(* * Copyright (c) 2016 - 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 module F = Format module L = Logging (** utilities for writing abstract domains/transfer function tests *) (** structured language that makes it easy to write small test programs in OCaml *) module StructuredSil = struct type assertion = string type label = int type structured_instr = | Cmd of Sil.instr | If of Sil.exp * structured_instr list * structured_instr list | While of Sil.exp * structured_instr list (* try/catch/finally. note: there is no throw. the semantics are that every command in the try block is assumed to be possibly-excepting, and the catch block captures all exceptions *) | Try of structured_instr list * structured_instr list * structured_instr list | Invariant of assertion * label (* gets autotranslated into assertions about abstract state *) type structured_program = structured_instr list let rec pp_structured_instr fmt = function | Cmd instr -> (Sil.pp_instr pe_text) fmt instr | If (exp, then_instrs, else_instrs) -> (* TODO (t10287763): indent bodies of if/while *) F.fprintf fmt "if (%a) {@.%a@.} else {@.%a@.}" (Sil.pp_exp pe_text) exp pp_structured_instr_list then_instrs pp_structured_instr_list else_instrs | While (exp, instrs) -> F.fprintf fmt "while (%a) {@.%a@.}" (Sil.pp_exp pe_text) exp pp_structured_instr_list instrs | Try (try_, catch, finally) -> F.fprintf fmt "try {@.%a@.} catch (...) {@.%a@.} finally {@.%a@.}" pp_structured_instr_list try_ pp_structured_instr_list catch pp_structured_instr_list finally | Invariant (inv_str, label) -> F.fprintf fmt "invariant %d: %s" label inv_str and pp_structured_instr_list fmt instrs = F.pp_print_list ~pp_sep:F.pp_print_newline (fun fmt instr -> F.fprintf fmt "%a" pp_structured_instr instr) fmt instrs let pp_structured_program = pp_structured_instr_list let dummy_typ = Typ.Tvoid let dummy_loc = Location.dummy let dummy_procname = Procname.empty_block let label_counter = ref 0 let fresh_label () = incr label_counter; !label_counter let invariant inv_str = Invariant (inv_str, fresh_label ()) let pvar_of_str str = Pvar.mk (Mangled.from_string str) dummy_procname let var_of_str str = Sil.Lvar (pvar_of_str str) let ident_of_str str = Ident.create_normal (Ident.string_to_name str) 0 let unknown_exp = var_of_str "__unknown__" let make_letderef ~rhs_typ lhs_id rhs_exp = Cmd (Sil.Letderef (lhs_id, rhs_exp, rhs_typ, dummy_loc)) let make_set ~rhs_typ ~lhs_exp ~rhs_exp = Cmd (Sil.Set (lhs_exp, rhs_typ, rhs_exp, dummy_loc)) let make_call ?(procname=dummy_procname) ret_ids args = let call_exp = Sil.Const (Const.Cfun procname) in Cmd (Sil.Call (ret_ids, call_exp, args, dummy_loc, Sil.cf_default)) let id_assign_id ?(rhs_typ=dummy_typ) lhs rhs = let lhs_id = ident_of_str lhs in let rhs_exp = Sil.Var (ident_of_str rhs) in make_letderef ~rhs_typ lhs_id rhs_exp let id_assign_var ?(rhs_typ=dummy_typ) lhs rhs = let lhs_id = ident_of_str lhs in let rhs_exp = var_of_str rhs in make_letderef ~rhs_typ lhs_id rhs_exp let id_set_id ?(rhs_typ=dummy_typ) lhs_id rhs_id = let lhs_exp = Sil.Var (ident_of_str lhs_id) in let rhs_exp = Sil.Var (ident_of_str rhs_id) in make_set ~rhs_typ ~lhs_exp ~rhs_exp let var_assign_exp ~rhs_typ lhs rhs_exp = let lhs_exp = var_of_str lhs in make_set ~rhs_typ ~lhs_exp ~rhs_exp let var_assign_int lhs rhs = let rhs_exp = Sil.exp_int (IntLit.of_int rhs) in let rhs_typ = Typ.Tint Typ.IInt in var_assign_exp ~rhs_typ lhs rhs_exp let var_assign_id ?(rhs_typ=dummy_typ) lhs rhs = let lhs_exp = var_of_str lhs in let rhs_exp = Sil.Var (ident_of_str rhs) in make_set ~rhs_typ ~lhs_exp ~rhs_exp (* x = &y *) let var_assign_addrof_var ?(rhs_typ=dummy_typ) lhs rhs = let lhs_exp = var_of_str lhs in let rhs_exp = var_of_str rhs in make_set ~rhs_typ ~lhs_exp ~rhs_exp let call_unknown ret_id_strs arg_strs = let args = IList.map (fun param_str -> (var_of_str param_str, dummy_typ)) arg_strs in let ret_ids = IList.map ident_of_str ret_id_strs in make_call ret_ids args let call_unknown_no_ret arg_strs = call_unknown [] arg_strs end module Make (CFG : ProcCfg.S with type node = Cfg.Node.t) (S : Scheduler.Make) (T : TransferFunctions.Make) = struct open StructuredSil module I = AbstractInterpreter.Make (CFG) (S) (T) module M = I.M type assert_map = string M.t let structured_program_to_cfg program = let cfg = Cfg.Node.create_cfg () in let pdesc = Cfg.Procdesc.create cfg (ProcAttributes.default dummy_procname !Config.curr_language) in let create_node kind cmds = Cfg.Node.create cfg dummy_loc kind cmds pdesc in let set_succs cur_node succs ~exn_handlers= Cfg.Node.set_succs_exn cfg cur_node succs exn_handlers in let mk_prune_nodes_for_cond cond_exp if_kind = let mk_prune_node cond_exp if_kind true_branch = let prune_instr = Sil.Prune (cond_exp, dummy_loc, true_branch, if_kind) in create_node (Cfg.Node.Prune_node (true_branch, if_kind, "")) [prune_instr] in let true_prune_node = mk_prune_node cond_exp if_kind true in let false_prune_node = let negated_cond_exp = Sil.UnOp (Unop.LNot, cond_exp, None) in mk_prune_node negated_cond_exp if_kind false in true_prune_node, false_prune_node in let rec structured_instr_to_node (last_node, assert_map) exn_handlers = function | Cmd cmd -> let node = create_node (Cfg.Node.Stmt_node "") [cmd] in set_succs last_node [node] ~exn_handlers; node, assert_map | If (exp, then_instrs, else_instrs) -> let then_prune_node, else_prune_node = mk_prune_nodes_for_cond exp Sil.Ik_if in set_succs last_node [then_prune_node; else_prune_node] ~exn_handlers; let then_branch_end_node, assert_map' = structured_instrs_to_node then_prune_node assert_map exn_handlers then_instrs in let else_branch_end_node, assert_map'' = structured_instrs_to_node else_prune_node assert_map' exn_handlers else_instrs in let join_node = create_node Cfg.Node.Join_node [] in set_succs then_branch_end_node [join_node] ~exn_handlers; set_succs else_branch_end_node [join_node] ~exn_handlers; join_node, assert_map'' | While (exp, body_instrs) -> let loop_head_join_node = create_node Cfg.Node.Join_node [] in set_succs last_node [loop_head_join_node] ~exn_handlers; let true_prune_node, false_prune_node = mk_prune_nodes_for_cond exp Sil.Ik_while in set_succs loop_head_join_node [true_prune_node; false_prune_node] ~exn_handlers; let loop_body_end_node, assert_map' = structured_instrs_to_node true_prune_node assert_map exn_handlers body_instrs in let loop_exit_node = create_node (Cfg.Node.Skip_node "") [] in set_succs loop_body_end_node [loop_head_join_node] ~exn_handlers; set_succs false_prune_node [loop_exit_node] ~exn_handlers; loop_exit_node, assert_map' | Try (try_instrs, catch_instrs, finally_instrs) -> let catch_start_node = create_node (Cfg.Node.Skip_node "exn_handler") [] in (* use [catch_start_node] as the exn handler *) let try_end_node, assert_map' = structured_instrs_to_node last_node assert_map [catch_start_node] try_instrs in let catch_end_node, assert_map'' = structured_instrs_to_node catch_start_node assert_map' exn_handlers catch_instrs in let finally_start_node = create_node (Cfg.Node.Skip_node "finally") [] in set_succs try_end_node [finally_start_node] ~exn_handlers; set_succs catch_end_node [finally_start_node] ~exn_handlers; structured_instrs_to_node finally_start_node assert_map'' exn_handlers finally_instrs | Invariant (inv_str, inv_label) -> let node = create_node (Cfg.Node.Stmt_node "Invariant") [] in set_succs last_node [node] ~exn_handlers; (* add the assertion to be checked after analysis converges *) node, M.add (CFG.id node) (inv_str, inv_label) assert_map and structured_instrs_to_node last_node assert_map exn_handlers instrs = IList.fold_left (fun acc instr -> structured_instr_to_node acc exn_handlers instr) (last_node, assert_map) instrs in let start_node = create_node (Cfg.Node.Start_node pdesc) [] in Cfg.Procdesc.set_start_node pdesc start_node; let no_exn_handlers = [] in let last_node, assert_map = structured_instrs_to_node start_node M.empty no_exn_handlers program in let exit_node = create_node (Cfg.Node.Exit_node pdesc) [] in set_succs last_node [exit_node] ~exn_handlers:no_exn_handlers; Cfg.Procdesc.set_exit_node pdesc exit_node; pdesc, assert_map let create_test test_program extras _ = let pdesc, assert_map = structured_program_to_cfg test_program in let inv_map = I.exec_pdesc (ProcData.make pdesc (Tenv.create ()) extras) in let collect_invariant_mismatches node_id (inv_str, inv_label) error_msgs_acc = let post_str = try let state = M.find node_id inv_map in pp_to_string I.A.pp state.post with Not_found -> "_|_" in if inv_str <> post_str then let error_msg = F.fprintf F.str_formatter "> Expected state %s at invariant %d, but found state %s" inv_str inv_label post_str |> F.flush_str_formatter in error_msg :: error_msgs_acc else error_msgs_acc in match M.fold collect_invariant_mismatches assert_map [] with | [] -> () (* no mismatches, test passed *) | error_msgs -> let mismatches_str = F.pp_print_list (fun fmt error_msg -> F.fprintf fmt "%s" error_msg) F.str_formatter (IList.rev error_msgs) |> F.flush_str_formatter in let assert_fail_message = F.fprintf F.str_formatter "Error while analyzing@.%a:@.%s@." pp_structured_program test_program mismatches_str |> F.flush_str_formatter in OUnit2.assert_failure assert_fail_message let create_tests extras tests = let open OUnit2 in IList.map (fun (name, test_program) -> name>::create_test test_program extras) tests end