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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) *)
(************************************************************************)
(* File initially created by Gérard Huet and Thierry Coquand in 1984 *)
(* Extension to inductive constructions by Christine Paulin for Coq V5.6 *)
(* Extension to mutual inductive constructions by Christine Paulin for
Coq V5.10.2 *)
(* Extension to co-inductive constructions by Eduardo Gimenez *)
(* Optimization of substitution functions by Chet Murthy *)
(* Optimization of lifting functions by Bruno Barras, Mar 1997 *)
(* Hash-consing by Bruno Barras in Feb 1998 *)
(* Restructuration of Coq of the type-checking kernel by Jean-Christophe
Filliâtre, 1999 *)
(* Abstraction of the syntax of terms and iterators by Hugo Herbelin, 2000 *)
(* Cleaning and lightening of the kernel by Bruno Barras, Nov 2001 *)
(* This file defines the internal syntax of the Calculus of
Inductive Constructions (CIC) terms together with constructors,
destructors, iterators and basic functions *)
open Util
open Names
open Univ
type existential_key = Evar.t
type metavariable = int
(* This defines the strategy to use for verifiying a Cast *)
(* Warning: REVERTcast is not exported to vo-files; as of r14492, it has to *)
(* come after the vo-exported cast_kind so as to be compatible with coqchk *)
type cast_kind = VMcast | NATIVEcast | DEFAULTcast | REVERTcast
(* This defines Cases annotations *)
type case_style = LetStyle | IfStyle | LetPatternStyle | MatchStyle | RegularStyle
type case_printing =
{ ind_tags : bool list; (** tell whether letin or lambda in the arity of the inductive type *)
cstr_tags : bool list array; (* whether each pattern var of each constructor is a let-in (true) or not (false) *)
style : case_style }
(* INVARIANT:
* - Array.length ci_cstr_ndecls = Array.length ci_cstr_nargs
* - forall (i : 0 .. pred (Array.length ci_cstr_ndecls)),
* ci_cstr_ndecls.(i) >= ci_cstr_nargs.(i)
*)
type case_info =
{ ci_ind : inductive; (* inductive type to which belongs the value that is being matched *)
ci_npar : int; (* number of parameters of the above inductive type *)
ci_cstr_ndecls : int array; (* For each constructor, the corresponding integer determines
the number of values that can be bound in a match-construct.
NOTE: parameters of the inductive type are therefore excluded from the count *)
ci_cstr_nargs : int array; (* for each constructor, the corresponding integers determines
the number of values that can be applied to the constructor,
in addition to the parameters of the related inductive type
NOTE: "lets" are therefore excluded from the count
NOTE: parameters of the inductive type are also excluded from the count *)
ci_pp_info : case_printing (* not interpreted by the kernel *)
}
(********************************************************************)
(* Constructions as implemented *)
(********************************************************************)
(* [constr array] is an instance matching definitional [named_context] in
the same order (i.e. last argument first) *)
type 'constr pexistential = existential_key * 'constr array
type ('constr, 'types) prec_declaration =
Name.t array * 'types array * 'constr array
type ('constr, 'types) pfixpoint =
(int array * int) * ('constr, 'types) prec_declaration
type ('constr, 'types) pcofixpoint =
int * ('constr, 'types) prec_declaration
type 'a puniverses = 'a Univ.puniverses
type pconstant = Constant.t puniverses
type pinductive = inductive puniverses
type pconstructor = constructor puniverses
(* [Var] is used for named variables and [Rel] for variables as
de Bruijn indices. *)
type ('constr, 'types, 'sort, 'univs) kind_of_term =
| Rel of int
| Var of Id.t
| Meta of metavariable
| Evar of 'constr pexistential
| Sort of 'sort
| Cast of 'constr * cast_kind * 'types
| Prod of Name.t * 'types * 'types
| Lambda of Name.t * 'types * 'constr
| LetIn of Name.t * 'constr * 'types * 'constr
| App of 'constr * 'constr array
| Const of (Constant.t * 'univs)
| Ind of (inductive * 'univs)
| Construct of (constructor * 'univs)
| Case of case_info * 'constr * 'constr * 'constr array
| Fix of ('constr, 'types) pfixpoint
| CoFix of ('constr, 'types) pcofixpoint
| Proj of projection * 'constr
(* constr is the fixpoint of the previous type. Requires option
-rectypes of the Caml compiler to be set *)
type t = (t, t, Sorts.t, Instance.t) kind_of_term
type constr = t
type existential = existential_key * constr array
type rec_declaration = Name.t array * constr array * constr array
type fixpoint = (int array * int) * rec_declaration
(* The array of [int]'s tells for each component of the array of
mutual fixpoints the number of lambdas to skip before finding the
recursive argument (e.g., value is 2 in "fix f (x:A) (y:=t) (z:B)
(v:=u) (w:I) {struct w}"), telling to skip x and z and that w is
the recursive argument);
The second component [int] tells which component of the block is
returned *)
type cofixpoint = int * rec_declaration
(* The component [int] tells which component of the block of
cofixpoint is returned *)
type types = constr
(*********************)
(* Term constructors *)
(*********************)
(* Constructs a de Bruijn index with number n *)
let rels =
[|Rel 1;Rel 2;Rel 3;Rel 4;Rel 5;Rel 6;Rel 7; Rel 8;
Rel 9;Rel 10;Rel 11;Rel 12;Rel 13;Rel 14;Rel 15; Rel 16|]
let mkRel n = if 0<n && n<=16 then rels.(n-1) else Rel n
(* Construct a type *)
let mkProp = Sort Sorts.prop
let mkSet = Sort Sorts.set
let mkType u = Sort (Sorts.Type u)
let mkSort = function
| Sorts.Prop Sorts.Null -> mkProp (* Easy sharing *)
| Sorts.Prop Sorts.Pos -> mkSet
| s -> Sort s
(* Constructs the term t1::t2, i.e. the term t1 casted with the type t2 *)
(* (that means t2 is declared as the type of t1) *)
let mkCast (t1,k2,t2) =
match t1 with
| Cast (c,k1, _) when (k1 == VMcast || k1 == NATIVEcast) && k1 == k2 -> Cast (c,k1,t2)
| _ -> Cast (t1,k2,t2)
(* Constructs the product (x:t1)t2 *)
let mkProd (x,t1,t2) = Prod (x,t1,t2)
(* Constructs the abstraction [x:t1]t2 *)
let mkLambda (x,t1,t2) = Lambda (x,t1,t2)
(* Constructs [x=c_1:t]c_2 *)
let mkLetIn (x,c1,t,c2) = LetIn (x,c1,t,c2)
(* If lt = [t1; ...; tn], constructs the application (t1 ... tn) *)
(* We ensure applicative terms have at least one argument and the
function is not itself an applicative term *)
let mkApp (f, a) =
if Int.equal (Array.length a) 0 then f else
match f with
| App (g, cl) -> App (g, Array.append cl a)
| _ -> App (f, a)
let map_puniverses f (x,u) = (f x, u)
let in_punivs a = (a, Univ.Instance.empty)
(* Constructs a constant *)
let mkConst c = Const (in_punivs c)
let mkConstU c = Const c
(* Constructs an applied projection *)
let mkProj (p,c) = Proj (p,c)
(* Constructs an existential variable *)
let mkEvar e = Evar e
(* Constructs the ith (co)inductive type of the block named kn *)
let mkInd m = Ind (in_punivs m)
let mkIndU m = Ind m
(* Constructs the jth constructor of the ith (co)inductive type of the
block named kn. *)
let mkConstruct c = Construct (in_punivs c)
let mkConstructU c = Construct c
let mkConstructUi ((ind,u),i) = Construct ((ind,i),u)
(* Constructs the term <p>Case c of c1 | c2 .. | cn end *)
let mkCase (ci, p, c, ac) = Case (ci, p, c, ac)
(* If recindxs = [|i1,...in|]
funnames = [|f1,...fn|]
typarray = [|t1,...tn|]
bodies = [|b1,...bn|]
then
mkFix ((recindxs,i),(funnames,typarray,bodies))
constructs the ith function of the block
Fixpoint f1 [ctx1] : t1 := b1
with f2 [ctx2] : t2 := b2
...
with fn [ctxn] : tn := bn.
where the length of the jth context is ij.
*)
let mkFix fix = Fix fix
(* If funnames = [|f1,...fn|]
typarray = [|t1,...tn|]
bodies = [|b1,...bn|]
then
mkCoFix (i,(funnames,typsarray,bodies))
constructs the ith function of the block
CoFixpoint f1 : t1 := b1
with f2 : t2 := b2
...
with fn : tn := bn.
*)
let mkCoFix cofix= CoFix cofix
(* Constructs an existential variable named "?n" *)
let mkMeta n = Meta n
(* Constructs a Variable named id *)
let mkVar id = Var id
(************************************************************************)
(* kind_of_term = constructions as seen by the user *)
(************************************************************************)
(* User view of [constr]. For [App], it is ensured there is at
least one argument and the function is not itself an applicative
term *)
let kind c = c
(* The other way around. We treat specifically smart constructors *)
let of_kind = function
| App (f, a) -> mkApp (f, a)
| Cast (c, knd, t) -> mkCast (c, knd, t)
| k -> k
(**********************************************************************)
(* Non primitive term destructors *)
(**********************************************************************)
(* Destructor operations : partial functions
Raise [DestKO] if the const has not the expected form *)
exception DestKO
let isMeta c = match kind c with Meta _ -> true | _ -> false
(* Destructs a type *)
let isSort c = match kind c with
| Sort _ -> true
| _ -> false
let rec isprop c = match kind c with
| Sort (Sorts.Prop _) -> true
| Cast (c,_,_) -> isprop c
| _ -> false
let rec is_Prop c = match kind c with
| Sort (Sorts.Prop Sorts.Null) -> true
| Cast (c,_,_) -> is_Prop c
| _ -> false
let rec is_Set c = match kind c with
| Sort (Sorts.Prop Sorts.Pos) -> true
| Cast (c,_,_) -> is_Set c
| _ -> false
let rec is_Type c = match kind c with
| Sort (Sorts.Type _) -> true
| Cast (c,_,_) -> is_Type c
| _ -> false
let is_small = Sorts.is_small
let iskind c = isprop c || is_Type c
(* Tests if an evar *)
let isEvar c = match kind c with Evar _ -> true | _ -> false
let isEvar_or_Meta c = match kind c with
| Evar _ | Meta _ -> true
| _ -> false
let isCast c = match kind c with Cast _ -> true | _ -> false
(* Tests if a de Bruijn index *)
let isRel c = match kind c with Rel _ -> true | _ -> false
let isRelN n c =
match kind c with Rel n' -> Int.equal n n' | _ -> false
(* Tests if a variable *)
let isVar c = match kind c with Var _ -> true | _ -> false
let isVarId id c = match kind c with Var id' -> Id.equal id id' | _ -> false
(* Tests if an inductive *)
let isInd c = match kind c with Ind _ -> true | _ -> false
let isProd c = match kind c with | Prod _ -> true | _ -> false
let isLambda c = match kind c with | Lambda _ -> true | _ -> false
let isLetIn c = match kind c with LetIn _ -> true | _ -> false
let isApp c = match kind c with App _ -> true | _ -> false
let isConst c = match kind c with Const _ -> true | _ -> false
let isConstruct c = match kind c with Construct _ -> true | _ -> false
let isCase c = match kind c with Case _ -> true | _ -> false
let isProj c = match kind c with Proj _ -> true | _ -> false
let isFix c = match kind c with Fix _ -> true | _ -> false
let isCoFix c = match kind c with CoFix _ -> true | _ -> false
(* Destructs a de Bruijn index *)
let destRel c = match kind c with
| Rel n -> n
| _ -> raise DestKO
(* Destructs an existential variable *)
let destMeta c = match kind c with
| Meta n -> n
| _ -> raise DestKO
(* Destructs a variable *)
let destVar c = match kind c with
| Var id -> id
| _ -> raise DestKO
let destSort c = match kind c with
| Sort s -> s
| _ -> raise DestKO
(* Destructs a casted term *)
let destCast c = match kind c with
| Cast (t1,k,t2) -> (t1,k,t2)
| _ -> raise DestKO
(* Destructs the product (x:t1)t2 *)
let destProd c = match kind c with
| Prod (x,t1,t2) -> (x,t1,t2)
| _ -> raise DestKO
(* Destructs the abstraction [x:t1]t2 *)
let destLambda c = match kind c with
| Lambda (x,t1,t2) -> (x,t1,t2)
| _ -> raise DestKO
(* Destructs the let [x:=b:t1]t2 *)
let destLetIn c = match kind c with
| LetIn (x,b,t1,t2) -> (x,b,t1,t2)
| _ -> raise DestKO
(* Destructs an application *)
let destApp c = match kind c with
| App (f,a) -> (f, a)
| _ -> raise DestKO
(* Destructs a constant *)
let destConst c = match kind c with
| Const kn -> kn
| _ -> raise DestKO
(* Destructs an existential variable *)
let destEvar c = match kind c with
| Evar (kn, a as r) -> r
| _ -> raise DestKO
(* Destructs a (co)inductive type named kn *)
let destInd c = match kind c with
| Ind (kn, a as r) -> r
| _ -> raise DestKO
(* Destructs a constructor *)
let destConstruct c = match kind c with
| Construct (kn, a as r) -> r
| _ -> raise DestKO
(* Destructs a term <p>Case c of lc1 | lc2 .. | lcn end *)
let destCase c = match kind c with
| Case (ci,p,c,v) -> (ci,p,c,v)
| _ -> raise DestKO
let destProj c = match kind c with
| Proj (p, c) -> (p, c)
| _ -> raise DestKO
let destFix c = match kind c with
| Fix fix -> fix
| _ -> raise DestKO
let destCoFix c = match kind c with
| CoFix cofix -> cofix
| _ -> raise DestKO
(******************************************************************)
(* Flattening and unflattening of embedded applications and casts *)
(******************************************************************)
let decompose_app c =
match kind c with
| App (f,cl) -> (f, Array.to_list cl)
| _ -> (c,[])
let decompose_appvect c =
match kind c with
| App (f,cl) -> (f, cl)
| _ -> (c,[||])
(****************************************************************************)
(* Functions to recur through subterms *)
(****************************************************************************)
(* [fold f acc c] folds [f] on the immediate subterms of [c]
starting from [acc] and proceeding from left to right according to
the usual representation of the constructions; it is not recursive *)
let fold f acc c = match kind 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
(* [iter f c] iters [f] on the immediate subterms of [c]; it is
not recursive and the order with which subterms are processed is
not specified *)
let iter f c = match kind 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
(* [iter_with_binders g f n c] iters [f n] on the immediate
subterms of [c]; it carries an extra data [n] (typically a lift
index) which is processed by [g] (which typically add 1 to [n]) at
each binder traversal; it is not recursive and the order with which
subterms are processed is not specified *)
let iter_with_binders g f n c = match kind c with
| (Rel _ | Meta _ | Var _ | Sort _ | Const _ | Ind _
| Construct _) -> ()
| Cast (c,_,t) -> f n c; f n t
| Prod (_,t,c) -> f n t; f (g n) c
| Lambda (_,t,c) -> f n t; f (g n) c
| LetIn (_,b,t,c) -> f n b; f n t; f (g 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 (_,(_,tl,bl)) ->
CArray.Fun1.iter f n tl;
CArray.Fun1.iter f (iterate g (Array.length tl) n) bl
| CoFix (_,(_,tl,bl)) ->
CArray.Fun1.iter f n tl;
CArray.Fun1.iter f (iterate g (Array.length tl) n) bl
(* [map f c] maps [f] on the immediate subterms of [c]; it is
not recursive and the order with which subterms are processed is
not specified *)
let map f c = match kind 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'))
(* Like {!map} but with an accumulator. *)
let fold_map f accu c = match kind c with
| (Rel _ | Meta _ | Var _ | Sort _ | Const _ | Ind _
| Construct _) -> accu, c
| Cast (b,k,t) ->
let accu, b' = f accu b in
let accu, t' = f accu t in
if b'==b && t' == t then accu, c
else accu, mkCast (b', k, t')
| Prod (na,t,b) ->
let accu, b' = f accu b in
let accu, t' = f accu t in
if b'==b && t' == t then accu, c
else accu, mkProd (na, t', b')
| Lambda (na,t,b) ->
let accu, b' = f accu b in
let accu, t' = f accu t in
if b'==b && t' == t then accu, c
else accu, mkLambda (na, t', b')
| LetIn (na,b,t,k) ->
let accu, b' = f accu b in
let accu, t' = f accu t in
let accu, k' = f accu k in
if b'==b && t' == t && k'==k then accu, c
else accu, mkLetIn (na, b', t', k')
| App (b,l) ->
let accu, b' = f accu b in
let accu, l' = Array.smartfoldmap f accu l in
if b'==b && l'==l then accu, c
else accu, mkApp (b', l')
| Proj (p,t) ->
let accu, t' = f accu t in
if t' == t then accu, c
else accu, mkProj (p, t')
| Evar (e,l) ->
let accu, l' = Array.smartfoldmap f accu l in
if l'==l then accu, c
else accu, mkEvar (e, l')
| Case (ci,p,b,bl) ->
let accu, b' = f accu b in
let accu, p' = f accu p in
let accu, bl' = Array.smartfoldmap f accu bl in
if b'==b && p'==p && bl'==bl then accu, c
else accu, mkCase (ci, p', b', bl')
| Fix (ln,(lna,tl,bl)) ->
let accu, tl' = Array.smartfoldmap f accu tl in
let accu, bl' = Array.smartfoldmap f accu bl in
if tl'==tl && bl'==bl then accu, c
else accu, mkFix (ln,(lna,tl',bl'))
| CoFix(ln,(lna,tl,bl)) ->
let accu, tl' = Array.smartfoldmap f accu tl in
let accu, bl' = Array.smartfoldmap f accu bl in
if tl'==tl && bl'==bl then accu, c
else accu, mkCoFix (ln,(lna,tl',bl'))
(* [map_with_binders g f n c] maps [f n] on the immediate
subterms of [c]; it carries an extra data [n] (typically a lift
index) which is processed by [g] (which typically add 1 to [n]) at
each binder traversal; it is not recursive and the order with which
subterms are processed is not specified *)
let map_with_binders g f l c0 = match kind 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'))
(* [compare_head_gen_evar k1 k2 u s e eq leq c1 c2] compare [c1] and
[c2] (using [k1] to expose the structure of [c1] and [k2] to expose
the structure [c2]) using [eq] to compare the immediate subterms of
[c1] of [c2] for conversion if needed, [leq] for cumulativity, [u]
to compare universe instances, and [s] to compare sorts; Cast's,
application associativity, binders name and Cases annotations are
not taken into account. Note that as [kind1] and [kind2] are
potentially different, we cannot use, in recursive case, the
optimisation that physically equal arrays are equals (hence the
calls to {!Array.equal_norefl}). *)
let compare_head_gen_leq_with kind1 kind2 eq_universes leq_sorts eq leq t1 t2 =
match kind1 t1, kind2 t2 with
| Rel n1, Rel n2 -> Int.equal n1 n2
| Meta m1, Meta m2 -> Int.equal m1 m2
| Var id1, Var id2 -> Id.equal id1 id2
| Sort s1, Sort s2 -> leq_sorts s1 s2
| Cast (c1,_,_), _ -> leq c1 t2
| _, Cast (c2,_,_) -> leq t1 c2
| Prod (_,t1,c1), Prod (_,t2,c2) -> eq t1 t2 && leq c1 c2
| Lambda (_,t1,c1), Lambda (_,t2,c2) -> eq t1 t2 && eq c1 c2
| LetIn (_,b1,t1,c1), LetIn (_,b2,t2,c2) -> eq b1 b2 && eq t1 t2 && leq c1 c2
(* Why do we suddenly make a special case for Cast here? *)
| App (Cast(c1, _, _),l1), _ -> leq (mkApp (c1,l1)) t2
| _, App (Cast (c2, _, _),l2) -> leq t1 (mkApp (c2,l2))
| App (c1,l1), App (c2,l2) ->
Int.equal (Array.length l1) (Array.length l2) &&
eq c1 c2 && Array.equal_norefl eq l1 l2
| Proj (p1,c1), Proj (p2,c2) -> Projection.equal p1 p2 && eq c1 c2
| Evar (e1,l1), Evar (e2,l2) -> Evar.equal e1 e2 && Array.equal eq l1 l2
| Const (c1,u1), Const (c2,u2) -> Constant.equal c1 c2 && eq_universes true u1 u2
| Ind (c1,u1), Ind (c2,u2) -> eq_ind c1 c2 && eq_universes false u1 u2
| Construct (c1,u1), Construct (c2,u2) -> eq_constructor c1 c2 && eq_universes false u1 u2
| Case (_,p1,c1,bl1), Case (_,p2,c2,bl2) ->
eq p1 p2 && eq c1 c2 && Array.equal eq bl1 bl2
| Fix ((ln1, i1),(_,tl1,bl1)), Fix ((ln2, i2),(_,tl2,bl2)) ->
Int.equal i1 i2 && Array.equal Int.equal ln1 ln2
&& Array.equal_norefl eq tl1 tl2 && Array.equal_norefl eq bl1 bl2
| CoFix(ln1,(_,tl1,bl1)), CoFix(ln2,(_,tl2,bl2)) ->
Int.equal ln1 ln2 && Array.equal_norefl eq tl1 tl2 && Array.equal_norefl eq bl1 bl2
| (Rel _ | Meta _ | Var _ | Sort _ | Prod _ | Lambda _ | LetIn _ | App _
| Proj _ | Evar _ | Const _ | Ind _ | Construct _ | Case _ | Fix _
| CoFix _), _ -> false
(* [compare_head_gen_leq u s eq leq c1 c2] compare [c1] and [c2] using [eq] to compare
the immediate subterms of [c1] of [c2] for conversion if needed, [leq] for cumulativity,
[u] to compare universe instances and [s] to compare sorts; Cast's,
application associativity, binders name and Cases annotations are
not taken into account *)
let compare_head_gen_leq eq_universes leq_sorts eq leq t1 t2 =
compare_head_gen_leq_with kind kind eq_universes leq_sorts eq leq t1 t2
(* [compare_head_gen u s f c1 c2] compare [c1] and [c2] using [f] to
compare the immediate subterms of [c1] of [c2] if needed, [u] to
compare universe instances and [s] to compare sorts; Cast's,
application associativity, binders name and Cases annotations are
not taken into account.
[compare_head_gen_with] is a variant taking kind-of-term functions,
to expose subterms of [c1] and [c2], as arguments. *)
let compare_head_gen_with kind1 kind2 eq_universes eq_sorts eq t1 t2 =
compare_head_gen_leq_with kind1 kind2 eq_universes eq_sorts eq eq t1 t2
let compare_head_gen eq_universes eq_sorts eq t1 t2 =
compare_head_gen_leq eq_universes eq_sorts eq eq t1 t2
let compare_head = compare_head_gen (fun _ -> Univ.Instance.equal) Sorts.equal
(*******************************)
(* alpha conversion functions *)
(*******************************)
(* alpha conversion : ignore print names and casts *)
let rec eq_constr m n =
(m == n) || compare_head_gen (fun _ -> Instance.equal) Sorts.equal eq_constr m n
let equal m n = eq_constr m n (* to avoid tracing a recursive fun *)
let eq_constr_univs univs m n =
if m == n then true
else
let eq_universes _ = UGraph.check_eq_instances univs in
let eq_sorts s1 s2 = s1 == s2 || UGraph.check_eq univs (Sorts.univ_of_sort s1) (Sorts.univ_of_sort s2) in
let rec eq_constr' m n =
m == n || compare_head_gen eq_universes eq_sorts eq_constr' m n
in compare_head_gen eq_universes eq_sorts eq_constr' m n
let leq_constr_univs univs m n =
if m == n then true
else
let eq_universes _ = UGraph.check_eq_instances univs in
let eq_sorts s1 s2 = s1 == s2 ||
UGraph.check_eq univs (Sorts.univ_of_sort s1) (Sorts.univ_of_sort s2) in
let leq_sorts s1 s2 = s1 == s2 ||
UGraph.check_leq univs (Sorts.univ_of_sort s1) (Sorts.univ_of_sort s2) in
let rec eq_constr' m n =
m == n || compare_head_gen eq_universes eq_sorts eq_constr' m n
in
let rec compare_leq m n =
compare_head_gen_leq eq_universes leq_sorts eq_constr' leq_constr' m n
and leq_constr' m n = m == n || compare_leq m n in
compare_leq m n
let eq_constr_univs_infer univs m n =
if m == n then true, Constraint.empty
else
let cstrs = ref Constraint.empty in
let eq_universes strict = UGraph.check_eq_instances univs in
let eq_sorts s1 s2 =
if Sorts.equal s1 s2 then true
else
let u1 = Sorts.univ_of_sort s1 and u2 = Sorts.univ_of_sort s2 in
if UGraph.check_eq univs u1 u2 then true
else
(cstrs := Univ.enforce_eq u1 u2 !cstrs;
true)
in
let rec eq_constr' m n =
m == n || compare_head_gen eq_universes eq_sorts eq_constr' m n
in
let res = compare_head_gen eq_universes eq_sorts eq_constr' m n in
res, !cstrs
let leq_constr_univs_infer univs m n =
if m == n then true, Constraint.empty
else
let cstrs = ref Constraint.empty in
let eq_universes strict l l' = UGraph.check_eq_instances univs l l' in
let eq_sorts s1 s2 =
if Sorts.equal s1 s2 then true
else
let u1 = Sorts.univ_of_sort s1 and u2 = Sorts.univ_of_sort s2 in
if UGraph.check_eq univs u1 u2 then true
else (cstrs := Univ.enforce_eq u1 u2 !cstrs;
true)
in
let leq_sorts s1 s2 =
if Sorts.equal s1 s2 then true
else
let u1 = Sorts.univ_of_sort s1 and u2 = Sorts.univ_of_sort s2 in
if UGraph.check_leq univs u1 u2 then true
else
(cstrs := Univ.enforce_leq u1 u2 !cstrs;
true)
in
let rec eq_constr' m n =
m == n || compare_head_gen eq_universes eq_sorts eq_constr' m n
in
let rec compare_leq m n =
compare_head_gen_leq eq_universes leq_sorts eq_constr' leq_constr' m n
and leq_constr' m n = m == n || compare_leq m n in
let res = compare_leq m n in
res, !cstrs
let always_true _ _ = true
let rec eq_constr_nounivs m n =
(m == n) || compare_head_gen (fun _ -> always_true) always_true eq_constr_nounivs m n
let constr_ord_int f t1 t2 =
let (=?) f g i1 i2 j1 j2=
let c = f i1 i2 in
if Int.equal c 0 then g j1 j2 else c in
let (==?) fg h i1 i2 j1 j2 k1 k2=
let c=fg i1 i2 j1 j2 in
if Int.equal c 0 then h k1 k2 else c in
let fix_cmp (a1, i1) (a2, i2) =
((Array.compare Int.compare) =? Int.compare) a1 a2 i1 i2
in
match kind t1, kind t2 with
| Cast (c1,_,_), _ -> f c1 t2
| _, Cast (c2,_,_) -> f t1 c2
(* Why this special case? *)
| App (Cast(c1,_,_),l1), _ -> f (mkApp (c1,l1)) t2
| _, App (Cast(c2, _,_),l2) -> f t1 (mkApp (c2,l2))
| Rel n1, Rel n2 -> Int.compare n1 n2
| Rel _, _ -> -1 | _, Rel _ -> 1
| Var id1, Var id2 -> Id.compare id1 id2
| Var _, _ -> -1 | _, Var _ -> 1
| Meta m1, Meta m2 -> Int.compare m1 m2
| Meta _, _ -> -1 | _, Meta _ -> 1
| Evar (e1,l1), Evar (e2,l2) ->
(Evar.compare =? (Array.compare f)) e1 e2 l1 l2
| Evar _, _ -> -1 | _, Evar _ -> 1
| Sort s1, Sort s2 -> Sorts.compare s1 s2
| Sort _, _ -> -1 | _, Sort _ -> 1
| Prod (_,t1,c1), Prod (_,t2,c2)
| Lambda (_,t1,c1), Lambda (_,t2,c2) ->
(f =? f) t1 t2 c1 c2
| Prod _, _ -> -1 | _, Prod _ -> 1
| Lambda _, _ -> -1 | _, Lambda _ -> 1
| LetIn (_,b1,t1,c1), LetIn (_,b2,t2,c2) ->
((f =? f) ==? f) b1 b2 t1 t2 c1 c2
| LetIn _, _ -> -1 | _, LetIn _ -> 1
| App (c1,l1), App (c2,l2) -> (f =? (Array.compare f)) c1 c2 l1 l2
| App _, _ -> -1 | _, App _ -> 1
| Const (c1,u1), Const (c2,u2) -> Constant.CanOrd.compare c1 c2
| Const _, _ -> -1 | _, Const _ -> 1
| Ind (ind1, u1), Ind (ind2, u2) -> ind_ord ind1 ind2
| Ind _, _ -> -1 | _, Ind _ -> 1
| Construct (ct1,u1), Construct (ct2,u2) -> constructor_ord ct1 ct2
| Construct _, _ -> -1 | _, Construct _ -> 1
| Case (_,p1,c1,bl1), Case (_,p2,c2,bl2) ->
((f =? f) ==? (Array.compare f)) p1 p2 c1 c2 bl1 bl2
| Case _, _ -> -1 | _, Case _ -> 1
| Fix (ln1,(_,tl1,bl1)), Fix (ln2,(_,tl2,bl2)) ->
((fix_cmp =? (Array.compare f)) ==? (Array.compare f))
ln1 ln2 tl1 tl2 bl1 bl2
| Fix _, _ -> -1 | _, Fix _ -> 1
| CoFix(ln1,(_,tl1,bl1)), CoFix(ln2,(_,tl2,bl2)) ->
((Int.compare =? (Array.compare f)) ==? (Array.compare f))
ln1 ln2 tl1 tl2 bl1 bl2
| CoFix _, _ -> -1 | _, CoFix _ -> 1
| Proj (p1,c1), Proj (p2,c2) -> (Projection.compare =? f) p1 p2 c1 c2
let rec compare m n=
constr_ord_int compare m n
(*******************)
(* hash-consing *)
(*******************)
(* Hash-consing of [constr] does not use the module [Hashcons] because
[Hashcons] is not efficient on deep tree-like data
structures. Indeed, [Hashcons] is based the (very efficient)
generic hash function [Hashtbl.hash], which computes the hash key
through a depth bounded traversal of the data structure to be
hashed. As a consequence, for a deep [constr] like the natural
number 1000 (S (S (... (S O)))), the same hash is assigned to all
the sub [constr]s greater than the maximal depth handled by
[Hashtbl.hash]. This entails a huge number of collisions in the
hash table and leads to cubic hash-consing in this worst-case.
In order to compute a hash key that is independent of the data
structure depth while being constant-time, an incremental hashing
function must be devised. A standard implementation creates a cache
of the hashing function by decorating each node of the hash-consed
data structure with its hash key. In that case, the hash function
can deduce the hash key of a toplevel data structure by a local
computation based on the cache held on its substructures.
Unfortunately, this simple implementation introduces a space
overhead that is damageable for the hash-consing of small [constr]s
(the most common case). One can think of an heterogeneous
distribution of caches on smartly chosen nodes, but this is forbidden
by the use of generic equality in Coq source code. (Indeed, this forces
each [constr] to have a unique canonical representation.)
Given that hash-consing proceeds inductively, we can nonetheless
computes the hash key incrementally during hash-consing by changing
a little the signature of the hash-consing function: it now returns
both the hash-consed term and its hash key. This simple solution is
implemented in the following code: it does not introduce a space
overhead in [constr], that's why the efficiency is unchanged for
small [constr]s. Besides, it does handle deep [constr]s without
introducing an unreasonable number of collisions in the hash table.
Some benchmarks make us think that this implementation of
hash-consing is linear in the size of the hash-consed data
structure for our daily use of Coq.
*)
let array_eqeq t1 t2 =
t1 == t2 ||
(Int.equal (Array.length t1) (Array.length t2) &&
let rec aux i =
(Int.equal i (Array.length t1)) || (t1.(i) == t2.(i) && aux (i + 1))
in aux 0)
let hasheq t1 t2 =
match t1, t2 with
| Rel n1, Rel n2 -> n1 == n2
| Meta m1, Meta m2 -> m1 == m2
| Var id1, Var id2 -> id1 == id2
| Sort s1, Sort s2 -> s1 == s2
| Cast (c1,k1,t1), Cast (c2,k2,t2) -> c1 == c2 && k1 == k2 && t1 == t2
| Prod (n1,t1,c1), Prod (n2,t2,c2) -> n1 == n2 && t1 == t2 && c1 == c2
| Lambda (n1,t1,c1), Lambda (n2,t2,c2) -> n1 == n2 && t1 == t2 && c1 == c2
| LetIn (n1,b1,t1,c1), LetIn (n2,b2,t2,c2) ->
n1 == n2 && b1 == b2 && t1 == t2 && c1 == c2
| App (c1,l1), App (c2,l2) -> c1 == c2 && array_eqeq l1 l2
| Proj (p1,c1), Proj(p2,c2) -> p1 == p2 && c1 == c2
| Evar (e1,l1), Evar (e2,l2) -> e1 == e2 && array_eqeq l1 l2
| Const (c1,u1), Const (c2,u2) -> c1 == c2 && u1 == u2
| Ind (ind1,u1), Ind (ind2,u2) -> ind1 == ind2 && u1 == u2
| Construct (cstr1,u1), Construct (cstr2,u2) -> cstr1 == cstr2 && u1 == u2
| Case (ci1,p1,c1,bl1), Case (ci2,p2,c2,bl2) ->
ci1 == ci2 && p1 == p2 && c1 == c2 && array_eqeq bl1 bl2
| Fix ((ln1, i1),(lna1,tl1,bl1)), Fix ((ln2, i2),(lna2,tl2,bl2)) ->
Int.equal i1 i2
&& Array.equal Int.equal ln1 ln2
&& array_eqeq lna1 lna2
&& array_eqeq tl1 tl2
&& array_eqeq bl1 bl2
| CoFix(ln1,(lna1,tl1,bl1)), CoFix(ln2,(lna2,tl2,bl2)) ->
Int.equal ln1 ln2
&& array_eqeq lna1 lna2
&& array_eqeq tl1 tl2
&& array_eqeq bl1 bl2
| (Rel _ | Meta _ | Var _ | Sort _ | Cast _ | Prod _ | Lambda _ | LetIn _
| App _ | Proj _ | Evar _ | Const _ | Ind _ | Construct _ | Case _
| Fix _ | CoFix _), _ -> false
(** Note that the following Make has the side effect of creating
once and for all the table we'll use for hash-consing all constr *)
module HashsetTerm =
Hashset.Make(struct type t = constr let eq = hasheq end)
module HashsetTermArray =
Hashset.Make(struct type t = constr array let eq = array_eqeq end)
let term_table = HashsetTerm.create 19991
(* The associative table to hashcons terms. *)
let term_array_table = HashsetTermArray.create 4999
(* The associative table to hashcons term arrays. *)
open Hashset.Combine
let hash_cast_kind = function
| VMcast -> 0
| NATIVEcast -> 1
| DEFAULTcast -> 2
| REVERTcast -> 3
let sh_instance = Univ.Instance.share
(* [hashcons hash_consing_functions constr] computes an hash-consed
representation for [constr] using [hash_consing_functions] on
leaves. *)
let hashcons (sh_sort,sh_ci,sh_construct,sh_ind,sh_con,sh_na,sh_id) =
let rec hash_term t =
match t with
| Var i ->
(Var (sh_id i), combinesmall 1 (Id.hash i))
| Sort s ->
(Sort (sh_sort s), combinesmall 2 (Sorts.hash s))
| Cast (c, k, t) ->
let c, hc = sh_rec c in
let t, ht = sh_rec t in
(Cast (c, k, t), combinesmall 3 (combine3 hc (hash_cast_kind k) ht))
| Prod (na,t,c) ->
let t, ht = sh_rec t
and c, hc = sh_rec c in
(Prod (sh_na na, t, c), combinesmall 4 (combine3 (Name.hash na) ht hc))
| Lambda (na,t,c) ->
let t, ht = sh_rec t
and c, hc = sh_rec c in
(Lambda (sh_na na, t, c), combinesmall 5 (combine3 (Name.hash na) ht hc))
| LetIn (na,b,t,c) ->
let b, hb = sh_rec b in
let t, ht = sh_rec t in
let c, hc = sh_rec c in
(LetIn (sh_na na, b, t, c), combinesmall 6 (combine4 (Name.hash na) hb ht hc))
| App (c,l) ->
let c, hc = sh_rec c in
let l, hl = hash_term_array l in
(App (c,l), combinesmall 7 (combine hl hc))
| Evar (e,l) ->
let l, hl = hash_term_array l in
(Evar (e,l), combinesmall 8 (combine (Evar.hash e) hl))
| Proj (p,c) ->
let c, hc = sh_rec c in
let p' = Projection.hcons p in
(Proj (p', c), combinesmall 17 (combine (Projection.SyntacticOrd.hash p') hc))
| Const (c,u) ->
let c' = sh_con c in
let u', hu = sh_instance u in
(Const (c', u'), combinesmall 9 (combine (Constant.SyntacticOrd.hash c) hu))
| Ind (ind,u) ->
let u', hu = sh_instance u in
(Ind (sh_ind ind, u'),
combinesmall 10 (combine (ind_syntactic_hash ind) hu))
| Construct (c,u) ->
let u', hu = sh_instance u in
(Construct (sh_construct c, u'),
combinesmall 11 (combine (constructor_syntactic_hash c) hu))
| Case (ci,p,c,bl) ->
let p, hp = sh_rec p
and c, hc = sh_rec c in
let bl,hbl = hash_term_array bl in
let hbl = combine (combine hc hp) hbl in
(Case (sh_ci ci, p, c, bl), combinesmall 12 hbl)
| Fix (ln,(lna,tl,bl)) ->
let bl,hbl = hash_term_array bl in
let tl,htl = hash_term_array tl in
let () = Array.iteri (fun i x -> Array.unsafe_set lna i (sh_na x)) lna in
let fold accu na = combine (Name.hash na) accu in
let hna = Array.fold_left fold 0 lna in
let h = combine3 hna hbl htl in
(Fix (ln,(lna,tl,bl)), combinesmall 13 h)
| CoFix(ln,(lna,tl,bl)) ->
let bl,hbl = hash_term_array bl in
let tl,htl = hash_term_array tl in
let () = Array.iteri (fun i x -> Array.unsafe_set lna i (sh_na x)) lna in
let fold accu na = combine (Name.hash na) accu in
let hna = Array.fold_left fold 0 lna in
let h = combine3 hna hbl htl in
(CoFix (ln,(lna,tl,bl)), combinesmall 14 h)
| Meta n ->
(t, combinesmall 15 n)
| Rel n ->
(t, combinesmall 16 n)
and sh_rec t =
let (y, h) = hash_term t in
(* [h] must be positive. *)
let h = h land 0x3FFFFFFF in
(HashsetTerm.repr h y term_table, h)
(* Note : During hash-cons of arrays, we modify them *in place* *)
and hash_term_array t =
let accu = ref 0 in
for i = 0 to Array.length t - 1 do
let x, h = sh_rec (Array.unsafe_get t i) in
accu := combine !accu h;
Array.unsafe_set t i x
done;
(* [h] must be positive. *)
let h = !accu land 0x3FFFFFFF in
(HashsetTermArray.repr h t term_array_table, h)
in
(* Make sure our statically allocated Rels (1 to 16) are considered
as canonical, and hence hash-consed to themselves *)
ignore (hash_term_array rels);
fun t -> fst (sh_rec t)
(* Exported hashing fonction on constr, used mainly in plugins.
Appears to have slight differences from [snd (hash_term t)] above ? *)
let rec hash t =
match kind t with
| Var i -> combinesmall 1 (Id.hash i)
| Sort s -> combinesmall 2 (Sorts.hash s)
| Cast (c, k, t) ->
let hc = hash c in
let ht = hash t in
combinesmall 3 (combine3 hc (hash_cast_kind k) ht)
| Prod (_, t, c) -> combinesmall 4 (combine (hash t) (hash c))
| Lambda (_, t, c) -> combinesmall 5 (combine (hash t) (hash c))
| LetIn (_, b, t, c) ->
combinesmall 6 (combine3 (hash b) (hash t) (hash c))
| App (Cast(c, _, _),l) -> hash (mkApp (c,l))
| App (c,l) ->
combinesmall 7 (combine (hash_term_array l) (hash c))
| Proj (p,c) ->
combinesmall 17 (combine (Projection.hash p) (hash c))
| Evar (e,l) ->
combinesmall 8 (combine (Evar.hash e) (hash_term_array l))
| Const (c,u) ->
combinesmall 9 (combine (Constant.hash c) (Instance.hash u))
| Ind (ind,u) ->
combinesmall 10 (combine (ind_hash ind) (Instance.hash u))
| Construct (c,u) ->
combinesmall 11 (combine (constructor_hash c) (Instance.hash u))
| Case (_ , p, c, bl) ->
combinesmall 12 (combine3 (hash c) (hash p) (hash_term_array bl))
| Fix (ln ,(_, tl, bl)) ->
combinesmall 13 (combine (hash_term_array bl) (hash_term_array tl))
| CoFix(ln, (_, tl, bl)) ->
combinesmall 14 (combine (hash_term_array bl) (hash_term_array tl))
| Meta n -> combinesmall 15 n
| Rel n -> combinesmall 16 n
and hash_term_array t =
Array.fold_left (fun acc t -> combine (hash t) acc) 0 t
module CaseinfoHash =
struct
type t = case_info
type u = inductive -> inductive
let hashcons hind ci = { ci with ci_ind = hind ci.ci_ind }
let pp_info_equal info1 info2 =
List.equal (==) info1.ind_tags info2.ind_tags &&
Array.equal (List.equal (==)) info1.cstr_tags info2.cstr_tags &&
info1.style == info2.style
let eq ci ci' =
ci.ci_ind == ci'.ci_ind &&
Int.equal ci.ci_npar ci'.ci_npar &&
Array.equal Int.equal ci.ci_cstr_ndecls ci'.ci_cstr_ndecls && (* we use [Array.equal] on purpose *)
Array.equal Int.equal ci.ci_cstr_nargs ci'.ci_cstr_nargs && (* we use [Array.equal] on purpose *)
pp_info_equal ci.ci_pp_info ci'.ci_pp_info (* we use (=) on purpose *)
open Hashset.Combine
let hash_bool b = if b then 0 else 1
let hash_bool_list = List.fold_left (fun n b -> combine n (hash_bool b))
let hash_pp_info info =
let h1 = match info.style with
| LetStyle -> 0
| IfStyle -> 1
| LetPatternStyle -> 2
| MatchStyle -> 3
| RegularStyle -> 4 in
let h2 = hash_bool_list 0 info.ind_tags in
let h3 = Array.fold_left hash_bool_list 0 info.cstr_tags in
combine3 h1 h2 h3
let hash ci =
let h1 = ind_hash ci.ci_ind in
let h2 = Int.hash ci.ci_npar in
let h3 = Array.fold_left combine 0 ci.ci_cstr_ndecls in
let h4 = Array.fold_left combine 0 ci.ci_cstr_nargs in
let h5 = hash_pp_info ci.ci_pp_info in
combine5 h1 h2 h3 h4 h5
end
module Hcaseinfo = Hashcons.Make(CaseinfoHash)
let case_info_hash = CaseinfoHash.hash
let hcons_caseinfo = Hashcons.simple_hcons Hcaseinfo.generate Hcaseinfo.hcons hcons_ind
let hcons =
hashcons
(Sorts.hcons,
hcons_caseinfo,
hcons_construct,
hcons_ind,
hcons_con,
Name.hcons,
Id.hcons)
(* let hcons_types = hcons_constr *)
|