/* SPDX-License-Identifier: GPL-2.0-only */ #include #include #include #include #include #include #include #include #include #include #include #include #include /* Pack the device_tree and place it at given position. */ static void pack_fdt(struct region *fdt, struct device_tree *dt) { printk(BIOS_INFO, "FIT: Flattening FDT to %p\n", (void *)fdt->offset); dt_flatten(dt, (void *)fdt->offset); prog_segment_loaded(fdt->offset, fdt->size, 0); } /** * Extract a node to given regions. * Returns true on error, false on success. */ static bool extract(struct region *region, struct fit_image_node *node) { void *dst = (void *)region->offset; const char *comp_name; size_t true_size = 0; if (node->size == 0) { printk(BIOS_ERR, "The %s size is 0\n", node->name); return true; } switch (node->compression) { case CBFS_COMPRESS_NONE: comp_name = "Relocating uncompressed"; break; case CBFS_COMPRESS_LZMA: comp_name = "Decompressing LZMA"; break; case CBFS_COMPRESS_LZ4: comp_name = "Decompressing LZ4"; break; default: printk(BIOS_ERR, "Unsupported compression\n"); return true; } printk(BIOS_INFO, "FIT: %s %s to %p\n", comp_name, node->name, dst); switch (node->compression) { case CBFS_COMPRESS_NONE: memcpy(dst, node->data, node->size); true_size = node->size; break; case CBFS_COMPRESS_LZMA: timestamp_add_now(TS_ULZMA_START); true_size = ulzman(node->data, node->size, dst, region->size); timestamp_add_now(TS_ULZMA_END); break; case CBFS_COMPRESS_LZ4: timestamp_add_now(TS_ULZ4F_START); true_size = ulz4fn(node->data, node->size, dst, region->size); timestamp_add_now(TS_ULZ4F_END); break; default: return true; } if (!true_size) { printk(BIOS_ERR, "%s decompression failed!\n", comp_name); return true; } return false; } static struct device_tree *unpack_fdt(struct fit_image_node *image_node) { void *data = image_node->data; if (image_node->compression != CBFS_COMPRESS_NONE) { /* TODO: This is an ugly heuristic for how much the size will expand on decompression, fix once FIT images support storing the real uncompressed size. */ struct region r = { .offset = 0, .size = image_node->size * 5 }; data = malloc(r.size); r.offset = (uintptr_t)data; if (!data || extract(&r, image_node)) return NULL; } return fdt_unflatten(data); } /** * Add coreboot tables, CBMEM information and optional board specific strapping * IDs to the device tree loaded via FIT. */ static void add_cb_fdt_data(struct device_tree *tree) { u32 addr_cells = 1, size_cells = 1; u64 reg_addrs[2], reg_sizes[2]; void *baseptr; size_t size; static const char *firmware_path[] = {"firmware", NULL}; struct device_tree_node *firmware_node = dt_find_node(tree->root, firmware_path, &addr_cells, &size_cells, 1); /* Need to add 'ranges' to the intermediate node to make 'reg' work. */ dt_add_bin_prop(firmware_node, "ranges", NULL, 0); static const char *coreboot_path[] = {"coreboot", NULL}; struct device_tree_node *coreboot_node = dt_find_node(firmware_node, coreboot_path, &addr_cells, &size_cells, 1); dt_add_string_prop(coreboot_node, "compatible", "coreboot"); /* Fetch CB tables from cbmem */ void *cbtable = cbmem_find(CBMEM_ID_CBTABLE); if (!cbtable) { printk(BIOS_WARNING, "FIT: No coreboot table found!\n"); return; } /* First 'reg' address range is the coreboot table. */ const struct lb_header *header = cbtable; reg_addrs[0] = (uintptr_t)header; reg_sizes[0] = header->header_bytes + header->table_bytes; /* Second is the CBMEM area (which usually includes the coreboot table). */ if (cbmem_get_region(&baseptr, &size)) { printk(BIOS_WARNING, "FIT: CBMEM pointer/size not found!\n"); return; } reg_addrs[1] = (uintptr_t)baseptr; reg_sizes[1] = size; dt_add_reg_prop(coreboot_node, reg_addrs, reg_sizes, 2, addr_cells, size_cells); /* Expose board ID, SKU ID, and RAM code to payload.*/ if (board_id() != UNDEFINED_STRAPPING_ID) dt_add_u32_prop(coreboot_node, "board-id", board_id()); if (sku_id() != UNDEFINED_STRAPPING_ID) dt_add_u32_prop(coreboot_node, "sku-id", sku_id()); if (ram_code() != UNDEFINED_STRAPPING_ID) dt_add_u32_prop(coreboot_node, "ram-code", ram_code()); } /* * Parse the uImage FIT, choose a configuration and extract images. */ void fit_payload(struct prog *payload, void *data) { struct device_tree *dt = NULL; struct region kernel = {0}, fdt = {0}, initrd = {0}; printk(BIOS_INFO, "FIT: Examine payload %s\n", payload->name); struct fit_config_node *config = fit_load(data); if (!config) { printk(BIOS_ERR, "Could not load FIT\n"); return; } dt = unpack_fdt(config->fdt); if (!dt) { printk(BIOS_ERR, "Failed to unflatten the FDT.\n"); return; } struct fit_overlay_chain *chain; list_for_each(chain, config->overlays, list_node) { struct device_tree *overlay = unpack_fdt(chain->overlay); if (!overlay || dt_apply_overlay(dt, overlay)) { printk(BIOS_ERR, "Failed to apply overlay %s!\n", chain->overlay->name); } } dt_apply_fixups(dt); /* Insert coreboot specific information */ add_cb_fdt_data(dt); /* Update device_tree */ #if defined(CONFIG_LINUX_COMMAND_LINE) fit_update_chosen(dt, (char *)CONFIG_LINUX_COMMAND_LINE); #endif fit_update_memory(dt); /* Collect infos for fit_payload_arch */ kernel.size = config->kernel->size; fdt.size = dt_flat_size(dt); initrd.size = config->ramdisk ? config->ramdisk->size : 0; /* Invoke arch specific payload placement and fixups */ if (!fit_payload_arch(payload, config, &kernel, &fdt, &initrd)) { printk(BIOS_ERR, "Failed to find free memory region\n"); bootmem_dump_ranges(); return; } /* Update ramdisk location in FDT */ if (config->ramdisk) fit_add_ramdisk(dt, (void *)initrd.offset, initrd.size); /* Repack FDT for handoff to kernel */ pack_fdt(&fdt, dt); if (config->ramdisk && extract(&initrd, config->ramdisk)) { printk(BIOS_ERR, "Failed to extract initrd\n"); prog_set_entry(payload, NULL, NULL); return; } timestamp_add_now(TS_KERNEL_DECOMPRESSION); if (extract(&kernel, config->kernel)) { printk(BIOS_ERR, "Failed to extract kernel\n"); prog_set_entry(payload, NULL, NULL); return; } timestamp_add_now(TS_KERNEL_START); }