com.android.dx.ssa.SCCP Maven / Gradle / Ivy
/*
* Copyright (C) 2007 The Android Open Source Project
*
* Licensed under the Apache License, Version 2.0 (the "License");
* you may not use this file except in compliance with the License.
* You may obtain a copy of the License at
*
* http://www.apache.org/licenses/LICENSE-2.0
*
* Unless required by applicable law or agreed to in writing, software
* distributed under the License is distributed on an "AS IS" BASIS,
* WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
* See the License for the specific language governing permissions and
* limitations under the License.
*/
package com.android.dx.ssa;
import com.android.dx.rop.code.CstInsn;
import com.android.dx.rop.code.Insn;
import com.android.dx.rop.code.PlainInsn;
import com.android.dx.rop.code.RegOps;
import com.android.dx.rop.code.RegisterSpec;
import com.android.dx.rop.code.RegisterSpecList;
import com.android.dx.rop.code.Rop;
import com.android.dx.rop.code.Rops;
import com.android.dx.rop.cst.Constant;
import com.android.dx.rop.cst.CstInteger;
import com.android.dx.rop.cst.TypedConstant;
import com.android.dx.rop.type.Type;
import com.android.dx.rop.type.TypeBearer;
import java.util.ArrayList;
import java.util.BitSet;
/**
* A small variant of Wegman and Zadeck's Sparse Conditional Constant
* Propagation algorithm.
*/
public class SCCP {
/** Lattice values */
private static final int TOP = 0;
private static final int CONSTANT = 1;
private static final int VARYING = 2;
/** method we're processing */
private final SsaMethod ssaMeth;
/** ssaMeth.getRegCount() */
private final int regCount;
/** Lattice values for each SSA register */
private final int[] latticeValues;
/** For those registers that are constant, this is the constant value */
private final Constant[] latticeConstants;
/** Worklist of basic blocks to be processed */
private final ArrayList cfgWorklist;
/** Worklist of executed basic blocks with phis to be processed */
private final ArrayList cfgPhiWorklist;
/** Bitset containing bits for each block that has been found executable */
private final BitSet executableBlocks;
/** Worklist for SSA edges. This is a list of registers to process */
private final ArrayList ssaWorklist;
/**
* Worklist for SSA edges that represent varying values. It makes the
* algorithm much faster if you move all values to VARYING as fast as
* possible.
*/
private final ArrayList varyingWorklist;
/** Worklist of potential branches to convert to gotos */
private final ArrayList branchWorklist;
private SCCP(SsaMethod ssaMeth) {
this.ssaMeth = ssaMeth;
this.regCount = ssaMeth.getRegCount();
this.latticeValues = new int[this.regCount];
this.latticeConstants = new Constant[this.regCount];
this.cfgWorklist = new ArrayList();
this.cfgPhiWorklist = new ArrayList();
this.executableBlocks = new BitSet(ssaMeth.getBlocks().size());
this.ssaWorklist = new ArrayList();
this.varyingWorklist = new ArrayList();
this.branchWorklist = new ArrayList();
for (int i = 0; i < this.regCount; i++) {
latticeValues[i] = TOP;
latticeConstants[i] = null;
}
}
/**
* Performs sparse conditional constant propagation on a method.
* @param ssaMethod Method to process
*/
public static void process (SsaMethod ssaMethod) {
new SCCP(ssaMethod).run();
}
/**
* Adds a SSA basic block to the CFG worklist if it's unexecuted, or
* to the CFG phi worklist if it's already executed.
* @param ssaBlock Block to add
*/
private void addBlockToWorklist(SsaBasicBlock ssaBlock) {
if (!executableBlocks.get(ssaBlock.getIndex())) {
cfgWorklist.add(ssaBlock);
executableBlocks.set(ssaBlock.getIndex());
} else {
cfgPhiWorklist.add(ssaBlock);
}
}
/**
* Adds an SSA register's uses to the SSA worklist.
* @param reg SSA register
* @param latticeValue new lattice value for @param reg.
*/
private void addUsersToWorklist(int reg, int latticeValue) {
if (latticeValue == VARYING) {
for (SsaInsn insn : ssaMeth.getUseListForRegister(reg)) {
varyingWorklist.add(insn);
}
} else {
for (SsaInsn insn : ssaMeth.getUseListForRegister(reg)) {
ssaWorklist.add(insn);
}
}
}
/**
* Sets a lattice value for a register to value.
* @param reg SSA register
* @param value Lattice value
* @param cst Constant value (may be null)
* @return true if the lattice value changed.
*/
private boolean setLatticeValueTo(int reg, int value, Constant cst) {
if (value != CONSTANT) {
if (latticeValues[reg] != value) {
latticeValues[reg] = value;
return true;
}
return false;
} else {
if (latticeValues[reg] != value
|| !latticeConstants[reg].equals(cst)) {
latticeValues[reg] = value;
latticeConstants[reg] = cst;
return true;
}
return false;
}
}
/**
* Simulates a PHI node and set the lattice for the result
* to the appropriate value.
* Meet values:
* TOP x anything = TOP
* VARYING x anything = VARYING
* CONSTANT x CONSTANT = CONSTANT if equal constants, VARYING otherwise
* @param insn PHI to simulate.
*/
private void simulatePhi(PhiInsn insn) {
int phiResultReg = insn.getResult().getReg();
if (latticeValues[phiResultReg] == VARYING) {
return;
}
RegisterSpecList sources = insn.getSources();
int phiResultValue = TOP;
Constant phiConstant = null;
int sourceSize = sources.size();
for (int i = 0; i < sourceSize; i++) {
int predBlockIndex = insn.predBlockIndexForSourcesIndex(i);
int sourceReg = sources.get(i).getReg();
int sourceRegValue = latticeValues[sourceReg];
if (!executableBlocks.get(predBlockIndex)) {
continue;
}
if (sourceRegValue == CONSTANT) {
if (phiConstant == null) {
phiConstant = latticeConstants[sourceReg];
phiResultValue = CONSTANT;
} else if (!latticeConstants[sourceReg].equals(phiConstant)){
phiResultValue = VARYING;
break;
}
} else {
phiResultValue = sourceRegValue;
break;
}
}
if (setLatticeValueTo(phiResultReg, phiResultValue, phiConstant)) {
addUsersToWorklist(phiResultReg, phiResultValue);
}
}
/**
* Simulate a block and note the results in the lattice.
* @param block Block to visit
*/
private void simulateBlock(SsaBasicBlock block) {
for (SsaInsn insn : block.getInsns()) {
if (insn instanceof PhiInsn) {
simulatePhi((PhiInsn) insn);
} else {
simulateStmt(insn);
}
}
}
/**
* Simulate the phis in a block and note the results in the lattice.
* @param block Block to visit
*/
private void simulatePhiBlock(SsaBasicBlock block) {
for (SsaInsn insn : block.getInsns()) {
if (insn instanceof PhiInsn) {
simulatePhi((PhiInsn) insn);
} else {
return;
}
}
}
private static String latticeValName(int latticeVal) {
switch (latticeVal) {
case TOP: return "TOP";
case CONSTANT: return "CONSTANT";
case VARYING: return "VARYING";
default: return "UNKNOWN";
}
}
/**
* Simulates branch insns, if possible. Adds reachable successor blocks
* to the CFG worklists.
* @param insn branch to simulate
*/
private void simulateBranch(SsaInsn insn) {
Rop opcode = insn.getOpcode();
RegisterSpecList sources = insn.getSources();
boolean constantBranch = false;
boolean constantSuccessor = false;
// Check if the insn is a branch with a constant condition
if (opcode.getBranchingness() == Rop.BRANCH_IF) {
Constant cA = null;
Constant cB = null;
RegisterSpec specA = sources.get(0);
int regA = specA.getReg();
if (!ssaMeth.isRegALocal(specA) &&
latticeValues[regA] == CONSTANT) {
cA = latticeConstants[regA];
}
if (sources.size() == 2) {
RegisterSpec specB = sources.get(1);
int regB = specB.getReg();
if (!ssaMeth.isRegALocal(specB) &&
latticeValues[regB] == CONSTANT) {
cB = latticeConstants[regB];
}
}
// Calculate the result of the condition
if (cA != null && sources.size() == 1) {
switch (((TypedConstant) cA).getBasicType()) {
case Type.BT_INT:
constantBranch = true;
int vA = ((CstInteger) cA).getValue();
switch (opcode.getOpcode()) {
case RegOps.IF_EQ:
constantSuccessor = (vA == 0);
break;
case RegOps.IF_NE:
constantSuccessor = (vA != 0);
break;
case RegOps.IF_LT:
constantSuccessor = (vA < 0);
break;
case RegOps.IF_GE:
constantSuccessor = (vA >= 0);
break;
case RegOps.IF_LE:
constantSuccessor = (vA <= 0);
break;
case RegOps.IF_GT:
constantSuccessor = (vA > 0);
break;
default:
throw new RuntimeException("Unexpected op");
}
break;
default:
// not yet supported
}
} else if (cA != null && cB != null) {
switch (((TypedConstant) cA).getBasicType()) {
case Type.BT_INT:
constantBranch = true;
int vA = ((CstInteger) cA).getValue();
int vB = ((CstInteger) cB).getValue();
switch (opcode.getOpcode()) {
case RegOps.IF_EQ:
constantSuccessor = (vA == vB);
break;
case RegOps.IF_NE:
constantSuccessor = (vA != vB);
break;
case RegOps.IF_LT:
constantSuccessor = (vA < vB);
break;
case RegOps.IF_GE:
constantSuccessor = (vA >= vB);
break;
case RegOps.IF_LE:
constantSuccessor = (vA <= vB);
break;
case RegOps.IF_GT:
constantSuccessor = (vA > vB);
break;
default:
throw new RuntimeException("Unexpected op");
}
break;
default:
// not yet supported
}
}
}
/*
* If condition is constant, add only the target block to the
* worklist. Otherwise, add all successors to the worklist.
*/
SsaBasicBlock block = insn.getBlock();
if (constantBranch) {
int successorBlock;
if (constantSuccessor) {
successorBlock = block.getSuccessorList().get(1);
} else {
successorBlock = block.getSuccessorList().get(0);
}
addBlockToWorklist(ssaMeth.getBlocks().get(successorBlock));
branchWorklist.add(insn);
} else {
for (int i = 0; i < block.getSuccessorList().size(); i++) {
int successorBlock = block.getSuccessorList().get(i);
addBlockToWorklist(ssaMeth.getBlocks().get(successorBlock));
}
}
}
/**
* Simulates math insns, if possible.
*
* @param insn non-null insn to simulate
* @param resultType basic type of the result
* @return constant result or null if not simulatable.
*/
private Constant simulateMath(SsaInsn insn, int resultType) {
Insn ropInsn = insn.getOriginalRopInsn();
int opcode = insn.getOpcode().getOpcode();
RegisterSpecList sources = insn.getSources();
int regA = sources.get(0).getReg();
Constant cA;
Constant cB;
if (latticeValues[regA] != CONSTANT) {
cA = null;
} else {
cA = latticeConstants[regA];
}
if (sources.size() == 1) {
CstInsn cstInsn = (CstInsn) ropInsn;
cB = cstInsn.getConstant();
} else { /* sources.size() == 2 */
int regB = sources.get(1).getReg();
if (latticeValues[regB] != CONSTANT) {
cB = null;
} else {
cB = latticeConstants[regB];
}
}
if (cA == null || cB == null) {
//TODO handle a constant of 0 with MUL or AND
return null;
}
switch (resultType) {
case Type.BT_INT:
int vR;
boolean skip=false;
int vA = ((CstInteger) cA).getValue();
int vB = ((CstInteger) cB).getValue();
switch (opcode) {
case RegOps.ADD:
vR = vA + vB;
break;
case RegOps.SUB:
// 1 source for reverse sub, 2 sources for regular sub
if (sources.size() == 1) {
vR = vB - vA;
} else {
vR = vA - vB;
}
break;
case RegOps.MUL:
vR = vA * vB;
break;
case RegOps.DIV:
if (vB == 0) {
skip = true;
vR = 0; // just to hide a warning
} else {
vR = vA / vB;
}
break;
case RegOps.AND:
vR = vA & vB;
break;
case RegOps.OR:
vR = vA | vB;
break;
case RegOps.XOR:
vR = vA ^ vB;
break;
case RegOps.SHL:
vR = vA << vB;
break;
case RegOps.SHR:
vR = vA >> vB;
break;
case RegOps.USHR:
vR = vA >>> vB;
break;
case RegOps.REM:
if (vB == 0) {
skip = true;
vR = 0; // just to hide a warning
} else {
vR = vA % vB;
}
break;
default:
throw new RuntimeException("Unexpected op");
}
return skip ? null : CstInteger.make(vR);
default:
// not yet supported
return null;
}
}
/**
* Simulates a statement and set the result lattice value.
* @param insn instruction to simulate
*/
private void simulateStmt(SsaInsn insn) {
Insn ropInsn = insn.getOriginalRopInsn();
if (ropInsn.getOpcode().getBranchingness() != Rop.BRANCH_NONE
|| ropInsn.getOpcode().isCallLike()) {
simulateBranch(insn);
}
int opcode = insn.getOpcode().getOpcode();
RegisterSpec result = insn.getResult();
if (result == null) {
// Find move-result-pseudo result for int div and int rem
if (opcode == RegOps.DIV || opcode == RegOps.REM) {
SsaBasicBlock succ = insn.getBlock().getPrimarySuccessor();
result = succ.getInsns().get(0).getResult();
} else {
return;
}
}
int resultReg = result.getReg();
int resultValue = VARYING;
Constant resultConstant = null;
switch (opcode) {
case RegOps.CONST: {
CstInsn cstInsn = (CstInsn)ropInsn;
resultValue = CONSTANT;
resultConstant = cstInsn.getConstant();
break;
}
case RegOps.MOVE: {
if (insn.getSources().size() == 1) {
int sourceReg = insn.getSources().get(0).getReg();
resultValue = latticeValues[sourceReg];
resultConstant = latticeConstants[sourceReg];
}
break;
}
case RegOps.ADD:
case RegOps.SUB:
case RegOps.MUL:
case RegOps.DIV:
case RegOps.AND:
case RegOps.OR:
case RegOps.XOR:
case RegOps.SHL:
case RegOps.SHR:
case RegOps.USHR:
case RegOps.REM: {
resultConstant = simulateMath(insn, result.getBasicType());
if (resultConstant != null) {
resultValue = CONSTANT;
}
break;
}
case RegOps.MOVE_RESULT_PSEUDO: {
if (latticeValues[resultReg] == CONSTANT) {
resultValue = latticeValues[resultReg];
resultConstant = latticeConstants[resultReg];
}
break;
}
// TODO: Handle non-int arithmetic.
// TODO: Eliminate check casts that we can prove the type of.
default: {}
}
if (setLatticeValueTo(resultReg, resultValue, resultConstant)) {
addUsersToWorklist(resultReg, resultValue);
}
}
private void run() {
SsaBasicBlock firstBlock = ssaMeth.getEntryBlock();
addBlockToWorklist(firstBlock);
/* Empty all the worklists by propagating our values */
while (!cfgWorklist.isEmpty()
|| !cfgPhiWorklist.isEmpty()
|| !ssaWorklist.isEmpty()
|| !varyingWorklist.isEmpty()) {
while (!cfgWorklist.isEmpty()) {
int listSize = cfgWorklist.size() - 1;
SsaBasicBlock block = cfgWorklist.remove(listSize);
simulateBlock(block);
}
while (!cfgPhiWorklist.isEmpty()) {
int listSize = cfgPhiWorklist.size() - 1;
SsaBasicBlock block = cfgPhiWorklist.remove(listSize);
simulatePhiBlock(block);
}
while (!varyingWorklist.isEmpty()) {
int listSize = varyingWorklist.size() - 1;
SsaInsn insn = varyingWorklist.remove(listSize);
if (!executableBlocks.get(insn.getBlock().getIndex())) {
continue;
}
if (insn instanceof PhiInsn) {
simulatePhi((PhiInsn)insn);
} else {
simulateStmt(insn);
}
}
while (!ssaWorklist.isEmpty()) {
int listSize = ssaWorklist.size() - 1;
SsaInsn insn = ssaWorklist.remove(listSize);
if (!executableBlocks.get(insn.getBlock().getIndex())) {
continue;
}
if (insn instanceof PhiInsn) {
simulatePhi((PhiInsn)insn);
} else {
simulateStmt(insn);
}
}
}
replaceConstants();
replaceBranches();
}
/**
* Replaces TypeBearers in source register specs with constant type
* bearers if possible. These are then referenced in later optimization
* steps.
*/
private void replaceConstants() {
for (int reg = 0; reg < regCount; reg++) {
if (latticeValues[reg] != CONSTANT) {
continue;
}
if (!(latticeConstants[reg] instanceof TypedConstant)) {
// We can't do much with these
continue;
}
SsaInsn defn = ssaMeth.getDefinitionForRegister(reg);
TypeBearer typeBearer = defn.getResult().getTypeBearer();
if (typeBearer.isConstant()) {
/*
* The definition was a constant already.
* The uses should be as well.
*/
continue;
}
// Update the destination RegisterSpec with the constant value
RegisterSpec dest = defn.getResult();
RegisterSpec newDest
= dest.withType((TypedConstant)latticeConstants[reg]);
defn.setResult(newDest);
/*
* Update the sources RegisterSpec's of all non-move uses.
* These will be used in later steps.
*/
for (SsaInsn insn : ssaMeth.getUseListForRegister(reg)) {
if (insn.isPhiOrMove()) {
continue;
}
NormalSsaInsn nInsn = (NormalSsaInsn) insn;
RegisterSpecList sources = insn.getSources();
int index = sources.indexOfRegister(reg);
RegisterSpec spec = sources.get(index);
RegisterSpec newSpec
= spec.withType((TypedConstant)latticeConstants[reg]);
nInsn.changeOneSource(index, newSpec);
}
}
}
/**
* Replaces branches that have constant conditions with gotos
*/
private void replaceBranches() {
for (SsaInsn insn : branchWorklist) {
// Find if a successor block is never executed
int oldSuccessor = -1;
SsaBasicBlock block = insn.getBlock();
int successorSize = block.getSuccessorList().size();
for (int i = 0; i < successorSize; i++) {
int successorBlock = block.getSuccessorList().get(i);
if (!executableBlocks.get(successorBlock)) {
oldSuccessor = successorBlock;
}
}
/*
* Prune branches that have already been handled and ones that no
* longer have constant conditions (no nonexecutable successors)
*/
if (successorSize != 2 || oldSuccessor == -1) continue;
// Replace branch with goto
Insn originalRopInsn = insn.getOriginalRopInsn();
block.replaceLastInsn(new PlainInsn(Rops.GOTO,
originalRopInsn.getPosition(), null, RegisterSpecList.EMPTY));
block.removeSuccessor(oldSuccessor);
}
}
}