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High Performance Primitive Collections Realtime
(fork of HPPC of Carrotsearch)
Fundamental data structures (maps, sets, lists, stacks, queues, heaps, sorts) generated for
combinations of object and primitive types to conserve JVM memory and speed
up execution. The Realtime fork intend of extending collections while tweaking and optimizations to remove any dynamic allocations at runtime,
and low variance execution times.
package com.carrotsearch.hppcrt.maps;
import com.carrotsearch.hppcrt.*;
import com.carrotsearch.hppcrt.cursors.*;
import com.carrotsearch.hppcrt.predicates.*;
import com.carrotsearch.hppcrt.procedures.*;
import com.carrotsearch.hppcrt.strategies.*;
import com.carrotsearch.hppcrt.hash.*;
//If RH is defined, RobinHood Hashing is in effect :
/**
* A hash map of long to VType, implemented using open
* addressing with linear probing for collision resolution.
*
* The difference with {@link LongObjectOpenHashMap} is that it uses a
* {@link LongHashingStrategy} to compare objects externally instead of using
* the built-in hashCode() / equals(). In particular, the management of null
* keys is up to the {@link LongHashingStrategy} implementation.
* The internal buffers of this implementation ({@link #keys}, {@link #values})
* are always allocated to the nearest size that is a power of two. When
* the capacity exceeds the given load factor, the buffer size is doubled.
*
* Important note. The implementation uses power-of-two tables and linear
* probing, which may cause poor performance (many collisions) if hash values are
* not properly distributed. Therefore, it is up to the {@link LongHashingStrategy} to
* assure good performance.
*
* This implementation supports null values.
*
* @author This code is inspired by the collaboration and implementation in the fastutil project.
*
* Robin-Hood hashing algorithm is also used to minimize variance
* in insertion and search-related operations, for an all-around smother operation at the cost
* of smaller peak performance:
* - Pedro Celis (1986) for the original Robin-Hood hashing paper,
* - MoonPolySoft/Cliff Moon for the initial Robin-hood on HPPC implementation,
* - Vincent Sonnier for the present implementation using cached hashes.
*
*/
@javax.annotation.Generated(date = "2015-02-27T19:21:08+0100", value = "HPPC-RT generated from: LongObjectOpenCustomHashMap.java")
public class LongObjectOpenCustomHashMap
implements LongObjectMap, Cloneable
{
/**
* Minimum capacity for the map.
*/
public final static int MIN_CAPACITY = HashContainerUtils.MIN_CAPACITY;
/**
* Default capacity.
*/
public final static int DEFAULT_CAPACITY = HashContainerUtils.DEFAULT_CAPACITY;
/**
* Default load factor.
*/
public final static float DEFAULT_LOAD_FACTOR = HashContainerUtils.DEFAULT_LOAD_FACTOR;
protected VType defaultValue = (null);
/**
* Hash-indexed array holding all keys.
*
* Direct map iteration: iterate {keys[i], values[i]} for i in [0; keys.length[ where keys[i] != 0/null, then also
* {0/null, {@link #allocatedDefaultKeyValue} } is in the map if {@link #allocatedDefaultKey} = true.
*
*
* Direct iteration warning:
* If the iteration goal is to fill another hash container, please iterate {@link #keys} in reverse to prevent performance losses.
* @see #values
*/
public long[] keys;
/**
* Hash-indexed array holding all values associated to the keys.
* stored in {@link #keys}.
*
* @see #keys
*/
public VType[] values;
/**
* * Caches the hash value = HASH(keys[i]) & mask, if keys[i] != 0/null,
* for every index i.
* * @see #assigned
*/
protected int[] hash_cache;
/**
*True if key = 0/null is in the map.
*/
public boolean allocatedDefaultKey = false;
/**
* if allocatedDefaultKey = true, contains the associated V to the key = 0/null
*/
public VType allocatedDefaultKeyValue;
/**
* Cached number of assigned slots in {@link #keys}.
*/
protected int assigned;
/**
* The load factor for this map (fraction of allocated slots
* before the buffers must be rehashed or reallocated).
*/
protected final float loadFactor;
/**
* Resize buffers when {@link #keys} hits this value.
*/
protected int resizeAt;
/**
* The most recent slot accessed in {@link #containsKey} (required for
* {@link #lget}).
*
* @see #containsKey
* @see #lget
*/
protected int lastSlot;
/**
* Custom hashing strategy :
* comparisons and hash codes of keys will be computed
* with the strategy methods instead of the native Object equals() and hashCode() methods.
*/
protected final LongHashingStrategy hashStrategy;
/**
* Creates a hash map with the default capacity of {@value #DEFAULT_CAPACITY},
* load factor of {@value #DEFAULT_LOAD_FACTOR}, using the hashStrategy as {@link LongHashingStrategy}
*
*
See class notes about hash distribution importance.
*/
public LongObjectOpenCustomHashMap(final LongHashingStrategy hashStrategy)
{
this(LongObjectOpenCustomHashMap.DEFAULT_CAPACITY, hashStrategy);
}
/**
* Creates a hash map with the given initial capacity, default load factor of
* {@value #DEFAULT_LOAD_FACTOR}, using the hashStrategy as {@link LongHashingStrategy}
*
* @param initialCapacity Initial capacity (greater than zero and automatically
* rounded to the next power of two).
*/
public LongObjectOpenCustomHashMap(final int initialCapacity, final LongHashingStrategy hashStrategy)
{
this(initialCapacity, LongObjectOpenCustomHashMap.DEFAULT_LOAD_FACTOR, hashStrategy);
}
/**
* Creates a hash map with the given initial capacity,
* load factor, using the hashStrategy as {@link LongHashingStrategy}
*
* @param initialCapacity Initial capacity (greater than zero and automatically
* rounded to the next power of two).
*
* @param loadFactor The load factor (greater than zero and smaller than 1).
*
*
*/
public LongObjectOpenCustomHashMap(final int initialCapacity, final float loadFactor, final LongHashingStrategy hashStrategy)
{
//only accept not-null strategies.
if (hashStrategy != null)
{
this.hashStrategy = hashStrategy;
}
else {
throw new IllegalArgumentException("LongObjectOpenCustomHashMap() cannot have a null hashStrategy !");
}
assert loadFactor > 0 && loadFactor <= 1 : "Load factor must be between (0, 1].";
this.loadFactor = loadFactor;
//take into account of the load factor to garantee no reallocations before reaching initialCapacity.
int internalCapacity = (int) (initialCapacity / loadFactor) + LongObjectOpenCustomHashMap.MIN_CAPACITY;
//align on next power of two
internalCapacity = HashContainerUtils.roundCapacity(internalCapacity);
this.keys = (new long[internalCapacity]);
this.values = (Internals.newArray(internalCapacity));
this.hash_cache = new int[internalCapacity];
//Take advantage of the rounding so that the resize occur a bit later than expected.
//allocate so that there is at least one slot that remains allocated = false
//this is compulsory to guarantee proper stop in searching loops
this.resizeAt = Math.max(3, (int) (internalCapacity * loadFactor)) - 2;
}
/**
* Create a hash map from all key-value pairs of another container.
*/
public LongObjectOpenCustomHashMap(final LongObjectAssociativeContainer container, final LongHashingStrategy hashStrategy)
{
this(container.size(), hashStrategy);
putAll(container);
}
/**
* {@inheritDoc}
*/
@Override
public VType put(long key, VType value)
{
if (key == (0L)) {
if (this.allocatedDefaultKey) {
final VType previousValue = this.allocatedDefaultKeyValue;
this.allocatedDefaultKeyValue = value;
return previousValue;
}
this.allocatedDefaultKeyValue = value;
this.allocatedDefaultKey = true;
return this.defaultValue;
}
final int mask = this.keys.length - 1;
final LongHashingStrategy strategy = this.hashStrategy;
final long[] keys = this.keys;
final VType[] values = this.values;
//copied straight from fastutil "fast-path"
int slot;
long curr;
//1.1 The rehashed key slot is occupied...
if ((curr = keys[slot = PhiMix.hash(strategy.computeHashCode(key)) & mask]) != (0L)) {
//1.2 the occupied place is indeed key, so only updates the value and nothing else.
if (strategy.equals(curr, key)) {
final VType oldValue = this.values[slot];
values[slot] = value;
return oldValue;
}
//1.3 key is colliding, manage below :
}
else if (this.assigned < this.resizeAt) {
//1.4 key is not colliding, without resize, so insert, return defaultValue.
keys[slot] = key;
values[slot] = value;
this.assigned++;
this.hash_cache[slot] = slot;
return this.defaultValue;
}
final int[] cached = this.hash_cache;
long tmpKey;
VType tmpValue;
int tmpAllocated;
int initial_slot = slot;
int dist = 0;
int existing_distance = 0;
//2. Slow path, find a place somewhere down there...
while ((keys[slot] != (0L)))
{
if (strategy.equals(key, keys[slot]))
{
final VType oldValue = values[slot];
values[slot] = value;
return oldValue;
}
//re-shuffle keys to minimize variance
existing_distance = (slot < cached[slot] ? slot + cached.length - cached[slot] : slot - cached[slot]);
if (dist > existing_distance)
{
//swap current (key, value, initial_slot) with slot places
tmpKey = keys[slot];
keys[slot] = key;
key = tmpKey;
tmpAllocated = cached[slot];
cached[slot] = initial_slot;
initial_slot = tmpAllocated;
tmpValue = values[slot];
values[slot] = value;
value = tmpValue;
dist = existing_distance;
}
slot = (slot + 1) & mask;
dist++;
}
// Check if we need to grow. If so, reallocate new data, fill in the last element
// and rehash.
if (this.assigned == this.resizeAt)
{
expandAndPut(key, value, slot);
}
else
{
this.assigned++;
cached[slot] = initial_slot;
keys[slot] = key;
values[slot] = value;
}
return this.defaultValue;
}
/**
* {@inheritDoc}
*/
@Override
public int putAll(final LongObjectAssociativeContainer container)
{
return putAll((Iterable>) container);
}
/**
* {@inheritDoc}
*/
@Override
public int putAll(final Iterable> iterable)
{
final int count = this.size();
for (final LongObjectCursor c : iterable)
{
put(c.key, c.value);
}
return this.size() - count;
}
/**
* {@inheritDoc}
*/
@Override
public boolean putIfAbsent(final long key, final VType value)
{
if (!containsKey(key))
{
put(key, value);
return true;
}
return false;
}
/**
* Expand the internal storage buffers (capacity) and rehash.
*/
private void expandAndPut(final long pendingKey, final VType pendingValue, final int freeSlot)
{
assert this.assigned == this.resizeAt;
//default sentinel value is never in the keys[] array, so never trigger reallocs
assert pendingKey != (0L);
// Try to allocate new buffers first. If we OOM, it'll be now without
// leaving the data structure in an inconsistent state.
final long[] oldKeys = this.keys;
final VType[] oldValues = this.values;
allocateBuffers(HashContainerUtils.nextCapacity(this.keys.length));
// We have succeeded at allocating new data so insert the pending key/value at
// the free slot in the old arrays before rehashing.
this.lastSlot = -1;
this.assigned++;
oldKeys[freeSlot] = pendingKey;
oldValues[freeSlot] = pendingValue;
//for inserts
final int mask = this.keys.length - 1;
final LongHashingStrategy strategy = this.hashStrategy;
long key = (0L);
VType value = (null);
int slot = -1;
final long[] keys = this.keys;
final VType[] values = this.values;
final int[] cached = this.hash_cache;
long tmpKey = (0L);
VType tmpValue = (null);
int tmpAllocated = -1;
int initial_slot = -1;
int dist = -1;
int existing_distance = -1;
//iterate all the old arrays to add in the newly allocated buffers
//It is important to iterate backwards to minimize the conflict chain length !
for (int i = oldKeys.length; --i >= 0;)
{
if ((oldKeys[i] != (0L)))
{
key = oldKeys[i];
value = oldValues[i];
slot = PhiMix.hash(strategy.computeHashCode(key)) & mask;
initial_slot = slot;
dist = 0;
while ((keys[slot] != (0L)))
{
//re-shuffle keys to minimize variance
existing_distance = (slot < cached[slot] ? slot + cached.length - cached[slot] : slot - cached[slot]);
if (dist > existing_distance)
{
//swap current (key, value, initial_slot) with slot places
tmpKey = keys[slot];
keys[slot] = key;
key = tmpKey;
tmpAllocated = cached[slot];
cached[slot] = initial_slot;
initial_slot = tmpAllocated;
tmpValue = values[slot];
values[slot] = value;
value = tmpValue;
dist = existing_distance;
}
slot = (slot + 1) & mask;
dist++;
} //end while
cached[slot] = initial_slot;
keys[slot] = key;
values[slot] = value;
}
}
}
/**
* Allocate internal buffers for a given capacity.
*
* @param capacity New capacity (must be a power of two).
*/
private void allocateBuffers(final int capacity)
{
final long[] keys = (new long[capacity]);
final VType[] values = (Internals.newArray(capacity));
final int[] cached = new int[capacity];
this.keys = keys;
this.values = values;
this.hash_cache = cached;
//allocate so that there is at least one slot that remains allocated = false
//this is compulsory to guarantee proper stop in searching loops
this.resizeAt = Math.max(3, (int) (capacity * this.loadFactor)) - 2;
}
/**
* {@inheritDoc}
*/
@Override
public VType remove(final long key)
{
if (key == (0L)) {
if (this.allocatedDefaultKey) {
final VType previousValue = this.allocatedDefaultKeyValue;
//help the GC
this.allocatedDefaultKeyValue = (null);
this.allocatedDefaultKey = false;
return previousValue;
}
return this.defaultValue;
}
final int mask = this.keys.length - 1;
final long[] keys = this.keys;
final VType[] values = this.values;
final LongHashingStrategy strategy = this.hashStrategy;
//copied straight from fastutil "fast-path"
int slot;
long curr;
//1.1 The rehashed slot is free, nothing to remove, return default value
if ((curr = keys[slot = PhiMix.hash(strategy.computeHashCode(key)) & mask]) == (0L)) {
return this.defaultValue;
}
//1.2) The rehashed entry is occupied by the key, remove it, return value
if (strategy.equals(curr, key)) {
final VType value = values[slot];
this.assigned--;
shiftConflictingKeys(slot);
return value;
}
//2. Hash collision, search for the key along the path
slot = (slot + 1) & mask;
int dist = 0;
final int[] cached = this.hash_cache;
//2. Slow path here
while ((keys[slot] != (0L))
&& dist <= (slot < cached[slot] ? slot + cached.length - cached[slot] : slot - cached[slot]) )
{
if (strategy.equals(key, keys[slot]))
{
final VType value = values[slot];
this.assigned--;
shiftConflictingKeys(slot);
return value;
}
slot = (slot + 1) & mask;
dist++;
} //end while true
return this.defaultValue;
}
/**
* Shift all the slot-conflicting keys allocated to (and including) slot.
*/
protected void shiftConflictingKeys(int slotCurr)
{
// Copied nearly verbatim from fastutil's impl.
final int mask = this.keys.length - 1;
int slotPrev, slotOther;
final LongHashingStrategy strategy = this.hashStrategy;
final long[] keys = this.keys;
final VType[] values = this.values;
final int[] cached = this.hash_cache;
while (true)
{
slotCurr = ((slotPrev = slotCurr) + 1) & mask;
while ((keys[slotCurr] != (0L)))
{
//use the cached value, no need to recompute
slotOther = cached[slotCurr];
if (slotPrev <= slotCurr)
{
// we're on the right of the original slot.
if (slotPrev >= slotOther || slotOther > slotCurr)
{
break;
}
}
else
{
// we've wrapped around.
if (slotPrev >= slotOther && slotOther > slotCurr)
{
break;
}
}
slotCurr = (slotCurr + 1) & mask;
}
if (!(keys[slotCurr] != (0L)))
{
break;
}
// Shift key/value/allocated triplet.
keys[slotPrev] = keys[slotCurr];
values[slotPrev] = values[slotCurr];
cached[slotPrev] = cached[slotCurr];
}
//means not allocated
keys[slotPrev] = (0L);
/* */
values[slotPrev] = (null);
/* */
}
/**
* {@inheritDoc}
*/
@Override
public int removeAll(final LongContainer container)
{
final int before = this.size();
for (final LongCursor cursor : container)
{
remove(cursor.value);
}
return before - this.size();
}
/**
* {@inheritDoc}
* Important!
* If the predicate actually injects the removed keys in another hash container, you may experience performance losses.
*/
@Override
public int removeAll(final LongPredicate predicate)
{
final int before = this.size();
if (this.allocatedDefaultKey) {
if (predicate.apply((0L)))
{
this.allocatedDefaultKey = false;
}
}
final long[] keys = this.keys;
for (int i = 0; i < keys.length;)
{
if ((keys[i] != (0L)))
{
if (predicate.apply(keys[i]))
{
this.assigned--;
shiftConflictingKeys(i);
// Repeat the check for the same i.
continue;
}
}
i++;
}
return before - this.size();
}
/**
* {@inheritDoc}
*
*
Use the following snippet of code to check for key existence
* first and then retrieve the value if it exists.
*
* if (map.containsKey(key))
* value = map.lget();
*
*/
@Override
public VType get(final long key)
{
if (key == (0L)) {
if (this.allocatedDefaultKey) {
return this.allocatedDefaultKeyValue;
}
return this.defaultValue;
}
final int mask = this.keys.length - 1;
final LongHashingStrategy strategy = this.hashStrategy;
final long[] keys = this.keys;
final VType[] values = this.values;
//copied straight from fastutil "fast-path"
int slot;
long curr;
//1.1 The rehashed slot is free, nothing to get, return default value
if ((curr = keys[slot = PhiMix.hash(strategy.computeHashCode(key)) & mask]) == (0L)) {
return this.defaultValue;
}
//1.2) The rehashed entry is occupied by the key, return value
if (strategy.equals(curr, key)) {
return values[slot];
}
//2. Hash collision, search for the key along the path
slot = (slot + 1) & mask;
int dist = 0;
final int[] cached = this.hash_cache;
while ((keys[slot] != (0L))
&& dist <= (slot < cached[slot] ? slot + cached.length - cached[slot] : slot - cached[slot]) )
{
if (strategy.equals(key, keys[slot]))
{
return values[slot];
}
slot = (slot + 1) & mask;
dist++;
} //end while true
return this.defaultValue;
}
/**
* Returns the last key stored in this has map for the corresponding
* most recent call to {@link #containsKey}.
* Precondition : {@link #containsKey} must have been called previously !
* Use the following snippet of code to check for key existence
* first and then retrieve the key value if it exists.
*
* if (map.containsKey(key))
* value = map.lkey();
*
*
* This is equivalent to calling:
*
* if (map.containsKey(key))
* key = map.keys[map.lslot()];
*
*/
public long lkey()
{
if (this.lastSlot == -2) {
return (0L);
}
assert this.lastSlot >= 0 : "Call containsKey() first.";
assert (this.keys[this.lastSlot] != (0L)) : "Last call to exists did not have any associated value.";
return this.keys[this.lastSlot];
}
/**
* Returns the last value saved in a call to {@link #containsKey}.
* Precondition : {@link #containsKey} must have been called previously !
* @see #containsKey
*/
public VType lget()
{
if (this.lastSlot == -2) {
return this.allocatedDefaultKeyValue;
}
assert this.lastSlot >= 0 : "Call containsKey() first.";
assert (this.keys[this.lastSlot] != (0L)) : "Last call to exists did not have any associated value.";
return this.values[this.lastSlot];
}
/**
* Sets the value corresponding to the key saved in the last
* call to {@link #containsKey}, if and only if the key exists
* in the map already.
* Precondition : {@link #containsKey} must have been called previously !
* @see #containsKey
* @return Returns the previous value stored under the given key.
*/
public VType lset(final VType value)
{
if (this.lastSlot == -2) {
final VType previous = this.allocatedDefaultKeyValue;
this.allocatedDefaultKeyValue = value;
return previous;
}
assert this.lastSlot >= 0 : "Call containsKey() first.";
assert (this.keys[this.lastSlot] != (0L)) : "Last call to exists did not have any associated value.";
final VType previous = this.values[this.lastSlot];
this.values[this.lastSlot] = value;
return previous;
}
/**
* @return Returns the slot of the last key looked up in a call to {@link #containsKey} if
* it returned true
* or else -2 if {@link #containsKey} were successful on key = 0
* @see #containsKey
*/
public int lslot()
{
assert this.lastSlot >= 0 || this.lastSlot == -2 : "Call containsKey() first.";
return this.lastSlot;
}
/**
* {@inheritDoc}
*
* Saves the associated value for fast access using {@link #lget}
* or {@link #lset}.
*
* if (map.containsKey(key))
* value = map.lget();
*
* or, to modify the value at the given key without looking up
* its slot twice:
*
* if (map.containsKey(key))
* map.lset(map.lget() + 1);
*
* */
@Override
public boolean containsKey(final long key)
{
if (key == (0L)) {
if (this.allocatedDefaultKey) {
this.lastSlot = -2;
}
else {
this.lastSlot = -1;
}
return this.allocatedDefaultKey;
}
final int mask = this.keys.length - 1;
final LongHashingStrategy strategy = this.hashStrategy;
final long[] keys = this.keys;
//copied straight from fastutil "fast-path"
int slot;
long curr;
//1.1 The rehashed slot is free, return false
if ((curr = keys[slot = PhiMix.hash(strategy.computeHashCode(key)) & mask]) == (0L)) {
this.lastSlot = -1;
return false;
}
//1.2) The rehashed entry is occupied by the key, return true
if (strategy.equals(curr, key)) {
this.lastSlot = slot;
return true;
}
//2. Hash collision, search for the key along the path
slot = (slot + 1) & mask;
int dist = 0;
final int[] cached = this.hash_cache;
while ((keys[slot] != (0L))
&& dist <= (slot < cached[slot] ? slot + cached.length - cached[slot] : slot - cached[slot]) )
{
if (strategy.equals(key, keys[slot]))
{
this.lastSlot = slot;
return true;
}
slot = (slot + 1) & mask;
dist++;
} //end while true
//unsuccessful search
this.lastSlot = -1;
return false;
}
/**
* {@inheritDoc}
*
* Does not release internal buffers.
*/
@Override
public void clear()
{
this.assigned = 0;
this.lastSlot = -1;
// States are always cleared.
this.allocatedDefaultKey = false;
//help the GC
this.allocatedDefaultKeyValue = (null);
//Faster than Arrays.fill(keys, null); // Help the GC.
LongArrays.blankArray(this.keys, 0, this.keys.length);
//Faster than Arrays.fill(values, null); // Help the GC.
ObjectArrays. blankArray(this.values, 0, this.values.length);
}
/**
* {@inheritDoc}
*/
@Override
public int size()
{
return this.assigned + (this.allocatedDefaultKey ? 1 : 0);
}
/**
* {@inheritDoc}
*/
@Override
public int capacity() {
return this.resizeAt - 1;
}
/**
* {@inheritDoc}
*
* Note that an empty container may still contain many deleted keys (that occupy buffer
* space). Adding even a single element to such a container may cause rehashing.
*/
@Override
public boolean isEmpty()
{
return size() == 0;
}
/**
* {@inheritDoc}
*/
@Override
public int hashCode()
{
final LongHashingStrategy strategy = this.hashStrategy;
int h = 0;
if (this.allocatedDefaultKey) {
h += 0 + Internals.rehash(this.allocatedDefaultKeyValue);
}
final long[] keys = this.keys;
final VType[] values = this.values;
for (int i = keys.length; --i >= 0;)
{
if ((keys[i] != (0L)))
{
h += PhiMix.hash(strategy.computeHashCode(keys[i])) + Internals.rehash(values[i]);
}
}
return h;
}
/**
* {@inheritDoc}
*/
@Override
public boolean equals(final Object obj)
{
if (obj != null)
{
if (obj == this)
{
return true;
}
if (!(obj instanceof LongObjectOpenCustomHashMap))
{
return false;
}
if (!this.hashStrategy.equals(((LongObjectOpenCustomHashMap) obj).hashStrategy))
{
return false;
}
@SuppressWarnings("unchecked")
final LongObjectOpenCustomHashMap other = (LongObjectOpenCustomHashMap) obj;
if (other.size() == this.size())
{
final EntryIterator it = this.iterator();
while (it.hasNext())
{
final LongObjectCursor c = it.next();
if (other.containsKey(c.key))
{
final VType v = other.get(c.key);
if ((c.value == null ? v == null : c.value.equals(v)))
{
continue;
}
}
//recycle
it.release();
return false;
}
return true;
}
}
return false;
}
/**
* An iterator implementation for {@link #iterator}.
*/
public final class EntryIterator extends AbstractIterator>
{
public final LongObjectCursor cursor;
public EntryIterator()
{
this.cursor = new LongObjectCursor();
this.cursor.index = -2;
}
/**
* Iterate backwards w.r.t the buffer, to
* minimize collision chains when filling another hash container (ex. with putAll())
*/
@Override
protected LongObjectCursor fetch()
{
if (this.cursor.index == LongObjectOpenCustomHashMap.this.keys.length + 1) {
if (LongObjectOpenCustomHashMap.this.allocatedDefaultKey) {
this.cursor.index = LongObjectOpenCustomHashMap.this.keys.length;
this.cursor.key = (0L);
this.cursor.value = LongObjectOpenCustomHashMap.this.allocatedDefaultKeyValue;
return this.cursor;
}
//no value associated with the default key, continue iteration...
this.cursor.index = LongObjectOpenCustomHashMap.this.keys.length;
}
int i = this.cursor.index - 1;
while (i >= 0 &&
!(LongObjectOpenCustomHashMap.this.keys[i] != (0L)))
{
i--;
}
if (i == -1)
{
return done();
}
this.cursor.index = i;
this.cursor.key = LongObjectOpenCustomHashMap.this.keys[i];
this.cursor.value = LongObjectOpenCustomHashMap.this.values[i];
return this.cursor;
}
}
/**
* internal pool of EntryIterator
*/
protected final IteratorPool, EntryIterator> entryIteratorPool = new IteratorPool, EntryIterator>(
new ObjectFactory() {
@Override
public EntryIterator create()
{
return new EntryIterator();
}
@Override
public void initialize(final EntryIterator obj)
{
obj.cursor.index = LongObjectOpenCustomHashMap.this.keys.length + 1;
}
@Override
public void reset(final EntryIterator obj) {
// nothing
}
});
/**
* {@inheritDoc}
* @return
*/
@Override
public EntryIterator iterator()
{
//return new EntryIterator();
return this.entryIteratorPool.borrow();
}
/**
* {@inheritDoc}
*/
@Override
public > T forEach(final T procedure)
{
if (this.allocatedDefaultKey) {
procedure.apply((0L), this.allocatedDefaultKeyValue);
}
final long[] keys = this.keys;
final VType[] values = this.values;
//Iterate in reverse for side-stepping the longest conflict chain
//in another hash, in case apply() is actually used to fill another hash container.
for (int i = keys.length - 1; i >= 0; i--)
{
if ((keys[i] != (0L)))
{
procedure.apply(keys[i], values[i]);
}
}
return procedure;
}
/**
* {@inheritDoc}
*/
@Override
public > T forEach(final T predicate)
{
if (this.allocatedDefaultKey) {
if (!predicate.apply((0L), this.allocatedDefaultKeyValue)) {
return predicate;
}
}
final long[] keys = this.keys;
final VType[] values = this.values;
//Iterate in reverse for side-stepping the longest conflict chain
//in another hash, in case apply() is actually used to fill another hash container.
for (int i = keys.length - 1; i >= 0; i--)
{
if ((keys[i] != (0L)))
{
if (!predicate.apply(keys[i], values[i]))
{
break;
}
}
} //end for
return predicate;
}
/**
* @return a new KeysContainer view of the keys of this associated container.
* This view then reflects all changes from the map.
*/
@Override
public KeysContainer keys()
{
return new KeysContainer();
}
/**
* A view of the keys inside this hash map.
*/
public final class KeysContainer
extends AbstractLongCollection implements LongLookupContainer
{
private final LongObjectOpenCustomHashMap owner =
LongObjectOpenCustomHashMap.this;
@Override
public boolean contains(final long e)
{
return containsKey(e);
}
@Override
public T forEach(final T procedure)
{
if (this.owner.allocatedDefaultKey) {
procedure.apply((0L));
}
final long[] keys = this.owner.keys;
//Iterate in reverse for side-stepping the longest conflict chain
//in another hash, in case apply() is actually used to fill another hash container.
for (int i = keys.length - 1; i >= 0; i--)
{
if ((keys[i] != (0L)))
{
procedure.apply(keys[i]);
}
}
return procedure;
}
@Override
public T forEach(final T predicate)
{
if (this.owner.allocatedDefaultKey) {
if (!predicate.apply((0L))) {
return predicate;
}
}
final long[] keys = this.owner.keys;
//Iterate in reverse for side-stepping the longest conflict chain
//in another hash, in case apply() is actually used to fill another hash container.
for (int i = keys.length - 1; i >= 0; i--)
{
if ((keys[i] != (0L)))
{
if (!predicate.apply(keys[i]))
{
break;
}
}
}
return predicate;
}
/**
* {@inheritDoc}
*/
@Override
public KeysIterator iterator()
{
//return new KeysIterator();
return this.keyIteratorPool.borrow();
}
/**
* {@inheritDoc}
*/
@Override
public int size()
{
return this.owner.size();
}
/**
* {@inheritDoc}
*/
@Override
public int capacity() {
return this.owner.capacity();
}
@Override
public void clear()
{
this.owner.clear();
}
@Override
public int removeAll(final LongPredicate predicate)
{
return this.owner.removeAll(predicate);
}
@Override
public int removeAllOccurrences(final long e)
{
final boolean hasKey = this.owner.containsKey(e);
int result = 0;
if (hasKey)
{
this.owner.remove(e);
result = 1;
}
return result;
}
/**
* internal pool of KeysIterator
*/
protected final IteratorPool keyIteratorPool = new IteratorPool(
new ObjectFactory() {
@Override
public KeysIterator create()
{
return new KeysIterator();
}
@Override
public void initialize(final KeysIterator obj)
{
obj.cursor.index = LongObjectOpenCustomHashMap.this.keys.length + 1;
}
@Override
public void reset(final KeysIterator obj) {
// nothing
}
});
@Override
public long[] toArray(final long[] target)
{
int count = 0;
if (this.owner.allocatedDefaultKey) {
target[count++] = (0L);
}
final long[] keys = this.owner.keys;
for (int i = 0; i < keys.length; i++)
{
if ((keys[i] != (0L)))
{
target[count++] = keys[i];
}
}
assert count == this.owner.size();
return target;
}
};
/**
* An iterator over the set of keys.
*/
public final class KeysIterator extends AbstractIterator
{
public final LongCursor cursor;
public KeysIterator()
{
this.cursor = new LongCursor();
this.cursor.index = -2;
}
/**
* Iterate backwards w.r.t the buffer, to
* minimize collision chains when filling another hash container (ex. with putAll())
*/
@Override
protected LongCursor fetch()
{
if (this.cursor.index == LongObjectOpenCustomHashMap.this.keys.length + 1) {
if (LongObjectOpenCustomHashMap.this.allocatedDefaultKey) {
this.cursor.index = LongObjectOpenCustomHashMap.this.keys.length;
this.cursor.value = (0L);
return this.cursor;
}
//no value associated with the default key, continue iteration...
this.cursor.index = LongObjectOpenCustomHashMap.this.keys.length;
}
int i = this.cursor.index - 1;
while (i >= 0 && !(LongObjectOpenCustomHashMap.this.keys[i] != (0L)))
{
i--;
}
if (i == -1)
{
return done();
}
this.cursor.index = i;
this.cursor.value = LongObjectOpenCustomHashMap.this.keys[i];
return this.cursor;
}
}
/**
* @return a new ValuesContainer, view of the values of this map.
* This view then reflects all changes from the map.
*/
@Override
public ValuesContainer values()
{
return new ValuesContainer();
}
/**
* A view over the set of values of this map.
*/
public final class ValuesContainer extends AbstractObjectCollection
{
private final LongObjectOpenCustomHashMap owner =
LongObjectOpenCustomHashMap.this;
/**
* {@inheritDoc}
*/
@Override
public int size()
{
return this.owner.size();
}
/**
* {@inheritDoc}
*/
@Override
public int capacity() {
return this.owner.capacity();
}
@Override
public boolean contains(final VType value)
{
if (this.owner.allocatedDefaultKey && (value == null ? this.owner.allocatedDefaultKeyValue == null : value.equals(this.owner.allocatedDefaultKeyValue))) {
return true;
}
// This is a linear scan over the values, but it's in the contract, so be it.
final long[] keys = this.owner.keys;
final VType[] values = this.owner.values;
for (int slot = 0; slot < keys.length; slot++)
{
if ((keys[slot] != (0L))
&& (value == null ? values[slot] == null : value.equals(values[slot])))
{
return true;
}
}
return false;
}
@Override
public > T forEach(final T procedure)
{
if (this.owner.allocatedDefaultKey) {
procedure.apply(this.owner.allocatedDefaultKeyValue);
}
final long[] keys = this.owner.keys;
final VType[] values = this.owner.values;
for (int slot = 0; slot < keys.length; slot++)
{
if ((keys[slot] != (0L))) {
procedure.apply(values[slot]);
}
}
return procedure;
}
@Override
public > T forEach(final T predicate)
{
if (this.owner.allocatedDefaultKey) {
if (!predicate.apply(this.owner.allocatedDefaultKeyValue))
{
return predicate;
}
}
final long[] keys = this.owner.keys;
final VType[] values = this.owner.values;
for (int slot = 0; slot < keys.length; slot++)
{
if ((keys[slot] != (0L)))
{
if (!predicate.apply(values[slot]))
{
break;
}
}
}
return predicate;
}
@Override
public ValuesIterator iterator()
{
// return new ValuesIterator();
return this.valuesIteratorPool.borrow();
}
/**
* {@inheritDoc}
* Indeed removes all the (key,value) pairs matching
* (key ? , e) with the same e, from the map.
*/
@Override
public int removeAllOccurrences(final VType e)
{
final int before = this.owner.size();
if (this.owner.allocatedDefaultKey) {
if ((e == null ? this.owner.allocatedDefaultKeyValue == null : e.equals(this.owner.allocatedDefaultKeyValue))) {
this.owner.allocatedDefaultKey = false;
}
}
final long[] keys = this.owner.keys;
final VType[] values = this.owner.values;
for (int slot = 0; slot < keys.length;)
{
if ((keys[slot] != (0L)))
{
if ((e == null ? values[slot] == null : e.equals(values[slot])))
{
this.owner.assigned--;
shiftConflictingKeys(slot);
// Repeat the check for the same i.
continue;
}
}
slot++;
}
return before - this.owner.size();
}
/**
* {@inheritDoc}
* Indeed removes all the (key,value) pairs matching
* the predicate for the values, from the map.
*/
@Override
public int removeAll(final ObjectPredicate predicate)
{
final int before = this.owner.size();
if (this.owner.allocatedDefaultKey) {
if (predicate.apply(this.owner.allocatedDefaultKeyValue)) {
this.owner.allocatedDefaultKey = false;
}
}
final long[] keys = this.owner.keys;
final VType[] values = this.owner.values;
for (int slot = 0; slot < keys.length;)
{
if ((keys[slot] != (0L)))
{
if (predicate.apply(values[slot]))
{
this.owner.assigned--;
shiftConflictingKeys(slot);
// Repeat the check for the same i.
continue;
}
}
slot++;
}
return before - this.owner.size();
}
/**
* {@inheritDoc}
* Alias for clear() the whole map.
*/
@Override
public void clear()
{
this.owner.clear();
}
/**
* internal pool of ValuesIterator
*/
protected final IteratorPool, ValuesIterator> valuesIteratorPool = new IteratorPool, ValuesIterator>(
new ObjectFactory() {
@Override
public ValuesIterator create()
{
return new ValuesIterator();
}
@Override
public void initialize(final ValuesIterator obj)
{
obj.cursor.index = LongObjectOpenCustomHashMap.this.keys.length + 1;
}
@Override
public void reset(final ValuesIterator obj) {
// nothing
}
});
@Override
public VType[] toArray(final VType[] target)
{
int count = 0;
if (this.owner.allocatedDefaultKey) {
target[count++] = this.owner.allocatedDefaultKeyValue;
}
final long[] keys = this.owner.keys;
final VType[] values = this.owner.values;
for (int i = 0; i < values.length; i++)
{
if ((keys[i] != (0L)))
{
target[count++] = values[i];
}
}
assert count == this.owner.size();
return target;
}
}
/**
* An iterator over the set of values.
*/
public final class ValuesIterator extends AbstractIterator>
{
public final ObjectCursor cursor;
public ValuesIterator()
{
this.cursor = new ObjectCursor();
this.cursor.index = -2;
}
/**
* Iterate backwards w.r.t the buffer, to
* minimize collision chains when filling another hash container (ex. with putAll())
*/
@Override
protected ObjectCursor fetch()
{
if (this.cursor.index == LongObjectOpenCustomHashMap.this.values.length + 1) {
if (LongObjectOpenCustomHashMap.this.allocatedDefaultKey) {
this.cursor.index = LongObjectOpenCustomHashMap.this.values.length;
this.cursor.value = LongObjectOpenCustomHashMap.this.allocatedDefaultKeyValue;
return this.cursor;
}
//no value associated with the default key, continue iteration...
this.cursor.index = LongObjectOpenCustomHashMap.this.keys.length;
}
int i = this.cursor.index - 1;
while (i >= 0 &&
!(LongObjectOpenCustomHashMap.this.keys[i] != (0L)))
{
i--;
}
if (i == -1)
{
return done();
}
this.cursor.index = i;
this.cursor.value = LongObjectOpenCustomHashMap.this.values[i];
return this.cursor;
}
}
/**
* Clone this object.
* * The returned clone will use the same HashingStrategy strategy.
* It also realizes a trim-to- this.size() in the process.
* */
@Override
public LongObjectOpenCustomHashMap clone()
{
/* */
@SuppressWarnings("unchecked")
final/* */
LongObjectOpenCustomHashMap cloned =
new LongObjectOpenCustomHashMap(this.size(), this.loadFactor, this.hashStrategy);
cloned.putAll(this);
cloned.allocatedDefaultKeyValue = this.allocatedDefaultKeyValue;
cloned.allocatedDefaultKey = this.allocatedDefaultKey;
cloned.defaultValue = this.defaultValue;
return cloned;
}
/**
* Convert the contents of this map to a human-friendly string.
*/
@Override
public String toString()
{
final StringBuilder buffer = new StringBuilder();
buffer.append("[");
boolean first = true;
for (final LongObjectCursor cursor : this)
{
if (!first)
{
buffer.append(", ");
}
buffer.append(cursor.key);
buffer.append("=>");
buffer.append(cursor.value);
first = false;
}
buffer.append("]");
return buffer.toString();
}
/**
* Creates a hash map from two index-aligned arrays of key-value pairs.
*/
public static LongObjectOpenCustomHashMap from(final long[] keys, final VType[] values, final LongHashingStrategy hashStrategy)
{
if (keys.length != values.length)
{
throw new IllegalArgumentException("Arrays of keys and values must have an identical length.");
}
final LongObjectOpenCustomHashMap map = new LongObjectOpenCustomHashMap(keys.length, hashStrategy);
for (int i = 0; i < keys.length; i++)
{
map.put(keys[i], values[i]);
}
return map;
}
/**
* Create a hash map from another associative container.
*/
public static LongObjectOpenCustomHashMap from(final LongObjectAssociativeContainer container, final LongHashingStrategy hashStrategy)
{
return new LongObjectOpenCustomHashMap(container, hashStrategy);
}
/**
* Create a new hash map without providing the full generic signature (constructor
* shortcut).
*/
public static LongObjectOpenCustomHashMap newInstance(final LongHashingStrategy hashStrategy)
{
return new LongObjectOpenCustomHashMap(hashStrategy);
}
/**
* Create a new hash map with initial capacity and load factor control. (constructor
* shortcut).
*/
public static LongObjectOpenCustomHashMap newInstance(final int initialCapacity, final float loadFactor, final LongHashingStrategy hashStrategy)
{
return new LongObjectOpenCustomHashMap(initialCapacity, loadFactor, hashStrategy);
}
/**
* Return the current {@link LongHashingStrategy} in use.
*/
public LongHashingStrategy strategy()
{
return this.hashStrategy;
}
/**
* Returns the "default value" value used
* in containers methods returning "default value"
* @return
*/
public VType getDefaultValue()
{
return this.defaultValue;
}
/**
* Set the "default value" value to be used
* in containers methods returning "default value"
* @return
*/
public void setDefaultValue(final VType defaultValue)
{
this.defaultValue = defaultValue;
}
//Test for existence in template
}
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