// Copyright 2015 The Chromium OS Authors. All rights reserved. // Use of this source code is governed by a BSD-style license that can be // found in the LICENSE file. #ifndef LIBBRILLO_BRILLO_BACKOFF_ENTRY_H_ #define LIBBRILLO_BRILLO_BACKOFF_ENTRY_H_ #include <base/time/time.h> #include <brillo/brillo_export.h> namespace brillo { // Provides the core logic needed for randomized exponential back-off // on requests to a given resource, given a back-off policy. // // This class is largely taken from net/base/backoff_entry.h from Chromium. // TODO(avakulenko): Consider packaging portions of Chrome's //net functionality // into the current libchrome library. class BRILLO_EXPORT BackoffEntry { public: // The set of parameters that define a back-off policy. struct Policy { // Number of initial errors (in sequence) to ignore before applying // exponential back-off rules. int num_errors_to_ignore; // Initial delay. The interpretation of this value depends on // always_use_initial_delay. It's either how long we wait between // requests before backoff starts, or how much we delay the first request // after backoff starts. int initial_delay_ms; // Factor by which the waiting time will be multiplied. double multiply_factor; // Fuzzing percentage. ex: 10% will spread requests randomly // between 90%-100% of the calculated time. double jitter_factor; // Maximum amount of time we are willing to delay our request, -1 // for no maximum. int64_t maximum_backoff_ms; // Time to keep an entry from being discarded even when it // has no significant state, -1 to never discard. int64_t entry_lifetime_ms; // If true, we always use a delay of initial_delay_ms, even before // we've seen num_errors_to_ignore errors. Otherwise, initial_delay_ms // is the first delay once we start exponential backoff. // // So if we're ignoring 1 error, we'll see (N, N, Nm, Nm^2, ...) if true, // and (0, 0, N, Nm, ...) when false, where N is initial_backoff_ms and // m is multiply_factor, assuming we've already seen one success. bool always_use_initial_delay; }; // Lifetime of policy must enclose lifetime of BackoffEntry. The // pointer must be valid but is not dereferenced during construction. explicit BackoffEntry(const Policy* const policy); virtual ~BackoffEntry() = default; // Inform this item that a request for the network resource it is // tracking was made, and whether it failed or succeeded. void InformOfRequest(bool succeeded); // Returns true if a request for the resource this item tracks should // be rejected at the present time due to exponential back-off policy. bool ShouldRejectRequest() const; // Returns the absolute time after which this entry (given its present // state) will no longer reject requests. base::TimeTicks GetReleaseTime() const; // Returns the time until a request can be sent. base::TimeDelta GetTimeUntilRelease() const; // Causes this object reject requests until the specified absolute time. // This can be used to e.g. implement support for a Retry-After header. void SetCustomReleaseTime(const base::TimeTicks& release_time); // Returns true if this object has no significant state (i.e. you could // just as well start with a fresh BackoffEntry object), and hasn't // had for Policy::entry_lifetime_ms. bool CanDiscard() const; // Resets this entry to a fresh (as if just constructed) state. void Reset(); // Returns the failure count for this entry. int failure_count() const { return failure_count_; } protected: // Equivalent to TimeTicks::Now(), virtual so unit tests can override. virtual base::TimeTicks ImplGetTimeNow() const; private: // Calculates when requests should again be allowed through. base::TimeTicks CalculateReleaseTime() const; // Timestamp calculated by the exponential back-off algorithm at which we are // allowed to start sending requests again. base::TimeTicks exponential_backoff_release_time_; // Counts request errors; decremented on success. int failure_count_; const Policy* const policy_; DISALLOW_COPY_AND_ASSIGN(BackoffEntry); }; } // namespace brillo #endif // LIBBRILLO_BRILLO_BACKOFF_ENTRY_H_