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223 lines
11 KiB
223 lines
11 KiB
package de.anomic.kelondro;
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// a collectionIndex is an index to collection (kelondroCollection) objects
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// such a collection ist defined by the following parameters
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// - chunksize
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// - chunkcount
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// each of such a collection is stored in a byte[] which may or may not have space for more chunks
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// than already exists in such an array. To store these arrays, we reserve entries in kelondroArray
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// database files. There will be a set of array files for different sizes of the collection arrays.
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// the 1st file has space for <loadfactor> chunks, the 2nd file for <loadfactor> * <loadfactor> chunks,
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// the 3rd file for <loadfactor>^^3 chunks, and the n-th file for <loadfactor>^^n chunks.
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// if the loadfactor is 4, then we have the following capacities:
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// file 0: 4
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// file 1: 16
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// file 2: 64
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// file 3: 256
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// file 4: 1024
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// file 5: 4096
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// file 6:16384
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// file 7:65536
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// the maximum number of such files is called the partitions number.
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// we don't want that these files grow too big, an kelondroOutOfLimitsException is throws if they
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// are oversized.
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// the collection arrays may be migration to another size during run-time, which means that not only the
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// partitions as mentioned above are maintained, but also a set of "shadow-partitions", that represent old
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// partitions and where data is read only and slowly migrated to the default partitions.
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import java.io.File;
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import java.io.IOException;
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import java.util.Iterator;
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public class kelondroCollectionIndex {
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private kelondroIndex index;
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private File path;
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private String filenameStub;
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private int loadfactor;
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private int chunksize;
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private int partitions;
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private int maxChunks;
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private kelondroArray[] array;
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private int[] arrayCapacity;
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private static File arrayFile(File path, String filenameStub, int loadfactor, int chunksize, int partitionNumber) {
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String lf = Integer.toHexString(loadfactor).toUpperCase();
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while (lf.length() < 2) lf = "0" + lf;
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String cs = Integer.toHexString(chunksize).toUpperCase();
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while (cs.length() < 4) cs = "0" + cs;
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String pn = Integer.toHexString(partitionNumber).toUpperCase();
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while (pn.length() < 2) pn = "0" + pn;
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return new File(path, filenameStub + "." + lf + "." + cs + "." + pn + ".kca"); // kelondro collection array
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}
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private static final long day = 1000 * 60 * 60 * 24;
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private static int daysSince2000(long time) {
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return (int) (time / day) - 10957;
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}
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public kelondroCollectionIndex(File path, String filenameStub, int keyLength, kelondroOrder indexOrder, long buffersize,
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int loadfactor, int chunksize, int partitions) throws IOException {
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this.path = path;
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this.filenameStub = filenameStub;
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this.chunksize = chunksize;
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this.partitions = partitions;
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this.loadfactor = loadfactor;
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// create index file(s)
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int[] columns;
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columns = new int[3];
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columns[0] = keyLength;
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columns[1] = 4; // chunksize (number of bytes in a single chunk, needed for migration option)
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columns[2] = 4; // chunkcount (number of chunks in this collection)
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columns[3] = 4; // index (position in index file)
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columns[4] = 2; // update time in days since 1.1.2000
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index = new kelondroSplittedTree(path, filenameStub, indexOrder, buffersize, 8, columns, 1, 80, true);
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// create array files
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this.array = new kelondroArray[partitions];
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this.arrayCapacity = new int[partitions];
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// open array files
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int load = 1;
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for (int i = 0; i < partitions; i++) {
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load = load * loadfactor;
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array[i] = openArrayFile(chunksize, i);
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arrayCapacity[i] = load;
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}
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this.maxChunks = load;
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}
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private kelondroArray openArrayFile(int genericChunkSize, int partitionNumber) throws IOException {
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File f = arrayFile(path, filenameStub, loadfactor, genericChunkSize, partitionNumber);
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if (f.exists()) {
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return new kelondroArray(f);
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} else {
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int load = 1; for (int i = 0; i < partitionNumber; i++) load = load * loadfactor;
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int[] columns = new int[4];
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columns[0] = index.columnSize(0); // add always the key
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columns[1] = 4; // chunkcount (raw format)
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columns[2] = 2; // last time read
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columns[3] = 2; // last time wrote
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columns[4] = 2; // flag string, assigns collection order as currently stored in table
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columns[5] = load * genericChunkSize;
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return new kelondroArray(f, columns, 0, true);
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}
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}
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private int arrayIndex(int requestedCapacity) throws kelondroOutOfLimitsException{
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// the requestedCapacity is the number of wanted chunks
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for (int i = 0; i < arrayCapacity.length; i++) {
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if (arrayCapacity[i] >= requestedCapacity) return i;
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}
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throw new kelondroOutOfLimitsException(maxChunks, requestedCapacity);
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}
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public void put(byte[] key, kelondroCollection collection) throws IOException, kelondroOutOfLimitsException {
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if (collection.size() > maxChunks) throw new kelondroOutOfLimitsException(maxChunks, collection.size());
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// first find an old entry, if one exists
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byte[][] oldindexrow = index.get(key);
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// define the new storage array
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byte[][] newarrayrow = new byte[][]{key,
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kelondroNaturalOrder.encodeLong((long) collection.size(), 4),
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collection.getOrderingSignature().getBytes(),
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collection.toByteArray()};
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if (oldindexrow == null) {
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// the collection is new
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// find appropriate partition for the collection:
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int part = arrayIndex(collection.size());
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// write a new entry in this array
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int newRowNumber = array[part].add(newarrayrow);
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// store the new row number in the index
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index.put(new byte[][]{key,
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kelondroNaturalOrder.encodeLong(this.chunksize, 4),
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kelondroNaturalOrder.encodeLong(collection.size(), 4),
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kelondroNaturalOrder.encodeLong((long) newRowNumber, 4),
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kelondroNaturalOrder.encodeLong(daysSince2000(System.currentTimeMillis()), 2)
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});
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} else {
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// overwrite the old collection
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// read old information
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//int chunksize = (int) kelondroNaturalOrder.decodeLong(oldindexrow[1]); // needed only for migration
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int chunkcount = (int) kelondroNaturalOrder.decodeLong(oldindexrow[2]);
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int rownumber = (int) kelondroNaturalOrder.decodeLong(oldindexrow[3]);
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int oldPartitionNumber = arrayIndex(chunkcount);
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int newPartitionNumber = arrayIndex(collection.size());
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// see if we need new space or if we can overwrite the old space
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if (oldPartitionNumber == newPartitionNumber) {
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// we don't need a new slot, just write in the old one
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array[oldPartitionNumber].set(rownumber, newarrayrow);
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// update the index entry
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index.put(new byte[][]{key,
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kelondroNaturalOrder.encodeLong(this.chunksize, 4),
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kelondroNaturalOrder.encodeLong(collection.size(), 4),
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kelondroNaturalOrder.encodeLong((long) rownumber, 4),
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kelondroNaturalOrder.encodeLong(daysSince2000(System.currentTimeMillis()), 2)
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});
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} else {
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// we need a new slot, that means we must first delete the old entry
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array[oldPartitionNumber].remove(rownumber);
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// write a new entry in the other array
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int newRowNumber = array[newPartitionNumber].add(newarrayrow);
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// store the new row number in the index
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index.put(new byte[][]{key,
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kelondroNaturalOrder.encodeLong(this.chunksize, 4),
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kelondroNaturalOrder.encodeLong(collection.size(), 4),
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kelondroNaturalOrder.encodeLong((long) newRowNumber, 4),
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kelondroNaturalOrder.encodeLong(daysSince2000(System.currentTimeMillis()), 2)
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});
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}
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}
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}
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public kelondroCollection get(byte[] key) throws IOException {
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// find an entry, if one exists
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byte[][] indexrow = index.get(key);
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if (indexrow == null) return null;
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// read values
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int chunksize = (int) kelondroNaturalOrder.decodeLong(indexrow[1]);
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int chunkcount = (int) kelondroNaturalOrder.decodeLong(indexrow[2]);
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int rownumber = (int) kelondroNaturalOrder.decodeLong(indexrow[3]);
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int partitionnumber = arrayIndex(chunkcount);
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// open array entry
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byte[][] arrayrow = array[partitionnumber].get(rownumber);
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if (arrayrow == null) throw new kelondroException(arrayFile(this.path, this.filenameStub, this.loadfactor, chunksize, partitionnumber).toString(), "array does not contain expected row");
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// read the row and define a collection
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int chunkcountInArray = (int) kelondroNaturalOrder.decodeLong(arrayrow[1]);
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if (chunkcountInArray != chunkcount) throw new kelondroException(arrayFile(this.path, this.filenameStub, this.loadfactor, chunksize, partitionnumber).toString(), "array has different chunkcount than index: index = " + chunkcount + ", array = " + chunkcountInArray);
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return new kelondroCollection(chunksize, chunkcount, new String(arrayrow[2]), arrayrow[3]);
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}
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public void remove(byte[] key) throws IOException {
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// find an entry, if one exists
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byte[][] indexrow = index.get(key);
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if (indexrow == null) return;
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// read values
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//int chunksize = (int) kelondroNaturalOrder.decodeLong(indexrow[1]);
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int chunkcount = (int) kelondroNaturalOrder.decodeLong(indexrow[2]);
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int rownumber = (int) kelondroNaturalOrder.decodeLong(indexrow[3]);
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int partitionnumber = arrayIndex(chunkcount);
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// remove array entry
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array[partitionnumber].remove(rownumber);
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}
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/*
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public Iterator collections(boolean up, boolean rotating) throws IOException {
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// Objects are of type kelondroCollection
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}
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*/
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public static void main(String[] args) {
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System.out.println(new java.util.Date(10957 * day));
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System.out.println(new java.util.Date(0));
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System.out.println(daysSince2000(System.currentTimeMillis()));
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}
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}
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