Mercurial > hg > graal-compiler
view graal/com.oracle.graal.lir/src/com/oracle/graal/lir/alloc/lsra/MoveResolver.java @ 23390:de7387a91cea
materialized value of a linear scan interval can be any Constant, remove unnecessary restriction that it must be a JavaConstant
| author | Christian Wimmer <christian.wimmer@oracle.com> |
|---|---|
| date | Thu, 04 Feb 2016 17:19:14 -0800 |
| parents | 40f5437c92e9 |
| children |
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/* * Copyright (c) 2009, 2015, 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 com.oracle.graal.lir.alloc.lsra; import static jdk.vm.ci.code.ValueUtil.asRegister; import static jdk.vm.ci.code.ValueUtil.isIllegal; import static jdk.vm.ci.code.ValueUtil.isRegister; import java.util.ArrayList; import java.util.HashSet; import java.util.List; import jdk.vm.ci.common.JVMCIError; import jdk.vm.ci.meta.AllocatableValue; import jdk.vm.ci.meta.Constant; import jdk.vm.ci.meta.LIRKind; import jdk.vm.ci.meta.Value; import com.oracle.graal.debug.Debug; import com.oracle.graal.debug.DebugMetric; import com.oracle.graal.debug.Indent; import com.oracle.graal.lir.LIRInsertionBuffer; import com.oracle.graal.lir.LIRInstruction; /** */ public class MoveResolver { private static final DebugMetric cycleBreakingSlotsAllocated = Debug.metric("LSRA[cycleBreakingSlotsAllocated]"); private final LinearScan allocator; private int insertIdx; private LIRInsertionBuffer insertionBuffer; // buffer where moves are inserted private final List<Interval> mappingFrom; private final List<Constant> mappingFromOpr; private final List<Interval> mappingTo; private boolean multipleReadsAllowed; private final int[] registerBlocked; protected void setValueBlocked(Value location, int direction) { assert direction == 1 || direction == -1 : "out of bounds"; if (isRegister(location)) { registerBlocked[asRegister(location).number] += direction; } else { throw JVMCIError.shouldNotReachHere("unhandled value " + location); } } protected Interval getMappingFrom(int i) { return mappingFrom.get(i); } protected int mappingFromSize() { return mappingFrom.size(); } protected int valueBlocked(Value location) { if (isRegister(location)) { return registerBlocked[asRegister(location).number]; } throw JVMCIError.shouldNotReachHere("unhandled value " + location); } void setMultipleReadsAllowed() { multipleReadsAllowed = true; } protected boolean areMultipleReadsAllowed() { return multipleReadsAllowed; } boolean hasMappings() { return mappingFrom.size() > 0; } protected LinearScan getAllocator() { return allocator; } protected MoveResolver(LinearScan allocator) { this.allocator = allocator; this.multipleReadsAllowed = false; this.mappingFrom = new ArrayList<>(8); this.mappingFromOpr = new ArrayList<>(8); this.mappingTo = new ArrayList<>(8); this.insertIdx = -1; this.insertionBuffer = new LIRInsertionBuffer(); this.registerBlocked = new int[allocator.getRegisters().length]; } protected boolean checkEmpty() { assert mappingFrom.size() == 0 && mappingFromOpr.size() == 0 && mappingTo.size() == 0 : "list must be empty before and after processing"; for (int i = 0; i < getAllocator().getRegisters().length; i++) { assert registerBlocked[i] == 0 : "register map must be empty before and after processing"; } checkMultipleReads(); return true; } protected void checkMultipleReads() { assert !areMultipleReadsAllowed() : "must have default value"; } private boolean verifyBeforeResolve() { assert mappingFrom.size() == mappingFromOpr.size() : "length must be equal"; assert mappingFrom.size() == mappingTo.size() : "length must be equal"; assert insertIdx != -1 : "insert position not set"; int i; int j; if (!areMultipleReadsAllowed()) { for (i = 0; i < mappingFrom.size(); i++) { for (j = i + 1; j < mappingFrom.size(); j++) { assert mappingFrom.get(i) == null || mappingFrom.get(i) != mappingFrom.get(j) : "cannot read from same interval twice"; } } } for (i = 0; i < mappingTo.size(); i++) { for (j = i + 1; j < mappingTo.size(); j++) { assert mappingTo.get(i) != mappingTo.get(j) : "cannot write to same interval twice"; } } HashSet<Value> usedRegs = new HashSet<>(); if (!areMultipleReadsAllowed()) { for (i = 0; i < mappingFrom.size(); i++) { Interval interval = mappingFrom.get(i); if (interval != null && !isIllegal(interval.location())) { boolean unique = usedRegs.add(interval.location()); assert unique : "cannot read from same register twice"; } } } usedRegs.clear(); for (i = 0; i < mappingTo.size(); i++) { Interval interval = mappingTo.get(i); if (isIllegal(interval.location())) { // After insertion the location may become illegal, so don't check it since multiple // intervals might be illegal. continue; } boolean unique = usedRegs.add(interval.location()); assert unique : "cannot write to same register twice"; } verifyStackSlotMapping(); return true; } protected void verifyStackSlotMapping() { HashSet<Value> usedRegs = new HashSet<>(); for (int i = 0; i < mappingFrom.size(); i++) { Interval interval = mappingFrom.get(i); if (interval != null && !isRegister(interval.location())) { usedRegs.add(interval.location()); } } for (int i = 0; i < mappingTo.size(); i++) { Interval interval = mappingTo.get(i); assert !usedRegs.contains(interval.location()) || checkIntervalLocation(mappingFrom.get(i), interval, mappingFromOpr.get(i)) : "stack slots used in mappingFrom must be disjoint to mappingTo"; } } private static boolean checkIntervalLocation(Interval from, Interval to, Constant fromOpr) { if (from == null) { return fromOpr != null; } else { return to.location().equals(from.location()); } } // mark assignedReg and assignedRegHi of the interval as blocked private void blockRegisters(Interval interval) { Value location = interval.location(); if (mightBeBlocked(location)) { assert areMultipleReadsAllowed() || valueBlocked(location) == 0 : "location already marked as used: " + location; int direction = 1; setValueBlocked(location, direction); Debug.log("block %s", location); } } // mark assignedReg and assignedRegHi of the interval as unblocked private void unblockRegisters(Interval interval) { Value location = interval.location(); if (mightBeBlocked(location)) { assert valueBlocked(location) > 0 : "location already marked as unused: " + location; setValueBlocked(location, -1); Debug.log("unblock %s", location); } } /** * Checks if the {@linkplain Interval#location() location} of {@code to} is not blocked or is * only blocked by {@code from}. */ private boolean safeToProcessMove(Interval from, Interval to) { Value fromReg = from != null ? from.location() : null; Value location = to.location(); if (mightBeBlocked(location)) { if ((valueBlocked(location) > 1 || (valueBlocked(location) == 1 && !isMoveToSelf(fromReg, location)))) { return false; } } return true; } protected boolean isMoveToSelf(Value from, Value to) { assert to != null; if (to.equals(from)) { return true; } if (from != null && isRegister(from) && isRegister(to) && asRegister(from).equals(asRegister(to))) { assert LIRKind.verifyMoveKinds(to.getLIRKind(), from.getLIRKind()) : String.format("Same register but Kind mismatch %s <- %s", to, from); return true; } return false; } protected boolean mightBeBlocked(Value location) { return isRegister(location); } private void createInsertionBuffer(List<LIRInstruction> list) { assert !insertionBuffer.initialized() : "overwriting existing buffer"; insertionBuffer.init(list); } private void appendInsertionBuffer() { if (insertionBuffer.initialized()) { insertionBuffer.finish(); } assert !insertionBuffer.initialized() : "must be uninitialized now"; insertIdx = -1; } private void insertMove(Interval fromInterval, Interval toInterval) { assert !fromInterval.operand.equals(toInterval.operand) : "from and to interval equal: " + fromInterval; assert LIRKind.verifyMoveKinds(toInterval.kind(), fromInterval.kind()) : "move between different types"; assert insertIdx != -1 : "must setup insert position first"; insertionBuffer.append(insertIdx, createMove(fromInterval.operand, toInterval.operand, fromInterval.location(), toInterval.location())); if (Debug.isLogEnabled()) { Debug.log("insert move from %s to %s at %d", fromInterval, toInterval, insertIdx); } } /** * @param fromOpr {@link Interval#operand operand} of the {@code from} interval * @param toOpr {@link Interval#operand operand} of the {@code to} interval * @param fromLocation {@link Interval#location() location} of the {@code to} interval * @param toLocation {@link Interval#location() location} of the {@code to} interval */ protected LIRInstruction createMove(AllocatableValue fromOpr, AllocatableValue toOpr, AllocatableValue fromLocation, AllocatableValue toLocation) { return getAllocator().getSpillMoveFactory().createMove(toOpr, fromOpr); } private void insertMove(Constant fromOpr, Interval toInterval) { assert insertIdx != -1 : "must setup insert position first"; AllocatableValue toOpr = toInterval.operand; LIRInstruction move = getAllocator().getSpillMoveFactory().createLoad(toOpr, fromOpr); insertionBuffer.append(insertIdx, move); if (Debug.isLogEnabled()) { Debug.log("insert move from value %s to %s at %d", fromOpr, toInterval, insertIdx); } } @SuppressWarnings("try") private void resolveMappings() { try (Indent indent = Debug.logAndIndent("resolveMapping")) { assert verifyBeforeResolve(); if (Debug.isLogEnabled()) { printMapping(); } // Block all registers that are used as input operands of a move. // When a register is blocked, no move to this register is emitted. // This is necessary for detecting cycles in moves. int i; for (i = mappingFrom.size() - 1; i >= 0; i--) { Interval fromInterval = mappingFrom.get(i); if (fromInterval != null) { blockRegisters(fromInterval); } } int spillCandidate = -1; while (mappingFrom.size() > 0) { boolean processedInterval = false; for (i = mappingFrom.size() - 1; i >= 0; i--) { Interval fromInterval = mappingFrom.get(i); Interval toInterval = mappingTo.get(i); if (safeToProcessMove(fromInterval, toInterval)) { // this interval can be processed because target is free if (fromInterval != null) { insertMove(fromInterval, toInterval); unblockRegisters(fromInterval); } else { insertMove(mappingFromOpr.get(i), toInterval); } mappingFrom.remove(i); mappingFromOpr.remove(i); mappingTo.remove(i); processedInterval = true; } else if (fromInterval != null && isRegister(fromInterval.location())) { // this interval cannot be processed now because target is not free // it starts in a register, so it is a possible candidate for spilling spillCandidate = i; } } if (!processedInterval) { breakCycle(spillCandidate); } } } // reset to default value multipleReadsAllowed = false; // check that all intervals have been processed assert checkEmpty(); } protected void breakCycle(int spillCandidate) { // no move could be processed because there is a cycle in the move list // (e.g. r1 . r2, r2 . r1), so one interval must be spilled to memory assert spillCandidate != -1 : "no interval in register for spilling found"; // create a new spill interval and assign a stack slot to it Interval fromInterval = mappingFrom.get(spillCandidate); // do not allocate a new spill slot for temporary interval, but // use spill slot assigned to fromInterval. Otherwise moves from // one stack slot to another can happen (not allowed by LIRAssembler AllocatableValue spillSlot = fromInterval.spillSlot(); if (spillSlot == null) { spillSlot = getAllocator().getFrameMapBuilder().allocateSpillSlot(fromInterval.kind()); fromInterval.setSpillSlot(spillSlot); cycleBreakingSlotsAllocated.increment(); } spillInterval(spillCandidate, fromInterval, spillSlot); } protected void spillInterval(int spillCandidate, Interval fromInterval, AllocatableValue spillSlot) { assert mappingFrom.get(spillCandidate).equals(fromInterval); Interval spillInterval = getAllocator().createDerivedInterval(fromInterval); spillInterval.setKind(fromInterval.kind()); // add a dummy range because real position is difficult to calculate // Note: this range is a special case when the integrity of the allocation is // checked spillInterval.addRange(1, 2); spillInterval.assignLocation(spillSlot); if (Debug.isLogEnabled()) { Debug.log("created new Interval for spilling: %s", spillInterval); } blockRegisters(spillInterval); // insert a move from register to stack and update the mapping insertMove(fromInterval, spillInterval); mappingFrom.set(spillCandidate, spillInterval); unblockRegisters(fromInterval); } @SuppressWarnings("try") private void printMapping() { try (Indent indent = Debug.logAndIndent("Mapping")) { for (int i = mappingFrom.size() - 1; i >= 0; i--) { Interval fromInterval = mappingFrom.get(i); Interval toInterval = mappingTo.get(i); String from; Value to = toInterval.location(); if (fromInterval == null) { from = mappingFromOpr.get(i).toString(); } else { from = fromInterval.location().toString(); } Debug.log("move %s <- %s", from, to); } } } void setInsertPosition(List<LIRInstruction> insertList, int insertIdx) { assert this.insertIdx == -1 : "use moveInsertPosition instead of setInsertPosition when data already set"; createInsertionBuffer(insertList); this.insertIdx = insertIdx; } void moveInsertPosition(List<LIRInstruction> newInsertList, int newInsertIdx) { if (insertionBuffer.lirList() != null && (insertionBuffer.lirList() != newInsertList || this.insertIdx != newInsertIdx)) { // insert position changed . resolve current mappings resolveMappings(); } if (insertionBuffer.lirList() != newInsertList) { // block changed . append insertionBuffer because it is // bound to a specific block and create a new insertionBuffer appendInsertionBuffer(); createInsertionBuffer(newInsertList); } this.insertIdx = newInsertIdx; } public void addMapping(Interval fromInterval, Interval toInterval) { if (isIllegal(toInterval.location()) && toInterval.canMaterialize()) { if (Debug.isLogEnabled()) { Debug.log("no store to rematerializable interval %s needed", toInterval); } return; } if (isIllegal(fromInterval.location()) && fromInterval.canMaterialize()) { // Instead of a reload, re-materialize the value Constant rematValue = fromInterval.getMaterializedValue(); addMapping(rematValue, toInterval); return; } if (Debug.isLogEnabled()) { Debug.log("add move mapping from %s to %s", fromInterval, toInterval); } assert !fromInterval.operand.equals(toInterval.operand) : "from and to interval equal: " + fromInterval; assert LIRKind.verifyMoveKinds(toInterval.kind(), fromInterval.kind()) : String.format("Kind mismatch: %s vs. %s, from=%s, to=%s", fromInterval.kind(), toInterval.kind(), fromInterval, toInterval); mappingFrom.add(fromInterval); mappingFromOpr.add(null); mappingTo.add(toInterval); } public void addMapping(Constant fromOpr, Interval toInterval) { if (Debug.isLogEnabled()) { Debug.log("add move mapping from %s to %s", fromOpr, toInterval); } mappingFrom.add(null); mappingFromOpr.add(fromOpr); mappingTo.add(toInterval); } void resolveAndAppendMoves() { if (hasMappings()) { resolveMappings(); } appendInsertionBuffer(); } }