net/der/encode_values_unittest.cc - chromium/src - Git at Google

 // Copyright 2016 The Chromium 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 "net/der/encode_values.h"

 #include "base/strings/string_piece.h"
 #include "base/time/time.h"
 #include "net/der/parse_values.h"
 #include "testing/gtest/include/gtest/gtest.h"

 namespace net {
 namespace der {
 namespace test {

 namespace {

 template <size_t N>
 base::StringPiece ToStringPiece(const uint8_t (&data)[N]) {
   return base::StringPiece(reinterpret_cast<const char*>(data), N);
 }

 }  // namespace

 TEST(EncodeValuesTest, EncodeTimeAsGeneralizedTime) {
   // Fri, 24 Jun 2016 17:04:54 GMT
   base::Time time =
       base::Time::UnixEpoch() + base::TimeDelta::FromSeconds(1466787894);
   GeneralizedTime generalized_time;
   ASSERT_TRUE(EncodeTimeAsGeneralizedTime(time, &generalized_time));
   EXPECT_EQ(2016, generalized_time.year);
   EXPECT_EQ(6, generalized_time.month);
   EXPECT_EQ(24, generalized_time.day);
   EXPECT_EQ(17, generalized_time.hours);
   EXPECT_EQ(4, generalized_time.minutes);
   EXPECT_EQ(54, generalized_time.seconds);
 }

 // ASN.1 GeneralizedTime can represent dates from year 0000 to 9999, and
 // although base::Time can represent times from before the Windows epoch and
 // after the 32-bit time_t maximum, the conversion between base::Time and
 // der::GeneralizedTime goes through the time representation of the underlying
 // platform, which might not be able to handle the full GeneralizedTime date
 // range. Out-of-range times should not be converted to der::GeneralizedTime.
 //
 // Thus, this test focuses on an input date 31 years before the Windows epoch,
 // and confirms that EncodeTimeAsGeneralizedTime() produces the correct result
 // on platforms where it returns true. As of this writing, it will return false
 // on Windows.
 TEST(EncodeValuesTest, EncodeTimeFromBeforeWindowsEpoch) {
   constexpr int kYearsBeforeWindowsEpoch = 1601 - 1570;
   constexpr int kDaysPerYear = 365;
   constexpr int kExtraLeapDaysOverThoseYears = 8;
   constexpr base::Time kStartOfYear1570 =
       base::Time() -
       base::TimeDelta::FromDays(kYearsBeforeWindowsEpoch * kDaysPerYear +
                                 kExtraLeapDaysOverThoseYears);

   GeneralizedTime generalized_time;
   if (!EncodeTimeAsGeneralizedTime(kStartOfYear1570, &generalized_time))
     return;

   EXPECT_EQ(1570, generalized_time.year);
   EXPECT_EQ(1, generalized_time.month);
   EXPECT_EQ(1, generalized_time.day);
   EXPECT_EQ(0, generalized_time.hours);
   EXPECT_EQ(0, generalized_time.minutes);
   EXPECT_EQ(0, generalized_time.seconds);
 }

 // Sat, 1 Jan 2039 00:00:00 GMT. See above comment. This time may be
 // unrepresentable on 32-bit systems.
 TEST(EncodeValuesTest, EncodeTimeAfterTimeTMax) {
   base::Time::Exploded exploded;
   exploded.year = 2039;
   exploded.month = 1;
   exploded.day_of_week = 7;
   exploded.day_of_month = 1;
   exploded.hour = 0;
   exploded.minute = 0;
   exploded.second = 0;
   exploded.millisecond = 0;

   base::Time time;
   if (!base::Time::FromUTCExploded(exploded, &time))
     return;

   GeneralizedTime generalized_time;
   ASSERT_TRUE(EncodeTimeAsGeneralizedTime(time, &generalized_time));
   EXPECT_EQ(2039, generalized_time.year);
   EXPECT_EQ(1, generalized_time.month);
   EXPECT_EQ(1, generalized_time.day);
   EXPECT_EQ(0, generalized_time.hours);
   EXPECT_EQ(0, generalized_time.minutes);
   EXPECT_EQ(0, generalized_time.seconds);
 }

 TEST(EncodeValuesTest, GeneralizedTimeToTime) {
   GeneralizedTime generalized_time;
   generalized_time.year = 2016;
   generalized_time.month = 6;
   generalized_time.day = 24;
   generalized_time.hours = 17;
   generalized_time.minutes = 4;
   generalized_time.seconds = 54;
   base::Time time;
   ASSERT_TRUE(GeneralizedTimeToTime(generalized_time, &time));
   EXPECT_EQ(base::Time::UnixEpoch() + base::TimeDelta::FromSeconds(1466787894),
             time);
 }

 TEST(EncodeValuesTest, GeneralizedTimeToTimeBeforeWindowsEpoch) {
   base::Time::Exploded exploded;
   exploded.year = 1570;
   exploded.month = 1;
   exploded.day_of_week = 5;
   exploded.day_of_month = 1;
   exploded.hour = 0;
   exploded.minute = 0;
   exploded.second = 0;
   exploded.millisecond = 0;

   base::Time expected_time;
   bool platform_can_represent_time =
       base::Time::FromUTCExploded(exploded, &expected_time);

   GeneralizedTime generalized_time;
   generalized_time.year = exploded.year;
   generalized_time.month = exploded.month;
   generalized_time.day = exploded.day_of_month;
   generalized_time.hours = exploded.hour;
   generalized_time.minutes = exploded.minute;
   generalized_time.seconds = exploded.second;
   base::Time time;
   ASSERT_TRUE(GeneralizedTimeToTime(generalized_time, &time));
   if (platform_can_represent_time)
     EXPECT_EQ(expected_time, time);
   else
     EXPECT_EQ(base::Time::Min(), time);

   generalized_time.day = 0;  // Invalid day of month.
   // Should fail even if outside range platform can represent.
   EXPECT_FALSE(GeneralizedTimeToTime(generalized_time, &time));
 }

 TEST(EncodeValuesTest, GeneralizedTimeToTimeAfter32BitPosixMaxYear) {
   base::Time::Exploded exploded;
   exploded.year = 2039;
   exploded.month = 1;
   exploded.day_of_week = 6;
   exploded.day_of_month = 1;
   exploded.hour = 0;
   exploded.minute = 0;
   exploded.second = 0;
   exploded.millisecond = 0;

   base::Time expected_time;
   bool platform_can_represent_time =
       base::Time::FromUTCExploded(exploded, &expected_time);

   GeneralizedTime generalized_time;
   generalized_time.year = exploded.year;
   generalized_time.month = exploded.month;
   generalized_time.day = exploded.day_of_month;
   generalized_time.hours = exploded.hour;
   generalized_time.minutes = exploded.minute;
   generalized_time.seconds = exploded.second;
   base::Time time;
   ASSERT_TRUE(GeneralizedTimeToTime(generalized_time, &time));
   if (platform_can_represent_time)
     EXPECT_EQ(expected_time, time);
   else
     EXPECT_EQ(base::Time::Max(), time);

   generalized_time.day = 0;  // Invalid day of month.
   // Should fail even if outside range platform can represent.
   EXPECT_FALSE(GeneralizedTimeToTime(generalized_time, &time));
 }

 TEST(EncodeValuesTest, EncodeGeneralizedTime) {
   GeneralizedTime time;
   time.year = 2014;
   time.month = 12;
   time.day = 18;
   time.hours = 16;
   time.minutes = 12;
   time.seconds = 59;

   // Encode a time where no components have leading zeros.
   uint8_t out[kGeneralizedTimeLength];
   ASSERT_TRUE(EncodeGeneralizedTime(time, out));
   EXPECT_EQ("20141218161259Z", ToStringPiece(out));

   // Test bounds on all components. Note the encoding function does not validate
   // the input is a valid time, only that it is encodable.
   time.year = 0;
   time.month = 0;
   time.day = 0;
   time.hours = 0;
   time.minutes = 0;
   time.seconds = 0;
   ASSERT_TRUE(EncodeGeneralizedTime(time, out));
   EXPECT_EQ("00000000000000Z", ToStringPiece(out));

   time.year = 9999;
   time.month = 99;
   time.day = 99;
   time.hours = 99;
   time.minutes = 99;
   time.seconds = 99;
   ASSERT_TRUE(EncodeGeneralizedTime(time, out));
   EXPECT_EQ("99999999999999Z", ToStringPiece(out));

   time.year = 10000;
   EXPECT_FALSE(EncodeGeneralizedTime(time, out));

   time.year = 2000;
   time.month = 100;
   EXPECT_FALSE(EncodeGeneralizedTime(time, out));
 }

 TEST(EncodeValuesTest, EncodeUTCTime) {
   GeneralizedTime time;
   time.year = 2014;
   time.month = 12;
   time.day = 18;
   time.hours = 16;
   time.minutes = 12;
   time.seconds = 59;

   // Encode a time where no components have leading zeros.
   uint8_t out[kUTCTimeLength];
   ASSERT_TRUE(EncodeUTCTime(time, out));
   EXPECT_EQ("141218161259Z", ToStringPiece(out));

   time.year = 2049;
   ASSERT_TRUE(EncodeUTCTime(time, out));
   EXPECT_EQ("491218161259Z", ToStringPiece(out));

   time.year = 2000;
   ASSERT_TRUE(EncodeUTCTime(time, out));
   EXPECT_EQ("001218161259Z", ToStringPiece(out));

   time.year = 1999;
   ASSERT_TRUE(EncodeUTCTime(time, out));
   EXPECT_EQ("991218161259Z", ToStringPiece(out));

   time.year = 1950;
   ASSERT_TRUE(EncodeUTCTime(time, out));
   EXPECT_EQ("501218161259Z", ToStringPiece(out));

   time.year = 2050;
   EXPECT_FALSE(EncodeUTCTime(time, out));

   time.year = 1949;
   EXPECT_FALSE(EncodeUTCTime(time, out));

   // Test bounds on all components. Note the encoding function does not validate
   // the input is a valid time, only that it is encodable.
   time.year = 2000;
   time.month = 0;
   time.day = 0;
   time.hours = 0;
   time.minutes = 0;
   time.seconds = 0;
   ASSERT_TRUE(EncodeUTCTime(time, out));
   EXPECT_EQ("000000000000Z", ToStringPiece(out));

   time.year = 1999;
   time.month = 99;
   time.day = 99;
   time.hours = 99;
   time.minutes = 99;
   time.seconds = 99;
   ASSERT_TRUE(EncodeUTCTime(time, out));
   EXPECT_EQ("999999999999Z", ToStringPiece(out));

   time.year = 2000;
   time.month = 100;
   EXPECT_FALSE(EncodeUTCTime(time, out));
 }

 }  // namespace test

 }  // namespace der

 }  // namespace net
	// Copyright 2016 The Chromium 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 "net/der/encode_values.h"

	#include "base/strings/string_piece.h"
	#include "base/time/time.h"
	#include "net/der/parse_values.h"
	#include "testing/gtest/include/gtest/gtest.h"

	namespace net {
	namespace der {
	namespace test {

	namespace {

	template <size_t N>
	base::StringPiece ToStringPiece(const uint8_t (&data)[N]) {
	return base::StringPiece(reinterpret_cast<const char*>(data), N);
	}

	} // namespace

	TEST(EncodeValuesTest, EncodeTimeAsGeneralizedTime) {
	// Fri, 24 Jun 2016 17:04:54 GMT
	base::Time time =
	base::Time::UnixEpoch() + base::TimeDelta::FromSeconds(1466787894);
	GeneralizedTime generalized_time;
	ASSERT_TRUE(EncodeTimeAsGeneralizedTime(time, &generalized_time));
	EXPECT_EQ(2016, generalized_time.year);
	EXPECT_EQ(6, generalized_time.month);
	EXPECT_EQ(24, generalized_time.day);
	EXPECT_EQ(17, generalized_time.hours);
	EXPECT_EQ(4, generalized_time.minutes);
	EXPECT_EQ(54, generalized_time.seconds);
	}

	// ASN.1 GeneralizedTime can represent dates from year 0000 to 9999, and
	// although base::Time can represent times from before the Windows epoch and
	// after the 32-bit time_t maximum, the conversion between base::Time and
	// der::GeneralizedTime goes through the time representation of the underlying
	// platform, which might not be able to handle the full GeneralizedTime date
	// range. Out-of-range times should not be converted to der::GeneralizedTime.
	//
	// Thus, this test focuses on an input date 31 years before the Windows epoch,
	// and confirms that EncodeTimeAsGeneralizedTime() produces the correct result
	// on platforms where it returns true. As of this writing, it will return false
	// on Windows.
	TEST(EncodeValuesTest, EncodeTimeFromBeforeWindowsEpoch) {
	constexpr int kYearsBeforeWindowsEpoch = 1601 - 1570;
	constexpr int kDaysPerYear = 365;
	constexpr int kExtraLeapDaysOverThoseYears = 8;
	constexpr base::Time kStartOfYear1570 =
	base::Time() -
	base::TimeDelta::FromDays(kYearsBeforeWindowsEpoch * kDaysPerYear +
	kExtraLeapDaysOverThoseYears);

	GeneralizedTime generalized_time;
	if (!EncodeTimeAsGeneralizedTime(kStartOfYear1570, &generalized_time))
	return;

	EXPECT_EQ(1570, generalized_time.year);
	EXPECT_EQ(1, generalized_time.month);
	EXPECT_EQ(1, generalized_time.day);
	EXPECT_EQ(0, generalized_time.hours);
	EXPECT_EQ(0, generalized_time.minutes);
	EXPECT_EQ(0, generalized_time.seconds);
	}

	// Sat, 1 Jan 2039 00:00:00 GMT. See above comment. This time may be
	// unrepresentable on 32-bit systems.
	TEST(EncodeValuesTest, EncodeTimeAfterTimeTMax) {
	base::Time::Exploded exploded;
	exploded.year = 2039;
	exploded.month = 1;
	exploded.day_of_week = 7;
	exploded.day_of_month = 1;
	exploded.hour = 0;
	exploded.minute = 0;
	exploded.second = 0;
	exploded.millisecond = 0;

	base::Time time;
	if (!base::Time::FromUTCExploded(exploded, &time))
	return;

	GeneralizedTime generalized_time;
	ASSERT_TRUE(EncodeTimeAsGeneralizedTime(time, &generalized_time));
	EXPECT_EQ(2039, generalized_time.year);
	EXPECT_EQ(1, generalized_time.month);
	EXPECT_EQ(1, generalized_time.day);
	EXPECT_EQ(0, generalized_time.hours);
	EXPECT_EQ(0, generalized_time.minutes);
	EXPECT_EQ(0, generalized_time.seconds);
	}

	TEST(EncodeValuesTest, GeneralizedTimeToTime) {
	GeneralizedTime generalized_time;
	generalized_time.year = 2016;
	generalized_time.month = 6;
	generalized_time.day = 24;
	generalized_time.hours = 17;
	generalized_time.minutes = 4;
	generalized_time.seconds = 54;
	base::Time time;
	ASSERT_TRUE(GeneralizedTimeToTime(generalized_time, &time));
	EXPECT_EQ(base::Time::UnixEpoch() + base::TimeDelta::FromSeconds(1466787894),
	time);
	}

	TEST(EncodeValuesTest, GeneralizedTimeToTimeBeforeWindowsEpoch) {
	base::Time::Exploded exploded;
	exploded.year = 1570;
	exploded.month = 1;
	exploded.day_of_week = 5;
	exploded.day_of_month = 1;
	exploded.hour = 0;
	exploded.minute = 0;
	exploded.second = 0;
	exploded.millisecond = 0;

	base::Time expected_time;
	bool platform_can_represent_time =
	base::Time::FromUTCExploded(exploded, &expected_time);

	GeneralizedTime generalized_time;
	generalized_time.year = exploded.year;
	generalized_time.month = exploded.month;
	generalized_time.day = exploded.day_of_month;
	generalized_time.hours = exploded.hour;
	generalized_time.minutes = exploded.minute;
	generalized_time.seconds = exploded.second;
	base::Time time;
	ASSERT_TRUE(GeneralizedTimeToTime(generalized_time, &time));
	if (platform_can_represent_time)
	EXPECT_EQ(expected_time, time);
	else
	EXPECT_EQ(base::Time::Min(), time);

	generalized_time.day = 0; // Invalid day of month.
	// Should fail even if outside range platform can represent.
	EXPECT_FALSE(GeneralizedTimeToTime(generalized_time, &time));
	}

	TEST(EncodeValuesTest, GeneralizedTimeToTimeAfter32BitPosixMaxYear) {
	base::Time::Exploded exploded;
	exploded.year = 2039;
	exploded.month = 1;
	exploded.day_of_week = 6;
	exploded.day_of_month = 1;
	exploded.hour = 0;
	exploded.minute = 0;
	exploded.second = 0;
	exploded.millisecond = 0;

	base::Time expected_time;
	bool platform_can_represent_time =
	base::Time::FromUTCExploded(exploded, &expected_time);

	GeneralizedTime generalized_time;
	generalized_time.year = exploded.year;
	generalized_time.month = exploded.month;
	generalized_time.day = exploded.day_of_month;
	generalized_time.hours = exploded.hour;
	generalized_time.minutes = exploded.minute;
	generalized_time.seconds = exploded.second;
	base::Time time;
	ASSERT_TRUE(GeneralizedTimeToTime(generalized_time, &time));
	if (platform_can_represent_time)
	EXPECT_EQ(expected_time, time);
	else
	EXPECT_EQ(base::Time::Max(), time);

	generalized_time.day = 0; // Invalid day of month.
	// Should fail even if outside range platform can represent.
	EXPECT_FALSE(GeneralizedTimeToTime(generalized_time, &time));
	}

	TEST(EncodeValuesTest, EncodeGeneralizedTime) {
	GeneralizedTime time;
	time.year = 2014;
	time.month = 12;
	time.day = 18;
	time.hours = 16;
	time.minutes = 12;
	time.seconds = 59;

	// Encode a time where no components have leading zeros.
	uint8_t out[kGeneralizedTimeLength];
	ASSERT_TRUE(EncodeGeneralizedTime(time, out));
	EXPECT_EQ("20141218161259Z", ToStringPiece(out));

	// Test bounds on all components. Note the encoding function does not validate
	// the input is a valid time, only that it is encodable.
	time.year = 0;
	time.month = 0;
	time.day = 0;
	time.hours = 0;
	time.minutes = 0;
	time.seconds = 0;
	ASSERT_TRUE(EncodeGeneralizedTime(time, out));
	EXPECT_EQ("00000000000000Z", ToStringPiece(out));

	time.year = 9999;
	time.month = 99;
	time.day = 99;
	time.hours = 99;
	time.minutes = 99;
	time.seconds = 99;
	ASSERT_TRUE(EncodeGeneralizedTime(time, out));
	EXPECT_EQ("99999999999999Z", ToStringPiece(out));

	time.year = 10000;
	EXPECT_FALSE(EncodeGeneralizedTime(time, out));

	time.year = 2000;
	time.month = 100;
	EXPECT_FALSE(EncodeGeneralizedTime(time, out));
	}

	TEST(EncodeValuesTest, EncodeUTCTime) {
	GeneralizedTime time;
	time.year = 2014;
	time.month = 12;
	time.day = 18;
	time.hours = 16;
	time.minutes = 12;
	time.seconds = 59;

	// Encode a time where no components have leading zeros.
	uint8_t out[kUTCTimeLength];
	ASSERT_TRUE(EncodeUTCTime(time, out));
	EXPECT_EQ("141218161259Z", ToStringPiece(out));

	time.year = 2049;
	ASSERT_TRUE(EncodeUTCTime(time, out));
	EXPECT_EQ("491218161259Z", ToStringPiece(out));

	time.year = 2000;
	ASSERT_TRUE(EncodeUTCTime(time, out));
	EXPECT_EQ("001218161259Z", ToStringPiece(out));

	time.year = 1999;
	ASSERT_TRUE(EncodeUTCTime(time, out));
	EXPECT_EQ("991218161259Z", ToStringPiece(out));

	time.year = 1950;
	ASSERT_TRUE(EncodeUTCTime(time, out));
	EXPECT_EQ("501218161259Z", ToStringPiece(out));

	time.year = 2050;
	EXPECT_FALSE(EncodeUTCTime(time, out));

	time.year = 1949;
	EXPECT_FALSE(EncodeUTCTime(time, out));

	// Test bounds on all components. Note the encoding function does not validate
	// the input is a valid time, only that it is encodable.
	time.year = 2000;
	time.month = 0;
	time.day = 0;
	time.hours = 0;
	time.minutes = 0;
	time.seconds = 0;
	ASSERT_TRUE(EncodeUTCTime(time, out));
	EXPECT_EQ("000000000000Z", ToStringPiece(out));

	time.year = 1999;
	time.month = 99;
	time.day = 99;
	time.hours = 99;
	time.minutes = 99;
	time.seconds = 99;
	ASSERT_TRUE(EncodeUTCTime(time, out));
	EXPECT_EQ("999999999999Z", ToStringPiece(out));

	time.year = 2000;
	time.month = 100;
	EXPECT_FALSE(EncodeUTCTime(time, out));
	}

	} // namespace test

	} // namespace der

	} // namespace net