/* * Copyright (c) 2017-2023 Nordic Semiconductor ASA * Copyright (c) 2018 Intel Corporation * * SPDX-License-Identifier: Apache-2.0 */ #include #include #include #include #include #include #include /* Buffer is only needed for bytes that follow command and offset */ #define BUF_ARRAY_CNT (CONFIG_SHELL_ARGC_MAX - 2) /* This only issues compilation error when it would not be possible * to extract at least one byte from command line arguments, yet * it does not warrant successful writes if BUF_ARRAY_CNT * is smaller than flash write alignment. */ BUILD_ASSERT(BUF_ARRAY_CNT >= 1); static const struct device *const zephyr_flash_controller = DEVICE_DT_GET_OR_NULL(DT_CHOSEN(zephyr_flash_controller)); static uint8_t __aligned(4) test_arr[CONFIG_FLASH_SHELL_BUFFER_SIZE]; static int parse_helper(const struct shell *sh, size_t *argc, char **argv[], const struct device * *flash_dev, uint32_t *addr) { char *endptr; *addr = strtoul((*argv)[1], &endptr, 16); if (*endptr != '\0') { /* flash controller from user input */ *flash_dev = device_get_binding((*argv)[1]); if (!*flash_dev) { shell_error(sh, "Given flash device was not found"); return -ENODEV; } } else if (zephyr_flash_controller != NULL) { /* default to zephyr,flash-controller */ if (!device_is_ready(zephyr_flash_controller)) { shell_error(sh, "Default flash driver not ready"); return -ENODEV; } *flash_dev = zephyr_flash_controller; } else { /* no flash controller given, no default available */ shell_error(sh, "No flash device specified (required)"); return -ENODEV; } if (*endptr == '\0') { return 0; } if (*argc < 3) { shell_error(sh, "Missing address."); return -EINVAL; } *addr = strtoul((*argv)[2], &endptr, 16); (*argc)--; (*argv)++; return 0; } static int cmd_erase(const struct shell *sh, size_t argc, char *argv[]) { const struct device *flash_dev; uint32_t page_addr; int result; uint32_t size; result = parse_helper(sh, &argc, &argv, &flash_dev, &page_addr); if (result) { return result; } if (argc > 2) { size = strtoul(argv[2], NULL, 16); } else { struct flash_pages_info info; result = flash_get_page_info_by_offs(flash_dev, page_addr, &info); if (result != 0) { shell_error(sh, "Could not determine page size, " "code %d.", result); return -EINVAL; } size = info.size; } result = flash_erase(flash_dev, page_addr, size); if (result) { shell_error(sh, "Erase Failed, code %d.", result); } else { shell_print(sh, "Erase success."); } return result; } static int cmd_write(const struct shell *sh, size_t argc, char *argv[]) { uint32_t __aligned(4) check_array[BUF_ARRAY_CNT]; uint32_t __aligned(4) buf_array[BUF_ARRAY_CNT]; const struct device *flash_dev; uint32_t w_addr; int ret; size_t op_size; ret = parse_helper(sh, &argc, &argv, &flash_dev, &w_addr); if (ret) { return ret; } if (argc <= 2) { shell_error(sh, "Missing data to be written."); return -EINVAL; } op_size = 0; for (int i = 2; i < argc; i++) { int j = i - 2; buf_array[j] = strtoul(argv[i], NULL, 16); check_array[j] = ~buf_array[j]; op_size += sizeof(buf_array[0]); } if (flash_write(flash_dev, w_addr, buf_array, op_size) != 0) { shell_error(sh, "Write internal ERROR!"); return -EIO; } shell_print(sh, "Write OK."); if (flash_read(flash_dev, w_addr, check_array, op_size) < 0) { shell_print(sh, "Verification read ERROR!"); return -EIO; } if (memcmp(buf_array, check_array, op_size) == 0) { shell_print(sh, "Verified."); } else { shell_error(sh, "Verification ERROR!"); return -EIO; } return 0; } static int cmd_read(const struct shell *sh, size_t argc, char *argv[]) { const struct device *flash_dev; uint32_t addr; int todo; int upto; int cnt; int ret; ret = parse_helper(sh, &argc, &argv, &flash_dev, &addr); if (ret) { return ret; } if (argc > 2) { cnt = strtoul(argv[2], NULL, 16); } else { cnt = 1; } for (upto = 0; upto < cnt; upto += todo) { uint8_t data[SHELL_HEXDUMP_BYTES_IN_LINE]; todo = MIN(cnt - upto, SHELL_HEXDUMP_BYTES_IN_LINE); ret = flash_read(flash_dev, addr, data, todo); if (ret != 0) { shell_error(sh, "Read ERROR!"); return -EIO; } shell_hexdump_line(sh, addr, data, todo); addr += todo; } shell_print(sh, ""); return 0; } static int cmd_test(const struct shell *sh, size_t argc, char *argv[]) { const struct device *flash_dev; uint32_t repeat; int result; uint32_t addr; uint32_t size; static uint8_t __aligned(4) check_arr[CONFIG_FLASH_SHELL_BUFFER_SIZE]; result = parse_helper(sh, &argc, &argv, &flash_dev, &addr); if (result) { return result; } size = strtoul(argv[2], NULL, 16); repeat = strtoul(argv[3], NULL, 16); if (size > CONFIG_FLASH_SHELL_BUFFER_SIZE) { shell_error(sh, " must be at most 0x%x.", CONFIG_FLASH_SHELL_BUFFER_SIZE); return -EINVAL; } if (repeat == 0) { repeat = 1; } for (uint32_t i = 0; i < size; i++) { test_arr[i] = (uint8_t)i; } result = 0; while (repeat--) { result = flash_erase(flash_dev, addr, size); if (result) { shell_error(sh, "Erase Failed, code %d.", result); break; } shell_print(sh, "Erase OK."); result = flash_write(flash_dev, addr, test_arr, size); if (result) { shell_error(sh, "Write failed, code %d", result); break; } shell_print(sh, "Write OK."); result = flash_read(flash_dev, addr, check_arr, size); if (result < 0) { shell_print(sh, "Verification read failed, code: %d", result); break; } if (memcmp(test_arr, check_arr, size) != 0) { shell_error(sh, "Verification ERROR!"); break; } shell_print(sh, "Verified OK."); } if (result == 0) { shell_print(sh, "Erase-Write-Verify test done."); } return result; } #ifdef CONFIG_FLASH_SHELL_TEST_COMMANDS const static uint8_t speed_types[][4] = { "B", "KiB", "MiB", "GiB" }; const static uint32_t speed_divisor = 1024; static int read_write_erase_validate(const struct shell *sh, size_t argc, char *argv[], uint32_t *size, uint32_t *repeat) { if (argc < 4) { shell_error(sh, "Missing parameters: "); return -EINVAL; } *size = strtoul(argv[2], NULL, 0); *repeat = strtoul(argv[3], NULL, 0); if (*size == 0 || *size > CONFIG_FLASH_SHELL_BUFFER_SIZE) { shell_error(sh, " must be between 0x1 and 0x%x.", CONFIG_FLASH_SHELL_BUFFER_SIZE); return -EINVAL; } if (*repeat == 0 || *repeat > 10) { shell_error(sh, " must be between 1 and 10."); return -EINVAL; } return 0; } static void speed_output(const struct shell *sh, uint64_t total_time, double loops, double size) { double time_per_loop = (double)total_time / loops; double throughput = size; uint8_t speed_index = 0; if (time_per_loop > 0) { throughput /= (time_per_loop / 1000.0); } while (throughput >= (double)speed_divisor && speed_index < ARRAY_SIZE(speed_types)) { throughput /= (double)speed_divisor; ++speed_index; } shell_print(sh, "Total: %llums, Per loop: ~%.0fms, Speed: ~%.1f%sps", total_time, time_per_loop, throughput, speed_types[speed_index]); } static int cmd_read_test(const struct shell *sh, size_t argc, char *argv[]) { const struct device *flash_dev; uint32_t repeat; int result; uint32_t addr; uint32_t size; uint64_t start_time; uint64_t loop_time; uint64_t total_time = 0; uint32_t loops = 0; result = parse_helper(sh, &argc, &argv, &flash_dev, &addr); if (result) { return result; } result = read_write_erase_validate(sh, argc, argv, &size, &repeat); if (result) { return result; } while (repeat--) { start_time = k_uptime_get(); result = flash_read(flash_dev, addr, test_arr, size); loop_time = k_uptime_delta(&start_time); if (result) { shell_error(sh, "Read failed: %d", result); break; } ++loops; total_time += loop_time; shell_print(sh, "Loop #%u done in %llums.", loops, loop_time); } if (result == 0) { speed_output(sh, total_time, (double)loops, (double)size); } return result; } static int cmd_write_test(const struct shell *sh, size_t argc, char *argv[]) { const struct device *flash_dev; uint32_t repeat; int result; uint32_t addr; uint32_t size; uint64_t start_time; uint64_t loop_time; uint64_t total_time = 0; uint32_t loops = 0; result = parse_helper(sh, &argc, &argv, &flash_dev, &addr); if (result) { return result; } result = read_write_erase_validate(sh, argc, argv, &size, &repeat); if (result) { return result; } for (uint32_t i = 0; i < size; i++) { test_arr[i] = (uint8_t)i; } while (repeat--) { start_time = k_uptime_get(); result = flash_write(flash_dev, addr, test_arr, size); loop_time = k_uptime_delta(&start_time); if (result) { shell_error(sh, "Write failed: %d", result); break; } ++loops; total_time += loop_time; shell_print(sh, "Loop #%u done in %llu ticks.", loops, loop_time); } if (result == 0) { speed_output(sh, total_time, (double)loops, (double)size); } return result; } static int cmd_erase_test(const struct shell *sh, size_t argc, char *argv[]) { const struct device *flash_dev; uint32_t repeat; int result; uint32_t addr; uint32_t size; uint64_t start_time; uint64_t loop_time; uint64_t total_time = 0; uint32_t loops = 0; result = parse_helper(sh, &argc, &argv, &flash_dev, &addr); if (result) { return result; } result = read_write_erase_validate(sh, argc, argv, &size, &repeat); if (result) { return result; } for (uint32_t i = 0; i < size; i++) { test_arr[i] = (uint8_t)i; } while (repeat--) { start_time = k_uptime_get(); result = flash_erase(flash_dev, addr, size); loop_time = k_uptime_delta(&start_time); if (result) { shell_error(sh, "Erase failed: %d", result); break; } ++loops; total_time += loop_time; shell_print(sh, "Loop #%u done in %llums.", loops, loop_time); } if (result == 0) { speed_output(sh, total_time, (double)loops, (double)size); } return result; } static int cmd_erase_write_test(const struct shell *sh, size_t argc, char *argv[]) { const struct device *flash_dev; uint32_t repeat; int result_erase = 0; int result_write = 0; uint32_t addr; uint32_t size; uint64_t start_time; uint64_t loop_time; uint64_t total_time = 0; uint32_t loops = 0; result_erase = parse_helper(sh, &argc, &argv, &flash_dev, &addr); if (result_erase) { return result_erase; } result_erase = read_write_erase_validate(sh, argc, argv, &size, &repeat); if (result_erase) { return result_erase; } for (uint32_t i = 0; i < size; i++) { test_arr[i] = (uint8_t)i; } while (repeat--) { start_time = k_uptime_get(); result_erase = flash_erase(flash_dev, addr, size); result_write = flash_write(flash_dev, addr, test_arr, size); loop_time = k_uptime_delta(&start_time); if (result_erase) { shell_error(sh, "Erase failed: %d", result_erase); break; } if (result_write) { shell_error(sh, "Write failed: %d", result_write); break; } ++loops; total_time += loop_time; shell_print(sh, "Loop #%u done in %llums.", loops, loop_time); } if (result_erase == 0 && result_write == 0) { speed_output(sh, total_time, (double)loops, (double)size); } return (result_erase != 0 ? result_erase : result_write); } #endif static int set_bypass(const struct shell *sh, shell_bypass_cb_t bypass) { static bool in_use; if (bypass && in_use) { shell_error(sh, "flash load supports setting bypass on a single instance."); return -EBUSY; } /* Mark that we have set or unset the bypass function */ in_use = bypass != NULL; if (in_use) { shell_print(sh, "Loading..."); } shell_set_bypass(sh, bypass); return 0; } #define FLASH_LOAD_BUF_MAX 256 static const struct device *flash_load_dev; static uint32_t flash_load_buf_size; static uint32_t flash_load_addr; static uint32_t flash_load_total; static uint32_t flash_load_written; static uint32_t flash_load_chunk; static uint32_t flash_load_boff; static uint8_t flash_load_buf[FLASH_LOAD_BUF_MAX]; static void bypass_cb(const struct shell *sh, uint8_t *recv, size_t len) { uint32_t left_to_read = flash_load_total - flash_load_written - flash_load_boff; uint32_t to_copy = MIN(len, left_to_read); uint32_t copied = 0; while (copied < to_copy) { uint32_t buf_copy = MIN(to_copy, flash_load_buf_size - flash_load_boff); memcpy(flash_load_buf + flash_load_boff, recv + copied, buf_copy); flash_load_boff += buf_copy; copied += buf_copy; /* Buffer is full. Write data to memory. */ if (flash_load_boff == flash_load_buf_size) { uint32_t addr = flash_load_addr + flash_load_written; int rc = flash_write(flash_load_dev, addr, flash_load_buf, flash_load_buf_size); if (rc != 0) { shell_error(sh, "Write to addr %x on dev %p ERROR!", addr, flash_load_dev); } shell_print(sh, "Written chunk %d", flash_load_chunk); flash_load_written += flash_load_buf_size; flash_load_chunk++; flash_load_boff = 0; } } /* When data is not aligned to flash_load_buf_size there may be partial write * at the end. */ if (flash_load_written < flash_load_total && flash_load_written + flash_load_boff >= flash_load_total) { uint32_t addr = flash_load_addr + flash_load_written; int rc = flash_write(flash_load_dev, addr, flash_load_buf, flash_load_boff); if (rc != 0) { set_bypass(sh, NULL); shell_error(sh, "Write to addr %x on dev %p ERROR!", addr, flash_load_dev); return; } shell_print(sh, "Written chunk %d", flash_load_chunk); flash_load_written += flash_load_boff; flash_load_chunk++; } if (flash_load_written >= flash_load_total) { set_bypass(sh, NULL); shell_print(sh, "Read all"); } } static int cmd_load(const struct shell *sh, size_t argc, char *argv[]) { const struct device *flash_dev; int result; uint32_t addr; uint32_t size; ssize_t write_block_size; result = parse_helper(sh, &argc, &argv, &flash_dev, &addr); if (result) { return result; } size = strtoul(argv[2], NULL, 0); write_block_size = flash_get_write_block_size(flash_dev); /* Check if size is aligned */ if (size % write_block_size != 0) { shell_error(sh, "Size must be %zu bytes aligned", write_block_size); return -EIO; } /* Align buffer size to write_block_size */ flash_load_buf_size = FLASH_LOAD_BUF_MAX; if (flash_load_buf_size < write_block_size) { shell_error(sh, "Size of buffer is too small to be aligned to %zu.", write_block_size); return -ENOSPC; } /* If buffer size is not aligned then change its size. */ if (flash_load_buf_size % write_block_size != 0) { flash_load_buf_size -= flash_load_buf_size % write_block_size; shell_warn(sh, "Load buffer was not aligned to %zu.", write_block_size); shell_warn(sh, "Effective load buffer size was set from %d to %d", FLASH_LOAD_BUF_MAX, flash_load_buf_size); } /* Prepare data for callback. */ flash_load_dev = flash_dev; flash_load_addr = addr; flash_load_total = size; flash_load_written = 0; flash_load_boff = 0; flash_load_chunk = 0; shell_print(sh, "Send %d bytes to complete flash load command", size); set_bypass(sh, bypass_cb); return 0; } static int cmd_page_info(const struct shell *sh, size_t argc, char *argv[]) { const struct device *flash_dev; struct flash_pages_info info; int result; uint32_t addr; result = parse_helper(sh, &argc, &argv, &flash_dev, &addr); if (result) { return result; } result = flash_get_page_info_by_offs(flash_dev, addr, &info); if (result != 0) { shell_error(sh, "Could not determine page size, error code %d.", result); return -EINVAL; } shell_print(sh, "Page for address 0x%x:\nstart offset: 0x%lx\nsize: %zu\nindex: %d", addr, info.start_offset, info.size, info.index); return 0; } static void device_name_get(size_t idx, struct shell_static_entry *entry); SHELL_DYNAMIC_CMD_CREATE(dsub_device_name, device_name_get); static void device_name_get(size_t idx, struct shell_static_entry *entry) { const struct device *dev = shell_device_lookup(idx, NULL); entry->syntax = (dev != NULL) ? dev->name : NULL; entry->handler = NULL; entry->help = NULL; entry->subcmd = &dsub_device_name; } SHELL_STATIC_SUBCMD_SET_CREATE(flash_cmds, SHELL_CMD_ARG(erase, &dsub_device_name, "[] []", cmd_erase, 2, 2), SHELL_CMD_ARG(read, &dsub_device_name, "[]
[]", cmd_read, 2, 2), SHELL_CMD_ARG(test, &dsub_device_name, "[]
", cmd_test, 4, 1), SHELL_CMD_ARG(write, &dsub_device_name, "[]
[...]", cmd_write, 3, BUF_ARRAY_CNT), SHELL_CMD_ARG(load, &dsub_device_name, "[]
", cmd_load, 3, 1), SHELL_CMD_ARG(page_info, &dsub_device_name, "[]
", cmd_page_info, 2, 1), #ifdef CONFIG_FLASH_SHELL_TEST_COMMANDS SHELL_CMD_ARG(read_test, &dsub_device_name, "[]
", cmd_read_test, 4, 1), SHELL_CMD_ARG(write_test, &dsub_device_name, "[]
", cmd_write_test, 4, 1), SHELL_CMD_ARG(erase_test, &dsub_device_name, "[]
", cmd_erase_test, 4, 1), SHELL_CMD_ARG(erase_write_test, &dsub_device_name, "[]
", cmd_erase_write_test, 4, 1), #endif SHELL_SUBCMD_SET_END ); static int cmd_flash(const struct shell *sh, size_t argc, char **argv) { shell_error(sh, "%s:unknown parameter: %s", argv[0], argv[1]); return -EINVAL; } SHELL_CMD_ARG_REGISTER(flash, &flash_cmds, "Flash shell commands", cmd_flash, 2, 0);