Adapted to modular code generation.
(* Title: HOL/inductive_codegen.ML
ID: $Id$
Author: Stefan Berghofer, TU Muenchen
Code generator for inductive predicates.
*)
signature INDUCTIVE_CODEGEN =
sig
val add : string option -> theory attribute
val setup : (theory -> theory) list
end;
structure InductiveCodegen : INDUCTIVE_CODEGEN =
struct
open Codegen;
(**** theory data ****)
structure CodegenData = TheoryDataFun
(struct
val name = "HOL/inductive_codegen";
type T =
{intros : (thm * string) list Symtab.table,
graph : unit Graph.T,
eqns : (thm * string) list Symtab.table};
val empty =
{intros = Symtab.empty, graph = Graph.empty, eqns = Symtab.empty};
val copy = I;
val extend = I;
fun merge _ ({intros=intros1, graph=graph1, eqns=eqns1},
{intros=intros2, graph=graph2, eqns=eqns2}) =
{intros = Symtab.merge_multi (Drule.eq_thm_prop o pairself fst)
(intros1, intros2),
graph = Graph.merge (K true) (graph1, graph2),
eqns = Symtab.merge_multi (Drule.eq_thm_prop o pairself fst)
(eqns1, eqns2)};
fun print _ _ = ();
end);
fun warn thm = warning ("InductiveCodegen: Not a proper clause:\n" ^
string_of_thm thm);
fun add_node (g, x) = Graph.new_node (x, ()) g handle Graph.DUP _ => g;
fun add optmod (p as (thy, thm)) =
let
val {intros, graph, eqns} = CodegenData.get thy;
fun thyname_of s = (case optmod of
NONE => thyname_of_const s thy | SOME s => s);
in (case concl_of thm of
_ $ (Const ("op :", _) $ _ $ t) => (case head_of t of
Const (s, _) =>
let val cs = foldr add_term_consts [] (prems_of thm)
in (CodegenData.put
{intros = Symtab.update ((s,
getOpt (Symtab.lookup (intros, s), []) @
[(thm, thyname_of s)]), intros),
graph = foldr (uncurry (Graph.add_edge o pair s))
(Library.foldl add_node (graph, s :: cs)) cs,
eqns = eqns} thy, thm)
end
| _ => (warn thm; p))
| _ $ (Const ("op =", _) $ t $ _) => (case head_of t of
Const (s, _) =>
(CodegenData.put {intros = intros, graph = graph,
eqns = Symtab.update ((s,
getOpt (Symtab.lookup (eqns, s), []) @
[(thm, thyname_of s)]), eqns)} thy, thm)
| _ => (warn thm; p))
| _ => (warn thm; p))
end;
fun get_clauses thy s =
let val {intros, graph, ...} = CodegenData.get thy
in case Symtab.lookup (intros, s) of
NONE => (case InductivePackage.get_inductive thy s of
NONE => NONE
| SOME ({names, ...}, {intrs, ...}) =>
SOME (names, thyname_of_const s thy,
preprocess thy intrs))
| SOME _ =>
let
val SOME names = find_first
(fn xs => s mem xs) (Graph.strong_conn graph);
val intrs = List.concat (map
(fn s => valOf (Symtab.lookup (intros, s))) names);
val (_, (_, thyname)) = split_last intrs
in SOME (names, thyname, preprocess thy (map fst intrs)) end
end;
(**** improper tuples ****)
fun prod_factors p (Const ("Pair", _) $ t $ u) =
p :: prod_factors (1::p) t @ prod_factors (2::p) u
| prod_factors p _ = [];
fun split_prod p ps t = if p mem ps then (case t of
Const ("Pair", _) $ t $ u =>
split_prod (1::p) ps t @ split_prod (2::p) ps u
| _ => error "Inconsistent use of products") else [t];
fun full_split_prod (Const ("Pair", _) $ t $ u) =
full_split_prod t @ full_split_prod u
| full_split_prod t = [t];
datatype factors = FVar of int list list | FFix of int list list;
exception Factors;
fun mg_factor (FVar f) (FVar f') = FVar (f inter f')
| mg_factor (FVar f) (FFix f') =
if f' subset f then FFix f' else raise Factors
| mg_factor (FFix f) (FVar f') =
if f subset f' then FFix f else raise Factors
| mg_factor (FFix f) (FFix f') =
if f subset f' andalso f' subset f then FFix f else raise Factors;
fun dest_factors (FVar f) = f
| dest_factors (FFix f) = f;
fun infer_factors sg extra_fs (fs, (optf, t)) =
let fun err s = error (s ^ "\n" ^ Sign.string_of_term sg t)
in (case (optf, strip_comb t) of
(SOME f, (Const (name, _), args)) =>
(case assoc (extra_fs, name) of
NONE => overwrite (fs, (name, getOpt
(Option.map (mg_factor f) (assoc (fs, name)), f)))
| SOME (fs', f') => (mg_factor f (FFix f');
Library.foldl (infer_factors sg extra_fs)
(fs, map (Option.map FFix) fs' ~~ args)))
| (SOME f, (Var ((name, _), _), [])) =>
overwrite (fs, (name, getOpt
(Option.map (mg_factor f) (assoc (fs, name)), f)))
| (NONE, _) => fs
| _ => err "Illegal term")
handle Factors => err "Product factor mismatch in"
end;
fun string_of_factors p ps = if p mem ps then
"(" ^ string_of_factors (1::p) ps ^ ", " ^ string_of_factors (2::p) ps ^ ")"
else "_";
(**** check if a term contains only constructor functions ****)
fun is_constrt thy =
let
val cnstrs = List.concat (List.concat (map
(map (fn (_, (_, _, cs)) => map (apsnd length) cs) o #descr o snd)
(Symtab.dest (DatatypePackage.get_datatypes thy))));
fun check t = (case strip_comb t of
(Var _, []) => true
| (Const (s, _), ts) => (case assoc (cnstrs, s) of
NONE => false
| SOME i => length ts = i andalso forall check ts)
| _ => false)
in check end;
(**** check if a type is an equality type (i.e. doesn't contain fun) ****)
fun is_eqT (Type (s, Ts)) = s <> "fun" andalso forall is_eqT Ts
| is_eqT _ = true;
(**** mode inference ****)
fun string_of_mode (iss, is) = space_implode " -> " (map
(fn NONE => "X"
| SOME js => enclose "[" "]" (commas (map string_of_int js)))
(iss @ [SOME is]));
fun print_modes modes = message ("Inferred modes:\n" ^
space_implode "\n" (map (fn (s, ms) => s ^ ": " ^ commas (map
string_of_mode ms)) modes));
val term_vs = map (fst o fst o dest_Var) o term_vars;
val terms_vs = distinct o List.concat o (map term_vs);
(** collect all Vars in a term (with duplicates!) **)
fun term_vTs t = map (apfst fst o dest_Var)
(List.filter is_Var (foldl_aterms (op :: o Library.swap) ([], t)));
fun get_args _ _ [] = ([], [])
| get_args is i (x::xs) = (if i mem is then apfst else apsnd) (cons x)
(get_args is (i+1) xs);
fun merge xs [] = xs
| merge [] ys = ys
| merge (x::xs) (y::ys) = if length x >= length y then x::merge xs (y::ys)
else y::merge (x::xs) ys;
fun subsets i j = if i <= j then
let val is = subsets (i+1) j
in merge (map (fn ks => i::ks) is) is end
else [[]];
fun cprod ([], ys) = []
| cprod (x :: xs, ys) = map (pair x) ys @ cprod (xs, ys);
fun cprods xss = foldr (map op :: o cprod) [[]] xss;
datatype mode = Mode of (int list option list * int list) * mode option list;
fun modes_of modes t =
let
fun mk_modes name args = List.concat
(map (fn (m as (iss, is)) => map (Mode o pair m) (cprods (map
(fn (NONE, _) => [NONE]
| (SOME js, arg) => map SOME
(List.filter (fn Mode ((_, js'), _) => js=js') (modes_of modes arg)))
(iss ~~ args)))) (valOf (assoc (modes, name))))
in (case strip_comb t of
(Const ("op =", Type (_, [T, _])), _) =>
[Mode (([], [1]), []), Mode (([], [2]), [])] @
(if is_eqT T then [Mode (([], [1, 2]), [])] else [])
| (Const (name, _), args) => mk_modes name args
| (Var ((name, _), _), args) => mk_modes name args
| (Free (name, _), args) => mk_modes name args)
end;
datatype indprem = Prem of term list * term | Sidecond of term;
fun select_mode_prem thy modes vs ps =
find_first (isSome o snd) (ps ~~ map
(fn Prem (us, t) => find_first (fn Mode ((_, is), _) =>
let
val (in_ts, out_ts) = get_args is 1 us;
val (out_ts', in_ts') = List.partition (is_constrt thy) out_ts;
val vTs = List.concat (map term_vTs out_ts');
val dupTs = map snd (duplicates vTs) @
List.mapPartial (curry assoc vTs) vs;
in
terms_vs (in_ts @ in_ts') subset vs andalso
forall (is_eqT o fastype_of) in_ts' andalso
term_vs t subset vs andalso
forall is_eqT dupTs
end)
(modes_of modes t handle Option => [Mode (([], []), [])])
| Sidecond t => if term_vs t subset vs then SOME (Mode (([], []), []))
else NONE) ps);
fun check_mode_clause thy arg_vs modes (iss, is) (ts, ps) =
let
val modes' = modes @ List.mapPartial
(fn (_, NONE) => NONE | (v, SOME js) => SOME (v, [([], js)]))
(arg_vs ~~ iss);
fun check_mode_prems vs [] = SOME vs
| check_mode_prems vs ps = (case select_mode_prem thy modes' vs ps of
NONE => NONE
| SOME (x, _) => check_mode_prems
(case x of Prem (us, _) => vs union terms_vs us | _ => vs)
(filter_out (equal x) ps));
val (in_ts, in_ts') = List.partition (is_constrt thy) (fst (get_args is 1 ts));
val in_vs = terms_vs in_ts;
val concl_vs = terms_vs ts
in
forall is_eqT (map snd (duplicates (List.concat (map term_vTs in_ts)))) andalso
forall (is_eqT o fastype_of) in_ts' andalso
(case check_mode_prems (arg_vs union in_vs) ps of
NONE => false
| SOME vs => concl_vs subset vs)
end;
fun check_modes_pred thy arg_vs preds modes (p, ms) =
let val SOME rs = assoc (preds, p)
in (p, List.filter (fn m => case find_index
(not o check_mode_clause thy arg_vs modes m) rs of
~1 => true
| i => (message ("Clause " ^ string_of_int (i+1) ^ " of " ^
p ^ " violates mode " ^ string_of_mode m); false)) ms)
end;
fun fixp f x =
let val y = f x
in if x = y then x else fixp f y end;
fun infer_modes thy extra_modes factors arg_vs preds = fixp (fn modes =>
map (check_modes_pred thy arg_vs preds (modes @ extra_modes)) modes)
(map (fn (s, (fs, f)) => (s, cprod (cprods (map
(fn NONE => [NONE]
| SOME f' => map SOME (subsets 1 (length f' + 1))) fs),
subsets 1 (length f + 1)))) factors);
(**** code generation ****)
fun mk_eq (x::xs) =
let fun mk_eqs _ [] = []
| mk_eqs a (b::cs) = Pretty.str (a ^ " = " ^ b) :: mk_eqs b cs
in mk_eqs x xs end;
fun mk_tuple xs = Pretty.block (Pretty.str "(" ::
List.concat (separate [Pretty.str ",", Pretty.brk 1] (map single xs)) @
[Pretty.str ")"]);
(* convert nested pairs to n-tuple *)
fun conv_ntuple [_] t ps = ps
| conv_ntuple [_, _] t ps = ps
| conv_ntuple us t ps =
let
val xs = map (fn i => Pretty.str ("x" ^ string_of_int i))
(1 upto length us);
fun ntuple (ys as (x, T) :: xs) U =
if T = U then (x, xs)
else
let
val Type ("*", [U1, U2]) = U;
val (p1, ys1) = ntuple ys U1;
val (p2, ys2) = ntuple ys1 U2
in (mk_tuple [p1, p2], ys2) end
in
[Pretty.str "Seq.map (fn", Pretty.brk 1,
fst (ntuple (xs ~~ map fastype_of us) (HOLogic.dest_setT (fastype_of t))),
Pretty.str " =>", Pretty.brk 1, mk_tuple xs, Pretty.str ")",
Pretty.brk 1, parens (Pretty.block ps)]
end;
(* convert n-tuple to nested pairs *)
fun conv_ntuple' fs T ps =
let
fun mk_x i = Pretty.str ("x" ^ string_of_int i);
fun conv i js (Type ("*", [T, U])) =
if js mem fs then
let
val (p, i') = conv i (1::js) T;
val (q, i'') = conv i' (2::js) U
in (mk_tuple [p, q], i'') end
else (mk_x i, i+1)
| conv i js _ = (mk_x i, i+1)
val (p, i) = conv 1 [] T
in
if i > 3 then
[Pretty.str "Seq.map (fn", Pretty.brk 1,
mk_tuple (map mk_x (1 upto i-1)), Pretty.str " =>", Pretty.brk 1,
p, Pretty.str ")", Pretty.brk 1, parens (Pretty.block ps)]
else ps
end;
fun mk_v ((names, vs), s) = (case assoc (vs, s) of
NONE => ((names, (s, [s])::vs), s)
| SOME xs => let val s' = variant names s in
((s'::names, overwrite (vs, (s, s'::xs))), s') end);
fun distinct_v (nvs, Var ((s, 0), T)) =
apsnd (Var o rpair T o rpair 0) (mk_v (nvs, s))
| distinct_v (nvs, t $ u) =
let
val (nvs', t') = distinct_v (nvs, t);
val (nvs'', u') = distinct_v (nvs', u);
in (nvs'', t' $ u') end
| distinct_v x = x;
fun is_exhaustive (Var _) = true
| is_exhaustive (Const ("Pair", _) $ t $ u) =
is_exhaustive t andalso is_exhaustive u
| is_exhaustive _ = false;
fun compile_match nvs eq_ps out_ps success_p can_fail =
let val eqs = List.concat (separate [Pretty.str " andalso", Pretty.brk 1]
(map single (List.concat (map (mk_eq o snd) nvs) @ eq_ps)));
in
Pretty.block
([Pretty.str "(fn ", mk_tuple out_ps, Pretty.str " =>", Pretty.brk 1] @
(Pretty.block ((if eqs=[] then [] else Pretty.str "if " ::
[Pretty.block eqs, Pretty.brk 1, Pretty.str "then "]) @
(success_p ::
(if eqs=[] then [] else [Pretty.brk 1, Pretty.str "else Seq.empty"]))) ::
(if can_fail then
[Pretty.brk 1, Pretty.str "| _ => Seq.empty)"]
else [Pretty.str ")"])))
end;
fun strip_spaces s = implode (fst (take_suffix (equal " ") (explode s)));
fun modename thy thyname thyname' s (iss, is) = space_implode "__"
(mk_const_id (sign_of thy) thyname thyname' (strip_spaces s) ::
map (space_implode "_" o map string_of_int) (List.mapPartial I iss @ [is]));
fun compile_expr thy defs dep thyname brack thynames (gr, (NONE, t)) =
apsnd single (invoke_codegen thy defs dep thyname brack (gr, t))
| compile_expr _ _ _ _ _ _ (gr, (SOME _, Var ((name, _), _))) =
(gr, [Pretty.str name])
| compile_expr thy defs dep thyname brack thynames (gr, (SOME (Mode (mode, ms)), t)) =
let
val (Const (name, _), args) = strip_comb t;
val (gr', ps) = foldl_map
(compile_expr thy defs dep thyname true thynames) (gr, ms ~~ args);
in (gr', (if brack andalso not (null ps) then
single o parens o Pretty.block else I)
(List.concat (separate [Pretty.brk 1]
([Pretty.str (modename thy thyname
(if name = "op =" then ""
else the (assoc (thynames, name))) name mode)] :: ps))))
end;
fun compile_clause thy defs gr dep thyname all_vs arg_vs modes thynames (iss, is) (ts, ps) =
let
val modes' = modes @ List.mapPartial
(fn (_, NONE) => NONE | (v, SOME js) => SOME (v, [([], js)]))
(arg_vs ~~ iss);
fun check_constrt ((names, eqs), t) =
if is_constrt thy t then ((names, eqs), t) else
let val s = variant names "x";
in ((s::names, (s, t)::eqs), Var ((s, 0), fastype_of t)) end;
fun compile_eq (gr, (s, t)) =
apsnd (Pretty.block o cons (Pretty.str (s ^ " = ")) o single)
(invoke_codegen thy defs dep thyname false (gr, t));
val (in_ts, out_ts) = get_args is 1 ts;
val ((all_vs', eqs), in_ts') =
foldl_map check_constrt ((all_vs, []), in_ts);
fun is_ind t = (case head_of t of
Const (s, _) => s = "op =" orelse isSome (assoc (modes, s))
| Var ((s, _), _) => s mem arg_vs);
fun compile_prems out_ts' vs names gr [] =
let
val (gr2, out_ps) = foldl_map
(invoke_codegen thy defs dep thyname false) (gr, out_ts);
val (gr3, eq_ps) = foldl_map compile_eq (gr2, eqs);
val ((names', eqs'), out_ts'') =
foldl_map check_constrt ((names, []), out_ts');
val (nvs, out_ts''') = foldl_map distinct_v
((names', map (fn x => (x, [x])) vs), out_ts'');
val (gr4, out_ps') = foldl_map
(invoke_codegen thy defs dep thyname false) (gr3, out_ts''');
val (gr5, eq_ps') = foldl_map compile_eq (gr4, eqs')
in
(gr5, compile_match (snd nvs) (eq_ps @ eq_ps') out_ps'
(Pretty.block [Pretty.str "Seq.single", Pretty.brk 1, mk_tuple out_ps])
(exists (not o is_exhaustive) out_ts'''))
end
| compile_prems out_ts vs names gr ps =
let
val vs' = distinct (List.concat (vs :: map term_vs out_ts));
val SOME (p, mode as SOME (Mode ((_, js), _))) =
select_mode_prem thy modes' vs' ps;
val ps' = filter_out (equal p) ps;
val ((names', eqs), out_ts') =
foldl_map check_constrt ((names, []), out_ts);
val (nvs, out_ts'') = foldl_map distinct_v
((names', map (fn x => (x, [x])) vs), out_ts');
val (gr0, out_ps) = foldl_map
(invoke_codegen thy defs dep thyname false) (gr, out_ts'');
val (gr1, eq_ps) = foldl_map compile_eq (gr0, eqs)
in
(case p of
Prem (us, t) =>
let
val (in_ts, out_ts''') = get_args js 1 us;
val (gr2, in_ps) = foldl_map
(invoke_codegen thy defs dep thyname false) (gr1, in_ts);
val (gr3, ps) = if is_ind t then
apsnd (fn ps => ps @ [Pretty.brk 1, mk_tuple in_ps])
(compile_expr thy defs dep thyname false thynames
(gr2, (mode, t)))
else
apsnd (fn p => conv_ntuple us t
[Pretty.str "Seq.of_list", Pretty.brk 1, p])
(invoke_codegen thy defs dep thyname true (gr2, t));
val (gr4, rest) = compile_prems out_ts''' vs' (fst nvs) gr3 ps';
in
(gr4, compile_match (snd nvs) eq_ps out_ps
(Pretty.block (ps @
[Pretty.str " :->", Pretty.brk 1, rest]))
(exists (not o is_exhaustive) out_ts''))
end
| Sidecond t =>
let
val (gr2, side_p) = invoke_codegen thy defs dep thyname true (gr1, t);
val (gr3, rest) = compile_prems [] vs' (fst nvs) gr2 ps';
in
(gr3, compile_match (snd nvs) eq_ps out_ps
(Pretty.block [Pretty.str "?? ", side_p,
Pretty.str " :->", Pretty.brk 1, rest])
(exists (not o is_exhaustive) out_ts''))
end)
end;
val (gr', prem_p) = compile_prems in_ts' arg_vs all_vs' gr ps;
in
(gr', Pretty.block [Pretty.str "Seq.single inp :->", Pretty.brk 1, prem_p])
end;
fun compile_pred thy defs gr dep thyname prfx all_vs arg_vs modes thynames s cls mode =
let val (gr', cl_ps) = foldl_map (fn (gr, cl) => compile_clause thy defs
gr dep thyname all_vs arg_vs modes thynames mode cl) (gr, cls)
in
((gr', "and "), Pretty.block
([Pretty.block (separate (Pretty.brk 1)
(Pretty.str (prfx ^ modename thy thyname thyname s mode) ::
map Pretty.str arg_vs) @
[Pretty.str " inp ="]),
Pretty.brk 1] @
List.concat (separate [Pretty.str " ++", Pretty.brk 1] (map single cl_ps))))
end;
fun compile_preds thy defs gr dep thyname all_vs arg_vs modes thynames preds =
let val ((gr', _), prs) = foldl_map (fn ((gr, prfx), (s, cls)) =>
foldl_map (fn ((gr', prfx'), mode) => compile_pred thy defs gr'
dep thyname prfx' all_vs arg_vs modes thynames s cls mode)
((gr, prfx), valOf (assoc (modes, s)))) ((gr, "fun "), preds)
in
(gr', space_implode "\n\n" (map Pretty.string_of (List.concat prs)) ^ ";\n\n")
end;
(**** processing of introduction rules ****)
exception Modes of
(string * (int list option list * int list) list) list *
(string * (int list list option list * int list list)) list *
string;
fun lookup_modes gr dep = foldl (fn ((xs, ys, z), (xss, yss, zss)) =>
(xss @ xs, yss @ ys, zss @ map (rpair z o fst) ys)) ([], [], [])
(map ((fn (SOME (Modes x), _, _) => x | _ => ([], [], "")) o Graph.get_node gr)
(Graph.all_preds gr [dep]));
fun print_factors factors = message ("Factors:\n" ^
space_implode "\n" (map (fn (s, (fs, f)) => s ^ ": " ^
space_implode " -> " (map
(fn NONE => "X" | SOME f' => string_of_factors [] f')
(fs @ [SOME f]))) factors));
fun prep_intrs intrs = map (rename_term o #prop o rep_thm o standard) intrs;
fun constrain cs [] = []
| constrain cs ((s, xs) :: ys) = (s, case assoc (cs, s) of
NONE => xs
| SOME xs' => xs inter xs') :: constrain cs ys;
fun mk_extra_defs thy defs gr dep names ts =
Library.foldl (fn (gr, name) =>
if name mem names then gr
else (case get_clauses thy name of
NONE => gr
| SOME (names, thyname, intrs) =>
mk_ind_def thy defs gr dep names thyname [] [] (prep_intrs intrs)))
(gr, foldr add_term_consts [] ts)
and mk_ind_def thy defs gr dep names thyname modecs factorcs intrs =
Graph.add_edge (hd names, dep) gr handle Graph.UNDEF _ =>
let
val _ $ (_ $ _ $ u) = Logic.strip_imp_concl (hd intrs);
val (_, args) = strip_comb u;
val arg_vs = List.concat (map term_vs args);
fun dest_prem factors (_ $ (p as (Const ("op :", _) $ t $ u))) =
(case assoc (factors, case head_of u of
Const (name, _) => name | Var ((name, _), _) => name) of
NONE => Prem (full_split_prod t, u)
| SOME f => Prem (split_prod [] f t, u))
| dest_prem factors (_ $ ((eq as Const ("op =", _)) $ t $ u)) =
Prem ([t, u], eq)
| dest_prem factors (_ $ t) = Sidecond t;
fun add_clause factors (clauses, intr) =
let
val _ $ (_ $ t $ u) = Logic.strip_imp_concl intr;
val Const (name, _) = head_of u;
val prems = map (dest_prem factors) (Logic.strip_imp_prems intr);
in
(overwrite (clauses, (name, getOpt (assoc (clauses, name), []) @
[(split_prod [] (valOf (assoc (factors, name))) t, prems)])))
end;
fun check_set (Const (s, _)) = s mem names orelse isSome (get_clauses thy s)
| check_set (Var ((s, _), _)) = s mem arg_vs
| check_set _ = false;
fun add_prod_factors extra_fs (fs, _ $ (Const ("op :", _) $ t $ u)) =
if check_set (head_of u)
then infer_factors (sign_of thy) extra_fs
(fs, (SOME (FVar (prod_factors [] t)), u))
else fs
| add_prod_factors _ (fs, _) = fs;
val gr' = mk_extra_defs thy defs
(Graph.add_edge (hd names, dep)
(Graph.new_node (hd names, (NONE, "", "")) gr)) (hd names) names intrs;
val (extra_modes, extra_factors, extra_thynames) = lookup_modes gr' (hd names);
val fs = constrain factorcs (map (apsnd dest_factors)
(Library.foldl (add_prod_factors extra_factors) ([], List.concat (map (fn t =>
Logic.strip_imp_concl t :: Logic.strip_imp_prems t) intrs))));
val factors = List.mapPartial (fn (name, f) =>
if name mem arg_vs then NONE
else SOME (name, (map (curry assoc fs) arg_vs, f))) fs;
val clauses =
Library.foldl (add_clause (fs @ map (apsnd snd) extra_factors)) ([], intrs);
val modes = constrain modecs
(infer_modes thy extra_modes factors arg_vs clauses);
val _ = print_factors factors;
val _ = print_modes modes;
val (gr'', s) = compile_preds thy defs gr' (hd names) thyname (terms_vs intrs)
arg_vs (modes @ extra_modes)
(map (rpair thyname o fst) factors @ extra_thynames) clauses;
in
(Graph.map_node (hd names)
(K (SOME (Modes (modes, factors, thyname)), thyname, s)) gr'')
end;
fun find_mode s u modes is = (case find_first (fn Mode ((_, js), _) => is=js)
(modes_of modes u handle Option => []) of
NONE => error ("No such mode for " ^ s ^ ": " ^ string_of_mode ([], is))
| mode => mode);
fun mk_ind_call thy defs gr dep thyname t u is_query = (case head_of u of
Const (s, T) => (case (get_clauses thy s, get_assoc_code thy s T) of
(NONE, _) => NONE
| (SOME (names, thyname', intrs), NONE) =>
let
fun mk_mode (((ts, mode), i), Const ("dummy_pattern", _)) =
((ts, mode), i+1)
| mk_mode (((ts, mode), i), t) = ((ts @ [t], mode @ [i]), i+1);
val gr1 = mk_extra_defs thy defs
(mk_ind_def thy defs gr dep names thyname' [] [] (prep_intrs intrs)) dep names [u];
val (modes, factors, thynames) = lookup_modes gr1 dep;
val ts = split_prod [] (snd (valOf (assoc (factors, s)))) t;
val (ts', is) = if is_query then
fst (Library.foldl mk_mode ((([], []), 1), ts))
else (ts, 1 upto length ts);
val mode = find_mode s u modes is;
val (gr2, in_ps) = foldl_map
(invoke_codegen thy defs dep thyname false) (gr1, ts');
val (gr3, ps) =
compile_expr thy defs dep thyname false thynames (gr2, (mode, u))
in
SOME (gr3, Pretty.block
(ps @ [Pretty.brk 1, mk_tuple in_ps]))
end
| _ => NONE)
| _ => NONE);
fun list_of_indset thy defs gr dep thyname brack u = (case head_of u of
Const (s, T) => (case (get_clauses thy s, get_assoc_code thy s T) of
(NONE, _) => NONE
| (SOME (names, thyname', intrs), NONE) =>
let
val gr1 = mk_extra_defs thy defs
(mk_ind_def thy defs gr dep names thyname' [] [] (prep_intrs intrs)) dep names [u];
val (modes, factors, thynames) = lookup_modes gr1 dep;
val mode = find_mode s u modes [];
val (gr2, ps) =
compile_expr thy defs dep thyname false thynames (gr1, (mode, u))
in
SOME (gr2, (if brack then parens else I)
(Pretty.block ([Pretty.str "Seq.list_of", Pretty.brk 1,
Pretty.str "("] @
conv_ntuple' (snd (valOf (assoc (factors, s))))
(HOLogic.dest_setT (fastype_of u))
(ps @ [Pretty.brk 1, Pretty.str "()"]) @
[Pretty.str ")"])))
end
| _ => NONE)
| _ => NONE);
fun clause_of_eqn eqn =
let
val (t, u) = HOLogic.dest_eq (HOLogic.dest_Trueprop (concl_of eqn));
val (Const (s, T), ts) = strip_comb t;
val (Ts, U) = strip_type T
in
rename_term
(Logic.list_implies (prems_of eqn, HOLogic.mk_Trueprop (HOLogic.mk_mem
(foldr1 HOLogic.mk_prod (ts @ [u]), Const (s ^ " ",
HOLogic.mk_setT (foldr1 HOLogic.mk_prodT (Ts @ [U])))))))
end;
fun mk_fun thy defs name eqns dep thyname thyname' gr =
let
val fun_id = mk_const_id (sign_of thy) thyname' thyname' name;
val call_id = mk_const_id (sign_of thy) thyname thyname' name
in (Graph.add_edge (name, dep) gr handle Graph.UNDEF _ =>
let
val clauses = map clause_of_eqn eqns;
val pname = name ^ " ";
val arity = length (snd (strip_comb (fst (HOLogic.dest_eq
(HOLogic.dest_Trueprop (concl_of (hd eqns)))))));
val mode = 1 upto arity;
val vars = map (fn i => Pretty.str ("x" ^ string_of_int i)) mode;
val s = Pretty.string_of (Pretty.block
[mk_app false (Pretty.str ("fun " ^ fun_id)) vars, Pretty.str " =",
Pretty.brk 1, Pretty.str "Seq.hd", Pretty.brk 1,
parens (Pretty.block [Pretty.str (modename thy thyname' thyname' pname ([], mode)),
Pretty.brk 1, mk_tuple vars])]) ^ ";\n\n";
val gr' = mk_ind_def thy defs (Graph.add_edge (name, dep)
(Graph.new_node (name, (NONE, thyname', s)) gr)) name [pname] thyname'
[(pname, [([], mode)])]
[(pname, map (fn i => replicate i 2) (0 upto arity-1))]
clauses;
val (modes, _, _) = lookup_modes gr' dep;
val _ = find_mode pname (snd (HOLogic.dest_mem (HOLogic.dest_Trueprop
(Logic.strip_imp_concl (hd clauses))))) modes mode
in gr' end, call_id)
end;
fun inductive_codegen thy defs gr dep thyname brack (Const ("op :", _) $ t $ u) =
((case mk_ind_call thy defs gr dep thyname (Term.no_dummy_patterns t) u false of
NONE => NONE
| SOME (gr', call_p) => SOME (gr', (if brack then parens else I)
(Pretty.block [Pretty.str "?! (", call_p, Pretty.str ")"])))
handle TERM _ => mk_ind_call thy defs gr dep thyname t u true)
| inductive_codegen thy defs gr dep thyname brack t = (case strip_comb t of
(Const (s, _), ts) => (case Symtab.lookup (#eqns (CodegenData.get thy), s) of
NONE => list_of_indset thy defs gr dep thyname brack t
| SOME eqns =>
let
val (_, (_, thyname')) = split_last eqns;
val (gr', id) = mk_fun thy defs s (preprocess thy (map fst eqns))
dep thyname thyname' gr;
val (gr'', ps) = foldl_map
(invoke_codegen thy defs dep thyname true) (gr', ts);
in SOME (gr'', mk_app brack (Pretty.str id) ps)
end)
| _ => NONE);
val setup =
[add_codegen "inductive" inductive_codegen,
CodegenData.init,
add_attribute "ind"
(Scan.option (Args.$$$ "target" |-- Args.colon |-- Args.name) >> add)];
end;
(**** combinators for code generated from inductive predicates ****)
infix 5 :->;
infix 3 ++;
fun s :-> f = Seq.flat (Seq.map f s);
fun s1 ++ s2 = Seq.append (s1, s2);
fun ?? b = if b then Seq.single () else Seq.empty;
fun ?! s = isSome (Seq.pull s);
fun op_61__1 x = Seq.single x;
val op_61__2 = op_61__1;
fun op_61__1_2 (x, y) = ?? (x = y);