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|
(************************************************************************)
(* v * The Coq Proof Assistant / The Coq Development Team *)
(* <O___,, * INRIA - CNRS - LIX - LRI - PPS - Copyright 1999-2015 *)
(* \VV/ **************************************************************)
(* // * This file is distributed under the terms of the *)
(* * GNU Lesser General Public License Version 2.1 *)
(************************************************************************)
open Pp
open Errors
open Util
open Evd
open Environ
open Proof_type
open Logic
let sig_it x = x.it
let project x = x.sigma
(* Getting env *)
let pf_env gls = Global.env_of_context (Goal.V82.hyps (project gls) (sig_it gls))
let pf_hyps gls = named_context_of_val (Goal.V82.hyps (project gls) (sig_it gls))
let refiner pr goal_sigma =
let (sgl,sigma') = prim_refiner pr goal_sigma.sigma goal_sigma.it in
{ it = sgl; sigma = sigma'; }
(* Profiling refiner *)
let refiner =
if Flags.profile then
let refiner_key = Profile.declare_profile "refiner" in
Profile.profile2 refiner_key refiner
else refiner
(*********************)
(* Tacticals *)
(*********************)
let unpackage glsig = (ref (glsig.sigma)), glsig.it
let repackage r v = {it = v; sigma = !r; }
let apply_sig_tac r tac g =
Control.check_for_interrupt (); (* Breakpoint *)
let glsigma = tac (repackage r g) in
r := glsigma.sigma;
glsigma.it
(* [goal_goal_list : goal sigma -> goal list sigma] *)
let goal_goal_list gls = {it=[gls.it]; sigma=gls.sigma; }
(* identity tactic without any message *)
let tclIDTAC gls = goal_goal_list gls
(* the message printing identity tactic *)
let tclIDTAC_MESSAGE s gls =
Pp.msg_info (hov 0 s); pp_flush (); tclIDTAC gls
(* General failure tactic *)
let tclFAIL_s s gls = errorlabstrm "Refiner.tclFAIL_s" (str s)
(* A special exception for levels for the Fail tactic *)
exception FailError of int * std_ppcmds Lazy.t
(* The Fail tactic *)
let tclFAIL lvl s g = raise (FailError (lvl,lazy s))
let tclFAIL_lazy lvl s g = raise (FailError (lvl,s))
let start_tac gls =
let sigr, g = unpackage gls in
(sigr, [g])
let finish_tac (sigr,gl) = repackage sigr gl
(* Apply [tacfi.(i)] on the first n subgoals, [tacli.(i)] on the last
m subgoals, and [tac] on the others *)
let thens3parts_tac tacfi tac tacli (sigr,gs) =
let nf = Array.length tacfi in
let nl = Array.length tacli in
let ng = List.length gs in
if ng<nf+nl then errorlabstrm "Refiner.thensn_tac" (str "Not enough subgoals.");
let gll =
(List.map_i (fun i ->
apply_sig_tac sigr (if i<nf then tacfi.(i) else if i>=ng-nl then tacli.(nl-ng+i) else tac))
0 gs) in
(sigr,List.flatten gll)
(* Apply [taci.(i)] on the first n subgoals and [tac] on the others *)
let thensf_tac taci tac = thens3parts_tac taci tac [||]
(* Apply [tac i] on the ith subgoal (no subgoals number check) *)
let thensi_tac tac (sigr,gs) =
let gll =
List.map_i (fun i -> apply_sig_tac sigr (tac i)) 1 gs in
(sigr, List.flatten gll)
let then_tac tac = thensf_tac [||] tac
(* [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] *)
let tclTHENS3PARTS tac1 tacfi tac tacli gls =
finish_tac (thens3parts_tac tacfi tac tacli (then_tac tac1 (start_tac gls)))
(* [tclTHENSFIRSTn tac1 [|t1 ; ... ; tn|] tac2 gls] applies the tactic [tac1]
to [gls] and applies [t1], ..., [tn] to the first [n] resulting
subgoals, and [tac2] to the others subgoals. Raises an error if
the number of resulting subgoals is strictly less than [n] *)
let tclTHENSFIRSTn tac1 taci tac = tclTHENS3PARTS tac1 taci tac [||]
(* [tclTHENSLASTn tac1 tac2 [|t1 ;...; tn|] gls] applies the tactic [tac1]
to [gls] and applies [t1], ..., [tn] to the last [n] resulting
subgoals, and [tac2] to the other subgoals. Raises an error if the
number of resulting subgoals is strictly less than [n] *)
let tclTHENSLASTn tac1 tac taci = tclTHENS3PARTS tac1 [||] tac taci
(* [tclTHEN_i tac taci gls] applies the tactic [tac] to [gls] and applies
[(taci i)] to the i_th resulting subgoal (starting from 1), whatever the
number of subgoals is *)
let tclTHEN_i tac taci gls =
finish_tac (thensi_tac taci (then_tac tac (start_tac gls)))
let tclTHENLASTn tac1 taci = tclTHENSLASTn tac1 tclIDTAC taci
let tclTHENFIRSTn tac1 taci = tclTHENSFIRSTn tac1 taci tclIDTAC
(* [tclTHEN tac1 tac2 gls] applies the tactic [tac1] to [gls] and applies
[tac2] to every resulting subgoals *)
let tclTHEN tac1 tac2 = tclTHENS3PARTS tac1 [||] tac2 [||]
(* [tclTHENSV 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] *)
let tclTHENSV tac1 tac2v =
tclTHENS3PARTS tac1 tac2v (tclFAIL_s "Wrong number of tactics.") [||]
let tclTHENS tac1 tac2l = tclTHENSV tac1 (Array.of_list tac2l)
(* [tclTHENLAST tac1 tac2 gls] applies the tactic [tac1] to [gls] and [tac2]
to the last resulting subgoal *)
let tclTHENLAST tac1 tac2 = tclTHENSLASTn tac1 tclIDTAC [|tac2|]
(* [tclTHENFIRST tac1 tac2 gls] applies the tactic [tac1] to [gls] and [tac2]
to the first resulting subgoal *)
let tclTHENFIRST tac1 tac2 = tclTHENSFIRSTn tac1 [|tac2|] tclIDTAC
(* [tclTHENLIST [t1;..;tn]] applies [t1] then [t2] ... then [tn]. More
convenient than [tclTHEN] when [n] is large. *)
let rec tclTHENLIST = function
[] -> tclIDTAC
| t1::tacl -> tclTHEN t1 (tclTHENLIST tacl)
(* [tclMAP f [x1..xn]] builds [(f x1);(f x2);...(f xn)] *)
let tclMAP tacfun l =
List.fold_right (fun x -> (tclTHEN (tacfun x))) l tclIDTAC
(* PROGRESS tac ptree applies tac to the goal ptree and fails if tac leaves
the goal unchanged *)
let tclWEAK_PROGRESS tac ptree =
let rslt = tac ptree in
if Goal.V82.weak_progress rslt ptree then rslt
else errorlabstrm "Refiner.WEAK_PROGRESS" (str"Failed to progress.")
(* PROGRESS tac ptree applies tac to the goal ptree and fails if tac leaves
the goal unchanged *)
let tclPROGRESS tac ptree =
let rslt = tac ptree in
if Goal.V82.progress rslt ptree then rslt
else errorlabstrm "Refiner.PROGRESS" (str"Failed to progress.")
(* Same as tclWEAK_PROGRESS but fails also if tactics generates several goals,
one of them being identical to the original goal *)
let tclNOTSAMEGOAL (tac : tactic) goal =
let same_goal gls1 evd2 gl2 =
Goal.V82.same_goal gls1.sigma gls1.it evd2 gl2
in
let rslt = tac goal in
let {it=gls;sigma=sigma} = rslt in
if List.exists (same_goal goal sigma) gls
then errorlabstrm "Refiner.tclNOTSAMEGOAL"
(str"Tactic generated a subgoal identical to the original goal.")
else rslt
(* Execute tac and show the names of hypothesis create by tac in
the "as" format. The resulting goals are printed *after* the
as-expression, which forces pg to some gymnastic. TODO: Have
something similar (better?) in the xml protocol. *)
let tclSHOWHYPS (tac : tactic) (goal: Goal.goal Evd.sigma)
:Proof_type.goal list Evd.sigma =
let oldhyps:Context.named_context = pf_hyps goal in
let rslt:Proof_type.goal list Evd.sigma = tac goal in
let { it = gls; sigma = sigma; } = rslt in
let hyps:Context.named_context list =
List.map (fun gl -> pf_hyps { it = gl; sigma=sigma; }) gls in
let newhyps =
List.map
(fun hypl -> List.subtract Context.eq_named_declaration hypl oldhyps)
hyps
in
let emacs_str s =
if !Flags.print_emacs then s else "" in
let s =
let frst = ref true in
List.fold_left
(fun acc lh -> acc ^ (if !frst then (frst:=false;"") else " | ")
^ (List.fold_left
(fun acc (nm,_,_) -> (Names.Id.to_string nm) ^ " " ^ acc)
"" lh))
"" newhyps in
pp (str (emacs_str "<infoH>")
++ (hov 0 (str s))
++ (str (emacs_str "</infoH>")) ++ fnl());
rslt;;
let catch_failerror (e, info) =
if catchable_exception e then Control.check_for_interrupt ()
else match e with
| FailError (0,_) ->
Control.check_for_interrupt ()
| FailError (lvl,s) ->
iraise (FailError (lvl - 1, s), info)
| e -> iraise (e, info)
(** FIXME: do we need to add a [Errors.push] here? *)
(* ORELSE0 t1 t2 tries to apply t1 and if it fails, applies t2 *)
let tclORELSE0 t1 t2 g =
try
t1 g
with (* Breakpoint *)
| e when Errors.noncritical e ->
let e = Errors.push e in catch_failerror e; t2 g
(* ORELSE t1 t2 tries to apply t1 and if it fails or does not progress,
then applies t2 *)
let tclORELSE t1 t2 = tclORELSE0 (tclPROGRESS t1) t2
(* applies t1;t2then if t1 succeeds or t2else if t1 fails
t2* are called in terminal position (unless t1 produces more than
1 subgoal!) *)
let tclORELSE_THEN t1 t2then t2else gls =
match
try Some(tclPROGRESS t1 gls)
with e when Errors.noncritical e ->
let e = Errors.push e in catch_failerror e; None
with
| None -> t2else gls
| Some sgl ->
let sigr, gl = unpackage sgl in
finish_tac (then_tac t2then (sigr,gl))
(* TRY f tries to apply f, and if it fails, leave the goal unchanged *)
let tclTRY f = (tclORELSE0 f tclIDTAC)
let tclTHENTRY f g = (tclTHEN f (tclTRY g))
(* Try the first tactic that does not fail in a list of tactics *)
let rec tclFIRST = function
| [] -> tclFAIL_s "No applicable tactic."
| t::rest -> tclORELSE0 t (tclFIRST rest)
let ite_gen tcal tac_if continue tac_else gl=
let success=ref false in
let tac_if0 gl=
let result=tac_if gl in
success:=true;result in
let tac_else0 e gl=
if !success then
iraise e
else
try
tac_else gl
with
e' when Errors.noncritical e' -> iraise e in
try
tcal tac_if0 continue gl
with (* Breakpoint *)
| e when Errors.noncritical e ->
let e = Errors.push e in catch_failerror e; tac_else0 e gl
(* Try the first tactic and, if it succeeds, continue with
the second one, and if it fails, use the third one *)
let tclIFTHENELSE=ite_gen tclTHEN
(* Idem with tclTHENS and tclTHENSV *)
let tclIFTHENSELSE=ite_gen tclTHENS
let tclIFTHENSVELSE=ite_gen tclTHENSV
let tclIFTHENTRYELSEMUST tac1 tac2 gl =
tclIFTHENELSE tac1 (tclTRY tac2) tac2 gl
(* Fails if a tactic did not solve the goal *)
let tclCOMPLETE tac = tclTHEN tac (tclFAIL_s "Proof is not complete.")
(* Try the first thats solves the current goal *)
let tclSOLVE tacl = tclFIRST (List.map tclCOMPLETE tacl)
(* Iteration tacticals *)
let tclDO n t =
let rec dorec k =
if k < 0 then errorlabstrm "Refiner.tclDO"
(str"Wrong argument : Do needs a positive integer.");
if Int.equal k 0 then tclIDTAC
else if Int.equal k 1 then t else (tclTHEN t (dorec (k-1)))
in
dorec n
(* Beware: call by need of CAML, g is needed *)
let rec tclREPEAT t g =
tclORELSE_THEN t (tclREPEAT t) tclIDTAC g
let tclAT_LEAST_ONCE t = (tclTHEN t (tclREPEAT t))
(* Repeat on the first subgoal (no failure if no more subgoal) *)
let rec tclREPEAT_MAIN t g =
(tclORELSE (tclTHEN_i t (fun i -> if Int.equal i 1 then (tclREPEAT_MAIN t) else
tclIDTAC)) tclIDTAC) g
(* Change evars *)
let tclEVARS sigma gls = tclIDTAC {gls with sigma=sigma}
let tclEVARUNIVCONTEXT ctx gls = tclIDTAC {gls with sigma= Evd.set_universe_context gls.sigma ctx}
(* Push universe context *)
let tclPUSHCONTEXT rigid ctx tac gl =
tclTHEN (tclEVARS (Evd.merge_context_set rigid (project gl) ctx)) tac gl
let tclPUSHEVARUNIVCONTEXT ctx gl =
tclEVARS (Evd.merge_universe_context (project gl) ctx) gl
let tclPUSHCONSTRAINTS cst gl =
tclEVARS (Evd.add_constraints (project gl) cst) gl
|