// Copyright 2015 The Weave 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 "src/backoff_entry.h" #include using base::TimeDelta; using base::TimeTicks; namespace weave { BackoffEntry::Policy base_policy = {0, 1000, 2.0, 0.0, 20000, 2000, false}; class TestBackoffEntry : public BackoffEntry { public: explicit TestBackoffEntry(const Policy* const policy) : BackoffEntry(policy), now_(TimeTicks()) { // Work around initialization in constructor not picking up // fake time. SetCustomReleaseTime(TimeTicks()); } ~TestBackoffEntry() override {} TimeTicks ImplGetTimeNow() const override { return now_; } void set_now(const TimeTicks& now) { now_ = now; } private: TimeTicks now_; DISALLOW_COPY_AND_ASSIGN(TestBackoffEntry); }; TEST(BackoffEntryTest, BaseTest) { TestBackoffEntry entry(&base_policy); EXPECT_FALSE(entry.ShouldRejectRequest()); EXPECT_EQ(TimeDelta(), entry.GetTimeUntilRelease()); entry.InformOfRequest(false); EXPECT_TRUE(entry.ShouldRejectRequest()); EXPECT_EQ(TimeDelta::FromMilliseconds(1000), entry.GetTimeUntilRelease()); } TEST(BackoffEntryTest, CanDiscardNeverExpires) { BackoffEntry::Policy never_expires_policy = base_policy; never_expires_policy.entry_lifetime_ms = -1; TestBackoffEntry never_expires(&never_expires_policy); EXPECT_FALSE(never_expires.CanDiscard()); never_expires.set_now(TimeTicks() + TimeDelta::FromDays(100)); EXPECT_FALSE(never_expires.CanDiscard()); } TEST(BackoffEntryTest, CanDiscard) { TestBackoffEntry entry(&base_policy); // Because lifetime is non-zero, we shouldn't be able to discard yet. EXPECT_FALSE(entry.CanDiscard()); // Test the "being used" case. entry.InformOfRequest(false); EXPECT_FALSE(entry.CanDiscard()); // Test the case where there are errors but we can time out. entry.set_now(entry.GetReleaseTime() + TimeDelta::FromMilliseconds(1)); EXPECT_FALSE(entry.CanDiscard()); entry.set_now( entry.GetReleaseTime() + TimeDelta::FromMilliseconds(base_policy.maximum_backoff_ms + 1)); EXPECT_TRUE(entry.CanDiscard()); // Test the final case (no errors, dependent only on specified lifetime). entry.set_now(entry.GetReleaseTime() + TimeDelta::FromMilliseconds(base_policy.entry_lifetime_ms - 1)); entry.InformOfRequest(true); EXPECT_FALSE(entry.CanDiscard()); entry.set_now(entry.GetReleaseTime() + TimeDelta::FromMilliseconds(base_policy.entry_lifetime_ms)); EXPECT_TRUE(entry.CanDiscard()); } TEST(BackoffEntryTest, CanDiscardAlwaysDelay) { BackoffEntry::Policy always_delay_policy = base_policy; always_delay_policy.always_use_initial_delay = true; always_delay_policy.entry_lifetime_ms = 0; TestBackoffEntry entry(&always_delay_policy); // Because lifetime is non-zero, we shouldn't be able to discard yet. entry.set_now(entry.GetReleaseTime() + TimeDelta::FromMilliseconds(2000)); EXPECT_TRUE(entry.CanDiscard()); // Even with no failures, we wait until the delay before we allow discard. entry.InformOfRequest(true); EXPECT_FALSE(entry.CanDiscard()); // Wait until the delay expires, and we can discard the entry again. entry.set_now(entry.GetReleaseTime() + TimeDelta::FromMilliseconds(1000)); EXPECT_TRUE(entry.CanDiscard()); } TEST(BackoffEntryTest, CanDiscardNotStored) { BackoffEntry::Policy no_store_policy = base_policy; no_store_policy.entry_lifetime_ms = 0; TestBackoffEntry not_stored(&no_store_policy); EXPECT_TRUE(not_stored.CanDiscard()); } TEST(BackoffEntryTest, ShouldIgnoreFirstTwo) { BackoffEntry::Policy lenient_policy = base_policy; lenient_policy.num_errors_to_ignore = 2; BackoffEntry entry(&lenient_policy); entry.InformOfRequest(false); EXPECT_FALSE(entry.ShouldRejectRequest()); entry.InformOfRequest(false); EXPECT_FALSE(entry.ShouldRejectRequest()); entry.InformOfRequest(false); EXPECT_TRUE(entry.ShouldRejectRequest()); } TEST(BackoffEntryTest, ReleaseTimeCalculation) { TestBackoffEntry entry(&base_policy); // With zero errors, should return "now". TimeTicks result = entry.GetReleaseTime(); EXPECT_EQ(entry.ImplGetTimeNow(), result); // 1 error. entry.InformOfRequest(false); result = entry.GetReleaseTime(); EXPECT_EQ(entry.ImplGetTimeNow() + TimeDelta::FromMilliseconds(1000), result); EXPECT_EQ(TimeDelta::FromMilliseconds(1000), entry.GetTimeUntilRelease()); // 2 errors. entry.InformOfRequest(false); result = entry.GetReleaseTime(); EXPECT_EQ(entry.ImplGetTimeNow() + TimeDelta::FromMilliseconds(2000), result); EXPECT_EQ(TimeDelta::FromMilliseconds(2000), entry.GetTimeUntilRelease()); // 3 errors. entry.InformOfRequest(false); result = entry.GetReleaseTime(); EXPECT_EQ(entry.ImplGetTimeNow() + TimeDelta::FromMilliseconds(4000), result); EXPECT_EQ(TimeDelta::FromMilliseconds(4000), entry.GetTimeUntilRelease()); // 6 errors (to check it doesn't pass maximum). entry.InformOfRequest(false); entry.InformOfRequest(false); entry.InformOfRequest(false); result = entry.GetReleaseTime(); EXPECT_EQ(entry.ImplGetTimeNow() + TimeDelta::FromMilliseconds(20000), result); } TEST(BackoffEntryTest, ReleaseTimeCalculationAlwaysDelay) { BackoffEntry::Policy always_delay_policy = base_policy; always_delay_policy.always_use_initial_delay = true; always_delay_policy.num_errors_to_ignore = 2; TestBackoffEntry entry(&always_delay_policy); // With previous requests, should return "now". TimeTicks result = entry.GetReleaseTime(); EXPECT_EQ(TimeDelta(), entry.GetTimeUntilRelease()); // 1 error. entry.InformOfRequest(false); EXPECT_EQ(TimeDelta::FromMilliseconds(1000), entry.GetTimeUntilRelease()); // 2 errors. entry.InformOfRequest(false); EXPECT_EQ(TimeDelta::FromMilliseconds(1000), entry.GetTimeUntilRelease()); // 3 errors, exponential backoff starts. entry.InformOfRequest(false); EXPECT_EQ(TimeDelta::FromMilliseconds(2000), entry.GetTimeUntilRelease()); // 4 errors. entry.InformOfRequest(false); EXPECT_EQ(TimeDelta::FromMilliseconds(4000), entry.GetTimeUntilRelease()); // 8 errors (to check it doesn't pass maximum). entry.InformOfRequest(false); entry.InformOfRequest(false); entry.InformOfRequest(false); entry.InformOfRequest(false); result = entry.GetReleaseTime(); EXPECT_EQ(TimeDelta::FromMilliseconds(20000), entry.GetTimeUntilRelease()); } TEST(BackoffEntryTest, ReleaseTimeCalculationWithJitter) { for (int i = 0; i < 10; ++i) { BackoffEntry::Policy jittery_policy = base_policy; jittery_policy.jitter_factor = 0.2; TestBackoffEntry entry(&jittery_policy); entry.InformOfRequest(false); entry.InformOfRequest(false); entry.InformOfRequest(false); TimeTicks result = entry.GetReleaseTime(); EXPECT_LE(entry.ImplGetTimeNow() + TimeDelta::FromMilliseconds(3200), result); EXPECT_GE(entry.ImplGetTimeNow() + TimeDelta::FromMilliseconds(4000), result); } } TEST(BackoffEntryTest, FailureThenSuccess) { TestBackoffEntry entry(&base_policy); // Failure count 1, establishes horizon. entry.InformOfRequest(false); TimeTicks release_time = entry.GetReleaseTime(); EXPECT_EQ(TimeTicks() + TimeDelta::FromMilliseconds(1000), release_time); // Success, failure count 0, should not advance past // the horizon that was already set. entry.set_now(release_time - TimeDelta::FromMilliseconds(200)); entry.InformOfRequest(true); EXPECT_EQ(release_time, entry.GetReleaseTime()); // Failure, failure count 1. entry.InformOfRequest(false); EXPECT_EQ(release_time + TimeDelta::FromMilliseconds(800), entry.GetReleaseTime()); } TEST(BackoffEntryTest, FailureThenSuccessAlwaysDelay) { BackoffEntry::Policy always_delay_policy = base_policy; always_delay_policy.always_use_initial_delay = true; always_delay_policy.num_errors_to_ignore = 1; TestBackoffEntry entry(&always_delay_policy); // Failure count 1. entry.InformOfRequest(false); EXPECT_EQ(TimeDelta::FromMilliseconds(1000), entry.GetTimeUntilRelease()); // Failure count 2. entry.InformOfRequest(false); EXPECT_EQ(TimeDelta::FromMilliseconds(2000), entry.GetTimeUntilRelease()); entry.set_now(entry.GetReleaseTime() + TimeDelta::FromMilliseconds(2000)); // Success. We should go back to the original delay. entry.InformOfRequest(true); EXPECT_EQ(TimeDelta::FromMilliseconds(1000), entry.GetTimeUntilRelease()); // Failure count reaches 2 again. We should increase the delay once more. entry.InformOfRequest(false); EXPECT_EQ(TimeDelta::FromMilliseconds(2000), entry.GetTimeUntilRelease()); entry.set_now(entry.GetReleaseTime() + TimeDelta::FromMilliseconds(2000)); } TEST(BackoffEntryTest, RetainCustomHorizon) { TestBackoffEntry custom(&base_policy); TimeTicks custom_horizon = TimeTicks() + TimeDelta::FromDays(3); custom.SetCustomReleaseTime(custom_horizon); custom.InformOfRequest(false); custom.InformOfRequest(true); custom.set_now(TimeTicks() + TimeDelta::FromDays(2)); custom.InformOfRequest(false); custom.InformOfRequest(true); EXPECT_EQ(custom_horizon, custom.GetReleaseTime()); // Now check that once we are at or past the custom horizon, // we get normal behavior. custom.set_now(TimeTicks() + TimeDelta::FromDays(3)); custom.InformOfRequest(false); EXPECT_EQ( TimeTicks() + TimeDelta::FromDays(3) + TimeDelta::FromMilliseconds(1000), custom.GetReleaseTime()); } TEST(BackoffEntryTest, RetainCustomHorizonWhenInitialErrorsIgnored) { // Regression test for a bug discovered during code review. BackoffEntry::Policy lenient_policy = base_policy; lenient_policy.num_errors_to_ignore = 1; TestBackoffEntry custom(&lenient_policy); TimeTicks custom_horizon = TimeTicks() + TimeDelta::FromDays(3); custom.SetCustomReleaseTime(custom_horizon); custom.InformOfRequest(false); // This must not reset the horizon. EXPECT_EQ(custom_horizon, custom.GetReleaseTime()); } TEST(BackoffEntryTest, OverflowProtection) { BackoffEntry::Policy large_multiply_policy = base_policy; large_multiply_policy.multiply_factor = 256; TestBackoffEntry custom(&large_multiply_policy); // Trigger enough failures such that more than 11 bits of exponent are used // to represent the exponential backoff intermediate values. Given a multiply // factor of 256 (2^8), 129 iterations is enough: 2^(8*(129-1)) = 2^1024. for (int i = 0; i < 129; ++i) { custom.set_now(custom.ImplGetTimeNow() + custom.GetTimeUntilRelease()); custom.InformOfRequest(false); ASSERT_TRUE(custom.ShouldRejectRequest()); } // Max delay should still be respected. EXPECT_EQ(20000, custom.GetTimeUntilRelease().InMilliseconds()); } } // namespace weave