svn commit: r897700 - in /lucene/mahout/trunk/math/src: main/java-templates/org/apache/mahout/math/map/ test/java-templates/org/apache/mahout/math/map/

[sr...@apache.org]

Author: srowen
Date: Sun Jan 10 20:30:25 2010
New Revision: 897700

URL: http://svn.apache.org/viewvc?rev=897700&view=rev
Log:
MAHOUT-239 -- more files

Added:
    lucene/mahout/trunk/math/src/main/java-templates/org/apache/mahout/math/map/OpenKeyTypeValueTypeHashMap.java.t
    lucene/mahout/trunk/math/src/test/java-templates/org/apache/mahout/math/map/
    lucene/mahout/trunk/math/src/test/java-templates/org/apache/mahout/math/map/OpenKeyTypeValueTypeHashMapTest.java.t

Added: lucene/mahout/trunk/math/src/main/java-templates/org/apache/mahout/math/map/OpenKeyTypeValueTypeHashMap.java.t
URL: http://svn.apache.org/viewvc/lucene/mahout/trunk/math/src/main/java-templates/org/apache/mahout/math/map/OpenKeyTypeValueTypeHashMap.java.t?rev=897700&view=auto
==============================================================================
--- lucene/mahout/trunk/math/src/main/java-templates/org/apache/mahout/math/map/OpenKeyTypeValueTypeHashMap.java.t (added)
+++ lucene/mahout/trunk/math/src/main/java-templates/org/apache/mahout/math/map/OpenKeyTypeValueTypeHashMap.java.t Sun Jan 10 20:30:25 2010
@@ -0,0 +1,607 @@
+/**
+ * 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. See the License for the
+ * specific language governing permissions and limitations
+ * under the License.
+ */
+
+/*
+Copyright � 1999 CERN - European Organization for Nuclear Research.
+Permission to use, copy, modify, distribute and sell this software and its documentation for any purpose 
+is hereby granted without fee, provided that the above copyright notice appear in all copies and 
+that both that copyright notice and this permission notice appear in supporting documentation. 
+CERN makes no representations about the suitability of this software for any purpose. 
+It is provided "as is" without expressed or implied warranty.
+*/
+package org.apache.mahout.math.map;
+
+import java.util.Arrays;
+
+import org.apache.mahout.math.function.${keyTypeCap}${valueTypeCap}Procedure;
+import org.apache.mahout.math.function.${keyTypeCap}Procedure;
+import org.apache.mahout.math.list.${keyTypeCap}ArrayList;
+
+#if (${keyType} != ${valueType})
+import org.apache.mahout.math.list.${valueTypeCap}ArrayList;
+#end
+
+/**
+  * Open hash map from ${keyType} keys to ${valueType} values.
+ **/
+public class Open${keyTypeCap}${valueTypeCap}HashMap extends Abstract${keyTypeCap}${valueTypeCap}Map {
+  protected static final byte FREE = 0;
+  protected static final byte FULL = 1;
+  protected static final byte REMOVED = 2;
+#if (${keyTypeFloating} == 'true')
+#set ($noKeyComment = "${keyTypeCap}.NaN")
+  protected static final ${keyType} NO_KEY_VALUE = ${keyTypeCap}.NaN;
+#else
+#set ($noKeyComment = "0")
+  protected static final ${keyType} NO_KEY_VALUE = 0;
+#end
+
+  /** The hash table keys. */
+  protected ${keyType}[] table;
+
+  /** The hash table values. */
+  protected ${valueType}[] values;
+
+  /** The state of each hash table entry (FREE, FULL, REMOVED). */
+  protected byte[] state;
+
+  /** The number of table entries in state==FREE. */
+  protected int freeEntries;
+
+
+  /** Constructs an empty map with default capacity and default load factors. */
+  public Open${keyTypeCap}${valueTypeCap}HashMap() {
+    this(defaultCapacity);
+  }
+
+  /**
+   * Constructs an empty map with the specified initial capacity and default load factors.
+   *
+   * @param initialCapacity the initial capacity of the map.
+   * @throws IllegalArgumentException if the initial capacity is less than zero.
+   */
+  public Open${keyTypeCap}${valueTypeCap}HashMap(int initialCapacity) {
+    this(initialCapacity, defaultMinLoadFactor, defaultMaxLoadFactor);
+  }
+
+  /**
+   * Constructs an empty map with the specified initial capacity and the specified minimum and maximum load factor.
+   *
+   * @param initialCapacity the initial capacity.
+   * @param minLoadFactor   the minimum load factor.
+   * @param maxLoadFactor   the maximum load factor.
+   * @throws IllegalArgumentException if <tt>initialCapacity < 0 || (minLoadFactor < 0.0 || minLoadFactor >= 1.0) ||
+   *                                  (maxLoadFactor <= 0.0 || maxLoadFactor >= 1.0) || (minLoadFactor >=
+   *                                  maxLoadFactor)</tt>.
+   */
+  public Open${keyTypeCap}${valueTypeCap}HashMap(int initialCapacity, double minLoadFactor, double maxLoadFactor) {
+    setUp(initialCapacity, minLoadFactor, maxLoadFactor);
+  }
+
+  /** Removes all (key,value) associations from the receiver. Implicitly calls <tt>trimToSize()</tt>. */
+  @Override
+  public void clear() {
+    Arrays.fill(this.state, 0, state.length - 1, FREE);
+    distinct = 0;
+    freeEntries = table.length; // delta
+    trimToSize();
+  }
+
+  /**
+   * Returns a deep copy of the receiver.
+   *
+   * @return a deep copy of the receiver.
+   */
+  @Override
+  public Object clone() {
+    Open${keyTypeCap}${valueTypeCap}HashMap copy = (Open${keyTypeCap}${valueTypeCap}HashMap) super.clone();
+    copy.table = copy.table.clone();
+    copy.values = copy.values.clone();
+    copy.state = copy.state.clone();
+    return copy;
+  }
+
+  /**
+   * Returns <tt>true</tt> if the receiver contains the specified key.
+   *
+   * @return <tt>true</tt> if the receiver contains the specified key.
+   */
+  @Override
+  public boolean containsKey(${keyType} key) {
+    return indexOfKey(key) >= 0;
+  }
+
+  /**
+   * Returns <tt>true</tt> if the receiver contains the specified value.
+   *
+   * @return <tt>true</tt> if the receiver contains the specified value.
+   */
+  @Override
+  public boolean containsValue(${valueType} value) {
+    return indexOfValue(value) >= 0;
+  }
+
+  /**
+   * Ensures that the receiver can hold at least the specified number of associations without needing to allocate new
+   * internal memory. If necessary, allocates new internal memory and increases the capacity of the receiver. <p> This
+   * method never need be called; it is for performance tuning only. Calling this method before <tt>put()</tt>ing a
+   * large number of associations boosts performance, because the receiver will grow only once instead of potentially
+   * many times and hash collisions get less probable.
+   *
+   * @param minCapacity the desired minimum capacity.
+   */
+  @Override
+  public void ensureCapacity(int minCapacity) {
+    if (table.length < minCapacity) {
+      int newCapacity = nextPrime(minCapacity);
+      rehash(newCapacity);
+    }
+  }
+
+  /**
+   * Applies a procedure to each key of the receiver, if any. Note: Iterates over the keys in no particular order.
+   * Subclasses can define a particular order, for example, "sorted by key". All methods which <i>can</i> be expressed
+   * in terms of this method (most methods can) <i>must guarantee</i> to use the <i>same</i> order defined by this
+   * method, even if it is no particular order. This is necessary so that, for example, methods <tt>keys</tt> and
+   * <tt>values</tt> will yield association pairs, not two uncorrelated lists.
+   *
+   * @param procedure the procedure to be applied. Stops iteration if the procedure returns <tt>false</tt>, otherwise
+   *                  continues.
+   * @return <tt>false</tt> if the procedure stopped before all keys where iterated over, <tt>true</tt> otherwise.
+   */
+  @Override
+  public boolean forEachKey(${keyTypeCap}Procedure procedure) {
+    for (int i = table.length; i-- > 0;) {
+      if (state[i] == FULL) {
+        if (!procedure.apply(table[i])) {
+          return false;
+        }
+      }
+    }
+    return true;
+  }
+
+  /**
+   * Applies a procedure to each (key,value) pair of the receiver, if any. Iteration order is guaranteed to be
+   * <i>identical</i> to the order used by method {@link #forEachKey(${keyTypeCap}Procedure)}.
+   *
+   * @param procedure the procedure to be applied. Stops iteration if the procedure returns <tt>false</tt>, otherwise
+   *                  continues.
+   * @return <tt>false</tt> if the procedure stopped before all keys where iterated over, <tt>true</tt> otherwise.
+   */
+  @Override
+  public boolean forEachPair(${keyTypeCap}${valueTypeCap}Procedure procedure) {
+    for (int i = table.length; i-- > 0;) {
+      if (state[i] == FULL) {
+        if (!procedure.apply(table[i], values[i])) {
+          return false;
+        }
+      }
+    }
+    return true;
+  }
+
+  /**
+   * Returns the value associated with the specified key. It is often a good idea to first check with {@link
+   * #containsKey(double)} whether the given key has a value associated or not, i.e. whether there exists an association
+   * for the given key or not.
+   *
+   * @param key the key to be searched for.
+   * @return the value associated with the specified key; <tt>0</tt> if no such key is present.
+   */
+  @Override
+  public ${valueType} get(${keyType} key) {
+    int i = indexOfKey(key);
+    if (i < 0) {
+      return 0;
+    } //not contained
+    return values[i];
+  }
+
+  /**
+   * @param key the key to be added to the receiver.
+   * @return the index where the key would need to be inserted, if it is not already contained. Returns -index-1 if the
+   *         key is already contained at slot index. Therefore, if the returned index < 0, then it is already contained
+   *         at slot -index-1. If the returned index >= 0, then it is NOT already contained and should be inserted at
+   *         slot index.
+   */
+  protected int indexOfInsertion(${keyType} key) {
+    ${keyType}[] tab = table;
+    byte[] stat = state;
+    int length = tab.length;
+
+    int hash = HashFunctions.hash(key) & 0x7FFFFFFF;
+    int i = hash % length;
+    int decrement = hash % (length - 2); // double hashing, see http://www.eece.unm.edu/faculty/heileman/hash/node4.html
+    //int decrement = (hash / length) % length;
+    if (decrement == 0) {
+      decrement = 1;
+    }
+
+    // stop if we find a removed or free slot, or if we find the key itself
+    // do NOT skip over removed slots (yes, open addressing is like that...)
+    while (stat[i] == FULL && tab[i] != key) {
+      i -= decrement;
+      //hashCollisions++;
+      if (i < 0) {
+        i += length;
+      }
+    }
+
+    if (stat[i] == REMOVED) {
+      // stop if we find a free slot, or if we find the key itself.
+      // do skip over removed slots (yes, open addressing is like that...)
+      // assertion: there is at least one FREE slot.
+      int j = i;
+      while (stat[i] != FREE && (stat[i] == REMOVED || tab[i] != key)) {
+        i -= decrement;
+        //hashCollisions++;
+        if (i < 0) {
+          i += length;
+        }
+      }
+      if (stat[i] == FREE) {
+        i = j;
+      }
+    }
+
+
+    if (stat[i] == FULL) {
+      // key already contained at slot i.
+      // return a negative number identifying the slot.
+      return -i - 1;
+    }
+    // not already contained, should be inserted at slot i.
+    // return a number >= 0 identifying the slot.
+    return i;
+  }
+
+  /**
+   * @param key the key to be searched in the receiver.
+   * @return the index where the key is contained in the receiver, returns -1 if the key was not found.
+   */
+  protected int indexOfKey(${keyType} key) {
+    ${keyType}[] tab = table;
+    byte[] stat = state;
+    int length = tab.length;
+
+    int hash = HashFunctions.hash(key) & 0x7FFFFFFF;
+    int i = hash % length;
+    int decrement = hash % (length - 2); // double hashing, see http://www.eece.unm.edu/faculty/heileman/hash/node4.html
+    //int decrement = (hash / length) % length;
+    if (decrement == 0) {
+      decrement = 1;
+    }
+
+    // stop if we find a free slot, or if we find the key itself.
+    // do skip over removed slots (yes, open addressing is like that...)
+    while (stat[i] != FREE && (stat[i] == REMOVED || tab[i] != key)) {
+      i -= decrement;
+      //hashCollisions++;
+      if (i < 0) {
+        i += length;
+      }
+    }
+
+    if (stat[i] == FREE) {
+      return -1;
+    } // not found
+    return i; //found, return index where key is contained
+  }
+
+  /**
+   * @param value the value to be searched in the receiver.
+   * @return the index where the value is contained in the receiver, returns -1 if the value was not found.
+   */
+  protected int indexOfValue(${valueType} value) {
+    ${valueType}[] val = values;
+    byte[] stat = state;
+
+    for (int i = stat.length; --i >= 0;) {
+      if (stat[i] == FULL && val[i] == value) {
+        return i;
+      }
+    }
+
+    return -1; // not found
+  }
+
+  /**
+   * Returns the first key the given value is associated with. It is often a good idea to first check with {@link
+   * #containsValue(int)} whether there exists an association from a key to this value. Search order is guaranteed to be
+   * <i>identical</i> to the order used by method {@link #forEachKey(${keyTypeCap}Procedure)}.
+   *
+   * @param value the value to search for.
+   * @return the first key for which holds <tt>get(key) == value</tt>; 
+   * returns <tt>${noKeyComment}</tt> if no such key
+   *         exists.
+   */
+  @Override
+  public ${keyType} keyOf(${valueType} value) {
+    //returns the first key found; there may be more matching keys, however.
+    int i = indexOfValue(value);
+    if (i < 0) {
+      return NO_KEY_VALUE;
+    }
+    return table[i];
+  }
+
+  /**
+   * Fills all keys contained in the receiver into the specified list. Fills the list, starting at index 0. After this
+   * call returns the specified list has a new size that equals <tt>this.size()</tt>. Iteration order is guaranteed to
+   * be <i>identical</i> to the order used by method {@link #forEachKey(${keyTypeCap}Procedure)}.
+   * <p> This method can be used
+   * to iterate over the keys of the receiver.
+   *
+   * @param list the list to be filled, can have any size.
+   */
+  @Override
+  public void keys(${keyTypeCap}ArrayList list) {
+    list.setSize(distinct);
+    ${keyType} [] elements = list.elements();
+
+    ${keyType} [] tab = table;
+    byte[] stat = state;
+
+    int j = 0;
+    for (int i = tab.length; i-- > 0;) {
+      if (stat[i] == FULL) {
+        elements[j++] = tab[i];
+      }
+    }
+  }
+
+  /**
+   * Fills all pairs satisfying a given condition into the specified lists. Fills into the lists, starting at index 0.
+   * After this call returns the specified lists both have a new size, the number of pairs satisfying the condition.
+   * Iteration order is guaranteed to be <i>identical</i> to the order used by method {@link
+   * #forEachKey(${keyTypeCap}Procedure)}. <p> <b>Example:</b> <br>
+   * <pre>
+   * ${keyTypeCap}${valueTypeCap}Procedure condition = new ${keyTypeCap}${valueTypeCap}Procedure() { // match even values only
+   * public boolean apply(${keyType} key, ${valueType} value) { return value%2==0; }
+   * }
+   * keys = (8,7,6), values = (1,2,2) --> keyList = (6,8), valueList = (2,1)</tt>
+   * </pre>
+   *
+   * @param condition the condition to be matched. Takes the current key as first and the current value as second
+   *                  argument.
+   * @param keyList   the list to be filled with keys, can have any size.
+   * @param valueList the list to be filled with values, can have any size.
+   */
+  @Override
+  public void pairsMatching(${keyTypeCap}${valueTypeCap}Procedure condition, 
+                            ${keyTypeCap}ArrayList keyList, 
+                            ${valueTypeCap}ArrayList valueList) {
+    keyList.clear();
+    valueList.clear();
+
+    for (int i = table.length; i-- > 0;) {
+      if (state[i] == FULL && condition.apply(table[i], values[i])) {
+        keyList.add(table[i]);
+        valueList.add(values[i]);
+      }
+    }
+  }
+
+  /**
+   * Associates the given key with the given value. Replaces any old <tt>(key,someOtherValue)</tt> association, if
+   * existing.
+   *
+   * @param key   the key the value shall be associated with.
+   * @param value the value to be associated.
+   * @return <tt>true</tt> if the receiver did not already contain such a key; <tt>false</tt> if the receiver did
+   *         already contain such a key - the new value has now replaced the formerly associated value.
+   */
+  @Override
+  public boolean put(${keyType} key, ${valueType} value) {
+    int i = indexOfInsertion(key);
+    if (i < 0) { //already contained
+      i = -i - 1;
+      this.values[i] = value;
+      return false;
+    }
+
+    if (this.distinct > this.highWaterMark) {
+      int newCapacity = chooseGrowCapacity(this.distinct + 1, this.minLoadFactor, this.maxLoadFactor);
+      /*
+      log.info("grow rehashing ");
+      log.info("at distinct="+distinct+", capacity="+table.length+" to newCapacity="+newCapacity+" ...");
+      */
+      rehash(newCapacity);
+      return put(key, value);
+    }
+
+    this.table[i] = key;
+    this.values[i] = value;
+    if (this.state[i] == FREE) {
+      this.freeEntries--;
+    }
+    this.state[i] = FULL;
+    this.distinct++;
+
+    if (this.freeEntries < 1) { //delta
+      int newCapacity = chooseGrowCapacity(this.distinct + 1, this.minLoadFactor, this.maxLoadFactor);
+      rehash(newCapacity);
+    }
+
+    return true;
+  }
+
+  /**
+   * Rehashes the contents of the receiver into a new table with a smaller or larger capacity. This method is called
+   * automatically when the number of keys in the receiver exceeds the high water mark or falls below the low water
+   * mark.
+   */
+  protected void rehash(int newCapacity) {
+    int oldCapacity = table.length;
+    //if (oldCapacity == newCapacity) return;
+
+    ${keyType}[] oldTable = table;
+    ${valueType}[] oldValues = values;
+    byte[] oldState = state;
+
+    ${keyType}[] newTable = new ${keyType}[newCapacity];
+    ${valueType}[] newValues = new ${valueType}[newCapacity];
+    byte[] newState = new byte[newCapacity];
+
+    this.lowWaterMark = chooseLowWaterMark(newCapacity, this.minLoadFactor);
+    this.highWaterMark = chooseHighWaterMark(newCapacity, this.maxLoadFactor);
+
+    this.table = newTable;
+    this.values = newValues;
+    this.state = newState;
+    this.freeEntries = newCapacity - this.distinct; // delta
+
+    for (int i = oldCapacity; i-- > 0;) {
+      if (oldState[i] == FULL) {
+        ${keyType} element = oldTable[i];
+        int index = indexOfInsertion(element);
+        newTable[index] = element;
+        newValues[index] = oldValues[i];
+        newState[index] = FULL;
+      }
+    }
+  }
+
+  /**
+   * Removes the given key with its associated element from the receiver, if present.
+   *
+   * @param key the key to be removed from the receiver.
+   * @return <tt>true</tt> if the receiver contained the specified key, <tt>false</tt> otherwise.
+   */
+  @Override
+  public boolean removeKey(${keyType} key) {
+    int i = indexOfKey(key);
+    if (i < 0) {
+      return false;
+    } // key not contained
+
+    this.state[i] = REMOVED;
+    //this.values[i]=0; // delta
+    this.distinct--;
+
+    if (this.distinct < this.lowWaterMark) {
+      int newCapacity = chooseShrinkCapacity(this.distinct, this.minLoadFactor, this.maxLoadFactor);
+      /*
+      if (table.length != newCapacity) {
+        log.info("shrink rehashing ");
+        log.info("at distinct="+distinct+", capacity="+table.length+" to newCapacity="+newCapacity+" ...");
+      }
+      */
+      rehash(newCapacity);
+    }
+
+    return true;
+  }
+
+  /**
+   * Initializes the receiver.
+   *
+   * @param initialCapacity the initial capacity of the receiver.
+   * @param minLoadFactor   the minLoadFactor of the receiver.
+   * @param maxLoadFactor   the maxLoadFactor of the receiver.
+   * @throws IllegalArgumentException if <tt>initialCapacity < 0 || (minLoadFactor < 0.0 || minLoadFactor >= 1.0) ||
+   *                                  (maxLoadFactor <= 0.0 || maxLoadFactor >= 1.0) || (minLoadFactor >=
+   *                                  maxLoadFactor)</tt>.
+   */
+  @Override
+  protected void setUp(int initialCapacity, double minLoadFactor, double maxLoadFactor) {
+    int capacity = initialCapacity;
+    super.setUp(capacity, minLoadFactor, maxLoadFactor);
+    capacity = nextPrime(capacity);
+    if (capacity == 0) {
+      capacity = 1;
+    } // open addressing needs at least one FREE slot at any time.
+
+    this.table = new ${keyType}[capacity];
+    this.values = new ${valueType}[capacity];
+    this.state = new byte[capacity];
+
+    // memory will be exhausted long before this pathological case happens, anyway.
+    this.minLoadFactor = minLoadFactor;
+    if (capacity == PrimeFinder.largestPrime) {
+      this.maxLoadFactor = 1.0;
+    } else {
+      this.maxLoadFactor = maxLoadFactor;
+    }
+
+    this.distinct = 0;
+    this.freeEntries = capacity; // delta
+
+    // lowWaterMark will be established upon first expansion.
+    // establishing it now (upon instance construction) would immediately make the table shrink upon first put(...).
+    // After all the idea of an "initialCapacity" implies violating lowWaterMarks when an object is young.
+    // See ensureCapacity(...)
+    this.lowWaterMark = 0;
+    this.highWaterMark = chooseHighWaterMark(capacity, this.maxLoadFactor);
+  }
+
+  /**
+   * Trims the capacity of the receiver to be the receiver's current size. Releases any superfluous internal memory. An
+   * application can use this operation to minimize the storage of the receiver.
+   */
+  @Override
+  public void trimToSize() {
+    // * 1.2 because open addressing's performance exponentially degrades beyond that point
+    // so that even rehashing the table can take very long
+    int newCapacity = nextPrime((int) (1 + 1.2 * size()));
+    if (table.length > newCapacity) {
+      rehash(newCapacity);
+    }
+  }
+
+  /**
+   * Fills all values contained in the receiver into the specified list. Fills the list, starting at index 0. After this
+   * call returns the specified list has a new size that equals <tt>this.size()</tt>. Iteration order is guaranteed to
+   * be <i>identical</i> to the order used by method {@link #forEachKey(${keyTypeCap}Procedure)}. 
+   * <p> This method can be used
+   * to iterate over the values of the receiver.
+   *
+   * @param list the list to be filled, can have any size.
+   */
+  @Override
+  public void values(${valueTypeCap}ArrayList list) {
+    list.setSize(distinct);
+    ${valueType}[] elements = list.elements();
+
+    ${valueType}[] val = values;
+    byte[] stat = state;
+
+    int j = 0;
+    for (int i = stat.length; i-- > 0;) {
+      if (stat[i] == FULL) {
+        elements[j++] = val[i];
+      }
+    }
+  }
+  
+  /**
+   * Access for unit tests.
+   * @param capacity
+   * @param minLoadFactor
+   * @param maxLoadFactor
+   */
+  void getInternalFactors(int[] capacity, 
+      double[] minLoadFactor, 
+      double[] maxLoadFactor) {
+    capacity[0] = table.length;
+    minLoadFactor[0] = this.minLoadFactor;
+    maxLoadFactor[0] = this.maxLoadFactor;
+  }
+}

Added: lucene/mahout/trunk/math/src/test/java-templates/org/apache/mahout/math/map/OpenKeyTypeValueTypeHashMapTest.java.t
URL: http://svn.apache.org/viewvc/lucene/mahout/trunk/math/src/test/java-templates/org/apache/mahout/math/map/OpenKeyTypeValueTypeHashMapTest.java.t?rev=897700&view=auto
==============================================================================
--- lucene/mahout/trunk/math/src/test/java-templates/org/apache/mahout/math/map/OpenKeyTypeValueTypeHashMapTest.java.t (added)
+++ lucene/mahout/trunk/math/src/test/java-templates/org/apache/mahout/math/map/OpenKeyTypeValueTypeHashMapTest.java.t Sun Jan 10 20:30:25 2010
@@ -0,0 +1,383 @@
+/**
+ * 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. See the License for the
+ * specific language governing permissions and limitations
+ * under the License.
+ */
+ 
+#if (${keyTypeFloating} == 'true')
+#set ($keyEpsilon = ", (${keyType})0.000001")
+#else 
+#set ($keyEpsilon = "")
+#end
+#if (${valueTypeFloating} == 'true')
+#set ($valueEpsilon = ", (${valueType})0.000001")
+#else 
+#set ($valueEpsilon = "")
+#end
+  
+ package org.apache.mahout.math.map;
+ 
+import java.util.ArrayList;
+import java.util.Arrays;
+import java.util.Collections;
+import java.util.List;
+
+import org.apache.mahout.math.function.${keyTypeCap}${valueTypeCap}Procedure;
+import org.apache.mahout.math.function.${keyTypeCap}Procedure;
+import org.apache.mahout.math.list.${keyTypeCap}ArrayList;
+#if (${keyType} != ${valueType})
+import org.apache.mahout.math.list.${valueTypeCap}ArrayList;
+#end
+import org.junit.Assert;
+import org.junit.Test;
+
+public class Open${keyTypeCap}${valueTypeCap}HashMapTest extends Assert {
+
+  
+  @Test
+  public void testConstructors() {
+    Open${keyTypeCap}${valueTypeCap}HashMap map = new Open${keyTypeCap}${valueTypeCap}HashMap();
+    int[] capacity = new int[1];
+    double[] minLoadFactor = new double[1];
+    double[] maxLoadFactor = new double[1];
+    
+    map.getInternalFactors(capacity, minLoadFactor, maxLoadFactor);
+    assertEquals(AbstractMap.defaultCapacity, capacity[0]);
+    assertEquals(AbstractMap.defaultMaxLoadFactor, maxLoadFactor[0], 0.001);
+    assertEquals(AbstractMap.defaultMinLoadFactor, minLoadFactor[0], 0.001);
+    int prime = PrimeFinder.nextPrime(907);
+    map = new Open${keyTypeCap}${valueTypeCap}HashMap(prime);
+    
+    map.getInternalFactors(capacity, minLoadFactor, maxLoadFactor);
+    assertEquals(prime, capacity[0]);
+    assertEquals(AbstractMap.defaultMaxLoadFactor, maxLoadFactor[0], 0.001);
+    assertEquals(AbstractMap.defaultMinLoadFactor, minLoadFactor[0], 0.001);
+    
+    map = new Open${keyTypeCap}${valueTypeCap}HashMap(prime, 0.4, 0.8);
+    map.getInternalFactors(capacity, minLoadFactor, maxLoadFactor);
+    assertEquals(prime, capacity[0]);
+    assertEquals(0.4, minLoadFactor[0], 0.001);
+    assertEquals(0.8, maxLoadFactor[0], 0.001);
+  }
+  
+  @Test
+  public void testEnsureCapacity() {
+    Open${keyTypeCap}${valueTypeCap}HashMap map = new Open${keyTypeCap}${valueTypeCap}HashMap();
+    int prime = PrimeFinder.nextPrime(907);
+    
+    map.ensureCapacity(prime);
+    int[] capacity = new int[1];
+    double[] minLoadFactor = new double[1];
+    double[] maxLoadFactor = new double[1];
+    
+    map.getInternalFactors(capacity, minLoadFactor, maxLoadFactor);
+    assertEquals(prime, capacity[0]);
+  }
+  
+  @Test
+  public void testClear() {
+    Open${keyTypeCap}${valueTypeCap}HashMap map = new Open${keyTypeCap}${valueTypeCap}HashMap();
+    map.put((${keyType}) 11, (${valueType}) 22);
+    assertEquals(1, map.size());
+    map.clear();
+    assertEquals(0, map.size());
+    assertEquals(0, map.get((${keyType}) 11), 0.0000001);
+  }
+  
+  @Test
+  public void testClone() {
+    Open${keyTypeCap}${valueTypeCap}HashMap map = new Open${keyTypeCap}${valueTypeCap}HashMap();
+    map.put((${keyType}) 11, (${valueType}) 22);
+    Open${keyTypeCap}${valueTypeCap}HashMap map2 = (Open${keyTypeCap}${valueTypeCap}HashMap) map.clone();
+    map.clear();
+    assertEquals(1, map2.size());
+  }
+  
+  @Test
+  public void testContainsKey() {
+    Open${keyTypeCap}${valueTypeCap}HashMap map = new Open${keyTypeCap}${valueTypeCap}HashMap();
+    map.put(($keyType) 11, (${valueType}) 22);
+    assertTrue(map.containsKey(($keyType) 11));
+    assertFalse(map.containsKey(($keyType) 12));
+  }
+  
+  @Test
+  public void testContainValue() {
+    Open${keyTypeCap}${valueTypeCap}HashMap map = new Open${keyTypeCap}${valueTypeCap}HashMap();
+    map.put(($keyType) 11, (${valueType}) 22);
+    assertTrue(map.containsValue((${valueType}) 22));
+    assertFalse(map.containsValue((${valueType}) 23));
+  }
+  
+  @Test
+  public void testForEachKey() {
+    final ${keyTypeCap}ArrayList keys = new ${keyTypeCap}ArrayList();
+    Open${keyTypeCap}${valueTypeCap}HashMap map = new Open${keyTypeCap}${valueTypeCap}HashMap();
+    map.put(($keyType) 11, (${valueType}) 22);
+    map.put(($keyType) 12, (${valueType}) 23);
+    map.put(($keyType) 13, (${valueType}) 24);
+    map.put(($keyType) 14, (${valueType}) 25);
+    map.removeKey(($keyType) 13);
+    map.forEachKey(new ${keyTypeCap}Procedure() {
+      
+      @Override
+      public boolean apply(${keyType} element) {
+        keys.add(element);
+        return true;
+      }
+    });
+    
+    ${keyType}[] keysArray = keys.toArray(new ${keyType}[keys.size()]);
+    Arrays.sort(keysArray);
+    
+    assertArrayEquals(new ${keyType}[] {11, 12, 14}, keysArray ${keyEpsilon});
+  }
+  
+  private static class Pair implements Comparable<Pair> {
+    ${keyType} k;
+    ${valueType} v;
+    
+    Pair(${keyType} k, ${valueType} v) {
+      this.k = k;
+      this.v = v;
+    }
+    
+    @Override
+    public int compareTo(Pair o) {
+      if (k < o.k) {
+        return -1;
+      } else if (k == o.k) {
+        return 0;
+      } else {
+        return 1;
+      }
+    }
+  }
+  
+  @Test
+  public void testForEachPair() {
+    final List<Pair> pairs = new ArrayList<Pair>();
+    Open${keyTypeCap}${valueTypeCap}HashMap map = new Open${keyTypeCap}${valueTypeCap}HashMap();
+    map.put(($keyType) 11, (${valueType}) 22);
+    map.put(($keyType) 12, (${valueType}) 23);
+    map.put(($keyType) 13, (${valueType}) 24);
+    map.put(($keyType) 14, (${valueType}) 25);
+    map.removeKey(($keyType) 13);
+    map.forEachPair(new ${keyTypeCap}${valueTypeCap}Procedure() {
+      
+      @Override
+      public boolean apply(${keyType} first, ${valueType} second) {
+        pairs.add(new Pair(first, second));
+        return true;
+      }
+    });
+    
+    Collections.sort(pairs);
+    assertEquals(3, pairs.size());
+    assertEquals(($keyType) 11, pairs.get(0).k ${keyEpsilon});
+    assertEquals((${valueType}) 22, pairs.get(0).v ${valueEpsilon});
+    assertEquals(($keyType) 12, pairs.get(1).k ${keyEpsilon});
+    assertEquals((${valueType}) 23, pairs.get(1).v ${valueEpsilon});
+    assertEquals(($keyType) 14, pairs.get(2).k ${keyEpsilon});
+    assertEquals((${valueType}) 25, pairs.get(2).v ${valueEpsilon});
+    
+    pairs.clear();
+    map.forEachPair(new ${keyTypeCap}${valueTypeCap}Procedure() {
+      int count = 0;
+      
+      @Override
+      public boolean apply(${keyType} first, ${valueType} second) {
+        pairs.add(new Pair(first, second));
+        count++;
+        return count < 2;
+      }
+    });
+    
+    assertEquals(2, pairs.size());
+  }
+  
+  @Test
+  public void testGet() {
+    Open${keyTypeCap}${valueTypeCap}HashMap map = new Open${keyTypeCap}${valueTypeCap}HashMap();
+    map.put(($keyType) 11, (${valueType}) 22);
+    map.put(($keyType) 12, (${valueType}) 23);
+    assertEquals(22, map.get(($keyType)11) ${valueEpsilon});
+    assertEquals(0, map.get(($keyType)0) ${valueEpsilon});
+  }
+
+  /*
+   * Note that the javadoc says 'first' but the order
+   * is not defined.
+   */
+  @Test
+  public void testKeyOf() {
+    Open${keyTypeCap}${valueTypeCap}HashMap map = new Open${keyTypeCap}${valueTypeCap}HashMap();
+    map.put(($keyType) 11, (${valueType}) 22);
+    map.put(($keyType) 12, (${valueType}) 22);
+    ${keyType} k = map.keyOf((${valueType})22);
+    assertTrue(k == 11 || k == 12);
+    k = map.keyOf((${valueType})101);
+#if (${keyTypeFloating} == 'true')
+    assertTrue(${keyTypeCap}.isNaN(k));
+#else
+    assertEquals(0, k ${keyEpsilon});
+#end
+  }
+  
+  @Test
+  public void testKeys() {
+    Open${keyTypeCap}${valueTypeCap}HashMap map = new Open${keyTypeCap}${valueTypeCap}HashMap();
+    map.put(($keyType) 11, (${valueType}) 22);
+    map.put(($keyType) 12, (${valueType}) 22);
+    ${keyTypeCap}ArrayList keys = new ${keyTypeCap}ArrayList();
+    map.keys(keys);
+    keys.sort();
+    assertEquals(11, keys.get(0) ${keyEpsilon});
+    assertEquals(12, keys.get(1) ${keyEpsilon});
+    ${keyTypeCap}ArrayList k2 = map.keys();
+    k2.sort();
+    assertEquals(keys, k2);
+  }
+  
+  @Test
+  public void testPairsMatching() {
+    ${keyTypeCap}ArrayList keyList = new ${keyTypeCap}ArrayList();
+    ${valueTypeCap}ArrayList valueList = new ${valueTypeCap}ArrayList();
+    Open${keyTypeCap}${valueTypeCap}HashMap map = new Open${keyTypeCap}${valueTypeCap}HashMap();
+    map.put(($keyType) 11, (${valueType}) 22);
+    map.put(($keyType) 12, (${valueType}) 23);
+    map.put(($keyType) 13, (${valueType}) 24);
+    map.put(($keyType) 14, (${valueType}) 25);
+    map.removeKey(($keyType) 13);
+    map.pairsMatching(new ${keyTypeCap}${valueTypeCap}Procedure() {
+
+      @Override
+      public boolean apply(${keyType} first, ${valueType} second) {
+        return (first % 2) == 0;
+      }},
+        keyList, valueList);
+    keyList.sort();
+    valueList.sort();
+    assertEquals(2, keyList.size());
+    assertEquals(2, valueList.size());
+    assertEquals(12, keyList.get(0) ${keyEpsilon});
+    assertEquals(14, keyList.get(1) ${keyEpsilon});
+    assertEquals(23, valueList.get(0) ${valueEpsilon});
+    assertEquals(25, valueList.get(1) ${valueEpsilon});
+  }
+  
+  @Test
+  public void testValues() {
+    Open${keyTypeCap}${valueTypeCap}HashMap map = new Open${keyTypeCap}${valueTypeCap}HashMap();
+    map.put(($keyType) 11, (${valueType}) 22);
+    map.put(($keyType) 12, (${valueType}) 23);
+    map.put(($keyType) 13, (${valueType}) 24);
+    map.put(($keyType) 14, (${valueType}) 25);
+    map.removeKey(($keyType) 13);
+    ${valueTypeCap}ArrayList values = new ${valueTypeCap}ArrayList(100);
+    map.values(values);
+    assertEquals(3, values.size());
+    values.sort();
+    assertEquals(22, values.get(0) ${valueEpsilon});
+    assertEquals(23, values.get(1) ${valueEpsilon});
+    assertEquals(25, values.get(2) ${valueEpsilon});
+  }
+  
+  // tests of the code in the abstract class
+  
+  @Test
+  public void testCopy() {
+    Open${keyTypeCap}${valueTypeCap}HashMap map = new Open${keyTypeCap}${valueTypeCap}HashMap();
+    map.put(($keyType) 11, (${valueType}) 22);
+    Open${keyTypeCap}${valueTypeCap}HashMap map2 = (Open${keyTypeCap}${valueTypeCap}HashMap) map.copy();
+    map.clear();
+    assertEquals(1, map2.size());
+  }
+  
+  @Test
+  public void testEquals() {
+    // since there are no other subclasses of 
+    // Abstractxxx available, we have to just test the
+    // obvious.
+    Open${keyTypeCap}${valueTypeCap}HashMap map = new Open${keyTypeCap}${valueTypeCap}HashMap();
+    map.put(($keyType) 11, (${valueType}) 22);
+    map.put(($keyType) 12, (${valueType}) 23);
+    map.put(($keyType) 13, (${valueType}) 24);
+    map.put(($keyType) 14, (${valueType}) 25);
+    map.removeKey(($keyType) 13);
+    Open${keyTypeCap}${valueTypeCap}HashMap map2 = (Open${keyTypeCap}${valueTypeCap}HashMap) map.copy();
+    assertTrue(map.equals(map2));
+    assertTrue(map2.equals(map));
+    assertFalse("Hello Sailor".equals(map));
+    assertFalse(map.equals("hello sailor"));
+    map2.removeKey(($keyType) 11);
+    assertFalse(map.equals(map2));
+    assertFalse(map2.equals(map));
+  }
+  
+  // keys() tested in testKeys
+  
+  @Test
+  public void testKeysSortedByValue() {
+    Open${keyTypeCap}${valueTypeCap}HashMap map = new Open${keyTypeCap}${valueTypeCap}HashMap();
+    map.put(($keyType) 11, (${valueType}) 22);
+    map.put(($keyType) 12, (${valueType}) 23);
+    map.put(($keyType) 13, (${valueType}) 24);
+    map.put(($keyType) 14, (${valueType}) 25);
+    map.removeKey(($keyType) 13);
+    ${keyTypeCap}ArrayList keys = new ${keyTypeCap}ArrayList();
+    map.keysSortedByValue(keys);
+    ${keyType}[] keysArray = keys.toArray(new ${keyType}[keys.size()]);
+    assertArrayEquals(new ${keyType}[] {11, 12, 14},
+        keysArray ${keyEpsilon});
+  }
+  
+  @Test
+  public void testPairsSortedByKey() {
+    Open${keyTypeCap}${valueTypeCap}HashMap map = new Open${keyTypeCap}${valueTypeCap}HashMap();
+    map.put(($keyType) 11, (${valueType}) 100);
+    map.put(($keyType) 12, (${valueType}) 70);
+    map.put(($keyType) 13, (${valueType}) 30);
+    map.put(($keyType) 14, (${valueType}) 3);
+    
+    ${keyTypeCap}ArrayList keys = new ${keyTypeCap}ArrayList();
+    ${valueTypeCap}ArrayList values = new ${valueTypeCap}ArrayList();
+    map.pairsSortedByKey(keys, values);
+    
+    assertEquals(4, keys.size());
+    assertEquals(4, values.size());
+    assertEquals(($keyType) 11, keys.get(0) ${keyEpsilon});
+    assertEquals((${valueType}) 100, values.get(0) ${valueEpsilon});
+    assertEquals(($keyType) 12, keys.get(1) ${keyEpsilon});
+    assertEquals((${valueType}) 70, values.get(1) ${valueEpsilon});
+    assertEquals(($keyType) 13, keys.get(2) ${keyEpsilon});
+    assertEquals((${valueType}) 30, values.get(2) ${valueEpsilon});
+    assertEquals(($keyType) 14, keys.get(3) ${keyEpsilon});
+    assertEquals((${valueType}) 3, values.get(3) ${valueEpsilon});
+    keys.clear();
+    values.clear();
+    map.pairsSortedByValue(keys, values);
+    assertEquals(($keyType) 11, keys.get(3) ${keyEpsilon});
+    assertEquals((${valueType}) 100, values.get(3) ${valueEpsilon});
+    assertEquals(($keyType) 12, keys.get(2) ${keyEpsilon});
+    assertEquals((${valueType}) 70, values.get(2) ${valueEpsilon});
+    assertEquals(($keyType) 13, keys.get(1) ${keyEpsilon});
+    assertEquals((${valueType}) 30, values.get(1) ${valueEpsilon});
+    assertEquals(($keyType) 14, keys.get(0) ${keyEpsilon});
+    assertEquals(($valueType) 3, values.get(0) ${valueEpsilon});
+  }
+ 
+ }