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(*
* 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;
}
[Infer][incremental] Preventing --changed-only incremental mode from corrupting the future Summary: When someone runs --changed-only mode, there is a risk of corrupting the results for future analyses. The problem is that changed-only mode does not analyze the callers of changed procedures. If a subsequent analysis relies on the specs of one of these callers, they will be stale and may give the wrong results. To be concrete, let's say we know `Parent.foo()` calls `Child.bar()` and we do the following rounds of analysis: Analysis round 1: Analyze all files, including `Parent` and `Child` Analysis round 2: Analyze `Child.bar()` only with `--changed-only flag`. `Parent.foo()` is now stale. Analysis round 3: Add procedure `Parent.baz()` that calls `Parent.foo()`, analyze in (any) incremental mode. The analysis will only analyze `Parent.baz()`. However, the specs for `Parent.foo()` are stale and may give us bad results for `Parent.baz()`. We want the analysis to re-analyze `Parent.baz()`, but before this diff it will not. This diff fixes this problem by adding a `STALE` status bit to procedure summaries. In `--changed-only` mode, the callers of a changed procedures are not re-analyzed, but their summaries are marked as stale. For both `--changed-only` and regular incremental mode, callees of changed procedures that are marked as stale are re-analyzed even if they have not changed. This is better than a more obvious solution like deleting stale procedure summaries, since that would force the next analysis to re-analyze all stale procedures even if it does not need the results for whatever analysis it is doing. This scheme implemented in this diff ensures that each analysis only does the work that it needs to compute reliable results for its changed procedures.
9 years ago
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 Typ.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: @[<h>%a@]@." Errlog.pp_errors err_log;
F.fprintf fmt "WARNINGS: @[<h>%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<br>@\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 () = Typ.pp_decl pe_text pp_name 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 () =
Typ.pp_decl pe_text pp_procname 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 "<LISTING>@\n";
pp_specs pe fmt (get_specs_from_payload summary);
F.fprintf fmt "</LISTING>@\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@[<v 2> %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
*)