Proofview
This files defines the basic mechanism of proofs: the proofview
type is the state which tactics manipulate (a global state for existential variables, together with the list of goals), and the type 'a tactic
is the (abstract) type of tactics modifying the proof state and returning a value of type 'a
.
val proofview : proofview -> Evar.t list * Evd.evar_map
Returns a stylised view of a proofview for use by, for instance, ide-s.
val init :
Evd.evar_map ->
(Environ.env * EConstr.types) list ->
entry * proofview
Initialises a proofview, the main argument is a list of environments (including a named_context
which are used as hypotheses) pair with conclusion types, creating accordingly many initial goals. Because a proof does not necessarily starts in an empty evar_map
(indeed a proof can be triggered by an incomplete pretyping), init
takes an additional argument to represent the initial evar_map
.
type telescope =
| TNil of Evd.evar_map |
| TCons of Environ.env
* Evd.evar_map
* EConstr.types
* Evd.evar_map ->
EConstr.constr ->
telescope |
A telescope
is a list of environment and conclusion like in init
, except that each element may depend on the previous goals. The telescope passes the goals in the form of a Term.constr
which represents the goal as an evar
. The evar_map
is threaded in state passing style.
Like init
, but goals are allowed to be dependent on one another. Dependencies between goals is represented with the type telescope
instead of list
. Note that the first evar_map
of the telescope plays the role of the evar_map
argument in init
.
val finished : proofview -> bool
finished pv
is true
if and only if pv
is complete. That is, if it has an empty list of focused goals. There could still be unsolved subgoals, but they would then be out of focus.
val return : proofview -> Evd.evar_map
Returns the current evar
state.
val partial_proof : entry -> proofview -> EConstr.constr list
val initial_goals :
entry ->
(Environ.named_context_val * EConstr.constr * EConstr.types) list
goal <-> goal_with_state
val with_empty_state : Proofview_monad.goal -> Proofview_monad.goal_with_state
val drop_state : Proofview_monad.goal_with_state -> Proofview_monad.goal
val goal_with_state :
Proofview_monad.goal ->
Proofview_monad.StateStore.t ->
Proofview_monad.goal_with_state
A focus_context
represents the part of the proof view which has been removed by a focusing action, it can be used to unfocus later on.
val focus_context : focus_context -> Evar.t list * Evar.t list
Returns a stylised view of a focus_context for use by, for instance, ide-s.
val focus : int -> int -> proofview -> proofview * focus_context
focus i j
focuses a proofview on the goals from index i
to index j
(inclusive, goals are indexed from 1
). I.e. goals number i
to j
become the only focused goals of the returned proofview. It returns the focused proofview, and a context for the focus stack.
val unfocus : focus_context -> proofview -> proofview
Unfocuses a proofview with respect to a context.
shelve_unifiable
, tactics to reorder the focused goals, 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.'a tactic
, in a sense a tactic can be seen as a function (without argument) which returns a value of type 'a and modifies the environment (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. 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).NonLogical
module below.val apply :
name:Names.Id.t ->
poly:bool ->
Environ.env ->
'a tactic ->
proofview ->
'a * proofview * bool * Proofview_monad.Info.tree
Applies a tactic to the current proofview. Returns a tuple a,pv,(b,sh,gu)
where a
is the return value of the tactic, pv
is the updated proofview, b
a boolean which is true
if the tactic has not done any action considered unsafe (such as admitting a lemma), sh
is the list of goals which have been shelved by the tactic, and gu
the list of goals on which the tactic has given up. In case of multiple success the first one is selected. If there is no success, fails with Logic_monad.TacticFailure
val tclUNIT : 'a -> 'a tactic
Unit of the tactic monad.
Interprets the ";" (semicolon) of Ltac. As a monadic operation, it's a specialized "bind".
tclIGNORE t
has the same operational content as t
, but drops the returned value.
val tclZERO : ?info:Exninfo.info -> exn -> 'a tactic
tclZERO e
fails with exception e
. It has no success. Exception is supposed to be non critical
val tclOR : 'a tactic -> ( Exninfo.iexn -> 'a tactic ) -> 'a tactic
tclOR t1 t2
behaves like 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
. In other words, tclOR
inserts a backtracking point. In t2
, exception can be assumed non critical.
val tclORELSE : 'a tactic -> ( Exninfo.iexn -> 'a tactic ) -> 'a tactic
tclORELSE t1 t2
is equal to t1
if t1
has at least one success or t2 e
if t1
fails with e
. It is analogous to try/with
handler of exception in that it is not a backtracking point. In t2
, exception can be assumed non critical.
val tclIFCATCH :
'a tactic ->
( 'a -> 'b tactic ) ->
( Exninfo.iexn -> 'b tactic ) ->
'b 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
. In f
exception can be assumed non critical.
tclONCE t
behave like t
except it has at most one success: tclONCE t
stops after the first success of t
. If t
fails with e
, tclONCE t
also fails with e
.
tclEXACTLY_ONCE e t
succeeds as t
if t
has exactly one success. Otherwise it fails. The tactic t
is run until its first success, then a failure with exception e
is simulated (e
has to be non critical). If t
yields another success, then tclEXACTLY_ONCE e t
fails with MoreThanOneSuccess
(it is a user error). Otherwise, tclEXACTLY_ONCE e t
succeeds with the first success of t
. Notice that the choice of e
is relevant, as the presence of further successes may depend on e
(see tclOR
).
tclCASE t
splits t
into its first success and a continuation. It is the most general primitive to control backtracking.
val tclBREAK :
( Exninfo.iexn -> Exninfo.iexn option ) ->
'a tactic ->
'a tactic
tclBREAK p t
is a generalization of tclONCE t
. Instead of stopping after the first success, it succeeds like t
until a failure with an exception e
such that p e = Some e'
is raised. At which point it drops the remaining successes, failing with e'
. tclONCE t
is equivalent to tclBREAK (fun e -> Some e) t
.
tclFOCUS i j t
applies t
after focusing on the goals number i
to j
(see focus
). The rest of the goals is restored after the tactic action. If the specified range doesn't correspond to existing goals, fails with the nosuchgoal
argument, by default raising NoSuchGoals
(a user error). This exception is caught at toplevel with a default message.
tclFOCUSLIST li t
applies t
on the list of focused goals described by li
. Each element of li
is a pair (i, j)
denoting the goals numbered from i
to j
(inclusive, starting from 1). It will try to apply t
to all the valid goals in any of these intervals. If the set of such goals is not a single range, then it will move goals such that it is a single range. (So, for instance, [1, 3-5]; idtac.
is not the identity.) If the set of such goals is empty, it will fail with nosuchgoal
, by default raising NoSuchGoals 0
.
val tclFOCUSID : ?nosuchgoal:'a tactic -> Names.Id.t -> 'a tactic -> 'a tactic
tclFOCUSID x t
applies t
on a (single) focused goal like tclFOCUS
. The goal is found by its name rather than its number. Fails with nosuchgoal
, by default raising NoSuchGoals 1
.
tclTRYFOCUS i j t
behaves like tclFOCUS
, except that if the specified range doesn't correspond to existing goals, behaves like tclUNIT ()
instead of failing.
Dispatch tacticals are used to apply a different tactic to each goal under focus. 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 in a focus restricted 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.
tclEXTEND b r e
is a variant of 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).
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. It is equivalent to tclEXTEND [] tac []
.
val shelve : unit tactic
Shelves all the goals under focus. The goals are placed on the shelf for later use (or being solved by side-effects).
Shelves the given list of goals, which might include some that are under focus and some that aren't. All the goals are placed on the shelf for later use (or being solved by side-effects).
val unifiable : Evd.evar_map -> Evar.t -> Evar.t list -> bool
unifiable sigma g l
checks whether g
appears in another subgoal of l
. The list l
may contain g
, but it does not affect the result. Used by shelve_unifiable
.
val shelve_unifiable : 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 guard_no_unifiable : Names.Name.t list option tactic
guard_no_unifiable
returns the list of unifiable goals if some goals are unifiable (see shelve_unifiable
) in the current focus.
unshelve l p
moves all the goals in l
from the shelf and put them at the end of the focused goals of p, if they are still undefined after advance
val depends_on : Evd.evar_map -> Evar.t -> Evar.t -> bool
depends_on g1 g2 sigma
checks if g1 occurs in the type/ctx of g2
with_shelf tac
executes tac
and returns its result together with the set of goals shelved by tac
. The current shelf is unchanged and the returned list contains only unsolved goals.
val cycle : int -> 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 swap : int -> 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 revgoals : unit tactic
revgoals
reverses the list of focused goals.
val numgoals : int tactic
numgoals
returns the number of goals under focus.
val tclEVARMAP : Evd.evar_map tactic
tclEVARMAP
doesn't affect the proof, it returns the current evar_map
.
val tclENV : Environ.env 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 obtained via Proofview.Goal.env
.
val tclEFFECTS : Evd.side_effects -> unit tactic
tclEFFECTS eff
add the effects eff
to the current state.
val mark_as_unsafe : unit tactic
mark_as_unsafe
declares the current tactic is unsafe.
val give_up : unit tactic
Gives up on the goal under focus. Reports an unsafe status. Proofs with given up goals cannot be closed.
tclPROGRESS t
checks the state of the proof after t
. It it is identical to the state before, then tclPROGRESS t
fails, otherwise it succeeds like t
.
module Progress : sig ... end
val tclCHECKINTERRUPT : unit tactic
Checks for interrupts
tclTIMEOUT n t
can have only one success. In case of timeout it fails with tclZERO Tac_Timeout
.
tclTIME s t
displays time for each atomic call to t, using s as an identifying annotation if present
val tclProofInfo : (Names.Id.t * bool) tactic
Internal, don't use.
module Unsafe : sig ... end
The primitives in the Unsafe
module should be avoided as much as possible, since they can make the proof state inconsistent. They are nevertheless helpful, in particular when interfacing the pretyping and the proof engine.
module UnsafeRepr : sig ... end
This module gives access to the innards of the monad. Its use is restricted to very specific cases.
module Goal : sig ... end
module Trace : sig ... end
module NonLogical : module type of Logic_monad.NonLogical
The NonLogical
module allows the execution of effects (including I/O) in tactics (non-logical side-effects are not discarded at failures).
val tclLIFT : 'a NonLogical.t -> 'a tactic
tclLIFT c
is a tactic which behaves exactly as c
.
module Notations : sig ... end