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-- PSL - Utils
-- Copyright (C) 2002-2016 Tristan Gingold
--
-- This program is free software: you can redistribute it and/or modify
-- it under the terms of the GNU General Public License as published by
-- the Free Software Foundation, either version 2 of the License, or
-- (at your option) any later version.
--
-- This program is distributed in the hope that it will be useful,
-- but WITHOUT ANY WARRANTY; without even the implied warranty of
-- MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
-- GNU General Public License for more details.
--
-- You should have received a copy of the GNU General Public License
-- along with this program. If not, see <gnu.org/licenses>.
with PSL.Types; use PSL.Types;
with PSL.Nodes_Priv;
with PSL.Errors; use PSL.Errors;
package body PSL.NFAs.Utils is
generic
with function Get_First_Edge (S : NFA_State) return NFA_Edge;
with function Get_Next_Edge (E : NFA_Edge) return NFA_Edge;
with procedure Set_First_Edge (S : NFA_State; E : NFA_Edge);
with procedure Set_Next_Edge (E : NFA_Edge; N_E : NFA_Edge);
with function Get_Edge_State (E : NFA_Edge) return NFA_State;
package Sort_Edges is
procedure Sort_Edges (S : NFA_State);
procedure Sort_Edges (N : NFA);
end Sort_Edges;
package body Sort_Edges is
-- Use merge sort to sort a list of edges.
-- The first edge is START and the list has LEN edges.
-- RES is the head of the sorted list.
-- NEXT_EDGE is the LEN + 1 edge (not sorted).
procedure Edges_Merge_Sort (Start : NFA_Edge;
Len : Natural;
Res : out NFA_Edge;
Next_Edge : out NFA_Edge)
is
function Lt (L, R : NFA_Edge) return Boolean
is
L_Expr : constant Node := Get_Edge_Expr (L);
R_Expr : constant Node := Get_Edge_Expr (R);
begin
return PSL.Nodes_Priv."<" (L_Expr, R_Expr)
or else (L_Expr = R_Expr
and then Get_Edge_State (L) < Get_Edge_State (R));
end Lt;
pragma Inline (Lt);
Half : constant Natural := Len / 2;
Left_Start, Right_Start : NFA_Edge;
Left_Next, Right_Next : NFA_Edge;
L, R : NFA_Edge;
Last, E : NFA_Edge;
begin
-- With less than 2 elements, the sort is trivial.
if Len < 2 then
if Len = 0 then
Next_Edge := Start;
else
Next_Edge := Get_Next_Edge (Start);
end if;
Res := Start;
return;
end if;
-- Sort each half.
Edges_Merge_Sort (Start, Half, Left_Start, Left_Next);
Edges_Merge_Sort (Left_Next, Len - Half, Right_Start, Right_Next);
-- Merge.
L := Left_Start;
R := Right_Start;
Last := No_Edge;
loop
-- Take from left iff:
-- * it is not empty
-- * right is empty or else (left < right)
if L /= Left_Next and then (R = Right_Next or else Lt (L, R)) then
E := L;
L := Get_Next_Edge (L);
-- Take from right if right is not empty.
elsif R /= Right_Next then
E := R;
R := Get_Next_Edge (R);
-- Both left are right are empty.
else
exit;
end if;
if Last = No_Edge then
Res := E;
else
Set_Next_Edge (Last, E);
end if;
Last := E;
end loop;
-- Let the link clean.
Next_Edge := Right_Next;
Set_Next_Edge (Last, Next_Edge);
end Edges_Merge_Sort;
procedure Sort_Edges (S : NFA_State)
is
Nbr_Edges : Natural;
First_E, E, Res : NFA_Edge;
begin
-- Count number of edges.
Nbr_Edges := 0;
First_E := Get_First_Edge (S);
E := First_E;
while E /= No_Edge loop
Nbr_Edges := Nbr_Edges + 1;
E := Get_Next_Edge (E);
end loop;
-- Sort edges by expression.
Edges_Merge_Sort (First_E, Nbr_Edges, Res, E);
pragma Assert (E = No_Edge);
Set_First_Edge (S, Res);
end Sort_Edges;
procedure Sort_Edges (N : NFA)
is
S : NFA_State;
begin
-- Iterate on states.
S := Get_First_State (N);
while S /= No_State loop
Sort_Edges (S);
S := Get_Next_State (S);
end loop;
end Sort_Edges;
end Sort_Edges;
package Sort_Src_Edges_Pkg is new
Sort_Edges (Get_First_Edge => Get_First_Src_Edge,
Get_Next_Edge => Get_Next_Src_Edge,
Set_First_Edge => Set_First_Src_Edge,
Set_Next_Edge => Set_Next_Src_Edge,
Get_Edge_State => Get_Edge_Dest);
procedure Sort_Src_Edges (S : NFA_State) renames
Sort_Src_Edges_Pkg.Sort_Edges;
procedure Sort_Src_Edges (N : NFA) renames
Sort_Src_Edges_Pkg.Sort_Edges;
package Sort_Dest_Edges_Pkg is new
Sort_Edges (Get_First_Edge => Get_First_Dest_Edge,
Get_Next_Edge => Get_Next_Dest_Edge,
Set_First_Edge => Set_First_Dest_Edge,
Set_Next_Edge => Set_Next_Dest_Edge,
Get_Edge_State => Get_Edge_Src);
procedure Sort_Dest_Edges (S : NFA_State) renames
Sort_Dest_Edges_Pkg.Sort_Edges;
procedure Sort_Dest_Edges (N : NFA) renames
Sort_Dest_Edges_Pkg.Sort_Edges;
generic
with function Get_First_Edge_Reverse (S : NFA_State) return NFA_Edge;
with function Get_First_Edge (S : NFA_State) return NFA_Edge;
with procedure Set_First_Edge (S : NFA_State; E : NFA_Edge);
with function Get_Next_Edge (E : NFA_Edge) return NFA_Edge;
with procedure Set_Next_Edge (E : NFA_Edge; E1 : NFA_Edge);
with procedure Set_Edge_State (E : NFA_Edge; S : NFA_State);
procedure Merge_State (N : NFA; S : NFA_State; S1 : NFA_State);
procedure Merge_State (N : NFA; S : NFA_State; S1 : NFA_State)
is
E, First_E, Next_E : NFA_Edge;
begin
pragma Assert (S /= S1);
-- Discard outgoing edges of S1.
loop
E := Get_First_Edge_Reverse (S1);
exit when E = No_Edge;
Remove_Edge (E);
end loop;
-- Prepend incoming edges of S1 to S.
First_E := Get_First_Edge (S);
E := Get_First_Edge (S1);
while E /= No_Edge loop
Next_E := Get_Next_Edge (E);
Set_Next_Edge (E, First_E);
Set_Edge_State (E, S);
First_E := E;
E := Next_E;
end loop;
Set_First_Edge (S, First_E);
Set_First_Edge (S1, No_Edge);
-- Move the active state if it is deleted.
if Get_Active_State (N) = S1 then
Set_Active_State (N, S);
end if;
Remove_State (N, S1);
end Merge_State;
procedure Merge_State_Dest_1 is new Merge_State
(Get_First_Edge_Reverse => Get_First_Src_Edge,
Get_First_Edge => Get_First_Dest_Edge,
Set_First_Edge => Set_First_Dest_Edge,
Get_Next_Edge => Get_Next_Dest_Edge,
Set_Next_Edge => Set_Next_Dest_Edge,
Set_Edge_State => Set_Edge_Dest);
procedure Merge_State_Dest (N : NFA; S : NFA_State; S1 : NFA_State) renames
Merge_State_Dest_1;
procedure Merge_State_Src_1 is new Merge_State
(Get_First_Edge_Reverse => Get_First_Dest_Edge,
Get_First_Edge => Get_First_Src_Edge,
Set_First_Edge => Set_First_Src_Edge,
Get_Next_Edge => Get_Next_Src_Edge,
Set_Next_Edge => Set_Next_Src_Edge,
Set_Edge_State => Set_Edge_Src);
procedure Merge_State_Src (N : NFA; S : NFA_State; S1 : NFA_State) renames
Merge_State_Src_1;
procedure Sort_Outgoing_Edges (N : NFA; Nbr_States : Natural)
is
Last_State : constant NFA_State := NFA_State (Nbr_States) - 1;
type Edge_Array is array (0 .. Last_State) of NFA_Edge;
Edges : Edge_Array := (others => No_Edge);
S, D : NFA_State;
E, Next_E : NFA_Edge;
First_Edge, Last_Edge : NFA_Edge;
begin
-- Iterate on states.
S := Get_First_State (N);
while S /= No_State loop
-- Create an array of edges
E := Get_First_Dest_Edge (S);
while E /= No_Edge loop
Next_E := Get_Next_Dest_Edge (E);
D := Get_Edge_Dest (E);
if Edges (D) /= No_Edge then
-- TODO: merge edges.
raise Program_Error;
end if;
Edges (D) := E;
E := Next_E;
end loop;
-- Rebuild the edge list (sorted by destination).
Last_Edge := No_Edge;
First_Edge := No_Edge;
for I in Edge_Array'Range loop
E := Edges (I);
if E /= No_Edge then
Edges (I) := No_Edge;
if First_Edge = No_Edge then
First_Edge := E;
else
Set_Next_Dest_Edge (Last_Edge, E);
end if;
Last_Edge := E;
end if;
end loop;
Set_First_Dest_Edge (S, First_Edge);
S := Get_Next_State (S);
end loop;
end Sort_Outgoing_Edges;
pragma Unreferenced (Sort_Outgoing_Edges);
generic
with function Get_First_Edge (S : NFA_State) return NFA_Edge;
with function Get_Next_Edge (E : NFA_Edge) return NFA_Edge;
with function Get_State_Reverse (E : NFA_Edge) return NFA_State;
with function Get_First_Edge_Reverse (S : NFA_State) return NFA_Edge;
with function Get_Next_Edge_Reverse (E : NFA_Edge) return NFA_Edge;
procedure Check_Edges_Gen (N : NFA);
procedure Check_Edges_Gen (N : NFA)
is
S : NFA_State;
E : NFA_Edge;
R_S : NFA_State;
R_E : NFA_Edge;
begin
S := Get_First_State (N);
while S /= No_State loop
E := Get_First_Edge (S);
while E /= No_Edge loop
R_S := Get_State_Reverse (E);
R_E := Get_First_Edge_Reverse (R_S);
while R_E /= No_Edge and then R_E /= E loop
R_E := Get_Next_Edge_Reverse (R_E);
end loop;
if R_E /= E then
raise Program_Error;
end if;
E := Get_Next_Edge (E);
end loop;
S := Get_Next_State (S);
end loop;
end Check_Edges_Gen;
procedure Check_Edges_Src is new Check_Edges_Gen
(Get_First_Edge => Get_First_Src_Edge,
Get_Next_Edge => Get_Next_Src_Edge,
Get_State_Reverse => Get_Edge_Dest,
Get_First_Edge_Reverse => Get_First_Dest_Edge,
Get_Next_Edge_Reverse => Get_Next_Dest_Edge);
procedure Check_Edges_Dest is new Check_Edges_Gen
(Get_First_Edge => Get_First_Dest_Edge,
Get_Next_Edge => Get_Next_Dest_Edge,
Get_State_Reverse => Get_Edge_Src,
Get_First_Edge_Reverse => Get_First_Src_Edge,
Get_Next_Edge_Reverse => Get_Next_Src_Edge);
procedure Check_NFA (N : NFA) is
begin
Check_Edges_Src (N);
Check_Edges_Dest (N);
end Check_NFA;
function Has_EOS (N : Node) return Boolean is
begin
case Get_Kind (N) is
when N_EOS =>
return True;
when N_False
| N_True
| N_HDL_Bool =>
return False;
when N_Not_Bool =>
return Has_EOS (Get_Boolean (N));
when N_And_Bool
| N_Or_Bool
| N_Imp_Bool =>
return Has_EOS (Get_Left (N)) or else Has_EOS (Get_Right (N));
when others =>
Error_Kind ("Has_EOS", N);
end case;
end Has_EOS;
procedure Set_Init_Loop (N : NFA)
is
Start : constant NFA_State := Get_Start_State (N);
E : NFA_Edge;
Expr : Node;
begin
-- Look for existing edge.
E := Get_First_Src_Edge (Start);
while E /= No_Edge loop
if Get_Edge_Dest (E) = Start then
Expr := Get_Edge_Expr (E);
if Get_Kind (Expr) = N_True then
return;
end if;
Set_Edge_Expr (E, True_Node);
return;
end if;
E := Get_Next_Src_Edge (E);
end loop;
-- No existing edge. Create one.
Add_Edge (Start, Start, True_Node);
end Set_Init_Loop;
end PSL.NFAs.Utils;
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