soot.jimple.toolkits.scalar.pre.LazyCodeMotion Maven / Gradle / Ivy
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/* Soot - a J*va Optimization Framework
* Copyright (C) 2002 Florian Loitsch
*
* This library is free software; you can redistribute it and/or
* modify it under the terms of the GNU Lesser General Public
* License as published by the Free Software Foundation; either
* version 2.1 of the License, or (at your option) any later version.
*
* This library 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
* Lesser General Public License for more details.
*
* You should have received a copy of the GNU Lesser General Public
* License along with this library; if not, write to the
* Free Software Foundation, Inc., 59 Temple Place - Suite 330,
* Boston, MA 02111-1307, USA.
*/
/*
* Modified by the Sable Research Group and others 1997-1999.
* See the 'credits' file distributed with Soot for the complete list of
* contributors. (Soot is distributed at http://www.sable.mcgill.ca/soot)
*/
package soot.jimple.toolkits.scalar.pre;
import soot.options.*;
import soot.jimple.toolkits.graph.*;
import soot.jimple.toolkits.scalar.*;
import soot.*;
import soot.toolkits.scalar.*;
import soot.toolkits.graph.*;
import soot.jimple.*;
import java.util.*;
import soot.util.*;
import soot.jimple.toolkits.pointer.PASideEffectTester;
import soot.options.LCMOptions;
/**
* Performs a partial redundancy elimination (= code motion). This is done, by
* introducing helper-vars, that store an already computed value, or if a
* compuation only arrives partially (not from all predecessors) inserts a new
* computation on these paths afterwards).
*
* In order to catch every redundant expression, this transformation must be
* done on a graph without critical edges. Therefore the first thing we do, is
* removing them. A subsequent pass can then easily remove the synthetic nodes
* we have introduced.
*
* The term "lazy" refers to the fact, that we move computations only if
* necessary.
*
* @see soot.jimple.toolkits.graph.CriticalEdgeRemover
*/
public class LazyCodeMotion extends BodyTransformer {
public LazyCodeMotion( Singletons.Global g ) {}
public static LazyCodeMotion v() { return G.v().soot_jimple_toolkits_scalar_pre_LazyCodeMotion(); }
private static final String PREFIX = "$lcm";
/**
* performs the lazy code motion.
*/
protected void internalTransform(Body b, String phaseName, Map opts) {
LCMOptions options = new LCMOptions( opts );
HashMap expToHelper = new HashMap();
Chain unitChain = b.getUnits();
if(Options.v().verbose()) G.v().out.println("[" + b.getMethod().getName() +
"] Performing Lazy Code Motion...");
if (options.unroll()) new LoopConditionUnroller().transform(b, phaseName + ".lcu");
CriticalEdgeRemover.v().transform(b, phaseName + ".cer");
UnitGraph graph = new BriefUnitGraph(b);
/* map each unit to its RHS. only take binary expressions */
Map unitToEquivRhs = new UnitMap(b, graph.size() + 1, 0.7f) {
protected Object mapTo(Unit unit) {
Value tmp = SootFilter.noInvokeRhs(unit);
Value tmp2 = SootFilter.binop(tmp);
if (tmp2 == null) tmp2 = SootFilter.concreteRef(tmp);
return SootFilter.equiVal(tmp2);
}
};
/* same as before, but without exception-throwing expressions */
Map unitToNoExceptionEquivRhs = new UnitMap(b, graph.size() + 1, 0.7f) {
protected Object mapTo(Unit unit) {
Value tmp = SootFilter.binopRhs(unit);
tmp = SootFilter.noExceptionThrowing(tmp);
return SootFilter.equiVal(tmp);
}
};
FlowUniverse universe = new CollectionFlowUniverse(unitToEquivRhs.values());
BoundedFlowSet set = new ArrayPackedSet(universe);
/* if a more precise sideeffect-tester comes out, please change it here! */
SideEffectTester sideEffect;
if( Scene.v().hasCallGraph() && !options.naive_side_effect() ) {
sideEffect = new PASideEffectTester();
} else {
sideEffect = new NaiveSideEffectTester();
}
sideEffect.newMethod( b.getMethod() );
UpSafetyAnalysis upSafe;
DownSafetyAnalysis downSafe;
EarliestnessComputation earliest;
DelayabilityAnalysis delay;
NotIsolatedAnalysis notIsolated;
LatestComputation latest;
if (options.safety() == LCMOptions.safety_safe)
upSafe = new UpSafetyAnalysis(graph, unitToNoExceptionEquivRhs,
sideEffect, set);
else
upSafe = new UpSafetyAnalysis(graph, unitToEquivRhs, sideEffect, set);
if (options.safety() == LCMOptions.safety_unsafe)
downSafe = new DownSafetyAnalysis(graph, unitToEquivRhs, sideEffect, set);
else {
downSafe = new DownSafetyAnalysis(graph, unitToNoExceptionEquivRhs,
sideEffect, set);
/* we include the exception-throwing expressions at their uses */
Iterator unitIt = unitChain.iterator();
while (unitIt.hasNext()) {
Unit currentUnit = (Unit)unitIt.next();
Object rhs = unitToEquivRhs.get(currentUnit);
if (rhs != null)
((FlowSet)downSafe.getFlowBefore(currentUnit)).add(rhs);
}
}
earliest = new EarliestnessComputation(graph, upSafe, downSafe, sideEffect,
set);
delay = new DelayabilityAnalysis(graph, earliest, unitToEquivRhs, set);
latest = new LatestComputation(graph, delay, unitToEquivRhs, set);
notIsolated = new NotIsolatedAnalysis(graph, latest, unitToEquivRhs, set);
LocalCreation localCreation = new LocalCreation(b.getLocals(), PREFIX);
/* debug */
/*
{
G.v().out.println("========" + b.getMethod().getName());
Iterator unitIt = unitChain.iterator();
while (unitIt.hasNext()) {
Unit currentUnit = (Unit) unitIt.next();
Value equiVal = (Value)unitToEquivRhs.get(currentUnit);
FlowSet latestSet = (FlowSet)latest.getFlowBefore(currentUnit);
FlowSet notIsolatedSet =
(FlowSet)notIsolated.getFlowAfter(currentUnit);
FlowSet delaySet = (FlowSet)delay.getFlowBefore(currentUnit);
FlowSet earlySet = ((FlowSet)earliest.getFlowBefore(currentUnit));
FlowSet upSet = (FlowSet)upSafe.getFlowBefore(currentUnit);
FlowSet downSet = (FlowSet)downSafe.getFlowBefore(currentUnit);
G.v().out.println(currentUnit);
G.v().out.println(" rh: " + equiVal);
G.v().out.println(" up: " + upSet);
G.v().out.println(" do: " + downSet);
G.v().out.println(" is: " + notIsolatedSet);
G.v().out.println(" ea: " + earlySet);
G.v().out.println(" db: " + delaySet);
G.v().out.println(" la: " + latestSet);
}
}
*/
{ /* insert the computations */
Iterator unitIt = unitChain.snapshotIterator();
while (unitIt.hasNext()) {
Unit currentUnit = (Unit)unitIt.next();
FlowSet latestSet = (FlowSet)latest.getFlowBefore(currentUnit);
FlowSet notIsolatedSet =
(FlowSet)notIsolated.getFlowAfter(currentUnit);
FlowSet insertHere = latestSet.clone();
insertHere.intersection(notIsolatedSet, insertHere);
Iterator insertIt = insertHere.iterator();
while (insertIt.hasNext()) {
EquivalentValue equiVal = (EquivalentValue)insertIt.next();
/* get the unic helper-name for this expression */
Local helper = expToHelper.get(equiVal);
if (helper == null) {
helper = localCreation.newLocal(equiVal.getType());
expToHelper.put(equiVal, helper);
}
/* insert a new Assignment-stmt before the currentUnit */
Value insertValue = Jimple.cloneIfNecessary(equiVal.getValue());
Unit firstComp = Jimple.v().newAssignStmt(helper, insertValue);
unitChain.insertBefore(firstComp, currentUnit);
// G.v().out.print("x");
}
}
}
{ /* replace old computations by the helper-vars */
Iterator unitIt = unitChain.iterator();
while (unitIt.hasNext()) {
Unit currentUnit = (Unit)unitIt.next();
EquivalentValue rhs = (EquivalentValue)unitToEquivRhs.get(currentUnit);
if (rhs != null) {
FlowSet latestSet = (FlowSet)latest.getFlowBefore(currentUnit);
FlowSet notIsolatedSet =
(FlowSet)notIsolated.getFlowAfter(currentUnit);
if (!latestSet.contains(rhs) && notIsolatedSet.contains(rhs)) {
Local helper = expToHelper.get(rhs);
try {
((AssignStmt)currentUnit).setRightOp(helper);
} catch (RuntimeException e){
G.v().out.println("Error on "+b.getMethod().getName());
G.v().out.println(currentUnit.toString());
G.v().out.println(latestSet);
G.v().out.println(notIsolatedSet);
throw e;
}
// G.v().out.print(".");
}
}
}
}
if(Options.v().verbose())
G.v().out.println("[" + b.getMethod().getName() +
"] Lazy Code Motion done.");
}
}