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International Component for Unicode for Java (ICU4J) is a mature, widely used Java library
providing Unicode and Globalization support
/*
******************************************************************************
* Copyright (C) 1996-2011, International Business Machines Corporation and *
* others. All Rights Reserved. *
******************************************************************************
*/
/**
* Store bits (Unicode character properties) in bit set vectors.
*
* This is a port of the C++ class UPropsVectors from ICU4C
*
* @author Shaopeng Jia
* @internal
*/
package com.ibm.icu.impl;
import java.util.Arrays;
import java.util.Comparator;
/**
* Unicode Properties Vectors associated with code point ranges.
*
* Rows of primitive integers in a contiguous array store the range limits and
* the properties vectors.
*
* In each row, row[0] contains the start code point and row[1] contains the
* limit code point, which is the start of the next range.
*
* Initially, there is only one range [0..0x110000] with values 0.
*
* It would be possible to store only one range boundary per row, but
* self-contained rows allow to later sort them by contents.
*/
public class PropsVectors {
private int v[];
private int columns; // number of columns, plus two for start
// and limit values
private int maxRows;
private int rows;
private int prevRow; // search optimization: remember last row seen
private boolean isCompacted;
// internal function to compare elements in v and target. Return true iff
// elements in v starting from index1 to index1 + length - 1
// are exactly the same as elements in target
// starting from index2 to index2 + length - 1
private boolean areElementsSame(int index1, int[] target, int index2,
int length) {
for (int i = 0; i < length; ++i) {
if (v[index1 + i] != target[index2 + i]) {
return false;
}
}
return true;
}
// internal function which given rangeStart, returns
// index where v[index]<=rangeStart= v[index]) {
if (rangeStart < v[index + 1]) {
// same row as last seen
return index;
} else {
index += columns;
if (rangeStart < v[index + 1]) {
++prevRow;
return index;
} else {
index += columns;
if (rangeStart < v[index + 1]) {
prevRow += 2;
return index;
} else if ((rangeStart - v[index + 1]) < 10) {
// we are close, continue looping
prevRow += 2;
do {
++prevRow;
index += columns;
} while (rangeStart >= v[index + 1]);
return index;
}
}
}
} else if (rangeStart < v[1]) {
// the very first row
prevRow = 0;
return 0;
}
// do a binary search for the start of the range
int start = 0;
int mid = 0;
int limit = rows;
while (start < limit - 1) {
mid = (start + limit) / 2;
index = columns * mid;
if (rangeStart < v[index]) {
limit = mid;
} else if (rangeStart < v[index + 1]) {
prevRow = mid;
return index;
} else {
start = mid;
}
}
// must be found because all ranges together always cover
// all of Unicode
prevRow = start;
index = start * columns;
return index;
}
/*
* Special pseudo code points for storing the initialValue and the
* errorValue which are used to initialize a Trie or similar.
*/
public final static int FIRST_SPECIAL_CP = 0x110000;
public final static int INITIAL_VALUE_CP = 0x110000;
public final static int ERROR_VALUE_CP = 0x110001;
public final static int MAX_CP = 0x110001;
public final static int INITIAL_ROWS = 1 << 12;
public final static int MEDIUM_ROWS = 1 << 16;
public final static int MAX_ROWS = MAX_CP + 1;
/*
* Constructor.
* @param numOfColumns Number of value integers (32-bit int) per row.
*/
public PropsVectors(int numOfColumns) {
if (numOfColumns < 1) {
throw new IllegalArgumentException("numOfColumns need to be no "
+ "less than 1; but it is " + numOfColumns);
}
columns = numOfColumns + 2; // count range start and limit columns
v = new int[INITIAL_ROWS * columns];
maxRows = INITIAL_ROWS;
rows = 2 + (MAX_CP - FIRST_SPECIAL_CP);
prevRow = 0;
isCompacted = false;
v[0] = 0;
v[1] = 0x110000;
int index = columns;
for (int cp = FIRST_SPECIAL_CP; cp <= MAX_CP; ++cp) {
v[index] = cp;
v[index + 1] = cp + 1;
index += columns;
}
}
/*
* In rows for code points [start..end], select the column, reset the mask
* bits and set the value bits (ANDed with the mask).
*
* @throws IllegalArgumentException
*
* @throws IllegalStateException
*
* @throws IndexOutOfBoundsException
*/
public void setValue(int start, int end, int column, int value, int mask) {
if (start < 0 || start > end || end > MAX_CP || column < 0
|| column >= (columns - 2)) {
throw new IllegalArgumentException();
}
if (isCompacted) {
throw new IllegalStateException("Shouldn't be called after"
+ "compact()!");
}
int firstRow, lastRow;
int limit = end + 1;
boolean splitFirstRow, splitLastRow;
// skip range start and limit columns
column += 2;
value &= mask;
// find the rows whose ranges overlap with the input range
// find the first and last row, always successful
firstRow = findRow(start);
lastRow = findRow(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 = (start != v[firstRow] && value != (v[firstRow + column] & mask));
splitLastRow = (limit != v[lastRow + 1] && value != (v[lastRow + column] & mask));
// split first/last rows if necessary
if (splitFirstRow || splitLastRow) {
int rowsToExpand = 0;
if (splitFirstRow) {
++rowsToExpand;
}
if (splitLastRow) {
++rowsToExpand;
}
int newMaxRows = 0;
if ((rows + rowsToExpand) > maxRows) {
if (maxRows < MEDIUM_ROWS) {
newMaxRows = MEDIUM_ROWS;
} else if (maxRows < MAX_ROWS) {
newMaxRows = MAX_ROWS;
} else {
throw new IndexOutOfBoundsException(
"MAX_ROWS exceeded! Increase it to a higher value" +
"in the implementation");
}
int[] temp = new int[newMaxRows * columns];
System.arraycopy(v, 0, temp, 0, rows * columns);
v = temp;
maxRows = newMaxRows;
}
// count the number of row cells to move after the last row,
// and move them
int count = (rows * columns) - (lastRow + columns);
if (count > 0) {
System.arraycopy(v, lastRow + columns, v, lastRow
+ (1 + rowsToExpand) * columns, count);
}
rows += rowsToExpand;
// 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 = lastRow - firstRow + columns;
System.arraycopy(v, firstRow, v, firstRow + columns, count);
lastRow += columns;
// split the range and move the firstRow pointer
v[firstRow + 1] = v[firstRow + columns] = start;
firstRow += columns;
}
// split the last row
if (splitLastRow) {
// copy the last row data
System.arraycopy(v, lastRow, v, lastRow + columns, columns);
// split the range and move the firstRow pointer
v[lastRow + 1] = v[lastRow + columns] = limit;
}
}
// set the "row last seen" to the last row for the range
prevRow = lastRow / columns;
// set the input value in all remaining rows
firstRow += column;
lastRow += column;
mask = ~mask;
for (;;) {
v[firstRow] = (v[firstRow] & mask) | value;
if (firstRow == lastRow) {
break;
}
firstRow += columns;
}
}
/*
* Always returns 0 if called after compact().
*/
public int getValue(int c, int column) {
if (isCompacted || c < 0 || c > MAX_CP || column < 0
|| column >= (columns - 2)) {
return 0;
}
int index = findRow(c);
return v[index + 2 + column];
}
/*
* Returns an array which contains value elements
* in row rowIndex.
*
* @throws IllegalStateException
* @throws IllegalArgumentException
*/
public int[] getRow(int rowIndex) {
if (isCompacted) {
throw new IllegalStateException(
"Illegal Invocation of the method after compact()");
}
if (rowIndex < 0 || rowIndex > rows) {
throw new IllegalArgumentException("rowIndex out of bound!");
}
int[] rowToReturn = new int[columns - 2];
System.arraycopy(v, rowIndex * columns + 2, rowToReturn, 0,
columns - 2);
return rowToReturn;
}
/*
* Returns an int which is the start codepoint
* in row rowIndex.
*
* @throws IllegalStateException
*
* @throws IllegalArgumentException
*/
public int getRowStart(int rowIndex) {
if (isCompacted) {
throw new IllegalStateException(
"Illegal Invocation of the method after compact()");
}
if (rowIndex < 0 || rowIndex > rows) {
throw new IllegalArgumentException("rowIndex out of bound!");
}
return v[rowIndex * columns];
}
/*
* Returns an int which is the limit codepoint
* minus 1 in row rowIndex.
*
* @throws IllegalStateException
*
* @throws IllegalArgumentException
*/
public int getRowEnd(int rowIndex) {
if (isCompacted) {
throw new IllegalStateException(
"Illegal Invocation of the method after compact()");
}
if (rowIndex < 0 || rowIndex > rows) {
throw new IllegalArgumentException("rowIndex out of bound!");
}
return v[rowIndex * columns + 1] - 1;
}
/*
* Compact the vectors:
* - modify the memory
* - keep only unique vectors
* - store them contiguously from the beginning of the memory
* - for each (non-unique) row, call the respective function in
* CompactHandler
*
* The handler's rowIndex is the index of the row in the compacted
* memory block. Therefore, it starts at 0 increases in increments of the
* columns value.
*
* In a first phase, only special values are delivered (each exactly once).
* Then CompactHandler::startRealValues() is called
* where rowIndex is the length of the compacted array.
* Then, in the second phase, the CompactHandler::setRowIndexForRange() is
* called for each row of real values.
*/
public void compact(CompactHandler compactor) {
if (isCompacted) {
return;
}
// Set the flag now: Sorting and compacting destroys the builder
// data structure.
isCompacted = true;
int valueColumns = columns - 2; // not counting start & limit
// sort the properties vectors to find unique vector values
Integer[] indexArray = new Integer[rows];
for (int i = 0; i < rows; ++i) {
indexArray[i] = Integer.valueOf(columns * i);
}
Arrays.sort(indexArray, new Comparator() {
public int compare(Integer o1, Integer o2) {
int indexOfRow1 = o1.intValue();
int indexOfRow2 = o2.intValue();
int count = columns; // includes start/limit columns
// start comparing after start/limit
// but wrap around to them
int index = 2;
do {
if (v[indexOfRow1 + index] != v[indexOfRow2 + index]) {
return v[indexOfRow1 + index] < v[indexOfRow2 + index] ? -1
: 1;
}
if (++index == columns) {
index = 0;
}
} while (--count > 0);
return 0;
}
});
/*
* 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.
*/
int count = -valueColumns;
for (int i = 0; i < rows; ++i) {
int start = v[indexArray[i].intValue()];
// count a new values vector if it is different
// from the current one
if (count < 0 || !areElementsSame(indexArray[i].intValue() + 2, v,
indexArray[i-1].intValue() + 2, valueColumns)) {
count += valueColumns;
}
if (start == INITIAL_VALUE_CP) {
compactor.setRowIndexForInitialValue(count);
} else if (start == ERROR_VALUE_CP) {
compactor.setRowIndexForErrorValue(count);
}
}
// 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.
compactor.startRealValues(count);
/*
* 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.
*/
int[] temp = new int[count];
count = -valueColumns;
for (int i = 0; i < rows; ++i) {
int start = v[indexArray[i].intValue()];
int limit = v[indexArray[i].intValue() + 1];
// count a new values vector if it is different
// from the current one
if (count < 0 || !areElementsSame(indexArray[i].intValue() + 2,
temp, count, valueColumns)) {
count += valueColumns;
System.arraycopy(v, indexArray[i].intValue() + 2, temp, count,
valueColumns);
}
if (start < FIRST_SPECIAL_CP) {
compactor.setRowIndexForRange(start, limit - 1, count);
}
}
v = temp;
// count is at the beginning of the last vector,
// add one to include that last vector
rows = count / valueColumns + 1;
}
/*
* Get the vectors array after calling compact().
*
* @throws IllegalStateException
*/
public int[] getCompactedArray() {
if (!isCompacted) {
throw new IllegalStateException(
"Illegal Invocation of the method before compact()");
}
return v;
}
/*
* Get the number of rows for the compacted array.
*
* @throws IllegalStateException
*/
public int getCompactedRows() {
if (!isCompacted) {
throw new IllegalStateException(
"Illegal Invocation of the method before compact()");
}
return rows;
}
/*
* Get the number of columns for the compacted array.
*
* @throws IllegalStateException
*/
public int getCompactedColumns() {
if (!isCompacted) {
throw new IllegalStateException(
"Illegal Invocation of the method before compact()");
}
return columns - 2;
}
/*
* Call compact(), create a IntTrie with indexes into the compacted
* vectors array.
*/
public IntTrie compactToTrieWithRowIndexes() {
PVecToTrieCompactHandler compactor = new PVecToTrieCompactHandler();
compact(compactor);
return compactor.builder.serialize(new DefaultGetFoldedValue(
compactor.builder), new DefaultGetFoldingOffset());
}
// inner class implementation of Trie.DataManipulate
private static class DefaultGetFoldingOffset implements Trie.DataManipulate {
public int getFoldingOffset(int value) {
return value;
}
}
// inner class implementation of TrieBuilder.DataManipulate
private static class DefaultGetFoldedValue implements
TrieBuilder.DataManipulate {
private IntTrieBuilder builder;
public DefaultGetFoldedValue(IntTrieBuilder inBuilder) {
builder = inBuilder;
}
public int getFoldedValue(int start, int offset) {
int initialValue = builder.m_initialValue_;
int limit = start + 0x400;
while (start < limit) {
boolean[] inBlockZero = new boolean[1];
int value = builder.getValue(start, inBlockZero);
if (inBlockZero[0]) {
start += TrieBuilder.DATA_BLOCK_LENGTH;
} else if (value != initialValue) {
return offset;
} else {
++start;
}
}
return 0;
}
}
public static interface CompactHandler {
public void setRowIndexForRange(int start, int end, int rowIndex);
public void setRowIndexForInitialValue(int rowIndex);
public void setRowIndexForErrorValue(int rowIndex);
public void startRealValues(int rowIndex);
}
}