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|
(** val negb : bool -> bool **)
let negb = function
| true -> false
| false -> true
type nat =
| O
| S of nat
(** val app : 'a1 list -> 'a1 list -> 'a1 list **)
let rec app l m =
match l with
| [] -> m
| a::l1 -> a::(app l1 m)
type comparison =
| Eq
| Lt
| Gt
(** val compOpp : comparison -> comparison **)
let compOpp = function
| Eq -> Eq
| Lt -> Gt
| Gt -> Lt
module Coq__1 = struct
(** val add : nat -> nat -> nat **)
let rec add n0 m =
match n0 with
| O -> m
| S p -> S (add p m)
end
include Coq__1
type positive =
| XI of positive
| XO of positive
| XH
type n =
| N0
| Npos of positive
type z =
| Z0
| Zpos of positive
| Zneg of positive
module Pos =
struct
type mask =
| IsNul
| IsPos of positive
| IsNeg
end
module Coq_Pos =
struct
(** val succ : positive -> positive **)
let rec succ = function
| XI p -> XO (succ p)
| XO p -> XI p
| XH -> XO XH
(** val add : positive -> positive -> positive **)
let rec add x y =
match x with
| XI p ->
(match y with
| XI q0 -> XO (add_carry p q0)
| XO q0 -> XI (add p q0)
| XH -> XO (succ p))
| XO p ->
(match y with
| XI q0 -> XI (add p q0)
| XO q0 -> XO (add p q0)
| XH -> XI p)
| XH -> (match y with
| XI q0 -> XO (succ q0)
| XO q0 -> XI q0
| XH -> XO XH)
(** val add_carry : positive -> positive -> positive **)
and add_carry x y =
match x with
| XI p ->
(match y with
| XI q0 -> XI (add_carry p q0)
| XO q0 -> XO (add_carry p q0)
| XH -> XI (succ p))
| XO p ->
(match y with
| XI q0 -> XO (add_carry p q0)
| XO q0 -> XI (add p q0)
| XH -> XO (succ p))
| XH ->
(match y with
| XI q0 -> XI (succ q0)
| XO q0 -> XO (succ q0)
| XH -> XI XH)
(** val pred_double : positive -> positive **)
let rec pred_double = function
| XI p -> XI (XO p)
| XO p -> XI (pred_double p)
| XH -> XH
type mask = Pos.mask =
| IsNul
| IsPos of positive
| IsNeg
(** val succ_double_mask : mask -> mask **)
let succ_double_mask = function
| IsNul -> IsPos XH
| IsPos p -> IsPos (XI p)
| IsNeg -> IsNeg
(** val double_mask : mask -> mask **)
let double_mask = function
| IsPos p -> IsPos (XO p)
| x0 -> x0
(** val double_pred_mask : positive -> mask **)
let double_pred_mask = function
| XI p -> IsPos (XO (XO p))
| XO p -> IsPos (XO (pred_double p))
| XH -> IsNul
(** val sub_mask : positive -> positive -> mask **)
let rec sub_mask x y =
match x with
| XI p ->
(match y with
| XI q0 -> double_mask (sub_mask p q0)
| XO q0 -> succ_double_mask (sub_mask p q0)
| XH -> IsPos (XO p))
| XO p ->
(match y with
| XI q0 -> succ_double_mask (sub_mask_carry p q0)
| XO q0 -> double_mask (sub_mask p q0)
| XH -> IsPos (pred_double p))
| XH -> (match y with
| XH -> IsNul
| _ -> IsNeg)
(** val sub_mask_carry : positive -> positive -> mask **)
and sub_mask_carry x y =
match x with
| XI p ->
(match y with
| XI q0 -> succ_double_mask (sub_mask_carry p q0)
| XO q0 -> double_mask (sub_mask p q0)
| XH -> IsPos (pred_double p))
| XO p ->
(match y with
| XI q0 -> double_mask (sub_mask_carry p q0)
| XO q0 -> succ_double_mask (sub_mask_carry p q0)
| XH -> double_pred_mask p)
| XH -> IsNeg
(** val sub : positive -> positive -> positive **)
let sub x y =
match sub_mask x y with
| IsPos z0 -> z0
| _ -> XH
(** val mul : positive -> positive -> positive **)
let rec mul x y =
match x with
| XI p -> add y (XO (mul p y))
| XO p -> XO (mul p y)
| XH -> y
(** val size_nat : positive -> nat **)
let rec size_nat = function
| XI p2 -> S (size_nat p2)
| XO p2 -> S (size_nat p2)
| XH -> S O
(** val compare_cont : comparison -> positive -> positive -> comparison **)
let rec compare_cont r x y =
match x with
| XI p ->
(match y with
| XI q0 -> compare_cont r p q0
| XO q0 -> compare_cont Gt p q0
| XH -> Gt)
| XO p ->
(match y with
| XI q0 -> compare_cont Lt p q0
| XO q0 -> compare_cont r p q0
| XH -> Gt)
| XH -> (match y with
| XH -> r
| _ -> Lt)
(** val compare : positive -> positive -> comparison **)
let compare =
compare_cont Eq
(** val gcdn : nat -> positive -> positive -> positive **)
let rec gcdn n0 a b =
match n0 with
| O -> XH
| S n1 ->
(match a with
| XI a' ->
(match b with
| XI b' ->
(match compare a' b' with
| Eq -> a
| Lt -> gcdn n1 (sub b' a') a
| Gt -> gcdn n1 (sub a' b') b)
| XO b0 -> gcdn n1 a b0
| XH -> XH)
| XO a0 ->
(match b with
| XI _ -> gcdn n1 a0 b
| XO b0 -> XO (gcdn n1 a0 b0)
| XH -> XH)
| XH -> XH)
(** val gcd : positive -> positive -> positive **)
let gcd a b =
gcdn (Coq__1.add (size_nat a) (size_nat b)) a b
(** val of_succ_nat : nat -> positive **)
let rec of_succ_nat = function
| O -> XH
| S x -> succ (of_succ_nat x)
end
module N =
struct
(** val of_nat : nat -> n **)
let of_nat = function
| O -> N0
| S n' -> Npos (Coq_Pos.of_succ_nat n')
end
(** val pow_pos : ('a1 -> 'a1 -> 'a1) -> 'a1 -> positive -> 'a1 **)
let rec pow_pos rmul x = function
| XI i0 -> let p = pow_pos rmul x i0 in rmul x (rmul p p)
| XO i0 -> let p = pow_pos rmul x i0 in rmul p p
| XH -> x
(** val nth : nat -> 'a1 list -> 'a1 -> 'a1 **)
let rec nth n0 l default =
match n0 with
| O -> (match l with
| [] -> default
| x::_ -> x)
| S m -> (match l with
| [] -> default
| _::t0 -> nth m t0 default)
(** val map : ('a1 -> 'a2) -> 'a1 list -> 'a2 list **)
let rec map f = function
| [] -> []
| a::t0 -> (f a)::(map f t0)
(** val fold_right : ('a2 -> 'a1 -> 'a1) -> 'a1 -> 'a2 list -> 'a1 **)
let rec fold_right f a0 = function
| [] -> a0
| b::t0 -> f b (fold_right f a0 t0)
module Z =
struct
(** val double : z -> z **)
let double = function
| Z0 -> Z0
| Zpos p -> Zpos (XO p)
| Zneg p -> Zneg (XO p)
(** val succ_double : z -> z **)
let succ_double = function
| Z0 -> Zpos XH
| Zpos p -> Zpos (XI p)
| Zneg p -> Zneg (Coq_Pos.pred_double p)
(** val pred_double : z -> z **)
let pred_double = function
| Z0 -> Zneg XH
| Zpos p -> Zpos (Coq_Pos.pred_double p)
| Zneg p -> Zneg (XI p)
(** val pos_sub : positive -> positive -> z **)
let rec pos_sub x y =
match x with
| XI p ->
(match y with
| XI q0 -> double (pos_sub p q0)
| XO q0 -> succ_double (pos_sub p q0)
| XH -> Zpos (XO p))
| XO p ->
(match y with
| XI q0 -> pred_double (pos_sub p q0)
| XO q0 -> double (pos_sub p q0)
| XH -> Zpos (Coq_Pos.pred_double p))
| XH ->
(match y with
| XI q0 -> Zneg (XO q0)
| XO q0 -> Zneg (Coq_Pos.pred_double q0)
| XH -> Z0)
(** val add : z -> z -> z **)
let add x y =
match x with
| Z0 -> y
| Zpos x' ->
(match y with
| Z0 -> x
| Zpos y' -> Zpos (Coq_Pos.add x' y')
| Zneg y' -> pos_sub x' y')
| Zneg x' ->
(match y with
| Z0 -> x
| Zpos y' -> pos_sub y' x'
| Zneg y' -> Zneg (Coq_Pos.add x' y'))
(** val opp : z -> z **)
let opp = function
| Z0 -> Z0
| Zpos x0 -> Zneg x0
| Zneg x0 -> Zpos x0
(** val sub : z -> z -> z **)
let sub m n0 =
add m (opp n0)
(** val mul : z -> z -> z **)
let mul x y =
match x with
| Z0 -> Z0
| Zpos x' ->
(match y with
| Z0 -> Z0
| Zpos y' -> Zpos (Coq_Pos.mul x' y')
| Zneg y' -> Zneg (Coq_Pos.mul x' y'))
| Zneg x' ->
(match y with
| Z0 -> Z0
| Zpos y' -> Zneg (Coq_Pos.mul x' y')
| Zneg y' -> Zpos (Coq_Pos.mul x' y'))
(** val compare : z -> z -> comparison **)
let compare x y =
match x with
| Z0 -> (match y with
| Z0 -> Eq
| Zpos _ -> Lt
| Zneg _ -> Gt)
| Zpos x' -> (match y with
| Zpos y' -> Coq_Pos.compare x' y'
| _ -> Gt)
| Zneg x' ->
(match y with
| Zneg y' -> compOpp (Coq_Pos.compare x' y')
| _ -> Lt)
(** val leb : z -> z -> bool **)
let leb x y =
match compare x y with
| Gt -> false
| _ -> true
(** val ltb : z -> z -> bool **)
let ltb x y =
match compare x y with
| Lt -> true
| _ -> false
(** val gtb : z -> z -> bool **)
let gtb x y =
match compare x y with
| Gt -> true
| _ -> false
(** val max : z -> z -> z **)
let max n0 m =
match compare n0 m with
| Lt -> m
| _ -> n0
(** val abs : z -> z **)
let abs = function
| Zneg p -> Zpos p
| x -> x
(** val to_N : z -> n **)
let to_N = function
| Zpos p -> Npos p
| _ -> N0
(** val pos_div_eucl : positive -> z -> z * z **)
let rec pos_div_eucl a b =
match a with
| XI a' ->
let q0,r = pos_div_eucl a' b in
let r' = add (mul (Zpos (XO XH)) r) (Zpos XH) in
if ltb r' b
then (mul (Zpos (XO XH)) q0),r'
else (add (mul (Zpos (XO XH)) q0) (Zpos XH)),(sub r' b)
| XO a' ->
let q0,r = pos_div_eucl a' b in
let r' = mul (Zpos (XO XH)) r in
if ltb r' b
then (mul (Zpos (XO XH)) q0),r'
else (add (mul (Zpos (XO XH)) q0) (Zpos XH)),(sub r' b)
| XH -> if leb (Zpos (XO XH)) b then Z0,(Zpos XH) else (Zpos XH),Z0
(** val div_eucl : z -> z -> z * z **)
let div_eucl a b =
match a with
| Z0 -> Z0,Z0
| Zpos a' ->
(match b with
| Z0 -> Z0,Z0
| Zpos _ -> pos_div_eucl a' b
| Zneg b' ->
let q0,r = pos_div_eucl a' (Zpos b') in
(match r with
| Z0 -> (opp q0),Z0
| _ -> (opp (add q0 (Zpos XH))),(add b r)))
| Zneg a' ->
(match b with
| Z0 -> Z0,Z0
| Zpos _ ->
let q0,r = pos_div_eucl a' b in
(match r with
| Z0 -> (opp q0),Z0
| _ -> (opp (add q0 (Zpos XH))),(sub b r))
| Zneg b' -> let q0,r = pos_div_eucl a' (Zpos b') in q0,(opp r))
(** val div : z -> z -> z **)
let div a b =
let q0,_ = div_eucl a b in q0
(** val gcd : z -> z -> z **)
let gcd a b =
match a with
| Z0 -> abs b
| Zpos a0 ->
(match b with
| Z0 -> abs a
| Zpos b0 -> Zpos (Coq_Pos.gcd a0 b0)
| Zneg b0 -> Zpos (Coq_Pos.gcd a0 b0))
| Zneg a0 ->
(match b with
| Z0 -> abs a
| Zpos b0 -> Zpos (Coq_Pos.gcd a0 b0)
| Zneg b0 -> Zpos (Coq_Pos.gcd a0 b0))
end
(** val zeq_bool : z -> z -> bool **)
let zeq_bool x y =
match Z.compare x y with
| Eq -> true
| _ -> false
type 'c pol =
| Pc of 'c
| Pinj of positive * 'c pol
| PX of 'c pol * positive * 'c pol
(** val p0 : 'a1 -> 'a1 pol **)
let p0 cO =
Pc cO
(** val p1 : 'a1 -> 'a1 pol **)
let p1 cI =
Pc cI
(** val peq : ('a1 -> 'a1 -> bool) -> 'a1 pol -> 'a1 pol -> bool **)
let rec peq ceqb p p' =
match p with
| Pc c -> (match p' with
| Pc c' -> ceqb c c'
| _ -> false)
| Pinj (j, q0) ->
(match p' with
| Pinj (j', q') ->
(match Coq_Pos.compare j j' with
| Eq -> peq ceqb q0 q'
| _ -> false)
| _ -> false)
| PX (p2, i, q0) ->
(match p' with
| PX (p'0, i', q') ->
(match Coq_Pos.compare i i' with
| Eq -> if peq ceqb p2 p'0 then peq ceqb q0 q' else false
| _ -> false)
| _ -> false)
(** val mkPinj : positive -> 'a1 pol -> 'a1 pol **)
let mkPinj j p = match p with
| Pc _ -> p
| Pinj (j', q0) -> Pinj ((Coq_Pos.add j j'), q0)
| PX (_, _, _) -> Pinj (j, p)
(** val mkPinj_pred : positive -> 'a1 pol -> 'a1 pol **)
let mkPinj_pred j p =
match j with
| XI j0 -> Pinj ((XO j0), p)
| XO j0 -> Pinj ((Coq_Pos.pred_double j0), p)
| XH -> p
(** val mkPX :
'a1 -> ('a1 -> 'a1 -> bool) -> 'a1 pol -> positive -> 'a1 pol -> 'a1 pol **)
let mkPX cO ceqb p i q0 =
match p with
| Pc c -> if ceqb c cO then mkPinj XH q0 else PX (p, i, q0)
| Pinj (_, _) -> PX (p, i, q0)
| PX (p', i', q') ->
if peq ceqb q' (p0 cO)
then PX (p', (Coq_Pos.add i' i), q0)
else PX (p, i, q0)
(** val mkXi : 'a1 -> 'a1 -> positive -> 'a1 pol **)
let mkXi cO cI i =
PX ((p1 cI), i, (p0 cO))
(** val mkX : 'a1 -> 'a1 -> 'a1 pol **)
let mkX cO cI =
mkXi cO cI XH
(** val popp : ('a1 -> 'a1) -> 'a1 pol -> 'a1 pol **)
let rec popp copp = function
| Pc c -> Pc (copp c)
| Pinj (j, q0) -> Pinj (j, (popp copp q0))
| PX (p2, i, q0) -> PX ((popp copp p2), i, (popp copp q0))
(** val paddC : ('a1 -> 'a1 -> 'a1) -> 'a1 pol -> 'a1 -> 'a1 pol **)
let rec paddC cadd p c =
match p with
| Pc c1 -> Pc (cadd c1 c)
| Pinj (j, q0) -> Pinj (j, (paddC cadd q0 c))
| PX (p2, i, q0) -> PX (p2, i, (paddC cadd q0 c))
(** val psubC : ('a1 -> 'a1 -> 'a1) -> 'a1 pol -> 'a1 -> 'a1 pol **)
let rec psubC csub p c =
match p with
| Pc c1 -> Pc (csub c1 c)
| Pinj (j, q0) -> Pinj (j, (psubC csub q0 c))
| PX (p2, i, q0) -> PX (p2, i, (psubC csub q0 c))
(** val paddI :
('a1 -> 'a1 -> 'a1) -> ('a1 pol -> 'a1 pol -> 'a1 pol) -> 'a1 pol ->
positive -> 'a1 pol -> 'a1 pol **)
let rec paddI cadd pop q0 j = function
| Pc c -> mkPinj j (paddC cadd q0 c)
| Pinj (j', q') ->
(match Z.pos_sub j' j with
| Z0 -> mkPinj j (pop q' q0)
| Zpos k -> mkPinj j (pop (Pinj (k, q')) q0)
| Zneg k -> mkPinj j' (paddI cadd pop q0 k q'))
| PX (p2, i, q') ->
(match j with
| XI j0 -> PX (p2, i, (paddI cadd pop q0 (XO j0) q'))
| XO j0 -> PX (p2, i, (paddI cadd pop q0 (Coq_Pos.pred_double j0) q'))
| XH -> PX (p2, i, (pop q' q0)))
(** val psubI :
('a1 -> 'a1 -> 'a1) -> ('a1 -> 'a1) -> ('a1 pol -> 'a1 pol -> 'a1 pol) ->
'a1 pol -> positive -> 'a1 pol -> 'a1 pol **)
let rec psubI cadd copp pop q0 j = function
| Pc c -> mkPinj j (paddC cadd (popp copp q0) c)
| Pinj (j', q') ->
(match Z.pos_sub j' j with
| Z0 -> mkPinj j (pop q' q0)
| Zpos k -> mkPinj j (pop (Pinj (k, q')) q0)
| Zneg k -> mkPinj j' (psubI cadd copp pop q0 k q'))
| PX (p2, i, q') ->
(match j with
| XI j0 -> PX (p2, i, (psubI cadd copp pop q0 (XO j0) q'))
| XO j0 -> PX (p2, i, (psubI cadd copp pop q0 (Coq_Pos.pred_double j0) q'))
| XH -> PX (p2, i, (pop q' q0)))
(** val paddX :
'a1 -> ('a1 -> 'a1 -> bool) -> ('a1 pol -> 'a1 pol -> 'a1 pol) -> 'a1 pol
-> positive -> 'a1 pol -> 'a1 pol **)
let rec paddX cO ceqb pop p' i' p = match p with
| Pc _ -> PX (p', i', p)
| Pinj (j, q') ->
(match j with
| XI j0 -> PX (p', i', (Pinj ((XO j0), q')))
| XO j0 -> PX (p', i', (Pinj ((Coq_Pos.pred_double j0), q')))
| XH -> PX (p', i', q'))
| PX (p2, i, q') ->
(match Z.pos_sub i i' with
| Z0 -> mkPX cO ceqb (pop p2 p') i q'
| Zpos k -> mkPX cO ceqb (pop (PX (p2, k, (p0 cO))) p') i' q'
| Zneg k -> mkPX cO ceqb (paddX cO ceqb pop p' k p2) i q')
(** val psubX :
'a1 -> ('a1 -> 'a1) -> ('a1 -> 'a1 -> bool) -> ('a1 pol -> 'a1 pol -> 'a1
pol) -> 'a1 pol -> positive -> 'a1 pol -> 'a1 pol **)
let rec psubX cO copp ceqb pop p' i' p = match p with
| Pc _ -> PX ((popp copp p'), i', p)
| Pinj (j, q') ->
(match j with
| XI j0 -> PX ((popp copp p'), i', (Pinj ((XO j0), q')))
| XO j0 -> PX ((popp copp p'), i', (Pinj ((Coq_Pos.pred_double j0), q')))
| XH -> PX ((popp copp p'), i', q'))
| PX (p2, i, q') ->
(match Z.pos_sub i i' with
| Z0 -> mkPX cO ceqb (pop p2 p') i q'
| Zpos k -> mkPX cO ceqb (pop (PX (p2, k, (p0 cO))) p') i' q'
| Zneg k -> mkPX cO ceqb (psubX cO copp ceqb pop p' k p2) i q')
(** val padd :
'a1 -> ('a1 -> 'a1 -> 'a1) -> ('a1 -> 'a1 -> bool) -> 'a1 pol -> 'a1 pol
-> 'a1 pol **)
let rec padd cO cadd ceqb p = function
| Pc c' -> paddC cadd p c'
| Pinj (j', q') -> paddI cadd (padd cO cadd ceqb) q' j' p
| PX (p'0, i', q') ->
(match p with
| Pc c -> PX (p'0, i', (paddC cadd q' c))
| Pinj (j, q0) ->
(match j with
| XI j0 -> PX (p'0, i', (padd cO cadd ceqb (Pinj ((XO j0), q0)) q'))
| XO j0 ->
PX (p'0, i',
(padd cO cadd ceqb (Pinj ((Coq_Pos.pred_double j0), q0)) q'))
| XH -> PX (p'0, i', (padd cO cadd ceqb q0 q')))
| PX (p2, i, q0) ->
(match Z.pos_sub i i' with
| Z0 ->
mkPX cO ceqb (padd cO cadd ceqb p2 p'0) i (padd cO cadd ceqb q0 q')
| Zpos k ->
mkPX cO ceqb (padd cO cadd ceqb (PX (p2, k, (p0 cO))) p'0) i'
(padd cO cadd ceqb q0 q')
| Zneg k ->
mkPX cO ceqb (paddX cO ceqb (padd cO cadd ceqb) p'0 k p2) i
(padd cO cadd ceqb q0 q')))
(** val psub :
'a1 -> ('a1 -> 'a1 -> 'a1) -> ('a1 -> 'a1 -> 'a1) -> ('a1 -> 'a1) -> ('a1
-> 'a1 -> bool) -> 'a1 pol -> 'a1 pol -> 'a1 pol **)
let rec psub cO cadd csub copp ceqb p = function
| Pc c' -> psubC csub p c'
| Pinj (j', q') -> psubI cadd copp (psub cO cadd csub copp ceqb) q' j' p
| PX (p'0, i', q') ->
(match p with
| Pc c -> PX ((popp copp p'0), i', (paddC cadd (popp copp q') c))
| Pinj (j, q0) ->
(match j with
| XI j0 ->
PX ((popp copp p'0), i',
(psub cO cadd csub copp ceqb (Pinj ((XO j0), q0)) q'))
| XO j0 ->
PX ((popp copp p'0), i',
(psub cO cadd csub copp ceqb (Pinj ((Coq_Pos.pred_double j0), q0))
q'))
| XH -> PX ((popp copp p'0), i', (psub cO cadd csub copp ceqb q0 q')))
| PX (p2, i, q0) ->
(match Z.pos_sub i i' with
| Z0 ->
mkPX cO ceqb (psub cO cadd csub copp ceqb p2 p'0) i
(psub cO cadd csub copp ceqb q0 q')
| Zpos k ->
mkPX cO ceqb (psub cO cadd csub copp ceqb (PX (p2, k, (p0 cO))) p'0)
i' (psub cO cadd csub copp ceqb q0 q')
| Zneg k ->
mkPX cO ceqb
(psubX cO copp ceqb (psub cO cadd csub copp ceqb) p'0 k p2) i
(psub cO cadd csub copp ceqb q0 q')))
(** val pmulC_aux :
'a1 -> ('a1 -> 'a1 -> 'a1) -> ('a1 -> 'a1 -> bool) -> 'a1 pol -> 'a1 ->
'a1 pol **)
let rec pmulC_aux cO cmul ceqb p c =
match p with
| Pc c' -> Pc (cmul c' c)
| Pinj (j, q0) -> mkPinj j (pmulC_aux cO cmul ceqb q0 c)
| PX (p2, i, q0) ->
mkPX cO ceqb (pmulC_aux cO cmul ceqb p2 c) i (pmulC_aux cO cmul ceqb q0 c)
(** val pmulC :
'a1 -> 'a1 -> ('a1 -> 'a1 -> 'a1) -> ('a1 -> 'a1 -> bool) -> 'a1 pol ->
'a1 -> 'a1 pol **)
let pmulC cO cI cmul ceqb p c =
if ceqb c cO
then p0 cO
else if ceqb c cI then p else pmulC_aux cO cmul ceqb p c
(** val pmulI :
'a1 -> 'a1 -> ('a1 -> 'a1 -> 'a1) -> ('a1 -> 'a1 -> bool) -> ('a1 pol ->
'a1 pol -> 'a1 pol) -> 'a1 pol -> positive -> 'a1 pol -> 'a1 pol **)
let rec pmulI cO cI cmul ceqb pmul0 q0 j = function
| Pc c -> mkPinj j (pmulC cO cI cmul ceqb q0 c)
| Pinj (j', q') ->
(match Z.pos_sub j' j with
| Z0 -> mkPinj j (pmul0 q' q0)
| Zpos k -> mkPinj j (pmul0 (Pinj (k, q')) q0)
| Zneg k -> mkPinj j' (pmulI cO cI cmul ceqb pmul0 q0 k q'))
| PX (p', i', q') ->
(match j with
| XI j' ->
mkPX cO ceqb (pmulI cO cI cmul ceqb pmul0 q0 j p') i'
(pmulI cO cI cmul ceqb pmul0 q0 (XO j') q')
| XO j' ->
mkPX cO ceqb (pmulI cO cI cmul ceqb pmul0 q0 j p') i'
(pmulI cO cI cmul ceqb pmul0 q0 (Coq_Pos.pred_double j') q')
| XH ->
mkPX cO ceqb (pmulI cO cI cmul ceqb pmul0 q0 XH p') i' (pmul0 q' q0))
(** val pmul :
'a1 -> 'a1 -> ('a1 -> 'a1 -> 'a1) -> ('a1 -> 'a1 -> 'a1) -> ('a1 -> 'a1
-> bool) -> 'a1 pol -> 'a1 pol -> 'a1 pol **)
let rec pmul cO cI cadd cmul ceqb p p'' = match p'' with
| Pc c -> pmulC cO cI cmul ceqb p c
| Pinj (j', q') -> pmulI cO cI cmul ceqb (pmul cO cI cadd cmul ceqb) q' j' p
| PX (p', i', q') ->
(match p with
| Pc c -> pmulC cO cI cmul ceqb p'' c
| Pinj (j, q0) ->
let qQ' =
match j with
| XI j0 -> pmul cO cI cadd cmul ceqb (Pinj ((XO j0), q0)) q'
| XO j0 ->
pmul cO cI cadd cmul ceqb (Pinj ((Coq_Pos.pred_double j0), q0)) q'
| XH -> pmul cO cI cadd cmul ceqb q0 q'
in
mkPX cO ceqb (pmul cO cI cadd cmul ceqb p p') i' qQ'
| PX (p2, i, q0) ->
let qQ' = pmul cO cI cadd cmul ceqb q0 q' in
let pQ' = pmulI cO cI cmul ceqb (pmul cO cI cadd cmul ceqb) q' XH p2 in
let qP' = pmul cO cI cadd cmul ceqb (mkPinj XH q0) p' in
let pP' = pmul cO cI cadd cmul ceqb p2 p' in
padd cO cadd ceqb
(mkPX cO ceqb (padd cO cadd ceqb (mkPX cO ceqb pP' i (p0 cO)) qP') i'
(p0 cO)) (mkPX cO ceqb pQ' i qQ'))
(** val psquare :
'a1 -> 'a1 -> ('a1 -> 'a1 -> 'a1) -> ('a1 -> 'a1 -> 'a1) -> ('a1 -> 'a1
-> bool) -> 'a1 pol -> 'a1 pol **)
let rec psquare cO cI cadd cmul ceqb = function
| Pc c -> Pc (cmul c c)
| Pinj (j, q0) -> Pinj (j, (psquare cO cI cadd cmul ceqb q0))
| PX (p2, i, q0) ->
let twoPQ =
pmul cO cI cadd cmul ceqb p2
(mkPinj XH (pmulC cO cI cmul ceqb q0 (cadd cI cI)))
in
let q2 = psquare cO cI cadd cmul ceqb q0 in
let p3 = psquare cO cI cadd cmul ceqb p2 in
mkPX cO ceqb (padd cO cadd ceqb (mkPX cO ceqb p3 i (p0 cO)) twoPQ) i q2
type 'c pExpr =
| PEc of 'c
| PEX of positive
| PEadd of 'c pExpr * 'c pExpr
| PEsub of 'c pExpr * 'c pExpr
| PEmul of 'c pExpr * 'c pExpr
| PEopp of 'c pExpr
| PEpow of 'c pExpr * n
(** val mk_X : 'a1 -> 'a1 -> positive -> 'a1 pol **)
let mk_X cO cI j =
mkPinj_pred j (mkX cO cI)
(** val ppow_pos :
'a1 -> 'a1 -> ('a1 -> 'a1 -> 'a1) -> ('a1 -> 'a1 -> 'a1) -> ('a1 -> 'a1
-> bool) -> ('a1 pol -> 'a1 pol) -> 'a1 pol -> 'a1 pol -> positive -> 'a1
pol **)
let rec ppow_pos cO cI cadd cmul ceqb subst_l res p = function
| XI p3 ->
subst_l
(pmul cO cI cadd cmul ceqb
(ppow_pos cO cI cadd cmul ceqb subst_l
(ppow_pos cO cI cadd cmul ceqb subst_l res p p3) p p3) p)
| XO p3 ->
ppow_pos cO cI cadd cmul ceqb subst_l
(ppow_pos cO cI cadd cmul ceqb subst_l res p p3) p p3
| XH -> subst_l (pmul cO cI cadd cmul ceqb res p)
(** val ppow_N :
'a1 -> 'a1 -> ('a1 -> 'a1 -> 'a1) -> ('a1 -> 'a1 -> 'a1) -> ('a1 -> 'a1
-> bool) -> ('a1 pol -> 'a1 pol) -> 'a1 pol -> n -> 'a1 pol **)
let ppow_N cO cI cadd cmul ceqb subst_l p = function
| N0 -> p1 cI
| Npos p2 -> ppow_pos cO cI cadd cmul ceqb subst_l (p1 cI) p p2
(** val norm_aux :
'a1 -> 'a1 -> ('a1 -> 'a1 -> 'a1) -> ('a1 -> 'a1 -> 'a1) -> ('a1 -> 'a1
-> 'a1) -> ('a1 -> 'a1) -> ('a1 -> 'a1 -> bool) -> 'a1 pExpr -> 'a1 pol **)
let rec norm_aux cO cI cadd cmul csub copp ceqb = function
| PEc c -> Pc c
| PEX j -> mk_X cO cI j
| PEadd (pe1, pe2) ->
(match pe1 with
| PEopp pe3 ->
psub cO cadd csub copp ceqb
(norm_aux cO cI cadd cmul csub copp ceqb pe2)
(norm_aux cO cI cadd cmul csub copp ceqb pe3)
| _ ->
(match pe2 with
| PEopp pe3 ->
psub cO cadd csub copp ceqb
(norm_aux cO cI cadd cmul csub copp ceqb pe1)
(norm_aux cO cI cadd cmul csub copp ceqb pe3)
| _ ->
padd cO cadd ceqb (norm_aux cO cI cadd cmul csub copp ceqb pe1)
(norm_aux cO cI cadd cmul csub copp ceqb pe2)))
| PEsub (pe1, pe2) ->
psub cO cadd csub copp ceqb (norm_aux cO cI cadd cmul csub copp ceqb pe1)
(norm_aux cO cI cadd cmul csub copp ceqb pe2)
| PEmul (pe1, pe2) ->
pmul cO cI cadd cmul ceqb (norm_aux cO cI cadd cmul csub copp ceqb pe1)
(norm_aux cO cI cadd cmul csub copp ceqb pe2)
| PEopp pe1 -> popp copp (norm_aux cO cI cadd cmul csub copp ceqb pe1)
| PEpow (pe1, n0) ->
ppow_N cO cI cadd cmul ceqb (fun p -> p)
(norm_aux cO cI cadd cmul csub copp ceqb pe1) n0
type 'a bFormula =
| TT
| FF
| X
| A of 'a
| Cj of 'a bFormula * 'a bFormula
| D of 'a bFormula * 'a bFormula
| N of 'a bFormula
| I of 'a bFormula * 'a bFormula
(** val map_bformula : ('a1 -> 'a2) -> 'a1 bFormula -> 'a2 bFormula **)
let rec map_bformula fct = function
| TT -> TT
| FF -> FF
| X -> X
| A a -> A (fct a)
| Cj (f1, f2) -> Cj ((map_bformula fct f1), (map_bformula fct f2))
| D (f1, f2) -> D ((map_bformula fct f1), (map_bformula fct f2))
| N f0 -> N (map_bformula fct f0)
| I (f1, f2) -> I ((map_bformula fct f1), (map_bformula fct f2))
type 'x clause = 'x list
type 'x cnf = 'x clause list
(** val tt : 'a1 cnf **)
let tt =
[]
(** val ff : 'a1 cnf **)
let ff =
[]::[]
(** val add_term :
('a1 -> bool) -> ('a1 -> 'a1 -> 'a1 option) -> 'a1 -> 'a1 clause -> 'a1
clause option **)
let rec add_term unsat deduce t0 = function
| [] ->
(match deduce t0 t0 with
| Some u -> if unsat u then None else Some (t0::[])
| None -> Some (t0::[]))
| t'::cl0 ->
(match deduce t0 t' with
| Some u ->
if unsat u
then None
else (match add_term unsat deduce t0 cl0 with
| Some cl' -> Some (t'::cl')
| None -> None)
| None ->
(match add_term unsat deduce t0 cl0 with
| Some cl' -> Some (t'::cl')
| None -> None))
(** val or_clause :
('a1 -> bool) -> ('a1 -> 'a1 -> 'a1 option) -> 'a1 clause -> 'a1 clause
-> 'a1 clause option **)
let rec or_clause unsat deduce cl1 cl2 =
match cl1 with
| [] -> Some cl2
| t0::cl ->
(match add_term unsat deduce t0 cl2 with
| Some cl' -> or_clause unsat deduce cl cl'
| None -> None)
(** val or_clause_cnf :
('a1 -> bool) -> ('a1 -> 'a1 -> 'a1 option) -> 'a1 clause -> 'a1 cnf ->
'a1 cnf **)
let or_clause_cnf unsat deduce t0 f =
fold_right (fun e acc ->
match or_clause unsat deduce t0 e with
| Some cl -> cl::acc
| None -> acc) [] f
(** val or_cnf :
('a1 -> bool) -> ('a1 -> 'a1 -> 'a1 option) -> 'a1 cnf -> 'a1 cnf -> 'a1
cnf **)
let rec or_cnf unsat deduce f f' =
match f with
| [] -> tt
| e::rst ->
app (or_cnf unsat deduce rst f') (or_clause_cnf unsat deduce e f')
(** val and_cnf : 'a1 cnf -> 'a1 cnf -> 'a1 cnf **)
let and_cnf f1 f2 =
app f1 f2
(** val xcnf :
('a2 -> bool) -> ('a2 -> 'a2 -> 'a2 option) -> ('a1 -> 'a2 cnf) -> ('a1
-> 'a2 cnf) -> bool -> 'a1 bFormula -> 'a2 cnf **)
let rec xcnf unsat deduce normalise0 negate0 pol0 = function
| TT -> if pol0 then tt else ff
| FF -> if pol0 then ff else tt
| X -> ff
| A x -> if pol0 then normalise0 x else negate0 x
| Cj (e1, e2) ->
if pol0
then and_cnf (xcnf unsat deduce normalise0 negate0 pol0 e1)
(xcnf unsat deduce normalise0 negate0 pol0 e2)
else or_cnf unsat deduce (xcnf unsat deduce normalise0 negate0 pol0 e1)
(xcnf unsat deduce normalise0 negate0 pol0 e2)
| D (e1, e2) ->
if pol0
then or_cnf unsat deduce (xcnf unsat deduce normalise0 negate0 pol0 e1)
(xcnf unsat deduce normalise0 negate0 pol0 e2)
else and_cnf (xcnf unsat deduce normalise0 negate0 pol0 e1)
(xcnf unsat deduce normalise0 negate0 pol0 e2)
| N e -> xcnf unsat deduce normalise0 negate0 (negb pol0) e
| I (e1, e2) ->
if pol0
then or_cnf unsat deduce
(xcnf unsat deduce normalise0 negate0 (negb pol0) e1)
(xcnf unsat deduce normalise0 negate0 pol0 e2)
else and_cnf (xcnf unsat deduce normalise0 negate0 (negb pol0) e1)
(xcnf unsat deduce normalise0 negate0 pol0 e2)
(** val cnf_checker :
('a1 list -> 'a2 -> bool) -> 'a1 cnf -> 'a2 list -> bool **)
let rec cnf_checker checker f l =
match f with
| [] -> true
| e::f0 ->
(match l with
| [] -> false
| c::l0 -> if checker e c then cnf_checker checker f0 l0 else false)
(** val tauto_checker :
('a2 -> bool) -> ('a2 -> 'a2 -> 'a2 option) -> ('a1 -> 'a2 cnf) -> ('a1
-> 'a2 cnf) -> ('a2 list -> 'a3 -> bool) -> 'a1 bFormula -> 'a3 list ->
bool **)
let tauto_checker unsat deduce normalise0 negate0 checker f w =
cnf_checker checker (xcnf unsat deduce normalise0 negate0 true f) w
(** val cneqb : ('a1 -> 'a1 -> bool) -> 'a1 -> 'a1 -> bool **)
let cneqb ceqb x y =
negb (ceqb x y)
(** val cltb :
('a1 -> 'a1 -> bool) -> ('a1 -> 'a1 -> bool) -> 'a1 -> 'a1 -> bool **)
let cltb ceqb cleb x y =
(&&) (cleb x y) (cneqb ceqb x y)
type 'c polC = 'c pol
type op1 =
| Equal
| NonEqual
| Strict
| NonStrict
type 'c nFormula = 'c polC * op1
(** val opMult : op1 -> op1 -> op1 option **)
let opMult o o' =
match o with
| Equal -> Some Equal
| NonEqual ->
(match o' with
| Equal -> Some Equal
| NonEqual -> Some NonEqual
| _ -> None)
| Strict -> (match o' with
| NonEqual -> None
| _ -> Some o')
| NonStrict ->
(match o' with
| Equal -> Some Equal
| NonEqual -> None
| _ -> Some NonStrict)
(** val opAdd : op1 -> op1 -> op1 option **)
let opAdd o o' =
match o with
| Equal -> Some o'
| NonEqual -> (match o' with
| Equal -> Some NonEqual
| _ -> None)
| Strict -> (match o' with
| NonEqual -> None
| _ -> Some Strict)
| NonStrict ->
(match o' with
| Equal -> Some NonStrict
| NonEqual -> None
| x -> Some x)
type 'c psatz =
| PsatzIn of nat
| PsatzSquare of 'c polC
| PsatzMulC of 'c polC * 'c psatz
| PsatzMulE of 'c psatz * 'c psatz
| PsatzAdd of 'c psatz * 'c psatz
| PsatzC of 'c
| PsatzZ
(** val map_option : ('a1 -> 'a2 option) -> 'a1 option -> 'a2 option **)
let map_option f = function
| Some x -> f x
| None -> None
(** val map_option2 :
('a1 -> 'a2 -> 'a3 option) -> 'a1 option -> 'a2 option -> 'a3 option **)
let map_option2 f o o' =
match o with
| Some x -> (match o' with
| Some x' -> f x x'
| None -> None)
| None -> None
(** val pexpr_times_nformula :
'a1 -> 'a1 -> ('a1 -> 'a1 -> 'a1) -> ('a1 -> 'a1 -> 'a1) -> ('a1 -> 'a1
-> bool) -> 'a1 polC -> 'a1 nFormula -> 'a1 nFormula option **)
let pexpr_times_nformula cO cI cplus ctimes ceqb e = function
| ef,o ->
(match o with
| Equal -> Some ((pmul cO cI cplus ctimes ceqb e ef),Equal)
| _ -> None)
(** val nformula_times_nformula :
'a1 -> 'a1 -> ('a1 -> 'a1 -> 'a1) -> ('a1 -> 'a1 -> 'a1) -> ('a1 -> 'a1
-> bool) -> 'a1 nFormula -> 'a1 nFormula -> 'a1 nFormula option **)
let nformula_times_nformula cO cI cplus ctimes ceqb f1 f2 =
let e1,o1 = f1 in
let e2,o2 = f2 in
map_option (fun x -> Some ((pmul cO cI cplus ctimes ceqb e1 e2),x))
(opMult o1 o2)
(** val nformula_plus_nformula :
'a1 -> ('a1 -> 'a1 -> 'a1) -> ('a1 -> 'a1 -> bool) -> 'a1 nFormula -> 'a1
nFormula -> 'a1 nFormula option **)
let nformula_plus_nformula cO cplus ceqb f1 f2 =
let e1,o1 = f1 in
let e2,o2 = f2 in
map_option (fun x -> Some ((padd cO cplus ceqb e1 e2),x)) (opAdd o1 o2)
(** val eval_Psatz :
'a1 -> 'a1 -> ('a1 -> 'a1 -> 'a1) -> ('a1 -> 'a1 -> 'a1) -> ('a1 -> 'a1
-> bool) -> ('a1 -> 'a1 -> bool) -> 'a1 nFormula list -> 'a1 psatz -> 'a1
nFormula option **)
let rec eval_Psatz cO cI cplus ctimes ceqb cleb l = function
| PsatzIn n0 -> Some (nth n0 l ((Pc cO),Equal))
| PsatzSquare e0 -> Some ((psquare cO cI cplus ctimes ceqb e0),NonStrict)
| PsatzMulC (re, e0) ->
map_option (pexpr_times_nformula cO cI cplus ctimes ceqb re)
(eval_Psatz cO cI cplus ctimes ceqb cleb l e0)
| PsatzMulE (f1, f2) ->
map_option2 (nformula_times_nformula cO cI cplus ctimes ceqb)
(eval_Psatz cO cI cplus ctimes ceqb cleb l f1)
(eval_Psatz cO cI cplus ctimes ceqb cleb l f2)
| PsatzAdd (f1, f2) ->
map_option2 (nformula_plus_nformula cO cplus ceqb)
(eval_Psatz cO cI cplus ctimes ceqb cleb l f1)
(eval_Psatz cO cI cplus ctimes ceqb cleb l f2)
| PsatzC c -> if cltb ceqb cleb cO c then Some ((Pc c),Strict) else None
| PsatzZ -> Some ((Pc cO),Equal)
(** val check_inconsistent :
'a1 -> ('a1 -> 'a1 -> bool) -> ('a1 -> 'a1 -> bool) -> 'a1 nFormula ->
bool **)
let check_inconsistent cO ceqb cleb = function
| e,op ->
(match e with
| Pc c ->
(match op with
| Equal -> cneqb ceqb c cO
| NonEqual -> ceqb c cO
| Strict -> cleb c cO
| NonStrict -> cltb ceqb cleb c cO)
| _ -> false)
(** val check_normalised_formulas :
'a1 -> 'a1 -> ('a1 -> 'a1 -> 'a1) -> ('a1 -> 'a1 -> 'a1) -> ('a1 -> 'a1
-> bool) -> ('a1 -> 'a1 -> bool) -> 'a1 nFormula list -> 'a1 psatz -> bool **)
let check_normalised_formulas cO cI cplus ctimes ceqb cleb l cm =
match eval_Psatz cO cI cplus ctimes ceqb cleb l cm with
| Some f -> check_inconsistent cO ceqb cleb f
| None -> false
type op2 =
| OpEq
| OpNEq
| OpLe
| OpGe
| OpLt
| OpGt
type 't formula = { flhs : 't pExpr; fop : op2; frhs : 't pExpr }
(** val norm :
'a1 -> 'a1 -> ('a1 -> 'a1 -> 'a1) -> ('a1 -> 'a1 -> 'a1) -> ('a1 -> 'a1
-> 'a1) -> ('a1 -> 'a1) -> ('a1 -> 'a1 -> bool) -> 'a1 pExpr -> 'a1 pol **)
let norm cO cI cplus ctimes cminus copp ceqb =
norm_aux cO cI cplus ctimes cminus copp ceqb
(** val psub0 :
'a1 -> ('a1 -> 'a1 -> 'a1) -> ('a1 -> 'a1 -> 'a1) -> ('a1 -> 'a1) -> ('a1
-> 'a1 -> bool) -> 'a1 pol -> 'a1 pol -> 'a1 pol **)
let psub0 cO cplus cminus copp ceqb =
psub cO cplus cminus copp ceqb
(** val padd0 :
'a1 -> ('a1 -> 'a1 -> 'a1) -> ('a1 -> 'a1 -> bool) -> 'a1 pol -> 'a1 pol
-> 'a1 pol **)
let padd0 cO cplus ceqb =
padd cO cplus ceqb
(** val xnormalise :
'a1 -> 'a1 -> ('a1 -> 'a1 -> 'a1) -> ('a1 -> 'a1 -> 'a1) -> ('a1 -> 'a1
-> 'a1) -> ('a1 -> 'a1) -> ('a1 -> 'a1 -> bool) -> 'a1 formula -> 'a1
nFormula list **)
let xnormalise cO cI cplus ctimes cminus copp ceqb t0 =
let { flhs = lhs; fop = o; frhs = rhs } = t0 in
let lhs0 = norm cO cI cplus ctimes cminus copp ceqb lhs in
let rhs0 = norm cO cI cplus ctimes cminus copp ceqb rhs in
(match o with
| OpEq ->
((psub0 cO cplus cminus copp ceqb lhs0 rhs0),Strict)::(((psub0 cO cplus
cminus copp
ceqb rhs0 lhs0),Strict)::[])
| OpNEq -> ((psub0 cO cplus cminus copp ceqb lhs0 rhs0),Equal)::[]
| OpLe -> ((psub0 cO cplus cminus copp ceqb lhs0 rhs0),Strict)::[]
| OpGe -> ((psub0 cO cplus cminus copp ceqb rhs0 lhs0),Strict)::[]
| OpLt -> ((psub0 cO cplus cminus copp ceqb lhs0 rhs0),NonStrict)::[]
| OpGt -> ((psub0 cO cplus cminus copp ceqb rhs0 lhs0),NonStrict)::[])
(** val cnf_normalise :
'a1 -> 'a1 -> ('a1 -> 'a1 -> 'a1) -> ('a1 -> 'a1 -> 'a1) -> ('a1 -> 'a1
-> 'a1) -> ('a1 -> 'a1) -> ('a1 -> 'a1 -> bool) -> 'a1 formula -> 'a1
nFormula cnf **)
let cnf_normalise cO cI cplus ctimes cminus copp ceqb t0 =
map (fun x -> x::[]) (xnormalise cO cI cplus ctimes cminus copp ceqb t0)
(** val xnegate :
'a1 -> 'a1 -> ('a1 -> 'a1 -> 'a1) -> ('a1 -> 'a1 -> 'a1) -> ('a1 -> 'a1
-> 'a1) -> ('a1 -> 'a1) -> ('a1 -> 'a1 -> bool) -> 'a1 formula -> 'a1
nFormula list **)
let xnegate cO cI cplus ctimes cminus copp ceqb t0 =
let { flhs = lhs; fop = o; frhs = rhs } = t0 in
let lhs0 = norm cO cI cplus ctimes cminus copp ceqb lhs in
let rhs0 = norm cO cI cplus ctimes cminus copp ceqb rhs in
(match o with
| OpEq -> ((psub0 cO cplus cminus copp ceqb lhs0 rhs0),Equal)::[]
| OpNEq ->
((psub0 cO cplus cminus copp ceqb lhs0 rhs0),Strict)::(((psub0 cO cplus
cminus copp
ceqb rhs0 lhs0),Strict)::[])
| OpLe -> ((psub0 cO cplus cminus copp ceqb rhs0 lhs0),NonStrict)::[]
| OpGe -> ((psub0 cO cplus cminus copp ceqb lhs0 rhs0),NonStrict)::[]
| OpLt -> ((psub0 cO cplus cminus copp ceqb rhs0 lhs0),Strict)::[]
| OpGt -> ((psub0 cO cplus cminus copp ceqb lhs0 rhs0),Strict)::[])
(** val cnf_negate :
'a1 -> 'a1 -> ('a1 -> 'a1 -> 'a1) -> ('a1 -> 'a1 -> 'a1) -> ('a1 -> 'a1
-> 'a1) -> ('a1 -> 'a1) -> ('a1 -> 'a1 -> bool) -> 'a1 formula -> 'a1
nFormula cnf **)
let cnf_negate cO cI cplus ctimes cminus copp ceqb t0 =
map (fun x -> x::[]) (xnegate cO cI cplus ctimes cminus copp ceqb t0)
(** val xdenorm : positive -> 'a1 pol -> 'a1 pExpr **)
let rec xdenorm jmp = function
| Pc c -> PEc c
| Pinj (j, p2) -> xdenorm (Coq_Pos.add j jmp) p2
| PX (p2, j, q0) ->
PEadd ((PEmul ((xdenorm jmp p2), (PEpow ((PEX jmp), (Npos j))))),
(xdenorm (Coq_Pos.succ jmp) q0))
(** val denorm : 'a1 pol -> 'a1 pExpr **)
let denorm p =
xdenorm XH p
(** val map_PExpr : ('a2 -> 'a1) -> 'a2 pExpr -> 'a1 pExpr **)
let rec map_PExpr c_of_S = function
| PEc c -> PEc (c_of_S c)
| PEX p -> PEX p
| PEadd (e1, e2) -> PEadd ((map_PExpr c_of_S e1), (map_PExpr c_of_S e2))
| PEsub (e1, e2) -> PEsub ((map_PExpr c_of_S e1), (map_PExpr c_of_S e2))
| PEmul (e1, e2) -> PEmul ((map_PExpr c_of_S e1), (map_PExpr c_of_S e2))
| PEopp e0 -> PEopp (map_PExpr c_of_S e0)
| PEpow (e0, n0) -> PEpow ((map_PExpr c_of_S e0), n0)
(** val map_Formula : ('a2 -> 'a1) -> 'a2 formula -> 'a1 formula **)
let map_Formula c_of_S f =
let { flhs = l; fop = o; frhs = r } = f in
{ flhs = (map_PExpr c_of_S l); fop = o; frhs = (map_PExpr c_of_S r) }
(** val simpl_cone :
'a1 -> 'a1 -> ('a1 -> 'a1 -> 'a1) -> ('a1 -> 'a1 -> bool) -> 'a1 psatz ->
'a1 psatz **)
let simpl_cone cO cI ctimes ceqb e = match e with
| PsatzSquare t0 ->
(match t0 with
| Pc c -> if ceqb cO c then PsatzZ else PsatzC (ctimes c c)
| _ -> PsatzSquare t0)
| PsatzMulE (t1, t2) ->
(match t1 with
| PsatzMulE (x, x0) ->
(match x with
| PsatzC p2 ->
(match t2 with
| PsatzC c -> PsatzMulE ((PsatzC (ctimes c p2)), x0)
| PsatzZ -> PsatzZ
| _ -> e)
| _ ->
(match x0 with
| PsatzC p2 ->
(match t2 with
| PsatzC c -> PsatzMulE ((PsatzC (ctimes c p2)), x)
| PsatzZ -> PsatzZ
| _ -> e)
| _ ->
(match t2 with
| PsatzC c -> if ceqb cI c then t1 else PsatzMulE (t1, t2)
| PsatzZ -> PsatzZ
| _ -> e)))
| PsatzC c ->
(match t2 with
| PsatzMulE (x, x0) ->
(match x with
| PsatzC p2 -> PsatzMulE ((PsatzC (ctimes c p2)), x0)
| _ ->
(match x0 with
| PsatzC p2 -> PsatzMulE ((PsatzC (ctimes c p2)), x)
| _ -> if ceqb cI c then t2 else PsatzMulE (t1, t2)))
| PsatzAdd (y, z0) ->
PsatzAdd ((PsatzMulE ((PsatzC c), y)), (PsatzMulE ((PsatzC c), z0)))
| PsatzC c0 -> PsatzC (ctimes c c0)
| PsatzZ -> PsatzZ
| _ -> if ceqb cI c then t2 else PsatzMulE (t1, t2))
| PsatzZ -> PsatzZ
| _ ->
(match t2 with
| PsatzC c -> if ceqb cI c then t1 else PsatzMulE (t1, t2)
| PsatzZ -> PsatzZ
| _ -> e))
| PsatzAdd (t1, t2) ->
(match t1 with
| PsatzZ -> t2
| _ -> (match t2 with
| PsatzZ -> t1
| _ -> PsatzAdd (t1, t2)))
| _ -> e
type q = { qnum : z; qden : positive }
(** val qnum : q -> z **)
let qnum x = x.qnum
(** val qden : q -> positive **)
let qden x = x.qden
(** val qeq_bool : q -> q -> bool **)
let qeq_bool x y =
zeq_bool (Z.mul x.qnum (Zpos y.qden)) (Z.mul y.qnum (Zpos x.qden))
(** val qle_bool : q -> q -> bool **)
let qle_bool x y =
Z.leb (Z.mul x.qnum (Zpos y.qden)) (Z.mul y.qnum (Zpos x.qden))
(** val qplus : q -> q -> q **)
let qplus x y =
{ qnum = (Z.add (Z.mul x.qnum (Zpos y.qden)) (Z.mul y.qnum (Zpos x.qden)));
qden = (Coq_Pos.mul x.qden y.qden) }
(** val qmult : q -> q -> q **)
let qmult x y =
{ qnum = (Z.mul x.qnum y.qnum); qden = (Coq_Pos.mul x.qden y.qden) }
(** val qopp : q -> q **)
let qopp x =
{ qnum = (Z.opp x.qnum); qden = x.qden }
(** val qminus : q -> q -> q **)
let qminus x y =
qplus x (qopp y)
(** val qinv : q -> q **)
let qinv x =
match x.qnum with
| Z0 -> { qnum = Z0; qden = XH }
| Zpos p -> { qnum = (Zpos x.qden); qden = p }
| Zneg p -> { qnum = (Zneg x.qden); qden = p }
(** val qpower_positive : q -> positive -> q **)
let qpower_positive =
pow_pos qmult
(** val qpower : q -> z -> q **)
let qpower q0 = function
| Z0 -> { qnum = (Zpos XH); qden = XH }
| Zpos p -> qpower_positive q0 p
| Zneg p -> qinv (qpower_positive q0 p)
type 'a t =
| Empty
| Leaf of 'a
| Node of 'a t * 'a * 'a t
(** val find : 'a1 -> 'a1 t -> positive -> 'a1 **)
let rec find default vm p =
match vm with
| Empty -> default
| Leaf i -> i
| Node (l, e, r) ->
(match p with
| XI p2 -> find default r p2
| XO p2 -> find default l p2
| XH -> e)
(** val singleton : 'a1 -> positive -> 'a1 -> 'a1 t **)
let rec singleton default x v =
match x with
| XI p -> Node (Empty, default, (singleton default p v))
| XO p -> Node ((singleton default p v), default, Empty)
| XH -> Leaf v
(** val vm_add : 'a1 -> positive -> 'a1 -> 'a1 t -> 'a1 t **)
let rec vm_add default x v = function
| Empty -> singleton default x v
| Leaf vl ->
(match x with
| XI p -> Node (Empty, vl, (singleton default p v))
| XO p -> Node ((singleton default p v), vl, Empty)
| XH -> Leaf v)
| Node (l, o, r) ->
(match x with
| XI p -> Node (l, o, (vm_add default p v r))
| XO p -> Node ((vm_add default p v l), o, r)
| XH -> Node (l, v, r))
type zWitness = z psatz
(** val zWeakChecker : z nFormula list -> z psatz -> bool **)
let zWeakChecker =
check_normalised_formulas Z0 (Zpos XH) Z.add Z.mul zeq_bool Z.leb
(** val psub1 : z pol -> z pol -> z pol **)
let psub1 =
psub0 Z0 Z.add Z.sub Z.opp zeq_bool
(** val padd1 : z pol -> z pol -> z pol **)
let padd1 =
padd0 Z0 Z.add zeq_bool
(** val norm0 : z pExpr -> z pol **)
let norm0 =
norm Z0 (Zpos XH) Z.add Z.mul Z.sub Z.opp zeq_bool
(** val xnormalise0 : z formula -> z nFormula list **)
let xnormalise0 t0 =
let { flhs = lhs; fop = o; frhs = rhs } = t0 in
let lhs0 = norm0 lhs in
let rhs0 = norm0 rhs in
(match o with
| OpEq ->
((psub1 lhs0 (padd1 rhs0 (Pc (Zpos XH)))),NonStrict)::(((psub1 rhs0
(padd1 lhs0
(Pc (Zpos
XH)))),NonStrict)::[])
| OpNEq -> ((psub1 lhs0 rhs0),Equal)::[]
| OpLe -> ((psub1 lhs0 (padd1 rhs0 (Pc (Zpos XH)))),NonStrict)::[]
| OpGe -> ((psub1 rhs0 (padd1 lhs0 (Pc (Zpos XH)))),NonStrict)::[]
| OpLt -> ((psub1 lhs0 rhs0),NonStrict)::[]
| OpGt -> ((psub1 rhs0 lhs0),NonStrict)::[])
(** val normalise : z formula -> z nFormula cnf **)
let normalise t0 =
map (fun x -> x::[]) (xnormalise0 t0)
(** val xnegate0 : z formula -> z nFormula list **)
let xnegate0 t0 =
let { flhs = lhs; fop = o; frhs = rhs } = t0 in
let lhs0 = norm0 lhs in
let rhs0 = norm0 rhs in
(match o with
| OpEq -> ((psub1 lhs0 rhs0),Equal)::[]
| OpNEq ->
((psub1 lhs0 (padd1 rhs0 (Pc (Zpos XH)))),NonStrict)::(((psub1 rhs0
(padd1 lhs0
(Pc (Zpos
XH)))),NonStrict)::[])
| OpLe -> ((psub1 rhs0 lhs0),NonStrict)::[]
| OpGe -> ((psub1 lhs0 rhs0),NonStrict)::[]
| OpLt -> ((psub1 rhs0 (padd1 lhs0 (Pc (Zpos XH)))),NonStrict)::[]
| OpGt -> ((psub1 lhs0 (padd1 rhs0 (Pc (Zpos XH)))),NonStrict)::[])
(** val negate : z formula -> z nFormula cnf **)
let negate t0 =
map (fun x -> x::[]) (xnegate0 t0)
(** val zunsat : z nFormula -> bool **)
let zunsat =
check_inconsistent Z0 zeq_bool Z.leb
(** val zdeduce : z nFormula -> z nFormula -> z nFormula option **)
let zdeduce =
nformula_plus_nformula Z0 Z.add zeq_bool
(** val ceiling : z -> z -> z **)
let ceiling a b =
let q0,r = Z.div_eucl a b in
(match r with
| Z0 -> q0
| _ -> Z.add q0 (Zpos XH))
type zArithProof =
| DoneProof
| RatProof of zWitness * zArithProof
| CutProof of zWitness * zArithProof
| EnumProof of zWitness * zWitness * zArithProof list
(** val zgcdM : z -> z -> z **)
let zgcdM x y =
Z.max (Z.gcd x y) (Zpos XH)
(** val zgcd_pol : z polC -> z * z **)
let rec zgcd_pol = function
| Pc c -> Z0,c
| Pinj (_, p2) -> zgcd_pol p2
| PX (p2, _, q0) ->
let g1,c1 = zgcd_pol p2 in
let g2,c2 = zgcd_pol q0 in (zgcdM (zgcdM g1 c1) g2),c2
(** val zdiv_pol : z polC -> z -> z polC **)
let rec zdiv_pol p x =
match p with
| Pc c -> Pc (Z.div c x)
| Pinj (j, p2) -> Pinj (j, (zdiv_pol p2 x))
| PX (p2, j, q0) -> PX ((zdiv_pol p2 x), j, (zdiv_pol q0 x))
(** val makeCuttingPlane : z polC -> z polC * z **)
let makeCuttingPlane p =
let g,c = zgcd_pol p in
if Z.gtb g Z0
then (zdiv_pol (psubC Z.sub p c) g),(Z.opp (ceiling (Z.opp c) g))
else p,Z0
(** val genCuttingPlane : z nFormula -> ((z polC * z) * op1) option **)
let genCuttingPlane = function
| e,op ->
(match op with
| Equal ->
let g,c = zgcd_pol e in
if (&&) (Z.gtb g Z0)
((&&) (negb (zeq_bool c Z0)) (negb (zeq_bool (Z.gcd g c) g)))
then None
else Some ((makeCuttingPlane e),Equal)
| NonEqual -> Some ((e,Z0),op)
| Strict -> Some ((makeCuttingPlane (psubC Z.sub e (Zpos XH))),NonStrict)
| NonStrict -> Some ((makeCuttingPlane e),NonStrict))
(** val nformula_of_cutting_plane : ((z polC * z) * op1) -> z nFormula **)
let nformula_of_cutting_plane = function
| e_z,o -> let e,z0 = e_z in (padd1 e (Pc z0)),o
(** val is_pol_Z0 : z polC -> bool **)
let is_pol_Z0 = function
| Pc z0 -> (match z0 with
| Z0 -> true
| _ -> false)
| _ -> false
(** val eval_Psatz0 : z nFormula list -> zWitness -> z nFormula option **)
let eval_Psatz0 =
eval_Psatz Z0 (Zpos XH) Z.add Z.mul zeq_bool Z.leb
(** val valid_cut_sign : op1 -> bool **)
let valid_cut_sign = function
| Equal -> true
| NonStrict -> true
| _ -> false
(** val zChecker : z nFormula list -> zArithProof -> bool **)
let rec zChecker l = function
| DoneProof -> false
| RatProof (w, pf0) ->
(match eval_Psatz0 l w with
| Some f -> if zunsat f then true else zChecker (f::l) pf0
| None -> false)
| CutProof (w, pf0) ->
(match eval_Psatz0 l w with
| Some f ->
(match genCuttingPlane f with
| Some cp -> zChecker ((nformula_of_cutting_plane cp)::l) pf0
| None -> true)
| None -> false)
| EnumProof (w1, w2, pf0) ->
(match eval_Psatz0 l w1 with
| Some f1 ->
(match eval_Psatz0 l w2 with
| Some f2 ->
(match genCuttingPlane f1 with
| Some p ->
let p2,op3 = p in
let e1,z1 = p2 in
(match genCuttingPlane f2 with
| Some p3 ->
let p4,op4 = p3 in
let e2,z2 = p4 in
if (&&) ((&&) (valid_cut_sign op3) (valid_cut_sign op4))
(is_pol_Z0 (padd1 e1 e2))
then let rec label pfs lb ub =
match pfs with
| [] -> Z.gtb lb ub
| pf1::rsr ->
(&&) (zChecker (((psub1 e1 (Pc lb)),Equal)::l) pf1)
(label rsr (Z.add lb (Zpos XH)) ub)
in label pf0 (Z.opp z1) z2
else false
| None -> true)
| None -> true)
| None -> false)
| None -> false)
(** val zTautoChecker : z formula bFormula -> zArithProof list -> bool **)
let zTautoChecker f w =
tauto_checker zunsat zdeduce normalise negate zChecker f w
type qWitness = q psatz
(** val qWeakChecker : q nFormula list -> q psatz -> bool **)
let qWeakChecker =
check_normalised_formulas { qnum = Z0; qden = XH } { qnum = (Zpos XH);
qden = XH } qplus qmult qeq_bool qle_bool
(** val qnormalise : q formula -> q nFormula cnf **)
let qnormalise =
cnf_normalise { qnum = Z0; qden = XH } { qnum = (Zpos XH); qden = XH }
qplus qmult qminus qopp qeq_bool
(** val qnegate : q formula -> q nFormula cnf **)
let qnegate =
cnf_negate { qnum = Z0; qden = XH } { qnum = (Zpos XH); qden = XH } qplus
qmult qminus qopp qeq_bool
(** val qunsat : q nFormula -> bool **)
let qunsat =
check_inconsistent { qnum = Z0; qden = XH } qeq_bool qle_bool
(** val qdeduce : q nFormula -> q nFormula -> q nFormula option **)
let qdeduce =
nformula_plus_nformula { qnum = Z0; qden = XH } qplus qeq_bool
(** val qTautoChecker : q formula bFormula -> qWitness list -> bool **)
let qTautoChecker f w =
tauto_checker qunsat qdeduce qnormalise qnegate qWeakChecker f w
type rcst =
| C0
| C1
| CQ of q
| CZ of z
| CPlus of rcst * rcst
| CMinus of rcst * rcst
| CMult of rcst * rcst
| CInv of rcst
| COpp of rcst
(** val q_of_Rcst : rcst -> q **)
let rec q_of_Rcst = function
| C0 -> { qnum = Z0; qden = XH }
| C1 -> { qnum = (Zpos XH); qden = XH }
| CQ q0 -> q0
| CZ z0 -> { qnum = z0; qden = XH }
| CPlus (r1, r2) -> qplus (q_of_Rcst r1) (q_of_Rcst r2)
| CMinus (r1, r2) -> qminus (q_of_Rcst r1) (q_of_Rcst r2)
| CMult (r1, r2) -> qmult (q_of_Rcst r1) (q_of_Rcst r2)
| CInv r0 -> qinv (q_of_Rcst r0)
| COpp r0 -> qopp (q_of_Rcst r0)
type rWitness = q psatz
(** val rWeakChecker : q nFormula list -> q psatz -> bool **)
let rWeakChecker =
check_normalised_formulas { qnum = Z0; qden = XH } { qnum = (Zpos XH);
qden = XH } qplus qmult qeq_bool qle_bool
(** val rnormalise : q formula -> q nFormula cnf **)
let rnormalise =
cnf_normalise { qnum = Z0; qden = XH } { qnum = (Zpos XH); qden = XH }
qplus qmult qminus qopp qeq_bool
(** val rnegate : q formula -> q nFormula cnf **)
let rnegate =
cnf_negate { qnum = Z0; qden = XH } { qnum = (Zpos XH); qden = XH } qplus
qmult qminus qopp qeq_bool
(** val runsat : q nFormula -> bool **)
let runsat =
check_inconsistent { qnum = Z0; qden = XH } qeq_bool qle_bool
(** val rdeduce : q nFormula -> q nFormula -> q nFormula option **)
let rdeduce =
nformula_plus_nformula { qnum = Z0; qden = XH } qplus qeq_bool
(** val rTautoChecker : rcst formula bFormula -> rWitness list -> bool **)
let rTautoChecker f w =
tauto_checker runsat rdeduce rnormalise rnegate rWeakChecker
(map_bformula (map_Formula q_of_Rcst) f) w
|