src/third_party/icu/source/common/propsvec.c - cobalt - Git at Google

 /*
 *******************************************************************************
 *
 *   Copyright (C) 2002-2011, International Business Machines
 *   Corporation and others.  All Rights Reserved.
 *
 *******************************************************************************
 *   file name:  propsvec.c
 *   encoding:   US-ASCII
 *   tab size:   8 (not used)
 *   indentation:4
 *
 *   created on: 2002feb22
 *   created by: Markus W. Scherer
 *
 *   Store bits (Unicode character properties) in bit set vectors.
 */

 #include "starboard/client_porting/poem/assert_poem.h"
 #include "starboard/client_porting/poem/string_poem.h"
 #if !defined(STARBOARD)
 #include <stdlib.h>
 #endif
 #include "unicode/utypes.h"
 #include "cmemory.h"
 #include "utrie.h"
 #include "utrie2.h"
 #include "uarrsort.h"
 #include "propsvec.h"
 #include "uassert.h"

 struct UPropsVectors {
     uint32_t *v;
     int32_t columns;  /* number of columns, plus two for start & limit values */
     int32_t maxRows;
     int32_t rows;
     int32_t prevRow;  /* search optimization: remember last row seen */
     UBool isCompacted;
 };

 #define UPVEC_INITIAL_ROWS (1<<12)
 #define UPVEC_MEDIUM_ROWS ((int32_t)1<<16)
 #define UPVEC_MAX_ROWS (UPVEC_MAX_CP+1)

 U_CAPI UPropsVectors * U_EXPORT2
 upvec_open(int32_t columns, UErrorCode *pErrorCode) {
     UPropsVectors *pv;
     uint32_t *v, *row;
     uint32_t cp;

     if(U_FAILURE(*pErrorCode)) {
         return NULL;
     }
     if(columns<1) {
         *pErrorCode=U_ILLEGAL_ARGUMENT_ERROR;
         return NULL;
     }
     columns+=2; /* count range start and limit columns */

     pv=(UPropsVectors *)uprv_malloc(sizeof(UPropsVectors));
     v=(uint32_t *)uprv_malloc(UPVEC_INITIAL_ROWS*columns*4);
     if(pv==NULL || v==NULL) {
         uprv_free(pv);
         uprv_free(v);
         *pErrorCode=U_MEMORY_ALLOCATION_ERROR;
         return NULL;
     }
     uprv_memset(pv, 0, sizeof(UPropsVectors));
     pv->v=v;
     pv->columns=columns;
     pv->maxRows=UPVEC_INITIAL_ROWS;
     pv->rows=2+(UPVEC_MAX_CP-UPVEC_FIRST_SPECIAL_CP);

     /* set the all-Unicode row and the special-value rows */
     row=pv->v;
     uprv_memset(row, 0, pv->rows*columns*4);
     row[0]=0;
     row[1]=0x110000;
     row+=columns;
     for(cp=UPVEC_FIRST_SPECIAL_CP; cp<=UPVEC_MAX_CP; ++cp) {
         row[0]=cp;
         row[1]=cp+1;
         row+=columns;
     }
     return pv;
 }

 U_CAPI void U_EXPORT2
 upvec_close(UPropsVectors *pv) {
     if(pv!=NULL) {
         uprv_free(pv->v);
         uprv_free(pv);
     }
 }

 static uint32_t *
 _findRow(UPropsVectors *pv, UChar32 rangeStart) {
     uint32_t *row;
     int32_t columns, i, start, limit, prevRow;

     columns=pv->columns;
     limit=pv->rows;
     prevRow=pv->prevRow;

     /* check the vicinity of the last-seen row (start searching with an unrolled loop) */
     row=pv->v+prevRow*columns;
     if(rangeStart>=(UChar32)row[0]) {
         if(rangeStart<(UChar32)row[1]) {
             /* same row as last seen */
             return row;
         } else if(rangeStart<(UChar32)(row+=columns)[1]) {
             /* next row after the last one */
             pv->prevRow=prevRow+1;
             return row;
         } else if(rangeStart<(UChar32)(row+=columns)[1]) {
             /* second row after the last one */
             pv->prevRow=prevRow+2;
             return row;
         } else if((rangeStart-(UChar32)row[1])<10) {
             /* we are close, continue looping */
             prevRow+=2;
             do {
                 ++prevRow;
                 row+=columns;
             } while(rangeStart>=(UChar32)row[1]);
             pv->prevRow=prevRow;
             return row;
         }
     } else if(rangeStart<(UChar32)pv->v[1]) {
         /* the very first row */
         pv->prevRow=0;
         return pv->v;
     }

     /* do a binary search for the start of the range */
     start=0;
     while(start<limit-1) {
         i=(start+limit)/2;
         row=pv->v+i*columns;
         if(rangeStart<(UChar32)row[0]) {
             limit=i;
         } else if(rangeStart<(UChar32)row[1]) {
             pv->prevRow=i;
             return row;
         } else {
             start=i;
         }
     }

     /* must be found because all ranges together always cover all of Unicode */
     pv->prevRow=start;
     return pv->v+start*columns;
 }

 U_CAPI void U_EXPORT2
 upvec_setValue(UPropsVectors *pv,
                UChar32 start, UChar32 end,
                int32_t column,
                uint32_t value, uint32_t mask,
                UErrorCode *pErrorCode) {
     uint32_t *firstRow, *lastRow;
     int32_t columns;
     UChar32 limit;
     UBool splitFirstRow, splitLastRow;

     /* argument checking */
     if(U_FAILURE(*pErrorCode)) {
         return;
     }
     if( pv==NULL ||
         start<0 || start>end || end>UPVEC_MAX_CP ||
         column<0 || column>=(pv->columns-2)
     ) {
         *pErrorCode=U_ILLEGAL_ARGUMENT_ERROR;
         return;
     }
     if(pv->isCompacted) {
         *pErrorCode=U_NO_WRITE_PERMISSION;
         return;
     }
     limit=end+1;

     /* initialize */
     columns=pv->columns;
     column+=2; /* skip range start and limit columns */
     value&=mask;

     /* find the rows whose ranges overlap with the input range */

     /* find the first and last rows, always successful */
     firstRow=_findRow(pv, start);
     lastRow=_findRow(pv, end);

     /*
      * Rows need to be split if they partially overlap with the
      * input range (only possible for the first and last rows)
      * and if their value differs from the input value.
      */
     splitFirstRow= (UBool)(start!=(UChar32)firstRow[0] && value!=(firstRow[column]&mask));
     splitLastRow= (UBool)(limit!=(UChar32)lastRow[1] && value!=(lastRow[column]&mask));

     /* split first/last rows if necessary */
     if(splitFirstRow || splitLastRow) {
         int32_t count, rows;

         rows=pv->rows;
         if((rows+splitFirstRow+splitLastRow)>pv->maxRows) {
             uint32_t *newVectors;
             int32_t newMaxRows;

             if(pv->maxRows<UPVEC_MEDIUM_ROWS) {
                 newMaxRows=UPVEC_MEDIUM_ROWS;
             } else if(pv->maxRows<UPVEC_MAX_ROWS) {
                 newMaxRows=UPVEC_MAX_ROWS;
             } else {
                 /* Implementation bug, or UPVEC_MAX_ROWS too low. */
                 *pErrorCode=U_INTERNAL_PROGRAM_ERROR;
                 return;
             }
             newVectors=(uint32_t *)uprv_malloc(newMaxRows*columns*4);
             if(newVectors==NULL) {
                 *pErrorCode=U_MEMORY_ALLOCATION_ERROR;
                 return;
             }
             uprv_memcpy(newVectors, pv->v, rows*columns*4);
             firstRow=newVectors+(firstRow-pv->v);
             lastRow=newVectors+(lastRow-pv->v);
             uprv_free(pv->v);
             pv->v=newVectors;
             pv->maxRows=newMaxRows;
         }

         /* count the number of row cells to move after the last row, and move them */
         count = (int32_t)((pv->v+rows*columns)-(lastRow+columns));
         if(count>0) {
             uprv_memmove(
                 lastRow+(1+splitFirstRow+splitLastRow)*columns,
                 lastRow+columns,
                 count*4);
         }
         pv->rows=rows+splitFirstRow+splitLastRow;

         /* split the first row, and move the firstRow pointer to the second part */
         if(splitFirstRow) {
             /* copy all affected rows up one and move the lastRow pointer */
             count = (int32_t)((lastRow-firstRow)+columns);
             uprv_memmove(firstRow+columns, firstRow, count*4);
             lastRow+=columns;

             /* split the range and move the firstRow pointer */
             firstRow[1]=firstRow[columns]=(uint32_t)start;
             firstRow+=columns;
         }

         /* split the last row */
         if(splitLastRow) {
             /* copy the last row data */
             uprv_memcpy(lastRow+columns, lastRow, columns*4);

             /* split the range and move the firstRow pointer */
             lastRow[1]=lastRow[columns]=(uint32_t)limit;
         }
     }

     /* set the "row last seen" to the last row for the range */
     pv->prevRow=(int32_t)((lastRow-(pv->v))/columns);

     /* set the input value in all remaining rows */
     firstRow+=column;
     lastRow+=column;
     mask=~mask;
     for(;;) {
         *firstRow=(*firstRow&mask)|value;
         if(firstRow==lastRow) {
             break;
         }
         firstRow+=columns;
     }
 }

 U_CAPI uint32_t U_EXPORT2
 upvec_getValue(const UPropsVectors *pv, UChar32 c, int32_t column) {
     uint32_t *row;
     UPropsVectors *ncpv;

     if(pv->isCompacted || c<0 || c>UPVEC_MAX_CP || column<0 || column>=(pv->columns-2)) {
         return 0;
     }
     ncpv=(UPropsVectors *)pv;
     row=_findRow(ncpv, c);
     return row[2+column];
 }

 U_CAPI uint32_t * U_EXPORT2
 upvec_getRow(const UPropsVectors *pv, int32_t rowIndex,
              UChar32 *pRangeStart, UChar32 *pRangeEnd) {
     uint32_t *row;
     int32_t columns;

     if(pv->isCompacted || rowIndex<0 || rowIndex>=pv->rows) {
         return NULL;
     }

     columns=pv->columns;
     row=pv->v+rowIndex*columns;
     if(pRangeStart!=NULL) {
         *pRangeStart=(UChar32)row[0];
     }
     if(pRangeEnd!=NULL) {
         *pRangeEnd=(UChar32)row[1]-1;
     }
     return row+2;
 }

 static int32_t U_CALLCONV
 upvec_compareRows(const void *context, const void *l, const void *r) {
     const uint32_t *left=(const uint32_t *)l, *right=(const uint32_t *)r;
     const UPropsVectors *pv=(const UPropsVectors *)context;
     int32_t i, count, columns;

     count=columns=pv->columns; /* includes start/limit columns */

     /* start comparing after start/limit but wrap around to them */
     i=2;
     do {
         if(left[i]!=right[i]) {
             return left[i]<right[i] ? -1 : 1;
         }
         if(++i==columns) {
             i=0;
         }
     } while(--count>0);

     return 0;
 }

 U_CAPI void U_EXPORT2
 upvec_compact(UPropsVectors *pv, UPVecCompactHandler *handler, void *context, UErrorCode *pErrorCode) {
     uint32_t *row;
     int32_t i, columns, valueColumns, rows, count;
     UChar32 start, limit;

     /* argument checking */
     if(U_FAILURE(*pErrorCode)) {
         return;
     }
     if(handler==NULL) {
         *pErrorCode=U_ILLEGAL_ARGUMENT_ERROR;
         return;
     }
     if(pv->isCompacted) {
         return;
     }

     /* Set the flag now: Sorting and compacting destroys the builder data structure. */
     pv->isCompacted=TRUE;

     rows=pv->rows;
     columns=pv->columns;
     U_ASSERT(columns>=3); /* upvec_open asserts this */
     valueColumns=columns-2; /* not counting start & limit */

     /* sort the properties vectors to find unique vector values */
     uprv_sortArray(pv->v, rows, columns*4,
                    upvec_compareRows, pv, FALSE, pErrorCode);
     if(U_FAILURE(*pErrorCode)) {
         return;
     }

     /*
      * Find and set the special values.
      * This has to do almost the same work as the compaction below,
      * to find the indexes where the special-value rows will move.
      */
     row=pv->v;
     count=-valueColumns;
     for(i=0; i<rows; ++i) {
         start=(UChar32)row[0];

         /* count a new values vector if it is different from the current one */
         if(count<0 || 0!=uprv_memcmp(row+2, row-valueColumns, valueColumns*4)) {
             count+=valueColumns;
         }

         if(start>=UPVEC_FIRST_SPECIAL_CP) {
             handler(context, start, start, count, row+2, valueColumns, pErrorCode);
             if(U_FAILURE(*pErrorCode)) {
                 return;
             }
         }

         row+=columns;
     }

     /* count is at the beginning of the last vector, add valueColumns to include that last vector */
     count+=valueColumns;

     /* Call the handler once more to signal the start of delivering real values. */
     handler(context, UPVEC_START_REAL_VALUES_CP, UPVEC_START_REAL_VALUES_CP,
             count, row-valueColumns, valueColumns, pErrorCode);
     if(U_FAILURE(*pErrorCode)) {
         return;
     }

     /*
      * Move vector contents up to a contiguous array with only unique
      * vector values, and call the handler function for each vector.
      *
      * This destroys the Properties Vector structure and replaces it
      * with an array of just vector values.
      */
     row=pv->v;
     count=-valueColumns;
     for(i=0; i<rows; ++i) {
         /* fetch these first before memmove() may overwrite them */
         start=(UChar32)row[0];
         limit=(UChar32)row[1];

         /* add a new values vector if it is different from the current one */
         if(count<0 || 0!=uprv_memcmp(row+2, pv->v+count, valueColumns*4)) {
             count+=valueColumns;
             uprv_memmove(pv->v+count, row+2, valueColumns*4);
         }

         if(start<UPVEC_FIRST_SPECIAL_CP) {
             handler(context, start, limit-1, count, pv->v+count, valueColumns, pErrorCode);
             if(U_FAILURE(*pErrorCode)) {
                 return;
             }
         }

         row+=columns;
     }

     /* count is at the beginning of the last vector, add one to include that last vector */
     pv->rows=count/valueColumns+1;
 }

 U_CAPI const uint32_t * U_EXPORT2
 upvec_getArray(const UPropsVectors *pv, int32_t *pRows, int32_t *pColumns) {
     if(!pv->isCompacted) {
         return NULL;
     }
     if(pRows!=NULL) {
         *pRows=pv->rows;
     }
     if(pColumns!=NULL) {
         *pColumns=pv->columns-2;
     }
     return pv->v;
 }

 U_CAPI uint32_t * U_EXPORT2
 upvec_cloneArray(const UPropsVectors *pv,
                  int32_t *pRows, int32_t *pColumns, UErrorCode *pErrorCode) {
     uint32_t *clonedArray;
     int32_t byteLength;

     if(U_FAILURE(*pErrorCode)) {
         return NULL;
     }
     if(!pv->isCompacted) {
         *pErrorCode=U_ILLEGAL_ARGUMENT_ERROR;
         return NULL;
     }
     byteLength=pv->rows*(pv->columns-2)*4;
     clonedArray=(uint32_t *)uprv_malloc(byteLength);
     if(clonedArray==NULL) {
         *pErrorCode=U_MEMORY_ALLOCATION_ERROR;
         return NULL;
     }
     uprv_memcpy(clonedArray, pv->v, byteLength);
     if(pRows!=NULL) {
         *pRows=pv->rows;
     }
     if(pColumns!=NULL) {
         *pColumns=pv->columns-2;
     }
     return clonedArray;
 }

 U_CAPI UTrie2 * U_EXPORT2
 upvec_compactToUTrie2WithRowIndexes(UPropsVectors *pv, UErrorCode *pErrorCode) {
     UPVecToUTrie2Context toUTrie2={ NULL };
     upvec_compact(pv, upvec_compactToUTrie2Handler, &toUTrie2, pErrorCode);
     utrie2_freeze(toUTrie2.trie, UTRIE2_16_VALUE_BITS, pErrorCode);
     if(U_FAILURE(*pErrorCode)) {
         utrie2_close(toUTrie2.trie);
         toUTrie2.trie=NULL;
     }
     return toUTrie2.trie;
 }

 /*
  * TODO(markus): Add upvec_16BitsToUTrie2() function that enumerates all rows, extracts
  * some 16-bit field and builds and returns a UTrie2.
  */

 U_CAPI void U_CALLCONV
 upvec_compactToUTrie2Handler(void *context,
                              UChar32 start, UChar32 end,
                              int32_t rowIndex, uint32_t *row, int32_t columns,
                              UErrorCode *pErrorCode) {
     UPVecToUTrie2Context *toUTrie2=(UPVecToUTrie2Context *)context;
     if(start<UPVEC_FIRST_SPECIAL_CP) {
         utrie2_setRange32(toUTrie2->trie, start, end, (uint32_t)rowIndex, TRUE, pErrorCode);
     } else {
         switch(start) {
         case UPVEC_INITIAL_VALUE_CP:
             toUTrie2->initialValue=rowIndex;
             break;
         case UPVEC_ERROR_VALUE_CP:
             toUTrie2->errorValue=rowIndex;
             break;
         case UPVEC_START_REAL_VALUES_CP:
             toUTrie2->maxValue=rowIndex;
             if(rowIndex>0xffff) {
                 /* too many rows for a 16-bit trie */
                 *pErrorCode=U_INDEX_OUTOFBOUNDS_ERROR;
             } else {
                 toUTrie2->trie=utrie2_open(toUTrie2->initialValue,
                                            toUTrie2->errorValue, pErrorCode);
             }
             break;
         default:
             break;
         }
     }
 }
	/*
	*******************************************************************************
	*
	* Copyright (C) 2002-2011, International Business Machines
	* Corporation and others. All Rights Reserved.
	*
	*******************************************************************************
	* file name: propsvec.c
	* encoding: US-ASCII
	* tab size: 8 (not used)
	* indentation:4
	*
	* created on: 2002feb22
	* created by: Markus W. Scherer
	*
	* Store bits (Unicode character properties) in bit set vectors.
	*/

	#include "starboard/client_porting/poem/assert_poem.h"
	#include "starboard/client_porting/poem/string_poem.h"
	#if !defined(STARBOARD)
	#include <stdlib.h>
	#endif
	#include "unicode/utypes.h"
	#include "cmemory.h"
	#include "utrie.h"
	#include "utrie2.h"
	#include "uarrsort.h"
	#include "propsvec.h"
	#include "uassert.h"

	struct UPropsVectors {
	uint32_t *v;
	int32_t columns; /* number of columns, plus two for start & limit values */
	int32_t maxRows;
	int32_t rows;
	int32_t prevRow; /* search optimization: remember last row seen */
	UBool isCompacted;
	};

	#define UPVEC_INITIAL_ROWS (1<<12)
	#define UPVEC_MEDIUM_ROWS ((int32_t)1<<16)
	#define UPVEC_MAX_ROWS (UPVEC_MAX_CP+1)

	U_CAPI UPropsVectors * U_EXPORT2
	upvec_open(int32_t columns, UErrorCode *pErrorCode) {
	UPropsVectors *pv;
	uint32_t v, row;
	uint32_t cp;

	if(U_FAILURE(*pErrorCode)) {
	return NULL;
	}
	if(columns<1) {
	*pErrorCode=U_ILLEGAL_ARGUMENT_ERROR;
	return NULL;
	}
	columns+=2; /* count range start and limit columns */

	pv=(UPropsVectors *)uprv_malloc(sizeof(UPropsVectors));
	v=(uint32_t )uprv_malloc(UPVEC_INITIAL_ROWScolumns*4);
	if(pv==NULL \|\| v==NULL) {
	uprv_free(pv);
	uprv_free(v);
	*pErrorCode=U_MEMORY_ALLOCATION_ERROR;
	return NULL;
	}
	uprv_memset(pv, 0, sizeof(UPropsVectors));
	pv->v=v;
	pv->columns=columns;
	pv->maxRows=UPVEC_INITIAL_ROWS;
	pv->rows=2+(UPVEC_MAX_CP-UPVEC_FIRST_SPECIAL_CP);

	/* set the all-Unicode row and the special-value rows */
	row=pv->v;
	uprv_memset(row, 0, pv->rowscolumns4);
	row[0]=0;
	row[1]=0x110000;
	row+=columns;
	for(cp=UPVEC_FIRST_SPECIAL_CP; cp<=UPVEC_MAX_CP; ++cp) {
	row[0]=cp;
	row[1]=cp+1;
	row+=columns;
	}
	return pv;
	}

	U_CAPI void U_EXPORT2
	upvec_close(UPropsVectors *pv) {
	if(pv!=NULL) {
	uprv_free(pv->v);
	uprv_free(pv);
	}
	}

	static uint32_t *
	_findRow(UPropsVectors *pv, UChar32 rangeStart) {
	uint32_t *row;
	int32_t columns, i, start, limit, prevRow;

	columns=pv->columns;
	limit=pv->rows;
	prevRow=pv->prevRow;

	/* check the vicinity of the last-seen row (start searching with an unrolled loop) */
	row=pv->v+prevRow*columns;
	if(rangeStart>=(UChar32)row[0]) {
	if(rangeStart<(UChar32)row[1]) {
	/* same row as last seen */
	return row;
	} else if(rangeStart<(UChar32)(row+=columns)[1]) {
	/* next row after the last one */
	pv->prevRow=prevRow+1;
	return row;
	} else if(rangeStart<(UChar32)(row+=columns)[1]) {
	/* second row after the last one */
	pv->prevRow=prevRow+2;
	return row;
	} else if((rangeStart-(UChar32)row[1])<10) {
	/* we are close, continue looping */
	prevRow+=2;
	do {
	++prevRow;
	row+=columns;
	} while(rangeStart>=(UChar32)row[1]);
	pv->prevRow=prevRow;
	return row;
	}
	} else if(rangeStart<(UChar32)pv->v[1]) {
	/* the very first row */
	pv->prevRow=0;
	return pv->v;
	}

	/* do a binary search for the start of the range */
	start=0;
	while(start<limit-1) {
	i=(start+limit)/2;
	row=pv->v+i*columns;
	if(rangeStart<(UChar32)row[0]) {
	limit=i;
	} else if(rangeStart<(UChar32)row[1]) {
	pv->prevRow=i;
	return row;
	} else {
	start=i;
	}
	}

	/* must be found because all ranges together always cover all of Unicode */
	pv->prevRow=start;
	return pv->v+start*columns;
	}

	U_CAPI void U_EXPORT2
	upvec_setValue(UPropsVectors *pv,
	UChar32 start, UChar32 end,
	int32_t column,
	uint32_t value, uint32_t mask,
	UErrorCode *pErrorCode) {
	uint32_t firstRow, lastRow;
	int32_t columns;
	UChar32 limit;
	UBool splitFirstRow, splitLastRow;

	/* argument checking */
	if(U_FAILURE(*pErrorCode)) {
	return;
	}
	if( pv==NULL \|\|
	start<0 \|\| start>end \|\| end>UPVEC_MAX_CP \|\|
	column<0 \|\| column>=(pv->columns-2)
	) {
	*pErrorCode=U_ILLEGAL_ARGUMENT_ERROR;
	return;
	}
	if(pv->isCompacted) {
	*pErrorCode=U_NO_WRITE_PERMISSION;
	return;
	}
	limit=end+1;

	/* initialize */
	columns=pv->columns;
	column+=2; /* skip range start and limit columns */
	value&=mask;

	/* find the rows whose ranges overlap with the input range */

	/* find the first and last rows, always successful */
	firstRow=_findRow(pv, start);
	lastRow=_findRow(pv, end);

	/*
	* Rows need to be split if they partially overlap with the
	* input range (only possible for the first and last rows)
	* and if their value differs from the input value.
	*/
	splitFirstRow= (UBool)(start!=(UChar32)firstRow[0] && value!=(firstRow[column]&mask));
	splitLastRow= (UBool)(limit!=(UChar32)lastRow[1] && value!=(lastRow[column]&mask));

	/* split first/last rows if necessary */
	if(splitFirstRow \|\| splitLastRow) {
	int32_t count, rows;

	rows=pv->rows;
	if((rows+splitFirstRow+splitLastRow)>pv->maxRows) {
	uint32_t *newVectors;
	int32_t newMaxRows;

	if(pv->maxRows<UPVEC_MEDIUM_ROWS) {
	newMaxRows=UPVEC_MEDIUM_ROWS;
	} else if(pv->maxRows<UPVEC_MAX_ROWS) {
	newMaxRows=UPVEC_MAX_ROWS;
	} else {
	/* Implementation bug, or UPVEC_MAX_ROWS too low. */
	*pErrorCode=U_INTERNAL_PROGRAM_ERROR;
	return;
	}
	newVectors=(uint32_t )uprv_malloc(newMaxRowscolumns*4);
	if(newVectors==NULL) {
	*pErrorCode=U_MEMORY_ALLOCATION_ERROR;
	return;
	}
	uprv_memcpy(newVectors, pv->v, rowscolumns4);
	firstRow=newVectors+(firstRow-pv->v);
	lastRow=newVectors+(lastRow-pv->v);
	uprv_free(pv->v);
	pv->v=newVectors;
	pv->maxRows=newMaxRows;
	}

	/* count the number of row cells to move after the last row, and move them */
	count = (int32_t)((pv->v+rows*columns)-(lastRow+columns));
	if(count>0) {
	uprv_memmove(
	lastRow+(1+splitFirstRow+splitLastRow)*columns,
	lastRow+columns,
	count*4);
	}
	pv->rows=rows+splitFirstRow+splitLastRow;

	/* split the first row, and move the firstRow pointer to the second part */
	if(splitFirstRow) {
	/* copy all affected rows up one and move the lastRow pointer */
	count = (int32_t)((lastRow-firstRow)+columns);
	uprv_memmove(firstRow+columns, firstRow, count*4);
	lastRow+=columns;

	/* split the range and move the firstRow pointer */
	firstRow[1]=firstRow[columns]=(uint32_t)start;
	firstRow+=columns;
	}

	/* split the last row */
	if(splitLastRow) {
	/* copy the last row data */
	uprv_memcpy(lastRow+columns, lastRow, columns*4);

	/* split the range and move the firstRow pointer */
	lastRow[1]=lastRow[columns]=(uint32_t)limit;
	}
	}

	/* set the "row last seen" to the last row for the range */
	pv->prevRow=(int32_t)((lastRow-(pv->v))/columns);

	/* set the input value in all remaining rows */
	firstRow+=column;
	lastRow+=column;
	mask=~mask;
	for(;;) {
	firstRow=(firstRow&mask)\|value;
	if(firstRow==lastRow) {
	break;
	}
	firstRow+=columns;
	}
	}

	U_CAPI uint32_t U_EXPORT2
	upvec_getValue(const UPropsVectors *pv, UChar32 c, int32_t column) {
	uint32_t *row;
	UPropsVectors *ncpv;

	if(pv->isCompacted \|\| c<0 \|\| c>UPVEC_MAX_CP \|\| column<0 \|\| column>=(pv->columns-2)) {
	return 0;
	}
	ncpv=(UPropsVectors *)pv;
	row=_findRow(ncpv, c);
	return row[2+column];
	}

	U_CAPI uint32_t * U_EXPORT2
	upvec_getRow(const UPropsVectors *pv, int32_t rowIndex,
	UChar32 pRangeStart, UChar32 pRangeEnd) {
	uint32_t *row;
	int32_t columns;

	if(pv->isCompacted \|\| rowIndex<0 \|\| rowIndex>=pv->rows) {
	return NULL;
	}

	columns=pv->columns;
	row=pv->v+rowIndex*columns;
	if(pRangeStart!=NULL) {
	*pRangeStart=(UChar32)row[0];
	}
	if(pRangeEnd!=NULL) {
	*pRangeEnd=(UChar32)row[1]-1;
	}
	return row+2;
	}

	static int32_t U_CALLCONV
	upvec_compareRows(const void context, const void l, const void *r) {
	const uint32_t left=(const uint32_t )l, right=(const uint32_t )r;
	const UPropsVectors pv=(const UPropsVectors )context;
	int32_t i, count, columns;

	count=columns=pv->columns; /* includes start/limit columns */

	/* start comparing after start/limit but wrap around to them */
	i=2;
	do {
	if(left[i]!=right[i]) {
	return left[i]<right[i] ? -1 : 1;
	}
	if(++i==columns) {
	i=0;
	}
	} while(--count>0);

	return 0;
	}

	U_CAPI void U_EXPORT2
	upvec_compact(UPropsVectors pv, UPVecCompactHandler handler, void context, UErrorCode pErrorCode) {
	uint32_t *row;
	int32_t i, columns, valueColumns, rows, count;
	UChar32 start, limit;

	/* argument checking */
	if(U_FAILURE(*pErrorCode)) {
	return;
	}
	if(handler==NULL) {
	*pErrorCode=U_ILLEGAL_ARGUMENT_ERROR;
	return;
	}
	if(pv->isCompacted) {
	return;
	}

	/* Set the flag now: Sorting and compacting destroys the builder data structure. */
	pv->isCompacted=TRUE;

	rows=pv->rows;
	columns=pv->columns;
	U_ASSERT(columns>=3); /* upvec_open asserts this */
	valueColumns=columns-2; /* not counting start & limit */

	/* sort the properties vectors to find unique vector values */
	uprv_sortArray(pv->v, rows, columns*4,
	upvec_compareRows, pv, FALSE, pErrorCode);
	if(U_FAILURE(*pErrorCode)) {
	return;
	}

	/*
	* Find and set the special values.
	* This has to do almost the same work as the compaction below,
	* to find the indexes where the special-value rows will move.
	*/
	row=pv->v;
	count=-valueColumns;
	for(i=0; i<rows; ++i) {
	start=(UChar32)row[0];

	/* count a new values vector if it is different from the current one */
	if(count<0 \|\| 0!=uprv_memcmp(row+2, row-valueColumns, valueColumns*4)) {
	count+=valueColumns;
	}

	if(start>=UPVEC_FIRST_SPECIAL_CP) {
	handler(context, start, start, count, row+2, valueColumns, pErrorCode);
	if(U_FAILURE(*pErrorCode)) {
	return;
	}
	}

	row+=columns;
	}

	/* count is at the beginning of the last vector, add valueColumns to include that last vector */
	count+=valueColumns;

	/* Call the handler once more to signal the start of delivering real values. */
	handler(context, UPVEC_START_REAL_VALUES_CP, UPVEC_START_REAL_VALUES_CP,
	count, row-valueColumns, valueColumns, pErrorCode);
	if(U_FAILURE(*pErrorCode)) {
	return;
	}

	/*
	* Move vector contents up to a contiguous array with only unique
	* vector values, and call the handler function for each vector.
	*
	* This destroys the Properties Vector structure and replaces it
	* with an array of just vector values.
	*/
	row=pv->v;
	count=-valueColumns;
	for(i=0; i<rows; ++i) {
	/* fetch these first before memmove() may overwrite them */
	start=(UChar32)row[0];
	limit=(UChar32)row[1];

	/* add a new values vector if it is different from the current one */
	if(count<0 \|\| 0!=uprv_memcmp(row+2, pv->v+count, valueColumns*4)) {
	count+=valueColumns;
	uprv_memmove(pv->v+count, row+2, valueColumns*4);
	}

	if(start<UPVEC_FIRST_SPECIAL_CP) {
	handler(context, start, limit-1, count, pv->v+count, valueColumns, pErrorCode);
	if(U_FAILURE(*pErrorCode)) {
	return;
	}
	}

	row+=columns;
	}

	/* count is at the beginning of the last vector, add one to include that last vector */
	pv->rows=count/valueColumns+1;
	}

	U_CAPI const uint32_t * U_EXPORT2
	upvec_getArray(const UPropsVectors pv, int32_t pRows, int32_t *pColumns) {
	if(!pv->isCompacted) {
	return NULL;
	}
	if(pRows!=NULL) {
	*pRows=pv->rows;
	}
	if(pColumns!=NULL) {
	*pColumns=pv->columns-2;
	}
	return pv->v;
	}

	U_CAPI uint32_t * U_EXPORT2
	upvec_cloneArray(const UPropsVectors *pv,
	int32_t pRows, int32_t pColumns, UErrorCode *pErrorCode) {
	uint32_t *clonedArray;
	int32_t byteLength;

	if(U_FAILURE(*pErrorCode)) {
	return NULL;
	}
	if(!pv->isCompacted) {
	*pErrorCode=U_ILLEGAL_ARGUMENT_ERROR;
	return NULL;
	}
	byteLength=pv->rows(pv->columns-2)4;
	clonedArray=(uint32_t *)uprv_malloc(byteLength);
	if(clonedArray==NULL) {
	*pErrorCode=U_MEMORY_ALLOCATION_ERROR;
	return NULL;
	}
	uprv_memcpy(clonedArray, pv->v, byteLength);
	if(pRows!=NULL) {
	*pRows=pv->rows;
	}
	if(pColumns!=NULL) {
	*pColumns=pv->columns-2;
	}
	return clonedArray;
	}

	U_CAPI UTrie2 * U_EXPORT2
	upvec_compactToUTrie2WithRowIndexes(UPropsVectors pv, UErrorCode pErrorCode) {
	UPVecToUTrie2Context toUTrie2={ NULL };
	upvec_compact(pv, upvec_compactToUTrie2Handler, &toUTrie2, pErrorCode);
	utrie2_freeze(toUTrie2.trie, UTRIE2_16_VALUE_BITS, pErrorCode);
	if(U_FAILURE(*pErrorCode)) {
	utrie2_close(toUTrie2.trie);
	toUTrie2.trie=NULL;
	}
	return toUTrie2.trie;
	}

	/*
	* TODO(markus): Add upvec_16BitsToUTrie2() function that enumerates all rows, extracts
	* some 16-bit field and builds and returns a UTrie2.
	*/

	U_CAPI void U_CALLCONV
	upvec_compactToUTrie2Handler(void *context,
	UChar32 start, UChar32 end,
	int32_t rowIndex, uint32_t *row, int32_t columns,
	UErrorCode *pErrorCode) {
	UPVecToUTrie2Context toUTrie2=(UPVecToUTrie2Context )context;
	if(start<UPVEC_FIRST_SPECIAL_CP) {
	utrie2_setRange32(toUTrie2->trie, start, end, (uint32_t)rowIndex, TRUE, pErrorCode);
	} else {
	switch(start) {
	case UPVEC_INITIAL_VALUE_CP:
	toUTrie2->initialValue=rowIndex;
	break;
	case UPVEC_ERROR_VALUE_CP:
	toUTrie2->errorValue=rowIndex;
	break;
	case UPVEC_START_REAL_VALUES_CP:
	toUTrie2->maxValue=rowIndex;
	if(rowIndex>0xffff) {
	/* too many rows for a 16-bit trie */
	*pErrorCode=U_INDEX_OUTOFBOUNDS_ERROR;
	} else {
	toUTrie2->trie=utrie2_open(toUTrie2->initialValue,
	toUTrie2->errorValue, pErrorCode);
	}
	break;
	default:
	break;
	}
	}
	}