(************************************************************************) (* * The Coq Proof Assistant / The Coq Development Team *) (* v * Copyright INRIA, CNRS and contributors *) (* t -> bool (** Equality over identifiers. *) val compare : t -> t -> int (** Comparison over identifiers. *) val hash : t -> int (** Hash over identifiers. *) val is_valid : string -> bool (** Check that a string may be converted to an identifier. *) val is_valid_ident_part : string -> bool (** Check that a string is a valid part of an identifier *) val of_bytes : bytes -> t val of_string : string -> t (** Converts a string into an identifier. @raise UserError if the string is invalid as an identifier. *) val of_string_soft : string -> t (** Same as {!of_string} except that any string made of supported UTF-8 characters is accepted. @raise UserError if the string is invalid as an UTF-8 string. *) val to_string : t -> string (** Converts a identifier into an string. *) val print : t -> Pp.t (** Pretty-printer. *) module Set : Set.S with type elt = t (** Finite sets of identifiers. *) module Map : Map.ExtS with type key = t and module Set := Set (** Finite maps of identifiers. *) module Pred : Predicate.S with type elt = t (** Predicates over identifiers. *) module List : List.MonoS with type elt = t (** Operations over lists of identifiers. *) val hcons : t -> t (** Hashconsing of identifiers. *) end (** Representation and operations on identifiers that are allowed to be anonymous (i.e. "_" in concrete syntax). *) module Name : sig type t = Anonymous (** anonymous identifier *) | Name of Id.t (** non-anonymous identifier *) val mk_name : Id.t -> t (** constructor *) val is_anonymous : t -> bool (** Return [true] iff a given name is [Anonymous]. *) val is_name : t -> bool (** Return [true] iff a given name is [Name _]. *) val compare : t -> t -> int (** Comparison over names. *) val equal : t -> t -> bool (** Equality over names. *) val hash : t -> int (** Hash over names. *) val hcons : t -> t (** Hashconsing over names. *) val print : t -> Pp.t (** Pretty-printer (print "_" for [Anonymous]. *) end (** {6 Type aliases} *) type name = Name.t = Anonymous | Name of Id.t [@@ocaml.deprecated "Use Name.t"] type variable = Id.t type module_ident = Id.t module ModIdset : Set.S with type elt = module_ident module ModIdmap : Map.ExtS with type key = module_ident and module Set := ModIdset (** {6 Directory paths = section names paths } *) module DirPath : sig type t (** Type of directory paths. Essentially a list of module identifiers. The order is reversed to improve sharing. E.g. A.B.C is ["C";"B";"A"] *) val equal : t -> t -> bool (** Equality over directory paths. *) val compare : t -> t -> int (** Comparison over directory paths. *) val hash : t -> int (** Hash over directory paths. *) val make : module_ident list -> t (** Create a directory path. (The list must be reversed). *) val repr : t -> module_ident list (** Represent a directory path. (The result list is reversed). *) val empty : t (** The empty directory path. *) val is_empty : t -> bool (** Test whether a directory path is empty. *) val initial : t (** Initial "seed" of the unique identifier generator *) val hcons : t -> t (** Hashconsing of directory paths. *) val to_string : t -> string (** Print non-empty directory paths as ["coq_root.module.submodule"] *) val print : t -> Pp.t end module DPset : Set.S with type elt = DirPath.t module DPmap : Map.ExtS with type key = DirPath.t and module Set := DPset (** {6 Names of structure elements } *) module Label : sig type t (** Type of labels *) val equal : t -> t -> bool (** Equality over labels *) val compare : t -> t -> int (** Comparison over labels. *) val hash : t -> int (** Hash over labels. *) val make : string -> t (** Create a label out of a string. *) val of_id : Id.t -> t (** Conversion from an identifier. *) val to_id : t -> Id.t (** Conversion to an identifier. *) val to_string : t -> string (** Conversion to string. *) val print : t -> Pp.t (** Pretty-printer. *) module Set : Set.S with type elt = t module Map : Map.ExtS with type key = t and module Set := Set val hcons : t -> t end (** {6 Unique names for bound modules} *) module MBId : sig type t (** Unique names for bound modules. Each call to [make] constructs a fresh unique identifier. *) val equal : t -> t -> bool (** Equality over unique bound names. *) val compare : t -> t -> int (** Comparison over unique bound names. *) val hash : t -> int (** Hash over unique bound names. *) val make : DirPath.t -> Id.t -> t (** The first argument is a file name, to prevent conflict between different files. *) val repr : t -> int * Id.t * DirPath.t (** Reverse of [make]. *) val to_id : t -> Id.t (** Return the identifier contained in the argument. *) val to_string : t -> string (** Encode as a string (not to be used for user-facing messages). *) val debug_to_string : t -> string (** Same as [to_string], but outputs extra information related to debug. *) end module MBIset : Set.S with type elt = MBId.t module MBImap : Map.ExtS with type key = MBId.t and module Set := MBIset (** {6 The module part of the kernel name } *) module ModPath : sig type t = | MPfile of DirPath.t | MPbound of MBId.t | MPdot of t * Label.t val compare : t -> t -> int val equal : t -> t -> bool val hash : t -> int val is_bound : t -> bool val initial : t (** Name of the toplevel structure ([= MPfile initial_dir]) *) val dp : t -> DirPath.t val to_string : t -> string (** Encode as a string (not to be used for user-facing messages). *) val debug_to_string : t -> string (** Same as [to_string], but outputs extra information related to debug. *) end module MPset : Set.S with type elt = ModPath.t module MPmap : Map.ExtS with type key = ModPath.t and module Set := MPset (** {6 The absolute names of objects seen by kernel } *) module KerName : sig type t (** Constructor and destructor *) val make : ModPath.t -> Label.t -> t val repr : t -> ModPath.t * Label.t (** Projections *) val modpath : t -> ModPath.t val label : t -> Label.t val to_string : t -> string (** Encode as a string (not to be used for user-facing messages). *) val print : t -> Pp.t (** Print internal representation (not to be used for user-facing messages). *) val debug_to_string : t -> string (** Same as [to_string], but outputs extra information related to debug. *) val debug_print : t -> Pp.t (** Same as [print], but outputs extra information related to debug. *) (** Comparisons *) val compare : t -> t -> int val equal : t -> t -> bool val hash : t -> int end module KNset : CSig.SetS with type elt = KerName.t module KNpred : Predicate.S with type elt = KerName.t module KNmap : Map.ExtS with type key = KerName.t and module Set := KNset (** {6 Signature for quotiented names} *) module type EqType = sig type t val compare : t -> t -> int val equal : t -> t -> bool val hash : t -> int end module type QNameS = sig type t (** A type of reference that implements an implicit quotient by containing two different names. The first one is the user name, i.e. what the user sees when printing. The second one is the canonical name, which is the actual absolute name of the reference. This mechanism is fundamentally tied to the module system of Coq. Functor application and module inclusion are the typical ways to introduce names where the canonical and user components differ. In particular, the two components should be undistinguishable from the point of view of typing, i.e. from a "kernel" ground. This aliasing only makes sense inside an environment, but at this point this notion is not even defined so, this dual name trick is fragile. One has to ensure many invariants when creating such names, but the kernel is quite lenient when it comes to checking that these invariants hold. (Read: there are soundness bugs lurking in the module system.) One could enforce the invariants by splitting the names and storing that information in the environment instead, but unfortunately, this wreaks havoc in the upper layers. The latter are infamously not stable by syntactic equality, in particular they might observe the difference between canonical and user names if not packed together. For this reason, it is discouraged to use the canonical-accessing API in the upper layers, notably the [CanOrd] module below. Instead, one should use their quotiented versions defined in the [Environ] module. Eventually all uses to [CanOrd] outside of the kernel should be removed. CAVEAT: name sets and maps are still exposing a canonical-accessing API surreptitiously. *) module CanOrd : EqType with type t = t (** Equality functions over the canonical name. Their use should be restricted to the kernel. *) module UserOrd : EqType with type t = t (** Equality functions over the user name. *) module SyntacticOrd : EqType with type t = t (** Equality functions using both names, for low-level uses. *) end (** {6 Constant Names } *) module Constant: sig type t (** Constructors *) val make : KerName.t -> KerName.t -> t (** Builds a constant name from a user and a canonical kernel name. *) val make1 : KerName.t -> t (** Special case of [make] where the user name is canonical. *) val make2 : ModPath.t -> Label.t -> t (** Shortcut for [(make1 (KerName.make2 ...))] *) (** Projections *) val user : t -> KerName.t val canonical : t -> KerName.t val repr2 : t -> ModPath.t * Label.t (** Shortcut for [KerName.repr (user ...)] *) val modpath : t -> ModPath.t (** Shortcut for [KerName.modpath (user ...)] *) val label : t -> Label.t (** Shortcut for [KerName.label (user ...)] *) (** Comparisons *) include QNameS with type t := t val equal : t -> t -> bool [@@ocaml.deprecated "Use QConstant.equal"] (** Default comparison, alias for [CanOrd.equal] *) val hash : t -> int [@@ocaml.deprecated "Use QConstant.hash"] (** Hashing function *) val change_label : t -> Label.t -> t (** Builds a new constant name with a different label *) (** Displaying *) val to_string : t -> string (** Encode as a string (not to be used for user-facing messages). *) val print : t -> Pp.t (** Print internal representation (not to be used for user-facing messages). *) val debug_to_string : t -> string (** Same as [to_string], but outputs extra information related to debug. *) val debug_print : t -> Pp.t (** Same as [print], but outputs extra information related to debug. *) end (** The [*_env] modules consider an order on user part of names the others consider an order on canonical part of names*) module Cpred : Predicate.S with type elt = Constant.t module Cset : CSig.SetS with type elt = Constant.t module Cset_env : CSig.SetS with type elt = Constant.t module Cmap : Map.ExtS with type key = Constant.t and module Set := Cset (** A map whose keys are constants (values of the {!Constant.t} type). Keys are ordered wrt. "canonical form" of the constant. *) module Cmap_env : Map.ExtS with type key = Constant.t and module Set := Cset_env (** A map whose keys are constants (values of the {!Constant.t} type). Keys are ordered wrt. "user form" of the constant. *) (** {6 Inductive names} *) module MutInd : sig type t (** Constructors *) val make : KerName.t -> KerName.t -> t (** Builds a mutual inductive name from a user and a canonical kernel name. *) val make1 : KerName.t -> t (** Special case of [make] where the user name is canonical. *) val make2 : ModPath.t -> Label.t -> t (** Shortcut for [(make1 (KerName.make2 ...))] *) (** Projections *) val user : t -> KerName.t val canonical : t -> KerName.t val repr2 : t -> ModPath.t * Label.t (** Shortcut for [KerName.repr (user ...)] *) val modpath : t -> ModPath.t (** Shortcut for [KerName.modpath (user ...)] *) val label : t -> Label.t (** Shortcut for [KerName.label (user ...)] *) (** Comparisons *) include QNameS with type t := t val equal : t -> t -> bool [@@ocaml.deprecated "Use QMutInd.equal"] (** Default comparison, alias for [CanOrd.equal] *) val hash : t -> int [@@ocaml.deprecated "Use QMutInd.hash"] (** Displaying *) val to_string : t -> string (** Encode as a string (not to be used for user-facing messages). *) val print : t -> Pp.t (** Print internal representation (not to be used for user-facing messages). *) val debug_to_string : t -> string (** Same as [to_string], but outputs extra information related to debug. *) val debug_print : t -> Pp.t (** Same as [print], but outputs extra information related to debug. *) end module Mindset : CSig.SetS with type elt = MutInd.t module Mindmap : Map.ExtS with type key = MutInd.t and module Set := Mindset module Mindmap_env : CMap.ExtS with type key = MutInd.t module Ind : sig (** Designation of a (particular) inductive type. *) type t = MutInd.t (* the name of the inductive type *) * int (* the position of this inductive type within the block of mutually-recursive inductive types. BEWARE: indexing starts from 0. *) val modpath : t -> ModPath.t include QNameS with type t := t end type inductive = Ind.t module Construct : sig (** Designation of a (particular) constructor of a (particular) inductive type. *) type t = Ind.t (* designates the inductive type *) * int (* the index of the constructor BEWARE: indexing starts from 1. *) val modpath : t -> ModPath.t include QNameS with type t := t end type constructor = Construct.t module Indset : CSet.S with type elt = inductive module Constrset : CSet.S with type elt = constructor module Indset_env : CSet.S with type elt = inductive module Constrset_env : CSet.S with type elt = constructor module Indmap : CMap.ExtS with type key = inductive and module Set := Indset module Constrmap : CMap.ExtS with type key = constructor and module Set := Constrset module Indmap_env : CMap.ExtS with type key = inductive and module Set := Indset_env module Constrmap_env : CMap.ExtS with type key = constructor and module Set := Constrset_env val ind_modpath : inductive -> ModPath.t [@@ocaml.deprecated "Use the Ind module"] val constr_modpath : constructor -> ModPath.t [@@ocaml.deprecated "Use the Construct module"] val ith_mutual_inductive : inductive -> int -> inductive val ith_constructor_of_inductive : inductive -> int -> constructor val inductive_of_constructor : constructor -> inductive val index_of_constructor : constructor -> int val eq_ind : inductive -> inductive -> bool [@@ocaml.deprecated "Use the Ind module"] val eq_user_ind : inductive -> inductive -> bool [@@ocaml.deprecated "Use the Ind module"] val eq_syntactic_ind : inductive -> inductive -> bool [@@ocaml.deprecated "Use the Ind module"] val ind_ord : inductive -> inductive -> int [@@ocaml.deprecated "Use the Ind module"] val ind_hash : inductive -> int [@@ocaml.deprecated "Use the Ind module"] val ind_user_ord : inductive -> inductive -> int [@@ocaml.deprecated "Use the Ind module"] val ind_user_hash : inductive -> int [@@ocaml.deprecated "Use the Ind module"] val ind_syntactic_ord : inductive -> inductive -> int [@@ocaml.deprecated "Use the Ind module"] val ind_syntactic_hash : inductive -> int [@@ocaml.deprecated "Use the Ind module"] val eq_constructor : constructor -> constructor -> bool [@@ocaml.deprecated "Use the Construct module"] val eq_user_constructor : constructor -> constructor -> bool [@@ocaml.deprecated "Use the Construct module"] val eq_syntactic_constructor : constructor -> constructor -> bool [@@ocaml.deprecated "Use the Construct module"] val constructor_ord : constructor -> constructor -> int [@@ocaml.deprecated "Use the Construct module"] val constructor_hash : constructor -> int [@@ocaml.deprecated "Use the Construct module"] val constructor_user_ord : constructor -> constructor -> int [@@ocaml.deprecated "Use the Construct module"] val constructor_user_hash : constructor -> int [@@ocaml.deprecated "Use the Construct module"] val constructor_syntactic_ord : constructor -> constructor -> int [@@ocaml.deprecated "Use the Construct module"] val constructor_syntactic_hash : constructor -> int [@@ocaml.deprecated "Use the Construct module"] (** {6 Hash-consing } *) val hcons_con : Constant.t -> Constant.t val hcons_mind : MutInd.t -> MutInd.t val hcons_ind : inductive -> inductive val hcons_construct : constructor -> constructor (******) type 'a tableKey = | ConstKey of 'a | VarKey of Id.t | RelKey of Int.t type inv_rel_key = int (** index in the [rel_context] part of environment starting by the end, {e inverse} of de Bruijn indice *) val eq_table_key : ('a -> 'a -> bool) -> 'a tableKey -> 'a tableKey -> bool val eq_constant_key : Constant.t -> Constant.t -> bool (** equalities on constant and inductive names (for the checker) *) val eq_ind_chk : inductive -> inductive -> bool (** {5 Module paths} *) type module_path = ModPath.t = | MPfile of DirPath.t | MPbound of MBId.t | MPdot of ModPath.t * Label.t [@@ocaml.deprecated "Alias type"] module Projection : sig module Repr : sig type t val make : inductive -> proj_npars:int -> proj_arg:int -> Label.t -> t include QNameS with type t := t val constant : t -> Constant.t (** Don't use this if you don't have to. *) val inductive : t -> inductive val mind : t -> MutInd.t val npars : t -> int val arg : t -> int val label : t -> Label.t val equal : t -> t -> bool [@@ocaml.deprecated "Use QProjection.equal"] val hash : t -> int [@@ocaml.deprecated "Use QProjection.hash"] val compare : t -> t -> int [@@ocaml.deprecated "Use QProjection.compare"] val map : (MutInd.t -> MutInd.t) -> t -> t val map_npars : (MutInd.t -> int -> MutInd.t * int) -> t -> t val to_string : t -> string (** Encode as a string (not to be used for user-facing messages). *) val print : t -> Pp.t (** Print internal representation (not to be used for user-facing messages). *) end type t (* = Repr.t * bool *) val make : Repr.t -> bool -> t val repr : t -> Repr.t include QNameS with type t := t val constant : t -> Constant.t val mind : t -> MutInd.t val inductive : t -> inductive val npars : t -> int val arg : t -> int val label : t -> Label.t val unfolded : t -> bool val unfold : t -> t val equal : t -> t -> bool [@@ocaml.deprecated "Use QProjection.equal"] val hash : t -> int [@@ocaml.deprecated "Use QProjection.hash"] val hcons : t -> t (** Hashconsing of projections. *) val repr_equal : t -> t -> bool [@@ocaml.deprecated "Use an explicit projection of Repr"] (** Ignoring the unfolding boolean. *) val compare : t -> t -> int [@@ocaml.deprecated "Use QProjection.compare"] val map : (MutInd.t -> MutInd.t) -> t -> t val map_npars : (MutInd.t -> int -> MutInd.t * int) -> t -> t val to_string : t -> string (** Encode as a string (not to be used for user-facing messages). *) val print : t -> Pp.t (** Print internal representation (not to be used for user-facing messages). *) end (** {6 Global reference is a kernel side type for all references together } *) (* XXX: Should we define GlobRefCan GlobRefUser? *) module GlobRef : sig type t = | VarRef of variable (** A reference to the section-context. *) | ConstRef of Constant.t (** A reference to the environment. *) | IndRef of inductive (** A reference to an inductive type. *) | ConstructRef of constructor (** A reference to a constructor of an inductive type. *) val equal : t -> t -> bool include QNameS with type t := t module Set_env : CSig.SetS with type elt = t module Map_env : Map.ExtS with type key = t and module Set := Set_env module Set : CSig.SetS with type elt = t module Map : Map.ExtS with type key = t and module Set := Set end (** Better to have it here that in Closure, since required in grammar.cma *) (* XXX: Move to a module *) type evaluable_global_reference = | EvalVarRef of Id.t | EvalConstRef of Constant.t val eq_egr : evaluable_global_reference -> evaluable_global_reference -> bool (** Located identifiers and objects with syntax. *) type lident = Id.t CAst.t type lname = Name.t CAst.t type lstring = string CAst.t