(* * Copyright (c) 2017 - 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! IStd module F = Format module L = Logging module Summary = Summary.Make (struct type payload = CostDomain.summary let update_payload sum (summary: Specs.summary) = {summary with payload= {summary.payload with cost= Some sum}} let read_payload (summary: Specs.summary) = summary.payload.cost end) (* We use this treshold to give error if the cost is above it. Currently it's set randomly to 200. *) let expensive_threshold = Itv.Bound.of_int 200 (* CFG module used in several other modules *) module CFG = ProcCfg.Normal module Node = struct include ProcCfg.DefaultNode let equal_id = [%compare.equal : id] end module NodesBasicCostDomain = struct include AbstractDomain.Pair (BufferOverrunDomain.Mem) (CostDomain.NodeInstructionToCostMap) let init = (BufferOverrunDomain.Mem.init, CostDomain.NodeInstructionToCostMap.empty) end (* Compute a map (node,instruction) -> basic_cost, where basic_cost is the cost known for a certain operation. For example for basic operation we set it to 1 and for function call we take it from the spec of the function. The nodes in the domain of the map are those in the path reaching the current node. *) module TransferFunctionsNodesBasicCost (CFG : ProcCfg.S) = struct module CFG = CFG module InferboTransferFunctions = BufferOverrunChecker.TransferFunctions (CFG) module Domain = NodesBasicCostDomain type extras = InferboTransferFunctions.extras let cost_atomic_instruction = Itv.Bound.one let instr_idx (node: CFG.node) instr = match CFG.instrs node with | [] -> 0 | instrs -> List.find_mapi_exn ~f:(fun idx i -> if Sil.equal_instr i instr then Some idx else None) instrs let exec_instr_cost _inferbo_mem (astate: CostDomain.NodeInstructionToCostMap.astate) {ProcData.pdesc} (node: CFG.node) instr : CostDomain.NodeInstructionToCostMap.astate = let nid_int = Procdesc.Node.get_id (CFG.underlying_node node) in let instr_idx = instr_idx node instr in let key = (nid_int, ProcCfg.Instr_index instr_idx) in let astate' = match instr with | Sil.Call (_, Exp.Const (Const.Cfun callee_pname), _, _, _) -> ( match Summary.read_summary pdesc callee_pname with | Some {post= cost_callee} -> CostDomain.NodeInstructionToCostMap.add key cost_callee astate | None -> CostDomain.NodeInstructionToCostMap.add key cost_atomic_instruction astate ) | Sil.Load _ | Sil.Store _ | Sil.Call _ | Sil.Prune _ -> CostDomain.NodeInstructionToCostMap.add key cost_atomic_instruction astate | _ -> astate in L.(debug Analysis Medium) "@\n>>>Instr: %a Cost: %a@\n" (Sil.pp_instr Pp.text) instr CostDomain.NodeInstructionToCostMap.pp astate' ; astate' let exec_instr (inferbo_mem, costmap) pdata node instr = let inferbo_mem = InferboTransferFunctions.exec_instr inferbo_mem pdata node instr in let costmap = exec_instr_cost inferbo_mem costmap pdata node instr in (inferbo_mem, costmap) let pp_session_name _node fmt = F.pp_print_string fmt "cost(basic)" end module AnalyzerNodesBasicCost = AbstractInterpreter.Make (CFG) (TransferFunctionsNodesBasicCost) (* Map associating to each node a bound on the number of times it can be executed. This bound is computed using environments (map: val -> values), using the following observation: the number of environments associated with a program point is an upperbound of the number of times the program point can be executed in any execution. The size of an environment env is computed as: |env| = |env(v1)| * ... * |env(n_k)| where |env(v)| is the size of the interval associated to v by env. Reference: see Stefan Bygde PhD thesis, 2010 *) module BoundMap = struct type t = Itv.Bound.t Node.IdMap.t let print_upper_bound_map bound_map = L.(debug Analysis Medium) "@\n\n******* Bound Map ITV **** @\n" ; Node.IdMap.iter (fun nid b -> L.(debug Analysis Medium) "@\n node: %a --> bound = %a @\n" Node.pp_id nid Itv.Bound.pp b ) bound_map ; L.(debug Analysis Medium) "@\n******* END Bound Map ITV **** @\n\n" let convert (mem: BufferOverrunDomain.Mem.astate) : CostDomain.EnvDomainBO.astate = let open AbstractDomain.Types in match mem with | Bottom -> assert false | NonBottom {BufferOverrunDomain.MemReach.heap} -> let env = BufferOverrunDomain.Heap.fold (fun loc data acc -> match loc with | AbsLoc.Loc.Var (Var.LogicalVar id) -> let key = Exp.Var id in CostDomain.EnvDomain.add key (BufferOverrunDomain.Val.get_itv data) acc | AbsLoc.Loc.Var (Var.ProgramVar v) -> let key = Exp.Lvar v in CostDomain.EnvDomain.add key (BufferOverrunDomain.Val.get_itv data) acc | _ -> acc ) heap CostDomain.EnvDomainBO.empty in env let compute_upperbound_map pdesc invariant_map_NodesBasicCost data_invariant_map control_invariant_map = let fparam = Procdesc.get_formals pdesc in let pname = Procdesc.get_proc_name pdesc in let fparam' = List.map ~f:(fun (m, _) -> Exp.Lvar (Pvar.mk m pname)) fparam in let compute_node_upper_bound bound_map node = let node_id = Procdesc.Node.get_id node in match Procdesc.Node.get_kind node with | Procdesc.Node.Exit_node _ -> Node.IdMap.add node_id Itv.Bound.one bound_map | _ -> let entry_state_opt = AnalyzerNodesBasicCost.extract_post node_id invariant_map_NodesBasicCost in match entry_state_opt with | Some (entry_mem, _) -> let env = convert entry_mem in (* compute all the dependencies, i.e. set of variables that affect the control flow upto the node *) let all_deps = Control.compute_all_deps data_invariant_map control_invariant_map node in L.(debug Analysis Medium) "@\n>>> All dependencies for node = %a : %a @\n\n" Procdesc.Node.pp node Control.VarSet.pp all_deps ; (* bound = env(v1) *... * env(vn) *) let bound = CostDomain.EnvDomainBO.fold (fun exp itv acc -> let itv' = match exp with | Exp.Var _ -> Itv.one (* For temp var we give [1,1] so it doesn't count*) | Exp.Lvar _ when List.mem fparam' exp ~equal:Exp.equal -> Itv.one | Exp.Lvar pvar when Control.VarSet.mem (Var.of_pvar pvar) all_deps -> itv | Exp.Lvar _ -> (* For a var that doesn't affect control flow directly or indirectly, we give [1,1] so it doesn't count *) Itv.one | _ -> assert false in let range = Itv.range itv' in L.(debug Analysis Medium) "@\n>>>For node = %i : exp=%a itv=%a range =%a @\n\n" (node_id :> int) Exp.pp exp Itv.pp itv' Itv.Bound.pp range ; Itv.Bound.mult acc range ) env Itv.Bound.one in L.(debug Analysis Medium) "@\n>>>Setting bound for node = %i to %a@\n\n" (node_id :> int) Itv.Bound.pp bound ; Node.IdMap.add node_id bound bound_map | _ -> Node.IdMap.add node_id Itv.Bound.zero bound_map in let bound_map = List.fold (CFG.nodes pdesc) ~f:compute_node_upper_bound ~init:Node.IdMap.empty in print_upper_bound_map bound_map ; bound_map let upperbound bound_map nid = match Node.IdMap.find_opt nid bound_map with | Some bound -> bound | None -> L.(debug Analysis Medium) "@\n\n[WARNING] Bound not found for node %a, returning Top @\n" Node.pp_id nid ; Itv.Bound.pinf end (* Structural Constraints are expressions of the kind: n <= n1 +...+ nk The informal meaning is: the number of times node n can be executed is less or equal to the sum of the number of times nodes n1,..., nk can be executed. *) module StructuralConstraints = struct type rhs = Single of Node.id | Sum of Node.IdSet.t type t = {lhs: Node.id; rhs: rhs} let is_single ~lhs:expected_lhs = function | {lhs; rhs= Single single} when Node.equal_id lhs expected_lhs -> Some single | _ -> None let is_sum ~lhs:expected_lhs = function | {lhs; rhs= Sum sum} when Node.equal_id lhs expected_lhs -> Some sum | _ -> None let pp_rhs fmt = function | Single nid -> Node.pp_id fmt nid | Sum nidset -> Pp.seq ~sep:" + " Node.pp_id fmt (Node.IdSet.elements nidset) let pp fmt {lhs; rhs} = F.fprintf fmt "%a <= %a" Node.pp_id lhs pp_rhs rhs let print_constraint_list constraints = L.(debug Analysis Medium) "@\n\n******* Structural Constraints **** @\n" ; List.iter ~f:(fun c -> L.(debug Analysis Medium) "@\n %a @\n" pp c) constraints ; L.(debug Analysis Medium) "@\n******* END Structural Constraints **** @\n\n" (* for each program point return a set of contraints of the kind i<=Sum_{j \in Predecessors(i) } j i<=Sum_{j \in Successors(i)} j *) let compute_structural_constraints cfg = let compute_node_constraints acc node = let constraints_append node get_nodes tail = match get_nodes node with | [] -> tail | [single] -> {lhs= CFG.id node; rhs= Single (CFG.id single)} :: tail | nodes -> let sum = List.fold nodes ~init:Node.IdSet.empty ~f:(fun idset node -> Node.IdSet.add (CFG.id node) idset ) in {lhs= CFG.id node; rhs= Sum sum} :: tail in acc |> constraints_append node Procdesc.Node.get_preds |> constraints_append node Procdesc.Node.get_succs in let constraints = List.fold (CFG.nodes cfg) ~f:compute_node_constraints ~init:[] in print_constraint_list constraints ; constraints end (* MinTree is used to compute: \max (\Sum_{n \in Nodes} c_n * x_n ) given a set of contraints on x_n. The constraints involve the contro flow of the program. *) module MinTree = struct type mt_node = Leaf of (Node.id * Itv.Bound.t) | Min of mt_node list | Plus of mt_node list let add_leaf node nid leaf = let leaf' = Leaf (nid, leaf) in match node with Min l -> Min (leaf' :: l) | Plus l -> Plus (leaf' :: l) | _ -> assert false let plus_seq pp f l = Pp.seq ~sep:" + " pp f l let rec pp fmt node = match node with | Leaf (nid, c) -> F.fprintf fmt "%a:%a" Node.pp_id nid Itv.Bound.pp c | Min l -> F.fprintf fmt "Min(%a)" (Pp.comma_seq pp) l | Plus l -> F.fprintf fmt "(%a)" (plus_seq pp) l let add_child node child = match child with | Plus [] | Min [] -> node (* if it's a dummy child, don't add it *) | _ -> match node with Plus l -> Plus (child :: l) | Min l -> Min (child :: l) | _ -> assert false (* finds the subset of constraints of the form x_k <= x_j *) let get_k_single_constraints constraints k = List.filter_map constraints ~f:(StructuralConstraints.is_single ~lhs:k) (* finds the subset of constraints of the form x_k <= x_j1 +...+ x_jn and return the addends of the sum x_j1+x_j2+..+x_j_n*) let get_k_sum_constraints constraints k = List.filter_map constraints ~f:(StructuralConstraints.is_sum ~lhs:k) let rec evaluate_tree t = match t with | Leaf (_, c) -> c | Min l -> evaluate_operator Itv.Bound.min l | Plus l -> evaluate_operator Itv.Bound.plus_u l and evaluate_operator op l = match l with | [] -> assert false | [c] -> evaluate_tree c | c :: l' -> let res_c = evaluate_tree c in let res_l' = evaluate_operator op l' in op res_c res_l' (* TO DO: replace equality on sets with something more efficient*) let rec add_without_rep s list_of_sets = match list_of_sets with | [] -> [s] | s' :: tail -> if Node.IdSet.equal s s' then list_of_sets else s' :: add_without_rep s tail (* a plus node is well formed if has at least two addends *) let is_well_formed_plus_node plus_node = match plus_node with Plus (_ :: _ :: _) -> true | _ -> false let rec minimum_propagation (bound_map: BoundMap.t) (q: Node.id) (visited: Node.IdSet.t) (constraints: StructuralConstraints.t list) = let rec build_min node branch visited_acc worklist = match worklist with | [] -> (node, branch, visited_acc) | k :: rest -> if Node.IdSet.mem k visited_acc then build_min node branch visited_acc rest else let visited_acc = Node.IdSet.add k visited_acc in let node = add_leaf node k (BoundMap.upperbound bound_map k) in let k_constraints_upperbound = get_k_single_constraints constraints k in let worklist = List.filter ~f:(fun ub_id -> not (Node.IdSet.mem ub_id visited_acc)) k_constraints_upperbound |> List.rev_append worklist in let k_sum_constraints = get_k_sum_constraints constraints k in let branch = List.fold_left ~f:(fun branch set_addend -> if Node.IdSet.is_empty (Node.IdSet.inter set_addend visited_acc) then add_without_rep set_addend branch else branch ) ~init:branch k_sum_constraints in build_min node branch visited_acc worklist in let node, branch, visited_res = build_min (Min []) [] visited [q] in List.fold_left ~f:(fun i_node addend -> if Node.IdSet.cardinal addend < 2 then assert false else ( L.(debug Analysis Medium) "@\n\n|Set addends| = %i {" (Node.IdSet.cardinal addend) ; Node.IdSet.iter (fun e -> L.(debug Analysis Medium) " %a, " Node.pp_id e) addend ; L.(debug Analysis Medium) " }@\n " ) ; let plus_node = Node.IdSet.fold (fun n acc -> let child = minimum_propagation bound_map n visited_res constraints in add_child acc child ) addend (Plus []) in (* without this check it would add plus node with just one child, and give wrong results *) if is_well_formed_plus_node plus_node then add_child i_node plus_node else i_node ) ~init:node branch let compute_trees_from_contraints bound_map cfg constraints = let min_trees = List.fold ~f:(fun acc node -> let nid = Node.id node in (nid, minimum_propagation bound_map nid Node.IdSet.empty constraints) :: acc ) ~init:[] (CFG.nodes cfg) in List.iter ~f:(fun (nid, t) -> L.(debug Analysis Medium) "@\n node %a = %a @\n" Node.pp_id nid pp t) min_trees ; min_trees end module ReportedOnNodes = AbstractDomain.FiniteSet (Int) type extras_TransferFunctionsWCET = { basic_cost_map: AnalyzerNodesBasicCost.invariant_map ; min_trees_map: Itv.Bound.t Node.IdMap.t ; summary: Specs.summary } (* Calculate the final Worst Case Execution Time predicted for each node. It uses the basic cost of the nodes (computed previously by AnalyzerNodesBasicCost) and MinTrees which give an upperbound on the number of times a node can be executed *) module TransferFunctionsWCET (CFG : ProcCfg.S) = struct module CFG = CFG module Domain = AbstractDomain.Pair (Itv.Bound) (ReportedOnNodes) type extras = extras_TransferFunctionsWCET (* We don't report when the cost is Top as it corresponds to subsequent 'don't know's. Instead, we report Top cost only at the top level per function when `report_infinity` is set to true *) let report_cost summary instr (cost: Itv.Bound.t) nid reported_so_far = let mk_message () = F.asprintf "The execution time from the beginning of the function up to this program point is likely \ above the acceptable threshold of %a (estimated cost %a)" Itv.Bound.pp expensive_threshold Itv.Bound.pp cost in match cost with | b when Itv.Bound.is_not_infty b -> ( let above_expensive_threshold = not (Itv.Bound.le cost expensive_threshold) in let cost_desc = F.asprintf "with estimated cost %a" Itv.Bound.pp cost in match instr with | Sil.Call (_, _, _, loc, _) when above_expensive_threshold -> let ltr = [Errlog.make_trace_element 0 loc cost_desc []] in let exn = Exceptions.Checkers (IssueType.expensive_execution_time_call, Localise.verbatim_desc (mk_message ())) in Reporting.log_error summary ~loc ~ltr exn ; (cost, ReportedOnNodes.add nid reported_so_far) | Sil.Load (_, _, _, loc) | Sil.Store (_, _, _, loc) | Sil.Call (_, _, _, loc, _) | Sil.Prune (_, loc, _, _) when above_expensive_threshold -> let ltr = [Errlog.make_trace_element 0 loc cost_desc []] in let exn = Exceptions.Checkers (IssueType.expensive_execution_time_call, Localise.verbatim_desc (mk_message ())) in Reporting.log_error summary ~loc ~ltr exn ; (cost, ReportedOnNodes.add nid reported_so_far) | _ -> (cost, reported_so_far) ) | _ -> (cost, reported_so_far) (* get a list of nodes and check if we have already reported for at least one of them. In that case no need to report again. *) let should_report preds reported_so_far = List.for_all ~f:(fun n -> let n_id = (Procdesc.Node.get_id n :> int) in not (ReportedOnNodes.mem n_id reported_so_far) ) preds let exec_instr (astate: Domain.astate) {ProcData.extras} (node: CFG.node) instr : Domain.astate = let {basic_cost_map= invariant_map_cost; min_trees_map= trees; summary} = extras in let map_cost m : Itv.Bound.t = CostDomain.NodeInstructionToCostMap.fold (fun ((node_id, _) as instr_node_id) c acc -> let t = Node.IdMap.find node_id trees in let c_node = Itv.Bound.mult c t in L.(debug Analysis Medium) "@\n [AnalyzerWCET] Adding cost: (%a) --> c =%a t = %a @\n" ProcCfg.InstrNode.pp_id instr_node_id Itv.Bound.pp c Itv.Bound.pp t ; let c_node' = Itv.Bound.plus_u acc c_node in L.(debug Analysis Medium) "@\n [AnalyzerWCET] Adding cost: (%a) --> c_node=%a cost = %a @\n" ProcCfg.InstrNode.pp_id instr_node_id Itv.Bound.pp c_node Itv.Bound.pp c_node' ; c_node' ) m Itv.Bound.zero in let und_node = CFG.underlying_node node in let node_id = Procdesc.Node.get_id und_node in let cost_node = match AnalyzerNodesBasicCost.extract_post node_id invariant_map_cost with | Some (_, node_map) -> L.(debug Analysis Medium) "@\n AnalyzerWCET] Final map for node: %a @\n" Procdesc.Node.pp_id node_id ; map_cost node_map | _ -> assert false in L.(debug Analysis Medium) "@\n>>>AnalyzerWCET] Instr: %a Cost: %a@\n" (Sil.pp_instr Pp.text) instr Itv.Bound.pp cost_node ; let reported_so_far = snd astate in let astate' = let preds = Procdesc.Node.get_preds und_node in if should_report (und_node :: preds) reported_so_far then report_cost summary instr cost_node (node_id :> int) reported_so_far else (cost_node, reported_so_far) in astate' let pp_session_name _node fmt = F.pp_print_string fmt "cost(wcet)" end module AnalyzerWCET = AbstractInterpreter.Make (CFG) (TransferFunctionsWCET) let check_and_report_infinity cost proc_desc summary = if not (Itv.Bound.is_not_infty cost) then let loc = Procdesc.get_start_node proc_desc |> Procdesc.Node.get_loc in let message = F.asprintf "The execution time of the function %a cannot be computed" Typ.Procname.pp (Procdesc.get_proc_name proc_desc) in let exn = Exceptions.Checkers (IssueType.infinite_execution_time_call, Localise.verbatim_desc message) in Reporting.log_error ~loc summary exn let checker {Callbacks.tenv; summary; proc_desc} : Specs.summary = Preanal.do_preanalysis proc_desc tenv ; let proc_data = ProcData.make_default proc_desc tenv in let cfg = CFG.from_pdesc proc_desc in (* computes the data dependencies: node -> (var -> var set) *) let data_dep_invariant_map = Control.DataDepAnalyzer.exec_cfg cfg proc_data ~initial:Control.DataDepMap.empty ~debug:true in (* computes the control dependencies: node -> var set *) let control_dep_invariant_map = Control.ControlDepAnalyzer.exec_cfg cfg proc_data ~initial:Control.ControlDepSet.empty ~debug:true in let invariant_map_NodesBasicCost = (*compute_WCET cfg invariant_map min_trees in *) AnalyzerNodesBasicCost.exec_cfg cfg proc_data ~initial:NodesBasicCostDomain.init ~debug:true in (* given the semantics computes the upper bound on the number of times a node could be executed *) let bound_map = BoundMap.compute_upperbound_map cfg invariant_map_NodesBasicCost data_dep_invariant_map control_dep_invariant_map in let constraints = StructuralConstraints.compute_structural_constraints cfg in let min_trees = MinTree.compute_trees_from_contraints bound_map cfg constraints in let trees_valuation = List.fold ~f:(fun acc (nid, t) -> let res = MinTree.evaluate_tree t in L.(debug Analysis Medium) "@\n Tree %a eval to %a @\n" Node.pp_id nid Itv.Bound.pp res ; Node.IdMap.add nid res acc ) ~init:Node.IdMap.empty min_trees in let initWCET = (Itv.Bound.zero, ReportedOnNodes.empty) in let invariant_map_WCETFinal = (* Final map with nodes cost *) AnalyzerWCET.exec_cfg cfg (ProcData.make proc_desc tenv {basic_cost_map= invariant_map_NodesBasicCost; min_trees_map= trees_valuation; summary}) ~initial:initWCET ~debug:true in match AnalyzerWCET.extract_post (CFG.id (CFG.exit_node cfg)) invariant_map_WCETFinal with | Some (exit_cost, _) -> check_and_report_infinity exit_cost proc_desc summary ; Summary.update_summary {post= exit_cost} summary | None -> if Procdesc.Node.get_succs (Procdesc.get_start_node proc_desc) <> [] then ( L.internal_error "Failed to compute final cost for function %a" Typ.Procname.pp (Procdesc.get_proc_name proc_desc) ; summary ) else summary