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nets.ml
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nets.ml
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(* ========================================================================= *)
(* Term nets: reasonably fast lookup based on term matchability. *)
(* *)
(* John Harrison, University of Cambridge Computer Laboratory *)
(* *)
(* (c) Copyright, University of Cambridge 1998 *)
(* (c) Copyright, John Harrison 1998-2007 *)
(* ========================================================================= *)
needs "basics.ml";;
(* ------------------------------------------------------------------------- *)
(* Term nets are a finitely branching tree structure; at each level we *)
(* have a set of branches and a set of "values". Linearization is *)
(* performed from the left of a combination; even in iterated *)
(* combinations we look at the head first. This is probably fastest, and *)
(* anyway it's useful to allow our restricted second order matches: if *)
(* the head is a variable then then whole term is treated as a variable. *)
(* ------------------------------------------------------------------------- *)
type term_label = Vnet (* variable (instantiable) *)
| Lcnet of (string * int) (* local constant *)
| Cnet of (string * int) (* constant *)
| Lnet of int;; (* lambda term (abstraction) *)
type 'a net = Netnode of (term_label * 'a net) list * 'a list;;
(* ------------------------------------------------------------------------- *)
(* The empty net. *)
(* ------------------------------------------------------------------------- *)
let empty_net = Netnode([],[]);;
(* ------------------------------------------------------------------------- *)
(* Insert a new element into a net. *)
(* ------------------------------------------------------------------------- *)
let enter =
let label_to_store lconsts tm =
let op,args = strip_comb tm in
if is_const op then Cnet(fst(dest_const op),length args),args
else if is_abs op then
let bv,bod = dest_abs op in
let bod' = if mem bv lconsts then vsubst [genvar(type_of bv),bv] bod
else bod in
Lnet(length args),bod'::args
else if mem op lconsts then Lcnet(fst(dest_var op),length args),args
else Vnet,[] in
let canon_eq x y =
try Pervasives.compare x y = 0 with Invalid_argument _ -> false
and canon_lt x y =
try Pervasives.compare x y < 0 with Invalid_argument _ -> false in
let rec sinsert x l =
if l = [] then [x] else
let h = hd l in
if canon_eq h x then failwith "sinsert" else
if canon_lt x h then x::l else
h::(sinsert x (tl l)) in
let set_insert x l = try sinsert x l with Failure "sinsert" -> l in
let rec net_update lconsts (elem,tms,Netnode(edges,tips)) =
match tms with
[] -> Netnode(edges,set_insert elem tips)
| (tm::rtms) ->
let label,ntms = label_to_store lconsts tm in
let child,others =
try (snd F_F I) (remove (fun (x,y) -> x = label) edges)
with Failure _ -> (empty_net,edges) in
let new_child = net_update lconsts (elem,ntms@rtms,child) in
Netnode ((label,new_child)::others,tips) in
fun lconsts (tm,elem) net -> net_update lconsts (elem,[tm],net);;
(* ------------------------------------------------------------------------- *)
(* Look up a term in a net and return possible matches. *)
(* ------------------------------------------------------------------------- *)
let lookup =
let label_for_lookup tm =
let op,args = strip_comb tm in
if is_const op then Cnet(fst(dest_const op),length args),args
else if is_abs op then Lnet(length args),(body op)::args
else Lcnet(fst(dest_var op),length args),args in
let rec follow (tms,Netnode(edges,tips)) =
match tms with
[] -> tips
| (tm::rtms) ->
let label,ntms = label_for_lookup tm in
let collection =
try let child = assoc label edges in
follow(ntms @ rtms, child)
with Failure _ -> [] in
if label = Vnet then collection else
try collection @ follow(rtms,assoc Vnet edges)
with Failure _ -> collection in
fun tm net -> follow([tm],net);;
(* ------------------------------------------------------------------------- *)
(* Function to merge two nets (code from Don Syme's hol-lite). *)
(* ------------------------------------------------------------------------- *)
let merge_nets =
let canon_eq x y =
try Pervasives.compare x y = 0 with Invalid_argument _ -> false
and canon_lt x y =
try Pervasives.compare x y < 0 with Invalid_argument _ -> false in
let rec set_merge l1 l2 =
if l1 = [] then l2
else if l2 = [] then l1 else
let h1 = hd l1 and t1 = tl l1
and h2 = hd l2 and t2 = tl l2 in
if canon_eq h1 h2 then h1::(set_merge t1 t2)
else if canon_lt h1 h2 then h1::(set_merge t1 l2)
else h2::(set_merge l1 t2) in
let rec merge_nets (Netnode(l1,data1),Netnode(l2,data2)) =
let add_node ((lab,net) as p) l =
try let (lab',net'),rest = remove (fun (x,y) -> x = lab) l in
(lab',merge_nets (net,net'))::rest
with Failure _ -> p::l in
Netnode(itlist add_node l2 (itlist add_node l1 []),
set_merge data1 data2) in
merge_nets;;