(* Title: Pure/codegen.ML
ID: $Id$
Author: Stefan Berghofer, TU Muenchen
License: GPL (GNU GENERAL PUBLIC LICENSE)
Generic code generator.
*)
signature CODEGEN =
sig
val quiet_mode : bool ref
val message : string -> unit
val mode : string list ref
val margin : int ref
datatype 'a mixfix =
Arg
| Ignore
| Pretty of Pretty.T
| Quote of 'a;
type 'a codegen
val add_codegen: string -> term codegen -> theory -> theory
val add_tycodegen: string -> typ codegen -> theory -> theory
val add_attribute: string -> (Args.T list -> theory attribute * Args.T list) -> theory -> theory
val print_codegens: theory -> unit
val generate_code: theory -> (string * string) list -> string
val generate_code_i: theory -> (string * term) list -> string
val assoc_consts: (xstring * string option * term mixfix list) list -> theory -> theory
val assoc_consts_i: (xstring * typ option * term mixfix list) list -> theory -> theory
val assoc_types: (xstring * typ mixfix list) list -> theory -> theory
val get_assoc_code: theory -> string -> typ -> term mixfix list option
val get_assoc_type: theory -> string -> typ mixfix list option
val invoke_codegen: theory -> string -> bool ->
(exn option * string) Graph.T * term -> (exn option * string) Graph.T * Pretty.T
val invoke_tycodegen: theory -> string -> bool ->
(exn option * string) Graph.T * typ -> (exn option * string) Graph.T * Pretty.T
val mk_const_id: Sign.sg -> string -> string
val mk_type_id: Sign.sg -> string -> string
val rename_term: term -> term
val get_defn: theory -> string -> typ -> ((term list * term) * int option) option
val is_instance: theory -> typ -> typ -> bool
val parens: Pretty.T -> Pretty.T
val mk_app: bool -> Pretty.T -> Pretty.T list -> Pretty.T
val eta_expand: term -> term list -> int -> term
val strip_tname: string -> string
val mk_type: bool -> typ -> Pretty.T
val mk_term_of: Sign.sg -> bool -> typ -> Pretty.T
val mk_gen: Sign.sg -> bool -> string list -> string -> typ -> Pretty.T
val test_fn: (int -> (string * term) list option) ref
val test_term: theory -> int -> int -> term -> (string * term) list option
val parse_mixfix: (string -> 'a) -> string -> 'a mixfix list
val parsers: OuterSyntax.parser list
val setup: (theory -> theory) list
end;
structure Codegen : CODEGEN =
struct
val quiet_mode = ref true;
fun message s = if !quiet_mode then () else writeln s;
val mode = ref ([] : string list);
val margin = ref 80;
(**** Mixfix syntax ****)
datatype 'a mixfix =
Arg
| Ignore
| Pretty of Pretty.T
| Quote of 'a;
fun is_arg Arg = true
| is_arg Ignore = true
| is_arg _ = false;
fun quotes_of [] = []
| quotes_of (Quote q :: ms) = q :: quotes_of ms
| quotes_of (_ :: ms) = quotes_of ms;
fun args_of [] xs = ([], xs)
| args_of (Arg :: ms) (x :: xs) = apfst (cons x) (args_of ms xs)
| args_of (Ignore :: ms) (_ :: xs) = args_of ms xs
| args_of (_ :: ms) xs = args_of ms xs;
fun num_args x = length (filter is_arg x);
(**** theory data ****)
(* type of code generators *)
type 'a codegen = theory -> (exn option * string) Graph.T ->
string -> bool -> 'a -> ((exn option * string) Graph.T * Pretty.T) option;
(* parameters for random testing *)
type test_params =
{size: int, iterations: int, default_type: typ option};
fun merge_test_params
{size = size1, iterations = iterations1, default_type = default_type1}
{size = size2, iterations = iterations2, default_type = default_type2} =
{size = Int.max (size1, size2),
iterations = Int.max (iterations1, iterations2),
default_type = case default_type1 of
None => default_type2
| _ => default_type1};
val default_test_params : test_params =
{size = 10, iterations = 100, default_type = None};
fun set_size size ({iterations, default_type, ...} : test_params) =
{size = size, iterations = iterations, default_type = default_type};
fun set_iterations iterations ({size, default_type, ...} : test_params) =
{size = size, iterations = iterations, default_type = default_type};
fun set_default_type s sg ({size, iterations, ...} : test_params) =
{size = size, iterations = iterations,
default_type = Some (typ_of (read_ctyp sg s))};
(* data kind 'Pure/codegen' *)
structure CodegenArgs =
struct
val name = "Pure/codegen";
type T =
{codegens : (string * term codegen) list,
tycodegens : (string * typ codegen) list,
consts : ((string * typ) * term mixfix list) list,
types : (string * typ mixfix list) list,
attrs: (string * (Args.T list -> theory attribute * Args.T list)) list,
test_params: test_params};
val empty =
{codegens = [], tycodegens = [], consts = [], types = [], attrs = [],
test_params = default_test_params};
val copy = I;
val prep_ext = I;
fun merge
({codegens = codegens1, tycodegens = tycodegens1,
consts = consts1, types = types1, attrs = attrs1,
test_params = test_params1},
{codegens = codegens2, tycodegens = tycodegens2,
consts = consts2, types = types2, attrs = attrs2,
test_params = test_params2}) =
{codegens = rev (merge_alists (rev codegens1) (rev codegens2)),
tycodegens = rev (merge_alists (rev tycodegens1) (rev tycodegens2)),
consts = merge_alists consts1 consts2,
types = merge_alists types1 types2,
attrs = merge_alists attrs1 attrs2,
test_params = merge_test_params test_params1 test_params2};
fun print sg ({codegens, tycodegens, ...} : T) =
Pretty.writeln (Pretty.chunks
[Pretty.strs ("term code generators:" :: map fst codegens),
Pretty.strs ("type code generators:" :: map fst tycodegens)]);
end;
structure CodegenData = TheoryDataFun(CodegenArgs);
val print_codegens = CodegenData.print;
(**** access parameters for random testing ****)
fun get_test_params thy = #test_params (CodegenData.get thy);
fun map_test_params f thy =
let val {codegens, tycodegens, consts, types, attrs, test_params} =
CodegenData.get thy;
in CodegenData.put {codegens = codegens, tycodegens = tycodegens,
consts = consts, types = types, attrs = attrs,
test_params = f test_params} thy
end;
(**** add new code generators to theory ****)
fun add_codegen name f thy =
let val {codegens, tycodegens, consts, types, attrs, test_params} =
CodegenData.get thy
in (case assoc (codegens, name) of
None => CodegenData.put {codegens = (name, f) :: codegens,
tycodegens = tycodegens, consts = consts, types = types,
attrs = attrs, test_params = test_params} thy
| Some _ => error ("Code generator " ^ name ^ " already declared"))
end;
fun add_tycodegen name f thy =
let val {codegens, tycodegens, consts, types, attrs, test_params} =
CodegenData.get thy
in (case assoc (tycodegens, name) of
None => CodegenData.put {tycodegens = (name, f) :: tycodegens,
codegens = codegens, consts = consts, types = types,
attrs = attrs, test_params = test_params} thy
| Some _ => error ("Code generator " ^ name ^ " already declared"))
end;
(**** code attribute ****)
fun add_attribute name att thy =
let val {codegens, tycodegens, consts, types, attrs, test_params} =
CodegenData.get thy
in (case assoc (attrs, name) of
None => CodegenData.put {tycodegens = tycodegens,
codegens = codegens, consts = consts, types = types,
attrs = (name, att) :: attrs, test_params = test_params} thy
| Some _ => error ("Code attribute " ^ name ^ " already declared"))
end;
fun mk_parser (a, p) = (if a = "" then Scan.succeed "" else Args.$$$ a) |-- p;
val code_attr =
Attrib.syntax (Scan.depend (fn thy => foldr op || (map mk_parser
(#attrs (CodegenData.get thy)), Scan.fail) >> pair thy));
(**** associate constants with target language code ****)
fun gen_assoc_consts prep_type xs thy = foldl (fn (thy, (s, tyopt, syn)) =>
let
val sg = sign_of thy;
val {codegens, tycodegens, consts, types, attrs, test_params} =
CodegenData.get thy;
val cname = Sign.intern_const sg s;
in
(case Sign.const_type sg cname of
Some T =>
let val T' = (case tyopt of
None => T
| Some ty =>
let val U = prep_type sg ty
in if Type.typ_instance (Sign.tsig_of sg, U, T) then U
else error ("Illegal type constraint for constant " ^ cname)
end)
in (case assoc (consts, (cname, T')) of
None => CodegenData.put {codegens = codegens,
tycodegens = tycodegens,
consts = ((cname, T'), syn) :: consts,
types = types, attrs = attrs, test_params = test_params} thy
| Some _ => error ("Constant " ^ cname ^ " already associated with code"))
end
| _ => error ("Not a constant: " ^ s))
end) (thy, xs);
val assoc_consts_i = gen_assoc_consts (K I);
val assoc_consts = gen_assoc_consts (fn sg => typ_of o read_ctyp sg);
(**** associate types with target language types ****)
fun assoc_types xs thy = foldl (fn (thy, (s, syn)) =>
let
val {codegens, tycodegens, consts, types, attrs, test_params} =
CodegenData.get thy;
val tc = Sign.intern_tycon (sign_of thy) s
in
(case assoc (types, tc) of
None => CodegenData.put {codegens = codegens,
tycodegens = tycodegens, consts = consts,
types = (tc, syn) :: types, attrs = attrs,
test_params = test_params} thy
| Some _ => error ("Type " ^ tc ^ " already associated with code"))
end) (thy, xs);
fun get_assoc_type thy s = assoc (#types (CodegenData.get thy), s);
(**** make valid ML identifiers ****)
fun gen_mk_id kind rename sg s =
let
val (xs as x::_) = explode (rename (space_implode "_"
(NameSpace.unpack (Sign.cond_extern sg kind s))));
fun check_str [] = ""
| check_str (" " :: xs) = "_" ^ check_str xs
| check_str (x :: xs) =
(if Symbol.is_letdig x then x
else "_" ^ string_of_int (ord x)) ^ check_str xs
in
(if not (Symbol.is_letter x) then "id" else "") ^ check_str xs
end;
val mk_const_id = gen_mk_id Sign.constK
(fn s => if s mem ThmDatabase.ml_reserved then s ^ "_const" else s);
val mk_type_id = gen_mk_id Sign.typeK
(fn s => if s mem ThmDatabase.ml_reserved then s ^ "_type" else s);
fun rename_terms ts =
let
val names = foldr add_term_names
(ts, map (fst o fst) (Drule.vars_of_terms ts));
val clash = names inter ThmDatabase.ml_reserved;
val ps = clash ~~ variantlist (clash, names);
fun rename (Var ((a, i), T)) = Var ((if_none (assoc (ps, a)) a, i), T)
| rename (Free (a, T)) = Free (if_none (assoc (ps, a)) a, T)
| rename (Abs (s, T, t)) = Abs (s, T, rename t)
| rename (t $ u) = rename t $ rename u
| rename t = t;
in
map rename ts
end;
val rename_term = hd o rename_terms o single;
(**** retrieve definition of constant ****)
fun is_instance thy T1 T2 =
Type.typ_instance (Sign.tsig_of (sign_of thy), T1, Type.varifyT T2);
fun get_assoc_code thy s T = apsome snd (find_first (fn ((s', T'), _) =>
s = s' andalso is_instance thy T T') (#consts (CodegenData.get thy)));
fun get_defn thy s T =
let
val axms = flat (map (Symtab.dest o #axioms o Theory.rep_theory)
(thy :: Theory.ancestors_of thy));
val defs = mapfilter (fn (_, t) =>
(let
val (lhs, rhs) = Logic.dest_equals t;
val (c, args) = strip_comb lhs;
val (s', T') = dest_Const c
in if s=s' then Some (T', split_last (rename_terms (args @ [rhs])))
else None end) handle TERM _ => None) axms;
val i = find_index (is_instance thy T o fst) defs
in
if i>=0 then Some (snd (nth_elem (i, defs)),
if length defs = 1 then None else Some i)
else None
end;
(**** invoke suitable code generator for term / type ****)
fun invoke_codegen thy dep brack (gr, t) = (case get_first
(fn (_, f) => f thy gr dep brack t) (#codegens (CodegenData.get thy)) of
None => error ("Unable to generate code for term:\n" ^
Sign.string_of_term (sign_of thy) t ^ "\nrequired by:\n" ^
commas (Graph.all_succs gr [dep]))
| Some x => x);
fun invoke_tycodegen thy dep brack (gr, T) = (case get_first
(fn (_, f) => f thy gr dep brack T) (#tycodegens (CodegenData.get thy)) of
None => error ("Unable to generate code for type:\n" ^
Sign.string_of_typ (sign_of thy) T ^ "\nrequired by:\n" ^
commas (Graph.all_succs gr [dep]))
| Some x => x);
(**** code generator for mixfix expressions ****)
fun parens p = Pretty.block [Pretty.str "(", p, Pretty.str ")"];
fun pretty_fn [] p = [p]
| pretty_fn (x::xs) p = Pretty.str ("fn " ^ x ^ " =>") ::
Pretty.brk 1 :: pretty_fn xs p;
fun pretty_mixfix [] [] _ = []
| pretty_mixfix (Arg :: ms) (p :: ps) qs = p :: pretty_mixfix ms ps qs
| pretty_mixfix (Ignore :: ms) ps qs = pretty_mixfix ms ps qs
| pretty_mixfix (Pretty p :: ms) ps qs = p :: pretty_mixfix ms ps qs
| pretty_mixfix (Quote _ :: ms) ps (q :: qs) = q :: pretty_mixfix ms ps qs;
(**** default code generators ****)
fun eta_expand t ts i =
let
val (Ts, _) = strip_type (fastype_of t);
val j = i - length ts
in
foldr (fn (T, t) => Abs ("x", T, t))
(take (j, Ts), list_comb (t, ts @ map Bound (j-1 downto 0)))
end;
fun mk_app _ p [] = p
| mk_app brack p ps = if brack then
Pretty.block (Pretty.str "(" ::
separate (Pretty.brk 1) (p :: ps) @ [Pretty.str ")"])
else Pretty.block (separate (Pretty.brk 1) (p :: ps));
fun new_names t xs = variantlist (xs,
map (fst o fst o dest_Var) (term_vars t) union
add_term_names (t, ThmDatabase.ml_reserved));
fun new_name t x = hd (new_names t [x]);
fun default_codegen thy gr dep brack t =
let
val (u, ts) = strip_comb t;
fun codegens brack = foldl_map (invoke_codegen thy dep brack)
in (case u of
Var ((s, i), T) =>
let
val (gr', ps) = codegens true (gr, ts);
val (gr'', _) = invoke_tycodegen thy dep false (gr', T)
in Some (gr'', mk_app brack (Pretty.str (s ^
(if i=0 then "" else string_of_int i))) ps)
end
| Free (s, T) =>
let
val (gr', ps) = codegens true (gr, ts);
val (gr'', _) = invoke_tycodegen thy dep false (gr', T)
in Some (gr'', mk_app brack (Pretty.str s) ps) end
| Const (s, T) =>
(case get_assoc_code thy s T of
Some ms =>
let val i = num_args ms
in if length ts < i then
default_codegen thy gr dep brack (eta_expand u ts i)
else
let
val (ts1, ts2) = args_of ms ts;
val (gr1, ps1) = codegens false (gr, ts1);
val (gr2, ps2) = codegens true (gr1, ts2);
val (gr3, ps3) = codegens false (gr2, quotes_of ms);
in
Some (gr3, mk_app brack (Pretty.block (pretty_mixfix ms ps1 ps3)) ps2)
end
end
| None => (case get_defn thy s T of
None => None
| Some ((args, rhs), k) =>
let
val id = mk_const_id (sign_of thy) s ^ (case k of
None => "" | Some i => "_def" ^ string_of_int i);
val (gr', ps) = codegens true (gr, ts);
in
Some (Graph.add_edge (id, dep) gr' handle Graph.UNDEF _ =>
let
val _ = message ("expanding definition of " ^ s);
val (Ts, _) = strip_type T;
val (args', rhs') =
if not (null args) orelse null Ts then (args, rhs) else
let val v = Free (new_name rhs "x", hd Ts)
in ([v], betapply (rhs, v)) end;
val (gr1, p) = invoke_codegen thy id false
(Graph.add_edge (id, dep)
(Graph.new_node (id, (None, "")) gr'), rhs');
val (gr2, xs) = codegens false (gr1, args');
val (gr3, ty) = invoke_tycodegen thy id false (gr2, T);
in Graph.map_node id (K (None, Pretty.string_of (Pretty.block
(separate (Pretty.brk 1) (if null args' then
[Pretty.str ("val " ^ id ^ " :"), ty]
else Pretty.str ("fun " ^ id) :: xs) @
[Pretty.str " =", Pretty.brk 1, p, Pretty.str ";"])) ^ "\n\n")) gr3
end, mk_app brack (Pretty.str id) ps)
end))
| Abs _ =>
let
val (bs, Ts) = ListPair.unzip (strip_abs_vars u);
val t = strip_abs_body u
val bs' = new_names t bs;
val (gr1, ps) = codegens true (gr, ts);
val (gr2, p) = invoke_codegen thy dep false
(gr1, subst_bounds (map Free (rev (bs' ~~ Ts)), t));
in
Some (gr2, mk_app brack (Pretty.block (Pretty.str "(" :: pretty_fn bs' p @
[Pretty.str ")"])) ps)
end
| _ => None)
end;
fun default_tycodegen thy gr dep brack (TVar ((s, i), _)) =
Some (gr, Pretty.str (s ^ (if i = 0 then "" else string_of_int i)))
| default_tycodegen thy gr dep brack (TFree (s, _)) = Some (gr, Pretty.str s)
| default_tycodegen thy gr dep brack (Type (s, Ts)) =
(case assoc (#types (CodegenData.get thy), s) of
None => None
| Some ms =>
let
val (gr', ps) = foldl_map
(invoke_tycodegen thy dep false) (gr, fst (args_of ms Ts));
val (gr'', qs) = foldl_map
(invoke_tycodegen thy dep false) (gr', quotes_of ms)
in Some (gr'', Pretty.block (pretty_mixfix ms ps qs)) end);
fun output_code gr xs = implode (map (snd o Graph.get_node gr)
(rev (Graph.all_preds gr xs)));
fun gen_generate_code prep_term thy =
setmp print_mode [] (Pretty.setmp_margin (!margin) (fn xs =>
let
val sg = sign_of thy;
val gr = Graph.new_node ("<Top>", (None, "")) Graph.empty;
val (gr', ps) = foldl_map (fn (gr, (s, t)) => apsnd (pair s)
(invoke_codegen thy "<Top>" false (gr, t)))
(gr, map (apsnd (prep_term sg)) xs)
in
"structure Generated =\nstruct\n\n" ^
output_code gr' ["<Top>"] ^
space_implode "\n\n" (map (fn (s', p) => Pretty.string_of (Pretty.block
[Pretty.str ("val " ^ s' ^ " ="), Pretty.brk 1, p, Pretty.str ";"])) ps) ^
"\n\nend;\n\nopen Generated;\n"
end));
val generate_code_i = gen_generate_code (K I);
val generate_code = gen_generate_code
(fn sg => term_of o read_cterm sg o rpair TypeInfer.logicT);
(**** Reflection ****)
val strip_tname = implode o tl o explode;
fun pretty_list xs = Pretty.block (Pretty.str "[" ::
flat (separate [Pretty.str ",", Pretty.brk 1] (map single xs)) @
[Pretty.str "]"]);
fun mk_type p (TVar ((s, i), _)) = Pretty.str
(strip_tname s ^ (if i = 0 then "" else string_of_int i) ^ "T")
| mk_type p (TFree (s, _)) = Pretty.str (strip_tname s ^ "T")
| mk_type p (Type (s, Ts)) = (if p then parens else I) (Pretty.block
[Pretty.str "Type", Pretty.brk 1, Pretty.str ("(\"" ^ s ^ "\","),
Pretty.brk 1, pretty_list (map (mk_type false) Ts), Pretty.str ")"]);
fun mk_term_of sg p (TVar ((s, i), _)) = Pretty.str
(strip_tname s ^ (if i = 0 then "" else string_of_int i) ^ "F")
| mk_term_of sg p (TFree (s, _)) = Pretty.str (strip_tname s ^ "F")
| mk_term_of sg p (Type (s, Ts)) = (if p then parens else I) (Pretty.block
(separate (Pretty.brk 1) (Pretty.str ("term_of_" ^ mk_type_id sg s) ::
flat (map (fn T => [mk_term_of sg true T, mk_type true T]) Ts))));
(**** Test data generators ****)
fun mk_gen sg p xs a (TVar ((s, i), _)) = Pretty.str
(strip_tname s ^ (if i = 0 then "" else string_of_int i) ^ "G")
| mk_gen sg p xs a (TFree (s, _)) = Pretty.str (strip_tname s ^ "G")
| mk_gen sg p xs a (Type (s, Ts)) = (if p then parens else I) (Pretty.block
(separate (Pretty.brk 1) (Pretty.str ("gen_" ^ mk_type_id sg s ^
(if s mem xs then "'" else "")) :: map (mk_gen sg true xs a) Ts @
(if s mem xs then [Pretty.str a] else []))));
val test_fn : (int -> (string * term) list option) ref = ref (fn _ => None);
fun test_term thy sz i t =
let
val _ = assert (null (term_tvars t) andalso null (term_tfrees t))
"Term to be tested contains type variables";
val _ = assert (null (term_vars t))
"Term to be tested contains schematic variables";
val sg = sign_of thy;
val frees = map dest_Free (term_frees t);
val szname = variant (map fst frees) "i";
val s = "structure TestTerm =\nstruct\n\n" ^
setmp mode ["term_of", "test"] (generate_code_i thy)
[("testf", list_abs_free (frees, t))] ^
"\n" ^ Pretty.string_of
(Pretty.block [Pretty.str "val () = Codegen.test_fn :=",
Pretty.brk 1, Pretty.str ("(fn " ^ szname ^ " =>"), Pretty.brk 1,
Pretty.blk (0, [Pretty.str "let", Pretty.brk 1,
Pretty.blk (0, separate Pretty.fbrk (map (fn (s, T) =>
Pretty.block [Pretty.str ("val " ^ s ^ " ="), Pretty.brk 1,
mk_gen sg false [] "" T, Pretty.brk 1,
Pretty.str (szname ^ ";")]) frees)),
Pretty.brk 1, Pretty.str "in", Pretty.brk 1,
Pretty.block [Pretty.str "if ",
mk_app false (Pretty.str "testf") (map (Pretty.str o fst) frees),
Pretty.brk 1, Pretty.str "then Library.None",
Pretty.brk 1, Pretty.str "else ",
Pretty.block [Pretty.str "Library.Some ", Pretty.block (Pretty.str "[" ::
flat (separate [Pretty.str ",", Pretty.brk 1]
(map (fn (s, T) => [Pretty.block
[Pretty.str ("(" ^ Library.quote s ^ ","), Pretty.brk 1,
mk_app false (mk_term_of sg false T)
[Pretty.str s], Pretty.str ")"]]) frees)) @
[Pretty.str "]"])]],
Pretty.brk 1, Pretty.str "end"]), Pretty.str ");"]) ^
"\n\nend;\n";
val _ = use_text Context.ml_output false s;
fun iter f k = if k > i then None
else (case (f () handle Match =>
(warning "Exception Match raised in generated code"; None)) of
None => iter f (k+1) | Some x => Some x);
fun test k = if k > sz then None
else (priority ("Test data size: " ^ string_of_int k);
case iter (fn () => !test_fn k) 1 of
None => test (k+1) | Some x => Some x);
in test 0 end;
fun test_goal ({size, iterations, default_type}, tvinsts) i st =
let
val sg = Toplevel.sign_of st;
fun strip (Const ("all", _) $ Abs (_, _, t)) = strip t
| strip t = t;
val (gi, frees) = Logic.goal_params
(prop_of (snd (snd (Proof.get_goal (Toplevel.proof_of st))))) i;
val gi' = ObjectLogic.atomize_term sg (map_term_types
(map_type_tfree (fn p as (s, _) => if_none (assoc (tvinsts, s))
(if_none default_type (TFree p)))) (subst_bounds (frees, strip gi)));
in case test_term (Toplevel.theory_of st) size iterations gi' of
None => writeln "No counterexamples found."
| Some cex => writeln ("Counterexample found:\n" ^
Pretty.string_of (Pretty.chunks (map (fn (s, t) =>
Pretty.block [Pretty.str (s ^ " ="), Pretty.brk 1,
Sign.pretty_term sg t]) cex)))
end;
(**** Interface ****)
val str = setmp print_mode [] Pretty.str;
fun parse_mixfix rd s =
(case Scan.finite Symbol.stopper (Scan.repeat
( $$ "_" >> K Arg
|| $$ "?" >> K Ignore
|| $$ "/" |-- Scan.repeat ($$ " ") >> (Pretty o Pretty.brk o length)
|| $$ "{" |-- $$ "*" |-- Scan.repeat1
( $$ "'" |-- Scan.one Symbol.not_eof
|| Scan.unless ($$ "*" -- $$ "}") (Scan.one Symbol.not_eof)) --|
$$ "*" --| $$ "}" >> (Quote o rd o implode)
|| Scan.repeat1
( $$ "'" |-- Scan.one Symbol.not_eof
|| Scan.unless ($$ "_" || $$ "?" || $$ "/" || $$ "{" |-- $$ "*")
(Scan.one Symbol.not_eof)) >> (Pretty o str o implode)))
(Symbol.explode s) of
(p, []) => p
| _ => error ("Malformed annotation: " ^ quote s));
structure P = OuterParse and K = OuterSyntax.Keyword;
val assoc_typeP =
OuterSyntax.command "types_code"
"associate types with target language types" K.thy_decl
(Scan.repeat1 (P.xname --| P.$$$ "(" -- P.string --| P.$$$ ")") >>
(fn xs => Toplevel.theory (fn thy => assoc_types
(map (fn (name, mfx) => (name, parse_mixfix
(typ_of o read_ctyp (sign_of thy)) mfx)) xs) thy)));
val assoc_constP =
OuterSyntax.command "consts_code"
"associate constants with target language code" K.thy_decl
(Scan.repeat1
(P.xname -- (Scan.option (P.$$$ "::" |-- P.typ)) --|
P.$$$ "(" -- P.string --| P.$$$ ")") >>
(fn xs => Toplevel.theory (fn thy => assoc_consts
(map (fn ((name, optype), mfx) => (name, optype, parse_mixfix
(term_of o read_cterm (sign_of thy) o rpair TypeInfer.logicT) mfx))
xs) thy)));
val generate_codeP =
OuterSyntax.command "generate_code" "generates code for terms" K.thy_decl
(Scan.option (P.$$$ "(" |-- P.name --| P.$$$ ")") --
Scan.optional (P.$$$ "[" |-- P.enum "," P.xname --| P.$$$ "]") (!mode) --
Scan.repeat1 (P.name --| P.$$$ "=" -- P.term) >>
(fn ((opt_fname, mode'), xs) => Toplevel.theory (fn thy =>
((case opt_fname of
None => use_text Context.ml_output false
| Some fname => File.write (Path.unpack fname))
(setmp mode mode' (generate_code thy) xs); thy))));
val params =
[("size", P.nat >> (K o set_size)),
("iterations", P.nat >> (K o set_iterations)),
("default_type", P.typ >> set_default_type)];
val parse_test_params = P.short_ident :-- (fn s =>
P.$$$ "=" |-- if_none (assoc (params, s)) Scan.fail) >> snd;
fun parse_tyinst xs =
(P.type_ident --| P.$$$ "=" -- P.typ >> (fn (v, s) => fn sg =>
fn (x, ys) => (x, (v, typ_of (read_ctyp sg s)) :: ys))) xs;
fun app [] x = x
| app (f :: fs) x = app fs (f x);
val test_paramsP =
OuterSyntax.command "quickcheck_params" "set parameters for random testing" K.thy_decl
(P.$$$ "[" |-- P.list1 parse_test_params --| P.$$$ "]" >>
(fn fs => Toplevel.theory (fn thy =>
map_test_params (app (map (fn f => f (sign_of thy)) fs)) thy)));
val testP =
OuterSyntax.command "quickcheck" "try to find counterexample for subgoal" K.diag
(Scan.option (P.$$$ "[" |-- P.list1
( parse_test_params >> (fn f => fn sg => apfst (f sg))
|| parse_tyinst) --| P.$$$ "]") -- Scan.optional P.nat 1 >>
(fn (ps, g) => Toplevel.keep (fn st =>
test_goal (app (if_none (apsome
(map (fn f => f (Toplevel.sign_of st))) ps) [])
(get_test_params (Toplevel.theory_of st), [])) g st)));
val parsers = [assoc_typeP, assoc_constP, generate_codeP, test_paramsP, testP];
val setup =
[CodegenData.init,
add_codegen "default" default_codegen,
add_tycodegen "default" default_tycodegen,
assoc_types [("fun", parse_mixfix (K dummyT) "(_ ->/ _)")],
Attrib.add_attributes [("code",
(code_attr, K Attrib.undef_local_attribute),
"declare theorems for code generation")]];
end;
OuterSyntax.add_parsers Codegen.parsers;