// 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/proxy_resolution/proxy_resolution_service.h" #include #include #include #include "base/bind.h" #include "base/bind_helpers.h" #include "base/compiler_specific.h" #include "base/location.h" #include "base/logging.h" #include "base/macros.h" #include "base/memory/weak_ptr.h" #include "base/metrics/histogram_macros.h" #include "base/single_thread_task_runner.h" #include "base/strings/string_util.h" #include "base/threading/thread_task_runner_handle.h" #include "base/time/time.h" #include "base/values.h" #include "net/base/net_errors.h" #include "net/base/proxy_delegate.h" #include "net/base/url_util.h" #include "net/log/net_log.h" #include "net/log/net_log_capture_mode.h" #include "net/log/net_log_event_type.h" #include "net/log/net_log_with_source.h" #include "net/proxy_resolution/dhcp_pac_file_fetcher.h" #include "net/proxy_resolution/multi_threaded_proxy_resolver.h" #include "net/proxy_resolution/pac_file_decider.h" #include "net/proxy_resolution/pac_file_fetcher.h" #include "net/proxy_resolution/proxy_config_service_fixed.h" #include "net/proxy_resolution/proxy_resolver.h" #include "net/proxy_resolution/proxy_resolver_factory.h" #include "net/url_request/url_request_context.h" #include "url/gurl.h" #if defined(OS_WIN) #include "net/proxy_resolution/proxy_config_service_win.h" #include "net/proxy_resolution/proxy_resolver_winhttp.h" #elif defined(OS_IOS) #include "net/proxy_resolution/proxy_config_service_ios.h" #include "net/proxy_resolution/proxy_resolver_mac.h" #elif defined(OS_MACOSX) #include "net/proxy_resolution/proxy_config_service_mac.h" #include "net/proxy_resolution/proxy_resolver_mac.h" #elif defined(OS_LINUX) && !defined(OS_CHROMEOS) #include "net/proxy_resolution/proxy_config_service_linux.h" #elif defined(OS_ANDROID) #include "net/proxy_resolution/proxy_config_service_android.h" #endif using base::TimeDelta; using base::TimeTicks; namespace net { namespace { #if defined(OS_WIN) || defined(OS_IOS) || defined(OS_MACOSX) || \ (defined(OS_LINUX) && !defined(OS_CHROMEOS)) constexpr net::NetworkTrafficAnnotationTag kSystemProxyConfigTrafficAnnotation = net::DefineNetworkTrafficAnnotation("proxy_config_system", R"( semantics { sender: "Proxy Config" description: "Establishing a connection through a proxy server using system proxy " "settings." trigger: "Whenever a network request is made when the system proxy settings " "are used, and they indicate to use a proxy server." data: "Proxy configuration." destination: OTHER destination_other: "The proxy server specified in the configuration." } policy { cookies_allowed: NO setting: "User cannot override system proxy settings, but can change them " "through 'Advanced/System/Open proxy settings'." policy_exception_justification: "Using either of 'ProxyMode', 'ProxyServer', or 'ProxyPacUrl' " "policies can set Chrome to use a specific proxy settings and avoid " "system proxy." })"); #endif const size_t kDefaultNumPacThreads = 4; // When the IP address changes we don't immediately re-run proxy auto-config. // Instead, we wait for |kDelayAfterNetworkChangesMs| before // attempting to re-valuate proxy auto-config. // // During this time window, any resolve requests sent to the // ProxyResolutionService will be queued. Once we have waited the required // amount of them, the proxy auto-config step will be run, and the queued // requests resumed. // // The reason we play this game is that our signal for detecting network // changes (NetworkChangeNotifier) may fire *before* the system's networking // dependencies are fully configured. This is a problem since it means if // we were to run proxy auto-config right away, it could fail due to spurious // DNS failures. (see http://crbug.com/50779 for more details.) // // By adding the wait window, we give things a better chance to get properly // set up. Network failures can happen at any time though, so we additionally // poll the PAC script for changes, which will allow us to recover from these // sorts of problems. const int64_t kDelayAfterNetworkChangesMs = 2000; // This is the default policy for polling the PAC script. // // In response to a failure, the poll intervals are: // 0: 8 seconds (scheduled on timer) // 1: 32 seconds // 2: 2 minutes // 3+: 4 hours // // In response to a success, the poll intervals are: // 0+: 12 hours // // Only the 8 second poll is scheduled on a timer, the rest happen in response // to network activity (and hence will take longer than the written time). // // Explanation for these values: // // TODO(eroman): These values are somewhat arbitrary, and need to be tuned // using some histograms data. Trying to be conservative so as not to break // existing setups when deployed. A simple exponential retry scheme would be // more elegant, but places more load on server. // // The motivation for trying quickly after failures (8 seconds) is to recover // from spurious network failures, which are common after the IP address has // just changed (like DNS failing to resolve). The next 32 second boundary is // to try and catch other VPN weirdness which anecdotally I have seen take // 10+ seconds for some users. // // The motivation for re-trying after a success is to check for possible // content changes to the script, or to the WPAD auto-discovery results. We are // not very aggressive with these checks so as to minimize the risk of // overloading existing PAC setups. Moreover it is unlikely that PAC scripts // change very frequently in existing setups. More research is needed to // motivate what safe values are here, and what other user agents do. // // Comparison to other browsers: // // In Firefox the PAC URL is re-tried on failures according to // network.proxy.autoconfig_retry_interval_min and // network.proxy.autoconfig_retry_interval_max. The defaults are 5 seconds and // 5 minutes respectively. It doubles the interval at each attempt. // // TODO(eroman): Figure out what Internet Explorer does. class DefaultPollPolicy : public ProxyResolutionService::PacPollPolicy { public: DefaultPollPolicy() = default; Mode GetNextDelay(int initial_error, TimeDelta current_delay, TimeDelta* next_delay) const override { if (initial_error != OK) { // Re-try policy for failures. const int kDelay1Seconds = 8; const int kDelay2Seconds = 32; const int kDelay3Seconds = 2 * 60; // 2 minutes const int kDelay4Seconds = 4 * 60 * 60; // 4 Hours // Initial poll. if (current_delay < TimeDelta()) { *next_delay = TimeDelta::FromSeconds(kDelay1Seconds); return MODE_USE_TIMER; } switch (current_delay.InSeconds()) { case kDelay1Seconds: *next_delay = TimeDelta::FromSeconds(kDelay2Seconds); return MODE_START_AFTER_ACTIVITY; case kDelay2Seconds: *next_delay = TimeDelta::FromSeconds(kDelay3Seconds); return MODE_START_AFTER_ACTIVITY; default: *next_delay = TimeDelta::FromSeconds(kDelay4Seconds); return MODE_START_AFTER_ACTIVITY; } } else { // Re-try policy for succeses. *next_delay = TimeDelta::FromHours(12); return MODE_START_AFTER_ACTIVITY; } } private: DISALLOW_COPY_AND_ASSIGN(DefaultPollPolicy); }; // Config getter that always returns direct settings. class ProxyConfigServiceDirect : public ProxyConfigService { public: // ProxyConfigService implementation: void AddObserver(Observer* observer) override {} void RemoveObserver(Observer* observer) override {} ConfigAvailability GetLatestProxyConfig( ProxyConfigWithAnnotation* config) override { *config = ProxyConfigWithAnnotation::CreateDirect(); return CONFIG_VALID; } }; // Proxy resolver that fails every time. class ProxyResolverNull : public ProxyResolver { public: ProxyResolverNull() = default; // ProxyResolver implementation. int GetProxyForURL(const GURL& url, ProxyInfo* results, CompletionOnceCallback callback, std::unique_ptr* request, const NetLogWithSource& net_log) override { return ERR_NOT_IMPLEMENTED; } }; // ProxyResolver that simulates a PAC script which returns // |pac_string| for every single URL. class ProxyResolverFromPacString : public ProxyResolver { public: explicit ProxyResolverFromPacString(const std::string& pac_string) : pac_string_(pac_string) {} int GetProxyForURL(const GURL& url, ProxyInfo* results, CompletionOnceCallback callback, std::unique_ptr* request, const NetLogWithSource& net_log) override { results->UsePacString(pac_string_); return OK; } private: const std::string pac_string_; }; // Creates ProxyResolvers using a platform-specific implementation. class ProxyResolverFactoryForSystem : public MultiThreadedProxyResolverFactory { public: explicit ProxyResolverFactoryForSystem(size_t max_num_threads) : MultiThreadedProxyResolverFactory(max_num_threads, false /*expects_pac_bytes*/) {} std::unique_ptr CreateProxyResolverFactory() override { #if defined(OS_WIN) return std::make_unique(); #elif defined(OS_MACOSX) return std::make_unique(); #else NOTREACHED(); return NULL; #endif } static bool IsSupported() { #if defined(OS_WIN) || defined(OS_MACOSX) return true; #else return false; #endif } private: DISALLOW_COPY_AND_ASSIGN(ProxyResolverFactoryForSystem); }; class ProxyResolverFactoryForNullResolver : public ProxyResolverFactory { public: ProxyResolverFactoryForNullResolver() : ProxyResolverFactory(false) {} // ProxyResolverFactory overrides. int CreateProxyResolver(const scoped_refptr& pac_script, std::unique_ptr* resolver, CompletionOnceCallback callback, std::unique_ptr* request) override { resolver->reset(new ProxyResolverNull()); return OK; } private: DISALLOW_COPY_AND_ASSIGN(ProxyResolverFactoryForNullResolver); }; class ProxyResolverFactoryForPacResult : public ProxyResolverFactory { public: explicit ProxyResolverFactoryForPacResult(const std::string& pac_string) : ProxyResolverFactory(false), pac_string_(pac_string) {} // ProxyResolverFactory override. int CreateProxyResolver(const scoped_refptr& pac_script, std::unique_ptr* resolver, CompletionOnceCallback callback, std::unique_ptr* request) override { resolver->reset(new ProxyResolverFromPacString(pac_string_)); return OK; } private: const std::string pac_string_; DISALLOW_COPY_AND_ASSIGN(ProxyResolverFactoryForPacResult); }; // Returns NetLog parameters describing a proxy configuration change. std::unique_ptr NetLogProxyConfigChangedCallback( const base::Optional* old_config, const ProxyConfigWithAnnotation* new_config, NetLogCaptureMode /* capture_mode */) { std::unique_ptr dict(new base::DictionaryValue()); // The "old_config" is optional -- the first notification will not have // any "previous" configuration. if (old_config->has_value()) dict->Set("old_config", (*old_config)->value().ToValue()); dict->Set("new_config", new_config->value().ToValue()); return std::move(dict); } std::unique_ptr NetLogBadProxyListCallback( const ProxyRetryInfoMap* retry_info, NetLogCaptureMode /* capture_mode */) { auto dict = std::make_unique(); auto list = std::make_unique(); for (ProxyRetryInfoMap::const_iterator iter = retry_info->begin(); iter != retry_info->end(); ++iter) { list->AppendString(iter->first); } dict->Set("bad_proxy_list", std::move(list)); return std::move(dict); } // Returns NetLog parameters on a successfuly proxy resolution. std::unique_ptr NetLogFinishedResolvingProxyCallback( const ProxyInfo* result, NetLogCaptureMode /* capture_mode */) { std::unique_ptr dict(new base::DictionaryValue()); dict->SetString("pac_string", result->ToPacString()); return std::move(dict); } #if defined(OS_CHROMEOS) class UnsetProxyConfigService : public ProxyConfigService { public: UnsetProxyConfigService() = default; ~UnsetProxyConfigService() override = default; void AddObserver(Observer* observer) override {} void RemoveObserver(Observer* observer) override {} ConfigAvailability GetLatestProxyConfig( ProxyConfigWithAnnotation* config) override { return CONFIG_UNSET; } }; #endif // Returns a sanitized copy of |url| which is safe to pass on to a PAC script. // The method for sanitizing is determined by |policy|. See the comments for // that enum for details. GURL SanitizeUrl(const GURL& url, ProxyResolutionService::SanitizeUrlPolicy policy) { DCHECK(url.is_valid()); GURL::Replacements replacements; replacements.ClearUsername(); replacements.ClearPassword(); replacements.ClearRef(); if (policy == ProxyResolutionService::SanitizeUrlPolicy::SAFE && url.SchemeIsCryptographic()) { replacements.ClearPath(); replacements.ClearQuery(); } return url.ReplaceComponents(replacements); } // Do not change the enumerated value as it is relied on by histograms. enum class PacUrlSchemeForHistogram { kOther = 0, kHttp = 1, kHttps = 2, kFtp = 3, kFile = 4, kData = 5, kMaxValue = kData, }; PacUrlSchemeForHistogram GetPacUrlScheme(const GURL& pac_url) { if (pac_url.SchemeIs("http")) return PacUrlSchemeForHistogram::kHttp; if (pac_url.SchemeIs("https")) return PacUrlSchemeForHistogram::kHttps; if (pac_url.SchemeIs("data")) return PacUrlSchemeForHistogram::kData; if (pac_url.SchemeIs("ftp")) return PacUrlSchemeForHistogram::kFtp; if (pac_url.SchemeIs("file")) return PacUrlSchemeForHistogram::kFile; return PacUrlSchemeForHistogram::kOther; } } // namespace // ProxyResolutionService::InitProxyResolver ---------------------------------- // This glues together two asynchronous steps: // (1) PacFileDecider -- try to fetch/validate a sequence of PAC scripts // to figure out what we should configure against. // (2) Feed the fetched PAC script into the ProxyResolver. // // InitProxyResolver is a single-use class which encapsulates cancellation as // part of its destructor. Start() or StartSkipDecider() should be called just // once. The instance can be destroyed at any time, and the request will be // cancelled. class ProxyResolutionService::InitProxyResolver { public: InitProxyResolver() : proxy_resolver_factory_(nullptr), proxy_resolver_(NULL), next_state_(STATE_NONE), quick_check_enabled_(true) {} ~InitProxyResolver() { // Note that the destruction of PacFileDecider will automatically cancel // any outstanding work. } // Begins initializing the proxy resolver; calls |callback| when done. A // ProxyResolver instance will be created using |proxy_resolver_factory| and // returned via |proxy_resolver| if the final result is OK. int Start(std::unique_ptr* proxy_resolver, ProxyResolverFactory* proxy_resolver_factory, PacFileFetcher* pac_file_fetcher, DhcpPacFileFetcher* dhcp_pac_file_fetcher, NetLog* net_log, const ProxyConfigWithAnnotation& config, TimeDelta wait_delay, CompletionOnceCallback callback) { DCHECK_EQ(STATE_NONE, next_state_); proxy_resolver_ = proxy_resolver; proxy_resolver_factory_ = proxy_resolver_factory; decider_.reset( new PacFileDecider(pac_file_fetcher, dhcp_pac_file_fetcher, net_log)); decider_->set_quick_check_enabled(quick_check_enabled_); config_ = config; wait_delay_ = wait_delay; callback_ = std::move(callback); next_state_ = STATE_DECIDE_PAC_FILE; return DoLoop(OK); } // Similar to Start(), however it skips the PacFileDecider stage. Instead // |effective_config|, |decider_result| and |script_data| will be used as the // inputs for initializing the ProxyResolver. A ProxyResolver instance will // be created using |proxy_resolver_factory| and returned via // |proxy_resolver| if the final result is OK. int StartSkipDecider(std::unique_ptr* proxy_resolver, ProxyResolverFactory* proxy_resolver_factory, const ProxyConfigWithAnnotation& effective_config, int decider_result, PacFileData* script_data, CompletionOnceCallback callback) { DCHECK_EQ(STATE_NONE, next_state_); proxy_resolver_ = proxy_resolver; proxy_resolver_factory_ = proxy_resolver_factory; effective_config_ = effective_config; script_data_ = script_data; callback_ = std::move(callback); if (decider_result != OK) return decider_result; next_state_ = STATE_CREATE_RESOLVER; return DoLoop(OK); } // Returns the proxy configuration that was selected by PacFileDecider. // Should only be called upon completion of the initialization. const ProxyConfigWithAnnotation& effective_config() const { DCHECK_EQ(STATE_NONE, next_state_); return effective_config_; } // Returns the PAC script data that was selected by PacFileDecider. // Should only be called upon completion of the initialization. const scoped_refptr& script_data() { DCHECK_EQ(STATE_NONE, next_state_); return script_data_; } LoadState GetLoadState() const { if (next_state_ == STATE_DECIDE_PAC_FILE_COMPLETE) { // In addition to downloading, this state may also include the stall time // after network change events (kDelayAfterNetworkChangesMs). return LOAD_STATE_DOWNLOADING_PAC_FILE; } return LOAD_STATE_RESOLVING_PROXY_FOR_URL; } // This must be called before the HostResolver is torn down. void OnShutdown() { if (decider_) decider_->OnShutdown(); } void set_quick_check_enabled(bool enabled) { quick_check_enabled_ = enabled; } bool quick_check_enabled() const { return quick_check_enabled_; } private: enum State { STATE_NONE, STATE_DECIDE_PAC_FILE, STATE_DECIDE_PAC_FILE_COMPLETE, STATE_CREATE_RESOLVER, STATE_CREATE_RESOLVER_COMPLETE, }; int DoLoop(int result) { DCHECK_NE(next_state_, STATE_NONE); int rv = result; do { State state = next_state_; next_state_ = STATE_NONE; switch (state) { case STATE_DECIDE_PAC_FILE: DCHECK_EQ(OK, rv); rv = DoDecidePacFile(); break; case STATE_DECIDE_PAC_FILE_COMPLETE: rv = DoDecidePacFileComplete(rv); break; case STATE_CREATE_RESOLVER: DCHECK_EQ(OK, rv); rv = DoCreateResolver(); break; case STATE_CREATE_RESOLVER_COMPLETE: rv = DoCreateResolverComplete(rv); break; default: NOTREACHED() << "bad state: " << state; rv = ERR_UNEXPECTED; break; } } while (rv != ERR_IO_PENDING && next_state_ != STATE_NONE); return rv; } int DoDecidePacFile() { next_state_ = STATE_DECIDE_PAC_FILE_COMPLETE; return decider_->Start( config_, wait_delay_, proxy_resolver_factory_->expects_pac_bytes(), base::Bind(&InitProxyResolver::OnIOCompletion, base::Unretained(this))); } int DoDecidePacFileComplete(int result) { if (result != OK) return result; effective_config_ = decider_->effective_config(); script_data_ = decider_->script_data(); next_state_ = STATE_CREATE_RESOLVER; return OK; } int DoCreateResolver() { DCHECK(script_data_.get()); // TODO(eroman): Should log this latency to the NetLog. next_state_ = STATE_CREATE_RESOLVER_COMPLETE; return proxy_resolver_factory_->CreateProxyResolver( script_data_, proxy_resolver_, base::Bind(&InitProxyResolver::OnIOCompletion, base::Unretained(this)), &create_resolver_request_); } int DoCreateResolverComplete(int result) { if (result != OK) proxy_resolver_->reset(); return result; } void OnIOCompletion(int result) { DCHECK_NE(STATE_NONE, next_state_); int rv = DoLoop(result); if (rv != ERR_IO_PENDING) std::move(callback_).Run(result); } ProxyConfigWithAnnotation config_; ProxyConfigWithAnnotation effective_config_; scoped_refptr script_data_; TimeDelta wait_delay_; std::unique_ptr decider_; ProxyResolverFactory* proxy_resolver_factory_; std::unique_ptr create_resolver_request_; std::unique_ptr* proxy_resolver_; CompletionOnceCallback callback_; State next_state_; bool quick_check_enabled_; DISALLOW_COPY_AND_ASSIGN(InitProxyResolver); }; // ProxyResolutionService::PacFileDeciderPoller --------------------------- // This helper class encapsulates the logic to schedule and run periodic // background checks to see if the PAC script (or effective proxy configuration) // has changed. If a change is detected, then the caller will be notified via // the ChangeCallback. class ProxyResolutionService::PacFileDeciderPoller { public: typedef base::Callback< void(int, PacFileData*, const ProxyConfigWithAnnotation&)> ChangeCallback; // Builds a poller helper, and starts polling for updates. Whenever a change // is observed, |callback| will be invoked with the details. // // |config| specifies the (unresolved) proxy configuration to poll. // |proxy_resolver_expects_pac_bytes| the type of proxy resolver we expect // to use the resulting script data with // (so it can choose the right format). // |pac_file_fetcher| this pointer must remain alive throughout our // lifetime. It is the dependency that will be used // for downloading PAC files. // |dhcp_pac_file_fetcher| similar to |pac_file_fetcher|, but for // he DHCP dependency. // |init_net_error| This is the initial network error (possibly success) // encountered by the first PAC fetch attempt. We use it // to schedule updates more aggressively if the initial // fetch resulted in an error. // |init_script_data| the initial script data from the PAC fetch attempt. // This is the baseline used to determine when the // script's contents have changed. // |net_log| the NetLog to log progress into. PacFileDeciderPoller(ChangeCallback callback, const ProxyConfigWithAnnotation& config, bool proxy_resolver_expects_pac_bytes, PacFileFetcher* pac_file_fetcher, DhcpPacFileFetcher* dhcp_pac_file_fetcher, int init_net_error, const scoped_refptr& init_script_data, NetLog* net_log) : change_callback_(callback), config_(config), proxy_resolver_expects_pac_bytes_(proxy_resolver_expects_pac_bytes), pac_file_fetcher_(pac_file_fetcher), dhcp_pac_file_fetcher_(dhcp_pac_file_fetcher), last_error_(init_net_error), last_script_data_(init_script_data), last_poll_time_(TimeTicks::Now()), default_poll_policy_(), weak_factory_(this) { // Set the initial poll delay. next_poll_mode_ = poll_policy()->GetNextDelay( last_error_, TimeDelta::FromSeconds(-1), &next_poll_delay_); TryToStartNextPoll(false); } void OnLazyPoll() { // We have just been notified of network activity. Use this opportunity to // see if we can start our next poll. TryToStartNextPoll(true); } static const PacPollPolicy* set_policy(const PacPollPolicy* policy) { const PacPollPolicy* prev = poll_policy_; poll_policy_ = policy; return prev; } void set_quick_check_enabled(bool enabled) { quick_check_enabled_ = enabled; } bool quick_check_enabled() const { return quick_check_enabled_; } private: // Returns the effective poll policy (the one injected by unit-tests, or the // default). const PacPollPolicy* poll_policy() { if (poll_policy_) return poll_policy_; return &default_poll_policy_; } void StartPollTimer() { DCHECK(!decider_.get()); base::ThreadTaskRunnerHandle::Get()->PostDelayedTask( FROM_HERE, base::Bind(&PacFileDeciderPoller::DoPoll, weak_factory_.GetWeakPtr()), next_poll_delay_); } void TryToStartNextPoll(bool triggered_by_activity) { switch (next_poll_mode_) { case PacPollPolicy::MODE_USE_TIMER: if (!triggered_by_activity) StartPollTimer(); break; case PacPollPolicy::MODE_START_AFTER_ACTIVITY: if (triggered_by_activity && !decider_.get()) { TimeDelta elapsed_time = TimeTicks::Now() - last_poll_time_; if (elapsed_time >= next_poll_delay_) DoPoll(); } break; } } void DoPoll() { last_poll_time_ = TimeTicks::Now(); // Start the PAC file decider to see if anything has changed. // TODO(eroman): Pass a proper NetLog rather than NULL. decider_.reset( new PacFileDecider(pac_file_fetcher_, dhcp_pac_file_fetcher_, NULL)); decider_->set_quick_check_enabled(quick_check_enabled_); int result = decider_->Start( config_, TimeDelta(), proxy_resolver_expects_pac_bytes_, base::Bind(&PacFileDeciderPoller::OnPacFileDeciderCompleted, base::Unretained(this))); if (result != ERR_IO_PENDING) OnPacFileDeciderCompleted(result); } void OnPacFileDeciderCompleted(int result) { if (HasScriptDataChanged(result, decider_->script_data())) { // Something has changed, we must notify the ProxyResolutionService so it // can re-initialize its ProxyResolver. Note that we post a notification // task rather than calling it directly -- this is done to avoid an ugly // destruction sequence, since |this| might be destroyed as a result of // the notification. base::ThreadTaskRunnerHandle::Get()->PostTask( FROM_HERE, base::Bind( &PacFileDeciderPoller::NotifyProxyResolutionServiceOfChange, weak_factory_.GetWeakPtr(), result, decider_->script_data(), decider_->effective_config())); return; } decider_.reset(); // Decide when the next poll should take place, and possibly start the // next timer. next_poll_mode_ = poll_policy()->GetNextDelay( last_error_, next_poll_delay_, &next_poll_delay_); TryToStartNextPoll(false); } bool HasScriptDataChanged(int result, const scoped_refptr& script_data) { if (result != last_error_) { // Something changed -- it was failing before and now it succeeded, or // conversely it succeeded before and now it failed. Or it failed in // both cases, however the specific failure error codes differ. return true; } if (result != OK) { // If it failed last time and failed again with the same error code this // time, then nothing has actually changed. return false; } // Otherwise if it succeeded both this time and last time, we need to look // closer and see if we ended up downloading different content for the PAC // script. return !script_data->Equals(last_script_data_.get()); } void NotifyProxyResolutionServiceOfChange( int result, const scoped_refptr& script_data, const ProxyConfigWithAnnotation& effective_config) { // Note that |this| may be deleted after calling into the // ProxyResolutionService. change_callback_.Run(result, script_data.get(), effective_config); } ChangeCallback change_callback_; ProxyConfigWithAnnotation config_; bool proxy_resolver_expects_pac_bytes_; PacFileFetcher* pac_file_fetcher_; DhcpPacFileFetcher* dhcp_pac_file_fetcher_; int last_error_; scoped_refptr last_script_data_; std::unique_ptr decider_; TimeDelta next_poll_delay_; PacPollPolicy::Mode next_poll_mode_; TimeTicks last_poll_time_; // Polling policy injected by unit-tests. Otherwise this is NULL and the // default policy will be used. static const PacPollPolicy* poll_policy_; const DefaultPollPolicy default_poll_policy_; bool quick_check_enabled_; base::WeakPtrFactory weak_factory_; DISALLOW_COPY_AND_ASSIGN(PacFileDeciderPoller); }; // static const ProxyResolutionService::PacPollPolicy* ProxyResolutionService::PacFileDeciderPoller::poll_policy_ = NULL; // ProxyResolutionService::Request -------------------------------------------- class ProxyResolutionService::Request : public base::RefCounted { public: Request(ProxyResolutionService* service, const GURL& url, const std::string& method, ProxyDelegate* proxy_delegate, ProxyInfo* results, CompletionOnceCallback user_callback, const NetLogWithSource& net_log) : service_(service), user_callback_(std::move(user_callback)), results_(results), url_(url), method_(method), proxy_delegate_(proxy_delegate), resolve_job_(nullptr), net_log_(net_log), creation_time_(TimeTicks::Now()) { DCHECK(!user_callback_.is_null()); } // Starts the resolve proxy request. int Start() { DCHECK(!was_cancelled()); DCHECK(!is_started()); DCHECK(service_->config_); traffic_annotation_ = MutableNetworkTrafficAnnotationTag( service_->config_->traffic_annotation()); if (service_->ApplyPacBypassRules(url_, results_)) return OK; return resolver()->GetProxyForURL( url_, results_, base::Bind(&Request::QueryComplete, base::Unretained(this)), &resolve_job_, net_log_); } bool is_started() const { // Note that !! casts to bool. (VS gives a warning otherwise). return !!resolve_job_.get(); } void StartAndCompleteCheckingForSynchronous() { int rv = service_->TryToCompleteSynchronously(url_, proxy_delegate_, results_); if (rv == ERR_IO_PENDING) rv = Start(); if (rv != ERR_IO_PENDING) QueryComplete(rv); } void CancelResolveJob() { DCHECK(is_started()); // The request may already be running in the resolver. resolve_job_.reset(); DCHECK(!is_started()); } void Cancel() { net_log_.AddEvent(NetLogEventType::CANCELLED); if (is_started()) CancelResolveJob(); // Mark as cancelled, to prevent accessing this again later. service_ = NULL; user_callback_.Reset(); results_ = NULL; net_log_.EndEvent(NetLogEventType::PROXY_RESOLUTION_SERVICE); } // Returns true if Cancel() has been called. bool was_cancelled() const { return user_callback_.is_null(); } // Helper to call after ProxyResolver completion (both synchronous and // asynchronous). Fixes up the result that is to be returned to user. int QueryDidComplete(int result_code) { DCHECK(!was_cancelled()); // Clear |resolve_job_| so is_started() returns false while // DidFinishResolvingProxy() runs. resolve_job_.reset(); // Note that DidFinishResolvingProxy might modify |results_|. int rv = service_->DidFinishResolvingProxy(url_, method_, proxy_delegate_, results_, result_code, net_log_); // Make a note in the results which configuration was in use at the // time of the resolve. results_->did_use_pac_script_ = true; results_->proxy_resolve_start_time_ = creation_time_; results_->proxy_resolve_end_time_ = TimeTicks::Now(); // If annotation is not already set, e.g. through TryToCompleteSynchronously // function, use in-progress-resolve annotation. if (!results_->traffic_annotation_.is_valid()) results_->set_traffic_annotation(traffic_annotation_); // If proxy is set without error, ensure that an annotation is provided. if (!rv) DCHECK(results_->traffic_annotation_.is_valid()); // Reset the state associated with in-progress-resolve. traffic_annotation_.reset(); return rv; } NetLogWithSource* net_log() { return &net_log_; } LoadState GetLoadState() const { if (is_started()) return resolve_job_->GetLoadState(); return LOAD_STATE_RESOLVING_PROXY_FOR_URL; } private: friend class base::RefCounted; ~Request() = default; // Callback for when the ProxyResolver request has completed. void QueryComplete(int result_code) { result_code = QueryDidComplete(result_code); // Remove this completed Request from the service's pending list. /// (which will probably cause deletion of |this|). if (!user_callback_.is_null()) { CompletionOnceCallback callback = std::move(user_callback_); service_->RemovePendingRequest(this); std::move(callback).Run(result_code); } } ProxyResolver* resolver() const { return service_->resolver_.get(); } // Note that we don't hold a reference to the ProxyResolutionService. // Outstanding requests are cancelled during ~ProxyResolutionService, so this // is guaranteed to be valid throughout our lifetime. ProxyResolutionService* service_; CompletionOnceCallback user_callback_; ProxyInfo* results_; GURL url_; std::string method_; ProxyDelegate* proxy_delegate_; std::unique_ptr resolve_job_; MutableNetworkTrafficAnnotationTag traffic_annotation_; NetLogWithSource net_log_; // Time when the request was created. Stored here rather than in |results_| // because the time in |results_| will be cleared. TimeTicks creation_time_; }; // ProxyResolutionService ----------------------------------------------------- ProxyResolutionService::ProxyResolutionService( std::unique_ptr config_service, std::unique_ptr resolver_factory, NetLog* net_log) : resolver_factory_(std::move(resolver_factory)), current_state_(STATE_NONE), net_log_(net_log), stall_proxy_auto_config_delay_( TimeDelta::FromMilliseconds(kDelayAfterNetworkChangesMs)), quick_check_enabled_(true), sanitize_url_policy_(SanitizeUrlPolicy::SAFE) { NetworkChangeNotifier::AddIPAddressObserver(this); NetworkChangeNotifier::AddDNSObserver(this); ResetConfigService(std::move(config_service)); } // static std::unique_ptr ProxyResolutionService::CreateUsingSystemProxyResolver( std::unique_ptr proxy_config_service, NetLog* net_log) { DCHECK(proxy_config_service); if (!ProxyResolverFactoryForSystem::IsSupported()) { VLOG(1) << "PAC support disabled because there is no system implementation"; return CreateWithoutProxyResolver(std::move(proxy_config_service), net_log); } return std::make_unique( std::move(proxy_config_service), std::make_unique(kDefaultNumPacThreads), net_log); } // static std::unique_ptr ProxyResolutionService::CreateWithoutProxyResolver( std::unique_ptr proxy_config_service, NetLog* net_log) { return std::make_unique( std::move(proxy_config_service), std::make_unique(), net_log); } // static std::unique_ptr ProxyResolutionService::CreateFixed( const ProxyConfigWithAnnotation& pc) { // TODO(eroman): This isn't quite right, won't work if |pc| specifies // a PAC script. return CreateUsingSystemProxyResolver( std::make_unique(pc), NULL); } // static std::unique_ptr ProxyResolutionService::CreateFixed( const std::string& proxy, const NetworkTrafficAnnotationTag& traffic_annotation) { ProxyConfig proxy_config; proxy_config.proxy_rules().ParseFromString(proxy); ProxyConfigWithAnnotation annotated_config(proxy_config, traffic_annotation); return ProxyResolutionService::CreateFixed(annotated_config); } // static std::unique_ptr ProxyResolutionService::CreateDirect() { return CreateDirectWithNetLog(NULL); } std::unique_ptr ProxyResolutionService::CreateDirectWithNetLog(NetLog* net_log) { // Use direct connections. return std::make_unique( std::make_unique(), std::make_unique(), net_log); } // static std::unique_ptr ProxyResolutionService::CreateFixedFromPacResult( const std::string& pac_string, const NetworkTrafficAnnotationTag& traffic_annotation) { // We need the settings to contain an "automatic" setting, otherwise the // ProxyResolver dependency we give it will never be used. std::unique_ptr proxy_config_service( new ProxyConfigServiceFixed(ProxyConfigWithAnnotation( ProxyConfig::CreateAutoDetect(), traffic_annotation))); return std::make_unique( std::move(proxy_config_service), std::make_unique(pac_string), nullptr); } int ProxyResolutionService::ResolveProxy(const GURL& raw_url, const std::string& method, ProxyInfo* result, CompletionOnceCallback callback, Request** pac_request, ProxyDelegate* proxy_delegate, const NetLogWithSource& net_log) { DCHECK(!callback.is_null()); return ResolveProxyHelper(raw_url, method, result, std::move(callback), pac_request, proxy_delegate, net_log); } int ProxyResolutionService::ResolveProxyHelper( const GURL& raw_url, const std::string& method, ProxyInfo* result, CompletionOnceCallback callback, Request** pac_request, ProxyDelegate* proxy_delegate, const NetLogWithSource& net_log) { DCHECK_CALLED_ON_VALID_THREAD(thread_checker_); net_log.BeginEvent(NetLogEventType::PROXY_RESOLUTION_SERVICE); // Notify our polling-based dependencies that a resolve is taking place. // This way they can schedule their polls in response to network activity. config_service_->OnLazyPoll(); if (script_poller_.get()) script_poller_->OnLazyPoll(); if (current_state_ == STATE_NONE) ApplyProxyConfigIfAvailable(); // Sanitize the URL before passing it on to the proxy resolver (i.e. PAC // script). The goal is to remove sensitive data (like embedded user names // and password), and local data (i.e. reference fragment) which does not need // to be disclosed to the resolver. GURL url = SanitizeUrl(raw_url, sanitize_url_policy_); // Check if the request can be completed right away. (This is the case when // using a direct connection for example). int rv = TryToCompleteSynchronously(url, proxy_delegate, result); if (rv != ERR_IO_PENDING) { rv = DidFinishResolvingProxy(url, method, proxy_delegate, result, rv, net_log); return rv; } if (callback.is_null()) return ERR_IO_PENDING; scoped_refptr req(new Request(this, url, method, proxy_delegate, result, std::move(callback), net_log)); if (current_state_ == STATE_READY) { // Start the resolve request. rv = req->Start(); if (rv != ERR_IO_PENDING) return req->QueryDidComplete(rv); } else { req->net_log()->BeginEvent( NetLogEventType::PROXY_RESOLUTION_SERVICE_WAITING_FOR_INIT_PAC); } DCHECK_EQ(ERR_IO_PENDING, rv); DCHECK(!ContainsPendingRequest(req.get())); pending_requests_.insert(req); // Completion will be notified through |callback|, unless the caller cancels // the request using |pac_request|. if (pac_request) *pac_request = req.get(); return rv; // ERR_IO_PENDING } bool ProxyResolutionService::TryResolveProxySynchronously( const GURL& raw_url, const std::string& method, ProxyInfo* result, ProxyDelegate* proxy_delegate, const NetLogWithSource& net_log) { return ResolveProxyHelper(raw_url, method, result, CompletionOnceCallback(), nullptr /* pac_request*/, proxy_delegate, net_log) == OK; } int ProxyResolutionService::TryToCompleteSynchronously( const GURL& url, ProxyDelegate* proxy_delegate, ProxyInfo* result) { DCHECK_NE(STATE_NONE, current_state_); if (current_state_ != STATE_READY) return ERR_IO_PENDING; // Still initializing. DCHECK(config_); // If it was impossible to fetch or parse the PAC script, we cannot complete // the request here and bail out. if (permanent_error_ != OK) { // Before returning the permanent error check if the URL would have been // implicitly bypassed. if (ApplyPacBypassRules(url, result)) return OK; return permanent_error_; } if (config_->value().HasAutomaticSettings()) return ERR_IO_PENDING; // Must submit the request to the proxy resolver. // Use the manual proxy settings. config_->value().proxy_rules().Apply(url, result); result->set_traffic_annotation( MutableNetworkTrafficAnnotationTag(config_->traffic_annotation())); return OK; } ProxyResolutionService::~ProxyResolutionService() { DCHECK_CALLED_ON_VALID_THREAD(thread_checker_); NetworkChangeNotifier::RemoveIPAddressObserver(this); NetworkChangeNotifier::RemoveDNSObserver(this); config_service_->RemoveObserver(this); // Cancel any inprogress requests. for (PendingRequests::iterator it = pending_requests_.begin(); it != pending_requests_.end(); ++it) { (*it)->Cancel(); } } void ProxyResolutionService::SuspendAllPendingRequests() { for (PendingRequests::iterator it = pending_requests_.begin(); it != pending_requests_.end(); ++it) { Request* req = it->get(); if (req->is_started()) { req->CancelResolveJob(); req->net_log()->BeginEvent( NetLogEventType::PROXY_RESOLUTION_SERVICE_WAITING_FOR_INIT_PAC); } } } void ProxyResolutionService::SetReady() { DCHECK(!init_proxy_resolver_.get()); current_state_ = STATE_READY; // Make a copy in case |this| is deleted during the synchronous completion // of one of the requests. If |this| is deleted then all of the Request // instances will be Cancel()-ed. PendingRequests pending_copy = pending_requests_; for (PendingRequests::iterator it = pending_copy.begin(); it != pending_copy.end(); ++it) { Request* req = it->get(); if (!req->is_started() && !req->was_cancelled()) { req->net_log()->EndEvent( NetLogEventType::PROXY_RESOLUTION_SERVICE_WAITING_FOR_INIT_PAC); // Note that we re-check for synchronous completion, in case we are // no longer using a ProxyResolver (can happen if we fell-back to manual). req->StartAndCompleteCheckingForSynchronous(); } } } void ProxyResolutionService::ApplyProxyConfigIfAvailable() { DCHECK_EQ(STATE_NONE, current_state_); config_service_->OnLazyPoll(); // If we have already fetched the configuration, start applying it. if (fetched_config_) { InitializeUsingLastFetchedConfig(); return; } // Otherwise we need to first fetch the configuration. current_state_ = STATE_WAITING_FOR_PROXY_CONFIG; // Retrieve the current proxy configuration from the ProxyConfigService. // If a configuration is not available yet, we will get called back later // by our ProxyConfigService::Observer once it changes. ProxyConfigWithAnnotation config; ProxyConfigService::ConfigAvailability availability = config_service_->GetLatestProxyConfig(&config); if (availability != ProxyConfigService::CONFIG_PENDING) OnProxyConfigChanged(config, availability); } void ProxyResolutionService::OnInitProxyResolverComplete(int result) { DCHECK_EQ(STATE_WAITING_FOR_INIT_PROXY_RESOLVER, current_state_); DCHECK(init_proxy_resolver_.get()); DCHECK(fetched_config_); DCHECK(fetched_config_->value().HasAutomaticSettings()); config_ = init_proxy_resolver_->effective_config(); // At this point we have decided which proxy settings to use (i.e. which PAC // script if any). We start up a background poller to periodically revisit // this decision. If the contents of the PAC script change, or if the // result of proxy auto-discovery changes, this poller will notice it and // will trigger a re-initialization using the newly discovered PAC. script_poller_.reset(new PacFileDeciderPoller( base::Bind(&ProxyResolutionService::InitializeUsingDecidedConfig, base::Unretained(this)), fetched_config_.value(), resolver_factory_->expects_pac_bytes(), pac_file_fetcher_.get(), dhcp_pac_file_fetcher_.get(), result, init_proxy_resolver_->script_data(), NULL)); script_poller_->set_quick_check_enabled(quick_check_enabled_); init_proxy_resolver_.reset(); if (result != OK) { if (fetched_config_->value().pac_mandatory()) { VLOG(1) << "Failed configuring with mandatory PAC script, blocking all " "traffic."; config_ = fetched_config_; result = ERR_MANDATORY_PROXY_CONFIGURATION_FAILED; } else { VLOG(1) << "Failed configuring with PAC script, falling-back to manual " "proxy servers."; ProxyConfig proxy_config = fetched_config_->value(); proxy_config.ClearAutomaticSettings(); config_ = ProxyConfigWithAnnotation( proxy_config, fetched_config_->traffic_annotation()); result = OK; } } permanent_error_ = result; // Resume any requests which we had to defer until the PAC script was // downloaded. SetReady(); } bool ProxyResolutionService::MarkProxiesAsBadUntil( const ProxyInfo& result, base::TimeDelta retry_delay, const std::vector& additional_bad_proxies, const NetLogWithSource& net_log) { result.proxy_list_.UpdateRetryInfoOnFallback(&proxy_retry_info_, retry_delay, false, additional_bad_proxies, OK, net_log); return result.proxy_list_.size() > (additional_bad_proxies.size() + 1); } void ProxyResolutionService::ReportSuccess(const ProxyInfo& result, ProxyDelegate* proxy_delegate) { DCHECK_CALLED_ON_VALID_THREAD(thread_checker_); const ProxyRetryInfoMap& new_retry_info = result.proxy_retry_info(); if (new_retry_info.empty()) return; for (ProxyRetryInfoMap::const_iterator iter = new_retry_info.begin(); iter != new_retry_info.end(); ++iter) { ProxyRetryInfoMap::iterator existing = proxy_retry_info_.find(iter->first); if (existing == proxy_retry_info_.end()) { proxy_retry_info_[iter->first] = iter->second; if (proxy_delegate) { const ProxyServer& bad_proxy = ProxyServer::FromURI(iter->first, ProxyServer::SCHEME_HTTP); const ProxyRetryInfo& proxy_retry_info = iter->second; proxy_delegate->OnFallback(bad_proxy, proxy_retry_info.net_error); } } else if (existing->second.bad_until < iter->second.bad_until) existing->second.bad_until = iter->second.bad_until; } if (net_log_) { net_log_->AddGlobalEntry( NetLogEventType::BAD_PROXY_LIST_REPORTED, base::Bind(&NetLogBadProxyListCallback, &new_retry_info)); } } void ProxyResolutionService::CancelRequest(Request* req) { DCHECK_CALLED_ON_VALID_THREAD(thread_checker_); DCHECK(req); req->Cancel(); RemovePendingRequest(req); } LoadState ProxyResolutionService::GetLoadState(const Request* req) const { CHECK(req); if (current_state_ == STATE_WAITING_FOR_INIT_PROXY_RESOLVER) return init_proxy_resolver_->GetLoadState(); return req->GetLoadState(); } bool ProxyResolutionService::ContainsPendingRequest(Request* req) { return pending_requests_.count(req) == 1; } void ProxyResolutionService::RemovePendingRequest(Request* req) { DCHECK(ContainsPendingRequest(req)); pending_requests_.erase(req); } int ProxyResolutionService::DidFinishResolvingProxy( const GURL& url, const std::string& method, ProxyDelegate* proxy_delegate, ProxyInfo* result, int result_code, const NetLogWithSource& net_log) { // Log the result of the proxy resolution. if (result_code == OK) { // Allow the proxy delegate to interpose on the resolution decision, // possibly modifying the ProxyInfo. if (proxy_delegate) proxy_delegate->OnResolveProxy(url, method, proxy_retry_info_, result); net_log.AddEvent( NetLogEventType::PROXY_RESOLUTION_SERVICE_RESOLVED_PROXY_LIST, base::Bind(&NetLogFinishedResolvingProxyCallback, result)); // This check is done to only log the NetLog event when necessary, it's // not a performance optimization. if (!proxy_retry_info_.empty()) { result->DeprioritizeBadProxies(proxy_retry_info_); net_log.AddEvent( NetLogEventType::PROXY_RESOLUTION_SERVICE_DEPRIORITIZED_BAD_PROXIES, base::Bind(&NetLogFinishedResolvingProxyCallback, result)); } } else { net_log.AddEventWithNetErrorCode( NetLogEventType::PROXY_RESOLUTION_SERVICE_RESOLVED_PROXY_LIST, result_code); bool reset_config = result_code == ERR_PAC_SCRIPT_TERMINATED; if (!config_->value().pac_mandatory()) { // Fall-back to direct when the proxy resolver fails. This corresponds // with a javascript runtime error in the PAC script. // // This implicit fall-back to direct matches Firefox 3.5 and // Internet Explorer 8. For more information, see: // // http://www.chromium.org/developers/design-documents/proxy-settings-fallback result->UseDirect(); result_code = OK; // Allow the proxy delegate to interpose on the resolution decision, // possibly modifying the ProxyInfo. if (proxy_delegate) proxy_delegate->OnResolveProxy(url, method, proxy_retry_info_, result); } else { result_code = ERR_MANDATORY_PROXY_CONFIGURATION_FAILED; } if (reset_config) { ResetProxyConfig(false); // If the ProxyResolver crashed, force it to be re-initialized for the // next request by resetting the proxy config. If there are other pending // requests, trigger the recreation immediately so those requests retry. if (pending_requests_.size() > 1) ApplyProxyConfigIfAvailable(); } } net_log.EndEvent(NetLogEventType::PROXY_RESOLUTION_SERVICE); return result_code; } void ProxyResolutionService::SetPacFileFetchers( std::unique_ptr pac_file_fetcher, std::unique_ptr dhcp_pac_file_fetcher) { DCHECK_CALLED_ON_VALID_THREAD(thread_checker_); State previous_state = ResetProxyConfig(false); pac_file_fetcher_ = std::move(pac_file_fetcher); dhcp_pac_file_fetcher_ = std::move(dhcp_pac_file_fetcher); if (previous_state != STATE_NONE) ApplyProxyConfigIfAvailable(); } void ProxyResolutionService::OnShutdown() { // Order here does not matter for correctness. |init_proxy_resolver_| is first // because shutting it down also cancels its requests using the fetcher. if (init_proxy_resolver_) init_proxy_resolver_->OnShutdown(); if (pac_file_fetcher_) pac_file_fetcher_->OnShutdown(); if (dhcp_pac_file_fetcher_) dhcp_pac_file_fetcher_->OnShutdown(); } PacFileFetcher* ProxyResolutionService::GetPacFileFetcher() const { DCHECK_CALLED_ON_VALID_THREAD(thread_checker_); return pac_file_fetcher_.get(); } ProxyResolutionService::State ProxyResolutionService::ResetProxyConfig( bool reset_fetched_config) { DCHECK_CALLED_ON_VALID_THREAD(thread_checker_); State previous_state = current_state_; permanent_error_ = OK; proxy_retry_info_.clear(); script_poller_.reset(); init_proxy_resolver_.reset(); SuspendAllPendingRequests(); resolver_.reset(); config_ = base::nullopt; if (reset_fetched_config) fetched_config_ = base::nullopt; current_state_ = STATE_NONE; return previous_state; } void ProxyResolutionService::ResetConfigService( std::unique_ptr new_proxy_config_service) { DCHECK_CALLED_ON_VALID_THREAD(thread_checker_); State previous_state = ResetProxyConfig(true); // Release the old configuration service. if (config_service_.get()) config_service_->RemoveObserver(this); // Set the new configuration service. config_service_ = std::move(new_proxy_config_service); config_service_->AddObserver(this); if (previous_state != STATE_NONE) ApplyProxyConfigIfAvailable(); } void ProxyResolutionService::ForceReloadProxyConfig() { DCHECK_CALLED_ON_VALID_THREAD(thread_checker_); ResetProxyConfig(false); ApplyProxyConfigIfAvailable(); } // static std::unique_ptr ProxyResolutionService::CreateSystemProxyConfigService( const scoped_refptr& main_task_runner) { #if defined(OS_WIN) return std::make_unique( kSystemProxyConfigTrafficAnnotation); #elif defined(OS_IOS) return std::make_unique( kSystemProxyConfigTrafficAnnotation); #elif defined(OS_MACOSX) return std::make_unique( main_task_runner, kSystemProxyConfigTrafficAnnotation); #elif defined(OS_CHROMEOS) LOG(ERROR) << "ProxyConfigService for ChromeOS should be created in " << "profile_io_data.cc::CreateProxyConfigService and this should " << "be used only for examples."; return std::make_unique(); #elif defined(OS_LINUX) std::unique_ptr linux_config_service( new ProxyConfigServiceLinux()); // Assume we got called on the thread that runs the default glib // main loop, so the current thread is where we should be running // gsettings calls from. scoped_refptr glib_thread_task_runner = base::ThreadTaskRunnerHandle::Get(); // Synchronously fetch the current proxy config (since we are running on // glib_default_loop). Additionally register for notifications (delivered in // either |glib_default_loop| or an internal sequenced task runner) to // keep us updated when the proxy config changes. linux_config_service->SetupAndFetchInitialConfig( glib_thread_task_runner, main_task_runner, kSystemProxyConfigTrafficAnnotation); return std::move(linux_config_service); #elif defined(OS_ANDROID) return std::make_unique( main_task_runner, base::ThreadTaskRunnerHandle::Get()); #else LOG(WARNING) << "Failed to choose a system proxy settings fetcher " "for this platform."; return std::make_unique(); #endif } // static const ProxyResolutionService::PacPollPolicy* ProxyResolutionService::set_pac_script_poll_policy( const PacPollPolicy* policy) { return PacFileDeciderPoller::set_policy(policy); } // static std::unique_ptr ProxyResolutionService::CreateDefaultPacPollPolicy() { return std::unique_ptr(new DefaultPollPolicy()); } void ProxyResolutionService::OnProxyConfigChanged( const ProxyConfigWithAnnotation& config, ProxyConfigService::ConfigAvailability availability) { // Retrieve the current proxy configuration from the ProxyConfigService. // If a configuration is not available yet, we will get called back later // by our ProxyConfigService::Observer once it changes. ProxyConfigWithAnnotation effective_config; switch (availability) { case ProxyConfigService::CONFIG_PENDING: // ProxyConfigService implementors should never pass CONFIG_PENDING. NOTREACHED() << "Proxy config change with CONFIG_PENDING availability!"; return; case ProxyConfigService::CONFIG_VALID: effective_config = config; break; case ProxyConfigService::CONFIG_UNSET: effective_config = ProxyConfigWithAnnotation::CreateDirect(); break; } // Emit the proxy settings change to the NetLog stream. if (net_log_) { net_log_->AddGlobalEntry(NetLogEventType::PROXY_CONFIG_CHANGED, base::Bind(&NetLogProxyConfigChangedCallback, &fetched_config_, &effective_config)); } if (config.value().has_pac_url()) { UMA_HISTOGRAM_ENUMERATION("Net.ProxyResolutionService.PacUrlScheme", GetPacUrlScheme(config.value().pac_url())); } // Set the new configuration as the most recently fetched one. fetched_config_ = effective_config; InitializeUsingLastFetchedConfig(); } bool ProxyResolutionService::ApplyPacBypassRules(const GURL& url, ProxyInfo* results) { DCHECK(config_); if (ProxyBypassRules::MatchesImplicitRules(url)) { results->UseDirectWithBypassedProxy(); return true; } return false; } void ProxyResolutionService::InitializeUsingLastFetchedConfig() { ResetProxyConfig(false); DCHECK(fetched_config_); if (!fetched_config_->value().HasAutomaticSettings()) { config_ = fetched_config_; SetReady(); return; } // Start downloading + testing the PAC scripts for this new configuration. current_state_ = STATE_WAITING_FOR_INIT_PROXY_RESOLVER; // If we changed networks recently, we should delay running proxy auto-config. TimeDelta wait_delay = stall_proxy_autoconfig_until_ - TimeTicks::Now(); init_proxy_resolver_.reset(new InitProxyResolver()); init_proxy_resolver_->set_quick_check_enabled(quick_check_enabled_); int rv = init_proxy_resolver_->Start( &resolver_, resolver_factory_.get(), pac_file_fetcher_.get(), dhcp_pac_file_fetcher_.get(), net_log_, fetched_config_.value(), wait_delay, base::Bind(&ProxyResolutionService::OnInitProxyResolverComplete, base::Unretained(this))); if (rv != ERR_IO_PENDING) OnInitProxyResolverComplete(rv); } void ProxyResolutionService::InitializeUsingDecidedConfig( int decider_result, PacFileData* script_data, const ProxyConfigWithAnnotation& effective_config) { DCHECK(fetched_config_); DCHECK(fetched_config_->value().HasAutomaticSettings()); ResetProxyConfig(false); current_state_ = STATE_WAITING_FOR_INIT_PROXY_RESOLVER; init_proxy_resolver_.reset(new InitProxyResolver()); int rv = init_proxy_resolver_->StartSkipDecider( &resolver_, resolver_factory_.get(), effective_config, decider_result, script_data, base::Bind(&ProxyResolutionService::OnInitProxyResolverComplete, base::Unretained(this))); if (rv != ERR_IO_PENDING) OnInitProxyResolverComplete(rv); } void ProxyResolutionService::OnIPAddressChanged() { // See the comment block by |kDelayAfterNetworkChangesMs| for info. stall_proxy_autoconfig_until_ = TimeTicks::Now() + stall_proxy_auto_config_delay_; State previous_state = ResetProxyConfig(false); if (previous_state != STATE_NONE) ApplyProxyConfigIfAvailable(); } void ProxyResolutionService::OnDNSChanged() { OnIPAddressChanged(); } } // namespace net