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|
(************************************************************************)
(* v * The Coq Proof Assistant / The Coq Development Team *)
(* <O___,, * CNRS-Ecole Polytechnique-INRIA Futurs-Universite Paris Sud *)
(* \VV/ **************************************************************)
(* // * This file is distributed under the terms of the *)
(* * GNU Lesser General Public License Version 2.1 *)
(************************************************************************)
(*i $Id: genarg.mli 11309 2008-08-06 10:30:35Z herbelin $ i*)
open Util
open Names
open Term
open Libnames
open Rawterm
open Topconstr
open Term
open Evd
type 'a and_short_name = 'a * identifier located option
type 'a or_by_notation = AN of 'a | ByNotation of loc * string
(* In globalize tactics, we need to keep the initial [constr_expr] to recompute*)
(* in the environment by the effective calls to Intro, Inversion, etc *)
(* The [constr_expr] field is [None] in TacDef though *)
type rawconstr_and_expr = rawconstr * constr_expr option
type open_constr_expr = unit * constr_expr
type open_rawconstr = unit * rawconstr_and_expr
type 'a with_ebindings = 'a * open_constr bindings
type intro_pattern_expr =
| IntroOrAndPattern of or_and_intro_pattern_expr
| IntroWildcard
| IntroRewrite of bool
| IntroIdentifier of identifier
| IntroFresh of identifier
| IntroAnonymous
and or_and_intro_pattern_expr = (loc * intro_pattern_expr) list list
val pr_intro_pattern : intro_pattern_expr located -> Pp.std_ppcmds
val pr_or_and_intro_pattern : or_and_intro_pattern_expr -> Pp.std_ppcmds
(* The route of a generic argument, from parsing to evaluation
\begin{verbatim}
parsing in_raw out_raw
char stream ----> rawtype ----> constr_expr generic_argument --------|
encapsulation decaps |
|
V
rawtype
|
globalization |
V
glob_type
|
encaps |
in_glob |
V
rawconstr generic_argument
|
out in out_glob |
type <--- constr generic_argument <---- type <------ rawtype <--------|
| 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], [rawconstr] 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 identifier 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}
*)
(* 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 = constr_expr
type glevel = rawconstr_and_expr
type tlevel = open_constr
type ('a,'co) abstract_argument_type
val rawwit_bool : (bool,rlevel) abstract_argument_type
val globwit_bool : (bool,glevel) abstract_argument_type
val wit_bool : (bool,tlevel) abstract_argument_type
val rawwit_int : (int,rlevel) abstract_argument_type
val globwit_int : (int,glevel) abstract_argument_type
val wit_int : (int,tlevel) abstract_argument_type
val rawwit_int_or_var : (int or_var,rlevel) abstract_argument_type
val globwit_int_or_var : (int or_var,glevel) abstract_argument_type
val wit_int_or_var : (int or_var,tlevel) abstract_argument_type
val rawwit_string : (string,rlevel) abstract_argument_type
val globwit_string : (string,glevel) abstract_argument_type
val wit_string : (string,tlevel) abstract_argument_type
val rawwit_pre_ident : (string,rlevel) abstract_argument_type
val globwit_pre_ident : (string,glevel) abstract_argument_type
val wit_pre_ident : (string,tlevel) abstract_argument_type
val rawwit_intro_pattern : (intro_pattern_expr located,rlevel) abstract_argument_type
val globwit_intro_pattern : (intro_pattern_expr located,glevel) abstract_argument_type
val wit_intro_pattern : (intro_pattern_expr located,tlevel) abstract_argument_type
val rawwit_ident : (identifier,rlevel) abstract_argument_type
val globwit_ident : (identifier,glevel) abstract_argument_type
val wit_ident : (identifier,tlevel) abstract_argument_type
val rawwit_var : (identifier located,rlevel) abstract_argument_type
val globwit_var : (identifier located,glevel) abstract_argument_type
val wit_var : (identifier,tlevel) abstract_argument_type
val rawwit_ref : (reference,rlevel) abstract_argument_type
val globwit_ref : (global_reference located or_var,glevel) abstract_argument_type
val wit_ref : (global_reference,tlevel) abstract_argument_type
val rawwit_quant_hyp : (quantified_hypothesis,rlevel) abstract_argument_type
val globwit_quant_hyp : (quantified_hypothesis,glevel) abstract_argument_type
val wit_quant_hyp : (quantified_hypothesis,tlevel) abstract_argument_type
val rawwit_sort : (rawsort,rlevel) abstract_argument_type
val globwit_sort : (rawsort,glevel) abstract_argument_type
val wit_sort : (sorts,tlevel) abstract_argument_type
val rawwit_constr : (constr_expr,rlevel) abstract_argument_type
val globwit_constr : (rawconstr_and_expr,glevel) abstract_argument_type
val wit_constr : (constr,tlevel) abstract_argument_type
val rawwit_constr_may_eval : ((constr_expr,reference or_by_notation) may_eval,rlevel) abstract_argument_type
val globwit_constr_may_eval : ((rawconstr_and_expr,evaluable_global_reference and_short_name or_var) may_eval,glevel) abstract_argument_type
val wit_constr_may_eval : (constr,tlevel) abstract_argument_type
val rawwit_open_constr_gen : bool -> (open_constr_expr,rlevel) abstract_argument_type
val globwit_open_constr_gen : bool -> (open_rawconstr,glevel) abstract_argument_type
val wit_open_constr_gen : bool -> (open_constr,tlevel) abstract_argument_type
val rawwit_open_constr : (open_constr_expr,rlevel) abstract_argument_type
val globwit_open_constr : (open_rawconstr,glevel) abstract_argument_type
val wit_open_constr : (open_constr,tlevel) abstract_argument_type
val rawwit_casted_open_constr : (open_constr_expr,rlevel) abstract_argument_type
val globwit_casted_open_constr : (open_rawconstr,glevel) abstract_argument_type
val wit_casted_open_constr : (open_constr,tlevel) abstract_argument_type
val rawwit_constr_with_bindings : (constr_expr with_bindings,rlevel) abstract_argument_type
val globwit_constr_with_bindings : (rawconstr_and_expr with_bindings,glevel) abstract_argument_type
val wit_constr_with_bindings : (constr with_ebindings,tlevel) abstract_argument_type
val rawwit_bindings : (constr_expr bindings,rlevel) abstract_argument_type
val globwit_bindings : (rawconstr_and_expr bindings,glevel) abstract_argument_type
val wit_bindings : (open_constr bindings,tlevel) abstract_argument_type
val rawwit_red_expr : ((constr_expr,reference or_by_notation) red_expr_gen,rlevel) abstract_argument_type
val globwit_red_expr : ((rawconstr_and_expr,evaluable_global_reference and_short_name or_var) red_expr_gen,glevel) abstract_argument_type
val wit_red_expr : ((constr,evaluable_global_reference) red_expr_gen,tlevel) abstract_argument_type
val wit_list0 :
('a,'co) abstract_argument_type -> ('a list,'co) abstract_argument_type
val wit_list1 :
('a,'co) abstract_argument_type -> ('a list,'co) abstract_argument_type
val wit_opt :
('a,'co) abstract_argument_type -> ('a option,'co) abstract_argument_type
val wit_pair :
('a,'co) abstract_argument_type ->
('b,'co) abstract_argument_type ->
('a * 'b,'co) abstract_argument_type
(* ['a generic_argument] = (Sigma t:type. t[[constr/'a]]) *)
type 'a generic_argument
val fold_list0 :
('a generic_argument -> 'c -> 'c) -> 'a generic_argument -> 'c -> 'c
val fold_list1 :
('a generic_argument -> 'c -> 'c) -> 'a generic_argument -> 'c -> 'c
val fold_opt :
('a generic_argument -> 'c) -> 'c -> 'a generic_argument -> 'c
val fold_pair :
('a generic_argument -> 'a generic_argument -> 'c) ->
'a generic_argument -> 'c
(* [app_list0] fails if applied to an argument not of tag [List0 t]
for some [t]; it's the responsability of the caller to ensure it *)
val app_list0 : ('a generic_argument -> 'b generic_argument) ->
'a generic_argument -> 'b generic_argument
val app_list1 : ('a generic_argument -> 'b generic_argument) ->
'a generic_argument -> 'b generic_argument
val app_opt : ('a generic_argument -> 'b generic_argument) ->
'a generic_argument -> 'b generic_argument
val app_pair :
('a generic_argument -> 'b generic_argument) ->
('a generic_argument -> 'b generic_argument)
-> 'a generic_argument -> 'b generic_argument
(* create a new generic type of argument: force to associate
unique ML types at each of the three levels *)
val create_arg : string ->
('a,tlevel) abstract_argument_type
* ('globa,glevel) abstract_argument_type
* ('rawa,rlevel) abstract_argument_type
val exists_argtype : string -> bool
type argument_type =
(* Basic types *)
| BoolArgType
| IntArgType
| IntOrVarArgType
| StringArgType
| PreIdentArgType
| IntroPatternArgType
| IdentArgType
| VarArgType
| RefArgType
(* Specific types *)
| SortArgType
| ConstrArgType
| ConstrMayEvalArgType
| QuantHypArgType
| OpenConstrArgType of bool
| ConstrWithBindingsArgType
| BindingsArgType
| RedExprArgType
| List0ArgType of argument_type
| List1ArgType of argument_type
| OptArgType of argument_type
| PairArgType of argument_type * argument_type
| ExtraArgType of string
val genarg_tag : 'a generic_argument -> argument_type
val unquote : ('a,'co) abstract_argument_type -> argument_type
val in_gen :
('a,'co) abstract_argument_type -> 'a -> 'co generic_argument
val out_gen :
('a,'co) abstract_argument_type -> 'co generic_argument -> 'a
(* [in_generic] is used in combination with camlp4 [Gramext.action] magic
[in_generic: !l:type, !a:argument_type -> |a|_l -> 'l generic_argument]
where |a|_l is the interpretation of a at level l
[in_generic] is not typable; we replace the second argument by an absurd
type (with no introduction rule)
*)
type an_arg_of_this_type
val in_generic :
argument_type -> an_arg_of_this_type -> 'co generic_argument
|
