ocaml/typing/types.mli

467 lines
16 KiB
OCaml

(**************************************************************************)
(* *)
(* OCaml *)
(* *)
(* Xavier Leroy, projet Cristal, INRIA Rocquencourt *)
(* *)
(* Copyright 1996 Institut National de Recherche en Informatique et *)
(* en Automatique. *)
(* *)
(* All rights reserved. This file is distributed under the terms of *)
(* the GNU Lesser General Public License version 2.1, with the *)
(* special exception on linking described in the file LICENSE. *)
(* *)
(**************************************************************************)
(** {0 Representation of types and declarations} *)
(** [Types] defines the representation of types and declarations (that is, the
content of module signatures).
CMI files are made of marshalled types.
*)
(** Asttypes exposes basic definitions shared both by Parsetree and Types. *)
open Asttypes
(** Type expressions for the core language.
The [type_desc] variant defines all the possible type expressions one can
find in OCaml. [type_expr] wraps this with some annotations.
The [level] field tracks the level of polymorphism associated to a type,
guiding the generalization algorithm.
Put shortly, when referring to a type in a given environment, both the type
and the environment have a level. If the type has an higher level, then it
can be considered fully polymorphic (type variables will be printed as
['a]), otherwise it'll be weakly polymorphic, or non generalized (type
variables printed as ['_a]).
See [http://okmij.org/ftp/ML/generalization.html] for more information.
Note about [type_declaration]: one should not make the confusion between
[type_expr] and [type_declaration].
[type_declaration] refers specifically to the [type] construct in OCaml
language, where you create and name a new type or type alias.
[type_expr] is used when you refer to existing types, e.g. when annotating
the expected type of a value.
Also, as the type system of OCaml is generative, a [type_declaration] can
have the side-effect of introducing a new type constructor, different from
all other known types.
Whereas [type_expr] is a pure construct which allows referring to existing
types.
Note on mutability: TBD.
*)
type type_expr =
{ mutable desc: type_desc;
mutable level: int;
id: int }
and type_desc =
| Tvar of string option
(** [Tvar (Some "a")] ==> ['a] or ['_a]
[Tvar None] ==> [_] *)
| Tarrow of arg_label * type_expr * type_expr * commutable
(** [Tarrow (Nolabel, e1, e2, c)] ==> [e1 -> e2]
[Tarrow (Labelled "l", e1, e2, c)] ==> [l:e1 -> e2]
[Tarrow (Optional "l", e1, e2, c)] ==> [?l:e1 -> e2]
See [commutable] for the last argument. *)
| Ttuple of type_expr list
(** [Ttuple [t1;...;tn]] ==> [(t1 * ... * tn)] *)
| Tconstr of Path.t * type_expr list * abbrev_memo ref
(** [Tconstr (`A.B.t', [t1;...;tn], _)] ==> [(t1,...,tn) A.B.t]
The last parameter keep tracks of known expansions, see [abbrev_memo]. *)
| Tobject of type_expr * (Path.t * type_expr list) option ref
(** [Tobject (`f1:t1;...;fn: tn', `None')] ==> [< f1: t1; ...; fn: tn >]
f1, fn are represented as a linked list of types using Tfield and Tnil
constructors.
[Tobject (_, `Some (`A.ct', [t1;...;tn]')] ==> [(t1, ..., tn) A.ct].
where A.ct is the type of some class.
There are also special cases for so-called "class-types", cf. [Typeclass]
and [Ctype.set_object_name]:
[Tobject (Tfield(_,_,...(Tfield(_,_,rv)...),
Some(`A.#ct`, [rv;t1;...;tn])]
==> [(t1, ..., tn) #A.ct]
[Tobject (_, Some(`A.#ct`, [Tnil;t1;...;tn])] ==> [(t1, ..., tn) A.ct]
where [rv] is the hidden row variable.
*)
| Tfield of string * field_kind * type_expr * type_expr
(** [Tfield ("foo", Fpresent, t, ts)] ==> [<...; foo : t; ts>] *)
| Tnil
(** [Tnil] ==> [<...; >] *)
| Tlink of type_expr
(** Indirection used by unification engine. *)
| Tsubst of type_expr (* for copying *)
(** [Tsubst] is used temporarily to store information in low-level
functions manipulating representation of types, such as
instantiation or copy.
This constructor should not appear outside of these cases. *)
| Tvariant of row_desc
(** Representation of polymorphic variants, see [row_desc]. *)
| Tunivar of string option
(** Occurrence of a type variable introduced by a
forall quantifier / [Tpoly]. *)
| Tpoly of type_expr * type_expr list
(** [Tpoly (ty,tyl)] ==> ['a1... 'an. ty],
where 'a1 ... 'an are names given to types in tyl
and occurences of those types in ty. *)
| Tpackage of Path.t * Longident.t list * type_expr list
(** Type of a first-class module (a.k.a package). *)
(** [ `X | `Y ] (row_closed = true)
[< `X | `Y ] (row_closed = true)
[> `X | `Y ] (row_closed = false)
[< `X | `Y > `X ] (row_closed = true)
type t = [> `X ] as 'a (row_more = Tvar a)
type t = private [> `X ] (row_more = Tconstr (t#row, [], ref Mnil)
And for:
let f = function `X -> `X -> | `Y -> `X
the type of "f" will be a [Tarrow] whose lhs will (basically) be:
Tvariant { row_fields = [("X", _)];
row_more =
Tvariant { row_fields = [("Y", _)];
row_more =
Tvariant { row_fields = [];
row_more = _;
_ };
_ };
_
}
*)
and row_desc =
{ row_fields: (label * row_field) list;
row_more: type_expr;
row_bound: unit; (* kept for compatibility *)
row_closed: bool;
row_fixed: bool;
row_name: (Path.t * type_expr list) option }
and row_field =
Rpresent of type_expr option
| Reither of bool * type_expr list * bool * row_field option ref
(* 1st true denotes a constant constructor *)
(* 2nd true denotes a tag in a pattern matching, and
is erased later *)
| Rabsent
(** [abbrev_memo] allows one to keep track of different expansions of a type
alias. This is done for performance purposes.
For instance, when defining [type 'a pair = 'a * 'a], when one refers to an
['a pair], it is just a shortcut for the ['a * 'a] type.
This expansion will be stored in the [abbrev_memo] of the corresponding
[Tconstr] node.
In practice, [abbrev_memo] behaves like list of expansions with a mutable
tail.
Note on marshalling: [abbrev_memo] must not appear in saved types.
[Btype], with [cleanup_abbrev] and [memo], takes care of tracking and
removing abbreviations.
*)
and abbrev_memo =
| Mnil (** No known abbrevation *)
| Mcons of private_flag * Path.t * type_expr * type_expr * abbrev_memo
(** Found one abbreviation.
A valid abbreviation should be at least as visible and reachable by the
same path.
The first expression is the abbreviation and the second the expansion. *)
| Mlink of abbrev_memo ref
(** Abbreviations can be found after this indirection *)
and field_kind =
Fvar of field_kind option ref
| Fpresent
| Fabsent
(** [commutable] is a flag appended to every arrow type.
When typing an application, if the type of the functional is
known, its type is instantiated with [Cok] arrows, otherwise as
[Clink (ref Cunknown)].
When the type is not known, the application will be used to infer
the actual type. This is fragile in presence of labels where
there is no principal type.
Two incompatible applications relying on [Cunknown] arrows will
trigger an error.
let f g =
g ~a:() ~b:();
g ~b:() ~a:();
Error: This function is applied to arguments
in an order different from other calls.
This is only allowed when the real type is known.
*)
and commutable =
Cok
| Cunknown
| Clink of commutable ref
module TypeOps : sig
type t = type_expr
val compare : t -> t -> int
val equal : t -> t -> bool
val hash : t -> int
end
(* Maps of methods and instance variables *)
module Meths : Map.S with type key = string
module Vars : Map.S with type key = string
(* Value descriptions *)
type value_description =
{ val_type: type_expr; (* Type of the value *)
val_kind: value_kind;
val_loc: Location.t;
val_attributes: Parsetree.attributes;
}
and value_kind =
Val_reg (* Regular value *)
| Val_prim of Primitive.description (* Primitive *)
| Val_ivar of mutable_flag * string (* Instance variable (mutable ?) *)
| Val_self of (Ident.t * type_expr) Meths.t ref *
(Ident.t * mutable_flag * virtual_flag * type_expr) Vars.t ref *
string * type_expr
(* Self *)
| Val_anc of (string * Ident.t) list * string
(* Ancestor *)
| Val_unbound (* Unbound variable *)
(* Variance *)
module Variance : sig
type t
type f = May_pos | May_neg | May_weak | Inj | Pos | Neg | Inv
val null : t (* no occurence *)
val full : t (* strictly invariant *)
val covariant : t (* strictly covariant *)
val may_inv : t (* maybe invariant *)
val union : t -> t -> t
val inter : t -> t -> t
val subset : t -> t -> bool
val set : f -> bool -> t -> t
val mem : f -> t -> bool
val conjugate : t -> t (* exchange positive and negative *)
val get_upper : t -> bool * bool (* may_pos, may_neg *)
val get_lower : t -> bool * bool * bool * bool (* pos, neg, inv, inj *)
end
(* Type definitions *)
type type_declaration =
{ type_params: type_expr list;
type_arity: int;
type_kind: type_kind;
type_private: private_flag;
type_manifest: type_expr option;
type_variance: Variance.t list;
(* covariant, contravariant, weakly contravariant, injective *)
type_newtype_level: (int * int) option;
(* definition level * expansion level *)
type_loc: Location.t;
type_attributes: Parsetree.attributes;
type_immediate: bool; (* true iff type should not be a pointer *)
}
and type_kind =
Type_abstract
| Type_record of label_declaration list * record_representation
| Type_variant of constructor_declaration list
| Type_open
and record_representation =
Record_regular (* All fields are boxed / tagged *)
| Record_float (* All fields are floats *)
| Record_inlined of int (* Inlined record *)
| Record_extension (* Inlined record under extension *)
and label_declaration =
{
ld_id: Ident.t;
ld_mutable: mutable_flag;
ld_type: type_expr;
ld_loc: Location.t;
ld_attributes: Parsetree.attributes;
}
and constructor_declaration =
{
cd_id: Ident.t;
cd_args: constructor_arguments;
cd_res: type_expr option;
cd_loc: Location.t;
cd_attributes: Parsetree.attributes;
}
and constructor_arguments =
| Cstr_tuple of type_expr list
| Cstr_record of label_declaration list
type extension_constructor =
{
ext_type_path: Path.t;
ext_type_params: type_expr list;
ext_args: constructor_arguments;
ext_ret_type: type_expr option;
ext_private: private_flag;
ext_loc: Location.t;
ext_attributes: Parsetree.attributes;
}
and type_transparence =
Type_public (* unrestricted expansion *)
| Type_new (* "new" type *)
| Type_private (* private type *)
(* Type expressions for the class language *)
module Concr : Set.S with type elt = string
type class_type =
Cty_constr of Path.t * type_expr list * class_type
| Cty_signature of class_signature
| Cty_arrow of arg_label * type_expr * class_type
and class_signature =
{ csig_self: type_expr;
csig_vars:
(Asttypes.mutable_flag * Asttypes.virtual_flag * type_expr) Vars.t;
csig_concr: Concr.t;
csig_inher: (Path.t * type_expr list) list }
type class_declaration =
{ cty_params: type_expr list;
mutable cty_type: class_type;
cty_path: Path.t;
cty_new: type_expr option;
cty_variance: Variance.t list;
cty_loc: Location.t;
cty_attributes: Parsetree.attributes;
}
type class_type_declaration =
{ clty_params: type_expr list;
clty_type: class_type;
clty_path: Path.t;
clty_variance: Variance.t list;
clty_loc: Location.t;
clty_attributes: Parsetree.attributes;
}
(* Type expressions for the module language *)
type module_type =
Mty_ident of Path.t
| Mty_signature of signature
| Mty_functor of Ident.t * module_type option * module_type
| Mty_alias of Path.t
and signature = signature_item list
and signature_item =
Sig_value of Ident.t * value_description
| Sig_type of Ident.t * type_declaration * rec_status
| Sig_typext of Ident.t * extension_constructor * ext_status
| Sig_module of Ident.t * module_declaration * rec_status
| Sig_modtype of Ident.t * modtype_declaration
| Sig_class of Ident.t * class_declaration * rec_status
| Sig_class_type of Ident.t * class_type_declaration * rec_status
and module_declaration =
{
md_type: module_type;
md_attributes: Parsetree.attributes;
md_loc: Location.t;
}
and modtype_declaration =
{
mtd_type: module_type option; (* None: abstract *)
mtd_attributes: Parsetree.attributes;
mtd_loc: Location.t;
}
and rec_status =
Trec_not (* first in a nonrecursive group *)
| Trec_first (* first in a recursive group *)
| Trec_next (* not first in a recursive/nonrecursive group *)
and ext_status =
Text_first (* first constructor in an extension *)
| Text_next (* not first constructor in an extension *)
| Text_exception
(* Constructor and record label descriptions inserted held in typing
environments *)
type constructor_description =
{ cstr_name: string; (* Constructor name *)
cstr_res: type_expr; (* Type of the result *)
cstr_existentials: type_expr list; (* list of existentials *)
cstr_args: type_expr list; (* Type of the arguments *)
cstr_arity: int; (* Number of arguments *)
cstr_tag: constructor_tag; (* Tag for heap blocks *)
cstr_consts: int; (* Number of constant constructors *)
cstr_nonconsts: int; (* Number of non-const constructors *)
cstr_normal: int; (* Number of non generalized constrs *)
cstr_generalized: bool; (* Constrained return type? *)
cstr_private: private_flag; (* Read-only constructor? *)
cstr_loc: Location.t;
cstr_attributes: Parsetree.attributes;
cstr_inlined: type_declaration option;
}
and constructor_tag =
Cstr_constant of int (* Constant constructor (an int) *)
| Cstr_block of int (* Regular constructor (a block) *)
| Cstr_extension of Path.t * bool (* Extension constructor
true if a constant false if a block*)
type label_description =
{ lbl_name: string; (* Short name *)
lbl_res: type_expr; (* Type of the result *)
lbl_arg: type_expr; (* Type of the argument *)
lbl_mut: mutable_flag; (* Is this a mutable field? *)
lbl_pos: int; (* Position in block *)
lbl_all: label_description array; (* All the labels in this type *)
lbl_repres: record_representation; (* Representation for this record *)
lbl_private: private_flag; (* Read-only field? *)
lbl_loc: Location.t;
lbl_attributes: Parsetree.attributes;
}