--- a/src/Pure/old_goals.ML Wed Sep 01 22:59:11 2010 +0200
+++ /dev/null Thu Jan 01 00:00:00 1970 +0000
@@ -1,440 +0,0 @@
-(* Title: Pure/old_goals.ML
- Author: Lawrence C Paulson, Cambridge University Computer Laboratory
- Copyright 1993 University of Cambridge
-
-Old-style goal stack package. The goal stack initially holds a dummy
-proof, and can never become empty. Each goal stack consists of a list
-of levels. The undo list is a list of goal stacks. Finally, there
-may be a stack of pending proofs.
-*)
-
-signature OLD_GOALS =
-sig
- type proof
- val premises: unit -> thm list
- val reset_goals: unit -> unit
- val result_error_fn: (thm -> string -> thm) Unsynchronized.ref
- val print_sign_exn: theory -> exn -> 'a
- val prove_goalw_cterm: thm list->cterm->(thm list->tactic list)->thm
- val prove_goalw_cterm_nocheck: thm list->cterm->(thm list->tactic list)->thm
- val prove_goalw: theory -> thm list -> string -> (thm list -> tactic list) -> thm
- val prove_goal: theory -> string -> (thm list -> tactic list) -> thm
- val topthm: unit -> thm
- val result: unit -> thm
- val uresult: unit -> thm
- val getgoal: int -> term
- val print_exn: exn -> 'a
- val filter_goal: (term*term->bool) -> thm list -> int -> thm list
- val prlev: int -> unit
- val pr: unit -> unit
- val prlim: int -> unit
- val goalw_cterm: thm list -> cterm -> thm list
- val goalw: theory -> thm list -> string -> thm list
- val goal: theory -> string -> thm list
- val Goalw: thm list -> string -> thm list
- val Goal: string -> thm list
- val simple_prove_goal_cterm: cterm->(thm list->tactic list)->thm
- val by: tactic -> unit
- val byev: tactic list -> unit
- val back: unit -> unit
- val choplev: int -> unit
- val chop: unit -> unit
- val undo: unit -> unit
- val save_proof: unit -> proof
- val restore_proof: proof -> thm list
- val push_proof: unit -> unit
- val pop_proof: unit -> thm list
- val rotate_proof: unit -> thm list
- val qed: string -> unit
- val qed_goal: string -> theory -> string -> (thm list -> tactic list) -> unit
- val qed_goalw: string -> theory -> thm list -> string
- -> (thm list -> tactic list) -> unit
- val qed_spec_mp: string -> unit
- val qed_goal_spec_mp: string -> theory -> string -> (thm list -> tactic list) -> unit
- val qed_goalw_spec_mp: string -> theory -> thm list -> string
- -> (thm list -> tactic list) -> unit
-end;
-
-structure OldGoals: OLD_GOALS =
-struct
-
-
-(*** Goal package ***)
-
-(*Each level of goal stack includes a proof state and alternative states,
- the output of the tactic applied to the preceeding level. *)
-type gstack = (thm * thm Seq.seq) list;
-
-datatype proof = Proof of gstack list * thm list * (bool*thm->thm);
-
-
-(*** References ***)
-
-(*Current assumption list -- set by "goal".*)
-val curr_prems = Unsynchronized.ref([] : thm list);
-
-(*Return assumption list -- useful if you didn't save "goal"'s result. *)
-fun premises() = !curr_prems;
-
-(*Current result maker -- set by "goal", used by "result". *)
-fun init_mkresult _ = error "No goal has been supplied in subgoal module";
-val curr_mkresult = Unsynchronized.ref (init_mkresult: bool*thm->thm);
-
-(*List of previous goal stacks, for the undo operation. Set by setstate.
- A list of lists!*)
-val undo_list = Unsynchronized.ref([[(asm_rl, Seq.empty)]] : gstack list);
-
-(* Stack of proof attempts *)
-val proofstack = Unsynchronized.ref([]: proof list);
-
-(*reset all refs*)
-fun reset_goals () =
- (curr_prems := []; curr_mkresult := init_mkresult;
- undo_list := [[(asm_rl, Seq.empty)]]);
-
-
-(*** Setting up goal-directed proof ***)
-
-(*Generates the list of new theories when the proof state's theory changes*)
-fun thy_error (thy,thy') =
- let val names = subtract (op =) (Context.display_names thy) (Context.display_names thy')
- in case names of
- [name] => "\nNew theory: " ^ name
- | _ => "\nNew theories: " ^ space_implode ", " names
- end;
-
-(*Default action is to print an error message; could be suppressed for
- special applications.*)
-fun result_error_default state msg : thm =
- Pretty.str "Bad final proof state:" ::
- Goal_Display.pretty_goals_without_context (!goals_limit) state @
- [Pretty.str msg, Pretty.str "Proof failed!"] |> Pretty.chunks |> Pretty.string_of |> error;
-
-val result_error_fn = Unsynchronized.ref result_error_default;
-
-
-(*Common treatment of "goal" and "prove_goal":
- Return assumptions, initial proof state, and function to make result.
- "atomic" indicates if the goal should be wrapped up in the function
- "Goal::prop=>prop" to avoid assumptions being returned separately.
-*)
-fun prepare_proof atomic rths chorn =
- let
- val thy = Thm.theory_of_cterm chorn;
- val horn = Thm.term_of chorn;
- val _ = Term.no_dummy_patterns horn handle TERM (msg, _) => error msg;
- val (As, B) = Logic.strip_horn horn;
- val atoms = atomic andalso
- forall (fn t => not (can Logic.dest_implies t orelse Logic.is_all t)) As;
- val (As,B) = if atoms then ([],horn) else (As,B);
- val cAs = map (cterm_of thy) As;
- val prems = map (rewrite_rule rths o Thm.forall_elim_vars 0 o Thm.assume) cAs;
- val cB = cterm_of thy B;
- val st0 = let val st = Goal.init cB |> fold Thm.weaken cAs
- in rewrite_goals_rule rths st end
- (*discharges assumptions from state in the order they appear in goal;
- checks (if requested) that resulting theorem is equivalent to goal. *)
- fun mkresult (check,state) =
- let val state = Seq.hd (Thm.flexflex_rule state)
- handle THM _ => state (*smash flexflex pairs*)
- val ngoals = nprems_of state
- val ath = implies_intr_list cAs state
- val th = Goal.conclude ath
- val thy' = Thm.theory_of_thm th
- val {hyps, prop, ...} = Thm.rep_thm th
- val final_th = Drule.export_without_context th
- in if not check then final_th
- else if not (Theory.eq_thy(thy,thy')) then !result_error_fn state
- ("Theory of proof state has changed!" ^
- thy_error (thy,thy'))
- else if ngoals>0 then !result_error_fn state
- (string_of_int ngoals ^ " unsolved goals!")
- else if not (null hyps) then !result_error_fn state
- ("Additional hypotheses:\n" ^
- cat_lines (map (Syntax.string_of_term_global thy) hyps))
- else if Pattern.matches thy
- (Envir.beta_norm (term_of chorn), Envir.beta_norm prop)
- then final_th
- else !result_error_fn state "proved a different theorem"
- end
- in
- if Theory.eq_thy(thy, Thm.theory_of_thm st0)
- then (prems, st0, mkresult)
- else error ("Definitions would change the proof state's theory" ^
- thy_error (thy, Thm.theory_of_thm st0))
- end
- handle THM(s,_,_) => error("prepare_proof: exception THM was raised!\n" ^ s);
-
-(*Prints exceptions readably to users*)
-fun print_sign_exn_unit thy e =
- case e of
- THM (msg,i,thms) =>
- (writeln ("Exception THM " ^ string_of_int i ^ " raised:\n" ^ msg);
- List.app (writeln o Display.string_of_thm_global thy) thms)
- | THEORY (msg,thys) =>
- (writeln ("Exception THEORY raised:\n" ^ msg);
- List.app (writeln o Context.str_of_thy) thys)
- | TERM (msg,ts) =>
- (writeln ("Exception TERM raised:\n" ^ msg);
- List.app (writeln o Syntax.string_of_term_global thy) ts)
- | TYPE (msg,Ts,ts) =>
- (writeln ("Exception TYPE raised:\n" ^ msg);
- List.app (writeln o Syntax.string_of_typ_global thy) Ts;
- List.app (writeln o Syntax.string_of_term_global thy) ts)
- | e => raise e;
-
-(*Prints an exception, then fails*)
-fun print_sign_exn thy e = (print_sign_exn_unit thy e; raise ERROR "");
-
-(** the prove_goal.... commands
- Prove theorem using the listed tactics; check it has the specified form.
- Augment theory with all type assignments of goal.
- Syntax is similar to "goal" command for easy keyboard use. **)
-
-(*Version taking the goal as a cterm*)
-fun prove_goalw_cterm_general check rths chorn tacsf =
- let val (prems, st0, mkresult) = prepare_proof false rths chorn
- val tac = EVERY (tacsf prems)
- fun statef() =
- (case Seq.pull (tac st0) of
- SOME(st,_) => st
- | _ => error ("prove_goal: tactic failed"))
- in mkresult (check, cond_timeit (!Output.timing) "" statef) end;
-
-(*Two variants: one checking the result, one not.
- Neither prints runtime messages: they are for internal packages.*)
-fun prove_goalw_cterm rths chorn =
- setmp_CRITICAL Output.timing false (prove_goalw_cterm_general true rths chorn)
-and prove_goalw_cterm_nocheck rths chorn =
- setmp_CRITICAL Output.timing false (prove_goalw_cterm_general false rths chorn);
-
-
-(*Version taking the goal as a string*)
-fun prove_goalw thy rths agoal tacsf =
- let val chorn = cterm_of thy (Syntax.read_prop_global thy agoal)
- in prove_goalw_cterm_general true rths chorn tacsf end
- handle ERROR msg => cat_error msg (*from read_prop?*)
- ("The error(s) above occurred for " ^ quote agoal);
-
-(*String version with no meta-rewrite-rules*)
-fun prove_goal thy = prove_goalw thy [];
-
-
-
-(*** Commands etc ***)
-
-(*Return the current goal stack, if any, from undo_list*)
-fun getstate() : gstack = case !undo_list of
- [] => error"No current state in subgoal module"
- | x::_ => x;
-
-(*Pops the given goal stack*)
-fun pop [] = error"Cannot go back past the beginning of the proof!"
- | pop (pair::pairs) = (pair,pairs);
-
-
-(* Print a level of the goal stack *)
-
-fun print_top ((th, _), pairs) =
- let
- val n = length pairs;
- val m = (! goals_limit);
- val ngoals = nprems_of th;
- in
- [Pretty.str ("Level " ^ string_of_int n ^
- (if ngoals > 0 then " (" ^ string_of_int ngoals ^ " subgoal" ^
- (if ngoals <> 1 then "s" else "") ^ ")"
- else ""))] @
- Goal_Display.pretty_goals_without_context m th
- end |> Pretty.chunks |> Pretty.writeln;
-
-(*Printing can raise exceptions, so the assignment occurs last.
- Can do setstate[(st,Seq.empty)] to set st as the state. *)
-fun setstate newgoals =
- (print_top (pop newgoals); undo_list := newgoals :: !undo_list);
-
-(*Given a proof state transformation, return a command that updates
- the goal stack*)
-fun make_command com = setstate (com (pop (getstate())));
-
-(*Apply a function on proof states to the current goal stack*)
-fun apply_fun f = f (pop(getstate()));
-
-(*Return the top theorem, representing the proof state*)
-fun topthm () = apply_fun (fn ((th,_), _) => th);
-
-(*Return the final result. *)
-fun result () = !curr_mkresult (true, topthm());
-
-(*Return the result UNCHECKED that it equals the goal -- for synthesis,
- answer extraction, or other instantiation of Vars *)
-fun uresult () = !curr_mkresult (false, topthm());
-
-(*Get subgoal i from goal stack*)
-fun getgoal i = Logic.get_goal (prop_of (topthm())) i;
-
-(*Prints exceptions nicely at top level;
- raises the exception in order to have a polymorphic type!*)
-fun print_exn e = (print_sign_exn_unit (Thm.theory_of_thm (topthm())) e; raise e);
-
-(*Which thms could apply to goal i? (debugs tactics involving filter_thms) *)
-fun filter_goal could ths i = filter_thms could (999, getgoal i, ths);
-
-(*For inspecting earlier levels of the backward proof*)
-fun chop_level n (pair,pairs) =
- let val level = length pairs
- in if n<0 andalso ~n <= level
- then List.drop (pair::pairs, ~n)
- else if 0<=n andalso n<= level
- then List.drop (pair::pairs, level - n)
- else error ("Level number must lie between 0 and " ^
- string_of_int level)
- end;
-
-(*Print the given level of the proof; prlev ~1 prints previous level*)
-fun prlev n = apply_fun (print_top o pop o (chop_level n));
-fun pr () = apply_fun print_top;
-
-(*Set goals_limit and print again*)
-fun prlim n = (goals_limit:=n; pr());
-
-(** the goal.... commands
- Read main goal. Set global variables curr_prems, curr_mkresult.
- Initial subgoal and premises are rewritten using rths. **)
-
-(*Version taking the goal as a cterm; if you have a term t and theory thy, use
- goalw_cterm rths (cterm_of thy t); *)
-fun agoalw_cterm atomic rths chorn =
- let val (prems, st0, mkresult) = prepare_proof atomic rths chorn
- in undo_list := [];
- setstate [ (st0, Seq.empty) ];
- curr_prems := prems;
- curr_mkresult := mkresult;
- prems
- end;
-
-val goalw_cterm = agoalw_cterm false;
-
-(*Version taking the goal as a string*)
-fun agoalw atomic thy rths agoal =
- agoalw_cterm atomic rths (cterm_of thy (Syntax.read_prop_global thy agoal))
- handle ERROR msg => cat_error msg (*from type_assign, etc via prepare_proof*)
- ("The error(s) above occurred for " ^ quote agoal);
-
-val goalw = agoalw false;
-fun goal thy = goalw thy [];
-
-(*now the versions that wrap the goal up in `Goal' to make it atomic*)
-fun Goalw thms s = agoalw true (ML_Context.the_global_context ()) thms s;
-val Goal = Goalw [];
-
-(*simple version with minimal amount of checking and postprocessing*)
-fun simple_prove_goal_cterm G f =
- let
- val As = Drule.strip_imp_prems G;
- val B = Drule.strip_imp_concl G;
- val asms = map Assumption.assume As;
- fun check NONE = error "prove_goal: tactic failed"
- | check (SOME (thm, _)) = (case nprems_of thm of
- 0 => thm
- | i => !result_error_fn thm (string_of_int i ^ " unsolved goals!"))
- in
- Drule.export_without_context (implies_intr_list As
- (check (Seq.pull (EVERY (f asms) (Thm.trivial B)))))
- end;
-
-
-(*Proof step "by" the given tactic -- apply tactic to the proof state*)
-fun by_com tac ((th,ths), pairs) : gstack =
- (case Seq.pull(tac th) of
- NONE => error"by: tactic failed"
- | SOME(th2,ths2) =>
- (if Thm.eq_thm(th,th2)
- then warning "Warning: same as previous level"
- else if Thm.eq_thm_thy(th,th2) then ()
- else warning ("Warning: theory of proof state has changed" ^
- thy_error (Thm.theory_of_thm th, Thm.theory_of_thm th2));
- ((th2,ths2)::(th,ths)::pairs)));
-
-fun by tac = cond_timeit (!Output.timing) ""
- (fn() => make_command (by_com tac));
-
-(* byev[tac1,...,tacn] applies tac1 THEN ... THEN tacn.
- Good for debugging proofs involving prove_goal.*)
-val byev = by o EVERY;
-
-
-(*Backtracking means find an alternative result from a tactic.
- If none at this level, try earlier levels*)
-fun backtrack [] = error"back: no alternatives"
- | backtrack ((th,thstr) :: pairs) =
- (case Seq.pull thstr of
- NONE => (writeln"Going back a level..."; backtrack pairs)
- | SOME(th2,thstr2) =>
- (if Thm.eq_thm(th,th2)
- then warning "Warning: same as previous choice at this level"
- else if Thm.eq_thm_thy(th,th2) then ()
- else warning "Warning: theory of proof state has changed";
- (th2,thstr2)::pairs));
-
-fun back() = setstate (backtrack (getstate()));
-
-(*Chop back to previous level of the proof*)
-fun choplev n = make_command (chop_level n);
-
-(*Chopping back the goal stack*)
-fun chop () = make_command (fn (_,pairs) => pairs);
-
-(*Restore the previous proof state; discard current state. *)
-fun undo() = case !undo_list of
- [] => error"No proof state"
- | [_] => error"Already at initial state"
- | _::newundo => (undo_list := newundo; pr()) ;
-
-
-(*** Managing the proof stack ***)
-
-fun save_proof() = Proof(!undo_list, !curr_prems, !curr_mkresult);
-
-fun restore_proof(Proof(ul,prems,mk)) =
- (undo_list:= ul; curr_prems:= prems; curr_mkresult := mk; prems);
-
-
-fun top_proof() = case !proofstack of
- [] => error("Stack of proof attempts is empty!")
- | p::ps => (p,ps);
-
-(* push a copy of the current proof state on to the stack *)
-fun push_proof() = (proofstack := (save_proof() :: !proofstack));
-
-(* discard the top proof state of the stack *)
-fun pop_proof() =
- let val (p,ps) = top_proof()
- val prems = restore_proof p
- in proofstack := ps; pr(); prems end;
-
-(* rotate the stack so that the top element goes to the bottom *)
-fun rotate_proof() =
- let val (p,ps) = top_proof()
- in proofstack := ps@[save_proof()];
- restore_proof p;
- pr();
- !curr_prems
- end;
-
-
-(** theorem bindings **)
-
-fun qed name = ML_Context.ml_store_thm (name, result ());
-fun qed_goal name thy goal tacsf = ML_Context.ml_store_thm (name, prove_goal thy goal tacsf);
-fun qed_goalw name thy rews goal tacsf =
- ML_Context.ml_store_thm (name, prove_goalw thy rews goal tacsf);
-fun qed_spec_mp name =
- ML_Context.ml_store_thm (name, Object_Logic.rulify_no_asm (result ()));
-fun qed_goal_spec_mp name thy s p =
- bind_thm (name, Object_Logic.rulify_no_asm (prove_goal thy s p));
-fun qed_goalw_spec_mp name thy defs s p =
- bind_thm (name, Object_Logic.rulify_no_asm (prove_goalw thy defs s p));
-
-end;
-