netty5/resolver-dns/src/main/java/io/netty/resolver/dns/DnsNameResolver.java
Norman Maurer 1672b6d12c
Add support for TCP fallback when we receive a truncated DnsResponse (#9139)
Motivation:

Sometimes DNS responses can be very large which mean they will not fit in a UDP packet. When this is happening the DNS server will set the TC flag (truncated flag) to tell the resolver that the response was truncated. When a truncated response was received we should allow to retry via TCP and use the received response (if possible) as a replacement for the truncated one.

See https://tools.ietf.org/html/rfc7766.

Modifications:

- Add support for TCP fallback by allow to specify a socketChannelFactory / socketChannelType on the DnsNameResolverBuilder. If this is set to something different then null we will try to fallback to TCP.
- Add decoder / encoder for TCP
- Add unit tests

Result:

Support for TCP fallback as defined by https://tools.ietf.org/html/rfc7766 when using DnsNameResolver.
2019-05-17 14:37:11 +02:00

1424 lines
63 KiB
Java

/*
* Copyright 2014 The Netty Project
*
* The Netty Project licenses this file to you under the Apache License,
* version 2.0 (the "License"); you may not use this file except in compliance
* with the License. You may obtain a copy of the License at:
*
* http://www.apache.org/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 io.netty.resolver.dns;
import io.netty.bootstrap.Bootstrap;
import io.netty.buffer.ByteBuf;
import io.netty.buffer.Unpooled;
import io.netty.channel.AddressedEnvelope;
import io.netty.channel.Channel;
import io.netty.channel.ChannelFactory;
import io.netty.channel.ChannelFuture;
import io.netty.channel.ChannelFutureListener;
import io.netty.channel.ChannelHandlerContext;
import io.netty.channel.ChannelInboundHandlerAdapter;
import io.netty.channel.ChannelInitializer;
import io.netty.channel.ChannelOption;
import io.netty.channel.ChannelPromise;
import io.netty.channel.EventLoop;
import io.netty.channel.FixedRecvByteBufAllocator;
import io.netty.channel.socket.DatagramChannel;
import io.netty.channel.socket.InternetProtocolFamily;
import io.netty.channel.socket.SocketChannel;
import io.netty.handler.codec.dns.DatagramDnsQueryEncoder;
import io.netty.handler.codec.dns.DatagramDnsResponse;
import io.netty.handler.codec.dns.DatagramDnsResponseDecoder;
import io.netty.handler.codec.dns.DefaultDnsRawRecord;
import io.netty.handler.codec.dns.DnsQuestion;
import io.netty.handler.codec.dns.DnsRawRecord;
import io.netty.handler.codec.dns.DnsRecord;
import io.netty.handler.codec.dns.DnsRecordType;
import io.netty.handler.codec.dns.DnsResponse;
import io.netty.handler.codec.dns.TcpDnsQueryEncoder;
import io.netty.handler.codec.dns.TcpDnsResponseDecoder;
import io.netty.resolver.HostsFileEntries;
import io.netty.resolver.HostsFileEntriesResolver;
import io.netty.resolver.InetNameResolver;
import io.netty.resolver.ResolvedAddressTypes;
import io.netty.util.NetUtil;
import io.netty.util.ReferenceCountUtil;
import io.netty.util.concurrent.EventExecutor;
import io.netty.util.concurrent.FastThreadLocal;
import io.netty.util.concurrent.Future;
import io.netty.util.concurrent.FutureListener;
import io.netty.util.concurrent.Promise;
import io.netty.util.internal.EmptyArrays;
import io.netty.util.internal.PlatformDependent;
import io.netty.util.internal.StringUtil;
import io.netty.util.internal.UnstableApi;
import io.netty.util.internal.logging.InternalLogger;
import io.netty.util.internal.logging.InternalLoggerFactory;
import java.lang.reflect.Method;
import java.net.IDN;
import java.net.Inet4Address;
import java.net.Inet6Address;
import java.net.InetAddress;
import java.net.InetSocketAddress;
import java.net.NetworkInterface;
import java.net.SocketAddress;
import java.net.SocketException;
import java.util.ArrayList;
import java.util.Collection;
import java.util.Collections;
import java.util.Comparator;
import java.util.Enumeration;
import java.util.Iterator;
import java.util.List;
import static io.netty.resolver.dns.DefaultDnsServerAddressStreamProvider.DNS_PORT;
import static io.netty.resolver.dns.UnixResolverDnsServerAddressStreamProvider.parseEtcResolverFirstNdots;
import static io.netty.util.internal.ObjectUtil.checkNotNull;
import static io.netty.util.internal.ObjectUtil.checkPositive;
/**
* A DNS-based {@link InetNameResolver}.
*/
@UnstableApi
public class DnsNameResolver extends InetNameResolver {
private static final InternalLogger logger = InternalLoggerFactory.getInstance(DnsNameResolver.class);
private static final String LOCALHOST = "localhost";
private static final InetAddress LOCALHOST_ADDRESS;
private static final DnsRecord[] EMPTY_ADDITIONALS = new DnsRecord[0];
private static final DnsRecordType[] IPV4_ONLY_RESOLVED_RECORD_TYPES =
{DnsRecordType.A};
private static final InternetProtocolFamily[] IPV4_ONLY_RESOLVED_PROTOCOL_FAMILIES =
{InternetProtocolFamily.IPv4};
private static final DnsRecordType[] IPV4_PREFERRED_RESOLVED_RECORD_TYPES =
{DnsRecordType.A, DnsRecordType.AAAA};
private static final InternetProtocolFamily[] IPV4_PREFERRED_RESOLVED_PROTOCOL_FAMILIES =
{InternetProtocolFamily.IPv4, InternetProtocolFamily.IPv6};
private static final DnsRecordType[] IPV6_ONLY_RESOLVED_RECORD_TYPES =
{DnsRecordType.AAAA};
private static final InternetProtocolFamily[] IPV6_ONLY_RESOLVED_PROTOCOL_FAMILIES =
{InternetProtocolFamily.IPv6};
private static final DnsRecordType[] IPV6_PREFERRED_RESOLVED_RECORD_TYPES =
{DnsRecordType.AAAA, DnsRecordType.A};
private static final InternetProtocolFamily[] IPV6_PREFERRED_RESOLVED_PROTOCOL_FAMILIES =
{InternetProtocolFamily.IPv6, InternetProtocolFamily.IPv4};
static final ResolvedAddressTypes DEFAULT_RESOLVE_ADDRESS_TYPES;
static final String[] DEFAULT_SEARCH_DOMAINS;
private static final int DEFAULT_NDOTS;
static {
if (NetUtil.isIpV4StackPreferred() || !anyInterfaceSupportsIpV6()) {
DEFAULT_RESOLVE_ADDRESS_TYPES = ResolvedAddressTypes.IPV4_ONLY;
LOCALHOST_ADDRESS = NetUtil.LOCALHOST4;
} else {
if (NetUtil.isIpV6AddressesPreferred()) {
DEFAULT_RESOLVE_ADDRESS_TYPES = ResolvedAddressTypes.IPV6_PREFERRED;
LOCALHOST_ADDRESS = NetUtil.LOCALHOST6;
} else {
DEFAULT_RESOLVE_ADDRESS_TYPES = ResolvedAddressTypes.IPV4_PREFERRED;
LOCALHOST_ADDRESS = NetUtil.LOCALHOST4;
}
}
}
static {
String[] searchDomains;
try {
List<String> list = PlatformDependent.isWindows()
? getSearchDomainsHack()
: UnixResolverDnsServerAddressStreamProvider.parseEtcResolverSearchDomains();
searchDomains = list.toArray(new String[0]);
} catch (Exception ignore) {
// Failed to get the system name search domain list.
searchDomains = EmptyArrays.EMPTY_STRINGS;
}
DEFAULT_SEARCH_DOMAINS = searchDomains;
int ndots;
try {
ndots = parseEtcResolverFirstNdots();
} catch (Exception ignore) {
ndots = UnixResolverDnsServerAddressStreamProvider.DEFAULT_NDOTS;
}
DEFAULT_NDOTS = ndots;
}
/**
* Returns {@code true} if any {@link NetworkInterface} supports {@code IPv6}, {@code false} otherwise.
*/
private static boolean anyInterfaceSupportsIpV6() {
try {
Enumeration<NetworkInterface> interfaces = NetworkInterface.getNetworkInterfaces();
while (interfaces.hasMoreElements()) {
NetworkInterface iface = interfaces.nextElement();
Enumeration<InetAddress> addresses = iface.getInetAddresses();
while (addresses.hasMoreElements()) {
if (addresses.nextElement() instanceof Inet6Address) {
return true;
}
}
}
} catch (SocketException e) {
logger.debug("Unable to detect if any interface supports IPv6, assuming IPv4-only", e);
// ignore
}
return false;
}
@SuppressWarnings("unchecked")
private static List<String> getSearchDomainsHack() throws Exception {
// This code on Java 9+ yields a warning about illegal reflective access that will be denied in
// a future release. There doesn't seem to be a better way to get search domains for Windows yet.
Class<?> configClass = Class.forName("sun.net.dns.ResolverConfiguration");
Method open = configClass.getMethod("open");
Method nameservers = configClass.getMethod("searchlist");
Object instance = open.invoke(null);
return (List<String>) nameservers.invoke(instance);
}
private static final DatagramDnsResponseDecoder DATAGRAM_DECODER = new DatagramDnsResponseDecoder();
private static final DatagramDnsQueryEncoder DATAGRAM_ENCODER = new DatagramDnsQueryEncoder();
private static final TcpDnsQueryEncoder TCP_ENCODER = new TcpDnsQueryEncoder();
final Future<Channel> channelFuture;
final Channel ch;
// Comparator that ensures we will try first to use the nameservers that use our preferred address type.
private final Comparator<InetSocketAddress> nameServerComparator;
/**
* Manages the {@link DnsQueryContext}s in progress and their query IDs.
*/
final DnsQueryContextManager queryContextManager = new DnsQueryContextManager();
/**
* Cache for {@link #doResolve(String, Promise)} and {@link #doResolveAll(String, Promise)}.
*/
private final DnsCache resolveCache;
private final AuthoritativeDnsServerCache authoritativeDnsServerCache;
private final DnsCnameCache cnameCache;
private final FastThreadLocal<DnsServerAddressStream> nameServerAddrStream =
new FastThreadLocal<DnsServerAddressStream>() {
@Override
protected DnsServerAddressStream initialValue() {
return dnsServerAddressStreamProvider.nameServerAddressStream("");
}
};
private final long queryTimeoutMillis;
private final int maxQueriesPerResolve;
private final ResolvedAddressTypes resolvedAddressTypes;
private final InternetProtocolFamily[] resolvedInternetProtocolFamilies;
private final boolean recursionDesired;
private final int maxPayloadSize;
private final boolean optResourceEnabled;
private final HostsFileEntriesResolver hostsFileEntriesResolver;
private final DnsServerAddressStreamProvider dnsServerAddressStreamProvider;
private final String[] searchDomains;
private final int ndots;
private final boolean supportsAAAARecords;
private final boolean supportsARecords;
private final InternetProtocolFamily preferredAddressType;
private final DnsRecordType[] resolveRecordTypes;
private final boolean decodeIdn;
private final DnsQueryLifecycleObserverFactory dnsQueryLifecycleObserverFactory;
private final boolean completeOncePreferredResolved;
private final ChannelFactory<? extends SocketChannel> socketChannelFactory;
/**
* Creates a new DNS-based name resolver that communicates with the specified list of DNS servers.
*
* @param eventLoop the {@link EventLoop} which will perform the communication with the DNS servers
* @param channelFactory the {@link ChannelFactory} that will create a {@link DatagramChannel}
* @param resolveCache the DNS resolved entries cache
* @param authoritativeDnsServerCache the cache used to find the authoritative DNS server for a domain
* @param dnsQueryLifecycleObserverFactory used to generate new instances of {@link DnsQueryLifecycleObserver} which
* can be used to track metrics for DNS servers.
* @param queryTimeoutMillis timeout of each DNS query in millis
* @param resolvedAddressTypes the preferred address types
* @param recursionDesired if recursion desired flag must be set
* @param maxQueriesPerResolve the maximum allowed number of DNS queries for a given name resolution
* @param traceEnabled if trace is enabled
* @param maxPayloadSize the capacity of the datagram packet buffer
* @param optResourceEnabled if automatic inclusion of a optional records is enabled
* @param hostsFileEntriesResolver the {@link HostsFileEntriesResolver} used to check for local aliases
* @param dnsServerAddressStreamProvider The {@link DnsServerAddressStreamProvider} used to determine the name
* servers for each hostname lookup.
* @param searchDomains the list of search domain
* (can be null, if so, will try to default to the underlying platform ones)
* @param ndots the ndots value
* @param decodeIdn {@code true} if domain / host names should be decoded to unicode when received.
* See <a href="https://tools.ietf.org/html/rfc3492">rfc3492</a>.
* @deprecated Use {@link DnsNameResolverBuilder}.
*/
@Deprecated
public DnsNameResolver(
EventLoop eventLoop,
ChannelFactory<? extends DatagramChannel> channelFactory,
final DnsCache resolveCache,
final DnsCache authoritativeDnsServerCache,
DnsQueryLifecycleObserverFactory dnsQueryLifecycleObserverFactory,
long queryTimeoutMillis,
ResolvedAddressTypes resolvedAddressTypes,
boolean recursionDesired,
int maxQueriesPerResolve,
boolean traceEnabled,
int maxPayloadSize,
boolean optResourceEnabled,
HostsFileEntriesResolver hostsFileEntriesResolver,
DnsServerAddressStreamProvider dnsServerAddressStreamProvider,
String[] searchDomains,
int ndots,
boolean decodeIdn) {
this(eventLoop, channelFactory, resolveCache,
new AuthoritativeDnsServerCacheAdapter(authoritativeDnsServerCache), dnsQueryLifecycleObserverFactory,
queryTimeoutMillis, resolvedAddressTypes, recursionDesired, maxQueriesPerResolve, traceEnabled,
maxPayloadSize, optResourceEnabled, hostsFileEntriesResolver, dnsServerAddressStreamProvider,
searchDomains, ndots, decodeIdn);
}
/**
* Creates a new DNS-based name resolver that communicates with the specified list of DNS servers.
*
* @param eventLoop the {@link EventLoop} which will perform the communication with the DNS servers
* @param channelFactory the {@link ChannelFactory} that will create a {@link DatagramChannel}
* @param resolveCache the DNS resolved entries cache
* @param authoritativeDnsServerCache the cache used to find the authoritative DNS server for a domain
* @param dnsQueryLifecycleObserverFactory used to generate new instances of {@link DnsQueryLifecycleObserver} which
* can be used to track metrics for DNS servers.
* @param queryTimeoutMillis timeout of each DNS query in millis
* @param resolvedAddressTypes the preferred address types
* @param recursionDesired if recursion desired flag must be set
* @param maxQueriesPerResolve the maximum allowed number of DNS queries for a given name resolution
* @param traceEnabled if trace is enabled
* @param maxPayloadSize the capacity of the datagram packet buffer
* @param optResourceEnabled if automatic inclusion of a optional records is enabled
* @param hostsFileEntriesResolver the {@link HostsFileEntriesResolver} used to check for local aliases
* @param dnsServerAddressStreamProvider The {@link DnsServerAddressStreamProvider} used to determine the name
* servers for each hostname lookup.
* @param searchDomains the list of search domain
* (can be null, if so, will try to default to the underlying platform ones)
* @param ndots the ndots value
* @param decodeIdn {@code true} if domain / host names should be decoded to unicode when received.
* See <a href="https://tools.ietf.org/html/rfc3492">rfc3492</a>.
* @deprecated Use {@link DnsNameResolverBuilder}.
*/
@Deprecated
public DnsNameResolver(
EventLoop eventLoop,
ChannelFactory<? extends DatagramChannel> channelFactory,
final DnsCache resolveCache,
final AuthoritativeDnsServerCache authoritativeDnsServerCache,
DnsQueryLifecycleObserverFactory dnsQueryLifecycleObserverFactory,
long queryTimeoutMillis,
ResolvedAddressTypes resolvedAddressTypes,
boolean recursionDesired,
int maxQueriesPerResolve,
boolean traceEnabled,
int maxPayloadSize,
boolean optResourceEnabled,
HostsFileEntriesResolver hostsFileEntriesResolver,
DnsServerAddressStreamProvider dnsServerAddressStreamProvider,
String[] searchDomains,
int ndots,
boolean decodeIdn) {
this(eventLoop, channelFactory, null, resolveCache, NoopDnsCnameCache.INSTANCE, authoritativeDnsServerCache,
dnsQueryLifecycleObserverFactory, queryTimeoutMillis, resolvedAddressTypes, recursionDesired,
maxQueriesPerResolve, traceEnabled, maxPayloadSize, optResourceEnabled, hostsFileEntriesResolver,
dnsServerAddressStreamProvider, searchDomains, ndots, decodeIdn, false);
}
DnsNameResolver(
EventLoop eventLoop,
ChannelFactory<? extends DatagramChannel> channelFactory,
ChannelFactory<? extends SocketChannel> socketChannelFactory,
final DnsCache resolveCache,
final DnsCnameCache cnameCache,
final AuthoritativeDnsServerCache authoritativeDnsServerCache,
DnsQueryLifecycleObserverFactory dnsQueryLifecycleObserverFactory,
long queryTimeoutMillis,
ResolvedAddressTypes resolvedAddressTypes,
boolean recursionDesired,
int maxQueriesPerResolve,
boolean traceEnabled,
int maxPayloadSize,
boolean optResourceEnabled,
HostsFileEntriesResolver hostsFileEntriesResolver,
DnsServerAddressStreamProvider dnsServerAddressStreamProvider,
String[] searchDomains,
int ndots,
boolean decodeIdn,
boolean completeOncePreferredResolved) {
super(eventLoop);
this.queryTimeoutMillis = checkPositive(queryTimeoutMillis, "queryTimeoutMillis");
this.resolvedAddressTypes = resolvedAddressTypes != null ? resolvedAddressTypes : DEFAULT_RESOLVE_ADDRESS_TYPES;
this.recursionDesired = recursionDesired;
this.maxQueriesPerResolve = checkPositive(maxQueriesPerResolve, "maxQueriesPerResolve");
this.maxPayloadSize = checkPositive(maxPayloadSize, "maxPayloadSize");
this.optResourceEnabled = optResourceEnabled;
this.hostsFileEntriesResolver = checkNotNull(hostsFileEntriesResolver, "hostsFileEntriesResolver");
this.dnsServerAddressStreamProvider =
checkNotNull(dnsServerAddressStreamProvider, "dnsServerAddressStreamProvider");
this.resolveCache = checkNotNull(resolveCache, "resolveCache");
this.cnameCache = checkNotNull(cnameCache, "cnameCache");
this.dnsQueryLifecycleObserverFactory = traceEnabled ?
dnsQueryLifecycleObserverFactory instanceof NoopDnsQueryLifecycleObserverFactory ?
new TraceDnsQueryLifeCycleObserverFactory() :
new BiDnsQueryLifecycleObserverFactory(new TraceDnsQueryLifeCycleObserverFactory(),
dnsQueryLifecycleObserverFactory) :
checkNotNull(dnsQueryLifecycleObserverFactory, "dnsQueryLifecycleObserverFactory");
this.searchDomains = searchDomains != null ? searchDomains.clone() : DEFAULT_SEARCH_DOMAINS;
this.ndots = ndots >= 0 ? ndots : DEFAULT_NDOTS;
this.decodeIdn = decodeIdn;
this.completeOncePreferredResolved = completeOncePreferredResolved;
this.socketChannelFactory = socketChannelFactory;
switch (this.resolvedAddressTypes) {
case IPV4_ONLY:
supportsAAAARecords = false;
supportsARecords = true;
resolveRecordTypes = IPV4_ONLY_RESOLVED_RECORD_TYPES;
resolvedInternetProtocolFamilies = IPV4_ONLY_RESOLVED_PROTOCOL_FAMILIES;
break;
case IPV4_PREFERRED:
supportsAAAARecords = true;
supportsARecords = true;
resolveRecordTypes = IPV4_PREFERRED_RESOLVED_RECORD_TYPES;
resolvedInternetProtocolFamilies = IPV4_PREFERRED_RESOLVED_PROTOCOL_FAMILIES;
break;
case IPV6_ONLY:
supportsAAAARecords = true;
supportsARecords = false;
resolveRecordTypes = IPV6_ONLY_RESOLVED_RECORD_TYPES;
resolvedInternetProtocolFamilies = IPV6_ONLY_RESOLVED_PROTOCOL_FAMILIES;
break;
case IPV6_PREFERRED:
supportsAAAARecords = true;
supportsARecords = true;
resolveRecordTypes = IPV6_PREFERRED_RESOLVED_RECORD_TYPES;
resolvedInternetProtocolFamilies = IPV6_PREFERRED_RESOLVED_PROTOCOL_FAMILIES;
break;
default:
throw new IllegalArgumentException("Unknown ResolvedAddressTypes " + resolvedAddressTypes);
}
preferredAddressType = preferredAddressType(this.resolvedAddressTypes);
this.authoritativeDnsServerCache = checkNotNull(authoritativeDnsServerCache, "authoritativeDnsServerCache");
nameServerComparator = new NameServerComparator(preferredAddressType.addressType());
Bootstrap b = new Bootstrap();
b.group(executor());
b.channelFactory(channelFactory);
b.option(ChannelOption.DATAGRAM_CHANNEL_ACTIVE_ON_REGISTRATION, true);
final DnsResponseHandler responseHandler = new DnsResponseHandler(executor().<Channel>newPromise());
b.handler(new ChannelInitializer<DatagramChannel>() {
@Override
protected void initChannel(DatagramChannel ch) {
ch.pipeline().addLast(DATAGRAM_ENCODER, DATAGRAM_DECODER, responseHandler);
}
});
channelFuture = responseHandler.channelActivePromise;
ChannelFuture future = b.register();
Throwable cause = future.cause();
if (cause != null) {
if (cause instanceof RuntimeException) {
throw (RuntimeException) cause;
}
if (cause instanceof Error) {
throw (Error) cause;
}
throw new IllegalStateException("Unable to create / register Channel", cause);
}
ch = future.channel();
ch.config().setRecvByteBufAllocator(new FixedRecvByteBufAllocator(maxPayloadSize));
ch.closeFuture().addListener(new ChannelFutureListener() {
@Override
public void operationComplete(ChannelFuture future) {
resolveCache.clear();
cnameCache.clear();
authoritativeDnsServerCache.clear();
}
});
}
static InternetProtocolFamily preferredAddressType(ResolvedAddressTypes resolvedAddressTypes) {
switch (resolvedAddressTypes) {
case IPV4_ONLY:
case IPV4_PREFERRED:
return InternetProtocolFamily.IPv4;
case IPV6_ONLY:
case IPV6_PREFERRED:
return InternetProtocolFamily.IPv6;
default:
throw new IllegalArgumentException("Unknown ResolvedAddressTypes " + resolvedAddressTypes);
}
}
// Only here to override in unit tests.
InetSocketAddress newRedirectServerAddress(InetAddress server) {
return new InetSocketAddress(server, DNS_PORT);
}
final DnsQueryLifecycleObserverFactory dnsQueryLifecycleObserverFactory() {
return dnsQueryLifecycleObserverFactory;
}
/**
* Creates a new {@link DnsServerAddressStream} to following a redirected DNS query. By overriding this
* it provides the opportunity to sort the name servers before following a redirected DNS query.
*
* @param hostname the hostname.
* @param nameservers The addresses of the DNS servers which are used in the event of a redirect. This may
* contain resolved and unresolved addresses so the used {@link DnsServerAddressStream} must
* allow unresolved addresses if you want to include these as well.
* @return A {@link DnsServerAddressStream} which will be used to follow the DNS redirect or {@code null} if
* none should be followed.
*/
protected DnsServerAddressStream newRedirectDnsServerStream(
@SuppressWarnings("unused") String hostname, List<InetSocketAddress> nameservers) {
DnsServerAddressStream cached = authoritativeDnsServerCache().get(hostname);
if (cached == null || cached.size() == 0) {
// If there is no cache hit (which may be the case for example when a NoopAuthoritativeDnsServerCache
// is used), we will just directly use the provided nameservers.
Collections.sort(nameservers, nameServerComparator);
return new SequentialDnsServerAddressStream(nameservers, 0);
}
return cached;
}
/**
* Returns the resolution cache.
*/
public DnsCache resolveCache() {
return resolveCache;
}
/**
* Returns the {@link DnsCnameCache}.
*/
DnsCnameCache cnameCache() {
return cnameCache;
}
/**
* Returns the cache used for authoritative DNS servers for a domain.
*/
public AuthoritativeDnsServerCache authoritativeDnsServerCache() {
return authoritativeDnsServerCache;
}
/**
* Returns the timeout of each DNS query performed by this resolver (in milliseconds).
* The default value is 5 seconds.
*/
public long queryTimeoutMillis() {
return queryTimeoutMillis;
}
/**
* Returns the {@link ResolvedAddressTypes} resolved by {@link #resolve(String)}.
* The default value depends on the value of the system property {@code "java.net.preferIPv6Addresses"}.
*/
public ResolvedAddressTypes resolvedAddressTypes() {
return resolvedAddressTypes;
}
InternetProtocolFamily[] resolvedInternetProtocolFamiliesUnsafe() {
return resolvedInternetProtocolFamilies;
}
final String[] searchDomains() {
return searchDomains;
}
final int ndots() {
return ndots;
}
final boolean supportsAAAARecords() {
return supportsAAAARecords;
}
final boolean supportsARecords() {
return supportsARecords;
}
final InternetProtocolFamily preferredAddressType() {
return preferredAddressType;
}
final DnsRecordType[] resolveRecordTypes() {
return resolveRecordTypes;
}
final boolean isDecodeIdn() {
return decodeIdn;
}
/**
* Returns {@code true} if and only if this resolver sends a DNS query with the RD (recursion desired) flag set.
* The default value is {@code true}.
*/
public boolean isRecursionDesired() {
return recursionDesired;
}
/**
* Returns the maximum allowed number of DNS queries to send when resolving a host name.
* The default value is {@code 8}.
*/
public int maxQueriesPerResolve() {
return maxQueriesPerResolve;
}
/**
* Returns the capacity of the datagram packet buffer (in bytes). The default value is {@code 4096} bytes.
*/
public int maxPayloadSize() {
return maxPayloadSize;
}
/**
* Returns the automatic inclusion of a optional records that tries to give the remote DNS server a hint about how
* much data the resolver can read per response is enabled.
*/
public boolean isOptResourceEnabled() {
return optResourceEnabled;
}
/**
* Returns the component that tries to resolve hostnames against the hosts file prior to asking to
* remotes DNS servers.
*/
public HostsFileEntriesResolver hostsFileEntriesResolver() {
return hostsFileEntriesResolver;
}
/**
* Closes the internal datagram channel used for sending and receiving DNS messages, and clears all DNS resource
* records from the cache. Attempting to send a DNS query or to resolve a domain name will fail once this method
* has been called.
*/
@Override
public void close() {
if (ch.isOpen()) {
ch.close();
}
}
@Override
protected EventLoop executor() {
return (EventLoop) super.executor();
}
private InetAddress resolveHostsFileEntry(String hostname) {
if (hostsFileEntriesResolver == null) {
return null;
} else {
InetAddress address = hostsFileEntriesResolver.address(hostname, resolvedAddressTypes);
if (address == null && PlatformDependent.isWindows() && LOCALHOST.equalsIgnoreCase(hostname)) {
// If we tried to resolve localhost we need workaround that windows removed localhost from its
// hostfile in later versions.
// See https://github.com/netty/netty/issues/5386
return LOCALHOST_ADDRESS;
}
return address;
}
}
/**
* Resolves the specified name into an address.
*
* @param inetHost the name to resolve
* @param additionals additional records ({@code OPT})
*
* @return the address as the result of the resolution
*/
public final Future<InetAddress> resolve(String inetHost, Iterable<DnsRecord> additionals) {
return resolve(inetHost, additionals, executor().<InetAddress>newPromise());
}
/**
* Resolves the specified name into an address.
*
* @param inetHost the name to resolve
* @param additionals additional records ({@code OPT})
* @param promise the {@link Promise} which will be fulfilled when the name resolution is finished
*
* @return the address as the result of the resolution
*/
public final Future<InetAddress> resolve(String inetHost, Iterable<DnsRecord> additionals,
Promise<InetAddress> promise) {
checkNotNull(promise, "promise");
DnsRecord[] additionalsArray = toArray(additionals, true);
try {
doResolve(inetHost, additionalsArray, promise, resolveCache);
return promise;
} catch (Exception e) {
return promise.setFailure(e);
}
}
/**
* Resolves the specified host name and port into a list of address.
*
* @param inetHost the name to resolve
* @param additionals additional records ({@code OPT})
*
* @return the list of the address as the result of the resolution
*/
public final Future<List<InetAddress>> resolveAll(String inetHost, Iterable<DnsRecord> additionals) {
return resolveAll(inetHost, additionals, executor().<List<InetAddress>>newPromise());
}
/**
* Resolves the specified host name and port into a list of address.
*
* @param inetHost the name to resolve
* @param additionals additional records ({@code OPT})
* @param promise the {@link Promise} which will be fulfilled when the name resolution is finished
*
* @return the list of the address as the result of the resolution
*/
public final Future<List<InetAddress>> resolveAll(String inetHost, Iterable<DnsRecord> additionals,
Promise<List<InetAddress>> promise) {
checkNotNull(promise, "promise");
DnsRecord[] additionalsArray = toArray(additionals, true);
try {
doResolveAll(inetHost, additionalsArray, promise, resolveCache);
return promise;
} catch (Exception e) {
return promise.setFailure(e);
}
}
@Override
protected void doResolve(String inetHost, Promise<InetAddress> promise) throws Exception {
doResolve(inetHost, EMPTY_ADDITIONALS, promise, resolveCache);
}
/**
* Resolves the {@link DnsRecord}s that are matched by the specified {@link DnsQuestion}. Unlike
* {@link #query(DnsQuestion)}, this method handles redirection, CNAMEs and multiple name servers.
* If the specified {@link DnsQuestion} is {@code A} or {@code AAAA}, this method looks up the configured
* {@link HostsFileEntries} before sending a query to the name servers. If a match is found in the
* {@link HostsFileEntries}, a synthetic {@code A} or {@code AAAA} record will be returned.
*
* @param question the question
*
* @return the list of the {@link DnsRecord}s as the result of the resolution
*/
public final Future<List<DnsRecord>> resolveAll(DnsQuestion question) {
return resolveAll(question, EMPTY_ADDITIONALS, executor().<List<DnsRecord>>newPromise());
}
/**
* Resolves the {@link DnsRecord}s that are matched by the specified {@link DnsQuestion}. Unlike
* {@link #query(DnsQuestion)}, this method handles redirection, CNAMEs and multiple name servers.
* If the specified {@link DnsQuestion} is {@code A} or {@code AAAA}, this method looks up the configured
* {@link HostsFileEntries} before sending a query to the name servers. If a match is found in the
* {@link HostsFileEntries}, a synthetic {@code A} or {@code AAAA} record will be returned.
*
* @param question the question
* @param additionals additional records ({@code OPT})
*
* @return the list of the {@link DnsRecord}s as the result of the resolution
*/
public final Future<List<DnsRecord>> resolveAll(DnsQuestion question, Iterable<DnsRecord> additionals) {
return resolveAll(question, additionals, executor().<List<DnsRecord>>newPromise());
}
/**
* Resolves the {@link DnsRecord}s that are matched by the specified {@link DnsQuestion}. Unlike
* {@link #query(DnsQuestion)}, this method handles redirection, CNAMEs and multiple name servers.
* If the specified {@link DnsQuestion} is {@code A} or {@code AAAA}, this method looks up the configured
* {@link HostsFileEntries} before sending a query to the name servers. If a match is found in the
* {@link HostsFileEntries}, a synthetic {@code A} or {@code AAAA} record will be returned.
*
* @param question the question
* @param additionals additional records ({@code OPT})
* @param promise the {@link Promise} which will be fulfilled when the resolution is finished
*
* @return the list of the {@link DnsRecord}s as the result of the resolution
*/
public final Future<List<DnsRecord>> resolveAll(DnsQuestion question, Iterable<DnsRecord> additionals,
Promise<List<DnsRecord>> promise) {
final DnsRecord[] additionalsArray = toArray(additionals, true);
return resolveAll(question, additionalsArray, promise);
}
private Future<List<DnsRecord>> resolveAll(DnsQuestion question, DnsRecord[] additionals,
Promise<List<DnsRecord>> promise) {
checkNotNull(question, "question");
checkNotNull(promise, "promise");
// Respect /etc/hosts as well if the record type is A or AAAA.
final DnsRecordType type = question.type();
final String hostname = question.name();
if (type == DnsRecordType.A || type == DnsRecordType.AAAA) {
final InetAddress hostsFileEntry = resolveHostsFileEntry(hostname);
if (hostsFileEntry != null) {
ByteBuf content = null;
if (hostsFileEntry instanceof Inet4Address) {
if (type == DnsRecordType.A) {
content = Unpooled.wrappedBuffer(hostsFileEntry.getAddress());
}
} else if (hostsFileEntry instanceof Inet6Address) {
if (type == DnsRecordType.AAAA) {
content = Unpooled.wrappedBuffer(hostsFileEntry.getAddress());
}
}
if (content != null) {
// Our current implementation does not support reloading the hosts file,
// so use a fairly large TTL (1 day, i.e. 86400 seconds).
trySuccess(promise, Collections.<DnsRecord>singletonList(
new DefaultDnsRawRecord(hostname, type, 86400, content)));
return promise;
}
}
}
// It was not A/AAAA question or there was no entry in /etc/hosts.
final DnsServerAddressStream nameServerAddrs =
dnsServerAddressStreamProvider.nameServerAddressStream(hostname);
new DnsRecordResolveContext(this, question, additionals, nameServerAddrs).resolve(promise);
return promise;
}
private static DnsRecord[] toArray(Iterable<DnsRecord> additionals, boolean validateType) {
checkNotNull(additionals, "additionals");
if (additionals instanceof Collection) {
Collection<DnsRecord> records = (Collection<DnsRecord>) additionals;
for (DnsRecord r: additionals) {
validateAdditional(r, validateType);
}
return records.toArray(new DnsRecord[records.size()]);
}
Iterator<DnsRecord> additionalsIt = additionals.iterator();
if (!additionalsIt.hasNext()) {
return EMPTY_ADDITIONALS;
}
List<DnsRecord> records = new ArrayList<DnsRecord>();
do {
DnsRecord r = additionalsIt.next();
validateAdditional(r, validateType);
records.add(r);
} while (additionalsIt.hasNext());
return records.toArray(new DnsRecord[records.size()]);
}
private static void validateAdditional(DnsRecord record, boolean validateType) {
checkNotNull(record, "record");
if (validateType && record instanceof DnsRawRecord) {
throw new IllegalArgumentException("DnsRawRecord implementations not allowed: " + record);
}
}
private InetAddress loopbackAddress() {
return preferredAddressType().localhost();
}
/**
* Hook designed for extensibility so one can pass a different cache on each resolution attempt
* instead of using the global one.
*/
protected void doResolve(String inetHost,
DnsRecord[] additionals,
Promise<InetAddress> promise,
DnsCache resolveCache) throws Exception {
if (inetHost == null || inetHost.isEmpty()) {
// If an empty hostname is used we should use "localhost", just like InetAddress.getByName(...) does.
promise.setSuccess(loopbackAddress());
return;
}
final byte[] bytes = NetUtil.createByteArrayFromIpAddressString(inetHost);
if (bytes != null) {
// The inetHost is actually an ipaddress.
promise.setSuccess(InetAddress.getByAddress(bytes));
return;
}
final String hostname = hostname(inetHost);
InetAddress hostsFileEntry = resolveHostsFileEntry(hostname);
if (hostsFileEntry != null) {
promise.setSuccess(hostsFileEntry);
return;
}
if (!doResolveCached(hostname, additionals, promise, resolveCache)) {
doResolveUncached(hostname, additionals, promise, resolveCache, true);
}
}
private boolean doResolveCached(String hostname,
DnsRecord[] additionals,
Promise<InetAddress> promise,
DnsCache resolveCache) {
final List<? extends DnsCacheEntry> cachedEntries = resolveCache.get(hostname, additionals);
if (cachedEntries == null || cachedEntries.isEmpty()) {
return false;
}
Throwable cause = cachedEntries.get(0).cause();
if (cause == null) {
final int numEntries = cachedEntries.size();
// Find the first entry with the preferred address type.
for (InternetProtocolFamily f : resolvedInternetProtocolFamilies) {
for (int i = 0; i < numEntries; i++) {
final DnsCacheEntry e = cachedEntries.get(i);
if (f.addressType().isInstance(e.address())) {
trySuccess(promise, e.address());
return true;
}
}
}
return false;
} else {
tryFailure(promise, cause);
return true;
}
}
static <T> void trySuccess(Promise<T> promise, T result) {
if (!promise.trySuccess(result)) {
// There is nothing really wrong with not be able to notify the promise as we may have raced here because
// of multiple queries that have been executed. Log it with trace level anyway just in case the user
// wants to better understand what happened.
logger.trace("Failed to notify success ({}) to a promise: {}", result, promise);
}
}
private static void tryFailure(Promise<?> promise, Throwable cause) {
if (!promise.tryFailure(cause)) {
// There is nothing really wrong with not be able to notify the promise as we may have raced here because
// of multiple queries that have been executed. Log it with trace level anyway just in case the user
// wants to better understand what happened.
logger.trace("Failed to notify failure to a promise: {}", promise, cause);
}
}
private void doResolveUncached(String hostname,
DnsRecord[] additionals,
final Promise<InetAddress> promise,
DnsCache resolveCache, boolean completeEarlyIfPossible) {
final Promise<List<InetAddress>> allPromise = executor().newPromise();
doResolveAllUncached(hostname, additionals, allPromise, resolveCache, true);
allPromise.addListener(new FutureListener<List<InetAddress>>() {
@Override
public void operationComplete(Future<List<InetAddress>> future) {
if (future.isSuccess()) {
trySuccess(promise, future.getNow().get(0));
} else {
tryFailure(promise, future.cause());
}
}
});
}
@Override
protected void doResolveAll(String inetHost, Promise<List<InetAddress>> promise) throws Exception {
doResolveAll(inetHost, EMPTY_ADDITIONALS, promise, resolveCache);
}
/**
* Hook designed for extensibility so one can pass a different cache on each resolution attempt
* instead of using the global one.
*/
protected void doResolveAll(String inetHost,
DnsRecord[] additionals,
Promise<List<InetAddress>> promise,
DnsCache resolveCache) throws Exception {
if (inetHost == null || inetHost.isEmpty()) {
// If an empty hostname is used we should use "localhost", just like InetAddress.getAllByName(...) does.
promise.setSuccess(Collections.singletonList(loopbackAddress()));
return;
}
final byte[] bytes = NetUtil.createByteArrayFromIpAddressString(inetHost);
if (bytes != null) {
// The unresolvedAddress was created via a String that contains an ipaddress.
promise.setSuccess(Collections.singletonList(InetAddress.getByAddress(bytes)));
return;
}
final String hostname = hostname(inetHost);
InetAddress hostsFileEntry = resolveHostsFileEntry(hostname);
if (hostsFileEntry != null) {
promise.setSuccess(Collections.singletonList(hostsFileEntry));
return;
}
if (!doResolveAllCached(hostname, additionals, promise, resolveCache, resolvedInternetProtocolFamilies)) {
doResolveAllUncached(hostname, additionals, promise, resolveCache, completeOncePreferredResolved);
}
}
static boolean doResolveAllCached(String hostname,
DnsRecord[] additionals,
Promise<List<InetAddress>> promise,
DnsCache resolveCache,
InternetProtocolFamily[] resolvedInternetProtocolFamilies) {
final List<? extends DnsCacheEntry> cachedEntries = resolveCache.get(hostname, additionals);
if (cachedEntries == null || cachedEntries.isEmpty()) {
return false;
}
Throwable cause = cachedEntries.get(0).cause();
if (cause == null) {
List<InetAddress> result = null;
final int numEntries = cachedEntries.size();
for (InternetProtocolFamily f : resolvedInternetProtocolFamilies) {
for (int i = 0; i < numEntries; i++) {
final DnsCacheEntry e = cachedEntries.get(i);
if (f.addressType().isInstance(e.address())) {
if (result == null) {
result = new ArrayList<InetAddress>(numEntries);
}
result.add(e.address());
}
}
}
if (result != null) {
trySuccess(promise, result);
return true;
}
return false;
} else {
tryFailure(promise, cause);
return true;
}
}
private void doResolveAllUncached(final String hostname,
final DnsRecord[] additionals,
final Promise<List<InetAddress>> promise,
final DnsCache resolveCache,
final boolean completeEarlyIfPossible) {
// Call doResolveUncached0(...) in the EventLoop as we may need to submit multiple queries which would need
// to submit multiple Runnable at the end if we are not already on the EventLoop.
EventExecutor executor = executor();
if (executor.inEventLoop()) {
doResolveAllUncached0(hostname, additionals, promise, resolveCache, completeEarlyIfPossible);
} else {
executor.execute(new Runnable() {
@Override
public void run() {
doResolveAllUncached0(hostname, additionals, promise, resolveCache, completeEarlyIfPossible);
}
});
}
}
private void doResolveAllUncached0(String hostname,
DnsRecord[] additionals,
Promise<List<InetAddress>> promise,
DnsCache resolveCache,
boolean completeEarlyIfPossible) {
assert executor().inEventLoop();
final DnsServerAddressStream nameServerAddrs =
dnsServerAddressStreamProvider.nameServerAddressStream(hostname);
new DnsAddressResolveContext(this, hostname, additionals, nameServerAddrs, resolveCache,
authoritativeDnsServerCache, completeEarlyIfPossible).resolve(promise);
}
private static String hostname(String inetHost) {
String hostname = IDN.toASCII(inetHost);
// Check for http://bugs.java.com/bugdatabase/view_bug.do?bug_id=6894622
if (StringUtil.endsWith(inetHost, '.') && !StringUtil.endsWith(hostname, '.')) {
hostname += ".";
}
return hostname;
}
/**
* Sends a DNS query with the specified question.
*/
public Future<AddressedEnvelope<DnsResponse, InetSocketAddress>> query(DnsQuestion question) {
return query(nextNameServerAddress(), question);
}
/**
* Sends a DNS query with the specified question with additional records.
*/
public Future<AddressedEnvelope<DnsResponse, InetSocketAddress>> query(
DnsQuestion question, Iterable<DnsRecord> additionals) {
return query(nextNameServerAddress(), question, additionals);
}
/**
* Sends a DNS query with the specified question.
*/
public Future<AddressedEnvelope<DnsResponse, InetSocketAddress>> query(
DnsQuestion question, Promise<AddressedEnvelope<? extends DnsResponse, InetSocketAddress>> promise) {
return query(nextNameServerAddress(), question, Collections.<DnsRecord>emptyList(), promise);
}
private InetSocketAddress nextNameServerAddress() {
return nameServerAddrStream.get().next();
}
/**
* Sends a DNS query with the specified question using the specified name server list.
*/
public Future<AddressedEnvelope<DnsResponse, InetSocketAddress>> query(
InetSocketAddress nameServerAddr, DnsQuestion question) {
return query0(nameServerAddr, question, EMPTY_ADDITIONALS, true, ch.newPromise(),
ch.eventLoop().<AddressedEnvelope<? extends DnsResponse, InetSocketAddress>>newPromise());
}
/**
* Sends a DNS query with the specified question with additional records using the specified name server list.
*/
public Future<AddressedEnvelope<DnsResponse, InetSocketAddress>> query(
InetSocketAddress nameServerAddr, DnsQuestion question, Iterable<DnsRecord> additionals) {
return query0(nameServerAddr, question, toArray(additionals, false), true, ch.newPromise(),
ch.eventLoop().<AddressedEnvelope<? extends DnsResponse, InetSocketAddress>>newPromise());
}
/**
* Sends a DNS query with the specified question using the specified name server list.
*/
public Future<AddressedEnvelope<DnsResponse, InetSocketAddress>> query(
InetSocketAddress nameServerAddr, DnsQuestion question,
Promise<AddressedEnvelope<? extends DnsResponse, InetSocketAddress>> promise) {
return query0(nameServerAddr, question, EMPTY_ADDITIONALS, true, ch.newPromise(), promise);
}
/**
* Sends a DNS query with the specified question with additional records using the specified name server list.
*/
public Future<AddressedEnvelope<DnsResponse, InetSocketAddress>> query(
InetSocketAddress nameServerAddr, DnsQuestion question,
Iterable<DnsRecord> additionals,
Promise<AddressedEnvelope<? extends DnsResponse, InetSocketAddress>> promise) {
return query0(nameServerAddr, question, toArray(additionals, false), true, ch.newPromise(), promise);
}
/**
* Returns {@code true} if the {@link Throwable} was caused by an timeout or transport error.
* These methods can be used on the {@link Future#cause()} that is returned by the various methods exposed by this
* {@link DnsNameResolver}.
*/
public static boolean isTransportOrTimeoutError(Throwable cause) {
return cause != null && cause.getCause() instanceof DnsNameResolverException;
}
/**
* Returns {@code true} if the {@link Throwable} was caused by an timeout.
* These methods can be used on the {@link Future#cause()} that is returned by the various methods exposed by this
* {@link DnsNameResolver}.
*/
public static boolean isTimeoutError(Throwable cause) {
return cause != null && cause.getCause() instanceof DnsNameResolverTimeoutException;
}
final void flushQueries() {
ch.flush();
}
final Future<AddressedEnvelope<DnsResponse, InetSocketAddress>> query0(
InetSocketAddress nameServerAddr, DnsQuestion question,
DnsRecord[] additionals,
boolean flush,
ChannelPromise writePromise,
Promise<AddressedEnvelope<? extends DnsResponse, InetSocketAddress>> promise) {
assert !writePromise.isVoid();
final Promise<AddressedEnvelope<DnsResponse, InetSocketAddress>> castPromise = cast(
checkNotNull(promise, "promise"));
try {
new DatagramDnsQueryContext(this, nameServerAddr, question, additionals, castPromise)
.query(flush, writePromise);
return castPromise;
} catch (Exception e) {
return castPromise.setFailure(e);
}
}
@SuppressWarnings("unchecked")
private static Promise<AddressedEnvelope<DnsResponse, InetSocketAddress>> cast(Promise<?> promise) {
return (Promise<AddressedEnvelope<DnsResponse, InetSocketAddress>>) promise;
}
final DnsServerAddressStream newNameServerAddressStream(String hostname) {
return dnsServerAddressStreamProvider.nameServerAddressStream(hostname);
}
private final class DnsResponseHandler extends ChannelInboundHandlerAdapter {
private final Promise<Channel> channelActivePromise;
DnsResponseHandler(Promise<Channel> channelActivePromise) {
this.channelActivePromise = channelActivePromise;
}
@Override
public void channelRead(ChannelHandlerContext ctx, Object msg) {
try {
final DatagramDnsResponse res = (DatagramDnsResponse) msg;
final int queryId = res.id();
if (logger.isDebugEnabled()) {
logger.debug("{} RECEIVED: UDP [{}: {}], {}", ch, queryId, res.sender(), res);
}
final DnsQueryContext qCtx = queryContextManager.get(res.sender(), queryId);
if (qCtx == null) {
logger.warn("{} Received a DNS response with an unknown ID: {}", ch, queryId);
return;
}
// Check if the response was truncated and if we can fallback to TCP to retry.
if (res.isTruncated() && socketChannelFactory != null) {
// Let's retain as we may need it later on.
res.retain();
Bootstrap bs = new Bootstrap();
bs.option(ChannelOption.SO_REUSEADDR, true)
.group(executor())
.channelFactory(socketChannelFactory)
.handler(new ChannelInitializer<Channel>() {
@Override
protected void initChannel(Channel ch) {
ch.pipeline().addLast(TCP_ENCODER);
ch.pipeline().addLast(new TcpDnsResponseDecoder());
ch.pipeline().addLast(new ChannelInboundHandlerAdapter() {
private boolean finish;
@Override
public void channelRead(ChannelHandlerContext ctx, Object msg) {
try {
Channel channel = ctx.channel();
DnsResponse response = (DnsResponse) msg;
int queryId = response.id();
if (logger.isDebugEnabled()) {
logger.debug("{} RECEIVED: TCP [{}: {}], {}", channel, queryId,
channel.remoteAddress(), response);
}
DnsQueryContext tcpCtx = queryContextManager.get(res.sender(), queryId);
if (tcpCtx == null) {
logger.warn("{} Received a DNS response with an unknown ID: {}",
channel, queryId);
qCtx.finish(res);
return;
}
// Release the original response as we will use the response that we
// received via TCP fallback.
res.release();
tcpCtx.finish(new AddressedEnvelopeAdapter(
(InetSocketAddress) ctx.channel().remoteAddress(),
(InetSocketAddress) ctx.channel().localAddress(),
response));
finish = true;
} finally {
ReferenceCountUtil.release(msg);
}
}
@Override
public void exceptionCaught(ChannelHandlerContext ctx, Throwable cause) {
if (!finish) {
if (logger.isDebugEnabled()) {
logger.debug("{} Error during processing response: TCP [{}: {}]",
ctx.channel(), queryId,
ctx.channel().remoteAddress(), cause);
}
// TCP fallback failed, just use the truncated response as
qCtx.finish(res);
}
}
});
}
});
bs.connect(res.sender()).addListener(new ChannelFutureListener() {
@Override
public void operationComplete(ChannelFuture future) {
if (future.isSuccess()) {
final Channel channel = future.channel();
Promise<AddressedEnvelope<DnsResponse, InetSocketAddress>> promise =
channel.eventLoop().newPromise();
new TcpDnsQueryContext(DnsNameResolver.this, channel,
(InetSocketAddress) channel.remoteAddress(), qCtx.question(),
EMPTY_ADDITIONALS, promise).query(true, future.channel().newPromise());
promise.addListener(
new FutureListener<AddressedEnvelope<DnsResponse, InetSocketAddress>>() {
@Override
public void operationComplete(
Future<AddressedEnvelope<DnsResponse, InetSocketAddress>> future) {
channel.close();
if (future.isSuccess()) {
qCtx.finish(future.getNow());
} else {
// TCP fallback failed, just use the truncated response.
qCtx.finish(res);
}
}
});
} else {
if (logger.isDebugEnabled()) {
logger.debug("{} Unable to fallback to TCP [{}]", queryId, future.cause());
}
// TCP fallback failed, just use the truncated response.
qCtx.finish(res);
}
}
});
} else {
qCtx.finish(res);
}
} finally {
ReferenceCountUtil.safeRelease(msg);
}
}
@Override
public void channelActive(ChannelHandlerContext ctx) throws Exception {
super.channelActive(ctx);
channelActivePromise.setSuccess(ctx.channel());
}
@Override
public void exceptionCaught(ChannelHandlerContext ctx, Throwable cause) {
logger.warn("{} Unexpected exception: ", ctx.channel(), cause);
}
}
private final class AddressedEnvelopeAdapter implements AddressedEnvelope<DnsResponse, InetSocketAddress> {
private final InetSocketAddress sender;
private final InetSocketAddress recipient;
private final DnsResponse response;
AddressedEnvelopeAdapter(InetSocketAddress sender, InetSocketAddress recipient, DnsResponse response) {
this.sender = sender;
this.recipient = recipient;
this.response = response;
}
@Override
public DnsResponse content() {
return response;
}
@Override
public InetSocketAddress sender() {
return sender;
}
@Override
public InetSocketAddress recipient() {
return recipient;
}
@Override
public AddressedEnvelope<DnsResponse, InetSocketAddress> retain() {
response.retain();
return this;
}
@Override
public AddressedEnvelope<DnsResponse, InetSocketAddress> retain(int increment) {
response.retain(increment);
return this;
}
@Override
public AddressedEnvelope<DnsResponse, InetSocketAddress> touch() {
response.touch();
return this;
}
@Override
public AddressedEnvelope<DnsResponse, InetSocketAddress> touch(Object hint) {
response.touch(hint);
return this;
}
@Override
public int refCnt() {
return response.refCnt();
}
@Override
public boolean release() {
return response.release();
}
@Override
public boolean release(int decrement) {
return response.release(decrement);
}
@Override
public boolean equals(Object obj) {
if (this == obj) {
return true;
}
if (!(obj instanceof AddressedEnvelope)) {
return false;
}
@SuppressWarnings("unchecked")
final AddressedEnvelope<?, SocketAddress> that = (AddressedEnvelope<?, SocketAddress>) obj;
if (sender() == null) {
if (that.sender() != null) {
return false;
}
} else if (!sender().equals(that.sender())) {
return false;
}
if (recipient() == null) {
if (that.recipient() != null) {
return false;
}
} else if (!recipient().equals(that.recipient())) {
return false;
}
return response.equals(obj);
}
@Override
public int hashCode() {
int hashCode = response.hashCode();
if (sender() != null) {
hashCode = hashCode * 31 + sender().hashCode();
}
if (recipient() != null) {
hashCode = hashCode * 31 + recipient().hashCode();
}
return hashCode;
}
}
}