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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 $Id$ i*)

(*i*)
open Term
open Sign
open Evd
open Proof_trees
open Proof_type
open Tacexpr
(*i*)

(* The refiner (handles primitive rules and high-level tactics). *)

val sig_it  : 'a sigma -> 'a
val project : 'a sigma -> evar_map

val pf_env  : goal sigma -> Environ.env
val pf_hyps : goal sigma -> named_context

val unpackage : 'a sigma -> evar_map ref * 'a
val repackage : evar_map ref -> 'a -> 'a sigma
val apply_sig_tac :
  evar_map ref -> (goal sigma -> (goal list) sigma * validation) -> goal -> (goal list) * validation

type transformation_tactic = proof_tree -> (goal list * validation)

(*s Hiding the implementation of tactics. *)

(* [abstract_tactic tac] hides the (partial) proof produced by [tac] under
   a single proof node. The boolean tells if the default tactic is used. *)
val abstract_operation : compound_rule -> tactic -> tactic
val abstract_tactic : ?dflt:bool -> atomic_tactic_expr -> tactic -> tactic
val abstract_tactic_expr : ?dflt:bool -> tactic_expr -> tactic -> tactic
val abstract_extended_tactic :
  ?dflt:bool -> string -> typed_generic_argument list -> tactic -> tactic

val refiner : rule -> tactic
val frontier : transformation_tactic
val list_pf : proof_tree -> goal list
val unTAC : tactic -> goal sigma -> proof_tree sigma


(* Install a hook frontier_map and frontier_mapi call on the new node they create *)
val set_solve_hook : (Proof_type.proof_tree -> unit) -> unit
(* [frontier_map f n p] applies f on the n-th open subgoal of p and
   rebuilds proof-tree.
   n=1 for first goal, n negative counts from the right *)
val frontier_map :
  (proof_tree -> proof_tree) -> int -> proof_tree -> proof_tree

(* [frontier_mapi f p] applies (f i) on the i-th open subgoal of p. *)
val frontier_mapi :
  (int -> proof_tree -> proof_tree) -> proof_tree -> proof_tree

(*s Tacticals. *)

(* [tclNORMEVAR] forces propagation of evar constraints *)
val tclNORMEVAR       : tactic

(* [tclIDTAC] is the identity tactic without message printing*)
val tclIDTAC          : tactic
val tclIDTAC_MESSAGE  : Pp.std_ppcmds -> tactic

(* [tclEVARS sigma] changes the current evar map *)
val tclEVARS : evar_map -> tactic

(* [tclTHEN tac1 tac2 gls] applies the tactic [tac1] to [gls] and applies
   [tac2] to every resulting subgoals *)
val tclTHEN          : tactic -> tactic -> tactic

(* [tclTHENLIST [t1;..;tn]] applies [t1] THEN [t2] ... THEN [tn]. More
   convenient than [tclTHEN] when [n] is large *)
val tclTHENLIST      : tactic list -> tactic

(* [tclTHEN_i tac1 tac2 gls] applies the tactic [tac1] to [gls] and applies
   [(tac2 i)] to the [i]$^{th}$ resulting subgoal (starting from 1) *)
val tclTHEN_i        : tactic -> (int -> tactic) -> tactic

(* [tclTHENLAST tac1 tac2 gls] applies the tactic [tac1] to [gls] and [tac2]
   to the last resulting subgoal (previously called [tclTHENL]) *)
val tclTHENLAST         : tactic -> tactic -> tactic

(* [tclTHENFIRST tac1 tac2 gls] applies the tactic [tac1] to [gls] and [tac2]
   to the first resulting subgoal *)
val tclTHENFIRST         : tactic -> tactic -> tactic

(* [tclTHENS tac1 [|t1 ; ... ; tn|] gls] applies the tactic [tac1] to
   [gls] and applies [t1],..., [tn] to the [n] resulting subgoals. Raises
   an error if the number of resulting subgoals is not [n] *)
val tclTHENSV         : tactic -> tactic array -> tactic

(* Same with a list of tactics *)
val tclTHENS         : tactic -> tactic list -> tactic

(* [tclTHENST] is renamed [tclTHENSFIRSTn]
val tclTHENST        : tactic -> tactic array -> tactic -> tactic
*)

(* [tclTHENS3PARTS tac1 [|t1 ; ... ; tn|] tac2 [|t'1 ; ... ; t'm|] gls]
   applies the tactic [tac1] to [gls] then, applies [t1], ..., [tn] to
   the first [n] resulting subgoals, [t'1], ..., [t'm] to the last [m]
   subgoals and [tac2] to the rest of the subgoals in the middle. Raises an
   error if the number of resulting subgoals is strictly less than [n+m] *)
val tclTHENS3PARTS     : tactic -> tactic array -> tactic -> tactic array -> tactic

(* [tclTHENSLASTn tac1 [t1 ; ... ; tn] tac2 gls] applies [t1],...,[tn] on the
   last [n] resulting subgoals and [tac2] on the remaining first subgoals *)
val tclTHENSLASTn     : tactic -> tactic -> tactic array -> tactic

(* [tclTHENSFIRSTn tac1 [t1 ; ... ; tn] tac2 gls] first applies [tac1], then
   applies [t1],...,[tn] on the first [n] resulting subgoals and
   [tac2] for the remaining last subgoals (previously called tclTHENST) *)
val tclTHENSFIRSTn : tactic -> tactic array -> tactic -> tactic

(* [tclTHENLASTn tac1 [t1 ; ... ; tn] gls] first applies [tac1] then,
   applies [t1],...,[tn] on the last [n] resulting subgoals and leaves
   unchanged the other subgoals *)
val tclTHENLASTn    : tactic -> tactic array -> tactic

(* [tclTHENFIRSTn tac1 [t1 ; ... ; tn] gls] first applies [tac1] then,
   applies [t1],...,[tn] on the first [n] resulting subgoals and leaves
   unchanged the other subgoals (previously called [tclTHENSI]) *)
val tclTHENFIRSTn   : tactic -> tactic array -> tactic

(* A special exception for levels for the Fail tactic *)
exception FailError of int * Pp.std_ppcmds

(* Takes an exception and either raise it at the next
   level or do nothing. *)
val catch_failerror  : exn -> unit

val tclORELSE        : tactic -> tactic -> tactic
val tclREPEAT        : tactic -> tactic
val tclREPEAT_MAIN   : tactic -> tactic
val tclFIRST         : tactic list -> tactic
val tclSOLVE         : tactic list -> tactic
val tclTRY           : tactic -> tactic
val tclTHENTRY       : tactic -> tactic -> tactic
val tclCOMPLETE      : tactic -> tactic
val tclAT_LEAST_ONCE : tactic -> tactic
val tclFAIL          : int -> Pp.std_ppcmds -> tactic
val tclDO            : int -> tactic -> tactic
val tclPROGRESS      : tactic -> tactic
val tclWEAK_PROGRESS : tactic -> tactic
val tclNOTSAMEGOAL   : tactic -> tactic
val tclINFO          : tactic -> tactic

(* [tclIFTHENELSE tac1 tac2 tac3 gls] first applies [tac1] to [gls] then,
   if it succeeds, applies [tac2] to the resulting subgoals, 
   and if not applies [tac3] to the initial goal [gls] *)
val tclIFTHENELSE    : tactic -> tactic -> tactic -> tactic
val tclIFTHENSELSE   : tactic -> tactic list -> tactic ->tactic
val tclIFTHENSVELSE   : tactic -> tactic array -> tactic ->tactic

(* [tclIFTHENTRYELSEMUST tac1 tac2 gls] applies [tac1] then [tac2]. If [tac1]
   has been successful, then [tac2] may fail. Otherwise, [tac2] must succeed. 
   Equivalent to [(tac1;try tac2)||tac2] *)

val tclIFTHENTRYELSEMUST : tactic -> tactic -> tactic

(*s Tactics handling a list of goals. *)

type validation_list = proof_tree list -> proof_tree list

type tactic_list = (goal list sigma) -> (goal list sigma) * validation_list

val tclFIRSTLIST       : tactic_list list -> tactic_list
val tclIDTAC_list      : tactic_list
val first_goal         : 'a list sigma -> 'a sigma
val apply_tac_list     : tactic -> tactic_list
val then_tactic_list   : tactic_list -> tactic_list -> tactic_list
val tactic_list_tactic : tactic_list -> tactic
val goal_goal_list     : 'a sigma -> 'a list sigma


(*s Functions for handling the state of the proof editor. *)

type pftreestate

val proof_of_pftreestate : pftreestate -> proof_tree
val cursor_of_pftreestate : pftreestate -> int list
val is_top_pftreestate : pftreestate -> bool
val match_rule : (rule -> bool) -> pftreestate -> bool
val evc_of_pftreestate : pftreestate -> evar_map
val top_goal_of_pftreestate : pftreestate -> goal sigma
val nth_goal_of_pftreestate : int -> pftreestate -> goal sigma

val traverse : int -> pftreestate -> pftreestate
val map_pftreestate : 
  (evar_map ref -> proof_tree -> proof_tree) -> pftreestate -> pftreestate
val solve_nth_pftreestate : int -> tactic -> pftreestate -> pftreestate
val solve_pftreestate : tactic -> pftreestate -> pftreestate

(* a weak version of logical undoing, that is really correct only *)
(* if there are no existential variables.                         *)
val weak_undo_pftreestate : pftreestate -> pftreestate

val mk_pftreestate : goal -> pftreestate
val extract_open_proof : evar_map -> proof_tree -> constr * (int * types) list
val extract_open_pftreestate : pftreestate -> constr * Termops.meta_type_map
val extract_pftreestate : pftreestate -> constr
val first_unproven : pftreestate -> pftreestate
val last_unproven : pftreestate -> pftreestate
val nth_unproven : int -> pftreestate -> pftreestate
val node_prev_unproven : int -> pftreestate -> pftreestate
val node_next_unproven : int -> pftreestate -> pftreestate
val next_unproven : pftreestate -> pftreestate
val prev_unproven : pftreestate -> pftreestate
val top_of_tree : pftreestate -> pftreestate
val match_rule : (rule -> bool) -> pftreestate -> bool
val up_until_matching_rule : (rule -> bool) -> 
  pftreestate -> pftreestate
val up_to_matching_rule : (rule -> bool) -> 
  pftreestate -> pftreestate
val change_rule : (rule -> rule) -> pftreestate -> pftreestate
val change_constraints_pftreestate 
  : evar_map -> pftreestate -> pftreestate


(*s Pretty-printers. *)

(*i*)
open Pp
(*i*)
val set_info_printer :
  (evar_map -> named_context -> proof_tree -> Pp.std_ppcmds) -> unit