package mopsa
MOPSA: A Modular and Open Platform for Static Analysis using Abstract Interpretation
Install
Dune Dependency
Authors
Maintainers
Sources
mopsa-analyzer-v1.1.tar.gz
md5=fdee20e988343751de440b4f6b67c0f4
sha512=f5cbf1328785d3f5ce40155dada2d95e5de5cce4f084ea30cfb04d1ab10cc9403a26cfb3fa55d0f9da72244482130fdb89c286a9aed0d640bba46b7c00e09500
doc/src/lang/frontend.ml.html
Source file frontend.ml
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See the *) (* GNU Lesser General Public License for more details. *) (* *) (* You should have received a copy of the GNU Lesser General Public License *) (* along with this program. If not, see <http://www.gnu.org/licenses/>. *) (* *) (****************************************************************************) (** Universal frontend translates the parser's AST into Framework's AST. *) open Mopsa open Mopsa_universal_parser module NameG = struct let compt = ref 0 let fresh () = let rep = !compt in incr compt; rep end open Lexing open Ast open Mopsa module T = Ast module U = U_ast module Float = ItvUtils.Float (* vars to their unique identifier and declared types *) module MS = MapExt.StringMap type var_context = (int * typ) MS.t type fun_context = (T.fundec) MS.t let builtin_functions = [ {name = "mopsa_assume"; args = [None]; output = T_unit}; {name = "append"; args = [Some (T_array T_int); Some T_int]; output = T_unit}; ] let from_extent (e: U.extent) : Location.range = e type uvar = { uvar_range: range; uvar_uid: int; uvar_orig_name: string; uvar_uniq_name: string; } type var_kind += | V_uvar of uvar let () = register_var { print = (fun next fmt v -> match vkind v with | V_uvar var -> if !Framework.Core.Ast.Var.print_uniq_with_uid then Format.fprintf fmt "%s:%a" var.uvar_orig_name pp_relative_range var.uvar_range else Format.fprintf fmt "%s" var.uvar_orig_name | _ -> next fmt v ); compare = (fun next v1 v2 -> match vkind v1, vkind v2 with | V_uvar var1, V_uvar var2 -> Compare.compose [ (fun () -> Stdlib.compare var1.uvar_uid var2.uvar_uid); (fun () -> Stdlib.compare var1.uvar_uniq_name var2.uvar_uniq_name) ] | _ -> next v1 v2 ); } let from_var (v: string) (ext: U.extent) (var_ctx: var_context) = try let (id, typ) = MS.find v var_ctx in let uniq_name = (v ^ ":" ^ string_of_int id) in mkv uniq_name (V_uvar { uvar_range = ext; uvar_uid = id; uvar_orig_name = v; uvar_uniq_name = uniq_name }) typ with | Not_found -> Exceptions.panic_at ext "%s was not found in typing/naming context" v let rec from_typ (typ: U_ast.typ) : typ = match typ with | AST_INT -> T_int | AST_REAL -> T_float F_DOUBLE | AST_ARRAY t -> T_array (from_typ t) | AST_STRING -> T_string | AST_CHAR -> T_char (* find a common type for the arguments of binary operations *) let unify_typ (x:typ) (y:typ) : typ = match x,y with | T_int, T_float _ -> y | T_float _, T_int -> x | _ -> if compare_typ x y = 0 then x else Exceptions.panic "cannot unify types %a and %a" pp_typ x pp_typ y (* cast expression to the given type (if needed) *) let to_typ (t:typ) (e:expr) : expr = let range = erange e in let orgt = etyp e in if compare_typ orgt t = 0 then e else match ekind e, orgt, t with | _, (T_int | T_float _), (T_int | T_float _) -> mk_unop O_cast e ~etyp:t range | E_constant (C_top T_any), T_any, t -> {e with ekind = E_constant (C_top t); etyp = t} | _ -> Exceptions.panic "cannot convert expression %a of type %a to type %a" pp_expr e pp_typ orgt pp_typ t let from_binop (t: typ) (b: U.binary_op) : operator = match t, b with | T_int, AST_PLUS -> O_plus | T_int, AST_MINUS -> O_minus | T_int, AST_MULTIPLY -> O_mult | T_int, AST_DIVIDE -> O_div | T_int, AST_EQUAL -> O_eq | T_int, AST_NOT_EQUAL -> O_ne | T_int, AST_LESS -> O_lt | T_int, AST_LESS_EQUAL -> O_le | T_int, AST_GREATER -> O_gt | T_int, AST_GREATER_EQUAL -> O_ge | T_int, AST_AND -> O_log_and | T_int, AST_OR -> O_log_or | T_string, AST_CONCAT -> O_concat | T_string, AST_PLUS -> O_concat | T_string, AST_EQUAL -> O_eq | T_float _, AST_PLUS -> O_plus | T_float _, AST_MINUS -> O_minus | T_float _, AST_MULTIPLY -> O_mult | T_float _, AST_DIVIDE -> O_div | T_float _, AST_EQUAL -> O_eq | T_float _, AST_NOT_EQUAL -> O_ne | T_float _, AST_LESS -> O_lt | T_float _, AST_LESS_EQUAL -> O_le | T_float _, AST_GREATER -> O_gt | T_float _, AST_GREATER_EQUAL -> O_ge | T_array _, AST_CONCAT -> O_concat | _ -> Exceptions.panic "operator %a cannot be used with type %a" U_ast_printer.print_binary_op b pp_typ t let from_unop (t: typ) (b: U.unary_op) : operator = match t, b with | T_int, AST_UNARY_PLUS -> O_plus | T_int, AST_UNARY_MINUS -> O_minus | T_int, AST_NOT -> O_log_not | T_float f, AST_UNARY_PLUS -> O_plus | T_float f, AST_UNARY_MINUS -> O_minus | T_float f, AST_ROUND -> O_cast | _ -> Exceptions.panic "operator %a cannot be used with type %a" U_ast_printer.print_unary_op b pp_typ t let rec from_expr (e: U.expr) (ext : U.extent) (var_ctx: var_context) (fun_ctx: fun_context option): expr = let range = from_extent ext in match e with | AST_unit_const -> mk_expr ~etyp:T_unit (E_constant (C_unit)) range | AST_fun_call((f, f_ext), args) -> begin let look_in_builtins (fun_ctx) = let exception Match of (expr list * fun_builtin) in try List.iter (fun (bi:fun_builtin) -> let () = Debug.debug ~channel:("remove_me") "builtin: %s, fun: %s, b: %b" bi.name f (bi.name = f) in if bi.name = f && List.length bi.args = List.length args then let exception NoMatch in try let el = List.map2 (fun (e, ext) x -> match x with | Some x -> let e' = from_expr e ext var_ctx (fun_ctx) in let typ = etyp e' in let () = Debug.debug ~channel:("remove_me") "x: %a, typ: %a" pp_typ x pp_typ typ in if compare_typ typ x = 0 then e' else raise NoMatch | None -> from_expr e ext var_ctx (fun_ctx) ) args bi.args in raise (Match (el, bi)) with | NoMatch -> () ) builtin_functions; Exceptions.panic_at ext "%s was not found in naming context nor in builtin functions" f with | Match(el, bi) -> (mk_expr ~etyp:(bi.output) (E_call(mk_expr (E_function (Builtin bi)) range, el)) range) in match fun_ctx with | None -> look_in_builtins (None) | Some fun_ctx -> begin try let fundec = MS.find f fun_ctx in if List.length fundec.fun_parameters = List.length args then let el = List.map2 (fun (e, ext) x -> let e' = from_expr e ext var_ctx (Some fun_ctx) in let typ = etyp e' in if compare_typ x.vtyp typ = 0 then e' else Exceptions.panic_at ext "type of %a incompatible with declared function" U_ast_printer.print_expr e ) args fundec.fun_parameters in let rettyp = match fundec.fun_return_type with | None -> T_int | Some t -> t in (mk_expr ~etyp:rettyp (E_call(mk_expr (E_function (User_defined fundec)) range, el)) range) else Exceptions.panic_at ext "%s number of arguments incompatible with call" f with | Not_found -> begin look_in_builtins (Some fun_ctx) end end end | AST_unary (op, (e, ext)) -> begin let e = from_expr e ext var_ctx fun_ctx in let typ = etyp e in let op = from_unop typ op in mk_unop op e ~etyp:typ range end | AST_binary (op, (e1, ext1), (e2, ext2)) -> begin let e1 = from_expr e1 ext1 var_ctx fun_ctx in let typ1 = etyp e1 in let e2 = from_expr e2 ext2 var_ctx fun_ctx in let typ2 = etyp e2 in let typ = unify_typ typ1 typ2 in let e1,e2 = to_typ typ e1, to_typ typ e2 in let op = from_binop typ op in mk_binop e1 op e2 ~etyp:typ range end | AST_identifier (v, ext) -> mk_var (from_var v ext var_ctx) range | AST_int_const (s, _) -> mk_z (Z.of_string s) range | AST_bool_const (b, _) -> mk_int (if b then 1 else 0) range | AST_real_const (s, _) -> (* double interval enclosing the real value *) let lo = Float.of_string `DOUBLE `DOWN s and up = Float.of_string `DOUBLE `UP s in mk_float_interval ~prec:F_DOUBLE lo up range | AST_string_const (s, _) -> mk_string s range | AST_char_const(c, _) -> mk_int ~typ:T_int (int_of_char c) range | AST_array_const(a, _) -> mk_expr (E_array (List.map (fun (e, ext) -> from_expr e ext var_ctx fun_ctx) (Array.to_list a))) range | AST_rand((l, _), (u, _)) -> mk_z_interval (Z.of_string l) (Z.of_string u) range | AST_randf((l, _), (u, _)) -> mk_float_interval (float_of_string l) (float_of_string u) range | AST_rand_string -> mk_top T_any range | AST_array_access((e1, ext1), (e2, ext2)) -> begin let e1o = e1 in let e1 = from_expr e1 ext1 var_ctx fun_ctx in let e2 = from_expr e2 ext2 var_ctx fun_ctx in let e2 = to_typ T_int e2 in match etyp e1 with | T_string -> mk_expr (E_subscript(e1, e2)) ~etyp:T_int range | T_array t -> mk_expr (E_subscript(e1, e2)) ~etyp:t range | _ -> Exceptions.panic_at ext "%a is of type %a and can not be subscripted" U_ast_printer.print_expr e1o (pp_typ) (etyp e1) end | AST_len (e, ext) -> begin let e1 = from_expr e ext var_ctx fun_ctx in match etyp e1 with | T_string | T_array _ -> mk_expr (E_len e1) ~etyp:T_int range | _ -> Exceptions.panic_at ext "%a is of type %a and can not be lengthed" U_ast_printer.print_expr e (pp_typ) (etyp e1) end let rec from_stmt (s: U.stat) (ext: U.extent) (var_ctx: var_context) (fun_ctx: fun_context option): stmt = let range = from_extent ext in match s with | AST_block l -> mk_block (List.map (fun (x, ext) -> from_stmt x ext var_ctx fun_ctx) l) range | AST_assign((e1, ext1), (e2, ext2)) -> begin let e1o = e1 in match e1 with | AST_array_access(_, _) | AST_identifier _ -> let e1 = from_expr e1 ext1 var_ctx fun_ctx in let e2 = from_expr e2 ext2 var_ctx fun_ctx in let e2 = to_typ (etyp e1) e2 in mk_assign e1 e2 range | _ -> Exceptions.panic_at ext "%a not considered a left-value for now " U_ast_printer.print_expr e1o end | AST_if((e1, ext_e1), (s1, ext_s1), Some (s2, ext_s2)) -> let e1 = from_expr e1 ext_e1 var_ctx fun_ctx in let s1 = from_stmt s1 ext_s1 var_ctx fun_ctx in let s2 = from_stmt s2 ext_s2 var_ctx fun_ctx in mk_if e1 s1 s2 range | AST_if((e1, ext_e1), (s1, ext_s1), None) -> let e1 = from_expr e1 ext_e1 var_ctx fun_ctx in let s1 = from_stmt s1 ext_s1 var_ctx fun_ctx in mk_if e1 s1 (mk_nop range) range | AST_while((e1, ext_e1), (s1, ext_s1)) -> let e1 = from_expr e1 ext_e1 var_ctx fun_ctx in let s1 = from_stmt s1 ext_s1 var_ctx fun_ctx in mk_while e1 s1 range | AST_for((v1, ext_v1), (e1, ext_e1), (e2, ext_e2), (s1, ext_s1)) -> let e1 = from_expr e1 ext_e1 var_ctx fun_ctx in let e2 = from_expr e2 ext_e2 var_ctx fun_ctx in let v = from_var v1 ext_v1 var_ctx in let s1 = from_stmt s1 ext_s1 var_ctx fun_ctx in mk_block [ mk_assign (mk_var v (tag_range range "var_init_for_variable")) e1 (tag_range range "expr_init_for_variable"); mk_while (mk_binop (mk_var v (tag_range range "var_comp_for")) O_le e2 ~etyp:(T_int) (tag_range range "comp_for") ) (mk_block ( [ s1; mk_assign (mk_var v (tag_range range "var_incr_for")) (mk_binop (mk_var v (tag_range range "var_incr_for")) O_plus (mk_z Z.one (tag_range range "one_for")) ~etyp:(T_int) (tag_range range "incr_for") ) (tag_range range "assign_for") ]) (tag_range range "body_for") ) (tag_range range "total_for") ] range | AST_return (Some (e, ext)) -> let e = from_expr e ext var_ctx fun_ctx in {skind = S_return (Some e); srange = range } | AST_return None -> {skind = S_return None; srange = range } | AST_break -> {skind = S_break; srange = range} | AST_continue -> {skind = S_continue; srange = range} | AST_assert (e, ext) -> let e = from_expr e ext var_ctx fun_ctx in mk_assert e range | AST_assume (e, ext) -> let e = from_expr e ext var_ctx fun_ctx in mk_assume e range | AST_print -> mk_stmt S_print_state range | AST_expr(e, ext) -> let e' = from_expr e ext var_ctx fun_ctx in mk_expr_stmt e' range let rec check_declaration_list (dl : U.declaration U.ext list) = match dl with | p::q -> aux p q; check_declaration_list q | [] -> () and aux (((((_,v),e),_),_) as p : U.declaration U.ext) (dl: U.declaration U.ext list) = match dl with | ((((_,v'),e'),_),_)::q when v = v' -> Exceptions.panic_at e "%s has already been declared at %a" v' pp_range e' | p':: q -> aux p q | [] -> () let var_ctx_of_declaration (dl : U_ast.declaration U.ext list) (var_ctx: var_context) = let () = check_declaration_list dl in let add_var var_ctx v t = try MS.add v (NameG.fresh (), t) var_ctx with | Not_found -> MS.add v (NameG.fresh (), t) var_ctx in let var_ctx, gvars = List.fold_left (fun (var_ctx, gvars) ((((t, v), extv ), o), e) -> let new_var_ctx = add_var var_ctx v (from_typ t) in let vv = from_var v extv new_var_ctx in (new_var_ctx, vv :: gvars) ) (var_ctx, []) dl in var_ctx, gvars let var_ctx_init_of_declaration (dl : U_ast.declaration U.ext list) (var_ctx: var_context) (fun_ctx: fun_context option) (nvar_ctx)= let add_var var_ctx v t = try match nvar_ctx with | Some nvar_ctx -> MS.add v (MS.find v nvar_ctx) var_ctx | None -> MS.add v (NameG.fresh (), t) var_ctx with | Not_found -> assert false in let var_ctx, init, gvars = List.fold_left (fun (var_ctx, init, gvars) ((((t, v), extv ), o), e) -> let new_var_ctx = add_var var_ctx v (from_typ t) in let vv = from_var v extv new_var_ctx in let range = from_extent extv in let stmt_add = mk_add (mk_var vv (tag_range range "initializer_var")) (tag_range range "initializer") in let init = stmt_add :: init in match o with | Some (e, ext) -> let e = from_expr e ext var_ctx fun_ctx in let e = to_typ (from_typ t) e in let range = from_extent ext in let stmt_init = mk_assign (mk_var vv (tag_range range "initializer_var")) e (tag_range range "initializer") in (new_var_ctx, stmt_init :: init, vv :: gvars) | None -> (new_var_ctx, init, vv :: gvars) ) (var_ctx, [], []) dl in var_ctx, List.rev init, gvars let var_ctx_of_function (var_ctx: var_context) (fundec: U.fundec) = let add_var var_ctx v t = try MS.add v (NameG.fresh (), t) var_ctx with | Not_found -> MS.add v (NameG.fresh (), t) var_ctx in let var_ctx = List.fold_left (fun acc ((t, v), _) -> add_var acc v (from_typ t) ) var_ctx fundec.parameters in let var_ctx, _ = var_ctx_of_declaration fundec.locvars var_ctx in var_ctx let var_init_of_function (var_ctx: var_context) var_ctx_map (fun_ctx: fun_context) (fundec: U.fundec) = let nvar_ctx = MS.find fundec.funname var_ctx_map in let add_var var_ctx n_var_ctx v t = try MS.add v (MS.find v n_var_ctx) var_ctx with | Not_found -> assert false in let var_ctx = List.fold_left (fun acc ((t, v), _) -> add_var acc nvar_ctx v (from_typ t) ) var_ctx fundec.parameters in let var_ctx, init, _ = var_ctx_init_of_declaration fundec.locvars var_ctx (Some (fun_ctx)) (Some nvar_ctx) in var_ctx, init let from_fundec (f: U.fundec) (var_ctx: var_context): T.fundec = let typ = OptionExt.lift from_typ f.return_type in { fun_orig_name = f.funname; fun_uniq_name = f.funname; fun_range = from_extent f.range; fun_parameters = List.map (fun ((_, v), ext) -> from_var v ext var_ctx) f.parameters; fun_locvars = List.map (fun ((((_, v), _), _), ext) -> from_var v ext var_ctx) f.locvars; fun_body = mk_nop (from_extent (snd f.body)); fun_return_type = typ; fun_return_var = None; } let fun_ctx_of_global (fl: U_ast.fundec U.ext list) (var_ctx: var_context) = List.fold_left (fun (acc, var_ctx_map) (fundec, _) -> let var_ctx = var_ctx_of_function var_ctx fundec in (MS.add fundec.funname (from_fundec fundec var_ctx) acc, MS.add fundec.funname var_ctx var_ctx_map) ) (MS.empty, MS.empty) fl let add_body (fl: fun_context) (f: string) (b: stmt): unit = try let fundec = MS.find f fl in fundec.fun_body <- b; with | Not_found -> Exceptions.panic "[Universal.frontend] should not happen" let from_prog (p: U_ast.prog) : prog_kind = let ext = snd (p.main) in let var_ctx, init, gvars = var_ctx_init_of_declaration p.gvars MS.empty None None in let fun_ctx, var_ctx_map = fun_ctx_of_global p.funs var_ctx in List.iter (fun (fundec, ext) -> let var_ctx, init = var_init_of_function var_ctx var_ctx_map fun_ctx fundec in let body = from_stmt (fst fundec.body) (snd fundec.body) var_ctx (Some fun_ctx) in let total = mk_block (init @ [body]) (from_extent ext) in add_body fun_ctx fundec.funname total ) p.funs; let total = from_stmt (fst p.main) (snd p.main) var_ctx (Some fun_ctx) in let with_init = mk_block (init @ [total]) (from_extent ext) in P_universal { universal_gvars = gvars; universal_fundecs = (MS.bindings fun_ctx) |> List.map (snd); universal_main = with_init } let rec parse_program (files: string list): program = match files with | [filename] -> let ast = U_file_parser.parse_file filename in { prog_kind = from_prog ast; prog_range = mk_program_range [filename]; } | [] -> panic "no input file" | _ -> panic "analysis of multiple files not supported" (* Front-end registration *) let () = register_frontend { lang = "universal"; parse = parse_program; on_panic = fun _ _ _ -> (); }