scuffed-code/icu4c/source/common/ucmp16.c
1999-12-07 00:35:36 +00:00

473 lines
14 KiB
C

/*
*****************************************************************************************
* *
* COPYRIGHT: *
* (C) Copyright Taligent, Inc., 1997 *
* (C) Copyright International Business Machines Corporation, 1997-1998 *
* Licensed Material - Program-Property of IBM - All Rights Reserved. *
* US Government Users Restricted Rights - Use, duplication, or disclosure *
* restricted by GSA ADP Schedule Contract with IBM Corp. *
* *
*****************************************************************************************
*/
/*===============================================================================
*
* File cmpshrta.cpp
*
* Modification History:
*
* Date Name Description
* 2/5/97 aliu Added CompactIntArray streamIn and streamOut methods.
* 3/4/97 aliu Tuned performance of CompactIntArray constructor,
* 05/07/97 helena Added isBogus()
* based on performance data indicating that this_obj was slow.
* 07/15/98 erm Synched with Java 1.2 CompactShortArray.java.
* 07/30/98 erm Added changes from 07/29/98 code review.
* 11/01/99 weiv Added getArray, getIndex and getCount based on Jitterbug 4
*===============================================================================
*/
#include "ucmp16.h"
#include "cmemory.h"
#define arrayRegionMatches(source, sourceStart, target, targetStart, len) (icu_memcmp(&source[sourceStart], &target[targetStart], len * sizeof(int16_t)) != 0)
/* internal constants*/
#define UCMP16_kMaxUnicode_int 65535
#define UCMP16_kUnicodeCount_int (UCMP16_kMaxUnicode_int + 1)
#define UCMP16_kBlockShift_int 7
#define UCMP16_kBlockCount_int (1 << UCMP16_kBlockShift_int)
#define UCMP16_kBlockBytes_int (UCMP16_kBlockCount_int * sizeof(int16_t))
#define UCMP16_kIndexShift_int (16 - UCMP16_kBlockShift_int)
#define UCMP16_kIndexCount_int (1 << UCMP16_kIndexShift_int)
#define UCMP16_kBlockMask_int (UCMP16_kBlockCount_int - 1)
const int32_t UCMP16_kMaxUnicode = UCMP16_kMaxUnicode_int;
const int32_t UCMP16_kUnicodeCount = UCMP16_kUnicodeCount_int;
const int32_t UCMP16_kBlockShift = UCMP16_kBlockShift_int;
const int32_t UCMP16_kBlockCount = UCMP16_kBlockCount_int;
const int32_t UCMP16_kBlockBytes = UCMP16_kBlockBytes_int;
const int32_t UCMP16_kIndexShift = UCMP16_kIndexShift_int;
const int32_t UCMP16_kIndexCount = UCMP16_kIndexCount_int;
const uint32_t UCMP16_kBlockMask = UCMP16_kBlockMask_int;
/**
* Sets the array to the invalid memory state.
*/
static CompactShortArray* setToBogus(CompactShortArray* array);
static void touchBlock(CompactShortArray* this_obj,
int32_t i,
int16_t value);
static bool_t blockTouched(const CompactShortArray* this_obj,
int32_t i);
/* debug flags*/
/*=======================================================*/
int32_t ucmp16_getkUnicodeCount()
{return UCMP16_kUnicodeCount;}
int32_t ucmp16_getkBlockCount()
{return UCMP16_kBlockCount;}
CompactShortArray* ucmp16_open(int16_t defaultValue)
{
int32_t i;
CompactShortArray* this_obj = (CompactShortArray*) icu_malloc(sizeof(CompactShortArray));
if (this_obj == NULL) return NULL;
this_obj->fStructSize = sizeof(CompactShortArray);
this_obj->fCount = UCMP16_kUnicodeCount;
this_obj->fCompact = FALSE;
this_obj->fBogus = FALSE;
this_obj->fArray = NULL;
this_obj->fAlias = FALSE;
this_obj->fIndex = NULL;
this_obj->fHashes = NULL;
this_obj->fDefaultValue = defaultValue;
this_obj->fArray = (int16_t*)icu_malloc(UCMP16_kUnicodeCount * sizeof(int16_t));
if (this_obj->fArray == NULL)
{
this_obj->fBogus = TRUE;
return NULL;
}
this_obj->fIndex = (uint16_t*)icu_malloc(UCMP16_kIndexCount * sizeof(uint16_t));
if (this_obj->fIndex == NULL)
{
icu_free(this_obj->fArray);
this_obj->fArray = NULL;
this_obj->fBogus = TRUE;
return NULL;
}
this_obj->kBlockShift = UCMP16_kBlockShift;
this_obj->kBlockMask = UCMP16_kBlockMask;
for (i = 0; i < UCMP16_kUnicodeCount; i += 1)
{
this_obj->fArray[i] = defaultValue;
}
this_obj->fHashes =(int32_t*)icu_malloc(UCMP16_kIndexCount * sizeof(int32_t));
if (this_obj->fHashes == NULL)
{
icu_free(this_obj->fArray);
icu_free(this_obj->fIndex);
this_obj->fBogus = TRUE;
return NULL;
}
for (i = 0; i < UCMP16_kIndexCount; i += 1)
{
this_obj->fIndex[i] = (uint16_t)(i << UCMP16_kBlockShift);
this_obj->fHashes[i] = 0;
}
return this_obj;
}
CompactShortArray* ucmp16_openAdopt(uint16_t *indexArray,
int16_t *newValues,
int32_t count,
int16_t defaultValue)
{
CompactShortArray* this_obj = (CompactShortArray*) icu_malloc(sizeof(CompactShortArray));
if (this_obj == NULL) return NULL;
this_obj->fHashes = NULL;
this_obj->fCount = count;
this_obj->fDefaultValue = defaultValue;
this_obj->fBogus = FALSE;
this_obj->fArray = newValues;
this_obj->fIndex = indexArray;
this_obj->fCompact = count < UCMP16_kUnicodeCount;
this_obj->fStructSize = sizeof(CompactShortArray);
this_obj->kBlockShift = UCMP16_kBlockShift;
this_obj->kBlockMask = UCMP16_kBlockMask;
this_obj->fAlias = FALSE;
return this_obj;
}
CompactShortArray* ucmp16_openAdoptWithBlockShift(uint16_t *indexArray,
int16_t *newValues,
int32_t count,
int16_t defaultValue,
int32_t blockShift)
{
CompactShortArray* this_obj = ucmp16_openAdopt(indexArray,
newValues,
count,
defaultValue);
if (this_obj == NULL) return NULL;
this_obj->kBlockShift = blockShift;
this_obj->kBlockMask = (uint32_t) (((uint32_t)1 << (uint32_t)blockShift) - (uint32_t)1);
return this_obj;
}
CompactShortArray* ucmp16_openAlias(uint16_t *indexArray,
int16_t *newValues,
int32_t count,
int16_t defaultValue)
{
CompactShortArray* this_obj = (CompactShortArray*) icu_malloc(sizeof(CompactShortArray));
if (this_obj == NULL) return NULL;
this_obj->fHashes = NULL;
this_obj->fCount = count;
this_obj->fDefaultValue = defaultValue;
this_obj->fBogus = FALSE;
this_obj->fArray = newValues;
this_obj->fIndex = indexArray;
this_obj->fCompact = count < UCMP16_kUnicodeCount;
this_obj->fStructSize = sizeof(CompactShortArray);
this_obj->kBlockShift = UCMP16_kBlockShift;
this_obj->kBlockMask = UCMP16_kBlockMask;
this_obj->fAlias = TRUE;
return this_obj;
}
/*=======================================================*/
void ucmp16_close(CompactShortArray* this_obj)
{
if(this_obj != NULL) {
if(!this_obj->fAlias) {
if(this_obj->fArray != NULL) {
icu_free(this_obj->fArray);
}
if(this_obj->fIndex != NULL) {
icu_free(this_obj->fIndex);
}
}
if(this_obj->fHashes != NULL) {
icu_free(this_obj->fHashes);
}
icu_free(this_obj);
}
}
CompactShortArray* setToBogus(CompactShortArray* this_obj)
{
if(this_obj != NULL) {
if(!this_obj->fAlias) {
icu_free(this_obj->fArray);
this_obj->fArray = NULL;
icu_free(this_obj->fIndex);
this_obj->fIndex = NULL;
}
icu_free(this_obj->fHashes);
this_obj->fHashes = NULL;
this_obj->fCount = 0;
this_obj->fCompact = FALSE;
this_obj->fBogus = TRUE;
}
return this_obj;
}
void ucmp16_expand(CompactShortArray* this_obj)
{
if (this_obj->fCompact)
{
int32_t i;
int16_t *tempArray = (int16_t*)icu_malloc(UCMP16_kUnicodeCount * sizeof(int16_t));
if (tempArray == NULL)
{
this_obj->fBogus = TRUE;
return;
}
for (i = 0; i < UCMP16_kUnicodeCount; i += 1)
{
tempArray[i] = ucmp16_get(this_obj, (UChar)i); /* HSYS : How expand?*/
}
for (i = 0; i < (1 << (16 - this_obj->kBlockShift)); i += 1)
{
this_obj->fIndex[i] = (uint16_t)(i<<this_obj->kBlockShift);
}
icu_free(this_obj->fArray);
this_obj->fArray = tempArray;
this_obj->fCompact = FALSE;
}
}
void ucmp16_set(CompactShortArray* this_obj,
UChar c,
int16_t value)
{
if (this_obj->fCompact)
{
ucmp16_expand(this_obj);
if (this_obj->fBogus) return;
}
this_obj->fArray[(int32_t)c] = value;
if (value != this_obj->fDefaultValue)
{
touchBlock(this_obj, c >> this_obj->kBlockShift, value);
}
}
void ucmp16_setRange(CompactShortArray* this_obj,
UChar start,
UChar end,
int16_t value)
{
int32_t i;
if (this_obj->fCompact)
{
ucmp16_expand(this_obj);
if (this_obj->fBogus) return;
}
if (value != this_obj->fDefaultValue)
{
for (i = start; i <= end; i += 1)
{
this_obj->fArray[i] = value;
touchBlock(this_obj, i >> this_obj->kBlockShift, value);
}
}
else
{
for (i = start; i <= end; i += 1) this_obj->fArray[i] = value;
}
}
/*=======================================================*/
void ucmp16_compact(CompactShortArray* this_obj)
{
if (!this_obj->fCompact)
{
int32_t limitCompacted = 0;
int32_t i, iBlockStart;
int16_t iUntouched = -1;
for (i = 0, iBlockStart = 0; i < (1 << (16 - this_obj->kBlockShift)); i += 1, iBlockStart += (1 << this_obj->kBlockShift))
{
bool_t touched = blockTouched(this_obj, i);
this_obj->fIndex[i] = 0xFFFF;
if (!touched && iUntouched != -1)
{
/* If no values in this_obj block were set, we can just set its
* index to be the same as some other block with no values
* set, assuming we've seen one yet.
*/
this_obj->fIndex[i] = iUntouched;
}
else
{
int32_t j, jBlockStart;
for (j = 0, jBlockStart = 0;
j < limitCompacted;
j += 1, jBlockStart += (1 << this_obj->kBlockShift))
{
if (this_obj->fHashes[i] == this_obj->fHashes[j] &&
arrayRegionMatches(this_obj->fArray,
iBlockStart,
this_obj->fArray,
jBlockStart,
(1 << this_obj->kBlockShift)))
{
this_obj->fIndex[i] = (int16_t)jBlockStart;
}
}
/* TODO: verify this_obj is correct*/
if (this_obj->fIndex[i] == 0xFFFF)
{
/* we didn't match, so copy & update*/
icu_memcpy(&(this_obj->fArray[jBlockStart]),
&(this_obj->fArray[iBlockStart]),
(1 << this_obj->kBlockShift)*sizeof(int16_t));
this_obj->fIndex[i] = (int16_t)jBlockStart;
this_obj->fHashes[j] = this_obj->fHashes[i];
limitCompacted += 1;
if (!touched)
{
/* If this_obj is the first untouched block we've seen,*/
/* remember its index.*/
iUntouched = (int16_t)jBlockStart;
}
}
}
}
/* we are done compacting, so now make the array shorter*/
{
int32_t newSize = limitCompacted * (1 << this_obj->kBlockShift);
int16_t *result = (int16_t*) icu_malloc(sizeof(int16_t) * newSize);
icu_memcpy(result, this_obj->fArray, newSize * sizeof(int16_t));
icu_free(this_obj->fArray);
this_obj->fArray = result;
this_obj->fCount = newSize;
icu_free(this_obj->fHashes);
this_obj->fHashes = NULL;
this_obj->fCompact = TRUE;
}
}
}
/**
* Query whether a specified block was "touched", i.e. had a value set.
* Untouched blocks can be skipped when compacting the array
*/
int16_t ucmp16_getDefaultValue(const CompactShortArray* this_obj)
{
return this_obj->fDefaultValue;
}
void touchBlock(CompactShortArray* this_obj,
int32_t i,
int16_t value)
{
this_obj->fHashes[i] = (this_obj->fHashes[i] + (value << 1)) | 1;
}
bool_t blockTouched(const CompactShortArray* this_obj, int32_t i)
{
return (this_obj->fHashes[i] != 0);
}
uint32_t ucmp16_getCount(const CompactShortArray* this_obj)
{
return this_obj->fCount;
}
const int16_t* ucmp16_getArray(const CompactShortArray* this_obj)
{
return this_obj->fArray;
}
const uint16_t* ucmp16_getIndex(const CompactShortArray* this_obj)
{
return this_obj->fIndex;
}
/* We use sizeof(*array), etc so that this code can be as portable as
possible between the ucmpX_ family. Check lines marked 'SIZE'.
*/
U_CAPI CompactShortArray * U_EXPORT2 ucmp16_cloneFromData(const uint8_t **source, UErrorCode *status)
{
CompactShortArray *array;
const CompactShortArray *oldArray;
if(U_FAILURE(*status))
return NULL;
oldArray= (const CompactShortArray*)*source;
if(oldArray->fStructSize != sizeof(*oldArray))
{
*status = U_INVALID_TABLE_FORMAT; /* ? */
return NULL;
}
array = (CompactShortArray*)malloc(sizeof(*array));
icu_memcpy(array,*source, sizeof(*array));
*source += array->fStructSize;
array->fArray = (int16_t*)*source; /* SIZE */
*source += (sizeof(int16_t)*array->fCount); /* SIZE */
array->fIndex = (uint16_t*)*source;
*source += (sizeof(uint16_t)*UCMP16_kIndexCount); /* SIZE*/
array->fAlias = TRUE;
return array;
}