pw_kvs/key_value_store_test.cc - pigweed/pigweed - Git at Google

 // Copyright 2020 The Pigweed Authors
 //
 // 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
 //
 //     https://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.

 #define DUMP_KVS_STATE_TO_FILE 0
 #define USE_MEMORY_BUFFER 1

 #include "pw_kvs/key_value_store.h"

 #include <array>
 #include <cstdio>
 #include <cstring>
 #include <span>

 #if DUMP_KVS_STATE_TO_FILE
 #include <vector>
 #endif  // DUMP_KVS_STATE_TO_FILE

 #include "gtest/gtest.h"
 #include "pw_bytes/array.h"
 #include "pw_checksum/crc16_ccitt.h"
 #include "pw_kvs/crc16_checksum.h"
 #include "pw_kvs/fake_flash_memory.h"
 #include "pw_kvs/flash_memory.h"
 #include "pw_kvs/internal/entry.h"
 #include "pw_log/log.h"
 #include "pw_log/shorter.h"
 #include "pw_status/status.h"
 #include "pw_string/string_builder.h"

 namespace pw::kvs {
 namespace {

 using internal::EntryHeader;

 constexpr size_t kMaxEntries = 256;
 constexpr size_t kMaxUsableSectors = 256;

 // This is a self contained flash unit with both memory and a single partition.
 template <uint32_t kSectorSizeBytes, uint16_t kSectorCount>
 struct FlashWithPartitionFake {
   // Default to 16 byte alignment, which is common in practice.
   FlashWithPartitionFake() : FlashWithPartitionFake(16) {}
   FlashWithPartitionFake(size_t alignment_bytes)
       : memory(alignment_bytes), partition(&memory, 0, memory.sector_count()) {}

   FakeFlashMemoryBuffer<kSectorSizeBytes, kSectorCount> memory;
   FlashPartition partition;

  public:
 #if DUMP_KVS_STATE_TO_FILE
   Status Dump(const char* filename) {
     std::FILE* out_file = std::fopen(filename, "w+");
     if (out_file == nullptr) {
       PW_LOG_ERROR("Failed to dump to %s", filename);
       return Status::DataLoss();
     }
     std::vector<std::byte> out_vec(memory.size_bytes());
     Status status =
         memory.Read(0, std::span<std::byte>(out_vec.data(), out_vec.size()));
     if (status != OkStatus()) {
       fclose(out_file);
       return status;
     }

     size_t written =
         std::fwrite(out_vec.data(), 1, memory.size_bytes(), out_file);
     if (written != memory.size_bytes()) {
       PW_LOG_ERROR("Failed to dump to %s, written=%u",
                    filename,
                    static_cast<unsigned>(written));
       status = Status::DataLoss();
     } else {
       PW_LOG_INFO("Dumped to %s", filename);
       status = OkStatus();
     }

     fclose(out_file);
     return status;
   }
 #else
   Status Dump(const char*) { return OkStatus(); }
 #endif  // DUMP_KVS_STATE_TO_FILE
 };

 typedef FlashWithPartitionFake<4 * 128 /*sector size*/, 6 /*sectors*/> Flash;

 FakeFlashMemoryBuffer<1024, 60> large_test_flash(8);
 FlashPartition large_test_partition(&large_test_flash,
                                     0,
                                     large_test_flash.sector_count());

 constexpr std::array<const char*, 3> keys{"TestKey1", "Key2", "TestKey3"};

 ChecksumCrc16 checksum;
 // For KVS magic value always use a random 32 bit integer rather than a
 // human readable 4 bytes. See pw_kvs/format.h for more information.
 constexpr EntryFormat default_format{.magic = 0xa6cb3c16,
                                      .checksum = &checksum};

 }  // namespace

 TEST(InitCheck, TooFewSectors) {
   // Use test flash with 1 x 4k sectors, 16 byte alignment
   FakeFlashMemoryBuffer<4 * 1024, 1> test_flash(16);
   FlashPartition test_partition(&test_flash, 0, test_flash.sector_count());

   // For KVS magic value always use a random 32 bit integer rather than a
   // human readable 4 bytes. See pw_kvs/format.h for more information.
   constexpr EntryFormat format{.magic = 0x89bb14d2, .checksum = nullptr};
   KeyValueStoreBuffer<kMaxEntries, kMaxUsableSectors> kvs(&test_partition,
                                                           format);

   EXPECT_EQ(kvs.Init(), Status::FailedPrecondition());
 }

 TEST(InitCheck, ZeroSectors) {
   // Use test flash with 1 x 4k sectors, 16 byte alignment
   FakeFlashMemoryBuffer<4 * 1024, 1> test_flash(16);

   // Set FlashPartition to have 0 sectors.
   FlashPartition test_partition(&test_flash, 0, 0);

   // For KVS magic value always use a random 32 bit integer rather than a
   // human readable 4 bytes. See pw_kvs/format.h for more information.
   constexpr EntryFormat format{.magic = 0xd1da57c1, .checksum = nullptr};
   KeyValueStoreBuffer<kMaxEntries, kMaxUsableSectors> kvs(&test_partition,
                                                           format);

   EXPECT_EQ(kvs.Init(), Status::FailedPrecondition());
 }

 TEST(InitCheck, TooManySectors) {
   // Use test flash with 1 x 4k sectors, 16 byte alignment
   FakeFlashMemoryBuffer<4 * 1024, 5> test_flash(16);

   // Set FlashPartition to have 0 sectors.
   FlashPartition test_partition(&test_flash, 0, test_flash.sector_count());

   // For KVS magic value always use a random 32 bit integer rather than a
   // human readable 4 bytes. See pw_kvs/format.h for more information.
   constexpr EntryFormat format{.magic = 0x610f6d17, .checksum = nullptr};
   KeyValueStoreBuffer<kMaxEntries, 2> kvs(&test_partition, format);

   EXPECT_EQ(kvs.Init(), Status::FailedPrecondition());
 }

 #define ASSERT_OK(expr) ASSERT_EQ(OkStatus(), expr)
 #define EXPECT_OK(expr) EXPECT_EQ(OkStatus(), expr)

 TEST(InMemoryKvs, WriteOneKeyMultipleTimes) {
   // Create and erase the fake flash. It will persist across reloads.
   Flash flash;
   ASSERT_OK(flash.partition.Erase());

   int num_reloads = 2;
   for (int reload = 0; reload < num_reloads; ++reload) {
     DBG("xxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxx");
     DBG("xxx                                      xxxx");
     DBG("xxx               Reload %2d              xxxx", reload);
     DBG("xxx                                      xxxx");
     DBG("xxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxx");

     // Create and initialize the KVS. For KVS magic value always use a random 32
     // bit integer rather than a human readable 4 bytes. See pw_kvs/format.h for
     // more information.
     constexpr EntryFormat format{.magic = 0x83a9257, .checksum = nullptr};
     KeyValueStoreBuffer<kMaxEntries, kMaxUsableSectors> kvs(&flash.partition,
                                                             format);
     ASSERT_OK(kvs.Init());

     // Write the same entry many times.
     const char* key = "abcd";
     const size_t num_writes = 99;
     uint32_t written_value;
     EXPECT_EQ(kvs.size(), (reload == 0) ? 0 : 1u);
     for (uint32_t i = 0; i < num_writes; ++i) {
       DBG("PUT #%zu for key %s with value %zu", size_t(i), key, size_t(i));

       written_value = i + 0xfc;  // Prevent accidental pass with zero.
       EXPECT_OK(kvs.Put(key, written_value));
       EXPECT_EQ(kvs.size(), 1u);
     }

     // Verify that we can read the value back.
     DBG("GET final value for key: %s", key);
     uint32_t actual_value;
     EXPECT_OK(kvs.Get(key, &actual_value));
     EXPECT_EQ(actual_value, written_value);

     char fname_buf[64] = {'\0'};
     snprintf(&fname_buf[0],
              sizeof(fname_buf),
              "WriteOneKeyMultipleTimes_%d.bin",
              reload);
     flash.Dump(fname_buf)
         .IgnoreError();  // TODO(pwbug/387): Handle Status properly
   }
 }

 TEST(InMemoryKvs, WritingMultipleKeysIncreasesSize) {
   // Create and erase the fake flash.
   Flash flash;
   ASSERT_OK(flash.partition.Erase());

   // Create and initialize the KVS. For KVS magic value always use a random 32
   // bit integer rather than a human readable 4 bytes. See pw_kvs/format.h for
   // more information.
   constexpr EntryFormat format{.magic = 0x2ed3a058, .checksum = nullptr};
   KeyValueStoreBuffer<kMaxEntries, kMaxUsableSectors> kvs(&flash.partition,
                                                           format);
   ASSERT_OK(kvs.Init());

   // Write the same entry many times.
   const size_t num_writes = 10;
   EXPECT_EQ(kvs.size(), 0u);
   for (size_t i = 0; i < num_writes; ++i) {
     StringBuffer<150> key;
     key << "key_" << i;
     DBG("PUT #%zu for key %s with value %zu", i, key.c_str(), i);

     size_t value = i + 77;  // Prevent accidental pass with zero.
     EXPECT_OK(kvs.Put(key.view(), value));
     EXPECT_EQ(kvs.size(), i + 1);
   }
   flash.Dump("WritingMultipleKeysIncreasesSize.bin")
       .IgnoreError();  // TODO(pwbug/387): Handle Status properly
 }

 TEST(InMemoryKvs, WriteAndReadOneKey) {
   // Create and erase the fake flash.
   Flash flash;
   ASSERT_OK(flash.partition.Erase());

   // Create and initialize the KVS.
   // For KVS magic value always use a random 32 bit integer rather than a
   // human readable 4 bytes. See pw_kvs/format.h for more information.
   constexpr EntryFormat format{.magic = 0x5d70896, .checksum = nullptr};
   KeyValueStoreBuffer<kMaxEntries, kMaxUsableSectors> kvs(&flash.partition,
                                                           format);
   ASSERT_OK(kvs.Init());

   // Add one entry.
   const char* key = "Key1";
   DBG("PUT value for key: %s", key);
   uint8_t written_value = 0xDA;
   ASSERT_OK(kvs.Put(key, written_value));
   EXPECT_EQ(kvs.size(), 1u);

   DBG("GET value for key: %s", key);
   uint8_t actual_value;
   ASSERT_OK(kvs.Get(key, &actual_value));
   EXPECT_EQ(actual_value, written_value);

   EXPECT_EQ(kvs.size(), 1u);
 }

 TEST(InMemoryKvs, WriteOneKeyValueMultipleTimes) {
   // Create and erase the fake flash.
   Flash flash;
   ASSERT_OK(flash.partition.Erase());

   // Create and initialize the KVS.
   KeyValueStoreBuffer<kMaxEntries, kMaxUsableSectors> kvs(&flash.partition,
                                                           default_format);
   ASSERT_OK(kvs.Init());

   // Add one entry, with the same key and value, multiple times.
   const char* key = "Key1";
   uint8_t written_value = 0xDA;
   for (int i = 0; i < 50; i++) {
     DBG("PUT [%d] value for key: %s", i, key);
     ASSERT_OK(kvs.Put(key, written_value));
     EXPECT_EQ(kvs.size(), 1u);
   }

   DBG("GET value for key: %s", key);
   uint8_t actual_value;
   ASSERT_OK(kvs.Get(key, &actual_value));
   EXPECT_EQ(actual_value, written_value);

   // Verify that only one entry was written to the KVS.
   EXPECT_EQ(kvs.size(), 1u);
   EXPECT_EQ(kvs.transaction_count(), 1u);
   KeyValueStore::StorageStats stats = kvs.GetStorageStats();
   EXPECT_EQ(stats.reclaimable_bytes, 0u);
 }

 TEST(InMemoryKvs, Basic) {
   const char* key1 = "Key1";
   const char* key2 = "Key2";

   // Create and erase the fake flash.
   Flash flash;
   ASSERT_EQ(OkStatus(), flash.partition.Erase());

   // Create and initialize the KVS.
   // For KVS magic value always use a random 32 bit integer rather than a
   // human readable 4 bytes. See pw_kvs/format.h for more information.
   constexpr EntryFormat format{.magic = 0x7bf19895, .checksum = nullptr};
   KeyValueStoreBuffer<kMaxEntries, kMaxUsableSectors> kvs(&flash.partition,
                                                           format);
   ASSERT_OK(kvs.Init());

   // Add two entries with different keys and values.
   uint8_t value1 = 0xDA;
   ASSERT_OK(kvs.Put(key1, std::as_bytes(std::span(&value1, sizeof(value1)))));
   EXPECT_EQ(kvs.size(), 1u);

   uint32_t value2 = 0xBAD0301f;
   ASSERT_OK(kvs.Put(key2, value2));
   EXPECT_EQ(kvs.size(), 2u);

   // Verify data
   uint32_t test2;
   EXPECT_OK(kvs.Get(key2, &test2));

   uint8_t test1;
   ASSERT_OK(kvs.Get(key1, &test1));

   EXPECT_EQ(test1, value1);
   EXPECT_EQ(test2, value2);

   EXPECT_EQ(kvs.size(), 2u);
 }

 TEST(InMemoryKvs, CallingEraseTwice_NothingWrittenToFlash) {
   // Create and erase the fake flash.
   Flash flash;
   ASSERT_EQ(OkStatus(), flash.partition.Erase());

   // Create and initialize the KVS.
   KeyValueStoreBuffer<kMaxEntries, kMaxUsableSectors> kvs(&flash.partition,
                                                           default_format);
   ASSERT_OK(kvs.Init());

   const uint8_t kValue = 0xDA;
   ASSERT_EQ(OkStatus(), kvs.Put(keys[0], kValue));
   ASSERT_EQ(OkStatus(), kvs.Delete(keys[0]));

   // Compare before / after checksums to verify that nothing was written.
   const uint16_t crc = checksum::Crc16Ccitt::Calculate(flash.memory.buffer());

   EXPECT_EQ(kvs.Delete(keys[0]), Status::NotFound());

   EXPECT_EQ(crc, checksum::Crc16Ccitt::Calculate(flash.memory.buffer()));
 }

 class LargeEmptyInitializedKvs : public ::testing::Test {
  protected:
   LargeEmptyInitializedKvs() : kvs_(&large_test_partition, default_format) {
     ASSERT_EQ(OkStatus(), large_test_partition.Erase());
     ASSERT_EQ(OkStatus(), kvs_.Init());
   }

   KeyValueStoreBuffer<kMaxEntries, kMaxUsableSectors> kvs_;
 };

 TEST_F(LargeEmptyInitializedKvs, Basic) {
   const uint8_t kValue1 = 0xDA;
   const uint8_t kValue2 = 0x12;
   uint8_t value;
   ASSERT_EQ(OkStatus(), kvs_.Put(keys[0], kValue1));
   EXPECT_EQ(kvs_.size(), 1u);
   ASSERT_EQ(OkStatus(), kvs_.Delete(keys[0]));
   EXPECT_EQ(kvs_.Get(keys[0], &value), Status::NotFound());
   ASSERT_EQ(OkStatus(), kvs_.Put(keys[1], kValue1));
   ASSERT_EQ(OkStatus(), kvs_.Put(keys[2], kValue2));
   ASSERT_EQ(OkStatus(), kvs_.Delete(keys[1]));
   EXPECT_EQ(OkStatus(), kvs_.Get(keys[2], &value));
   EXPECT_EQ(kValue2, value);
   ASSERT_EQ(kvs_.Get(keys[1], &value), Status::NotFound());
   EXPECT_EQ(kvs_.size(), 1u);
 }

 TEST_F(LargeEmptyInitializedKvs, FullMaintenance) {
   const uint8_t kValue1 = 0xDA;
   const uint8_t kValue2 = 0x12;

   // Write a key and write again with a different value, resulting in a stale
   // entry from the first write.
   ASSERT_EQ(OkStatus(), kvs_.Put(keys[0], kValue1));
   ASSERT_EQ(OkStatus(), kvs_.Put(keys[0], kValue2));
   EXPECT_EQ(kvs_.size(), 1u);

   KeyValueStore::StorageStats stats = kvs_.GetStorageStats();
   EXPECT_EQ(stats.sector_erase_count, 0u);
   EXPECT_GT(stats.reclaimable_bytes, 0u);

   // Do regular FullMaintenance, which should not touch the sector with valid
   // data.
   EXPECT_EQ(OkStatus(), kvs_.FullMaintenance());
   stats = kvs_.GetStorageStats();
   EXPECT_EQ(stats.sector_erase_count, 0u);
   EXPECT_GT(stats.reclaimable_bytes, 0u);

   // Do aggressive FullMaintenance, which should GC the sector with valid data,
   // resulting in no reclaimable bytes and an erased sector.
   EXPECT_EQ(OkStatus(), kvs_.HeavyMaintenance());
   stats = kvs_.GetStorageStats();
   EXPECT_EQ(stats.sector_erase_count, 1u);
   EXPECT_EQ(stats.reclaimable_bytes, 0u);
 }

 TEST(InMemoryKvs, Put_MaxValueSize) {
   // Create and erase the fake flash.
   Flash flash;
   ASSERT_EQ(OkStatus(), flash.partition.Erase());

   // Create and initialize the KVS.
   KeyValueStoreBuffer<kMaxEntries, kMaxUsableSectors> kvs(&flash.partition,
                                                           default_format);
   ASSERT_OK(kvs.Init());

   size_t max_key_value_size = kvs.max_key_value_size_bytes();
   EXPECT_EQ(max_key_value_size,
             KeyValueStore::max_key_value_size_bytes(
                 flash.partition.sector_size_bytes()));

   size_t max_value_size =
       flash.partition.sector_size_bytes() - sizeof(EntryHeader) - 1;
   EXPECT_EQ(max_key_value_size, (max_value_size + 1));

   // Use the large_test_flash as a big chunk of data for the Put statement.
   ASSERT_GT(sizeof(large_test_flash), max_value_size + 2 * sizeof(EntryHeader));
   auto big_data = std::as_bytes(std::span(&large_test_flash, 1));

   EXPECT_EQ(OkStatus(), kvs.Put("K", big_data.subspan(0, max_value_size)));

   // Larger than maximum is rejected.
   EXPECT_EQ(Status::InvalidArgument(),
             kvs.Put("K", big_data.subspan(0, max_value_size + 1)));
   EXPECT_EQ(Status::InvalidArgument(), kvs.Put("K", big_data));
 }

 }  // namespace pw::kvs
	// Copyright 2020 The Pigweed Authors
	//
	// 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
	//
	// https://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.

	#define DUMP_KVS_STATE_TO_FILE 0
	#define USE_MEMORY_BUFFER 1

	#include "pw_kvs/key_value_store.h"

	#include <array>
	#include <cstdio>
	#include <cstring>
	#include <span>

	#if DUMP_KVS_STATE_TO_FILE
	#include <vector>
	#endif // DUMP_KVS_STATE_TO_FILE

	#include "gtest/gtest.h"
	#include "pw_bytes/array.h"
	#include "pw_checksum/crc16_ccitt.h"
	#include "pw_kvs/crc16_checksum.h"
	#include "pw_kvs/fake_flash_memory.h"
	#include "pw_kvs/flash_memory.h"
	#include "pw_kvs/internal/entry.h"
	#include "pw_log/log.h"
	#include "pw_log/shorter.h"
	#include "pw_status/status.h"
	#include "pw_string/string_builder.h"

	namespace pw::kvs {
	namespace {

	using internal::EntryHeader;

	constexpr size_t kMaxEntries = 256;
	constexpr size_t kMaxUsableSectors = 256;

	// This is a self contained flash unit with both memory and a single partition.
	template <uint32_t kSectorSizeBytes, uint16_t kSectorCount>
	struct FlashWithPartitionFake {
	// Default to 16 byte alignment, which is common in practice.
	FlashWithPartitionFake() : FlashWithPartitionFake(16) {}
	FlashWithPartitionFake(size_t alignment_bytes)
	: memory(alignment_bytes), partition(&memory, 0, memory.sector_count()) {}

	FakeFlashMemoryBuffer<kSectorSizeBytes, kSectorCount> memory;
	FlashPartition partition;

	public:
	#if DUMP_KVS_STATE_TO_FILE
	Status Dump(const char* filename) {
	std::FILE* out_file = std::fopen(filename, "w+");
	if (out_file == nullptr) {
	PW_LOG_ERROR("Failed to dump to %s", filename);
	return Status::DataLoss();
	}
	std::vector<std::byte> out_vec(memory.size_bytes());
	Status status =
	memory.Read(0, std::span<std::byte>(out_vec.data(), out_vec.size()));
	if (status != OkStatus()) {
	fclose(out_file);
	return status;
	}

	size_t written =
	std::fwrite(out_vec.data(), 1, memory.size_bytes(), out_file);
	if (written != memory.size_bytes()) {
	PW_LOG_ERROR("Failed to dump to %s, written=%u",
	filename,
	static_cast<unsigned>(written));
	status = Status::DataLoss();
	} else {
	PW_LOG_INFO("Dumped to %s", filename);
	status = OkStatus();
	}

	fclose(out_file);
	return status;
	}
	#else
	Status Dump(const char*) { return OkStatus(); }
	#endif // DUMP_KVS_STATE_TO_FILE
	};

	typedef FlashWithPartitionFake<4 * 128 /sector size/, 6 /sectors/> Flash;

	FakeFlashMemoryBuffer<1024, 60> large_test_flash(8);
	FlashPartition large_test_partition(&large_test_flash,
	0,
	large_test_flash.sector_count());

	constexpr std::array<const char*, 3> keys{"TestKey1", "Key2", "TestKey3"};

	ChecksumCrc16 checksum;
	// For KVS magic value always use a random 32 bit integer rather than a
	// human readable 4 bytes. See pw_kvs/format.h for more information.
	constexpr EntryFormat default_format{.magic = 0xa6cb3c16,
	.checksum = &checksum};

	} // namespace

	TEST(InitCheck, TooFewSectors) {
	// Use test flash with 1 x 4k sectors, 16 byte alignment
	FakeFlashMemoryBuffer<4 * 1024, 1> test_flash(16);
	FlashPartition test_partition(&test_flash, 0, test_flash.sector_count());

	// For KVS magic value always use a random 32 bit integer rather than a
	// human readable 4 bytes. See pw_kvs/format.h for more information.
	constexpr EntryFormat format{.magic = 0x89bb14d2, .checksum = nullptr};
	KeyValueStoreBuffer<kMaxEntries, kMaxUsableSectors> kvs(&test_partition,
	format);

	EXPECT_EQ(kvs.Init(), Status::FailedPrecondition());
	}

	TEST(InitCheck, ZeroSectors) {
	// Use test flash with 1 x 4k sectors, 16 byte alignment
	FakeFlashMemoryBuffer<4 * 1024, 1> test_flash(16);

	// Set FlashPartition to have 0 sectors.
	FlashPartition test_partition(&test_flash, 0, 0);

	// For KVS magic value always use a random 32 bit integer rather than a
	// human readable 4 bytes. See pw_kvs/format.h for more information.
	constexpr EntryFormat format{.magic = 0xd1da57c1, .checksum = nullptr};
	KeyValueStoreBuffer<kMaxEntries, kMaxUsableSectors> kvs(&test_partition,
	format);

	EXPECT_EQ(kvs.Init(), Status::FailedPrecondition());
	}

	TEST(InitCheck, TooManySectors) {
	// Use test flash with 1 x 4k sectors, 16 byte alignment
	FakeFlashMemoryBuffer<4 * 1024, 5> test_flash(16);

	// Set FlashPartition to have 0 sectors.
	FlashPartition test_partition(&test_flash, 0, test_flash.sector_count());

	// For KVS magic value always use a random 32 bit integer rather than a
	// human readable 4 bytes. See pw_kvs/format.h for more information.
	constexpr EntryFormat format{.magic = 0x610f6d17, .checksum = nullptr};
	KeyValueStoreBuffer<kMaxEntries, 2> kvs(&test_partition, format);

	EXPECT_EQ(kvs.Init(), Status::FailedPrecondition());
	}

	#define ASSERT_OK(expr) ASSERT_EQ(OkStatus(), expr)
	#define EXPECT_OK(expr) EXPECT_EQ(OkStatus(), expr)

	TEST(InMemoryKvs, WriteOneKeyMultipleTimes) {
	// Create and erase the fake flash. It will persist across reloads.
	Flash flash;
	ASSERT_OK(flash.partition.Erase());

	int num_reloads = 2;
	for (int reload = 0; reload < num_reloads; ++reload) {
	DBG("xxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxx");
	DBG("xxx xxxx");
	DBG("xxx Reload %2d xxxx", reload);
	DBG("xxx xxxx");
	DBG("xxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxx");

	// Create and initialize the KVS. For KVS magic value always use a random 32
	// bit integer rather than a human readable 4 bytes. See pw_kvs/format.h for
	// more information.
	constexpr EntryFormat format{.magic = 0x83a9257, .checksum = nullptr};
	KeyValueStoreBuffer<kMaxEntries, kMaxUsableSectors> kvs(&flash.partition,
	format);
	ASSERT_OK(kvs.Init());

	// Write the same entry many times.
	const char* key = "abcd";
	const size_t num_writes = 99;
	uint32_t written_value;
	EXPECT_EQ(kvs.size(), (reload == 0) ? 0 : 1u);
	for (uint32_t i = 0; i < num_writes; ++i) {
	DBG("PUT #%zu for key %s with value %zu", size_t(i), key, size_t(i));

	written_value = i + 0xfc; // Prevent accidental pass with zero.
	EXPECT_OK(kvs.Put(key, written_value));
	EXPECT_EQ(kvs.size(), 1u);
	}

	// Verify that we can read the value back.
	DBG("GET final value for key: %s", key);
	uint32_t actual_value;
	EXPECT_OK(kvs.Get(key, &actual_value));
	EXPECT_EQ(actual_value, written_value);

	char fname_buf[64] = {'\0'};
	snprintf(&fname_buf[0],
	sizeof(fname_buf),
	"WriteOneKeyMultipleTimes_%d.bin",
	reload);
	flash.Dump(fname_buf)
	.IgnoreError(); // TODO(pwbug/387): Handle Status properly
	}
	}

	TEST(InMemoryKvs, WritingMultipleKeysIncreasesSize) {
	// Create and erase the fake flash.
	Flash flash;
	ASSERT_OK(flash.partition.Erase());

	// Create and initialize the KVS. For KVS magic value always use a random 32
	// bit integer rather than a human readable 4 bytes. See pw_kvs/format.h for
	// more information.
	constexpr EntryFormat format{.magic = 0x2ed3a058, .checksum = nullptr};
	KeyValueStoreBuffer<kMaxEntries, kMaxUsableSectors> kvs(&flash.partition,
	format);
	ASSERT_OK(kvs.Init());

	// Write the same entry many times.
	const size_t num_writes = 10;
	EXPECT_EQ(kvs.size(), 0u);
	for (size_t i = 0; i < num_writes; ++i) {
	StringBuffer<150> key;
	key << "key_" << i;
	DBG("PUT #%zu for key %s with value %zu", i, key.c_str(), i);

	size_t value = i + 77; // Prevent accidental pass with zero.
	EXPECT_OK(kvs.Put(key.view(), value));
	EXPECT_EQ(kvs.size(), i + 1);
	}
	flash.Dump("WritingMultipleKeysIncreasesSize.bin")
	.IgnoreError(); // TODO(pwbug/387): Handle Status properly
	}

	TEST(InMemoryKvs, WriteAndReadOneKey) {
	// Create and erase the fake flash.
	Flash flash;
	ASSERT_OK(flash.partition.Erase());

	// Create and initialize the KVS.
	// For KVS magic value always use a random 32 bit integer rather than a
	// human readable 4 bytes. See pw_kvs/format.h for more information.
	constexpr EntryFormat format{.magic = 0x5d70896, .checksum = nullptr};
	KeyValueStoreBuffer<kMaxEntries, kMaxUsableSectors> kvs(&flash.partition,
	format);
	ASSERT_OK(kvs.Init());

	// Add one entry.
	const char* key = "Key1";
	DBG("PUT value for key: %s", key);
	uint8_t written_value = 0xDA;
	ASSERT_OK(kvs.Put(key, written_value));
	EXPECT_EQ(kvs.size(), 1u);

	DBG("GET value for key: %s", key);
	uint8_t actual_value;
	ASSERT_OK(kvs.Get(key, &actual_value));
	EXPECT_EQ(actual_value, written_value);

	EXPECT_EQ(kvs.size(), 1u);
	}

	TEST(InMemoryKvs, WriteOneKeyValueMultipleTimes) {
	// Create and erase the fake flash.
	Flash flash;
	ASSERT_OK(flash.partition.Erase());

	// Create and initialize the KVS.
	KeyValueStoreBuffer<kMaxEntries, kMaxUsableSectors> kvs(&flash.partition,
	default_format);
	ASSERT_OK(kvs.Init());

	// Add one entry, with the same key and value, multiple times.
	const char* key = "Key1";
	uint8_t written_value = 0xDA;
	for (int i = 0; i < 50; i++) {
	DBG("PUT [%d] value for key: %s", i, key);
	ASSERT_OK(kvs.Put(key, written_value));
	EXPECT_EQ(kvs.size(), 1u);
	}

	DBG("GET value for key: %s", key);
	uint8_t actual_value;
	ASSERT_OK(kvs.Get(key, &actual_value));
	EXPECT_EQ(actual_value, written_value);

	// Verify that only one entry was written to the KVS.
	EXPECT_EQ(kvs.size(), 1u);
	EXPECT_EQ(kvs.transaction_count(), 1u);
	KeyValueStore::StorageStats stats = kvs.GetStorageStats();
	EXPECT_EQ(stats.reclaimable_bytes, 0u);
	}

	TEST(InMemoryKvs, Basic) {
	const char* key1 = "Key1";
	const char* key2 = "Key2";

	// Create and erase the fake flash.
	Flash flash;
	ASSERT_EQ(OkStatus(), flash.partition.Erase());

	// Create and initialize the KVS.
	// For KVS magic value always use a random 32 bit integer rather than a
	// human readable 4 bytes. See pw_kvs/format.h for more information.
	constexpr EntryFormat format{.magic = 0x7bf19895, .checksum = nullptr};
	KeyValueStoreBuffer<kMaxEntries, kMaxUsableSectors> kvs(&flash.partition,
	format);
	ASSERT_OK(kvs.Init());

	// Add two entries with different keys and values.
	uint8_t value1 = 0xDA;
	ASSERT_OK(kvs.Put(key1, std::as_bytes(std::span(&value1, sizeof(value1)))));
	EXPECT_EQ(kvs.size(), 1u);

	uint32_t value2 = 0xBAD0301f;
	ASSERT_OK(kvs.Put(key2, value2));
	EXPECT_EQ(kvs.size(), 2u);

	// Verify data
	uint32_t test2;
	EXPECT_OK(kvs.Get(key2, &test2));

	uint8_t test1;
	ASSERT_OK(kvs.Get(key1, &test1));

	EXPECT_EQ(test1, value1);
	EXPECT_EQ(test2, value2);

	EXPECT_EQ(kvs.size(), 2u);
	}

	TEST(InMemoryKvs, CallingEraseTwice_NothingWrittenToFlash) {
	// Create and erase the fake flash.
	Flash flash;
	ASSERT_EQ(OkStatus(), flash.partition.Erase());

	// Create and initialize the KVS.
	KeyValueStoreBuffer<kMaxEntries, kMaxUsableSectors> kvs(&flash.partition,
	default_format);
	ASSERT_OK(kvs.Init());

	const uint8_t kValue = 0xDA;
	ASSERT_EQ(OkStatus(), kvs.Put(keys[0], kValue));
	ASSERT_EQ(OkStatus(), kvs.Delete(keys[0]));

	// Compare before / after checksums to verify that nothing was written.
	const uint16_t crc = checksum::Crc16Ccitt::Calculate(flash.memory.buffer());

	EXPECT_EQ(kvs.Delete(keys[0]), Status::NotFound());

	EXPECT_EQ(crc, checksum::Crc16Ccitt::Calculate(flash.memory.buffer()));
	}

	class LargeEmptyInitializedKvs : public ::testing::Test {
	protected:
	LargeEmptyInitializedKvs() : kvs_(&large_test_partition, default_format) {
	ASSERT_EQ(OkStatus(), large_test_partition.Erase());
	ASSERT_EQ(OkStatus(), kvs_.Init());
	}

	KeyValueStoreBuffer<kMaxEntries, kMaxUsableSectors> kvs_;
	};

	TEST_F(LargeEmptyInitializedKvs, Basic) {
	const uint8_t kValue1 = 0xDA;
	const uint8_t kValue2 = 0x12;
	uint8_t value;
	ASSERT_EQ(OkStatus(), kvs_.Put(keys[0], kValue1));
	EXPECT_EQ(kvs_.size(), 1u);
	ASSERT_EQ(OkStatus(), kvs_.Delete(keys[0]));
	EXPECT_EQ(kvs_.Get(keys[0], &value), Status::NotFound());
	ASSERT_EQ(OkStatus(), kvs_.Put(keys[1], kValue1));
	ASSERT_EQ(OkStatus(), kvs_.Put(keys[2], kValue2));
	ASSERT_EQ(OkStatus(), kvs_.Delete(keys[1]));
	EXPECT_EQ(OkStatus(), kvs_.Get(keys[2], &value));
	EXPECT_EQ(kValue2, value);
	ASSERT_EQ(kvs_.Get(keys[1], &value), Status::NotFound());
	EXPECT_EQ(kvs_.size(), 1u);
	}

	TEST_F(LargeEmptyInitializedKvs, FullMaintenance) {
	const uint8_t kValue1 = 0xDA;
	const uint8_t kValue2 = 0x12;

	// Write a key and write again with a different value, resulting in a stale
	// entry from the first write.
	ASSERT_EQ(OkStatus(), kvs_.Put(keys[0], kValue1));
	ASSERT_EQ(OkStatus(), kvs_.Put(keys[0], kValue2));
	EXPECT_EQ(kvs_.size(), 1u);

	KeyValueStore::StorageStats stats = kvs_.GetStorageStats();
	EXPECT_EQ(stats.sector_erase_count, 0u);
	EXPECT_GT(stats.reclaimable_bytes, 0u);

	// Do regular FullMaintenance, which should not touch the sector with valid
	// data.
	EXPECT_EQ(OkStatus(), kvs_.FullMaintenance());
	stats = kvs_.GetStorageStats();
	EXPECT_EQ(stats.sector_erase_count, 0u);
	EXPECT_GT(stats.reclaimable_bytes, 0u);

	// Do aggressive FullMaintenance, which should GC the sector with valid data,
	// resulting in no reclaimable bytes and an erased sector.
	EXPECT_EQ(OkStatus(), kvs_.HeavyMaintenance());
	stats = kvs_.GetStorageStats();
	EXPECT_EQ(stats.sector_erase_count, 1u);
	EXPECT_EQ(stats.reclaimable_bytes, 0u);
	}

	TEST(InMemoryKvs, Put_MaxValueSize) {
	// Create and erase the fake flash.
	Flash flash;
	ASSERT_EQ(OkStatus(), flash.partition.Erase());

	// Create and initialize the KVS.
	KeyValueStoreBuffer<kMaxEntries, kMaxUsableSectors> kvs(&flash.partition,
	default_format);
	ASSERT_OK(kvs.Init());

	size_t max_key_value_size = kvs.max_key_value_size_bytes();
	EXPECT_EQ(max_key_value_size,
	KeyValueStore::max_key_value_size_bytes(
	flash.partition.sector_size_bytes()));

	size_t max_value_size =
	flash.partition.sector_size_bytes() - sizeof(EntryHeader) - 1;
	EXPECT_EQ(max_key_value_size, (max_value_size + 1));

	// Use the large_test_flash as a big chunk of data for the Put statement.
	ASSERT_GT(sizeof(large_test_flash), max_value_size + 2 * sizeof(EntryHeader));
	auto big_data = std::as_bytes(std::span(&large_test_flash, 1));

	EXPECT_EQ(OkStatus(), kvs.Put("K", big_data.subspan(0, max_value_size)));

	// Larger than maximum is rejected.
	EXPECT_EQ(Status::InvalidArgument(),
	kvs.Put("K", big_data.subspan(0, max_value_size + 1)));
	EXPECT_EQ(Status::InvalidArgument(), kvs.Put("K", big_data));
	}

	} // namespace pw::kvs