net/dns/dns_session.cc - chromium/src - 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/dns/dns_session.h"

 #include "base/basictypes.h"
 #include "base/bind.h"
 #include "base/lazy_instance.h"
 #include "base/metrics/histogram.h"
 #include "base/metrics/sample_vector.h"
 #include "base/rand_util.h"
 #include "base/stl_util.h"
 #include "base/time/time.h"
 #include "net/base/ip_endpoint.h"
 #include "net/base/net_errors.h"
 #include "net/dns/dns_config_service.h"
 #include "net/dns/dns_socket_pool.h"
 #include "net/socket/stream_socket.h"
 #include "net/udp/datagram_client_socket.h"

 namespace net {

 namespace {
 // Never exceed max timeout.
 const unsigned kMaxTimeoutMs = 5000;
 // Set min timeout, in case we are talking to a local DNS proxy.
 const unsigned kMinTimeoutMs = 10;

 // Number of buckets in the histogram of observed RTTs.
 const size_t kRTTBucketCount = 100;
 // Target percentile in the RTT histogram used for retransmission timeout.
 const unsigned kRTOPercentile = 99;
 }  // namespace

 // Runtime statistics of DNS server.
 struct DnsSession::ServerStats {
   ServerStats(base::TimeDelta rtt_estimate_param, RttBuckets* buckets)
     : last_failure_count(0), rtt_estimate(rtt_estimate_param) {
     rtt_histogram.reset(new base::SampleVector(buckets));
     // Seed histogram with 2 samples at |rtt_estimate| timeout.
     rtt_histogram->Accumulate(rtt_estimate.InMilliseconds(), 2);
   }

   // Count of consecutive failures after last success.
   int last_failure_count;

   // Last time when server returned failure or timeout.
   base::Time last_failure;
   // Last time when server returned success.
   base::Time last_success;

   // Estimated RTT using moving average.
   base::TimeDelta rtt_estimate;
   // Estimated error in the above.
   base::TimeDelta rtt_deviation;

   // A histogram of observed RTT .
   scoped_ptr<base::SampleVector> rtt_histogram;

   DISALLOW_COPY_AND_ASSIGN(ServerStats);
 };

 // static
 base::LazyInstance<DnsSession::RttBuckets>::Leaky DnsSession::rtt_buckets_ =
     LAZY_INSTANCE_INITIALIZER;

 DnsSession::RttBuckets::RttBuckets() : base::BucketRanges(kRTTBucketCount + 1) {
   base::Histogram::InitializeBucketRanges(1, 5000, this);
 }

 DnsSession::SocketLease::SocketLease(scoped_refptr<DnsSession> session,
                                      unsigned server_index,
                                      scoped_ptr<DatagramClientSocket> socket)
     : session_(session), server_index_(server_index), socket_(socket.Pass()) {}

 DnsSession::SocketLease::~SocketLease() {
   session_->FreeSocket(server_index_, socket_.Pass());
 }

 DnsSession::DnsSession(const DnsConfig& config,
                        scoped_ptr<DnsSocketPool> socket_pool,
                        const RandIntCallback& rand_int_callback,
                        NetLog* net_log)
     : config_(config),
       socket_pool_(socket_pool.Pass()),
       rand_callback_(base::Bind(rand_int_callback, 0, kuint16max)),
       net_log_(net_log),
       server_index_(0) {
   socket_pool_->Initialize(&config_.nameservers, net_log);
   UMA_HISTOGRAM_CUSTOM_COUNTS(
       "AsyncDNS.ServerCount", config_.nameservers.size(), 0, 10, 10);
   for (size_t i = 0; i < config_.nameservers.size(); ++i) {
     server_stats_.push_back(new ServerStats(config_.timeout,
                                             rtt_buckets_.Pointer()));
   }
 }

 DnsSession::~DnsSession() {
   RecordServerStats();
 }

 int DnsSession::NextQueryId() const { return rand_callback_.Run(); }

 unsigned DnsSession::NextFirstServerIndex() {
   unsigned index = NextGoodServerIndex(server_index_);
   if (config_.rotate)
     server_index_ = (server_index_ + 1) % config_.nameservers.size();
   return index;
 }

 unsigned DnsSession::NextGoodServerIndex(unsigned server_index) {
   unsigned index = server_index;
   base::Time oldest_server_failure(base::Time::Now());
   unsigned oldest_server_failure_index = 0;

   UMA_HISTOGRAM_BOOLEAN("AsyncDNS.ServerIsGood",
                         server_stats_[server_index]->last_failure.is_null());

   do {
     base::Time cur_server_failure = server_stats_[index]->last_failure;
     // If number of failures on this server doesn't exceed number of allowed
     // attempts, return its index.
     if (server_stats_[server_index]->last_failure_count < config_.attempts) {
       return index;
     }
     // Track oldest failed server.
     if (cur_server_failure < oldest_server_failure) {
       oldest_server_failure = cur_server_failure;
       oldest_server_failure_index = index;
     }
     index = (index + 1) % config_.nameservers.size();
   } while (index != server_index);

   // If we are here it means that there are no successful servers, so we have
   // to use one that has failed oldest.
   return oldest_server_failure_index;
 }

 void DnsSession::RecordServerFailure(unsigned server_index) {
   UMA_HISTOGRAM_CUSTOM_COUNTS(
       "AsyncDNS.ServerFailureIndex", server_index, 0, 10, 10);
   ++(server_stats_[server_index]->last_failure_count);
   server_stats_[server_index]->last_failure = base::Time::Now();
 }

 void DnsSession::RecordServerSuccess(unsigned server_index) {
   if (server_stats_[server_index]->last_success.is_null()) {
     UMA_HISTOGRAM_COUNTS_100("AsyncDNS.ServerFailuresAfterNetworkChange",
                            server_stats_[server_index]->last_failure_count);
   } else {
     UMA_HISTOGRAM_COUNTS_100("AsyncDNS.ServerFailuresBeforeSuccess",
                            server_stats_[server_index]->last_failure_count);
   }
   server_stats_[server_index]->last_failure_count = 0;
   server_stats_[server_index]->last_failure = base::Time();
   server_stats_[server_index]->last_success = base::Time::Now();
 }

 void DnsSession::RecordRTT(unsigned server_index, base::TimeDelta rtt) {
   DCHECK_LT(server_index, server_stats_.size());

   // For measurement, assume it is the first attempt (no backoff).
   base::TimeDelta timeout_jacobson = NextTimeoutFromJacobson(server_index, 0);
   base::TimeDelta timeout_histogram = NextTimeoutFromHistogram(server_index, 0);
   UMA_HISTOGRAM_TIMES("AsyncDNS.TimeoutErrorJacobson", rtt - timeout_jacobson);
   UMA_HISTOGRAM_TIMES("AsyncDNS.TimeoutErrorHistogram",
                       rtt - timeout_histogram);
   UMA_HISTOGRAM_TIMES("AsyncDNS.TimeoutErrorJacobsonUnder",
                       timeout_jacobson - rtt);
   UMA_HISTOGRAM_TIMES("AsyncDNS.TimeoutErrorHistogramUnder",
                       timeout_histogram - rtt);

   // Jacobson/Karels algorithm for TCP.
   // Using parameters: alpha = 1/8, delta = 1/4, beta = 4
   base::TimeDelta& estimate = server_stats_[server_index]->rtt_estimate;
   base::TimeDelta& deviation = server_stats_[server_index]->rtt_deviation;
   base::TimeDelta current_error = rtt - estimate;
   estimate += current_error / 8;  // * alpha
   base::TimeDelta abs_error = base::TimeDelta::FromInternalValue(
       std::abs(current_error.ToInternalValue()));
   deviation += (abs_error - deviation) / 4;  // * delta

   // Histogram-based method.
   server_stats_[server_index]->rtt_histogram
       ->Accumulate(rtt.InMilliseconds(), 1);
 }

 void DnsSession::RecordLostPacket(unsigned server_index, int attempt) {
   base::TimeDelta timeout_jacobson =
       NextTimeoutFromJacobson(server_index, attempt);
   base::TimeDelta timeout_histogram =
       NextTimeoutFromHistogram(server_index, attempt);
   UMA_HISTOGRAM_TIMES("AsyncDNS.TimeoutSpentJacobson", timeout_jacobson);
   UMA_HISTOGRAM_TIMES("AsyncDNS.TimeoutSpentHistogram", timeout_histogram);
 }

 void DnsSession::RecordServerStats() {
   for (size_t index = 0; index < server_stats_.size(); ++index) {
     if (server_stats_[index]->last_failure_count) {
       if (server_stats_[index]->last_success.is_null()) {
         UMA_HISTOGRAM_COUNTS("AsyncDNS.ServerFailuresWithoutSuccess",
                              server_stats_[index]->last_failure_count);
       } else {
         UMA_HISTOGRAM_COUNTS("AsyncDNS.ServerFailuresAfterSuccess",
                              server_stats_[index]->last_failure_count);
       }
     }
   }
 }


 base::TimeDelta DnsSession::NextTimeout(unsigned server_index, int attempt) {
   // Respect config timeout if it exceeds |kMaxTimeoutMs|.
   if (config_.timeout.InMilliseconds() >= kMaxTimeoutMs)
     return config_.timeout;
   return NextTimeoutFromHistogram(server_index, attempt);
 }

 // Allocate a socket, already connected to the server address.
 scoped_ptr<DnsSession::SocketLease> DnsSession::AllocateSocket(
     unsigned server_index, const NetLog::Source& source) {
   scoped_ptr<DatagramClientSocket> socket;

   socket = socket_pool_->AllocateSocket(server_index);
   if (!socket.get())
     return scoped_ptr<SocketLease>();

   socket->NetLog().BeginEvent(NetLog::TYPE_SOCKET_IN_USE,
                               source.ToEventParametersCallback());

   SocketLease* lease = new SocketLease(this, server_index, socket.Pass());
   return scoped_ptr<SocketLease>(lease);
 }

 scoped_ptr<StreamSocket> DnsSession::CreateTCPSocket(
     unsigned server_index, const NetLog::Source& source) {
   return socket_pool_->CreateTCPSocket(server_index, source);
 }

 // Release a socket.
 void DnsSession::FreeSocket(unsigned server_index,
                             scoped_ptr<DatagramClientSocket> socket) {
   DCHECK(socket.get());

   socket->NetLog().EndEvent(NetLog::TYPE_SOCKET_IN_USE);

   socket_pool_->FreeSocket(server_index, socket.Pass());
 }

 base::TimeDelta DnsSession::NextTimeoutFromJacobson(unsigned server_index,
                                                     int attempt) {
   DCHECK_LT(server_index, server_stats_.size());

   base::TimeDelta timeout = server_stats_[server_index]->rtt_estimate +
                             4 * server_stats_[server_index]->rtt_deviation;

   timeout = std::max(timeout, base::TimeDelta::FromMilliseconds(kMinTimeoutMs));

   // The timeout doubles every full round.
   unsigned num_backoffs = attempt / config_.nameservers.size();

   return std::min(timeout * (1 << num_backoffs),
                   base::TimeDelta::FromMilliseconds(kMaxTimeoutMs));
 }

 base::TimeDelta DnsSession::NextTimeoutFromHistogram(unsigned server_index,
                                                      int attempt) {
   DCHECK_LT(server_index, server_stats_.size());

   COMPILE_ASSERT(std::numeric_limits<base::HistogramBase::Count>::is_signed,
                  histogram_base_count_assumed_to_be_signed);

   // Use fixed percentile of observed samples.
   const base::SampleVector& samples =
       *server_stats_[server_index]->rtt_histogram;

   base::HistogramBase::Count total = samples.TotalCount();
   base::HistogramBase::Count remaining_count = kRTOPercentile * total / 100;
   size_t index = 0;
   while (remaining_count > 0 && index < rtt_buckets_.Get().size()) {
     remaining_count -= samples.GetCountAtIndex(index);
     ++index;
   }

   base::TimeDelta timeout =
       base::TimeDelta::FromMilliseconds(rtt_buckets_.Get().range(index));

   timeout = std::max(timeout, base::TimeDelta::FromMilliseconds(kMinTimeoutMs));

   // The timeout still doubles every full round.
   unsigned num_backoffs = attempt / config_.nameservers.size();

   return std::min(timeout * (1 << num_backoffs),
                   base::TimeDelta::FromMilliseconds(kMaxTimeoutMs));
 }

 }  // 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/dns/dns_session.h"

	#include "base/basictypes.h"
	#include "base/bind.h"
	#include "base/lazy_instance.h"
	#include "base/metrics/histogram.h"
	#include "base/metrics/sample_vector.h"
	#include "base/rand_util.h"
	#include "base/stl_util.h"
	#include "base/time/time.h"
	#include "net/base/ip_endpoint.h"
	#include "net/base/net_errors.h"
	#include "net/dns/dns_config_service.h"
	#include "net/dns/dns_socket_pool.h"
	#include "net/socket/stream_socket.h"
	#include "net/udp/datagram_client_socket.h"

	namespace net {

	namespace {
	// Never exceed max timeout.
	const unsigned kMaxTimeoutMs = 5000;
	// Set min timeout, in case we are talking to a local DNS proxy.
	const unsigned kMinTimeoutMs = 10;

	// Number of buckets in the histogram of observed RTTs.
	const size_t kRTTBucketCount = 100;
	// Target percentile in the RTT histogram used for retransmission timeout.
	const unsigned kRTOPercentile = 99;
	} // namespace

	// Runtime statistics of DNS server.
	struct DnsSession::ServerStats {
	ServerStats(base::TimeDelta rtt_estimate_param, RttBuckets* buckets)
	: last_failure_count(0), rtt_estimate(rtt_estimate_param) {
	rtt_histogram.reset(new base::SampleVector(buckets));
	// Seed histogram with 2 samples at \|rtt_estimate\| timeout.
	rtt_histogram->Accumulate(rtt_estimate.InMilliseconds(), 2);
	}

	// Count of consecutive failures after last success.
	int last_failure_count;

	// Last time when server returned failure or timeout.
	base::Time last_failure;
	// Last time when server returned success.
	base::Time last_success;

	// Estimated RTT using moving average.
	base::TimeDelta rtt_estimate;
	// Estimated error in the above.
	base::TimeDelta rtt_deviation;

	// A histogram of observed RTT .
	scoped_ptr<base::SampleVector> rtt_histogram;

	DISALLOW_COPY_AND_ASSIGN(ServerStats);
	};

	// static
	base::LazyInstance<DnsSession::RttBuckets>::Leaky DnsSession::rtt_buckets_ =
	LAZY_INSTANCE_INITIALIZER;

	DnsSession::RttBuckets::RttBuckets() : base::BucketRanges(kRTTBucketCount + 1) {
	base::Histogram::InitializeBucketRanges(1, 5000, this);
	}

	DnsSession::SocketLease::SocketLease(scoped_refptr<DnsSession> session,
	unsigned server_index,
	scoped_ptr<DatagramClientSocket> socket)
	: session_(session), server_index_(server_index), socket_(socket.Pass()) {}

	DnsSession::SocketLease::~SocketLease() {
	session_->FreeSocket(server_index_, socket_.Pass());
	}

	DnsSession::DnsSession(const DnsConfig& config,
	scoped_ptr<DnsSocketPool> socket_pool,
	const RandIntCallback& rand_int_callback,
	NetLog* net_log)
	: config_(config),
	socket_pool_(socket_pool.Pass()),
	rand_callback_(base::Bind(rand_int_callback, 0, kuint16max)),
	net_log_(net_log),
	server_index_(0) {
	socket_pool_->Initialize(&config_.nameservers, net_log);
	UMA_HISTOGRAM_CUSTOM_COUNTS(
	"AsyncDNS.ServerCount", config_.nameservers.size(), 0, 10, 10);
	for (size_t i = 0; i < config_.nameservers.size(); ++i) {
	server_stats_.push_back(new ServerStats(config_.timeout,
	rtt_buckets_.Pointer()));
	}
	}

	DnsSession::~DnsSession() {
	RecordServerStats();
	}

	int DnsSession::NextQueryId() const { return rand_callback_.Run(); }

	unsigned DnsSession::NextFirstServerIndex() {
	unsigned index = NextGoodServerIndex(server_index_);
	if (config_.rotate)
	server_index_ = (server_index_ + 1) % config_.nameservers.size();
	return index;
	}

	unsigned DnsSession::NextGoodServerIndex(unsigned server_index) {
	unsigned index = server_index;
	base::Time oldest_server_failure(base::Time::Now());
	unsigned oldest_server_failure_index = 0;

	UMA_HISTOGRAM_BOOLEAN("AsyncDNS.ServerIsGood",
	server_stats_[server_index]->last_failure.is_null());

	do {
	base::Time cur_server_failure = server_stats_[index]->last_failure;
	// If number of failures on this server doesn't exceed number of allowed
	// attempts, return its index.
	if (server_stats_[server_index]->last_failure_count < config_.attempts) {
	return index;
	}
	// Track oldest failed server.
	if (cur_server_failure < oldest_server_failure) {
	oldest_server_failure = cur_server_failure;
	oldest_server_failure_index = index;
	}
	index = (index + 1) % config_.nameservers.size();
	} while (index != server_index);

	// If we are here it means that there are no successful servers, so we have
	// to use one that has failed oldest.
	return oldest_server_failure_index;
	}

	void DnsSession::RecordServerFailure(unsigned server_index) {
	UMA_HISTOGRAM_CUSTOM_COUNTS(
	"AsyncDNS.ServerFailureIndex", server_index, 0, 10, 10);
	++(server_stats_[server_index]->last_failure_count);
	server_stats_[server_index]->last_failure = base::Time::Now();
	}

	void DnsSession::RecordServerSuccess(unsigned server_index) {
	if (server_stats_[server_index]->last_success.is_null()) {
	UMA_HISTOGRAM_COUNTS_100("AsyncDNS.ServerFailuresAfterNetworkChange",
	server_stats_[server_index]->last_failure_count);
	} else {
	UMA_HISTOGRAM_COUNTS_100("AsyncDNS.ServerFailuresBeforeSuccess",
	server_stats_[server_index]->last_failure_count);
	}
	server_stats_[server_index]->last_failure_count = 0;
	server_stats_[server_index]->last_failure = base::Time();
	server_stats_[server_index]->last_success = base::Time::Now();
	}

	void DnsSession::RecordRTT(unsigned server_index, base::TimeDelta rtt) {
	DCHECK_LT(server_index, server_stats_.size());

	// For measurement, assume it is the first attempt (no backoff).
	base::TimeDelta timeout_jacobson = NextTimeoutFromJacobson(server_index, 0);
	base::TimeDelta timeout_histogram = NextTimeoutFromHistogram(server_index, 0);
	UMA_HISTOGRAM_TIMES("AsyncDNS.TimeoutErrorJacobson", rtt - timeout_jacobson);
	UMA_HISTOGRAM_TIMES("AsyncDNS.TimeoutErrorHistogram",
	rtt - timeout_histogram);
	UMA_HISTOGRAM_TIMES("AsyncDNS.TimeoutErrorJacobsonUnder",
	timeout_jacobson - rtt);
	UMA_HISTOGRAM_TIMES("AsyncDNS.TimeoutErrorHistogramUnder",
	timeout_histogram - rtt);

	// Jacobson/Karels algorithm for TCP.
	// Using parameters: alpha = 1/8, delta = 1/4, beta = 4
	base::TimeDelta& estimate = server_stats_[server_index]->rtt_estimate;
	base::TimeDelta& deviation = server_stats_[server_index]->rtt_deviation;
	base::TimeDelta current_error = rtt - estimate;
	estimate += current_error / 8; // * alpha
	base::TimeDelta abs_error = base::TimeDelta::FromInternalValue(
	std::abs(current_error.ToInternalValue()));
	deviation += (abs_error - deviation) / 4; // * delta

	// Histogram-based method.
	server_stats_[server_index]->rtt_histogram
	->Accumulate(rtt.InMilliseconds(), 1);
	}

	void DnsSession::RecordLostPacket(unsigned server_index, int attempt) {
	base::TimeDelta timeout_jacobson =
	NextTimeoutFromJacobson(server_index, attempt);
	base::TimeDelta timeout_histogram =
	NextTimeoutFromHistogram(server_index, attempt);
	UMA_HISTOGRAM_TIMES("AsyncDNS.TimeoutSpentJacobson", timeout_jacobson);
	UMA_HISTOGRAM_TIMES("AsyncDNS.TimeoutSpentHistogram", timeout_histogram);
	}

	void DnsSession::RecordServerStats() {
	for (size_t index = 0; index < server_stats_.size(); ++index) {
	if (server_stats_[index]->last_failure_count) {
	if (server_stats_[index]->last_success.is_null()) {
	UMA_HISTOGRAM_COUNTS("AsyncDNS.ServerFailuresWithoutSuccess",
	server_stats_[index]->last_failure_count);
	} else {
	UMA_HISTOGRAM_COUNTS("AsyncDNS.ServerFailuresAfterSuccess",
	server_stats_[index]->last_failure_count);
	}
	}
	}
	}


	base::TimeDelta DnsSession::NextTimeout(unsigned server_index, int attempt) {
	// Respect config timeout if it exceeds \|kMaxTimeoutMs\|.
	if (config_.timeout.InMilliseconds() >= kMaxTimeoutMs)
	return config_.timeout;
	return NextTimeoutFromHistogram(server_index, attempt);
	}

	// Allocate a socket, already connected to the server address.
	scoped_ptr<DnsSession::SocketLease> DnsSession::AllocateSocket(
	unsigned server_index, const NetLog::Source& source) {
	scoped_ptr<DatagramClientSocket> socket;

	socket = socket_pool_->AllocateSocket(server_index);
	if (!socket.get())
	return scoped_ptr<SocketLease>();

	socket->NetLog().BeginEvent(NetLog::TYPE_SOCKET_IN_USE,
	source.ToEventParametersCallback());

	SocketLease* lease = new SocketLease(this, server_index, socket.Pass());
	return scoped_ptr<SocketLease>(lease);
	}

	scoped_ptr<StreamSocket> DnsSession::CreateTCPSocket(
	unsigned server_index, const NetLog::Source& source) {
	return socket_pool_->CreateTCPSocket(server_index, source);
	}

	// Release a socket.
	void DnsSession::FreeSocket(unsigned server_index,
	scoped_ptr<DatagramClientSocket> socket) {
	DCHECK(socket.get());

	socket->NetLog().EndEvent(NetLog::TYPE_SOCKET_IN_USE);

	socket_pool_->FreeSocket(server_index, socket.Pass());
	}

	base::TimeDelta DnsSession::NextTimeoutFromJacobson(unsigned server_index,
	int attempt) {
	DCHECK_LT(server_index, server_stats_.size());

	base::TimeDelta timeout = server_stats_[server_index]->rtt_estimate +
	4 * server_stats_[server_index]->rtt_deviation;

	timeout = std::max(timeout, base::TimeDelta::FromMilliseconds(kMinTimeoutMs));

	// The timeout doubles every full round.
	unsigned num_backoffs = attempt / config_.nameservers.size();

	return std::min(timeout * (1 << num_backoffs),
	base::TimeDelta::FromMilliseconds(kMaxTimeoutMs));
	}

	base::TimeDelta DnsSession::NextTimeoutFromHistogram(unsigned server_index,
	int attempt) {
	DCHECK_LT(server_index, server_stats_.size());

	COMPILE_ASSERT(std::numeric_limits<base::HistogramBase::Count>::is_signed,
	histogram_base_count_assumed_to_be_signed);

	// Use fixed percentile of observed samples.
	const base::SampleVector& samples =
	*server_stats_[server_index]->rtt_histogram;

	base::HistogramBase::Count total = samples.TotalCount();
	base::HistogramBase::Count remaining_count = kRTOPercentile * total / 100;
	size_t index = 0;
	while (remaining_count > 0 && index < rtt_buckets_.Get().size()) {
	remaining_count -= samples.GetCountAtIndex(index);
	++index;
	}

	base::TimeDelta timeout =
	base::TimeDelta::FromMilliseconds(rtt_buckets_.Get().range(index));

	timeout = std::max(timeout, base::TimeDelta::FromMilliseconds(kMinTimeoutMs));

	// The timeout still doubles every full round.
	unsigned num_backoffs = attempt / config_.nameservers.size();

	return std::min(timeout * (1 << num_backoffs),
	base::TimeDelta::FromMilliseconds(kMaxTimeoutMs));
	}

	} // namespace net