// Copyright 2011 The Chromium Authors // Use of this source code is governed by a BSD-style license that can be // found in the LICENSE file. #include "base/rand_util.h" #include #include #include #include #include #include #include #include "base/containers/span.h" #include "base/logging.h" #include "base/time/time.h" #include "testing/gtest/include/gtest/gtest.h" namespace base { namespace { const int kIntMin = std::numeric_limits::min(); const int kIntMax = std::numeric_limits::max(); } // namespace TEST(RandUtilTest, RandInt) { EXPECT_EQ(base::RandInt(0, 0), 0); EXPECT_EQ(base::RandInt(kIntMin, kIntMin), kIntMin); EXPECT_EQ(base::RandInt(kIntMax, kIntMax), kIntMax); // Check that the DCHECKS in RandInt() don't fire due to internal overflow. // There was a 50% chance of that happening, so calling it 40 times means // the chances of this passing by accident are tiny (9e-13). for (int i = 0; i < 40; ++i) base::RandInt(kIntMin, kIntMax); } TEST(RandUtilTest, RandDouble) { // Force 64-bit precision, making sure we're not in a 80-bit FPU register. volatile double number = base::RandDouble(); EXPECT_GT(1.0, number); EXPECT_LE(0.0, number); } TEST(RandUtilTest, RandFloat) { // Force 32-bit precision, making sure we're not in an 80-bit FPU register. volatile float number = base::RandFloat(); EXPECT_GT(1.f, number); EXPECT_LE(0.f, number); } TEST(RandUtilTest, RandTimeDelta) { { const auto delta = base::RandTimeDelta(-base::Seconds(2), -base::Seconds(1)); EXPECT_GE(delta, -base::Seconds(2)); EXPECT_LT(delta, -base::Seconds(1)); } { const auto delta = base::RandTimeDelta(-base::Seconds(2), base::Seconds(2)); EXPECT_GE(delta, -base::Seconds(2)); EXPECT_LT(delta, base::Seconds(2)); } { const auto delta = base::RandTimeDelta(base::Seconds(1), base::Seconds(2)); EXPECT_GE(delta, base::Seconds(1)); EXPECT_LT(delta, base::Seconds(2)); } } TEST(RandUtilTest, RandTimeDeltaUpTo) { const auto delta = base::RandTimeDeltaUpTo(base::Seconds(2)); EXPECT_FALSE(delta.is_negative()); EXPECT_LT(delta, base::Seconds(2)); } TEST(RandUtilTest, BitsToOpenEndedUnitInterval) { // Force 64-bit precision, making sure we're not in an 80-bit FPU register. volatile double all_zeros = BitsToOpenEndedUnitInterval(0x0); EXPECT_EQ(0.0, all_zeros); // Force 64-bit precision, making sure we're not in an 80-bit FPU register. volatile double smallest_nonzero = BitsToOpenEndedUnitInterval(0x1); EXPECT_LT(0.0, smallest_nonzero); for (uint64_t i = 0x2; i < 0x10; ++i) { // Force 64-bit precision, making sure we're not in an 80-bit FPU register. volatile double number = BitsToOpenEndedUnitInterval(i); EXPECT_EQ(i * smallest_nonzero, number); } // Force 64-bit precision, making sure we're not in an 80-bit FPU register. volatile double all_ones = BitsToOpenEndedUnitInterval(UINT64_MAX); EXPECT_GT(1.0, all_ones); } TEST(RandUtilTest, BitsToOpenEndedUnitIntervalF) { // Force 32-bit precision, making sure we're not in an 80-bit FPU register. volatile float all_zeros = BitsToOpenEndedUnitIntervalF(0x0); EXPECT_EQ(0.f, all_zeros); // Force 32-bit precision, making sure we're not in an 80-bit FPU register. volatile float smallest_nonzero = BitsToOpenEndedUnitIntervalF(0x1); EXPECT_LT(0.f, smallest_nonzero); for (uint64_t i = 0x2; i < 0x10; ++i) { // Force 32-bit precision, making sure we're not in an 80-bit FPU register. volatile float number = BitsToOpenEndedUnitIntervalF(i); EXPECT_EQ(i * smallest_nonzero, number); } // Force 32-bit precision, making sure we're not in an 80-bit FPU register. volatile float all_ones = BitsToOpenEndedUnitIntervalF(UINT64_MAX); EXPECT_GT(1.f, all_ones); } TEST(RandUtilTest, RandBytes) { const size_t buffer_size = 50; uint8_t buffer[buffer_size]; memset(buffer, 0, buffer_size); base::RandBytes(buffer); std::sort(buffer, buffer + buffer_size); // Probability of occurrence of less than 25 unique bytes in 50 random bytes // is below 10^-25. EXPECT_GT(std::unique(buffer, buffer + buffer_size) - buffer, 25); } // Verify that calling base::RandBytes with an empty buffer doesn't fail. TEST(RandUtilTest, RandBytes0) { base::RandBytes(span()); base::RandBytes(nullptr, 0); } TEST(RandUtilTest, RandBytesAsVector) { std::vector random_vec = base::RandBytesAsVector(0); EXPECT_TRUE(random_vec.empty()); random_vec = base::RandBytesAsVector(1); EXPECT_EQ(1U, random_vec.size()); random_vec = base::RandBytesAsVector(145); EXPECT_EQ(145U, random_vec.size()); char accumulator = 0; for (auto i : random_vec) { accumulator |= i; } // In theory this test can fail, but it won't before the universe dies of // heat death. EXPECT_NE(0, accumulator); } TEST(RandUtilTest, RandBytesAsString) { std::string random_string = base::RandBytesAsString(1); EXPECT_EQ(1U, random_string.size()); random_string = base::RandBytesAsString(145); EXPECT_EQ(145U, random_string.size()); char accumulator = 0; for (auto i : random_string) accumulator |= i; // In theory this test can fail, but it won't before the universe dies of // heat death. EXPECT_NE(0, accumulator); } // Make sure that it is still appropriate to use RandGenerator in conjunction // with std::random_shuffle(). TEST(RandUtilTest, RandGeneratorForRandomShuffle) { EXPECT_EQ(base::RandGenerator(1), 0U); EXPECT_LE(std::numeric_limits::max(), std::numeric_limits::max()); } TEST(RandUtilTest, RandGeneratorIsUniform) { // Verify that RandGenerator has a uniform distribution. This is a // regression test that consistently failed when RandGenerator was // implemented this way: // // return base::RandUint64() % max; // // A degenerate case for such an implementation is e.g. a top of // range that is 2/3rds of the way to MAX_UINT64, in which case the // bottom half of the range would be twice as likely to occur as the // top half. A bit of calculus care of jar@ shows that the largest // measurable delta is when the top of the range is 3/4ths of the // way, so that's what we use in the test. constexpr uint64_t kTopOfRange = (std::numeric_limits::max() / 4ULL) * 3ULL; constexpr double kExpectedAverage = static_cast(kTopOfRange / 2); constexpr double kAllowedVariance = kExpectedAverage / 50.0; // +/- 2% constexpr int kMinAttempts = 1000; constexpr int kMaxAttempts = 1000000; double cumulative_average = 0.0; int count = 0; while (count < kMaxAttempts) { uint64_t value = base::RandGenerator(kTopOfRange); cumulative_average = (count * cumulative_average + value) / (count + 1); // Don't quit too quickly for things to start converging, or we may have // a false positive. if (count > kMinAttempts && kExpectedAverage - kAllowedVariance < cumulative_average && cumulative_average < kExpectedAverage + kAllowedVariance) { break; } ++count; } ASSERT_LT(count, kMaxAttempts) << "Expected average was " << kExpectedAverage << ", average ended at " << cumulative_average; } TEST(RandUtilTest, RandUint64ProducesBothValuesOfAllBits) { // This tests to see that our underlying random generator is good // enough, for some value of good enough. uint64_t kAllZeros = 0ULL; uint64_t kAllOnes = ~kAllZeros; uint64_t found_ones = kAllZeros; uint64_t found_zeros = kAllOnes; for (size_t i = 0; i < 1000; ++i) { uint64_t value = base::RandUint64(); found_ones |= value; found_zeros &= value; if (found_zeros == kAllZeros && found_ones == kAllOnes) return; } FAIL() << "Didn't achieve all bit values in maximum number of tries."; } TEST(RandUtilTest, RandBytesLonger) { // Fuchsia can only retrieve 256 bytes of entropy at a time, so make sure we // handle longer requests than that. std::string random_string0 = base::RandBytesAsString(255); EXPECT_EQ(255u, random_string0.size()); std::string random_string1 = base::RandBytesAsString(1023); EXPECT_EQ(1023u, random_string1.size()); std::string random_string2 = base::RandBytesAsString(4097); EXPECT_EQ(4097u, random_string2.size()); } // Benchmark test for RandBytes(). Disabled since it's intentionally slow and // does not test anything that isn't already tested by the existing RandBytes() // tests. TEST(RandUtilTest, DISABLED_RandBytesPerf) { // Benchmark the performance of |kTestIterations| of RandBytes() using a // buffer size of |kTestBufferSize|. const int kTestIterations = 10; const size_t kTestBufferSize = 1 * 1024 * 1024; std::unique_ptr buffer(new uint8_t[kTestBufferSize]); const base::TimeTicks now = base::TimeTicks::Now(); for (int i = 0; i < kTestIterations; ++i) base::RandBytes(make_span(buffer.get(), kTestBufferSize)); const base::TimeTicks end = base::TimeTicks::Now(); LOG(INFO) << "RandBytes(" << kTestBufferSize << ") took: " << (end - now).InMicroseconds() << "µs"; } TEST(RandUtilTest, InsecureRandomGeneratorProducesBothValuesOfAllBits) { // This tests to see that our underlying random generator is good // enough, for some value of good enough. uint64_t kAllZeros = 0ULL; uint64_t kAllOnes = ~kAllZeros; uint64_t found_ones = kAllZeros; uint64_t found_zeros = kAllOnes; InsecureRandomGenerator generator; for (size_t i = 0; i < 1000; ++i) { uint64_t value = generator.RandUint64(); found_ones |= value; found_zeros &= value; if (found_zeros == kAllZeros && found_ones == kAllOnes) return; } FAIL() << "Didn't achieve all bit values in maximum number of tries."; } namespace { constexpr double kXp1Percent = -2.33; constexpr double kXp99Percent = 2.33; double ChiSquaredCriticalValue(double nu, double x_p) { // From "The Art Of Computer Programming" (TAOCP), Volume 2, Section 3.3.1, // Table 1. This is the asymptotic value for nu > 30, up to O(1 / sqrt(nu)). return nu + sqrt(2. * nu) * x_p + 2. / 3. * (x_p * x_p) - 2. / 3.; } int ExtractBits(uint64_t value, int from_bit, int num_bits) { return (value >> from_bit) & ((1 << num_bits) - 1); } // Performs a Chi-Squared test on a subset of |num_bits| extracted starting from // |from_bit| in the generated value. // // See TAOCP, Volume 2, Section 3.3.1, and // https://en.wikipedia.org/wiki/Pearson%27s_chi-squared_test for details. // // This is only one of the many, many random number generator test we could do, // but they are cumbersome, as they are typically very slow, and expected to // fail from time to time, due to their probabilistic nature. // // The generator we use has however been vetted with the BigCrush test suite // from Marsaglia, so this should suffice as a smoke test that our // implementation is wrong. bool ChiSquaredTest(InsecureRandomGenerator& gen, size_t n, int from_bit, int num_bits) { const int range = 1 << num_bits; CHECK_EQ(static_cast(n % range), 0) << "Makes computations simpler"; std::vector samples(range, 0); // Count how many samples pf each value are found. All buckets should be // almost equal if the generator is suitably uniformly random. for (size_t i = 0; i < n; i++) { int sample = ExtractBits(gen.RandUint64(), from_bit, num_bits); samples[sample] += 1; } // Compute the Chi-Squared statistic, which is: // \Sum_{k=0}^{range-1} \frac{(count - expected)^2}{expected} double chi_squared = 0.; double expected_count = n / range; for (size_t sample_count : samples) { double deviation = sample_count - expected_count; chi_squared += (deviation * deviation) / expected_count; } // The generator should produce numbers that are not too far of (chi_squared // lower than a given quantile), but not too close to the ideal distribution // either (chi_squared is too low). // // See The Art Of Computer Programming, Volume 2, Section 3.3.1 for details. return chi_squared > ChiSquaredCriticalValue(range - 1, kXp1Percent) && chi_squared < ChiSquaredCriticalValue(range - 1, kXp99Percent); } } // namespace TEST(RandUtilTest, InsecureRandomGeneratorChiSquared) { constexpr int kIterations = 50; // Specifically test the low bits, which are usually weaker in random number // generators. We don't use them for the 32 bit number generation, but let's // make sure they are still suitable. for (int start_bit : {1, 2, 3, 8, 12, 20, 32, 48, 54}) { int pass_count = 0; for (int i = 0; i < kIterations; i++) { size_t samples = 1 << 16; InsecureRandomGenerator gen; // Fix the seed to make the test non-flaky. gen.ReseedForTesting(kIterations + 1); bool pass = ChiSquaredTest(gen, samples, start_bit, 8); pass_count += pass; } // We exclude 1% on each side, so we expect 98% of tests to pass, meaning 98 // * kIterations / 100. However this is asymptotic, so add a bit of leeway. int expected_pass_count = (kIterations * 98) / 100; EXPECT_GE(pass_count, expected_pass_count - ((kIterations * 2) / 100)) << "For start_bit = " << start_bit; } } TEST(RandUtilTest, InsecureRandomGeneratorRandDouble) { InsecureRandomGenerator gen; for (int i = 0; i < 1000; i++) { volatile double x = gen.RandDouble(); EXPECT_GE(x, 0.); EXPECT_LT(x, 1.); } } TEST(RandUtilTest, MetricsSubSampler) { MetricsSubSampler sub_sampler; int true_count = 0; int false_count = 0; for (int i = 0; i < 1000; ++i) { if (sub_sampler.ShouldSample(0.5)) { ++true_count; } else { ++false_count; } } // Validate that during normal operation MetricsSubSampler::ShouldSample() // does not always give the same result. It's technically possible to fail // this test during normal operation but if the sampling is realistic it // should happen about once every 2^999 times (the likelihood of the [1,999] // results being the same as [0], which can be either). This should not make // this test flaky in the eyes of automated testing. EXPECT_GT(true_count, 0); EXPECT_GT(false_count, 0); } TEST(RandUtilTest, MetricsSubSamplerTestingSupport) { MetricsSubSampler sub_sampler; // ScopedAlwaysSampleForTesting makes ShouldSample() return true with // any probability. { MetricsSubSampler::ScopedAlwaysSampleForTesting always_sample; for (int i = 0; i < 100; ++i) { EXPECT_TRUE(sub_sampler.ShouldSample(0)); EXPECT_TRUE(sub_sampler.ShouldSample(0.5)); EXPECT_TRUE(sub_sampler.ShouldSample(1)); } } // ScopedNeverSampleForTesting makes ShouldSample() return true with // any probability. { MetricsSubSampler::ScopedNeverSampleForTesting always_sample; for (int i = 0; i < 100; ++i) { EXPECT_FALSE(sub_sampler.ShouldSample(0)); EXPECT_FALSE(sub_sampler.ShouldSample(0.5)); EXPECT_FALSE(sub_sampler.ShouldSample(1)); } } } } // namespace base