@Override public void finish(long termsFilePointer) throws IOException { fst = fstBuilder.finish(); if (fst != null) { fst.save(out); } }
// Finishes all terms in this field @Override public void finish(long sumTotalTermFreq, long sumDocFreq, int docCount) throws IOException { if (numTerms > 0) { blockBuilder.finish(); // We better have one final "root" block: assert pending.size() == 1 && !pending.get(0).isTerm : "pending.size()=" + pending.size() + " pending=" + pending; final PendingBlock root = (PendingBlock) pending.get(0); assert root.prefix.length == 0; assert root.index.getEmptyOutput() != null; this.sumTotalTermFreq = sumTotalTermFreq; this.sumDocFreq = sumDocFreq; this.docCount = docCount; // Write FST to index indexStartFP = indexOut.getFilePointer(); root.index.save(indexOut); // System.out.println(" write FST " + indexStartFP + " field=" + fieldInfo.name); // if (SAVE_DOT_FILES || DEBUG) { // final String dotFileName = segment + "_" + fieldInfo.name + ".dot"; // Writer w = new OutputStreamWriter(new FileOutputStream(dotFileName)); // Util.toDot(root.index, w, false, false); // System.out.println("SAVED to " + dotFileName); // w.close(); // } fields.add( new FieldMetaData( fieldInfo, ((PendingBlock) pending.get(0)).index.getEmptyOutput(), numTerms, indexStartFP, sumTotalTermFreq, sumDocFreq, docCount)); } else { assert sumTotalTermFreq == 0 || fieldInfo.getIndexOptions() == IndexOptions.DOCS_ONLY && sumTotalTermFreq == -1; assert sumDocFreq == 0; assert docCount == 0; } }
@Override public void build(TermFreqIterator iterator) throws IOException { BytesRef scratch = new BytesRef(); TermFreqIterator iter = new WFSTTermFreqIteratorWrapper(iterator, BytesRef.getUTF8SortedAsUnicodeComparator()); IntsRef scratchInts = new IntsRef(); BytesRef previous = null; PositiveIntOutputs outputs = PositiveIntOutputs.getSingleton(true); Builder<Long> builder = new Builder<Long>(FST.INPUT_TYPE.BYTE1, outputs); while ((scratch = iter.next()) != null) { long cost = iter.weight(); if (previous == null) { previous = new BytesRef(); } else if (scratch.equals(previous)) { continue; // for duplicate suggestions, the best weight is actually // added } Util.toIntsRef(scratch, scratchInts); builder.add(scratchInts, cost); previous.copyBytes(scratch); } fst = builder.finish(); }
/** Builds an {@link SynonymMap} and returns it. */ public SynonymMap build() throws IOException { ByteSequenceOutputs outputs = ByteSequenceOutputs.getSingleton(); // TODO: are we using the best sharing options? org.apache.lucene.util.fst.Builder<BytesRef> builder = new org.apache.lucene.util.fst.Builder<>(FST.INPUT_TYPE.BYTE4, outputs); BytesRefBuilder scratch = new BytesRefBuilder(); ByteArrayDataOutput scratchOutput = new ByteArrayDataOutput(); final Set<Integer> dedupSet; if (dedup) { dedupSet = new HashSet<>(); } else { dedupSet = null; } final byte[] spare = new byte[5]; Set<CharsRef> keys = workingSet.keySet(); CharsRef sortedKeys[] = keys.toArray(new CharsRef[keys.size()]); Arrays.sort(sortedKeys, CharsRef.getUTF16SortedAsUTF8Comparator()); final IntsRefBuilder scratchIntsRef = new IntsRefBuilder(); // System.out.println("fmap.build"); for (int keyIdx = 0; keyIdx < sortedKeys.length; keyIdx++) { CharsRef input = sortedKeys[keyIdx]; MapEntry output = workingSet.get(input); int numEntries = output.ords.size(); // output size, assume the worst case int estimatedSize = 5 + numEntries * 5; // numEntries + one ord for each entry scratch.grow(estimatedSize); scratchOutput.reset(scratch.bytes()); // now write our output data: int count = 0; for (int i = 0; i < numEntries; i++) { if (dedupSet != null) { // box once final Integer ent = output.ords.get(i); if (dedupSet.contains(ent)) { continue; } dedupSet.add(ent); } scratchOutput.writeVInt(output.ords.get(i)); count++; } final int pos = scratchOutput.getPosition(); scratchOutput.writeVInt(count << 1 | (output.includeOrig ? 0 : 1)); final int pos2 = scratchOutput.getPosition(); final int vIntLen = pos2 - pos; // Move the count + includeOrig to the front of the byte[]: System.arraycopy(scratch.bytes(), pos, spare, 0, vIntLen); System.arraycopy(scratch.bytes(), 0, scratch.bytes(), vIntLen, pos); System.arraycopy(spare, 0, scratch.bytes(), 0, vIntLen); if (dedupSet != null) { dedupSet.clear(); } scratch.setLength(scratchOutput.getPosition()); // System.out.println(" add input=" + input + " output=" + scratch + " offset=" + // scratch.offset + " length=" + scratch.length + " count=" + count); builder.add(Util.toUTF32(input, scratchIntsRef), scratch.toBytesRef()); } FST<BytesRef> fst = builder.finish(); return new SynonymMap(fst, words, maxHorizontalContext); }
public void compileIndex(List<PendingBlock> floorBlocks, RAMOutputStream scratchBytes) throws IOException { assert (isFloor && floorBlocks != null && floorBlocks.size() != 0) || (!isFloor && floorBlocks == null) : "isFloor=" + isFloor + " floorBlocks=" + floorBlocks; assert scratchBytes.getFilePointer() == 0; // TODO: try writing the leading vLong in MSB order // (opposite of what Lucene does today), for better // outputs sharing in the FST scratchBytes.writeVLong(encodeOutput(fp, hasTerms, isFloor)); if (isFloor) { scratchBytes.writeVInt(floorBlocks.size()); for (PendingBlock sub : floorBlocks) { assert sub.floorLeadByte != -1; // if (DEBUG) { // System.out.println(" write floorLeadByte=" + // Integer.toHexString(sub.floorLeadByte&0xff)); // } scratchBytes.writeByte((byte) sub.floorLeadByte); assert sub.fp > fp; scratchBytes.writeVLong((sub.fp - fp) << 1 | (sub.hasTerms ? 1 : 0)); } } final ByteSequenceOutputs outputs = ByteSequenceOutputs.getSingleton(); final Builder<BytesRef> indexBuilder = new Builder<BytesRef>( FST.INPUT_TYPE.BYTE1, 0, 0, true, false, Integer.MAX_VALUE, outputs, null, false, PackedInts.COMPACT, true, 15); // if (DEBUG) { // System.out.println(" compile index for prefix=" + prefix); // } // indexBuilder.DEBUG = false; final byte[] bytes = new byte[(int) scratchBytes.getFilePointer()]; assert bytes.length > 0; scratchBytes.writeTo(bytes, 0); indexBuilder.add( Util.toIntsRef(prefix, scratchIntsRef), new BytesRef(bytes, 0, bytes.length)); scratchBytes.reset(); // Copy over index for all sub-blocks if (subIndices != null) { for (FST<BytesRef> subIndex : subIndices) { append(indexBuilder, subIndex); } } if (floorBlocks != null) { for (PendingBlock sub : floorBlocks) { if (sub.subIndices != null) { for (FST<BytesRef> subIndex : sub.subIndices) { append(indexBuilder, subIndex); } } sub.subIndices = null; } } index = indexBuilder.finish(); subIndices = null; /* Writer w = new OutputStreamWriter(new FileOutputStream("out.dot")); Util.toDot(index, w, false, false); System.out.println("SAVED to out.dot"); w.close(); */ }
private UserDictionary(List<String[]> featureEntries) throws IOException { int wordId = CUSTOM_DICTIONARY_WORD_ID_OFFSET; // TODO: should we allow multiple segmentations per input 'phrase'? // the old treemap didn't support this either, and i'm not sure if it's needed/useful? Collections.sort( featureEntries, new Comparator<String[]>() { @Override public int compare(String[] left, String[] right) { return left[0].compareTo(right[0]); } }); List<String> data = new ArrayList<>(featureEntries.size()); List<int[]> segmentations = new ArrayList<>(featureEntries.size()); PositiveIntOutputs fstOutput = PositiveIntOutputs.getSingleton(); Builder<Long> fstBuilder = new Builder<>(FST.INPUT_TYPE.BYTE2, fstOutput); IntsRefBuilder scratch = new IntsRefBuilder(); long ord = 0; for (String[] values : featureEntries) { String[] segmentation = values[1].replaceAll(" *", " ").split(" "); String[] readings = values[2].replaceAll(" *", " ").split(" "); String pos = values[3]; if (segmentation.length != readings.length) { throw new RuntimeException( "Illegal user dictionary entry " + values[0] + " - the number of segmentations (" + segmentation.length + ")" + " does not the match number of readings (" + readings.length + ")"); } int[] wordIdAndLength = new int[segmentation.length + 1]; // wordId offset, length, length.... wordIdAndLength[0] = wordId; for (int i = 0; i < segmentation.length; i++) { wordIdAndLength[i + 1] = segmentation[i].length(); data.add(readings[i] + INTERNAL_SEPARATOR + pos); wordId++; } // add mapping to FST String token = values[0]; scratch.grow(token.length()); scratch.setLength(token.length()); for (int i = 0; i < token.length(); i++) { scratch.setIntAt(i, (int) token.charAt(i)); } fstBuilder.add(scratch.get(), ord); segmentations.add(wordIdAndLength); ord++; } this.fst = new TokenInfoFST(fstBuilder.finish(), false); this.data = data.toArray(new String[data.size()]); this.segmentations = segmentations.toArray(new int[segmentations.size()][]); }