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--  Operations synthesis.
--  Copyright (C) 2019 Tristan Gingold
--
--  This file is part of GHDL.
--
--  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., 51 Franklin Street - Fifth Floor, Boston,
--  MA 02110-1301, USA.

with Types; use Types;

with Vhdl.Utils; use Vhdl.Utils;

with Synth.Errors; use Synth.Errors;
with Synth.Source; use Synth.Source;
with Synth.Expr; use Synth.Expr;
with Synth.Oper;
with Synth.Ieee.Std_Logic_1164; use Synth.Ieee.Std_Logic_1164;
with Synth.Ieee.Numeric_Std; use Synth.Ieee.Numeric_Std;

package body Synth.Static_Oper is
   --  From openiee:

   function Create_Res_Bound (Prev : Type_Acc) return Type_Acc is
   begin
      if Prev.Vbound.Dir = Iir_Downto
        and then Prev.Vbound.Right = 0
      then
         --  Normalized range
         return Prev;
      end if;

      return Create_Vec_Type_By_Length (Prev.W, Prev.Vec_El);
   end Create_Res_Bound;

   function Synth_Vector_Dyadic
     (L, R : Value_Acc; Op : Table_2d; Loc : Syn_Src) return Value_Acc
   is
      El_Typ : constant Type_Acc := L.Typ.Vec_El;
      Arr : Value_Array_Acc;
   begin
      if L.Arr.Len /= R.Arr.Len then
         Error_Msg_Synth (+Loc, "length of operands mismatch");
         return null;
      end if;

      Arr := Create_Value_Array (L.Arr.Len);
      for I in Arr.V'Range loop
         declare
            Ls : constant Std_Ulogic :=
              Std_Ulogic'Val (L.Arr.V (I).Scal);
            Rs : constant Std_Ulogic :=
              Std_Ulogic'Val (R.Arr.V (I).Scal);
            V : constant Std_Ulogic := Op (Ls, Rs);
         begin
            Arr.V (I) := Create_Value_Discrete (Std_Ulogic'Pos (V), El_Typ);
         end;
      end loop;

      return Create_Value_Const_Array (Create_Res_Bound (L.Typ), Arr);
   end Synth_Vector_Dyadic;

   procedure To_Std_Logic_Vector
     (Val : Value_Acc; Arr : out Std_Logic_Vector) is
   begin
      for I in Val.Arr.V'Range loop
         Arr (Natural (I)) := Std_Ulogic'Val (Val.Arr.V (I).Scal);
      end loop;
   end To_Std_Logic_Vector;

   function To_Value_Acc (Vec : Std_Logic_Vector; El_Typ : Type_Acc)
                         return Value_Acc
   is
      pragma Assert (Vec'First = 1);
      Res_Typ : Type_Acc;
      Arr : Value_Array_Acc;
   begin
      Res_Typ := Create_Vec_Type_By_Length (Uns32 (Vec'Last), El_Typ);
      Arr := Create_Value_Array (Iir_Index32 (Vec'Last));
      for I in Vec'Range loop
         Arr.V (Iir_Index32 (I)) :=
           Create_Value_Discrete (Std_Ulogic'Pos (Vec (I)), El_Typ);
      end loop;
      return Create_Value_Const_Array (Res_Typ, Arr);
   end To_Value_Acc;

   function Synth_Add_Uns_Uns (L, R : Value_Acc; Loc : Syn_Src)
                              return Value_Acc
   is
      pragma Unreferenced (Loc);
      L_Arr : Std_Logic_Vector (1 .. Natural (L.Arr.Len));
      R_Arr : Std_Logic_Vector (1 .. Natural (R.Arr.Len));
   begin
      To_Std_Logic_Vector (L, L_Arr);
      To_Std_Logic_Vector (R, R_Arr);
      declare
         Res_Arr : constant Std_Logic_Vector := Add_Uns_Uns (L_Arr, R_Arr);
      begin
         return To_Value_Acc (Res_Arr, L.Typ.Vec_El);
      end;
   end Synth_Add_Uns_Uns;

   function Synth_Add_Sgn_Int (L, R : Value_Acc; Loc : Syn_Src)
                              return Value_Acc
   is
      pragma Unreferenced (Loc);
      L_Arr : Std_Logic_Vector (1 .. Natural (L.Arr.Len));
      R_Val : constant Int64 := R.Scal;
   begin
      To_Std_Logic_Vector (L, L_Arr);
      declare
         Res_Arr : constant Std_Logic_Vector := Add_Sgn_Int (L_Arr, R_Val);
      begin
         return To_Value_Acc (Res_Arr, L.Typ.Vec_El);
      end;
   end Synth_Add_Sgn_Int;

   function Synth_Add_Uns_Nat (L, R : Value_Acc; Loc : Syn_Src)
                              return Value_Acc
   is
      pragma Unreferenced (Loc);
      L_Arr : Std_Logic_Vector (1 .. Natural (L.Arr.Len));
      R_Val : constant Uns64 := Uns64 (R.Scal);
   begin
      To_Std_Logic_Vector (L, L_Arr);
      declare
         Res_Arr : constant Std_Logic_Vector := Add_Uns_Nat (L_Arr, R_Val);
      begin
         return To_Value_Acc (Res_Arr, L.Typ.Vec_El);
      end;
   end Synth_Add_Uns_Nat;

   function Synth_Mul_Uns_Uns (L, R : Value_Acc; Loc : Syn_Src)
                              return Value_Acc
   is
      pragma Unreferenced (Loc);
      L_Arr : Std_Logic_Vector (1 .. Natural (L.Arr.Len));
      R_Arr : Std_Logic_Vector (1 .. Natural (R.Arr.Len));
   begin
      To_Std_Logic_Vector (L, L_Arr);
      To_Std_Logic_Vector (R, R_Arr);
      declare
         Res_Arr : constant Std_Logic_Vector := Mul_Uns_Uns (L_Arr, R_Arr);
      begin
         return To_Value_Acc (Res_Arr, L.Typ.Vec_El);
      end;
   end Synth_Mul_Uns_Uns;

   function Synth_Mul_Sgn_Sgn (L, R : Value_Acc; Loc : Syn_Src)
                              return Value_Acc
   is
      pragma Unreferenced (Loc);
      L_Arr : Std_Logic_Vector (1 .. Natural (L.Arr.Len));
      R_Arr : Std_Logic_Vector (1 .. Natural (R.Arr.Len));
   begin
      To_Std_Logic_Vector (L, L_Arr);
      To_Std_Logic_Vector (R, R_Arr);
      declare
         Res_Arr : constant Std_Logic_Vector := Mul_Sgn_Sgn (L_Arr, R_Arr);
      begin
         return To_Value_Acc (Res_Arr, L.Typ.Vec_El);
      end;
   end Synth_Mul_Sgn_Sgn;

   function Synth_Static_Dyadic_Predefined (Syn_Inst : Synth_Instance_Acc;
                                            Imp : Node;
                                            Left : Value_Acc;
                                            Right : Value_Acc;
                                            Expr : Node) return Value_Acc
   is
      Def : constant Iir_Predefined_Functions :=
        Get_Implicit_Definition (Imp);
      Res_Typ : constant Type_Acc :=
        Get_Value_Type (Syn_Inst, Get_Type (Expr));
   begin
      case Def is
         when Iir_Predefined_Error =>
            return null;

         when Iir_Predefined_Enum_Equality =>
            return Create_Value_Discrete
              (Boolean'Pos (Left.Scal = Right.Scal), Boolean_Type);

         when Iir_Predefined_Integer_Plus =>
            return Create_Value_Discrete
              (Get_Static_Discrete (Left) + Get_Static_Discrete (Right),
               Res_Typ);
         when Iir_Predefined_Integer_Minus =>
            return Create_Value_Discrete
              (Get_Static_Discrete (Left) - Get_Static_Discrete (Right),
               Res_Typ);
         when Iir_Predefined_Integer_Mul =>
            return Create_Value_Discrete
              (Get_Static_Discrete (Left) * Get_Static_Discrete (Right),
               Res_Typ);
         when Iir_Predefined_Integer_Div =>
            return Create_Value_Discrete
              (Left.Scal / Right.Scal, Res_Typ);
         when Iir_Predefined_Integer_Mod =>
            return Create_Value_Discrete
              (Get_Static_Discrete (Left) mod Get_Static_Discrete (Right),
               Res_Typ);
         when Iir_Predefined_Integer_Rem =>
            return Create_Value_Discrete
              (Left.Scal rem Right.Scal, Res_Typ);
         when Iir_Predefined_Integer_Exp =>
            return Create_Value_Discrete
              (Left.Scal ** Natural (Right.Scal), Res_Typ);
         when Iir_Predefined_Integer_Less_Equal =>
            return Create_Value_Discrete
              (Boolean'Pos (Left.Scal <= Right.Scal), Boolean_Type);
         when Iir_Predefined_Integer_Less =>
            return Create_Value_Discrete
              (Boolean'Pos (Left.Scal < Right.Scal), Boolean_Type);
         when Iir_Predefined_Integer_Greater_Equal =>
            return Create_Value_Discrete
              (Boolean'Pos (Left.Scal >= Right.Scal), Boolean_Type);
         when Iir_Predefined_Integer_Greater =>
            return Create_Value_Discrete
              (Boolean'Pos (Left.Scal > Right.Scal), Boolean_Type);
         when Iir_Predefined_Integer_Equality =>
            return Create_Value_Discrete
              (Boolean'Pos (Get_Static_Discrete (Left)
                              = Get_Static_Discrete (Right)), Boolean_Type);
         when Iir_Predefined_Integer_Inequality =>
            return Create_Value_Discrete
              (Boolean'Pos (Get_Static_Discrete (Left)
                              /= Get_Static_Discrete (Right)), Boolean_Type);
         when Iir_Predefined_Physical_Physical_Div
           | Iir_Predefined_Physical_Integer_Div =>
            return Create_Value_Discrete
              (Left.Scal / Right.Scal, Res_Typ);

         when Iir_Predefined_Floating_Less =>
            return Create_Value_Discrete
              (Boolean'Pos (Left.Fp < Right.Fp), Boolean_Type);
         when Iir_Predefined_Floating_Less_Equal =>
            return Create_Value_Discrete
              (Boolean'Pos (Left.Fp <= Right.Fp), Boolean_Type);
         when Iir_Predefined_Floating_Equality =>
            return Create_Value_Discrete
              (Boolean'Pos (Left.Fp = Right.Fp), Boolean_Type);
         when Iir_Predefined_Floating_Inequality =>
            return Create_Value_Discrete
              (Boolean'Pos (Left.Fp /= Right.Fp), Boolean_Type);
         when Iir_Predefined_Floating_Greater =>
            return Create_Value_Discrete
              (Boolean'Pos (Left.Fp > Right.Fp), Boolean_Type);
         when Iir_Predefined_Floating_Greater_Equal =>
            return Create_Value_Discrete
              (Boolean'Pos (Left.Fp >= Right.Fp), Boolean_Type);

         when Iir_Predefined_Floating_Plus =>
            return Create_Value_Float (Left.Fp + Right.Fp, Res_Typ);
         when Iir_Predefined_Floating_Minus =>
            return Create_Value_Float (Left.Fp - Right.Fp, Res_Typ);
         when Iir_Predefined_Floating_Mul =>
            return Create_Value_Float (Left.Fp * Right.Fp, Res_Typ);
         when Iir_Predefined_Floating_Div =>
            return Create_Value_Float (Left.Fp / Right.Fp, Res_Typ);
         when Iir_Predefined_Floating_Exp =>
            return Create_Value_Float
              (Left.Fp ** Natural (Right.Scal), Res_Typ);

         when Iir_Predefined_Array_Array_Concat =>
            declare
               Ret_Typ : constant Type_Acc :=
                 Get_Value_Type (Syn_Inst, Get_Return_Type (Imp));
               Bnd : Bound_Type;
               Res_Typ : Type_Acc;
               Arr : Value_Array_Acc;
            begin
               Bnd := Oper.Create_Bounds_From_Length
                 (Syn_Inst, Get_Index_Type (Get_Type (Expr), 0),
                  Left.Arr.Len + Right.Arr.Len);
               Res_Typ := Create_Onedimensional_Array_Subtype
                 (Ret_Typ, Bnd);
               Arr := Create_Value_Array (Left.Arr.Len + Right.Arr.Len);
               for I in Left.Arr.V'Range loop
                  Arr.V (I) := Left.Arr.V (I);
               end loop;
               for I in Right.Arr.V'Range loop
                  Arr.V (Left.Arr.Len + I) := Right.Arr.V (I);
               end loop;
               return Create_Value_Const_Array (Res_Typ, Arr);
            end;

         when Iir_Predefined_Array_Equality
           | Iir_Predefined_Record_Equality =>
            return Create_Value_Discrete
              (Boolean'Pos (Is_Equal (Left, Right)), Boolean_Type);
         when Iir_Predefined_Array_Inequality
            | Iir_Predefined_Record_Inequality =>
            return Create_Value_Discrete
              (Boolean'Pos (not Is_Equal (Left, Right)), Boolean_Type);

         when Iir_Predefined_Access_Equality =>
            return Create_Value_Discrete
              (Boolean'Pos (Left.Acc = Right.Acc), Boolean_Type);
         when Iir_Predefined_Access_Inequality =>
            return Create_Value_Discrete
              (Boolean'Pos (Left.Acc /= Right.Acc), Boolean_Type);

         when Iir_Predefined_Ieee_1164_Vector_And
           | Iir_Predefined_Ieee_Numeric_Std_And_Uns_Uns
           | Iir_Predefined_Ieee_Numeric_Std_And_Sgn_Sgn =>
            return Synth_Vector_Dyadic (Left, Right, And_Table, Expr);

         when Iir_Predefined_Ieee_1164_Vector_Or
           | Iir_Predefined_Ieee_Numeric_Std_Or_Uns_Uns
           | Iir_Predefined_Ieee_Numeric_Std_Or_Sgn_Sgn =>
            return Synth_Vector_Dyadic (Left, Right, Or_Table, Expr);

         when Iir_Predefined_Ieee_Numeric_Std_Add_Uns_Uns =>
            return Synth_Add_Uns_Uns (Left, Right, Expr);

         when Iir_Predefined_Ieee_Numeric_Std_Add_Sgn_Int =>
            return Synth_Add_Sgn_Int (Left, Right, Expr);

         when Iir_Predefined_Ieee_Numeric_Std_Add_Uns_Nat =>
            return Synth_Add_Uns_Nat (Left, Right, Expr);

         when Iir_Predefined_Ieee_Numeric_Std_Mul_Uns_Uns =>
            return Synth_Mul_Uns_Uns (Left, Right, Expr);

         when Iir_Predefined_Ieee_Numeric_Std_Mul_Sgn_Sgn =>
            return Synth_Mul_Sgn_Sgn (Left, Right, Expr);

         when others =>
            Error_Msg_Synth
              (+Expr, "synth_static_dyadic_predefined: unhandled "
                 & Iir_Predefined_Functions'Image (Def));
            raise Internal_Error;
      end case;
   end Synth_Static_Dyadic_Predefined;

   function Synth_Vector_Monadic
     (Vec : Value_Acc; Op : Table_1d) return Value_Acc
   is
      El_Typ : constant Type_Acc := Vec.Typ.Vec_El;
      Arr : Value_Array_Acc;
   begin
      Arr := Create_Value_Array (Vec.Arr.Len);
      for I in Arr.V'Range loop
         declare
            V : constant Std_Ulogic := Std_Ulogic'Val (Vec.Arr.V (I).Scal);
         begin
            Arr.V (I) :=
              Create_Value_Discrete (Std_Ulogic'Pos (Op (V)), El_Typ);
         end;
      end loop;

      return Create_Value_Const_Array (Create_Res_Bound (Vec.Typ), Arr);
   end Synth_Vector_Monadic;

   function Synth_Vector_Reduce
     (Init : Std_Ulogic; Vec : Value_Acc; Op : Table_2d) return Value_Acc
   is
      El_Typ : constant Type_Acc := Vec.Typ.Vec_El;
      Res : Std_Ulogic;
   begin
      Res := Init;
      for I in Vec.Arr.V'Range loop
         declare
            V : constant Std_Ulogic :=
              Std_Ulogic'Val (Vec.Arr.V (I).Scal);
         begin
            Res := Op (Res, V);
         end;
      end loop;

      return Create_Value_Discrete (Std_Ulogic'Pos (Res), El_Typ);
   end Synth_Vector_Reduce;

   function Synth_Static_Monadic_Predefined (Syn_Inst : Synth_Instance_Acc;
                                             Imp : Node;
                                             Operand : Value_Acc;
                                             Expr : Node) return Value_Acc
   is
      Def : constant Iir_Predefined_Functions :=
        Get_Implicit_Definition (Imp);
      Inter_Chain : constant Node :=
        Get_Interface_Declaration_Chain (Imp);
      Oper_Type : constant Node := Get_Type (Inter_Chain);
      Oper_Typ : constant Type_Acc := Get_Value_Type (Syn_Inst, Oper_Type);
      --  Res_Typ : constant Type_Acc :=
      --    Get_Value_Type (Syn_Inst, Get_Type (Expr));
   begin
      case Def is
         when Iir_Predefined_Boolean_Not
           | Iir_Predefined_Bit_Not =>
            return Create_Value_Discrete (1 - Operand.Scal, Oper_Typ);

         when Iir_Predefined_Integer_Negation =>
            return Create_Value_Discrete (-Operand.Scal, Oper_Typ);

         when Iir_Predefined_Floating_Negation =>
            return Create_Value_Float (-Operand.Fp, Oper_Typ);
         when Iir_Predefined_Floating_Identity =>
            return Operand;
         when Iir_Predefined_Floating_Absolute =>
            return Create_Value_Float (abs Operand.Fp, Oper_Typ);

         when Iir_Predefined_Ieee_1164_Condition_Operator =>
            --  Constant std_logic: need to convert.
            declare
               Val : Uns32;
               Zx : Uns32;
            begin
               From_Std_Logic (Operand.Scal, Val, Zx);
               return Create_Value_Discrete
                 (Boolean'Pos (Val = 1 and Zx = 0), Boolean_Type);
            end;

         when Iir_Predefined_Ieee_Numeric_Std_Neg_Sgn =>
            declare
               Op_Arr : Std_Logic_Vector (1 .. Natural (Operand.Arr.Len));
            begin
               To_Std_Logic_Vector (Operand, Op_Arr);
               declare
                  Res_Arr : constant Std_Logic_Vector := Neg_Sgn (Op_Arr);
               begin
                  return To_Value_Acc (Res_Arr, Operand.Typ.Vec_El);
               end;
            end;

         when Iir_Predefined_Ieee_1164_Vector_Not =>
            return Synth_Vector_Monadic (Operand, Not_Table);

         when Iir_Predefined_Ieee_1164_Vector_Or_Reduce =>
            return Synth_Vector_Reduce ('0', Operand, Or_Table);

         when others =>
            Error_Msg_Synth
              (+Expr, "synth_static_monadic_predefined: unhandled "
                 & Iir_Predefined_Functions'Image (Def));
            raise Internal_Error;
      end case;
   end Synth_Static_Monadic_Predefined;
end Synth.Static_Oper;