// 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_config_service.h"
#include "base/logging.h"
#include "base/metrics/histogram.h"
#include "base/values.h"
#include "net/base/ip_endpoint.h"
#include "net/base/ip_pattern.h"
namespace net {
NameServerClassifier::NameServerClassifier() {
// Google Public DNS addresses from:
// https://developers.google.com/speed/public-dns/docs/using
AddRule("8.8.8.8", NAME_SERVERS_TYPE_GOOGLE_PUBLIC_DNS);
AddRule("8.8.4.4", NAME_SERVERS_TYPE_GOOGLE_PUBLIC_DNS);
AddRule("2001:4860:4860:0:0:0:0:8888", NAME_SERVERS_TYPE_GOOGLE_PUBLIC_DNS),
AddRule("2001:4860:4860:0:0:0:0:8844", NAME_SERVERS_TYPE_GOOGLE_PUBLIC_DNS),
// Count localhost as private, since we don't know what upstream it uses:
AddRule("127.*.*.*", NAME_SERVERS_TYPE_PRIVATE);
AddRule("0:0:0:0:0:0:0:1", NAME_SERVERS_TYPE_PRIVATE);
// RFC 1918 private addresses:
AddRule("10.*.*.*", NAME_SERVERS_TYPE_PRIVATE);
AddRule("172.[16-31].*.*", NAME_SERVERS_TYPE_PRIVATE);
AddRule("192.168.*.*", NAME_SERVERS_TYPE_PRIVATE);
// IPv4 link-local addresses:
AddRule("169.254.*.*", NAME_SERVERS_TYPE_PRIVATE);
// IPv6 link-local addresses:
AddRule("fe80:*:*:*:*:*:*:*", NAME_SERVERS_TYPE_PRIVATE);
// Anything else counts as public:
AddRule("*.*.*.*", NAME_SERVERS_TYPE_PUBLIC);
AddRule("*:*:*:*:*:*:*:*", NAME_SERVERS_TYPE_PUBLIC);
}
NameServerClassifier::~NameServerClassifier() {}
NameServerClassifier::NameServersType NameServerClassifier::GetNameServersType(
const std::vector<IPEndPoint>& nameservers) const {
NameServersType type = NAME_SERVERS_TYPE_NONE;
for (std::vector<IPEndPoint>::const_iterator it = nameservers.begin();
it != nameservers.end();
++it) {
type = MergeNameServersTypes(type, GetNameServerType(it->address()));
}
return type;
}
struct NameServerClassifier::NameServerTypeRule {
NameServerTypeRule(const char* pattern_string, NameServersType type)
: type(type) {
bool parsed = pattern.ParsePattern(pattern_string);
DCHECK(parsed);
}
IPPattern pattern;
NameServersType type;
};
void NameServerClassifier::AddRule(const char* pattern_string,
NameServersType address_type) {
rules_.push_back(new NameServerTypeRule(pattern_string, address_type));
}
NameServerClassifier::NameServersType NameServerClassifier::GetNameServerType(
const IPAddressNumber& address) const {
for (ScopedVector<NameServerTypeRule>::const_iterator it = rules_.begin();
it != rules_.end();
++it) {
if ((*it)->pattern.Match(address))
return (*it)->type;
}
NOTREACHED();
return NAME_SERVERS_TYPE_NONE;
}
NameServerClassifier::NameServersType
NameServerClassifier::MergeNameServersTypes(NameServersType a,
NameServersType b) {
if (a == NAME_SERVERS_TYPE_NONE)
return b;
if (b == NAME_SERVERS_TYPE_NONE)
return a;
if (a == b)
return a;
return NAME_SERVERS_TYPE_MIXED;
}
// Default values are taken from glibc resolv.h except timeout which is set to
// |kDnsTimeoutSeconds|.
DnsConfig::DnsConfig()
: unhandled_options(false),
append_to_multi_label_name(true),
randomize_ports(false),
ndots(1),
timeout(base::TimeDelta::FromSeconds(kDnsTimeoutSeconds)),
attempts(2),
rotate(false),
edns0(false),
use_local_ipv6(false) {}
DnsConfig::~DnsConfig() {}
bool DnsConfig::Equals(const DnsConfig& d) const {
return EqualsIgnoreHosts(d) && (hosts == d.hosts);
}
bool DnsConfig::EqualsIgnoreHosts(const DnsConfig& d) const {
return (nameservers == d.nameservers) &&
(search == d.search) &&
(unhandled_options == d.unhandled_options) &&
(append_to_multi_label_name == d.append_to_multi_label_name) &&
(ndots == d.ndots) &&
(timeout == d.timeout) &&
(attempts == d.attempts) &&
(rotate == d.rotate) &&
(edns0 == d.edns0) &&
(use_local_ipv6 == d.use_local_ipv6);
}
void DnsConfig::CopyIgnoreHosts(const DnsConfig& d) {
nameservers = d.nameservers;
search = d.search;
unhandled_options = d.unhandled_options;
append_to_multi_label_name = d.append_to_multi_label_name;
ndots = d.ndots;
timeout = d.timeout;
attempts = d.attempts;
rotate = d.rotate;
edns0 = d.edns0;
use_local_ipv6 = d.use_local_ipv6;
}
base::Value* DnsConfig::ToValue() const {
base::DictionaryValue* dict = new base::DictionaryValue();
base::ListValue* list = new base::ListValue();
for (size_t i = 0; i < nameservers.size(); ++i)
list->Append(new base::StringValue(nameservers[i].ToString()));
dict->Set("nameservers", list);
list = new base::ListValue();
for (size_t i = 0; i < search.size(); ++i)
list->Append(new base::StringValue(search[i]));
dict->Set("search", list);
dict->SetBoolean("unhandled_options", unhandled_options);
dict->SetBoolean("append_to_multi_label_name", append_to_multi_label_name);
dict->SetInteger("ndots", ndots);
dict->SetDouble("timeout", timeout.InSecondsF());
dict->SetInteger("attempts", attempts);
dict->SetBoolean("rotate", rotate);
dict->SetBoolean("edns0", edns0);
dict->SetBoolean("use_local_ipv6", use_local_ipv6);
dict->SetInteger("num_hosts", hosts.size());
return dict;
}
DnsConfigService::DnsConfigService()
: watch_failed_(false),
have_config_(false),
have_hosts_(false),
need_update_(false),
last_sent_empty_(true) {}
DnsConfigService::~DnsConfigService() {
}
void DnsConfigService::ReadConfig(const CallbackType& callback) {
DCHECK(CalledOnValidThread());
DCHECK(!callback.is_null());
DCHECK(callback_.is_null());
callback_ = callback;
ReadNow();
}
void DnsConfigService::WatchConfig(const CallbackType& callback) {
DCHECK(CalledOnValidThread());
DCHECK(!callback.is_null());
DCHECK(callback_.is_null());
callback_ = callback;
watch_failed_ = !StartWatching();
ReadNow();
}
void DnsConfigService::InvalidateConfig() {
DCHECK(CalledOnValidThread());
base::TimeTicks now = base::TimeTicks::Now();
if (!last_invalidate_config_time_.is_null()) {
UMA_HISTOGRAM_LONG_TIMES("AsyncDNS.ConfigNotifyInterval",
now - last_invalidate_config_time_);
}
last_invalidate_config_time_ = now;
if (!have_config_)
return;
have_config_ = false;
StartTimer();
}
void DnsConfigService::InvalidateHosts() {
DCHECK(CalledOnValidThread());
base::TimeTicks now = base::TimeTicks::Now();
if (!last_invalidate_hosts_time_.is_null()) {
UMA_HISTOGRAM_LONG_TIMES("AsyncDNS.HostsNotifyInterval",
now - last_invalidate_hosts_time_);
}
last_invalidate_hosts_time_ = now;
if (!have_hosts_)
return;
have_hosts_ = false;
StartTimer();
}
void DnsConfigService::OnConfigRead(const DnsConfig& config) {
DCHECK(CalledOnValidThread());
DCHECK(config.IsValid());
bool changed = false;
if (!config.EqualsIgnoreHosts(dns_config_)) {
dns_config_.CopyIgnoreHosts(config);
need_update_ = true;
changed = true;
}
if (!changed && !last_sent_empty_time_.is_null()) {
UMA_HISTOGRAM_LONG_TIMES("AsyncDNS.UnchangedConfigInterval",
base::TimeTicks::Now() - last_sent_empty_time_);
}
UMA_HISTOGRAM_BOOLEAN("AsyncDNS.ConfigChange", changed);
UMA_HISTOGRAM_ENUMERATION(
"AsyncDNS.NameServersType",
classifier_.GetNameServersType(dns_config_.nameservers),
NameServerClassifier::NAME_SERVERS_TYPE_MAX_VALUE);
have_config_ = true;
if (have_hosts_ || watch_failed_)
OnCompleteConfig();
}
void DnsConfigService::OnHostsRead(const DnsHosts& hosts) {
DCHECK(CalledOnValidThread());
bool changed = false;
if (hosts != dns_config_.hosts) {
dns_config_.hosts = hosts;
need_update_ = true;
changed = true;
}
if (!changed && !last_sent_empty_time_.is_null()) {
UMA_HISTOGRAM_LONG_TIMES("AsyncDNS.UnchangedHostsInterval",
base::TimeTicks::Now() - last_sent_empty_time_);
}
UMA_HISTOGRAM_BOOLEAN("AsyncDNS.HostsChange", changed);
have_hosts_ = true;
if (have_config_ || watch_failed_)
OnCompleteConfig();
}
void DnsConfigService::StartTimer() {
DCHECK(CalledOnValidThread());
if (last_sent_empty_) {
DCHECK(!timer_.IsRunning());
return; // No need to withdraw again.
}
timer_.Stop();
// Give it a short timeout to come up with a valid config. Otherwise withdraw
// the config from the receiver. The goal is to avoid perceivable network
// outage (when using the wrong config) but at the same time avoid
// unnecessary Job aborts in HostResolverImpl. The signals come from multiple
// sources so it might receive multiple events during a config change.
// DHCP and user-induced changes are on the order of seconds, so 150ms should
// not add perceivable delay. On the other hand, config readers should finish
// within 150ms with the rare exception of I/O block or extra large HOSTS.
const base::TimeDelta kTimeout = base::TimeDelta::FromMilliseconds(150);
timer_.Start(FROM_HERE,
kTimeout,
this,
&DnsConfigService::OnTimeout);
}
void DnsConfigService::OnTimeout() {
DCHECK(CalledOnValidThread());
DCHECK(!last_sent_empty_);
// Indicate that even if there is no change in On*Read, we will need to
// update the receiver when the config becomes complete.
need_update_ = true;
// Empty config is considered invalid.
last_sent_empty_ = true;
last_sent_empty_time_ = base::TimeTicks::Now();
callback_.Run(DnsConfig());
}
void DnsConfigService::OnCompleteConfig() {
timer_.Stop();
if (!need_update_)
return;
need_update_ = false;
last_sent_empty_ = false;
if (watch_failed_) {
// If a watch failed, the config may not be accurate, so report empty.
callback_.Run(DnsConfig());
} else {
callback_.Run(dns_config_);
}
}
} // namespace net