// SPDX-License-Identifier: GPL-2.0+ /* * K3: System Firmware Loader * * Copyright (C) 2019 Texas Instruments Incorporated - http://www.ti.com/ * Andreas Dannenberg */ #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include "common.h" DECLARE_GLOBAL_DATA_PTR; /* Name of the FIT image nodes for SYSFW and its config data */ #define SYSFW_FIRMWARE "sysfw.bin" #define SYSFW_CFG_BOARD "board-cfg.bin" #define SYSFW_CFG_PM "pm-cfg.bin" #define SYSFW_CFG_RM "rm-cfg.bin" #define SYSFW_CFG_SEC "sec-cfg.bin" /* * It is assumed that remoteproc device 0 is the corresponding * system-controller that runs SYSFW. Make sure DT reflects the same. */ #define K3_SYSTEM_CONTROLLER_RPROC_ID 0 #define COMMON_HEADER_ADDRESS 0x41cffb00 #define BOARDCFG_ADDRESS 0x41c80000 #define COMP_TYPE_SBL_DATA 0x11 #define DESC_TYPE_BOARDCFG_PM_INDEX 0x2 #define DESC_TYPE_BOARDCFG_RM_INDEX 0x3 #define BOARD_CONFIG_RM_DESC_TYPE 0x000c #define BOARD_CONFIG_PM_DESC_TYPE 0x000e struct extboot_comp { u32 comp_type; u32 boot_core; u32 comp_opts; u64 dest_addr; u32 comp_size; }; struct extboot_header { u8 magic[8]; u32 num_comps; struct extboot_comp comps[5]; u32 reserved; }; struct bcfg_desc { u16 type; u16 offset; u16 size; u8 devgrp; u8 reserved; } __packed; struct bcfg_header { u8 num_elems; u8 sw_rev; struct bcfg_desc descs[4]; u16 reserved; } __packed; static bool sysfw_loaded; static void *sysfw_load_address; /* * Populate SPL hook to override the default load address used by the SPL * loader function with a custom address for SYSFW loading. */ struct image_header *spl_get_load_buffer(ssize_t offset, size_t size) { if (sysfw_loaded) return (struct image_header *)(CONFIG_SYS_TEXT_BASE + offset); else if (sysfw_load_address) return sysfw_load_address; else panic("SYSFW load address not defined!"); } /* * Populate SPL hook to skip the default SPL loader FIT post-processing steps * during SYSFW loading and return to the calling function so we can perform * our own custom processing. */ bool spl_load_simple_fit_skip_processing(void) { return !sysfw_loaded; } static int fit_get_data_by_name(const void *fit, int images, const char *name, const void **addr, size_t *size) { int node_offset; node_offset = fdt_subnode_offset(fit, images, name); if (node_offset < 0) return -ENOENT; return fit_image_get_data(fit, node_offset, addr, size); } static void k3_start_system_controller(int rproc_id, bool rproc_loaded, ulong addr, ulong size) { int ret; ret = rproc_dev_init(rproc_id); if (ret) panic("rproc failed to be initialized (%d)\n", ret); if (!rproc_loaded) { ret = rproc_load(rproc_id, addr, size); if (ret) panic("Firmware failed to start on rproc (%d)\n", ret); } ret = rproc_start(0); if (ret) panic("Firmware init failed on rproc (%d)\n", ret); } static void k3_sysfw_load_using_fit(void *fit) { int images; const void *sysfw_addr; size_t sysfw_size; int ret; /* Find the node holding the images information */ images = fdt_path_offset(fit, FIT_IMAGES_PATH); if (images < 0) panic("Cannot find /images node (%d)\n", images); /* Extract System Firmware (SYSFW) image from FIT */ ret = fit_get_data_by_name(fit, images, SYSFW_FIRMWARE, &sysfw_addr, &sysfw_size); if (ret < 0) panic("Error accessing %s node in FIT (%d)\n", SYSFW_FIRMWARE, ret); /* Start up system controller firmware */ k3_start_system_controller(K3_SYSTEM_CONTROLLER_RPROC_ID, false, (ulong)sysfw_addr, (ulong)sysfw_size); } static void k3_sysfw_configure_using_fit(void *fit, struct ti_sci_handle *ti_sci) { struct ti_sci_board_ops *board_ops = &ti_sci->ops.board_ops; int images; const void *cfg_fragment_addr; size_t cfg_fragment_size; int ret; u8 *buf; struct extboot_header *common_header; struct bcfg_header *bcfg_header; struct extboot_comp *comp; struct bcfg_desc *desc; u32 addr; bool copy_bcfg = false; /* Find the node holding the images information */ images = fdt_path_offset(fit, FIT_IMAGES_PATH); if (images < 0) panic("Cannot find /images node (%d)\n", images); /* Extract board configuration from FIT */ ret = fit_get_data_by_name(fit, images, SYSFW_CFG_BOARD, &cfg_fragment_addr, &cfg_fragment_size); if (ret < 0) panic("Error accessing %s node in FIT (%d)\n", SYSFW_CFG_BOARD, ret); /* Apply board configuration to SYSFW */ ret = board_ops->board_config(ti_sci, (u64)(u32)cfg_fragment_addr, (u32)cfg_fragment_size); if (ret) panic("Failed to set board configuration (%d)\n", ret); /* Extract power/clock (PM) specific configuration from FIT */ ret = fit_get_data_by_name(fit, images, SYSFW_CFG_PM, &cfg_fragment_addr, &cfg_fragment_size); if (ret < 0) panic("Error accessing %s node in FIT (%d)\n", SYSFW_CFG_PM, ret); /* Apply power/clock (PM) specific configuration to SYSFW */ if (!IS_ENABLED(CONFIG_K3_DM_FW)) { ret = board_ops->board_config_pm(ti_sci, (u64)(u32)cfg_fragment_addr, (u32)cfg_fragment_size); if (ret) panic("Failed to set board PM configuration (%d)\n", ret); } else { /* Initialize shared memory boardconfig buffer */ buf = (u8 *)COMMON_HEADER_ADDRESS; common_header = (struct extboot_header *)buf; /* Check if we have a struct populated by ROM in memory already */ if (strcmp((char *)common_header->magic, "EXTBOOT")) copy_bcfg = true; if (copy_bcfg) { strcpy((char *)common_header->magic, "EXTBOOT"); common_header->num_comps = 1; comp = &common_header->comps[0]; comp->comp_type = COMP_TYPE_SBL_DATA; comp->boot_core = 0x10; comp->comp_opts = 0; addr = (u32)BOARDCFG_ADDRESS; comp->dest_addr = addr; comp->comp_size = sizeof(*bcfg_header); bcfg_header = (struct bcfg_header *)addr; bcfg_header->num_elems = 2; bcfg_header->sw_rev = 0; desc = &bcfg_header->descs[0]; desc->type = BOARD_CONFIG_PM_DESC_TYPE; desc->offset = sizeof(*bcfg_header); desc->size = cfg_fragment_size; comp->comp_size += desc->size; desc->devgrp = 0; desc->reserved = 0; memcpy((u8 *)bcfg_header + desc->offset, cfg_fragment_addr, cfg_fragment_size); bcfg_header->descs[1].offset = desc->offset + desc->size; } } /* Extract resource management (RM) specific configuration from FIT */ ret = fit_get_data_by_name(fit, images, SYSFW_CFG_RM, &cfg_fragment_addr, &cfg_fragment_size); if (ret < 0) panic("Error accessing %s node in FIT (%d)\n", SYSFW_CFG_RM, ret); if (copy_bcfg) { desc = &bcfg_header->descs[1]; desc->type = BOARD_CONFIG_RM_DESC_TYPE; desc->size = cfg_fragment_size; comp->comp_size += desc->size; desc->devgrp = 0; desc->reserved = 0; memcpy((u8 *)bcfg_header + desc->offset, cfg_fragment_addr, cfg_fragment_size); } /* Apply resource management (RM) configuration to SYSFW */ ret = board_ops->board_config_rm(ti_sci, (u64)(u32)cfg_fragment_addr, (u32)cfg_fragment_size); if (ret) panic("Failed to set board RM configuration (%d)\n", ret); /* Extract security specific configuration from FIT */ ret = fit_get_data_by_name(fit, images, SYSFW_CFG_SEC, &cfg_fragment_addr, &cfg_fragment_size); if (ret < 0) panic("Error accessing %s node in FIT (%d)\n", SYSFW_CFG_SEC, ret); /* Apply security configuration to SYSFW */ ret = board_ops->board_config_security(ti_sci, (u64)(u32)cfg_fragment_addr, (u32)cfg_fragment_size); if (ret) panic("Failed to set board security configuration (%d)\n", ret); } #if CONFIG_IS_ENABLED(DFU) static int k3_sysfw_dfu_download(void *addr) { char dfu_str[50]; int ret; sprintf(dfu_str, "sysfw.itb ram 0x%p 0x%x", addr, CONFIG_K3_SYSFW_IMAGE_SIZE_MAX); ret = dfu_config_entities(dfu_str, "ram", "0"); if (ret) { dfu_free_entities(); goto exit; } run_usb_dnl_gadget(0, "usb_dnl_dfu"); exit: dfu_free_entities(); return ret; } #endif #if CONFIG_IS_ENABLED(SPI_LOAD) static void *k3_sysfw_get_spi_addr(void) { struct udevice *dev; fdt_addr_t addr; int ret; ret = uclass_find_device_by_seq(UCLASS_SPI, CONFIG_SF_DEFAULT_BUS, &dev); if (ret) return NULL; addr = dev_read_addr_index(dev, 1); if (addr == FDT_ADDR_T_NONE) return NULL; return (void *)(addr + CONFIG_K3_SYSFW_IMAGE_SPI_OFFS); } static void k3_sysfw_spi_copy(u32 *dst, u32 *src, size_t len) { size_t i; for (i = 0; i < len / sizeof(*dst); i++) *dst++ = *src++; } #endif #if CONFIG_IS_ENABLED(NOR_SUPPORT) static void *get_sysfw_hf_addr(void) { struct udevice *dev; fdt_addr_t addr; int ret; ret = uclass_find_first_device(UCLASS_MTD, &dev); if (ret) return NULL; addr = dev_read_addr_index(dev, 1); if (addr == FDT_ADDR_T_NONE) return NULL; return (void *)(addr + CONFIG_K3_SYSFW_IMAGE_SPI_OFFS); } #endif void k3_sysfw_loader(bool rom_loaded_sysfw, void (*config_pm_pre_callback)(void), void (*config_pm_done_callback)(void)) { struct spl_image_info spl_image = { 0 }; struct spl_boot_device bootdev = { 0 }; struct ti_sci_handle *ti_sci; #if CONFIG_IS_ENABLED(SPI_LOAD) void *sysfw_spi_base; #endif int ret = 0; if (rom_loaded_sysfw) { k3_start_system_controller(K3_SYSTEM_CONTROLLER_RPROC_ID, rom_loaded_sysfw, 0, 0); sysfw_loaded = true; return; } /* Reserve a block of aligned memory for loading the SYSFW image */ sysfw_load_address = memalign(ARCH_DMA_MINALIGN, CONFIG_K3_SYSFW_IMAGE_SIZE_MAX); if (!sysfw_load_address) panic("Error allocating %u bytes of memory for SYSFW image\n", CONFIG_K3_SYSFW_IMAGE_SIZE_MAX); debug("%s: allocated %u bytes at 0x%p\n", __func__, CONFIG_K3_SYSFW_IMAGE_SIZE_MAX, sysfw_load_address); /* Set load address for legacy modes that bypass spl_get_load_buffer */ spl_image.load_addr = (uintptr_t)sysfw_load_address; bootdev.boot_device = spl_boot_device(); /* Load combined System Controller firmware and config data image */ switch (bootdev.boot_device) { #if CONFIG_IS_ENABLED(MMC) case BOOT_DEVICE_MMC1: case BOOT_DEVICE_MMC2: case BOOT_DEVICE_MMC2_2: ret = spl_mmc_load(&spl_image, &bootdev, #ifdef CONFIG_K3_SYSFW_IMAGE_NAME CONFIG_K3_SYSFW_IMAGE_NAME, #else NULL, #endif #ifdef CONFIG_K3_SYSFW_IMAGE_MMCSD_RAW_MODE_PART CONFIG_K3_SYSFW_IMAGE_MMCSD_RAW_MODE_PART, #else 0, #endif #ifdef CONFIG_K3_SYSFW_IMAGE_MMCSD_RAW_MODE_SECT CONFIG_K3_SYSFW_IMAGE_MMCSD_RAW_MODE_SECT); #else 0); #endif break; #endif #if CONFIG_IS_ENABLED(SPI_LOAD) case BOOT_DEVICE_SPI: sysfw_spi_base = k3_sysfw_get_spi_addr(); if (!sysfw_spi_base) ret = -ENODEV; k3_sysfw_spi_copy(sysfw_load_address, sysfw_spi_base, CONFIG_K3_SYSFW_IMAGE_SIZE_MAX); break; #endif #if CONFIG_IS_ENABLED(NOR_SUPPORT) case BOOT_DEVICE_HYPERFLASH: sysfw_spi_base = get_sysfw_hf_addr(); if (!sysfw_spi_base) ret = -ENODEV; k3_sysfw_spi_copy(sysfw_load_address, sysfw_spi_base, CONFIG_K3_SYSFW_IMAGE_SIZE_MAX); break; #endif #if CONFIG_IS_ENABLED(YMODEM_SUPPORT) case BOOT_DEVICE_UART: #ifdef CONFIG_K3_EARLY_CONS /* * Establish a serial console if not yet available as required * for UART-based boot. For this use the early console feature * that allows setting up a UART for use before SYSFW has been * brought up. Note that the associated UART module's clocks * must have gotten enabled by the ROM bootcode which will be * the case when continuing to boot serially from the same * UART that the ROM loaded the initial bootloader from. */ if (!gd->have_console) early_console_init(); #endif ret = spl_ymodem_load_image(&spl_image, &bootdev); break; #endif #if CONFIG_IS_ENABLED(DFU) case BOOT_DEVICE_DFU: ret = k3_sysfw_dfu_download(sysfw_load_address); break; #endif #if CONFIG_IS_ENABLED(USB_STORAGE) case BOOT_DEVICE_USB: ret = spl_usb_load(&spl_image, &bootdev, CONFIG_SYS_USB_FAT_BOOT_PARTITION, #ifdef CONFIG_K3_SYSFW_IMAGE_NAME CONFIG_K3_SYSFW_IMAGE_NAME); #else NULL); #endif #endif break; default: panic("Loading SYSFW image from device %u not supported!\n", bootdev.boot_device); } if (ret) panic("Error %d occurred during loading SYSFW image!\n", ret); /* * Now that SYSFW got loaded set helper flag to restore regular SPL * loader behavior so we can later boot into the next stage as expected. */ sysfw_loaded = true; /* Ensure the SYSFW image is in FIT format */ if (image_get_magic((const image_header_t *)sysfw_load_address) != FDT_MAGIC) panic("SYSFW image not in FIT format!\n"); /* Extract and start SYSFW */ k3_sysfw_load_using_fit(sysfw_load_address); /* Get handle for accessing SYSFW services */ ti_sci = get_ti_sci_handle(); if (config_pm_pre_callback) config_pm_pre_callback(); /* Parse and apply the different SYSFW configuration fragments */ k3_sysfw_configure_using_fit(sysfw_load_address, ti_sci); /* * Now that all clocks and PM aspects are setup, invoke a user- * provided callback function. Usually this callback would be used * to setup or re-configure the U-Boot console UART. */ if (config_pm_done_callback) config_pm_done_callback(); }