/** Split an unpredicated predicate block. */
private void splitBlock(Hyperblock hb, PredicateBlock block) {
int chunkSize = (block.getBlockSize() + block.getFanout()) / 2;
int maxChunk = (int) (Trips2Machine.maxBlockSize * MAXFILL);
if (chunkSize > maxChunk) {
chunkSize = maxChunk;
}
Instruction splitLocation = findSplitLocation(hb, block, chunkSize);
PredicateBlock start = block.cut(splitLocation, gen);
Hyperblock nhb = new Hyperblock(start, regs);
// Insert the new hyperblock into the HFG.
for (int i = hb.numOutEdges() - 1; i > -1; i--) {
Hyperblock out = (Hyperblock) hb.getOutEdge(i);
out.replaceInEdge(hb, nhb);
hb.deleteOutEdge(out);
nhb.addOutEdge(out);
}
hb.addOutEdge(nhb);
nhb.addInEdge(hb);
workingSet.add(nhb);
hb.invalidateDomination();
hb.findLastBlock();
hb.determinePredicatesBranches();
nhb.findLastBlock();
nhb.determinePredicatesBranches();
// Update the return block if it has changed.
if (gen.getReturnBlock() == hb) {
gen.setReturnBlock(nhb);
}
}
/** Reverse if-convert the given predicate block from the hyperblock. */
private void reverseIfConvert(Hyperblock hb, PredicateBlock start) {
Stack<Node> wl = WorkArea.<Node>getStack("reverseIfConvert");
Stack<PredicateBlock> reverse = WorkArea.<PredicateBlock>getStack("reverseIfConvert");
Vector<PredicateBlock> blocks = new Vector<PredicateBlock>();
Vector<Hyperblock> hbs = new Vector<Hyperblock>();
// Find the blocks which need to be reverse if-converted.
start.nextVisit();
start.setVisited();
wl.add(start);
while (!wl.isEmpty()) {
PredicateBlock block = (PredicateBlock) wl.pop();
block.pushOutEdges(wl);
for (int i = 0; i < block.numInEdges(); i++) {
PredicateBlock pred = (PredicateBlock) block.getInEdge(i);
if (!pred.visited()) {
blocks.add(block);
break;
} else if (blocks.contains(pred) && block.numInEdges() > 1) {
blocks.add(block);
break;
}
}
}
// Order the blocks to reverse if-convert based on their depth from the root.
PredicateBlock head = hb.getFirstBlock();
Vector<PredicateBlock> wl2 = new Vector<PredicateBlock>();
head.nextVisit();
head.setVisited();
wl2.add(head);
while (!wl2.isEmpty()) {
int l = wl2.size();
for (int i = 0; i < l; i++) {
PredicateBlock block = wl2.get(i);
if (blocks.contains(block)) {
blocks.remove(block);
reverse.push(block);
}
}
wl2 = hb.getNextPFGLevel(wl2);
}
// Remove the special "dummy" last block from the PFG.
PredicateBlock last = hb.getLastBlock();
assert (last.numOutEdges() == 0 && !last.isPredicated());
if (last.getFirstInstruction() == null) {
for (int i = last.numInEdges() - 1; i > -1; i--) {
PredicateBlock pred = (PredicateBlock) last.getInEdge(i);
pred.deleteOutEdge(last);
last.deleteInEdge(pred);
}
reverse.remove(last);
}
// Reverse if-convert.
while (!reverse.isEmpty()) {
PredicateBlock block = reverse.pop();
Hyperblock hbn = reverseIfConvertBlock(block);
hbs.add(hbn);
workingSet.add(hbn);
}
// Update the PFG.
hb.updateLastBlock();
hb.invalidateDomination(); // The dominators are now invalid.
// Insert the new hyperblocks in the HFG.
HashMap<Instruction, Hyperblock> entries = computeEntries(hb, hbs);
hbs.add(hb);
Hyperblock.computeHyperblockFlowGraph(hbs, entries);
// Update the return block. Since 'hbs' is an ordered list, the
// first element in the list is the hyperblock with the return
// because this was the original tail of the PFG which was reverse
// if-converted.
if (hb == gen.getReturnBlock()) {
gen.setReturnBlock(hbs.firstElement());
}
WorkArea.<Node>returnStack(wl);
WorkArea.<PredicateBlock>returnStack(reverse);
}
