(* * Copyright (c) 2009 - 2013 Monoidics ltd. * Copyright (c) 2013 - present Facebook, Inc. * All rights reserved. * * This source code is licensed under the BSD style license found in the * LICENSE file in the root directory of this source tree. An additional grant * of patent rights can be found in the PATENTS file in the same directory. *) open! Utils (** Specifications and spec table *) module L = Logging module F = Format (* =============== START of support for spec tables =============== *) (** Module for joined props *) module Jprop = struct (** Remember when a prop is obtained as the join of two other props; the first parameter is an id *) type 'a t = | Prop of int * 'a Prop.t | Joined of int * 'a Prop.t * 'a t * 'a t let to_prop = function | Prop (_, p) -> p | Joined (_, p, _, _) -> p let to_number = function | Prop (n, _) -> n | Joined (n, _, _, _) -> n let rec fav_add_dfs fav = function | Prop (_, p) -> Prop.prop_fav_add_dfs fav p | Joined (_, p, jp1, jp2) -> Prop.prop_fav_add_dfs fav p; fav_add_dfs fav jp1; fav_add_dfs fav jp2 let rec normalize = function | Prop (n, p) -> Prop (n, Prop.normalize p) | Joined (n, p, jp1, jp2) -> Joined (n, Prop.normalize p, normalize jp1, normalize jp2) (** Return a compact representation of the jprop *) let rec compact sh = function | Prop (n, p) -> Prop (n, Prop.prop_compact sh p) | Joined(n, p, jp1, jp2) -> Joined(n, Prop.prop_compact sh p, compact sh jp1, compact sh jp2) (** Print the toplevel prop *) let pp_short pe f jp = Prop.pp_prop pe f (to_prop jp) (** Dump the toplevel prop *) let d_shallow (jp: Prop.normal t) = L.add_print_action (L.PTjprop_short, Obj.repr jp) (** Get identifies of the jprop *) let get_id = function | Prop (n, _) -> n | Joined (n, _, _, _) -> n (** Print a list of joined props, the boolean indicates whether to print subcomponents of joined props *) let pp_list pe shallow f jplist = let rec pp_seq_newline f = function | [] -> () | [Prop (n, p)] -> F.fprintf f "PROP %d:@\n%a" n (Prop.pp_prop pe) p | [Joined (n, p, p1, p2)] -> if not shallow then F.fprintf f "%a@\n" pp_seq_newline [p1]; if not shallow then F.fprintf f "%a@\n" pp_seq_newline [p2]; F.fprintf f "PROP %d (join of %d,%d):@\n%a" n (get_id p1) (get_id p2) (Prop.pp_prop pe) p | jp:: l -> F.fprintf f "%a@\n" pp_seq_newline [jp]; pp_seq_newline f l in pp_seq_newline f jplist (** dump a joined prop list, the boolean indicates whether to print toplevel props only *) let d_list (shallow: bool) (jplist: Prop.normal t list) = L.add_print_action (L.PTjprop_list, Obj.repr (shallow, jplist)) (** Comparison for joined_prop *) let rec compare jp1 jp2 = match jp1, jp2 with | Prop (_, p1), Prop (_, p2) -> Prop.prop_compare p1 p2 | Prop _, _ -> - 1 | _, Prop _ -> 1 | Joined (_, p1, jp1, jq1), Joined (_, p2, jp2, jq2) -> let n = Prop.prop_compare p1 p2 in if n <> 0 then n else let n = compare jp1 jp2 in if n <> 0 then n else compare jq1 jq2 (** Return true if the two join_prop's are equal *) let equal jp1 jp2 = compare jp1 jp2 == 0 let rec fav_add fav = function | Prop (_, p) -> Prop.prop_fav_add fav p | Joined (_, p, jp1, jp2) -> Prop.prop_fav_add fav p; fav_add fav jp1; fav_add fav jp2 let rec jprop_sub sub = function | Prop (n, p) -> Prop (n, Prop.prop_sub sub p) | Joined (n, p, jp1, jp2) -> let p' = Prop.prop_sub sub p in let jp1' = jprop_sub sub jp1 in let jp2' = jprop_sub sub jp2 in Joined (n, p', jp1', jp2') let filter (f: 'a t -> 'b option) jpl = let rec do_filter acc = function | [] -> acc | (Prop _ as jp) :: jpl -> (match f jp with | Some x -> do_filter (x:: acc) jpl | None -> do_filter acc jpl) | (Joined (_, _, jp1, jp2) as jp) :: jpl -> (match f jp with | Some x -> do_filter (x:: acc) jpl | None -> do_filter acc (jpl @ [jp1; jp2])) in do_filter [] jpl let rec map (f : 'a Prop.t -> 'b Prop.t) = function | Prop (n, p) -> Prop (n, f p) | Joined (n, p, jp1, jp2) -> Joined (n, f p, map f jp1, map f jp2) (* let rec jprop_sub sub = function | Prop (n, p) -> Prop (n, Prop.prop_sub sub p) | Joined (n, p, jp1, jp2) -> Joined (n, Prop.prop_sub sub p, jprop_sub sub jp1, jprop_sub sub jp2) *) end (***** End of module Jprop *****) module Visitedset = Set.Make (struct type t = Cfg.Node.id * int list let compare (node_id1, _) (node_id2, _) = Cfg.Node.id_compare node_id1 node_id2 end) let visited_str vis = let s = ref "" in let lines = ref IntSet.empty in let do_one (_, ns) = (* if IList.length ns > 1 then begin let ss = ref "" in IList.iter (fun n -> ss := !ss ^ " " ^ string_of_int n) ns; L.err "Node %d has lines %s@." node !ss end; *) IList.iter (fun n -> lines := IntSet.add n !lines) ns in Visitedset.iter do_one vis; IntSet.iter (fun n -> s := !s ^ " " ^ string_of_int n) !lines; !s (** A spec consists of: pre: a joined prop post: a list of props with path visited: a list of pairs (node_id, line) for the visited nodes *) type 'a spec = { pre: 'a Jprop.t; posts: ('a Prop.t * Paths.Path.t) list; visited : Visitedset.t } module NormSpec : sig (* encapsulate type for normalized specs *) type t val normalize : Prop.normal spec -> t val tospecs : t list -> Prop.normal spec list val compact : Sil.sharing_env -> t -> t (** Return a compact representation of the spec *) val erase_join_info_pre : t -> t (** Erase join info from pre of spec *) end = struct type t = Prop.normal spec let tospecs specs = specs let spec_fav (spec: Prop.normal spec) : Sil.fav = let fav = Sil.fav_new () in Jprop.fav_add_dfs fav spec.pre; IList.iter (fun (p, _) -> Prop.prop_fav_add_dfs fav p) spec.posts; fav let spec_sub sub spec = { pre = Jprop.normalize (Jprop.jprop_sub sub spec.pre); posts = IList.map (fun (p, path) -> (Prop.normalize (Prop.prop_sub sub p), path)) spec.posts; visited = spec.visited } (** Convert spec into normal form w.r.t. variable renaming *) let normalize (spec: Prop.normal spec) : Prop.normal spec = let fav = spec_fav spec in let idlist = Sil.fav_to_list fav in let count = ref 0 in let sub = Sil.sub_of_list (IList.map (fun id -> incr count; (id, Sil.Var (Ident.create_normal Ident.name_spec !count))) idlist) in spec_sub sub spec (** Return a compact representation of the spec *) let compact sh spec = let pre = Jprop.compact sh spec.pre in let posts = IList.map (fun (p, path) -> (Prop.prop_compact sh p, path)) spec.posts in { pre = pre; posts = posts; visited = spec.visited } (** Erase join info from pre of spec *) let erase_join_info_pre spec = let spec' = { spec with pre = Jprop.Prop (1, Jprop.to_prop spec.pre) } in normalize spec' end (** Convert spec into normal form w.r.t. variable renaming *) let spec_normalize = NormSpec.normalize (** Cast a list of normalized specs to a list of specs *) let normalized_specs_to_specs = NormSpec.tospecs module CallStats = struct (** module for tracing stats of function calls *) module PnameLocHash = Hashtbl.Make (struct type t = Procname.t * Location.t let hash (pname, loc) = Hashtbl.hash (Procname.hash_pname pname, loc.Location.line) let equal (pname1, loc1) (pname2, loc2) = Location.equal loc1 loc2 && Procname.equal pname1 pname2 end) type call_result = (** kind of result of a procedure call *) | CR_success (** successful call *) | CR_not_met (** precondition not met *) | CR_not_found (** the callee has no specs *) | CR_skip (** the callee was skipped *) type trace = (call_result * bool) list type t = trace PnameLocHash.t let trace_add tr (res : call_result) in_footprint = (res, in_footprint) :: tr let empty_trace : trace = [] let init calls = let hash = PnameLocHash.create 1 in let do_call pn_loc = PnameLocHash.add hash pn_loc empty_trace in IList.iter do_call calls; hash let trace t proc_name loc res in_footprint = let tr_old = try PnameLocHash.find t (proc_name, loc) with | Not_found -> PnameLocHash.add t (proc_name, loc) empty_trace; empty_trace in let tr_new = trace_add tr_old res in_footprint in PnameLocHash.replace t (proc_name, loc) tr_new let tr_elem_str (cr, in_footprint) = let s1 = match cr with | CR_success -> "OK" | CR_not_met -> "NotMet" | CR_not_found -> "NotFound" | CR_skip -> "Skip" in let s2 = if in_footprint then "FP" else "RE" in s1 ^ ":" ^ s2 let pp_trace fmt tr = pp_seq (fun fmt x -> F.fprintf fmt "%s" (tr_elem_str x)) fmt (IList.rev tr) let iter f t = let elems = ref [] in PnameLocHash.iter (fun x tr -> elems := (x, tr) :: !elems) t; let sorted_elems = let compare ((pname1, loc1), _) ((pname2, loc2), _) = let n = Procname.compare pname1 pname2 in if n <> 0 then n else Location.compare loc1 loc2 in IList.sort compare !elems in IList.iter (fun (x, tr) -> f x tr) sorted_elems (* let pp fmt t = let do_call (pname, loc) tr = F.fprintf fmt "%a %a: %a@\n" Procname.pp pname Location.pp loc pp_trace tr in iter do_call t *) end (** stats of the calls performed during the analysis *) type call_stats = CallStats.t (** Execution statistics *) type stats = { stats_time: float; (** Analysis time for the procedure *) stats_failure: SymOp.failure_kind option; (** what type of failure stopped the analysis (if any) *) stats_calls: Cg.in_out_calls; (** num of procs calling, and called *) symops: int; (** Number of SymOp's throughout the whole analysis of the function *) mutable nodes_visited_fp : IntSet.t; (** Nodes visited during the footprint phase *) mutable nodes_visited_re : IntSet.t; (** Nodes visited during the re-execution phase *) call_stats : call_stats; } type status = ACTIVE | INACTIVE | STALE type phase = FOOTPRINT | RE_EXECUTION type dependency_map_t = int Procname.Map.t (* name of callee + location of the call *) type call_site = Procname.t * Location.t let compare_call_site (pname1, loc1) (pname2, loc2) = let n = Procname.compare pname1 pname2 in if n <> 0 then n else Location.compare loc1 loc2 let pp_call_site fmt (pname, loc) = F.fprintf fmt "%a at %a" Procname.pp pname Location.pp loc module CallSiteSet = PrettyPrintable.MakePPSet(struct type t = call_site let compare = compare_call_site let pp_element = pp_call_site end) type call_summary = CallSiteSet.t Sil.AnnotMap.t (** Payload: results of some analysis *) type payload = { preposts : NormSpec.t list option; (** list of specs *) typestate : unit TypeState.t option; (** final typestate *) calls: call_summary option; } type summary = { dependency_map: dependency_map_t; (** maps children procs to timestamp as last seen at the start of an analysys phase for this proc *) nodes: Cfg.Node.id list; (** ids of cfg nodes of the procedure *) phase: phase; (** in FOOTPRINT phase or in RE_EXECUTION PHASE *) payload: payload; (** payload containing the result of some analysis *) sessions: int ref; (** Session number: how many nodes went trough symbolic execution *) stats: stats; (** statistics: execution time and list of errors *) status: status; (** ACTIVE when the proc is being analyzed *) timestamp: int; (** Timestamp of the specs, >= 0, increased every time the specs change *) attributes : ProcAttributes.t; (** Attributes of the procedure *) } type spec_tbl = (summary * DB.origin) Procname.Hash.t let spec_tbl: spec_tbl = Procname.Hash.create 128 let clear_spec_tbl () = Procname.Hash.clear spec_tbl (** pretty print analysis time; if [whole_seconds] is true, only print time in seconds *) let pp_time whole_seconds fmt t = if whole_seconds then F.fprintf fmt "%3.0f s" t else F.fprintf fmt "%f s" t let pp_failure_kind_opt fmt failure_kind_opt = match failure_kind_opt with | Some failure_kind -> SymOp.pp_failure_kind fmt failure_kind | None -> F.fprintf fmt "NONE" let pp_stats err_log whole_seconds fmt stats = F.fprintf fmt "TIME:%a FAILURE:%a SYMOPS:%d CALLS:%d,%d@\n" (pp_time whole_seconds) stats.stats_time pp_failure_kind_opt stats.stats_failure stats.symops stats.stats_calls.Cg.in_calls stats.stats_calls.Cg.out_calls; F.fprintf fmt "ERRORS: @[%a@]@." Errlog.pp_errors err_log; F.fprintf fmt "WARNINGS: @[%a@]" Errlog.pp_warnings err_log (** Print the spec *) let pp_spec pe num_opt fmt spec = let num_str = match num_opt with | None -> "----------" | Some (n, tot) -> Format.sprintf "%d of %d [nvisited:%s]" n tot (visited_str spec.visited) in let pre = Jprop.to_prop spec.pre in let pe_post = Prop.prop_update_obj_sub pe pre in let post_list = IList.map fst spec.posts in match pe.pe_kind with | PP_TEXT -> F.fprintf fmt "--------------------------- %s ---------------------------@\n" num_str; F.fprintf fmt "PRE:@\n%a@\n" (Prop.pp_prop pe_text) pre; F.fprintf fmt "%a@\n" (Propgraph.pp_proplist pe_post "POST" (pre, true)) post_list; F.fprintf fmt "----------------------------------------------------------------" | PP_HTML -> F.fprintf fmt "--------------------------- %s ---------------------------@\n" num_str; F.fprintf fmt "PRE:@\n%a%a%a@\n" Io_infer.Html.pp_start_color Blue (Prop.pp_prop (pe_html Blue)) pre Io_infer.Html.pp_end_color (); F.fprintf fmt "%a" (Propgraph.pp_proplist pe_post "POST" (Jprop.to_prop spec.pre, true)) post_list; F.fprintf fmt "----------------------------------------------------------------" | PP_LATEX -> F.fprintf fmt "\\textbf{\\large Requires}\\\\@\n@[%a%a%a@]\\\\@\n" Latex.pp_color Blue (Prop.pp_prop (pe_latex Blue)) pre Latex.pp_color pe.pe_color; F.fprintf fmt "\\textbf{\\large Ensures}\\\\@\n@[%a@]" (Propgraph.pp_proplist pe_post "POST" (pre, true)) post_list (** Dump a spec *) let d_spec (spec: 'a spec) = L.add_print_action (L.PTspec, Obj.repr spec) let pp_specs pe fmt specs = let total = IList.length specs in let cnt = ref 0 in match pe.pe_kind with | PP_TEXT -> IList.iter (fun spec -> incr cnt; F.fprintf fmt "%a@\n" (pp_spec pe (Some (!cnt, total))) spec) specs | PP_HTML -> IList.iter (fun spec -> incr cnt; F.fprintf fmt "%a
@\n" (pp_spec pe (Some (!cnt, total))) spec) specs | PP_LATEX -> IList.iter (fun spec -> incr cnt; F.fprintf fmt "\\subsection*{Spec %d of %d}@\n\\(%a\\)@\n" !cnt total (pp_spec pe None) spec) specs (** Print the decpendency map *) let pp_dependency_map fmt dependency_map = let pp_entry fmt proc_name n = F.fprintf fmt "%a=%d " Procname.pp proc_name n in Procname.Map.iter (pp_entry fmt) dependency_map let describe_timestamp summary = ("Timestamp", Printf.sprintf "%d" summary.timestamp) let describe_status summary = ("Status", if summary.status == ACTIVE then "ACTIVE" else "INACTIVE") let describe_phase summary = ("Phase", if summary.phase == FOOTPRINT then "FOOTPRINT" else "RE_EXECUTION") (** Return the signature of a procedure declaration as a string *) let get_signature summary = let s = ref "" in IList.iter (fun (p, typ) -> let pp_name f () = F.fprintf f "%a" Mangled.pp p in let pp f () = Sil.pp_type_decl pe_text pp_name Sil.pp_exp f typ in let decl = pp_to_string pp () in s := if !s = "" then decl else !s ^ ", " ^ decl) summary.attributes.ProcAttributes.formals; let pp_procname f () = F.fprintf f "%a" Procname.pp summary.attributes.ProcAttributes.proc_name in let pp f () = Sil.pp_type_decl pe_text pp_procname Sil.pp_exp f summary.attributes.ProcAttributes.ret_type in let decl = pp_to_string pp () in decl ^ "(" ^ !s ^ ")" let pp_summary_no_stats_specs fmt summary = let pp_pair fmt (x, y) = F.fprintf fmt "%s: %s" x y in F.fprintf fmt "%s@\n" (get_signature summary); F.fprintf fmt "%a@\n" pp_pair (describe_timestamp summary); F.fprintf fmt "%a@\n" pp_pair (describe_status summary); F.fprintf fmt "%a@\n" pp_pair (describe_phase summary); F.fprintf fmt "Dependency_map: @[%a@]@\n" pp_dependency_map summary.dependency_map let pp_stats_html err_log fmt = Errlog.pp_html [] fmt err_log let get_specs_from_payload summary = match summary.payload.preposts with | Some specs -> NormSpec.tospecs specs | None -> [] (** Print the summary *) let pp_summary pe whole_seconds fmt summary = let err_log = summary.attributes.ProcAttributes.err_log in match pe.pe_kind with | PP_TEXT -> pp_summary_no_stats_specs fmt summary; F.fprintf fmt "%a@\n" (pp_stats err_log whole_seconds) summary.stats; F.fprintf fmt "%a" (pp_specs pe) (get_specs_from_payload summary) | PP_HTML -> Io_infer.Html.pp_start_color fmt Black; F.fprintf fmt "@\n%a" pp_summary_no_stats_specs summary; Io_infer.Html.pp_end_color fmt (); pp_stats_html err_log fmt; Io_infer.Html.pp_hline fmt (); F.fprintf fmt "@\n"; pp_specs pe fmt (get_specs_from_payload summary); F.fprintf fmt "@\n" | PP_LATEX -> F.fprintf fmt "\\begin{verbatim}@\n"; pp_summary_no_stats_specs fmt summary; F.fprintf fmt "%a@\n" (pp_stats err_log whole_seconds) summary.stats; F.fprintf fmt "\\end{verbatim}@\n"; F.fprintf fmt "%a@\n" (pp_specs pe) (get_specs_from_payload summary) (** Print the spec table *) let pp_spec_table pe whole_seconds fmt () = Procname.Hash.iter (fun proc_name (summ, _) -> F.fprintf fmt "PROC %a@\n%a@\n" Procname.pp proc_name (pp_summary pe whole_seconds) summ ) spec_tbl let empty_stats calls in_out_calls_opt = { stats_time = 0.0; stats_failure = None; stats_calls = (match in_out_calls_opt with | Some in_out_calls -> in_out_calls | None -> { Cg.in_calls = 0; Cg.out_calls = 0 }); symops = 0; nodes_visited_fp = IntSet.empty; nodes_visited_re = IntSet.empty; call_stats = CallStats.init calls; } let payload_compact sh payload = match payload.preposts with | Some specs -> { payload with preposts = Some (IList.map (NormSpec.compact sh) specs); } | None -> payload (** Return a compact representation of the summary *) let summary_compact sh summary = { summary with payload = payload_compact sh summary.payload } let set_summary_origin proc_name summary origin = Procname.Hash.replace spec_tbl proc_name (summary, origin) let add_summary_origin (proc_name : Procname.t) (summary: summary) (origin: DB.origin) : unit = L.out "Adding summary for %a@\n@[ %a@]@." Procname.pp proc_name (pp_summary pe_text false) summary; set_summary_origin proc_name summary origin (** Add the summary to the table for the given function *) let add_summary (proc_name : Procname.t) (summary: summary) : unit = add_summary_origin proc_name summary DB.Res_dir let specs_filename pname = let pname_file = Procname.to_filename pname in pname_file ^ Config.specs_files_suffix (** path to the .specs file for the given procedure in the current results directory *) let res_dir_specs_filename pname = DB.Results_dir.path_to_filename DB.Results_dir.Abs_root [Config.specs_dir_name; specs_filename pname] (** paths to the .specs file for the given procedure in the current spec libraries *) let specs_library_filenames pname = IList.map (fun specs_dir -> DB.filename_from_string (Filename.concat specs_dir (specs_filename pname))) Config.specs_library (** paths to the .specs file for the given procedure in the models folder *) let specs_models_filename pname = DB.filename_from_string (Filename.concat Config.models_dir (specs_filename pname)) let summary_exists_in_models pname = Sys.file_exists (DB.filename_to_string (specs_models_filename pname)) let summary_serializer : summary Serialization.serializer = Serialization.create_serializer Serialization.summary_key (** Save summary for the procedure into the spec database *) let store_summary pname (summ: summary) = let process_payload payload = match payload.preposts with | Some specs -> { payload with preposts = Some (IList.map NormSpec.erase_join_info_pre specs); } | None -> payload in let summ1 = { summ with payload = process_payload summ.payload } in let summ2 = if Config.save_compact_summaries then summary_compact (Sil.create_sharing_env ()) summ1 else summ1 in let summ3 = if Config.save_time_in_summaries then summ2 else { summ2 with stats = { summ1.stats with stats_time = 0.0} } in Serialization.to_file summary_serializer (res_dir_specs_filename pname) summ3 (** Load procedure summary from the given file *) let load_summary specs_file = Serialization.from_file summary_serializer specs_file (** Load procedure summary for the given procedure name and update spec table *) let load_summary_to_spec_table proc_name = let add summ origin = add_summary_origin proc_name summ origin; true in let load_summary_models models_dir = match load_summary models_dir with | None -> false | Some summ -> add summ DB.Models in let rec load_summary_libs = function (* try to load the summary from a list of libs *) | [] -> false | spec_path :: spec_paths -> (match load_summary spec_path with | None -> load_summary_libs spec_paths | Some summ -> add summ Spec_lib) in let load_summary_ziplibs zip_specs_filename = let zip_specs_path = Filename.concat Config.specs_dir_name zip_specs_filename in match ZipLib.load summary_serializer zip_specs_path with | None -> false | Some (summary, origin) -> add summary origin in let default_spec_dir = res_dir_specs_filename proc_name in match load_summary default_spec_dir with | None -> (* search on models, libzips, and libs *) load_summary_models (specs_models_filename proc_name) || load_summary_ziplibs (specs_filename proc_name) || load_summary_libs (specs_library_filenames proc_name) | Some summ -> add summ DB.Res_dir let rec get_summary_origin proc_name = try Some (Procname.Hash.find spec_tbl proc_name) with Not_found -> if load_summary_to_spec_table proc_name then get_summary_origin proc_name else None let get_summary proc_name = match get_summary_origin proc_name with | Some (summary, _) -> Some summary | None -> None let get_summary_unsafe s proc_name = match get_summary proc_name with | None -> raise (Failure ( "[" ^ s ^ "] Specs.get_summary_unsafe: " ^ (Procname.to_string proc_name) ^ "Not_found")) | Some summary -> summary (** Check if the procedure is from a library: It's not defined, and there is no spec file for it. *) let proc_is_library proc_attributes = if not proc_attributes.ProcAttributes.is_defined then match get_summary proc_attributes.ProcAttributes.proc_name with | None -> true | Some _ -> false else false (** Try to find the attributes for a defined proc. First look at specs (to get attributes computed by analysis) then look at the attributes table. If no attributes can be found, return None. *) let proc_resolve_attributes proc_name = let from_attributes_table () = AttributesTable.load_attributes proc_name in let from_specs () = match get_summary proc_name with | Some summary -> Some summary.attributes | None -> None in match from_specs () with | Some attributes -> if attributes.ProcAttributes.is_defined then Some attributes else begin match from_attributes_table () with | Some attributes' -> Some attributes' | None -> Some attributes end | None -> from_attributes_table () (** Like proc_resolve_attributes but start from a proc_desc. *) let pdesc_resolve_attributes proc_desc = let proc_name = Cfg.Procdesc.get_proc_name proc_desc in match proc_resolve_attributes proc_name with | Some proc_attributes -> proc_attributes | None -> (* this should not happen *) assert false let get_origin proc_name = match get_summary_origin proc_name with | Some (_, origin) -> origin | None -> DB.Res_dir let summary_exists proc_name = match get_summary proc_name with | Some _ -> true | None -> false let get_status summary = summary.status let is_active proc_name = get_status (get_summary_unsafe "is_active" proc_name) = ACTIVE let is_inactive proc_name = get_status (get_summary_unsafe "is_active" proc_name) = INACTIVE let get_timestamp summary = summary.timestamp let get_proc_name summary = summary.attributes.ProcAttributes.proc_name let get_ret_type summary = summary.attributes.ProcAttributes.ret_type let get_formals summary = summary.attributes.ProcAttributes.formals let get_attributes summary = summary.attributes (** Get the flag with the given key for the procedure, if any *) (* TODO get_flag should get a summary as parameter *) let get_flag proc_name key = match get_summary proc_name with | None -> None | Some summary -> let proc_flags = summary.attributes.ProcAttributes.proc_flags in try Some (Hashtbl.find proc_flags key) with Not_found -> None (** Return the specs and parameters for the proc in the spec table *) let get_specs_formals proc_name = match get_summary proc_name with | None -> raise (Failure ("Specs.get_specs_formals: " ^ (Procname.to_string proc_name) ^ "Not_found")) | Some summary -> let specs = get_specs_from_payload summary in let formals = get_formals summary in (specs, formals) (** Return the specs for the proc in the spec table *) let get_specs proc_name = fst (get_specs_formals proc_name) (** Return the current phase for the proc *) let get_phase proc_name = match get_summary_origin proc_name with | None -> raise (Failure ("Specs.get_phase: " ^ (Procname.to_string proc_name) ^ " Not_found")) | Some (summary, _) -> summary.phase (** Set the current status for the proc *) let set_status proc_name status = match get_summary_origin proc_name with | None -> raise (Failure ("Specs.set_status: " ^ (Procname.to_string proc_name) ^ " Not_found")) | Some (summary, origin) -> set_summary_origin proc_name { summary with status = status } origin (** Create the initial dependency map with the given list of dependencies *) let mk_initial_dependency_map proc_list : dependency_map_t = IList.fold_left (fun map pname -> Procname.Map.add pname (- 1) map) Procname.Map.empty proc_list (** Re-initialize a dependency map *) let re_initialize_dependency_map dependency_map = Procname.Map.map (fun _ -> - 1) dependency_map (** Update the dependency map of [proc_name] with the current timestamps of the dependents *) let update_dependency_map proc_name = match get_summary_origin proc_name with | None -> raise (Failure ("Specs.update_dependency_map: " ^ (Procname.to_string proc_name) ^ " Not_found")) | Some (summary, origin) -> let current_dependency_map = Procname.Map.mapi (fun _ _ -> get_timestamp summary) summary.dependency_map in set_summary_origin proc_name { summary with dependency_map = current_dependency_map } origin let empty_payload = { preposts = None; typestate = None; calls = None; } (** [init_summary (depend_list, nodes, proc_flags, calls, in_out_calls_opt, proc_attributes)] initializes the summary for [proc_name] given dependent procs in list [depend_list]. *) let init_summary (depend_list, nodes, proc_flags, calls, in_out_calls_opt, proc_attributes) = let dependency_map = mk_initial_dependency_map depend_list in let summary = { dependency_map = dependency_map; nodes = nodes; phase = FOOTPRINT; sessions = ref 0; payload = empty_payload; stats = empty_stats calls in_out_calls_opt; status = INACTIVE; timestamp = 0; attributes = { proc_attributes with ProcAttributes.proc_flags = proc_flags; }; } in Procname.Hash.replace spec_tbl proc_attributes.ProcAttributes.proc_name (summary, DB.Res_dir) (** Reset a summary rebuilding the dependents and preserving the proc attributes if present. *) let reset_summary call_graph proc_name attributes_opt = let dependents = Cg.get_defined_children call_graph proc_name in let proc_attributes = match attributes_opt with | Some attributes -> attributes | None -> ProcAttributes.default proc_name !Config.curr_language in init_summary ( Procname.Set.elements dependents, [], proc_flags_empty (), [], Some (Cg.get_calls call_graph proc_name), proc_attributes ) (* =============== END of support for spec tables =============== *) (* let rec post_equal pl1 pl2 = match pl1, pl2 with | [],[] -> true | [], _:: _ -> false | _:: _,[] -> false | p1:: pl1', p2:: pl2' -> if Prop.prop_equal p1 p2 then post_equal pl1' pl2' else false *)