fpc/compiler/mips/ncpucnv.pas

{
    Copyright (c) 1998-2002 by Florian Klaempfl and David Zhang

    Generate MIPSEL assembler for type converting 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 ncpucnv;

{$i fpcdefs.inc}

interface

uses
  node, ncnv, ncgcnv, defcmp;

type
  tMIPSELtypeconvnode = class(TCgTypeConvNode)
  protected
    { procedure second_int_to_int;override; }
    { procedure second_string_to_string;override; }
    { procedure second_cstring_to_pchar;override; }
    { procedure second_string_to_chararray;override; }
    { procedure second_array_to_pointer;override; }
    function first_int_to_real: tnode; override;
    { procedure second_pointer_to_array;override; }
    { procedure second_chararray_to_string;override; }
    { procedure second_char_to_string;override; }
    procedure second_int_to_real; override;
    procedure second_real_to_real; override;
    { procedure second_cord_to_pointer;override; }
    { procedure second_proc_to_procvar;override; }
    { procedure second_bool_to_int;override; }
    procedure second_int_to_bool; override;
    { procedure second_load_smallset;override;  }
    { procedure second_ansistring_to_pchar;override; }
    { procedure second_pchar_to_string;override; }
    { procedure second_class_to_intf;override; }
    { procedure second_char_to_char;override; }
  end;

implementation

uses
  verbose, globtype, globals, systems,
  symconst, symdef, aasmbase, aasmtai, aasmdata,
  defutil,
  cgbase, cgutils, pass_1, pass_2, procinfo,
  ncon, ncal,
  ncgutil,
  cpubase, aasmcpu,
  tgobj, cgobj,
  hlcgobj;


{*****************************************************************************
                             FirstTypeConv
*****************************************************************************}

function tmipseltypeconvnode.first_int_to_real: tnode;
var
  fname: string[19];
begin
  { converting a 64bit integer to a float requires a helper }
  if is_64bitint(left.resultdef) or
     is_currency(left.resultdef) then
    begin
      result:=inherited first_int_to_real;
      exit;
    end
  else
    { other integers are supposed to be 32 bit }
    begin
      if is_signed(left.resultdef) then
        inserttypeconv(left,s32inttype)
      else
        inserttypeconv(left,u32inttype);
      firstpass(left);
    end;
  result := nil;
  expectloc:=LOC_FPUREGISTER;
end;


{*****************************************************************************
                             SecondTypeConv
*****************************************************************************}

procedure tMIPSELtypeconvnode.second_int_to_real;

  procedure loadsigned;
  begin
    hlcg.location_force_mem(current_asmdata.CurrAsmList, left.location, left.resultdef);
    location.Register := cg.getfpuregister(current_asmdata.CurrAsmList, location.size);
    { Load memory in fpu register }
    cg.a_loadfpu_ref_reg(current_asmdata.CurrAsmList, OS_F32, OS_F32, left.location.reference, location.Register);
    tg.ungetiftemp(current_asmdata.CurrAsmList, left.location.reference);
    { Convert value in fpu register from integer to float }
    case tfloatdef(resultdef).floattype of
      s32real:
        current_asmdata.CurrAsmList.concat(taicpu.op_reg_reg(A_CVT_S_W, location.Register, location.Register));
      s64real:
        current_asmdata.CurrAsmList.concat(taicpu.op_reg_reg(A_CVT_D_W, location.Register, location.Register));
      else
        internalerror(200408011);
    end;
  end;

var
  href:      treference;
  hregister: tregister;
  l1, l2:    tasmlabel;
  ai : TaiCpu;
  addend: array[boolean] of longword;
  bigendian: boolean;
begin
  location_reset(location, LOC_FPUREGISTER, def_cgsize(resultdef));
  if is_signed(left.resultdef) then
    loadsigned
  else
  begin
    current_asmdata.getdatalabel(l1);
    current_asmdata.getjumplabel(l2);
    reference_reset_symbol(href, l1, 0, sizeof(aint));
    hregister := cg.getintregister(current_asmdata.CurrAsmList, OS_32);
    hlcg.a_load_loc_reg(current_asmdata.CurrAsmList, left.resultdef, u32inttype, left.location, hregister);

    { Always load into 64-bit FPU register }
    hlcg.location_force_mem(current_asmdata.CurrAsmList, left.location, left.resultdef);
    location.Register := cg.getfpuregister(current_asmdata.CurrAsmList, OS_F64);
    cg.a_loadfpu_ref_reg(current_asmdata.CurrAsmList, OS_F32, OS_F32, left.location.reference, location.Register);
    tg.ungetiftemp(current_asmdata.CurrAsmList, left.location.reference);
    { Convert value in fpu register from integer to float }
    current_asmdata.CurrAsmList.concat(taicpu.op_reg_reg(A_CVT_D_W, location.Register, location.Register));

    ai := Taicpu.op_reg_reg_sym(A_BC, hregister, NR_R0, l2);
    ai.setCondition(C_GE);
    current_asmdata.CurrAsmList.concat(ai);

    case tfloatdef(resultdef).floattype of
      { converting dword to s64real first and cut off at the end avoids precision loss }
      s32real,
      s64real:
      begin
        hregister := cg.getfpuregister(current_asmdata.CurrAsmList, OS_F64);
        new_section(current_asmdata.asmlists[al_typedconsts],sec_rodata_norel,l1.name,const_align(8));
        current_asmdata.asmlists[al_typedconsts].concat(Tai_label.Create(l1));

        addend[false]:=0;
        addend[true]:=$41f00000;
        bigendian:=(target_info.endian=endian_big);

        { add double number 4294967296.0 = (1ull^32) = 0x41f00000,00000000 in little endian hex}
        current_asmdata.asmlists[al_typedconsts].concat(Tai_const.Create_32bit(addend[bigendian]));
        current_asmdata.asmlists[al_typedconsts].concat(Tai_const.Create_32bit(addend[not bigendian]));

        cg.a_loadfpu_ref_reg(current_asmdata.CurrAsmList, OS_F64, OS_F64, href, hregister);
        current_asmdata.CurrAsmList.concat(taicpu.op_reg_reg_reg(A_ADD_D, location.Register, hregister, location.Register));
        cg.a_label(current_asmdata.CurrAsmList, l2);

        { cut off if we should convert to single }
        if tfloatdef(resultdef).floattype = s32real then
        begin
          hregister := location.Register;
          location.Register := cg.getfpuregister(current_asmdata.CurrAsmList, location.size);
          current_asmdata.CurrAsmList.concat(taicpu.op_reg_reg(A_CVT_S_D, location.Register, hregister));
        end;
      end;
      else
        internalerror(200410031);
    end;
  end;
end;


procedure tMIPSELtypeconvnode.second_real_to_real;
const
  conv_op: array[tfloattype, tfloattype] of tasmop = (
    {    from:   s32      s64         s80     sc80    c64     cur    f128 }
    { s32 }  (A_MOV_S,   A_CVT_S_D, A_NONE, A_NONE, A_NONE, A_NONE, A_NONE),
    { s64 }  (A_CVT_D_S, A_MOV_D,   A_NONE, A_NONE, A_NONE, A_NONE, A_NONE),
    { s80 }  (A_NONE,    A_NONE,    A_NONE, A_NONE, A_NONE, A_NONE, A_NONE),
    { sc80 } (A_NONE,    A_NONE,    A_NONE, A_NONE, A_NONE, A_NONE, A_NONE),
    { c64 }  (A_NONE,    A_NONE,    A_NONE, A_NONE, A_NONE, A_NONE, A_NONE),
    { cur }  (A_NONE,    A_NONE,    A_NONE, A_NONE, A_NONE, A_NONE, A_NONE),
    { f128 } (A_NONE,    A_NONE,    A_NONE, A_NONE, A_NONE, A_NONE, A_NONE)
    );
var
  op: tasmop;
begin
  location_reset(location, LOC_FPUREGISTER, def_cgsize(resultdef));
  location_force_fpureg(current_asmdata.CurrAsmList, left.location, False);
  { Convert value in fpu register from integer to float }
  op := conv_op[tfloatdef(resultdef).floattype, tfloatdef(left.resultdef).floattype];
  if op = A_NONE then
    internalerror(200401121);
  location.Register := cg.getfpuregister(current_asmdata.CurrAsmList, location.size);
  current_asmdata.CurrAsmList.concat(taicpu.op_reg_reg(op, location.Register, left.location.Register));
end;


procedure tMIPSELtypeconvnode.second_int_to_bool;
var
  hreg1, hreg2: tregister;
  opsize: tcgsize;
  hlabel, oldtruelabel, oldfalselabel: tasmlabel;
  newsize  : tcgsize;
  href: treference;
begin
  oldtruelabel  := current_procinfo.CurrTrueLabel;
  oldfalselabel := current_procinfo.CurrFalseLabel;
  current_asmdata.getjumplabel(current_procinfo.CurrTrueLabel);
  current_asmdata.getjumplabel(current_procinfo.CurrFalseLabel);
  secondpass(left);
  if codegenerror then
    exit;

         { Explicit typecasts from any ordinal type to a boolean type }
         { must not change the ordinal value                          }
         if (nf_explicit in flags) and
            not(left.location.loc in [LOC_FLAGS,LOC_JUMP]) then
           begin
              location_copy(location,left.location);
              newsize:=def_cgsize(resultdef);
              { change of size? change sign only if location is LOC_(C)REGISTER? Then we have to sign/zero-extend }
              if (tcgsize2size[newsize]<>tcgsize2size[left.location.size]) or
                 ((newsize<>left.location.size) and (location.loc in [LOC_REGISTER,LOC_CREGISTER])) then
                hlcg.location_force_reg(current_asmdata.CurrAsmList,location,left.resultdef,resultdef,true)
              else
                location.size:=newsize;
              current_procinfo.CurrTrueLabel:=oldTrueLabel;
              current_procinfo.CurrFalseLabel:=oldFalseLabel;
              exit;
           end;

  location_reset(location, LOC_REGISTER, def_cgsize(resultdef));
  opsize := def_cgsize(left.resultdef);
  case left.location.loc of
    LOC_CREFERENCE, LOC_REFERENCE, LOC_REGISTER, LOC_CREGISTER:
    begin
      if left.location.loc in [LOC_CREFERENCE, LOC_REFERENCE] then
      begin
        hreg2 := cg.getintregister(current_asmdata.CurrAsmList, opsize);
{$ifndef cpu64bitalu}
        if left.location.size in [OS_64,OS_S64] then
          begin
            cg.a_load_ref_reg(current_asmdata.CurrAsmList,OS_INT,OS_INT,left.location.reference,hreg2);
            hreg1:=cg.getintregister(current_asmdata.CurrAsmList,OS_INT);
            href:=left.location.reference;
            inc(href.offset,4);
            cg.a_load_ref_reg(current_asmdata.CurrAsmList,OS_INT,OS_INT,href,hreg1);
            cg.a_op_reg_reg_reg(current_asmdata.CurrAsmList,OP_OR,OS_32,hreg1,hreg2,hreg2);
          end
          else
{$endif not cpu64bitalu}
            cg.a_load_ref_reg(current_asmdata.CurrAsmList, opsize, opsize, left.location.reference, hreg2);
      end
      else
        begin
          hreg2:=cg.getintregister(current_asmdata.CurrAsmList,OS_INT);
{$ifndef cpu64bitalu}
          if left.location.size in [OS_64,OS_S64] then
            begin
              hreg2:=cg.getintregister(current_asmdata.CurrAsmList,OS_32);
              cg.a_op_reg_reg_reg(current_asmdata.CurrAsmList,OP_OR,OS_32,left.location.register64.reghi,left.location.register64.reglo,hreg2);
             end
           else
{$endif not cpu64bitalu}
             cg.a_load_reg_reg(current_asmdata.CurrAsmList,opsize,opsize,left.location.register,hreg2);
         end;
       hreg1 := cg.getintregister(current_asmdata.CurrAsmList, opsize);
       current_asmdata.CurrAsmList.concat(taicpu.op_reg_reg_reg(A_SLTU, hreg1, NR_R0, hreg2));
    end;
    LOC_JUMP:
    begin
      hreg1 := cg.getintregister(current_asmdata.CurrAsmList, OS_INT);
      current_asmdata.getjumplabel(hlabel);
      cg.a_label(current_asmdata.CurrAsmList, current_procinfo.CurrTrueLabel);
      cg.a_load_const_reg(current_asmdata.CurrAsmList, OS_INT, 1, hreg1);
      cg.a_jmp_always(current_asmdata.CurrAsmList, hlabel);
      cg.a_label(current_asmdata.CurrAsmList, current_procinfo.CurrFalseLabel);
      cg.a_load_const_reg(current_asmdata.CurrAsmList, OS_INT, 0, hreg1);
      cg.a_label(current_asmdata.CurrAsmList, hlabel);
    end;
    else
      internalerror(10062);
  end;
  { Now hreg1 is either 0 or 1. For C booleans it must be 0 or -1. }
  if is_cbool(resultdef) then
    cg.a_op_reg_reg(current_asmdata.CurrAsmList,OP_NEG,OS_SINT,hreg1,hreg1);

{$ifndef cpu64bitalu}
  if (location.size in [OS_64,OS_S64]) then
    begin
      location.register64.reglo:=hreg1;
      location.register64.reghi:=cg.getintregister(current_asmdata.CurrAsmList,OS_32);
      if (is_cbool(resultdef)) then
       { reglo is either 0 or -1 -> reghi has to become the same }
          cg.a_load_reg_reg(current_asmdata.CurrAsmList,OS_32,OS_32,location.register64.reglo,location.register64.reghi)
       else
       { unsigned }
         cg.a_load_const_reg(current_asmdata.CurrAsmList,OS_32,0,location.register64.reghi);
       end
       else
{$endif not cpu64bitalu}
         location.Register := hreg1;


  current_procinfo.CurrTrueLabel  := oldtruelabel;
  current_procinfo.CurrFalseLabel := oldfalselabel;
end;


begin
  ctypeconvnode := tMIPSELtypeconvnode;
end.