/* Copyright 2017 The Chromium OS Authors. All rights reserved. * Use of this source code is governed by a BSD-style license that can be * found in the LICENSE file. */ /* * Verify and jump to a RW image if power supply is not sufficient. */ #include "battery.h" #include "charge_manager.h" #include "chipset.h" #include "clock.h" #include "console.h" #include "flash.h" #include "hooks.h" #include "host_command.h" #include "rsa.h" #include "rwsig.h" #include "sha256.h" #include "shared_mem.h" #include "system.h" #include "usb_pd.h" #include "vboot.h" #include "vb21_struct.h" #define CPRINTS(format, args...) cprints(CC_VBOOT,"VB " format, ## args) #define CPRINTF(format, args...) cprintf(CC_VBOOT,"VB " format, ## args) static int has_matrix_keyboard(void) { return 0; } static int is_efs_supported(void) { #ifdef CONFIG_VBOOT_EFS return 1; #else return 0; #endif } static int is_low_power_ap_boot_supported(void) { return 0; } static int verify_slot(enum system_image_copy_t slot) { const struct vb21_packed_key *vb21_key; const struct vb21_signature *vb21_sig; const struct rsa_public_key *key; const uint8_t *sig; const uint8_t *data; int len; int rv; CPRINTS("Verifying %s", system_image_copy_t_to_string(slot)); vb21_key = (const struct vb21_packed_key *)( CONFIG_MAPPED_STORAGE_BASE + CONFIG_EC_PROTECTED_STORAGE_OFF + CONFIG_RO_PUBKEY_STORAGE_OFF); rv = vb21_is_packed_key_valid(vb21_key); if (rv) { CPRINTS("Invalid key (%d)", rv); return EC_ERROR_VBOOT_KEY; } key = (const struct rsa_public_key *) ((const uint8_t *)vb21_key + vb21_key->key_offset); if (slot == SYSTEM_IMAGE_RW_A) { data = (const uint8_t *)(CONFIG_MAPPED_STORAGE_BASE + CONFIG_EC_WRITABLE_STORAGE_OFF + CONFIG_RW_A_STORAGE_OFF); vb21_sig = (const struct vb21_signature *)( CONFIG_MAPPED_STORAGE_BASE + CONFIG_EC_WRITABLE_STORAGE_OFF + CONFIG_RW_A_SIGN_STORAGE_OFF); } else { data = (const uint8_t *)(CONFIG_MAPPED_STORAGE_BASE + CONFIG_EC_WRITABLE_STORAGE_OFF + CONFIG_RW_B_STORAGE_OFF); vb21_sig = (const struct vb21_signature *)( CONFIG_MAPPED_STORAGE_BASE + CONFIG_EC_WRITABLE_STORAGE_OFF + CONFIG_RW_B_SIGN_STORAGE_OFF); } rv = vb21_is_signature_valid(vb21_sig, vb21_key); if (rv) { CPRINTS("Invalid signature (%d)", rv); return EC_ERROR_INVAL; } sig = (const uint8_t *)vb21_sig + vb21_sig->sig_offset; len = vb21_sig->data_size; if (vboot_is_padding_valid(data, len, CONFIG_RW_SIZE - CONFIG_RW_SIG_SIZE)) { CPRINTS("Invalid padding"); return EC_ERROR_INVAL; } rv = vboot_verify(data, len, key, sig); if (rv) { CPRINTS("Invalid data (%d)", rv); return EC_ERROR_INVAL; } CPRINTS("Verified %s", system_image_copy_t_to_string(slot)); return EC_SUCCESS; } static enum ec_status hc_verify_slot(struct host_cmd_handler_args *args) { const struct ec_params_efs_verify *p = args->params; enum system_image_copy_t slot; switch (p->region) { case EC_FLASH_REGION_ACTIVE: slot = system_get_active_copy(); break; case EC_FLASH_REGION_UPDATE: slot = system_get_update_copy(); break; default: return EC_RES_INVALID_PARAM; } return verify_slot(slot) ? EC_RES_ERROR : EC_RES_SUCCESS; } DECLARE_HOST_COMMAND(EC_CMD_EFS_VERIFY, hc_verify_slot, EC_VER_MASK(0)); static int verify_and_jump(void) { enum system_image_copy_t slot; int rv; /* 1. Decide which slot to try */ slot = system_get_active_copy(); /* 2. Verify the slot */ rv = verify_slot(slot); if (rv) { if (rv == EC_ERROR_VBOOT_KEY) /* Key error. The other slot isn't worth trying. */ return rv; slot = system_get_update_copy(); /* TODO(chromium:767050): Skip reading key again. */ rv = verify_slot(slot); if (rv) /* Both slots failed */ return rv; /* Proceed with the other slot. If this slot isn't expected, AP * will catch it and request recovery after a few attempts. */ if (system_set_active_copy(slot)) CPRINTS("Failed to activate %s", system_image_copy_t_to_string(slot)); } /* 3. Jump (and reboot) */ rv = system_run_image_copy(slot); CPRINTS("Failed to jump (%d)", rv); return rv; } /* Request more power: charging battery or more powerful AC adapter */ static void request_power(void) { CPRINTS("%s", __func__); } static void request_recovery(void) { CPRINTS("%s", __func__); led_critical(); } static int is_manual_recovery(void) { return host_is_event_set(EC_HOST_EVENT_KEYBOARD_RECOVERY); } static int pd_comm_enabled; int vboot_need_pd_comm(void) { return pd_comm_enabled; } void vboot_main(void) { CPRINTS("Main"); if (system_is_in_rw()) { /* * We come here and immediately return. LED shows power shortage * but it will be immediately corrected if the adapter can * provide enough power. */ CPRINTS("Already in RW. Wait for power..."); request_power(); return; } if (!(flash_get_protect() & EC_FLASH_PROTECT_GPIO_ASSERTED)) { /* * If hardware WP is disabled, PD communication is enabled. * We can return and wait for more power. * Note: If software WP is disabled, we still perform EFS even * though PD communication is enabled. */ CPRINTS("HW-WP not asserted."); request_power(); return; } if (is_manual_recovery()) { CPRINTS("Manual recovery"); if (battery_is_present() || has_matrix_keyboard()) { request_power(); return; } /* We don't request_power because we don't want to assume all * devices support a non type-c charger. We open up a security * hole by allowing EC-RO to do PD negotiation but attackers * don't gain meaningful advantage on devices without a matrix * keyboard */ CPRINTS("Enable PD comm"); pd_comm_enabled = 1; return; } if (!is_efs_supported()) { if (is_low_power_ap_boot_supported()) /* If a device supports this feature, AP's boot power * threshold should be set low. That will let EC-RO * boot AP and softsync take care of RW verification. */ return; request_power(); return; } clock_enable_module(MODULE_FAST_CPU, 1); /* If successful, this won't return. */ verify_and_jump(); clock_enable_module(MODULE_FAST_CPU, 0); /* Failed to jump. Need recovery. */ request_recovery(); }