/*
* Copyright (C) 2010 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.
*/
#include "Dalvik.h"
#include "Dataflow.h"
#include "libdex/OpCodeNames.h"
/* Convert the reg id from the callee to the original id passed by the caller */
static inline u4 convertRegId(const DecodedInstruction *invoke,
const Method *calleeMethod,
int calleeRegId, bool isRange)
{
/* The order in the original arg passing list */
int rank = calleeRegId -
(calleeMethod->registersSize - calleeMethod->insSize);
assert(rank >= 0);
if (!isRange) {
return invoke->arg[rank];
} else {
return invoke->vC + rank;
}
}
static void inlineGetter(CompilationUnit *cUnit,
const Method *calleeMethod,
MIR *invokeMIR,
BasicBlock *invokeBB,
bool isPredicted,
bool isRange)
{
BasicBlock *moveResultBB = invokeBB->fallThrough;
MIR *moveResultMIR = moveResultBB->firstMIRInsn;
MIR *newGetterMIR = dvmCompilerNew(sizeof(MIR), true);
DecodedInstruction getterInsn;
dexDecodeInstruction(gDvm.instrFormat, calleeMethod->insns, &getterInsn);
if (!dvmCompilerCanIncludeThisInstruction(calleeMethod, &getterInsn))
return;
/*
* Some getters (especially invoked through interface) are not followed
* by a move result.
*/
if ((moveResultMIR == NULL) ||
(moveResultMIR->dalvikInsn.opCode != OP_MOVE_RESULT &&
moveResultMIR->dalvikInsn.opCode != OP_MOVE_RESULT_OBJECT &&
moveResultMIR->dalvikInsn.opCode != OP_MOVE_RESULT_WIDE)) {
return;
}
int dfFlags = dvmCompilerDataFlowAttributes[getterInsn.opCode];
/* Expecting vA to be the destination register */
if (dfFlags & (DF_UA | DF_UA_WIDE)) {
LOGE("opcode %d has DF_UA set (not expected)", getterInsn.opCode);
dvmAbort();
}
if (dfFlags & DF_UB) {
getterInsn.vB = convertRegId(&invokeMIR->dalvikInsn, calleeMethod,
getterInsn.vB, isRange);
}
if (dfFlags & DF_UC) {
getterInsn.vC = convertRegId(&invokeMIR->dalvikInsn, calleeMethod,
getterInsn.vC, isRange);
}
getterInsn.vA = moveResultMIR->dalvikInsn.vA;
/* Now setup the Dalvik instruction with converted src/dst registers */
newGetterMIR->dalvikInsn = getterInsn;
newGetterMIR->width = gDvm.instrWidth[getterInsn.opCode];
newGetterMIR->OptimizationFlags |= MIR_CALLEE;
/*
* If the getter instruction is about to raise any exception, punt to the
* interpreter and re-execute the invoke.
*/
newGetterMIR->offset = invokeMIR->offset;
newGetterMIR->meta.calleeMethod = calleeMethod;
dvmCompilerInsertMIRAfter(invokeBB, invokeMIR, newGetterMIR);
if (isPredicted) {
MIR *invokeMIRSlow = dvmCompilerNew(sizeof(MIR), true);
*invokeMIRSlow = *invokeMIR;
invokeMIR->dalvikInsn.opCode = kMirOpCheckInlinePrediction;
/* Use vC to denote the first argument (ie this) */
if (!isRange) {
invokeMIR->dalvikInsn.vC = invokeMIRSlow->dalvikInsn.arg[0];
}
moveResultMIR->OptimizationFlags |= MIR_INLINED_PRED;
dvmCompilerInsertMIRAfter(invokeBB, newGetterMIR, invokeMIRSlow);
invokeMIRSlow->OptimizationFlags |= MIR_INLINED_PRED;
#if defined(WITH_JIT_TUNING)
gDvmJit.invokePolyGetterInlined++;
#endif
} else {
invokeMIR->OptimizationFlags |= MIR_INLINED;
moveResultMIR->OptimizationFlags |= MIR_INLINED;
#if defined(WITH_JIT_TUNING)
gDvmJit.invokeMonoGetterInlined++;
#endif
}
return;
}
static void inlineSetter(CompilationUnit *cUnit,
const Method *calleeMethod,
MIR *invokeMIR,
BasicBlock *invokeBB,
bool isPredicted,
bool isRange)
{
MIR *newSetterMIR = dvmCompilerNew(sizeof(MIR), true);
DecodedInstruction setterInsn;
dexDecodeInstruction(gDvm.instrFormat, calleeMethod->insns, &setterInsn);
if (!dvmCompilerCanIncludeThisInstruction(calleeMethod, &setterInsn))
return;
int dfFlags = dvmCompilerDataFlowAttributes[setterInsn.opCode];
if (dfFlags & (DF_UA | DF_UA_WIDE)) {
setterInsn.vA = convertRegId(&invokeMIR->dalvikInsn, calleeMethod,
setterInsn.vA, isRange);
}
if (dfFlags & DF_UB) {
setterInsn.vB = convertRegId(&invokeMIR->dalvikInsn, calleeMethod,
setterInsn.vB, isRange);
}
if (dfFlags & DF_UC) {
setterInsn.vC = convertRegId(&invokeMIR->dalvikInsn, calleeMethod,
setterInsn.vC, isRange);
}
/* Now setup the Dalvik instruction with converted src/dst registers */
newSetterMIR->dalvikInsn = setterInsn;
newSetterMIR->width = gDvm.instrWidth[setterInsn.opCode];
newSetterMIR->OptimizationFlags |= MIR_CALLEE;
/*
* If the setter instruction is about to raise any exception, punt to the
* interpreter and re-execute the invoke.
*/
newSetterMIR->offset = invokeMIR->offset;
newSetterMIR->meta.calleeMethod = calleeMethod;
dvmCompilerInsertMIRAfter(invokeBB, invokeMIR, newSetterMIR);
if (isPredicted) {
MIR *invokeMIRSlow = dvmCompilerNew(sizeof(MIR), true);
*invokeMIRSlow = *invokeMIR;
invokeMIR->dalvikInsn.opCode = kMirOpCheckInlinePrediction;
/* Use vC to denote the first argument (ie this) */
if (!isRange) {
invokeMIR->dalvikInsn.vC = invokeMIRSlow->dalvikInsn.arg[0];
}
dvmCompilerInsertMIRAfter(invokeBB, newSetterMIR, invokeMIRSlow);
invokeMIRSlow->OptimizationFlags |= MIR_INLINED_PRED;
#if defined(WITH_JIT_TUNING)
gDvmJit.invokePolySetterInlined++;
#endif
} else {
/*
* The invoke becomes no-op so it needs an explicit branch to jump to
* the chaining cell.
*/
invokeBB->needFallThroughBranch = true;
invokeMIR->OptimizationFlags |= MIR_INLINED;
#if defined(WITH_JIT_TUNING)
gDvmJit.invokeMonoSetterInlined++;
#endif
}
return;
}
static void tryInlineSingletonCallsite(CompilationUnit *cUnit,
const Method *calleeMethod,
MIR *invokeMIR,
BasicBlock *invokeBB,
bool isRange)
{
/* Not a Java method */
if (dvmIsNativeMethod(calleeMethod)) return;
CompilerMethodStats *methodStats =
dvmCompilerAnalyzeMethodBody(calleeMethod, true);
/* Empty callee - do nothing */
if (methodStats->attributes & METHOD_IS_EMPTY) {
/* The original invoke instruction is effectively turned into NOP */
invokeMIR->OptimizationFlags |= MIR_INLINED;
/*
* Need to insert an explicit branch to catch the falling knife (into
* the PC reconstruction or chaining cell).
*/
invokeBB->needFallThroughBranch = true;
return;
}
if (methodStats->attributes & METHOD_IS_GETTER) {
inlineGetter(cUnit, calleeMethod, invokeMIR, invokeBB, false, isRange);
return;
} else if (methodStats->attributes & METHOD_IS_SETTER) {
inlineSetter(cUnit, calleeMethod, invokeMIR, invokeBB, false, isRange);
return;
}
}
static void inlineEmptyVirtualCallee(CompilationUnit *cUnit,
const Method *calleeMethod,
MIR *invokeMIR,
BasicBlock *invokeBB)
{
MIR *invokeMIRSlow = dvmCompilerNew(sizeof(MIR), true);
*invokeMIRSlow = *invokeMIR;
invokeMIR->dalvikInsn.opCode = kMirOpCheckInlinePrediction;
dvmCompilerInsertMIRAfter(invokeBB, invokeMIR, invokeMIRSlow);
invokeMIRSlow->OptimizationFlags |= MIR_INLINED_PRED;
}
static void tryInlineVirtualCallsite(CompilationUnit *cUnit,
const Method *calleeMethod,
MIR *invokeMIR,
BasicBlock *invokeBB,
bool isRange)
{
/* Not a Java method */
if (dvmIsNativeMethod(calleeMethod)) return;
CompilerMethodStats *methodStats =
dvmCompilerAnalyzeMethodBody(calleeMethod, true);
/* Empty callee - do nothing by checking the clazz pointer */
if (methodStats->attributes & METHOD_IS_EMPTY) {
inlineEmptyVirtualCallee(cUnit, calleeMethod, invokeMIR, invokeBB);
return;
}
if (methodStats->attributes & METHOD_IS_GETTER) {
inlineGetter(cUnit, calleeMethod, invokeMIR, invokeBB, true, isRange);
return;
} else if (methodStats->attributes & METHOD_IS_SETTER) {
inlineSetter(cUnit, calleeMethod, invokeMIR, invokeBB, true, isRange);
return;
}
}
void dvmCompilerInlineMIR(CompilationUnit *cUnit)
{
int i;
bool isRange = false;
/*
* Analyze the basic block containing an invoke to see if it can be inlined
*/
for (i = 0; i < cUnit->numBlocks; i++) {
BasicBlock *bb = cUnit->blockList[i];
if (bb->blockType != kDalvikByteCode)
continue;
MIR *lastMIRInsn = bb->lastMIRInsn;
int opCode = lastMIRInsn->dalvikInsn.opCode;
int flags = dexGetInstrFlags(gDvm.instrFlags, opCode);
/* No invoke - continue */
if ((flags & kInstrInvoke) == 0)
continue;
/* Not a real invoke - continue */
if (opCode == OP_INVOKE_DIRECT_EMPTY)
continue;
/*
* If the invoke itself is selected for single stepping, don't bother
* to inline it.
*/
if (SINGLE_STEP_OP(opCode))
continue;
const Method *calleeMethod;
switch (opCode) {
case OP_INVOKE_SUPER:
case OP_INVOKE_DIRECT:
case OP_INVOKE_STATIC:
case OP_INVOKE_SUPER_QUICK:
calleeMethod = lastMIRInsn->meta.callsiteInfo->method;
break;
case OP_INVOKE_SUPER_RANGE:
case OP_INVOKE_DIRECT_RANGE:
case OP_INVOKE_STATIC_RANGE:
case OP_INVOKE_SUPER_QUICK_RANGE:
isRange = true;
calleeMethod = lastMIRInsn->meta.callsiteInfo->method;
break;
default:
calleeMethod = NULL;
break;
}
if (calleeMethod) {
tryInlineSingletonCallsite(cUnit, calleeMethod, lastMIRInsn, bb,
isRange);
return;
}
switch (opCode) {
case OP_INVOKE_VIRTUAL:
case OP_INVOKE_VIRTUAL_QUICK:
case OP_INVOKE_INTERFACE:
isRange = false;
calleeMethod = lastMIRInsn->meta.callsiteInfo->method;
break;
case OP_INVOKE_VIRTUAL_RANGE:
case OP_INVOKE_VIRTUAL_QUICK_RANGE:
case OP_INVOKE_INTERFACE_RANGE:
isRange = true;
calleeMethod = lastMIRInsn->meta.callsiteInfo->method;
break;
default:
break;
}
if (calleeMethod) {
tryInlineVirtualCallsite(cUnit, calleeMethod, lastMIRInsn, bb,
isRange);
return;
}
}
}