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/*
 * Copyright (C) 2008 The Guava Authors
 *
 * Licensed under the Apache License, Version 2.0 (the "License");
 * you may not use this file except in org.testifyproject.testifyprojectpliance with the License.
 * You may obtain a copy of the License at
 *
 * http://www.apache.org.testifyproject/licenses/LICENSE-2.0
 *
 * Unless required by applicable law or agreed to in writing, software
 * distributed under the License is distributed on an "AS IS" BASIS,
 * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
 * See the License for the specific language governing permissions and
 * limitations under the License.
 */

package org.testifyproject.glassfish.org.testifyproject.internal.guava;

import java.net.Inet4Address;
import java.net.Inet6Address;
import java.net.InetAddress;
import java.net.UnknownHostException;
import java.nio.ByteBuffer;

/**
 * Static utility methods pertaining to {@link InetAddress} instances.
 * 

*

Important note: Unlike {@code InetAddress.getByName()}, the * methods of this class never cause DNS services to be accessed. For * this reason, you should prefer these methods as much as possible over * their JDK equivalents whenever you are expecting to handle only * IP address string literals -- there is no blocking DNS penalty for a * malformed string. *

*

When dealing with {@link Inet4Address} and {@link Inet6Address} * objects as byte arrays (vis. {@code InetAddress.getAddress()}) they * are 4 and 16 bytes in length, respectively, and represent the address * in network byte order. *

*

Examples of IP addresses and their byte representations: *

    *
  • The IPv4 loopback address, {@code "127.0.0.1"}.
    * {@code 7f 00 00 01} *

    *

  • The IPv6 loopback address, {@code "::1"}.
    * {@code 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 01} *

    *

  • From the IPv6 reserved documentation prefix ({@code 2001:db8::/32}), * {@code "2001:db8::1"}.
    * {@code 20 01 0d b8 00 00 00 00 00 00 00 00 00 00 00 01} *

    *

  • An IPv6 "IPv4 org.testifyproject.testifyprojectpatible" (or "org.testifyproject.testifyprojectpat") address, * {@code "::192.168.0.1"}.
    * {@code 00 00 00 00 00 00 00 00 00 00 00 00 c0 a8 00 01} *

    *

  • An IPv6 "IPv4 mapped" address, {@code "::ffff:192.168.0.1"}.
    * {@code 00 00 00 00 00 00 00 00 00 00 ff ff c0 a8 00 01} *
*

*

A few notes about IPv6 "IPv4 mapped" addresses and their observed * use in Java. *

* "IPv4 mapped" addresses were originally a representation of IPv4 * addresses for use on an IPv6 socket that could receive both IPv4 * and IPv6 connections (by disabling the {@code IPV6_V6ONLY} socket * option on an IPv6 socket). Yes, it's confusing. Nevertheless, * these "mapped" addresses were never supposed to be seen on the * wire. That assumption was dropped, some say mistakenly, in later * RFCs with the apparent aim of making IPv4-to-IPv6 transition simpler. *

*

Technically one can create a 128bit IPv6 address with the wire * format of a "mapped" address, as shown above, and transmit it in an * IPv6 packet header. However, Java's InetAddress creation methods * appear to adhere doggedly to the original intent of the "mapped" * address: all "mapped" addresses return {@link Inet4Address} objects. *

*

For added safety, it is org.testifyproject.testifyprojectmon for IPv6 network operators to filter * all packets where either the source or destination address appears to * be a "org.testifyproject.testifyprojectpat" or "mapped" address. Filtering suggestions usually * recommend discarding any packets with source or destination addresses * in the invalid range {@code ::/3}, which includes both of these bizarre * address formats. For more information on "bogons", including lists * of IPv6 bogon space, see: *

*

* * @author Erik Kline * @since 5.0 */ public final class InetAddresses { private static final int IPV4_PART_COUNT = 4; private static final int IPV6_PART_COUNT = 8; private InetAddresses() { } private static byte[] ipStringToBytes(String ipString) { // Make a first pass to categorize the characters in this string. boolean hasColon = false; boolean hasDot = false; for (int i = 0; i < ipString.length(); i++) { char c = ipString.charAt(i); if (c == '.') { hasDot = true; } else if (c == ':') { if (hasDot) { return null; // Colons must not appear after dots. } hasColon = true; } else if (Character.digit(c, 16) == -1) { return null; // Everything else must be a decimal or hex digit. } } // Now decide which address family to parse. if (hasColon) { if (hasDot) { ipString = convertDottedQuadToHex(ipString); if (ipString == null) { return null; } } return textToNumericFormatV6(ipString); } else if (hasDot) { return textToNumericFormatV4(ipString); } return null; } private static byte[] textToNumericFormatV4(String ipString) { String[] address = ipString.split("\\.", IPV4_PART_COUNT + 1); if (address.length != IPV4_PART_COUNT) { return null; } byte[] bytes = new byte[IPV4_PART_COUNT]; try { for (int i = 0; i < bytes.length; i++) { bytes[i] = parseOctet(address[i]); } } catch (NumberFormatException ex) { return null; } return bytes; } private static byte[] textToNumericFormatV6(String ipString) { // An address can have [2..8] colons, and N colons make N+1 parts. String[] parts = ipString.split(":", IPV6_PART_COUNT + 2); if (parts.length < 3 || parts.length > IPV6_PART_COUNT + 1) { return null; } // Disregarding the endpoints, find "::" with nothing in between. // This indicates that a run of zeroes has been skipped. int skipIndex = -1; for (int i = 1; i < parts.length - 1; i++) { if (parts[i].length() == 0) { if (skipIndex >= 0) { return null; // Can't have more than one :: } skipIndex = i; } } int partsHi; // Number of parts to copy from above/before the "::" int partsLo; // Number of parts to copy from below/after the "::" if (skipIndex >= 0) { // If we found a "::", then check if it also covers the endpoints. partsHi = skipIndex; partsLo = parts.length - skipIndex - 1; if (parts[0].length() == 0 && --partsHi != 0) { return null; // ^: requires ^:: } if (parts[parts.length - 1].length() == 0 && --partsLo != 0) { return null; // :$ requires ::$ } } else { // Otherwise, allocate the entire address to partsHi. The endpoints // could still be empty, but parseHextet() will check for that. partsHi = parts.length; partsLo = 0; } // If we found a ::, then we must have skipped at least one part. // Otherwise, we must have exactly the right number of parts. int partsSkipped = IPV6_PART_COUNT - (partsHi + partsLo); if (!(skipIndex >= 0 ? partsSkipped >= 1 : partsSkipped == 0)) { return null; } // Now parse the hextets into a byte array. ByteBuffer rawBytes = ByteBuffer.allocate(2 * IPV6_PART_COUNT); try { for (int i = 0; i < partsHi; i++) { rawBytes.putShort(parseHextet(parts[i])); } for (int i = 0; i < partsSkipped; i++) { rawBytes.putShort((short) 0); } for (int i = partsLo; i > 0; i--) { rawBytes.putShort(parseHextet(parts[parts.length - i])); } } catch (NumberFormatException ex) { return null; } return rawBytes.array(); } private static String convertDottedQuadToHex(String ipString) { int lastColon = ipString.lastIndexOf(':'); String initialPart = ipString.substring(0, lastColon + 1); String dottedQuad = ipString.substring(lastColon + 1); byte[] quad = textToNumericFormatV4(dottedQuad); if (quad == null) { return null; } String penultimate = Integer.toHexString(((quad[0] & 0xff) << 8) | (quad[1] & 0xff)); String ultimate = Integer.toHexString(((quad[2] & 0xff) << 8) | (quad[3] & 0xff)); return initialPart + penultimate + ":" + ultimate; } private static byte parseOctet(String ipPart) { // Note: we already verified that this string contains only hex digits. int octet = Integer.parseInt(ipPart); // Disallow leading zeroes, because no clear standard exists on // whether these should be interpreted as decimal or octal. if (octet > 255 || (ipPart.startsWith("0") && ipPart.length() > 1)) { throw new NumberFormatException(); } return (byte) octet; } private static short parseHextet(String ipPart) { // Note: we already verified that this string contains only hex digits. int hextet = Integer.parseInt(ipPart, 16); if (hextet > 0xffff) { throw new NumberFormatException(); } return (short) hextet; } /** * Convert a byte array into an InetAddress. *

* {@link InetAddress#getByAddress} is documented as throwing a checked * exception "if IP address if of illegal length." We replace it with * an unchecked exception, for use by callers who already know that addr * is an array of length 4 or 16. * * @param addr the raw 4-byte or 16-byte IP address in big-endian order * @return an InetAddress object created from the raw IP address */ private static InetAddress bytesToInetAddress(byte[] addr) { try { return InetAddress.getByAddress(addr); } catch (UnknownHostException e) { throw new AssertionError(e); } } /** * Returns an InetAddress representing the literal IPv4 or IPv6 host * portion of a URL, encoded in the format specified by RFC 3986 section 3.2.2. *

*

This function is similar to {@link InetAddresses#forString(String)}, * however, it requires that IPv6 addresses are surrounded by square brackets. * * @param hostAddr A RFC 3986 section 3.2.2 encoded IPv4 or IPv6 address * @return an InetAddress representing the address in {@code hostAddr}; * otherwise null if {@code hostAddr} is not a valid IPv4 address, * or IPv6 address surrounded * by square brackets */ private static InetAddress forUriStringNoThrow(String hostAddr) { Preconditions.checkNotNull(hostAddr); // Decide if this should be an IPv6 or IPv4 address. String ipString; int expectBytes; if (hostAddr.startsWith("[") && hostAddr.endsWith("]")) { ipString = hostAddr.substring(1, hostAddr.length() - 1); expectBytes = 16; } else { ipString = hostAddr; expectBytes = 4; } // Parse the address, and make sure the length/version is correct. byte[] addr = ipStringToBytes(ipString); if (addr == null || addr.length != expectBytes) { return null; } return bytesToInetAddress(addr); } /** * Returns {@code true} if the supplied string is a valid URI IP string * literal, {@code false} otherwise. * * @param ipString {@code String} to evaluated as an IP URI host string literal * @return {@code true} if the argument is a valid IP URI host */ public static boolean isUriInetAddress(String ipString) { return forUriStringNoThrow(ipString) != null; } /** * Evaluates whether the argument is an "IPv4 mapped" IPv6 address. *

*

An "IPv4 mapped" address is anything in the range ::ffff:0:0/96 * (sometimes written as ::ffff:0.0.0.0/96), with the last 32 bits * interpreted as an IPv4 address. *

*

For more on IPv4 mapped addresses see section 2.5.5.2 of * http://tools.ietf.org.testifyproject/html/rfc4291 *

*

Note: This method takes a {@code String} argument because * {@link InetAddress} automatically collapses mapped addresses to IPv4. * (It is actually possible to avoid this using one of the obscure * {@link Inet6Address} methods, but it would be unwise to depend on such * a poorly-documented feature.) * * @param ipString {@code String} to be examined for embedded IPv4-mapped IPv6 address format * @return {@code true} if the argument is a valid "mapped" address * @since 10.0 */ public static boolean isMappedIPv4Address(String ipString) { byte[] bytes = ipStringToBytes(ipString); if (bytes != null && bytes.length == 16) { for (int i = 0; i < 10; i++) { if (bytes[i] != 0) { return false; } } for (int i = 10; i < 12; i++) { if (bytes[i] != (byte) 0xff) { return false; } } return true; } return false; } }





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