/* * Copyright (c) 2018-2023, Arm Limited and Contributors. All rights reserved. * * SPDX-License-Identifier: BSD-3-Clause */ #include #include #include #if CRYPTO_SUPPORT #include #endif /* CRYPTO_SUPPORT */ #include #include #include #include #include #include #include #include #include #if CRYPTO_SUPPORT static void *mbedtls_heap_addr; static size_t mbedtls_heap_size; /* * This function is the implementation of the shared Mbed TLS heap between * BL1 and BL2 for Arm platforms. The shared heap address is passed from BL1 * to BL2 with a pointer. This pointer resides inside the TB_FW_CONFIG file * which is a DTB. * * This function is placed inside an #if directive for the below reasons: * - To allocate space for the Mbed TLS heap --only if-- Trusted Board Boot * is enabled. * - This implementation requires the DTB to be present so that BL1 has a * mechanism to pass the pointer to BL2. */ int arm_get_mbedtls_heap(void **heap_addr, size_t *heap_size) { assert(heap_addr != NULL); assert(heap_size != NULL); #if defined(IMAGE_BL1) || BL2_AT_EL3 || defined(IMAGE_BL31) /* If in BL1 or BL2_AT_EL3 define a heap */ static unsigned char heap[TF_MBEDTLS_HEAP_SIZE]; *heap_addr = heap; *heap_size = sizeof(heap); mbedtls_heap_addr = heap; mbedtls_heap_size = sizeof(heap); #elif defined(IMAGE_BL2) /* If in BL2, retrieve the already allocated heap's info from DTB */ *heap_addr = FCONF_GET_PROPERTY(tbbr, dyn_config, mbedtls_heap_addr); *heap_size = FCONF_GET_PROPERTY(tbbr, dyn_config, mbedtls_heap_size); #endif return 0; } /* * Puts the shared Mbed TLS heap information to the DTB. * Executed only from BL1. */ void arm_bl1_set_mbedtls_heap(void) { int err; uintptr_t tb_fw_cfg_dtb; const struct dyn_cfg_dtb_info_t *tb_fw_config_info; /* * If tb_fw_cfg_dtb==NULL then DTB is not present for the current * platform. As such, we don't attempt to write to the DTB at all. * * If mbedtls_heap_addr==NULL, then it means we are using the default * heap implementation. As such, BL2 will have its own heap for sure * and hence there is no need to pass any information to the DTB. * * In the latter case, if we still wanted to write in the DTB the heap * information, we would need to call plat_get_mbedtls_heap to retrieve * the default heap's address and size. */ tb_fw_config_info = FCONF_GET_PROPERTY(dyn_cfg, dtb, TB_FW_CONFIG_ID); assert(tb_fw_config_info != NULL); tb_fw_cfg_dtb = tb_fw_config_info->config_addr; if ((tb_fw_cfg_dtb != 0UL) && (mbedtls_heap_addr != NULL)) { /* As libfdt uses void *, we can't avoid this cast */ void *dtb = (void *)tb_fw_cfg_dtb; err = arm_set_dtb_mbedtls_heap_info(dtb, mbedtls_heap_addr, mbedtls_heap_size); if (err < 0) { ERROR("%swrite shared Mbed TLS heap information%s", "BL1: unable to ", " to DTB\n"); panic(); } #if !MEASURED_BOOT /* * Ensure that the info written to the DTB is visible to other * images. It's critical because BL2 won't be able to proceed * without the heap info. * * In MEASURED_BOOT case flushing is done in a function which * is called after heap information is written in the DTB. */ flush_dcache_range(tb_fw_cfg_dtb, fdt_totalsize(dtb)); #endif /* !MEASURED_BOOT */ } } #endif /* CRYPTO_SUPPORT */ /* * BL2 utility function to initialize dynamic configuration specified by * FW_CONFIG. Populate the bl_mem_params_node_t of other FW_CONFIGs if * specified in FW_CONFIG. */ void arm_bl2_dyn_cfg_init(void) { unsigned int i; bl_mem_params_node_t *cfg_mem_params = NULL; uintptr_t image_base; uint32_t image_size; unsigned int error_config_id = MAX_IMAGE_IDS; const unsigned int config_ids[] = { HW_CONFIG_ID, SOC_FW_CONFIG_ID, NT_FW_CONFIG_ID, TOS_FW_CONFIG_ID }; const struct dyn_cfg_dtb_info_t *dtb_info; /* Iterate through all the fw config IDs */ for (i = 0; i < ARRAY_SIZE(config_ids); i++) { /* Get the config load address and size */ cfg_mem_params = get_bl_mem_params_node(config_ids[i]); if (cfg_mem_params == NULL) { VERBOSE("%sconfig_id = %d in bl_mem_params_node\n", "Couldn't find ", config_ids[i]); continue; } dtb_info = FCONF_GET_PROPERTY(dyn_cfg, dtb, config_ids[i]); if (dtb_info == NULL) { VERBOSE("%sconfig_id %d load info in FW_CONFIG\n", "Couldn't find ", config_ids[i]); continue; } image_base = dtb_info->config_addr; image_size = dtb_info->config_max_size; /* * Do some runtime checks on the load addresses of soc_fw_config, * tos_fw_config, nt_fw_config. This is not a comprehensive check * of all invalid addresses but to prevent trivial porting errors. */ if (config_ids[i] != HW_CONFIG_ID) { if (check_uptr_overflow(image_base, image_size)) { VERBOSE("%s=%d as its %s is overflowing uptr\n", "skip loading of firmware config", config_ids[i], "load-address"); error_config_id = config_ids[i]; continue; } #ifdef BL31_BASE /* Ensure the configs don't overlap with BL31 */ if ((image_base >= BL31_BASE) && (image_base <= BL31_LIMIT)) { VERBOSE("%s=%d as its %s is overlapping BL31\n", "skip loading of firmware config", config_ids[i], "load-address"); error_config_id = config_ids[i]; continue; } #endif /* Ensure the configs are loaded in a valid address */ if (image_base < ARM_BL_RAM_BASE) { VERBOSE("%s=%d as its %s is invalid\n", "skip loading of firmware config", config_ids[i], "load-address"); error_config_id = config_ids[i]; continue; } #ifdef BL32_BASE /* * If BL32 is present, ensure that the configs don't * overlap with it. */ if ((image_base >= BL32_BASE) && (image_base <= BL32_LIMIT)) { VERBOSE("%s=%d as its %s is overlapping BL32\n", "skip loading of firmware config", config_ids[i], "load-address"); error_config_id = config_ids[i]; continue; } #endif } cfg_mem_params->image_info.image_base = image_base; cfg_mem_params->image_info.image_max_size = (uint32_t)image_size; /* * Remove the IMAGE_ATTRIB_SKIP_LOADING attribute from * HW_CONFIG or FW_CONFIG nodes */ cfg_mem_params->image_info.h.attr &= ~IMAGE_ATTRIB_SKIP_LOADING; } if (error_config_id != MAX_IMAGE_IDS) { ERROR("Invalid config file %u\n", error_config_id); panic(); } }