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(************************************************************************)
(*  v      *   The Coq Proof Assistant  /  The Coq Development Team     *)
(* <O___,, *   INRIA - CNRS - LIX - LRI - PPS - Copyright 1999-2010     *)
(*   \VV/  **************************************************************)
(*    //   *      This file is distributed under the terms of the       *)
(*         *       GNU Lesser General Public License Version 2.1        *)
(************************************************************************)

(*i $Id$ i*)

(*i*)
open Names
(*i*)


(*s The sorts of CCI. *)

type contents = Pos | Null

type sorts =
  | Prop of contents       (* Prop and Set *)
  | Type of Univ.universe  (* Type *)

val set_sort  : sorts
val prop_sort : sorts
val type1_sort  : sorts

(*s The sorts family of CCI. *)

type sorts_family = InProp | InSet | InType

val family_of_sort : sorts -> sorts_family

(*s Useful types *)

(*s Existential variables *)
type existential_key = int

(*s Existential variables *)
type metavariable = int

(*s Case annotation *)
type case_style = LetStyle | IfStyle | LetPatternStyle | MatchStyle | RegularStyle
type case_printing =
  { ind_nargs : int; (* length of the arity of the inductive type *)
    style     : case_style }
(* the integer is the number of real args, needed for reduction *)
type case_info =
  { ci_ind        : inductive;
    ci_npar       : int;
    ci_cstr_nargs : int array; (* number of real args of each constructor *)
    ci_pp_info    : case_printing (* not interpreted by the kernel *)
  }

(*s*******************************************************************)
(* The type of constructions *)

type constr

(* [eq_constr a b] is true if [a] equals [b] modulo alpha, casts,
   and application grouping *)
val eq_constr : constr -> constr -> bool

(* [types] is the same as [constr] but is intended to be used for
   documentation to indicate that such or such function specifically works
   with {\em types} (i.e. terms of type a sort).
   (Rem:plurial form since [type] is a reserved ML keyword) *)

type types = constr

(*s Functions for dealing with constr terms.
  The following functions are intended to simplify and to uniform the
  manipulation of terms. Some of these functions may be overlapped with
  previous ones. *)

(*s Term constructors. *)

(* Constructs a DeBrujin index (DB indices begin at 1) *)
val mkRel : int -> constr

(* Constructs a Variable *)
val mkVar : identifier -> constr

(* Constructs an patvar named "?n" *)
val mkMeta : metavariable -> constr

(* Constructs an existential variable *)
type existential = existential_key * constr array
val mkEvar : existential -> constr

(* Construct a sort *)
val mkSort : sorts -> types
val mkProp : types
val mkSet  : types
val mkType : Univ.universe -> types


(* This defines the strategy to use for verifiying a Cast *)
type cast_kind = VMcast | DEFAULTcast

(* Constructs the term [t1::t2], i.e. the term $t_1$ casted with the
   type $t_2$ (that means t2 is declared as the type of t1). *)
val mkCast : constr * cast_kind * constr -> constr

(* Constructs the product [(x:t1)t2] *)
val mkProd : name * types * types -> types
val mkNamedProd : identifier -> types -> types -> types
(* non-dependant product $t_1 \rightarrow t_2$, an alias for
   [(_:t1)t2]. Beware $t_2$ is NOT lifted.
   Eg: A |- A->A is built by [(mkArrow (mkRel 0) (mkRel 1))] *)
val mkArrow : types -> types -> constr

(* Constructs the abstraction $[x:t_1]t_2$ *)
val mkLambda : name * types * constr -> constr
val mkNamedLambda : identifier -> types -> constr -> constr

(* Constructs the product [let x = t1 : t2 in t3] *)
val mkLetIn : name * constr * types * constr -> constr
val mkNamedLetIn : identifier -> constr -> types -> constr -> constr

(* [mkApp (f,[| t_1; ...; t_n |]] constructs the application
   $(f~t_1~\dots~t_n)$. *)
val mkApp : constr * constr array -> constr

(* Constructs a constant *)
(* The array of terms correspond to the variables introduced in the section *)
val mkConst : constant -> constr

(* Inductive types *)

(* Constructs the ith (co)inductive type of the block named kn *)
(* The array of terms correspond to the variables introduced in the section *)
val mkInd : inductive -> constr

(* Constructs the jth constructor of the ith (co)inductive type of the
   block named kn. The array of terms correspond to the variables
   introduced in the section *)
val mkConstruct : constructor -> constr

(* Constructs the term <p>Case c of c1 | c2 .. | cn end *)
val mkCase : case_info * constr * constr * constr array -> constr

(* If [recindxs = [|i1,...in|]]
      [funnames = [|f1,.....fn|]]
      [typarray = [|t1,...tn|]]
      [bodies   = [|b1,.....bn|]]
   then [ mkFix ((recindxs,i), funnames, typarray, bodies) ]
   constructs the $i$th function of the block (counting from 0)

    [Fixpoint f1 [ctx1] = b1
     with     f2 [ctx2] = b2
     ...
     with     fn [ctxn] = bn.]

   \noindent where the length of the $j$th context is $ij$.
*)
type rec_declaration = name array * types array * constr array
type fixpoint = (int array * int) * rec_declaration
val mkFix : fixpoint -> constr

(* If [funnames = [|f1,.....fn|]]
      [typarray = [|t1,...tn|]]
      [bodies   = [b1,.....bn]] \par\noindent
   then [mkCoFix (i, (typsarray, funnames, bodies))]
   constructs the ith function of the block

    [CoFixpoint f1 = b1
     with       f2 = b2
     ...
     with       fn = bn.]
 *)
type cofixpoint = int * rec_declaration
val mkCoFix : cofixpoint -> constr


(*s Concrete type for making pattern-matching. *)

(* [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 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 ('constr, 'types) kind_of_term =
  | Rel       of int
  | Var       of identifier
  | Meta      of metavariable
  | Evar      of 'constr pexistential
  | Sort      of sorts
  | Cast      of 'constr * cast_kind * 'types
  | Prod      of name * 'types * 'types
  | Lambda    of name * 'types * 'constr
  | LetIn     of name * 'constr * 'types * 'constr
  | App       of 'constr * 'constr array
  | Const     of constant
  | Ind       of inductive
  | Construct of constructor
  | Case      of case_info * 'constr * 'constr * 'constr array
  | Fix       of ('constr, 'types) pfixpoint
  | CoFix     of ('constr, 'types) pcofixpoint

(* User view of [constr]. For [App], it is ensured there is at
   least one argument and the function is not itself an applicative
   term *)

val kind_of_term : constr -> (constr, types) kind_of_term
val kind_of_term2 : constr -> ((constr,types) kind_of_term,constr) kind_of_term

(* Experimental *)
type ('constr, 'types) kind_of_type =
  | SortType   of sorts
  | CastType   of 'types * 'types
  | ProdType   of name * 'types * 'types
  | LetInType  of name * 'constr * 'types * 'types
  | AtomicType of 'constr * 'constr array

val kind_of_type : types -> (constr, types) kind_of_type

(*s Simple term case analysis. *)

val isRel  : constr -> bool
val isVar  : constr -> bool
val isInd  : constr -> bool
val isEvar : constr -> bool
val isMeta : constr -> bool
val isEvar_or_Meta : constr -> bool
val isSort : constr -> bool
val isCast : constr -> bool
val isApp : constr -> bool
val isLambda : constr -> bool
val isLetIn : constr -> bool
val isProd : constr -> bool
val isConst : constr -> bool
val isConstruct : constr -> bool
val isFix : constr -> bool
val isCoFix : constr -> bool
val isCase : constr -> bool

val is_Prop : constr -> bool
val is_Set  : constr -> bool
val isprop : constr -> bool
val is_Type : constr -> bool
val iskind : constr -> bool
val is_small : sorts -> bool

(*s Term destructors.
   Destructor operations are partial functions and
   raise [invalid_arg "dest*"] if the term has not the expected form. *)

(* Destructs a DeBrujin index *)
val destRel : constr -> int

(* Destructs an existential variable *)
val destMeta : constr -> metavariable

(* Destructs a variable *)
val destVar : constr -> identifier

(* Destructs a sort. [is_Prop] recognizes the sort \textsf{Prop}, whether
   [isprop] recognizes both \textsf{Prop} and \textsf{Set}. *)
val destSort : constr -> sorts

(* Destructs a casted term *)
val destCast : constr -> constr * cast_kind * constr

(* Destructs the product $(x:t_1)t_2$ *)
val destProd : types -> name * types * types

(* Destructs the abstraction $[x:t_1]t_2$ *)
val destLambda : constr -> name * types * constr

(* Destructs the let $[x:=b:t_1]t_2$ *)
val destLetIn : constr -> name * constr * types * constr

(* Destructs an application *)
val destApp : constr -> constr * constr array

(* Obsolete synonym of destApp *)
val destApplication : constr -> constr * constr array

(* Decompose any term as an applicative term; the list of args can be empty *)
val decompose_app : constr -> constr * constr list

(* Destructs a constant *)
val destConst : constr -> constant

(* Destructs an existential variable *)
val destEvar : constr -> existential

(* Destructs a (co)inductive type *)
val destInd : constr -> inductive

(* Destructs a constructor *)
val destConstruct : constr -> constructor

(* Destructs a term <p>Case c of lc1 | lc2 .. | lcn end *)
val destCase : constr -> case_info * constr * constr * constr array

(* Destructs the $i$th function of the block
   $\mathit{Fixpoint} ~ f_1 ~ [ctx_1] = b_1
    \mathit{with}     ~ f_2 ~ [ctx_2] = b_2
    \dots
    \mathit{with}     ~ f_n ~ [ctx_n] = b_n$,
   where the lenght of the $j$th context is $ij$.
*)
val destFix : constr -> fixpoint

val destCoFix : constr -> cofixpoint


(*s A {\em declaration} has the form (name,body,type). It is either an
    {\em assumption} if [body=None] or a {\em definition} if
    [body=Some actualbody]. It is referred by {\em name} if [na] is an
    identifier or by {\em relative index} if [na] is not an identifier
    (in the latter case, [na] is of type [name] but just for printing
    purpose *)

type named_declaration = identifier * constr option * types
type rel_declaration = name * constr option * types

val map_named_declaration :
  (constr -> constr) -> named_declaration -> named_declaration
val map_rel_declaration :
  (constr -> constr) -> rel_declaration -> rel_declaration

val fold_named_declaration :
  (constr -> 'a -> 'a) -> named_declaration -> 'a -> 'a
val fold_rel_declaration :
  (constr -> 'a -> 'a) -> rel_declaration -> 'a -> 'a

(*s Contexts of declarations referred to by de Bruijn indices *)

(* In [rel_context], more recent declaration is on top *)
type rel_context = rel_declaration list

val empty_rel_context : rel_context
val add_rel_decl : rel_declaration -> rel_context -> rel_context

val lookup_rel : int -> rel_context -> rel_declaration
val rel_context_length : rel_context -> int
val rel_context_nhyps : rel_context -> int

(* Constructs either [(x:t)c] or [[x=b:t]c] *)
val mkProd_or_LetIn : rel_declaration -> types -> types
val mkNamedProd_or_LetIn : named_declaration -> types -> types
val mkNamedProd_wo_LetIn : named_declaration -> types -> types

(* Constructs either [[x:t]c] or [[x=b:t]c] *)
val mkLambda_or_LetIn : rel_declaration -> constr -> constr
val mkNamedLambda_or_LetIn : named_declaration -> constr -> constr

(*s Other term constructors. *)

val abs_implicit : constr -> constr
val lambda_implicit : constr -> constr
val lambda_implicit_lift : int -> constr -> constr

(* [applist (f,args)] and co work as [mkApp] *)

val applist : constr * constr list -> constr
val applistc : constr -> constr list -> constr
val appvect : constr * constr array -> constr
val appvectc : constr -> constr array -> constr

(* [prodn n l b] = $(x_1:T_1)..(x_n:T_n)b$
   where $l = [(x_n,T_n);\dots;(x_1,T_1);Gamma]$ *)
val prodn : int -> (name * constr) list -> constr -> constr

(* [compose_prod l b] = $(x_1:T_1)..(x_n:T_n)b$
   where $l = [(x_n,T_n);\dots;(x_1,T_1)]$.
   Inverse of [decompose_prod]. *)
val compose_prod : (name * constr) list -> constr -> constr

(* [lamn n l b] = $[x_1:T_1]..[x_n:T_n]b$
   where $l = [(x_n,T_n);\dots;(x_1,T_1);Gamma]$ *)
val lamn : int -> (name * constr) list -> constr -> constr

(* [compose_lam l b] = $[x_1:T_1]..[x_n:T_n]b$
   where $l = [(x_n,T_n);\dots;(x_1,T_1)]$.
   Inverse of [it_destLam] *)
val compose_lam : (name * constr) list -> constr -> constr

(* [to_lambda n l]
   = $[x_1:T_1]...[x_n:T_n]T$
   where $l = (x_1:T_1)...(x_n:T_n)T$ *)
val to_lambda : int -> constr -> constr

(* [to_prod n l]
   = $(x_1:T_1)...(x_n:T_n)T$
   where $l = [x_1:T_1]...[x_n:T_n]T$ *)
val to_prod : int -> constr -> constr

(* pseudo-reduction rule *)

(* [prod_appvect] $(x1:B1;...;xn:Bn)B a1...an \rightarrow B[a1...an]$ *)
val prod_appvect : constr -> constr array -> constr
val prod_applist : constr -> constr list -> constr

val it_mkLambda_or_LetIn : constr -> rel_context -> constr
val it_mkProd_or_LetIn : types -> rel_context -> types

(*s Other term destructors. *)

(* Transforms a product term $(x_1:T_1)..(x_n:T_n)T$ into the pair
   $([(x_n,T_n);...;(x_1,T_1)],T)$, where $T$ is not a product.
   It includes also local definitions *)
val decompose_prod : constr -> (name*constr) list * constr

(* Transforms a lambda term $[x_1:T_1]..[x_n:T_n]T$ into the pair
   $([(x_n,T_n);...;(x_1,T_1)],T)$, where $T$ is not a lambda. *)
val decompose_lam : constr -> (name*constr) list * constr

(* Given a positive integer n, transforms a product term
   $(x_1:T_1)..(x_n:T_n)T$
   into the pair $([(xn,Tn);...;(x1,T1)],T)$. *)
val decompose_prod_n : int -> constr -> (name * constr) list * constr

(* Given a positive integer $n$, transforms a lambda term
   $[x_1:T_1]..[x_n:T_n]T$ into the pair $([(x_n,T_n);...;(x_1,T_1)],T)$ *)
val decompose_lam_n : int -> constr -> (name * constr) list * constr

(* Extract the premisses and the conclusion of a term of the form
   "(xi:Ti) ... (xj:=cj:Tj) ..., T" where T is not a product nor a let *)
val decompose_prod_assum : types -> rel_context * types

(* Idem with lambda's *)
val decompose_lam_assum : constr -> rel_context * constr

(* Idem but extract the first [n] premisses *)
val decompose_prod_n_assum : int -> types -> rel_context * types
val decompose_lam_n_assum : int -> constr -> rel_context * constr

(* [nb_lam] $[x_1:T_1]...[x_n:T_n]c$ where $c$ is not an abstraction
   gives $n$ (casts are ignored) *)
val nb_lam : constr -> int

(* Similar to [nb_lam], but gives the number of products instead *)
val nb_prod : constr -> int

(* Returns the premisses/parameters of a type/term (let-in included) *)
val prod_assum : types -> rel_context
val lam_assum : constr -> rel_context

(* Returns the first n-th premisses/parameters of a type/term (let included)*)
val prod_n_assum : int -> types -> rel_context
val lam_n_assum : int -> constr -> rel_context

(* Remove the premisses/parameters of a type/term *)
val strip_prod : types -> types
val strip_lam : constr -> constr

(* Remove the first n-th premisses/parameters of a type/term *)
val strip_prod_n : int -> types -> types
val strip_lam_n : int -> constr -> constr

(* Remove the premisses/parameters of a type/term (including let-in) *)
val strip_prod_assum : types -> types
val strip_lam_assum : constr -> constr

(* flattens application lists *)
val collapse_appl : constr -> constr


(* Removes recursively the casts around a term i.e.
   [strip_outer_cast] (Cast (Cast ... (Cast c, t) ... ))] is [c]. *)
val strip_outer_cast : constr -> constr

(* Apply a function letting Casted types in place *)
val under_casts : (constr -> constr) -> constr -> constr

(* Apply a function under components of Cast if any *)
val under_outer_cast : (constr -> constr) -> constr -> constr

(*s An "arity" is a term of the form [[x1:T1]...[xn:Tn]s] with [s] a sort.
    Such a term can canonically be seen as the pair of a context of types
    and of a sort *)

type arity = rel_context * sorts

(* Build an "arity" from its canonical form *)
val mkArity : arity -> types

(* Destructs an "arity" into its canonical form *)
val destArity : types -> arity

(* Tells if a term has the form of an arity *)
val isArity : types -> bool

(*s Occur checks *)

(* [closedn n M] is true iff [M] is a (deBruijn) closed term under n binders *)
val closedn : int -> constr -> bool

(* [closed0 M] is true iff [M] is a (deBruijn) closed term *)
val closed0 : constr -> bool

(* [noccurn n M] returns true iff [Rel n] does NOT occur in term [M]  *)
val noccurn : int -> constr -> bool

(* [noccur_between n m M] returns true iff [Rel p] does NOT occur in term [M]
  for n <= p < n+m *)
val noccur_between : int -> int -> constr -> bool

(* Checking function for terms containing existential- or
   meta-variables.  The function [noccur_with_meta] does not consider
   meta-variables applied to some terms (intented to be its local
   context) (for existential variables, it is necessarily the case) *)
val noccur_with_meta : int -> int -> constr -> bool

(*s Relocation and substitution *)

(* [exliftn el c] lifts [c] with lifting [el] *)
val exliftn : Esubst.lift -> constr -> constr

(* [liftn n k c] lifts by [n] indexes above or equal to [k] in [c] *)
val liftn : int -> int -> constr -> constr

(* [lift n c] lifts by [n] the positive indexes in [c] *)
val lift : int -> constr -> constr

(* [substnl [a1;...;an] k c] substitutes in parallel [a1],...,[an]
    for respectively [Rel(k+1)],...,[Rel(k+n)] in [c]; it relocates
    accordingly indexes in [a1],...,[an] *)
val substnl : constr list -> int -> constr -> constr
val substl : constr list -> constr -> constr
val subst1 : constr -> constr -> constr

val substnl_decl : constr list -> int -> rel_declaration -> rel_declaration
val substl_decl : constr list -> rel_declaration -> rel_declaration
val subst1_decl : constr -> rel_declaration -> rel_declaration

val subst1_named_decl : constr -> named_declaration -> named_declaration
val substl_named_decl : constr list -> named_declaration -> named_declaration

val replace_vars : (identifier * constr) list -> constr -> constr
val subst_var : identifier -> constr -> constr

(* [subst_vars [id1;...;idn] t] substitute [VAR idj] by [Rel j] in [t]
   if two names are identical, the one of least indice is kept *)
val subst_vars : identifier list -> constr -> constr
(* [substn_vars n [id1;...;idn] t] substitute [VAR idj] by [Rel j+n-1] in [t]
   if two names are identical, the one of least indice is kept *)
val substn_vars : int -> identifier list -> constr -> constr


(*s Functionals working on the immediate subterm of a construction *)

(* [fold_constr 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 *)

val fold_constr : ('a -> constr -> 'a) -> 'a -> constr -> 'a

(* [map_constr 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 *)

val map_constr : (constr -> constr) -> constr -> constr

(* [map_constr_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 *)

val map_constr_with_binders :
  ('a -> 'a) -> ('a -> constr -> constr) -> 'a -> constr -> constr

(* [iter_constr 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 *)

val iter_constr : (constr -> unit) -> constr -> unit

(* [iter_constr_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 *)

val iter_constr_with_binders :
  ('a -> 'a) -> ('a -> constr -> unit) -> 'a -> constr -> unit

(* [compare_constr f c1 c2] compare [c1] and [c2] using [f] to compare
   the immediate subterms of [c1] of [c2] if needed; Cast's, binders
   name and Cases annotations are not taken into account *)

val compare_constr : (constr -> constr -> bool) -> constr -> constr -> bool

(*********************************************************************)

val hcons_constr:
  (constant -> constant) *
  (mutual_inductive -> mutual_inductive) *
  (dir_path -> dir_path) *
  (name -> name) *
  (identifier -> identifier) *
  (string -> string)
  ->
    (constr -> constr) *
    (types -> types)

val hcons1_constr : constr -> constr
val hcons1_types : types -> types

(**************************************)

type values