Mercurial > hg > Members > kono > jpf-core
view src/main/gov/nasa/jpf/util/IntTable.java @ 4:d0a0ff1c0e10
added some infrastructure to pull-generate permutations (total, random and
pair-wise so far). The generators produce index arrays, i.e. permutations of
[0..N-1], which can be used to permute processing order of any indexable data
structure, for instance in CGs. This also includes a bare-bones PermutationCG
that takes the desired PermutationGenerator as input. Due to the N! nature of
the beast, beware of TotalPermutations in such CGs, even if most permutations
are handled by state matching.
| author | Peter Mehlitz <pcmehlitz@gmail.com> |
|---|---|
| date | Thu, 05 Feb 2015 18:53:33 -0800 |
| parents | 61d41facf527 |
| children |
line wrap: on
line source
/* * Copyright (C) 2014, United States Government, as represented by the * Administrator of the National Aeronautics and Space Administration. * All rights reserved. * * The Java Pathfinder core (jpf-core) platform is licensed under the * Apache License, Version 2.0 (the "License"); you may not use this file except * in compliance with the License. You may obtain a copy of the License at * * http://www.apache.org/licenses/LICENSE-2.0. * * Unless required by applicable law or agreed to in writing, software * distributed under the License is distributed on an "AS IS" BASIS, * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. * See the License for the specific language governing permissions and * limitations under the License. */ package gov.nasa.jpf.util; import gov.nasa.jpf.JPFException; import java.util.Iterator; /** * A hash map that holds int values associated with generic key objects. * This is a straight forward linked list hashmap. * * Key objects have to be invariant, lookup uses equality but checks for * identity as an optimization. * * note: this does deep copy clones, which can be quite expensive */ public final class IntTable<E> implements Iterable<IntTable.Entry<E>>, Cloneable{ static final int INIT_TBL_POW = 7; static final double MAX_LOAD = 0.80; //--- inner types /** * encapsulates an Entry in the table. changes to val will be reflected * in the table. */ public static class Entry<E> implements Cloneable { public final E key; public final int val; protected Entry<E> next; protected Entry(E k, int v) { key = k; val = v; next = null; } protected Entry(E k, int v, Entry<E> n) { key = k; val = v; next = n; } @Override @SuppressWarnings("unchecked") public Entry<E> clone() { try { return (Entry<E>)super.clone(); } catch (CloneNotSupportedException x){ throw new JPFException("clone failed"); } } @Override public String toString() { return key.toString() + " => " + val; } //--- methods required to use IntTable entries itself as HashMap keys // but beware - val can be modified since we expose it (never modify // key objects of HashMaps) @Override public int hashCode (){ return OATHash.hash(key.hashCode(), val); } @Override public boolean equals (Object o){ if (o instanceof Entry){ @SuppressWarnings("unchecked") Entry<E> other = (Entry<E>)o; if (val == other.val){ E k = other.key; if (key == k || key.equals(k)){ return true; } } } return false; } } /** * helper class to store a compact, invariant representation of this table */ public static class Snapshot<E> { protected final int tblSize; protected final int tblPow; protected final int[] indices; protected final E[] keys; protected final int[] vals; @SuppressWarnings("unchecked") protected Snapshot (IntTable<E> t){ Entry<E>[] tbl = t.table; int nEntries = t.size; tblSize = tbl.length; tblPow = t.tblPow; indices = new int[nEntries]; keys = (E[]) new Object[nEntries]; vals = new int[nEntries]; int j = 0; for (int i=0; i<tbl.length && j<nEntries; i++){ Entry<E> e = tbl[i]; if (e != null){ if (e.next == null){ // just one entry under this head indices[j] = i; keys[j] = e.key; vals[j] = e.val; j++; } else { // we have to store in reverse order so that restore preserves it // we do the revert here because storing happens once, whereas restore can happen many times int n = 1; for (Entry<E> ee = e.next; ee != null; ee = ee.next){ n++; } int k = j+n-1; j += n; for (; e != null; e = e.next){ indices[k] = i; keys[k] = e.key; vals[k] = e.val; k--; } } } } } } //--- instance fields protected Entry<E>[] table; // array of entry heads protected int tblPow; // = log_2(table.length) protected int mask; // = table.length - 1 protected int nextRehash; // = ceil(MAX_LOAD * table.length); protected int size; // number of Entry<E> objects reachable from table protected Entry<E> nullEntry = null; Snapshot<E> lastSnapshot; // cache for the last snapshot (nulled once the IntTable is changed) public IntTable() { this(INIT_TBL_POW); } public IntTable(int pow) { newTable(pow); size = 0; } public Snapshot<E> getSnapshot(){ if (lastSnapshot == null) { lastSnapshot = new Snapshot<E>(this); } return lastSnapshot; } @SuppressWarnings("unchecked") public void restore (Snapshot<E> snapshot){ Entry<E>[] tbl = new Entry[snapshot.tblSize]; int[] indices = snapshot.indices; E[] keys = snapshot.keys; int[] vals = snapshot.vals; int nEntries = vals.length; for (int i=0; i<nEntries; i++){ int idx = indices[i]; tbl[idx] = new Entry<E>( keys[i], vals[i], tbl[idx]); } table = tbl; size = nEntries; mask = table.length -1; nextRehash = (int) Math.ceil(MAX_LOAD * table.length); tblPow = snapshot.tblPow; lastSnapshot = snapshot; } // this is a deep copy (needs to be because entries are reused when growing the table) @Override public IntTable<E> clone() { try { @SuppressWarnings("unchecked") IntTable<E> t = (IntTable<E>)super.clone(); Entry<E>[] tbl = table.clone(); t.table = tbl; // clone entries int len = table.length; for (int i=0; i<len; i++){ Entry<E> eFirst = tbl[i]; if (eFirst != null){ eFirst = eFirst.clone(); Entry<E> ePrev = eFirst; for (Entry<E> e = eFirst.next; e != null; e = e.next){ e = e.clone(); ePrev.next = e; ePrev = e; } tbl[i] = eFirst; } } return t; } catch (CloneNotSupportedException cnsx){ throw new JPFException("clone failed"); } } @SuppressWarnings("unchecked") protected void newTable(int pow) { tblPow = pow; table = new Entry[1 << tblPow]; mask = table.length - 1; nextRehash = (int) Math.ceil(MAX_LOAD * table.length); } protected int getTableIndex(E key) { int hc = key.hashCode(); int ret = hc ^ 786668707; ret += (hc >>> tblPow); return (ret ^ 1558394450) & mask; } protected boolean maybeRehash() { if (size < nextRehash){ return false; } else { lastSnapshot = null; size = 0; Entry<E>[] old = table; int oldTblLength = old.length; newTable(tblPow + 1); int len = oldTblLength; for (int i = 0; i < len; i++) { addList(old[i]); } return true; } } private void addList(Entry<E> e) { Entry<E> cur = e; while (cur != null) { Entry<E> tmp = cur; cur = cur.next; addEntry(tmp, getTableIndex(tmp.key)); } } //--- the methods traversing the entry lists // helper for adding protected void addEntry(Entry<E> e, int idx) { e.next = table[idx]; table[idx] = e; size++; lastSnapshot = null; } // helper for searching protected Entry<E> getEntry(E key, int idx) { Entry<E> cur = table[idx]; while (cur != null) { E k = cur.key; // note - this assumes invariant keys !! if (k == key || (k.equals(key))){ return cur; } cur = cur.next; } return null; // not found } // helper for value update protected void replaceEntryValue( int idx, Entry<E> oldEntry, int newValue) { Entry<E> last = null; for (Entry<E> e = table[idx]; e != null; e = e.next, last = e) { if (e == oldEntry) { Entry<E> newEntry = new Entry<E>(oldEntry.key, newValue); newEntry.next = e.next; lastSnapshot = null; if (last == null) { table[idx] = newEntry; } else { last.next = newEntry; } } } } //--- public methods /** returns number of bindings in the table. */ public int size() { return size; } /** ONLY USE IF YOU ARE SURE NO PREVIOUS BINDING FOR key EXISTS. */ public Entry<E> add (E key, int val) { Entry<E> e = new Entry<E>(key,val); if (key == null) { nullEntry = e; } else { maybeRehash(); addEntry(e, getTableIndex(key)); } return e; } /** lookup, returning null if no binding. */ public Entry<E> get (E key) { return getEntry(key, getTableIndex(key)); } /** * a little optimization to speed up counter increments */ public Entry<E> getInc (E key){ int idx = getTableIndex(key); Entry<E> last = null; for (Entry<E> e = table[idx]; e != null; e = e.next) { if (e.key == key || e.key.equals(key)) { // found it, replace entry Entry<E> newEntry = new Entry<E>(key, e.val+1, e.next); lastSnapshot = null; if (last == null) { table[idx] = newEntry; } else { last.next = newEntry; } return newEntry; } else { last = e; } } // it wasn't there, add a new entry with value 1 Entry<E> newEntry = new Entry<E>( key, 1); if (maybeRehash()) { idx = getTableIndex(key); } addEntry( newEntry, idx); return newEntry; } /** just like HashMap put. */ public void put(E key, int val) { if (key == null) { if (nullEntry == null) { nullEntry = new Entry<E>(null,val); size++; } else { nullEntry = new Entry<E>(null, val); } return; } int idx = getTableIndex(key); Entry<E> e = getEntry(key, idx); if (e == null) { // wasn't there if (maybeRehash()){ idx = getTableIndex(key); } addEntry(new Entry<E>(key,val), idx); } else { replaceEntryValue( idx, e, val); lastSnapshot = null; } } /** removes a binding/entry from the table. */ public Entry<E> remove(E key) { int idx = getTableIndex(key); Entry<E> prev = null; Entry<E> cur = table[idx]; while (cur != null) { E k = cur.key; if (k == key || k.equals(key)) { if (prev == null) { table[idx] = cur.next; } else { prev.next = cur.next; } cur.next = null; size--; lastSnapshot = null; return cur; } prev = cur; cur = cur.next; } return null; // not found } /** empties the table, leaving it capacity the same. */ public void clear() { table = new Entry[table.length]; nullEntry = null; size = 0; lastSnapshot = null; } /** returns the next val to be assigned by a call to pool() on a fresh key. */ public int nextPoolVal() { return size; } /** gets the Entry associated with key, adding previous `size' if not yet bound. */ public Entry<E> pool(E key) { if (key == null) { if (nullEntry == null) { nullEntry = new Entry<E>(null,size); size++; } return nullEntry; } int idx = getTableIndex(key); Entry<E> e = getEntry(key, idx); if (e == null) { if (maybeRehash()) { idx = getTableIndex(key); } e = new Entry<E>(key,size); addEntry(e, idx); } return e; } /** shorthand for <code>pool(key).val</code>. */ public int poolIndex(E key) { return pool(key).val; } /** shorthand for <code>pool(key).key</code>. */ public E poolKey(E key) { return pool(key).key; } /** shorthand for <code>get(key) != null</code>. */ public boolean hasEntry(E key) { return get(key) != null; } /** * returns an iterator over the entries. unpredictable behavior could result if * using iterator after table is altered. */ @Override public Iterator<Entry<E>> iterator () { return new TblIterator(); } protected class TblIterator implements Iterator<Entry<E>> { int idx; Entry<E> cur; public TblIterator() { idx = -1; cur = null; advance(); } void advance() { if (cur != null) { cur = cur.next; } int len = table.length; while (idx < len && cur == null) { idx++; if (idx < len) { cur = table[idx]; } } } @Override public boolean hasNext () { return idx < table.length; } @Override public Entry<E> next () { Entry<E> e = cur; advance(); return e; } @Override public void remove () { throw new UnsupportedOperationException(); } } /** * for debugging purposes */ public void dump(){ System.out.print('{'); int n=0; for (int i=0; i<table.length; i++){ for (Entry<E> e = table[i]; e != null; e = e.next){ if (n++>0){ System.out.print(','); } System.out.print('('); System.out.print(e.key); System.out.print("=>"); System.out.print(e.val); System.out.print(')'); } } System.out.println('}'); } public int computeSize() { int n=0; for (int i=0; i<table.length; i++){ for (Entry<E> e = table[i]; e != null; e = e.next){ n++; } } return n; } }