/* * Copyright (C) 2011 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" /* Enter the node to the dfsOrder list then visit its successors */ STATIC void recordDFSPreOrder(CompilationUnit* cUnit, BasicBlock* block) { if (block->visited || block->hidden) return; block->visited = true; /* Enqueue the block id */ oatInsertGrowableList(&cUnit->dfsOrder, block->id); if (block->fallThrough) recordDFSPreOrder(cUnit, block->fallThrough); if (block->taken) recordDFSPreOrder(cUnit, block->taken); if (block->successorBlockList.blockListType != kNotUsed) { GrowableListIterator iterator; oatGrowableListIteratorInit(&block->successorBlockList.blocks, &iterator); while (true) { SuccessorBlockInfo *successorBlockInfo = (SuccessorBlockInfo *) oatGrowableListIteratorNext(&iterator); if (successorBlockInfo == NULL) break; BasicBlock* succBB = successorBlockInfo->block; recordDFSPreOrder(cUnit, succBB); } } return; } /* Sort the blocks by the Depth-First-Search pre-order */ STATIC void computeDFSOrder(CompilationUnit* cUnit) { /* Initialize or reset the DFS order list */ if (cUnit->dfsOrder.elemList == NULL) { oatInitGrowableList(&cUnit->dfsOrder, cUnit->numBlocks); } else { /* Just reset the used length on the counter */ cUnit->dfsOrder.numUsed = 0; } oatDataFlowAnalysisDispatcher(cUnit, oatClearVisitedFlag, kAllNodes, false /* isIterative */); recordDFSPreOrder(cUnit, cUnit->entryBlock); cUnit->numReachableBlocks = cUnit->dfsOrder.numUsed; } /* * Mark block bit on the per-Dalvik register vector to denote that Dalvik * register idx is defined in BasicBlock bb. */ STATIC bool fillDefBlockMatrix(CompilationUnit* cUnit, BasicBlock* bb) { if (bb->dataFlowInfo == NULL) return false; ArenaBitVectorIterator iterator; oatBitVectorIteratorInit(bb->dataFlowInfo->defV, &iterator); while (true) { int idx = oatBitVectorIteratorNext(&iterator); if (idx == -1) break; /* Block bb defines register idx */ oatSetBit(cUnit->defBlockMatrix[idx], bb->id); } return true; } STATIC void computeDefBlockMatrix(CompilationUnit* cUnit) { int numRegisters = cUnit->numDalvikRegisters; /* Allocate numDalvikRegisters bit vector pointers */ cUnit->defBlockMatrix = (ArenaBitVector **) oatNew(sizeof(ArenaBitVector *) * numRegisters, true); int i; /* Initialize numRegister vectors with numBlocks bits each */ for (i = 0; i < numRegisters; i++) { cUnit->defBlockMatrix[i] = oatAllocBitVector(cUnit->numBlocks, false); } oatDataFlowAnalysisDispatcher(cUnit, oatFindLocalLiveIn, kAllNodes, false /* isIterative */); oatDataFlowAnalysisDispatcher(cUnit, fillDefBlockMatrix, kAllNodes, false /* isIterative */); /* * Also set the incoming parameters as defs in the entry block. * Only need to handle the parameters for the outer method. */ int inReg = cUnit->method->NumRegisters() - cUnit->method->NumIns(); for (; inReg < cUnit->method->NumRegisters(); inReg++) { oatSetBit(cUnit->defBlockMatrix[inReg], cUnit->entryBlock->id); } } /* Compute the post-order traversal of the CFG */ STATIC void computeDomPostOrderTraversal(CompilationUnit* cUnit, BasicBlock* bb) { ArenaBitVectorIterator bvIterator; oatBitVectorIteratorInit(bb->iDominated, &bvIterator); GrowableList* blockList = &cUnit->blockList; /* Iterate through the dominated blocks first */ while (true) { int bbIdx = oatBitVectorIteratorNext(&bvIterator); if (bbIdx == -1) break; BasicBlock* dominatedBB = (BasicBlock* ) oatGrowableListGetElement(blockList, bbIdx); computeDomPostOrderTraversal(cUnit, dominatedBB); } /* Enter the current block id */ oatInsertGrowableList(&cUnit->domPostOrderTraversal, bb->id); /* hacky loop detection */ if (bb->taken && oatIsBitSet(bb->dominators, bb->taken->id)) { cUnit->hasLoop = true; } } STATIC void checkForDominanceFrontier(BasicBlock* domBB, const BasicBlock* succBB) { /* * TODO - evaluate whether phi will ever need to be inserted into exit * blocks. */ if (succBB->iDom != domBB && succBB->blockType == kDalvikByteCode && succBB->hidden == false) { oatSetBit(domBB->domFrontier, succBB->id); } } /* Worker function to compute the dominance frontier */ STATIC bool computeDominanceFrontier(CompilationUnit* cUnit, BasicBlock* bb) { GrowableList* blockList = &cUnit->blockList; /* Calculate DF_local */ if (bb->taken) { checkForDominanceFrontier(bb, bb->taken); } if (bb->fallThrough) { checkForDominanceFrontier(bb, bb->fallThrough); } if (bb->successorBlockList.blockListType != kNotUsed) { GrowableListIterator iterator; oatGrowableListIteratorInit(&bb->successorBlockList.blocks, &iterator); while (true) { SuccessorBlockInfo *successorBlockInfo = (SuccessorBlockInfo *) oatGrowableListIteratorNext(&iterator); if (successorBlockInfo == NULL) break; BasicBlock* succBB = successorBlockInfo->block; checkForDominanceFrontier(bb, succBB); } } /* Calculate DF_up */ ArenaBitVectorIterator bvIterator; oatBitVectorIteratorInit(bb->iDominated, &bvIterator); while (true) { int dominatedIdx = oatBitVectorIteratorNext(&bvIterator); if (dominatedIdx == -1) break; BasicBlock* dominatedBB = (BasicBlock* ) oatGrowableListGetElement(blockList, dominatedIdx); ArenaBitVectorIterator dfIterator; oatBitVectorIteratorInit(dominatedBB->domFrontier, &dfIterator); while (true) { int dfUpIdx = oatBitVectorIteratorNext(&dfIterator); if (dfUpIdx == -1) break; BasicBlock* dfUpBlock = (BasicBlock* ) oatGrowableListGetElement(blockList, dfUpIdx); checkForDominanceFrontier(bb, dfUpBlock); } } return true; } /* Worker function for initializing domination-related data structures */ STATIC bool initializeDominationInfo(CompilationUnit* cUnit, BasicBlock* bb) { int numTotalBlocks = cUnit->blockList.numUsed; if (bb->dominators == NULL ) { bb->dominators = oatAllocBitVector(numTotalBlocks, false /* expandable */); bb->iDominated = oatAllocBitVector(numTotalBlocks, false /* expandable */); bb->domFrontier = oatAllocBitVector(numTotalBlocks, false /* expandable */); } else { oatClearAllBits(bb->dominators); oatClearAllBits(bb->iDominated); oatClearAllBits(bb->domFrontier); } /* Set all bits in the dominator vector */ oatSetInitialBits(bb->dominators, numTotalBlocks); return true; } /* Worker function to compute each block's dominators */ STATIC bool computeBlockDominators(CompilationUnit* cUnit, BasicBlock* bb) { GrowableList* blockList = &cUnit->blockList; int numTotalBlocks = blockList->numUsed; ArenaBitVector* tempBlockV = cUnit->tempBlockV; ArenaBitVectorIterator bvIterator; /* * The dominator of the entry block has been preset to itself and we need * to skip the calculation here. */ if (bb == cUnit->entryBlock) return false; oatSetInitialBits(tempBlockV, numTotalBlocks); /* Iterate through the predecessors */ oatBitVectorIteratorInit(bb->predecessors, &bvIterator); while (true) { int predIdx = oatBitVectorIteratorNext(&bvIterator); if (predIdx == -1) break; BasicBlock* predBB = (BasicBlock* ) oatGrowableListGetElement( blockList, predIdx); /* tempBlockV = tempBlockV ^ dominators */ if (predBB->dominators != NULL) { oatIntersectBitVectors(tempBlockV, tempBlockV, predBB->dominators); } } oatSetBit(tempBlockV, bb->id); if (oatCompareBitVectors(tempBlockV, bb->dominators)) { oatCopyBitVector(bb->dominators, tempBlockV); return true; } return false; } /* Worker function to compute the idom */ STATIC bool computeImmediateDominator(CompilationUnit* cUnit, BasicBlock* bb) { GrowableList* blockList = &cUnit->blockList; ArenaBitVector* tempBlockV = cUnit->tempBlockV; ArenaBitVectorIterator bvIterator; BasicBlock* iDom; if (bb == cUnit->entryBlock) return false; oatCopyBitVector(tempBlockV, bb->dominators); oatClearBit(tempBlockV, bb->id); oatBitVectorIteratorInit(tempBlockV, &bvIterator); /* Should not see any dead block */ DCHECK_NE(oatCountSetBits(tempBlockV), 0); if (oatCountSetBits(tempBlockV) == 1) { iDom = (BasicBlock* ) oatGrowableListGetElement( blockList, oatBitVectorIteratorNext(&bvIterator)); bb->iDom = iDom; } else { int iDomIdx = oatBitVectorIteratorNext(&bvIterator); DCHECK_NE(iDomIdx, -1); while (true) { int nextDom = oatBitVectorIteratorNext(&bvIterator); if (nextDom == -1) break; BasicBlock* nextDomBB = (BasicBlock* ) oatGrowableListGetElement(blockList, nextDom); /* iDom dominates nextDom - set new iDom */ if (oatIsBitSet(nextDomBB->dominators, iDomIdx)) { iDomIdx = nextDom; } } iDom = (BasicBlock* ) oatGrowableListGetElement(blockList, iDomIdx); /* Set the immediate dominator block for bb */ bb->iDom = iDom; } /* Add bb to the iDominated set of the immediate dominator block */ oatSetBit(iDom->iDominated, bb->id); return true; } /* Compute dominators, immediate dominator, and dominance fronter */ STATIC void computeDominators(CompilationUnit* cUnit) { int numReachableBlocks = cUnit->numReachableBlocks; int numTotalBlocks = cUnit->blockList.numUsed; /* Initialize domination-related data structures */ oatDataFlowAnalysisDispatcher(cUnit, initializeDominationInfo, kReachableNodes, false /* isIterative */); /* Set the dominator for the root node */ oatClearAllBits(cUnit->entryBlock->dominators); oatSetBit(cUnit->entryBlock->dominators, cUnit->entryBlock->id); if (cUnit->tempBlockV == NULL) { cUnit->tempBlockV = oatAllocBitVector(numTotalBlocks, false /* expandable */); } else { oatClearAllBits(cUnit->tempBlockV); } oatDataFlowAnalysisDispatcher(cUnit, computeBlockDominators, kPreOrderDFSTraversal, true /* isIterative */); cUnit->entryBlock->iDom = NULL; oatDataFlowAnalysisDispatcher(cUnit, computeImmediateDominator, kReachableNodes, false /* isIterative */); /* * Now go ahead and compute the post order traversal based on the * iDominated sets. */ if (cUnit->domPostOrderTraversal.elemList == NULL) { oatInitGrowableList(&cUnit->domPostOrderTraversal, numReachableBlocks); } else { cUnit->domPostOrderTraversal.numUsed = 0; } computeDomPostOrderTraversal(cUnit, cUnit->entryBlock); DCHECK_EQ(cUnit->domPostOrderTraversal.numUsed, (unsigned) cUnit->numReachableBlocks); /* Now compute the dominance frontier for each block */ oatDataFlowAnalysisDispatcher(cUnit, computeDominanceFrontier, kPostOrderDOMTraversal, false /* isIterative */); } /* * Perform dest U= src1 ^ ~src2 * This is probably not general enough to be placed in BitVector.[ch]. */ STATIC void computeSuccLiveIn(ArenaBitVector* dest, const ArenaBitVector* src1, const ArenaBitVector* src2) { if (dest->storageSize != src1->storageSize || dest->storageSize != src2->storageSize || dest->expandable != src1->expandable || dest->expandable != src2->expandable) { LOG(FATAL) << "Incompatible set properties"; } unsigned int idx; for (idx = 0; idx < dest->storageSize; idx++) { dest->storage[idx] |= src1->storage[idx] & ~src2->storage[idx]; } } /* * Iterate through all successor blocks and propagate up the live-in sets. * The calculated result is used for phi-node pruning - where we only need to * insert a phi node if the variable is live-in to the block. */ STATIC bool computeBlockLiveIns(CompilationUnit* cUnit, BasicBlock* bb) { ArenaBitVector* tempDalvikRegisterV = cUnit->tempDalvikRegisterV; if (bb->dataFlowInfo == NULL) return false; oatCopyBitVector(tempDalvikRegisterV, bb->dataFlowInfo->liveInV); if (bb->taken && bb->taken->dataFlowInfo) computeSuccLiveIn(tempDalvikRegisterV, bb->taken->dataFlowInfo->liveInV, bb->dataFlowInfo->defV); if (bb->fallThrough && bb->fallThrough->dataFlowInfo) computeSuccLiveIn(tempDalvikRegisterV, bb->fallThrough->dataFlowInfo->liveInV, bb->dataFlowInfo->defV); if (bb->successorBlockList.blockListType != kNotUsed) { GrowableListIterator iterator; oatGrowableListIteratorInit(&bb->successorBlockList.blocks, &iterator); while (true) { SuccessorBlockInfo *successorBlockInfo = (SuccessorBlockInfo *) oatGrowableListIteratorNext(&iterator); if (successorBlockInfo == NULL) break; BasicBlock* succBB = successorBlockInfo->block; if (succBB->dataFlowInfo) { computeSuccLiveIn(tempDalvikRegisterV, succBB->dataFlowInfo->liveInV, bb->dataFlowInfo->defV); } } } if (oatCompareBitVectors(tempDalvikRegisterV, bb->dataFlowInfo->liveInV)) { oatCopyBitVector(bb->dataFlowInfo->liveInV, tempDalvikRegisterV); return true; } return false; } /* Insert phi nodes to for each variable to the dominance frontiers */ STATIC void insertPhiNodes(CompilationUnit* cUnit) { int dalvikReg; const GrowableList* blockList = &cUnit->blockList; ArenaBitVector* phiBlocks = oatAllocBitVector(cUnit->numBlocks, false); ArenaBitVector* tmpBlocks = oatAllocBitVector(cUnit->numBlocks, false); ArenaBitVector* inputBlocks = oatAllocBitVector(cUnit->numBlocks, false); cUnit->tempDalvikRegisterV = oatAllocBitVector(cUnit->numDalvikRegisters, false); oatDataFlowAnalysisDispatcher(cUnit, computeBlockLiveIns, kPostOrderDFSTraversal, true /* isIterative */); /* Iterate through each Dalvik register */ for (dalvikReg = 0; dalvikReg < cUnit->numDalvikRegisters; dalvikReg++) { bool change; ArenaBitVectorIterator iterator; oatCopyBitVector(inputBlocks, cUnit->defBlockMatrix[dalvikReg]); oatClearAllBits(phiBlocks); /* Calculate the phi blocks for each Dalvik register */ do { change = false; oatClearAllBits(tmpBlocks); oatBitVectorIteratorInit(inputBlocks, &iterator); while (true) { int idx = oatBitVectorIteratorNext(&iterator); if (idx == -1) break; BasicBlock* defBB = (BasicBlock* ) oatGrowableListGetElement(blockList, idx); /* Merge the dominance frontier to tmpBlocks */ if (defBB->domFrontier != NULL) { oatUnifyBitVectors(tmpBlocks, tmpBlocks, defBB->domFrontier); } } if (oatCompareBitVectors(phiBlocks, tmpBlocks)) { change = true; oatCopyBitVector(phiBlocks, tmpBlocks); /* * Iterate through the original blocks plus the new ones in * the dominance frontier. */ oatCopyBitVector(inputBlocks, phiBlocks); oatUnifyBitVectors(inputBlocks, inputBlocks, cUnit->defBlockMatrix[dalvikReg]); } } while (change); /* * Insert a phi node for dalvikReg in the phiBlocks if the Dalvik * register is in the live-in set. */ oatBitVectorIteratorInit(phiBlocks, &iterator); while (true) { int idx = oatBitVectorIteratorNext(&iterator); if (idx == -1) break; BasicBlock* phiBB = (BasicBlock* ) oatGrowableListGetElement(blockList, idx); /* Variable will be clobbered before being used - no need for phi */ if (!oatIsBitSet(phiBB->dataFlowInfo->liveInV, dalvikReg)) continue; MIR *phi = (MIR *) oatNew(sizeof(MIR), true); phi->dalvikInsn.opcode = (Opcode)kMirOpPhi; phi->dalvikInsn.vA = dalvikReg; phi->offset = phiBB->startOffset; phi->meta.phiNext = cUnit->phiList; cUnit->phiList = phi; oatPrependMIR(phiBB, phi); } } } /* * Worker function to insert phi-operands with latest SSA names from * predecessor blocks */ STATIC bool insertPhiNodeOperands(CompilationUnit* cUnit, BasicBlock* bb) { ArenaBitVector* ssaRegV = cUnit->tempSSARegisterV; ArenaBitVectorIterator bvIterator; GrowableList* blockList = &cUnit->blockList; MIR *mir; /* Phi nodes are at the beginning of each block */ for (mir = bb->firstMIRInsn; mir; mir = mir->next) { if (mir->dalvikInsn.opcode != (Opcode)kMirOpPhi) return true; int ssaReg = mir->ssaRep->defs[0]; int encodedDalvikValue = (int) oatGrowableListGetElement(cUnit->ssaToDalvikMap, ssaReg); int dalvikReg = DECODE_REG(encodedDalvikValue); oatClearAllBits(ssaRegV); /* Iterate through the predecessors */ oatBitVectorIteratorInit(bb->predecessors, &bvIterator); while (true) { int predIdx = oatBitVectorIteratorNext(&bvIterator); if (predIdx == -1) break; BasicBlock* predBB = (BasicBlock* ) oatGrowableListGetElement( blockList, predIdx); int encodedSSAValue = predBB->dataFlowInfo->dalvikToSSAMap[dalvikReg]; int ssaReg = DECODE_REG(encodedSSAValue); oatSetBit(ssaRegV, ssaReg); } /* Count the number of SSA registers for a Dalvik register */ int numUses = oatCountSetBits(ssaRegV); mir->ssaRep->numUses = numUses; mir->ssaRep->uses = (int *) oatNew(sizeof(int) * numUses, false); mir->ssaRep->fpUse = (bool *) oatNew(sizeof(bool) * numUses, true); ArenaBitVectorIterator phiIterator; oatBitVectorIteratorInit(ssaRegV, &phiIterator); int *usePtr = mir->ssaRep->uses; /* Set the uses array for the phi node */ while (true) { int ssaRegIdx = oatBitVectorIteratorNext(&phiIterator); if (ssaRegIdx == -1) break; *usePtr++ = ssaRegIdx; } } return true; } STATIC void doDFSPreOrderSSARename(CompilationUnit* cUnit, BasicBlock* block) { if (block->visited || block->hidden) return; block->visited = true; /* Process this block */ oatDoSSAConversion(cUnit, block); int mapSize = sizeof(int) * cUnit->method->NumRegisters(); /* Save SSA map snapshot */ int* savedSSAMap = (int*)oatNew(mapSize, false); memcpy(savedSSAMap, cUnit->dalvikToSSAMap, mapSize); if (block->fallThrough) { doDFSPreOrderSSARename(cUnit, block->fallThrough); /* Restore SSA map snapshot */ memcpy(cUnit->dalvikToSSAMap, savedSSAMap, mapSize); } if (block->taken) { doDFSPreOrderSSARename(cUnit, block->taken); /* Restore SSA map snapshot */ memcpy(cUnit->dalvikToSSAMap, savedSSAMap, mapSize); } if (block->successorBlockList.blockListType != kNotUsed) { GrowableListIterator iterator; oatGrowableListIteratorInit(&block->successorBlockList.blocks, &iterator); while (true) { SuccessorBlockInfo *successorBlockInfo = (SuccessorBlockInfo *) oatGrowableListIteratorNext(&iterator); if (successorBlockInfo == NULL) break; BasicBlock* succBB = successorBlockInfo->block; doDFSPreOrderSSARename(cUnit, succBB); /* Restore SSA map snapshot */ memcpy(cUnit->dalvikToSSAMap, savedSSAMap, mapSize); } } cUnit->dalvikToSSAMap = savedSSAMap; return; } /* Perform SSA transformation for the whole method */ void oatMethodSSATransformation(CompilationUnit* cUnit) { /* Compute the DFS order */ computeDFSOrder(cUnit); /* Compute the dominator info */ computeDominators(cUnit); /* Allocate data structures in preparation for SSA conversion */ oatInitializeSSAConversion(cUnit); /* Find out the "Dalvik reg def x block" relation */ computeDefBlockMatrix(cUnit); /* Insert phi nodes to dominance frontiers for all variables */ insertPhiNodes(cUnit); /* Rename register names by local defs and phi nodes */ oatDataFlowAnalysisDispatcher(cUnit, oatClearVisitedFlag, kAllNodes, false /* isIterative */); doDFSPreOrderSSARename(cUnit, cUnit->entryBlock); /* * Shared temp bit vector used by each block to count the number of defs * from all the predecessor blocks. */ cUnit->tempSSARegisterV = oatAllocBitVector(cUnit->numSSARegs, false); /* Insert phi-operands with latest SSA names from predecessor blocks */ oatDataFlowAnalysisDispatcher(cUnit, insertPhiNodeOperands, kReachableNodes, false /* isIterative */); }