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|
-- Interpreted simulation
-- Copyright (C) 2014 Tristan Gingold
--
-- GHDL 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, or (at your option) any later
-- version.
--
-- GHDL 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 GHDL; see the file COPYING. If not, write to the Free
-- Software Foundation, 59 Temple Place - Suite 330, Boston, MA
-- 02111-1307, USA.
with Ada.Unchecked_Conversion;
with Ada.Text_IO; use Ada.Text_IO;
with System;
with Grt.Types; use Grt.Types;
with Flags; use Flags;
with Errorout; use Errorout;
with Std_Package;
with Evaluation;
with Iirs_Utils; use Iirs_Utils;
with Annotations; use Annotations;
with Name_Table;
with File_Operation;
with Debugger; use Debugger;
with Std_Names;
with Str_Table;
with Files_Map;
with Iir_Chains; use Iir_Chains;
with Simulation; use Simulation;
with Grt.Astdio;
with Grt.Stdio;
with Grt.Options;
with Grt.Vstrings;
with Grt_Interface;
with Grt.Values;
with Grt.Errors;
with Grt.Std_Logic_1164;
package body Execution is
function Execute_Function_Call
(Block: Block_Instance_Acc; Expr: Iir; Imp : Iir)
return Iir_Value_Literal_Acc;
procedure Finish_Sequential_Statements
(Proc : Process_State_Acc; Complex_Stmt : Iir);
procedure Init_Sequential_Statements
(Proc : Process_State_Acc; Complex_Stmt : Iir);
procedure Update_Next_Statement (Proc : Process_State_Acc);
-- Display a message when an assertion has failed.
procedure Execute_Failed_Assertion (Report : String;
Severity : Natural;
Stmt: Iir);
function Get_Instance_By_Scope
(Instance: Block_Instance_Acc; Scope: Scope_Type)
return Block_Instance_Acc
is
Current: Block_Instance_Acc := Instance;
begin
case Scope.Kind is
when Scope_Kind_Frame =>
while Current /= null loop
if Current.Block_Scope = Scope then
return Current;
end if;
Current := Current.Up_Block;
end loop;
raise Internal_Error;
when Scope_Kind_Package =>
-- Global scope (packages)
return Package_Instances (Scope.Pkg_Index);
when Scope_Kind_Component =>
pragma Assert (Current_Component /= null);
return Current_Component;
when Scope_Kind_None =>
raise Internal_Error;
when Scope_Kind_Pkg_Inst =>
raise Internal_Error;
end case;
end Get_Instance_By_Scope;
function Get_Instance_For_Slot (Instance: Block_Instance_Acc; Decl: Iir)
return Block_Instance_Acc is
begin
return Get_Instance_By_Scope (Instance, Get_Info (Decl).Obj_Scope);
end Get_Instance_For_Slot;
procedure Create_Right_Bound_From_Length
(Bounds : Iir_Value_Literal_Acc; Len : Iir_Index32)
is
begin
pragma Assert (Bounds.Right = null);
case Bounds.Left.Kind is
when Iir_Value_E32 =>
declare
R : Ghdl_E32;
begin
case Bounds.Dir is
when Iir_To =>
R := Bounds.Left.E32 + Ghdl_E32 (Len - 1);
when Iir_Downto =>
R := Bounds.Left.E32 - Ghdl_E32 (Len - 1);
end case;
Bounds.Right := Create_E32_Value (R);
end;
when Iir_Value_I64 =>
declare
R : Ghdl_I64;
begin
case Bounds.Dir is
when Iir_To =>
R := Bounds.Left.I64 + Ghdl_I64 (Len - 1);
when Iir_Downto =>
R := Bounds.Left.I64 - Ghdl_I64 (Len - 1);
end case;
Bounds.Right := Create_I64_Value (R);
end;
when others =>
raise Internal_Error;
end case;
end Create_Right_Bound_From_Length;
function Create_Bounds_From_Length (Block : Block_Instance_Acc;
Atype : Iir;
Len : Iir_Index32)
return Iir_Value_Literal_Acc
is
Res : Iir_Value_Literal_Acc;
Index_Bounds : Iir_Value_Literal_Acc;
begin
Index_Bounds := Execute_Bounds (Block, Atype);
Res := Create_Range_Value (Left => Index_Bounds.Left,
Right => null,
Dir => Index_Bounds.Dir,
Length => Len);
if Len = 0 then
-- Special case.
Res.Right := Res.Left;
case Res.Left.Kind is
when Iir_Value_I64 =>
case Index_Bounds.Dir is
when Iir_To =>
Res.Left := Create_I64_Value (Res.Right.I64 + 1);
when Iir_Downto =>
Res.Left := Create_I64_Value (Res.Right.I64 - 1);
end case;
when others =>
raise Internal_Error;
end case;
else
Create_Right_Bound_From_Length (Res, Len);
end if;
return Res;
end Create_Bounds_From_Length;
function Execute_High_Limit (Bounds : Iir_Value_Literal_Acc)
return Iir_Value_Literal_Acc is
begin
if Bounds.Dir = Iir_To then
return Bounds.Right;
else
return Bounds.Left;
end if;
end Execute_High_Limit;
function Execute_Low_Limit (Bounds : Iir_Value_Literal_Acc)
return Iir_Value_Literal_Acc is
begin
if Bounds.Dir = Iir_To then
return Bounds.Left;
else
return Bounds.Right;
end if;
end Execute_Low_Limit;
function Execute_Left_Limit (Bounds : Iir_Value_Literal_Acc)
return Iir_Value_Literal_Acc is
begin
return Bounds.Left;
end Execute_Left_Limit;
function Execute_Right_Limit (Bounds : Iir_Value_Literal_Acc)
return Iir_Value_Literal_Acc is
begin
return Bounds.Right;
end Execute_Right_Limit;
function Execute_Length (Bounds : Iir_Value_Literal_Acc)
return Iir_Value_Literal_Acc is
begin
return Create_I64_Value (Ghdl_I64 (Bounds.Length));
end Execute_Length;
function Create_Enum_Value (Pos : Natural; Etype : Iir)
return Iir_Value_Literal_Acc
is
Base_Type : constant Iir := Get_Base_Type (Etype);
Mode : constant Iir_Value_Kind :=
Get_Info (Base_Type).Scalar_Mode;
begin
case Mode is
when Iir_Value_E32 =>
return Create_E32_Value (Ghdl_E32 (Pos));
when Iir_Value_B1 =>
return Create_B1_Value (Ghdl_B1'Val (Pos));
when others =>
raise Internal_Error;
end case;
end Create_Enum_Value;
function String_To_Iir_Value (Str : String) return Iir_Value_Literal_Acc
is
Res : Iir_Value_Literal_Acc;
begin
Res := Create_Array_Value (Str'Length, 1);
Res.Bounds.D (1) := Create_Range_Value
(Create_I64_Value (1),
Create_I64_Value (Str'Length),
Iir_To);
for I in Str'Range loop
Res.Val_Array.V (1 + Iir_Index32 (I - Str'First)) :=
Create_E32_Value (Character'Pos (Str (I)));
end loop;
return Res;
end String_To_Iir_Value;
function Execute_Image_Attribute (Val : Iir_Value_Literal_Acc;
Expr_Type : Iir)
return String
is
begin
case Get_Kind (Expr_Type) is
when Iir_Kind_Floating_Type_Definition
| Iir_Kind_Floating_Subtype_Definition =>
declare
Str : String (1 .. 24);
Last : Natural;
begin
Grt.Vstrings.To_String (Str, Last, Val.F64);
return Str (Str'First .. Last);
end;
when Iir_Kind_Integer_Type_Definition
| Iir_Kind_Integer_Subtype_Definition =>
declare
Str : String (1 .. 21);
First : Natural;
begin
Grt.Vstrings.To_String (Str, First, Val.I64);
return Str (First .. Str'Last);
end;
when Iir_Kind_Enumeration_Type_Definition
| Iir_Kind_Enumeration_Subtype_Definition =>
declare
Lits : constant Iir_List :=
Get_Enumeration_Literal_List (Get_Base_Type (Expr_Type));
Pos : Natural;
begin
case Val.Kind is
when Iir_Value_B1 =>
Pos := Ghdl_B1'Pos (Val.B1);
when Iir_Value_E32 =>
Pos := Ghdl_E32'Pos (Val.E32);
when others =>
raise Internal_Error;
end case;
return Name_Table.Image
(Get_Identifier (Get_Nth_Element (Lits, Pos)));
end;
when Iir_Kind_Physical_Type_Definition
| Iir_Kind_Physical_Subtype_Definition =>
declare
Str : String (1 .. 21);
First : Natural;
Id : constant Name_Id :=
Get_Identifier (Get_Primary_Unit (Get_Base_Type (Expr_Type)));
begin
Grt.Vstrings.To_String (Str, First, Val.I64);
return Str (First .. Str'Last) & ' ' & Name_Table.Image (Id);
end;
when others =>
Error_Kind ("execute_image_attribute", Expr_Type);
end case;
end Execute_Image_Attribute;
function Execute_Shift_Operator (Left : Iir_Value_Literal_Acc;
Count : Ghdl_I64;
Expr : Iir)
return Iir_Value_Literal_Acc
is
Func : constant Iir_Predefined_Shift_Functions :=
Get_Implicit_Definition (Get_Implementation (Expr));
Cnt : Iir_Index32;
Len : constant Iir_Index32 := Left.Bounds.D (1).Length;
Dir_Left : Boolean;
P : Iir_Index32;
Res : Iir_Value_Literal_Acc;
E : Iir_Value_Literal_Acc;
begin
-- LRM93 7.2.3
-- That is, if R is 0 or if L is a null array, the return value is L.
if Count = 0 or else Len = 0 then
return Left;
end if;
case Func is
when Iir_Predefined_Array_Sll
| Iir_Predefined_Array_Sla
| Iir_Predefined_Array_Rol =>
Dir_Left := True;
when Iir_Predefined_Array_Srl
| Iir_Predefined_Array_Sra
| Iir_Predefined_Array_Ror =>
Dir_Left := False;
end case;
if Count < 0 then
Cnt := Iir_Index32 (-Count);
Dir_Left := not Dir_Left;
else
Cnt := Iir_Index32 (Count);
end if;
case Func is
when Iir_Predefined_Array_Sll
| Iir_Predefined_Array_Srl =>
E := Create_Enum_Value
(0, Get_Element_Subtype (Get_Base_Type (Get_Type (Expr))));
when Iir_Predefined_Array_Sla
| Iir_Predefined_Array_Sra =>
if Dir_Left then
E := Left.Val_Array.V (Len);
else
E := Left.Val_Array.V (1);
end if;
when Iir_Predefined_Array_Rol
| Iir_Predefined_Array_Ror =>
Cnt := Cnt mod Len;
if not Dir_Left then
Cnt := (Len - Cnt) mod Len;
end if;
end case;
Res := Create_Array_Value (1);
Res.Bounds.D (1) := Left.Bounds.D (1);
Create_Array_Data (Res, Len);
P := 1;
case Func is
when Iir_Predefined_Array_Sll
| Iir_Predefined_Array_Srl
| Iir_Predefined_Array_Sla
| Iir_Predefined_Array_Sra =>
if Dir_Left then
if Cnt < Len then
for I in Cnt .. Len - 1 loop
Res.Val_Array.V (P) := Left.Val_Array.V (I + 1);
P := P + 1;
end loop;
else
Cnt := Len;
end if;
for I in 0 .. Cnt - 1 loop
Res.Val_Array.V (P) := E;
P := P + 1;
end loop;
else
if Cnt > Len then
Cnt := Len;
end if;
for I in 0 .. Cnt - 1 loop
Res.Val_Array.V (P) := E;
P := P + 1;
end loop;
for I in Cnt .. Len - 1 loop
Res.Val_Array.V (P) := Left.Val_Array.V (I - Cnt + 1);
P := P + 1;
end loop;
end if;
when Iir_Predefined_Array_Rol
| Iir_Predefined_Array_Ror =>
for I in 1 .. Len loop
Res.Val_Array.V (P) := Left.Val_Array.V (Cnt + 1);
P := P + 1;
Cnt := Cnt + 1;
if Cnt = Len then
Cnt := 0;
end if;
end loop;
end case;
return Res;
end Execute_Shift_Operator;
Hex_Chars : constant array (Natural range 0 .. 15) of Character :=
"0123456789ABCDEF";
function Execute_Bit_Vector_To_String (Val : Iir_Value_Literal_Acc;
Log_Base : Natural)
return Iir_Value_Literal_Acc
is
Base : constant Natural := 2 ** Log_Base;
Blen : constant Natural := Natural (Val.Bounds.D (1).Length);
Str : String (1 .. (Blen + Log_Base - 1) / Log_Base);
Pos : Natural;
V : Natural;
N : Natural;
begin
V := 0;
N := 1;
Pos := Str'Last;
for I in reverse Val.Val_Array.V'Range loop
V := V + Ghdl_B1'Pos (Val.Val_Array.V (I).B1) * N;
N := N * 2;
if N = Base or else I = Val.Val_Array.V'First then
Str (Pos) := Hex_Chars (V);
Pos := Pos - 1;
N := 1;
V := 0;
end if;
end loop;
return String_To_Iir_Value (Str);
end Execute_Bit_Vector_To_String;
procedure Check_Std_Ulogic_Dc
(Loc : Iir; V : Grt.Std_Logic_1164.Std_Ulogic)
is
use Grt.Std_Logic_1164;
begin
if V = '-' then
Execute_Failed_Assertion
("STD_LOGIC_1164: '-' operand for matching ordering operator",
2, Loc);
end if;
end Check_Std_Ulogic_Dc;
-- EXPR is the expression whose implementation is an implicit function.
function Execute_Implicit_Function (Block : Block_Instance_Acc;
Expr: Iir;
Left_Param : Iir;
Right_Param : Iir;
Res_Type : Iir)
return Iir_Value_Literal_Acc
is
pragma Unsuppress (Overflow_Check);
Func : Iir_Predefined_Functions;
-- Rename definition for monadic operations.
Left, Right: Iir_Value_Literal_Acc;
Operand : Iir_Value_Literal_Acc renames Left;
Result: Iir_Value_Literal_Acc;
procedure Eval_Right is
begin
Right := Execute_Expression (Block, Right_Param);
end Eval_Right;
-- Eval right argument, check left and right have same length,
-- Create RESULT from left.
procedure Eval_Array is
begin
Eval_Right;
if Left.Bounds.D (1).Length /= Right.Bounds.D (1).Length then
Error_Msg_Constraint (Expr);
end if;
-- Need to copy as the result is modified.
Result := Unshare (Left, Expr_Pool'Access);
end Eval_Array;
Imp : Iir;
begin
Imp := Get_Implementation (Expr);
if Get_Kind (Imp) in Iir_Kinds_Denoting_Name then
Imp := Get_Named_Entity (Imp);
end if;
Func := Get_Implicit_Definition (Imp);
-- Eval left operand.
case Func is
when Iir_Predefined_Now_Function =>
Left := null;
when Iir_Predefined_Bit_Rising_Edge
| Iir_Predefined_Boolean_Rising_Edge
| Iir_Predefined_Bit_Falling_Edge
| Iir_Predefined_Boolean_Falling_Edge=>
Operand := Execute_Name (Block, Left_Param, True);
when others =>
Left := Execute_Expression (Block, Left_Param);
end case;
Right := null;
case Func is
when Iir_Predefined_Error =>
raise Internal_Error;
when Iir_Predefined_Array_Array_Concat
| Iir_Predefined_Element_Array_Concat
| Iir_Predefined_Array_Element_Concat
| Iir_Predefined_Element_Element_Concat =>
Eval_Right;
declare
-- Array length of the result.
Len: Iir_Index32;
-- Index into the result.
Pos: Iir_Index32;
begin
-- Compute the length of the result.
case Func is
when Iir_Predefined_Array_Array_Concat =>
Len := Left.Val_Array.Len + Right.Val_Array.Len;
when Iir_Predefined_Element_Array_Concat =>
Len := 1 + Right.Val_Array.Len;
when Iir_Predefined_Array_Element_Concat =>
Len := Left.Val_Array.Len + 1;
when Iir_Predefined_Element_Element_Concat =>
Len := 1 + 1;
when others =>
raise Program_Error;
end case;
if Func = Iir_Predefined_Array_Array_Concat
and then Left.Val_Array.Len = 0
then
if Flags.Vhdl_Std = Vhdl_87 then
-- LRM87 7.2.3
-- [...], unless the left operand is a null array, in
-- which case the result of the concatenation is the
-- right operand.
return Right;
else
-- LRM93 7.2.4
-- If both operands are null arrays, then the result of
-- the concatenation is the right operand.
if Right.Val_Array.Len = 0 then
return Right;
end if;
end if;
end if;
if Flags.Vhdl_Std = Vhdl_87
and then (Func = Iir_Predefined_Array_Array_Concat
or Func = Iir_Predefined_Array_Element_Concat)
then
-- LRM87 7.2.3 Adding Operators
-- The left bound if this result is the left bound of the
-- left operand, [...]. The direction of the result is the
-- direction of the left operand, unless the left operand
-- is a null array, in which case the direction of the
-- result is that of the right operand.
Result := Create_Array_Value (Len, 1);
Result.Bounds.D (1) := Create_Range_Value
(Left.Bounds.D (1).Left, null, Left.Bounds.D (1).Dir, Len);
Create_Right_Bound_From_Length (Result.Bounds.D (1), Len);
else
-- Create the array result.
Result := Create_Array_Value (Len, 1);
Result.Bounds.D (1) := Create_Bounds_From_Length
(Block,
Get_First_Element (Get_Index_Subtype_List (Res_Type)),
Len);
end if;
-- Fill the result: left.
case Func is
when Iir_Predefined_Array_Array_Concat
| Iir_Predefined_Array_Element_Concat =>
for I in Left.Val_Array.V'Range loop
Result.Val_Array.V (I) := Left.Val_Array.V (I);
end loop;
Pos := Left.Val_Array.Len;
when Iir_Predefined_Element_Array_Concat
| Iir_Predefined_Element_Element_Concat =>
Result.Val_Array.V (1) := Left;
Pos := 1;
when others =>
raise Program_Error;
end case;
-- Note: here POS is equal to the position of the last element
-- filled, or 0 if no elements were filled.
-- Fill the result: right.
case Func is
when Iir_Predefined_Array_Array_Concat
| Iir_Predefined_Element_Array_Concat =>
for I in Right.Val_Array.V'Range loop
Result.Val_Array.V (Pos + I) := Right.Val_Array.V (I);
end loop;
when Iir_Predefined_Array_Element_Concat
| Iir_Predefined_Element_Element_Concat =>
Result.Val_Array.V (Pos + 1) := Right;
when others =>
raise Program_Error;
end case;
end;
when Iir_Predefined_Bit_And
| Iir_Predefined_Boolean_And =>
if Left.B1 = Lit_Enum_0.B1 then
-- Short circuit operator.
Result := Lit_Enum_0;
else
Eval_Right;
Result := Boolean_To_Lit (Right.B1 = Lit_Enum_1.B1);
end if;
when Iir_Predefined_Bit_Nand
| Iir_Predefined_Boolean_Nand =>
if Left.B1 = Lit_Enum_0.B1 then
-- Short circuit operator.
Result := Lit_Enum_1;
else
Eval_Right;
Result := Boolean_To_Lit (Right.B1 = Lit_Enum_0.B1);
end if;
when Iir_Predefined_Bit_Or
| Iir_Predefined_Boolean_Or =>
if Left.B1 = Lit_Enum_1.B1 then
-- Short circuit operator.
Result := Lit_Enum_1;
else
Eval_Right;
Result := Boolean_To_Lit (Right.B1 = Lit_Enum_1.B1);
end if;
when Iir_Predefined_Bit_Nor
| Iir_Predefined_Boolean_Nor =>
if Left.B1 = Lit_Enum_1.B1 then
-- Short circuit operator.
Result := Lit_Enum_0;
else
Eval_Right;
Result := Boolean_To_Lit (Right.B1 = Lit_Enum_0.B1);
end if;
when Iir_Predefined_Bit_Xor
| Iir_Predefined_Boolean_Xor =>
Eval_Right;
Result := Boolean_To_Lit (Left.B1 /= Right.B1);
when Iir_Predefined_Bit_Xnor
| Iir_Predefined_Boolean_Xnor =>
Eval_Right;
Result := Boolean_To_Lit (Left.B1 = Right.B1);
when Iir_Predefined_Bit_Not
| Iir_Predefined_Boolean_Not =>
Result := Boolean_To_Lit (Operand.B1 = Lit_Enum_0.B1);
when Iir_Predefined_Bit_Condition =>
Result := Boolean_To_Lit (Operand.B1 = Lit_Enum_1.B1);
when Iir_Predefined_Array_Sll
| Iir_Predefined_Array_Srl
| Iir_Predefined_Array_Sla
| Iir_Predefined_Array_Sra
| Iir_Predefined_Array_Rol
| Iir_Predefined_Array_Ror =>
Eval_Right;
Result := Execute_Shift_Operator (Left, Right.I64, Expr);
when Iir_Predefined_Enum_Equality
| Iir_Predefined_Integer_Equality
| Iir_Predefined_Array_Equality
| Iir_Predefined_Access_Equality
| Iir_Predefined_Physical_Equality
| Iir_Predefined_Floating_Equality
| Iir_Predefined_Record_Equality
| Iir_Predefined_Bit_Match_Equality
| Iir_Predefined_Bit_Array_Match_Equality =>
Eval_Right;
Result := Boolean_To_Lit (Is_Equal (Left, Right));
when Iir_Predefined_Enum_Inequality
| Iir_Predefined_Integer_Inequality
| Iir_Predefined_Array_Inequality
| Iir_Predefined_Access_Inequality
| Iir_Predefined_Physical_Inequality
| Iir_Predefined_Floating_Inequality
| Iir_Predefined_Record_Inequality
| Iir_Predefined_Bit_Match_Inequality
| Iir_Predefined_Bit_Array_Match_Inequality =>
Eval_Right;
Result := Boolean_To_Lit (not Is_Equal (Left, Right));
when Iir_Predefined_Integer_Less
| Iir_Predefined_Physical_Less =>
Eval_Right;
case Left.Kind is
when Iir_Value_I64 =>
Result := Boolean_To_Lit (Left.I64 < Right.I64);
when others =>
raise Internal_Error;
end case;
when Iir_Predefined_Integer_Greater
| Iir_Predefined_Physical_Greater =>
Eval_Right;
case Left.Kind is
when Iir_Value_I64 =>
Result := Boolean_To_Lit (Left.I64 > Right.I64);
when others =>
raise Internal_Error;
end case;
when Iir_Predefined_Integer_Less_Equal
| Iir_Predefined_Physical_Less_Equal =>
Eval_Right;
case Left.Kind is
when Iir_Value_I64 =>
Result := Boolean_To_Lit (Left.I64 <= Right.I64);
when others =>
raise Internal_Error;
end case;
when Iir_Predefined_Integer_Greater_Equal
| Iir_Predefined_Physical_Greater_Equal =>
Eval_Right;
case Left.Kind is
when Iir_Value_I64 =>
Result := Boolean_To_Lit (Left.I64 >= Right.I64);
when others =>
raise Internal_Error;
end case;
when Iir_Predefined_Enum_Less =>
Eval_Right;
case Left.Kind is
when Iir_Value_B1 =>
Result := Boolean_To_Lit (Left.B1 < Right.B1);
when Iir_Value_E32 =>
Result := Boolean_To_Lit (Left.E32 < Right.E32);
when others =>
raise Internal_Error;
end case;
when Iir_Predefined_Enum_Greater =>
Eval_Right;
case Left.Kind is
when Iir_Value_B1 =>
Result := Boolean_To_Lit (Left.B1 > Right.B1);
when Iir_Value_E32 =>
Result := Boolean_To_Lit (Left.E32 > Right.E32);
when others =>
raise Internal_Error;
end case;
when Iir_Predefined_Enum_Less_Equal =>
Eval_Right;
case Left.Kind is
when Iir_Value_B1 =>
Result := Boolean_To_Lit (Left.B1 <= Right.B1);
when Iir_Value_E32 =>
Result := Boolean_To_Lit (Left.E32 <= Right.E32);
when others =>
raise Internal_Error;
end case;
when Iir_Predefined_Enum_Greater_Equal =>
Eval_Right;
case Left.Kind is
when Iir_Value_B1 =>
Result := Boolean_To_Lit (Left.B1 >= Right.B1);
when Iir_Value_E32 =>
Result := Boolean_To_Lit (Left.E32 >= Right.E32);
when others =>
raise Internal_Error;
end case;
when Iir_Predefined_Enum_Minimum
| Iir_Predefined_Physical_Minimum =>
Eval_Right;
if Compare_Value (Left, Right) = Less then
Result := Left;
else
Result := Right;
end if;
when Iir_Predefined_Enum_Maximum
| Iir_Predefined_Physical_Maximum =>
Eval_Right;
if Compare_Value (Left, Right) = Less then
Result := Right;
else
Result := Left;
end if;
when Iir_Predefined_Integer_Plus
| Iir_Predefined_Physical_Plus =>
Eval_Right;
case Left.Kind is
when Iir_Value_I64 =>
Result := Create_I64_Value (Left.I64 + Right.I64);
when others =>
raise Internal_Error;
end case;
when Iir_Predefined_Integer_Minus
| Iir_Predefined_Physical_Minus =>
Eval_Right;
case Left.Kind is
when Iir_Value_I64 =>
Result := Create_I64_Value (Left.I64 - Right.I64);
when others =>
raise Internal_Error;
end case;
when Iir_Predefined_Integer_Mul =>
Eval_Right;
case Left.Kind is
when Iir_Value_I64 =>
Result := Create_I64_Value (Left.I64 * Right.I64);
when others =>
raise Internal_Error;
end case;
when Iir_Predefined_Integer_Mod =>
Eval_Right;
case Left.Kind is
when Iir_Value_I64 =>
if Right.I64 = 0 then
Error_Msg_Constraint (Expr);
end if;
Result := Create_I64_Value (Left.I64 mod Right.I64);
when others =>
raise Internal_Error;
end case;
when Iir_Predefined_Integer_Rem =>
Eval_Right;
case Left.Kind is
when Iir_Value_I64 =>
if Right.I64 = 0 then
Error_Msg_Constraint (Expr);
end if;
Result := Create_I64_Value (Left.I64 rem Right.I64);
when others =>
raise Internal_Error;
end case;
when Iir_Predefined_Integer_Div =>
Eval_Right;
case Left.Kind is
when Iir_Value_I64 =>
if Right.I64 = 0 then
Error_Msg_Constraint (Expr);
end if;
Result := Create_I64_Value (Left.I64 / Right.I64);
when others =>
raise Internal_Error;
end case;
when Iir_Predefined_Integer_Absolute
| Iir_Predefined_Physical_Absolute =>
case Operand.Kind is
when Iir_Value_I64 =>
Result := Create_I64_Value (abs Operand.I64);
when others =>
raise Internal_Error;
end case;
when Iir_Predefined_Integer_Negation
| Iir_Predefined_Physical_Negation =>
case Operand.Kind is
when Iir_Value_I64 =>
Result := Create_I64_Value (-Operand.I64);
when others =>
raise Internal_Error;
end case;
when Iir_Predefined_Integer_Identity
| Iir_Predefined_Physical_Identity =>
case Operand.Kind is
when Iir_Value_I64 =>
Result := Create_I64_Value (Operand.I64);
when others =>
raise Internal_Error;
end case;
when Iir_Predefined_Integer_Exp =>
Eval_Right;
case Left.Kind is
when Iir_Value_I64 =>
if Right.I64 < 0 then
Error_Msg_Constraint (Expr);
end if;
Result := Create_I64_Value (Left.I64 ** Natural (Right.I64));
when others =>
raise Internal_Error;
end case;
when Iir_Predefined_Integer_Minimum =>
Eval_Right;
Result := Create_I64_Value (Ghdl_I64'Min (Left.I64, Right.I64));
when Iir_Predefined_Integer_Maximum =>
Eval_Right;
Result := Create_I64_Value (Ghdl_I64'Max (Left.I64, Right.I64));
when Iir_Predefined_Floating_Mul =>
Eval_Right;
Result := Create_F64_Value (Left.F64 * Right.F64);
when Iir_Predefined_Floating_Div =>
Eval_Right;
Result := Create_F64_Value (Left.F64 / Right.F64);
when Iir_Predefined_Floating_Minus =>
Eval_Right;
Result := Create_F64_Value (Left.F64 - Right.F64);
when Iir_Predefined_Floating_Plus =>
Eval_Right;
Result := Create_F64_Value (Left.F64 + Right.F64);
when Iir_Predefined_Floating_Exp =>
Eval_Right;
Result := Create_F64_Value (Left.F64 ** Integer (Right.I64));
when Iir_Predefined_Floating_Identity =>
Result := Create_F64_Value (Operand.F64);
when Iir_Predefined_Floating_Negation =>
Result := Create_F64_Value (-Operand.F64);
when Iir_Predefined_Floating_Absolute =>
Result := Create_F64_Value (abs (Operand.F64));
when Iir_Predefined_Floating_Less =>
Eval_Right;
Result := Boolean_To_Lit (Left.F64 < Right.F64);
when Iir_Predefined_Floating_Less_Equal =>
Eval_Right;
Result := Boolean_To_Lit (Left.F64 <= Right.F64);
when Iir_Predefined_Floating_Greater =>
Eval_Right;
Result := Boolean_To_Lit (Left.F64 > Right.F64);
when Iir_Predefined_Floating_Greater_Equal =>
Eval_Right;
Result := Boolean_To_Lit (Left.F64 >= Right.F64);
when Iir_Predefined_Floating_Minimum =>
Eval_Right;
Result := Create_F64_Value (Ghdl_F64'Min (Left.F64, Right.F64));
when Iir_Predefined_Floating_Maximum =>
Eval_Right;
Result := Create_F64_Value (Ghdl_F64'Max (Left.F64, Right.F64));
when Iir_Predefined_Integer_Physical_Mul =>
Eval_Right;
Result := Create_I64_Value (Left.I64 * Right.I64);
when Iir_Predefined_Physical_Integer_Mul =>
Eval_Right;
Result := Create_I64_Value (Left.I64 * Right.I64);
when Iir_Predefined_Physical_Physical_Div =>
Eval_Right;
Result := Create_I64_Value (Left.I64 / Right.I64);
when Iir_Predefined_Physical_Integer_Div =>
Eval_Right;
Result := Create_I64_Value (Left.I64 / Right.I64);
when Iir_Predefined_Real_Physical_Mul =>
Eval_Right;
Result := Create_I64_Value
(Ghdl_I64 (Left.F64 * Ghdl_F64 (Right.I64)));
when Iir_Predefined_Physical_Real_Mul =>
Eval_Right;
Result := Create_I64_Value
(Ghdl_I64 (Ghdl_F64 (Left.I64) * Right.F64));
when Iir_Predefined_Physical_Real_Div =>
Eval_Right;
Result := Create_I64_Value
(Ghdl_I64 (Ghdl_F64 (Left.I64) / Right.F64));
when Iir_Predefined_Universal_I_R_Mul =>
Eval_Right;
Result := Create_F64_Value (Ghdl_F64 (Left.I64) * Right.F64);
when Iir_Predefined_Universal_R_I_Mul =>
Eval_Right;
Result := Create_F64_Value (Left.F64 * Ghdl_F64 (Right.I64));
when Iir_Predefined_TF_Array_And =>
Eval_Array;
for I in Result.Val_Array.V'Range loop
Result.Val_Array.V (I).B1 :=
Result.Val_Array.V (I).B1 and Right.Val_Array.V (I).B1;
end loop;
when Iir_Predefined_TF_Array_Nand =>
Eval_Array;
for I in Result.Val_Array.V'Range loop
Result.Val_Array.V (I).B1 :=
not (Result.Val_Array.V (I).B1 and Right.Val_Array.V (I).B1);
end loop;
when Iir_Predefined_TF_Array_Or =>
Eval_Array;
for I in Result.Val_Array.V'Range loop
Result.Val_Array.V (I).B1 :=
Result.Val_Array.V (I).B1 or Right.Val_Array.V (I).B1;
end loop;
when Iir_Predefined_TF_Array_Nor =>
Eval_Array;
for I in Result.Val_Array.V'Range loop
Result.Val_Array.V (I).B1 :=
not (Result.Val_Array.V (I).B1 or Right.Val_Array.V (I).B1);
end loop;
when Iir_Predefined_TF_Array_Xor =>
Eval_Array;
for I in Result.Val_Array.V'Range loop
Result.Val_Array.V (I).B1 :=
Result.Val_Array.V (I).B1 xor Right.Val_Array.V (I).B1;
end loop;
when Iir_Predefined_TF_Array_Xnor =>
Eval_Array;
for I in Result.Val_Array.V'Range loop
Result.Val_Array.V (I).B1 :=
not (Result.Val_Array.V (I).B1 xor Right.Val_Array.V (I).B1);
end loop;
when Iir_Predefined_TF_Array_Element_And =>
Eval_Right;
Result := Unshare (Left, Expr_Pool'Access);
for I in Result.Val_Array.V'Range loop
Result.Val_Array.V (I).B1 :=
Result.Val_Array.V (I).B1 and Right.B1;
end loop;
when Iir_Predefined_TF_Element_Array_And =>
Eval_Right;
Result := Unshare (Right, Expr_Pool'Access);
for I in Result.Val_Array.V'Range loop
Result.Val_Array.V (I).B1 :=
Result.Val_Array.V (I).B1 and Left.B1;
end loop;
when Iir_Predefined_TF_Array_Element_Or =>
Eval_Right;
Result := Unshare (Left, Expr_Pool'Access);
for I in Result.Val_Array.V'Range loop
Result.Val_Array.V (I).B1 :=
Result.Val_Array.V (I).B1 or Right.B1;
end loop;
when Iir_Predefined_TF_Element_Array_Or =>
Eval_Right;
Result := Unshare (Right, Expr_Pool'Access);
for I in Result.Val_Array.V'Range loop
Result.Val_Array.V (I).B1 :=
Result.Val_Array.V (I).B1 or Left.B1;
end loop;
when Iir_Predefined_TF_Array_Element_Xor =>
Eval_Right;
Result := Unshare (Left, Expr_Pool'Access);
for I in Result.Val_Array.V'Range loop
Result.Val_Array.V (I).B1 :=
Result.Val_Array.V (I).B1 xor Right.B1;
end loop;
when Iir_Predefined_TF_Element_Array_Xor =>
Eval_Right;
Result := Unshare (Right, Expr_Pool'Access);
for I in Result.Val_Array.V'Range loop
Result.Val_Array.V (I).B1 :=
Result.Val_Array.V (I).B1 xor Left.B1;
end loop;
when Iir_Predefined_TF_Array_Element_Nand =>
Eval_Right;
Result := Unshare (Left, Expr_Pool'Access);
for I in Result.Val_Array.V'Range loop
Result.Val_Array.V (I).B1 :=
not (Result.Val_Array.V (I).B1 and Right.B1);
end loop;
when Iir_Predefined_TF_Element_Array_Nand =>
Eval_Right;
Result := Unshare (Right, Expr_Pool'Access);
for I in Result.Val_Array.V'Range loop
Result.Val_Array.V (I).B1 :=
not (Result.Val_Array.V (I).B1 and Left.B1);
end loop;
when Iir_Predefined_TF_Array_Element_Nor =>
Eval_Right;
Result := Unshare (Left, Expr_Pool'Access);
for I in Result.Val_Array.V'Range loop
Result.Val_Array.V (I).B1 :=
not (Result.Val_Array.V (I).B1 or Right.B1);
end loop;
when Iir_Predefined_TF_Element_Array_Nor =>
Eval_Right;
Result := Unshare (Right, Expr_Pool'Access);
for I in Result.Val_Array.V'Range loop
Result.Val_Array.V (I).B1 :=
not (Result.Val_Array.V (I).B1 or Left.B1);
end loop;
when Iir_Predefined_TF_Array_Element_Xnor =>
Eval_Right;
Result := Unshare (Left, Expr_Pool'Access);
for I in Result.Val_Array.V'Range loop
Result.Val_Array.V (I).B1 :=
not (Result.Val_Array.V (I).B1 xor Right.B1);
end loop;
when Iir_Predefined_TF_Element_Array_Xnor =>
Eval_Right;
Result := Unshare (Right, Expr_Pool'Access);
for I in Result.Val_Array.V'Range loop
Result.Val_Array.V (I).B1 :=
not (Result.Val_Array.V (I).B1 xor Left.B1);
end loop;
when Iir_Predefined_TF_Array_Not =>
-- Need to copy as the result is modified.
Result := Unshare (Operand, Expr_Pool'Access);
for I in Result.Val_Array.V'Range loop
Result.Val_Array.V (I).B1 := not Result.Val_Array.V (I).B1;
end loop;
when Iir_Predefined_TF_Reduction_And =>
Result := Create_B1_Value (True);
for I in Operand.Val_Array.V'Range loop
Result.B1 := Result.B1 and Operand.Val_Array.V (I).B1;
end loop;
when Iir_Predefined_TF_Reduction_Nand =>
Result := Create_B1_Value (True);
for I in Operand.Val_Array.V'Range loop
Result.B1 := Result.B1 and Operand.Val_Array.V (I).B1;
end loop;
Result.B1 := not Result.B1;
when Iir_Predefined_TF_Reduction_Or =>
Result := Create_B1_Value (False);
for I in Operand.Val_Array.V'Range loop
Result.B1 := Result.B1 or Operand.Val_Array.V (I).B1;
end loop;
when Iir_Predefined_TF_Reduction_Nor =>
Result := Create_B1_Value (False);
for I in Operand.Val_Array.V'Range loop
Result.B1 := Result.B1 or Operand.Val_Array.V (I).B1;
end loop;
Result.B1 := not Result.B1;
when Iir_Predefined_TF_Reduction_Xor =>
Result := Create_B1_Value (False);
for I in Operand.Val_Array.V'Range loop
Result.B1 := Result.B1 xor Operand.Val_Array.V (I).B1;
end loop;
when Iir_Predefined_TF_Reduction_Xnor =>
Result := Create_B1_Value (False);
for I in Operand.Val_Array.V'Range loop
Result.B1 := Result.B1 xor Operand.Val_Array.V (I).B1;
end loop;
Result.B1 := not Result.B1;
when Iir_Predefined_Bit_Rising_Edge
| Iir_Predefined_Boolean_Rising_Edge =>
return Boolean_To_Lit
(Execute_Event_Attribute (Operand)
and then Execute_Signal_Value (Operand).B1 = True);
when Iir_Predefined_Bit_Falling_Edge
| Iir_Predefined_Boolean_Falling_Edge =>
return Boolean_To_Lit
(Execute_Event_Attribute (Operand)
and then Execute_Signal_Value (Operand).B1 = False);
when Iir_Predefined_Array_Greater =>
Eval_Right;
Result := Boolean_To_Lit (Compare_Value (Left, Right) = Greater);
when Iir_Predefined_Array_Greater_Equal =>
Eval_Right;
Result := Boolean_To_Lit (Compare_Value (Left, Right) >= Equal);
when Iir_Predefined_Array_Less =>
Eval_Right;
Result := Boolean_To_Lit (Compare_Value (Left, Right) = Less);
when Iir_Predefined_Array_Less_Equal =>
Eval_Right;
Result := Boolean_To_Lit (Compare_Value (Left, Right) <= Equal);
when Iir_Predefined_Array_Minimum =>
Eval_Right;
if Compare_Value (Left, Right) = Less then
Result := Left;
else
Result := Right;
end if;
when Iir_Predefined_Array_Maximum =>
Eval_Right;
if Compare_Value (Left, Right) = Less then
Result := Right;
else
Result := Left;
end if;
when Iir_Predefined_Vector_Maximum =>
declare
El_St : constant Iir :=
Get_Return_Type (Get_Implementation (Expr));
V : Iir_Value_Literal_Acc;
begin
Result := Execute_Low_Limit (Execute_Bounds (Block, El_St));
for I in Left.Val_Array.V'Range loop
V := Left.Val_Array.V (I);
if Compare_Value (V, Result) = Greater then
Result := V;
end if;
end loop;
end;
when Iir_Predefined_Vector_Minimum =>
declare
El_St : constant Iir :=
Get_Return_Type (Get_Implementation (Expr));
V : Iir_Value_Literal_Acc;
begin
Result := Execute_High_Limit (Execute_Bounds (Block, El_St));
for I in Left.Val_Array.V'Range loop
V := Left.Val_Array.V (I);
if Compare_Value (V, Result) = Less then
Result := V;
end if;
end loop;
end;
when Iir_Predefined_Endfile =>
Result := Boolean_To_Lit (File_Operation.Endfile (Left, Null_Iir));
when Iir_Predefined_Now_Function =>
Result := Create_I64_Value (Ghdl_I64 (Grt.Types.Current_Time));
when Iir_Predefined_Integer_To_String
| Iir_Predefined_Floating_To_String
| Iir_Predefined_Physical_To_String =>
Result := String_To_Iir_Value
(Execute_Image_Attribute (Left, Get_Type (Left_Param)));
when Iir_Predefined_Enum_To_String =>
declare
use Name_Table;
Base_Type : constant Iir :=
Get_Base_Type (Get_Type (Left_Param));
Lits : constant Iir_List :=
Get_Enumeration_Literal_List (Base_Type);
Pos : constant Natural := Get_Enum_Pos (Left);
Id : Name_Id;
begin
if Base_Type = Std_Package.Character_Type_Definition then
Result := String_To_Iir_Value ((1 => Character'Val (Pos)));
else
Id := Get_Identifier (Get_Nth_Element (Lits, Pos));
if Is_Character (Id) then
Result := String_To_Iir_Value ((1 => Get_Character (Id)));
else
Result := String_To_Iir_Value (Image (Id));
end if;
end if;
end;
when Iir_Predefined_Array_Char_To_String =>
declare
Str : String (1 .. Natural (Left.Bounds.D (1).Length));
Lits : constant Iir_List :=
Get_Enumeration_Literal_List
(Get_Base_Type
(Get_Element_Subtype (Get_Type (Left_Param))));
Pos : Natural;
begin
for I in Left.Val_Array.V'Range loop
Pos := Get_Enum_Pos (Left.Val_Array.V (I));
Str (Positive (I)) := Name_Table.Get_Character
(Get_Identifier (Get_Nth_Element (Lits, Pos)));
end loop;
Result := String_To_Iir_Value (Str);
end;
when Iir_Predefined_Bit_Vector_To_Hstring =>
return Execute_Bit_Vector_To_String (Left, 4);
when Iir_Predefined_Bit_Vector_To_Ostring =>
return Execute_Bit_Vector_To_String (Left, 3);
when Iir_Predefined_Real_To_String_Digits =>
Eval_Right;
declare
Str : Grt.Vstrings.String_Real_Digits;
Last : Natural;
begin
Grt.Vstrings.To_String
(Str, Last, Left.F64, Ghdl_I32 (Right.I64));
Result := String_To_Iir_Value (Str (1 .. Last));
end;
when Iir_Predefined_Real_To_String_Format =>
Eval_Right;
declare
Format : String (1 .. Natural (Right.Val_Array.Len) + 1);
Str : Grt.Vstrings.String_Real_Format;
Last : Natural;
begin
for I in Right.Val_Array.V'Range loop
Format (Positive (I)) :=
Character'Val (Right.Val_Array.V (I).E32);
end loop;
Format (Format'Last) := ASCII.NUL;
Grt.Vstrings.To_String
(Str, Last, Left.F64, To_Ghdl_C_String (Format'Address));
Result := String_To_Iir_Value (Str (1 .. Last));
end;
when Iir_Predefined_Time_To_String_Unit =>
Eval_Right;
declare
Str : Grt.Vstrings.String_Time_Unit;
First : Natural;
Unit : Iir;
begin
Unit := Get_Unit_Chain (Std_Package.Time_Type_Definition);
while Unit /= Null_Iir loop
exit when Evaluation.Get_Physical_Value (Unit)
= Iir_Int64 (Right.I64);
Unit := Get_Chain (Unit);
end loop;
if Unit = Null_Iir then
Error_Msg_Exec
("to_string for time called with wrong unit", Expr);
end if;
Grt.Vstrings.To_String (Str, First, Left.I64, Right.I64);
Result := String_To_Iir_Value
(Str (First .. Str'Last) & ' '
& Name_Table.Image (Get_Identifier (Unit)));
end;
when Iir_Predefined_Std_Ulogic_Match_Equality =>
Eval_Right;
declare
use Grt.Std_Logic_1164;
begin
Result := Create_E32_Value
(Std_Ulogic'Pos
(Match_Eq_Table (Std_Ulogic'Val (Left.E32),
Std_Ulogic'Val (Right.E32))));
end;
when Iir_Predefined_Std_Ulogic_Match_Inequality =>
Eval_Right;
declare
use Grt.Std_Logic_1164;
begin
Result := Create_E32_Value
(Std_Ulogic'Pos
(Not_Table (Match_Eq_Table (Std_Ulogic'Val (Left.E32),
Std_Ulogic'Val (Right.E32)))));
end;
when Iir_Predefined_Std_Ulogic_Match_Ordering_Functions =>
Eval_Right;
declare
use Grt.Std_Logic_1164;
L : constant Std_Ulogic := Std_Ulogic'Val (Left.E32);
R : constant Std_Ulogic := Std_Ulogic'Val (Right.E32);
Res : Std_Ulogic;
begin
Check_Std_Ulogic_Dc (Expr, L);
Check_Std_Ulogic_Dc (Expr, R);
case Iir_Predefined_Std_Ulogic_Match_Ordering_Functions (Func)
is
when Iir_Predefined_Std_Ulogic_Match_Less =>
Res := Match_Lt_Table (L, R);
when Iir_Predefined_Std_Ulogic_Match_Less_Equal =>
Res := Or_Table (Match_Lt_Table (L, R),
Match_Eq_Table (L, R));
when Iir_Predefined_Std_Ulogic_Match_Greater =>
Res := Not_Table (Or_Table (Match_Lt_Table (L, R),
Match_Eq_Table (L, R)));
when Iir_Predefined_Std_Ulogic_Match_Greater_Equal =>
Res := Not_Table (Match_Lt_Table (L, R));
end case;
Result := Create_E32_Value (Std_Ulogic'Pos (Res));
end;
when Iir_Predefined_Std_Ulogic_Array_Match_Equality
| Iir_Predefined_Std_Ulogic_Array_Match_Inequality =>
Eval_Right;
if Left.Bounds.D (1).Length /= Right.Bounds.D (1).Length then
Error_Msg_Constraint (Expr);
end if;
declare
use Grt.Std_Logic_1164;
Res : Std_Ulogic := '1';
begin
Result := Create_E32_Value (Std_Ulogic'Pos ('1'));
for I in Left.Val_Array.V'Range loop
Res := And_Table
(Res,
Match_Eq_Table
(Std_Ulogic'Val (Left.Val_Array.V (I).E32),
Std_Ulogic'Val (Right.Val_Array.V (I).E32)));
end loop;
if Func = Iir_Predefined_Std_Ulogic_Array_Match_Inequality then
Res := Not_Table (Res);
end if;
Result := Create_E32_Value (Std_Ulogic'Pos (Res));
end;
when others =>
Error_Msg_Elab ("execute_implicit_function: unimplemented " &
Iir_Predefined_Functions'Image (Func), Expr);
raise Internal_Error;
end case;
return Result;
exception
when Constraint_Error =>
Error_Msg_Constraint (Expr);
end Execute_Implicit_Function;
procedure Execute_Implicit_Procedure
(Block: Block_Instance_Acc; Stmt: Iir_Procedure_Call)
is
Imp : constant Iir := Get_Implementation (Stmt);
Assoc_Chain : constant Iir := Get_Parameter_Association_Chain (Stmt);
Assoc: Iir;
Args: Iir_Value_Literal_Array (0 .. 3);
Inter_Chain : Iir;
Expr_Mark : Mark_Type;
begin
Mark (Expr_Mark, Expr_Pool);
Assoc := Assoc_Chain;
for I in Iir_Index32 loop
exit when Assoc = Null_Iir;
Args (I) := Execute_Expression (Block, Get_Actual (Assoc));
Assoc := Get_Chain (Assoc);
end loop;
Inter_Chain := Get_Interface_Declaration_Chain (Imp);
case Get_Implicit_Definition (Imp) is
when Iir_Predefined_Deallocate =>
if Args (0).Val_Access /= null then
Free_Heap_Value (Args (0));
Args (0).Val_Access := null;
end if;
when Iir_Predefined_File_Open =>
File_Operation.File_Open
(Args (0), Args (1), Args (2), Inter_Chain, Stmt);
when Iir_Predefined_File_Open_Status =>
File_Operation.File_Open_Status
(Args (0), Args (1), Args (2), Args (3),
Get_Chain (Inter_Chain), Stmt);
when Iir_Predefined_Write =>
if Get_Text_File_Flag (Get_Type (Inter_Chain)) then
File_Operation.Write_Text (Args (0), Args (1));
else
File_Operation.Write_Binary (Args (0), Args (1));
end if;
when Iir_Predefined_Read_Length =>
if Get_Text_File_Flag (Get_Type (Inter_Chain)) then
File_Operation.Read_Length_Text
(Args (0), Args (1), Args (2));
else
File_Operation.Read_Length_Binary
(Args (0), Args (1), Args (2));
end if;
when Iir_Predefined_Read =>
File_Operation.Read_Binary (Args (0), Args (1));
when Iir_Predefined_Flush =>
File_Operation.Flush (Args (0));
when Iir_Predefined_File_Close =>
if Get_Text_File_Flag (Get_Type (Inter_Chain)) then
File_Operation.File_Close_Text (Args (0), Stmt);
else
File_Operation.File_Close_Binary (Args (0), Stmt);
end if;
when others =>
Error_Kind ("execute_implicit_procedure",
Get_Implicit_Definition (Imp));
end case;
Release (Expr_Mark, Expr_Pool);
end Execute_Implicit_Procedure;
procedure Execute_Foreign_Procedure
(Block: Block_Instance_Acc; Stmt: Iir_Procedure_Call)
is
Imp : constant Iir := Get_Implementation (Stmt);
Assoc_Chain : constant Iir := Get_Parameter_Association_Chain (Stmt);
Assoc: Iir;
Args: Iir_Value_Literal_Array (0 .. 3) := (others => null);
Expr_Mark : Mark_Type;
begin
Mark (Expr_Mark, Expr_Pool);
Assoc := Assoc_Chain;
for I in Args'Range loop
exit when Assoc = Null_Iir;
Args (I) := Execute_Expression (Block, Get_Actual (Assoc));
Assoc := Get_Chain (Assoc);
end loop;
case Get_Identifier (Imp) is
when Std_Names.Name_Untruncated_Text_Read =>
File_Operation.Untruncated_Text_Read
(Args (0), Args (1), Args (2));
when Std_Names.Name_Control_Simulation =>
Put_Line (Standard_Error, "simulation finished");
raise Simulation_Finished;
when others =>
Error_Msg_Exec ("unsupported foreign procedure call", Stmt);
end case;
Release (Expr_Mark, Expr_Pool);
end Execute_Foreign_Procedure;
-- Compute the offset for INDEX into a range BOUNDS.
-- EXPR is only used in case of error.
function Get_Index_Offset
(Index: Iir_Value_Literal_Acc;
Bounds: Iir_Value_Literal_Acc;
Expr: Iir)
return Iir_Index32
is
Left_Pos, Right_Pos: Iir_Value_Literal_Acc;
begin
Left_Pos := Bounds.Left;
Right_Pos := Bounds.Right;
if Index.Kind /= Left_Pos.Kind or else Index.Kind /= Right_Pos.Kind then
raise Internal_Error;
end if;
case Index.Kind is
when Iir_Value_B1 =>
case Bounds.Dir is
when Iir_To =>
if Index.B1 >= Left_Pos.B1 and then
Index.B1 <= Right_Pos.B1
then
-- to
return Ghdl_B1'Pos (Index.B1) - Ghdl_B1'Pos (Left_Pos.B1);
end if;
when Iir_Downto =>
if Index.B1 <= Left_Pos.B1 and then
Index.B1 >= Right_Pos.B1
then
-- downto
return Ghdl_B1'Pos (Left_Pos.B1) - Ghdl_B1'Pos (Index.B1);
end if;
end case;
when Iir_Value_E32 =>
case Bounds.Dir is
when Iir_To =>
if Index.E32 >= Left_Pos.E32 and then
Index.E32 <= Right_Pos.E32
then
-- to
return Iir_Index32 (Index.E32 - Left_Pos.E32);
end if;
when Iir_Downto =>
if Index.E32 <= Left_Pos.E32 and then
Index.E32 >= Right_Pos.E32
then
-- downto
return Iir_Index32 (Left_Pos.E32 - Index.E32);
end if;
end case;
when Iir_Value_I64 =>
case Bounds.Dir is
when Iir_To =>
if Index.I64 >= Left_Pos.I64 and then
Index.I64 <= Right_Pos.I64
then
-- to
return Iir_Index32 (Index.I64 - Left_Pos.I64);
end if;
when Iir_Downto =>
if Index.I64 <= Left_Pos.I64 and then
Index.I64 >= Right_Pos.I64
then
-- downto
return Iir_Index32 (Left_Pos.I64 - Index.I64);
end if;
end case;
when others =>
raise Internal_Error;
end case;
Error_Msg_Constraint (Expr);
return 0;
end Get_Index_Offset;
-- Create an iir_value_literal of kind iir_value_array and of life LIFE.
-- Allocate the array of bounds, and fill it from A_TYPE.
-- Allocate the array of values.
function Create_Array_Bounds_From_Type
(Block : Block_Instance_Acc;
A_Type : Iir;
Create_Val_Array : Boolean)
return Iir_Value_Literal_Acc
is
Res : Iir_Value_Literal_Acc;
Index_List : Iir_List;
Len : Iir_Index32;
Bound : Iir_Value_Literal_Acc;
begin
-- Only for constrained subtypes.
if Get_Kind (A_Type) = Iir_Kind_Array_Type_Definition then
raise Internal_Error;
end if;
Index_List := Get_Index_Subtype_List (A_Type);
Res := Create_Array_Value
(Iir_Index32 (Get_Nbr_Elements (Index_List)));
Len := 1;
for I in 1 .. Res.Bounds.Nbr_Dims loop
Bound := Execute_Bounds
(Block, Get_Nth_Element (Index_List, Natural (I - 1)));
Len := Len * Bound.Length;
Res.Bounds.D (I) := Bound;
end loop;
if Create_Val_Array then
Create_Array_Data (Res, Len);
end if;
return Res;
end Create_Array_Bounds_From_Type;
-- Return the steps (ie, offset in the array when index DIM is increased
-- by one) for array ARR and dimension DIM.
function Get_Step_For_Dim (Arr: Iir_Value_Literal_Acc; Dim : Natural)
return Iir_Index32
is
Bounds : Value_Bounds_Array_Acc renames Arr.Bounds;
Res : Iir_Index32;
begin
Res := 1;
for I in Iir_Index32 (Dim + 1) .. Bounds.Nbr_Dims loop
Res := Res * Bounds.D (I).Length;
end loop;
return Res;
end Get_Step_For_Dim;
-- Create a literal for a string or a bit_string
function String_To_Enumeration_Array_1 (Str: Iir; El_Type : Iir)
return Iir_Value_Literal_Acc
is
pragma Assert (Get_Kind (Str) = Iir_Kind_String_Literal8);
Id : constant String8_Id := Get_String8_Id (Str);
Len : constant Iir_Index32 := Iir_Index32 (Get_String_Length (Str));
El_Btype : constant Iir := Get_Base_Type (El_Type);
Lit: Iir_Value_Literal_Acc;
El : Iir_Value_Literal_Acc;
Element_Mode : Iir_Value_Scalars;
Pos : Nat8;
begin
Element_Mode := Get_Info (El_Btype).Scalar_Mode;
Lit := Create_Array_Value (Len, 1);
for I in Lit.Val_Array.V'Range loop
-- FIXME: use literal from type ??
Pos := Str_Table.Element_String8 (Id, Pos32 (I));
case Element_Mode is
when Iir_Value_B1 =>
El := Create_B1_Value (Ghdl_B1'Val (Pos));
when Iir_Value_E32 =>
El := Create_E32_Value (Ghdl_E32'Val (Pos));
when others =>
raise Internal_Error;
end case;
Lit.Val_Array.V (I) := El;
end loop;
return Lit;
end String_To_Enumeration_Array_1;
-- Create a literal for a string or a bit_string
function String_To_Enumeration_Array (Block: Block_Instance_Acc; Str: Iir)
return Iir_Value_Literal_Acc
is
Res : Iir_Value_Literal_Acc;
Array_Type: constant Iir := Get_Type (Str);
Index_Types : constant Iir_List := Get_Index_Subtype_List (Array_Type);
begin
-- Array must be unidimensional.
pragma Assert (Get_Nbr_Elements (Index_Types) = 1);
Res := String_To_Enumeration_Array_1
(Str, Get_Element_Subtype (Array_Type));
-- When created from static evaluation, a string may still have an
-- unconstrained type.
if Get_Constraint_State (Array_Type) /= Fully_Constrained then
Res.Bounds.D (1) :=
Create_Range_Value (Create_I64_Value (1),
Create_I64_Value (Ghdl_I64 (Res.Val_Array.Len)),
Iir_To,
Res.Val_Array.Len);
else
Res.Bounds.D (1) :=
Execute_Bounds (Block, Get_First_Element (Index_Types));
end if;
-- The range may not be statically constant.
if Res.Bounds.D (1).Length /= Res.Val_Array.Len then
Error_Msg_Constraint (Str);
end if;
return Res;
end String_To_Enumeration_Array;
-- Fill LENGTH elements of RES, starting at ORIG by steps of STEP.
-- Use expressions from (BLOCK, AGGREGATE) to fill the elements.
-- EL_TYPE is the type of the array element.
procedure Fill_Array_Aggregate_1
(Block : Block_Instance_Acc;
Aggregate : Iir;
Res : Iir_Value_Literal_Acc;
Orig : Iir_Index32;
Step : Iir_Index32;
Dim : Iir_Index32;
Nbr_Dim : Iir_Index32;
El_Type : Iir)
is
Value : Iir;
Bound : constant Iir_Value_Literal_Acc := Res.Bounds.D (Dim);
procedure Set_Elem (Pos : Iir_Index32)
is
Val : Iir_Value_Literal_Acc;
begin
if Dim = Nbr_Dim then
-- VALUE is an expression (which may be an aggregate, but not
-- a sub-aggregate.
Val := Execute_Expression_With_Type (Block, Value, El_Type);
-- LRM93 7.3.2.2
-- For a multi-dimensional aggregate of dimension n, a check
-- is made that all (n-1)-dimensional subaggregates have the
-- same bounds.
-- GHDL: I have added an implicit array conversion, however
-- it may be useful to allow cases like this:
-- type str_array is array (natural range <>)
-- of string (10 downto 1);
-- constant floats : str_array :=
-- ( "00000000.0", HT & "+1.5ABCDE");
-- The subtype of the first sub-aggregate (0.0) is
-- determinated by the context, according to rule 9 and 4
-- of LRM93 7.3.2.2 and therefore is string (10 downto 1),
-- while the subtype of the second sub-aggregate (HT & ...)
-- is determinated by rules 1 and 2 of LRM 7.2.4, and is
-- string (1 to 10).
-- Unless an implicit conversion is used, according to the
-- LRM, this should fail, but it makes no sens.
--
-- FIXME: Add a warning, a flag ?
--Implicit_Array_Conversion (Block, Val, El_Type, Value);
--Check_Constraints (Block, Val, El_Type, Value);
Res.Val_Array.V (1 + Orig + Pos * Step) := Val;
else
case Get_Kind (Value) is
when Iir_Kind_Aggregate =>
-- VALUE is a sub-aggregate.
Fill_Array_Aggregate_1 (Block, Value, Res,
Orig + Pos * Step,
Step / Res.Bounds.D (Dim + 1).Length,
Dim + 1, Nbr_Dim, El_Type);
when Iir_Kind_String_Literal8 =>
pragma Assert (Dim + 1 = Nbr_Dim);
Val := String_To_Enumeration_Array_1 (Value, El_Type);
if Val.Val_Array.Len /= Res.Bounds.D (Nbr_Dim).Length then
Error_Msg_Constraint (Value);
end if;
for I in Val.Val_Array.V'Range loop
Res.Val_Array.V (Orig + Pos * Step + I) :=
Val.Val_Array.V (I);
end loop;
when others =>
Error_Kind ("fill_array_aggregate_1", Value);
end case;
end if;
end Set_Elem;
procedure Set_Elem_By_Expr (Expr : Iir)
is
Expr_Pos: Iir_Value_Literal_Acc;
begin
Expr_Pos := Execute_Expression (Block, Expr);
Set_Elem (Get_Index_Offset (Expr_Pos, Bound, Expr));
end Set_Elem_By_Expr;
procedure Set_Elem_By_Range (Expr : Iir)
is
A_Range : Iir_Value_Literal_Acc;
High, Low : Iir_Value_Literal_Acc;
begin
A_Range := Execute_Bounds (Block, Expr);
if Is_Null_Range (A_Range) then
return;
end if;
if A_Range.Dir = Iir_To then
High := A_Range.Right;
Low := A_Range.Left;
else
High := A_Range.Left;
Low := A_Range.Right;
end if;
-- Locally modified (incremented)
Low := Unshare (Low, Expr_Pool'Access);
loop
Set_Elem (Get_Index_Offset (Low, Bound, Expr));
exit when Is_Equal (Low, High);
Increment (Low);
end loop;
end Set_Elem_By_Range;
Length : constant Iir_Index32 := Bound.Length;
Assoc : Iir;
Pos : Iir_Index32;
begin
Assoc := Get_Association_Choices_Chain (Aggregate);
Pos := 0;
while Assoc /= Null_Iir loop
Value := Get_Associated_Expr (Assoc);
loop
case Get_Kind (Assoc) is
when Iir_Kind_Choice_By_None =>
if Pos >= Length then
Error_Msg_Constraint (Assoc);
end if;
Set_Elem (Pos);
Pos := Pos + 1;
when Iir_Kind_Choice_By_Expression =>
Set_Elem_By_Expr (Get_Choice_Expression (Assoc));
when Iir_Kind_Choice_By_Range =>
Set_Elem_By_Range (Get_Choice_Range (Assoc));
when Iir_Kind_Choice_By_Others =>
for J in 1 .. Length loop
if Res.Val_Array.V (Orig + J * Step) = null then
Set_Elem (J - 1);
end if;
end loop;
return;
when others =>
raise Internal_Error;
end case;
Assoc := Get_Chain (Assoc);
exit when Assoc = Null_Iir;
exit when not Get_Same_Alternative_Flag (Assoc);
end loop;
end loop;
-- Check each elements have been set.
-- FIXME: check directly with type.
for J in 1 .. Length loop
if Res.Val_Array.V (Orig + J * Step) = null then
Error_Msg_Constraint (Aggregate);
end if;
end loop;
end Fill_Array_Aggregate_1;
-- Use expressions from (BLOCK, AGGREGATE) to fill RES.
procedure Fill_Array_Aggregate
(Block : Block_Instance_Acc;
Aggregate : Iir;
Res : Iir_Value_Literal_Acc)
is
Aggr_Type : constant Iir := Get_Type (Aggregate);
El_Type : constant Iir := Get_Element_Subtype (Aggr_Type);
Index_List : constant Iir_List := Get_Index_Subtype_List (Aggr_Type);
Nbr_Dim : constant Iir_Index32 :=
Iir_Index32 (Get_Nbr_Elements (Index_List));
Step : Iir_Index32;
begin
Step := Get_Step_For_Dim (Res, 1);
Fill_Array_Aggregate_1
(Block, Aggregate, Res, 0, Step, 1, Nbr_Dim, El_Type);
end Fill_Array_Aggregate;
function Execute_Record_Aggregate (Block: Block_Instance_Acc;
Aggregate: Iir;
Aggregate_Type: Iir)
return Iir_Value_Literal_Acc
is
List : constant Iir_List :=
Get_Elements_Declaration_List (Get_Base_Type (Aggregate_Type));
Res: Iir_Value_Literal_Acc;
Expr : Iir;
procedure Set_Expr (Pos : Iir_Index32) is
El : constant Iir := Get_Nth_Element (List, Natural (Pos - 1));
begin
Res.Val_Record.V (Pos) :=
Execute_Expression_With_Type (Block, Expr, Get_Type (El));
end Set_Expr;
Pos : Iir_Index32;
Assoc: Iir;
N_Expr : Iir;
begin
Res := Create_Record_Value (Iir_Index32 (Get_Nbr_Elements (List)));
Assoc := Get_Association_Choices_Chain (Aggregate);
Pos := 1;
loop
N_Expr := Get_Associated_Expr (Assoc);
if N_Expr /= Null_Iir then
Expr := N_Expr;
end if;
case Get_Kind (Assoc) is
when Iir_Kind_Choice_By_None =>
Set_Expr (Pos);
Pos := Pos + 1;
when Iir_Kind_Choice_By_Name =>
Set_Expr (1 + Get_Element_Position (Get_Choice_Name (Assoc)));
when Iir_Kind_Choice_By_Others =>
for I in Res.Val_Record.V'Range loop
if Res.Val_Record.V (I) = null then
Set_Expr (I);
end if;
end loop;
when others =>
Error_Kind ("execute_record_aggregate", Assoc);
end case;
Assoc := Get_Chain (Assoc);
exit when Assoc = Null_Iir;
end loop;
return Res;
end Execute_Record_Aggregate;
function Execute_Aggregate
(Block: Block_Instance_Acc;
Aggregate: Iir;
Aggregate_Type: Iir)
return Iir_Value_Literal_Acc
is
begin
case Get_Kind (Aggregate_Type) is
when Iir_Kind_Array_Type_Definition
| Iir_Kind_Array_Subtype_Definition =>
declare
Res : Iir_Value_Literal_Acc;
begin
Res := Create_Array_Bounds_From_Type
(Block, Aggregate_Type, True);
Fill_Array_Aggregate (Block, Aggregate, Res);
return Res;
end;
when Iir_Kind_Record_Type_Definition
| Iir_Kind_Record_Subtype_Definition =>
return Execute_Record_Aggregate
(Block, Aggregate, Aggregate_Type);
when others =>
Error_Kind ("execute_aggregate", Aggregate_Type);
end case;
end Execute_Aggregate;
function Execute_Simple_Aggregate (Block: Block_Instance_Acc; Aggr : Iir)
return Iir_Value_Literal_Acc
is
Res : Iir_Value_Literal_Acc;
List : constant Iir_List := Get_Simple_Aggregate_List (Aggr);
begin
Res := Create_Array_Bounds_From_Type (Block, Get_Type (Aggr), True);
for I in Res.Val_Array.V'Range loop
Res.Val_Array.V (I) :=
Execute_Expression (Block, Get_Nth_Element (List, Natural (I - 1)));
end loop;
return Res;
end Execute_Simple_Aggregate;
-- Fill LENGTH elements of RES, starting at ORIG by steps of STEP.
-- Use expressions from (BLOCK, AGGREGATE) to fill the elements.
-- EL_TYPE is the type of the array element.
procedure Execute_Name_Array_Aggregate
(Block : Block_Instance_Acc;
Aggregate : Iir;
Res : Iir_Value_Literal_Acc;
Orig : Iir_Index32;
Step : Iir_Index32;
Dim : Iir_Index32;
Nbr_Dim : Iir_Index32;
El_Type : Iir)
is
Value : Iir;
Bound : Iir_Value_Literal_Acc;
procedure Set_Elem (Pos : Iir_Index32)
is
Val : Iir_Value_Literal_Acc;
Is_Sig : Boolean;
begin
if Dim = Nbr_Dim then
-- VALUE is an expression (which may be an aggregate, but not
-- a sub-aggregate.
Execute_Name_With_Base (Block, Value, null, Val, Is_Sig);
Res.Val_Array.V (1 + Orig + Pos * Step) := Val;
else
-- VALUE is a sub-aggregate.
Execute_Name_Array_Aggregate
(Block, Value, Res,
Orig + Pos * Step,
Step / Res.Bounds.D (Dim + 1).Length,
Dim + 1, Nbr_Dim, El_Type);
end if;
end Set_Elem;
Assoc : Iir;
Pos : Iir_Index32;
begin
Assoc := Get_Association_Choices_Chain (Aggregate);
Bound := Res.Bounds.D (Dim);
Pos := 0;
while Assoc /= Null_Iir loop
Value := Get_Associated_Expr (Assoc);
case Get_Kind (Assoc) is
when Iir_Kind_Choice_By_None =>
null;
when Iir_Kind_Choice_By_Expression =>
declare
Expr_Pos: Iir_Value_Literal_Acc;
Val : constant Iir := Get_Expression (Assoc);
begin
Expr_Pos := Execute_Expression (Block, Val);
Pos := Get_Index_Offset (Expr_Pos, Bound, Val);
end;
when others =>
raise Internal_Error;
end case;
Set_Elem (Pos);
Pos := Pos + 1;
Assoc := Get_Chain (Assoc);
end loop;
end Execute_Name_Array_Aggregate;
function Execute_Record_Name_Aggregate
(Block: Block_Instance_Acc;
Aggregate: Iir;
Aggregate_Type: Iir)
return Iir_Value_Literal_Acc
is
List : constant Iir_List :=
Get_Elements_Declaration_List (Get_Base_Type (Aggregate_Type));
Res: Iir_Value_Literal_Acc;
Expr : Iir;
Pos : Iir_Index32;
El_Pos : Iir_Index32;
Is_Sig : Boolean;
Assoc: Iir;
begin
Res := Create_Record_Value (Iir_Index32 (Get_Nbr_Elements (List)));
Assoc := Get_Association_Choices_Chain (Aggregate);
Pos := 0;
loop
Expr := Get_Associated_Expr (Assoc);
if Expr = Null_Iir then
-- List of choices is not allowed.
raise Internal_Error;
end if;
case Get_Kind (Assoc) is
when Iir_Kind_Choice_By_None =>
El_Pos := Pos;
Pos := Pos + 1;
when Iir_Kind_Choice_By_Name =>
El_Pos := Get_Element_Position (Get_Name (Assoc));
when Iir_Kind_Choice_By_Others =>
raise Internal_Error;
when others =>
Error_Kind ("execute_record_name_aggregate", Assoc);
end case;
Execute_Name_With_Base
(Block, Expr, null, Res.Val_Record.V (1 + El_Pos), Is_Sig);
Assoc := Get_Chain (Assoc);
exit when Assoc = Null_Iir;
end loop;
return Res;
end Execute_Record_Name_Aggregate;
function Execute_Name_Aggregate
(Block: Block_Instance_Acc;
Aggregate: Iir;
Aggregate_Type: Iir)
return Iir_Value_Literal_Acc
is
begin
case Get_Kind (Aggregate_Type) is
when Iir_Kind_Array_Type_Definition
| Iir_Kind_Array_Subtype_Definition =>
declare
Res : Iir_Value_Literal_Acc;
El_Type : constant Iir := Get_Element_Subtype (Aggregate_Type);
Index_List : constant Iir_List :=
Get_Index_Subtype_List (Aggregate_Type);
Nbr_Dim : constant Iir_Index32 :=
Iir_Index32 (Get_Nbr_Elements (Index_List));
Step : Iir_Index32;
begin
Res := Create_Array_Bounds_From_Type
(Block, Aggregate_Type, True);
Step := Get_Step_For_Dim (Res, 1);
Execute_Name_Array_Aggregate
(Block, Aggregate, Res, 0, Step, 1, Nbr_Dim, El_Type);
return Res;
end;
when Iir_Kind_Record_Type_Definition
| Iir_Kind_Record_Subtype_Definition =>
return Execute_Record_Name_Aggregate
(Block, Aggregate, Aggregate_Type);
when others =>
Error_Kind ("execute_name_aggregate", Aggregate_Type);
end case;
end Execute_Name_Aggregate;
-- Return the indexes range of dimension DIM for type or object PREFIX.
-- DIM starts at 1.
function Execute_Indexes
(Block: Block_Instance_Acc; Prefix: Iir; Dim : Iir_Int64)
return Iir_Value_Literal_Acc
is
begin
case Get_Kind (Prefix) is
when Iir_Kind_Type_Declaration
| Iir_Kind_Subtype_Declaration =>
declare
Index : Iir;
begin
Index := Get_Nth_Element
(Get_Index_Subtype_List (Get_Type (Prefix)),
Natural (Dim - 1));
return Execute_Bounds (Block, Index);
end;
when Iir_Kinds_Denoting_Name =>
return Execute_Indexes (Block, Get_Named_Entity (Prefix), Dim);
when Iir_Kind_Array_Type_Definition
| Iir_Kind_Array_Subtype_Definition =>
Error_Kind ("execute_indexes", Prefix);
when others =>
declare
Orig : Iir_Value_Literal_Acc;
begin
Orig := Execute_Name (Block, Prefix, True);
return Orig.Bounds.D (Iir_Index32 (Dim));
end;
end case;
end Execute_Indexes;
function Execute_Bounds (Block: Block_Instance_Acc; Prefix: Iir)
return Iir_Value_Literal_Acc
is
Bound : Iir_Value_Literal_Acc;
begin
case Get_Kind (Prefix) is
when Iir_Kind_Range_Expression =>
declare
Info : constant Sim_Info_Acc := Get_Info (Prefix);
begin
if Info = null then
Bound := Create_Range_Value
(Execute_Expression (Block, Get_Left_Limit (Prefix)),
Execute_Expression (Block, Get_Right_Limit (Prefix)),
Get_Direction (Prefix));
elsif Info.Kind = Kind_Object then
Bound := Get_Instance_For_Slot
(Block, Prefix).Objects (Info.Slot);
else
raise Internal_Error;
end if;
end;
when Iir_Kind_Subtype_Declaration =>
return Execute_Bounds (Block, Get_Type (Prefix));
when Iir_Kind_Integer_Subtype_Definition
| Iir_Kind_Floating_Subtype_Definition
| Iir_Kind_Enumeration_Subtype_Definition
| Iir_Kind_Enumeration_Type_Definition
| Iir_Kind_Physical_Subtype_Definition =>
-- FIXME: move this block before and avoid recursion.
return Execute_Bounds (Block, Get_Range_Constraint (Prefix));
when Iir_Kind_Range_Array_Attribute =>
declare
Prefix_Val : Iir_Value_Literal_Acc;
Dim : Iir_Int64;
begin
Dim := Get_Value (Get_Parameter (Prefix));
Prefix_Val := Execute_Indexes (Block, Get_Prefix (Prefix), Dim);
Bound := Prefix_Val;
end;
when Iir_Kind_Reverse_Range_Array_Attribute =>
declare
Dim : Iir_Int64;
begin
Dim := Get_Value (Get_Parameter (Prefix));
Bound := Execute_Indexes (Block, Get_Prefix (Prefix), Dim);
case Bound.Dir is
when Iir_To =>
Bound := Create_Range_Value
(Bound.Right, Bound.Left, Iir_Downto, Bound.Length);
when Iir_Downto =>
Bound := Create_Range_Value
(Bound.Right, Bound.Left, Iir_To, Bound.Length);
end case;
end;
when Iir_Kind_Floating_Type_Definition
| Iir_Kind_Integer_Type_Definition =>
return Execute_Bounds
(Block,
Get_Range_Constraint (Get_Type (Get_Type_Declarator (Prefix))));
when Iir_Kinds_Denoting_Name =>
return Execute_Bounds (Block, Get_Named_Entity (Prefix));
when others =>
-- Error_Kind ("execute_bounds", Get_Kind (Prefix));
declare
Prefix_Val: Iir_Value_Literal_Acc;
begin
Prefix_Val := Execute_Expression (Block, Prefix);
Bound := Prefix_Val.Bounds.D (1);
end;
end case;
if not Bound.Dir'Valid then
raise Internal_Error;
end if;
return Bound;
end Execute_Bounds;
-- Perform type conversion as desribed in LRM93 7.3.5
function Execute_Type_Conversion (Block: Block_Instance_Acc;
Conv : Iir_Type_Conversion;
Val : Iir_Value_Literal_Acc)
return Iir_Value_Literal_Acc
is
Target_Type : constant Iir := Get_Type (Conv);
Res: Iir_Value_Literal_Acc;
begin
Res := Val;
case Get_Kind (Target_Type) is
when Iir_Kind_Integer_Type_Definition
| Iir_Kind_Integer_Subtype_Definition =>
case Res.Kind is
when Iir_Value_I64 =>
null;
when Iir_Value_F64 =>
if Res.F64 > Ghdl_F64 (Iir_Int64'Last) or
Res.F64 < Ghdl_F64 (Iir_Int64'First)
then
Error_Msg_Constraint (Conv);
end if;
Res := Create_I64_Value (Ghdl_I64 (Res.F64));
when Iir_Value_B1
| Iir_Value_E32
| Iir_Value_Range
| Iir_Value_Array
| Iir_Value_Signal
| Iir_Value_Record
| Iir_Value_Access
| Iir_Value_File
| Iir_Value_Protected
| Iir_Value_Quantity
| Iir_Value_Terminal =>
-- These values are not of abstract numeric type.
raise Internal_Error;
end case;
when Iir_Kind_Floating_Type_Definition
| Iir_Kind_Floating_Subtype_Definition =>
case Res.Kind is
when Iir_Value_F64 =>
null;
when Iir_Value_I64 =>
Res := Create_F64_Value (Ghdl_F64 (Res.I64));
when Iir_Value_B1
| Iir_Value_E32
| Iir_Value_Range
| Iir_Value_Array
| Iir_Value_Signal
| Iir_Value_Record
| Iir_Value_Access
| Iir_Value_File
| Iir_Value_Protected
| Iir_Value_Quantity
| Iir_Value_Terminal =>
-- These values are not of abstract numeric type.
raise Internal_Error;
end case;
when Iir_Kind_Enumeration_Type_Definition
| Iir_Kind_Enumeration_Subtype_Definition =>
-- Must be same type.
null;
when Iir_Kind_Physical_Type_Definition
| Iir_Kind_Physical_Subtype_Definition =>
-- Same type.
null;
when Iir_Kind_Record_Type_Definition
| Iir_Kind_Record_Subtype_Definition =>
-- Same type.
null;
when Iir_Kind_Array_Type_Definition =>
-- LRM93 7.3.5
-- if the type mark denotes an unconstrained array type and the
-- operand is not a null array, then for each index position, the
-- bounds of the result are obtained by converting the bounds of
-- the operand to the corresponding index type of the target type.
-- FIXME: what is bound conversion ??
null;
when Iir_Kind_Array_Subtype_Definition =>
-- LRM93 7.3.5
-- If the type mark denotes a constrained array subtype, then the
-- bounds of the result are those imposed by the type mark.
Implicit_Array_Conversion (Block, Res, Target_Type, Conv);
when others =>
Error_Kind ("execute_type_conversion", Target_Type);
end case;
Check_Constraints (Block, Res, Target_Type, Conv);
return Res;
end Execute_Type_Conversion;
-- Decrement VAL.
-- May raise a constraint error using EXPR.
function Execute_Dec (Val : Iir_Value_Literal_Acc; Expr : Iir)
return Iir_Value_Literal_Acc
is
Res : Iir_Value_Literal_Acc;
begin
case Val.Kind is
when Iir_Value_B1 =>
if Val.B1 = False then
Error_Msg_Constraint (Expr);
end if;
Res := Create_B1_Value (False);
when Iir_Value_E32 =>
if Val.E32 = 0 then
Error_Msg_Constraint (Expr);
end if;
Res := Create_E32_Value (Val.E32 - 1);
when Iir_Value_I64 =>
if Val.I64 = Ghdl_I64'First then
Error_Msg_Constraint (Expr);
end if;
Res := Create_I64_Value (Val.I64 - 1);
when others =>
raise Internal_Error;
end case;
return Res;
end Execute_Dec;
-- Increment VAL.
-- May raise a constraint error using EXPR.
function Execute_Inc (Val : Iir_Value_Literal_Acc; Expr : Iir)
return Iir_Value_Literal_Acc
is
Res : Iir_Value_Literal_Acc;
begin
case Val.Kind is
when Iir_Value_B1 =>
if Val.B1 = True then
Error_Msg_Constraint (Expr);
end if;
Res := Create_B1_Value (True);
when Iir_Value_E32 =>
if Val.E32 = Ghdl_E32'Last then
Error_Msg_Constraint (Expr);
end if;
Res := Create_E32_Value (Val.E32 + 1);
when Iir_Value_I64 =>
if Val.I64 = Ghdl_I64'Last then
Error_Msg_Constraint (Expr);
end if;
Res := Create_I64_Value (Val.I64 + 1);
when others =>
raise Internal_Error;
end case;
return Res;
end Execute_Inc;
function Execute_Expression_With_Type
(Block: Block_Instance_Acc;
Expr: Iir;
Expr_Type : Iir)
return Iir_Value_Literal_Acc
is
Res : Iir_Value_Literal_Acc;
begin
if Get_Kind (Expr) = Iir_Kind_Aggregate
and then not Is_Fully_Constrained_Type (Get_Type (Expr))
then
return Execute_Aggregate (Block, Expr, Expr_Type);
else
Res := Execute_Expression (Block, Expr);
Implicit_Array_Conversion (Block, Res, Expr_Type, Expr);
Check_Constraints (Block, Res, Expr_Type, Expr);
return Res;
end if;
end Execute_Expression_With_Type;
function Execute_Signal_Init_Value (Block : Block_Instance_Acc; Expr : Iir)
return Iir_Value_Literal_Acc
is
Base : constant Iir := Get_Object_Prefix (Expr, False);
Info : constant Sim_Info_Acc := Get_Info (Base);
Bblk : Block_Instance_Acc;
Base_Val : Iir_Value_Literal_Acc;
Res : Iir_Value_Literal_Acc;
Is_Sig : Boolean;
begin
if Get_Kind (Base) = Iir_Kind_Object_Alias_Declaration then
Bblk := Get_Instance_By_Scope (Block, Info.Obj_Scope);
Base_Val := Execute_Signal_Init_Value (Bblk, Get_Name (Base));
else
Bblk := Get_Instance_By_Scope (Block, Info.Obj_Scope);
Base_Val := Bblk.Objects (Info.Slot + 1);
end if;
Execute_Name_With_Base (Block, Expr, Base_Val, Res, Is_Sig);
pragma Assert (Is_Sig);
return Res;
end Execute_Signal_Init_Value;
-- Indexed element will be at Pfx.Val_Array.V (Pos + 1)
procedure Execute_Indexed_Name (Block: Block_Instance_Acc;
Expr: Iir;
Pfx : Iir_Value_Literal_Acc;
Pos : out Iir_Index32)
is
pragma Assert (Get_Kind (Expr) = Iir_Kind_Indexed_Name);
Index_List : constant Iir_List := Get_Index_List (Expr);
Nbr_Dimensions : constant Iir_Index32 :=
Iir_Index32 (Get_Nbr_Elements (Index_List));
Index: Iir;
Value: Iir_Value_Literal_Acc;
Off : Iir_Index32;
begin
for I in 1 .. Nbr_Dimensions loop
Index := Get_Nth_Element (Index_List, Natural (I - 1));
Value := Execute_Expression (Block, Index);
Off := Get_Index_Offset (Value, Pfx.Bounds.D (I), Expr);
if I = 1 then
Pos := Off;
else
Pos := Pos * Pfx.Bounds.D (I).Length + Off;
end if;
end loop;
end Execute_Indexed_Name;
-- Indexed element will be at Pfx.Val_Array.V (Pos)
procedure Execute_Slice_Name (Prefix_Array: Iir_Value_Literal_Acc;
Srange : Iir_Value_Literal_Acc;
Low : out Iir_Index32;
High : out Iir_Index32;
Loc : Iir)
is
Index_Order : Order;
-- Lower and upper bounds of the slice.
begin
pragma Assert (Prefix_Array /= null);
-- LRM93 6.5
-- It is an error if the direction of the discrete range is not
-- the same as that of the index range of the array denoted by
-- the prefix of the slice name.
if Srange.Dir /= Prefix_Array.Bounds.D (1).Dir then
Error_Msg_Exec ("slice direction mismatch", Loc);
end if;
-- LRM93 6.5
-- It is an error if either of the bounds of the
-- discrete range does not belong to the index range of the
-- prefixing array, unless the slice is a null slice.
Index_Order := Compare_Value (Srange.Left, Srange.Right);
if (Srange.Dir = Iir_To and Index_Order = Greater)
or (Srange.Dir = Iir_Downto and Index_Order = Less)
then
-- Null slice.
Low := 1;
High := 0;
else
Low := Get_Index_Offset
(Srange.Left, Prefix_Array.Bounds.D (1), Loc);
High := Get_Index_Offset
(Srange.Right, Prefix_Array.Bounds.D (1), Loc);
end if;
end Execute_Slice_Name;
procedure Execute_Name_With_Base (Block: Block_Instance_Acc;
Expr: Iir;
Base : Iir_Value_Literal_Acc;
Res : out Iir_Value_Literal_Acc;
Is_Sig : out Boolean)
is
Slot_Block: Block_Instance_Acc;
begin
-- Default value
Is_Sig := False;
case Get_Kind (Expr) is
when Iir_Kind_Interface_Signal_Declaration
| Iir_Kind_Signal_Declaration
| Iir_Kind_Guard_Signal_Declaration
| Iir_Kind_Stable_Attribute
| Iir_Kind_Quiet_Attribute
| Iir_Kind_Delayed_Attribute
| Iir_Kind_Transaction_Attribute =>
Is_Sig := True;
if Base /= null then
Res := Base;
else
Slot_Block := Get_Instance_For_Slot (Block, Expr);
Res := Slot_Block.Objects (Get_Info (Expr).Slot);
end if;
when Iir_Kind_Object_Alias_Declaration =>
-- FIXME: add a flag ?
Is_Sig := Is_Signal_Object (Expr);
if Base /= null then
Res := Base;
else
Slot_Block := Get_Instance_For_Slot (Block, Expr);
Res := Slot_Block.Objects (Get_Info (Expr).Slot);
end if;
when Iir_Kind_Interface_Constant_Declaration
| Iir_Kind_Constant_Declaration
| Iir_Kind_Interface_Variable_Declaration
| Iir_Kind_Variable_Declaration
| Iir_Kind_Interface_File_Declaration
| Iir_Kind_File_Declaration
| Iir_Kind_Attribute_Value
| Iir_Kind_Iterator_Declaration
| Iir_Kind_Terminal_Declaration
| Iir_Kinds_Quantity_Declaration =>
if Base /= null then
Res := Base;
else
declare
Info : constant Sim_Info_Acc := Get_Info (Expr);
begin
Slot_Block := Get_Instance_By_Scope (Block, Info.Obj_Scope);
Res := Slot_Block.Objects (Info.Slot);
end;
end if;
when Iir_Kind_Indexed_Name =>
declare
Pfx : Iir_Value_Literal_Acc;
Pos : Iir_Index32;
begin
Execute_Name_With_Base
(Block, Get_Prefix (Expr), Base, Pfx, Is_Sig);
Execute_Indexed_Name (Block, Expr, Pfx, Pos);
Res := Pfx.Val_Array.V (Pos + 1);
end;
when Iir_Kind_Slice_Name =>
declare
Prefix_Array: Iir_Value_Literal_Acc;
Srange : Iir_Value_Literal_Acc;
Low, High: Iir_Index32;
begin
Execute_Name_With_Base
(Block, Get_Prefix (Expr), Base, Prefix_Array, Is_Sig);
Srange := Execute_Bounds (Block, Get_Suffix (Expr));
Execute_Slice_Name (Prefix_Array, Srange, Low, High, Expr);
Res := Create_Array_Value (High - Low + 1, 1);
Res.Bounds.D (1) := Srange;
for I in Low .. High loop
Res.Val_Array.V (1 + I - Low) :=
Prefix_Array.Val_Array.V (1 + I);
end loop;
end;
when Iir_Kind_Selected_Element =>
declare
Prefix: Iir_Value_Literal_Acc;
Pos: Iir_Index32;
begin
Execute_Name_With_Base
(Block, Get_Prefix (Expr), Base, Prefix, Is_Sig);
Pos := Get_Element_Position (Get_Selected_Element (Expr));
Res := Prefix.Val_Record.V (Pos + 1);
end;
when Iir_Kind_Dereference
| Iir_Kind_Implicit_Dereference =>
declare
Prefix: Iir_Value_Literal_Acc;
begin
Prefix := Execute_Name (Block, Get_Prefix (Expr));
Res := Prefix.Val_Access;
if Res = null then
Error_Msg_Exec ("deferencing null access", Expr);
end if;
end;
when Iir_Kinds_Denoting_Name
| Iir_Kind_Attribute_Name =>
Execute_Name_With_Base
(Block, Get_Named_Entity (Expr), Base, Res, Is_Sig);
when Iir_Kind_Function_Call =>
-- A prefix can be an expression
if Base /= null then
raise Internal_Error;
end if;
Res := Execute_Expression (Block, Expr);
when Iir_Kind_Aggregate =>
Res := Execute_Name_Aggregate (Block, Expr, Get_Type (Expr));
-- FIXME: is_sig ?
when others =>
Error_Kind ("execute_name_with_base", Expr);
end case;
end Execute_Name_With_Base;
function Execute_Name (Block: Block_Instance_Acc;
Expr: Iir;
Ref : Boolean := False)
return Iir_Value_Literal_Acc
is
Res: Iir_Value_Literal_Acc;
Is_Sig : Boolean;
begin
Execute_Name_With_Base (Block, Expr, null, Res, Is_Sig);
if not Is_Sig or else Ref then
return Res;
else
return Execute_Signal_Value (Res);
end if;
end Execute_Name;
function Execute_Image_Attribute (Block: Block_Instance_Acc; Expr: Iir)
return Iir_Value_Literal_Acc
is
Val : Iir_Value_Literal_Acc;
Attr_Type : constant Iir := Get_Type (Get_Prefix (Expr));
begin
Val := Execute_Expression (Block, Get_Parameter (Expr));
return String_To_Iir_Value
(Execute_Image_Attribute (Val, Attr_Type));
end Execute_Image_Attribute;
function Execute_Value_Attribute (Block: Block_Instance_Acc;
Str_Val : Iir_Value_Literal_Acc;
Expr: Iir)
return Iir_Value_Literal_Acc
is
use Grt_Interface;
use Name_Table;
pragma Unreferenced (Block);
Expr_Type : constant Iir := Get_Type (Expr);
Res : Iir_Value_Literal_Acc;
Str_Bnd : aliased Std_String_Bound := Build_Bound (Str_Val);
Str_Str : aliased Std_String_Uncons (1 .. Str_Bnd.Dim_1.Length);
Str : aliased Std_String := (To_Std_String_Basep (Str_Str'Address),
To_Std_String_Boundp (Str_Bnd'Address));
begin
Set_Std_String_From_Iir_Value (Str, Str_Val);
case Get_Kind (Expr_Type) is
when Iir_Kind_Integer_Type_Definition
| Iir_Kind_Integer_Subtype_Definition =>
Res := Create_I64_Value
(Grt.Values.Ghdl_Value_I64 (Str'Unrestricted_Access));
when Iir_Kind_Floating_Type_Definition
| Iir_Kind_Floating_Subtype_Definition =>
Res := Create_F64_Value
(Grt.Values.Ghdl_Value_F64 (Str'Unrestricted_Access));
when Iir_Kind_Physical_Type_Definition
| Iir_Kind_Physical_Subtype_Definition =>
declare
Is_Real : Boolean;
Lit_Pos : Ghdl_Index_Type;
Lit_End : Ghdl_Index_Type;
Unit_Pos : Ghdl_Index_Type;
Unit_Len : Ghdl_Index_Type;
Mult : Ghdl_I64;
Unit : Iir;
Unit_Id : Name_Id;
begin
Grt.Values.Ghdl_Value_Physical_Split
(Str'Unrestricted_Access,
Is_Real, Lit_Pos, Lit_End, Unit_Pos);
-- Find unit.
Unit_Len := 0;
Unit_Pos := Unit_Pos + 1; -- From 0 based to 1 based
for I in Unit_Pos .. Str_Bnd.Dim_1.Length loop
exit when Grt.Values.Is_Whitespace (Str_Str (I));
Unit_Len := Unit_Len + 1;
Str_Str (I) := Grt.Values.To_LC (Str_Str (I));
end loop;
Unit := Get_Primary_Unit (Expr_Type);
while Unit /= Null_Iir loop
Unit_Id := Get_Identifier (Unit);
exit when Get_Name_Length (Unit_Id) = Natural (Unit_Len)
and then Image (Unit_Id) =
String (Str_Str (Unit_Pos .. Unit_Pos + Unit_Len - 1));
Unit := Get_Chain (Unit);
end loop;
if Unit = Null_Iir then
Error_Msg_Exec ("incorrect unit name", Expr);
end if;
Mult := Ghdl_I64 (Get_Value (Get_Physical_Unit_Value (Unit)));
Str_Bnd.Dim_1.Length := Lit_End;
if Is_Real then
Res := Create_I64_Value
(Ghdl_I64
(Grt.Values.Ghdl_Value_F64 (Str'Unrestricted_Access)
* Ghdl_F64 (Mult)));
else
Res := Create_I64_Value
(Grt.Values.Ghdl_Value_I64 (Str'Unrestricted_Access)
* Mult);
end if;
end;
when Iir_Kind_Enumeration_Type_Definition
| Iir_Kind_Enumeration_Subtype_Definition =>
declare
Lit_Start : Ghdl_Index_Type;
Lit_End : Ghdl_Index_Type;
Enums : constant Iir_List :=
Get_Enumeration_Literal_List (Get_Base_Type (Expr_Type));
Enum : Iir;
Lit_Id : Name_Id;
Enum_Id : Name_Id;
begin
-- Remove leading and trailing blanks
for I in Str_Str'Range loop
if not Grt.Values.Is_Whitespace (Str_Str (I)) then
Lit_Start := I;
exit;
end if;
end loop;
for I in reverse Lit_Start .. Str_Str'Last loop
if not Grt.Values.Is_Whitespace (Str_Str (I)) then
Lit_End := I;
exit;
end if;
end loop;
if Str_Str (Lit_Start) = '''
and then Str_Str (Lit_End) = '''
and then Lit_End = Lit_Start + 2
then
-- Enumeration literal.
Lit_Id := Get_Identifier (Str_Str (Lit_Start + 1));
for I in Natural loop
Enum := Get_Nth_Element (Enums, I);
exit when Enum = Null_Iir;
exit when Get_Identifier (Enum) = Lit_Id;
end loop;
else
-- Literal identifier.
-- Convert to lower case.
for I in Lit_Start .. Lit_End loop
Str_Str (I) := Grt.Values.To_LC (Str_Str (I));
end loop;
for I in Natural loop
Enum := Get_Nth_Element (Enums, I);
exit when Enum = Null_Iir;
Enum_Id := Get_Identifier (Enum);
exit when (Get_Name_Length (Enum_Id) =
Natural (Lit_End - Lit_Start + 1))
and then (Image (Enum_Id) =
String (Str_Str (Lit_Start .. Lit_End)));
end loop;
end if;
if Enum = Null_Iir then
Error_Msg_Exec
("incorrect enumeration literal for 'value", Expr);
end if;
return Create_Enum_Value
(Natural (Get_Enum_Pos (Enum)), Expr_Type);
end;
when others =>
Error_Kind ("value_attribute", Expr_Type);
end case;
return Res;
end Execute_Value_Attribute;
function Execute_Path_Instance_Name_Attribute
(Block : Block_Instance_Acc; Attr : Iir)
return Iir_Value_Literal_Acc
is
use Evaluation;
use Grt.Vstrings;
use Name_Table;
Name : constant Path_Instance_Name_Type :=
Get_Path_Instance_Name_Suffix (Attr);
Instance : Block_Instance_Acc;
Rstr : Rstring;
Is_Instance : constant Boolean :=
Get_Kind (Attr) = Iir_Kind_Instance_Name_Attribute;
begin
if Name.Path_Instance = Null_Iir then
return String_To_Iir_Value (Name.Suffix);
end if;
Instance := Get_Instance_By_Scope
(Block, Get_Info (Name.Path_Instance).Frame_Scope);
loop
case Get_Kind (Instance.Label) is
when Iir_Kind_Entity_Declaration =>
if Instance.Parent = null then
Prepend (Rstr, Image (Get_Identifier (Instance.Label)));
exit;
end if;
when Iir_Kind_Architecture_Body =>
if Is_Instance then
Prepend (Rstr, ')');
Prepend (Rstr, Image (Get_Identifier (Instance.Label)));
Prepend (Rstr, '(');
end if;
if Is_Instance or else Instance.Parent = null then
Prepend
(Rstr,
Image (Get_Identifier (Get_Entity (Instance.Label))));
end if;
if Instance.Parent = null then
Prepend (Rstr, ':');
exit;
else
Instance := Instance.Parent;
end if;
when Iir_Kind_Block_Statement =>
Prepend (Rstr, Image (Get_Label (Instance.Label)));
Prepend (Rstr, ':');
Instance := Instance.Parent;
when Iir_Kind_Iterator_Declaration =>
declare
Val : Iir_Value_Literal_Acc;
begin
Val := Execute_Name (Instance, Instance.Label);
Prepend (Rstr, ')');
Prepend (Rstr, Execute_Image_Attribute
(Val, Get_Type (Instance.Label)));
Prepend (Rstr, '(');
end;
Instance := Instance.Parent;
when Iir_Kind_Generate_Statement_Body =>
Prepend (Rstr, Image (Get_Label (Get_Parent (Instance.Label))));
Prepend (Rstr, ':');
Instance := Instance.Parent;
when Iir_Kind_Component_Instantiation_Statement =>
if Is_Instance then
Prepend (Rstr, '@');
end if;
Prepend (Rstr, Image (Get_Label (Instance.Label)));
Prepend (Rstr, ':');
Instance := Instance.Parent;
when others =>
Error_Kind ("Execute_Path_Instance_Name_Attribute",
Instance.Label);
end case;
end loop;
declare
Str1 : String (1 .. Length (Rstr));
Len1 : Natural;
begin
Copy (Rstr, Str1, Len1);
Free (Rstr);
return String_To_Iir_Value (Str1 & ':' & Name.Suffix);
end;
end Execute_Path_Instance_Name_Attribute;
-- For 'Last_Event and 'Last_Active: convert the absolute last time to
-- a relative delay.
function To_Relative_Time (T : Ghdl_I64) return Iir_Value_Literal_Acc is
A : Ghdl_I64;
begin
if T = -Ghdl_I64'Last then
A := Ghdl_I64'Last;
else
A := Ghdl_I64 (Grt.Types.Current_Time) - T;
end if;
return Create_I64_Value (A);
end To_Relative_Time;
-- Evaluate an expression.
function Execute_Expression (Block: Block_Instance_Acc; Expr: Iir)
return Iir_Value_Literal_Acc
is
Res: Iir_Value_Literal_Acc;
begin
case Get_Kind (Expr) is
when Iir_Kind_Interface_Signal_Declaration
| Iir_Kind_Signal_Declaration
| Iir_Kind_Guard_Signal_Declaration
| Iir_Kind_Stable_Attribute
| Iir_Kind_Quiet_Attribute
| Iir_Kind_Delayed_Attribute
| Iir_Kind_Transaction_Attribute
| Iir_Kind_Object_Alias_Declaration =>
Res := Execute_Name (Block, Expr);
return Res;
when Iir_Kind_Interface_Constant_Declaration
| Iir_Kind_Constant_Declaration
| Iir_Kind_Interface_Variable_Declaration
| Iir_Kind_Variable_Declaration
| Iir_Kind_Interface_File_Declaration
| Iir_Kind_File_Declaration
| Iir_Kind_Attribute_Value
| Iir_Kind_Iterator_Declaration
| Iir_Kind_Indexed_Name
| Iir_Kind_Slice_Name
| Iir_Kind_Selected_Element
| Iir_Kind_Dereference
| Iir_Kind_Implicit_Dereference =>
return Execute_Name (Block, Expr);
when Iir_Kinds_Denoting_Name
| Iir_Kind_Attribute_Name =>
return Execute_Expression (Block, Get_Named_Entity (Expr));
when Iir_Kind_Aggregate =>
return Execute_Aggregate (Block, Expr, Get_Type (Expr));
when Iir_Kind_Simple_Aggregate =>
return Execute_Simple_Aggregate (Block, Expr);
when Iir_Kinds_Dyadic_Operator
| Iir_Kinds_Monadic_Operator =>
declare
Imp : constant Iir := Get_Implementation (Expr);
begin
if Get_Implicit_Definition (Imp) in Iir_Predefined_Explicit then
return Execute_Function_Call (Block, Expr, Imp);
else
if Get_Kind (Expr) in Iir_Kinds_Dyadic_Operator then
Res := Execute_Implicit_Function
(Block, Expr, Get_Left (Expr), Get_Right (Expr),
Get_Type (Expr));
else
Res := Execute_Implicit_Function
(Block, Expr, Get_Operand (Expr), Null_Iir,
Get_Type (Expr));
end if;
return Res;
end if;
end;
when Iir_Kind_Function_Call =>
declare
Imp : constant Iir := Get_Implementation (Expr);
Assoc : Iir;
Args : Iir_Array (0 .. 1);
begin
if Get_Implicit_Definition (Imp) in Iir_Predefined_Explicit then
return Execute_Function_Call (Block, Expr, Imp);
else
Assoc := Get_Parameter_Association_Chain (Expr);
if Assoc /= Null_Iir then
Args (0) := Get_Actual (Assoc);
Assoc := Get_Chain (Assoc);
else
Args (0) := Null_Iir;
end if;
if Assoc /= Null_Iir then
Args (1) := Get_Actual (Assoc);
else
Args (1) := Null_Iir;
end if;
return Execute_Implicit_Function
(Block, Expr, Args (0), Args (1), Get_Type (Expr));
end if;
end;
when Iir_Kind_Integer_Literal =>
declare
Lit_Type : constant Iir := Get_Base_Type (Get_Type (Expr));
Lit : constant Iir_Int64 := Get_Value (Expr);
begin
case Get_Info (Lit_Type).Scalar_Mode is
when Iir_Value_I64 =>
return Create_I64_Value (Ghdl_I64 (Lit));
when others =>
raise Internal_Error;
end case;
end;
when Iir_Kind_Floating_Point_Literal =>
return Create_F64_Value (Ghdl_F64 (Get_Fp_Value (Expr)));
when Iir_Kind_Enumeration_Literal =>
declare
Lit_Type : constant Iir := Get_Base_Type (Get_Type (Expr));
Lit : constant Iir_Int32 := Get_Enum_Pos (Expr);
begin
case Get_Info (Lit_Type).Scalar_Mode is
when Iir_Value_B1 =>
return Create_B1_Value (Ghdl_B1'Val (Lit));
when Iir_Value_E32 =>
return Create_E32_Value (Ghdl_E32 (Lit));
when others =>
raise Internal_Error;
end case;
end;
when Iir_Kind_Physical_Int_Literal
| Iir_Kind_Physical_Fp_Literal
| Iir_Kind_Unit_Declaration =>
return Create_I64_Value
(Ghdl_I64 (Evaluation.Get_Physical_Value (Expr)));
when Iir_Kind_String_Literal8 =>
return String_To_Enumeration_Array (Block, Expr);
when Iir_Kind_Null_Literal =>
return Null_Lit;
when Iir_Kind_Overflow_Literal =>
Error_Msg_Constraint (Expr);
return null;
when Iir_Kind_Parenthesis_Expression =>
return Execute_Expression (Block, Get_Expression (Expr));
when Iir_Kind_Type_Conversion =>
return Execute_Type_Conversion
(Block, Expr,
Execute_Expression (Block, Get_Expression (Expr)));
when Iir_Kind_Qualified_Expression =>
Res := Execute_Expression_With_Type
(Block, Get_Expression (Expr), Get_Type (Get_Type_Mark (Expr)));
return Res;
when Iir_Kind_Allocator_By_Expression =>
Res := Execute_Expression (Block, Get_Expression (Expr));
Res := Unshare_Heap (Res);
return Create_Access_Value (Res);
when Iir_Kind_Allocator_By_Subtype =>
Res := Create_Value_For_Type
(Block,
Get_Type_Of_Subtype_Indication (Get_Subtype_Indication (Expr)),
Init_Value_Default);
Res := Unshare_Heap (Res);
return Create_Access_Value (Res);
when Iir_Kind_Left_Type_Attribute =>
Res := Execute_Bounds (Block, Get_Prefix (Expr));
return Execute_Left_Limit (Res);
when Iir_Kind_Right_Type_Attribute =>
Res := Execute_Bounds (Block, Get_Prefix (Expr));
return Execute_Right_Limit (Res);
when Iir_Kind_High_Type_Attribute =>
Res := Execute_Bounds (Block, Get_Prefix (Expr));
return Execute_High_Limit (Res);
when Iir_Kind_Low_Type_Attribute =>
Res := Execute_Bounds (Block, Get_Prefix (Expr));
return Execute_Low_Limit (Res);
when Iir_Kind_High_Array_Attribute =>
Res := Execute_Indexes
(Block, Get_Prefix (Expr), Get_Value (Get_Parameter (Expr)));
return Execute_High_Limit (Res);
when Iir_Kind_Low_Array_Attribute =>
Res := Execute_Indexes
(Block, Get_Prefix (Expr), Get_Value (Get_Parameter (Expr)));
return Execute_Low_Limit (Res);
when Iir_Kind_Left_Array_Attribute =>
Res := Execute_Indexes
(Block, Get_Prefix (Expr), Get_Value (Get_Parameter (Expr)));
return Execute_Left_Limit (Res);
when Iir_Kind_Right_Array_Attribute =>
Res := Execute_Indexes
(Block, Get_Prefix (Expr), Get_Value (Get_Parameter (Expr)));
return Execute_Right_Limit (Res);
when Iir_Kind_Length_Array_Attribute =>
Res := Execute_Indexes
(Block, Get_Prefix (Expr), Get_Value (Get_Parameter (Expr)));
return Execute_Length (Res);
when Iir_Kind_Ascending_Array_Attribute =>
Res := Execute_Indexes
(Block, Get_Prefix (Expr), Get_Value (Get_Parameter (Expr)));
return Boolean_To_Lit (Res.Dir = Iir_To);
when Iir_Kind_Event_Attribute =>
Res := Execute_Name (Block, Get_Prefix (Expr), True);
return Boolean_To_Lit (Execute_Event_Attribute (Res));
when Iir_Kind_Active_Attribute =>
Res := Execute_Name (Block, Get_Prefix (Expr), True);
return Boolean_To_Lit (Execute_Active_Attribute (Res));
when Iir_Kind_Driving_Attribute =>
Res := Execute_Name (Block, Get_Prefix (Expr), True);
return Boolean_To_Lit (Execute_Driving_Attribute (Res));
when Iir_Kind_Last_Value_Attribute =>
Res := Execute_Name (Block, Get_Prefix (Expr), True);
return Execute_Last_Value_Attribute (Res);
when Iir_Kind_Driving_Value_Attribute =>
Res := Execute_Name (Block, Get_Prefix (Expr), True);
return Execute_Driving_Value_Attribute (Res);
when Iir_Kind_Last_Event_Attribute =>
Res := Execute_Name (Block, Get_Prefix (Expr), True);
return To_Relative_Time (Execute_Last_Event_Attribute (Res));
when Iir_Kind_Last_Active_Attribute =>
Res := Execute_Name (Block, Get_Prefix (Expr), True);
return To_Relative_Time (Execute_Last_Active_Attribute (Res));
when Iir_Kind_Val_Attribute =>
declare
Prefix_Type: constant Iir := Get_Type (Get_Prefix (Expr));
Base_Type : constant Iir := Get_Base_Type (Prefix_Type);
Mode : constant Iir_Value_Kind :=
Get_Info (Base_Type).Scalar_Mode;
begin
Res := Execute_Expression (Block, Get_Parameter (Expr));
case Mode is
when Iir_Value_I64 =>
null;
when Iir_Value_E32 =>
Res := Create_E32_Value (Ghdl_E32 (Res.I64));
when Iir_Value_B1 =>
Res := Create_B1_Value (Ghdl_B1'Val (Res.I64));
when others =>
Error_Kind ("execute_expression(val attribute)",
Prefix_Type);
end case;
Check_Constraints (Block, Res, Prefix_Type, Expr);
return Res;
end;
when Iir_Kind_Pos_Attribute =>
declare
N_Res: Iir_Value_Literal_Acc;
Prefix_Type: constant Iir := Get_Type (Get_Prefix (Expr));
Base_Type : constant Iir := Get_Base_Type (Prefix_Type);
Mode : constant Iir_Value_Kind :=
Get_Info (Base_Type).Scalar_Mode;
begin
Res := Execute_Expression (Block, Get_Parameter (Expr));
case Mode is
when Iir_Value_I64 =>
null;
when Iir_Value_B1 =>
N_Res := Create_I64_Value (Ghdl_B1'Pos (Res.B1));
Res := N_Res;
when Iir_Value_E32 =>
N_Res := Create_I64_Value (Ghdl_I64 (Res.E32));
Res := N_Res;
when others =>
Error_Kind ("execute_expression(pos attribute)",
Base_Type);
end case;
Check_Constraints (Block, Res, Get_Type (Expr), Expr);
return Res;
end;
when Iir_Kind_Succ_Attribute =>
Res := Execute_Expression (Block, Get_Parameter (Expr));
Res := Execute_Inc (Res, Expr);
Check_Constraints (Block, Res, Get_Type (Expr), Expr);
return Res;
when Iir_Kind_Pred_Attribute =>
Res := Execute_Expression (Block, Get_Parameter (Expr));
Res := Execute_Dec (Res, Expr);
Check_Constraints (Block, Res, Get_Type (Expr), Expr);
return Res;
when Iir_Kind_Leftof_Attribute =>
declare
Bound : Iir_Value_Literal_Acc;
begin
Res := Execute_Expression (Block, Get_Parameter (Expr));
Bound := Execute_Bounds
(Block, Get_Type (Get_Prefix (Expr)));
case Bound.Dir is
when Iir_To =>
Res := Execute_Dec (Res, Expr);
when Iir_Downto =>
Res := Execute_Inc (Res, Expr);
end case;
Check_Constraints (Block, Res, Get_Type (Expr), Expr);
return Res;
end;
when Iir_Kind_Rightof_Attribute =>
declare
Bound : Iir_Value_Literal_Acc;
begin
Res := Execute_Expression (Block, Get_Parameter (Expr));
Bound := Execute_Bounds
(Block, Get_Type (Get_Prefix (Expr)));
case Bound.Dir is
when Iir_Downto =>
Res := Execute_Dec (Res, Expr);
when Iir_To =>
Res := Execute_Inc (Res, Expr);
end case;
Check_Constraints (Block, Res, Get_Type (Expr), Expr);
return Res;
end;
when Iir_Kind_Image_Attribute =>
return Execute_Image_Attribute (Block, Expr);
when Iir_Kind_Value_Attribute =>
Res := Execute_Expression (Block, Get_Parameter (Expr));
return Execute_Value_Attribute (Block, Res, Expr);
when Iir_Kind_Path_Name_Attribute
| Iir_Kind_Instance_Name_Attribute =>
return Execute_Path_Instance_Name_Attribute (Block, Expr);
when others =>
Error_Kind ("execute_expression", Expr);
end case;
end Execute_Expression;
procedure Execute_Dyadic_Association
(Out_Block: Block_Instance_Acc;
In_Block: Block_Instance_Acc;
Expr : Iir;
Inter_Chain: Iir)
is
Inter: Iir;
Val: Iir_Value_Literal_Acc;
begin
Inter := Inter_Chain;
for I in 0 .. 1 loop
if I = 0 then
Val := Execute_Expression (Out_Block, Get_Left (Expr));
else
Val := Execute_Expression (Out_Block, Get_Right (Expr));
end if;
Implicit_Array_Conversion (In_Block, Val, Get_Type (Inter), Expr);
Check_Constraints (In_Block, Val, Get_Type (Inter), Expr);
Elaboration.Create_Object (In_Block, Inter);
In_Block.Objects (Get_Info (Inter).Slot) :=
Unshare (Val, Instance_Pool);
Inter := Get_Chain (Inter);
end loop;
end Execute_Dyadic_Association;
procedure Execute_Monadic_Association
(Out_Block: Block_Instance_Acc;
In_Block: Block_Instance_Acc;
Expr : Iir;
Inter: Iir)
is
Val: Iir_Value_Literal_Acc;
begin
Val := Execute_Expression (Out_Block, Get_Operand (Expr));
Implicit_Array_Conversion (In_Block, Val, Get_Type (Inter), Expr);
Check_Constraints (In_Block, Val, Get_Type (Inter), Expr);
Elaboration.Create_Object (In_Block, Inter);
In_Block.Objects (Get_Info (Inter).Slot) :=
Unshare (Val, Instance_Pool);
end Execute_Monadic_Association;
-- Create a block instance for subprogram IMP.
function Create_Subprogram_Instance (Instance : Block_Instance_Acc;
Imp : Iir)
return Block_Instance_Acc
is
Func_Info : constant Sim_Info_Acc := Get_Info (Imp);
subtype Block_Type is Block_Instance_Type (Func_Info.Nbr_Objects);
function To_Block_Instance_Acc is new
Ada.Unchecked_Conversion (System.Address, Block_Instance_Acc);
function Alloc_Block_Instance is new
Alloc_On_Pool_Addr (Block_Type);
Up_Block: Block_Instance_Acc;
Res : Block_Instance_Acc;
begin
pragma Assert (Get_Kind (Imp) in Iir_Kinds_Subprogram_Declaration
or else Get_Kind (Imp) = Iir_Kind_Protected_Type_Body);
Up_Block := Get_Instance_By_Scope
(Instance, Get_Info (Get_Parent (Imp)).Frame_Scope);
Res := To_Block_Instance_Acc
(Alloc_Block_Instance
(Instance_Pool,
Block_Instance_Type'(Max_Objs => Func_Info.Nbr_Objects,
Block_Scope => Func_Info.Frame_Scope,
Up_Block => Up_Block,
Label => Imp,
Stmt => Null_Iir,
Parent => Instance,
Children => null,
Brother => null,
Marker => Empty_Marker,
Objects => (others => null),
Elab_Objects => 0,
In_Wait_Flag => False,
Actuals_Ref => null,
Result => null)));
return Res;
end Create_Subprogram_Instance;
-- Destroy a dynamic block_instance.
procedure Execute_Subprogram_Call_Final (Instance : Block_Instance_Acc)
is
Subprg_Body : constant Iir := Get_Subprogram_Body (Instance.Label);
begin
Finalize_Declarative_Part
(Instance, Get_Declaration_Chain (Subprg_Body));
end Execute_Subprogram_Call_Final;
function Execute_Function_Body (Instance : Block_Instance_Acc; Func : Iir)
return Iir_Value_Literal_Acc
is
Subprg_Body : constant Iir := Get_Subprogram_Body (Func);
Res : Iir_Value_Literal_Acc;
begin
Current_Process.Instance := Instance;
Elaborate_Declarative_Part
(Instance, Get_Declaration_Chain (Subprg_Body));
-- execute statements
Instance.Stmt := Get_Sequential_Statement_Chain (Subprg_Body);
Execute_Sequential_Statements (Current_Process);
pragma Assert (Current_Process.Instance = Instance);
if Instance.Result = null then
Error_Msg_Exec
("function scope exited without a return statement", Func);
end if;
-- Free variables, slots...
-- Need to copy the return value, because it can contains values from
-- arguments.
Res := Instance.Result;
Current_Process.Instance := Instance.Parent;
Execute_Subprogram_Call_Final (Instance);
return Res;
end Execute_Function_Body;
function Execute_Assoc_Function_Conversion
(Block : Block_Instance_Acc; Func : Iir; Val : Iir_Value_Literal_Acc)
return Iir_Value_Literal_Acc
is
Inter : Iir;
Instance : Block_Instance_Acc;
Res : Iir_Value_Literal_Acc;
Marker : Mark_Type;
begin
Mark (Marker, Instance_Pool.all);
-- Create an instance for this function.
Instance := Create_Subprogram_Instance (Block, Func);
Inter := Get_Interface_Declaration_Chain (Func);
Elaboration.Create_Object (Instance, Inter);
-- FIXME: implicit conversion
Instance.Objects (Get_Info (Inter).Slot) := Val;
Res := Execute_Function_Body (Instance, Func);
Res := Unshare (Res, Expr_Pool'Access);
Release (Marker, Instance_Pool.all);
return Res;
end Execute_Assoc_Function_Conversion;
function Execute_Assoc_Conversion
(Block : Block_Instance_Acc; Conv : Iir; Val : Iir_Value_Literal_Acc)
return Iir_Value_Literal_Acc
is
Ent : Iir;
begin
case Get_Kind (Conv) is
when Iir_Kind_Function_Call =>
-- FIXME: shouldn't CONV always be a denoting_name ?
return Execute_Assoc_Function_Conversion
(Block, Get_Implementation (Conv), Val);
when Iir_Kind_Type_Conversion =>
-- FIXME: shouldn't CONV always be a denoting_name ?
return Execute_Type_Conversion (Block, Conv, Val);
when Iir_Kinds_Denoting_Name
| Iir_Kind_Function_Declaration =>
Ent := Strip_Denoting_Name (Conv);
if Get_Kind (Ent) = Iir_Kind_Function_Declaration then
return Execute_Assoc_Function_Conversion (Block, Ent, Val);
elsif Get_Kind (Ent) in Iir_Kinds_Type_Declaration then
return Execute_Type_Conversion (Block, Ent, Val);
else
Error_Kind ("execute_assoc_conversion(1)", Ent);
end if;
when others =>
Error_Kind ("execute_assoc_conversion(2)", Conv);
end case;
end Execute_Assoc_Conversion;
procedure Associate_By_Reference (Block : Block_Instance_Acc;
Formal : Iir;
Formal_Base : Iir_Value_Literal_Acc;
Actual : Iir_Value_Literal_Acc)
is
Prefix : constant Iir := Strip_Denoting_Name (Get_Prefix (Formal));
Is_Sig : Boolean;
Pfx : Iir_Value_Literal_Acc;
Pos : Iir_Index32;
begin
if Get_Kind (Prefix) = Iir_Kind_Slice_Name then
-- That case is not handled correctly.
raise Program_Error;
end if;
Execute_Name_With_Base (Block, Prefix, Formal_Base, Pfx, Is_Sig);
case Get_Kind (Formal) is
when Iir_Kind_Indexed_Name =>
Execute_Indexed_Name (Block, Formal, Pfx, Pos);
Store (Pfx.Val_Array.V (Pos + 1), Actual);
when Iir_Kind_Selected_Element =>
Pos := Get_Element_Position (Get_Selected_Element (Formal));
Store (Pfx.Val_Record.V (Pos + 1), Actual);
when others =>
Error_Kind ("associate_by_reference", Formal);
end case;
end Associate_By_Reference;
-- Establish correspondance for association list ASSOC_LIST from block
-- instance OUT_BLOCK for subprogram of block SUBPRG_BLOCK.
procedure Execute_Association
(Out_Block: Block_Instance_Acc;
Subprg_Block: Block_Instance_Acc;
Assoc_Chain: Iir)
is
Nbr_Assoc : constant Natural := Get_Chain_Length (Assoc_Chain);
Assoc: Iir;
Actual : Iir;
Inter: Iir;
Formal : Iir;
Conv : Iir;
Val: Iir_Value_Literal_Acc;
Assoc_Idx : Iir_Index32;
Last_Individual : Iir_Value_Literal_Acc;
Mode : Iir_Mode;
Marker : Mark_Type;
begin
Subprg_Block.Actuals_Ref := null;
Mark (Marker, Expr_Pool);
Assoc := Assoc_Chain;
Assoc_Idx := 1;
while Assoc /= Null_Iir loop
Formal := Get_Formal (Assoc);
Inter := Get_Association_Interface (Assoc);
-- Extract the actual value.
case Get_Kind (Assoc) is
when Iir_Kind_Association_Element_Open =>
-- Not allowed in individual association.
pragma Assert (Formal = Inter);
pragma Assert (Get_Whole_Association_Flag (Assoc));
Actual := Get_Default_Value (Inter);
when Iir_Kind_Association_Element_By_Expression =>
Actual := Get_Actual (Assoc);
when Iir_Kind_Association_Element_By_Individual =>
-- Directly create the whole value on the instance pool, as its
-- life is longer than the statement.
if Get_Kind (Inter) = Iir_Kind_Interface_Signal_Declaration then
Last_Individual := Create_Value_For_Type
(Out_Block, Get_Actual_Type (Assoc), Init_Value_Signal);
else
Last_Individual := Create_Value_For_Type
(Out_Block, Get_Actual_Type (Assoc), Init_Value_Any);
end if;
Last_Individual :=
Unshare (Last_Individual, Instance_Pool);
Elaboration.Create_Object (Subprg_Block, Inter);
Subprg_Block.Objects (Get_Info (Inter).Slot) := Last_Individual;
goto Continue;
when others =>
Error_Kind ("execute_association(1)", Assoc);
end case;
-- Compute actual value.
case Get_Kind (Inter) is
when Iir_Kind_Interface_Constant_Declaration
| Iir_Kind_Interface_File_Declaration =>
Val := Execute_Expression (Out_Block, Actual);
Implicit_Array_Conversion
(Subprg_Block, Val, Get_Type (Formal), Assoc);
Check_Constraints (Subprg_Block, Val, Get_Type (Formal), Assoc);
when Iir_Kind_Interface_Signal_Declaration =>
Val := Execute_Name (Out_Block, Actual, True);
Implicit_Array_Conversion
(Subprg_Block, Val, Get_Type (Formal), Assoc);
when Iir_Kind_Interface_Variable_Declaration =>
Mode := Get_Mode (Inter);
if Mode = Iir_In_Mode then
-- FIXME: Ref ?
Val := Execute_Expression (Out_Block, Actual);
else
Val := Execute_Name (Out_Block, Actual, False);
end if;
-- FIXME: by value for scalars ?
-- Keep ref for back-copy
if Mode /= Iir_In_Mode then
if Subprg_Block.Actuals_Ref = null then
declare
subtype Actuals_Ref_Type is
Value_Array (Iir_Index32 (Nbr_Assoc));
function To_Value_Array_Acc is new
Ada.Unchecked_Conversion (System.Address,
Value_Array_Acc);
function Alloc_Actuals_Ref is new
Alloc_On_Pool_Addr (Actuals_Ref_Type);
begin
Subprg_Block.Actuals_Ref := To_Value_Array_Acc
(Alloc_Actuals_Ref
(Instance_Pool,
Actuals_Ref_Type'(Len => Iir_Index32 (Nbr_Assoc),
V => (others => null))));
end;
end if;
Subprg_Block.Actuals_Ref.V (Assoc_Idx) :=
Unshare_Bounds (Val, Instance_Pool);
end if;
if Mode = Iir_Out_Mode then
if Get_Out_Conversion (Assoc) /= Null_Iir then
-- For an OUT variable using an out conversion, don't
-- associate with the actual, create a temporary value.
Val := Create_Value_For_Type
(Out_Block, Get_Type (Formal), Init_Value_Default);
elsif Get_Kind (Get_Type (Formal)) in
Iir_Kinds_Scalar_Type_Definition
then
-- These are passed by value. Must be reset.
Val := Create_Value_For_Type
(Out_Block, Get_Type (Formal), Init_Value_Default);
end if;
else
if Get_Kind (Assoc) =
Iir_Kind_Association_Element_By_Expression
then
Conv := Get_In_Conversion (Assoc);
if Conv /= Null_Iir then
Val := Execute_Assoc_Conversion
(Subprg_Block, Conv, Val);
end if;
end if;
-- FIXME: check constraints ?
end if;
Implicit_Array_Conversion
(Subprg_Block, Val, Get_Type (Formal), Assoc);
when others =>
Error_Kind ("execute_association(2)", Inter);
end case;
if Get_Whole_Association_Flag (Assoc) then
case Get_Kind (Inter) is
when Iir_Kind_Interface_Constant_Declaration
| Iir_Kind_Interface_Variable_Declaration
| Iir_Kind_Interface_File_Declaration =>
-- FIXME: Arguments are passed by copy.
Elaboration.Create_Object (Subprg_Block, Inter);
Subprg_Block.Objects (Get_Info (Inter).Slot) :=
Unshare (Val, Instance_Pool);
when Iir_Kind_Interface_Signal_Declaration =>
Elaboration.Create_Signal (Subprg_Block, Inter);
Subprg_Block.Objects (Get_Info (Inter).Slot) :=
Unshare_Bounds (Val, Instance_Pool);
when others =>
Error_Kind ("execute_association", Inter);
end case;
else
Associate_By_Reference
(Subprg_Block, Formal, Last_Individual, Val);
end if;
<< Continue >> null;
Assoc := Get_Chain (Assoc);
Assoc_Idx := Assoc_Idx + 1;
end loop;
Release (Marker, Expr_Pool);
end Execute_Association;
procedure Execute_Back_Association (Instance : Block_Instance_Acc)
is
Proc : Iir;
Assoc: Iir;
Inter: Iir;
Formal : Iir;
Assoc_Idx : Iir_Index32;
begin
Proc := Get_Procedure_Call (Instance.Parent.Stmt);
Assoc := Get_Parameter_Association_Chain (Proc);
Assoc_Idx := 1;
while Assoc /= Null_Iir loop
if Get_Kind (Assoc) /= Iir_Kind_Association_Element_By_Individual then
Formal := Get_Formal (Assoc);
Inter := Get_Association_Interface (Assoc);
case Get_Kind (Inter) is
when Iir_Kind_Interface_Variable_Declaration =>
if Get_Mode (Inter) /= Iir_In_Mode
and then Get_Kind (Get_Type (Inter)) /=
Iir_Kind_File_Type_Definition
then
-- For out/inout variable interface, the value must
-- be copied (FIXME: unless when passed by reference ?).
declare
Targ : constant Iir_Value_Literal_Acc :=
Instance.Actuals_Ref.V (Assoc_Idx);
Base : constant Iir_Value_Literal_Acc :=
Instance.Objects (Get_Info (Inter).Slot);
Val : Iir_Value_Literal_Acc;
Conv : Iir;
Is_Sig : Boolean;
Expr_Mark : Mark_Type;
begin
Mark (Expr_Mark, Expr_Pool);
-- Extract for individual association.
Execute_Name_With_Base
(Instance, Formal, Base, Val, Is_Sig);
Conv := Get_Out_Conversion (Assoc);
if Conv /= Null_Iir then
Val := Execute_Assoc_Conversion
(Instance, Conv, Val);
-- FIXME: free val ?
end if;
Store (Targ, Val);
Release (Expr_Mark, Expr_Pool);
end;
end if;
when Iir_Kind_Interface_File_Declaration =>
null;
when Iir_Kind_Interface_Signal_Declaration
| Iir_Kind_Interface_Constant_Declaration =>
null;
when others =>
Error_Kind ("execute_back_association", Inter);
end case;
end if;
Assoc := Get_Chain (Assoc);
Assoc_Idx := Assoc_Idx + 1;
end loop;
end Execute_Back_Association;
-- When a subprogram of a protected type is called, a link to the object
-- must be passed. This procedure modifies the up_link of SUBPRG_BLOCK to
-- point to the block of the object (extracted from CALL and BLOCK).
-- This change doesn't modify the parent (so that the activation chain is
-- not changed).
procedure Adjust_Up_Link_For_Protected_Object
(Block: Block_Instance_Acc; Call: Iir; Subprg_Block : Block_Instance_Acc)
is
Meth_Obj : constant Iir := Get_Method_Object (Call);
Obj : Iir_Value_Literal_Acc;
Obj_Block : Block_Instance_Acc;
begin
if Meth_Obj /= Null_Iir then
Obj := Execute_Name (Block, Meth_Obj, True);
Obj_Block := Protected_Table.Table (Obj.Prot);
Subprg_Block.Up_Block := Obj_Block;
end if;
end Adjust_Up_Link_For_Protected_Object;
function Execute_Foreign_Function_Call
(Block: Block_Instance_Acc; Expr : Iir; Imp : Iir)
return Iir_Value_Literal_Acc
is
pragma Unreferenced (Block);
begin
case Get_Identifier (Imp) is
when Std_Names.Name_Get_Resolution_Limit =>
return Create_I64_Value
(Ghdl_I64
(Evaluation.Get_Physical_Value (Std_Package.Time_Base)));
when others =>
Error_Msg_Exec ("unsupported foreign function call", Expr);
end case;
return null;
end Execute_Foreign_Function_Call;
-- BLOCK is the block instance in which the function call appears.
function Execute_Function_Call
(Block: Block_Instance_Acc; Expr: Iir; Imp : Iir)
return Iir_Value_Literal_Acc
is
Inter_Chain : constant Iir := Get_Interface_Declaration_Chain (Imp);
Subprg_Block: Block_Instance_Acc;
Assoc_Chain: Iir;
Res : Iir_Value_Literal_Acc;
begin
Mark (Block.Marker, Instance_Pool.all);
Subprg_Block := Create_Subprogram_Instance (Block, Imp);
case Get_Kind (Expr) is
when Iir_Kind_Function_Call =>
Adjust_Up_Link_For_Protected_Object (Block, Expr, Subprg_Block);
Assoc_Chain := Get_Parameter_Association_Chain (Expr);
Execute_Association (Block, Subprg_Block, Assoc_Chain);
-- No out/inout interface for functions.
pragma Assert (Subprg_Block.Actuals_Ref = null);
when Iir_Kinds_Dyadic_Operator =>
Execute_Dyadic_Association
(Block, Subprg_Block, Expr, Inter_Chain);
when Iir_Kinds_Monadic_Operator =>
Execute_Monadic_Association
(Block, Subprg_Block, Expr, Inter_Chain);
when others =>
Error_Kind ("execute_subprogram_call_init", Expr);
end case;
if Get_Foreign_Flag (Imp) then
Res := Execute_Foreign_Function_Call (Subprg_Block, Expr, Imp);
else
Res := Execute_Function_Body (Subprg_Block, Imp);
end if;
-- Unfortunately, we don't know where the result has been allocated,
-- so copy it before releasing the instance pool.
Res := Unshare (Res, Expr_Pool'Access);
Release (Block.Marker, Instance_Pool.all);
return Res;
end Execute_Function_Call;
-- Slide an array VALUE using bounds from REF_VALUE. Do not modify
-- VALUE if not an array.
procedure Implicit_Array_Conversion (Value : in out Iir_Value_Literal_Acc;
Ref_Value : Iir_Value_Literal_Acc;
Expr : Iir)
is
Res : Iir_Value_Literal_Acc;
begin
if Value.Kind /= Iir_Value_Array then
return;
end if;
Res := Create_Array_Value (Value.Bounds.Nbr_Dims);
Res.Val_Array := Value.Val_Array;
for I in Value.Bounds.D'Range loop
if Value.Bounds.D (I).Length /= Ref_Value.Bounds.D (I).Length then
Error_Msg_Constraint (Expr);
return;
end if;
Res.Bounds.D (I) := Ref_Value.Bounds.D (I);
end loop;
Value := Res;
end Implicit_Array_Conversion;
procedure Implicit_Array_Conversion (Instance : Block_Instance_Acc;
Value : in out Iir_Value_Literal_Acc;
Ref_Type : Iir;
Expr : Iir)
is
Ref_Value : Iir_Value_Literal_Acc;
begin
-- Do array conversion only if REF_TYPE is a constrained array type
-- definition.
if Value.Kind /= Iir_Value_Array then
return;
end if;
if Get_Constraint_State (Ref_Type) /= Fully_Constrained then
return;
end if;
Ref_Value := Create_Array_Bounds_From_Type (Instance, Ref_Type, True);
for I in Value.Bounds.D'Range loop
if Value.Bounds.D (I).Length /= Ref_Value.Bounds.D (I).Length then
Error_Msg_Constraint (Expr);
return;
end if;
end loop;
Ref_Value.Val_Array.V := Value.Val_Array.V;
Value := Ref_Value;
end Implicit_Array_Conversion;
procedure Check_Array_Constraints
(Instance: Block_Instance_Acc;
Value: Iir_Value_Literal_Acc;
Def: Iir;
Expr: Iir)
is
Index_List: Iir_List;
Element_Subtype: Iir;
New_Bounds : Iir_Value_Literal_Acc;
begin
-- Nothing to check for unconstrained arrays.
if not Get_Index_Constraint_Flag (Def) then
return;
end if;
Index_List := Get_Index_Subtype_List (Def);
for I in Value.Bounds.D'Range loop
New_Bounds := Execute_Bounds
(Instance, Get_Nth_Element (Index_List, Natural (I - 1)));
if not Is_Equal (Value.Bounds.D (I), New_Bounds) then
Error_Msg_Constraint (Expr);
return;
end if;
end loop;
if Boolean'(False) then
Index_List := Get_Index_List (Def);
Element_Subtype := Get_Element_Subtype (Def);
for I in Value.Val_Array.V'Range loop
Check_Constraints
(Instance, Value.Val_Array.V (I), Element_Subtype, Expr);
end loop;
end if;
end Check_Array_Constraints;
-- Check DEST and SRC are array compatible.
procedure Check_Array_Match
(Instance: Block_Instance_Acc;
Dest: Iir_Value_Literal_Acc;
Src : Iir_Value_Literal_Acc;
Expr: Iir)
is
pragma Unreferenced (Instance);
begin
for I in Dest.Bounds.D'Range loop
if Dest.Bounds.D (I).Length /= Src.Bounds.D (I).Length then
Error_Msg_Constraint (Expr);
exit;
end if;
end loop;
end Check_Array_Match;
pragma Unreferenced (Check_Array_Match);
procedure Check_Constraints
(Instance: Block_Instance_Acc;
Value: Iir_Value_Literal_Acc;
Def: Iir;
Expr: Iir)
is
Base_Type : constant Iir := Get_Base_Type (Def);
High, Low: Iir_Value_Literal_Acc;
Bound : Iir_Value_Literal_Acc;
begin
case Get_Kind (Def) is
when Iir_Kind_Integer_Subtype_Definition
| Iir_Kind_Floating_Subtype_Definition
| Iir_Kind_Enumeration_Subtype_Definition
| Iir_Kind_Physical_Subtype_Definition
| Iir_Kind_Enumeration_Type_Definition =>
Bound := Execute_Bounds (Instance, Def);
if Bound.Dir = Iir_To then
High := Bound.Right;
Low := Bound.Left;
else
High := Bound.Left;
Low := Bound.Right;
end if;
case Get_Info (Base_Type).Scalar_Mode is
when Iir_Value_I64 =>
if Value.I64 in Low.I64 .. High.I64 then
return;
end if;
when Iir_Value_E32 =>
if Value.E32 in Low.E32 .. High.E32 then
return;
end if;
when Iir_Value_F64 =>
if Value.F64 in Low.F64 .. High.F64 then
return;
end if;
when Iir_Value_B1 =>
if Value.B1 in Low.B1 .. High.B1 then
return;
end if;
when others =>
raise Internal_Error;
end case;
when Iir_Kind_Array_Subtype_Definition
| Iir_Kind_Array_Type_Definition =>
Check_Array_Constraints (Instance, Value, Def, Expr);
return;
when Iir_Kind_Record_Type_Definition
| Iir_Kind_Record_Subtype_Definition =>
declare
El: Iir_Element_Declaration;
List : Iir_List;
begin
List := Get_Elements_Declaration_List (Get_Base_Type (Def));
for I in Natural loop
El := Get_Nth_Element (List, I);
exit when El = Null_Iir;
Check_Constraints
(Instance,
Value.Val_Record.V (Get_Element_Position (El) + 1),
Get_Type (El),
Expr);
end loop;
end;
return;
when Iir_Kind_Integer_Type_Definition =>
return;
when Iir_Kind_Floating_Type_Definition =>
return;
when Iir_Kind_Physical_Type_Definition =>
return;
when Iir_Kind_Access_Type_Definition
| Iir_Kind_Access_Subtype_Definition =>
return;
when Iir_Kind_File_Type_Definition =>
return;
when others =>
Error_Kind ("check_constraints", Def);
end case;
Error_Msg_Constraint (Expr);
end Check_Constraints;
function Execute_Resolution_Function
(Block: Block_Instance_Acc; Imp : Iir; Arr : Iir_Value_Literal_Acc)
return Iir_Value_Literal_Acc
is
Inter : Iir;
Instance : Block_Instance_Acc;
begin
-- Create a frame for this function.
Instance := Create_Subprogram_Instance (Block, Imp);
Inter := Get_Interface_Declaration_Chain (Imp);
Elaboration.Create_Object (Instance, Inter);
Instance.Objects (Get_Info (Inter).Slot) := Arr;
return Execute_Function_Body (Instance, Imp);
end Execute_Resolution_Function;
procedure Execute_Signal_Assignment
(Instance: Block_Instance_Acc;
Stmt: Iir_Signal_Assignment_Statement)
is
Wf : constant Iir_Waveform_Element := Get_Waveform_Chain (Stmt);
Nbr_We : constant Natural := Get_Chain_Length (Wf);
Transactions : Transaction_Type (Nbr_We);
We: Iir_Waveform_Element;
Res: Iir_Value_Literal_Acc;
Rdest: Iir_Value_Literal_Acc;
Targ_Type : Iir;
Marker : Mark_Type;
begin
Mark (Marker, Expr_Pool);
Rdest := Execute_Name (Instance, Get_Target (Stmt), True);
Targ_Type := Get_Type (Get_Target (Stmt));
-- Disconnection statement.
if Wf = Null_Iir then
Disconnect_Signal (Rdest);
Release (Marker, Expr_Pool);
return;
end if;
Transactions.Stmt := Stmt;
-- LRM93 8.4.1
-- Evaluation of a waveform consists of the evaluation of each waveform
-- elements in the waveform.
We := Wf;
for I in Transactions.Els'Range loop
declare
Trans : Transaction_El_Type renames Transactions.Els (I);
begin
if Get_Time (We) /= Null_Iir then
Res := Execute_Expression (Instance, Get_Time (We));
-- LRM93 8.4.1
-- It is an error if the time expression in a waveform element
-- evaluates to a negative value.
if Res.I64 < 0 then
Error_Msg_Exec ("time value is negative", Get_Time (We));
end if;
Trans.After := Std_Time (Res.I64);
else
-- LRM93 8.4.1
-- If the after clause of a waveform element is not present,
-- then an implicit "after 0 ns" is assumed.
Trans.After := 0;
end if;
-- LRM93 8.4.1
-- It is an error if the sequence of new transactions is not in
-- ascending order with respect to time.
if I > 1
and then Trans.After <= Transactions.Els (I - 1).After
then
Error_Msg_Exec
("sequence not in ascending order with respect to time", We);
end if;
if Get_Kind (Get_We_Value (We)) = Iir_Kind_Null_Literal then
-- null transaction.
Trans.Value := null;
else
-- LRM93 8.4.1
-- For the first form of waveform element, the value component
-- of the transaction is determined by the value expression in
-- the waveform element.
Trans.Value := Execute_Expression_With_Type
(Instance, Get_We_Value (We), Targ_Type);
end if;
end;
We := Get_Chain (We);
end loop;
pragma Assert (We = Null_Iir);
case Get_Delay_Mechanism (Stmt) is
when Iir_Transport_Delay =>
Transactions.Reject := 0;
when Iir_Inertial_Delay =>
-- LRM93 8.4
-- or, in the case that a pulse rejection limit is specified,
-- a pulse whose duration is shorter than that limit will not
-- be transmitted.
-- Every inertially delayed signal assignment has a pulse
-- rejection limit.
if Get_Reject_Time_Expression (Stmt) /= Null_Iir then
-- LRM93 8.4
-- If the delay mechanism specifies inertial delay, and if the
-- reserved word reject followed by a time expression is
-- present, then the time expression specifies the pulse
-- rejection limit.
Res := Execute_Expression
(Instance, Get_Reject_Time_Expression (Stmt));
-- LRM93 8.4
-- It is an error if the pulse rejection limit for any
-- inertially delayed signal assignement statement is either
-- negative ...
if Res.I64 < 0 then
Error_Msg_Exec ("reject time negative", Stmt);
end if;
-- LRM93 8.4
-- ... or greather than the time expression associated with
-- the first waveform element.
Transactions.Reject := Std_Time (Res.I64);
if Transactions.Reject > Transactions.Els (1).After then
Error_Msg_Exec
("reject time greather than time expression", Stmt);
end if;
else
-- LRM93 8.4
-- In all other cases, the pulse rejection limit is the time
-- expression associated ith the first waveform element.
Transactions.Reject := Transactions.Els (1).After;
end if;
end case;
-- FIXME: slice Transactions to remove transactions after end of time.
Assign_Value_To_Signal (Instance, Rdest, Transactions);
Release (Marker, Expr_Pool);
end Execute_Signal_Assignment;
-- Display a message when an assertion has failed.
-- REPORT is the value (string) to display, or null to use default message.
-- SEVERITY is the severity or null to use default (error).
-- STMT is used to display location.
procedure Execute_Failed_Assertion (Report : String;
Severity : Natural;
Stmt: Iir) is
begin
-- LRM93 8.2
-- The error message consists of at least:
-- 4: name of the design unit containing the assertion.
Put (Standard_Error, Disp_Location (Stmt));
-- 1: an indication that this message is from an assertion.
Put (Standard_Error, "(assertion ");
-- 2: the value of the severity level.
case Severity is
when 0 =>
Put (Standard_Error, "note");
when 1 =>
Put (Standard_Error, "warning");
when 2 =>
Put (Standard_Error, "error");
when 3 =>
Put (Standard_Error, "failure");
when others =>
Error_Internal (Null_Iir, "execute_failed_assertion");
end case;
if Disp_Time_Before_Values then
Put (Standard_Error, " at ");
Grt.Astdio.Put_Time (Grt.Stdio.stderr, Current_Time);
end if;
Put (Standard_Error, "): ");
-- 3: the value of the message string.
Put_Line (Standard_Error, Report);
-- Stop execution if the severity is too high.
if Severity >= Grt.Options.Severity_Level then
Debug (Reason_Assert);
Grt.Errors.Fatal_Error;
end if;
end Execute_Failed_Assertion;
procedure Execute_Failed_Assertion (Report : Iir_Value_Literal_Acc;
Severity : Natural;
Stmt: Iir) is
begin
if Report /= null then
declare
Msg : String (1 .. Natural (Report.Val_Array.Len));
begin
for I in Report.Val_Array.V'Range loop
Msg (Positive (I)) :=
Character'Val (Report.Val_Array.V (I).E32);
end loop;
Execute_Failed_Assertion (Msg, Severity, Stmt);
end;
else
-- The default value for the message string is:
-- "Assertion violation.".
-- Does the message string include quotes ?
Execute_Failed_Assertion ("Assertion violation.", Severity, Stmt);
end if;
end Execute_Failed_Assertion;
procedure Execute_Report_Statement
(Instance: Block_Instance_Acc; Stmt: Iir; Default_Severity : Natural)
is
Expr: Iir;
Report, Severity_Lit: Iir_Value_Literal_Acc;
Severity : Natural;
Marker : Mark_Type;
begin
Mark (Marker, Expr_Pool);
Expr := Get_Report_Expression (Stmt);
if Expr /= Null_Iir then
Report := Execute_Expression (Instance, Expr);
else
Report := null;
end if;
Expr := Get_Severity_Expression (Stmt);
if Expr /= Null_Iir then
Severity_Lit := Execute_Expression (Instance, Expr);
Severity := Natural'Val (Severity_Lit.E32);
else
Severity := Default_Severity;
end if;
Execute_Failed_Assertion (Report, Severity, Stmt);
Release (Marker, Expr_Pool);
end Execute_Report_Statement;
function Is_In_Choice
(Instance: Block_Instance_Acc;
Choice: Iir;
Expr: Iir_Value_Literal_Acc)
return Boolean
is
Res : Boolean;
begin
case Get_Kind (Choice) is
when Iir_Kind_Choice_By_Others =>
return True;
when Iir_Kind_Choice_By_Expression =>
declare
Expr1: Iir_Value_Literal_Acc;
begin
Expr1 := Execute_Expression
(Instance, Get_Choice_Expression (Choice));
Res := Is_Equal (Expr, Expr1);
return Res;
end;
when Iir_Kind_Choice_By_Range =>
declare
A_Range : Iir_Value_Literal_Acc;
begin
A_Range := Execute_Bounds
(Instance, Get_Choice_Range (Choice));
Res := Is_In_Range (Expr, A_Range);
end;
return Res;
when others =>
Error_Kind ("is_in_choice", Choice);
end case;
end Is_In_Choice;
-- Return TRUE iff VAL is in the range defined by BOUNDS.
function Is_In_Range (Val : Iir_Value_Literal_Acc;
Bounds : Iir_Value_Literal_Acc)
return Boolean
is
Max, Min : Iir_Value_Literal_Acc;
begin
case Bounds.Dir is
when Iir_To =>
Min := Bounds.Left;
Max := Bounds.Right;
when Iir_Downto =>
Min := Bounds.Right;
Max := Bounds.Left;
end case;
case Val.Kind is
when Iir_Value_E32 =>
return Val.E32 >= Min.E32 and Val.E32 <= Max.E32;
when Iir_Value_B1 =>
return Val.B1 >= Min.B1 and Val.B1 <= Max.B1;
when Iir_Value_I64 =>
return Val.I64 >= Min.I64 and Val.I64 <= Max.I64;
when others =>
raise Internal_Error;
return False;
end case;
end Is_In_Range;
-- Increment or decrement VAL according to BOUNDS.DIR.
-- FIXME: use increment ?
procedure Update_Loop_Index (Val : Iir_Value_Literal_Acc;
Bounds : Iir_Value_Literal_Acc)
is
begin
case Val.Kind is
when Iir_Value_E32 =>
case Bounds.Dir is
when Iir_To =>
Val.E32 := Val.E32 + 1;
when Iir_Downto =>
Val.E32 := Val.E32 - 1;
end case;
when Iir_Value_B1 =>
case Bounds.Dir is
when Iir_To =>
Val.B1 := True;
when Iir_Downto =>
Val.B1 := False;
end case;
when Iir_Value_I64 =>
case Bounds.Dir is
when Iir_To =>
Val.I64 := Val.I64 + 1;
when Iir_Downto =>
Val.I64 := Val.I64 - 1;
end case;
when others =>
raise Internal_Error;
end case;
end Update_Loop_Index;
procedure Finalize_For_Loop_Statement (Instance : Block_Instance_Acc;
Stmt : Iir)
is
begin
Destroy_Iterator_Declaration
(Instance, Get_Parameter_Specification (Stmt));
end Finalize_For_Loop_Statement;
procedure Finalize_Loop_Statement (Instance : Block_Instance_Acc;
Stmt : Iir)
is
begin
if Get_Kind (Stmt) = Iir_Kind_For_Loop_Statement then
Finalize_For_Loop_Statement (Instance, Stmt);
end if;
end Finalize_Loop_Statement;
procedure Execute_For_Loop_Statement (Proc : Process_State_Acc)
is
Instance : constant Block_Instance_Acc := Proc.Instance;
Stmt : constant Iir_For_Loop_Statement := Instance.Stmt;
Iterator : constant Iir := Get_Parameter_Specification (Stmt);
Bounds : Iir_Value_Literal_Acc;
Index : Iir_Value_Literal_Acc;
Stmt_Chain : Iir;
Is_Nul : Boolean;
Marker : Mark_Type;
begin
-- Elaborate the iterator (and its type).
Elaborate_Declaration (Instance, Iterator);
-- Extract bounds.
Mark (Marker, Expr_Pool);
Bounds := Execute_Bounds (Instance, Get_Type (Iterator));
Index := Instance.Objects (Get_Info (Iterator).Slot);
Store (Index, Bounds.Left);
Is_Nul := Is_Null_Range (Bounds);
Release (Marker, Expr_Pool);
if Is_Nul then
-- Loop is complete.
Finalize_For_Loop_Statement (Instance, Stmt);
Update_Next_Statement (Proc);
else
Stmt_Chain := Get_Sequential_Statement_Chain (Stmt);
if Stmt_Chain = Null_Iir then
-- Nothing to do for an empty loop.
Finalize_For_Loop_Statement (Instance, Stmt);
Update_Next_Statement (Proc);
else
Instance.Stmt := Stmt_Chain;
end if;
end if;
end Execute_For_Loop_Statement;
-- This function is called when there is no more statements to execute
-- in the statement list of a for_loop. Returns FALSE in case of end of
-- loop.
function Finish_For_Loop_Statement (Instance : Block_Instance_Acc)
return Boolean
is
Iterator : constant Iir := Get_Parameter_Specification (Instance.Stmt);
Bounds : Iir_Value_Literal_Acc;
Index : Iir_Value_Literal_Acc;
Marker : Mark_Type;
begin
-- FIXME: avoid allocation.
Mark (Marker, Expr_Pool);
Bounds := Execute_Bounds (Instance, Get_Type (Iterator));
Index := Instance.Objects (Get_Info (Iterator).Slot);
if Is_Equal (Index, Bounds.Right) then
-- Loop is complete.
Release (Marker, Expr_Pool);
Finalize_For_Loop_Statement (Instance, Instance.Stmt);
return False;
else
-- Update the loop index.
Update_Loop_Index (Index, Bounds);
Release (Marker, Expr_Pool);
-- start the loop again.
Instance.Stmt := Get_Sequential_Statement_Chain (Instance.Stmt);
return True;
end if;
end Finish_For_Loop_Statement;
-- Evaluate boolean condition COND. If COND is Null_Iir, returns true.
function Execute_Condition (Instance : Block_Instance_Acc;
Cond : Iir) return Boolean
is
V : Iir_Value_Literal_Acc;
Res : Boolean;
Marker : Mark_Type;
begin
if Cond = Null_Iir then
return True;
end if;
Mark (Marker, Expr_Pool);
V := Execute_Expression (Instance, Cond);
Res := V.B1 = True;
Release (Marker, Expr_Pool);
return Res;
end Execute_Condition;
-- Start a while loop statement, or return FALSE if the loop is not
-- executed.
procedure Execute_While_Loop_Statement (Proc : Process_State_Acc)
is
Instance: constant Block_Instance_Acc := Proc.Instance;
Stmt : constant Iir := Instance.Stmt;
Cond : Boolean;
begin
Cond := Execute_Condition (Instance, Get_Condition (Stmt));
if Cond then
Init_Sequential_Statements (Proc, Stmt);
else
Update_Next_Statement (Proc);
end if;
end Execute_While_Loop_Statement;
-- This function is called when there is no more statements to execute
-- in the statement list of a while loop. Returns FALSE iff loop is
-- completed.
function Finish_While_Loop_Statement (Instance : Block_Instance_Acc)
return Boolean
is
Cond : Boolean;
begin
Cond := Execute_Condition (Instance, Get_Condition (Instance.Stmt));
if Cond then
-- start the loop again.
Instance.Stmt := Get_Sequential_Statement_Chain (Instance.Stmt);
return True;
else
-- Loop is complete.
return False;
end if;
end Finish_While_Loop_Statement;
-- Return TRUE if the loop must be executed again
function Finish_Loop_Statement (Instance : Block_Instance_Acc;
Stmt : Iir) return Boolean is
begin
Instance.Stmt := Stmt;
case Get_Kind (Stmt) is
when Iir_Kind_While_Loop_Statement =>
return Finish_While_Loop_Statement (Instance);
when Iir_Kind_For_Loop_Statement =>
return Finish_For_Loop_Statement (Instance);
when others =>
Error_Kind ("finish_loop_statement", Stmt);
end case;
end Finish_Loop_Statement;
-- Return FALSE if the next statement should be executed (possibly
-- updated).
procedure Execute_Exit_Next_Statement (Proc : Process_State_Acc;
Is_Exit : Boolean)
is
Instance : constant Block_Instance_Acc := Proc.Instance;
Stmt : constant Iir := Instance.Stmt;
Label : constant Iir := Get_Named_Entity (Get_Loop_Label (Stmt));
Cond : Boolean;
Parent : Iir;
begin
Cond := Execute_Condition (Instance, Get_Condition (Stmt));
if not Cond then
Update_Next_Statement (Proc);
return;
end if;
Parent := Stmt;
loop
Parent := Get_Parent (Parent);
case Get_Kind (Parent) is
when Iir_Kind_For_Loop_Statement
| Iir_Kind_While_Loop_Statement =>
if Label = Null_Iir or else Label = Parent then
-- Target is this statement.
if Is_Exit then
Finalize_Loop_Statement (Instance, Parent);
Instance.Stmt := Parent;
Update_Next_Statement (Proc);
elsif not Finish_Loop_Statement (Instance, Parent) then
Update_Next_Statement (Proc);
else
Init_Sequential_Statements (Proc, Parent);
end if;
return;
else
Finalize_Loop_Statement (Instance, Parent);
end if;
when others =>
null;
end case;
end loop;
end Execute_Exit_Next_Statement;
procedure Execute_Case_Statement (Proc : Process_State_Acc)
is
Instance : constant Block_Instance_Acc := Proc.Instance;
Stmt : constant Iir := Instance.Stmt;
Value: Iir_Value_Literal_Acc;
Assoc: Iir;
Stmt_Chain : Iir;
Marker : Mark_Type;
begin
Mark (Marker, Expr_Pool);
Value := Execute_Expression (Instance, Get_Expression (Stmt));
Assoc := Get_Case_Statement_Alternative_Chain (Stmt);
while Assoc /= Null_Iir loop
if not Get_Same_Alternative_Flag (Assoc) then
Stmt_Chain := Get_Associated_Chain (Assoc);
end if;
if Is_In_Choice (Instance, Assoc, Value) then
if Stmt_Chain = Null_Iir then
Update_Next_Statement (Proc);
else
Instance.Stmt := Stmt_Chain;
end if;
Release (Marker, Expr_Pool);
return;
end if;
Assoc := Get_Chain (Assoc);
end loop;
-- FIXME: infinite loop???
Error_Msg_Exec ("no choice for expression", Stmt);
raise Internal_Error;
end Execute_Case_Statement;
procedure Execute_Call_Statement (Proc : Process_State_Acc)
is
Instance : constant Block_Instance_Acc := Proc.Instance;
Stmt : constant Iir := Instance.Stmt;
Call : constant Iir := Get_Procedure_Call (Stmt);
Imp : constant Iir := Get_Implementation (Call);
Subprg_Instance : Block_Instance_Acc;
Assoc_Chain: Iir;
Subprg_Body : Iir;
begin
if Get_Implicit_Definition (Imp) in Iir_Predefined_Implicit then
Execute_Implicit_Procedure (Instance, Call);
Update_Next_Statement (Proc);
elsif Get_Foreign_Flag (Imp) then
Execute_Foreign_Procedure (Instance, Call);
Update_Next_Statement (Proc);
else
Mark (Instance.Marker, Instance_Pool.all);
Subprg_Instance := Create_Subprogram_Instance (Instance, Imp);
Adjust_Up_Link_For_Protected_Object
(Instance, Call, Subprg_Instance);
Assoc_Chain := Get_Parameter_Association_Chain (Call);
Execute_Association (Instance, Subprg_Instance, Assoc_Chain);
Current_Process.Instance := Subprg_Instance;
Subprg_Body := Get_Subprogram_Body (Imp);
Elaborate_Declarative_Part
(Subprg_Instance, Get_Declaration_Chain (Subprg_Body));
Init_Sequential_Statements (Proc, Subprg_Body);
end if;
end Execute_Call_Statement;
procedure Finish_Procedure_Frame (Proc : Process_State_Acc)
is
Old_Instance : constant Block_Instance_Acc := Proc.Instance;
begin
Execute_Back_Association (Old_Instance);
Proc.Instance := Old_Instance.Parent;
Execute_Subprogram_Call_Final (Old_Instance);
Release (Proc.Instance.Marker, Instance_Pool.all);
end Finish_Procedure_Frame;
procedure Execute_If_Statement
(Proc : Process_State_Acc; Stmt: Iir_Wait_Statement)
is
Clause: Iir;
Cond: Boolean;
begin
Clause := Stmt;
loop
Cond := Execute_Condition (Proc.Instance, Get_Condition (Clause));
if Cond then
Init_Sequential_Statements (Proc, Clause);
return;
end if;
Clause := Get_Else_Clause (Clause);
exit when Clause = Null_Iir;
end loop;
Update_Next_Statement (Proc);
end Execute_If_Statement;
procedure Execute_Variable_Assignment
(Proc : Process_State_Acc; Stmt : Iir)
is
Instance : constant Block_Instance_Acc := Proc.Instance;
Target : constant Iir := Get_Target (Stmt);
Target_Type : constant Iir := Get_Type (Target);
Expr : constant Iir := Get_Expression (Stmt);
Expr_Type : constant Iir := Get_Type (Expr);
Target_Val: Iir_Value_Literal_Acc;
Res : Iir_Value_Literal_Acc;
Marker : Mark_Type;
begin
Mark (Marker, Expr_Pool);
Target_Val := Execute_Expression (Instance, Target);
-- If the type of the target is not static and the value is
-- an aggregate, then the aggregate may be contrained by the
-- target.
if Get_Kind (Expr) = Iir_Kind_Aggregate
and then Get_Type_Staticness (Expr_Type) < Locally
and then Get_Kind (Expr_Type)
in Iir_Kinds_Array_Type_Definition
then
Res := Copy_Array_Bound (Target_Val);
Fill_Array_Aggregate (Instance, Expr, Res);
else
Res := Execute_Expression (Instance, Expr);
end if;
if Get_Kind (Target_Type) in Iir_Kinds_Array_Type_Definition then
-- Note: target_type may be dynamic (slice case), so
-- check_constraints is not called.
Implicit_Array_Conversion (Res, Target_Val, Stmt);
else
Check_Constraints (Instance, Res, Target_Type, Stmt);
end if;
-- Note: we need to unshare before copying to avoid
-- overwrites (in assignments like: v (1 to 4) := v (3 to 6)).
-- FIXME: improve that handling (detect overlaps before).
Store (Target_Val, Unshare (Res, Expr_Pool'Access));
Release (Marker, Expr_Pool);
end Execute_Variable_Assignment;
function Execute_Return_Statement (Proc : Process_State_Acc)
return Boolean
is
Res : Iir_Value_Literal_Acc;
Instance : constant Block_Instance_Acc := Proc.Instance;
Stmt : constant Iir := Instance.Stmt;
Expr : constant Iir := Get_Expression (Stmt);
begin
if Expr /= Null_Iir then
Res := Execute_Expression (Instance, Expr);
Implicit_Array_Conversion (Instance, Res, Get_Type (Stmt), Stmt);
Check_Constraints (Instance, Res, Get_Type (Stmt), Stmt);
Instance.Result := Res;
end if;
case Get_Kind (Instance.Label) is
when Iir_Kind_Procedure_Declaration =>
Finish_Procedure_Frame (Proc);
Update_Next_Statement (Proc);
return False;
when Iir_Kind_Function_Declaration =>
return True;
when others =>
raise Internal_Error;
end case;
end Execute_Return_Statement;
procedure Finish_Sequential_Statements
(Proc : Process_State_Acc; Complex_Stmt : Iir)
is
Instance : Block_Instance_Acc := Proc.Instance;
Stmt : Iir;
begin
Stmt := Complex_Stmt;
loop
Instance.Stmt := Stmt;
case Get_Kind (Stmt) is
when Iir_Kind_For_Loop_Statement =>
if Finish_For_Loop_Statement (Instance) then
return;
end if;
when Iir_Kind_While_Loop_Statement =>
if Finish_While_Loop_Statement (Instance) then
return;
end if;
when Iir_Kind_Case_Statement
| Iir_Kind_If_Statement =>
null;
when Iir_Kind_Sensitized_Process_Statement =>
Instance.Stmt := Null_Iir;
return;
when Iir_Kind_Process_Statement =>
-- Start again.
Instance.Stmt := Get_Sequential_Statement_Chain (Stmt);
return;
when Iir_Kind_Procedure_Body =>
Finish_Procedure_Frame (Proc);
Instance := Proc.Instance;
when Iir_Kind_Function_Body =>
Error_Msg_Exec ("missing return statement in function", Stmt);
when others =>
Error_Kind ("execute_next_statement", Stmt);
end case;
Stmt := Get_Chain (Instance.Stmt);
if Stmt /= Null_Iir then
Instance.Stmt := Stmt;
return;
end if;
Stmt := Get_Parent (Instance.Stmt);
end loop;
end Finish_Sequential_Statements;
procedure Init_Sequential_Statements
(Proc : Process_State_Acc; Complex_Stmt : Iir)
is
Stmt : Iir;
begin
Stmt := Get_Sequential_Statement_Chain (Complex_Stmt);
if Stmt /= Null_Iir then
Proc.Instance.Stmt := Stmt;
else
Finish_Sequential_Statements (Proc, Complex_Stmt);
end if;
end Init_Sequential_Statements;
procedure Update_Next_Statement (Proc : Process_State_Acc)
is
Instance : constant Block_Instance_Acc := Proc.Instance;
Stmt : Iir;
begin
Stmt := Get_Chain (Instance.Stmt);
if Stmt /= Null_Iir then
Instance.Stmt := Stmt;
return;
end if;
Finish_Sequential_Statements (Proc, Get_Parent (Instance.Stmt));
end Update_Next_Statement;
procedure Execute_Sequential_Statements (Proc : Process_State_Acc)
is
Instance : Block_Instance_Acc;
Stmt: Iir;
begin
loop
Instance := Proc.Instance;
Stmt := Instance.Stmt;
-- End of process or subprogram.
exit when Stmt = Null_Iir;
if Trace_Statements then
declare
Name : Name_Id;
Line : Natural;
Col : Natural;
begin
Files_Map.Location_To_Position
(Get_Location (Stmt), Name, Line, Col);
Put_Line ("Execute statement at "
& Name_Table.Image (Name)
& Natural'Image (Line));
end;
end if;
if Flag_Need_Debug then
Debug (Reason_Break);
end if;
-- execute statement STMT.
case Get_Kind (Stmt) is
when Iir_Kind_Null_Statement =>
Update_Next_Statement (Proc);
when Iir_Kind_If_Statement =>
Execute_If_Statement (Proc, Stmt);
when Iir_Kind_Simple_Signal_Assignment_Statement =>
Execute_Signal_Assignment (Instance, Stmt);
Update_Next_Statement (Proc);
when Iir_Kind_Assertion_Statement =>
declare
Res : Boolean;
begin
Res := Execute_Condition
(Instance, Get_Assertion_Condition (Stmt));
if not Res then
Execute_Report_Statement (Instance, Stmt, 2);
end if;
end;
Update_Next_Statement (Proc);
when Iir_Kind_Report_Statement =>
Execute_Report_Statement (Instance, Stmt, 0);
Update_Next_Statement (Proc);
when Iir_Kind_Variable_Assignment_Statement =>
Execute_Variable_Assignment (Proc, Stmt);
Update_Next_Statement (Proc);
when Iir_Kind_Return_Statement =>
if Execute_Return_Statement (Proc) then
return;
end if;
when Iir_Kind_For_Loop_Statement =>
Execute_For_Loop_Statement (Proc);
when Iir_Kind_While_Loop_Statement =>
Execute_While_Loop_Statement (Proc);
when Iir_Kind_Case_Statement =>
Execute_Case_Statement (Proc);
when Iir_Kind_Wait_Statement =>
if Execute_Wait_Statement (Instance, Stmt) then
return;
end if;
Update_Next_Statement (Proc);
when Iir_Kind_Procedure_Call_Statement =>
Execute_Call_Statement (Proc);
when Iir_Kind_Exit_Statement =>
Execute_Exit_Next_Statement (Proc, True);
when Iir_Kind_Next_Statement =>
Execute_Exit_Next_Statement (Proc, False);
when others =>
Error_Kind ("execute_sequential_statements", Stmt);
end case;
end loop;
end Execute_Sequential_Statements;
end Execution;
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