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(************************************************************************)
(* v * The Coq Proof Assistant / The Coq Development Team *)
(* <O___,, * INRIA - CNRS - LIX - LRI - PPS - Copyright 1999-2011 *)
(* \VV/ **************************************************************)
(* // * This file is distributed under the terms of the *)
(* * GNU Lesser General Public License Version 2.1 *)
(************************************************************************)
(*i $Id: esubst.mli 14641 2011-11-06 11:59:10Z herbelin $ i*)
(*s Explicit substitutions of type ['a]. *)
(* - ESID(n) = %n END bounded identity
* - CONS([|t1..tn|],S) = (S.t1...tn) parallel substitution
* (beware of the order: indice 1 is substituted by tn)
* - SHIFT(n,S) = (^n o S) terms in S are relocated with n vars
* - LIFT(n,S) = (%n S) stands for ((^n o S).n...1)
(corresponds to S crossing n binders) *)
type 'a subs =
| ESID of int
| CONS of 'a array * 'a subs
| SHIFT of int * 'a subs
| LIFT of int * 'a subs
(* Derived constructors granting basic invariants *)
val subs_cons: 'a array * 'a subs -> 'a subs
val subs_shft: int * 'a subs -> 'a subs
val subs_lift: 'a subs -> 'a subs
val subs_liftn: int -> 'a subs -> 'a subs
(* [subs_shift_cons(k,s,[|t1..tn|])] builds (^k s).t1..tn *)
val subs_shift_cons: int * 'a subs * 'a array -> 'a subs
(* [expand_rel k subs] expands de Bruijn [k] in the explicit substitution
* [subs]. The result is either (Inl(lams,v)) when the variable is
* substituted by value [v] under lams binders (i.e. v *has* to be
* shifted by lams), or (Inr (k',p)) when the variable k is just relocated
* as k'; p is None if the variable points inside subs and Some(k) if the
* variable points k bindings beyond subs (cf argument of ESID).
*)
val expand_rel: int -> 'a subs -> (int * 'a, int * int option) Util.union
(* Tests whether a substitution behaves like the identity *)
val is_subs_id: 'a subs -> bool
(* Composition of substitutions: [comp mk_clos s1 s2] computes a
* substitution equivalent to applying s2 then s1. Argument
* mk_clos is used when a closure has to be created, i.e. when
* s1 is applied on an element of s2.
*)
val comp : ('a subs * 'a -> 'a) -> 'a subs -> 'a subs -> 'a subs
(*s Compact representation of explicit relocations. \\
[ELSHFT(l,n)] == lift of [n], then apply [lift l].
[ELLFT(n,l)] == apply [l] to de Bruijn > [n] i.e under n binders. *)
type lift =
| ELID
| ELSHFT of lift * int
| ELLFT of int * lift
val el_shft : int -> lift -> lift
val el_liftn : int -> lift -> lift
val el_lift : lift -> lift
val reloc_rel : int -> lift -> int
val is_lift_id : lift -> bool
|