/* * This file is part of the coreboot project. * * Copyright (C) 2013 Google, Inc. * * This program is free software; you can redistribute it and/or modify * it under the terms of the GNU General Public License as published by * the Free Software Foundation; version 2 of the License. * * This program is distributed in the hope that it will be useful, * but WITHOUT ANY WARRANTY; without even the implied warranty of * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the * GNU General Public License for more details. */ /* This needs to be pulled in first so that the handoff code below and * peek into the vb2 data structures. Additionally, vboot doesn't currently * include what it uses in its own headers. Provide the types it's after. * TODO: fix this necessity. */ #define NEED_VB20_INTERNALS #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include /** * Sets vboot_handoff based on the information in vb2_shared_data */ static void fill_vboot_handoff(struct vboot_handoff *vboot_handoff, struct vb2_shared_data *vb2_sd) { VbSharedDataHeader *vb_sd = (VbSharedDataHeader *)vboot_handoff->shared_data; uint32_t *oflags = &vboot_handoff->init_params.out_flags; vb_sd->flags |= VBSD_BOOT_FIRMWARE_VBOOT2; vboot_handoff->selected_firmware = vb2_sd->fw_slot; vb_sd->firmware_index = vb2_sd->fw_slot; vb_sd->magic = VB_SHARED_DATA_MAGIC; vb_sd->struct_version = VB_SHARED_DATA_VERSION; vb_sd->struct_size = sizeof(VbSharedDataHeader); vb_sd->data_size = VB_SHARED_DATA_MIN_SIZE; vb_sd->data_used = sizeof(VbSharedDataHeader); vb_sd->fw_version_tpm = vb2_sd->fw_version_secdata; if (get_write_protect_state()) vb_sd->flags |= VBSD_BOOT_FIRMWARE_WP_ENABLED; if (get_sw_write_protect_state()) vb_sd->flags |= VBSD_BOOT_FIRMWARE_SW_WP_ENABLED; if (vb2_sd->recovery_reason) { vb_sd->firmware_index = 0xFF; if (vb2_sd->flags & VB2_SD_FLAG_MANUAL_RECOVERY) vb_sd->flags |= VBSD_BOOT_REC_SWITCH_ON; *oflags |= VB_INIT_OUT_ENABLE_RECOVERY; *oflags |= VB_INIT_OUT_CLEAR_RAM; *oflags |= VB_INIT_OUT_ENABLE_DISPLAY; *oflags |= VB_INIT_OUT_ENABLE_USB_STORAGE; } if (vb2_sd->flags & VB2_SD_DEV_MODE_ENABLED) { *oflags |= VB_INIT_OUT_ENABLE_DEVELOPER; *oflags |= VB_INIT_OUT_CLEAR_RAM; *oflags |= VB_INIT_OUT_ENABLE_DISPLAY; *oflags |= VB_INIT_OUT_ENABLE_USB_STORAGE; vb_sd->flags |= VBSD_BOOT_DEV_SWITCH_ON; vb_sd->flags |= VBSD_LF_DEV_SWITCH_ON; } /* TODO: Set these in depthcharge */ if (!IS_ENABLED(CONFIG_PHYSICAL_DEV_SWITCH)) vb_sd->flags |= VBSD_HONOR_VIRT_DEV_SWITCH; if (IS_ENABLED(CONFIG_EC_SOFTWARE_SYNC)) vb_sd->flags |= VBSD_EC_SOFTWARE_SYNC; if (!IS_ENABLED(CONFIG_PHYSICAL_REC_SWITCH)) vb_sd->flags |= VBSD_BOOT_REC_SWITCH_VIRTUAL; if (IS_ENABLED(CONFIG_VBOOT_EC_SLOW_UPDATE)) vb_sd->flags |= VBSD_EC_SLOW_UPDATE; if (IS_ENABLED(CONFIG_VBOOT_OPROM_MATTERS)) { vb_sd->flags |= VBSD_OPROM_MATTERS; /* * Inform vboot if the display was enabled by dev/rec * mode or was requested by vboot kernel phase. */ if ((*oflags & VB_INIT_OUT_ENABLE_DISPLAY) || vboot_wants_oprom()) { vb_sd->flags |= VBSD_OPROM_LOADED; *oflags |= VB_INIT_OUT_ENABLE_DISPLAY; } } /* In vboot1, VBSD_FWB_TRIED is * set only if B is booted as explicitly requested. Therefore, if B is * booted because A was found bad, the flag should not be set. It's * better not to touch it if we can only ambiguously control it. */ /* if (vb2_sd->fw_slot) vb_sd->flags |= VBSD_FWB_TRIED; */ /* copy kernel subkey if it's found */ if (vb2_sd->workbuf_preamble_size) { struct vb2_fw_preamble *fp; uintptr_t dst, src; printk(BIOS_INFO, "Copying FW preamble\n"); fp = (struct vb2_fw_preamble *)((uintptr_t)vb2_sd + vb2_sd->workbuf_preamble_offset); src = (uintptr_t)&fp->kernel_subkey + fp->kernel_subkey.key_offset; dst = (uintptr_t)vb_sd + sizeof(VbSharedDataHeader); assert(dst + fp->kernel_subkey.key_size <= (uintptr_t)vboot_handoff + sizeof(*vboot_handoff)); memcpy((void *)dst, (void *)src, fp->kernel_subkey.key_size); vb_sd->data_used += fp->kernel_subkey.key_size; vb_sd->kernel_subkey.key_offset = dst - (uintptr_t)&vb_sd->kernel_subkey; vb_sd->kernel_subkey.key_size = fp->kernel_subkey.key_size; vb_sd->kernel_subkey.algorithm = fp->kernel_subkey.algorithm; vb_sd->kernel_subkey.key_version = fp->kernel_subkey.key_version; } vb_sd->recovery_reason = vb2_sd->recovery_reason; } void vboot_fill_handoff(void) { struct vboot_handoff *vh; struct vb2_shared_data *sd; sd = vb2_get_shared_data(); sd->workbuf_hash_offset = 0; sd->workbuf_hash_size = 0; printk(BIOS_INFO, "creating vboot_handoff structure\n"); vh = cbmem_add(CBMEM_ID_VBOOT_HANDOFF, sizeof(*vh)); if (vh == NULL) /* we don't need to failover gracefully here because this * shouldn't happen with the image that has passed QA. */ die("failed to allocate vboot_handoff structure\n"); memset(vh, 0, sizeof(*vh)); /* needed until we finish transtion to vboot2 for kernel verification */ fill_vboot_handoff(vh, sd); /* Log the recovery mode switches if required, before clearing them. */ log_recovery_mode_switch(); /* * The recovery mode switch is cleared (typically backed by EC) here * to allow multiple queries to get_recovery_mode_switch() and have * them return consistent results during the verified boot path as well * as dram initialization. x86 systems ignore the saved dram settings * in the recovery path in order to start from a clean slate. Therefore * clear the state here since this function is called when memory * is known to be up. */ clear_recovery_mode_switch(); } /* * For platforms that employ VBOOT_STARTS_IN_ROMSTAGE, the vboot * verification doesn't happen until after cbmem is brought online. * Therefore, the vboot results would not be initialized so don't * automatically add results when cbmem comes online. */ #if !IS_ENABLED(CONFIG_VBOOT_STARTS_IN_ROMSTAGE) static void vb2_fill_handoff_cbmem(int unused) { vboot_fill_handoff(); } ROMSTAGE_CBMEM_INIT_HOOK(vb2_fill_handoff_cbmem) #endif