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|
-- Semantic analysis pass for PSL.
-- Copyright (C) 2009 Tristan Gingold
--
-- This program is free software: you can redistribute it and/or modify
-- it under the terms of the GNU General Public License as published by
-- the Free Software Foundation, either version 2 of the License, or
-- (at your option) any later version.
--
-- This program is distributed in the hope that it will be useful,
-- but WITHOUT ANY WARRANTY; without even the implied warranty of
-- MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
-- GNU General Public License for more details.
--
-- You should have received a copy of the GNU General Public License
-- along with this program. If not, see <gnu.org/licenses>.
with Types; use Types;
with Errorout; use Errorout;
with PSL.Types; use PSL.Types;
with PSL.Nodes; use PSL.Nodes;
with PSL.Subsets;
with PSL.Hash;
with PSL.Rewrites;
with PSL.Errors; use PSL.Errors;
with Vhdl.Sem_Expr;
with Vhdl.Sem_Stmts; use Vhdl.Sem_Stmts;
with Vhdl.Sem_Scopes;
with Vhdl.Sem_Names;
with Vhdl.Sem_Lib;
with Vhdl.Sem_Decls;
with Vhdl.Utils; use Vhdl.Utils;
with Vhdl.Evaluation; use Vhdl.Evaluation;
with Vhdl.Std_Package;
with Vhdl.Ieee.Std_Logic_1164;
with Vhdl.Errors; use Vhdl.Errors;
with Vhdl.Xrefs; use Vhdl.Xrefs;
package body Vhdl.Sem_Psl is
procedure Sem_Psl_Directive_Clock (Stmt : Iir; Prop : in out PSL_Node);
-- Return TRUE iff Atype is a PSL boolean type.
-- See PSL1.1 5.1.2 Boolean expressions
function Is_Psl_Boolean_Type (Atype : Iir) return Boolean
is
Btype : Iir;
begin
if Atype = Null_Iir then
return False;
end if;
Btype := Get_Base_Type (Atype);
return Btype = Vhdl.Std_Package.Boolean_Type_Definition
or else Btype = Vhdl.Std_Package.Bit_Type_Definition
or else Btype = Vhdl.Ieee.Std_Logic_1164.Std_Ulogic_Type;
end Is_Psl_Boolean_Type;
-- Return TRUE if EXPR type is a PSL boolean type.
function Is_Psl_Boolean_Expr (Expr : Iir) return Boolean is
begin
return Is_Psl_Boolean_Type (Get_Type (Expr));
end Is_Psl_Boolean_Expr;
function Is_Psl_Bit_Type (Atype : Iir) return Boolean
is
Btype : constant Iir := Get_Base_Type (Atype);
begin
return Btype = Vhdl.Std_Package.Bit_Type_Definition
or else Btype = Vhdl.Ieee.Std_Logic_1164.Std_Ulogic_Type;
end Is_Psl_Bit_Type;
function Is_Psl_Bitvector_Type (Atype : Iir) return Boolean is
begin
if not Is_One_Dimensional_Array_Type (Atype) then
return False;
end if;
return Is_Psl_Bit_Type (Get_Element_Subtype (Atype));
end Is_Psl_Bitvector_Type;
function Sem_Prev_Builtin (Call : Iir; Atype : Iir) return Iir
is
use Vhdl.Sem_Expr;
use Vhdl.Std_Package;
Expr : Iir;
Count : Iir;
Clock : Iir;
First : Boolean;
begin
Expr := Get_Expression (Call);
First := Is_Expr_Not_Analyzed (Expr);
Expr := Sem_Expression_Ov (Expr, Atype);
if Expr /= Null_Iir then
Set_Expression (Call, Expr);
Set_Type (Call, Get_Type (Expr));
Set_Expr_Staticness (Call, None);
end if;
if First then
-- Analyze count and clock only once.
Count := Get_Count_Expression (Call);
if Count /= Null_Iir then
Count := Sem_Expression_Wildcard
(Count, Wildcard_Any_Integer_Type);
Count := Eval_Expr (Count);
Set_Count_Expression (Call, Count);
end if;
Clock := Get_Clock_Expression (Call);
if Clock /= Null_Iir then
Clock := Sem_Expression_Wildcard (Clock, Wildcard_Psl_Bit_Type);
Set_Clock_Expression (Call, Clock);
else
if Current_Psl_Default_Clock = Null_Iir then
Error_Msg_Sem (+Call, "no clock for PSL prev builtin");
else
Set_Default_Clock (Call, Current_Psl_Default_Clock);
end if;
end if;
end if;
return Call;
end Sem_Prev_Builtin;
function Sem_Clock_Builtin (Call : Iir) return Iir
is
use Vhdl.Sem_Expr;
use Vhdl.Std_Package;
Expr : Iir;
Clock : Iir;
First : Boolean;
begin
Expr := Get_Expression (Call);
First := Is_Expr_Not_Analyzed (Expr);
Expr := Sem_Expression (Expr, Null_Iir);
if Expr /= Null_Iir then
Set_Expression (Call, Expr);
Set_Type (Call, Vhdl.Std_Package.Boolean_Type_Definition);
Set_Expr_Staticness (Call, None);
end if;
if First then
-- Analyze clock only once.
Clock := Get_Clock_Expression (Call);
if Clock /= Null_Iir then
Clock := Sem_Expression_Wildcard (Clock, Wildcard_Psl_Bit_Type);
Set_Clock_Expression (Call, Clock);
else
if Current_Psl_Default_Clock = Null_Iir then
Error_Msg_Sem (+Call, "no clock for %n", +Call);
else
Set_Default_Clock (Call, Current_Psl_Default_Clock);
end if;
end if;
end if;
return Call;
end Sem_Clock_Builtin;
function Sem_Onehot_Builtin (Call : Iir) return Iir
is
use Vhdl.Sem_Expr;
use Vhdl.Std_Package;
Expr : Iir;
begin
Expr := Get_Expression (Call);
Expr := Sem_Expression (Expr, Null_Iir);
if Expr /= Null_Iir then
Set_Expression (Call, Expr);
Set_Type (Call, Vhdl.Std_Package.Boolean_Type_Definition);
Set_Expr_Staticness (Call, None);
if not Is_Psl_Bitvector_Type (Get_Type (Expr)) then
Error_Msg_Sem (+Call, "type of parameter must be bitvector");
end if;
end if;
return Call;
end Sem_Onehot_Builtin;
-- Convert VHDL and/or/not nodes to PSL nodes.
function Convert_Bool (Expr : Iir) return PSL_Node;
function Convert_Bool_Dyadic_Operator (Expr : Iir; Kind : PSL.Nodes.Nkind)
return PSL_Node
is
Left : constant Iir := Get_Left (Expr);
Right : constant Iir := Get_Right (Expr);
N : PSL_Node;
begin
if Is_Psl_Boolean_Expr (Left)
and then Is_Psl_Boolean_Expr (Right)
then
N := Create_Node (Kind);
Set_Location (N, Get_Location (Expr));
Set_Left (N, Convert_Bool (Left));
Set_Right (N, Convert_Bool (Right));
Free_Iir (Expr);
return N;
else
return Null_PSL_Node;
end if;
end Convert_Bool_Dyadic_Operator;
function Convert_Bool_Monadic_Operator (Expr : Iir; Kind : PSL.Nodes.Nkind)
return PSL_Node
is
Operand : constant Iir := Get_Operand (Expr);
N : PSL_Node;
begin
if Is_Psl_Boolean_Expr (Operand) then
N := Create_Node (Kind);
Set_Location (N, Get_Location (Expr));
Set_Boolean (N, Convert_Bool (Operand));
Free_Iir (Expr);
return N;
else
return Null_PSL_Node;
end if;
end Convert_Bool_Monadic_Operator;
-- Convert VHDL and/or/not nodes to PSL nodes.
function Convert_Bool (Expr : Iir) return PSL_Node
is
Res : PSL_Node;
begin
case Get_Kind (Expr) is
when Iir_Kind_And_Operator =>
Res := Convert_Bool_Dyadic_Operator (Expr, N_And_Bool);
if Res /= Null_PSL_Node then
return Res;
end if;
when Iir_Kind_Or_Operator =>
Res := Convert_Bool_Dyadic_Operator (Expr, N_Or_Bool);
if Res /= Null_PSL_Node then
return Res;
end if;
when Iir_Kind_Not_Operator =>
Res := Convert_Bool_Monadic_Operator (Expr, N_Not_Bool);
if Res /= Null_PSL_Node then
return Res;
end if;
when Iir_Kinds_Name =>
-- Get the named entity for names in order to hash it.
declare
Name : Iir;
Hnode : PSL_Node;
N : PSL_Node;
begin
Name := Get_Named_Entity (Expr);
if Name /= Null_Iir then
Hnode := PSL.Hash.Get_PSL_Node
(HDL_Node (Name), Get_Location (Name));
N := Create_Node (N_HDL_Expr);
Set_Location (N, Get_Location (Expr));
Set_HDL_Node (N, HDL_Node (Expr));
Set_HDL_Hash (N, Hnode);
return N;
end if;
end;
when others =>
null;
end case;
-- Default.
return PSL.Hash.Get_PSL_Node (HDL_Node (Expr), Get_Location (Expr));
end Convert_Bool;
-- Analyze an HDL expression. This may mostly a wrapper except in the
-- case when the expression is in fact a PSL expression.
function Sem_Hdl_Expr (N : PSL_Node) return PSL_Node
is
use Sem_Names;
Expr : Iir;
Expr_Type : Iir;
Name : Iir;
Decl : PSL_Node;
Res : PSL_Node;
begin
Expr := Get_HDL_Node (N);
if Get_Kind (Expr) in Iir_Kinds_Name then
Sem_Name (Expr);
Expr := Finish_Sem_Name (Expr);
Set_HDL_Node (N, Expr);
Name := Strip_Denoting_Name (Expr);
case Get_Kind (Name) is
when Iir_Kind_Error =>
return N;
when Iir_Kind_Overload_List =>
-- FIXME: todo.
raise Internal_Error;
when Iir_Kind_Psl_Declaration =>
Decl := Get_Psl_Declaration (Name);
case Get_Kind (Decl) is
when N_Sequence_Declaration =>
Res := Create_Node (N_Sequence_Instance);
when N_Property_Declaration =>
Res := Create_Node (N_Property_Instance);
when N_Boolean_Parameter
| N_Sequence_Parameter
| N_Const_Parameter
| N_Property_Parameter =>
-- FIXME: create a n_name
Free_Node (N);
Free_Iir (Expr);
return Decl;
when others =>
Error_Kind ("sem_hdl_expr(2)", Decl);
end case;
Set_Location (Res, Get_Location (N));
Set_Declaration (Res, Decl);
if Get_Parameter_List (Decl) /= Null_PSL_Node then
Error_Msg_Sem (+Res, "no actual for instantiation");
end if;
Free_Node (N);
Free_Iir (Expr);
return Res;
when Iir_Kind_Psl_Expression =>
-- Remove the two bridge nodes: from PSL to HDL and from
-- HDL to PSL.
Free_Node (N);
Res := Get_Psl_Expression (Name);
Free_Iir (Expr);
if Name /= Expr then
Free_Iir (Name);
end if;
return Res;
when Iir_Kind_Function_Call
| Iir_Kind_Indexed_Name
| Iir_Kind_Selected_Element
| Iir_Kinds_Expression_Attribute =>
Expr := Name;
when others =>
Expr := Name_To_Expression (Expr, Null_Iir);
end case;
else
Expr := Sem_Expr.Sem_Expression_Wildcard
(Expr, Std_Package.Wildcard_Psl_Boolean_Type);
end if;
if Expr = Null_Iir then
return N;
end if;
Expr_Type := Get_Type (Expr);
if Expr_Type = Null_Iir then
return N;
end if;
Free_Node (N);
if not Is_Overload_List (Expr_Type)
and then not Is_Psl_Boolean_Type (Expr_Type)
then
Error_Msg_Sem (+Expr, "type of expression must be boolean");
return PSL.Hash.Get_PSL_Node (HDL_Node (Expr), Get_Location (Expr));
else
return Convert_Bool (Expr);
end if;
end Sem_Hdl_Expr;
-- Sem a boolean node.
function Sem_Boolean (Bool : PSL_Node) return PSL_Node is
begin
case Get_Kind (Bool) is
when N_HDL_Expr =>
return Sem_Hdl_Expr (Bool);
when N_And_Bool
| N_Or_Bool =>
Set_Left (Bool, Sem_Boolean (Get_Left (Bool)));
Set_Right (Bool, Sem_Boolean (Get_Right (Bool)));
return Bool;
when others =>
Error_Kind ("psl.sem_boolean", Bool);
end case;
end Sem_Boolean;
procedure Sem_Boolean (N : PSL_Node)
is
Bool : PSL_Node;
begin
Bool := Get_Boolean (N);
Bool := Sem_Boolean (Bool);
Set_Boolean (N, Bool);
end Sem_Boolean;
-- Used by Sem_Property to rewrite a property logical operator to a
-- boolean logical operator.
function Reduce_Logic_Binary_Node (Prop : PSL_Node; Bool_Kind : Nkind)
return PSL_Node
is
Res : PSL_Node;
begin
Res := Create_Node (Bool_Kind);
Set_Location (Res, Get_Location (Prop));
Set_Left (Res, Get_Left (Prop));
Set_Right (Res, Get_Right (Prop));
Free_Node (Prop);
return Res;
end Reduce_Logic_Binary_Node;
function Reduce_Logic_Unary_Node (Prop : PSL_Node; Bool_Kind : Nkind)
return PSL_Node
is
Res : PSL_Node;
begin
Res := Create_Node (Bool_Kind);
Set_Location (Res, Get_Location (Prop));
Set_Boolean (Res, Get_Property (Prop));
Free_Node (Prop);
return Res;
end Reduce_Logic_Unary_Node;
function Sem_Sequence (Seq : PSL_Node) return PSL_Node
is
Res : PSL_Node;
L, R : PSL_Node;
begin
case Get_Kind (Seq) is
when N_Braced_SERE =>
Res := Sem_Sequence (Get_SERE (Seq));
Set_SERE (Seq, Res);
return Seq;
when N_Clocked_SERE =>
Res := Sem_Sequence (Get_SERE (Seq));
Set_SERE (Seq, Res);
Sem_Boolean (Seq);
return Seq;
when N_Concat_SERE
| N_Fusion_SERE
| N_Within_SERE
| N_Or_Seq
| N_And_Seq
| N_Match_And_Seq =>
L := Sem_Sequence (Get_Left (Seq));
Set_Left (Seq, L);
R := Sem_Sequence (Get_Right (Seq));
Set_Right (Seq, R);
return Seq;
when N_Star_Repeat_Seq
| N_Plus_Repeat_Seq =>
Res := Get_Sequence (Seq);
if Res /= Null_PSL_Node then
Res := Sem_Sequence (Res);
Set_Sequence (Seq, Res);
end if;
return Seq;
when N_Equal_Repeat_Seq
| N_Goto_Repeat_Seq =>
Res := Get_Boolean (Seq);
if Res /= Null_PSL_Node then
Res := Sem_Boolean (Res);
Set_Boolean (Seq, Res);
end if;
return Seq;
when N_And_Bool
| N_Or_Bool
| N_Not_Bool =>
return Sem_Boolean (Seq);
when N_HDL_Expr =>
Res := Sem_Hdl_Expr (Seq);
case Get_Kind (Res) is
when N_Sequence_Instance
| N_Endpoint_Instance
| N_Boolean_Parameter
| N_Booleans =>
null;
when N_Property_Instance =>
Error_Msg_Sem
(+Res, "property instance not allowed in PSL sequence");
when others =>
Error_Kind ("psl.sem_sequence.hdl", Res);
end case;
return Res;
when others =>
Error_Kind ("psl.sem_sequence", Seq);
end case;
end Sem_Sequence;
function Sem_Property (Prop : PSL_Node; Top : Boolean := False)
return PSL_Node;
procedure Sem_Property (N : PSL_Node; Top : Boolean := False)
is
Prop : PSL_Node;
begin
Prop := Get_Property (N);
Prop := Sem_Property (Prop, Top);
Set_Property (N, Prop);
end Sem_Property;
procedure Sem_Number (N : PSL_Node)
is
Num : PSL_Node;
begin
Num := Get_Number (N);
-- FIXME: todo
null;
Set_Number (N, Num);
end Sem_Number;
function Sem_Property (Prop : PSL_Node; Top : Boolean := False)
return PSL_Node
is
Res : PSL_Node;
begin
case Get_Kind (Prop) is
when N_Braced_SERE =>
return Sem_Sequence (Prop);
when N_Star_Repeat_Seq
| N_Plus_Repeat_Seq =>
declare
Seq : PSL_Node;
begin
Seq := Get_Sequence (Prop);
if Seq /= Null_PSL_Node then
Seq := Sem_Sequence (Seq);
Set_Sequence (Prop, Seq);
end if;
return Prop;
end;
when N_Equal_Repeat_Seq
| N_Goto_Repeat_Seq =>
declare
B : PSL_Node;
begin
B := Get_Boolean (Prop);
B := Sem_Boolean (B);
Set_Boolean (Prop, B);
return Prop;
end;
when N_Always
| N_Never =>
-- By extension, clock_event is allowed within outermost
-- always/never.
Sem_Property (Prop, Top);
return Prop;
when N_Eventually =>
Sem_Property (Prop);
return Prop;
when N_Clock_Event =>
Sem_Property (Prop);
Sem_Boolean (Prop);
if not Top then
Error_Msg_Sem (+Prop, "inner clock event not supported");
end if;
return Prop;
when N_Abort =>
Sem_Property (Prop);
Sem_Boolean (Prop);
return Prop;
when N_Until
| N_Before =>
Res := Sem_Property (Get_Left (Prop));
Set_Left (Prop, Res);
Res := Sem_Property (Get_Right (Prop));
Set_Right (Prop, Res);
return Prop;
when N_Log_Imp_Prop
| N_Log_Equiv_Prop
| N_And_Prop
| N_Or_Prop =>
declare
L, R : PSL_Node;
begin
L := Sem_Property (Get_Left (Prop));
Set_Left (Prop, L);
R := Sem_Property (Get_Right (Prop));
Set_Right (Prop, R);
if Get_Psl_Type (L) = Type_Boolean
and then Get_Psl_Type (R) = Type_Boolean
then
case Get_Kind (Prop) is
when N_And_Prop =>
return Reduce_Logic_Binary_Node (Prop, N_And_Bool);
when N_Or_Prop =>
return Reduce_Logic_Binary_Node (Prop, N_Or_Bool);
when N_Log_Imp_Prop =>
return Reduce_Logic_Binary_Node (Prop, N_Imp_Bool);
when N_Log_Equiv_Prop =>
return Reduce_Logic_Binary_Node (Prop, N_Equiv_Bool);
when others =>
Error_Kind ("psl.sem_property(log)", Prop);
end case;
else
return Prop;
end if;
end;
when N_Overlap_Imp_Seq
| N_Imp_Seq =>
Res := Sem_Sequence (Get_Sequence (Prop));
Set_Sequence (Prop, Res);
Sem_Property (Prop);
return Prop;
when N_Paren_Prop =>
declare
Op : PSL_Node;
begin
Op := Get_Property (Prop);
Op := Sem_Property (Op);
Set_Property (Prop, Op);
if Get_Psl_Type (Op) = Type_Boolean then
return Reduce_Logic_Unary_Node (Prop, N_Paren_Bool);
else
return Prop;
end if;
end;
when N_Next =>
Sem_Number (Prop);
Sem_Property (Prop);
return Prop;
when N_Next_A | N_Next_E =>
-- FIXME: range.
Sem_Property (Prop);
return Prop;
when N_Next_Event =>
Sem_Number (Prop);
Sem_Boolean (Prop);
Sem_Property (Prop);
return Prop;
when N_Next_Event_A | N_Next_Event_E =>
-- FIXME: range.
Sem_Boolean (Prop);
Sem_Property (Prop);
return Prop;
when N_HDL_Expr =>
Res := Sem_Hdl_Expr (Prop);
if not Top and then Get_Kind (Res) = N_Property_Instance then
declare
Decl : constant PSL_Node := Get_Declaration (Res);
begin
if Decl /= Null_PSL_Node
and then Get_Global_Clock (Decl) /= Null_PSL_Node
then
Error_Msg_Sem
(+Prop, "property instance already has a clock");
end if;
end;
end if;
return Res;
when others =>
Error_Kind ("psl.sem_property", Prop);
end case;
end Sem_Property;
-- Extract the clock from PROP.
procedure Extract_Clock (Prop : in out PSL_Node; Clk : out PSL_Node)
is
Child : PSL_Node;
begin
Clk := Null_PSL_Node;
case Get_Kind (Prop) is
when N_Clock_Event =>
Clk := Get_Boolean (Prop);
Prop := Get_Property (Prop);
when N_Clocked_SERE =>
Clk := Get_Boolean (Prop);
Prop := Get_SERE (Prop);
when N_Always
| N_Never =>
Child := Get_Property (Prop);
if Get_Kind (Child) = N_Clock_Event then
Set_Property (Prop, Get_Property (Child));
Clk := Get_Boolean (Child);
end if;
when N_Property_Instance =>
Child := Get_Declaration (Prop);
Clk := Get_Global_Clock (Child);
when others =>
null;
end case;
end Extract_Clock;
-- Sem a property/sequence/endpoint declaration.
procedure Sem_Psl_Declaration (Stmt : Iir)
is
use Sem_Scopes;
Decl : constant PSL_Node := Get_Psl_Declaration (Stmt);
Prop : PSL_Node;
Clk : PSL_Node;
Formal : PSL_Node;
El : Iir;
begin
Sem_Scopes.Add_Name (Stmt);
Xref_Decl (Stmt);
Open_Declarative_Region;
-- Make formal parameters visible.
Formal := Get_Parameter_List (Decl);
while Formal /= Null_PSL_Node loop
El := Create_Iir (Iir_Kind_Psl_Declaration);
Set_Location (El, Get_Location (Formal));
Set_Identifier (El, Get_Identifier (Formal));
Set_Psl_Declaration (El, Formal);
Sem_Scopes.Add_Name (El);
Xref_Decl (El);
Set_Visible_Flag (El, True);
Formal := Get_Chain (Formal);
end loop;
case Get_Kind (Decl) is
when N_Property_Declaration =>
-- FIXME: sem formal list
Prop := Get_Property (Decl);
Prop := Sem_Property (Prop, True);
Extract_Clock (Prop, Clk);
Set_Property (Decl, Prop);
Set_Global_Clock (Decl, Clk);
-- Check simple subset restrictions.
PSL.Subsets.Check_Simple (Prop);
when N_Sequence_Declaration
| N_Endpoint_Declaration =>
-- FIXME: sem formal list, do not allow property parameter.
Prop := Get_Sequence (Decl);
Prop := Sem_Sequence (Prop);
Set_Sequence (Decl, Prop);
PSL.Subsets.Check_Simple (Prop);
when others =>
Error_Kind ("sem_psl_declaration", Decl);
end case;
Set_Visible_Flag (Stmt, True);
Close_Declarative_Region;
end Sem_Psl_Declaration;
procedure Sem_Psl_Endpoint_Declaration (Stmt : Iir)
is
Decl : constant PSL_Node := Get_Psl_Declaration (Stmt);
Prop : PSL_Node;
begin
Sem_Scopes.Add_Name (Stmt);
Xref_Decl (Stmt);
pragma Assert (Get_Parameter_List (Decl) = Null_PSL_Node);
pragma Assert (Get_Kind (Decl) = N_Endpoint_Declaration);
Prop := Get_Sequence (Decl);
Prop := Sem_Sequence (Prop);
Sem_Psl_Directive_Clock (Stmt, Prop);
Set_Sequence (Decl, Prop);
PSL.Subsets.Check_Simple (Prop);
-- Endpoints are considered as an HDL declaration and must have a
-- type.
Set_Type (Stmt, Vhdl.Std_Package.Boolean_Type_Definition);
Set_Expr_Staticness (Stmt, None);
Set_Visible_Flag (Stmt, True);
end Sem_Psl_Endpoint_Declaration;
function Rewrite_As_Boolean_Expression (Prop : PSL_Node) return Iir
is
function Rewrite_Dyadic_Operator
(Expr : PSL_Node; Kind : Iir_Kind) return Iir
is
Res : Iir;
begin
Res := Create_Iir (Kind);
Set_Location (Res, Get_Location (Expr));
Set_Left (Res, Rewrite_As_Boolean_Expression (Get_Left (Expr)));
Set_Right (Res, Rewrite_As_Boolean_Expression (Get_Right (Expr)));
return Res;
end Rewrite_Dyadic_Operator;
function Rewrite_Monadic_Operator
(Expr : PSL_Node; Kind : Iir_Kind) return Iir
is
Res : Iir;
begin
Res := Create_Iir (Kind);
Set_Location (Res, Get_Location (Expr));
Set_Operand (Res, Rewrite_As_Boolean_Expression (Get_Boolean (Expr)));
return Res;
end Rewrite_Monadic_Operator;
begin
case Get_Kind (Prop) is
when N_HDL_Expr
| N_HDL_Bool =>
return Get_HDL_Node (Prop);
when N_And_Bool =>
return Rewrite_Dyadic_Operator (Prop, Iir_Kind_And_Operator);
when N_Or_Bool =>
return Rewrite_Dyadic_Operator (Prop, Iir_Kind_Or_Operator);
when N_Not_Bool =>
return Rewrite_Monadic_Operator (Prop, Iir_Kind_Not_Operator);
when N_Paren_Bool =>
declare
Expr : constant PSL_Node := Get_Boolean (Prop);
Hexpr : Iir;
Res : Iir;
begin
Res := Create_Iir (Iir_Kind_Parenthesis_Expression);
Set_Location (Res, Get_Location (Prop));
case Get_Kind (Expr) is
when N_HDL_Expr
| N_HDL_Bool =>
Hexpr := Get_HDL_Node (Expr);
Set_Expression (Res, Hexpr);
Set_Type (Res, Get_Type (Hexpr));
when others =>
Hexpr := Rewrite_As_Boolean_Expression (Expr);
Set_Expression (Res, Hexpr);
end case;
return Res;
end;
when others =>
Error_Kind ("rewrite_as_boolean_expression", Prop);
end case;
end Rewrite_As_Boolean_Expression;
function Rewrite_As_Concurrent_Assertion (Stmt : Iir) return Iir
is
Res : Iir;
Cond : Iir;
begin
Res := Create_Iir (Iir_Kind_Concurrent_Assertion_Statement);
Set_Location (Res, Get_Location (Stmt));
Cond := Rewrite_As_Boolean_Expression (Get_Psl_Property (Stmt));
if Get_Type (Cond) = Null_Iir then
Cond := Sem_Expr.Sem_Condition (Cond);
else
Cond := Sem_Expr.Sem_Condition_Pass2 (Cond);
end if;
Cond := Eval_Expr_If_Static (Cond);
Set_Assertion_Condition (Res, Cond);
Set_Label (Res, Get_Label (Stmt));
Set_Severity_Expression (Res, Get_Severity_Expression (Stmt));
Set_Report_Expression (Res, Get_Report_Expression (Stmt));
Set_Postponed_Flag (Res, Get_Postponed_Flag (Stmt));
Set_Parent (Res, Get_Parent (Stmt));
Set_Chain (Res, Get_Chain (Stmt));
return Res;
end Rewrite_As_Concurrent_Assertion;
-- Return True iff EXPR is a boolean expression.
function Is_Boolean_Assertion (Expr : PSL_Node) return Boolean is
begin
case Get_Kind (Expr) is
when N_HDL_Expr
| N_HDL_Bool =>
return True;
when N_And_Bool | N_Or_Bool | N_Not_Bool | N_Paren_Bool =>
return True;
when others =>
return False;
end case;
end Is_Boolean_Assertion;
procedure Sem_Psl_Directive_Clock (Stmt : Iir; Prop : in out PSL_Node)
is
Clk : PSL_Node;
begin
Extract_Clock (Prop, Clk);
if Clk = Null_PSL_Node then
if Current_Psl_Default_Clock = Null_Iir then
Error_Msg_Sem (+Stmt, "no clock for PSL directive");
Clk := Null_PSL_Node;
else
Clk := Get_Psl_Boolean (Current_Psl_Default_Clock);
end if;
end if;
Set_PSL_Clock (Stmt, Clk);
end Sem_Psl_Directive_Clock;
function Sem_Psl_Assert_Directive
(Stmt : Iir; Can_Rewrite : Boolean) return Iir
is
Prop : PSL_Node;
Res : Iir;
begin
pragma Assert (Get_Kind (Stmt) = Iir_Kind_Psl_Assert_Directive);
-- Sem report and severity expressions.
Sem_Report_Statement (Stmt);
Prop := Get_Psl_Property (Stmt);
Prop := Sem_Property (Prop, True);
Set_Psl_Property (Stmt, Prop);
if Can_Rewrite and then Is_Boolean_Assertion (Prop) then
-- This is a simple assertion. Convert to a non-PSL statement, as
-- the handling is simpler (and the assertion doesn't need a clock).
Res := Rewrite_As_Concurrent_Assertion (Stmt);
Free_Iir (Stmt);
return Res;
end if;
if Get_Postponed_Flag (Stmt) then
Error_Msg_Sem (+Stmt, "PSL assertions cannot be postponed");
Set_Postponed_Flag (Stmt, False);
end if;
-- Properties must be clocked.
Sem_Psl_Directive_Clock (Stmt, Prop);
Set_Psl_Property (Stmt, Prop);
-- Check simple subset restrictions.
PSL.Subsets.Check_Simple (Prop);
return Stmt;
end Sem_Psl_Assert_Directive;
procedure Sem_Psl_Assume_Directive (Stmt : Iir)
is
Prop : PSL_Node;
begin
Prop := Get_Psl_Property (Stmt);
Prop := Sem_Property (Prop, True);
Set_Psl_Property (Stmt, Prop);
-- Properties must be clocked.
Sem_Psl_Directive_Clock (Stmt, Prop);
Set_Psl_Property (Stmt, Prop);
-- Check simple subset restrictions.
PSL.Subsets.Check_Simple (Prop);
end Sem_Psl_Assume_Directive;
procedure Sem_Psl_Sequence (Stmt : Iir)
is
Seq : PSL_Node;
begin
Seq := Get_Psl_Sequence (Stmt);
Seq := Sem_Sequence (Seq);
-- Expect a pure sequence.
case Get_Kind (Seq) is
when N_Sequence_Instance
| N_Star_Repeat_Seq
| N_Goto_Repeat_Seq
| N_Plus_Repeat_Seq
| N_Equal_Repeat_Seq
| N_Braced_SERE
| N_Clocked_SERE =>
null;
when others =>
Error_Msg_Sem (+Seq, "sequence expected here");
end case;
-- Properties must be clocked.
Sem_Psl_Directive_Clock (Stmt, Seq);
Set_Psl_Sequence (Stmt, Seq);
-- Check simple subset restrictions.
PSL.Subsets.Check_Simple (Seq);
end Sem_Psl_Sequence;
procedure Sem_Psl_Cover_Directive (Stmt : Iir) is
begin
Sem_Report_Expression (Stmt);
Sem_Psl_Sequence (Stmt);
end Sem_Psl_Cover_Directive;
procedure Sem_Psl_Restrict_Directive (Stmt : Iir) is
begin
Sem_Psl_Sequence (Stmt);
end Sem_Psl_Restrict_Directive;
procedure Sem_Psl_Default_Clock (Stmt : Iir)
is
Expr : PSL_Node;
begin
if Current_Psl_Default_Clock /= Null_Iir
and then Get_Parent (Current_Psl_Default_Clock) = Get_Parent (Stmt)
then
Report_Start_Group;
Error_Msg_Sem
(+Stmt, "redeclaration of PSL default clock in the same region");
Error_Msg_Sem
(+Current_Psl_Default_Clock,
" (previous default clock declaration)");
Report_End_Group;
end if;
Expr := Sem_Boolean (Get_Psl_Boolean (Stmt));
Expr := PSL.Rewrites.Rewrite_Boolean (Expr);
Set_Psl_Boolean (Stmt, Expr);
Current_Psl_Default_Clock := Stmt;
end Sem_Psl_Default_Clock;
function Sem_Psl_Instance_Name (Name : Iir) return Iir
is
Prefix : constant Iir := Get_Prefix (Name);
Ent : constant Iir := Get_Named_Entity (Prefix);
Decl : constant PSL_Node := Get_Psl_Declaration (Ent);
Formal : PSL_Node;
Assoc : Iir;
Res : PSL_Node;
Last_Assoc : PSL_Node;
Assoc2 : PSL_Node;
Actual : Iir;
Psl_Actual : PSL_Node;
Res2 : Iir;
begin
pragma Assert (Get_Kind (Ent) = Iir_Kind_Psl_Declaration
or Get_Kind (Ent) = Iir_Kind_Psl_Endpoint_Declaration);
case Get_Kind (Decl) is
when N_Property_Declaration =>
Res := Create_Node (N_Property_Instance);
when N_Sequence_Declaration =>
Res := Create_Node (N_Sequence_Instance);
when N_Endpoint_Declaration =>
Res := Create_Node (N_Endpoint_Instance);
when others =>
Error_Msg_Sem (+Name, "can only instantiate a psl declaration");
return Null_Iir;
end case;
Set_Declaration (Res, Decl);
Set_Location (Res, Get_Location (Name));
Formal := Get_Parameter_List (Decl);
Assoc := Get_Association_Chain (Name);
Last_Assoc := Null_PSL_Node;
while Formal /= Null_PSL_Node loop
if Assoc = Null_Iir then
Error_Msg_Sem (+Name, "not enough association");
exit;
end if;
if Get_Kind (Assoc) /= Iir_Kind_Association_Element_By_Expression then
Error_Msg_Sem
(+Assoc, "open or individual association not allowed");
elsif Get_Formal (Assoc) /= Null_Iir then
Error_Msg_Sem (+Assoc, "named association not allowed in psl");
else
Actual := Get_Actual (Assoc);
-- FIXME: currently only boolean are parsed.
Actual := Sem_Expr.Sem_Expression (Actual, Null_Iir);
if Get_Kind (Actual) in Iir_Kinds_Name then
Actual := Get_Named_Entity (Actual);
end if;
Psl_Actual := PSL.Hash.Get_PSL_Node
(HDL_Node (Actual), Get_Location (Actual));
end if;
Assoc2 := Create_Node (N_Actual);
Set_Location (Assoc2, Get_Location (Assoc));
Set_Formal (Assoc2, Formal);
Set_Actual (Assoc2, Psl_Actual);
if Last_Assoc = Null_PSL_Node then
Set_Association_Chain (Res, Assoc2);
else
Set_Chain (Last_Assoc, Assoc2);
end if;
Last_Assoc := Assoc2;
Formal := Get_Chain (Formal);
Assoc := Get_Chain (Assoc);
end loop;
if Assoc /= Null_Iir then
Error_Msg_Sem (+Name, "too many association");
end if;
Res2 := Create_Iir (Iir_Kind_Psl_Expression);
Set_Psl_Expression (Res2, Res);
Location_Copy (Res2, Name);
return Res2;
end Sem_Psl_Instance_Name;
-- Called by sem_names to analyze a psl name.
function Sem_Psl_Name (Name : Iir) return Iir is
begin
case Get_Kind (Name) is
when Iir_Kind_Parenthesis_Name =>
return Sem_Psl_Instance_Name (Name);
when others =>
Error_Kind ("sem_psl_name", Name);
end case;
return Null_Iir;
end Sem_Psl_Name;
procedure Sem_Hierarchical_Name (Hier_Name : Iir; Unit : Iir)
is
Entity_Name : Iir;
Design_Entity : Iir;
Lib_Entity : Iir;
Arch_Name : Iir;
Arch : Iir;
Library : Iir_Library_Declaration;
begin
Entity_Name := Get_Entity_Name (Hier_Name);
Library := Get_Library (Get_Design_File (Get_Design_Unit (Unit)));
Design_Entity := Sem_Lib.Load_Primary_Unit
(Library, Get_Identifier (Entity_Name), Entity_Name);
if Design_Entity = Null_Iir then
Error_Msg_Sem (+Entity_Name,
"entity %n was not analysed", +Entity_Name);
return;
end if;
Lib_Entity := Get_Library_Unit (Design_Entity);
if Get_Kind (Lib_Entity) /= Iir_Kind_Entity_Declaration then
Error_Msg_Sem (+Entity_Name,
"name %i does not denote an entity", +Entity_Name);
return;
end if;
Set_Named_Entity (Entity_Name, Lib_Entity);
Xrefs.Xref_Ref (Entity_Name, Lib_Entity);
Arch_Name := Get_Architecture (Hier_Name);
if Arch_Name /= Null_Iir then
Arch := Sem_Lib.Load_Secondary_Unit
(Design_Entity, Get_Identifier (Arch_Name), Arch_Name);
if Arch /= Null_Iir then
Set_Named_Entity (Arch_Name, Get_Library_Unit (Arch));
end if;
end if;
end Sem_Hierarchical_Name;
procedure Sem_Psl_Verification_Unit (Unit : Iir)
is
Hier_Name : constant Iir := Get_Hierarchical_Name (Unit);
Entity : Iir;
Arch : Iir;
Item : Iir;
Prev_Item : Iir;
Attr_Spec_Chain : Iir;
begin
if Hier_Name = Null_Iir then
-- Hierarchical name is optional.
-- If the unit is not bound, the names are not bound too.
return;
end if;
Sem_Hierarchical_Name (Hier_Name, Unit);
-- Import declarations.
Entity := Get_Entity_Name (Hier_Name);
if Entity = Null_Iir then
return;
end if;
Entity := Get_Named_Entity (Entity);
if Entity = Null_Iir then
return;
end if;
Arch := Get_Architecture (Hier_Name);
if Arch /= Null_Iir then
Arch := Get_Named_Entity (Arch);
if Arch = Null_Iir then
return;
end if;
end if;
Sem_Scopes.Add_Context_Clauses (Get_Design_Unit (Entity));
Sem_Scopes.Open_Declarative_Region;
Set_Is_Within_Flag (Entity, True);
Sem_Scopes.Add_Entity_Declarations (Entity);
if Arch /= Null_Iir then
Sem_Scopes.Open_Scope_Extension;
Sem_Scopes.Extend_Scope_Of_Block_Declarations (Arch);
end if;
Attr_Spec_Chain := Null_Iir;
Prev_Item := Null_Iir;
Item := Get_Vunit_Item_Chain (Unit);
while Item /= Null_Iir loop
case Get_Kind (Item) is
when Iir_Kind_Psl_Default_Clock =>
Sem_Psl_Default_Clock (Item);
when Iir_Kind_Psl_Assert_Directive =>
Item := Sem_Psl_Assert_Directive (Item, False);
when Iir_Kind_Psl_Assume_Directive =>
Sem_Psl_Assume_Directive (Item);
when Iir_Kind_Psl_Restrict_Directive =>
Sem_Psl_Restrict_Directive (Item);
when Iir_Kind_Psl_Cover_Directive =>
Sem_Psl_Cover_Directive (Item);
when Iir_Kind_Signal_Declaration
| Iir_Kind_Function_Declaration
| Iir_Kind_Procedure_Declaration
| Iir_Kind_Function_Body
| Iir_Kind_Procedure_Body
| Iir_Kind_Attribute_Declaration
| Iir_Kind_Attribute_Specification =>
Sem_Decls.Sem_Declaration
(Item, Prev_Item, False, Attr_Spec_Chain);
when Iir_Kinds_Concurrent_Signal_Assignment
| Iir_Kinds_Process_Statement
| Iir_Kinds_Generate_Statement
| Iir_Kind_Block_Statement
| Iir_Kind_Concurrent_Procedure_Call_Statement
| Iir_Kind_Component_Instantiation_Statement =>
Sem_Stmts.Sem_Concurrent_Statement (Item, False);
when others =>
Error_Kind ("sem_psl_verification_unit", Item);
end case;
if Prev_Item = Null_Iir then
Set_Vunit_Item_Chain (Unit, Item);
else
Set_Chain (Prev_Item, Item);
end if;
Prev_Item := Item;
Item := Get_Chain (Item);
end loop;
if Arch /= Null_Iir then
Sem_Scopes.Close_Scope_Extension;
end if;
Sem_Scopes.Close_Declarative_Region;
Set_Is_Within_Flag (Entity, False);
end Sem_Psl_Verification_Unit;
end Vhdl.Sem_Psl;
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