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/*
* 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.back;
import com.android.dx.dex.DexOptions;
import com.android.dx.rop.code.CstInsn;
import com.android.dx.rop.code.LocalItem;
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.cst.CstInteger;
import com.android.dx.ssa.InterferenceRegisterMapper;
import com.android.dx.ssa.NormalSsaInsn;
import com.android.dx.ssa.Optimizer;
import com.android.dx.ssa.PhiInsn;
import com.android.dx.ssa.RegisterMapper;
import com.android.dx.ssa.SsaBasicBlock;
import com.android.dx.ssa.SsaInsn;
import com.android.dx.ssa.SsaMethod;
import com.android.dx.util.IntIterator;
import com.android.dx.util.IntSet;
import java.util.ArrayList;
import java.util.BitSet;
import java.util.Map;
import java.util.TreeMap;
/**
* Allocates registers in a first-fit fashion, with the bottom reserved for
* method parameters and all SSAregisters representing the same local variable
* kept together if possible.
*/
public class FirstFitLocalCombiningAllocator extends RegisterAllocator {
/**
* Alignment constraint that can be used during search of free registers.
*/
private enum Alignment {
EVEN {
@Override
int nextClearBit(BitSet bitSet, int startIdx) {
int bitNumber = bitSet.nextClearBit(startIdx);
while (!isEven(bitNumber)) {
bitNumber = bitSet.nextClearBit(bitNumber + 1);
}
return bitNumber;
}
},
ODD {
@Override
int nextClearBit(BitSet bitSet, int startIdx) {
int bitNumber = bitSet.nextClearBit(startIdx);
while (isEven(bitNumber)) {
bitNumber = bitSet.nextClearBit(bitNumber + 1);
}
return bitNumber;
}
},
UNSPECIFIED {
@Override
int nextClearBit(BitSet bitSet, int startIdx) {
return bitSet.nextClearBit(startIdx);
}
};
/**
* Returns the index of the first bit that is set to {@code false} that occurs on or after the
* specified starting index and that respect {@link Alignment}.
*
* @param bitSet bitSet working on.
* @param startIdx {@code >= 0;} the index to start checking from (inclusive).
* @return the index of the next clear bit respecting alignment.
*/
abstract int nextClearBit(BitSet bitSet, int startIdx);
}
/** local debug flag */
private static final boolean DEBUG = false;
/** maps local variable to a list of associated SSA registers */
private final Map> localVariables;
/** list of move-result-pesudo instructions seen in this method */
private final ArrayList moveResultPseudoInsns;
/** list of invoke-range instructions seen in this method */
private final ArrayList invokeRangeInsns;
/** list of phi instructions seen in this method */
private final ArrayList phiInsns;
/** indexed by SSA reg; the set of SSA regs we've mapped */
private final BitSet ssaRegsMapped;
/** Register mapper which will be our result */
private final InterferenceRegisterMapper mapper;
/** end of rop registers range (starting at 0) reserved for parameters */
private final int paramRangeEnd;
/** set of rop registers reserved for parameters or local variables */
private final BitSet reservedRopRegs;
/** set of rop registers that have been used by anything */
private final BitSet usedRopRegs;
/** true if converter should take steps to minimize rop-form registers */
private final boolean minimizeRegisters;
/**
* Constructs instance.
*
* @param ssaMeth {@code non-null;} method to process
* @param interference non-null interference graph for SSA registers
* @param minimizeRegisters true if converter should take steps to
* minimize rop-form registers
*/
public FirstFitLocalCombiningAllocator(
SsaMethod ssaMeth, InterferenceGraph interference,
boolean minimizeRegisters) {
super(ssaMeth, interference);
ssaRegsMapped = new BitSet(ssaMeth.getRegCount());
mapper = new InterferenceRegisterMapper(
interference, ssaMeth.getRegCount());
this.minimizeRegisters = minimizeRegisters;
/*
* Reserve space for the params at the bottom of the register
* space. Later, we'll flip the params to the end of the register
* space.
*/
paramRangeEnd = ssaMeth.getParamWidth();
reservedRopRegs = new BitSet(paramRangeEnd * 2);
reservedRopRegs.set(0, paramRangeEnd);
usedRopRegs = new BitSet(paramRangeEnd * 2);
localVariables = new TreeMap>();
moveResultPseudoInsns = new ArrayList();
invokeRangeInsns = new ArrayList();
phiInsns = new ArrayList();
}
/** {@inheritDoc} */
@Override
public boolean wantsParamsMovedHigh() {
return true;
}
/** {@inheritDoc} */
@Override
public RegisterMapper allocateRegisters() {
analyzeInstructions();
if (DEBUG) {
printLocalVars();
}
if (DEBUG) System.out.println("--->Mapping local-associated params");
handleLocalAssociatedParams();
if (DEBUG) System.out.println("--->Mapping other params");
handleUnassociatedParameters();
if (DEBUG) System.out.println("--->Mapping invoke-range");
handleInvokeRangeInsns();
if (DEBUG) {
System.out.println("--->Mapping local-associated non-params");
}
handleLocalAssociatedOther();
if (DEBUG) System.out.println("--->Mapping check-cast results");
handleCheckCastResults();
if (DEBUG) System.out.println("--->Mapping phis");
handlePhiInsns();
if (DEBUG) System.out.println("--->Mapping others");
handleNormalUnassociated();
return mapper;
}
/**
* Dumps local variable table to stdout for debugging.
*/
private void printLocalVars() {
System.out.println("Printing local vars");
for (Map.Entry> e :
localVariables.entrySet()) {
StringBuilder regs = new StringBuilder();
regs.append('{');
regs.append(' ');
for (RegisterSpec reg : e.getValue()) {
regs.append('v');
regs.append(reg.getReg());
regs.append(' ');
}
regs.append('}');
System.out.printf("Local: %s Registers: %s\n", e.getKey(), regs);
}
}
/**
* Maps all local-associated parameters to rop registers.
*/
private void handleLocalAssociatedParams() {
for (ArrayList ssaRegs : localVariables.values()) {
int sz = ssaRegs.size();
int paramIndex = -1;
int paramCategory = 0;
// First, find out if this local variable is a parameter.
for (int i = 0; i < sz; i++) {
RegisterSpec ssaSpec = ssaRegs.get(i);
int ssaReg = ssaSpec.getReg();
paramIndex = getParameterIndexForReg(ssaReg);
if (paramIndex >= 0) {
paramCategory = ssaSpec.getCategory();
addMapping(ssaSpec, paramIndex);
break;
}
}
if (paramIndex < 0) {
// This local wasn't a parameter.
continue;
}
// Any remaining local-associated registers will be mapped later.
tryMapRegs(ssaRegs, paramIndex, paramCategory, true);
}
}
/**
* Gets the parameter index for SSA registers that are method parameters.
* {@code -1} is returned for non-parameter registers.
*
* @param ssaReg {@code >=0;} SSA register to look up
* @return parameter index or {@code -1} if not a parameter
*/
private int getParameterIndexForReg(int ssaReg) {
SsaInsn defInsn = ssaMeth.getDefinitionForRegister(ssaReg);
if (defInsn == null) {
return -1;
}
Rop opcode = defInsn.getOpcode();
// opcode == null for phi insns.
if (opcode != null && opcode.getOpcode() == RegOps.MOVE_PARAM) {
CstInsn origInsn = (CstInsn) defInsn.getOriginalRopInsn();
return ((CstInteger) origInsn.getConstant()).getValue();
}
return -1;
}
/**
* Maps all local-associated registers that are not parameters.
* Tries to find an unreserved range that's wide enough for all of
* the SSA registers, and then tries to map them all to that
* range. If not all fit, a new range is tried until all registers
* have been fit.
*/
private void handleLocalAssociatedOther() {
for (ArrayList specs : localVariables.values()) {
int ropReg = paramRangeEnd;
boolean done = false;
do {
int maxCategory = 1;
// Compute max category for remaining unmapped registers.
int sz = specs.size();
for (int i = 0; i < sz; i++) {
RegisterSpec ssaSpec = specs.get(i);
int category = ssaSpec.getCategory();
if (!ssaRegsMapped.get(ssaSpec.getReg())
&& category > maxCategory) {
maxCategory = category;
}
}
ropReg = findRopRegForLocal(ropReg, maxCategory);
if (canMapRegs(specs, ropReg)) {
done = tryMapRegs(specs, ropReg, maxCategory, true);
}
// Increment for next call to findRopRegForLocal.
ropReg++;
} while (!done);
}
}
/**
* Tries to map a list of SSA registers into the a rop reg, marking
* used rop space as reserved. SSA registers that don't fit are left
* unmapped.
*
* @param specs {@code non-null;} SSA registers to attempt to map
* @param ropReg {@code >=0;} rop register to map to
* @param maxAllowedCategory {@code 1..2;} maximum category
* allowed in mapping.
* @param markReserved do so if {@code true}
* @return {@code true} if all registers were mapped, {@code false}
* if some remain unmapped
*/
private boolean tryMapRegs(
ArrayList specs, int ropReg,
int maxAllowedCategory, boolean markReserved) {
boolean remaining = false;
for (RegisterSpec spec : specs) {
if (ssaRegsMapped.get(spec.getReg())) {
continue;
}
boolean succeeded;
succeeded = tryMapReg(spec, ropReg, maxAllowedCategory);
remaining = !succeeded || remaining;
if (succeeded && markReserved) {
// This only needs to be called once really with
// the widest category used, but
markReserved(ropReg, spec.getCategory());
}
}
return !remaining;
}
/**
* Tries to map an SSA register to a rop register.
*
* @param ssaSpec {@code non-null;} SSA register
* @param ropReg {@code >=0;} rop register
* @param maxAllowedCategory {@code 1..2;} the maximum category
* that the SSA register is allowed to be
* @return {@code true} if map succeeded, {@code false} if not
*/
private boolean tryMapReg(RegisterSpec ssaSpec, int ropReg,
int maxAllowedCategory) {
if (ssaSpec.getCategory() <= maxAllowedCategory
&& !ssaRegsMapped.get(ssaSpec.getReg())
&& canMapReg(ssaSpec, ropReg)) {
addMapping(ssaSpec, ropReg);
return true;
}
return false;
}
/**
* Marks a range of rop registers as "reserved for a local variable."
*
* @param ropReg {@code >= 0;} rop register to reserve
* @param category {@code > 0;} width to reserve
*/
private void markReserved(int ropReg, int category) {
reservedRopRegs.set(ropReg, ropReg + category, true);
}
/**
* Checks to see if any rop registers in the specified range are reserved
* for local variables or parameters.
*
* @param ropRangeStart {@code >= 0;} lowest rop register
* @param width {@code > 0;} number of rop registers in range.
* @return {@code true} if any register in range is marked reserved
*/
private boolean rangeContainsReserved(int ropRangeStart, int width) {
for (int i = ropRangeStart; i < (ropRangeStart + width); i++) {
if (reservedRopRegs.get(i)) {
return true;
}
}
return false;
}
/**
* Returns true if given rop register represents the {@code this} pointer
* for a non-static method.
*
* @param startReg rop register
* @return true if the "this" pointer is located here.
*/
private boolean isThisPointerReg(int startReg) {
// "this" is always the first parameter.
return startReg == 0 && !ssaMeth.isStatic();
}
/**
* Return the register alignment constraint to have 64-bits registers that will be align on even
* dalvik registers after that parameter registers are move up to the top of the frame to match
* the calling convention.
*
* @param regCategory category of the register that will be aligned.
* @return the register alignment constraint.
*/
private Alignment getAlignment(int regCategory) {
Alignment alignment = Alignment.UNSPECIFIED;
if (DexOptions.ALIGN_64BIT_REGS_SUPPORT && regCategory == 2) {
if (isEven(paramRangeEnd)) {
alignment = Alignment.EVEN;
} else {
alignment = Alignment.ODD;
}
}
return alignment;
}
/**
* Finds unreserved rop registers with a specific category.
*
* @param startReg {@code >= 0;} a rop register to start the search at
* @param regCategory {@code > 0;} category of the searched registers.
* @return {@code >= 0;} start of available registers.
*/
private int findNextUnreservedRopReg(int startReg, int regCategory) {
return findNextUnreservedRopReg(startReg, regCategory, getAlignment(regCategory));
}
/**
* Finds a range of unreserved rop registers.
*
* @param startReg {@code >= 0;} a rop register to start the search at
* @param width {@code > 0;} the width, in registers, required.
* @param alignment the alignment constraint.
* @return {@code >= 0;} start of available register range.
*/
private int findNextUnreservedRopReg(int startReg, int width, Alignment alignment) {
int reg = alignment.nextClearBit(reservedRopRegs, startReg);
while (true) {
int i = 1;
while (i < width && !reservedRopRegs.get(reg + i)) {
i++;
}
if (i == width) {
return reg;
}
reg = alignment.nextClearBit(reservedRopRegs, reg + i);
}
}
/**
* Finds rop registers that can be used for local variables.
* If {@code MIX_LOCALS_AND_OTHER} is {@code false}, this means any
* rop register that has not yet been used.
*
* @param startReg {@code >= 0;} a rop register to start the search at
* @param category {@code > 0;} the register category required.
* @return {@code >= 0;} start of available registers.
*/
private int findRopRegForLocal(int startReg, int category) {
Alignment alignment = getAlignment(category);
int reg = alignment.nextClearBit(usedRopRegs, startReg);
while (true) {
int i = 1;
while (i < category && !usedRopRegs.get(reg + i)) {
i++;
}
if (i == category) {
return reg;
}
reg = alignment.nextClearBit(usedRopRegs, reg + i);
}
}
/**
* Maps any parameter that isn't local-associated, which can happen
* in the case where there is no java debug info.
*/
private void handleUnassociatedParameters() {
int szSsaRegs = ssaMeth.getRegCount();
for (int ssaReg = 0; ssaReg < szSsaRegs; ssaReg++) {
if (ssaRegsMapped.get(ssaReg)) {
// We already did this one above
continue;
}
int paramIndex = getParameterIndexForReg(ssaReg);
RegisterSpec ssaSpec = getDefinitionSpecForSsaReg(ssaReg);
if (paramIndex >= 0) {
addMapping(ssaSpec, paramIndex);
}
}
}
/**
* Handles all insns that want a register range for their sources.
*/
private void handleInvokeRangeInsns() {
for (NormalSsaInsn insn : invokeRangeInsns) {
adjustAndMapSourceRangeRange(insn);
}
}
/**
* Handles check cast results to reuse the same source register.
* Inserts a move if it can't map the same register to both and the
* check cast is not caught.
*/
private void handleCheckCastResults() {
for (NormalSsaInsn insn : moveResultPseudoInsns) {
RegisterSpec moveRegSpec = insn.getResult();
int moveReg = moveRegSpec.getReg();
BitSet predBlocks = insn.getBlock().getPredecessors();
// Expect one predecessor block only
if (predBlocks.cardinality() != 1) {
continue;
}
SsaBasicBlock predBlock =
ssaMeth.getBlocks().get(predBlocks.nextSetBit(0));
ArrayList insnList = predBlock.getInsns();
/**
* If the predecessor block has a check-cast, it will be the last
* instruction
*/
SsaInsn checkCastInsn = insnList.get(insnList.size() - 1);
if (checkCastInsn.getOpcode().getOpcode() != RegOps.CHECK_CAST) {
continue;
}
RegisterSpec checkRegSpec = checkCastInsn.getSources().get(0);
int checkReg = checkRegSpec.getReg();
/**
* See if either register is already mapped. Most likely the move
* result will be mapped already since the cast result is stored
* in a local variable.
*/
int category = checkRegSpec.getCategory();
boolean moveMapped = ssaRegsMapped.get(moveReg);
boolean checkMapped = ssaRegsMapped.get(checkReg);
if (moveMapped & !checkMapped) {
int moveRopReg = mapper.oldToNew(moveReg);
checkMapped = tryMapReg(checkRegSpec, moveRopReg, category);
}
if (checkMapped & !moveMapped) {
int checkRopReg = mapper.oldToNew(checkReg);
moveMapped = tryMapReg(moveRegSpec, checkRopReg, category);
}
// Map any unmapped registers to anything available
if (!moveMapped || !checkMapped) {
int ropReg = findNextUnreservedRopReg(paramRangeEnd, category);
ArrayList ssaRegs =
new ArrayList(2);
ssaRegs.add(moveRegSpec);
ssaRegs.add(checkRegSpec);
while (!tryMapRegs(ssaRegs, ropReg, category, false)) {
ropReg = findNextUnreservedRopReg(ropReg + 1, category);
}
}
/*
* If source and result have a different mapping, insert a move so
* they can have the same mapping. Don't do this if the check cast
* is caught, since it will overwrite a potentially live value.
*/
boolean hasExceptionHandlers =
checkCastInsn.getOriginalRopInsn().getCatches().size() != 0;
int moveRopReg = mapper.oldToNew(moveReg);
int checkRopReg = mapper.oldToNew(checkReg);
if (moveRopReg != checkRopReg && !hasExceptionHandlers) {
((NormalSsaInsn) checkCastInsn).changeOneSource(0,
insertMoveBefore(checkCastInsn, checkRegSpec));
addMapping(checkCastInsn.getSources().get(0), moveRopReg);
}
}
}
/**
* Handles all phi instructions, trying to map them to a common register.
*/
private void handlePhiInsns() {
for (PhiInsn insn : phiInsns) {
processPhiInsn(insn);
}
}
/**
* Maps all non-parameter, non-local variable registers.
*/
private void handleNormalUnassociated() {
int szSsaRegs = ssaMeth.getRegCount();
for (int ssaReg = 0; ssaReg < szSsaRegs; ssaReg++) {
if (ssaRegsMapped.get(ssaReg)) {
// We already did this one
continue;
}
RegisterSpec ssaSpec = getDefinitionSpecForSsaReg(ssaReg);
if (ssaSpec == null) continue;
int category = ssaSpec.getCategory();
// Find a rop reg that does not interfere
int ropReg = findNextUnreservedRopReg(paramRangeEnd, category);
while (!canMapReg(ssaSpec, ropReg)) {
ropReg = findNextUnreservedRopReg(ropReg + 1, category);
}
addMapping(ssaSpec, ropReg);
}
}
/**
* Checks to see if a list of SSA registers can all be mapped into
* the same rop reg. Ignores registers that have already been mapped,
* and checks the interference graph and ensures the range does not
* cross the parameter range.
*
* @param specs {@code non-null;} SSA registers to check
* @param ropReg {@code >=0;} rop register to check mapping to
* @return {@code true} if all unmapped registers can be mapped
*/
private boolean canMapRegs(ArrayList specs, int ropReg) {
for (RegisterSpec spec : specs) {
if (ssaRegsMapped.get(spec.getReg())) continue;
if (!canMapReg(spec, ropReg)) return false;
}
return true;
}
/**
* Checks to see if {@code ssaSpec} can be mapped to
* {@code ropReg}. Checks interference graph and ensures
* the range does not cross the parameter range.
*
* @param ssaSpec {@code non-null;} SSA spec
* @param ropReg prosepctive new-namespace reg
* @return {@code true} if mapping is possible
*/
private boolean canMapReg(RegisterSpec ssaSpec, int ropReg) {
int category = ssaSpec.getCategory();
return !(spansParamRange(ropReg, category)
|| mapper.interferes(ssaSpec, ropReg));
}
/**
* Returns true if the specified rop register + category
* will cross the boundry between the lower {@code paramWidth}
* registers reserved for method params and the upper registers. We cannot
* allocate a register that spans the param block and the normal block,
* because we will be moving the param block to high registers later.
*
* @param ssaReg register in new namespace
* @param category width that the register will have
* @return {@code true} in the case noted above
*/
private boolean spansParamRange(int ssaReg, int category) {
return ((ssaReg < paramRangeEnd)
&& ((ssaReg + category) > paramRangeEnd));
}
/**
* Analyze each instruction and find out all the local variable assignments
* and move-result-pseudo/invoke-range instrucitons.
*/
private void analyzeInstructions() {
ssaMeth.forEachInsn(new SsaInsn.Visitor() {
/** {@inheritDoc} */
public void visitMoveInsn(NormalSsaInsn insn) {
processInsn(insn);
}
/** {@inheritDoc} */
public void visitPhiInsn(PhiInsn insn) {
processInsn(insn);
}
/** {@inheritDoc} */
public void visitNonMoveInsn(NormalSsaInsn insn) {
processInsn(insn);
}
/**
* This method collects three types of instructions:
*
* 1) Adds a local variable assignment to the
* {@code localVariables} map.
* 2) Add move-result-pseudo to the
* {@code moveResultPseudoInsns} list.
* 3) Add invoke-range to the
* {@code invokeRangeInsns} list.
*
* @param insn {@code non-null;} insn that may represent a
* local variable assignment
*/
private void processInsn(SsaInsn insn) {
RegisterSpec assignment;
assignment = insn.getLocalAssignment();
if (assignment != null) {
LocalItem local = assignment.getLocalItem();
ArrayList regList
= localVariables.get(local);
if (regList == null) {
regList = new ArrayList();
localVariables.put(local, regList);
}
regList.add(assignment);
}
if (insn instanceof NormalSsaInsn) {
if (insn.getOpcode().getOpcode() ==
RegOps.MOVE_RESULT_PSEUDO) {
moveResultPseudoInsns.add((NormalSsaInsn) insn);
} else if (Optimizer.getAdvice().requiresSourcesInOrder(
insn.getOriginalRopInsn().getOpcode(),
insn.getSources())) {
invokeRangeInsns.add((NormalSsaInsn) insn);
}
} else if (insn instanceof PhiInsn) {
phiInsns.add((PhiInsn) insn);
}
}
});
}
/**
* Adds a mapping from an SSA register to a rop register.
* {@link #canMapReg} should have already been called.
*
* @param ssaSpec {@code non-null;} SSA register to map from
* @param ropReg {@code >=0;} rop register to map to
*/
private void addMapping(RegisterSpec ssaSpec, int ropReg) {
int ssaReg = ssaSpec.getReg();
// An assertion.
if (ssaRegsMapped.get(ssaReg) || !canMapReg(ssaSpec, ropReg)) {
throw new RuntimeException(
"attempt to add invalid register mapping");
}
if (DEBUG) {
System.out.printf("Add mapping s%d -> v%d c:%d\n",
ssaSpec.getReg(), ropReg, ssaSpec.getCategory());
}
int category = ssaSpec.getCategory();
mapper.addMapping(ssaSpec.getReg(), ropReg, category);
ssaRegsMapped.set(ssaReg);
usedRopRegs.set(ropReg, ropReg + category);
}
/**
* Maps the source registers of the specified instruction such that they
* will fall in a contiguous range in rop form. Moves are inserted as
* necessary to allow the range to be allocated.
*
* @param insn {@code non-null;} insn whos sources to process
*/
private void adjustAndMapSourceRangeRange(NormalSsaInsn insn) {
int newRegStart = findRangeAndAdjust(insn);
RegisterSpecList sources = insn.getSources();
int szSources = sources.size();
int nextRopReg = newRegStart;
for (int i = 0; i < szSources; i++) {
RegisterSpec source = sources.get(i);
int sourceReg = source.getReg();
int category = source.getCategory();
int curRopReg = nextRopReg;
nextRopReg += category;
if (ssaRegsMapped.get(sourceReg)) {
continue;
}
LocalItem localItem = getLocalItemForReg(sourceReg);
addMapping(source, curRopReg);
if (localItem != null) {
markReserved(curRopReg, category);
ArrayList similarRegisters
= localVariables.get(localItem);
int szSimilar = similarRegisters.size();
/*
* Try to map all SSA registers also associated with
* this local.
*/
for (int j = 0; j < szSimilar; j++) {
RegisterSpec similarSpec = similarRegisters.get(j);
int similarReg = similarSpec.getReg();
// Don't map anything that's also a source.
if (-1 != sources.indexOfRegister(similarReg)) {
continue;
}
// Registers left unmapped will get handled later.
tryMapReg(similarSpec, curRopReg, category);
}
}
}
}
/**
* Find a contiguous rop register range that fits the specified
* instruction's sources. First, try to center the range around
* sources that have already been mapped to rop registers. If that fails,
* just find a new contiguous range that doesn't interfere.
*
* @param insn {@code non-null;} the insn whose sources need to
* fit. Must be last insn in basic block.
* @return {@code >= 0;} rop register of start of range
*/
private int findRangeAndAdjust(NormalSsaInsn insn) {
RegisterSpecList sources = insn.getSources();
int szSources = sources.size();
// the category for each source index
int categoriesForIndex[] = new int[szSources];
int rangeLength = 0;
// Compute rangeLength and categoriesForIndex
for (int i = 0; i < szSources; i++) {
int category = sources.get(i).getCategory();
categoriesForIndex[i] = category;
rangeLength += categoriesForIndex[i];
}
// the highest score of fits tried so far
int maxScore = Integer.MIN_VALUE;
// the high scoring range's start
int resultRangeStart = -1;
// by source index: set of sources needing moves in high scoring plan
BitSet resultMovesRequired = null;
/*
* First, go through each source that's already been mapped. Try
* to center the range around the rop register this source is mapped
* to.
*/
int rangeStartOffset = 0;
for (int i = 0; i < szSources; i++) {
int ssaCenterReg = sources.get(i).getReg();
if (i != 0) {
rangeStartOffset -= categoriesForIndex[i - 1];
}
if (!ssaRegsMapped.get(ssaCenterReg)) {
continue;
}
int rangeStart = mapper.oldToNew(ssaCenterReg) + rangeStartOffset;
if (rangeStart < 0 || spansParamRange(rangeStart, rangeLength)) {
continue;
}
BitSet curMovesRequired = new BitSet(szSources);
int fitWidth
= fitPlanForRange(rangeStart, insn, categoriesForIndex,
curMovesRequired);
if (fitWidth < 0) {
continue;
}
int score = fitWidth - curMovesRequired.cardinality();
if (score > maxScore) {
maxScore = score;
resultRangeStart = rangeStart;
resultMovesRequired = curMovesRequired;
}
if (fitWidth == rangeLength) {
// We can't do any better than this, so stop here
break;
}
}
/*
* If we were unable to find a plan for a fit centered around
* an already-mapped source, just try to find a range of
* registers we can move the range into.
*/
if (resultRangeStart == -1) {
resultMovesRequired = new BitSet(szSources);
resultRangeStart = findAnyFittingRange(insn, rangeLength,
categoriesForIndex, resultMovesRequired);
}
/*
* Now, insert any moves required.
*/
for (int i = resultMovesRequired.nextSetBit(0); i >= 0;
i = resultMovesRequired.nextSetBit(i+1)) {
insn.changeOneSource(i, insertMoveBefore(insn, sources.get(i)));
}
return resultRangeStart;
}
/**
* Finds an unreserved range that will fit the sources of the
* specified instruction. Does not bother trying to center the range
* around an already-mapped source register;
*
* @param insn {@code non-null;} insn to build range for
* @param rangeLength {@code >=0;} length required in register units
* @param categoriesForIndex {@code non-null;} indexed by source index;
* the category for each source
* @param outMovesRequired {@code non-null;} an output parameter indexed by
* source index that will contain the set of sources which need
* moves inserted
* @return the rop register that starts the fitting range
*/
private int findAnyFittingRange(NormalSsaInsn insn, int rangeLength,
int[] categoriesForIndex, BitSet outMovesRequired) {
Alignment alignment = Alignment.UNSPECIFIED;
if (DexOptions.ALIGN_64BIT_REGS_SUPPORT) {
int regNumber = 0;
int p64bitsAligned = 0;
int p64bitsNotAligned = 0;
for (int category : categoriesForIndex) {
if (category == 2) {
if (isEven(regNumber)) {
p64bitsAligned++;
} else {
p64bitsNotAligned++;
}
regNumber += 2;
} else {
regNumber += 1;
}
}
if (p64bitsNotAligned > p64bitsAligned) {
if (isEven(paramRangeEnd)) {
alignment = Alignment.ODD;
} else {
alignment = Alignment.EVEN;
}
} else if (p64bitsAligned > 0) {
if (isEven(paramRangeEnd)) {
alignment = Alignment.EVEN;
} else {
alignment = Alignment.ODD;
}
}
}
int rangeStart = paramRangeEnd;
while (true) {
rangeStart = findNextUnreservedRopReg(rangeStart, rangeLength, alignment);
int fitWidth = fitPlanForRange(rangeStart, insn, categoriesForIndex, outMovesRequired);
if (fitWidth >= 0) {
break;
}
rangeStart++;
outMovesRequired.clear();
}
return rangeStart;
}
/**
* Attempts to build a plan for fitting a range of sources into rop
* registers.
*
* @param ropReg {@code >= 0;} rop reg that begins range
* @param insn {@code non-null;} insn to plan range for
* @param categoriesForIndex {@code non-null;} indexed by source index;
* the category for each source
* @param outMovesRequired {@code non-null;} an output parameter indexed by
* source index that will contain the set of sources which need
* moves inserted
* @return the width of the fit that that does not involve added moves or
* {@code -1} if "no fit possible"
*/
private int fitPlanForRange(int ropReg, NormalSsaInsn insn,
int[] categoriesForIndex, BitSet outMovesRequired) {
RegisterSpecList sources = insn.getSources();
int szSources = sources.size();
int fitWidth = 0;
IntSet liveOut = insn.getBlock().getLiveOutRegs();
RegisterSpecList liveOutSpecs = ssaSetToSpecs(liveOut);
// An SSA reg may only be mapped into a range once.
BitSet seen = new BitSet(ssaMeth.getRegCount());
for (int i = 0; i < szSources ; i++) {
RegisterSpec ssaSpec = sources.get(i);
int ssaReg = ssaSpec.getReg();
int category = categoriesForIndex[i];
if (i != 0) {
ropReg += categoriesForIndex[i-1];
}
if (ssaRegsMapped.get(ssaReg)
&& mapper.oldToNew(ssaReg) == ropReg) {
// This is a register that is already mapped appropriately.
fitWidth += category;
} else if (rangeContainsReserved(ropReg, category)) {
fitWidth = -1;
break;
} else if (!ssaRegsMapped.get(ssaReg)
&& canMapReg(ssaSpec, ropReg)
&& !seen.get(ssaReg)) {
// This is a register that can be mapped appropriately.
fitWidth += category;
} else if (!mapper.areAnyPinned(liveOutSpecs, ropReg, category)
&& !mapper.areAnyPinned(sources, ropReg, category)) {
/*
* This is a source that can be moved. We can insert a
* move as long as:
*
* * no SSA register pinned to the desired rop reg
* is live out on the block
*
* * no SSA register pinned to desired rop reg is
* a source of this insn (since this may require
* overlapping moves, which we can't presently handle)
*/
outMovesRequired.set(i);
} else {
fitWidth = -1;
break;
}
seen.set(ssaReg);
}
return fitWidth;
}
/**
* Converts a bit set of SSA registers into a RegisterSpecList containing
* the definition specs of all the registers.
*
* @param ssaSet {@code non-null;} set of SSA registers
* @return list of RegisterSpecs as noted above
*/
RegisterSpecList ssaSetToSpecs(IntSet ssaSet) {
RegisterSpecList result = new RegisterSpecList(ssaSet.elements());
IntIterator iter = ssaSet.iterator();
int i = 0;
while (iter.hasNext()) {
result.set(i++, getDefinitionSpecForSsaReg(iter.next()));
}
return result;
}
/**
* Gets a local item associated with an ssa register, if one exists.
*
* @param ssaReg {@code >= 0;} SSA register
* @return {@code null-ok;} associated local item or null
*/
private LocalItem getLocalItemForReg(int ssaReg) {
for (Map.Entry> entry :
localVariables.entrySet()) {
for (RegisterSpec spec : entry.getValue()) {
if (spec.getReg() == ssaReg) {
return entry.getKey();
}
}
}
return null;
}
/**
* Attempts to map the sources and result of a phi to a common register.
* Will try existing mappings first, from most to least common. If none
* of the registers have mappings yet, a new mapping is created.
*/
private void processPhiInsn(PhiInsn insn) {
RegisterSpec result = insn.getResult();
int resultReg = result.getReg();
int category = result.getCategory();
RegisterSpecList sources = insn.getSources();
int sourcesSize = sources.size();
// List of phi sources / result that need mapping
ArrayList ssaRegs = new ArrayList();
// Track how many times a particular mapping is found
Multiset mapSet = new Multiset(sourcesSize + 1);
/*
* If the result of the phi has an existing mapping, get it.
* Otherwise, add it to the list of regs that need mapping.
*/
if (ssaRegsMapped.get(resultReg)) {
mapSet.add(mapper.oldToNew(resultReg));
} else {
ssaRegs.add(result);
}
for (int i = 0; i < sourcesSize; i++) {
RegisterSpec source = sources.get(i);
SsaInsn def = ssaMeth.getDefinitionForRegister(source.getReg());
RegisterSpec sourceDef = def.getResult();
int sourceReg = sourceDef.getReg();
/*
* If a source of the phi has an existing mapping, get it.
* Otherwise, add it to the list of regs that need mapping.
*/
if (ssaRegsMapped.get(sourceReg)) {
mapSet.add(mapper.oldToNew(sourceReg));
} else {
ssaRegs.add(sourceDef);
}
}
// Try all existing mappings, with the most common ones first
for (int i = 0; i < mapSet.getSize(); i++) {
int maxReg = mapSet.getAndRemoveHighestCount();
tryMapRegs(ssaRegs, maxReg, category, false);
}
// Map any remaining unmapped regs with whatever fits
int mapReg = findNextUnreservedRopReg(paramRangeEnd, category);
while (!tryMapRegs(ssaRegs, mapReg, category, false)) {
mapReg = findNextUnreservedRopReg(mapReg + 1, category);
}
}
private static boolean isEven(int regNumger) {
return ((regNumger & 1) == 0);
}
// A set that tracks how often elements are added to it.
private static class Multiset {
private final int[] reg;
private final int[] count;
private int size;
/**
* Constructs an instance.
*
* @param maxSize the maximum distinct elements the set may have
*/
public Multiset(int maxSize) {
reg = new int[maxSize];
count = new int[maxSize];
size = 0;
}
/**
* Adds an element to the set.
*
* @param element element to add
*/
public void add(int element) {
for (int i = 0; i < size; i++) {
if (reg[i] == element) {
count[i]++;
return;
}
}
reg[size] = element;
count[size] = 1;
size++;
}
/**
* Searches the set for the element that has been added the most.
* In the case of a tie, the element that was added first is returned.
* Then, it clears the count on that element. The size of the set
* remains unchanged.
*
* @return element with the highest count
*/
public int getAndRemoveHighestCount() {
int maxIndex = -1;
int maxReg = -1;
int maxCount = 0;
for (int i = 0; i < size; i++) {
if (maxCount < count[i]) {
maxIndex = i;
maxReg = reg[i];
maxCount = count[i];
}
}
count[maxIndex] = 0;
return maxReg;
}
/**
* Gets the number of distinct elements in the set.
*
* @return size of the set
*/
public int getSize() {
return size;
}
}
}