(* Title: Tools/Code/code_runtime.ML
Author: Florian Haftmann, TU Muenchen
Runtime services building on code generation into implementation language SML.
*)
signature CODE_RUNTIME =
sig
val target: string
val value: Proof.context ->
(Proof.context -> unit -> 'a) * ((unit -> 'a) -> Proof.context -> Proof.context) * string ->
string * string -> 'a
type 'a cookie = (Proof.context -> unit -> 'a) * ((unit -> 'a) -> Proof.context -> Proof.context) * string
val dynamic_value: 'a cookie -> Proof.context -> string option
-> ((term -> term) -> 'a -> 'a) -> term -> string list -> 'a option
val dynamic_value_strict: 'a cookie -> Proof.context -> string option
-> ((term -> term) -> 'a -> 'a) -> term -> string list -> 'a
val dynamic_value_exn: 'a cookie -> Proof.context -> string option
-> ((term -> term) -> 'a -> 'a) -> term -> string list -> 'a Exn.result
val static_value: 'a cookie -> Proof.context -> string option
-> ((term -> term) -> 'a -> 'a) -> string list -> Proof.context -> term -> 'a option
val static_value_strict: 'a cookie -> Proof.context -> string option
-> ((term -> term) -> 'a -> 'a) -> string list -> Proof.context -> term -> 'a
val static_value_exn: 'a cookie -> Proof.context -> string option
-> ((term -> term) -> 'a -> 'a) -> string list -> Proof.context -> term -> 'a Exn.result
val dynamic_holds_conv: Proof.context -> conv
val static_holds_conv: Proof.context -> string list -> Proof.context -> conv
val code_reflect: (string * string list option) list -> string list -> string
-> string option -> theory -> theory
datatype truth = Holds
val put_truth: (unit -> truth) -> Proof.context -> Proof.context
val trace: bool Unsynchronized.ref
val polyml_as_definition: (binding * typ) list -> Path.T list -> theory -> theory
end;
structure Code_Runtime : CODE_RUNTIME =
struct
open Basic_Code_Symbol;
open Basic_Code_Thingol;
(** evaluation **)
(* technical prerequisites *)
val this = "Code_Runtime";
val s_truth = Long_Name.append this "truth";
val s_Holds = Long_Name.append this "Holds";
val target = "Eval";
val structure_generated = "Generated_Code";
datatype truth = Holds;
val _ = Theory.setup
(Code_Target.extend_target (target, (Code_ML.target_SML, I))
#> Code_Target.set_printings (Type_Constructor (@{type_name prop},
[(target, SOME (0, (K o K o K) (Code_Printer.str s_truth)))]))
#> Code_Target.set_printings (Constant (@{const_name Code_Generator.holds},
[(target, SOME (Code_Printer.plain_const_syntax s_Holds))]))
#> Code_Target.add_reserved target this
#> fold (Code_Target.add_reserved target) ["oo", "ooo", "oooo", "upto", "downto", "orf", "andf"]);
(*avoid further pervasive infix names*)
val trace = Unsynchronized.ref false;
fun exec verbose code =
(if ! trace then tracing code else ();
ML_Context.exec (fn () => Secure.use_text ML_Env.local_context (0, "generated code") verbose code));
fun value ctxt (get, put, put_ml) (prelude, value) =
let
val code = (prelude
^ "\nval _ = Context.set_thread_data (SOME (Context.map_proof (" ^ put_ml
^ " (fn () => " ^ value ^ ")) (ML_Context.the_generic_context ())))");
val ctxt' = ctxt
|> put (fn () => error ("Bad evaluation for " ^ quote put_ml))
|> Context.proof_map (exec false code);
in get ctxt' () end;
(* evaluation into target language values *)
type 'a cookie = (Proof.context -> unit -> 'a) * ((unit -> 'a) -> Proof.context -> Proof.context) * string;
fun reject_vars ctxt t =
((Sign.no_frees ctxt o Sign.no_vars ctxt o map_types (K dummyT)) t; t);
fun obtain_evaluator ctxt some_target program consts =
let
val evaluator' = Code_Target.evaluator ctxt (the_default target some_target) program consts false;
in
evaluator'
#> apfst (fn ml_modules => space_implode "\n\n" (map snd ml_modules))
end;
fun evaluation cookie ctxt evaluator vs_t args =
let
val (program_code, value_name) = evaluator vs_t;
val value_code = space_implode " "
(value_name :: "()" :: map (enclose "(" ")") args);
in Exn.interruptible_capture (value ctxt cookie) (program_code, value_code) end;
fun partiality_as_none e = SOME (Exn.release e)
handle General.Match => NONE
| General.Bind => NONE
| General.Fail _ => NONE;
fun dynamic_value_exn cookie ctxt some_target postproc t args =
let
val _ = reject_vars ctxt t;
val _ = if ! trace
then tracing ("Evaluation of term " ^ quote (Syntax.string_of_term ctxt t))
else ()
fun evaluator program ((_, vs_ty), t) deps =
evaluation cookie ctxt (obtain_evaluator ctxt some_target program deps) (vs_ty, t) args;
in Code_Thingol.dynamic_value ctxt (Exn.map_result o postproc) evaluator t end;
fun dynamic_value_strict cookie ctxt some_target postproc t args =
Exn.release (dynamic_value_exn cookie ctxt some_target postproc t args);
fun dynamic_value cookie ctxt some_target postproc t args =
partiality_as_none (dynamic_value_exn cookie ctxt some_target postproc t args);
fun static_evaluator cookie ctxt some_target program consts' =
let
val evaluator = obtain_evaluator ctxt some_target program (map Constant consts');
val evaluation' = evaluation cookie ctxt evaluator;
in fn _ => fn ((_, vs_ty), t) => fn _ => evaluation' (vs_ty, t) [] end;
fun static_value_exn cookie ctxt some_target postproc consts =
let
val evaluator = Code_Thingol.static_value ctxt (Exn.map_result o postproc) consts
(static_evaluator cookie ctxt some_target);
in fn ctxt' => evaluator ctxt' o reject_vars ctxt' end;
fun static_value_strict cookie ctxt some_target postproc consts =
Exn.release oo static_value_exn cookie ctxt some_target postproc consts;
fun static_value cookie thy some_target postproc consts =
partiality_as_none oo static_value_exn cookie thy some_target postproc consts;
(* evaluation for truth or nothing *)
structure Truth_Result = Proof_Data
(
type T = unit -> truth
(* FIXME avoid user error with non-user text *)
fun init _ () = error "Truth_Result"
);
val put_truth = Truth_Result.put;
val truth_cookie = (Truth_Result.get, put_truth, Long_Name.append this "put_truth");
val reject_vars = fn ctxt => tap (reject_vars ctxt o Thm.term_of);
local
fun check_holds ctxt evaluator vs_t ct =
let
val thy = Proof_Context.theory_of ctxt;
val t = Thm.term_of ct;
val _ = if fastype_of t <> propT
then error ("Not a proposition: " ^ Syntax.string_of_term_global thy t)
else ();
val iff = Thm.cterm_of thy (Term.Const (@{const_name Pure.eq}, propT --> propT --> propT));
val result = case partiality_as_none (evaluation truth_cookie ctxt evaluator vs_t [])
of SOME Holds => true
| _ => false;
in
Thm.mk_binop iff ct (if result then @{cprop "PROP Code_Generator.holds"} else ct)
end;
val (_, raw_check_holds_oracle) = Context.>>> (Context.map_theory_result
(Thm.add_oracle (@{binding holds_by_evaluation},
fn (ctxt, evaluator, vs_t, ct) => check_holds ctxt evaluator vs_t ct)));
fun check_holds_oracle ctxt evaluator ((_, vs_ty), t) deps ct =
raw_check_holds_oracle (ctxt, evaluator, (vs_ty, t), ct);
in
fun dynamic_holds_conv ctxt = Code_Thingol.dynamic_conv ctxt
(fn program => fn vs_t => fn deps =>
check_holds_oracle ctxt (obtain_evaluator ctxt NONE program deps) vs_t deps)
o reject_vars ctxt;
fun static_holds_conv ctxt consts =
Code_Thingol.static_conv ctxt consts (fn program => fn consts' =>
let
val evaluator' = obtain_evaluator ctxt NONE program (map Constant consts')
in
fn ctxt' => fn vs_t => fn deps => check_holds_oracle ctxt' evaluator' vs_t deps o reject_vars ctxt'
end);
(* o reject_vars ctxt'*)
end; (*local*)
(** instrumentalization **)
fun evaluation_code ctxt module_name tycos consts =
let
val thy = Proof_Context.theory_of ctxt;
val program = Code_Thingol.consts_program thy consts;
val (ml_modules, target_names) =
Code_Target.produce_code_for ctxt
target NONE module_name [] program false (map Constant consts @ map Type_Constructor tycos);
val ml_code = space_implode "\n\n" (map snd ml_modules);
val (consts', tycos') = chop (length consts) target_names;
val consts_map = map2 (fn const =>
fn NONE =>
error ("Constant " ^ (quote o Code.string_of_const thy) const ^
"\nhas a user-defined serialization")
| SOME const' => (const, const')) consts consts'
val tycos_map = map2 (fn tyco =>
fn NONE =>
error ("Type " ^ quote (Proof_Context.markup_type ctxt tyco) ^
"\nhas a user-defined serialization")
| SOME tyco' => (tyco, tyco')) tycos tycos';
in (ml_code, (tycos_map, consts_map)) end;
(* by antiquotation *)
local
structure Code_Antiq_Data = Proof_Data
(
type T = (string list * string list) * (bool
* (string * (string * string) list) lazy);
fun init _ = (([], []), (true, (Lazy.value ("", []))));
);
val is_first_occ = fst o snd o Code_Antiq_Data.get;
fun register_code new_tycos new_consts ctxt =
let
val ((tycos, consts), _) = Code_Antiq_Data.get ctxt;
val tycos' = fold (insert (op =)) new_tycos tycos;
val consts' = fold (insert (op =)) new_consts consts;
val acc_code = Lazy.lazy (fn () =>
evaluation_code ctxt structure_generated tycos' consts'
|> apsnd snd);
in Code_Antiq_Data.put ((tycos', consts'), (false, acc_code)) ctxt end;
fun register_const const = register_code [] [const];
fun print_code is_first const ctxt =
let
val (_, (_, acc_code)) = Code_Antiq_Data.get ctxt;
val (ml_code, consts_map) = Lazy.force acc_code;
val ml_code = if is_first then ml_code else "";
val body = "Isabelle." ^ the (AList.lookup (op =) consts_map const);
in (ml_code, body) end;
in
fun ml_code_antiq raw_const ctxt =
let
val thy = Proof_Context.theory_of ctxt;
val const = Code.check_const thy raw_const;
val is_first = is_first_occ ctxt;
in (print_code is_first const, register_const const ctxt) end;
end; (*local*)
(* reflection support *)
fun check_datatype thy tyco some_consts =
let
val constrs = (map fst o snd o fst o Code.get_type thy) tyco;
val _ = case some_consts
of SOME consts =>
let
val missing_constrs = subtract (op =) consts constrs;
val _ = if null missing_constrs then []
else error ("Missing constructor(s) " ^ commas_quote missing_constrs
^ " for datatype " ^ quote tyco);
val false_constrs = subtract (op =) constrs consts;
val _ = if null false_constrs then []
else error ("Non-constructor(s) " ^ commas_quote false_constrs
^ " for datatype " ^ quote tyco)
in () end
| NONE => ();
in (tyco, constrs) end;
fun add_eval_tyco (tyco, tyco') thy =
let
val k = Sign.arity_number thy tyco;
fun pr pr' _ [] = tyco'
| pr pr' _ [ty] =
Code_Printer.concat [pr' Code_Printer.BR ty, tyco']
| pr pr' _ tys =
Code_Printer.concat [Code_Printer.enum "," "(" ")" (map (pr' Code_Printer.BR) tys), tyco']
in
thy
|> Code_Target.set_printings (Type_Constructor (tyco, [(target, SOME (k, pr))]))
end;
fun add_eval_constr (const, const') thy =
let
val k = Code.args_number thy const;
fun pr pr' fxy ts = Code_Printer.brackify fxy
(const' :: the_list (Code_Printer.tuplify pr' Code_Printer.BR (map fst ts)));
in
thy
|> Code_Target.set_printings (Constant (const,
[(target, SOME (Code_Printer.simple_const_syntax (k, pr)))]))
end;
fun add_eval_const (const, const') = Code_Target.set_printings (Constant
(const, [(target, SOME (Code_Printer.simple_const_syntax (0, (K o K o K) const')))]));
fun process_reflection (code, (tyco_map, (constr_map, const_map))) module_name NONE thy =
thy
|> Code_Target.add_reserved target module_name
|> Context.theory_map (exec true code)
|> fold (add_eval_tyco o apsnd Code_Printer.str) tyco_map
|> fold (add_eval_constr o apsnd Code_Printer.str) constr_map
|> fold (add_eval_const o apsnd Code_Printer.str) const_map
| process_reflection (code, _) _ (SOME file_name) thy =
let
val preamble =
"(* Generated from " ^
Path.implode (Resources.thy_path (Path.basic (Context.theory_name thy))) ^
"; DO NOT EDIT! *)";
val _ = File.write (Path.explode file_name) (preamble ^ "\n\n" ^ code);
in
thy
end;
fun gen_code_reflect prep_type prep_const raw_datatypes raw_functions module_name some_file thy =
let
val ctxt = Proof_Context.init_global thy;
val datatypes = map (fn (raw_tyco, raw_cos) =>
(prep_type ctxt raw_tyco, (Option.map o map) (prep_const thy) raw_cos)) raw_datatypes;
val (tycos, constrs) = map_split (uncurry (check_datatype thy)) datatypes
|> apsnd flat;
val functions = map (prep_const thy) raw_functions;
val result = evaluation_code ctxt module_name tycos (constrs @ functions)
|> (apsnd o apsnd) (chop (length constrs));
in
thy
|> process_reflection result module_name some_file
end;
val code_reflect = gen_code_reflect Code_Target.cert_tyco (K I);
val code_reflect_cmd = gen_code_reflect Code_Target.read_tyco Code.read_const;
(** Isar setup **)
val _ =
Theory.setup (ML_Antiquotation.declaration @{binding code} Args.term (fn _ => ml_code_antiq));
local
val parse_datatype =
Parse.name --| @{keyword "="} --
(((Parse.sym_ident || Parse.string) >> (fn "_" => NONE | _ => Scan.fail ()))
|| ((Parse.term ::: (Scan.repeat (@{keyword "|"} |-- Parse.term))) >> SOME));
in
val _ =
Outer_Syntax.command @{command_spec "code_reflect"}
"enrich runtime environment with generated code"
(Parse.name -- Scan.optional (@{keyword "datatypes"} |-- Parse.!!! (parse_datatype
::: Scan.repeat (@{keyword "and"} |-- parse_datatype))) []
-- Scan.optional (@{keyword "functions"} |-- Parse.!!! (Scan.repeat1 Parse.name)) []
-- Scan.option (@{keyword "file"} |-- Parse.!!! Parse.name)
>> (fn (((module_name, raw_datatypes), raw_functions), some_file) => Toplevel.theory
(code_reflect_cmd raw_datatypes raw_functions module_name some_file)));
end; (*local*)
(** using external SML files as substitute for proper definitions -- only for polyml! **)
local
structure Loaded_Values = Theory_Data
(
type T = string list
val empty = []
val extend = I
fun merge data : T = Library.merge (op =) data
);
fun notify_val (string, value) =
let
val _ = #enterVal ML_Env.local_name_space (string, value);
val _ = Theory.setup (Loaded_Values.map (insert (op =) string));
in () end;
fun abort _ = error "Only value bindings allowed.";
val notifying_context : use_context =
{tune_source = #tune_source ML_Env.local_context,
name_space =
{lookupVal = #lookupVal ML_Env.local_name_space,
lookupType = #lookupType ML_Env.local_name_space,
lookupFix = #lookupFix ML_Env.local_name_space,
lookupStruct = #lookupStruct ML_Env.local_name_space,
lookupSig = #lookupSig ML_Env.local_name_space,
lookupFunct = #lookupFunct ML_Env.local_name_space,
enterVal = notify_val,
enterType = abort,
enterFix = abort,
enterStruct = abort,
enterSig = abort,
enterFunct = abort,
allVal = #allVal ML_Env.local_name_space,
allType = #allType ML_Env.local_name_space,
allFix = #allFix ML_Env.local_name_space,
allStruct = #allStruct ML_Env.local_name_space,
allSig = #allSig ML_Env.local_name_space,
allFunct = #allFunct ML_Env.local_name_space},
str_of_pos = #str_of_pos ML_Env.local_context,
print = #print ML_Env.local_context,
error = #error ML_Env.local_context};
in
fun use_file filepath thy =
let
val thy' = Loaded_Values.put [] thy;
val _ = Context.set_thread_data ((SOME o Context.Theory) thy');
val _ = Secure.use_text notifying_context
(0, Path.implode filepath) false (File.read filepath);
val thy'' = Context.the_theory (Context.the_thread_data ());
val names = Loaded_Values.get thy'';
in (names, thy'') end;
end;
fun add_definiendum (ml_name, (b, T)) thy =
thy
|> Code_Target.add_reserved target ml_name
|> Specification.axiomatization [(b, SOME T, NoSyn)] []
|-> (fn ([Const (const, _)], _) =>
Code_Target.set_printings (Constant (const,
[(target, SOME (Code_Printer.simple_const_syntax (0, (K o K o K o Code_Printer.str) ml_name)))]))
#> tap (fn thy => Code_Target.produce_code (Proof_Context.init_global thy) false [const] target NONE structure_generated []));
fun process_file filepath (definienda, thy) =
let
val (ml_names, thy') = use_file filepath thy;
val superfluous = subtract (fn ((name1, _), name2) => name1 = name2) definienda ml_names;
val _ = if null superfluous then ()
else error ("Value binding(s) " ^ commas_quote superfluous
^ " found in external file " ^ Path.print filepath
^ " not present among the given contants binding(s).");
val these_definienda = AList.make (the o AList.lookup (op =) definienda) ml_names;
val thy'' = fold add_definiendum these_definienda thy';
val definienda' = fold (AList.delete (op =)) ml_names definienda;
in (definienda', thy'') end;
fun polyml_as_definition bTs filepaths thy =
let
val definienda = map (fn bT => ((Binding.name_of o fst) bT, bT)) bTs;
val (remaining, thy') = fold process_file filepaths (definienda, thy);
val _ = if null remaining then ()
else error ("Constant binding(s) " ^ commas_quote (map fst remaining)
^ " not present in external file(s).");
in thy' end;
end; (*struct*)