/* * 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 "vm/compiler/CompilerInternals.h" #include "MipsLIR.h" #include "Codegen.h" #define DEBUG_OPT(X) /* Check RAW, WAR, and WAR dependency on the register operands */ #define CHECK_REG_DEP(use, def, check) ((def & check->useMask) || \ ((use | def) & check->defMask)) /* Scheduler heuristics */ #define MAX_HOIST_DISTANCE 20 #define LDLD_DISTANCE 4 #define LD_LATENCY 2 static inline bool isDalvikRegisterClobbered(MipsLIR *lir1, MipsLIR *lir2) { int reg1Lo = DECODE_ALIAS_INFO_REG(lir1->aliasInfo); int reg1Hi = reg1Lo + DECODE_ALIAS_INFO_WIDE(lir1->aliasInfo); int reg2Lo = DECODE_ALIAS_INFO_REG(lir2->aliasInfo); int reg2Hi = reg2Lo + DECODE_ALIAS_INFO_WIDE(lir2->aliasInfo); return (reg1Lo == reg2Lo) || (reg1Lo == reg2Hi) || (reg1Hi == reg2Lo); } #if 0 /* Debugging utility routine */ static void dumpDependentInsnPair(MipsLIR *thisLIR, MipsLIR *checkLIR, const char *optimization) { LOGD("************ %s ************", optimization); dvmDumpLIRInsn((LIR *) thisLIR, 0); dvmDumpLIRInsn((LIR *) checkLIR, 0); } #endif /* Convert a more expensive instruction (ie load) into a move */ static void convertMemOpIntoMove(CompilationUnit *cUnit, MipsLIR *origLIR, int dest, int src) { /* Insert a move to replace the load */ MipsLIR *moveLIR; moveLIR = dvmCompilerRegCopyNoInsert( cUnit, dest, src); /* * Insert the converted instruction after the original since the * optimization is scannng in the top-down order and the new instruction * will need to be re-checked (eg the new dest clobbers the src used in * thisLIR). */ dvmCompilerInsertLIRAfter((LIR *) origLIR, (LIR *) moveLIR); } /* * Perform a pass of top-down walk, from the second-last instruction in the * superblock, to eliminate redundant loads and stores. * * An earlier load can eliminate a later load iff * 1) They are must-aliases * 2) The native register is not clobbered in between * 3) The memory location is not written to in between * * An earlier store can eliminate a later load iff * 1) They are must-aliases * 2) The native register is not clobbered in between * 3) The memory location is not written to in between * * A later store can be eliminated by an earlier store iff * 1) They are must-aliases * 2) The memory location is not written to in between */ static void applyLoadStoreElimination(CompilationUnit *cUnit, MipsLIR *headLIR, MipsLIR *tailLIR) { MipsLIR *thisLIR; if (headLIR == tailLIR) return; for (thisLIR = PREV_LIR(tailLIR); thisLIR != headLIR; thisLIR = PREV_LIR(thisLIR)) { int sinkDistance = 0; /* Skip non-interesting instructions */ if ((thisLIR->flags.isNop == true) || isPseudoOpCode(thisLIR->opcode) || !(EncodingMap[thisLIR->opcode].flags & (IS_LOAD | IS_STORE))) { continue; } int nativeRegId = thisLIR->operands[0]; bool isThisLIRLoad = EncodingMap[thisLIR->opcode].flags & IS_LOAD; MipsLIR *checkLIR; /* Use the mem mask to determine the rough memory location */ u8 thisMemMask = (thisLIR->useMask | thisLIR->defMask) & ENCODE_MEM; /* * Currently only eliminate redundant ld/st for constant and Dalvik * register accesses. */ if (!(thisMemMask & (ENCODE_LITERAL | ENCODE_DALVIK_REG))) continue; /* * Add r15 (pc) to the resource mask to prevent this instruction * from sinking past branch instructions. Also take out the memory * region bits since stopMask is used to check data/control * dependencies. */ u8 stopUseRegMask = (ENCODE_REG_PC | thisLIR->useMask) & ~ENCODE_MEM; u8 stopDefRegMask = thisLIR->defMask & ~ENCODE_MEM; for (checkLIR = NEXT_LIR(thisLIR); checkLIR != tailLIR; checkLIR = NEXT_LIR(checkLIR)) { /* * Skip already dead instructions (whose dataflow information is * outdated and misleading). */ if (checkLIR->flags.isNop) continue; u8 checkMemMask = (checkLIR->useMask | checkLIR->defMask) & ENCODE_MEM; u8 aliasCondition = thisMemMask & checkMemMask; bool stopHere = false; /* * Potential aliases seen - check the alias relations */ if (checkMemMask != ENCODE_MEM && aliasCondition != 0) { bool isCheckLIRLoad = EncodingMap[checkLIR->opcode].flags & IS_LOAD; if (aliasCondition == ENCODE_LITERAL) { /* * Should only see literal loads in the instruction * stream. */ assert(!(EncodingMap[checkLIR->opcode].flags & IS_STORE)); /* Same value && same register type */ if (checkLIR->aliasInfo == thisLIR->aliasInfo && REGTYPE(checkLIR->operands[0]) == REGTYPE(nativeRegId)){ /* * Different destination register - insert * a move */ if (checkLIR->operands[0] != nativeRegId) { convertMemOpIntoMove(cUnit, checkLIR, checkLIR->operands[0], nativeRegId); } checkLIR->flags.isNop = true; } } else if (aliasCondition == ENCODE_DALVIK_REG) { /* Must alias */ if (checkLIR->aliasInfo == thisLIR->aliasInfo) { /* Only optimize compatible registers */ bool regCompatible = REGTYPE(checkLIR->operands[0]) == REGTYPE(nativeRegId); if ((isThisLIRLoad && isCheckLIRLoad) || (!isThisLIRLoad && isCheckLIRLoad)) { /* RAR or RAW */ if (regCompatible) { /* * Different destination register - * insert a move */ if (checkLIR->operands[0] != nativeRegId) { convertMemOpIntoMove(cUnit, checkLIR, checkLIR->operands[0], nativeRegId); } checkLIR->flags.isNop = true; } else { /* * Destinaions are of different types - * something complicated going on so * stop looking now. */ stopHere = true; } } else if (isThisLIRLoad && !isCheckLIRLoad) { /* WAR - register value is killed */ stopHere = true; } else if (!isThisLIRLoad && !isCheckLIRLoad) { /* WAW - nuke the earlier store */ thisLIR->flags.isNop = true; stopHere = true; } /* Partial overlap */ } else if (isDalvikRegisterClobbered(thisLIR, checkLIR)) { /* * It is actually ok to continue if checkLIR * is a read. But it is hard to make a test * case for this so we just stop here to be * conservative. */ stopHere = true; } } /* Memory content may be updated. Stop looking now. */ if (stopHere) { break; /* The checkLIR has been transformed - check the next one */ } else if (checkLIR->flags.isNop) { continue; } } /* * this and check LIRs have no memory dependency. Now check if * their register operands have any RAW, WAR, and WAW * dependencies. If so, stop looking. */ if (stopHere == false) { stopHere = CHECK_REG_DEP(stopUseRegMask, stopDefRegMask, checkLIR); } if (stopHere == true) { DEBUG_OPT(dumpDependentInsnPair(thisLIR, checkLIR, "REG CLOBBERED")); /* Only sink store instructions */ if (sinkDistance && !isThisLIRLoad) { MipsLIR *newStoreLIR = (MipsLIR *) dvmCompilerNew(sizeof(MipsLIR), true); *newStoreLIR = *thisLIR; /* * Stop point found - insert *before* the checkLIR * since the instruction list is scanned in the * top-down order. */ dvmCompilerInsertLIRBefore((LIR *) checkLIR, (LIR *) newStoreLIR); thisLIR->flags.isNop = true; } break; } else if (!checkLIR->flags.isNop) { sinkDistance++; } } } } /* * Perform a pass of bottom-up walk, from the second instruction in the * superblock, to try to hoist loads to earlier slots. */ static void applyLoadHoisting(CompilationUnit *cUnit, MipsLIR *headLIR, MipsLIR *tailLIR) { MipsLIR *thisLIR, *checkLIR; /* * Store the list of independent instructions that can be hoisted past. * Will decide the best place to insert later. */ MipsLIR *prevInstList[MAX_HOIST_DISTANCE]; /* Empty block */ if (headLIR == tailLIR) return; /* Start from the second instruction */ for (thisLIR = NEXT_LIR(headLIR); thisLIR != tailLIR; thisLIR = NEXT_LIR(thisLIR)) { /* Skip non-interesting instructions */ if ((thisLIR->flags.isNop == true) || isPseudoOpCode(thisLIR->opcode) || !(EncodingMap[thisLIR->opcode].flags & IS_LOAD)) { continue; } u8 stopUseAllMask = thisLIR->useMask; /* * Branches for null/range checks are marked with the true resource * bits, and loads to Dalvik registers, constant pools, and non-alias * locations are safe to be hoisted. So only mark the heap references * conservatively here. */ if (stopUseAllMask & ENCODE_HEAP_REF) { stopUseAllMask |= ENCODE_REG_PC; } /* Similar as above, but just check for pure register dependency */ u8 stopUseRegMask = stopUseAllMask & ~ENCODE_MEM; u8 stopDefRegMask = thisLIR->defMask & ~ENCODE_MEM; int nextSlot = 0; bool stopHere = false; /* Try to hoist the load to a good spot */ for (checkLIR = PREV_LIR(thisLIR); checkLIR != headLIR; checkLIR = PREV_LIR(checkLIR)) { /* * Skip already dead instructions (whose dataflow information is * outdated and misleading). */ if (checkLIR->flags.isNop) continue; u8 checkMemMask = checkLIR->defMask & ENCODE_MEM; u8 aliasCondition = stopUseAllMask & checkMemMask; stopHere = false; /* Potential WAR alias seen - check the exact relation */ if (checkMemMask != ENCODE_MEM && aliasCondition != 0) { /* We can fully disambiguate Dalvik references */ if (aliasCondition == ENCODE_DALVIK_REG) { /* Must alias or partually overlap */ if ((checkLIR->aliasInfo == thisLIR->aliasInfo) || isDalvikRegisterClobbered(thisLIR, checkLIR)) { stopHere = true; } /* Conservatively treat all heap refs as may-alias */ } else { assert(aliasCondition == ENCODE_HEAP_REF); stopHere = true; } /* Memory content may be updated. Stop looking now. */ if (stopHere) { prevInstList[nextSlot++] = checkLIR; break; } } if (stopHere == false) { stopHere = CHECK_REG_DEP(stopUseRegMask, stopDefRegMask, checkLIR); } /* * Store the dependent or non-pseudo/indepedent instruction to the * list. */ if (stopHere || !isPseudoOpCode(checkLIR->opcode)) { prevInstList[nextSlot++] = checkLIR; if (nextSlot == MAX_HOIST_DISTANCE) break; } /* Found a new place to put the load - move it here */ if (stopHere == true) { DEBUG_OPT(dumpDependentInsnPair(checkLIR, thisLIR "HOIST STOP")); break; } } /* * Reached the top - use headLIR as the dependent marker as all labels * are barriers. */ if (stopHere == false && nextSlot < MAX_HOIST_DISTANCE) { prevInstList[nextSlot++] = headLIR; } /* * At least one independent instruction is found. Scan in the reversed * direction to find a beneficial slot. */ if (nextSlot >= 2) { int firstSlot = nextSlot - 2; int slot; MipsLIR *depLIR = prevInstList[nextSlot-1]; /* If there is ld-ld dependency, wait LDLD_DISTANCE cycles */ if (!isPseudoOpCode(depLIR->opcode) && (EncodingMap[depLIR->opcode].flags & IS_LOAD)) { firstSlot -= LDLD_DISTANCE; } /* * Make sure we check slot >= 0 since firstSlot may be negative * when the loop is first entered. */ for (slot = firstSlot; slot >= 0; slot--) { MipsLIR *curLIR = prevInstList[slot]; MipsLIR *prevLIR = prevInstList[slot+1]; /* * Check the highest instruction. * ENCODE_ALL represents a scheduling barrier. */ if (prevLIR->defMask == ENCODE_ALL) { /* * If the first instruction is a load, don't hoist anything * above it since it is unlikely to be beneficial. */ if (EncodingMap[curLIR->opcode].flags & IS_LOAD) continue; /* * Need to unconditionally break here even if the hoisted * distance is greater than LD_LATENCY (ie more than enough * cycles are inserted to hide the load latency) since theu * subsequent code doesn't expect to compare against a * pseudo opcode (whose opcode value is negative). */ break; } /* * NOTE: now prevLIR is guaranteed to be a non-pseudo * instruction (ie accessing EncodingMap[prevLIR->opcode] is * safe). * * Try to find two instructions with load/use dependency until * the remaining instructions are less than LD_LATENCY. */ if (((curLIR->useMask & prevLIR->defMask) && (EncodingMap[prevLIR->opcode].flags & IS_LOAD)) || (slot < LD_LATENCY)) { break; } } /* Found a slot to hoist to */ if (slot >= 0) { MipsLIR *curLIR = prevInstList[slot]; MipsLIR *newLoadLIR = (MipsLIR *) dvmCompilerNew(sizeof(MipsLIR), true); *newLoadLIR = *thisLIR; /* * Insertion is guaranteed to succeed since checkLIR * is never the first LIR on the list */ dvmCompilerInsertLIRBefore((LIR *) curLIR, (LIR *) newLoadLIR); thisLIR->flags.isNop = true; } } } } void dvmCompilerApplyLocalOptimizations(CompilationUnit *cUnit, LIR *headLIR, LIR *tailLIR) { if (!(gDvmJit.disableOpt & (1 << kLoadStoreElimination))) { applyLoadStoreElimination(cUnit, (MipsLIR *) headLIR, (MipsLIR *) tailLIR); } if (!(gDvmJit.disableOpt & (1 << kLoadHoisting))) { applyLoadHoisting(cUnit, (MipsLIR *) headLIR, (MipsLIR *) tailLIR); } }