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//
// ========================================================================
// Copyright (c) 1995 Mort Bay Consulting Pty Ltd and others.
//
// This program and the accompanying materials are made available under the
// terms of the Eclipse Public License v. 2.0 which is available at
// https://www.eclipse.org/legal/epl-2.0, or the Apache License, Version 2.0
// which is available at https://www.apache.org/licenses/LICENSE-2.0.
//
// SPDX-License-Identifier: EPL-2.0 OR Apache-2.0
// ========================================================================
//

package org.eclipse.jetty.util;

import java.nio.ByteBuffer;
import java.util.AbstractMap;
import java.util.Arrays;
import java.util.HashSet;
import java.util.Map;
import java.util.Objects;
import java.util.Set;

/**
 * 

A Ternary Trie String lookup data structure.

*

* This Trie is of a fixed size and cannot grow (which can be a good thing with regards to DOS when used as a cache). *

*

* The Trie is stored in 3 arrays: *

*
*
char[] _tree
This is semantically 2 dimensional array flattened into a 1 dimensional char array. The second dimension * is that every 4 sequential elements represents a row of: character; hi index; eq index; low index, used to build a * ternary trie of key strings.
*
String[] _key
An array of key values where each element matches a row in the _tree array. A non zero key element * indicates that the _tree row is a complete key rather than an intermediate character of a longer key.
*
V[] _value
An array of values corresponding to the _key array
*
*

The lookup of a value will iterate through the _tree array matching characters. If the equal tree branch is followed, * then the _key array is looked up to see if this is a complete match. If a match is found then the _value array is looked up * to return the matching value. *

*

* This Trie may be instantiated either as case sensitive or insensitive. *

*

This Trie is not Threadsafe and contains no mutual exclusion * or deliberate memory barriers. It is intended for an ArrayTrie to be * built by a single thread and then used concurrently by multiple threads * and not mutated during that access. If concurrent mutations of the * Trie is required external locks need to be applied. *

* * @param the Entry type */ @Deprecated class ArrayTernaryTrie extends AbstractTrie { private static final int LO = 1; private static final int EQ = 2; private static final int HI = 3; /** * The Size of a Trie row is the char, and the low, equal and high * child pointers */ private static final int ROW_SIZE = 4; /** * The maximum capacity of the implementation. Over that, * the 16 bit indexes can overflow and the trie * cannot find existing entries anymore. */ private static final int MAX_CAPACITY = Character.MAX_VALUE - 1; /** * The Trie rows in a single array which allows a lookup of row,character * to the next row in the Trie. This is actually a 2 dimensional * array that has been flattened to achieve locality of reference. */ private final char[] _tree; /** * The key (if any) for a Trie row. * A row may be a leaf, a node or both in the Trie tree. */ private final String[] _key; /** * The value (if any) for a Trie row. * A row may be a leaf, a node or both in the Trie tree. */ private final V[] _value; /** * The number of rows allocated */ private char _rows; /** * Create a Trie * * @param caseSensitive true if the Trie is insensitive to the case of the key. * @param capacity The capacity of the Trie, which is in the worst case * is the total number of characters of all keys stored in the Trie. * @see AbstractTrie#requiredCapacity(Set, boolean) */ @SuppressWarnings("unchecked") ArrayTernaryTrie(boolean caseSensitive, int capacity) { super(caseSensitive); if (capacity > MAX_CAPACITY) throw new IllegalArgumentException("ArrayTernaryTrie maximum capacity overflow (" + capacity + " > " + MAX_CAPACITY + ")"); _value = (V[])new Object[capacity + 1]; _tree = new char[(capacity + 1) * ROW_SIZE]; _key = new String[capacity + 1]; } @Override public void clear() { _rows = 0; Arrays.fill(_value, null); Arrays.fill(_tree, (char)0); Arrays.fill(_key, null); } @Override public boolean put(String s, V v) { int t = 0; int limit = s.length(); if (limit > MAX_CAPACITY) return false; int last = 0; for (int k = 0; k < limit; k++) { char c = s.charAt(k); if (isCaseInsensitive() && c < 128) c = StringUtil.asciiToLowerCase(c); while (true) { if (_rows == MAX_CAPACITY) return false; int row = ROW_SIZE * t; // Do we need to create the new row? if (t == _rows) { _rows = (char)MathUtils.cappedAdd(_rows, 1, _key.length); if (_rows == _key.length) return false; _tree[row] = c; } char n = _tree[row]; int diff = n - c; if (diff == 0) t = _tree[last = (row + EQ)]; else if (diff < 0) t = _tree[last = (row + LO)]; else t = _tree[last = (row + HI)]; // do we need a new row? if (t == 0) { t = _rows; _tree[last] = (char)t; } if (diff == 0) break; } } // Do we need to create the new row? if (t == _rows) { if (_rows == _key.length) return false; _rows++; } // Put the key and value _key[t] = v == null ? null : s; _value[t] = v; return true; } @Override public V get(String s, int offset, int len) { int t = 0; for (int i = 0; i < len; ) { char c = s.charAt(offset + i++); if (isCaseInsensitive() && c < 128) c = StringUtil.asciiToLowerCase(c); while (true) { int row = ROW_SIZE * t; char n = _tree[row]; int diff = n - c; if (diff == 0) { t = _tree[row + EQ]; if (t == 0) return null; break; } t = _tree[row + hilo(diff)]; if (t == 0) return null; } } return _value[t]; } @Override public V get(ByteBuffer b, int offset, int len) { int t = 0; offset += b.position(); for (int i = 0; i < len; ) { byte c = (byte)(b.get(offset + i++) & 0x7f); if (isCaseInsensitive()) c = StringUtil.asciiToLowerCase(c); while (true) { int row = ROW_SIZE * t; char n = _tree[row]; int diff = n - c; if (diff == 0) { t = _tree[row + EQ]; if (t == 0) return null; break; } t = _tree[row + hilo(diff)]; if (t == 0) return null; } } return _value[t]; } @Override public V getBest(String s, int offset, int length) { return getBest(0, s, offset, length); } private V getBest(int t, String s, int offset, int len) { int node = t; int end = offset + len; loop: while (offset < end) { char c = s.charAt(offset++); len--; if (isCaseInsensitive() && c < 128) c = StringUtil.asciiToLowerCase(c); while (true) { int row = ROW_SIZE * t; char n = _tree[row]; int diff = n - c; if (diff == 0) { t = _tree[row + EQ]; if (t == 0) break loop; // if this node is a match, recurse to remember if (_key[t] != null) { node = t; V better = getBest(t, s, offset, len); if (better != null) return better; } break; } t = _tree[row + hilo(diff)]; if (t == 0) break loop; } } return _value[node]; } @Override public V getBest(ByteBuffer b, int offset, int len) { if (b.hasArray()) return getBest(0, b.array(), b.arrayOffset() + b.position() + offset, len); return getBest(0, b, offset, len); } @Override public V getBest(byte[] b, int offset, int len) { return getBest(0, b, offset, len); } private V getBest(int t, byte[] b, int offset, int len) { int node = t; int end = offset + len; loop: while (offset < end) { byte c = (byte)(b[offset++] & 0x7f); len--; if (isCaseInsensitive()) c = StringUtil.asciiToLowerCase(c); while (true) { int row = ROW_SIZE * t; char n = _tree[row]; int diff = n - c; if (diff == 0) { t = _tree[row + EQ]; if (t == 0) break loop; // if this node is a match, recurse to remember if (_key[t] != null) { node = t; V better = getBest(t, b, offset, len); if (better != null) return better; } break; } t = _tree[row + hilo(diff)]; if (t == 0) break loop; } } return _value[node]; } private V getBest(int t, ByteBuffer b, int offset, int len) { int node = t; int o = offset + b.position(); loop: for (int i = 0; i < len; i++) { if (o + i >= b.limit()) return null; byte c = (byte)(b.get(o + i) & 0x7f); if (isCaseInsensitive()) c = StringUtil.asciiToLowerCase(c); while (true) { int row = ROW_SIZE * t; char n = _tree[row]; int diff = n - c; if (diff == 0) { t = _tree[row + EQ]; if (t == 0) break loop; // if this node is a match, recurse to remember if (_key[t] != null) { node = t; V best = getBest(t, b, offset + i + 1, len - i - 1); if (best != null) return best; } break; } t = _tree[row + hilo(diff)]; if (t == 0) break loop; } } return _value[node]; } @Override public String toString() { StringBuilder buf = new StringBuilder(); buf.append("ATT@").append(Integer.toHexString(hashCode())).append('{'); buf.append("ci=").append(isCaseInsensitive()).append(';'); buf.append("c=").append(_tree.length / ROW_SIZE).append(';'); for (int r = 0; r <= _rows; r++) { if (_key[r] != null && _value[r] != null) { if (r != 0) buf.append(','); buf.append(_key[r]); buf.append('='); buf.append(_value[r]); } } buf.append('}'); return buf.toString(); } @Override public Set keySet() { Set keys = new HashSet<>(); for (int r = 0; r < _rows; r++) { if (_key[r] != null && _value[r] != null) keys.add(_key[r]); } return keys; } public int size() { int s = 0; for (int r = 0; r < _rows; r++) { if (_key[r] != null && _value[r] != null) s++; } return s; } public boolean isEmpty() { for (int r = 0; r < _rows; r++) { if (_key[r] != null && _value[r] != null) return false; } return true; } public Set> entrySet() { Set> entries = new HashSet<>(); for (int r = 0; r < _rows; r++) { if (_key[r] != null && _value[r] != null) entries.add(new AbstractMap.SimpleEntry<>(_key[r], _value[r])); } return entries; } public static int hilo(int diff) { // branchless equivalent to return ((diff<0)?LO:HI); // return 3+2*((diff&Integer.MIN_VALUE)>>Integer.SIZE-1); return 1 + (diff | Integer.MAX_VALUE) / (Integer.MAX_VALUE / 2); } public void dump() { for (int r = 0; r < _rows; r++) { char c = _tree[r * ROW_SIZE + 0]; System.err.printf("%4d [%s,%d,%d,%d] '%s':%s%n", r, (c < ' ' || c > 127) ? ("" + (int)c) : "'" + c + "'", (int)_tree[r * ROW_SIZE + LO], (int)_tree[r * ROW_SIZE + EQ], (int)_tree[r * ROW_SIZE + HI], _key[r], _value[r]); } } @Deprecated public static class Growing extends AbstractTrie { private final int _growby; private ArrayTernaryTrie _trie; public Growing(boolean insensitive, int capacity, int growby) { super(insensitive); _growby = growby; _trie = new ArrayTernaryTrie<>(insensitive, capacity); } @Override public int hashCode() { return _trie.hashCode(); } @Override public V remove(String s) { return _trie.remove(s); } @Override public boolean equals(Object o) { if (this == o) return true; if (o == null || getClass() != o.getClass()) return false; Growing growing = (Growing)o; return Objects.equals(_trie, growing._trie); } @Override public void clear() { _trie.clear(); } @Override public boolean put(V v) { return put(v.toString(), v); } @Override public boolean put(String s, V v) { boolean added = _trie.put(s, v); while (!added && _growby > 0) { int newCapacity = _trie._key.length + _growby; if (newCapacity > MAX_CAPACITY) return false; ArrayTernaryTrie bigger = new ArrayTernaryTrie<>(_trie.isCaseInsensitive(), newCapacity); for (Map.Entry entry : _trie.entrySet()) { bigger.put(entry.getKey(), entry.getValue()); } _trie = bigger; added = _trie.put(s, v); } return added; } @Override public V get(String s) { return _trie.get(s); } @Override public V get(ByteBuffer b) { return _trie.get(b); } @Override public V get(String s, int offset, int len) { return _trie.get(s, offset, len); } @Override public V get(ByteBuffer b, int offset, int len) { return _trie.get(b, offset, len); } @Override public V getBest(byte[] b, int offset, int len) { return _trie.getBest(b, offset, len); } @Override public V getBest(String s) { return _trie.getBest(s); } @Override public V getBest(String s, int offset, int length) { return _trie.getBest(s, offset, length); } @Override public V getBest(ByteBuffer b, int offset, int len) { return _trie.getBest(b, offset, len); } @Override public String toString() { return _trie.toString(); } @Override public Set keySet() { return _trie.keySet(); } public void dump() { _trie.dump(); } public boolean isEmpty() { return _trie.isEmpty(); } public int size() { return _trie.size(); } } }




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