(* Title: HOL/Tools/Sledgehammer/sledgehammer_atp_reconstruct.ML
Author: Lawrence C. Paulson, Cambridge University Computer Laboratory
Author: Claire Quigley, Cambridge University Computer Laboratory
Author: Jasmin Blanchette, TU Muenchen
Proof reconstruction for Sledgehammer.
*)
signature SLEDGEHAMMER_ATP_RECONSTRUCT =
sig
type 'a proof = 'a ATP_Proof.proof
type locality = Sledgehammer_Filter.locality
type type_system = Sledgehammer_ATP_Translate.type_system
type minimize_command = string list -> string
type metis_params =
string * minimize_command * type_system * string proof * int
* (string * locality) list vector * int list * thm * int
type isar_params =
Proof.context * bool * int * string Symtab.table * int list list
* int Symtab.table
type text_result = string * (string * locality) list
val repair_conjecture_shape_and_fact_names :
type_system -> string -> int list list -> int
-> (string * locality) list vector -> int list
-> int list list * int * (string * locality) list vector * int list
val used_facts_in_atp_proof :
type_system -> int -> (string * locality) list vector -> string proof
-> (string * locality) list
val used_facts_in_unsound_atp_proof :
type_system -> int list list -> int -> (string * locality) list vector
-> string proof -> string list option
val apply_on_subgoal : string -> int -> int -> string
val command_call : string -> string list -> string
val try_command_line : string -> string -> string
val minimize_line : ('a list -> string) -> 'a list -> string
val split_used_facts :
(string * locality) list
-> (string * locality) list * (string * locality) list
val metis_proof_text : metis_params -> text_result
val isar_proof_text : isar_params -> metis_params -> text_result
val proof_text : bool -> isar_params -> metis_params -> text_result
end;
structure Sledgehammer_ATP_Reconstruct : SLEDGEHAMMER_ATP_RECONSTRUCT =
struct
open ATP_Problem
open ATP_Proof
open Metis_Translate
open Sledgehammer_Util
open Sledgehammer_Filter
open Sledgehammer_ATP_Translate
type minimize_command = string list -> string
type metis_params =
string * minimize_command * type_system * string proof * int
* (string * locality) list vector * int list * thm * int
type isar_params =
Proof.context * bool * int * string Symtab.table * int list list
* int Symtab.table
type text_result = string * (string * locality) list
fun is_head_digit s = Char.isDigit (String.sub (s, 0))
val scan_integer = Scan.many1 is_head_digit >> (the o Int.fromString o implode)
val is_typed_helper_name =
String.isPrefix helper_prefix andf String.isSuffix typed_helper_suffix
fun find_first_in_list_vector vec key =
Vector.foldl (fn (ps, NONE) => AList.lookup (op =) ps key
| (_, value) => value) NONE vec
(** SPASS's Flotter hack **)
(* This is a hack required for keeping track of facts after they have been
clausified by SPASS's Flotter tool. The "ATP/scripts/spass" script is also
part of this hack. *)
val set_ClauseFormulaRelationN = "set_ClauseFormulaRelation"
fun extract_clause_sequence output =
let
val tokens_of = String.tokens (not o Char.isAlphaNum)
fun extract_num ("clause" :: (ss as _ :: _)) = Int.fromString (List.last ss)
| extract_num _ = NONE
in output |> split_lines |> map_filter (extract_num o tokens_of) end
val parse_clause_formula_pair =
$$ "(" |-- scan_integer --| $$ ","
-- (Symbol.scan_id ::: Scan.repeat ($$ "," |-- Symbol.scan_id)) --| $$ ")"
--| Scan.option ($$ ",")
val parse_clause_formula_relation =
Scan.this_string set_ClauseFormulaRelationN |-- $$ "("
|-- Scan.repeat parse_clause_formula_pair
val extract_clause_formula_relation =
Substring.full #> Substring.position set_ClauseFormulaRelationN
#> snd #> Substring.position "." #> fst #> Substring.string
#> raw_explode #> filter_out Symbol.is_blank #> parse_clause_formula_relation
#> fst
fun maybe_unprefix_fact_number type_sys =
polymorphism_of_type_sys type_sys <> Polymorphic
? (space_implode "_" o tl o space_explode "_")
fun repair_conjecture_shape_and_fact_names type_sys output conjecture_shape
fact_offset fact_names typed_helpers =
if String.isSubstring set_ClauseFormulaRelationN output then
let
val j0 = hd (hd conjecture_shape)
val seq = extract_clause_sequence output
val name_map = extract_clause_formula_relation output
fun renumber_conjecture j =
conjecture_prefix ^ string_of_int (j - j0)
|> AList.find (fn (s, ss) => member (op =) ss s) name_map
|> map (fn s => find_index (curry (op =) s) seq + 1)
fun names_for_number j =
j |> AList.lookup (op =) name_map |> these
|> map_filter (try (unascii_of o maybe_unprefix_fact_number type_sys
o unprefix fact_prefix))
|> map (fn name =>
(name, name |> find_first_in_list_vector fact_names |> the)
handle Option.Option =>
error ("No such fact: " ^ quote name ^ "."))
in
(conjecture_shape |> map (maps renumber_conjecture), 0,
seq |> map names_for_number |> Vector.fromList,
name_map |> filter (forall is_typed_helper_name o snd) |> map fst)
end
else
(conjecture_shape, fact_offset, fact_names, typed_helpers)
val vampire_step_prefix = "f" (* grrr... *)
val extract_step_number =
Int.fromString o perhaps (try (unprefix vampire_step_prefix))
fun resolve_fact type_sys _ fact_names (_, SOME s) =
(case try (unprefix fact_prefix) s of
SOME s' =>
let val s' = s' |> maybe_unprefix_fact_number type_sys |> unascii_of in
case find_first_in_list_vector fact_names s' of
SOME x => [(s', x)]
| NONE => []
end
| NONE => [])
| resolve_fact _ facts_offset fact_names (num, NONE) =
(case extract_step_number num of
SOME j =>
let val j = j - facts_offset in
if j > 0 andalso j <= Vector.length fact_names then
Vector.sub (fact_names, j - 1)
else
[]
end
| NONE => [])
fun is_fact type_sys conjecture_shape =
not o null o resolve_fact type_sys 0 conjecture_shape
fun resolve_conjecture _ (_, SOME s) =
(case try (unprefix conjecture_prefix) s of
SOME s' =>
(case Int.fromString s' of
SOME j => [j]
| NONE => [])
| NONE => [])
| resolve_conjecture conjecture_shape (num, NONE) =
case extract_step_number num of
SOME i => (case find_index (exists (curry (op =) i)) conjecture_shape of
~1 => []
| j => [j])
| NONE => []
fun is_conjecture conjecture_shape =
not o null o resolve_conjecture conjecture_shape
fun is_typed_helper _ (_, SOME s) = is_typed_helper_name s
| is_typed_helper typed_helpers (num, NONE) =
(case extract_step_number num of
SOME i => member (op =) typed_helpers i
| NONE => false)
fun add_fact type_sys facts_offset fact_names (Inference (name, _, [])) =
append (resolve_fact type_sys facts_offset fact_names name)
| add_fact _ _ _ _ = I
fun used_facts_in_atp_proof type_sys facts_offset fact_names atp_proof =
if null atp_proof then Vector.foldl (op @) [] fact_names
else fold (add_fact type_sys facts_offset fact_names) atp_proof []
fun is_conjecture_referred_to_in_proof conjecture_shape =
exists (fn Inference (name, _, []) => is_conjecture conjecture_shape name
| _ => false)
fun used_facts_in_unsound_atp_proof type_sys conjecture_shape facts_offset
fact_names atp_proof =
let
val used_facts = used_facts_in_atp_proof type_sys facts_offset fact_names
atp_proof
in
if forall (is_locality_global o snd) used_facts andalso
not (is_conjecture_referred_to_in_proof conjecture_shape atp_proof) then
SOME (map fst used_facts)
else
NONE
end
(** Soft-core proof reconstruction: Metis one-liner **)
fun string_for_label (s, num) = s ^ string_of_int num
fun set_settings "" = ""
| set_settings settings = "using [[" ^ settings ^ "]] "
fun apply_on_subgoal settings _ 1 = set_settings settings ^ "by "
| apply_on_subgoal settings 1 _ = set_settings settings ^ "apply "
| apply_on_subgoal settings i n =
"prefer " ^ string_of_int i ^ " " ^ apply_on_subgoal settings 1 n
fun command_call name [] = name
| command_call name args = "(" ^ name ^ " " ^ space_implode " " args ^ ")"
fun try_command_line banner command =
banner ^ ": " ^ Markup.markup Markup.sendback command ^ "."
fun using_labels [] = ""
| using_labels ls =
"using " ^ space_implode " " (map string_for_label ls) ^ " "
fun metis_name full_types = if full_types then "metisFT" else "metis"
fun metis_call full_types ss = command_call (metis_name full_types) ss
fun metis_command full_types i n (ls, ss) =
using_labels ls ^ apply_on_subgoal "" i n ^ metis_call full_types ss
fun minimize_line _ [] = ""
| minimize_line minimize_command ss =
case minimize_command ss of
"" => ""
| command =>
"\nTo minimize the number of lemmas, try this: " ^
Markup.markup Markup.sendback command ^ "."
val split_used_facts =
List.partition (curry (op =) Chained o snd)
#> pairself (sort_distinct (string_ord o pairself fst))
fun uses_typed_helpers typed_helpers =
exists (fn Inference (name, _, []) => is_typed_helper typed_helpers name
| _ => false)
fun metis_proof_text (banner, minimize_command, type_sys, atp_proof,
facts_offset, fact_names, typed_helpers, goal, i) =
let
val (chained, extra) =
atp_proof |> used_facts_in_atp_proof type_sys facts_offset fact_names
|> split_used_facts
val full_types = uses_typed_helpers typed_helpers atp_proof
val n = Logic.count_prems (prop_of goal)
val metis = metis_command full_types i n ([], map fst extra)
in
(try_command_line banner metis ^
minimize_line minimize_command (map fst (extra @ chained)),
extra @ chained)
end
(** Hard-core proof reconstruction: structured Isar proofs **)
(* Simple simplifications to ensure that sort annotations don't leave a trail of
spurious "True"s. *)
fun s_not (Const (@{const_name All}, T) $ Abs (s, T', t')) =
Const (@{const_name Ex}, T) $ Abs (s, T', s_not t')
| s_not (Const (@{const_name Ex}, T) $ Abs (s, T', t')) =
Const (@{const_name All}, T) $ Abs (s, T', s_not t')
| s_not (@{const HOL.implies} $ t1 $ t2) = @{const HOL.conj} $ t1 $ s_not t2
| s_not (@{const HOL.conj} $ t1 $ t2) =
@{const HOL.disj} $ s_not t1 $ s_not t2
| s_not (@{const HOL.disj} $ t1 $ t2) =
@{const HOL.conj} $ s_not t1 $ s_not t2
| s_not (@{const False}) = @{const True}
| s_not (@{const True}) = @{const False}
| s_not (@{const Not} $ t) = t
| s_not t = @{const Not} $ t
fun s_conj (@{const True}, t2) = t2
| s_conj (t1, @{const True}) = t1
| s_conj p = HOLogic.mk_conj p
fun s_disj (@{const False}, t2) = t2
| s_disj (t1, @{const False}) = t1
| s_disj p = HOLogic.mk_disj p
fun s_imp (@{const True}, t2) = t2
| s_imp (t1, @{const False}) = s_not t1
| s_imp p = HOLogic.mk_imp p
fun s_iff (@{const True}, t2) = t2
| s_iff (t1, @{const True}) = t1
| s_iff (t1, t2) = HOLogic.eq_const HOLogic.boolT $ t1 $ t2
fun forall_of v t = HOLogic.all_const (fastype_of v) $ lambda v t
fun exists_of v t = HOLogic.exists_const (fastype_of v) $ lambda v t
val indent_size = 2
val no_label = ("", ~1)
val raw_prefix = "X"
val assum_prefix = "A"
val have_prefix = "F"
fun raw_label_for_name conjecture_shape name =
case resolve_conjecture conjecture_shape name of
[j] => (conjecture_prefix, j)
| _ => case Int.fromString (fst name) of
SOME j => (raw_prefix, j)
| NONE => (raw_prefix ^ fst name, 0)
(**** INTERPRETATION OF TSTP SYNTAX TREES ****)
exception FO_TERM of string fo_term list
exception FORMULA of (string, string, string fo_term) formula list
exception SAME of unit
(* Type variables are given the basic sort "HOL.type". Some will later be
constrained by information from type literals, or by type inference. *)
fun typ_from_fo_term tfrees (u as ATerm (a, us)) =
let val Ts = map (typ_from_fo_term tfrees) us in
case strip_prefix_and_unascii type_const_prefix a of
SOME b => Type (invert_const b, Ts)
| NONE =>
if not (null us) then
raise FO_TERM [u] (* only "tconst"s have type arguments *)
else case strip_prefix_and_unascii tfree_prefix a of
SOME b =>
let val s = "'" ^ b in
TFree (s, AList.lookup (op =) tfrees s |> the_default HOLogic.typeS)
end
| NONE =>
case strip_prefix_and_unascii tvar_prefix a of
SOME b => TVar (("'" ^ b, 0), HOLogic.typeS)
| NONE =>
(* Variable from the ATP, say "X1" *)
Type_Infer.param 0 (a, HOLogic.typeS)
end
(* Type class literal applied to a type. Returns triple of polarity, class,
type. *)
fun type_constraint_from_term tfrees (u as ATerm (a, us)) =
case (strip_prefix_and_unascii class_prefix a,
map (typ_from_fo_term tfrees) us) of
(SOME b, [T]) => (b, T)
| _ => raise FO_TERM [u]
(** Accumulate type constraints in a formula: negative type literals **)
fun add_var (key, z) = Vartab.map_default (key, []) (cons z)
fun add_type_constraint false (cl, TFree (a ,_)) = add_var ((a, ~1), cl)
| add_type_constraint false (cl, TVar (ix, _)) = add_var (ix, cl)
| add_type_constraint _ _ = I
fun repair_atp_variable_name f s =
let
fun subscript_name s n = s ^ nat_subscript n
val s = String.map f s
in
case space_explode "_" s of
[_] => (case take_suffix Char.isDigit (String.explode s) of
(cs1 as _ :: _, cs2 as _ :: _) =>
subscript_name (String.implode cs1)
(the (Int.fromString (String.implode cs2)))
| (_, _) => s)
| [s1, s2] => (case Int.fromString s2 of
SOME n => subscript_name s1 n
| NONE => s)
| _ => s
end
(* First-order translation. No types are known for variables. "HOLogic.typeT"
should allow them to be inferred. *)
fun raw_term_from_pred thy sym_tab tfrees =
let
fun aux opt_T extra_us u =
case u of
ATerm (a, us) =>
if String.isPrefix tff_type_prefix a then
@{const True} (* ignore TFF type information *)
else case strip_prefix_and_unascii const_prefix a of
SOME "equal" =>
let val ts = map (aux NONE []) us in
if length ts = 2 andalso hd ts aconv List.last ts then
(* Vampire is keen on producing these. *)
@{const True}
else
list_comb (Const (@{const_name HOL.eq}, HOLogic.typeT), ts)
end
| SOME s =>
let
val ((s', s), mangled_us) = s |> unmangled_const |>> `invert_const
in
if s' = type_tag_name then
case mangled_us @ us of
[typ_u, term_u] =>
aux (SOME (typ_from_fo_term tfrees typ_u)) extra_us term_u
| _ => raise FO_TERM us
else if s' = predicator_base then
aux (SOME @{typ bool}) [] (hd us)
else if s' = explicit_app_base then
aux opt_T (nth us 1 :: extra_us) (hd us)
else if s' = type_pred_base then
@{const True} (* ignore type predicates *)
else
let
val num_ty_args =
length us - the_default 0 (Symtab.lookup sym_tab s)
val (type_us, term_us) =
chop num_ty_args us |>> append mangled_us
(* Extra args from "hAPP" come after any arguments given
directly to the constant. *)
val term_ts = map (aux NONE []) term_us
val extra_ts = map (aux NONE []) extra_us
val T =
if num_type_args thy s' = length type_us then
Sign.const_instance thy
(s', map (typ_from_fo_term tfrees) type_us)
else case opt_T of
SOME T => map fastype_of (term_ts @ extra_ts) ---> T
| NONE => HOLogic.typeT
val s' = s' |> unproxify_const
in list_comb (Const (s', T), term_ts @ extra_ts) end
end
| NONE => (* a free or schematic variable *)
let
val ts = map (aux NONE []) (us @ extra_us)
val T = map fastype_of ts ---> HOLogic.typeT
val t =
case strip_prefix_and_unascii fixed_var_prefix a of
SOME b => Free (b, T)
| NONE =>
case strip_prefix_and_unascii schematic_var_prefix a of
SOME b => Var ((b, 0), T)
| NONE =>
if is_atp_variable a then
Var ((repair_atp_variable_name Char.toLower a, 0), T)
else
(* Skolem constants? *)
Var ((repair_atp_variable_name Char.toUpper a, 0), T)
in list_comb (t, ts) end
in aux (SOME HOLogic.boolT) [] end
fun term_from_pred thy sym_tab tfrees pos (u as ATerm (s, _)) =
if String.isPrefix class_prefix s then
add_type_constraint pos (type_constraint_from_term tfrees u)
#> pair @{const True}
else
pair (raw_term_from_pred thy sym_tab tfrees u)
val combinator_table =
[(@{const_name Meson.COMBI}, @{thm Meson.COMBI_def_raw}),
(@{const_name Meson.COMBK}, @{thm Meson.COMBK_def_raw}),
(@{const_name Meson.COMBB}, @{thm Meson.COMBB_def_raw}),
(@{const_name Meson.COMBC}, @{thm Meson.COMBC_def_raw}),
(@{const_name Meson.COMBS}, @{thm Meson.COMBS_def_raw})]
fun uncombine_term thy =
let
fun aux (t1 $ t2) = betapply (pairself aux (t1, t2))
| aux (Abs (s, T, t')) = Abs (s, T, aux t')
| aux (t as Const (x as (s, _))) =
(case AList.lookup (op =) combinator_table s of
SOME thm => thm |> prop_of |> specialize_type thy x
|> Logic.dest_equals |> snd
| NONE => t)
| aux t = t
in aux end
(* Update schematic type variables with detected sort constraints. It's not
totally clear whether this code is necessary. *)
fun repair_tvar_sorts (t, tvar_tab) =
let
fun do_type (Type (a, Ts)) = Type (a, map do_type Ts)
| do_type (TVar (xi, s)) =
TVar (xi, the_default s (Vartab.lookup tvar_tab xi))
| do_type (TFree z) = TFree z
fun do_term (Const (a, T)) = Const (a, do_type T)
| do_term (Free (a, T)) = Free (a, do_type T)
| do_term (Var (xi, T)) = Var (xi, do_type T)
| do_term (t as Bound _) = t
| do_term (Abs (a, T, t)) = Abs (a, do_type T, do_term t)
| do_term (t1 $ t2) = do_term t1 $ do_term t2
in t |> not (Vartab.is_empty tvar_tab) ? do_term end
fun quantify_over_var quant_of var_s t =
let
val vars = [] |> Term.add_vars t |> filter (fn ((s, _), _) => s = var_s)
|> map Var
in fold_rev quant_of vars t end
(* Interpret an ATP formula as a HOL term, extracting sort constraints as they
appear in the formula. *)
fun prop_from_formula thy sym_tab tfrees phi =
let
fun do_formula pos phi =
case phi of
AQuant (_, [], phi) => do_formula pos phi
| AQuant (q, (s, _) :: xs, phi') =>
do_formula pos (AQuant (q, xs, phi'))
(* FIXME: TFF *)
#>> quantify_over_var (case q of
AForall => forall_of
| AExists => exists_of)
(repair_atp_variable_name Char.toLower s)
| AConn (ANot, [phi']) => do_formula (not pos) phi' #>> s_not
| AConn (c, [phi1, phi2]) =>
do_formula (pos |> c = AImplies ? not) phi1
##>> do_formula pos phi2
#>> (case c of
AAnd => s_conj
| AOr => s_disj
| AImplies => s_imp
| AIf => s_imp o swap
| AIff => s_iff
| ANotIff => s_not o s_iff
| _ => raise Fail "unexpected connective")
| AAtom tm => term_from_pred thy sym_tab tfrees pos tm
| _ => raise FORMULA [phi]
in repair_tvar_sorts (do_formula true phi Vartab.empty) end
fun check_formula ctxt =
Type.constraint HOLogic.boolT
#> Syntax.check_term
(Proof_Context.set_mode Proof_Context.mode_schematic ctxt)
(**** Translation of TSTP files to Isar Proofs ****)
fun unvarify_term (Var ((s, 0), T)) = Free (s, T)
| unvarify_term t = raise TERM ("unvarify_term: non-Var", [t])
fun decode_line sym_tab tfrees (Definition (name, phi1, phi2)) ctxt =
let
val thy = Proof_Context.theory_of ctxt
val t1 = prop_from_formula thy sym_tab tfrees phi1
val vars = snd (strip_comb t1)
val frees = map unvarify_term vars
val unvarify_args = subst_atomic (vars ~~ frees)
val t2 = prop_from_formula thy sym_tab tfrees phi2
val (t1, t2) =
HOLogic.eq_const HOLogic.typeT $ t1 $ t2
|> unvarify_args |> uncombine_term thy |> check_formula ctxt
|> HOLogic.dest_eq
in
(Definition (name, t1, t2),
fold Variable.declare_term (maps OldTerm.term_frees [t1, t2]) ctxt)
end
| decode_line sym_tab tfrees (Inference (name, u, deps)) ctxt =
let
val thy = Proof_Context.theory_of ctxt
val t = u |> prop_from_formula thy sym_tab tfrees
|> uncombine_term thy |> check_formula ctxt
in
(Inference (name, t, deps),
fold Variable.declare_term (OldTerm.term_frees t) ctxt)
end
fun decode_lines ctxt sym_tab tfrees lines =
fst (fold_map (decode_line sym_tab tfrees) lines ctxt)
fun is_same_inference _ (Definition _) = false
| is_same_inference t (Inference (_, t', _)) = t aconv t'
(* No "real" literals means only type information (tfree_tcs, clsrel, or
clsarity). *)
val is_only_type_information = curry (op aconv) HOLogic.true_const
fun replace_one_dependency (old, new) dep =
if is_same_step (dep, old) then new else [dep]
fun replace_dependencies_in_line _ (line as Definition _) = line
| replace_dependencies_in_line p (Inference (name, t, deps)) =
Inference (name, t, fold (union (op =) o replace_one_dependency p) deps [])
(* Discard facts; consolidate adjacent lines that prove the same formula, since
they differ only in type information.*)
fun add_line _ _ _ (line as Definition _) lines = line :: lines
| add_line type_sys conjecture_shape fact_names (Inference (name, t, []))
lines =
(* No dependencies: fact, conjecture, or (for Vampire) internal facts or
definitions. *)
if is_fact type_sys fact_names name then
(* Facts are not proof lines. *)
if is_only_type_information t then
map (replace_dependencies_in_line (name, [])) lines
(* Is there a repetition? If so, replace later line by earlier one. *)
else case take_prefix (not o is_same_inference t) lines of
(_, []) => lines (* no repetition of proof line *)
| (pre, Inference (name', _, _) :: post) =>
pre @ map (replace_dependencies_in_line (name', [name])) post
| _ => raise Fail "unexpected inference"
else if is_conjecture conjecture_shape name then
Inference (name, s_not t, []) :: lines
else
map (replace_dependencies_in_line (name, [])) lines
| add_line _ _ _ (Inference (name, t, deps)) lines =
(* Type information will be deleted later; skip repetition test. *)
if is_only_type_information t then
Inference (name, t, deps) :: lines
(* Is there a repetition? If so, replace later line by earlier one. *)
else case take_prefix (not o is_same_inference t) lines of
(* FIXME: Doesn't this code risk conflating proofs involving different
types? *)
(_, []) => Inference (name, t, deps) :: lines
| (pre, Inference (name', t', _) :: post) =>
Inference (name, t', deps) ::
pre @ map (replace_dependencies_in_line (name', [name])) post
| _ => raise Fail "unexpected inference"
(* Recursively delete empty lines (type information) from the proof. *)
fun add_nontrivial_line (Inference (name, t, [])) lines =
if is_only_type_information t then delete_dependency name lines
else Inference (name, t, []) :: lines
| add_nontrivial_line line lines = line :: lines
and delete_dependency name lines =
fold_rev add_nontrivial_line
(map (replace_dependencies_in_line (name, [])) lines) []
(* ATPs sometimes reuse free variable names in the strangest ways. Removing
offending lines often does the trick. *)
fun is_bad_free frees (Free x) = not (member (op =) frees x)
| is_bad_free _ _ = false
fun add_desired_line _ _ _ _ _ (line as Definition (name, _, _)) (j, lines) =
(j, line :: map (replace_dependencies_in_line (name, [])) lines)
| add_desired_line type_sys isar_shrink_factor conjecture_shape fact_names
frees (Inference (name, t, deps)) (j, lines) =
(j + 1,
if is_fact type_sys fact_names name orelse
is_conjecture conjecture_shape name orelse
(* the last line must be kept *)
j = 0 orelse
(not (is_only_type_information t) andalso
null (Term.add_tvars t []) andalso
not (exists_subterm (is_bad_free frees) t) andalso
length deps >= 2 andalso j mod isar_shrink_factor = 0 andalso
(* kill next to last line, which usually results in a trivial step *)
j <> 1) then
Inference (name, t, deps) :: lines (* keep line *)
else
map (replace_dependencies_in_line (name, deps)) lines) (* drop line *)
(** Isar proof construction and manipulation **)
fun merge_fact_sets (ls1, ss1) (ls2, ss2) =
(union (op =) ls1 ls2, union (op =) ss1 ss2)
type label = string * int
type facts = label list * string list
datatype isar_qualifier = Show | Then | Moreover | Ultimately
datatype isar_step =
Fix of (string * typ) list |
Let of term * term |
Assume of label * term |
Have of isar_qualifier list * label * term * byline
and byline =
ByMetis of facts |
CaseSplit of isar_step list list * facts
fun smart_case_split [] facts = ByMetis facts
| smart_case_split proofs facts = CaseSplit (proofs, facts)
fun add_fact_from_dependency type_sys conjecture_shape facts_offset fact_names
name =
if is_fact type_sys fact_names name then
apsnd (union (op =)
(map fst (resolve_fact type_sys facts_offset fact_names name)))
else
apfst (insert (op =) (raw_label_for_name conjecture_shape name))
fun step_for_line _ _ _ _ _ (Definition (_, t1, t2)) = Let (t1, t2)
| step_for_line _ conjecture_shape _ _ _ (Inference (name, t, [])) =
Assume (raw_label_for_name conjecture_shape name, t)
| step_for_line type_sys conjecture_shape facts_offset
fact_names j (Inference (name, t, deps)) =
Have (if j = 1 then [Show] else [],
raw_label_for_name conjecture_shape name,
fold_rev forall_of (map Var (Term.add_vars t [])) t,
ByMetis (fold (add_fact_from_dependency type_sys conjecture_shape
facts_offset fact_names)
deps ([], [])))
fun repair_name "$true" = "c_True"
| repair_name "$false" = "c_False"
| repair_name "$$e" = "c_equal" (* seen in Vampire proofs *)
| repair_name "equal" = "c_equal" (* needed by SPASS? *)
| repair_name s =
if String.isPrefix "sQ" s andalso String.isSuffix "_eqProxy" s then
"c_equal" (* seen in Vampire proofs *)
else
s
fun isar_proof_from_atp_proof pool ctxt type_sys tfrees isar_shrink_factor
atp_proof conjecture_shape facts_offset fact_names sym_tab params
frees =
let
val lines =
atp_proof
|> nasty_atp_proof pool
|> map_term_names_in_atp_proof repair_name
|> decode_lines ctxt sym_tab tfrees
|> rpair [] |-> fold_rev (add_line type_sys conjecture_shape fact_names)
|> rpair [] |-> fold_rev add_nontrivial_line
|> rpair (0, [])
|-> fold_rev (add_desired_line type_sys isar_shrink_factor
conjecture_shape fact_names frees)
|> snd
in
(if null params then [] else [Fix params]) @
map2 (step_for_line type_sys conjecture_shape facts_offset fact_names)
(length lines downto 1) lines
end
(* When redirecting proofs, we keep information about the labels seen so far in
the "backpatches" data structure. The first component indicates which facts
should be associated with forthcoming proof steps. The second component is a
pair ("assum_ls", "drop_ls"), where "assum_ls" are the labels that should
become assumptions and "drop_ls" are the labels that should be dropped in a
case split. *)
type backpatches = (label * facts) list * (label list * label list)
fun used_labels_of_step (Have (_, _, _, by)) =
(case by of
ByMetis (ls, _) => ls
| CaseSplit (proofs, (ls, _)) =>
fold (union (op =) o used_labels_of) proofs ls)
| used_labels_of_step _ = []
and used_labels_of proof = fold (union (op =) o used_labels_of_step) proof []
fun new_labels_of_step (Fix _) = []
| new_labels_of_step (Let _) = []
| new_labels_of_step (Assume (l, _)) = [l]
| new_labels_of_step (Have (_, l, _, _)) = [l]
val new_labels_of = maps new_labels_of_step
val join_proofs =
let
fun aux _ [] = NONE
| aux proof_tail (proofs as (proof1 :: _)) =
if exists null proofs then
NONE
else if forall (curry (op =) (hd proof1) o hd) (tl proofs) then
aux (hd proof1 :: proof_tail) (map tl proofs)
else case hd proof1 of
Have ([], l, t, _) => (* FIXME: should we really ignore the "by"? *)
if forall (fn Have ([], l', t', _) :: _ => (l, t) = (l', t')
| _ => false) (tl proofs) andalso
not (exists (member (op =) (maps new_labels_of proofs))
(used_labels_of proof_tail)) then
SOME (l, t, map rev proofs, proof_tail)
else
NONE
| _ => NONE
in aux [] o map rev end
fun case_split_qualifiers proofs =
case length proofs of
0 => []
| 1 => [Then]
| _ => [Ultimately]
fun redirect_proof hyp_ts concl_t proof =
let
(* The first pass outputs those steps that are independent of the negated
conjecture. The second pass flips the proof by contradiction to obtain a
direct proof, introducing case splits when an inference depends on
several facts that depend on the negated conjecture. *)
val concl_l = (conjecture_prefix, length hyp_ts)
fun first_pass ([], contra) = ([], contra)
| first_pass ((step as Fix _) :: proof, contra) =
first_pass (proof, contra) |>> cons step
| first_pass ((step as Let _) :: proof, contra) =
first_pass (proof, contra) |>> cons step
| first_pass ((step as Assume (l as (_, j), _)) :: proof, contra) =
if l = concl_l then first_pass (proof, contra ||> cons step)
else first_pass (proof, contra) |>> cons (Assume (l, nth hyp_ts j))
| first_pass (Have (qs, l, t, ByMetis (ls, ss)) :: proof, contra) =
let val step = Have (qs, l, t, ByMetis (ls, ss)) in
if exists (member (op =) (fst contra)) ls then
first_pass (proof, contra |>> cons l ||> cons step)
else
first_pass (proof, contra) |>> cons step
end
| first_pass _ = raise Fail "malformed proof"
val (proof_top, (contra_ls, contra_proof)) =
first_pass (proof, ([concl_l], []))
val backpatch_label = the_default ([], []) oo AList.lookup (op =) o fst
fun backpatch_labels patches ls =
fold merge_fact_sets (map (backpatch_label patches) ls) ([], [])
fun second_pass end_qs ([], assums, patches) =
([Have (end_qs, no_label, concl_t,
ByMetis (backpatch_labels patches (map snd assums)))], patches)
| second_pass end_qs (Assume (l, t) :: proof, assums, patches) =
second_pass end_qs (proof, (t, l) :: assums, patches)
| second_pass end_qs (Have (qs, l, t, ByMetis (ls, ss)) :: proof, assums,
patches) =
(if member (op =) (snd (snd patches)) l andalso
not (member (op =) (fst (snd patches)) l) andalso
not (AList.defined (op =) (fst patches) l) then
second_pass end_qs (proof, assums, patches ||> apsnd (append ls))
else case List.partition (member (op =) contra_ls) ls of
([contra_l], co_ls) =>
if member (op =) qs Show then
second_pass end_qs (proof, assums,
patches |>> cons (contra_l, (co_ls, ss)))
else
second_pass end_qs
(proof, assums,
patches |>> cons (contra_l, (l :: co_ls, ss)))
|>> cons (if member (op =) (fst (snd patches)) l then
Assume (l, s_not t)
else
Have (qs, l, s_not t,
ByMetis (backpatch_label patches l)))
| (contra_ls as _ :: _, co_ls) =>
let
val proofs =
map_filter
(fn l =>
if l = concl_l then
NONE
else
let
val drop_ls = filter (curry (op <>) l) contra_ls
in
second_pass []
(proof, assums,
patches ||> apfst (insert (op =) l)
||> apsnd (union (op =) drop_ls))
|> fst |> SOME
end) contra_ls
val (assumes, facts) =
if member (op =) (fst (snd patches)) l then
([Assume (l, s_not t)], (l :: co_ls, ss))
else
([], (co_ls, ss))
in
(case join_proofs proofs of
SOME (l, t, proofs, proof_tail) =>
Have (case_split_qualifiers proofs @
(if null proof_tail then end_qs else []), l, t,
smart_case_split proofs facts) :: proof_tail
| NONE =>
[Have (case_split_qualifiers proofs @ end_qs, no_label,
concl_t, smart_case_split proofs facts)],
patches)
|>> append assumes
end
| _ => raise Fail "malformed proof")
| second_pass _ _ = raise Fail "malformed proof"
val proof_bottom =
second_pass [Show] (contra_proof, [], ([], ([], []))) |> fst
in proof_top @ proof_bottom end
(* FIXME: Still needed? Probably not. *)
val kill_duplicate_assumptions_in_proof =
let
fun relabel_facts subst =
apfst (map (fn l => AList.lookup (op =) subst l |> the_default l))
fun do_step (step as Assume (l, t)) (proof, subst, assums) =
(case AList.lookup (op aconv) assums t of
SOME l' => (proof, (l, l') :: subst, assums)
| NONE => (step :: proof, subst, (t, l) :: assums))
| do_step (Have (qs, l, t, by)) (proof, subst, assums) =
(Have (qs, l, t,
case by of
ByMetis facts => ByMetis (relabel_facts subst facts)
| CaseSplit (proofs, facts) =>
CaseSplit (map do_proof proofs, relabel_facts subst facts)) ::
proof, subst, assums)
| do_step step (proof, subst, assums) = (step :: proof, subst, assums)
and do_proof proof = fold do_step proof ([], [], []) |> #1 |> rev
in do_proof end
val then_chain_proof =
let
fun aux _ [] = []
| aux _ ((step as Assume (l, _)) :: proof) = step :: aux l proof
| aux l' (Have (qs, l, t, by) :: proof) =
(case by of
ByMetis (ls, ss) =>
Have (if member (op =) ls l' then
(Then :: qs, l, t,
ByMetis (filter_out (curry (op =) l') ls, ss))
else
(qs, l, t, ByMetis (ls, ss)))
| CaseSplit (proofs, facts) =>
Have (qs, l, t, CaseSplit (map (aux no_label) proofs, facts))) ::
aux l proof
| aux _ (step :: proof) = step :: aux no_label proof
in aux no_label end
fun kill_useless_labels_in_proof proof =
let
val used_ls = used_labels_of proof
fun do_label l = if member (op =) used_ls l then l else no_label
fun do_step (Assume (l, t)) = Assume (do_label l, t)
| do_step (Have (qs, l, t, by)) =
Have (qs, do_label l, t,
case by of
CaseSplit (proofs, facts) =>
CaseSplit (map (map do_step) proofs, facts)
| _ => by)
| do_step step = step
in map do_step proof end
fun prefix_for_depth n = replicate_string (n + 1)
val relabel_proof =
let
fun aux _ _ _ [] = []
| aux subst depth (next_assum, next_fact) (Assume (l, t) :: proof) =
if l = no_label then
Assume (l, t) :: aux subst depth (next_assum, next_fact) proof
else
let val l' = (prefix_for_depth depth assum_prefix, next_assum) in
Assume (l', t) ::
aux ((l, l') :: subst) depth (next_assum + 1, next_fact) proof
end
| aux subst depth (next_assum, next_fact) (Have (qs, l, t, by) :: proof) =
let
val (l', subst, next_fact) =
if l = no_label then
(l, subst, next_fact)
else
let
val l' = (prefix_for_depth depth have_prefix, next_fact)
in (l', (l, l') :: subst, next_fact + 1) end
val relabel_facts =
apfst (maps (the_list o AList.lookup (op =) subst))
val by =
case by of
ByMetis facts => ByMetis (relabel_facts facts)
| CaseSplit (proofs, facts) =>
CaseSplit (map (aux subst (depth + 1) (1, 1)) proofs,
relabel_facts facts)
in
Have (qs, l', t, by) ::
aux subst depth (next_assum, next_fact) proof
end
| aux subst depth nextp (step :: proof) =
step :: aux subst depth nextp proof
in aux [] 0 (1, 1) end
fun string_for_proof ctxt0 full_types i n =
let
val ctxt =
ctxt0 |> Config.put show_free_types false
|> Config.put show_types true
|> Config.put show_sorts true
fun fix_print_mode f x =
Print_Mode.setmp (filter (curry (op =) Symbol.xsymbolsN)
(print_mode_value ())) f x
fun do_indent ind = replicate_string (ind * indent_size) " "
fun do_free (s, T) =
maybe_quote s ^ " :: " ^
maybe_quote (fix_print_mode (Syntax.string_of_typ ctxt) T)
fun do_label l = if l = no_label then "" else string_for_label l ^ ": "
fun do_have qs =
(if member (op =) qs Moreover then "moreover " else "") ^
(if member (op =) qs Ultimately then "ultimately " else "") ^
(if member (op =) qs Then then
if member (op =) qs Show then "thus" else "hence"
else
if member (op =) qs Show then "show" else "have")
val do_term = maybe_quote o fix_print_mode (Syntax.string_of_term ctxt)
fun do_facts (ls, ss) =
metis_command full_types 1 1
(ls |> sort_distinct (prod_ord string_ord int_ord),
ss |> sort_distinct string_ord)
and do_step ind (Fix xs) =
do_indent ind ^ "fix " ^ space_implode " and " (map do_free xs) ^ "\n"
| do_step ind (Let (t1, t2)) =
do_indent ind ^ "let " ^ do_term t1 ^ " = " ^ do_term t2 ^ "\n"
| do_step ind (Assume (l, t)) =
do_indent ind ^ "assume " ^ do_label l ^ do_term t ^ "\n"
| do_step ind (Have (qs, l, t, ByMetis facts)) =
do_indent ind ^ do_have qs ^ " " ^
do_label l ^ do_term t ^ " " ^ do_facts facts ^ "\n"
| do_step ind (Have (qs, l, t, CaseSplit (proofs, facts))) =
space_implode (do_indent ind ^ "moreover\n")
(map (do_block ind) proofs) ^
do_indent ind ^ do_have qs ^ " " ^ do_label l ^ do_term t ^ " " ^
do_facts facts ^ "\n"
and do_steps prefix suffix ind steps =
let val s = implode (map (do_step ind) steps) in
replicate_string (ind * indent_size - size prefix) " " ^ prefix ^
String.extract (s, ind * indent_size,
SOME (size s - ind * indent_size - 1)) ^
suffix ^ "\n"
end
and do_block ind proof = do_steps "{ " " }" (ind + 1) proof
(* One-step proofs are pointless; better use the Metis one-liner
directly. *)
and do_proof [Have (_, _, _, ByMetis _)] = ""
| do_proof proof =
(if i <> 1 then "prefer " ^ string_of_int i ^ "\n" else "") ^
do_indent 0 ^ "proof -\n" ^ do_steps "" "" 1 proof ^ do_indent 0 ^
(if n <> 1 then "next" else "qed")
in do_proof end
fun isar_proof_text (ctxt, debug, isar_shrink_factor, pool, conjecture_shape,
sym_tab)
(metis_params as (_, _, type_sys, atp_proof, facts_offset,
fact_names, typed_helpers, goal, i)) =
let
val (params, hyp_ts, concl_t) = strip_subgoal goal i
val frees = fold Term.add_frees (concl_t :: hyp_ts) []
val tfrees = fold Term.add_tfrees (concl_t :: hyp_ts) []
val full_types = uses_typed_helpers typed_helpers atp_proof
val n = Logic.count_prems (prop_of goal)
val (one_line_proof, lemma_names) = metis_proof_text metis_params
fun isar_proof_for () =
case isar_proof_from_atp_proof pool ctxt type_sys tfrees
isar_shrink_factor atp_proof conjecture_shape facts_offset
fact_names sym_tab params frees
|> redirect_proof hyp_ts concl_t
|> kill_duplicate_assumptions_in_proof
|> then_chain_proof
|> kill_useless_labels_in_proof
|> relabel_proof
|> string_for_proof ctxt full_types i n of
"" => "\nNo structured proof available (proof too short)."
| proof => "\n\nStructured proof:\n" ^ Markup.markup Markup.sendback proof
val isar_proof =
if debug then
isar_proof_for ()
else
try isar_proof_for ()
|> the_default "\nWarning: The Isar proof construction failed."
in (one_line_proof ^ isar_proof, lemma_names) end
fun proof_text isar_proof isar_params metis_params =
(if isar_proof then isar_proof_text isar_params else metis_proof_text)
metis_params
end;