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|
(************************************************************************)
(* v * The Coq Proof Assistant / The Coq Development Team *)
(* <O___,, * INRIA - CNRS - LIX - LRI - PPS - Copyright 1999-2016 *)
(* \VV/ **************************************************************)
(* // * This file is distributed under the terms of the *)
(* * GNU Lesser General Public License Version 2.1 *)
(************************************************************************)
(* Recursive polynomials: R[x1]...[xn]. *)
open Util
open Utile
(* 1. Coefficients: R *)
module type Coef = sig
type t
val equal : t -> t -> bool
val lt : t -> t -> bool
val le : t -> t -> bool
val abs : t -> t
val plus : t -> t -> t
val mult : t -> t -> t
val sub : t -> t -> t
val opp : t -> t
val div : t -> t -> t
val modulo : t -> t -> t
val puis : t -> int -> t
val pgcd : t -> t -> t
val hash : t -> int
val of_num : Num.num -> t
val to_string : t -> string
end
module type S = sig
type coef
type variable = int
type t = Pint of coef | Prec of variable * t array
val of_num : Num.num -> t
val x : variable -> t
val monome : variable -> int -> t
val is_constantP : t -> bool
val is_zero : t -> bool
val max_var_pol : t -> variable
val max_var_pol2 : t -> variable
val max_var : t array -> variable
val equal : t -> t -> bool
val norm : t -> t
val deg : variable -> t -> int
val deg_total : t -> int
val copyP : t -> t
val coef : variable -> int -> t -> t
val plusP : t -> t -> t
val content : t -> coef
val div_int : t -> coef -> t
val vire_contenu : t -> t
val vars : t -> variable list
val int_of_Pint : t -> coef
val multx : int -> variable -> t -> t
val multP : t -> t -> t
val deriv : variable -> t -> t
val oppP : t -> t
val moinsP : t -> t -> t
val puisP : t -> int -> t
val ( @@ ) : t -> t -> t
val ( -- ) : t -> t -> t
val ( ^^ ) : t -> int -> t
val coefDom : variable -> t -> t
val coefConst : variable -> t -> t
val remP : variable -> t -> t
val coef_int_tete : t -> coef
val normc : t -> t
val coef_constant : t -> coef
val univ : bool ref
val string_of_var : int -> string
val nsP : int ref
val to_string : t -> string
val printP : t -> unit
val print_tpoly : t array -> unit
val print_lpoly : t list -> unit
val quo_rem_pol : t -> t -> variable -> t * t
val div_pol : t -> t -> variable -> t
val divP : t -> t -> t
val div_pol_rat : t -> t -> bool
val pseudo_div : t -> t -> variable -> t * t * int * t
val pgcdP : t -> t -> t
val pgcd_pol : t -> t -> variable -> t
val content_pol : t -> variable -> t
val pgcd_coef_pol : t -> t -> variable -> t
val pgcd_pol_rec : t -> t -> variable -> t
val gcd_sub_res : t -> t -> variable -> t
val gcd_sub_res_rec : t -> t -> t -> t -> int -> variable -> t
val lazard_power : t -> t -> int -> variable -> t
val hash : t -> int
module Hashpol : Hashtbl.S with type key=t
end
(***********************************************************************
2. Type of polynomials, operations.
*)
module Make (C:Coef) = struct
type coef = C.t
let coef_of_int i = C.of_num (Num.Int i)
let coef0 = coef_of_int 0
let coef1 = coef_of_int 1
type variable = int
type t =
Pint of coef (* constant polynomial *)
| Prec of variable * (t array) (* coefficients, increasing degree *)
(* by default, operations work with normalized polynomials:
- variables are positive integers
- coefficients of a polynomial in x only use variables < x
- no zero coefficient at beginning
- no Prec(x,a) where a is constant in x
*)
(* constant polynomials *)
let of_num x = Pint (C.of_num x)
let cf0 = of_num (Num.Int 0)
let cf1 = of_num (Num.Int 1)
(* nth variable *)
let x n = Prec (n,[|cf0;cf1|])
(* create v^n *)
let monome v n =
match n with
0->Pint coef1;
|_->let tmp = Array.make (n+1) (Pint coef0) in
tmp.(n)<-(Pint coef1);
Prec (v, tmp)
let is_constantP = function
Pint _ -> true
| Prec _ -> false
let int_of_Pint = function
Pint x -> x
| _ -> failwith "non"
let is_zero p =
match p with Pint n -> if C.equal n coef0 then true else false |_-> false
let max_var_pol p =
match p with
Pint _ -> 0
|Prec(x,_) -> x
(* p not normalized *)
let rec max_var_pol2 p =
match p with
Pint _ -> 0
|Prec(v,c)-> Array.fold_right (fun q m -> max (max_var_pol2 q) m) c v
let max_var l = Array.fold_right (fun p m -> max (max_var_pol2 p) m) l 0
(* equality between polynomials *)
let rec equal p q =
match (p,q) with
(Pint a,Pint b) -> C.equal a b
|(Prec(x,p1),Prec(y,q1)) -> (Int.equal x y) && Array.for_all2 equal p1 q1
| (_,_) -> false
(* normalize polynomial: remove head zeros, coefficients are normalized
if constant, returns the coefficient
*)
let norm p = match p with
Pint _ -> p
|Prec (x,a)->
let d = (Array.length a -1) in
let n = ref d in
while !n>0 && (equal a.(!n) (Pint coef0)) do
n:=!n-1;
done;
if !n<0 then Pint coef0
else if Int.equal !n 0 then a.(0)
else if Int.equal !n d then p
else (let b=Array.make (!n+1) (Pint coef0) in
for i=0 to !n do b.(i)<-a.(i);done;
Prec(x,b))
(* degree in v, v >= max var of p *)
let deg v p =
match p with
Prec(x,p1) when Int.equal x v -> Array.length p1 -1
|_ -> 0
(* total degree *)
let rec deg_total p =
match p with
Prec (x,p1) -> let d = ref 0 in
Array.iteri (fun i q -> d:= (max !d (i+(deg_total q)))) p1;
!d
|_ -> 0
let rec copyP p =
match p with
Pint i -> Pint i
|Prec(x,q) -> Prec(x,Array.map copyP q)
(* coefficient of degree i in v, v >= max var of p *)
let coef v i p =
match p with
Prec (x,p1) when Int.equal x v -> if i<(Array.length p1) then p1.(i) else Pint coef0
|_ -> if Int.equal i 0 then p else Pint coef0
(* addition *)
let rec plusP p q =
let res =
(match (p,q) with
(Pint a,Pint b) -> Pint (C.plus a b)
|(Pint a, Prec (y,q1)) -> let q2=Array.map copyP q1 in
q2.(0)<- plusP p q1.(0);
Prec (y,q2)
|(Prec (x,p1),Pint b) -> let p2=Array.map copyP p1 in
p2.(0)<- plusP p1.(0) q;
Prec (x,p2)
|(Prec (x,p1),Prec (y,q1)) ->
if x<y then (let q2=Array.map copyP q1 in
q2.(0)<- plusP p q1.(0);
Prec (y,q2))
else if x>y then (let p2=Array.map copyP p1 in
p2.(0)<- plusP p1.(0) q;
Prec (x,p2))
else
(let n=max (deg x p) (deg x q) in
let r=Array.make (n+1) (Pint coef0) in
for i=0 to n do
r.(i)<- plusP (coef x i p) (coef x i q);
done;
Prec(x,r)))
in norm res
(* content, positive integer *)
let rec content p =
match p with
Pint a -> C.abs a
| Prec (x ,p1) ->
Array.fold_left C.pgcd coef0 (Array.map content p1)
let rec div_int p a=
match p with
Pint b -> Pint (C.div b a)
| Prec(x,p1) -> Prec(x,Array.map (fun x -> div_int x a) p1)
let vire_contenu p =
let c = content p in
if C.equal c coef0 then p else div_int p c
(* sorted list of variables of a polynomial *)
let rec vars=function
Pint _->[]
| Prec (x,l)->(List.flatten ([x]::(List.map vars (Array.to_list l))))
(* multiply p by v^n, v >= max_var p *)
let multx n v p =
match p with
Prec (x,p1) when Int.equal x v -> let p2= Array.make ((Array.length p1)+n) (Pint coef0) in
for i=0 to (Array.length p1)-1 do
p2.(i+n)<-p1.(i);
done;
Prec (x,p2)
|_ -> if equal p (Pint coef0) then (Pint coef0)
else (let p2=Array.make (n+1) (Pint coef0) in
p2.(n)<-p;
Prec (v,p2))
(* product *)
let rec multP p q =
match (p,q) with
(Pint a,Pint b) -> Pint (C.mult a b)
|(Pint a, Prec (y,q1)) ->
if C.equal a coef0 then Pint coef0
else let q2 = Array.map (fun z-> multP p z) q1 in
Prec (y,q2)
|(Prec (x,p1), Pint b) ->
if C.equal b coef0 then Pint coef0
else let p2 = Array.map (fun z-> multP z q) p1 in
Prec (x,p2)
|(Prec (x,p1), Prec(y,q1)) ->
if x<y
then (let q2 = Array.map (fun z-> multP p z) q1 in
Prec (y,q2))
else if x>y
then (let p2 = Array.map (fun z-> multP z q) p1 in
Prec (x,p2))
else Array.fold_left plusP (Pint coef0)
(Array.mapi (fun i z-> (multx i x (multP z q))) p1)
(* derive p with variable v, v >= max_var p *)
let deriv v p =
match p with
Pint a -> Pint coef0
| Prec(x,p1) when Int.equal x v ->
let d = Array.length p1 -1 in
if Int.equal d 1 then p1.(1)
else
(let p2 = Array.make d (Pint coef0) in
for i=0 to d-1 do
p2.(i)<- multP (Pint (coef_of_int (i+1))) p1.(i+1);
done;
Prec (x,p2))
| Prec(x,p1)-> Pint coef0
(* opposite *)
let rec oppP p =
match p with
Pint a -> Pint (C.opp a)
|Prec(x,p1) -> Prec(x,Array.map oppP p1)
let moinsP p q=plusP p (oppP q)
let rec puisP p n = match n with
0 -> cf1
|_ -> (multP p (puisP p (n-1)))
(* infix notations *)
(*let (++) a b = plusP a b
*)
let (@@) a b = multP a b
let (--) a b = moinsP a b
let (^^) a b = puisP a b
(* leading coefficient in v, v>= max_var p *)
let coefDom v p= coef v (deg v p) p
let coefConst v p = coef v 0 p
(* tail of a polynomial *)
let remP v p =
moinsP p (multP (coefDom v p) (puisP (x v) (deg v p)))
(* first interger coefficient of p *)
let rec coef_int_tete p =
let v = max_var_pol p in
if v>0
then coef_int_tete (coefDom v p)
else (match p with | Pint a -> a |_ -> assert false)
(* divide by the content and make the head int coef positive *)
let normc p =
let p = vire_contenu p in
let a = coef_int_tete p in
if C.le coef0 a then p else oppP p
(* constant coef of normalized polynomial *)
let rec coef_constant p =
match p with
Pint a->a
|Prec(_,q)->coef_constant q.(0)
(***********************************************************************
3. Printing polynomials.
*)
(* if univ = false, we use x,y,z,a,b,c,d... as variables, else x1,x2,...
*)
let univ=ref true
let string_of_var x=
if !univ then
"u"^(string_of_int x)
else
if x<=3 then String.make 1 (Char.chr(x+(Char.code 'w')))
else String.make 1 (Char.chr(x-4+(Char.code 'a')))
let nsP = ref 0
let rec string_of_Pcut p =
if (!nsP)<=0
then "..."
else
match p with
|Pint a-> nsP:=(!nsP)-1;
if C.le coef0 a
then C.to_string a
else "("^(C.to_string a)^")"
|Prec (x,t)->
let v=string_of_var x
and s=ref ""
and sp=ref "" in
let st0 = string_of_Pcut t.(0) in
if not (String.equal st0 "0")
then s:=st0;
let fin = ref false in
for i=(Array.length t)-1 downto 1 do
if (!nsP)<0
then (sp:="...";
if not (!fin) then s:=(!s)^"+"^(!sp);
fin:=true)
else (
let si=string_of_Pcut t.(i) in
sp:="";
if Int.equal i 1
then (
if not (String.equal si "0")
then (nsP:=(!nsP)-1;
if String.equal si "1"
then sp:=v
else
(if (String.contains si '+')
then sp:="("^si^")*"^v
else sp:=si^"*"^v)))
else (
if not (String.equal si "0")
then (nsP:=(!nsP)-1;
if String.equal si "1"
then sp:=v^"^"^(string_of_int i)
else (if (String.contains si '+')
then sp:="("^si^")*"^v^"^"^(string_of_int i)
else sp:=si^"*"^v^"^"^(string_of_int i))));
if not (String.is_empty !sp) && not (!fin)
then (nsP:=(!nsP)-1;
if String.is_empty !s
then s:=!sp
else s:=(!s)^"+"^(!sp)));
done;
if String.is_empty !s then (nsP:=(!nsP)-1;
(s:="0"));
!s
let to_string p =
nsP:=20;
string_of_Pcut p
let printP p = Format.printf "@[%s@]" (to_string p)
let print_tpoly lp =
let s = ref "\n{ " in
Array.iter (fun p -> s:=(!s)^(to_string p)^"\n") lp;
prt0 ((!s)^"}")
let print_lpoly lp = print_tpoly (Array.of_list lp)
(***********************************************************************
4. Exact division of polynomials.
*)
(* return (s,r) s.t. p = s*q+r *)
let rec quo_rem_pol p q x =
if Int.equal x 0
then (match (p,q) with
|(Pint a, Pint b) ->
if C.equal (C.modulo a b) coef0
then (Pint (C.div a b), cf0)
else failwith "div_pol1"
|_ -> assert false)
else
let m = deg x q in
let b = coefDom x q in
let q1 = remP x q in (* q = b*x^m+q1 *)
let r = ref p in
let s = ref cf0 in
let continue =ref true in
while (!continue) && (not (equal !r cf0)) do
let n = deg x !r in
if n<m
then continue:=false
else (
let a = coefDom x !r in
let p1 = remP x !r in (* r = a*x^n+p1 *)
let c = div_pol a b (x-1) in (* a = c*b *)
let s1 = c @@ ((monome x (n-m))) in
s:= plusP (!s) s1;
r:= p1 -- (s1 @@ q1);
)
done;
(!s,!r)
(* returns quotient p/q if q divides p, else fails *)
and div_pol p q x =
let (s,r) = quo_rem_pol p q x in
if equal r cf0
then s
else failwith ("div_pol:\n"
^"p:"^(to_string p)^"\n"
^"q:"^(to_string q)^"\n"
^"r:"^(to_string r)^"\n"
^"x:"^(string_of_int x)^"\n"
)
let divP p q=
let x = max (max_var_pol p) (max_var_pol q) in
div_pol p q x
let div_pol_rat p q=
let x = max (max_var_pol p) (max_var_pol q) in
try
let r = puisP (Pint(coef_int_tete q)) (1+(deg x p)-(deg x q)) in
let _ = div_pol (multP p r) q x in
true
with Failure _ -> false
(***********************************************************************
5. Pseudo-division and gcd with subresultants.
*)
(* pseudo division :
q = c*x^m+q1
retruns (r,c,d,s) s.t. c^d*p = s*q + r.
*)
let pseudo_div p q x =
match q with
Pint _ -> (cf0, q,1, p)
| Prec (v,q1) when not (Int.equal x v) -> (cf0, q,1, p)
| Prec (v,q1) ->
(
(* pr "pseudo_division: c^d*p = s*q + r";*)
let delta = ref 0 in
let r = ref p in
let c = coefDom x q in
let q1 = remP x q in
let d' = deg x q in
let s = ref cf0 in
while (deg x !r)>=(deg x q) do
let d = deg x !r in
let a = coefDom x !r in
let r1=remP x !r in
let u = a @@ ((monome x (d-d'))) in
r:=(c @@ r1) -- (u @@ q1);
s:=plusP (c @@ (!s)) u;
delta := (!delta) + 1;
done;
(*
pr ("deg d: "^(string_of_int (!delta))^", deg c: "^(string_of_int (deg_total c)));
pr ("deg r:"^(string_of_int (deg_total !r)));
*)
(!r,c,!delta, !s)
)
(* gcd with subresultants *)
let rec pgcdP p q =
let x = max (max_var_pol p) (max_var_pol q) in
pgcd_pol p q x
and pgcd_pol p q x =
pgcd_pol_rec p q x
and content_pol p x =
match p with
Prec(v,p1) when Int.equal v x ->
Array.fold_left (fun a b -> pgcd_pol_rec a b (x-1)) cf0 p1
| _ -> p
and pgcd_coef_pol c p x =
match p with
Prec(v,p1) when Int.equal x v ->
Array.fold_left (fun a b -> pgcd_pol_rec a b (x-1)) c p1
|_ -> pgcd_pol_rec c p (x-1)
and pgcd_pol_rec p q x =
match (p,q) with
(Pint a,Pint b) -> Pint (C.pgcd (C.abs a) (C.abs b))
|_ ->
if equal p cf0
then q
else if equal q cf0
then p
else if Int.equal (deg x q) 0
then pgcd_coef_pol q p x
else if Int.equal (deg x p) 0
then pgcd_coef_pol p q x
else (
let a = content_pol p x in
let b = content_pol q x in
let c = pgcd_pol_rec a b (x-1) in
pr (string_of_int x);
let p1 = div_pol p c x in
let q1 = div_pol q c x in
let r = gcd_sub_res p1 q1 x in
let cr = content_pol r x in
let res = c @@ (div_pol r cr x) in
res
)
(* Sub-résultants:
ai*Ai = Qi*Ai+1 + bi*Ai+2
deg Ai+2 < deg Ai+1
Ai = ci*X^ni + ...
di = ni - ni+1
ai = (- ci+1)^(di + 1)
b1 = 1
bi = ci*si^di si i>1
s1 = 1
si+1 = ((ci+1)^di*si)/si^di
*)
and gcd_sub_res p q x =
if equal q cf0
then p
else
let d = deg x p in
let d' = deg x q in
if d<d'
then gcd_sub_res q p x
else
let delta = d-d' in
let c' = coefDom x q in
let r = snd (quo_rem_pol (((oppP c')^^(delta+1))@@p) (oppP q) x) in
gcd_sub_res_rec q r (c'^^delta) c' d' x
and gcd_sub_res_rec p q s c d x =
if equal q cf0
then p
else (
let d' = deg x q in
let c' = coefDom x q in
let delta = d-d' in
let r = snd (quo_rem_pol (((oppP c')^^(delta+1))@@p) (oppP q) x) in
let s'= lazard_power c' s delta x in
gcd_sub_res_rec q (div_pol r (c @@ (s^^delta)) x) s' c' d' x
)
and lazard_power c s d x =
let res = ref c in
for _i = 1 to d - 1 do
res:= div_pol ((!res)@@c) s x;
done;
!res
(* memoizations *)
let rec hash = function
Pint a -> (C.hash a)
| Prec (v,p) ->
Array.fold_right (fun q h -> h + hash q) p 0
module Hashpol = Hashtbl.Make(
struct
type poly = t
type t = poly
let equal = equal
let hash = hash
end)
end
|