(* Title: HOL/Tools/Sledgehammer/sledgehammer_filter.ML
Author: Jia Meng, Cambridge University Computer Laboratory and NICTA
Author: Jasmin Blanchette, TU Muenchen
Sledgehammer's relevance filter.
*)
signature SLEDGEHAMMER_FILTER =
sig
datatype locality = General | Intro | Elim | Simp | Local | Assum | Chained
type relevance_fudge =
{allow_ext : bool,
local_const_multiplier : real,
worse_irrel_freq : real,
higher_order_irrel_weight : real,
abs_rel_weight : real,
abs_irrel_weight : real,
skolem_irrel_weight : real,
theory_const_rel_weight : real,
theory_const_irrel_weight : real,
intro_bonus : real,
elim_bonus : real,
simp_bonus : real,
local_bonus : real,
assum_bonus : real,
chained_bonus : real,
max_imperfect : real,
max_imperfect_exp : real,
threshold_divisor : real,
ridiculous_threshold : real}
type relevance_override =
{add : (Facts.ref * Attrib.src list) list,
del : (Facts.ref * Attrib.src list) list,
only : bool}
val trace : bool Unsynchronized.ref
val fact_from_ref :
Proof.context -> unit Symtab.table -> thm list
-> Facts.ref * Attrib.src list -> ((string * locality) * thm) list
val all_facts :
Proof.context -> 'a Symtab.table -> bool -> relevance_fudge -> thm list
-> thm list -> (((unit -> string) * locality) * (bool * thm)) list
val const_names_in_fact :
theory -> (string * typ -> term list -> bool * term list) -> term
-> string list
val relevant_facts :
Proof.context -> bool -> real * real -> int
-> (string * typ -> term list -> bool * term list) -> relevance_fudge
-> relevance_override -> thm list -> term list -> term
-> ((string * locality) * thm) list
end;
structure Sledgehammer_Filter : SLEDGEHAMMER_FILTER =
struct
open Sledgehammer_Util
val trace = Unsynchronized.ref false
fun trace_msg msg = if !trace then tracing (msg ()) else ()
(* experimental features *)
val respect_no_atp = true
val instantiate_inducts = false
datatype locality = General | Intro | Elim | Simp | Local | Assum | Chained
type relevance_fudge =
{allow_ext : bool,
local_const_multiplier : real,
worse_irrel_freq : real,
higher_order_irrel_weight : real,
abs_rel_weight : real,
abs_irrel_weight : real,
skolem_irrel_weight : real,
theory_const_rel_weight : real,
theory_const_irrel_weight : real,
intro_bonus : real,
elim_bonus : real,
simp_bonus : real,
local_bonus : real,
assum_bonus : real,
chained_bonus : real,
max_imperfect : real,
max_imperfect_exp : real,
threshold_divisor : real,
ridiculous_threshold : real}
type relevance_override =
{add : (Facts.ref * Attrib.src list) list,
del : (Facts.ref * Attrib.src list) list,
only : bool}
val sledgehammer_prefix = "Sledgehammer" ^ Long_Name.separator
val abs_name = sledgehammer_prefix ^ "abs"
val skolem_prefix = sledgehammer_prefix ^ "sko"
val theory_const_suffix = Long_Name.separator ^ " 1"
fun needs_quoting reserved s =
Symtab.defined reserved s orelse
exists (not o Syntax.is_identifier) (Long_Name.explode s)
fun make_name reserved multi j name =
(name |> needs_quoting reserved name ? quote) ^
(if multi then "(" ^ string_of_int j ^ ")" else "")
fun explode_interval _ (Facts.FromTo (i, j)) = i upto j
| explode_interval max (Facts.From i) = i upto i + max - 1
| explode_interval _ (Facts.Single i) = [i]
val backquote =
raw_explode #> map (fn "`" => "\\`" | s => s) #> implode #> enclose "`" "`"
fun fact_from_ref ctxt reserved chained_ths (xthm as (xref, args)) =
let
val ths = Attrib.eval_thms ctxt [xthm]
val bracket =
implode (map (fn arg => "[" ^ Pretty.str_of (Args.pretty_src ctxt arg)
^ "]") args)
fun nth_name j =
case xref of
Facts.Fact s => backquote s ^ bracket
| Facts.Named (("", _), _) => "[" ^ bracket ^ "]"
| Facts.Named ((name, _), NONE) =>
make_name reserved (length ths > 1) (j + 1) name ^ bracket
| Facts.Named ((name, _), SOME intervals) =>
make_name reserved true
(nth (maps (explode_interval (length ths)) intervals) j) name ^
bracket
in
(ths, (0, []))
|-> fold (fn th => fn (j, rest) =>
(j + 1, ((nth_name j,
if member Thm.eq_thm chained_ths th then Chained
else General), th) :: rest))
|> snd
end
(* This is a terrible hack. Free variables are sometimes code as "M__" when they
are displayed as "M" and we want to avoid clashes with these. But sometimes
it's even worse: "Ma__" encodes "M". So we simply reserve all prefixes of all
free variables. In the worse case scenario, where the fact won't be resolved
correctly, the user can fix it manually, e.g., by naming the fact in
question. Ideally we would need nothing of it, but backticks just don't work
with schematic variables. *)
fun all_prefixes_of s =
map (fn i => String.extract (s, 0, SOME i)) (1 upto size s - 1)
fun close_form t =
(t, [] |> Term.add_free_names t |> maps all_prefixes_of)
|> fold (fn ((s, i), T) => fn (t', taken) =>
let val s' = Name.variant taken s in
((if fastype_of t' = HOLogic.boolT then HOLogic.all_const
else Term.all) T
$ Abs (s', T, abstract_over (Var ((s, i), T), t')),
s' :: taken)
end)
(Term.add_vars t [] |> sort_wrt (fst o fst))
|> fst
fun string_for_term ctxt t =
Print_Mode.setmp (filter (curry (op =) Symbol.xsymbolsN)
(print_mode_value ())) (Syntax.string_of_term ctxt) t
|> String.translate (fn c => if Char.isPrint c then str c else "")
|> simplify_spaces
(** Structural induction rules **)
fun struct_induct_rule_on th =
case Logic.strip_horn (prop_of th) of
(prems, @{const Trueprop}
$ ((p as Var ((p_name, 0), _)) $ (a as Var (_, ind_T)))) =>
if not (is_TVar ind_T) andalso length prems > 1 andalso
exists (exists_subterm (curry (op aconv) p)) prems andalso
not (exists (exists_subterm (curry (op aconv) a)) prems) then
SOME (p_name, ind_T)
else
NONE
| _ => NONE
fun instantiate_induct_rule ctxt concl_prop p_name ((name, loc), (multi, th))
ind_x =
let
fun varify_noninducts (t as Free (s, T)) =
if (s, T) = ind_x orelse can dest_funT T then t else Var ((s, 0), T)
| varify_noninducts t = t
val p_inst =
concl_prop |> map_aterms varify_noninducts |> close_form
|> lambda (Free ind_x)
|> string_for_term ctxt
in
((fn () => name () ^ "[where " ^ p_name ^ " = " ^ quote p_inst ^ "]", loc),
(multi, th |> read_instantiate ctxt [((p_name, 0), p_inst)]))
end
fun type_match thy (T1, T2) =
(Sign.typ_match thy (T2, T1) Vartab.empty; true)
handle Type.TYPE_MATCH => false
fun instantiate_if_induct_rule ctxt stmt stmt_xs (ax as (_, (_, th))) =
case struct_induct_rule_on th of
SOME (p_name, ind_T) =>
let val thy = ProofContext.theory_of ctxt in
stmt_xs |> filter (fn (_, T) => type_match thy (T, ind_T))
|> map_filter (try (instantiate_induct_rule ctxt stmt p_name ax))
end
| NONE => [ax]
(***************************************************************)
(* Relevance Filtering *)
(***************************************************************)
(*** constants with types ***)
fun order_of_type (Type (@{type_name fun}, [T1, @{typ bool}])) =
order_of_type T1 (* cheat: pretend sets are first-order *)
| order_of_type (Type (@{type_name fun}, [T1, T2])) =
Int.max (order_of_type T1 + 1, order_of_type T2)
| order_of_type (Type (_, Ts)) = fold (Integer.max o order_of_type) Ts 0
| order_of_type _ = 0
(* An abstraction of Isabelle types and first-order terms *)
datatype pattern = PVar | PApp of string * pattern list
datatype ptype = PType of int * pattern list
fun string_for_pattern PVar = "_"
| string_for_pattern (PApp (s, ps)) =
if null ps then s else s ^ string_for_patterns ps
and string_for_patterns ps = "(" ^ commas (map string_for_pattern ps) ^ ")"
fun string_for_ptype (PType (_, ps)) = string_for_patterns ps
(*Is the second type an instance of the first one?*)
fun match_pattern (PVar, _) = true
| match_pattern (PApp _, PVar) = false
| match_pattern (PApp (s, ps), PApp (t, qs)) =
s = t andalso match_patterns (ps, qs)
and match_patterns (_, []) = true
| match_patterns ([], _) = false
| match_patterns (p :: ps, q :: qs) =
match_pattern (p, q) andalso match_patterns (ps, qs)
fun match_ptype (PType (_, ps), PType (_, qs)) = match_patterns (ps, qs)
(* Is there a unifiable constant? *)
fun pconst_mem f consts (s, ps) =
exists (curry (match_ptype o f) ps)
(map snd (filter (curry (op =) s o fst) consts))
fun pconst_hyper_mem f const_tab (s, ps) =
exists (curry (match_ptype o f) ps) (these (Symtab.lookup const_tab s))
fun pattern_for_type (Type (s, Ts)) = PApp (s, map pattern_for_type Ts)
| pattern_for_type (TFree (s, _)) = PApp (s, [])
| pattern_for_type (TVar _) = PVar
(* Pairs a constant with the list of its type instantiations. *)
fun ptype thy const x =
(if const then map pattern_for_type (these (try (Sign.const_typargs thy) x))
else [])
fun rich_ptype thy const (s, T) =
PType (order_of_type T, ptype thy const (s, T))
fun rich_pconst thy const (s, T) = (s, rich_ptype thy const (s, T))
fun string_for_hyper_pconst (s, ps) =
s ^ "{" ^ commas (map string_for_ptype ps) ^ "}"
(* Add a pconstant to the table, but a [] entry means a standard
connective, which we ignore.*)
fun add_pconst_to_table also_skolem (s, p) =
if (not also_skolem andalso String.isPrefix skolem_prefix s) then I
else Symtab.map_default (s, [p]) (insert (op =) p)
fun pconsts_in_terms thy is_built_in_const also_skolems pos ts =
let
val flip = Option.map not
(* We include free variables, as well as constants, to handle locales. For
each quantifiers that must necessarily be skolemized by the automatic
prover, we introduce a fresh constant to simulate the effect of
Skolemization. *)
fun do_const const x ts =
let val (built_in, ts) = is_built_in_const x ts in
(not built_in
? add_pconst_to_table also_skolems (rich_pconst thy const x))
#> fold do_term ts
end
and do_term t =
case strip_comb t of
(Const x, ts) => do_const true x ts
| (Free x, ts) => do_const false x ts
| (Abs (_, T, t'), ts) =>
(null ts
? add_pconst_to_table true (abs_name, PType (order_of_type T + 1, [])))
#> fold do_term (t' :: ts)
| (_, ts) => fold do_term ts
fun do_quantifier will_surely_be_skolemized abs_T body_t =
do_formula pos body_t
#> (if also_skolems andalso will_surely_be_skolemized then
add_pconst_to_table true
(gensym skolem_prefix, PType (order_of_type abs_T, []))
else
I)
and do_term_or_formula T =
if T = HOLogic.boolT then do_formula NONE else do_term
and do_formula pos t =
case t of
Const (@{const_name all}, _) $ Abs (_, T, t') =>
do_quantifier (pos = SOME false) T t'
| @{const "==>"} $ t1 $ t2 =>
do_formula (flip pos) t1 #> do_formula pos t2
| Const (@{const_name "=="}, Type (_, [T, _])) $ t1 $ t2 =>
fold (do_term_or_formula T) [t1, t2]
| @{const Trueprop} $ t1 => do_formula pos t1
| @{const False} => I
| @{const True} => I
| @{const Not} $ t1 => do_formula (flip pos) t1
| Const (@{const_name All}, _) $ Abs (_, T, t') =>
do_quantifier (pos = SOME false) T t'
| Const (@{const_name Ex}, _) $ Abs (_, T, t') =>
do_quantifier (pos = SOME true) T t'
| @{const HOL.conj} $ t1 $ t2 => fold (do_formula pos) [t1, t2]
| @{const HOL.disj} $ t1 $ t2 => fold (do_formula pos) [t1, t2]
| @{const HOL.implies} $ t1 $ t2 =>
do_formula (flip pos) t1 #> do_formula pos t2
| Const (@{const_name HOL.eq}, Type (_, [T, _])) $ t1 $ t2 =>
fold (do_term_or_formula T) [t1, t2]
| Const (@{const_name If}, Type (_, [_, Type (_, [T, _])]))
$ t1 $ t2 $ t3 =>
do_formula NONE t1 #> fold (do_term_or_formula T) [t2, t3]
| Const (@{const_name Ex1}, _) $ Abs (_, T, t') =>
do_quantifier (is_some pos) T t'
| Const (@{const_name Ball}, _) $ t1 $ Abs (_, T, t') =>
do_quantifier (pos = SOME false) T
(HOLogic.mk_imp (incr_boundvars 1 t1 $ Bound 0, t'))
| Const (@{const_name Bex}, _) $ t1 $ Abs (_, T, t') =>
do_quantifier (pos = SOME true) T
(HOLogic.mk_conj (incr_boundvars 1 t1 $ Bound 0, t'))
| (t0 as Const (_, @{typ bool})) $ t1 =>
do_term t0 #> do_formula pos t1 (* theory constant *)
| _ => do_term t
in Symtab.empty |> fold (do_formula pos) ts end
(*Inserts a dummy "constant" referring to the theory name, so that relevance
takes the given theory into account.*)
fun theory_constify ({theory_const_rel_weight, theory_const_irrel_weight, ...}
: relevance_fudge) thy_name t =
if exists (curry (op <) 0.0) [theory_const_rel_weight,
theory_const_irrel_weight] then
Const (thy_name ^ theory_const_suffix, @{typ bool}) $ t
else
t
fun theory_const_prop_of fudge th =
theory_constify fudge (Context.theory_name (theory_of_thm th)) (prop_of th)
(**** Constant / Type Frequencies ****)
(* A two-dimensional symbol table counts frequencies of constants. It's keyed
first by constant name and second by its list of type instantiations. For the
latter, we need a linear ordering on "pattern list". *)
fun pattern_ord p =
case p of
(PVar, PVar) => EQUAL
| (PVar, PApp _) => LESS
| (PApp _, PVar) => GREATER
| (PApp q1, PApp q2) =>
prod_ord fast_string_ord (dict_ord pattern_ord) (q1, q2)
fun ptype_ord (PType p, PType q) =
prod_ord (dict_ord pattern_ord) int_ord (swap p, swap q)
structure PType_Tab = Table(type key = ptype val ord = ptype_ord)
fun count_fact_consts thy fudge =
let
fun do_const const (s, T) ts =
(* Two-dimensional table update. Constant maps to types maps to count. *)
PType_Tab.map_default (rich_ptype thy const (s, T), 0) (Integer.add 1)
|> Symtab.map_default (s, PType_Tab.empty)
#> fold do_term ts
and do_term t =
case strip_comb t of
(Const x, ts) => do_const true x ts
| (Free x, ts) => do_const false x ts
| (Abs (_, _, t'), ts) => fold do_term (t' :: ts)
| (_, ts) => fold do_term ts
in do_term o theory_const_prop_of fudge o snd end
(**** Actual Filtering Code ****)
fun pow_int _ 0 = 1.0
| pow_int x 1 = x
| pow_int x n = if n > 0 then x * pow_int x (n - 1) else pow_int x (n + 1) / x
(*The frequency of a constant is the sum of those of all instances of its type.*)
fun pconst_freq match const_tab (c, ps) =
PType_Tab.fold (fn (qs, m) => match (ps, qs) ? Integer.add m)
(the (Symtab.lookup const_tab c)) 0
(* A surprising number of theorems contain only a few significant constants.
These include all induction rules, and other general theorems. *)
(* "log" seems best in practice. A constant function of one ignores the constant
frequencies. Rare constants give more points if they are relevant than less
rare ones. *)
fun rel_weight_for _ freq = 1.0 + 2.0 / Math.ln (Real.fromInt freq + 1.0)
(* Irrelevant constants are treated differently. We associate lower penalties to
very rare constants and very common ones -- the former because they can't
lead to the inclusion of too many new facts, and the latter because they are
so common as to be of little interest. *)
fun irrel_weight_for ({worse_irrel_freq, higher_order_irrel_weight, ...}
: relevance_fudge) order freq =
let val (k, x) = worse_irrel_freq |> `Real.ceil in
(if freq < k then Math.ln (Real.fromInt (freq + 1)) / Math.ln x
else rel_weight_for order freq / rel_weight_for order k)
* pow_int higher_order_irrel_weight (order - 1)
end
fun multiplier_for_const_name local_const_multiplier s =
if String.isSubstring "." s then 1.0 else local_const_multiplier
(* Computes a constant's weight, as determined by its frequency. *)
fun generic_pconst_weight local_const_multiplier abs_weight skolem_weight
theory_const_weight weight_for f const_tab
(c as (s, PType (m, _))) =
if s = abs_name then
abs_weight
else if String.isPrefix skolem_prefix s then
skolem_weight
else if String.isSuffix theory_const_suffix s then
theory_const_weight
else
multiplier_for_const_name local_const_multiplier s
* weight_for m (pconst_freq (match_ptype o f) const_tab c)
fun rel_pconst_weight ({local_const_multiplier, abs_rel_weight,
theory_const_rel_weight, ...} : relevance_fudge)
const_tab =
generic_pconst_weight local_const_multiplier abs_rel_weight 0.0
theory_const_rel_weight rel_weight_for I const_tab
fun irrel_pconst_weight (fudge as {local_const_multiplier, abs_irrel_weight,
skolem_irrel_weight,
theory_const_irrel_weight, ...}) const_tab =
generic_pconst_weight local_const_multiplier abs_irrel_weight
skolem_irrel_weight theory_const_irrel_weight
(irrel_weight_for fudge) swap const_tab
fun locality_bonus (_ : relevance_fudge) General = 0.0
| locality_bonus {intro_bonus, ...} Intro = intro_bonus
| locality_bonus {elim_bonus, ...} Elim = elim_bonus
| locality_bonus {simp_bonus, ...} Simp = simp_bonus
| locality_bonus {local_bonus, ...} Local = local_bonus
| locality_bonus {assum_bonus, ...} Assum = assum_bonus
| locality_bonus {chained_bonus, ...} Chained = chained_bonus
fun is_odd_const_name s =
s = abs_name orelse String.isPrefix skolem_prefix s orelse
String.isSuffix theory_const_suffix s
fun fact_weight fudge loc const_tab relevant_consts fact_consts =
case fact_consts |> List.partition (pconst_hyper_mem I relevant_consts)
||> filter_out (pconst_hyper_mem swap relevant_consts) of
([], _) => 0.0
| (rel, irrel) =>
if forall (forall (is_odd_const_name o fst)) [rel, irrel] then
0.0
else
let
val irrel = irrel |> filter_out (pconst_mem swap rel)
val rel_weight =
0.0 |> fold (curry (op +) o rel_pconst_weight fudge const_tab) rel
val irrel_weight =
~ (locality_bonus fudge loc)
|> fold (curry (op +) o irrel_pconst_weight fudge const_tab) irrel
val res = rel_weight / (rel_weight + irrel_weight)
in if Real.isFinite res then res else 0.0 end
fun pconsts_in_fact thy is_built_in_const t =
Symtab.fold (fn (s, pss) => fold (cons o pair s) pss)
(pconsts_in_terms thy is_built_in_const true (SOME true) [t]) []
fun pair_consts_fact thy is_built_in_const fudge fact =
case fact |> snd |> theory_const_prop_of fudge
|> pconsts_in_fact thy is_built_in_const of
[] => NONE
| consts => SOME ((fact, consts), NONE)
val const_names_in_fact = map fst ooo pconsts_in_fact
type annotated_thm =
(((unit -> string) * locality) * thm) * (string * ptype) list
fun take_most_relevant max_relevant remaining_max
({max_imperfect, max_imperfect_exp, ...} : relevance_fudge)
(candidates : (annotated_thm * real) list) =
let
val max_imperfect =
Real.ceil (Math.pow (max_imperfect,
Math.pow (Real.fromInt remaining_max
/ Real.fromInt max_relevant, max_imperfect_exp)))
val (perfect, imperfect) =
candidates |> sort (Real.compare o swap o pairself snd)
|> take_prefix (fn (_, w) => w > 0.99999)
val ((accepts, more_rejects), rejects) =
chop max_imperfect imperfect |>> append perfect |>> chop remaining_max
in
trace_msg (fn () =>
"Actually passed (" ^ string_of_int (length accepts) ^ " of " ^
string_of_int (length candidates) ^ "): " ^
(accepts |> map (fn ((((name, _), _), _), weight) =>
name () ^ " [" ^ Real.toString weight ^ "]")
|> commas));
(accepts, more_rejects @ rejects)
end
fun if_empty_replace_with_locality thy is_built_in_const facts loc tab =
if Symtab.is_empty tab then
pconsts_in_terms thy is_built_in_const false (SOME false)
(map_filter (fn ((_, loc'), th) =>
if loc' = loc then SOME (prop_of th) else NONE) facts)
else
tab
fun add_arities is_built_in_const th =
let
fun aux _ _ NONE = NONE
| aux t args (SOME tab) =
case t of
t1 $ t2 => SOME tab |> aux t1 (t2 :: args) |> aux t2 []
| Const (x as (s, _)) =>
(if is_built_in_const x args |> fst then
SOME tab
else case Symtab.lookup tab s of
NONE => SOME (Symtab.update (s, length args) tab)
| SOME n => if n = length args then SOME tab else NONE)
| _ => SOME tab
in aux (prop_of th) [] end
fun needs_ext is_built_in_const facts =
fold (add_arities is_built_in_const o snd) facts (SOME Symtab.empty)
|> is_none
fun relevance_filter ctxt threshold0 decay max_relevant is_built_in_const
(fudge as {threshold_divisor, ridiculous_threshold, ...})
({add, del, ...} : relevance_override) facts goal_ts =
let
val thy = ProofContext.theory_of ctxt
val const_tab = fold (count_fact_consts thy fudge) facts Symtab.empty
val goal_const_tab =
pconsts_in_terms thy is_built_in_const false (SOME false) goal_ts
|> fold (if_empty_replace_with_locality thy is_built_in_const facts)
[Chained, Assum, Local]
val add_ths = Attrib.eval_thms ctxt add
val del_ths = Attrib.eval_thms ctxt del
val facts = facts |> filter_out (member Thm.eq_thm del_ths o snd)
fun iter j remaining_max threshold rel_const_tab hopeless hopeful =
let
fun relevant [] _ [] =
(* Nothing has been added this iteration. *)
if j = 0 andalso threshold >= ridiculous_threshold then
(* First iteration? Try again. *)
iter 0 max_relevant (threshold / threshold_divisor) rel_const_tab
hopeless hopeful
else
[]
| relevant candidates rejects [] =
let
val (accepts, more_rejects) =
take_most_relevant max_relevant remaining_max fudge candidates
val rel_const_tab' =
rel_const_tab
|> fold (add_pconst_to_table false) (maps (snd o fst) accepts)
fun is_dirty (c, _) =
Symtab.lookup rel_const_tab' c <> Symtab.lookup rel_const_tab c
val (hopeful_rejects, hopeless_rejects) =
(rejects @ hopeless, ([], []))
|-> fold (fn (ax as (_, consts), old_weight) =>
if exists is_dirty consts then
apfst (cons (ax, NONE))
else
apsnd (cons (ax, old_weight)))
|>> append (more_rejects
|> map (fn (ax as (_, consts), old_weight) =>
(ax, if exists is_dirty consts then NONE
else SOME old_weight)))
val threshold =
1.0 - (1.0 - threshold)
* Math.pow (decay, Real.fromInt (length accepts))
val remaining_max = remaining_max - length accepts
in
trace_msg (fn () => "New or updated constants: " ^
commas (rel_const_tab' |> Symtab.dest
|> subtract (op =) (rel_const_tab |> Symtab.dest)
|> map string_for_hyper_pconst));
map (fst o fst) accepts @
(if remaining_max = 0 then
[]
else
iter (j + 1) remaining_max threshold rel_const_tab'
hopeless_rejects hopeful_rejects)
end
| relevant candidates rejects
(((ax as (((_, loc), _), fact_consts)), cached_weight)
:: hopeful) =
let
val weight =
case cached_weight of
SOME w => w
| NONE => fact_weight fudge loc const_tab rel_const_tab
fact_consts
in
if weight >= threshold then
relevant ((ax, weight) :: candidates) rejects hopeful
else
relevant candidates ((ax, weight) :: rejects) hopeful
end
in
trace_msg (fn () =>
"ITERATION " ^ string_of_int j ^ ": current threshold: " ^
Real.toString threshold ^ ", constants: " ^
commas (rel_const_tab |> Symtab.dest
|> filter (curry (op <>) [] o snd)
|> map string_for_hyper_pconst));
relevant [] [] hopeful
end
fun add_facts ths accepts =
(facts |> filter (member Thm.eq_thm ths o snd)) @
(accepts |> filter_out (member Thm.eq_thm ths o snd))
|> take max_relevant
in
facts |> map_filter (pair_consts_fact thy is_built_in_const fudge)
|> iter 0 max_relevant threshold0 goal_const_tab []
|> not (null add_ths) ? add_facts add_ths
|> (fn accepts =>
accepts |> needs_ext is_built_in_const accepts
? add_facts @{thms ext})
|> tap (fn accepts => trace_msg (fn () =>
"Total relevant: " ^ string_of_int (length accepts)))
end
(***************************************************************)
(* Retrieving and filtering lemmas *)
(***************************************************************)
(*** retrieve lemmas and filter them ***)
(*Reject theorems with names like "List.filter.filter_list_def" or
"Accessible_Part.acc.defs", as these are definitions arising from packages.*)
fun is_package_def a =
let val names = Long_Name.explode a in
(length names > 2 andalso not (hd names = "local") andalso
String.isSuffix "_def" a) orelse String.isSuffix "_defs" a
end
fun mk_fact_table f xs =
fold (Termtab.update o `(prop_of o f)) xs Termtab.empty
fun uniquify xs = Termtab.fold (cons o snd) (mk_fact_table snd xs) []
(* FIXME: put other record thms here, or declare as "no_atp" *)
val multi_base_blacklist =
["defs", "select_defs", "update_defs", "split", "splits", "split_asm",
"cases", "ext_cases", "eq.simps", "eq.refl", "nchotomy", "case_cong",
"weak_case_cong"]
|> not instantiate_inducts ? append ["induct", "inducts"]
|> map (prefix ".")
val max_lambda_nesting = 3
fun term_has_too_many_lambdas max (t1 $ t2) =
exists (term_has_too_many_lambdas max) [t1, t2]
| term_has_too_many_lambdas max (Abs (_, _, t)) =
max = 0 orelse term_has_too_many_lambdas (max - 1) t
| term_has_too_many_lambdas _ _ = false
(* Don't count nested lambdas at the level of formulas, since they are
quantifiers. *)
fun formula_has_too_many_lambdas Ts (Abs (_, T, t)) =
formula_has_too_many_lambdas (T :: Ts) t
| formula_has_too_many_lambdas Ts t =
if member (op =) [HOLogic.boolT, propT] (fastype_of1 (Ts, t)) then
exists (formula_has_too_many_lambdas Ts) (#2 (strip_comb t))
else
term_has_too_many_lambdas max_lambda_nesting t
(* The max apply depth of any "metis" call in "Metis_Examples" (on 2007-10-31)
was 11. *)
val max_apply_depth = 15
fun apply_depth (f $ t) = Int.max (apply_depth f, apply_depth t + 1)
| apply_depth (Abs (_, _, t)) = apply_depth t
| apply_depth _ = 0
fun is_formula_too_complex t =
apply_depth t > max_apply_depth orelse formula_has_too_many_lambdas [] t
(* FIXME: Extend to "Meson" and "Metis" *)
val exists_sledgehammer_const =
exists_Const (fn (s, _) => String.isPrefix sledgehammer_prefix s)
(* FIXME: make more reliable *)
val exists_low_level_class_const =
exists_Const (fn (s, _) =>
String.isSubstring (Long_Name.separator ^ "class" ^ Long_Name.separator) s)
fun is_metastrange_theorem th =
case head_of (concl_of th) of
Const (a, _) => (a <> @{const_name Trueprop} andalso
a <> @{const_name "=="})
| _ => false
fun is_that_fact th =
String.isSuffix (Long_Name.separator ^ Obtain.thatN) (Thm.get_name_hint th)
andalso exists_subterm (fn Free (s, _) => s = Name.skolem Auto_Bind.thesisN
| _ => false) (prop_of th)
val type_has_top_sort =
exists_subtype (fn TFree (_, []) => true | TVar (_, []) => true | _ => false)
(**** Predicates to detect unwanted facts (prolific or likely to cause
unsoundness) ****)
(* Too general means, positive equality literal with a variable X as one
operand, when X does not occur properly in the other operand. This rules out
clearly inconsistent facts such as X = a | X = b, though it by no means
guarantees soundness. *)
(* Unwanted equalities are those between a (bound or schematic) variable that
does not properly occur in the second operand. *)
val is_exhaustive_finite =
let
fun is_bad_equal (Var z) t =
not (exists_subterm (fn Var z' => z = z' | _ => false) t)
| is_bad_equal (Bound j) t = not (loose_bvar1 (t, j))
| is_bad_equal _ _ = false
fun do_equals t1 t2 = is_bad_equal t1 t2 orelse is_bad_equal t2 t1
fun do_formula pos t =
case (pos, t) of
(_, @{const Trueprop} $ t1) => do_formula pos t1
| (true, Const (@{const_name all}, _) $ Abs (_, _, t')) =>
do_formula pos t'
| (true, Const (@{const_name All}, _) $ Abs (_, _, t')) =>
do_formula pos t'
| (false, Const (@{const_name Ex}, _) $ Abs (_, _, t')) =>
do_formula pos t'
| (_, @{const "==>"} $ t1 $ t2) =>
do_formula (not pos) t1 andalso
(t2 = @{prop False} orelse do_formula pos t2)
| (_, @{const HOL.implies} $ t1 $ t2) =>
do_formula (not pos) t1 andalso
(t2 = @{const False} orelse do_formula pos t2)
| (_, @{const Not} $ t1) => do_formula (not pos) t1
| (true, @{const HOL.disj} $ t1 $ t2) => forall (do_formula pos) [t1, t2]
| (false, @{const HOL.conj} $ t1 $ t2) => forall (do_formula pos) [t1, t2]
| (true, Const (@{const_name HOL.eq}, _) $ t1 $ t2) => do_equals t1 t2
| (true, Const (@{const_name "=="}, _) $ t1 $ t2) => do_equals t1 t2
| _ => false
in do_formula true end
fun has_bound_or_var_of_type tycons =
exists_subterm (fn Var (_, Type (s, _)) => member (op =) tycons s
| Abs (_, Type (s, _), _) => member (op =) tycons s
| _ => false)
(* Facts are forbidden to contain variables of these types. The typical reason
is that they lead to unsoundness. Note that "unit" satisfies numerous
equations like "?x = ()". The resulting clauses will have no type constraint,
yielding false proofs. Even "bool" leads to many unsound proofs, though only
for higher-order problems. *)
val dangerous_types = [@{type_name unit}, @{type_name bool}, @{type_name prop}];
(* Facts containing variables of type "unit" or "bool" or of the form
"ALL x. x = A | x = B | x = C" are likely to lead to unsound proofs if types
are omitted. *)
fun is_dangerous_term no_dangerous_types t =
not no_dangerous_types andalso
let val t = transform_elim_term t in
has_bound_or_var_of_type dangerous_types t orelse
is_exhaustive_finite t
end
fun is_theorem_bad_for_atps no_dangerous_types thm =
let val t = prop_of thm in
is_formula_too_complex t orelse exists_type type_has_top_sort t orelse
is_dangerous_term no_dangerous_types t orelse
exists_sledgehammer_const t orelse exists_low_level_class_const t orelse
is_metastrange_theorem thm orelse is_that_fact thm
end
fun clasimpset_rules_of ctxt =
let
val {safeIs, safeEs, hazIs, hazEs, ...} = ctxt |> claset_of |> rep_cs
val intros = safeIs @ hazIs
val elims = map Classical.classical_rule (safeEs @ hazEs)
val simps = ctxt |> simpset_of |> dest_ss |> #simps |> map snd
in (mk_fact_table I intros, mk_fact_table I elims, mk_fact_table I simps) end
fun all_facts ctxt reserved no_dangerous_types
({intro_bonus, elim_bonus, simp_bonus, ...} : relevance_fudge)
add_ths chained_ths =
let
val thy = ProofContext.theory_of ctxt
val global_facts = Global_Theory.facts_of thy
val local_facts = ProofContext.facts_of ctxt
val named_locals = local_facts |> Facts.dest_static []
val assms = Assumption.all_assms_of ctxt
fun is_assum th = exists (fn ct => prop_of th aconv term_of ct) assms
val is_chained = member Thm.eq_thm chained_ths
val (intros, elims, simps) =
if exists (curry (op <) 0.0) [intro_bonus, elim_bonus, simp_bonus] then
clasimpset_rules_of ctxt
else
(Termtab.empty, Termtab.empty, Termtab.empty)
fun is_good_unnamed_local th =
not (Thm.has_name_hint th) andalso
forall (fn (_, ths) => not (member Thm.eq_thm ths th)) named_locals
val unnamed_locals =
union Thm.eq_thm (Facts.props local_facts) chained_ths
|> filter is_good_unnamed_local |> map (pair "" o single)
val full_space =
Name_Space.merge (Facts.space_of global_facts, Facts.space_of local_facts)
fun add_facts global foldx facts =
foldx (fn (name0, ths) =>
if name0 <> "" andalso
forall (not o member Thm.eq_thm add_ths) ths andalso
(Facts.is_concealed facts name0 orelse
(respect_no_atp andalso is_package_def name0) orelse
exists (fn s => String.isSuffix s name0) multi_base_blacklist orelse
String.isSuffix "_def_raw" (* FIXME: crude hack *) name0) then
I
else
let
val multi = length ths > 1
val backquote_thm =
backquote o string_for_term ctxt o close_form o prop_of
fun check_thms a =
case try (ProofContext.get_thms ctxt) a of
NONE => false
| SOME ths' => Thm.eq_thms (ths, ths')
in
pair 1
#> fold (fn th => fn (j, rest) =>
(j + 1,
if is_theorem_bad_for_atps no_dangerous_types th andalso
not (member Thm.eq_thm add_ths th) then
rest
else
(((fn () =>
if name0 = "" then
th |> backquote_thm
else
let
val name1 = Facts.extern facts name0
val name2 = Name_Space.extern full_space name0
in
case find_first check_thms [name1, name2, name0] of
SOME name => make_name reserved multi j name
| NONE => ""
end),
let val t = prop_of th in
if is_chained th then
Chained
else if global then
if Termtab.defined intros t then Intro
else if Termtab.defined elims t then Elim
else if Termtab.defined simps t then Simp
else General
else
if is_assum th then Assum else Local
end),
(multi, th)) :: rest)) ths
#> snd
end)
in
[] |> add_facts false fold local_facts (unnamed_locals @ named_locals)
|> add_facts true Facts.fold_static global_facts global_facts
end
(* The single-name theorems go after the multiple-name ones, so that single
names are preferred when both are available. *)
fun rearrange_facts ctxt respect_no_atp =
List.partition (fst o snd) #> op @ #> map (apsnd snd)
#> respect_no_atp ? filter_out (No_ATPs.member ctxt o snd)
fun external_frees t =
[] |> Term.add_frees t |> filter_out (can Name.dest_internal o fst)
fun relevant_facts ctxt no_dangerous_types (threshold0, threshold1)
max_relevant is_built_in_const fudge
(override as {add, only, ...}) chained_ths hyp_ts concl_t =
let
val thy = ProofContext.theory_of ctxt
val decay = Math.pow ((1.0 - threshold1) / (1.0 - threshold0),
1.0 / Real.fromInt (max_relevant + 1))
val add_ths = Attrib.eval_thms ctxt add
val reserved = reserved_isar_keyword_table ()
val ind_stmt =
Logic.list_implies (hyp_ts |> filter_out (null o external_frees), concl_t)
|> Object_Logic.atomize_term thy
val ind_stmt_xs = external_frees ind_stmt
val facts =
(if only then
maps (map (fn ((name, loc), th) => ((K name, loc), (true, th)))
o fact_from_ref ctxt reserved chained_ths) add
else
all_facts ctxt reserved no_dangerous_types fudge add_ths chained_ths)
|> instantiate_inducts
? maps (instantiate_if_induct_rule ctxt ind_stmt ind_stmt_xs)
|> rearrange_facts ctxt (respect_no_atp andalso not only)
|> uniquify
in
trace_msg (fn () => "Considering " ^ string_of_int (length facts) ^
" facts");
(if only orelse threshold1 < 0.0 then
facts
else if threshold0 > 1.0 orelse threshold0 > threshold1 orelse
max_relevant = 0 then
[]
else
((concl_t |> theory_constify fudge (Context.theory_name thy)) :: hyp_ts)
|> relevance_filter ctxt threshold0 decay max_relevant is_built_in_const
fudge override facts)
|> map (apfst (apfst (fn f => f ())))
end
end;