//===--- ImmutableIntervalMap.h - Immutable (functional) map ---*- C++ -*-===//
//
// The LLVM Compiler Infrastructure
//
// This file is distributed under the University of Illinois Open Source
// License. See LICENSE.TXT for details.
//
//===----------------------------------------------------------------------===//
//
// This file defines the ImmutableIntervalMap class.
//
//===----------------------------------------------------------------------===//
#ifndef LLVM_ADT_IMMUTABLE_INTERVAL_MAP_H
#define LLVM_ADT_IMMUTABLE_INTERVAL_MAP_H
#include "llvm/ADT/ImmutableMap.h"
namespace llvm {
class Interval {
private:
int64_t Start;
int64_t End;
public:
Interval(int64_t S, int64_t E) : Start(S), End(E) {}
int64_t getStart() const { return Start; }
int64_t getEnd() const { return End; }
};
template <typename T>
struct ImutIntervalInfo {
typedef const std::pair<Interval, T> value_type;
typedef const value_type &value_type_ref;
typedef const Interval key_type;
typedef const Interval &key_type_ref;
typedef const T data_type;
typedef const T &data_type_ref;
static key_type_ref KeyOfValue(value_type_ref V) {
return V.first;
}
static data_type_ref DataOfValue(value_type_ref V) {
return V.second;
}
static bool isEqual(key_type_ref L, key_type_ref R) {
return L.getStart() == R.getStart() && L.getEnd() == R.getEnd();
}
static bool isDataEqual(data_type_ref L, data_type_ref R) {
return ImutContainerInfo<T>::isEqual(L,R);
}
static bool isLess(key_type_ref L, key_type_ref R) {
// Assume L and R does not overlap.
if (L.getStart() < R.getStart()) {
assert(L.getEnd() < R.getStart());
return true;
} else if (L.getStart() == R.getStart()) {
assert(L.getEnd() == R.getEnd());
return false;
} else {
assert(L.getStart() > R.getEnd());
return false;
}
}
static bool isContainedIn(key_type_ref K, key_type_ref L) {
if (K.getStart() >= L.getStart() && K.getEnd() <= L.getEnd())
return true;
else
return false;
}
static void Profile(FoldingSetNodeID &ID, value_type_ref V) {
ID.AddInteger(V.first.getStart());
ID.AddInteger(V.first.getEnd());
ImutProfileInfo<T>::Profile(ID, V.second);
}
};
template <typename ImutInfo>
class ImutIntervalAVLFactory : public ImutAVLFactory<ImutInfo> {
typedef ImutAVLTree<ImutInfo> TreeTy;
typedef typename ImutInfo::value_type value_type;
typedef typename ImutInfo::value_type_ref value_type_ref;
typedef typename ImutInfo::key_type key_type;
typedef typename ImutInfo::key_type_ref key_type_ref;
typedef typename ImutInfo::data_type data_type;
typedef typename ImutInfo::data_type_ref data_type_ref;
public:
ImutIntervalAVLFactory(BumpPtrAllocator &Alloc)
: ImutAVLFactory<ImutInfo>(Alloc) {}
TreeTy *Add(TreeTy *T, value_type_ref V) {
T = add_internal(V,T);
this->MarkImmutable(T);
return T;
}
TreeTy *Find(TreeTy *T, key_type_ref K) {
if (!T)
return NULL;
key_type_ref CurrentKey = ImutInfo::KeyOfValue(this->getValue(T));
if (ImutInfo::isContainedIn(K, CurrentKey))
return T;
else if (ImutInfo::isLess(K, CurrentKey))
return Find(this->getLeft(T), K);
else
return Find(this->getRight(T), K);
}
private:
TreeTy *add_internal(value_type_ref V, TreeTy *T) {
key_type_ref K = ImutInfo::KeyOfValue(V);
T = removeAllOverlaps(T, K);
if (this->isEmpty(T))
return this->CreateNode(NULL, V, NULL);
assert(!T->isMutable());
key_type_ref KCurrent = ImutInfo::KeyOfValue(this->Value(T));
if (ImutInfo::isLess(K, KCurrent))
return this->Balance(add_internal(V, this->Left(T)), this->Value(T),
this->Right(T));
else
return this->Balance(this->Left(T), this->Value(T),
add_internal(V, this->Right(T)));
}
// Remove all overlaps from T.
TreeTy *removeAllOverlaps(TreeTy *T, key_type_ref K) {
bool Changed;
do {
Changed = false;
T = removeOverlap(T, K, Changed);
this->markImmutable(T);
} while (Changed);
return T;
}
// Remove one overlap from T.
TreeTy *removeOverlap(TreeTy *T, key_type_ref K, bool &Changed) {
if (!T)
return NULL;
Interval CurrentK = ImutInfo::KeyOfValue(this->Value(T));
// If current key does not overlap the inserted key.
if (CurrentK.getStart() > K.getEnd())
return this->Balance(removeOverlap(this->Left(T), K, Changed),
this->Value(T), this->Right(T));
else if (CurrentK.getEnd() < K.getStart())
return this->Balance(this->Left(T), this->Value(T),
removeOverlap(this->Right(T), K, Changed));
// Current key overlaps with the inserted key.
// Remove the current key.
Changed = true;
data_type_ref OldData = ImutInfo::DataOfValue(this->Value(T));
T = this->Remove_internal(CurrentK, T);
// Add back the unoverlapped part of the current key.
if (CurrentK.getStart() < K.getStart()) {
if (CurrentK.getEnd() <= K.getEnd()) {
Interval NewK(CurrentK.getStart(), K.getStart()-1);
return add_internal(std::make_pair(NewK, OldData), T);
} else {
Interval NewK1(CurrentK.getStart(), K.getStart()-1);
T = add_internal(std::make_pair(NewK1, OldData), T);
Interval NewK2(K.getEnd()+1, CurrentK.getEnd());
return add_internal(std::make_pair(NewK2, OldData), T);
}
} else {
if (CurrentK.getEnd() > K.getEnd()) {
Interval NewK(K.getEnd()+1, CurrentK.getEnd());
return add_internal(std::make_pair(NewK, OldData), T);
} else
return T;
}
}
};
/// ImmutableIntervalMap maps an interval [start, end] to a value. The intervals
/// in the map are guaranteed to be disjoint.
template <typename ValT>
class ImmutableIntervalMap
: public ImmutableMap<Interval, ValT, ImutIntervalInfo<ValT> > {
typedef typename ImutIntervalInfo<ValT>::value_type value_type;
typedef typename ImutIntervalInfo<ValT>::value_type_ref value_type_ref;
typedef typename ImutIntervalInfo<ValT>::key_type key_type;
typedef typename ImutIntervalInfo<ValT>::key_type_ref key_type_ref;
typedef typename ImutIntervalInfo<ValT>::data_type data_type;
typedef typename ImutIntervalInfo<ValT>::data_type_ref data_type_ref;
typedef ImutAVLTree<ImutIntervalInfo<ValT> > TreeTy;
public:
explicit ImmutableIntervalMap(TreeTy *R)
: ImmutableMap<Interval, ValT, ImutIntervalInfo<ValT> >(R) {}
class Factory {
ImutIntervalAVLFactory<ImutIntervalInfo<ValT> > F;
public:
Factory(BumpPtrAllocator& Alloc) : F(Alloc) {}
ImmutableIntervalMap getEmptyMap() {
return ImmutableIntervalMap(F.getEmptyTree());
}
ImmutableIntervalMap add(ImmutableIntervalMap Old,
key_type_ref K, data_type_ref D) {
TreeTy *T = F.add(Old.Root, std::pair<key_type, data_type>(K, D));
return ImmutableIntervalMap(F.getCanonicalTree(T));
}
ImmutableIntervalMap remove(ImmutableIntervalMap Old, key_type_ref K) {
TreeTy *T = F.remove(Old.Root, K);
return ImmutableIntervalMap(F.getCanonicalTree(T));
}
data_type *lookup(ImmutableIntervalMap M, key_type_ref K) {
TreeTy *T = F.Find(M.getRoot(), K);
if (T)
return &T->getValue().second;
else
return 0;
}
};
private:
// For ImmutableIntervalMap, the lookup operation has to be done by the
// factory.
data_type* lookup(key_type_ref K) const;
};
} // end namespace llvm
#endif