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.operator/operator_conversions.ml.html
Source file operator_conversions.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(**************************************************************************) (* 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). *) (* *) (**************************************************************************) open Operator_sig module type Conversion = sig module From_Arity:ARITY module To_Arity:ARITY val ar0: 'r From_Arity.ar0 -> 'r To_Arity.ar0 val ar1: ('a,'r) From_Arity.ar1 -> ('a,'r) To_Arity.ar1 val ar2: ('a,'b,'r) From_Arity.ar2 -> ('a,'b,'r) To_Arity.ar2 val ar3: ('a,'b,'c,'r) From_Arity.ar3 -> ('a,'b,'c,'r) To_Arity.ar3 end module Convert_Boolean_Forward (C:Conversion) (F:BOOLEAN_FORWARD with module Arity := C.From_Arity) = struct type boolean = F.boolean let true_ = C.ar0 F.true_ let false_ = C.ar0 F.false_ let not = C.ar1 F.not let (&&) = C.ar2 F.(&&) let (||) = C.ar2 F.(||) end module Convert_Integer_Forward (C:Conversion) (F:INTEGER_FORWARD with module Arity := C.From_Arity) = struct type boolean = F.boolean type integer = F.integer let iconst k = C.ar0 (F.iconst k) let iadd = C.ar2 F.iadd let isub = C.ar2 F.isub let imul = C.ar2 F.imul let idiv = C.ar2 F.idiv let imod = C.ar2 F.imod let ishl = C.ar2 F.ishl let ishr = C.ar2 F.ishr let ior = C.ar2 F.ior let ixor = C.ar2 F.ixor let iand = C.ar2 F.iand (* Redundant *) let zero = C.ar0 (F.zero) let one = C.ar0 (F.one) let ile = C.ar2 F.ile let ieq = C.ar2 F.ieq let itimes k = C.ar1 (F.itimes k) end module Convert_Bitvector_Forward (C:Conversion) (F:BITVECTOR_FORWARD with module Arity := C.From_Arity) = struct type boolean = F.boolean type bitvector = F.bitvector let biadd ~size ~flags = C.ar2 (F.biadd ~size ~flags) let bisub ~size ~flags = C.ar2 (F.bisub ~size ~flags) let bisdiv ~size = C.ar2 (F.bisdiv ~size) let bismod ~size = C.ar2 (F.bismod ~size) let biudiv ~size = C.ar2 (F.biudiv ~size) let biumod ~size = C.ar2 (F.biumod ~size) let bimul ~size ~flags = C.ar2 (F.bimul ~flags ~size) let beq ~size = C.ar2 (F.beq ~size) let bisle ~size = C.ar2 (F.bisle ~size) let biule ~size = C.ar2 (F.biule ~size) let bconcat ~size1 ~size2 = C.ar2 @@ F.bconcat ~size1 ~size2 let bextract ~size ~index ~oldsize = C.ar1 (F.bextract ~size ~index ~oldsize) let band ~size = C.ar2 (F.band ~size) let bor ~size = C.ar2 (F.bor ~size) let bxor ~size = C.ar2 (F.bxor ~size) let buext ~size ~oldsize = C.ar1 (F.buext ~size ~oldsize) let bsext ~size ~oldsize = C.ar1 (F.bsext ~size ~oldsize) let bofbool ~size = C.ar1 (F.bofbool ~size) let bshl ~size ~flags = C.ar2 (F.bshl ~size ~flags) let bashr ~size = C.ar2 (F.bashr ~size) let blshr ~size = C.ar2 (F.blshr ~size) let biconst ~size k = C.ar0 (F.biconst ~size k) end module Convert_Binary_Forward (C:Conversion) (F:BINARY_FORWARD with module Arity := C.From_Arity) = struct include Convert_Bitvector_Forward(C)(struct include F type bitvector = binary end) type binary = F.binary let buninit ~size = C.ar0 (F.buninit ~size) let valid ~size access_type = C.ar1 (F.valid ~size access_type) let valid_ptr_arith ~size arith_type = C.ar2 (F.valid_ptr_arith ~size arith_type) let bshift ~size ~offset ~max = C.ar1 (F.bshift ~size ~offset ~max) let bindex ~size scale = C.ar2 (F.bindex ~size scale) let bchoose ~size cond = C.ar1 (F.bchoose ~size cond) end module Convert_Block_Forward (C:Conversion) (F:BLOCK_FORWARD with module Arity := C.From_Arity) = struct type boolean = F.boolean type value = F.value type block = F.block type offset = F.offset let sizeof = C.ar1 F.sizeof let concat = C.ar2 F.concat let load ~size = C.ar2 (F.load ~size) let store ~size = C.ar3 (F.store ~size) let binary_to_block ~size = C.ar1 (F.binary_to_block ~size) end module Convert_Enum_Forward (C:Conversion) (F:ENUM_FORWARD with module Arity := C.From_Arity) = struct type boolean = F.boolean type enum = F.enum let caseof ~case = C.ar1 (F.caseof ~case) let enum_const ~case = C.ar0 (F.enum_const ~case) end module Convert_Memory_Forward (C:Conversion) (F:MEMORY_FORWARD with module Arity := C.From_Arity) = struct type boolean = F.boolean type address = F.address type memory = F.memory type block = F.block type value = F.value let load ~size= C.ar2 (F.load ~size) let store ~size= C.ar3 (F.store ~size) let load_block = C.ar2 F.load_block let store_block = C.ar3 F.store_block let memcpy ~size= C.ar3 (F.memcpy ~size) let free = C.ar2 F.free let malloc ~id ~malloc_size = C.ar1 (F.malloc ~id ~malloc_size) let unknown ~level = C.ar0 (F.unknown ~level) end (* module Convert_Binary_Forward_Monomorphic *) (* (C:sig *) (* module From_Arity:Arity *) (* module To_Arity:Arity *) (* type from_binary *) (* type from_boolean *) (* type from_world *) (* type to_binary *) (* type to_boolean *) (* type to_world *) (* val ar0_bin: from_binary From_Arity.ar0 -> to_binary To_Arity.ar0 *) (* val ar1_world_bin: (from_world,from_binary) From_Arity.ar1 -> (to_world,to_binary) To_Arity.ar1 *) (* val ar1_bin_bin: (from_binary,from_binary) From_Arity.ar1 -> (to_binary,to_binary) To_Arity.ar1 *) (* val ar1_bin_bool: (from_binary,from_boolean) From_Arity.ar1 -> (to_binary,to_boolean) To_Arity.ar1 *) (* val ar2_bool_bin_bin: (from_boolean,from_binary,from_binary) From_Arity.ar2 -> (to_boolean,to_binary,to_binary) To_Arity.ar2 *) (* val ar2_bin_bin_bin: (from_binary,from_binary,from_binary) From_Arity.ar2 -> (to_binary,to_binary,to_binary) To_Arity.ar2 *) (* val ar2_bin_bin_bool: (from_binary,from_binary,from_boolean) From_Arity.ar2 -> (to_binary,to_binary,to_boolean) To_Arity.ar2 *) (* val variadic: (from_binary,from_binary) From_Arity.variadic -> (to_binary,to_binary) To_Arity.variadic *) (* end) *) (* (F:Binary_Forward with module Arity := C.From_Arity *) (* and type world = C.from_world *) (* and type binary = C.from_binary *) (* and type boolean = C.from_boolean) = *) (* struct *) (* let nondet ~size = C.variadic (F.nondet ~size) *) (* let assume ~size = C.ar2_bool_bin_bin (F.assume ~size) *) (* let bitimes k = C.ar1_bin_bin (F.bitimes k) *) (* let biadd = C.ar2_bin_bin_bin F.biadd *) (* let bisdiv ~size = C.ar2_bin_bin_bin (F.bisdiv ~size) *) (* let bismod ~size = C.ar2_bin_bin_bin (F.bismod ~size) *) (* let bimul ~size = C.ar2_bin_bin_bin (F.bimul ~size) *) (* let beq = C.ar2_bin_bin_bool F.beq *) (* let bisle = C.ar2_bin_bin_bool F.bisle *) (* let bislt = C.ar2_bin_bin_bool F.bislt *) (* let biule = C.ar2_bin_bin_bool F.biule *) (* let biult = C.ar2_bin_bin_bool F.biult *) (* let bconcat = C.variadic F.bconcat *) (* let bextract ~size ~index = C.ar1_bin_bin (F.bextract ~size ~index) *) (* let band ~size = C.ar2_bin_bin_bin (F.band ~size) *) (* let bor ~size = C.ar2_bin_bin_bin (F.bor ~size) *) (* let bxor ~size = C.ar2_bin_bin_bin (F.bxor ~size) *) (* let buext ~size = C.ar1_bin_bin (F.buext ~size) *) (* let bsext ~size = C.ar1_bin_bin (F.bsext ~size) *) (* let bshl ~size = C.ar2_bin_bin_bin (F.bshl ~size) *) (* let bashr ~size = C.ar2_bin_bin_bin (F.bashr ~size) *) (* let blshr ~size = C.ar2_bin_bin_bin (F.blshr ~size) *) (* let biconst ~size k = C.ar0_bin (F.biconst ~size k) *) (* let baddr ~size addr = C.ar0_bin (F.baddr ~size addr) *) (* let bunknown ~size = C.ar1_world_bin (F.bunknown ~size) *) (* let valid ~size = C.ar1_bin_bool (F.valid ~size) *) (* end *)