(***********************************************************************) (* *) (* Objective Caml *) (* *) (* Jerome Vouillon, projet Cristal, INRIA Rocquencourt *) (* *) (* Copyright 1996 Institut National de Recherche en Informatique et *) (* en Automatique. All rights reserved. This file is distributed *) (* under the terms of the GNU Library General Public License, with *) (* the special exception on linking described in file ../LICENSE. *) (* *) (***********************************************************************) (* $Id$ *) open Obj (**** Object representation ****) let last_id = ref 0 let new_id () = let id = !last_id in incr last_id; id let set_id o id = let id0 = !id in Array.unsafe_set (Obj.magic o : int array) 1 id0; id := id0 + 1 (**** Object copy ****) let copy o = let o = (Obj.obj (Obj.dup (Obj.repr o))) in set_id o last_id; o (**** Compression options ****) (* Parameters *) type params = { mutable compact_table : bool; mutable copy_parent : bool; mutable clean_when_copying : bool; mutable retry_count : int; mutable bucket_small_size : int } let params = { compact_table = true; copy_parent = true; clean_when_copying = true; retry_count = 3; bucket_small_size = 16 } (**** Parameters ****) let step = Sys.word_size / 16 let first_bucket = 0 let bucket_size = 32 (* Must be 256 or less *) let initial_object_size = 2 (**** Index ****) type label = int let label_count = ref 0 let next label = incr label_count; let label = label + step in if label mod (step * bucket_size) = 0 then label + step * (65536 - bucket_size) else label let decode label = (label / 65536 / step, (label mod (step * bucket_size)) / step) (**** Items ****) type item let dummy_item = (magic () : item) (**** Buckets ****) type bucket = item array let version = ref 0 let set_bucket_version (bucket : bucket) = bucket.(bucket_size) <- (magic !version : item) let bucket_version bucket = (magic bucket.(bucket_size) : int) let bucket_list = ref [] let empty_bucket = [| |] let new_bucket () = let bucket = Array.create (bucket_size + 1) dummy_item in set_bucket_version bucket; bucket_list := bucket :: !bucket_list; bucket let copy_bucket bucket = let bucket = Array.copy bucket in set_bucket_version bucket; bucket.(bucket_size) <- (magic !version : item); bucket_list := bucket :: !bucket_list; bucket (**** Make a clean bucket ****) let new_filled_bucket pos methods = let bucket = new_bucket () in List.iter (fun (lab, met) -> let (buck, elem) = decode lab in if buck = pos then bucket.(elem) <- (magic met : item)) (List.rev methods); bucket (**** Bucket merging ****) let small_buckets = ref (Array.create 10 [| |]) let small_bucket_count = ref 0 let insert_bucket bucket = let length = Array.length !small_buckets in if !small_bucket_count >= length then begin let new_array = Array.create (2 * length) [| |] in Array.blit !small_buckets 0 new_array 0 length; small_buckets := new_array end; !small_buckets.(!small_bucket_count) <- bucket; incr small_bucket_count let remove_bucket n = !small_buckets.(n) <- !small_buckets.(!small_bucket_count - 1); decr small_bucket_count let bucket_used b = let n = ref 0 in for i = 0 to bucket_size - 1 do if b.(i) != dummy_item then incr n done; !n let small_bucket b = bucket_used b <= params.bucket_small_size exception Failed let rec except e = function [] -> [] | e'::l -> if e == e' then l else e'::(except e l) let merge_buckets b1 b2 = for i = 0 to bucket_size - 1 do if (b2.(i) != dummy_item) && (b1.(i) != dummy_item) && (b2.(i) != b1.(i)) then raise Failed done; for i = 0 to bucket_size - 1 do if b2.(i) != dummy_item then b1.(i) <- b2.(i) done; bucket_list := except b2 !bucket_list; b1 let rec choose bucket i = if (i > 0) && (!small_bucket_count > 0) then begin let n = Random.int !small_bucket_count in if not (small_bucket !small_buckets.(n)) then begin remove_bucket n; choose bucket i end else try merge_buckets !small_buckets.(n) bucket with Failed -> choose bucket (i - 1) end else begin insert_bucket bucket; bucket end let compact b = if (b != empty_bucket) && (bucket_version b = !version) && (small_bucket b) then choose b params.retry_count else b let compact_buckets buckets = for i = first_bucket to Array.length buckets - 1 do buckets.(i) <- compact buckets.(i) done (**** Labels ****) let first_label = first_bucket * 65536 * step let last_label = ref first_label let methods = Hashtbl.create 101 let new_label () = let label = !last_label in last_label := next !last_label; label let new_method met = try Hashtbl.find methods met with Not_found -> let label = new_label () in Hashtbl.add methods met label; label let new_anonymous_method = new_label (**** Types ****) type obj = t array (**** Sparse array ****) module Vars = Map.Make(struct type t = string let compare = compare end) type vars = int Vars.t module Meths = Map.Make(struct type t = string let compare = compare end) type meths = label Meths.t module Labs = Map.Make(struct type t = label let compare = compare end) type labs = bool Labs.t (* The compiler assumes that the first field of this structure is [size]. *) type table = { mutable size: int; mutable buckets: bucket array; mutable methods_by_name: meths; mutable methods_by_label: labs; mutable previous_states: (meths * labs * (label * item) list * vars * label list * string list) list; mutable hidden_meths: (label * item) list; mutable vars: vars; mutable initializers: (obj -> unit) list } let table_count = ref 0 let new_table () = incr table_count; { buckets = [| |]; methods_by_name = Meths.empty; methods_by_label = Labs.empty; previous_states = []; hidden_meths = []; vars = Vars.empty; initializers = []; size = initial_object_size } let resize array new_size = let old_size = Array.length array.buckets in if new_size > old_size then begin let new_buck = Array.create new_size empty_bucket in Array.blit array.buckets 0 new_buck 0 old_size; array.buckets <- new_buck end let put array label element = let (buck, elem) = decode label in resize array (buck + 1); let bucket = ref (array.buckets.(buck)) in if !bucket == empty_bucket then begin bucket := new_bucket (); array.buckets.(buck) <- !bucket end; !bucket.(elem) <- element (**** Classes ****) let method_count = ref 0 let inst_var_count = ref 0 type t type meth = item let get_method_label table name = try Meths.find name table.methods_by_name with Not_found -> let label = new_anonymous_method () in table.methods_by_name <- Meths.add name label table.methods_by_name; table.methods_by_label <- Labs.add label true table.methods_by_label; label let set_method table label element = incr method_count; if Labs.find label table.methods_by_label then put table label element else table.hidden_meths <- (label, element) :: table.hidden_meths let get_method table label = try List.assoc label table.hidden_meths with Not_found -> let (buck, elem) = decode label in table.buckets.(buck).(elem) let narrow table vars virt_meths concr_meths = let virt_meth_labs = List.map (get_method_label table) virt_meths in let concr_meth_labs = List.map (get_method_label table) concr_meths in table.previous_states <- (table.methods_by_name, table.methods_by_label, table.hidden_meths, table.vars, virt_meth_labs, vars) :: table.previous_states; table.vars <- Vars.empty; let by_name = ref Meths.empty in let by_label = ref Labs.empty in List.iter2 (fun met label -> by_name := Meths.add met label !by_name; by_label := Labs.add label (try Labs.find label table.methods_by_label with Not_found -> true) !by_label) concr_meths concr_meth_labs; List.iter2 (fun met label -> by_name := Meths.add met label !by_name; by_label := Labs.add label false !by_label) virt_meths virt_meth_labs; table.methods_by_name <- !by_name; table.methods_by_label <- !by_label; table.hidden_meths <- List.fold_right (fun ((lab, _) as met) hm -> if List.mem lab virt_meth_labs then hm else met::hm) table.hidden_meths [] let widen table = let (by_name, by_label, saved_hidden_meths, saved_vars, virt_meths, vars) = List.hd table.previous_states in table.previous_states <- List.tl table.previous_states; table.vars <- List.fold_left (fun s v -> Vars.add v (Vars.find v table.vars) s) saved_vars vars; table.methods_by_name <- by_name; table.methods_by_label <- by_label; table.hidden_meths <- List.fold_right (fun ((lab, _) as met) hm -> if List.mem lab virt_meths then hm else met::hm) table.hidden_meths saved_hidden_meths let new_slot table = let index = table.size in table.size <- index + 1; index let new_variable table name = let index = new_slot table in table.vars <- Vars.add name index table.vars; index let get_variable table name = Vars.find name table.vars let add_initializer table f = table.initializers <- f::table.initializers let create_table public_methods = let table = new_table () in List.iter (function met -> let lab = new_method met in table.methods_by_name <- Meths.add met lab table.methods_by_name; table.methods_by_label <- Labs.add lab true table.methods_by_label) public_methods; table let init_class table = inst_var_count := !inst_var_count + table.size - 1; if params.compact_table then compact_buckets table.buckets; table.initializers <- List.rev table.initializers (**** Objects ****) let create_object table = (* XXX Appel de [obj_block] *) let obj = Obj.new_block Obj.object_tag table.size in (* XXX Appel de [modify] *) Obj.set_field obj 0 (Obj.repr table.buckets); set_id obj last_id; (Obj.obj obj) let rec iter_f obj = function [] -> () | f::l -> f obj; iter_f obj l let run_initializers obj table = let inits = table.initializers in if inits <> [] then iter_f obj inits let send obj lab = let (buck, elem) = decode lab in (magic obj : (obj -> t) array array array).(0).(buck).(elem) obj (**** Statistics ****) type stats = { classes: int; labels: int; methods: int; inst_vars: int; buckets: int; distrib : int array; small_bucket_count: int; small_bucket_max: int } let distrib () = let d = Array.create 32 0 in List.iter (function b -> let n = bucket_used b in d.(n - 1) <- d.(n - 1) + 1) !bucket_list; d let stats () = { classes = !table_count; labels = !label_count; methods = !method_count; inst_vars = !inst_var_count; buckets = List.length !bucket_list; distrib = distrib (); small_bucket_count = !small_bucket_count; small_bucket_max = Array.length !small_buckets } let sort_buck lst = List.map snd (Sort.list (fun (n, _) (n', _) -> n <= n') (List.map (function b -> (bucket_used b, b)) lst)) let show_buckets () = List.iter (function b -> for i = 0 to bucket_size - 1 do print_char (if b.(i) == dummy_item then '.' else '*') done; print_newline ()) (sort_buck !bucket_list)