infrastructure for attaching names to hypothesis in cases; realised via the same tag mechanism as case names
(* Title: Pure/Isar/rule_cases.ML
Author: Markus Wenzel, TU Muenchen
Annotations and local contexts of rules.
*)
infix 1 THEN_ALL_NEW_CASES;
signature BASIC_RULE_CASES =
sig
type cases
type cases_tactic
val CASES: cases -> tactic -> cases_tactic
val NO_CASES: tactic -> cases_tactic
val SUBGOAL_CASES: ((term * int) -> cases_tactic) -> int -> cases_tactic
val THEN_ALL_NEW_CASES: (int -> cases_tactic) * (int -> tactic) -> int -> cases_tactic
end
signature RULE_CASES =
sig
include BASIC_RULE_CASES
datatype T = Case of
{fixes: (binding * typ) list,
assumes: (string * term list) list,
binds: (indexname * term option) list,
cases: (string * T) list}
val case_hypsN: string
val strip_params: term -> (string * typ) list
val make_common: theory * term ->
((string * string list) * string list) list -> cases
val make_nested: term -> theory * term ->
((string * string list) * string list) list -> cases
val apply: term list -> T -> T
val consume: thm list -> thm list -> ('a * int) * thm ->
(('a * (int * thm list)) * thm) Seq.seq
val add_consumes: int -> thm -> thm
val get_consumes: thm -> int
val consumes: int -> attribute
val consumes_default: int -> attribute
val get_constraints: thm -> int
val constraints: int -> attribute
val name: string list -> thm -> thm
val case_names: string list -> attribute
val cases_hyp_names: string list list -> attribute
val case_conclusion: string * string list -> attribute
val is_inner_rule: thm -> bool
val inner_rule: attribute
val save: thm -> thm -> thm
val get: thm -> ((string * string list) * string list) list * int
val rename_params: string list list -> thm -> thm
val params: string list list -> attribute
val internalize_params: thm -> thm
val mutual_rule: Proof.context -> thm list -> (int list * thm) option
val strict_mutual_rule: Proof.context -> thm list -> int list * thm
end;
structure Rule_Cases: RULE_CASES =
struct
(** cases **)
datatype T = Case of
{fixes: (binding * typ) list,
assumes: (string * term list) list,
binds: (indexname * term option) list,
cases: (string * T) list};
type cases = (string * T option) list;
val case_conclN = "case";
val case_hypsN = "hyps";
val case_premsN = "prems";
val strip_params = map (apfst (perhaps (try Name.dest_skolem))) o Logic.strip_params;
local
fun abs xs t = Term.list_abs (xs, t);
fun app us t = Term.betapplys (t, us);
fun dest_binops cs tm =
let
val n = length cs;
fun dest 0 _ = []
| dest 1 t = [t]
| dest k (_ $ t $ u) = t :: dest (k - 1) u
| dest _ _ = raise TERM ("Expected " ^ string_of_int n ^ " binop arguments", [tm]);
in cs ~~ dest n tm end;
fun extract_fixes NONE prop = (strip_params prop, [])
| extract_fixes (SOME outline) prop =
chop (length (Logic.strip_params outline)) (strip_params prop);
fun extract_assumes _ _ NONE prop = ([("", Logic.strip_assums_hyp prop)], [])
| extract_assumes qual hnames (SOME outline) prop =
let
val (hyps, prems) =
chop (length (Logic.strip_assums_hyp outline)) (Logic.strip_assums_hyp prop)
fun extract ((hname,h)::ps) = (qual hname, h :: map snd ps);
val (hyps1,hyps2) = chop (length hnames) hyps;
val pairs1 = if hyps1 = [] then [] else hnames ~~ hyps1;
val pairs = pairs1 @ (map (pair case_hypsN) hyps2);
val named_hyps = map extract (partition_eq (eq_fst op =) pairs)
in (named_hyps, [(qual case_premsN, prems)]) end;
fun bindings args = map (apfst Binding.name) args;
fun extract_case thy (case_outline, raw_prop) name hnames concls =
let
val props = Logic.dest_conjunctions (Drule.norm_hhf thy raw_prop);
val len = length props;
val nested = is_some case_outline andalso len > 1;
fun extract prop =
let
val (fixes1, fixes2) = extract_fixes case_outline prop;
val abs_fixes = abs (fixes1 @ fixes2);
fun abs_fixes1 t =
if not nested then abs_fixes t
else abs fixes1 (app (map (Term.dummy_pattern o #2) fixes2) (abs fixes2 t));
val (assumes1, assumes2) = extract_assumes (Long_Name.qualify name) hnames case_outline prop
|> pairself (map (apsnd (maps Logic.dest_conjunctions)));
val concl = Object_Logic.drop_judgment thy (Logic.strip_assums_concl prop);
val binds =
(case_conclN, concl) :: dest_binops concls concl
|> map (fn (x, t) => ((x, 0), SOME (abs_fixes t)));
in
((fixes1, map (apsnd (map abs_fixes1)) assumes1),
((fixes2, map (apsnd (map abs_fixes)) assumes2), binds))
end;
val cases = map extract props;
fun common_case ((fixes1, assumes1), ((fixes2, assumes2), binds)) =
Case {fixes = bindings (fixes1 @ fixes2),
assumes = assumes1 @ assumes2, binds = binds, cases = []};
fun inner_case (_, ((fixes2, assumes2), binds)) =
Case {fixes = bindings fixes2, assumes = assumes2, binds = binds, cases = []};
fun nested_case ((fixes1, assumes1), _) =
Case {fixes = bindings fixes1, assumes = assumes1, binds = [],
cases = map string_of_int (1 upto len) ~~ map inner_case cases};
in
if len = 0 then NONE
else if len = 1 then SOME (common_case (hd cases))
else if is_none case_outline orelse length (distinct (op =) (map fst cases)) > 1 then NONE
else SOME (nested_case (hd cases))
end;
fun make rule_struct (thy, prop) cases =
let
val n = length cases;
val nprems = Logic.count_prems prop;
fun add_case ((name, hnames), concls) (cs, i) =
((case try (fn () =>
(Option.map (curry Logic.nth_prem i) rule_struct, Logic.nth_prem (i, prop))) () of
NONE => (name, NONE)
| SOME p => (name, extract_case thy p name hnames concls)) :: cs, i - 1);
in fold_rev add_case (drop (Int.max (n - nprems, 0)) cases) ([], n) |> #1 end;
in
val make_common = make NONE;
fun make_nested rule_struct = make (SOME rule_struct);
fun apply args =
let
fun appl (Case {fixes, assumes, binds, cases}) =
let
val assumes' = map (apsnd (map (app args))) assumes;
val binds' = map (apsnd (Option.map (app args))) binds;
val cases' = map (apsnd appl) cases;
in Case {fixes = fixes, assumes = assumes', binds = binds', cases = cases'} end;
in appl end;
end;
(** tactics with cases **)
type cases_tactic = thm -> (cases * thm) Seq.seq;
fun CASES cases tac st = Seq.map (pair cases) (tac st);
fun NO_CASES tac = CASES [] tac;
fun SUBGOAL_CASES tac i st =
(case try Logic.nth_prem (i, Thm.prop_of st) of
SOME goal => tac (goal, i) st
| NONE => Seq.empty);
fun (tac1 THEN_ALL_NEW_CASES tac2) i st =
st |> tac1 i |> Seq.maps (fn (cases, st') =>
CASES cases (Seq.INTERVAL tac2 i (i + nprems_of st' - nprems_of st)) st');
(** consume facts **)
local
fun unfold_prems n defs th =
if null defs then th
else Conv.fconv_rule (Conv.prems_conv n (Raw_Simplifier.rewrite true defs)) th;
fun unfold_prems_concls defs th =
if null defs orelse not (can Logic.dest_conjunction (Thm.concl_of th)) then th
else
Conv.fconv_rule
(Conv.concl_conv ~1 (Conjunction.convs
(Conv.prems_conv ~1 (Raw_Simplifier.rewrite true defs)))) th;
in
fun consume defs facts ((xx, n), th) =
let val m = Int.min (length facts, n) in
th
|> unfold_prems n defs
|> unfold_prems_concls defs
|> Drule.multi_resolve (take m facts)
|> Seq.map (pair (xx, (n - m, drop m facts)))
end;
end;
val consumes_tagN = "consumes";
fun lookup_consumes th =
(case AList.lookup (op =) (Thm.get_tags th) consumes_tagN of
NONE => NONE
| SOME s =>
(case Lexicon.read_nat s of SOME n => SOME n
| _ => raise THM ("Malformed 'consumes' tag of theorem", 0, [th])));
fun get_consumes th = the_default 0 (lookup_consumes th);
fun put_consumes NONE th = th
| put_consumes (SOME n) th = th
|> Thm.untag_rule consumes_tagN
|> Thm.tag_rule (consumes_tagN, string_of_int (if n < 0 then Thm.nprems_of th + n else n));
fun add_consumes k th = put_consumes (SOME (k + get_consumes th)) th;
val save_consumes = put_consumes o lookup_consumes;
fun consumes n = Thm.rule_attribute (K (put_consumes (SOME n)));
fun consumes_default n x =
if is_some (lookup_consumes (#2 x)) then x else consumes n x;
(** equality constraints **)
val constraints_tagN = "constraints";
fun lookup_constraints th =
(case AList.lookup (op =) (Thm.get_tags th) constraints_tagN of
NONE => NONE
| SOME s =>
(case Lexicon.read_nat s of SOME n => SOME n
| _ => raise THM ("Malformed 'constraints' tag of theorem", 0, [th])));
fun get_constraints th = the_default 0 (lookup_constraints th);
fun put_constraints NONE th = th
| put_constraints (SOME n) th = th
|> Thm.untag_rule constraints_tagN
|> Thm.tag_rule (constraints_tagN, string_of_int (if n < 0 then 0 else n));
val save_constraints = put_constraints o lookup_constraints;
fun constraints n = Thm.rule_attribute (K (put_constraints (SOME n)));
(** case names **)
val implode_args = space_implode ";";
val explode_args = space_explode ";";
val case_names_tagN = "case_names";
fun add_case_names NONE = I
| add_case_names (SOME names) =
Thm.untag_rule case_names_tagN
#> Thm.tag_rule (case_names_tagN, implode_args names);
fun lookup_case_names th =
AList.lookup (op =) (Thm.get_tags th) case_names_tagN
|> Option.map explode_args;
val save_case_names = add_case_names o lookup_case_names;
val name = add_case_names o SOME;
fun case_names ss = Thm.rule_attribute (K (name ss));
(** hyp names **)
val implode_hyps = implode_args o map (suffix "," o space_implode ",");
val explode_hyps = map (space_explode "," o unsuffix ",") o explode_args;
val cases_hyp_names_tagN = "cases_hyp_names";
fun add_cases_hyp_names NONE = I
| add_cases_hyp_names (SOME namess) =
Thm.untag_rule cases_hyp_names_tagN
#> Thm.tag_rule (cases_hyp_names_tagN, implode_hyps namess);
fun lookup_cases_hyp_names th =
AList.lookup (op =) (Thm.get_tags th) cases_hyp_names_tagN
|> Option.map explode_hyps;
val save_cases_hyp_names = add_cases_hyp_names o lookup_cases_hyp_names;
fun cases_hyp_names ss =
Thm.rule_attribute (K (add_cases_hyp_names (SOME ss)));
(** case conclusions **)
val case_concl_tagN = "case_conclusion";
fun get_case_concl name (a, b) =
if a = case_concl_tagN then
(case explode_args b of c :: cs => if c = name then SOME cs else NONE)
else NONE;
fun add_case_concl (name, cs) = Thm.map_tags (fn tags =>
filter_out (is_some o get_case_concl name) tags @
[(case_concl_tagN, implode_args (name :: cs))]);
fun get_case_concls th name =
these (get_first (get_case_concl name) (Thm.get_tags th));
fun save_case_concls th =
let val concls = Thm.get_tags th |> map_filter
(fn (a, b) =>
if a = case_concl_tagN then (case explode_args b of c :: cs => SOME (c, cs) | _ => NONE)
else NONE)
in fold add_case_concl concls end;
fun case_conclusion concl = Thm.rule_attribute (K (add_case_concl concl));
(** inner rule **)
val inner_rule_tagN = "inner_rule";
fun is_inner_rule th =
AList.defined (op =) (Thm.get_tags th) inner_rule_tagN;
fun put_inner_rule inner =
Thm.untag_rule inner_rule_tagN
#> inner ? Thm.tag_rule (inner_rule_tagN, "");
val save_inner_rule = put_inner_rule o is_inner_rule;
val inner_rule = Thm.rule_attribute (K (put_inner_rule true));
(** case declarations **)
(* access hints *)
fun save th =
save_consumes th #>
save_constraints th #>
save_case_names th #>
save_cases_hyp_names th #>
save_case_concls th #>
save_inner_rule th;
fun get th =
let
val n = get_consumes th;
val cases =
(case lookup_case_names th of
NONE => map (rpair [] o Library.string_of_int) (1 upto (Thm.nprems_of th - n))
| SOME names => map (fn name => (name, get_case_concls th name)) names);
val cases_hyps = (case lookup_cases_hyp_names th of
NONE => replicate (length cases) []
| SOME names => names);
fun regroup ((name,concls),hyps) = ((name,hyps),concls)
in (map regroup (cases ~~ cases_hyps), n) end;
(* params *)
fun rename_params xss th =
th
|> fold_index (fn (i, xs) => Thm.rename_params_rule (xs, i + 1)) xss
|> save th;
fun params xss = Thm.rule_attribute (K (rename_params xss));
(* internalize parameter names *)
fun internalize_params rule =
let
fun rename prem =
let val xs =
map (Name.internal o Name.clean o fst) (Logic.strip_params prem)
in Logic.list_rename_params (xs, prem) end;
fun rename_prems prop =
let val (As, C) = Logic.strip_horn prop
in Logic.list_implies (map rename As, C) end;
in Thm.equal_elim (Thm.reflexive (Drule.cterm_fun rename_prems (Thm.cprop_of rule))) rule end;
(** mutual_rule **)
local
fun equal_cterms ts us =
is_equal (list_ord (Term_Ord.fast_term_ord o pairself Thm.term_of) (ts, us));
fun prep_rule n th =
let
val th' = Thm.permute_prems 0 n th;
val prems = take (Thm.nprems_of th' - n) (Drule.cprems_of th');
val th'' = Drule.implies_elim_list th' (map Thm.assume prems);
in (prems, (n, th'')) end;
in
fun mutual_rule _ [] = NONE
| mutual_rule _ [th] = SOME ([0], th)
| mutual_rule ctxt (ths as th :: _) =
let
val ((_, ths'), ctxt') = Variable.import true ths ctxt;
val rules as (prems, _) :: _ = map (prep_rule (get_consumes th)) ths';
val (ns, rls) = split_list (map #2 rules);
in
if not (forall (equal_cterms prems o #1) rules) then NONE
else
SOME (ns,
rls
|> Conjunction.intr_balanced
|> Drule.implies_intr_list prems
|> singleton (Variable.export ctxt' ctxt)
|> save th
|> put_consumes (SOME 0))
end;
end;
fun strict_mutual_rule ctxt ths =
(case mutual_rule ctxt ths of
NONE => error "Failed to join given rules into one mutual rule"
| SOME res => res);
end;
structure Basic_Rule_Cases: BASIC_RULE_CASES = Rule_Cases;
open Basic_Rule_Cases;