src/net/server/http_server.cc - cobalt - Git at Google

 // Copyright (c) 2012 The Chromium Authors. All rights reserved.
 // Use of this source code is governed by a BSD-style license that can be
 // found in the LICENSE file.

 #include "net/server/http_server.h"

 #include <utility>

 #include "base/bind.h"
 #include "base/compiler_specific.h"
 #include "base/location.h"
 #include "base/logging.h"
 #include "base/single_thread_task_runner.h"
 #include "base/strings/string_number_conversions.h"
 #include "base/strings/string_util.h"
 #include "base/sys_byteorder.h"
 #include "base/threading/thread_task_runner_handle.h"
 #include "build/build_config.h"
 #include "net/base/net_errors.h"
 #include "net/server/http_connection.h"
 #include "net/server/http_server_request_info.h"
 #include "net/server/http_server_response_info.h"
 #include "net/server/web_socket.h"
 #include "net/socket/server_socket.h"
 #include "net/socket/stream_socket.h"
 #include "net/socket/tcp_server_socket.h"
 #include "starboard/common/socket.h"

 namespace net {

 namespace {

 constexpr NetworkTrafficAnnotationTag
     kHttpServerErrorResponseTrafficAnnotation =
         DefineNetworkTrafficAnnotation("http_server_error_response",
                                        R"(
       semantics {
         sender: "HTTP Server"
         description: "Error response from the built-in HTTP server."
         trigger: "Sending a request to the HTTP server that it can't handle."
         data: "A 500 error code."
         destination: OTHER
         destination_other: "Any destination the consumer selects."
       }
       policy {
         cookies_allowed: NO
         setting:
           "This request cannot be disabled in settings. However it will never "
           "be made unless user activates an HTTP server."
         policy_exception_justification:
           "Not implemented, not used if HTTP Server is not activated."
       })");

 }  // namespace

 HttpServer::HttpServer(std::unique_ptr<ServerSocket> server_socket,
                        HttpServer::Delegate* delegate)
     : server_socket_(std::move(server_socket)),
       delegate_(delegate),
       last_id_(0),
       weak_ptr_factory_(this) {
   DCHECK(server_socket_);
   // Start accepting connections in next run loop in case when delegate is not
   // ready to get callbacks.
   base::ThreadTaskRunnerHandle::Get()->PostTask(
       FROM_HERE,
       base::Bind(&HttpServer::DoAcceptLoop, weak_ptr_factory_.GetWeakPtr()));
 }

 HttpServer::~HttpServer() = default;

 void HttpServer::AcceptWebSocket(
     int connection_id,
     const HttpServerRequestInfo& request,
     NetworkTrafficAnnotationTag traffic_annotation) {
   HttpConnection* connection = FindConnection(connection_id);
   if (connection == NULL)
     return;
   DCHECK(connection->web_socket());
   connection->web_socket()->Accept(request, traffic_annotation);
 }

 void HttpServer::SendOverWebSocket(
     int connection_id,
     const std::string& data,
     NetworkTrafficAnnotationTag traffic_annotation) {
   HttpConnection* connection = FindConnection(connection_id);
   if (connection == NULL)
     return;
   DCHECK(connection->web_socket());
   connection->web_socket()->Send(data, traffic_annotation);
 }

 void HttpServer::SendRaw(int connection_id,
                          const std::string& data,
                          NetworkTrafficAnnotationTag traffic_annotation) {
   HttpConnection* connection = FindConnection(connection_id);
   if (connection == NULL)
     return;

   bool writing_in_progress = !connection->write_buf()->IsEmpty();
   if (connection->write_buf()->Append(data) && !writing_in_progress)
     DoWriteLoop(connection, traffic_annotation);
 }

 void HttpServer::SendResponse(int connection_id,
                               const HttpServerResponseInfo& response,
                               NetworkTrafficAnnotationTag traffic_annotation) {
   SendRaw(connection_id, response.Serialize(), traffic_annotation);
 }

 void HttpServer::Send(int connection_id,
                       HttpStatusCode status_code,
                       const std::string& data,
                       const std::string& content_type,
                       NetworkTrafficAnnotationTag traffic_annotation) {
   HttpServerResponseInfo response(status_code);
   response.SetContentHeaders(data.size(), content_type);
   SendResponse(connection_id, response, traffic_annotation);
   SendRaw(connection_id, data, traffic_annotation);
 }

 void HttpServer::Send200(int connection_id,
                          const std::string& data,
                          const std::string& content_type,
                          NetworkTrafficAnnotationTag traffic_annotation) {
   Send(connection_id, HTTP_OK, data, content_type, traffic_annotation);
 }

 void HttpServer::Send404(int connection_id,
                          NetworkTrafficAnnotationTag traffic_annotation) {
   SendResponse(connection_id, HttpServerResponseInfo::CreateFor404(),
                traffic_annotation);
 }

 void HttpServer::Send500(int connection_id,
                          const std::string& message,
                          NetworkTrafficAnnotationTag traffic_annotation) {
   SendResponse(connection_id, HttpServerResponseInfo::CreateFor500(message),
                traffic_annotation);
 }

 void HttpServer::Close(int connection_id) {
   auto it = id_to_connection_.find(connection_id);
   if (it == id_to_connection_.end())
     return;

   std::unique_ptr<HttpConnection> connection = std::move(it->second);
   id_to_connection_.erase(it);
   delegate_->OnClose(connection_id);

   // The call stack might have callbacks which still have the pointer of
   // connection. Instead of referencing connection with ID all the time,
   // destroys the connection in next run loop to make sure any pending
   // callbacks in the call stack return.
   base::ThreadTaskRunnerHandle::Get()->DeleteSoon(FROM_HERE,
                                                   connection.release());
 }

 int HttpServer::GetLocalAddress(IPEndPoint* address) {
   return server_socket_->GetLocalAddress(address);
 }

 #if defined(STARBOARD)
 int HttpServer::GetLocalInterfaceAddress(IPEndPoint* address) {
   int result = GetLocalAddress(address);
   if (result != net::OK) {
     DLOG(ERROR) << "Error getting server local address.";
     return result;
   }

   // If listening to INADDR_ANY get an interface IP address.
   if (address->address().IsZero()) {
     SbSocketAddress any_ip;
     memset(&(any_ip.address), 0, sizeof(any_ip.address));
     SbSocketAddress interface_address;
     // Prefer to report the interface's IPv4 address.
     any_ip.type = kSbSocketAddressTypeIpv4;
     if (!SbSocketGetInterfaceAddress(&any_ip, &interface_address, nullptr)) {
       any_ip.type = kSbSocketAddressTypeIpv6;
       if (!SbSocketGetInterfaceAddress(&any_ip, &interface_address, nullptr)) {
         DLOG(ERROR) << "Error getting interface address.";
         return ERR_FAILED;
       }
     }
     interface_address.port = address->port();
     if (!address->FromSbSocketAddress(&interface_address)) {
       DLOG(ERROR) << "Error converting socket address.";
       return ERR_FAILED;
     }
   }

   return OK;
 }
 #endif  // defined(STARBOARD)

 void HttpServer::SetReceiveBufferSize(int connection_id, int32_t size) {
   HttpConnection* connection = FindConnection(connection_id);
   if (connection)
     connection->read_buf()->set_max_buffer_size(size);
 }

 void HttpServer::SetSendBufferSize(int connection_id, int32_t size) {
   HttpConnection* connection = FindConnection(connection_id);
   if (connection)
     connection->write_buf()->set_max_buffer_size(size);
 }

 void HttpServer::DoAcceptLoop() {
   int rv;
   do {
     rv = server_socket_->Accept(&accepted_socket_,
                                 base::Bind(&HttpServer::OnAcceptCompleted,
                                            weak_ptr_factory_.GetWeakPtr()));
     if (rv == ERR_IO_PENDING)
       return;
     rv = HandleAcceptResult(rv);
   } while (rv == OK);
 }

 void HttpServer::OnAcceptCompleted(int rv) {
   if (HandleAcceptResult(rv) == OK)
     DoAcceptLoop();
 }

 int HttpServer::HandleAcceptResult(int rv) {
   if (rv < 0) {
     LOG(ERROR) << "Accept error: rv=" << rv;
     return rv;
   }

   std::unique_ptr<HttpConnection> connection_ptr =
       std::make_unique<HttpConnection>(++last_id_, std::move(accepted_socket_));
   HttpConnection* connection = connection_ptr.get();
   id_to_connection_[connection->id()] = std::move(connection_ptr);
   delegate_->OnConnect(connection->id());
   if (!HasClosedConnection(connection))
     DoReadLoop(connection);
   return OK;
 }

 void HttpServer::DoReadLoop(HttpConnection* connection) {
   int rv;
   do {
     HttpConnection::ReadIOBuffer* read_buf = connection->read_buf();
     // Increases read buffer size if necessary.
     if (read_buf->RemainingCapacity() == 0 && !read_buf->IncreaseCapacity()) {
       Close(connection->id());
       return;
     }

     rv = connection->socket()->Read(
         read_buf,
         read_buf->RemainingCapacity(),
         base::Bind(&HttpServer::OnReadCompleted,
                    weak_ptr_factory_.GetWeakPtr(), connection->id()));
     if (rv == ERR_IO_PENDING)
       return;
     rv = HandleReadResult(connection, rv);
   } while (rv == OK);
 }

 void HttpServer::OnReadCompleted(int connection_id, int rv) {
   HttpConnection* connection = FindConnection(connection_id);
   if (!connection)  // It might be closed right before by write error.
     return;

   if (HandleReadResult(connection, rv) == OK)
     DoReadLoop(connection);
 }

 int HttpServer::HandleReadResult(HttpConnection* connection, int rv) {
   if (rv <= 0) {
     Close(connection->id());
     return rv == 0 ? ERR_CONNECTION_CLOSED : rv;
   }

   HttpConnection::ReadIOBuffer* read_buf = connection->read_buf();
   read_buf->DidRead(rv);

   // Handles http requests or websocket messages.
   while (read_buf->GetSize() > 0) {
     if (connection->web_socket()) {
       std::string message;
       WebSocket::ParseResult result = connection->web_socket()->Read(&message);
       if (result == WebSocket::FRAME_INCOMPLETE)
         break;

       if (result == WebSocket::FRAME_CLOSE ||
           result == WebSocket::FRAME_ERROR) {
         Close(connection->id());
         return ERR_CONNECTION_CLOSED;
       }
       delegate_->OnWebSocketMessage(connection->id(), message);
       if (HasClosedConnection(connection))
         return ERR_CONNECTION_CLOSED;
       continue;
     }

     HttpServerRequestInfo request;
     size_t pos = 0;
     if (!ParseHeaders(read_buf->StartOfBuffer(), read_buf->GetSize(),
                       &request, &pos)) {
       // An error has occured. Close the connection.
       Close(connection->id());
       return ERR_CONNECTION_CLOSED;
     } else if (!pos) {
       // If pos is 0, all the data in read_buf has been consumed, but the
       // headers have not been fully parsed yet. Continue parsing when more data
       // rolls in.
       break;
     }

     // Sets peer address if exists.
     connection->socket()->GetPeerAddress(&request.peer);

     if (request.HasHeaderValue("connection", "upgrade")) {
       connection->SetWebSocket(std::make_unique<WebSocket>(this, connection));
       read_buf->DidConsume(pos);
       delegate_->OnWebSocketRequest(connection->id(), request);
       if (HasClosedConnection(connection))
         return ERR_CONNECTION_CLOSED;
       continue;
     }

     const char kContentLength[] = "content-length";
     if (request.headers.count(kContentLength) > 0) {
       size_t content_length = 0;
       const size_t kMaxBodySize = 100 << 20;
       if (!base::StringToSizeT(request.GetHeaderValue(kContentLength),
                                &content_length) ||
           content_length > kMaxBodySize) {
         SendResponse(connection->id(),
                      HttpServerResponseInfo::CreateFor500(
                          "request content-length too big or unknown."),
                      kHttpServerErrorResponseTrafficAnnotation);
         Close(connection->id());
         return ERR_CONNECTION_CLOSED;
       }

       if (read_buf->GetSize() - pos < content_length)
         break;  // Not enough data was received yet.
       request.data.assign(read_buf->StartOfBuffer() + pos, content_length);
       pos += content_length;
     }

     read_buf->DidConsume(pos);
     delegate_->OnHttpRequest(connection->id(), request);
     if (HasClosedConnection(connection))
       return ERR_CONNECTION_CLOSED;
   }

   return OK;
 }

 void HttpServer::DoWriteLoop(HttpConnection* connection,
                              NetworkTrafficAnnotationTag traffic_annotation) {
   int rv = OK;
   HttpConnection::QueuedWriteIOBuffer* write_buf = connection->write_buf();
   while (rv == OK && write_buf->GetSizeToWrite() > 0) {
     rv = connection->socket()->Write(
         write_buf, write_buf->GetSizeToWrite(),
         base::Bind(&HttpServer::OnWriteCompleted,
                    weak_ptr_factory_.GetWeakPtr(), connection->id(),
                    traffic_annotation),
         traffic_annotation);
     if (rv == ERR_IO_PENDING || rv == OK)
       return;
     rv = HandleWriteResult(connection, rv);
   }
 }

 void HttpServer::OnWriteCompleted(
     int connection_id,
     NetworkTrafficAnnotationTag traffic_annotation,
     int rv) {
   HttpConnection* connection = FindConnection(connection_id);
   if (!connection)  // It might be closed right before by read error.
     return;

   if (HandleWriteResult(connection, rv) == OK)
     DoWriteLoop(connection, traffic_annotation);
 }

 int HttpServer::HandleWriteResult(HttpConnection* connection, int rv) {
   if (rv < 0) {
     Close(connection->id());
     return rv;
   }

   connection->write_buf()->DidConsume(rv);
   return OK;
 }

 namespace {

 //
 // HTTP Request Parser
 // This HTTP request parser uses a simple state machine to quickly parse
 // through the headers.  The parser is not 100% complete, as it is designed
 // for use in this simple test driver.
 //
 // Known issues:
 //   - does not handle whitespace on first HTTP line correctly.  Expects
 //     a single space between the method/url and url/protocol.

 // Input character types.
 enum header_parse_inputs {
   INPUT_LWS,
   INPUT_CR,
   INPUT_LF,
   INPUT_COLON,
   INPUT_DEFAULT,
   MAX_INPUTS,
 };

 // Parser states.
 enum header_parse_states {
   ST_METHOD,     // Receiving the method
   ST_URL,        // Receiving the URL
   ST_PROTO,      // Receiving the protocol
   ST_HEADER,     // Starting a Request Header
   ST_NAME,       // Receiving a request header name
   ST_SEPARATOR,  // Receiving the separator between header name and value
   ST_VALUE,      // Receiving a request header value
   ST_DONE,       // Parsing is complete and successful
   ST_ERR,        // Parsing encountered invalid syntax.
   MAX_STATES
 };

 // State transition table
 const int parser_state[MAX_STATES][MAX_INPUTS] = {
     /* METHOD    */ {ST_URL, ST_ERR, ST_ERR, ST_ERR, ST_METHOD},
     /* URL       */ {ST_PROTO, ST_ERR, ST_ERR, ST_URL, ST_URL},
     /* PROTOCOL  */ {ST_ERR, ST_HEADER, ST_NAME, ST_ERR, ST_PROTO},
     /* HEADER    */ {ST_ERR, ST_ERR, ST_NAME, ST_ERR, ST_ERR},
     /* NAME      */ {ST_SEPARATOR, ST_DONE, ST_ERR, ST_VALUE, ST_NAME},
     /* SEPARATOR */ {ST_SEPARATOR, ST_ERR, ST_ERR, ST_VALUE, ST_ERR},
     /* VALUE     */ {ST_VALUE, ST_HEADER, ST_NAME, ST_VALUE, ST_VALUE},
     /* DONE      */ {ST_DONE, ST_DONE, ST_DONE, ST_DONE, ST_DONE},
     /* ERR       */ {ST_ERR, ST_ERR, ST_ERR, ST_ERR, ST_ERR}};

 // Convert an input character to the parser's input token.
 int charToInput(char ch) {
   switch (ch) {
     case ' ':
     case '\t':
       return INPUT_LWS;
     case '\r':
       return INPUT_CR;
     case '\n':
       return INPUT_LF;
     case ':':
       return INPUT_COLON;
   }
   return INPUT_DEFAULT;
 }

 }  // namespace

 bool HttpServer::ParseHeaders(const char* data,
                               size_t data_len,
                               HttpServerRequestInfo* info,
                               size_t* ppos) {
   size_t& pos = *ppos;
   int state = ST_METHOD;
   std::string buffer;
   std::string header_name;
   std::string header_value;
   while (pos < data_len) {
     char ch = data[pos++];
     int input = charToInput(ch);
     int next_state = parser_state[state][input];

     bool transition = (next_state != state);
     HttpServerRequestInfo::HeadersMap::iterator it;
     if (transition) {
       // Do any actions based on state transitions.
       switch (state) {
         case ST_METHOD:
           info->method = buffer;
           buffer.clear();
           break;
         case ST_URL:
           info->path = buffer;
           buffer.clear();
           break;
         case ST_PROTO:
           if (buffer != "HTTP/1.1") {
             LOG(ERROR) << "Cannot handle request with protocol: " << buffer;
             next_state = ST_ERR;
           }
           buffer.clear();
           break;
         case ST_NAME:
           header_name = base::ToLowerASCII(buffer);
           buffer.clear();
           break;
         case ST_VALUE:
           base::TrimWhitespaceASCII(buffer, base::TRIM_LEADING, &header_value);
           it = info->headers.find(header_name);
           // See the second paragraph ("A sender MUST NOT generate multiple
           // header fields...") of tools.ietf.org/html/rfc7230#section-3.2.2.
           if (it == info->headers.end()) {
             info->headers[header_name] = header_value;
           } else {
             it->second.append(",");
             it->second.append(header_value);
           }
           buffer.clear();
           break;
         case ST_SEPARATOR:
           break;
       }
       state = next_state;
     } else {
       // Do any actions based on current state
       switch (state) {
         case ST_METHOD:
         case ST_URL:
         case ST_PROTO:
         case ST_VALUE:
         case ST_NAME:
           buffer.append(&ch, 1);
           break;
         case ST_DONE:
           // We got CR to get this far, also need the LF
           return (input == INPUT_LF);
         case ST_ERR:
           return false;
       }
     }
   }
   // No more characters, but we haven't finished parsing yet. Signal this to
   // the caller by setting |pos| to zero.
   pos = 0;
   return true;
 }

 HttpConnection* HttpServer::FindConnection(int connection_id) {
   auto it = id_to_connection_.find(connection_id);
   if (it == id_to_connection_.end())
     return nullptr;
   return it->second.get();
 }

 // This is called after any delegate callbacks are called to check if Close()
 // has been called during callback processing. Using the pointer of connection,
 // |connection| is safe here because Close() deletes the connection in next run
 // loop.
 bool HttpServer::HasClosedConnection(HttpConnection* connection) {
   return FindConnection(connection->id()) != connection;
 }

 }  // namespace net
	// Copyright (c) 2012 The Chromium Authors. All rights reserved.
	// Use of this source code is governed by a BSD-style license that can be
	// found in the LICENSE file.

	#include "net/server/http_server.h"

	#include <utility>

	#include "base/bind.h"
	#include "base/compiler_specific.h"
	#include "base/location.h"
	#include "base/logging.h"
	#include "base/single_thread_task_runner.h"
	#include "base/strings/string_number_conversions.h"
	#include "base/strings/string_util.h"
	#include "base/sys_byteorder.h"
	#include "base/threading/thread_task_runner_handle.h"
	#include "build/build_config.h"
	#include "net/base/net_errors.h"
	#include "net/server/http_connection.h"
	#include "net/server/http_server_request_info.h"
	#include "net/server/http_server_response_info.h"
	#include "net/server/web_socket.h"
	#include "net/socket/server_socket.h"
	#include "net/socket/stream_socket.h"
	#include "net/socket/tcp_server_socket.h"
	#include "starboard/common/socket.h"

	namespace net {

	namespace {

	constexpr NetworkTrafficAnnotationTag
	kHttpServerErrorResponseTrafficAnnotation =
	DefineNetworkTrafficAnnotation("http_server_error_response",
	R"(
	semantics {
	sender: "HTTP Server"
	description: "Error response from the built-in HTTP server."
	trigger: "Sending a request to the HTTP server that it can't handle."
	data: "A 500 error code."
	destination: OTHER
	destination_other: "Any destination the consumer selects."
	}
	policy {
	cookies_allowed: NO
	setting:
	"This request cannot be disabled in settings. However it will never "
	"be made unless user activates an HTTP server."
	policy_exception_justification:
	"Not implemented, not used if HTTP Server is not activated."
	})");

	} // namespace

	HttpServer::HttpServer(std::unique_ptr<ServerSocket> server_socket,
	HttpServer::Delegate* delegate)
	: server_socket_(std::move(server_socket)),
	delegate_(delegate),
	last_id_(0),
	weak_ptr_factory_(this) {
	DCHECK(server_socket_);
	// Start accepting connections in next run loop in case when delegate is not
	// ready to get callbacks.
	base::ThreadTaskRunnerHandle::Get()->PostTask(
	FROM_HERE,
	base::Bind(&HttpServer::DoAcceptLoop, weak_ptr_factory_.GetWeakPtr()));
	}

	HttpServer::~HttpServer() = default;

	void HttpServer::AcceptWebSocket(
	int connection_id,
	const HttpServerRequestInfo& request,
	NetworkTrafficAnnotationTag traffic_annotation) {
	HttpConnection* connection = FindConnection(connection_id);
	if (connection == NULL)
	return;
	DCHECK(connection->web_socket());
	connection->web_socket()->Accept(request, traffic_annotation);
	}

	void HttpServer::SendOverWebSocket(
	int connection_id,
	const std::string& data,
	NetworkTrafficAnnotationTag traffic_annotation) {
	HttpConnection* connection = FindConnection(connection_id);
	if (connection == NULL)
	return;
	DCHECK(connection->web_socket());
	connection->web_socket()->Send(data, traffic_annotation);
	}

	void HttpServer::SendRaw(int connection_id,
	const std::string& data,
	NetworkTrafficAnnotationTag traffic_annotation) {
	HttpConnection* connection = FindConnection(connection_id);
	if (connection == NULL)
	return;

	bool writing_in_progress = !connection->write_buf()->IsEmpty();
	if (connection->write_buf()->Append(data) && !writing_in_progress)
	DoWriteLoop(connection, traffic_annotation);
	}

	void HttpServer::SendResponse(int connection_id,
	const HttpServerResponseInfo& response,
	NetworkTrafficAnnotationTag traffic_annotation) {
	SendRaw(connection_id, response.Serialize(), traffic_annotation);
	}

	void HttpServer::Send(int connection_id,
	HttpStatusCode status_code,
	const std::string& data,
	const std::string& content_type,
	NetworkTrafficAnnotationTag traffic_annotation) {
	HttpServerResponseInfo response(status_code);
	response.SetContentHeaders(data.size(), content_type);
	SendResponse(connection_id, response, traffic_annotation);
	SendRaw(connection_id, data, traffic_annotation);
	}

	void HttpServer::Send200(int connection_id,
	const std::string& data,
	const std::string& content_type,
	NetworkTrafficAnnotationTag traffic_annotation) {
	Send(connection_id, HTTP_OK, data, content_type, traffic_annotation);
	}

	void HttpServer::Send404(int connection_id,
	NetworkTrafficAnnotationTag traffic_annotation) {
	SendResponse(connection_id, HttpServerResponseInfo::CreateFor404(),
	traffic_annotation);
	}

	void HttpServer::Send500(int connection_id,
	const std::string& message,
	NetworkTrafficAnnotationTag traffic_annotation) {
	SendResponse(connection_id, HttpServerResponseInfo::CreateFor500(message),
	traffic_annotation);
	}

	void HttpServer::Close(int connection_id) {
	auto it = id_to_connection_.find(connection_id);
	if (it == id_to_connection_.end())
	return;

	std::unique_ptr<HttpConnection> connection = std::move(it->second);
	id_to_connection_.erase(it);
	delegate_->OnClose(connection_id);

	// The call stack might have callbacks which still have the pointer of
	// connection. Instead of referencing connection with ID all the time,
	// destroys the connection in next run loop to make sure any pending
	// callbacks in the call stack return.
	base::ThreadTaskRunnerHandle::Get()->DeleteSoon(FROM_HERE,
	connection.release());
	}

	int HttpServer::GetLocalAddress(IPEndPoint* address) {
	return server_socket_->GetLocalAddress(address);
	}

	#if defined(STARBOARD)
	int HttpServer::GetLocalInterfaceAddress(IPEndPoint* address) {
	int result = GetLocalAddress(address);
	if (result != net::OK) {
	DLOG(ERROR) << "Error getting server local address.";
	return result;
	}

	// If listening to INADDR_ANY get an interface IP address.
	if (address->address().IsZero()) {
	SbSocketAddress any_ip;
	memset(&(any_ip.address), 0, sizeof(any_ip.address));
	SbSocketAddress interface_address;
	// Prefer to report the interface's IPv4 address.
	any_ip.type = kSbSocketAddressTypeIpv4;
	if (!SbSocketGetInterfaceAddress(&any_ip, &interface_address, nullptr)) {
	any_ip.type = kSbSocketAddressTypeIpv6;
	if (!SbSocketGetInterfaceAddress(&any_ip, &interface_address, nullptr)) {
	DLOG(ERROR) << "Error getting interface address.";
	return ERR_FAILED;
	}
	}
	interface_address.port = address->port();
	if (!address->FromSbSocketAddress(&interface_address)) {
	DLOG(ERROR) << "Error converting socket address.";
	return ERR_FAILED;
	}
	}

	return OK;
	}
	#endif // defined(STARBOARD)

	void HttpServer::SetReceiveBufferSize(int connection_id, int32_t size) {
	HttpConnection* connection = FindConnection(connection_id);
	if (connection)
	connection->read_buf()->set_max_buffer_size(size);
	}

	void HttpServer::SetSendBufferSize(int connection_id, int32_t size) {
	HttpConnection* connection = FindConnection(connection_id);
	if (connection)
	connection->write_buf()->set_max_buffer_size(size);
	}

	void HttpServer::DoAcceptLoop() {
	int rv;
	do {
	rv = server_socket_->Accept(&accepted_socket_,
	base::Bind(&HttpServer::OnAcceptCompleted,
	weak_ptr_factory_.GetWeakPtr()));
	if (rv == ERR_IO_PENDING)
	return;
	rv = HandleAcceptResult(rv);
	} while (rv == OK);
	}

	void HttpServer::OnAcceptCompleted(int rv) {
	if (HandleAcceptResult(rv) == OK)
	DoAcceptLoop();
	}

	int HttpServer::HandleAcceptResult(int rv) {
	if (rv < 0) {
	LOG(ERROR) << "Accept error: rv=" << rv;
	return rv;
	}

	std::unique_ptr<HttpConnection> connection_ptr =
	std::make_unique<HttpConnection>(++last_id_, std::move(accepted_socket_));
	HttpConnection* connection = connection_ptr.get();
	id_to_connection_[connection->id()] = std::move(connection_ptr);
	delegate_->OnConnect(connection->id());
	if (!HasClosedConnection(connection))
	DoReadLoop(connection);
	return OK;
	}

	void HttpServer::DoReadLoop(HttpConnection* connection) {
	int rv;
	do {
	HttpConnection::ReadIOBuffer* read_buf = connection->read_buf();
	// Increases read buffer size if necessary.
	if (read_buf->RemainingCapacity() == 0 && !read_buf->IncreaseCapacity()) {
	Close(connection->id());
	return;
	}

	rv = connection->socket()->Read(
	read_buf,
	read_buf->RemainingCapacity(),
	base::Bind(&HttpServer::OnReadCompleted,
	weak_ptr_factory_.GetWeakPtr(), connection->id()));
	if (rv == ERR_IO_PENDING)
	return;
	rv = HandleReadResult(connection, rv);
	} while (rv == OK);
	}

	void HttpServer::OnReadCompleted(int connection_id, int rv) {
	HttpConnection* connection = FindConnection(connection_id);
	if (!connection) // It might be closed right before by write error.
	return;

	if (HandleReadResult(connection, rv) == OK)
	DoReadLoop(connection);
	}

	int HttpServer::HandleReadResult(HttpConnection* connection, int rv) {
	if (rv <= 0) {
	Close(connection->id());
	return rv == 0 ? ERR_CONNECTION_CLOSED : rv;
	}

	HttpConnection::ReadIOBuffer* read_buf = connection->read_buf();
	read_buf->DidRead(rv);

	// Handles http requests or websocket messages.
	while (read_buf->GetSize() > 0) {
	if (connection->web_socket()) {
	std::string message;
	WebSocket::ParseResult result = connection->web_socket()->Read(&message);
	if (result == WebSocket::FRAME_INCOMPLETE)
	break;

	if (result == WebSocket::FRAME_CLOSE \|\|
	result == WebSocket::FRAME_ERROR) {
	Close(connection->id());
	return ERR_CONNECTION_CLOSED;
	}
	delegate_->OnWebSocketMessage(connection->id(), message);
	if (HasClosedConnection(connection))
	return ERR_CONNECTION_CLOSED;
	continue;
	}

	HttpServerRequestInfo request;
	size_t pos = 0;
	if (!ParseHeaders(read_buf->StartOfBuffer(), read_buf->GetSize(),
	&request, &pos)) {
	// An error has occured. Close the connection.
	Close(connection->id());
	return ERR_CONNECTION_CLOSED;
	} else if (!pos) {
	// If pos is 0, all the data in read_buf has been consumed, but the
	// headers have not been fully parsed yet. Continue parsing when more data
	// rolls in.
	break;
	}

	// Sets peer address if exists.
	connection->socket()->GetPeerAddress(&request.peer);

	if (request.HasHeaderValue("connection", "upgrade")) {
	connection->SetWebSocket(std::make_unique<WebSocket>(this, connection));
	read_buf->DidConsume(pos);
	delegate_->OnWebSocketRequest(connection->id(), request);
	if (HasClosedConnection(connection))
	return ERR_CONNECTION_CLOSED;
	continue;
	}

	const char kContentLength[] = "content-length";
	if (request.headers.count(kContentLength) > 0) {
	size_t content_length = 0;
	const size_t kMaxBodySize = 100 << 20;
	if (!base::StringToSizeT(request.GetHeaderValue(kContentLength),
	&content_length) \|\|
	content_length > kMaxBodySize) {
	SendResponse(connection->id(),
	HttpServerResponseInfo::CreateFor500(
	"request content-length too big or unknown."),
	kHttpServerErrorResponseTrafficAnnotation);
	Close(connection->id());
	return ERR_CONNECTION_CLOSED;
	}

	if (read_buf->GetSize() - pos < content_length)
	break; // Not enough data was received yet.
	request.data.assign(read_buf->StartOfBuffer() + pos, content_length);
	pos += content_length;
	}

	read_buf->DidConsume(pos);
	delegate_->OnHttpRequest(connection->id(), request);
	if (HasClosedConnection(connection))
	return ERR_CONNECTION_CLOSED;
	}

	return OK;
	}

	void HttpServer::DoWriteLoop(HttpConnection* connection,
	NetworkTrafficAnnotationTag traffic_annotation) {
	int rv = OK;
	HttpConnection::QueuedWriteIOBuffer* write_buf = connection->write_buf();
	while (rv == OK && write_buf->GetSizeToWrite() > 0) {
	rv = connection->socket()->Write(
	write_buf, write_buf->GetSizeToWrite(),
	base::Bind(&HttpServer::OnWriteCompleted,
	weak_ptr_factory_.GetWeakPtr(), connection->id(),
	traffic_annotation),
	traffic_annotation);
	if (rv == ERR_IO_PENDING \|\| rv == OK)
	return;
	rv = HandleWriteResult(connection, rv);
	}
	}

	void HttpServer::OnWriteCompleted(
	int connection_id,
	NetworkTrafficAnnotationTag traffic_annotation,
	int rv) {
	HttpConnection* connection = FindConnection(connection_id);
	if (!connection) // It might be closed right before by read error.
	return;

	if (HandleWriteResult(connection, rv) == OK)
	DoWriteLoop(connection, traffic_annotation);
	}

	int HttpServer::HandleWriteResult(HttpConnection* connection, int rv) {
	if (rv < 0) {
	Close(connection->id());
	return rv;
	}

	connection->write_buf()->DidConsume(rv);
	return OK;
	}

	namespace {

	//
	// HTTP Request Parser
	// This HTTP request parser uses a simple state machine to quickly parse
	// through the headers. The parser is not 100% complete, as it is designed
	// for use in this simple test driver.
	//
	// Known issues:
	// - does not handle whitespace on first HTTP line correctly. Expects
	// a single space between the method/url and url/protocol.

	// Input character types.
	enum header_parse_inputs {
	INPUT_LWS,
	INPUT_CR,
	INPUT_LF,
	INPUT_COLON,
	INPUT_DEFAULT,
	MAX_INPUTS,
	};

	// Parser states.
	enum header_parse_states {
	ST_METHOD, // Receiving the method
	ST_URL, // Receiving the URL
	ST_PROTO, // Receiving the protocol
	ST_HEADER, // Starting a Request Header
	ST_NAME, // Receiving a request header name
	ST_SEPARATOR, // Receiving the separator between header name and value
	ST_VALUE, // Receiving a request header value
	ST_DONE, // Parsing is complete and successful
	ST_ERR, // Parsing encountered invalid syntax.
	MAX_STATES
	};

	// State transition table
	const int parser_state[MAX_STATES][MAX_INPUTS] = {
	/* METHOD */ {ST_URL, ST_ERR, ST_ERR, ST_ERR, ST_METHOD},
	/* URL */ {ST_PROTO, ST_ERR, ST_ERR, ST_URL, ST_URL},
	/* PROTOCOL */ {ST_ERR, ST_HEADER, ST_NAME, ST_ERR, ST_PROTO},
	/* HEADER */ {ST_ERR, ST_ERR, ST_NAME, ST_ERR, ST_ERR},
	/* NAME */ {ST_SEPARATOR, ST_DONE, ST_ERR, ST_VALUE, ST_NAME},
	/* SEPARATOR */ {ST_SEPARATOR, ST_ERR, ST_ERR, ST_VALUE, ST_ERR},
	/* VALUE */ {ST_VALUE, ST_HEADER, ST_NAME, ST_VALUE, ST_VALUE},
	/* DONE */ {ST_DONE, ST_DONE, ST_DONE, ST_DONE, ST_DONE},
	/* ERR */ {ST_ERR, ST_ERR, ST_ERR, ST_ERR, ST_ERR}};

	// Convert an input character to the parser's input token.
	int charToInput(char ch) {
	switch (ch) {
	case ' ':
	case '\t':
	return INPUT_LWS;
	case '\r':
	return INPUT_CR;
	case '\n':
	return INPUT_LF;
	case ':':
	return INPUT_COLON;
	}
	return INPUT_DEFAULT;
	}

	} // namespace

	bool HttpServer::ParseHeaders(const char* data,
	size_t data_len,
	HttpServerRequestInfo* info,
	size_t* ppos) {
	size_t& pos = *ppos;
	int state = ST_METHOD;
	std::string buffer;
	std::string header_name;
	std::string header_value;
	while (pos < data_len) {
	char ch = data[pos++];
	int input = charToInput(ch);
	int next_state = parser_state[state][input];

	bool transition = (next_state != state);
	HttpServerRequestInfo::HeadersMap::iterator it;
	if (transition) {
	// Do any actions based on state transitions.
	switch (state) {
	case ST_METHOD:
	info->method = buffer;
	buffer.clear();
	break;
	case ST_URL:
	info->path = buffer;
	buffer.clear();
	break;
	case ST_PROTO:
	if (buffer != "HTTP/1.1") {
	LOG(ERROR) << "Cannot handle request with protocol: " << buffer;
	next_state = ST_ERR;
	}
	buffer.clear();
	break;
	case ST_NAME:
	header_name = base::ToLowerASCII(buffer);
	buffer.clear();
	break;
	case ST_VALUE:
	base::TrimWhitespaceASCII(buffer, base::TRIM_LEADING, &header_value);
	it = info->headers.find(header_name);
	// See the second paragraph ("A sender MUST NOT generate multiple
	// header fields...") of tools.ietf.org/html/rfc7230#section-3.2.2.
	if (it == info->headers.end()) {
	info->headers[header_name] = header_value;
	} else {
	it->second.append(",");
	it->second.append(header_value);
	}
	buffer.clear();
	break;
	case ST_SEPARATOR:
	break;
	}
	state = next_state;
	} else {
	// Do any actions based on current state
	switch (state) {
	case ST_METHOD:
	case ST_URL:
	case ST_PROTO:
	case ST_VALUE:
	case ST_NAME:
	buffer.append(&ch, 1);
	break;
	case ST_DONE:
	// We got CR to get this far, also need the LF
	return (input == INPUT_LF);
	case ST_ERR:
	return false;
	}
	}
	}
	// No more characters, but we haven't finished parsing yet. Signal this to
	// the caller by setting \|pos\| to zero.
	pos = 0;
	return true;
	}

	HttpConnection* HttpServer::FindConnection(int connection_id) {
	auto it = id_to_connection_.find(connection_id);
	if (it == id_to_connection_.end())
	return nullptr;
	return it->second.get();
	}

	// This is called after any delegate callbacks are called to check if Close()
	// has been called during callback processing. Using the pointer of connection,
	// \|connection\| is safe here because Close() deletes the connection in next run
	// loop.
	bool HttpServer::HasClosedConnection(HttpConnection* connection) {
	return FindConnection(connection->id()) != connection;
	}

	} // namespace net