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|
-- Environment definition for 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 Netlists.Builders; use Netlists.Builders;
with Netlists.Concats;
with Netlists.Gates;
with Netlists.Gates_Ports;
with Netlists.Locations; use Netlists.Locations;
with Netlists.Utils; use Netlists.Utils;
with Netlists.Folds; use Netlists.Folds;
with Netlists.Inference;
with Synth.Flags;
package body Synth.Environment is
procedure Phi_Assign
(Ctxt : Builders.Context_Acc; Dest : Wire_Id; Pasgn : Partial_Assign);
procedure Set_Wire_Mark (Wid : Wire_Id; Mark : Boolean := True) is
begin
Wire_Id_Table.Table (Wid).Mark_Flag := Mark;
end Set_Wire_Mark;
function Get_Wire_Mark (Wid : Wire_Id) return Boolean is
begin
return Wire_Id_Table.Table (Wid).Mark_Flag;
end Get_Wire_Mark;
function Alloc_Wire (Kind : Wire_Kind; Decl : Decl_Type) return Wire_Id
is
Res : Wire_Id;
begin
Wire_Id_Table.Append ((Kind => Kind,
Mark_Flag => False,
Decl => Decl,
Gate => No_Net,
Cur_Assign => No_Seq_Assign,
Final_Assign => No_Conc_Assign,
Nbr_Final_Assign => 0));
Res := Wire_Id_Table.Last;
return Res;
end Alloc_Wire;
procedure Free_Wire (Wid : Wire_Id)
is
Wire_Rec : Wire_Id_Record renames Wire_Id_Table.Table (Wid);
begin
-- Check the wire was not already free.
pragma Assert (Wire_Rec.Kind /= Wire_None);
-- All the assignments have been handled.
pragma Assert (Wire_Rec.Cur_Assign = No_Seq_Assign);
Wire_Rec.Kind := Wire_None;
end Free_Wire;
procedure Set_Kind (Wid : Wire_Id; Kind : Wire_Kind)
is
Wire_Rec : Wire_Id_Record renames Wire_Id_Table.Table (Wid);
begin
pragma Assert (Kind = Wire_Unset or Wire_Rec.Kind = Wire_Unset);
Wire_Rec.Kind := Kind;
end Set_Kind;
function Get_Kind (Wid : Wire_Id) return Wire_Kind
is
Wire_Rec : Wire_Id_Record renames Wire_Id_Table.Table (Wid);
begin
pragma Assert (Wire_Rec.Kind /= Wire_None);
return Wire_Rec.Kind;
end Get_Kind;
procedure Set_Wire_Gate (Wid : Wire_Id; Gate : Net) is
begin
-- Cannot override a gate.
pragma Assert (Wire_Id_Table.Table (Wid).Gate = No_Net);
Wire_Id_Table.Table (Wid).Gate := Gate;
end Set_Wire_Gate;
function Get_Wire_Gate (Wid : Wire_Id) return Net is
begin
return Wire_Id_Table.Table (Wid).Gate;
end Get_Wire_Gate;
function Get_Wire_Id (W : Seq_Assign) return Wire_Id is
begin
return Assign_Table.Table (W).Id;
end Get_Wire_Id;
function Get_Assign_Prev (Asgn : Seq_Assign) return Seq_Assign is
begin
return Assign_Table.Table (Asgn).Prev;
end Get_Assign_Prev;
function Get_Assign_Chain (Asgn : Seq_Assign) return Seq_Assign is
begin
return Assign_Table.Table (Asgn).Chain;
end Get_Assign_Chain;
procedure Set_Assign_Chain (Asgn : Seq_Assign; Chain : Seq_Assign) is
begin
Assign_Table.Table (Asgn).Chain := Chain;
end Set_Assign_Chain;
function Get_Assign_Is_Static (Asgn : Seq_Assign) return Boolean is
begin
return Assign_Table.Table (Asgn).Val.Is_Static = True;
end Get_Assign_Is_Static;
function Get_Assign_Static_Val (Asgn : Seq_Assign) return Static_Type is
begin
return Assign_Table.Table (Asgn).Val.Val;
end Get_Assign_Static_Val;
function Get_Assign_Partial (Asgn : Seq_Assign) return Partial_Assign is
begin
-- Note: fails if the value is static.
-- Use Get_Assign_Partial_Force if you want to automatically convert
-- the value to a Partial_Assign (a net).
return Assign_Table.Table (Asgn).Val.Asgns;
end Get_Assign_Partial;
function Get_Seq_Assign_Value (Asgn : Seq_Assign) return Seq_Assign_Value is
begin
return Assign_Table.Table (Asgn).Val;
end Get_Seq_Assign_Value;
function New_Partial_Assign (Val : Net; Offset : Uns32)
return Partial_Assign is
begin
Partial_Assign_Table.Append ((Next => No_Partial_Assign,
Value => Val,
Offset => Offset));
return Partial_Assign_Table.Last;
end New_Partial_Assign;
function Get_Partial_Offset (Asgn : Partial_Assign) return Uns32 is
begin
return Partial_Assign_Table.Table (Asgn).Offset;
end Get_Partial_Offset;
function Get_Partial_Value (Asgn : Partial_Assign) return Net is
begin
return Partial_Assign_Table.Table (Asgn).Value;
end Get_Partial_Value;
function Get_Partial_Next (Asgn : Partial_Assign) return Partial_Assign is
begin
return Partial_Assign_Table.Table (Asgn).Next;
end Get_Partial_Next;
procedure Set_Partial_Next (Asgn : Partial_Assign;
Chain : Partial_Assign) is
begin
Partial_Assign_Table.Table (Asgn).Next := Chain;
end Set_Partial_Next;
function Current_Phi return Phi_Id is
begin
return Phis_Table.Last;
end Current_Phi;
procedure Push_Phi is
begin
Phis_Table.Append ((First => No_Seq_Assign,
Last => No_Seq_Assign,
Nbr => 0,
En => No_Wire_Id));
end Push_Phi;
procedure Mark (M : out Wire_Id) is
begin
M := Wire_Id_Table.Last;
end Mark;
procedure Release (M : in out Wire_Id)
is
Last : Wire_Id;
begin
-- Check all wires to be released are free.
Last := M;
for I in M + 1 .. Wire_Id_Table.Last loop
declare
Wire_Rec : Wire_Id_Record renames Wire_Id_Table.Table (I);
Asgn : Seq_Assign;
begin
case Wire_Rec.Kind is
when Wire_None =>
null;
when Wire_Enable =>
-- Keep. This renames the wire, but the only references
-- must be in the wire.
Last := Last + 1;
if Last /= I then
-- Renames.
Asgn := Wire_Rec.Cur_Assign;
while Asgn /= No_Seq_Assign loop
Assign_Table.Table (Asgn).Id := Last;
Asgn := Get_Assign_Prev (Asgn);
end loop;
Wire_Id_Table.Table (Last) := Wire_Rec;
end if;
when others =>
raise Internal_Error;
end case;
end;
end loop;
-- Release.
Wire_Id_Table.Set_Last (Last);
M := No_Wire_Id;
end Release;
procedure All_Released is
begin
if Wire_Id_Table.Last /= No_Wire_Id then
raise Internal_Error;
end if;
end All_Released;
-- Concatenate when possible partial assignments of HEAD.
procedure Merge_Partial_Assignments
(Ctxt : Context_Acc; Head : Seq_Assign_Value)
is
use Netlists.Concats;
First : Partial_Assign;
Next : Partial_Assign;
Concat : Concat_Type;
Expected_Next_Off : Uns32;
Next_Off : Uns32;
Next_Val : Net;
begin
if Head.Is_Static /= False then
return;
end if;
First := Head.Asgns;
loop
exit when First = No_Partial_Assign;
Next := Get_Partial_Next (First);
exit when Next = No_Partial_Assign;
Expected_Next_Off := Get_Partial_Offset (First)
+ Get_Width (Get_Partial_Value (First));
Next_Off := Get_Partial_Offset (Next);
if Expected_Next_Off = Next_Off then
-- Merge First and Next.
Next_Val := Get_Partial_Value (Next);
Append (Concat, Get_Partial_Value (First));
Append (Concat, Next_Val);
Expected_Next_Off := Next_Off + Get_Width (Next_Val);
-- Merge as long as possible.
loop
Next := Get_Partial_Next (Next);
exit when Next = No_Partial_Assign;
Next_Off := Get_Partial_Offset (Next);
Next_Val := Get_Partial_Value (Next);
exit when Next_Off /= Expected_Next_Off;
Append (Concat, Next_Val);
Expected_Next_Off := Next_Off + Get_Width (Next_Val);
end loop;
-- Replace.
declare
First_Record : Partial_Assign_Record renames
Partial_Assign_Table.Table (First);
begin
Build (Ctxt, Concat, First_Record.Value);
First_Record.Next := Next;
end;
end if;
First := Next;
end loop;
end Merge_Partial_Assignments;
-- Get list of assignments for this current block.
procedure Pop_Phi (Phi : out Phi_Type)
is
Cur_Phi : constant Phi_Id := Current_Phi;
Asgn : Seq_Assign;
begin
-- Pop.
Phi := Phis_Table.Table (Cur_Phi);
Phis_Table.Decrement_Last;
-- Point to previous wires. The current values are the ones before
-- the block.
Asgn := Phi.First;
while Asgn /= No_Seq_Assign loop
pragma Assert (Assign_Table.Table (Asgn).Phi = Cur_Phi);
Wire_Id_Table.Table (Get_Wire_Id (Asgn)).Cur_Assign :=
Get_Assign_Prev (Asgn);
Asgn := Get_Assign_Chain (Asgn);
end loop;
end Pop_Phi;
procedure Phi_Discard_Wires (Wid1 : Wire_Id; Wid2 : Wire_Id)
is
Phi : Phi_Type renames Phis_Table.Table (Current_Phi);
Asgn, Next_Asgn : Seq_Assign;
Wid : Wire_Id;
begin
Asgn := Phi.First;
Phi := (First => No_Seq_Assign,
Last => No_Seq_Assign,
Nbr => 0,
En => No_Wire_Id);
while Asgn /= No_Seq_Assign loop
pragma Assert (Assign_Table.Table (Asgn).Phi = Current_Phi);
Next_Asgn := Get_Assign_Chain (Asgn);
Set_Assign_Chain (Asgn, No_Seq_Assign);
Wid := Get_Wire_Id (Asgn);
if Wid = Wid1 or Wid = Wid2 then
-- Discard.
pragma Assert (Wid /= No_Wire_Id);
Wire_Id_Table.Table (Wid).Cur_Assign := No_Seq_Assign;
else
-- Append.
if Phi.First = No_Seq_Assign then
Phi.First := Asgn;
else
Set_Assign_Chain (Phi.Last, Asgn);
end if;
Phi.Nbr := Phi.Nbr + 1;
Phi.Last := Asgn;
end if;
Asgn := Next_Asgn;
end loop;
end Phi_Discard_Wires;
function Get_Conc_Offset (Asgn : Conc_Assign) return Uns32 is
begin
return Conc_Assign_Table.Table (Asgn).Offset;
end Get_Conc_Offset;
function Get_Conc_Value (Asgn : Conc_Assign) return Net is
begin
return Conc_Assign_Table.Table (Asgn).Value;
end Get_Conc_Value;
function Get_Conc_Chain (Asgn : Conc_Assign) return Conc_Assign is
begin
return Conc_Assign_Table.Table (Asgn).Next;
end Get_Conc_Chain;
procedure Set_Conc_Chain (Asgn : Conc_Assign; Chain : Conc_Assign) is
begin
Conc_Assign_Table.Table (Asgn).Next := Chain;
end Set_Conc_Chain;
procedure Add_Conc_Assign (Wid : Wire_Id; Val : Net; Off : Uns32)
is
Wire_Rec : Wire_Id_Record renames Wire_Id_Table.Table (Wid);
begin
pragma Assert (Wire_Rec.Kind /= Wire_None);
Conc_Assign_Table.Append ((Next => Wire_Rec.Final_Assign,
Value => Val,
Offset => Off));
Wire_Rec.Final_Assign := Conc_Assign_Table.Last;
Wire_Rec.Nbr_Final_Assign := Wire_Rec.Nbr_Final_Assign + 1;
end Add_Conc_Assign;
procedure Pop_And_Merge_Phi_Wire (Ctxt : Builders.Context_Acc;
Asgn_Rec : Seq_Assign_Record;
Loc : Location_Type)
is
Wid : constant Wire_Id := Asgn_Rec.Id;
Wire_Rec : Wire_Id_Record renames Wire_Id_Table.Table (Wid);
Outport : constant Net := Wire_Rec.Gate;
-- Must be connected to an Id_Output or Id_Signal
pragma Assert (Outport /= No_Net);
P : Partial_Assign;
Res : Net;
begin
-- Check output is not already assigned.
pragma Assert (Get_Input_Net (Get_Net_Parent (Outport), 0) = No_Net);
case Asgn_Rec.Val.Is_Static is
when Unknown =>
raise Internal_Error;
when True =>
-- Create a net. No inference to do.
Res := Static_To_Net (Ctxt, Asgn_Rec.Val.Val);
if Wire_Rec.Kind = Wire_Enable then
Connect (Get_Input (Get_Net_Parent (Outport), 0), Res);
else
Add_Conc_Assign (Wid, Res, 0);
end if;
when False =>
P := Asgn_Rec.Val.Asgns;
pragma Assert (P /= No_Partial_Assign);
while P /= No_Partial_Assign loop
declare
Pa : Partial_Assign_Record renames
Partial_Assign_Table.Table (P);
begin
if Synth.Flags.Flag_Debug_Noinference then
Add_Conc_Assign (Wid, Pa.Value, Pa.Offset);
elsif Wire_Rec.Kind = Wire_Enable then
-- Possibly infere a idff/iadff.
pragma Assert (Pa.Offset = 0);
pragma Assert (Pa.Next = No_Partial_Assign);
Res := Inference.Infere_Assert
(Ctxt, Pa.Value, Outport, Loc);
Connect (Get_Input (Get_Net_Parent (Outport), 0), Res);
else
-- Note: lifetime is currently based on the kind of the
-- wire (variable -> not reused beyond this process).
-- This is OK for vhdl but not general.
Res := Inference.Infere
(Ctxt, Pa.Value, Pa.Offset, Outport, Loc,
Wire_Rec.Kind = Wire_Variable);
Add_Conc_Assign (Wid, Res, Pa.Offset);
end if;
P := Pa.Next;
end;
end loop;
end case;
end Pop_And_Merge_Phi_Wire;
-- This procedure is called after each concurrent statement to assign
-- values to signals.
procedure Pop_And_Merge_Phi (Ctxt : Builders.Context_Acc;
Loc : Location_Type)
is
Phi : Phi_Type;
Asgn : Seq_Assign;
begin
Pop_Phi (Phi);
-- Must be the last phi.
pragma Assert (Phis_Table.Last = No_Phi_Id);
-- It is possible that the same value is assigned to different targets.
-- Example:
-- if rising_edge(clk) then
-- a := c;
-- end if;
-- b := a;
-- Because the assignment is not yet done, only the net is stored in
-- the partial assign. When the net for variable A is infered and
-- changed to a dff, it is not known that it will also be assigned to
-- variable B.
--
-- Mark gates that will be infered. And if already marked, insert
-- a nop.
Asgn := Phi.First;
while Asgn /= No_Seq_Assign loop
declare
Asgn_Rec : Seq_Assign_Record renames Assign_Table.Table (Asgn);
P : Partial_Assign;
begin
if Asgn_Rec.Val.Is_Static = False then
P := Asgn_Rec.Val.Asgns;
pragma Assert (P /= No_Partial_Assign);
while P /= No_Partial_Assign loop
declare
Pa : Partial_Assign_Record
renames Partial_Assign_Table.Table (P);
Res_Inst : constant Instance := Get_Net_Parent (Pa.Value);
begin
if Get_Mark_Flag (Res_Inst)
and then Get_Id (Res_Inst) = Gates.Id_Mux2
then
-- A nop is needed iff the value is reused and will be
-- inferred (which is only possible for Id_Mux2).
Pa.Value := Build_Nop (Ctxt, Pa.Value);
else
Set_Mark_Flag (Res_Inst, True);
end if;
P := Pa.Next;
end;
end loop;
end if;
Asgn := Asgn_Rec.Chain;
end;
end loop;
-- Clear mark flag.
Asgn := Phi.First;
while Asgn /= No_Seq_Assign loop
declare
Asgn_Rec : Seq_Assign_Record renames Assign_Table.Table (Asgn);
P : Partial_Assign;
begin
if Asgn_Rec.Val.Is_Static = False then
P := Asgn_Rec.Val.Asgns;
pragma Assert (P /= No_Partial_Assign);
while P /= No_Partial_Assign loop
declare
Pa : Partial_Assign_Record
renames Partial_Assign_Table.Table (P);
Res_Inst : constant Instance := Get_Net_Parent (Pa.Value);
begin
Set_Mark_Flag (Res_Inst, False);
P := Pa.Next;
end;
end loop;
end if;
Asgn := Asgn_Rec.Chain;
end;
end loop;
Asgn := Phi.First;
while Asgn /= No_Seq_Assign loop
declare
Asgn_Rec : Seq_Assign_Record renames Assign_Table.Table (Asgn);
begin
Pop_And_Merge_Phi_Wire (Ctxt, Asgn_Rec, Loc);
Asgn := Asgn_Rec.Chain;
end;
end loop;
end Pop_And_Merge_Phi;
procedure Propagate_Phi_Until_Mark (Ctxt : Builders.Context_Acc;
Phi : Phi_Type;
Mark : Wire_Id)
is
Asgn, Next_Asgn : Seq_Assign;
begin
Asgn := Phi.First;
while Asgn /= No_Seq_Assign loop
declare
Asgn_Rec : Seq_Assign_Record renames Assign_Table.Table (Asgn);
Wid : constant Wire_Id := Asgn_Rec.Id;
Pasgn, Next_Pasgn : Partial_Assign;
begin
-- FIXME: Asgn_Rec may become invalid due to allocation by
-- Phi_Assign. So we read what is needed before calling
-- Phi_Assign.
Next_Asgn := Asgn_Rec.Chain;
if Wid <= Mark then
case Asgn_Rec.Val.Is_Static is
when Unknown =>
raise Internal_Error;
when True =>
Phi_Assign_Static (Wid, Asgn_Rec.Val.Val);
when False =>
Pasgn := Asgn_Rec.Val.Asgns;
while Pasgn /= No_Partial_Assign loop
Next_Pasgn := Get_Partial_Next (Pasgn);
Set_Partial_Next (Pasgn, No_Partial_Assign);
Phi_Assign (Ctxt, Wid, Pasgn);
Pasgn := Next_Pasgn;
end loop;
end case;
end if;
Asgn := Next_Asgn;
end;
end loop;
end Propagate_Phi_Until_Mark;
-- Merge sort of conc_assign by offset.
function Le_Conc_Assign (Left, Right : Conc_Assign) return Boolean is
begin
if Get_Conc_Offset (Left) < Get_Conc_Offset (Right) then
return True;
end if;
if Get_Conc_Offset (Left) = Get_Conc_Offset (Right) then
return (Get_Width (Get_Conc_Value (Left))
< Get_Width (Get_Conc_Value (Right)));
else
return False;
end if;
end Le_Conc_Assign;
procedure Sort_Conc_Assign (Chain : Conc_Assign;
Len : Natural;
First : out Conc_Assign;
Next : out Conc_Assign)
is
Left, Right : Conc_Assign;
Last : Conc_Assign;
El : Conc_Assign;
begin
if Len = 0 then
First := No_Conc_Assign;
Next := Chain;
elsif Len = 1 then
First := Chain;
Next := Get_Conc_Chain (Chain);
Set_Conc_Chain (Chain, No_Conc_Assign);
else
-- Divide.
Sort_Conc_Assign (Chain, Len / 2, Left, Right);
Sort_Conc_Assign (Right, Len - Len / 2, Right, Next);
First := No_Conc_Assign;
Last := No_Conc_Assign;
for I in 1 .. Len loop
pragma Assert (not (Left = No_Conc_Assign
and Right = No_Conc_Assign));
if Right = No_Conc_Assign
or else
(Left /= No_Conc_Assign and then Le_Conc_Assign (Left, Right))
then
El := Left;
Left := Get_Conc_Chain (Left);
else
pragma Assert (Right /= No_Conc_Assign);
El := Right;
Right := Get_Conc_Chain (Right);
end if;
-- Append
if First = No_Conc_Assign then
First := El;
else
Set_Conc_Chain (Last, El);
end if;
Last := El;
end loop;
Set_Conc_Chain (Last, No_Conc_Assign);
end if;
end Sort_Conc_Assign;
-- Return True iff PREV and NEXT are two concurrent assignments for
-- a multiport memory.
function Is_Finalize_Assignment_Multiport (Prev, Next : Conc_Assign)
return Boolean
is
use Netlists.Gates;
P_Val : Net;
N_Val : Net;
begin
-- The assignemnts must fully overlap (same offset and same width).
if Get_Conc_Offset (Prev) /= Get_Conc_Offset (Next) then
return False;
end if;
P_Val := Get_Conc_Value (Prev);
N_Val := Get_Conc_Value (Next);
if Get_Width (P_Val) /= Get_Width (N_Val) then
return False;
end if;
-- Both assignments must be a dff.
case Get_Id (Get_Net_Parent (P_Val)) is
when Id_Dyn_Insert_En =>
null;
when others =>
return False;
end case;
case Get_Id (Get_Net_Parent (N_Val)) is
when Id_Dyn_Insert_En =>
null;
when others =>
return False;
end case;
return True;
end Is_Finalize_Assignment_Multiport;
function Is_Tribuf_Net (N : Net) return Boolean
is
use Netlists.Gates;
begin
case Get_Id (Get_Net_Parent (N)) is
when Id_Tri
| Id_Resolver
| Id_Port =>
return True;
when others =>
return False;
end case;
end Is_Tribuf_Net;
function Is_Tribuf_Assignment (Prev, Next : Conc_Assign) return Boolean
is
P_Val : Net;
N_Val : Net;
begin
-- The assignemnts must fully overlap (same offset and same width).
if Get_Conc_Offset (Prev) /= Get_Conc_Offset (Next) then
return False;
end if;
P_Val := Get_Conc_Value (Prev);
N_Val := Get_Conc_Value (Next);
if Get_Width (P_Val) /= Get_Width (N_Val) then
return False;
end if;
-- Both assignments must be a tri or a resolver.
return Is_Tribuf_Net (P_Val)
and then Is_Tribuf_Net (N_Val);
end Is_Tribuf_Assignment;
-- Compute the VALUE to be assigned to WIRE_REC. Handle partial
-- assignment, multiple assignments and error cases.
procedure Finalize_Complex_Assignment (Ctxt : Builders.Context_Acc;
Wire_Rec : Wire_Id_Record;
Value : out Net)
is
Wire_Width : constant Width := Get_Width (Wire_Rec.Gate);
First_Assign : Conc_Assign;
Asgn : Conc_Assign;
Last_Asgn : Conc_Assign;
New_Asgn : Conc_Assign;
Next_Off : Uns32;
Expected_Off : Uns32;
Nbr_Assign : Natural;
begin
Nbr_Assign := Wire_Rec.Nbr_Final_Assign;
-- Sort assignments by offset.
Asgn := Wire_Rec.Final_Assign;
Sort_Conc_Assign (Asgn, Nbr_Assign, Asgn, Last_Asgn);
First_Assign := Asgn;
-- Report overlaps and holes, count number of inputs
Last_Asgn := No_Conc_Assign;
Expected_Off := 0;
while (Expected_Off < Wire_Width) or Asgn /= No_Conc_Assign loop
-- NEXT_OFF is the offset of the next assignment.
-- EXPECTED_OFF is the offset just after the previous assignment.
if Asgn /= No_Conc_Assign then
Next_Off := Get_Conc_Offset (Asgn);
else
-- If there is no more assignment, simulate a hole until the end.
Next_Off := Wire_Width;
end if;
if Next_Off = Expected_Off then
-- Normal case.
pragma Assert (Asgn /= No_Conc_Assign);
Expected_Off := Expected_Off + Get_Width (Get_Conc_Value (Asgn));
Last_Asgn := Asgn;
Asgn := Get_Conc_Chain (Asgn);
elsif Next_Off > Expected_Off then
-- There is an hole.
Warning_No_Assignment (Wire_Rec.Decl, Expected_Off, Next_Off - 1);
-- Insert conc_assign with initial value.
-- FIXME: handle initial values.
Conc_Assign_Table.Append
((Next => Asgn,
Value => Build_Const_Z (Ctxt, Next_Off - Expected_Off),
Offset => Expected_Off));
New_Asgn := Conc_Assign_Table.Last;
if Last_Asgn = No_Conc_Assign then
First_Assign := New_Asgn;
else
Set_Conc_Chain (Last_Asgn, New_Asgn);
end if;
Last_Asgn := New_Asgn;
Nbr_Assign := Nbr_Assign + 1;
Expected_Off := Next_Off;
else
-- Overlap.
pragma Assert (Next_Off < Expected_Off);
pragma Assert (Asgn /= No_Conc_Assign);
if Wire_Rec.Kind = Wire_Variable
and then Is_Finalize_Assignment_Multiport (Last_Asgn, Asgn)
then
-- Insert a multiport (for shared variable).
declare
Last_Asgn_Rec : Conc_Assign_Record renames
Conc_Assign_Table.Table (Last_Asgn);
begin
Last_Asgn_Rec.Value := Build_Mem_Multiport
(Ctxt, Last_Asgn_Rec.Value, Get_Conc_Value (Asgn));
end;
-- Remove this assignment.
Nbr_Assign := Nbr_Assign - 1;
Set_Conc_Chain (Last_Asgn, Get_Conc_Chain (Asgn));
elsif Is_Tribuf_Assignment (Last_Asgn, Asgn) then
-- Insert a resolver.
declare
Last_Asgn_Rec : Conc_Assign_Record renames
Conc_Assign_Table.Table (Last_Asgn);
V : constant Net := Last_Asgn_Rec.Value;
begin
Last_Asgn_Rec.Value := Build_Resolver
(Ctxt, V, Get_Conc_Value (Asgn));
Copy_Location (Last_Asgn_Rec.Value, V);
end;
-- Remove this assignment.
Nbr_Assign := Nbr_Assign - 1;
Set_Conc_Chain (Last_Asgn, Get_Conc_Chain (Asgn));
else
declare
Asgn_Wd : constant Width :=
Get_Width (Get_Conc_Value (Asgn));
Overlap_Wd : Width;
begin
Overlap_Wd := Asgn_Wd;
if Next_Off + Overlap_Wd > Expected_Off then
Overlap_Wd := Expected_Off - Next_Off;
end if;
Error_Multiple_Assignments
(Wire_Rec.Decl, Next_Off, Next_Off + Overlap_Wd - 1);
if Next_Off + Asgn_Wd < Expected_Off then
-- Remove this assignment
Nbr_Assign := Nbr_Assign - 1;
Set_Conc_Chain (Last_Asgn, Get_Conc_Chain (Asgn));
else
Expected_Off := Next_Off + Asgn_Wd;
Last_Asgn := Asgn;
end if;
end;
end if;
Asgn := Get_Conc_Chain (Asgn);
end if;
end loop;
-- Create concat
-- Set concat inputs
if Nbr_Assign = 1 then
Value := Get_Conc_Value (First_Assign);
elsif Nbr_Assign = 2 then
Value := Build_Concat2 (Ctxt,
Get_Conc_Value (Last_Asgn),
Get_Conc_Value (First_Assign));
else
Value := Build_Concatn (Ctxt, Wire_Width, Uns32 (Nbr_Assign));
declare
Inst : constant Instance := Get_Net_Parent (Value);
begin
Asgn := First_Assign;
for I in reverse 0 .. Nbr_Assign - 1 loop
Connect (Get_Input (Inst, Port_Idx (I)), Get_Conc_Value (Asgn));
Asgn := Get_Conc_Chain (Asgn);
end loop;
end;
end if;
end Finalize_Complex_Assignment;
procedure Finalize_Assignment
(Ctxt : Builders.Context_Acc; Wid : Wire_Id)
is
Wire_Rec : Wire_Id_Record renames Wire_Id_Table.Table (Wid);
Gate_Inst : constant Instance := Get_Net_Parent (Wire_Rec.Gate);
Inp : constant Input := Get_Input (Gate_Inst, 0);
Value : Net;
begin
case Wire_Rec.Nbr_Final_Assign is
when 0 =>
-- TODO: use initial value ?
-- TODO: fix that in synth-decls.finalize_object.
if Wire_Rec.Kind = Wire_Output then
Warning_No_Assignment (Wire_Rec.Decl, 1, 0);
if Get_Id (Gate_Inst) = Gates.Id_Iinout then
Value := Get_Input_Net (Gate_Inst, 1);
else
Value := Build_Const_Z (Ctxt, Get_Width (Wire_Rec.Gate));
end if;
else
return;
end if;
when 1 =>
declare
Conc_Asgn : Conc_Assign_Record renames
Conc_Assign_Table.Table (Wire_Rec.Final_Assign);
begin
if Conc_Asgn.Offset = 0
and then (Get_Width (Conc_Asgn.Value)
= Get_Width (Wire_Rec.Gate))
then
-- Single and full assignment.
Value := Conc_Asgn.Value;
else
-- Partial assignment.
Finalize_Complex_Assignment (Ctxt, Wire_Rec, Value);
end if;
end;
Wire_Rec.Final_Assign := No_Conc_Assign;
when others =>
-- Multiple assignments.
Finalize_Complex_Assignment (Ctxt, Wire_Rec, Value);
Wire_Rec.Final_Assign := No_Conc_Assign;
end case;
Connect (Inp, Value);
end Finalize_Assignment;
procedure Finalize_Wires is
begin
pragma Assert (Phis_Table.Last = No_Phi_Id);
-- pragma Assert (Assign_Table.Last = No_Seq_Assign);
for Wid in Wire_Id_Table.First + 1 .. Wire_Id_Table.Last loop
declare
Wire_Rec : Wire_Id_Record renames Wire_Id_Table.Table (Wid);
begin
pragma Assert (Wire_Rec.Kind = Wire_None
or Wire_Rec.Kind = Wire_Enable);
pragma Assert (Wire_Rec.Final_Assign = No_Conc_Assign);
null;
end;
end loop;
Wire_Id_Table.Set_Last (No_Wire_Id);
end Finalize_Wires;
-- Sort the LEN first wires of chain W (linked by Chain) in Id increasing
-- values. The result is assigned to FIRST and the first non-sorted wire
-- (the one after LEN) is assigned to NEXT. The chain headed by FIRST
-- is truncated to LEN elements.
-- Use a merge sort.
procedure Sort_Wires (Asgn : Seq_Assign;
Len : Uns32;
First : out Seq_Assign;
Next : out Seq_Assign)
is
Left, Right : Seq_Assign;
Last : Seq_Assign;
El : Seq_Assign;
begin
if Len = 0 then
-- Empty chain.
First := No_Seq_Assign;
Next := Asgn;
return;
elsif Len = 1 then
-- Chain with one element.
First := Asgn;
Next := Get_Assign_Chain (First);
Set_Assign_Chain (First, No_Seq_Assign);
return;
else
-- Divide.
Sort_Wires (Asgn, Len / 2, Left, Right);
Sort_Wires (Right, Len - Len / 2, Right, Next);
-- Conquer: merge.
First := No_Seq_Assign;
Last := No_Seq_Assign;
for I in 1 .. Len loop
if Left /= No_Seq_Assign
and then (Right = No_Seq_Assign
or else Get_Wire_Id (Left) <= Get_Wire_Id (Right))
then
El := Left;
Left := Get_Assign_Chain (Left);
else
pragma Assert (Right /= No_Seq_Assign);
El := Right;
Right := Get_Assign_Chain (Right);
end if;
-- Append
if First = No_Seq_Assign then
First := El;
else
Set_Assign_Chain (Last, El);
end if;
Last := El;
end loop;
Set_Assign_Chain (Last, No_Seq_Assign);
end if;
end Sort_Wires;
function Sort_Phi (P : Phi_Type) return Seq_Assign
is
Res, Last : Seq_Assign;
begin
Sort_Wires (P.First, P.Nbr, Res, Last);
pragma Assert (Last = No_Seq_Assign);
return Res;
end Sort_Phi;
function Get_Assign_Value (Ctxt : Builders.Context_Acc; Asgn : Seq_Assign)
return Net
is
Asgn_Rec : Seq_Assign_Record renames Assign_Table.Table (Asgn);
Wid_Rec : Wire_Id_Record renames Wire_Id_Table.Table (Asgn_Rec.Id);
W : constant Width := Get_Width (Wid_Rec.Gate);
begin
case Wid_Rec.Kind is
when Wire_Signal | Wire_Output | Wire_Inout
| Wire_Variable | Wire_Unset =>
null;
when Wire_Input | Wire_Enable | Wire_None =>
raise Internal_Error;
end case;
if Asgn_Rec.Val.Is_Static = True then
return Static_To_Net (Ctxt, Asgn_Rec.Val.Val);
end if;
-- Cannot be empty.
pragma Assert (Asgn_Rec.Val.Asgns /= No_Partial_Assign);
-- Simple case: fully assigned.
declare
Pasgn : Partial_Assign_Record renames
Partial_Assign_Table.Table (Asgn_Rec.Val.Asgns);
begin
if Pasgn.Offset = 0 and then Get_Width (Pasgn.Value) = W then
return Pasgn.Value;
end if;
end;
return Get_Current_Assign_Value (Ctxt, Asgn_Rec.Id, 0, W);
end Get_Assign_Value;
function Get_Current_Value (Ctxt : Builders.Context_Acc; Wid : Wire_Id)
return Net
is
Wire_Rec : Wire_Id_Record renames Wire_Id_Table.Table (Wid);
pragma Assert (Wire_Rec.Kind /= Wire_None);
begin
case Wire_Rec.Kind is
when Wire_Variable =>
if Wire_Rec.Cur_Assign = No_Seq_Assign then
-- The variable was never assigned, so the variable value is
-- the initial value.
-- FIXME: use initial value directly ?
return Wire_Rec.Gate;
else
return Get_Assign_Value (Ctxt, Wire_Rec.Cur_Assign);
end if;
when Wire_Signal | Wire_Output | Wire_Inout | Wire_Input
| Wire_Enable =>
-- For signals, always read the previous value.
return Wire_Rec.Gate;
when Wire_Unset =>
pragma Assert (Wire_Rec.Cur_Assign = No_Seq_Assign);
return Wire_Rec.Gate;
when Wire_None =>
raise Internal_Error;
end case;
end Get_Current_Value;
-- Get the current value of W for WD bits at offset OFF.
function Get_Current_Assign_Value
(Ctxt : Context_Acc; Wid : Wire_Id; Off : Uns32; Wd : Width)
return Net
is
Wire_Rec : Wire_Id_Record renames Wire_Id_Table.Table (Wid);
pragma Assert (Wire_Rec.Kind /= Wire_None);
First_Seq : Seq_Assign;
begin
-- Latest seq assign
First_Seq := Wire_Rec.Cur_Assign;
-- If no seq assign, return current value.
if First_Seq = No_Seq_Assign then
return Build2_Extract_Push (Ctxt, Wire_Rec.Gate, Off, Wd);
end if;
-- If the current value is static, just return it.
if Get_Assign_Is_Static (First_Seq) then
return Partial_Static_To_Net
(Ctxt, Get_Assign_Static_Val (First_Seq), Off, Wd);
end if;
-- If the range is the same as the seq assign, return the value.
declare
P : constant Partial_Assign := Get_Assign_Partial (First_Seq);
V : Net;
begin
if Get_Partial_Offset (P) = Off then
V := Get_Partial_Value (P);
if Get_Width (V) = Wd then
return V;
end if;
end if;
end;
-- Build a vector
declare
use Netlists.Concats;
Vec : Concat_Type;
Seq : Seq_Assign;
P : Partial_Assign;
Cur_Off : Uns32;
Cur_Wd : Width;
Res : Net;
begin
Cur_Off := Off;
Cur_Wd := Wd;
pragma Assert (Wd > 0);
loop
-- Find value at CUR_OFF from assignment. Start at the top
-- phi (which is not a static value).
Seq := First_Seq;
P := Get_Assign_Partial (Seq);
loop
pragma Assert (P /= No_Partial_Assign);
declare
Pr : Partial_Assign_Record renames
Partial_Assign_Table.Table (P);
Pw : constant Width := Get_Width (Pr.Value);
begin
if Pr.Offset <= Cur_Off
and then Pr.Offset + Pw > Cur_Off
then
-- Found.
if Pr.Offset = Cur_Off and then Pw <= Cur_Wd then
-- No need to extract.
Append (Vec, Pr.Value);
Cur_Wd := Pw;
else
Cur_Wd := Width'Min
(Cur_Wd, Pw - (Cur_Off - Pr.Offset));
Append
(Vec,
Build2_Extract_Push (Ctxt, Pr.Value,
Cur_Off - Pr.Offset, Cur_Wd));
end if;
exit;
end if;
if Pr.Offset + Pw <= Cur_Off then
-- Skip this partial, it is before what we are searching.
P := Pr.Next;
elsif Pr.Offset > Cur_Off
and then Pr.Offset < Cur_Off + Cur_Wd
then
-- There is a partial assignment that should be
-- considered, but first we need some values before it.
-- Reduce WD and continue to search in previous;
Cur_Wd := Pr.Offset - Cur_Off;
P := No_Partial_Assign;
else
-- The next partial assignment is beyond what we are
-- searching.
-- Continue to search in previous.
P := No_Partial_Assign;
end if;
if P = No_Partial_Assign then
Seq := Get_Assign_Prev (Seq);
if Seq = No_Seq_Assign then
-- Extract from gate.
Append (Vec, Build2_Extract_Push (Ctxt, Wire_Rec.Gate,
Cur_Off, Cur_Wd));
exit;
end if;
if Get_Assign_Is_Static (Seq) then
-- Extract from static value.
Append (Vec, Partial_Static_To_Net
(Ctxt, Get_Assign_Static_Val (Seq),
Cur_Off, Cur_Wd));
exit;
end if;
P := Get_Assign_Partial (Seq);
end if;
end;
end loop;
Cur_Off := Cur_Off + Cur_Wd;
Cur_Wd := Wd - (Cur_Off - Off);
exit when Cur_Off = Off + Wd;
end loop;
-- Concat
Build (Ctxt, Vec, Res);
return Res;
end;
end Get_Current_Assign_Value;
-- P is an array of Partial_Assign. Each element is a list
-- of partial assign from a different basic block.
-- Extract the value to nets N of the maximal partial assignment starting
-- at offset OFF for all partial assignments. Fully handled partial
-- assignments are poped. Set the offset and width to OFF and WD of the
-- result.
procedure Extract_Merge_Partial_Assigns (Ctxt : Builders.Context_Acc;
P : in out Seq_Assign_Value_Array;
N : out Net_Array;
Off : in out Uns32;
Wd : out Width)
is
Min_Off : Uns32;
begin
Min_Off := Off;
-- Look for the partial assign with the least offset (but still
-- greather than Min_Off). Also extract the least width.
Off := Uns32'Last;
Wd := Width'Last;
for I in P'Range loop
case P (I).Is_Static is
when Unknown =>
-- No assignment.
null;
when True =>
declare
P_Wd : constant Width := Get_Width (P (I).Val); --.Typ.W;
begin
if Min_Off >= P_Wd then
-- No net can be beyond the width.
pragma Assert (Off = Uns32'Last);
pragma Assert (Wd = Width'Last);
return;
end if;
if Off > Min_Off and then Off < P_Wd then
-- There is already an assignment for an offset after
-- the minimum. Stick to the min!
Wd := Off - Min_Off;
Off := Min_Off;
else
-- Either no assignment, or an assignment at Min_Off.
Off := Min_Off;
Wd := Width'Min (Wd, P_Wd - Min_Off);
end if;
end;
when False =>
declare
pragma Assert (P (I).Asgns /= No_Partial_Assign);
Pa : Partial_Assign_Record
renames Partial_Assign_Table.Table (P (I).Asgns);
N_Wd : Width;
N_Off : Uns32;
begin
if Pa.Offset < Off and then Min_Off < Off then
-- There is an assignment for an offset before the
-- current one. Handle it.
pragma Assert (Off >= Min_Off);
N_Off := Uns32'Max (Pa.Offset, Min_Off);
N_Wd := Get_Width (Pa.Value) - (N_Off - Pa.Offset);
Wd := Width'Min (N_Wd, Off - N_Off);
Off := N_Off;
elsif Pa.Offset = Off
or else (Off = Min_Off and then Pa.Offset < Off)
then
-- Reduce the width if the assignment is shorter.
Wd := Width'Min
(Wd, Get_Width (Pa.Value) - (Off - Pa.Offset));
elsif Pa.Offset < Off + Wd then
-- Reduce the width when there is an assignment after
-- the current offset.
Wd := Pa.Offset - Off;
end if;
end;
end case;
end loop;
-- No more assignments.
if Off = Uns32'Last and Wd = Width'Last then
return;
end if;
-- Get the values for that offset/width. Update lists.
for I in P'Range loop
-- Default: no partial assignment. Get extract previous value.
N (I) := No_Net;
case P (I).Is_Static is
when Unknown =>
null;
when True =>
N (I) := Partial_Static_To_Net (Ctxt, P (I).Val, Off, Wd);
when False =>
if Get_Partial_Offset (P (I).Asgns) <= Off then
declare
Asgn : constant Partial_Assign := P (I).Asgns;
Val : constant Net := Get_Partial_Value (Asgn);
P_W : constant Width := Get_Width (Val);
P_Off : constant Uns32 := Get_Partial_Offset (Asgn);
begin
-- There is a partial assignment.
if P_Off = Off and then P_W = Wd then
-- Full covered.
N (I) := Val;
P (I).Asgns := Get_Partial_Next (Asgn);
else
N (I) := Build_Extract (Ctxt, Val, Off - P_Off, Wd);
if P_Off + P_W = Off + Wd then
P (I).Asgns := Get_Partial_Next (Asgn);
end if;
end if;
end;
if P (I).Asgns = No_Partial_Assign then
P (I) := No_Seq_Assign_Value;
end if;
end if;
end case;
end loop;
end Extract_Merge_Partial_Assigns;
procedure Partial_Assign_Init (List : out Partial_Assign_List) is
begin
List := (First | Last => No_Partial_Assign);
end Partial_Assign_Init;
procedure Partial_Assign_Append (List : in out Partial_Assign_List;
Pasgn : Partial_Assign) is
begin
if List.First = No_Partial_Assign then
List.First := Pasgn;
else
Set_Partial_Next (List.Last, Pasgn);
end if;
List.Last := Pasgn;
end Partial_Assign_Append;
procedure Merge_Partial_Assigns (Ctxt : Builders.Context_Acc;
Wid : Wire_Id;
List : in out Partial_Assign_List)
is
Pasgn : Partial_Assign;
begin
while List.First /= No_Partial_Assign loop
Pasgn := Get_Partial_Next (List.First);
Set_Partial_Next (List.First, No_Partial_Assign);
Phi_Assign (Ctxt, Wid, List.First);
List.First := Pasgn;
end loop;
end Merge_Partial_Assigns;
-- Sub-routine of Merge_Assigns when the net is a dyn_insert
-- Try to transform it to a dyn_insert_en
function Merge_Dyn_Insert (Ctxt : Builders.Context_Acc;
Sel : Net;
N1_Inst : Instance;
N0 : Net) return Net
is
V : Net;
New_Inst : Instance;
begin
-- TODO: handle a serie of dyn_insert
-- TODO: also handle dyn_insert_en
-- TODO: negative SEL ?
V := Get_Input_Net (N1_Inst, 0);
if Same_Net (V, N0) then
New_Inst := Add_Enable_To_Dyn_Insert (Ctxt, N1_Inst, Sel);
return Get_Output (New_Inst, 0);
else
return Build_Mux2 (Ctxt, Sel, N0, Get_Output (N1_Inst, 0));
end if;
end Merge_Dyn_Insert;
procedure Merge_Assigns (Ctxt : Builders.Context_Acc;
Wid : Wire_Id;
Sel : Net;
F_Asgns : Seq_Assign_Value;
T_Asgns : Seq_Assign_Value;
Loc : Location_Type)
is
use Netlists.Gates;
use Netlists.Gates_Ports;
P : Seq_Assign_Value_Array (0 .. 1);
N : Net_Array (0 .. 1);
Min_Off : Uns32;
Off : Uns32;
Wd : Width;
Res : Net;
List : Partial_Assign_List;
Pasgn : Partial_Assign;
N1_Inst : Instance;
begin
P := (0 => F_Asgns, 1 => T_Asgns);
Partial_Assign_Init (List);
Min_Off := 0;
loop
Off := Min_Off;
Extract_Merge_Partial_Assigns (Ctxt, P, N, Off, Wd);
-- No more assignments.
exit when Off = Uns32'Last and Wd = Width'Last;
for I in N'Range loop
if N (I) = No_Net then
-- No partial assignment. Get extract previous value.
N (I) := Get_Current_Assign_Value (Ctxt, Wid, Off, Wd);
end if;
end loop;
-- Possible optimizations:
-- if C1 then _ _ _
-- if C2 then R0-|0\ R0-|0\ R0 -|0\
-- R := V; ==> | |-- T --+ | |- R ==> | |- R
-- end if; V-|_/ +----|_/ V-|_/
-- end if; C2 C1 C1.C2
--
-- Note: N (0) ~ R0, N (1) ~ T = first mux input
--
-- This really helps inference as the net R0 doesn't have to be
-- walked twice (in absence of memoization).
-- This optimization is not performed if T is used. This check is
-- not really necessary as if T is assigned it will also be handled
-- in this procedure and will be muxed by C1. But this simplifies
-- memory handling.
-- Build mux.
N1_Inst := Get_Net_Parent (N (1));
if Get_Id (N1_Inst) = Id_Mux2
and then not Is_Connected (N (1))
and then Same_Net (Get_Driver (Get_Mux2_I0 (N1_Inst)), N (0))
then
declare
N1_Net : Net;
N1_Sel : Input;
N1_Sel_Net : Net;
begin
N1_Net := Get_Output (N1_Inst, 0);
N1_Sel := Get_Input (N1_Inst, 0);
N1_Sel_Net := Get_Driver (N1_Sel);
if not Is_Connected (N1_Net) then
-- If the previous mux2 is not used, just modify it.
Res := N1_Net;
Disconnect (N1_Sel);
N1_Sel_Net := Build_Dyadic (Ctxt, Id_And, Sel, N1_Sel_Net);
Set_Location (N1_Sel_Net, Loc);
Connect (N1_Sel, N1_Sel_Net);
else
Res := Build_Dyadic (Ctxt, Id_And, Sel, N1_Sel_Net);
Set_Location (Res, Loc);
Res := Build_Mux2
(Ctxt, Res, N (0), Get_Driver (Get_Mux2_I1 (N1_Inst)));
end if;
end;
elsif not Flags.Flag_Debug_Nomemory1
and then Get_Id (N1_Inst) = Id_Dyn_Insert
and then not Is_Connected (N (1))
then
Res := Merge_Dyn_Insert (Ctxt, Sel, N1_Inst, N (0));
elsif N (0) = N (1) then
-- Minor optimization: no need to add a mux if both sides are
-- equal. But this is important for the control wires.
Res := N (0);
else
Res := Build_Mux2 (Ctxt, Sel, N (0), N (1));
end if;
Set_Location (Res, Loc);
-- Keep the result in a list.
Pasgn := New_Partial_Assign (Res, Off);
Partial_Assign_Append (List, Pasgn);
Min_Off := Off + Wd;
end loop;
-- Do the assignments from the result list.
-- It cannot be done before because the assignments will overwrite the
-- last assignments which are read to create a partial assignment.
Merge_Partial_Assigns (Ctxt, Wid, List);
end Merge_Assigns;
function Merge_Static_Assigns (Wid : Wire_Id; Tv, Fv : Seq_Assign_Value)
return Boolean
is
Prev : Static_Type;
begin
-- First case: both TV and FV are static.
if Tv.Is_Static = True and then Fv.Is_Static = True then
if Is_Equal (Tv.Val, Fv.Val) then
Phi_Assign_Static (Wid, Tv.Val);
return True;
else
return False;
end if;
end if;
-- If either TV or FV are nets, they cannot be merged.
if Tv.Is_Static = False or else Fv.Is_Static = False then
return False;
end if;
-- Get the previous value.
declare
Wire_Rec : Wire_Id_Record renames Wire_Id_Table.Table (Wid);
pragma Assert (Wire_Rec.Kind /= Wire_None);
First_Seq : Seq_Assign;
begin
-- Latest seq assign
First_Seq := Wire_Rec.Cur_Assign;
-- If no seq assign, fails.
if First_Seq = No_Seq_Assign then
return False;
end if;
if not Get_Assign_Is_Static (First_Seq) then
return False;
end if;
Prev := Get_Assign_Static_Val (First_Seq);
end;
if Tv.Is_Static = True then
pragma Assert (Fv = No_Seq_Assign_Value);
return Is_Equal (Tv.Val, Prev);
else
pragma Assert (Fv.Is_Static = True);
pragma Assert (Tv = No_Seq_Assign_Value);
return Is_Equal (Fv.Val, Prev);
end if;
end Merge_Static_Assigns;
-- Add muxes for two lists T and F of assignments.
procedure Merge_Phis (Ctxt : Builders.Context_Acc;
Sel : Net;
T, F : Phi_Type;
Loc : Location_Type)
is
T_Asgns : Seq_Assign;
F_Asgns : Seq_Assign;
W : Wire_Id;
Tv, Fv : Seq_Assign_Value;
begin
T_Asgns := Sort_Phi (T);
F_Asgns := Sort_Phi (F);
while T_Asgns /= No_Seq_Assign or F_Asgns /= No_Seq_Assign loop
-- Extract a wire.
if T_Asgns = No_Seq_Assign
or else (F_Asgns /= No_Seq_Assign
and then Get_Wire_Id (F_Asgns) < Get_Wire_Id (T_Asgns))
then
-- Has an assignment only for the false branch.
W := Get_Wire_Id (F_Asgns);
Fv := Get_Seq_Assign_Value (F_Asgns);
Tv := No_Seq_Assign_Value;
F_Asgns := Get_Assign_Chain (F_Asgns);
elsif F_Asgns = No_Seq_Assign
or else (T_Asgns /= No_Seq_Assign
and then Get_Wire_Id (T_Asgns) < Get_Wire_Id (F_Asgns))
then
-- Has an assignment only for the true branch.
W := Get_Wire_Id (T_Asgns);
Fv := No_Seq_Assign_Value;
Tv := Get_Seq_Assign_Value (T_Asgns);
T_Asgns := Get_Assign_Chain (T_Asgns);
else
-- Has assignments for both the true and the false branch.
pragma Assert (Get_Wire_Id (F_Asgns) = Get_Wire_Id (T_Asgns));
W := Get_Wire_Id (F_Asgns);
Fv := Get_Seq_Assign_Value (F_Asgns);
Tv := Get_Seq_Assign_Value (T_Asgns);
T_Asgns := Get_Assign_Chain (T_Asgns);
F_Asgns := Get_Assign_Chain (F_Asgns);
end if;
-- Merge partial assigns as much as possible. This reduce
-- propagation of splits.
Merge_Partial_Assignments (Ctxt, Fv);
Merge_Partial_Assignments (Ctxt, Tv);
if not Merge_Static_Assigns (W, Tv, Fv) then
Merge_Assigns (Ctxt, W, Sel, Fv, Tv, Loc);
end if;
end loop;
end Merge_Phis;
procedure Phi_Append_Assign (P : in out Phi_Type; Asgn : Seq_Assign) is
begin
-- Chain assignment in the current sequence.
if P.First = No_Seq_Assign then
P.First := Asgn;
else
Set_Assign_Chain (P.Last, Asgn);
end if;
P.Last := Asgn;
P.Nbr := P.Nbr + 1;
end Phi_Append_Assign;
procedure Phi_Append_Assign (Asgn : Seq_Assign)
is
pragma Assert (Asgn /= No_Seq_Assign);
Asgn_Rec : Seq_Assign_Record renames Assign_Table.Table (Asgn);
pragma Assert (Asgn_Rec.Phi = Current_Phi);
pragma Assert (Asgn_Rec.Chain = No_Seq_Assign);
begin
Phi_Append_Assign (Phis_Table.Table (Phis_Table.Last), Asgn);
end Phi_Append_Assign;
function Phi_Enable (Ctxt : Builders.Context_Acc;
Decl : Decl_Type;
Val_0 : Static_Type;
Val_1 : Static_Type;
Loc : Location_Type) return Net
is
Last : constant Phi_Id := Phis_Table.Last;
Wid : Wire_Id;
N : Net;
Asgn : Seq_Assign;
begin
if Last = No_Phi_Id then
-- Can be called only when a phi is created.
raise Internal_Error;
end if;
if Last = No_Phi_Id + 1 then
-- That's the first phi, which is always enabled.
return No_Net;
end if;
-- Cached value.
Wid := Phis_Table.Table (Last).En;
if Wid = No_Wire_Id then
Wid := Alloc_Wire (Wire_Enable, Decl);
Phis_Table.Table (Last).En := Wid;
-- Create the Enable gate.
N := Build_Enable (Ctxt);
Set_Location (N, Loc);
Set_Wire_Gate (Wid, N);
-- Initialize to '0'.
-- This is really cheating, as it is like assigning in the first
-- phi.
Assign_Table.Append ((Phi => No_Phi_Id + 1,
Id => Wid,
Prev => No_Seq_Assign,
Chain => No_Seq_Assign,
Val => (Is_Static => True, Val => Val_0)));
Asgn := Assign_Table.Last;
Wire_Id_Table.Table (Wid).Cur_Assign := Asgn;
Phi_Append_Assign (Phis_Table.Table (No_Phi_Id + 1), Asgn);
-- Assign to '1'.
Phi_Assign_Static (Wid, Val_1);
return N;
else
return Get_Current_Value (Ctxt, Wid);
end if;
end Phi_Enable;
-- Check consistency:
-- - ordered.
-- - no overlaps.
procedure Check (Seq : Seq_Assign)
is
Seq_Asgn : Seq_Assign_Record renames Assign_Table.Table (Seq);
Prev_El : Partial_Assign;
begin
Prev_El := Seq_Asgn.Val.Asgns;
if Prev_El = No_Partial_Assign then
-- It's empty!
return;
end if;
loop
declare
Prev : Partial_Assign_Record
renames Partial_Assign_Table.Table (Prev_El);
El : constant Partial_Assign := Prev.Next;
begin
if El = No_Partial_Assign then
-- Done.
exit;
end if;
declare
Cur : Partial_Assign_Record
renames Partial_Assign_Table.Table (El);
begin
-- Check no overlap.
if Cur.Offset < Prev.Offset + Get_Width (Prev.Value) then
raise Internal_Error;
end if;
end;
Prev_El := El;
end;
end loop;
end Check;
-- Insert partial assignment ASGN to list SEQ.
-- Deal with overrides. Place it correctly.
procedure Insert_Partial_Assign
(Ctxt : Builders.Context_Acc; Seq : Seq_Assign; Asgn : Partial_Assign)
is
V : Partial_Assign_Record renames Partial_Assign_Table.Table (Asgn);
V_Next : constant Uns32 := V.Offset + Get_Width (V.Value);
Seq_Asgn : Seq_Assign_Record renames Assign_Table.Table (Seq);
El, Last_El : Partial_Assign;
Inserted : Boolean;
begin
Inserted := False;
Last_El := No_Partial_Assign;
El := Seq_Asgn.Val.Asgns;
while El /= No_Partial_Assign loop
declare
P : Partial_Assign_Record renames Partial_Assign_Table.Table (El);
P_Next : constant Uns32 := P.Offset + Get_Width (P.Value);
begin
if V.Offset < P_Next and then V_Next > P.Offset then
-- Override.
if V.Offset <= P.Offset and then V_Next >= P_Next then
-- Full override:
-- V.Off V.Next
-- |------------------||
-- |----------||
-- P.Off P.Next
-- Remove it.
-- FIXME: free it.
if not Inserted then
if Last_El /= No_Partial_Assign then
Partial_Assign_Table.Table (Last_El).Next := Asgn;
else
Seq_Asgn.Val.Asgns := Asgn;
end if;
V.Next := P.Next;
Inserted := True;
Last_El := Asgn;
else
pragma Assert (Last_El /= No_Partial_Assign);
Partial_Assign_Table.Table (Last_El).Next := P.Next;
end if;
elsif V.Offset <= P.Offset and then V_Next < P_Next then
-- Overrides the beginning of EL.
-- V.Off V.Next
-- |--------------||
-- |----------||
-- P.Off P.Next
-- Shrink EL.
P.Value := Build2_Extract_Push (Ctxt, P.Value,
Off => V_Next - P.Offset,
W => P_Next - V_Next);
P.Offset := V_Next;
if not Inserted then
if Last_El /= No_Partial_Assign then
Partial_Assign_Table.Table (Last_El).Next := Asgn;
else
Seq_Asgn.Val.Asgns := Asgn;
end if;
V.Next := El;
Inserted := True;
end if;
-- No more possible overlaps.
exit;
elsif V.Offset > P.Offset and then P_Next <= V_Next then
-- Overrides the end of EL.
-- V.Off V.Next
-- |------------------||
-- |----------||
-- P.Off P.Next
-- Shrink EL.
P.Value := Build2_Extract_Push (Ctxt, P.Value,
Off => 0,
W => V.Offset - P.Offset);
pragma Assert (not Inserted);
V.Next := P.Next;
P.Next := Asgn;
Last_El := Asgn;
Inserted := True;
elsif V.Offset > P.Offset and then V_Next < P_Next then
-- Contained within EL.
-- V.Off V.Next
-- |----------||
-- |---------------||
-- P.Off P.Next
-- Split EL.
pragma Assert (not Inserted);
Partial_Assign_Table.Append
((Next => P.Next,
Value => Build2_Extract_Push (Ctxt, P.Value,
Off => V_Next - P.Offset,
W => P_Next - V_Next),
Offset => V_Next));
V.Next := Partial_Assign_Table.Last;
P.Value := Build2_Extract_Push (Ctxt, P.Value,
Off => 0,
W => V.Offset - P.Offset);
P.Next := Asgn;
Inserted := True;
-- No more possible overlaps.
exit;
else
-- No other case.
raise Internal_Error;
end if;
else
if V.Offset < P.Offset then
-- Insert before P (if not already inserted).
if not Inserted then
if Last_El /= No_Partial_Assign then
Partial_Assign_Table.Table (Last_El).Next := Asgn;
else
Seq_Asgn.Val.Asgns := Asgn;
end if;
V.Next := El;
Inserted := True;
end if;
exit;
elsif P.Next = No_Partial_Assign then
if not Inserted then
-- Insert after P.
P.Next := Asgn;
Inserted := True;
end if;
exit;
else
Last_El := El;
end if;
end if;
El := P.Next;
end;
end loop;
pragma Assert (Inserted);
pragma Debug (Check (Seq));
end Insert_Partial_Assign;
procedure Phi_Assign
(Ctxt : Builders.Context_Acc; Dest : Wire_Id; Pasgn : Partial_Assign)
is
Wire_Rec : Wire_Id_Record renames Wire_Id_Table.Table (Dest);
pragma Assert (Wire_Rec.Kind /= Wire_None);
Cur_Asgn : constant Seq_Assign := Wire_Rec.Cur_Assign;
begin
if Cur_Asgn = No_Seq_Assign
or else Assign_Table.Table (Cur_Asgn).Phi < Current_Phi
then
-- Never assigned, or first assignment in that level
Assign_Table.Append ((Phi => Current_Phi,
Id => Dest,
Prev => Cur_Asgn,
Chain => No_Seq_Assign,
Val => (Is_Static => False, Asgns => Pasgn)));
Wire_Rec.Cur_Assign := Assign_Table.Last;
Phi_Append_Assign (Assign_Table.Last);
else
-- Overwrite.
if Get_Assign_Is_Static (Cur_Asgn) then
-- Force seq_assign to be a net.
declare
Asgn_Rec : Seq_Assign_Record renames
Assign_Table.Table (Cur_Asgn);
N : Net;
Pa : Partial_Assign;
begin
N := Static_To_Net (Ctxt, Asgn_Rec.Val.Val);
Pa := New_Partial_Assign (N, 0);
Asgn_Rec.Val := (Is_Static => False, Asgns => Pa);
end;
end if;
Insert_Partial_Assign (Ctxt, Cur_Asgn, Pasgn);
end if;
end Phi_Assign;
procedure Phi_Assign_Net
(Ctxt : Builders.Context_Acc; Dest : Wire_Id; Val : Net; Offset : Uns32)
is
Pasgn : Partial_Assign;
begin
Pasgn := New_Partial_Assign (Val, Offset);
Phi_Assign (Ctxt, Dest, Pasgn);
end Phi_Assign_Net;
procedure Phi_Assign_Static (Dest : Wire_Id; Val : Static_Type)
is
Wire_Rec : Wire_Id_Record renames Wire_Id_Table.Table (Dest);
pragma Assert (Wire_Rec.Kind /= Wire_None);
Cur_Asgn : constant Seq_Assign := Wire_Rec.Cur_Assign;
begin
if Cur_Asgn = No_Seq_Assign
or else Assign_Table.Table (Cur_Asgn).Phi < Current_Phi
then
-- Never assigned, or first assignment in that level
Assign_Table.Append ((Phi => Current_Phi,
Id => Dest,
Prev => Cur_Asgn,
Chain => No_Seq_Assign,
Val => (Is_Static => True, Val => Val)));
Wire_Rec.Cur_Assign := Assign_Table.Last;
Phi_Append_Assign (Assign_Table.Last);
else
Assign_Table.Table (Cur_Asgn).Val := (Is_Static => True, Val => Val);
end if;
end Phi_Assign_Static;
-- Return the net driving WID when it is known to be possibly constant.
-- Return No_Net is not constant.
function Is_Static_Wire (Wid : Wire_Id) return Boolean
is
Wire_Rec : Wire_Id_Record renames Wire_Id_Table.Table (Wid);
begin
if Wire_Rec.Kind /= Wire_Variable then
return False;
end if;
if Wire_Rec.Cur_Assign = No_Seq_Assign then
return False;
end if;
return Get_Assign_Is_Static (Wire_Rec.Cur_Assign);
end Is_Static_Wire;
function Get_Static_Wire (Wid : Wire_Id) return Static_Type
is
Wire_Rec : Wire_Id_Record renames Wire_Id_Table.Table (Wid);
begin
return Get_Assign_Static_Val (Wire_Rec.Cur_Assign);
end Get_Static_Wire;
begin
Wire_Id_Table.Append ((Kind => Wire_None,
Mark_Flag => False,
Decl => <>,
Gate => No_Net,
Cur_Assign => No_Seq_Assign,
Final_Assign => No_Conc_Assign,
Nbr_Final_Assign => 0));
pragma Assert (Wire_Id_Table.Last = No_Wire_Id);
Assign_Table.Append ((Phi => No_Phi_Id,
Id => No_Wire_Id,
Prev => No_Seq_Assign,
Chain => No_Seq_Assign,
Val => (Is_Static => False,
Asgns => No_Partial_Assign)));
pragma Assert (Assign_Table.Last = No_Seq_Assign);
Partial_Assign_Table.Append ((Next => No_Partial_Assign,
Value => No_Net,
Offset => 0));
pragma Assert (Partial_Assign_Table.Last = No_Partial_Assign);
Phis_Table.Append ((First => No_Seq_Assign,
Last => No_Seq_Assign,
Nbr => 0,
En => No_Wire_Id));
pragma Assert (Phis_Table.Last = No_Phi_Id);
Conc_Assign_Table.Append ((Next => No_Conc_Assign,
Value => No_Net,
Offset => 0));
pragma Assert (Conc_Assign_Table.Last = No_Conc_Assign);
end Synth.Environment;
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