2004-09-02 00:55:40 +02:00
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//===-- llvm/ADT/EquivalenceClasses.h - Generic Equiv. Classes --*- C++ -*-===//
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2005-04-21 22:19:05 +02:00
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//
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2003-10-20 21:46:57 +02:00
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// The LLVM Compiler Infrastructure
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//
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2007-12-29 20:59:42 +01:00
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// This file is distributed under the University of Illinois Open Source
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// License. See LICENSE.TXT for details.
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2005-04-21 22:19:05 +02:00
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//
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2003-10-20 21:46:57 +02:00
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//===----------------------------------------------------------------------===//
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2005-04-21 22:19:05 +02:00
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//
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2005-03-19 06:14:29 +01:00
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// Generic implementation of equivalence classes through the use Tarjan's
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// efficient union-find algorithm.
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2005-04-21 22:19:05 +02:00
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//
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2003-09-30 20:37:50 +02:00
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//===----------------------------------------------------------------------===//
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2003-05-30 00:44:25 +02:00
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2004-09-02 00:55:40 +02:00
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#ifndef LLVM_ADT_EQUIVALENCECLASSES_H
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#define LLVM_ADT_EQUIVALENCECLASSES_H
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2003-05-30 00:44:25 +02:00
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2008-05-29 19:41:17 +02:00
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#include "llvm/ADT/iterator.h"
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#include "llvm/Support/DataTypes.h"
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#include <set>
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2003-11-11 23:41:34 +01:00
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namespace llvm {
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/// EquivalenceClasses - This represents a collection of equivalence classes and
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/// supports three efficient operations: insert an element into a class of its
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/// own, union two classes, and find the class for a given element. In
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/// addition to these modification methods, it is possible to iterate over all
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/// of the equivalence classes and all of the elements in a class.
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///
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/// This implementation is an efficient implementation that only stores one copy
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/// of the element being indexed per entry in the set, and allows any arbitrary
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/// type to be indexed (as long as it can be ordered with operator<).
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///
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/// Here is a simple example using integers:
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///
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/// EquivalenceClasses<int> EC;
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/// EC.unionSets(1, 2); // insert 1, 2 into the same set
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/// EC.insert(4); EC.insert(5); // insert 4, 5 into own sets
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/// EC.unionSets(5, 1); // merge the set for 1 with 5's set.
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///
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/// for (EquivalenceClasses<int>::iterator I = EC.begin(), E = EC.end();
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/// I != E; ++I) { // Iterate over all of the equivalence sets.
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/// if (!I->isLeader()) continue; // Ignore non-leader sets.
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/// for (EquivalenceClasses<int>::member_iterator MI = EC.member_begin(I);
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/// MI != EC.member_end(); ++MI) // Loop over members in this set.
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/// cerr << *MI << " "; // Print member.
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/// cerr << "\n"; // Finish set.
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/// }
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///
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/// This example prints:
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/// 4
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/// 5 1 2
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///
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template <class ElemTy>
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class EquivalenceClasses {
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/// ECValue - The EquivalenceClasses data structure is just a set of these.
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/// Each of these represents a relation for a value. First it stores the
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/// value itself, which provides the ordering that the set queries. Next, it
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/// provides a "next pointer", which is used to enumerate all of the elements
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/// in the unioned set. Finally, it defines either a "end of list pointer" or
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/// "leader pointer" depending on whether the value itself is a leader. A
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/// "leader pointer" points to the node that is the leader for this element,
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/// if the node is not a leader. A "end of list pointer" points to the last
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/// node in the list of members of this list. Whether or not a node is a
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/// leader is determined by a bit stolen from one of the pointers.
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class ECValue {
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friend class EquivalenceClasses;
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mutable const ECValue *Leader, *Next;
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ElemTy Data;
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// ECValue ctor - Start out with EndOfList pointing to this node, Next is
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// Null, isLeader = true.
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ECValue(const ElemTy &Elt)
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: Leader(this), Next((ECValue*)(intptr_t)1), Data(Elt) {}
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const ECValue *getLeader() const {
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if (isLeader()) return this;
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if (Leader->isLeader()) return Leader;
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// Path compression.
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return Leader = Leader->getLeader();
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}
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const ECValue *getEndOfList() const {
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assert(isLeader() && "Cannot get the end of a list for a non-leader!");
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return Leader;
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}
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void setNext(const ECValue *NewNext) const {
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assert(getNext() == 0 && "Already has a next pointer!");
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Next = (const ECValue*)((intptr_t)NewNext | (intptr_t)isLeader());
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}
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public:
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ECValue(const ECValue &RHS) : Leader(this), Next((ECValue*)(intptr_t)1),
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Data(RHS.Data) {
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// Only support copying of singleton nodes.
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assert(RHS.isLeader() && RHS.getNext() == 0 && "Not a singleton!");
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}
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bool operator<(const ECValue &UFN) const { return Data < UFN.Data; }
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bool isLeader() const { return (intptr_t)Next & 1; }
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const ElemTy &getData() const { return Data; }
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const ECValue *getNext() const {
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return (ECValue*)((intptr_t)Next & ~(intptr_t)1);
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}
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template<typename T>
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bool operator<(const T &Val) const { return Data < Val; }
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};
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/// TheMapping - This implicitly provides a mapping from ElemTy values to the
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/// ECValues, it just keeps the key as part of the value.
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std::set<ECValue> TheMapping;
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public:
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EquivalenceClasses() {}
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EquivalenceClasses(const EquivalenceClasses &RHS) {
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operator=(RHS);
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}
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const EquivalenceClasses &operator=(const EquivalenceClasses &RHS) {
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TheMapping.clear();
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for (iterator I = RHS.begin(), E = RHS.end(); I != E; ++I)
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if (I->isLeader()) {
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member_iterator MI = RHS.member_begin(I);
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member_iterator LeaderIt = member_begin(insert(*MI));
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for (++MI; MI != member_end(); ++MI)
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unionSets(LeaderIt, member_begin(insert(*MI)));
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}
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return *this;
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}
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//===--------------------------------------------------------------------===//
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// Inspection methods
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//
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/// iterator* - Provides a way to iterate over all values in the set.
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typedef typename std::set<ECValue>::const_iterator iterator;
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iterator begin() const { return TheMapping.begin(); }
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iterator end() const { return TheMapping.end(); }
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bool empty() const { return TheMapping.empty(); }
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/// member_* Iterate over the members of an equivalence class.
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///
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class member_iterator;
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member_iterator member_begin(iterator I) const {
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// Only leaders provide anything to iterate over.
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return member_iterator(I->isLeader() ? &*I : 0);
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}
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member_iterator member_end() const {
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return member_iterator(0);
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}
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/// findValue - Return an iterator to the specified value. If it does not
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/// exist, end() is returned.
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iterator findValue(const ElemTy &V) const {
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return TheMapping.find(V);
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}
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/// getLeaderValue - Return the leader for the specified value that is in the
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/// set. It is an error to call this method for a value that is not yet in
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/// the set. For that, call getOrInsertLeaderValue(V).
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const ElemTy &getLeaderValue(const ElemTy &V) const {
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member_iterator MI = findLeader(V);
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assert(MI != member_end() && "Value is not in the set!");
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return *MI;
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}
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/// getOrInsertLeaderValue - Return the leader for the specified value that is
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/// in the set. If the member is not in the set, it is inserted, then
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/// returned.
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const ElemTy &getOrInsertLeaderValue(const ElemTy &V) const {
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member_iterator MI = findLeader(insert(V));
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assert(MI != member_end() && "Value is not in the set!");
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return *MI;
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}
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2005-03-19 20:26:14 +01:00
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/// getNumClasses - Return the number of equivalence classes in this set.
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/// Note that this is a linear time operation.
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unsigned getNumClasses() const {
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unsigned NC = 0;
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for (iterator I = begin(), E = end(); I != E; ++I)
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if (I->isLeader()) ++NC;
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return NC;
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}
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2005-03-19 06:14:29 +01:00
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//===--------------------------------------------------------------------===//
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// Mutation methods
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/// insert - Insert a new value into the union/find set, ignoring the request
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/// if the value already exists.
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iterator insert(const ElemTy &Data) {
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return TheMapping.insert(Data).first;
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}
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/// findLeader - Given a value in the set, return a member iterator for the
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/// equivalence class it is in. This does the path-compression part that
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/// makes union-find "union findy". This returns an end iterator if the value
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/// is not in the equivalence class.
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///
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member_iterator findLeader(iterator I) const {
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if (I == TheMapping.end()) return member_end();
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return member_iterator(I->getLeader());
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}
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member_iterator findLeader(const ElemTy &V) const {
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return findLeader(TheMapping.find(V));
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}
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/// union - Merge the two equivalence sets for the specified values, inserting
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/// them if they do not already exist in the equivalence set.
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member_iterator unionSets(const ElemTy &V1, const ElemTy &V2) {
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iterator V1I = insert(V1), V2I = insert(V2);
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return unionSets(findLeader(V1I), findLeader(V2I));
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}
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member_iterator unionSets(member_iterator L1, member_iterator L2) {
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assert(L1 != member_end() && L2 != member_end() && "Illegal inputs!");
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if (L1 == L2) return L1; // Unifying the same two sets, noop.
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// Otherwise, this is a real union operation. Set the end of the L1 list to
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// point to the L2 leader node.
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const ECValue &L1LV = *L1.Node, &L2LV = *L2.Node;
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L1LV.getEndOfList()->setNext(&L2LV);
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// Update L1LV's end of list pointer.
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L1LV.Leader = L2LV.getEndOfList();
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// Clear L2's leader flag:
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L2LV.Next = L2LV.getNext();
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// L2's leader is now L1.
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L2LV.Leader = &L1LV;
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return L1;
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}
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class member_iterator : public forward_iterator<ElemTy, ptrdiff_t> {
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typedef forward_iterator<const ElemTy, ptrdiff_t> super;
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const ECValue *Node;
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friend class EquivalenceClasses;
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public:
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typedef size_t size_type;
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typedef typename super::pointer pointer;
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typedef typename super::reference reference;
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explicit member_iterator() {}
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explicit member_iterator(const ECValue *N) : Node(N) {}
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member_iterator(const member_iterator &I) : Node(I.Node) {}
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reference operator*() const {
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assert(Node != 0 && "Dereferencing end()!");
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return Node->getData();
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}
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reference operator->() const { return operator*(); }
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member_iterator &operator++() {
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assert(Node != 0 && "++'d off the end of the list!");
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Node = Node->getNext();
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return *this;
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}
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member_iterator operator++(int) { // postincrement operators.
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member_iterator tmp = *this;
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++*this;
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return tmp;
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}
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bool operator==(const member_iterator &RHS) const {
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return Node == RHS.Node;
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}
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bool operator!=(const member_iterator &RHS) const {
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return Node != RHS.Node;
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}
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};
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};
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2003-11-11 23:41:34 +01:00
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} // End llvm namespace
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2003-05-30 00:44:25 +02:00
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#endif
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