rocksdb/util/ribbon_test.cc

//  Copyright (c) Facebook, Inc. and its affiliates. All Rights Reserved.
//  This source code is licensed under both the GPLv2 (found in the
//  COPYING file in the root directory) and Apache 2.0 License
//  (found in the LICENSE.Apache file in the root directory).

#include <cmath>

#include "test_util/testharness.h"
#include "util/coding.h"
#include "util/hash.h"
#include "util/ribbon_impl.h"

#ifndef GFLAGS
uint32_t FLAGS_thoroughness = 5;
#else
#include "util/gflags_compat.h"
using GFLAGS_NAMESPACE::ParseCommandLineFlags;
// Using 500 is a good test when you have time to be thorough.
// Default is for general RocksDB regression test runs.
DEFINE_uint32(thoroughness, 5, "iterations per configuration");
#endif  // GFLAGS

template <typename TypesAndSettings>
class RibbonTypeParamTest : public ::testing::Test {};

class RibbonTest : public ::testing::Test {};

struct DefaultTypesAndSettings {
  using CoeffRow = ROCKSDB_NAMESPACE::Unsigned128;
  using ResultRow = uint8_t;
  using Index = uint32_t;
  using Hash = uint64_t;
  using Key = ROCKSDB_NAMESPACE::Slice;
  using Seed = uint32_t;
  static constexpr bool kIsFilter = true;
  static constexpr bool kFirstCoeffAlwaysOne = true;
  static constexpr bool kUseSmash = false;
  static Hash HashFn(const Key& key, Seed seed) {
    return ROCKSDB_NAMESPACE::Hash64(key.data(), key.size(), seed);
  }
};

using TypesAndSettings_Coeff128 = DefaultTypesAndSettings;
struct TypesAndSettings_Coeff128Smash : public DefaultTypesAndSettings {
  static constexpr bool kUseSmash = true;
};
struct TypesAndSettings_Coeff64 : public DefaultTypesAndSettings {
  using CoeffRow = uint64_t;
};
struct TypesAndSettings_Coeff64Smash : public DefaultTypesAndSettings {
  using CoeffRow = uint64_t;
  static constexpr bool kUseSmash = true;
};
struct TypesAndSettings_Result16 : public DefaultTypesAndSettings {
  using ResultRow = uint16_t;
};
struct TypesAndSettings_IndexSizeT : public DefaultTypesAndSettings {
  using Index = size_t;
};
struct TypesAndSettings_Hash32 : public DefaultTypesAndSettings {
  using Hash = uint32_t;
  static Hash HashFn(const Key& key, Seed seed) {
    // NOTE: Using RockDB 32-bit Hash() here fails test below because of
    // insufficient mixing of seed (or generally insufficient mixing)
    return ROCKSDB_NAMESPACE::Upper32of64(
        ROCKSDB_NAMESPACE::Hash64(key.data(), key.size(), seed));
  }
};
struct TypesAndSettings_Hash32_Result16 : public TypesAndSettings_Hash32 {
  using ResultRow = uint16_t;
};
struct TypesAndSettings_KeyString : public DefaultTypesAndSettings {
  using Key = std::string;
};
struct TypesAndSettings_Seed8 : public DefaultTypesAndSettings {
  using Seed = uint8_t;
};
struct TypesAndSettings_NoAlwaysOne : public DefaultTypesAndSettings {
  static constexpr bool kFirstCoeffAlwaysOne = false;
};
struct TypesAndSettings_RehasherWrapped : public DefaultTypesAndSettings {
  // This doesn't directly use StandardRehasher as a whole, but simulates
  // its behavior with unseeded hash of key, then seeded hash-to-hash
  // tranform.
  static Hash HashFn(const Key& key, Seed seed) {
    Hash unseeded = DefaultTypesAndSettings::HashFn(key, /*seed*/ 0);
    using Rehasher = ROCKSDB_NAMESPACE::ribbon::StandardRehasherAdapter<
        DefaultTypesAndSettings>;
    return Rehasher::HashFn(unseeded, seed);
  }
};
struct TypesAndSettings_Rehasher32Wrapped : public TypesAndSettings_Hash32 {
  // This doesn't directly use StandardRehasher as a whole, but simulates
  // its behavior with unseeded hash of key, then seeded hash-to-hash
  // tranform.
  static Hash HashFn(const Key& key, Seed seed) {
    Hash unseeded = TypesAndSettings_Hash32::HashFn(key, /*seed*/ 0);
    using Rehasher = ROCKSDB_NAMESPACE::ribbon::StandardRehasherAdapter<
        TypesAndSettings_Hash32>;
    return Rehasher::HashFn(unseeded, seed);
  }
};

using TestTypesAndSettings =
    ::testing::Types<TypesAndSettings_Coeff128, TypesAndSettings_Coeff128Smash,
                     TypesAndSettings_Coeff64, TypesAndSettings_Coeff64Smash,
                     TypesAndSettings_Result16, TypesAndSettings_IndexSizeT,
                     TypesAndSettings_Hash32, TypesAndSettings_Hash32_Result16,
                     TypesAndSettings_KeyString, TypesAndSettings_Seed8,
                     TypesAndSettings_NoAlwaysOne,
                     TypesAndSettings_RehasherWrapped,
                     TypesAndSettings_Rehasher32Wrapped>;
TYPED_TEST_CASE(RibbonTypeParamTest, TestTypesAndSettings);

namespace {

struct KeyGen {
  KeyGen(const std::string& prefix, uint64_t id) : id_(id), str_(prefix) {
    ROCKSDB_NAMESPACE::PutFixed64(&str_, id_);
  }

  // Prefix (only one required)
  KeyGen& operator++() {
    ++id_;
    return *this;
  }

  KeyGen& operator+=(uint64_t incr) {
    id_ += incr;
    return *this;
  }

  const std::string& operator*() {
    // Use multiplication to mix things up a little in the key
    ROCKSDB_NAMESPACE::EncodeFixed64(&str_[str_.size() - 8],
                                     id_ * uint64_t{0x1500000001});
    return str_;
  }

  bool operator==(const KeyGen& other) {
    // Same prefix is assumed
    return id_ == other.id_;
  }
  bool operator!=(const KeyGen& other) {
    // Same prefix is assumed
    return id_ != other.id_;
  }

  uint64_t id_;
  std::string str_;
};

// For testing Poisson-distributed (or similar) statistics, get value for
// `stddevs_allowed` standard deviations above expected mean
// `expected_count`.
// (Poisson approximates Binomial only if probability of a trial being
// in the count is low.)
uint64_t PoissonUpperBound(double expected_count, double stddevs_allowed) {
  return static_cast<uint64_t>(
      expected_count + stddevs_allowed * std::sqrt(expected_count) + 1.0);
}

uint64_t PoissonLowerBound(double expected_count, double stddevs_allowed) {
  return static_cast<uint64_t>(std::max(
      0.0, expected_count - stddevs_allowed * std::sqrt(expected_count)));
}

uint64_t FrequentPoissonUpperBound(double expected_count) {
  // Allow up to 5.0 standard deviations for frequently checked statistics
  return PoissonUpperBound(expected_count, 5.0);
}

uint64_t FrequentPoissonLowerBound(double expected_count) {
  return PoissonLowerBound(expected_count, 5.0);
}

uint64_t InfrequentPoissonUpperBound(double expected_count) {
  // Allow up to 3 standard deviations for infrequently checked statistics
  return PoissonUpperBound(expected_count, 3.0);
}

uint64_t InfrequentPoissonLowerBound(double expected_count) {
  return PoissonLowerBound(expected_count, 3.0);
}

}  // namespace

TYPED_TEST(RibbonTypeParamTest, CompactnessAndBacktrackAndFpRate) {
  IMPORT_RIBBON_TYPES_AND_SETTINGS(TypeParam);
  IMPORT_RIBBON_IMPL_TYPES(TypeParam);

  // For testing FP rate etc.
  constexpr Index kNumToCheck = 100000;
  constexpr size_t kNumSolutionColumns = 8U * sizeof(ResultRow);
  const double expected_fp_count =
      kNumToCheck * std::pow(0.5, kNumSolutionColumns);

  const auto log2_thoroughness =
      static_cast<Seed>(ROCKSDB_NAMESPACE::FloorLog2(FLAGS_thoroughness));
  // FIXME: This upper bound seems excessive
  const Seed max_seed = 12 + log2_thoroughness;

  // With overhead of just 2%, expect ~50% encoding success per
  // seed with ~5k keys on 64-bit ribbon, or ~150k keys on 128-bit ribbon.
  const double kFactor = 1.02;

  uint64_t total_reseeds = 0;
  uint64_t total_single_failures = 0;
  uint64_t total_batch_successes = 0;
  uint64_t total_fp_count = 0;
  uint64_t total_added = 0;

  for (uint32_t i = 0; i < FLAGS_thoroughness; ++i) {
    Index numToAdd =
        sizeof(CoeffRow) == 16 ? 130000 : TypeParam::kUseSmash ? 5000 : 2500;

    // Use different values between that number and 50% of that number
    numToAdd -= (i * 15485863) % (numToAdd / 2);

    total_added += numToAdd;

    const Index kNumSlots = static_cast<Index>(numToAdd * kFactor);

    std::string prefix;
    // Take different samples if you change thoroughness
    ROCKSDB_NAMESPACE::PutFixed32(&prefix,
                                  i + (FLAGS_thoroughness * 123456789U));

    // Batch that must be added
    std::string added_str = prefix + "added";
    KeyGen keys_begin(added_str, 0);
    KeyGen keys_end(added_str, numToAdd);

    // Batch that may or may not be added
    const Index kBatchSize =
        sizeof(CoeffRow) == 16 ? 300 : TypeParam::kUseSmash ? 20 : 10;
    std::string batch_str = prefix + "batch";
    KeyGen batch_begin(batch_str, 0);
    KeyGen batch_end(batch_str, kBatchSize);

    // Batch never (successfully) added, but used for querying FP rate
    std::string not_str = prefix + "not";
    KeyGen other_keys_begin(not_str, 0);
    KeyGen other_keys_end(not_str, kNumToCheck);

    SimpleSoln soln;
    Hasher hasher;
    bool first_single;
    bool second_single;
    bool batch_success;
    {
      Banding banding;
      // Traditional solve for a fixed set.
      ASSERT_TRUE(banding.ResetAndFindSeedToSolve(kNumSlots, keys_begin,
                                                  keys_end, max_seed));

      // Now to test backtracking, starting with guaranteed fail
      Index occupied_count = banding.GetOccupiedCount();
      banding.EnsureBacktrackSize(kNumToCheck);
      ASSERT_FALSE(
          banding.AddRangeOrRollBack(other_keys_begin, other_keys_end));
      ASSERT_EQ(occupied_count, banding.GetOccupiedCount());

      // Check that we still have a good chance of adding a couple more
      // individually
      first_single = banding.Add("one_more");
      second_single = banding.Add("two_more");
      Index more_added = (first_single ? 1 : 0) + (second_single ? 1 : 0);
      total_single_failures += 2U - more_added;

      // Or as a batch
      batch_success = banding.AddRangeOrRollBack(batch_begin, batch_end);
      if (batch_success) {
        more_added += kBatchSize;
        ++total_batch_successes;
      }
      ASSERT_LE(banding.GetOccupiedCount(), occupied_count + more_added);

      // Now back-substitution
      soln.BackSubstFrom(banding);
      Seed seed = banding.GetSeed();
      total_reseeds += seed;
      if (seed > log2_thoroughness + 1) {
        fprintf(stderr, "%s high reseeds at %u, %u: %u\n",
                seed > log2_thoroughness + 8 ? "FIXME Extremely" : "Somewhat",
                static_cast<unsigned>(i), static_cast<unsigned>(numToAdd),
                static_cast<unsigned>(seed));
      }
      hasher.ResetSeed(seed);
    }
    // soln and hasher now independent of Banding object

    // Verify keys added
    KeyGen cur = keys_begin;
    while (cur != keys_end) {
      EXPECT_TRUE(soln.FilterQuery(*cur, hasher));
      ++cur;
    }
    // We (maybe) snuck these in!
    if (first_single) {
      EXPECT_TRUE(soln.FilterQuery("one_more", hasher));
    }
    if (second_single) {
      EXPECT_TRUE(soln.FilterQuery("two_more", hasher));
    }
    if (batch_success) {
      cur = batch_begin;
      while (cur != batch_end) {
        EXPECT_TRUE(soln.FilterQuery(*cur, hasher));
        ++cur;
      }
    }

    // Check FP rate (depends only on number of result bits == solution columns)
    Index fp_count = 0;
    cur = other_keys_begin;
    while (cur != other_keys_end) {
      fp_count += soln.FilterQuery(*cur, hasher) ? 1 : 0;
      ++cur;
    }
    // For expected FP rate, also include false positives due to collisions
    // in Hash value. (Negligible for 64-bit, can matter for 32-bit.)
    double correction =
        1.0 * kNumToCheck * numToAdd / std::pow(256.0, sizeof(Hash));
    EXPECT_LE(fp_count,
              FrequentPoissonUpperBound(expected_fp_count + correction));
    EXPECT_GE(fp_count,
              FrequentPoissonLowerBound(expected_fp_count + correction));

    total_fp_count += fp_count;
  }

  {
    double average_reseeds = 1.0 * total_reseeds / FLAGS_thoroughness;
    fprintf(stderr, "Average re-seeds: %g\n", average_reseeds);
    // Values above were chosen to target around 50% chance of encoding success
    // rate (average of 1.0 re-seeds) or slightly better. But 1.1 is also close
    // enough.
    EXPECT_LE(total_reseeds,
              InfrequentPoissonUpperBound(1.1 * FLAGS_thoroughness));
    EXPECT_GE(total_reseeds,
              InfrequentPoissonLowerBound(0.9 * FLAGS_thoroughness));
  }

  {
    uint64_t total_singles = 2 * FLAGS_thoroughness;
    double single_failure_rate = 1.0 * total_single_failures / total_singles;
    fprintf(stderr, "Add'l single, failure rate: %g\n", single_failure_rate);
    // A rough bound (one sided) based on nothing in particular
    double expected_single_failures =
        1.0 * total_singles /
        (sizeof(CoeffRow) == 16 ? 128 : TypeParam::kUseSmash ? 64 : 32);
    EXPECT_LE(total_single_failures,
              InfrequentPoissonUpperBound(expected_single_failures));
  }

  {
    // Counting successes here for Poisson to approximate the Binomial
    // distribution.
    // A rough bound (one sided) based on nothing in particular.
    double expected_batch_successes = 1.0 * FLAGS_thoroughness / 2;
    uint64_t lower_bound =
        InfrequentPoissonLowerBound(expected_batch_successes);
    fprintf(stderr, "Add'l batch, success rate: %g (>= %g)\n",
            1.0 * total_batch_successes / FLAGS_thoroughness,
            1.0 * lower_bound / FLAGS_thoroughness);
    EXPECT_GE(total_batch_successes, lower_bound);
  }

  {
    uint64_t total_checked = uint64_t{kNumToCheck} * FLAGS_thoroughness;
    double expected_total_fp_count =
        total_checked * std::pow(0.5, kNumSolutionColumns);
    // For expected FP rate, also include false positives due to collisions
    // in Hash value. (Negligible for 64-bit, can matter for 32-bit.)
    expected_total_fp_count += 1.0 * total_checked * total_added /
                               FLAGS_thoroughness /
                               std::pow(256.0, sizeof(Hash));
    uint64_t upper_bound = InfrequentPoissonUpperBound(expected_total_fp_count);
    uint64_t lower_bound = InfrequentPoissonLowerBound(expected_total_fp_count);
    fprintf(stderr, "Average FP rate: %g (~= %g, <= %g, >= %g)\n",
            1.0 * total_fp_count / total_checked,
            expected_total_fp_count / total_checked,
            1.0 * upper_bound / total_checked,
            1.0 * lower_bound / total_checked);
    // FIXME: this can fail for Result16, e.g. --thoroughness=100
    // Seems due to inexpensive hashing in StandardHasher::GetCoeffRow and
    // GetResultRowFromHash as replacing those with different Hash64 instances
    // fixes it, at least mostly.
    EXPECT_LE(total_fp_count, upper_bound);
    EXPECT_GE(total_fp_count, lower_bound);
  }
}

TEST(RibbonTest, Another) {
  IMPORT_RIBBON_TYPES_AND_SETTINGS(DefaultTypesAndSettings);
  IMPORT_RIBBON_IMPL_TYPES(DefaultTypesAndSettings);

  // TODO
}

int main(int argc, char** argv) {
  ::testing::InitGoogleTest(&argc, argv);
#ifdef GFLAGS
  ParseCommandLineFlags(&argc, &argv, true);
#endif  // GFLAGS
  return RUN_ALL_TESTS();
}
Ribbon: initial (general) algorithms and basic unit test (#7491) Summary: This is intended as the first commit toward a near-optimal alternative to static Bloom filters for SSTs. Stephan Walzer and I have agreed upon the name "Ribbon" for a PHSF based on his linear system construction in "Efficient Gauss Elimination for Near-Quadratic Matrices with One Short Random Block per Row, with Applications" ("SGauss") and my much faster "on the fly" algorithm for gaussian elimination (or for this linear system, "banding"), which can be faster than peeling while also more compact and flexible. See util/ribbon_alg.h for more detailed introduction and background. RIBBON = Rapid Incremental Boolean Banding ON-the-fly This commit just adds generic (templatized) core algorithms and a basic unit test showing some features, including the ability to construct structures within 2.5% space overhead vs. information theoretic lower bound. (Compare to cache-local Bloom filter's ~50% space overhead -> ~30% reduction anticipated.) This commit does not include the storage scheme necessary to make queries fast, especially for filter queries, nor fractional "result bits", but there is some description already and those implementations will come soon. Nor does this commit add FilterPolicy support, for use in SST files, but that will also come soon. Pull Request resolved: https://github.com/facebook/rocksdb/pull/7491 Reviewed By: jay-zhuang Differential Revision: D24517954 Pulled By: pdillinger fbshipit-source-id: 0119ee597e250d7e0edd38ada2ba50d755606fa7 4 years ago			`// Copyright (c) Facebook, Inc. and its affiliates. All Rights Reserved.`
			`// This source code is licensed under both the GPLv2 (found in the`
			`// COPYING file in the root directory) and Apache 2.0 License`
			`// (found in the LICENSE.Apache file in the root directory).`

			`#include <cmath>`

			`#include "test_util/testharness.h"`
			`#include "util/coding.h"`
			`#include "util/hash.h"`
			`#include "util/ribbon_impl.h"`

			`#ifndef GFLAGS`
			`uint32_t FLAGS_thoroughness = 5;`
			`#else`
			`#include "util/gflags_compat.h"`
			`using GFLAGS_NAMESPACE::ParseCommandLineFlags;`
			`// Using 500 is a good test when you have time to be thorough.`
			`// Default is for general RocksDB regression test runs.`
			`DEFINE_uint32(thoroughness, 5, "iterations per configuration");`
			`#endif // GFLAGS`

			`template <typename TypesAndSettings>`
			`class RibbonTypeParamTest : public ::testing::Test {};`

			`class RibbonTest : public ::testing::Test {};`

			`struct DefaultTypesAndSettings {`
			`using CoeffRow = ROCKSDB_NAMESPACE::Unsigned128;`
			`using ResultRow = uint8_t;`
			`using Index = uint32_t;`
			`using Hash = uint64_t;`
			`using Key = ROCKSDB_NAMESPACE::Slice;`
			`using Seed = uint32_t;`
			`static constexpr bool kIsFilter = true;`
			`static constexpr bool kFirstCoeffAlwaysOne = true;`
			`static constexpr bool kUseSmash = false;`
			`static Hash HashFn(const Key& key, Seed seed) {`
			`return ROCKSDB_NAMESPACE::Hash64(key.data(), key.size(), seed);`
			`}`
			`};`

			`using TypesAndSettings_Coeff128 = DefaultTypesAndSettings;`
			`struct TypesAndSettings_Coeff128Smash : public DefaultTypesAndSettings {`
			`static constexpr bool kUseSmash = true;`
			`};`
			`struct TypesAndSettings_Coeff64 : public DefaultTypesAndSettings {`
			`using CoeffRow = uint64_t;`
			`};`
			`struct TypesAndSettings_Coeff64Smash : public DefaultTypesAndSettings {`
			`using CoeffRow = uint64_t;`
			`static constexpr bool kUseSmash = true;`
			`};`
			`struct TypesAndSettings_Result16 : public DefaultTypesAndSettings {`
			`using ResultRow = uint16_t;`
			`};`
			`struct TypesAndSettings_IndexSizeT : public DefaultTypesAndSettings {`
			`using Index = size_t;`
			`};`
			`struct TypesAndSettings_Hash32 : public DefaultTypesAndSettings {`
			`using Hash = uint32_t;`
			`static Hash HashFn(const Key& key, Seed seed) {`
			`// NOTE: Using RockDB 32-bit Hash() here fails test below because of`
			`// insufficient mixing of seed (or generally insufficient mixing)`
			`return ROCKSDB_NAMESPACE::Upper32of64(`
			`ROCKSDB_NAMESPACE::Hash64(key.data(), key.size(), seed));`
			`}`
			`};`
			`struct TypesAndSettings_Hash32_Result16 : public TypesAndSettings_Hash32 {`
			`using ResultRow = uint16_t;`
			`};`
			`struct TypesAndSettings_KeyString : public DefaultTypesAndSettings {`
			`using Key = std::string;`
			`};`
			`struct TypesAndSettings_Seed8 : public DefaultTypesAndSettings {`
			`using Seed = uint8_t;`
			`};`
			`struct TypesAndSettings_NoAlwaysOne : public DefaultTypesAndSettings {`
			`static constexpr bool kFirstCoeffAlwaysOne = false;`
			`};`
			`struct TypesAndSettings_RehasherWrapped : public DefaultTypesAndSettings {`
			`// This doesn't directly use StandardRehasher as a whole, but simulates`
			`// its behavior with unseeded hash of key, then seeded hash-to-hash`
			`// tranform.`
			`static Hash HashFn(const Key& key, Seed seed) {`
			`Hash unseeded = DefaultTypesAndSettings::HashFn(key, /seed/ 0);`
			`using Rehasher = ROCKSDB_NAMESPACE::ribbon::StandardRehasherAdapter<`
			`DefaultTypesAndSettings>;`
			`return Rehasher::HashFn(unseeded, seed);`
			`}`
			`};`
			`struct TypesAndSettings_Rehasher32Wrapped : public TypesAndSettings_Hash32 {`
			`// This doesn't directly use StandardRehasher as a whole, but simulates`
			`// its behavior with unseeded hash of key, then seeded hash-to-hash`
			`// tranform.`
			`static Hash HashFn(const Key& key, Seed seed) {`
			`Hash unseeded = TypesAndSettings_Hash32::HashFn(key, /seed/ 0);`
			`using Rehasher = ROCKSDB_NAMESPACE::ribbon::StandardRehasherAdapter<`
			`TypesAndSettings_Hash32>;`
			`return Rehasher::HashFn(unseeded, seed);`
			`}`
			`};`

			`using TestTypesAndSettings =`
			`::testing::Types<TypesAndSettings_Coeff128, TypesAndSettings_Coeff128Smash,`
			`TypesAndSettings_Coeff64, TypesAndSettings_Coeff64Smash,`
			`TypesAndSettings_Result16, TypesAndSettings_IndexSizeT,`
			`TypesAndSettings_Hash32, TypesAndSettings_Hash32_Result16,`
			`TypesAndSettings_KeyString, TypesAndSettings_Seed8,`
			`TypesAndSettings_NoAlwaysOne,`
			`TypesAndSettings_RehasherWrapped,`
			`TypesAndSettings_Rehasher32Wrapped>;`
			`TYPED_TEST_CASE(RibbonTypeParamTest, TestTypesAndSettings);`

			`namespace {`

			`struct KeyGen {`
			`KeyGen(const std::string& prefix, uint64_t id) : id_(id), str_(prefix) {`
			`ROCKSDB_NAMESPACE::PutFixed64(&str_, id_);`
			`}`

			`// Prefix (only one required)`
			`KeyGen& operator++() {`
			`++id_;`
			`return *this;`
			`}`

			`KeyGen& operator+=(uint64_t incr) {`
			`id_ += incr;`
			`return *this;`
			`}`

			`const std::string& operator*() {`
			`// Use multiplication to mix things up a little in the key`
			`ROCKSDB_NAMESPACE::EncodeFixed64(&str_[str_.size() - 8],`
			`id_ * uint64_t{0x1500000001});`
			`return str_;`
			`}`

			`bool operator==(const KeyGen& other) {`
			`// Same prefix is assumed`
			`return id_ == other.id_;`
			`}`
			`bool operator!=(const KeyGen& other) {`
			`// Same prefix is assumed`
			`return id_ != other.id_;`
			`}`

			`uint64_t id_;`
			`std::string str_;`
			`};`

			`// For testing Poisson-distributed (or similar) statistics, get value for`
			// `stddevs_allowed` standard deviations above expected mean
			// `expected_count`.
			`// (Poisson approximates Binomial only if probability of a trial being`
			`// in the count is low.)`
			`uint64_t PoissonUpperBound(double expected_count, double stddevs_allowed) {`
			`return static_cast<uint64_t>(`
			`expected_count + stddevs_allowed * std::sqrt(expected_count) + 1.0);`
			`}`

			`uint64_t PoissonLowerBound(double expected_count, double stddevs_allowed) {`
			`return static_cast<uint64_t>(std::max(`
			`0.0, expected_count - stddevs_allowed * std::sqrt(expected_count)));`
			`}`

			`uint64_t FrequentPoissonUpperBound(double expected_count) {`
			`// Allow up to 5.0 standard deviations for frequently checked statistics`
			`return PoissonUpperBound(expected_count, 5.0);`
			`}`

			`uint64_t FrequentPoissonLowerBound(double expected_count) {`
			`return PoissonLowerBound(expected_count, 5.0);`
			`}`

			`uint64_t InfrequentPoissonUpperBound(double expected_count) {`
			`// Allow up to 3 standard deviations for infrequently checked statistics`
			`return PoissonUpperBound(expected_count, 3.0);`
			`}`

			`uint64_t InfrequentPoissonLowerBound(double expected_count) {`
			`return PoissonLowerBound(expected_count, 3.0);`
			`}`

			`} // namespace`

			`TYPED_TEST(RibbonTypeParamTest, CompactnessAndBacktrackAndFpRate) {`
			`IMPORT_RIBBON_TYPES_AND_SETTINGS(TypeParam);`
			`IMPORT_RIBBON_IMPL_TYPES(TypeParam);`

			`// For testing FP rate etc.`
			`constexpr Index kNumToCheck = 100000;`
			`constexpr size_t kNumSolutionColumns = 8U * sizeof(ResultRow);`
			`const double expected_fp_count =`
			`kNumToCheck * std::pow(0.5, kNumSolutionColumns);`

			`const auto log2_thoroughness =`
			`static_cast<Seed>(ROCKSDB_NAMESPACE::FloorLog2(FLAGS_thoroughness));`
			`// FIXME: This upper bound seems excessive`
			`const Seed max_seed = 12 + log2_thoroughness;`

			`// With overhead of just 2%, expect ~50% encoding success per`
			`// seed with ~5k keys on 64-bit ribbon, or ~150k keys on 128-bit ribbon.`
			`const double kFactor = 1.02;`

			`uint64_t total_reseeds = 0;`
			`uint64_t total_single_failures = 0;`
			`uint64_t total_batch_successes = 0;`
			`uint64_t total_fp_count = 0;`
			`uint64_t total_added = 0;`

			`for (uint32_t i = 0; i < FLAGS_thoroughness; ++i) {`
			`Index numToAdd =`
			`sizeof(CoeffRow) == 16 ? 130000 : TypeParam::kUseSmash ? 5000 : 2500;`

			`// Use different values between that number and 50% of that number`
			`numToAdd -= (i * 15485863) % (numToAdd / 2);`

			`total_added += numToAdd;`

			`const Index kNumSlots = static_cast<Index>(numToAdd * kFactor);`

			`std::string prefix;`
			`// Take different samples if you change thoroughness`
			`ROCKSDB_NAMESPACE::PutFixed32(&prefix,`
			`i + (FLAGS_thoroughness * 123456789U));`

			`// Batch that must be added`
			`std::string added_str = prefix + "added";`
			`KeyGen keys_begin(added_str, 0);`
			`KeyGen keys_end(added_str, numToAdd);`

			`// Batch that may or may not be added`
			`const Index kBatchSize =`
			`sizeof(CoeffRow) == 16 ? 300 : TypeParam::kUseSmash ? 20 : 10;`
			`std::string batch_str = prefix + "batch";`
			`KeyGen batch_begin(batch_str, 0);`
			`KeyGen batch_end(batch_str, kBatchSize);`

			`// Batch never (successfully) added, but used for querying FP rate`
			`std::string not_str = prefix + "not";`
			`KeyGen other_keys_begin(not_str, 0);`
			`KeyGen other_keys_end(not_str, kNumToCheck);`

			`SimpleSoln soln;`
			`Hasher hasher;`
			`bool first_single;`
			`bool second_single;`
			`bool batch_success;`
			`{`
			`Banding banding;`
			`// Traditional solve for a fixed set.`
			`ASSERT_TRUE(banding.ResetAndFindSeedToSolve(kNumSlots, keys_begin,`
			`keys_end, max_seed));`

			`// Now to test backtracking, starting with guaranteed fail`
			`Index occupied_count = banding.GetOccupiedCount();`
			`banding.EnsureBacktrackSize(kNumToCheck);`
			`ASSERT_FALSE(`
			`banding.AddRangeOrRollBack(other_keys_begin, other_keys_end));`
			`ASSERT_EQ(occupied_count, banding.GetOccupiedCount());`

			`// Check that we still have a good chance of adding a couple more`
			`// individually`
			`first_single = banding.Add("one_more");`
			`second_single = banding.Add("two_more");`
			`Index more_added = (first_single ? 1 : 0) + (second_single ? 1 : 0);`
			`total_single_failures += 2U - more_added;`

			`// Or as a batch`
			`batch_success = banding.AddRangeOrRollBack(batch_begin, batch_end);`
			`if (batch_success) {`
			`more_added += kBatchSize;`
			`++total_batch_successes;`
			`}`
			`ASSERT_LE(banding.GetOccupiedCount(), occupied_count + more_added);`

			`// Now back-substitution`
			`soln.BackSubstFrom(banding);`
			`Seed seed = banding.GetSeed();`
			`total_reseeds += seed;`
			`if (seed > log2_thoroughness + 1) {`
			`fprintf(stderr, "%s high reseeds at %u, %u: %u\n",`
			`seed > log2_thoroughness + 8 ? "FIXME Extremely" : "Somewhat",`
			`static_cast<unsigned>(i), static_cast<unsigned>(numToAdd),`
			`static_cast<unsigned>(seed));`
			`}`
			`hasher.ResetSeed(seed);`
			`}`
			`// soln and hasher now independent of Banding object`

			`// Verify keys added`
			`KeyGen cur = keys_begin;`
			`while (cur != keys_end) {`
			`EXPECT_TRUE(soln.FilterQuery(*cur, hasher));`
			`++cur;`
			`}`
			`// We (maybe) snuck these in!`
			`if (first_single) {`
			`EXPECT_TRUE(soln.FilterQuery("one_more", hasher));`
			`}`
			`if (second_single) {`
			`EXPECT_TRUE(soln.FilterQuery("two_more", hasher));`
			`}`
			`if (batch_success) {`
			`cur = batch_begin;`
			`while (cur != batch_end) {`
			`EXPECT_TRUE(soln.FilterQuery(*cur, hasher));`
			`++cur;`
			`}`
			`}`

			`// Check FP rate (depends only on number of result bits == solution columns)`
			`Index fp_count = 0;`
			`cur = other_keys_begin;`
			`while (cur != other_keys_end) {`
			`fp_count += soln.FilterQuery(*cur, hasher) ? 1 : 0;`
			`++cur;`
			`}`
			`// For expected FP rate, also include false positives due to collisions`
			`// in Hash value. (Negligible for 64-bit, can matter for 32-bit.)`
			`double correction =`
			`1.0 * kNumToCheck * numToAdd / std::pow(256.0, sizeof(Hash));`
			`EXPECT_LE(fp_count,`
			`FrequentPoissonUpperBound(expected_fp_count + correction));`
			`EXPECT_GE(fp_count,`
			`FrequentPoissonLowerBound(expected_fp_count + correction));`

			`total_fp_count += fp_count;`
			`}`

			`{`
			`double average_reseeds = 1.0 * total_reseeds / FLAGS_thoroughness;`
			`fprintf(stderr, "Average re-seeds: %g\n", average_reseeds);`
			`// Values above were chosen to target around 50% chance of encoding success`
			`// rate (average of 1.0 re-seeds) or slightly better. But 1.1 is also close`
			`// enough.`
			`EXPECT_LE(total_reseeds,`
			`InfrequentPoissonUpperBound(1.1 * FLAGS_thoroughness));`
			`EXPECT_GE(total_reseeds,`
			`InfrequentPoissonLowerBound(0.9 * FLAGS_thoroughness));`
			`}`

			`{`
			`uint64_t total_singles = 2 * FLAGS_thoroughness;`
			`double single_failure_rate = 1.0 * total_single_failures / total_singles;`
			`fprintf(stderr, "Add'l single, failure rate: %g\n", single_failure_rate);`
			`// A rough bound (one sided) based on nothing in particular`
			`double expected_single_failures =`
			`1.0 * total_singles /`
			`(sizeof(CoeffRow) == 16 ? 128 : TypeParam::kUseSmash ? 64 : 32);`
			`EXPECT_LE(total_single_failures,`
			`InfrequentPoissonUpperBound(expected_single_failures));`
			`}`

			`{`
			`// Counting successes here for Poisson to approximate the Binomial`
			`// distribution.`
			`// A rough bound (one sided) based on nothing in particular.`
			`double expected_batch_successes = 1.0 * FLAGS_thoroughness / 2;`
			`uint64_t lower_bound =`
			`InfrequentPoissonLowerBound(expected_batch_successes);`
			`fprintf(stderr, "Add'l batch, success rate: %g (>= %g)\n",`
			`1.0 * total_batch_successes / FLAGS_thoroughness,`
			`1.0 * lower_bound / FLAGS_thoroughness);`
			`EXPECT_GE(total_batch_successes, lower_bound);`
			`}`

			`{`
			`uint64_t total_checked = uint64_t{kNumToCheck} * FLAGS_thoroughness;`
			`double expected_total_fp_count =`
			`total_checked * std::pow(0.5, kNumSolutionColumns);`
			`// For expected FP rate, also include false positives due to collisions`
			`// in Hash value. (Negligible for 64-bit, can matter for 32-bit.)`
			`expected_total_fp_count += 1.0 * total_checked * total_added /`
			`FLAGS_thoroughness /`
			`std::pow(256.0, sizeof(Hash));`
			`uint64_t upper_bound = InfrequentPoissonUpperBound(expected_total_fp_count);`
			`uint64_t lower_bound = InfrequentPoissonLowerBound(expected_total_fp_count);`
			`fprintf(stderr, "Average FP rate: %g (~= %g, <= %g, >= %g)\n",`
			`1.0 * total_fp_count / total_checked,`
			`expected_total_fp_count / total_checked,`
			`1.0 * upper_bound / total_checked,`
			`1.0 * lower_bound / total_checked);`
			`// FIXME: this can fail for Result16, e.g. --thoroughness=100`
			`// Seems due to inexpensive hashing in StandardHasher::GetCoeffRow and`
			`// GetResultRowFromHash as replacing those with different Hash64 instances`
			`// fixes it, at least mostly.`
			`EXPECT_LE(total_fp_count, upper_bound);`
			`EXPECT_GE(total_fp_count, lower_bound);`
			`}`
			`}`

			`TEST(RibbonTest, Another) {`
			`IMPORT_RIBBON_TYPES_AND_SETTINGS(DefaultTypesAndSettings);`
			`IMPORT_RIBBON_IMPL_TYPES(DefaultTypesAndSettings);`

			`// TODO`
			`}`

			`int main(int argc, char** argv) {`
			`::testing::InitGoogleTest(&argc, argv);`
			`#ifdef GFLAGS`
			`ParseCommandLineFlags(&argc, &argv, true);`
			`#endif // GFLAGS`
			`return RUN_ALL_TESTS();`
			`}`