Notation (coq-core.Notation)

val notation_cat : Libobject.category

val pr_notation : Constrexpr.notation -> Pp.t

Printing

val notation_entry_eq : Constrexpr.notation_entry -> Constrexpr.notation_entry -> bool

Equality on notation_entry.

val notation_with_optional_scope_eq : Constrexpr.notation_with_optional_scope -> Constrexpr.notation_with_optional_scope -> bool

val notation_eq : Constrexpr.notation -> Constrexpr.notation -> bool

Equality on notation.

module NotationSet : Stdlib.Set.S with type elt = Constrexpr.notation

module NotationMap : CMap.ExtS with type key = Constrexpr.notation and module Set := NotationSet

module SpecificNotationSet : Stdlib.Set.S with type elt = Constrexpr.specific_notation

module SpecificNotationMap : CMap.ExtS with type key = Constrexpr.specific_notation and module Set := SpecificNotationSet

Scopes

A scope is a set of interpreters for symbols + optional interpreter and printers for integers + optional delimiters

type delimiters = string

type scope

type scopes

= scope_name list

val declare_scope : Notation_term.scope_name -> unit

val ensure_scope : Notation_term.scope_name -> unit

val current_scopes : unit -> scopes

val scope_is_open_in_scopes : Notation_term.scope_name -> scopes -> bool

Check where a scope is opened or not in a scope list, or in * the current opened scopes

val scope_is_open : Notation_term.scope_name -> bool

val open_scope : Notation_term.scope_name -> unit

Open scope

val close_scope : Notation_term.scope_name -> unit

val normalize_scope : string -> Notation_term.scope_name

Return a scope taking either a scope name or delimiter

val empty_scope_stack : scopes

Extend a list of scopes

val push_scope : Notation_term.scope_name -> scopes -> scopes

val find_scope : Notation_term.scope_name -> scope

Declare delimiters for printing

val declare_delimiters : Notation_term.scope_name -> delimiters -> unit

val remove_delimiters : Notation_term.scope_name -> unit

val find_delimiters_scope : ?loc:Loc.t -> delimiters -> Notation_term.scope_name

Declare and uses back and forth an interpretation of primitive token

A number interpreter is the pair of an interpreter for **(hexa)decimal** numbers in terms and an optional interpreter in pattern, if non integer or negative numbers are not supported, the interpreter must fail with an appropriate error message

type notation_location = (Names.DirPath.t * Names.DirPath.t) * string

type required_module = Libnames.full_path * string list

type rawnum = NumTok.Signed.t

The unique id string below will be used to refer to a particular registered interpreter/uninterpreter of number or string notation. Using the same uid for different (un)interpreters will fail. If at most one interpretation of prim token is used per scope, then the scope name could be used as unique id.

type prim_token_uid = string

type 'a prim_token_interpreter = ?loc:Loc.t -> 'a -> Glob_term.glob_constr

type 'a prim_token_uninterpreter = Glob_term.any_glob_constr -> 'a option

type 'a prim_token_interpretation = 'a prim_token_interpreter * 'a prim_token_uninterpreter

val register_rawnumeral_interpretation : ?allow_overwrite:bool -> prim_token_uid -> rawnum prim_token_interpretation -> unit

val register_bignumeral_interpretation : ?allow_overwrite:bool -> prim_token_uid -> Z.t prim_token_interpretation -> unit

val register_string_interpretation : ?allow_overwrite:bool -> prim_token_uid -> string prim_token_interpretation -> unit

* Number notation

type prim_token_notation_error =

| UnexpectedTerm of Constr.t

| UnexpectedNonOptionTerm of Constr.t

exception PrimTokenNotationError of string * Environ.env * Evd.evar_map * prim_token_notation_error

type numnot_option =

| Nop

| Warning of NumTok.UnsignedNat.t

| Abstract of NumTok.UnsignedNat.t

type int_ty = {

dec_uint : Names.inductive;

dec_int : Names.inductive;

hex_uint : Names.inductive;

hex_int : Names.inductive;

uint : Names.inductive;

int : Names.inductive;

}

type z_pos_ty = {

z_ty : Names.inductive;

pos_ty : Names.inductive;

}

type number_ty = {

int : int_ty;

decimal : Names.inductive;

hexadecimal : Names.inductive;

number : Names.inductive;

}

type pos_neg_int63_ty = {

pos_neg_int63_ty : Names.inductive;

}

type target_kind =

| Int of int_ty

| UInt of int_ty

| Z of z_pos_ty

| Int63 of pos_neg_int63_ty

| Float64

| Number of number_ty

type string_target_kind =

| ListByte

| Byte

type option_kind =

| Option

| Direct

type 'target conversion_kind = 'target * option_kind

type to_post_arg =

| ToPostCopy

| ToPostAs of int

| ToPostHole

| ToPostCheck of Constr.t

A postprocessing translation to_post can be done after execution of the to_ty interpreter. The reverse translation is performed before the of_ty uninterpreter.

to_post is an array of n lists l_i of tuples (f, t, args). When the head symbol of the translated term matches one of the f in the list l_0 it is replaced by t and its arguments are translated acording to args where ToPostCopy means that the argument is kept unchanged and ToPostAs k means that the argument is recursively translated according to l_k. ToPostHole introduces an additional implicit argument hole (in the reverse translation, the corresponding argument is removed). ToPostCheck r behaves as ToPostCopy except in the reverse translation which fails if the copied term is not r. When n is null, no translation is performed.

type ('target, 'warning) prim_token_notation_obj = {

to_kind : 'target conversion_kind;

to_ty : Names.GlobRef.t;

to_post : (Names.GlobRef.t * Names.GlobRef.t * to_post_arg list) list array;

of_kind : 'target conversion_kind;

of_ty : Names.GlobRef.t;

ty_name : Libnames.qualid;

warning : 'warning;

}

type number_notation_obj = (target_kind, numnot_option) prim_token_notation_obj

type string_notation_obj = (string_target_kind, unit) prim_token_notation_obj

type prim_token_interp_info =

| Uid of prim_token_uid

| NumberNotation of number_notation_obj

| StringNotation of string_notation_obj

type prim_token_infos = {

`pt_local : bool;`	(* Is this interpretation local? *)
`pt_scope : Notation_term.scope_name;`	(* Concerned scope *)
`pt_interp_info : prim_token_interp_info;`	(* Unique id "pointing" to (un)interp functions, OR a number notation object describing (un)interp functions *)
`pt_required : required_module;`	(* Module that should be loaded first *)
`pt_refs : Names.GlobRef.t list;`	(* Entry points during uninterpretation *)
`pt_in_match : bool;`	(* Is this prim token legal in match patterns ? *)

}

Note: most of the time, the pt_refs field above will contain inductive constructors (e.g. O and S for nat). But it could also be injection functions such as IZR for reals.

Activate a prim token interpretation whose unique id and functions have already been registered.

val enable_prim_token_interpretation : prim_token_infos -> unit

Compatibility. Avoid the next two functions, they will now store unnecessary objects in the library segment. Instead, combine register_*_interpretation and enable_prim_token_interpretation (the latter inside a Mltop.declare_cache_obj).

val declare_numeral_interpreter : ?local:bool ->
Notation_term.scope_name -> required_module -> Z.t prim_token_interpreter -> (Glob_term.glob_constr list * Z.t prim_token_uninterpreter * bool) -> unit

val declare_string_interpreter : ?local:bool ->
Notation_term.scope_name -> required_module -> string prim_token_interpreter -> (Glob_term.glob_constr list * string prim_token_uninterpreter * bool) -> unit

Return the term/cases_pattern bound to a primitive token in a given scope context

val interp_prim_token : ?loc:Loc.t -> Constrexpr.prim_token -> Notation_term.subscopes -> Glob_term.glob_constr * (notation_location * Notation_term.scope_name option)

val interp_prim_token_cases_pattern_expr : ?loc:Loc.t ->
(Names.GlobRef.t -> unit) -> Constrexpr.prim_token -> Notation_term.subscopes -> Glob_term.glob_constr * (notation_location * Notation_term.scope_name option)

Return the primitive token associated to a term/cases_pattern; raise No_match if no such token

val uninterp_prim_token : 'a Glob_term.glob_constr_g -> Notation_term.subscopes -> Constrexpr.prim_token * delimiters option

val uninterp_prim_token_cases_pattern : 'a Glob_term.cases_pattern_g -> Notation_term.subscopes -> Names.Name.t * Constrexpr.prim_token * delimiters option

val availability_of_prim_token : Constrexpr.prim_token -> Notation_term.scope_name -> Notation_term.subscopes -> delimiters option option

Declare and interpret back and forth a notation

type entry_coercion_kind =

| IsEntryCoercion of Constrexpr.notation_entry_level

| IsEntryGlobal of string * int

| IsEntryIdent of string * int

val declare_notation : (Constrexpr.notation_with_optional_scope * Constrexpr.notation) -> Notation_term.interpretation -> notation_location -> use:Notationextern.notation_use -> also_in_cases_pattern:bool ->
entry_coercion_kind option -> Deprecation.t option -> unit

val interp_notation : ?loc:Loc.t -> Constrexpr.notation -> Notation_term.subscopes -> Notation_term.interpretation * (notation_location * Notation_term.scope_name option)

Return the interpretation bound to a notation

val availability_of_notation : Constrexpr.specific_notation -> Notation_term.subscopes -> (Notation_term.scope_name option * delimiters option) option

Test if a notation is available in the scopes context scopes; if available, the result is not None; the first argument is itself not None if a delimiters is needed

val is_printing_inactive_rule : Notationextern.interp_rule -> Notation_term.interpretation -> bool

type 'a notation_query_pattern_gen = {

notation_entry_pattern : Constrexpr.notation_entry list;

interp_rule_key_pattern : (Constrexpr.notation_key, 'a) Util.union option;

use_pattern : Notationextern.notation_use;

scope_pattern : Constrexpr.notation_with_optional_scope option;

interpretation_pattern : Notation_term.interpretation option;

}

type notation_query_pattern = Libnames.qualid notation_query_pattern_gen

val toggle_notations : on:bool -> all:bool -> (Glob_term.glob_constr -> Pp.t) -> notation_query_pattern -> unit

Miscellaneous

val interpret_notation_string : string -> string

Take a notation string and turn it into a notation key. eg. "x + y" becomes "_ + _".

val interp_notation_as_global_reference : ?loc:Loc.t -> head:bool ->
(Names.GlobRef.t -> bool) -> Constrexpr.notation_key -> delimiters option -> Names.GlobRef.t

If head is true, also allows applied global references.

val declare_arguments_scope : bool -> Names.GlobRef.t -> Notation_term.scope_name list list -> unit

Declares and looks for scopes associated to arguments of a global ref

val find_arguments_scope : Names.GlobRef.t -> Notation_term.scope_name list list

type scope_class

val scope_class_compare : scope_class -> scope_class -> int

Comparison of scope_class

val subst_scope_class : Environ.env -> Mod_subst.substitution -> scope_class -> scope_class option

type add_scope_where =

`\| AddScopeTop`
`\| AddScopeBottom`	(* add new scope at top or bottom of existing stack (default is reset) *)

val declare_scope_class : Notation_term.scope_name -> ?where:add_scope_where -> scope_class -> unit

val declare_ref_arguments_scope : Evd.evar_map -> Names.GlobRef.t -> unit

val compute_arguments_scope : Environ.env -> Evd.evar_map -> EConstr.types -> Notation_term.scope_name list list

val compute_type_scope : Environ.env -> Evd.evar_map -> EConstr.types -> Notation_term.scope_name list

val current_type_scope_names : unit -> Notation_term.scope_name list

Get the current scopes bound to Sortclass

val scope_class_of_class : Coercionops.cl_typ -> scope_class

Building notation key

type symbol =

| Terminal of string

| NonTerminal of Names.Id.t

| SProdList of Names.Id.t * symbol list

| Break of int

val symbol_eq : symbol -> symbol -> bool

val make_notation_key : Constrexpr.notation_entry -> symbol list -> Constrexpr.notation

Make/decompose a notation of the form "_ U _"

val decompose_notation_key : Constrexpr.notation -> Constrexpr.notation_entry * symbol list

type notation_symbols = {

recvars : (Names.Id.t * Names.Id.t) list;

mainvars : Names.Id.t list;

symbols : symbol list;

}

val decompose_raw_notation : string -> notation_symbols

Decompose a notation of the form "a 'U' b" together with the lists of pairs of recursive variables and the list of all variables binding in the notation

val pr_scope_class : scope_class -> Pp.t

Prints scopes (expects a pure aconstr printer)

val pr_scope : (Glob_term.glob_constr -> Pp.t) -> Notation_term.scope_name -> Pp.t

val pr_scopes : (Glob_term.glob_constr -> Pp.t) -> Pp.t

val locate_notation : (Glob_term.glob_constr -> Pp.t) -> Constrexpr.notation_key -> Notation_term.scope_name option -> Pp.t

val pr_visibility : (Glob_term.glob_constr -> Pp.t) -> Notation_term.scope_name option -> Pp.t

val make_notation_entry_level : Constrexpr.notation_entry -> Constrexpr.entry_level -> Constrexpr.notation_entry_level

type entry_coercion = (Constrexpr.notation_with_optional_scope * Constrexpr.notation) list

val declare_entry_coercion : Constrexpr.specific_notation -> Constrexpr.entry_level option -> Constrexpr.notation_entry_level -> unit

val availability_of_entry_coercion : Constrexpr.notation_entry_level -> Constrexpr.notation_entry_level -> entry_coercion option

val declare_custom_entry_has_global : string -> int -> unit

val declare_custom_entry_has_ident : string -> int -> unit

val entry_has_global : Constrexpr.notation_entry_level -> bool

val entry_has_ident : Constrexpr.notation_entry_level -> bool

Dealing with precedences

type level = Constrexpr.notation_entry * Constrexpr.entry_level * Constrexpr.entry_relative_level list

val level_eq : level -> level -> bool

val entry_relative_level_eq : Constrexpr.entry_relative_level -> Constrexpr.entry_relative_level -> bool

Declare and test the level of a (possibly uninterpreted) notation

val declare_notation_level : Constrexpr.notation -> level -> unit

val level_of_notation : Constrexpr.notation -> level

raise Not_found if not declared

Rem: printing rules for primitive token are canonical

val with_notation_protection : ('a -> 'b) -> 'a -> 'b

val int63_of_pos_bigint : Z.t -> Uint63.t

Conversion from bigint to int63