01ecf332ff
* Initial import of wear-leveling algorithm. * Alignment. * Docs tweaks. * Lock/unlock. * Update quantum/wear_leveling/wear_leveling_internal.h Co-authored-by: Stefan Kerkmann <karlk90@pm.me> * More tests, fix issue with consolidation when unlocked. * More tests. * Review comments. * Add plumbing for FNV1a. * Another test checking that checksum mismatch clears the cache. * Check that the write log still gets played back. Co-authored-by: Stefan Kerkmann <karlk90@pm.me>
295 lines
15 KiB
C++
295 lines
15 KiB
C++
// Copyright 2022 Nick Brassel (@tzarc)
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// SPDX-License-Identifier: GPL-2.0-or-later
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#include <numeric>
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#include "gtest/gtest.h"
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#include "gmock/gmock.h"
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#include "backing_mocks.hpp"
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class WearLeveling2ByteOptimizedWrites : public ::testing::Test {
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protected:
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void SetUp() override {
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MockBackingStore::Instance().reset_instance();
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wear_leveling_init();
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}
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};
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static std::array<std::uint8_t, WEAR_LEVELING_LOGICAL_SIZE> verify_data;
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static wear_leveling_status_t test_write(const uint32_t address, const void* value, size_t length) {
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memcpy(&verify_data[address], value, length);
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return wear_leveling_write(address, value, length);
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}
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/**
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* This test ensures the correct number of backing store writes occurs with a multibyte write, given the input buffer size.
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*/
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TEST_F(WearLeveling2ByteOptimizedWrites, MultibyteBackingStoreWriteCounts) {
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auto& inst = MockBackingStore::Instance();
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for (std::size_t length = 1; length <= 5; ++length) {
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// Clear things out
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std::fill(verify_data.begin(), verify_data.end(), 0);
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inst.reset_instance();
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wear_leveling_init();
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// Generate a test block of data
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std::vector<std::uint8_t> testvalue(length);
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std::iota(testvalue.begin(), testvalue.end(), 0x20);
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// Write the data
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EXPECT_EQ(test_write(2000, testvalue.data(), testvalue.size()), WEAR_LEVELING_SUCCESS) << "Write failed with incorrect status";
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std::size_t expected;
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if (length > 3) {
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expected = 4;
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} else if (length > 1) {
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expected = 3;
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} else {
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expected = 2;
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}
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// Check that we got the expected number of write log entries
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EXPECT_EQ(std::distance(inst.log_begin(), inst.log_end()), expected);
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}
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}
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/**
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* This test runs through writing U16 values of `0` or `1` over the entire logical address range, to even addresses only.
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* - Addresses <16384 will result in a single optimised backing write
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* - Higher addresses will result in a multibyte write of 3 backing writes
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*/
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TEST_F(WearLeveling2ByteOptimizedWrites, WriteOneThenZeroToEvenAddresses) {
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auto& inst = MockBackingStore::Instance();
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// Only attempt writes for each address up to a limit that would NOT force a consolidated data write.
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std::size_t writes_per_loop = (MOCK_WRITE_LOG_MAX_ENTRIES::value / 6) - 1; // Worst case is 6 writes for each pair of writes of 0/1
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std::size_t final_address;
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for (uint32_t address = 0; address < WEAR_LEVELING_LOGICAL_SIZE; address += (writes_per_loop * 2)) {
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// Clear things out
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std::fill(verify_data.begin(), verify_data.end(), 0);
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inst.reset_instance();
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wear_leveling_init();
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// Loop through all the addresses in this range
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std::size_t expected = 0;
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for (uint32_t offset = 0; offset < (writes_per_loop * 2); offset += 2) {
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// If we're about to exceed the limit of the logical store, skip the writes
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if (address + offset + 2 > WEAR_LEVELING_LOGICAL_SIZE) {
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break;
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}
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// The default erased value of the wear-leveling cache is zero, so we write a one first, then a zero, to ensure a backing store write occurs.
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uint16_t val = 1;
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EXPECT_EQ(test_write(address + offset, &val, sizeof(val)), WEAR_LEVELING_SUCCESS) << "Write failed with incorrect status";
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val = 0;
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EXPECT_EQ(test_write(address + offset, &val, sizeof(val)), WEAR_LEVELING_SUCCESS) << "Write failed with incorrect status";
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std::size_t backing_store_writes_expected = 0;
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if (address + offset < 16384) {
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// A U16 value of 0/1 at an even address <16384 will result in 1 backing write each, so we need 2 backing writes for 2 logical writes
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backing_store_writes_expected = 2;
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} else {
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// All other addresses result in a multibyte write (3 backing store writes) to write two local bytes of data
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backing_store_writes_expected = 6;
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}
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// Keep track of the total number of expected writes to the backing store
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expected += backing_store_writes_expected;
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// Verify we're at the correct number of writes
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EXPECT_EQ(std::distance(inst.log_begin(), inst.log_end()), expected) << "Write log doesn't match required number of backing store writes for address " << (address + offset);
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// Verify that the write log entries we expect are actually present
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std::size_t write_index = expected - backing_store_writes_expected;
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auto write_iter = inst.log_begin() + write_index;
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write_log_entry_t e;
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if (address + offset < 16384) {
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// A U16 value of 0/1 at an even address <16384 will result in 1 backing write each, so we need 2 backing writes for 2 logical writes
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for (std::size_t i = 0; i < 2; ++i) {
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e.raw16[0] = write_iter->value;
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EXPECT_EQ(LOG_ENTRY_GET_TYPE(e), LOG_ENTRY_TYPE_WORD_01) << "Invalid write log entry type at " << (address + offset);
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++write_iter;
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}
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} else {
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// Multibyte write
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e.raw16[0] = write_iter->value;
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EXPECT_EQ(LOG_ENTRY_GET_TYPE(e), LOG_ENTRY_TYPE_MULTIBYTE) << "Invalid write log entry type at " << (address + offset);
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EXPECT_EQ(LOG_ENTRY_MULTIBYTE_GET_LENGTH(e), 2) << "Invalid write log entry length at " << (address + offset);
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++write_iter;
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}
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// Keep track of the final address written, so we can verify the entire logical range was handled
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final_address = address + offset;
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}
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// Verify the number of writes that occurred to the backing store
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size_t backing_write_count = std::distance(inst.log_begin(), inst.log_end());
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EXPECT_EQ(backing_write_count, expected) << "Invalid write count at address " << address;
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// Verify the data is what we expected
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std::array<std::uint8_t, WEAR_LEVELING_LOGICAL_SIZE> readback;
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EXPECT_EQ(wear_leveling_read(0, readback.data(), WEAR_LEVELING_LOGICAL_SIZE), WEAR_LEVELING_SUCCESS) << "Failed to read back the saved data";
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EXPECT_TRUE(memcmp(readback.data(), verify_data.data(), WEAR_LEVELING_LOGICAL_SIZE) == 0) << "Readback for address " << address << " did not match";
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// Re-init and re-read, testing the reload capability
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EXPECT_NE(wear_leveling_init(), WEAR_LEVELING_FAILED) << "Re-initialisation failed";
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EXPECT_EQ(wear_leveling_read(0, readback.data(), WEAR_LEVELING_LOGICAL_SIZE), WEAR_LEVELING_SUCCESS) << "Failed to read back the saved data";
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EXPECT_TRUE(memcmp(readback.data(), verify_data.data(), WEAR_LEVELING_LOGICAL_SIZE) == 0) << "Readback for address " << address << " did not match";
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}
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// Verify the full range of the logical area got written
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EXPECT_EQ(final_address, WEAR_LEVELING_LOGICAL_SIZE - 2) << "Invalid final write address";
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}
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/**
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* This test runs through writing U16 values of `0` or `1` over the entire logical address range, to odd addresses only.
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* - Addresses <63 will result in 2 optimised backing writes
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* - Address 63 results in a single optimised backing write for the first logical byte, and a multibyte write of 2 backing writes for the second logical byte
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* - Higher addresses will result in a multibyte write of 3 backing writes
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*/
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TEST_F(WearLeveling2ByteOptimizedWrites, WriteOneThenZeroToOddAddresses) {
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auto& inst = MockBackingStore::Instance();
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// Only attempt writes for each address up to a limit that would NOT force a consolidated data write.
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std::size_t writes_per_loop = (MOCK_WRITE_LOG_MAX_ENTRIES::value / 6) - 1; // Worst case is 6 writes for each pair of writes of 0/1
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std::size_t final_address;
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for (uint32_t address = 1; address < WEAR_LEVELING_LOGICAL_SIZE; address += (writes_per_loop * 2)) {
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// Clear things out
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std::fill(verify_data.begin(), verify_data.end(), 0);
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inst.reset_instance();
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wear_leveling_init();
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// Loop through all the addresses in this range
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std::size_t expected = 0;
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for (uint32_t offset = 0; offset < (writes_per_loop * 2); offset += 2) {
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// If we're about to exceed the limit of the logical store, skip the writes
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if (address + offset + 2 > WEAR_LEVELING_LOGICAL_SIZE) {
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break;
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}
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// The default erased value of the wear-leveling cache is zero, so we write a one first, then a zero, to ensure a backing store write occurs.
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uint16_t val = 1;
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EXPECT_EQ(test_write(address + offset, &val, sizeof(val)), WEAR_LEVELING_SUCCESS) << "Write failed with incorrect status";
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val = 0;
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EXPECT_EQ(test_write(address + offset, &val, sizeof(val)), WEAR_LEVELING_SUCCESS) << "Write failed with incorrect status";
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std::size_t backing_store_writes_expected = 0;
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if (address + offset < 63) {
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// A U16 value of 0/1 at an odd address <64 will result in 2 backing writes each, so we need 4 backing writes for 2 logical writes
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backing_store_writes_expected = 4;
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} else if (address + offset == 63) {
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// If we're straddling the boundary for optimised bytes (addr==64), then the first logical byte is written using the optimised write (1 backing
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// store write), and the second logical byte uses a multibyte write (2 backing store writes)
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backing_store_writes_expected = 2 // First logical bytes written using optimised log entries
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+ 4; // Second logical bytes written using multibyte log entries
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} else {
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// All other addresses result in a multibyte write (3 backing store writes) to write two local bytes of data
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backing_store_writes_expected = 6;
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}
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// Keep track of the total number of expected writes to the backing store
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expected += backing_store_writes_expected;
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// Verify we're at the correct number of writes
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EXPECT_EQ(std::distance(inst.log_begin(), inst.log_end()), expected) << "Write log doesn't match required number of backing store writes for address " << (address + offset);
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// Verify that the write log entries we expect are actually present
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std::size_t write_index = expected - backing_store_writes_expected;
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auto write_iter = inst.log_begin() + write_index;
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write_log_entry_t e;
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if (address + offset < 63) {
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// A U16 value of 0/1 at an odd address <64 will result in 2 backing writes each, so we need 4 backing writes for 2 logical writes
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for (std::size_t i = 0; i < 4; ++i) {
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e.raw16[0] = write_iter->value;
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EXPECT_EQ(LOG_ENTRY_GET_TYPE(e), LOG_ENTRY_TYPE_OPTIMIZED_64) << "Invalid write log entry type";
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++write_iter;
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}
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} else if (address + offset == 63) {
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// First log entry is the 64-addr optimised one
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e.raw16[0] = write_iter->value;
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EXPECT_EQ(LOG_ENTRY_GET_TYPE(e), LOG_ENTRY_TYPE_OPTIMIZED_64) << "Invalid write log entry type";
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++write_iter;
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// Second log entry is the multibyte entry for the second logical byte
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e.raw16[0] = write_iter->value;
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EXPECT_EQ(LOG_ENTRY_GET_TYPE(e), LOG_ENTRY_TYPE_MULTIBYTE) << "Invalid write log entry type";
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EXPECT_EQ(LOG_ENTRY_MULTIBYTE_GET_LENGTH(e), 1) << "Invalid write log entry length";
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++write_iter;
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} else {
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// Multibyte write
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e.raw16[0] = write_iter->value;
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EXPECT_EQ(LOG_ENTRY_GET_TYPE(e), LOG_ENTRY_TYPE_MULTIBYTE) << "Invalid write log entry type";
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EXPECT_EQ(LOG_ENTRY_MULTIBYTE_GET_LENGTH(e), 2) << "Invalid write log entry length";
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++write_iter;
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}
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// Keep track of the final address written, so we can verify the entire logical range was handled
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final_address = address + offset;
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}
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// Verify the number of writes that occurred to the backing store
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size_t backing_write_count = std::distance(inst.log_begin(), inst.log_end());
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EXPECT_EQ(backing_write_count, expected) << "Invalid write count at address " << address;
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// Verify the data is what we expected
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std::array<std::uint8_t, WEAR_LEVELING_LOGICAL_SIZE> readback;
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EXPECT_EQ(wear_leveling_read(0, readback.data(), WEAR_LEVELING_LOGICAL_SIZE), WEAR_LEVELING_SUCCESS) << "Failed to read back the saved data";
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EXPECT_TRUE(memcmp(readback.data(), verify_data.data(), WEAR_LEVELING_LOGICAL_SIZE) == 0) << "Readback for address " << address << " did not match";
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// Re-init and re-read, testing the reload capability
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EXPECT_NE(wear_leveling_init(), WEAR_LEVELING_FAILED) << "Re-initialisation failed";
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EXPECT_EQ(wear_leveling_read(0, readback.data(), WEAR_LEVELING_LOGICAL_SIZE), WEAR_LEVELING_SUCCESS) << "Failed to read back the saved data";
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EXPECT_TRUE(memcmp(readback.data(), verify_data.data(), WEAR_LEVELING_LOGICAL_SIZE) == 0) << "Readback for address " << address << " did not match";
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}
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// Verify the full range of the logical area got written
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EXPECT_EQ(final_address, WEAR_LEVELING_LOGICAL_SIZE - 3) << "Invalid final write address";
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}
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/**
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* This test verifies readback after playback of the write log, simulating power loss and reboot.
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*/
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TEST_F(WearLeveling2ByteOptimizedWrites, PlaybackReadbackOptimized64_Success) {
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auto& inst = MockBackingStore::Instance();
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auto logstart = inst.storage_begin() + (WEAR_LEVELING_LOGICAL_SIZE / sizeof(backing_store_int_t));
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// Invalid FNV1a_64 hash
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(logstart + 0)->set(0);
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(logstart + 1)->set(0);
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(logstart + 2)->set(0);
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(logstart + 3)->set(0);
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// Set up a 1-byte logical write of 0x11 at logical offset 0x01
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auto entry0 = LOG_ENTRY_MAKE_OPTIMIZED_64(0x01, 0x11);
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(logstart + 4)->set(~entry0.raw16[0]); // start at offset 4 to skip FNV1a_64 result
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wear_leveling_init();
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uint8_t tmp;
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wear_leveling_read(0x01, &tmp, sizeof(tmp));
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EXPECT_EQ(tmp, 0x11) << "Failed to read back the seeded data";
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}
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/**
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* This test verifies readback after playback of the write log, simulating power loss and reboot.
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*/
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TEST_F(WearLeveling2ByteOptimizedWrites, PlaybackReadbackWord01_Success) {
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auto& inst = MockBackingStore::Instance();
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auto logstart = inst.storage_begin() + (WEAR_LEVELING_LOGICAL_SIZE / sizeof(backing_store_int_t));
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// Invalid FNV1a_64 hash
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(logstart + 0)->set(0);
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(logstart + 1)->set(0);
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(logstart + 2)->set(0);
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(logstart + 3)->set(0);
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// Set up a 1-byte logical write of 1 at logical offset 0x02
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auto entry0 = LOG_ENTRY_MAKE_WORD_01(0x02, 1);
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(logstart + 4)->set(~entry0.raw16[0]); // start at offset 4 to skip FNV1a_64 result
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wear_leveling_init();
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uint8_t tmp;
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wear_leveling_read(0x02, &tmp, sizeof(tmp));
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EXPECT_EQ(tmp, 1) << "Failed to read back the seeded data";
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}
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