blob: e0226e9e193d72c9da947cd96fa426fca70b41b2 [file] [log] [blame]
/*
* Copyright (C) 2009 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 "libdex/DexOpcodes.h"
#include "libdex/DexCatch.h"
#include "interp/Jit.h"
#include "CompilerInternals.h"
#include "Dataflow.h"
static inline bool contentIsInsn(const u2 *codePtr) {
u2 instr = *codePtr;
Opcode opcode = (Opcode)(instr & 0xff);
/*
* Since the low 8-bit in metadata may look like OP_NOP, we need to check
* both the low and whole sub-word to determine whether it is code or data.
*/
return (opcode != OP_NOP || instr == 0);
}
/*
* Parse an instruction, return the length of the instruction
*/
static inline int parseInsn(const u2 *codePtr, DecodedInstruction *decInsn,
bool printMe)
{
// Don't parse instruction data
if (!contentIsInsn(codePtr)) {
return 0;
}
u2 instr = *codePtr;
Opcode opcode = dexOpcodeFromCodeUnit(instr);
dexDecodeInstruction(codePtr, decInsn);
if (printMe) {
char *decodedString = dvmCompilerGetDalvikDisassembly(decInsn, NULL);
ALOGD("%p: %#06x %s", codePtr, opcode, decodedString);
}
return dexGetWidthFromOpcode(opcode);
}
#define UNKNOWN_TARGET 0xffffffff
/*
* Identify block-ending instructions and collect supplemental information
* regarding the following instructions.
*/
static inline bool findBlockBoundary(const Method *caller, MIR *insn,
unsigned int curOffset,
unsigned int *target, bool *isInvoke,
const Method **callee)
{
switch (insn->dalvikInsn.opcode) {
/* Target is not compile-time constant */
case OP_RETURN_VOID:
case OP_RETURN:
case OP_RETURN_WIDE:
case OP_RETURN_OBJECT:
case OP_THROW:
*target = UNKNOWN_TARGET;
break;
case OP_INVOKE_VIRTUAL:
case OP_INVOKE_VIRTUAL_RANGE:
case OP_INVOKE_INTERFACE:
case OP_INVOKE_INTERFACE_RANGE:
case OP_INVOKE_VIRTUAL_QUICK:
case OP_INVOKE_VIRTUAL_QUICK_RANGE:
*isInvoke = true;
break;
case OP_INVOKE_SUPER:
case OP_INVOKE_SUPER_RANGE: {
int mIndex = caller->clazz->pDvmDex->
pResMethods[insn->dalvikInsn.vB]->methodIndex;
const Method *calleeMethod =
caller->clazz->super->vtable[mIndex];
if (calleeMethod && !dvmIsNativeMethod(calleeMethod)) {
*target = (unsigned int) calleeMethod->insns;
}
*isInvoke = true;
*callee = calleeMethod;
break;
}
case OP_INVOKE_STATIC:
case OP_INVOKE_STATIC_RANGE: {
const Method *calleeMethod =
caller->clazz->pDvmDex->pResMethods[insn->dalvikInsn.vB];
if (calleeMethod && !dvmIsNativeMethod(calleeMethod)) {
*target = (unsigned int) calleeMethod->insns;
}
*isInvoke = true;
*callee = calleeMethod;
break;
}
case OP_INVOKE_SUPER_QUICK:
case OP_INVOKE_SUPER_QUICK_RANGE: {
const Method *calleeMethod =
caller->clazz->super->vtable[insn->dalvikInsn.vB];
if (calleeMethod && !dvmIsNativeMethod(calleeMethod)) {
*target = (unsigned int) calleeMethod->insns;
}
*isInvoke = true;
*callee = calleeMethod;
break;
}
case OP_INVOKE_DIRECT:
case OP_INVOKE_DIRECT_RANGE: {
const Method *calleeMethod =
caller->clazz->pDvmDex->pResMethods[insn->dalvikInsn.vB];
if (calleeMethod && !dvmIsNativeMethod(calleeMethod)) {
*target = (unsigned int) calleeMethod->insns;
}
*isInvoke = true;
*callee = calleeMethod;
break;
}
case OP_GOTO:
case OP_GOTO_16:
case OP_GOTO_32:
*target = curOffset + (int) insn->dalvikInsn.vA;
break;
case OP_IF_EQ:
case OP_IF_NE:
case OP_IF_LT:
case OP_IF_GE:
case OP_IF_GT:
case OP_IF_LE:
*target = curOffset + (int) insn->dalvikInsn.vC;
break;
case OP_IF_EQZ:
case OP_IF_NEZ:
case OP_IF_LTZ:
case OP_IF_GEZ:
case OP_IF_GTZ:
case OP_IF_LEZ:
*target = curOffset + (int) insn->dalvikInsn.vB;
break;
default:
return false;
}
return true;
}
static inline bool isGoto(MIR *insn)
{
switch (insn->dalvikInsn.opcode) {
case OP_GOTO:
case OP_GOTO_16:
case OP_GOTO_32:
return true;
default:
return false;
}
}
/*
* Identify unconditional branch instructions
*/
static inline bool isUnconditionalBranch(MIR *insn)
{
switch (insn->dalvikInsn.opcode) {
case OP_RETURN_VOID:
case OP_RETURN:
case OP_RETURN_WIDE:
case OP_RETURN_OBJECT:
return true;
default:
return isGoto(insn);
}
}
/*
* dvmHashTableLookup() callback
*/
static int compareMethod(const CompilerMethodStats *m1,
const CompilerMethodStats *m2)
{
return (int) m1->method - (int) m2->method;
}
/*
* Analyze the body of the method to collect high-level information regarding
* inlining:
* - is empty method?
* - is getter/setter?
* - can throw exception?
*
* Currently the inliner only handles getters and setters. When its capability
* becomes more sophisticated more information will be retrieved here.
*/
static int analyzeInlineTarget(DecodedInstruction *dalvikInsn, int attributes,
int offset)
{
int flags = dexGetFlagsFromOpcode(dalvikInsn->opcode);
int dalvikOpcode = dalvikInsn->opcode;
if (flags & kInstrInvoke) {
attributes &= ~METHOD_IS_LEAF;
}
if (!(flags & kInstrCanReturn)) {
if (!(dvmCompilerDataFlowAttributes[dalvikOpcode] &
DF_IS_GETTER)) {
attributes &= ~METHOD_IS_GETTER;
}
if (!(dvmCompilerDataFlowAttributes[dalvikOpcode] &
DF_IS_SETTER)) {
attributes &= ~METHOD_IS_SETTER;
}
}
/*
* The expected instruction sequence is setter will never return value and
* getter will also do. Clear the bits if the behavior is discovered
* otherwise.
*/
if (flags & kInstrCanReturn) {
if (dalvikOpcode == OP_RETURN_VOID) {
attributes &= ~METHOD_IS_GETTER;
}
else {
attributes &= ~METHOD_IS_SETTER;
}
}
if (flags & kInstrCanThrow) {
attributes &= ~METHOD_IS_THROW_FREE;
}
if (offset == 0 && dalvikOpcode == OP_RETURN_VOID) {
attributes |= METHOD_IS_EMPTY;
}
/*
* Check if this opcode is selected for single stepping.
* If so, don't inline the callee as there is no stack frame for the
* interpreter to single-step through the instruction.
*/
if (SINGLE_STEP_OP(dalvikOpcode)) {
attributes &= ~(METHOD_IS_GETTER | METHOD_IS_SETTER);
}
return attributes;
}
/*
* Analyze each method whose traces are ever compiled. Collect a variety of
* statistics like the ratio of exercised vs overall code and code bloat
* ratios. If isCallee is true, also analyze each instruction in more details
* to see if it is suitable for inlining.
*/
CompilerMethodStats *dvmCompilerAnalyzeMethodBody(const Method *method,
bool isCallee)
{
const DexCode *dexCode = dvmGetMethodCode(method);
const u2 *codePtr = dexCode->insns;
const u2 *codeEnd = dexCode->insns + dexCode->insnsSize;
int insnSize = 0;
int hashValue = dvmComputeUtf8Hash(method->name);
CompilerMethodStats dummyMethodEntry; // For hash table lookup
CompilerMethodStats *realMethodEntry; // For hash table storage
/* For lookup only */
dummyMethodEntry.method = method;
realMethodEntry = (CompilerMethodStats *)
dvmHashTableLookup(gDvmJit.methodStatsTable,
hashValue,
&dummyMethodEntry,
(HashCompareFunc) compareMethod,
false);
/* This method has never been analyzed before - create an entry */
if (realMethodEntry == NULL) {
realMethodEntry =
(CompilerMethodStats *) calloc(1, sizeof(CompilerMethodStats));
realMethodEntry->method = method;
dvmHashTableLookup(gDvmJit.methodStatsTable, hashValue,
realMethodEntry,
(HashCompareFunc) compareMethod,
true);
}
/* This method is invoked as a callee and has been analyzed - just return */
if ((isCallee == true) && (realMethodEntry->attributes & METHOD_IS_CALLEE))
return realMethodEntry;
/*
* Similarly, return if this method has been compiled before as a hot
* method already.
*/
if ((isCallee == false) &&
(realMethodEntry->attributes & METHOD_IS_HOT))
return realMethodEntry;
int attributes;
/* Method hasn't been analyzed for the desired purpose yet */
if (isCallee) {
/* Aggressively set the attributes until proven otherwise */
attributes = METHOD_IS_LEAF | METHOD_IS_THROW_FREE | METHOD_IS_CALLEE |
METHOD_IS_GETTER | METHOD_IS_SETTER;
} else {
attributes = METHOD_IS_HOT;
}
/* Count the number of instructions */
while (codePtr < codeEnd) {
DecodedInstruction dalvikInsn;
int width = parseInsn(codePtr, &dalvikInsn, false);
/* Terminate when the data section is seen */
if (width == 0)
break;
if (isCallee) {
attributes = analyzeInlineTarget(&dalvikInsn, attributes, insnSize);
}
insnSize += width;
codePtr += width;
}
/*
* Only handle simple getters/setters with one instruction followed by
* return
*/
if ((attributes & (METHOD_IS_GETTER | METHOD_IS_SETTER)) &&
(insnSize != 3)) {
attributes &= ~(METHOD_IS_GETTER | METHOD_IS_SETTER);
}
realMethodEntry->dalvikSize = insnSize * 2;
realMethodEntry->attributes |= attributes;
#if 0
/* Uncomment the following to explore various callee patterns */
if (attributes & METHOD_IS_THROW_FREE) {
ALOGE("%s%s is inlinable%s", method->clazz->descriptor, method->name,
(attributes & METHOD_IS_EMPTY) ? " empty" : "");
}
if (attributes & METHOD_IS_LEAF) {
ALOGE("%s%s is leaf %d%s", method->clazz->descriptor, method->name,
insnSize, insnSize < 5 ? " (small)" : "");
}
if (attributes & (METHOD_IS_GETTER | METHOD_IS_SETTER)) {
ALOGE("%s%s is %s", method->clazz->descriptor, method->name,
attributes & METHOD_IS_GETTER ? "getter": "setter");
}
if (attributes ==
(METHOD_IS_LEAF | METHOD_IS_THROW_FREE | METHOD_IS_CALLEE)) {
ALOGE("%s%s is inlinable non setter/getter", method->clazz->descriptor,
method->name);
}
#endif
return realMethodEntry;
}
/*
* Crawl the stack of the thread that requesed compilation to see if any of the
* ancestors are on the blacklist.
*/
static bool filterMethodByCallGraph(Thread *thread, const char *curMethodName)
{
/* Crawl the Dalvik stack frames and compare the method name*/
StackSaveArea *ssaPtr = ((StackSaveArea *) thread->interpSave.curFrame) - 1;
while (ssaPtr != ((StackSaveArea *) NULL) - 1) {
const Method *method = ssaPtr->method;
if (method) {
int hashValue = dvmComputeUtf8Hash(method->name);
bool found =
dvmHashTableLookup(gDvmJit.methodTable, hashValue,
(char *) method->name,
(HashCompareFunc) strcmp, false) !=
NULL;
if (found) {
ALOGD("Method %s (--> %s) found on the JIT %s list",
method->name, curMethodName,
gDvmJit.includeSelectedMethod ? "white" : "black");
return true;
}
}
ssaPtr = ((StackSaveArea *) ssaPtr->prevFrame) - 1;
};
return false;
}
/*
* Since we are including instructions from possibly a cold method into the
* current trace, we need to make sure that all the associated information
* with the callee is properly initialized. If not, we punt on this inline
* target.
*
* TODO: volatile instructions will be handled later.
*/
bool dvmCompilerCanIncludeThisInstruction(const Method *method,
const DecodedInstruction *insn)
{
switch (insn->opcode) {
case OP_NEW_INSTANCE:
case OP_CHECK_CAST: {
ClassObject *classPtr = (ClassObject *)(void*)
(method->clazz->pDvmDex->pResClasses[insn->vB]);
/* Class hasn't been initialized yet */
if (classPtr == NULL) {
return false;
}
return true;
}
case OP_SGET:
case OP_SGET_WIDE:
case OP_SGET_OBJECT:
case OP_SGET_BOOLEAN:
case OP_SGET_BYTE:
case OP_SGET_CHAR:
case OP_SGET_SHORT:
case OP_SPUT:
case OP_SPUT_WIDE:
case OP_SPUT_OBJECT:
case OP_SPUT_BOOLEAN:
case OP_SPUT_BYTE:
case OP_SPUT_CHAR:
case OP_SPUT_SHORT: {
void *fieldPtr = (void*)
(method->clazz->pDvmDex->pResFields[insn->vB]);
if (fieldPtr == NULL) {
return false;
}
return true;
}
case OP_INVOKE_SUPER:
case OP_INVOKE_SUPER_RANGE: {
int mIndex = method->clazz->pDvmDex->
pResMethods[insn->vB]->methodIndex;
const Method *calleeMethod = method->clazz->super->vtable[mIndex];
if (calleeMethod == NULL) {
return false;
}
return true;
}
case OP_INVOKE_SUPER_QUICK:
case OP_INVOKE_SUPER_QUICK_RANGE: {
const Method *calleeMethod = method->clazz->super->vtable[insn->vB];
if (calleeMethod == NULL) {
return false;
}
return true;
}
case OP_INVOKE_STATIC:
case OP_INVOKE_STATIC_RANGE:
case OP_INVOKE_DIRECT:
case OP_INVOKE_DIRECT_RANGE: {
const Method *calleeMethod =
method->clazz->pDvmDex->pResMethods[insn->vB];
if (calleeMethod == NULL) {
return false;
}
return true;
}
case OP_CONST_CLASS: {
void *classPtr = (void*)
(method->clazz->pDvmDex->pResClasses[insn->vB]);
if (classPtr == NULL) {
return false;
}
return true;
}
case OP_CONST_STRING_JUMBO:
case OP_CONST_STRING: {
void *strPtr = (void*)
(method->clazz->pDvmDex->pResStrings[insn->vB]);
if (strPtr == NULL) {
return false;
}
return true;
}
default:
return true;
}
}
/* Split an existing block from the specified code offset into two */
static BasicBlock *splitBlock(CompilationUnit *cUnit,
unsigned int codeOffset,
BasicBlock *origBlock,
BasicBlock **immedPredBlockP)
{
MIR *insn = origBlock->firstMIRInsn;
while (insn) {
if (insn->offset == codeOffset) break;
insn = insn->next;
}
if (insn == NULL) {
ALOGE("Break split failed");
dvmAbort();
}
BasicBlock *bottomBlock = dvmCompilerNewBB(kDalvikByteCode,
cUnit->numBlocks++);
dvmInsertGrowableList(&cUnit->blockList, (intptr_t) bottomBlock);
bottomBlock->startOffset = codeOffset;
bottomBlock->firstMIRInsn = insn;
bottomBlock->lastMIRInsn = origBlock->lastMIRInsn;
/* Handle the taken path */
bottomBlock->taken = origBlock->taken;
if (bottomBlock->taken) {
origBlock->taken = NULL;
dvmCompilerClearBit(bottomBlock->taken->predecessors, origBlock->id);
dvmCompilerSetBit(bottomBlock->taken->predecessors, bottomBlock->id);
}
/* Handle the fallthrough path */
bottomBlock->needFallThroughBranch = origBlock->needFallThroughBranch;
bottomBlock->fallThrough = origBlock->fallThrough;
origBlock->fallThrough = bottomBlock;
origBlock->needFallThroughBranch = true;
dvmCompilerSetBit(bottomBlock->predecessors, origBlock->id);
if (bottomBlock->fallThrough) {
dvmCompilerClearBit(bottomBlock->fallThrough->predecessors,
origBlock->id);
dvmCompilerSetBit(bottomBlock->fallThrough->predecessors,
bottomBlock->id);
}
/* Handle the successor list */
if (origBlock->successorBlockList.blockListType != kNotUsed) {
bottomBlock->successorBlockList = origBlock->successorBlockList;
origBlock->successorBlockList.blockListType = kNotUsed;
GrowableListIterator iterator;
dvmGrowableListIteratorInit(&bottomBlock->successorBlockList.blocks,
&iterator);
while (true) {
SuccessorBlockInfo *successorBlockInfo =
(SuccessorBlockInfo *) dvmGrowableListIteratorNext(&iterator);
if (successorBlockInfo == NULL) break;
BasicBlock *bb = successorBlockInfo->block;
dvmCompilerClearBit(bb->predecessors, origBlock->id);
dvmCompilerSetBit(bb->predecessors, bottomBlock->id);
}
}
origBlock->lastMIRInsn = insn->prev;
insn->prev->next = NULL;
insn->prev = NULL;
/*
* Update the immediate predecessor block pointer so that outgoing edges
* can be applied to the proper block.
*/
if (immedPredBlockP) {
assert(*immedPredBlockP == origBlock);
*immedPredBlockP = bottomBlock;
}
return bottomBlock;
}
/*
* Given a code offset, find out the block that starts with it. If the offset
* is in the middle of an existing block, split it into two. If immedPredBlockP
* is non-null and is the block being split, update *immedPredBlockP to point
* to the bottom block so that outgoing edges can be setup properly (by the
* caller).
*/
static BasicBlock *findBlock(CompilationUnit *cUnit,
unsigned int codeOffset,
bool split, bool create,
BasicBlock **immedPredBlockP)
{
GrowableList *blockList = &cUnit->blockList;
BasicBlock *bb;
unsigned int i;
for (i = 0; i < blockList->numUsed; i++) {
bb = (BasicBlock *) blockList->elemList[i];
if (bb->blockType != kDalvikByteCode) continue;
if (bb->startOffset == codeOffset) return bb;
/* Check if a branch jumps into the middle of an existing block */
if ((split == true) && (codeOffset > bb->startOffset) &&
(bb->lastMIRInsn != NULL) &&
(codeOffset <= bb->lastMIRInsn->offset)) {
BasicBlock *newBB = splitBlock(cUnit, codeOffset, bb,
bb == *immedPredBlockP ?
immedPredBlockP : NULL);
return newBB;
}
}
if (create) {
bb = dvmCompilerNewBB(kDalvikByteCode, cUnit->numBlocks++);
dvmInsertGrowableList(&cUnit->blockList, (intptr_t) bb);
bb->startOffset = codeOffset;
return bb;
}
return NULL;
}
/* Dump the CFG into a DOT graph */
void dvmDumpCFG(CompilationUnit *cUnit, const char *dirPrefix)
{
const Method *method = cUnit->method;
FILE *file;
char *signature = dexProtoCopyMethodDescriptor(&method->prototype);
char startOffset[80];
sprintf(startOffset, "_%x", cUnit->entryBlock->fallThrough->startOffset);
char *fileName = (char *) dvmCompilerNew(
strlen(dirPrefix) +
strlen(method->clazz->descriptor) +
strlen(method->name) +
strlen(signature) +
strlen(startOffset) +
strlen(".dot") + 1, true);
sprintf(fileName, "%s%s%s%s%s.dot", dirPrefix,
method->clazz->descriptor, method->name, signature, startOffset);
free(signature);
/*
* Convert the special characters into a filesystem- and shell-friendly
* format.
*/
int i;
for (i = strlen(dirPrefix); fileName[i]; i++) {
if (fileName[i] == '/') {
fileName[i] = '_';
} else if (fileName[i] == ';') {
fileName[i] = '#';
} else if (fileName[i] == '$') {
fileName[i] = '+';
} else if (fileName[i] == '(' || fileName[i] == ')') {
fileName[i] = '@';
} else if (fileName[i] == '<' || fileName[i] == '>') {
fileName[i] = '=';
}
}
file = fopen(fileName, "w");
if (file == NULL) {
return;
}
fprintf(file, "digraph G {\n");
fprintf(file, " rankdir=TB\n");
int numReachableBlocks = cUnit->numReachableBlocks;
int idx;
const GrowableList *blockList = &cUnit->blockList;
for (idx = 0; idx < numReachableBlocks; idx++) {
int blockIdx = cUnit->dfsOrder.elemList[idx];
BasicBlock *bb = (BasicBlock *) dvmGrowableListGetElement(blockList,
blockIdx);
if (bb == NULL) break;
if (bb->blockType == kEntryBlock) {
fprintf(file, " entry [shape=Mdiamond];\n");
} else if (bb->blockType == kExitBlock) {
fprintf(file, " exit [shape=Mdiamond];\n");
} else if (bb->blockType == kDalvikByteCode) {
fprintf(file, " block%04x [shape=record,label = \"{ \\\n",
bb->startOffset);
const MIR *mir;
fprintf(file, " {block id %d\\l}%s\\\n", bb->id,
bb->firstMIRInsn ? " | " : " ");
for (mir = bb->firstMIRInsn; mir; mir = mir->next) {
fprintf(file, " {%04x %s\\l}%s\\\n", mir->offset,
mir->ssaRep ?
dvmCompilerFullDisassembler(cUnit, mir) :
dexGetOpcodeName(mir->dalvikInsn.opcode),
mir->next ? " | " : " ");
}
fprintf(file, " }\"];\n\n");
} else if (bb->blockType == kExceptionHandling) {
char blockName[BLOCK_NAME_LEN];
dvmGetBlockName(bb, blockName);
fprintf(file, " %s [shape=invhouse];\n", blockName);
}
char blockName1[BLOCK_NAME_LEN], blockName2[BLOCK_NAME_LEN];
if (bb->taken) {
dvmGetBlockName(bb, blockName1);
dvmGetBlockName(bb->taken, blockName2);
fprintf(file, " %s:s -> %s:n [style=dotted]\n",
blockName1, blockName2);
}
if (bb->fallThrough) {
dvmGetBlockName(bb, blockName1);
dvmGetBlockName(bb->fallThrough, blockName2);
fprintf(file, " %s:s -> %s:n\n", blockName1, blockName2);
}
if (bb->successorBlockList.blockListType != kNotUsed) {
fprintf(file, " succ%04x [shape=%s,label = \"{ \\\n",
bb->startOffset,
(bb->successorBlockList.blockListType == kCatch) ?
"Mrecord" : "record");
GrowableListIterator iterator;
dvmGrowableListIteratorInit(&bb->successorBlockList.blocks,
&iterator);
SuccessorBlockInfo *successorBlockInfo =
(SuccessorBlockInfo *) dvmGrowableListIteratorNext(&iterator);
int succId = 0;
while (true) {
if (successorBlockInfo == NULL) break;
BasicBlock *destBlock = successorBlockInfo->block;
SuccessorBlockInfo *nextSuccessorBlockInfo =
(SuccessorBlockInfo *) dvmGrowableListIteratorNext(&iterator);
fprintf(file, " {<f%d> %04x: %04x\\l}%s\\\n",
succId++,
successorBlockInfo->key,
destBlock->startOffset,
(nextSuccessorBlockInfo != NULL) ? " | " : " ");
successorBlockInfo = nextSuccessorBlockInfo;
}
fprintf(file, " }\"];\n\n");
dvmGetBlockName(bb, blockName1);
fprintf(file, " %s:s -> succ%04x:n [style=dashed]\n",
blockName1, bb->startOffset);
if (bb->successorBlockList.blockListType == kPackedSwitch ||
bb->successorBlockList.blockListType == kSparseSwitch) {
dvmGrowableListIteratorInit(&bb->successorBlockList.blocks,
&iterator);
succId = 0;
while (true) {
SuccessorBlockInfo *successorBlockInfo =
(SuccessorBlockInfo *)
dvmGrowableListIteratorNext(&iterator);
if (successorBlockInfo == NULL) break;
BasicBlock *destBlock = successorBlockInfo->block;
dvmGetBlockName(destBlock, blockName2);
fprintf(file, " succ%04x:f%d:e -> %s:n\n",
bb->startOffset, succId++,
blockName2);
}
}
}
fprintf(file, "\n");
/*
* If we need to debug the dominator tree, uncomment the following code
*/
#if 1
dvmGetBlockName(bb, blockName1);
fprintf(file, " cfg%s [label=\"%s\", shape=none];\n",
blockName1, blockName1);
if (bb->iDom) {
dvmGetBlockName(bb->iDom, blockName2);
fprintf(file, " cfg%s:s -> cfg%s:n\n\n",
blockName2, blockName1);
}
#endif
}
fprintf(file, "}\n");
fclose(file);
}
/* Verify if all the successor is connected with all the claimed predecessors */
static bool verifyPredInfo(CompilationUnit *cUnit, BasicBlock *bb)
{
BitVectorIterator bvIterator;
dvmBitVectorIteratorInit(bb->predecessors, &bvIterator);
while (true) {
int blockIdx = dvmBitVectorIteratorNext(&bvIterator);
if (blockIdx == -1) break;
BasicBlock *predBB = (BasicBlock *)
dvmGrowableListGetElement(&cUnit->blockList, blockIdx);
bool found = false;
if (predBB->taken == bb) {
found = true;
} else if (predBB->fallThrough == bb) {
found = true;
} else if (predBB->successorBlockList.blockListType != kNotUsed) {
GrowableListIterator iterator;
dvmGrowableListIteratorInit(&predBB->successorBlockList.blocks,
&iterator);
while (true) {
SuccessorBlockInfo *successorBlockInfo =
(SuccessorBlockInfo *)
dvmGrowableListIteratorNext(&iterator);
if (successorBlockInfo == NULL) break;
BasicBlock *succBB = successorBlockInfo->block;
if (succBB == bb) {
found = true;
break;
}
}
}
if (found == false) {
char blockName1[BLOCK_NAME_LEN], blockName2[BLOCK_NAME_LEN];
dvmGetBlockName(bb, blockName1);
dvmGetBlockName(predBB, blockName2);
dvmDumpCFG(cUnit, "/sdcard/cfg/");
ALOGE("Successor %s not found from %s",
blockName1, blockName2);
dvmAbort();
}
}
return true;
}
/* Identify code range in try blocks and set up the empty catch blocks */
static void processTryCatchBlocks(CompilationUnit *cUnit)
{
const Method *meth = cUnit->method;
const DexCode *pCode = dvmGetMethodCode(meth);
int triesSize = pCode->triesSize;
int i;
int offset;
if (triesSize == 0) {
return;
}
const DexTry *pTries = dexGetTries(pCode);
BitVector *tryBlockAddr = cUnit->tryBlockAddr;
/* Mark all the insn offsets in Try blocks */
for (i = 0; i < triesSize; i++) {
const DexTry* pTry = &pTries[i];
/* all in 16-bit units */
int startOffset = pTry->startAddr;
int endOffset = startOffset + pTry->insnCount;
for (offset = startOffset; offset < endOffset; offset++) {
dvmCompilerSetBit(tryBlockAddr, offset);
}
}
/* Iterate over each of the handlers to enqueue the empty Catch blocks */
offset = dexGetFirstHandlerOffset(pCode);
int handlersSize = dexGetHandlersSize(pCode);
for (i = 0; i < handlersSize; i++) {
DexCatchIterator iterator;
dexCatchIteratorInit(&iterator, pCode, offset);
for (;;) {
DexCatchHandler* handler = dexCatchIteratorNext(&iterator);
if (handler == NULL) {
break;
}
/*
* Create dummy catch blocks first. Since these are created before
* other blocks are processed, "split" is specified as false.
*/
findBlock(cUnit, handler->address,
/* split */
false,
/* create */
true,
/* immedPredBlockP */
NULL);
}
offset = dexCatchIteratorGetEndOffset(&iterator, pCode);
}
}
/* Process instructions with the kInstrCanBranch flag */
static void processCanBranch(CompilationUnit *cUnit, BasicBlock *curBlock,
MIR *insn, int curOffset, int width, int flags,
const u2* codePtr, const u2* codeEnd)
{
int target = curOffset;
switch (insn->dalvikInsn.opcode) {
case OP_GOTO:
case OP_GOTO_16:
case OP_GOTO_32:
target += (int) insn->dalvikInsn.vA;
break;
case OP_IF_EQ:
case OP_IF_NE:
case OP_IF_LT:
case OP_IF_GE:
case OP_IF_GT:
case OP_IF_LE:
target += (int) insn->dalvikInsn.vC;
break;
case OP_IF_EQZ:
case OP_IF_NEZ:
case OP_IF_LTZ:
case OP_IF_GEZ:
case OP_IF_GTZ:
case OP_IF_LEZ:
target += (int) insn->dalvikInsn.vB;
break;
default:
ALOGE("Unexpected opcode(%d) with kInstrCanBranch set",
insn->dalvikInsn.opcode);
dvmAbort();
}
BasicBlock *takenBlock = findBlock(cUnit, target,
/* split */
true,
/* create */
true,
/* immedPredBlockP */
&curBlock);
curBlock->taken = takenBlock;
dvmCompilerSetBit(takenBlock->predecessors, curBlock->id);
/* Always terminate the current block for conditional branches */
if (flags & kInstrCanContinue) {
BasicBlock *fallthroughBlock = findBlock(cUnit,
curOffset + width,
/*
* If the method is processed
* in sequential order from the
* beginning, we don't need to
* specify split for continue
* blocks. However, this
* routine can be called by
* compileLoop, which starts
* parsing the method from an
* arbitrary address in the
* method body.
*/
true,
/* create */
true,
/* immedPredBlockP */
&curBlock);
curBlock->fallThrough = fallthroughBlock;
dvmCompilerSetBit(fallthroughBlock->predecessors, curBlock->id);
} else if (codePtr < codeEnd) {
/* Create a fallthrough block for real instructions (incl. OP_NOP) */
if (contentIsInsn(codePtr)) {
findBlock(cUnit, curOffset + width,
/* split */
false,
/* create */
true,
/* immedPredBlockP */
NULL);
}
}
}
/* Process instructions with the kInstrCanSwitch flag */
static void processCanSwitch(CompilationUnit *cUnit, BasicBlock *curBlock,
MIR *insn, int curOffset, int width, int flags)
{
u2 *switchData= (u2 *) (cUnit->method->insns + curOffset +
insn->dalvikInsn.vB);
int size;
int *keyTable;
int *targetTable;
int i;
int firstKey;
/*
* Packed switch data format:
* ushort ident = 0x0100 magic value
* ushort size number of entries in the table
* int first_key first (and lowest) switch case value
* int targets[size] branch targets, relative to switch opcode
*
* Total size is (4+size*2) 16-bit code units.
*/
if (insn->dalvikInsn.opcode == OP_PACKED_SWITCH) {
assert(switchData[0] == kPackedSwitchSignature);
size = switchData[1];
firstKey = switchData[2] | (switchData[3] << 16);
targetTable = (int *) &switchData[4];
keyTable = NULL; // Make the compiler happy
/*
* Sparse switch data format:
* ushort ident = 0x0200 magic value
* ushort size number of entries in the table; > 0
* int keys[size] keys, sorted low-to-high; 32-bit aligned
* int targets[size] branch targets, relative to switch opcode
*
* Total size is (2+size*4) 16-bit code units.
*/
} else {
assert(switchData[0] == kSparseSwitchSignature);
size = switchData[1];
keyTable = (int *) &switchData[2];
targetTable = (int *) &switchData[2 + size*2];
firstKey = 0; // To make the compiler happy
}
if (curBlock->successorBlockList.blockListType != kNotUsed) {
ALOGE("Successor block list already in use: %d",
curBlock->successorBlockList.blockListType);
dvmAbort();
}
curBlock->successorBlockList.blockListType =
(insn->dalvikInsn.opcode == OP_PACKED_SWITCH) ?
kPackedSwitch : kSparseSwitch;
dvmInitGrowableList(&curBlock->successorBlockList.blocks, size);
for (i = 0; i < size; i++) {
BasicBlock *caseBlock = findBlock(cUnit, curOffset + targetTable[i],
/* split */
true,
/* create */
true,
/* immedPredBlockP */
&curBlock);
SuccessorBlockInfo *successorBlockInfo =
(SuccessorBlockInfo *) dvmCompilerNew(sizeof(SuccessorBlockInfo),
false);
successorBlockInfo->block = caseBlock;
successorBlockInfo->key = (insn->dalvikInsn.opcode == OP_PACKED_SWITCH)?
firstKey + i : keyTable[i];
dvmInsertGrowableList(&curBlock->successorBlockList.blocks,
(intptr_t) successorBlockInfo);
dvmCompilerSetBit(caseBlock->predecessors, curBlock->id);
}
/* Fall-through case */
BasicBlock *fallthroughBlock = findBlock(cUnit,
curOffset + width,
/* split */
false,
/* create */
true,
/* immedPredBlockP */
NULL);
curBlock->fallThrough = fallthroughBlock;
dvmCompilerSetBit(fallthroughBlock->predecessors, curBlock->id);
}
/* Process instructions with the kInstrCanThrow flag */
static void processCanThrow(CompilationUnit *cUnit, BasicBlock *curBlock,
MIR *insn, int curOffset, int width, int flags,
BitVector *tryBlockAddr, const u2 *codePtr,
const u2* codeEnd)
{
const Method *method = cUnit->method;
const DexCode *dexCode = dvmGetMethodCode(method);
/* In try block */
if (dvmIsBitSet(tryBlockAddr, curOffset)) {
DexCatchIterator iterator;
if (!dexFindCatchHandler(&iterator, dexCode, curOffset)) {
ALOGE("Catch block not found in dexfile for insn %x in %s",
curOffset, method->name);
dvmAbort();
}
if (curBlock->successorBlockList.blockListType != kNotUsed) {
ALOGE("Successor block list already in use: %d",
curBlock->successorBlockList.blockListType);
dvmAbort();
}
curBlock->successorBlockList.blockListType = kCatch;
dvmInitGrowableList(&curBlock->successorBlockList.blocks, 2);
for (;;) {
DexCatchHandler* handler = dexCatchIteratorNext(&iterator);
if (handler == NULL) {
break;
}
BasicBlock *catchBlock = findBlock(cUnit, handler->address,
/* split */
false,
/* create */
false,
/* immedPredBlockP */
NULL);
SuccessorBlockInfo *successorBlockInfo =
(SuccessorBlockInfo *) dvmCompilerNew(sizeof(SuccessorBlockInfo),
false);
successorBlockInfo->block = catchBlock;
successorBlockInfo->key = handler->typeIdx;
dvmInsertGrowableList(&curBlock->successorBlockList.blocks,
(intptr_t) successorBlockInfo);
dvmCompilerSetBit(catchBlock->predecessors, curBlock->id);
}
} else {
BasicBlock *ehBlock = dvmCompilerNewBB(kExceptionHandling,
cUnit->numBlocks++);
curBlock->taken = ehBlock;
dvmInsertGrowableList(&cUnit->blockList, (intptr_t) ehBlock);
ehBlock->startOffset = curOffset;
dvmCompilerSetBit(ehBlock->predecessors, curBlock->id);
}
/*
* Force the current block to terminate.
*
* Data may be present before codeEnd, so we need to parse it to know
* whether it is code or data.
*/
if (codePtr < codeEnd) {
/* Create a fallthrough block for real instructions (incl. OP_NOP) */
if (contentIsInsn(codePtr)) {
BasicBlock *fallthroughBlock = findBlock(cUnit,
curOffset + width,
/* split */
false,
/* create */
true,
/* immedPredBlockP */
NULL);
/*
* OP_THROW and OP_THROW_VERIFICATION_ERROR are unconditional
* branches.
*/
if (insn->dalvikInsn.opcode != OP_THROW_VERIFICATION_ERROR &&
insn->dalvikInsn.opcode != OP_THROW) {
curBlock->fallThrough = fallthroughBlock;
dvmCompilerSetBit(fallthroughBlock->predecessors, curBlock->id);
}
}
}
}
/*
* Similar to dvmCompileTrace, but the entity processed here is the whole
* method.
*
* TODO: implementation will be revisited when the trace builder can provide
* whole-method traces.
*/
bool dvmCompileMethod(const Method *method, JitTranslationInfo *info)
{
CompilationUnit cUnit;
const DexCode *dexCode = dvmGetMethodCode(method);
const u2 *codePtr = dexCode->insns;
const u2 *codeEnd = dexCode->insns + dexCode->insnsSize;
int numBlocks = 0;
unsigned int curOffset = 0;
/* Method already compiled */
if (dvmJitGetMethodAddr(codePtr)) {
info->codeAddress = NULL;
return false;
}
memset(&cUnit, 0, sizeof(cUnit));
cUnit.method = method;
cUnit.jitMode = kJitMethod;
/* Initialize the block list */
dvmInitGrowableList(&cUnit.blockList, 4);
/*
* FIXME - PC reconstruction list won't be needed after the codegen routines
* are enhanced to true method mode.
*/
/* Initialize the PC reconstruction list */
dvmInitGrowableList(&cUnit.pcReconstructionList, 8);
/* Allocate the bit-vector to track the beginning of basic blocks */
BitVector *tryBlockAddr = dvmCompilerAllocBitVector(dexCode->insnsSize,
true /* expandable */);
cUnit.tryBlockAddr = tryBlockAddr;
/* Create the default entry and exit blocks and enter them to the list */
BasicBlock *entryBlock = dvmCompilerNewBB(kEntryBlock, numBlocks++);
BasicBlock *exitBlock = dvmCompilerNewBB(kExitBlock, numBlocks++);
cUnit.entryBlock = entryBlock;
cUnit.exitBlock = exitBlock;
dvmInsertGrowableList(&cUnit.blockList, (intptr_t) entryBlock);
dvmInsertGrowableList(&cUnit.blockList, (intptr_t) exitBlock);
/* Current block to record parsed instructions */
BasicBlock *curBlock = dvmCompilerNewBB(kDalvikByteCode, numBlocks++);
curBlock->startOffset = 0;
dvmInsertGrowableList(&cUnit.blockList, (intptr_t) curBlock);
entryBlock->fallThrough = curBlock;
dvmCompilerSetBit(curBlock->predecessors, entryBlock->id);
/*
* Store back the number of blocks since new blocks may be created of
* accessing cUnit.
*/
cUnit.numBlocks = numBlocks;
/* Identify code range in try blocks and set up the empty catch blocks */
processTryCatchBlocks(&cUnit);
/* Parse all instructions and put them into containing basic blocks */
while (codePtr < codeEnd) {
MIR *insn = (MIR *) dvmCompilerNew(sizeof(MIR), true);
insn->offset = curOffset;
int width = parseInsn(codePtr, &insn->dalvikInsn, false);
insn->width = width;
/* Terminate when the data section is seen */
if (width == 0)
break;
dvmCompilerAppendMIR(curBlock, insn);
codePtr += width;
int flags = dexGetFlagsFromOpcode(insn->dalvikInsn.opcode);
if (flags & kInstrCanBranch) {
processCanBranch(&cUnit, curBlock, insn, curOffset, width, flags,
codePtr, codeEnd);
} else if (flags & kInstrCanReturn) {
curBlock->fallThrough = exitBlock;
dvmCompilerSetBit(exitBlock->predecessors, curBlock->id);
/*
* Terminate the current block if there are instructions
* afterwards.
*/
if (codePtr < codeEnd) {
/*
* Create a fallthrough block for real instructions
* (incl. OP_NOP).
*/
if (contentIsInsn(codePtr)) {
findBlock(&cUnit, curOffset + width,
/* split */
false,
/* create */
true,
/* immedPredBlockP */
NULL);
}
}
} else if (flags & kInstrCanThrow) {
processCanThrow(&cUnit, curBlock, insn, curOffset, width, flags,
tryBlockAddr, codePtr, codeEnd);
} else if (flags & kInstrCanSwitch) {
processCanSwitch(&cUnit, curBlock, insn, curOffset, width, flags);
}
curOffset += width;
BasicBlock *nextBlock = findBlock(&cUnit, curOffset,
/* split */
false,
/* create */
false,
/* immedPredBlockP */
NULL);
if (nextBlock) {
/*
* The next instruction could be the target of a previously parsed
* forward branch so a block is already created. If the current
* instruction is not an unconditional branch, connect them through
* the fall-through link.
*/
assert(curBlock->fallThrough == NULL ||
curBlock->fallThrough == nextBlock ||
curBlock->fallThrough == exitBlock);
if ((curBlock->fallThrough == NULL) &&
(flags & kInstrCanContinue)) {
curBlock->fallThrough = nextBlock;
dvmCompilerSetBit(nextBlock->predecessors, curBlock->id);
}
curBlock = nextBlock;
}
}
if (cUnit.printMe) {
dvmCompilerDumpCompilationUnit(&cUnit);
}
/* Adjust this value accordingly once inlining is performed */
cUnit.numDalvikRegisters = cUnit.method->registersSize;
/* Verify if all blocks are connected as claimed */
/* FIXME - to be disabled in the future */
dvmCompilerDataFlowAnalysisDispatcher(&cUnit, verifyPredInfo,
kAllNodes,
false /* isIterative */);
/* Perform SSA transformation for the whole method */
dvmCompilerMethodSSATransformation(&cUnit);
dvmCompilerInitializeRegAlloc(&cUnit); // Needs to happen after SSA naming
/* Allocate Registers using simple local allocation scheme */
dvmCompilerLocalRegAlloc(&cUnit);
/* Convert MIR to LIR, etc. */
dvmCompilerMethodMIR2LIR(&cUnit);
// Debugging only
//dvmDumpCFG(&cUnit, "/sdcard/cfg/");
/* Method is not empty */
if (cUnit.firstLIRInsn) {
/* Convert LIR into machine code. Loop for recoverable retries */
do {
dvmCompilerAssembleLIR(&cUnit, info);
cUnit.assemblerRetries++;
if (cUnit.printMe && cUnit.assemblerStatus != kSuccess)
ALOGD("Assembler abort #%d on %d",cUnit.assemblerRetries,
cUnit.assemblerStatus);
} while (cUnit.assemblerStatus == kRetryAll);
if (cUnit.printMe) {
dvmCompilerCodegenDump(&cUnit);
}
if (info->codeAddress) {
dvmJitSetCodeAddr(dexCode->insns, info->codeAddress,
info->instructionSet, true, 0);
/*
* Clear the codeAddress for the enclosing trace to reuse the info
*/
info->codeAddress = NULL;
}
}
return false;
}
/* Extending the trace by crawling the code from curBlock */
static bool exhaustTrace(CompilationUnit *cUnit, BasicBlock *curBlock)
{
unsigned int curOffset = curBlock->startOffset;
const u2 *codePtr = cUnit->method->insns + curOffset;
if (curBlock->visited == true) return false;
curBlock->visited = true;
if (curBlock->blockType == kEntryBlock ||
curBlock->blockType == kExitBlock) {
return false;
}
/*
* Block has been parsed - check the taken/fallThrough in case it is a split
* block.
*/
if (curBlock->firstMIRInsn != NULL) {
bool changed = false;
if (curBlock->taken)
changed |= exhaustTrace(cUnit, curBlock->taken);
if (curBlock->fallThrough)
changed |= exhaustTrace(cUnit, curBlock->fallThrough);
return changed;
}
while (true) {
MIR *insn = (MIR *) dvmCompilerNew(sizeof(MIR), true);
insn->offset = curOffset;
int width = parseInsn(codePtr, &insn->dalvikInsn, false);
insn->width = width;
/* Terminate when the data section is seen */
if (width == 0)
break;
dvmCompilerAppendMIR(curBlock, insn);
codePtr += width;
int flags = dexGetFlagsFromOpcode(insn->dalvikInsn.opcode);
/* Stop extending the trace after seeing these instructions */
if (flags & (kInstrCanReturn | kInstrCanSwitch | kInstrInvoke)) {
curBlock->fallThrough = cUnit->exitBlock;
dvmCompilerSetBit(cUnit->exitBlock->predecessors, curBlock->id);
break;
} else if (flags & kInstrCanBranch) {
processCanBranch(cUnit, curBlock, insn, curOffset, width, flags,
codePtr, NULL);
if (curBlock->taken) {
exhaustTrace(cUnit, curBlock->taken);
}
if (curBlock->fallThrough) {
exhaustTrace(cUnit, curBlock->fallThrough);
}
break;
}
curOffset += width;
BasicBlock *nextBlock = findBlock(cUnit, curOffset,
/* split */
false,
/* create */
false,
/* immedPredBlockP */
NULL);
if (nextBlock) {
/*
* The next instruction could be the target of a previously parsed
* forward branch so a block is already created. If the current
* instruction is not an unconditional branch, connect them through
* the fall-through link.
*/
assert(curBlock->fallThrough == NULL ||
curBlock->fallThrough == nextBlock ||
curBlock->fallThrough == cUnit->exitBlock);
if ((curBlock->fallThrough == NULL) &&
(flags & kInstrCanContinue)) {
curBlock->needFallThroughBranch = true;
curBlock->fallThrough = nextBlock;
dvmCompilerSetBit(nextBlock->predecessors, curBlock->id);
}
/* Block has been visited - no more parsing needed */
if (nextBlock->visited == true) {
return true;
}
curBlock = nextBlock;
}
}
return true;
}
/* Compile a loop */
static bool compileLoop(CompilationUnit *cUnit, unsigned int startOffset,
JitTraceDescription *desc, int numMaxInsts,
JitTranslationInfo *info, jmp_buf *bailPtr,
int optHints)
{
int numBlocks = 0;
unsigned int curOffset = startOffset;
bool changed;
BasicBlock *bb;
#if defined(WITH_JIT_TUNING)
CompilerMethodStats *methodStats;
#endif
cUnit->jitMode = kJitLoop;
/* Initialize the block list */
dvmInitGrowableList(&cUnit->blockList, 4);
/* Initialize the PC reconstruction list */
dvmInitGrowableList(&cUnit->pcReconstructionList, 8);
/* Create the default entry and exit blocks and enter them to the list */
BasicBlock *entryBlock = dvmCompilerNewBB(kEntryBlock, numBlocks++);
entryBlock->startOffset = curOffset;
BasicBlock *exitBlock = dvmCompilerNewBB(kExitBlock, numBlocks++);
cUnit->entryBlock = entryBlock;
cUnit->exitBlock = exitBlock;
dvmInsertGrowableList(&cUnit->blockList, (intptr_t) entryBlock);
dvmInsertGrowableList(&cUnit->blockList, (intptr_t) exitBlock);
/* Current block to record parsed instructions */
BasicBlock *curBlock = dvmCompilerNewBB(kDalvikByteCode, numBlocks++);
curBlock->startOffset = curOffset;
dvmInsertGrowableList(&cUnit->blockList, (intptr_t) curBlock);
entryBlock->fallThrough = curBlock;
dvmCompilerSetBit(curBlock->predecessors, entryBlock->id);
/*
* Store back the number of blocks since new blocks may be created of
* accessing cUnit.
*/
cUnit->numBlocks = numBlocks;
do {
dvmCompilerDataFlowAnalysisDispatcher(cUnit,
dvmCompilerClearVisitedFlag,
kAllNodes,
false /* isIterative */);
changed = exhaustTrace(cUnit, curBlock);
} while (changed);
/* Backward chaining block */
bb = dvmCompilerNewBB(kChainingCellBackwardBranch, cUnit->numBlocks++);
dvmInsertGrowableList(&cUnit->blockList, (intptr_t) bb);
cUnit->backChainBlock = bb;
/* A special block to host PC reconstruction code */
bb = dvmCompilerNewBB(kPCReconstruction, cUnit->numBlocks++);
dvmInsertGrowableList(&cUnit->blockList, (intptr_t) bb);
/* And one final block that publishes the PC and raises the exception */
bb = dvmCompilerNewBB(kExceptionHandling, cUnit->numBlocks++);
dvmInsertGrowableList(&cUnit->blockList, (intptr_t) bb);
cUnit->puntBlock = bb;
cUnit->numDalvikRegisters = cUnit->method->registersSize;
/* Verify if all blocks are connected as claimed */
/* FIXME - to be disabled in the future */
dvmCompilerDataFlowAnalysisDispatcher(cUnit, verifyPredInfo,
kAllNodes,
false /* isIterative */);
/* Try to identify a loop */
if (!dvmCompilerBuildLoop(cUnit))
goto bail;
dvmCompilerLoopOpt(cUnit);
/*
* Change the backward branch to the backward chaining cell after dataflow
* analsys/optimizations are done.
*/
dvmCompilerInsertBackwardChaining(cUnit);
dvmCompilerInitializeRegAlloc(cUnit);
/* Allocate Registers using simple local allocation scheme */
dvmCompilerLocalRegAlloc(cUnit);
/* Convert MIR to LIR, etc. */
dvmCompilerMIR2LIR(cUnit);
/* Loop contains never executed blocks / heavy instructions */
if (cUnit->quitLoopMode) {
if (cUnit->printMe || gDvmJit.receivedSIGUSR2) {
ALOGD("Loop trace @ offset %04x aborted due to unresolved code info",
cUnit->entryBlock->startOffset);
}
goto bail;
}
/* Convert LIR into machine code. Loop for recoverable retries */
do {
dvmCompilerAssembleLIR(cUnit, info);
cUnit->assemblerRetries++;
if (cUnit->printMe && cUnit->assemblerStatus != kSuccess)
ALOGD("Assembler abort #%d on %d", cUnit->assemblerRetries,
cUnit->assemblerStatus);
} while (cUnit->assemblerStatus == kRetryAll);
/* Loop is too big - bail out */
if (cUnit->assemblerStatus == kRetryHalve) {
goto bail;
}
if (cUnit->printMe || gDvmJit.receivedSIGUSR2) {
ALOGD("Loop trace @ offset %04x", cUnit->entryBlock->startOffset);
dvmCompilerCodegenDump(cUnit);
}
/*
* If this trace uses class objects as constants,
* dvmJitInstallClassObjectPointers will switch the thread state
* to running and look up the class pointers using the descriptor/loader
* tuple stored in the callsite info structure. We need to make this window
* as short as possible since it is blocking GC.
*/
if (cUnit->hasClassLiterals && info->codeAddress) {
dvmJitInstallClassObjectPointers(cUnit, (char *) info->codeAddress);
}
/*
* Since callsiteinfo is allocated from the arena, delay the reset until
* class pointers are resolved.
*/
dvmCompilerArenaReset();
assert(cUnit->assemblerStatus == kSuccess);
#if defined(WITH_JIT_TUNING)
/* Locate the entry to store compilation statistics for this method */
methodStats = dvmCompilerAnalyzeMethodBody(desc->method, false);
methodStats->nativeSize += cUnit->totalSize;
#endif
return info->codeAddress != NULL;
bail:
/* Retry the original trace with JIT_OPT_NO_LOOP disabled */
dvmCompilerArenaReset();
return dvmCompileTrace(desc, numMaxInsts, info, bailPtr,
optHints | JIT_OPT_NO_LOOP);
}
/*
* Main entry point to start trace compilation. Basic blocks are constructed
* first and they will be passed to the codegen routines to convert Dalvik
* bytecode into machine code.
*/
bool dvmCompileTrace(JitTraceDescription *desc, int numMaxInsts,
JitTranslationInfo *info, jmp_buf *bailPtr,
int optHints)
{
const DexCode *dexCode = dvmGetMethodCode(desc->method);
const JitTraceRun* currRun = &desc->trace[0];
unsigned int curOffset = currRun->info.frag.startOffset;
unsigned int startOffset = curOffset;
unsigned int numInsts = currRun->info.frag.numInsts;
const u2 *codePtr = dexCode->insns + curOffset;
int traceSize = 0; // # of half-words
const u2 *startCodePtr = codePtr;
BasicBlock *curBB, *entryCodeBB;
int numBlocks = 0;
static int compilationId;
CompilationUnit cUnit;
GrowableList *blockList;
#if defined(WITH_JIT_TUNING)
CompilerMethodStats *methodStats;
#endif
/* If we've already compiled this trace, just return success */
if (dvmJitGetTraceAddr(startCodePtr) && !info->discardResult) {
/*
* Make sure the codeAddress is NULL so that it won't clobber the
* existing entry.
*/
info->codeAddress = NULL;
return true;
}
/* If the work order is stale, discard it */
if (info->cacheVersion != gDvmJit.cacheVersion) {
return false;
}
compilationId++;
memset(&cUnit, 0, sizeof(CompilationUnit));
#if defined(WITH_JIT_TUNING)
/* Locate the entry to store compilation statistics for this method */
methodStats = dvmCompilerAnalyzeMethodBody(desc->method, false);
#endif
/* Set the recover buffer pointer */
cUnit.bailPtr = bailPtr;
/* Initialize the printMe flag */
cUnit.printMe = gDvmJit.printMe;
/* Setup the method */
cUnit.method = desc->method;
/* Store the trace descriptor and set the initial mode */
cUnit.traceDesc = desc;
cUnit.jitMode = kJitTrace;
/* Initialize the PC reconstruction list */
dvmInitGrowableList(&cUnit.pcReconstructionList, 8);
/* Initialize the basic block list */
blockList = &cUnit.blockList;
dvmInitGrowableList(blockList, 8);
/* Identify traces that we don't want to compile */
if (gDvmJit.methodTable) {
int len = strlen(desc->method->clazz->descriptor) +
strlen(desc->method->name) + 1;
char *fullSignature = (char *)dvmCompilerNew(len, true);
strcpy(fullSignature, desc->method->clazz->descriptor);
strcat(fullSignature, desc->method->name);
int hashValue = dvmComputeUtf8Hash(fullSignature);
/*
* Doing three levels of screening to see whether we want to skip
* compiling this method
*/
/* First, check the full "class;method" signature */
bool methodFound =
dvmHashTableLookup(gDvmJit.methodTable, hashValue,
fullSignature, (HashCompareFunc) strcmp,
false) !=
NULL;
/* Full signature not found - check the enclosing class */
if (methodFound == false) {
int hashValue = dvmComputeUtf8Hash(desc->method->clazz->descriptor);
methodFound =
dvmHashTableLookup(gDvmJit.methodTable, hashValue,
(char *) desc->method->clazz->descriptor,
(HashCompareFunc) strcmp, false) !=
NULL;
/* Enclosing class not found - check the method name */
if (methodFound == false) {
int hashValue = dvmComputeUtf8Hash(desc->method->name);
methodFound =
dvmHashTableLookup(gDvmJit.methodTable, hashValue,
(char *) desc->method->name,
(HashCompareFunc) strcmp, false) !=
NULL;
/*
* Debug by call-graph is enabled. Check if the debug list
* covers any methods on the VM stack.
*/
if (methodFound == false && gDvmJit.checkCallGraph == true) {
methodFound =
filterMethodByCallGraph(info->requestingThread,
desc->method->name);
}
}
}
/*
* Under the following conditions, the trace will be *conservatively*
* compiled by only containing single-step instructions to and from the
* interpreter.
* 1) If includeSelectedMethod == false, the method matches the full or
* partial signature stored in the hash table.
*
* 2) If includeSelectedMethod == true, the method does not match the
* full and partial signature stored in the hash table.
*/
if (gDvmJit.includeSelectedMethod != methodFound) {
cUnit.allSingleStep = true;
} else {
/* Compile the trace as normal */
/* Print the method we cherry picked */
if (gDvmJit.includeSelectedMethod == true) {
cUnit.printMe = true;
}
}
}
/* Allocate the entry block */
curBB = dvmCompilerNewBB(kEntryBlock, numBlocks++);
dvmInsertGrowableList(blockList, (intptr_t) curBB);
curBB->startOffset = curOffset;
entryCodeBB = dvmCompilerNewBB(kDalvikByteCode, numBlocks++);
dvmInsertGrowableList(blockList, (intptr_t) entryCodeBB);
entryCodeBB->startOffset = curOffset;
curBB->fallThrough = entryCodeBB;
curBB = entryCodeBB;
if (cUnit.printMe) {
ALOGD("--------\nCompiler: Building trace for %s, offset %#x",
desc->method->name, curOffset);
}
/*
* Analyze the trace descriptor and include up to the maximal number
* of Dalvik instructions into the IR.
*/
while (1) {
MIR *insn;
int width;
insn = (MIR *)dvmCompilerNew(sizeof(MIR), true);
insn->offset = curOffset;
width = parseInsn(codePtr, &insn->dalvikInsn, cUnit.printMe);
/* The trace should never incude instruction data */
assert(width);
insn->width = width;
traceSize += width;
dvmCompilerAppendMIR(curBB, insn);
cUnit.numInsts++;
int flags = dexGetFlagsFromOpcode(insn->dalvikInsn.opcode);
if (flags & kInstrInvoke) {
const Method *calleeMethod = (const Method *)
currRun[JIT_TRACE_CUR_METHOD].info.meta;
assert(numInsts == 1);
CallsiteInfo *callsiteInfo =
(CallsiteInfo *)dvmCompilerNew(sizeof(CallsiteInfo), true);
callsiteInfo->classDescriptor = (const char *)
currRun[JIT_TRACE_CLASS_DESC].info.meta;
callsiteInfo->classLoader = (Object *)
currRun[JIT_TRACE_CLASS_LOADER].info.meta;
callsiteInfo->method = calleeMethod;
insn->meta.callsiteInfo = callsiteInfo;
}
/* Instruction limit reached - terminate the trace here */
if (cUnit.numInsts >= numMaxInsts) {
break;
}
if (--numInsts == 0) {
if (currRun->info.frag.runEnd) {
break;
} else {
/* Advance to the next trace description (ie non-meta info) */
do {
currRun++;
} while (!currRun->isCode);
/* Dummy end-of-run marker seen */
if (currRun->info.frag.numInsts == 0) {
break;
}
curBB = dvmCompilerNewBB(kDalvikByteCode, numBlocks++);
dvmInsertGrowableList(blockList, (intptr_t) curBB);
curOffset = currRun->info.frag.startOffset;
numInsts = currRun->info.frag.numInsts;
curBB->startOffset = curOffset;
codePtr = dexCode->insns + curOffset;
}
} else {
curOffset += width;
codePtr += width;
}
}
#if defined(WITH_JIT_TUNING)
/* Convert # of half-word to bytes */
methodStats->compiledDalvikSize += traceSize * 2;
#endif
/*
* Now scan basic blocks containing real code to connect the
* taken/fallthrough links. Also create chaining cells for code not included
* in the trace.
*/
size_t blockId;
for (blockId = 0; blockId < blockList->numUsed; blockId++) {
curBB = (BasicBlock *) dvmGrowableListGetElement(blockList, blockId);
MIR *lastInsn = curBB->lastMIRInsn;
/* Skip empty blocks */
if (lastInsn == NULL) {
continue;
}
curOffset = lastInsn->offset;
unsigned int targetOffset = curOffset;
unsigned int fallThroughOffset = curOffset + lastInsn->width;
bool isInvoke = false;
const Method *callee = NULL;
findBlockBoundary(desc->method, curBB->lastMIRInsn, curOffset,
&targetOffset, &isInvoke, &callee);
/* Link the taken and fallthrough blocks */
BasicBlock *searchBB;
int flags = dexGetFlagsFromOpcode(lastInsn->dalvikInsn.opcode);
if (flags & kInstrInvoke) {
cUnit.hasInvoke = true;
}
/* Backward branch seen */
if (isInvoke == false &&
(flags & kInstrCanBranch) != 0 &&
targetOffset < curOffset &&
(optHints & JIT_OPT_NO_LOOP) == 0) {
dvmCompilerArenaReset();
return compileLoop(&cUnit, startOffset, desc, numMaxInsts,
info, bailPtr, optHints);
}
/* No backward branch in the trace - start searching the next BB */
size_t searchBlockId;
for (searchBlockId = blockId+1; searchBlockId < blockList->numUsed;
searchBlockId++) {
searchBB = (BasicBlock *) dvmGrowableListGetElement(blockList,
searchBlockId);
if (targetOffset == searchBB->startOffset) {
curBB->taken = searchBB;
dvmCompilerSetBit(searchBB->predecessors, curBB->id);
}
if (fallThroughOffset == searchBB->startOffset) {
curBB->fallThrough = searchBB;
dvmCompilerSetBit(searchBB->predecessors, curBB->id);
/*
* Fallthrough block of an invoke instruction needs to be
* aligned to 4-byte boundary (alignment instruction to be
* inserted later.
*/
if (flags & kInstrInvoke) {
searchBB->isFallThroughFromInvoke = true;
}
}
}
/*
* Some blocks are ended by non-control-flow-change instructions,
* currently only due to trace length constraint. In this case we need
* to generate an explicit branch at the end of the block to jump to
* the chaining cell.
*/
curBB->needFallThroughBranch =
((flags & (kInstrCanBranch | kInstrCanSwitch | kInstrCanReturn |
kInstrInvoke)) == 0);
if (lastInsn->dalvikInsn.opcode == OP_PACKED_SWITCH ||
lastInsn->dalvikInsn.opcode == OP_SPARSE_SWITCH) {
int i;
const u2 *switchData = desc->method->insns + lastInsn->offset +
lastInsn->dalvikInsn.vB;
int size = switchData[1];
int maxChains = MIN(size, MAX_CHAINED_SWITCH_CASES);
/*
* Generate the landing pad for cases whose ranks are higher than
* MAX_CHAINED_SWITCH_CASES. The code will re-enter the interpreter
* through the NoChain point.
*/
if (maxChains != size) {
cUnit.switchOverflowPad =
desc->method->insns + lastInsn->offset;
}
s4 *targets = (s4 *) (switchData + 2 +
(lastInsn->dalvikInsn.opcode == OP_PACKED_SWITCH ?
2 : size * 2));
/* One chaining cell for the first MAX_CHAINED_SWITCH_CASES cases */
for (i = 0; i < maxChains; i++) {
BasicBlock *caseChain = dvmCompilerNewBB(kChainingCellNormal,
numBlocks++);
dvmInsertGrowableList(blockList, (intptr_t) caseChain);
caseChain->startOffset = lastInsn->offset + targets[i];
}
/* One more chaining cell for the default case */
BasicBlock *caseChain = dvmCompilerNewBB(kChainingCellNormal,
numBlocks++);
dvmInsertGrowableList(blockList, (intptr_t) caseChain);
caseChain->startOffset = lastInsn->offset + lastInsn->width;
/* Fallthrough block not included in the trace */
} else if (!isUnconditionalBranch(lastInsn) &&
curBB->fallThrough == NULL) {
BasicBlock *fallThroughBB;
/*
* If the chaining cell is after an invoke or
* instruction that cannot change the control flow, request a hot
* chaining cell.
*/
if (isInvoke || curBB->needFallThroughBranch) {
fallThroughBB = dvmCompilerNewBB(kChainingCellHot, numBlocks++);
} else {
fallThroughBB = dvmCompilerNewBB(kChainingCellNormal,
numBlocks++);
}
dvmInsertGrowableList(blockList, (intptr_t) fallThroughBB);
fallThroughBB->startOffset = fallThroughOffset;
curBB->fallThrough = fallThroughBB;
dvmCompilerSetBit(fallThroughBB->predecessors, curBB->id);
}
/* Target block not included in the trace */
if (curBB->taken == NULL &&
(isGoto(lastInsn) || isInvoke ||
(targetOffset != UNKNOWN_TARGET && targetOffset != curOffset))) {
BasicBlock *newBB = NULL;
if (isInvoke) {
/* Monomorphic callee */
if (callee) {
/* JNI call doesn't need a chaining cell */
if (!dvmIsNativeMethod(callee)) {
newBB = dvmCompilerNewBB(kChainingCellInvokeSingleton,
numBlocks++);
newBB->startOffset = 0;
newBB->containingMethod = callee;
}
/* Will resolve at runtime */
} else {
newBB = dvmCompilerNewBB(kChainingCellInvokePredicted,
numBlocks++);
newBB->startOffset = 0;
}
/* For unconditional branches, request a hot chaining cell */
} else {
#if !defined(WITH_SELF_VERIFICATION)
newBB = dvmCompilerNewBB(dexIsGoto(flags) ?
kChainingCellHot :
kChainingCellNormal,
numBlocks++);
newBB->startOffset = targetOffset;
#else
/* Handle branches that branch back into the block */
if (targetOffset >= curBB->firstMIRInsn->offset &&
targetOffset <= curBB->lastMIRInsn->offset) {
newBB = dvmCompilerNewBB(kChainingCellBackwardBranch,
numBlocks++);
} else {
newBB = dvmCompilerNewBB(dexIsGoto(flags) ?
kChainingCellHot :
kChainingCellNormal,
numBlocks++);
}
newBB->startOffset = targetOffset;
#endif
}
if (newBB) {
curBB->taken = newBB;
dvmCompilerSetBit(newBB->predecessors, curBB->id);
dvmInsertGrowableList(blockList, (intptr_t) newBB);
}
}
}
/* Now create a special block to host PC reconstruction code */
curBB = dvmCompilerNewBB(kPCReconstruction, numBlocks++);
dvmInsertGrowableList(blockList, (intptr_t) curBB);
/* And one final block that publishes the PC and raise the exception */
curBB = dvmCompilerNewBB(kExceptionHandling, numBlocks++);
dvmInsertGrowableList(blockList, (intptr_t) curBB);
cUnit.puntBlock = curBB;
if (cUnit.printMe) {
char* signature =
dexProtoCopyMethodDescriptor(&desc->method->prototype);
ALOGD("TRACEINFO (%d): 0x%08x %s%s.%s %#x %d of %d, %d blocks",
compilationId,
(intptr_t) desc->method->insns,
desc->method->clazz->descriptor,
desc->method->name,
signature,
desc->trace[0].info.frag.startOffset,
traceSize,
dexCode->insnsSize,
numBlocks);
free(signature);
}
cUnit.numBlocks = numBlocks;
/* Set the instruction set to use (NOTE: later components may change it) */
cUnit.instructionSet = dvmCompilerInstructionSet();
/* Inline transformation @ the MIR level */
if (cUnit.hasInvoke && !(gDvmJit.disableOpt & (1 << kMethodInlining))) {
dvmCompilerInlineMIR(&cUnit, info);
}
cUnit.numDalvikRegisters = cUnit.method->registersSize;
/* Preparation for SSA conversion */
dvmInitializeSSAConversion(&cUnit);
dvmCompilerNonLoopAnalysis(&cUnit);
dvmCompilerInitializeRegAlloc(&cUnit); // Needs to happen after SSA naming
if (cUnit.printMe) {
dvmCompilerDumpCompilationUnit(&cUnit);
}
/* Allocate Registers using simple local allocation scheme */
dvmCompilerLocalRegAlloc(&cUnit);
/* Convert MIR to LIR, etc. */
dvmCompilerMIR2LIR(&cUnit);
/* Convert LIR into machine code. Loop for recoverable retries */
do {
dvmCompilerAssembleLIR(&cUnit, info);
cUnit.assemblerRetries++;
if (cUnit.printMe && cUnit.assemblerStatus != kSuccess)
ALOGD("Assembler abort #%d on %d",cUnit.assemblerRetries,
cUnit.assemblerStatus);
} while (cUnit.assemblerStatus == kRetryAll);
if (cUnit.printMe) {
ALOGD("Trace Dalvik PC: %p", startCodePtr);
dvmCompilerCodegenDump(&cUnit);
ALOGD("End %s%s, %d Dalvik instructions",
desc->method->clazz->descriptor, desc->method->name,
cUnit.numInsts);
}
if (cUnit.assemblerStatus == kRetryHalve) {
/* Reset the compiler resource pool before retry */
dvmCompilerArenaReset();
/* Halve the instruction count and start from the top */
return dvmCompileTrace(desc, cUnit.numInsts / 2, info, bailPtr,
optHints);
}
/*
* If this trace uses class objects as constants,
* dvmJitInstallClassObjectPointers will switch the thread state
* to running and look up the class pointers using the descriptor/loader
* tuple stored in the callsite info structure. We need to make this window
* as short as possible since it is blocking GC.
*/
if (cUnit.hasClassLiterals && info->codeAddress) {
dvmJitInstallClassObjectPointers(&cUnit, (char *) info->codeAddress);
}
/*
* Since callsiteinfo is allocated from the arena, delay the reset until
* class pointers are resolved.
*/
dvmCompilerArenaReset();
assert(cUnit.assemblerStatus == kSuccess);
#if defined(WITH_JIT_TUNING)
methodStats->nativeSize += cUnit.totalSize;
#endif
return info->codeAddress != NULL;
}