+
+ // Loop over all of the alive blocks in the function. If any successor
+ // blocks are not alive, we adjust the outgoing branches to branch to the
+ // first live postdominator of the live block, adjusting any PHI nodes in
+ // the block to reflect this.
+ //
+ for (Function::iterator I = Func->begin(), E = Func->end(); I != E; ++I)
+ if (AliveBlocks.count(I)) {
+ BasicBlock *BB = I;
+ TerminatorInst *TI = BB->getTerminator();
+
+ // If the terminator instruction is alive, but the block it is contained
+ // in IS alive, this means that this terminator is a conditional branch
+ // on a condition that doesn't matter. Make it an unconditional branch
+ // to ONE of the successors. This has the side effect of dropping a use
+ // of the conditional value, which may also be dead.
+ if (!LiveSet.count(TI))
+ TI = convertToUnconditionalBranch(TI);
+
+ // Loop over all of the successors, looking for ones that are not alive.
+ // We cannot save the number of successors in the terminator instruction
+ // here because we may remove them if we don't have a postdominator...
+ //
+ for (unsigned i = 0; i != TI->getNumSuccessors(); ++i)
+ if (!AliveBlocks.count(TI->getSuccessor(i))) {
+ // Scan up the postdominator tree, looking for the first
+ // postdominator that is alive, and the last postdominator that is
+ // dead...
+ //
+ PostDominatorTree::Node *LastNode = DT[TI->getSuccessor(i)];
+
+ // There is a special case here... if there IS no post-dominator for
+ // the block we have no owhere to point our branch to. Instead,
+ // convert it to a return. This can only happen if the code
+ // branched into an infinite loop. Note that this may not be
+ // desirable, because we _are_ altering the behavior of the code.
+ // This is a well known drawback of ADCE, so in the future if we
+ // choose to revisit the decision, this is where it should be.
+ //
+ if (LastNode == 0) { // No postdominator!
+ // Call RemoveSuccessor to transmogrify the terminator instruction
+ // to not contain the outgoing branch, or to create a new
+ // terminator if the form fundamentally changes (i.e.,
+ // unconditional branch to return). Note that this will change a
+ // branch into an infinite loop into a return instruction!
+ //
+ RemoveSuccessor(TI, i);
+
+ // RemoveSuccessor may replace TI... make sure we have a fresh
+ // pointer... and e variable.
+ //
+ TI = BB->getTerminator();
+
+ // Rescan this successor...
+ --i;
+ } else {
+ PostDominatorTree::Node *NextNode = LastNode->getIDom();
+
+ while (!AliveBlocks.count(NextNode->getBlock())) {
+ LastNode = NextNode;
+ NextNode = NextNode->getIDom();
+ }
+
+ // Get the basic blocks that we need...
+ BasicBlock *LastDead = LastNode->getBlock();
+ BasicBlock *NextAlive = NextNode->getBlock();
+
+ // Make the conditional branch now go to the next alive block...
+ TI->getSuccessor(i)->removePredecessor(BB);
+ TI->setSuccessor(i, NextAlive);
+
+ // If there are PHI nodes in NextAlive, we need to add entries to
+ // the PHI nodes for the new incoming edge. The incoming values
+ // should be identical to the incoming values for LastDead.
+ //
+ for (BasicBlock::iterator II = NextAlive->begin();
+ PHINode *PN = dyn_cast<PHINode>(II); ++II)
+ if (LiveSet.count(PN)) { // Only modify live phi nodes
+ // Get the incoming value for LastDead...
+ int OldIdx = PN->getBasicBlockIndex(LastDead);
+ assert(OldIdx != -1 &&"LastDead is not a pred of NextAlive!");
+ Value *InVal = PN->getIncomingValue(OldIdx);
+
+ // Add an incoming value for BB now...
+ PN->addIncoming(InVal, BB);
+ }
+ }
+ }
+
+ // Now loop over all of the instructions in the basic block, telling
+ // dead instructions to drop their references. This is so that the next
+ // sweep over the program can safely delete dead instructions without
+ // other dead instructions still referring to them.
+ //
+ dropReferencesOfDeadInstructionsInLiveBlock(BB);
+ }