(* Title: HOL/Tools/SMT/smt_translate.ML
Author: Sascha Boehme, TU Muenchen
Translate theorems into an SMT intermediate format and serialize them.
*)
signature SMT_TRANSLATE =
sig
(*intermediate term structure*)
datatype squant = SForall | SExists
datatype 'a spattern = SPat of 'a list | SNoPat of 'a list
datatype sterm =
SVar of int |
SApp of string * sterm list |
SLet of string * sterm * sterm |
SQua of squant * string list * sterm spattern list * int option * sterm
(*translation configuration*)
type prefixes = {sort_prefix: string, func_prefix: string}
type sign = {
header: string list,
sorts: string list,
dtyps: (string * (string * (string * string) list) list) list list,
funcs: (string * (string list * string)) list }
type config = {
prefixes: prefixes,
header: term list -> string list,
is_fol: bool,
has_datatypes: bool,
serialize: string list -> sign -> sterm list -> string }
type recon = {
context: Proof.context,
typs: typ Symtab.table,
terms: term Symtab.table,
rewrite_rules: thm list,
assms: (int * thm) list }
(*translation*)
val add_config: SMT_Utils.class * (Proof.context -> config) ->
Context.generic -> Context.generic
val translate: Proof.context -> string list -> (int * thm) list ->
string * recon
end
structure SMT_Translate: SMT_TRANSLATE =
struct
(* intermediate term structure *)
datatype squant = SForall | SExists
datatype 'a spattern = SPat of 'a list | SNoPat of 'a list
datatype sterm =
SVar of int |
SApp of string * sterm list |
SLet of string * sterm * sterm |
SQua of squant * string list * sterm spattern list * int option * sterm
(* translation configuration *)
type prefixes = {sort_prefix: string, func_prefix: string}
type sign = {
header: string list,
sorts: string list,
dtyps: (string * (string * (string * string) list) list) list list,
funcs: (string * (string list * string)) list }
type config = {
prefixes: prefixes,
header: term list -> string list,
is_fol: bool,
has_datatypes: bool,
serialize: string list -> sign -> sterm list -> string }
type recon = {
context: Proof.context,
typs: typ Symtab.table,
terms: term Symtab.table,
rewrite_rules: thm list,
assms: (int * thm) list }
(* translation context *)
fun make_tr_context {sort_prefix, func_prefix} =
(sort_prefix, 1, Typtab.empty, func_prefix, 1, Termtab.empty)
fun string_of_index pre i = pre ^ string_of_int i
fun add_typ T proper (cx as (sp, Tidx, typs, fp, idx, terms)) =
(case Typtab.lookup typs T of
SOME (n, _) => (n, cx)
| NONE =>
let
val n = string_of_index sp Tidx
val typs' = Typtab.update (T, (n, proper)) typs
in (n, (sp, Tidx+1, typs', fp, idx, terms)) end)
fun add_fun t sort (cx as (sp, Tidx, typs, fp, idx, terms)) =
(case Termtab.lookup terms t of
SOME (n, _) => (n, cx)
| NONE =>
let
val n = string_of_index fp idx
val terms' = Termtab.update (t, (n, sort)) terms
in (n, (sp, Tidx, typs, fp, idx+1, terms')) end)
fun sign_of header dtyps (_, _, typs, _, _, terms) = {
header = header,
sorts = Typtab.fold (fn (_, (n, true)) => cons n | _ => I) typs [],
dtyps = dtyps,
funcs = Termtab.fold (fn (_, (n, SOME ss)) => cons (n,ss) | _ => I) terms []}
fun recon_of ctxt rules thms ithms (_, _, typs, _, _, terms) =
let
fun add_typ (T, (n, _)) = Symtab.update (n, T)
val typs' = Typtab.fold add_typ typs Symtab.empty
fun add_fun (t, (n, _)) = Symtab.update (n, t)
val terms' = Termtab.fold add_fun terms Symtab.empty
val assms = map (pair ~1) thms @ ithms
in
{context=ctxt, typs=typs', terms=terms', rewrite_rules=rules, assms=assms}
end
(* preprocessing *)
(** FIXME **)
local
(*
force eta-expansion for constructors and selectors,
add missing datatype selectors via hypothetical definitions,
also return necessary datatype and record theorems
*)
in
fun collect_datatypes_and_records (tr_context, ctxt) ts =
(([], tr_context, ctxt), ts)
end
(** eta-expand quantifiers, let expressions and built-ins *)
local
fun eta T t = Abs (Name.uu, T, Term.incr_boundvars 1 t $ Bound 0)
fun exp T = eta (Term.domain_type (Term.domain_type T))
fun exp2 T q =
let val U = Term.domain_type T
in Abs (Name.uu, U, q $ eta (Term.domain_type U) (Bound 0)) end
fun exp2' T l =
let val (U1, U2) = Term.dest_funT T ||> Term.domain_type
in Abs (Name.uu, U1, eta U2 (l $ Bound 0)) end
fun expf k i T t =
let val Ts = drop i (fst (SMT_Utils.dest_funT k T))
in
Term.incr_boundvars (length Ts) t
|> fold_index (fn (i, _) => fn u => u $ Bound i) Ts
|> fold_rev (fn T => fn u => Abs (Name.uu, T, u)) Ts
end
in
fun eta_expand ctxt =
let
fun expand ((q as Const (@{const_name All}, _)) $ Abs a) = q $ abs_expand a
| expand ((q as Const (@{const_name All}, T)) $ t) = q $ exp T t
| expand (q as Const (@{const_name All}, T)) = exp2 T q
| expand ((q as Const (@{const_name Ex}, _)) $ Abs a) = q $ abs_expand a
| expand ((q as Const (@{const_name Ex}, T)) $ t) = q $ exp T t
| expand (q as Const (@{const_name Ex}, T)) = exp2 T q
| expand ((l as Const (@{const_name Let}, _)) $ t $ Abs a) =
l $ expand t $ abs_expand a
| expand ((l as Const (@{const_name Let}, T)) $ t $ u) =
l $ expand t $ exp (Term.range_type T) u
| expand ((l as Const (@{const_name Let}, T)) $ t) =
exp2 T (l $ expand t)
| expand (l as Const (@{const_name Let}, T)) = exp2' T l
| expand t =
(case Term.strip_comb t of
(u as Const (c as (_, T)), ts) =>
(case SMT_Builtin.dest_builtin ctxt c ts of
SOME (_, k, us, mk) =>
if k = length us then mk (map expand us)
else expf k (length ts) T (mk (map expand us))
| NONE => Term.list_comb (u, map expand ts))
| (Abs a, ts) => Term.list_comb (abs_expand a, map expand ts)
| (u, ts) => Term.list_comb (u, map expand ts))
and abs_expand (n, T, t) = Abs (n, T, expand t)
in map expand end
end
(** lambda-lifting **)
local
fun mk_def Ts T lhs rhs =
let
val eq = HOLogic.eq_const T $ lhs $ rhs
val trigger =
[[Const (@{const_name SMT.pat}, T --> @{typ SMT.pattern}) $ lhs]]
|> map (HOLogic.mk_list @{typ SMT.pattern})
|> HOLogic.mk_list @{typ "SMT.pattern list"}
fun mk_all T t = HOLogic.all_const T $ Abs (Name.uu, T, t)
in fold mk_all Ts (@{const SMT.trigger} $ trigger $ eq) end
fun mk_abs Ts = fold (fn T => fn t => Abs (Name.uu, T, t)) Ts
fun dest_abs Ts (Abs (_, T, t)) = dest_abs (T :: Ts) t
| dest_abs Ts t = (Ts, t)
fun replace_lambda Us Ts t (cx as (defs, ctxt)) =
let
val t1 = mk_abs Us t
val bs = sort int_ord (Term.add_loose_bnos (t1, 0, []))
fun rep i k = if member (op =) bs i then (Bound k, k+1) else (Bound i, k)
val (rs, _) = fold_map rep (0 upto length Ts - 1) 0
val t2 = Term.subst_bounds (rs, t1)
val Ts' = map (nth Ts) bs
val (_, t3) = dest_abs [] t2
val t4 = mk_abs Ts' t2
val T = Term.fastype_of1 (Us @ Ts, t)
fun app f = Term.list_comb (f, map Bound (rev bs))
in
(case Termtab.lookup defs t4 of
SOME (f, _) => (app f, cx)
| NONE =>
let
val (n, ctxt') =
yield_singleton Variable.variant_fixes Name.uu ctxt
val (is, UTs) = split_list (map_index I (Us @ Ts'))
val f = Free (n, rev UTs ---> T)
val lhs = Term.list_comb (f, map Bound (rev is))
val def = mk_def UTs (Term.fastype_of1 (Us @ Ts, t)) lhs t3
in (app f, (Termtab.update (t4, (f, def)) defs, ctxt')) end)
end
fun traverse Ts t =
(case t of
(q as Const (@{const_name All}, _)) $ Abs a =>
abs_traverse Ts a #>> (fn a' => q $ Abs a')
| (q as Const (@{const_name Ex}, _)) $ Abs a =>
abs_traverse Ts a #>> (fn a' => q $ Abs a')
| (l as Const (@{const_name Let}, _)) $ u $ Abs a =>
traverse Ts u ##>> abs_traverse Ts a #>>
(fn (u', a') => l $ u' $ Abs a')
| Abs _ =>
let val (Us, u) = dest_abs [] t
in traverse (Us @ Ts) u #-> replace_lambda Us Ts end
| u1 $ u2 => traverse Ts u1 ##>> traverse Ts u2 #>> (op $)
| _ => pair t)
and abs_traverse Ts (n, T, t) = traverse (T::Ts) t #>> (fn t' => (n, T, t'))
in
fun lift_lambdas ctxt ts =
(Termtab.empty, ctxt)
|> fold_map (traverse []) ts
|> (fn (us, (defs, ctxt')) =>
(ctxt', Termtab.fold (cons o snd o snd) defs us))
end
(** introduce explicit applications **)
local
(*
Make application explicit for functions with varying number of arguments.
*)
fun add t i = Termtab.map_default (t, i) (Integer.min i)
fun min_arities t =
(case Term.strip_comb t of
(u as Const _, ts) => add u (length ts) #> fold min_arities ts
| (u as Free _, ts) => add u (length ts) #> fold min_arities ts
| (Abs (_, _, u), ts) => min_arities u #> fold min_arities ts
| (_, ts) => fold min_arities ts)
fun app u (t, T) =
(Const (@{const_name SMT.fun_app}, T --> T) $ t $ u, Term.range_type T)
fun apply i t T ts =
let
val (ts1, ts2) = chop i ts
val (_, U) = SMT_Utils.dest_funT i T
in fst (fold app ts2 (Term.list_comb (t, ts1), U)) end
in
fun intro_explicit_application ts =
let
val arities = fold min_arities ts Termtab.empty
fun apply' t = apply (the (Termtab.lookup arities t)) t
fun traverse Ts t =
(case Term.strip_comb t of
(u as Const (_, T), ts) => apply' u T (map (traverse Ts) ts)
| (u as Free (_, T), ts) => apply' u T (map (traverse Ts) ts)
| (u as Bound i, ts) => apply 0 u (nth Ts i) (map (traverse Ts) ts)
| (Abs (n, T, u), ts) => traverses Ts (Abs (n, T, traverse (T::Ts) u)) ts
| (u, ts) => traverses Ts u ts)
and traverses Ts t ts = Term.list_comb (t, map (traverse Ts) ts)
in map (traverse []) ts end
val fun_app_eq = mk_meta_eq @{thm SMT.fun_app_def}
end
(** map HOL formulas to FOL formulas (i.e., separate formulas froms terms) **)
local
val term_bool = @{lemma "SMT.term_true ~= SMT.term_false"
by (simp add: SMT.term_true_def SMT.term_false_def)}
val fol_rules = [
Let_def,
mk_meta_eq @{thm SMT.term_true_def},
mk_meta_eq @{thm SMT.term_false_def},
@{lemma "P = True == P" by (rule eq_reflection) simp},
@{lemma "if P then True else False == P" by (rule eq_reflection) simp}]
fun reduce_let (Const (@{const_name Let}, _) $ t $ u) =
reduce_let (Term.betapply (u, t))
| reduce_let (t $ u) = reduce_let t $ reduce_let u
| reduce_let (Abs (n, T, t)) = Abs (n, T, reduce_let t)
| reduce_let t = t
fun as_term t = @{const HOL.eq (bool)} $ t $ @{const SMT.term_true}
fun wrap_in_if t =
@{const If (bool)} $ t $ @{const SMT.term_true} $ @{const SMT.term_false}
fun is_builtin_conn_or_pred ctxt c ts =
is_some (SMT_Builtin.dest_builtin_conn ctxt c ts) orelse
is_some (SMT_Builtin.dest_builtin_pred ctxt c ts)
fun builtin b ctxt c ts =
(case (Const c, ts) of
(@{const HOL.eq (bool)}, [t, u]) =>
if t = @{const SMT.term_true} orelse u = @{const SMT.term_true} then
SMT_Builtin.dest_builtin_eq ctxt t u
else b ctxt c ts
| _ => b ctxt c ts)
in
fun folify ctxt =
let
fun in_list T f t = HOLogic.mk_list T (map f (HOLogic.dest_list t))
fun in_term t =
(case Term.strip_comb t of
(@{const True}, []) => @{const SMT.term_true}
| (@{const False}, []) => @{const SMT.term_false}
| (u as Const (@{const_name If}, _), [t1, t2, t3]) =>
u $ in_form t1 $ in_term t2 $ in_term t3
| (Const c, ts) =>
if is_builtin_conn_or_pred ctxt c ts then wrap_in_if (in_form t)
else Term.list_comb (Const c, map in_term ts)
| (Free c, ts) => Term.list_comb (Free c, map in_term ts)
| _ => t)
and in_weight ((c as @{const SMT.weight}) $ w $ t) = c $ w $ in_form t
| in_weight t = in_form t
and in_pat ((p as Const (@{const_name SMT.pat}, _)) $ t) = p $ in_term t
| in_pat ((p as Const (@{const_name SMT.nopat}, _)) $ t) = p $ in_term t
| in_pat t = raise TERM ("bad pattern", [t])
and in_pats ps =
in_list @{typ "SMT.pattern list"} (in_list @{typ SMT.pattern} in_pat) ps
and in_trigger ((c as @{const SMT.trigger}) $ p $ t) =
c $ in_pats p $ in_weight t
| in_trigger t = in_weight t
and in_form t =
(case Term.strip_comb t of
(q as Const (qn, _), [Abs (n, T, u)]) =>
if member (op =) [@{const_name All}, @{const_name Ex}] qn then
q $ Abs (n, T, in_trigger u)
else as_term (in_term t)
| (Const c, ts) =>
(case SMT_Builtin.dest_builtin_conn ctxt c ts of
SOME (_, _, us, mk) => mk (map in_form us)
| NONE =>
(case SMT_Builtin.dest_builtin_pred ctxt c ts of
SOME (_, _, us, mk) => mk (map in_term us)
| NONE => as_term (in_term t)))
| _ => as_term (in_term t))
in
map (reduce_let #> in_form) #>
cons (SMT_Utils.prop_of term_bool) #>
pair (fol_rules, [term_bool], builtin)
end
end
(* translation into intermediate format *)
(** utility functions **)
val quantifier = (fn
@{const_name All} => SOME SForall
| @{const_name Ex} => SOME SExists
| _ => NONE)
fun group_quant qname Ts (t as Const (q, _) $ Abs (_, T, u)) =
if q = qname then group_quant qname (T :: Ts) u else (Ts, t)
| group_quant _ Ts t = (Ts, t)
fun dest_weight (@{const SMT.weight} $ w $ t) =
(SOME (snd (HOLogic.dest_number w)), t)
| dest_weight t = (NONE, t)
fun dest_pat (Const (@{const_name SMT.pat}, _) $ t) = (t, true)
| dest_pat (Const (@{const_name SMT.nopat}, _) $ t) = (t, false)
| dest_pat t = raise TERM ("bad pattern", [t])
fun dest_pats [] = I
| dest_pats ts =
(case map dest_pat ts |> split_list ||> distinct (op =) of
(ps, [true]) => cons (SPat ps)
| (ps, [false]) => cons (SNoPat ps)
| _ => raise TERM ("bad multi-pattern", ts))
fun dest_trigger (@{const SMT.trigger} $ tl $ t) =
(rev (fold (dest_pats o HOLogic.dest_list) (HOLogic.dest_list tl) []), t)
| dest_trigger t = ([], t)
fun dest_quant qn T t = quantifier qn |> Option.map (fn q =>
let
val (Ts, u) = group_quant qn [T] t
val (ps, p) = dest_trigger u
val (w, b) = dest_weight p
in (q, rev Ts, ps, w, b) end)
fun fold_map_pat f (SPat ts) = fold_map f ts #>> SPat
| fold_map_pat f (SNoPat ts) = fold_map f ts #>> SNoPat
(** translation from Isabelle terms into SMT intermediate terms **)
fun intermediate header dtyps builtin ctxt ts trx =
let
fun transT (T as TFree _) = add_typ T true
| transT (T as TVar _) = (fn _ => raise TYPE ("bad SMT type", [T], []))
| transT (T as Type _) =
(case SMT_Builtin.dest_builtin_typ ctxt T of
SOME n => pair n
| NONE => add_typ T true)
fun app n ts = SApp (n, ts)
fun trans t =
(case Term.strip_comb t of
(Const (qn, _), [Abs (_, T, t1)]) =>
(case dest_quant qn T t1 of
SOME (q, Ts, ps, w, b) =>
fold_map transT Ts ##>> fold_map (fold_map_pat trans) ps ##>>
trans b #>> (fn ((Ts', ps'), b') => SQua (q, Ts', ps', w, b'))
| NONE => raise TERM ("unsupported quantifier", [t]))
| (Const (@{const_name Let}, _), [t1, Abs (_, T, t2)]) =>
transT T ##>> trans t1 ##>> trans t2 #>>
(fn ((U, u1), u2) => SLet (U, u1, u2))
| (u as Const (c as (_, T)), ts) =>
(case builtin ctxt c ts of
SOME (n, _, us, _) => fold_map trans us #>> app n
| NONE => transs u T ts)
| (u as Free (_, T), ts) => transs u T ts
| (Bound i, []) => pair (SVar i)
| _ => raise TERM ("bad SMT term", [t]))
and transs t T ts =
let val (Us, U) = SMT_Utils.dest_funT (length ts) T
in
fold_map transT Us ##>> transT U #-> (fn Up =>
add_fun t (SOME Up) ##>> fold_map trans ts #>> SApp)
end
val (us, trx') = fold_map trans ts trx
in ((sign_of (header ts) dtyps trx', us), trx') end
(* translation *)
structure Configs = Generic_Data
(
type T = (Proof.context -> config) SMT_Utils.dict
val empty = []
val extend = I
fun merge data = SMT_Utils.dict_merge fst data
)
fun add_config (cs, cfg) = Configs.map (SMT_Utils.dict_update (cs, cfg))
fun get_config ctxt =
let val cs = SMT_Config.solver_class_of ctxt
in
(case SMT_Utils.dict_get (Configs.get (Context.Proof ctxt)) cs of
SOME cfg => cfg ctxt
| NONE => error ("SMT: no translation configuration found " ^
"for solver class " ^ quote (SMT_Utils.string_of_class cs)))
end
fun translate ctxt comments ithms =
let
val {prefixes, is_fol, header, has_datatypes, serialize} = get_config ctxt
val with_datatypes =
has_datatypes andalso Config.get ctxt SMT_Config.datatypes
fun no_dtyps (tr_context, ctxt) ts = (([], tr_context, ctxt), ts)
val ts1 = map (Envir.beta_eta_contract o SMT_Utils.prop_of o snd) ithms
val ((dtyps, tr_context, ctxt1), ts2) =
((make_tr_context prefixes, ctxt), ts1)
|-> (if with_datatypes then collect_datatypes_and_records else no_dtyps)
val (ctxt2, ts3) =
ts2
|> eta_expand ctxt1
|> lift_lambdas ctxt1
||> intro_explicit_application
val ((rewrite_rules, extra_thms, builtin), ts4) =
(if is_fol then folify ctxt2 else pair ([], [], I)) ts3
val rewrite_rules' = fun_app_eq :: rewrite_rules
in
(ts4, tr_context)
|-> intermediate header dtyps (builtin SMT_Builtin.dest_builtin) ctxt2
|>> uncurry (serialize comments)
||> recon_of ctxt2 rewrite_rules' extra_thms ithms
end
end