1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
17
18
19
20
21
22
23
24
25
26
27
28
29
30
31
32
33
34
35
36
37
38
39
40
41
42
43
44
45
46
47
48
49
50
51
52
53
54
55
56
57
58
59
60
61
62
63
64
65
66
67
68
69
70
71
72
73
74
75
76
77
78
79
80
81
82
83
84
85
86
87
88
89
90
91
92
93
94
95
96
97
98
99
100
101
102
103
104
105
106
107
108
109
110
111
112
113
114
115
116
117
118
119
120
121
122
123
124
125
126
127
128
129
|
(************************************************************************)
(* v * The Coq Proof Assistant / The Coq Development Team *)
(* <O___,, * INRIA - CNRS - LIX - LRI - PPS - Copyright 1999-2017 *)
(* \VV/ **************************************************************)
(* // * This file is distributed under the terms of the *)
(* * GNU Lesser General Public License Version 2.1 *)
(************************************************************************)
(** Untyped intermediate terms *)
(** [glob_constr] comes after [constr_expr] and before [constr].
Resolution of names, insertion of implicit arguments placeholder,
and notations are done, but coercions, inference of implicit
arguments and pattern-matching compilation are not. *)
open Names
open Globnames
open Decl_kinds
open Misctypes
type existential_name = Id.t
(** The kind of patterns that occurs in "match ... with ... end"
locs here refers to the ident's location, not whole pat *)
type 'a cases_pattern_r =
| PatVar of Name.t
| PatCstr of constructor * 'a cases_pattern_g list * Name.t
(** [PatCstr(p,C,l,x)] = "|'C' 'l' as 'x'" *)
and 'a cases_pattern_g = ('a cases_pattern_r, 'a) DAst.t
type cases_pattern = [ `any ] cases_pattern_g
(** Representation of an internalized (or in other words globalized) term. *)
type 'a glob_constr_r =
| GRef of global_reference * glob_level list option
(** An identifier that represents a reference to an object defined
either in the (global) environment or in the (local) context. *)
| GVar of Id.t
(** An identifier that cannot be regarded as "GRef".
Bound variables are typically represented this way. *)
| GEvar of existential_name * (Id.t * 'a glob_constr_g) list
| GPatVar of Evar_kinds.matching_var_kind (** Used for patterns only *)
| GApp of 'a glob_constr_g * 'a glob_constr_g list
| GLambda of Name.t * binding_kind * 'a glob_constr_g * 'a glob_constr_g
| GProd of Name.t * binding_kind * 'a glob_constr_g * 'a glob_constr_g
| GLetIn of Name.t * 'a glob_constr_g * 'a glob_constr_g option * 'a glob_constr_g
| GCases of case_style * 'a glob_constr_g option * 'a tomatch_tuples_g * 'a cases_clauses_g
(** [GCases(style,r,tur,cc)] = "match 'tur' return 'r' with 'cc'" (in [MatchStyle]) *)
| GLetTuple of Name.t list * (Name.t * 'a glob_constr_g option) * 'a glob_constr_g * 'a glob_constr_g
| GIf of 'a glob_constr_g * (Name.t * 'a glob_constr_g option) * 'a glob_constr_g * 'a glob_constr_g
| GRec of 'a fix_kind_g * Id.t array * 'a glob_decl_g list array *
'a glob_constr_g array * 'a glob_constr_g array
| GSort of glob_sort
| GHole of Evar_kinds.t * intro_pattern_naming_expr * Genarg.glob_generic_argument option
| GCast of 'a glob_constr_g * 'a glob_constr_g cast_type
and 'a glob_constr_g = ('a glob_constr_r, 'a) DAst.t
and 'a glob_decl_g = Name.t * binding_kind * 'a glob_constr_g option * 'a glob_constr_g
and 'a fix_recursion_order_g =
| GStructRec
| GWfRec of 'a glob_constr_g
| GMeasureRec of 'a glob_constr_g * 'a glob_constr_g option
and 'a fix_kind_g =
| GFix of ((int option * 'a fix_recursion_order_g) array * int)
| GCoFix of int
and 'a predicate_pattern_g =
Name.t * (inductive * Name.t list) Loc.located option
(** [(na,id)] = "as 'na' in 'id'" where if [id] is [Some(l,I,k,args)]. *)
and 'a tomatch_tuple_g = ('a glob_constr_g * 'a predicate_pattern_g)
and 'a tomatch_tuples_g = 'a tomatch_tuple_g list
and 'a cases_clause_g = (Id.t list * 'a cases_pattern_g list * 'a glob_constr_g) Loc.located
(** [(p,il,cl,t)] = "|'cl' => 't'". Precondition: the free variables
of [t] are members of [il]. *)
and 'a cases_clauses_g = 'a cases_clause_g list
type glob_constr = [ `any ] glob_constr_g
type tomatch_tuple = [ `any ] tomatch_tuple_g
type tomatch_tuples = [ `any ] tomatch_tuples_g
type cases_clause = [ `any ] cases_clause_g
type cases_clauses = [ `any ] cases_clauses_g
type glob_decl = [ `any ] glob_decl_g
type fix_kind = [ `any ] fix_kind_g
type predicate_pattern = [ `any ] predicate_pattern_g
type fix_recursion_order = [ `any ] fix_recursion_order_g
type any_glob_constr = AnyGlobConstr : 'r glob_constr_g -> any_glob_constr
type 'a extended_glob_local_binder_r =
| GLocalAssum of Name.t * binding_kind * 'a glob_constr_g
| GLocalDef of Name.t * binding_kind * 'a glob_constr_g * 'a glob_constr_g option
| GLocalPattern of ('a cases_pattern_g * Id.t list) * Id.t * binding_kind * 'a glob_constr_g
and 'a extended_glob_local_binder_g = ('a extended_glob_local_binder_r, 'a) DAst.t
type extended_glob_local_binder = [ `any ] extended_glob_local_binder_g
(** A globalised term together with a closure representing the value
of its free variables. Intended for use when these variables are taken
from the Ltac environment. *)
type closure = {
idents:Id.t Id.Map.t;
typed: Pattern.constr_under_binders Id.Map.t ;
untyped:closed_glob_constr Id.Map.t }
and closed_glob_constr = {
closure: closure;
term: glob_constr }
(** Ltac variable maps *)
type var_map = Pattern.constr_under_binders Id.Map.t
type uconstr_var_map = closed_glob_constr Id.Map.t
type unbound_ltac_var_map = Geninterp.Val.t Id.Map.t
type ltac_var_map = {
ltac_constrs : var_map;
(** Ltac variables bound to constrs *)
ltac_uconstrs : uconstr_var_map;
(** Ltac variables bound to untyped constrs *)
ltac_idents: Id.t Id.Map.t;
(** Ltac variables bound to identifiers *)
ltac_genargs : unbound_ltac_var_map;
(** Ltac variables bound to other kinds of arguments *)
}
|