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(************************************************************************)
(* v * The Coq Proof Assistant / The Coq Development Team *)
(* <O___,, * CNRS-Ecole Polytechnique-INRIA Futurs-Universite Paris Sud *)
(* \VV/ **************************************************************)
(* // * This file is distributed under the terms of the *)
(* * GNU Lesser General Public License Version 2.1 *)
(************************************************************************)
(* $Id$ *)
(*i*)
open Pp
(*i*)
(***************************************************)
(* Basic operations on (unbounded) integer numbers *)
(***************************************************)
(* An integer is canonically represented as an array of k-digits blocs.
0 is represented by the empty array and -1 by the singleton [|-1|].
The first bloc is in the range ]0;10^k[ for positive numbers.
The first bloc is in the range ]-10^k;-1[ for negative ones.
All other blocs are numbers in the range [0;10^k[.
Negative numbers are represented using 2's complementation. For instance,
with 4-digits blocs, [-9655;6789] denotes -96543211
*)
(* The base is a power of 10 in order to facilitate the parsing and printing
of numbers in digital notation.
All functions, to the exception of to_string and of_string should work
with an arbitrary base, even if not a power of 10.
In practice, we set k=4 so that no overflow in ocaml machine words
(i.e. the interval [-2^30;2^30-1]) occur when multiplying two
numbers less than (10^k)
*)
(* The main parameters *)
let size =
let rec log10 n = if n < 10 then 0 else 1 + log10 (n / 10) in
(log10 max_int) / 2
let format_size =
(* How to parametrize a printf format *)
if size = 4 then Printf.sprintf "%04d"
else fun n ->
let rec aux j l n =
if j=size then l else aux (j+1) (string_of_int (n mod 10) :: l) (n/10)
in String.concat "" (aux 0 [] n)
(* The base is 10^size *)
let base =
let rec exp10 = function 0 -> 1 | n -> 10 * exp10 (n-1) in exp10 size
(* Basic numbers *)
let zero = [||]
let neg_one = [|-1|]
(* Sign of an integer *)
let is_strictly_neg n = n<>[||] && n.(0) < 0
let is_strictly_pos n = n<>[||] && n.(0) > 0
let is_neg_or_zero n = n=[||] or n.(0) < 0
let is_pos_or_zero n = n=[||] or n.(0) > 0
let normalize_pos n =
let k = ref 0 in
while !k < Array.length n & n.(!k) = 0 do incr k done;
Array.sub n !k (Array.length n - !k)
let normalize_neg n =
let k = ref 1 in
while !k < Array.length n & n.(!k) = base - 1 do incr k done;
let n' = Array.sub n !k (Array.length n - !k) in
if Array.length n' = 0 then [|-1|] else (n'.(0) <- n'.(0) - base; n')
let rec normalize n =
if Array.length n = 0 then n else
if n.(0) = -1 then normalize_neg n else normalize_pos n
let neg m =
if m = zero then zero else
let n = Array.copy m in
let i = ref (Array.length m - 1) in
while !i > 0 & n.(!i) = 0 do decr i done;
if !i > 0 then begin
n.(!i) <- base - n.(!i); decr i;
while !i > 0 do n.(!i) <- base - 1 - n.(!i); decr i done;
n.(0) <- - n.(0) - 1;
if n.(0) < -1 then (n.(0) <- n.(0) + base; Array.append [| -1 |] n) else
if n.(0) = - base then (n.(0) <- 0; Array.append [| -1 |] n)
else normalize n
end else (n.(0) <- - n.(0); n)
let push_carry r j =
let j = ref j in
while !j > 0 & r.(!j) < 0 do
r.(!j) <- r.(!j) + base; decr j; r.(!j) <- r.(!j) - 1
done;
while !j > 0 & r.(!j) >= base do
r.(!j) <- r.(!j) - base; decr j; r.(!j) <- r.(!j) + 1
done;
if r.(0) >= base then (r.(0) <- r.(0) - base; Array.append [| 1 |] r)
else if r.(0) < -base then (r.(0) <- r.(0) + 2*base; Array.append [| -2 |] r)
else if r.(0) = -base then (r.(0) <- 0; Array.append [| -1 |] r)
else normalize r
let add_to r a j =
if a = zero then r else begin
for i = Array.length r - 1 downto j+1 do
r.(i) <- r.(i) + a.(i-j);
if r.(i) >= base then (r.(i) <- r.(i) - base; r.(i-1) <- r.(i-1) + 1)
done;
r.(j) <- r.(j) + a.(0);
push_carry r j
end
let add n m =
let d = Array.length n - Array.length m in
if d > 0 then add_to (Array.copy n) m d else add_to (Array.copy m) n (-d)
let sub_to r a j =
if a = zero then r else begin
for i = Array.length r - 1 downto j+1 do
r.(i) <- r.(i) - a.(i-j);
if r.(i) < 0 then (r.(i) <- r.(i) + base; r.(i-1) <- r.(i-1) - 1)
done;
r.(j) <- r.(j) - a.(0);
push_carry r j
end
let sub n m =
let d = Array.length n - Array.length m in
if d >= 0 then sub_to (Array.copy n) m d
else let r = neg m in add_to r n (Array.length r - Array.length n)
let rec mult m n =
if m = zero or n = zero then zero else
let l = Array.length m + Array.length n in
let r = Array.create l 0 in
for i = Array.length m - 1 downto 0 do
for j = Array.length n - 1 downto 0 do
let p = m.(i) * n.(j) + r.(i+j+1) in
let (q,s) =
if p < 0
then (p + 1) / base - 1, (p + 1) mod base + base - 1
else p / base, p mod base in
r.(i+j+1) <- s;
if q <> 0 then r.(i+j) <- r.(i+j) + q;
done
done;
normalize r
let rec less_than_same_size m n i j =
i < Array.length m &&
(m.(i) < n.(j) or (m.(i) = n.(j) && less_than_same_size m n (i+1) (j+1)))
let less_than m n =
if is_strictly_neg m then
is_pos_or_zero n or Array.length m > Array.length n
or (Array.length m = Array.length n && less_than_same_size m n 0 0)
else
is_strictly_pos n && (Array.length m < Array.length n or
(Array.length m = Array.length n && less_than_same_size m n 0 0))
let equal m n = (m = n)
let less_than_shift_pos k m n =
(Array.length m - k < Array.length n)
or (Array.length m - k = Array.length n && less_than_same_size m n k 0)
let rec can_divide k m d i =
(i = Array.length d) or
(m.(k+i) > d.(i)) or
(m.(k+i) = d.(i) && can_divide k m d (i+1))
(* computes m - d * q * base^(|m|-k) in-place on positive numbers *)
let sub_mult m d q k =
if q <> 0 then
for i = Array.length d - 1 downto 0 do
let v = d.(i) * q in
m.(k+i) <- m.(k+i) - v mod base;
if m.(k+i) < 0 then (m.(k+i) <- m.(k+i) + base; m.(k+i-1) <- m.(k+i-1) -1);
if v >= base then m.(k+i-1) <- m.(k+i-1) - v / base;
done
let euclid m d =
let isnegm, m =
if is_strictly_neg m then (-1),neg m else 1,Array.copy m in
let isnegd, d = if is_strictly_neg d then (-1),neg d else 1,d in
if d = zero then raise Division_by_zero;
let q,r =
if less_than m d then (zero,m) else
let ql = Array.length m - Array.length d in
let q = Array.create (ql+1) 0 in
let i = ref 0 in
while not (less_than_shift_pos !i m d) do
if m.(!i)=0 then incr i else
if can_divide !i m d 0 then begin
let v =
if Array.length d > 1 && d.(0) <> m.(!i) then
(m.(!i) * base + m.(!i+1)) / (d.(0) * base + d.(1) + 1)
else
m.(!i) / d.(0) in
q.(!i) <- q.(!i) + v;
sub_mult m d v !i
end else begin
let v = (m.(!i) * base + m.(!i+1)) / (d.(0) + 1) in
q.(!i) <- q.(!i) + v / base;
sub_mult m d (v / base) !i;
q.(!i+1) <- q.(!i+1) + v mod base;
if q.(!i+1) >= base then
(q.(!i+1) <- q.(!i+1)-base; q.(!i) <- q.(!i)+1);
sub_mult m d (v mod base) (!i+1)
end
done;
(normalize q, normalize m) in
(if isnegd * isnegm = -1 then neg q else q),
(if isnegm = -1 then neg r else r)
(* Parsing/printing ordinary 10-based numbers *)
let of_string s =
let isneg = String.length s > 1 & s.[0] = '-' in
let n = if isneg then 1 else 0 in
let d = ref n in
while !d < String.length s && s.[!d] = '0' do incr d done;
if !d = String.length s then zero else
let r = (String.length s - !d) mod size in
let h = String.sub s (!d) r in
if !d = String.length s - 1 && isneg && h="1" then neg_one else
let e = if h<>"" then 1 else 0 in
let l = (String.length s - !d) / size in
let a = Array.create (l + e + n) 0 in
if isneg then begin
a.(0) <- (-1);
let carry = ref 0 in
for i=l downto 1 do
let v = int_of_string (String.sub s ((i-1)*size + !d +r) size)+ !carry in
if v <> 0 then (a.(i+e)<- base - v; carry := 1) else carry := 0
done;
if e=1 then a.(1) <- base - !carry - int_of_string h;
end
else begin
if e=1 then a.(0) <- int_of_string h;
for i=1 to l do
a.(i+e-1) <- int_of_string (String.sub s ((i-1)*size + !d + r) size)
done
end;
a
let to_string_pos sgn n =
if Array.length n = 0 then "0" else
sgn ^
String.concat ""
(string_of_int n.(0) :: List.map format_size (List.tl (Array.to_list n)))
let to_string n =
if is_strictly_neg n then to_string_pos "-" (neg n)
else to_string_pos "" n
(******************************************************************)
(* Optimized operations on (unbounded) integer numbers *)
(* integers smaller than base are represented as machine integers *)
(******************************************************************)
type bigint = Obj.t
let ints_of_int n =
if n >= base then [| n / base; n mod base |]
else if n <= - base then [| n / base - 1; n mod base + base |]
else if n = 0 then [| |] else [| n |]
let big_of_int n =
if n >= base then Obj.repr [| n / base; n mod base |]
else if n <= - base then Obj.repr [| n / base - 1; n mod base + base |]
else Obj.repr n
let big_of_ints n =
let n = normalize n in
if n = zero then Obj.repr 0 else
if Array.length n = 1 then Obj.repr n.(0) else
Obj.repr n
let coerce_to_int = (Obj.magic : Obj.t -> int)
let coerce_to_ints = (Obj.magic : Obj.t -> int array)
let ints_of_z n =
if Obj.is_int n then ints_of_int (coerce_to_int n)
else coerce_to_ints n
let app_pair f (m, n) =
(f m, f n)
let add m n =
if Obj.is_int m & Obj.is_int n
then big_of_int (coerce_to_int m + coerce_to_int n)
else big_of_ints (add (ints_of_z m) (ints_of_z n))
let sub m n =
if Obj.is_int m & Obj.is_int n
then big_of_int (coerce_to_int m - coerce_to_int n)
else big_of_ints (sub (ints_of_z m) (ints_of_z n))
let mult m n =
if Obj.is_int m & Obj.is_int n
then big_of_int (coerce_to_int m * coerce_to_int n)
else big_of_ints (mult (ints_of_z m) (ints_of_z n))
let euclid m n =
if Obj.is_int m & Obj.is_int n
then app_pair big_of_int
(coerce_to_int m / coerce_to_int n, coerce_to_int m mod coerce_to_int n)
else app_pair big_of_ints (euclid (ints_of_z m) (ints_of_z n))
let less_than m n =
if Obj.is_int m & Obj.is_int n
then coerce_to_int m < coerce_to_int n
else less_than (ints_of_z m) (ints_of_z n)
let neg n =
if Obj.is_int n then big_of_int (- (coerce_to_int n))
else big_of_ints (neg (ints_of_z n))
let of_string m = big_of_ints (of_string m)
let to_string m = to_string (ints_of_z m)
let zero = big_of_int 0
let one = big_of_int 1
let sub_1 n = sub n one
let add_1 n = add n one
let two = big_of_int 2
let mult_2 n = add n n
let div2_with_rest n =
let (q,b) = euclid n two in
(q, b = one)
let is_strictly_neg n = is_strictly_neg (ints_of_z n)
let is_strictly_pos n = is_strictly_pos (ints_of_z n)
let is_neg_or_zero n = is_neg_or_zero (ints_of_z n)
let is_pos_or_zero n = is_pos_or_zero (ints_of_z n)
let pr_bigint n = str (to_string n)
(* spiwack: computes n^m *)
(* The basic idea of the algorithm is that n^(2m) = (n^2)^m *)
(* In practice the algorithm performs :
k*n^0 = k
k*n^(2m) = k*(n*n)^m
k*n^(2m+1) = (n*k)*(n*n)^m *)
let pow =
let rec pow_aux odd_rest n m = (* odd_rest is the k from above *)
if is_neg_or_zero m then
odd_rest
else
let (quo,rem) = div2_with_rest m in
pow_aux
((* [if m mod 2 = 1]*)
if rem then
mult n odd_rest
else
odd_rest )
(* quo = [m/2] *)
(mult n n) quo
in
pow_aux one
(* Testing suite *)
let check () =
let numbers = [
"1";"2";"99";"100";"101";"9999";"10000";"10001";
"999999";"1000000";"1000001";"99999999";"100000000";"100000001";
"1234";"5678";"12345678";"987654321";
"-1";"-2";"-99";"-100";"-101";"-9999";"-10000";"-10001";
"-999999";"-1000000";"-1000001";"-99999999";"-100000000";"-100000001";
"-1234";"-5678";"-12345678";"-987654321";"0"
]
in
let eucl n m =
let n' = abs_float n and m' = abs_float m in
let q' = floor (n' /. m') in let r' = n' -. m' *. q' in
(if n *. m < 0. & q' <> 0. then -. q' else q'),
(if n < 0. then -. r' else r') in
let round f = floor (abs_float f +. 0.5) *. (if f < 0. then -1. else 1.) in
let i = ref 0 in
let compare op n n' =
incr i;
let s = Printf.sprintf "%30s" (to_string n) in
let s' = Printf.sprintf "% 30.0f" (round n') in
if s <> s' then Printf.printf "%s: %s <> %s\n" op s s' in
List.iter (fun a -> List.iter (fun b ->
let n = of_string a and m = of_string b in
let n' = float_of_string a and m' = float_of_string b in
let a = add n m and a' = n' +. m' in
let s = sub n m and s' = n' -. m' in
let p = mult n m and p' = n' *. m' in
let q,r = try euclid n m with Division_by_zero -> zero,zero
and q',r' = eucl n' m' in
compare "+" a a';
compare "-" s s';
compare "*" p p';
compare "/" q q';
compare "%" r r') numbers) numbers;
Printf.printf "%i tests done\n" !i
|