(************************************************************************) (* * The Rocq Prover / The Rocq Development Team *) (* v * Copyright INRIA, CNRS and contributors *) (* <O___,, * (see version control and CREDITS file for authors & dates) *) (* \VV/ **************************************************************) (* // * This file is distributed under the terms of the *) (* * GNU Lesser General Public License Version 2.1 *) (* * (see LICENSE file for the text of the license) *) (************************************************************************)
open Pp open CErrors open Util open Names open Nameops open Constr open Context open Termops open Environ open EConstr open Vars open Namegen open Declarations open Inductiveops open Reductionops open Evd open Tacred open Genredexpr open Logic open Clenv open Tacticals open Hipattern open Rocqlib open Evarutil open Indrec open Pretype_errors open Unification open Locus open Locusops open Tactypes open Proofview.Notations open Context.Named.Declaration
exception IntroAlreadyDeclared of Id.t
exception ClearDependency of env * evar_map * Id.t option * Evarutil.clear_dependency_error * GlobRef.t option
exception ReplacingDependency of env * evar_map * Id.t * Evarutil.clear_dependency_error * GlobRef.t option
exception AlreadyUsed of Id.t
exception UsedTwice of Id.t
exception VariableHasNoValue of Id.t
exception ConvertIncompatibleTypes of env * evar_map * constr * constr
exception ConvertNotAType
exception NotConvertible
exception NotUnfoldable
exception NoQuantifiedHypothesis of quantified_hypothesis * bool
exception CannotFindInstance of Id.t
exception NothingToRewrite of Id.t
exception IllFormedEliminationType
exception UnableToApplyLemma of env * evar_map * constr * constr
exception DependsOnBody of Id.t list * Id.Set.t * Id.t option
exception NotRightNumberConstructors of int
exception NotEnoughConstructors
exception ConstructorNumberedFromOne
exception NoConstructors
exception UnexpectedExtraPattern of int option * delayed_open_constr intro_pattern_expr
exception CannotFindInductiveArgument
exception OneIntroPatternExpected
exception KeepAndClearModifierOnlyForHypotheses
exception FixpointOnNonInductiveType
exception NotEnoughProducts
exception AllMethodsInCoinductiveType
exception ReplacementIllTyped of exn
exception NotEnoughPremises
exception NeedDependentProduct
let error ?loc e =
Loc.raise ?loc e
let clear_in_global_msg = function
| None -> mt ()
| Some ref -> str " implicitly in " ++ Printer.pr_global ref
let clear_dependency_msg env sigma id err inglobal = let ppidupper = function Some id -> Id.print id | None -> str "This variable"in let ppid = function Some id -> Id.print id | None -> str "this variable"in let pp = clear_in_global_msg inglobal in match err with
| Evarutil.OccurHypInSimpleClause None ->
ppidupper id ++ str " is used" ++ pp ++ str " in conclusion."
| Evarutil.OccurHypInSimpleClause (Some id') ->
ppidupper id ++ strbrk " is used" ++ pp ++ str " in hypothesis " ++ Id.print id' ++ str"."
| Evarutil.EvarTypingBreak ev ->
str "Cannot remove " ++ ppid id ++
strbrk " without breaking the typing of " ++
Printer.pr_leconstr_env env sigma (mkEvar ev) ++ str"."
| Evarutil.NoCandidatesLeft ev ->
str "Cannot remove " ++ ppid id ++ str " as it would leave the existential " ++
Printer.pr_existential_key env sigma ev ++ str" without candidates."
let replacing_dependency_msg env sigma id err inglobal = let pp = clear_in_global_msg inglobal in match err with
| Evarutil.OccurHypInSimpleClause None ->
str "Cannot change " ++ Id.print id ++ str ", it is used" ++ pp ++ str " in conclusion."
| Evarutil.OccurHypInSimpleClause (Some id') ->
str "Cannot change " ++ Id.print id ++
strbrk ", it is used" ++ pp ++ str " in hypothesis " ++ Id.print id' ++ str"."
| Evarutil.EvarTypingBreak ev ->
str "Cannot change " ++ Id.print id ++
strbrk " without breaking the typing of " ++
Printer.pr_leconstr_env env sigma (mkEvar ev) ++ str"."
| Evarutil.NoCandidatesLeft ev ->
str "Cannot change " ++ Id.print id ++ str " as it would leave the existential " ++
Printer.pr_existential_key env sigma ev ++ str" without candidates."
let msg_quantified_hypothesis = function
| NamedHyp id ->
str "quantified hypothesis named " ++ Id.print id.CAst.v
| AnonHyp n ->
pr_nth n ++
str " non dependent hypothesis"
let explain_unexpected_extra_pattern bound pat = let nb = Option.get bound in let s1,s2,s3 = match pat with
| IntroNaming (IntroIdentifier _) -> "name", (String.plural nb " introduction pattern"), "no"
| _ -> "introduction pattern", "", "none"in
str "Unexpected " ++ str s1 ++ str " (" ++
(if Int.equal nb 0 then (str s3 ++ str s2) else
(str "at most " ++ int nb ++ str s2)) ++ spc () ++
str (if Int.equal nb 1 then"was"else"were") ++
strbrk " expected in the branch)."
exception Unhandled
let wrap_unhandled f e = try Some (f e) with Unhandled -> None
let tactic_interp_error_handler = function
| IntroAlreadyDeclared id ->
Id.print id ++ str " is already declared."
| ClearDependency (env,sigma,id,err,inglobal) ->
clear_dependency_msg env sigma id err inglobal
| ReplacingDependency (env,sigma,id,err,inglobal) ->
replacing_dependency_msg env sigma id err inglobal
| AlreadyUsed id ->
Id.print id ++ str " is already used."
| UsedTwice id ->
Id.print id ++ str" is used twice."
| VariableHasNoValue id ->
Id.print id ++ str" is not a defined hypothesis."
| ConvertIncompatibleTypes (env,sigma,t1,t2) ->
str "The first term has type" ++ spc () ++
quote (Termops.Internal.print_constr_env env sigma t1) ++ spc () ++
strbrk "while the second term has incompatible type" ++ spc () ++
quote (Termops.Internal.print_constr_env env sigma t2) ++ str "."
| ConvertNotAType ->
str "Not a type."
| NotConvertible ->
str "Not convertible."
| NotUnfoldable ->
str "Cannot unfold a non-constant."
| NoQuantifiedHypothesis (id,red) ->
str "No " ++ msg_quantified_hypothesis id ++
strbrk " in current goal" ++
(if red then strbrk " even after head-reduction"else mt ()) ++ str"."
| CannotFindInstance id ->
str "Cannot find an instance for " ++ Id.print id ++ str"."
| NothingToRewrite id ->
str "Nothing to rewrite in " ++ Id.print id ++ str"."
| IllFormedEliminationType ->
str "The type of elimination clause is not well-formed."
| UnableToApplyLemma (env,sigma,thm,t) ->
str "Unable to apply lemma of type" ++ brk(1,1) ++
quote (Printer.pr_leconstr_env env sigma thm) ++ spc() ++
str "on hypothesis of type" ++ brk(1,1) ++
quote (Printer.pr_leconstr_env env sigma t) ++
str "."
| DependsOnBody (idl,ids,where) -> let idl = List.filter (fun id -> Id.Set.mem id ids) idl in let on_the_bodies = function
| [] -> assert false
| [id] -> str " depends on the body of " ++ Id.print id
| l -> str " depends on the bodies of " ++ pr_sequence Id.print l in
(match where with
| None -> str "Conclusion" ++ on_the_bodies idl
| Some id -> str "Hypothesis " ++ Id.print id ++ on_the_bodies idl)
| NotRightNumberConstructors n ->
str "Not an inductive goal with " ++ int n ++ str (String.plural n " constructor") ++ str "."
| NotEnoughConstructors ->
str "Not enough constructors."
| ConstructorNumberedFromOne ->
str "The constructors are numbered starting from 1."
| NoConstructors ->
str "The type has no constructors."
| UnexpectedExtraPattern (bound,pat) ->
explain_unexpected_extra_pattern bound pat
| CannotFindInductiveArgument ->
str "Cannot find inductive argument of elimination scheme."
| OneIntroPatternExpected ->
str "Introduction pattern for one hypothesis expected."
| KeepAndClearModifierOnlyForHypotheses ->
str "keep/clear modifiers apply only to hypothesis names."
| FixpointOnNonInductiveType ->
str "Cannot do a fixpoint on a non inductive type."
| NotEnoughProducts ->
str "Not enough products."
| AllMethodsInCoinductiveType ->
str "All methods must construct elements in coinductive types."
| ReplacementIllTyped e ->
str "Replacement would lead to an ill-typed term:" ++ spc () ++ CErrors.print e
| NotEnoughPremises ->
str "Applied theorem does not have enough premises."
| NeedDependentProduct ->
str "Needs a non-dependent product."
| _ -> raise Unhandled
let _ = CErrors.register_handler (wrap_unhandled tactic_interp_error_handler)
let error_clear_dependency env sigma id err inglobal =
error (ClearDependency (env,sigma,Some id,err,inglobal))
let error_replacing_dependency env sigma id err inglobal =
error (ReplacingDependency (env,sigma,id,err,inglobal))
(** This tactic creates a partial proof realizing the introduction rule, but
does not check anything. *) let unsafe_intro env decl ~relevance b =
Refine.refine_with_principal ~typecheck:falsebeginfun sigma -> let ctx = named_context_val env in let nctx = push_named_context_val decl ctx in let inst = EConstr.identity_subst_val (named_context_val env) in let ninst = SList.cons (mkRel 1) inst in let nb = subst1 (mkVar (NamedDecl.get_id decl)) b in let (sigma, ev) = new_pure_evar nctx sigma ~relevance nb in
(sigma, mkLambda_or_LetIn (NamedDecl.to_rel_decl decl) (mkEvar (ev, ninst)),
Some ev) end
let introduction id =
Proofview.Goal.enter beginfun gl -> let concl = Proofview.Goal.concl gl in let relevance = Proofview.Goal.relevance gl in let sigma = Tacmach.project gl in let hyps = named_context_val (Proofview.Goal.env gl) in let env = Proofview.Goal.env gl in let () = if mem_named_context_val id hyps then
error (IntroAlreadyDeclared id) in letopen Context.Named.Declaration in match EConstr.kind sigma concl with
| Prod (id0, t, b) -> unsafe_intro env (LocalAssum ({id0 with binder_name=id}, t)) ~relevance b
| LetIn (id0, c, t, b) -> unsafe_intro env (LocalDef ({id0 with binder_name=id}, c, t)) ~relevance b
| _ -> raise (RefinerError (env, sigma, IntroNeedsProduct)) end
(* Not sure if being able to disable [cast] is useful. Uses seem picked somewhat randomly. *) let convert_concl ~cast ~check ty k =
Proofview.Goal.enter beginfun gl -> let env = Proofview.Goal.env gl in let conclty = Proofview.Goal.concl gl in
Refine.refine_with_principal ~typecheck:falsebeginfun sigma -> let sigma = if check thenbegin let sigma, _ = Typing.type_of env sigma ty in match Reductionops.infer_conv env sigma ty conclty with
| None -> error NotConvertible
| Some sigma -> sigma endelse sigma in let (sigma, x) = Evarutil.new_evar env sigma ty in let ans = ifnot cast then x else mkCast(x,k,conclty) in
(sigma, ans, Some (fst @@ destEvar sigma x)) end end
let convert_hyp ~check ~reorder d =
Proofview.Goal.enter beginfun gl -> let env = Proofview.Goal.env gl in let sigma = Tacmach.project gl in let ty = Proofview.Goal.concl gl in let sign = convert_hyp ~check ~reorder env sigma d in let env = reset_with_named_context sign env in
Refine.refine_with_principal ~typecheck:falsebeginfun sigma -> let sigma, ev = Evarutil.new_evar env sigma ty in
sigma, ev, Some (fst @@ destEvar sigma ev) end end
let convert_gen pb x y =
Proofview.Goal.enter beginfun gl -> match Tacmach.pf_apply (Reductionops.infer_conv ~pb) gl x y with
| Some sigma -> Proofview.Unsafe.tclEVARS sigma
| None -> error NotConvertible
| exception e when CErrors.noncritical e -> let _, info = Exninfo.capture e in (* FIXME: Sometimes an anomaly is raised from conversion *)
error ?loc:(Loc.get_loc info) NotConvertible end
let convert x y = convert_gen Conversion.CONV x y let convert_leq x y = convert_gen Conversion.CUMUL x y
(* This tactic enables users to remove hypotheses from the signature. * Some care is taken to prevent them from removing variables that are * subsequently used in other hypotheses or in the conclusion of the
* goal. *)
let clear_gen fail = function
| [] -> Proofview.tclUNIT ()
| ids ->
Proofview.Goal.enter beginfun gl -> let ids = List.fold_right Id.Set.add ids Id.Set.empty in (* clear_hyps_in_evi does not require nf terms *) let env = Proofview.Goal.env gl in let sigma = Tacmach.project gl in let concl = Proofview.Goal.concl gl in let (sigma, hyps, concl) = try clear_hyps_in_evi env sigma (named_context_val env) concl ids with Evarutil.ClearDependencyError (id,err,inglobal) -> fail env sigma id err inglobal in let env = reset_with_named_context hyps env in
Proofview.tclTHEN (Proofview.Unsafe.tclEVARS sigma)
(Refine.refine_with_principal ~typecheck:falsebeginfun sigma -> let sigma, ev = Evarutil.new_evar env sigma concl in
sigma, ev, Some (fst @@ destEvar sigma ev) end) end
let clear ids = clear_gen error_clear_dependency ids let clear_for_replacing ids = clear_gen error_replacing_dependency ids
let apply_clear_request clear_flag dft c = let doclear = match clear_flag with
| None -> if dft then c else None
| Some true -> beginmatch c with
| None -> error KeepAndClearModifierOnlyForHypotheses
| Some id -> Some id end
| Some false -> None in match doclear with
| None -> Proofview.tclUNIT ()
| Some id -> clear [id]
(* Moving hypotheses *) let move_hyp id dest =
Proofview.Goal.enter beginfun gl -> let env = Proofview.Goal.env gl in let sigma = Tacmach.project gl in let ty = Proofview.Goal.concl gl in let sign = named_context_val env in let sign' = move_hyp_in_named_context env sigma id dest sign in let env = reset_with_named_context sign' env in
Refine.refine_with_principal ~typecheck:falsebeginfun sigma -> let sigma, ev = Evarutil.new_evar env sigma ty in
sigma, ev, Some (fst @@ destEvar sigma ev) end end
(* Renaming hypotheses *) let rename_hyp repl = let fold accu (src, dst) = match accu with
| None -> None
| Some (srcs, dsts) -> if Id.Set.mem src srcs then None elseif Id.Set.mem dst dsts then None else let srcs = Id.Set.add src srcs in let dsts = Id.Set.add dst dsts in
Some (srcs, dsts) in let init = Some (Id.Set.empty, Id.Set.empty) in let dom = List.fold_left fold init repl in match dom with
| None -> let info = Exninfo.reify () in
Tacticals.tclZEROMSG ~info (str "Not a one-to-one name mapping")
| Some (src, dst) ->
Proofview.Goal.enter beginfun gl -> let concl = Proofview.Goal.concl gl in let env = Proofview.Goal.env gl in let sign = named_context_val env in let sigma = Proofview.Goal.sigma gl in let relevance = Proofview.Goal.relevance gl in (* Check that we do not mess variables *) let vars = ids_of_named_context_val sign in let () = ifnot (Id.Set.subset src vars) then let hyp = Id.Set.choose (Id.Set.diff src vars) in raise (RefinerError (env, sigma, NoSuchHyp hyp)) in let mods = Id.Set.diff vars src in let () = try let elt = Id.Set.choose (Id.Set.inter dst mods) in
error (AlreadyUsed elt) with Not_found -> () in (* All is well *) let make_subst (src, dst) = (src, mkVar dst) in let subst = List.map make_subst repl in let subst c = Vars.replace_vars sigma subst c in let replace id = tryList.assoc_f Id.equal id repl with Not_found -> id in letmap decl = decl |> NamedDecl.map_id replace |> NamedDecl.map_constr subst in let ohyps = named_context_of_val sign in let nhyps = List.mapmap ohyps in let nconcl = subst concl in let nctx = val_of_named_context nhyps in let fold odecl ndecl accu = if Id.equal (NamedDecl.get_id odecl) (NamedDecl.get_id ndecl) then
SList.default accu else
SList.cons (mkVar @@ NamedDecl.get_id odecl) accu in let instance = List.fold_right2 fold ohyps nhyps SList.empty in
Refine.refine_with_principal ~typecheck:falsebeginfun sigma -> let sigma, ev = Evarutil.new_pure_evar nctx sigma ~relevance nconcl in
sigma, mkEvar (ev, instance), Some ev end end
let fresh_id_in_env avoid id env = let avoid' = ids_of_named_context_val (named_context_val env) in let avoid = if Id.Set.is_empty avoid then avoid' else Id.Set.union avoid' avoid in
next_ident_away_in_goal (Global.env ()) id avoid
let new_fresh_id avoid id gl =
fresh_id_in_env avoid id (Proofview.Goal.env gl)
let id_of_name_with_default id = function
| Anonymous -> id
| Name id -> id
let default_id_of_sort sigma s = if ESorts.is_small sigma s then default_small_ident else default_type_ident
let default_id env sigma decl = letopen Context.Rel.Declaration in match decl with
| LocalAssum (name,t) -> let dft = default_id_of_sort sigma (Retyping.get_sort_of env sigma t) in
id_of_name_with_default dft name.binder_name
| LocalDef (name,b,_) -> id_of_name_using_hdchar env sigma b name.binder_name
(* Non primitive introduction tactics are treated by intro_then_gen There is possibly renaming, with possibly names to avoid and
possibly a move to do after the introduction *)
type name_flag =
| NamingAvoid of Id.Set.t
| NamingBasedOn of Id.t * Id.Set.t
| NamingMustBe of lident
let naming_of_name = function
| Anonymous -> NamingAvoid Id.Set.empty
| Name id -> NamingMustBe (CAst.make id)
let find_name mayrepl decl naming gl = match naming with
| NamingAvoid idl -> (* this case must be compatible with [find_intro_names] below. *) let env = Proofview.Goal.env gl in let sigma = Tacmach.project gl in
new_fresh_id idl (default_id env sigma decl) gl
| NamingBasedOn (id,idl) -> new_fresh_id idl id gl
| NamingMustBe {CAst.loc;v=id} -> (* When name is given, we allow to hide a global name *) let ids_of_hyps = Tacmach.pf_ids_set_of_hyps gl in ifnot mayrepl && Id.Set.mem id ids_of_hyps then
error ?loc (AlreadyUsed id);
id
(**************************************************************) (* Computing position of hypotheses for replacing *) (**************************************************************)
let get_next_hyp_position env sigma id = let rec aux = function
| [] -> error_no_such_hypothesis env sigma id
| decl :: right -> if Id.equal (NamedDecl.get_id decl) id then match right with decl::_ -> MoveBefore (NamedDecl.get_id decl) | [] -> MoveFirst else
aux right in
aux
let get_previous_hyp_position env sigma id = let rec aux dest = function
| [] -> error_no_such_hypothesis env sigma id
| decl :: right -> let hyp = NamedDecl.get_id decl in if Id.equal hyp id then dest else aux (MoveAfter hyp) right in
aux MoveLast
let clear_hyps2 env sigma ids sign t cl = try
Evarutil.clear_hyps2_in_evi env sigma sign t cl ids with Evarutil.ClearDependencyError (id,err,inglobal) ->
error_replacing_dependency env sigma id err inglobal
let internal_cut ?(check=true) replace id t =
Proofview.Goal.enter beginfun gl -> let env = Proofview.Goal.env gl in let sigma = Tacmach.project gl in let concl = Proofview.Goal.concl gl in let sign = named_context_val env in let r = Retyping.relevance_of_type env sigma t in let env',t,concl,sigma = if replace then let nexthyp = get_next_hyp_position env sigma id (named_context_of_val sign) in let sigma,sign',t,concl = clear_hyps2 env sigma (Id.Set.singleton id) sign t concl in let sign' = insert_decl_in_named_context env sigma (LocalAssum (make_annot id r,t)) nexthyp sign'in
Environ.reset_with_named_context sign' env,t,concl,sigma else
(if check && mem_named_context_val id sign then
error (IntroAlreadyDeclared id);
push_named (LocalAssum (make_annot id r,t)) env,t,concl,sigma) in let nf_t = nf_betaiota env sigma t in
Proofview.tclTHEN
(Proofview.Unsafe.tclEVARS sigma)
(Refine.refine_with_principal ~typecheck:falsebeginfun sigma -> let (sigma, ev) = Evarutil.new_evar env sigma nf_t in let (sigma, ev') = Evarutil.new_evar env' sigma concl in let term = mkLetIn (make_annot (Name id) r, ev, t, EConstr.Vars.subst_var sigma id ev') in
(sigma, term, Some (fst @@ destEvar sigma ev')) end) end
let assert_before_then_gen b naming t tac = letopen Context.Rel.Declaration in
Proofview.Goal.enter beginfun gl -> let id = find_name b (LocalAssum (make_annot Anonymous Sorts.Relevant,t)) naming gl in
Tacticals.tclTHENLAST
(internal_cut b id t)
(tac id) end
let assert_before_gen b naming t =
assert_before_then_gen b naming t (fun _ -> Proofview.tclUNIT ())
let assert_before na = assert_before_gen false (naming_of_name na) let assert_before_replacing id = assert_before_gen true (NamingMustBe (CAst.make id))
let replace_error_option err tac = match err with
| None -> tac
| Some (e, info) ->
Proofview.tclORELSE tac (fun _ -> Proofview.tclZERO ~info e)
let assert_after_then_gen b naming t tac = letopen Context.Rel.Declaration in
Proofview.Goal.enter beginfun gl -> let id = find_name b (LocalAssum (make_annot Anonymous Sorts.Relevant,t)) naming gl in
Tacticals.tclTHENFIRST
(internal_cut b id t <*> Proofview.cycle 1)
(tac id) end
let assert_after_gen b naming t =
assert_after_then_gen b naming t (fun _ -> (Proofview.tclUNIT ()))
let assert_after na = assert_after_gen false (naming_of_name na) let assert_after_replacing id = assert_after_gen true (NamingMustBe (CAst.make id))
(**************************************************************) (* Fixpoints and CoFixpoints *) (**************************************************************)
let rec mk_holes env sigma = function
| [] -> (sigma, [])
| arg :: rem -> let (sigma, arg) = Evarutil.new_evar env sigma arg in let (sigma, rem) = mk_holes env sigma rem in
(sigma, arg :: rem)
let rec check_mutind env sigma k cl = match EConstr.kind sigma (strip_outer_cast sigma cl) with
| Prod (na, c1, b) -> if Int.equal k 1 then try ignore (find_inductive env sigma c1) with Not_found -> error FixpointOnNonInductiveType else letopen Context.Rel.Declaration in
check_mutind (push_rel (LocalAssum (na, c1)) env) sigma (pred k) b
| LetIn (na, c1, t, b) -> letopen Context.Rel.Declaration in
check_mutind (push_rel (LocalDef (na, c1, t)) env) sigma k b
| _ -> error NotEnoughProducts
(* Refine as a fixpoint *) let mutual_fix f n rest j = Proofview.Goal.enter beginfun gl -> let env = Proofview.Goal.env gl in let sigma = Tacmach.project gl in let concl = Proofview.Goal.concl gl in let () = check_mutind env sigma n concl in let firsts, lasts = List.chop j rest in letall = firsts @ (f, n, concl) :: lasts in letall = List.map (fun (f, n, ar) -> let r = Retyping.relevance_of_type env sigma ar in
(f, r, n, ar)) all in let rec mk_sign sign = function
| [] -> sign
| (f, r, n, ar) :: oth -> letopen Context.Named.Declaration in let () = check_mutind env sigma n ar in if mem_named_context_val f sign then
error (IntroAlreadyDeclared f);
mk_sign (push_named_context_val (LocalAssum (make_annot f r, ar)) sign) oth in let nenv = reset_with_named_context (mk_sign (named_context_val env) all) env in
Refine.refine ~typecheck:falsebeginfun sigma -> let (sigma, evs) = mk_holes nenv sigma (List.map (fun (_,_,_,ar) -> ar) all) in let ids, rs, _, ars = List.split4 allin let evs = List.map (Vars.subst_vars sigma (List.rev ids)) evs in let indxs = Array.of_list (List.map (fun n -> n-1) (List.map (fun (_,_,n,_) -> n) all)) in let funnames = Array.of_list (List.map2 (fun i r -> make_annot (Name i) r) ids rs) in let bodies = Array.of_list evs in let typarray = Array.of_list ars in let oterm = mkFix ((indxs,0),(funnames,typarray,bodies)) in
(sigma, oterm) end end
let fix id n = mutual_fix id n [] 0
let rec check_is_mutcoind env sigma cl = let b = whd_all env sigma cl in match EConstr.kind sigma b with
| Prod (na, c1, b) -> letopen Context.Rel.Declaration in
check_is_mutcoind (push_rel (LocalAssum (na,c1)) env) sigma b
| _ -> try let _ = find_coinductive env sigma b in () with Not_found ->
error AllMethodsInCoinductiveType
(* Refine as a cofixpoint *) let mutual_cofix f others j = Proofview.Goal.enter beginfun gl -> let env = Proofview.Goal.env gl in let sigma = Tacmach.project gl in let concl = Proofview.Goal.concl gl in let firsts,lasts = List.chop j others in letall = firsts @ (f, concl) :: lasts in List.iter (fun (_, c) -> check_is_mutcoind env sigma c) all; letall = List.map (fun (id,t) -> (id, Retyping.relevance_of_type env sigma t, t)) allin let rec mk_sign sign = function
| [] -> sign
| (f, r, ar) :: oth -> letopen Context.Named.Declaration in if mem_named_context_val f sign then
error (AlreadyUsed f);
mk_sign (push_named_context_val (LocalAssum (make_annot f r, ar)) sign) oth in let nenv = reset_with_named_context (mk_sign (named_context_val env) all) env in
Refine.refine ~typecheck:falsebeginfun sigma -> let (ids, rs, types) = List.split3 allin let (sigma, evs) = mk_holes nenv sigma types in let evs = List.map (Vars.subst_vars sigma (List.rev ids)) evs in (* TODO relevance *) let funnames = Array.of_list (List.map2 (fun i r -> make_annot (Name i) r) ids rs) in let typarray = Array.of_list types in let bodies = Array.of_list evs in let oterm = mkCoFix (0, (funnames, typarray, bodies)) in
(sigma, oterm) end end
let cofix id = mutual_cofix id [] 0
(**************************************************************) (* Reduction and conversion tactics *) (**************************************************************)
type tactic_reduction = Reductionops.reduction_function type e_tactic_reduction = Reductionops.e_reduction_function
let[@ocaml.inline] (let*) m f = match m with
| NoChange -> NoChange
| Changed v -> f v
let e_pf_change_decl (redfun : bool -> Tacred.change_function) where env sigma decl = letopen Context.Named.Declaration in match decl with
| LocalAssum (id,ty) -> let () = if where == InHypValueOnly then error (VariableHasNoValue id.binder_name) in let* (sigma, ty') = redfun false env sigma ty in
Changed (sigma, LocalAssum (id, ty'))
| LocalDef (id,b,ty) -> let (sigma, b') = if where != InHypTypeOnly thenmatch redfun true env sigma b with
| NoChange -> (sigma, NoChange)
| Changed (sigma, b') -> (sigma, Changed b') else (sigma, NoChange) in let (sigma, ty') = if where != InHypValueOnly thenmatch redfun false env sigma ty with
| NoChange -> (sigma, NoChange)
| Changed (sigma, ty') -> (sigma, Changed ty') else (sigma, NoChange) in match b', ty'with
| NoChange, NoChange -> NoChange
| Changed b', NoChange -> Changed (sigma, LocalDef (id, b', ty))
| NoChange, Changed ty' -> Changed (sigma, LocalDef (id, b, ty'))
| Changed b', Changed ty' -> Changed (sigma, LocalDef (id, b', ty'))
let bind_change_occurrences occs = function
| None -> None
| Some c -> Some (Redexpr.out_with_occurrences (occs,c))
(* The following two tactics apply an arbitrary reduction function either to the conclusion or to a
certain hypothesis *)
let e_change_in_concl ~cast ~check (redfun, sty) =
Proofview.Goal.enter beginfun gl -> let sigma = Proofview.Goal.sigma gl in match redfun (Tacmach.pf_env gl) sigma (Tacmach.pf_concl gl) with
| NoChange -> Proofview.tclUNIT ()
| Changed (sigma, c') ->
Proofview.tclTHEN (Proofview.Unsafe.tclEVARS sigma)
(convert_concl ~cast ~check c' sty) end
let e_change_in_hyp ~check ~reorder redfun (id,where) =
Proofview.Goal.enter beginfun gl -> let sigma = Proofview.Goal.sigma gl in let hyp = Tacmach.pf_get_hyp id gl in match e_pf_change_decl redfun where (Proofview.Goal.env gl) sigma hyp with
| NoChange -> Proofview.tclUNIT ()
| Changed (sigma, c) ->
Proofview.tclTHEN (Proofview.Unsafe.tclEVARS sigma)
(convert_hyp ~check ~reorder c) end
let e_change_option ~check ~reorder (redfun, sty) = function
| None ->
e_change_in_concl ~cast:true ~check (redfun, sty)
| Some id -> let redfun _ env sigma c = redfun env sigma c in
e_change_in_hyp ~check ~reorder redfun id
type hyp_conversion =
| AnyHypConv (** Arbitrary conversion *)
| StableHypConv (** Does not introduce new dependencies on variables *)
| LocalHypConv (** Same as above plus no dependence on the named environment *)
let e_change_in_hyps ~check ~reorder f args = match args with
| [] -> Proofview.tclUNIT ()
| _ :: _ ->
Proofview.Goal.enter beginfun gl -> let env = Proofview.Goal.env gl in let sigma = Tacmach.project gl in let (env, sigma) = match reorder with
| LocalHypConv -> (* If the reduction function is known not to depend on the named
context, then we can perform it in parallel. *) let fold accu arg = let (id, redfun) = f arg in let old = try Id.Map.find id accu with Not_found -> [] in
Id.Map.add id (redfun :: old) accu in let reds = List.fold_left fold Id.Map.empty args in let evdref = ref sigma in letmap d = let id = NamedDecl.get_id d in match Id.Map.find id reds with
| reds -> let d = EConstr.of_named_decl d in let fold redfun (sigma, d) = match redfun env sigma d with
| NoChange -> sigma, d
| Changed (sigma, d) -> sigma, d in let (sigma, d) = List.fold_right fold reds (sigma, d) in let () = evdref := sigma in
EConstr.Unsafe.to_named_decl d
| exception Not_found -> d in let sign = Environ.map_named_val map (Environ.named_context_val env) in let env = reset_with_named_context sign env in
(env, !evdref)
| StableHypConv | AnyHypConv -> let reorder = reorder == AnyHypConv in let fold (env, sigma) arg = let (id, redfun) = f arg in let hyp = try lookup_named id env with Not_found -> raise (RefinerError (env, sigma, NoSuchHyp id)) in match redfun env sigma hyp with
| NoChange -> (env, sigma)
| Changed (sigma, d) -> let sign = Logic.convert_hyp ~check ~reorder env sigma d in let env = reset_with_named_context sign env in
(env, sigma) in List.fold_left fold (env, sigma) args in let ty = Proofview.Goal.concl gl in
Proofview.Unsafe.tclEVARS sigma
<*>
Refine.refine_with_principal ~typecheck:falsebeginfun sigma -> let sigma, ev = Evarutil.new_evar env sigma ty in
sigma, ev, Some (fst @@ destEvar sigma ev) end end
let e_reduct_in_concl ~cast ~check (redfun, sty) = let redfun env sigma c = Changed (redfun env sigma c) in
e_change_in_concl ~cast ~check (redfun, sty)
let reduct_in_concl ~cast ~check (redfun, sty) = let redfun env sigma c = Changed (sigma, redfun env sigma c) in
e_change_in_concl ~cast ~check (redfun, sty)
let e_reduct_in_hyp ~check ~reorder redfun (id, where) = let redfun _ env sigma c = Changed (redfun env sigma c) in
e_change_in_hyp ~check ~reorder redfun (id, where)
let reduct_in_hyp ~check ~reorder redfun (id, where) = let redfun _ env sigma c = Changed (sigma, redfun env sigma c) in
e_change_in_hyp ~check ~reorder redfun (id, where)
let e_reduct_option ~check redfun = function
| Some id -> e_reduct_in_hyp ~check ~reorder:check (fst redfun) id
| None -> e_reduct_in_concl ~cast:true ~check redfun
let reduct_option ~check (redfun, sty) where = let redfun env sigma c = (sigma, redfun env sigma c) in
e_reduct_option ~check (redfun, sty) where
let make_change_arg c pats env sigma =
Changed (sigma, replace_vars sigma (Id.Map.bindings pats) c) (* TODO: fast-path *)
let is_partial_template_head env sigma c = let (hd, args) = decompose_app sigma c in match destRef sigma hd with
| (ConstructRef (ind, _) | IndRef ind), _ -> let (mib, _) = Inductive.lookup_mind_specif env ind in beginmatch mib.mind_template with
| None -> false
| Some _ -> Array.length args < mib.mind_nparams end
| (VarRef _ | ConstRef _), _ -> false
| exception DestKO -> false
let check_types env sigma mayneedglobalcheck deep newc origc = let t1 = Retyping.get_type_of env sigma newc in if deep thenbegin let () = (* When changing a partially applied template term in a context, one must be careful to resynthetize the constraints as the implicit levels from
the arguments are not written in the term. *) if is_partial_template_head env sigma newc ||
is_partial_template_head env sigma origc then
mayneedglobalcheck := true in let t2 = Retyping.get_type_of env sigma origc in let sigma, t2 = Evarsolve.refresh_universes
~onlyalg:true (Some false) env sigma t2 in match infer_conv ~pb:Conversion.CUMUL env sigma t1 t2 with
| None -> if
isSort sigma (whd_all env sigma t1) &&
isSort sigma (whd_all env sigma t2) then (mayneedglobalcheck := true; sigma) else
error (ConvertIncompatibleTypes (env,sigma,t2,t1))
| Some sigma -> sigma end else ifnot (isSort sigma (whd_all env sigma t1)) then
error ConvertNotAType else sigma
(* Now we introduce different instances of the previous tacticals *) let change_and_check cv_pb mayneedglobalcheck deep t env sigma c = match t env sigma with
| NoChange -> NoChange
| Changed (sigma, t') -> let sigma = check_types env sigma mayneedglobalcheck deep t' c in match infer_conv ~pb:cv_pb env sigma t' c with
| None -> error NotConvertible
| Some sigma -> Changed (sigma, t')
(* Use cumulativity only if changing the conclusion not a subterm *) let change_on_subterm ~check cv_pb deep t where env sigma c = let mayneedglobalcheck = reffalsein let ans = match where with
| None -> if check then
change_and_check cv_pb mayneedglobalcheck deep (t Id.Map.empty) env sigma c else
t Id.Map.empty env sigma
| Some occl ->
e_contextually false occl
(fun subst -> if check then
change_and_check Conversion.CONV mayneedglobalcheck true (t subst) else fun env sigma _c -> t subst env sigma) env sigma c in match ans with
| NoChange -> NoChange
| Changed (sigma, c) -> let sigma = if !mayneedglobalcheck then begin try fst (Typing.type_of env sigma c) with e when noncritical e ->
error (ReplacementIllTyped e) endelse sigma in
Changed (sigma, c)
let change_in_concl ~check occl t = (* No need to check in e_change_in_concl, the check is done in change_on_subterm *)
e_change_in_concl ~cast:false ~check:false
((change_on_subterm ~check Conversion.CUMUL false t occl),DEFAULTcast)
let change_in_hyp ~check occl t id = (* Same as above *)
e_change_in_hyp ~check:false ~reorder:check (fun x -> change_on_subterm ~check Conversion.CONV x t occl) id
let concrete_clause_of enum_hyps cl = match cl.onhyps with
| None -> let f id = (id, AllOccurrences, InHyp) in List.map f (enum_hyps ())
| Some l -> List.map (fun ((occs, id), w) -> (id, occs, w)) l
let change ~check chg c cls =
Proofview.Goal.enter beginfun gl -> let hyps = concrete_clause_of (fun () -> Tacmach.pf_ids_of_hyps gl) cls in beginmatch cls.concl_occs with
| NoOccurrences -> Proofview.tclUNIT ()
| occs -> change_in_concl ~check (bind_change_occurrences occs chg) c end
<*> let f (id, occs, where) = let occl = bind_change_occurrences occs chg in let redfun deep env sigma t = change_on_subterm ~check Conversion.CONV deep c occl env sigma t in let redfun env sigma d = e_pf_change_decl redfun where env sigma d in
(id, redfun) in let reorder = if check then AnyHypConv else StableHypConv in (* Don't check, we do it already in [change_on_subterm] *)
e_change_in_hyps ~check:false ~reorder f hyps end
let change_concl t =
change_in_concl ~check:true None (make_change_arg t)
let red_product_exn env sigma c = match red_product env sigma c with
| None -> user_err Pp.(str "No head constant to reduce.")
| Some c -> c
(* Pour usage interne (le niveau User est pris en compte par reduce) *) let red_in_concl = reduct_in_concl ~cast:true ~check:false (red_product_exn,DEFAULTcast) let red_in_hyp = reduct_in_hyp ~check:false ~reorder:false red_product_exn let red_option = reduct_option ~check:false (red_product_exn,DEFAULTcast) let hnf_in_concl = reduct_in_concl ~cast:true ~check:false (hnf_constr,DEFAULTcast) let hnf_in_hyp = reduct_in_hyp ~check:false ~reorder:false hnf_constr let hnf_option = reduct_option ~check:false (hnf_constr,DEFAULTcast) let simpl_in_concl = reduct_in_concl ~cast:true ~check:false (simpl,DEFAULTcast) let simpl_in_hyp = reduct_in_hyp ~check:false ~reorder:false simpl let simpl_option = reduct_option ~check:false (simpl,DEFAULTcast) let normalise_in_concl = reduct_in_concl ~cast:true ~check:false (compute,DEFAULTcast) let normalise_in_hyp = reduct_in_hyp ~check:false ~reorder:false compute let normalise_option = reduct_option ~check:false (compute,DEFAULTcast) let normalise_vm_in_concl = reduct_in_concl ~cast:true ~check:false (Redexpr.cbv_vm,VMcast) let unfold_in_concl loccname = reduct_in_concl ~cast:true ~check:false (unfoldn loccname,DEFAULTcast) let unfold_in_hyp loccname = reduct_in_hyp ~check:false ~reorder:false (unfoldn loccname) let unfold_option loccname = reduct_option ~check:false (unfoldn loccname,DEFAULTcast) let pattern_option l = e_change_option ~check:false ~reorder:false (pattern_occs l,DEFAULTcast)
(* The main reduction function *)
let is_local_flag env flags = if flags.rDelta thenfalse else let check = function
| Evaluable.EvalVarRef _ -> false
| Evaluable.EvalConstRef c -> Id.Set.is_empty (Environ.vars_of_global env (GlobRef.ConstRef c))
| Evaluable.EvalProjectionRef c -> false(* FIXME *) in List.for_all check flags.rConst
let is_local_unfold env flags = let check (_, c) = match c with
| Evaluable.EvalVarRef _ -> false
| Evaluable.EvalConstRef c -> Id.Set.is_empty (Environ.vars_of_global env (GlobRef.ConstRef c))
| Evaluable.EvalProjectionRef c -> false(* FIXME *) in List.for_all check flags
let change_of_red_expr_val ?occs redexp = let (redfun, kind) = Redexpr.reduction_of_red_expr_val ?occs redexp in let redfun env sigma c = Changed (redfun env sigma c) in(* TODO: fast-path *)
(redfun, kind)
let reduce redexp cl = let trace env sigma = letopen Printer in let pr = ((fun e -> pr_econstr_env e), (fun e -> pr_leconstr_env e), pr_evaluable_reference, pr_constr_pattern_env, int) in
Pp.(hov 2 (Ppred.pr_red_expr_env env sigma pr str redexp)) in
Proofview.Goal.enter beginfun gl -> let env = Proofview.Goal.env gl in let sigma = Proofview.Goal.sigma gl in let hyps = concrete_clause_of (fun () -> Tacmach.pf_ids_of_hyps gl) cl in let nbcl = (if cl.concl_occs = NoOccurrences then 0 else 1) + List.length hyps in let check = match redexp with Fold _ | Pattern _ -> true | _ -> falsein let reorder = match redexp with
| Fold _ | Pattern _ -> AnyHypConv
| Simpl (flags, _) | Cbv flags | Cbn flags | Lazy flags -> if is_local_flag env flags then LocalHypConv else StableHypConv
| Unfold flags -> if is_local_unfold env flags then LocalHypConv else StableHypConv
| Red | Hnf | CbvVm _ | CbvNative _ -> StableHypConv
| ExtraRedExpr _ -> StableHypConv (* Should we be that lenient ?*) in let redexp = Redexpr.eval_red_expr env redexp in
Proofview.Trace.name_tactic (fun () -> trace env sigma) begin beginmatch cl.concl_occs with
| NoOccurrences -> Proofview.tclUNIT ()
| occs -> let occs = Redexpr.out_occurrences occs in let redfun = change_of_red_expr_val ~occs:(occs, nbcl) redexp in
e_change_in_concl ~cast:true ~check redfun end
<*> let f (id, occs, where) = let occs = Redexpr.out_occurrences occs in let (redfun, _) = change_of_red_expr_val ~occs:(occs, nbcl) redexp in let redfun _ env sigma c = redfun env sigma c in let redfun env sigma d = e_pf_change_decl redfun where env sigma d in
(id, redfun) in
e_change_in_hyps ~check ~reorder f hyps end end
(* Unfolding occurrences of a constant *)
let unfold_constr = function
| GlobRef.ConstRef sp -> unfold_in_concl [AllOccurrences,EvalConstRef sp]
| GlobRef.VarRef id -> unfold_in_concl [AllOccurrences,EvalVarRef id]
| _ -> error NotUnfoldable
(* Returns the names that would be created by intros, without doing intros. This function is supposed to be compatible with an iteration of [find_name] above. As [default_id] checks the sort of the type to build hyp names, we maintain an environment to be able
to type dependent hyps. *) let find_intro_names env0 sigma ctxt = let _, res, _ = List.fold_right
(fun decl acc -> let env,idl,avoid = acc in let name = fresh_id_in_env avoid (default_id env sigma decl) env0 in let newenv = push_rel decl env in
(newenv, name :: idl, Id.Set.add name avoid))
ctxt (env0, [], Id.Set.empty) in List.rev res
let build_intro_tac id dest tac = match dest with
| MoveLast -> Tacticals.tclTHEN (introduction id) (tac id)
| dest -> Tacticals.tclTHENLIST
[introduction id; move_hyp id dest; tac id]
let rec intro_then_gen name_flag move_flag ~force ~dep tac = letopen Context.Rel.Declaration in
Proofview.Goal.enter beginfun gl -> let sigma = Tacmach.project gl in let env = Tacmach.pf_env gl in let concl = Proofview.Goal.concl gl in match EConstr.kind sigma concl with
| Prod (name,t,u) when not dep || not (noccurn sigma 1 u) -> let name = find_name false (LocalAssum (name,t)) name_flag gl in
build_intro_tac name move_flag tac
| LetIn (name,b,t,u) when not dep || not (noccurn sigma 1 u) -> let name = find_name false (LocalDef (name,b,t)) name_flag gl in
build_intro_tac name move_flag tac
| Evar ev when force -> let name = find_name false (LocalAssum (anonR,concl)) name_flag gl in let sigma, t = Evardefine.define_evar_as_product env sigma ~name ev in
Tacticals.tclTHEN
(Proofview.Unsafe.tclEVARS sigma)
(intro_then_gen name_flag move_flag ~force ~dep tac)
| _ -> beginifnot force then let info = Exninfo.reify () in
Proofview.tclZERO ~info (RefinerError (env, sigma, IntroNeedsProduct)) (* Note: red_in_concl includes betaiotazeta and this was like *) (* this since at least V6.3 (a pity *) (* that intro do betaiotazeta only when reduction is needed; and *) (* probably also a pity that intro does zeta *) else Proofview.tclUNIT () end <*>
Proofview.tclORELSE
(Tacticals.tclTHEN hnf_in_concl
(intro_then_gen name_flag move_flag ~force:false ~dep tac)) begin function (e, info) -> match e with
| RefinerError (env, sigma, IntroNeedsProduct) ->
Tacticals.tclZEROMSG ~info (str "No product even after head-reduction.")
| e -> Proofview.tclZERO ~info e end end
let drop_intro_name (_ : Id.t) = Proofview.tclUNIT ()
let intro_gen n m ~force ~dep = intro_then_gen n m ~force ~dep drop_intro_name let intro_mustbe_force id = intro_gen (NamingMustBe (CAst.make id)) MoveLast ~force:true ~dep:false let intro_using_then id = intro_then_gen (NamingBasedOn (id, Id.Set.empty)) MoveLast ~force:false ~dep:false let intro_using id = intro_using_then id drop_intro_name
let intro_then = intro_then_gen (NamingAvoid Id.Set.empty) MoveLast ~force:false ~dep:false let intro = intro_then drop_intro_name let introf = intro_gen (NamingAvoid Id.Set.empty) MoveLast ~force:true ~dep:false let intro_avoiding l = intro_gen (NamingAvoid l) MoveLast ~force:false ~dep:false
let intro_move_avoid idopt avoid hto = match idopt with
| None -> intro_gen (NamingAvoid avoid) hto ~force:true ~dep:false
| Some id -> intro_gen (NamingMustBe (CAst.make id)) hto ~force:true ~dep:false
let intro_move idopt hto = intro_move_avoid idopt Id.Set.empty hto
(**** Multiple introduction tactics ****)
let rec intros_using = function
| [] -> Proofview.tclUNIT()
| str::l -> Tacticals.tclTHEN (intro_using str) (intros_using l)
let rec intros_mustbe_force = function
| [] -> Proofview.tclUNIT()
| str::l -> Tacticals.tclTHEN (intro_mustbe_force str) (intros_mustbe_force l)
let rec intros_using_then_helper tac acc = function
| [] -> tac (List.rev acc)
| str::l -> intro_using_then str (fun str' -> intros_using_then_helper tac (str'::acc) l) let intros_using_then l tac = intros_using_then_helper tac [] l
let is_overbound bound n = match bound with None -> false | Some p -> n >= p
let intro_forthcoming_last_then_gen avoid dep_flag bound n tac = letopen RelDecl in
Proofview.Goal.enter beginfun gl -> let env = Proofview.Goal.env gl in let sigma = Proofview.Goal.sigma gl in let concl = Proofview.Goal.concl gl in let relevance = Proofview.Goal.relevance gl in let avoid = let avoid' = ids_of_named_context_val (named_context_val env) in if Id.Set.is_empty avoid then avoid' else Id.Set.union avoid' avoid in let rec decompose env avoid n concl subst decls ndecls = let decl = if is_overbound bound n then None elsematch EConstr.kind sigma concl with
| Prod (na, t, u) when not dep_flag || not (noccurn sigma 1 u) ->
Some (LocalAssum (na, t), u)
| LetIn (na, b, t, u) when not dep_flag || not (noccurn sigma 1 u) ->
Some (LocalDef (na, b, t), u)
| _ -> None in match decl with
| None -> ndecls, decls, Vars.esubst Vars.lift_substituend subst concl
| Some (decl, concl) -> let id = default_id env sigma decl in let id = next_ident_away_in_goal (Global.env ()) id avoid in let avoid = Id.Set.add id avoid in let env = EConstr.push_rel decl env in let ndecl = NamedDecl.of_rel_decl (fun _ -> id) decl in let ndecl = NamedDecl.map_constr (fun c -> Vars.esubst Vars.lift_substituend subst c) ndecl in let subst = Esubst.subs_cons (make_substituend @@ mkVar id) subst in
decompose env avoid (n + 1) concl subst (decl :: decls) (ndecl :: ndecls) in let (ndecls, decls, nconcl) = decompose env avoid n concl (Esubst.subs_id 0) [] [] in let ids = List.map NamedDecl.get_id ndecls in ifList.is_empty ids then tac [] else Refine.refine_with_principal ~typecheck:falsebeginfun sigma -> let ctx = named_context_val env in let nctx = List.fold_right push_named_context_val ndecls ctx in let inst = SList.defaultn (List.length @@ Environ.named_context env) SList.empty in let rels = List.init (List.length decls) (fun i -> mkRel (i + 1)) in let ninst = List.fold_right (fun c accu -> SList.cons c accu) rels inst in let (sigma, ev) = new_pure_evar nctx sigma ~relevance nconcl in
(sigma, it_mkLambda_or_LetIn (mkEvar (ev, ninst)) decls,
Some ev) end <*> tac ids end
let intro_forthcoming_then_gen avoid move_flag ~dep bound n tac = match move_flag with
| MoveLast -> (* Fast path *)
intro_forthcoming_last_then_gen avoid dep bound n tac
| MoveFirst | MoveAfter _ | MoveBefore _ -> let rec aux n ids = (* Note: we always use the bound when there is one for "*" and "**" *) ifnot (is_overbound bound n) then
Proofview.tclORELSE begin
intro_then_gen (NamingAvoid avoid) move_flag ~force:false ~dep
(fun id -> aux (n+1) (id::ids)) end begin function (e, info) -> match e with
| RefinerError (env, sigma, IntroNeedsProduct) ->
tac ids
| e -> Proofview.tclZERO ~info e end else
tac ids in
aux n []
let intro_replacing id =
Proofview.Goal.enter beginfun gl -> let env, sigma = Proofview.Goal.(env gl, sigma gl) in let hyps = Proofview.Goal.hyps gl in let next_hyp = get_next_hyp_position env sigma id hyps in
Tacticals.tclTHENLIST [
clear_for_replacing [id];
introduction id;
move_hyp id next_hyp;
] end
(* We have e.g. [x, y, y', x', y'' |- forall y y' y'', G] and want to reintroduce y, y,' y''. Note that we have to clear y, y' and y''
before introducing y because y' or y'' can e.g. depend on old y. *)
(* This version assumes that replacement is actually possible *) (* (ids given in the introduction order) *) (* We keep a sub-optimality in cleaing for compatibility with *) (* the behavior of inversion *) let intros_possibly_replacing ids = let suboptimal = truein
Proofview.Goal.enter beginfun gl -> let env, sigma = Proofview.Goal.(env gl, sigma gl) in let hyps = Proofview.Goal.hyps gl in let posl = List.map (fun id -> (id, get_next_hyp_position env sigma id hyps)) ids in
Tacticals.tclTHEN
(Tacticals.tclMAP (fun id ->
Tacticals.tclTRY (clear_for_replacing [id]))
(if suboptimal then ids elseList.rev ids))
(Tacticals.tclMAP (fun (id,pos) ->
Tacticals.tclORELSE (intro_move (Some id) pos) (intro_using id))
posl) end
(* This version assumes that replacement is actually possible *) let intros_replacing ids =
Proofview.Goal.enter beginfun gl -> let hyps = Proofview.Goal.hyps gl in let env, sigma = Proofview.Goal.(env gl, sigma gl) in let posl = List.map (fun id -> (id, get_next_hyp_position env sigma id hyps)) ids in
Tacticals.tclTHEN
(clear_for_replacing ids)
(Tacticals.tclMAP (fun (id,pos) -> intro_move (Some id) pos) posl) end
(* The standard for implementing Automatic Introduction *) let auto_intros_tac ids = let fold used = function
| Name id -> Id.Set.add id used
| Anonymous -> used in let avoid = NamingAvoid (List.fold_left fold Id.Set.empty ids) in let naming = function
| Name id -> NamingMustBe CAst.(make id)
| Anonymous -> avoid in
Tacticals.tclMAP (fun name -> intro_gen (naming name) MoveLast ~force:true ~dep:false) (List.rev ids)
(* User-level introduction tactics *)
let lookup_hypothesis_as_renamed env sigma ccl = function
| AnonHyp n -> Detyping.lookup_index_as_renamed env sigma ccl n
| NamedHyp id -> Detyping.lookup_name_as_displayed env sigma ccl id.CAst.v
let lookup_hypothesis_as_renamed_gen red h gl = let env = Proofview.Goal.env gl in let rec aux ccl = match lookup_hypothesis_as_renamed env (Tacmach.project gl) ccl h with
| None when red -> beginmatch red_product env (Proofview.Goal.sigma gl) ccl with
| None -> None
| Some c -> aux c end
| x -> x in
aux (Proofview.Goal.concl gl)
let is_quantified_hypothesis id gl = match lookup_hypothesis_as_renamed_gen false (NamedHyp (CAst.make id)) gl with
| Some _ -> true
| None -> false
let warn_deprecated_intros_until_0 =
CWarnings.create ~name:"deprecated-intros-until-0" ~category:CWarnings.CoreCategories.tactics
(fun () ->
strbrk"\"intros until 0\" is deprecated, use \"intros *\"; instead of \"induction 0\" and \"destruct 0\" use explicitly a name.\"")
let depth_of_quantified_hypothesis red h gl = if h = AnonHyp 0 then warn_deprecated_intros_until_0 (); match lookup_hypothesis_as_renamed_gen red h gl with
| Some depth -> depth
| None -> error (NoQuantifiedHypothesis(h,red))
let intros_until_gen red h =
Proofview.Goal.enter beginfun gl -> let n = depth_of_quantified_hypothesis red h gl in
Tacticals.tclDO n (if red then introf else intro) end
let intros_until_id id = intros_until_gen false (NamedHyp (CAst.make id)) let intros_until_n_gen red n = intros_until_gen red (AnonHyp n)
let intros_until = intros_until_gen true let intros_until_n = intros_until_n_gen true
let tclCHECKVAR id =
Proofview.Goal.enter beginfun gl -> let _ = Tacmach.pf_get_hyp id gl in
Proofview.tclUNIT () end
let try_intros_until_id_check id =
Tacticals.tclORELSE (intros_until_id id) (tclCHECKVAR id)
let try_intros_until tac = function
| NamedHyp {CAst.v=id} -> Tacticals.tclTHEN (try_intros_until_id_check id) (tac id)
| AnonHyp n -> Tacticals.tclTHEN (intros_until_n n) (Tacticals.onLastHypId tac)
type evars_flag = bool(* true = pose evars false = fail on evars *) type rec_flag = bool(* true = recursive false = not recursive *) type advanced_flag = bool(* true = advanced false = basic *) type clear_flag = booloption(* true = clear hyp, false = keep hyp, None = use default *)
type'a core_destruction_arg =
| ElimOnConstr of'a
| ElimOnIdent of lident
| ElimOnAnonHyp of int
type'a destruction_arg =
clear_flag * 'a core_destruction_arg
let onInductionArg tac = function
| clear_flag,ElimOnConstr cbl ->
tac clear_flag cbl
| clear_flag,ElimOnAnonHyp n ->
Tacticals.tclTHEN
(intros_until_n n)
(Tacticals.onLastHyp (fun c -> tac clear_flag (c,NoBindings)))
| clear_flag,ElimOnIdent {CAst.v=id} -> (* A quantified hypothesis *)
Tacticals.tclTHEN
(try_intros_until_id_check id)
(tac clear_flag (mkVar id,NoBindings))
let map_destruction_arg f sigma = function
| clear_flag,ElimOnConstr g -> let sigma,x = f sigma g in (sigma, (clear_flag,ElimOnConstr x))
| clear_flag,ElimOnAnonHyp n as x -> (sigma,x)
| clear_flag,ElimOnIdent id as x -> (sigma,x)
let finish_evar_resolution ?(flags=Pretyping.all_and_fail_flags) env current_sigma (pending,c) = let sigma = Pretyping.solve_remaining_evars flags env current_sigma ?initial:pending in
(sigma, nf_evar sigma c)
let finish_delayed_evar_resolution with_evars env sigma f = let (sigma', (c, lbind)) = f env sigma in let flags = tactic_infer_flags with_evars in let (sigma', c) = finish_evar_resolution ~flags env sigma' (Some sigma,c) in
(sigma', (c, lbind))
let force_destruction_arg with_evars env sigma c =
map_destruction_arg (finish_delayed_evar_resolution with_evars env) sigma c
(****************************************) (* tactic "cut" (actually modus ponens) *) (****************************************)
let cut c =
Proofview.Goal.enter beginfun gl -> let env = Proofview.Goal.env gl in let sigma = Tacmach.project gl in let concl = Proofview.Goal.concl gl in (* Backward compat: ensure that [c] is well-typed. Plus we need to
know the relevance *) match Typing.sort_of env sigma c with
| exception e when noncritical e -> let _, info = Exninfo.capture e in
Tacticals.tclZEROMSG ~info (str "Not a proposition or a type.")
| sigma, s -> let r = ESorts.relevance_of_sort s in let id = next_name_away_with_default "H" Anonymous (Tacmach.pf_ids_set_of_hyps gl) in
Proofview.tclTHEN (Proofview.Unsafe.tclEVARS sigma)
(Refine.refine_with_principal ~typecheck:falsebeginfun h -> let (h, f) = Evarutil.new_evar env h (mkArrow c r concl) in let ev = fst @@ destEvar h f in let (h, x) = Evarutil.new_evar env h c in let f = mkLetIn (make_annot (Name id) r, x, c, mkApp (f, [|mkRel 1|])) in
(h, f, Some ev) end) end
let check_unresolved_evars_of_metas sigma clenv = (* This checks that Metas turned into Evars by *) (* Refiner.pose_all_metas_as_evars are resolved *) let metas = clenv_meta_list clenv in let iter mv () = match Unification.Meta.meta_opt_fvalue metas mv with
| Some c -> beginmatch Constr.kind (EConstr.Unsafe.to_constr c.rebus) with
| Evar (evk,_) when Evd.is_undefined (clenv_evd clenv) evk
&& not (Evd.mem sigma evk) -> let na = Unification.Meta.meta_name metas mv in let id = match na with Name id -> id | _ -> anomaly (Pp.str "unnamed dependent meta.") in
error (CannotFindInstance id)
| _ -> () end
| None -> () in
Unification.Meta.fold iter metas ()
let do_replace id = function
| NamingMustBe {CAst.v=id'} when Option.equal Id.equal id (Some id') -> true
| _ -> false
(* For a clenv expressing some lemma [C[?1:T1,...,?n:Tn] : P] and some goal [G], [clenv_refine_in] returns [n+1] subgoals, the [n] last ones (resp [n] first ones if [sidecond_first] is [true]) being the [Ti] and the first one (resp last one) being [G] whose hypothesis
[id] is replaced by P using the proof given by [tac] *)
let clenv_refine_in with_evars targetid replace env sigma0 clenv = let clenv = Clenv.clenv_pose_dependent_evars ~with_evars clenv in let evd = Typeclasses.resolve_typeclasses ~fail:(not with_evars) env (clenv_evd clenv) in let clenv = Clenv.update_clenv_evd clenv evd (Clenv.clenv_meta_list clenv) in let new_hyp_typ = clenv_type clenv in ifnot with_evars then check_unresolved_evars_of_metas sigma0 clenv; let [@ocaml.warning "-3"] exact_tac = Clenv.Internal.refiner clenv in let naming = NamingMustBe (CAst.make targetid) in
Proofview.Unsafe.tclEVARS evd <*>
Proofview.Goal.enter beginfun gl -> let id = find_name replace (LocalAssum (make_annot Anonymous Sorts.Relevant, new_hyp_typ)) naming gl in
Tacticals.tclTHENLAST (internal_cut replace id new_hyp_typ <*> Proofview.cycle 1) exact_tac end
let nth_arg i c = match i with
| None -> List.last c
| Some i -> List.nth c i
let index_of_ind_arg sigma t = let rec aux i j t = match EConstr.kind sigma t with
| LetIn (_, _, _, t) -> aux i j t
| Prod (_,t,u) -> (* heuristic *) if isInd sigma (fst (decompose_app sigma t)) then aux (Some j) (j+1) u else aux i (j+1) u
| _ -> match i with
| Some i -> i
| None -> error CannotFindInductiveArgument in aux None 0 t
(* * Elimination tactic with bindings and using an arbitrary * elimination constant called elimc. This constant should end * with a clause (x:I)(P .. ), where P is a bound variable. * The term c is of type t, which is a product ending with a type * matching I, lbindc are the expected terms for c arguments
*)
type eliminator =
| ElimConstant of (Constant.t * EInstance.t) (* Constant generated by a scheme function *)
| ElimClause of EConstr.constr with_bindings (* Arbitrary expression provided by the user *)
let general_elim_clause0 with_evars flags (submetas, c, ty) elim =
Proofview.Goal.enter beginfun gl -> let env = Proofview.Goal.env gl in let sigma = Proofview.Goal.sigma gl in let clause, bindings, index = match elim with
| ElimConstant cst -> let elimc = mkConstU cst in let elimt = Retyping.get_type_of env sigma elimc in let i = index_of_ind_arg sigma elimt in
(elimc, elimt), NoBindings, Some i
| ElimClause (elimc, lbindelimc) -> let elimt = Retyping.get_type_of env sigma elimc in
(elimc, elimt), lbindelimc, None in let elimclause = make_clenv_binding env sigma clause bindings in let indmv = try nth_arg index (clenv_arguments elimclause) with Failure _ | Invalid_argument _ -> error IllFormedEliminationType in let elimclause = clenv_instantiate ~flags ~submetas indmv elimclause (c, ty) in
Clenv.res_pf elimclause ~with_evars ~with_classes:true ~flags end
let general_elim_clause_in0 with_evars flags id (submetas, c, ty) elim =
Proofview.Goal.enter beginfun gl -> let env = Proofview.Goal.env gl in let sigma = Tacmach.project gl in let elimc = mkConstU elim in let elimt = Retyping.get_type_of env sigma elimc in let i = index_of_ind_arg sigma elimt in let elimclause = mk_clenv_from env sigma (elimc, elimt) in let indmv = try nth_arg (Some i) (clenv_arguments elimclause) with Failure _ | Invalid_argument _ -> error IllFormedEliminationType in (* Assumes that the metas of [c] are part of [sigma] already *) let hypmv = matchList.remove Int.equal indmv (clenv_independent elimclause) with
| [a] -> a
| _ -> error IllFormedEliminationType in let elimclause = clenv_instantiate ~flags ~submetas indmv elimclause (c, ty) in let hyp = mkVar id in let hyp_typ = Retyping.get_type_of env sigma hyp in let elimclause = try clenv_instantiate ~flags hypmv elimclause (hyp, hyp_typ) with PretypeError (env,evd,NoOccurrenceFound (op,_)) -> (* Set the hypothesis name in the message *) raise (PretypeError (env,evd,NoOccurrenceFound (op,Some id))) in let new_hyp_typ = clenv_type elimclause in if EConstr.eq_constr sigma hyp_typ new_hyp_typ then
error (NothingToRewrite id);
clenv_refine_in with_evars id true env sigma elimclause end
let general_elim with_evars clear_flag (c, lbindc) elim =
Proofview.Goal.enter beginfun gl -> let env = Proofview.Goal.env gl in let sigma = Tacmach.project gl in let ct = Retyping.get_type_of env sigma c in let id = try Some (destVar sigma c) with DestKO -> None in let t = try snd (reduce_to_quantified_ind env sigma ct) with UserError _ -> ct in let indclause = make_clenv_binding env sigma (c, t) lbindc in let flags = elim_flags () in let metas = clenv_meta_list indclause in let submetas = (clenv_arguments indclause, metas) in
Proofview.Unsafe.tclEVARS (clenv_evd indclause) <*>
Tacticals.tclTHEN
(general_elim_clause0 with_evars flags (submetas, c, clenv_type indclause) elim)
(apply_clear_request clear_flag (use_clear_hyp_by_default ()) id) end
let general_elim_clause with_evars flags where arg elim =
Proofview.tclENV >>= fun env ->
Proofview.tclEVARMAP >>= fun sigma -> let (sigma, (elim, u)) = Evd.fresh_constant_instance env sigma elim in
Proofview.Unsafe.tclEVARS sigma <*> match where with
| None -> general_elim_clause0 with_evars flags arg (ElimConstant (elim, EInstance.make u))
| Some id -> general_elim_clause_in0 with_evars flags id arg (elim, EInstance.make u)
(* Case analysis tactics *)
let general_case_analysis_in_context with_evars clear_flag (c,lbindc) =
Proofview.Goal.enter beginfun gl -> let sigma = Proofview.Goal.sigma gl in let env = Proofview.Goal.env gl in let concl = Proofview.Goal.concl gl in let state = Proofview.Goal.state gl in let ct = Retyping.get_type_of env sigma c in let (mind, _), t = reduce_to_quantified_ind env sigma ct in let dep = if dependent sigma c concl thentrue else default_case_analysis_dependence env mind in let id = try Some (destVar sigma c) with DestKO -> None in let indclause = make_clenv_binding env sigma (c, t) lbindc in let indclause = Clenv.clenv_pose_dependent_evars ~with_evars:true indclause in let argtype = clenv_type indclause in(* Guaranteed to be meta-free *) let tac =
Proofview.tclEVARMAP >>= fun sigma -> let sigma = Evd.push_future_goals sigma in let (sigma, ev) = Evarutil.new_evar env sigma argtype in let _, sigma = Evd.pop_future_goals sigma in let evk, _ = destEvar sigma ev in let indclause = Clenv.update_clenv_evd indclause sigma (Clenv.clenv_meta_list indclause) in
Proofview.Unsafe.tclEVARS sigma <*>
Proofview.Unsafe.tclNEWGOALS ~before:true [Proofview.goal_with_state evk state] <*>
Proofview.tclDISPATCH [Clenv.res_pf ~with_evars:true indclause; tclIDTAC] <*>
Proofview.tclEXTEND [] tclIDTAC [Clenv.case_pf ~with_evars ~dep (ev, argtype)] in let sigma = clenv_evd indclause in
Tacticals.tclTHENLIST [
Tacticals.tclWITHHOLES with_evars tac sigma;
apply_clear_request clear_flag (use_clear_hyp_by_default ()) id;
] end
let general_case_analysis with_evars clear_flag (c,lbindc as cx) =
Proofview.tclEVARMAP >>= fun sigma -> match EConstr.kind sigma c with
| Var id when lbindc == NoBindings ->
Tacticals.tclTHEN (try_intros_until_id_check id)
(general_case_analysis_in_context with_evars clear_flag cx)
| _ ->
general_case_analysis_in_context with_evars clear_flag cx
let simplest_case c = general_case_analysis false None (c,NoBindings) let simplest_ecase c = general_case_analysis true None (c,NoBindings)
(* Elimination tactic with bindings but using the default elimination
* constant associated with the type. *)
exception IsNonrec
let is_nonrec env mind = (Environ.lookup_mind (fst mind) env).mind_finite == Declarations.BiFinite
let find_ind_eliminator env sigma ind s = let c = lookup_eliminator env ind s in let sigma, c = EConstr.fresh_global env sigma c in
sigma, destConst sigma c
let default_elim with_evars clear_flag (c,_ as cx) =
Proofview.tclORELSE
(Proofview.Goal.enter beginfun gl -> let env = Proofview.Goal.env gl in let sigma = Proofview.Goal.sigma gl in let concl = Proofview.Goal.concl gl in let sigma, t = Typing.type_of env sigma c in let (ind,u) = eval_to_quantified_ind env sigma t in if is_nonrec env ind thenraise IsNonrec; let sigma, elim = find_ind_eliminator env sigma ind
(Retyping.get_sort_quality_of env sigma concl) in
Proofview.tclTHEN (Proofview.Unsafe.tclEVARS sigma)
(general_elim with_evars clear_flag cx (ElimConstant elim)) end) begin function (e, info) -> match e with
| IsNonrec -> (* For records, induction principles aren't there by default
anymore. Instead, we do a case analysis. *)
general_case_analysis with_evars clear_flag cx
| e -> Proofview.tclZERO ~info e end
let elim_in_context with_evars clear_flag c = function
| Some elim ->
general_elim with_evars clear_flag c (ElimClause elim)
| None -> default_elim with_evars clear_flag c
let elim with_evars clear_flag (c,lbindc as cx) elim =
Proofview.tclEVARMAP >>= fun sigma -> match EConstr.kind sigma c with
| Var id when lbindc == NoBindings ->
Tacticals.tclTHEN (try_intros_until_id_check id)
(elim_in_context with_evars clear_flag cx elim)
| _ ->
elim_in_context with_evars clear_flag cx elim
(* The simplest elimination tactic, with no substitutions at all. *)
let simplest_elim c = default_elim false None (c,NoBindings)
(* Elimination in hypothesis *) (* Typically, elimclause := (eq_ind ?x ?P ?H ?y ?Heq : ?P ?y) indclause : forall ..., hyps -> a=b (to take place of ?Heq) id : phi(a) (to take place of ?H) and the result is to overwrite id with the proof of phi(b)
but this generalizes to any elimination scheme with one constructor (e.g. it could replace id:A->B->C by id:C, knowing A/\B)
*)
(* Apply a tactic below the products of the conclusion of a lemma *)
type conjunction_status =
| DefinedRecord of Constant.t optionlist
| NotADefinedRecordUseScheme
let make_projection env sigma params cstr sign elim i n c (ind, u) = letopen Context.Rel.Declaration in let elim = match elim with
| NotADefinedRecordUseScheme -> (* bugs: goes from right to left when i increases! *) let cs_args = cstr.cs_args in let decl = List.nth cs_args i in let t = RelDecl.get_type decl in let b = match decl with LocalAssum _ -> mkRel (i+1) | LocalDef (_,b,_) -> b in if (* excludes dependent projection types *)
noccur_between sigma 1 (n-i-1) t (* to avoid surprising unifications, excludes flexible
projection types or lambda which will be instantiated by Meta/Evar *)
&& not (isEvar sigma (fst (whd_betaiota_stack env sigma t)))
&& (not (isRel sigma t)) then let (_, mip) as specif = Inductive.lookup_mind_specif env ind in let t = lift (i + 1 - n) t in let ksort = Retyping.get_sort_quality_of (push_rel_context sign env) sigma t in if UnivGen.QualityOrSet.eliminates_to
(UnivGen.QualityOrSet.of_quality @@ Inductiveops.elim_sort specif) ksort then let arity = List.firstn mip.mind_nrealdecls mip.mind_arity_ctxt in let mknas ctx = Array.of_list (List.rev_map get_annot ctx) in let ci = Inductiveops.make_case_info env ind RegularStyle in let br = [| mknas cs_args, b |] in let args = Context.Rel.instance mkRel 0 sign in let indr = ERelevance.make @@
Inductive.relevance_of_ind_body mip (EConstr.Unsafe.to_instance u) in let pnas = Array.append (mknas (EConstr.of_rel_context arity)) [|make_annot Anonymous indr|] in let p = (pnas, lift (Array.length pnas) t) in let c = mkCase (ci, u, Array.of_list params, (p, get_relevance decl), NoInvert, mkApp (c, args), br) in
Some (sigma, it_mkLambda_or_LetIn c sign, it_mkProd_or_LetIn t sign) else None else
None
| DefinedRecord l -> (* goes from left to right when i increases! *) matchList.nth l i with
| Some proj -> let args = Context.Rel.instance mkRel 0 sign in let sigma, proj = match Structures.PrimitiveProjections.find_opt_with_relevance (proj,u) with
| Some (proj,r) ->
sigma, mkProj (Projection.make proj false, r, mkApp (c, args))
| None -> let env = EConstr.push_rel_context sign env in let args = Array.append (Array.of_list params) [|mkApp (c, args)|] in
Typing.checked_appvect env sigma (mkConstU (proj, u)) args in letapp = it_mkLambda_or_LetIn proj sign in let t = Retyping.get_type_of env sigma appin
Some (sigma, app, t)
| None -> None in elim
let descend_in_conjunctions avoid tac (err, info) c =
Proofview.Goal.enter beginfun gl -> let env = Proofview.Goal.env gl in let sigma = Tacmach.project gl in try let t = Retyping.get_type_of env sigma c in let ((ind,u),t) = reduce_to_quantified_ind env sigma t in let sign,ccl = EConstr.decompose_prod_decls sigma t in match match_with_tuple env sigma ccl with
| Some (_,_,isrec) -> (* At this point, ind is known to be an index-free one-constructor
inductive type, potentially recursive. *) let n = (constructors_nrealargs env ind).(0) in let IndType (indf,_) = find_rectype env sigma ccl in let (_,inst), params = dest_ind_family indf in let cstr = (get_constructors env indf).(0) in let elim = try DefinedRecord (Structures.Structure.find_projections ind) with Not_found -> NotADefinedRecordUseScheme in let or_tac t1 t2 e = Proofview.tclORELSE (t1 e) t2 in List.fold_right or_tac
(List.init n (fun i (err, info) ->
Proofview.Goal.enter beginfun gl -> let env = Proofview.Goal.env gl in let sigma = Tacmach.project gl in match make_projection env sigma params cstr sign elim i n c (ind, u) with
| None ->
Proofview.tclZERO ~info err
| Some (sigma, p, pt) ->
Proofview.Unsafe.tclEVARS sigma <*>
Tacticals.tclTHENS
(Proofview.tclORELSE
(assert_before_gen false (NamingAvoid avoid) pt)
(fun _ -> Proofview.tclZERO ~info err))
[Proofview.tclORELSE
(Refine.refine ~typecheck:false (fun h -> (h, p)))
(fun _ -> Proofview.tclZERO ~info err); (* Might be ill-typed due to forbidden elimination. *)
Tacticals.onLastHypId (tac (err, info) (not isrec))] end))
(fun (err, info) -> Proofview.tclZERO ~info err)
(err, info)
| None -> Proofview.tclZERO ~info err with RefinerError _|UserError _ -> Proofview.tclZERO ~info err end
let general_apply ?(with_classes=true) ?(respect_opaque=false) with_delta with_destruct with_evars
clear_flag {CAst.loc;v=(c,lbind : EConstr.constr with_bindings)} =
Proofview.Goal.enter beginfun gl -> let concl = Proofview.Goal.concl gl in let sigma = Tacmach.project gl in let id = try Some (destVar sigma c) with DestKO -> None in (* The actual type of the theorem. It will be matched against the goal. If this fails, then the head constant will be unfolded step by
step. *) let concl_nprod = nb_prod_modulo_zeta sigma concl in let rec try_main_apply with_destruct c =
Proofview.Goal.enter beginfun gl -> let env = Proofview.Goal.env gl in let sigma = Tacmach.project gl in let ts = if respect_opaque then Conv_oracle.get_transp_state (oracle env) else TransparentState.full in let flags = if with_delta then default_unify_flags () else default_no_delta_unify_flags ts in let thm_ty = nf_betaiota env sigma (Retyping.get_type_of env sigma c) in let sigma, thm_ty = Evarsolve.refresh_universes ~onlyalg:true None env sigma thm_ty in let try_apply thm_ty nprod = try let n = nb_prod_modulo_zeta sigma thm_ty - nprod in if n<0 then error NotEnoughPremises; let clause = make_clenv_binding_apply env sigma (Some n) (c,thm_ty) lbind in
Clenv.res_pf clause ~with_classes ~with_evars ~flags with exn when noncritical exn -> let exn, info = Exninfo.capture exn in
Proofview.tclZERO ~info exn in let rec try_red_apply thm_ty (exn0, info) = match red_product env sigma thm_ty with
| Some red_thm -> (* Try to head-reduce the conclusion of the theorem *)
Proofview.tclORELSE
(try_apply red_thm concl_nprod)
(fun _ -> try_red_apply red_thm (exn0, info))
| None -> (* Last chance: if the head is a variable, apply may try
second order unification *) let info = Option.cata (fun loc -> Loc.add_loc info loc) info loc in let tac = if with_destruct then
Proofview.tclORELSE
(descend_in_conjunctions Id.Set.empty
(fun _ b id ->
Tacticals.tclTHEN
(try_main_apply b (mkVar id))
(clear [id]))
(exn0, info) c)
(fun _ -> Proofview.tclZERO ~info exn0) else
Proofview.tclZERO ~info exn0 in ifnot (Int.equal concl_nprod 0) then
Tacticals.tclORELSE0 (try_apply thm_ty 0) tac else
tac in
Proofview.tclORELSE
(try_apply thm_ty concl_nprod)
(try_red_apply thm_ty) end in
Tacticals.tclTHEN
(try_main_apply with_destruct c)
(apply_clear_request clear_flag (use_clear_hyp_by_default ()) id) end
let rec apply_with_bindings_gen ?with_classes b e = function
| [] -> Proofview.tclUNIT ()
| [k,cb] -> general_apply ?with_classes b b e k cb
| (k,cb)::cbl ->
Tacticals.tclTHENLAST
(general_apply ?with_classes b b e k cb)
(apply_with_bindings_gen ?with_classes b e cbl)
let apply_with_delayed_bindings_gen b e l = let one k {CAst.loc;v=cb} =
Proofview.Goal.enter beginfun _ ->
Tacticals.tclRUNWITHHOLES e cb
(fun cb -> general_apply ~respect_opaque:(not b) b b e k CAst.(make ?loc cb)) end in let rec aux = function
| [] -> Proofview.tclUNIT ()
| [k,f] -> one k f
| (k,f)::cbl ->
Tacticals.tclTHENLAST
(one k f) (aux cbl) in aux l
let apply_with_bindings cb = apply_with_bindings_gen falsefalse [None,(CAst.make cb)]
let eapply_with_bindings ?with_classes cb = apply_with_bindings_gen ?with_classes falsetrue [None,(CAst.make cb)]
let apply c = apply_with_bindings_gen falsefalse [None,(CAst.make (c,NoBindings))]
let eapply ?with_classes c =
apply_with_bindings_gen ?with_classes falsetrue [None,(CAst.make (c,NoBindings))]
let apply_list = function
| c::l -> apply_with_bindings (c,ImplicitBindings l)
| _ -> assert false
(* [apply_in hyp c] replaces
hyp : forall y1, ti -> t hyp : rho(u) ======================== with ============ and the ======= goal goal rho(ti)
assuming that [c] has type [forall x1..xn -> t' -> u] for some [t] unifiable with [t'] with unifier [rho]
*)
exception UnableToApply
let progress_with_clause env flags (id, t) clause mvs = let innerclause = mk_clenv_from_n env (clenv_evd clause) 0 (mkVar id, t) in ifList.is_empty mvs thenraise UnableToApply; let f mv = let rec find innerclause = let metas = clenv_meta_list innerclause in let submetas = (clenv_arguments innerclause, metas) in try
Some (clenv_instantiate mv ~flags ~submetas clause (mkVar id, clenv_type innerclause)) with e when noncritical e -> match clenv_push_prod innerclause with
| Some (_, _, innerclause) -> find innerclause
| None -> None in find innerclause in matchList.find_map f mvs with
| Some v -> v
| None -> raise UnableToApply
let apply_in_once_main flags (id, t) env sigma (loc,d,lbind) = let thm = nf_betaiota env sigma (Retyping.get_type_of env sigma d) in let rec aux clause mvs = try progress_with_clause env flags (id, t) clause mvs with e when CErrors.noncritical e -> let e' = Exninfo.capture e in match clenv_push_prod clause with
| Some (mv, dep, clause) -> aux clause (if dep then [] else [mv])
| None -> match e with
| UnableToApply -> error ?loc (UnableToApplyLemma (env,sigma,thm,t))
| _ -> Exninfo.iraise e' in let clenv = make_clenv_binding env sigma (d,thm) lbind in let mvs = List.rev (clenv_independent clenv) in
aux clenv mvs
let apply_in_once ?(respect_opaque = false) with_delta
with_destruct with_evars naming id (clear_flag,{ CAst.loc; v= d,lbind}) tac = letopen Context.Rel.Declaration in
Proofview.Goal.enter beginfun gl -> let t' = Tacmach.pf_get_hyp_typ id gl in let targetid = find_name true (LocalAssum (make_annot Anonymous Sorts.Relevant,t')) naming gl in let replace = Id.equal id targetid in let rec aux ?err idstoclear with_destruct c =
Proofview.Goal.enter beginfun gl -> let env = Proofview.Goal.env gl in let sigma = Tacmach.project gl in let idc = try Some (destVar (Tacmach.project gl) c) with DestKO -> None in let ts = if respect_opaque then Conv_oracle.get_transp_state (oracle env) else TransparentState.full in let flags = if with_delta then default_unify_flags () else default_no_delta_unify_flags ts in try let clause = apply_in_once_main flags (id, t') env sigma (loc,c,lbind) in let cleartac = apply_clear_request clear_flag false idc <*> clear idstoclear in let refine = Tacticals.tclTHENFIRST (clenv_refine_in with_evars targetid replace env sigma clause) cleartac in
Tacticals.tclTHENFIRST (replace_error_option err refine) (tac targetid) with e when with_destruct && CErrors.noncritical e -> let err = Option.default (Exninfo.capture e) err in
(descend_in_conjunctions (Id.Set.singleton targetid)
(fun err b id -> aux ~err (id::idstoclear) b (mkVar id))
err c) end in
aux [] with_destruct d end
let apply_in_delayed_once ?(respect_opaque = false) with_delta
with_destruct with_evars naming id (clear_flag,{CAst.loc;v=f}) tac =
Proofview.Goal.enter beginfun _ ->
Tacticals.tclRUNWITHHOLES with_evars f
(fun c -> apply_in_once ~respect_opaque with_delta with_destruct with_evars
naming id (clear_flag,CAst.(make ?loc c)) tac) end
(* A useful resolution tactic which, if c:A->B, transforms |- C into |- B -> C and |- A
------------------- Gamma |- c : A -> B Gamma |- ?2 : A ---------------------------------------- Gamma |- B Gamma |- ?1 : B -> C ----------------------------------------------------- Gamma |- ? : C
Ltac lapply c := let ty := check c in match eval hnf in ty with ?A -> ?B => cut B; [ idtac | apply c ] end.
*)
let cut_and_apply c =
Proofview.Goal.enter beginfun gl -> let env = Proofview.Goal.env gl in let sigma = Proofview.Goal.sigma gl in let concl = Proofview.Goal.concl gl in let sigma, t = Typing.type_of env sigma c in match EConstr.kind sigma (hnf_constr env sigma t) with
| Prod (_,c1,c2) when Vars.noccurn sigma 1 c2 ->
Proofview.tclTHEN (Proofview.Unsafe.tclEVARS sigma)
(Refine.refine ~typecheck:falsebeginfun sigma -> let typ = mkProd (make_annot Anonymous ERelevance.relevant, c2, concl) in let (sigma, f) = Evarutil.new_evar env sigma typ in let (sigma, x) = Evarutil.new_evar env sigma c1 in
(sigma, mkApp (f, [|mkApp (c, [|x|])|])) end)
| _ -> error NeedDependentProduct end
let exact_no_check c =
Refine.refine ~typecheck:false (fun h -> (h,c))
let exact_check c =
Proofview.Goal.enter beginfun gl -> let sigma = Proofview.Goal.sigma gl in (* We do not need to normalize the goal because we just check convertibility *) let concl = Proofview.Goal.concl gl in let env = Proofview.Goal.env gl in let sigma, ct = Typing.type_of env sigma c in
Tacticals.tclTHEN (Proofview.Unsafe.tclEVARS sigma)
(Tacticals.tclTHEN (convert_leq ct concl) (exact_no_check c)) end
let cast_no_check cast c =
Proofview.Goal.enter beginfun gl -> let concl = Proofview.Goal.concl gl in
exact_no_check (mkCast (c, cast, concl)) end
let vm_cast_no_check c = cast_no_check VMcast c let native_cast_no_check c = cast_no_check NATIVEcast c
let exact_proof c = letopen Tacmach in
Proofview.Goal.enter beginfun gl ->
Refine.refine ~typecheck:falsebeginfun sigma -> let (c, ctx) = Constrintern.interp_casted_constr (pf_env gl) sigma c (pf_concl gl) in let sigma = Evd.set_universe_context sigma ctx in
(sigma, c) end end
let assumption = let rec arec gl only_eq = function
| [] -> if only_eq then let hyps = Proofview.Goal.hyps gl in
arec gl false hyps else let info = Exninfo.reify () in
Tacticals.tclZEROMSG ~info (str "No such assumption.")
| decl::rest -> let t = NamedDecl.get_type decl in let concl = Proofview.Goal.concl gl in let sigma = Tacmach.project gl in let ans = if only_eq then if EConstr.eq_constr sigma t concl then Some sigma else None else let env = Proofview.Goal.env gl in
infer_conv env sigma t concl in match ans with
| Some sigma ->
(Proofview.Unsafe.tclEVARS sigma) <*>
exact_no_check (mkVar (NamedDecl.get_id decl))
| None -> arec gl only_eq rest in let assumption_tac gl = let hyps = Proofview.Goal.hyps gl in
arec gl true hyps in
Proofview.Goal.enter assumption_tac
(*****************************************************************) (* Modification of a local context *) (*****************************************************************)
let check_is_type env sigma idl ids ty = try let sigma, _ = Typing.sort_of env sigma ty in
sigma with e when CErrors.noncritical e -> raise (DependsOnBody (idl, ids, None))
let check_decl env sigma idl ids decl = letopen Context.Named.Declaration in let ty = NamedDecl.get_type decl in try let sigma, _ = Typing.sort_of env sigma ty in let sigma = match decl with
| LocalAssum _ -> sigma
| LocalDef (_,c,_) -> Typing.check env sigma c ty in
sigma with e when CErrors.noncritical e -> let id = NamedDecl.get_id decl in raise (DependsOnBody (idl, ids, Some id))
let clear_body idl = letopen Context.Named.Declaration in
Proofview.Goal.enter beginfun gl -> let env = Proofview.Goal.env gl in let concl = Proofview.Goal.concl gl in let sigma = Tacmach.project gl in let ctx = named_context env in let ids = Id.Set.of_list idl in (* We assume the context to respect dependencies *) let rec fold ids ctx = if Id.Set.is_empty ids then let base_env = reset_context env in let env = push_named_context ctx base_env in
env, sigma, Id.Set.empty else match ctx with
| [] -> assert false
| decl :: ctx -> let decl, ids, found = match decl with
| LocalAssum (id,t) -> let () = if Id.Set.mem id.binder_name ids then
error (VariableHasNoValue id.binder_name) in
decl, ids, false
| LocalDef (id,_,t) as decl -> if Id.Set.mem id.binder_name ids then LocalAssum (id, t), Id.Set.remove id.binder_name ids, true else decl, ids, false in let env, sigma, ids = fold ids ctx in if Id.Set.exists (fun id -> occur_var_in_decl env sigma id decl) ids then let sigma = check_decl env sigma idl ids decl in(* can sigma really change? *) let ids = Id.Set.add (get_id decl) ids in
push_named decl env, sigma, Id.Set.add (get_id decl) ids else
push_named decl env, sigma, if found then Id.Set.add (get_id decl) ids else ids in try let env, sigma, ids = fold ids ctx in let sigma = if Id.Set.exists (fun id -> occur_var env sigma id concl) ids then
check_is_type env sigma idl ids concl else sigma in
Proofview.Unsafe.tclEVARS sigma <*>
Refine.refine_with_principal ~typecheck:falsebeginfun sigma -> let sigma, ev = Evarutil.new_evar env sigma concl in
sigma, ev, Some (fst @@ destEvar sigma ev) end with DependsOnBody _ as exn -> let _, info = Exninfo.capture exn in
Proofview.tclZERO ~info exn end
(* Takes a list of booleans, and introduces all the variables * quantified in the goal which are associated with a value
* true in the boolean list. *)
let keep hyps =
Proofview.Goal.enter beginfun gl ->
Proofview.tclENV >>= fun env -> let ccl = Proofview.Goal.concl gl in let sigma = Tacmach.project gl in let cl,_ =
fold_named_context_reverse (fun (clear,keep) decl -> let decl = EConstr.of_named_decl decl in let hyp = NamedDecl.get_id decl in if Id.List.mem hyp hyps
|| List.exists (occur_var_in_decl env sigma hyp) keep
|| occur_var env sigma hyp ccl then (clear,decl::keep) else (hyp::clear,keep))
~init:([],[]) (Proofview.Goal.env gl) in
clear cl end
(* Given a type [T] convertible to [forall x1..xn:A1..An(x1..xn-1), G(x1..xn)] and [a1..an:A1..An(a1..an-1)] such that the goal is [G(a1..an)],
this generalizes [hyps |- goal] into [hyps |- T] *)
let apply_type ~typecheck newcl args =
Proofview.Goal.enter beginfun gl -> let env = Proofview.Goal.env gl in
Refine.refine_with_principal ~typecheck beginfun sigma -> let newcl = nf_betaiota env sigma newcl (* As in former Logic.refine *) in let (sigma, ev) = Evarutil.new_evar env sigma newcl in
(sigma, applist (ev, args), Some (fst @@ destEvar sigma ev)) end end
let check_number_of_constructors expctdnumopt i nconstr = if Int.equal i 0 then error ConstructorNumberedFromOne; beginmatch expctdnumopt with
| Some n when not (Int.equal n nconstr) ->
error (NotRightNumberConstructors n)
| _ -> () end; if i > nconstr then error NotEnoughConstructors
let constructor_core with_evars cstr lbind =
Proofview.Goal.enter beginfun gl -> let sigma = Proofview.Goal.sigma gl in let env = Proofview.Goal.env gl in let (sigma, (cons, u)) = Evd.fresh_constructor_instance env sigma cstr in let cons = mkConstructU (cons, EInstance.make u) in let apply_tac = general_apply truefalse with_evars None (CAst.make (cons,lbind)) in
Tacticals.tclTHEN (Proofview.Unsafe.tclEVARS sigma) apply_tac end
let constructor_tac with_evars expctdnumopt i lbind =
Proofview.Goal.enter beginfun gl -> let cl = Tacmach.pf_concl gl in let env = Proofview.Goal.env gl in let ((ind,_),redcl) = Tacmach.pf_apply Tacred.reduce_to_quantified_ind gl cl in let nconstr = Array.length (snd (Inductive.lookup_mind_specif env ind)).mind_consnames in
check_number_of_constructors expctdnumopt i nconstr;
Tacticals.tclTHENLIST [
convert_concl ~cast:false ~check:false redcl DEFAULTcast;
intros;
constructor_core with_evars (ind, i) lbind
] end
let one_constructor i lbind = constructor_tac false None i lbind
(* Try to apply the constructor of the inductive definition followed by a tactic t given as an argument. Should be generalize in Constructor (Fun c : I -> tactic)
*)
let any_constructor with_evars tacopt = let one_constr = let tac cstr = constructor_core with_evars cstr NoBindings in match tacopt with
| None -> tac
| Some t -> fun cstr -> Tacticals.tclTHEN (tac cstr) t in let rec any_constr ind n i () = if Int.equal i n then one_constr (ind,i) else Tacticals.tclORD (one_constr (ind,i)) (any_constr ind n (i + 1)) in
Proofview.Goal.enter beginfun gl -> let cl = Tacmach.pf_concl gl in let env = Proofview.Goal.env gl in let (ind,_),redcl = Tacmach.pf_apply Tacred.reduce_to_quantified_ind gl cl in let nconstr =
Array.length (snd (Inductive.lookup_mind_specif env ind)).mind_consnames in if Int.equal nconstr 0 then error NoConstructors;
Tacticals.tclTHENLIST [
convert_concl ~cast:false ~check:false redcl DEFAULTcast;
intros;
any_constr ind nconstr 1 ()
] end
let left_with_bindings with_evars = constructor_tac with_evars (Some 2) 1 let right_with_bindings with_evars = constructor_tac with_evars (Some 2) 2 let split_with_bindings with_evars l =
Tacticals.tclMAP (constructor_tac with_evars (Some 1) 1) l let split_with_delayed_bindings with_evars bl =
Tacticals.tclMAPDELAYEDWITHHOLES with_evars bl
(constructor_tac with_evars (Some 1) 1)
let left = left_with_bindings false let simplest_left = left NoBindings
let right = right_with_bindings false let simplest_right = right NoBindings
let split = constructor_tac false (Some 1) 1 let simplest_split = split NoBindings
(* Rewriting function for rewriting one hypothesis at the time *) let (forward_general_rewrite_clause, general_rewrite_clause) = Hook.make ()
(* Rewriting function for substitution (x=t) everywhere at the same time *) let (forward_subst_one, subst_one) = Hook.make ()
let intro_decomp_eq_function = ref (fun _ -> failwith "Not implemented")
let declare_intro_decomp_eq f = intro_decomp_eq_function := f
let my_find_eq_data_decompose env sigma t = try Some (find_eq_data_decompose env sigma t) with e when is_anomaly e (* Hack in case equality is not yet defined... one day, maybe,
known equalities will be dynamically registered *)
-> None
| Constr_matching.PatternMatchingFailure -> None
let intro_decomp_eq ?loc l thin tac id =
Proofview.Goal.enter beginfun gl -> let c = mkVar id in let env = Proofview.Goal.env gl in let sigma = Proofview.Goal.sigma gl in let {uj_type=t} = Typing.judge_of_variable env id in let _,t = reduce_to_atomic_ind env sigma t in match my_find_eq_data_decompose env sigma t with
| Some (eq,u,eq_args) ->
!intro_decomp_eq_function
(fun n -> tac ((CAst.make id)::thin) (Some n) l)
(eq,t,eq_args) (c, t)
| None -> let info = Exninfo.reify () in
Tacticals.tclZEROMSG ~info (str "Not a primitive equality here.") end
let intro_or_and_pattern ?loc with_evars ll thin tac id =
Proofview.Goal.enter beginfun gl -> let c = mkVar id in let env = Proofview.Goal.env gl in let sigma = Proofview.Goal.sigma gl in let {uj_type=t} = Typing.judge_of_variable env id in let ind = eval_to_quantified_ind env sigma t in let branchsigns = compute_constructor_signatures env ~rec_flag:false ind in let nv_with_let = Array.mapList.length branchsigns in let ll = fix_empty_or_and_pattern (Array.length branchsigns) ll in let ll = get_and_check_or_and_pattern ?loc ll branchsigns in letcase = if with_evars then simplest_ecase else simplest_case in
Tacticals.tclTHENLASTn
(Tacticals.tclTHEN (case c) (clear [id]))
(Array.map2 (fun n l -> tac thin (Some n) l)
nv_with_let ll) end
let rewrite_hyp_then with_evars thin l2r id tac = let rew_on l2r =
Hook.get forward_general_rewrite_clause l2r with_evars (mkVar id,NoBindings) in let subst_on l2r x rhs =
Hook.get forward_subst_one true x (id,rhs,l2r) in let clear_var_and_eq id' = clear [id';id] in let early_clear id' thin = List.filter (fun {CAst.v=id} -> not (Id.equal id id')) thin in
Proofview.Goal.enter beginfun gl -> let env = Proofview.Goal.env gl in let sigma = Tacmach.project gl in let {uj_type=t} = Typing.judge_of_variable env id in let t = whd_all env sigma t in let eqtac, thin = match match_with_equality_type env sigma t with
| Some (hdcncl,[_;lhs;rhs]) -> if l2r && isVar sigma lhs && not (occur_var env sigma (destVar sigma lhs) rhs) then let id' = destVar sigma lhs in
subst_on l2r id' rhs, early_clear id' thin elseifnot l2r && isVar sigma rhs && not (occur_var env sigma (destVar sigma rhs) lhs) then let id' = destVar sigma rhs in
subst_on l2r id' lhs, early_clear id' thin else
Tacticals.tclTHEN (rew_on l2r onConcl) (clear [id]),
thin
| Some (hdcncl,[c]) -> let l2r = not l2r in(* equality of the form eq_true *) if isVar sigma c then let id' = destVar sigma c in
Tacticals.tclTHEN (rew_on l2r allHypsAndConcl)
(clear_var_and_eq id'),
early_clear id' thin else
Tacticals.tclTHEN (rew_on l2r onConcl) (clear [id]),
thin
| _ ->
Tacticals.tclTHEN (rew_on l2r onConcl) (clear [id]),
thin in (* Skip the side conditions of the rewriting step *)
Tacticals.tclTHENFIRST eqtac (tac thin) end
let rec collect_intro_names = letopen CAst in function
| {v=IntroForthcoming _} :: l -> collect_intro_names l
| {v=IntroNaming (IntroIdentifier id)} :: l -> let ids1, ids2 = collect_intro_names l in Id.Set.add id ids1, ids2
| {v=IntroAction (IntroOrAndPattern l)} :: l' -> let ll = match l with IntroAndPattern l -> [l] | IntroOrPattern ll -> ll in let fold (ids1',ids2') l = let ids1, ids2 = collect_intro_names (l@l') in
Id.Set.union ids1 ids1', Id.Set.union ids2 ids2'in List.fold_left fold (Id.Set.empty,Id.Set.empty) ll
| {v=IntroAction (IntroInjection l)} :: l' ->
collect_intro_names (l@l')
| {v=IntroAction (IntroApplyOn (c,pat))} :: l' ->
collect_intro_names (pat::l')
| {v=IntroNaming (IntroFresh id)} :: l -> let ids1, ids2 = collect_intro_names l in ids1, Id.Set.add id ids2
| {v=(IntroNaming IntroAnonymous
| IntroAction (IntroWildcard | IntroRewrite _))} :: l ->
collect_intro_names l
| [] -> Id.Set.empty, Id.Set.empty
let explicit_intro_names l = fst (collect_intro_names l)
let explicit_all_intro_names l = let ids1,ids2 = collect_intro_names l in Id.Set.union ids1 ids2
let rec check_name_unicity env ok seen = letopen CAst in function
| {v=IntroForthcoming _} :: l -> check_name_unicity env ok seen l
| {loc;v=IntroNaming (IntroIdentifier id)} :: l ->
(try
ignore (ifList.mem_f Id.equal id ok thenraise Not_found else lookup_named id env);
error ?loc (AlreadyUsed id) with Not_found -> ifList.mem_f Id.equal id seen then
error ?loc (UsedTwice id) else
check_name_unicity env ok (id::seen) l)
| {v=IntroAction (IntroOrAndPattern l)} :: l' -> let ll = match l with IntroAndPattern l -> [l] | IntroOrPattern ll -> ll in List.iter (fun l -> check_name_unicity env ok seen (l@l')) ll
| {v=IntroAction (IntroInjection l)} :: l' ->
check_name_unicity env ok seen (l@l')
| {v=IntroAction (IntroApplyOn (c,pat))} :: l' ->
check_name_unicity env ok seen (pat::l')
| {v=(IntroNaming (IntroAnonymous | IntroFresh _)
| IntroAction (IntroWildcard | IntroRewrite _))} :: l ->
check_name_unicity env ok seen l
| [] -> ()
let make_naming ?loc avoid l = function
| IntroIdentifier id -> NamingMustBe (CAst.make ?loc id)
| IntroAnonymous -> NamingAvoid (Id.Set.union avoid (explicit_intro_names l))
| IntroFresh id -> NamingBasedOn (id, Id.Set.union avoid (explicit_intro_names l))
let rec make_naming_action avoid l = function (* In theory, we could use a tmp id like "wild_id" for all actions
but we prefer to avoid it to avoid this kind of "ugly" names *)
| IntroWildcard ->
NamingBasedOn (Id.of_string "_H", Id.Set.union avoid (explicit_all_intro_names l))
| IntroApplyOn (_,{CAst.v=pat;loc}) -> make_naming_pattern avoid ?loc l pat
| (IntroOrAndPattern _ | IntroInjection _ | IntroRewrite _) as pat ->
NamingAvoid(Id.Set.union avoid (explicit_intro_names ((CAst.make @@ IntroAction pat)::l)))
and make_naming_pattern ?loc avoid l = function
| IntroNaming pat -> make_naming ?loc avoid l pat
| IntroAction pat -> make_naming_action avoid l pat
| IntroForthcoming _ -> NamingAvoid (Id.Set.union avoid (explicit_intro_names l))
let prepare_naming ?loc pat = make_naming ?loc Id.Set.empty [] pat
let fit_bound n = function
| None -> true
| Some n' -> n = n'
let exceed_bound n = function
| None -> false
| Some n' -> n >= n'
(* We delay thinning until the completion of the whole intros tactic to ensure that dependent hypotheses are cleared in the right dependency order (see BZ#1000); we use fresh names, not used in
the tactic, for the hyps to clear *) (* In [intro_patterns_core b avoid ids thin destopt bound n tac patl]: [b]: compatibility flag, if false at toplevel, do not complete incomplete trailing toplevel or_and patterns (as in "intros []", see [bracketing_last_or_and_intro_pattern]) [avoid]: names to avoid when creating an internal name [ids]: collect introduced names for possible use by the [tac] continuation [thin]: collect names to erase at the end [destopt]: position in the context where to introduce the hypotheses [bound]: number of pending intros to do in the current or-and pattern, with remembering of [b] flag if at toplevel [n]: number of introduction done in the current or-and pattern [tac]: continuation tactic [patl]: introduction patterns to interpret
*)
let rec intro_patterns_core with_evars avoid ids thin destopt bound n tac =
function
| [] when fit_bound n bound ->
tac ids thin
| [] -> (* Behave as IntroAnonymous *)
intro_patterns_core with_evars avoid ids thin destopt bound n tac
[CAst.make @@ IntroNaming IntroAnonymous]
| {CAst.loc;v=pat} :: l -> if exceed_bound n bound then error ?loc (UnexpectedExtraPattern(bound,pat)) else match pat with
| IntroForthcoming onlydeps -> let naming = Id.Set.union avoid (explicit_intro_names l) in
intro_forthcoming_then_gen naming destopt ~dep:onlydeps bound n
(fun ids -> intro_patterns_core with_evars avoid ids thin destopt bound
(n+List.length ids) tac l)
| IntroAction pat -> let naming = make_naming_action avoid l pat in
intro_then_gen naming destopt ~force:true ~dep:false
(intro_pattern_action ?loc with_evars pat thin destopt
(fun thin bound' -> intro_patterns_core with_evars avoid ids thin destopt bound' 0
(fun ids thin ->
intro_patterns_core with_evars avoid ids thin destopt bound (n+1) tac l)))
| IntroNaming pat -> let naming = make_naming avoid l pat in
intro_then_gen naming destopt ~force:true ~dep:false
(fun id -> intro_patterns_core with_evars avoid (id::ids) thin destopt bound (n+1) tac l)
and intro_pattern_action ?loc with_evars pat thin destopt tac id = match pat with
| IntroWildcard ->
tac (CAst.(make ?loc id)::thin) None []
| IntroOrAndPattern ll ->
intro_or_and_pattern ?loc with_evars ll thin tac id
| IntroInjection l' ->
intro_decomp_eq ?loc l' thin tac id
| IntroRewrite l2r ->
rewrite_hyp_then with_evars thin l2r id (fun thin -> tac thin None [])
| IntroApplyOn ({CAst.loc=loc';v=f},{CAst.loc;v=pat}) -> let naming = NamingMustBe (CAst.make ?loc id) in let tac_ipat = prepare_action ?loc with_evars destopt pat in let f =
tactic_of_delayed f >>= fun c ->
Proofview.tclUNIT (c, NoBindings) in
apply_in_delayed_once truetrue with_evars naming id (None,CAst.make ?loc:loc' f)
(fun id -> Tacticals.tclTHENLIST [tac_ipat id; tac thin None []])
and prepare_action ?loc with_evars destopt = function
| IntroNaming ipat ->
(fun _ -> Proofview.tclUNIT ())
| IntroAction ipat ->
(let tac thin bound =
intro_patterns_core with_evars Id.Set.empty [] thin destopt bound 0
(fun _ l -> clear_wildcards l) in fun id ->
intro_pattern_action ?loc with_evars ipat [] destopt tac id)
| IntroForthcoming _ -> error ?loc OneIntroPatternExpected
let intro_patterns_head_core with_evars destopt bound pat =
Proofview.Goal.enter beginfun gl -> let env = Proofview.Goal.env gl in
check_name_unicity env [] [] pat;
intro_patterns_core with_evars Id.Set.empty [] [] destopt
bound 0 (fun _ l -> clear_wildcards l) pat end
let intro_patterns_bound_to with_evars n destopt =
intro_patterns_head_core with_evars destopt (Some n)
let intro_patterns_to with_evars destopt =
intro_patterns_head_core with_evars destopt None
let intro_pattern_to with_evars destopt pat =
intro_patterns_to with_evars destopt [CAst.make pat]
let intro_patterns with_evars = intro_patterns_to with_evars MoveLast
(* Implements "intros" *) let intros_patterns with_evars = function
| [] -> intros
| l -> intro_patterns_to with_evars MoveLast l
let prepare_intros_opt with_evars dft destopt ipat = let naming, loc, ipat = match ipat with
| None -> let pat = IntroNaming dft in make_naming_pattern Id.Set.empty [] pat, None, pat
| Some {CAst.loc;v=(IntroNaming pat as ipat)} -> (* "apply ... in H as id" needs to use id and H is kept iff id<>H *)
prepare_naming ?loc pat, loc, ipat
| Some {CAst.loc;v=(IntroAction pat as ipat)} -> (* "apply ... in H as pat" reuses H so that old H is always cleared *)
(match dft with IntroIdentifier _ -> prepare_naming ?loc dft | _ -> make_naming_action Id.Set.empty [] pat),
loc, ipat
| Some {CAst.loc;v=(IntroForthcoming _)} -> assert falsein
naming, prepare_action ?loc with_evars destopt ipat
let ipat_of_name = function
| Anonymous -> None
| Name id -> Some (CAst.make @@ IntroNaming (IntroIdentifier id))
let head_ident sigma c = let c = fst (decompose_app sigma (snd (decompose_lambda_decls sigma c))) in if isVar sigma c then Some (destVar sigma c) else None
(* apply in as *)
let general_apply_in ?(respect_opaque=false) with_delta
with_destruct with_evars id lemmas ipat then_tac = let tac (naming,lemma) tac id =
apply_in_delayed_once ~respect_opaque with_delta
with_destruct with_evars naming id lemma tac in
Proofview.Goal.enter beginfun gl -> let destopt = if with_evars then MoveLast (* evars would depend on the whole context *) else ( let env, sigma = Proofview.Goal.(env gl, sigma gl) in
get_previous_hyp_position env sigma id (Proofview.Goal.hyps gl)
) in let naming,ipat_tac =
prepare_intros_opt with_evars (IntroIdentifier id) destopt ipat in let lemmas_target, last_lemma_target = let last,first = List.sep_last lemmas in List.map (fun lem -> (NamingMustBe (CAst.make id),lem)) first, (naming,last) in (* We chain apply_in_once, ending with an intro pattern *) List.fold_right tac lemmas_target
(tac last_lemma_target (fun id -> Tacticals.tclTHEN (ipat_tac id) then_tac)) id end
(* if sidecond_first then
(* Skip the side conditions of the applied lemma *)
Tacticals.tclTHENLAST (tclMAPLAST tac lemmas_target) (ipat_tac id) else
Tacticals.tclTHENFIRST (tclMAPFIRST tac lemmas_target) (ipat_tac id)
*)
let apply_in simple with_evars id lemmas ipat = let lemmas = List.map (fun (k,{CAst.loc;v=l}) -> k, CAst.make ?loc (Proofview.tclUNIT l)) lemmas in
general_apply_in simple simple with_evars id lemmas ipat Tacticals.tclIDTAC
let apply_delayed_in simple with_evars id lemmas ipat then_tac =
general_apply_in ~respect_opaque:true simple simple with_evars id lemmas ipat then_tac
(* Implementation without generalisation: abbrev will be lost in hyps in *) (* in the extracted proof *)
let decode_hyp = function
| None -> MoveLast
| Some id -> MoveAfter id
(* [letin_tac b (... abstract over c ...) gl] transforms [...x1:T1(c),...,x2:T2(c),... |- G(c)] into [...x:T;Heqx:(x=c);x1:T1(x),...,x2:T2(x),... |- G(x)] if [b] is false or [...x:=c:T;x1:T1(x),...,x2:T2(x),... |- G(x)] if [b] is true
*)
let letin_tac_gen with_eq (id,depdecls,lastlhyp,ccl,c) ty =
Proofview.Goal.enter beginfun gl -> let sigma = Proofview.Goal.sigma gl in let env = Proofview.Goal.env gl in let (sigma, t) = match ty with
| Some t -> (sigma, t)
| None -> let t = typ_of env sigma c in
Evarsolve.refresh_universes ~onlyalg:true (Some false) env sigma t in let rel = Retyping.relevance_of_term env sigma c in let (sigma, (newcl, eq_tac)) = match with_eq with
| Some (lr,{CAst.loc;v=ido}) -> let heq = match ido with
| IntroAnonymous -> new_fresh_id (Id.Set.singleton id) (add_prefix "Heq" id) gl
| IntroFresh heq_base -> new_fresh_id (Id.Set.singleton id) heq_base gl
| IntroIdentifier id -> id in let eqdata = build_rocq_eq_data () in let args = if lr then [mkVar id;c] else [c;mkVar id]in let (sigma, eq) = Evd.fresh_global env sigma eqdata.eq in let refl = mkRef (eqdata.refl, snd @@ destRef sigma eq) in let sigma, eq = Typing.checked_applist env sigma eq [t] in let eq = applist (eq, args) in let refl = applist (refl, [t; mkVar id]) in let r = Retyping.relevance_of_term env sigma refl in let term = mkNamedLetIn sigma (make_annot id rel) c t
(mkLetIn (make_annot (Name heq) r, refl, eq, ccl)) in let ans = term,
Tacticals.tclTHENLIST
[
intro_gen (NamingMustBe CAst.(make ?loc heq)) (decode_hyp lastlhyp) ~force:true ~dep:false;
clear_body [heq;id]] in
(sigma, ans)
| None ->
(sigma, (mkNamedLetIn sigma (make_annot id rel) c t ccl, Proofview.tclUNIT ())) in
Tacticals.tclTHENLIST
[ Proofview.Unsafe.tclEVARS sigma;
convert_concl ~cast:false ~check:false newcl DEFAULTcast;
intro_gen (NamingMustBe (CAst.make id)) (decode_hyp lastlhyp) ~force:true ~dep:false;
Tacticals.tclMAP (convert_hyp ~check:false ~reorder:false) depdecls;
eq_tac ] end
let pose_tac na c =
Proofview.Goal.enter beginfun gl -> let sigma = Proofview.Goal.sigma gl in let env = Proofview.Goal.env gl in let hyps = named_context_val env in let concl = Proofview.Goal.concl gl in let relevance = Proofview.Goal.relevance gl in let t = typ_of env sigma c in let rel = Retyping.relevance_of_term env sigma c in let (sigma, t) = Evarsolve.refresh_universes ~onlyalg:true (Some false) env sigma t in let id = match na with
| Name id -> let () = if mem_named_context_val id hyps then
error (IntroAlreadyDeclared id) in
id
| Anonymous -> let id = id_of_name_using_hdchar env sigma t Anonymous in
next_ident_away_in_goal (Global.env ()) id (ids_of_named_context_val hyps) in
Proofview.Unsafe.tclEVARS sigma <*>
Refine.refine ~typecheck:falsebeginfun sigma -> let id = make_annot id rel in let nhyps = EConstr.push_named_context_val (NamedDecl.LocalDef (id, c, t)) hyps in let (sigma, ev) = Evarutil.new_pure_evar nhyps sigma ~relevance concl in let inst = EConstr.identity_subst_val hyps in let body = mkEvar (ev, SList.cons (mkRel 1) inst) in
(sigma, mkLetIn (map_annot Name.mk_name id, c, t, body)) end end
let letin_tac with_eq id c ty occs =
Proofview.Goal.enter beginfun gl -> let sigma = Proofview.Goal.sigma gl in let env = Proofview.Goal.env gl in let ccl = Proofview.Goal.concl gl in let abs = AbstractExact (id,c,ty,occs,true) in let (id,_,depdecls,lastlhyp,ccl,res) = make_abstraction env sigma ccl abs in (* We keep the original term to match but record the potential side-effects
of unifying universes. *) let (sigma, c) = match res with
| None -> (sigma, c)
| Some (sigma, _) -> (sigma, c) in
Proofview.tclTHEN (Proofview.Unsafe.tclEVARS sigma)
(letin_tac_gen with_eq (id,depdecls,lastlhyp,ccl,c) ty) end
let letin_pat_tac with_evars with_eq id c occs =
Proofview.Goal.enter beginfun gl -> let sigma = Proofview.Goal.sigma gl in let env = Proofview.Goal.env gl in let ccl = Proofview.Goal.concl gl in let check t = truein let abs = AbstractPattern (false,check,id,c,occs) in let (id,_,depdecls,lastlhyp,ccl,res) = make_abstraction env sigma ccl abs in let (sigma, c) = match res with
| None -> finish_evar_resolution ~flags:(tactic_infer_flags with_evars) env sigma c
| Some res -> res in
Proofview.tclTHEN (Proofview.Unsafe.tclEVARS sigma)
(letin_tac_gen with_eq (id,depdecls,lastlhyp,ccl,c) None) end
(* Tactics "pose proof" (usetac=None) and "assert"/"enough" (otherwise) *) let forward b usetac ipat c = match usetac with
| None ->
Proofview.Goal.enter beginfun gl -> let t = Tacmach.pf_get_type_of gl c in let sigma = Tacmach.project gl in let hd = head_ident sigma c in let assert_as = let naming,tac = prepare_intros_opt false IntroAnonymous MoveLast ipat in let repl = do_replace hd naming in if repl then assert_before_gen true naming t else assert_before_then_gen false naming t tac in
Tacticals.tclTHENFIRST assert_as (exact_no_check c) end
| Some tac -> let tac = match tac with
| None -> Tacticals.tclIDTAC
| Some tac -> Tacticals.tclCOMPLETE tac in let naming, assert_tac = prepare_intros_opt false IntroAnonymous MoveLast ipat in if b then
Tacticals.tclTHENFIRST (assert_before_then_gen false naming c assert_tac) tac else
Tacticals.tclTHENS3PARTS
(assert_after_then_gen false naming c assert_tac) [||] tac [|Tacticals.tclIDTAC|]
let pose_proof na c = forward true None (ipat_of_name na) c let assert_by na t tac = forward true (Some (Some tac)) (ipat_of_name na) t let enough_by na t tac = forward false (Some (Some tac)) (ipat_of_name na) t
(* Instantiating some arguments (whatever their position) of an hypothesis or any term, leaving other arguments quantified. If operating on an hypothesis of the goal, the new hypothesis replaces it.
(c,lbind) are supposed to be of the form ((H t1 t2 ... tm) , someBindings) whete t1..tn are user given args, to which someBinding must be combined.
The goal is to pose a proof with body
(fun y1...yp => H t1 t2 ... tm u1 ... uq)
where yi are the remaining arguments of H that lbind could not solve, ui are a mix of inferred args and yi. The overall effect is to remove from H as much quantification as possible given
lbind. *)
module Specialize : sig val unify_bindings : evar_map -> (evar_map -> int -> 'a -> evar_map) ->
types -> 'a bindings -> evar_map (* Unfortunate small code duplication with EClause *) end = struct
let make_evar_clause sigma t = letopen EConstr in letopen Vars in let rec clrec holes n t = match EConstr.kind sigma t with
| Cast (t, _, _) -> clrec holes n t
| Prod (na, t1, t2) -> let dep = not (noccurn sigma 1 t2) in let hole = { hole_evar = n; hole_deps = dep; hole_name = na.binder_name; } in
clrec (hole :: holes) (n + 1) t2
| LetIn (na, b, _, t) -> clrec holes n (subst1 b t)
| _ -> holes in let holes = clrec [] 0 t in List.rev holes
let evar_with_name holes ({CAst.v=id} as lid) = letmap h = match h.hole_name with
| Anonymous -> None
| Name id' -> if Id.equal id id'then Some h else None in let hole = List.map_filter map holes in match hole with
| [] -> let fold h accu = match h.hole_name with
| Anonymous -> accu
| Name id -> id :: accu in let mvl = List.fold_right fold holes [] in
EClause.explain_no_such_bound_variable mvl lid
| h::_ -> h.hole_evar
let evar_of_binder holes = function
| NamedHyp s -> evar_with_name holes s
| AnonHyp n -> try let nondeps = List.filter (fun hole -> not hole.hole_deps) holes in let h = List.nth nondeps (pred n) in
h.hole_evar with e when CErrors.noncritical e ->
user_err Pp.(str "No such binder.")
let solve_evar_clause sigma unify holes = function
| NoBindings -> sigma
| ImplicitBindings largs -> letmap h = if h.hole_deps then Some h.hole_evar else None in let evs = List.map_filter map holes in let len = List.length evs in if Int.equal len (List.length largs) then let fold sigma ev arg = unify sigma ev arg in let sigma = List.fold_left2 fold sigma evs largs in
sigma else
EClause.error_not_right_number_missing_arguments len
| ExplicitBindings lbind -> let () = EClause.check_bindings lbind in let fold sigma {CAst.v=(binder, c)} = let ev = evar_of_binder holes binder in
unify sigma ev c in let sigma = List.fold_left fold sigma lbind in
sigma
let unify_bindings sigma unify ty = let holes = make_evar_clause sigma ty in
solve_evar_clause sigma unify holes
end
let specialize (c,lbind) ipat =
Proofview.Goal.enter beginfun gl -> let env = Proofview.Goal.env gl in let sigma = Proofview.Goal.sigma gl in let typ_of_c = Retyping.get_type_of env sigma c in let sigma, term, typ = match lbind with
| NoBindings ->
sigma, c, typ_of_c
| ExplicitBindings _ | ImplicitBindings _ -> let ctx, ty = decompose_prod_decls sigma typ_of_c in (* Create a new context where variables mentioned further in the telescope are turned into evars that live in the telescope context. This allows instantiating each evar with the original variable as a default value.
For instance, on Γ := [x : A, y : B{x}, z : C{x, y}] it produces evars [x : A ⊢ ?X : A] [x : A, y : B{?X{x}} ⊢ ?Y : B{?X{x}}] [x : A, y : B{?X{x}}, z : C{?X{x}, ?Y{x, y}} ⊢ ?Z : C{?X{x}, ?Y{x, y}}] and returns the context Δ := [x : A, y : B{?X{x}}, z : C{?X{x}, ?Y{x, y}}] together with a substitution [?X, ?Y, ?Z] : Γ ⊢ Δ.
*) letopen RelDecl in let rec instantiate sigma env subst accu = function
| [] -> sigma, subst, rel_context env, List.rev accu
| LocalAssum (na, t) :: decls -> let t = Vars.esubst Vars.lift_substituend subst t in let env = push_rel (LocalAssum (na, t)) env in let typeclass_candidate = Typeclasses.is_maybe_class_type sigma t in let sigma, ev = Evarutil.new_evar ~typeclass_candidate env sigma (lift 1 t) in let subst = Esubst.subs_cons (Vars.make_substituend ev) (Esubst.subs_shft (1, subst)) in
instantiate sigma env subst ((env, ev) :: accu) decls
| LocalDef (na, b, t) :: decls -> let b = Vars.esubst Vars.lift_substituend subst b in let t = Vars.esubst Vars.lift_substituend subst t in let env = push_rel (LocalDef (na, b, t)) env in let subst = Esubst.subs_lift subst in
instantiate sigma env subst accu decls in let sigma, subst, nctx, holes = instantiate sigma env (Esubst.subs_id 0) [] (List.rev ctx) in let nty = Vars.esubst Vars.lift_substituend subst ty in (* Solve holes with the provided bindings *) let unify sigma n c = let env, ev = List.nth holes n in
Evarconv.unify env sigma CONV ev c in let sigma = Specialize.unify_bindings sigma unify typ_of_c lbind in (* Instantiate unsolved holes with their default value *) let fold sigma (env, ev) = if isEvar sigma ev then Evarconv.unify env sigma CONV ev (mkRel 1) else sigma in let sigma = List.fold_left fold sigma holes in (* Requantify the proof term and its type *) let args = Context.Rel.instance_list mkRel 0 ctx in let nc = applist (c, List.map (fun c -> Vars.esubst Vars.lift_substituend subst c) args) in let rec rebuild rels ctx c ty = match ctx with
| [] -> c, ty
| decl :: ctx -> let lift s = Int.Set.fold (fun n accu -> Int.Set.add (n - 1) accu) s Int.Set.empty in let c, ty, rels = (* We always keep let bindings *) if RelDecl.is_local_def decl || Int.Set.mem 1 rels then let rels = lift (Int.Set.remove 1 rels) in let rels = RelDecl.fold_constr (fun c accu -> Int.Set.union accu (free_rels sigma c)) decl rels in
mkLambda_or_LetIn decl c, mkProd_or_LetIn decl ty, rels else subst1 mkProp (* dummy *) c, subst1 mkProp ty, lift rels in
rebuild rels ctx c ty in let rels = Int.Set.union (free_rels sigma nc) (free_rels sigma nty) in let nc, nty = rebuild rels nctx nc nty in
sigma, nc, nty in let tac = match EConstr.kind sigma (fst(EConstr.decompose_app sigma (snd(EConstr.decompose_lambda_decls sigma c)))) with
| Var id when Id.List.mem id (Tacmach.pf_ids_of_hyps gl) -> (* Like assert (id:=id args) but with the concept of specialization *) let ipat = match ipat with None -> Some (CAst.make (IntroNaming (IntroIdentifier id))) | _ -> ipat in let naming,tac = prepare_intros_opt false IntroAnonymous MoveLast ipat in let repl = do_replace (Some id) naming in (* "specialize H ... as H", "specialize H ...": do not clear (cleared implicitly at replacing time) *) (* "specialize H ... as H'", "specialize H ... as ?H": keep a copy by convention *) (* "specialize H ... as any_other_pattern": clear *) let doclear = match ipat with
| Some {CAst.v=IntroNaming (IntroIdentifier _ | IntroFresh _)} -> false
| _ -> truein let tac = if doclear thenfun id' -> Tacticals.tclTHEN (clear [id]) (tac id') else tac in
Tacticals.tclTHENFIRST
(assert_before_then_gen repl naming typ tac)
(exact_no_check term)
| _ -> match ipat with
| None -> (* Like generalize with extra support for "with" bindings *) (* even though the "with" bindings forces full application *) (* TODO: add intro to be more homogeneous. It will break
scripts but will be easy to fix *)
(Tacticals.tclTHENLAST (cut typ) (exact_no_check term))
| Some _ as ipat -> (* Like pose proof with extra support for "with" bindings *) (* even though the "with" bindings forces full application *) let naming, tac = prepare_intros_opt false IntroAnonymous MoveLast ipat in
Tacticals.tclTHENFIRST
(assert_before_then_gen false naming typ tac)
(exact_no_check term) in
Tacticals.tclTHEN (Proofview.Unsafe.tclEVARS sigma) tac end
(*****************************) (* Ad hoc unfold *) (*****************************)
(* The two following functions should already exist, but found nowhere *) (* Unfolds x by its definition everywhere *) let unfold_body x = letopen Context.Named.Declaration in
Proofview.Goal.enter beginfun gl -> (* We normalize the given hypothesis immediately. *) let env = Proofview.Goal.env gl in let sigma = Proofview.Goal.sigma gl in let xval = match Environ.lookup_named x env with
| LocalAssum _ -> error (VariableHasNoValue x)
| LocalDef (_,xval,_) -> xval in let xval = EConstr.of_constr xval in
Tacticals.afterHyp x beginfun aft -> let hl = List.fold_right (fun decl cl -> (NamedDecl.get_id decl, InHyp) :: cl) aft [] in let rfun _ _ c = replace_vars sigma [x, xval] c in let reducth h = reduct_in_hyp ~check:false ~reorder:false rfun h in let reductc = reduct_in_concl ~cast:false ~check:false (rfun, DEFAULTcast) in
Tacticals.tclTHENLIST [Tacticals.tclMAP reducth hl; reductc] end end
let dest_intro_patterns with_evars avoid thin dest pat tac =
intro_patterns_core with_evars avoid [] thin dest None 0 tac pat
let rocq_heq_ref = lazy (Rocqlib.lib_ref "core.JMeq.type")
let compare_upto_variables sigma x y = let rec compare x y = if (isVar sigma x || isRel sigma x) && (isVar sigma y || isRel sigma y) thentrue else compare_constr sigma compare x y in
compare x y
let specialize_eqs id = letopen Context.Rel.Declaration in
Proofview.Goal.enter beginfun gl -> let env = Proofview.Goal.env gl in let ty = Tacmach.pf_get_hyp_typ id gl in let evars = ref (Proofview.Goal.sigma gl) in let unif env evars c1 c2 =
compare_upto_variables !evars c1 c2 &&
(match Evarconv.unify_delay env !evars c1 c2 with
| sigma -> evars := sigma; true
| exception Evarconv.UnableToUnify _ -> false) in let rec aux in_eqs ctx acc ty = match EConstr.kind !evars ty with
| Prod (na, t, b) ->
(match EConstr.kind !evars t with
| App (eq, [| eqty; x; y |]) when is_lib_ref env !evars "core.eq.type" eq -> let c = if noccur_between !evars 1 (List.length ctx) x then y else x in let pt = mkApp (eq, [| eqty; c; c |]) in let ind = destInd !evars eq in let p = mkApp (mkConstructUi (ind,0), [| eqty; c |]) in if unif (push_rel_context ctx env) evars pt t then
aux true ctx (mkApp (acc, [| p |])) (subst1 p b) else acc, in_eqs, ctx, ty
| App (heq, [| eqty; x; eqty'; y |]) when isRefX env !evars (Lazy.force rocq_heq_ref) heq -> let eqt, c = if noccur_between !evars 1 (List.length ctx) x then eqty', y else eqty, x in let pt = mkApp (heq, [| eqt; c; eqt; c |]) in let ind = destInd !evars heq in let p = mkApp (mkConstructUi (ind,0), [| eqt; c |]) in if unif (push_rel_context ctx env) evars pt t then
aux true ctx (mkApp (acc, [| p |])) (subst1 p b) else acc, in_eqs, ctx, ty
| _ -> if in_eqs then acc, in_eqs, ctx, ty else let typeclass_candidate = Typeclasses.is_maybe_class_type !evars t in let sigma, e = Evarutil.new_evar ~typeclass_candidate (push_rel_context ctx env) !evars t in
evars := sigma;
aux false (LocalDef (na,e,t) :: ctx) (mkApp (lift 1 acc, [| mkRel 1 |])) b)
| t -> acc, in_eqs, ctx, ty in let acc, worked, ctx, ty = aux false [] (mkVar id) ty in let ctx' = nf_rel_context_evar !evars ctx in let ctx'' = List.map (function
| LocalDef (n,k,t) when isEvar !evars k -> LocalAssum (n,t)
| decl -> decl) ctx' in let ty' = it_mkProd_or_LetIn ty ctx'' in let acc' = it_mkLambda_or_LetIn acc ctx'' in let ty' = Tacred.whd_simpl env !evars ty' and acc' = Tacred.whd_simpl env !evars acc'in let ty' = Evarutil.nf_evar !evars ty'in if worked then
Tacticals.tclTHENFIRST
(internal_cut true id ty')
(exact_no_check ((* refresh_universes_strict *) acc')) else let info = Exninfo.reify () in
Tacticals.tclFAIL ~info (str "Nothing to do in hypothesis " ++ Id.print id) end
let specialize_eqs id = Proofview.Goal.enter beginfun gl -> let msg = str "Specialization not allowed on dependent hypotheses"in
Proofview.tclOR (clear [id])
(fun (_,info) -> Tacticals.tclZEROMSG ~info msg) >>= fun () ->
specialize_eqs id end
let exfalso =
Proofview.Goal.enter beginfun gl -> let env = Proofview.Goal.env gl in let sigma = Proofview.Goal.sigma gl in let (sigma, f) = Evd.fresh_global env sigma (Rocqlib.lib_ref "core.False.type") in let (ind, _) = reduce_to_atomic_ind env sigma f in let s = Retyping.get_sort_quality_of env sigma (Proofview.Goal.concl gl) in let sigma, elimc = find_ind_eliminator env sigma (fst ind) s in let elimc = mkConstU elimc in let elimt = Retyping.get_type_of env sigma elimc in let clause = mk_clenv_from env sigma (elimc, elimt) in
Proofview.tclTHEN (Proofview.Unsafe.tclEVARS sigma) (Clenv.res_pf clause ~flags:(elim_flags ()) ~with_evars:false) end
(************************************************) (* Tactics related with logic connectives *) (************************************************)
(* Reflexivity tactics *)
let (forward_setoid_reflexivity, setoid_reflexivity) = Hook.make ()
let maybe_betadeltaiota_concl allowred gl = let concl = Tacmach.pf_concl gl in let sigma = Tacmach.project gl in ifnot allowred then concl else let env = Proofview.Goal.env gl in
whd_all env sigma concl
let reflexivity_red allowred =
Proofview.Goal.enter beginfun gl -> (* PL: usual reflexivity don't perform any reduction when searching for an equality, but we may need to do some when called back from
inside setoid_reflexivity (see Optimize cases in setoid_replace.ml). *) let env = Tacmach.pf_env gl in let sigma = Tacmach.project gl in let concl = maybe_betadeltaiota_concl allowred gl in match match_with_equality_type env sigma concl with
| None -> let info = Exninfo.reify () in
Proofview.tclZERO ~info NoEquationFound
| Some _ -> one_constructor 1 NoBindings end
let reflexivity =
Proofview.tclORELSE
(reflexivity_red false) begin function (e, info) -> match e with
| NoEquationFound -> Hook.get forward_setoid_reflexivity
| e -> Proofview.tclZERO ~info e end
let intros_reflexivity = (Tacticals.tclTHEN intros reflexivity)
(* Symmetry tactics *)
(* This tactic first tries to apply a constant named sym_eq, where eq is the name of the equality predicate. If this constant is not defined and the conclusion is a=b, it solves the goal doing (Cut
b=a;Intro H;Case H;Constructor 1) *)
let (forward_setoid_symmetry, setoid_symmetry) = Hook.make ()
(* This is probably not very useful any longer *) let prove_symmetry hdcncl eq_kind = let symc = match eq_kind with
| MonomorphicLeibnizEq (c1,c2) -> mkApp(hdcncl,[|c2;c1|])
| PolymorphicLeibnizEq (typ,c1,c2) -> mkApp(hdcncl,[|typ;c2;c1|])
| HeterogenousEq (t1,c1,t2,c2) -> mkApp(hdcncl,[|t2;c2;t1;c1|]) in
Tacticals.tclTHENFIRST (cut symc)
(Tacticals.tclTHENLIST
[ intro;
Tacticals.onLastHyp simplest_case;
one_constructor 1 NoBindings ])
let match_with_equation c =
Proofview.tclEVARMAP >>= fun sigma ->
Proofview.tclENV >>= fun env -> try let res = match_with_equation env sigma c in
Proofview.tclUNIT res with NoEquationFound as exn -> let _, info = Exninfo.capture exn in
Proofview.tclZERO ~info NoEquationFound
let symmetry_red allowred =
Proofview.Goal.enter beginfun gl -> (* PL: usual symmetry don't perform any reduction when searching for an equality, but we may need to do some when called back from
inside setoid_reflexivity (see Optimize cases in setoid_replace.ml). *) let concl = maybe_betadeltaiota_concl allowred gl in
match_with_equation concl >>= fun with_eqn -> match with_eqn with
| Some eq_data,_,_ ->
Tacticals.tclTHEN
(convert_concl ~cast:false ~check:false concl DEFAULTcast)
(Tacticals.pf_constr_of_global eq_data.sym >>= apply)
| None,eq,eq_kind -> prove_symmetry eq eq_kind end
let symmetry =
Proofview.tclORELSE
(symmetry_red false) begin function (e, info) -> match e with
| NoEquationFound -> Hook.get forward_setoid_symmetry
| e -> Proofview.tclZERO ~info e end
let (forward_setoid_symmetry_in, setoid_symmetry_in) = Hook.make ()
let symmetry_in id =
Proofview.Goal.enter beginfun gl -> let sigma, ctype = Tacmach.pf_type_of gl (mkVar id) in let sign,t = decompose_prod_decls sigma ctype in
tclEVARSTHEN sigma
(Proofview.tclORELSE begin
match_with_equation t >>= fun (_,hdcncl,eq) -> let symccl = match eq with
| MonomorphicLeibnizEq (c1,c2) -> mkApp (hdcncl, [| c2; c1 |])
| PolymorphicLeibnizEq (typ,c1,c2) -> mkApp (hdcncl, [| typ; c2; c1 |])
| HeterogenousEq (t1,c1,t2,c2) -> mkApp (hdcncl, [| t2; c2; t1; c1 |]) in
Tacticals.tclTHENS (cut (EConstr.it_mkProd_or_LetIn symccl sign))
[ intro_replacing id;
Tacticals.tclTHENLIST [ intros; symmetry; apply (mkVar id); assumption ] ] end begin function (e, info) -> match e with
| NoEquationFound -> Hook.get forward_setoid_symmetry_in id
| e -> Proofview.tclZERO ~info e end) end
let intros_symmetry =
Tacticals.onClause
(function
| None -> Tacticals.tclTHEN intros symmetry
| Some id -> symmetry_in id)
(* Transitivity tactics *)
(* This tactic first tries to apply a constant named eq_trans, where eq is the name of the equality predicate. If this constant is not defined and the conclusion is a=b, it solves the goal doing Cut x1=x2; [Cut x2=x3; [Intros e1 e2; Case e2;Assumption | Idtac] | Idtac] --Eduardo (19/8/97)
*)
let (forward_setoid_transitivity, setoid_transitivity) = Hook.make ()
(* This is probably not very useful any longer *) let prove_transitivity hdcncl eq_kind t =
Proofview.Goal.enter beginfun gl -> let eq1, eq2 = match eq_kind with
| MonomorphicLeibnizEq (c1,c2) ->
mkApp (hdcncl, [| c1; t|]), mkApp (hdcncl, [| t; c2 |])
| PolymorphicLeibnizEq (typ,c1,c2) ->
mkApp (hdcncl, [| typ; c1; t |]), mkApp (hdcncl, [| typ; t; c2 |])
| HeterogenousEq (typ1,c1,typ2,c2) -> let env = Proofview.Goal.env gl in let sigma = Tacmach.project gl in let typt = Retyping.get_type_of env sigma t in
mkApp(hdcncl, [| typ1; c1; typt ;t |]),
mkApp(hdcncl, [| typt; t; typ2; c2 |]) in
Tacticals.tclTHENFIRST (cut eq2)
(Tacticals.tclTHENFIRST (cut eq1)
(Tacticals.tclTHENLIST
[ Tacticals.tclDO 2 intro;
Tacticals.onLastHyp simplest_case;
assumption ])) end
let transitivity_red allowred t =
Proofview.Goal.enter beginfun gl -> (* PL: usual transitivity don't perform any reduction when searching for an equality, but we may need to do some when called back from
inside setoid_reflexivity (see Optimize cases in setoid_replace.ml). *) let concl = maybe_betadeltaiota_concl allowred gl in
match_with_equation concl >>= fun with_eqn -> match with_eqn with
| Some eq_data,_,_ ->
Tacticals.tclTHEN
(convert_concl ~cast:false ~check:false concl DEFAULTcast)
(match t with
| None -> Tacticals.pf_constr_of_global eq_data.trans >>= eapply
| Some t -> Tacticals.pf_constr_of_global eq_data.trans >>= fun trans -> apply_list [trans; t])
| None,eq,eq_kind -> match t with
| None -> let info = Exninfo.reify () in
Tacticals.tclZEROMSG ~info (str"etransitivity not supported for this relation.")
| Some t -> prove_transitivity eq eq_kind t end
let transitivity_gen t =
Proofview.tclORELSE
(transitivity_red false t) begin function (e, info) -> match e with
| NoEquationFound -> Hook.get forward_setoid_transitivity t
| e -> Proofview.tclZERO ~info e end
let etransitivity = transitivity_gen None let transitivity t = transitivity_gen (Some t)
let intros_transitivity n = Tacticals.tclTHEN intros (transitivity_gen n)
let constr_eq ~strict x y = let fail ~info = Tacticals.tclFAIL ~info (str "Not equal") in let fail_universes ~info = Tacticals.tclFAIL ~info (str "Not equal (due to universes)") in
Proofview.Goal.enter beginfun gl -> let env = Tacmach.pf_env gl in let evd = Tacmach.project gl in match EConstr.eq_constr_universes env evd x y with
| Some csts -> if strict then if UState.check_universe_constraints (Evd.ustate evd) csts then Proofview.tclUNIT () else let info = Exninfo.reify () in
fail_universes ~info else let csts = UnivProblem.Set.force csts in beginmatch Evd.add_universe_constraints evd csts with
| evd -> Proofview.Unsafe.tclEVARS evd
| exception (UGraph.UniverseInconsistency _ as e) -> let _, info = Exninfo.capture e in
fail_universes ~info end
| None -> let info = Exninfo.reify () in
fail ~info end
let unify ?(state=TransparentState.full) x y =
Proofview.Goal.enter beginfun gl -> let env = Proofview.Goal.env gl in let sigma = Proofview.Goal.sigma gl in try let core_flags =
{ (default_unify_flags ()).core_unify_flags with
modulo_delta = state;
modulo_conv_on_closed_terms = Some state} in (* What to do on merge and subterm flags?? *) let flags = { (default_unify_flags ()) with
core_unify_flags = core_flags;
merge_unify_flags = core_flags;
subterm_unify_flags = { core_flags with modulo_delta = TransparentState.empty } } in let _, sigma = w_unify (Tacmach.pf_env gl) sigma Conversion.CONV ~flags x y in
Proofview.Unsafe.tclEVARS sigma with e when noncritical e -> let e, info = Exninfo.capture e in
Proofview.tclZERO ~info (PretypeError (env, sigma, CannotUnify (x, y, None))) end
let evarconv_unify ?(state=TransparentState.full) ?(with_ho=true) x y =
Proofview.Goal.enter beginfun gl -> let env = Proofview.Goal.env gl in let sigma = Proofview.Goal.sigma gl in try let flags = Evarconv.default_flags_of state in let sigma = Evarconv.unify ~flags ~with_ho env sigma Conversion.CONV x y in
Proofview.Unsafe.tclEVARS sigma with e when noncritical e -> let e, info = Exninfo.capture e in
Proofview.tclZERO ~info (PretypeError (env, sigma, CannotUnify (x, y, None))) end
(** [tclWRAPFINALLY before tac finally] runs [before] before each entry-point of [tac] and passes the result of [before] to [finally], which is then run at each exit-point of [tac], regardless of whether it succeeds or fails. Said another way, if [tac] succeeds, then it behaves as [before >>= fun v -> tac >>= fun ret -> finally v <*> tclUNIT ret]; otherwise, if [tac] fails with [e], it behaves as [before >>= fun v -> finally v <*> tclZERO e]. Note that if [tac] succeeds [n] times before finally failing, [before] and [finally] are both run [n+1] times (once around each
succuess, and once more around the final failure). *) (* We should probably export this somewhere, but it's not clear where. As per https://github.com/rocq-prover/rocq/pull/12197#discussion_r418480525 and https://gitter.im/coq/coq?at=5ead5c35347bd616304e83ef, we don't export it from Proofview, because it seems somehow not primitive enough. We don't export it from this file because it is more of a tactical than a tactic. But we also don't export it from Tacticals because all of the non-New tacticals there operate on `tactic`, not `Proofview.tactic`, and all of the `New` tacticals that deal with multi-success things are focussing, i.e., apply their arguments on each goal separately (and it even says so in the comment on `New`), whereas it's important that `tclWRAPFINALLY` doesn't introduce
extra focussing. *) let rec tclWRAPFINALLY before tac finally = letopen Proofview in letopen Proofview.Notations in
before >>= fun v -> tclCASE tac >>= function
| Fail (e, info) -> finally v >>= fun () -> tclZERO ~info e
| Next (ret, tac') -> tclOR
(finally v >>= fun () -> tclUNIT ret)
(fun e -> tclWRAPFINALLY before (tac' e) finally)
let with_set_strategy lvl_ql k = let glob_key r = match r with
| GlobRef.ConstRef sp -> begin match Structures.PrimitiveProjections.find_opt sp with
| None -> Evaluable.EvalConstRef sp
| Some p -> Evaluable.EvalProjectionRef p end
| GlobRef.VarRef id -> Evaluable.EvalVarRef id
| _ -> user_err Pp.(str "cannot set an inductive type or a constructor as transparent") in let kl = List.concat (List.map (fun (lvl, ql) -> List.map (fun q -> (lvl, glob_key q)) ql) lvl_ql) in
tclWRAPFINALLY
(Proofview.tclENV >>= fun env -> let orig_kl = List.map (fun (_lvl, k) ->
(Conv_oracle.get_strategy (Environ.oracle env) (Evaluable.to_kevaluable k), k))
kl in (* Because the global env might be desynchronized from the proof-local env, we need to update the global env to have this tactic play nicely with abstract. TODO: When abstract no longer depends on Global, delete this
let orig_kl_global = ... in *) let orig_kl_global = List.map (fun (_lvl, k) ->
(Conv_oracle.get_strategy (Environ.oracle (Global.env ())) (Evaluable.to_kevaluable k), k))
kl in let env = List.fold_left (fun env (lvl, k) ->
Environ.set_oracle env
(Conv_oracle.set_strategy (Environ.oracle env) (Evaluable.to_kevaluable k) lvl)) env kl in
Proofview.Unsafe.tclSETENV env <*> (* TODO: When abstract no longer depends on Global, remove this
[Proofview.tclLIFT] block *)
Proofview.tclLIFT (Proofview.NonLogical.make (fun () -> List.iter (fun (lvl, k) -> Global.set_strategy (Evaluable.to_kevaluable k) lvl) kl)) <*>
Proofview.tclUNIT (orig_kl, orig_kl_global))
k
(fun (orig_kl, orig_kl_global) -> (* TODO: When abstract no longer depends on Global, remove this
[Proofview.tclLIFT] block *)
Proofview.tclLIFT (Proofview.NonLogical.make (fun () -> List.iter (fun (lvl, k) -> Global.set_strategy (Evaluable.to_kevaluable k) lvl) orig_kl_global)) <*>
Proofview.tclENV >>= fun env -> let env = List.fold_left (fun env (lvl, k) ->
Environ.set_oracle env
(Conv_oracle.set_strategy (Environ.oracle env) (Evaluable.to_kevaluable k) lvl)) env orig_kl in
Proofview.Unsafe.tclSETENV env)
module Simple = struct (** Simplified version of some of the above tactics *)
let intro x = intro_move (Some x) MoveLast
let apply c =
apply_with_bindings_gen falsefalse [None,(CAst.make (c,NoBindings))] let eapply c =
apply_with_bindings_gen falsetrue [None,(CAst.make (c,NoBindings))] let elim c = elim false None (c,NoBindings) None letcase c = general_case_analysis false None (c,NoBindings)
let apply_in id c =
apply_in falsefalse id [None,(CAst.make (c, NoBindings))] None
end
(** Tacticals defined directly in term of Proofview *) let reduce_after_refine = (* For backward compatibility reasons, we do not contract let-ins, but we unfold them. *) let redfun env t = let flags = RedFlags.red_add_transparent RedFlags.allnolet TransparentState.empty in
clos_norm_flags flags env t in
reduct_in_concl ~cast:false ~check:false (redfun,DEFAULTcast)
let refine ~typecheck c =
Refine.refine ~typecheck c <*>
reduce_after_refine
module Internal = struct
let explicit_intro_names = explicit_intro_names let check_name_unicity = check_name_unicity let clear_gen = clear_gen let clear_wildcards = clear_wildcards let dest_intro_patterns = dest_intro_patterns
end
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