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|
(************************************************************************)
(* * The Coq Proof Assistant / The Coq Development Team *)
(* v * INRIA, CNRS and contributors - Copyright 1999-2018 *)
(* <O___,, * (see CREDITS file for the list of authors) *)
(* \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) *)
(************************************************************************)
open CErrors
open Util
open Names
open Constr
open Context
open Evd
module API :
sig
module ESorts :
sig
type t
val make : Sorts.t -> t
val kind : Evd.evar_map -> t -> Sorts.t
val unsafe_to_sorts : t -> Sorts.t
end
module EInstance :
sig
type t
val make : Univ.Instance.t -> t
val kind : Evd.evar_map -> t -> Univ.Instance.t
val empty : t
val is_empty : t -> bool
val unsafe_to_instance : t -> Univ.Instance.t
end
type t
val kind : Evd.evar_map -> t -> (t, t, ESorts.t, EInstance.t) Constr.kind_of_term
val kind_upto : Evd.evar_map -> constr -> (constr, types, Sorts.t, Univ.Instance.t) Constr.kind_of_term
val kind_of_type : Evd.evar_map -> t -> (t, t) Term.kind_of_type
val whd_evar : Evd.evar_map -> t -> t
val of_kind : (t, t, ESorts.t, EInstance.t) Constr.kind_of_term -> t
val of_constr : Constr.t -> t
val to_constr : evar_map -> t -> Constr.t
val unsafe_to_constr : t -> Constr.t
val unsafe_eq : (t, Constr.t) eq
val of_named_decl : (Constr.t, Constr.types) Context.Named.Declaration.pt -> (t, t) Context.Named.Declaration.pt
val unsafe_to_named_decl : (t, t) Context.Named.Declaration.pt -> (Constr.t, Constr.types) Context.Named.Declaration.pt
val unsafe_to_rel_decl : (t, t) Context.Rel.Declaration.pt -> (Constr.t, Constr.types) Context.Rel.Declaration.pt
val of_rel_decl : (Constr.t, Constr.types) Context.Rel.Declaration.pt -> (t, t) Context.Rel.Declaration.pt
val to_rel_decl : Evd.evar_map -> (t, t) Context.Rel.Declaration.pt -> (Constr.t, Constr.types) Context.Rel.Declaration.pt
end =
struct
module ESorts =
struct
type t = Sorts.t
let make s = s
let kind sigma = function
| Sorts.Type u -> Sorts.sort_of_univ (Evd.normalize_universe sigma u)
| s -> s
let unsafe_to_sorts s = s
end
module EInstance =
struct
type t = Univ.Instance.t
let make i = i
let kind sigma i =
if Univ.Instance.is_empty i then i
else Evd.normalize_universe_instance sigma i
let empty = Univ.Instance.empty
let is_empty = Univ.Instance.is_empty
let unsafe_to_instance t = t
end
type t = Constr.t
let safe_evar_value sigma ev =
try Some (Evd.existential_value sigma ev)
with NotInstantiatedEvar | Not_found -> None
let rec whd_evar sigma c =
match Constr.kind c with
| Evar ev ->
begin match safe_evar_value sigma ev with
| Some c -> whd_evar sigma c
| None -> c
end
| App (f, args) when isEvar f ->
(** Enforce smart constructor invariant on applications *)
let ev = destEvar f in
begin match safe_evar_value sigma ev with
| None -> c
| Some f -> whd_evar sigma (mkApp (f, args))
end
| Cast (c0, k, t) when isEvar c0 ->
(** Enforce smart constructor invariant on casts. *)
let ev = destEvar c0 in
begin match safe_evar_value sigma ev with
| None -> c
| Some c -> whd_evar sigma (mkCast (c, k, t))
end
| _ -> c
let kind sigma c = Constr.kind (whd_evar sigma c)
let kind_upto = kind
let kind_of_type sigma c = Term.kind_of_type (whd_evar sigma c)
let of_kind = Constr.of_kind
let of_constr c = c
let unsafe_to_constr c = c
let unsafe_eq = Refl
let rec to_constr sigma c = match Constr.kind c with
| Evar ev ->
begin match safe_evar_value sigma ev with
| Some c -> to_constr sigma c
| None -> Constr.map (fun c -> to_constr sigma c) c
end
| Sort (Sorts.Type u) ->
let u' = Evd.normalize_universe sigma u in
if u' == u then c else mkSort (Sorts.sort_of_univ u')
| Const (c', u) when not (Univ.Instance.is_empty u) ->
let u' = Evd.normalize_universe_instance sigma u in
if u' == u then c else mkConstU (c', u')
| Ind (i, u) when not (Univ.Instance.is_empty u) ->
let u' = Evd.normalize_universe_instance sigma u in
if u' == u then c else mkIndU (i, u')
| Construct (co, u) when not (Univ.Instance.is_empty u) ->
let u' = Evd.normalize_universe_instance sigma u in
if u' == u then c else mkConstructU (co, u')
| _ -> Constr.map (fun c -> to_constr sigma c) c
let of_named_decl d = d
let unsafe_to_named_decl d = d
let of_rel_decl d = d
let unsafe_to_rel_decl d = d
let to_rel_decl sigma d = Context.Rel.Declaration.map_constr (to_constr sigma) d
end
include API
type types = t
type constr = t
type existential = t pexistential
type fixpoint = (t, t) pfixpoint
type cofixpoint = (t, t) pcofixpoint
type unsafe_judgment = (constr, types) Environ.punsafe_judgment
type unsafe_type_judgment = types Environ.punsafe_type_judgment
type named_declaration = (constr, types) Context.Named.Declaration.pt
type rel_declaration = (constr, types) Context.Rel.Declaration.pt
type named_context = (constr, types) Context.Named.pt
type rel_context = (constr, types) Context.Rel.pt
type 'a puniverses = 'a * EInstance.t
let in_punivs a = (a, EInstance.empty)
let mkProp = of_kind (Sort (ESorts.make Sorts.prop))
let mkSet = of_kind (Sort (ESorts.make Sorts.set))
let mkType u = of_kind (Sort (ESorts.make (Sorts.Type u)))
let mkRel n = of_kind (Rel n)
let mkVar id = of_kind (Var id)
let mkMeta n = of_kind (Meta n)
let mkEvar e = of_kind (Evar e)
let mkSort s = of_kind (Sort (ESorts.make s))
let mkCast (b, k, t) = of_kind (Cast (b, k, t))
let mkProd (na, t, u) = of_kind (Prod (na, t, u))
let mkLambda (na, t, c) = of_kind (Lambda (na, t, c))
let mkLetIn (na, b, t, c) = of_kind (LetIn (na, b, t, c))
let mkApp (f, arg) = of_kind (App (f, arg))
let mkConstU pc = of_kind (Const pc)
let mkConst c = of_kind (Const (in_punivs c))
let mkIndU pi = of_kind (Ind pi)
let mkInd i = of_kind (Ind (in_punivs i))
let mkConstructU pc = of_kind (Construct pc)
let mkConstruct c = of_kind (Construct (in_punivs c))
let mkConstructUi ((ind,u),i) = of_kind (Construct ((ind,i),u))
let mkCase (ci, c, r, p) = of_kind (Case (ci, c, r, p))
let mkFix f = of_kind (Fix f)
let mkCoFix f = of_kind (CoFix f)
let mkProj (p, c) = of_kind (Proj (p, c))
let mkArrow t1 t2 = of_kind (Prod (Anonymous, t1, t2))
let applist (f, arg) = mkApp (f, Array.of_list arg)
let isRel sigma c = match kind sigma c with Rel _ -> true | _ -> false
let isVar sigma c = match kind sigma c with Var _ -> true | _ -> false
let isInd sigma c = match kind sigma c with Ind _ -> true | _ -> false
let isEvar sigma c = match kind sigma c with Evar _ -> true | _ -> false
let isMeta sigma c = match kind sigma c with Meta _ -> true | _ -> false
let isSort sigma c = match kind sigma c with Sort _ -> true | _ -> false
let isCast sigma c = match kind sigma c with Cast _ -> true | _ -> false
let isApp sigma c = match kind sigma c with App _ -> true | _ -> false
let isLambda sigma c = match kind sigma c with Lambda _ -> true | _ -> false
let isLetIn sigma c = match kind sigma c with LetIn _ -> true | _ -> false
let isProd sigma c = match kind sigma c with Prod _ -> true | _ -> false
let isConst sigma c = match kind sigma c with Const _ -> true | _ -> false
let isConstruct sigma c = match kind sigma c with Construct _ -> true | _ -> false
let isFix sigma c = match kind sigma c with Fix _ -> true | _ -> false
let isCoFix sigma c = match kind sigma c with CoFix _ -> true | _ -> false
let isCase sigma c = match kind sigma c with Case _ -> true | _ -> false
let isProj sigma c = match kind sigma c with Proj _ -> true | _ -> false
let isVarId sigma id c =
match kind sigma c with Var id' -> Id.equal id id' | _ -> false
let isRelN sigma n c =
match kind sigma c with Rel n' -> Int.equal n n' | _ -> false
let destRel sigma c = match kind sigma c with
| Rel p -> p
| _ -> raise DestKO
let destVar sigma c = match kind sigma c with
| Var p -> p
| _ -> raise DestKO
let destInd sigma c = match kind sigma c with
| Ind p -> p
| _ -> raise DestKO
let destEvar sigma c = match kind sigma c with
| Evar p -> p
| _ -> raise DestKO
let destMeta sigma c = match kind sigma c with
| Meta p -> p
| _ -> raise DestKO
let destSort sigma c = match kind sigma c with
| Sort p -> p
| _ -> raise DestKO
let destCast sigma c = match kind sigma c with
| Cast (c, k, t) -> (c, k, t)
| _ -> raise DestKO
let destApp sigma c = match kind sigma c with
| App (f, a) -> (f, a)
| _ -> raise DestKO
let destLambda sigma c = match kind sigma c with
| Lambda (na, t, c) -> (na, t, c)
| _ -> raise DestKO
let destLetIn sigma c = match kind sigma c with
| LetIn (na, b, t, c) -> (na, b, t, c)
| _ -> raise DestKO
let destProd sigma c = match kind sigma c with
| Prod (na, t, c) -> (na, t, c)
| _ -> raise DestKO
let destConst sigma c = match kind sigma c with
| Const p -> p
| _ -> raise DestKO
let destConstruct sigma c = match kind sigma c with
| Construct p -> p
| _ -> raise DestKO
let destFix sigma c = match kind sigma c with
| Fix p -> p
| _ -> raise DestKO
let destCoFix sigma c = match kind sigma c with
| CoFix p -> p
| _ -> raise DestKO
let destCase sigma c = match kind sigma c with
| Case (ci, t, c, p) -> (ci, t, c, p)
| _ -> raise DestKO
let destProj sigma c = match kind sigma c with
| Proj (p, c) -> (p, c)
| _ -> raise DestKO
let decompose_app sigma c =
match kind sigma c with
| App (f,cl) -> (f, Array.to_list cl)
| _ -> (c,[])
let decompose_lam sigma c =
let rec lamdec_rec l c = match kind sigma c with
| Lambda (x,t,c) -> lamdec_rec ((x,t)::l) c
| Cast (c,_,_) -> lamdec_rec l c
| _ -> l,c
in
lamdec_rec [] c
let decompose_lam_assum sigma c =
let open Rel.Declaration in
let rec lamdec_rec l c =
match kind sigma c with
| Lambda (x,t,c) -> lamdec_rec (Context.Rel.add (LocalAssum (x,t)) l) c
| LetIn (x,b,t,c) -> lamdec_rec (Context.Rel.add (LocalDef (x,b,t)) l) c
| Cast (c,_,_) -> lamdec_rec l c
| _ -> l,c
in
lamdec_rec Context.Rel.empty c
let decompose_lam_n_assum sigma n c =
let open Rel.Declaration in
if n < 0 then
user_err Pp.(str "decompose_lam_n_assum: integer parameter must be positive");
let rec lamdec_rec l n c =
if Int.equal n 0 then l,c
else
match kind sigma c with
| Lambda (x,t,c) -> lamdec_rec (Context.Rel.add (LocalAssum (x,t)) l) (n-1) c
| LetIn (x,b,t,c) -> lamdec_rec (Context.Rel.add (LocalDef (x,b,t)) l) n c
| Cast (c,_,_) -> lamdec_rec l n c
| c -> user_err Pp.(str "decompose_lam_n_assum: not enough abstractions")
in
lamdec_rec Context.Rel.empty n c
let decompose_lam_n_decls sigma n =
let open Rel.Declaration in
if n < 0 then
user_err Pp.(str "decompose_lam_n_decls: integer parameter must be positive");
let rec lamdec_rec l n c =
if Int.equal n 0 then l,c
else
match kind sigma c with
| Lambda (x,t,c) -> lamdec_rec (Context.Rel.add (LocalAssum (x,t)) l) (n-1) c
| LetIn (x,b,t,c) -> lamdec_rec (Context.Rel.add (LocalDef (x,b,t)) l) (n-1) c
| Cast (c,_,_) -> lamdec_rec l n c
| c -> user_err Pp.(str "decompose_lam_n_decls: not enough abstractions")
in
lamdec_rec Context.Rel.empty n
let lamn n env b =
let rec lamrec = function
| (0, env, b) -> b
| (n, ((v,t)::l), b) -> lamrec (n-1, l, mkLambda (v,t,b))
| _ -> assert false
in
lamrec (n,env,b)
let compose_lam l b = lamn (List.length l) l b
let rec to_lambda sigma n prod =
if Int.equal n 0 then
prod
else
match kind sigma prod with
| Prod (na,ty,bd) -> mkLambda (na,ty,to_lambda sigma (n-1) bd)
| Cast (c,_,_) -> to_lambda sigma n c
| _ -> user_err ~hdr:"to_lambda" (Pp.mt ())
let decompose_prod sigma c =
let rec proddec_rec l c = match kind sigma c with
| Prod (x,t,c) -> proddec_rec ((x,t)::l) c
| Cast (c,_,_) -> proddec_rec l c
| _ -> l,c
in
proddec_rec [] c
let decompose_prod_assum sigma c =
let open Rel.Declaration in
let rec proddec_rec l c =
match kind sigma c with
| Prod (x,t,c) -> proddec_rec (Context.Rel.add (LocalAssum (x,t)) l) c
| LetIn (x,b,t,c) -> proddec_rec (Context.Rel.add (LocalDef (x,b,t)) l) c
| Cast (c,_,_) -> proddec_rec l c
| _ -> l,c
in
proddec_rec Context.Rel.empty c
let decompose_prod_n_assum sigma n c =
let open Rel.Declaration in
if n < 0 then
user_err Pp.(str "decompose_prod_n_assum: integer parameter must be positive");
let rec prodec_rec l n c =
if Int.equal n 0 then l,c
else
match kind sigma c with
| Prod (x,t,c) -> prodec_rec (Context.Rel.add (LocalAssum (x,t)) l) (n-1) c
| LetIn (x,b,t,c) -> prodec_rec (Context.Rel.add (LocalDef (x,b,t)) l) (n-1) c
| Cast (c,_,_) -> prodec_rec l n c
| c -> user_err Pp.(str "decompose_prod_n_assum: not enough assumptions")
in
prodec_rec Context.Rel.empty n c
let existential_type sigma (evk, args) =
of_constr (existential_type sigma (evk, Array.map unsafe_to_constr args))
let map sigma f c = match kind sigma c with
| (Rel _ | Meta _ | Var _ | Sort _ | Const _ | Ind _
| Construct _) -> c
| Cast (b,k,t) ->
let b' = f b in
let t' = f t in
if b'==b && t' == t then c
else mkCast (b', k, t')
| Prod (na,t,b) ->
let b' = f b in
let t' = f t in
if b'==b && t' == t then c
else mkProd (na, t', b')
| Lambda (na,t,b) ->
let b' = f b in
let t' = f t in
if b'==b && t' == t then c
else mkLambda (na, t', b')
| LetIn (na,b,t,k) ->
let b' = f b in
let t' = f t in
let k' = f k in
if b'==b && t' == t && k'==k then c
else mkLetIn (na, b', t', k')
| App (b,l) ->
let b' = f b in
let l' = Array.smartmap f l in
if b'==b && l'==l then c
else mkApp (b', l')
| Proj (p,t) ->
let t' = f t in
if t' == t then c
else mkProj (p, t')
| Evar (e,l) ->
let l' = Array.smartmap f l in
if l'==l then c
else mkEvar (e, l')
| Case (ci,p,b,bl) ->
let b' = f b in
let p' = f p in
let bl' = Array.smartmap f bl in
if b'==b && p'==p && bl'==bl then c
else mkCase (ci, p', b', bl')
| Fix (ln,(lna,tl,bl)) ->
let tl' = Array.smartmap f tl in
let bl' = Array.smartmap f bl in
if tl'==tl && bl'==bl then c
else mkFix (ln,(lna,tl',bl'))
| CoFix(ln,(lna,tl,bl)) ->
let tl' = Array.smartmap f tl in
let bl' = Array.smartmap f bl in
if tl'==tl && bl'==bl then c
else mkCoFix (ln,(lna,tl',bl'))
let map_with_binders sigma g f l c0 = match kind sigma c0 with
| (Rel _ | Meta _ | Var _ | Sort _ | Const _ | Ind _
| Construct _) -> c0
| Cast (c, k, t) ->
let c' = f l c in
let t' = f l t in
if c' == c && t' == t then c0
else mkCast (c', k, t')
| Prod (na, t, c) ->
let t' = f l t in
let c' = f (g l) c in
if t' == t && c' == c then c0
else mkProd (na, t', c')
| Lambda (na, t, c) ->
let t' = f l t in
let c' = f (g l) c in
if t' == t && c' == c then c0
else mkLambda (na, t', c')
| LetIn (na, b, t, c) ->
let b' = f l b in
let t' = f l t in
let c' = f (g l) c in
if b' == b && t' == t && c' == c then c0
else mkLetIn (na, b', t', c')
| App (c, al) ->
let c' = f l c in
let al' = CArray.Fun1.smartmap f l al in
if c' == c && al' == al then c0
else mkApp (c', al')
| Proj (p, t) ->
let t' = f l t in
if t' == t then c0
else mkProj (p, t')
| Evar (e, al) ->
let al' = CArray.Fun1.smartmap f l al in
if al' == al then c0
else mkEvar (e, al')
| Case (ci, p, c, bl) ->
let p' = f l p in
let c' = f l c in
let bl' = CArray.Fun1.smartmap f l bl in
if p' == p && c' == c && bl' == bl then c0
else mkCase (ci, p', c', bl')
| Fix (ln, (lna, tl, bl)) ->
let tl' = CArray.Fun1.smartmap f l tl in
let l' = iterate g (Array.length tl) l in
let bl' = CArray.Fun1.smartmap f l' bl in
if tl' == tl && bl' == bl then c0
else mkFix (ln,(lna,tl',bl'))
| CoFix(ln,(lna,tl,bl)) ->
let tl' = CArray.Fun1.smartmap f l tl in
let l' = iterate g (Array.length tl) l in
let bl' = CArray.Fun1.smartmap f l' bl in
mkCoFix (ln,(lna,tl',bl'))
let iter sigma f c = match kind sigma c with
| (Rel _ | Meta _ | Var _ | Sort _ | Const _ | Ind _
| Construct _) -> ()
| Cast (c,_,t) -> f c; f t
| Prod (_,t,c) -> f t; f c
| Lambda (_,t,c) -> f t; f c
| LetIn (_,b,t,c) -> f b; f t; f c
| App (c,l) -> f c; Array.iter f l
| Proj (p,c) -> f c
| Evar (_,l) -> Array.iter f l
| Case (_,p,c,bl) -> f p; f c; Array.iter f bl
| Fix (_,(_,tl,bl)) -> Array.iter f tl; Array.iter f bl
| CoFix (_,(_,tl,bl)) -> Array.iter f tl; Array.iter f bl
let iter_with_full_binders sigma g f n c =
let open Context.Rel.Declaration in
match kind sigma c with
| (Rel _ | Meta _ | Var _ | Sort _ | Const _ | Ind _
| Construct _) -> ()
| Cast (c,_,t) -> f n c; f n t
| Prod (na,t,c) -> f n t; f (g (LocalAssum (na, t)) n) c
| Lambda (na,t,c) -> f n t; f (g (LocalAssum (na, t)) n) c
| LetIn (na,b,t,c) -> f n b; f n t; f (g (LocalDef (na, b, t)) n) c
| App (c,l) -> f n c; CArray.Fun1.iter f n l
| Evar (_,l) -> CArray.Fun1.iter f n l
| Case (_,p,c,bl) -> f n p; f n c; CArray.Fun1.iter f n bl
| Proj (p,c) -> f n c
| Fix (_,(lna,tl,bl)) ->
Array.iter (f n) tl;
let n' = Array.fold_left2 (fun n na t -> g (LocalAssum (na,t)) n) n lna tl in
Array.iter (f n') bl
| CoFix (_,(lna,tl,bl)) ->
Array.iter (f n) tl;
let n' = Array.fold_left2 (fun n na t -> g (LocalAssum (na,t)) n) n lna tl in
Array.iter (f n') bl
let iter_with_binders sigma g f n c =
iter_with_full_binders sigma (fun _ acc -> g acc) f n c
let fold sigma f acc c = match kind sigma c with
| (Rel _ | Meta _ | Var _ | Sort _ | Const _ | Ind _
| Construct _) -> acc
| Cast (c,_,t) -> f (f acc c) t
| Prod (_,t,c) -> f (f acc t) c
| Lambda (_,t,c) -> f (f acc t) c
| LetIn (_,b,t,c) -> f (f (f acc b) t) c
| App (c,l) -> Array.fold_left f (f acc c) l
| Proj (p,c) -> f acc c
| Evar (_,l) -> Array.fold_left f acc l
| Case (_,p,c,bl) -> Array.fold_left f (f (f acc p) c) bl
| Fix (_,(lna,tl,bl)) ->
Array.fold_left2 (fun acc t b -> f (f acc t) b) acc tl bl
| CoFix (_,(lna,tl,bl)) ->
Array.fold_left2 (fun acc t b -> f (f acc t) b) acc tl bl
let compare_gen k eq_inst eq_sort eq_constr nargs c1 c2 =
(c1 == c2) || Constr.compare_head_gen_with k k eq_inst eq_sort eq_constr nargs c1 c2
let eq_constr sigma c1 c2 =
let kind c = kind_upto sigma c in
let rec eq_constr nargs c1 c2 =
compare_gen kind (fun _ _ -> Univ.Instance.equal) Sorts.equal eq_constr nargs c1 c2
in
eq_constr 0 (unsafe_to_constr c1) (unsafe_to_constr c2)
let eq_constr_nounivs sigma c1 c2 =
let kind c = kind_upto sigma c in
let rec eq_constr nargs c1 c2 =
compare_gen kind (fun _ _ _ _ -> true) (fun _ _ -> true) eq_constr nargs c1 c2
in
eq_constr 0 (unsafe_to_constr c1) (unsafe_to_constr c2)
let compare_constr sigma cmp c1 c2 =
let kind c = kind_upto sigma c in
let cmp nargs c1 c2 = cmp (of_constr c1) (of_constr c2) in
compare_gen kind (fun _ _ -> Univ.Instance.equal) Sorts.equal cmp 0 (unsafe_to_constr c1) (unsafe_to_constr c2)
let compare_cumulative_instances cv_pb nargs_ok variances u u' cstrs =
let open Universes in
if not nargs_ok then enforce_eq_instances_univs false u u' cstrs
else
CArray.fold_left3
(fun cstrs v u u' ->
let open Univ.Variance in
match v with
| Irrelevant -> Constraints.add (UWeak (u,u')) cstrs
| Covariant ->
let u = Univ.Universe.make u in
let u' = Univ.Universe.make u' in
(match cv_pb with
| Reduction.CONV -> Constraints.add (UEq (u,u')) cstrs
| Reduction.CUMUL -> Constraints.add (ULe (u,u')) cstrs)
| Invariant ->
let u = Univ.Universe.make u in
let u' = Univ.Universe.make u' in
Constraints.add (UEq (u,u')) cstrs)
cstrs variances (Univ.Instance.to_array u) (Univ.Instance.to_array u')
let cmp_inductives cv_pb (mind,ind as spec) nargs u1 u2 cstrs =
let open Universes in
match mind.Declarations.mind_universes with
| Declarations.Monomorphic_ind _ ->
assert (Univ.Instance.length u1 = 0 && Univ.Instance.length u2 = 0);
cstrs
| Declarations.Polymorphic_ind _ ->
enforce_eq_instances_univs false u1 u2 cstrs
| Declarations.Cumulative_ind cumi ->
let num_param_arity = Reduction.inductive_cumulativity_arguments spec in
let variances = Univ.ACumulativityInfo.variance cumi in
compare_cumulative_instances cv_pb (Int.equal num_param_arity nargs) variances u1 u2 cstrs
let cmp_constructors (mind, ind, cns as spec) nargs u1 u2 cstrs =
let open Universes in
match mind.Declarations.mind_universes with
| Declarations.Monomorphic_ind _ ->
cstrs
| Declarations.Polymorphic_ind _ ->
enforce_eq_instances_univs false u1 u2 cstrs
| Declarations.Cumulative_ind cumi ->
let num_cnstr_args = Reduction.constructor_cumulativity_arguments spec in
if not (Int.equal num_cnstr_args nargs)
then enforce_eq_instances_univs false u1 u2 cstrs
else
Array.fold_left2 (fun cstrs u1 u2 -> Universes.(Constraints.add (UWeak (u1,u2)) cstrs))
cstrs (Univ.Instance.to_array u1) (Univ.Instance.to_array u2)
let eq_universes env sigma cstrs cv_pb ref nargs l l' =
if Univ.Instance.is_empty l then (assert (Univ.Instance.is_empty l'); true)
else
let l = Evd.normalize_universe_instance sigma l
and l' = Evd.normalize_universe_instance sigma l' in
let open Universes in
match ref with
| VarRef _ -> assert false (* variables don't have instances *)
| ConstRef _ ->
cstrs := enforce_eq_instances_univs true l l' !cstrs; true
| IndRef ind ->
let mind = Environ.lookup_mind (fst ind) env in
cstrs := cmp_inductives cv_pb (mind,snd ind) nargs l l' !cstrs;
true
| ConstructRef ((mi,ind),ctor) ->
let mind = Environ.lookup_mind mi env in
cstrs := cmp_constructors (mind,ind,ctor) nargs l l' !cstrs;
true
let test_constr_universes env sigma leq m n =
let open Universes in
let kind c = kind_upto sigma c in
if m == n then Some Constraints.empty
else
let cstrs = ref Constraints.empty in
let cv_pb = if leq then Reduction.CUMUL else Reduction.CONV in
let eq_universes ref nargs l l' = eq_universes env sigma cstrs Reduction.CONV ref nargs l l'
and leq_universes ref nargs l l' = eq_universes env sigma cstrs cv_pb ref nargs l l' in
let eq_sorts s1 s2 =
let s1 = ESorts.kind sigma (ESorts.make s1) in
let s2 = ESorts.kind sigma (ESorts.make s2) in
if Sorts.equal s1 s2 then true
else (cstrs := Constraints.add
(UEq (Sorts.univ_of_sort s1,Sorts.univ_of_sort s2)) !cstrs;
true)
in
let leq_sorts s1 s2 =
let s1 = ESorts.kind sigma (ESorts.make s1) in
let s2 = ESorts.kind sigma (ESorts.make s2) in
if Sorts.equal s1 s2 then true
else
(cstrs := Constraints.add
(ULe (Sorts.univ_of_sort s1,Sorts.univ_of_sort s2)) !cstrs;
true)
in
let rec eq_constr' nargs m n = compare_gen kind eq_universes eq_sorts eq_constr' nargs m n in
let res =
if leq then
let rec compare_leq nargs m n =
Constr.compare_head_gen_leq_with kind kind leq_universes leq_sorts
eq_constr' leq_constr' nargs m n
and leq_constr' nargs m n = m == n || compare_leq nargs m n in
compare_leq 0 m n
else
Constr.compare_head_gen_with kind kind eq_universes eq_sorts eq_constr' 0 m n
in
if res then Some !cstrs else None
let eq_constr_universes env sigma m n =
test_constr_universes env sigma false (unsafe_to_constr m) (unsafe_to_constr n)
let leq_constr_universes env sigma m n =
test_constr_universes env sigma true (unsafe_to_constr m) (unsafe_to_constr n)
let compare_head_gen_proj env sigma equ eqs eqc' nargs m n =
let kind c = kind_upto sigma c in
match kind_upto sigma m, kind_upto sigma n with
| Proj (p, c), App (f, args)
| App (f, args), Proj (p, c) ->
(match kind_upto sigma f with
| Const (p', u) when Constant.equal (Projection.constant p) p' ->
let pb = Environ.lookup_projection p env in
let npars = pb.Declarations.proj_npars in
if Array.length args == npars + 1 then
eqc' 0 c args.(npars)
else false
| _ -> false)
| _ -> Constr.compare_head_gen_with kind kind equ eqs eqc' nargs m n
let eq_constr_universes_proj env sigma m n =
let open Universes in
if m == n then Some Constraints.empty
else
let cstrs = ref Constraints.empty in
let eq_universes ref l l' = eq_universes env sigma cstrs Reduction.CONV ref l l' in
let eq_sorts s1 s2 =
if Sorts.equal s1 s2 then true
else
(cstrs := Constraints.add
(UEq (Sorts.univ_of_sort s1, Sorts.univ_of_sort s2)) !cstrs;
true)
in
let rec eq_constr' nargs m n =
m == n || compare_head_gen_proj env sigma eq_universes eq_sorts eq_constr' nargs m n
in
let res = eq_constr' 0 (unsafe_to_constr m) (unsafe_to_constr n) in
if res then Some !cstrs else None
let universes_of_constr env sigma c =
let open Univ in
let open Declarations in
let rec aux s c =
match kind sigma c with
| Const (c, u) ->
begin match (Environ.lookup_constant c env).const_universes with
| Polymorphic_const _ ->
LSet.fold LSet.add (Instance.levels (EInstance.kind sigma u)) s
| Monomorphic_const (univs, _) ->
LSet.union s univs
end
| Ind ((mind,_), u) | Construct (((mind,_),_), u) ->
begin match (Environ.lookup_mind mind env).mind_universes with
| Cumulative_ind _ | Polymorphic_ind _ ->
LSet.fold LSet.add (Instance.levels (EInstance.kind sigma u)) s
| Monomorphic_ind (univs,_) ->
LSet.union s univs
end
| Sort u ->
let sort = ESorts.kind sigma u in
if Sorts.is_small sort then s
else
let u = Sorts.univ_of_sort sort in
LSet.fold LSet.add (Universe.levels u) s
| Evar (k, args) ->
let concl = Evd.evar_concl (Evd.find sigma k) in
fold sigma aux (aux s (of_constr concl)) c
| _ -> fold sigma aux s c
in aux LSet.empty c
open Context
open Environ
let cast_list : type a b. (a,b) eq -> a list -> b list =
fun Refl x -> x
let cast_list_snd : type a b. (a,b) eq -> ('c * a) list -> ('c * b) list =
fun Refl x -> x
let cast_rel_decl :
type a b. (a,b) eq -> (a, a) Rel.Declaration.pt -> (b, b) Rel.Declaration.pt =
fun Refl x -> x
let cast_rel_context :
type a b. (a,b) eq -> (a, a) Rel.pt -> (b, b) Rel.pt =
fun Refl x -> x
let cast_rec_decl :
type a b. (a,b) eq -> (a, a) Constr.prec_declaration -> (b, b) Constr.prec_declaration =
fun Refl x -> x
let cast_named_decl :
type a b. (a,b) eq -> (a, a) Named.Declaration.pt -> (b, b) Named.Declaration.pt =
fun Refl x -> x
let cast_named_context :
type a b. (a,b) eq -> (a, a) Named.pt -> (b, b) Named.pt =
fun Refl x -> x
module Vars =
struct
exception LocalOccur
let to_constr = unsafe_to_constr
let to_rel_decl = unsafe_to_rel_decl
type substl = t list
(** Operations that commute with evar-normalization *)
let lift n c = of_constr (Vars.lift n (to_constr c))
let liftn n m c = of_constr (Vars.liftn n m (to_constr c))
let substnl subst n c = of_constr (Vars.substnl (cast_list unsafe_eq subst) n (to_constr c))
let substl subst c = of_constr (Vars.substl (cast_list unsafe_eq subst) (to_constr c))
let subst1 c r = of_constr (Vars.subst1 (to_constr c) (to_constr r))
let substnl_decl subst n d = of_rel_decl (Vars.substnl_decl (cast_list unsafe_eq subst) n (to_rel_decl d))
let substl_decl subst d = of_rel_decl (Vars.substl_decl (cast_list unsafe_eq subst) (to_rel_decl d))
let subst1_decl c d = of_rel_decl (Vars.subst1_decl (to_constr c) (to_rel_decl d))
let replace_vars subst c =
of_constr (Vars.replace_vars (cast_list_snd unsafe_eq subst) (to_constr c))
let substn_vars n subst c = of_constr (Vars.substn_vars n subst (to_constr c))
let subst_vars subst c = of_constr (Vars.subst_vars subst (to_constr c))
let subst_var subst c = of_constr (Vars.subst_var subst (to_constr c))
let subst_univs_level_constr subst c =
of_constr (Vars.subst_univs_level_constr subst (to_constr c))
(** Operations that dot NOT commute with evar-normalization *)
let noccurn sigma n term =
let rec occur_rec n c = match kind sigma c with
| Rel m -> if Int.equal m n then raise LocalOccur
| _ -> iter_with_binders sigma succ occur_rec n c
in
try occur_rec n term; true with LocalOccur -> false
let noccur_between sigma n m term =
let rec occur_rec n c = match kind sigma c with
| Rel p -> if n<=p && p<n+m then raise LocalOccur
| _ -> iter_with_binders sigma succ occur_rec n c
in
try occur_rec n term; true with LocalOccur -> false
let closedn sigma n c =
let rec closed_rec n c = match kind sigma c with
| Rel m -> if m>n then raise LocalOccur
| _ -> iter_with_binders sigma succ closed_rec n c
in
try closed_rec n c; true with LocalOccur -> false
let closed0 sigma c = closedn sigma 0 c
let subst_of_rel_context_instance ctx subst =
cast_list (sym unsafe_eq)
(Vars.subst_of_rel_context_instance (cast_rel_context unsafe_eq ctx) (cast_list unsafe_eq subst))
end
let rec isArity sigma c =
match kind sigma c with
| Prod (_,_,c) -> isArity sigma c
| LetIn (_,b,_,c) -> isArity sigma (Vars.subst1 b c)
| Cast (c,_,_) -> isArity sigma c
| Sort _ -> true
| _ -> false
type arity = rel_context * ESorts.t
let destArity sigma =
let open Context.Rel.Declaration in
let rec prodec_rec l c =
match kind sigma c with
| Prod (x,t,c) -> prodec_rec (LocalAssum (x,t) :: l) c
| LetIn (x,b,t,c) -> prodec_rec (LocalDef (x,b,t) :: l) c
| Cast (c,_,_) -> prodec_rec l c
| Sort s -> l,s
| _ -> anomaly ~label:"destArity" (Pp.str "not an arity.")
in
prodec_rec []
let mkProd_or_LetIn decl c =
let open Context.Rel.Declaration in
match decl with
| LocalAssum (na,t) -> mkProd (na, t, c)
| LocalDef (na,b,t) -> mkLetIn (na, b, t, c)
let mkLambda_or_LetIn decl c =
let open Context.Rel.Declaration in
match decl with
| LocalAssum (na,t) -> mkLambda (na, t, c)
| LocalDef (na,b,t) -> mkLetIn (na, b, t, c)
let mkNamedProd id typ c = mkProd (Name id, typ, Vars.subst_var id c)
let mkNamedLambda id typ c = mkLambda (Name id, typ, Vars.subst_var id c)
let mkNamedLetIn id c1 t c2 = mkLetIn (Name id, c1, t, Vars.subst_var id c2)
let mkNamedProd_or_LetIn decl c =
let open Context.Named.Declaration in
match decl with
| LocalAssum (id,t) -> mkNamedProd id t c
| LocalDef (id,b,t) -> mkNamedLetIn id b t c
let mkNamedLambda_or_LetIn decl c =
let open Context.Named.Declaration in
match decl with
| LocalAssum (id,t) -> mkNamedLambda id t c
| LocalDef (id,b,t) -> mkNamedLetIn id b t c
let it_mkProd_or_LetIn t ctx = List.fold_left (fun c d -> mkProd_or_LetIn d c) t ctx
let it_mkLambda_or_LetIn t ctx = List.fold_left (fun c d -> mkLambda_or_LetIn d c) t ctx
let push_rel d e = push_rel (cast_rel_decl unsafe_eq d) e
let push_rel_context d e = push_rel_context (cast_rel_context unsafe_eq d) e
let push_rec_types d e = push_rec_types (cast_rec_decl unsafe_eq d) e
let push_named d e = push_named (cast_named_decl unsafe_eq d) e
let push_named_context d e = push_named_context (cast_named_context unsafe_eq d) e
let push_named_context_val d e = push_named_context_val (cast_named_decl unsafe_eq d) e
let rel_context e = cast_rel_context (sym unsafe_eq) (rel_context e)
let named_context e = cast_named_context (sym unsafe_eq) (named_context e)
let val_of_named_context e = val_of_named_context (cast_named_context unsafe_eq e)
let named_context_of_val e = cast_named_context (sym unsafe_eq) (named_context_of_val e)
let lookup_rel i e = cast_rel_decl (sym unsafe_eq) (lookup_rel i e)
let lookup_named n e = cast_named_decl (sym unsafe_eq) (lookup_named n e)
let lookup_named_val n e = cast_named_decl (sym unsafe_eq) (lookup_named_val n e)
let map_rel_context_in_env f env sign =
let rec aux env acc = function
| d::sign ->
aux (push_rel d env) (Context.Rel.Declaration.map_constr (f env) d :: acc) sign
| [] ->
acc
in
aux env [] (List.rev sign)
let fresh_global ?loc ?rigid ?names env sigma reference =
let (evd,t) = Evd.fresh_global ?loc ?rigid ?names env sigma reference in
evd, of_constr t
let is_global sigma gr c =
Globnames.is_global gr (to_constr sigma c)
module Unsafe =
struct
let to_sorts = ESorts.unsafe_to_sorts
let to_instance = EInstance.unsafe_to_instance
let to_constr = unsafe_to_constr
let to_rel_decl = unsafe_to_rel_decl
let to_named_decl = unsafe_to_named_decl
let eq = unsafe_eq
end
|