pw_kvs/entry_test.cc - platform/external/pigweed - Gitiles

 // 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.

 #include "pw_kvs/internal/entry.h"

 #include <span>
 #include <string_view>

 #include "gtest/gtest.h"
 #include "pw_bytes/array.h"
 #include "pw_kvs/alignment.h"
 #include "pw_kvs/checksum.h"
 #include "pw_kvs/crc16_checksum.h"
 #include "pw_kvs/fake_flash_memory.h"
 #include "pw_kvs/flash_memory.h"
 #include "pw_kvs/format.h"

 namespace pw::kvs::internal {
 namespace {

 using std::byte;
 using std::string_view;

 // For 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 kFormat{0x961c2ff9, nullptr};

 TEST(Entry, Size_RoundsUpToAlignment) {
   // Use FakeFlashMemory, rather than FakeFlashMemoryBuffer, so the class gets
   // tested/used directly.
   std::array<std::byte, 64 * 2> buffer;

   // Flash alignment needs to be 1 due to how the partition is used in this
   // test.
   FakeFlashMemory flash(buffer, 64, 2, 1);

   for (size_t alignment_bytes = 1; alignment_bytes <= 4096; ++alignment_bytes) {
     FlashPartition partition(&flash, 0, flash.sector_count(), alignment_bytes);
     const size_t align = AlignUp(alignment_bytes, Entry::kMinAlignmentBytes);

     for (size_t value : {size_t(0), align - 1, align, align + 1, 2 * align}) {
       Entry entry =
           Entry::Valid(partition, 0, kFormat, "k", {nullptr, value}, 0);

       ASSERT_EQ(AlignUp(sizeof(EntryHeader) + 1 /* key */ + value, align),
                 entry.size());
     }

     Entry entry = Entry::Tombstone(partition, 0, kFormat, "k", 0);
     ASSERT_EQ(AlignUp(sizeof(EntryHeader) + 1 /* key */, align), entry.size());
   }
 }

 TEST(Entry, Construct_ValidEntry) {
   FakeFlashMemoryBuffer<64, 2> flash(16);
   FlashPartition partition(&flash, 0, flash.sector_count());

   auto entry = Entry::Valid(
       partition, 1, kFormat, "k", std::as_bytes(std::span("123")), 9876);

   EXPECT_FALSE(entry.deleted());
   EXPECT_EQ(entry.magic(), kFormat.magic);
   EXPECT_EQ(entry.value_size(), sizeof("123"));
   EXPECT_EQ(entry.transaction_id(), 9876u);
 }

 TEST(Entry, Construct_Tombstone) {
   FakeFlashMemoryBuffer<64, 2> flash(16);
   FlashPartition partition(&flash, 0, flash.sector_count());

   auto entry = Entry::Tombstone(partition, 1, kFormat, "key", 123);

   EXPECT_TRUE(entry.deleted());
   EXPECT_EQ(entry.magic(), kFormat.magic);
   EXPECT_EQ(entry.value_size(), 0u);
   EXPECT_EQ(entry.transaction_id(), 123u);
 }

 // For magic value always use a unique random 32 bit integer rather than a human
 // readable 4 bytes. See pw_kvs/format.h for more information.
 constexpr uint32_t kMagicWithChecksum = 0xad165142;
 constexpr uint32_t kTransactionId1 = 0x96979899;

 constexpr auto kKey1 = bytes::String("key45");
 constexpr auto kValue1 = bytes::String("VALUE!");
 constexpr auto kPadding1 = bytes::String("\0\0\0\0\0");

 constexpr auto kHeader1 = bytes::Concat(kMagicWithChecksum,
                                         uint32_t(0x23aa),  // checksum (CRC16)
                                         uint8_t(1),        // alignment (32 B)
                                         uint8_t(kKey1.size()),     // key length
                                         uint16_t(kValue1.size()),  // value size
                                         kTransactionId1  // transaction ID
 );

 constexpr auto kEntryWithoutPadding1 = bytes::Concat(kHeader1, kKey1, kValue1);
 constexpr auto kEntry1 = bytes::Concat(kEntryWithoutPadding1, kPadding1);
 static_assert(kEntry1.size() == 32);

 ChecksumCrc16 default_checksum;
 constexpr EntryFormat kFormatWithChecksum{kMagicWithChecksum,
                                           &default_checksum};
 constexpr internal::EntryFormats kFormats(kFormatWithChecksum);

 class ValidEntryInFlash : public ::testing::Test {
  protected:
   ValidEntryInFlash() : flash_(kEntry1), partition_(&flash_) {
     EXPECT_EQ(OkStatus(), Entry::Read(partition_, 0, kFormats, &entry_));
   }

   FakeFlashMemoryBuffer<1024, 4> flash_;
   FlashPartition partition_;
   Entry entry_;
 };

 TEST_F(ValidEntryInFlash, PassesChecksumVerification) {
   EXPECT_EQ(OkStatus(), entry_.VerifyChecksumInFlash());
   EXPECT_EQ(OkStatus(), entry_.VerifyChecksum("key45", kValue1));
 }

 TEST_F(ValidEntryInFlash, HeaderContents) {
   EXPECT_EQ(entry_.magic(), kMagicWithChecksum);
   EXPECT_EQ(entry_.key_length(), 5u);
   EXPECT_EQ(entry_.value_size(), 6u);
   EXPECT_EQ(entry_.transaction_id(), kTransactionId1);
   EXPECT_FALSE(entry_.deleted());
 }

 TEST_F(ValidEntryInFlash, ReadKey) {
   Entry::KeyBuffer key = {};
   auto result = entry_.ReadKey(key);

   ASSERT_EQ(OkStatus(), result.status());
   EXPECT_EQ(result.size(), entry_.key_length());
   EXPECT_STREQ(key.data(), "key45");
 }

 TEST_F(ValidEntryInFlash, ReadValue) {
   char value[32] = {};
   auto result = entry_.ReadValue(std::as_writable_bytes(std::span(value)));

   ASSERT_EQ(OkStatus(), result.status());
   EXPECT_EQ(result.size(), entry_.value_size());
   EXPECT_STREQ(value, "VALUE!");
 }

 TEST_F(ValidEntryInFlash, ReadValue_BufferTooSmall) {
   char value[3] = {};
   auto result = entry_.ReadValue(std::as_writable_bytes(std::span(value)));

   ASSERT_EQ(Status::ResourceExhausted(), result.status());
   EXPECT_EQ(3u, result.size());
   EXPECT_EQ(value[0], 'V');
   EXPECT_EQ(value[1], 'A');
   EXPECT_EQ(value[2], 'L');
 }

 TEST_F(ValidEntryInFlash, ReadValue_WithOffset) {
   char value[3] = {};
   auto result = entry_.ReadValue(std::as_writable_bytes(std::span(value)), 3);

   ASSERT_EQ(OkStatus(), result.status());
   EXPECT_EQ(3u, result.size());
   EXPECT_EQ(value[0], 'U');
   EXPECT_EQ(value[1], 'E');
   EXPECT_EQ(value[2], '!');
 }

 TEST_F(ValidEntryInFlash, ReadValue_WithOffset_BufferTooSmall) {
   char value[1] = {};
   auto result = entry_.ReadValue(std::as_writable_bytes(std::span(value)), 4);

   ASSERT_EQ(Status::ResourceExhausted(), result.status());
   EXPECT_EQ(1u, result.size());
   EXPECT_EQ(value[0], 'E');
 }

 TEST_F(ValidEntryInFlash, ReadValue_WithOffset_EmptyRead) {
   char value[16] = {'?'};
   auto result = entry_.ReadValue(std::as_writable_bytes(std::span(value)), 6);

   ASSERT_EQ(OkStatus(), result.status());
   EXPECT_EQ(0u, result.size());
   EXPECT_EQ(value[0], '?');
 }

 TEST_F(ValidEntryInFlash, ReadValue_WithOffset_PastEnd) {
   char value[16] = {};
   auto result = entry_.ReadValue(std::as_writable_bytes(std::span(value)), 7);

   EXPECT_EQ(Status::OutOfRange(), result.status());
   EXPECT_EQ(0u, result.size());
 }

 TEST(ValidEntry, Write) {
   FakeFlashMemoryBuffer<1024, 4> flash;
   FlashPartition partition(&flash, 0, flash.sector_count(), 32);

   Entry entry = Entry::Valid(
       partition, 64, kFormatWithChecksum, "key45", kValue1, kTransactionId1);

   auto result = entry.Write("key45", kValue1);
   EXPECT_EQ(OkStatus(), result.status());
   EXPECT_EQ(32u, result.size());
   EXPECT_EQ(std::memcmp(&flash.buffer()[64], kEntry1.data(), kEntry1.size()),
             0);
 }

 constexpr auto kHeader2 = bytes::String(
     "\x42\x51\x16\xad"  // magic
     "\xba\xb3\x00\x00"  // checksum (CRC16)
     "\x00"              // alignment
     "\x01"              // key length
     "\xff\xff"          // value size
     "\x00\x01\x02\x03"  // transaction ID
 );

 constexpr auto kKeyAndPadding2 =
     bytes::String("K\0\0\0\0\0\0\0\0\0\0\0\0\0\0\0");

 class TombstoneEntryInFlash : public ::testing::Test {
  protected:
   TombstoneEntryInFlash()
       : flash_(bytes::Concat(kHeader2, kKeyAndPadding2)), partition_(&flash_) {
     EXPECT_EQ(OkStatus(), Entry::Read(partition_, 0, kFormats, &entry_));
   }

   FakeFlashMemoryBuffer<1024, 4> flash_;
   FlashPartition partition_;
   Entry entry_;
 };

 TEST_F(TombstoneEntryInFlash, PassesChecksumVerification) {
   EXPECT_EQ(OkStatus(), entry_.VerifyChecksumInFlash());
   EXPECT_EQ(OkStatus(), entry_.VerifyChecksum("K", {}));
 }

 TEST_F(TombstoneEntryInFlash, HeaderContents) {
   EXPECT_EQ(entry_.magic(), kMagicWithChecksum);
   EXPECT_EQ(entry_.key_length(), 1u);
   EXPECT_EQ(entry_.value_size(), 0u);
   EXPECT_EQ(entry_.transaction_id(), 0x03020100u);
   EXPECT_TRUE(entry_.deleted());
 }

 TEST_F(TombstoneEntryInFlash, ReadKey) {
   Entry::KeyBuffer key = {};
   auto result = entry_.ReadKey(key);

   ASSERT_EQ(OkStatus(), result.status());
   EXPECT_EQ(result.size(), entry_.key_length());
   EXPECT_STREQ(key.data(), "K");
 }

 TEST_F(TombstoneEntryInFlash, ReadValue) {
   char value[32] = {};
   auto result = entry_.ReadValue(std::as_writable_bytes(std::span(value)));

   ASSERT_EQ(OkStatus(), result.status());
   EXPECT_EQ(0u, result.size());
 }

 TEST(TombstoneEntry, Write) {
   FakeFlashMemoryBuffer<1024, 4> flash;
   FlashPartition partition(&flash);
   ChecksumCrc16 checksum;

   Entry entry =
       Entry::Tombstone(partition, 16, kFormatWithChecksum, "K", 0x03020100);

   auto result = entry.Write("K", {});
   EXPECT_EQ(OkStatus(), result.status());
   EXPECT_EQ(32u, result.size());
   EXPECT_EQ(std::memcmp(&flash.buffer()[16],
                         bytes::Concat(kHeader2, kKeyAndPadding2).data(),
                         kEntry1.size()),
             0);
 }

 TEST(Entry, Checksum_NoChecksumRequiresZero) {
   FakeFlashMemoryBuffer<1024, 4> flash(kEntry1);
   FlashPartition partition(&flash);
   Entry entry;

   const EntryFormat format{kMagicWithChecksum, nullptr};
   const internal::EntryFormats formats(format);

   ASSERT_EQ(OkStatus(), Entry::Read(partition, 0, formats, &entry));

   EXPECT_EQ(Status::DataLoss(), entry.VerifyChecksumInFlash());
   EXPECT_EQ(Status::DataLoss(), entry.VerifyChecksum({}, {}));

   std::memset(&flash.buffer()[4], 0, 4);  // set the checksum field to 0
   ASSERT_EQ(OkStatus(), Entry::Read(partition, 0, formats, &entry));
   EXPECT_EQ(OkStatus(), entry.VerifyChecksumInFlash());
   EXPECT_EQ(OkStatus(), entry.VerifyChecksum({}, {}));
 }

 TEST(Entry, Checksum_ChecksPadding) {
   FakeFlashMemoryBuffer<1024, 4> flash(
       bytes::Concat(kHeader1, kKey1, kValue1, bytes::String("\0\0\0\0\1")));
   FlashPartition partition(&flash);
   Entry entry;
   ASSERT_EQ(OkStatus(), Entry::Read(partition, 0, kFormats, &entry));

   // Last byte in padding is a 1; should fail.
   EXPECT_EQ(Status::DataLoss(), entry.VerifyChecksumInFlash());

   // The in-memory verification fills in 0s for the padding.
   EXPECT_EQ(OkStatus(), entry.VerifyChecksum("key45", kValue1));

   flash.buffer()[kEntry1.size() - 1] = byte{0};
   EXPECT_EQ(OkStatus(), entry.VerifyChecksumInFlash());
 }

 TEST_F(ValidEntryInFlash, Update_SameFormat_TransactionIdIsUpdated) {
   ASSERT_EQ(OkStatus(),
             entry_.Update(kFormatWithChecksum, kTransactionId1 + 3));

   EXPECT_EQ(kFormatWithChecksum.magic, entry_.magic());
   EXPECT_EQ(0u, entry_.address());
   EXPECT_EQ(kTransactionId1 + 3, entry_.transaction_id());
   EXPECT_FALSE(entry_.deleted());
 }

 TEST_F(ValidEntryInFlash,
        Update_DifferentFormat_MagicAndTransactionIdAreUpdated) {
   ASSERT_EQ(OkStatus(), entry_.Update(kFormat, kTransactionId1 + 6));

   EXPECT_EQ(kFormat.magic, entry_.magic());
   EXPECT_EQ(0u, entry_.address());
   EXPECT_EQ(kTransactionId1 + 6, entry_.transaction_id());
   EXPECT_FALSE(entry_.deleted());
 }

 TEST_F(ValidEntryInFlash, Update_ReadError_WithChecksumIsError) {
   flash_.InjectReadError(FlashError::Unconditional(Status::Aborted()));

   EXPECT_EQ(Status::Aborted(),
             entry_.Update(kFormatWithChecksum, kTransactionId1 + 1));
 }

 // For 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 kNoChecksumFormat{.magic = 0x721bad24,
                                         .checksum = nullptr};

 TEST_F(ValidEntryInFlash, Update_ReadError_NoChecksumIsOkay) {
   flash_.InjectReadError(FlashError::Unconditional(Status::Aborted()));

   EXPECT_EQ(OkStatus(), entry_.Update(kNoChecksumFormat, kTransactionId1 + 1));
 }

 TEST_F(ValidEntryInFlash, Copy) {
   auto result = entry_.Copy(123);

   EXPECT_EQ(OkStatus(), result.status());
   EXPECT_EQ(entry_.size(), result.size());
   EXPECT_EQ(0,
             std::memcmp(
                 &flash_.buffer().data()[123], kEntry1.data(), kEntry1.size()));
 }

 TEST_F(ValidEntryInFlash, Copy_ReadError) {
   flash_.InjectReadError(FlashError::Unconditional(Status::Unimplemented()));
   auto result = entry_.Copy(kEntry1.size());
   EXPECT_EQ(Status::Unimplemented(), result.status());
   EXPECT_EQ(0u, result.size());
 }

 constexpr uint32_t ByteSum(std::span<const byte> bytes, uint32_t value = 0) {
   for (byte b : bytes) {
     value += unsigned(b);
   }
   return value;
 }

 // Sums the bytes, adding one to each byte so that zeroes change the checksum.
 class ChecksumSummation final : public ChecksumAlgorithm {
  public:
   ChecksumSummation()
       : ChecksumAlgorithm(std::as_bytes(std::span(&sum_, 1))), sum_(0) {}

   void Reset() override { sum_ = 0; }

   void Update(std::span<const byte> data) override {
     for (byte b : data) {
       sum_ += unsigned(b) + 1;  // Add 1 so zero-value bytes affect checksum.
     }
   }

  private:
   uint32_t sum_;
 } sum_checksum;

 // For 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 uint32_t kMagicWithSum = 0x6093aadb;
 constexpr EntryFormat kFormatWithSum{kMagicWithSum, &sum_checksum};
 constexpr internal::EntryFormats kFormatsWithSum(kFormatWithSum);

 template <size_t alignment>
 constexpr auto MakeNewFormatWithSumEntry() {
   constexpr uint8_t alignment_units = (alignment + 15) / 16 - 1;
   constexpr size_t size = AlignUp(kEntryWithoutPadding1.size(), alignment);

   constexpr uint32_t checksum =
       ByteSum(bytes::Concat(kFormatWithSum.magic)) + 0 /* checksum */ +
       alignment_units + kKey1.size() + kValue1.size() +
       ByteSum(bytes::Concat(kTransactionId1 + 1)) + ByteSum(kKey1) +
       ByteSum(kValue1) + size /* +1 for each byte in the checksum */;

   constexpr auto kNewHeader1 =
       bytes::Concat(kFormatWithSum.magic,      // magic
                     checksum,                  // checksum (byte sum)
                     alignment_units,           // alignment (in 16 B units)
                     uint8_t(kKey1.size()),     // key length
                     uint16_t(kValue1.size()),  // value size
                     kTransactionId1 + 1);      // transaction ID
   constexpr size_t padding = Padding(kEntryWithoutPadding1.size(), alignment);
   return bytes::Concat(
       kNewHeader1, kKey1, kValue1, bytes::Initialized<padding>(0));
 }

 TEST_F(ValidEntryInFlash, UpdateAndCopy_DifferentFormatSmallerAlignment) {
   // Uses 16-bit alignment, smaller than the original entry's alignment.
   ASSERT_EQ(OkStatus(), entry_.Update(kFormatWithSum, kTransactionId1 + 1));

   StatusWithSize result = entry_.Copy(kEntry1.size());
   ASSERT_EQ(OkStatus(), result.status());
   EXPECT_EQ(kEntry1.size(), result.size());

   constexpr auto new_data = MakeNewFormatWithSumEntry<16>();
   static_assert(new_data.size() == 32);

   EXPECT_EQ(
       0,
       std::memcmp(
           &flash_.buffer()[kEntry1.size()], new_data.data(), new_data.size()));
   Entry new_entry;
   ASSERT_EQ(OkStatus(),
             Entry::Read(partition_, 32, kFormatsWithSum, &new_entry));
   EXPECT_EQ(OkStatus(), new_entry.VerifyChecksumInFlash());
   EXPECT_EQ(kFormatWithSum.magic, new_entry.magic());
   EXPECT_EQ(kTransactionId1 + 1, new_entry.transaction_id());
 }

 TEST(ValidEntryInFlash, UpdateAndCopy_DifferentFormatSameAlignment) {
   // Use 32-bit alignment, the same as the original entry's alignment.
   FakeFlashMemoryBuffer<1024, 4> flash(kEntry1);
   FlashPartition partition(&flash, 0, 4, 32);
   Entry entry;
   ASSERT_EQ(OkStatus(), Entry::Read(partition, 0, kFormats, &entry));

   ASSERT_EQ(OkStatus(), entry.Update(kFormatWithSum, kTransactionId1 + 1));

   StatusWithSize result = entry.Copy(32);
   ASSERT_EQ(OkStatus(), result.status());
   EXPECT_EQ(AlignUp(kEntry1.size(), 32), result.size());

   constexpr auto new_data = MakeNewFormatWithSumEntry<32>();
   static_assert(new_data.size() == 32);

   EXPECT_EQ(0,
             std::memcmp(&flash.buffer()[32], new_data.data(), new_data.size()));

   Entry new_entry;
   ASSERT_EQ(OkStatus(),
             Entry::Read(partition, 32, kFormatsWithSum, &new_entry));
   EXPECT_EQ(OkStatus(), new_entry.VerifyChecksumInFlash());
   EXPECT_EQ(kTransactionId1 + 1, new_entry.transaction_id());
 }

 TEST(ValidEntryInFlash, UpdateAndCopy_DifferentFormatLargerAlignment) {
   // Use 64-bit alignment, larger than the original entry's alignment.
   FakeFlashMemoryBuffer<1024, 4> flash(kEntry1);
   FlashPartition partition(&flash, 0, 4, 64);
   Entry entry;
   ASSERT_EQ(OkStatus(), Entry::Read(partition, 0, kFormats, &entry));

   ASSERT_EQ(OkStatus(), entry.Update(kFormatWithSum, kTransactionId1 + 1));

   StatusWithSize result = entry.Copy(64);
   ASSERT_EQ(OkStatus(), result.status());
   EXPECT_EQ(AlignUp(kEntry1.size(), 64), result.size());

   constexpr auto new_data = MakeNewFormatWithSumEntry<64>();
   static_assert(new_data.size() == 64);

   EXPECT_EQ(0,
             std::memcmp(&flash.buffer()[64], new_data.data(), new_data.size()));

   Entry new_entry;
   ASSERT_EQ(OkStatus(),
             Entry::Read(partition, 64, kFormatsWithSum, &new_entry));
   EXPECT_EQ(OkStatus(), new_entry.VerifyChecksumInFlash());
   EXPECT_EQ(kTransactionId1 + 1, new_entry.transaction_id());
 }

 TEST_F(ValidEntryInFlash, UpdateAndCopy_NoChecksum_UpdatesToNewFormat) {
   // For 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 no_checksum{.magic = 0x43fae18f, .checksum = nullptr};

   ASSERT_EQ(OkStatus(), entry_.Update(no_checksum, kTransactionId1 + 1));

   auto result = entry_.Copy(kEntry1.size());
   ASSERT_EQ(OkStatus(), result.status());
   EXPECT_EQ(kEntry1.size(), result.size());

   constexpr auto kNewHeader1 =
       bytes::Concat(no_checksum.magic,  // magic
                     uint32_t(0),        // checksum (none)
                     uint8_t(0),         // alignment (changed to 16 B from 32)
                     uint8_t(kKey1.size()),     // key length
                     uint16_t(kValue1.size()),  // value size
                     kTransactionId1 + 1);      // transaction ID
   constexpr auto kNewEntry1 =
       bytes::Concat(kNewHeader1, kKey1, kValue1, kPadding1);

   EXPECT_EQ(0,
             std::memcmp(&flash_.buffer()[kEntry1.size()],
                         kNewEntry1.data(),
                         kNewEntry1.size()));
 }

 TEST_F(ValidEntryInFlash, UpdateAndCopyMultple_DifferentFormat) {
   ASSERT_EQ(OkStatus(), entry_.Update(kFormatWithSum, kTransactionId1 + 6));

   FlashPartition::Address new_address = entry_.size();

   for (int i = 0; i < 10; i++) {
     StatusWithSize copy_result = entry_.Copy(new_address + (i * entry_.size()));
     ASSERT_EQ(OkStatus(), copy_result.status());
     ASSERT_EQ(kEntry1.size(), copy_result.size());
   }

   for (int j = 0; j < 10; j++) {
     Entry entry;
     FlashPartition::Address read_address = (new_address + (j * entry_.size()));
     ASSERT_EQ(OkStatus(),
               Entry::Read(partition_, read_address, kFormatsWithSum, &entry));

     EXPECT_EQ(OkStatus(), entry.VerifyChecksumInFlash());
     EXPECT_EQ(kFormatWithSum.magic, entry.magic());
     EXPECT_EQ(read_address, entry.address());
     EXPECT_EQ(kTransactionId1 + 6, entry.transaction_id());
     EXPECT_FALSE(entry.deleted());
   }
 }

 TEST_F(ValidEntryInFlash, DifferentFormat_UpdatedCopy_FailsWithWrongMagic) {
   ASSERT_EQ(OkStatus(), entry_.Update(kFormatWithSum, kTransactionId1 + 6));

   FlashPartition::Address new_address = entry_.size();

   StatusWithSize copy_result = entry_.Copy(new_address);
   ASSERT_EQ(OkStatus(), copy_result.status());
   ASSERT_EQ(kEntry1.size(), copy_result.size());

   Entry entry;
   ASSERT_EQ(Status::DataLoss(),
             Entry::Read(partition_, new_address, kFormats, &entry));
 }

 TEST_F(ValidEntryInFlash, UpdateAndCopy_WriteError) {
   flash_.InjectWriteError(FlashError::Unconditional(Status::Cancelled()));

   ASSERT_EQ(OkStatus(), entry_.Update(kNoChecksumFormat, kTransactionId1 + 1));

   auto result = entry_.Copy(kEntry1.size());
   EXPECT_EQ(Status::Cancelled(), result.status());
   EXPECT_EQ(kEntry1.size(), result.size());
 }

 }  // namespace
 }  // namespace pw::kvs::internal
	// 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.

	#include "pw_kvs/internal/entry.h"

	#include <span>
	#include <string_view>

	#include "gtest/gtest.h"
	#include "pw_bytes/array.h"
	#include "pw_kvs/alignment.h"
	#include "pw_kvs/checksum.h"
	#include "pw_kvs/crc16_checksum.h"
	#include "pw_kvs/fake_flash_memory.h"
	#include "pw_kvs/flash_memory.h"
	#include "pw_kvs/format.h"

	namespace pw::kvs::internal {
	namespace {

	using std::byte;
	using std::string_view;

	// For 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 kFormat{0x961c2ff9, nullptr};

	TEST(Entry, Size_RoundsUpToAlignment) {
	// Use FakeFlashMemory, rather than FakeFlashMemoryBuffer, so the class gets
	// tested/used directly.
	std::array<std::byte, 64 * 2> buffer;

	// Flash alignment needs to be 1 due to how the partition is used in this
	// test.
	FakeFlashMemory flash(buffer, 64, 2, 1);

	for (size_t alignment_bytes = 1; alignment_bytes <= 4096; ++alignment_bytes) {
	FlashPartition partition(&flash, 0, flash.sector_count(), alignment_bytes);
	const size_t align = AlignUp(alignment_bytes, Entry::kMinAlignmentBytes);

	for (size_t value : {size_t(0), align - 1, align, align + 1, 2 * align}) {
	Entry entry =
	Entry::Valid(partition, 0, kFormat, "k", {nullptr, value}, 0);

	ASSERT_EQ(AlignUp(sizeof(EntryHeader) + 1 /* key */ + value, align),
	entry.size());
	}

	Entry entry = Entry::Tombstone(partition, 0, kFormat, "k", 0);
	ASSERT_EQ(AlignUp(sizeof(EntryHeader) + 1 /* key */, align), entry.size());
	}
	}

	TEST(Entry, Construct_ValidEntry) {
	FakeFlashMemoryBuffer<64, 2> flash(16);
	FlashPartition partition(&flash, 0, flash.sector_count());

	auto entry = Entry::Valid(
	partition, 1, kFormat, "k", std::as_bytes(std::span("123")), 9876);

	EXPECT_FALSE(entry.deleted());
	EXPECT_EQ(entry.magic(), kFormat.magic);
	EXPECT_EQ(entry.value_size(), sizeof("123"));
	EXPECT_EQ(entry.transaction_id(), 9876u);
	}

	TEST(Entry, Construct_Tombstone) {
	FakeFlashMemoryBuffer<64, 2> flash(16);
	FlashPartition partition(&flash, 0, flash.sector_count());

	auto entry = Entry::Tombstone(partition, 1, kFormat, "key", 123);

	EXPECT_TRUE(entry.deleted());
	EXPECT_EQ(entry.magic(), kFormat.magic);
	EXPECT_EQ(entry.value_size(), 0u);
	EXPECT_EQ(entry.transaction_id(), 123u);
	}

	// For magic value always use a unique random 32 bit integer rather than a human
	// readable 4 bytes. See pw_kvs/format.h for more information.
	constexpr uint32_t kMagicWithChecksum = 0xad165142;
	constexpr uint32_t kTransactionId1 = 0x96979899;

	constexpr auto kKey1 = bytes::String("key45");
	constexpr auto kValue1 = bytes::String("VALUE!");
	constexpr auto kPadding1 = bytes::String("\0\0\0\0\0");

	constexpr auto kHeader1 = bytes::Concat(kMagicWithChecksum,
	uint32_t(0x23aa), // checksum (CRC16)
	uint8_t(1), // alignment (32 B)
	uint8_t(kKey1.size()), // key length
	uint16_t(kValue1.size()), // value size
	kTransactionId1 // transaction ID
	);

	constexpr auto kEntryWithoutPadding1 = bytes::Concat(kHeader1, kKey1, kValue1);
	constexpr auto kEntry1 = bytes::Concat(kEntryWithoutPadding1, kPadding1);
	static_assert(kEntry1.size() == 32);

	ChecksumCrc16 default_checksum;
	constexpr EntryFormat kFormatWithChecksum{kMagicWithChecksum,
	&default_checksum};
	constexpr internal::EntryFormats kFormats(kFormatWithChecksum);

	class ValidEntryInFlash : public ::testing::Test {
	protected:
	ValidEntryInFlash() : flash_(kEntry1), partition_(&flash_) {
	EXPECT_EQ(OkStatus(), Entry::Read(partition_, 0, kFormats, &entry_));
	}

	FakeFlashMemoryBuffer<1024, 4> flash_;
	FlashPartition partition_;
	Entry entry_;
	};

	TEST_F(ValidEntryInFlash, PassesChecksumVerification) {
	EXPECT_EQ(OkStatus(), entry_.VerifyChecksumInFlash());
	EXPECT_EQ(OkStatus(), entry_.VerifyChecksum("key45", kValue1));
	}

	TEST_F(ValidEntryInFlash, HeaderContents) {
	EXPECT_EQ(entry_.magic(), kMagicWithChecksum);
	EXPECT_EQ(entry_.key_length(), 5u);
	EXPECT_EQ(entry_.value_size(), 6u);
	EXPECT_EQ(entry_.transaction_id(), kTransactionId1);
	EXPECT_FALSE(entry_.deleted());
	}

	TEST_F(ValidEntryInFlash, ReadKey) {
	Entry::KeyBuffer key = {};
	auto result = entry_.ReadKey(key);

	ASSERT_EQ(OkStatus(), result.status());
	EXPECT_EQ(result.size(), entry_.key_length());
	EXPECT_STREQ(key.data(), "key45");
	}

	TEST_F(ValidEntryInFlash, ReadValue) {
	char value[32] = {};
	auto result = entry_.ReadValue(std::as_writable_bytes(std::span(value)));

	ASSERT_EQ(OkStatus(), result.status());
	EXPECT_EQ(result.size(), entry_.value_size());
	EXPECT_STREQ(value, "VALUE!");
	}

	TEST_F(ValidEntryInFlash, ReadValue_BufferTooSmall) {
	char value[3] = {};
	auto result = entry_.ReadValue(std::as_writable_bytes(std::span(value)));

	ASSERT_EQ(Status::ResourceExhausted(), result.status());
	EXPECT_EQ(3u, result.size());
	EXPECT_EQ(value[0], 'V');
	EXPECT_EQ(value[1], 'A');
	EXPECT_EQ(value[2], 'L');
	}

	TEST_F(ValidEntryInFlash, ReadValue_WithOffset) {
	char value[3] = {};
	auto result = entry_.ReadValue(std::as_writable_bytes(std::span(value)), 3);

	ASSERT_EQ(OkStatus(), result.status());
	EXPECT_EQ(3u, result.size());
	EXPECT_EQ(value[0], 'U');
	EXPECT_EQ(value[1], 'E');
	EXPECT_EQ(value[2], '!');
	}

	TEST_F(ValidEntryInFlash, ReadValue_WithOffset_BufferTooSmall) {
	char value[1] = {};
	auto result = entry_.ReadValue(std::as_writable_bytes(std::span(value)), 4);

	ASSERT_EQ(Status::ResourceExhausted(), result.status());
	EXPECT_EQ(1u, result.size());
	EXPECT_EQ(value[0], 'E');
	}

	TEST_F(ValidEntryInFlash, ReadValue_WithOffset_EmptyRead) {
	char value[16] = {'?'};
	auto result = entry_.ReadValue(std::as_writable_bytes(std::span(value)), 6);

	ASSERT_EQ(OkStatus(), result.status());
	EXPECT_EQ(0u, result.size());
	EXPECT_EQ(value[0], '?');
	}

	TEST_F(ValidEntryInFlash, ReadValue_WithOffset_PastEnd) {
	char value[16] = {};
	auto result = entry_.ReadValue(std::as_writable_bytes(std::span(value)), 7);

	EXPECT_EQ(Status::OutOfRange(), result.status());
	EXPECT_EQ(0u, result.size());
	}

	TEST(ValidEntry, Write) {
	FakeFlashMemoryBuffer<1024, 4> flash;
	FlashPartition partition(&flash, 0, flash.sector_count(), 32);

	Entry entry = Entry::Valid(
	partition, 64, kFormatWithChecksum, "key45", kValue1, kTransactionId1);

	auto result = entry.Write("key45", kValue1);
	EXPECT_EQ(OkStatus(), result.status());
	EXPECT_EQ(32u, result.size());
	EXPECT_EQ(std::memcmp(&flash.buffer()[64], kEntry1.data(), kEntry1.size()),
	0);
	}

	constexpr auto kHeader2 = bytes::String(
	"\x42\x51\x16\xad" // magic
	"\xba\xb3\x00\x00" // checksum (CRC16)
	"\x00" // alignment
	"\x01" // key length
	"\xff\xff" // value size
	"\x00\x01\x02\x03" // transaction ID
	);

	constexpr auto kKeyAndPadding2 =
	bytes::String("K\0\0\0\0\0\0\0\0\0\0\0\0\0\0\0");

	class TombstoneEntryInFlash : public ::testing::Test {
	protected:
	TombstoneEntryInFlash()
	: flash_(bytes::Concat(kHeader2, kKeyAndPadding2)), partition_(&flash_) {
	EXPECT_EQ(OkStatus(), Entry::Read(partition_, 0, kFormats, &entry_));
	}

	FakeFlashMemoryBuffer<1024, 4> flash_;
	FlashPartition partition_;
	Entry entry_;
	};

	TEST_F(TombstoneEntryInFlash, PassesChecksumVerification) {
	EXPECT_EQ(OkStatus(), entry_.VerifyChecksumInFlash());
	EXPECT_EQ(OkStatus(), entry_.VerifyChecksum("K", {}));
	}

	TEST_F(TombstoneEntryInFlash, HeaderContents) {
	EXPECT_EQ(entry_.magic(), kMagicWithChecksum);
	EXPECT_EQ(entry_.key_length(), 1u);
	EXPECT_EQ(entry_.value_size(), 0u);
	EXPECT_EQ(entry_.transaction_id(), 0x03020100u);
	EXPECT_TRUE(entry_.deleted());
	}

	TEST_F(TombstoneEntryInFlash, ReadKey) {
	Entry::KeyBuffer key = {};
	auto result = entry_.ReadKey(key);

	ASSERT_EQ(OkStatus(), result.status());
	EXPECT_EQ(result.size(), entry_.key_length());
	EXPECT_STREQ(key.data(), "K");
	}

	TEST_F(TombstoneEntryInFlash, ReadValue) {
	char value[32] = {};
	auto result = entry_.ReadValue(std::as_writable_bytes(std::span(value)));

	ASSERT_EQ(OkStatus(), result.status());
	EXPECT_EQ(0u, result.size());
	}

	TEST(TombstoneEntry, Write) {
	FakeFlashMemoryBuffer<1024, 4> flash;
	FlashPartition partition(&flash);
	ChecksumCrc16 checksum;

	Entry entry =
	Entry::Tombstone(partition, 16, kFormatWithChecksum, "K", 0x03020100);

	auto result = entry.Write("K", {});
	EXPECT_EQ(OkStatus(), result.status());
	EXPECT_EQ(32u, result.size());
	EXPECT_EQ(std::memcmp(&flash.buffer()[16],
	bytes::Concat(kHeader2, kKeyAndPadding2).data(),
	kEntry1.size()),
	0);
	}

	TEST(Entry, Checksum_NoChecksumRequiresZero) {
	FakeFlashMemoryBuffer<1024, 4> flash(kEntry1);
	FlashPartition partition(&flash);
	Entry entry;

	const EntryFormat format{kMagicWithChecksum, nullptr};
	const internal::EntryFormats formats(format);

	ASSERT_EQ(OkStatus(), Entry::Read(partition, 0, formats, &entry));

	EXPECT_EQ(Status::DataLoss(), entry.VerifyChecksumInFlash());
	EXPECT_EQ(Status::DataLoss(), entry.VerifyChecksum({}, {}));

	std::memset(&flash.buffer()[4], 0, 4); // set the checksum field to 0
	ASSERT_EQ(OkStatus(), Entry::Read(partition, 0, formats, &entry));
	EXPECT_EQ(OkStatus(), entry.VerifyChecksumInFlash());
	EXPECT_EQ(OkStatus(), entry.VerifyChecksum({}, {}));
	}

	TEST(Entry, Checksum_ChecksPadding) {
	FakeFlashMemoryBuffer<1024, 4> flash(
	bytes::Concat(kHeader1, kKey1, kValue1, bytes::String("\0\0\0\0\1")));
	FlashPartition partition(&flash);
	Entry entry;
	ASSERT_EQ(OkStatus(), Entry::Read(partition, 0, kFormats, &entry));

	// Last byte in padding is a 1; should fail.
	EXPECT_EQ(Status::DataLoss(), entry.VerifyChecksumInFlash());

	// The in-memory verification fills in 0s for the padding.
	EXPECT_EQ(OkStatus(), entry.VerifyChecksum("key45", kValue1));

	flash.buffer()[kEntry1.size() - 1] = byte{0};
	EXPECT_EQ(OkStatus(), entry.VerifyChecksumInFlash());
	}

	TEST_F(ValidEntryInFlash, Update_SameFormat_TransactionIdIsUpdated) {
	ASSERT_EQ(OkStatus(),
	entry_.Update(kFormatWithChecksum, kTransactionId1 + 3));

	EXPECT_EQ(kFormatWithChecksum.magic, entry_.magic());
	EXPECT_EQ(0u, entry_.address());
	EXPECT_EQ(kTransactionId1 + 3, entry_.transaction_id());
	EXPECT_FALSE(entry_.deleted());
	}

	TEST_F(ValidEntryInFlash,
	Update_DifferentFormat_MagicAndTransactionIdAreUpdated) {
	ASSERT_EQ(OkStatus(), entry_.Update(kFormat, kTransactionId1 + 6));

	EXPECT_EQ(kFormat.magic, entry_.magic());
	EXPECT_EQ(0u, entry_.address());
	EXPECT_EQ(kTransactionId1 + 6, entry_.transaction_id());
	EXPECT_FALSE(entry_.deleted());
	}

	TEST_F(ValidEntryInFlash, Update_ReadError_WithChecksumIsError) {
	flash_.InjectReadError(FlashError::Unconditional(Status::Aborted()));

	EXPECT_EQ(Status::Aborted(),
	entry_.Update(kFormatWithChecksum, kTransactionId1 + 1));
	}

	// For 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 kNoChecksumFormat{.magic = 0x721bad24,
	.checksum = nullptr};

	TEST_F(ValidEntryInFlash, Update_ReadError_NoChecksumIsOkay) {
	flash_.InjectReadError(FlashError::Unconditional(Status::Aborted()));

	EXPECT_EQ(OkStatus(), entry_.Update(kNoChecksumFormat, kTransactionId1 + 1));
	}

	TEST_F(ValidEntryInFlash, Copy) {
	auto result = entry_.Copy(123);

	EXPECT_EQ(OkStatus(), result.status());
	EXPECT_EQ(entry_.size(), result.size());
	EXPECT_EQ(0,
	std::memcmp(
	&flash_.buffer().data()[123], kEntry1.data(), kEntry1.size()));
	}

	TEST_F(ValidEntryInFlash, Copy_ReadError) {
	flash_.InjectReadError(FlashError::Unconditional(Status::Unimplemented()));
	auto result = entry_.Copy(kEntry1.size());
	EXPECT_EQ(Status::Unimplemented(), result.status());
	EXPECT_EQ(0u, result.size());
	}

	constexpr uint32_t ByteSum(std::span<const byte> bytes, uint32_t value = 0) {
	for (byte b : bytes) {
	value += unsigned(b);
	}
	return value;
	}

	// Sums the bytes, adding one to each byte so that zeroes change the checksum.
	class ChecksumSummation final : public ChecksumAlgorithm {
	public:
	ChecksumSummation()
	: ChecksumAlgorithm(std::as_bytes(std::span(&sum_, 1))), sum_(0) {}

	void Reset() override { sum_ = 0; }

	void Update(std::span<const byte> data) override {
	for (byte b : data) {
	sum_ += unsigned(b) + 1; // Add 1 so zero-value bytes affect checksum.
	}
	}

	private:
	uint32_t sum_;
	} sum_checksum;

	// For 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 uint32_t kMagicWithSum = 0x6093aadb;
	constexpr EntryFormat kFormatWithSum{kMagicWithSum, &sum_checksum};
	constexpr internal::EntryFormats kFormatsWithSum(kFormatWithSum);

	template <size_t alignment>
	constexpr auto MakeNewFormatWithSumEntry() {
	constexpr uint8_t alignment_units = (alignment + 15) / 16 - 1;
	constexpr size_t size = AlignUp(kEntryWithoutPadding1.size(), alignment);

	constexpr uint32_t checksum =
	ByteSum(bytes::Concat(kFormatWithSum.magic)) + 0 /* checksum */ +
	alignment_units + kKey1.size() + kValue1.size() +
	ByteSum(bytes::Concat(kTransactionId1 + 1)) + ByteSum(kKey1) +
	ByteSum(kValue1) + size /* +1 for each byte in the checksum */;

	constexpr auto kNewHeader1 =
	bytes::Concat(kFormatWithSum.magic, // magic
	checksum, // checksum (byte sum)
	alignment_units, // alignment (in 16 B units)
	uint8_t(kKey1.size()), // key length
	uint16_t(kValue1.size()), // value size
	kTransactionId1 + 1); // transaction ID
	constexpr size_t padding = Padding(kEntryWithoutPadding1.size(), alignment);
	return bytes::Concat(
	kNewHeader1, kKey1, kValue1, bytes::Initialized<padding>(0));
	}

	TEST_F(ValidEntryInFlash, UpdateAndCopy_DifferentFormatSmallerAlignment) {
	// Uses 16-bit alignment, smaller than the original entry's alignment.
	ASSERT_EQ(OkStatus(), entry_.Update(kFormatWithSum, kTransactionId1 + 1));

	StatusWithSize result = entry_.Copy(kEntry1.size());
	ASSERT_EQ(OkStatus(), result.status());
	EXPECT_EQ(kEntry1.size(), result.size());

	constexpr auto new_data = MakeNewFormatWithSumEntry<16>();
	static_assert(new_data.size() == 32);

	EXPECT_EQ(
	0,
	std::memcmp(
	&flash_.buffer()[kEntry1.size()], new_data.data(), new_data.size()));
	Entry new_entry;
	ASSERT_EQ(OkStatus(),
	Entry::Read(partition_, 32, kFormatsWithSum, &new_entry));
	EXPECT_EQ(OkStatus(), new_entry.VerifyChecksumInFlash());
	EXPECT_EQ(kFormatWithSum.magic, new_entry.magic());
	EXPECT_EQ(kTransactionId1 + 1, new_entry.transaction_id());
	}

	TEST(ValidEntryInFlash, UpdateAndCopy_DifferentFormatSameAlignment) {
	// Use 32-bit alignment, the same as the original entry's alignment.
	FakeFlashMemoryBuffer<1024, 4> flash(kEntry1);
	FlashPartition partition(&flash, 0, 4, 32);
	Entry entry;
	ASSERT_EQ(OkStatus(), Entry::Read(partition, 0, kFormats, &entry));

	ASSERT_EQ(OkStatus(), entry.Update(kFormatWithSum, kTransactionId1 + 1));

	StatusWithSize result = entry.Copy(32);
	ASSERT_EQ(OkStatus(), result.status());
	EXPECT_EQ(AlignUp(kEntry1.size(), 32), result.size());

	constexpr auto new_data = MakeNewFormatWithSumEntry<32>();
	static_assert(new_data.size() == 32);

	EXPECT_EQ(0,
	std::memcmp(&flash.buffer()[32], new_data.data(), new_data.size()));

	Entry new_entry;
	ASSERT_EQ(OkStatus(),
	Entry::Read(partition, 32, kFormatsWithSum, &new_entry));
	EXPECT_EQ(OkStatus(), new_entry.VerifyChecksumInFlash());
	EXPECT_EQ(kTransactionId1 + 1, new_entry.transaction_id());
	}

	TEST(ValidEntryInFlash, UpdateAndCopy_DifferentFormatLargerAlignment) {
	// Use 64-bit alignment, larger than the original entry's alignment.
	FakeFlashMemoryBuffer<1024, 4> flash(kEntry1);
	FlashPartition partition(&flash, 0, 4, 64);
	Entry entry;
	ASSERT_EQ(OkStatus(), Entry::Read(partition, 0, kFormats, &entry));

	ASSERT_EQ(OkStatus(), entry.Update(kFormatWithSum, kTransactionId1 + 1));

	StatusWithSize result = entry.Copy(64);
	ASSERT_EQ(OkStatus(), result.status());
	EXPECT_EQ(AlignUp(kEntry1.size(), 64), result.size());

	constexpr auto new_data = MakeNewFormatWithSumEntry<64>();
	static_assert(new_data.size() == 64);

	EXPECT_EQ(0,
	std::memcmp(&flash.buffer()[64], new_data.data(), new_data.size()));

	Entry new_entry;
	ASSERT_EQ(OkStatus(),
	Entry::Read(partition, 64, kFormatsWithSum, &new_entry));
	EXPECT_EQ(OkStatus(), new_entry.VerifyChecksumInFlash());
	EXPECT_EQ(kTransactionId1 + 1, new_entry.transaction_id());
	}

	TEST_F(ValidEntryInFlash, UpdateAndCopy_NoChecksum_UpdatesToNewFormat) {
	// For 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 no_checksum{.magic = 0x43fae18f, .checksum = nullptr};

	ASSERT_EQ(OkStatus(), entry_.Update(no_checksum, kTransactionId1 + 1));

	auto result = entry_.Copy(kEntry1.size());
	ASSERT_EQ(OkStatus(), result.status());
	EXPECT_EQ(kEntry1.size(), result.size());

	constexpr auto kNewHeader1 =
	bytes::Concat(no_checksum.magic, // magic
	uint32_t(0), // checksum (none)
	uint8_t(0), // alignment (changed to 16 B from 32)
	uint8_t(kKey1.size()), // key length
	uint16_t(kValue1.size()), // value size
	kTransactionId1 + 1); // transaction ID
	constexpr auto kNewEntry1 =
	bytes::Concat(kNewHeader1, kKey1, kValue1, kPadding1);

	EXPECT_EQ(0,
	std::memcmp(&flash_.buffer()[kEntry1.size()],
	kNewEntry1.data(),
	kNewEntry1.size()));
	}

	TEST_F(ValidEntryInFlash, UpdateAndCopyMultple_DifferentFormat) {
	ASSERT_EQ(OkStatus(), entry_.Update(kFormatWithSum, kTransactionId1 + 6));

	FlashPartition::Address new_address = entry_.size();

	for (int i = 0; i < 10; i++) {
	StatusWithSize copy_result = entry_.Copy(new_address + (i * entry_.size()));
	ASSERT_EQ(OkStatus(), copy_result.status());
	ASSERT_EQ(kEntry1.size(), copy_result.size());
	}

	for (int j = 0; j < 10; j++) {
	Entry entry;
	FlashPartition::Address read_address = (new_address + (j * entry_.size()));
	ASSERT_EQ(OkStatus(),
	Entry::Read(partition_, read_address, kFormatsWithSum, &entry));

	EXPECT_EQ(OkStatus(), entry.VerifyChecksumInFlash());
	EXPECT_EQ(kFormatWithSum.magic, entry.magic());
	EXPECT_EQ(read_address, entry.address());
	EXPECT_EQ(kTransactionId1 + 6, entry.transaction_id());
	EXPECT_FALSE(entry.deleted());
	}
	}

	TEST_F(ValidEntryInFlash, DifferentFormat_UpdatedCopy_FailsWithWrongMagic) {
	ASSERT_EQ(OkStatus(), entry_.Update(kFormatWithSum, kTransactionId1 + 6));

	FlashPartition::Address new_address = entry_.size();

	StatusWithSize copy_result = entry_.Copy(new_address);
	ASSERT_EQ(OkStatus(), copy_result.status());
	ASSERT_EQ(kEntry1.size(), copy_result.size());

	Entry entry;
	ASSERT_EQ(Status::DataLoss(),
	Entry::Read(partition_, new_address, kFormats, &entry));
	}

	TEST_F(ValidEntryInFlash, UpdateAndCopy_WriteError) {
	flash_.InjectWriteError(FlashError::Unconditional(Status::Cancelled()));

	ASSERT_EQ(OkStatus(), entry_.Update(kNoChecksumFormat, kTransactionId1 + 1));

	auto result = entry_.Copy(kEntry1.size());
	EXPECT_EQ(Status::Cancelled(), result.status());
	EXPECT_EQ(kEntry1.size(), result.size());
	}

	} // namespace
	} // namespace pw::kvs::internal