package de.anomic.kelondro; // a collectionIndex is an index to kelondroRowCollection objects // such a collection ist defined by the following parameters // - chunksize // - chunkcount // each of such a collection is stored in a byte[] which may or may not have space for more chunks // than already exists in such an array. To store these arrays, we reserve entries in kelondroArray // database files. There will be a set of array files for different sizes of the collection arrays. // the 1st file has space for chunks, the 2nd file for * chunks, // the 3rd file for ^^3 chunks, and the n-th file for ^^n chunks. // if the loadfactor is 4, then we have the following capacities: // file 0: 4 // file 1: 16 // file 2: 64 // file 3: 256 // file 4: 1024 // file 5: 4096 // file 6:16384 // file 7:65536 // the maximum number of such files is called the partitions number. // we don't want that these files grow too big, an kelondroOutOfLimitsException is throws if they // are oversized. // the collection arrays may be migration to another size during run-time, which means that not only the // partitions as mentioned above are maintained, but also a set of "shadow-partitions", that represent old // partitions and where data is read only and slowly migrated to the default partitions. import java.io.File; import java.io.IOException; import java.util.HashMap; import java.util.Iterator; import java.util.Map; import java.util.Set; import de.anomic.server.serverFileUtils; public class kelondroCollectionIndex { protected kelondroIndex index; private File path; private String filenameStub; private int loadfactor; private Map arrays; // Map of (partitionNumber"-"chunksize)/kelondroFixedWidthArray - Objects private kelondroRow playloadrow; // definition of the payload (chunks inside the collections) // private int partitions; // this is the maxmimum number of array files; yet not used private static final int idx_col_key = 0; // the index private static final int idx_col_chunksize = 1; // chunksize (number of bytes in a single chunk, needed for migration option) private static final int idx_col_chunkcount = 2; // chunkcount (number of chunks in this collection) needed to identify array file that has the chunks private static final int idx_col_indexpos = 3; // indexpos (position in index file) private static final int idx_col_lastread = 4; // a time stamp, update time in days since 1.1.2000 private static final int idx_col_lastwrote = 5; // a time stamp, update time in days since 1.1.2000 private static kelondroRow indexRow(int keylen) { return new kelondroRow( "byte[] key-" + keylen + "," + "int chunksize-4 {b256}," + "int chunkcount-4 {b256}," + "int indexpos-4 {b256}," + "short lastread-2 {b256}, " + "short lastwrote-2 {b256}" ); } private static String fillZ(String s, int len) { while (s.length() < len) s = "0" + s; return s; } private static File arrayFile(File path, String filenameStub, int loadfactor, int chunksize, int partitionNumber, int serialNumber) { String lf = fillZ(Integer.toHexString(loadfactor).toUpperCase(), 2); String cs = fillZ(Integer.toHexString(chunksize).toUpperCase(), 4); String pn = fillZ(Integer.toHexString(partitionNumber).toUpperCase(), 2); String sn = fillZ(Integer.toHexString(serialNumber).toUpperCase(), 2); return new File(path, filenameStub + "." + lf + "." + cs + "." + pn + "." + sn + ".kca"); // kelondro collection array } private static File propertyFile(File path, String filenameStub, int loadfactor, int chunksize) { String lf = fillZ(Integer.toHexString(loadfactor).toUpperCase(), 2); String cs = fillZ(Integer.toHexString(chunksize).toUpperCase(), 4); return new File(path, filenameStub + "." + lf + "." + cs + ".properties"); // kelondro collection array } public kelondroCollectionIndex(File path, String filenameStub, int keyLength, kelondroOrder indexOrder, long buffersize, long preloadTime, int loadfactor, kelondroRow rowdef) throws IOException { // the buffersize is number of bytes that are only used if the kelondroFlexTable is backed up with a kelondroTree this.path = path; this.filenameStub = filenameStub; this.playloadrow = rowdef; this.loadfactor = loadfactor; // create index table index = new kelondroFlexTable(path, filenameStub + ".index.table", indexOrder, buffersize, preloadTime, indexRow(keyLength), true); // save/check property file for this array File propfile = propertyFile(path, filenameStub, loadfactor, rowdef.objectsize()); Map props = new HashMap(); if (propfile.exists()) { props = serverFileUtils.loadHashMap(propfile); String stored_rowdef = (String) props.get("rowdef"); if ((stored_rowdef == null) || (!(rowdef.subsumes(new kelondroRow(stored_rowdef))))) { System.out.println("FATAL ERROR: stored rowdef '" + stored_rowdef + "' does not match with new rowdef '" + rowdef + "' for array cluster '" + path + "/" + filenameStub + "'"); System.exit(-1); } } props.put("rowdef", rowdef.toString()); serverFileUtils.saveMap(propfile, props, "CollectionIndex properties"); // open array files this.arrays = new HashMap(); // all entries will be dynamically created with getArray() } private kelondroFixedWidthArray openArrayFile(int partitionNumber, int serialNumber, boolean create) throws IOException { File f = arrayFile(path, filenameStub, loadfactor, playloadrow.objectsize(), partitionNumber, serialNumber); int load = arrayCapacity(partitionNumber); kelondroRow rowdef = new kelondroRow( "byte[] key-" + index.row().width(0) + "," + "byte[] collection-" + (kelondroRowCollection.exportOverheadSize + load * this.playloadrow.objectsize()) ); if (f.exists()) { return new kelondroFixedWidthArray(f, rowdef); } else if (create) { return new kelondroFixedWidthArray(f, rowdef, 0, true); } else { return null; } } private kelondroFixedWidthArray getArray(int partitionNumber, int serialNumber, int chunksize) { String accessKey = partitionNumber + "-" + chunksize; kelondroFixedWidthArray array = (kelondroFixedWidthArray) arrays.get(accessKey); if (array != null) return array; try { array = openArrayFile(partitionNumber, serialNumber, true); } catch (IOException e) { return null; } arrays.put(accessKey, array); return array; } private int arrayCapacity(int arrayCounter) { int load = this.loadfactor; for (int i = 0; i < arrayCounter; i++) load = load * this.loadfactor; return load; } private int arrayIndex(int requestedCapacity) throws kelondroOutOfLimitsException{ // the requestedCapacity is the number of wanted chunks int load = 1, i = 0; while (true) { load = load * this.loadfactor; if (load >= requestedCapacity) return i; i++; } } public int size() throws IOException { return index.size(); } public void put(byte[] key, kelondroRowCollection collection) throws IOException, kelondroOutOfLimitsException { // this replaces an old collection by a new one // this method is not approriate to extend an existing collection with another collection putmergeremove(key, collection, false, null, false); } public void merge(byte[] key, kelondroRowCollection collection) throws IOException, kelondroOutOfLimitsException { putmergeremove(key, collection, true, null, false); } public int remove(byte[] key, Set removekeys, boolean deletecomplete) throws IOException, kelondroOutOfLimitsException { return putmergeremove(key, null, false, removekeys, deletecomplete); } private int putmergeremove(byte[] key, kelondroRowCollection collection, boolean merge, Set removekeys, boolean deletecomplete) throws IOException, kelondroOutOfLimitsException { //if (collection.size() > maxChunks) throw new kelondroOutOfLimitsException(maxChunks, collection.size()); if ((!merge) && (removekeys != null) && (collection != null) && (collection.size() == 0)) { // this is not a replacement, it is a deletion delete(key); return 0; } synchronized (index) { // first find an old entry, if one exists kelondroRow.Entry oldindexrow = index.get(key); if (oldindexrow == null) { if ((collection != null) && (collection.size() > 0)) { // the collection is new overwrite(key, collection); } return 0; } // overwrite the old collection // read old information int oldchunksize = (int) oldindexrow.getColLong(idx_col_chunksize); // needed only for migration int oldchunkcount = (int) oldindexrow.getColLong(idx_col_chunkcount); int oldrownumber = (int) oldindexrow.getColLong(idx_col_indexpos); int oldPartitionNumber = arrayIndex(oldchunkcount); int oldSerialNumber = 0; if (merge) { // load the old collection and join it with the old kelondroRowSet oldcollection = getdelete(oldindexrow, false, false); // join with new collection oldcollection.addAll(collection); collection = oldcollection; } int removed = 0; if (removekeys != null) { // load the old collection and remove keys kelondroRowSet oldcollection = getdelete(oldindexrow, false, false); // remove the keys from the set Iterator i = removekeys.iterator(); Object k; while (i.hasNext()) { k = i.next(); if (k instanceof byte[]) {if (oldcollection.remove((byte[]) k) != null) removed++;} if (k instanceof String) {if (oldcollection.remove(((String) k).getBytes()) != null) removed++;} } collection = oldcollection; } if (collection.size() == 0) { if (deletecomplete) { kelondroFixedWidthArray array = getArray(oldPartitionNumber, oldSerialNumber, oldchunksize); array.remove(oldrownumber); } return removed; } int newPartitionNumber = arrayIndex(collection.size()); int newSerialNumber = 0; // see if we need new space or if we can overwrite the old space if (oldPartitionNumber == newPartitionNumber) { // we don't need a new slot, just write into the old one // find array file kelondroFixedWidthArray array = getArray(newPartitionNumber, newSerialNumber, this.playloadrow.objectsize()); // define row kelondroRow.Entry arrayEntry = array.row().newEntry(); arrayEntry.setCol(0, key); arrayEntry.setCol(1, collection.exportCollection()); // overwrite entry in this array array.set(oldrownumber, arrayEntry); // update the index entry oldindexrow.setCol(idx_col_chunkcount, collection.size()); oldindexrow.setCol(idx_col_lastwrote, kelondroRowCollection.daysSince2000(System.currentTimeMillis())); index.put(oldindexrow); } else { // we need a new slot, that means we must first delete the old entry // find array file kelondroFixedWidthArray array = getArray(oldPartitionNumber, oldSerialNumber, oldchunksize); // delete old entry array.remove(oldrownumber); // write a new entry in the other array overwrite(key, collection); } return removed; } } private void overwrite(byte[] key, kelondroRowCollection collection) throws IOException { // helper method, should not be called directly and only within a synchronized(index) environment // simply store a collection without check if the collection existed before // find array file kelondroFixedWidthArray array = getArray(arrayIndex(collection.size()), 0, this.playloadrow.objectsize()); // define row kelondroRow.Entry arrayEntry = array.row().newEntry(); arrayEntry.setCol(0, key); arrayEntry.setCol(1, collection.exportCollection()); // write a new entry in this array int newRowNumber = array.add(arrayEntry); // store the new row number in the index kelondroRow.Entry indexEntry = index.row().newEntry(); indexEntry.setCol(idx_col_key, key); indexEntry.setCol(idx_col_chunksize, this.playloadrow.objectsize()); indexEntry.setCol(idx_col_chunkcount, collection.size()); indexEntry.setCol(idx_col_indexpos, (long) newRowNumber); indexEntry.setCol(idx_col_lastread, kelondroRowCollection.daysSince2000(System.currentTimeMillis())); indexEntry.setCol(idx_col_lastwrote, kelondroRowCollection.daysSince2000(System.currentTimeMillis())); index.put(indexEntry); } public int indexSize(byte[] key) throws IOException { synchronized (index) { kelondroRow.Entry indexrow = index.get(key); if (indexrow == null) return 0; return (int) indexrow.getColLong(idx_col_chunkcount); } } public kelondroRowSet get(byte[] key, boolean deleteIfEmpty) throws IOException { // find an entry, if one exists synchronized (index) { kelondroRow.Entry indexrow = index.get(key); if (indexrow == null) return null; return getdelete(indexrow, false, deleteIfEmpty); } } public kelondroRowSet delete(byte[] key) throws IOException { // find an entry, if one exists synchronized (index) { kelondroRow.Entry indexrow = index.get(key); if (indexrow == null) return null; return getdelete(indexrow, true, false); } } protected kelondroRowSet getdelete(kelondroRow.Entry indexrow, boolean remove, boolean deleteIfEmpty) throws IOException { // call this only within a synchronized(index) environment // read values int chunksize = (int) indexrow.getColLong(idx_col_chunksize); int chunkcount = (int) indexrow.getColLong(idx_col_chunkcount); int rownumber = (int) indexrow.getColLong(idx_col_indexpos); int partitionnumber = arrayIndex(chunkcount); int serialnumber = 0; // open array entry kelondroFixedWidthArray array = getArray(partitionnumber, serialnumber, chunksize); kelondroRow.Entry arrayrow = array.get(rownumber); if (arrayrow == null) throw new kelondroException(arrayFile(this.path, this.filenameStub, this.loadfactor, chunksize, partitionnumber, serialnumber).toString(), "array does not contain expected row"); // read the row and define a collection kelondroRowSet collection = new kelondroRowSet(this.playloadrow, arrayrow.getColBytes(1)); // FIXME: this does not yet work with different rowdef in case of several rowdef.objectsize() if (index.order().compare(arrayrow.getColBytes(0), indexrow.getColBytes(idx_col_key)) != 0) { // check if we got the right row; this row is wrong. Fix it: index.remove(indexrow.getColBytes(idx_col_key)); // the wrong row cannot be fixed // store the row number in the index; this may be a double-entry, but better than nothing kelondroRow.Entry indexEntry = index.row().newEntry(); indexEntry.setCol(idx_col_key, arrayrow.getColBytes(0)); indexEntry.setCol(idx_col_chunksize, this.playloadrow.objectsize()); indexEntry.setCol(idx_col_chunkcount, collection.size()); indexEntry.setCol(idx_col_indexpos, (long) rownumber); indexEntry.setCol(idx_col_lastread, kelondroRowCollection.daysSince2000(System.currentTimeMillis())); indexEntry.setCol(idx_col_lastwrote, kelondroRowCollection.daysSince2000(System.currentTimeMillis())); index.put(indexEntry); throw new kelondroException(arrayFile(this.path, this.filenameStub, this.loadfactor, chunksize, partitionnumber, serialnumber).toString(), "array contains wrong row '" + new String(arrayrow.getColBytes(0)) + "', expected is '" + new String(indexrow.getColBytes(idx_col_key)) + "', the row has been fixed"); } int chunkcountInArray = collection.size(); if (chunkcountInArray != chunkcount) { // fix the entry in index indexrow.setCol(idx_col_chunkcount, chunkcountInArray); index.put(indexrow); array.logFailure("INCONSISTENCY in " + arrayFile(this.path, this.filenameStub, this.loadfactor, chunksize, partitionnumber, serialnumber).toString() + ": array has different chunkcount than index: index = " + chunkcount + ", array = " + chunkcountInArray + "; the index has been auto-fixed"); } if ((remove) || ((chunkcountInArray == 0) && (deleteIfEmpty))) array.remove(rownumber); return collection; } public Iterator keycollections(byte[] startKey, boolean rot) { // returns an iteration of {byte[], kelondroRowSet} Objects try { return new keycollectionIterator(startKey, rot); } catch (IOException e) { e.printStackTrace(); return null; } } public class keycollectionIterator implements Iterator { Iterator indexRowIterator; public keycollectionIterator(byte[] startKey, boolean rot) throws IOException { // iterator of {byte[], kelondroRowSet} Objects indexRowIterator = index.rows(true, rot, startKey); } public boolean hasNext() { return indexRowIterator.hasNext(); } public Object next() { kelondroRow.Entry indexrow = (kelondroRow.Entry) indexRowIterator.next(); if (indexrow == null) return null; try { return new Object[]{indexrow.getColBytes(0), getdelete(indexrow, false, false)}; } catch (IOException e) { e.printStackTrace(); return null; } } public void remove() { indexRowIterator.remove(); } } public void close() throws IOException { this.index.close(); Iterator i = arrays.values().iterator(); while (i.hasNext()) { ((kelondroFixedWidthArray) i.next()).close(); } } public static void main(String[] args) { // define payload structure kelondroRow rowdef = new kelondroRow("byte[] a-10, byte[] b-80"); File path = new File(args[0]); String filenameStub = args[1]; long buffersize = 10000000; long preloadTime = 10000; try { // initialize collection index kelondroCollectionIndex collectionIndex = new kelondroCollectionIndex( path, filenameStub, 9 /*keyLength*/, kelondroNaturalOrder.naturalOrder, buffersize, preloadTime, 4 /*loadfactor*/, rowdef); // fill index with values kelondroRowSet collection = new kelondroRowSet(rowdef); collection.add(rowdef.newEntry(new byte[][]{"abc".getBytes(), "efg".getBytes()})); collectionIndex.put("erstes".getBytes(), collection); for (int i = 0; i <= 17; i++) { collection = new kelondroRowSet(rowdef); for (int j = 0; j < i; j++) { collection.add(rowdef.newEntry(new byte[][]{("abc" + j).getBytes(), "xxx".getBytes()})); } System.out.println("put key-" + i + ": " + collection.toString()); collectionIndex.put(("key-" + i).getBytes(), collection); } // extend collections with more values for (int i = 0; i <= 17; i++) { collection = new kelondroRowSet(rowdef); for (int j = 0; j < i; j++) { collection.add(rowdef.newEntry(new byte[][]{("def" + j).getBytes(), "xxx".getBytes()})); } collectionIndex.merge(("key-" + i).getBytes(), collection); } collectionIndex.close(); // printout of index kelondroFlexTable index = new kelondroFlexTable(path, filenameStub + ".index", kelondroNaturalOrder.naturalOrder, buffersize, preloadTime, indexRow(9), true); index.print(); index.close(); } catch (IOException e) { e.printStackTrace(); } } }