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// ============================================================================ // __ // \\__/ o\ (C) 2017-2018 Robert Finch, Waterloo // \ __ / All rights reserved. // \/_// robfinch<remove>@finitron.ca // || // // CC64 - 'C' derived language compiler // - 64 bit CPU // // This source file is free software: you can redistribute it and/or modify // it under the terms of the GNU Lesser General Public License as published // by the Free Software Foundation, either version 3 of the License, or // (at your option) any later version. // // This source file is distributed in the hope that it will be useful, // but WITHOUT ANY WARRANTY; without even the implied warranty of // MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the // GNU General Public License for more details. // // You should have received a copy of the GNU General Public License // along with this program. If not, see <http://www.gnu.org/licenses/>. // // ============================================================================ // #include "stdafx.h" void CSETable::Assign(CSETable *t) { memcpy(this, t, sizeof(CSETable)); } static int CSECmp(const void *a, const void *b) { CSE *csp1, *csp2; int aa, bb; csp1 = (CSE *)a; csp2 = (CSE *)b; aa = csp1->OptimizationDesireability(); bb = csp2->OptimizationDesireability(); if (aa < bb) return (1); else if (aa == bb) return (0); else return (-1); } void CSETable::Sort(int(*cmp)(const void *a, const void *b)) { qsort(table, (size_t)csendx, sizeof(CSE), cmp); } // InsertNodeIntoCSEList will enter a reference to an expression node into the // common expression table. duse is a flag indicating whether or not // this reference will be dereferenced. CSE *CSETable::InsertNode(ENODE *node, int duse) { CSE *csp; if ((csp = Search(node)) == nullptr) { /* add to tree */ if (csendx > 499) throw new C64PException(ERR_CSETABLE, 0x01); csp = &table[csendx]; csendx++; if (loop_active > 1) { csp->uses = (loop_active - 1) * 5; csp->duses = (duse != 0) * ((loop_active - 1) * 5); } else { csp->uses = 1; csp->duses = (duse != 0); } csp->exp = node->Clone(); csp->voidf = 0; csp->reg = 0; csp->isfp = csp->exp->IsFloatType(); return (csp); } if (loop_active < 2) { (csp->uses)++; if (duse) (csp->duses)++; } else { (csp->uses) += ((loop_active - 1) * 5); if (duse) (csp->duses) += ((loop_active - 1) * 5); } return (csp); } // // SearchCSEList will search the common expression table for an entry // that matches the node passed and return a pointer to it. // CSE *CSETable::Search(ENODE *node) { int cnt; for (cnt = 0; cnt < csendx; cnt++) { if (ENODE::IsEqual(node, table[cnt].exp)) return (&table[cnt]); } return ((CSE *)nullptr); } // voidauto2 searches the entire CSE table for auto dereferenced node which // point to the passed node. There might be more than one LValue that matches. // voidauto will void an auto dereference node which points to // the same auto constant as node. // int CSETable::voidauto2(ENODE *node) { int uses; bool voided; int cnt; uses = 0; voided = false; for (cnt = 0; cnt < csendx; cnt++) { if (IsLValue(table[cnt].exp) && ENODE::IsEqual(node, table[cnt].exp->p[0])) { table[cnt].voidf = 1; voided = true; uses += table[cnt].uses; } } return (voided ? uses : -1); } // Make multiple passes over the CSE table in order to use // up all temporary registers. Allocates on the progressively // less desirable. int CSETable::AllocateGPRegisters() { CSE *csp; bool alloc; int pass; int reg; reg = regFirstRegvar; for (pass = 0; pass < 4; pass++) { for (csp = First(); csp; csp = Next()) { if (csp->OptimizationDesireability() != 0) { if (!csp->voidf && csp->reg == -1) { if (csp->exp->etype != bt_vector && !csp->isfp) { switch (pass) { case 0: case 1: case 2: alloc = (csp->OptimizationDesireability() >= 4) && reg < regLastRegvar; break; case 3: alloc = (csp->OptimizationDesireability() >= 4) && reg < regLastRegvar; break; } if (alloc) csp->reg = reg++; else csp->reg = -1; } } } } } return (reg); } int CSETable::AllocateFPRegisters() { CSE *csp; bool alloc; int pass; int reg; reg = regFirstRegvar; for (pass = 0; pass < 4; pass++) { for (csp = First(); csp; csp = Next()) { if (csp->OptimizationDesireability() != 0) { if (!csp->voidf && csp->reg == -1) { if (csp->isfp) { switch (pass) { case 0: case 1: case 2: alloc = (csp->OptimizationDesireability() >= 4) && reg < regLastRegvar; break; case 3: alloc = (csp->OptimizationDesireability() >= 4) && reg < regLastRegvar; break; // if(( csp->duses > csp->uses / (8 << nn)) && reg < regLastRegvar ) // <- address register assignments } if (alloc) csp->reg = reg++; else csp->reg = -1; } } } } } return (reg); } int CSETable::AllocateVectorRegisters() { int nn, vreg; CSE *csp; bool alloc; vreg = regFirstRegvar; for (nn = 0; nn < 4; nn++) { for (csp = First(); csp; csp = Next()) { if (csp->exp) { if (csp->exp->etype == bt_vector && csp->reg == -1 && vreg < regLastRegvar) { switch (nn) { case 0: case 1: case 2: alloc = (csp->OptimizationDesireability() >= 4 - nn) && (csp->duses > csp->uses / (8 << nn)); break; case 3: alloc = (!csp->voidf) && (csp->uses > 3); break; } if (alloc) csp->reg = vreg++; else csp->reg = -1; } } } } return (vreg); } void CSETable::InitializeTempRegs() { Operand *ap, *ap2, *ap3; CSE *csp; ENODE *exptr; int size; for (csp = First(); csp; csp = Next()) { if (csp->reg != -1) { // see if preload needed exptr = csp->exp; if (1 || !IsLValue(exptr) || (exptr->p[0]->i > 0)) { initstack(); { ap = GenerateExpression(exptr, F_REG | F_IMMED | F_MEM | F_FPREG, sizeOfWord); ap2 = csp->isfp ? makefpreg(csp->reg) : makereg(csp->reg); if (csp->isfp) ap2->type = ap->type; ap2->isPtr = ap->isPtr; if (ap->mode == am_imm) { if (ap2->mode == am_fpreg) { ap3 = GetTempRegister(); GenLdi(ap3, ap); GenerateDiadic(op_mov, 0, ap2, ap3); ReleaseTempReg(ap3); } else GenLdi(ap2, ap); } else if (ap->mode == am_reg) GenerateDiadic(op_mov, 0, ap2, ap); else { size = GetNaturalSize(exptr); ap->isUnsigned = exptr->isUnsigned; GenLoad(ap2, ap, size, size); } } ReleaseTempReg(ap); } } } } void CSETable::GenerateRegMask(CSE *csp, uint64_t *mask, uint64_t *rmask) { if (csp->reg != -1) { *rmask = *rmask | (1LL << (63 - csp->reg)); *mask = *mask | (1LL << csp->reg); } } // ---------------------------------------------------------------------------- // AllocateRegisterVars will allocate registers for the expressions that have // a high enough desirability. // ---------------------------------------------------------------------------- int CSETable::AllocateRegisterVars() { CSE *csp; uint64_t mask, rmask; uint64_t fpmask, fprmask; uint64_t vmask, vrmask; mask = 0; rmask = 0; fpmask = 0; fprmask = 0; vmask = 0; vrmask = 0; // Sort the CSE table according to desirability of allocating // a register. if (pass == 1) Sort(CSECmp); // Initialize to no allocated registers for (csp = First(); csp; csp = Next()) csp->reg = -1; AllocateGPRegisters(); AllocateFPRegisters(); AllocateVectorRegisters(); // Generate bit masks of allocated registers for (csp = First(); csp; csp = Next()) { if (csp->exp) { if (csp->exp->IsFloatType()) GenerateRegMask(csp, &fpmask, &fprmask); else if (csp->exp->etype == bt_vector) GenerateRegMask(csp, &vrmask, &vmask); else GenerateRegMask(csp, &mask, &rmask); } else GenerateRegMask(csp, &mask, &rmask); } Dump(); // Push temporaries on the stack. SaveRegisterVars(mask, rmask); SaveFPRegisterVars(fpmask, fprmask); save_mask = mask; fpsave_mask = fpmask; InitializeTempRegs(); return (popcnt(mask)); } /* * opt1 is the externally callable optimization routine. it will * collect and allocate common subexpressions and substitute the * tempref for all occurrances of the expression within the block. */ int CSETable::Optimize(Statement *block) { int nn; //csendx = 0; dfs.printf("<CSETable__Optimize>"); nn = 0; if (pass == 1) { if (currentFn->csetbl == nullptr) { currentFn->csetbl = new CSETable; } Clear(); } else if (pass == 2) { //Assign(currentFn->csetbl); } dfs.printf("Pass:%d ", pass); if (opt_noregs == FALSE) { if (pass == 1) block->scan(); /* collect expressions */ nn = AllocateRegisterVars(); if (pass == 2) block->repcse(); /* replace allocated expressions */ } if (pass == 1) ;// currentFn->csetbl->Assign(pCSETable); else if (pass == 2) { if (currentFn->csetbl && !currentFn->IsInline) { delete currentFn->csetbl; currentFn->csetbl = nullptr; } } dfs.printf("</CSETable__Optimize>\n"); return (nn); } // Immediate constants have low priority. // Even though their use might be high, they are given a low priority. void CSETable::Dump() { int nn; CSE *csp; dfs.printf("<CSETable>For %s\n", (char *)currentFn->sym->name->c_str()); dfs.printf( "*The expression must be used three or more times before it will be allocated\n" "to a register.\n"); dfs.printf("N OD Uses DUses Void Reg Sym\n"); for (nn = 0; nn < csendx; nn++) { csp = &table[nn]; dfs.printf("%d: ", nn); dfs.printf("%d ", csp->OptimizationDesireability()); dfs.printf("%d ", csp->uses); dfs.printf("%d ", csp->duses); dfs.printf("%d ", (int)csp->voidf); dfs.printf("%d ", csp->reg); if (csp->exp && csp->exp->sym) dfs.printf("%s ", (char *)csp->exp->sym->name->c_str()); if (csp->exp && csp->exp->sp) dfs.printf("%s ", (char *)((std::string *)(csp->exp->sp))->c_str()); dfs.printf("\n"); } dfs.printf("</CSETable>\n"); }