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/*
 * JBoss, Home of Professional Open Source.
 * Copyright 2014 Red Hat, Inc., and individual contributors
 * as indicated by the @author tags.
 *
 * Licensed 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.undertow.server;

import io.undertow.UndertowLogger;
import io.undertow.UndertowMessages;
import io.undertow.UndertowOptions;
import io.undertow.channels.DetachableStreamSinkChannel;
import io.undertow.channels.DetachableStreamSourceChannel;
import io.undertow.conduits.EmptyStreamSourceConduit;
import io.undertow.connector.PooledByteBuffer;
import io.undertow.io.AsyncReceiverImpl;
import io.undertow.io.AsyncSenderImpl;
import io.undertow.io.BlockingReceiverImpl;
import io.undertow.io.BlockingSenderImpl;
import io.undertow.io.Receiver;
import io.undertow.io.Sender;
import io.undertow.io.UndertowInputStream;
import io.undertow.io.UndertowOutputStream;
import io.undertow.security.api.SecurityContext;
import io.undertow.server.handlers.Cookie;
import io.undertow.util.AbstractAttachable;
import io.undertow.util.AttachmentKey;
import io.undertow.util.ConduitFactory;
import io.undertow.util.Cookies;
import io.undertow.util.HeaderMap;
import io.undertow.util.Headers;
import io.undertow.util.HttpString;
import io.undertow.util.Methods;
import io.undertow.util.NetworkUtils;
import io.undertow.util.Protocols;
import io.undertow.util.Rfc6265CookieSupport;
import io.undertow.util.StatusCodes;
import org.jboss.logging.Logger;
import org.xnio.Buffers;
import org.xnio.ChannelExceptionHandler;
import org.xnio.ChannelListener;
import org.xnio.ChannelListeners;
import org.xnio.IoUtils;
import org.xnio.XnioIoThread;
import org.xnio.channels.Channels;
import org.xnio.channels.Configurable;
import org.xnio.channels.StreamSinkChannel;
import org.xnio.channels.StreamSourceChannel;
import org.xnio.conduits.Conduit;
import org.xnio.conduits.ConduitStreamSinkChannel;
import org.xnio.conduits.ConduitStreamSourceChannel;
import org.xnio.conduits.StreamSinkConduit;
import org.xnio.conduits.StreamSourceConduit;

import java.io.IOException;
import java.io.InputStream;
import java.io.OutputStream;
import java.net.InetSocketAddress;
import java.nio.ByteBuffer;
import java.nio.channels.Channel;
import java.nio.channels.FileChannel;
import java.util.ArrayDeque;
import java.util.Deque;
import java.util.Map;
import java.util.Set;
import java.util.TreeMap;
import java.util.concurrent.Executor;
import java.util.concurrent.TimeUnit;

import static org.xnio.Bits.allAreSet;
import static org.xnio.Bits.anyAreClear;
import static org.xnio.Bits.anyAreSet;
import static org.xnio.Bits.intBitMask;

/**
 * An HTTP server request/response exchange.  An instance of this class is constructed as soon as the request headers are
 * fully parsed.
 *
 * @author David M. Lloyd
 * @author Richard Opalka
 */
public final class HttpServerExchange extends AbstractAttachable {

    // immutable state

    private static final Logger log = Logger.getLogger(HttpServerExchange.class);

    private static final RuntimePermission SET_SECURITY_CONTEXT = new RuntimePermission("io.undertow.SET_SECURITY_CONTEXT");
    private static final String ISO_8859_1 = "ISO-8859-1";
    private static final String HTTPS = "https";

    /**
     * The HTTP reason phrase to send. This is an attachment rather than a field as it is rarely used. If this is not set
     * a generic description from the RFC is used instead.
     */
    private static final AttachmentKey REASON_PHRASE = AttachmentKey.create(String.class);

    /**
     * The attachment key that buffered request data is attached under.
     */
    static final AttachmentKey BUFFERED_REQUEST_DATA = AttachmentKey.create(PooledByteBuffer[].class);

    /**
     * Attachment key that can be used to hold additional request attributes
     */
    public static final AttachmentKey> REQUEST_ATTRIBUTES = AttachmentKey.create(Map.class);

    /**
     * Attachment key that can be used to hold a remotely authenticated user
     */
    public static final AttachmentKey REMOTE_USER = AttachmentKey.create(String.class);


    /**
     * Attachment key that can be used as a flag of secure attribute
     */
    public static final AttachmentKey SECURE_REQUEST = AttachmentKey.create(Boolean.class);

    private final ServerConnection connection;
    private final HeaderMap requestHeaders;
    private final HeaderMap responseHeaders;

    private int exchangeCompletionListenersCount = 0;
    private ExchangeCompletionListener[] exchangeCompleteListeners;
    private DefaultResponseListener[] defaultResponseListeners;

    private Map> queryParameters;
    private Map> pathParameters;

    private DelegatingIterable requestCookies;
    private DelegatingIterable responseCookies;

    private Map deprecatedRequestCookies;
    private Map deprecatedResponseCookies;

    /**
     * The actual response channel. May be null if it has not been created yet.
     */
    private WriteDispatchChannel responseChannel;
    /**
     * The actual request channel. May be null if it has not been created yet.
     */
    protected ReadDispatchChannel requestChannel;

    private BlockingHttpExchange blockingHttpExchange;

    private HttpString protocol;

    /**
     * The security context
     */
    private SecurityContext securityContext;

    // mutable state

    private int state = 200;
    private HttpString requestMethod = HttpString.EMPTY;
    private String requestScheme;

    /**
     * The original request URI. This will include the host name if it was specified by the client.
     * 

* This is not decoded in any way, and does not include the query string. *

* Examples: * GET http://localhost:8080/myFile.jsf?foo=bar HTTP/1.1 -> 'http://localhost:8080/myFile.jsf' * POST /my+File.jsf?foo=bar HTTP/1.1 -> '/my+File.jsf' */ private String requestURI; /** * The request path. This will be decoded by the server, and does not include the query string. *

* This path is not canonicalised, so care must be taken to ensure that escape attacks are not possible. *

* Examples: * GET http://localhost:8080/b/../my+File.jsf?foo=bar HTTP/1.1 -> '/b/../my+File.jsf' * POST /my+File.jsf?foo=bar HTTP/1.1 -> '/my File.jsf' */ private String requestPath; /** * The remaining unresolved portion of request path. If a {@link io.undertow.server.handlers.CanonicalPathHandler} is * installed this will be canonicalised. *

* Initially this will be equal to {@link #requestPath}, however it will be modified as handlers resolve the path. */ private String relativePath; /** * The resolved part of the canonical path. */ private String resolvedPath = ""; /** * the query string */ private String queryString = ""; private int requestWrapperCount = 0; private ConduitWrapper[] requestWrappers; //we don't allocate these by default, as for get requests they are not used private int responseWrapperCount = 0; private ConduitWrapper[] responseWrappers; private Sender sender; private Receiver receiver; private long requestStartTime = -1; /** * The maximum entity size. This can be modified before the request stream is obtained, however once the request * stream is obtained this cannot be modified further. *

* The default value for this is determined by the {@link io.undertow.UndertowOptions#MAX_ENTITY_SIZE} option. A value * of 0 indicates that this is unbounded. *

* In case of multipart handling, this will default to {@link io.undertow.UndertowOptions#MULTIPART_MAX_ENTITY_SIZE} *

* If this entity size is exceeded the request channel will be forcibly closed. *

* TODO: integrate this with HTTP 100-continue responses, to make it possible to send a 417 rather than just forcibly * closing the channel. * * @see io.undertow.UndertowOptions#MAX_ENTITY_SIZE * @see io.undertow.UndertowOptions#MULTIPART_MAX_ENTITY_SIZE */ private long maxEntitySize; /** * When the call stack return this task will be executed by the executor specified in {@link #dispatchExecutor}. * If the executor is null then it will be executed by the XNIO worker. */ private Runnable dispatchTask; /** * The executor that is to be used to dispatch the {@link #dispatchTask}. Note that this is not cleared * between dispatches, so once a request has been dispatched once then all subsequent dispatches will use * the same executor. */ private Executor dispatchExecutor; /** * The number of bytes that have been sent to the remote client. This does not include headers, * only the entity body, and does not take any transfer or content encoding into account. */ private long responseBytesSent = 0; private static final int MASK_RESPONSE_CODE = intBitMask(0, 9); /** * Flag that is set when the response sending begins */ private static final int FLAG_RESPONSE_SENT = 1 << 10; /** * Flag that is sent when the response has been fully written and flushed. */ private static final int FLAG_RESPONSE_TERMINATED = 1 << 11; /** * Flag that is set once the request has been fully read. For zero * length requests this is set immediately. */ private static final int FLAG_REQUEST_TERMINATED = 1 << 12; /** * Flag that is set if this is a persistent connection, and the * connection should be re-used. */ private static final int FLAG_PERSISTENT = 1 << 14; /** * If this flag is set it means that the request has been dispatched, * and will not be ending when the call stack returns. *

* This could be because it is being dispatched to a worker thread from * an IO thread, or because resume(Reads/Writes) has been called. */ private static final int FLAG_DISPATCHED = 1 << 15; /** * Flag that is set if the {@link #requestURI} field contains the hostname. */ private static final int FLAG_URI_CONTAINS_HOST = 1 << 16; /** * If this flag is set then the request is current running through a * handler chain. *

* This will be true most of the time, this only time this will return * false is when performing async operations outside the scope of a call to * {@link Connectors#executeRootHandler(HttpHandler, HttpServerExchange)}, * such as when performing async IO. *

* If this is true then when the call stack returns the exchange will either be dispatched, * or the exchange will be ended. */ private static final int FLAG_IN_CALL = 1 << 17; /** * Flag that indicates that reads should be resumed when the call stack returns. */ private static final int FLAG_SHOULD_RESUME_READS = 1 << 18; /** * Flag that indicates that writes should be resumed when the call stack returns */ private static final int FLAG_SHOULD_RESUME_WRITES = 1 << 19; /** * Flag that indicates that the request channel has been reset, and {@link #getRequestChannel()} can be called again */ private static final int FLAG_REQUEST_RESET= 1 << 20; /** * The source address for the request. If this is null then the actual source address from the channel is used */ private InetSocketAddress sourceAddress; /** * The destination address for the request. If this is null then the actual source address from the channel is used */ private InetSocketAddress destinationAddress; public HttpServerExchange(final ServerConnection connection, long maxEntitySize) { this(connection, new HeaderMap(), new HeaderMap(), maxEntitySize); } public HttpServerExchange(final ServerConnection connection) { this(connection, 0); } public HttpServerExchange(final ServerConnection connection, final HeaderMap requestHeaders, final HeaderMap responseHeaders, long maxEntitySize) { this.connection = connection; this.maxEntitySize = maxEntitySize; this.requestHeaders = requestHeaders; this.responseHeaders = responseHeaders; } /** * Get the request protocol string. Normally this is one of the strings listed in {@link Protocols}. * * @return the request protocol string */ public HttpString getProtocol() { return protocol; } /** * Sets the http protocol * * @param protocol */ public HttpServerExchange setProtocol(final HttpString protocol) { this.protocol = protocol; return this; } /** * Determine whether this request conforms to HTTP 0.9. * * @return {@code true} if the request protocol is equal to {@link Protocols#HTTP_0_9}, {@code false} otherwise */ public boolean isHttp09() { return protocol.equals(Protocols.HTTP_0_9); } /** * Determine whether this request conforms to HTTP 1.0. * * @return {@code true} if the request protocol is equal to {@link Protocols#HTTP_1_0}, {@code false} otherwise */ public boolean isHttp10() { return protocol.equals(Protocols.HTTP_1_0); } /** * Determine whether this request conforms to HTTP 1.1. * * @return {@code true} if the request protocol is equal to {@link Protocols#HTTP_1_1}, {@code false} otherwise */ public boolean isHttp11() { return protocol.equals(Protocols.HTTP_1_1); } public boolean isSecure() { Boolean secure = getAttachment(SECURE_REQUEST); if(secure != null && secure) { return true; } String scheme = getRequestScheme(); if (scheme != null && scheme.equalsIgnoreCase(HTTPS)) { return true; } return false; } /** * Get the HTTP request method. Normally this is one of the strings listed in {@link io.undertow.util.Methods}. * * @return the HTTP request method */ public HttpString getRequestMethod() { return requestMethod; } /** * Set the HTTP request method. * * @param requestMethod the HTTP request method */ public HttpServerExchange setRequestMethod(final HttpString requestMethod) { this.requestMethod = requestMethod; return this; } /** * Get the request URI scheme. Normally this is one of {@code http} or {@code https}. * * @return the request URI scheme */ public String getRequestScheme() { return requestScheme; } /** * Set the request URI scheme. * * @param requestScheme the request URI scheme */ public HttpServerExchange setRequestScheme(final String requestScheme) { this.requestScheme = requestScheme; return this; } /** * The original request URI. This will include the host name, protocol etc * if it was specified by the client. *

* This is not decoded in any way, and does not include the query string. *

* Examples: * GET http://localhost:8080/myFile.jsf?foo=bar HTTP/1.1 -> 'http://localhost:8080/myFile.jsf' * POST /my+File.jsf?foo=bar HTTP/1.1 -> '/my+File.jsf' */ public String getRequestURI() { return requestURI; } /** * Sets the request URI * * @param requestURI The new request URI */ public HttpServerExchange setRequestURI(final String requestURI) { this.requestURI = requestURI; return this; } /** * Sets the request URI * * @param requestURI The new request URI * @param containsHost If this is true the request URI contains the host part */ public HttpServerExchange setRequestURI(final String requestURI, boolean containsHost) { this.requestURI = requestURI; if (containsHost) { this.state |= FLAG_URI_CONTAINS_HOST; } else { this.state &= ~FLAG_URI_CONTAINS_HOST; } return this; } /** * If a request was submitted to the server with a full URI instead of just a path this * will return true. For example: *

* GET http://localhost:8080/b/../my+File.jsf?foo=bar HTTP/1.1 -> true * POST /my+File.jsf?foo=bar HTTP/1.1 -> false * * @return true If the request URI contains the host part of the URI */ public boolean isHostIncludedInRequestURI() { return anyAreSet(state, FLAG_URI_CONTAINS_HOST); } /** * The request path. This will be decoded by the server, and does not include the query string. *

* This path is not canonicalised, so care must be taken to ensure that escape attacks are not possible. *

* Examples: * GET http://localhost:8080/b/../my+File.jsf?foo=bar HTTP/1.1 -> '/b/../my+File.jsf' * POST /my+File.jsf?foo=bar HTTP/1.1 -> '/my File.jsf' */ public String getRequestPath() { return requestPath; } /** * Set the request URI path. * * @param requestPath the request URI path */ public HttpServerExchange setRequestPath(final String requestPath) { this.requestPath = requestPath; return this; } /** * Get the request relative path. This is the path which should be evaluated by the current handler. *

* If the {@link io.undertow.server.handlers.CanonicalPathHandler} is installed in the current chain * then this path with be canonicalized * * @return the request relative path */ public String getRelativePath() { return relativePath; } /** * Set the request relative path. * * @param relativePath the request relative path */ public HttpServerExchange setRelativePath(final String relativePath) { this.relativePath = relativePath; return this; } /** * Get the resolved path. * * @return the resolved path */ public String getResolvedPath() { return resolvedPath; } /** * Set the resolved path. * * @param resolvedPath the resolved path */ public HttpServerExchange setResolvedPath(final String resolvedPath) { this.resolvedPath = resolvedPath; return this; } /** * * @return The query string, without the leading ? */ public String getQueryString() { return queryString; } /** * Set query string. Leading ? char will be removed automatically. */ public HttpServerExchange setQueryString(final String queryString) { // Clean leading ? if( queryString.length() > 0 && queryString.charAt(0) == '?' ) { this.queryString = queryString.substring(1); } else { this.queryString = queryString; } return this; } /** * Reconstructs the complete URL as seen by the user. This includes scheme, host name etc, * but does not include query string. *

* This is not decoded. */ public String getRequestURL() { if (isHostIncludedInRequestURI()) { return getRequestURI(); } else { return getRequestScheme() + "://" + getHostAndPort() + getRequestURI(); } } /** * Returns the request charset. If none was explicitly specified it will return * "ISO-8859-1", which is the default charset for HTTP requests. * * @return The character encoding */ public String getRequestCharset() { return extractCharset(requestHeaders); } /** * Returns the response charset. If none was explicitly specified it will return * "ISO-8859-1", which is the default charset for HTTP requests. * * @return The character encoding */ public String getResponseCharset() { HeaderMap headers = responseHeaders; return extractCharset(headers); } private String extractCharset(HeaderMap headers) { String contentType = headers.getFirst(Headers.CONTENT_TYPE); if (contentType != null) { String value = Headers.extractQuotedValueFromHeader(contentType, "charset"); if (value != null) { return value; } } return ISO_8859_1; } /** * Return the host that this request was sent to, in general this will be the * value of the Host header, minus the port specifier. *

* If this resolves to an IPv6 address it will not be enclosed by square brackets. * Care must be taken when constructing URLs based on this method to ensure IPv6 URLs * are handled correctly. * * @return The host part of the destination address */ public String getHostName() { String host = requestHeaders.getFirst(Headers.HOST); if (host == null || "".equals(host.trim())) { host = getDestinationAddress().getHostString(); } else { if (host.startsWith("[")) { host = host.substring(1, host.indexOf(']')); } else if (host.indexOf(':') != -1) { host = host.substring(0, host.indexOf(':')); } } return host; } /** * Return the host, and also the port if this request was sent to a non-standard port. In general * this will just be the value of the Host header. *

* If this resolves to an IPv6 address it *will* be enclosed by square brackets. The return * value of this method is suitable for inclusion in a URL. * * @return The host and port part of the destination address */ public String getHostAndPort() { String host = requestHeaders.getFirst(Headers.HOST); if (host == null || "".equals(host.trim())) { InetSocketAddress address = getDestinationAddress(); host = NetworkUtils.formatPossibleIpv6Address(address.getHostString()); int port = address.getPort(); if (!((getRequestScheme().equals("http") && port == 80) || (getRequestScheme().equals("https") && port == 443))) { host = host + ":" + port; } } return host; } /** * Return the port that this request was sent to. In general this will be the value of the Host * header, minus the host name. * * @return The port part of the destination address */ public int getHostPort() { String host = requestHeaders.getFirst(Headers.HOST); if (host != null) { //for ipv6 addresses we make sure we take out the first part, which can have multiple occurrences of : final int colonIndex; if (host.startsWith("[")) { colonIndex = host.indexOf(':', host.indexOf(']')); } else { colonIndex = host.indexOf(':'); } if (colonIndex != -1) { try { return Integer.parseInt(host.substring(colonIndex + 1)); } catch (NumberFormatException ignore) {} } if (getRequestScheme().equals("https")) { return 443; } else if (getRequestScheme().equals("http")) { return 80; } } return getDestinationAddress().getPort(); } /** * Get the underlying HTTP connection. * * @return the underlying HTTP connection */ public ServerConnection getConnection() { return connection; } public boolean isPersistent() { return anyAreSet(state, FLAG_PERSISTENT); } /** * * @return true If the current thread in the IO thread for the exchange */ public boolean isInIoThread() { return getIoThread() == Thread.currentThread(); } /** * * @return True if this exchange represents an upgrade response */ public boolean isUpgrade() { return getStatusCode() == StatusCodes.SWITCHING_PROTOCOLS; } /** * * @return The number of bytes sent in the entity body */ public long getResponseBytesSent() { if(Connectors.isEntityBodyAllowed(this) && !getRequestMethod().equals(Methods.HEAD)) { return responseBytesSent; } else { return 0; //body is not allowed, even if we attempt to write it will be ignored } } /** * Updates the number of response bytes sent. Used when compression is in use * @param bytes The number of bytes to increase the response size by. May be negative */ void updateBytesSent(long bytes) { if(Connectors.isEntityBodyAllowed(this) && !getRequestMethod().equals(Methods.HEAD)) { responseBytesSent += bytes; } } public HttpServerExchange setPersistent(final boolean persistent) { if (persistent) { this.state = this.state | FLAG_PERSISTENT; } else { this.state = this.state & ~FLAG_PERSISTENT; } return this; } public boolean isDispatched() { return anyAreSet(state, FLAG_DISPATCHED); } public HttpServerExchange unDispatch() { state &= ~FLAG_DISPATCHED; dispatchTask = null; return this; } /** * {@link #dispatch(Executor, Runnable)} should be used instead of this method, as it is hard to use safely. * * Use {@link io.undertow.util.SameThreadExecutor#INSTANCE} if you do not want to dispatch to another thread. * * @return this exchange */ @Deprecated public HttpServerExchange dispatch() { state |= FLAG_DISPATCHED; return this; } /** * Dispatches this request to the XNIO worker thread pool. Once the call stack returns * the given runnable will be submitted to the executor. *

* In general handlers should first check the value of {@link #isInIoThread()} before * calling this method, and only dispatch if the request is actually running in the IO * thread. * * @param runnable The task to run * @throws IllegalStateException If this exchange has already been dispatched */ public HttpServerExchange dispatch(final Runnable runnable) { dispatch(null, runnable); return this; } /** * Dispatches this request to the given executor. Once the call stack returns * the given runnable will be submitted to the executor. *

* In general handlers should first check the value of {@link #isInIoThread()} before * calling this method, and only dispatch if the request is actually running in the IO * thread. * * @param runnable The task to run * @throws IllegalStateException If this exchange has already been dispatched */ public HttpServerExchange dispatch(final Executor executor, final Runnable runnable) { if (isInCall()) { if (executor != null) { this.dispatchExecutor = executor; } state |= FLAG_DISPATCHED; if(anyAreSet(state, FLAG_SHOULD_RESUME_READS | FLAG_SHOULD_RESUME_WRITES)) { throw UndertowMessages.MESSAGES.resumedAndDispatched(); } this.dispatchTask = runnable; } else { if (executor == null) { getConnection().getWorker().execute(runnable); } else { executor.execute(runnable); } } return this; } public HttpServerExchange dispatch(final HttpHandler handler) { dispatch(null, handler); return this; } public HttpServerExchange dispatch(final Executor executor, final HttpHandler handler) { final Runnable runnable = new Runnable() { @Override public void run() { Connectors.executeRootHandler(handler, HttpServerExchange.this); } }; dispatch(executor, runnable); return this; } /** * Sets the executor that is used for dispatch operations where no executor is specified. * * @param executor The executor to use */ public HttpServerExchange setDispatchExecutor(final Executor executor) { if (executor == null) { dispatchExecutor = null; } else { dispatchExecutor = executor; } return this; } /** * Gets the current executor that is used for dispatch operations. This may be null * * @return The current dispatch executor */ public Executor getDispatchExecutor() { return dispatchExecutor; } /** * @return The current dispatch task */ Runnable getDispatchTask() { return dispatchTask; } boolean isInCall() { return anyAreSet(state, FLAG_IN_CALL); } HttpServerExchange setInCall(boolean value) { if (value) { state |= FLAG_IN_CALL; } else { state &= ~FLAG_IN_CALL; } return this; } /** * Upgrade the channel to a raw socket. This method set the response code to 101, and then marks both the * request and response as terminated, which means that once the current request is completed the raw channel * can be obtained from {@link io.undertow.server.protocol.http.HttpServerConnection#getChannel()} * * @throws IllegalStateException if a response or upgrade was already sent, or if the request body is already being * read */ public HttpServerExchange upgradeChannel(final HttpUpgradeListener listener) { if (!connection.isUpgradeSupported()) { throw UndertowMessages.MESSAGES.upgradeNotSupported(); } if(!getRequestHeaders().contains(Headers.UPGRADE)) { throw UndertowMessages.MESSAGES.notAnUpgradeRequest(); } UndertowLogger.REQUEST_LOGGER.debugf("Upgrading request %s", this); connection.setUpgradeListener(listener); setStatusCode(StatusCodes.SWITCHING_PROTOCOLS); getResponseHeaders().put(Headers.CONNECTION, Headers.UPGRADE_STRING); return this; } /** * Upgrade the channel to a raw socket. This method set the response code to 101, and then marks both the * request and response as terminated, which means that once the current request is completed the raw channel * can be obtained from {@link io.undertow.server.protocol.http.HttpServerConnection#getChannel()} * * @param productName the product name to report to the client * @throws IllegalStateException if a response or upgrade was already sent, or if the request body is already being * read */ public HttpServerExchange upgradeChannel(String productName, final HttpUpgradeListener listener) { if (!connection.isUpgradeSupported()) { throw UndertowMessages.MESSAGES.upgradeNotSupported(); } UndertowLogger.REQUEST_LOGGER.debugf("Upgrading request %s", this); connection.setUpgradeListener(listener); setStatusCode(StatusCodes.SWITCHING_PROTOCOLS); final HeaderMap headers = getResponseHeaders(); headers.put(Headers.UPGRADE, productName); headers.put(Headers.CONNECTION, Headers.UPGRADE_STRING); return this; } /** * * @param connectListener * @return */ public HttpServerExchange acceptConnectRequest(HttpUpgradeListener connectListener) { if(!getRequestMethod().equals(Methods.CONNECT)) { throw UndertowMessages.MESSAGES.notAConnectRequest(); } connection.setConnectListener(connectListener); return this; } public HttpServerExchange addExchangeCompleteListener(final ExchangeCompletionListener listener) { if(isComplete() || this.exchangeCompletionListenersCount == -1) { throw UndertowMessages.MESSAGES.exchangeAlreadyComplete(); } final int exchangeCompletionListenersCount = this.exchangeCompletionListenersCount++; ExchangeCompletionListener[] exchangeCompleteListeners = this.exchangeCompleteListeners; if (exchangeCompleteListeners == null || exchangeCompleteListeners.length == exchangeCompletionListenersCount) { ExchangeCompletionListener[] old = exchangeCompleteListeners; this.exchangeCompleteListeners = exchangeCompleteListeners = new ExchangeCompletionListener[exchangeCompletionListenersCount + 2]; if(old != null) { System.arraycopy(old, 0, exchangeCompleteListeners, 0, exchangeCompletionListenersCount); } } exchangeCompleteListeners[exchangeCompletionListenersCount] = listener; return this; } public HttpServerExchange addDefaultResponseListener(final DefaultResponseListener listener) { int i = 0; if(defaultResponseListeners == null) { defaultResponseListeners = new DefaultResponseListener[2]; } else { while (i != defaultResponseListeners.length && defaultResponseListeners[i] != null) { ++i; } if (i == defaultResponseListeners.length) { DefaultResponseListener[] old = defaultResponseListeners; defaultResponseListeners = new DefaultResponseListener[defaultResponseListeners.length + 2]; System.arraycopy(old, 0, defaultResponseListeners, 0, old.length); } } defaultResponseListeners[i] = listener; return this; } /** * Get the source address of the HTTP request. * * @return the source address of the HTTP request */ public InetSocketAddress getSourceAddress() { if (sourceAddress != null) { return sourceAddress; } return connection.getPeerAddress(InetSocketAddress.class); } /** * Sets the source address of the HTTP request. If this is not explicitly set * the actual source address of the channel is used. * * @param sourceAddress The address */ public HttpServerExchange setSourceAddress(InetSocketAddress sourceAddress) { this.sourceAddress = sourceAddress; return this; } /** * Get the destination address of the HTTP request. * * @return the destination address of the HTTP request */ public InetSocketAddress getDestinationAddress() { if (destinationAddress != null) { return destinationAddress; } return connection.getLocalAddress(InetSocketAddress.class); } /** * Sets the destination address of the HTTP request. If this is not explicitly set * the actual destination address of the channel is used. * * @param destinationAddress The address */ public HttpServerExchange setDestinationAddress(InetSocketAddress destinationAddress) { this.destinationAddress = destinationAddress; return this; } /** * Get the request headers. * * @return the request headers */ public HeaderMap getRequestHeaders() { return requestHeaders; } /** * @return The content length of the request, or -1 if it has not been set */ public long getRequestContentLength() { String contentLengthString = requestHeaders.getFirst(Headers.CONTENT_LENGTH); if (contentLengthString == null) { return -1; } return Long.parseLong(contentLengthString); } /** * Get the response headers. * * @return the response headers */ public HeaderMap getResponseHeaders() { return responseHeaders; } /** * @return The content length of the response, or -1 if it has not been set */ public long getResponseContentLength() { String contentLengthString = responseHeaders.getFirst(Headers.CONTENT_LENGTH); if (contentLengthString == null) { return -1; } return Long.parseLong(contentLengthString); } /** * Sets the response content length * * @param length The content length */ public HttpServerExchange setResponseContentLength(long length) { if (length == -1) { responseHeaders.remove(Headers.CONTENT_LENGTH); } else { responseHeaders.put(Headers.CONTENT_LENGTH, Long.toString(length)); } return this; } /** * Returns a mutable map of query parameters. * * @return The query parameters */ public Map> getQueryParameters() { if (queryParameters == null) { queryParameters = new TreeMap<>(); } return queryParameters; } public HttpServerExchange addQueryParam(final String name, final String param) { if (queryParameters == null) { queryParameters = new TreeMap<>(); } Deque list = queryParameters.get(name); if (list == null) { queryParameters.put(name, list = new ArrayDeque<>(2)); } list.add(param); return this; } /** * Returns a mutable map of path parameters * * @return The path parameters */ public Map> getPathParameters() { if (pathParameters == null) { pathParameters = new TreeMap<>(); } return pathParameters; } public HttpServerExchange addPathParam(final String name, final String param) { if (pathParameters == null) { pathParameters = new TreeMap<>(); } Deque list = pathParameters.get(name); if (list == null) { pathParameters.put(name, list = new ArrayDeque<>(2)); } list.add(param); return this; } /** * @return A mutable map of request cookies * @deprecated use either {@link #requestCookies()} or {@link #getRequestCookie(String)} or {@link #setRequestCookie(Cookie)} methods instead */ @Deprecated public Map getRequestCookies() { if (deprecatedRequestCookies == null) { deprecatedRequestCookies = new MapDelegatingToSet((Set)((DelegatingIterable)requestCookies()).getDelegate()); } return deprecatedRequestCookies; } /** * Sets a request cookie * * @param cookie The cookie */ public HttpServerExchange setRequestCookie(final Cookie cookie) { if (cookie == null) return this; if (getConnection().getUndertowOptions().get(UndertowOptions.ENABLE_RFC6265_COOKIE_VALIDATION, UndertowOptions.DEFAULT_ENABLE_RFC6265_COOKIE_VALIDATION)) { if (cookie.getValue() != null && !cookie.getValue().isEmpty()) { Rfc6265CookieSupport.validateCookieValue(cookie.getValue()); } if (cookie.getPath() != null && !cookie.getPath().isEmpty()) { Rfc6265CookieSupport.validatePath(cookie.getPath()); } if (cookie.getDomain() != null && !cookie.getDomain().isEmpty()) { Rfc6265CookieSupport.validateDomain(cookie.getDomain()); } } ((Set)((DelegatingIterable)requestCookies()).getDelegate()).add(cookie); return this; } public Cookie getRequestCookie(final String name) { if (name == null) return null; for (Cookie cookie : requestCookies()) { if (name.equals(cookie.getName())) { // TODO: QUESTION: Shouldn't we check instead of just name also // TODO requestPath (stored in this exchange request path) and // TODO: domain (stored in Host HTTP header). return cookie; } } return null; } /** * Returns unmodifiable enumeration of request cookies. * @return A read-only enumeration of request cookies */ public Iterable requestCookies() { if (requestCookies == null) { Set requestCookiesParam = new OverridableTreeSet<>(); requestCookies = new DelegatingIterable<>(requestCookiesParam); Cookies.parseRequestCookies( getConnection().getUndertowOptions().get(UndertowOptions.MAX_COOKIES, 200), getConnection().getUndertowOptions().get(UndertowOptions.ALLOW_EQUALS_IN_COOKIE_VALUE, false), requestHeaders.get(Headers.COOKIE), requestCookiesParam); } return requestCookies; } /** * Sets a response cookie * * @param cookie The cookie */ public HttpServerExchange setResponseCookie(final Cookie cookie) { if (cookie == null) return this; if (getConnection().getUndertowOptions().get(UndertowOptions.ENABLE_RFC6265_COOKIE_VALIDATION, UndertowOptions.DEFAULT_ENABLE_RFC6265_COOKIE_VALIDATION)) { if (cookie.getValue() != null && !cookie.getValue().isEmpty()) { Rfc6265CookieSupport.validateCookieValue(cookie.getValue()); } if (cookie.getPath() != null && !cookie.getPath().isEmpty()) { Rfc6265CookieSupport.validatePath(cookie.getPath()); } if (cookie.getDomain() != null && !cookie.getDomain().isEmpty()) { Rfc6265CookieSupport.validateDomain(cookie.getDomain()); } } ((Set)((DelegatingIterable)responseCookies()).getDelegate()).add(cookie); return this; } /** * @return A mutable map of response cookies * @deprecated use either {@link #responseCookies()} or {@link #setResponseCookie(Cookie)} methods instead */ @Deprecated public Map getResponseCookies() { if (deprecatedResponseCookies == null) { deprecatedResponseCookies = new MapDelegatingToSet((Set)((DelegatingIterable)responseCookies()).getDelegate()); } return deprecatedResponseCookies; } /** * Returns unmodifiable enumeration of response cookies. * @return A read-only enumeration of response cookies */ public Iterable responseCookies() { if (responseCookies == null) { responseCookies = new DelegatingIterable<>(new OverridableTreeSet<>()); } return responseCookies; } /** * @return true If the response has already been started */ public boolean isResponseStarted() { return allAreSet(state, FLAG_RESPONSE_SENT); } /** * Get the inbound request. If there is no request body, calling this method * may cause the next request to immediately be processed. The {@link StreamSourceChannel#close()} or {@link StreamSourceChannel#shutdownReads()} * method must be called at some point after the request is processed to prevent resource leakage and to allow * the next request to proceed. Any unread content will be discarded. * * @return the channel for the inbound request, or {@code null} if another party already acquired the channel */ public StreamSourceChannel getRequestChannel() { if (requestChannel != null) { if(anyAreSet(state, FLAG_REQUEST_RESET)) { state &= ~FLAG_REQUEST_RESET; return requestChannel; } return null; } if (anyAreSet(state, FLAG_REQUEST_TERMINATED)) { return requestChannel = new ReadDispatchChannel(new ConduitStreamSourceChannel(Configurable.EMPTY, new EmptyStreamSourceConduit(getIoThread()))); } final ConduitWrapper[] wrappers = this.requestWrappers; final ConduitStreamSourceChannel sourceChannel = connection.getSourceChannel(); if (wrappers != null) { this.requestWrappers = null; final WrapperConduitFactory factory = new WrapperConduitFactory<>(wrappers, requestWrapperCount, sourceChannel.getConduit(), this); sourceChannel.setConduit(factory.create()); } return requestChannel = new ReadDispatchChannel(sourceChannel); } void resetRequestChannel() { state |= FLAG_REQUEST_RESET; } public boolean isRequestChannelAvailable() { return requestChannel == null || anyAreSet(state, FLAG_REQUEST_RESET); } /** * Returns true if the completion handler for this exchange has been invoked, and the request is considered * finished. */ public boolean isComplete() { return allAreSet(state, FLAG_REQUEST_TERMINATED | FLAG_RESPONSE_TERMINATED); } /** * Returns true if all data has been read from the request, or if there * was not data. * * @return true if the request is complete */ public boolean isRequestComplete() { PooledByteBuffer[] data = getAttachment(BUFFERED_REQUEST_DATA); if(data != null) { return false; } return allAreSet(state, FLAG_REQUEST_TERMINATED); } /** * @return true if the responses is complete */ public boolean isResponseComplete() { return allAreSet(state, FLAG_RESPONSE_TERMINATED); } /** * Force the codec to treat the request as fully read. Should only be invoked by handlers which downgrade * the socket or implement a transfer coding. */ void terminateRequest() { int oldVal = state; if (allAreSet(oldVal, FLAG_REQUEST_TERMINATED)) { // idempotent return; } if (requestChannel != null) { requestChannel.requestDone(); } this.state = oldVal | FLAG_REQUEST_TERMINATED; if (anyAreSet(oldVal, FLAG_RESPONSE_TERMINATED)) { invokeExchangeCompleteListeners(); } } private void invokeExchangeCompleteListeners() { if (exchangeCompletionListenersCount > 0) { int i = exchangeCompletionListenersCount - 1; ExchangeCompletionListener next = exchangeCompleteListeners[i]; exchangeCompletionListenersCount = -1; next.exchangeEvent(this, new ExchangeCompleteNextListener(exchangeCompleteListeners, this, i)); } else if (exchangeCompletionListenersCount == 0) { exchangeCompletionListenersCount = -1; connection.exchangeComplete(this); } } /** * Get the response channel. The channel must be closed and fully flushed before the next response can be started. * In order to close the channel you must first call {@link org.xnio.channels.StreamSinkChannel#shutdownWrites()}, * and then call {@link org.xnio.channels.StreamSinkChannel#flush()} until it returns true. Alternatively you can * call {@link #endExchange()}, which will close the channel as part of its cleanup. *

* Closing a fixed-length response before the corresponding number of bytes has been written will cause the connection * to be reset and subsequent requests to fail; thus it is important to ensure that the proper content length is * delivered when one is specified. The response channel may not be writable until after the response headers have * been sent. *

* If this method is not called then an empty or default response body will be used, depending on the response code set. *

* The returned channel will begin to write out headers when the first write request is initiated, or when * {@link org.xnio.channels.StreamSinkChannel#shutdownWrites()} is called on the channel with no content being written. * Once the channel is acquired, however, the response code and headers may not be modified. *

* * @return the response channel, or {@code null} if another party already acquired the channel */ public StreamSinkChannel getResponseChannel() { if (responseChannel != null) { return null; } final ConduitWrapper[] wrappers = responseWrappers; this.responseWrappers = null; final ConduitStreamSinkChannel sinkChannel = connection.getSinkChannel(); if (sinkChannel == null) { return null; } if(wrappers != null) { final WrapperStreamSinkConduitFactory factory = new WrapperStreamSinkConduitFactory(wrappers, responseWrapperCount, this, sinkChannel.getConduit()); sinkChannel.setConduit(factory.create()); } else { sinkChannel.setConduit(connection.getSinkConduit(this, sinkChannel.getConduit())); } this.responseChannel = new WriteDispatchChannel(sinkChannel); this.startResponse(); return responseChannel; } /** * Get the response sender. *

* For blocking exchanges this will return a sender that uses the underlying output stream. * * @return the response sender, or {@code null} if another party already acquired the channel or the sender * @see #getResponseChannel() */ public Sender getResponseSender() { if (blockingHttpExchange != null) { return blockingHttpExchange.getSender(); } if (sender != null) { return sender; } return sender = new AsyncSenderImpl(this); } public Receiver getRequestReceiver() { if(blockingHttpExchange != null) { return blockingHttpExchange.getReceiver(); } if(receiver != null) { return receiver; } return receiver = new AsyncReceiverImpl(this); } /** * @return true if {@link #getResponseChannel()} has not been called */ public boolean isResponseChannelAvailable() { return responseChannel == null; } /** * Get the status code. * * @see #getStatusCode() * @return the status code */ @Deprecated public int getResponseCode() { return state & MASK_RESPONSE_CODE; } /** * Change the status code for this response. If not specified, the code will be a {@code 200}. Setting * the status code after the response headers have been transmitted has no effect. * * @see #setStatusCode(int) * @param statusCode the new code * @throws IllegalStateException if a response or upgrade was already sent */ @Deprecated public HttpServerExchange setResponseCode(final int statusCode) { return setStatusCode(statusCode); } /** * Get the status code. * * @return the status code */ public int getStatusCode() { return state & MASK_RESPONSE_CODE; } /** * Change the status code for this response. If not specified, the code will be a {@code 200}. Setting * the status code after the response headers have been transmitted has no effect. * * @param statusCode the new code * @throws IllegalStateException if a response or upgrade was already sent */ public HttpServerExchange setStatusCode(final int statusCode) { if (statusCode < 0 || statusCode > 999) { throw new IllegalArgumentException("Invalid response code"); } int oldVal = state; if (allAreSet(oldVal, FLAG_RESPONSE_SENT)) { throw UndertowMessages.MESSAGES.responseAlreadyStarted(); } if(statusCode >= 500) { if(UndertowLogger.ERROR_RESPONSE.isDebugEnabled()) { UndertowLogger.ERROR_RESPONSE.debugf(new RuntimeException(), "Setting error code %s for exchange %s", statusCode, this); } } this.state = oldVal & ~MASK_RESPONSE_CODE | statusCode & MASK_RESPONSE_CODE; return this; } /** * Sets the HTTP reason phrase. Depending on the protocol this may or may not be honoured. In particular HTTP2 * has removed support for the reason phrase. * * This method should only be used to interact with legacy frameworks that give special meaning to the reason phrase. * * @param message The status message * @return this exchange */ public HttpServerExchange setReasonPhrase(String message) { putAttachment(REASON_PHRASE, message); return this; } /** * * @return The current reason phrase */ public String getReasonPhrase() { return getAttachment(REASON_PHRASE); } /** * Adds a {@link ConduitWrapper} to the request wrapper chain. * * @param wrapper the wrapper */ public HttpServerExchange addRequestWrapper(final ConduitWrapper wrapper) { ConduitWrapper[] wrappers = requestWrappers; if (requestChannel != null) { throw UndertowMessages.MESSAGES.requestChannelAlreadyProvided(); } if (wrappers == null) { wrappers = requestWrappers = new ConduitWrapper[2]; } else if (wrappers.length == requestWrapperCount) { requestWrappers = new ConduitWrapper[wrappers.length + 2]; System.arraycopy(wrappers, 0, requestWrappers, 0, wrappers.length); wrappers = requestWrappers; } wrappers[requestWrapperCount++] = wrapper; return this; } /** * Adds a {@link ConduitWrapper} to the response wrapper chain. * * @param wrapper the wrapper */ public HttpServerExchange addResponseWrapper(final ConduitWrapper wrapper) { ConduitWrapper[] wrappers = responseWrappers; if (responseChannel != null) { throw UndertowMessages.MESSAGES.responseChannelAlreadyProvided(); } if(wrappers == null) { this.responseWrappers = wrappers = new ConduitWrapper[2]; } else if (wrappers.length == responseWrapperCount) { responseWrappers = new ConduitWrapper[wrappers.length + 2]; System.arraycopy(wrappers, 0, responseWrappers, 0, wrappers.length); wrappers = responseWrappers; } wrappers[responseWrapperCount++] = wrapper; return this; } /** * Calling this method puts the exchange in blocking mode, and creates a * {@link BlockingHttpExchange} object to store the streams. *

* When an exchange is in blocking mode the input stream methods become * available, other than that there is presently no major difference * between blocking an non-blocking modes. * * @return The existing blocking exchange, if any */ public BlockingHttpExchange startBlocking() { final BlockingHttpExchange old = this.blockingHttpExchange; blockingHttpExchange = new DefaultBlockingHttpExchange(this); return old; } /** * Calling this method puts the exchange in blocking mode, using the given * blocking exchange as the source of the streams. *

* When an exchange is in blocking mode the input stream methods become * available, other than that there is presently no major difference * between blocking an non-blocking modes. *

* Note that this method may be called multiple times with different * exchange objects, to allow handlers to modify the streams * that are being used. * * @return The existing blocking exchange, if any */ public BlockingHttpExchange startBlocking(final BlockingHttpExchange httpExchange) { final BlockingHttpExchange old = this.blockingHttpExchange; blockingHttpExchange = httpExchange; return old; } /** * Returns true if {@link #startBlocking()} or {@link #startBlocking(BlockingHttpExchange)} has been called. * * @return true If this is a blocking HTTP server exchange */ public boolean isBlocking() { return blockingHttpExchange != null; } /** * @return The input stream * @throws IllegalStateException if {@link #startBlocking()} has not been called */ public InputStream getInputStream() { if (blockingHttpExchange == null) { throw UndertowMessages.MESSAGES.startBlockingHasNotBeenCalled(); } return blockingHttpExchange.getInputStream(); } /** * @return The output stream * @throws IllegalStateException if {@link #startBlocking()} has not been called */ public OutputStream getOutputStream() { if (blockingHttpExchange == null) { throw UndertowMessages.MESSAGES.startBlockingHasNotBeenCalled(); } return blockingHttpExchange.getOutputStream(); } /** * Force the codec to treat the response as fully written. Should only be invoked by handlers which downgrade * the socket or implement a transfer coding. */ HttpServerExchange terminateResponse() { int oldVal = state; if (allAreSet(oldVal, FLAG_RESPONSE_TERMINATED)) { // idempotent return this; } if(responseChannel != null) { responseChannel.responseDone(); } this.state = oldVal | FLAG_RESPONSE_TERMINATED; if (anyAreSet(oldVal, FLAG_REQUEST_TERMINATED)) { invokeExchangeCompleteListeners(); } return this; } /** * @return The request start time using the JVM's high-resolution time source, * in nanoseconds, or -1 if this was not recorded * @see UndertowOptions#RECORD_REQUEST_START_TIME * @see Connectors#setRequestStartTime(HttpServerExchange) */ public long getRequestStartTime() { return requestStartTime; } HttpServerExchange setRequestStartTime(long requestStartTime) { this.requestStartTime = requestStartTime; return this; } /** * Ends the exchange by fully draining the request channel, and flushing the response channel. *

* This can result in handoff to an XNIO worker, so after this method is called the exchange should * not be modified by the caller. *

* If the exchange is already complete this method is a noop */ public HttpServerExchange endExchange() { final int state = this.state; if (allAreSet(state, FLAG_REQUEST_TERMINATED | FLAG_RESPONSE_TERMINATED)) { if(blockingHttpExchange != null) { //we still have to close the blocking exchange in this case, IoUtils.safeClose(blockingHttpExchange); } return this; } if(defaultResponseListeners != null) { int i = defaultResponseListeners.length - 1; while (i >= 0) { DefaultResponseListener listener = defaultResponseListeners[i]; if (listener != null) { defaultResponseListeners[i] = null; try { if (listener.handleDefaultResponse(this)) { return this; } } catch (Throwable e) { UndertowLogger.REQUEST_LOGGER.debug("Exception running default response listener", e); } } i--; } } if (anyAreClear(state, FLAG_REQUEST_TERMINATED)) { connection.terminateRequestChannel(this); } if (blockingHttpExchange != null) { try { //TODO: can we end up in this situation in a IO thread? blockingHttpExchange.close(); } catch (IOException e) { UndertowLogger.REQUEST_IO_LOGGER.ioException(e); IoUtils.safeClose(connection); } catch (Throwable t) { UndertowLogger.REQUEST_IO_LOGGER.handleUnexpectedFailure(t); IoUtils.safeClose(connection); } } //417 means that we are rejecting the request //so the client should not actually send any data if (anyAreClear(state, FLAG_REQUEST_TERMINATED)) { //not really sure what the best thing to do here is //for now we are just going to drain the channel if (requestChannel == null) { getRequestChannel(); } int totalRead = 0; for (; ; ) { try { long read = Channels.drain(requestChannel, Long.MAX_VALUE); totalRead += read; if (read == 0) { //if the response code is 417 this is a rejected continuation request. //however there is a chance the client could have sent the data anyway //so we attempt to drain, and if we have not drained anything then we //assume the server has not sent any data if (getStatusCode() != StatusCodes.EXPECTATION_FAILED || totalRead > 0) { requestChannel.getReadSetter().set(ChannelListeners.drainListener(Long.MAX_VALUE, new ChannelListener() { @Override public void handleEvent(final StreamSourceChannel channel) { if (anyAreClear(state, FLAG_RESPONSE_TERMINATED)) { closeAndFlushResponse(); } } }, new ChannelExceptionHandler() { @Override public void handleException(final StreamSourceChannel channel, final IOException e) { //make sure the listeners have been invoked //unless the connection has been killed this is a no-op terminateRequest(); terminateResponse(); UndertowLogger.REQUEST_LOGGER.debug("Exception draining request stream", e); IoUtils.safeClose(connection); } } )); requestChannel.resumeReads(); return this; } else { break; } } else if (read == -1) { break; } } catch (Throwable t) { if (t instanceof IOException) { UndertowLogger.REQUEST_IO_LOGGER.ioException((IOException) t); } else { UndertowLogger.REQUEST_IO_LOGGER.handleUnexpectedFailure(t); } invokeExchangeCompleteListeners(); IoUtils.safeClose(connection); return this; } } } if (anyAreClear(state, FLAG_RESPONSE_TERMINATED)) { closeAndFlushResponse(); } return this; } private void closeAndFlushResponse() { if(!connection.isOpen()) { //not much point trying to flush //make sure the listeners have been invoked terminateRequest(); terminateResponse(); return; } try { if (isResponseChannelAvailable()) { if(!getRequestMethod().equals(Methods.CONNECT) && !(getRequestMethod().equals(Methods.HEAD) && getResponseHeaders().contains(Headers.CONTENT_LENGTH)) && Connectors.isEntityBodyAllowed(this)) { //according to getResponseHeaders().put(Headers.CONTENT_LENGTH, "0"); } getResponseChannel(); } else if (anyAreClear(state, FLAG_RESPONSE_TERMINATED) && !responseChannel.isOpen()) { // UNDERTOW-1664: Http/2 response channels may be closed prior to the connection. There's // no reason to attempt to flush a response for a closed channel but we must ensure // the listeners have been invoked. invokeExchangeCompleteListeners(); IoUtils.safeClose(connection); return; } responseChannel.shutdownWrites(); if (!responseChannel.flush()) { responseChannel.getWriteSetter().set(ChannelListeners.flushingChannelListener( new ChannelListener() { @Override public void handleEvent(final StreamSinkChannel channel) { channel.suspendWrites(); channel.getWriteSetter().set(null); //defensive programming, should never happen if (anyAreClear(state, FLAG_RESPONSE_TERMINATED)) { //make sure the listeners have been invoked invokeExchangeCompleteListeners(); UndertowLogger.ROOT_LOGGER.responseWasNotTerminated(connection, HttpServerExchange.this); IoUtils.safeClose(connection); } } }, new ChannelExceptionHandler() { @Override public void handleException(final Channel channel, final IOException exception) { //make sure the listeners have been invoked invokeExchangeCompleteListeners(); UndertowLogger.REQUEST_LOGGER.debug("Exception ending request", exception); IoUtils.safeClose(connection); } } )); responseChannel.resumeWrites(); } else { //defensive programming, should never happen if (anyAreClear(state, FLAG_RESPONSE_TERMINATED)) { //make sure the listeners have been invoked invokeExchangeCompleteListeners(); UndertowLogger.ROOT_LOGGER.responseWasNotTerminated(connection, this); IoUtils.safeClose(connection); } } } catch (Throwable t) { if (t instanceof IOException) { UndertowLogger.REQUEST_IO_LOGGER.ioException((IOException) t); } else { UndertowLogger.REQUEST_IO_LOGGER.handleUnexpectedFailure(t); } invokeExchangeCompleteListeners(); IoUtils.safeClose(connection); } } /** * Transmit the response headers. After this method successfully returns, * the response channel may become writable. *

* If this method fails the request and response channels will be closed. *

* This method runs asynchronously. If the channel is writable it will * attempt to write as much of the response header as possible, and then * queue the rest in a listener and return. *

* If future handlers in the chain attempt to write before this is finished * XNIO will just magically sort it out so it works. This is not actually * implemented yet, so we just terminate the connection straight away at * the moment. *

* TODO: make this work properly * * @throws IllegalStateException if the response headers were already sent */ HttpServerExchange startResponse() throws IllegalStateException { int oldVal = state; if (allAreSet(oldVal, FLAG_RESPONSE_SENT)) { throw UndertowMessages.MESSAGES.responseAlreadyStarted(); } this.state = oldVal | FLAG_RESPONSE_SENT; log.tracef("Starting to write response for %s", this); return this; } public XnioIoThread getIoThread() { return connection.getIoThread(); } /** * @return The maximum entity size for this exchange */ public long getMaxEntitySize() { return maxEntitySize; } /** * Sets the max entity size for this exchange. This cannot be modified after the request channel has been obtained. * * @param maxEntitySize The max entity size */ public HttpServerExchange setMaxEntitySize(final long maxEntitySize) { if (!isRequestChannelAvailable()) { throw UndertowMessages.MESSAGES.requestChannelAlreadyProvided(); } this.maxEntitySize = maxEntitySize; connection.maxEntitySizeUpdated(this); return this; } public SecurityContext getSecurityContext() { return securityContext; } public void setSecurityContext(SecurityContext securityContext) { SecurityManager sm = System.getSecurityManager(); if(sm != null) { sm.checkPermission(SET_SECURITY_CONTEXT); } this.securityContext = securityContext; } /** * Adds a listener that will be invoked on response commit * * @param listener The response listener */ public void addResponseCommitListener(final ResponseCommitListener listener) { //technically it is possible to modify the exchange after the response conduit has been created //as the response channel should not be retrieved until it is about to be written to //if we get complaints about this we can add support for it, however it makes the exchange bigger and the connectors more complex addResponseWrapper(new ConduitWrapper() { @Override public StreamSinkConduit wrap(ConduitFactory factory, HttpServerExchange exchange) { listener.beforeCommit(exchange); return factory.create(); } }); } /** * Actually resumes reads or writes, if the relevant method has been called. * * @return true if reads or writes were resumed */ boolean runResumeReadWrite() { boolean ret = false; if(anyAreSet(state, FLAG_SHOULD_RESUME_WRITES)) { responseChannel.runResume(); ret = true; } if(anyAreSet(state, FLAG_SHOULD_RESUME_READS)) { requestChannel.runResume(); ret = true; } return ret; } boolean isResumed() { return anyAreSet(state, FLAG_SHOULD_RESUME_WRITES | FLAG_SHOULD_RESUME_READS); } private static class ExchangeCompleteNextListener implements ExchangeCompletionListener.NextListener { private final ExchangeCompletionListener[] list; private final HttpServerExchange exchange; private int i; ExchangeCompleteNextListener(final ExchangeCompletionListener[] list, final HttpServerExchange exchange, int i) { this.list = list; this.exchange = exchange; this.i = i; } @Override public void proceed() { if (--i >= 0) { final ExchangeCompletionListener next = list[i]; next.exchangeEvent(exchange, this); } else if(i == -1) { exchange.connection.exchangeComplete(exchange); } } } private static class DefaultBlockingHttpExchange implements BlockingHttpExchange { private InputStream inputStream; private UndertowOutputStream outputStream; private Sender sender; private final HttpServerExchange exchange; DefaultBlockingHttpExchange(final HttpServerExchange exchange) { this.exchange = exchange; } public InputStream getInputStream() { if (inputStream == null) { inputStream = new UndertowInputStream(exchange); } return inputStream; } public UndertowOutputStream getOutputStream() { if (outputStream == null) { outputStream = new UndertowOutputStream(exchange); } return outputStream; } @Override public Sender getSender() { if (sender == null) { sender = new BlockingSenderImpl(exchange, getOutputStream()); } return sender; } @Override public void close() throws IOException { try { getInputStream().close(); } finally { getOutputStream().close(); } } @Override public Receiver getReceiver() { return new BlockingReceiverImpl(exchange, getInputStream()); } } /** * Channel implementation that is actually provided to clients of the exchange. *

* We do not provide the underlying conduit channel, as this is shared between requests, so we need to make sure that after this request * is done the the channel cannot affect the next request. *

* It also delays a wakeup/resumesWrites calls until the current call stack has returned, thus ensuring that only 1 thread is * active in the exchange at any one time. */ private class WriteDispatchChannel extends DetachableStreamSinkChannel implements StreamSinkChannel { private boolean wakeup; WriteDispatchChannel(final ConduitStreamSinkChannel delegate) { super(delegate); } @Override protected boolean isFinished() { return allAreSet(state, FLAG_RESPONSE_TERMINATED); } @Override public void resumeWrites() { if (isInCall()) { state |= FLAG_SHOULD_RESUME_WRITES; if(anyAreSet(state, FLAG_DISPATCHED)) { throw UndertowMessages.MESSAGES.resumedAndDispatched(); } } else if(!isFinished()){ delegate.resumeWrites(); } } @Override public void suspendWrites() { state &= ~FLAG_SHOULD_RESUME_WRITES; super.suspendWrites(); } @Override public void wakeupWrites() { if (isFinished()) { return; } if (isInCall()) { wakeup = true; state |= FLAG_SHOULD_RESUME_WRITES; if(anyAreSet(state, FLAG_DISPATCHED)) { throw UndertowMessages.MESSAGES.resumedAndDispatched(); } } else { delegate.wakeupWrites(); } } @Override public boolean isWriteResumed() { return anyAreSet(state, FLAG_SHOULD_RESUME_WRITES) || super.isWriteResumed(); } public void runResume() { if (isWriteResumed()) { if(isFinished()) { invokeListener(); } else { if (wakeup) { wakeup = false; state &= ~FLAG_SHOULD_RESUME_WRITES; delegate.wakeupWrites(); } else { state &= ~FLAG_SHOULD_RESUME_WRITES; delegate.resumeWrites(); } } } else if(wakeup) { wakeup = false; invokeListener(); } } private void invokeListener() { if(writeSetter != null) { super.getIoThread().execute(new Runnable() { @Override public void run() { ChannelListeners.invokeChannelListener(WriteDispatchChannel.this, writeSetter.get()); } }); } } @Override public void awaitWritable() throws IOException { if(Thread.currentThread() == super.getIoThread()) { throw UndertowMessages.MESSAGES.awaitCalledFromIoThread(); } super.awaitWritable(); } @Override public void awaitWritable(long time, TimeUnit timeUnit) throws IOException { if(Thread.currentThread() == super.getIoThread()) { throw UndertowMessages.MESSAGES.awaitCalledFromIoThread(); } super.awaitWritable(time, timeUnit); } @Override public long transferFrom(FileChannel src, long position, long count) throws IOException { long l = super.transferFrom(src, position, count); if(l > 0) { responseBytesSent += l; } return l; } @Override public long transferFrom(StreamSourceChannel source, long count, ByteBuffer throughBuffer) throws IOException { long l = super.transferFrom(source, count, throughBuffer); if(l > 0) { responseBytesSent += l; } return l; } @Override public long write(ByteBuffer[] srcs, int offset, int length) throws IOException { long l = super.write(srcs, offset, length); responseBytesSent += l; return l; } @Override public long write(ByteBuffer[] srcs) throws IOException { long l = super.write(srcs); responseBytesSent += l; return l; } @Override public int writeFinal(ByteBuffer src) throws IOException { int l = super.writeFinal(src); responseBytesSent += l; return l; } @Override public long writeFinal(ByteBuffer[] srcs, int offset, int length) throws IOException { long l = super.writeFinal(srcs, offset, length); responseBytesSent += l; return l; } @Override public long writeFinal(ByteBuffer[] srcs) throws IOException { long l = super.writeFinal(srcs); responseBytesSent += l; return l; } @Override public int write(ByteBuffer src) throws IOException { int l = super.write(src); responseBytesSent += l; return l; } } /** * Channel implementation that is actually provided to clients of the exchange. We do not provide the underlying * conduit channel, as this will become the next requests conduit channel, so if a thread is still hanging onto this * exchange it can result in problems. *

* It also delays a readResume call until the current call stack has returned, thus ensuring that only 1 thread is * active in the exchange at any one time. *

* It also handles buffered request data. */ private final class ReadDispatchChannel extends DetachableStreamSourceChannel implements StreamSourceChannel { private boolean wakeup = true; private boolean readsResumed = false; ReadDispatchChannel(final ConduitStreamSourceChannel delegate) { super(delegate); } @Override protected boolean isFinished() { return allAreSet(state, FLAG_REQUEST_TERMINATED); } @Override public void resumeReads() { readsResumed = true; if (isInCall()) { state |= FLAG_SHOULD_RESUME_READS; if(anyAreSet(state, FLAG_DISPATCHED)) { throw UndertowMessages.MESSAGES.resumedAndDispatched(); } } else if (!isFinished()) { delegate.resumeReads(); } } public void wakeupReads() { if (isInCall()) { wakeup = true; state |= FLAG_SHOULD_RESUME_READS; if(anyAreSet(state, FLAG_DISPATCHED)) { throw UndertowMessages.MESSAGES.resumedAndDispatched(); } } else { if(isFinished()) { invokeListener(); } else { delegate.wakeupReads(); } } } private void invokeListener() { if(readSetter != null) { super.getIoThread().execute(new Runnable() { @Override public void run() { ChannelListeners.invokeChannelListener(ReadDispatchChannel.this, readSetter.get()); } }); } } public void requestDone() { if(delegate instanceof ConduitStreamSourceChannel) { ((ConduitStreamSourceChannel)delegate).setReadListener(null); ((ConduitStreamSourceChannel)delegate).setCloseListener(null); } else { delegate.getReadSetter().set(null); delegate.getCloseSetter().set(null); } } @Override public long transferTo(long position, long count, FileChannel target) throws IOException { PooledByteBuffer[] buffered = getAttachment(BUFFERED_REQUEST_DATA); if (buffered == null) { return super.transferTo(position, count, target); } return target.transferFrom(this, position, count); } @Override public void awaitReadable() throws IOException { if(Thread.currentThread() == super.getIoThread()) { throw UndertowMessages.MESSAGES.awaitCalledFromIoThread(); } PooledByteBuffer[] buffered = getAttachment(BUFFERED_REQUEST_DATA); if (buffered == null) { super.awaitReadable(); } } @Override public void suspendReads() { readsResumed = false; state &= ~(FLAG_SHOULD_RESUME_READS); super.suspendReads(); } @Override public long transferTo(long count, ByteBuffer throughBuffer, StreamSinkChannel target) throws IOException { PooledByteBuffer[] buffered = getAttachment(BUFFERED_REQUEST_DATA); if (buffered == null) { return super.transferTo(count, throughBuffer, target); } //make sure there is no garbage in throughBuffer throughBuffer.position(0); throughBuffer.limit(0); long copied = 0; for (int i = 0; i < buffered.length; ++i) { PooledByteBuffer pooled = buffered[i]; if (pooled != null) { final ByteBuffer buf = pooled.getBuffer(); if (buf.hasRemaining()) { int res = target.write(buf); if (!buf.hasRemaining()) { pooled.close(); buffered[i] = null; } if (res == 0) { return copied; } else { copied += res; } } else { pooled.close(); buffered[i] = null; } } } removeAttachment(BUFFERED_REQUEST_DATA); if (copied == 0) { return super.transferTo(count, throughBuffer, target); } else { return copied; } } @Override public void awaitReadable(long time, TimeUnit timeUnit) throws IOException { if(Thread.currentThread() == super.getIoThread()) { throw UndertowMessages.MESSAGES.awaitCalledFromIoThread(); } PooledByteBuffer[] buffered = getAttachment(BUFFERED_REQUEST_DATA); if (buffered == null) { super.awaitReadable(time, timeUnit); } } @Override public long read(ByteBuffer[] dsts, int offset, int length) throws IOException { PooledByteBuffer[] buffered = getAttachment(BUFFERED_REQUEST_DATA); if (buffered == null) { return super.read(dsts, offset, length); } long copied = 0; for (int i = 0; i < buffered.length; ++i) { PooledByteBuffer pooled = buffered[i]; if (pooled != null) { final ByteBuffer buf = pooled.getBuffer(); if (buf.hasRemaining()) { copied += Buffers.copy(dsts, offset, length, buf); if (!buf.hasRemaining()) { pooled.close(); buffered[i] = null; } if (!Buffers.hasRemaining(dsts, offset, length)) { return copied; } } else { pooled.close(); buffered[i] = null; } } } removeAttachment(BUFFERED_REQUEST_DATA); if (copied == 0) { return super.read(dsts, offset, length); } else { return copied; } } @Override public long read(ByteBuffer[] dsts) throws IOException { return read(dsts, 0, dsts.length); } @Override public boolean isOpen() { PooledByteBuffer[] buffered = getAttachment(BUFFERED_REQUEST_DATA); if (buffered != null) { return true; } return super.isOpen(); } @Override public void close() throws IOException { PooledByteBuffer[] buffered = getAttachment(BUFFERED_REQUEST_DATA); if (buffered != null) { for (PooledByteBuffer pooled : buffered) { if (pooled != null) { pooled.close(); } } } removeAttachment(BUFFERED_REQUEST_DATA); super.close(); } @Override public boolean isReadResumed() { PooledByteBuffer[] buffered = getAttachment(BUFFERED_REQUEST_DATA); if (buffered != null) { return readsResumed; } if(isFinished()) { return false; } return anyAreSet(state, FLAG_SHOULD_RESUME_READS) || super.isReadResumed(); } @Override public int read(ByteBuffer dst) throws IOException { PooledByteBuffer[] buffered = getAttachment(BUFFERED_REQUEST_DATA); if (buffered == null) { return super.read(dst); } int copied = 0; for (int i = 0; i < buffered.length; ++i) { PooledByteBuffer pooled = buffered[i]; if (pooled != null) { final ByteBuffer buf = pooled.getBuffer(); if (buf.hasRemaining()) { copied += Buffers.copy(dst, buf); if (!buf.hasRemaining()) { pooled.close(); buffered[i] = null; } if (!dst.hasRemaining()) { return copied; } } else { pooled.close(); buffered[i] = null; } } } removeAttachment(BUFFERED_REQUEST_DATA); if (copied == 0) { return super.read(dst); } else { return copied; } } public void runResume() { if (isReadResumed()) { if(isFinished()) { invokeListener(); } else { if (wakeup) { wakeup = false; state &= ~FLAG_SHOULD_RESUME_READS; delegate.wakeupReads(); } else { state &= ~FLAG_SHOULD_RESUME_READS; delegate.resumeReads(); } } } else if(wakeup) { wakeup = false; invokeListener(); } } } public static class WrapperStreamSinkConduitFactory implements ConduitFactory { private final HttpServerExchange exchange; private final ConduitWrapper[] wrappers; private int position; private final StreamSinkConduit first; public WrapperStreamSinkConduitFactory(ConduitWrapper[] wrappers, int wrapperCount, HttpServerExchange exchange, StreamSinkConduit first) { this.wrappers = wrappers; this.exchange = exchange; this.first = first; this.position = wrapperCount - 1; } @Override public StreamSinkConduit create() { if (position == -1) { return exchange.getConnection().getSinkConduit(exchange, first); } else { return wrappers[position--].wrap(this, exchange); } } } public static class WrapperConduitFactory implements ConduitFactory { private final HttpServerExchange exchange; private final ConduitWrapper[] wrappers; private int position; private T first; public WrapperConduitFactory(ConduitWrapper[] wrappers, int wrapperCount, T first, HttpServerExchange exchange) { this.wrappers = wrappers; this.exchange = exchange; this.position = wrapperCount - 1; this.first = first; } @Override public T create() { if (position == -1) { return first; } else { return wrappers[position--].wrap(this, exchange); } } } @Override public String toString() { return "HttpServerExchange{ " + getRequestMethod().toString() + " " + getRequestURI() + '}'; } }





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