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/*
 * Licensed to the Apache Software Foundation (ASF) under one or more
 * contributor license agreements.  See the NOTICE file distributed with
 * this work for additional information regarding copyright ownership.
 * The ASF licenses this file to You under the Apache License, Version 2.0
 * (the "License"); you may not use this file except in compliance with
 * the License.  You may obtain a copy of the License at
 *
 *     http://www.apache.org/licenses/LICENSE-2.0
 *
 * Unless required by applicable law or agreed to in writing, software
 * distributed under the License is distributed on an "AS IS" BASIS,
 * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
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package org.apache.lucene.search.suggest.fst;

import java.io.Closeable;
import java.io.IOException;
import java.util.Comparator;

import org.apache.lucene.search.suggest.InMemorySorter;
import org.apache.lucene.util.BytesRef;
import org.apache.lucene.util.BytesRefBuilder;
import org.apache.lucene.util.BytesRefIterator;
import org.apache.lucene.util.IntsRefBuilder;
import org.apache.lucene.util.fst.*;

/**
 * Finite state automata based implementation of "autocomplete" functionality.
 * 
 * 

Implementation details

* *

* The construction step in {@link #finalize()} works as follows: *

    *
  • A set of input terms and their buckets is given.
  • *
  • All terms in the input are prefixed with a synthetic pseudo-character * (code) of the weight bucket the term fell into. For example a term * abc with a discretized weight equal '1' would become * 1abc.
  • *
  • The terms are then sorted by their raw value of UTF-8 character values * (including the synthetic bucket code in front).
  • *
  • A finite state automaton ({@link FST}) is constructed from the input. The * root node has arcs labeled with all possible weights. We cache all these * arcs, highest-weight first.
  • *
* *

* At runtime, in {@link FSTCompletion#lookup(CharSequence, int)}, * the automaton is utilized as follows: *

    *
  • For each possible term weight encoded in the automaton (cached arcs from * the root above), starting with the highest one, we descend along the path of * the input key. If the key is not a prefix of a sequence in the automaton * (path ends prematurely), we exit immediately -- no completions.
  • *
  • Otherwise, we have found an internal automaton node that ends the key. * The entire subautomaton (all paths) starting from this node form the key's * completions. We start the traversal of this subautomaton. Every time we * reach a final state (arc), we add a single suggestion to the list of results * (the weight of this suggestion is constant and equal to the root path we * started from). The tricky part is that because automaton edges are sorted and * we scan depth-first, we can terminate the entire procedure as soon as we * collect enough suggestions the user requested.
  • *
  • In case the number of suggestions collected in the step above is still * insufficient, we proceed to the next (smaller) weight leaving the root node * and repeat the same algorithm again.
  • *
* *

Runtime behavior and performance characteristic

* * The algorithm described above is optimized for finding suggestions to short * prefixes in a top-weights-first order. This is probably the most common use * case: it allows presenting suggestions early and sorts them by the global * frequency (and then alphabetically). * *

* If there is an exact match in the automaton, it is returned first on the * results list (even with by-weight sorting). * *

* Note that the maximum lookup time for any prefix is the time of * descending to the subtree, plus traversal of the subtree up to the number of * requested suggestions (because they are already presorted by weight on the * root level and alphabetically at any node level). * *

* To order alphabetically only (no ordering by priorities), use identical term * weights for all terms. Alphabetical suggestions are returned even if * non-constant weights are used, but the algorithm for doing this is * suboptimal. * *

* "alphabetically" in any of the documentation above indicates UTF-8 * representation order, nothing else. * *

* NOTE: the FST file format is experimental and subject to suddenly * change, requiring you to rebuild the FST suggest index. * * @see FSTCompletion * @lucene.experimental */ public class FSTCompletionBuilder { /** * Default number of buckets. */ public static final int DEFAULT_BUCKETS = 10; /** * The number of separate buckets for weights (discretization). The more * buckets, the more fine-grained term weights (priorities) can be assigned. * The speed of lookup will not decrease for prefixes which have * highly-weighted completions (because these are filled-in first), but will * decrease significantly for low-weighted terms (but these should be * infrequent, so it is all right). * *

* The number of buckets must be within [1, 255] range. */ private final int buckets; /** * Finite state automaton encoding all the lookup terms. See class notes for * details. */ FST automaton; /** * FST construction require re-sorting the input. This is the class that * collects all the input entries, their weights and then provides sorted * order. */ private final BytesRefSorter sorter; /** * Scratch buffer for {@link #add(BytesRef, int)}. */ private final BytesRefBuilder scratch = new BytesRefBuilder(); /** * Max tail sharing length. */ private final int shareMaxTailLength; /** * Creates an {@link FSTCompletion} with default options: 10 buckets, exact match * promoted to first position and {@link InMemorySorter} with a comparator obtained from * {@link Comparator#naturalOrder()}. */ public FSTCompletionBuilder() { this(DEFAULT_BUCKETS, new InMemorySorter(Comparator.naturalOrder()), Integer.MAX_VALUE); } /** * Creates an FSTCompletion with the specified options. * @param buckets * The number of buckets for weight discretization. Buckets are used * in {@link #add(BytesRef, int)} and must be smaller than the number * given here. * * @param sorter * {@link BytesRefSorter} used for re-sorting input for the automaton. * For large inputs, use on-disk sorting implementations. The sorter * is closed automatically in {@link #build()} if it implements * {@link Closeable}. * * @param shareMaxTailLength * Max shared suffix sharing length. * * See the description of this parameter in {@link Builder}'s constructor. * In general, for very large inputs you'll want to construct a non-minimal * automaton which will be larger, but the construction will take far less ram. * For minimal automata, set it to {@link Integer#MAX_VALUE}. */ public FSTCompletionBuilder(int buckets, BytesRefSorter sorter, int shareMaxTailLength) { if (buckets < 1 || buckets > 255) { throw new IllegalArgumentException("Buckets must be >= 1 and <= 255: " + buckets); } if (sorter == null) throw new IllegalArgumentException( "BytesRefSorter must not be null."); this.sorter = sorter; this.buckets = buckets; this.shareMaxTailLength = shareMaxTailLength; } /** * Appends a single suggestion and its weight to the internal buffers. * * @param utf8 * The suggestion (utf8 representation) to be added. The content is * copied and the object can be reused. * @param bucket * The bucket to place this suggestion in. Must be non-negative and * smaller than the number of buckets passed in the constructor. * Higher numbers indicate suggestions that should be presented * before suggestions placed in smaller buckets. */ public void add(BytesRef utf8, int bucket) throws IOException { if (bucket < 0 || bucket >= buckets) { throw new IllegalArgumentException( "Bucket outside of the allowed range [0, " + buckets + "): " + bucket); } scratch.grow(utf8.length + 10); scratch.clear(); scratch.append((byte) bucket); scratch.append(utf8); sorter.add(scratch.get()); } /** * Builds the final automaton from a list of added entries. This method may * take a longer while as it needs to build the automaton. */ public FSTCompletion build() throws IOException { this.automaton = buildAutomaton(sorter); if (sorter instanceof Closeable) { ((Closeable) sorter).close(); } return new FSTCompletion(automaton); } /** * Builds the final automaton from a list of entries. */ private FST buildAutomaton(BytesRefSorter sorter) throws IOException { // Build the automaton. final Outputs outputs = NoOutputs.getSingleton(); final Object empty = outputs.getNoOutput(); final Builder builder = new Builder<>( FST.INPUT_TYPE.BYTE1, 0, 0, true, true, shareMaxTailLength, outputs, true, 15); BytesRefBuilder scratch = new BytesRefBuilder(); BytesRef entry; final IntsRefBuilder scratchIntsRef = new IntsRefBuilder(); int count = 0; BytesRefIterator iter = sorter.iterator(); while((entry = iter.next()) != null) { count++; if (scratch.get().compareTo(entry) != 0) { builder.add(Util.toIntsRef(entry, scratchIntsRef), empty); scratch.copyBytes(entry); } } return count == 0 ? null : builder.finish(); } }