(* Auxiliary antiquotations for the tutorial. *)
structure AntiquoteSetup =
struct
open OutputTutorial
(* functions for generating appropriate expressions *)
fun ml_val_open ys xs txt =
let fun ml_val_open_aux ys txt =
"fn " ^ (case ys of [] => "_" | _ => enclose "(" ")" (commas ys)) ^ " => (" ^ txt ^ ")";
in
(case xs of
[] => ml_val_open_aux ys txt
| _ => ml_val_open_aux ys ("let open " ^ (space_implode " " xs) ^ " in " ^ txt ^ " end"))
end;
fun ml_val txt = ml_val_open [] [] txt;
fun ml_pat (lhs, pat) =
let
val pat' = implode (map (fn "\\<dots>" => "_" | s => s) (Symbol.explode pat))
in "val " ^ pat' ^ " = " ^ lhs end;
fun ml_struct txt = "functor DUMMY_FUNCTOR() = struct structure DUMMY = " ^ txt ^ " end";
fun ml_type txt = "val _ = NONE : (" ^ txt ^ ") option";
(* eval function *)
fun eval_fn ctxt exp =
ML_Context.eval_in (SOME ctxt) false Position.none exp
(* string functions *)
fun string_explode prefix_str txt =
map (fn s => prefix_str ^ s) (split_lines txt)
val transform_cmts_str =
Source.of_string
#> ML_Lex.source
#> Source.exhaust
#> Chunks.transform_cmts
#> implode
#> string_explode ""
(* checks and prints open expressions *)
fun output_ml {context = ctxt, ...} (txt, (ovars, structs)) =
(eval_fn ctxt (ml_val_open ovars structs txt);
if structs = []
then output_indexed (transform_cmts_str txt) {main = Code txt, minor = ""}
else output_indexed (transform_cmts_str txt)
{main = Code txt, minor = ("in {\\tt\\slshape{}" ^ (implode structs) ^ "}")})
val parser_ml = Scan.lift (Args.name --
(Scan.optional (Args.$$$ "for" |-- OuterParse.!!! (Scan.repeat1 Args.name)) [] --
Scan.optional (Args.$$$ "in" |-- OuterParse.!!! (Scan.repeat1 Args.name)) []))
(* checks and prints types and structures *)
fun output_struct {context = ctxt, ...} txt =
(eval_fn ctxt (ml_struct txt);
output_indexed (string_explode "" txt) {main = Code txt, minor = "structure"})
fun output_type {context = ctxt, ...} txt =
(eval_fn ctxt (ml_type txt);
output_indexed (string_explode "" txt) {main = Code txt, minor = "type"})
(* checks and expression agains a result pattern *)
fun output_response {context = ctxt, ...} (lhs, pat) =
(eval_fn ctxt (ml_pat (lhs, pat));
output ((string_explode "" lhs) @ (string_explode "> " pat)))
(* checks the expressions, but does not check it against a result pattern *)
fun output_response_fake {context = ctxt, ...} (lhs, pat) =
(eval_fn ctxt (ml_val lhs);
output ((string_explode "" lhs) @ (string_explode "> " pat)))
(* checks the expressions, but does not check it against a result pattern *)
fun ouput_response_fake_both _ (lhs, pat) =
output ((string_explode "" lhs) @ (string_explode "> " pat))
val single_arg = Scan.lift (Args.name)
val two_args = Scan.lift (Args.name -- Args.name)
val _ = ThyOutput.antiquotation "ML" parser_ml output_ml
val _ = ThyOutput.antiquotation "ML_type" single_arg output_type
val _ = ThyOutput.antiquotation "ML_struct" single_arg output_struct
val _ = ThyOutput.antiquotation "ML_response" two_args output_response
val _ = ThyOutput.antiquotation "ML_response_fake" two_args output_response_fake
val _ = ThyOutput.antiquotation "ML_response_fake_both" two_args ouput_response_fake_both
fun href_link txt =
let
val raw = Symbol.encode_raw
val path = "http://isabelle.in.tum.de/repos/isabelle/raw-file/tip/src/"
in
(raw "\\href{") ^ (raw path) ^ (raw txt) ^ (raw "}{") ^ txt ^ (raw "}")
end
(* checks whether a file exists in the Isabelle distribution *)
fun check_file_exists _ txt =
(if File.exists (Path.append (Path.explode ("~~/src")) (Path.explode txt))
then output [href_link txt]
else error ("Source file " ^ (quote txt) ^ " does not exist."))
val _ = ThyOutput.antiquotation "ML_file" single_arg check_file_exists
(* replaces the official subgoal antiquotation with one *)
(* that is closer to the actual output *)
fun output_goals {state = node, ...} _ =
let
fun subgoals 0 = ""
| subgoals 1 = "goal (1 subgoal):"
| subgoals n = "goal (" ^ string_of_int n ^ " subgoals):"
fun proof_state state =
(case try Toplevel.proof_of state of
SOME prf => prf
| _ => error "No proof state")
val state = proof_state node;
val goals = Pretty.chunks (Proof.pretty_goals false state);
val {prop, ...} = rep_thm (Proof.get_goal state |> snd |> snd);
val (As, B) = Logic.strip_horn prop;
val output = (case (length As) of
0 => [goals]
| n => [Pretty.str (subgoals n), goals])
in
ThyOutput.output output
end
val _ = ThyOutput.antiquotation "subgoals" (Scan.succeed ()) output_goals
end;