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(************************************************************************)
(* v * The Coq Proof Assistant / The Coq Development Team *)
(* <O___,, * INRIA - CNRS - LIX - LRI - PPS - Copyright 1999-2015 *)
(* \VV/ **************************************************************)
(* // * This file is distributed under the terms of the *)
(* * GNU Lesser General Public License Version 2.1 *)
(************************************************************************)
(** The route of a generic argument, from parsing to evaluation.
In the following diagram, "object" can be tactic_expr, constr, tactic_arg, etc.
{% \begin{%}verbatim{% }%}
parsing in_raw out_raw
char stream ---> raw_object ---> raw_object generic_argument -------+
encapsulation decaps|
|
V
raw_object
|
globalization |
V
glob_object
|
encaps |
in_glob |
V
glob_object generic_argument
|
out in out_glob |
object <--- object generic_argument <--- object <--- glob_object <---+
| decaps encaps interp decaps
|
V
effective use
{% \end{%}verbatim{% }%}
To distinguish between the uninterpreted (raw), globalized and
interpreted worlds, we annotate the type [generic_argument] by a
phantom argument which is either [constr_expr], [glob_constr] or
[constr].
Transformation for each type :
{% \begin{%}verbatim{% }%}
tag raw open type cooked closed type
BoolArgType bool bool
IntArgType int int
IntOrVarArgType int or_var int
StringArgType string (parsed w/ "") string
PreIdentArgType string (parsed w/o "") (vernac only)
IdentArgType true identifier identifier
IdentArgType false identifier (pattern_ident) identifier
IntroPatternArgType intro_pattern_expr intro_pattern_expr
VarArgType identifier located identifier
RefArgType reference global_reference
QuantHypArgType quantified_hypothesis quantified_hypothesis
ConstrArgType constr_expr constr
ConstrMayEvalArgType constr_expr may_eval constr
OpenConstrArgType open_constr_expr open_constr
ConstrWithBindingsArgType constr_expr with_bindings constr with_bindings
BindingsArgType constr_expr bindings constr bindings
List0ArgType of argument_type
List1ArgType of argument_type
OptArgType of argument_type
ExtraArgType of string '_a '_b
{% \end{%}verbatim{% }%}
*)
(** {5 Generic types} *)
type ('raw, 'glob, 'top) genarg_type
(** Generic types. ['raw] is the OCaml lowest level, ['glob] is the globalized
one, and ['top] the internalized one. *)
type 'a uniform_genarg_type = ('a, 'a, 'a) genarg_type
(** Alias for concision when the three types agree. *)
val make0 : 'raw option -> string -> ('raw, 'glob, 'top) genarg_type
(** Create a new generic type of argument: force to associate
unique ML types at each of the three levels. *)
val create_arg : 'raw option -> string -> ('raw, 'glob, 'top) genarg_type
(** Alias for [make0]. *)
(** {5 Specialized types} *)
(** All of [rlevel], [glevel] and [tlevel] must be non convertible
to ensure the injectivity of the type inference from type
['co generic_argument] to [('a,'co) abstract_argument_type];
this guarantees that, for 'co fixed, the type of
out_gen is monomorphic over 'a, hence type-safe
*)
type rlevel
type glevel
type tlevel
type ('a, 'co) abstract_argument_type
(** Type at level ['co] represented by an OCaml value of type ['a]. *)
type 'a raw_abstract_argument_type = ('a, rlevel) abstract_argument_type
(** Specialized type at raw level. *)
type 'a glob_abstract_argument_type = ('a, glevel) abstract_argument_type
(** Specialized type at globalized level. *)
type 'a typed_abstract_argument_type = ('a, tlevel) abstract_argument_type
(** Specialized type at internalized level. *)
(** {6 Projections} *)
val rawwit : ('a, 'b, 'c) genarg_type -> ('a, rlevel) abstract_argument_type
(** Projection on the raw type constructor. *)
val glbwit : ('a, 'b, 'c) genarg_type -> ('b, glevel) abstract_argument_type
(** Projection on the globalized type constructor. *)
val topwit : ('a, 'b, 'c) genarg_type -> ('c, tlevel) abstract_argument_type
(** Projection on the internalized type constructor. *)
(** {5 Generic arguments} *)
type 'a generic_argument
(** A inhabitant of ['level generic_argument] is a inhabitant of some type at
level ['level], together with the representation of this type. *)
type raw_generic_argument = rlevel generic_argument
type glob_generic_argument = glevel generic_argument
type typed_generic_argument = tlevel generic_argument
(** {6 Constructors} *)
val in_gen : ('a, 'co) abstract_argument_type -> 'a -> 'co generic_argument
(** [in_gen t x] embeds an argument of type [t] into a generic argument. *)
val out_gen : ('a, 'co) abstract_argument_type -> 'co generic_argument -> 'a
(** [out_gen t x] recovers an argument of type [t] from a generic argument. It
fails if [x] has not the right dynamic type. *)
val has_type : 'co generic_argument -> ('a, 'co) abstract_argument_type -> bool
(** [has_type v t] tells whether [v] has type [t]. If true, it ensures that
[out_gen t v] will not raise a dynamic type exception. *)
(** {6 Destructors} *)
type ('a, 'b, 'c, 'l) cast
val raw : ('a, 'b, 'c, rlevel) cast -> 'a
val glb : ('a, 'b, 'c, glevel) cast -> 'b
val top : ('a, 'b, 'c, tlevel) cast -> 'c
type ('r, 'l) unpacker =
{ unpacker : 'a 'b 'c. ('a, 'b, 'c) genarg_type -> ('a, 'b, 'c, 'l) cast -> 'r }
val unpack : ('r, 'l) unpacker -> 'l generic_argument -> 'r
(** Existential-type destructors. *)
(** {6 Manipulation of generic arguments}
Those functions fail if they are applied to an argument which has not the right
dynamic type. *)
type ('r, 'l) list_unpacker =
{ list_unpacker : 'a 'b 'c. ('a, 'b, 'c) genarg_type ->
('a list, 'b list, 'c list, 'l) cast -> 'r }
val list_unpack : ('r, 'l) list_unpacker -> 'l generic_argument -> 'r
type ('r, 'l) opt_unpacker =
{ opt_unpacker : 'a 'b 'c. ('a, 'b, 'c) genarg_type ->
('a option, 'b option, 'c option, 'l) cast -> 'r }
val opt_unpack : ('r, 'l) opt_unpacker -> 'l generic_argument -> 'r
type ('r, 'l) pair_unpacker =
{ pair_unpacker : 'a1 'a2 'b1 'b2 'c1 'c2.
('a1, 'b1, 'c1) genarg_type -> ('a2, 'b2, 'c2) genarg_type ->
(('a1 * 'a2), ('b1 * 'b2), ('c1 * 'c2), 'l) cast -> 'r }
val pair_unpack : ('r, 'l) pair_unpacker -> 'l generic_argument -> 'r
(** {6 Type reification} *)
type argument_type =
(** Basic types *)
| IntOrVarArgType
| IdentArgType
| VarArgType
(** Specific types *)
| GenArgType
| ConstrArgType
| ConstrMayEvalArgType
| QuantHypArgType
| OpenConstrArgType
| ConstrWithBindingsArgType
| BindingsArgType
| RedExprArgType
| ListArgType of argument_type
| OptArgType of argument_type
| PairArgType of argument_type * argument_type
| ExtraArgType of string
val argument_type_eq : argument_type -> argument_type -> bool
val pr_argument_type : argument_type -> Pp.std_ppcmds
(** Print a human-readable representation for a given type. *)
val genarg_tag : 'a generic_argument -> argument_type
val unquote : ('a, 'co) abstract_argument_type -> argument_type
(** {6 Registering genarg-manipulating functions}
This is boilerplate code used here and there in the code of Coq. *)
module type GenObj =
sig
type ('raw, 'glb, 'top) obj
(** An object manipulating generic arguments. *)
val name : string
(** A name for such kind of manipulation, e.g. [interp]. *)
val default : ('raw, 'glb, 'top) genarg_type -> ('raw, 'glb, 'top) obj option
(** A generic object when there is no registered object for this type. *)
end
module Register (M : GenObj) :
sig
val register0 : ('raw, 'glb, 'top) genarg_type ->
('raw, 'glb, 'top) M.obj -> unit
(** Register a ground type manipulation function. *)
val obj : ('raw, 'glb, 'top) genarg_type -> ('raw, 'glb, 'top) M.obj
(** Recover a manipulation function at a given type. *)
end
(** {5 Basic generic type constructors} *)
(** {6 Parameterized types} *)
val wit_list : ('a, 'b, 'c) genarg_type -> ('a list, 'b list, 'c list) genarg_type
val wit_opt : ('a, 'b, 'c) genarg_type -> ('a option, 'b option, 'c option) genarg_type
val wit_pair : ('a1, 'b1, 'c1) genarg_type -> ('a2, 'b2, 'c2) genarg_type ->
('a1 * 'a2, 'b1 * 'b2, 'c1 * 'c2) genarg_type
(** {5 Magic used by the parser} *)
val default_empty_value : ('raw, 'glb, 'top) genarg_type -> 'raw option
val register_name0 : ('a, 'b, 'c) genarg_type -> string -> unit
(** Used by the extension to give a name to types. The string should be the
absolute path of the argument witness, e.g.
[register_name0 wit_toto "MyArg.wit_toto"]. *)
val get_name0 : string -> string
(** Return the absolute path of a given witness. *)
(** {5 Unsafe loophole} *)
module Unsafe :
sig
(** Unsafe magic functions. Not for kids. This is provided here as a loophole to
escape this module. Do NOT use outside of the dedicated areas. NOT. EVER. *)
val inj : argument_type -> Obj.t -> 'lev generic_argument
(** Injects an object as generic argument. !!!BEWARE!!! only do this as
[inj tpe x] where:
1. [tpe] is the reification of a [('a, 'b, 'c) genarg_type];
2. [x] has type ['a], ['b] or ['c] according to the return level ['lev]. *)
val prj : 'lev generic_argument -> Obj.t
(** Recover the contents of a generic argument. *)
end
|