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llvm-6502/include/llvm/Support/IntegersSubsetMapping.h
Stepan Dyatkovskiy 6a59073735 Part of r159527. Splitted into series of patches and gone with fixed PR13256: 
IntegersSubsetMapping
  - Replaced type of Items field from std::list with std::map. In neares future I'll test it with DenseMap and do the correspond replacement
    if possible.



git-svn-id: https://llvm.org/svn/llvm-project/llvm/trunk@159659 91177308-0d34-0410-b5e6-96231b3b80d8
2012-07-03 13:46:45 +00:00

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//===- IntegersSubsetMapping.h - Mapping subset ==> Successor ---*- C++ -*-===//
//
// The LLVM Compiler Infrastructure
//
// This file is distributed under the University of Illinois Open Source
// License. See LICENSE.TXT for details.
//
//===----------------------------------------------------------------------===//
//
/// @file
/// IntegersSubsetMapping is mapping from A to B, where
/// Items in A is subsets of integers,
/// Items in B some pointers (Successors).
/// If user which to add another subset for successor that is already
/// exists in mapping, IntegersSubsetMapping merges existing subset with
/// added one.
//
//===----------------------------------------------------------------------===//
#ifndef CRSBUILDER_H_
#define CRSBUILDER_H_
#include "llvm/Support/IntegersSubset.h"
#include <list>
#include <map>
#include <vector>
namespace llvm {
template <class SuccessorClass,
class IntegersSubsetTy = IntegersSubset,
class IntTy = IntItem>
class IntegersSubsetMapping {
// FIXME: To much similar iterators typedefs, similar names.
// - Rename RangeIterator to the cluster iterator.
// - Remove unused "add" methods.
// - Class contents needs cleaning.
public:
typedef IntRange<IntTy> RangeTy;
struct RangeEx : public RangeTy {
RangeEx() : Weight(1) {}
RangeEx(const RangeTy &R) : RangeTy(R), Weight(1) {}
RangeEx(const IntTy &C) : RangeTy(C), Weight(1) {}
RangeEx(const IntTy &L, const IntTy &H) : RangeTy(L, H), Weight(1) {}
RangeEx(const IntTy &L, const IntTy &H, unsigned W) :
RangeTy(L, H), Weight(W) {}
unsigned Weight;
};
typedef std::pair<RangeEx, SuccessorClass*> Cluster;
typedef std::list<RangeTy> RangesCollection;
typedef typename RangesCollection::iterator RangesCollectionIt;
typedef typename RangesCollection::const_iterator RangesCollectionConstIt;
typedef IntegersSubsetMapping<SuccessorClass, IntegersSubsetTy, IntTy> self;
protected:
typedef std::map<RangeEx, SuccessorClass*> CaseItems;
typedef typename CaseItems::iterator CaseItemIt;
typedef typename CaseItems::const_iterator CaseItemConstIt;
// TODO: Change unclean CRS prefixes to SubsetMap for example.
typedef std::map<SuccessorClass*, RangesCollection > CRSMap;
typedef typename CRSMap::iterator CRSMapIt;
CaseItems Items;
bool SingleNumbersOnly;
bool isIntersected(CaseItemIt& LItem, CaseItemIt& RItem) {
return LItem->first.getHigh() >= RItem->first.getLow();
}
bool isJoinable(CaseItemIt& LItem, CaseItemIt& RItem) {
if (LItem->second != RItem->second) {
assert(!isIntersected(LItem, RItem) &&
"Intersected items with different successors!");
return false;
}
APInt RLow = RItem->first.getLow();
if (RLow != APInt::getNullValue(RLow.getBitWidth()))
--RLow;
return LItem->first.getHigh() >= RLow;
}
enum DiffProcessState {
L_OPENED,
INTERSECT_OPENED,
R_OPENED,
ALL_IS_CLOSED
};
class DiffStateMachine {
DiffProcessState State;
IntTy OpenPt;
SuccessorClass *CurrentLSuccessor;
SuccessorClass *CurrentRSuccessor;
self *LeftMapping;
self *IntersectionMapping;
self *RightMapping;
public:
typedef
IntegersSubsetMapping<SuccessorClass, IntegersSubsetTy, IntTy> MappingTy;
DiffStateMachine(MappingTy *L,
MappingTy *Intersection,
MappingTy *R) :
State(ALL_IS_CLOSED),
LeftMapping(L),
IntersectionMapping(Intersection),
RightMapping(R)
{}
void onLOpen(const IntTy &Pt, SuccessorClass *S) {
switch (State) {
case R_OPENED:
if (Pt > OpenPt/*Don't add empty ranges.*/ && RightMapping)
RightMapping->add(OpenPt, Pt-1, CurrentRSuccessor);
State = INTERSECT_OPENED;
break;
case ALL_IS_CLOSED:
State = L_OPENED;
break;
default:
assert(0 && "Got unexpected point.");
break;
}
CurrentLSuccessor = S;
OpenPt = Pt;
}
void onLClose(const IntTy &Pt) {
switch (State) {
case L_OPENED:
assert(Pt >= OpenPt &&
"Subset is not sorted or contains overlapped ranges");
if (LeftMapping)
LeftMapping->add(OpenPt, Pt, CurrentLSuccessor);
State = ALL_IS_CLOSED;
break;
case INTERSECT_OPENED:
if (IntersectionMapping)
IntersectionMapping->add(OpenPt, Pt, CurrentLSuccessor);
OpenPt = Pt + 1;
State = R_OPENED;
break;
default:
assert(0 && "Got unexpected point.");
break;
}
}
void onROpen(const IntTy &Pt, SuccessorClass *S) {
switch (State) {
case L_OPENED:
if (Pt > OpenPt && LeftMapping)
LeftMapping->add(OpenPt, Pt-1, CurrentLSuccessor);
State = INTERSECT_OPENED;
break;
case ALL_IS_CLOSED:
State = R_OPENED;
break;
default:
assert(0 && "Got unexpected point.");
break;
}
CurrentRSuccessor = S;
OpenPt = Pt;
}
void onRClose(const IntTy &Pt) {
switch (State) {
case R_OPENED:
assert(Pt >= OpenPt &&
"Subset is not sorted or contains overlapped ranges");
if (RightMapping)
RightMapping->add(OpenPt, Pt, CurrentRSuccessor);
State = ALL_IS_CLOSED;
break;
case INTERSECT_OPENED:
if (IntersectionMapping)
IntersectionMapping->add(OpenPt, Pt, CurrentLSuccessor);
OpenPt = Pt + 1;
State = L_OPENED;
break;
default:
assert(0 && "Got unexpected point.");
break;
}
}
void onRLOpen(const IntTy &Pt,
SuccessorClass *LS,
SuccessorClass *RS) {
switch (State) {
case ALL_IS_CLOSED:
State = INTERSECT_OPENED;
break;
default:
assert(0 && "Got unexpected point.");
break;
}
CurrentLSuccessor = LS;
CurrentRSuccessor = RS;
OpenPt = Pt;
}
void onRLClose(const IntTy &Pt) {
switch (State) {
case INTERSECT_OPENED:
if (IntersectionMapping)
IntersectionMapping->add(OpenPt, Pt, CurrentLSuccessor);
State = ALL_IS_CLOSED;
break;
default:
assert(0 && "Got unexpected point.");
break;
}
}
bool isLOpened() { return State == L_OPENED; }
bool isROpened() { return State == R_OPENED; }
};
void diff_single_numbers(self *LExclude, self *Intersection, self *RExclude,
const self& RHS) {
CaseItemConstIt L = Items.begin(), R = RHS.Items.begin();
CaseItemConstIt el = Items.end(), er = RHS.Items.end();
while (L != el && R != er) {
const Cluster &LCluster = *L;
const RangeEx &LRange = LCluster.first;
const Cluster &RCluster = *R;
const RangeEx &RRange = RCluster.first;
if (LRange.getLow() < RRange.getLow()) {
if (LExclude)
LExclude->add(LRange.getLow(), LCluster.second);
++L;
} else if (LRange.getLow() > RRange.getLow()) {
if (RExclude)
RExclude->add(RRange.getLow(), RCluster.second);
++R;
} else {
if (Intersection)
Intersection->add(LRange.getLow(), LCluster.second);
++L;
++R;
}
}
if (L != Items.end()) {
if (LExclude)
do {
LExclude->add(L->first, L->second);
++L;
} while (L != Items.end());
} else if (R != RHS.Items.end()) {
if (RExclude)
do {
RExclude->add(R->first, R->second);
++R;
} while (R != RHS.Items.end());
}
}
public:
// Don't public CaseItems itself. Don't allow edit the Items directly.
// Just present the user way to iterate over the internal collection
// sharing iterator, begin() and end(). Editing should be controlled by
// factory.
typedef CaseItemIt RangeIterator;
typedef std::pair<SuccessorClass*, IntegersSubsetTy> Case;
typedef std::list<Case> Cases;
IntegersSubsetMapping() : SingleNumbersOnly(true) {}
bool verify(RangeIterator& errItem) {
if (Items.empty())
return true;
for (CaseItemIt j = Items.begin(), i = j++, e = Items.end();
j != e; i = j++) {
if (isIntersected(i, j) && i->second != j->second) {
errItem = j;
return false;
}
}
return true;
}
void optimize() {
if (Items.size() < 2)
return;
CaseItems OldItems = Items;
Items.clear();
const IntTy *Low = &OldItems.begin()->first.getLow();
const IntTy *High = &OldItems.begin()->first.getHigh();
unsigned Weight = 1;
SuccessorClass *Successor = OldItems.begin()->second;
for (CaseItemIt j = OldItems.begin(), i = j++, e = OldItems.end();
j != e; i = j++) {
if (isJoinable(i, j)) {
const IntTy *CurHigh = &j->first.getHigh();
++Weight;
if (*CurHigh > *High)
High = CurHigh;
} else {
RangeEx R(*Low, *High, Weight);
add(R, Successor);
Low = &j->first.getLow();
High = &j->first.getHigh();
Weight = 1;
Successor = j->second;
}
}
RangeEx R(*Low, *High, Weight);
add(R, Successor);
}
/// Adds a constant value.
void add(const IntTy &C, SuccessorClass *S = 0) {
RangeTy R(C);
add(R, S);
}
/// Adds a range.
void add(const IntTy &Low, const IntTy &High, SuccessorClass *S = 0) {
RangeTy R(Low, High);
add(R, S);
}
void add(const RangeTy &R, SuccessorClass *S = 0) {
RangeEx REx = R;
add(REx, S);
}
void add(const RangeEx &R, SuccessorClass *S = 0) {
Items.insert(std::make_pair(R, S));
if (!R.isSingleNumber())
SingleNumbersOnly = false;
}
/// Adds all ranges and values from given ranges set to the current
/// mapping.
void add(const IntegersSubsetTy &CRS, SuccessorClass *S = 0) {
for (unsigned i = 0, e = CRS.getNumItems(); i < e; ++i) {
RangeTy R = CRS.getItem(i);
add(R, S);
}
}
void add(self& RHS) {
Items.insert(RHS.Items.begin(), RHS.Items.end());
if (!RHS.SingleNumbersOnly)
SingleNumbersOnly = false;
}
void add(const RangesCollection& RHS, SuccessorClass *S = 0) {
for (RangesCollectionConstIt i = RHS.begin(), e = RHS.end(); i != e; ++i)
add(*i, S);
}
/// Removes items from set.
void removeItem(RangeIterator i) { Items.erase(i); }
/// Calculates the difference between this mapping and RHS.
/// THIS without RHS is placed into LExclude,
/// RHS without THIS is placed into RExclude,
/// THIS intersect RHS is placed into Intersection.
void diff(self *LExclude, self *Intersection, self *RExclude,
const self& RHS) {
if (SingleNumbersOnly && RHS.SingleNumbersOnly) {
diff_single_numbers(LExclude, Intersection, RExclude, RHS);
return;
}
DiffStateMachine Machine(LExclude, Intersection, RExclude);
CaseItemConstIt L = Items.begin(), R = RHS.Items.begin();
CaseItemConstIt el = Items.end(), er = RHS.Items.end();
while (L != el && R != er) {
const Cluster &LCluster = *L;
const RangeEx &LRange = LCluster.first;
const Cluster &RCluster = *R;
const RangeEx &RRange = RCluster.first;
if (LRange.getHigh() < RRange.getLow()) {
Machine.onLOpen(LRange.getLow(), LCluster.second);
Machine.onLClose(LRange.getHigh());
++L;
continue;
}
if (LRange.getLow() > RRange.getHigh()) {
Machine.onROpen(RRange.getLow(), RCluster.second);
Machine.onRClose(RRange.getHigh());
++R;
continue;
}
if (LRange.isSingleNumber() && RRange.isSingleNumber()) {
Machine.onRLOpen(LRange.getLow(), LCluster.second, RCluster.second);
Machine.onRLClose(LRange.getLow());
++L;
++R;
continue;
}
if (LRange.isSingleNumber()) {
Machine.onLOpen(LRange.getLow(), LCluster.second);
Machine.onLClose(LRange.getLow());
++L;
while(L != Items.end() && L->first.getHigh() < RRange.getHigh()) {
Machine.onLOpen(LRange.getLow(), LCluster.second);
Machine.onLClose(LRange.getLow());
++L;
}
continue;
} else if (RRange.isSingleNumber()) {
Machine.onROpen(R->first.getLow(), R->second);
Machine.onRClose(R->first.getHigh());
++R;
while(R != RHS.Items.end() && R->first.getHigh() < LRange.getHigh()) {
Machine.onROpen(R->first.getLow(), R->second);
Machine.onRClose(R->first.getHigh());
++R;
}
continue;
} else
if (LRange.getLow() < RRange.getLow()) {
// May be opened in previous iteration.
if (!Machine.isLOpened())
Machine.onLOpen(LRange.getLow(), LCluster.second);
Machine.onROpen(RRange.getLow(), RCluster.second);
}
else if (RRange.getLow() < LRange.getLow()) {
if (!Machine.isROpened())
Machine.onROpen(RRange.getLow(), RCluster.second);
Machine.onLOpen(LRange.getLow(), LCluster.second);
}
else
Machine.onRLOpen(LRange.getLow(), LCluster.second, RCluster.second);
if (LRange.getHigh() < RRange.getHigh()) {
Machine.onLClose(LRange.getHigh());
++L;
while(L != Items.end() && L->first.getHigh() < RRange.getHigh()) {
Machine.onLOpen(L->first.getLow(), L->second);
Machine.onLClose(L->first.getHigh());
++L;
}
}
else if (RRange.getHigh() < LRange.getHigh()) {
Machine.onRClose(RRange.getHigh());
++R;
while(R != RHS.Items.end() && R->first.getHigh() < LRange.getHigh()) {
Machine.onROpen(R->first.getLow(), R->second);
Machine.onRClose(R->first.getHigh());
++R;
}
}
else {
Machine.onRLClose(LRange.getHigh());
++L;
++R;
}
}
if (L != Items.end()) {
if (Machine.isLOpened()) {
Machine.onLClose(L->first.getHigh());
++L;
}
if (LExclude)
while (L != Items.end()) {
LExclude->add(L->first, L->second);
++L;
}
} else if (R != RHS.Items.end()) {
if (Machine.isROpened()) {
Machine.onRClose(R->first.getHigh());
++R;
}
if (RExclude)
while (R != RHS.Items.end()) {
RExclude->add(R->first, R->second);
++R;
}
}
}
/// Builds the finalized case objects.
void getCases(Cases& TheCases) {
CRSMap TheCRSMap;
for (RangeIterator i = this->begin(); i != this->end(); ++i)
TheCRSMap[i->second].push_back(i->first);
for (CRSMapIt i = TheCRSMap.begin(), e = TheCRSMap.end(); i != e; ++i)
TheCases.push_back(std::make_pair(i->first, IntegersSubsetTy(i->second)));
}
/// Builds the finalized case objects ignoring successor values, as though
/// all ranges belongs to the same successor.
IntegersSubsetTy getCase() {
RangesCollection Ranges;
for (RangeIterator i = this->begin(); i != this->end(); ++i)
Ranges.push_back(i->first);
return IntegersSubsetTy(Ranges);
}
/// Returns true if there is no ranges and values inside.
bool empty() const { return Items.empty(); }
void clear() {
Items.clear();
// Don't reset Sorted flag:
// 1. For empty mapping it matters nothing.
// 2. After first item will added Sorted flag will cleared.
}
// Returns number of clusters
unsigned size() const {
return Items.size();
}
RangeIterator begin() { return Items.begin(); }
RangeIterator end() { return Items.end(); }
};
class BasicBlock;
typedef IntegersSubsetMapping<BasicBlock> IntegersSubsetToBB;
}
#endif /* CRSBUILDER_H_ */
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