src/jdk.internal.vm.compiler/share/classes/org.graalvm.compiler.lir/src/org/graalvm/compiler/lir/stackslotalloc/LSStackSlotAllocator.java
/*
* Copyright (c) 2014, 2019, Oracle and/or its affiliates. All rights reserved.
* DO NOT ALTER OR REMOVE COPYRIGHT NOTICES OR THIS FILE HEADER.
*
* This code is free software; you can redistribute it and/or modify it
* under the terms of the GNU General Public License version 2 only, as
* published by the Free Software Foundation.
*
* This code is distributed in the hope that it will be useful, but WITHOUT
* ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or
* FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License
* version 2 for more details (a copy is included in the LICENSE file that
* accompanied this code).
*
* You should have received a copy of the GNU General Public License version
* 2 along with this work; if not, write to the Free Software Foundation,
* Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301 USA.
*
* Please contact Oracle, 500 Oracle Parkway, Redwood Shores, CA 94065 USA
* or visit www.oracle.com if you need additional information or have any
* questions.
*/
package org.graalvm.compiler.lir.stackslotalloc;
import static org.graalvm.compiler.debug.DebugContext.BASIC_LEVEL;
import static org.graalvm.compiler.lir.LIRValueUtil.asVirtualStackSlot;
import static org.graalvm.compiler.lir.LIRValueUtil.isVirtualStackSlot;
import static org.graalvm.compiler.lir.phases.LIRPhase.Options.LIROptimization;
import java.util.ArrayDeque;
import java.util.ArrayList;
import java.util.Arrays;
import java.util.Deque;
import java.util.EnumSet;
import java.util.PriorityQueue;
import java.util.function.Predicate;
import jdk.internal.vm.compiler.collections.EconomicSet;
import org.graalvm.compiler.core.common.LIRKind;
import org.graalvm.compiler.core.common.cfg.AbstractBlockBase;
import org.graalvm.compiler.debug.DebugCloseable;
import org.graalvm.compiler.debug.DebugContext;
import org.graalvm.compiler.debug.Indent;
import org.graalvm.compiler.debug.TimerKey;
import org.graalvm.compiler.lir.LIR;
import org.graalvm.compiler.lir.LIRInstruction;
import org.graalvm.compiler.lir.LIRInstruction.OperandFlag;
import org.graalvm.compiler.lir.LIRInstruction.OperandMode;
import org.graalvm.compiler.lir.ValueProcedure;
import org.graalvm.compiler.lir.VirtualStackSlot;
import org.graalvm.compiler.lir.framemap.FrameMap;
import org.graalvm.compiler.lir.framemap.FrameMapBuilderTool;
import org.graalvm.compiler.lir.framemap.SimpleVirtualStackSlot;
import org.graalvm.compiler.lir.framemap.VirtualStackSlotRange;
import org.graalvm.compiler.lir.gen.LIRGenerationResult;
import org.graalvm.compiler.lir.phases.AllocationPhase;
import org.graalvm.compiler.options.NestedBooleanOptionKey;
import org.graalvm.compiler.options.Option;
import org.graalvm.compiler.options.OptionType;
import jdk.vm.ci.code.CodeUtil;
import jdk.vm.ci.code.StackSlot;
import jdk.vm.ci.code.TargetDescription;
import jdk.vm.ci.meta.Value;
import jdk.vm.ci.meta.ValueKind;
/**
* Linear Scan {@link StackSlotAllocatorUtil stack slot allocator}.
* <p>
* <b>Remark:</b> The analysis works under the assumption that a stack slot is no longer live after
* its last usage. If an {@link LIRInstruction instruction} transfers the raw address of the stack
* slot to another location, e.g. a registers, and this location is referenced later on, the
* {@link org.graalvm.compiler.lir.LIRInstruction.Use usage} of the stack slot must be marked with
* the {@link OperandFlag#UNINITIALIZED}. Otherwise the stack slot might be reused and its content
* destroyed.
*/
public final class LSStackSlotAllocator extends AllocationPhase {
public static class Options {
// @formatter:off
@Option(help = "Use linear scan stack slot allocation.", type = OptionType.Debug)
public static final NestedBooleanOptionKey LIROptLSStackSlotAllocator = new NestedBooleanOptionKey(LIROptimization, true);
// @formatter:on
}
private static final TimerKey MainTimer = DebugContext.timer("LSStackSlotAllocator");
private static final TimerKey NumInstTimer = DebugContext.timer("LSStackSlotAllocator[NumberInstruction]");
private static final TimerKey BuildIntervalsTimer = DebugContext.timer("LSStackSlotAllocator[BuildIntervals]");
private static final TimerKey VerifyIntervalsTimer = DebugContext.timer("LSStackSlotAllocator[VerifyIntervals]");
private static final TimerKey AllocateSlotsTimer = DebugContext.timer("LSStackSlotAllocator[AllocateSlots]");
private static final TimerKey AssignSlotsTimer = DebugContext.timer("LSStackSlotAllocator[AssignSlots]");
@Override
protected void run(TargetDescription target, LIRGenerationResult lirGenRes, AllocationContext context) {
allocateStackSlots((FrameMapBuilderTool) lirGenRes.getFrameMapBuilder(), lirGenRes);
lirGenRes.buildFrameMap();
}
@SuppressWarnings("try")
public static void allocateStackSlots(FrameMapBuilderTool builder, LIRGenerationResult res) {
if (builder.getNumberOfStackSlots() > 0) {
try (DebugCloseable t = MainTimer.start(res.getLIR().getDebug())) {
new Allocator(res.getLIR(), builder).allocate();
}
}
}
private static final class Allocator {
private final LIR lir;
private final DebugContext debug;
private final FrameMapBuilderTool frameMapBuilder;
private final StackInterval[] stackSlotMap;
private final PriorityQueue<StackInterval> unhandled;
private final PriorityQueue<StackInterval> active;
private final AbstractBlockBase<?>[] sortedBlocks;
private final int maxOpId;
@SuppressWarnings("try")
private Allocator(LIR lir, FrameMapBuilderTool frameMapBuilder) {
this.lir = lir;
this.debug = lir.getDebug();
this.frameMapBuilder = frameMapBuilder;
this.stackSlotMap = new StackInterval[frameMapBuilder.getNumberOfStackSlots()];
this.sortedBlocks = lir.getControlFlowGraph().getBlocks();
// insert by from
this.unhandled = new PriorityQueue<>((a, b) -> a.from() - b.from());
// insert by to
this.active = new PriorityQueue<>((a, b) -> a.to() - b.to());
try (DebugCloseable t = NumInstTimer.start(debug)) {
// step 1: number instructions
this.maxOpId = numberInstructions(lir, sortedBlocks);
}
}
@SuppressWarnings("try")
private void allocate() {
debug.dump(DebugContext.VERBOSE_LEVEL, lir, "After StackSlot numbering");
boolean allocationFramesizeEnabled = StackSlotAllocatorUtil.allocatedFramesize.isEnabled(debug);
long currentFrameSize = allocationFramesizeEnabled ? frameMapBuilder.getFrameMap().currentFrameSize() : 0;
EconomicSet<LIRInstruction> usePos;
// step 2: build intervals
try (DebugContext.Scope s = debug.scope("StackSlotAllocationBuildIntervals"); Indent indent = debug.logAndIndent("BuildIntervals"); DebugCloseable t = BuildIntervalsTimer.start(debug)) {
usePos = buildIntervals();
}
// step 3: verify intervals
if (debug.areScopesEnabled()) {
try (DebugCloseable t = VerifyIntervalsTimer.start(debug)) {
assert verifyIntervals();
}
}
if (debug.isDumpEnabled(DebugContext.VERBOSE_LEVEL)) {
dumpIntervals("Before stack slot allocation");
}
// step 4: allocate stack slots
try (DebugCloseable t = AllocateSlotsTimer.start(debug)) {
/*
* Allocate primitive spill slots before reference spill slots. This ensures a
* ReferenceMap will be as compact as possible and only exceed the encoding limit of
* a stack offset if there are really too many objects live on the stack at an
* instruction with a ReferenceMap (as opposed to the method simply having a very
* large frame).
*/
allocateStackSlots(IS_PRIMITIVE_INTERVAL);
allocateStackSlots(IS_REFERENCE_INTERVAL);
}
if (debug.isDumpEnabled(DebugContext.VERBOSE_LEVEL)) {
dumpIntervals("After stack slot allocation");
}
// step 5: assign stack slots
try (DebugCloseable t = AssignSlotsTimer.start(debug)) {
assignStackSlots(usePos);
}
if (allocationFramesizeEnabled) {
StackSlotAllocatorUtil.allocatedFramesize.add(debug, frameMapBuilder.getFrameMap().currentFrameSize() - currentFrameSize);
}
}
// ====================
// step 1: number instructions
// ====================
/**
* Numbers all instructions in all blocks.
*
* @return The id of the last operation.
*/
private static int numberInstructions(LIR lir, AbstractBlockBase<?>[] sortedBlocks) {
int opId = 0;
int index = 0;
for (AbstractBlockBase<?> block : sortedBlocks) {
ArrayList<LIRInstruction> instructions = lir.getLIRforBlock(block);
int numInst = instructions.size();
for (int j = 0; j < numInst; j++) {
LIRInstruction op = instructions.get(j);
op.setId(opId);
index++;
opId += 2; // numbering of lirOps by two
}
}
assert (index << 1) == opId : "must match: " + (index << 1);
return opId - 2;
}
// ====================
// step 2: build intervals
// ====================
private EconomicSet<LIRInstruction> buildIntervals() {
return new FixPointIntervalBuilder(lir, stackSlotMap, maxOpId()).build();
}
// ====================
// step 3: verify intervals
// ====================
private boolean verifyIntervals() {
for (StackInterval interval : stackSlotMap) {
if (interval != null) {
assert interval.verify(maxOpId());
}
}
return true;
}
// ====================
// step 4: allocate stack slots
// ====================
@SuppressWarnings("try")
private void allocateStackSlots(Predicate<StackInterval> predicate) {
for (StackInterval interval : stackSlotMap) {
if (interval != null && (predicate == null || predicate.test(interval))) {
unhandled.add(interval);
}
}
for (StackInterval current = activateNext(); current != null; current = activateNext()) {
try (Indent indent = debug.logAndIndent("allocate %s", current)) {
allocateSlot(current);
}
}
// Cannot re-use free slots between rounds of slot allocation
freeSlots = null;
active.clear();
}
private static final Predicate<StackInterval> IS_REFERENCE_INTERVAL = new Predicate<StackInterval>() {
@Override
public boolean test(StackInterval interval) {
return !((LIRKind) interval.kind()).isValue();
}
};
private static final Predicate<StackInterval> IS_PRIMITIVE_INTERVAL = new Predicate<StackInterval>() {
@Override
public boolean test(StackInterval interval) {
return ((LIRKind) interval.kind()).isValue();
}
};
private void allocateSlot(StackInterval current) {
VirtualStackSlot virtualSlot = current.getOperand();
final StackSlot location;
if (virtualSlot instanceof VirtualStackSlotRange) {
// No reuse of ranges (yet).
VirtualStackSlotRange slotRange = (VirtualStackSlotRange) virtualSlot;
location = frameMapBuilder.getFrameMap().allocateStackSlots(slotRange.getSlots());
StackSlotAllocatorUtil.virtualFramesize.add(debug, frameMapBuilder.getFrameMap().spillSlotRangeSize(slotRange.getSlots()));
StackSlotAllocatorUtil.allocatedSlots.increment(debug);
} else {
assert virtualSlot instanceof SimpleVirtualStackSlot : "Unexpected VirtualStackSlot type: " + virtualSlot;
StackSlot slot = findFreeSlot((SimpleVirtualStackSlot) virtualSlot);
if (slot != null) {
/*
* Free stack slot available. Note that we create a new one because the kind
* might not match.
*/
location = StackSlot.get(current.kind(), slot.getRawOffset(), slot.getRawAddFrameSize());
StackSlotAllocatorUtil.reusedSlots.increment(debug);
debug.log(BASIC_LEVEL, "Reuse stack slot %s (reallocated from %s) for virtual stack slot %s", location, slot, virtualSlot);
} else {
// Allocate new stack slot.
location = frameMapBuilder.getFrameMap().allocateSpillSlot(virtualSlot.getValueKind());
StackSlotAllocatorUtil.virtualFramesize.add(debug, frameMapBuilder.getFrameMap().spillSlotSize(virtualSlot.getValueKind()));
StackSlotAllocatorUtil.allocatedSlots.increment(debug);
debug.log(BASIC_LEVEL, "New stack slot %s for virtual stack slot %s", location, virtualSlot);
}
}
debug.log("Allocate location %s for interval %s", location, current);
current.setLocation(location);
}
/**
* Map from log2 of {@link FrameMap#spillSlotSize(ValueKind) a spill slot size} to a list of
* free stack slots.
*/
private ArrayList<Deque<StackSlot>> freeSlots;
/**
* @return The list of free stack slots for {@code index} or {@code null} if there is none.
*/
private Deque<StackSlot> getNullOrFreeSlots(int index) {
if (freeSlots == null) {
return null;
}
if (index < freeSlots.size()) {
return freeSlots.get(index);
}
return null;
}
/**
* @return the list of free stack slots for {@code index}. If there is none a list is
* created.
*/
private Deque<StackSlot> getOrInitFreeSlots(int index) {
Deque<StackSlot> freeList = null;
if (freeSlots == null) {
freeSlots = new ArrayList<>(6);
} else if (index < freeSlots.size()) {
freeList = freeSlots.get(index);
}
if (freeList == null) {
int requiredSize = index + 1;
for (int i = freeSlots.size(); i < requiredSize; i++) {
freeSlots.add(null);
}
freeList = new ArrayDeque<>();
freeSlots.set(index, freeList);
}
return freeList;
}
/**
* Gets a free stack slot for {@code slot} or {@code null} if there is none.
*/
private StackSlot findFreeSlot(SimpleVirtualStackSlot slot) {
assert slot != null;
int size = log2SpillSlotSize(slot.getValueKind());
Deque<StackSlot> freeList = getNullOrFreeSlots(size);
if (freeList == null) {
return null;
}
return freeList.pollLast();
}
/**
* Adds a stack slot to the list of free slots.
*/
private void freeSlot(StackSlot slot) {
int size = log2SpillSlotSize(slot.getValueKind());
getOrInitFreeSlots(size).addLast(slot);
}
private int log2SpillSlotSize(ValueKind<?> kind) {
int size = frameMapBuilder.getFrameMap().spillSlotSize(kind);
assert CodeUtil.isPowerOf2(size);
return CodeUtil.log2(size);
}
/**
* Gets the next unhandled interval and finishes handled intervals.
*/
private StackInterval activateNext() {
if (unhandled.isEmpty()) {
return null;
}
StackInterval next = unhandled.poll();
// finish handled intervals
for (int id = next.from(); activePeekId() < id;) {
finished(active.poll());
}
debug.log("active %s", next);
active.add(next);
return next;
}
/**
* Gets the lowest {@link StackInterval#to() end position} of all active intervals. If there
* is none {@link Integer#MAX_VALUE} is returned.
*/
private int activePeekId() {
StackInterval first = active.peek();
if (first == null) {
return Integer.MAX_VALUE;
}
return first.to();
}
/**
* Finishes {@code interval} by adding its location to the list of free stack slots.
*/
private void finished(StackInterval interval) {
StackSlot location = interval.location();
debug.log("finished %s (freeing %s)", interval, location);
freeSlot(location);
}
// ====================
// step 5: assign stack slots
// ====================
private void assignStackSlots(EconomicSet<LIRInstruction> usePos) {
for (LIRInstruction op : usePos) {
op.forEachInput(assignSlot);
op.forEachAlive(assignSlot);
op.forEachState(assignSlot);
op.forEachTemp(assignSlot);
op.forEachOutput(assignSlot);
}
}
ValueProcedure assignSlot = new ValueProcedure() {
@Override
public Value doValue(Value value, OperandMode mode, EnumSet<OperandFlag> flags) {
if (isVirtualStackSlot(value)) {
VirtualStackSlot slot = asVirtualStackSlot(value);
StackInterval interval = get(slot);
assert interval != null;
return interval.location();
}
return value;
}
};
// ====================
//
// ====================
/**
* Gets the highest instruction id.
*/
private int maxOpId() {
return maxOpId;
}
private StackInterval get(VirtualStackSlot stackSlot) {
return stackSlotMap[stackSlot.getId()];
}
private void dumpIntervals(String label) {
debug.dump(DebugContext.VERBOSE_LEVEL, new StackIntervalDumper(Arrays.copyOf(stackSlotMap, stackSlotMap.length)), label);
}
}
}