// // Copyright (C) 2014 The Android Open Source Project // // Licensed under the Apache License, Version 2.0 (the "License"); // you may not use this file except in compliance with the License. // You may obtain a copy of the License at // // http://www.apache.org/licenses/LICENSE-2.0 // // Unless required by applicable law or agreed to in writing, software // distributed under the License is distributed on an "AS IS" BASIS, // WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. // See the License for the specific language governing permissions and // limitations under the License. // #include "update_engine/update_manager/evaluation_context.h" #include #include #include #include #include #include #include #include #include #include "update_engine/common/utils.h" using base::Callback; using base::Closure; using base::Time; using base::TimeDelta; using brillo::MessageLoop; using chromeos_update_engine::ClockInterface; using std::string; using std::unique_ptr; namespace { // Returns whether |curr_time| surpassed |ref_time|; if not, also checks whether // |ref_time| is sooner than the current value of |*reeval_time|, in which case // the latter is updated to the former. bool IsTimeGreaterThanHelper(Time ref_time, Time curr_time, Time* reeval_time) { if (curr_time > ref_time) return true; // Remember the nearest reference we've checked against in this evaluation. if (*reeval_time > ref_time) *reeval_time = ref_time; return false; } // If |expires| never happens (maximal value), returns the maximal interval; // otherwise, returns the difference between |expires| and |curr|. TimeDelta GetTimeout(Time curr, Time expires) { if (expires.is_max()) return TimeDelta::Max(); return expires - curr; } } // namespace namespace chromeos_update_manager { EvaluationContext::EvaluationContext( ClockInterface* clock, TimeDelta evaluation_timeout, TimeDelta expiration_timeout, unique_ptr> unregister_cb) : clock_(clock), evaluation_timeout_(evaluation_timeout), expiration_timeout_(expiration_timeout), unregister_cb_(std::move(unregister_cb)), weak_ptr_factory_(this) { ResetEvaluation(); ResetExpiration(); } EvaluationContext::~EvaluationContext() { RemoveObserversAndTimeout(); if (unregister_cb_.get()) unregister_cb_->Run(this); } unique_ptr EvaluationContext::RemoveObserversAndTimeout() { for (auto& it : value_cache_) { if (it.first->GetMode() == kVariableModeAsync) it.first->RemoveObserver(this); } MessageLoop::current()->CancelTask(timeout_event_); timeout_event_ = MessageLoop::kTaskIdNull; return std::move(callback_); } TimeDelta EvaluationContext::RemainingTime(Time monotonic_deadline) const { if (monotonic_deadline.is_max()) return TimeDelta::Max(); TimeDelta remaining = monotonic_deadline - clock_->GetMonotonicTime(); return std::max(remaining, TimeDelta()); } Time EvaluationContext::MonotonicDeadline(TimeDelta timeout) { return (timeout.is_max() ? Time::Max() : clock_->GetMonotonicTime() + timeout); } void EvaluationContext::ValueChanged(BaseVariable* var) { DLOG(INFO) << "ValueChanged() called for variable " << var->GetName(); OnValueChangedOrTimeout(); } void EvaluationContext::OnTimeout() { DLOG(INFO) << "OnTimeout() called due to " << (timeout_marks_expiration_ ? "expiration" : "poll interval"); timeout_event_ = MessageLoop::kTaskIdNull; is_expired_ = timeout_marks_expiration_; OnValueChangedOrTimeout(); } void EvaluationContext::OnValueChangedOrTimeout() { // Copy the callback handle locally, allowing it to be reassigned. unique_ptr callback = RemoveObserversAndTimeout(); if (callback.get()) callback->Run(); } bool EvaluationContext::IsWallclockTimeGreaterThan(Time timestamp) { return IsTimeGreaterThanHelper( timestamp, evaluation_start_wallclock_, &reevaluation_time_wallclock_); } bool EvaluationContext::IsMonotonicTimeGreaterThan(Time timestamp) { return IsTimeGreaterThanHelper( timestamp, evaluation_start_monotonic_, &reevaluation_time_monotonic_); } void EvaluationContext::ResetEvaluation() { evaluation_start_wallclock_ = clock_->GetWallclockTime(); evaluation_start_monotonic_ = clock_->GetMonotonicTime(); reevaluation_time_wallclock_ = Time::Max(); reevaluation_time_monotonic_ = Time::Max(); evaluation_monotonic_deadline_ = MonotonicDeadline(evaluation_timeout_); // Remove the cached values of non-const variables for (auto it = value_cache_.begin(); it != value_cache_.end();) { if (it->first->GetMode() == kVariableModeConst) { ++it; } else { it = value_cache_.erase(it); } } } void EvaluationContext::ResetExpiration() { expiration_monotonic_deadline_ = MonotonicDeadline(expiration_timeout_); is_expired_ = false; } bool EvaluationContext::RunOnValueChangeOrTimeout(Closure callback) { // Check that the method was not called more than once. if (callback_.get()) { LOG(ERROR) << "RunOnValueChangeOrTimeout called more than once."; return false; } // Check that the context did not yet expire. if (is_expired()) { LOG(ERROR) << "RunOnValueChangeOrTimeout called on an expired context."; return false; } // Handle reevaluation due to a Is{Wallclock,Monotonic}TimeGreaterThan(). We // choose the smaller of the differences between evaluation start time and // reevaluation time among the wallclock and monotonic scales. TimeDelta timeout = std::min( GetTimeout(evaluation_start_wallclock_, reevaluation_time_wallclock_), GetTimeout(evaluation_start_monotonic_, reevaluation_time_monotonic_)); // Handle reevaluation due to async or poll variables. bool waiting_for_value_change = false; for (auto& it : value_cache_) { switch (it.first->GetMode()) { case kVariableModeAsync: DLOG(INFO) << "Waiting for value on " << it.first->GetName(); it.first->AddObserver(this); waiting_for_value_change = true; break; case kVariableModePoll: timeout = std::min(timeout, it.first->GetPollInterval()); break; case kVariableModeConst: // Ignored. break; } } // Check if the re-evaluation is actually being scheduled. If there are no // events waited for, this function should return false. if (!waiting_for_value_change && timeout.is_max()) return false; // Ensure that we take into account the expiration timeout. TimeDelta expiration = RemainingTime(expiration_monotonic_deadline_); timeout_marks_expiration_ = expiration < timeout; if (timeout_marks_expiration_) timeout = expiration; // Store the reevaluation callback. callback_.reset(new Closure(callback)); // Schedule a timeout event, if one is set. if (!timeout.is_max()) { DLOG(INFO) << "Waiting for timeout in " << chromeos_update_engine::utils::FormatTimeDelta(timeout); timeout_event_ = MessageLoop::current()->PostDelayedTask( FROM_HERE, base::Bind(&EvaluationContext::OnTimeout, weak_ptr_factory_.GetWeakPtr()), timeout); } return true; } string EvaluationContext::DumpContext() const { auto variables = std::make_unique(); for (auto& it : value_cache_) { variables->SetString(it.first->GetName(), it.second.ToString()); } base::DictionaryValue value; value.Set("variables", std::move(variables)); value.SetString( "evaluation_start_wallclock", chromeos_update_engine::utils::ToString(evaluation_start_wallclock_)); value.SetString( "evaluation_start_monotonic", chromeos_update_engine::utils::ToString(evaluation_start_monotonic_)); string json_str; base::JSONWriter::WriteWithOptions( value, base::JSONWriter::OPTIONS_PRETTY_PRINT, &json_str); base::TrimWhitespaceASCII(json_str, base::TRIM_TRAILING, &json_str); return json_str; } } // namespace chromeos_update_manager