1; i<64; ++i) {
if(combineAndQC[i]) {
printf("combiningFlags==0x%02x qcFlags(NF?C)==0x%02x\n", (i&0xc)>>2, i&0x33);
}
}
#endif
/* add hangul/jamo specials */
setHangulJamoSpecials();
/* store search tables and USerializedSets for canonical starters (after Hangul/Jamo specials!) */
enumTrie(makeCanonSetFn, NULL);
/* clone the normalization builder trie to make the final data tries */
if( NULL==utrie_clone(norm32Trie, normTrie, NULL, 0) ||
NULL==utrie_clone(fcdTrie, normTrie, NULL, 0) ||
NULL==utrie_clone(auxTrie, normTrie, NULL, 0)
) {
fprintf(stderr, "error: unable to clone the normalization trie\n");
exit(U_MEMORY_ALLOCATION_ERROR);
}
/* --- finalize data for quick checks & normalization --- */
/* turn the Norm structs (stage2, norms) into 32-bit data words */
makeAll32();
/* --- finalize data for FCD checks --- */
/* FCD data: take Norm.canonBothCCs and store them in the FCD table */
makeFCD();
/* --- finalize auxiliary normalization data --- */
makeAux();
if(beVerbose) {
#if 0
printf("number of stage 2 entries: %ld\n", stage2Mem->index);
printf("size of stage 1 (BMP) & 2 (uncompacted) + extra data: %ld bytes\n", _NORM_STAGE_1_BMP_COUNT*2+stage2Mem->index*4+extraMem->index*2);
#endif
printf("combining CPs tops: fwd %u both %u back %u\n", combineFwdTop, combineBothTop, combineBackTop);
printf("combining table count: %u\n", combiningTableTop);
}
}
#endif /* #if !UCONFIG_NO_NORMALIZATION */
extern void
generateData(const char *dataDir) {
static uint8_t normTrieBlock[100000], fcdTrieBlock[100000], auxTrieBlock[100000];
UNewDataMemory *pData;
UErrorCode errorCode=U_ZERO_ERROR;
int32_t size, dataLength;
#if UCONFIG_NO_NORMALIZATION
size=0;
#else
int32_t normTrieSize, fcdTrieSize, auxTrieSize;
normTrieSize=utrie_serialize(norm32Trie, normTrieBlock, sizeof(normTrieBlock), getFoldedNormValue, FALSE, &errorCode);
if(U_FAILURE(errorCode)) {
fprintf(stderr, "error: utrie_serialize(normalization properties) failed, %s\n", u_errorName(errorCode));
exit(errorCode);
}
fcdTrieSize=utrie_serialize(fcdTrie, fcdTrieBlock, sizeof(fcdTrieBlock), getFoldedFCDValue, TRUE, &errorCode);
if(U_FAILURE(errorCode)) {
fprintf(stderr, "error: utrie_serialize(FCD data) failed, %s\n", u_errorName(errorCode));
exit(errorCode);
}
auxTrieSize=utrie_serialize(auxTrie, auxTrieBlock, sizeof(auxTrieBlock), getFoldedAuxValue, TRUE, &errorCode);
if(U_FAILURE(errorCode)) {
fprintf(stderr, "error: utrie_serialize(auxiliary data) failed, %s\n", u_errorName(errorCode));
exit(errorCode);
}
/* move the parts of canonStartSets[] together into a contiguous block */
if(canonStartSetsTop<_NORM_MAX_CANON_SETS) {
uprv_memmove(canonStartSets+canonStartSetsTop,
canonStartSets+_NORM_MAX_CANON_SETS,
canonStartSets[_NORM_SET_INDEX_CANON_BMP_TABLE_LENGTH]*2);
}
canonStartSetsTop+=canonStartSets[_NORM_SET_INDEX_CANON_BMP_TABLE_LENGTH];
if(canonStartSetsTop<(_NORM_MAX_CANON_SETS+_NORM_MAX_SET_SEARCH_TABLE_LENGTH)) {
uprv_memmove(canonStartSets+canonStartSetsTop,
canonStartSets+_NORM_MAX_CANON_SETS+_NORM_MAX_SET_SEARCH_TABLE_LENGTH,
canonStartSets[_NORM_SET_INDEX_CANON_SUPP_TABLE_LENGTH]*2);
}
canonStartSetsTop+=canonStartSets[_NORM_SET_INDEX_CANON_SUPP_TABLE_LENGTH];
/* make sure that the FCD trie is 4-aligned */
if((extraMem->index+combiningTableTop)&1) {
combiningTable[combiningTableTop++]=0x1234; /* add one 16-bit word for an even number */
}
/* pad canonStartSets to 4-alignment, too */
if(canonStartSetsTop&1) {
canonStartSets[canonStartSetsTop++]=0x1235;
}
size=
_NORM_INDEX_TOP*4+
normTrieSize+
extraMem->index*2+
combiningTableTop*2+
fcdTrieSize+
auxTrieSize+
canonStartSetsTop*2;
if(beVerbose) {
printf("size of normalization trie %5u bytes\n", normTrieSize);
printf("size of 16-bit extra memory %5u UChars/uint16_t\n", extraMem->index);
printf(" of that: FC_NFKC_Closure size %5u UChars/uint16_t\n", ((uint16_t *)utm_getStart(extraMem))[0]);
printf("size of combining table %5u uint16_t\n", combiningTableTop);
printf("size of FCD trie %5u bytes\n", fcdTrieSize);
printf("size of auxiliary trie %5u bytes\n", auxTrieSize);
printf("size of canonStartSets[] %5u uint16_t\n", canonStartSetsTop);
printf(" number of indexes %5u uint16_t\n", _NORM_SET_INDEX_TOP);
printf(" size of sets %5u uint16_t\n", canonStartSets[_NORM_SET_INDEX_CANON_SETS_LENGTH]-_NORM_SET_INDEX_TOP);
printf(" number of sets %5d\n", canonSetsCount);
printf(" size of BMP search table %5u uint16_t\n", canonStartSets[_NORM_SET_INDEX_CANON_BMP_TABLE_LENGTH]);
printf(" size of supplementary search table %5u uint16_t\n", canonStartSets[_NORM_SET_INDEX_CANON_SUPP_TABLE_LENGTH]);
printf("size of " U_ICUDATA_NAME "_" DATA_NAME "." DATA_TYPE " contents: %ld bytes\n", (long)size);
}
indexes[_NORM_INDEX_TRIE_SIZE]=normTrieSize;
indexes[_NORM_INDEX_UCHAR_COUNT]=(uint16_t)extraMem->index;
indexes[_NORM_INDEX_COMBINE_DATA_COUNT]=combiningTableTop;
indexes[_NORM_INDEX_COMBINE_FWD_COUNT]=combineFwdTop;
indexes[_NORM_INDEX_COMBINE_BOTH_COUNT]=(uint16_t)(combineBothTop-combineFwdTop);
indexes[_NORM_INDEX_COMBINE_BACK_COUNT]=(uint16_t)(combineBackTop-combineBothTop);
/* the quick check minimum code points are already set */
indexes[_NORM_INDEX_FCD_TRIE_SIZE]=fcdTrieSize;
indexes[_NORM_INDEX_AUX_TRIE_SIZE]=auxTrieSize;
indexes[_NORM_INDEX_CANON_SET_COUNT]=canonStartSetsTop;
#endif
/* write the data */
pData=udata_create(dataDir, DATA_TYPE, U_ICUDATA_NAME "_" DATA_NAME, &dataInfo,
haveCopyright ? U_COPYRIGHT_STRING : NULL, &errorCode);
if(U_FAILURE(errorCode)) {
fprintf(stderr, "gennorm: unable to create the output file, error %d\n", errorCode);
exit(errorCode);
}
#if !UCONFIG_NO_NORMALIZATION
udata_writeBlock(pData, indexes, sizeof(indexes));
udata_writeBlock(pData, normTrieBlock, normTrieSize);
udata_writeBlock(pData, utm_getStart(extraMem), extraMem->index*2);
udata_writeBlock(pData, combiningTable, combiningTableTop*2);
udata_writeBlock(pData, fcdTrieBlock, fcdTrieSize);
udata_writeBlock(pData, auxTrieBlock, auxTrieSize);
udata_writeBlock(pData, canonStartSets, canonStartSetsTop*2);
#endif
/* finish up */
dataLength=udata_finish(pData, &errorCode);
if(U_FAILURE(errorCode)) {
fprintf(stderr, "gennorm: error %d writing the output file\n", errorCode);
exit(errorCode);
}
if(dataLength!=size) {
fprintf(stderr, "gennorm error: data length %ld != calculated size %ld\n",
(long)dataLength, (long)size);
exit(U_INTERNAL_PROGRAM_ERROR);
}
}
#if !UCONFIG_NO_NORMALIZATION
extern void
cleanUpData(void) {
int32_t i, count;
count=(int32_t)normMem->index;
for(i=0; i<count; ++i) {
uset_close(norms[i].canonStart);
}
utm_close(normMem);
utm_close(utf32Mem);
utm_close(extraMem);
utm_close(combiningTriplesMem);
utrie_close(normTrie);
utrie_close(norm32Trie);
utrie_close(fcdTrie);
utrie_close(auxTrie);
uprv_free(normTrie);
uprv_free(norm32Trie);
uprv_free(fcdTrie);
uprv_free(auxTrie);
}
#endif /* #if !UCONFIG_NO_NORMALIZATION */
/*
* Hey, Emacs, please set the following:
*
* Local Variables:
* indent-tabs-mode: nil
* End:
*
*/