/* * Copyright (C) 2019 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 "src/trace_processor/importers/common/clock_tracker.h" #include #include #include "src/trace_processor/importers/common/machine_tracker.h" #include "src/trace_processor/importers/common/metadata_tracker.h" #include "src/trace_processor/storage/trace_storage.h" #include "src/trace_processor/types/trace_processor_context.h" #include "test/gtest_and_gmock.h" #include "protos/perfetto/common/builtin_clock.pbzero.h" #include "protos/perfetto/trace/clock_snapshot.pbzero.h" namespace perfetto { namespace trace_processor { class ClockTrackerTest : public ::testing::Test { public: ClockTrackerTest() { context_.storage.reset(new TraceStorage()); context_.metadata_tracker.reset( new MetadataTracker(context_.storage.get())); } // using ClockId = uint64_t; TraceProcessorContext context_; ClockTracker ct_{&context_}; base::StatusOr Convert(ClockTracker::ClockId src_clock_id, int64_t src_timestamp, ClockTracker::ClockId target_clock_id) { return ct_.Convert(src_clock_id, src_timestamp, target_clock_id); } }; namespace { using ::testing::NiceMock; using Clock = protos::pbzero::ClockSnapshot::Clock; constexpr auto REALTIME = protos::pbzero::BUILTIN_CLOCK_REALTIME; constexpr auto BOOTTIME = protos::pbzero::BUILTIN_CLOCK_BOOTTIME; constexpr auto MONOTONIC = protos::pbzero::BUILTIN_CLOCK_MONOTONIC; constexpr auto MONOTONIC_COARSE = protos::pbzero::BUILTIN_CLOCK_MONOTONIC_COARSE; constexpr auto MONOTONIC_RAW = protos::pbzero::BUILTIN_CLOCK_MONOTONIC_RAW; TEST_F(ClockTrackerTest, ClockDomainConversions) { EXPECT_FALSE(ct_.ToTraceTime(REALTIME, 0).ok()); ct_.AddSnapshot({{REALTIME, 10}, {BOOTTIME, 10010}}); ct_.AddSnapshot({{REALTIME, 20}, {BOOTTIME, 20220}}); ct_.AddSnapshot({{REALTIME, 30}, {BOOTTIME, 30030}}); ct_.AddSnapshot({{MONOTONIC, 1000}, {BOOTTIME, 100000}}); EXPECT_EQ(*ct_.ToTraceTime(REALTIME, 0), 10000); EXPECT_EQ(*ct_.ToTraceTime(REALTIME, 1), 10001); EXPECT_EQ(*ct_.ToTraceTime(REALTIME, 9), 10009); EXPECT_EQ(*ct_.ToTraceTime(REALTIME, 10), 10010); EXPECT_EQ(*ct_.ToTraceTime(REALTIME, 11), 10011); EXPECT_EQ(*ct_.ToTraceTime(REALTIME, 19), 10019); EXPECT_EQ(*ct_.ToTraceTime(REALTIME, 20), 20220); EXPECT_EQ(*ct_.ToTraceTime(REALTIME, 21), 20221); EXPECT_EQ(*ct_.ToTraceTime(REALTIME, 29), 20229); EXPECT_EQ(*ct_.ToTraceTime(REALTIME, 30), 30030); EXPECT_EQ(*ct_.ToTraceTime(REALTIME, 40), 30040); EXPECT_EQ(*ct_.ToTraceTime(MONOTONIC, 0), 100000 - 1000); EXPECT_EQ(*ct_.ToTraceTime(MONOTONIC, 999), 100000 - 1); EXPECT_EQ(*ct_.ToTraceTime(MONOTONIC, 1000), 100000); EXPECT_EQ(*ct_.ToTraceTime(MONOTONIC, 1e6), static_cast(100000 - 1000 + 1e6)); } TEST_F(ClockTrackerTest, ToTraceTimeFromSnapshot) { EXPECT_FALSE(ct_.ToTraceTime(REALTIME, 0).ok()); EXPECT_EQ(*ct_.ToTraceTimeFromSnapshot({{REALTIME, 10}, {BOOTTIME, 10010}}), 10010); EXPECT_EQ(ct_.ToTraceTimeFromSnapshot({{MONOTONIC, 10}, {REALTIME, 10010}}), std::nullopt); } // When a clock moves backwards conversions *from* that clock are forbidden // but conversions *to* that clock should still work. // Think to the case of REALTIME going backwards from 3AM to 2AM during DST day. // You can't convert 2.10AM REALTIME to BOOTTIME because there are two possible // answers, but you can still unambiguosly convert BOOTTIME into REALTIME. TEST_F(ClockTrackerTest, RealTimeClockMovingBackwards) { ct_.AddSnapshot({{BOOTTIME, 10010}, {REALTIME, 10}}); // At this point conversions are still possible in both ways because we // haven't broken monotonicity yet. EXPECT_EQ(*ct_.ToTraceTime(REALTIME, 11), 10011); ct_.AddSnapshot({{BOOTTIME, 10020}, {REALTIME, 20}}); ct_.AddSnapshot({{BOOTTIME, 30040}, {REALTIME, 40}}); ct_.AddSnapshot({{BOOTTIME, 40030}, {REALTIME, 30}}); // Now only BOOTIME -> REALTIME conversion should be possible. EXPECT_FALSE(ct_.ToTraceTime(REALTIME, 11).ok()); EXPECT_EQ(*Convert(BOOTTIME, 10011, REALTIME), 11); EXPECT_EQ(*Convert(BOOTTIME, 10029, REALTIME), 29); EXPECT_EQ(*Convert(BOOTTIME, 40030, REALTIME), 30); EXPECT_EQ(*Convert(BOOTTIME, 40040, REALTIME), 40); ct_.AddSnapshot({{BOOTTIME, 50000}, {REALTIME, 50}}); EXPECT_EQ(*Convert(BOOTTIME, 50005, REALTIME), 55); ct_.AddSnapshot({{BOOTTIME, 60020}, {REALTIME, 20}}); EXPECT_EQ(*Convert(BOOTTIME, 60020, REALTIME), 20); } // Simulate the following scenario: // MONOTONIC = MONOTONIC_COARSE + 10 // BOOTTIME = MONOTONIC + 1000 (until T=200) // BOOTTIME = MONOTONIC + 2000 (from T=200) // Then resolve MONOTONIC_COARSE. This requires a two-level resolution: // MONOTONIC_COARSE -> MONOTONIC -> BOOTTIME. TEST_F(ClockTrackerTest, ChainedResolutionSimple) { ct_.AddSnapshot({{MONOTONIC_COARSE, 1}, {MONOTONIC, 11}}); ct_.AddSnapshot({{MONOTONIC, 100}, {BOOTTIME, 1100}}); ct_.AddSnapshot({{MONOTONIC, 200}, {BOOTTIME, 2200}}); // MONOTONIC_COARSE@100 == MONOTONIC@110 == BOOTTIME@1100. EXPECT_EQ(*ct_.ToTraceTime(MONOTONIC, 110), 1110); EXPECT_EQ(*ct_.ToTraceTime(MONOTONIC_COARSE, 100), 100 + 10 + 1000); EXPECT_EQ(*ct_.ToTraceTime(MONOTONIC_COARSE, 202), 202 + 10 + 2000); } TEST_F(ClockTrackerTest, ChainedResolutionHard) { // MONOTONIC_COARSE = MONOTONIC_RAW - 1. ct_.AddSnapshot({{MONOTONIC_RAW, 10}, {MONOTONIC_COARSE, 9}}); // MONOTONIC = MONOTONIC_COARSE - 50. ct_.AddSnapshot({{MONOTONIC_COARSE, 100}, {MONOTONIC, 50}}); // BOOTTIME = MONOTONIC + 1000 until T=100 (see below). ct_.AddSnapshot({{MONOTONIC, 1}, {BOOTTIME, 1001}, {REALTIME, 10001}}); // BOOTTIME = MONOTONIC + 2000 from T=100. // At the same time, REALTIME goes backwards. ct_.AddSnapshot({{MONOTONIC, 101}, {BOOTTIME, 2101}, {REALTIME, 9101}}); // 1-hop conversions. EXPECT_EQ(*Convert(MONOTONIC_RAW, 2, MONOTONIC_COARSE), 1); EXPECT_EQ(*Convert(MONOTONIC_COARSE, 1, MONOTONIC_RAW), 2); EXPECT_EQ(*Convert(MONOTONIC_RAW, 100001, MONOTONIC_COARSE), 100000); EXPECT_EQ(*Convert(MONOTONIC_COARSE, 100000, MONOTONIC_RAW), 100001); // 2-hop conversions (MONOTONIC_RAW <-> MONOTONIC_COARSE <-> MONOTONIC). // From above, MONOTONIC = (MONOTONIC_RAW - 1) - 50. EXPECT_EQ(*Convert(MONOTONIC_RAW, 53, MONOTONIC), 53 - 1 - 50); EXPECT_EQ(*Convert(MONOTONIC, 2, MONOTONIC_RAW), 2 + 1 + 50); // 3-hop conversions (as above + BOOTTIME) EXPECT_EQ(*Convert(MONOTONIC_RAW, 53, BOOTTIME), 53 - 1 - 50 + 1000); EXPECT_EQ(*Convert(BOOTTIME, 1002, MONOTONIC_RAW), 1002 - 1000 + 1 + 50); EXPECT_EQ(*Convert(MONOTONIC_RAW, 753, BOOTTIME), 753 - 1 - 50 + 2000); EXPECT_EQ(*Convert(BOOTTIME, 2702, MONOTONIC_RAW), 2702 - 2000 + 1 + 50); // 3-hop conversion to REALTIME, one way only (REALTIME goes backwards). EXPECT_EQ(*Convert(MONOTONIC_RAW, 53, REALTIME), 53 - 1 - 50 + 10000); EXPECT_EQ(*Convert(MONOTONIC_RAW, 753, REALTIME), 753 - 1 - 50 + 9000); } // Regression test for b/158182858. When taking two snapshots back-to-back, // MONOTONIC_COARSE might be stuck to the last value. We should still be able // to convert both ways in this case. TEST_F(ClockTrackerTest, NonStrictlyMonotonic) { ct_.AddSnapshot({{BOOTTIME, 101}, {MONOTONIC, 51}, {MONOTONIC_COARSE, 50}}); ct_.AddSnapshot({{BOOTTIME, 105}, {MONOTONIC, 55}, {MONOTONIC_COARSE, 50}}); // This last snapshot is deliberately identical to the previous one. This // is to simulate the case of taking two snapshots so close to each other // that all clocks are identical. ct_.AddSnapshot({{BOOTTIME, 105}, {MONOTONIC, 55}, {MONOTONIC_COARSE, 50}}); EXPECT_EQ(*Convert(MONOTONIC_COARSE, 49, MONOTONIC), 50); EXPECT_EQ(*Convert(MONOTONIC_COARSE, 50, MONOTONIC), 55); EXPECT_EQ(*Convert(MONOTONIC_COARSE, 51, MONOTONIC), 56); EXPECT_EQ(*Convert(MONOTONIC_COARSE, 40, BOOTTIME), 91); EXPECT_EQ(*Convert(MONOTONIC_COARSE, 50, BOOTTIME), 105); EXPECT_EQ(*Convert(MONOTONIC_COARSE, 55, BOOTTIME), 110); EXPECT_EQ(*Convert(BOOTTIME, 91, MONOTONIC_COARSE), 40); EXPECT_EQ(*Convert(BOOTTIME, 105, MONOTONIC_COARSE), 50); EXPECT_EQ(*Convert(BOOTTIME, 110, MONOTONIC_COARSE), 55); } TEST_F(ClockTrackerTest, SequenceScopedClocks) { ct_.AddSnapshot({{MONOTONIC, 1000}, {BOOTTIME, 100000}}); ClockTracker::ClockId c64_1 = ct_.SequenceToGlobalClock(1, 64); ClockTracker::ClockId c65_1 = ct_.SequenceToGlobalClock(1, 65); ClockTracker::ClockId c66_1 = ct_.SequenceToGlobalClock(1, 66); ClockTracker::ClockId c66_2 = ct_.SequenceToGlobalClock(2, 64); ct_.AddSnapshot( {{MONOTONIC, 10000}, {c64_1, 100000}, {c65_1, 100, /*unit_multiplier_ns=*/1000, /*is_incremental=*/false}, {c66_1, 10, /*unit_multiplier_ns=*/1000, /*is_incremental=*/true}}); // c64_1 is non-incremental and in nanos. EXPECT_EQ(*Convert(c64_1, 150000, MONOTONIC), 60000); EXPECT_EQ(*Convert(c64_1, 150000, BOOTTIME), 159000); EXPECT_EQ(*ct_.ToTraceTime(c64_1, 150000), 159000); // c65_1 is non-incremental and in micros. EXPECT_EQ(*Convert(c65_1, 150, MONOTONIC), 60000); EXPECT_EQ(*Convert(c65_1, 150, BOOTTIME), 159000); EXPECT_EQ(*ct_.ToTraceTime(c65_1, 150), 159000); // c66_1 is incremental and in micros. EXPECT_EQ(*Convert(c66_1, 1 /* abs 11 */, MONOTONIC), 11000); EXPECT_EQ(*Convert(c66_1, 1 /* abs 12 */, MONOTONIC), 12000); EXPECT_EQ(*Convert(c66_1, 1 /* abs 13 */, BOOTTIME), 112000); EXPECT_EQ(*ct_.ToTraceTime(c66_1, 2 /* abs 15 */), 114000); ct_.AddSnapshot( {{MONOTONIC, 20000}, {c66_1, 20, /*unit_multiplier_ns=*/1000, /*incremental=*/true}}); ct_.AddSnapshot( {{MONOTONIC, 20000}, {c66_2, 20, /*unit_multiplier_ns=*/1000, /*incremental=*/true}}); // c66_1 and c66_2 are both incremental and in micros, but shouldn't affect // each other. EXPECT_EQ(*Convert(c66_1, 1 /* abs 21 */, MONOTONIC), 21000); EXPECT_EQ(*Convert(c66_2, 2 /* abs 22 */, MONOTONIC), 22000); EXPECT_EQ(*Convert(c66_1, 1 /* abs 22 */, MONOTONIC), 22000); EXPECT_EQ(*Convert(c66_2, 2 /* abs 24 */, MONOTONIC), 24000); EXPECT_EQ(*Convert(c66_1, 1 /* abs 23 */, BOOTTIME), 122000); EXPECT_EQ(*Convert(c66_2, 2 /* abs 26 */, BOOTTIME), 125000); EXPECT_EQ(*ct_.ToTraceTime(c66_1, 2 /* abs 25 */), 124000); EXPECT_EQ(*ct_.ToTraceTime(c66_2, 4 /* abs 30 */), 129000); } // Tests that the cache doesn't affect the results of Convert() in unexpected // ways. TEST_F(ClockTrackerTest, CacheDoesntAffectResults) { std::minstd_rand rnd; int last_mono = 0; int last_boot = 0; int last_raw = 0; static const int increments[] = {1, 2, 10}; for (int i = 0; i < 1000; i++) { last_mono += increments[rnd() % base::ArraySize(increments)]; last_boot += increments[rnd() % base::ArraySize(increments)]; ct_.AddSnapshot({{MONOTONIC, last_mono}, {BOOTTIME, last_boot}}); last_raw += increments[rnd() % base::ArraySize(increments)]; last_boot += increments[rnd() % base::ArraySize(increments)]; ct_.AddSnapshot({{MONOTONIC_RAW, last_raw}, {BOOTTIME, last_boot}}); } for (int i = 0; i < 1000; i++) { int64_t val = static_cast(rnd()) % 10000; for (int j = 0; j < 5; j++) { ClockTracker::ClockId src; ClockTracker::ClockId tgt; if (j == 0) { std::tie(src, tgt) = std::make_tuple(MONOTONIC, BOOTTIME); } else if (j == 1) { std::tie(src, tgt) = std::make_tuple(MONOTONIC_RAW, BOOTTIME); } else if (j == 2) { std::tie(src, tgt) = std::make_tuple(BOOTTIME, MONOTONIC); } else if (j == 3) { std::tie(src, tgt) = std::make_tuple(BOOTTIME, MONOTONIC_RAW); } else if (j == 4) { std::tie(src, tgt) = std::make_tuple(MONOTONIC_RAW, MONOTONIC); } else { PERFETTO_FATAL("j out of bounds"); } // It will still write the cache, just not lookup. ct_.set_cache_lookups_disabled_for_testing(true); auto not_cached = Convert(src, val, tgt); // This should 100% hit the cache. ct_.set_cache_lookups_disabled_for_testing(false); auto cached = Convert(src, val, tgt); ASSERT_EQ(not_cached.value(), cached.value()); } } } // Test clock conversion with offset to the host. TEST_F(ClockTrackerTest, ClockOffset) { EXPECT_FALSE(ct_.ToTraceTime(REALTIME, 0).ok()); context_.machine_tracker = std::make_unique(&context_, 0x1001); // Client-to-host BOOTTIME offset is -10000 ns. ct_.SetClockOffset(BOOTTIME, -10000); ct_.AddSnapshot({{REALTIME, 10}, {BOOTTIME, 10010}}); ct_.AddSnapshot({{REALTIME, 20}, {BOOTTIME, 20220}}); ct_.AddSnapshot({{REALTIME, 30}, {BOOTTIME, 30030}}); ct_.AddSnapshot({{MONOTONIC, 1000}, {BOOTTIME, 100000}}); auto seq_clock_1 = ct_.SequenceToGlobalClock(1, 64); auto seq_clock_2 = ct_.SequenceToGlobalClock(2, 64); ct_.AddSnapshot({{MONOTONIC, 2000}, {seq_clock_1, 1200}}); ct_.AddSnapshot({{seq_clock_1, 1300}, {seq_clock_2, 2000, 10, false}}); EXPECT_EQ(*ct_.ToTraceTime(REALTIME, 0), 20000); EXPECT_EQ(*ct_.ToTraceTime(REALTIME, 1), 20001); EXPECT_EQ(*ct_.ToTraceTime(REALTIME, 9), 20009); EXPECT_EQ(*ct_.ToTraceTime(REALTIME, 10), 20010); EXPECT_EQ(*ct_.ToTraceTime(REALTIME, 11), 20011); EXPECT_EQ(*ct_.ToTraceTime(REALTIME, 19), 20019); EXPECT_EQ(*ct_.ToTraceTime(REALTIME, 20), 30220); EXPECT_EQ(*ct_.ToTraceTime(REALTIME, 21), 30221); EXPECT_EQ(*ct_.ToTraceTime(REALTIME, 29), 30229); EXPECT_EQ(*ct_.ToTraceTime(REALTIME, 30), 40030); EXPECT_EQ(*ct_.ToTraceTime(REALTIME, 40), 40040); EXPECT_EQ(*ct_.ToTraceTime(MONOTONIC, 0), 100000 - 1000 + 10000); EXPECT_EQ(*ct_.ToTraceTime(MONOTONIC, 999), 100000 - 1 + 10000); EXPECT_EQ(*ct_.ToTraceTime(MONOTONIC, 1000), 100000 + 10000); EXPECT_EQ(*ct_.ToTraceTime(MONOTONIC, 1e6), static_cast(100000 - 1000 + 1e6 + 10000)); // seq_clock_1 -> MONOTONIC -> BOOTTIME -> apply offset. EXPECT_EQ(*ct_.ToTraceTime(seq_clock_1, 1100), -100 + 1000 + 100000 + 10000); // seq_clock_2 -> seq_clock_1 -> MONOTONIC -> BOOTTIME -> apply offset. EXPECT_EQ(*ct_.ToTraceTime(seq_clock_2, 2100), 100 * 10 + 100 + 1000 + 100000 + 10000); } // Test conversion of remote machine timestamps without offset. This can happen // if timestamp conversion for remote machines is done by trace data // post-processing. TEST_F(ClockTrackerTest, RemoteNoClockOffset) { context_.machine_tracker = std::make_unique(&context_, 0x1001); ct_.AddSnapshot({{REALTIME, 10}, {BOOTTIME, 10010}}); ct_.AddSnapshot({{REALTIME, 20}, {BOOTTIME, 20220}}); ct_.AddSnapshot({{MONOTONIC, 1000}, {BOOTTIME, 100000}}); auto seq_clock_1 = ct_.SequenceToGlobalClock(1, 64); auto seq_clock_2 = ct_.SequenceToGlobalClock(2, 64); ct_.AddSnapshot({{MONOTONIC, 2000}, {seq_clock_1, 1200}}); ct_.AddSnapshot({{seq_clock_1, 1300}, {seq_clock_2, 2000, 10, false}}); EXPECT_EQ(*ct_.ToTraceTime(REALTIME, 0), 10000); EXPECT_EQ(*ct_.ToTraceTime(REALTIME, 9), 10009); EXPECT_EQ(*ct_.ToTraceTime(REALTIME, 10), 10010); EXPECT_EQ(*ct_.ToTraceTime(REALTIME, 11), 10011); EXPECT_EQ(*ct_.ToTraceTime(REALTIME, 19), 10019); EXPECT_EQ(*ct_.ToTraceTime(REALTIME, 20), 20220); EXPECT_EQ(*ct_.ToTraceTime(REALTIME, 21), 20221); EXPECT_EQ(*ct_.ToTraceTime(MONOTONIC, 0), 100000 - 1000); EXPECT_EQ(*ct_.ToTraceTime(MONOTONIC, 999), 100000 - 1); EXPECT_EQ(*ct_.ToTraceTime(MONOTONIC, 1000), 100000); EXPECT_EQ(*ct_.ToTraceTime(MONOTONIC, 1e6), static_cast(100000 - 1000 + 1e6)); // seq_clock_1 -> MONOTONIC -> BOOTTIME. EXPECT_EQ(*ct_.ToTraceTime(seq_clock_1, 1100), -100 + 1000 + 100000); // seq_clock_2 -> seq_clock_1 -> MONOTONIC -> BOOTTIME. EXPECT_EQ(*ct_.ToTraceTime(seq_clock_2, 2100), 100 * 10 + 100 + 1000 + 100000); } // Test clock offset of non-defualt trace time clock domain. TEST_F(ClockTrackerTest, NonDefaultTraceTimeClock) { context_.machine_tracker = std::make_unique(&context_, 0x1001); ct_.SetTraceTimeClock(MONOTONIC); ct_.SetClockOffset(MONOTONIC, -2000); ct_.SetClockOffset(BOOTTIME, -10000); // This doesn't take effect. ct_.AddSnapshot({{REALTIME, 10}, {BOOTTIME, 10010}}); ct_.AddSnapshot({{MONOTONIC, 1000}, {BOOTTIME, 100000}}); auto seq_clock_1 = ct_.SequenceToGlobalClock(1, 64); ct_.AddSnapshot({{MONOTONIC, 2000}, {seq_clock_1, 1200}}); int64_t realtime_to_trace_time_delta = -10 + 10010 - 100000 + 1000 - (-2000); EXPECT_EQ(*ct_.ToTraceTime(REALTIME, 9), 9 + realtime_to_trace_time_delta); EXPECT_EQ(*ct_.ToTraceTime(REALTIME, 10), 10 + realtime_to_trace_time_delta); EXPECT_EQ(*ct_.ToTraceTime(REALTIME, 20), 20 + realtime_to_trace_time_delta); int64_t mono_to_trace_time_delta = -2000; EXPECT_EQ(*ct_.ToTraceTime(MONOTONIC, 0), 0 - mono_to_trace_time_delta); EXPECT_EQ(*ct_.ToTraceTime(MONOTONIC, 999), 999 - mono_to_trace_time_delta); EXPECT_EQ(*ct_.ToTraceTime(MONOTONIC, 1000), 1000 - mono_to_trace_time_delta); EXPECT_EQ(*ct_.ToTraceTime(MONOTONIC, 1e6), static_cast(1e6) - mono_to_trace_time_delta); // seq_clock_1 -> MONOTONIC. EXPECT_EQ(*ct_.ToTraceTime(seq_clock_1, 1100), 1100 - 1200 + 2000 - (-2000)); } } // namespace } // namespace trace_processor } // namespace perfetto