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qmk_firmware/platforms/test/eeprom_stm32_tests.cpp

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eeprom_stm32: implement high density wear leveling (#12567) * eeprom_stm32: implement wear leveling Update EECONFIG_MAGIC_NUMBER eeprom_stm32: check emulated eeprom size is large enough * eeprom_stm32: Increasing simulated EEPROM density on stm32 * Adding utility script to decode emulated eeprom * Adding unit tests * Applying qmk cformat changes * cleaned up flash mocking * Fix for stm32eeprom_parser.py checking via signature with wrong base * Fix for nk65 keyboard Co-authored-by: Ilya Zhuravlev <whatever@xyz.is> Co-authored-by: zvecr <git@zvecr.com>
2 years ago
 
  1. /* Copyright 2021 by Don Kjer

  2.  *
  3.  * This program is free software: you can redistribute it and/or modify
  4.  * it under the terms of the GNU General Public License as published by
  5.  * the Free Software Foundation, either version 2 of the License, or
  6.  * (at your option) any later version.
  7.  *
  8.  * This program is distributed in the hope that it will be useful,
  9.  * but WITHOUT ANY WARRANTY; without even the implied warranty of
  10.  * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the
  11.  * GNU General Public License for more details.
  12.  *
  13.  * You should have received a copy of the GNU General Public License
  14.  * along with this program.  If not, see <http://www.gnu.org/licenses/>.

  15.  */
  16. 

  17. #include "gtest/gtest.h"

  18. 

  19. extern "C" {
  20. #include "eeprom.h"

  21. }
  22. 

  23. /* Mock Flash Parameters:

  24.  *
  25.  * === Large Layout ===
  26.  * flash size: 65536
  27.  * page size: 2048
  28.  * density pages: 16
  29.  * Simulated EEPROM size: 16384
  30.  *
  31.  * FlashBuf Layout:
  32.  * [Unused | Compact |  Write Log  ]
  33.  * [0......|32768......|49152......65535]
  34.  *
  35.  * === Tiny Layout ===
  36.  * flash size: 1024
  37.  * page size: 512
  38.  * density pages: 1
  39.  * Simulated EEPROM size: 256
  40.  *
  41.  * FlashBuf Layout:
  42.  * [Unused | Compact |  Write Log  ]
  43.  * [0......|512......|768......1023]
  44.  *
  45.  */
  46. 

  47. #define LOG_SIZE EEPROM_SIZE

  48. #define LOG_BASE (MOCK_FLASH_SIZE - LOG_SIZE)

  49. #define EEPROM_BASE (LOG_BASE - EEPROM_SIZE)

  50. 

  51. /* Log encoding helpers */
  52. #define BYTE_VALUE(addr, value) (((addr) << 8) | (value))

  53. #define WORD_ZERO(addr) (0x8000 | ((addr) >> 1))

  54. #define WORD_ONE(addr) (0xA000 | ((addr) >> 1))

  55. #define WORD_NEXT(addr) (0xE000 | (((addr)-0x80) >> 1))

  56. 

  57. class EepromStm32Test : public testing::Test {
  58.    public:
  59.     EepromStm32Test() {}
  60.     ~EepromStm32Test() {}
  61. 

  62.    protected:
  63.     void SetUp() override { EEPROM_Erase(); }
  64. 

  65.     void TearDown() override {
  66. #ifdef EEPROM_DEBUG

  67.         dumpEepromDataBuf();
  68. #endif

  69.     }
  70. };
  71. 

  72. TEST_F(EepromStm32Test, TestErase) {
  73.     EEPROM_WriteDataByte(0, 0x42);
  74.     EEPROM_Erase();
  75.     EXPECT_EQ(EEPROM_ReadDataByte(0), 0);
  76.     EXPECT_EQ(EEPROM_ReadDataByte(1), 0);
  77. }
  78. 

  79. TEST_F(EepromStm32Test, TestReadGarbage) {
  80.     uint8_t garbage = 0x3c;
  81.     for (int i = 0; i < MOCK_FLASH_SIZE; ++i) {
  82.         garbage ^= 0xa3;
  83.         garbage += i;
  84.         FlashBuf[i] = garbage;
  85.     }
  86.     EEPROM_Init();  // Just verify we don't crash

  87. }
  88. 

  89. TEST_F(EepromStm32Test, TestWriteBadAddress) {
  90.     EXPECT_EQ(EEPROM_WriteDataByte(EEPROM_SIZE, 0x42), FLASH_BAD_ADDRESS);
  91.     EXPECT_EQ(EEPROM_WriteDataWord(EEPROM_SIZE - 1, 0xbeef), FLASH_BAD_ADDRESS);
  92.     EXPECT_EQ(EEPROM_WriteDataWord(EEPROM_SIZE, 0xbeef), FLASH_BAD_ADDRESS);
  93. }
  94. 

  95. TEST_F(EepromStm32Test, TestReadBadAddress) {
  96.     EXPECT_EQ(EEPROM_ReadDataByte(EEPROM_SIZE), 0xFF);
  97.     EXPECT_EQ(EEPROM_ReadDataWord(EEPROM_SIZE - 1), 0xFFFF);
  98.     EXPECT_EQ(EEPROM_ReadDataWord(EEPROM_SIZE), 0xFFFF);
  99.     EXPECT_EQ(eeprom_read_dword((uint32_t*)(EEPROM_SIZE - 4)), 0);
  100.     EXPECT_EQ(eeprom_read_dword((uint32_t*)(EEPROM_SIZE - 3)), 0xFF000000);
  101.     EXPECT_EQ(eeprom_read_dword((uint32_t*)EEPROM_SIZE), 0xFFFFFFFF);
  102. }
  103. 

  104. TEST_F(EepromStm32Test, TestReadByte) {
  105.     /* Direct compacted-area baseline: Address < 0x80 */
  106.     FlashBuf[EEPROM_BASE + 2] = ~0xef;
  107.     FlashBuf[EEPROM_BASE + 3] = ~0xbe;
  108.     /* Direct compacted-area baseline: Address >= 0x80 */
  109.     FlashBuf[EEPROM_BASE + EEPROM_SIZE - 2] = ~0x78;
  110.     FlashBuf[EEPROM_BASE + EEPROM_SIZE - 1] = ~0x56;
  111.     /* Check values */
  112.     EEPROM_Init();
  113.     EXPECT_EQ(EEPROM_ReadDataByte(2), 0xef);
  114.     EXPECT_EQ(EEPROM_ReadDataByte(3), 0xbe);
  115.     EXPECT_EQ(EEPROM_ReadDataByte(EEPROM_SIZE - 2), 0x78);
  116.     EXPECT_EQ(EEPROM_ReadDataByte(EEPROM_SIZE - 1), 0x56);
  117.     /* Write Log byte value */
  118.     FlashBuf[LOG_BASE]     = 0x65;
  119.     FlashBuf[LOG_BASE + 1] = 3;
  120.     /* Write Log word value */
  121.     *(uint16_t*)&FlashBuf[LOG_BASE + 2] = WORD_NEXT(EEPROM_SIZE - 2);
  122.     *(uint16_t*)&FlashBuf[LOG_BASE + 4] = ~0x9abc;
  123.     /* Check values */
  124.     EEPROM_Init();
  125.     EXPECT_EQ(EEPROM_ReadDataByte(2), 0xef);
  126.     EXPECT_EQ(EEPROM_ReadDataByte(3), 0x65);
  127.     EXPECT_EQ(EEPROM_ReadDataByte(EEPROM_SIZE - 2), 0xbc);
  128.     EXPECT_EQ(EEPROM_ReadDataByte(EEPROM_SIZE - 1), 0x9a);
  129. }
  130. 

  131. TEST_F(EepromStm32Test, TestWriteByte) {
  132.     /* Direct compacted-area baseline: Address < 0x80 */
  133.     EEPROM_WriteDataByte(2, 0xef);
  134.     EEPROM_WriteDataByte(3, 0xbe);
  135.     /* Direct compacted-area baseline: Address >= 0x80 */
  136.     EEPROM_WriteDataByte(EEPROM_SIZE - 2, 0x78);
  137.     EEPROM_WriteDataByte(EEPROM_SIZE - 1, 0x56);
  138.     /* Check values */
  139.     /* First write in each aligned word should have been direct */
  140.     EXPECT_EQ(FlashBuf[EEPROM_BASE + 2], (uint8_t)~0xef);
  141.     EXPECT_EQ(FlashBuf[EEPROM_BASE + EEPROM_SIZE - 2], (uint8_t)~0x78);
  142. 

  143.     /* Second write per aligned word requires a log entry */
  144.     EXPECT_EQ(*(uint16_t*)&FlashBuf[LOG_BASE], BYTE_VALUE(3, 0xbe));
  145.     EXPECT_EQ(*(uint16_t*)&FlashBuf[LOG_BASE + 2], WORD_NEXT(EEPROM_SIZE - 1));
  146.     EXPECT_EQ(*(uint16_t*)&FlashBuf[LOG_BASE + 4], (uint16_t)~0x5678);
  147. }
  148. 

  149. TEST_F(EepromStm32Test, TestByteRoundTrip) {
  150.     /* Direct compacted-area: Address < 0x80 */
  151.     EEPROM_WriteDataWord(0, 0xdead);
  152.     EEPROM_WriteDataByte(2, 0xef);
  153.     EEPROM_WriteDataByte(3, 0xbe);
  154.     /* Direct compacted-area: Address >= 0x80 */
  155.     EEPROM_WriteDataByte(EEPROM_SIZE - 2, 0x78);
  156.     EEPROM_WriteDataByte(EEPROM_SIZE - 1, 0x56);
  157.     /* Check values */
  158.     EEPROM_Init();
  159.     EXPECT_EQ(EEPROM_ReadDataByte(0), 0xad);
  160.     EXPECT_EQ(EEPROM_ReadDataByte(1), 0xde);
  161.     EXPECT_EQ(EEPROM_ReadDataByte(2), 0xef);
  162.     EXPECT_EQ(EEPROM_ReadDataByte(3), 0xbe);
  163.     EXPECT_EQ(EEPROM_ReadDataByte(EEPROM_SIZE - 2), 0x78);
  164.     EXPECT_EQ(EEPROM_ReadDataByte(EEPROM_SIZE - 1), 0x56);
  165.     /* Write log entries */
  166.     EEPROM_WriteDataByte(2, 0x80);
  167.     EEPROM_WriteDataByte(EEPROM_SIZE - 2, 0x3c);
  168.     /* Check values */
  169.     EEPROM_Init();
  170.     EXPECT_EQ(EEPROM_ReadDataByte(2), 0x80);
  171.     EXPECT_EQ(EEPROM_ReadDataByte(3), 0xbe);
  172.     EXPECT_EQ(EEPROM_ReadDataByte(EEPROM_SIZE - 2), 0x3c);
  173.     EXPECT_EQ(EEPROM_ReadDataByte(EEPROM_SIZE - 1), 0x56);
  174. }
  175. 

  176. TEST_F(EepromStm32Test, TestReadWord) {
  177.     /* Direct compacted-area baseline: Address < 0x80 */
  178.     FlashBuf[EEPROM_BASE + 0] = ~0xad;
  179.     FlashBuf[EEPROM_BASE + 1] = ~0xde;
  180.     /* Direct compacted-area baseline: Address >= 0x80 */
  181.     FlashBuf[EEPROM_BASE + 200]             = ~0xcd;
  182.     FlashBuf[EEPROM_BASE + 201]             = ~0xab;
  183.     FlashBuf[EEPROM_BASE + EEPROM_SIZE - 4] = ~0x34;
  184.     FlashBuf[EEPROM_BASE + EEPROM_SIZE - 3] = ~0x12;
  185.     FlashBuf[EEPROM_BASE + EEPROM_SIZE - 2] = ~0x78;
  186.     FlashBuf[EEPROM_BASE + EEPROM_SIZE - 1] = ~0x56;
  187.     /* Check values */
  188.     EEPROM_Init();
  189.     EXPECT_EQ(EEPROM_ReadDataWord(0), 0xdead);
  190.     EXPECT_EQ(EEPROM_ReadDataWord(200), 0xabcd);
  191.     EXPECT_EQ(EEPROM_ReadDataWord(EEPROM_SIZE - 4), 0x1234);
  192.     EXPECT_EQ(EEPROM_ReadDataWord(EEPROM_SIZE - 2), 0x5678);
  193.     /* Write Log word zero-encoded */
  194.     *(uint16_t*)&FlashBuf[LOG_BASE] = WORD_ZERO(200);
  195.     /* Write Log word one-encoded */
  196.     *(uint16_t*)&FlashBuf[LOG_BASE + 2] = WORD_ONE(EEPROM_SIZE - 4);
  197.     /* Write Log word value */
  198.     *(uint16_t*)&FlashBuf[LOG_BASE + 4] = WORD_NEXT(EEPROM_SIZE - 2);
  199.     *(uint16_t*)&FlashBuf[LOG_BASE + 6] = ~0x9abc;
  200.     /* Check values */
  201.     EEPROM_Init();
  202.     EXPECT_EQ(EEPROM_ReadDataWord(200), 0);
  203.     EXPECT_EQ(EEPROM_ReadDataWord(EEPROM_SIZE - 4), 1);
  204.     EXPECT_EQ(EEPROM_ReadDataWord(EEPROM_SIZE - 2), 0x9abc);
  205. }
  206. 

  207. TEST_F(EepromStm32Test, TestWriteWord) {
  208.     /* Direct compacted-area: Address < 0x80 */
  209.     EEPROM_WriteDataWord(0, 0xdead);  // Aligned

  210.     EEPROM_WriteDataWord(3, 0xbeef);  // Unaligned

  211.     /* Direct compacted-area: Address >= 0x80 */
  212.     EEPROM_WriteDataWord(200, 0xabcd);  // Aligned

  213.     EEPROM_WriteDataWord(203, 0x9876);  // Unaligned

  214.     EEPROM_WriteDataWord(EEPROM_SIZE - 4, 0x1234);
  215.     EEPROM_WriteDataWord(EEPROM_SIZE - 2, 0x5678);
  216.     /* Write Log word zero-encoded */
  217.     EEPROM_WriteDataWord(EEPROM_SIZE - 4, 0);
  218.     /* Write Log word one-encoded */
  219.     EEPROM_WriteDataWord(EEPROM_SIZE - 2, 1);
  220.     /* Write Log word value aligned */
  221.     EEPROM_WriteDataWord(200, 0x4321);  // Aligned

  222.     /* Write Log word value unaligned */
  223.     EEPROM_WriteDataByte(202, 0x3c);    // Set neighboring byte

  224.     EEPROM_WriteDataWord(203, 0xcdef);  // Unaligned

  225.     /* Check values */
  226.     /* Direct compacted-area */
  227.     EXPECT_EQ(*(uint16_t*)&FlashBuf[EEPROM_BASE], (uint16_t)~0xdead);
  228.     EXPECT_EQ(*(uint16_t*)&FlashBuf[EEPROM_BASE + 3], (uint16_t)~0xbeef);
  229.     EXPECT_EQ(*(uint16_t*)&FlashBuf[EEPROM_BASE + 200], (uint16_t)~0xabcd);
  230.     EXPECT_EQ(FlashBuf[EEPROM_BASE + 203], (uint8_t)~0x76);
  231.     EXPECT_EQ(FlashBuf[EEPROM_BASE + 204], (uint8_t)~0x98);
  232.     EXPECT_EQ(*(uint16_t*)&FlashBuf[EEPROM_BASE + EEPROM_SIZE - 4], (uint16_t)~0x1234);
  233.     EXPECT_EQ(*(uint16_t*)&FlashBuf[EEPROM_BASE + EEPROM_SIZE - 2], (uint16_t)~0x5678);
  234.     /* Write Log word zero-encoded */
  235.     EXPECT_EQ(*(uint16_t*)&FlashBuf[LOG_BASE], WORD_ZERO(EEPROM_SIZE - 4));
  236.     /* Write Log word one-encoded */
  237.     EXPECT_EQ(*(uint16_t*)&FlashBuf[LOG_BASE + 2], WORD_ONE(EEPROM_SIZE - 2));
  238.     /* Write Log word value aligned */
  239.     EXPECT_EQ(*(uint16_t*)&FlashBuf[LOG_BASE + 4], WORD_NEXT(200));
  240.     EXPECT_EQ(*(uint16_t*)&FlashBuf[LOG_BASE + 6], (uint16_t)~0x4321);
  241.     /* Write Log word value unaligned */
  242.     EXPECT_EQ(*(uint16_t*)&FlashBuf[LOG_BASE + 8], WORD_NEXT(202));
  243.     EXPECT_EQ(*(uint16_t*)&FlashBuf[LOG_BASE + 10], (uint16_t)~0x763c);
  244.     EXPECT_EQ(*(uint16_t*)&FlashBuf[LOG_BASE + 12], WORD_NEXT(202));
  245.     EXPECT_EQ(*(uint16_t*)&FlashBuf[LOG_BASE + 14], (uint16_t)~0xef3c);
  246.     EXPECT_EQ(*(uint16_t*)&FlashBuf[LOG_BASE + 16], WORD_NEXT(204));
  247.     EXPECT_EQ(*(uint16_t*)&FlashBuf[LOG_BASE + 18], (uint16_t)~0x00cd);
  248. }
  249. 

  250. TEST_F(EepromStm32Test, TestWordRoundTrip) {
  251.     /* Direct compacted-area: Address < 0x80 */
  252.     EEPROM_WriteDataWord(0, 0xdead);  // Aligned

  253.     EEPROM_WriteDataWord(3, 0xbeef);  // Unaligned

  254.     /* Direct compacted-area: Address >= 0x80 */
  255.     EEPROM_WriteDataWord(200, 0xabcd);  // Aligned

  256.     EEPROM_WriteDataWord(203, 0x9876);  // Unaligned

  257.     EEPROM_WriteDataWord(EEPROM_SIZE - 4, 0x1234);
  258.     EEPROM_WriteDataWord(EEPROM_SIZE - 2, 0x5678);
  259.     /* Check values */
  260.     EEPROM_Init();
  261.     EXPECT_EQ(EEPROM_ReadDataWord(0), 0xdead);
  262.     EXPECT_EQ(EEPROM_ReadDataWord(3), 0xbeef);
  263.     EXPECT_EQ(EEPROM_ReadDataWord(200), 0xabcd);
  264.     EXPECT_EQ(EEPROM_ReadDataWord(203), 0x9876);
  265.     EXPECT_EQ(EEPROM_ReadDataWord(EEPROM_SIZE - 4), 0x1234);
  266.     EXPECT_EQ(EEPROM_ReadDataWord(EEPROM_SIZE - 2), 0x5678);
  267. 

  268.     /* Write Log word zero-encoded */
  269.     EEPROM_WriteDataWord(EEPROM_SIZE - 4, 0);
  270.     /* Write Log word one-encoded */
  271.     EEPROM_WriteDataWord(EEPROM_SIZE - 2, 1);
  272.     /* Write Log word value aligned */
  273.     EEPROM_WriteDataWord(200, 0x4321);  // Aligned

  274.     /* Write Log word value unaligned */
  275.     EEPROM_WriteDataByte(202, 0x3c);    // Set neighboring byte

  276.     EEPROM_WriteDataWord(203, 0xcdef);  // Unaligned

  277.     /* Check values */
  278.     EEPROM_Init();
  279.     EXPECT_EQ(EEPROM_ReadDataWord(200), 0x4321);
  280.     EXPECT_EQ(EEPROM_ReadDataByte(202), 0x3c);
  281.     EXPECT_EQ(EEPROM_ReadDataWord(203), 0xcdef);
  282.     EXPECT_EQ(EEPROM_ReadDataWord(EEPROM_SIZE - 4), 0);
  283.     EXPECT_EQ(EEPROM_ReadDataWord(EEPROM_SIZE - 2), 1);
  284. }
  285. 

  286. TEST_F(EepromStm32Test, TestByteWordBoundary) {
  287.     /* Direct compacted-area write */
  288.     EEPROM_WriteDataWord(0x7e, 0xdead);
  289.     EEPROM_WriteDataWord(0x80, 0xbeef);
  290.     /* Byte log entry */
  291.     EEPROM_WriteDataByte(0x7f, 0x3c);
  292.     /* Word log entry */
  293.     EEPROM_WriteDataByte(0x80, 0x18);
  294.     /* Check values */
  295.     EEPROM_Init();
  296.     EXPECT_EQ(EEPROM_ReadDataWord(0x7e), 0x3cad);
  297.     EXPECT_EQ(EEPROM_ReadDataWord(0x80), 0xbe18);
  298.     EXPECT_EQ(*(uint16_t*)&FlashBuf[LOG_BASE], BYTE_VALUE(0x7f, 0x3c));
  299.     EXPECT_EQ(*(uint16_t*)&FlashBuf[LOG_BASE + 2], WORD_NEXT(0x80));
  300.     EXPECT_EQ(*(uint16_t*)&FlashBuf[LOG_BASE + 4], (uint16_t)~0xbe18);
  301.     /* Byte log entries */
  302.     EEPROM_WriteDataWord(0x7e, 0xcafe);
  303.     /* Check values */
  304.     EEPROM_Init();
  305.     EXPECT_EQ(EEPROM_ReadDataWord(0x7e), 0xcafe);
  306.     EXPECT_EQ(*(uint16_t*)&FlashBuf[LOG_BASE + 6], BYTE_VALUE(0x7e, 0xfe));
  307.     EXPECT_EQ(*(uint16_t*)&FlashBuf[LOG_BASE + 8], BYTE_VALUE(0x7f, 0xca));
  308.     /* Byte and Word log entries */
  309.     EEPROM_WriteDataWord(0x7f, 0xba5e);
  310.     /* Check values */
  311.     EEPROM_Init();
  312.     EXPECT_EQ(EEPROM_ReadDataWord(0x7f), 0xba5e);
  313.     EXPECT_EQ(*(uint16_t*)&FlashBuf[LOG_BASE + 10], BYTE_VALUE(0x7f, 0x5e));
  314.     EXPECT_EQ(*(uint16_t*)&FlashBuf[LOG_BASE + 12], WORD_NEXT(0x80));
  315.     EXPECT_EQ(*(uint16_t*)&FlashBuf[LOG_BASE + 14], (uint16_t)~0xbeba);
  316.     /* Word log entry */
  317.     EEPROM_WriteDataWord(0x80, 0xf00d);
  318.     /* Check values */
  319.     EEPROM_Init();
  320.     EXPECT_EQ(EEPROM_ReadDataWord(0x80), 0xf00d);
  321.     EXPECT_EQ(*(uint16_t*)&FlashBuf[LOG_BASE + 16], WORD_NEXT(0x80));
  322.     EXPECT_EQ(*(uint16_t*)&FlashBuf[LOG_BASE + 18], (uint16_t)~0xf00d);
  323. }
  324. 

  325. TEST_F(EepromStm32Test, TestDWordRoundTrip) {
  326.     /* Direct compacted-area: Address < 0x80 */
  327.     eeprom_write_dword((uint32_t*)0, 0xdeadbeef);  // Aligned

  328.     eeprom_write_dword((uint32_t*)9, 0x12345678);  // Unaligned

  329.     /* Direct compacted-area: Address >= 0x80 */
  330.     eeprom_write_dword((uint32_t*)200, 0xfacef00d);
  331.     eeprom_write_dword((uint32_t*)(EEPROM_SIZE - 4), 0xba5eba11);  // Aligned

  332.     eeprom_write_dword((uint32_t*)(EEPROM_SIZE - 9), 0xcafed00d);  // Unaligned

  333.     /* Check direct values */
  334.     EEPROM_Init();
  335.     EXPECT_EQ(eeprom_read_dword((uint32_t*)0), 0xdeadbeef);
  336.     EXPECT_EQ(eeprom_read_dword((uint32_t*)9), 0x12345678);
  337.     EXPECT_EQ(eeprom_read_dword((uint32_t*)200), 0xfacef00d);
  338.     EXPECT_EQ(eeprom_read_dword((uint32_t*)(EEPROM_SIZE - 4)), 0xba5eba11);  // Aligned

  339.     EXPECT_EQ(eeprom_read_dword((uint32_t*)(EEPROM_SIZE - 9)), 0xcafed00d);  // Unaligned

  340.     /* Write Log byte encoded */
  341.     eeprom_write_dword((uint32_t*)0, 0xdecafbad);
  342.     eeprom_write_dword((uint32_t*)9, 0x87654321);
  343.     /* Write Log word encoded */
  344.     eeprom_write_dword((uint32_t*)200, 1);
  345.     /* Write Log word value aligned */
  346.     eeprom_write_dword((uint32_t*)(EEPROM_SIZE - 4), 0xdeadc0de);  // Aligned

  347.     eeprom_write_dword((uint32_t*)(EEPROM_SIZE - 9), 0x6789abcd);  // Unaligned

  348.     /* Check log values */
  349.     EEPROM_Init();
  350.     EXPECT_EQ(eeprom_read_dword((uint32_t*)0), 0xdecafbad);
  351.     EXPECT_EQ(eeprom_read_dword((uint32_t*)9), 0x87654321);
  352.     EXPECT_EQ(eeprom_read_dword((uint32_t*)200), 1);
  353.     EXPECT_EQ(eeprom_read_dword((uint32_t*)(EEPROM_SIZE - 4)), 0xdeadc0de);  // Aligned

  354.     EXPECT_EQ(eeprom_read_dword((uint32_t*)(EEPROM_SIZE - 9)), 0x6789abcd);  // Unaligned

  355. }
  356. 

  357. TEST_F(EepromStm32Test, TestBlockRoundTrip) {
  358.     char  src0[] = "0123456789abcdef";
  359.     void* src1   = (void*)&src0[1];
  360.     /* Various alignments of src & dst, Address < 0x80 */
  361.     eeprom_write_block(src0, (void*)0, sizeof(src0));
  362.     eeprom_write_block(src0, (void*)21, sizeof(src0));
  363.     eeprom_write_block(src1, (void*)40, sizeof(src0) - 1);
  364.     eeprom_write_block(src1, (void*)61, sizeof(src0) - 1);
  365.     /* Various alignments of src & dst, Address >= 0x80 */
  366.     eeprom_write_block(src0, (void*)140, sizeof(src0));
  367.     eeprom_write_block(src0, (void*)161, sizeof(src0));
  368.     eeprom_write_block(src1, (void*)180, sizeof(src0) - 1);
  369.     eeprom_write_block(src1, (void*)201, sizeof(src0) - 1);
  370. 

  371.     /* Check values */
  372.     EEPROM_Init();
  373. 

  374.     char  dstBuf[256] = {0};
  375.     char* dst0a       = (char*)dstBuf;
  376.     char* dst0b       = (char*)&dstBuf[20];
  377.     char* dst1a       = (char*)&dstBuf[41];
  378.     char* dst1b       = (char*)&dstBuf[61];
  379.     char* dst0c       = (char*)&dstBuf[80];
  380.     char* dst0d       = (char*)&dstBuf[100];
  381.     char* dst1c       = (char*)&dstBuf[121];
  382.     char* dst1d       = (char*)&dstBuf[141];
  383.     eeprom_read_block((void*)dst0a, (void*)0, sizeof(src0));
  384.     eeprom_read_block((void*)dst0b, (void*)21, sizeof(src0));
  385.     eeprom_read_block((void*)dst1a, (void*)40, sizeof(src0) - 1);
  386.     eeprom_read_block((void*)dst1b, (void*)61, sizeof(src0) - 1);
  387.     eeprom_read_block((void*)dst0c, (void*)140, sizeof(src0));
  388.     eeprom_read_block((void*)dst0d, (void*)161, sizeof(src0));
  389.     eeprom_read_block((void*)dst1c, (void*)180, sizeof(src0) - 1);
  390.     eeprom_read_block((void*)dst1d, (void*)201, sizeof(src0) - 1);
  391.     EXPECT_EQ(strcmp((char*)src0, dst0a), 0);
  392.     EXPECT_EQ(strcmp((char*)src0, dst0b), 0);
  393.     EXPECT_EQ(strcmp((char*)src0, dst0c), 0);
  394.     EXPECT_EQ(strcmp((char*)src0, dst0d), 0);
  395.     EXPECT_EQ(strcmp((char*)src1, dst1a), 0);
  396.     EXPECT_EQ(strcmp((char*)src1, dst1b), 0);
  397.     EXPECT_EQ(strcmp((char*)src1, dst1c), 0);
  398.     EXPECT_EQ(strcmp((char*)src1, dst1d), 0);
  399. }
  400. 

  401. TEST_F(EepromStm32Test, TestCompaction) {
  402.     /* Direct writes */
  403.     eeprom_write_dword((uint32_t*)0, 0xdeadbeef);
  404.     eeprom_write_byte((uint8_t*)4, 0x3c);
  405.     eeprom_write_word((uint16_t*)6, 0xd00d);
  406.     eeprom_write_dword((uint32_t*)150, 0xcafef00d);
  407.     eeprom_write_dword((uint32_t*)200, 0x12345678);
  408.     /* Fill write log entries */
  409.     uint32_t i;
  410.     uint32_t val = 0xd8453c6b;
  411.     for (i = 0; i < (LOG_SIZE / (sizeof(uint32_t) * 2)); i++) {
  412.         val ^= 0x593ca5b3;
  413.         val += i;
  414.         eeprom_write_dword((uint32_t*)200, val);
  415.     }
  416.     /* Check values pre-compaction */
  417.     EEPROM_Init();
  418.     EXPECT_EQ(eeprom_read_dword((uint32_t*)0), 0xdeadbeef);
  419.     EXPECT_EQ(eeprom_read_byte((uint8_t*)4), 0x3c);
  420.     EXPECT_EQ(eeprom_read_word((uint16_t*)6), 0xd00d);
  421.     EXPECT_EQ(eeprom_read_dword((uint32_t*)150), 0xcafef00d);
  422.     EXPECT_EQ(eeprom_read_dword((uint32_t*)200), val);
  423.     EXPECT_NE(*(uint16_t*)&FlashBuf[LOG_BASE], 0xFFFF);
  424.     EXPECT_NE(*(uint16_t*)&FlashBuf[LOG_BASE + LOG_SIZE - 2], 0xFFFF);
  425.     /* Run compaction */
  426.     eeprom_write_byte((uint8_t*)4, 0x1f);
  427.     EEPROM_Init();
  428.     EXPECT_EQ(eeprom_read_dword((uint32_t*)0), 0xdeadbeef);
  429.     EXPECT_EQ(eeprom_read_byte((uint8_t*)4), 0x1f);
  430.     EXPECT_EQ(eeprom_read_word((uint16_t*)6), 0xd00d);
  431.     EXPECT_EQ(eeprom_read_dword((uint32_t*)150), 0xcafef00d);
  432.     EXPECT_EQ(eeprom_read_dword((uint32_t*)200), val);
  433.     EXPECT_EQ(*(uint16_t*)&FlashBuf[LOG_BASE], 0xFFFF);
  434.     EXPECT_EQ(*(uint16_t*)&FlashBuf[LOG_BASE + LOG_SIZE - 2], 0xFFFF);
  435. }