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|
-- Statements synthesis.
-- Copyright (C) 2017 Tristan Gingold
--
-- This file is part of GHDL.
--
-- This program is free software: you can redistribute it and/or modify
-- it under the terms of the GNU General Public License as published by
-- the Free Software Foundation, either version 2 of the License, or
-- (at your option) any later version.
--
-- This program is distributed in the hope that it will be useful,
-- but WITHOUT ANY WARRANTY; without even the implied warranty of
-- MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
-- GNU General Public License for more details.
--
-- You should have received a copy of the GNU General Public License
-- along with this program. If not, see <gnu.org/licenses>.
with Ada.Unchecked_Deallocation;
with Grt.Types; use Grt.Types;
with Grt.Algos;
with Grt.Severity; use Grt.Severity;
with Areapools;
with Name_Table;
with Std_Names;
with Errorout; use Errorout;
with Files_Map;
with Simple_IO;
with Vhdl.Errors; use Vhdl.Errors;
with Vhdl.Sem_Expr;
with Vhdl.Sem_Inst;
with Vhdl.Utils; use Vhdl.Utils;
with Vhdl.Std_Package;
with Vhdl.Evaluation;
with Vhdl.Ieee.Std_Logic_1164;
with PSL.Types;
with PSL.NFAs;
with Synth.Memtype; use Synth.Memtype;
with Synth.Errors; use Synth.Errors;
with Synth.Vhdl_Decls; use Synth.Vhdl_Decls;
with Synth.Vhdl_Expr; use Synth.Vhdl_Expr;
with Synth.Vhdl_Insts; use Synth.Vhdl_Insts;
with Synth.Source;
with Synth.Vhdl_Static_Proc;
with Synth.Vhdl_Heap;
with Synth.Flags;
with Synth.Debugger;
with Netlists.Builders; use Netlists.Builders;
with Netlists.Folds; use Netlists.Folds;
with Netlists.Gates; use Netlists.Gates;
with Netlists.Utils; use Netlists.Utils;
with Netlists.Locations; use Netlists.Locations;
package body Synth.Vhdl_Stmts is
procedure Synth_Sequential_Statements
(C : in out Seq_Context; Stmts : Node);
procedure Set_Location (N : Net; Loc : Node)
renames Synth.Source.Set_Location;
function Synth_Waveform (Syn_Inst : Synth_Instance_Acc;
Wf : Node;
Targ_Type : Type_Acc) return Valtyp
is
Res : Valtyp;
begin
if Get_Kind (Wf) = Iir_Kind_Unaffected_Waveform then
-- TODO
raise Internal_Error;
end if;
if Get_Chain (Wf) /= Null_Node then
-- Warning.
null;
end if;
if Get_Time (Wf) /= Null_Node then
-- Warning
null;
end if;
if Targ_Type = null then
return Synth_Expression (Syn_Inst, Get_We_Value (Wf));
else
Res := Synth_Expression_With_Type
(Syn_Inst, Get_We_Value (Wf), Targ_Type);
Res := Synth_Subtype_Conversion
(Get_Build (Syn_Inst), Res, Targ_Type, False, Wf);
return Res;
end if;
end Synth_Waveform;
procedure Synth_Assignment_Prefix (Syn_Inst : Synth_Instance_Acc;
Pfx : Node;
Dest_Base : out Valtyp;
Dest_Typ : out Type_Acc;
Dest_Off : out Value_Offsets;
Dest_Dyn : out Dyn_Name) is
begin
case Get_Kind (Pfx) is
when Iir_Kind_Simple_Name =>
Synth_Assignment_Prefix (Syn_Inst, Get_Named_Entity (Pfx),
Dest_Base, Dest_Typ, Dest_Off, Dest_Dyn);
when Iir_Kind_Interface_Signal_Declaration
| Iir_Kind_Variable_Declaration
| Iir_Kind_Interface_Variable_Declaration
| Iir_Kind_Signal_Declaration
| Iir_Kind_Anonymous_Signal_Declaration
| Iir_Kind_Interface_Constant_Declaration
| Iir_Kind_Constant_Declaration
| Iir_Kind_File_Declaration
| Iir_Kind_Interface_File_Declaration
| Iir_Kind_Object_Alias_Declaration =>
declare
Targ : constant Valtyp := Get_Value (Syn_Inst, Pfx);
begin
Dest_Dyn := No_Dyn_Name;
Dest_Typ := Targ.Typ;
if Targ.Val.Kind = Value_Alias then
-- Replace alias by the aliased name.
Dest_Base := (Targ.Val.A_Typ, Targ.Val.A_Obj);
Dest_Off := Targ.Val.A_Off;
else
Dest_Base := Targ;
Dest_Off := (0, 0);
end if;
end;
when Iir_Kind_Function_Call =>
Dest_Base := Synth_Expression (Syn_Inst, Pfx);
Dest_Typ := Dest_Base.Typ;
Dest_Off := (0, 0);
Dest_Dyn := No_Dyn_Name;
when Iir_Kind_Indexed_Name =>
declare
Voff : Net;
Off : Value_Offsets;
begin
Synth_Assignment_Prefix
(Syn_Inst, Get_Prefix (Pfx),
Dest_Base, Dest_Typ, Dest_Off, Dest_Dyn);
Strip_Const (Dest_Base);
Synth_Indexed_Name (Syn_Inst, Pfx, Dest_Typ, Voff, Off);
if Voff = No_Net then
-- Static index.
Dest_Off := Dest_Off + Off;
else
-- Dynamic index.
if Dest_Dyn.Voff = No_Net then
-- The first one.
Dest_Dyn := (Pfx_Off => Dest_Off,
Pfx_Typ => Dest_Typ,
Voff => Voff);
Dest_Off := Off;
else
-- Nested one.
-- FIXME
Dest_Off := Dest_Off + Off;
-- if Dest_Off /= (0, 0) then
-- Error_Msg_Synth (+Pfx, "nested memory not supported");
-- end if;
Dest_Dyn.Voff := Build_Addidx
(Get_Build (Syn_Inst), Dest_Dyn.Voff, Voff);
end if;
end if;
Dest_Typ := Get_Array_Element (Dest_Typ);
end;
when Iir_Kind_Selected_Element =>
declare
Idx : constant Iir_Index32 :=
Get_Element_Position (Get_Named_Entity (Pfx));
begin
Synth_Assignment_Prefix
(Syn_Inst, Get_Prefix (Pfx),
Dest_Base, Dest_Typ, Dest_Off, Dest_Dyn);
Dest_Off.Net_Off :=
Dest_Off.Net_Off + Dest_Typ.Rec.E (Idx + 1).Boff;
Dest_Off.Mem_Off :=
Dest_Off.Mem_Off + Dest_Typ.Rec.E (Idx + 1).Moff;
Dest_Typ := Dest_Typ.Rec.E (Idx + 1).Typ;
end;
when Iir_Kind_Slice_Name =>
declare
Pfx_Bnd : Bound_Type;
El_Typ : Type_Acc;
Res_Bnd : Bound_Type;
Sl_Voff : Net;
Sl_Off : Value_Offsets;
begin
Synth_Assignment_Prefix
(Syn_Inst, Get_Prefix (Pfx),
Dest_Base, Dest_Typ, Dest_Off, Dest_Dyn);
Strip_Const (Dest_Base);
Get_Onedimensional_Array_Bounds (Dest_Typ, Pfx_Bnd, El_Typ);
Synth_Slice_Suffix (Syn_Inst, Pfx, Pfx_Bnd, El_Typ,
Res_Bnd, Sl_Voff, Sl_Off);
if Sl_Voff = No_Net then
-- Fixed slice.
Dest_Typ := Create_Onedimensional_Array_Subtype
(Dest_Typ, Res_Bnd);
Dest_Off.Net_Off := Dest_Off.Net_Off + Sl_Off.Net_Off;
Dest_Off.Mem_Off := Dest_Off.Mem_Off + Sl_Off.Mem_Off;
else
-- Variable slice.
if Dest_Dyn.Voff = No_Net then
-- First one.
Dest_Dyn := (Pfx_Off => Dest_Off,
Pfx_Typ => Dest_Typ,
Voff => Sl_Voff);
Dest_Off := Sl_Off;
else
-- Nested.
if Dest_Off /= (0, 0) then
Error_Msg_Synth (+Pfx, "nested memory not supported");
end if;
Dest_Dyn.Voff := Build_Addidx
(Get_Build (Syn_Inst), Dest_Dyn.Voff, Sl_Voff);
end if;
Dest_Typ := Create_Slice_Type (Res_Bnd.Len, El_Typ);
end if;
end;
when Iir_Kind_Implicit_Dereference
| Iir_Kind_Dereference =>
Synth_Assignment_Prefix
(Syn_Inst, Get_Prefix (Pfx),
Dest_Base, Dest_Typ, Dest_Off, Dest_Dyn);
if Dest_Off /= (0, 0) and then Dest_Dyn.Voff /= No_Net then
raise Internal_Error;
end if;
Dest_Base := Vhdl_Heap.Synth_Dereference (Read_Access (Dest_Base));
Dest_Typ := Dest_Base.Typ;
when others =>
Error_Kind ("synth_assignment_prefix", Pfx);
end case;
end Synth_Assignment_Prefix;
type Target_Kind is
(
-- The target is an object or a static part of it.
Target_Simple,
-- The target is an aggregate.
Target_Aggregate,
-- The assignment is dynamically indexed.
Target_Memory
);
type Target_Info (Kind : Target_Kind := Target_Simple) is record
-- In all cases, the type of the target is known or computed.
Targ_Type : Type_Acc;
case Kind is
when Target_Simple =>
-- For a simple target, the destination is known.
Obj : Valtyp;
Off : Value_Offsets;
when Target_Aggregate =>
-- For an aggregate: the type is computed and the details will
-- be handled at the assignment.
Aggr : Node;
when Target_Memory =>
-- For a memory: the destination is known.
Mem_Obj : Valtyp;
-- The dynamic offset.
Mem_Dyn : Dyn_Name;
-- Offset of the data to be accessed from the memory.
Mem_Doff : Uns32;
end case;
end record;
type Target_Info_Array is array (Natural range <>) of Target_Info;
function Synth_Aggregate_Target_Type (Syn_Inst : Synth_Instance_Acc;
Target : Node) return Type_Acc
is
Targ_Type : constant Node := Get_Type (Target);
Base_Type : constant Node := Get_Base_Type (Targ_Type);
Base_Typ : Type_Acc;
Bnd : Bound_Type;
Len : Uns32;
Res : Type_Acc;
begin
Base_Typ := Get_Subtype_Object (Syn_Inst, Base_Type);
-- It's a basetype, so not bounded.
pragma Assert (Base_Typ.Kind = Type_Unbounded_Vector);
if Is_Fully_Constrained_Type (Targ_Type) then
-- If the aggregate subtype is known, just use it.
Bnd := Vhdl_Expr.Synth_Array_Bounds (Syn_Inst, Targ_Type, 1);
else
-- Ok, so the subtype of the aggregate is not known, in general
-- because the length of an element is not known. That's with
-- vhdl-2008.
Len := 0;
declare
Choice : Node;
El : Node;
El_Typ : Type_Acc;
begin
Choice := Get_Association_Choices_Chain (Target);
while Choice /= Null_Node loop
pragma Assert (Get_Kind (Choice) = Iir_Kind_Choice_By_None);
El := Get_Associated_Expr (Choice);
El_Typ := Synth_Type_Of_Object (Syn_Inst, El);
Bnd := Get_Array_Bound (El_Typ, 1);
Len := Len + Bnd.Len;
Choice := Get_Chain (Choice);
end loop;
end;
-- Compute the range.
declare
Idx_Type : constant Node := Get_Index_Type (Base_Type, 0);
Idx_Typ : Type_Acc;
begin
Idx_Typ := Get_Subtype_Object (Syn_Inst, Idx_Type);
Bnd := (Dir => Idx_Typ.Drange.Dir,
Left => Int32 (Idx_Typ.Drange.Left),
Right => 0,
Len => Len);
case Bnd.Dir is
when Dir_To =>
Bnd.Right := Bnd.Left + Int32 (Len);
when Dir_Downto =>
Bnd.Right := Bnd.Left - Int32 (Len);
end case;
end;
end if;
-- Compute the type.
case Base_Typ.Kind is
when Type_Unbounded_Vector =>
Res := Create_Vector_Type (Bnd, Base_Typ.Uvec_El);
when others =>
raise Internal_Error;
end case;
return Res;
end Synth_Aggregate_Target_Type;
function Synth_Target (Syn_Inst : Synth_Instance_Acc;
Target : Node) return Target_Info is
begin
case Get_Kind (Target) is
when Iir_Kind_Aggregate =>
return Target_Info'(Kind => Target_Aggregate,
Targ_Type => Synth_Aggregate_Target_Type
(Syn_Inst, Target),
Aggr => Target);
when Iir_Kind_Simple_Name
| Iir_Kind_Selected_Element
| Iir_Kind_Interface_Signal_Declaration
| Iir_Kind_Variable_Declaration
| Iir_Kind_Signal_Declaration
| Iir_Kind_Anonymous_Signal_Declaration
| Iir_Kind_Indexed_Name
| Iir_Kind_Slice_Name
| Iir_Kind_Dereference =>
declare
Base : Valtyp;
Typ : Type_Acc;
Off : Value_Offsets;
Dyn : Dyn_Name;
begin
Synth_Assignment_Prefix (Syn_Inst, Target, Base, Typ, Off, Dyn);
if Dyn.Voff = No_Net then
-- FIXME: check index.
return Target_Info'(Kind => Target_Simple,
Targ_Type => Typ,
Obj => Base,
Off => Off);
else
return Target_Info'(Kind => Target_Memory,
Targ_Type => Typ,
Mem_Obj => Base,
Mem_Dyn => Dyn,
Mem_Doff => Off.Net_Off);
end if;
end;
when others =>
Error_Kind ("synth_target", Target);
end case;
end Synth_Target;
procedure Synth_Assignment (Syn_Inst : Synth_Instance_Acc;
Target : Target_Info;
Val : Valtyp;
Loc : Node);
-- Extract a part of VAL from a target aggregate at offset OFF (offset
-- in the array).
function Aggregate_Extract (Ctxt : Context_Acc;
Val : Valtyp;
Off : Uns32;
Typ : Type_Acc;
Loc : Node) return Valtyp
is
El_Typ : constant Type_Acc := Get_Array_Element (Val.Typ);
begin
case Val.Val.Kind is
when Value_Net
| Value_Wire =>
declare
N : Net;
begin
N := Build2_Extract
(Ctxt, Get_Net (Ctxt, Val), Off * El_Typ.W, Typ.W);
Set_Location (N, Loc);
return Create_Value_Net (N, Typ);
end;
when Value_Memory =>
declare
Res : Valtyp;
begin
Res := Create_Value_Memory (Typ);
-- Need to reverse offsets.
Copy_Memory
(Res.Val.Mem,
Val.Val.Mem + (Val.Typ.Sz - Size_Type (Off + 1) * El_Typ.Sz),
Typ.Sz);
return Res;
end;
when others =>
raise Internal_Error;
end case;
end Aggregate_Extract;
procedure Synth_Assignment_Aggregate (Syn_Inst : Synth_Instance_Acc;
Target : Node;
Target_Typ : Type_Acc;
Val : Valtyp;
Loc : Node)
is
Ctxt : constant Context_Acc := Get_Build (Syn_Inst);
Targ_Bnd : constant Bound_Type := Get_Array_Bound (Target_Typ, 1);
Choice : Node;
Assoc : Node;
Pos : Uns32;
Targ_Info : Target_Info;
begin
Choice := Get_Association_Choices_Chain (Target);
Pos := Targ_Bnd.Len;
while Is_Valid (Choice) loop
Assoc := Get_Associated_Expr (Choice);
case Get_Kind (Choice) is
when Iir_Kind_Choice_By_None =>
Targ_Info := Synth_Target (Syn_Inst, Assoc);
if Get_Element_Type_Flag (Choice) then
Pos := Pos - 1;
else
Pos := Pos - Get_Array_Bound (Targ_Info.Targ_Type, 1).Len;
end if;
Synth_Assignment
(Syn_Inst, Targ_Info,
Aggregate_Extract (Ctxt, Val, Pos,
Targ_Info.Targ_Type, Assoc),
Loc);
when others =>
Error_Kind ("synth_assignment_aggregate", Choice);
end case;
Choice := Get_Chain (Choice);
end loop;
end Synth_Assignment_Aggregate;
procedure Synth_Assignment (Syn_Inst : Synth_Instance_Acc;
Target : Target_Info;
Val : Valtyp;
Loc : Node)
is
Ctxt : constant Context_Acc := Get_Build (Syn_Inst);
V : Valtyp;
begin
V := Synth_Subtype_Conversion (Ctxt, Val, Target.Targ_Type, False, Loc);
pragma Unreferenced (Val);
if V = No_Valtyp then
-- In case of error.
return;
end if;
case Target.Kind is
when Target_Aggregate =>
Synth_Assignment_Aggregate
(Syn_Inst, Target.Aggr, Target.Targ_Type, V, Loc);
when Target_Simple =>
if V.Typ.Sz = 0 then
-- If there is nothing to assign (like a null slice),
-- return now.
return;
end if;
if Target.Obj.Val.Kind = Value_Wire then
if Is_Static (V.Val)
and then V.Typ.Sz = Target.Obj.Typ.Sz
then
pragma Assert (Target.Off = (0, 0));
Phi_Assign_Static
(Target.Obj.Val.W, Unshare (Get_Memtyp (V)));
else
if V.Typ.W = 0 then
-- Forget about null wires.
return;
end if;
Phi_Assign_Net (Ctxt, Target.Obj.Val.W,
Get_Net (Ctxt, V), Target.Off.Net_Off);
end if;
else
if not Is_Static (V.Val) then
-- Maybe the error message is too cryptic ?
Error_Msg_Synth
(+Loc, "cannot assign a net to a static value");
else
Strip_Const (V);
Copy_Memory (Target.Obj.Val.Mem + Target.Off.Mem_Off,
V.Val.Mem, V.Typ.Sz);
end if;
end if;
when Target_Memory =>
declare
Ctxt : constant Context_Acc := Get_Build (Syn_Inst);
N : Net;
begin
N := Get_Current_Assign_Value
(Ctxt, Target.Mem_Obj.Val.W,
Target.Mem_Dyn.Pfx_Off.Net_Off, Target.Mem_Dyn.Pfx_Typ.W);
N := Build_Dyn_Insert (Ctxt, N, Get_Net (Ctxt, V),
Target.Mem_Dyn.Voff, Target.Mem_Doff);
Set_Location (N, Loc);
Phi_Assign_Net (Ctxt, Target.Mem_Obj.Val.W, N,
Target.Mem_Dyn.Pfx_Off.Net_Off);
end;
end case;
end Synth_Assignment;
procedure Synth_Assignment (Syn_Inst : Synth_Instance_Acc;
Target : Node;
Val : Valtyp;
Loc : Node)
is
Info : Target_Info;
begin
Info := Synth_Target (Syn_Inst, Target);
Synth_Assignment (Syn_Inst, Info, Val, Loc);
end Synth_Assignment;
function Synth_Read_Memory (Syn_Inst : Synth_Instance_Acc;
Obj : Valtyp;
Res_Typ : Type_Acc;
Off : Uns32;
Dyn : Dyn_Name;
Loc : Node) return Valtyp
is
Ctxt : constant Context_Acc := Get_Build (Syn_Inst);
N : Net;
begin
N := Get_Net (Ctxt, Obj);
if Dyn.Voff /= No_Net then
Synth.Source.Set_Location_Maybe (N, Loc);
if Res_Typ.W /= 0 then
-- Do not try to extract if the net is null.
N := Build_Dyn_Extract (Ctxt, N, Dyn.Voff,
Off + Dyn.Pfx_Off.Net_Off, Res_Typ.W);
end if;
else
pragma Assert (not Is_Static (Obj.Val));
N := Build2_Extract (Ctxt, N, Off, Res_Typ.W);
end if;
Set_Location (N, Loc);
return Create_Value_Net (N, Res_Typ);
end Synth_Read_Memory;
function Synth_Read (Syn_Inst : Synth_Instance_Acc;
Targ : Target_Info;
Loc : Node) return Valtyp
is
Ctxt : constant Context_Acc := Get_Build (Syn_Inst);
N : Net;
begin
case Targ.Kind is
when Target_Simple =>
N := Build2_Extract (Ctxt, Get_Net (Ctxt, Targ.Obj),
Targ.Off.Net_Off, Targ.Targ_Type.W);
return Create_Value_Net (N, Targ.Targ_Type);
when Target_Aggregate =>
raise Internal_Error;
when Target_Memory =>
return Synth_Read_Memory (Syn_Inst, Targ.Mem_Obj, Targ.Targ_Type,
0, Targ.Mem_Dyn, Loc);
end case;
end Synth_Read;
-- Concurrent or sequential simple signal assignment
procedure Synth_Simple_Signal_Assignment
(Syn_Inst : Synth_Instance_Acc; Stmt : Node)
is
Targ : Target_Info;
Val : Valtyp;
begin
Targ := Synth_Target (Syn_Inst, Get_Target (Stmt));
Val := Synth_Waveform
(Syn_Inst, Get_Waveform_Chain (Stmt), Targ.Targ_Type);
Synth_Assignment (Syn_Inst, Targ, Val, Stmt);
end Synth_Simple_Signal_Assignment;
procedure Synth_Conditional_Signal_Assignment
(Syn_Inst : Synth_Instance_Acc; Stmt : Node)
is
Ctxt : constant Context_Acc := Get_Build (Syn_Inst);
Targ : Target_Info;
Cond : Node;
Cwf : Node;
Inp : Input;
Val, Cond_Val : Valtyp;
Cond_Net : Net;
First, Last : Net;
V : Net;
begin
Targ := Synth_Target (Syn_Inst, Get_Target (Stmt));
Last := No_Net;
Cwf := Get_Conditional_Waveform_Chain (Stmt);
Cond := Null_Node;
while Cwf /= Null_Node loop
Val := Synth_Waveform
(Syn_Inst, Get_Waveform_Chain (Cwf), Targ.Targ_Type);
if Val = No_Valtyp then
-- Mark the error, but try to continue.
Set_Error (Syn_Inst);
else
V := Get_Net (Ctxt, Val);
Cond := Get_Condition (Cwf);
if Cond /= Null_Node then
Cond_Val := Synth_Expression (Syn_Inst, Cond);
if Cond_Val = No_Valtyp then
Cond_Net := Build_Const_UB32 (Ctxt, 0, 1);
else
Cond_Net := Get_Net (Ctxt, Cond_Val);
end if;
V := Build_Mux2 (Ctxt, Cond_Net, No_Net, V);
Set_Location (V, Cwf);
end if;
if Last /= No_Net then
Inp := Get_Input (Get_Net_Parent (Last), 1);
Connect (Inp, V);
else
First := V;
end if;
Last := V;
end if;
Cwf := Get_Chain (Cwf);
end loop;
if Cond /= Null_Node then
pragma Assert (Last /= No_Net);
Inp := Get_Input (Get_Net_Parent (Last), 1);
if Get_Driver (Inp) = No_Net then
-- No else.
Val := Synth_Read (Syn_Inst, Targ, Stmt);
Connect (Inp, Get_Net (Ctxt, Val));
end if;
end if;
Val := Create_Value_Net (First, Targ.Targ_Type);
Synth_Assignment (Syn_Inst, Targ, Val, Stmt);
end Synth_Conditional_Signal_Assignment;
procedure Synth_Variable_Assignment (C : Seq_Context; Stmt : Node)
is
Targ : Target_Info;
Val : Valtyp;
begin
Targ := Synth_Target (C.Inst, Get_Target (Stmt));
Val := Synth_Expression_With_Type
(C.Inst, Get_Expression (Stmt), Targ.Targ_Type);
if Val = No_Valtyp then
Set_Error (C.Inst);
return;
end if;
Synth_Assignment (C.Inst, Targ, Val, Stmt);
end Synth_Variable_Assignment;
procedure Synth_Conditional_Variable_Assignment
(C : Seq_Context; Stmt : Node)
is
Ctxt : constant Context_Acc := Get_Build (C.Inst);
Target : constant Node := Get_Target (Stmt);
Targ_Type : Type_Acc;
Cond : Node;
Ce : Node;
Val, Cond_Val : Valtyp;
V : Net;
First, Last : Net;
begin
Targ_Type := Get_Subtype_Object (C.Inst, Get_Type (Target));
Last := No_Net;
Ce := Get_Conditional_Expression_Chain (Stmt);
while Ce /= Null_Node loop
Val := Synth_Expression_With_Type
(C.Inst, Get_Expression (Ce), Targ_Type);
V := Get_Net (Ctxt, Val);
Cond := Get_Condition (Ce);
if Cond /= Null_Node then
Cond_Val := Synth_Expression (C.Inst, Cond);
V := Build_Mux2 (Ctxt, Get_Net (Ctxt, Cond_Val), No_Net, V);
Set_Location (V, Ce);
end if;
if Last /= No_Net then
Connect (Get_Input (Get_Net_Parent (Last), 1), V);
else
First := V;
end if;
Last := V;
Ce := Get_Chain (Ce);
end loop;
Val := Create_Value_Net (First, Targ_Type);
Synth_Assignment (C.Inst, Target, Val, Stmt);
end Synth_Conditional_Variable_Assignment;
procedure Synth_If_Statement (C : in out Seq_Context; Stmt : Node)
is
Cond : constant Node := Get_Condition (Stmt);
Els : constant Node := Get_Else_Clause (Stmt);
Ctxt : constant Context_Acc := Get_Build (C.Inst);
Cond_Val : Valtyp;
Cond_Net : Net;
Phi_True : Phi_Type;
Phi_False : Phi_Type;
begin
Cond_Val := Synth_Expression (C.Inst, Cond);
if Cond_Val = No_Valtyp then
Set_Error (C.Inst);
return;
end if;
if Is_Static_Val (Cond_Val.Val) then
Strip_Const (Cond_Val);
if Read_Discrete (Get_Value_Memtyp (Cond_Val)) = 1 then
-- True.
Synth_Sequential_Statements
(C, Get_Sequential_Statement_Chain (Stmt));
else
pragma Assert (Read_Discrete (Get_Value_Memtyp (Cond_Val)) = 0);
if Is_Valid (Els) then
-- Else part
if Is_Null (Get_Condition (Els)) then
-- Final else part.
Synth_Sequential_Statements
(C, Get_Sequential_Statement_Chain (Els));
else
-- Elsif. Handled as a nested if.
Synth_If_Statement (C, Els);
end if;
end if;
end if;
else
-- The statements for the 'then' part.
Push_Phi;
Synth_Sequential_Statements
(C, Get_Sequential_Statement_Chain (Stmt));
Pop_Phi (Phi_True);
Push_Phi;
if Is_Valid (Els) then
if Is_Null (Get_Condition (Els)) then
-- Final else part.
Synth_Sequential_Statements
(C, Get_Sequential_Statement_Chain (Els));
else
-- Elsif. Handled as a nested if.
Synth_If_Statement (C, Els);
end if;
end if;
Pop_Phi (Phi_False);
Cond_Net := Get_Net (Ctxt, Cond_Val);
Merge_Phis (Ctxt, Cond_Net, Phi_True, Phi_False, Get_Location (Stmt));
end if;
end Synth_If_Statement;
type Alternative_Index is new Int32;
-- Only keep '0' and '1' in choices for std_logic.
function Ignore_Choice_Logic (V : Ghdl_U8; Loc : Node) return Boolean is
begin
case V is
when Vhdl.Ieee.Std_Logic_1164.Std_Logic_0_Pos
| Vhdl.Ieee.Std_Logic_1164.Std_Logic_1_Pos =>
return False;
when Vhdl.Ieee.Std_Logic_1164.Std_Logic_L_Pos
| Vhdl.Ieee.Std_Logic_1164.Std_Logic_H_Pos =>
Warning_Msg_Synth
(+Loc, "choice with 'L' or 'H' value is ignored");
return True;
when Vhdl.Ieee.Std_Logic_1164.Std_Logic_U_Pos
| Vhdl.Ieee.Std_Logic_1164.Std_Logic_X_Pos
| Vhdl.Ieee.Std_Logic_1164.Std_Logic_D_Pos
| Vhdl.Ieee.Std_Logic_1164.Std_Logic_Z_Pos
| Vhdl.Ieee.Std_Logic_1164.Std_Logic_W_Pos =>
Warning_Msg_Synth (+Loc, "choice with meta-value is ignored");
return True;
when others =>
-- Only 9 values.
raise Internal_Error;
end case;
end Ignore_Choice_Logic;
function Ignore_Choice_Expression (V : Valtyp; Loc : Node) return Boolean is
begin
case V.Typ.Kind is
when Type_Bit =>
return False;
when Type_Logic =>
if V.Typ = Logic_Type then
return Ignore_Choice_Logic (Read_U8 (V.Val.Mem), Loc);
else
return False;
end if;
when Type_Discrete =>
return False;
when Type_Vector =>
if V.Typ.Vec_El = Logic_Type then
for I in 1 .. Size_Type (V.Typ.Vbound.Len) loop
if Ignore_Choice_Logic (Read_U8 (V.Val.Mem + (I - 1)), Loc)
then
return True;
end if;
end loop;
return False;
else
return False;
end if;
when Type_Array =>
return False;
when others =>
raise Internal_Error;
end case;
end Ignore_Choice_Expression;
-- Create the condition for choices of CHOICE chain belonging to the same
-- alternative. Update CHOICE to the next alternative.
procedure Synth_Choice (Syn_Inst : Synth_Instance_Acc;
Sel : Net;
Choice_Typ : Type_Acc;
Nets : in out Net_Array;
Other_Choice : in out Nat32;
Choice_Idx : in out Nat32;
Choice : in out Node)
is
Ctxt : constant Context_Acc := Get_Build (Syn_Inst);
Cond : Net;
Res : Net;
begin
Res := No_Net;
loop
case Iir_Kinds_Case_Choice (Get_Kind (Choice)) is
when Iir_Kind_Choice_By_Expression =>
declare
V : Valtyp;
begin
V := Synth_Expression_With_Basetype
(Syn_Inst, Get_Choice_Expression (Choice));
V := Synth_Subtype_Conversion
(Ctxt, V, Choice_Typ, False, Choice);
if Ignore_Choice_Expression (V, Choice) then
Cond := No_Net;
else
Cond := Build_Compare
(Ctxt, Id_Eq, Sel, Get_Net (Ctxt, V));
Set_Location (Cond, Choice);
end if;
end;
when Iir_Kind_Choice_By_Range =>
declare
Rng : Discrete_Range_Type;
Cmp_L, Cmp_R : Module_Id;
L, R : Net;
begin
Synth_Discrete_Range
(Syn_Inst, Get_Choice_Range (Choice), Rng);
if Rng.Is_Signed then
case Rng.Dir is
when Dir_To =>
Cmp_L := Id_Sge;
Cmp_R := Id_Sle;
when Dir_Downto =>
Cmp_L := Id_Sle;
Cmp_R := Id_Sge;
end case;
L := Build2_Const_Int (Ctxt, Rng.Left, Choice_Typ.W);
R := Build2_Const_Int (Ctxt, Rng.Right, Choice_Typ.W);
else
case Rng.Dir is
when Dir_To =>
Cmp_L := Id_Uge;
Cmp_R := Id_Ule;
when Dir_Downto =>
Cmp_L := Id_Ule;
Cmp_R := Id_Uge;
end case;
L := Build2_Const_Uns
(Ctxt, Uns64 (Rng.Left), Choice_Typ.W);
R := Build2_Const_Uns
(Ctxt, Uns64 (Rng.Right), Choice_Typ.W);
end if;
L := Build_Compare (Ctxt, Cmp_L, Sel, L);
Set_Location (L, Choice);
R := Build_Compare (Ctxt, Cmp_R, Sel, R);
Set_Location (R, Choice);
Cond := Build_Dyadic (Ctxt, Id_And, L, R);
Set_Location (Cond, Choice);
end;
when Iir_Kind_Choice_By_Others =>
-- Last and only one.
pragma Assert (Res = No_Net);
Other_Choice := Choice_Idx + 1;
pragma Assert (Get_Chain (Choice) = Null_Node);
Choice := Null_Node;
return;
end case;
if not Get_Same_Alternative_Flag (Choice) then
-- First choice.
Choice_Idx := Choice_Idx + 1;
Res := Cond;
else
if Cond = No_Net then
-- No new condition.
null;
else
if Res /= No_Net then
Res := Build_Dyadic (Ctxt, Id_Or, Res, Cond);
Set_Location (Res, Choice);
else
Res := Cond;
end if;
end if;
end if;
Choice := Get_Chain (Choice);
exit when Choice = Null_Node
or else not Get_Same_Alternative_Flag (Choice);
end loop;
if Res = No_Net then
Res := Build_Const_UB32 (Ctxt, 0, 1);
end if;
Nets (Choice_Idx) := Res;
end Synth_Choice;
type Alternative_Data_Type is record
Asgns : Seq_Assign;
Val : Net;
end record;
type Alternative_Data_Array is
array (Alternative_Index range <>) of Alternative_Data_Type;
type Alternative_Data_Acc is access Alternative_Data_Array;
procedure Free_Alternative_Data_Array is new Ada.Unchecked_Deallocation
(Alternative_Data_Array, Alternative_Data_Acc);
type Wire_Id_Array is array (Natural range <>) of Wire_Id;
type Wire_Id_Array_Acc is access Wire_Id_Array;
procedure Free_Wire_Id_Array is new Ada.Unchecked_Deallocation
(Wire_Id_Array, Wire_Id_Array_Acc);
procedure Sort_Wire_Id_Array (Arr : in out Wire_Id_Array)
is
function Lt (Op1, Op2 : Natural) return Boolean is
begin
return Is_Lt (Arr (Op1), Arr (Op2));
end Lt;
procedure Swap (From : Natural; To : Natural)
is
T : Wire_Id;
begin
T := Arr (From);
Arr (From) := Arr (To);
Arr (To) := T;
end Swap;
procedure Wid_Heap_Sort is
new Grt.Algos.Heap_Sort (Lt => Lt, Swap => Swap);
begin
Wid_Heap_Sort (Arr'Length);
end Sort_Wire_Id_Array;
-- Count the number of wires used in all the alternatives.
function Count_Wires_In_Alternatives (Alts : Alternative_Data_Array)
return Natural
is
Res : Natural;
Asgn : Seq_Assign;
W : Wire_Id;
begin
Res := 0;
for I in Alts'Range loop
Asgn := Alts (I).Asgns;
while Asgn /= No_Seq_Assign loop
W := Get_Wire_Id (Asgn);
if not Get_Wire_Mark (W) then
Res := Res + 1;
Set_Wire_Mark (W, True);
end if;
Asgn := Get_Assign_Chain (Asgn);
end loop;
end loop;
return Res;
end Count_Wires_In_Alternatives;
-- Fill ARR from wire_id of ALTS.
procedure Fill_Wire_Id_Array (Arr : out Wire_Id_Array;
Alts : Alternative_Data_Array)
is
Idx : Natural;
Asgn : Seq_Assign;
W : Wire_Id;
begin
Idx := Arr'First;
for I in Alts'Range loop
Asgn := Alts (I).Asgns;
while Asgn /= No_Seq_Assign loop
W := Get_Wire_Id (Asgn);
if Get_Wire_Mark (W) then
Arr (Idx) := W;
Idx := Idx + 1;
Set_Wire_Mark (W, False);
end if;
Asgn := Get_Assign_Chain (Asgn);
end loop;
end loop;
pragma Assert (Idx = Arr'Last + 1);
end Fill_Wire_Id_Array;
type Seq_Assign_Value_Array_Acc is access Seq_Assign_Value_Array;
procedure Free_Seq_Assign_Value_Array is new Ada.Unchecked_Deallocation
(Seq_Assign_Value_Array, Seq_Assign_Value_Array_Acc);
function Is_Assign_Value_Array_Static
(Wid : Wire_Id; Arr : Seq_Assign_Value_Array) return Memtyp
is
Res : Memtyp;
Prev_Val : Memtyp;
begin
Prev_Val := Null_Memtyp;
for I in Arr'Range loop
case Arr (I).Is_Static is
when False =>
-- A value is not static.
return Null_Memtyp;
when Unknown =>
if Prev_Val = Null_Memtyp then
-- First use of previous value.
if not Is_Static_Wire (Wid) then
-- The previous value is not static.
return Null_Memtyp;
end if;
Prev_Val := Get_Static_Wire (Wid);
if Res /= Null_Memtyp then
-- There is already a result.
if not Is_Equal (Res, Prev_Val) then
-- The previous value is different from the result.
return Null_Memtyp;
end if;
else
Res := Prev_Val;
end if;
end if;
when True =>
if Res = Null_Memtyp then
-- First value. Keep it.
Res := Arr (I).Val;
else
if not Is_Equal (Res, Arr (I).Val) then
-- Value is different.
return Null_Memtyp;
end if;
end if;
end case;
end loop;
return Res;
end Is_Assign_Value_Array_Static;
procedure Synth_Case_Statement_Dynamic
(C : in out Seq_Context; Stmt : Node; Sel : Valtyp)
is
use Vhdl.Sem_Expr;
Ctxt : constant Context_Acc := Get_Build (C.Inst);
Choices : constant Node := Get_Case_Statement_Alternative_Chain (Stmt);
Case_Info : Choice_Info_Type;
-- Array of alternatives
Alts : Alternative_Data_Acc;
Alt_Idx : Alternative_Index;
Others_Alt_Idx : Alternative_Index;
Nbr_Choices : Nat32;
Pasgns : Seq_Assign_Value_Array_Acc;
Nets : Net_Array_Acc;
Nbr_Wires : Natural;
Wires : Wire_Id_Array_Acc;
Sel_Net : Net;
begin
-- Strategies to synthesize a case statement. Assume the selector is
-- a net of W bits
-- - a large mux, with 2**W inputs
-- - if the number of choices is dense
-- - if W is small
-- - a onehot mux. Each choice is converted to an single bit condition
-- by adding a comparison operator (equal for single choice,
-- inequalities for ranges, or for multiple choices). Only one of
-- these conditions is true (plus 'others').
-- - if the number of choices is sparse
-- - large range choices
-- - a tree of mux/mux2
-- - large number of choices, densily grouped but sparsed compared
-- to 2**W (eg: a partially filled memory)
-- - divide and conquier
-- Count choices and alternatives.
Count_Choices (Case_Info, Choices);
--Fill_Choices_Array (Case_Info, Choices);
-- Allocate structures.
-- Because there is no 1-1 link between choices and alternatives,
-- create an array for the choices and an array for the alternatives.
Alts := new Alternative_Data_Array
(1 .. Alternative_Index (Case_Info.Nbr_Alternatives));
-- Compute number of non-default alternatives.
Nbr_Choices := Nat32 (Case_Info.Nbr_Alternatives);
if Case_Info.Others_Choice /= Null_Node then
Nbr_Choices := Nbr_Choices - 1;
end if;
Nets := new Net_Array (1 .. Int32 (Alts'Last));
Sel_Net := Get_Net (Ctxt, Sel);
-- Synth statements and keep list of assignments.
-- Also synth choices.
declare
Choice : Node;
Choice_Idx, Other_Choice : Nat32;
Phi : Phi_Type;
begin
Alt_Idx := 0;
Choice_Idx := 0;
Other_Choice := 0;
Choice := Choices;
while Is_Valid (Choice) loop
-- Must be a choice for a new alternative.
pragma Assert (not Get_Same_Alternative_Flag (Choice));
-- A new sequence of statements.
Alt_Idx := Alt_Idx + 1;
Push_Phi;
Synth_Sequential_Statements (C, Get_Associated_Chain (Choice));
Pop_Phi (Phi);
Alts (Alt_Idx).Asgns := Sort_Phi (Phi);
Synth_Choice (C.Inst, Sel_Net, Sel.Typ,
Nets.all, Other_Choice, Choice_Idx, Choice);
end loop;
pragma Assert (Choice_Idx = Nbr_Choices);
Others_Alt_Idx := Alternative_Index (Other_Choice);
end;
-- Create the one-hot vector.
if Nbr_Choices = 0 then
Sel_Net := No_Net;
else
Sel_Net := Build2_Concat (Ctxt, Nets (1 .. Nbr_Choices));
end if;
-- Create list of wire_id, sort it.
Nbr_Wires := Count_Wires_In_Alternatives (Alts.all);
Wires := new Wire_Id_Array (1 .. Nbr_Wires);
Fill_Wire_Id_Array (Wires.all, Alts.all);
Sort_Wire_Id_Array (Wires.all);
-- Associate each choice with the assign node
-- For each wire_id:
-- Build mux2/mux4 tree (group by 4)
Pasgns := new Seq_Assign_Value_Array (1 .. Int32 (Alts'Last));
-- For each wire, compute the result.
for I in Wires'Range loop
declare
Wi : constant Wire_Id := Wires (I);
Last_Val : Net;
Res_Inst : Instance;
Res : Net;
Default : Net;
Min_Off, Off : Uns32;
Wd : Width;
List : Partial_Assign_List;
Sval : Memtyp;
begin
-- Extract the value for each branch.
for I in Alts'Range loop
-- If there is an assignment to Wi in Alt, it will define the
-- value.
if Get_Wire_Id (Alts (I).Asgns) = Wi then
Pasgns (Int32 (I)) :=
Get_Seq_Assign_Value (Alts (I).Asgns);
Alts (I).Asgns := Get_Assign_Chain (Alts (I).Asgns);
else
Pasgns (Int32 (I)) := (Is_Static => Unknown);
end if;
end loop;
-- If:
-- 1) All present values in PASGNS are static
-- 2) There is no missing values *or* the previous value is
-- static.
-- 3) The default value is unused *or* it is static
-- 4) All the values are equal.
-- then assign directly.
Sval := Is_Assign_Value_Array_Static (Wi, Pasgns.all);
if Sval /= Null_Memtyp then
-- Use static assignment.
Phi_Assign_Static (Wi, Sval);
else
-- Compute the final value for each partial part of the wire.
Partial_Assign_Init (List);
Min_Off := 0;
loop
Off := Min_Off;
-- Extract value of partial assignments to NETS.
Extract_Merge_Partial_Assigns
(Ctxt, Pasgns.all, Nets.all, Off, Wd);
exit when Off = Uns32'Last and Wd = Width'Last;
-- If a branch has no value, use the value before the case.
-- Also do it for the default value!
Last_Val := No_Net;
for I in Nets'Range loop
if Nets (I) = No_Net then
if Last_Val = No_Net then
Last_Val := Get_Current_Assign_Value
(Ctxt, Wi, Off, Wd);
end if;
Nets (I) := Last_Val;
end if;
end loop;
-- Extract default value (for missing alternative).
if Others_Alt_Idx /= 0 then
Default := Nets (Int32 (Others_Alt_Idx));
else
Default := Build_Const_X (Ctxt, Wd);
end if;
if Nbr_Choices = 0 then
Res := Default;
else
Res := Build_Pmux (Ctxt, Sel_Net, Default);
Res_Inst := Get_Net_Parent (Res);
Set_Location (Res_Inst, Get_Location (Stmt));
for I in 1 .. Nbr_Choices loop
Connect
(Get_Input (Res_Inst, Port_Nbr (2 + I - Nets'First)),
Nets (I));
end loop;
end if;
Partial_Assign_Append (List, New_Partial_Assign (Res, Off));
Min_Off := Off + Wd;
end loop;
Merge_Partial_Assigns (Ctxt, Wi, List);
end if;
end;
end loop;
-- free.
Free_Wire_Id_Array (Wires);
Free_Alternative_Data_Array (Alts);
Free_Seq_Assign_Value_Array (Pasgns);
Free_Net_Array (Nets);
end Synth_Case_Statement_Dynamic;
procedure Synth_Case_Statement_Static_Array
(C : in out Seq_Context; Stmt : Node; Sel : Valtyp)
is
Choices : constant Node := Get_Case_Statement_Alternative_Chain (Stmt);
Choice : Node;
Stmts : Node;
Sel_Expr : Node;
Sel_Val : Valtyp;
begin
-- Synth statements, extract choice value.
Stmts := Null_Node;
Choice := Choices;
loop
pragma Assert (Is_Valid (Choice));
if not Get_Same_Alternative_Flag (Choice) then
Stmts := Get_Associated_Chain (Choice);
end if;
case Get_Kind (Choice) is
when Iir_Kind_Choice_By_Expression =>
Sel_Expr := Get_Choice_Expression (Choice);
Sel_Val := Synth_Expression_With_Basetype (C.Inst, Sel_Expr);
if Is_Equal (Sel_Val, Sel) then
Synth_Sequential_Statements (C, Stmts);
exit;
end if;
when Iir_Kind_Choice_By_Others =>
Synth_Sequential_Statements (C, Stmts);
exit;
when others =>
raise Internal_Error;
end case;
Choice := Get_Chain (Choice);
end loop;
end Synth_Case_Statement_Static_Array;
procedure Synth_Case_Statement_Static_Scalar
(C : in out Seq_Context; Stmt : Node; Sel : Int64)
is
Choices : constant Node := Get_Case_Statement_Alternative_Chain (Stmt);
Choice : Node;
Stmts : Node;
Sel_Expr : Node;
begin
-- Synth statements, extract choice value.
Stmts := Null_Node;
Choice := Choices;
loop
pragma Assert (Is_Valid (Choice));
if not Get_Same_Alternative_Flag (Choice) then
Stmts := Get_Associated_Chain (Choice);
end if;
case Get_Kind (Choice) is
when Iir_Kind_Choice_By_Expression =>
Sel_Expr := Get_Choice_Expression (Choice);
if Vhdl.Evaluation.Eval_Pos (Sel_Expr) = Sel then
Synth_Sequential_Statements (C, Stmts);
exit;
end if;
when Iir_Kind_Choice_By_Others =>
Synth_Sequential_Statements (C, Stmts);
exit;
when Iir_Kind_Choice_By_Range =>
declare
Bnd : Discrete_Range_Type;
Is_In : Boolean;
begin
Synth_Discrete_Range
(C.Inst, Get_Choice_Range (Choice), Bnd);
case Bnd.Dir is
when Dir_To =>
Is_In := Sel >= Bnd.Left and Sel <= Bnd.Right;
when Dir_Downto =>
Is_In := Sel <= Bnd.Left and Sel >= Bnd.Right;
end case;
if Is_In then
Synth_Sequential_Statements (C, Stmts);
exit;
end if;
end;
when others =>
raise Internal_Error;
end case;
Choice := Get_Chain (Choice);
end loop;
end Synth_Case_Statement_Static_Scalar;
procedure Synth_Case_Statement (C : in out Seq_Context; Stmt : Node)
is
Expr : constant Node := Get_Expression (Stmt);
Sel : Valtyp;
begin
Sel := Synth_Expression_With_Basetype (C.Inst, Expr);
Strip_Const (Sel);
if Is_Static (Sel.Val) then
case Sel.Typ.Kind is
when Type_Bit
| Type_Logic
| Type_Discrete =>
Synth_Case_Statement_Static_Scalar (C, Stmt,
Read_Discrete (Sel));
when Type_Vector
| Type_Array =>
Synth_Case_Statement_Static_Array (C, Stmt, Sel);
when others =>
raise Internal_Error;
end case;
else
Synth_Case_Statement_Dynamic (C, Stmt, Sel);
end if;
end Synth_Case_Statement;
procedure Synth_Selected_Signal_Assignment
(Syn_Inst : Synth_Instance_Acc; Stmt : Node)
is
use Vhdl.Sem_Expr;
Ctxt : constant Context_Acc := Get_Build (Syn_Inst);
Expr : constant Node := Get_Expression (Stmt);
Choices : constant Node := Get_Selected_Waveform_Chain (Stmt);
Targ : Target_Info;
Targ_Type : Type_Acc;
Case_Info : Choice_Info_Type;
-- Array of alternatives
Alts : Alternative_Data_Acc;
Alt_Idx : Alternative_Index;
Others_Alt_Idx : Alternative_Index;
-- Array of choices. Contains tuple of (Value, Alternative).
Nbr_Choices : Nat32;
Nets : Net_Array_Acc;
Sel : Valtyp;
Sel_Net : Net;
begin
Targ := Synth_Target (Syn_Inst, Get_Target (Stmt));
Targ_Type := Targ.Targ_Type;
-- Create a net for the expression.
Sel := Synth_Expression_With_Basetype (Syn_Inst, Expr);
Sel_Net := Get_Net (Ctxt, Sel);
-- Count choices and alternatives.
Count_Choices (Case_Info, Choices);
-- Fill_Choices_Array (Case_Info, Choices);
-- Allocate structures.
-- Because there is no 1-1 link between choices and alternatives,
-- create an array for the choices and an array for the alternatives.
Alts := new Alternative_Data_Array
(1 .. Alternative_Index (Case_Info.Nbr_Alternatives));
-- Compute number of non-default alternatives.
Nbr_Choices := Nat32 (Case_Info.Nbr_Alternatives);
if Case_Info.Others_Choice /= Null_Node then
Nbr_Choices := Nbr_Choices - 1;
end if;
Nets := new Net_Array (1 .. Nbr_Choices);
-- Synth statements, extract choice value.
declare
Choice, Wf : Node;
Val : Valtyp;
Choice_Idx, Other_Choice : Nat32;
begin
Alt_Idx := 0;
Choice_Idx := 0;
Other_Choice := 0;
Choice := Choices;
while Is_Valid (Choice) loop
pragma Assert (not Get_Same_Alternative_Flag (Choice));
Wf := Get_Associated_Chain (Choice);
Val := Synth_Waveform (Syn_Inst, Wf, Targ_Type);
Alt_Idx := Alt_Idx + 1;
Alts (Alt_Idx).Val := Get_Net (Ctxt, Val);
Synth_Choice (Syn_Inst, Sel_Net, Sel.Typ,
Nets.all, Other_Choice, Choice_Idx, Choice);
end loop;
pragma Assert (Choice_Idx = Nbr_Choices);
Others_Alt_Idx := Alternative_Index (Other_Choice);
end;
-- Create the one-hot vector.
if Nbr_Choices = 0 then
Sel_Net := No_Net;
else
Sel_Net := Build2_Concat (Ctxt, Nets (1 .. Nbr_Choices));
end if;
declare
Res : Net;
Res_Inst : Instance;
Default : Net;
begin
-- Extract default value (for missing alternative).
if Others_Alt_Idx /= 0 then
Default := Alts (Others_Alt_Idx).Val;
else
Default := Build_Const_X (Ctxt, Targ_Type.W);
end if;
if Nbr_Choices = 0 then
Res := Default;
else
Res := Build_Pmux (Ctxt, Sel_Net, Default);
Res_Inst := Get_Net_Parent (Res);
Set_Location (Res_Inst, Get_Location (Stmt));
for I in 1 .. Nbr_Choices loop
Connect
(Get_Input (Res_Inst, Port_Nbr (2 + I - Nets'First)),
Alts (Alternative_Index (I)).Val);
end loop;
end if;
Synth_Assignment
(Syn_Inst, Targ, Create_Value_Net (Res, Targ_Type), Stmt);
end;
-- free.
Free_Alternative_Data_Array (Alts);
Free_Net_Array (Nets);
end Synth_Selected_Signal_Assignment;
function Synth_Label (Syn_Inst : Synth_Instance_Acc; Stmt : Node)
return Sname
is
Label : constant Name_Id := Get_Label (Stmt);
begin
if Label = Null_Identifier then
return No_Sname;
else
return New_Sname_User (Label, Get_Sname (Syn_Inst));
end if;
end Synth_Label;
function Is_Copyback_Interface (Inter : Node) return Boolean is
begin
case Iir_Parameter_Modes (Get_Mode (Inter)) is
when Iir_In_Mode =>
return False;
when Iir_Out_Mode | Iir_Inout_Mode =>
return Get_Kind (Inter) = Iir_Kind_Interface_Variable_Declaration;
end case;
end Is_Copyback_Interface;
type Association_Iterator_Kind is
(Association_Function,
Association_Operator);
type Association_Iterator_Init
(Kind : Association_Iterator_Kind := Association_Function) is
record
Inter_Chain : Node;
case Kind is
when Association_Function =>
Assoc_Chain : Node;
when Association_Operator =>
Left : Node;
Right : Node;
end case;
end record;
function Association_Iterator_Build (Inter_Chain : Node; Assoc_Chain : Node)
return Association_Iterator_Init is
begin
return Association_Iterator_Init'(Kind => Association_Function,
Inter_Chain => Inter_Chain,
Assoc_Chain => Assoc_Chain);
end Association_Iterator_Build;
function Association_Iterator_Build
(Inter_Chain : Node; Left : Node; Right : Node)
return Association_Iterator_Init is
begin
return Association_Iterator_Init'(Kind => Association_Operator,
Inter_Chain => Inter_Chain,
Left => Left,
Right => Right);
end Association_Iterator_Build;
function Count_Associations (Init : Association_Iterator_Init)
return Natural
is
Assoc : Node;
Assoc_Inter : Node;
Inter : Node;
Nbr_Inout : Natural;
begin
case Init.Kind is
when Association_Function =>
Nbr_Inout := 0;
Assoc := Init.Assoc_Chain;
Assoc_Inter := Init.Inter_Chain;
while Is_Valid (Assoc) loop
Inter := Get_Association_Interface (Assoc, Assoc_Inter);
if Is_Copyback_Interface (Inter) then
Nbr_Inout := Nbr_Inout + 1;
end if;
Next_Association_Interface (Assoc, Assoc_Inter);
end loop;
return Nbr_Inout;
when Association_Operator =>
return 0;
end case;
end Count_Associations;
type Association_Iterator
(Kind : Association_Iterator_Kind := Association_Function) is
record
Inter : Node;
case Kind is
when Association_Function =>
First_Named_Assoc : Node;
Next_Assoc : Node;
when Association_Operator =>
Op1 : Node;
Op2 : Node;
end case;
end record;
procedure Association_Iterate_Init (Iterator : out Association_Iterator;
Init : Association_Iterator_Init) is
begin
case Init.Kind is
when Association_Function =>
Iterator := (Kind => Association_Function,
Inter => Init.Inter_Chain,
First_Named_Assoc => Null_Node,
Next_Assoc => Init.Assoc_Chain);
when Association_Operator =>
Iterator := (Kind => Association_Operator,
Inter => Init.Inter_Chain,
Op1 => Init.Left,
Op2 => Init.Right);
end case;
end Association_Iterate_Init;
-- Return the next association.
-- ASSOC can be:
-- * an Iir_Kind_Association_By_XXX node (normal case)
-- * Null_Iir if INTER is not associated (and has a default value).
-- * an expression (for operator association).
procedure Association_Iterate_Next (Iterator : in out Association_Iterator;
Inter : out Node;
Assoc : out Node)
is
Formal : Node;
begin
Inter := Iterator.Inter;
if Inter = Null_Node then
-- End of iterator.
Assoc := Null_Node;
return;
else
-- Advance to the next interface for the next call.
Iterator.Inter := Get_Chain (Iterator.Inter);
end if;
case Iterator.Kind is
when Association_Function =>
if Iterator.First_Named_Assoc = Null_Node then
Assoc := Iterator.Next_Assoc;
if Assoc = Null_Node then
-- No more association: open association.
return;
end if;
Formal := Get_Formal (Assoc);
if Formal = Null_Node then
-- Association by position.
-- Update for the next call.
Iterator.Next_Assoc := Get_Chain (Assoc);
return;
end if;
Iterator.First_Named_Assoc := Assoc;
end if;
-- Search by name.
Assoc := Iterator.First_Named_Assoc;
while Assoc /= Null_Node loop
Formal := Get_Formal (Assoc);
pragma Assert (Formal /= Null_Node);
Formal := Get_Interface_Of_Formal (Formal);
if Formal = Inter then
-- Found.
-- Optimize in case assocs are in order.
if Assoc = Iterator.First_Named_Assoc then
Iterator.First_Named_Assoc := Get_Chain (Assoc);
end if;
return;
end if;
Assoc := Get_Chain (Assoc);
end loop;
-- Not found: open association.
return;
when Association_Operator =>
Assoc := Iterator.Op1;
Iterator.Op1 := Iterator.Op2;
Iterator.Op2 := Null_Node;
end case;
end Association_Iterate_Next;
procedure Synth_Subprogram_Association (Subprg_Inst : Synth_Instance_Acc;
Caller_Inst : Synth_Instance_Acc;
Init : Association_Iterator_Init;
Infos : out Target_Info_Array)
is
pragma Assert (Infos'First = 1);
Ctxt : constant Context_Acc := Get_Build (Caller_Inst);
Inter : Node;
Inter_Type : Type_Acc;
Assoc : Node;
Actual : Node;
Val : Valtyp;
Nbr_Inout : Natural;
Iterator : Association_Iterator;
Info : Target_Info;
begin
Set_Instance_Const (Subprg_Inst, True);
Nbr_Inout := 0;
-- Process in INTER order.
Association_Iterate_Init (Iterator, Init);
loop
Association_Iterate_Next (Iterator, Inter, Assoc);
exit when Inter = Null_Node;
Inter_Type := Get_Subtype_Object (Caller_Inst, Get_Type (Inter));
case Iir_Parameter_Modes (Get_Mode (Inter)) is
when Iir_In_Mode =>
if Assoc = Null_Node
or else Get_Kind (Assoc) = Iir_Kind_Association_Element_Open
then
Actual := Get_Default_Value (Inter);
Val := Synth_Expression_With_Type
(Subprg_Inst, Actual, Inter_Type);
else
if Get_Kind (Assoc) =
Iir_Kind_Association_Element_By_Expression
then
Actual := Get_Actual (Assoc);
else
Actual := Assoc;
end if;
Val := Synth_Expression_With_Type
(Caller_Inst, Actual, Inter_Type);
end if;
when Iir_Out_Mode | Iir_Inout_Mode =>
Actual := Get_Actual (Assoc);
Info := Synth_Target (Caller_Inst, Actual);
case Iir_Kinds_Interface_Object_Declaration (Get_Kind (Inter))
is
when Iir_Kind_Interface_Constant_Declaration =>
raise Internal_Error;
when Iir_Kind_Interface_Variable_Declaration =>
-- Always pass by value.
Nbr_Inout := Nbr_Inout + 1;
Infos (Nbr_Inout) := Info;
if Info.Kind /= Target_Memory
and then Is_Static (Info.Obj.Val)
then
Val := Create_Value_Memory (Info.Targ_Type);
Copy_Memory (Val.Val.Mem,
Info.Obj.Val.Mem + Info.Off.Mem_Off,
Info.Targ_Type.Sz);
else
Val := Synth_Read (Caller_Inst, Info, Assoc);
end if;
when Iir_Kind_Interface_Signal_Declaration =>
-- Always pass by reference (use an alias).
if Info.Kind = Target_Memory then
raise Internal_Error;
end if;
Val := Create_Value_Alias
(Info.Obj, Info.Off, Info.Targ_Type);
when Iir_Kind_Interface_File_Declaration =>
Val := Info.Obj;
when Iir_Kind_Interface_Quantity_Declaration =>
raise Internal_Error;
end case;
end case;
if Val = No_Valtyp then
Set_Error (Subprg_Inst);
return;
end if;
-- FIXME: conversion only for constants, reshape for all.
Val := Synth_Subtype_Conversion (Ctxt, Val, Inter_Type, True, Assoc);
if Get_Instance_Const (Subprg_Inst) and then not Is_Static (Val.Val)
then
Set_Instance_Const (Subprg_Inst, False);
end if;
case Iir_Kinds_Interface_Object_Declaration (Get_Kind (Inter)) is
when Iir_Kind_Interface_Constant_Declaration =>
-- Pass by reference.
Create_Object (Subprg_Inst, Inter, Val);
when Iir_Kind_Interface_Variable_Declaration =>
-- Arguments are passed by copy.
if Is_Static (Val.Val) or else Get_Mode (Inter) = Iir_In_Mode
then
Val := Unshare (Val, Current_Pool);
else
-- Will be changed to a wire.
null;
end if;
Create_Object (Subprg_Inst, Inter, Val);
when Iir_Kind_Interface_Signal_Declaration =>
Create_Object (Subprg_Inst, Inter, Val);
when Iir_Kind_Interface_File_Declaration =>
Create_Object (Subprg_Inst, Inter, Val);
when Iir_Kind_Interface_Quantity_Declaration =>
raise Internal_Error;
end case;
end loop;
end Synth_Subprogram_Association;
procedure Synth_Subprogram_Association (Subprg_Inst : Synth_Instance_Acc;
Caller_Inst : Synth_Instance_Acc;
Inter_Chain : Node;
Assoc_Chain : Node)
is
Infos : Target_Info_Array (1 .. 0);
pragma Unreferenced (Infos);
Init : Association_Iterator_Init;
begin
Init := Association_Iterator_Build (Inter_Chain, Assoc_Chain);
Synth_Subprogram_Association (Subprg_Inst, Caller_Inst, Init, Infos);
end Synth_Subprogram_Association;
-- Create wires for out and inout interface variables.
procedure Synth_Subprogram_Association_Wires
(Subprg_Inst : Synth_Instance_Acc; Init : Association_Iterator_Init)
is
Ctxt : constant Context_Acc := Get_Build (Subprg_Inst);
Inter : Node;
Assoc : Node;
Val : Valtyp;
Iterator : Association_Iterator;
Wire : Wire_Id;
begin
-- Process in INTER order.
Association_Iterate_Init (Iterator, Init);
loop
Association_Iterate_Next (Iterator, Inter, Assoc);
exit when Inter = Null_Node;
if Get_Mode (Inter) in Iir_Out_Modes
and then Get_Kind (Inter) = Iir_Kind_Interface_Variable_Declaration
then
Val := Get_Value (Subprg_Inst, Inter);
-- Arguments are passed by copy.
Wire := Alloc_Wire (Wire_Variable, (Inter, Val.Typ));
Set_Wire_Gate (Wire, Get_Net (Ctxt, Val));
Val := Create_Value_Wire (Wire, Val.Typ);
Create_Object_Force (Subprg_Inst, Inter, No_Valtyp);
Create_Object_Force (Subprg_Inst, Inter, Val);
end if;
end loop;
end Synth_Subprogram_Association_Wires;
procedure Synth_Subprogram_Back_Association
(Subprg_Inst : Synth_Instance_Acc;
Caller_Inst : Synth_Instance_Acc;
Init : Association_Iterator_Init;
Infos : Target_Info_Array)
is
pragma Assert (Infos'First = 1);
Inter : Node;
Assoc : Node;
Assoc_Inter : Node;
Val : Valtyp;
Nbr_Inout : Natural;
begin
Nbr_Inout := 0;
pragma Assert (Init.Kind = Association_Function);
Assoc := Init.Assoc_Chain;
Assoc_Inter := Init.Inter_Chain;
while Is_Valid (Assoc) loop
Inter := Get_Association_Interface (Assoc, Assoc_Inter);
if Is_Copyback_Interface (Inter) then
if not Get_Whole_Association_Flag (Assoc) then
raise Internal_Error;
end if;
Nbr_Inout := Nbr_Inout + 1;
Val := Get_Value (Subprg_Inst, Inter);
Synth_Assignment (Caller_Inst, Infos (Nbr_Inout), Val, Assoc);
-- Free wire used for out/inout interface variables.
if Val.Val.Kind = Value_Wire then
Phi_Discard_Wires (Val.Val.W, No_Wire_Id);
Free_Wire (Val.Val.W);
end if;
end if;
Next_Association_Interface (Assoc, Assoc_Inter);
end loop;
pragma Assert (Nbr_Inout = Infos'Last);
end Synth_Subprogram_Back_Association;
function Build_Control_Signal (Syn_Inst : Synth_Instance_Acc;
W : Width;
Loc : Source.Syn_Src) return Net
is
Ctxt : constant Context_Acc := Get_Build (Syn_Inst);
Res : Net;
begin
Res := Build_Signal (Ctxt, New_Internal_Name (Ctxt), W);
Set_Location (Res, Loc);
return Res;
end Build_Control_Signal;
function Synth_Dynamic_Subprogram_Call (Syn_Inst : Synth_Instance_Acc;
Sub_Inst : Synth_Instance_Acc;
Call : Node;
Init : Association_Iterator_Init;
Infos : Target_Info_Array)
return Valtyp
is
Imp : constant Node := Get_Implementation (Call);
Is_Func : constant Boolean := Is_Function_Declaration (Imp);
Bod : constant Node := Vhdl.Sem_Inst.Get_Subprogram_Body_Origin (Imp);
Ctxt : constant Context_Acc := Get_Build (Syn_Inst);
Res : Valtyp;
C : Seq_Context (Mode_Dynamic);
Wire_Mark : Wire_Id;
Subprg_Phi : Phi_Type;
begin
Mark (Wire_Mark);
C := (Mode => Mode_Dynamic,
Inst => Sub_Inst,
Cur_Loop => null,
W_En => No_Wire_Id,
W_Ret => No_Wire_Id,
W_Val => No_Wire_Id,
Ret_Init => No_Net,
Ret_Value => No_Valtyp,
Ret_Typ => null,
Nbr_Ret => 0);
C.W_En := Alloc_Wire (Wire_Variable, (Imp, Bit_Type));
C.W_Ret := Alloc_Wire (Wire_Variable, (Imp, Bit_Type));
if Is_Func then
C.W_Val := Alloc_Wire (Wire_Variable, (Imp, null));
end if;
-- Create a phi so that all assignments are gathered.
Push_Phi;
Synth_Subprogram_Association_Wires (Sub_Inst, Init);
if Is_Func then
-- Set a default value for the return.
C.Ret_Typ := Get_Subtype_Object (Syn_Inst, Get_Return_Type (Imp));
Set_Wire_Gate (C.W_Val,
Build_Control_Signal (Sub_Inst, C.Ret_Typ.W, Imp));
C.Ret_Init := Build_Const_X (Ctxt, C.Ret_Typ.W);
Phi_Assign_Net (Ctxt, C.W_Val, C.Ret_Init, 0);
end if;
Set_Wire_Gate
(C.W_En, Build_Control_Signal (Sub_Inst, 1, Imp));
Phi_Assign_Static (C.W_En, Bit1);
Set_Wire_Gate
(C.W_Ret, Build_Control_Signal (Sub_Inst, 1, Imp));
Phi_Assign_Static (C.W_Ret, Bit1);
Vhdl_Decls.Synth_Declarations
(C.Inst, Get_Declaration_Chain (Bod), True);
if not Is_Error (C.Inst) then
Synth_Sequential_Statements (C, Get_Sequential_Statement_Chain (Bod));
end if;
if Is_Error (C.Inst) then
Res := No_Valtyp;
else
if Is_Func then
if C.Nbr_Ret = 0 then
raise Internal_Error;
elsif C.Nbr_Ret = 1 and then Is_Static (C.Ret_Value.Val) then
Res := C.Ret_Value;
else
Res := Create_Value_Net
(Get_Current_Value (Ctxt, C.W_Val), C.Ret_Value.Typ);
end if;
else
Res := No_Valtyp;
Synth_Subprogram_Back_Association (C.Inst, Syn_Inst, Init, Infos);
end if;
end if;
Pop_Phi (Subprg_Phi);
Vhdl_Decls.Finalize_Declarations
(C.Inst, Get_Declaration_Chain (Bod), True);
pragma Unreferenced (Infos);
-- Propagate assignments.
-- Wires that have been created for this subprogram will be destroyed.
-- But assignment for outer wires (passed through parameters) have
-- to be kept. We cannot merge phi because this won't be allowed for
-- local wires.
Propagate_Phi_Until_Mark (Ctxt, Subprg_Phi, Wire_Mark);
-- Free wires.
-- These wires are currently unassigned because they were created
-- within the Phi.
Free_Wire (C.W_En);
Free_Wire (C.W_Ret);
if Is_Func then
Free_Wire (C.W_Val);
end if;
Release (Wire_Mark);
return Res;
end Synth_Dynamic_Subprogram_Call;
function Synth_Static_Subprogram_Call (Syn_Inst : Synth_Instance_Acc;
Sub_Inst : Synth_Instance_Acc;
Call : Node;
Bod : Node;
Init : Association_Iterator_Init;
Infos : Target_Info_Array)
return Valtyp
is
Imp : constant Node := Get_Implementation (Call);
Is_Func : constant Boolean := Is_Function_Declaration (Imp);
Res : Valtyp;
C : Seq_Context (Mode_Static);
begin
C := (Mode_Static,
Inst => Sub_Inst,
Cur_Loop => null,
S_En => True,
Ret_Value => No_Valtyp,
Ret_Typ => null,
Nbr_Ret => 0);
if Is_Func then
-- Set a default value for the return.
C.Ret_Typ := Get_Subtype_Object (Syn_Inst, Get_Return_Type (Imp));
end if;
Synth_Declarations (C.Inst, Get_Declaration_Chain (Bod), True);
if not Is_Error (C.Inst) then
Synth_Sequential_Statements (C, Get_Sequential_Statement_Chain (Bod));
end if;
if Is_Error (C.Inst) then
Res := No_Valtyp;
else
if Is_Func then
if C.Nbr_Ret = 0 then
Error_Msg_Synth
(+Call, "function call completed without a return statement");
Res := No_Valtyp;
else
pragma Assert (C.Nbr_Ret = 1);
pragma Assert (Is_Static (C.Ret_Value.Val));
Res := C.Ret_Value;
end if;
else
Res := No_Valtyp;
Synth_Subprogram_Back_Association (C.Inst, Syn_Inst, Init, Infos);
end if;
end if;
Vhdl_Decls.Finalize_Declarations
(C.Inst, Get_Declaration_Chain (Bod), True);
pragma Unreferenced (Infos);
return Res;
end Synth_Static_Subprogram_Call;
function Synth_Subprogram_Call (Syn_Inst : Synth_Instance_Acc;
Call : Node;
Init : Association_Iterator_Init)
return Valtyp
is
Ctxt : constant Context_Acc := Get_Build (Syn_Inst);
Imp : constant Node := Get_Implementation (Call);
Is_Func : constant Boolean := Is_Function_Declaration (Imp);
Bod : constant Node := Vhdl.Sem_Inst.Get_Subprogram_Body_Origin (Imp);
Nbr_Inout : constant Natural := Count_Associations (Init);
Infos : Target_Info_Array (1 .. Nbr_Inout);
Area_Mark : Areapools.Mark_Type;
Res : Valtyp;
Sub_Inst : Synth_Instance_Acc;
Up_Inst : Synth_Instance_Acc;
begin
Areapools.Mark (Area_Mark, Instance_Pool.all);
Up_Inst := Get_Instance_By_Scope (Syn_Inst, Get_Parent_Scope (Imp));
Sub_Inst := Make_Instance (Up_Inst, Bod, New_Internal_Name (Ctxt));
Set_Instance_Base (Sub_Inst, Syn_Inst);
Synth_Subprogram_Association (Sub_Inst, Syn_Inst, Init, Infos);
if Is_Error (Sub_Inst) then
Res := No_Valtyp;
else
if not Is_Func then
if Get_Purity_State (Imp) /= Pure then
Set_Instance_Const (Sub_Inst, False);
end if;
end if;
if Get_Instance_Const (Sub_Inst) then
Res := Synth_Static_Subprogram_Call
(Syn_Inst, Sub_Inst, Call, Bod, Init, Infos);
else
Res := Synth_Dynamic_Subprogram_Call
(Syn_Inst, Sub_Inst, Call, Init, Infos);
end if;
end if;
-- Propagate error.
if Is_Error (Sub_Inst) then
Set_Error (Syn_Inst);
end if;
if Debugger.Flag_Need_Debug then
Debugger.Debug_Leave (Sub_Inst);
end if;
Free_Instance (Sub_Inst);
Areapools.Release (Area_Mark, Instance_Pool.all);
return Res;
end Synth_Subprogram_Call;
function Synth_Subprogram_Call
(Syn_Inst : Synth_Instance_Acc; Call : Node) return Valtyp
is
Imp : constant Node := Get_Implementation (Call);
Assoc_Chain : constant Node := Get_Parameter_Association_Chain (Call);
Inter_Chain : constant Node := Get_Interface_Declaration_Chain (Imp);
Init : Association_Iterator_Init;
begin
Init := Association_Iterator_Build (Inter_Chain, Assoc_Chain);
return Synth_Subprogram_Call (Syn_Inst, Call, Init);
end Synth_Subprogram_Call;
function Synth_User_Operator (Syn_Inst : Synth_Instance_Acc;
Left_Expr : Node;
Right_Expr : Node;
Expr : Node) return Valtyp
is
Imp : constant Node := Get_Implementation (Expr);
Inter_Chain : constant Node := Get_Interface_Declaration_Chain (Imp);
Init : Association_Iterator_Init;
begin
Init := Association_Iterator_Build (Inter_Chain, Left_Expr, Right_Expr);
return Synth_Subprogram_Call (Syn_Inst, Expr, Init);
end Synth_User_Operator;
procedure Synth_Implicit_Procedure_Call
(Syn_Inst : Synth_Instance_Acc; Call : Node)
is
Ctxt : constant Context_Acc := Get_Build (Syn_Inst);
Imp : constant Node := Get_Implementation (Call);
Assoc_Chain : constant Node := Get_Parameter_Association_Chain (Call);
Inter_Chain : constant Node := Get_Interface_Declaration_Chain (Imp);
Init : constant Association_Iterator_Init :=
Association_Iterator_Build (Inter_Chain, Assoc_Chain);
Nbr_Inout : constant Natural := Count_Associations (Init);
Infos : Target_Info_Array (1 .. Nbr_Inout);
Area_Mark : Areapools.Mark_Type;
Sub_Inst : Synth_Instance_Acc;
begin
Areapools.Mark (Area_Mark, Instance_Pool.all);
Sub_Inst := Make_Instance (Syn_Inst, Imp, New_Internal_Name (Ctxt));
Synth_Subprogram_Association (Sub_Inst, Syn_Inst, Init, Infos);
Synth.Vhdl_Static_Proc.Synth_Static_Procedure (Sub_Inst, Imp, Call);
Synth_Subprogram_Back_Association (Sub_Inst, Syn_Inst, Init, Infos);
Free_Instance (Sub_Inst);
Areapools.Release (Area_Mark, Instance_Pool.all);
end Synth_Implicit_Procedure_Call;
procedure Synth_Procedure_Call
(Syn_Inst : Synth_Instance_Acc; Stmt : Node)
is
Call : constant Node := Get_Procedure_Call (Stmt);
Imp : constant Node := Get_Implementation (Call);
Res : Valtyp;
begin
case Get_Implicit_Definition (Imp) is
when Iir_Predefined_None =>
if Get_Foreign_Flag (Imp) then
Error_Msg_Synth
(+Stmt, "call to foreign %n is not supported", +Imp);
else
Res := Synth_Subprogram_Call (Syn_Inst, Call);
pragma Assert (Res = No_Valtyp);
end if;
when others =>
Synth_Implicit_Procedure_Call (Syn_Inst, Call);
end case;
end Synth_Procedure_Call;
procedure Update_Index (Rng : Discrete_Range_Type; V : in out Valtyp)
is
T : Int64;
begin
T := Read_Discrete (V);
case Rng.Dir is
when Dir_To =>
T := T + 1;
when Dir_Downto =>
T := T - 1;
end case;
Write_Discrete (V, T);
end Update_Index;
-- Return True iff WID is a static wire and its value is V.
function Is_Static_Bit (Wid : Wire_Id; V : Ghdl_U8) return Boolean
is
M : Memtyp;
begin
if not Is_Static_Wire (Wid) then
return False;
end if;
M := Get_Static_Wire (Wid);
return Read_U8 (M) = V;
end Is_Static_Bit;
function Is_Static_Bit0 (Wid : Wire_Id) return Boolean is
begin
return Is_Static_Bit (Wid, 0);
end Is_Static_Bit0;
function Is_Static_Bit1 (Wid : Wire_Id) return Boolean is
begin
return Is_Static_Bit (Wid, 1);
end Is_Static_Bit1;
pragma Inline (Is_Static_Bit0);
pragma Inline (Is_Static_Bit1);
procedure Loop_Control_Init (C : Seq_Context; Stmt : Node)
is
Lc : constant Loop_Context_Acc := C.Cur_Loop;
begin
-- We might create new wires that will be destroy at the end of the
-- loop. Use mark and sweep to control their lifetime.
Mark (C.Cur_Loop.Wire_Mark);
if Lc.Prev_Loop /= null and then Lc.Prev_Loop.Need_Quit then
-- An exit or next statement that targets an outer loop may suspend
-- the execution of this loop.
Lc.W_Quit := Alloc_Wire (Wire_Variable, (Lc.Loop_Stmt, Bit_Type));
Set_Wire_Gate (Lc.W_Quit, Build_Control_Signal (C.Inst, 1, Stmt));
Phi_Assign_Static (Lc.W_Quit, Bit1);
end if;
if Get_Exit_Flag (Stmt) or else Get_Next_Flag (Stmt) then
-- There is an exit or next statement that target this loop.
-- We need to save W_En, as if the execution is suspended due to
-- exit or next, it will resume at the end of the loop.
if Is_Static_Wire (C.W_En) then
pragma Assert (Is_Static_Bit1 (C.W_En));
Lc.Saved_En := No_Net;
else
Lc.Saved_En := Get_Current_Value (null, C.W_En);
end if;
-- Subloops may be suspended if there is an exit or a next statement
-- for this loop within subloops.
Lc.Need_Quit := True;
end if;
if Get_Exit_Flag (Stmt) then
-- There is an exit statement for this loop. Create the wire.
Lc.W_Exit := Alloc_Wire (Wire_Variable, (Lc.Loop_Stmt, Bit_Type));
Set_Wire_Gate (Lc.W_Exit, Build_Control_Signal (C.Inst, 1, Stmt));
Phi_Assign_Static (Lc.W_Exit, Bit1);
end if;
end Loop_Control_Init;
procedure Loop_Control_And_Start (Is_Net : out Boolean;
S : out Boolean;
N : out Net;
En : Net) is
begin
if En = No_Net then
Is_Net := False;
N := No_Net;
S := True;
else
Is_Net := True;
N := En;
S := True;
end if;
end Loop_Control_And_Start;
procedure Loop_Control_And (C : Seq_Context;
Is_Net : in out Boolean;
S : in out Boolean;
N : in out Net;
R : Wire_Id)
is
Res : Net;
begin
if R = No_Wire_Id or else Is_Static_Bit1 (R) then
-- No change.
return;
end if;
if Is_Static_Bit0 (R) then
-- Stays 0.
Is_Net := False;
S := False;
N := No_Net;
return;
end if;
if not Is_Net and then not S then
-- Was 0, remains 0.
return;
end if;
pragma Assert (Is_Net or else S);
-- Optimize common cases.
Res := Get_Current_Value (null, R);
if Is_Net then
N := Build_Dyadic (Get_Build (C.Inst), Id_And, N, Res);
Set_Location (N, C.Cur_Loop.Loop_Stmt);
else
N := Res;
end if;
Is_Net := True;
end Loop_Control_And;
procedure Loop_Control_And_Assign (C : Seq_Context;
Is_Net : Boolean;
S : Boolean;
N : Net;
W : Wire_Id) is
begin
if Is_Net then
Phi_Assign_Net (Get_Build (C.Inst), W, N, 0);
else
if S then
Phi_Assign_Static (W, Bit1);
else
Phi_Assign_Static (W, Bit0);
end if;
end if;
end Loop_Control_And_Assign;
procedure Loop_Control_Update (C : Seq_Context)
is
Lc : constant Loop_Context_Acc := C.Cur_Loop;
N : Net;
S : Boolean;
Is_Net : Boolean;
begin
if not Lc.Need_Quit then
-- No next/exit statement for this loop. So no control.
return;
end if;
-- Execution continue iff:
-- 1. Loop was enabled (Lc.Saved_En)
Loop_Control_And_Start (Is_Net, S, N, Lc.Saved_En);
-- 2. No return (C.W_Ret)
Loop_Control_And (C, Is_Net, S, N, C.W_Ret);
-- 3. No exit.
Loop_Control_And (C, Is_Net, S, N, Lc.W_Exit);
-- 4. No quit.
Loop_Control_And (C, Is_Net, S, N, Lc.W_Quit);
Loop_Control_And_Assign (C, Is_Net, S, N, C.W_En);
end Loop_Control_Update;
procedure Loop_Control_Finish (C : Seq_Context)
is
Lc : constant Loop_Context_Acc := C.Cur_Loop;
N : Net;
S : Boolean;
Is_Net : Boolean;
begin
-- Execution continue after this loop iff:
-- 1. Loop was enabled (Lc.Saved_En)
Loop_Control_And_Start (Is_Net, S, N, Lc.Saved_En);
-- 2. No return (C.W_Ret)
Loop_Control_And (C, Is_Net, S, N, C.W_Ret);
-- 3. No quit (C.W_Quit)
Loop_Control_And (C, Is_Net, S, N, Lc.W_Quit);
Phi_Discard_Wires (Lc.W_Quit, Lc.W_Exit);
if Lc.W_Quit /= No_Wire_Id then
Free_Wire (Lc.W_Quit);
end if;
if Lc.W_Exit /= No_Wire_Id then
Free_Wire (Lc.W_Exit);
end if;
Release (C.Cur_Loop.Wire_Mark);
Loop_Control_And_Assign (C, Is_Net, S, N, C.W_En);
end Loop_Control_Finish;
procedure Synth_Dynamic_Exit_Next_Statement
(C : in out Seq_Context; Stmt : Node)
is
Ctxt : constant Context_Acc := Get_Build (C.Inst);
Cond : constant Node := Get_Condition (Stmt);
Is_Exit : constant Boolean := Get_Kind (Stmt) = Iir_Kind_Exit_Statement;
Static_Cond : Boolean;
Loop_Label : Node;
Lc : Loop_Context_Acc;
Cond_Val : Valtyp;
Phi_True : Phi_Type;
Phi_False : Phi_Type;
begin
if Cond /= Null_Node then
Cond_Val := Synth_Expression (C.Inst, Cond);
Static_Cond := Is_Static_Val (Cond_Val.Val);
if Static_Cond then
if Get_Static_Discrete (Cond_Val) = 0 then
-- Not executed.
return;
end if;
else
-- Create a branch for the True case.
Push_Phi;
end if;
end if;
-- Execution is suspended for the current sequence of statements.
Phi_Assign_Static (C.W_En, Bit0);
Lc := C.Cur_Loop;
-- Compute the loop statement indicated by the exit/next statement.
Loop_Label := Get_Loop_Label (Stmt);
if Loop_Label = Null_Node then
Loop_Label := Lc.Loop_Stmt;
else
Loop_Label := Get_Named_Entity (Loop_Label);
end if;
-- Update the W_Exit and W_Quit flags for the loops. All the loops
-- until the label are canceled.
loop
if Lc.Loop_Stmt = Loop_Label then
-- Final loop.
if Is_Exit then
Phi_Assign_Static (Lc.W_Exit, Bit0);
end if;
exit;
else
Phi_Assign_Static (Lc.W_Quit, Bit0);
end if;
Lc := Lc.Prev_Loop;
end loop;
if Cond /= Null_Node and not Static_Cond then
Pop_Phi (Phi_True);
-- If the condition is false, do nothing.
Push_Phi;
Pop_Phi (Phi_False);
Merge_Phis (Ctxt, Get_Net (Ctxt, Cond_Val), Phi_True, Phi_False,
Get_Location (Stmt));
end if;
end Synth_Dynamic_Exit_Next_Statement;
procedure Synth_Static_Exit_Next_Statement
(C : in out Seq_Context; Stmt : Node)
is
Cond : constant Node := Get_Condition (Stmt);
Is_Exit : constant Boolean := Get_Kind (Stmt) = Iir_Kind_Exit_Statement;
Loop_Label : Node;
Lc : Loop_Context_Acc;
Cond_Val : Valtyp;
begin
if Cond /= Null_Node then
Cond_Val := Synth_Expression (C.Inst, Cond);
if Cond_Val = No_Valtyp then
Set_Error (C.Inst);
return;
end if;
pragma Assert (Is_Static_Val (Cond_Val.Val));
if Get_Static_Discrete (Cond_Val) = 0 then
-- Not executed.
return;
end if;
end if;
-- Execution is suspended.
C.S_En := False;
Lc := C.Cur_Loop;
Loop_Label := Get_Loop_Label (Stmt);
if Loop_Label = Null_Node then
Loop_Label := Lc.Loop_Stmt;
else
Loop_Label := Get_Named_Entity (Loop_Label);
end if;
loop
if Lc.Loop_Stmt = Loop_Label then
if Is_Exit then
Lc.S_Exit := True;
end if;
exit;
else
Lc.S_Quit := True;
end if;
Lc := Lc.Prev_Loop;
end loop;
end Synth_Static_Exit_Next_Statement;
procedure Init_For_Loop_Statement (C : in out Seq_Context;
Stmt : Node;
Val : out Valtyp)
is
Iterator : constant Node := Get_Parameter_Specification (Stmt);
It_Type : constant Node := Get_Declaration_Type (Iterator);
It_Rng : Type_Acc;
begin
if It_Type /= Null_Node then
Synth_Subtype_Indication (C.Inst, It_Type);
end if;
-- Initial value.
It_Rng := Get_Subtype_Object (C.Inst, Get_Type (Iterator));
Val := Create_Value_Discrete (It_Rng.Drange.Left, It_Rng);
Create_Object (C.Inst, Iterator, Val);
end Init_For_Loop_Statement;
procedure Finish_For_Loop_Statement (C : in out Seq_Context;
Stmt : Node)
is
Iterator : constant Node := Get_Parameter_Specification (Stmt);
It_Type : constant Node := Get_Declaration_Type (Iterator);
begin
Destroy_Object (C.Inst, Iterator);
if It_Type /= Null_Node then
Destroy_Object (C.Inst, It_Type);
end if;
end Finish_For_Loop_Statement;
procedure Synth_Dynamic_For_Loop_Statement
(C : in out Seq_Context; Stmt : Node)
is
Stmts : constant Node := Get_Sequential_Statement_Chain (Stmt);
Val : Valtyp;
Lc : aliased Loop_Context (Mode_Dynamic);
begin
Lc := (Mode => Mode_Dynamic,
Prev_Loop => C.Cur_Loop,
Loop_Stmt => Stmt,
Need_Quit => False,
Saved_En => No_Net,
W_Exit => No_Wire_Id,
W_Quit => No_Wire_Id,
Wire_Mark => No_Wire_Id);
C.Cur_Loop := Lc'Unrestricted_Access;
Loop_Control_Init (C, Stmt);
Init_For_Loop_Statement (C, Stmt, Val);
while In_Range (Val.Typ.Drange, Read_Discrete (Val)) loop
Synth_Sequential_Statements (C, Stmts);
Update_Index (Val.Typ.Drange, Val);
Loop_Control_Update (C);
-- Constant exit.
exit when Is_Static_Bit0 (C.W_En);
-- FIXME: dynamic exits.
end loop;
Loop_Control_Finish (C);
Finish_For_Loop_Statement (C, Stmt);
C.Cur_Loop := Lc.Prev_Loop;
end Synth_Dynamic_For_Loop_Statement;
procedure Synth_Static_For_Loop_Statement
(C : in out Seq_Context; Stmt : Node)
is
Stmts : constant Node := Get_Sequential_Statement_Chain (Stmt);
Val : Valtyp;
Lc : aliased Loop_Context (Mode_Static);
begin
Lc := (Mode_Static,
Prev_Loop => C.Cur_Loop,
Loop_Stmt => Stmt,
S_Exit => False,
S_Quit => False);
C.Cur_Loop := Lc'Unrestricted_Access;
Init_For_Loop_Statement (C, Stmt, Val);
while In_Range (Val.Typ.Drange, Read_Discrete (Val)) loop
Synth_Sequential_Statements (C, Stmts);
C.S_En := True;
Update_Index (Val.Typ.Drange, Val);
exit when Lc.S_Exit or Lc.S_Quit or C.Nbr_Ret > 0;
end loop;
Finish_For_Loop_Statement (C, Stmt);
C.Cur_Loop := Lc.Prev_Loop;
end Synth_Static_For_Loop_Statement;
procedure Synth_Dynamic_While_Loop_Statement
(C : in out Seq_Context; Stmt : Node)
is
Stmts : constant Node := Get_Sequential_Statement_Chain (Stmt);
Cond : constant Node := Get_Condition (Stmt);
Val : Valtyp;
Lc : aliased Loop_Context (Mode_Dynamic);
Iter_Nbr : Natural;
begin
Lc := (Mode => Mode_Dynamic,
Prev_Loop => C.Cur_Loop,
Loop_Stmt => Stmt,
Need_Quit => False,
Saved_En => No_Net,
W_Exit => No_Wire_Id,
W_Quit => No_Wire_Id,
Wire_Mark => No_Wire_Id);
C.Cur_Loop := Lc'Unrestricted_Access;
Iter_Nbr := 0;
Loop_Control_Init (C, Stmt);
loop
if Cond /= Null_Node then
Val := Synth_Expression_With_Type (C.Inst, Cond, Boolean_Type);
if not Is_Static (Val.Val) then
Error_Msg_Synth (+Cond, "loop condition must be static");
exit;
end if;
exit when Read_Discrete (Val) = 0;
end if;
Synth_Sequential_Statements (C, Stmts);
Loop_Control_Update (C);
-- Exit from the loop if W_Exit/W_Ret/W_Quit = 0
exit when Lc.W_Exit /= No_Wire_Id and then Is_Static_Bit0 (Lc.W_Exit);
exit when C.W_Ret /= No_Wire_Id and then Is_Static_Bit0 (C.W_Ret);
exit when Lc.W_Quit /= No_Wire_Id and then Is_Static_Bit0 (Lc.W_Quit);
Iter_Nbr := Iter_Nbr + 1;
if Iter_Nbr > Flags.Flag_Max_Loop and Flags.Flag_Max_Loop /= 0 then
Error_Msg_Synth
(+Stmt, "maximum number of iterations (%v) reached",
+Uns32 (Flags.Flag_Max_Loop));
exit;
end if;
end loop;
Loop_Control_Finish (C);
C.Cur_Loop := Lc.Prev_Loop;
end Synth_Dynamic_While_Loop_Statement;
procedure Synth_Static_While_Loop_Statement
(C : in out Seq_Context; Stmt : Node)
is
Stmts : constant Node := Get_Sequential_Statement_Chain (Stmt);
Cond : constant Node := Get_Condition (Stmt);
Val : Valtyp;
Lc : aliased Loop_Context (Mode_Static);
begin
Lc := (Mode => Mode_Static,
Prev_Loop => C.Cur_Loop,
Loop_Stmt => Stmt,
S_Exit => False,
S_Quit => False);
C.Cur_Loop := Lc'Unrestricted_Access;
loop
if Cond /= Null_Node then
Val := Synth_Expression_With_Type (C.Inst, Cond, Boolean_Type);
pragma Assert (Is_Static (Val.Val));
exit when Read_Discrete (Val) = 0;
end if;
Synth_Sequential_Statements (C, Stmts);
C.S_En := True;
-- Exit from the loop if S_Exit/S_Quit
exit when Lc.S_Exit or Lc.S_Quit or C.Nbr_Ret > 0;
end loop;
C.Cur_Loop := Lc.Prev_Loop;
end Synth_Static_While_Loop_Statement;
procedure Synth_Return_Statement (C : in out Seq_Context; Stmt : Node)
is
Is_Dyn : constant Boolean := not Get_Instance_Const (C.Inst);
Ctxt : constant Context_Acc := Get_Build (C.Inst);
Val : Valtyp;
Expr : constant Node := Get_Expression (Stmt);
begin
if Expr /= Null_Node then
-- Return in function.
Val := Synth_Expression_With_Type (C.Inst, Expr, C.Ret_Typ);
if Val = No_Valtyp then
Set_Error (C.Inst);
return;
end if;
Val := Synth_Subtype_Conversion (Ctxt, Val, C.Ret_Typ, True, Stmt);
if C.Nbr_Ret = 0 then
C.Ret_Value := Val;
if not Is_Bounded_Type (C.Ret_Typ) then
-- The function was declared with an unconstrained return type.
-- Now that a value has been returned, we know the subtype of
-- the returned values. So adjust it.
-- All the returned values must have the same length.
C.Ret_Typ := Val.Typ;
if Is_Dyn then
Set_Width (Get_Wire_Gate (C.W_Val), C.Ret_Typ.W);
Set_Width (C.Ret_Init, C.Ret_Typ.W);
end if;
end if;
end if;
if Is_Dyn then
Phi_Assign_Net (Ctxt, C.W_Val, Get_Net (Ctxt, Val), 0);
end if;
end if;
if Is_Dyn then
-- The subprogram has returned. Do not execute further statements.
Phi_Assign_Static (C.W_En, Bit0);
if C.W_Ret /= No_Wire_Id then
Phi_Assign_Static (C.W_Ret, Bit0);
end if;
end if;
C.Nbr_Ret := C.Nbr_Ret + 1;
end Synth_Return_Statement;
procedure Synth_Static_Report (Syn_Inst : Synth_Instance_Acc; Stmt : Node)
is
use Simple_IO;
Is_Report : constant Boolean :=
Get_Kind (Stmt) = Iir_Kind_Report_Statement;
Rep_Expr : constant Node := Get_Report_Expression (Stmt);
Sev_Expr : constant Node := Get_Severity_Expression (Stmt);
Rep : Valtyp;
Sev : Valtyp;
Sev_V : Natural;
begin
if Rep_Expr /= Null_Node then
Rep := Synth_Expression_With_Basetype (Syn_Inst, Rep_Expr);
if Rep = No_Valtyp then
Set_Error (Syn_Inst);
return;
end if;
Strip_Const (Rep);
end if;
if Sev_Expr /= Null_Node then
Sev := Synth_Expression (Syn_Inst, Sev_Expr);
if Sev = No_Valtyp then
Set_Error (Syn_Inst);
return;
end if;
Strip_Const (Sev);
end if;
Put_Err (Disp_Location (Stmt));
Put_Err (":(");
if Is_Report then
Put_Err ("report");
else
Put_Err ("assertion");
end if;
Put_Err (' ');
if Sev = No_Valtyp then
if Is_Report then
Sev_V := 0;
else
Sev_V := 2;
end if;
else
Sev_V := Natural (Read_Discrete (Sev));
end if;
case Sev_V is
when Note_Severity =>
Put_Err ("note");
when Warning_Severity =>
Put_Err ("warning");
when Error_Severity =>
Put_Err ("error");
when Failure_Severity =>
Put_Err ("failure");
when others =>
Put_Err ("??");
end case;
Put_Err ("): ");
if Rep = No_Valtyp then
Put_Line_Err ("assertion failure");
else
Put_Line_Err (Value_To_String (Rep));
end if;
if Sev_V >= Flags.Severity_Level then
Error_Msg_Synth (+Stmt, "error due to assertion failure");
end if;
end Synth_Static_Report;
procedure Synth_Static_Report_Statement (C : Seq_Context; Stmt : Node) is
begin
Synth_Static_Report (C.Inst, Stmt);
end Synth_Static_Report_Statement;
procedure Synth_Static_Assertion_Statement (C : Seq_Context; Stmt : Node)
is
Cond : Valtyp;
begin
Cond := Synth_Expression (C.Inst, Get_Assertion_Condition (Stmt));
if Cond = No_Valtyp then
Set_Error (C.Inst);
return;
end if;
pragma Assert (Is_Static (Cond.Val));
Strip_Const (Cond);
if Read_Discrete (Cond) = 1 then
return;
end if;
Synth_Static_Report (C.Inst, Stmt);
end Synth_Static_Assertion_Statement;
procedure Synth_Dynamic_Assertion_Statement (C : Seq_Context; Stmt : Node)
is
Ctxt : constant Context_Acc := Get_Build (C.Inst);
Loc : constant Location_Type := Get_Location (Stmt);
Cond : Valtyp;
N : Net;
En : Net;
Inst : Instance;
begin
if not Flags.Flag_Formal then
return;
end if;
Cond := Synth_Expression (C.Inst, Get_Assertion_Condition (Stmt));
if Cond = No_Valtyp then
Set_Error (C.Inst);
return;
end if;
N := Get_Net (Ctxt, Cond);
En := Phi_Enable (Ctxt, (Stmt, Bit_Type), Bit0, Bit1,
Get_Location (Stmt));
if En /= No_Net then
-- Build: En -> Cond
N := Build2_Imp (Ctxt, En, N, Loc);
end if;
Inst := Build_Assert (Ctxt, Synth_Label (C.Inst, Stmt), N);
Set_Location (Inst, Loc);
end Synth_Dynamic_Assertion_Statement;
procedure Synth_Sequential_Statements
(C : in out Seq_Context; Stmts : Node)
is
Is_Dyn : constant Boolean := not Get_Instance_Const (C.Inst);
Ctxt : constant Context_Acc := Get_Build (C.Inst);
Stmt : Node;
Phi_T, Phi_F : Phi_Type;
Has_Phi : Boolean;
begin
Stmt := Stmts;
while Is_Valid (Stmt) loop
if Is_Dyn then
pragma Assert (not Is_Static_Bit0 (C.W_En));
Has_Phi := not Is_Static_Bit1 (C.W_En);
if Has_Phi then
Push_Phi;
end if;
end if;
if Flags.Flag_Trace_Statements then
declare
Name : Name_Id;
Line : Natural;
Col : Natural;
begin
Files_Map.Location_To_Position
(Get_Location (Stmt), Name, Line, Col);
Simple_IO.Put_Line ("Execute statement at "
& Name_Table.Image (Name)
& Natural'Image (Line));
end;
end if;
if Synth.Debugger.Flag_Need_Debug then
Synth.Debugger.Debug_Break (C.Inst, Stmt);
end if;
case Get_Kind (Stmt) is
when Iir_Kind_If_Statement =>
Synth_If_Statement (C, Stmt);
when Iir_Kind_Simple_Signal_Assignment_Statement =>
Synth_Simple_Signal_Assignment (C.Inst, Stmt);
when Iir_Kind_Conditional_Signal_Assignment_Statement =>
Synth_Conditional_Signal_Assignment (C.Inst, Stmt);
when Iir_Kind_Variable_Assignment_Statement =>
Synth_Variable_Assignment (C, Stmt);
when Iir_Kind_Conditional_Variable_Assignment_Statement =>
Synth_Conditional_Variable_Assignment (C, Stmt);
when Iir_Kind_Case_Statement =>
Synth_Case_Statement (C, Stmt);
when Iir_Kind_For_Loop_Statement =>
if Is_Dyn then
Synth_Dynamic_For_Loop_Statement (C, Stmt);
else
Synth_Static_For_Loop_Statement (C, Stmt);
end if;
when Iir_Kind_While_Loop_Statement =>
if Is_Dyn then
Synth_Dynamic_While_Loop_Statement (C, Stmt);
else
Synth_Static_While_Loop_Statement (C, Stmt);
end if;
when Iir_Kind_Null_Statement =>
-- Easy
null;
when Iir_Kind_Return_Statement =>
Synth_Return_Statement (C, Stmt);
when Iir_Kind_Procedure_Call_Statement =>
Synth_Procedure_Call (C.Inst, Stmt);
when Iir_Kind_Report_Statement =>
if not Is_Dyn then
Synth_Static_Report_Statement (C, Stmt);
end if;
when Iir_Kind_Assertion_Statement =>
if not Is_Dyn then
Synth_Static_Assertion_Statement (C, Stmt);
else
Synth_Dynamic_Assertion_Statement (C, Stmt);
end if;
when Iir_Kind_Exit_Statement
| Iir_Kind_Next_Statement =>
if Is_Dyn then
Synth_Dynamic_Exit_Next_Statement (C, Stmt);
else
Synth_Static_Exit_Next_Statement (C, Stmt);
end if;
when others =>
Error_Kind ("synth_sequential_statements", Stmt);
end case;
if Is_Dyn then
if Has_Phi then
Pop_Phi (Phi_T);
Push_Phi;
Pop_Phi (Phi_F);
Merge_Phis (Ctxt, Get_Current_Value (Ctxt, C.W_En),
Phi_T, Phi_F, Get_Location (Stmt));
end if;
if Is_Static_Bit0 (C.W_En) then
-- Not more execution.
return;
end if;
else
if not C.S_En or C.Nbr_Ret /= 0 then
return;
end if;
end if;
Stmt := Get_Chain (Stmt);
end loop;
end Synth_Sequential_Statements;
Proc_Pool : aliased Areapools.Areapool;
-- Synthesis of statements of a non-sensitized process.
procedure Synth_Process_Sequential_Statements
(C : in out Seq_Context; Proc : Node)
is
Ctxt : constant Context_Acc := Get_Build (C.Inst);
Stmt : Node;
Cond : Node;
Cond_Val : Valtyp;
Phi_True : Phi_Type;
Phi_False : Phi_Type;
begin
Stmt := Get_Sequential_Statement_Chain (Proc);
-- The first statement must be a wait statement.
if Get_Kind (Stmt) /= Iir_Kind_Wait_Statement then
Error_Msg_Synth (+Stmt, "expect wait as the first statement");
return;
end if;
-- Handle the condition as an if.
Cond := Get_Condition_Clause (Stmt);
if Cond = Null_Node then
Error_Msg_Synth (+Stmt, "expect wait condition");
return;
end if;
Cond_Val := Synth_Expression (C.Inst, Cond);
Push_Phi;
Synth_Sequential_Statements (C, Get_Chain (Stmt));
Pop_Phi (Phi_True);
Push_Phi;
Pop_Phi (Phi_False);
Merge_Phis (Ctxt, Get_Net (Ctxt, Cond_Val), Phi_True, Phi_False,
Get_Location (Stmt));
end Synth_Process_Sequential_Statements;
procedure Synth_Process_Statement
(Syn_Inst : Synth_Instance_Acc; Proc : Node)
is
use Areapools;
Label : constant Name_Id := Get_Identifier (Proc);
Decls_Chain : constant Node := Get_Declaration_Chain (Proc);
Prev_Instance_Pool : constant Areapool_Acc := Instance_Pool;
Ctxt : constant Context_Acc := Get_Build (Syn_Inst);
M : Areapools.Mark_Type;
C_Sname : Sname;
C : Seq_Context (Mode_Dynamic);
begin
if Label = Null_Identifier then
C_Sname := New_Internal_Name (Ctxt, Get_Sname (Syn_Inst));
else
C_Sname := New_Sname_User (Label, Get_Sname (Syn_Inst));
end if;
C := (Mode => Mode_Dynamic,
Inst => Make_Instance (Syn_Inst, Proc, C_Sname),
Cur_Loop => null,
W_En => Alloc_Wire (Wire_Variable, (Proc, Bit_Type)),
W_Ret => No_Wire_Id,
W_Val => No_Wire_Id,
Ret_Init => No_Net,
Ret_Value => No_Valtyp,
Ret_Typ => null,
Nbr_Ret => 0);
Mark (M, Proc_Pool);
Instance_Pool := Proc_Pool'Access;
Push_Phi;
Synth_Declarations (C.Inst, Decls_Chain);
Set_Wire_Gate (C.W_En, Build_Control_Signal (Syn_Inst, 1, Proc));
Phi_Assign_Static (C.W_En, Bit1);
if not Is_Error (C.Inst) then
case Iir_Kinds_Process_Statement (Get_Kind (Proc)) is
when Iir_Kind_Sensitized_Process_Statement =>
Synth_Sequential_Statements
(C, Get_Sequential_Statement_Chain (Proc));
-- FIXME: check sensitivity list.
when Iir_Kind_Process_Statement =>
Synth_Process_Sequential_Statements (C, Proc);
end case;
end if;
Pop_And_Merge_Phi (Ctxt, Get_Location (Proc));
Finalize_Declarations (C.Inst, Decls_Chain);
Free_Instance (C.Inst);
Release (M, Proc_Pool);
Instance_Pool := Prev_Instance_Pool;
Finalize_Assignment (Ctxt, C.W_En);
Free_Wire (C.W_En);
end Synth_Process_Statement;
function Synth_User_Function_Call
(Syn_Inst : Synth_Instance_Acc; Expr : Node) return Valtyp is
begin
-- Is it a call to an ieee function ?
declare
Imp : constant Node := Get_Implementation (Expr);
Pkg : constant Node := Get_Parent (Imp);
Unit : Node;
Lib : Node;
begin
if Get_Kind (Pkg) = Iir_Kind_Package_Declaration
and then not Is_Uninstantiated_Package (Pkg)
then
Unit := Get_Parent (Pkg);
if Get_Kind (Unit) = Iir_Kind_Design_Unit then
Lib := Get_Library (Get_Design_File (Unit));
if Get_Identifier (Lib) = Std_Names.Name_Ieee then
Error_Msg_Synth
(+Expr, "unhandled call to ieee function %i", +Imp);
Set_Error (Syn_Inst);
return No_Valtyp;
end if;
end if;
end if;
end;
return Synth_Subprogram_Call (Syn_Inst, Expr);
end Synth_User_Function_Call;
procedure Synth_Concurrent_Assertion_Statement
(Syn_Inst : Synth_Instance_Acc; Stmt : Node)
is
Ctxt : constant Context_Acc := Get_Build (Syn_Inst);
Cond : constant Node := Get_Assertion_Condition (Stmt);
Val : Valtyp;
Inst : Instance;
begin
Val := Synth_Expression (Syn_Inst, Cond);
if Val = No_Valtyp then
Set_Error (Syn_Inst);
return;
end if;
if Is_Static (Val.Val) then
if Read_Discrete (Val) /= 1 then
Synth_Static_Report (Syn_Inst, Stmt);
end if;
return;
end if;
if not Flags.Flag_Formal then
-- Ignore the net.
return;
end if;
Inst := Build_Assert
(Ctxt, Synth_Label (Syn_Inst, Stmt), Get_Net (Ctxt, Val));
Set_Location (Inst, Get_Location (Stmt));
end Synth_Concurrent_Assertion_Statement;
procedure Synth_Block_Statement (Syn_Inst : Synth_Instance_Acc; Blk : Node)
is
use Areapools;
Prev_Instance_Pool : constant Areapool_Acc := Instance_Pool;
Blk_Inst : Synth_Instance_Acc;
Blk_Sname : Sname;
M : Areapools.Mark_Type;
begin
-- No support for guard or header.
if Get_Block_Header (Blk) /= Null_Node
or else Get_Guard_Decl (Blk) /= Null_Node
then
raise Internal_Error;
end if;
Apply_Block_Configuration
(Get_Block_Block_Configuration (Blk), Blk);
Blk_Sname := New_Sname_User (Get_Identifier (Blk), Get_Sname (Syn_Inst));
Blk_Inst := Make_Instance (Syn_Inst, Blk, Blk_Sname);
Mark (M, Proc_Pool);
Instance_Pool := Proc_Pool'Access;
Synth_Declarations (Blk_Inst, Get_Declaration_Chain (Blk));
Synth_Concurrent_Statements
(Blk_Inst, Get_Concurrent_Statement_Chain (Blk));
Synth_Attribute_Values (Blk_Inst, Blk);
Finalize_Declarations (Blk_Inst, Get_Declaration_Chain (Blk));
Free_Instance (Blk_Inst);
Release (M, Proc_Pool);
Instance_Pool := Prev_Instance_Pool;
end Synth_Block_Statement;
function Synth_Psl_NFA (Syn_Inst : Synth_Instance_Acc;
NFA : PSL.Types.PSL_NFA;
Nbr_States : Int32;
States : Net;
Loc : Source.Syn_Src) return Net
is
use PSL.NFAs;
Ctxt : constant Context_Acc := Get_Build (Syn_Inst);
S : NFA_State;
S_Num : Int32;
D_Num : Int32;
I : Net;
Cond : Net;
E : NFA_Edge;
D_Arr : Net_Array_Acc;
Res : Net;
begin
D_Arr := new Net_Array'(0 .. Nbr_States - 1 => No_Net);
-- For each state:
S := Get_First_State (NFA);
while S /= No_State loop
S_Num := Get_State_Label (S);
I := Build_Extract_Bit (Ctxt, States, Uns32 (S_Num));
Set_Location (I, Loc);
-- For each edge:
E := Get_First_Src_Edge (S);
while E /= No_Edge loop
-- Edge condition.
Cond := Build_Dyadic
(Ctxt, Id_And,
I, Synth_PSL_Expression (Syn_Inst, Get_Edge_Expr (E)));
Set_Location (Cond, Loc);
-- TODO: if EOS is present, then this is a live state.
-- Reverse order for final concatenation.
D_Num := Nbr_States - 1 - Get_State_Label (Get_Edge_Dest (E));
if D_Arr (D_Num) /= No_Net then
Cond := Build_Dyadic (Ctxt, Id_Or, D_Arr (D_Num), Cond);
Set_Location (Cond, Loc);
end if;
D_Arr (D_Num) := Cond;
E := Get_Next_Src_Edge (E);
end loop;
S := Get_Next_State (S);
end loop;
if D_Arr (Nbr_States - 1) = No_Net then
D_Arr (Nbr_States - 1) := Build_Const_UB32 (Ctxt, 0, 1);
end if;
Concat_Array (Ctxt, D_Arr.all, Res);
Free_Net_Array (D_Arr);
return Res;
end Synth_Psl_NFA;
procedure Synth_Psl_Dff (Syn_Inst : Synth_Instance_Acc;
Stmt : Node;
Next_States : out Net)
is
Ctxt : constant Context_Acc := Get_Build (Syn_Inst);
Nbr_States : constant Int32 := Get_PSL_Nbr_States (Stmt);
States : Net;
Init : Net;
Clk : Net;
Clk_Inst : Instance;
begin
-- create init net, clock net
Init := Build_Const_UB32 (Ctxt, 1, Uns32 (Nbr_States));
Set_Location (Init, Stmt);
Clk := Synth_PSL_Expression (Syn_Inst, Get_PSL_Clock (Stmt));
-- Check the clock is an edge and extract it.
Clk_Inst := Get_Net_Parent (Clk);
if Get_Id (Clk_Inst) not in Edge_Module_Id then
Error_Msg_Synth (+Stmt, "clock is not an edge");
Next_States := No_Net;
return;
end if;
-- build idff
States := Build_Idff (Ctxt, Clk, No_Net, Init);
Set_Location (States, Stmt);
-- create update nets
-- For each state: if set, evaluate all outgoing edges.
Next_States :=
Synth_Psl_NFA (Syn_Inst, Get_PSL_NFA (Stmt), Nbr_States, States, Stmt);
Connect (Get_Input (Get_Net_Parent (States), 1), Next_States);
end Synth_Psl_Dff;
function Synth_Psl_Final
(Syn_Inst : Synth_Instance_Acc; Stmt : Node; Next_States : Net) return Net
is
use PSL.Types;
use PSL.NFAs;
NFA : constant PSL_NFA := Get_PSL_NFA (Stmt);
Res : Net;
begin
Res := Build_Extract_Bit
(Get_Build (Syn_Inst), Next_States,
Uns32 (Get_State_Label (Get_Final_State (NFA))));
Set_Location (Res, Stmt);
return Res;
end Synth_Psl_Final;
function Synth_Psl_Not_Final
(Syn_Inst : Synth_Instance_Acc; Stmt : Node; Next_States : Net)
return Net
is
Res : Net;
begin
Res := Build_Monadic (Get_Build (Syn_Inst), Id_Not,
Synth_Psl_Final (Syn_Inst, Stmt, Next_States));
Set_Location (Res, Stmt);
return Res;
end Synth_Psl_Not_Final;
procedure Synth_Psl_Restrict_Directive
(Syn_Inst : Synth_Instance_Acc; Stmt : Node)
is
Ctxt : constant Context_Acc := Get_Build (Syn_Inst);
Next_States : Net;
Res : Net;
Inst : Instance;
begin
if not Flags.Flag_Formal then
return;
end if;
-- Build assume gate.
-- Note: for synthesis, we assume the next state will be correct.
-- (If we assume on States, then the first cycle is ignored).
Synth_Psl_Dff (Syn_Inst, Stmt, Next_States);
if Next_States /= No_Net then
-- The restriction holds as long as there is a 1 in the NFA state.
Res := Build_Reduce (Ctxt, Id_Red_Or, Next_States);
Set_Location (Res, Stmt);
Inst := Build_Assume (Ctxt, Synth_Label (Syn_Inst, Stmt), Res);
Set_Location (Inst, Get_Location (Stmt));
end if;
end Synth_Psl_Restrict_Directive;
procedure Synth_Psl_Cover_Directive
(Syn_Inst : Synth_Instance_Acc; Stmt : Node)
is
Next_States : Net;
Res : Net;
Inst : Instance;
begin
if not Flags.Flag_Formal then
return;
end if;
-- Build cover gate.
-- Note: for synthesis, we assume the next state will be correct.
-- (If we assume on States, then the first cycle is ignored).
Synth_Psl_Dff (Syn_Inst, Stmt, Next_States);
if Next_States /= No_Net then
-- The sequence is covered as soon as the final state is reached.
Res := Synth_Psl_Final (Syn_Inst, Stmt, Next_States);
Inst := Build_Cover
(Get_Build (Syn_Inst), Synth_Label (Syn_Inst, Stmt), Res);
Set_Location (Inst, Get_Location (Stmt));
end if;
end Synth_Psl_Cover_Directive;
procedure Synth_Psl_Assume_Directive
(Syn_Inst : Synth_Instance_Acc; Stmt : Node)
is
Ctxt : constant Context_Acc := Get_Build (Syn_Inst);
Next_States : Net;
Inst : Instance;
begin
if not Flags.Flag_Formal then
return;
end if;
-- Build assume gate.
-- Note: for synthesis, we assume the next state will be correct.
-- (If we assume on States, then the first cycle is ignored).
Synth_Psl_Dff (Syn_Inst, Stmt, Next_States);
if Next_States /= No_Net then
Inst := Build_Assume
(Ctxt, Synth_Label (Syn_Inst, Stmt),
Synth_Psl_Not_Final (Syn_Inst, Stmt, Next_States));
Set_Location (Inst, Get_Location (Stmt));
end if;
end Synth_Psl_Assume_Directive;
procedure Synth_Psl_Assert_Directive
(Syn_Inst : Synth_Instance_Acc; Stmt : Node)
is
use PSL.Types;
use PSL.NFAs;
Ctxt : constant Context_Acc := Get_Build (Syn_Inst);
NFA : constant PSL_NFA := Get_PSL_NFA (Stmt);
Active : NFA_State;
Next_States : Net;
Inst : Instance;
Lab : Sname;
begin
if not Flags.Flag_Formal then
return;
end if;
-- Build assert gate.
-- Note: for synthesis, we assume the next state will be correct.
-- (If we assert on States, then the first cycle is ignored).
Synth_Psl_Dff (Syn_Inst, Stmt, Next_States);
if Next_States = No_Net then
return;
end if;
Lab := Synth_Label (Syn_Inst, Stmt);
Inst := Build_Assert
(Ctxt, Lab, Synth_Psl_Not_Final (Syn_Inst, Stmt, Next_States));
Set_Location (Inst, Get_Location (Stmt));
-- Also add a cover gate to cover assertion activation.
if Flags.Flag_Assert_Cover then
Active := Get_Active_State (NFA);
if Active /= No_State then
if Lab /= No_Sname then
Lab := New_Sname_User (Std_Names.Name_Cover, Lab);
end if;
Inst := Build_Assert_Cover
(Get_Build (Syn_Inst), Lab,
Build_Extract_Bit (Get_Build (Syn_Inst), Next_States,
Uns32 (Get_State_Label (Active))));
Set_Location (Inst, Get_Location (Stmt));
end if;
end if;
end Synth_Psl_Assert_Directive;
procedure Synth_Generate_Statement_Body
(Syn_Inst : Synth_Instance_Acc;
Bod : Node;
Name : Sname;
Iterator : Node := Null_Node;
Iterator_Val : Valtyp := No_Valtyp)
is
use Areapools;
Decls_Chain : constant Node := Get_Declaration_Chain (Bod);
Prev_Instance_Pool : constant Areapool_Acc := Instance_Pool;
Bod_Inst : Synth_Instance_Acc;
M : Areapools.Mark_Type;
begin
Bod_Inst := Make_Instance (Syn_Inst, Bod, Name);
Mark (M, Proc_Pool);
Instance_Pool := Proc_Pool'Access;
if Iterator /= Null_Node then
-- Add the iterator (for for-generate).
Create_Object (Bod_Inst, Iterator, Iterator_Val);
end if;
Synth_Declarations (Bod_Inst, Decls_Chain);
Synth_Concurrent_Statements
(Bod_Inst, Get_Concurrent_Statement_Chain (Bod));
Synth_Attribute_Values (Bod_Inst, Bod);
Finalize_Declarations (Bod_Inst, Decls_Chain);
Free_Instance (Bod_Inst);
Release (M, Proc_Pool);
Instance_Pool := Prev_Instance_Pool;
end Synth_Generate_Statement_Body;
procedure Synth_If_Generate_Statement
(Syn_Inst : Synth_Instance_Acc; Stmt : Node)
is
Gen : Node;
Bod : Node;
Icond : Node;
Cond : Valtyp;
Name : Sname;
begin
Gen := Stmt;
Name := New_Sname_User (Get_Identifier (Stmt), Get_Sname (Syn_Inst));
loop
Icond := Get_Condition (Gen);
if Icond /= Null_Node then
Cond := Synth_Expression (Syn_Inst, Icond);
Strip_Const (Cond);
else
-- It is the else generate.
Cond := No_Valtyp;
end if;
if Cond = No_Valtyp or else Read_Discrete (Cond) = 1 then
Bod := Get_Generate_Statement_Body (Gen);
Apply_Block_Configuration
(Get_Generate_Block_Configuration (Bod), Bod);
Synth_Generate_Statement_Body (Syn_Inst, Bod, Name);
exit;
end if;
Gen := Get_Generate_Else_Clause (Gen);
exit when Gen = Null_Node;
end loop;
end Synth_If_Generate_Statement;
procedure Synth_For_Generate_Statement
(Syn_Inst : Synth_Instance_Acc; Stmt : Node)
is
Iterator : constant Node := Get_Parameter_Specification (Stmt);
Bod : constant Node := Get_Generate_Statement_Body (Stmt);
Configs : constant Node := Get_Generate_Block_Configuration (Bod);
It_Type : constant Node := Get_Declaration_Type (Iterator);
Config : Node;
It_Rng : Type_Acc;
Val : Valtyp;
Name : Sname;
Lname : Sname;
begin
if It_Type /= Null_Node then
Synth_Subtype_Indication (Syn_Inst, It_Type);
end if;
-- Initial value.
It_Rng := Get_Subtype_Object (Syn_Inst, Get_Type (Iterator));
Val := Create_Value_Discrete (It_Rng.Drange.Left, It_Rng);
Name := New_Sname_User (Get_Identifier (Stmt), Get_Sname (Syn_Inst));
while In_Range (It_Rng.Drange, Read_Discrete (Val)) loop
-- Find and apply the config block.
declare
Spec : Node;
begin
Config := Configs;
while Config /= Null_Node loop
Spec := Get_Block_Specification (Config);
case Get_Kind (Spec) is
when Iir_Kind_Simple_Name =>
exit;
when others =>
Error_Kind ("synth_for_generate_statement", Spec);
end case;
Config := Get_Prev_Block_Configuration (Config);
end loop;
if Config = Null_Node then
raise Internal_Error;
end if;
Apply_Block_Configuration (Config, Bod);
end;
-- FIXME: get position ?
Lname := New_Sname_Version (Uns32 (Read_Discrete (Val)), Name);
Synth_Generate_Statement_Body (Syn_Inst, Bod, Lname, Iterator, Val);
Update_Index (It_Rng.Drange, Val);
end loop;
end Synth_For_Generate_Statement;
procedure Synth_Concurrent_Statement
(Syn_Inst : Synth_Instance_Acc; Stmt : Node)
is
Ctxt : constant Context_Acc := Get_Build (Syn_Inst);
begin
case Get_Kind (Stmt) is
when Iir_Kind_Concurrent_Simple_Signal_Assignment =>
Push_Phi;
Synth_Simple_Signal_Assignment (Syn_Inst, Stmt);
Pop_And_Merge_Phi (Ctxt, Get_Location (Stmt));
when Iir_Kind_Concurrent_Conditional_Signal_Assignment =>
Push_Phi;
Synth_Conditional_Signal_Assignment (Syn_Inst, Stmt);
Pop_And_Merge_Phi (Ctxt, Get_Location (Stmt));
when Iir_Kind_Concurrent_Selected_Signal_Assignment =>
Push_Phi;
Synth_Selected_Signal_Assignment (Syn_Inst, Stmt);
Pop_And_Merge_Phi (Ctxt, Get_Location (Stmt));
when Iir_Kind_Concurrent_Procedure_Call_Statement =>
Push_Phi;
Synth_Procedure_Call (Syn_Inst, Stmt);
Pop_And_Merge_Phi (Ctxt, Get_Location (Stmt));
when Iir_Kinds_Process_Statement =>
Synth_Process_Statement (Syn_Inst, Stmt);
when Iir_Kind_If_Generate_Statement =>
Synth_If_Generate_Statement (Syn_Inst, Stmt);
when Iir_Kind_For_Generate_Statement =>
Synth_For_Generate_Statement (Syn_Inst, Stmt);
when Iir_Kind_Component_Instantiation_Statement =>
if Is_Component_Instantiation (Stmt) then
declare
Comp_Config : constant Node :=
Get_Component_Configuration (Stmt);
begin
if Get_Binding_Indication (Comp_Config) = Null_Node then
-- Not bound.
Synth_Blackbox_Instantiation_Statement (Syn_Inst, Stmt);
else
Synth_Component_Instantiation_Statement (Syn_Inst, Stmt);
end if;
end;
-- Un-apply configuration.
Set_Component_Configuration (Stmt, Null_Node);
else
Synth_Design_Instantiation_Statement (Syn_Inst, Stmt);
end if;
when Iir_Kind_Block_Statement =>
Synth_Block_Statement (Syn_Inst, Stmt);
when Iir_Kind_Psl_Default_Clock =>
null;
when Iir_Kind_Psl_Restrict_Directive =>
Synth_Psl_Restrict_Directive (Syn_Inst, Stmt);
when Iir_Kind_Psl_Assume_Directive =>
if Flags.Flag_Assume_As_Assert then
Synth_Psl_Assert_Directive (Syn_Inst, Stmt);
else
Synth_Psl_Assume_Directive (Syn_Inst, Stmt);
end if;
when Iir_Kind_Psl_Cover_Directive =>
Synth_Psl_Cover_Directive (Syn_Inst, Stmt);
when Iir_Kind_Psl_Assert_Directive =>
if Flags.Flag_Assert_As_Assume then
Synth_Psl_Assume_Directive (Syn_Inst, Stmt);
else
Synth_Psl_Assert_Directive (Syn_Inst, Stmt);
end if;
when Iir_Kind_Concurrent_Assertion_Statement =>
-- Passive statement.
Synth_Concurrent_Assertion_Statement (Syn_Inst, Stmt);
when others =>
Error_Kind ("synth_concurrent_statement", Stmt);
end case;
end Synth_Concurrent_Statement;
procedure Synth_Concurrent_Statements
(Syn_Inst : Synth_Instance_Acc; Stmts : Node)
is
Stmt : Node;
begin
Stmt := Stmts;
while Is_Valid (Stmt) loop
Synth_Concurrent_Statement (Syn_Inst, Stmt);
Stmt := Get_Chain (Stmt);
end loop;
end Synth_Concurrent_Statements;
-- For allconst/allseq/...
procedure Synth_Attribute_Formal (Syn_Inst : Synth_Instance_Acc;
Val : Node;
Id : Formal_Module_Id)
is
Spec : constant Node := Get_Attribute_Specification (Val);
Sig : constant Node := Get_Designated_Entity (Val);
V : Valtyp;
begin
-- The type must be boolean
if (Get_Base_Type (Get_Type (Val)) /=
Vhdl.Std_Package.Boolean_Type_Definition)
then
Error_Msg_Synth (+Val, "type of attribute %i must be boolean",
(1 => +Get_Attribute_Designator (Spec)));
return;
end if;
-- The designated entity must be a signal.
if Get_Kind (Sig) /= Iir_Kind_Signal_Declaration then
Error_Msg_Synth (+Val, "attribute %i only applies to signals",
(1 => +Get_Attribute_Designator (Spec)));
return;
end if;
-- The value must be true
V := Synth_Expression_With_Type
(Syn_Inst, Get_Expression (Spec), Boolean_Type);
if Read_Discrete (V) /= 1 then
return;
end if;
declare
Off : Value_Offsets;
Dyn : Dyn_Name;
N : Net;
Base : Valtyp;
Typ : Type_Acc;
begin
Synth_Assignment_Prefix (Syn_Inst, Sig, Base, Typ, Off, Dyn);
pragma Assert (Off = (0, 0));
pragma Assert (Dyn.Voff = No_Net);
pragma Assert (Base.Val.Kind = Value_Wire);
pragma Assert (Base.Typ = Typ);
N := Build_Formal_Input (Get_Build (Syn_Inst), Id, Typ.W);
Set_Location (N, Val);
Add_Conc_Assign (Base.Val.W, N, 0);
end;
end Synth_Attribute_Formal;
procedure Synth_Attribute_Values
(Syn_Inst : Synth_Instance_Acc; Unit : Node)
is
use Std_Names;
Val : Node;
Spec : Node;
Id : Name_Id;
begin
Val := Get_Attribute_Value_Chain (Unit);
while Val /= Null_Node loop
Spec := Get_Attribute_Specification (Val);
Id := Get_Identifier (Get_Attribute_Designator (Spec));
case Id is
when Name_Allconst =>
Synth_Attribute_Formal (Syn_Inst, Val, Id_Allconst);
when Name_Allseq =>
Synth_Attribute_Formal (Syn_Inst, Val, Id_Allseq);
when Name_Anyconst =>
Synth_Attribute_Formal (Syn_Inst, Val, Id_Anyconst);
when Name_Anyseq =>
Synth_Attribute_Formal (Syn_Inst, Val, Id_Anyseq);
when Name_Loc =>
-- Applies to nets/ports.
null;
when others =>
Warning_Msg_Synth (+Spec, "unhandled attribute %i", (1 => +Id));
end case;
Val := Get_Value_Chain (Val);
end loop;
end Synth_Attribute_Values;
procedure Synth_Verification_Unit
(Syn_Inst : Synth_Instance_Acc; Unit : Node)
is
use Areapools;
Prev_Instance_Pool : constant Areapool_Acc := Instance_Pool;
Unit_Inst : Synth_Instance_Acc;
Unit_Sname : Sname;
M : Areapools.Mark_Type;
Item : Node;
Last_Type : Node;
begin
Unit_Sname := New_Sname_User (Get_Identifier (Unit),
Get_Sname (Syn_Inst));
Unit_Inst := Make_Instance (Syn_Inst, Unit, Unit_Sname);
Mark (M, Proc_Pool);
Instance_Pool := Proc_Pool'Access;
Apply_Block_Configuration
(Get_Verification_Block_Configuration (Unit), Unit);
Last_Type := Null_Node;
Item := Get_Vunit_Item_Chain (Unit);
while Item /= Null_Node loop
case Get_Kind (Item) is
when Iir_Kind_Psl_Default_Clock =>
null;
when Iir_Kind_Psl_Assert_Directive =>
Synth_Psl_Assert_Directive (Unit_Inst, Item);
when Iir_Kind_Psl_Assume_Directive =>
Synth_Psl_Assume_Directive (Unit_Inst, Item);
when Iir_Kind_Psl_Restrict_Directive =>
Synth_Psl_Restrict_Directive (Unit_Inst, Item);
when Iir_Kind_Psl_Cover_Directive =>
Synth_Psl_Cover_Directive (Unit_Inst, 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 =>
Synth_Declaration (Unit_Inst, Item, False, Last_Type);
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 =>
Synth_Concurrent_Statement (Unit_Inst, Item);
when others =>
Error_Kind ("synth_verification_unit", Item);
end case;
Item := Get_Chain (Item);
end loop;
Synth_Attribute_Values (Unit_Inst, Unit);
-- Finalize
Item := Get_Vunit_Item_Chain (Unit);
while Item /= Null_Node loop
case Get_Kind (Item) is
when Iir_Kind_Psl_Default_Clock
| Iir_Kind_Psl_Assert_Directive
| Iir_Kind_Psl_Assume_Directive
| Iir_Kind_Psl_Restrict_Directive
| Iir_Kind_Psl_Cover_Directive =>
null;
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 =>
null;
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 =>
Finalize_Declaration (Unit_Inst, Item, False);
when others =>
Error_Kind ("synth_verification_unit(2)", Item);
end case;
Item := Get_Chain (Item);
end loop;
Free_Instance (Unit_Inst);
Release (M, Proc_Pool);
Instance_Pool := Prev_Instance_Pool;
end Synth_Verification_Unit;
end Synth.Vhdl_Stmts;
|