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/*
* Copyright 2018 Google
*
* 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 "Firestore/core/include/firebase/firestore/timestamp.h"
#include <limits>
#include <utility>
#include <vector>
#include "gtest/gtest.h"
namespace firebase {
namespace {
using TimePoint = std::chrono::time_point<std::chrono::system_clock>;
using Sec = std::chrono::seconds;
using Ms = std::chrono::milliseconds;
const auto kUpperBound = 253402300800L - 1;
const auto kLowerBound = -62135596800L;
// For near-bounds tests that use <chrono>, it's important to only run them if
// system_clock::duration can represent values this large (e.g., on Linux, it's
// system_clock::duration uses nanoseconds precision and thus would overflow
// trying to represent very large numbers).
bool CanSystemClockDurationHold(const Sec seconds) {
namespace chr = std::chrono;
if (seconds.count() >= 0) {
const auto max_seconds =
chr::duration_cast<chr::seconds>(TimePoint::duration::max()).count();
return max_seconds >= seconds.count();
} else {
const auto min_seconds =
chr::duration_cast<chr::seconds>(TimePoint::duration::min()).count();
return min_seconds <= seconds.count();
}
}
} // namespace
TEST(Timestamp, Constructors) {
const Timestamp zero;
EXPECT_EQ(0, zero.seconds());
EXPECT_EQ(0, zero.nanoseconds());
const Timestamp positive(100, 200);
EXPECT_EQ(100, positive.seconds());
EXPECT_EQ(200, positive.nanoseconds());
const Timestamp negative(-100, 200);
EXPECT_EQ(-100, negative.seconds());
EXPECT_EQ(200, negative.nanoseconds());
const Timestamp now = Timestamp::Now();
EXPECT_LT(0, now.seconds());
EXPECT_LE(0, now.nanoseconds());
Timestamp copy_now = now;
EXPECT_EQ(now, copy_now);
EXPECT_EQ(now.seconds(), copy_now.seconds());
EXPECT_EQ(now.nanoseconds(), copy_now.nanoseconds());
const Timestamp move_now = std::move(copy_now);
EXPECT_EQ(now, move_now);
}
TEST(Timestamp, Bounds) {
const Timestamp max_timestamp{kUpperBound, 999999999};
EXPECT_EQ(kUpperBound, max_timestamp.seconds());
EXPECT_EQ(999999999, max_timestamp.nanoseconds());
const Timestamp min_timestamp{kLowerBound, 0};
EXPECT_EQ(kLowerBound, min_timestamp.seconds());
EXPECT_EQ(0, min_timestamp.nanoseconds());
}
TEST(Timestamp, FromTimeT) {
const Timestamp zero = Timestamp::FromTimeT(std::time_t{});
EXPECT_EQ(0, zero.seconds());
EXPECT_EQ(0, zero.nanoseconds());
const Timestamp positive = Timestamp::FromTimeT(std::time_t{123456});
EXPECT_EQ(123456, positive.seconds());
EXPECT_EQ(0, positive.nanoseconds());
const Timestamp negative = Timestamp::FromTimeT(std::time_t{-123456});
EXPECT_EQ(-123456, negative.seconds());
EXPECT_EQ(0, negative.nanoseconds());
}
TEST(Timestamp, FromChrono) {
const auto zero = Timestamp::FromTimePoint(TimePoint{});
EXPECT_EQ(0, zero.seconds());
EXPECT_EQ(0, zero.nanoseconds());
const auto sec = Timestamp::FromTimePoint(TimePoint{Sec(123)});
EXPECT_EQ(123, sec.seconds());
EXPECT_EQ(0, sec.nanoseconds());
const auto ms = Timestamp::FromTimePoint(TimePoint{Sec(123) + Ms(456)});
EXPECT_EQ(123, ms.seconds());
EXPECT_EQ(456000000, ms.nanoseconds());
}
TEST(Timestamp, FromChronoNegativeTime) {
const auto no_fraction = Timestamp::FromTimePoint(TimePoint{Sec(-123)});
EXPECT_EQ(-123, no_fraction.seconds());
EXPECT_EQ(0, no_fraction.nanoseconds());
const auto with_positive_fraction =
Timestamp::FromTimePoint(TimePoint{Sec(-123) + Ms(456)});
EXPECT_EQ(-123, with_positive_fraction.seconds());
EXPECT_EQ(456000000, with_positive_fraction.nanoseconds());
const auto with_negative_fraction =
Timestamp::FromTimePoint(TimePoint{Sec(-122) + Ms(-544)});
EXPECT_EQ(-123, with_negative_fraction.seconds());
EXPECT_EQ(456000000, with_negative_fraction.nanoseconds());
const auto with_large_negative_fraction =
Timestamp::FromTimePoint(TimePoint{Sec(-122) + Ms(-100544)});
EXPECT_EQ(-223, with_large_negative_fraction.seconds());
EXPECT_EQ(456000000, with_large_negative_fraction.nanoseconds());
const auto only_negative_fraction =
Timestamp::FromTimePoint(TimePoint{Ms(-544)});
EXPECT_EQ(-1, only_negative_fraction.seconds());
EXPECT_EQ(456000000, only_negative_fraction.nanoseconds());
const auto positive_time_negative_fraction =
Timestamp::FromTimePoint(TimePoint{Sec(1) + Ms(-544)});
EXPECT_EQ(0, positive_time_negative_fraction.seconds());
EXPECT_EQ(456000000, positive_time_negative_fraction.nanoseconds());
if (CanSystemClockDurationHold(Sec(kUpperBound + 1))) {
const auto near_bounds =
Timestamp::FromTimePoint(TimePoint{Sec(kUpperBound + 1) + Ms(-544)});
EXPECT_EQ(kUpperBound, near_bounds.seconds());
EXPECT_EQ(456000000, near_bounds.nanoseconds());
}
}
TEST(Timestamp, ToChrono) {
namespace chr = std::chrono;
// Note: this line is outside the inner block because otherwise clang-format
// gets confused about namespace alias on the line above.
const Timestamp positive{123, 456789000};
{
const auto micros = positive.ToTimePoint().time_since_epoch();
EXPECT_EQ(123456789, chr::duration_cast<chr::microseconds>(micros).count());
const auto millis =
positive.ToTimePoint<chr::system_clock, chr::milliseconds>()
.time_since_epoch();
EXPECT_EQ(123456000, chr::duration_cast<chr::microseconds>(millis).count());
const auto nanos =
positive.ToTimePoint<chr::system_clock, chr::nanoseconds>()
.time_since_epoch();
EXPECT_EQ(123456789000,
chr::duration_cast<chr::nanoseconds>(nanos).count());
}
{
const Timestamp negative{-123, 456000000};
const auto millis =
negative.ToTimePoint<chr::system_clock, chr::milliseconds>()
.time_since_epoch();
const auto seconds = chr::duration_cast<chr::seconds>(millis);
EXPECT_EQ(-122, seconds.count());
EXPECT_EQ(-544,
chr::duration_cast<chr::milliseconds>(millis - seconds).count());
}
// Bounds
{
const Timestamp max{kUpperBound, 999999999};
const auto max_micros = max.ToTimePoint().time_since_epoch();
EXPECT_EQ(kUpperBound * 1000 * 1000 + 999999,
chr::duration_cast<chr::microseconds>(max_micros).count());
const Timestamp min{kLowerBound, 0};
const auto min_micros = min.ToTimePoint().time_since_epoch();
EXPECT_EQ(kLowerBound * 1000 * 1000,
chr::duration_cast<chr::microseconds>(min_micros).count());
}
// Overflow
{
const Timestamp max{kUpperBound, 999999999};
const auto max_nanos =
max.ToTimePoint<chr::system_clock, chr::nanoseconds>()
.time_since_epoch();
EXPECT_EQ(std::numeric_limits<chr::nanoseconds::rep>::max(),
chr::duration_cast<chr::nanoseconds>(max_nanos).count());
const Timestamp min{kLowerBound, 0};
const auto min_nanos =
min.ToTimePoint<chr::system_clock, chr::nanoseconds>()
.time_since_epoch();
EXPECT_EQ(std::numeric_limits<chr::nanoseconds::rep>::min(),
chr::duration_cast<chr::nanoseconds>(min_nanos).count());
}
}
TEST(Timestamp, Comparison) {
EXPECT_LT(Timestamp(), Timestamp(1, 2));
EXPECT_LT(Timestamp(1, 2), Timestamp(2, 1));
EXPECT_LT(Timestamp(2, 1), Timestamp(2, 2));
EXPECT_GT(Timestamp(1, 1), Timestamp());
EXPECT_GT(Timestamp(2, 1), Timestamp(1, 2));
EXPECT_GT(Timestamp(2, 2), Timestamp(2, 1));
EXPECT_LE(Timestamp(), Timestamp());
EXPECT_LE(Timestamp(), Timestamp(1, 2));
EXPECT_LE(Timestamp(1, 2), Timestamp(2, 1));
EXPECT_LE(Timestamp(2, 1), Timestamp(2, 1));
EXPECT_LE(Timestamp(2, 1), Timestamp(2, 2));
EXPECT_GE(Timestamp(), Timestamp());
EXPECT_GE(Timestamp(1, 1), Timestamp());
EXPECT_GE(Timestamp(1, 1), Timestamp(1, 1));
EXPECT_GE(Timestamp(2, 1), Timestamp(1, 2));
EXPECT_GE(Timestamp(2, 1), Timestamp(2, 1));
EXPECT_GE(Timestamp(2, 2), Timestamp(2, 1));
EXPECT_EQ(Timestamp(), Timestamp());
EXPECT_EQ(Timestamp(), Timestamp(0, 0));
EXPECT_EQ(Timestamp(123, 123456789), Timestamp(123, 123456789));
EXPECT_NE(Timestamp(), Timestamp(0, 1));
EXPECT_NE(Timestamp(), Timestamp(1, 0));
EXPECT_NE(Timestamp(123, 123456789), Timestamp(123, 123456780));
}
TEST(Timestamp, Hash) {
const Timestamp foo1{123, 456000000};
const Timestamp foo2 = foo1;
const Timestamp foo3 =
Timestamp::FromTimePoint(TimePoint{Sec(123) + Ms(456)});
EXPECT_EQ(std::hash<Timestamp>()(foo1), std::hash<Timestamp>()(foo2));
EXPECT_EQ(std::hash<Timestamp>()(foo2), std::hash<Timestamp>()(foo3));
const Timestamp bar{123, 456};
EXPECT_NE(std::hash<Timestamp>()(foo1), std::hash<Timestamp>()(bar));
}
TEST(Timestamp, InvalidArguments) {
// Negative nanoseconds.
ASSERT_ANY_THROW(Timestamp(0, -1));
ASSERT_ANY_THROW(Timestamp(100, -1));
ASSERT_ANY_THROW(Timestamp(100, -12346789));
// Nanoseconds that are more than one second.
ASSERT_ANY_THROW(Timestamp(0, 999999999 + 1));
// Seconds beyond supported range.
ASSERT_ANY_THROW(Timestamp(kLowerBound - 1, 0));
ASSERT_ANY_THROW(Timestamp(kUpperBound + 1, 0));
}
TEST(Timestamp, InvalidArgumentsChrono) {
// Make sure Timestamp doesn't accept values beyond the supported range, if
// system clock-based time_point on this platform can represent values this
// large.
if (CanSystemClockDurationHold(Sec(kUpperBound + 1))) {
ASSERT_ANY_THROW(Timestamp::FromTimePoint(TimePoint{Sec(kUpperBound + 1)}));
}
if (CanSystemClockDurationHold(Sec(kLowerBound - 1))) {
ASSERT_ANY_THROW(Timestamp::FromTimePoint(TimePoint{Sec(kLowerBound - 1)}));
}
}
TEST(Timestamp, ToString) {
EXPECT_EQ(Timestamp().ToString(), "Timestamp(seconds=0, nanoseconds=0)");
EXPECT_EQ(Timestamp(123, 123456789).ToString(),
"Timestamp(seconds=123, nanoseconds=123456789)");
EXPECT_EQ(Timestamp(-123, 123456789).ToString(),
"Timestamp(seconds=-123, nanoseconds=123456789)");
}
} // namespace firebase
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