package codex
The Codex library for building static analysers based on abstract interpretation
Install
dune-project
Dependency
Authors
Maintainers
Sources
1.0-rc4.tar.gz
md5=bc7266a140c6886add673ede90e335d3
sha512=8da42c0ff2c1098c5f9cb2b5b43b306faf7ac93b8f5ae00c176918cee761f249ff45b29309f31a05bbcf6312304f86a0d5a000eb3f1094d3d3c2b9b4c7f5c386
doc/src/codex.domains/overflow_checks.ml.html
Source file overflow_checks.ml
1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 33 34 35 36 37 38 39 40 41 42 43 44 45 46 47 48 49 50 51 52 53 54 55 56 57 58 59 60 61 62 63 64 65 66 67 68 69 70 71 72 73 74 75 76 77 78 79 80 81 82 83 84 85 86 87 88 89 90 91 92 93 94 95 96 97 98 99 100 101 102 103 104 105 106 107 108 109 110 111 112 113 114 115 116 117 118 119 120 121 122 123 124 125 126 127 128 129 130 131 132 133 134 135 136 137 138 139 140 141 142 143 144 145 146 147 148 149 150 151 152 153 154 155 156 157 158 159 160 161 162 163 164 165 166 167 168 169 170 171 172 173 174 175 176 177 178 179 180 181 182 183 184 185 186 187 188 189 190 191 192 193 194 195 196 197 198 199 200 201 202 203 204 205 206 207 208 209 210 211 212 213 214 215 216 217 218(**************************************************************************) (* This file is part of the Codex semantics library. *) (* *) (* Copyright (C) 2013-2025 *) (* CEA (Commissariat à l'énergie atomique et aux énergies *) (* alternatives) *) (* *) (* you can redistribute it and/or modify it under the terms of the GNU *) (* Lesser General Public License as published by the Free Software *) (* Foundation, version 2.1. *) (* *) (* It is distributed in the hope that it will be useful, *) (* but WITHOUT ANY WARRANTY; without even the implied warranty of *) (* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the *) (* GNU Lesser General Public License for more details. *) (* *) (* See the GNU Lesser General Public License version 2.1 *) (* for more details (enclosed in the file LICENSE). *) (* *) (**************************************************************************) module Log = Tracelog.Make(struct let category = "Domains.Overflow_checks" end);; module In_bits = Units.In_bits open Operator.Alarm let increase_size = Codex_config.extend_size_for_additive_operations module Make (Sub : Sig.BASE_WITH_INTEGER) = struct include Sub (* TODO: Ideally, we would emit alarms here otherwise some assumptions could go unnoticed. This requires that every new pointer is assumed to be in the correct range, which we don't do for now. *) let should_emit_alarm = false let emit_unsigned_signed_alarms = false module Binary_Forward = struct include Sub.Binary_Forward (* TODO: Should be provided in the domain signature; assume true is a workaround. *) let clone dom = let dom' = match Sub.assume dom (Sub.Boolean_Forward.true_ dom) with | Some x -> x | None -> assert false in dom' (* Evaluate a condition in a copy of dom (to not pollute it with new terms), that is removed if the condition is valid. Otherwise, calls [emit_alarm] then refine dom assuming that the condition is true. "valid" means that the condition does not return false if [id_or_not] is id, and does not return true if it is Quadrivalent.not. *) let check_cond mkcond emit_alarm dom = let dom' = clone dom in let cond = mkcond dom' in match query_boolean dom' cond with | Lattices.Quadrivalent.True -> () | Lattices.Quadrivalent.Bottom -> Log.fatal (fun p -> p "Evaluation of an overflow condition returned a bottom. \ This is probably an analyzer error that should not have happened \ (the bottom should have been catched earlier). Please report.") | Lattices.Quadrivalent.(False | Top) -> emit_alarm (); begin match assume dom' cond (* Further refine the error. *) with | None -> raise Sig.Bottom | Some dom'' -> Sub.Context.assign dom dom'' end (** [check_overflow ~signed ~small_size ~wide_size value] Adds assertion ensuring that [value], a binary value of size [~wide_size] bits, can correctly fit on [~small_size] bits without over/underflow. - If [~signed], this means [-2^{small_size-1} <=s value <=s 2^{small_size-1} - 1] - If not [~signed], this means [0 <=u value <=u 2^small_size - 1] *) let check_overflow ~signed ~(small_size:In_bits.t) ~wide_size operation value dom = let compare = (if signed then bisle else biule) in let two_pow_size = Z.shift_left Z.one (if signed then (small_size:>int)-1 else (small_size:>int)) in (* Upper bound *) let upper_bound = Z.sub two_pow_size Z.one in let mkcond dom = let upper_bound_val = biconst ~size:wide_size upper_bound dom in compare ~size:wide_size dom value upper_bound_val in let emit_alarm () = if should_emit_alarm then let size = small_size in let overflow_type = if signed then Signed else Unsigned in Emit_alarm.emit_alarm (Integer_overflow{size;operation;overflow_type}) in check_cond mkcond emit_alarm dom; (* lower bound *) if signed then let lower_bound = Z.neg two_pow_size in let mkcond dom = let lower_bound_val = biconst ~size:wide_size lower_bound dom in compare ~size:wide_size dom lower_bound_val value in let emit_alarm () = if should_emit_alarm then begin let size = small_size in let overflow_type = Signed in Emit_alarm.emit_alarm (Integer_underflow {size;operation;overflow_type}) end in check_cond mkcond emit_alarm dom (** [term_builder ~signed dom ~small_size ~wide_size binop v1 v2 r] extends [v1], [v2] from [~small_size] to [~wide_size], computes the [binop] on [~wide_size], then assumes there are no overflows. *) let term_builder ~signed dom ~small_size ~wide_size binop op v1 v2 = let dom = clone dom in let extend = if signed then bsext else buext in let v1_wide = extend ~size:wide_size ~oldsize:small_size dom v1 in let v2_wide = extend ~size:wide_size ~oldsize:small_size dom v2 in let res = binop ~size:wide_size dom v1_wide v2_wide in check_overflow ~signed ~small_size ~wide_size op res dom (** Variant of [term_builder] (with inlined [check_overflow]) for the [~nusw] case (adding an unsigned (pointer) and a signed [offset]) result must fit on [unsigned] without overflow or underflow. *) let check_nusw orig_dom ~small_size ~wide_size binop operation v1 v2 = let dom = clone orig_dom in let overflow_type = Operator.Alarm.Unsigned_signed in let v1_wide = buext ~size:wide_size ~oldsize:small_size dom v1 in let v2_wide = bsext ~size:wide_size ~oldsize:small_size dom v2 in let res = binop ~size:wide_size dom v1_wide v2_wide in let two_pow_size = Z.shift_left Z.one (small_size:>int) in (* Upper bound *) let mkcond dom = let upper_bound = Z.sub two_pow_size Z.one in let upper_bound_val = biconst ~size:wide_size upper_bound dom in bisle ~size:wide_size dom res upper_bound_val in let emit_alarm() = let size = small_size in if emit_unsigned_signed_alarms then Emit_alarm.emit_alarm (Integer_overflow { overflow_type; size; operation }) in check_cond mkcond emit_alarm dom; (* lower bound *) let mkcond dom = let lower_bound_val = biconst ~size:wide_size Z.zero dom in bisle ~size:wide_size dom lower_bound_val res in let emit_alarm() = let size = small_size in if emit_unsigned_signed_alarms then Emit_alarm.emit_alarm (Integer_underflow {overflow_type; size; operation }); in check_cond mkcond emit_alarm dom (** [binop_with_overflow_guard ~small_size ~wide_size binop_func v1 v2] returns [binop_func ~size:small_size v1 v2], but first it ensures that no overflow occurs by computing [binop_func ~size:wide_size v1 v2] and checking that it fits on [~small_size] bits. @param ~small_size should be the size of terms [v1] and [v2] @param ~wide_size should be large enough to ensure that [binop_func ~size:wide_size v1 v2] does not overflow *) let binop_with_overflow_guard ~nsw ~nuw ~nusw dom ~small_size ~wide_size binop op v1 v2 = if nsw then term_builder ~signed:true dom ~small_size ~wide_size binop op v1 v2; if nuw then term_builder ~signed:false dom ~small_size ~wide_size binop op v1 v2; if nusw (* We need size+1 here to be able to sign compare unsigned values *) then check_nusw dom ~small_size ~wide_size:(increase_size wide_size) binop op v1 v2; binop ~size:small_size dom v1 v2 let biadd ~size ~flags dom a b = let Operator.Flags.Biadd.{nsw;nuw;nusw} = Operator.Flags.Biadd.unpack flags in (* if nsw || nuw || nusw then Emit_alarm.feedback "OverflowAddition size:%d nsw:%b nuw:%b nusw:%b (%a + %a = %a)" size nsw nuw nusw Terms.pretty a Terms.pretty b Terms.pretty res; *) binop_with_overflow_guard ~nsw ~nuw ~nusw dom ~small_size:size ~wide_size:(increase_size size) (* No overflow on n+1 bits *) (Binary_Forward.biadd ~flags) Biadd a b let bisub ~size ~flags dom a b = let Operator.Flags.Bisub.{nsw;nuw;nusw} = Operator.Flags.Bisub.unpack flags in (* if nsw || nuw || nusw then Emit_alarm.feedback "OverflowSubtraction size:%d nsw:%b nuw:%b nusw:%b (%a + %a = %a)" size nsw nuw nusw Terms.pretty a Terms.pretty b Terms.pretty res; *) binop_with_overflow_guard ~nsw ~nuw ~nusw dom ~small_size:size ~wide_size:(increase_size size) (* No overflow on n+1 bits *) (Binary_Forward.bisub ~flags) Bisub a b let bimul ~size ~flags dom a b = (* Binary_Forward.bimul ~size ~nsw ~nuw dom a b *) let Operator.Flags.Bimul.{nsw;nuw} = Operator.Flags.Bimul.unpack flags in binop_with_overflow_guard ~nsw ~nuw ~nusw:false dom ~small_size:size ~wide_size:In_bits.(double size) (* No overflow on 2n bits *) (Binary_Forward.bimul ~flags) Bimul a b (* There is only one case whe div overflows: MIN_INT / -1 *) let bisdiv ~size dom a b = let mkcond dom = let minus_one = biconst ~size Z.minus_one dom in let div_is_neg_one = beq ~size dom b minus_one in let min_int = biconst ~size (Z.neg (Z.shift_left Z.one ((size:>int)-1))) dom in let num_is_min_int = beq ~size dom a min_int in let cond = Boolean_Forward.(&&) dom div_is_neg_one num_is_min_int in Boolean_Forward.not dom cond in let emit_alarm () = if should_emit_alarm then begin let overflow_type = Signed in let alarm = Integer_overflow { overflow_type; size; operation = Bisdiv } in Emit_alarm.emit_alarm alarm end in check_cond mkcond emit_alarm dom; bisdiv ~size dom a b ;; end end