/***** BEGIN LICENSE BLOCK *****
* Version: CPL 1.0/GPL 2.0/LGPL 2.1
*
* The contents of this file are subject to the Common Public
* License Version 1.0 (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.eclipse.org/legal/cpl-v10.html
*
* Software distributed under the License is distributed on an "AS
* IS" basis, WITHOUT WARRANTY OF ANY KIND, either express or
* implied. See the License for the specific language governing
* rights and limitations under the License.
*
* Copyright (C) 2001 Chad Fowler <chadfowler@chadfowler.com>
* Copyright (C) 2001 Alan Moore <alan_moore@gmx.net>
* Copyright (C) 2001-2002 Benoit Cerrina <b.cerrina@wanadoo.fr>
* Copyright (C) 2001-2004 Jan Arne Petersen <jpetersen@uni-bonn.de>
* Copyright (C) 2002-2004 Anders Bengtsson <ndrsbngtssn@yahoo.se>
* Copyright (C) 2004-2006 Thomas E Enebo <enebo@acm.org>
* Copyright (C) 2004 Stefan Matthias Aust <sma@3plus4.de>
* Copyright (C) 2005 Charles O Nutter <headius@headius.com>
* Copyright (C) 2006 Ola Bini <Ola.Bini@ki.se>
* Copyright (C) 2006 Tim Azzopardi <tim@tigerfive.com>
* Copyright (C) 2006 Miguel Covarrubias <mlcovarrubias@gmail.com>
* Copyright (C) 2007 MenTaLguY <mental@rydia.net>
*
* Alternatively, the contents of this file may be used under the terms of
* either of the GNU General Public License Version 2 or later (the "GPL"),
* or the GNU Lesser General Public License Version 2.1 or later (the "LGPL"),
* in which case the provisions of the GPL or the LGPL are applicable instead
* of those above. If you wish to allow use of your version of this file only
* under the terms of either the GPL or the LGPL, and not to allow others to
* use your version of this file under the terms of the CPL, indicate your
* decision by deleting the provisions above and replace them with the notice
* and other provisions required by the GPL or the LGPL. If you do not delete
* the provisions above, a recipient may use your version of this file under
* the terms of any one of the CPL, the GPL or the LGPL.
***** END LICENSE BLOCK *****/
package org.jruby;
import static org.jruby.RubyEnumerator.enumeratorize;
import java.io.IOException;
import java.util.AbstractCollection;
import java.util.AbstractSet;
import java.util.Collection;
import java.util.Map;
import java.util.NoSuchElementException;
import java.util.Iterator;
import java.util.Set;
import java.util.concurrent.atomic.AtomicInteger;
import org.jruby.anno.JRubyClass;
import org.jruby.anno.JRubyMethod;
import org.jruby.common.IRubyWarnings.ID;
import org.jruby.exceptions.RaiseException;
import org.jruby.javasupport.JavaUtil;
import org.jruby.javasupport.util.RuntimeHelpers;
import org.jruby.runtime.Arity;
import org.jruby.runtime.Block;
import org.jruby.runtime.ClassIndex;
import org.jruby.runtime.ObjectAllocator;
import org.jruby.runtime.ThreadContext;
import static org.jruby.runtime.Visibility.*;
import org.jruby.runtime.builtin.IRubyObject;
import org.jruby.runtime.invokedynamic.MethodNames;
import org.jruby.runtime.marshal.MarshalStream;
import org.jruby.runtime.marshal.UnmarshalStream;
import org.jruby.util.TypeConverter;
import org.jruby.util.RecursiveComparator;
import static org.jruby.CompatVersion.*;
import static org.jruby.javasupport.util.RuntimeHelpers.invokedynamic;
import static org.jruby.runtime.invokedynamic.MethodNames.HASH;
// Design overview:
//
// RubyHash is implemented as hash table with a singly-linked list of
// RubyHash.RubyHashEntry objects for each bucket. RubyHashEntry objects
// are also kept in a doubly-linked list which reflects their insertion
// order and is used for iteration. For simplicity, this latter list is
// circular; a dummy RubyHashEntry, RubyHash.head, is used to mark the
// ends of the list.
//
// When an entry is removed from the table, it is also removed from the
// doubly-linked list. However, while the reference to the previous
// RubyHashEntry is cleared (to mark the entry as dead), the reference
// to the next RubyHashEntry is preserved so that iterators are not
// invalidated: any iterator with a reference to a dead entry can climb
// back up into the list of live entries by chasing next references until
// it finds a live entry (or head).
//
// Ordinarily, this scheme would require O(N) time to clear a hash (since
// each RubyHashEntry would need to be visited and unlinked from the
// iteration list), but RubyHash also maintains a generation count. Every
// time the hash is cleared, the doubly-linked list is simply discarded and
// the generation count incremented. Iterators check to see whether the
// generation count has changed; if it has, they reset themselves back to
// the new start of the list.
//
// This design means that iterators are never invalidated by changes to the
// hashtable, and they do not need to modify the structure during their
// lifecycle.
//
/** Implementation of the Hash class.
*
* Concurrency: no synchronization is required among readers, but
* all users must synchronize externally with writers.
*
*/
@JRubyClass(name = "Hash", include="Enumerable")
public class RubyHash extends RubyObject implements Map {
public static final int DEFAULT_INSPECT_STR_SIZE = 20;
public static RubyClass createHashClass(Ruby runtime) {
RubyClass hashc = runtime.defineClass("Hash", runtime.getObject(), HASH_ALLOCATOR);
runtime.setHash(hashc);
hashc.index = ClassIndex.HASH;
hashc.setReifiedClass(RubyHash.class);
hashc.kindOf = new RubyModule.KindOf() {
@Override
public boolean isKindOf(IRubyObject obj, RubyModule type) {
return obj instanceof RubyHash;
}
};
hashc.includeModule(runtime.getEnumerable());
hashc.defineAnnotatedMethods(RubyHash.class);
return hashc;
}
private final static ObjectAllocator HASH_ALLOCATOR = new ObjectAllocator() {
public IRubyObject allocate(Ruby runtime, RubyClass klass) {
return new RubyHash(runtime, klass);
}
};
@Override
public int getNativeTypeIndex() {
return ClassIndex.HASH;
}
/** rb_hash_s_create
*
*/
@JRubyMethod(name = "[]", rest = true, meta = true)
public static IRubyObject create(ThreadContext context, IRubyObject recv, IRubyObject[] args, Block block) {
RubyClass klass = (RubyClass) recv;
Ruby runtime = context.runtime;
RubyHash hash;
if (args.length == 1) {
IRubyObject tmp = TypeConverter.convertToTypeWithCheck(
args[0], runtime.getHash(), "to_hash");
if (!tmp.isNil()) {
RubyHash otherHash = (RubyHash) tmp;
return new RubyHash(runtime, klass, otherHash);
}
tmp = TypeConverter.convertToTypeWithCheck(args[0], runtime.getArray(), "to_ary");
if (!tmp.isNil()) {
hash = (RubyHash)klass.allocate();
RubyArray arr = (RubyArray)tmp;
for(int i = 0, j = arr.getLength(); i<j; i++) {
IRubyObject v = TypeConverter.convertToTypeWithCheck(arr.entry(i), runtime.getArray(), "to_ary");
IRubyObject key = runtime.getNil();
IRubyObject val = runtime.getNil();
if(v.isNil()) {
continue;
}
switch(((RubyArray)v).getLength()) {
case 2:
val = ((RubyArray)v).entry(1);
case 1:
key = ((RubyArray)v).entry(0);
hash.fastASet(key, val);
}
}
return hash;
}
}
if ((args.length & 1) != 0) {
throw runtime.newArgumentError("odd number of arguments for Hash");
}
hash = (RubyHash)klass.allocate();
for (int i=0; i < args.length; i+=2) hash.op_aset(context, args[i], args[i+1]);
return hash;
}
@JRubyMethod(name = "try_convert", meta = true, compat = RUBY1_9)
public static IRubyObject try_convert(ThreadContext context, IRubyObject recv, IRubyObject args) {
return TypeConverter.convertToTypeWithCheck(args, context.runtime.getHash(), "to_hash");
}
/** rb_hash_new
*
*/
public static final RubyHash newHash(Ruby runtime) {
return new RubyHash(runtime);
}
/** rb_hash_new
*
*/
public static final RubyHash newSmallHash(Ruby runtime) {
return new RubyHash(runtime, 1);
}
/** rb_hash_new
*
*/
public static final RubyHash newHash(Ruby runtime, Map valueMap, IRubyObject defaultValue) {
assert defaultValue != null;
return new RubyHash(runtime, valueMap, defaultValue);
}
private RubyHashEntry[] table;
protected int size = 0;
private int threshold;
private static final int PROCDEFAULT_HASH_F = 1 << 10;
private IRubyObject ifNone;
private RubyHash(Ruby runtime, RubyClass klass, RubyHash other) {
super(runtime, klass);
this.ifNone = runtime.getNil();
threshold = INITIAL_THRESHOLD;
table = other.internalCopyTable(head);
size = other.size;
}
public RubyHash(Ruby runtime, RubyClass klass) {
super(runtime, klass);
this.ifNone = runtime.getNil();
alloc();
}
public RubyHash(Ruby runtime, int buckets) {
this(runtime, runtime.getNil(), buckets);
}
public RubyHash(Ruby runtime) {
this(runtime, runtime.getNil());
}
public RubyHash(Ruby runtime, IRubyObject defaultValue) {
super(runtime, runtime.getHash());
this.ifNone = defaultValue;
alloc();
}
public RubyHash(Ruby runtime, IRubyObject defaultValue, int buckets) {
super(runtime, runtime.getHash());
this.ifNone = defaultValue;
alloc(buckets);
}
/*
* Constructor for internal usage (mainly for Array#|, Array#&, Array#- and Array#uniq)
* it doesn't initialize ifNone field
*/
RubyHash(Ruby runtime, boolean objectSpace) {
super(runtime, runtime.getHash(), objectSpace);
alloc();
}
// TODO should this be deprecated ? (to be efficient, internals should deal with RubyHash directly)
public RubyHash(Ruby runtime, Map valueMap, IRubyObject defaultValue) {
super(runtime, runtime.getHash());
this.ifNone = defaultValue;
alloc();
for (Iterator iter = valueMap.entrySet().iterator();iter.hasNext();) {
Map.Entry e = (Map.Entry)iter.next();
internalPut((IRubyObject)e.getKey(), (IRubyObject)e.getValue());
}
}
private final void alloc() {
threshold = INITIAL_THRESHOLD;
generation++;
head.nextAdded = head.prevAdded = head;
table = new RubyHashEntry[MRI_HASH_RESIZE ? MRI_INITIAL_CAPACITY : JAVASOFT_INITIAL_CAPACITY];
}
private final void alloc(int buckets) {
threshold = INITIAL_THRESHOLD;
generation++;
head.nextAdded = head.prevAdded = head;
table = new RubyHashEntry[buckets];
}
/* ============================
* Here are hash internals
* (This could be extracted to a separate class but it's not too large though)
* ============================
*/
private static final int MRI_PRIMES[] = {
8 + 3, 16 + 3, 32 + 5, 64 + 3, 128 + 3, 256 + 27, 512 + 9, 1024 + 9, 2048 + 5, 4096 + 3,
8192 + 27, 16384 + 43, 32768 + 3, 65536 + 45, 131072 + 29, 262144 + 3, 524288 + 21, 1048576 + 7,
2097152 + 17, 4194304 + 15, 8388608 + 9, 16777216 + 43, 33554432 + 35, 67108864 + 15,
134217728 + 29, 268435456 + 3, 536870912 + 11, 1073741824 + 85, 0
};
private static final int JAVASOFT_INITIAL_CAPACITY = 8; // 16 ?
private static final int MRI_INITIAL_CAPACITY = MRI_PRIMES[0];
private static final int INITIAL_THRESHOLD = JAVASOFT_INITIAL_CAPACITY - (JAVASOFT_INITIAL_CAPACITY >> 2);
private static final int MAXIMUM_CAPACITY = 1 << 30;
public static final RubyHashEntry NO_ENTRY = new RubyHashEntry();
private int generation = 0; // generation count for O(1) clears
private final RubyHashEntry head = new RubyHashEntry();
{ head.prevAdded = head.nextAdded = head; }
public static final class RubyHashEntry implements Map.Entry {
private IRubyObject key;
private IRubyObject value;
private RubyHashEntry next;
private RubyHashEntry prevAdded;
private RubyHashEntry nextAdded;
private int hash;
RubyHashEntry() {
key = NEVER;
}
public RubyHashEntry(int h, IRubyObject k, IRubyObject v, RubyHashEntry e, RubyHashEntry head) {
key = k; value = v; next = e; hash = h;
if (head != null) {
prevAdded = head.prevAdded;
nextAdded = head;
nextAdded.prevAdded = this;
prevAdded.nextAdded = this;
}
}
public void detach() {
if (prevAdded != null) {
prevAdded.nextAdded = nextAdded;
nextAdded.prevAdded = prevAdded;
prevAdded = null;
}
}
public boolean isLive() {
return prevAdded != null;
}
public Object getKey() {
return key;
}
public Object getJavaifiedKey(){
return key.toJava(Object.class);
}
public Object getValue() {
return value;
}
public Object getJavaifiedValue() {
return value.toJava(Object.class);
}
public Object setValue(Object value) {
IRubyObject oldValue = this.value;
if (value instanceof IRubyObject) {
this.value = (IRubyObject)value;
} else {
throw new UnsupportedOperationException("directEntrySet() doesn't support setValue for non IRubyObject instance entries, convert them manually or use entrySet() instead");
}
return oldValue;
}
@Override
public boolean equals(Object other){
if(!(other instanceof RubyHashEntry)) return false;
RubyHashEntry otherEntry = (RubyHashEntry)other;
return (key == otherEntry.key || key.eql(otherEntry.key)) &&
(value == otherEntry.value || value.equals(otherEntry.value));
}
@Override
public int hashCode(){
return key.hashCode() ^ value.hashCode();
}
}
private static int JavaSoftHashValue(int h) {
h ^= (h >>> 20) ^ (h >>> 12);
return h ^ (h >>> 7) ^ (h >>> 4);
}
private static int JavaSoftBucketIndex(final int h, final int length) {
return h & (length - 1);
}
private static int MRIHashValue(int h) {
return h & HASH_SIGN_BIT_MASK;
}
private static final int HASH_SIGN_BIT_MASK = ~(1 << 31);
private static int MRIBucketIndex(final int h, final int length) {
return ((h & HASH_SIGN_BIT_MASK) % length);
}
private final void resize(int newCapacity) {
final RubyHashEntry[] oldTable = table;
final RubyHashEntry[] newTable = new RubyHashEntry[newCapacity];
for (int j = 0; j < oldTable.length; j++) {
RubyHashEntry entry = oldTable[j];
oldTable[j] = null;
while (entry != null) {
RubyHashEntry next = entry.next;
int i = bucketIndex(entry.hash, newCapacity);
entry.next = newTable[i];
newTable[i] = entry;
entry = next;
}
}
table = newTable;
}
private final void JavaSoftCheckResize() {
if (overThreshold()) {
RubyHashEntry[] tbl = table;
if (tbl.length == MAXIMUM_CAPACITY) {
threshold = Integer.MAX_VALUE;
return;
}
resizeAndAdjustThreshold(table);
}
}
private boolean overThreshold() {
return size > threshold;
}
private void resizeAndAdjustThreshold(RubyHashEntry[] oldTable) {
int newCapacity = oldTable.length << 1;
resize(newCapacity);
threshold = newCapacity - (newCapacity >> 2);
}
private static final int MIN_CAPA = 8;
private static final int ST_DEFAULT_MAX_DENSITY = 5;
private final void MRICheckResize() {
if (size / table.length > ST_DEFAULT_MAX_DENSITY) {
int forSize = table.length + 1; // size + 1;
for (int i=0, newCapacity = MIN_CAPA; i < MRI_PRIMES.length; i++, newCapacity <<= 1) {
if (newCapacity > forSize) {
resize(MRI_PRIMES[i]);
return;
}
}
return; // suboptimal for large hashes (> 1073741824 + 85 entries) not very likely to happen
}
}
// ------------------------------
private static final boolean MRI_HASH = true;
private static final boolean MRI_HASH_RESIZE = true;
protected static int hashValue(final int h) {
return MRI_HASH ? MRIHashValue(h) : JavaSoftHashValue(h);
}
private static int bucketIndex(final int h, final int length) {
return MRI_HASH ? MRIBucketIndex(h, length) : JavaSoftBucketIndex(h, length);
}
private void checkResize() {
if (MRI_HASH_RESIZE) MRICheckResize(); else JavaSoftCheckResize();
}
private void checkIterating() {
if (iteratorCount.get() > 0) {
throw getRuntime().newRuntimeError("can't add a new key into hash during iteration");
}
}
// ------------------------------
public static long collisions = 0;
// put implementation
private final void internalPut(final IRubyObject key, final IRubyObject value) {
internalPut(key, value, true);
}
private final void internalPutSmall(final IRubyObject key, final IRubyObject value) {
internalPutSmall(key, value, true);
}
protected void internalPut(final IRubyObject key, final IRubyObject value, final boolean checkForExisting) {
checkResize();
internalPutSmall(key, value, checkForExisting);
}
protected void internalPutSmall(final IRubyObject key, final IRubyObject value, final boolean checkForExisting) {
final int hash = hashValue(key.hashCode());
final int i = bucketIndex(hash, table.length);
// if (table[i] != null) collisions++;
if (checkForExisting) {
for (RubyHashEntry entry = table[i]; entry != null; entry = entry.next) {
if (internalKeyExist(entry, hash, key)) {
entry.value = value;
return;
}
}
}
checkIterating();
table[i] = new RubyHashEntry(hash, key, value, table[i], head);
size++;
}
// get implementation
protected IRubyObject internalGet(IRubyObject key) { // specialized for value
return internalGetEntry(key).value;
}
protected RubyHashEntry internalGetEntry(IRubyObject key) {
final int hash = hashValue(key.hashCode());
for (RubyHashEntry entry = table[bucketIndex(hash, table.length)]; entry != null; entry = entry.next) {
if (internalKeyExist(entry, hash, key)) {
return entry;
}
}
return NO_ENTRY;
}
private boolean internalKeyExist(RubyHashEntry entry, int hash, IRubyObject key) {
return (entry.hash == hash
&& (entry.key == key || (!isComparedByIdentity() && key.eql(entry.key))));
}
// delete implementation
protected RubyHashEntry internalDelete(final IRubyObject key) {
return internalDelete(hashValue(key.hashCode()), MATCH_KEY, key);
}
protected RubyHashEntry internalDeleteEntry(final RubyHashEntry entry) {
// n.b. we need to recompute the hash in case the key object was modified
return internalDelete(hashValue(entry.key.hashCode()), MATCH_ENTRY, entry);
}
private final RubyHashEntry internalDelete(final int hash, final EntryMatchType matchType, final Object obj) {
final int i = bucketIndex(hash, table.length);
RubyHashEntry entry = table[i];
if (entry != null) {
RubyHashEntry prior = null;
for (; entry != null; prior = entry, entry = entry.next) {
if (entry.hash == hash && matchType.matches(entry, obj)) {
if (prior != null) {
prior.next = entry.next;
} else {
table[i] = entry.next;
}
entry.detach();
size--;
return entry;
}
}
}
return NO_ENTRY;
}
private static abstract class EntryMatchType {
public abstract boolean matches(final RubyHashEntry entry, final Object obj);
}
private static final EntryMatchType MATCH_KEY = new EntryMatchType() {
public boolean matches(final RubyHashEntry entry, final Object obj) {
final IRubyObject key = entry.key;
return obj == key || (((IRubyObject)obj).eql(key));
}
};
private static final EntryMatchType MATCH_ENTRY = new EntryMatchType() {
public boolean matches(final RubyHashEntry entry, final Object obj) {
return entry.equals(obj);
}
};
private final RubyHashEntry[] internalCopyTable(RubyHashEntry destHead) {
RubyHashEntry[]newTable = new RubyHashEntry[table.length];
for (RubyHashEntry entry = head.nextAdded; entry != head; entry = entry.nextAdded) {
int i = bucketIndex(entry.hash, table.length);
newTable[i] = new RubyHashEntry(entry.hash, entry.key, entry.value, newTable[i], destHead);
}
return newTable;
}
public static abstract class Visitor {
public abstract void visit(IRubyObject key, IRubyObject value);
}
public void visitAll(Visitor visitor) {
int startGeneration = generation;
for (RubyHashEntry entry = head.nextAdded; entry != head; entry = entry.nextAdded) {
if (startGeneration != generation) {
startGeneration = generation;
entry = head.nextAdded;
if (entry == head) break;
}
if (entry.isLive()) visitor.visit(entry.key, entry.value);
}
}
/* ============================
* End of hash internals
* ============================
*/
/* ================
* Instance Methods
* ================
*/
/** rb_hash_initialize
*
*/
@JRubyMethod(optional = 1, visibility = PRIVATE)
public IRubyObject initialize(IRubyObject[] args, final Block block) {
modify();
if (block.isGiven()) {
if (args.length > 0) throw getRuntime().newArgumentError("wrong number of arguments");
ifNone = getRuntime().newProc(Block.Type.PROC, block);
flags |= PROCDEFAULT_HASH_F;
} else {
Arity.checkArgumentCount(getRuntime(), args, 0, 1);
if (args.length == 1) ifNone = args[0];
}
return this;
}
/** rb_hash_default
*
*/
@Deprecated
public IRubyObject default_value_get(ThreadContext context, IRubyObject[] args) {
switch (args.length) {
case 0: return default_value_get(context);
case 1: return default_value_get(context, args[0]);
default:
throw context.runtime.newArgumentError(args.length, 1);
}
}
@JRubyMethod(name = "default")
public IRubyObject default_value_get(ThreadContext context) {
if ((flags & PROCDEFAULT_HASH_F) != 0) {
return getRuntime().getNil();
}
return ifNone;
}
@JRubyMethod(name = "default")
public IRubyObject default_value_get(ThreadContext context, IRubyObject arg) {
if ((flags & PROCDEFAULT_HASH_F) != 0) {
return RuntimeHelpers.invoke(context, ifNone, "call", this, arg);
}
return ifNone;
}
/** rb_hash_set_default
*
*/
@JRubyMethod(name = "default=", required = 1)
public IRubyObject default_value_set(final IRubyObject defaultValue) {
modify();
ifNone = defaultValue;
flags &= ~PROCDEFAULT_HASH_F;
return ifNone;
}
/** rb_hash_default_proc
*
*/
@JRubyMethod
public IRubyObject default_proc() {
return (flags & PROCDEFAULT_HASH_F) != 0 ? ifNone : getRuntime().getNil();
}
/** default_proc_arity_check
*
*/
private void checkDefaultProcArity(IRubyObject proc) {
int n = ((RubyProc)proc).getBlock().arity().getValue();
if(((RubyProc)proc).getBlock().type == Block.Type.LAMBDA && n != 2 && (n >= 0 || n < -3)) {
if(n < 0) n = -n-1;
throw getRuntime().newTypeError("default_proc takes two arguments (2 for " + n + ")");
}
}
/** rb_hash_set_default_proc
*
*/
@JRubyMethod(name = "default_proc=", compat = RUBY1_9)
public IRubyObject set_default_proc(IRubyObject proc) {
modify();
IRubyObject b = TypeConverter.convertToType(proc, getRuntime().getProc(), "to_proc");
if(b.isNil() || !(b instanceof RubyProc)) {
throw getRuntime().newTypeError("wrong default_proc type " + proc.getMetaClass() + " (expected Proc)");
}
proc = b;
checkDefaultProcArity(proc);
ifNone = proc;
flags |= PROCDEFAULT_HASH_F;
return proc;
}
/** rb_hash_modify
*
*/
public void modify() {
testFrozen("Hash");
}
/** inspect_hash
*
*/
private IRubyObject inspectHash(final ThreadContext context) {
final RubyString str = RubyString.newStringLight(context.runtime, DEFAULT_INSPECT_STR_SIZE);
str.cat((byte)'{');
final boolean[] firstEntry = new boolean[1];
firstEntry[0] = true;
final boolean is19 = context.runtime.is1_9();
visitAll(new Visitor() {
public void visit(IRubyObject key, IRubyObject value) {
if (!firstEntry[0]) str.cat((byte)',').cat((byte)' ');
RubyString inspectedKey = inspect(context, key);
RubyString inspectedValue = inspect(context, value);
if (is19) {
str.cat19(inspectedKey);
str.cat((byte)'=').cat((byte)'>');
str.cat19(inspectedValue);
} else {
str.cat(inspectedKey);
str.cat((byte)'=').cat((byte)'>');
str.cat(inspectedValue);
}
firstEntry[0] = false;
}
});
str.cat((byte)'}');
return str;
}
/** rb_hash_inspect
*
*/
@JRubyMethod(name = "inspect")
public IRubyObject inspect(ThreadContext context) {
if (size == 0) return getRuntime().newString("{}");
if (getRuntime().isInspecting(this)) return getRuntime().newString("{...}");
try {
getRuntime().registerInspecting(this);
return inspectHash(context);
} finally {
getRuntime().unregisterInspecting(this);
}
}
/** rb_hash_size
*
*/
@JRubyMethod(name = {"size", "length"})
public RubyFixnum rb_size() {
return getRuntime().newFixnum(size);
}
/** rb_hash_empty_p
*
*/
@JRubyMethod(name = "empty?")
public RubyBoolean empty_p() {
return size == 0 ? getRuntime().getTrue() : getRuntime().getFalse();
}
/** rb_hash_to_a
*
*/
@JRubyMethod(name = "to_a")
@Override
public RubyArray to_a() {
final Ruby runtime = getRuntime();
try {
final RubyArray result = RubyArray.newArray(runtime, size);
visitAll(new Visitor() {
public void visit(IRubyObject key, IRubyObject value) {
result.append(RubyArray.newArray(runtime, key, value));
}
});
result.setTaint(isTaint());
return result;
} catch (NegativeArraySizeException nase) {
throw concurrentModification();
}
}
/** rb_hash_to_s & to_s_hash
*
*/
@JRubyMethod(name = "to_s")
public IRubyObject to_s(ThreadContext context) {
Ruby runtime = context.runtime;
if (runtime.isInspecting(this)) return runtime.newString("{...}");
try {
runtime.registerInspecting(this);
return to_a().to_s();
} finally {
runtime.unregisterInspecting(this);
}
}
@JRubyMethod(name = "to_s", compat = RUBY1_9)
public IRubyObject to_s19(ThreadContext context) {
return inspect(context);
}
/** rb_hash_rehash
*
*/
@JRubyMethod(name = "rehash")
public RubyHash rehash() {
if (iteratorCount.get() > 0) {
throw getRuntime().newRuntimeError("rehash during iteration");
}
modify();
final RubyHashEntry[] oldTable = table;
final RubyHashEntry[] newTable = new RubyHashEntry[oldTable.length];
for (int j = 0; j < oldTable.length; j++) {
RubyHashEntry entry = oldTable[j];
oldTable[j] = null;
while (entry != null) {
RubyHashEntry next = entry.next;
entry.hash = hashValue(entry.key.hashCode()); // update the hash value
int i = bucketIndex(entry.hash, newTable.length);
entry.next = newTable[i];
newTable[i] = entry;
entry = next;
}
}
table = newTable;
return this;
}
/** rb_hash_to_hash
*
*/
@JRubyMethod(name = "to_hash")
public RubyHash to_hash() {
return this;
}
@Override
public RubyHash convertToHash() {
return this;
}
public final void fastASet(IRubyObject key, IRubyObject value) {
internalPut(key, value);
}
public final RubyHash fastASetChained(IRubyObject key, IRubyObject value) {
internalPut(key, value);
return this;
}
public final void fastASetCheckString(Ruby runtime, IRubyObject key, IRubyObject value) {
if (key instanceof RubyString) {
op_asetForString(runtime, (RubyString) key, value);
} else {
internalPut(key, value);
}
}
public final void fastASetSmallCheckString(Ruby runtime, IRubyObject key, IRubyObject value) {
if (key instanceof RubyString) {
op_asetSmallForString(runtime, (RubyString) key, value);
} else {
internalPutSmall(key, value);
}
}
public final void fastASetCheckString19(Ruby runtime, IRubyObject key, IRubyObject value) {
if (key.getMetaClass().getRealClass() == runtime.getString()) {
op_asetForString(runtime, (RubyString) key, value);
} else {
internalPut(key, value);
}
}
public final void fastASetSmallCheckString19(Ruby runtime, IRubyObject key, IRubyObject value) {
if (key.getMetaClass().getRealClass() == runtime.getString()) {
op_asetSmallForString(runtime, (RubyString) key, value);
} else {
internalPutSmall(key, value);
}
}
@Deprecated
public IRubyObject op_aset(IRubyObject key, IRubyObject value) {
return op_aset(getRuntime().getCurrentContext(), key, value);
}
/** rb_hash_aset
*
*/
@JRubyMethod(name = {"[]=", "store"}, required = 2, compat = RUBY1_8)
public IRubyObject op_aset(ThreadContext context, IRubyObject key, IRubyObject value) {
modify();
fastASetCheckString(context.runtime, key, value);
return value;
}
@JRubyMethod(name = {"[]=", "store"}, required = 2, compat = RUBY1_9)
public IRubyObject op_aset19(ThreadContext context, IRubyObject key, IRubyObject value) {
modify();
fastASetCheckString19(context.runtime, key, value);
return value;
}
protected void op_asetForString(Ruby runtime, RubyString key, IRubyObject value) {
final RubyHashEntry entry = internalGetEntry(key);
if (entry != NO_ENTRY) {
entry.value = value;
} else {
checkIterating();
if (!key.isFrozen()) {
key = key.strDup(runtime, key.getMetaClass().getRealClass());
key.setFrozen(true);
}
internalPut(key, value, false);
}
}
protected void op_asetSmallForString(Ruby runtime, RubyString key, IRubyObject value) {
final RubyHashEntry entry = internalGetEntry(key);
if (entry != NO_ENTRY) {
entry.value = value;
} else {
checkIterating();
if (!key.isFrozen()) {
key = key.strDup(runtime, key.getMetaClass().getRealClass());
key.setFrozen(true);
}
internalPutSmall(key, value, false);
}
}
/**
* Note: this is included as a compatibility measure for AR-JDBC
* @deprecated use RubyHash.op_aset instead
*/
public IRubyObject aset(IRubyObject key, IRubyObject value) {
return op_aset(getRuntime().getCurrentContext(), key, value);
}
/**
* Note: this is included as a compatibility measure for Mongrel+JRuby
* @deprecated use RubyHash.op_aref instead
*/
public IRubyObject aref(IRubyObject key) {
return op_aref(getRuntime().getCurrentContext(), key);
}
public final IRubyObject fastARef(IRubyObject key) { // retuns null when not found to avoid unnecessary getRuntime().getNil() call
return internalGet(key);
}
public RubyBoolean compare(final ThreadContext context, final MethodNames method, IRubyObject other) {
Ruby runtime = context.runtime;
if (!(other instanceof RubyHash)) {
if (!other.respondsTo("to_hash")) {
return runtime.getFalse();
} else {
return RuntimeHelpers.rbEqual(context, other, this);
}
}
final RubyHash otherHash = (RubyHash) other;
if (this.size != otherHash.size) {
return runtime.getFalse();
}
try {
visitAll(new Visitor() {
public void visit(IRubyObject key, IRubyObject value) {
IRubyObject value2 = otherHash.fastARef(key);
if (value2 == null) {
// other hash does not contain key
throw MISMATCH;
}
if (!(method == MethodNames.OP_EQUAL ?
RuntimeHelpers.rbEqual(context, value, value2) :
RuntimeHelpers.rbEql(context, value, value2)).isTrue()) {
throw MISMATCH;
}
}
});
} catch (Mismatch e) {
return runtime.getFalse();
}
return runtime.getTrue();
}
/** rb_hash_equal
*
*/
@JRubyMethod(name = "==")
public IRubyObject op_equal(final ThreadContext context, IRubyObject other) {
return RecursiveComparator.compare(context, MethodNames.OP_EQUAL, this, other);
}
/** rb_hash_eql
*
*/
@JRubyMethod(name = "eql?")
public IRubyObject op_eql19(final ThreadContext context, IRubyObject other) {
return RecursiveComparator.compare(context, MethodNames.EQL, this, other);
}
/** rb_hash_aref
*
*/
@JRubyMethod(name = "[]", required = 1)
public IRubyObject op_aref(ThreadContext context, IRubyObject key) {
IRubyObject value;
return ((value = internalGet(key)) == null) ? callMethod(context, "default", key) : value;
}
/** rb_hash_hash
*
*/
@JRubyMethod(name = "hash", compat = RUBY1_8)
public RubyFixnum hash() {
final Ruby runtime = getRuntime();
final ThreadContext context = runtime.getCurrentContext();
if (size == 0 || runtime.isInspecting(this)) return RubyFixnum.zero(runtime);
final long hash[] = new long[]{size};
try {
runtime.registerInspecting(this);
visitAll(new Visitor() {
public void visit(IRubyObject key, IRubyObject value) {
hash[0] ^= invokedynamic(context, key, HASH).convertToInteger().getLongValue();
hash[0] ^= invokedynamic(context, value, HASH).convertToInteger().getLongValue();
}
});
} finally {
runtime.unregisterInspecting(this);
}
return RubyFixnum.newFixnum(runtime, hash[0]);
}
/** rb_hash_hash
*
*/
@JRubyMethod(name = "hash", compat = RUBY1_9)
public RubyFixnum hash19() {
final Ruby runtime = getRuntime();
final ThreadContext context = runtime.getCurrentContext();
return (RubyFixnum)getRuntime().execRecursiveOuter(new Ruby.RecursiveFunction() {
public IRubyObject call(IRubyObject obj, boolean recur) {
if(size == 0) {
return RubyFixnum.zero(runtime);
}
final long[] h = new long[]{size};
if(recur) {
h[0] ^= RubyNumeric.num2long(invokedynamic(context, runtime.getHash(), HASH));
} else {
visitAll(new Visitor() {
public void visit(IRubyObject key, IRubyObject value) {
h[0] ^= invokedynamic(context, key, HASH).convertToInteger().getLongValue();
h[0] ^= invokedynamic(context, value, HASH).convertToInteger().getLongValue();
}
});
}
return runtime.newFixnum(h[0]);
}
}, this);
}
/** rb_hash_fetch
*
*/
@JRubyMethod(required = 1, optional = 1)
public IRubyObject fetch(ThreadContext context, IRubyObject[] args, Block block) {
Ruby runtime = context.runtime;
if (args.length == 2 && block.isGiven()) {
getRuntime().getWarnings().warn(ID.BLOCK_BEATS_DEFAULT_VALUE, "block supersedes default value argument");
}
IRubyObject value;
if ((value = internalGet(args[0])) == null) {
if (block.isGiven()) return block.yield(context, args[0]);
if (args.length == 1) {
if (runtime.is1_9()) {
throw runtime.newKeyError("key not found: " + args[0]);
} else {
throw runtime.newIndexError("key not found");
}
}
return args[1];
}
return value;
}
/** rb_hash_has_key
*
*/
@JRubyMethod(name = {"has_key?", "key?", "include?", "member?"}, required = 1)
public RubyBoolean has_key_p(IRubyObject key) {
return internalGetEntry(key) == NO_ENTRY ? getRuntime().getFalse() : getRuntime().getTrue();
}
private static class Found extends RuntimeException {
@Override
public synchronized Throwable fillInStackTrace() {
return null;
}
}
private static final Found FOUND = new Found();
private static class FoundKey extends Found {
public final IRubyObject key;
FoundKey(IRubyObject key) {
super();
this.key = key;
}
}
private static class FoundPair extends FoundKey {
public final IRubyObject value;
FoundPair(IRubyObject key, IRubyObject value) {
super(key);
this.value = value;
}
}
private boolean hasValue(final ThreadContext context, final IRubyObject expected) {
try {
visitAll(new Visitor() {
public void visit(IRubyObject key, IRubyObject value) {
if (equalInternal(context, value, expected)) {
throw FOUND;
}
}
});
return false;
} catch (Found found) {
return true;
}
}
/** rb_hash_has_value
*
*/
@JRubyMethod(name = {"has_value?", "value?"}, required = 1)
public RubyBoolean has_value_p(ThreadContext context, IRubyObject expected) {
return getRuntime().newBoolean(hasValue(context, expected));
}
private AtomicInteger iteratorCount = new AtomicInteger(0);
private void iteratorEntry() {
iteratorCount.incrementAndGet();
}
private void iteratorExit() {
iteratorCount.decrementAndGet();
}
private void iteratorVisitAll(Visitor visitor) {
try {
iteratorEntry();
visitAll(visitor);
} finally {
iteratorExit();
}
}
/** rb_hash_each
*
*/
public RubyHash eachCommon(final ThreadContext context, final Block block) {
if (block.arity() == Arity.TWO_ARGUMENTS) {
iteratorVisitAll(new Visitor() {
public void visit(IRubyObject key, IRubyObject value) {
block.yieldSpecific(context, key, value);
}
});
} else {
final Ruby runtime = context.runtime;
iteratorVisitAll(new Visitor() {
public void visit(IRubyObject key, IRubyObject value) {
block.yield(context, RubyArray.newArray(runtime, key, value));
}
});
}
return this;
}
@JRubyMethod(compat = RUBY1_8)
public IRubyObject each(final ThreadContext context, final Block block) {
return block.isGiven() ? eachCommon(context, block) : enumeratorize(context.runtime, this, "each");
}
@JRubyMethod(name = "each", compat = RUBY1_9)
public IRubyObject each19(final ThreadContext context, final Block block) {
return block.isGiven() ? each_pairCommon(context, block, true) : enumeratorize(context.runtime, this, "each");
}
/** rb_hash_each_pair
*
*/
public RubyHash each_pairCommon(final ThreadContext context, final Block block, final boolean oneNine) {
final Ruby runtime = getRuntime();
iteratorVisitAll(new Visitor() {
public void visit(IRubyObject key, IRubyObject value) {
// rb_yield_values(2,...) equivalent
if (oneNine) {
block.yield(context, RubyArray.newArray(runtime, key, value));
} else {
block.yieldArray(context, RubyArray.newArray(runtime, key, value), null, null);
}
}
});
return this;
}
@JRubyMethod
public IRubyObject each_pair(final ThreadContext context, final Block block) {
return block.isGiven() ? each_pairCommon(context, block, context.runtime.is1_9()) : enumeratorize(context.runtime, this, "each_pair");
}
/** rb_hash_each_value
*
*/
public RubyHash each_valueCommon(final ThreadContext context, final Block block) {
iteratorVisitAll(new Visitor() {
public void visit(IRubyObject key, IRubyObject value) {
block.yield(context, value);
}
});
return this;
}
@JRubyMethod
public IRubyObject each_value(final ThreadContext context, final Block block) {
return block.isGiven() ? each_valueCommon(context, block) : enumeratorize(context.runtime, this, "each_value");
}
/** rb_hash_each_key
*
*/
public RubyHash each_keyCommon(final ThreadContext context, final Block block) {
iteratorVisitAll(new Visitor() {
public void visit(IRubyObject key, IRubyObject value) {
block.yield(context, key);
}
});
return this;
}
@JRubyMethod
public IRubyObject each_key(final ThreadContext context, final Block block) {
return block.isGiven() ? each_keyCommon(context, block) : enumeratorize(context.runtime, this, "each_key");
}
@JRubyMethod(name = "select!", compat = RUBY1_9)
public IRubyObject select_bang(final ThreadContext context, final Block block) {
if (block.isGiven()) {
if (keep_ifCommon(context, block)) {
return this;
} else {
return context.runtime.getNil();
}
} else {
return enumeratorize(context.runtime, this, "each_key");
}
}
@JRubyMethod(compat = RUBY1_9)
public IRubyObject keep_if(final ThreadContext context, final Block block) {
if (block.isGiven()) {
keep_ifCommon(context, block);
return this;
} else {
return enumeratorize(context.runtime, this, "each_key");
}
}
public boolean keep_ifCommon(final ThreadContext context, final Block block) {
testFrozen("hash");
final boolean[] modified = {false};
iteratorVisitAll(new Visitor() {
public void visit(IRubyObject key, IRubyObject value) {
if (!block.yieldSpecific(context, key, value).isTrue()) {
modified[0] = true;
remove(key);
}
}
});
return modified[0];
}
/** rb_hash_sort
*
*/
@JRubyMethod
public IRubyObject sort(ThreadContext context, Block block) {
return to_a().sort_bang(context, block);
}
/** rb_hash_index
*
*/
@JRubyMethod(compat = RUBY1_8)
public IRubyObject index(ThreadContext context, IRubyObject expected) {
IRubyObject key = internalIndex(context, expected);
return key != null ? key : context.runtime.getNil();
}
@JRubyMethod(name = "index", compat = RUBY1_9)
public IRubyObject index19(ThreadContext context, IRubyObject expected) {
context.runtime.getWarnings().warn(ID.DEPRECATED_METHOD, "Hash#index is deprecated; use Hash#key");
return key(context, expected);
}
@JRubyMethod(compat = RUBY1_9)
public IRubyObject key(ThreadContext context, IRubyObject expected) {
IRubyObject key = internalIndex(context, expected);
return key != null ? key : context.runtime.getNil();
}
private IRubyObject internalIndex(final ThreadContext context, final IRubyObject expected) {
try {
visitAll(new Visitor() {
public void visit(IRubyObject key, IRubyObject value) {
if (equalInternal(context, value, expected)) {
throw new FoundKey(key);
}
}
});
return null;
} catch (FoundKey found) {
return found.key;
}
}
/** rb_hash_indexes
*
*/
@JRubyMethod(name = {"indexes", "indices"}, rest = true)
public RubyArray indices(ThreadContext context, IRubyObject[] indices) {
return values_at(context, indices);
}
/** rb_hash_keys
*
*/
@JRubyMethod(name = "keys")
public RubyArray keys() {
final Ruby runtime = getRuntime();
try {
final RubyArray keys = RubyArray.newArray(runtime, size);
visitAll(new Visitor() {
public void visit(IRubyObject key, IRubyObject value) {
keys.append(key);
}
});
return keys;
} catch (NegativeArraySizeException nase) {
throw concurrentModification();
}
}
/** rb_hash_values
*
*/
@JRubyMethod(name = "values")
public RubyArray rb_values() {
try {
final RubyArray values = RubyArray.newArray(getRuntime(), size);
visitAll(new Visitor() {
public void visit(IRubyObject key, IRubyObject value) {
values.append(value);
}
});
return values;
} catch (NegativeArraySizeException nase) {
throw concurrentModification();
}
}
/** rb_hash_equal
*
*/
private static class Mismatch extends RuntimeException {}
private static final Mismatch MISMATCH = new Mismatch();
/** rb_hash_shift
*
*/
@JRubyMethod(name = "shift")
public IRubyObject shift(ThreadContext context) {
modify();
RubyHashEntry entry = head.nextAdded;
if (entry != head) {
RubyArray result = RubyArray.newArray(getRuntime(), entry.key, entry.value);
internalDeleteEntry(entry);
return result;
}
if ((flags & PROCDEFAULT_HASH_F) != 0) {
return RuntimeHelpers.invoke(context, ifNone, "call", this, getRuntime().getNil());
} else {
return ifNone;
}
}
public final boolean fastDelete(IRubyObject key) {
return internalDelete(key) != NO_ENTRY;
}
/** rb_hash_delete
*
*/
@JRubyMethod
public IRubyObject delete(ThreadContext context, IRubyObject key, Block block) {
modify();
final RubyHashEntry entry = internalDelete(key);
if (entry != NO_ENTRY) return entry.value;
if (block.isGiven()) return block.yield(context, key);
return getRuntime().getNil();
}
/** rb_hash_select
*
*/
@JRubyMethod
public IRubyObject select(final ThreadContext context, final Block block) {
final Ruby runtime = getRuntime();
if (!block.isGiven()) return enumeratorize(runtime, this, "select");
final RubyArray result = runtime.newArray();
iteratorVisitAll(new Visitor() {
public void visit(IRubyObject key, IRubyObject value) {
if (block.yieldArray(context, runtime.newArray(key, value), null, null).isTrue()) {
result.append(runtime.newArray(key, value));
}
}
});
return result;
}
@JRubyMethod(name = "select", compat = RUBY1_9)
public IRubyObject select19(final ThreadContext context, final Block block) {
final Ruby runtime = context.runtime;
if (!block.isGiven()) return enumeratorize(runtime, this, "select");
final RubyHash result = newHash(runtime);
iteratorVisitAll(new Visitor() {
public void visit(IRubyObject key, IRubyObject value) {
if (block.yieldArray(context, runtime.newArray(key, value), null, null).isTrue()) {
result.fastASet(key, value);
}
}
});
return result;
}
/** rb_hash_delete_if
*
*/
public RubyHash delete_ifInternal(final ThreadContext context, final Block block) {
modify();
final Ruby runtime = getRuntime();
final RubyHash self = this;
iteratorVisitAll(new Visitor() {
public void visit(IRubyObject key, IRubyObject value) {
if (block.yieldArray(context, RubyArray.newArray(runtime, key, value), null, null).isTrue()) {
self.delete(context, key, Block.NULL_BLOCK);
}
}
});
return this;
}
@JRubyMethod
public IRubyObject delete_if(final ThreadContext context, final Block block) {
return block.isGiven() ? delete_ifInternal(context, block) : enumeratorize(context.runtime, this, "delete_if");
}
/** rb_hash_reject
*
*/
public RubyHash rejectInternal(ThreadContext context, Block block) {
return ((RubyHash)dup()).delete_ifInternal(context, block);
}
@JRubyMethod
public IRubyObject reject(final ThreadContext context, final Block block) {
return block.isGiven() ? rejectInternal(context, block) : enumeratorize(context.runtime, this, "reject");
}
/** rb_hash_reject_bang
*
*/
public IRubyObject reject_bangInternal(ThreadContext context, Block block) {
int n = size;
delete_if(context, block);
if (n == size) return getRuntime().getNil();
return this;
}
@JRubyMethod(name = "reject!")
public IRubyObject reject_bang(final ThreadContext context, final Block block) {
return block.isGiven() ? reject_bangInternal(context, block) : enumeratorize(context.runtime, this, "reject!");
}
/** rb_hash_clear
*
*/
@JRubyMethod(name = "clear")
public RubyHash rb_clear() {
modify();
if (size > 0) {
alloc();
size = 0;
}
return this;
}
/** rb_hash_invert
*
*/
@JRubyMethod(name = "invert")
public RubyHash invert(final ThreadContext context) {
final RubyHash result = newHash(getRuntime());
visitAll(new Visitor() {
public void visit(IRubyObject key, IRubyObject value) {
result.op_aset(context, value, key);
}
});
return result;
}
/** rb_hash_update
*
*/
@JRubyMethod(name = {"merge!", "update"}, required = 1, compat = RUBY1_8)
public RubyHash merge_bang(final ThreadContext context, final IRubyObject other, final Block block) {
final RubyHash otherHash = other.convertToHash();
if (otherHash.empty_p().isTrue()) {
return this;
}
modify();
final Ruby runtime = getRuntime();
final RubyHash self = this;
otherHash.visitAll(new Visitor() {
public void visit(IRubyObject key, IRubyObject value) {
if (block.isGiven()) {
IRubyObject existing = self.internalGet(key);
if (existing != null) {
value = block.yield(context, RubyArray.newArrayNoCopy(runtime, new IRubyObject[]{key, existing, value}));
}
}
self.op_aset(context, key, value);
}
});
return this;
}
/** rb_hash_update
*
*/
@JRubyMethod(name = {"merge!", "update"}, required = 1, compat = RUBY1_9)
public RubyHash merge_bang19(final ThreadContext context, final IRubyObject other, final Block block) {
modify();
final RubyHash otherHash = other.convertToHash();
if (otherHash.empty_p().isTrue()) {
return this;
}
final Ruby runtime = getRuntime();
final RubyHash self = this;
otherHash.visitAll(new Visitor() {
public void visit(IRubyObject key, IRubyObject value) {
if (block.isGiven()) {
IRubyObject existing = self.internalGet(key);
if (existing != null) {
value = block.yield(context, RubyArray.newArrayNoCopy(runtime, new IRubyObject[]{key, existing, value}));
}
}
self.op_aset(context, key, value);
}
});
return this;
}
/** rb_hash_merge
*
*/
@JRubyMethod
public RubyHash merge(ThreadContext context, IRubyObject other, Block block) {
return ((RubyHash)dup()).merge_bang(context, other, block);
}
/** rb_hash_replace
*
*/
@JRubyMethod(visibility = PRIVATE, compat = RUBY1_8)
public RubyHash initialize_copy(ThreadContext context, IRubyObject other) {
return replace(context, other);
}
/** rb_hash_replace
*
*/
@JRubyMethod(name = "initialize_copy", required = 1, visibility = PRIVATE, compat = RUBY1_9)
public RubyHash initialize_copy19(ThreadContext context, IRubyObject other) {
return replace19(context, other);
}
/** rb_hash_replace
*
*/
@JRubyMethod(name = "replace", required = 1, compat = RUBY1_8)
public RubyHash replace(final ThreadContext context, IRubyObject other) {
final RubyHash self = this;
return replaceCommon(context, other, new Visitor() {
public void visit(IRubyObject key, IRubyObject value) {
self.op_aset(context, key, value);
}
});
}
@JRubyMethod(name = "replace", required = 1, compat = RUBY1_9)
public RubyHash replace19(final ThreadContext context, IRubyObject other) {
final RubyHash self = this;
return replaceCommon19(context, other, new Visitor() {
public void visit(IRubyObject key, IRubyObject value) {
self.op_aset19(context, key, value);
}
});
}
private RubyHash replaceCommon(final ThreadContext context, IRubyObject other, Visitor visitor) {
final RubyHash otherHash = other.convertToHash();
if (this == otherHash) return this;
rb_clear();
if (!isComparedByIdentity() && otherHash.isComparedByIdentity()) {
setComparedByIdentity(true);
}
otherHash.visitAll(visitor);
ifNone = otherHash.ifNone;
if ((otherHash.flags & PROCDEFAULT_HASH_F) != 0) {
flags |= PROCDEFAULT_HASH_F;
} else {
flags &= ~PROCDEFAULT_HASH_F;
}
return this;
}
private RubyHash replaceCommon19(final ThreadContext context, IRubyObject other, Visitor visitor) {
final RubyHash otherHash = other.convertToHash();
rb_clear();
if (this == otherHash) return this;
if (!isComparedByIdentity() && otherHash.isComparedByIdentity()) {
setComparedByIdentity(true);
}
otherHash.visitAll(visitor);
ifNone = otherHash.ifNone;
if ((otherHash.flags & PROCDEFAULT_HASH_F) != 0) {
flags |= PROCDEFAULT_HASH_F;
} else {
flags &= ~PROCDEFAULT_HASH_F;
}
return this;
}
/** rb_hash_values_at
*
*/
@JRubyMethod(name = "values_at", rest = true)
public RubyArray values_at(ThreadContext context, IRubyObject[] args) {
RubyArray result = RubyArray.newArray(getRuntime(), args.length);
for (int i = 0; i < args.length; i++) {
result.append(op_aref(context, args[i]));
}
return result;
}
@JRubyMethod(name = "assoc", compat = RUBY1_9)
public IRubyObject assoc(final ThreadContext context, final IRubyObject obj) {
try {
visitAll(new Visitor() {
public void visit(IRubyObject key, IRubyObject value) {
if (equalInternal(context, obj, key)) {
throw new FoundPair(key, value);
}
}
});
return context.runtime.getNil();
} catch (FoundPair found) {
return context.runtime.newArray(found.key, found.value);
}
}
@JRubyMethod(name = "rassoc", compat = RUBY1_9)
public IRubyObject rassoc(final ThreadContext context, final IRubyObject obj) {
try {
visitAll(new Visitor() {
public void visit(IRubyObject key, IRubyObject value) {
if (equalInternal(context, obj, value)) {
throw new FoundPair(key, value);
}
}
});
return context.runtime.getNil();
} catch (FoundPair found) {
return context.runtime.newArray(found.key, found.value);
}
}
@JRubyMethod(name = "flatten", compat = RUBY1_9)
public IRubyObject flatten(ThreadContext context) {
RubyArray ary = to_a();
ary.callMethod(context, "flatten!", RubyFixnum.one(context.runtime));
return ary;
}
@JRubyMethod(name = "flatten", compat = RUBY1_9)
public IRubyObject flatten(ThreadContext context, IRubyObject level) {
RubyArray ary = to_a();
ary.callMethod(context, "flatten!", level);
return ary;
}
@JRubyMethod(name = "compare_by_identity", compat = RUBY1_9)
public IRubyObject getCompareByIdentity(ThreadContext context) {
modify();
setComparedByIdentity(true);
return this;
}
@JRubyMethod(name = "compare_by_identity?", compat = RUBY1_9)
public IRubyObject getCompareByIdentity_p(ThreadContext context) {
return context.runtime.newBoolean(isComparedByIdentity());
}
@JRubyMethod(compat = RUBY1_9)
public IRubyObject dup(ThreadContext context) {
RubyHash dup = (RubyHash) super.dup();
dup.setComparedByIdentity(isComparedByIdentity());
return dup;
}
@JRubyMethod(name = "clone", compat = RUBY1_9)
public IRubyObject rbClone(ThreadContext context) {
RubyHash clone = (RubyHash) super.rbClone();
clone.setComparedByIdentity(isComparedByIdentity());
return clone;
}
public boolean hasDefaultProc() {
return (flags & PROCDEFAULT_HASH_F) != 0;
}
public IRubyObject getIfNone(){
return ifNone;
}
private static class VisitorIOException extends RuntimeException {
VisitorIOException(Throwable cause) {
super(cause);
}
}
// FIXME: Total hack to get flash in Rails marshalling/unmarshalling in session ok...We need
// to totally change marshalling to work with overridden core classes.
public static void marshalTo(final RubyHash hash, final MarshalStream output) throws IOException {
output.registerLinkTarget(hash);
output.writeInt(hash.size);
try {
hash.visitAll(new Visitor() {
public void visit(IRubyObject key, IRubyObject value) {
try {
output.dumpObject(key);
output.dumpObject(value);
} catch (IOException e) {
throw new VisitorIOException(e);
}
}
});
} catch (VisitorIOException e) {
throw (IOException)e.getCause();
}
if (!hash.ifNone.isNil()) output.dumpObject(hash.ifNone);
}
public static RubyHash unmarshalFrom(UnmarshalStream input, boolean defaultValue) throws IOException {
RubyHash result = newHash(input.getRuntime());
input.registerLinkTarget(result);
int size = input.unmarshalInt();
for (int i = 0; i < size; i++) {
result.fastASetCheckString(input.getRuntime(), input.unmarshalObject(), input.unmarshalObject());
}
if (defaultValue) result.default_value_set(input.unmarshalObject());
return result;
}
@Override
public Class getJavaClass() {
return Map.class;
}
// Satisfy java.util.Set interface (for Java integration)
public int size() {
return size;
}
public boolean isEmpty() {
return size == 0;
}
public boolean containsKey(Object key) {
return internalGet(JavaUtil.convertJavaToUsableRubyObject(getRuntime(), key)) != null;
}
public boolean containsValue(Object value) {
return hasValue(getRuntime().getCurrentContext(), JavaUtil.convertJavaToUsableRubyObject(getRuntime(), value));
}
public Object get(Object key) {
IRubyObject gotten = internalGet(JavaUtil.convertJavaToUsableRubyObject(getRuntime(), key));
return gotten == null ? null : gotten.toJava(Object.class);
}
public Object put(Object key, Object value) {
internalPut(JavaUtil.convertJavaToUsableRubyObject(getRuntime(), key), JavaUtil.convertJavaToUsableRubyObject(getRuntime(), value));
return value;
}
public Object remove(Object key) {
IRubyObject rubyKey = JavaUtil.convertJavaToUsableRubyObject(getRuntime(), key);
return internalDelete(rubyKey).value;
}
public void putAll(Map map) {
Ruby runtime = getRuntime();
for (Iterator<Map.Entry> iter = map.entrySet().iterator(); iter.hasNext();) {
Map.Entry entry = iter.next();
internalPut(JavaUtil.convertJavaToUsableRubyObject(runtime, entry.getKey()), JavaUtil.convertJavaToUsableRubyObject(runtime, entry.getValue()));
}
}
public void clear() {
rb_clear();
}
@Override
public boolean equals(Object other) {
if (!(other instanceof RubyHash)) return false;
if (this == other) return true;
return op_equal(getRuntime().getCurrentContext(), (RubyHash)other).isTrue() ? true : false;
}
public Set keySet() {
return new BaseSet(KEY_VIEW);
}
public Set directKeySet() {
return new BaseSet(DIRECT_KEY_VIEW);
}
public Collection values() {
return new BaseCollection(VALUE_VIEW);
}
public Collection directValues() {
return new BaseCollection(DIRECT_VALUE_VIEW);
}
public Set entrySet() {
return new BaseSet(ENTRY_VIEW);
}
public Set directEntrySet() {
return new BaseSet(DIRECT_ENTRY_VIEW);
}
private final RaiseException concurrentModification() {
return getRuntime().newConcurrencyError(
"Detected invalid hash contents due to unsynchronized modifications with concurrent users");
}
/**
* Is this object compared by identity or not? Shortcut for doing
* getFlag(COMPARE_BY_IDENTITY_F).
*
* @return true if this object is compared by identity, false otherwise
*/
protected boolean isComparedByIdentity() {
return (flags & COMPARE_BY_IDENTITY_F) != 0;
}
/**
* Sets whether this object is compared by identity or not. Shortcut for doing
* setFlag(COMPARE_BY_IDENTITY_F, frozen).
*
* @param comparedByIdentity should this object be compared by identity?
*/
public void setComparedByIdentity(boolean comparedByIdentity) {
if (comparedByIdentity) {
flags |= COMPARE_BY_IDENTITY_F;
} else {
flags &= ~COMPARE_BY_IDENTITY_F;
}
}
private class BaseSet extends AbstractSet {
final EntryView view;
public BaseSet(EntryView view) {
this.view = view;
}
public Iterator iterator() {
return new BaseIterator(view);
}
@Override
public boolean contains(Object o) {
return view.contains(RubyHash.this, o);
}
@Override
public void clear() {
RubyHash.this.clear();
}
public int size() {
return RubyHash.this.size;
}
@Override
public boolean remove(Object o) {
return view.remove(RubyHash.this, o);
}
}
private class BaseCollection extends AbstractCollection {
final EntryView view;
public BaseCollection(EntryView view) {
this.view = view;
}
public Iterator iterator() {
return new BaseIterator(view);
}
@Override
public boolean contains(Object o) {
return view.contains(RubyHash.this, o);
}
@Override
public void clear() {
RubyHash.this.clear();
}
public int size() {
return RubyHash.this.size;
}
@Override
public boolean remove(Object o) {
return view.remove(RubyHash.this, o);
}
}
private class BaseIterator implements Iterator {
final private EntryView view;
private RubyHashEntry entry;
private boolean peeking;
private int startGeneration;
public BaseIterator(EntryView view) {
this.view = view;
this.entry = head;
this.startGeneration = generation;
}
private void advance(boolean consume) {
if (!peeking) {
do {
if (startGeneration != generation) {
startGeneration = generation;
entry = head;
}
entry = entry.nextAdded;
} while (entry != head && !entry.isLive());
}
peeking = !consume;
}
public Object next() {
advance(true);
if (entry == head) {
peeking = true; // remain where we are
throw new NoSuchElementException();
}
return view.convertEntry(getRuntime(), entry);
}
// once hasNext has been called, we commit to next() returning
// the entry it found, even if it were subsequently deleted
public boolean hasNext() {
advance(false);
return entry != head;
}
public void remove() {
if (entry == head) {
throw new IllegalStateException("Iterator out of range");
}
internalDeleteEntry(entry);
}
}
private static abstract class EntryView {
public abstract Object convertEntry(Ruby runtime, RubyHashEntry value);
public abstract boolean contains(RubyHash hash, Object o);
public abstract boolean remove(RubyHash hash, Object o);
}
private static final EntryView DIRECT_KEY_VIEW = new EntryView() {
public Object convertEntry(Ruby runtime, RubyHashEntry entry) {
return entry.key;
}
public boolean contains(RubyHash hash, Object o) {
if (!(o instanceof IRubyObject)) return false;
return hash.internalGet((IRubyObject)o) != null;
}
public boolean remove(RubyHash hash, Object o) {
if (!(o instanceof IRubyObject)) return false;
return hash.internalDelete((IRubyObject)o) != NO_ENTRY;
}
};
private static final EntryView KEY_VIEW = new EntryView() {
public Object convertEntry(Ruby runtime, RubyHashEntry entry) {
return entry.key.toJava(Object.class);
}
public boolean contains(RubyHash hash, Object o) {
return hash.containsKey(o);
}
public boolean remove(RubyHash hash, Object o) {
return hash.remove(o) != null;
}
};
private static final EntryView DIRECT_VALUE_VIEW = new EntryView() {
public Object convertEntry(Ruby runtime, RubyHashEntry entry) {
return entry.value;
}
public boolean contains(RubyHash hash, Object o) {
if (!(o instanceof IRubyObject)) return false;
IRubyObject obj = (IRubyObject)o;
return hash.hasValue(obj.getRuntime().getCurrentContext(), obj);
}
public boolean remove(RubyHash hash, Object o) {
if (!(o instanceof IRubyObject)) return false;
IRubyObject obj = (IRubyObject) o;
IRubyObject key = hash.internalIndex(obj.getRuntime().getCurrentContext(), obj);
if (key == null) return false;
return hash.internalDelete(key) != NO_ENTRY;
}
};
private static final EntryView VALUE_VIEW = new EntryView() {
public Object convertEntry(Ruby runtime, RubyHashEntry entry) {
return entry.value.toJava(Object.class);
}
public boolean contains(RubyHash hash, Object o) {
return hash.containsValue(o);
}
public boolean remove(RubyHash hash, Object o) {
IRubyObject value = JavaUtil.convertJavaToUsableRubyObject(hash.getRuntime(), o);
IRubyObject key = hash.internalIndex(hash.getRuntime().getCurrentContext(), value);
if (key == null) return false;
return hash.internalDelete(key) != NO_ENTRY;
}
};
private static final EntryView DIRECT_ENTRY_VIEW = new EntryView() {
public Object convertEntry(Ruby runtime, RubyHashEntry entry) {
return entry;
}
public boolean contains(RubyHash hash, Object o) {
if (!(o instanceof RubyHashEntry)) return false;
RubyHashEntry entry = (RubyHashEntry)o;
RubyHashEntry candidate = hash.internalGetEntry(entry.key);
return candidate != NO_ENTRY && entry.equals(candidate);
}
public boolean remove(RubyHash hash, Object o) {
if (!(o instanceof RubyHashEntry)) return false;
return hash.internalDeleteEntry((RubyHashEntry)o) != NO_ENTRY;
}
};
private static final EntryView ENTRY_VIEW = new EntryView() {
public Object convertEntry(Ruby runtime, RubyHashEntry entry) {
return new ConvertingEntry(runtime, entry);
}
public boolean contains(RubyHash hash, Object o) {
if (!(o instanceof ConvertingEntry)) return false;
ConvertingEntry entry = (ConvertingEntry)o;
RubyHashEntry candidate = hash.internalGetEntry(entry.entry.key);
return candidate != NO_ENTRY && entry.entry.equals(candidate);
}
public boolean remove(RubyHash hash, Object o) {
if (!(o instanceof ConvertingEntry)) return false;
ConvertingEntry entry = (ConvertingEntry)o;
return hash.internalDeleteEntry(entry.entry) != NO_ENTRY;
}
};
private static class ConvertingEntry implements Map.Entry {
private final RubyHashEntry entry;
private final Ruby runtime;
public ConvertingEntry(Ruby runtime, RubyHashEntry entry) {
this.entry = entry;
this.runtime = runtime;
}
public Object getKey() {
return entry.key.toJava(Object.class);
}
public Object getValue() {
return entry.value.toJava(Object.class);
}
public Object setValue(Object o) {
return entry.setValue(JavaUtil.convertJavaToUsableRubyObject(runtime, o));
}
@Override
public boolean equals(Object o) {
if (!(o instanceof ConvertingEntry)) {
return false;
}
ConvertingEntry other = (ConvertingEntry)o;
return entry.equals(other.entry);
}
@Override
public int hashCode() {
return entry.hashCode();
}
}
}