src/net/der/parse_values_unittest.cc - cobalt - Git at Google

 // Copyright 2015 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/parse_values.h"

 #include "base/macros.h"
 #include "base/stl_util.h"
 #include "starboard/types.h"
 #include "testing/gtest/include/gtest/gtest.h"

 namespace net {
 namespace der {
 namespace test {

 namespace {

 template <size_t N>
 Input FromStringLiteral(const char(&data)[N]) {
   // Strings are null-terminated. The null terminating byte shouldn't be
   // included in the Input, so the size is N - 1 instead of N.
   return Input(reinterpret_cast<const uint8_t*>(data), N - 1);
 }

 }  // namespace

 TEST(ParseValuesTest, ParseBool) {
   uint8_t buf[] = {0xFF, 0x00};
   Input value(buf, 1);
   bool out;
   EXPECT_TRUE(ParseBool(value, &out));
   EXPECT_TRUE(out);

   buf[0] = 0;
   EXPECT_TRUE(ParseBool(value, &out));
   EXPECT_FALSE(out);

   buf[0] = 1;
   EXPECT_FALSE(ParseBool(value, &out));
   EXPECT_TRUE(ParseBoolRelaxed(value, &out));
   EXPECT_TRUE(out);

   buf[0] = 0xFF;
   value = Input(buf, 2);
   EXPECT_FALSE(ParseBool(value, &out));
   value = Input(buf, 0);
   EXPECT_FALSE(ParseBool(value, &out));
 }

 TEST(ParseValuesTest, ParseTimes) {
   GeneralizedTime out;

   EXPECT_TRUE(ParseUTCTime(FromStringLiteral("140218161200Z"), &out));

   // DER-encoded UTCTime must end with 'Z'.
   EXPECT_FALSE(ParseUTCTime(FromStringLiteral("140218161200X"), &out));

   // Check that a negative number (-4 in this case) doesn't get parsed as
   // a 2-digit number.
   EXPECT_FALSE(ParseUTCTime(FromStringLiteral("-40218161200Z"), &out));

   // Check that numbers with a leading 0 don't get parsed in octal by making
   // the second digit an invalid octal digit (e.g. 09).
   EXPECT_TRUE(ParseUTCTime(FromStringLiteral("090218161200Z"), &out));

   // Check that the length is validated.
   EXPECT_FALSE(ParseUTCTime(FromStringLiteral("140218161200"), &out));
   EXPECT_FALSE(ParseUTCTime(FromStringLiteral("140218161200Z0"), &out));
   EXPECT_FALSE(ParseUTCTimeRelaxed(FromStringLiteral("140218161200"), &out));
   EXPECT_FALSE(ParseUTCTimeRelaxed(FromStringLiteral("140218161200Z0"), &out));

   // Check strictness of UTCTime parsers.
   EXPECT_FALSE(ParseUTCTime(FromStringLiteral("1402181612Z"), &out));
   EXPECT_TRUE(ParseUTCTimeRelaxed(FromStringLiteral("1402181612Z"), &out));

   // Check that the time ends in Z.
   EXPECT_FALSE(ParseUTCTimeRelaxed(FromStringLiteral("1402181612Z0"), &out));

   // Check that ParseUTCTimeRelaxed calls ValidateGeneralizedTime.
   EXPECT_FALSE(ParseUTCTimeRelaxed(FromStringLiteral("1402181662Z"), &out));

   // Check format of GeneralizedTime.

   // Years 0 and 9999 are allowed.
   EXPECT_TRUE(ParseGeneralizedTime(FromStringLiteral("00000101000000Z"), &out));
   EXPECT_EQ(0, out.year);
   EXPECT_TRUE(ParseGeneralizedTime(FromStringLiteral("99991231235960Z"), &out));
   EXPECT_EQ(9999, out.year);

   // Leap seconds are allowed.
   EXPECT_TRUE(ParseGeneralizedTime(FromStringLiteral("20140218161260Z"), &out));

   // But nothing larger than a leap second.
   EXPECT_FALSE(
       ParseGeneralizedTime(FromStringLiteral("20140218161261Z"), &out));

   // Minutes only go up to 59.
   EXPECT_FALSE(
       ParseGeneralizedTime(FromStringLiteral("20140218166000Z"), &out));

   // Hours only go up to 23.
   EXPECT_FALSE(
       ParseGeneralizedTime(FromStringLiteral("20140218240000Z"), &out));
   // The 0th day of a month is invalid.
   EXPECT_FALSE(
       ParseGeneralizedTime(FromStringLiteral("20140200161200Z"), &out));
   // The 0th month is invalid.
   EXPECT_FALSE(
       ParseGeneralizedTime(FromStringLiteral("20140018161200Z"), &out));
   // Months greater than 12 are invalid.
   EXPECT_FALSE(
       ParseGeneralizedTime(FromStringLiteral("20141318161200Z"), &out));

   // Some months have 31 days.
   EXPECT_TRUE(ParseGeneralizedTime(FromStringLiteral("20140131000000Z"), &out));

   // September has only 30 days.
   EXPECT_FALSE(
       ParseGeneralizedTime(FromStringLiteral("20140931000000Z"), &out));

   // February has only 28 days...
   EXPECT_FALSE(
       ParseGeneralizedTime(FromStringLiteral("20140229000000Z"), &out));

   // ... unless it's a leap year.
   EXPECT_TRUE(ParseGeneralizedTime(FromStringLiteral("20160229000000Z"), &out));

   // There aren't any leap days in years divisible by 100...
   EXPECT_FALSE(
       ParseGeneralizedTime(FromStringLiteral("21000229000000Z"), &out));

   // ...unless it's also divisible by 400.
   EXPECT_TRUE(ParseGeneralizedTime(FromStringLiteral("20000229000000Z"), &out));

   // Check more perverse invalid inputs.

   // Check that trailing null bytes are not ignored.
   EXPECT_FALSE(
       ParseGeneralizedTime(FromStringLiteral("20001231010203Z\0"), &out));

   // Check what happens when a null byte is in the middle of the input.
   EXPECT_FALSE(ParseGeneralizedTime(FromStringLiteral(
                                         "200\0"
                                         "1231010203Z"),
                                     &out));

   // The year can't be in hex.
   EXPECT_FALSE(
       ParseGeneralizedTime(FromStringLiteral("0x201231000000Z"), &out));

   // The last byte must be 'Z'.
   EXPECT_FALSE(
       ParseGeneralizedTime(FromStringLiteral("20001231000000X"), &out));

   // Check that the length is validated.
   EXPECT_FALSE(ParseGeneralizedTime(FromStringLiteral("20140218161200"), &out));
   EXPECT_FALSE(
       ParseGeneralizedTime(FromStringLiteral("20140218161200Z0"), &out));
 }

 TEST(ParseValuesTest, TimesCompare) {
   GeneralizedTime time1;
   GeneralizedTime time2;
   GeneralizedTime time3;
   GeneralizedTime time4;

   ASSERT_TRUE(
       ParseGeneralizedTime(FromStringLiteral("20140218161200Z"), &time1));
   // Test that ParseUTCTime correctly normalizes the year.
   ASSERT_TRUE(ParseUTCTime(FromStringLiteral("150218161200Z"), &time2));
   ASSERT_TRUE(ParseUTCTimeRelaxed(FromStringLiteral("1503070000Z"), &time3));
   ASSERT_TRUE(
       ParseGeneralizedTime(FromStringLiteral("20160218161200Z"), &time4));
   EXPECT_TRUE(time1 < time2);
   EXPECT_TRUE(time2 < time3);
   EXPECT_TRUE(time3 < time4);

   EXPECT_TRUE(time2 > time1);
   EXPECT_TRUE(time2 >= time1);
   EXPECT_TRUE(time3 <= time4);
   EXPECT_TRUE(time1 <= time1);
   EXPECT_TRUE(time1 >= time1);
 }

 TEST(ParseValuesTest, UTCTimeRange) {
   GeneralizedTime time;
   ASSERT_TRUE(
       ParseGeneralizedTime(FromStringLiteral("20140218161200Z"), &time));
   EXPECT_TRUE(time.InUTCTimeRange());

   time.year = 1950;
   EXPECT_TRUE(time.InUTCTimeRange());

   time.year = 1949;
   EXPECT_FALSE(time.InUTCTimeRange());

   time.year = 2049;
   EXPECT_TRUE(time.InUTCTimeRange());

   time.year = 2050;
   EXPECT_FALSE(time.InUTCTimeRange());
 }

 struct Uint64TestData {
   bool should_pass;
   const uint8_t input[9];
   size_t length;
   uint64_t expected_value;
 };

 const Uint64TestData kUint64TestData[] = {
     {true, {0x00}, 1, 0},
     // This number fails because it is not a minimal representation.
     {false, {0x00, 0x00}, 2},
     {true, {0x01}, 1, 1},
     {false, {0xFF}, 1},
     {true, {0x7F, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF}, 8, INT64_MAX},
     {true,
      {0x00, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF},
      9,
      UINT64_MAX},
     // This number fails because it is negative.
     {false, {0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF}, 8},
     {false, {0x80, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00}, 8},
     {false, {0x00, 0x01}, 2},
     {false, {0x01, 0x02, 0x03, 0x04, 0x05, 0x06, 0x07, 0x08, 0x09}, 9},
     {false, {0}, 0},
 };

 TEST(ParseValuesTest, ParseUint64) {
   for (size_t i = 0; i < base::size(kUint64TestData); i++) {
     const Uint64TestData& test_case = kUint64TestData[i];
     SCOPED_TRACE(i);

     uint64_t result;
     EXPECT_EQ(test_case.should_pass,
               ParseUint64(Input(test_case.input, test_case.length), &result));
     if (test_case.should_pass)
       EXPECT_EQ(test_case.expected_value, result);
   }
 }

 struct Uint8TestData {
   bool should_pass;
   const uint8_t input[9];
   size_t length;
   uint8_t expected_value;
 };

 const Uint8TestData kUint8TestData[] = {
     {true, {0x00}, 1, 0},
     // This number fails because it is not a minimal representation.
     {false, {0x00, 0x00}, 2},
     {true, {0x01}, 1, 1},
     {false, {0x01, 0xFF}, 2},
     {false, {0x03, 0x83}, 2},
     {true, {0x7F}, 1, 0x7F},
     {true, {0x00, 0xFF}, 2, 0xFF},
     // This number fails because it is negative.
     {false, {0xFF}, 1},
     {false, {0x80}, 1},
     {false, {0x00, 0x01}, 2},
     {false, {0}, 0},
 };

 TEST(ParseValuesTest, ParseUint8) {
   for (size_t i = 0; i < base::size(kUint8TestData); i++) {
     const Uint8TestData& test_case = kUint8TestData[i];
     SCOPED_TRACE(i);

     uint8_t result;
     EXPECT_EQ(test_case.should_pass,
               ParseUint8(Input(test_case.input, test_case.length), &result));
     if (test_case.should_pass)
       EXPECT_EQ(test_case.expected_value, result);
   }
 }

 struct IsValidIntegerTestData {
   bool should_pass;
   const uint8_t input[2];
   size_t length;
   bool negative;
 };

 const IsValidIntegerTestData kIsValidIntegerTestData[] = {
     // Empty input (invalid DER).
     {false, {0x00}, 0},

     // The correct encoding for zero.
     {true, {0x00}, 1, false},

     // Invalid representation of zero (not minimal)
     {false, {0x00, 0x00}, 2},

     // Valid single byte negative numbers.
     {true, {0x80}, 1, true},
     {true, {0xFF}, 1, true},

     // Non-minimal negative number.
     {false, {0xFF, 0x80}, 2},

     // Positive number with a legitimate leading zero.
     {true, {0x00, 0x80}, 2, false},

     // A legitimate negative number that starts with FF (MSB of second byte is
     // 0 so OK).
     {true, {0xFF, 0x7F}, 2, true},
 };

 TEST(ParseValuesTest, IsValidInteger) {
   for (size_t i = 0; i < base::size(kIsValidIntegerTestData); i++) {
     const auto& test_case = kIsValidIntegerTestData[i];
     SCOPED_TRACE(i);

     bool negative;
     EXPECT_EQ(
         test_case.should_pass,
         IsValidInteger(Input(test_case.input, test_case.length), &negative));
     if (test_case.should_pass)
       EXPECT_EQ(test_case.negative, negative);
   }
 }

 // Tests parsing an empty BIT STRING.
 TEST(ParseValuesTest, ParseBitStringEmptyNoUnusedBits) {
   const uint8_t kData[] = {0x00};

   BitString bit_string;
   ASSERT_TRUE(ParseBitString(Input(kData), &bit_string));

   EXPECT_EQ(0u, bit_string.unused_bits());
   EXPECT_EQ(0u, bit_string.bytes().Length());

   EXPECT_FALSE(bit_string.AssertsBit(0));
   EXPECT_FALSE(bit_string.AssertsBit(1));
   EXPECT_FALSE(bit_string.AssertsBit(3));
 }

 // Tests parsing an empty BIT STRING that incorrectly claims one unused bit.
 TEST(ParseValuesTest, ParseBitStringEmptyOneUnusedBit) {
   const uint8_t kData[] = {0x01};

   BitString bit_string;
   EXPECT_FALSE(ParseBitString(Input(kData), &bit_string));
 }

 // Tests parsing an empty BIT STRING that is not minmally encoded (the entire
 // last byte is comprised of unused bits).
 TEST(ParseValuesTest, ParseBitStringNonEmptyTooManyUnusedBits) {
   const uint8_t kData[] = {0x08, 0x00};

   BitString bit_string;
   EXPECT_FALSE(ParseBitString(Input(kData), &bit_string));
 }

 // Tests parsing a BIT STRING of 7 bits each of which are 1.
 TEST(ParseValuesTest, ParseBitStringSevenOneBits) {
   const uint8_t kData[] = {0x01, 0xFE};

   BitString bit_string;
   ASSERT_TRUE(ParseBitString(Input(kData), &bit_string));

   EXPECT_EQ(1u, bit_string.unused_bits());
   EXPECT_EQ(1u, bit_string.bytes().Length());
   EXPECT_EQ(0xFE, bit_string.bytes().UnsafeData()[0]);

   EXPECT_TRUE(bit_string.AssertsBit(0));
   EXPECT_TRUE(bit_string.AssertsBit(1));
   EXPECT_TRUE(bit_string.AssertsBit(2));
   EXPECT_TRUE(bit_string.AssertsBit(3));
   EXPECT_TRUE(bit_string.AssertsBit(4));
   EXPECT_TRUE(bit_string.AssertsBit(5));
   EXPECT_TRUE(bit_string.AssertsBit(6));
   EXPECT_FALSE(bit_string.AssertsBit(7));
   EXPECT_FALSE(bit_string.AssertsBit(8));
 }

 // Tests parsing a BIT STRING of 7 bits each of which are 1. The unused bit
 // however is set to 1, which is an invalid encoding.
 TEST(ParseValuesTest, ParseBitStringSevenOneBitsUnusedBitIsOne) {
   const uint8_t kData[] = {0x01, 0xFF};

   BitString bit_string;
   EXPECT_FALSE(ParseBitString(Input(kData), &bit_string));
 }

 }  // namespace test
 }  // namespace der
 }  // namespace net
	// Copyright 2015 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/parse_values.h"

	#include "base/macros.h"
	#include "base/stl_util.h"
	#include "starboard/types.h"
	#include "testing/gtest/include/gtest/gtest.h"

	namespace net {
	namespace der {
	namespace test {

	namespace {

	template <size_t N>
	Input FromStringLiteral(const char(&data)[N]) {
	// Strings are null-terminated. The null terminating byte shouldn't be
	// included in the Input, so the size is N - 1 instead of N.
	return Input(reinterpret_cast<const uint8_t*>(data), N - 1);
	}

	} // namespace

	TEST(ParseValuesTest, ParseBool) {
	uint8_t buf[] = {0xFF, 0x00};
	Input value(buf, 1);
	bool out;
	EXPECT_TRUE(ParseBool(value, &out));
	EXPECT_TRUE(out);

	buf[0] = 0;
	EXPECT_TRUE(ParseBool(value, &out));
	EXPECT_FALSE(out);

	buf[0] = 1;
	EXPECT_FALSE(ParseBool(value, &out));
	EXPECT_TRUE(ParseBoolRelaxed(value, &out));
	EXPECT_TRUE(out);

	buf[0] = 0xFF;
	value = Input(buf, 2);
	EXPECT_FALSE(ParseBool(value, &out));
	value = Input(buf, 0);
	EXPECT_FALSE(ParseBool(value, &out));
	}

	TEST(ParseValuesTest, ParseTimes) {
	GeneralizedTime out;

	EXPECT_TRUE(ParseUTCTime(FromStringLiteral("140218161200Z"), &out));

	// DER-encoded UTCTime must end with 'Z'.
	EXPECT_FALSE(ParseUTCTime(FromStringLiteral("140218161200X"), &out));

	// Check that a negative number (-4 in this case) doesn't get parsed as
	// a 2-digit number.
	EXPECT_FALSE(ParseUTCTime(FromStringLiteral("-40218161200Z"), &out));

	// Check that numbers with a leading 0 don't get parsed in octal by making
	// the second digit an invalid octal digit (e.g. 09).
	EXPECT_TRUE(ParseUTCTime(FromStringLiteral("090218161200Z"), &out));

	// Check that the length is validated.
	EXPECT_FALSE(ParseUTCTime(FromStringLiteral("140218161200"), &out));
	EXPECT_FALSE(ParseUTCTime(FromStringLiteral("140218161200Z0"), &out));
	EXPECT_FALSE(ParseUTCTimeRelaxed(FromStringLiteral("140218161200"), &out));
	EXPECT_FALSE(ParseUTCTimeRelaxed(FromStringLiteral("140218161200Z0"), &out));

	// Check strictness of UTCTime parsers.
	EXPECT_FALSE(ParseUTCTime(FromStringLiteral("1402181612Z"), &out));
	EXPECT_TRUE(ParseUTCTimeRelaxed(FromStringLiteral("1402181612Z"), &out));

	// Check that the time ends in Z.
	EXPECT_FALSE(ParseUTCTimeRelaxed(FromStringLiteral("1402181612Z0"), &out));

	// Check that ParseUTCTimeRelaxed calls ValidateGeneralizedTime.
	EXPECT_FALSE(ParseUTCTimeRelaxed(FromStringLiteral("1402181662Z"), &out));

	// Check format of GeneralizedTime.

	// Years 0 and 9999 are allowed.
	EXPECT_TRUE(ParseGeneralizedTime(FromStringLiteral("00000101000000Z"), &out));
	EXPECT_EQ(0, out.year);
	EXPECT_TRUE(ParseGeneralizedTime(FromStringLiteral("99991231235960Z"), &out));
	EXPECT_EQ(9999, out.year);

	// Leap seconds are allowed.
	EXPECT_TRUE(ParseGeneralizedTime(FromStringLiteral("20140218161260Z"), &out));

	// But nothing larger than a leap second.
	EXPECT_FALSE(
	ParseGeneralizedTime(FromStringLiteral("20140218161261Z"), &out));

	// Minutes only go up to 59.
	EXPECT_FALSE(
	ParseGeneralizedTime(FromStringLiteral("20140218166000Z"), &out));

	// Hours only go up to 23.
	EXPECT_FALSE(
	ParseGeneralizedTime(FromStringLiteral("20140218240000Z"), &out));
	// The 0th day of a month is invalid.
	EXPECT_FALSE(
	ParseGeneralizedTime(FromStringLiteral("20140200161200Z"), &out));
	// The 0th month is invalid.
	EXPECT_FALSE(
	ParseGeneralizedTime(FromStringLiteral("20140018161200Z"), &out));
	// Months greater than 12 are invalid.
	EXPECT_FALSE(
	ParseGeneralizedTime(FromStringLiteral("20141318161200Z"), &out));

	// Some months have 31 days.
	EXPECT_TRUE(ParseGeneralizedTime(FromStringLiteral("20140131000000Z"), &out));

	// September has only 30 days.
	EXPECT_FALSE(
	ParseGeneralizedTime(FromStringLiteral("20140931000000Z"), &out));

	// February has only 28 days...
	EXPECT_FALSE(
	ParseGeneralizedTime(FromStringLiteral("20140229000000Z"), &out));

	// ... unless it's a leap year.
	EXPECT_TRUE(ParseGeneralizedTime(FromStringLiteral("20160229000000Z"), &out));

	// There aren't any leap days in years divisible by 100...
	EXPECT_FALSE(
	ParseGeneralizedTime(FromStringLiteral("21000229000000Z"), &out));

	// ...unless it's also divisible by 400.
	EXPECT_TRUE(ParseGeneralizedTime(FromStringLiteral("20000229000000Z"), &out));

	// Check more perverse invalid inputs.

	// Check that trailing null bytes are not ignored.
	EXPECT_FALSE(
	ParseGeneralizedTime(FromStringLiteral("20001231010203Z\0"), &out));

	// Check what happens when a null byte is in the middle of the input.
	EXPECT_FALSE(ParseGeneralizedTime(FromStringLiteral(
	"200\0"
	"1231010203Z"),
	&out));

	// The year can't be in hex.
	EXPECT_FALSE(
	ParseGeneralizedTime(FromStringLiteral("0x201231000000Z"), &out));

	// The last byte must be 'Z'.
	EXPECT_FALSE(
	ParseGeneralizedTime(FromStringLiteral("20001231000000X"), &out));

	// Check that the length is validated.
	EXPECT_FALSE(ParseGeneralizedTime(FromStringLiteral("20140218161200"), &out));
	EXPECT_FALSE(
	ParseGeneralizedTime(FromStringLiteral("20140218161200Z0"), &out));
	}

	TEST(ParseValuesTest, TimesCompare) {
	GeneralizedTime time1;
	GeneralizedTime time2;
	GeneralizedTime time3;
	GeneralizedTime time4;

	ASSERT_TRUE(
	ParseGeneralizedTime(FromStringLiteral("20140218161200Z"), &time1));
	// Test that ParseUTCTime correctly normalizes the year.
	ASSERT_TRUE(ParseUTCTime(FromStringLiteral("150218161200Z"), &time2));
	ASSERT_TRUE(ParseUTCTimeRelaxed(FromStringLiteral("1503070000Z"), &time3));
	ASSERT_TRUE(
	ParseGeneralizedTime(FromStringLiteral("20160218161200Z"), &time4));
	EXPECT_TRUE(time1 < time2);
	EXPECT_TRUE(time2 < time3);
	EXPECT_TRUE(time3 < time4);

	EXPECT_TRUE(time2 > time1);
	EXPECT_TRUE(time2 >= time1);
	EXPECT_TRUE(time3 <= time4);
	EXPECT_TRUE(time1 <= time1);
	EXPECT_TRUE(time1 >= time1);
	}

	TEST(ParseValuesTest, UTCTimeRange) {
	GeneralizedTime time;
	ASSERT_TRUE(
	ParseGeneralizedTime(FromStringLiteral("20140218161200Z"), &time));
	EXPECT_TRUE(time.InUTCTimeRange());

	time.year = 1950;
	EXPECT_TRUE(time.InUTCTimeRange());

	time.year = 1949;
	EXPECT_FALSE(time.InUTCTimeRange());

	time.year = 2049;
	EXPECT_TRUE(time.InUTCTimeRange());

	time.year = 2050;
	EXPECT_FALSE(time.InUTCTimeRange());
	}

	struct Uint64TestData {
	bool should_pass;
	const uint8_t input[9];
	size_t length;
	uint64_t expected_value;
	};

	const Uint64TestData kUint64TestData[] = {
	{true, {0x00}, 1, 0},
	// This number fails because it is not a minimal representation.
	{false, {0x00, 0x00}, 2},
	{true, {0x01}, 1, 1},
	{false, {0xFF}, 1},
	{true, {0x7F, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF}, 8, INT64_MAX},
	{true,
	{0x00, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF},
	9,
	UINT64_MAX},
	// This number fails because it is negative.
	{false, {0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF}, 8},
	{false, {0x80, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00}, 8},
	{false, {0x00, 0x01}, 2},
	{false, {0x01, 0x02, 0x03, 0x04, 0x05, 0x06, 0x07, 0x08, 0x09}, 9},
	{false, {0}, 0},
	};

	TEST(ParseValuesTest, ParseUint64) {
	for (size_t i = 0; i < base::size(kUint64TestData); i++) {
	const Uint64TestData& test_case = kUint64TestData[i];
	SCOPED_TRACE(i);

	uint64_t result;
	EXPECT_EQ(test_case.should_pass,
	ParseUint64(Input(test_case.input, test_case.length), &result));
	if (test_case.should_pass)
	EXPECT_EQ(test_case.expected_value, result);
	}
	}

	struct Uint8TestData {
	bool should_pass;
	const uint8_t input[9];
	size_t length;
	uint8_t expected_value;
	};

	const Uint8TestData kUint8TestData[] = {
	{true, {0x00}, 1, 0},
	// This number fails because it is not a minimal representation.
	{false, {0x00, 0x00}, 2},
	{true, {0x01}, 1, 1},
	{false, {0x01, 0xFF}, 2},
	{false, {0x03, 0x83}, 2},
	{true, {0x7F}, 1, 0x7F},
	{true, {0x00, 0xFF}, 2, 0xFF},
	// This number fails because it is negative.
	{false, {0xFF}, 1},
	{false, {0x80}, 1},
	{false, {0x00, 0x01}, 2},
	{false, {0}, 0},
	};

	TEST(ParseValuesTest, ParseUint8) {
	for (size_t i = 0; i < base::size(kUint8TestData); i++) {
	const Uint8TestData& test_case = kUint8TestData[i];
	SCOPED_TRACE(i);

	uint8_t result;
	EXPECT_EQ(test_case.should_pass,
	ParseUint8(Input(test_case.input, test_case.length), &result));
	if (test_case.should_pass)
	EXPECT_EQ(test_case.expected_value, result);
	}
	}

	struct IsValidIntegerTestData {
	bool should_pass;
	const uint8_t input[2];
	size_t length;
	bool negative;
	};

	const IsValidIntegerTestData kIsValidIntegerTestData[] = {
	// Empty input (invalid DER).
	{false, {0x00}, 0},

	// The correct encoding for zero.
	{true, {0x00}, 1, false},

	// Invalid representation of zero (not minimal)
	{false, {0x00, 0x00}, 2},

	// Valid single byte negative numbers.
	{true, {0x80}, 1, true},
	{true, {0xFF}, 1, true},

	// Non-minimal negative number.
	{false, {0xFF, 0x80}, 2},

	// Positive number with a legitimate leading zero.
	{true, {0x00, 0x80}, 2, false},

	// A legitimate negative number that starts with FF (MSB of second byte is
	// 0 so OK).
	{true, {0xFF, 0x7F}, 2, true},
	};

	TEST(ParseValuesTest, IsValidInteger) {
	for (size_t i = 0; i < base::size(kIsValidIntegerTestData); i++) {
	const auto& test_case = kIsValidIntegerTestData[i];
	SCOPED_TRACE(i);

	bool negative;
	EXPECT_EQ(
	test_case.should_pass,
	IsValidInteger(Input(test_case.input, test_case.length), &negative));
	if (test_case.should_pass)
	EXPECT_EQ(test_case.negative, negative);
	}
	}

	// Tests parsing an empty BIT STRING.
	TEST(ParseValuesTest, ParseBitStringEmptyNoUnusedBits) {
	const uint8_t kData[] = {0x00};

	BitString bit_string;
	ASSERT_TRUE(ParseBitString(Input(kData), &bit_string));

	EXPECT_EQ(0u, bit_string.unused_bits());
	EXPECT_EQ(0u, bit_string.bytes().Length());

	EXPECT_FALSE(bit_string.AssertsBit(0));
	EXPECT_FALSE(bit_string.AssertsBit(1));
	EXPECT_FALSE(bit_string.AssertsBit(3));
	}

	// Tests parsing an empty BIT STRING that incorrectly claims one unused bit.
	TEST(ParseValuesTest, ParseBitStringEmptyOneUnusedBit) {
	const uint8_t kData[] = {0x01};

	BitString bit_string;
	EXPECT_FALSE(ParseBitString(Input(kData), &bit_string));
	}

	// Tests parsing an empty BIT STRING that is not minmally encoded (the entire
	// last byte is comprised of unused bits).
	TEST(ParseValuesTest, ParseBitStringNonEmptyTooManyUnusedBits) {
	const uint8_t kData[] = {0x08, 0x00};

	BitString bit_string;
	EXPECT_FALSE(ParseBitString(Input(kData), &bit_string));
	}

	// Tests parsing a BIT STRING of 7 bits each of which are 1.
	TEST(ParseValuesTest, ParseBitStringSevenOneBits) {
	const uint8_t kData[] = {0x01, 0xFE};

	BitString bit_string;
	ASSERT_TRUE(ParseBitString(Input(kData), &bit_string));

	EXPECT_EQ(1u, bit_string.unused_bits());
	EXPECT_EQ(1u, bit_string.bytes().Length());
	EXPECT_EQ(0xFE, bit_string.bytes().UnsafeData()[0]);

	EXPECT_TRUE(bit_string.AssertsBit(0));
	EXPECT_TRUE(bit_string.AssertsBit(1));
	EXPECT_TRUE(bit_string.AssertsBit(2));
	EXPECT_TRUE(bit_string.AssertsBit(3));
	EXPECT_TRUE(bit_string.AssertsBit(4));
	EXPECT_TRUE(bit_string.AssertsBit(5));
	EXPECT_TRUE(bit_string.AssertsBit(6));
	EXPECT_FALSE(bit_string.AssertsBit(7));
	EXPECT_FALSE(bit_string.AssertsBit(8));
	}

	// Tests parsing a BIT STRING of 7 bits each of which are 1. The unused bit
	// however is set to 1, which is an invalid encoding.
	TEST(ParseValuesTest, ParseBitStringSevenOneBitsUnusedBitIsOne) {
	const uint8_t kData[] = {0x01, 0xFF};

	BitString bit_string;
	EXPECT_FALSE(ParseBitString(Input(kData), &bit_string));
	}

	} // namespace test
	} // namespace der
	} // namespace net