1 /* 2 * Copyright (C) 2008 The Guava Authors 3 * 4 * Licensed under the Apache License, Version 2.0 (the "License"); 5 * you may not use this file except in compliance with the License. 6 * You may obtain a copy of the License at 7 * 8 * http://www.apache.org/licenses/LICENSE-2.0 9 * 10 * Unless required by applicable law or agreed to in writing, software 11 * distributed under the License is distributed on an "AS IS" BASIS, 12 * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. 13 * See the License for the specific language governing permissions and 14 * limitations under the License. 15 */ 16 17 package com.google.common.net; 18 19 import com.google.common.annotations.Beta; 20 import com.google.common.base.MoreObjects; 21 import com.google.common.base.Preconditions; 22 import com.google.common.hash.Hashing; 23 import com.google.common.io.ByteStreams; 24 import com.google.common.primitives.Ints; 25 26 import java.net.Inet4Address; 27 import java.net.Inet6Address; 28 import java.net.InetAddress; 29 import java.net.UnknownHostException; 30 import java.nio.ByteBuffer; 31 import java.util.Arrays; 32 33 import javax.annotation.Nullable; 34 35 /** 36 * Static utility methods pertaining to {@link InetAddress} instances. 37 * 38 * <p><b>Important note:</b> Unlike {@code InetAddress.getByName()}, the 39 * methods of this class never cause DNS services to be accessed. For 40 * this reason, you should prefer these methods as much as possible over 41 * their JDK equivalents whenever you are expecting to handle only 42 * IP address string literals -- there is no blocking DNS penalty for a 43 * malformed string. 44 * 45 * <p>When dealing with {@link Inet4Address} and {@link Inet6Address} 46 * objects as byte arrays (vis. {@code InetAddress.getAddress()}) they 47 * are 4 and 16 bytes in length, respectively, and represent the address 48 * in network byte order. 49 * 50 * <p>Examples of IP addresses and their byte representations: 51 * <ul> 52 * <li>The IPv4 loopback address, {@code "127.0.0.1"}.<br/> 53 * {@code 7f 00 00 01} 54 * 55 * <li>The IPv6 loopback address, {@code "::1"}.<br/> 56 * {@code 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 01} 57 * 58 * <li>From the IPv6 reserved documentation prefix ({@code 2001:db8::/32}), 59 * {@code "2001:db8::1"}.<br/> 60 * {@code 20 01 0d b8 00 00 00 00 00 00 00 00 00 00 00 01} 61 * 62 * <li>An IPv6 "IPv4 compatible" (or "compat") address, 63 * {@code "::192.168.0.1"}.<br/> 64 * {@code 00 00 00 00 00 00 00 00 00 00 00 00 c0 a8 00 01} 65 * 66 * <li>An IPv6 "IPv4 mapped" address, {@code "::ffff:192.168.0.1"}.<br/> 67 * {@code 00 00 00 00 00 00 00 00 00 00 ff ff c0 a8 00 01} 68 * </ul> 69 * 70 * <p>A few notes about IPv6 "IPv4 mapped" addresses and their observed 71 * use in Java. 72 * <br><br> 73 * "IPv4 mapped" addresses were originally a representation of IPv4 74 * addresses for use on an IPv6 socket that could receive both IPv4 75 * and IPv6 connections (by disabling the {@code IPV6_V6ONLY} socket 76 * option on an IPv6 socket). Yes, it's confusing. Nevertheless, 77 * these "mapped" addresses were never supposed to be seen on the 78 * wire. That assumption was dropped, some say mistakenly, in later 79 * RFCs with the apparent aim of making IPv4-to-IPv6 transition simpler. 80 * 81 * <p>Technically one <i>can</i> create a 128bit IPv6 address with the wire 82 * format of a "mapped" address, as shown above, and transmit it in an 83 * IPv6 packet header. However, Java's InetAddress creation methods 84 * appear to adhere doggedly to the original intent of the "mapped" 85 * address: all "mapped" addresses return {@link Inet4Address} objects. 86 * 87 * <p>For added safety, it is common for IPv6 network operators to filter 88 * all packets where either the source or destination address appears to 89 * be a "compat" or "mapped" address. Filtering suggestions usually 90 * recommend discarding any packets with source or destination addresses 91 * in the invalid range {@code ::/3}, which includes both of these bizarre 92 * address formats. For more information on "bogons", including lists 93 * of IPv6 bogon space, see: 94 * 95 * <ul> 96 * <li><a target="_parent" 97 * href="http://en.wikipedia.org/wiki/Bogon_filtering" 98 * >http://en.wikipedia.org/wiki/Bogon_filtering</a> 99 * <li><a target="_parent" 100 * href="http://www.cymru.com/Bogons/ipv6.txt" 101 * >http://www.cymru.com/Bogons/ipv6.txt</a> 102 * <li><a target="_parent" 103 * href="http://www.cymru.com/Bogons/v6bogon.html" 104 * >http://www.cymru.com/Bogons/v6bogon.html</a> 105 * <li><a target="_parent" 106 * href="http://www.space.net/~gert/RIPE/ipv6-filters.html" 107 * >http://www.space.net/~gert/RIPE/ipv6-filters.html</a> 108 * </ul> 109 * 110 * @author Erik Kline 111 * @since 5.0 112 */ 113 @Beta 114 public final class InetAddresses { 115 private static final int IPV4_PART_COUNT = 4; 116 private static final int IPV6_PART_COUNT = 8; 117 private static final Inet4Address LOOPBACK4 = (Inet4Address) forString("127.0.0.1"); 118 private static final Inet4Address ANY4 = (Inet4Address) forString("0.0.0.0"); 119 InetAddresses()120 private InetAddresses() {} 121 122 /** 123 * Returns an {@link Inet4Address}, given a byte array representation of the IPv4 address. 124 * 125 * @param bytes byte array representing an IPv4 address (should be of length 4) 126 * @return {@link Inet4Address} corresponding to the supplied byte array 127 * @throws IllegalArgumentException if a valid {@link Inet4Address} can not be created 128 */ getInet4Address(byte[] bytes)129 private static Inet4Address getInet4Address(byte[] bytes) { 130 Preconditions.checkArgument(bytes.length == 4, 131 "Byte array has invalid length for an IPv4 address: %s != 4.", 132 bytes.length); 133 134 // Given a 4-byte array, this cast should always succeed. 135 return (Inet4Address) bytesToInetAddress(bytes); 136 } 137 138 /** 139 * Returns the {@link InetAddress} having the given string representation. 140 * 141 * <p>This deliberately avoids all nameservice lookups (e.g. no DNS). 142 * 143 * @param ipString {@code String} containing an IPv4 or IPv6 string literal, e.g. 144 * {@code "192.168.0.1"} or {@code "2001:db8::1"} 145 * @return {@link InetAddress} representing the argument 146 * @throws IllegalArgumentException if the argument is not a valid IP string literal 147 */ forString(String ipString)148 public static InetAddress forString(String ipString) { 149 byte[] addr = ipStringToBytes(ipString); 150 151 // The argument was malformed, i.e. not an IP string literal. 152 if (addr == null) { 153 throw new IllegalArgumentException( 154 String.format("'%s' is not an IP string literal.", ipString)); 155 } 156 157 return bytesToInetAddress(addr); 158 } 159 160 /** 161 * Returns {@code true} if the supplied string is a valid IP string 162 * literal, {@code false} otherwise. 163 * 164 * @param ipString {@code String} to evaluated as an IP string literal 165 * @return {@code true} if the argument is a valid IP string literal 166 */ isInetAddress(String ipString)167 public static boolean isInetAddress(String ipString) { 168 return ipStringToBytes(ipString) != null; 169 } 170 ipStringToBytes(String ipString)171 private static byte[] ipStringToBytes(String ipString) { 172 // Make a first pass to categorize the characters in this string. 173 boolean hasColon = false; 174 boolean hasDot = false; 175 for (int i = 0; i < ipString.length(); i++) { 176 char c = ipString.charAt(i); 177 if (c == '.') { 178 hasDot = true; 179 } else if (c == ':') { 180 if (hasDot) { 181 return null; // Colons must not appear after dots. 182 } 183 hasColon = true; 184 } else if (Character.digit(c, 16) == -1) { 185 return null; // Everything else must be a decimal or hex digit. 186 } 187 } 188 189 // Now decide which address family to parse. 190 if (hasColon) { 191 if (hasDot) { 192 ipString = convertDottedQuadToHex(ipString); 193 if (ipString == null) { 194 return null; 195 } 196 } 197 return textToNumericFormatV6(ipString); 198 } else if (hasDot) { 199 return textToNumericFormatV4(ipString); 200 } 201 return null; 202 } 203 textToNumericFormatV4(String ipString)204 private static byte[] textToNumericFormatV4(String ipString) { 205 String[] address = ipString.split("\\.", IPV4_PART_COUNT + 1); 206 if (address.length != IPV4_PART_COUNT) { 207 return null; 208 } 209 210 byte[] bytes = new byte[IPV4_PART_COUNT]; 211 try { 212 for (int i = 0; i < bytes.length; i++) { 213 bytes[i] = parseOctet(address[i]); 214 } 215 } catch (NumberFormatException ex) { 216 return null; 217 } 218 219 return bytes; 220 } 221 textToNumericFormatV6(String ipString)222 private static byte[] textToNumericFormatV6(String ipString) { 223 // An address can have [2..8] colons, and N colons make N+1 parts. 224 String[] parts = ipString.split(":", IPV6_PART_COUNT + 2); 225 if (parts.length < 3 || parts.length > IPV6_PART_COUNT + 1) { 226 return null; 227 } 228 229 // Disregarding the endpoints, find "::" with nothing in between. 230 // This indicates that a run of zeroes has been skipped. 231 int skipIndex = -1; 232 for (int i = 1; i < parts.length - 1; i++) { 233 if (parts[i].length() == 0) { 234 if (skipIndex >= 0) { 235 return null; // Can't have more than one :: 236 } 237 skipIndex = i; 238 } 239 } 240 241 int partsHi; // Number of parts to copy from above/before the "::" 242 int partsLo; // Number of parts to copy from below/after the "::" 243 if (skipIndex >= 0) { 244 // If we found a "::", then check if it also covers the endpoints. 245 partsHi = skipIndex; 246 partsLo = parts.length - skipIndex - 1; 247 if (parts[0].length() == 0 && --partsHi != 0) { 248 return null; // ^: requires ^:: 249 } 250 if (parts[parts.length - 1].length() == 0 && --partsLo != 0) { 251 return null; // :$ requires ::$ 252 } 253 } else { 254 // Otherwise, allocate the entire address to partsHi. The endpoints 255 // could still be empty, but parseHextet() will check for that. 256 partsHi = parts.length; 257 partsLo = 0; 258 } 259 260 // If we found a ::, then we must have skipped at least one part. 261 // Otherwise, we must have exactly the right number of parts. 262 int partsSkipped = IPV6_PART_COUNT - (partsHi + partsLo); 263 if (!(skipIndex >= 0 ? partsSkipped >= 1 : partsSkipped == 0)) { 264 return null; 265 } 266 267 // Now parse the hextets into a byte array. 268 ByteBuffer rawBytes = ByteBuffer.allocate(2 * IPV6_PART_COUNT); 269 try { 270 for (int i = 0; i < partsHi; i++) { 271 rawBytes.putShort(parseHextet(parts[i])); 272 } 273 for (int i = 0; i < partsSkipped; i++) { 274 rawBytes.putShort((short) 0); 275 } 276 for (int i = partsLo; i > 0; i--) { 277 rawBytes.putShort(parseHextet(parts[parts.length - i])); 278 } 279 } catch (NumberFormatException ex) { 280 return null; 281 } 282 return rawBytes.array(); 283 } 284 convertDottedQuadToHex(String ipString)285 private static String convertDottedQuadToHex(String ipString) { 286 int lastColon = ipString.lastIndexOf(':'); 287 String initialPart = ipString.substring(0, lastColon + 1); 288 String dottedQuad = ipString.substring(lastColon + 1); 289 byte[] quad = textToNumericFormatV4(dottedQuad); 290 if (quad == null) { 291 return null; 292 } 293 String penultimate = Integer.toHexString(((quad[0] & 0xff) << 8) | (quad[1] & 0xff)); 294 String ultimate = Integer.toHexString(((quad[2] & 0xff) << 8) | (quad[3] & 0xff)); 295 return initialPart + penultimate + ":" + ultimate; 296 } 297 parseOctet(String ipPart)298 private static byte parseOctet(String ipPart) { 299 // Note: we already verified that this string contains only hex digits. 300 int octet = Integer.parseInt(ipPart); 301 // Disallow leading zeroes, because no clear standard exists on 302 // whether these should be interpreted as decimal or octal. 303 if (octet > 255 || (ipPart.startsWith("0") && ipPart.length() > 1)) { 304 throw new NumberFormatException(); 305 } 306 return (byte) octet; 307 } 308 parseHextet(String ipPart)309 private static short parseHextet(String ipPart) { 310 // Note: we already verified that this string contains only hex digits. 311 int hextet = Integer.parseInt(ipPart, 16); 312 if (hextet > 0xffff) { 313 throw new NumberFormatException(); 314 } 315 return (short) hextet; 316 } 317 318 /** 319 * Convert a byte array into an InetAddress. 320 * 321 * {@link InetAddress#getByAddress} is documented as throwing a checked 322 * exception "if IP address if of illegal length." We replace it with 323 * an unchecked exception, for use by callers who already know that addr 324 * is an array of length 4 or 16. 325 * 326 * @param addr the raw 4-byte or 16-byte IP address in big-endian order 327 * @return an InetAddress object created from the raw IP address 328 */ bytesToInetAddress(byte[] addr)329 private static InetAddress bytesToInetAddress(byte[] addr) { 330 try { 331 return InetAddress.getByAddress(addr); 332 } catch (UnknownHostException e) { 333 throw new AssertionError(e); 334 } 335 } 336 337 /** 338 * Returns the string representation of an {@link InetAddress}. 339 * 340 * <p>For IPv4 addresses, this is identical to 341 * {@link InetAddress#getHostAddress()}, but for IPv6 addresses, the output 342 * follows <a href="http://tools.ietf.org/html/rfc5952">RFC 5952</a> 343 * section 4. The main difference is that this method uses "::" for zero 344 * compression, while Java's version uses the uncompressed form. 345 * 346 * <p>This method uses hexadecimal for all IPv6 addresses, including 347 * IPv4-mapped IPv6 addresses such as "::c000:201". The output does not 348 * include a Scope ID. 349 * 350 * @param ip {@link InetAddress} to be converted to an address string 351 * @return {@code String} containing the text-formatted IP address 352 * @since 10.0 353 */ toAddrString(InetAddress ip)354 public static String toAddrString(InetAddress ip) { 355 Preconditions.checkNotNull(ip); 356 if (ip instanceof Inet4Address) { 357 // For IPv4, Java's formatting is good enough. 358 return ip.getHostAddress(); 359 } 360 Preconditions.checkArgument(ip instanceof Inet6Address); 361 byte[] bytes = ip.getAddress(); 362 int[] hextets = new int[IPV6_PART_COUNT]; 363 for (int i = 0; i < hextets.length; i++) { 364 hextets[i] = Ints.fromBytes( 365 (byte) 0, (byte) 0, bytes[2 * i], bytes[2 * i + 1]); 366 } 367 compressLongestRunOfZeroes(hextets); 368 return hextetsToIPv6String(hextets); 369 } 370 371 /** 372 * Identify and mark the longest run of zeroes in an IPv6 address. 373 * 374 * <p>Only runs of two or more hextets are considered. In case of a tie, the 375 * leftmost run wins. If a qualifying run is found, its hextets are replaced 376 * by the sentinel value -1. 377 * 378 * @param hextets {@code int[]} mutable array of eight 16-bit hextets 379 */ compressLongestRunOfZeroes(int[] hextets)380 private static void compressLongestRunOfZeroes(int[] hextets) { 381 int bestRunStart = -1; 382 int bestRunLength = -1; 383 int runStart = -1; 384 for (int i = 0; i < hextets.length + 1; i++) { 385 if (i < hextets.length && hextets[i] == 0) { 386 if (runStart < 0) { 387 runStart = i; 388 } 389 } else if (runStart >= 0) { 390 int runLength = i - runStart; 391 if (runLength > bestRunLength) { 392 bestRunStart = runStart; 393 bestRunLength = runLength; 394 } 395 runStart = -1; 396 } 397 } 398 if (bestRunLength >= 2) { 399 Arrays.fill(hextets, bestRunStart, bestRunStart + bestRunLength, -1); 400 } 401 } 402 403 /** 404 * Convert a list of hextets into a human-readable IPv6 address. 405 * 406 * <p>In order for "::" compression to work, the input should contain negative 407 * sentinel values in place of the elided zeroes. 408 * 409 * @param hextets {@code int[]} array of eight 16-bit hextets, or -1s 410 */ hextetsToIPv6String(int[] hextets)411 private static String hextetsToIPv6String(int[] hextets) { 412 /* 413 * While scanning the array, handle these state transitions: 414 * start->num => "num" start->gap => "::" 415 * num->num => ":num" num->gap => "::" 416 * gap->num => "num" gap->gap => "" 417 */ 418 StringBuilder buf = new StringBuilder(39); 419 boolean lastWasNumber = false; 420 for (int i = 0; i < hextets.length; i++) { 421 boolean thisIsNumber = hextets[i] >= 0; 422 if (thisIsNumber) { 423 if (lastWasNumber) { 424 buf.append(':'); 425 } 426 buf.append(Integer.toHexString(hextets[i])); 427 } else { 428 if (i == 0 || lastWasNumber) { 429 buf.append("::"); 430 } 431 } 432 lastWasNumber = thisIsNumber; 433 } 434 return buf.toString(); 435 } 436 437 /** 438 * Returns the string representation of an {@link InetAddress} suitable 439 * for inclusion in a URI. 440 * 441 * <p>For IPv4 addresses, this is identical to 442 * {@link InetAddress#getHostAddress()}, but for IPv6 addresses it 443 * compresses zeroes and surrounds the text with square brackets; for example 444 * {@code "[2001:db8::1]"}. 445 * 446 * <p>Per section 3.2.2 of 447 * <a target="_parent" 448 * href="http://tools.ietf.org/html/rfc3986#section-3.2.2" 449 * >http://tools.ietf.org/html/rfc3986</a>, 450 * a URI containing an IPv6 string literal is of the form 451 * {@code "http://[2001:db8::1]:8888/index.html"}. 452 * 453 * <p>Use of either {@link InetAddresses#toAddrString}, 454 * {@link InetAddress#getHostAddress()}, or this method is recommended over 455 * {@link InetAddress#toString()} when an IP address string literal is 456 * desired. This is because {@link InetAddress#toString()} prints the 457 * hostname and the IP address string joined by a "/". 458 * 459 * @param ip {@link InetAddress} to be converted to URI string literal 460 * @return {@code String} containing URI-safe string literal 461 */ toUriString(InetAddress ip)462 public static String toUriString(InetAddress ip) { 463 if (ip instanceof Inet6Address) { 464 return "[" + toAddrString(ip) + "]"; 465 } 466 return toAddrString(ip); 467 } 468 469 /** 470 * Returns an InetAddress representing the literal IPv4 or IPv6 host 471 * portion of a URL, encoded in the format specified by RFC 3986 section 3.2.2. 472 * 473 * <p>This function is similar to {@link InetAddresses#forString(String)}, 474 * however, it requires that IPv6 addresses are surrounded by square brackets. 475 * 476 * <p>This function is the inverse of 477 * {@link InetAddresses#toUriString(java.net.InetAddress)}. 478 * 479 * @param hostAddr A RFC 3986 section 3.2.2 encoded IPv4 or IPv6 address 480 * @return an InetAddress representing the address in {@code hostAddr} 481 * @throws IllegalArgumentException if {@code hostAddr} is not a valid 482 * IPv4 address, or IPv6 address surrounded by square brackets 483 */ forUriString(String hostAddr)484 public static InetAddress forUriString(String hostAddr) { 485 Preconditions.checkNotNull(hostAddr); 486 487 // Decide if this should be an IPv6 or IPv4 address. 488 String ipString; 489 int expectBytes; 490 if (hostAddr.startsWith("[") && hostAddr.endsWith("]")) { 491 ipString = hostAddr.substring(1, hostAddr.length() - 1); 492 expectBytes = 16; 493 } else { 494 ipString = hostAddr; 495 expectBytes = 4; 496 } 497 498 // Parse the address, and make sure the length/version is correct. 499 byte[] addr = ipStringToBytes(ipString); 500 if (addr == null || addr.length != expectBytes) { 501 throw new IllegalArgumentException( 502 String.format("Not a valid URI IP literal: '%s'", hostAddr)); 503 } 504 505 return bytesToInetAddress(addr); 506 } 507 508 /** 509 * Returns {@code true} if the supplied string is a valid URI IP string 510 * literal, {@code false} otherwise. 511 * 512 * @param ipString {@code String} to evaluated as an IP URI host string literal 513 * @return {@code true} if the argument is a valid IP URI host 514 */ isUriInetAddress(String ipString)515 public static boolean isUriInetAddress(String ipString) { 516 try { 517 forUriString(ipString); 518 return true; 519 } catch (IllegalArgumentException e) { 520 return false; 521 } 522 } 523 524 /** 525 * Evaluates whether the argument is an IPv6 "compat" address. 526 * 527 * <p>An "IPv4 compatible", or "compat", address is one with 96 leading 528 * bits of zero, with the remaining 32 bits interpreted as an 529 * IPv4 address. These are conventionally represented in string 530 * literals as {@code "::192.168.0.1"}, though {@code "::c0a8:1"} is 531 * also considered an IPv4 compatible address (and equivalent to 532 * {@code "::192.168.0.1"}). 533 * 534 * <p>For more on IPv4 compatible addresses see section 2.5.5.1 of 535 * <a target="_parent" 536 * href="http://tools.ietf.org/html/rfc4291#section-2.5.5.1" 537 * >http://tools.ietf.org/html/rfc4291</a> 538 * 539 * <p>NOTE: This method is different from 540 * {@link Inet6Address#isIPv4CompatibleAddress} in that it more 541 * correctly classifies {@code "::"} and {@code "::1"} as 542 * proper IPv6 addresses (which they are), NOT IPv4 compatible 543 * addresses (which they are generally NOT considered to be). 544 * 545 * @param ip {@link Inet6Address} to be examined for embedded IPv4 compatible address format 546 * @return {@code true} if the argument is a valid "compat" address 547 */ isCompatIPv4Address(Inet6Address ip)548 public static boolean isCompatIPv4Address(Inet6Address ip) { 549 if (!ip.isIPv4CompatibleAddress()) { 550 return false; 551 } 552 553 byte[] bytes = ip.getAddress(); 554 if ((bytes[12] == 0) && (bytes[13] == 0) && (bytes[14] == 0) 555 && ((bytes[15] == 0) || (bytes[15] == 1))) { 556 return false; 557 } 558 559 return true; 560 } 561 562 /** 563 * Returns the IPv4 address embedded in an IPv4 compatible address. 564 * 565 * @param ip {@link Inet6Address} to be examined for an embedded IPv4 address 566 * @return {@link Inet4Address} of the embedded IPv4 address 567 * @throws IllegalArgumentException if the argument is not a valid IPv4 compatible address 568 */ getCompatIPv4Address(Inet6Address ip)569 public static Inet4Address getCompatIPv4Address(Inet6Address ip) { 570 Preconditions.checkArgument(isCompatIPv4Address(ip), 571 "Address '%s' is not IPv4-compatible.", toAddrString(ip)); 572 573 return getInet4Address(Arrays.copyOfRange(ip.getAddress(), 12, 16)); 574 } 575 576 /** 577 * Evaluates whether the argument is a 6to4 address. 578 * 579 * <p>6to4 addresses begin with the {@code "2002::/16"} prefix. 580 * The next 32 bits are the IPv4 address of the host to which 581 * IPv6-in-IPv4 tunneled packets should be routed. 582 * 583 * <p>For more on 6to4 addresses see section 2 of 584 * <a target="_parent" href="http://tools.ietf.org/html/rfc3056#section-2" 585 * >http://tools.ietf.org/html/rfc3056</a> 586 * 587 * @param ip {@link Inet6Address} to be examined for 6to4 address format 588 * @return {@code true} if the argument is a 6to4 address 589 */ is6to4Address(Inet6Address ip)590 public static boolean is6to4Address(Inet6Address ip) { 591 byte[] bytes = ip.getAddress(); 592 return (bytes[0] == (byte) 0x20) && (bytes[1] == (byte) 0x02); 593 } 594 595 /** 596 * Returns the IPv4 address embedded in a 6to4 address. 597 * 598 * @param ip {@link Inet6Address} to be examined for embedded IPv4 in 6to4 address 599 * @return {@link Inet4Address} of embedded IPv4 in 6to4 address 600 * @throws IllegalArgumentException if the argument is not a valid IPv6 6to4 address 601 */ get6to4IPv4Address(Inet6Address ip)602 public static Inet4Address get6to4IPv4Address(Inet6Address ip) { 603 Preconditions.checkArgument(is6to4Address(ip), 604 "Address '%s' is not a 6to4 address.", toAddrString(ip)); 605 606 return getInet4Address(Arrays.copyOfRange(ip.getAddress(), 2, 6)); 607 } 608 609 /** 610 * A simple immutable data class to encapsulate the information to be found in a 611 * Teredo address. 612 * 613 * <p>All of the fields in this class are encoded in various portions 614 * of the IPv6 address as part of the protocol. More protocols details 615 * can be found at: 616 * <a target="_parent" href="http://en.wikipedia.org/wiki/Teredo_tunneling" 617 * >http://en.wikipedia.org/wiki/Teredo_tunneling</a>. 618 * 619 * <p>The RFC can be found here: 620 * <a target="_parent" href="http://tools.ietf.org/html/rfc4380" 621 * >http://tools.ietf.org/html/rfc4380</a>. 622 * 623 * @since 5.0 624 */ 625 @Beta 626 public static final class TeredoInfo { 627 private final Inet4Address server; 628 private final Inet4Address client; 629 private final int port; 630 private final int flags; 631 632 /** 633 * Constructs a TeredoInfo instance. 634 * 635 * <p>Both server and client can be {@code null}, in which case the 636 * value {@code "0.0.0.0"} will be assumed. 637 * 638 * @throws IllegalArgumentException if either of the {@code port} or the {@code flags} 639 * arguments are out of range of an unsigned short 640 */ 641 // TODO: why is this public? TeredoInfo( @ullable Inet4Address server, @Nullable Inet4Address client, int port, int flags)642 public TeredoInfo( 643 @Nullable Inet4Address server, @Nullable Inet4Address client, int port, int flags) { 644 Preconditions.checkArgument((port >= 0) && (port <= 0xffff), 645 "port '%s' is out of range (0 <= port <= 0xffff)", port); 646 Preconditions.checkArgument((flags >= 0) && (flags <= 0xffff), 647 "flags '%s' is out of range (0 <= flags <= 0xffff)", flags); 648 649 this.server = MoreObjects.firstNonNull(server, ANY4); 650 this.client = MoreObjects.firstNonNull(client, ANY4); 651 this.port = port; 652 this.flags = flags; 653 } 654 getServer()655 public Inet4Address getServer() { 656 return server; 657 } 658 getClient()659 public Inet4Address getClient() { 660 return client; 661 } 662 getPort()663 public int getPort() { 664 return port; 665 } 666 getFlags()667 public int getFlags() { 668 return flags; 669 } 670 } 671 672 /** 673 * Evaluates whether the argument is a Teredo address. 674 * 675 * <p>Teredo addresses begin with the {@code "2001::/32"} prefix. 676 * 677 * @param ip {@link Inet6Address} to be examined for Teredo address format 678 * @return {@code true} if the argument is a Teredo address 679 */ isTeredoAddress(Inet6Address ip)680 public static boolean isTeredoAddress(Inet6Address ip) { 681 byte[] bytes = ip.getAddress(); 682 return (bytes[0] == (byte) 0x20) && (bytes[1] == (byte) 0x01) 683 && (bytes[2] == 0) && (bytes[3] == 0); 684 } 685 686 /** 687 * Returns the Teredo information embedded in a Teredo address. 688 * 689 * @param ip {@link Inet6Address} to be examined for embedded Teredo information 690 * @return extracted {@code TeredoInfo} 691 * @throws IllegalArgumentException if the argument is not a valid IPv6 Teredo address 692 */ getTeredoInfo(Inet6Address ip)693 public static TeredoInfo getTeredoInfo(Inet6Address ip) { 694 Preconditions.checkArgument(isTeredoAddress(ip), 695 "Address '%s' is not a Teredo address.", toAddrString(ip)); 696 697 byte[] bytes = ip.getAddress(); 698 Inet4Address server = getInet4Address(Arrays.copyOfRange(bytes, 4, 8)); 699 700 int flags = ByteStreams.newDataInput(bytes, 8).readShort() & 0xffff; 701 702 // Teredo obfuscates the mapped client port, per section 4 of the RFC. 703 int port = ~ByteStreams.newDataInput(bytes, 10).readShort() & 0xffff; 704 705 byte[] clientBytes = Arrays.copyOfRange(bytes, 12, 16); 706 for (int i = 0; i < clientBytes.length; i++) { 707 // Teredo obfuscates the mapped client IP, per section 4 of the RFC. 708 clientBytes[i] = (byte) ~clientBytes[i]; 709 } 710 Inet4Address client = getInet4Address(clientBytes); 711 712 return new TeredoInfo(server, client, port, flags); 713 } 714 715 /** 716 * Evaluates whether the argument is an ISATAP address. 717 * 718 * <p>From RFC 5214: "ISATAP interface identifiers are constructed in 719 * Modified EUI-64 format [...] by concatenating the 24-bit IANA OUI 720 * (00-00-5E), the 8-bit hexadecimal value 0xFE, and a 32-bit IPv4 721 * address in network byte order [...]" 722 * 723 * <p>For more on ISATAP addresses see section 6.1 of 724 * <a target="_parent" href="http://tools.ietf.org/html/rfc5214#section-6.1" 725 * >http://tools.ietf.org/html/rfc5214</a> 726 * 727 * @param ip {@link Inet6Address} to be examined for ISATAP address format 728 * @return {@code true} if the argument is an ISATAP address 729 */ isIsatapAddress(Inet6Address ip)730 public static boolean isIsatapAddress(Inet6Address ip) { 731 732 // If it's a Teredo address with the right port (41217, or 0xa101) 733 // which would be encoded as 0x5efe then it can't be an ISATAP address. 734 if (isTeredoAddress(ip)) { 735 return false; 736 } 737 738 byte[] bytes = ip.getAddress(); 739 740 if ((bytes[8] | (byte) 0x03) != (byte) 0x03) { 741 742 // Verify that high byte of the 64 bit identifier is zero, modulo 743 // the U/L and G bits, with which we are not concerned. 744 return false; 745 } 746 747 return (bytes[9] == (byte) 0x00) && (bytes[10] == (byte) 0x5e) 748 && (bytes[11] == (byte) 0xfe); 749 } 750 751 /** 752 * Returns the IPv4 address embedded in an ISATAP address. 753 * 754 * @param ip {@link Inet6Address} to be examined for embedded IPv4 in ISATAP address 755 * @return {@link Inet4Address} of embedded IPv4 in an ISATAP address 756 * @throws IllegalArgumentException if the argument is not a valid IPv6 ISATAP address 757 */ getIsatapIPv4Address(Inet6Address ip)758 public static Inet4Address getIsatapIPv4Address(Inet6Address ip) { 759 Preconditions.checkArgument(isIsatapAddress(ip), 760 "Address '%s' is not an ISATAP address.", toAddrString(ip)); 761 762 return getInet4Address(Arrays.copyOfRange(ip.getAddress(), 12, 16)); 763 } 764 765 /** 766 * Examines the Inet6Address to determine if it is an IPv6 address of one 767 * of the specified address types that contain an embedded IPv4 address. 768 * 769 * <p>NOTE: ISATAP addresses are explicitly excluded from this method 770 * due to their trivial spoofability. With other transition addresses 771 * spoofing involves (at least) infection of one's BGP routing table. 772 * 773 * @param ip {@link Inet6Address} to be examined for embedded IPv4 client address 774 * @return {@code true} if there is an embedded IPv4 client address 775 * @since 7.0 776 */ hasEmbeddedIPv4ClientAddress(Inet6Address ip)777 public static boolean hasEmbeddedIPv4ClientAddress(Inet6Address ip) { 778 return isCompatIPv4Address(ip) || is6to4Address(ip) || isTeredoAddress(ip); 779 } 780 781 /** 782 * Examines the Inet6Address to extract the embedded IPv4 client address 783 * if the InetAddress is an IPv6 address of one of the specified address 784 * types that contain an embedded IPv4 address. 785 * 786 * <p>NOTE: ISATAP addresses are explicitly excluded from this method 787 * due to their trivial spoofability. With other transition addresses 788 * spoofing involves (at least) infection of one's BGP routing table. 789 * 790 * @param ip {@link Inet6Address} to be examined for embedded IPv4 client address 791 * @return {@link Inet4Address} of embedded IPv4 client address 792 * @throws IllegalArgumentException if the argument does not have a valid embedded IPv4 address 793 */ getEmbeddedIPv4ClientAddress(Inet6Address ip)794 public static Inet4Address getEmbeddedIPv4ClientAddress(Inet6Address ip) { 795 if (isCompatIPv4Address(ip)) { 796 return getCompatIPv4Address(ip); 797 } 798 799 if (is6to4Address(ip)) { 800 return get6to4IPv4Address(ip); 801 } 802 803 if (isTeredoAddress(ip)) { 804 return getTeredoInfo(ip).getClient(); 805 } 806 807 throw new IllegalArgumentException( 808 String.format("'%s' has no embedded IPv4 address.", toAddrString(ip))); 809 } 810 811 /** 812 * Evaluates whether the argument is an "IPv4 mapped" IPv6 address. 813 * 814 * <p>An "IPv4 mapped" address is anything in the range ::ffff:0:0/96 815 * (sometimes written as ::ffff:0.0.0.0/96), with the last 32 bits 816 * interpreted as an IPv4 address. 817 * 818 * <p>For more on IPv4 mapped addresses see section 2.5.5.2 of 819 * <a target="_parent" 820 * href="http://tools.ietf.org/html/rfc4291#section-2.5.5.2" 821 * >http://tools.ietf.org/html/rfc4291</a> 822 * 823 * <p>Note: This method takes a {@code String} argument because 824 * {@link InetAddress} automatically collapses mapped addresses to IPv4. 825 * (It is actually possible to avoid this using one of the obscure 826 * {@link Inet6Address} methods, but it would be unwise to depend on such 827 * a poorly-documented feature.) 828 * 829 * @param ipString {@code String} to be examined for embedded IPv4-mapped IPv6 address format 830 * @return {@code true} if the argument is a valid "mapped" address 831 * @since 10.0 832 */ isMappedIPv4Address(String ipString)833 public static boolean isMappedIPv4Address(String ipString) { 834 byte[] bytes = ipStringToBytes(ipString); 835 if (bytes != null && bytes.length == 16) { 836 for (int i = 0; i < 10; i++) { 837 if (bytes[i] != 0) { 838 return false; 839 } 840 } 841 for (int i = 10; i < 12; i++) { 842 if (bytes[i] != (byte) 0xff) { 843 return false; 844 } 845 } 846 return true; 847 } 848 return false; 849 } 850 851 /** 852 * Coerces an IPv6 address into an IPv4 address. 853 * 854 * <p>HACK: As long as applications continue to use IPv4 addresses for 855 * indexing into tables, accounting, et cetera, it may be necessary to 856 * <b>coerce</b> IPv6 addresses into IPv4 addresses. This function does 857 * so by hashing the upper 64 bits into {@code 224.0.0.0/3} 858 * (64 bits into 29 bits). 859 * 860 * <p>A "coerced" IPv4 address is equivalent to itself. 861 * 862 * <p>NOTE: This function is failsafe for security purposes: ALL IPv6 863 * addresses (except localhost (::1)) are hashed to avoid the security 864 * risk associated with extracting an embedded IPv4 address that might 865 * permit elevated privileges. 866 * 867 * @param ip {@link InetAddress} to "coerce" 868 * @return {@link Inet4Address} represented "coerced" address 869 * @since 7.0 870 */ getCoercedIPv4Address(InetAddress ip)871 public static Inet4Address getCoercedIPv4Address(InetAddress ip) { 872 if (ip instanceof Inet4Address) { 873 return (Inet4Address) ip; 874 } 875 876 // Special cases: 877 byte[] bytes = ip.getAddress(); 878 boolean leadingBytesOfZero = true; 879 for (int i = 0; i < 15; ++i) { 880 if (bytes[i] != 0) { 881 leadingBytesOfZero = false; 882 break; 883 } 884 } 885 if (leadingBytesOfZero && (bytes[15] == 1)) { 886 return LOOPBACK4; // ::1 887 } else if (leadingBytesOfZero && (bytes[15] == 0)) { 888 return ANY4; // ::0 889 } 890 891 Inet6Address ip6 = (Inet6Address) ip; 892 long addressAsLong = 0; 893 if (hasEmbeddedIPv4ClientAddress(ip6)) { 894 addressAsLong = getEmbeddedIPv4ClientAddress(ip6).hashCode(); 895 } else { 896 897 // Just extract the high 64 bits (assuming the rest is user-modifiable). 898 addressAsLong = ByteBuffer.wrap(ip6.getAddress(), 0, 8).getLong(); 899 } 900 901 // Many strategies for hashing are possible. This might suffice for now. 902 int coercedHash = Hashing.murmur3_32().hashLong(addressAsLong).asInt(); 903 904 // Squash into 224/4 Multicast and 240/4 Reserved space (i.e. 224/3). 905 coercedHash |= 0xe0000000; 906 907 // Fixup to avoid some "illegal" values. Currently the only potential 908 // illegal value is 255.255.255.255. 909 if (coercedHash == 0xffffffff) { 910 coercedHash = 0xfffffffe; 911 } 912 913 return getInet4Address(Ints.toByteArray(coercedHash)); 914 } 915 916 /** 917 * Returns an integer representing an IPv4 address regardless of 918 * whether the supplied argument is an IPv4 address or not. 919 * 920 * <p>IPv6 addresses are <b>coerced</b> to IPv4 addresses before being 921 * converted to integers. 922 * 923 * <p>As long as there are applications that assume that all IP addresses 924 * are IPv4 addresses and can therefore be converted safely to integers 925 * (for whatever purpose) this function can be used to handle IPv6 926 * addresses as well until the application is suitably fixed. 927 * 928 * <p>NOTE: an IPv6 address coerced to an IPv4 address can only be used 929 * for such purposes as rudimentary identification or indexing into a 930 * collection of real {@link InetAddress}es. They cannot be used as 931 * real addresses for the purposes of network communication. 932 * 933 * @param ip {@link InetAddress} to convert 934 * @return {@code int}, "coerced" if ip is not an IPv4 address 935 * @since 7.0 936 */ coerceToInteger(InetAddress ip)937 public static int coerceToInteger(InetAddress ip) { 938 return ByteStreams.newDataInput(getCoercedIPv4Address(ip).getAddress()).readInt(); 939 } 940 941 /** 942 * Returns an Inet4Address having the integer value specified by 943 * the argument. 944 * 945 * @param address {@code int}, the 32bit integer address to be converted 946 * @return {@link Inet4Address} equivalent of the argument 947 */ fromInteger(int address)948 public static Inet4Address fromInteger(int address) { 949 return getInet4Address(Ints.toByteArray(address)); 950 } 951 952 /** 953 * Returns an address from a <b>little-endian ordered</b> byte array 954 * (the opposite of what {@link InetAddress#getByAddress} expects). 955 * 956 * <p>IPv4 address byte array must be 4 bytes long and IPv6 byte array 957 * must be 16 bytes long. 958 * 959 * @param addr the raw IP address in little-endian byte order 960 * @return an InetAddress object created from the raw IP address 961 * @throws UnknownHostException if IP address is of illegal length 962 */ fromLittleEndianByteArray(byte[] addr)963 public static InetAddress fromLittleEndianByteArray(byte[] addr) throws UnknownHostException { 964 byte[] reversed = new byte[addr.length]; 965 for (int i = 0; i < addr.length; i++) { 966 reversed[i] = addr[addr.length - i - 1]; 967 } 968 return InetAddress.getByAddress(reversed); 969 } 970 971 /** 972 * Returns a new InetAddress that is one less than the passed in address. 973 * This method works for both IPv4 and IPv6 addresses. 974 * 975 * @param address the InetAddress to decrement 976 * @return a new InetAddress that is one less than the passed in address 977 * @throws IllegalArgumentException if InetAddress is at the beginning of its range 978 * @since 18.0 979 */ decrement(InetAddress address)980 public static InetAddress decrement(InetAddress address) { 981 byte[] addr = address.getAddress(); 982 int i = addr.length - 1; 983 while (i >= 0 && addr[i] == (byte) 0x00) { 984 addr[i] = (byte) 0xff; 985 i--; 986 } 987 988 Preconditions.checkArgument(i >= 0, "Decrementing %s would wrap.", address); 989 990 addr[i]--; 991 return bytesToInetAddress(addr); 992 } 993 994 /** 995 * Returns a new InetAddress that is one more than the passed in address. 996 * This method works for both IPv4 and IPv6 addresses. 997 * 998 * @param address the InetAddress to increment 999 * @return a new InetAddress that is one more than the passed in address 1000 * @throws IllegalArgumentException if InetAddress is at the end of its range 1001 * @since 10.0 1002 */ increment(InetAddress address)1003 public static InetAddress increment(InetAddress address) { 1004 byte[] addr = address.getAddress(); 1005 int i = addr.length - 1; 1006 while (i >= 0 && addr[i] == (byte) 0xff) { 1007 addr[i] = 0; 1008 i--; 1009 } 1010 1011 Preconditions.checkArgument(i >= 0, "Incrementing %s would wrap.", address); 1012 1013 addr[i]++; 1014 return bytesToInetAddress(addr); 1015 } 1016 1017 /** 1018 * Returns true if the InetAddress is either 255.255.255.255 for IPv4 or 1019 * ffff:ffff:ffff:ffff:ffff:ffff:ffff:ffff for IPv6. 1020 * 1021 * @return true if the InetAddress is either 255.255.255.255 for IPv4 or 1022 * ffff:ffff:ffff:ffff:ffff:ffff:ffff:ffff for IPv6 1023 * @since 10.0 1024 */ isMaximum(InetAddress address)1025 public static boolean isMaximum(InetAddress address) { 1026 byte[] addr = address.getAddress(); 1027 for (int i = 0; i < addr.length; i++) { 1028 if (addr[i] != (byte) 0xff) { 1029 return false; 1030 } 1031 } 1032 return true; 1033 } 1034 } 1035