{ Copyright (c) 1998-2002 by Florian Klaempfl Generate PowerPC assembler for math nodes This program is free software; you can redistribute it and/or modify it under the terms of the GNU General Public License as published by the Free Software Foundation; either version 2 of the License, or (at your option) any later version. This program 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, write to the Free Software Foundation, Inc., 675 Mass Ave, Cambridge, MA 02139, USA. **************************************************************************** } unit nppcmat; {$i fpcdefs.inc} interface uses node,nmat; type tppcmoddivnode = class(tmoddivnode) function pass_1: tnode;override; procedure pass_generate_code;override; end; tppcshlshrnode = class(tshlshrnode) procedure pass_generate_code;override; { everything will be handled in pass_2 } function first_shlshr64bitint: tnode; override; end; tppcunaryminusnode = class(tunaryminusnode) procedure pass_generate_code;override; end; tppcnotnode = class(tnotnode) procedure pass_generate_code;override; end; implementation uses globtype,systems,constexp, cutils,verbose,globals, symconst, aasmbase,aasmcpu,aasmtai,aasmdata, defutil, cgbase,cgutils,cgobj,pass_2, ncon,procinfo, cpubase, ncgutil,cgcpu; {$ifopt r+} {$r-} {$define rangeon} {$endif} {$ifopt q+} {$q-} {$define overflowon} {$endif} { helper functions } procedure getmagic_unsigned32(d : dword; out magic_m : dword; out magic_add : boolean; out magic_shift : dword); var p : longint; nc, delta, q1, r1, q2, r2 : dword; begin assert(d > 0); magic_add := false; nc := dword(- 1) - dword(-d) mod d; p := 31; { initialize p } q1 := $80000000 div nc; { initialize q1 = 2p/nc } r1 := $80000000 - q1*nc; { initialize r1 = rem(2p,nc) } q2 := $7FFFFFFF div d; { initialize q2 = (2p-1)/d } r2 := $7FFFFFFF - q2*d; { initialize r2 = rem((2p-1),d) } repeat inc(p); if (r1 >= (nc - r1)) then begin q1 := 2 * q1 + 1; { update q1 } r1 := 2*r1 - nc; { update r1 } end else begin q1 := 2*q1; { update q1 } r1 := 2*r1; { update r1 } end; if ((r2 + 1) >= (d - r2)) then begin if (q2 >= $7FFFFFFF) then magic_add := true; q2 := 2*q2 + 1; { update q2 } r2 := 2*r2 + 1 - d; { update r2 } end else begin if (q2 >= $80000000) then magic_add := true; q2 := 2*q2; { update q2 } r2 := 2*r2 + 1; { update r2 } end; delta := d - 1 - r2; until not ((p < 64) and ((q1 < delta) or ((q1 = delta) and (r1 = 0)))); magic_m := q2 + 1; { resulting magic number } magic_shift := p - 32; { resulting shift } end; procedure getmagic_signed32(d : longint; out magic_m : longint; out magic_s : longint); const two_31 : DWord = high(longint)+1; var p : Longint; ad, anc, delta, q1, r1, q2, r2, t : DWord; begin assert((d < -1) or (d > 1)); ad := abs(d); t := two_31 + (DWord(d) shr 31); anc := t - 1 - t mod ad; { absolute value of nc } p := 31; { initialize p } q1 := two_31 div anc; { initialize q1 = 2p/abs(nc) } r1 := two_31 - q1*anc; { initialize r1 = rem(2p,abs(nc)) } q2 := two_31 div ad; { initialize q2 = 2p/abs(d) } r2 := two_31 - q2*ad; { initialize r2 = rem(2p,abs(d)) } repeat inc(p); q1 := 2*q1; { update q1 = 2p/abs(nc) } r1 := 2*r1; { update r1 = rem(2p/abs(nc)) } if (r1 >= anc) then begin { must be unsigned comparison } inc(q1); dec(r1, anc); end; q2 := 2*q2; { update q2 = 2p/abs(d) } r2 := 2*r2; { update r2 = rem(2p/abs(d)) } if (r2 >= ad) then begin { must be unsigned comparison } inc(q2); dec(r2, ad); end; delta := ad - r2; until not ((q1 < delta) or ((q1 = delta) and (r1 = 0))); magic_m := q2 + 1; if (d < 0) then begin magic_m := -magic_m; { resulting magic number } end; magic_s := p - 32; { resulting shift } end; {$ifdef rangeon} {$r+} {$undef rangeon} {$endif} {$ifdef overflowon} {$q+} {$undef overflowon} {$endif} {***************************************************************************** TPPCMODDIVNODE *****************************************************************************} function tppcmoddivnode.pass_1: tnode; begin result := inherited pass_1; if not assigned(result) then include(current_procinfo.flags,pi_do_call); end; procedure tppcmoddivnode.pass_generate_code; const { signed overflow } divops: array[boolean, boolean] of tasmop = ((A_DIVWU,A_DIVWU_),(A_DIVW,A_DIVWO_)); zerocond: tasmcond = (dirhint: DH_Plus; simple: true; cond:C_NE; cr: RS_CR1); var power : longint; op : tasmop; numerator, divider, resultreg : tregister; size : Tcgsize; hl : tasmlabel; done: boolean; procedure genOrdConstNodeDiv; const negops : array[boolean] of tasmop = (A_NEG, A_NEGO); var magic, shift : longint; u_magic, u_shift : dword; u_add : boolean; divreg : tregister; begin if (tordconstnode(right).value = 0) then begin internalerror(2005061701); end else if (tordconstnode(right).value = 1) then begin cg.a_load_reg_reg(current_asmdata.CurrAsmList, OS_INT, OS_INT, numerator, resultreg); end else if (tordconstnode(right).value = int64(-1)) then begin // note: only in the signed case possible..., may overflow current_asmdata.CurrAsmList.concat(taicpu.op_reg_reg(negops[cs_check_overflow in current_settings.localswitches], resultreg, numerator)); end else if (ispowerof2(tordconstnode(right).value, power)) then begin if (is_signed(right.resultdef)) then begin { From "The PowerPC Compiler Writer's Guide", pg. 52ff } cg.a_op_const_reg_reg(current_asmdata.CurrAsmList, OP_SAR, OS_INT, power, numerator, resultreg); current_asmdata.CurrAsmList.concat(taicpu.op_reg_reg(A_ADDZE, resultreg, resultreg)); end else begin cg.a_op_const_reg_reg(current_asmdata.CurrAsmList, OP_SHR, OS_INT, power, numerator, resultreg) end; end else begin { replace division by multiplication, both implementations } { from "The PowerPC Compiler Writer's Guide" pg. 53ff } divreg := cg.getintregister(current_asmdata.CurrAsmList, OS_INT); if (is_signed(right.resultdef)) then begin getmagic_signed32(tordconstnode(right).value.svalue, magic, shift); // load magic value cg.a_load_const_reg(current_asmdata.CurrAsmList, OS_INT, magic, divreg); // multiply current_asmdata.CurrAsmList.concat(taicpu.op_reg_reg_reg(A_MULHW, resultreg, numerator, divreg)); // add/subtract numerator if (tordconstnode(right).value > 0) and (magic < 0) then begin cg.a_op_reg_reg_reg(current_asmdata.CurrAsmList, OP_ADD, OS_INT, numerator, resultreg, resultreg); end else if (tordconstnode(right).value < 0) and (magic > 0) then begin cg.a_op_reg_reg_reg(current_asmdata.CurrAsmList, OP_SUB, OS_INT, numerator, resultreg, resultreg); end; // shift shift places to the right (arithmetic) cg.a_op_const_reg_reg(current_asmdata.CurrAsmList, OP_SAR, OS_INT, shift, resultreg, resultreg); // extract and add sign bit if (tordconstnode(right).value >= 0) then begin cg.a_op_const_reg_reg(current_asmdata.CurrAsmList, OP_SHR, OS_INT, 31, numerator, divreg); end else begin cg.a_op_const_reg_reg(current_asmdata.CurrAsmList, OP_SHR, OS_INT, 31, resultreg, divreg); end; cg.a_op_reg_reg_reg(current_asmdata.CurrAsmList, OP_ADD, OS_INT, resultreg, divreg, resultreg); end else begin getmagic_unsigned32(tordconstnode(right).value.uvalue, u_magic, u_add, u_shift); // load magic in divreg cg.a_load_const_reg(current_asmdata.CurrAsmList, OS_INT, aint(u_magic), divreg); current_asmdata.CurrAsmList.concat(taicpu.op_reg_reg_reg(A_MULHWU, resultreg, numerator, divreg)); if (u_add) then begin cg.a_op_reg_reg_reg(current_asmdata.CurrAsmList, OP_SUB, OS_INT, resultreg, numerator, divreg); cg.a_op_const_reg_reg(current_asmdata.CurrAsmList, OP_SHR, OS_INT, 1, divreg, divreg); cg.a_op_reg_reg_reg(current_asmdata.CurrAsmList, OP_ADD, OS_INT, divreg, resultreg, divreg); cg.a_op_const_reg_reg(current_asmdata.CurrAsmList, OP_SHR, OS_INT, u_shift-1, divreg, resultreg); end else begin cg.a_op_const_reg_reg(current_asmdata.CurrAsmList, OP_SHR, OS_INT, u_shift, resultreg, resultreg); end; end; end; done := true; end; procedure genOrdConstNodeMod; var modreg, maskreg, tempreg : tregister; begin if (tordconstnode(right).value = 0) then begin internalerror(2005061702); end else if (abs(tordconstnode(right).value.svalue) = 1) then begin // x mod +/-1 is always zero cg.a_load_const_reg(current_asmdata.CurrAsmList, OS_INT, 0, resultreg); end else if (ispowerof2(tordconstnode(right).value, power)) then begin if (is_signed(right.resultdef)) then begin tempreg := cg.getintregister(current_asmdata.CurrAsmList, OS_INT); maskreg := cg.getintregister(current_asmdata.CurrAsmList, OS_INT); modreg := cg.getintregister(current_asmdata.CurrAsmList, OS_INT); cg.a_load_const_reg(current_asmdata.CurrAsmList, OS_INT, abs(tordconstnode(right).value.svalue)-1, modreg); cg.a_op_const_reg_reg(current_asmdata.CurrAsmList, OP_SAR, OS_INT, 31, numerator, maskreg); cg.a_op_reg_reg_reg(current_asmdata.CurrAsmList, OP_AND, OS_INT, numerator, modreg, tempreg); current_asmdata.CurrAsmList.concat(taicpu.op_reg_reg_reg(A_ANDC, maskreg, maskreg, modreg)); current_asmdata.CurrAsmList.concat(taicpu.op_reg_reg_const(A_SUBFIC, modreg, tempreg, 0)); current_asmdata.CurrAsmList.concat(taicpu.op_reg_reg_reg(A_SUBFE, modreg, modreg, modreg)); cg.a_op_reg_reg_reg(current_asmdata.CurrAsmList, OP_AND, OS_INT, modreg, maskreg, maskreg); cg.a_op_reg_reg_reg(current_asmdata.CurrAsmList, OP_OR, OS_INT, maskreg, tempreg, resultreg); end else begin cg.a_op_const_reg_reg(current_asmdata.CurrAsmList, OP_AND, OS_INT, tordconstnode(right).value.svalue-1, numerator, resultreg); end; end else begin genOrdConstNodeDiv(); cg.a_op_const_reg_reg(current_asmdata.CurrAsmList, OP_MUL, OS_INT, tordconstnode(right).value.svalue, resultreg, resultreg); cg.a_op_reg_reg_reg(current_asmdata.CurrAsmList, OP_SUB, OS_INT, resultreg, numerator, resultreg); end; end; begin secondpass(left); secondpass(right); location_copy(location,left.location); { put numerator in register } size:=def_cgsize(left.resultdef); location_force_reg(current_asmdata.CurrAsmList,left.location, size,true); location_copy(location,left.location); numerator := location.register; resultreg := location.register; if (location.loc = LOC_CREGISTER) then begin location.loc := LOC_REGISTER; location.register := cg.getintregister(current_asmdata.CurrAsmList,size); resultreg := location.register; end else if (nodetype = modn) or (right.nodetype = ordconstn) then begin // for a modulus op, and for const nodes we need the result register // to be an extra register resultreg := cg.getintregister(current_asmdata.CurrAsmList,size); end; done := false; if (right.nodetype = ordconstn) then begin if (nodetype = divn) then genOrdConstNodeDiv else genOrdConstNodeMod; done := true; end; if (not done) then begin { load divider in a register if necessary } location_force_reg(current_asmdata.CurrAsmList,right.location, def_cgsize(right.resultdef),true); if (right.nodetype <> ordconstn) then current_asmdata.CurrAsmList.concat(taicpu.op_reg_reg_const(A_CMPWI,NR_CR1, right.location.register,0)); divider := right.location.register; { needs overflow checking, (-maxlongint-1) div (-1) overflows! } op := divops[is_signed(right.resultdef), cs_check_overflow in current_settings.localswitches]; current_asmdata.CurrAsmList.concat(taicpu.op_reg_reg_reg(op,resultreg,numerator, divider)); if (nodetype = modn) then begin current_asmdata.CurrAsmList.concat(taicpu.op_reg_reg_reg(A_MULLW,resultreg, divider,resultreg)); current_asmdata.CurrAsmList.concat(taicpu.op_reg_reg_reg(A_SUB,location.register, numerator,resultreg)); resultreg := location.register; end; end; { set result location } location.loc:=LOC_REGISTER; location.register:=resultreg; if right.nodetype <> ordconstn then begin current_asmdata.getjumplabel(hl); current_asmdata.CurrAsmList.concat(taicpu.op_cond_sym(A_BC,zerocond,hl)); cg.a_call_name(current_asmdata.CurrAsmList,'FPC_DIVBYZERO',false); cg.a_label(current_asmdata.CurrAsmList,hl); end; { unsigned division/module can only overflow in case of division by zero } { (but checking this overflow flag is more convoluted than performing a } { simple comparison with 0) } if is_signed(right.resultdef) then cg.g_overflowcheck(current_asmdata.CurrAsmList,location,resultdef); end; {***************************************************************************** TPPCSHLRSHRNODE *****************************************************************************} function tppcshlshrnode.first_shlshr64bitint: tnode; begin result := nil; end; procedure tppcshlshrnode.pass_generate_code; var resultreg, hregister1,hregister2, hreg64hi,hreg64lo : tregister; op : topcg; asmop1, asmop2: tasmop; shiftval: aint; begin secondpass(left); secondpass(right); if is_64bitint(left.resultdef) then begin location_force_reg(current_asmdata.CurrAsmList,left.location, def_cgsize(left.resultdef),true); location_copy(location,left.location); hreg64hi := location.register64.reghi; hreg64lo := location.register64.reglo; if (location.loc = LOC_CREGISTER) then begin location.loc := LOC_REGISTER; location.register64.reghi := cg.getintregister(current_asmdata.CurrAsmList,OS_32); location.register64.reglo := cg.getintregister(current_asmdata.CurrAsmList,OS_32); end; if (right.nodetype = ordconstn) then begin shiftval := tordconstnode(right).value.svalue; shiftval := shiftval and 63; { I think the statements below is much more correct instead of the hack above, but then we fail tshlshr.pp :/ if shiftval > 63 then begin cg.a_load_const_reg(current_asmdata.CurrAsmList,OS_32,0,location.register64.reglo); cg.a_load_const_reg(current_asmdata.CurrAsmList,OS_32,0,location.register64.reglo); end else } if shiftval > 31 then begin if nodetype = shln then begin cg.a_op_const_reg_reg(current_asmdata.CurrAsmList,OP_SHL,OS_32, shiftval and 31,hreg64lo,location.register64.reghi); cg.a_load_const_reg(current_asmdata.CurrAsmList,OS_32,0,location.register64.reglo); end else begin cg.a_op_const_reg_reg(current_asmdata.CurrAsmList,OP_SHR,OS_32, shiftval and 31,hreg64hi,location.register64.reglo); cg.a_load_const_reg(current_asmdata.CurrAsmList,OS_32,0,location.register64.reghi); end; end else begin if nodetype = shln then begin current_asmdata.CurrAsmList.concat(taicpu.op_reg_reg_const_const_const( A_RLWINM,location.register64.reghi,hreg64hi,shiftval, 0,31-shiftval)); current_asmdata.CurrAsmList.concat(taicpu.op_reg_reg_const_const_const( A_RLWIMI,location.register64.reghi,hreg64lo,shiftval, 32-shiftval,31)); current_asmdata.CurrAsmList.concat(taicpu.op_reg_reg_const_const_const( A_RLWINM,location.register64.reglo,hreg64lo,shiftval, 0,31-shiftval)); end else begin current_asmdata.CurrAsmList.concat(taicpu.op_reg_reg_const_const_const( A_RLWINM,location.register64.reglo,hreg64lo,32-shiftval, shiftval,31)); current_asmdata.CurrAsmList.concat(taicpu.op_reg_reg_const_const_const( A_RLWIMI,location.register64.reglo,hreg64hi,32-shiftval, 0,shiftval-1)); current_asmdata.CurrAsmList.concat(taicpu.op_reg_reg_const_const_const( A_RLWINM,location.register64.reghi,hreg64hi,32-shiftval, shiftval,31)); end; end; end else { no constant shiftcount } begin location_force_reg(current_asmdata.CurrAsmList,right.location,OS_S32,true); hregister1 := right.location.register; if nodetype = shln then begin asmop1 := A_SLW; asmop2 := A_SRW; end else begin asmop1 := A_SRW; asmop2 := A_SLW; resultreg := hreg64hi; hreg64hi := hreg64lo; hreg64lo := resultreg; resultreg := location.register64.reghi; location.register64.reghi := location.register64.reglo; location.register64.reglo := resultreg; end; cg.getcpuregister(current_asmdata.CurrAsmList,NR_R0); current_asmdata.CurrAsmList.concat(taicpu.op_reg_reg_const(A_SUBFIC, NR_R0,hregister1,32)); current_asmdata.CurrAsmList.concat(taicpu.op_reg_reg_reg(asmop1, location.register64.reghi,hreg64hi,hregister1)); current_asmdata.CurrAsmList.concat(taicpu.op_reg_reg_reg(asmop2, NR_R0,hreg64lo,NR_R0)); current_asmdata.CurrAsmList.concat(taicpu.op_reg_reg_reg(A_OR, location.register64.reghi,location.register64.reghi,NR_R0)); current_asmdata.CurrAsmList.concat(taicpu.op_reg_reg_const(A_SUBI, NR_R0,hregister1,32)); current_asmdata.CurrAsmList.concat(taicpu.op_reg_reg_reg(asmop1, NR_R0,hreg64lo,NR_R0)); current_asmdata.CurrAsmList.concat(taicpu.op_reg_reg_reg(A_OR, location.register64.reghi,location.register64.reghi,NR_R0)); current_asmdata.CurrAsmList.concat(taicpu.op_reg_reg_reg(asmop1, location.register64.reglo,hreg64lo,hregister1)); cg.ungetcpuregister(current_asmdata.CurrAsmList,NR_R0); if nodetype = shrn then begin resultreg := location.register64.reghi; location.register64.reghi := location.register64.reglo; location.register64.reglo := resultreg; end; end end else begin { load left operators in a register } location_force_reg(current_asmdata.CurrAsmList,left.location,def_cgsize(left.resultdef),true); location_copy(location,left.location); resultreg := location.register; hregister1 := location.register; location.loc := LOC_REGISTER; resultreg := cg.getintregister(current_asmdata.CurrAsmList,location.size); location.register := resultreg; { determine operator } if nodetype=shln then op:=OP_SHL else op:=OP_SHR; { shifting by a constant directly coded: } if (right.nodetype=ordconstn) then cg.a_op_const_reg_reg(current_asmdata.CurrAsmList,op,location.size, tordconstnode(right).value.svalue and 31,hregister1,resultreg) else begin { load shift count in a register if necessary } location_force_reg(current_asmdata.CurrAsmList,right.location,def_cgsize(right.resultdef),true); hregister2 := right.location.register; cg.a_op_reg_reg_reg(current_asmdata.CurrAsmList,op,location.size,hregister2, hregister1,resultreg); end; end; end; {***************************************************************************** TPPCUNARYMINUSNODE *****************************************************************************} procedure tppcunaryminusnode.pass_generate_code; var src1: tregister; op: tasmop; begin secondpass(left); if is_64bit(left.resultdef) then begin location_force_reg(current_asmdata.CurrAsmList,left.location,def_cgsize(left.resultdef),true); location_copy(location,left.location); if (location.loc = LOC_CREGISTER) then begin location.register64.reglo := cg.getintregister(current_asmdata.CurrAsmList,OS_INT); location.register64.reghi := cg.getintregister(current_asmdata.CurrAsmList,OS_INT); location.loc := LOC_REGISTER; end; current_asmdata.CurrAsmList.concat(taicpu.op_reg_reg_const(A_SUBFIC, location.register64.reglo,left.location.register64.reglo,0)); if not(cs_check_overflow in current_settings.localswitches) then current_asmdata.CurrAsmList.concat(taicpu.op_reg_reg(A_SUBFZE, location.register64.reghi,left.location.register64.reghi)) else current_asmdata.CurrAsmList.concat(taicpu.op_reg_reg(A_SUBFZEO_, location.register64.reghi,left.location.register64.reghi)); end else begin location_copy(location,left.location); location.loc:=LOC_REGISTER; case left.location.loc of LOC_FPUREGISTER, LOC_REGISTER: begin src1 := left.location.register; location.register := src1; end; LOC_CFPUREGISTER, LOC_CREGISTER: begin src1 := left.location.register; if left.location.loc = LOC_CREGISTER then location.register := cg.getintregister(current_asmdata.CurrAsmList,OS_INT) else location.register := cg.getfpuregister(current_asmdata.CurrAsmList,location.size); end; LOC_REFERENCE,LOC_CREFERENCE: begin if (left.resultdef.typ=floatdef) then begin src1 := cg.getfpuregister(current_asmdata.CurrAsmList,def_cgsize(left.resultdef)); location.register := src1; cg.a_loadfpu_ref_reg(current_asmdata.CurrAsmList, left.location.size,left.location.size, left.location.reference,src1); end else begin src1 := cg.getintregister(current_asmdata.CurrAsmList,OS_32); location.register:= src1; cg.a_load_ref_reg(current_asmdata.CurrAsmList,OS_32,OS_32, left.location.reference,src1); end; end; end; { choose appropriate operand } if left.resultdef.typ <> floatdef then begin if not(cs_check_overflow in current_settings.localswitches) then op := A_NEG else op := A_NEGO_; location.loc := LOC_REGISTER; end else begin op := A_FNEG; location.loc := LOC_FPUREGISTER; end; { emit operation } current_asmdata.CurrAsmList.concat(taicpu.op_reg_reg(op,location.register,src1)); end; { Here was a problem... } { Operand to be negated always } { seems to be converted to signed } { 32-bit before doing neg!! } { So this is useless... } { that's not true: -2^31 gives an overflow error if it is negated (FK) } cg.g_overflowcheck(current_asmdata.CurrAsmList,location,resultdef); end; {***************************************************************************** TPPCNOTNODE *****************************************************************************} procedure tppcnotnode.pass_generate_code; var hl : tasmlabel; begin if is_boolean(resultdef) then begin { if the location is LOC_JUMP, we do the secondpass after the labels are allocated } if left.expectloc=LOC_JUMP then begin hl:=current_procinfo.CurrTrueLabel; current_procinfo.CurrTrueLabel:=current_procinfo.CurrFalseLabel; current_procinfo.CurrFalseLabel:=hl; secondpass(left); maketojumpbool(current_asmdata.CurrAsmList,left,lr_load_regvars); hl:=current_procinfo.CurrTrueLabel; current_procinfo.CurrTrueLabel:=current_procinfo.CurrFalseLabel; current_procinfo.CurrFalseLabel:=hl; location.loc:=LOC_JUMP; end else begin secondpass(left); case left.location.loc of LOC_FLAGS : begin location_copy(location,left.location); inverse_flags(location.resflags); end; LOC_REGISTER, LOC_CREGISTER, LOC_REFERENCE, LOC_CREFERENCE, LOC_SUBSETREG, LOC_CSUBSETREG, LOC_SUBSETREF, LOC_CSUBSETREF: begin location_force_reg(current_asmdata.CurrAsmList,left.location,def_cgsize(left.resultdef),true); current_asmdata.CurrAsmList.concat(taicpu.op_reg_const(A_CMPWI,left.location.register,0)); location_reset(location,LOC_FLAGS,OS_NO); location.resflags.cr:=RS_CR0; location.resflags.flag:=F_EQ; end; else internalerror(2003042401); end; end; end else if is_64bitint(left.resultdef) then begin secondpass(left); location_force_reg(current_asmdata.CurrAsmList,left.location,def_cgsize(left.resultdef),false); location_copy(location,left.location); { perform the NOT operation } current_asmdata.CurrAsmList.concat(taicpu.op_reg_reg(A_NOT,location.register64.reghi, location.register64.reghi)); current_asmdata.CurrAsmList.concat(taicpu.op_reg_reg(A_NOT,location.register64.reglo, location.register64.reglo)); end else begin secondpass(left); location_force_reg(current_asmdata.CurrAsmList,left.location,def_cgsize(left.resultdef),true); location_copy(location,left.location); location.loc := LOC_REGISTER; location.register := cg.getintregister(current_asmdata.CurrAsmList,OS_INT); { perform the NOT operation } cg.a_op_reg_reg(current_asmdata.CurrAsmList,OP_NOT,def_cgsize(resultdef),left.location.register, location.register); end; end; begin cmoddivnode:=tppcmoddivnode; cshlshrnode:=tppcshlshrnode; cunaryminusnode:=tppcunaryminusnode; cnotnode:=tppcnotnode; end.