#include "compiler/LoopOptimization.h" #include "compiler/CFunc.h" #include "compiler/CParser.h" #include "compiler/BitVectors.h" #include "compiler/CompilerTools.h" #include "compiler/LoopDetection.h" #include "compiler/PCode.h" #include "compiler/Registers.h" #include "compiler/UseDefChains.h" #include "compiler/objects.h" #include "compiler/types.h" int optimizedloops; int optimizedloop_full_unroll; int optimizedloop_trans_regs; static UInt32 *liveonexit; static UInt32 *inductionvariables; static int last_virtual_GPR; static int ispowerof2(SInt32 value) { int bit = getbit(value); return (bit > 0 && bit < 31) ? bit : 0; } static void insertupdateinstructions(Loop *loop) { // nothing } static void computeliveonexit(Loop *loop) { UInt32 *usevec; UInt32 *defvec; BlockList *blocklist; RegUseOrDef *list; int gpr; bitvectorinitialize(usevec = oalloc(4 * ((number_of_Uses + 31) >> 5)), number_of_Uses, 0); for (blocklist = loop->blocks; blocklist; blocklist = blocklist->next) { if (bitvectorgetbit(blocklist->block->blockIndex, loop->vec24)) bitvectorunion(usevec, usedefinfo[blocklist->block->blockIndex].usevec1C, number_of_Uses); } bitvectorinitialize(defvec = oalloc(4 * ((number_of_Defs + 31) >> 5)), number_of_Defs, 0); if (loop->preheader) bitvectorunion(defvec, usedefinfo[loop->preheader->blockIndex].defvec8, number_of_Defs); bitvectorinitialize(liveonexit, last_virtual_GPR, 0); for (gpr = 32; gpr < last_virtual_GPR; gpr++) { for (list = reg_Defs[RegClass_GPR][gpr]; list; list = list->next) { if (bitvectorgetbit(list->id, defvec)) { if (!Defs[list->id].pcode->block || bitvectorgetbit(Defs[list->id].pcode->block->blockIndex, loop->memberblocks)) { bitvectorsetbit(gpr, liveonexit); break; } } } for (list = reg_Uses[RegClass_GPR][gpr]; list; list = list->next) { if (bitvectorgetbit(list->id, usevec)) { if (!Uses[list->id].pcode->block || !bitvectorgetbit(Uses[list->id].pcode->block->blockIndex, loop->memberblocks)) { bitvectorsetbit(gpr, liveonexit); break; } } } } } static void eliminateinductionvariables(Loop *loop) { BlockList *blocklist; PCode *instr; PCode *nextInstr; PCodeArg *op; int i; bitvectorinitialize(inductionvariables, last_virtual_GPR, 0xFFFFFFFF); for (blocklist = loop->blocks; blocklist; blocklist = blocklist->next) { for (instr = blocklist->block->firstPCode; instr; instr = instr->nextPCode) { if ( instr->op != PC_ADDI || instr->args[0].data.reg.reg < 32 || instr->args[0].data.reg.reg >= last_virtual_GPR || instr->args[1].data.reg.reg != instr->args[0].data.reg.reg ) { op = instr->args; i = instr->argCount; while (i--) { if ( op->kind == PCOp_REGISTER && op->arg == RegClass_GPR && op->data.reg.reg >= n_real_registers[RegClass_GPR] && op->data.reg.reg < last_virtual_GPR ) bitvectorclearbit(op->data.reg.reg, inductionvariables); op++; } } } } if (loop->parent) { for (instr = loop->preheader->firstPCode; instr; instr = nextInstr) { nextInstr = instr->nextPCode; op = instr->args; i = instr->argCount; while (i--) { if ( op->kind == PCOp_REGISTER && op->arg == RegClass_GPR && op->data.reg.reg >= n_real_registers[RegClass_GPR] && op->data.reg.reg < last_virtual_GPR ) bitvectorsetbit(op->data.reg.reg, liveonexit); op++; } } } for (blocklist = loop->blocks; blocklist; blocklist = blocklist->next) { for (instr = blocklist->block->firstPCode; instr; instr = nextInstr) { nextInstr = instr->nextPCode; if ( instr->op == PC_ADDI && instr->args[0].data.reg.reg >= 32 && instr->args[0].data.reg.reg < last_virtual_GPR && instr->args[1].data.reg.reg == instr->args[0].data.reg.reg && bitvectorgetbit(instr->args[0].data.reg.reg, inductionvariables) && !bitvectorgetbit(instr->args[0].data.reg.reg, liveonexit) ) { deletepcode(instr); optimizedloops = 1; } } } } static void skiplooptest(Loop *loop) { PCodeBlock *preheader; PCodeLabel *label; PCLink **ptr; PCLink *link; PCode *lastInstr; PCode *instr; preheader = loop->preheader; lastInstr = loop->body->lastPCode; #line 340 CError_ASSERT(lastInstr->args[2].kind == PCOp_LABEL); label = lastInstr->args[2].data.label.label; preheader->lastPCode->args[0].data.label.label = label; preheader->successors->block = label->block; ptr = &loop->body->predecessors; while ((link = *ptr)) { if (link->block == preheader) { *ptr = link->nextLink; break; } ptr = &link->nextLink; } link->nextLink = label->block->predecessors; label->block->predecessors = link; while (1) { instr = loop->body->firstPCode; #line 369 CError_ASSERT(instr); if (instr->op == PC_CMP || instr->op == PC_CMPI || instr->op == PC_CMPLI || instr->op == PC_CMPL) break; deletepcode(instr); insertpcodebefore(loop->preheader->lastPCode, instr); loop->bodySize--; } for (instr = instr->nextPCode; instr && !(instr->flags & fPCodeFlag1); instr = instr->nextPCode) insertpcodebefore(loop->preheader->lastPCode, copypcode(instr)); } static void unrollloop(Loop *loop) { PCodeBlock *newBlock; int i; int factor; PCode *instr; PCodeBlock *block; PCode *firstInstr; PCode *nextInstr; for (factor = copts.ppc_unroll_factor_limit; factor > 1; factor--) { if ((loop->iterationCount % factor) == 0 && (loop->bodySize - 2) * factor <= copts.ppc_unroll_instructions_limit) break; } if (factor == 1) return; if ((loop->iterationCount / factor) != 1 && loop->bodySize < 4) return; newBlock = oalloc(sizeof(PCodeBlock)); newBlock->firstPCode = newBlock->lastPCode = NULL; for (i = 0; i < factor - 1; i++) { firstInstr = loop->body->firstPCode; #line 448 CError_ASSERT(firstInstr); if (firstInstr->op != PC_CMP && firstInstr->op != PC_CMPL && firstInstr->op != PC_CMPI && firstInstr->op != PC_CMPLI) { #line 450 CError_FATAL(); } for (instr = firstInstr->nextPCode; instr && !(instr->flags & fPCodeFlag1); instr = instr->nextPCode) appendpcode(newBlock, copypcode(instr)); for (block = loop->preheader->successors->block; block != loop->body; block = block->successors->block) { for (instr = block->firstPCode; instr; instr = instr->nextPCode) { if (instr->op != PC_B) appendpcode(newBlock, copypcode(instr)); } } } block = loop->body->predecessors->block; for (instr = newBlock->firstPCode; instr; instr = nextInstr) { nextInstr = instr->nextPCode; appendpcode(block, instr); } loop->iterationCount /= factor; } void pccomputepredecessors1(PCodeBlock *block) { PCLink *succ; PCLink *pred; for (succ = block->successors; succ; succ = succ->nextLink) { if (!succ->block) { #line 496 CError_FATAL(); } else { for (pred = succ->block->predecessors; pred; pred = pred->nextLink) { if (pred->block == block) break; } if (!pred) { pred = lalloc(sizeof(PCLink)); pred->block = block; pred->nextLink = succ->block->predecessors; succ->block->predecessors = pred; } } } } static PCodeBlock *insertnewpcblock(PCodeBlock *block, int loopWeight) { PCodeBlock *newBlock; PCodeBlock *nextBlock; PCodeLabel *label; PCLink *prev; PCLink *link; label = makepclabel(); newBlock = lalloc(sizeof(PCodeBlock)); nextBlock = block->nextBlock; newBlock->nextBlock = nextBlock; block->nextBlock = newBlock; newBlock->prevBlock = block; nextBlock->prevBlock = newBlock; newBlock->labels = NULL; newBlock->predecessors = newBlock->successors = NULL; newBlock->firstPCode = newBlock->lastPCode = NULL; newBlock->pcodeCount = 0; newBlock->loopWeight = loopWeight; newBlock->flags = 0; newBlock->blockIndex = pcblockcount++; pclabel(newBlock, label); prev = NULL; for (link = block->successors; link; link = link->nextLink) { if (link->block == nextBlock) { if (!prev) block->successors = link->nextLink; else prev->nextLink = link->nextLink; link->nextLink = NULL; newBlock->successors = link; break; } prev = link; } prev = NULL; for (link = nextBlock->predecessors; link; link = link->nextLink) { if (link->block == block) { if (!prev) nextBlock->predecessors = link->nextLink; else prev->nextLink = link->nextLink; link->nextLink = NULL; newBlock->predecessors = link; break; } prev = link; } link = lalloc(sizeof(PCLink)); link->block = newBlock; link->nextLink = block->successors; block->successors = link; link = lalloc(sizeof(PCLink)); link->block = newBlock; link->nextLink = nextBlock->predecessors; nextBlock->predecessors = link; return newBlock; } static void unrollloopconditional(Loop *loop) { PCodeBlock *lastBlock; PCodeLabel *label24; PCode *instr; PCode *instrCopy; int outputBlockCount; int inputBlockCount; PCodeBlock **blocks; PCodeBlock **blocks2; PCodeBlock **blocks3; PCode *firstInstr; int factor; PCodeBlock *block; PCLink *link; PCLink *prev; int i; int j; int k; int instructionCount; label24 = NULL; outputBlockCount = 0; instructionCount = 0; for (factor = copts.ppc_unroll_factor_limit; factor > 1; factor--) { if ((loop->iterationCount % factor) == 0 && (loop->bodySize - 2) * factor <= copts.ppc_unroll_instructions_limit) break; } if (factor == 1) return; inputBlockCount = 0; for (block = loop->preheader->successors->block; block != loop->body; block = block->nextBlock) { inputBlockCount++; if (!bitvectorgetbit(block->blockIndex, loop->memberblocks)) instructionCount += block->pcodeCount; } if ((loop->bodySize - instructionCount - 2) < instructionCount || instructionCount > 8) return; blocks = oalloc(inputBlockCount * sizeof(PCodeBlock *)); blocks2 = oalloc(inputBlockCount * sizeof(PCodeBlock *)); blocks3 = oalloc(factor * (inputBlockCount * sizeof(PCodeBlock *))); memclrw(blocks, inputBlockCount * sizeof(PCodeBlock *)); memclrw(blocks2, inputBlockCount * sizeof(PCodeBlock *)); memclrw(blocks3, factor * (inputBlockCount * sizeof(PCodeBlock *))); block = loop->preheader->nextBlock; for (i = 0; i < inputBlockCount; i++) { blocks[i] = block; block = block->nextBlock; } lastBlock = blocks[inputBlockCount - 1]; for (i = 0; i < factor - 1; i++) { for (j = 0; j < inputBlockCount; j++) { blocks2[j] = insertnewpcblock(lastBlock, loop->loopWeight); blocks3[outputBlockCount++] = blocks2[j]; lastBlock = blocks2[j]; } if (label24) { pclabel(blocks2[0], label24); label24 = NULL; } for (j = 0; j < inputBlockCount; j++) { for (instr = blocks[j]->firstPCode; instr; instr = instr->nextPCode) { if (instr->flags & fPCodeFlag1) { PCodeArg *op; int opID; instrCopy = copypcode(instr); op = NULL; for (opID = 0; opID < instr->argCount; opID++) { if (instr->args[opID].kind == PCOp_LABEL) { op = &instr->args[opID]; break; } } if (op) { if (op->data.label.label->block == loop->body) { if (!label24) label24 = makepclabel(); instrCopy->args[opID].data.label.label = label24; } else { for (k = 0; k < inputBlockCount; k++) { if (op->data.label.label->block == blocks[k]) { instrCopy->args[opID].data.label.label = blocks2[k]->labels; break; } } } } appendpcode(blocks2[j], instrCopy); if (op) pcbranch(blocks2[j], instrCopy->args[opID].data.label.label); } else { appendpcode(blocks2[j], copypcode(instr)); } } } firstInstr = loop->body->firstPCode; #line 762 CError_ASSERT(firstInstr != NULL); if (firstInstr->op != PC_CMP && firstInstr->op != PC_CMPL && firstInstr->op != PC_CMPI && firstInstr->op != PC_CMPLI) { #line 764 CError_FATAL(); } for (instr = firstInstr->nextPCode; instr && !(instr->flags & fPCodeFlag1); instr = instr->nextPCode) appendpcode(blocks2[inputBlockCount - 1], copypcode(instr)); for (j = 0; j < inputBlockCount; j++) { for (link = blocks[j]->successors; link; link = link->nextLink) { if (link->block == blocks[j]->nextBlock) break; } if (!link) { for (link = blocks2[j]->successors, prev = NULL; link; link = link->nextLink) { if (link->block == blocks2[j]->nextBlock) { if (prev) prev->nextLink = link->nextLink; else blocks2[j]->successors = link->nextLink; } else { prev = link; } } for (link = blocks2[j]->nextBlock->predecessors, prev = NULL; link; link = link->nextLink) { if (link->block == blocks2[j]) { if (prev) prev->nextLink = link->nextLink; else blocks2[j]->nextBlock->predecessors = link->nextLink; } else { prev = link; } } } } } if (label24) pclabel(loop->body, label24); for (i = 0; i < inputBlockCount; i++) { for (instr = blocks[i]->firstPCode; instr; instr = instr->nextPCode) { if (instr->flags & fPCodeFlag1) { PCodeArg *op; int opID; op = NULL; for (opID = 0; opID < instr->argCount; opID++) { if (instr->args[opID].kind == PCOp_LABEL) { op = &instr->args[opID]; break; } } if (op && op->data.label.label->block == loop->body) { instr->args[opID].data.label.label = blocks3[0]->labels; for (link = blocks[i]->successors, prev = NULL; link; link = link->nextLink) { if (link->block == loop->body) { if (prev) prev->nextLink = link->nextLink; else blocks[i]->successors = link->nextLink; } else { prev = link; } } for (link = loop->body->predecessors, prev = NULL; link; link = link->nextLink) { if (link->block == blocks[i]) { if (prev) prev->nextLink = link->nextLink; else loop->body->predecessors = link->nextLink; } else { prev = link; } } link = blocks[i]->successors; while (link && link->block != blocks3[0]) link = link->nextLink; if (!link) { pcbranch(blocks[i], op->data.label.label); pccomputepredecessors1(blocks[i]); } } } } } for (i = 0; i < outputBlockCount; i++) pccomputepredecessors1(blocks3[i]); loop->iterationCount /= factor; } static void unrollunknownBDNZ(Loop *loop) { int factor; // r29 PCodeBlock *preheader; // r17 PCodeBlock *blockA; // r23 PCodeBlock *postheader; // r22 PCodeBlock *newblock1; // r26 PCodeBlock *newblock2; // r31 PCodeBlock *newblock3; // r19 PCodeBlock *newblock4; // r20 PCodeBlock *newblock5; // r24 PCode *mtctr; // r21 int mtctr_reg; // r27 PCode *instr28; // r28 PCode *instr6; // r6 PCodeBlock *block; PCode *instr; PCodeArg *op; int i; int val; short mtctr_shifted_reg; // r16 short reg25; // r25 PCLink *link; if (loop->bodySize < 4) return; factor = 128; while (factor > copts.ppc_unroll_factor_limit) factor >>= 1; while (factor > 1 && (loop->bodySize - 2) * factor > copts.ppc_unroll_instructions_limit) factor >>= 1; if (factor < 2) return; preheader = loop->preheader; blockA = loop->body->nextBlock; postheader = preheader->nextBlock; newblock1 = insertnewpcblock(preheader, loop->loopWeight); newblock2 = insertnewpcblock(newblock1, loop->loopWeight); newblock3 = insertnewpcblock(newblock2, loop->loopWeight); newblock4 = insertnewpcblock(newblock3, loop->loopWeight); newblock5 = insertnewpcblock(newblock4, loop->loopWeight); addblocktoloop(loop, newblock1); addblocktoloop(loop, newblock2); addblocktoloop(loop, newblock3); addblocktoloop(loop, newblock4); addblocktoloop(loop, newblock5); for (instr = preheader->lastPCode; instr; instr = instr->prevPCode) { if (instr->op == PC_MTCTR) { mtctr = instr; mtctr_reg = instr->args[0].data.reg.reg; } } if (!mtctr) return; instr28 = NULL; for (block = postheader; block != loop->body; block = block->successors->block) { for (instr = block->firstPCode; instr; instr = instr->nextPCode) { if (instr->op != PC_B) { appendpcode(newblock2, copypcode(instr)); if (instr == loop->pc18) instr28 = newblock2->lastPCode; } } } if (!instr28) { appendpcode(newblock2, copypcode(loop->pc18)); instr28 = newblock2->lastPCode; } instr6 = NULL; for (instr = newblock2->firstPCode; instr; instr = instr->nextPCode) { if (instr != instr28) { op = instr->args; i = instr->argCount; while (i--) { if ( op->kind == PCOp_REGISTER && op->arg == RegClass_GPR && op->data.reg.reg == loop->pc18->args[0].data.reg.reg && (op->data.reg.effect & (EffectRead | EffectWrite)) ) { instr6 = instr; break; } op++; } } if (instr6) break; } if (!instr6) { deletepcode(instr28); deletepcode(loop->pc18); if (loop->footer) blockA = loop->footer; else blockA = insertnewpcblock(loop->body, loop->loopWeight); } else { instr28 = NULL; } for (i = 1; i < factor; i++) { for (block = postheader; block != loop->body; block = block->successors->block) { for (instr = block->firstPCode; instr; instr = instr->nextPCode) { if (instr->op != PC_B) appendpcode(newblock2, copypcode(instr)); } } } mtctr_shifted_reg = used_virtual_registers[RegClass_GPR]++; appendpcode(newblock1, makepcode( PC_RLWINM, mtctr_shifted_reg, mtctr_reg, 32 - ispowerof2(factor), ispowerof2(factor), 31)); appendpcode(newblock1, makepcode(PC_CMPLI, 0, mtctr_shifted_reg, 0)); if (instr28) { reg25 = used_virtual_registers[RegClass_GPR]++; if (loop->step == 1) { instr = makepcode(PC_MR, reg25, mtctr_reg); } else if (loop->step == -1) { instr = makepcode(PC_NEG, reg25, mtctr_reg); } else { val = ispowerof2(abs(loop->step)); if (val > 0) { instr = makepcode(PC_RLWINM, reg25, mtctr_reg, val, 0, 31 - val); if (loop->step < 0) { appendpcode(newblock1, instr); instr = makepcode(PC_NEG, reg25, reg25); } } else { instr = makepcode(PC_MULLI, reg25, mtctr_reg, loop->step); } } appendpcode(newblock1, instr); } appendpcode(newblock1, makepcode(PC_MTCTR, mtctr_shifted_reg)); appendpcode(newblock1, makepcode(PC_BT, 0, 2, newblock5->labels)); pcbranch(newblock1, newblock5->labels); link = lalloc(sizeof(PCLink)); link->block = newblock1; link->nextLink = newblock5->predecessors; newblock5->predecessors = link; appendpcode(newblock3, makepcode(PC_BDNZ, newblock2->labels)); pcbranch(newblock3, newblock2->labels); link = lalloc(sizeof(PCLink)); link->block = newblock3; link->nextLink = newblock2->predecessors; newblock2->predecessors = link; appendpcode(newblock4, makepcode(PC_ANDI, mtctr_reg, mtctr_reg, factor - 1)); appendpcode(newblock4, makepcode(PC_BT, 0, 2, blockA->labels)); pcbranch(newblock4, blockA->labels); link = lalloc(sizeof(PCLink)); link->block = newblock4; link->nextLink = blockA->predecessors; blockA->predecessors = link; deletepcode(mtctr); appendpcode(newblock5, mtctr); if (instr28 && bitvectorgetbit(instr28->args[0].data.reg.reg, liveonexit)) { instr = makepcode(PC_ADD, instr28->args[0].data.reg.reg, instr28->args[0].data.reg.reg, reg25); if (blockA->firstPCode) insertpcodebefore(blockA->firstPCode, instr); else appendpcode(blockA, instr); } } static void deleteloop(Loop *loop) { PCodeBlock *body; PCodeBlock *preheader; PCodeBlock *nextblock; PCodeLabel *label; PCode *instr; PCLink **ptr; PCLink *link; PCodeBlock *block; body = loop->body; preheader = loop->preheader; nextblock = body->nextBlock; label = makepclabel(); while (1) { instr = body->firstPCode; #line 1294 CError_ASSERT(instr != NULL); if (instr->op == PC_CMP || instr->op == PC_CMPI || instr->op == PC_CMPLI || instr->op == PC_CMPL) break; deletepcode(instr); insertpcodebefore(loop->preheader->lastPCode, instr); loop->bodySize--; } pclabel(nextblock, label); preheader->lastPCode->args[0].data.label.label = label; preheader->successors->block = nextblock; ptr = &nextblock->predecessors; while ((link = *ptr)) { if (link->block == body) { link->block = preheader; break; } ptr = &link->nextLink; } block = pcbasicblocks; while ((nextblock = block->nextBlock)) { if (bitvectorgetbit(nextblock->blockIndex, loop->memberblocks)) block->nextBlock = nextblock->nextBlock; else block = nextblock; } } static void deleteloopheader(Loop *loop) { PCLink *link; PCLink **ptr; ptr = &loop->body->successors; while ((link = *ptr)) { if (link->block == loop->body->lastPCode->args[2].data.label.label->block) { *ptr = link->nextLink; break; } ptr = &link->nextLink; } ptr = &loop->body->lastPCode->args[2].data.label.label->block->predecessors; while ((link = *ptr)) { if (link->block == loop->body) { *ptr = link->nextLink; break; } ptr = &link->nextLink; } deletepcode(loop->body->firstPCode); deletepcode(loop->body->lastPCode); optimizedloop_full_unroll = 1; } static void rewriteloopwithBDNZ(Loop *loop) { PCode *instr; if (!FITS_IN_SHORT(loop->iterationCount)) { instr = makepcode(PC_LIS, used_virtual_registers[RegClass_GPR]++, 0, HIGH_PART(loop->iterationCount)); insertpcodebefore(loop->preheader->lastPCode, instr); if (loop->iterationCount != 0) insertpcodeafter(instr, makepcode(PC_ADDI, instr->args[0].data.reg.reg, instr->args[0].data.reg.reg, 0, LOW_PART(loop->iterationCount))); } else { instr = makepcode(PC_LI, used_virtual_registers[RegClass_GPR]++, loop->iterationCount); insertpcodebefore(loop->preheader->lastPCode, instr); } insertpcodebefore(loop->preheader->lastPCode, makepcode(PC_MTCTR, instr->args[0].data.reg.reg)); instr = makepcode(PC_BDNZ, loop->body->lastPCode->args[2].data.label.label); deletepcode(loop->body->firstPCode); deletepcode(loop->body->lastPCode); appendpcode(loop->body, instr); for (loop = loop->parent; loop; loop = loop->parent) loop->x4E = 1; } static void rewriteunknownloopwithBDNZ(Loop *loop) { SInt32 value1; // r24 SInt32 value2; // r30 Opcode branchOpcode; // r19 SInt32 absStep; // r28 int branchCondition; // r20 int counterReg; // r27 int reg1; // r26 int reg2; // r22 unsigned char mode; // r23 PCodeBlock *afterLoop; // r25 PCode *addiInstr; PCode *instr; PCLink *link; PCLink **ptr; absStep = abs(loop->step); afterLoop = NULL; for (addiInstr = loop->body->lastPCode->prevPCode; addiInstr->op == PC_ADDI; addiInstr = loop->body->lastPCode->prevPCode) { deletepcode(addiInstr); if (loop->body->lastPCode->args[2].data.label.label->block->firstPCode) insertpcodebefore(loop->body->lastPCode->args[2].data.label.label->block->firstPCode, addiInstr); else appendpcode(loop->body->lastPCode->args[2].data.label.label->block, addiInstr); afterLoop = insertnewpcblock(loop->body, loop->loopWeight); appendpcode(afterLoop, copypcode(addiInstr)); loop->footer = afterLoop; } if (loop->unknownCondition == ELESS) { branchOpcode = PC_BF; if (loop->lowerType == LOOP_BOUND_CONSTANT) { branchCondition = 1; value1 = loop->lower; reg1 = addiInstr->args[2].data.reg.reg; value2 = absStep - 1 - loop->lower; mode = 0; } else if (loop->upperType == LOOP_BOUND_CONSTANT) { branchCondition = 0; value1 = loop->upper; reg1 = addiInstr->args[1].data.reg.reg; value2 = absStep - 1 + loop->upper; mode = 1; } else { branchCondition = 0; reg1 = addiInstr->args[1].data.reg.reg; reg2 = addiInstr->args[2].data.reg.reg; value2 = absStep - 1; mode = 2; } } else if (loop->unknownCondition == ELESSEQU) { branchOpcode = PC_BT; if (loop->lowerType == LOOP_BOUND_CONSTANT) { branchCondition = 0; value1 = loop->lower; reg1 = addiInstr->args[2].data.reg.reg; value2 = absStep - loop->lower; mode = 0; } else if (loop->upperType == LOOP_BOUND_CONSTANT) { branchCondition = 1; value1 = loop->upper; reg1 = addiInstr->args[1].data.reg.reg; value2 = absStep + loop->upper; mode = 1; } else { branchCondition = 1; value1 = 0; reg1 = addiInstr->args[1].data.reg.reg; reg2 = addiInstr->args[2].data.reg.reg; value2 = absStep; mode = 2; } } else if (loop->unknownCondition == EGREATER) { branchOpcode = PC_BF; if (loop->lowerType == LOOP_BOUND_CONSTANT) { branchCondition = 0; value1 = loop->lower; reg1 = addiInstr->args[2].data.reg.reg; value2 = absStep - 1 + loop->lower; mode = 1; } else if (loop->upperType == LOOP_BOUND_CONSTANT) { branchCondition = 1; value1 = loop->upper; reg1 = addiInstr->args[1].data.reg.reg; value2 = absStep - 1 - loop->upper; mode = 0; } else { branchCondition = 1; value1 = 0; reg1 = addiInstr->args[1].data.reg.reg; reg2 = addiInstr->args[2].data.reg.reg; value2 = absStep - 1; mode = 3; } } else if (loop->unknownCondition == EGREATEREQU) { branchOpcode = PC_BT; if (loop->lowerType == LOOP_BOUND_CONSTANT) { branchCondition = 1; value1 = loop->lower; reg1 = addiInstr->args[2].data.reg.reg; value2 = absStep + loop->lower; mode = 1; } else if (loop->upperType == LOOP_BOUND_CONSTANT) { branchCondition = 0; value1 = loop->upper; reg1 = addiInstr->args[1].data.reg.reg; value2 = absStep - loop->upper; mode = 0; } else { branchCondition = 0; reg1 = addiInstr->args[1].data.reg.reg; reg2 = addiInstr->args[2].data.reg.reg; value2 = absStep; mode = 3; } } else if (loop->unknownCondition == ENOTEQU) { branchOpcode = PC_BT; branchCondition = 2; if (loop->step > 0) { if (loop->lowerType == LOOP_BOUND_CONSTANT) { value1 = loop->lower; reg1 = addiInstr->args[2].data.reg.reg; value2 = absStep - 1 - loop->lower; mode = 0; } else if (loop->upperType == LOOP_BOUND_CONSTANT) { value1 = loop->upper; reg1 = addiInstr->args[1].data.reg.reg; value2 = absStep - 1 + loop->upper; mode = 1; } else { reg1 = addiInstr->args[1].data.reg.reg; reg2 = addiInstr->args[2].data.reg.reg; value2 = absStep - 1; mode = 2; } } else { if (loop->lowerType == LOOP_BOUND_CONSTANT) { value1 = loop->lower; reg1 = addiInstr->args[2].data.reg.reg; value2 = absStep - 1 + loop->lower; mode = 1; } else if (loop->upperType == LOOP_BOUND_CONSTANT) { value1 = loop->upper; reg1 = addiInstr->args[1].data.reg.reg; value2 = absStep - 1 - loop->upper; mode = 0; } else { reg1 = addiInstr->args[1].data.reg.reg; reg2 = addiInstr->args[2].data.reg.reg; value2 = absStep - 1; mode = 3; } } } while (1) { instr = loop->body->firstPCode; #line 1857 CError_ASSERT(instr); if (instr->op == PC_CMP || instr->op == PC_CMPI || instr->op == PC_CMPLI || instr->op == PC_CMPL) break; deletepcode(instr); insertpcodebefore(loop->preheader->lastPCode, instr); loop->bodySize--; } // build a value for mtctr counterReg = used_virtual_registers[RegClass_GPR]++; if (mode == 1) { if (value2 == 0) { insertpcodebefore(loop->preheader->lastPCode, makepcode(PC_NEG, counterReg, reg1)); } else if (FITS_IN_SHORT(value2)) { insertpcodebefore(loop->preheader->lastPCode, makepcode(PC_SUBFIC, counterReg, reg1, value2)); } else { insertpcodebefore(loop->preheader->lastPCode, makepcode(PC_LIS, counterReg, 0, HIGH_PART(value2))); if (value2 != 0) { insertpcodebefore(loop->preheader->lastPCode, makepcode(PC_ADDI, counterReg, counterReg, 0, LOW_PART(value2))); } insertpcodebefore(loop->preheader->lastPCode, makepcode(PC_SUBF, counterReg, reg1, counterReg)); } } else if (mode == 0) { if (value2 == 0) { insertpcodebefore(loop->preheader->lastPCode, makepcode(PC_MR, counterReg, reg1)); } else if (FITS_IN_SHORT(value2)) { insertpcodebefore(loop->preheader->lastPCode, makepcode(PC_ADDI, counterReg, reg1, 0, value2)); } else { insertpcodebefore(loop->preheader->lastPCode, makepcode(PC_ADDIS, counterReg, reg1, 0, HIGH_PART(value2))); if (value2 != 0) { insertpcodebefore(loop->preheader->lastPCode, makepcode(PC_ADDI, counterReg, counterReg, 0, LOW_PART(value2))); } } } else if (mode == 2) { if (value2 == 0) { insertpcodebefore(loop->preheader->lastPCode, makepcode(PC_SUBF, counterReg, reg1, reg2)); } else if (FITS_IN_SHORT(value2)) { insertpcodebefore(loop->preheader->lastPCode, makepcode(PC_ADDI, counterReg, reg2, 0, value2)); insertpcodebefore(loop->preheader->lastPCode, makepcode(PC_SUBF, counterReg, reg1, counterReg)); } else { insertpcodebefore(loop->preheader->lastPCode, makepcode(PC_ADDIS, counterReg, reg2, 0, HIGH_PART(value2))); if (value2 != 0) { insertpcodebefore(loop->preheader->lastPCode, makepcode(PC_ADDI, counterReg, counterReg, 0, LOW_PART(value2))); } insertpcodebefore(loop->preheader->lastPCode, makepcode(PC_SUBF, counterReg, reg1, counterReg)); } } else { if (value2 == 0) { insertpcodebefore(loop->preheader->lastPCode, makepcode(PC_SUBF, counterReg, reg2, reg1)); } else { if (FITS_IN_SHORT(value2)) { insertpcodebefore(loop->preheader->lastPCode, makepcode(PC_ADDI, counterReg, reg1, 0, value2)); } else { insertpcodebefore(loop->preheader->lastPCode, makepcode(PC_ADDIS, counterReg, reg1, 0, HIGH_PART(value2))); if (value2 != 0) { insertpcodebefore(loop->preheader->lastPCode, makepcode(PC_ADDI, counterReg, counterReg, 0, LOW_PART(value2))); } } insertpcodebefore(loop->preheader->lastPCode, makepcode(PC_SUBF, counterReg, reg2, counterReg)); } } if (absStep > 1) { unsigned char bits; if ((bits = ispowerof2(absStep))) { insertpcodebefore(loop->preheader->lastPCode, makepcode(PC_RLWINM, counterReg, counterReg, 32 - bits, bits, 31)); } else { int reg = used_virtual_registers[RegClass_GPR]++; insertpcodebefore(loop->preheader->lastPCode, makepcode(PC_LI, reg, absStep)); insertpcodebefore(loop->preheader->lastPCode, makepcode(PC_DIVWU, counterReg, counterReg, reg)); } } insertpcodebefore(loop->preheader->lastPCode, makepcode(PC_MTCTR, counterReg)); if (mode < 2) { if (addiInstr->op == PC_CMPL || addiInstr->op == PC_CMPLI) { if (FITS_IN_USHORT(value1)) { insertpcodebefore(loop->preheader->lastPCode, makepcode(PC_CMPLI, 0, reg1, value1)); } else { PCode *tmp; tmp = makepcode(PC_LIS, used_virtual_registers[RegClass_GPR]++, 0, HIGH_PART(value1)); insertpcodebefore(loop->preheader->lastPCode, tmp); if (loop->iterationCount != 0) insertpcodeafter(tmp, makepcode(PC_ADDI, tmp->args[0].data.reg.reg, tmp->args[0].data.reg.reg, 0, LOW_PART(value1))); insertpcodebefore(loop->preheader->lastPCode, makepcode(PC_CMPL, 0, reg1, tmp->args[0].data.reg.reg)); } } else { if (FITS_IN_SHORT(value1)) { insertpcodebefore(loop->preheader->lastPCode, makepcode(PC_CMPI, 0, reg1, value1)); } else { PCode *tmp; tmp = makepcode(PC_LIS, used_virtual_registers[RegClass_GPR]++, 0, HIGH_PART(value1)); insertpcodebefore(loop->preheader->lastPCode, tmp); if (loop->iterationCount != 0) insertpcodeafter(tmp, makepcode(PC_ADDI, tmp->args[0].data.reg.reg, tmp->args[0].data.reg.reg, 0, LOW_PART(value1))); insertpcodebefore(loop->preheader->lastPCode, makepcode(PC_CMP, 0, reg1, tmp->args[0].data.reg.reg)); } } } else { if (addiInstr->op == PC_CMPL || addiInstr->op == PC_CMPLI) { insertpcodebefore(loop->preheader->lastPCode, makepcode(PC_CMPL, 0, reg1, reg2)); } else { insertpcodebefore(loop->preheader->lastPCode, makepcode(PC_CMP, 0, reg1, reg2)); } } if (!afterLoop) afterLoop = loop->body->nextBlock; instr = makepcode(branchOpcode, 0, branchCondition, afterLoop->labels); deletepcode(loop->preheader->lastPCode); appendpcode(loop->preheader, instr); instr = makepcode(PC_BDNZ, loop->body->lastPCode->args[2].data.label.label); deletepcode(loop->body->firstPCode); deletepcode(loop->body->lastPCode); appendpcode(loop->body, instr); loop->preheader->successors = NULL; ptr = &loop->body->predecessors; while ((link = *ptr)) { if (link->block == loop->preheader) { *ptr = link->nextLink; break; } ptr = &link->nextLink; } link = lalloc(sizeof(PCLink)); link->block = loop->preheader->nextBlock; link->nextLink = loop->preheader->successors; loop->preheader->successors = link; link = lalloc(sizeof(PCLink)); link->block = loop->preheader; link->nextLink = loop->preheader->nextBlock->predecessors; loop->preheader->nextBlock->predecessors = link; link = lalloc(sizeof(PCLink)); link->block = afterLoop; link->nextLink = loop->preheader->successors; loop->preheader->successors = link; link = lalloc(sizeof(PCLink)); link->block = loop->preheader; link->nextLink = afterLoop->predecessors; afterLoop->predecessors = link; for (loop = loop->parent; loop; loop = loop->parent) loop->x4E = 1; } static void optimizeloop(Loop *loop) { computeliveonexit(loop); if (loop->x53 || loop->x54) insertupdateinstructions(loop); if (loop->isKnownCountingLoop) { if (loop->iterationCount > 0) { skiplooptest(loop); if (!copts.optimize_for_size && !loop->x4D && !loop->x57) { if (loop->x4F) unrollloop(loop); else if (!loop->x4E) unrollloopconditional(loop); } } if (loop->iterationCount != 0) { if (loop->iterationCount == 1) deleteloopheader(loop); else if (!loop->x4E && !loop->x4D) rewriteloopwithBDNZ(loop); } optimizedloops = 1; } else if (loop->isUnknownCountingLoop && !loop->x4E && !loop->x4D) { rewriteunknownloopwithBDNZ(loop); if (copts.ppc_unroll_speculative && !copts.optimize_for_size) { if (loop->x4F && !loop->x57 && !loop->x52) unrollunknownBDNZ(loop); } optimizedloops = 1; } eliminateinductionvariables(loop); } typedef struct LocalArray { struct LocalArray *next; Object *object; unsigned int invalid:1; unsigned int isFloat:1; unsigned int isSigned:1; SInt32 elementSize; SInt32 arraySize; SInt32 elementCount; int totalUses; int elements[1]; } LocalArray; static LocalArray *scanforlocalarrays(void) { SInt32 elementCount; LocalArray *head; LocalArray *array; ObjectList *list; int i; SInt32 arraySize; SInt32 elementSize; head = NULL; for (list = locals; list; list = list->next) { if ( list->object && !(IS_TYPE_POINTER(list->object->type) ? (TPTR_QUAL(list->object->type) & Q_VOLATILE) : (list->object->qual & Q_VOLATILE)) && list->object->type && IS_TYPE_ARRAY(list->object->type) && TPTR_TARGET(list->object->type) && TPTR_TARGET(list->object->type)->type < TYPESTRUCT ) { arraySize = list->object->type->size; elementSize = TPTR_TARGET(list->object->type)->size; elementCount = arraySize / elementSize; if (elementCount > 0 && elementCount <= 8) { array = oalloc(sizeof(int) * (elementCount - 1) + sizeof(LocalArray)); array->next = head; head = array; array->object = list->object; array->elementSize = elementSize; array->arraySize = arraySize; array->elementCount = elementCount; array->totalUses = 0; array->isSigned = 1; array->isFloat = IS_TYPE_FLOAT(TPTR_TARGET(list->object->type)); array->invalid = 0; array->isSigned = 1; if (!array->isFloat && is_unsigned(TPTR_TARGET(list->object->type))) array->isSigned = 0; for (i = 0; i < elementCount; i++) { array->elements[i] = 0; } } } } return head; } static LocalArray *lookup_array_object(LocalArray *arrays, Object *object) { while (arrays) { if (arrays->object == object) return arrays; arrays = arrays->next; } return NULL; } void changearraytoregisters(void) { LocalArray *arrays; PCodeBlock *block; PCode *instr; int i; PCodeArg *op; LocalArray **ptr; LocalArray *array; int intCounter; int floatCounter; int reg; int reg2; PCode *newInstr; arrays = NULL; if ((arrays = scanforlocalarrays())) { for (block = pcbasicblocks; block; block = block->nextBlock) { for (instr = block->firstPCode; instr; instr = instr->nextPCode) { if (!(instr->flags & fPCodeFlag1) && instr->argCount) { op = instr->args; i = instr->argCount; while (i--) { if ( op->kind == PCOp_MEMORY && (PCOpMemoryArg) op->arg == PCOpMemory1 && (array = lookup_array_object(arrays, op->data.mem.obj)) && !array->invalid ) { if ( (instr->flags & (fPCodeFlag2 | fPCodeFlag4)) && (op->data.mem.offset % array->elementSize) == 0 && op->data.mem.offset < array->arraySize ) { switch (instr->op) { case PC_LBZ: case PC_STB: if (array->elementSize != 1) array->invalid = 1; break; case PC_LHZ: case PC_LHA: case PC_STH: if (array->elementSize != 2) array->invalid = 1; break; case PC_LWZ: case PC_STW: if (array->elementSize != 4) array->invalid = 1; break; case PC_LFD: case PC_STFD: if (array->elementSize != 8) array->invalid = 1; break; default: array->invalid = 1; break; } if (!array->invalid) array->elements[op->data.mem.offset / array->elementSize]++; } else { array->invalid = 1; } } op++; } } } } intCounter = 0; floatCounter = 0; ptr = &arrays; array = *ptr; while (array) { if (array->invalid) { *ptr = array = array->next; continue; } if (array->isFloat) floatCounter += array->elementCount; if (!array->isFloat) intCounter += array->elementCount; for (i = 0; i < array->elementCount; i++) array->totalUses += array->elements[i]; array = array->next; } if (arrays) { while (intCounter > 8) { LocalArray *best; int score; score = 0; best = NULL; for (array = arrays; array; array = array->next) { if (!array->isFloat) { if (best) { if (array->totalUses < score) { score = array->totalUses; best = array; } } else { best = array; score = array->totalUses; } } } if (!best) break; if (best == arrays) { arrays = best->next; } else { for (array = arrays; array; array = array->next) { if (array->next == best) { array->next = best->next; break; } } } intCounter -= best->elementCount; } while (floatCounter > 8) { LocalArray *best; int score; score = 0; best = NULL; for (array = arrays; array; array = array->next) { if (array->isFloat) { if (best) { if (array->totalUses < score) { score = array->totalUses; best = array; } } else { best = array; score = array->totalUses; } } } if (!best) break; if (best == arrays) { arrays = best->next; } else { for (array = arrays; array; array = array->next) { if (array->next == best) { array->next = best->next; break; } } } floatCounter -= best->elementCount; } #line 2394 CError_ASSERT(intCounter <= 8 && floatCounter <= 8); if (!arrays) return; optimizedloop_trans_regs = 1; for (array = arrays; array; array = array->next) { for (i = 0; i < array->elementCount; i++) { if (array->isFloat) array->elements[i] = used_virtual_registers[RegClass_FPR]++; else array->elements[i] = used_virtual_registers[RegClass_GPR]++; } } for (block = pcbasicblocks; block; block = block->nextBlock) { for (instr = block->firstPCode; instr; instr = instr->nextPCode) { if ( !(instr->flags & fPCodeFlag1) && instr->argCount && (instr->flags & (fPCodeFlag2 | fPCodeFlag4)) && instr->args[2].kind == PCOp_MEMORY && (PCOpMemoryArg) instr->args[2].arg == PCOpMemory1 && (array = lookup_array_object(arrays, instr->args[2].data.mem.obj)) && !(array->invalid) ) { reg2 = instr->args[0].data.reg.reg; reg = array->elements[instr->args[2].data.mem.offset / array->elementSize]; newInstr = NULL; switch (instr->op) { case PC_LBZ: if (array->isSigned) newInstr = makepcode(PC_MR, reg2, reg); else newInstr = makepcode(PC_RLWINM, reg2, reg, 0, 24, 31); break; case PC_STB: if (array->isSigned) newInstr = makepcode(PC_EXTSB, reg, reg2); else newInstr = makepcode(PC_RLWINM, reg, reg2, 0, 24, 31); break; case PC_LHZ: newInstr = makepcode(PC_RLWINM, reg2, reg, 0, 16, 31); break; case PC_LHA: newInstr = makepcode(PC_EXTSH, reg2, reg); break; case PC_STH: if (array->isSigned) newInstr = makepcode(PC_EXTSH, reg, reg2); else newInstr = makepcode(PC_RLWINM, reg, reg2, 0, 16, 31); break; case PC_LWZ: newInstr = makepcode(PC_MR, reg2, reg); break; case PC_STW: newInstr = makepcode(PC_MR, reg, reg2); break; case PC_LFD: newInstr = makepcode(PC_FMR, reg2, reg); break; case PC_STFD: newInstr = makepcode(PC_FMR, reg, reg2); break; default: #line 2494 CError_FATAL(); break; } if (newInstr) { insertpcodebefore(instr, newInstr); deletepcode(instr); instr = newInstr; } } } } } } freeoheap(); } static void optimizenestedloops(Loop *loop) { while (loop) { if (loop->children) optimizenestedloops(loop->children); optimizeloop(loop); loop = loop->nextSibling; } } void optimizeloops(void) { optimizedloops = 0; optimizedloop_full_unroll = 0; optimizedloop_trans_regs = 0; if (loopsinflowgraph) { computeusedefchains(0); last_virtual_GPR = used_virtual_registers[RegClass_GPR]; liveonexit = oalloc(4 * ((used_virtual_registers[RegClass_GPR] + 31) >> 5)); inductionvariables = oalloc(4 * ((last_virtual_GPR + 31) >> 5)); optimizenestedloops(loopsinflowgraph); freeoheap(); } }