@Test
public void testBlockSchedule() {
ScheduleResult schedule =
getFinalSchedule("testBlockScheduleSnippet", TestMode.WITHOUT_FRAMESTATES);
StructuredGraph graph = schedule.getCFG().graph;
NodeIterable<WriteNode> writeNodes = graph.getNodes().filter(WriteNode.class);
assertDeepEquals(1, schedule.getCFG().getBlocks().size());
assertDeepEquals(8, writeNodes.count());
assertDeepEquals(1, graph.getNodes().filter(FloatingReadNode.class).count());
FloatingReadNode read = graph.getNodes().filter(FloatingReadNode.class).first();
WriteNode[] writes = new WriteNode[8];
int i = 0;
for (WriteNode n : writeNodes) {
writes[i] = n;
i++;
}
assertOrderedAfterSchedule(schedule, writes[4], read);
assertOrderedAfterSchedule(schedule, read, writes[5]);
for (int j = 0; j < 7; j++) {
assertOrderedAfterSchedule(schedule, writes[j], writes[j + 1]);
}
}
@Test
public void testIfRead3() {
ScheduleResult schedule = getFinalSchedule("testIfRead3Snippet", TestMode.WITHOUT_FRAMESTATES);
assertDeepEquals(4, schedule.getCFG().getBlocks().size());
assertReadWithinStartBlock(schedule, false);
assertReadWithinAllReturnBlocks(schedule, true);
}
@Test
public void testAntiDependency() {
ScheduleResult schedule =
getFinalSchedule("testAntiDependencySnippet", TestMode.WITHOUT_FRAMESTATES);
assertDeepEquals(4, schedule.getCFG().getBlocks().size());
assertReadBeforeAllWritesInStartBlock(schedule);
}
@Test
public void testIfRead1() {
ScheduleResult schedule = getFinalSchedule("testIfRead1Snippet", TestMode.WITHOUT_FRAMESTATES);
assertDeepEquals(3, schedule.getCFG().getBlocks().size());
assertReadWithinStartBlock(schedule, true);
assertReadAndWriteInSameBlock(schedule, false);
}
private void assertReadWithinStartBlock(ScheduleResult schedule, boolean withinStartBlock) {
boolean readEncountered = false;
for (Node node : schedule.getBlockToNodesMap().get(schedule.getCFG().getStartBlock())) {
if (node instanceof FloatingReadNode) {
readEncountered = true;
}
}
assertDeepEquals(withinStartBlock, readEncountered);
}
@Test
public void testIfRead2() {
ScheduleResult schedule = getFinalSchedule("testIfRead2Snippet", TestMode.WITHOUT_FRAMESTATES);
assertDeepEquals(3, schedule.getCFG().getBlocks().size());
assertDeepEquals(1, schedule.getCFG().graph.getNodes().filter(FloatingReadNode.class).count());
assertReadWithinStartBlock(schedule, false);
assertReadWithinAllReturnBlocks(schedule, false);
assertReadAndWriteInSameBlock(schedule, false);
}
@Test
public void testLoop9() {
ScheduleResult schedule = getFinalSchedule("testLoop9Snippet", TestMode.WITHOUT_FRAMESTATES);
StructuredGraph graph = schedule.getCFG().getStartBlock().getBeginNode().graph();
assertThat(graph.getNodes(ReturnNode.TYPE), hasCount(1));
ReturnNode ret = graph.getNodes(ReturnNode.TYPE).first();
assertThat(ret.result(), instanceOf(FloatingReadNode.class));
Block readBlock = schedule.getNodeToBlockMap().get(ret.result());
Assert.assertEquals(0, readBlock.getLoopDepth());
}
@Override
public void run(StructuredGraph graph) {
schedulePhase.apply(graph, false);
schedule = graph.getLastSchedule();
schedule.getCFG().computePostdominators();
Block startBlock = schedule.getCFG().getStartBlock();
ProcessFrame rootFrame =
new ProcessFrame(startBlock, graph.createNodeBitMap(), startBlock.getBeginNode(), null);
LoweringPhase.processBlock(rootFrame);
}
@Test
public void testArrayCopy() {
ScheduleResult schedule =
getFinalSchedule("testArrayCopySnippet", TestMode.INLINED_WITHOUT_FRAMESTATES);
StructuredGraph graph = schedule.getCFG().getStartBlock().getBeginNode().graph();
assertDeepEquals(1, graph.getNodes(ReturnNode.TYPE).count());
ReturnNode ret = graph.getNodes(ReturnNode.TYPE).first();
assertTrue(
ret.result() + " should be a FloatingReadNode", ret.result() instanceof FloatingReadNode);
assertDeepEquals(schedule.getCFG().blockFor(ret), schedule.getCFG().blockFor(ret.result()));
assertReadWithinAllReturnBlocks(schedule, true);
}
@Test
public void testSimple() {
for (TestMode mode : TestMode.values()) {
ScheduleResult schedule = getFinalSchedule("testSimpleSnippet", mode);
StructuredGraph graph = schedule.getCFG().graph;
assertReadAndWriteInSameBlock(schedule, true);
assertOrderedAfterSchedule(
schedule,
graph.getNodes().filter(FloatingReadNode.class).first(),
graph.getNodes().filter(WriteNode.class).first());
}
}
private static void assertReadBeforeAllWritesInStartBlock(ScheduleResult schedule) {
boolean writeNodeFound = false;
boolean readNodeFound = false;
for (Node node : schedule.nodesFor(schedule.getCFG().getStartBlock())) {
if (node instanceof FloatingReadNode) {
assertTrue(!writeNodeFound);
readNodeFound = true;
} else if (node instanceof WriteNode) {
writeNodeFound = true;
}
}
assertTrue(readNodeFound);
}
/**
* Gets all usages of a floating, lowerable node that are unscheduled.
*
* <p>Given that the lowering of such nodes may introduce fixed nodes, they must be lowered in
* the context of a usage that dominates all other usages. The fixed nodes resulting from
* lowering are attached to the fixed node context of the dominating usage. This ensures the
* post-lowering graph still has a valid schedule.
*
* @param node a {@link Lowerable} node
*/
private Collection<Node> getUnscheduledUsages(Node node) {
List<Node> unscheduledUsages = new ArrayList<>();
if (node instanceof FloatingNode) {
for (Node usage : node.usages()) {
if (usage instanceof ValueNode) {
if (schedule.getCFG().getNodeToBlock().isNew(usage)
|| schedule.getCFG().blockFor(usage) == null) {
unscheduledUsages.add(usage);
}
}
}
}
return unscheduledUsages;
}
private void assertReadWithinAllReturnBlocks(ScheduleResult schedule, boolean withinReturnBlock) {
StructuredGraph graph = schedule.getCFG().graph;
assertTrue(graph.getNodes(ReturnNode.TYPE).isNotEmpty());
int withRead = 0;
int returnBlocks = 0;
for (ReturnNode returnNode : graph.getNodes(ReturnNode.TYPE)) {
Block block = schedule.getCFG().getNodeToBlock().get(returnNode);
for (Node node : schedule.getBlockToNodesMap().get(block)) {
if (node instanceof FloatingReadNode) {
withRead++;
break;
}
}
returnBlocks++;
}
assertDeepEquals(withRead == returnBlocks, withinReturnBlock);
}
@Test
public void testValueProxyInputs() {
StructuredGraph graph = parseEager("testValueProxyInputsSnippet", AllowAssumptions.YES);
for (FrameState fs : graph.getNodes().filter(FrameState.class).snapshot()) {
fs.replaceAtUsages(null);
GraphUtil.killWithUnusedFloatingInputs(fs);
}
SchedulePhase schedulePhase = new SchedulePhase(SchedulingStrategy.LATEST);
schedulePhase.apply(graph);
ScheduleResult schedule = graph.getLastSchedule();
NodeMap<Block> nodeToBlock = schedule.getCFG().getNodeToBlock();
assertTrue(graph.getNodes().filter(LoopExitNode.class).count() == 1);
LoopExitNode loopExit = graph.getNodes().filter(LoopExitNode.class).first();
List<Node> list = schedule.nodesFor(nodeToBlock.get(loopExit));
for (BinaryArithmeticNode<?> node : graph.getNodes().filter(BinaryArithmeticNode.class)) {
if (!(node instanceof AddNode)) {
assertTrue(node.toString(), nodeToBlock.get(node) == nodeToBlock.get(loopExit));
assertTrue(
list.indexOf(node) + " < " + list.indexOf(loopExit) + ", " + node + ", " + loopExit,
list.indexOf(node) < list.indexOf(loopExit));
}
}
}
private static void assertReadAndWriteInSameBlock(ScheduleResult schedule, boolean inSame) {
StructuredGraph graph = schedule.getCFG().graph;
FloatingReadNode read = graph.getNodes().filter(FloatingReadNode.class).first();
WriteNode write = graph.getNodes().filter(WriteNode.class).first();
assertTrue(!(inSame ^ schedule.getCFG().blockFor(read) == schedule.getCFG().blockFor(write)));
}
@SuppressWarnings("try")
private AnchoringNode process(
final Block b, final NodeBitMap activeGuards, final AnchoringNode startAnchor) {
final LoweringToolImpl loweringTool =
new LoweringToolImpl(context, startAnchor, activeGuards, b.getBeginNode());
// Lower the instructions of this block.
List<Node> nodes = schedule.nodesFor(b);
for (Node node : nodes) {
if (node.isDeleted()) {
// This case can happen when previous lowerings deleted nodes.
continue;
}
// Cache the next node to be able to reconstruct the previous of the next node
// after lowering.
FixedNode nextNode = null;
if (node instanceof FixedWithNextNode) {
nextNode = ((FixedWithNextNode) node).next();
} else {
nextNode = loweringTool.lastFixedNode().next();
}
if (node instanceof Lowerable) {
Collection<Node> unscheduledUsages = null;
assert (unscheduledUsages = getUnscheduledUsages(node)) != null;
Mark preLoweringMark = node.graph().getMark();
try (DebugCloseable s = node.graph().withNodeContext(node)) {
((Lowerable) node).lower(loweringTool);
}
if (loweringTool.guardAnchor.asNode().isDeleted()) {
// TODO nextNode could be deleted but this is not currently supported
assert nextNode.isAlive();
loweringTool.guardAnchor = AbstractBeginNode.prevBegin(nextNode);
}
assert checkPostNodeLowering(node, loweringTool, preLoweringMark, unscheduledUsages);
}
if (!nextNode.isAlive()) {
// can happen when the rest of the block is killed by lowering
// (e.g. by an unconditional deopt)
break;
} else {
Node nextLastFixed = nextNode.predecessor();
if (!(nextLastFixed instanceof FixedWithNextNode)) {
// insert begin node, to have a valid last fixed for next lowerable node.
// This is about lowering a FixedWithNextNode to a control split while this
// FixedWithNextNode is followed by some kind of BeginNode.
// For example the when a FixedGuard followed by a loop exit is lowered to a
// control-split + deopt.
AbstractBeginNode begin = node.graph().add(new BeginNode());
nextLastFixed.replaceFirstSuccessor(nextNode, begin);
begin.setNext(nextNode);
nextLastFixed = begin;
}
loweringTool.setLastFixedNode((FixedWithNextNode) nextLastFixed);
}
}
return loweringTool.getCurrentGuardAnchor();
}