export consts_of;
removed const_expansion;
pretty_term', infer_types(_simult): separate Consts.T argument;
added generic certify;
simplified certify_term/prop;
(* Title: Pure/Isar/obtain.ML
ID: $Id$
Author: Markus Wenzel, TU Muenchen
The 'obtain' and 'guess' language elements -- generalized existence at
the level of proof texts: 'obtain' involves a proof that certain
fixes/assumes may be introduced into the present context; 'guess' is
similar, but derives these elements from the course of reasoning!
<chain_facts>
obtain x where "A x" <proof> ==
have "!!thesis. (!!x. A x ==> thesis) ==> thesis"
proof succeed
fix thesis
assume that [intro?]: "!!x. A x ==> thesis"
<chain_facts>
show thesis
apply (insert that)
<proof>
qed
fix x assm <<obtain_export>> "A x"
<chain_facts>
guess x <proof body> <proof end> ==
{
fix thesis
<chain_facts> have "PROP ?guess"
apply magic -- {* turns goal into "thesis ==> #thesis" *}
<proof body>
apply_end magic -- {* turns final "(!!x. P x ==> thesis) ==> #thesis" into
"#((!!x. A x ==> thesis) ==> thesis)" which is a finished goal state *}
<proof end>
}
fix x assm <<obtain_export>> "A x"
*)
signature OBTAIN =
sig
val obtain: string -> (string * string option) list ->
((string * Attrib.src list) * (string * (string list * string list)) list) list
-> bool -> Proof.state -> Proof.state
val obtain_i: string -> (string * typ option) list ->
((string * attribute list) * (term * (term list * term list)) list) list
-> bool -> Proof.state -> Proof.state
val guess: (string * string option) list -> bool -> Proof.state -> Proof.state
val guess_i: (string * typ option) list -> bool -> Proof.state -> Proof.state
val statement: (string * ((string * 'typ option) list * 'term list)) list ->
(('typ, 'term, 'fact) Element.ctxt list *
((string * Attrib.src list) * ('term * ('term list * 'term list)) list) list) *
(((string * Attrib.src list) * (term * (term list * term list)) list) list -> Proof.context ->
(((string * Attrib.src list) * (term * (term list * term list)) list) list * thm list) *
Proof.context)
end;
structure Obtain: OBTAIN =
struct
(** obtain_export **)
(*
[x, A x]
:
B
--------
B
*)
fun obtain_export ctxt parms rule cprops thm =
let
val {thy, prop, maxidx, ...} = Thm.rep_thm thm;
val cparms = map (Thm.cterm_of thy) parms;
val thm' = thm
|> Drule.implies_intr_protected cprops
|> Drule.forall_intr_list cparms
|> Drule.forall_elim_vars (maxidx + 1);
val elim_tacs = replicate (length cprops) (Tactic.etac Drule.protectI);
val concl = Logic.strip_assums_concl prop;
val bads = parms inter (Term.term_frees concl);
in
if not (null bads) then
error ("Conclusion contains obtained parameters: " ^
space_implode " " (map (ProofContext.string_of_term ctxt) bads))
else if not (ObjectLogic.is_judgment thy concl) then
error "Conclusion in obtained context must be object-logic judgments"
else (Tactic.rtac thm' THEN' RANGE elim_tacs) 1 rule
end;
(** obtain **)
fun bind_judgment ctxt name =
let
val (bind, _) = ProofContext.bind_fixes [name] ctxt;
val (t as _ $ Free v) = bind (ObjectLogic.fixed_judgment (ProofContext.theory_of ctxt) name);
in (v, t) end;
val thatN = "that";
local
fun gen_obtain prep_att prep_vars prep_propp
name raw_vars raw_asms int state =
let
val _ = Proof.assert_forward_or_chain state;
val ctxt = Proof.context_of state;
val thy = Proof.theory_of state;
val chain_facts = if can Proof.assert_chain state then Proof.the_facts state else [];
(*obtain vars*)
val (vars, vars_ctxt) = prep_vars (map Syntax.no_syn raw_vars) ctxt;
val (_, fix_ctxt) = vars_ctxt |> ProofContext.add_fixes_i vars;
val xs = map #1 vars;
(*obtain asms*)
val (asms_ctxt, proppss) = prep_propp (fix_ctxt, map snd raw_asms);
val asm_props = List.concat (map (map fst) proppss);
val asms = map fst (Attrib.map_specs (prep_att thy) raw_asms) ~~ proppss;
val _ = ProofContext.warn_extra_tfrees fix_ctxt asms_ctxt;
(*obtain statements*)
val thesisN = Term.variant xs AutoBind.thesisN;
val (thesis_var, thesis) = bind_judgment fix_ctxt thesisN;
fun occs_var x = Library.get_first (fn t =>
Term.find_free t (ProofContext.get_skolem fix_ctxt x)) asm_props;
val raw_parms = map occs_var xs;
val parms = List.mapPartial I raw_parms;
val parm_names =
List.mapPartial (fn (SOME (Free a), x) => SOME (a, x) | _ => NONE) (raw_parms ~~ xs);
val that_name = if name = "" then thatN else name;
val that_prop =
Term.list_all_free (map #1 parm_names, Logic.list_implies (asm_props, thesis))
|> Library.curry Logic.list_rename_params (map #2 parm_names);
val obtain_prop =
Logic.list_rename_params ([AutoBind.thesisN],
Term.list_all_free ([thesis_var], Logic.mk_implies (that_prop, thesis)));
fun after_qed _ =
Proof.local_qed (NONE, false)
#> Seq.map (`Proof.the_fact #-> (fn rule =>
Proof.fix_i (xs ~~ map #2 vars)
#> Proof.assm_i (K (obtain_export ctxt parms rule)) asms));
in
state
|> Proof.enter_forward
|> Proof.have_i NONE (K Seq.single) [(("", []), [(obtain_prop, ([], []))])] int
|> Proof.proof (SOME Method.succeed_text) |> Seq.hd
|> Proof.fix_i [(thesisN, NONE)]
|> Proof.assume_i [((that_name, [ContextRules.intro_query NONE]), [(that_prop, ([], []))])]
|> `Proof.the_facts
||> Proof.chain_facts chain_facts
||> Proof.show_i NONE after_qed [(("", []), [(thesis, ([], []))])] false
|-> Proof.refine_insert
end;
in
val obtain = gen_obtain Attrib.attribute ProofContext.read_vars ProofContext.read_propp;
val obtain_i = gen_obtain (K I) ProofContext.cert_vars ProofContext.cert_propp;
end;
(** guess **)
local
fun match_params ctxt vars rule =
let
val thy = ProofContext.theory_of ctxt;
val string_of_typ = ProofContext.string_of_typ ctxt;
val string_of_term = setmp show_types true (ProofContext.string_of_term ctxt);
fun err msg th = error (msg ^ ":\n" ^ ProofContext.string_of_thm ctxt th);
val params = RuleCases.strip_params (Logic.nth_prem (1, Thm.prop_of rule));
val m = length vars;
val n = length params;
val _ = conditional (m > n)
(fn () => err "More variables than parameters in obtained rule" rule);
fun match ((x, SOME T), (y, U)) tyenv =
((x, T), Sign.typ_match thy (U, T) tyenv handle Type.TYPE_MATCH =>
err ("Failed to match variable " ^
string_of_term (Free (x, T)) ^ " against parameter " ^
string_of_term (Syntax.mark_boundT (y, Envir.norm_type tyenv U)) ^ " in") rule)
| match ((x, NONE), (_, U)) tyenv = ((x, U), tyenv);
val (xs, tyenv) = fold_map match (vars ~~ Library.take (m, params)) Vartab.empty;
val ys = Library.drop (m, params);
val norm_type = Envir.norm_type tyenv;
val xs' = xs |> map (apsnd norm_type);
val ys' =
map Syntax.internal (Term.variantlist (map fst ys, map fst xs)) ~~
map (norm_type o snd) ys;
val instT =
fold (Term.add_tvarsT o #2) params []
|> map (TVar #> (fn T => (Thm.ctyp_of thy T, Thm.ctyp_of thy (norm_type T))));
val rule' = rule |> Thm.instantiate (instT, []);
val tvars = Drule.tvars_of rule';
val vars = fold (remove op =) (Term.add_vars (Thm.concl_of rule') []) (Drule.vars_of rule');
val _ =
if null tvars andalso null vars then ()
else err ("Illegal schematic variable(s) " ^
commas (map (string_of_typ o TVar) tvars @ map (string_of_term o Var) vars) ^ " in") rule';
in (xs' @ ys', rule') end;
fun inferred_type (x, _, mx) ctxt =
let val ((_, T), ctxt') = ProofContext.inferred_param x ctxt
in ((x, SOME T, mx), ctxt') end;
fun gen_guess prep_vars raw_vars int state =
let
val _ = Proof.assert_forward_or_chain state;
val thy = Proof.theory_of state;
val ctxt = Proof.context_of state;
val chain_facts = if can Proof.assert_chain state then Proof.the_facts state else [];
val (thesis_var, thesis) = bind_judgment ctxt AutoBind.thesisN;
val (vars, _) = ctxt |> prep_vars (map Syntax.no_syn raw_vars) |-> fold_map inferred_type;
fun check_result th =
(case Thm.prems_of th of
[prem] =>
if Thm.concl_of th aconv thesis andalso
Logic.strip_assums_concl prem aconv thesis then ()
else error ("Guessed a different clause:\n" ^ ProofContext.string_of_thm ctxt th)
| [] => error "Goal solved -- nothing guessed."
| _ => error ("Guess split into several cases:\n" ^ ProofContext.string_of_thm ctxt th));
fun guess_context raw_rule =
let
val (parms, rule) = match_params ctxt (map (fn (x, T, _) => (x, T)) vars) raw_rule;
val (bind, _) = ProofContext.bind_fixes (map #1 parms) ctxt;
val ts = map (bind o Free) parms;
val ps = map dest_Free ts;
val asms =
Logic.strip_assums_hyp (Logic.nth_prem (1, Thm.prop_of rule))
|> map (fn asm => (Term.betapplys (Term.list_abs (ps, asm), ts), ([], [])));
val _ = conditional (null asms) (fn () => error "Trivial result -- nothing guessed");
in
Proof.fix_i (map (apsnd SOME) parms)
#> Proof.assm_i (K (obtain_export ctxt ts rule)) [(("", []), asms)]
#> Proof.add_binds_i AutoBind.no_facts
end;
val before_qed = SOME (Method.primitive_text (Goal.conclude #> Goal.protect));
fun after_qed [[res]] =
(check_result res; Proof.end_block #> Seq.map (`Proof.the_fact #-> guess_context));
in
state
|> Proof.enter_forward
|> Proof.begin_block
|> Proof.fix_i [(AutoBind.thesisN, NONE)]
|> Proof.chain_facts chain_facts
|> Proof.local_goal (ProofDisplay.print_results int) (K I) (apsnd (rpair I))
"guess" before_qed after_qed [(("", []), [Var (("guess", 0), propT)])]
|> Proof.refine (Method.primitive_text (K (Goal.init (Thm.cterm_of thy thesis)))) |> Seq.hd
end;
in
val guess = gen_guess ProofContext.read_vars;
val guess_i = gen_guess ProofContext.cert_vars;
end;
(** statements with several cases **)
fun statement cases =
let
val names =
cases |> map_index (fn (i, ("", _)) => string_of_int (i + 1) | (_, (name, _)) => name);
val elems = cases |> map (fn (_, (vars, _)) =>
Element.Constrains (vars |> List.mapPartial (fn (x, SOME T) => SOME (x, T) | _ => NONE)));
val concl = cases |> map (fn (_, (_, props)) => (("", []), map (rpair ([], [])) props));
fun mk_stmt stmt ctxt =
let
val thesis =
ObjectLogic.fixed_judgment (ProofContext.theory_of ctxt) AutoBind.thesisN;
val atts = map Attrib.internal
[RuleCases.consumes (~ (length cases)), RuleCases.case_names names];
fun assume_case ((name, (vars, _)), (_, propp)) ctxt' =
let
val xs = map fst vars;
val props = map fst propp;
val (parms, ctxt'') =
ctxt'
|> fold ProofContext.declare_term props
|> fold_map ProofContext.inferred_param xs;
val asm = Term.list_all_free (parms, Logic.list_implies (props, thesis));
in
ctxt' |> (snd o ProofContext.add_fixes_i (map (fn x => (x, NONE, NoSyn)) xs));
ctxt' |> ProofContext.add_assms_i ProofContext.assume_export
[((name, [ContextRules.intro_query NONE]), [(asm, ([], []))])]
|>> (fn [(_, [th])] => th)
end;
val (ths, ctxt') = ctxt
|> (snd o ProofContext.add_fixes_i [(AutoBind.thesisN, NONE, NoSyn)])
|> fold_map assume_case (cases ~~ stmt)
|-> (fn ths => ProofContext.note_thmss_i [((thatN, []), [(ths, [])])] #> #2 #> pair ths);
in (([(("", atts), [(thesis, ([], []))])], ths), ctxt') end;
in ((elems, concl), mk_stmt) end;
end;