(************************************************************************) (* * The Rocq Prover / The Rocq Development Team *) (* v * Copyright INRIA, CNRS and contributors *) (* <O___,, * (see version control and CREDITS file for authors & dates) *) (* \VV/ **************************************************************) (* // * This file is distributed under the terms of the *) (* * GNU Lesser General Public License Version 2.1 *) (* * (see LICENSE file for the text of the license) *) (************************************************************************) (* *) (* Micromega: A reflexive tactic using the Positivstellensatz *) (* *) (* Frédéric Besson (Irisa/Inria) 2006-20018 *) (* *) (************************************************************************)
open NumCompat open Q.Notations open Mutils
module Mc = Micromega
let max_nb_cstr = ref max_int
type var = int
let debug = false let ( <+> ) = ( +/ ) let ( <*> ) = ( */ )
module Monomial : sig type t
valconst : t val is_const : t -> bool val var : var -> t val is_var : t -> bool val get_var : t -> var option val prod : t -> t -> t val factor : t -> var -> t option val compare : t -> t -> int val pp : out_channel -> t -> unit val fold : (var -> int -> 'a -> 'a) -> t -> 'a -> 'a val sqrt : t -> t option val variables : t -> ISet.t val degree : t -> int val subset : t -> t -> bool val output : out_channel -> t -> unit end = struct type t = int array (* Compact representation [| d; e₀; v₀; ...; eₙ; vₙ |] where d = Σi v_i is the multi-degree e_i gives the variable number as a diff, i.e. the variable at position i is Σi e_i, and e_i ≠ 0 for all i > 0 v_i is the degree of e_i, must be ≠ 0
*)
letconst = [|0|]
let subset m1 m2 =
m1.(0) <= m2.(0) &&
let len1 = Array.length m1 in let len2 = Array.length m2 in
let get_var m c v =
v+m.(c) , m.(c+1) in
let rec xsubset cur1 v1 e1 cur2 v2 e2 = match Int.compare v1 v2 with
| 0 -> e1 <= e2 &&
(if cur1 + 2 = len1 thentrue elseif cur2 + 2 = len2 thenfalse else let (v1,e1) = get_var m1 (cur1+2) v1 in let (v2,e2) = get_var m2 (cur2+2) v2 in
xsubset (cur1+2) v1 e1 (cur2+2) v2 e2)
| -1 -> false
| _ -> if cur2 + 2 = len2 thenfalse elselet (v2,e2) = get_var m2 (cur2+2) v2 in
xsubset cur1 v1 e1 (cur2+2) v2 e2 in if len1 <= 1 thentrue elseif len2 <= 1 thenfalse else xsubset 1 m1.(1) m1.(2) 1 m2.(1) m2.(2)
let is_const (m : t) = match m with [|_|] -> true | _ -> false
let var x = [|1; x; 1|]
let is_var (m : t) = Int.equal m.(0) 1
let get_var (m : t) = match m with
| [|1; x; _|] -> Some x
| _ -> None
let prod (m1 : t) (m2 : t) = let len1 = Array.length m1 in let len2 = Array.length m2 in (* Compute the number of variables in the monomial *) let rec nvars accu cur1 cur2 i1 i2 = if Int.equal i1 len1 && Int.equal i2 len2 then accu elseif Int.equal i1 len1 then accu + (len2 - i2) elseif Int.equal i2 len2 then accu + (len1 - i1) else let ncur1 = cur1 + m1.(i1) in let ncur2 = cur2 + m2.(i2) in if ncur1 < ncur2 then nvars (accu + 2) ncur1 cur2 (i1 + 2) i2 elseif ncur1 > ncur2 then nvars (accu + 2) cur1 ncur2 i1 (i2 + 2) else nvars (accu + 2) ncur1 ncur2 (i1 + 2) (i2 + 2) in let n = nvars 1 0 0 1 1 in let m = Array.make n 0 in let () = m.(0) <- m1.(0) + m2.(0) in (* Set the variable exponents *) let rec set cur cur1 cur2 i i1 i2 = if Int.equal i1 len1 && Int.equal i2 len2 then () elseif Int.equal i1 len1 then let ncur2 = cur2 + m2.(i2) in let () = m.(i) <- ncur2 - cur in let () = m.(i + 1) <- m2.(i2 + 1) in set ncur2 cur1 ncur2 (i + 2) i1 (i2 + 2) elseif Int.equal i2 len2 then let ncur1 = cur1 + m1.(i1) in let () = m.(i) <- ncur1 - cur in let () = m.(i + 1) <- m1.(i1 + 1) in set ncur1 ncur1 cur2 (i + 2) (i1 + 2) i2 else let ncur1 = cur1 + m1.(i1) in let ncur2 = cur2 + m2.(i2) in if ncur1 < ncur2 then let () = m.(i) <- ncur1 - cur in let () = m.(i + 1) <- m1.(i1 + 1) in set ncur1 ncur1 cur2 (i + 2) (i1 + 2) i2 elseif ncur1 > ncur2 then let () = m.(i) <- ncur2 - cur in let () = m.(i + 1) <- m2.(i2 + 1) in set ncur2 cur1 ncur2 (i + 2) i1 (i2 + 2) else let () = m.(i) <- ncur1 - cur in let () = m.(i + 1) <- m1.(i1 + 1) + m2.(i2 + 1) in set ncur1 ncur1 ncur2 (i + 2) (i1 + 2) (i2 + 2) in let () = set 0 0 0 1 1 1 in
m
(* [factor m x] returns [None] if [x] does not appear in [m], and decreases
its exponent by one otherwise *) let factor (m : t) (x : var) = let len = Array.length m in let rec factor cur i = if Int.equal i len then None else let ncur = cur + m.(i) in let k = m.(i + 1) in if ncur < x then factor ncur (i + 2) elseif x < ncur then None elseif Int.equal k 1 then (* Need to squeeze out the binding for x *) let ans = Array.make (len - 2) 0 in let () = ans.(0) <- m.(0) - 1 in let () = Array.blit m 1 ans 1 (i - 1) in let () = Array.blit m (i + 2) ans i (len - i - 2) in (* Correct the diff *) let () = ifnot (Int.equal len (i + 2)) then ans.(i) <- ans.(i) + m.(i) in
Some ans else let ans = Array.copy m in let () = ans.(0) <- ans.(0) - 1 in let () = ans.(i + 1) <- ans.(i + 1) - 1 in
Some ans in
factor 0 1
let sqrt (m : t) = match m with
| [|_|] -> Some const
| _ -> let m = Array.copy m in let len = Array.length m in let () = m.(0) <- m.(0) / 2 in let rec set i = if Int.equal i len then () else let v = m.(i + 1) in let () = if v mod 2 = 0 then m.(i + 1) <- v / 2 else raise_notrace Exit in set (i + 2) in trylet () = set 1 in Some m with Exit -> None
let degree (m : t) = m.(0)
let fold f (m : t) accu = let len = Array.length m in let rec fold accu cur i = if Int.equal i len then accu else let cur = cur + m.(i) in let accu = f cur m.(i + 1) accu in
fold accu cur (i + 2) in
fold accu 0 1
let output o m = fold (fun v i () -> Printf.fprintf o "x%i^%i" v i) m ()
let variables (m : t) =
fold (fun x _ accu -> ISet.add x accu) m ISet.empty
let pp o m = let pp_elt o (k, v) = if v = 1 then Printf.fprintf o "x%i" k else Printf.fprintf o "x%i^%i" k v in let rec pp_list o l = match l with
| [] -> ()
| [e] -> pp_elt o e
| e :: l -> Printf.fprintf o "%a*%a" pp_elt e pp_list l in
pp_list o (List.rev @@ fold (fun x v accu -> (x, v) :: accu) m [])
end
module MonMap = struct
include Map.Make (Monomial)
let union f =
merge (fun x v1 v2 -> match (v1, v2) with
| None, None -> None
| Some v, None | None, Some v -> Some v
| Some v1, Some v2 -> f x v1 v2) end
let pp_mon o (m, i) = if Monomial.is_const m then if Q.zero =/ i then () else Printf.fprintf o "%s" (Q.to_string i) elseif Q.one =/ i then Monomial.pp o m elseif Q.minus_one =/ i then Printf.fprintf o "-%a" Monomial.pp m elseif Q.zero =/ i then () else Printf.fprintf o "%s*%a" (Q.to_string i) Monomial.pp m
module Poly : (* A polynomial is a map of monomials *) (* This is probably a naive implementation (expected to be fast enough - Rocq is probably the bottleneck) *The new ring contribution is using a sparse Horner representation.
*) sig type t
val pp : out_channel -> t -> unit val get : Monomial.t -> t -> Q.t val variable : var -> t val add : Monomial.t -> Q.t -> t -> t val constant : Q.t -> t val product : t -> t -> t val addition : t -> t -> t val uminus : t -> t val fold : (Monomial.t -> Q.t -> 'a -> 'a) -> t -> 'a -> 'a val factorise : var -> t -> t * t end = struct (*normalisation bug : 0*x ... *)
module P = Map.Make (Monomial) open P
type t = Q.t P.t
let pp o p = P.iter (fun mn i -> Printf.fprintf o "%a + " pp_mon (mn, i)) p
(* Get the coefficient of monomial mn *) let get : Monomial.t -> t -> Q.t = fun mn p -> tryfind mn p with Not_found -> Q.zero
(* The polynomial 1.x *) let variable : var -> t = fun x -> add (Monomial.var x) Q.one empty
(*The constant polynomial *) let constant : Q.t -> t = fun c -> add Monomial.const c empty
(* The addition of a monomial *)
let add : Monomial.t -> Q.t -> t -> t = fun mn v p -> if Q.sign v = 0 then p else let vl = get mn p <+> v in if Q.sign vl = 0 then remove mn p else add mn vl p
(** Design choice: empty is not a polynomial I do not remember why ....
**)
(* The product by a monomial *) let mult : Monomial.t -> Q.t -> t -> t = fun mn v p -> if Q.sign v = 0 then constant Q.zero else
fold
(fun mn' v' res -> P.add (Monomial.prod mn mn') (v <*> v') res)
p empty
let addition : t -> t -> t = fun p1 p2 -> fold (fun mn v p -> add mn v p) p1 p2
let product : t -> t -> t = fun p1 p2 -> fold (fun mn v res -> addition (mult mn v p2) res) p1 empty
let uminus : t -> t = fun p -> map (fun v -> Q.neg v) p let fold = P.fold
let factorise x p =
P.fold
(fun m v (px, cx) -> match Monomial.factor m x with
| None -> (px, add m v cx)
| Some mx ->
(add mx v px, cx))
p
(constant Q.zero, constant Q.zero) end
type vector = Vect.t
type cstr = {coeffs : vector; op : op; cst : Q.t}
and op = Eq | Ge | Gt
exception Strict
let is_strict c = c.op = Gt let eval_op = function Eq -> ( =/ ) | Ge -> ( >=/ ) | Gt -> ( >/ ) let string_of_op = function Eq -> "=" | Ge -> ">=" | Gt -> ">"
let compare_op o1 o2 = match (o1, o2) with
| Eq, Eq -> 0
| Eq, _ -> -1
| _, Eq -> 1
| Ge, Ge -> 0
| Ge, _ -> -1
| _, Ge -> 1
| Gt, Gt -> 0
let output_cstr o {coeffs; op; cst} =
Printf.fprintf o "%a %s %s" Vect.pp coeffs (string_of_op op) (Q.to_string cst)
let opMult o1 o2 = match (o1, o2) with Eq, _ | _, Eq -> Eq | Ge, _ | _, Ge -> Ge | Gt, Gt -> Gt
let opAdd o1 o2 = match (o1, o2) with Eq, x | x, Eq -> x | Gt, x | x, Gt -> Gt | Ge, Ge -> Ge
module LinPoly = struct (** A linear polynomial a0 + a1.x1 + ... + an.xn By convention, the constant a0 is the coefficient of the variable 0.
*)
(** A hash table might be preferable but requires a hash function. *) let (index_of_monomial : int MonoMap.t ref) = ref MonoMap.empty
let (monomial_of_index : Monomial.t IntMap.t ref) = ref IntMap.empty let fresh = ref 0
let reserve vr = if !fresh > vr then failwith (Printf.sprintf "Cannot reserve %i" vr) else fresh := vr + 1
let safe_reserve vr = if !fresh > vr then () else fresh := vr + 1
let get_fresh () = let vr = !fresh in
incr fresh; vr
let register m = try MonoMap.find m !index_of_monomial with Not_found -> let res = !fresh in
index_of_monomial := MonoMap.add m res !index_of_monomial;
monomial_of_index := IntMap.add res m !monomial_of_index;
incr fresh;
res
let var v = Vect.set (MonT.register (Monomial.var v)) Q.one Vect.null
let of_monomial m = let v = MonT.register m in
Vect.set v Q.one Vect.null
let linpol_of_pol p =
Poly.fold
(fun mon num vct -> let vr = MonT.register mon in
Vect.set vr num vct)
p Vect.null
let pol_of_linpol v =
Vect.fold
(fun p vr n -> Poly.add (MonT.retrieve vr) n p)
(Poly.constant Q.zero) v
let rocq_poly_of_linpol cst p = let pol_of_mon m =
Monomial.fold
(fun x v p ->
Mc.PEmul (Mc.PEpow (Mc.PEX (CamlToCoq.positive x), CamlToCoq.n v), p))
m
(Mc.PEc (cst Q.one)) in
Vect.fold
(fun acc x v -> let mn = MonT.retrieve x in
Mc.PEadd (Mc.PEmul (Mc.PEc (cst v), pol_of_mon mn), acc))
(Mc.PEc (cst Q.zero))
p
let pp_var o vr = try Monomial.pp o (MonT.retrieve vr) (* this is a non-linear variable *) with Not_found -> Printf.fprintf o "v%i" vr
let pp o p = Vect.pp_gen pp_var o p let constant c = if Q.sign c = 0 then Vect.null else Vect.set 0 c Vect.null
let is_linear p =
Vect.for_all
(fun v _ -> let mn = MonT.retrieve v in
Monomial.is_var mn || Monomial.is_const mn)
p
let is_variable p = let (x, v), r = Vect.decomp_fst p in if Vect.is_null r && v >/ Q.zero then Monomial.get_var (MonT.retrieve x) else None
let factorise x p = let px, cx = Poly.factorise x (pol_of_linpol p) in
(linpol_of_pol px, linpol_of_pol cx)
let is_linear_for x p = let a, b = factorise x p in
Vect.is_constant a
let search_all_linear p l =
Vect.fold
(fun acc x v -> if p v then let x' = MonT.retrieve x in match Monomial.get_var x' with
| None -> acc
| Some x -> if is_linear_for x l then x :: acc else acc else acc)
[] l
let min_list (l : int list) = match l with [] -> None | e :: l -> Some (List.fold_left min e l)
let search_linear p l = min_list (search_all_linear p l)
let of_vect v =
Vect.fold
(fun acc v vl -> addition (product (var v) (constant vl)) acc)
Vect.null v
let variables p =
Vect.fold
(fun acc v _ -> ISet.union (Monomial.variables (MonT.retrieve v)) acc)
ISet.empty p
let monomials p = Vect.fold (fun acc v _ -> ISet.add v acc) ISet.empty p
let pp_goal typ o l = let vars = List.fold_left
(fun acc p -> ISet.union acc (variables (fst p)))
ISet.empty l in let pp_vars o i =
ISet.iter (fun v -> Printf.fprintf o "(x%i : %s) " v typ) vars in
Printf.fprintf o "forall %a\n" pp_vars vars; List.iteri
(fun i (p, op) ->
Printf.fprintf o "(H%i : %a %s 0)\n" i pp p (string_of_op op))
l;
Printf.fprintf o ", False\n"
let collect_square p =
Vect.fold
(fun acc v _ -> let m = MonT.retrieve v in match Monomial.sqrt m with None -> acc | Some s -> MonMap.add s m acc)
MonMap.empty p end
module ProofFormat = struct type prf_rule =
| Annot ofstring * prf_rule
| Hyp of int
| Def of int
| Refof int
| Cst of Q.t
| Zero
| Square of Vect.t
| MulC of Vect.t * prf_rule
| Gcd of Z.t * prf_rule
| MulPrf of prf_rule * prf_rule
| AddPrf of prf_rule * prf_rule
| CutPrf of prf_rule
| LetPrf of prf_rule * prf_rule
type proof =
| Done
| Step of int * prf_rule * proof
| Split of int * Vect.t * proof * proof
| Enum of int * prf_rule * Vect.t * prf_rule * proof list
| ExProof of int * int * int * var * var * var * proof
(* x = z - t, z >= 0, t >= 0 *)
let rec output_prf_rule o = function
| Annot (s, p) -> Printf.fprintf o "(%a)@%s" output_prf_rule p s
| Hyp i -> Printf.fprintf o "Hyp %i" i
| Def i -> Printf.fprintf o "Def %i" i
| Ref i -> Printf.fprintf o "Ref %i" i
| LetPrf (p1, p2) ->
Printf.fprintf o "Let (%a) in %a" output_prf_rule p1 output_prf_rule p2
| Cst c -> Printf.fprintf o "Cst %s" (Q.to_string c)
| Zero -> Printf.fprintf o "Zero"
| Square s -> Printf.fprintf o "(%a)^2" Poly.pp (LinPoly.pol_of_linpol s)
| MulC (p, pr) ->
Printf.fprintf o "(%a) * (%a)" Poly.pp (LinPoly.pol_of_linpol p)
output_prf_rule pr
| MulPrf (p1, p2) ->
Printf.fprintf o "(%a) * (%a)" output_prf_rule p1 output_prf_rule p2
| AddPrf (p1, p2) ->
Printf.fprintf o "%a + %a" output_prf_rule p1 output_prf_rule p2
| CutPrf p -> Printf.fprintf o "[%a]" output_prf_rule p
| Gcd (c, p) -> Printf.fprintf o "(%a)/%s" output_prf_rule p (Z.to_string c)
let rec output_proof o = function
| Done -> Printf.fprintf o "."
| Step (i, p, pf) ->
Printf.fprintf o "%i:= %a\n ; %a" i output_prf_rule p output_proof pf
| Split (i, v, p1, p2) ->
Printf.fprintf o "%i:=%a ; { %a } { %a }" i Vect.pp v output_proof p1
output_proof p2
| Enum (i, p1, v, p2, pl) ->
Printf.fprintf o "%i{%a<=%a<=%a}%a" i output_prf_rule p1 Vect.pp v
output_prf_rule p2 (pp_list ";" output_proof) pl
| ExProof (i, j, k, x, z, t, pr) ->
Printf.fprintf o "%i := %i = %i - %i ; %i := %i >= 0 ; %i := %i >= 0 ; %a"
i x z t j z k t output_proof pr
let cmp_pair c1 c2 (x1, x2) (y1, y2) = match c1 x1 y1 with 0 -> c2 x2 y2 | i -> i
let rec compare p1 p2 = match (p1, p2) with
| Annot (s1, p1), Annot (s2, p2) -> if s1 = s2 then compare p1 p2 elseString.compare s1 s2
| Hyp i, Hyp j -> Int.compare i j
| Def i, Def j -> Int.compare i j
| Ref i, Ref j -> Int.compare i j
| Cst n, Cst m -> Q.compare n m
| Zero, Zero -> 0
| Square v1, Square v2 -> Vect.compare v1 v2
| MulC (v1, p1), MulC (v2, p2) ->
cmp_pair Vect.compare compare (v1, p1) (v2, p2)
| Gcd (b1, p1), Gcd (b2, p2) ->
cmp_pair Z.compare compare (b1, p1) (b2, p2)
| MulPrf (p1, q1), MulPrf (p2, q2) ->
cmp_pair compare compare (p1, q1) (p2, q2)
| AddPrf (p1, q1), AddPrf (p2, q2) ->
cmp_pair compare compare (p1, q1) (p2, q2)
| CutPrf p, CutPrf p' -> compare p p'
| LetPrf(p1,q1) , LetPrf(p2,q2) ->
cmp_pair compare compare (p1, q1) (p2, q2)
| _, _ -> Int.compare (id_of_constr p1) (id_of_constr p2) end
module PrfRuleMap = Map.Make (OrdPrfRule)
let rec pr_size = function
| Annot (_, p) -> pr_size p
| Zero | Square _ -> Q.zero
| Hyp _ -> Q.one
| Def _ -> Q.one
| Ref _ -> Q.one
| Cst n -> n
| Gcd (i, p) -> pr_size p // Q.of_bigint i
| MulPrf (p1, p2) | AddPrf (p1, p2) | LetPrf (p1, p2) ->
pr_size p1 +/ pr_size p2
| CutPrf p -> pr_size p
| MulC (v, p) -> pr_size p
let rec pr_unit = function
| Annot (_, p) -> pr_unit p
| Zero | Square _ -> true
| Hyp _ -> true
| Def _ -> true
| Cst n -> true
| _ -> false
let rec pr_rule_max_hyp = function
| Annot (_, p) -> pr_rule_max_hyp p
| Hyp i -> i
| Def i -> -1
| Ref i -> -1
| Cst _ | Zero | Square _ -> -1
| MulC (_, p) | CutPrf p | Gcd (_, p) -> pr_rule_max_hyp p
| MulPrf (p1, p2) | AddPrf (p1, p2) | LetPrf (p1, p2) ->
max (pr_rule_max_hyp p1) (pr_rule_max_hyp p2)
let rec pr_rule_max_def = function
| Annot (_, p) -> pr_rule_max_hyp p
| Hyp i -> -1
| Def i -> i
| Ref _ -> -1
| Cst _ | Zero | Square _ -> -1
| MulC (_, p) | CutPrf p | Gcd (_, p) -> pr_rule_max_def p
| MulPrf (p1, p2) | AddPrf (p1, p2) | LetPrf (p1, p2) ->
max (pr_rule_max_def p1) (pr_rule_max_def p2)
let rec proof_max_def = function
| Done -> -1
| Step (i, pr, prf) -> max i (max (pr_rule_max_def pr) (proof_max_def prf))
| Split (i, _, p1, p2) -> max i (max (proof_max_def p1) (proof_max_def p2))
| Enum (i, p1, _, p2, l) -> let m = max (pr_rule_max_def p1) (pr_rule_max_def p2) in List.fold_left (fun i prf -> max i (proof_max_def prf)) (max i m) l
| ExProof (i, j, k, _, _, _, prf) ->
max (max (max i j) k) (proof_max_def prf)
(** [pr_rule_def_cut id pr] gives an explicit [id] to cut rules.
This is because the Rocq proof format only accept they as a proof-step *) let pr_rule_def_cut m id p = let rec pr_rule_def_cut m id = function
| Annot (_, p) -> pr_rule_def_cut m id p
| MulC (p, prf) -> let bds, m, id', prf' = pr_rule_def_cut m id prf in
(bds, m, id', MulC (p, prf'))
| MulPrf (p1, p2) -> let bds1, m, id, p1 = pr_rule_def_cut m id p1 in let bds2, m, id, p2 = pr_rule_def_cut m id p2 in
(bds2 @ bds1, m, id, MulPrf (p1, p2))
| AddPrf (p1, p2) -> let bds1, m, id, p1 = pr_rule_def_cut m id p1 in let bds2, m, id, p2 = pr_rule_def_cut m id p2 in
(bds2 @ bds1, m, id, AddPrf (p1, p2))
| LetPrf (p1, p2) -> let bds1, m, id, p1 = pr_rule_def_cut m id p1 in let bds2, m, id, p2 = pr_rule_def_cut m id p2 in
(bds2 @ bds1, m, id, LetPrf (p1, p2))
| CutPrf p | Gcd (_, p) -> ( let bds, m, id, p = pr_rule_def_cut m id p in try let id' = PrfRuleMap.find p m in
(bds, m, id, Def id') with Not_found -> let m = PrfRuleMap.add p id m in
((id, p) :: bds, m, id + 1, Def id) )
| (Square _ | Cst _ | Def _ | Hyp _ | Ref _ | Zero) as x -> ([], m, id, x) in
pr_rule_def_cut m id p
(* Do not define top-level cuts *) let pr_rule_def_cut m id = function
| CutPrf p -> let bds, m, ids, p' = pr_rule_def_cut m id p in
(bds, m, ids, CutPrf p')
| p -> pr_rule_def_cut m id p
let rec implicit_cut p = match p with CutPrf p -> implicit_cut p | _ -> p
let rec pr_rule_collect_defs pr = match pr with
| Annot (_, pr) -> pr_rule_collect_defs pr
| Def i -> ISet.add i ISet.empty
| Hyp i -> ISet.empty
| Ref i -> ISet.empty
| Cst _ | Zero | Square _ -> ISet.empty
| MulC (_, pr) | Gcd (_, pr) | CutPrf pr -> pr_rule_collect_defs pr
| MulPrf (p1, p2) | AddPrf (p1, p2) | LetPrf (p1, p2) ->
ISet.union (pr_rule_collect_defs p1) (pr_rule_collect_defs p2)
let add_proof x y = match (x, y) with Zero, p | p, Zero -> p | _ -> AddPrf (x, y)
let rec mul_cst_proof c p = match p with
| Annot (s, p) -> Annot (s, mul_cst_proof c p)
| MulC (v, p') -> MulC (Vect.mul c v, p')
| _ -> ( match Q.sign c with
| 0 -> Zero (* This is likely to be a bug *)
| -1 ->
MulC (LinPoly.constant c, p) (* [p] should represent an equality *)
| 1 -> if Q.one =/ c then p else MulPrf (Cst c, p)
| _ -> assert false )
let sMulC v p = let c, v' = Vect.decomp_cst v in if Vect.is_null v' then mul_cst_proof c p else MulC (v, p)
let mul_proof p1 p2 = match (p1, p2) with
| Zero, _ | _, Zero -> Zero
| Cst c, p | p, Cst c -> mul_cst_proof c p
| _, _ -> MulPrf (p1, p2)
let prf_rule_of_map m =
PrfRuleMap.fold (fun k v acc -> add_proof (sMulC v k) acc) m Zero
let rec dev_prf_rule p = match p with
| Annot (s, p) -> dev_prf_rule p
| Hyp _ | Def _ | Ref _ | Cst _ | Zero | Square _ ->
PrfRuleMap.singleton p (LinPoly.constant Q.one)
| MulC (v, p) ->
PrfRuleMap.map (fun v1 -> LinPoly.product v v1) (dev_prf_rule p)
| AddPrf (p1, p2) ->
PrfRuleMap.merge
(fun k o1 o2 -> match (o1, o2) with
| None, None -> None
| None, Some v | Some v, None -> Some v
| Some v1, Some v2 -> Some (LinPoly.addition v1 v2))
(dev_prf_rule p1) (dev_prf_rule p2)
| MulPrf (p1, p2) -> ( let p1' = dev_prf_rule p1 in let p2' = dev_prf_rule p2 in let p1'' = prf_rule_of_map p1' in let p2'' = prf_rule_of_map p2' in match p1''with
| Cst c -> PrfRuleMap.map (fun v1 -> Vect.mul c v1) p2'
| _ -> PrfRuleMap.singleton (MulPrf (p1'', p2'')) (LinPoly.constant Q.one)
)
| Gcd (c, p) ->
PrfRuleMap.singleton
(Gcd (c, prf_rule_of_map (dev_prf_rule p)))
(LinPoly.constant Q.one)
| CutPrf p ->
PrfRuleMap.singleton
(CutPrf (prf_rule_of_map (dev_prf_rule p)))
(LinPoly.constant Q.one)
| LetPrf (p1, p2) -> let p1' = dev_prf_rule p1 in let p2' = dev_prf_rule p2 in let p1'' = prf_rule_of_map p1' in let p2'' = prf_rule_of_map p2' in
PrfRuleMap.singleton (LetPrf (p1'', p2'')) (LinPoly.constant Q.one)
let simplify_prf_rule p = prf_rule_of_map (dev_prf_rule p)
(** [simplify_proof p] removes proof steps that are never re-used. *) let rec simplify_proof p = match p with
| Done -> (Done, ISet.empty)
| Step (i, pr, Done) -> (p, ISet.add i (pr_rule_collect_defs pr))
| Step (i, pr, prf) -> let prf', hyps = simplify_proof prf in ifnot (ISet.mem i hyps) then (prf', hyps) else
( Step (i, pr, prf')
, ISet.add i (ISet.union (pr_rule_collect_defs pr) hyps) )
| Split (i, v, p1, p2) -> let p1, h1 = simplify_proof p1 in let p2, h2 = simplify_proof p2 in ifnot (ISet.mem i h1) then (p1, h1) (* Should not have computed p2 *) elseifnot (ISet.mem i h2) then (p2, h2) else (Split (i, v, p1, p2), ISet.add i (ISet.union h1 h2))
| Enum (i, p1, v, p2, pl) -> let pl, hl = List.split (List.map simplify_proof pl) in let hyps = List.fold_left ISet.union ISet.empty hl in
( Enum (i, p1, v, p2, pl)
, ISet.add i
(ISet.union
(ISet.union (pr_rule_collect_defs p1) (pr_rule_collect_defs p2))
hyps) )
| ExProof (i, j, k, x, z, t, prf) -> let prf', hyps = simplify_proof prf in if
(not (ISet.mem i hyps))
&& (not (ISet.mem j hyps))
&& not (ISet.mem k hyps) then (prf', hyps) else
( ExProof (i, j, k, x, z, t, prf')
, ISet.add i (ISet.add j (ISet.add k hyps)) )
let rec normalise_proof id prf = match prf with
| Done -> (id, Done)
| Step (i, Gcd (c, p), Done) -> normalise_proof id (Step (i, p, Done))
| Step (i, p, prf) -> let bds, m, id, p' =
pr_rule_def_cut PrfRuleMap.empty id (simplify_prf_rule p) in let id, prf = normalise_proof id prf in let prf = List.fold_left
(fun acc (i, p) -> Step (i, CutPrf p, acc))
(Step (i, p', prf))
bds in
(id, prf)
| Split (i, v, p1, p2) -> let id, p1 = normalise_proof id p1 in let id, p2 = normalise_proof id p2 in
(id, Split (i, v, p1, p2))
| ExProof (i, j, k, x, z, t, prf) -> let id, prf = normalise_proof id prf in
(id, ExProof (i, j, k, x, z, t, prf))
| Enum (i, p1, v, p2, pl) -> (* Why do I have top-level cuts ? *) (* let p1 = implicit_cut p1 in let p2 = implicit_cut p2 in let (ids,prfs) = List.split (List.map (normalise_proof id) pl) in (List.fold_left max 0 ids , Enum(i,p1,v,p2,prfs))
*) let bds1, m, id, p1' =
pr_rule_def_cut PrfRuleMap.empty id (implicit_cut p1) in let bds2, m, id, p2' = pr_rule_def_cut m id (implicit_cut p2) in let ids, prfs = List.split (List.map (normalise_proof id) pl) in
( List.fold_left max 0 ids
, List.fold_left
(fun acc (i, p) -> Step (i, CutPrf p, acc))
(Enum (i, p1', v, p2', prfs))
(bds2 @ bds1) )
let normalise_proof id prf = let prf = fst (simplify_proof prf) in let res = normalise_proof id prf in if debug then
Printf.printf "normalise_proof %a -> %a" output_proof prf output_proof
(snd res);
res
(* let mul_proof p1 p2 = let res = mul_proof p1 p2 in Printf.printf "mul_proof %a %a = %a\n" output_prf_rule p1 output_prf_rule p2 output_prf_rule res; res
let add_proof p1 p2 = let res = add_proof p1 p2 in Printf.printf "add_proof %a %a = %a\n" output_prf_rule p1 output_prf_rule p2 output_prf_rule res; res
let sMulC v p = let res = sMulC v p in Printf.printf "sMulC %a %a = %a\n" Vect.pp v output_prf_rule p output_prf_rule res ; res
let mul_cst_proof c p = let res = mul_cst_proof c p in Printf.printf "mul_cst_proof %s %a = %a\n" (Num.string_of_num c) output_prf_rule p output_prf_rule res ; res
*)
let proof_of_farkas env vect =
Vect.fold
(fun prf x n -> add_proof (mul_cst_proof n (IMap.find x env)) prf)
Zero vect
module Env : sig type t val make : int -> t val id_of_def : int -> t -> int val id_of_hyp : int -> t -> int val push_ref : t -> t val push_def : int -> t -> t end = struct
(* Environments are of the form refs @ defs @ hyps *) type t =
{
lref : int;
ndefs : int; (* Size of ldefs *)
ldefs : int Int.Map.t;
nhyps : int;
}
let push_def i { nhyps; ndefs; lref; ldefs } = let () = if lref <> 0 then failwith "Cannot push def"in
{ nhyps; ndefs = ndefs + 1; lref; ldefs = Int.Map.add i ndefs ldefs }
let make n = { nhyps = n; ndefs = 0; lref = 0; ldefs = Int.Map.empty }
let id_of_def def { nhyps; ndefs; lref; ldefs } = try let pos = Int.Map.find def ldefs in
lref + (ndefs - pos - 1) with Not_found -> failwith "Cannot find def"
let id_of_hyp h { nhyps; ndefs; lref; ldefs } = if 0 <= h && h < nhyps then lref + ndefs + h else failwith "Cannot find hyp"
end
let cmpl_prf_rule norm (cst : Q.t -> 'a) env prf = let rec cmpl env = function
| Annot (s, p) -> cmpl env p
| Ref i -> Mc.PsatzIn (CamlToCoq.nat i)
| Hyp h -> Mc.PsatzIn (CamlToCoq.nat (Env.id_of_hyp h env))
| Def d -> Mc.PsatzIn (CamlToCoq.nat (Env.id_of_def d env))
| Cst i -> Mc.PsatzC (cst i)
| Zero -> Mc.PsatzZ
| MulPrf (p1, p2) -> Mc.PsatzMulE (cmpl env p1, cmpl env p2)
| AddPrf (p1, p2) -> Mc.PsatzAdd (cmpl env p1, cmpl env p2)
| LetPrf (p1, p2) -> Mc.PsatzLet (cmpl env p1, cmpl (Env.push_ref env) p2)
| MulC (lp, p) -> let lp = norm (LinPoly.rocq_poly_of_linpol cst lp) in
Mc.PsatzMulC (lp, cmpl env p)
| Square lp -> Mc.PsatzSquare (norm (LinPoly.rocq_poly_of_linpol cst lp))
| _ -> failwith "Cuts should already be compiled" in
cmpl env prf
let cmpl_prf_rule_z env r =
cmpl_prf_rule Mc.normZ (fun x -> CamlToCoq.bigint (Q.num x)) env r
let cmpl_pol_z lp = try let cst x = CamlToCoq.bigint (Q.num x) in
Mc.normZ (LinPoly.rocq_poly_of_linpol cst lp) with x ->
Printf.printf "cmpl_pol_z %s %a\n" (Printexc.to_string x) LinPoly.pp lp; raise x
let rec cmpl_proof env prf = match prf with
| Done -> Mc.DoneProof
| Step (i, p, prf) -> ( match p with
| CutPrf p' ->
Mc.CutProof (cmpl_prf_rule_z env p', cmpl_proof (Env.push_def i env) prf)
| _ -> Mc.RatProof (cmpl_prf_rule_z env p, cmpl_proof (Env.push_def i env) prf)
)
| Split (i, v, p1, p2) ->
Mc.SplitProof
( cmpl_pol_z v
, cmpl_proof (Env.push_def i env) p1
, cmpl_proof (Env.push_def i env) p2 )
| Enum (i, p1, _, p2, l) ->
Mc.EnumProof
( cmpl_prf_rule_z env p1
, cmpl_prf_rule_z env p2
, List.map (cmpl_proof (Env.push_def i env)) l )
| ExProof (i, j, k, x, _, _, prf) ->
Mc.ExProof
(CamlToCoq.positive x, cmpl_proof (Env.push_def i (Env.push_def j (Env.push_def k env))) prf)
let compile_proof env prf = let id = 1 + proof_max_def prf in let _, prf = normalise_proof id prf in
cmpl_proof env prf
end
module WithProof = struct type t = (LinPoly.t * op) * ProofFormat.prf_rule
let repr p = p
let proof p = snd p
let polynomial ((p, _), _) = p
(* The comparison ignores proofs on purpose *) let compare : t -> t -> int = fun ((lp1, o1), _) ((lp2, o2), _) -> let c = Vect.compare lp1 lp2 in if c = 0 then compare_op o1 o2 else c
let annot s (p, prf) = (p, ProofFormat.Annot (s, prf))
let output o ((lp, op), prf) =
Printf.fprintf o "%a %s 0 by %a\n" LinPoly.pp lp (string_of_op op)
ProofFormat.output_prf_rule prf
let output_sys o l = List.iter (Printf.fprintf o "%a\n" output) l
exception InvalidProof
let zero = ((Vect.null, Eq), ProofFormat.Zero) letconst n = ((LinPoly.constant n, Ge), ProofFormat.Cst n) let of_cstr (c, prf) = ((Vect.set 0 (Q.neg c.cst) c.coeffs, c.op), prf)
let product : t -> t -> t = fun ((p1, o1), prf1) ((p2, o2), prf2) ->
((LinPoly.product p1 p2, opMult o1 o2), ProofFormat.mul_proof prf1 prf2)
let addition : t -> t -> t = fun ((p1, o1), prf1) ((p2, o2), prf2) ->
((Vect.add p1 p2, opAdd o1 o2), ProofFormat.add_proof prf1 prf2)
let neg : t -> t = fun ((p1, o1), prf1) -> match o1 with
| Eq ->
((Vect.mul Q.minus_one p1, o1), ProofFormat.mul_cst_proof Q.minus_one prf1)
| _ -> failwith "neg: invalid proof"
let mul_cst c ((p1, o1), prf1) = let () = match o1 with
| Eq -> ()
| Gt | Ge -> assert (c >/ Q.zero) in let p = LinPoly.mul_cst c p1 in let prf = ProofFormat.mul_cst_proof c prf1 in
((p, o1), prf)
let mult p ((p1, o1), prf1) = match o1 with
| Eq -> ((LinPoly.product p p1, o1), ProofFormat.sMulC p prf1)
| Gt | Ge -> let n, r = Vect.decomp_cst p in if Vect.is_null r && n >/ Q.zero then
((LinPoly.product p p1, o1), ProofFormat.mul_cst_proof n prf1) else ( if debug then
Printf.printf "mult_error %a [*] %a\n" LinPoly.pp p output
((p1, o1), prf1); raise InvalidProof )
let def p op i = ((p, op), ProofFormat.Def i)
let mkhyp p op i = ((p, op), ProofFormat.Hyp i)
let square p q = ((p, Ge), ProofFormat.Square q)
let cutting_plane ((p, o), prf) = let c, p' = Vect.decomp_cst p in let g = Vect.gcd p' in if Z.equal Z.one g || c =/ Q.zero || not (Z.equal (Q.den c) Z.one) then None (* Nothing to do *) else let c1 = c // Q.of_bigint g in let c1' = Q.floor c1 in if c1 =/ c1' then None else match o with
| Eq ->
Some ((Vect.set 0 Q.minus_one Vect.null, Eq), ProofFormat.CutPrf prf)
| Gt -> failwith "cutting_plane ignore strict constraints"
| Ge -> (* This is a non-trivial common divisor *)
Some
( (Vect.set 0 c1' (Vect.div (Q.of_bigint g) p), o)
, ProofFormat.CutPrf prf )
let construct_sign p = let c, p' = Vect.decomp_cst p in if Vect.is_null p' then
Some
( match Q.sign c with
| 0 -> (true, Eq, ProofFormat.Zero)
| 1 -> (true, Gt, ProofFormat.Cst c)
| _ (*-1*) -> (false, Gt, ProofFormat.Cst (Q.neg c)) ) else None
let get_sign l p = match construct_sign p with
| None -> ( try let (p', o), prf = List.find (fun ((p', o), prf) -> Vect.equal p p') l in
Some (true, o, prf) with Not_found -> ( let p = Vect.uminus p in try let (p', o), prf = List.find (fun ((p', o), prf) -> Vect.equal p p') l in
Some (false, o, prf) with Not_found -> None ) )
| Some s -> Some s
let mult_sign : bool -> t -> t = fun b ((p, o), prf) -> if b then ((p, o), prf) else ((Vect.uminus p, o), prf)
let rec linear_pivot sys ((lp1, op1), prf1) x ((lp2, op2), prf2) = (* lp1 = a1.x + b1 *) let a1, b1 = LinPoly.factorise x lp1 in (* lp2 = a2.x + b2 *) let a2, b2 = LinPoly.factorise x lp2 in if Vect.is_null a2 then(* We are done *)
Some ((lp2, op2), prf2) else match (op1, op2) with
| Eq, (Ge | Gt) -> ( match get_sign sys a1 with
| None -> None (* Impossible to pivot without sign information *)
| Some (b, o, prf) -> let sa1 = mult_sign b ((a1, o), prf) in let sa2 = if b then Vect.uminus a2 else a2 in let (lp2, op2), prf2 =
addition
(product sa1 ((lp2, op2), prf2))
(mult sa2 ((lp1, op1), prf1)) in
linear_pivot sys ((lp1, op1), prf1) x ((lp2, op2), prf2) )
| Eq, Eq -> let (lp2, op2), prf2 =
addition
(mult a1 ((lp2, op2), prf2))
(mult (Vect.uminus a2) ((lp1, op1), prf1)) in
linear_pivot sys ((lp1, op1), prf1) x ((lp2, op2), prf2)
| (Ge | Gt), (Ge | Gt) -> ( match (get_sign sys a1, get_sign sys a2) with
| Some (b1, o1, p1), Some (b2, o2, p2) -> if b1 <> b2 then let (lp2, op2), prf2 =
addition
(product (mult_sign b1 ((a1, o1), p1)) ((lp2, op2), prf2))
(product (mult_sign b2 ((a2, o2), p2)) ((lp1, op1), prf1)) in
linear_pivot sys ((lp1, op1), prf1) x ((lp2, op2), prf2) else None
| _ -> None )
| (Ge | Gt), Eq -> failwith "pivot: equality as second argument"
let linear_pivot sys ((lp1, op1), prf1) x ((lp2, op2), prf2) = match linear_pivot sys ((lp1, op1), prf1) x ((lp2, op2), prf2) with
| None -> None
| Some (c, p) -> Some (c, ProofFormat.simplify_prf_rule p)
let is_substitution strict ((p, o), prf) = let pred v = if strict then v =/ Q.one || v =/ Q.minus_one elsetruein match o with Eq -> LinPoly.search_linear pred p | _ -> None
let sort (sys : t list) = letsize ((p, o), prf) = let _, p' = Vect.decomp_cst p in let (x, q), p' = Vect.decomp_fst p'in
Vect.fold
(fun (l, (q, x)) x' q' -> let q' = Q.abs q'in
(l + 1, if q </ q then (q, x) else (q', x')))
(1, (Q.abs q, x))
p in let cmp ((l1, (q1, _)), ((_, o), _)) ((l2, (q2, _)), ((_, o'), _)) = if l1 < l2 then -1 elseif l1 = l2 then Q.compare q1 q2 else 1 in List.sort cmp (List.rev_map (fun wp -> (size wp, wp)) sys)
let iterate_pivot p sys0 = let elim sys = let oeq, sys' = extract p sys in match oeq with
| None -> None
| Some (v, pc) -> simplify (linear_pivot sys0 pc v) sys' in
iterate_until_stable elim (List.map snd (sort sys0))
let subst_constant is_int sys = let is_integer q = Q.(q =/ floor q) in let is_constant ((c, o), p) = match o with
| Ge | Gt -> None
| Eq -> (
Vect.Bound.( match of_vect c with
| None -> None
| Some b -> if (not is_int) || is_integer (b.cst // b.coeff) then
Monomial.get_var (LinPoly.MonT.retrieve b.var) else None) ) in
iterate_pivot is_constant sys
let subst sys0 = iterate_pivot (is_substitution true) sys0
let saturate_subst b sys0 = let select = is_substitution b in let gen (v, pc) ((c, op), prf) = if ISet.mem v (LinPoly.variables c) then
linear_pivot sys0 pc v ((c, op), prf) else None in
saturate select gen sys0
let simple_pivot (q1, x) ((v1, o1), prf1) ((v2, o2), prf2) = let q2 = Vect.get x v2 in if q2 =/ Q.zero then None else let cv1, cv2 = if Q.sign q1 <> Q.sign q2 then (Q.abs q2, Q.abs q1) else match (o1, o2) with
| Eq, _ -> (q2, Q.abs q1)
| _, Eq -> (Q.abs q2, q2)
| _, _ -> (Q.zero, Q.zero) in if cv2 =/ Q.zero then None else
Some
( (Vect.mul_add cv1 v1 cv2 v2, opAdd o1 o2)
, ProofFormat.add_proof
(ProofFormat.mul_cst_proof cv1 prf1)
(ProofFormat.mul_cst_proof cv2 prf2) )
end
module BoundWithProof = struct
type t = Vect.Bound.t * op * ProofFormat.prf_rule
let make ((p, o), prf) = match Vect.Bound.of_vect p with
| None -> None
| Some b -> Some (b, o, prf)
let plet (o1,p1) (o2,p2) f = match ProofFormat.pr_unit p1 , ProofFormat.pr_unit p2 with
| true , true -> f (o1,p1) (o2,p2)
| false , false -> let (o,prf) = f (o1,ProofFormat.Ref 1) (o2,ProofFormat.Ref 0) in
(o, ProofFormat.LetPrf(p1,ProofFormat.LetPrf(p2,prf)))
| true , false -> let (o,prf) = f (o1,p1) (o2,ProofFormat.Ref 0) in
(o, ProofFormat.LetPrf(p2,prf))
| false , true -> let (o,prf) = f (o1,ProofFormat.Ref 0) (o2,p2) in
(o,ProofFormat.LetPrf(p1,prf))
let pext c (o, prf) = if c =/ Q.zero then (Eq, ProofFormat.Zero) else (o, ProofFormat.mul_cst_proof c prf)
let mul_bound (b1, o1, prf1) (b2, o2, prf2) = letopen Vect.Bound in match (b1, b2) with
| {cst = c1; var = v1; coeff = c1'},
{cst = c2; var = v2; coeff = c2'} -> let good_coeff b o = match o with
| Eq -> Some (Q.neg b)
| _ -> if b <=/ Q.zero then Some (Q.neg b) else None in match (good_coeff c1 o2, good_coeff c2 o1) with
| None, _ | _, None -> None
| Some c1, Some c2 -> let w1 = (o1, prf1) in let w2 = (o2, prf2) in let (o, prf) = plet w1 w2 (fun w1 w2 -> padd (padd (pmul w1 w2) (pext c1 w2)) (pext c2 w1)) in let b = {
cst = Q.neg (c1 */ c2);
var = LinPoly.MonT.register (Monomial.prod (LinPoly.MonT.retrieve v1) (LinPoly.MonT.retrieve v2));
coeff = c1' */ c2';
} in
Some (b, o, prf)
let bound (b, _, _) = b
let proof (b, o, w) = let p = Vect.Bound.to_vect b in
((p, o), w) end
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