/* * Copyright (c) 2015-2019, ARM Limited and Contributors. All rights reserved. * * SPDX-License-Identifier: BSD-3-Clause */ #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include /* IO devices */ static const io_dev_connector_t *dummy_dev_con; static uintptr_t dummy_dev_handle; static uintptr_t dummy_dev_spec; static uintptr_t image_dev_handle; static uintptr_t storage_dev_handle; #if STM32MP_SDMMC || STM32MP_EMMC static io_block_spec_t gpt_block_spec = { .offset = 0, .length = 34 * MMC_BLOCK_SIZE, /* Size of GPT table */ }; static uint32_t block_buffer[MMC_BLOCK_SIZE] __aligned(MMC_BLOCK_SIZE); static const io_block_dev_spec_t mmc_block_dev_spec = { /* It's used as temp buffer in block driver */ .buffer = { .offset = (size_t)&block_buffer, .length = MMC_BLOCK_SIZE, }, .ops = { .read = mmc_read_blocks, .write = NULL, }, .block_size = MMC_BLOCK_SIZE, }; static const io_dev_connector_t *mmc_dev_con; #endif /* STM32MP_SDMMC || STM32MP_EMMC */ #if STM32MP_RAW_NAND static io_mtd_dev_spec_t nand_dev_spec = { .ops = { .init = nand_raw_init, .read = nand_read, }, }; static const io_dev_connector_t *nand_dev_con; #endif #if STM32MP_SPI_NAND static io_mtd_dev_spec_t spi_nand_dev_spec = { .ops = { .init = spi_nand_init, .read = nand_read, }, }; static const io_dev_connector_t *spi_dev_con; #endif #ifdef AARCH32_SP_OPTEE static const struct stm32image_part_info optee_header_partition_spec = { .name = OPTEE_HEADER_IMAGE_NAME, .binary_type = OPTEE_HEADER_BINARY_TYPE, }; static const struct stm32image_part_info optee_pager_partition_spec = { .name = OPTEE_PAGER_IMAGE_NAME, .binary_type = OPTEE_PAGER_BINARY_TYPE, }; static const struct stm32image_part_info optee_paged_partition_spec = { .name = OPTEE_PAGED_IMAGE_NAME, .binary_type = OPTEE_PAGED_BINARY_TYPE, }; #else static const io_block_spec_t bl32_block_spec = { .offset = BL32_BASE, .length = STM32MP_BL32_SIZE }; #endif static const io_block_spec_t bl2_block_spec = { .offset = BL2_BASE, .length = STM32MP_BL2_SIZE, }; static const struct stm32image_part_info bl33_partition_spec = { .name = BL33_IMAGE_NAME, .binary_type = BL33_BINARY_TYPE, }; enum { IMG_IDX_BL33, #ifdef AARCH32_SP_OPTEE IMG_IDX_OPTEE_HEADER, IMG_IDX_OPTEE_PAGER, IMG_IDX_OPTEE_PAGED, #endif IMG_IDX_NUM }; static struct stm32image_device_info stm32image_dev_info_spec __unused = { .lba_size = MMC_BLOCK_SIZE, .part_info[IMG_IDX_BL33] = { .name = BL33_IMAGE_NAME, .binary_type = BL33_BINARY_TYPE, }, #ifdef AARCH32_SP_OPTEE .part_info[IMG_IDX_OPTEE_HEADER] = { .name = OPTEE_HEADER_IMAGE_NAME, .binary_type = OPTEE_HEADER_BINARY_TYPE, }, .part_info[IMG_IDX_OPTEE_PAGER] = { .name = OPTEE_PAGER_IMAGE_NAME, .binary_type = OPTEE_PAGER_BINARY_TYPE, }, .part_info[IMG_IDX_OPTEE_PAGED] = { .name = OPTEE_PAGED_IMAGE_NAME, .binary_type = OPTEE_PAGED_BINARY_TYPE, }, #endif }; static io_block_spec_t stm32image_block_spec = { .offset = 0, .length = 0, }; static const io_dev_connector_t *stm32image_dev_con __unused; static int open_dummy(const uintptr_t spec); static int open_image(const uintptr_t spec); static int open_storage(const uintptr_t spec); struct plat_io_policy { uintptr_t *dev_handle; uintptr_t image_spec; int (*check)(const uintptr_t spec); }; static const struct plat_io_policy policies[] = { [BL2_IMAGE_ID] = { .dev_handle = &dummy_dev_handle, .image_spec = (uintptr_t)&bl2_block_spec, .check = open_dummy }, #ifdef AARCH32_SP_OPTEE [BL32_IMAGE_ID] = { .dev_handle = &image_dev_handle, .image_spec = (uintptr_t)&optee_header_partition_spec, .check = open_image }, [BL32_EXTRA1_IMAGE_ID] = { .dev_handle = &image_dev_handle, .image_spec = (uintptr_t)&optee_pager_partition_spec, .check = open_image }, [BL32_EXTRA2_IMAGE_ID] = { .dev_handle = &image_dev_handle, .image_spec = (uintptr_t)&optee_paged_partition_spec, .check = open_image }, #else [BL32_IMAGE_ID] = { .dev_handle = &dummy_dev_handle, .image_spec = (uintptr_t)&bl32_block_spec, .check = open_dummy }, #endif [BL33_IMAGE_ID] = { .dev_handle = &image_dev_handle, .image_spec = (uintptr_t)&bl33_partition_spec, .check = open_image }, #if STM32MP_SDMMC || STM32MP_EMMC [GPT_IMAGE_ID] = { .dev_handle = &storage_dev_handle, .image_spec = (uintptr_t)&gpt_block_spec, .check = open_storage }, #endif [STM32_IMAGE_ID] = { .dev_handle = &storage_dev_handle, .image_spec = (uintptr_t)&stm32image_block_spec, .check = open_storage } }; static int open_dummy(const uintptr_t spec) { return io_dev_init(dummy_dev_handle, 0); } static int open_image(const uintptr_t spec) { return io_dev_init(image_dev_handle, 0); } static int open_storage(const uintptr_t spec) { return io_dev_init(storage_dev_handle, 0); } static void print_boot_device(boot_api_context_t *boot_context) { switch (boot_context->boot_interface_selected) { case BOOT_API_CTX_BOOT_INTERFACE_SEL_FLASH_SD: INFO("Using SDMMC\n"); break; case BOOT_API_CTX_BOOT_INTERFACE_SEL_FLASH_EMMC: INFO("Using EMMC\n"); break; case BOOT_API_CTX_BOOT_INTERFACE_SEL_FLASH_NAND_FMC: INFO("Using FMC NAND\n"); break; case BOOT_API_CTX_BOOT_INTERFACE_SEL_FLASH_NAND_QSPI: INFO("Using SPI NAND\n"); break; default: ERROR("Boot interface not found\n"); panic(); break; } if (boot_context->boot_interface_instance != 0U) { INFO(" Instance %d\n", boot_context->boot_interface_instance); } } #if STM32MP_SDMMC || STM32MP_EMMC static void boot_mmc(enum mmc_device_type mmc_dev_type, uint16_t boot_interface_instance) { int io_result __unused; uint8_t idx; struct stm32image_part_info *part; struct stm32_sdmmc2_params params; struct mmc_device_info device_info; const partition_entry_t *entry; zeromem(&device_info, sizeof(struct mmc_device_info)); zeromem(¶ms, sizeof(struct stm32_sdmmc2_params)); device_info.mmc_dev_type = mmc_dev_type; switch (boot_interface_instance) { case 1: params.reg_base = STM32MP_SDMMC1_BASE; break; case 2: params.reg_base = STM32MP_SDMMC2_BASE; break; case 3: params.reg_base = STM32MP_SDMMC3_BASE; break; default: WARN("SDMMC instance not found, using default\n"); if (mmc_dev_type == MMC_IS_SD) { params.reg_base = STM32MP_SDMMC1_BASE; } else { params.reg_base = STM32MP_SDMMC2_BASE; } break; } params.device_info = &device_info; if (stm32_sdmmc2_mmc_init(¶ms) != 0) { ERROR("SDMMC%u init failed\n", boot_interface_instance); panic(); } /* Open MMC as a block device to read GPT table */ io_result = register_io_dev_block(&mmc_dev_con); if (io_result != 0) { panic(); } io_result = io_dev_open(mmc_dev_con, (uintptr_t)&mmc_block_dev_spec, &storage_dev_handle); assert(io_result == 0); partition_init(GPT_IMAGE_ID); io_result = io_dev_close(storage_dev_handle); assert(io_result == 0); stm32image_dev_info_spec.device_size = stm32_sdmmc2_mmc_get_device_size(); for (idx = 0U; idx < IMG_IDX_NUM; idx++) { part = &stm32image_dev_info_spec.part_info[idx]; entry = get_partition_entry(part->name); if (entry == NULL) { ERROR("Partition %s not found\n", part->name); panic(); } part->part_offset = entry->start; part->bkp_offset = 0U; } /* * Re-open MMC with io_mmc, for better perfs compared to * io_block. */ io_result = register_io_dev_mmc(&mmc_dev_con); assert(io_result == 0); io_result = io_dev_open(mmc_dev_con, 0, &storage_dev_handle); assert(io_result == 0); io_result = register_io_dev_stm32image(&stm32image_dev_con); assert(io_result == 0); io_result = io_dev_open(stm32image_dev_con, (uintptr_t)&stm32image_dev_info_spec, &image_dev_handle); assert(io_result == 0); } #endif /* STM32MP_SDMMC || STM32MP_EMMC */ #if STM32MP_RAW_NAND static void boot_fmc2_nand(boot_api_context_t *boot_context) { int io_result __unused; uint8_t idx; struct stm32image_part_info *part; io_result = stm32_fmc2_init(); assert(io_result == 0); /* Register the IO device on this platform */ io_result = register_io_dev_mtd(&nand_dev_con); assert(io_result == 0); /* Open connections to device */ io_result = io_dev_open(nand_dev_con, (uintptr_t)&nand_dev_spec, &storage_dev_handle); assert(io_result == 0); stm32image_dev_info_spec.device_size = nand_dev_spec.device_size; idx = IMG_IDX_BL33; part = &stm32image_dev_info_spec.part_info[idx]; part->part_offset = STM32MP_NAND_BL33_OFFSET; part->bkp_offset = nand_dev_spec.erase_size; #ifdef AARCH32_SP_OPTEE idx = IMG_IDX_OPTEE_HEADER; part = &stm32image_dev_info_spec.part_info[idx]; part->part_offset = STM32MP_NAND_TEEH_OFFSET; part->bkp_offset = nand_dev_spec.erase_size; idx = IMG_IDX_OPTEE_PAGED; part = &stm32image_dev_info_spec.part_info[idx]; part->part_offset = STM32MP_NAND_TEED_OFFSET; part->bkp_offset = nand_dev_spec.erase_size; idx = IMG_IDX_OPTEE_PAGER; part = &stm32image_dev_info_spec.part_info[idx]; part->part_offset = STM32MP_NAND_TEEX_OFFSET; part->bkp_offset = nand_dev_spec.erase_size; #endif io_result = register_io_dev_stm32image(&stm32image_dev_con); assert(io_result == 0); io_result = io_dev_open(stm32image_dev_con, (uintptr_t)&stm32image_dev_info_spec, &image_dev_handle); assert(io_result == 0); } #endif /* STM32MP_RAW_NAND */ #if STM32MP_SPI_NAND static void boot_spi_nand(boot_api_context_t *boot_context) { int io_result __unused; uint8_t idx; struct stm32image_part_info *part; io_result = stm32_qspi_init(); assert(io_result == 0); io_result = register_io_dev_mtd(&spi_dev_con); assert(io_result == 0); /* Open connections to device */ io_result = io_dev_open(spi_dev_con, (uintptr_t)&spi_nand_dev_spec, &storage_dev_handle); assert(io_result == 0); stm32image_dev_info_spec.device_size = spi_nand_dev_spec.device_size; idx = IMG_IDX_BL33; part = &stm32image_dev_info_spec.part_info[idx]; part->part_offset = STM32MP_NAND_BL33_OFFSET; part->bkp_offset = spi_nand_dev_spec.erase_size; #ifdef AARCH32_SP_OPTEE idx = IMG_IDX_OPTEE_HEADER; part = &stm32image_dev_info_spec.part_info[idx]; part->part_offset = STM32MP_NAND_TEEH_OFFSET; part->bkp_offset = spi_nand_dev_spec.erase_size; idx = IMG_IDX_OPTEE_PAGED; part = &stm32image_dev_info_spec.part_info[idx]; part->part_offset = STM32MP_NAND_TEED_OFFSET; part->bkp_offset = spi_nand_dev_spec.erase_size; idx = IMG_IDX_OPTEE_PAGER; part = &stm32image_dev_info_spec.part_info[idx]; part->part_offset = STM32MP_NAND_TEEX_OFFSET; part->bkp_offset = spi_nand_dev_spec.erase_size; #endif io_result = register_io_dev_stm32image(&stm32image_dev_con); assert(io_result == 0); io_result = io_dev_open(stm32image_dev_con, (uintptr_t)&stm32image_dev_info_spec, &image_dev_handle); assert(io_result == 0); } #endif /* STM32MP_SPI_NAND */ void stm32mp_io_setup(void) { int io_result __unused; boot_api_context_t *boot_context = (boot_api_context_t *)stm32mp_get_boot_ctx_address(); print_boot_device(boot_context); if ((boot_context->boot_partition_used_toboot == 1U) || (boot_context->boot_partition_used_toboot == 2U)) { INFO("Boot used partition fsbl%d\n", boot_context->boot_partition_used_toboot); } io_result = register_io_dev_dummy(&dummy_dev_con); assert(io_result == 0); io_result = io_dev_open(dummy_dev_con, dummy_dev_spec, &dummy_dev_handle); assert(io_result == 0); switch (boot_context->boot_interface_selected) { #if STM32MP_SDMMC case BOOT_API_CTX_BOOT_INTERFACE_SEL_FLASH_SD: dmbsy(); boot_mmc(MMC_IS_SD, boot_context->boot_interface_instance); break; #endif #if STM32MP_EMMC case BOOT_API_CTX_BOOT_INTERFACE_SEL_FLASH_EMMC: dmbsy(); boot_mmc(MMC_IS_EMMC, boot_context->boot_interface_instance); break; #endif #if STM32MP_RAW_NAND case BOOT_API_CTX_BOOT_INTERFACE_SEL_FLASH_NAND_FMC: dmbsy(); boot_fmc2_nand(boot_context); break; #endif #if STM32MP_SPI_NAND case BOOT_API_CTX_BOOT_INTERFACE_SEL_FLASH_NAND_QSPI: dmbsy(); boot_spi_nand(boot_context); break; #endif default: ERROR("Boot interface %d not supported\n", boot_context->boot_interface_selected); break; } } /* * Return an IO device handle and specification which can be used to access * an image. Use this to enforce platform load policy. */ int plat_get_image_source(unsigned int image_id, uintptr_t *dev_handle, uintptr_t *image_spec) { int rc; const struct plat_io_policy *policy; assert(image_id < ARRAY_SIZE(policies)); policy = &policies[image_id]; rc = policy->check(policy->image_spec); if (rc == 0) { *image_spec = policy->image_spec; *dev_handle = *(policy->dev_handle); } return rc; }