1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
17
18
19
20
21
22
23
24
25
26
27
28
29
30
31
32
33
34
35
36
37
38
39
40
41
42
43
44
45
46
47
48
49
50
51
52
53
54
55
56
57
58
59
60
61
62
63
64
65
66
67
68
69
70
71
72
73
74
75
76
77
78
79
80
81
82
83
84
85
86
87
88
89
90
91
92
93
94
95
96
97
98
99
100
101
102
103
104
105
106
107
108
109
110
111
112
113
114
115
116
117
118
119
120
121
122
123
124
125
126
127
128
129
130
131
132
133
134
135
136
137
138
139
140
141
142
143
144
145
146
147
148
149
150
151
152
153
154
155
156
157
158
159
160
161
162
163
164
165
166
167
168
169
170
171
172
173
174
175
176
177
178
179
180
181
182
|
(* Programmed by Jedidiah Barber *)
(* Licensed under the Sunset License v1.0 *)
let usage_msg = "Usage: wallsolve [options]"
let input_seq = ref (Array.make 0 (Z.of_int 0))
let depth_limit = ref 20
let anon_fun item =
prerr_endline "Error: Don't know what to do with anonymous argument";
exit 2
let input_immediate items =
if Array.length !input_seq > 0 then
(prerr_endline "Error: Multiple input sequences specified";
exit 2)
else
try input_seq := Util.read_integer_list items
with Util.Not_an_integer s ->
prerr_endline ("Error: The argument '" ^ s ^ "' is not an integer");
exit 2
let input_from_file filename =
if Array.length !input_seq > 0 then
(prerr_endline "Error: Multiple input sequences specified";
exit 2)
else
try input_seq := Util.read_sequence_file filename
with Util.Not_an_integer s ->
prerr_endline ("Error: The item '" ^ s ^ "' from file '" ^ filename ^ "' is not an integer");
exit 2
let speclist =
[("-f", Arg.String input_from_file, "Read input integer sequence from file");
("-i", Arg.String input_immediate, "Integer input sequence with values separated by commas");
("-l", Arg.Set_int depth_limit, "Sets maximum levels to generate, default 20")]
module My_Algebra =
struct
type t = Poly.t
let zero = Poly.zero
let one = Poly.one
let add = Poly.add
let sub = Poly.sub
let mul = Poly.mul
let div = Poly.div
let to_string = Poly.to_string
end
module My_Wall = Wall.Make (My_Algebra)
let _ =
if Array.length Sys.argv <= 1 then
(Arg.usage speclist usage_msg;
exit 1);
Arg.parse speclist anon_fun usage_msg;
if Array.length !input_seq = 0 then
(prerr_endline "Error: No input sequence provided";
exit 2);
if Array.length !input_seq < 2 then
(prerr_endline "Error: Input sequence not long enough to solve";
exit 2);
(* Convert input integer sequence into the right sort of input polynomial sequence. *)
let poly_offset n =
Poly.of_list [(Z.neg !input_seq.(n), Z.one); (!input_seq.(n+1), Z.zero)] in
let poly_inputs =
Array.init (Array.length !input_seq - 1) poly_offset in
(* Generate the number wall and look at the bottom most non-zero row. *)
let scribbles =
My_Wall.create
~dimx:(Array.length poly_inputs)
~dimy:!depth_limit
~init:poly_inputs in
let row_of_interest =
My_Wall.last_nonzero_row scribbles in
(* Test whether there is actually a row of zeros under the row of interest. *)
if row_of_interest = My_Wall.y_length scribbles - 1 then
(prerr_endline "Error: Depth limit too low to solve sequence";
exit 2);
(* Test whether the row of interest has enough entries to be sure of them all being the same. *)
let exists_pred x =
if My_Wall.has_value scribbles ~x ~y:row_of_interest then 1 else 0 in
let array_sum =
Array.fold_left ( + ) 0 in
let naturals_to n =
Array.init n (fun n -> n) in
if array_sum (Array.map exists_pred (naturals_to (My_Wall.x_length scribbles))) < 3 then
(prerr_endline "Error: Input sequence not long enough to solve";
exit 2);
(* Need to normalize the polynomials in the row as if they were set equal to zero. *)
let rec gcd a b =
Z.(if b = zero then a else gcd b (a mod b)) in
let normalize p =
let sign_correct x =
if Z.(Poly.get_coeff ~expnt:(Poly.degree x) x < zero) then Poly.neg x else x in
let coefficients =
List.map fst (Poly.to_list p) in
let divisor =
List.fold_left gcd Z.zero coefficients in
sign_correct (Poly.div p (Poly.of_zint divisor)) in
(* Now let's look at the polynomial right in the middle. *)
let key_poly =
normalize (My_Wall.get scribbles
~x:((Array.length poly_inputs) / 2 + 1)
~y:row_of_interest) in
(* Check for degeneracy. *)
if Poly.degree key_poly = Z.zero then
(prerr_endline "Error: Result is degree zero, not sure how that happened";
exit 2);
(* Check that all the polynomials in the row of interest are equal once normalized. *)
let equals_pred x =
let value = My_Wall.get_opt scribbles ~x ~y:row_of_interest in
if Option.is_some value then
normalize (Option.get value) = key_poly
else
true in
if not (Array.for_all equals_pred (naturals_to (My_Wall.x_length scribbles))) then
(prerr_endline "Error: Polynomials differ, maybe try a longer sequence?";
exit 2);
(* Print out the polynomial as if it was a recurrence relation with the highest degree term *)
(* being on the left hand side and the remaining terms being on the right hand side. *)
let print_relation p =
let lhs = List.hd p in
let rhs = List.map (fun (x,y) -> (Z.neg x, y)) (List.tl p) in
if fst lhs <> Z.one then print_string (Z.to_string (fst lhs)); print_string "S(n) =";
let print_rhs_item minus plus (c,e) =
print_string " ";
if c < Z.zero then print_string minus else print_string plus;
if (Z.abs c) <> Z.one then print_string (Z.to_string (Z.abs c));
print_string ("S(n-" ^ Z.to_string Z.(snd lhs - e) ^ ")") in
print_rhs_item "-" "" (List.hd rhs);
List.iter (print_rhs_item "- " "+ ") (List.tl rhs) in
print_relation (Poly.to_list key_poly);
print_newline ();
(* This... should probably never trigger, but might as well check anyway. *)
if Poly.degree key_poly > Z.of_int (Array.length !input_seq) then
(prerr_endline "Error: Recurrence relation longer than input sequence... wtfhow?";
exit 2);
(* Calculate and print the predicted next number of the input sequence. *)
let calc_next p inp =
let lhs = List.hd p in
let rhs = List.map (fun (x,y) -> (Z.neg x, y)) (List.tl p) in
let rec process result terms =
if terms = [] then
result
else
let current = List.hd terms in
let index = Array.length inp - Z.(to_int (snd lhs - snd current)) in
process Z.(result + fst current * inp.(index)) (List.tl terms) in
Z.div (process Z.zero rhs) (fst lhs) in
print_string ("Next: " ^ Z.to_string (calc_next (Poly.to_list key_poly) !input_seq));
print_newline ()
|