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|
(************************************************************************)
(* v * The Coq Proof Assistant / The Coq Development Team *)
(* <O___,, * INRIA - CNRS - LIX - LRI - PPS - Copyright 1999-2012 *)
(* \VV/ **************************************************************)
(* // * This file is distributed under the terms of the *)
(* * GNU Lesser General Public License Version 2.1 *)
(************************************************************************)
(* The proofview datastructure is a pure datastructure underlying the notion
of proof (namely, a proof is a proofview which can evolve and has safety
mechanisms attached).
The general idea of the structure is that it is composed of a chemical
solution: an unstructured bag of stuff which has some relations with
one another, which represents the various subnodes of the proof. Together
with a comb: a datastructure that gives some order to some of these nodes,
namely the (focused) open goals.
The natural candidate for the solution is an {!Evd.evar_map}, that is
a calculus of evars. The comb is then a list of goals (evars wrapped
with some extra information, like possible name anotations).
There is also need of a list of the evars which initialised the proofview
to be able to return information about the proofview. *)
open Term
type proofview
(* Returns a stylised view of a proofview for use by, for instance,
ide-s. *)
(* spiwack: the type of [proofview] will change as we push more
refined functions to ide-s. This would be better than spawning a
new nearly identical function everytime. Hence the generic name. *)
(* In this version: returns the list of focused goals together with
the [evar_map] context. *)
val proofview : proofview -> Goal.goal list * Evd.evar_map
type entry
(* Initialises a proofview, the argument is a list of environement,
conclusion types, creating that many initial goals. *)
val init : Evd.evar_map -> (Environ.env * Term.types) list -> entry * proofview
type telescope =
| TNil of Evd.evar_map
| TCons of Environ.env * Evd.evar_map * Term.types * (Evd.evar_map -> Term.constr -> telescope)
(* Like [init], but goals are allowed to be depedenent on one
another. Dependencies between goals is represented with the type
[telescope] instead of [list]. *)
val dependent_init : telescope -> entry * proofview
(* Returns whether this proofview is finished or not. That is,
if it has empty subgoals in the comb. There could still be unsolved
subgoaled, but they would then be out of the view, focused out. *)
val finished : proofview -> bool
(* Returns the current value of the proofview partial proofs. *)
val return : proofview -> Evd.evar_map
val partial_proof : entry -> proofview -> constr list
val initial_goals : entry -> (constr * types) list
val emit_side_effects : Declareops.side_effects -> proofview -> proofview
(*** Focusing operations ***)
(* [IndexOutOfRange] occurs in case of malformed indices
with respect to list lengths. *)
exception IndexOutOfRange
(* Type of the object which allow to unfocus a view.*)
type focus_context
(* Returns a stylised view of a focus_context for use by, for
instance, ide-s. *)
(* spiwack: the type of [focus_context] will change as we push more
refined functions to ide-s. This would be better than spawning a
new nearly identical function everytime. Hence the generic name. *)
(* In this version: returns the number of goals that are held *)
val focus_context : focus_context -> Goal.goal list * Goal.goal list
(* [focus i j] focuses a proofview on the goals from index [i] to index [j]
(inclusive). (i.e. goals number [i] to [j] become the only goals of the
returned proofview).
It returns the focus proof, and a context for the focus trace. *)
val focus : int -> int -> proofview -> proofview * focus_context
(* Unfocuses a proofview with respect to a context. *)
val unfocus : focus_context -> proofview -> proofview
(* The tactic monad:
- Tactics are objects which apply a transformation to all
the subgoals of the current view at the same time. By opposition
to the old vision of applying it to a single goal. It allows
tactics such as [shelve_unifiable] or tactics to reorder
the focused goals (not done yet).
(* spiwack: the ordering of goals, though, is actually rather
brittle. It would be much more interesting to find a more
robust way to adress goals, I have no idea at this time
though*)
or global automation tactic for dependent subgoals (instantiating
an evar has influences on the other goals of the proof in progress,
not being able to take that into account causes the current eauto
tactic to fail on some instances where it could succeed).
Another benefit is that it is possible to write tactics that can
be executed even if there are no focused goals.
- Tactics form a monad ['a tactic], in a sense a tactic can be
seens as a function (without argument) which returns a value
of type 'a and modifies the environement (in our case: the view).
Tactics of course have arguments, but these are given at the
meta-level as OCaml functions.
Most tactics in the sense we are used to return [()], that is
no really interesting values. But some might pass information
around.
(* spiwack: as far as I'm aware this doesn't really relate to
F. Kirchner and C. Muñoz.
*)
The tactics seen in Coq's Ltac are (for now at least) only
[unit tactic], the return values are kept for the OCaml toolkit.
The operation or the monad are [Proofview.tclUNIT] (which is the
"return" of the tactic monad) [Proofview.tclBIND] (which is
the "bind") and [Proofview.tclTHEN] (which is a specialized
bind on unit-returning tactics).
*)
type +'a tactic
type 'a case =
| Fail of exn
| Next of 'a * (exn -> 'a tactic)
(* Applies a tactic to the current proofview. *)
(* the return boolean signals the use of an unsafe tactic, in which
case it is [false]. *)
val apply : Environ.env -> 'a tactic -> proofview -> 'a
* proofview
* (bool*(Goal.goal list*Goal.goal list))
(*** tacticals ***)
(* Unit of the tactic monad *)
val tclUNIT : 'a -> 'a tactic
(* Bind operation of the tactic monad *)
val tclBIND : 'a tactic -> ('a -> 'b tactic) -> 'b tactic
(* Interprets the ";" (semicolon) of Ltac.
As a monadic operation, it's a specialized "bind"
on unit-returning tactic (meaning "there is no value to bind") *)
val tclTHEN : unit tactic -> 'a tactic -> 'a tactic
(* [tclIGNORE t] has the same operational content as [t],
but drops the value at the end. *)
val tclIGNORE : 'a tactic -> unit tactic
(* [tclOR t1 t2 = t1] as long as [t1] succeeds. Whenever the successes
of [t1] have been depleted and it failed with [e], then it behaves
as [t2 e]. No interleaving at this point. *)
val tclOR : 'a tactic -> (exn -> 'a tactic) -> 'a tactic
(* [tclZERO] always fails *)
val tclZERO : exn -> 'a tactic
(* [tclORELSE t1 t2] behaves like [t1] if [t1] succeeds at least once
or [t2 e] if [t1] fails with [e]. *)
val tclORELSE : 'a tactic -> (exn -> 'a tactic) -> 'a tactic
(* [tclCASE t] observes the head of the tactic and returns it as a value *)
val tclCASE : 'a tactic -> 'a case tactic
(* [tclIFCATCH a s f] is a generalisation of [tclORELSE]: if [a]
succeeds at least once then it behaves as [tclBIND a s] otherwise, if [a]
fails with [e], then it behaves as [f e]. *)
val tclIFCATCH : 'a tactic -> ('a -> 'b tactic) -> (exn -> 'b tactic) -> 'b tactic
(* [tclONCE t] fails if [t] fails, otherwise it has exactly one
success. *)
val tclONCE : 'a tactic -> 'a tactic
(* [tclBREAK f t] is a generalization of [tclONCE t]. Instead of stopping at the
first element encountered, it waits for the tactic to return an exception
satisfying [f], and drop the remaining results. [tclONCE t] is equivalent to
[tclBREAK (fun _ -> true) t]. *)
val tclBREAK : (exn -> bool) -> 'a tactic -> 'a tactic
(* [tclEXACTLY_ONCE e t] succeeds as [t] if [t] has exactly one
success. Otherwise it fails. It may behave differently than [t] as
there may be extra non-logical effects used to discover that [t]
does not have a second success. Moreover the second success may be
conditional on the error received: [e] is used. *)
val tclEXACTLY_ONCE : exn -> 'a tactic -> 'a tactic
(* Focuses a tactic at a range of subgoals, found by their indices.
The other goals are restored to the focus when the tactic is done.
If the specified range doesn't correspond to existing goals, fails
with [NoSuchGoals]. *)
exception NoSuchGoals
val tclFOCUS : int -> int -> 'a tactic -> 'a tactic
(* Focuses a tactic at a range of subgoals, found by their indices.
The other goals are restored to the focus when the tactic is done.
If the specified range doesn't correspond to existing goals, behaves
like [tclUNIT ()]. *)
val tclTRYFOCUS : int -> int -> unit tactic -> unit tactic
(* Dispatch tacticals are used to apply a different tactic to each goal under
consideration. They come in two flavours:
[tclDISPATCH] takes a list of [unit tactic]-s and build a [unit tactic].
[tclDISPATCHL] takes a list of ['a tactic] and returns an ['a list tactic].
They both work by applying each of the tactic to the corresponding
goal (starting with the first goal). In the case of [tclDISPATCHL],
the tactic returns a list of the same size as the argument list (of
tactics), each element being the result of the tactic executed in
the corresponding goal.
When the length of the tactic list is not the number of goal,
raises [SizeMismatch (g,t)] where [g] is the number of available
goals, and [t] the number of tactics passed. *)
exception SizeMismatch of int*int
val tclDISPATCH : unit tactic list -> unit tactic
val tclDISPATCHL : 'a tactic list -> 'a list tactic
(* [tclEXTEND b r e] is a variant to [tclDISPATCH], where the [r] tactic
is "repeated" enough time such that every goal has a tactic assigned to it
([b] is the list of tactics applied to the first goals, [e] to the last goals, and [r]
is applied to every goal in between. *)
val tclEXTEND : unit tactic list -> unit tactic -> unit tactic list -> unit tactic
(* [tclINDEPENDENT tac] runs [tac] on each goal successively, from the
first one to the last one. Backtracking in one goal is independent of
backtracking in another. *)
val tclINDEPENDENT : unit tactic -> unit tactic
(* [tclSENSITIVE] views goal-type tactics as a special kind of tactics.*)
val tclSENSITIVE : Goal.subgoals Goal.sensitive -> unit tactic
(* [tclPROGRESS t] behaves has [t] as long as [t] progresses. *)
val tclPROGRESS : 'a tactic -> 'a tactic
(* [tclEVARMAP] doesn't affect the proof, it returns the current evar_map. *)
val tclEVARMAP : Evd.evar_map tactic
(* [tclENV] doesn't affect the proof, it returns the current
environment. It is not the environment of a particular goal,
rather the "global" environment of the proof. The goal-wise
environment is returned by {!Proofview.Goal.env}. *)
val tclENV : Environ.env tactic
(* [tclUPDATE_ENV e] modifies the global environment of the tactic. It is
required by workarounds like the [abstract] tactical. Not to be used by the
casual user. *)
val tclUPDATE_ENV : Environ.env -> unit tactic
(* [tclEFFECTS eff] add the effects [eff] to the current state. *)
val tclEFFECTS : Declareops.side_effects -> unit tactic
(* Checks for interrupts *)
val tclCHECKINTERRUPT : unit tactic
(* Shelves all the goals under focus. The goals are placed on the
shelf for later use (or being solved by side-effects). *)
val shelve : unit tactic
(* Shelves the unifiable goals under focus, i.e. the goals which
appear in other goals under focus (the unfocused goals are not
considered). *)
val shelve_unifiable : unit tactic
(* [unshelve l p] adds all the goals in [l] at the end of the focused
goals of p *)
val unshelve : Goal.goal list -> proofview -> proofview
(* Gives up on the goal under focus. Reports an unsafe status. Proofs
with given up goals cannot be closed. *)
val give_up : unit tactic
(** If [n] is positive, [cycle n] puts the [n] first goal last. If [n]
is negative, then it puts the [n] last goals first.*)
val cycle : int -> unit tactic
(** [swap i j] swaps the position of goals number [i] and [j]
(negative numbers can be used to address goals from the end. Goals
are indexed from [1]. For simplicity index [0] corresponds to goal
[1] as well, rather than raising an error. *)
val swap : int -> int -> unit tactic
(** [revgoals] reverse the list of focused goals. *)
val revgoals : unit tactic
(** [numgoals] returns the number of goals under focus. *)
val numgoals : int tactic
exception Timeout
(** [tclTIMEOUT n t] can have only one success.
In case of timeout if fails with [tclZERO Timeout]. *)
val tclTIMEOUT : int -> 'a tactic -> 'a tactic
(** [tclTIME s t] displays time for each atomic call to t, using s as an
identifying annotation if present *)
val tclTIME : string option -> 'a tactic -> 'a tactic
(** [mark_as_unsafe] signals that the current tactic is unsafe. *)
val mark_as_unsafe : unit tactic
module Monad : Monad.S with type +'a t = 'a tactic
(*** Commands ***)
val in_proofview : proofview -> (Evd.evar_map -> 'a) -> 'a
(* Notations for building tactics. *)
module Notations : sig
(* tclBIND *)
val (>>=) : 'a tactic -> ('a -> 'b tactic) -> 'b tactic
(* tclTHEN *)
val (<*>) : unit tactic -> 'a tactic -> 'a tactic
(* tclOR *)
val (<+>) : 'a tactic -> 'a tactic -> 'a tactic
end
(*** Compatibility layer with <= 8.2 tactics ***)
module V82 : sig
type tac = Goal.goal Evd.sigma -> Goal.goal list Evd.sigma
val tactic : tac -> unit tactic
(* normalises the evars in the goals, and stores the result in
solution. *)
val nf_evar_goals : unit tactic
val tclEVARS : Evd.evar_map -> unit tactic
(* Set the evar universe context *)
val tclEVARUNIVCONTEXT : Evd.evar_universe_context -> unit tactic
val has_unresolved_evar : proofview -> bool
(* Main function in the implementation of Grab Existential Variables.
Resets the proofview's goals so that it contains all unresolved evars
(in chronological order of insertion). *)
val grab : proofview -> proofview
(* Returns the open goals of the proofview together with the evar_map to
interprete them. *)
val goals : proofview -> Goal.goal list Evd.sigma
val top_goals : entry -> proofview -> Goal.goal list Evd.sigma
(* returns the existential variable used to start the proof *)
val top_evars : entry -> Evd.evar list
(* Implements the Existential command *)
val instantiate_evar : int -> Constrexpr.constr_expr -> proofview -> proofview
(* Caution: this function loses quite a bit of information. It
should be avoided as much as possible. It should work as
expected for a tactic obtained from {!V82.tactic} though. *)
val of_tactic : 'a tactic -> tac
(* marks as unsafe if the argument is [false] *)
val put_status : bool -> unit tactic
(* exception for which it is deemed to be safe to transmute into
tactic failure. *)
val catchable_exception : exn -> bool
(* transforms every Ocaml (catchable) exception into a failure in
the monad. *)
val wrap_exceptions : (unit -> 'a tactic) -> 'a tactic
end
(* The module goal provides an interface for goal-dependent tactics. *)
(* spiwack: there are still parts of the code which depend on proofs/goal.ml.
Eventually I'll try to remove it in favour of [Proofview.Goal] *)
module Goal : sig
(** The type of goals. The parameter type is a phantom argument indicating
whether the data contained in the goal has been normalized w.r.t. the
current sigma. If it is the case, it is flagged [ `NF ]. You may still
access the un-normalized data using {!assume} if you known you do not rely
on the assumption of being normalized, at your own risk. *)
type 'a t
(** Assume that you do not need the goal to be normalized. *)
val assume : 'a t -> [ `NF ] t
(* [concl], [hyps], [env] and [sigma] given a goal [gl] return
respectively the conclusion of [gl], the hypotheses of [gl], the
environment of [gl] (i.e. the global environment and the hypotheses)
and the current evar map. *)
val concl : [ `NF ] t -> Term.constr
val hyps : [ `NF ] t -> Context.named_context
val env : 'a t -> Environ.env
val sigma : 'a t -> Evd.evar_map
(* [nf_enter t] execute the goal-dependent tactic [t] in each goal
independently. In particular [t] need not backtrack the same way in
each goal. *)
val nf_enter : ([ `NF ] t -> unit tactic) -> unit tactic
(** Same as nf_enter, but does not normalize the goal beforehand. *)
val enter : ([ `LZ ] t -> unit tactic) -> unit tactic
(** Recover the list of current goals under focus *)
val nf_goals : [ `NF ] t list tactic
(** Recover the list of current goals under focus, without evar-normalization *)
val goals : [ `LZ ] t list tactic
(* compatibility: avoid if possible *)
val goal : [ `NF ] t -> Goal.goal
(** [refresh g] updates the [sigma g] to the current value, may be
useful with compatibility functions like [Tacmach.New.of_old] *)
val refresh_sigma : 'a t -> 'a t tactic
end
(** A light interface for building tactics out of partial term. Be careful,
the [refine] function does not do any typechecking, so you may construct
ill-typed terms without noticing. *)
module Refine : sig
type handle
(** A handle to thread along in state-passing style. *)
val new_evar : handle -> Environ.env -> Constr.types -> handle * Constr.t
(** Create a new hole that will be added to the goals to solve. *)
val new_evar_instance : handle -> Environ.named_context_val ->
Constr.types -> Constr.t list -> handle * Constr.t
(** Create a new hole with the given signature and instance. *)
val fresh_constructor_instance :
handle -> Environ.env -> Names.constructor -> handle * Constr.pconstructor
(** Creates a constructor with fresh universe variables. *)
val update : handle -> (Evd.evar_map -> Evd.evar_map * 'a) -> handle * 'a
(** [update h f] update the handle by applying [f] to the underlying evar map.
The [f] function must be monotonous, that is, for any evar map [evd],
[fst (f evd)] should be an extension of [evd]. New evars generated by [f]
are turned into goals. Use with care. *)
val refine : ?unsafe:bool -> (handle -> handle * Constr.t) -> unit tactic
(** Given a term with holes that have been generated through {!new_evar}, this
function fills the current hole with the given constr and creates goals
for all the holes in their generation order. Exceptions raised by the
function are caught. *)
val refine_casted : ?unsafe:bool -> (handle -> handle * Constr.t) -> unit tactic
(** Like {!refine} except the refined term is coerced to the conclusion of the
current goal. *)
end
(* The [NonLogical] module allows the execution of side effects in tactics
(non-logical side-effects are not discarded at failures). *)
module NonLogical : sig
(* ['a t] is the monadic type of side-effect issuing commands. *)
type +'a t
(* ['a ref] is a type of references to assignables. *)
type 'a ref
(* The unit of the non-logical monad. *)
val ret : 'a -> 'a t
(* The bind of the non-logical monad. *)
val bind : 'a t -> ('a -> 'b t) -> 'b t
(* [ignore c] drops the returned value, otherwise behaves like
[c]. *)
val ignore : 'a t -> unit t
(* Specialised version of [bind] when the first argument return
[()]. *)
val seq : unit t -> 'a t -> 'a t
(* [ref x] creates a reference containing [x]. *)
val ref : 'a -> 'a ref t
(* [set r x] assigns [x] to [r]. *)
val set : 'a ref -> 'a -> unit t
(* [get r] returns the value of [r] *)
val get : 'a ref -> 'a t
(* [read_line] reads one line on the standard input. *)
val read_line : string t
(* [print_char a] prints [a] to the standard output. *)
val print_char : char -> unit t
(* [print stm] prints [stm] to the standard output. *)
val print : Pp.std_ppcmds -> unit t
(* [raise e] raises an error [e] which cannot be caught by logical
operation.*)
val raise : exn -> 'a t
(* [catch c h] runs the command [c] until it returns a value [v], in
which case [catch c h] behaves like [c], or [c] raises an exception
[e] in which case it continues with [h e]. *)
val catch : 'a t -> (exn -> 'a t) -> 'a t
(* [timeout t c] runs [c] for [t] seconds if [c] succeeds in time
then [timeout t c] behaves like [c], otherwise it fails with
[Proof_errors.Timeout]. *)
val timeout : int -> 'a t -> 'a t
(** [make f] internalize effects done by [f] in the monad. Exceptions raised
by [f] are encapsulated the same way {!raise} does it. *)
val make : (unit -> 'a) -> 'a t
(* [run c] performs [c]'s side effects for real. *)
val run : 'a t -> 'a
end
(* [tclLIFT c] includes the non-logical command [c] in a tactic. *)
val tclLIFT : 'a NonLogical.t -> 'a tactic
|