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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 swap_nodes(ENODE *node) { ENODE *temp; temp = node->p[0]; node->p[0] = node->p[1]; node->p[1] = temp; } bool ENODE::IsEqualOperand(Operand *a, Operand *b) { return (Operand::IsEqual(a, b)); }; char ENODE::fsize() { switch (etype) { case bt_float: return ('d'); case bt_double: return ('d'); case bt_triple: return ('t'); case bt_quad: return ('q'); default: return ('d'); } } long ENODE::GetReferenceSize() { switch (nodetype) /* get load size */ { case en_b_ref: case en_ub_ref: case en_bfieldref: case en_ubfieldref: return (1); case en_c_ref: case en_uc_ref: case en_cfieldref: case en_ucfieldref: return (2); case en_ref32: case en_ref32u: return (4); case en_h_ref: case en_uh_ref: case en_hfieldref: case en_uhfieldref: return (sizeOfWord / 2); case en_w_ref: case en_uw_ref: case en_wfieldref: case en_uwfieldref: return (sizeOfWord); case en_fpregvar: if (tp) return(tp->size); else return (sizeOfFPD); case en_tempref: case en_regvar: return (sizeOfWord); case en_dbl_ref: return (sizeOfFPD); case en_quad_ref: return (sizeOfFPQ); case en_flt_ref: return (sizeOfFPD); case en_triple_ref: return (sizeOfFPT); case en_hp_ref: return (sizeOfPtr >> 1); case en_wp_ref: return (sizeOfPtr); case en_vector_ref: return (512); // return node->esize; } return (8); } bool ENODE::IsBitfield() { return (nodetype == en_wfieldref || nodetype == en_bfieldref || nodetype == en_cfieldref || nodetype == en_hfieldref || nodetype == en_ubfieldref || nodetype == en_ucfieldref || nodetype == en_uhfieldref || nodetype == en_uwfieldref ); } // // equalnode will return 1 if the expressions pointed to by // node1 and node2 are equivalent. // bool ENODE::IsEqual(ENODE *node1, ENODE *node2) { if (node1 == nullptr || node2 == nullptr) { return (false); } if (node1->nodetype != node2->nodetype) { return (false); } switch (node1->nodetype) { case en_fcon: return (Float128::IsEqual(&node1->f128, &node2->f128)); // return (node1->f == node2->f); case en_regvar: case en_fpregvar: case en_tempref: case en_icon: case en_labcon: case en_classcon: // Check type ? case en_autocon: case en_autovcon: case en_autofcon: { return (node1->i == node2->i); } case en_nacon: { return (node1->sp->compare(*node2->sp) == 0); } case en_cnacon: return (node1->sp->compare(*node2->sp) == 0); default: if (IsLValue(node1) && IsEqual(node1->p[0], node2->p[0])) { // if( equalnode(node1->p[0], node2->p[0]) ) return (true); } } return (false); } ENODE *ENODE::Clone() { ENODE *temp; if (this == nullptr) return (ENODE *)nullptr; temp = allocEnode(); memcpy(temp, this, sizeof(ENODE)); // copy all the fields return (temp); } // repexpr will replace all allocated references within an expression // with tempref nodes. void ENODE::repexpr() { CSE *csp; if (this == nullptr) return; switch (nodetype) { case en_fcon: case en_autofcon: case en_tempfpref: if ((csp = currentFn->csetbl->Search(this)) != nullptr) { csp->isfp = TRUE; //**** a kludge if (csp->reg > 0) { nodetype = en_fpregvar; i = csp->reg; } } break; /* if( (csp = SearchCSEList(node)) != NULL ) { if( csp->reg > 0 ) { node->nodetype = en_fpregvar; node->i = csp->reg; } } break; */ case en_icon: case en_nacon: case en_labcon: case en_autovcon: case en_autocon: case en_classcon: case en_cnacon: case en_clabcon: case en_tempref: if ((csp = currentFn->csetbl->Search(this)) != NULL) { if (csp->reg > 0) { nodetype = en_regvar; i = csp->reg; } } break; case en_ref32: case en_ref32u: case en_b_ref: case en_c_ref: case en_h_ref: case en_w_ref: case en_ub_ref: case en_uc_ref: case en_uh_ref: case en_uw_ref: case en_wp_ref: case en_hp_ref: case en_bfieldref: case en_ubfieldref: case en_cfieldref: case en_ucfieldref: case en_hfieldref: case en_uhfieldref: case en_wfieldref: case en_uwfieldref: case en_vector_ref: if ((csp = currentFn->csetbl->Search(this)) != NULL) { if (csp->reg > 0) { nodetype = en_regvar; i = csp->reg; } else p[0]->repexpr(); } else p[0]->repexpr(); break; case en_dbl_ref: case en_flt_ref: case en_quad_ref: if ((csp = currentFn->csetbl->Search(this)) != NULL) { if (csp->reg > 0) { nodetype = en_fpregvar; i = csp->reg; } else p[0]->repexpr(); } else p[0]->repexpr(); break; case en_cbc: case en_cubw: case en_cbh: case en_cucw: case en_cbw: case en_cuhw: case en_cbu: case en_ccu: case en_chu: case en_cubu: case en_cucu: case en_cuhu: case en_ccwp: case en_cucwp: case en_cch: case en_ccw: case en_chw: case en_uminus: case en_abs: case en_sxb: case en_sxh: case en_sxc: case en_not: case en_compl: case en_chk: p[0]->repexpr(); break; case en_i2d: p[0]->repexpr(); break; case en_i2q: case en_d2i: case en_q2i: case en_s2q: case en_d2q: case en_t2q: p[0]->repexpr(); break; case en_add: case en_sub: case en_mul: case en_mulu: case en_div: case en_udiv: case en_mod: case en_umod: case en_shl: case en_asl: case en_shlu: case en_shru: case en_asr: case en_shr: case en_and: case en_or: case en_xor: case en_land: case en_lor: case en_eq: case en_ne: case en_lt: case en_le: case en_gt: case en_ge: case en_ult: case en_ule: case en_ugt: case en_uge: case en_feq: case en_fne: case en_flt: case en_fle: case en_fgt: case en_fge: case en_fdmul: case en_fddiv: case en_fdadd: case en_fdsub: case en_fadd: case en_fsub: case en_fmul: case en_fdiv: case en_veq: case en_vne: case en_vlt: case en_vle: case en_vgt: case en_vge: case en_vadd: case en_vsub: case en_vmul: case en_vdiv: case en_vadds: case en_vsubs: case en_vmuls: case en_vdivs: case en_cond: case en_void: case en_asadd: case en_assub: case en_asmul: case en_asmulu: case en_asdiv: case en_asdivu: case en_asor: case en_asand: case en_asxor: case en_asmod: case en_aslsh: case en_asrsh: case en_fcall: case en_list: case en_aggregate: case en_assign: p[0]->repexpr(); p[1]->repexpr(); break; case en_regvar: case en_fpregvar: break; case en_bchk: p[0]->repexpr(); p[1]->repexpr(); p[2]->repexpr(); break; default: dfs.printf("Uncoded node in repexr():%d\r\n", nodetype); } } /* * scanexpr will scan the expression pointed to by node for optimizable * subexpressions. when an optimizable expression is found it is entered * into the tree. if a reference to an autocon node is scanned the * corresponding auto dereferenced node will be voided. duse should be * set if the expression will be dereferenced. */ void ENODE::scanexpr(int duse) { CSE *csp, *csp1; int first; int nn; if (this == nullptr) return; switch (nodetype) { case en_fpregvar: case en_regvar: break; case en_cnacon: case en_clabcon: case en_fcon: case en_icon: case en_labcon: case en_nacon: currentFn->csetbl->InsertNode(this, duse); break; case en_autofcon: case en_tempfpref: csp1 = currentFn->csetbl->InsertNode(this, duse); csp1->isfp = TRUE; if ((nn = currentFn->csetbl->voidauto2(this)) > 0) { csp1->duses += loop_active; csp1->uses = csp1->duses + nn - loop_active; } break; case en_autovcon: case en_autocon: case en_classcon: case en_tempref: csp1 = currentFn->csetbl->InsertNode(this, duse); if ((nn = currentFn->csetbl->voidauto2(this)) > 0) { csp1->duses += loop_active; csp1->uses = csp1->duses + nn - loop_active; } break; case en_ref32: case en_ref32u: case en_b_ref: case en_c_ref: case en_h_ref: case en_w_ref: case en_ub_ref: case en_uc_ref: case en_uh_ref: case en_uw_ref: case en_flt_ref: case en_dbl_ref: case en_quad_ref: case en_bfieldref: case en_ubfieldref: case en_cfieldref: case en_ucfieldref: case en_hfieldref: case en_uhfieldref: case en_wfieldref: case en_uwfieldref: case en_wp_ref: case en_hp_ref: case en_vector_ref: // There is something wrong with the following code that causes // it to remove zero extension conversion from a byte to a word. if (p[0]->nodetype == en_autocon || p[0]->nodetype == en_autofcon || p[0]->nodetype == en_classcon || p[0]->nodetype == en_autovcon) { first = (currentFn->csetbl->Search(this) == nullptr); // Detect if this is the first insert csp = currentFn->csetbl->InsertNode(this, duse); if (csp->voidf) p[0]->scanexpr(1); // take care: the non-derereferenced use of the autocon node may // already be in the list. In this case, set voidf to 1 if (currentFn->csetbl->Search(p[0]) != NULL) { csp->voidf = 1; p[0]->scanexpr(1); } else { // if( csp->voidf ) // scanexpr(node->p[0],1); if (first) { ///* look for register nodes */ //int i = 0; //long j = node->p[0]->i; //if ((node->p[0]->nodetype== en_regvar || node->p[0]->nodetype==en_bregvar) && // (j >= 11 && j < 18)) //{ // csp->voidf--; /* this is not in auto_lst */ // //csp->uses += 90 * (100 - i); // //csp->duses += 30 * (100 - i); // break; //} ///* set voidf if the node is not in autolst */ //csp->voidf++; //i = 0; //while (i < autoptr) { // if (autolst[i] == j) { // csp->voidf--; // break; // } // ++i; //} /* * even if that item must not be put in a register, * it is legal to put its address therein */ //if (csp->voidf) // scanexpr(node->p[0], 1); //} //if( csp->voidf ) // scanexpr(node->p[0],1); } } } else p[0]->scanexpr(1); break; case en_cbc: case en_cubw: case en_cbh: case en_cucw: case en_cbw: case en_cuhw: case en_cbu: case en_ccu: case en_chu: case en_cubu: case en_cucu: case en_cuhu: case en_ccwp: case en_cucwp: case en_cch: case en_ccw: case en_chw: case en_uminus: case en_abs: case en_sxb: case en_sxc: case en_sxh: case en_zxb: case en_zxc: case en_zxh: case en_compl: case en_not: case en_chk: p[0]->scanexpr(duse); break; case en_i2d: p[0]->scanexpr(duse); break; case en_i2q: case en_d2i: case en_q2i: case en_s2q: case en_d2q: case en_t2q: p[0]->scanexpr(duse); break; case en_asadd: case en_assub: case en_add: case en_sub: p[0]->scanexpr(duse); p[1]->scanexpr(duse); break; case en_mul: case en_mulu: case en_div: case en_udiv: case en_shl: case en_asl: case en_shlu: case en_shr: case en_shru: case en_asr: case en_mod: case en_umod: case en_and: case en_or: case en_xor: case en_lor: case en_land: case en_eq: case en_ne: case en_gt: case en_ge: case en_lt: case en_le: case en_ugt: case en_uge: case en_ult: case en_ule: case en_feq: case en_fne: case en_flt: case en_fle: case en_fgt: case en_fge: case en_fdmul: case en_fddiv: case en_fdadd: case en_fdsub: case en_fadd: case en_fsub: case en_fmul: case en_fdiv: case en_veq: case en_vne: case en_vlt: case en_vle: case en_vgt: case en_vge: case en_vadd: case en_vsub: case en_vmul: case en_vdiv: case en_vadds: case en_vsubs: case en_vmuls: case en_vdivs: case en_asmul: case en_asmulu: case en_asdiv: case en_asdivu: case en_asmod: case en_aslsh: case en_asrsh: case en_asand: case en_asxor: case en_asor: case en_cond: case en_void: case en_list: case en_aggregate: p[0]->scanexpr(0); p[1]->scanexpr(0); break; case en_assign: p[0]->scanexpr(0); p[1]->scanexpr(0); break; case en_fcall: p[0]->scanexpr(1); p[1]->scanexpr(0); break; case en_bchk: p[0]->scanexpr(0); p[1]->scanexpr(0); p[2]->scanexpr(0); break; default: dfs.printf("Uncoded node in ENODE::scanexpr():%d\r\n", nodetype); } } // ---------------------------------------------------------------------------- // Generate code to evaluate an index node (^+) and return the addressing mode // of the result. This routine takes no flags since it always returns either // am_ind or am_indx. // // No reason to ReleaseTempReg() because the registers used are transported // forward. // ---------------------------------------------------------------------------- Operand *ENODE::GenIndex() { Operand *ap1, *ap2; if ((p[0]->nodetype == en_tempref || p[0]->nodetype == en_regvar) && (p[1]->nodetype == en_tempref || p[1]->nodetype == en_regvar)) { /* both nodes are registers */ // Don't need to free ap2 here. It is included in ap1. GenerateHint(8); ap1 = GenerateExpression(p[0], F_REG, 8); ap2 = GenerateExpression(p[1], F_REG, 8); GenerateHint(9); ap1->mode = am_indx2; ap1->sreg = ap2->preg; ap1->deep2 = ap2->deep2; ap1->offset = makeinode(en_icon, 0); ap1->scale = scale; return (ap1); } GenerateHint(8); ap1 = GenerateExpression(p[0], F_REG | F_IMMED, 8); if (ap1->mode == am_imm) { ap2 = GenerateExpression(p[1], F_REG | F_IMM0, 8); if (ap2->mode == am_imm) { // value is zero ap1->mode = am_direct; return (ap1); } GenerateHint(9); ap2->mode = am_indx; ap2->offset = ap1->offset; ap2->isUnsigned = ap1->isUnsigned; return (ap2); } ap2 = GenerateExpression(p[1], F_ALL, 8); /* get right op */ GenerateHint(9); if (ap2->mode == am_imm && ap1->mode == am_reg) /* make am_indx */ { ap2->mode = am_indx; ap2->preg = ap1->preg; ap2->deep = ap1->deep; return ap2; } if (ap2->mode == am_ind && ap1->mode == am_reg) { ap2->mode = am_indx2; ap2->sreg = ap1->preg; ap2->deep2 = ap1->deep; return ap2; } if (ap2->mode == am_direct && ap1->mode == am_reg) { ap2->mode = am_indx; ap2->preg = ap1->preg; ap2->deep = ap1->deep; return ap2; } // ap1->mode must be F_REG ap2->MakeLegal( F_REG, 8); ap1->mode = am_indx2; /* make indexed */ ap1->sreg = ap2->preg; ap1->deep2 = ap2->deep; ap1->offset = makeinode(en_icon, 0); ap1->scale = scale; return ap1; /* return indexed */ } // // Generate code to evaluate a condition operator node (?:) // Operand *ENODE::GenHook(int flags, int size) { Operand *ap1, *ap2, *ap3, *ap4; int false_label, end_label; OCODE *ip1; int n1; ENODE *node; false_label = nextlabel++; end_label = nextlabel++; flags = (flags & F_REG) | F_VOL; /* if (p[0]->constflag && p[1]->constflag) { GeneratePredicateMonadic(hook_predreg,op_op_ldi,make_immed(p[0]->i)); GeneratePredicateMonadic(hook_predreg,op_ldi,make_immed(p[0]->i)); } */ ip1 = peep_tail; if (!opt_nocgo) { ap4 = GetTempRegister(); ap1 = GenerateExpression(p[0], flags, size); ap2 = GenerateExpression(p[1]->p[0], flags, size); ap3 = GenerateExpression(p[1]->p[1], (flags & ~F_VOL) | F_IMMED, size); n1 = PeepCount(ip1); if (n1 < 20) { Generate4adic(op_cmovenz, 0, ap4, ap1, ap2, ap3); ReleaseTempReg(ap3); ReleaseTempReg(ap2); ReleaseTempReg(ap1); return (ap4); } ReleaseTempReg(ap3); ReleaseTempReg(ap2); ReleaseTempReg(ap1); ReleaseTempReg(ap4); peep_tail = ip1; peep_tail->fwd = nullptr; } ap2 = GenerateExpression(p[1]->p[1], flags, size); n1 = PeepCount(ip1); if (opt_nocgo) n1 = 9999; if (n1 > 4) { peep_tail = ip1; peep_tail->fwd = nullptr; } GenerateFalseJump(p[0], false_label, 0); node = p[1]; ap1 = GenerateExpression(node->p[0], flags, size); if (n1 > 4) GenerateDiadic(op_bra, 0, make_clabel(end_label), 0); else { if (!IsEqualOperand(ap1, ap2)) { GenerateMonadic(op_hint, 0, make_immed(2)); GenerateDiadic(op_mov, 0, ap2, ap1); } } GenerateLabel(false_label); if (n1 > 4) { ap2 = GenerateExpression(node->p[1], flags, size); if (!IsEqualOperand(ap1, ap2)) { GenerateMonadic(op_hint, 0, make_immed(2)); GenerateDiadic(op_mov, 0, ap1, ap2); } } if (n1 > 4) { ReleaseTempReg(ap2); GenerateLabel(end_label); return (ap1); } else { ReleaseTempReg(ap1); GenerateLabel(end_label); return (ap2); } } Operand *ENODE::GenShift(int flags, int size, int op) { Operand *ap1, *ap2, *ap3; ap3 = GetTempRegister(); ap1 = GenerateExpression(p[0], F_REG, size); ap2 = GenerateExpression(p[1], F_REG | F_IMM6, 8); GenerateTriadic(op, size, ap3, ap1, ap2); // Rotates automatically sign extend if ((op == op_rol || op == op_ror) && ap2->isUnsigned) switch (size) { case 1: GenerateDiadic(op_zxb, 0, ap3, ap3); break; case 2: GenerateDiadic(op_zxc, 0, ap3, ap3); break; case 4: GenerateDiadic(op_zxh, 0, ap3, ap3); break; default:; } ReleaseTempRegister(ap2); ReleaseTempRegister(ap1); ap3->MakeLegal(flags, size); return (ap3); } Operand *ENODE::GenAssignShift(int flags, int size, int op) { Operand *ap1, *ap2, *ap3; //size = GetNaturalSize(node->p[0]); ap3 = GenerateExpression(p[0], F_ALL & ~F_IMMED, size); ap2 = GenerateExpression(p[1], F_REG | F_IMM6, size); if (ap3->mode == am_reg) { GenerateTriadic(op, size, ap3, ap3, ap2); ReleaseTempRegister(ap2); ap3->MakeLegal(flags, size); return (ap3); } ap1 = GetTempRegister(); GenLoad(ap1, ap3, size, size); GenerateTriadic(op, size, ap1, ap1, ap2); GenStore(ap1, ap3, size); ReleaseTempRegister(ap1); ReleaseTempRegister(ap2); ap3->MakeLegal(flags, size); return (ap3); } // // generate code to evaluate a mod operator or a divide // operator. // Operand *ENODE::GenDivMod(int flags, int size, int op) { Operand *ap1, *ap2, *ap3; //if( node->p[0]->nodetype == en_icon ) //??? // swap_nodes(node); if (op == op_fdiv) { ap3 = GetTempFPRegister(); ap1 = GenerateExpression(p[0], F_FPREG, 8); ap2 = GenerateExpression(p[1], F_FPREG, 8); } else { ap3 = GetTempRegister(); ap1 = GenerateExpression(p[0], F_REG, 8); ap2 = GenerateExpression(p[1], F_REG | F_IMMED, 8); } if (op == op_fdiv) { // Generate a convert operation ? if (ap1->fpsize() != ap2->fpsize()) { if (ap2->fpsize() == 's') GenerateDiadic(op_fcvtsq, 0, ap2, ap2); } GenerateTriadic(op, ap1->fpsize(), ap3, ap1, ap2); } else GenerateTriadic(op, 0, ap3, ap1, ap2); // GenerateDiadic(op_ext,0,ap3,0); ap3->MakeLegal( flags, 2); ReleaseTempReg(ap2); ReleaseTempReg(ap1); return (ap3); } // // Generate code to evaluate a unary minus or complement. // Operand *ENODE::GenUnary(int flags, int size, int op) { Operand *ap, *ap2; if (IsFloatType()) { ap2 = GetTempFPRegister(); ap = GenerateExpression(p[0], F_FPREG, size); if (op == op_neg) op = op_fneg; GenerateDiadic(op, fsize(), ap2, ap); } else if (etype == bt_vector) { ap2 = GetTempVectorRegister(); ap = GenerateExpression(p[0], F_VREG, size); GenerateDiadic(op, 0, ap2, ap); } else { ap2 = GetTempRegister(); ap = GenerateExpression(p[0], F_REG, size); GenerateHint(3); GenerateDiadic(op, 0, ap2, ap); } ReleaseTempReg(ap); ap2->MakeLegal( flags, size); return (ap2); } // Generate code for a binary expression Operand *ENODE::GenBinary(int flags, int size, int op) { Operand *ap1, *ap2, *ap3, *ap4; if (IsFloatType()) { ap3 = GetTempFPRegister(); ap1 = GenerateExpression(p[0], F_FPREG, size); ap2 = GenerateExpression(p[1], F_FPREG, size); // Generate a convert operation ? if (ap1->fpsize() != ap2->fpsize()) { if (ap2->fpsize() == 's') GenerateDiadic(op_fcvtsq, 0, ap2, ap2); } GenerateTriadic(op, ap1->fpsize(), ap3, ap1, ap2); ap3->type = ap1->type; } else if (op == op_vadd || op == op_vsub || op == op_vmul || op == op_vdiv || op == op_vadds || op == op_vsubs || op == op_vmuls || op == op_vdivs || op == op_veins) { ap3 = GetTempVectorRegister(); if (ENODE::IsEqual(p[0], p[1]) && !opt_nocgo) { ap1 = GenerateExpression(p[0], F_VREG, size); ap2 = GenerateExpression(vmask, F_VMREG, size); Generate4adic(op, 0, ap3, ap1, ap1, ap2); ReleaseTempReg(ap2); ap2 = nullptr; } else { ap1 = GenerateExpression(p[0], F_VREG, size); ap2 = GenerateExpression(p[1], F_VREG, size); ap4 = GenerateExpression(vmask, F_VMREG, size); Generate4adic(op, 0, ap3, ap1, ap2, ap4); ReleaseTempReg(ap4); } // Generate a convert operation ? //if (fpsize(ap1) != fpsize(ap2)) { // if (fpsize(ap2)=='s') // GenerateDiadic(op_fcvtsq, 0, ap2, ap2); //} } else if (op == op_vex) { ap3 = GetTempRegister(); ap1 = GenerateExpression(p[0], F_REG, size); ap2 = GenerateExpression(p[1], F_REG, size); GenerateTriadic(op, 0, ap3, ap1, ap2); } else { ap3 = GetTempRegister(); if (ENODE::IsEqual(p[0], p[1]) && !opt_nocgo) { ap1 = GenerateExpression(p[0], F_REG, size); ap2 = nullptr; GenerateTriadic(op, 0, ap3, ap1, ap1); } else { ap1 = GenerateExpression(p[0], F_REG, size); ap2 = GenerateExpression(p[1], F_REG | F_IMMED, size); if (ap2->mode == am_imm) { switch (op) { case op_and: GenerateTriadic(op, 0, ap3, ap1, make_immed(ap2->offset->i)); /* if (ap2->offset->i & 0xFFFF0000LL) GenerateDiadic(op_andq1,0,ap3,make_immed((ap2->offset->i >> 16) & 0xFFFFLL)); if (ap2->offset->i & 0xFFFF00000000LL) GenerateDiadic(op_andq2,0,ap3,make_immed((ap2->offset->i >> 32) & 0xFFFFLL)); if (ap2->offset->i & 0xFFFF000000000000LL) GenerateDiadic(op_andq3,0,ap3,make_immed((ap2->offset->i >> 48) & 0xFFFFLL)); */ break; case op_or: GenerateTriadic(op, 0, ap3, ap1, make_immed(ap2->offset->i)); /* if (ap2->offset->i & 0xFFFF0000LL) GenerateDiadic(op_orq1,0,ap3,make_immed((ap2->offset->i >> 16) & 0xFFFFLL)); if (ap2->offset->i & 0xFFFF00000000LL) GenerateDiadic(op_orq2,0,ap3,make_immed((ap2->offset->i >> 32) & 0xFFFFLL)); if (ap2->offset->i & 0xFFFF000000000000LL) GenerateDiadic(op_orq3,0,ap3,make_immed((ap2->offset->i >> 48) & 0xFFFFLL)); */ break; // Most ops handle a max 16 bit immediate operand. If the operand is over 16 bits // it has to be loaded into a register. default: if (ap2->offset->i < -32768LL || ap2->offset->i > 32767LL) { ap4 = GetTempRegister(); GenerateTriadic(op_or, 0, ap4, makereg(regZero), make_immed(ap2->offset->i)); /* if (ap2->offset->i & 0xFFFF0000LL) GenerateDiadic(op_orq1,0,ap4,make_immed((ap2->offset->i >> 16) & 0xFFFFLL)); if (ap2->offset->i & 0xFFFF00000000LL) GenerateDiadic(op_orq2,0,ap4,make_immed((ap2->offset->i >> 32) & 0xFFFFLL)); if (ap2->offset->i & 0xFFFF000000000000LL) GenerateDiadic(op_orq3,0,ap4,make_immed((ap2->offset->i >> 48) & 0xFFFFLL)); */ GenerateTriadic(op, 0, ap3, ap1, ap4); ReleaseTempReg(ap4); } else GenerateTriadic(op, 0, ap3, ap1, ap2); } } else GenerateTriadic(op, 0, ap3, ap1, ap2); } } if (ap2) ReleaseTempReg(ap2); ReleaseTempReg(ap1); ap3->MakeLegal( flags, size); return (ap3); } Operand *ENODE::GenAssignAdd(int flags, int size, int op) { Operand *ap1, *ap2, *ap3; int ssize; bool negf = false; ssize = GetNaturalSize(p[0]); if (ssize > size) size = ssize; if (p[0]->IsBitfield()) { ap3 = GetTempRegister(); ap1 = GenerateBitfieldDereference(p[0], F_REG | F_MEM, size); GenerateDiadic(op_mov, 0, ap3, ap1); ap2 = GenerateExpression(p[1], F_REG | F_IMMED, size); GenerateTriadic(op, 0, ap1, ap1, ap2); GenerateBitfieldInsert(ap3, ap1, ap1->offset->bit_offset, ap1->offset->bit_width); GenStore(ap3, ap1->next, ssize); ReleaseTempReg(ap2); ReleaseTempReg(ap1->next); ReleaseTempReg(ap1); ap3->MakeLegal( flags, size); return (ap3); } if (IsFloatType()) { ap1 = GenerateExpression(p[0], F_FPREG | F_MEM, ssize); ap2 = GenerateExpression(p[1], F_FPREG, size); if (op == op_add) op = op_fadd; else if (op == op_sub) op = op_fsub; } else if (etype == bt_vector) { ap1 = GenerateExpression(p[0], F_REG | F_MEM, ssize); ap2 = GenerateExpression(p[1], F_REG, size); if (op == op_add) op = op_vadd; else if (op == op_sub) op = op_vsub; } else { ap1 = GenerateExpression(p[0], F_ALL, ssize); ap2 = GenerateExpression(p[1], F_REG | F_IMMED, size); } if (ap1->mode == am_reg) { GenerateTriadic(op, 0, ap1, ap1, ap2); } else if (ap1->mode == am_fpreg) { GenerateTriadic(op, ap1->fpsize(), ap1, ap1, ap2); ReleaseTempReg(ap2); ap1->MakeLegal( flags, size); return (ap1); } else { GenMemop(op, ap1, ap2, ssize); } ReleaseTempReg(ap2); if (ap1->type != stddouble.GetIndex() && !ap1->isUnsigned) ap1->GenSignExtend(ssize, size, flags); ap1->MakeLegal( flags, size); return (ap1); } Operand *ENODE::GenAssignLogic(int flags, int size, int op) { Operand *ap1, *ap2, *ap3; int ssize; ssize = GetNaturalSize(p[0]); if (ssize > size) size = ssize; if (p[0]->IsBitfield()) { ap3 = GetTempRegister(); ap1 = GenerateBitfieldDereference(p[0], F_REG | F_MEM, size); GenerateDiadic(op_mov, 0, ap3, ap1); ap2 = GenerateExpression(p[1], F_REG | F_IMMED, size); GenerateTriadic(op, 0, ap1, ap1, ap2); GenerateBitfieldInsert(ap3, ap1, ap1->offset->bit_offset, ap1->offset->bit_width); GenStore(ap3, ap1->next, ssize); ReleaseTempReg(ap2); ReleaseTempReg(ap1->next); ReleaseTempReg(ap1); ap3->MakeLegal( flags, size); return (ap3); } ap1 = GenerateExpression(p[0], F_ALL & ~F_FPREG, ssize); ap2 = GenerateExpression(p[1], F_REG | F_IMMED, size); if (ap1->mode == am_reg) { GenerateTriadic(op, 0, ap1, ap1, ap2); } else { GenMemop(op, ap1, ap2, ssize); } ReleaseTempRegister(ap2); if (!ap1->isUnsigned && !(flags & F_NOVALUE)) { if (size > ssize) { if (ap1->mode != am_reg) { ap1->MakeLegal( F_REG, ssize); } switch (ssize) { case 1: GenerateDiadic(op_sxb, 0, ap1, ap1); break; case 2: GenerateDiadic(op_sxc, 0, ap1, ap1); break; case 4: GenerateDiadic(op_sxh, 0, ap1, ap1); break; } ap1->MakeLegal( flags, size); return (ap1); } ap1->GenSignExtend(ssize, size, flags); } ap1->MakeLegal( flags, size); return (ap1); } Operand *ENODE::GenLand(int flags, int op) { Operand *ap1, *ap2, *ap3, *ap4, *ap5; ap3 = GetTempRegister(); ap1 = GenerateExpression(p[0], flags, 8); ap4 = GetTempRegister(); GenerateDiadic(op_redor, 0, ap4, ap1); ap2 = GenerateExpression(p[1], flags, 8); ap5 = GetTempRegister(); GenerateDiadic(op_redor, 0, ap5, ap2); GenerateTriadic(op, 0, ap3, ap4, ap5); ReleaseTempReg(ap5); ReleaseTempReg(ap2); ReleaseTempReg(ap4); ReleaseTempReg(ap1); ap3->MakeLegal( flags, 8); return (ap3); } void ENODE::PutConstant(txtoStream& ofs, unsigned int lowhigh, unsigned int rshift) { // ASM statment text (up to 3500 chars) may be placed in the following buffer. static char buf[4000]; switch (nodetype) { case en_autofcon: sprintf_s(buf, sizeof(buf), "%lld", i); ofs.write(buf); break; case en_fcon: goto j1; // The following spits out a warning, but is okay. sprintf_s(buf, sizeof(buf), "0x%llx", f); ofs.write(buf); break; case en_autovcon: case en_autocon: case en_icon: if (lowhigh == 2) { sprintf_s(buf, sizeof(buf), "%lld", i & 0xffff); ofs.write(buf); } else if (lowhigh == 3) { sprintf_s(buf, sizeof(buf), "%lld", (i >> 16) & 0xffff); ofs.write(buf); } else { sprintf_s(buf, sizeof(buf), "%lld", i); ofs.write(buf); } if (rshift > 0) { sprintf_s(buf, sizeof(buf), ">>%d", rshift); ofs.write(buf); } break; case en_labcon: j1: sprintf_s(buf, sizeof(buf), "%s_%lld", GetNamespace(), i); ofs.write(buf); if (rshift > 0) { sprintf_s(buf, sizeof(buf), ">>%d", rshift); ofs.write(buf); } break; case en_clabcon: sprintf_s(buf, sizeof(buf), "%s_%lld", GetNamespace(), i); ofs.write(buf); if (rshift > 0) { sprintf_s(buf, sizeof(buf), ">>%d", rshift); ofs.write(buf); } break; case en_nacon: sprintf_s(buf, sizeof(buf), "%s", (char *)sp->c_str()); ofs.write(buf); if (lowhigh == 3) { sprintf_s(buf, sizeof(buf), ">>16"); ofs.write(buf); } if (rshift > 0) { sprintf_s(buf, sizeof(buf), ">>%d", rshift); ofs.write(buf); } break; case en_cnacon: sprintf_s(buf, sizeof(buf), "%s", (char *)msp->c_str()); ofs.write(buf); if (rshift > 0) { sprintf_s(buf, sizeof(buf), ">>%d", rshift); ofs.write(buf); } break; case en_add: p[0]->PutConstant(ofs, 0, 0); ofs.write("+"); p[1]->PutConstant(ofs, 0, 0); break; case en_sub: p[0]->PutConstant(ofs, 0, 0); ofs.write("-"); p[1]->PutConstant(ofs, 0, 0); break; case en_uminus: ofs.write("-"); p[0]->PutConstant(ofs, 0, 0); break; default: printf("DIAG - illegal constant node.\n"); break; } } ENODE *ENODE::GetConstantHex(std::ifstream& ifs) { static char buf[4000]; ENODE *ep; ep = allocEnode(); ifs.read(buf, 2); buf[2] = '\0'; ep->nodetype = (e_node)strtol(buf, nullptr, 16); switch (ep->nodetype) { case en_autofcon: ifs.read(buf, 8); buf[8] = '\0'; ep->i = strtol(buf, nullptr, 16); break; case en_fcon: goto j1; case en_autovcon: case en_autocon: case en_icon: ifs.read(buf, 8); buf[8] = '\0'; ep->i = strtol(buf, nullptr, 16); break; case en_labcon: j1: ; } } void ENODE::PutConstantHex(txtoStream& ofs, unsigned int lowhigh, unsigned int rshift) { // ASM statment text (up to 3500 chars) may be placed in the following buffer. static char buf[4000]; ofs.printf("N%02X", nodetype); switch (nodetype) { case en_autofcon: sprintf_s(buf, sizeof(buf), "%08LLX", i); ofs.write(buf); break; case en_fcon: goto j1; case en_autovcon: case en_autocon: case en_icon: sprintf_s(buf, sizeof(buf), "%08llX", i); ofs.write(buf); break; case en_labcon: j1: sprintf_s(buf, sizeof(buf), "%s_%lld:", GetNamespace(), i); ofs.write(buf); break; case en_clabcon: sprintf_s(buf, sizeof(buf), "%s_%lld:", GetNamespace(), i); ofs.write(buf); break; case en_nacon: sprintf_s(buf, sizeof(buf), "%s:", (char *)sp->c_str()); ofs.write(buf); break; case en_cnacon: sprintf_s(buf, sizeof(buf), "%s:", (char *)msp->c_str()); ofs.write(buf); break; case en_add: p[0]->PutConstantHex(ofs, 0, 0); ofs.write("+"); p[1]->PutConstantHex(ofs, 0, 0); break; case en_sub: p[0]->PutConstantHex(ofs, 0, 0); ofs.write("-"); p[1]->PutConstantHex(ofs, 0, 0); break; case en_uminus: ofs.write("-"); p[0]->PutConstantHex(ofs, 0, 0); break; default: printf("DIAG - illegal constant node.\n"); break; } }