(* Title: Pure/display.ML
ID: $Id$
Author: Lawrence C Paulson, Cambridge University Computer Laboratory
Copyright 1993 University of Cambridge
Printing of theories, theorems, etc.
*)
signature BASIC_DISPLAY =
sig
val goals_limit: int ref
val show_hyps: bool ref
val show_tags: bool ref
val string_of_thm: thm -> string
val print_thm: thm -> unit
val print_thms: thm list -> unit
val prth: thm -> thm
val prthq: thm Seq.seq -> thm Seq.seq
val prths: thm list -> thm list
val string_of_ctyp: ctyp -> string
val print_ctyp: ctyp -> unit
val string_of_cterm: cterm -> string
val print_cterm: cterm -> unit
val print_syntax: theory -> unit
val show_consts: bool ref
end;
signature DISPLAY =
sig
include BASIC_DISPLAY
val pretty_flexpair: Pretty.pp -> term * term -> Pretty.T
val pretty_thm_aux: Pretty.pp -> bool -> bool -> term list -> thm -> Pretty.T
val pretty_thm_no_quote: thm -> Pretty.T
val pretty_thm: thm -> Pretty.T
val pretty_thms: thm list -> Pretty.T
val pretty_thm_sg: theory -> thm -> Pretty.T
val pretty_thms_sg: theory -> thm list -> Pretty.T
val pprint_thm: thm -> pprint_args -> unit
val pretty_ctyp: ctyp -> Pretty.T
val pprint_ctyp: ctyp -> pprint_args -> unit
val pretty_cterm: cterm -> Pretty.T
val pprint_cterm: cterm -> pprint_args -> unit
val pretty_full_theory: theory -> Pretty.T list
val pretty_goals_aux: Pretty.pp -> string -> bool * bool -> int -> thm -> Pretty.T list
val pretty_goals: int -> thm -> Pretty.T list
val print_goals: int -> thm -> unit
val current_goals_markers: (string * string * string) ref
val pretty_current_goals: int -> int -> thm -> Pretty.T list
val print_current_goals_default: int -> int -> thm -> unit
val print_current_goals_fn: (int -> int -> thm -> unit) ref
end;
structure Display: DISPLAY =
struct
(** print thm **)
val goals_limit = ref 10; (*max number of goals to print*)
val show_hyps = ref false; (*false: print meta-hypotheses as dots*)
val show_tags = ref false; (*false: suppress tags*)
fun pretty_tag (name, args) = Pretty.strs (name :: map Library.quote args);
val pretty_tags = Pretty.list "[" "]" o map pretty_tag;
fun pretty_flexpair pp (t, u) = Pretty.block
[Pretty.term pp t, Pretty.str " =?=", Pretty.brk 1, Pretty.term pp u];
fun pretty_thm_aux pp quote show_hyps' asms raw_th =
let
val th = Thm.strip_shyps raw_th;
val {hyps, tpairs, prop, der = (ora, _), ...} = Thm.rep_thm th;
val xshyps = Thm.extra_shyps th;
val (_, tags) = Thm.get_name_tags th;
val q = if quote then Pretty.quote else I;
val prt_term = q o (Pretty.term pp);
val hyps' = if ! show_hyps then hyps else fold (remove (op aconv)) asms hyps;
val ora' = ora andalso (! show_hyps orelse not (! quick_and_dirty));
val hlen = length xshyps + length hyps' + length tpairs;
val hsymbs =
if hlen = 0 andalso not ora' then []
else if ! show_hyps orelse show_hyps' then
[Pretty.brk 2, Pretty.list "[" "]"
(map (q o pretty_flexpair pp) tpairs @ map prt_term hyps' @
map (Pretty.sort pp) xshyps @
(if ora' then [Pretty.str "!"] else []))]
else [Pretty.brk 2, Pretty.str ("[" ^ implode (replicate hlen ".") ^
(if ora' then "!" else "") ^ "]")];
val tsymbs =
if null tags orelse not (! show_tags) then []
else [Pretty.brk 1, pretty_tags tags];
in Pretty.block (prt_term prop :: (hsymbs @ tsymbs)) end;
fun gen_pretty_thm quote th =
pretty_thm_aux (Sign.pp (Thm.theory_of_thm th)) quote false [] th;
val pretty_thm = gen_pretty_thm true;
val pretty_thm_no_quote = gen_pretty_thm false;
val string_of_thm = Pretty.string_of o pretty_thm;
val pprint_thm = Pretty.pprint o pretty_thm;
fun pretty_thms [th] = pretty_thm th
| pretty_thms ths = Pretty.block (Pretty.fbreaks (map pretty_thm ths));
val pretty_thm_sg = pretty_thm oo Thm.transfer;
val pretty_thms_sg = pretty_thms oo (map o Thm.transfer);
(* top-level commands for printing theorems *)
val print_thm = Pretty.writeln o pretty_thm;
val print_thms = Pretty.writeln o pretty_thms;
fun prth th = (print_thm th; th);
fun prthq thq = (Seq.print (K print_thm) 100000 thq; thq);
fun prths ths = (prthq (Seq.of_list ths); ths);
(* other printing commands *)
fun pretty_ctyp cT =
let val {thy, T, ...} = rep_ctyp cT in Sign.pretty_typ thy T end;
fun pprint_ctyp cT =
let val {thy, T, ...} = rep_ctyp cT in Sign.pprint_typ thy T end;
fun string_of_ctyp cT =
let val {thy, T, ...} = rep_ctyp cT in Sign.string_of_typ thy T end;
val print_ctyp = writeln o string_of_ctyp;
fun pretty_cterm ct =
let val {thy, t, ...} = rep_cterm ct in Sign.pretty_term thy t end;
fun pprint_cterm ct =
let val {thy, t, ...} = rep_cterm ct in Sign.pprint_term thy t end;
fun string_of_cterm ct =
let val {thy, t, ...} = rep_cterm ct in Sign.string_of_term thy t end;
val print_cterm = writeln o string_of_cterm;
(** print theory **)
val print_syntax = Syntax.print_syntax o Sign.syn_of;
(* pretty_full_theory *)
fun pretty_full_theory thy =
let
fun prt_cls c = Sign.pretty_sort thy [c];
fun prt_sort S = Sign.pretty_sort thy S;
fun prt_arity t (c, Ss) = Sign.pretty_arity thy (t, Ss, [c]);
fun prt_typ ty = Pretty.quote (Sign.pretty_typ thy ty);
val prt_typ_no_tvars = prt_typ o Type.freeze_type;
fun prt_term t = Pretty.quote (Sign.pretty_term thy t);
val prt_term_no_vars = prt_term o Logic.unvarify;
fun pretty_classrel (c, []) = prt_cls c
| pretty_classrel (c, cs) = Pretty.block
(prt_cls c :: Pretty.str " <" :: Pretty.brk 1 ::
Pretty.commas (map prt_cls cs));
fun pretty_default S = Pretty.block
[Pretty.str "default sort:", Pretty.brk 1, prt_sort S];
fun pretty_witness NONE = Pretty.str "universal non-emptiness witness: -"
| pretty_witness (SOME (T, S)) = Pretty.block
[Pretty.str "universal non-emptiness witness:", Pretty.brk 1,
prt_typ_no_tvars T, Pretty.str " ::", Pretty.brk 1, prt_sort S];
val tfrees = map (fn v => TFree (v, []));
fun pretty_type syn (t, (Type.LogicalType n, _)) =
if syn then NONE
else SOME (prt_typ (Type (t, tfrees (Term.invent_names [] "'a" n))))
| pretty_type syn (t, (Type.Abbreviation (vs, U, syn'), _)) =
if syn <> syn' then NONE
else SOME (Pretty.block
[prt_typ (Type (t, tfrees vs)), Pretty.str " =", Pretty.brk 1, prt_typ U])
| pretty_type syn (t, (Type.Nonterminal, _)) =
if not syn then NONE
else SOME (prt_typ (Type (t, [])));
val pretty_arities = List.concat o map (fn (t, ars) => map (prt_arity t) ars);
fun pretty_const (c, (ty, rhs)) = Pretty.block
([Pretty.str c, Pretty.str " ::", Pretty.brk 1, prt_typ_no_tvars ty] @
(case rhs of NONE => [] | SOME t => [Pretty.str " ==", Pretty.brk 1, prt_term_no_vars t]));
fun prt_axm (a, t) = Pretty.block [Pretty.str (a ^ ":"), Pretty.brk 1, prt_term_no_vars t];
val {axioms, defs = _, oracles} = Theory.rep_theory thy;
val {naming, syn = _, tsig, consts} = Sign.rep_sg thy;
val {constants, constraints} = Consts.dest consts;
val {classes, default, types, arities, log_types = _, witness} = Type.rep_tsig tsig;
val clsses = NameSpace.dest_table (apsnd (Symtab.make o Graph.dest) classes);
val tdecls = NameSpace.dest_table types;
val arties = NameSpace.dest_table (Sign.type_space thy, arities);
val cnsts = NameSpace.extern_table constants;
val cnstrs = NameSpace.extern_table constraints |> map (apsnd (rpair NONE));
val axms = NameSpace.extern_table axioms;
val oras = NameSpace.extern_table oracles;
in
[Pretty.strs ("names:" :: Context.names_of thy),
Pretty.strs ("theory data:" :: Context.theory_data_of thy),
Pretty.strs ("proof data:" :: Context.proof_data_of thy),
Pretty.strs ["name prefix:", NameSpace.path_of naming],
Pretty.big_list "classes:" (map pretty_classrel clsses),
pretty_default default,
pretty_witness witness,
Pretty.big_list "syntactic types:" (List.mapPartial (pretty_type true) tdecls),
Pretty.big_list "logical types:" (List.mapPartial (pretty_type false) tdecls),
Pretty.big_list "type arities:" (pretty_arities arties),
Pretty.big_list "consts:" (map pretty_const cnsts),
Pretty.big_list "const constraints:" (map pretty_const cnstrs),
Pretty.big_list "axioms:" (map prt_axm axms),
Pretty.strs ("oracles:" :: (map #1 oras))]
end;
(** print_goals **)
(* print_goals etc. *)
val show_consts = ref false; (*true: show consts with types in proof state output*)
(*print thm A1,...,An/B in "goal style" -- premises as numbered subgoals*)
local
fun ins_entry (x, y) [] = [(x, [y])]
| ins_entry (x, y) ((pair as (x', ys')) :: pairs) =
if x = x' then (x', y ins ys') :: pairs
else pair :: ins_entry (x, y) pairs;
fun add_consts (Const (c, T), env) = ins_entry (T, (c, T)) env
| add_consts (t $ u, env) = add_consts (u, add_consts (t, env))
| add_consts (Abs (_, _, t), env) = add_consts (t, env)
| add_consts (_, env) = env;
fun add_vars (Free (x, T), env) = ins_entry (T, (x, ~1)) env
| add_vars (Var (xi, T), env) = ins_entry (T, xi) env
| add_vars (Abs (_, _, t), env) = add_vars (t, env)
| add_vars (t $ u, env) = add_vars (u, add_vars (t, env))
| add_vars (_, env) = env;
fun add_varsT (Type (_, Ts), env) = foldr add_varsT env Ts
| add_varsT (TFree (x, S), env) = ins_entry (S, (x, ~1)) env
| add_varsT (TVar (xi, S), env) = ins_entry (S, xi) env;
fun sort_idxs vs = map (apsnd (sort (prod_ord string_ord int_ord))) vs;
fun sort_cnsts cs = map (apsnd (sort_wrt fst)) cs;
fun consts_of t = sort_cnsts (add_consts (t, []));
fun vars_of t = sort_idxs (add_vars (t, []));
fun varsT_of t = rev (sort_idxs (it_term_types add_varsT (t, [])));
in
fun pretty_goals_aux pp begin_goal (msg, main) maxgoals state =
let
fun prt_atoms prt prtT (X, xs) = Pretty.block
[Pretty.block (Pretty.commas (map prt xs)), Pretty.str " ::",
Pretty.brk 1, prtT X];
fun prt_var (x, ~1) = Pretty.term pp (Syntax.free x)
| prt_var xi = Pretty.term pp (Syntax.var xi);
fun prt_varT (x, ~1) = Pretty.typ pp (TFree (x, []))
| prt_varT xi = Pretty.typ pp (TVar (xi, []));
val prt_consts = prt_atoms (Pretty.term pp o Const) (Pretty.typ pp);
val prt_vars = prt_atoms prt_var (Pretty.typ pp);
val prt_varsT = prt_atoms prt_varT (Pretty.sort pp);
fun pretty_list _ _ [] = []
| pretty_list name prt lst = [Pretty.big_list name (map prt lst)];
fun pretty_subgoal (n, A) = Pretty.blk (0,
[Pretty.str (begin_goal ^ " " ^ string_of_int n ^ ". "), Pretty.term pp A]);
fun pretty_subgoals As = map pretty_subgoal (1 upto length As ~~ As);
val pretty_ffpairs = pretty_list "flex-flex pairs:" (pretty_flexpair pp);
val pretty_consts = pretty_list "constants:" prt_consts o consts_of;
val pretty_vars = pretty_list "variables:" prt_vars o vars_of;
val pretty_varsT = pretty_list "type variables:" prt_varsT o varsT_of;
val {prop, tpairs, ...} = Thm.rep_thm state;
val (As, B) = Logic.strip_horn prop;
val ngoals = length As;
fun pretty_gs (types, sorts) =
(if main then [Pretty.term pp B] else []) @
(if ngoals = 0 then [Pretty.str "No subgoals!"]
else if ngoals > maxgoals then
pretty_subgoals (Library.take (maxgoals, As)) @
(if msg then [Pretty.str ("A total of " ^ string_of_int ngoals ^ " subgoals...")]
else [])
else pretty_subgoals As) @
pretty_ffpairs tpairs @
(if ! show_consts then pretty_consts prop else []) @
(if types then pretty_vars prop else []) @
(if sorts then pretty_varsT prop else []);
in
setmp show_no_free_types true
(setmp show_types (! show_types orelse ! show_sorts orelse ! show_all_types)
(setmp show_sorts false pretty_gs))
(! show_types orelse ! show_sorts orelse ! show_all_types, ! show_sorts)
end;
fun pretty_goals_marker bg n th =
pretty_goals_aux (Sign.pp (Thm.theory_of_thm th)) bg (true, true) n th;
val pretty_goals = pretty_goals_marker "";
val print_goals = (Pretty.writeln o Pretty.chunks) oo pretty_goals_marker "";
end;
(* print_current_goals *)
val current_goals_markers = ref ("", "", "");
fun pretty_current_goals n m th =
let
val ref (begin_state, end_state, begin_goal) = current_goals_markers;
val ngoals = nprems_of th;
in
(if begin_state = "" then [] else [Pretty.str begin_state]) @
[Pretty.str ("Level " ^ string_of_int n ^
(if ngoals > 0 then " (" ^ string_of_int ngoals ^ " subgoal" ^
(if ngoals <> 1 then "s" else "") ^ ")"
else ""))] @
pretty_goals_marker begin_goal m th @
(if end_state = "" then [] else [Pretty.str end_state])
end;
fun print_current_goals_default n m th =
Pretty.writeln (Pretty.chunks (pretty_current_goals n m th));
val print_current_goals_fn = ref print_current_goals_default;
end;
structure BasicDisplay: BASIC_DISPLAY = Display;
open BasicDisplay;