/*
 * Copyright 2014 Red Hat, Inc.
 *
 * Red Hat 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.vertx.reactivex.core.http;

import io.vertx.reactivex.RxHelper;
import io.vertx.reactivex.ObservableHelper;
import io.vertx.reactivex.FlowableHelper;
import io.vertx.reactivex.impl.AsyncResultMaybe;
import io.vertx.reactivex.impl.AsyncResultSingle;
import io.vertx.reactivex.impl.AsyncResultCompletable;
import io.vertx.reactivex.WriteStreamObserver;
import io.vertx.reactivex.WriteStreamSubscriber;
import java.util.Map;
import java.util.Set;
import java.util.List;
import java.util.Iterator;
import java.util.function.Function;
import java.util.stream.Collectors;
import io.vertx.core.Handler;
import io.vertx.core.AsyncResult;
import io.vertx.core.json.JsonObject;
import io.vertx.core.json.JsonArray;
import io.vertx.lang.rx.RxGen;
import io.vertx.lang.rx.TypeArg;
import io.vertx.lang.rx.MappingIterator;

Represents a client-side WebSocket.
 NOTE: This class has been automatically generated from the original non RX-ified interface using Vert.x codegen. /**
 * Represents a client-side WebSocket.
 *
 * <p/>
 * NOTE: This class has been automatically generated from the {@link io.vertx.core.http.WebSocket original} non RX-ified interface using Vert.x codegen.
 */

@RxGen(io.vertx.core.http.WebSocket.class)
public class WebSocket implements io.vertx.reactivex.core.http.WebSocketBase {

  @Override
  public String toString() {
    return delegate.toString();
  }

  @Override
  public boolean equals(Object o) {
    if (this == o) return true;
    if (o == null || getClass() != o.getClass()) return false;
    WebSocket that = (WebSocket) o;
    return delegate.equals(that.delegate);
  }
  
  @Override
  public int hashCode() {
    return delegate.hashCode();
  }

  public static final TypeArg<WebSocket> __TYPE_ARG = new TypeArg<>(    obj -> new WebSocket((io.vertx.core.http.WebSocket) obj),
    WebSocket::getDelegate
  );

  private final io.vertx.core.http.WebSocket delegate;
  
  public WebSocket(io.vertx.core.http.WebSocket delegate) {
    this.delegate = delegate;
  }

  public WebSocket(Object delegate) {
    this.delegate = (io.vertx.core.http.WebSocket)delegate;
  }

  public io.vertx.core.http.WebSocket getDelegate() {
    return delegate;
  }

  private io.reactivex.Observable<io.vertx.reactivex.core.buffer.Buffer> observable;
  private io.reactivex.Flowable<io.vertx.reactivex.core.buffer.Buffer> flowable;

  public synchronized io.reactivex.Observable<io.vertx.reactivex.core.buffer.Buffer> toObservable() {
    if (observable == null) {
      Function<io.vertx.core.buffer.Buffer, io.vertx.reactivex.core.buffer.Buffer> conv = io.vertx.reactivex.core.buffer.Buffer::newInstance;
      observable = ObservableHelper.toObservable(delegate, conv);
    }
    return observable;
  }

  public synchronized io.reactivex.Flowable<io.vertx.reactivex.core.buffer.Buffer> toFlowable() {
    if (flowable == null) {
      Function<io.vertx.core.buffer.Buffer, io.vertx.reactivex.core.buffer.Buffer> conv = io.vertx.reactivex.core.buffer.Buffer::newInstance;
      flowable = FlowableHelper.toFlowable(delegate, conv);
    }
    return flowable;
  }

  private WriteStreamObserver<io.vertx.reactivex.core.buffer.Buffer> observer;
  private WriteStreamSubscriber<io.vertx.reactivex.core.buffer.Buffer> subscriber;

  public synchronized WriteStreamObserver<io.vertx.reactivex.core.buffer.Buffer> toObserver() {
    if (observer == null) {
      Function<io.vertx.reactivex.core.buffer.Buffer, io.vertx.core.buffer.Buffer> conv = io.vertx.reactivex.core.buffer.Buffer::getDelegate;
      observer = RxHelper.toObserver(getDelegate(), conv);
    }
    return observer;
  }

  public synchronized WriteStreamSubscriber<io.vertx.reactivex.core.buffer.Buffer> toSubscriber() {
    if (subscriber == null) {
      Function<io.vertx.reactivex.core.buffer.Buffer, io.vertx.core.buffer.Buffer> conv = io.vertx.reactivex.core.buffer.Buffer::getDelegate;
      subscriber = RxHelper.toSubscriber(getDelegate(), conv);
    }
    return subscriber;
  }

  private static final TypeArg<io.vertx.reactivex.core.buffer.Buffer> TYPE_ARG_0 = new TypeArg<io.vertx.reactivex.core.buffer.Buffer>(o1 -> io.vertx.reactivex.core.buffer.Buffer.newInstance((io.vertx.core.buffer.Buffer)o1), o1 -> o1.getDelegate());

  
Same as  but with an handler called when the operation completes
Params:
data – 
handler – /**
   * Same as  but with an <code>handler</code> called when the operation completes
   * @param data 
   * @param handler 
   */
  public void write(io.vertx.reactivex.core.buffer.Buffer data, Handler<AsyncResult<Void>> handler) { 
    delegate.write(data.getDelegate(), handler);
  }

  
Same as  but with an handler called when the operation completes
Params:
data – /**
   * Same as  but with an <code>handler</code> called when the operation completes
   * @param data 
   */
  public void write(io.vertx.reactivex.core.buffer.Buffer data) {
    write(data, ar -> { });
  }

  
Same as  but with an handler called when the operation completes
Params:
data – 
Returns:
/**
   * Same as  but with an <code>handler</code> called when the operation completes
   * @param data 
   * @return 
   */
  public io.reactivex.Completable rxWrite(io.vertx.reactivex.core.buffer.Buffer data) { 
    return AsyncResultCompletable.toCompletable($handler -> {
      write(data, $handler);
    });
  }

  
Same as  but with an handler called when the operation completes
Params:
data – 
handler – /**
   * Same as  but with an <code>handler</code> called when the operation completes
   * @param data 
   * @param handler 
   */
  public void end(io.vertx.reactivex.core.buffer.Buffer data, Handler<AsyncResult<Void>> handler) { 
    delegate.end(data.getDelegate(), handler);
  }

  
Same as  but with an handler called when the operation completes
Params:
data – /**
   * Same as  but with an <code>handler</code> called when the operation completes
   * @param data 
   */
  public void end(io.vertx.reactivex.core.buffer.Buffer data) {
    end(data, ar -> { });
  }

  
Same as  but with an handler called when the operation completes
Params:
data – 
Returns:
/**
   * Same as  but with an <code>handler</code> called when the operation completes
   * @param data 
   * @return 
   */
  public io.reactivex.Completable rxEnd(io.vertx.reactivex.core.buffer.Buffer data) { 
    return AsyncResultCompletable.toCompletable($handler -> {
      end(data, $handler);
    });
  }

  
This will return true if there are more bytes in the write queue than the value set using setWriteQueueMaxSize 
Returns:
true if write queue is full/**
   * This will return <code>true</code> if there are more bytes in the write queue than the value set using {@link io.vertx.reactivex.core.http.WebSocket#setWriteQueueMaxSize}
   * @return <code>true</code> if write queue is full
   */
  public boolean writeQueueFull() { 
    boolean ret = delegate.writeQueueFull();
    return ret;
  }

  
Pause this stream and return a  to transfer the elements of this stream to a destination .

The stream will be resumed when the pipe will be wired to a WriteStream.
Returns:
a pipe/**
   * Pause this stream and return a  to transfer the elements of this stream to a destination .
   * <p/>
   * The stream will be resumed when the pipe will be wired to a <code>WriteStream</code>.
   * @return a pipe
   */
  public io.vertx.reactivex.core.streams.Pipe<io.vertx.reactivex.core.buffer.Buffer> pipe() { 
    io.vertx.reactivex.core.streams.Pipe<io.vertx.reactivex.core.buffer.Buffer> ret = io.vertx.reactivex.core.streams.Pipe.newInstance((io.vertx.core.streams.Pipe)delegate.pipe(), TYPE_ARG_0);
    return ret;
  }

  
Pipe this ReadStream to the WriteStream.

Elements emitted by this stream will be written to the write stream until this stream ends or fails.

Once this stream has ended or failed, the write stream will be ended and the handler will be
called with the result.
Params:
dst – the destination write stream
handler – /**
   * Pipe this <code>ReadStream</code> to the <code>WriteStream</code>.
   * <p>
   * Elements emitted by this stream will be written to the write stream until this stream ends or fails.
   * <p>
   * Once this stream has ended or failed, the write stream will be ended and the <code>handler</code> will be
   * called with the result.
   * @param dst the destination write stream
   * @param handler 
   */
  public void pipeTo(io.vertx.reactivex.core.streams.WriteStream<io.vertx.reactivex.core.buffer.Buffer> dst, Handler<AsyncResult<Void>> handler) { 
    delegate.pipeTo(dst.getDelegate(), handler);
  }

  
Pipe this ReadStream to the WriteStream.

Elements emitted by this stream will be written to the write stream until this stream ends or fails.

Once this stream has ended or failed, the write stream will be ended and the handler will be
called with the result.
Params:
dst – the destination write stream/**
   * Pipe this <code>ReadStream</code> to the <code>WriteStream</code>.
   * <p>
   * Elements emitted by this stream will be written to the write stream until this stream ends or fails.
   * <p>
   * Once this stream has ended or failed, the write stream will be ended and the <code>handler</code> will be
   * called with the result.
   * @param dst the destination write stream
   */
  public void pipeTo(io.vertx.reactivex.core.streams.WriteStream<io.vertx.reactivex.core.buffer.Buffer> dst) {
    pipeTo(dst, ar -> { });
  }

  
Pipe this ReadStream to the WriteStream.

Elements emitted by this stream will be written to the write stream until this stream ends or fails.

Once this stream has ended or failed, the write stream will be ended and the handler will be
called with the result.
Params:
dst – the destination write stream
Returns:
/**
   * Pipe this <code>ReadStream</code> to the <code>WriteStream</code>.
   * <p>
   * Elements emitted by this stream will be written to the write stream until this stream ends or fails.
   * <p>
   * Once this stream has ended or failed, the write stream will be ended and the <code>handler</code> will be
   * called with the result.
   * @param dst the destination write stream
   * @return 
   */
  public io.reactivex.Completable rxPipeTo(io.vertx.reactivex.core.streams.WriteStream<io.vertx.reactivex.core.buffer.Buffer> dst) { 
    return AsyncResultCompletable.toCompletable($handler -> {
      pipeTo(dst, $handler);
    });
  }

  
When a WebSocket is created it automatically registers an event handler with the event bus - the ID of that
handler is given by this method.

Given this ID, a different event loop can send a binary frame to that event handler using the event bus and
that buffer will be received by this instance in its own event loop and written to the underlying connection. This
allows you to write data to other WebSockets which are owned by different event loops.
Returns:
the binary handler id/**
   * When a <code>WebSocket</code> is created it automatically registers an event handler with the event bus - the ID of that
   * handler is given by this method.
   * <p>
   * Given this ID, a different event loop can send a binary frame to that event handler using the event bus and
   * that buffer will be received by this instance in its own event loop and written to the underlying connection. This
   * allows you to write data to other WebSockets which are owned by different event loops.
   * @return the binary handler id
   */
  public String binaryHandlerID() { 
    String ret = delegate.binaryHandlerID();
    return ret;
  }

  
When a WebSocket is created it automatically registers an event handler with the eventbus, the ID of that
handler is given by textHandlerID.

Given this ID, a different event loop can send a text frame to that event handler using the event bus and
that buffer will be received by this instance in its own event loop and written to the underlying connection. This
allows you to write data to other WebSockets which are owned by different event loops.
Returns:
/**
   * When a <code>WebSocket</code> is created it automatically registers an event handler with the eventbus, the ID of that
   * handler is given by <code>textHandlerID</code>.
   * <p>
   * Given this ID, a different event loop can send a text frame to that event handler using the event bus and
   * that buffer will be received by this instance in its own event loop and written to the underlying connection. This
   * allows you to write data to other WebSockets which are owned by different event loops.
   * @return 
   */
  public String textHandlerID() { 
    String ret = delegate.textHandlerID();
    return ret;
  }

  
Returns the WebSocket sub protocol selected by the WebSocket handshake.

On the server, the value will be null when the handler receives the WebSocket callback as the
handshake will not be completed yet.
Returns:
/**
   * Returns the WebSocket sub protocol selected by the WebSocket handshake.
   * <p/>
   * On the server, the value will be <code>null</code> when the handler receives the WebSocket callback as the
   * handshake will not be completed yet.
   * @return 
   */
  public String subProtocol() { 
    String ret = delegate.subProtocol();
    return ret;
  }

  
Returns the close status code received from the remote endpoint or null when not yet received.
Returns:
/**
   * Returns the close status code received from the remote endpoint or <code>null</code> when not yet received.
   * @return 
   */
  public Short closeStatusCode() { 
    Short ret = delegate.closeStatusCode();
    return ret;
  }

  
Returns the close reason message from the remote endpoint or null when not yet received.
Returns:
/**
   * Returns the close reason message from the remote endpoint or <code>null</code> when not yet received.
   * @return 
   */
  public String closeReason() { 
    String ret = delegate.closeReason();
    return ret;
  }

  
 Returns the HTTP headers when the WebSocket is first obtained in the handler.
 

 The headers will be null on subsequent interactions.
Returns:
the headers/**
   *  Returns the HTTP headers when the WebSocket is first obtained in the handler.
   *  <p/>
   *  The headers will be <code>null</code> on subsequent interactions.
   * @return the headers
   */
  public io.vertx.reactivex.core.MultiMap headers() { 
    io.vertx.reactivex.core.MultiMap ret = io.vertx.reactivex.core.MultiMap.newInstance((io.vertx.core.MultiMap)delegate.headers());
    return ret;
  }

  
Writes a ping frame to the connection. This will be written in a single frame. Ping frames may be at most 125 bytes (octets).

This method should not be used to write application data and should only be used for implementing a keep alive or
to ensure the client is still responsive, see RFC 6455 Section section 5.5.2.

There is no handler for ping frames because RFC 6455  clearly
states that the only response to a ping frame is a pong frame with identical contents.
Params:
data – the data to write, may be at most 125 bytes
handler – called when the ping frame has been successfully written
Returns:
a reference to this, so the API can be used fluently/**
   * Writes a ping frame to the connection. This will be written in a single frame. Ping frames may be at most 125 bytes (octets).
   * <p>
   * This method should not be used to write application data and should only be used for implementing a keep alive or
   * to ensure the client is still responsive, see RFC 6455 Section <a href="https://tools.ietf.org/html/rfc6455#section-5.5.2">section 5.5.2</a>.
   * <p>
   * There is no handler for ping frames because RFC 6455  clearly
   * states that the only response to a ping frame is a pong frame with identical contents.
   * @param data the data to write, may be at most 125 bytes
   * @param handler called when the ping frame has been successfully written
   * @return a reference to this, so the API can be used fluently
   */
  public io.vertx.reactivex.core.http.WebSocketBase writePing(io.vertx.reactivex.core.buffer.Buffer data, Handler<AsyncResult<Void>> handler) { 
    delegate.writePing(data.getDelegate(), handler);
    return this;
  }

  
Writes a ping frame to the connection. This will be written in a single frame. Ping frames may be at most 125 bytes (octets).

This method should not be used to write application data and should only be used for implementing a keep alive or
to ensure the client is still responsive, see RFC 6455 Section section 5.5.2.

There is no handler for ping frames because RFC 6455  clearly
states that the only response to a ping frame is a pong frame with identical contents.
Params:
data – the data to write, may be at most 125 bytes
Returns:
a reference to this, so the API can be used fluently/**
   * Writes a ping frame to the connection. This will be written in a single frame. Ping frames may be at most 125 bytes (octets).
   * <p>
   * This method should not be used to write application data and should only be used for implementing a keep alive or
   * to ensure the client is still responsive, see RFC 6455 Section <a href="https://tools.ietf.org/html/rfc6455#section-5.5.2">section 5.5.2</a>.
   * <p>
   * There is no handler for ping frames because RFC 6455  clearly
   * states that the only response to a ping frame is a pong frame with identical contents.
   * @param data the data to write, may be at most 125 bytes
   * @return a reference to this, so the API can be used fluently
   */
  public io.vertx.reactivex.core.http.WebSocketBase writePing(io.vertx.reactivex.core.buffer.Buffer data) {
    return 
writePing(data, ar -> { });
  }

  
Writes a ping frame to the connection. This will be written in a single frame. Ping frames may be at most 125 bytes (octets).

This method should not be used to write application data and should only be used for implementing a keep alive or
to ensure the client is still responsive, see RFC 6455 Section section 5.5.2.

There is no handler for ping frames because RFC 6455  clearly
states that the only response to a ping frame is a pong frame with identical contents.
Params:
data – the data to write, may be at most 125 bytes
Returns:
a reference to this, so the API can be used fluently/**
   * Writes a ping frame to the connection. This will be written in a single frame. Ping frames may be at most 125 bytes (octets).
   * <p>
   * This method should not be used to write application data and should only be used for implementing a keep alive or
   * to ensure the client is still responsive, see RFC 6455 Section <a href="https://tools.ietf.org/html/rfc6455#section-5.5.2">section 5.5.2</a>.
   * <p>
   * There is no handler for ping frames because RFC 6455  clearly
   * states that the only response to a ping frame is a pong frame with identical contents.
   * @param data the data to write, may be at most 125 bytes
   * @return a reference to this, so the API can be used fluently
   */
  public io.reactivex.Completable rxWritePing(io.vertx.reactivex.core.buffer.Buffer data) { 
    return AsyncResultCompletable.toCompletable($handler -> {
      writePing(data, $handler);
    });
  }

  
Writes a pong frame to the connection. This will be written in a single frame. Pong frames may be at most 125 bytes (octets).

This method should not be used to write application data and should only be used for implementing a keep alive or
to ensure the client is still responsive, see RFC 6455 section 5.5.2.

There is no need to manually write a pong frame, as the server and client both handle responding to a ping from with a pong from
automatically and this is exposed to users. RFC 6455 section 5.5.3 states that pongs may be sent unsolicited in order
to implement a one way heartbeat.
Params:
data – the data to write, may be at most 125 bytes
handler – called when the pong frame has been successfully written
Returns:
a reference to this, so the API can be used fluently/**
   * Writes a pong frame to the connection. This will be written in a single frame. Pong frames may be at most 125 bytes (octets).
   * <p>
   * This method should not be used to write application data and should only be used for implementing a keep alive or
   * to ensure the client is still responsive, see RFC 6455 <a href="https://tools.ietf.org/html/rfc6455#section-5.5.2">section 5.5.2</a>.
   * <p>
   * There is no need to manually write a pong frame, as the server and client both handle responding to a ping from with a pong from
   * automatically and this is exposed to users. RFC 6455 <a href="https://tools.ietf.org/html/rfc6455#section-5.5.3">section 5.5.3</a> states that pongs may be sent unsolicited in order
   * to implement a one way heartbeat.
   * @param data the data to write, may be at most 125 bytes
   * @param handler called when the pong frame has been successfully written
   * @return a reference to this, so the API can be used fluently
   */
  public io.vertx.reactivex.core.http.WebSocketBase writePong(io.vertx.reactivex.core.buffer.Buffer data, Handler<AsyncResult<Void>> handler) { 
    delegate.writePong(data.getDelegate(), handler);
    return this;
  }

  
Writes a pong frame to the connection. This will be written in a single frame. Pong frames may be at most 125 bytes (octets).

This method should not be used to write application data and should only be used for implementing a keep alive or
to ensure the client is still responsive, see RFC 6455 section 5.5.2.

There is no need to manually write a pong frame, as the server and client both handle responding to a ping from with a pong from
automatically and this is exposed to users. RFC 6455 section 5.5.3 states that pongs may be sent unsolicited in order
to implement a one way heartbeat.
Params:
data – the data to write, may be at most 125 bytes
Returns:
a reference to this, so the API can be used fluently/**
   * Writes a pong frame to the connection. This will be written in a single frame. Pong frames may be at most 125 bytes (octets).
   * <p>
   * This method should not be used to write application data and should only be used for implementing a keep alive or
   * to ensure the client is still responsive, see RFC 6455 <a href="https://tools.ietf.org/html/rfc6455#section-5.5.2">section 5.5.2</a>.
   * <p>
   * There is no need to manually write a pong frame, as the server and client both handle responding to a ping from with a pong from
   * automatically and this is exposed to users. RFC 6455 <a href="https://tools.ietf.org/html/rfc6455#section-5.5.3">section 5.5.3</a> states that pongs may be sent unsolicited in order
   * to implement a one way heartbeat.
   * @param data the data to write, may be at most 125 bytes
   * @return a reference to this, so the API can be used fluently
   */
  public io.vertx.reactivex.core.http.WebSocketBase writePong(io.vertx.reactivex.core.buffer.Buffer data) {
    return 
writePong(data, ar -> { });
  }

  
Writes a pong frame to the connection. This will be written in a single frame. Pong frames may be at most 125 bytes (octets).

This method should not be used to write application data and should only be used for implementing a keep alive or
to ensure the client is still responsive, see RFC 6455 section 5.5.2.

There is no need to manually write a pong frame, as the server and client both handle responding to a ping from with a pong from
automatically and this is exposed to users. RFC 6455 section 5.5.3 states that pongs may be sent unsolicited in order
to implement a one way heartbeat.
Params:
data – the data to write, may be at most 125 bytes
Returns:
a reference to this, so the API can be used fluently/**
   * Writes a pong frame to the connection. This will be written in a single frame. Pong frames may be at most 125 bytes (octets).
   * <p>
   * This method should not be used to write application data and should only be used for implementing a keep alive or
   * to ensure the client is still responsive, see RFC 6455 <a href="https://tools.ietf.org/html/rfc6455#section-5.5.2">section 5.5.2</a>.
   * <p>
   * There is no need to manually write a pong frame, as the server and client both handle responding to a ping from with a pong from
   * automatically and this is exposed to users. RFC 6455 <a href="https://tools.ietf.org/html/rfc6455#section-5.5.3">section 5.5.3</a> states that pongs may be sent unsolicited in order
   * to implement a one way heartbeat.
   * @param data the data to write, may be at most 125 bytes
   * @return a reference to this, so the API can be used fluently
   */
  public io.reactivex.Completable rxWritePong(io.vertx.reactivex.core.buffer.Buffer data) { 
    return AsyncResultCompletable.toCompletable($handler -> {
      writePong(data, $handler);
    });
  }

  
Set a text message handler on the connection. This handler will be called similar to the
, but the buffer will be converted to a String first
Params:
handler – the handler
Returns:
a reference to this, so the API can be used fluently/**
   * Set a text message handler on the connection. This handler will be called similar to the
   * , but the buffer will be converted to a String first
   * @param handler the handler
   * @return a reference to this, so the API can be used fluently
   */
  public io.vertx.reactivex.core.http.WebSocketBase textMessageHandler(Handler<String> handler) { 
    delegate.textMessageHandler(handler);
    return this;
  }

  
Set a binary message handler on the connection. This handler serves a similar purpose to handler except that if a message comes into the socket in multiple frames, the data from the frames will be aggregated into a single buffer before calling the handler (using WebSocketFrame.isFinal to find the boundaries). 
Params:
handler – the handler
Returns:
a reference to this, so the API can be used fluently/**
   * Set a binary message handler on the connection. This handler serves a similar purpose to {@link io.vertx.reactivex.core.http.WebSocket#handler}
   * except that if a message comes into the socket in multiple frames, the data from the frames will be aggregated
   * into a single buffer before calling the handler (using {@link io.vertx.reactivex.core.http.WebSocketFrame#isFinal} to find the boundaries).
   * @param handler the handler
   * @return a reference to this, so the API can be used fluently
   */
  public io.vertx.reactivex.core.http.WebSocketBase binaryMessageHandler(Handler<io.vertx.reactivex.core.buffer.Buffer> handler) { 
    delegate.binaryMessageHandler(new Handler<io.vertx.core.buffer.Buffer>() {
      public void handle(io.vertx.core.buffer.Buffer event) {
        handler.handle(io.vertx.reactivex.core.buffer.Buffer.newInstance((io.vertx.core.buffer.Buffer)event));
      }
    });
    return this;
  }

  
Set a pong frame handler on the connection.  This handler will be invoked every time a pong frame is received
on the server, and can be used by both clients and servers since the RFC 6455 section 5.5.2 and section 5.5.3 do not
specify whether the client or server sends a ping.

Pong frames may be at most 125 bytes (octets).

There is no ping handler since ping frames should immediately be responded to with a pong frame with identical content

Pong frames may be received unsolicited.
Params:
handler – the handler
Returns:
a reference to this, so the API can be used fluently/**
   * Set a pong frame handler on the connection.  This handler will be invoked every time a pong frame is received
   * on the server, and can be used by both clients and servers since the RFC 6455 <a href="https://tools.ietf.org/html/rfc6455#section-5.5.2">section 5.5.2</a> and <a href="https://tools.ietf.org/html/rfc6455#section-5.5.3">section 5.5.3</a> do not
   * specify whether the client or server sends a ping.
   * <p>
   * Pong frames may be at most 125 bytes (octets).
   * <p>
   * There is no ping handler since ping frames should immediately be responded to with a pong frame with identical content
   * <p>
   * Pong frames may be received unsolicited.
   * @param handler the handler
   * @return a reference to this, so the API can be used fluently
   */
  public io.vertx.reactivex.core.http.WebSocketBase pongHandler(Handler<io.vertx.reactivex.core.buffer.Buffer> handler) { 
    delegate.pongHandler(new Handler<io.vertx.core.buffer.Buffer>() {
      public void handle(io.vertx.core.buffer.Buffer event) {
        handler.handle(io.vertx.reactivex.core.buffer.Buffer.newInstance((io.vertx.core.buffer.Buffer)event));
      }
    });
    return this;
  }

  
Calls WebSocketBase.close 
Params:
handler – /**
   * 
   *
   * Calls {@link io.vertx.reactivex.core.http.WebSocketBase#close}
   * @param handler 
   */
  public void end(Handler<AsyncResult<Void>> handler) { 
    delegate.end(handler);
  }

  
Calls WebSocketBase.close /**
   * 
   *
   * Calls {@link io.vertx.reactivex.core.http.WebSocketBase#close}
   */
  public void end() {
    end(ar -> { });
  }

  
Calls WebSocketBase.close 
Returns:
/**
   * 
   *
   * Calls {@link io.vertx.reactivex.core.http.WebSocketBase#close}
   * @return 
   */
  public io.reactivex.Completable rxEnd() { 
    return AsyncResultCompletable.toCompletable($handler -> {
      end($handler);
    });
  }

  
Same as WebSocketBase.close but with an handler called when the operation completes
Params:
handler – /**
   * Same as {@link io.vertx.reactivex.core.http.WebSocketBase#close} but with an <code>handler</code> called when the operation completes
   * @param handler 
   */
  public void close(Handler<AsyncResult<Void>> handler) { 
    delegate.close(handler);
  }

  
Same as WebSocketBase.close but with an handler called when the operation completes
/**
   * Same as {@link io.vertx.reactivex.core.http.WebSocketBase#close} but with an <code>handler</code> called when the operation completes
   */
  public void close() {
    close(ar -> { });
  }

  
Same as WebSocketBase.close but with an handler called when the operation completes
Returns:
/**
   * Same as {@link io.vertx.reactivex.core.http.WebSocketBase#close} but with an <code>handler</code> called when the operation completes
   * @return 
   */
  public io.reactivex.Completable rxClose() { 
    return AsyncResultCompletable.toCompletable($handler -> {
      close($handler);
    });
  }

  
Same as WebSocketBase.close but with an handler called when the operation completes
Params:
statusCode – 
handler – /**
   * Same as {@link io.vertx.reactivex.core.http.WebSocketBase#close} but with an <code>handler</code> called when the operation completes
   * @param statusCode 
   * @param handler 
   */
  public void close(short statusCode, Handler<AsyncResult<Void>> handler) { 
    delegate.close(statusCode, handler);
  }

  
Same as WebSocketBase.close but with an handler called when the operation completes
Params:
statusCode – /**
   * Same as {@link io.vertx.reactivex.core.http.WebSocketBase#close} but with an <code>handler</code> called when the operation completes
   * @param statusCode 
   */
  public void close(short statusCode) {
    close(statusCode, ar -> { });
  }

  
Same as WebSocketBase.close but with an handler called when the operation completes
Params:
statusCode – 
Returns:
/**
   * Same as {@link io.vertx.reactivex.core.http.WebSocketBase#close} but with an <code>handler</code> called when the operation completes
   * @param statusCode 
   * @return 
   */
  public io.reactivex.Completable rxClose(short statusCode) { 
    return AsyncResultCompletable.toCompletable($handler -> {
      close(statusCode, $handler);
    });
  }

  
Same as  but with an handler called when the operation completes
Params:
statusCode – 
reason – 
handler – /**
   * Same as  but with an <code>handler</code> called when the operation completes
   * @param statusCode 
   * @param reason 
   * @param handler 
   */
  public void close(short statusCode, String reason, Handler<AsyncResult<Void>> handler) { 
    delegate.close(statusCode, reason, handler);
  }

  
Same as  but with an handler called when the operation completes
Params:
statusCode – 
reason – /**
   * Same as  but with an <code>handler</code> called when the operation completes
   * @param statusCode 
   * @param reason 
   */
  public void close(short statusCode, String reason) {
    close(statusCode, reason, ar -> { });
  }

  
Same as  but with an handler called when the operation completes
Params:
statusCode – 
reason – 
Returns:
/**
   * Same as  but with an <code>handler</code> called when the operation completes
   * @param statusCode 
   * @param reason 
   * @return 
   */
  public io.reactivex.Completable rxClose(short statusCode, String reason) { 
    return AsyncResultCompletable.toCompletable($handler -> {
      close(statusCode, reason, $handler);
    });
  }

  
Returns:
the remote address for this connection, possibly null (e.g a server bound on a domain socket). If useProxyProtocol is set to true, the address returned will be of the actual connecting client./**
   * @return the remote address for this connection, possibly <code>null</code> (e.g a server bound on a domain socket). If <code>useProxyProtocol</code> is set to <code>true</code>, the address returned will be of the actual connecting client.
   */
  public io.vertx.reactivex.core.net.SocketAddress remoteAddress() { 
    if (cached_0 != null) {
      return cached_0;
    }
    io.vertx.reactivex.core.net.SocketAddress ret = io.vertx.reactivex.core.net.SocketAddress.newInstance((io.vertx.core.net.SocketAddress)delegate.remoteAddress());
    cached_0 = ret;
    return ret;
  }

  
Returns:
the local address for this connection, possibly null (e.g a server bound on a domain socket) If useProxyProtocol is set to true, the address returned will be of the proxy./**
   * @return the local address for this connection, possibly <code>null</code> (e.g a server bound on a domain socket) If <code>useProxyProtocol</code> is set to <code>true</code>, the address returned will be of the proxy.
   */
  public io.vertx.reactivex.core.net.SocketAddress localAddress() { 
    if (cached_1 != null) {
      return cached_1;
    }
    io.vertx.reactivex.core.net.SocketAddress ret = io.vertx.reactivex.core.net.SocketAddress.newInstance((io.vertx.core.net.SocketAddress)delegate.localAddress());
    cached_1 = ret;
    return ret;
  }

  
Returns:
true if this HttpConnection is encrypted via SSL/TLS./**
   * @return true if this {@link io.vertx.reactivex.core.http.HttpConnection} is encrypted via SSL/TLS.
   */
  public boolean isSsl() { 
    boolean ret = delegate.isSsl();
    return ret;
  }

  
Returns:
true if the WebSocket is closed/**
   * @return <code>true</code> if the WebSocket is closed
   */
  public boolean isClosed() { 
    boolean ret = delegate.isClosed();
    return ret;
  }

  public io.vertx.reactivex.core.http.WebSocket exceptionHandler(Handler<java.lang.Throwable> handler) { 
    delegate.exceptionHandler(handler);
    return this;
  }

  public io.vertx.reactivex.core.http.WebSocket handler(Handler<io.vertx.reactivex.core.buffer.Buffer> handler) { 
    delegate.handler(new Handler<io.vertx.core.buffer.Buffer>() {
      public void handle(io.vertx.core.buffer.Buffer event) {
        handler.handle(io.vertx.reactivex.core.buffer.Buffer.newInstance((io.vertx.core.buffer.Buffer)event));
      }
    });
    return this;
  }

  public io.vertx.reactivex.core.http.WebSocket pause() { 
    delegate.pause();
    return this;
  }

  public io.vertx.reactivex.core.http.WebSocket resume() { 
    delegate.resume();
    return this;
  }

  public io.vertx.reactivex.core.http.WebSocket fetch(long amount) { 
    delegate.fetch(amount);
    return this;
  }

  public io.vertx.reactivex.core.http.WebSocket endHandler(Handler<Void> endHandler) { 
    delegate.endHandler(endHandler);
    return this;
  }

  public io.vertx.reactivex.core.http.WebSocket setWriteQueueMaxSize(int maxSize) { 
    delegate.setWriteQueueMaxSize(maxSize);
    return this;
  }

  public io.vertx.reactivex.core.http.WebSocket drainHandler(Handler<Void> handler) { 
    delegate.drainHandler(handler);
    return this;
  }

  public io.vertx.reactivex.core.http.WebSocket writeFrame(io.vertx.reactivex.core.http.WebSocketFrame frame, Handler<AsyncResult<Void>> handler) { 
    delegate.writeFrame(frame.getDelegate(), handler);
    return this;
  }

  public io.vertx.reactivex.core.http.WebSocket writeFrame(io.vertx.reactivex.core.http.WebSocketFrame frame) {
    return 
writeFrame(frame, ar -> { });
  }

  public io.reactivex.Completable rxWriteFrame(io.vertx.reactivex.core.http.WebSocketFrame frame) { 
    return AsyncResultCompletable.toCompletable($handler -> {
      writeFrame(frame, $handler);
    });
  }

  public io.vertx.reactivex.core.http.WebSocket writeFinalTextFrame(String text, Handler<AsyncResult<Void>> handler) { 
    delegate.writeFinalTextFrame(text, handler);
    return this;
  }

  public io.vertx.reactivex.core.http.WebSocket writeFinalTextFrame(String text) {
    return 
writeFinalTextFrame(text, ar -> { });
  }

  public io.reactivex.Completable rxWriteFinalTextFrame(String text) { 
    return AsyncResultCompletable.toCompletable($handler -> {
      writeFinalTextFrame(text, $handler);
    });
  }

  public io.vertx.reactivex.core.http.WebSocket writeFinalBinaryFrame(io.vertx.reactivex.core.buffer.Buffer data, Handler<AsyncResult<Void>> handler) { 
    delegate.writeFinalBinaryFrame(data.getDelegate(), handler);
    return this;
  }

  public io.vertx.reactivex.core.http.WebSocket writeFinalBinaryFrame(io.vertx.reactivex.core.buffer.Buffer data) {
    return 
writeFinalBinaryFrame(data, ar -> { });
  }

  public io.reactivex.Completable rxWriteFinalBinaryFrame(io.vertx.reactivex.core.buffer.Buffer data) { 
    return AsyncResultCompletable.toCompletable($handler -> {
      writeFinalBinaryFrame(data, $handler);
    });
  }

  public io.vertx.reactivex.core.http.WebSocket writeBinaryMessage(io.vertx.reactivex.core.buffer.Buffer data, Handler<AsyncResult<Void>> handler) { 
    delegate.writeBinaryMessage(data.getDelegate(), handler);
    return this;
  }

  public io.vertx.reactivex.core.http.WebSocket writeBinaryMessage(io.vertx.reactivex.core.buffer.Buffer data) {
    return 
writeBinaryMessage(data, ar -> { });
  }

  public io.reactivex.Completable rxWriteBinaryMessage(io.vertx.reactivex.core.buffer.Buffer data) { 
    return AsyncResultCompletable.toCompletable($handler -> {
      writeBinaryMessage(data, $handler);
    });
  }

  public io.vertx.reactivex.core.http.WebSocket writeTextMessage(String text, Handler<AsyncResult<Void>> handler) { 
    delegate.writeTextMessage(text, handler);
    return this;
  }

  public io.vertx.reactivex.core.http.WebSocket writeTextMessage(String text) {
    return 
writeTextMessage(text, ar -> { });
  }

  public io.reactivex.Completable rxWriteTextMessage(String text) { 
    return AsyncResultCompletable.toCompletable($handler -> {
      writeTextMessage(text, $handler);
    });
  }

  public io.vertx.reactivex.core.http.WebSocket closeHandler(Handler<Void> handler) { 
    delegate.closeHandler(handler);
    return this;
  }

  public io.vertx.reactivex.core.http.WebSocket frameHandler(Handler<io.vertx.reactivex.core.http.WebSocketFrame> handler) { 
    delegate.frameHandler(new Handler<io.vertx.core.http.WebSocketFrame>() {
      public void handle(io.vertx.core.http.WebSocketFrame event) {
        handler.handle(io.vertx.reactivex.core.http.WebSocketFrame.newInstance((io.vertx.core.http.WebSocketFrame)event));
      }
    });
    return this;
  }

  
Returns:
SSLSession associated with the underlying socket. Returns null if connection is not SSL./**
   * @return SSLSession associated with the underlying socket. Returns null if connection is not SSL.
   */
  public javax.net.ssl.SSLSession sslSession() { 
    javax.net.ssl.SSLSession ret = delegate.sslSession();
    return ret;
  }

  private io.vertx.reactivex.core.net.SocketAddress cached_0;
  private io.vertx.reactivex.core.net.SocketAddress cached_1;
  public static WebSocket newInstance(io.vertx.core.http.WebSocket arg) {
    return arg != null ? new WebSocket(arg) : null;
  }

}