-- 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 Types_Utils; use Types_Utils; with Mutils; with Vhdl.Ieee.Std_Logic_1164; use Vhdl.Ieee.Std_Logic_1164; with Vhdl.Errors; use Vhdl.Errors; with Vhdl.Utils; use Vhdl.Utils; with Areapools; with Netlists; use Netlists; with Netlists.Gates; use Netlists.Gates; with Netlists.Builders; use Netlists.Builders; with Netlists.Folds; use Netlists.Folds; with Netlists.Utils; with Synth.Errors; use Synth.Errors; with Synth.Stmts; use Synth.Stmts; with Synth.Expr; use Synth.Expr; with Synth.Source; with Synth.Static_Oper; use Synth.Static_Oper; package body Synth.Oper is procedure Set_Location (N : Net; Loc : Node) renames Synth.Source.Set_Location; function Synth_Uresize (Ctxt : Context_Acc; N : Net; W : Width; Loc : Node) return Net is begin return Build2_Uresize (Ctxt, N, W, Get_Location (Loc)); end Synth_Uresize; function Synth_Uresize (Ctxt : Context_Acc; Val : Valtyp; W : Width; Loc : Node) return Net is Res : Net; begin if Is_Static (Val.Val) and then Val.Typ.Kind = Type_Discrete then if Val.Typ.Drange.Is_Signed and then Read_Discrete (Val) < 0 then -- TODO. raise Internal_Error; else Res := Build2_Const_Uns (Ctxt, To_Uns64 (Read_Discrete (Val)), W); end if; Set_Location (Res, Loc); return Res; end if; return Synth_Uresize (Ctxt, Get_Net (Ctxt, Val), W, Loc); end Synth_Uresize; function Synth_Sresize (Ctxt : Context_Acc; Val : Valtyp; W : Width; Loc : Node) return Net is Res : Net; begin if Is_Static (Val.Val) and then Val.Typ.Kind = Type_Discrete then if Val.Typ.Drange.Is_Signed then Res := Build2_Const_Int (Ctxt, Read_Discrete (Val), W); else -- TODO. raise Internal_Error; end if; Set_Location (Res, Loc); return Res; end if; return Build2_Sresize (Ctxt, Get_Net (Ctxt, Val), W, Get_Location (Loc)); end Synth_Sresize; function Synth_Bit_Eq_Const (Ctxt : Context_Acc; Cst : Valtyp; Expr : Valtyp; Loc : Node) return Valtyp is Val : Uns32; Zx : Uns32; N : Net; begin if Is_Static (Expr.Val) then return Create_Value_Discrete (Boolean'Pos (Read_Discrete (Cst) = Read_Discrete (Expr)), Boolean_Type); end if; To_Logic (Read_Discrete (Cst), Cst.Typ, Val, Zx); if Zx /= 0 then -- Equal unknown -> return X N := Build_Const_UL32 (Ctxt, 0, 1, 1); Set_Location (N, Loc); return Create_Value_Net (N, Boolean_Type); elsif Val = 1 then -- The result type is a boolean; convert if needed. if Expr.Typ.Kind = Type_Logic then return Create_Value_Net (Get_Net (Ctxt, Expr), Boolean_Type); else pragma Assert (Expr.Typ.Kind = Type_Bit); return Expr; end if; else pragma Assert (Val = 0); N := Build_Monadic (Ctxt, Id_Not, Get_Net (Ctxt, Expr)); Set_Location (N, Loc); return Create_Value_Net (N, Boolean_Type); end if; end Synth_Bit_Eq_Const; -- Create the result range of an operator. According to the ieee standard, -- the range is LEN-1 downto 0. function Create_Res_Bound (Prev : Valtyp) return Type_Acc is Res : Type_Acc; begin Res := Prev.Typ; case Res.Kind is when Type_Vector => if Res.Vbound.Dir = Dir_Downto and then Res.Vbound.Right = 0 then -- Normalized range return Res; end if; return Create_Vec_Type_By_Length (Res.W, Res.Vec_El); when Type_Slice => return Create_Vec_Type_By_Length (Res.W, Res.Slice_El); when Type_Unbounded_Vector => raise Internal_Error; when others => raise Internal_Error; end case; end Create_Res_Bound; function Create_Bounds_From_Length (Syn_Inst : Synth_Instance_Acc; Atype : Iir; Len : Iir_Index32) return Bound_Type is Res : Bound_Type; Index_Bounds : Discrete_Range_Type; begin Synth_Discrete_Range (Syn_Inst, Atype, Index_Bounds); Res := (Left => Int32 (Index_Bounds.Left), Right => 0, Dir => Index_Bounds.Dir, Len => Uns32 (Len)); if Len = 0 then -- Special case. Res.Right := Res.Left; case Index_Bounds.Dir is when Dir_To => Res.Left := Res.Right + 1; when Dir_Downto => Res.Left := Res.Right - 1; end case; else case Index_Bounds.Dir is when Dir_To => Res.Right := Res.Left + Int32 (Len - 1); when Dir_Downto => Res.Right := Res.Left - Int32 (Len - 1); end case; end if; return Res; end Create_Bounds_From_Length; -- Do a match comparison between CST and OPER. -- Return No_Net if CST has incorrect value. function Synth_Match (Ctxt : Context_Acc; Cst : Valtyp; Oper : Valtyp; Expr : Node; Op : Compare_Module_Id := Id_Eq) return Net is Wd : constant Width := Cst.Typ.W; pragma Assert (Wd > 0); Nwords : constant Natural := Natural ((Wd + 31) / 32); Mask : Uns32_Arr_Acc; Vals : Uns32_Arr_Acc; Boff : Natural; Woff : Natural; B : Uns32; M : Uns32; Nv : Net; Nm : Net; Res : Net; begin -- Flatten 0/1 DC. Mask := new Uns32_Arr'(0 .. Nwords - 1 => 0); Vals := new Uns32_Arr'(0 .. Nwords - 1 => 0); Boff := 0; Woff := 0; for I in reverse 1 .. Vec_Length (Cst.Typ) loop case Read_U8 (Cst.Val.Mem + Size_Type (I - 1)) is when Std_Logic_0_Pos | Std_Logic_L_Pos => B := 0; M := 1; when Std_Logic_1_Pos | Std_Logic_H_Pos => B := 1; M := 1; when Std_Logic_U_Pos | Std_Logic_X_Pos | Std_Logic_Z_Pos | Std_Logic_W_Pos => -- Never match -- FIXME: warning ? Unchecked_Deallocate (Mask); Unchecked_Deallocate (Vals); return No_Net; when Std_Logic_D_Pos => B := 0; M := 0; when others => raise Internal_Error; end case; Mask (Woff) := Mask (Woff) or Shift_Left (M, Boff); Vals (Woff) := Vals (Woff) or Shift_Left (B, Boff); Boff := Boff + 1; if Boff = 32 then Boff := 0; Woff := Woff + 1; end if; end loop; -- Generate and + eq Nv := Build2_Const_Vec (Ctxt, Wd, Vals.all); Set_Location (Nv, Expr); Unchecked_Deallocate (Vals); Nm := Build2_Const_Vec (Ctxt, Wd, Mask.all); Set_Location (Nm, Expr); Unchecked_Deallocate (Mask); Res := Build_Dyadic (Ctxt, Id_And, Get_Net (Ctxt, Oper), Nm); Set_Location (Res, Expr); Res := Build_Compare (Ctxt, Op, Res, Nv); Set_Location (Res, Expr); return Res; end Synth_Match; -- Note: LEFT or RIGHT can be a single bit. function Synth_Dyadic_Uns_Uns (Ctxt : Context_Acc; Id : Dyadic_Module_Id; Left, Right : Valtyp; Expr : Node) return Valtyp is W : constant Width := Width'Max (Left.Typ.W, Right.Typ.W); El_Typ : Type_Acc; Rtype : Type_Acc; L1, R1 : Net; N : Net; begin if Left.Typ.Kind = Type_Vector then El_Typ := Left.Typ.Vec_El; elsif Right.Typ.Kind = Type_Vector then El_Typ := Right.Typ.Vec_El; else raise Internal_Error; end if; Rtype := Create_Vec_Type_By_Length (W, El_Typ); L1 := Synth_Uresize (Ctxt, Left, W, Expr); R1 := Synth_Uresize (Ctxt, Right, W, Expr); N := Build_Dyadic (Ctxt, Id, L1, R1); Set_Location (N, Expr); return Create_Value_Net (N, Rtype); end Synth_Dyadic_Uns_Uns; function Synth_Dyadic_Uns_Nat (Ctxt : Context_Acc; Id : Dyadic_Module_Id; Left, Right : Valtyp; Expr : Node) return Valtyp is L : constant Net := Get_Net (Ctxt, Left); R1 : Net; N : Net; begin R1 := Synth_Uresize (Ctxt, Right, Left.Typ.W, Expr); N := Build_Dyadic (Ctxt, Id, L, R1); Set_Location (N, Expr); return Create_Value_Net (N, Create_Res_Bound (Left)); end Synth_Dyadic_Uns_Nat; function Synth_Dyadic_Nat_Uns (Ctxt : Context_Acc; Id : Dyadic_Module_Id; Left, Right : Valtyp; Expr : Node) return Valtyp is R : constant Net := Get_Net (Ctxt, Right); L1 : Net; N : Net; begin L1 := Synth_Uresize (Ctxt, Left, Right.Typ.W, Expr); N := Build_Dyadic (Ctxt, Id, L1, R); Set_Location (N, Expr); return Create_Value_Net (N, Create_Res_Bound (Right)); end Synth_Dyadic_Nat_Uns; -- Note: LEFT or RIGHT can be a single bit. function Synth_Dyadic_Sgn_Sgn (Ctxt : Context_Acc; Id : Dyadic_Module_Id; Left, Right : Valtyp; Expr : Node) return Valtyp is W : constant Width := Width'Max (Left.Typ.W, Right.Typ.W); El_Typ : Type_Acc; Rtype : Type_Acc; L1, R1 : Net; N : Net; begin if Left.Typ.Kind = Type_Vector then El_Typ := Left.Typ.Vec_El; elsif Right.Typ.Kind = Type_Vector then El_Typ := Right.Typ.Vec_El; else raise Internal_Error; end if; Rtype := Create_Vec_Type_By_Length (W, El_Typ); L1 := Synth_Sresize (Ctxt, Left, W, Expr); R1 := Synth_Sresize (Ctxt, Right, W, Expr); N := Build_Dyadic (Ctxt, Id, L1, R1); Set_Location (N, Expr); return Create_Value_Net (N, Rtype); end Synth_Dyadic_Sgn_Sgn; function Synth_Dyadic_Sgn_Int (Ctxt : Context_Acc; Id : Dyadic_Module_Id; Left, Right : Valtyp; Expr : Node) return Valtyp is L : constant Net := Get_Net (Ctxt, Left); R1 : Net; N : Net; begin R1 := Synth_Sresize (Ctxt, Right, Left.Typ.W, Expr); N := Build_Dyadic (Ctxt, Id, L, R1); Set_Location (N, Expr); return Create_Value_Net (N, Create_Res_Bound (Left)); end Synth_Dyadic_Sgn_Int; function Synth_Dyadic_Int_Sgn (Ctxt : Context_Acc; Id : Dyadic_Module_Id; Left, Right : Valtyp; Expr : Node) return Valtyp is R : constant Net := Get_Net (Ctxt, Right); L1 : Net; N : Net; begin L1 := Synth_Sresize (Ctxt, Left, Right.Typ.W, Expr); N := Build_Dyadic (Ctxt, Id, R, L1); Set_Location (N, Expr); return Create_Value_Net (N, Create_Res_Bound (Right)); end Synth_Dyadic_Int_Sgn; function Synth_Dyadic_Operation (Syn_Inst : Synth_Instance_Acc; Imp : Node; Left_Expr : Node; Right_Expr : Node; Expr : Node) return Valtyp is Ctxt : constant Context_Acc := Get_Build (Syn_Inst); Def : constant Iir_Predefined_Functions := Get_Implicit_Definition (Imp); Inter_Chain : constant Node := Get_Interface_Declaration_Chain (Imp); Expr_Type : constant Node := Get_Type (Expr); Left_Type : constant Node := Get_Type (Inter_Chain); Right_Type : constant Node := Get_Type (Get_Chain (Inter_Chain)); Left_Typ : constant Type_Acc := Get_Subtype_Object (Syn_Inst, Left_Type); Right_Typ : constant Type_Acc := Get_Subtype_Object (Syn_Inst, Right_Type); Expr_Typ : constant Type_Acc := Get_Subtype_Object (Syn_Inst, Expr_Type); Srec : Memtyp; Left : Valtyp; Right : Valtyp; function Synth_Bit_Dyadic (Id : Dyadic_Module_Id) return Valtyp is N : Net; begin N := Build_Dyadic (Ctxt, Id, Get_Net (Ctxt, Left), Get_Net (Ctxt, Right)); Set_Location (N, Expr); return Create_Value_Net (N, Left.Typ); end Synth_Bit_Dyadic; function Synth_Compare (Id : Compare_Module_Id; Res_Type : Type_Acc) return Valtyp is N : Net; begin pragma Assert (Left_Type = Right_Type); pragma Assert (Res_Type = Expr_Typ); N := Build2_Compare (Ctxt, Id, Get_Net (Ctxt, Left), Get_Net (Ctxt, Right)); Set_Location (N, Expr); return Create_Value_Net (N, Res_Type); end Synth_Compare; function Synth_Minmax (Id : Compare_Module_Id) return Valtyp is L : constant Net := Get_Net (Ctxt, Left); R : constant Net := Get_Net (Ctxt, Right); Sel, N : Net; begin pragma Assert (Left_Type = Right_Type); Sel := Build2_Compare (Ctxt, Id, L, R); Set_Location (Sel, Expr); N := Build_Mux2 (Ctxt, Sel, R, L); Set_Location (N, Expr); return Create_Value_Net (N, Expr_Typ); end Synth_Minmax; function Synth_Compare_Array (Id : Compare_Module_Id; Res_Type : Type_Acc) return Valtyp is N : Net; begin if Left.Typ.Kind = Type_Vector then Warning_Msg_Synth (+Expr, "comparing non-numeric vector is unexpected"); if Left.Typ.W = Right.Typ.W then N := Build2_Compare (Ctxt, Id, Get_Net (Ctxt, Left), Get_Net (Ctxt, Right)); Set_Location (N, Expr); return Create_Value_Net (N, Res_Type); elsif Left.Typ.W < Right.Typ.W then -- TODO: truncate right, compare using id_eq. raise Internal_Error; else -- TODO: truncate left, compare using id. raise Internal_Error; end if; else raise Internal_Error; end if; end Synth_Compare_Array; function Synth_Compare_Uns_Nat (Id : Compare_Module_Id; Res_Type : Type_Acc) return Valtyp is N : Net; begin N := Synth_Uresize (Ctxt, Right, Left.Typ.W, Expr); N := Build2_Compare (Ctxt, Id, Get_Net (Ctxt, Left), N); Set_Location (N, Expr); return Create_Value_Net (N, Res_Type); end Synth_Compare_Uns_Nat; function Synth_Compare_Nat_Uns (Id : Compare_Module_Id; Res_Type : Type_Acc) return Valtyp is N : Net; begin N := Synth_Uresize (Ctxt, Left, Right.Typ.W, Expr); N := Build2_Compare (Ctxt, Id, Get_Net (Ctxt, Right), N); Set_Location (N, Expr); return Create_Value_Net (N, Res_Type); end Synth_Compare_Nat_Uns; function Synth_Compare_Sgn_Int (Id : Compare_Module_Id; Res_Typ : Type_Acc) return Valtyp is N : Net; begin N := Synth_Sresize (Ctxt, Right, Left.Typ.W, Expr); N := Build2_Compare (Ctxt, Id, Get_Net (Ctxt, Left), N); Set_Location (N, Expr); return Create_Value_Net (N, Res_Typ); end Synth_Compare_Sgn_Int; function Synth_Compare_Int_Sgn (Id : Compare_Module_Id; Res_Typ : Type_Acc) return Valtyp is N : Net; begin N := Synth_Sresize (Ctxt, Left, Right.Typ.W, Expr); N := Build2_Compare (Ctxt, Id, N, Get_Net (Ctxt, Right)); Set_Location (N, Expr); return Create_Value_Net (N, Res_Typ); end Synth_Compare_Int_Sgn; function Synth_Vec_Dyadic (Id : Dyadic_Module_Id) return Valtyp is N : Net; begin if Left.Typ.W /= Right.Typ.W then Error_Msg_Synth (+Expr, "operands don't have the same length"); return No_Valtyp; end if; N := Build_Dyadic (Ctxt, Id, Get_Net (Ctxt, Left), Get_Net (Ctxt, Right)); Set_Location (N, Expr); return Create_Value_Net (N, Create_Res_Bound (Left)); end Synth_Vec_Dyadic; function Synth_Int_Dyadic (Id : Dyadic_Module_Id) return Valtyp is Etype : constant Type_Acc := Get_Subtype_Object (Syn_Inst, Expr_Type); N : Net; begin N := Build_Dyadic (Ctxt, Id, Get_Net (Ctxt, Left), Get_Net (Ctxt, Right)); Set_Location (N, Expr); return Create_Value_Net (N, Etype); end Synth_Int_Dyadic; function Synth_Compare_Uns_Uns (Id : Compare_Module_Id; Res_Type : Type_Acc) return Valtyp is W : constant Width := Width'Max (Left.Typ.W, Right.Typ.W); L1, R1 : Net; N : Net; begin L1 := Synth_Uresize (Ctxt, Left, W, Expr); R1 := Synth_Uresize (Ctxt, Right, W, Expr); N := Build2_Compare (Ctxt, Id, L1, R1); Set_Location (N, Expr); return Create_Value_Net (N, Res_Type); end Synth_Compare_Uns_Uns; function Synth_Compare_Sgn_Sgn (Id : Compare_Module_Id; Res_Typ : Type_Acc) return Valtyp is W : constant Width := Width'Max (Left.Typ.W, Right.Typ.W); L1, R1 : Net; N : Net; begin L1 := Synth_Sresize (Ctxt, Left, W, Expr); R1 := Synth_Sresize (Ctxt, Right, W, Expr); N := Build2_Compare (Ctxt, Id, L1, R1); Set_Location (N, Expr); return Create_Value_Net (N, Res_Typ); end Synth_Compare_Sgn_Sgn; type Oper_Kind is (Oper_Left, Oper_Right); function Synth_Udivmod (Id : Dyadic_Module_Id; Vec : Oper_Kind) return Valtyp is W : constant Width := Width'Max (Left.Typ.W, Right.Typ.W); L1, R1 : Net; Res_Typ : Type_Acc; N : Net; begin L1 := Synth_Uresize (Ctxt, Left, W, Expr); R1 := Synth_Uresize (Ctxt, Right, W, Expr); case Vec is when Oper_Left => Res_Typ := Left.Typ; when Oper_Right => Res_Typ := Right.Typ; end case; Res_Typ := Create_Vec_Type_By_Length (Res_Typ.W, Res_Typ.Vec_El); N := Build_Dyadic (Ctxt, Id, L1, R1); Set_Location (N, Expr); N := Build2_Uresize (Ctxt, N, Res_Typ.W, Get_Location (Expr)); return Create_Value_Net (N, Res_Typ); end Synth_Udivmod; function Synth_Sdivmod (Id : Dyadic_Module_Id; Vec : Oper_Kind) return Valtyp is W : constant Width := Width'Max (Left.Typ.W, Right.Typ.W); L1, R1 : Net; Res_Typ : Type_Acc; N : Net; begin L1 := Synth_Sresize (Ctxt, Left, W, Expr); R1 := Synth_Sresize (Ctxt, Right, W, Expr); case Vec is when Oper_Left => Res_Typ := Left.Typ; when Oper_Right => Res_Typ := Right.Typ; end case; Res_Typ := Create_Vec_Type_By_Length (Res_Typ.W, Res_Typ.Vec_El); N := Build_Dyadic (Ctxt, Id, L1, R1); Set_Location (N, Expr); N := Build2_Sresize (Ctxt, N, Res_Typ.W, Get_Location (Expr)); return Create_Value_Net (N, Res_Typ); end Synth_Sdivmod; function Synth_Shift (Sh_Pos : Module_Id; Sh_Neg : Module_Id) return Valtyp is L1, R1 : Net; N, Nn, Nr1, Cond : Net; begin L1 := Get_Net (Ctxt, Left); R1 := Get_Net (Ctxt, Right); -- Handle the case when the RHS is positive. N := Build_Shift_Rotate (Ctxt, Sh_Pos, L1, R1); Set_Location (N, Expr); if not Is_Positive (Right) then -- If we cannot trivially prove that the RHS is positive, also -- handle the case when it could be negative. -- At worst, the optimizer will remove that part. Nr1 := Build_Monadic (Ctxt, Id_Neg, R1); Set_Location (Nr1, Expr); Nn := Build_Shift_Rotate (Ctxt, Sh_Neg, L1, Nr1); Set_Location (Nn, Expr); -- Extract the sign bit. Cond := Build_Extract (Ctxt, R1, Get_Width (R1) - 1, 1); Set_Location (Cond, Expr); N := Build_Mux2 (Ctxt, Cond, N, Nn); Set_Location (N, Expr); end if; return Create_Value_Net (N, Create_Res_Bound (Left)); end Synth_Shift; function Synth_Rotation (Id : Module_Id) return Valtyp is Amt : Int64; Ww : Width; L1, R1 : Net; N : Net; begin if Is_Static_Val (Right.Val) then Amt := Get_Static_Discrete (Right); if Amt < 0 then raise Internal_Error; end if; Amt := Amt mod Int64 (Left.Typ.W); R1 := Build_Const_UB32 (Ctxt, Uns32 (Amt), Right.Typ.W); Set_Location (R1, Right_Expr); elsif not Is_Positive (Right) then Error_Msg_Synth (+Expr, "rotation quantity must be unsigned"); return Left; else R1 := Get_Net (Ctxt, Right); Ww := Netlists.Utils.Clog2 (Left.Typ.W); if Right.Typ.W >= Ww then if Mutils.Is_Power2 (Uns64 (Left.Typ.W)) then R1 := Build2_Trunc (Ctxt, Id_Utrunc, R1, Ww, +Expr); else Error_Msg_Synth (+Expr, "vector length of rotation must be a power of 2"); return Left; end if; end if; end if; L1 := Get_Net (Ctxt, Left); N := Build_Shift_Rotate (Ctxt, Id, L1, R1); Set_Location (N, Expr); return Create_Value_Net (N, Create_Res_Bound (Left)); end Synth_Rotation; begin Left := Synth_Expression_With_Type (Syn_Inst, Left_Expr, Left_Typ); if Left = No_Valtyp then return No_Valtyp; end if; Left := Synth_Subtype_Conversion (Ctxt, Left, Left_Typ, False, Expr); Right := Synth_Expression_With_Type (Syn_Inst, Right_Expr, Right_Typ); if Right = No_Valtyp then return No_Valtyp; end if; Right := Synth_Subtype_Conversion (Ctxt, Right, Right_Typ, False, Expr); if Is_Static_Val (Left.Val) and Is_Static_Val (Right.Val) then Srec := Synth_Static_Dyadic_Predefined (Syn_Inst, Imp, Get_Value_Memtyp (Left), Get_Value_Memtyp (Right), Expr); if Srec = Null_Memtyp then return No_Valtyp; end if; return Create_Value_Memtyp (Srec); end if; Strip_Const (Left); Strip_Const (Right); case Def is when Iir_Predefined_Error => return No_Valtyp; when Iir_Predefined_Bit_And | Iir_Predefined_Boolean_And | Iir_Predefined_Ieee_1164_Scalar_And => return Synth_Bit_Dyadic (Id_And); when Iir_Predefined_Bit_Xor | Iir_Predefined_Boolean_Xor | Iir_Predefined_Ieee_1164_Scalar_Xor => return Synth_Bit_Dyadic (Id_Xor); when Iir_Predefined_Bit_Or | Iir_Predefined_Boolean_Or | Iir_Predefined_Ieee_1164_Scalar_Or => return Synth_Bit_Dyadic (Id_Or); when Iir_Predefined_Bit_Nor | Iir_Predefined_Ieee_1164_Scalar_Nor => return Synth_Bit_Dyadic (Id_Nor); when Iir_Predefined_Bit_Nand | Iir_Predefined_Boolean_Nand | Iir_Predefined_Ieee_1164_Scalar_Nand => return Synth_Bit_Dyadic (Id_Nand); when Iir_Predefined_Bit_Xnor | Iir_Predefined_Boolean_Xnor | Iir_Predefined_Ieee_1164_Scalar_Xnor => return Synth_Bit_Dyadic (Id_Xnor); 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_Vec_Dyadic (Id_And); 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_Vec_Dyadic (Id_Or); when Iir_Predefined_Ieee_1164_Vector_Nand | Iir_Predefined_Ieee_Numeric_Std_Nand_Uns_Uns | Iir_Predefined_Ieee_Numeric_Std_Nand_Sgn_Sgn => return Synth_Vec_Dyadic (Id_Nand); when Iir_Predefined_Ieee_1164_Vector_Nor | Iir_Predefined_Ieee_Numeric_Std_Nor_Uns_Uns | Iir_Predefined_Ieee_Numeric_Std_Nor_Sgn_Sgn => return Synth_Vec_Dyadic (Id_Nor); when Iir_Predefined_TF_Array_Xor | Iir_Predefined_Ieee_1164_Vector_Xor | Iir_Predefined_Ieee_Numeric_Std_Xor_Uns_Uns | Iir_Predefined_Ieee_Numeric_Std_Xor_Sgn_Sgn => return Synth_Vec_Dyadic (Id_Xor); when Iir_Predefined_Ieee_1164_Vector_Xnor | Iir_Predefined_Ieee_Numeric_Std_Xnor_Uns_Uns | Iir_Predefined_Ieee_Numeric_Std_Xnor_Sgn_Sgn => return Synth_Vec_Dyadic (Id_Xnor); when Iir_Predefined_Enum_Equality => if Left_Typ = Bit_Type or else Left_Typ = Logic_Type then if Is_Static (Left.Val) then return Synth_Bit_Eq_Const (Ctxt, Left, Right, Expr); elsif Is_Static (Right.Val) then return Synth_Bit_Eq_Const (Ctxt, Right, Left, Expr); end if; end if; return Synth_Compare (Id_Eq, Boolean_Type); when Iir_Predefined_Enum_Inequality => -- TODO: Optimize ? return Synth_Compare (Id_Ne, Boolean_Type); when Iir_Predefined_Enum_Less_Equal => return Synth_Compare (Id_Ult, Boolean_Type); when Iir_Predefined_Std_Ulogic_Match_Equality => return Synth_Compare (Id_Eq, Logic_Type); when Iir_Predefined_Std_Ulogic_Match_Inequality => return Synth_Compare (Id_Ne, Logic_Type); when Iir_Predefined_Std_Ulogic_Match_Less => return Synth_Compare (Id_Ult, Logic_Type); when Iir_Predefined_Std_Ulogic_Match_Less_Equal => return Synth_Compare (Id_Ule, Logic_Type); when Iir_Predefined_Std_Ulogic_Match_Greater => return Synth_Compare (Id_Ugt, Logic_Type); when Iir_Predefined_Std_Ulogic_Match_Greater_Equal => return Synth_Compare (Id_Uge, Logic_Type); when Iir_Predefined_Array_Equality | Iir_Predefined_Record_Equality => if not Is_Matching_Bounds (Left.Typ, Right.Typ) then Warning_Msg_Synth (+Expr, "length of '=' operands doesn't match, result is false"); return Create_Value_Discrete (0, Boolean_Type); end if; return Synth_Compare (Id_Eq, Boolean_Type); when Iir_Predefined_Std_Ulogic_Array_Match_Equality => declare Cst, Oper : Valtyp; Res : Net; begin if Left.Typ.W /= Right.Typ.W then Error_Msg_Synth (+Expr, "operands of ?= don't have the same size"); return Create_Value_Discrete (0, Bit_Type); end if; if Is_Static (Left.Val) then Cst := Left; Oper := Right; elsif Is_Static (Right.Val) then Cst := Right; Oper := Left; else Warning_Msg_Synth (+Expr, "no operand of ?= is constant, handled like ="); return Synth_Compare (Id_Eq, Logic_Type); end if; Res := Synth_Match (Ctxt, Cst, Oper, Expr); if Res = No_Net then return Create_Value_Discrete (Std_Logic_X_Pos, Expr_Typ); else return Create_Value_Net (Res, Logic_Type); end if; end; when Iir_Predefined_Std_Ulogic_Array_Match_Inequality => declare Cst, Oper : Valtyp; Res : Net; begin if Left.Typ.W /= Right.Typ.W then Error_Msg_Synth (+Expr, "operands of ?/= don't have the same size"); return Create_Value_Discrete (1, Bit_Type); end if; if Is_Static (Left.Val) then Cst := Left; Oper := Right; elsif Is_Static (Right.Val) then Cst := Right; Oper := Left; else Warning_Msg_Synth (+Expr, "no operand of ?/= is constant, handled like /="); return Synth_Compare (Id_Ne, Logic_Type); end if; Res := Synth_Match (Ctxt, Cst, Oper, Expr, Id_Ne); if Res = No_Net then return Create_Value_Discrete (Std_Logic_X_Pos, Expr_Typ); else return Create_Value_Net (Res, Logic_Type); end if; end; when Iir_Predefined_Array_Inequality | Iir_Predefined_Record_Inequality => if not Is_Matching_Bounds (Left.Typ, Right.Typ) then Warning_Msg_Synth (+Expr, "length of '/=' operands doesn't match, result is true"); return Create_Value_Discrete (1, Boolean_Type); end if; return Synth_Compare (Id_Ne, Boolean_Type); when Iir_Predefined_Array_Greater => return Synth_Compare_Array (Id_Ugt, Boolean_Type); when Iir_Predefined_Array_Greater_Equal => return Synth_Compare_Array (Id_Uge, Boolean_Type); when Iir_Predefined_Array_Less => return Synth_Compare_Array (Id_Ult, Boolean_Type); when Iir_Predefined_Ieee_Numeric_Std_Add_Uns_Nat | Iir_Predefined_Ieee_Std_Logic_Unsigned_Add_Slv_Int => -- "+" (Unsigned, Natural) return Synth_Dyadic_Uns_Nat (Ctxt, Id_Add, Left, Right, Expr); when Iir_Predefined_Ieee_Numeric_Std_Add_Nat_Uns => -- "+" (Natural, Unsigned) return Synth_Dyadic_Nat_Uns (Ctxt, Id_Add, Left, Right, Expr); when Iir_Predefined_Ieee_Numeric_Std_Add_Uns_Uns | Iir_Predefined_Ieee_Numeric_Std_Add_Uns_Log | Iir_Predefined_Ieee_Std_Logic_Unsigned_Add_Slv_Log | Iir_Predefined_Ieee_Std_Logic_Unsigned_Add_Slv_Slv | Iir_Predefined_Ieee_Std_Logic_Arith_Add_Uns_Uns_Uns | Iir_Predefined_Ieee_Std_Logic_Arith_Add_Uns_Uns_Slv | Iir_Predefined_Ieee_Std_Logic_Arith_Add_Uns_Log_Slv | Iir_Predefined_Ieee_Std_Logic_Arith_Add_Uns_Log_Uns => -- "+" (Unsigned, Unsigned) return Synth_Dyadic_Uns_Uns (Ctxt, Id_Add, Left, Right, Expr); when Iir_Predefined_Ieee_Numeric_Std_Add_Sgn_Int | Iir_Predefined_Ieee_Std_Logic_Signed_Add_Slv_Int => -- "+" (Signed, Integer) return Synth_Dyadic_Sgn_Int (Ctxt, Id_Add, Left, Right, Expr); when Iir_Predefined_Ieee_Numeric_Std_Add_Int_Sgn | Iir_Predefined_Ieee_Std_Logic_Arith_Add_Int_Sgn_Sgn | Iir_Predefined_Ieee_Std_Logic_Arith_Add_Int_Sgn_Slv => -- "+" (Integer, Signed) return Synth_Dyadic_Int_Sgn (Ctxt, Id_Add, Left, Right, Expr); when Iir_Predefined_Ieee_Numeric_Std_Add_Sgn_Sgn | Iir_Predefined_Ieee_Numeric_Std_Add_Sgn_Log | Iir_Predefined_Ieee_Numeric_Std_Add_Log_Sgn | Iir_Predefined_Ieee_Std_Logic_Arith_Add_Sgn_Sgn_Sgn | Iir_Predefined_Ieee_Std_Logic_Arith_Add_Sgn_Log_Sgn | Iir_Predefined_Ieee_Std_Logic_Arith_Add_Log_Sgn_Sgn | Iir_Predefined_Ieee_Std_Logic_Arith_Add_Sgn_Sgn_Slv | Iir_Predefined_Ieee_Std_Logic_Signed_Add_Slv_Slv => -- "+" (Signed, Signed) return Synth_Dyadic_Sgn_Sgn (Ctxt, Id_Add, Left, Right, Expr); when Iir_Predefined_Ieee_Numeric_Std_Sub_Uns_Nat | Iir_Predefined_Ieee_Std_Logic_Unsigned_Sub_Slv_Int => -- "-" (Unsigned, Natural) return Synth_Dyadic_Uns_Nat (Ctxt, Id_Sub, Left, Right, Expr); when Iir_Predefined_Ieee_Numeric_Std_Sub_Uns_Uns | Iir_Predefined_Ieee_Std_Logic_Unsigned_Sub_Slv_Slv | Iir_Predefined_Ieee_Std_Logic_Unsigned_Sub_Log_Slv | Iir_Predefined_Ieee_Std_Logic_Unsigned_Sub_Slv_Log | Iir_Predefined_Ieee_Std_Logic_Arith_Sub_Uns_Uns_Uns | Iir_Predefined_Ieee_Std_Logic_Arith_Sub_Uns_Uns_Slv | Iir_Predefined_Ieee_Std_Logic_Arith_Sub_Uns_Log_Uns => -- "-" (Unsigned, Unsigned) return Synth_Dyadic_Uns_Uns (Ctxt, Id_Sub, Left, Right, Expr); when Iir_Predefined_Ieee_Numeric_Std_Sub_Nat_Uns => -- "-" (Natural, Unsigned) return Synth_Dyadic_Nat_Uns (Ctxt, Id_Sub, Left, Right, Expr); when Iir_Predefined_Ieee_Numeric_Std_Sub_Sgn_Int | Iir_Predefined_Ieee_Std_Logic_Signed_Sub_Slv_Int => -- "-" (Signed, Integer) return Synth_Dyadic_Sgn_Int (Ctxt, Id_Sub, Left, Right, Expr); when Iir_Predefined_Ieee_Numeric_Std_Sub_Int_Sgn => -- "-" (Integer, Signed) return Synth_Dyadic_Int_Sgn (Ctxt, Id_Sub, Left, Right, Expr); when Iir_Predefined_Ieee_Numeric_Std_Sub_Sgn_Sgn | Iir_Predefined_Ieee_Numeric_Std_Sub_Sgn_Log | Iir_Predefined_Ieee_Numeric_Std_Sub_Log_Sgn | Iir_Predefined_Ieee_Std_Logic_Signed_Sub_Slv_Slv => -- "-" (Signed, Signed) return Synth_Dyadic_Sgn_Sgn (Ctxt, Id_Sub, Left, Right, Expr); when Iir_Predefined_Ieee_Numeric_Std_Mul_Sgn_Sgn | Iir_Predefined_Ieee_Std_Logic_Arith_Mul_Sgn_Sgn_Sgn | Iir_Predefined_Ieee_Std_Logic_Arith_Mul_Sgn_Sgn_Slv | Iir_Predefined_Ieee_Std_Logic_Signed_Mul_Slv_Slv => -- "*" (Signed, Signed) declare W : constant Width := Left.Typ.W + Right.Typ.W; L, R : Net; N : Net; begin L := Synth_Sresize (Ctxt, Left, W, Left_Expr); R := Synth_Sresize (Ctxt, Right, W, Right_Expr); N := Build_Dyadic (Ctxt, Id_Smul, L, R); Set_Location (N, Expr); return Create_Value_Net (N, Create_Vec_Type_By_Length (W, Left.Typ.Vec_El)); end; when Iir_Predefined_Ieee_Numeric_Std_Mul_Sgn_Int => declare Lw : constant Width := Left.Typ.W; W : constant Width := 2 * Lw; Rtype : Type_Acc; L, R : Net; N : Net; begin L := Synth_Sresize (Ctxt, Left, W, Left_Expr); R := Synth_Sresize (Ctxt, Right, W, Right_Expr); Rtype := Create_Vec_Type_By_Length (W, Left.Typ.Vec_El); N := Build_Dyadic (Ctxt, Id_Smul, L, R); Set_Location (N, Expr); return Create_Value_Net (N, Rtype); end; when Iir_Predefined_Ieee_Numeric_Std_Mul_Int_Sgn => declare Rw : constant Width := Right.Typ.W; W : constant Width := 2 * Rw; Rtype : Type_Acc; L, R : Net; N : Net; begin L := Synth_Sresize (Ctxt, Left, W, Left_Expr); R := Synth_Sresize (Ctxt, Right, W, Right_Expr); Rtype := Create_Vec_Type_By_Length (W, Right.Typ.Vec_El); N := Build_Dyadic (Ctxt, Id_Smul, L, R); Set_Location (N, Expr); return Create_Value_Net (N, Rtype); end; when Iir_Predefined_Ieee_Numeric_Std_Mul_Uns_Uns | Iir_Predefined_Ieee_Std_Logic_Arith_Mul_Uns_Uns_Uns | Iir_Predefined_Ieee_Std_Logic_Arith_Mul_Uns_Uns_Slv | Iir_Predefined_Ieee_Std_Logic_Unsigned_Mul_Slv_Slv => -- "*" (unsigned, unsigned) declare W : constant Width := Left.Typ.W + Right.Typ.W; Rtype : Type_Acc; L, R : Net; N : Net; begin L := Synth_Uresize (Ctxt, Left, W, Left_Expr); R := Synth_Uresize (Ctxt, Right, W, Right_Expr); Rtype := Create_Vec_Type_By_Length (W, Left.Typ.Vec_El); N := Build_Dyadic (Ctxt, Id_Umul, L, R); Set_Location (N, Expr); return Create_Value_Net (N, Rtype); end; when Iir_Predefined_Ieee_Numeric_Std_Mul_Uns_Nat => declare Lw : constant Width := Left.Typ.W; W : constant Width := 2 * Lw; L1, R1 : Net; Rtype : Type_Acc; N : Net; begin L1 := Synth_Uresize (Ctxt, Left, W, Expr); R1 := Synth_Uresize (Ctxt, Right, W, Expr); Rtype := Create_Vec_Type_By_Length (W, Left.Typ.Vec_El); N := Build_Dyadic (Ctxt, Id_Umul, L1, R1); Set_Location (N, Expr); return Create_Value_Net (N, Rtype); end; when Iir_Predefined_Ieee_Numeric_Std_Mul_Nat_Uns => declare Rw : constant Width := Right.Typ.W; W : constant Width := 2 * Rw; L1, R1 : Net; Rtype : Type_Acc; N : Net; begin L1 := Synth_Uresize (Ctxt, Left, W, Expr); R1 := Synth_Uresize (Ctxt, Right, W, Expr); Rtype := Create_Vec_Type_By_Length (W, Right.Typ.Vec_El); N := Build_Dyadic (Ctxt, Id_Umul, L1, R1); Set_Location (N, Expr); return Create_Value_Net (N, Rtype); end; when Iir_Predefined_Ieee_Std_Logic_Arith_Mul_Uns_Sgn_Sgn => -- "*" (unsigned, signed) declare W : constant Width := Left.Typ.W + 1 + Right.Typ.W; Rtype : Type_Acc; L, R : Net; N : Net; begin L := Synth_Uresize (Ctxt, Left, W, Left_Expr); R := Synth_Sresize (Ctxt, Right, W, Right_Expr); Rtype := Create_Vec_Type_By_Length (W, Left.Typ.Vec_El); N := Build_Dyadic (Ctxt, Id_Smul, L, R); Set_Location (N, Expr); return Create_Value_Net (N, Rtype); end; when Iir_Predefined_Ieee_Numeric_Std_Div_Uns_Uns | Iir_Predefined_Ieee_Numeric_Std_Div_Uns_Nat => return Synth_Udivmod (Id_Udiv, Oper_Left); when Iir_Predefined_Ieee_Numeric_Std_Div_Nat_Uns => return Synth_Udivmod (Id_Udiv, Oper_Right); when Iir_Predefined_Ieee_Numeric_Std_Div_Sgn_Int | Iir_Predefined_Ieee_Numeric_Std_Div_Sgn_Sgn => return Synth_Sdivmod (Id_Sdiv, Oper_Left); when Iir_Predefined_Ieee_Numeric_Std_Div_Int_Sgn => return Synth_Sdivmod (Id_Sdiv, Oper_Right); when Iir_Predefined_Ieee_Numeric_Std_Rem_Uns_Nat => return Synth_Udivmod (Id_Umod, Oper_Left); when Iir_Predefined_Ieee_Numeric_Std_Rem_Uns_Uns | Iir_Predefined_Ieee_Numeric_Std_Rem_Nat_Uns => return Synth_Udivmod (Id_Umod, Oper_Right); when Iir_Predefined_Ieee_Numeric_Std_Rem_Sgn_Int => return Synth_Sdivmod (Id_Srem, Oper_Left); when Iir_Predefined_Ieee_Numeric_Std_Rem_Sgn_Sgn | Iir_Predefined_Ieee_Numeric_Std_Rem_Int_Sgn => return Synth_Sdivmod (Id_Srem, Oper_Right); when Iir_Predefined_Ieee_Numeric_Std_Mod_Uns_Nat => return Synth_Udivmod (Id_Umod, Oper_Left); when Iir_Predefined_Ieee_Numeric_Std_Mod_Uns_Uns | Iir_Predefined_Ieee_Numeric_Std_Mod_Nat_Uns => return Synth_Udivmod (Id_Umod, Oper_Right); when Iir_Predefined_Ieee_Numeric_Std_Mod_Sgn_Int => return Synth_Sdivmod (Id_Smod, Oper_Left); when Iir_Predefined_Ieee_Numeric_Std_Mod_Sgn_Sgn | Iir_Predefined_Ieee_Numeric_Std_Mod_Int_Sgn => return Synth_Sdivmod (Id_Smod, Oper_Right); when Iir_Predefined_Ieee_Numeric_Std_Eq_Uns_Uns | Iir_Predefined_Ieee_Std_Logic_Unsigned_Eq_Slv_Slv | Iir_Predefined_Ieee_Numeric_Std_Match_Eq_Uns_Uns => -- "=" (Unsigned, Unsigned) [resize] return Synth_Compare_Uns_Uns (Id_Eq, Expr_Typ); when Iir_Predefined_Ieee_Numeric_Std_Eq_Uns_Nat | Iir_Predefined_Ieee_Numeric_Std_Match_Eq_Uns_Nat | Iir_Predefined_Ieee_Std_Logic_Unsigned_Eq_Slv_Int => -- "=" (Unsigned, Natural) return Synth_Compare_Uns_Nat (Id_Eq, Expr_Typ); when Iir_Predefined_Ieee_Numeric_Std_Eq_Nat_Uns | Iir_Predefined_Ieee_Numeric_Std_Match_Eq_Nat_Uns => -- "=" (Natural, Unsigned) [resize] return Synth_Compare_Nat_Uns (Id_Eq, Expr_Typ); when Iir_Predefined_Ieee_Numeric_Std_Eq_Sgn_Int | Iir_Predefined_Ieee_Numeric_Std_Match_Eq_Sgn_Int => -- "=" (Signed, Integer) return Synth_Compare_Sgn_Int (Id_Eq, Expr_Typ); when Iir_Predefined_Ieee_Numeric_Std_Eq_Sgn_Sgn | Iir_Predefined_Ieee_Numeric_Std_Match_Eq_Sgn_Sgn => -- "=" (Signed, Signed) [resize] return Synth_Compare_Sgn_Sgn (Id_Eq, Expr_Typ); when Iir_Predefined_Ieee_Numeric_Std_Eq_Int_Sgn | Iir_Predefined_Ieee_Numeric_Std_Match_Eq_Int_Sgn => -- "=" (Integer, Signed) return Synth_Compare_Int_Sgn (Id_Eq, Expr_Typ); when Iir_Predefined_Ieee_Numeric_Std_Ne_Uns_Uns | Iir_Predefined_Ieee_Std_Logic_Unsigned_Ne_Slv_Slv | Iir_Predefined_Ieee_Numeric_Std_Match_Ne_Uns_Uns => -- "/=" (Unsigned, Unsigned) [resize] return Synth_Compare_Uns_Uns (Id_Ne, Expr_Typ); when Iir_Predefined_Ieee_Numeric_Std_Ne_Uns_Nat | Iir_Predefined_Ieee_Numeric_Std_Match_Ne_Uns_Nat => -- "/=" (Unsigned, Natural) return Synth_Compare_Uns_Nat (Id_Ne, Expr_Typ); when Iir_Predefined_Ieee_Numeric_Std_Ne_Nat_Uns | Iir_Predefined_Ieee_Numeric_Std_Match_Ne_Nat_Uns => -- "/=" (Natural, Unsigned) [resize] return Synth_Compare_Nat_Uns (Id_Ne, Expr_Typ); when Iir_Predefined_Ieee_Numeric_Std_Ne_Sgn_Sgn | Iir_Predefined_Ieee_Numeric_Std_Match_Ne_Sgn_Sgn => -- "/=" (Signed, Signed) [resize] return Synth_Compare_Sgn_Sgn (Id_Ne, Expr_Typ); when Iir_Predefined_Ieee_Numeric_Std_Ne_Sgn_Int | Iir_Predefined_Ieee_Numeric_Std_Match_Ne_Sgn_Int => -- "/=" (Signed, Integer) return Synth_Compare_Sgn_Int (Id_Ne, Expr_Typ); when Iir_Predefined_Ieee_Numeric_Std_Ne_Int_Sgn | Iir_Predefined_Ieee_Numeric_Std_Match_Ne_Int_Sgn => -- "/=" (Integer, Signed) return Synth_Compare_Int_Sgn (Id_Ne, Expr_Typ); when Iir_Predefined_Ieee_Numeric_Std_Lt_Uns_Nat | Iir_Predefined_Ieee_Numeric_Std_Match_Lt_Uns_Nat => -- "<" (Unsigned, Natural) if Is_Static (Right.Val) and then Read_Discrete (Right) = 0 then -- Always false. return Create_Value_Discrete (0, Expr_Typ); end if; return Synth_Compare_Uns_Nat (Id_Ult, Expr_Typ); when Iir_Predefined_Ieee_Numeric_Std_Lt_Uns_Uns | Iir_Predefined_Ieee_Numeric_Std_Match_Lt_Uns_Uns | Iir_Predefined_Ieee_Std_Logic_Unsigned_Lt_Slv_Slv | Iir_Predefined_Ieee_Std_Logic_Arith_Lt_Uns_Uns => -- "<" (Unsigned, Unsigned) [resize] return Synth_Compare_Uns_Uns (Id_Ult, Expr_Typ); when Iir_Predefined_Ieee_Numeric_Std_Lt_Nat_Uns | Iir_Predefined_Ieee_Numeric_Std_Match_Lt_Nat_Uns => -- "<" (Natural, Unsigned) [resize] return Synth_Compare_Nat_Uns (Id_Ult, Expr_Typ); when Iir_Predefined_Ieee_Numeric_Std_Lt_Sgn_Sgn | Iir_Predefined_Ieee_Numeric_Std_Match_Lt_Sgn_Sgn => -- "<" (Signed, Signed) [resize] return Synth_Compare_Sgn_Sgn (Id_Slt, Expr_Typ); when Iir_Predefined_Ieee_Numeric_Std_Lt_Sgn_Int | Iir_Predefined_Ieee_Numeric_Std_Match_Lt_Sgn_Int => -- "<" (Signed, Integer) return Synth_Compare_Sgn_Int (Id_Slt, Expr_Typ); when Iir_Predefined_Ieee_Numeric_Std_Lt_Int_Sgn | Iir_Predefined_Ieee_Numeric_Std_Match_Lt_Int_Sgn => -- "<" (Integer, Signed) return Synth_Compare_Int_Sgn (Id_Slt, Expr_Typ); when Iir_Predefined_Ieee_Numeric_Std_Le_Uns_Uns | Iir_Predefined_Ieee_Std_Logic_Unsigned_Le_Slv_Slv | Iir_Predefined_Ieee_Numeric_Std_Match_Le_Uns_Uns => -- "<=" (Unsigned, Unsigned) [resize] return Synth_Compare_Uns_Uns (Id_Ule, Expr_Typ); when Iir_Predefined_Ieee_Numeric_Std_Le_Uns_Nat | Iir_Predefined_Ieee_Numeric_Std_Match_Le_Uns_Nat | Iir_Predefined_Ieee_Std_Logic_Unsigned_Le_Slv_Int => -- "<=" (Unsigned, Natural) return Synth_Compare_Uns_Nat (Id_Ule, Expr_Typ); when Iir_Predefined_Ieee_Numeric_Std_Le_Nat_Uns | Iir_Predefined_Ieee_Numeric_Std_Match_Le_Nat_Uns => -- "<=" (Natural, Unsigned) [resize] return Synth_Compare_Nat_Uns (Id_Ule, Expr_Typ); when Iir_Predefined_Ieee_Numeric_Std_Le_Sgn_Sgn | Iir_Predefined_Ieee_Numeric_Std_Match_Le_Sgn_Sgn => -- "<=" (Signed, Signed) return Synth_Compare_Sgn_Sgn (Id_Sle, Expr_Typ); when Iir_Predefined_Ieee_Numeric_Std_Le_Sgn_Int | Iir_Predefined_Ieee_Numeric_Std_Match_Le_Sgn_Int => -- "<=" (Signed, Integer) return Synth_Compare_Sgn_Int (Id_Sle, Expr_Typ); when Iir_Predefined_Ieee_Numeric_Std_Le_Int_Sgn | Iir_Predefined_Ieee_Numeric_Std_Match_Le_Int_Sgn => -- "<=" (Integer, Signed) return Synth_Compare_Int_Sgn (Id_Sle, Expr_Typ); when Iir_Predefined_Ieee_Numeric_Std_Gt_Uns_Uns | Iir_Predefined_Ieee_Std_Logic_Unsigned_Gt_Slv_Slv | Iir_Predefined_Ieee_Numeric_Std_Match_Gt_Uns_Uns => -- ">" (Unsigned, Unsigned) [resize] return Synth_Compare_Uns_Uns (Id_Ugt, Expr_Typ); when Iir_Predefined_Ieee_Numeric_Std_Gt_Uns_Nat | Iir_Predefined_Ieee_Numeric_Std_Match_Gt_Uns_Nat | Iir_Predefined_Ieee_Std_Logic_Unsigned_Gt_Slv_Int => -- ">" (Unsigned, Natural) return Synth_Compare_Uns_Nat (Id_Ugt, Expr_Typ); when Iir_Predefined_Ieee_Numeric_Std_Gt_Nat_Uns | Iir_Predefined_Ieee_Numeric_Std_Match_Gt_Nat_Uns => -- ">" (Natural, Unsigned) [resize] return Synth_Compare_Nat_Uns (Id_Ugt, Expr_Typ); when Iir_Predefined_Ieee_Numeric_Std_Gt_Sgn_Sgn | Iir_Predefined_Ieee_Numeric_Std_Match_Gt_Sgn_Sgn | Iir_Predefined_Ieee_Std_Logic_Arith_Gt_Sgn_Sgn => -- ">" (Signed, Signed) [resize] return Synth_Compare_Sgn_Sgn (Id_Sgt, Expr_Typ); when Iir_Predefined_Ieee_Numeric_Std_Gt_Sgn_Int | Iir_Predefined_Ieee_Numeric_Std_Match_Gt_Sgn_Int | Iir_Predefined_Ieee_Std_Logic_Arith_Gt_Sgn_Int => -- ">" (Signed, Integer) return Synth_Compare_Sgn_Int (Id_Sgt, Expr_Typ); when Iir_Predefined_Ieee_Numeric_Std_Gt_Int_Sgn | Iir_Predefined_Ieee_Numeric_Std_Match_Gt_Int_Sgn => -- ">" (Integer, Signed) return Synth_Compare_Int_Sgn (Id_Sgt, Expr_Typ); when Iir_Predefined_Ieee_Numeric_Std_Ge_Uns_Uns | Iir_Predefined_Ieee_Numeric_Std_Match_Ge_Uns_Uns | Iir_Predefined_Ieee_Std_Logic_Unsigned_Ge_Slv_Slv | Iir_Predefined_Ieee_Std_Logic_Arith_Ge_Uns_Uns => -- ">=" (Unsigned, Unsigned) [resize] return Synth_Compare_Uns_Uns (Id_Uge, Expr_Typ); when Iir_Predefined_Ieee_Numeric_Std_Ge_Nat_Uns | Iir_Predefined_Ieee_Numeric_Std_Match_Ge_Nat_Uns => -- ">=" (Natural, Unsigned) [resize] return Synth_Compare_Nat_Uns (Id_Uge, Expr_Typ); when Iir_Predefined_Ieee_Numeric_Std_Ge_Uns_Nat | Iir_Predefined_Ieee_Numeric_Std_Match_Ge_Uns_Nat | Iir_Predefined_Ieee_Std_Logic_Unsigned_Ge_Slv_Int => -- ">=" (Unsigned, Natural) return Synth_Compare_Uns_Nat (Id_Uge, Expr_Typ); when Iir_Predefined_Ieee_Numeric_Std_Ge_Sgn_Sgn | Iir_Predefined_Ieee_Numeric_Std_Match_Ge_Sgn_Sgn => -- ">=" (Signed, Signed) [resize] return Synth_Compare_Sgn_Sgn (Id_Sge, Expr_Typ); when Iir_Predefined_Ieee_Numeric_Std_Ge_Sgn_Int | Iir_Predefined_Ieee_Numeric_Std_Match_Ge_Sgn_Int => -- ">=" (Signed, Integer) return Synth_Compare_Sgn_Int (Id_Sge, Expr_Typ); when Iir_Predefined_Ieee_Numeric_Std_Ge_Int_Sgn | Iir_Predefined_Ieee_Numeric_Std_Match_Ge_Int_Sgn => -- ">=" (Integer, Signed) return Synth_Compare_Int_Sgn (Id_Sge, Expr_Typ); when Iir_Predefined_Array_Element_Concat => declare L : constant Net := Get_Net (Ctxt, Left); Bnd : Bound_Type; N : Net; begin N := Build_Concat2 (Ctxt, L, Get_Net (Ctxt, Right)); Set_Location (N, Expr); Bnd := Create_Bounds_From_Length (Syn_Inst, Get_Index_Type (Get_Type (Expr), 0), Iir_Index32 (Get_Bound_Length (Left.Typ, 1) + 1)); return Create_Value_Net (N, Create_Onedimensional_Array_Subtype (Left_Typ, Bnd)); end; when Iir_Predefined_Element_Array_Concat => declare R : constant Net := Get_Net (Ctxt, Right); Bnd : Bound_Type; N : Net; begin N := Build_Concat2 (Ctxt, Get_Net (Ctxt, Left), R); Set_Location (N, Expr); Bnd := Create_Bounds_From_Length (Syn_Inst, Get_Index_Type (Get_Type (Expr), 0), Iir_Index32 (Get_Bound_Length (Right.Typ, 1) + 1)); return Create_Value_Net (N, Create_Onedimensional_Array_Subtype (Right_Typ, Bnd)); end; when Iir_Predefined_Element_Element_Concat => declare N : Net; Bnd : Bound_Type; begin N := Build_Concat2 (Ctxt, Get_Net (Ctxt, Left), Get_Net (Ctxt, Right)); Set_Location (N, Expr); Bnd := Create_Bounds_From_Length (Syn_Inst, Get_Index_Type (Get_Type (Expr), 0), 2); return Create_Value_Net (N, Create_Onedimensional_Array_Subtype (Expr_Typ, Bnd)); end; when Iir_Predefined_Array_Array_Concat => declare L : constant Net := Get_Net (Ctxt, Left); R : constant Net := Get_Net (Ctxt, Right); Bnd : Bound_Type; N : Net; begin N := Build_Concat2 (Ctxt, L, R); Set_Location (N, Expr); Bnd := Create_Bounds_From_Length (Syn_Inst, Get_Index_Type (Get_Type (Expr), 0), Iir_Index32 (Get_Bound_Length (Left.Typ, 1) + Get_Bound_Length (Right.Typ, 1))); return Create_Value_Net (N, Create_Onedimensional_Array_Subtype (Expr_Typ, Bnd)); end; when Iir_Predefined_Integer_Plus => return Synth_Int_Dyadic (Id_Add); when Iir_Predefined_Integer_Minus => return Synth_Int_Dyadic (Id_Sub); when Iir_Predefined_Integer_Mul => return Synth_Int_Dyadic (Id_Smul); when Iir_Predefined_Integer_Div => return Synth_Int_Dyadic (Id_Sdiv); when Iir_Predefined_Integer_Mod => if Is_Static_Val (Right.Val) then -- Optimize when the divisor is a power of 2. declare use Mutils; Etype : constant Type_Acc := Get_Subtype_Object (Syn_Inst, Expr_Type); R : constant Int64 := Get_Static_Discrete (Right); Log_R : Natural; N : Net; begin if R > 0 and then Is_Power2 (Uns64 (R)) then Log_R := Clog2 (Uns64 (R)); pragma Assert (Log_R <= Natural (Left.Typ.W)); N := Get_Net (Ctxt, Left); N := Build2_Extract (Ctxt, N, 0, Width (Log_R)); N := Build2_Uresize (Ctxt, N, Left.Typ.W, Get_Location (Expr)); return Create_Value_Net (N, Etype); end if; end; end if; return Synth_Int_Dyadic (Id_Smod); when Iir_Predefined_Integer_Rem => return Synth_Int_Dyadic (Id_Srem); when Iir_Predefined_Integer_Exp => Error_Msg_Synth (+Expr, "non-constant exponentiation not supported"); return No_Valtyp; when Iir_Predefined_Integer_Less_Equal => return Synth_Compare (Id_Sle, Boolean_Type); when Iir_Predefined_Integer_Less => return Synth_Compare (Id_Slt, Boolean_Type); when Iir_Predefined_Integer_Greater_Equal => return Synth_Compare (Id_Sge, Boolean_Type); when Iir_Predefined_Integer_Greater => return Synth_Compare (Id_Sgt, Boolean_Type); when Iir_Predefined_Integer_Equality => return Synth_Compare (Id_Eq, Boolean_Type); when Iir_Predefined_Integer_Inequality => return Synth_Compare (Id_Ne, Boolean_Type); when Iir_Predefined_Integer_Minimum => return Synth_Minmax (Id_Slt); when Iir_Predefined_Integer_Maximum => return Synth_Minmax (Id_Sgt); when Iir_Predefined_Physical_Physical_Div => Error_Msg_Synth (+Expr, "non-constant division not supported"); return No_Valtyp; when Iir_Predefined_Floating_Div => Error_Msg_Synth (+Expr, "non-constant division not supported"); return No_Valtyp; when Iir_Predefined_Ieee_Numeric_Std_Sra_Sgn_Int => return Synth_Shift (Id_Asr, Id_Lsl); when Iir_Predefined_Ieee_Numeric_Std_Sll_Uns_Int | Iir_Predefined_Ieee_Numeric_Std_Sll_Sgn_Int => return Synth_Shift (Id_Lsl, Id_Lsr); when Iir_Predefined_Ieee_Numeric_Std_Srl_Uns_Int | Iir_Predefined_Ieee_Numeric_Std_Srl_Sgn_Int => return Synth_Shift (Id_Lsr, Id_Lsl); when Iir_Predefined_Ieee_1164_Vector_Ror => return Synth_Rotation (Id_Ror); when others => Error_Msg_Synth (+Expr, "synth_dyadic_operation: unhandled " & Iir_Predefined_Functions'Image (Def)); return No_Valtyp; end case; end Synth_Dyadic_Operation; function Synth_Monadic_Operation (Syn_Inst : Synth_Instance_Acc; Imp : Node; Operand_Expr : Node; Loc : Node) return Valtyp is Ctxt : constant Context_Acc := Get_Build (Syn_Inst); 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_Subtype_Object (Syn_Inst, Oper_Type); Operand : Valtyp; function Synth_Bit_Monadic (Id : Monadic_Module_Id) return Valtyp is N : Net; begin N := Build_Monadic (Ctxt, Id, Get_Net (Ctxt, Operand)); Set_Location (N, Loc); return Create_Value_Net (N, Operand.Typ); end Synth_Bit_Monadic; function Synth_Vec_Monadic (Id : Monadic_Module_Id) return Valtyp is Op: constant Net := Get_Net (Ctxt, Operand); N : Net; begin N := Build_Monadic (Ctxt, Id, Op); Set_Location (N, Loc); return Create_Value_Net (N, Create_Res_Bound (Operand)); end Synth_Vec_Monadic; function Synth_Vec_Reduce_Monadic (Id : Reduce_Module_Id) return Valtyp is Op: constant Net := Get_Net (Ctxt, Operand); N : Net; begin N := Build_Reduce (Ctxt, Id, Op); Set_Location (N, Loc); return Create_Value_Net (N, Operand.Typ.Vec_El); end Synth_Vec_Reduce_Monadic; begin Operand := Synth_Expression_With_Type (Syn_Inst, Operand_Expr, Oper_Typ); if Operand = No_Valtyp then return No_Valtyp; end if; Operand := Synth_Subtype_Conversion (Ctxt, Operand, Oper_Typ, False, Loc); Strip_Const (Operand); if Is_Static_Val (Operand.Val) then return Create_Value_Memtyp (Synth_Static_Monadic_Predefined (Syn_Inst, Imp, Get_Value_Memtyp (Operand), Loc)); end if; case Def is when Iir_Predefined_Error => return No_Valtyp; when Iir_Predefined_Ieee_1164_Scalar_Not => return Synth_Bit_Monadic (Id_Not); when Iir_Predefined_Boolean_Not | Iir_Predefined_Bit_Not => return Synth_Bit_Monadic (Id_Not); when Iir_Predefined_Ieee_1164_Vector_Not | Iir_Predefined_Ieee_Numeric_Std_Not_Uns | Iir_Predefined_Ieee_Numeric_Std_Not_Sgn => return Synth_Vec_Monadic (Id_Not); when Iir_Predefined_Ieee_Numeric_Std_Neg_Uns | Iir_Predefined_Ieee_Numeric_Std_Neg_Sgn => return Synth_Vec_Monadic (Id_Neg); when Iir_Predefined_Ieee_Numeric_Std_Abs_Sgn => return Synth_Vec_Monadic (Id_Abs); when Iir_Predefined_Ieee_1164_Vector_And_Reduce => return Synth_Vec_Reduce_Monadic(Id_Red_And); when Iir_Predefined_Ieee_1164_Vector_Or_Reduce => return Synth_Vec_Reduce_Monadic(Id_Red_Or); when Iir_Predefined_Ieee_1164_Condition_Operator => return Create_Value_Net (Get_Net (Ctxt, Operand), Get_Subtype_Object (Syn_Inst, Get_Type (Imp))); when Iir_Predefined_Integer_Negation => declare N : Net; begin N := Build_Monadic (Ctxt, Id_Neg, Get_Net (Ctxt, Operand)); Set_Location (N, Loc); return Create_Value_Net (N, Operand.Typ); end; when others => Error_Msg_Synth (+Loc, "unhandled monadic: " & Iir_Predefined_Functions'Image (Def)); raise Internal_Error; end case; end Synth_Monadic_Operation; function Synth_Shift_Rotate (Ctxt : Context_Acc; Id : Shift_Rotate_Module_Id; Left, Right : Valtyp; Expr : Node) return Valtyp is L : constant Net := Get_Net (Ctxt, Left); N : Net; begin N := Build_Shift_Rotate (Ctxt, Id, L, Get_Net (Ctxt, Right)); Set_Location (N, Expr); return Create_Value_Net (N, Create_Res_Bound (Left)); end Synth_Shift_Rotate; function Synth_Dynamic_Predefined_Function_Call (Subprg_Inst : Synth_Instance_Acc; Expr : Node) return Valtyp is Ctxt : constant Context_Acc := Get_Build (Subprg_Inst); Imp : constant Node := Get_Implementation (Expr); Def : constant Iir_Predefined_Functions := Get_Implicit_Definition (Imp); Inter_Chain : constant Node := Get_Interface_Declaration_Chain (Imp); Param1 : Node; Param2 : Node; Res_Typ : constant Type_Acc := Get_Subtype_Object (Subprg_Inst, Get_Type (Imp)); -- Resize PARAM1 to PARAM2 bit according to IS_SIGNED. function Synth_Conv_Vector (Is_Signed : Boolean) return Valtyp is Arg : constant Valtyp := Get_Value (Subprg_Inst, Param1); Size_Vt : Valtyp; Size : Width; Arg_Net : Net; begin Size_Vt := Get_Value (Subprg_Inst, Param2); Strip_Const (Size_Vt); if not Is_Static (Size_Vt.Val) then Error_Msg_Synth (+Expr, "size parameter must be constant"); return No_Valtyp; end if; Size := Uns32 (Read_Discrete (Size_Vt)); Arg_Net := Get_Net (Ctxt, Arg); Arg_Net := Build2_Resize (Ctxt, Arg_Net, Size, Is_Signed, Get_Location (Expr)); return Create_Value_Net (Arg_Net, Create_Vec_Type_By_Length (Size, Logic_Type)); end Synth_Conv_Vector; L : Valtyp; R : Valtyp; begin Param1 := Inter_Chain; if Param1 /= Null_Node then L := Get_Value (Subprg_Inst, Param1); Param2 := Get_Chain (Inter_Chain); if Param2 /= Null_Node then R := Get_Value (Subprg_Inst, Param2); else R := No_Valtyp; end if; else L := No_Valtyp; R := No_Valtyp; Param2 := Null_Node; end if; case Def is when Iir_Predefined_Ieee_1164_Rising_Edge => declare Edge : Net; begin Edge := Build_Posedge (Ctxt, Get_Net (Ctxt, L)); Set_Location (Edge, Expr); return Create_Value_Net (Edge, Res_Typ); end; when Iir_Predefined_Ieee_1164_Falling_Edge => declare Edge : Net; begin Edge := Build_Negedge (Ctxt, Get_Net (Ctxt, L)); Set_Location (Edge, Expr); return Create_Value_Net (Edge, Res_Typ); end; when Iir_Predefined_Ieee_1164_Scalar_Is_X | Iir_Predefined_Ieee_1164_Vector_Is_X => -- Always false. return Create_Value_Discrete (0, Boolean_Type); when Iir_Predefined_Ieee_1164_To_Bitvector | Iir_Predefined_Ieee_1164_To_Stdlogicvector_Suv | Iir_Predefined_Ieee_1164_To_Stdlogicvector_Bv | Iir_Predefined_Ieee_Numeric_Std_To_01_Uns | Iir_Predefined_Ieee_Numeric_Std_To_01_Sgn => if Is_Static (L.Val) then raise Internal_Error; end if; return Create_Value_Net (Get_Net (Ctxt, L), Create_Res_Bound (L)); when Iir_Predefined_Ieee_1164_To_Bit => return Create_Value_Net (Get_Net (Ctxt, L), Res_Typ); when Iir_Predefined_Ieee_Numeric_Std_Touns_Nat_Nat_Uns | Iir_Predefined_Ieee_Std_Logic_Arith_Conv_Unsigned_Int => return Synth_Conv_Vector (False); when Iir_Predefined_Ieee_Numeric_Std_Tosgn_Int_Nat_Sgn | Iir_Predefined_Ieee_Std_Logic_Arith_Conv_Vector_Int => return Synth_Conv_Vector (True); when Iir_Predefined_Ieee_Numeric_Std_Toint_Uns_Nat | Iir_Predefined_Ieee_Std_Logic_Arith_Conv_Integer_Uns | Iir_Predefined_Ieee_Std_Logic_Arith_Conv_Integer_Log | Iir_Predefined_Ieee_Std_Logic_Unsigned_Conv_Integer => -- UNSIGNED to Natural. return Create_Value_Net (Synth_Uresize (Ctxt, Get_Net (Ctxt, L), Res_Typ.W, Expr), Res_Typ); when Iir_Predefined_Ieee_Numeric_Std_Toint_Sgn_Int => -- SIGNED to Integer. return Create_Value_Net (Synth_Sresize (Ctxt, L, Res_Typ.W, Expr), Res_Typ); when Iir_Predefined_Ieee_Numeric_Std_Resize_Uns_Nat | Iir_Predefined_Ieee_Std_Logic_Arith_Ext => declare W : Width; begin if not Is_Static (R.Val) then Error_Msg_Synth (+Expr, "size must be constant"); return No_Valtyp; end if; W := Uns32 (Read_Discrete (R)); return Create_Value_Net (Synth_Uresize (Ctxt, Get_Net (Ctxt, L), W, Expr), Create_Vec_Type_By_Length (W, Logic_Type)); end; when Iir_Predefined_Ieee_Numeric_Std_Resize_Sgn_Nat | Iir_Predefined_Ieee_Std_Logic_Arith_Sxt => declare W : Width; begin if not Is_Static (R.Val) then Error_Msg_Synth (+Expr, "size must be constant"); return No_Valtyp; end if; W := Uns32 (Read_Discrete (R)); return Create_Value_Net (Build2_Sresize (Ctxt, Get_Net (Ctxt, L), W, Get_Location (Expr)), Create_Vec_Type_By_Length (W, Logic_Type)); end; when Iir_Predefined_Ieee_Numeric_Std_Shf_Left_Uns_Nat | Iir_Predefined_Ieee_Numeric_Std_Shf_Left_Sgn_Nat => return Synth_Shift_Rotate (Ctxt, Id_Lsl, L, R, Expr); when Iir_Predefined_Ieee_Numeric_Std_Shf_Right_Uns_Nat => return Synth_Shift_Rotate (Ctxt, Id_Lsr, L, R, Expr); when Iir_Predefined_Ieee_Numeric_Std_Shf_Right_Sgn_Nat => return Synth_Shift_Rotate (Ctxt, Id_Asr, L, R, Expr); when Iir_Predefined_Ieee_Numeric_Std_Rot_Left_Uns_Nat => return Synth_Shift_Rotate (Ctxt, Id_Rol, L, R, Expr); when Iir_Predefined_Ieee_Numeric_Std_Rot_Right_Uns_Nat => return Synth_Shift_Rotate (Ctxt, Id_Ror, L, R, Expr); when Iir_Predefined_Ieee_Numeric_Std_Min_Uns_Uns => return Synth_Dyadic_Uns_Uns (Ctxt, Id_Umin, L, R, Expr); when Iir_Predefined_Ieee_Numeric_Std_Min_Uns_Nat => return Synth_Dyadic_Uns_Nat (Ctxt, Id_Umin, L, R, Expr); when Iir_Predefined_Ieee_Numeric_Std_Min_Nat_Uns => return Synth_Dyadic_Nat_Uns (Ctxt, Id_Umin, L, R, Expr); when Iir_Predefined_Ieee_Numeric_Std_Min_Sgn_Sgn => return Synth_Dyadic_Sgn_Sgn (Ctxt, Id_Smin, L, R, Expr); when Iir_Predefined_Ieee_Numeric_Std_Min_Sgn_Int => return Synth_Dyadic_Sgn_Int (Ctxt, Id_Smin, L, R, Expr); when Iir_Predefined_Ieee_Numeric_Std_Min_Int_Sgn => return Synth_Dyadic_Int_Sgn (Ctxt, Id_Smin, L, R, Expr); when Iir_Predefined_Ieee_Numeric_Std_Max_Uns_Uns => return Synth_Dyadic_Uns_Uns (Ctxt, Id_Umax, L, R, Expr); when Iir_Predefined_Ieee_Numeric_Std_Max_Uns_Nat => return Synth_Dyadic_Uns_Nat (Ctxt, Id_Umax, L, R, Expr); when Iir_Predefined_Ieee_Numeric_Std_Max_Nat_Uns => return Synth_Dyadic_Nat_Uns (Ctxt, Id_Umax, L, R, Expr); when Iir_Predefined_Ieee_Numeric_Std_Max_Sgn_Sgn => return Synth_Dyadic_Sgn_Sgn (Ctxt, Id_Smax, L, R, Expr); when Iir_Predefined_Ieee_Numeric_Std_Max_Sgn_Int => return Synth_Dyadic_Sgn_Int (Ctxt, Id_Smax, L, R, Expr); when Iir_Predefined_Ieee_Numeric_Std_Max_Int_Sgn => return Synth_Dyadic_Int_Sgn (Ctxt, Id_Smax, L, R, Expr); when Iir_Predefined_Ieee_Std_Logic_Misc_Or_Reduce_Slv | Iir_Predefined_Ieee_Std_Logic_Misc_Or_Reduce_Suv => declare N : Net; begin N := Build_Reduce (Ctxt, Id_Red_Or, Get_Net (Ctxt, L)); Set_Location (N, Expr); return Create_Value_Net (N, Res_Typ); end; when Iir_Predefined_Ieee_Numeric_Std_Match_Suv | Iir_Predefined_Ieee_Numeric_Std_Match_Slv => declare Cst, Oper : Valtyp; Res : Net; begin if Is_Static (L.Val) then Cst := L; Oper := R; elsif Is_Static (R.Val) then Cst := R; Oper := L; else Error_Msg_Synth (+Expr, "one operand of std_match must be constant"); return No_Valtyp; end if; if Oper.Typ.W /= Cst.Typ.W then Error_Msg_Synth (+Expr, "operands of std_match don't have the same size"); return Create_Value_Discrete (0, Boolean_Type); end if; Res := Synth_Match (Ctxt, Cst, Oper, Expr); if Res = No_Net then return Create_Value_Discrete (0, Boolean_Type); else return Create_Value_Net (Res, Boolean_Type); end if; end; when others => Error_Msg_Synth (+Expr, "unhandled function: " & Iir_Predefined_Functions'Image (Def)); return No_Valtyp; end case; end Synth_Dynamic_Predefined_Function_Call; function Synth_Predefined_Function_Call (Syn_Inst : Synth_Instance_Acc; Expr : Node) return Valtyp is Imp : constant Node := Get_Implementation (Expr); Assoc_Chain : constant Node := Get_Parameter_Association_Chain (Expr); Inter_Chain : constant Node := Get_Interface_Declaration_Chain (Imp); Inter : Node; Subprg_Inst : Synth_Instance_Acc; M : Areapools.Mark_Type; Static : Boolean; Res : Valtyp; begin Areapools.Mark (M, Instance_Pool.all); Subprg_Inst := Make_Instance (Syn_Inst, Imp); Synth_Subprogram_Association (Subprg_Inst, Syn_Inst, Inter_Chain, Assoc_Chain); if Is_Error (Subprg_Inst) then Res := No_Valtyp; else -- If all operands are static, handle the call differently. Static := True; Inter := Inter_Chain; while Inter /= Null_Node loop if not Is_Static (Get_Value (Subprg_Inst, Inter).Val) then Static := False; exit; end if; Inter := Get_Chain (Inter); end loop; if Static then Res := Create_Value_Memtyp (Synth_Static_Predefined_Function_Call (Subprg_Inst, Expr)); else Res := Synth_Dynamic_Predefined_Function_Call (Subprg_Inst, Expr); end if; end if; Free_Instance (Subprg_Inst); Areapools.Release (M, Instance_Pool.all); return Res; end Synth_Predefined_Function_Call; function Synth_Operator_Function_Call (Syn_Inst : Synth_Instance_Acc; Expr : Node) return Valtyp is Imp : constant Node := Get_Implementation (Expr); Assoc : Node; Inter : Node; Op1, Op2 : Node; begin Assoc := Get_Parameter_Association_Chain (Expr); Inter := Get_Interface_Declaration_Chain (Imp); Op1 := Get_Actual (Assoc); if Get_Chain (Inter) = Null_Node then return Synth_Monadic_Operation (Syn_Inst, Imp, Op1, Expr); else Op2 := Get_Actual (Get_Chain (Assoc)); return Synth_Dyadic_Operation (Syn_Inst, Imp, Op1, Op2, Expr); end if; end Synth_Operator_Function_Call; end Synth.Oper;