// SPDX-License-Identifier: GPL-2.0+ /* * Copyright (C) 2018 Stefan Roese */ #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #define MT76XX_AGPIO_CFG 0x1000003c #define FACTORY_DATA_OFFS 0xc0000 #define FACTORY_DATA_SECT_SIZE 0x10000 #if ((CONFIG_ENV_OFFSET_REDUND + CONFIG_ENV_SIZE) > FACTORY_DATA_OFFS) #error "U-Boot image with environment too big (overlapping with factory-data)!" #endif #define FACTORY_DATA_USER_OFFS 0x140 #define FACTORY_DATA_SIZE 0x1f0 #define FACTORY_DATA_CRC_LEN (FACTORY_DATA_SIZE - \ FACTORY_DATA_USER_OFFS - sizeof(u32)) #define FACTORY_DATA_MAGIC 0xCAFEBABE struct factory_data_values { u8 pad_1[4]; u8 wifi_mac[6]; /* offs: 0x004: binary value */ u8 pad_2[30]; u8 eth_mac[6]; /* offs: 0x028: binary value */ u8 pad_3[FACTORY_DATA_USER_OFFS - 4 - 6 - 30 - 6]; /* User values start here at offset 0x140 */ u32 crc; u32 magic; u32 version; char ipr_id[UUID_STR_LEN]; /* UUID as string w/o ending \0 */ char hqv_id[UUID_STR_LEN]; /* UUID as string w/o ending \0 */ char unielec_id[UUID_STR_LEN]; /* UUID as string w/o ending \0 */ }; int board_early_init_f(void) { void __iomem *gpio_mode; /* Configure digital vs analog GPIOs */ gpio_mode = ioremap_nocache(MT76XX_AGPIO_CFG, 0x100); iowrite32(0x00fe01ff, gpio_mode); return 0; } static bool prepare_uuid_var(const char *fd_ptr, const char *env_var_name, char errorchar) { char str[UUID_STR_LEN + 1] = { 0 }; /* Enough for UUID stuff */ bool env_updated = false; char *env; int i; memcpy(str, fd_ptr, UUID_STR_LEN); /* Convert non-ascii character to 'X' */ for (i = 0; i < UUID_STR_LEN; i++) { if (!(isascii(str[i]) && isprint(str[i]))) str[i] = errorchar; } env = env_get(env_var_name); if (strcmp(env, str)) { env_set(env_var_name, str); env_updated = true; } return env_updated; } static void factory_data_env_config(void) { struct factory_data_values *fd; struct spi_flash *sf; int env_updated = 0; char str[UUID_STR_LEN + 1]; /* Enough for UUID stuff */ char *env; u8 *buf; u32 crc; int ret; u8 *ptr; buf = malloc(FACTORY_DATA_SIZE); if (!buf) { printf("F-Data:Unable to allocate buffer\n"); return; } /* * Get values from factory-data area in SPI NOR */ sf = spi_flash_probe(CONFIG_SF_DEFAULT_BUS, CONFIG_SF_DEFAULT_CS, CONFIG_SF_DEFAULT_SPEED, CONFIG_SF_DEFAULT_MODE); if (!sf) { printf("F-Data:Unable to access SPI NOR flash\n"); goto err_free; } ret = spi_flash_read(sf, FACTORY_DATA_OFFS, FACTORY_DATA_SIZE, (void *)buf); if (ret) { printf("F-Data:Unable to read factory-data from SPI NOR\n"); goto err_spi_flash; } fd = (struct factory_data_values *)buf; if (fd->magic != FACTORY_DATA_MAGIC) printf("F-Data:Magic value not correct\n"); crc = crc32(0, (u8 *)&fd->magic, FACTORY_DATA_CRC_LEN); if (crc != fd->crc) printf("F-Data:CRC not correct\n"); else printf("F-Data:factory-data version %x detected\n", fd->version); /* Handle wifi_mac env variable */ ptr = fd->wifi_mac; sprintf(str, "%pM", ptr); if (!is_valid_ethaddr(ptr)) printf("F-Data:Invalid MAC addr: wifi_mac %s\n", str); env = env_get("wifiaddr"); if (strcmp(env, str)) { env_set("wifiaddr", str); env_updated = 1; } /* Handle eth_mac env variable */ ptr = fd->eth_mac; sprintf(str, "%pM", ptr); if (!is_valid_ethaddr(ptr)) printf("F-Data:Invalid MAC addr: eth_mac %s\n", str); env = env_get("ethaddr"); if (strcmp(env, str)) { env_set("ethaddr", str); env_updated = 1; } /* Handle UUID env variables */ env_updated |= prepare_uuid_var(fd->ipr_id, "linuxmoduleid", 'X'); env_updated |= prepare_uuid_var(fd->hqv_id, "linuxmodulehqvid", '\0'); env_updated |= prepare_uuid_var(fd->unielec_id, "linuxmoduleunielecid", '\0'); /* Check if the environment was updated and needs to get stored */ if (env_updated != 0) { printf("F-Data:Values don't match env values -> saving\n"); env_save(); } else { debug("F-Data:Values match current env values\n"); } err_spi_flash: spi_flash_free(sf); err_free: free(buf); } int board_late_init(void) { factory_data_env_config(); return 0; } static void copy_or_generate_uuid(char *fd_ptr, const char *env_var_name) { char str[UUID_STR_LEN + 1] = { 0 }; /* Enough for UUID stuff */ char *env; /* Don't use the UUID dest place, as the \0 char won't fit */ env = env_get(env_var_name); if (env) strncpy(str, env, UUID_STR_LEN); else gen_rand_uuid_str(str, UUID_STR_FORMAT_STD); memcpy(fd_ptr, str, UUID_STR_LEN); } /* * Helper function to provide some sane factory-data values for testing * purpose, when these values are not programmed correctly */ int do_fd_write(struct cmd_tbl *cmdtp, int flag, int argc, char *const argv[]) { struct factory_data_values *fd; struct spi_flash *sf; u8 *buf; int ret = CMD_RET_FAILURE; buf = malloc(FACTORY_DATA_SECT_SIZE); if (!buf) { printf("F-Data:Unable to allocate buffer\n"); return CMD_RET_FAILURE; } sf = spi_flash_probe(CONFIG_SF_DEFAULT_BUS, CONFIG_SF_DEFAULT_CS, CONFIG_SF_DEFAULT_SPEED, CONFIG_SF_DEFAULT_MODE); if (!sf) { printf("F-Data:Unable to access SPI NOR flash\n"); goto err_free; } /* Generate the factory-data struct */ /* Fist read complete sector into buffer */ ret = spi_flash_read(sf, FACTORY_DATA_OFFS, FACTORY_DATA_SECT_SIZE, (void *)buf); if (ret) { printf("F-Data:spi_flash_read failed (%d)\n", ret); goto err_spi_flash; } fd = (struct factory_data_values *)buf; fd->magic = FACTORY_DATA_MAGIC; fd->version = 0x1; /* Use existing MAC and UUID values or generate some random ones */ if (!eth_env_get_enetaddr("wifiaddr", fd->wifi_mac)) { net_random_ethaddr(fd->wifi_mac); /* to get a different seed value for the MAC address */ mdelay(10); } if (!eth_env_get_enetaddr("ethaddr", fd->eth_mac)) net_random_ethaddr(fd->eth_mac); copy_or_generate_uuid(fd->ipr_id, "linuxmoduleid"); copy_or_generate_uuid(fd->hqv_id, "linuxmodulehqvid"); copy_or_generate_uuid(fd->unielec_id, "linuxmoduleunielecid"); printf("New factory-data values:\n"); printf("wifiaddr=%pM\n", fd->wifi_mac); printf("ethaddr=%pM\n", fd->eth_mac); /* * We don't have the \0 char at the end, so we need to specify the * length in the printf format instead */ printf("linuxmoduleid=%." __stringify(UUID_STR_LEN) "s\n", fd->ipr_id); printf("linuxmodulehqvid=%." __stringify(UUID_STR_LEN) "s\n", fd->hqv_id); printf("linuxmoduleunielecid=%." __stringify(UUID_STR_LEN) "s\n", fd->unielec_id); fd->crc = crc32(0, (u8 *)&fd->magic, FACTORY_DATA_CRC_LEN); ret = spi_flash_erase(sf, FACTORY_DATA_OFFS, FACTORY_DATA_SECT_SIZE); if (ret) { printf("F-Data:spi_flash_erase failed (%d)\n", ret); goto err_spi_flash; } ret = spi_flash_write(sf, FACTORY_DATA_OFFS, FACTORY_DATA_SECT_SIZE, buf); if (ret) { printf("F-Data:spi_flash_write failed (%d)\n", ret); goto err_spi_flash; } printf("F-Data:factory-data values written to SPI NOR flash\n"); err_spi_flash: spi_flash_free(sf); err_free: free(buf); return ret; } #ifndef CONFIG_SPL_BUILD U_BOOT_CMD( fd_write, 1, 0, do_fd_write, "Write test factory-data values to SPI NOR", "\n" ); #endif