summaryrefslogtreecommitdiff
path: root/quantum/wear_leveling/tests/wear_leveling_2byte_optimized_writes.cpp
blob: 0b03113c89ff8ab69e29842ad03bd0a7238f026b (plain)
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
17
18
19
20
21
22
23
24
25
26
27
28
29
30
31
32
33
34
35
36
37
38
39
40
41
42
43
44
45
46
47
48
49
50
51
52
53
54
55
56
57
58
59
60
61
62
63
64
65
66
67
68
69
70
71
72
73
74
75
76
77
78
79
80
81
82
83
84
85
86
87
88
89
90
91
92
93
94
95
96
97
98
99
100
101
102
103
104
105
106
107
108
109
110
111
112
113
114
115
116
117
118
119
120
121
122
123
124
125
126
127
128
129
130
131
132
133
134
135
136
137
138
139
140
141
142
143
144
145
146
147
148
149
150
151
152
153
154
155
156
157
158
159
160
161
162
163
164
165
166
167
168
169
170
171
172
173
174
175
176
177
178
179
180
181
182
183
184
185
186
187
188
189
190
191
192
193
194
195
196
197
198
199
200
201
202
203
204
205
206
207
208
209
210
211
212
213
214
215
216
217
218
219
220
221
222
223
224
225
226
227
228
229
230
231
232
233
234
235
236
237
238
239
240
241
242
243
244
245
246
247
248
249
250
251
252
253
254
255
256
257
258
259
260
261
262
263
264
265
266
267
268
269
270
271
272
273
274
275
276
277
278
279
280
281
282
283
284
285
286
287
288
289
290
291
292
293
294
295
// Copyright 2022 Nick Brassel (@tzarc)
// SPDX-License-Identifier: GPL-2.0-or-later
#include <numeric>
#include "gtest/gtest.h"
#include "gmock/gmock.h"
#include "backing_mocks.hpp"

class WearLeveling2ByteOptimizedWrites : public ::testing::Test {
   protected:
    void SetUp() override {
        MockBackingStore::Instance().reset_instance();
        wear_leveling_init();
    }
};

static std::array<std::uint8_t, WEAR_LEVELING_LOGICAL_SIZE> verify_data;

static wear_leveling_status_t test_write(const uint32_t address, const void* value, size_t length) {
    memcpy(&verify_data[address], value, length);
    return wear_leveling_write(address, value, length);
}

/**
 * This test ensures the correct number of backing store writes occurs with a multibyte write, given the input buffer size.
 */
TEST_F(WearLeveling2ByteOptimizedWrites, MultibyteBackingStoreWriteCounts) {
    auto& inst = MockBackingStore::Instance();

    for (std::size_t length = 1; length <= 5; ++length) {
        // Clear things out
        std::fill(verify_data.begin(), verify_data.end(), 0);
        inst.reset_instance();
        wear_leveling_init();

        // Generate a test block of data
        std::vector<std::uint8_t> testvalue(length);
        std::iota(testvalue.begin(), testvalue.end(), 0x20);

        // Write the data
        EXPECT_EQ(test_write(2000, testvalue.data(), testvalue.size()), WEAR_LEVELING_SUCCESS) << "Write failed with incorrect status";

        std::size_t expected;
        if (length > 3) {
            expected = 4;
        } else if (length > 1) {
            expected = 3;
        } else {
            expected = 2;
        }

        // Check that we got the expected number of write log entries
        EXPECT_EQ(std::distance(inst.log_begin(), inst.log_end()), expected);
    }
}

/**
 * This test runs through writing U16 values of `0` or `1` over the entire logical address range, to even addresses only.
 *  - Addresses <16384 will result in a single optimised backing write
 *  - Higher addresses will result in a multibyte write of 3 backing writes
 */
TEST_F(WearLeveling2ByteOptimizedWrites, WriteOneThenZeroToEvenAddresses) {
    auto& inst = MockBackingStore::Instance();

    // Only attempt writes for each address up to a limit that would NOT force a consolidated data write.
    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
    std::size_t final_address;
    for (uint32_t address = 0; address < WEAR_LEVELING_LOGICAL_SIZE; address += (writes_per_loop * 2)) {
        // Clear things out
        std::fill(verify_data.begin(), verify_data.end(), 0);
        inst.reset_instance();
        wear_leveling_init();

        // Loop through all the addresses in this range
        std::size_t expected = 0;
        for (uint32_t offset = 0; offset < (writes_per_loop * 2); offset += 2) {
            // If we're about to exceed the limit of the logical store, skip the writes
            if (address + offset + 2 > WEAR_LEVELING_LOGICAL_SIZE) {
                break;
            }

            // 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.
            uint16_t val = 1;
            EXPECT_EQ(test_write(address + offset, &val, sizeof(val)), WEAR_LEVELING_SUCCESS) << "Write failed with incorrect status";
            val = 0;
            EXPECT_EQ(test_write(address + offset, &val, sizeof(val)), WEAR_LEVELING_SUCCESS) << "Write failed with incorrect status";

            std::size_t backing_store_writes_expected = 0;
            if (address + offset < 16384) {
                // 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
                backing_store_writes_expected = 2;
            } else {
                // All other addresses result in a multibyte write (3 backing store writes) to write two local bytes of data
                backing_store_writes_expected = 6;
            }

            // Keep track of the total number of expected writes to the backing store
            expected += backing_store_writes_expected;

            // Verify we're at the correct number of writes
            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);

            // Verify that the write log entries we expect are actually present
            std::size_t       write_index = expected - backing_store_writes_expected;
            auto              write_iter  = inst.log_begin() + write_index;
            write_log_entry_t e;
            if (address + offset < 16384) {
                // 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
                for (std::size_t i = 0; i < 2; ++i) {
                    e.raw16[0] = write_iter->value;
                    EXPECT_EQ(LOG_ENTRY_GET_TYPE(e), LOG_ENTRY_TYPE_WORD_01) << "Invalid write log entry type at " << (address + offset);
                    ++write_iter;
                }
            } else {
                // Multibyte write
                e.raw16[0] = write_iter->value;
                EXPECT_EQ(LOG_ENTRY_GET_TYPE(e), LOG_ENTRY_TYPE_MULTIBYTE) << "Invalid write log entry type at " << (address + offset);
                EXPECT_EQ(LOG_ENTRY_MULTIBYTE_GET_LENGTH(e), 2) << "Invalid write log entry length at " << (address + offset);
                ++write_iter;
            }

            // Keep track of the final address written, so we can verify the entire logical range was handled
            final_address = address + offset;
        }

        // Verify the number of writes that occurred to the backing store
        size_t backing_write_count = std::distance(inst.log_begin(), inst.log_end());
        EXPECT_EQ(backing_write_count, expected) << "Invalid write count at address " << address;

        // Verify the data is what we expected
        std::array<std::uint8_t, WEAR_LEVELING_LOGICAL_SIZE> readback;
        EXPECT_EQ(wear_leveling_read(0, readback.data(), WEAR_LEVELING_LOGICAL_SIZE), WEAR_LEVELING_SUCCESS) << "Failed to read back the saved data";
        EXPECT_TRUE(memcmp(readback.data(), verify_data.data(), WEAR_LEVELING_LOGICAL_SIZE) == 0) << "Readback for address " << address << " did not match";

        // Re-init and re-read, testing the reload capability
        EXPECT_NE(wear_leveling_init(), WEAR_LEVELING_FAILED) << "Re-initialisation failed";
        EXPECT_EQ(wear_leveling_read(0, readback.data(), WEAR_LEVELING_LOGICAL_SIZE), WEAR_LEVELING_SUCCESS) << "Failed to read back the saved data";
        EXPECT_TRUE(memcmp(readback.data(), verify_data.data(), WEAR_LEVELING_LOGICAL_SIZE) == 0) << "Readback for address " << address << " did not match";
    }

    // Verify the full range of the logical area got written
    EXPECT_EQ(final_address, WEAR_LEVELING_LOGICAL_SIZE - 2) << "Invalid final write address";
}

/**
 * This test runs through writing U16 values of `0` or `1` over the entire logical address range, to odd addresses only.
 *  - Addresses <63 will result in 2 optimised backing writes
 *  - 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
 *  - Higher addresses will result in a multibyte write of 3 backing writes
 */
TEST_F(WearLeveling2ByteOptimizedWrites, WriteOneThenZeroToOddAddresses) {
    auto& inst = MockBackingStore::Instance();

    // Only attempt writes for each address up to a limit that would NOT force a consolidated data write.
    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
    std::size_t final_address;
    for (uint32_t address = 1; address < WEAR_LEVELING_LOGICAL_SIZE; address += (writes_per_loop * 2)) {
        // Clear things out
        std::fill(verify_data.begin(), verify_data.end(), 0);
        inst.reset_instance();
        wear_leveling_init();

        // Loop through all the addresses in this range
        std::size_t expected = 0;
        for (uint32_t offset = 0; offset < (writes_per_loop * 2); offset += 2) {
            // If we're about to exceed the limit of the logical store, skip the writes
            if (address + offset + 2 > WEAR_LEVELING_LOGICAL_SIZE) {
                break;
            }

            // 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.
            uint16_t val = 1;
            EXPECT_EQ(test_write(address + offset, &val, sizeof(val)), WEAR_LEVELING_SUCCESS) << "Write failed with incorrect status";
            val = 0;
            EXPECT_EQ(test_write(address + offset, &val, sizeof(val)), WEAR_LEVELING_SUCCESS) << "Write failed with incorrect status";

            std::size_t backing_store_writes_expected = 0;
            if (address + offset < 63) {
                // 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
                backing_store_writes_expected = 4;
            } else if (address + offset == 63) {
                // If we're straddling the boundary for optimised bytes (addr==64), then the first logical byte is written using the optimised write (1 backing
                // store write), and the second logical byte uses a multibyte write (2 backing store writes)
                backing_store_writes_expected = 2    // First logical bytes written using optimised log entries
                                                + 4; // Second logical bytes written using multibyte log entries
            } else {
                // All other addresses result in a multibyte write (3 backing store writes) to write two local bytes of data
                backing_store_writes_expected = 6;
            }

            // Keep track of the total number of expected writes to the backing store
            expected += backing_store_writes_expected;

            // Verify we're at the correct number of writes
            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);

            // Verify that the write log entries we expect are actually present
            std::size_t       write_index = expected - backing_store_writes_expected;
            auto              write_iter  = inst.log_begin() + write_index;
            write_log_entry_t e;
            if (address + offset < 63) {
                // 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
                for (std::size_t i = 0; i < 4; ++i) {
                    e.raw16[0] = write_iter->value;
                    EXPECT_EQ(LOG_ENTRY_GET_TYPE(e), LOG_ENTRY_TYPE_OPTIMIZED_64) << "Invalid write log entry type";
                    ++write_iter;
                }
            } else if (address + offset == 63) {
                // First log entry is the 64-addr optimised one
                e.raw16[0] = write_iter->value;
                EXPECT_EQ(LOG_ENTRY_GET_TYPE(e), LOG_ENTRY_TYPE_OPTIMIZED_64) << "Invalid write log entry type";
                ++write_iter;

                // Second log entry is the multibyte entry for the second logical byte
                e.raw16[0] = write_iter->value;
                EXPECT_EQ(LOG_ENTRY_GET_TYPE(e), LOG_ENTRY_TYPE_MULTIBYTE) << "Invalid write log entry type";
                EXPECT_EQ(LOG_ENTRY_MULTIBYTE_GET_LENGTH(e), 1) << "Invalid write log entry length";
                ++write_iter;
            } else {
                // Multibyte write
                e.raw16[0] = write_iter->value;
                EXPECT_EQ(LOG_ENTRY_GET_TYPE(e), LOG_ENTRY_TYPE_MULTIBYTE) << "Invalid write log entry type";
                EXPECT_EQ(LOG_ENTRY_MULTIBYTE_GET_LENGTH(e), 2) << "Invalid write log entry length";
                ++write_iter;
            }

            // Keep track of the final address written, so we can verify the entire logical range was handled
            final_address = address + offset;
        }

        // Verify the number of writes that occurred to the backing store
        size_t backing_write_count = std::distance(inst.log_begin(), inst.log_end());
        EXPECT_EQ(backing_write_count, expected) << "Invalid write count at address " << address;

        // Verify the data is what we expected
        std::array<std::uint8_t, WEAR_LEVELING_LOGICAL_SIZE> readback;
        EXPECT_EQ(wear_leveling_read(0, readback.data(), WEAR_LEVELING_LOGICAL_SIZE), WEAR_LEVELING_SUCCESS) << "Failed to read back the saved data";
        EXPECT_TRUE(memcmp(readback.data(), verify_data.data(), WEAR_LEVELING_LOGICAL_SIZE) == 0) << "Readback for address " << address << " did not match";

        // Re-init and re-read, testing the reload capability
        EXPECT_NE(wear_leveling_init(), WEAR_LEVELING_FAILED) << "Re-initialisation failed";
        EXPECT_EQ(wear_leveling_read(0, readback.data(), WEAR_LEVELING_LOGICAL_SIZE), WEAR_LEVELING_SUCCESS) << "Failed to read back the saved data";
        EXPECT_TRUE(memcmp(readback.data(), verify_data.data(), WEAR_LEVELING_LOGICAL_SIZE) == 0) << "Readback for address " << address << " did not match";
    }

    // Verify the full range of the logical area got written
    EXPECT_EQ(final_address, WEAR_LEVELING_LOGICAL_SIZE - 3) << "Invalid final write address";
}

/**
 * This test verifies readback after playback of the write log, simulating power loss and reboot.
 */
TEST_F(WearLeveling2ByteOptimizedWrites, PlaybackReadbackOptimized64_Success) {
    auto& inst     = MockBackingStore::Instance();
    auto  logstart = inst.storage_begin() + (WEAR_LEVELING_LOGICAL_SIZE / sizeof(backing_store_int_t));

    // Invalid FNV1a_64 hash
    (logstart + 0)->set(0);
    (logstart + 1)->set(0);
    (logstart + 2)->set(0);
    (logstart + 3)->set(0);

    // Set up a 1-byte logical write of 0x11 at logical offset 0x01
    auto entry0 = LOG_ENTRY_MAKE_OPTIMIZED_64(0x01, 0x11);
    (logstart + 4)->set(~entry0.raw16[0]); // start at offset 4 to skip FNV1a_64 result

    wear_leveling_init();
    uint8_t tmp;

    wear_leveling_read(0x01, &tmp, sizeof(tmp));
    EXPECT_EQ(tmp, 0x11) << "Failed to read back the seeded data";
}

/**
 * This test verifies readback after playback of the write log, simulating power loss and reboot.
 */
TEST_F(WearLeveling2ByteOptimizedWrites, PlaybackReadbackWord01_Success) {
    auto& inst     = MockBackingStore::Instance();
    auto  logstart = inst.storage_begin() + (WEAR_LEVELING_LOGICAL_SIZE / sizeof(backing_store_int_t));

    // Invalid FNV1a_64 hash
    (logstart + 0)->set(0);
    (logstart + 1)->set(0);
    (logstart + 2)->set(0);
    (logstart + 3)->set(0);

    // Set up a 1-byte logical write of 1 at logical offset 0x02
    auto entry0 = LOG_ENTRY_MAKE_WORD_01(0x02, 1);
    (logstart + 4)->set(~entry0.raw16[0]); // start at offset 4 to skip FNV1a_64 result

    wear_leveling_init();
    uint8_t tmp;

    wear_leveling_read(0x02, &tmp, sizeof(tmp));
    EXPECT_EQ(tmp, 1) << "Failed to read back the seeded data";
}