#include "compiler/IroCSE.h" #include "compiler/IroDump.h" #include "compiler/IroFlowgraph.h" #include "compiler/IroLinearForm.h" #include "compiler/IroMalloc.h" #include "compiler/IroPointerAnalysis.h" #include "compiler/IroSubable.h" #include "compiler/IroUtil.h" #include "compiler/IroVars.h" #include "compiler/CError.h" #include "compiler/CExpr.h" #include "compiler/CInt64.h" #include "compiler/CParser.h" #include "compiler/CompilerTools.h" #include "compiler/objects.h" BitVector *IRO_Depends; Boolean IRO_NotSubable; Boolean IRO_IsVolatile; Boolean IRO_CouldError; IROExpr *IRO_FirstExpr; IROExpr *IRO_LastExpr; SInt32 IRO_NumExprs; static Boolean HasVectorOperand; // forward decls static void IRO_DependsOnForDataFlow(IROLinear *linear, Boolean flag); static void GetDependsOfIndirect(IROLinear *nd) { IROListNode *resultList; IROListNode *next; IROListNode *list; IROListNode *scan; IROLinear *scannd; Object *obj; VarRecord *var; int index; Boolean result; Boolean foundObjRef; result = 0; if (nd && copts.opt_pointer_analysis && nd->pointsToFunction && FunctionName) { resultList = NULL; PointerAnalysis_LookupLinearNodePointerExpr(FunctionName, nd, &resultList); if ((list = resultList)) { for (scan = list; scan; scan = scan->nextList) { if (!scan->list.head || !scan->list.tail) { result = 1; break; } foundObjRef = 0; for (scannd = scan->list.head; scannd != scan->list.tail->next; scannd = scannd->next) { if (scannd->type == IROLinearOperand && scannd->u.node->type == EOBJREF) { foundObjRef = 1; break; } } if (!foundObjRef) { result = 1; break; } } if (!result) { while (list) { for (scannd = list->list.head; scannd != list->list.tail->next; scannd = scannd->next) { if (scannd->type == IROLinearOperand && scannd->u.node->type == EOBJREF) { obj = scannd->u.node->data.objref; #line 119 CError_ASSERT(obj != NULL); var = IRO_FindVar(obj, 1, 1); #line 121 CError_ASSERT(var != NULL); index = var->index; #line 123 CError_ASSERT(index != 0); if (is_volatile_object(obj)) { IRO_IsVolatile = 1; IRO_NotSubable = 1; } Bv_SetBit(index, IRO_Depends); } } list = list->nextList; } } while (resultList) { next = resultList->nextList; IRO_free(resultList); resultList = next; } } else { result = 1; } } else { result = 1; } if (result) { nd = nd->u.monadic; if (nd->type == IROLinearOp1Arg && nd->nodetype == EBITFIELD) nd = nd->u.monadic; if (nd->type == IROLinearOp2Arg && nd->nodetype == EADD) { IRO_BaseTerms = 0; IRO_VarTerms = 0; IRO_DecomposeAddressExpression_Cheap(nd); if (IRO_BaseTerms != 1) { IRO_CouldError = 1; Bv_SetBit(0, IRO_Depends); Bv_Or(IRO_FuncKills, IRO_Depends); } if (IRO_VarTerms) IRO_CouldError = 1; } else { IRO_CouldError = 1; Bv_SetBit(0, IRO_Depends); Bv_Or(IRO_FuncKills, IRO_Depends); } } } static void GetDependsOfFunctionCallForDataFlow(IROLinear *nd) { IROLinear *innernd; IROListNode *resultList; IROListNode *next; IROListNode *list; IROListNode *scan; IROLinear *scannd; Object *obj; VarRecord *var; int index; Boolean result; Boolean foundObjRef; ObjectList *olist; ObjectList *depsList; result = 0; innernd = nd->u.funccall.linear8; if (innernd && copts.opt_pointer_analysis && innernd->pointsToFunction && FunctionName) { resultList = NULL; PointerAnalysis_LookupLinearNodePointerExpr(FunctionName, innernd, &resultList); if ((list = resultList)) { for (scan = list; scan; scan = scan->nextList) { if (!scan->list.head || !scan->list.tail) { result = 1; break; } foundObjRef = 0; for (scannd = scan->list.head; scannd != scan->list.tail->next; scannd = scannd->next) { if (scannd->type == IROLinearOperand && scannd->u.node->type == EOBJREF) { foundObjRef = 1; obj = scannd->u.node->data.objref; #line 234 CError_ASSERT(obj != NULL); depsList = NULL; PointerAnalysis_GetFunctionDependencies(obj, nd, &depsList); for (olist = depsList; olist; olist = olist->next) { if (!olist->object) { result = 1; break; } } while (depsList) { olist = depsList->next; IRO_free(depsList); depsList = olist; } if (result) break; } } if (!foundObjRef) result = 1; if (result) break; } if (!result) { for (list = resultList; list; list = list->nextList) { for (scannd = list->list.head; scannd != list->list.tail->next; scannd = scannd->next) { if (scannd->type == IROLinearOperand && scannd->u.node->type == EOBJREF) { obj = scannd->u.node->data.objref; depsList = NULL; PointerAnalysis_GetFunctionDependencies(obj, nd, &depsList); for (olist = depsList; olist; olist = olist->next) { var = IRO_FindVar(olist->object, 1, 1); #line 285 CError_ASSERT(var != NULL); index = var->index; #line 287 CError_ASSERT(index != 0); if (is_volatile_object(olist->object)) { IRO_IsVolatile = 1; IRO_NotSubable = 1; } Bv_SetBit(index, IRO_Depends); } while (depsList) { olist = depsList->next; IRO_free(depsList); depsList = olist; } } } } } while (resultList) { next = resultList->nextList; IRO_free(resultList); resultList = next; } } else { result = 1; } } else { result = 1; } if (result) { IRO_DependsOnForDataFlow(nd->u.funccall.linear8, 0); Bv_Or(IRO_FuncKills, IRO_Depends); for (index = nd->u.funccall.argCount - 1; index >= 0; index--) IRO_DependsOnForDataFlow(nd->u.funccall.args[index], 0); } } static void IRO_DependsOn(IROLinear *linear, Boolean flag) { VarRecord *var; IROLinear *inner; if (linear->rtype && CParser_IsVolatile(linear->rtype, linear->nodeflags & ENODE_FLAG_QUALS)) { IRO_IsVolatile = 1; IRO_NotSubable = 1; } if (!IRO_NotSubable) { switch (linear->type) { case IROLinearOperand: if (flag && linear->u.node->type == EOBJREF) { if ((var = IRO_FindVar(linear->u.node->data.objref, 0, 1))) { if (is_volatile_object(var->object)) { IRO_IsVolatile = 1; IRO_NotSubable = 1; } Bv_SetBit(var->index, IRO_Depends); } else { IRO_NotSubable = 1; } } break; case IROLinearOp1Arg: if (IRO_IsAssignOp[linear->nodetype]) { IRO_NotSubable = 1; } else { inner = linear->u.monadic; if (linear->nodetype == EINDIRECT) { if (inner->type == IROLinearOp1Arg && inner->nodetype == EBITFIELD) inner = inner->u.monadic; if (inner->type != IROLinearOperand || inner->u.node->type != EOBJREF) GetDependsOfIndirect(linear); } IRO_DependsOn(inner, linear->nodetype == EINDIRECT); } break; case IROLinearOp2Arg: if (IRO_IsAssignOp[linear->nodetype]) { IRO_NotSubable = 1; } else { if (linear->nodetype == EDIV || linear->nodetype == EMODULO) { if (IRO_IsIntConstant(linear->u.diadic.right)) { if (CInt64_Equal(linear->u.diadic.right->u.node->data.intval, cint64_zero)) IRO_CouldError = 1; } else { IRO_CouldError = 1; } } IRO_DependsOn(linear->u.diadic.left, flag); IRO_DependsOn(linear->u.diadic.right, flag); } break; case IROLinearOp3Arg: if (IRO_IsAssignOp[linear->nodetype]) { IRO_NotSubable = 1; } else { IRO_DependsOn(linear->u.args3.a, flag); IRO_DependsOn(linear->u.args3.b, flag); IRO_DependsOn(linear->u.args3.c, flag); } break; case IROLinearFunccall: IRO_NotSubable = 1; break; default: #line 479 CError_FATAL(); } } } static void IRO_DependsOnForDataFlow(IROLinear *linear, Boolean flag) { VarRecord *var; IROLinear *inner; if (linear->rtype && CParser_IsVolatile(linear->rtype, linear->nodeflags & ENODE_FLAG_QUALS)) { IRO_IsVolatile = 1; IRO_NotSubable = 1; } switch (linear->type) { case IROLinearOperand: if (flag && linear->u.node->type == EOBJREF) { if ((var = IRO_FindVar(linear->u.node->data.objref, 0, 1))) { if (is_volatile_object(var->object)) { IRO_IsVolatile = 1; IRO_NotSubable = 1; } Bv_SetBit(var->index, IRO_Depends); } else { IRO_NotSubable = 1; } } break; case IROLinearOp1Arg: if (IRO_IsAssignOp[linear->nodetype]) IRO_NotSubable = 1; inner = linear->u.monadic; if (linear->nodetype == EINDIRECT) { if (inner->type == IROLinearOp1Arg && inner->nodetype == EBITFIELD) inner = inner->u.monadic; if (inner->type != IROLinearOperand || inner->u.node->type != EOBJREF) GetDependsOfIndirect(linear); } IRO_DependsOnForDataFlow(inner, linear->nodetype == EINDIRECT); break; case IROLinearOp2Arg: if (IRO_IsAssignOp[linear->nodetype]) IRO_NotSubable = 1; if (linear->nodetype == EDIV || linear->nodetype == EMODULO) { if (IRO_IsIntConstant(linear->u.diadic.right)) { if (CInt64_Equal(linear->u.diadic.right->u.node->data.intval, cint64_zero)) IRO_CouldError = 1; } else { IRO_CouldError = 1; } } IRO_DependsOnForDataFlow(linear->u.diadic.left, flag); IRO_DependsOnForDataFlow(linear->u.diadic.right, flag); break; case IROLinearOp3Arg: if (IRO_IsAssignOp[linear->nodetype]) IRO_NotSubable = 1; IRO_DependsOnForDataFlow(linear->u.args3.a, flag); IRO_DependsOnForDataFlow(linear->u.args3.b, flag); IRO_DependsOnForDataFlow(linear->u.args3.c, flag); break; case IROLinearFunccall: IRO_NotSubable = 1; GetDependsOfFunctionCallForDataFlow(linear); break; default: #line 650 CError_FATAL(); } } void IRO_FindDepends_NoAlloc(IROLinear *linear) { Bv_Clear(IRO_Depends); IRO_CouldError = 0; IRO_NotSubable = 0; IRO_IsVolatile = 0; IRO_DependsOnForDataFlow(linear, 0); } void IRO_FindDepends(IROLinear *linear) { Bv_AllocVector(&IRO_Depends, IRO_NumVars + 1); IRO_CouldError = 0; IRO_NotSubable = 0; IRO_DependsOn(linear, 0); } static void VecAct(IROLinear *linear, Boolean isFirst) { if (!isFirst && (linear->flags & IROLF_VecOpBase)) HasVectorOperand = 1; } static Boolean IRO_DoesNotHaveVectorOperand(IROLinear *linear) { HasVectorOperand = 0; IRO_WalkTree(linear, VecAct); return HasVectorOperand == 0; } static void IRO_AddExpression(IROLinear *linear, IRONode *node, Boolean flag) { IROExpr *expr; if ((linear->flags & IROLF_Reffed) && IRO_IsSubableExpression(linear) && IRO_DoesNotHaveVectorOperand(linear)) { expr = oalloc(sizeof(IROExpr)); expr->x0 = 0; expr->index = ++IRO_NumExprs; expr->linear = linear; expr->x8 = NULL; expr->node = node; IRO_FindDepends(linear); expr->depends = IRO_Depends; expr->notSubable = IRO_NotSubable; expr->couldError = IRO_CouldError; expr->next = NULL; expr->x14 = NULL; if (IRO_FirstExpr) IRO_LastExpr->next = expr; else IRO_FirstExpr = expr; IRO_LastExpr = expr; linear->expr = expr; } } void IRO_FindExpressions(BitVector *bv, Boolean flag) { IROLinear *nd; IRONode *fnode; IRO_FirstExpr = IRO_LastExpr = NULL; IRO_NumExprs = 0; for (fnode = IRO_FirstNode; fnode; fnode = fnode->nextnode) { if (!bv || Bv_IsBitSet(fnode->index, bv)) { for (nd = fnode->first; nd; nd = nd->next) { nd->expr = NULL; IRO_AddExpression(nd, fnode, flag); if (nd == fnode->last) break; } } else { for (nd = fnode->first; nd; nd = nd->next) { nd->expr = NULL; if (nd == fnode->last) break; } } } IRO_CheckForUserBreak(); } void IRO_RemoveExpr(IROExpr *expr) { IROExpr *prev; IROExpr *scan; scan = IRO_FirstExpr; prev = NULL; while (scan != expr) { prev = scan; scan = scan->next; #line 809 CError_ASSERT(scan); } expr->linear->expr = NULL; if (prev) prev->next = expr->next; else IRO_FirstExpr = expr->next; } static void GetExprKillsByIndirectAssignment(IROLinear *linear) { IROLinear *inner; IROListNode *resultList; IROListNode *next; IROListNode *list; IROListNode *scan; IROLinear *scannd; Object *obj; VarRecord *var; int index; Boolean result; Boolean foundObjRef; IROExpr *expr; result = 0; if (linear->type == IROLinearOp2Arg) linear = linear->u.diadic.left; else linear = linear->u.monadic; if ( linear && linear->type == IROLinearOp1Arg && linear->nodetype == EINDIRECT && (inner = linear->u.monadic) && copts.opt_pointer_analysis && inner->pointsToFunction && FunctionName ) { resultList = NULL; PointerAnalysis_LookupLinearNodePointerExpr(FunctionName, inner, &resultList); if ((list = resultList)) { for (scan = list; scan; scan = scan->nextList) { if (!scan->list.head || !scan->list.tail) { result = 1; break; } foundObjRef = 0; for (scannd = scan->list.head; scannd != scan->list.tail->next; scannd = scannd->next) { if (scannd->type == IROLinearOperand && scannd->u.node->type == EOBJREF) { foundObjRef = 1; break; } } if (!foundObjRef) { result = 1; break; } } if (!result) { while (list) { for (scannd = list->list.head; scannd != list->list.tail->next; scannd = scannd->next) { if (scannd->type == IROLinearOperand && scannd->u.node->type == EOBJREF) { obj = scannd->u.node->data.objref; #line 893 CError_ASSERT(obj != NULL); var = IRO_FindVar(obj, 1, 1); #line 895 CError_ASSERT(var != NULL); index = var->index; for (expr = IRO_FirstExpr; expr; expr = expr->next) { if (Bv_IsBitSet(index, expr->depends)) Bv_SetBit(expr->index, IRO_ExprKills); } } } list = list->nextList; } } while (resultList) { next = resultList->nextList; IRO_free(resultList); resultList = next; } } else { result = 1; } } else { result = 1; } if (result) { for (expr = IRO_FirstExpr; expr; expr = expr->next) { if (Bv_BitsInCommon(expr->depends, IRO_FuncKills)) Bv_SetBit(expr->index, IRO_ExprKills); } } } static void GetExprKillsByFunctionCall(IROLinear *funccall) { IROLinear *innernd; IROListNode *resultList; IROListNode *next; IROListNode *list; IROListNode *scan; IROLinear *scannd; Object *obj; VarRecord *var; int index; Boolean result; Boolean foundObjRef; ObjectList *olist; ObjectList *depsList; IROExpr *expr; result = 0; innernd = funccall->u.funccall.linear8; if (innernd && copts.opt_pointer_analysis && innernd->pointsToFunction && FunctionName) { resultList = NULL; PointerAnalysis_LookupLinearNodePointerExpr(FunctionName, innernd, &resultList); if ((list = resultList)) { for (scan = list; scan; scan = scan->nextList) { if (!scan->list.head || !scan->list.tail) { result = 1; break; } foundObjRef = 0; for (scannd = scan->list.head; scannd != scan->list.tail->next; scannd = scannd->next) { if (scannd->type == IROLinearOperand && scannd->u.node->type == EOBJREF) { foundObjRef = 1; obj = scannd->u.node->data.objref; #line 991 CError_ASSERT(obj != NULL); depsList = NULL; PointerAnalysis_GetFunctionKills(obj, funccall, &depsList); for (olist = depsList; olist; olist = olist->next) { if (!olist->object) { result = 1; break; } } while (depsList) { olist = depsList->next; IRO_free(depsList); depsList = olist; } if (result) break; } } if (!foundObjRef) result = 1; if (result) break; } if (!result) { for (list = resultList; list; list = list->nextList) { for (scannd = list->list.head; scannd != list->list.tail->next; scannd = scannd->next) { if (scannd->type == IROLinearOperand && scannd->u.node->type == EOBJREF) { obj = scannd->u.node->data.objref; depsList = NULL; PointerAnalysis_GetFunctionKills(obj, funccall, &depsList); for (olist = depsList; olist; olist = olist->next) { var = IRO_FindVar(olist->object, 1, 1); #line 1042 CError_ASSERT(var != NULL); index = var->index; #line 1044 CError_ASSERT(index != 0); for (expr = IRO_FirstExpr; expr; expr = expr->next) { if (Bv_IsBitSet(index, expr->depends)) Bv_SetBit(expr->index, IRO_ExprKills); } } while (depsList) { olist = depsList->next; IRO_free(depsList); depsList = olist; } } } } } while (resultList) { next = resultList->nextList; IRO_free(resultList); resultList = next; } } else { result = 1; } } else { result = 1; } if (result) { for (expr = IRO_FirstExpr; expr; expr = expr->next) { if (Bv_BitsInCommon(expr->depends, IRO_FuncKills)) Bv_SetBit(expr->index, IRO_ExprKills); } } } static void IRO_GetExprKills(IROLinear *linear) { Bv_Clear(IRO_ExprKills); switch (linear->type) { case IROLinearOp1Arg: case IROLinearOp2Arg: if (IRO_IsAssignOp[linear->nodetype]) { VarRecord *var; int index; var = IRO_FindAssigned(linear); index = 0; if (var) index = var->index; if (!index) { GetExprKillsByIndirectAssignment(linear); } else { IROExpr *expr; for (expr = IRO_FirstExpr; expr; expr = expr->next) { if (Bv_IsBitSet(index, expr->depends)) Bv_SetBit(expr->index, IRO_ExprKills); } } } break; case IROLinearAsm: { IROExpr *expr; IRO_GetKills(linear); for (expr = IRO_FirstExpr; expr; expr = expr->next) { if (Bv_BitsInCommon(expr->depends, IRO_VarKills)) Bv_SetBit(expr->index, IRO_ExprKills); } break; } case IROLinearFunccall: GetExprKillsByFunctionCall(linear); break; } } void IRO_ComputeAvail(void) { IRONode *node; IROLinear *linear; SInt32 counter; BitVector *bv; Boolean flag; counter = 0; node = IRO_FirstNode; Bv_AllocVector(&IRO_VarKills, IRO_NumVars + 1); Bv_AllocVector(&IRO_ExprKills, IRO_NumExprs + 1); while (node) { Bv_AllocVector(&node->x16, IRO_NumExprs); if (node->numpred) Bv_Set(node->x16); Bv_AllocVector(&node->x22, IRO_NumExprs); Bv_AllocVector(&node->x1E, IRO_NumExprs); Bv_AllocVector(&node->x1A, IRO_NumExprs); for (linear = node->first; linear; linear = linear->next) { if (linear->expr) Bv_SetBit(linear->expr->index, node->x1E); IRO_GetExprKills(linear); Bv_Or(IRO_ExprKills, node->x22); Bv_Minus(IRO_ExprKills, node->x1E); if (linear == node->last) break; if (counter > 250) { IRO_CheckForUserBreak(); counter = 0; } else { counter++; } } Bv_Copy(node->x16, node->x1A); Bv_Minus(node->x22, node->x1A); Bv_Or(node->x1E, node->x1A); node = node->nextnode; } IRO_CheckForUserBreak(); Bv_AllocVector(&bv, IRO_NumExprs); do { flag = 0; for (node = IRO_FirstNode; node; node = node->nextnode) { if (!node->numpred) { Bv_Clear(bv); } else { UInt16 i; Bv_Set(bv); for (i = 0; i < node->numpred; i++) Bv_And(IRO_NodeTable[node->pred[i]]->x1A, bv); } if (!Bv_Compare(bv, node->x16)) { flag = 1; Bv_Copy(bv, node->x16); } Bv_Copy(node->x16, node->x1A); Bv_Minus(node->x22, node->x1A); Bv_Or(node->x1E, node->x1A); } IRO_CheckForUserBreak(); } while (flag); } static void IRO_MakeReplacementEmbedded(IROExpr *expr) { IROLinear *opnd; IROLinear *ind; IROLinear *ass; IRO_GetTemp(expr); opnd = IRO_NewLinear(IROLinearOperand); opnd->u.node = create_objectrefnode(expr->x8); opnd->rtype = opnd->u.node->data.objref->type; opnd->index = ++IRO_NumLinear; opnd->flags |= IROLF_Reffed | IROLF_Assigned | IROLF_Ind; ind = IRO_NewLinear(IROLinearOp1Arg); ind->nodetype = EINDIRECT; ind->rtype = expr->linear->rtype; ind->u.monadic = opnd; ind->index = ++IRO_NumLinear; ind->flags |= IROLF_Reffed | IROLF_Assigned; ass = IRO_NewLinear(IROLinearOp2Arg); ass->nodetype = EASS; ass->u.diadic.left = ind; ass->u.diadic.right = expr->linear; ass->rtype = expr->linear->rtype; ass->index = ++IRO_NumLinear; opnd->next = ind; ind->next = ass; IRO_ReplaceReferenceWithNode(expr->linear, ass); IRO_PasteAfter(opnd, ass, expr->linear); } static void IRO_ActUnmarkSubExpressions(IROLinear *linear, Boolean isFirst) { if (isFirst) linear->flags &= ~IROLF_8; } static void CheckCommonSub(IROLinear *linear) { IROExpr *expr; for (expr = IRO_FirstExpr; expr; expr = expr->next) { if (expr->linear != linear && !expr->x14) { if (Bv_IsBitSet(expr->index, IRO_Avail) && !expr->notSubable && IRO_ExprsSame(linear, expr->linear)) { IRO_WalkTree(linear, IRO_ActUnmarkSubExpressions); linear->flags |= IROLF_8; linear->expr->x14 = expr; break; } } } } static void MoveCommonSub(IROExpr *expr) { SInt32 best; SInt32 sz1; SInt32 sz2; SInt32 i1; SInt32 i2; IROLinear *scan; IROLinear *array1[64]; IROLinear *array2[64]; IROExpr *scanexpr; sz1 = 0; scan = expr->linear; do { scan = IRO_LocateFather(scan); if (scan) { if (sz1 == 64) return; array1[sz1++] = scan; } } while (scan); best = -1; for (scanexpr = IRO_FirstExpr; scanexpr; scanexpr = scanexpr->next) { if (scanexpr->x14 == expr) { sz2 = 0; scan = scanexpr->linear; do { scan = IRO_LocateFather(scan); if (scan) { if (sz2 == 64) return; array2[sz2++] = scan; } } while (scan); i1 = sz1; i2 = sz2; while (i1 && i2 && array1[sz1 - 1] == array2[sz2 - 1]) { i1--; i2--; } if (i1 != sz1 && i1 > best) best = i1; } } if (best < 0) { IRO_MakeReplacementEmbedded(expr); } else { IROLinear *start; IROLinear *comma; IRO_Dump("Moving common sub from node %d to %d\n", expr->linear->index, array1[best]->index); start = IRO_FindStart(array1[best]); IRO_GetTemp(expr); IRO_ReplaceReference(expr->linear, expr->x8, expr->linear); IRO_MoveExpression(expr, start); comma = IRO_NewLinear(IROLinearOp2Arg); comma->nodetype = ECOMMA; comma->rtype = array1[best]->rtype; comma->u.diadic.left = IRO_AssignToTemp(expr); comma->u.diadic.right = array1[best]; comma->stmt = array1[best]->stmt; IRO_ReplaceReferenceWithNode(array1[best], comma); IRO_PasteAfter(comma, comma, array1[best]); } } static void ReplaceCommonSub(IROLinear *linear) { IROExpr *expr = linear->expr->x14; if (!expr->x8) { MoveCommonSub(expr); if (!expr->x8) return; } IRO_Dump("Replacing common sub at %d with %d\n", linear->index, expr->linear->index); IRO_ReplaceReference(linear, expr->x8, linear); IRO_RemoveExpr(linear->expr); IRO_NopOut(linear); } void IRO_CommonSubs(void) { IRONode *node; IROLinear *linear; SInt32 counter; counter = 0; for (node = IRO_FirstNode; node; node = node->nextnode) { IRO_Avail = node->x16; linear = node->first; while (1) { if (!linear) break; if (linear->expr && !linear->expr->notSubable) CheckCommonSub(linear); if (linear->expr) Bv_SetBit(linear->expr->index, IRO_Avail); IRO_GetExprKills(linear); Bv_Minus(IRO_ExprKills, IRO_Avail); if (linear == node->last) break; if (counter > 250) { IRO_CheckForUserBreak(); counter = 0; } else { counter++; } linear = linear->next; } } for (node = IRO_FirstNode; node; node = node->nextnode) { for (linear = node->first; linear; linear = linear->next) { if (linear->expr && (linear->flags & IROLF_8) && !IRO_HasSideEffect(linear)) ReplaceCommonSub(linear); if (linear == node->last) break; if (counter > 250) { IRO_CheckForUserBreak(); counter = 0; } else { counter++; } } } IRO_CheckForUserBreak(); } static Boolean CountThisSubableOperandUse() { } static void GetSubableOperandUseCount() { } static void IRO_MakeTopLevelExprForSubableOperand(IROLinear *linear) { IROLinear *copy = IRO_NewLinear(IROLinearOperand); memcpy(copy, linear, sizeof(IROLinear)); copy->index = ++IRO_NumLinear; if (IRO_FirstLinear && IRO_FirstLinear->type == IROLinearNop) IRO_PasteAfter(copy, copy, IRO_FirstLinear); else IRO_Paste(copy, copy, IRO_FirstLinear); } void IRO_GenerateTopLevelExprsForSubableOperands(void) { IROLinear *nd; IRONode *fnode; VarRecord *var; BitVector *bv; Bv_AllocVector(&bv, IRO_NumVars + 1); for (fnode = IRO_FirstNode; fnode; fnode = fnode->nextnode) { for (nd = fnode->first; nd; nd = nd->next) { nd->expr = NULL; if ((nd->flags & IROLF_Reffed) && IRO_IsSubableExpression(nd) && IRO_DoesNotHaveVectorOperand(nd)) { if (nd->type == IROLinearOperand && nd->u.node && nd->u.node->type == EOBJREF) { if ((var = IRO_FindVar(nd->u.node->data.objref, 0, 1))) { if (!Bv_IsBitSet(var->index, bv)) { IRO_MakeTopLevelExprForSubableOperand(nd); Bv_SetBit(var->index, bv); } } } } if (nd == fnode->last) break; } } }