void TempScopInfo::buildCondition(BasicBlock *BB, BasicBlock *RegionEntry) {
BBCond Cond;
DomTreeNode *BBNode = DT->getNode(BB), *EntryNode = DT->getNode(RegionEntry);
assert(BBNode && EntryNode && "Get null node while building condition!");
// Walk up the dominance tree until reaching the entry node. Add all
// conditions on the path to BB except if BB postdominates the block
// containing the condition.
while (BBNode != EntryNode) {
BasicBlock *CurBB = BBNode->getBlock();
BBNode = BBNode->getIDom();
assert(BBNode && "BBNode should not reach the root node!");
if (PDT->dominates(CurBB, BBNode->getBlock()))
continue;
BranchInst *Br = dyn_cast<BranchInst>(BBNode->getBlock()->getTerminator());
assert(Br && "A Valid Scop should only contain branch instruction");
if (Br->isUnconditional())
continue;
// Is BB on the ELSE side of the branch?
bool inverted = DT->dominates(Br->getSuccessor(1), BB);
Comparison *Cmp;
buildAffineCondition(*(Br->getCondition()), inverted, &Cmp);
Cond.push_back(*Cmp);
}
if (!Cond.empty())
BBConds[BB] = Cond;
}
/// Helper function to print the condition
static void printBBCond(raw_ostream &OS, const BBCond &Cond) {
assert(!Cond.empty() && "Unexpected empty condition!");
Cond[0].print(OS);
for (unsigned i = 1, e = Cond.size(); i != e; ++i) {
OS << " && ";
Cond[i].print(OS);
}
}
void TempScopInfo::buildCondition(BasicBlock *BB, Region &R) {
BasicBlock *RegionEntry = R.getEntry();
BBCond Cond;
DomTreeNode *BBNode = DT->getNode(BB), *EntryNode = DT->getNode(RegionEntry);
assert(BBNode && EntryNode && "Get null node while building condition!");
// Walk up the dominance tree until reaching the entry node. Collect all
// branching blocks on the path to BB except if BB postdominates the block
// containing the condition.
SmallVector<BasicBlock *, 4> DominatorBrBlocks;
while (BBNode != EntryNode) {
BasicBlock *CurBB = BBNode->getBlock();
BBNode = BBNode->getIDom();
assert(BBNode && "BBNode should not reach the root node!");
if (PDT->dominates(CurBB, BBNode->getBlock()))
continue;
BranchInst *Br = dyn_cast<BranchInst>(BBNode->getBlock()->getTerminator());
assert(Br && "A Valid Scop should only contain branch instruction");
if (Br->isUnconditional())
continue;
DominatorBrBlocks.push_back(BBNode->getBlock());
}
RegionInfo *RI = R.getRegionInfo();
// Iterate in reverse order over the dominating blocks. Until a non-affine
// branch was encountered add all conditions collected. If a non-affine branch
// was encountered, stop as we overapproximate from here on anyway.
for (auto BIt = DominatorBrBlocks.rbegin(), BEnd = DominatorBrBlocks.rend();
BIt != BEnd; BIt++) {
BasicBlock *BBNode = *BIt;
BranchInst *Br = dyn_cast<BranchInst>(BBNode->getTerminator());
assert(Br && "A Valid Scop should only contain branch instruction");
assert(Br->isConditional() && "Assumed a conditional branch");
if (SD->isNonAffineSubRegion(RI->getRegionFor(BBNode), &R))
break;
BasicBlock *TrueBB = Br->getSuccessor(0), *FalseBB = Br->getSuccessor(1);
// Is BB on the ELSE side of the branch?
bool inverted = DT->dominates(FalseBB, BB);
// If both TrueBB and FalseBB dominate BB, one of them must be the target of
// a back-edge, i.e. a loop header.
if (inverted && DT->dominates(TrueBB, BB)) {
assert(
(DT->dominates(TrueBB, FalseBB) || DT->dominates(FalseBB, TrueBB)) &&
"One of the successors should be the loop header and dominate the"
"other!");
// It is not an invert if the FalseBB is the header.
if (DT->dominates(FalseBB, TrueBB))
inverted = false;
}
Comparison *Cmp;
buildAffineCondition(*(Br->getCondition()), inverted, &Cmp);
Cond.push_back(*Cmp);
}
if (!Cond.empty())
BBConds[BB] = Cond;
}