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|
-- Expressions synthesis.
-- Copyright (C) 2017 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 Ada.Unchecked_Conversion;
with Ada.Unchecked_Deallocation;
with Std_Names;
with Ieee.Std_Logic_1164;
with Std_Package;
with Errorout; use Errorout;
with Execution;
with Grt.Types; use Grt.Types;
with Synth.Errors; use Synth.Errors;
with Synth.Context; use Synth.Context;
with Synth.Types; use Synth.Types;
with Netlists; use Netlists;
with Netlists.Gates; use Netlists.Gates;
with Netlists.Builders; use Netlists.Builders;
package body Synth.Expr is
function Is_Const (Val : Value_Acc) return Boolean is
begin
return Val.Kind = Value_Lit;
end Is_Const;
function Get_Width (Val : Value_Acc) return Uns32 is
begin
case Val.Kind is
when Value_Lit =>
if Is_Bit_Type (Val.Lit_Type) then
return 1;
else
raise Internal_Error;
end if;
when Value_Wire
| Value_Net =>
return Get_Width (Get_Net (Val));
when others =>
raise Internal_Error; -- TODO
end case;
end Get_Width;
procedure To_Logic (Lit : Iir_Value_Literal_Acc;
Val : out Uns32;
Xz : out Uns32) is
begin
case Lit.Kind is
when Iir_Value_B1 =>
Xz := 0;
Val := Ghdl_B1'Pos (Lit.B1);
when Iir_Value_E8 =>
-- Std_logic.
case Lit.E8 is
when Ieee.Std_Logic_1164.Std_Logic_0_Pos
| Ieee.Std_Logic_1164.Std_Logic_L_Pos =>
Val := 0;
Xz := 0;
when Ieee.Std_Logic_1164.Std_Logic_1_Pos
| Ieee.Std_Logic_1164.Std_Logic_H_Pos =>
Val := 1;
Xz := 0;
when Ieee.Std_Logic_1164.Std_Logic_U_Pos
| Ieee.Std_Logic_1164.Std_Logic_X_Pos
| Ieee.Std_Logic_1164.Std_Logic_D_Pos =>
Val := 0;
Xz := 1;
when Ieee.Std_Logic_1164.Std_Logic_Z_Pos
| Ieee.Std_Logic_1164.Std_Logic_W_Pos =>
Val := 1;
Xz := 1;
when others =>
-- Only 9 values.
raise Internal_Error;
end case;
when others =>
raise Internal_Error;
end case;
end To_Logic;
function Bit_Extract (Val : Value_Acc; Off : Uns32) return Value_Acc is
begin
case Val.Kind is
when Value_Lit =>
declare
Lit : constant Iir_Value_Literal_Acc := Val.Lit;
begin
pragma Assert (Lit.Kind = Iir_Value_Array);
pragma Assert (Lit.Bounds.Nbr_Dims = 1);
pragma Assert (Lit.Bounds.D (1).Length >= Iir_Index32 (Off));
return Create_Value_Lit
(Lit.Val_Array.V (Lit.Val_Array.Len - Iir_Index32 (Off)),
Get_Element_Subtype (Val.Lit_Type));
end;
when Value_Net
| Value_Wire =>
return Create_Value_Net
(Build_Extract_Bit (Build_Context, Get_Net (Val), Off),
No_Range);
when others =>
raise Internal_Error;
end case;
end Bit_Extract;
function Synth_Uresize (Val : Value_Acc; W : Width) return Net
is
N : constant Net := Get_Net (Val);
Wn : constant Width := Get_Width (N);
begin
if Wn > W then
return Build_Trunc (Build_Context, Id_Utrunc, N, W);
elsif Wn < W then
return Build_Extend (Build_Context, Id_Uextend, N, W);
else
return N;
end if;
end Synth_Uresize;
procedure Fill_Array_Aggregate
(Syn_Inst : Synth_Instance_Acc;
Aggr : Iir;
Res : Value_Acc;
Dim : Iir_Index32;
Orig : Iir_Index32;
Stride : Iir_Index32)
is
Bound : constant Iir_Value_Literal_Acc := Res.Bounds.D (Dim);
Value : Iir;
Assoc : Iir;
Pos : Iir_Index32;
procedure Set_Elem (Pos : Iir_Index32)
is
Val : Value_Acc;
begin
if Dim = Res.Bounds.Nbr_Dims then
Val := Synth_Expression_With_Type
(Syn_Inst, Value, Get_Element_Subtype (Get_Type (Aggr)));
Res.Arr.V (Orig + Stride * Pos) := Val;
else
Error_Msg_Synth (+Assoc, "multi-dim aggregate not handled");
end if;
end Set_Elem;
begin
Assoc := Get_Association_Choices_Chain (Aggr);
Pos := 0;
while Is_Valid (Assoc) loop
Value := Get_Associated_Expr (Assoc);
loop
case Get_Kind (Assoc) is
when Iir_Kind_Choice_By_None =>
if Pos >= Bound.Length then
Error_Msg_Synth (+Assoc, "element out of array bound");
else
Set_Elem (Pos);
end if;
Pos := Pos + 1;
when others =>
Error_Msg_Synth
(+Assoc, "unhandled association form");
end case;
Assoc := Get_Chain (Assoc);
exit when Is_Null (Assoc);
exit when not Get_Same_Alternative_Flag (Assoc);
end loop;
end loop;
end Fill_Array_Aggregate;
type Net_Array is array (Iir_Index32 range <>) of Net;
type Net_Array_Acc is access Net_Array;
procedure Free_Net_Array is new Ada.Unchecked_Deallocation
(Net_Array, Net_Array_Acc);
-- Convert the one-dimension VAL to a net.
function Vectorize_Array (Val : Value_Acc) return Value_Acc
is
Arr : Net_Array_Acc;
Len : Iir_Index32;
Idx, New_Idx : Iir_Index32;
Res : Value_Acc;
begin
Len := Val.Arr.Len;
-- Dynamically allocate ARR to handle large arrays.
Arr := new Net_Array (1 .. Len);
for I in Arr'Range loop
Arr (I) := Get_Net (Val.Arr.V (I));
end loop;
while Len > 1 loop
Idx := 1;
New_Idx := 0;
while Idx <= Len loop
-- Gather at most 4 nets.
New_Idx := New_Idx + 1;
if Idx = Len then
Arr (New_Idx) := Arr (Idx);
Idx := Idx + 1;
elsif Idx + 1 = Len then
Arr (New_Idx) := Build_Concat2
(Build_Context, Arr (Idx), Arr (Idx + 1));
Idx := Idx + 2;
elsif Idx + 2 = Len then
Arr (New_Idx) := Build_Concat3
(Build_Context, Arr (Idx), Arr (Idx + 1), Arr (Idx + 2));
Idx := Idx + 3;
else
Arr (New_Idx) := Build_Concat4
(Build_Context,
Arr (Idx), Arr (Idx + 1), Arr (Idx + 2), Arr (Idx + 3));
Idx := Idx + 4;
end if;
end loop;
Len := New_Idx;
end loop;
Res := Create_Value_Net (Arr (1), Bounds_To_Range (Val.Bounds.D (1)));
Free_Net_Array (Arr);
return Res;
end Vectorize_Array;
function Synth_Aggregate (Syn_Inst : Synth_Instance_Acc;
Aggr : Iir;
Aggr_Type : Iir) return Value_Acc is
begin
case Get_Kind (Aggr_Type) is
when Iir_Kind_Array_Type_Definition
| Iir_Kind_Array_Subtype_Definition =>
declare
Bnd : Iir_Value_Literal_Acc;
Res : Value_Acc;
begin
-- Create bounds.
Bnd := Execution.Create_Array_Bounds_From_Type
(Syn_Inst.Sim, Aggr_Type, False);
-- Allocate result
Res := Create_Array_Value (Bnd.Bounds);
Create_Array_Data (Res);
Fill_Array_Aggregate
(Syn_Inst, Aggr, Res,
1, 1, Res.Arr.Len / Res.Bounds.D (1).Length);
if Is_Vector_Type (Aggr_Type) then
-- Vectorize
Res := Vectorize_Array (Res);
end if;
return Res;
end;
when Iir_Kind_Record_Type_Definition
| Iir_Kind_Record_Subtype_Definition =>
raise Internal_Error;
when others =>
Error_Kind ("synth_aggregate", Aggr_Type);
end case;
end Synth_Aggregate;
function Synth_Bit_Eq_Const (Cst : Value_Acc; Expr : Value_Acc; Loc : Iir)
return Value_Acc
is
pragma Unreferenced (Loc);
Val : Uns32;
Xz : Uns32;
begin
To_Logic (Cst.Lit, Val, Xz);
if Xz /= 0 then
return Create_Value_Net
(Build_Const_UL32 (Build_Context, 0, 1, 1), No_Range);
elsif Val = 1 then
return Expr;
else
pragma Assert (Val = 0);
return Create_Value_Net
(Build_Monadic (Build_Context, Id_Not, Get_Net (Expr)), No_Range);
end if;
end Synth_Bit_Eq_Const;
function Extract_Range (Val : Value_Acc) return Value_Range_Acc is
begin
case Val.Kind is
when Value_Net =>
return Val.N_Range;
when Value_Wire =>
return Val.W_Range;
when others =>
raise Internal_Error;
end case;
end Extract_Range;
-- Create the result range of an operator. According to the ieee standard,
-- the range is LEN-1 downto 0.
function Create_Res_Range (Prev : Value_Acc; N : Net)
return Value_Range_Acc
is
Res : Value_Range_Acc;
Wd : Width;
begin
case Prev.Kind is
when Value_Net
| Value_Wire =>
Res := Extract_Range (Prev);
when Value_Lit =>
Res := No_Range;
when others =>
raise Internal_Error;
end case;
if Res /= No_Range
and then Res.Dir = Iir_Downto
and then Res.Right = 0
then
-- Normalized range
return Res;
end if;
Wd := Get_Width (N);
return Create_Range_Value ((Iir_Downto, Wd, Int32 (Wd - 1), 0));
end Create_Res_Range;
function Synth_Dyadic_Operation (Def : Iir_Predefined_Functions;
Left : Value_Acc;
Right : Value_Acc;
Loc : Iir) return Value_Acc
is
function Synth_Bit_Dyadic (Id : Dyadic_Module_Id) return Value_Acc is
begin
return Create_Value_Net
(Build_Dyadic (Build_Context, Id, Get_Net (Left), Get_Net (Right)),
No_Range);
end Synth_Bit_Dyadic;
-- function Synth_Vec_Dyadic (Id : Dyadic_Module_Id) return Value_Acc
-- is
-- L : constant Net := Get_Net (Left);
-- begin
-- return Create_Value_Net
-- (Build_Dyadic (Build_Context, Id, L, Get_Net (Right)),
-- Create_Res_Range (Left, L));
-- end Synth_Vec_Dyadic;
begin
case Def is
when Iir_Predefined_Error =>
return null;
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_Ieee_1164_Scalar_Xor =>
return Synth_Bit_Dyadic (Id_Xor);
when Iir_Predefined_Bit_Or
| Iir_Predefined_Ieee_1164_Scalar_Or =>
return Synth_Bit_Dyadic (Id_Or);
when Iir_Predefined_Enum_Equality =>
if Get_Width (Left) = 1 then
if Is_Const (Left) then
return Synth_Bit_Eq_Const (Left, Right, Loc);
elsif Is_Const (Right) then
return Synth_Bit_Eq_Const (Right, Left, Loc);
end if;
end if;
-- TODO
Error_Msg_Synth (+Loc, "unsupported enum equality");
raise Internal_Error;
when Iir_Predefined_Ieee_Numeric_Std_Add_Uns_Nat =>
-- "+" (Unsigned, Natural)
declare
L : constant Net := Get_Net (Left);
begin
return Create_Value_Net
(Build_Dyadic (Build_Context, Id_Add,
L,
Synth_Uresize (Right, Get_Width (Left))),
Create_Res_Range (Left, L));
end;
when Iir_Predefined_Ieee_Numeric_Std_Eq_Uns_Nat =>
-- "=" (Unsigned, Natural)
return Create_Value_Net
(Build_Compare (Build_Context, Id_Eq,
Get_Net (Left),
Synth_Uresize (Right, Get_Width (Left))),
No_Range);
when others =>
Error_Msg_Synth
(+Loc,
"unhandled dyadic: " & Iir_Predefined_Functions'Image (Def));
raise Internal_Error;
end case;
end Synth_Dyadic_Operation;
function Synth_Monadic_Operation (Def : Iir_Predefined_Functions;
Operand : Value_Acc;
Loc : Iir) return Value_Acc
is
function Synth_Bit_Monadic (Id : Monadic_Module_Id) return Value_Acc is
begin
return Create_Value_Net
(Build_Monadic (Build_Context, Id, Get_Net (Operand)),
No_Range);
end Synth_Bit_Monadic;
begin
case Def is
when Iir_Predefined_Error =>
return null;
when Iir_Predefined_Ieee_1164_Scalar_Not =>
return Synth_Bit_Monadic (Id_Not);
when others =>
Error_Msg_Synth
(+Loc,
"unhandled monadic: " & Iir_Predefined_Functions'Image (Def));
raise Internal_Error;
end case;
end Synth_Monadic_Operation;
function Synth_Name (Syn_Inst : Synth_Instance_Acc; Name : Iir)
return Value_Acc is
begin
case Get_Kind (Name) is
when Iir_Kind_Simple_Name =>
return Synth_Name (Syn_Inst, Get_Named_Entity (Name));
when Iir_Kind_Interface_Signal_Declaration
| Iir_Kind_Variable_Declaration
| Iir_Kind_Signal_Declaration =>
return Get_Value (Syn_Inst, Name);
when others =>
Error_Kind ("synth_name", Name);
end case;
end Synth_Name;
function In_Range (Rng : Value_Range_Acc; V : Int32) return Boolean is
begin
case Rng.Dir is
when Iir_To =>
return V >= Rng.Left and then V <= Rng.Right;
when Iir_Downto =>
return V <= Rng.Left and then V >= Rng.Right;
end case;
end In_Range;
function Synth_Indexed_Name (Syn_Inst : Synth_Instance_Acc; Name : Iir)
return Value_Acc
is
Pfx : constant Value_Acc :=
Synth_Expression (Syn_Inst, Get_Prefix (Name));
Indexes : constant Iir_List := Get_Index_List (Name);
Idx_Val : constant Value_Acc :=
Synth_Expression (Syn_Inst, Get_Nth_Element (Indexes, 0));
Rng : Value_Range_Acc;
Idx : Int32;
begin
if Get_Nbr_Elements (Indexes) /= 1 then
Error_Msg_Synth (+Name, "multi-dim arrays not supported");
return null;
end if;
if Idx_Val.Kind /= Value_Lit
or else Idx_Val.Lit.Kind /= Iir_Value_I64
then
Error_Msg_Synth (+Name, "non constant integer index not supported");
return null;
end if;
Rng := Extract_Range (Pfx);
Idx := Int32 (Idx_Val.Lit.I64);
if not In_Range (Rng, Idx) then
Error_Msg_Synth (+Name, "index not within bounds");
return null;
end if;
case Rng.Dir is
when Iir_To =>
return Bit_Extract (Pfx, Uns32 (Idx - Rng.Left));
when Iir_Downto =>
return Bit_Extract (Pfx, Uns32 (Rng.Right - Idx));
end case;
end Synth_Indexed_Name;
-- Match: clk_signal_name'event
-- and return clk_signal_name.
function Extract_Event_Expr_Prefix (Expr : Iir) return Iir is
begin
if Get_Kind (Expr) = Iir_Kind_Event_Attribute then
return Get_Prefix (Expr);
else
return Null_Iir;
end if;
end Extract_Event_Expr_Prefix;
function Is_Same_Node (Left, Right : Iir) return Boolean is
begin
if Get_Kind (Left) /= Get_Kind (Right) then
return False;
end if;
case Get_Kind (Left) is
when Iir_Kind_Simple_Name =>
return Get_Named_Entity (Left) = Get_Named_Entity (Right);
when others =>
Error_Kind ("is_same_node", Left);
end case;
end Is_Same_Node;
-- Match: clk_signal_name = '1' | clk_signal_name = '0'
function Extract_Clock_Level
(Syn_Inst : Synth_Instance_Acc; Expr : Iir; Prefix : Iir) return Net
is
Clk : Net;
Imp : Iir;
Left, Right : Iir;
Lit : Iir;
Posedge : Boolean;
begin
Clk := Get_Net (Synth_Name (Syn_Inst, Prefix));
if Get_Kind (Expr) /= Iir_Kind_Equality_Operator then
Error_Msg_Synth (+Expr, "ill-formed clock-level, '=' expected");
return Build_Edge (Build_Context, True, Clk);
end if;
Imp := Get_Implementation (Expr);
if Get_Implicit_Definition (Imp) /= Iir_Predefined_Enum_Equality then
Error_Msg_Synth (+Expr, "ill-formed clock-level, '=' expected");
return Build_Edge (Build_Context, True, Clk);
end if;
Left := Get_Left (Expr);
Right := Get_Right (Expr);
if Get_Kind (Right) /= Iir_Kind_Character_Literal then
Error_Msg_Synth
(+Expr, "ill-formed clock-level, '0' or '1' expected");
return Build_Edge (Build_Context, True, Clk);
end if;
Lit := Get_Named_Entity (Right);
if Lit = Std_Package.Bit_0
or else Lit = Ieee.Std_Logic_1164.Std_Ulogic_0
then
Posedge := False;
elsif Lit = Std_Package.Bit_1
or else Lit = Ieee.Std_Logic_1164.Std_Ulogic_1
then
Posedge := True;
else
Error_Msg_Synth
(+Lit, "ill-formed clock-level, '0' or '1' expected");
Posedge := True;
end if;
if not Is_Same_Node (Prefix, Left) then
Error_Msg_Synth
(+Left, "clock signal name doesn't match");
end if;
return Build_Edge (Build_Context, Posedge, Clk);
end Extract_Clock_Level;
function Synth_Clock_Edge (Syn_Inst : Synth_Instance_Acc; Expr : Iir)
return Value_Acc
is
pragma Assert (Get_Kind (Expr) = Iir_Kind_And_Operator);
Left : constant Iir := Get_Left (Expr);
Right : constant Iir := Get_Right (Expr);
Prefix : Iir;
begin
-- Try with left.
Prefix := Extract_Event_Expr_Prefix (Left);
if Is_Valid (Prefix) then
return Create_Value_Net
(Extract_Clock_Level (Syn_Inst, Right, Prefix), No_Range);
end if;
-- Try with right.
Prefix := Extract_Event_Expr_Prefix (Right);
if Is_Valid (Prefix) then
return Create_Value_Net
(Extract_Clock_Level (Syn_Inst, Left, Prefix), No_Range);
end if;
return null;
end Synth_Clock_Edge;
function Synth_Type_Conversion (Syn_Inst : Synth_Instance_Acc; Conv : Iir)
return Value_Acc
is
Expr : constant Iir := Get_Expression (Conv);
Val : Value_Acc;
begin
Val := Synth_Expression (Syn_Inst, Expr);
if Is_Vector_Type (Get_Type (Conv)) then
return Val;
else
Error_Msg_Synth (+Conv, "unhandled type conversion");
return Val;
end if;
end Synth_Type_Conversion;
function Synth_Assoc_In (Syn_Inst : Synth_Instance_Acc;
Assoc : Iir) return Value_Acc is
begin
if Get_Kind (Assoc) = Iir_Kind_Association_Element_By_Expression then
return Synth_Expression (Syn_Inst, Get_Actual (Assoc));
else
Error_Kind ("synth_assoc_in", Assoc);
end if;
end Synth_Assoc_In;
procedure Error_Unknown_Operator (Imp : Iir; Loc : Iir) is
begin
if Get_Kind (Get_Parent (Imp)) = Iir_Kind_Package_Declaration
and then (Get_Identifier
(Get_Library
(Get_Design_File (Get_Design_Unit (Get_Parent (Imp)))))
= Std_Names.Name_Ieee)
then
Error_Msg_Synth (+Loc, "unhandled predefined IEEE operator %i", +Imp);
Error_Msg_Synth (+Imp, " declared here");
else
Error_Msg_Synth (+Loc, "user defined operator %i not handled", +Imp);
end if;
end Error_Unknown_Operator;
function Synth_Expression_With_Type
(Syn_Inst : Synth_Instance_Acc; Expr : Iir; Expr_Type : Iir)
return Value_Acc is
begin
case Get_Kind (Expr) is
when Iir_Kinds_Dyadic_Operator =>
declare
Imp : constant Iir := Get_Implementation (Expr);
Def : constant Iir_Predefined_Functions :=
Get_Implicit_Definition (Imp);
Left : Value_Acc;
Right : Value_Acc;
begin
-- Match clock-edge
if Def = Iir_Predefined_Boolean_And then
Left := Synth_Clock_Edge (Syn_Inst, Expr);
if Left /= null then
return Left;
end if;
end if;
Left := Synth_Expression (Syn_Inst, Get_Left (Expr));
Right := Synth_Expression (Syn_Inst, Get_Right (Expr));
if Def in Iir_Predefined_Implicit
or else Def in Iir_Predefined_IEEE_Explicit
then
return Synth_Dyadic_Operation (Def, Left, Right, Expr);
else
Error_Unknown_Operator (Imp, Expr);
return Left;
end if;
end;
when Iir_Kinds_Monadic_Operator =>
declare
Imp : constant Iir := Get_Implementation (Expr);
Def : constant Iir_Predefined_Functions :=
Get_Implicit_Definition (Imp);
Operand : Value_Acc;
begin
Operand := Synth_Expression (Syn_Inst, Get_Operand (Expr));
if Def in Iir_Predefined_Implicit
or else Def in Iir_Predefined_IEEE_Explicit
then
return Synth_Monadic_Operation (Def, Operand, Expr);
else
Error_Unknown_Operator (Imp, Expr);
return Operand;
end if;
end;
when Iir_Kind_Simple_Name =>
return Synth_Name (Syn_Inst, Expr);
when Iir_Kind_Indexed_Name =>
return Synth_Indexed_Name (Syn_Inst, Expr);
when Iir_Kind_Character_Literal
| Iir_Kind_Integer_Literal
| Iir_Kind_String_Literal8 =>
return Create_Value_Lit
(Execution.Execute_Expression (Syn_Inst.Sim, Expr),
Get_Base_Type (Get_Type (Expr)));
when Iir_Kind_Type_Conversion =>
return Synth_Type_Conversion (Syn_Inst, Expr);
when Iir_Kind_Qualified_Expression =>
return Synth_Expression_With_Type
(Syn_Inst, Get_Expression (Expr), Get_Type (Expr));
when Iir_Kind_Function_Call =>
declare
Imp : constant Iir := Get_Implementation (Expr);
Clk : Net;
begin
if Imp = Ieee.Std_Logic_1164.Rising_Edge then
Clk := Get_Net
(Synth_Assoc_In
(Syn_Inst, Get_Parameter_Association_Chain (Expr)));
return Create_Value_Net
(Build_Edge (Build_Context, True, Clk), No_Range);
end if;
Error_Msg_Synth
(+Expr, "user function call to %i is not handled", +Imp);
end;
when Iir_Kind_Aggregate =>
return Synth_Aggregate (Syn_Inst, Expr, Expr_Type);
when others =>
Error_Kind ("synth_expression", Expr);
end case;
return null;
end Synth_Expression_With_Type;
function Synth_Expression (Syn_Inst : Synth_Instance_Acc; Expr : Iir)
return Value_Acc is
begin
return Synth_Expression_With_Type (Syn_Inst, Expr, Get_Type (Expr));
end Synth_Expression;
end Synth.Expr;
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