firmware/lib/vboot_api_kernel.c - mirrors/cros/chromiumos/platform/vboot_reference - Git at Google

 /* Copyright (c) 2013 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.
  *
  * High-level firmware wrapper API - entry points for kernel selection
  */

 #include "sysincludes.h"

 #include "2sysincludes.h"
 #include "2common.h"
 #include "2misc.h"
 #include "2nvstorage.h"
 #include "2rsa.h"
 #include "ec_sync.h"
 #include "gbb_access.h"
 #include "gbb_header.h"
 #include "load_kernel_fw.h"
 #include "region.h"
 #include "rollback_index.h"
 #include "utility.h"
 #include "vb2_common.h"
 #include "vboot_api.h"
 #include "vboot_common.h"
 #include "vboot_kernel.h"
 #include "vboot_nvstorage.h"

 /* Global variables */
 static VbNvContext vnc;
 static struct RollbackSpaceFwmp fwmp;
 static LoadKernelParams lkp;
 static struct vb2_context ctx;
 static uint8_t *unaligned_workbuf;

 #ifdef CHROMEOS_ENVIRONMENT
 /* Global variable accessors for unit tests */

 struct RollbackSpaceFwmp *VbApiKernelGetFwmp(void)
 {
 	return &fwmp;
 }

 struct LoadKernelParams *VbApiKernelGetParams(void)
 {
 	return &lkp;
 }

 #endif

 /**
  * Set recovery request (called from vboot_api_kernel.c functions only)
  */
 static void VbSetRecoveryRequest(struct vb2_context *ctx,
 				 uint32_t recovery_request)
 {
 	VB2_DEBUG("VbSetRecoveryRequest(%d)\n", (int)recovery_request);
 	vb2_nv_set(ctx, VB2_NV_RECOVERY_REQUEST, recovery_request);
 }

 static void VbNvLoad(void)
 {
 	VbExNvStorageRead(vnc.raw);
 	VbNvSetup(&vnc);
 }

 static void VbNvCommit(void)
 {
 	VbNvTeardown(&vnc);
 	if (vnc.raw_changed)
 		VbExNvStorageWrite(vnc.raw);
 }

 void vb2_nv_commit(struct vb2_context *ctx)
 {
 	/* Copy nvdata back to old vboot1 nv context if needed */
 	if (ctx->flags & VB2_CONTEXT_NVDATA_CHANGED) {
 		memcpy(vnc.raw, ctx->nvdata, VB2_NVDATA_SIZE);
 		vnc.raw_changed = 1;
 		ctx->flags &= ~VB2_CONTEXT_NVDATA_CHANGED;
 	}

 	VbNvCommit();
 }

 uint32_t vb2_get_fwmp_flags(void)
 {
 	return fwmp.flags;
 }

 /**
  * Attempt loading a kernel from the specified type(s) of disks.
  *
  * If successful, sets p->disk_handle to the disk for the kernel and returns
  * VBERROR_SUCCESS.
  *
  * @param ctx			Vboot context
  * @param cparams		Vboot common params
  * @param p			Parameters for loading kernel
  * @param get_info_flags	Flags to pass to VbExDiskGetInfo()
  * @return VBERROR_SUCCESS, VBERROR_NO_DISK_FOUND if no disks of the specified
  * type were found, or other non-zero VBERROR_ codes for other failures.
  */
 uint32_t VbTryLoadKernel(struct vb2_context *ctx, VbCommonParams *cparams,
                          uint32_t get_info_flags)
 {
 	VbError_t retval = VBERROR_UNKNOWN;
 	VbDiskInfo* disk_info = NULL;
 	uint32_t disk_count = 0;
 	uint32_t i;

 	VB2_DEBUG("VbTryLoadKernel() start, get_info_flags=0x%x\n",
 		  (unsigned)get_info_flags);

 	lkp.fwmp = &fwmp;
 	lkp.nv_context = &vnc;
 	lkp.disk_handle = NULL;

 	/* Find disks */
 	if (VBERROR_SUCCESS != VbExDiskGetInfo(&disk_info, &disk_count,
 					       get_info_flags))
 		disk_count = 0;

 	VB2_DEBUG("VbTryLoadKernel() found %d disks\n", (int)disk_count);
 	if (0 == disk_count) {
 		VbSetRecoveryRequest(ctx, VBNV_RECOVERY_RW_NO_DISK);
 		return VBERROR_NO_DISK_FOUND;
 	}

 	/* Loop over disks */
 	for (i = 0; i < disk_count; i++) {
 		VB2_DEBUG("VbTryLoadKernel() trying disk %d\n", (int)i);
 		/*
 		 * Sanity-check what we can. FWIW, VbTryLoadKernel() is always
 		 * called with only a single bit set in get_info_flags.
 		 *
 		 * Ensure 512-byte sectors and non-trivially sized disk (for
 		 * cgptlib) and that we got a partition with only the flags we
 		 * asked for.
 		 */
 		if (512 != disk_info[i].bytes_per_lba ||
 		    16 > disk_info[i].lba_count ||
 		    get_info_flags != (disk_info[i].flags &
 				       ~VB_DISK_FLAG_EXTERNAL_GPT)) {
 			VB2_DEBUG("  skipping: bytes_per_lba=%" PRIu64
 				  " lba_count=%" PRIu64 " flags=0x%x\n",
 				  disk_info[i].bytes_per_lba,
 				  disk_info[i].lba_count,
 				  disk_info[i].flags);
 			continue;
 		}
 		lkp.disk_handle = disk_info[i].handle;
 		lkp.bytes_per_lba = disk_info[i].bytes_per_lba;
 		lkp.gpt_lba_count = disk_info[i].lba_count;
 		lkp.streaming_lba_count = disk_info[i].streaming_lba_count
 						?: lkp.gpt_lba_count;
 		lkp.boot_flags |= disk_info[i].flags & VB_DISK_FLAG_EXTERNAL_GPT
 				? BOOT_FLAG_EXTERNAL_GPT : 0;
 		retval = LoadKernel(ctx, &lkp, cparams);
 		VB2_DEBUG("VbTryLoadKernel() LoadKernel() = %d\n", retval);

 		/*
 		 * Stop now if we found a kernel.
 		 *
 		 * TODO: If recovery requested, should track the farthest we
 		 * get, instead of just returning the value from the last disk
 		 * attempted.
 		 */
 		if (VBERROR_SUCCESS == retval)
 			break;
 	}

 	/* If we didn't find any good kernels, don't return a disk handle. */
 	if (VBERROR_SUCCESS != retval) {
 		VbSetRecoveryRequest(ctx, VBNV_RECOVERY_RW_NO_KERNEL);
 		lkp.disk_handle = NULL;
 	}

 	VbExDiskFreeInfo(disk_info, lkp.disk_handle);

 	/*
 	 * Pass through return code.  Recovery reason (if any) has already been
 	 * set by LoadKernel().
 	 */
 	return retval;
 }

 VbError_t VbBootNormal(struct vb2_context *ctx, VbCommonParams *cparams)
 {
 	VbSharedDataHeader *shared =
 		(VbSharedDataHeader *)cparams->shared_data_blob;

 	/* Boot from fixed disk only */
 	VB2_DEBUG("Entering\n");

 	VbError_t rv = VbTryLoadKernel(ctx, cparams, VB_DISK_FLAG_FIXED);

 	VB2_DEBUG("Checking if TPM kernel version needs advancing\n");

 	if ((1 == shared->firmware_index) && (shared->flags & VBSD_FWB_TRIED)) {
 		/*
 		 * Special cases for when we're trying a new firmware B.  These
 		 * are needed because firmware updates also usually change the
 		 * kernel key, which means that the B firmware can only boot a
 		 * new kernel, and the old firmware in A can only boot the
 		 * previous kernel.
 		 *
 		 * Don't advance the TPM if we're trying a new firmware B,
 		 * because we don't yet know if the new kernel will
 		 * successfully boot.  We still want to be able to fall back to
 		 * the previous firmware+kernel if the new firmware+kernel
 		 * fails.
 		 *
 		 * If we found only invalid kernels, reboot and try again.
 		 * This allows us to fall back to the previous firmware+kernel
 		 * instead of giving up and going to recovery mode right away.
 		 * We'll still go to recovery mode if we run out of tries and
 		 * the old firmware can't find a kernel it likes.
 		 */
 		if (rv == VBERROR_INVALID_KERNEL_FOUND) {
 			VB2_DEBUG("Trying FW B; only found invalid kernels.\n");
 			VbSetRecoveryRequest(ctx, VBNV_RECOVERY_NOT_REQUESTED);
 		}

 		return rv;
 	}

 	if ((shared->kernel_version_tpm > shared->kernel_version_tpm_start) &&
 	    RollbackKernelWrite(shared->kernel_version_tpm)) {
 		VB2_DEBUG("Error writing kernel versions to TPM.\n");
 		VbSetRecoveryRequest(ctx, VBNV_RECOVERY_RW_TPM_W_ERROR);
 		return VBERROR_TPM_WRITE_KERNEL;
 	}

 	return rv;
 }

 /* This function is also used by tests */
 void VbApiKernelFree(VbCommonParams *cparams)
 {
 	/* VbSelectAndLoadKernel() always allocates this, tests don't */
 	if (cparams->gbb) {
 		free(cparams->gbb);
 		cparams->gbb = NULL;
 	}
 	if (cparams->bmp) {
 		free(cparams->bmp);
 		cparams->bmp = NULL;
 	}
 }

 static VbError_t vb2_kernel_setup(VbCommonParams *cparams,
 				  VbSelectAndLoadKernelParams *kparams)
 {
 	VbSharedDataHeader *shared =
 		(VbSharedDataHeader *)cparams->shared_data_blob;

 	/* Start timer */
 	shared->timer_vb_select_and_load_kernel_enter = VbExGetTimer();

 	/*
 	 * Set up vboot context.
 	 *
 	 * TODO: Propagate this up to higher API levels, and use more of the
 	 * context fields (e.g. secdatak) and flags.
 	 */
 	memset(&ctx, 0, sizeof(ctx));

 	VbNvLoad();
 	memcpy(ctx.nvdata, vnc.raw, VB2_NVDATA_SIZE);

 	if (shared->recovery_reason)
 		ctx.flags |= VB2_CONTEXT_RECOVERY_MODE;
 	if (shared->flags & VBSD_BOOT_DEV_SWITCH_ON)
 		ctx.flags |= VB2_CONTEXT_DEVELOPER_MODE;

 	ctx.workbuf_size = VB2_KERNEL_WORKBUF_RECOMMENDED_SIZE +
 			VB2_WORKBUF_ALIGN;

 	unaligned_workbuf = ctx.workbuf = malloc(ctx.workbuf_size);
 	if (!unaligned_workbuf) {
 		VB2_DEBUG("Can't allocate work buffer\n");
 		VbSetRecoveryRequest(&ctx, VB2_RECOVERY_RW_SHARED_DATA);
 		return VBERROR_INIT_SHARED_DATA;
 	}

 	if (VB2_SUCCESS != vb2_align(&ctx.workbuf, &ctx.workbuf_size,
 				     VB2_WORKBUF_ALIGN,
 				     VB2_KERNEL_WORKBUF_RECOMMENDED_SIZE)) {
 		VB2_DEBUG("Can't align work buffer\n");
 		VbSetRecoveryRequest(&ctx, VB2_RECOVERY_RW_SHARED_DATA);
 		return VBERROR_INIT_SHARED_DATA;
 	}

 	if (VB2_SUCCESS != vb2_init_context(&ctx)) {
 		VB2_DEBUG("Can't init vb2_context\n");
 		free(unaligned_workbuf);
 		VbSetRecoveryRequest(&ctx, VB2_RECOVERY_RW_SHARED_DATA);
 		return VBERROR_INIT_SHARED_DATA;
 	}

 	struct vb2_shared_data *sd = vb2_get_sd(&ctx);
 	sd->recovery_reason = shared->recovery_reason;

 	/*
 	 * If we're in recovery mode just to do memory retraining, all we
 	 * need to do is reboot.
 	 */
 	if (shared->recovery_reason == VBNV_RECOVERY_TRAIN_AND_REBOOT) {
 		VB2_DEBUG("Reboot after retraining in recovery.\n");
 		return VBERROR_REBOOT_REQUIRED;
 	}

 	/* Fill in params for calls to LoadKernel() */
 	memset(&lkp, 0, sizeof(lkp));
 	lkp.kernel_buffer = kparams->kernel_buffer;
 	lkp.kernel_buffer_size = kparams->kernel_buffer_size;

 	/* Clear output params in case we fail */
 	kparams->disk_handle = NULL;
 	kparams->partition_number = 0;
 	kparams->bootloader_address = 0;
 	kparams->bootloader_size = 0;
 	kparams->flags = 0;
 	memset(kparams->partition_guid, 0, sizeof(kparams->partition_guid));

 	/* Read GBB header, since we'll needs flags from it */
 	cparams->bmp = NULL;
 	cparams->gbb = malloc(sizeof(*cparams->gbb));
 	uint32_t retval = VbGbbReadHeader_static(cparams, cparams->gbb);
 	if (retval)
 		return retval;

 	/* Read kernel version from the TPM.  Ignore errors in recovery mode. */
 	if (RollbackKernelRead(&shared->kernel_version_tpm)) {
 		VB2_DEBUG("Unable to get kernel versions from TPM\n");
 		if (!shared->recovery_reason) {
 			VbSetRecoveryRequest(&ctx,
 					     VBNV_RECOVERY_RW_TPM_R_ERROR);
 			return VBERROR_TPM_READ_KERNEL;
 		}
 	}

 	shared->kernel_version_tpm_start = shared->kernel_version_tpm;

 	/* Read FWMP.  Ignore errors in recovery mode. */
 	if (cparams->gbb->flags & GBB_FLAG_DISABLE_FWMP) {
 		memset(&fwmp, 0, sizeof(fwmp));
 	} else if (RollbackFwmpRead(&fwmp)) {
 		VB2_DEBUG("Unable to get FWMP from TPM\n");
 		if (!shared->recovery_reason) {
 			VbSetRecoveryRequest(&ctx,
 					     VBNV_RECOVERY_RW_TPM_R_ERROR);
 			return VBERROR_TPM_READ_FWMP;
 		}
 	}

 	return VBERROR_SUCCESS;
 }

 static VbError_t vb2_kernel_phase4(VbCommonParams *cparams,
 				   VbSelectAndLoadKernelParams *kparams)
 {
 	VbSharedDataHeader *shared =
 		(VbSharedDataHeader *)cparams->shared_data_blob;

 	/* Save disk parameters */
 	kparams->disk_handle = lkp.disk_handle;
 	kparams->partition_number = lkp.partition_number;
 	kparams->bootloader_address = lkp.bootloader_address;
 	kparams->bootloader_size = lkp.bootloader_size;
 	kparams->flags = lkp.flags;
 	kparams->kernel_buffer = lkp.kernel_buffer;
 	kparams->kernel_buffer_size = lkp.kernel_buffer_size;
 	memcpy(kparams->partition_guid, lkp.partition_guid,
 	       sizeof(kparams->partition_guid));

 	/* Lock the kernel versions if not in recovery mode */
 	if (!shared->recovery_reason &&
 	    RollbackKernelLock(shared->recovery_reason)) {
 		VB2_DEBUG("Error locking kernel versions.\n");
 		VbSetRecoveryRequest(&ctx, VBNV_RECOVERY_RW_TPM_L_ERROR);
 		return VBERROR_TPM_LOCK_KERNEL;
 	}

 	return VBERROR_SUCCESS;
 }

 static void vb2_kernel_cleanup(struct vb2_context *ctx, VbCommonParams *cparams)
 {
 	VbSharedDataHeader *shared =
 			(VbSharedDataHeader *)cparams->shared_data_blob;

 	/*
 	 * Clean up vboot context.
 	 *
 	 * TODO: This should propagate up to higher levels
 	 */

 	/* Free buffers */
 	free(unaligned_workbuf);
 	VbApiKernelFree(cparams);

 	vb2_nv_commit(ctx);

 	/* Stop timer */
 	shared->timer_vb_select_and_load_kernel_exit = VbExGetTimer();
 }

 VbError_t VbSelectAndLoadKernel(VbCommonParams *cparams,
                                 VbSelectAndLoadKernelParams *kparams)
 {
 	VbSharedDataHeader *shared =
 		(VbSharedDataHeader *)cparams->shared_data_blob;

 	VbError_t retval = vb2_kernel_setup(cparams, kparams);
 	if (retval)
 		goto VbSelectAndLoadKernel_exit;

 	/*
 	 * Do EC software sync if necessary.  This has UI, but it's just a
 	 * single non-interactive WAIT screen.
 	 */
 	retval = ec_sync_all(&ctx, cparams);
 	if (retval)
 		goto VbSelectAndLoadKernel_exit;

 	/* Select boot path */
 	if (shared->recovery_reason) {
 		/* Recovery boot.  This has UI. */
 	        if (kparams->inflags & VB_SALK_INFLAGS_ENABLE_DETACHABLE_UI)
 	            retval = VbBootRecoveryMenu(&ctx, cparams);
 	        else
 		    retval = VbBootRecovery(&ctx, cparams);
 		VbExEcEnteringMode(0, VB_EC_RECOVERY);
 	} else if (shared->flags & VBSD_BOOT_DEV_SWITCH_ON) {
 		/* Developer boot.  This has UI. */
 	        if (kparams->inflags & VB_SALK_INFLAGS_ENABLE_DETACHABLE_UI)
 		    retval = VbBootDeveloperMenu(&ctx, cparams);
 		else
 		    retval = VbBootDeveloper(&ctx, cparams);
 		VbExEcEnteringMode(0, VB_EC_DEVELOPER);
 	} else {
 		/* Normal boot */
 		retval = VbBootNormal(&ctx, cparams);
 		VbExEcEnteringMode(0, VB_EC_NORMAL);
 	}

  VbSelectAndLoadKernel_exit:

 	if (VBERROR_SUCCESS == retval)
 		retval = vb2_kernel_phase4(cparams, kparams);

 	vb2_kernel_cleanup(&ctx, cparams);

 	/* Pass through return value from boot path */
 	VB2_DEBUG("Returning %d\n", (int)retval);
 	return retval;
 }

 VbError_t VbVerifyMemoryBootImage(VbCommonParams *cparams,
 				  VbSelectAndLoadKernelParams *kparams,
 				  void *boot_image,
 				  size_t image_size)
 {
 	VbError_t retval;
 	VbPublicKey* kernel_subkey = NULL;
 	uint8_t *kbuf;
 	VbKeyBlockHeader *key_block;
 	VbSharedDataHeader *shared =
 		(VbSharedDataHeader *)cparams->shared_data_blob;
 	VbKernelPreambleHeader *preamble;
 	uint64_t body_offset;
 	int hash_only = 0;
 	int dev_switch;
 	uint32_t allow_fastboot_full_cap = 0;
 	uint8_t *workbuf = NULL;
 	struct vb2_workbuf wb;

 	if ((boot_image == NULL) || (image_size == 0))
 		return VBERROR_INVALID_PARAMETER;

 	/* Clear output params in case we fail. */
 	kparams->disk_handle = NULL;
 	kparams->partition_number = 0;
 	kparams->bootloader_address = 0;
 	kparams->bootloader_size = 0;
 	kparams->flags = 0;
 	memset(kparams->partition_guid, 0, sizeof(kparams->partition_guid));

 	kbuf = boot_image;

 	/* Read GBB Header */
 	cparams->bmp = NULL;
 	cparams->gbb = malloc(sizeof(*cparams->gbb));
 	retval = VbGbbReadHeader_static(cparams, cparams->gbb);
 	if (VBERROR_SUCCESS != retval) {
 		VB2_DEBUG("Gbb read header failed.\n");
 		return retval;
 	}

 	/*
 	 * We don't care verifying the image if:
 	 * 1. dev-mode switch is on and
 	 * 2a. GBB_FLAG_FORCE_DEV_BOOT_FASTBOOT_FULL_CAP is set, or
 	 * 2b. DEV_BOOT_FASTBOOT_FULL_CAP flag is set in NvStorage
 	 *
 	 * Check only the integrity of the image.
 	 */
 	dev_switch = shared->flags & VBSD_BOOT_DEV_SWITCH_ON;

 	VbNvLoad();
 	VbNvGet(&vnc, VB2_NV_DEV_BOOT_FASTBOOT_FULL_CAP,
 		&allow_fastboot_full_cap);

 	if (0 == allow_fastboot_full_cap) {
 		allow_fastboot_full_cap = !!(cparams->gbb->flags &
 				GBB_FLAG_FORCE_DEV_BOOT_FASTBOOT_FULL_CAP);
 	}

 	if (dev_switch && allow_fastboot_full_cap) {
 		VB2_DEBUG("Only performing integrity-check.\n");
 		hash_only = 1;
 	} else {
 		/* Get recovery key. */
 		retval = VbGbbReadRecoveryKey(cparams, &kernel_subkey);
 		if (VBERROR_SUCCESS != retval) {
 			VB2_DEBUG("Gbb Read Recovery key failed.\n");
 			return retval;
 		}
 	}

 	/* If we fail at any step, retval returned would be invalid kernel. */
 	retval = VBERROR_INVALID_KERNEL_FOUND;

 	/* Allocate work buffer */
 	workbuf = (uint8_t *)malloc(VB2_KERNEL_WORKBUF_RECOMMENDED_SIZE);
 	if (!workbuf)
 		goto fail;
 	vb2_workbuf_init(&wb, workbuf, VB2_KERNEL_WORKBUF_RECOMMENDED_SIZE);

 	/* Verify the key block. */
 	key_block = (VbKeyBlockHeader *)kbuf;
 	struct vb2_keyblock *keyblock2 = (struct vb2_keyblock *)kbuf;
 	int rv;
 	if (hash_only) {
 		rv = vb2_verify_keyblock_hash(keyblock2, image_size, &wb);
 	} else {
 		/* Unpack kernel subkey */
 		struct vb2_public_key kernel_subkey2;
 		if (VB2_SUCCESS !=
 		    vb2_unpack_key(&kernel_subkey2,
 				   (struct vb2_packed_key *)kernel_subkey)) {
 			VB2_DEBUG("Unable to unpack kernel subkey\n");
 			goto fail;
 		}
 		rv = vb2_verify_keyblock(keyblock2, image_size,
 					 &kernel_subkey2, &wb);
 	}

 	if (VB2_SUCCESS != rv) {
 		VB2_DEBUG("Verifying key block signature/hash failed.\n");
 		goto fail;
 	}

 	/* Check the key block flags against the current boot mode. */
 	if (!(key_block->key_block_flags &
 	      (dev_switch ? KEY_BLOCK_FLAG_DEVELOPER_1 :
 	       KEY_BLOCK_FLAG_DEVELOPER_0))) {
 		VB2_DEBUG("Key block developer flag mismatch.\n");
 		if (hash_only == 0)
 			goto fail;
 	}

 	if (!(key_block->key_block_flags & KEY_BLOCK_FLAG_RECOVERY_1)) {
 		VB2_DEBUG("Key block recovery flag mismatch.\n");
 		if (hash_only == 0)
 			goto fail;
 	}

 	/* Get key for preamble/data verification from the key block. */
 	struct vb2_public_key data_key2;
 	if (VB2_SUCCESS != vb2_unpack_key(&data_key2, &keyblock2->data_key)) {
 		VB2_DEBUG("Unable to unpack kernel data key\n");
 		goto fail;
 	}

 	/* Verify the preamble, which follows the key block */
 	preamble = (VbKernelPreambleHeader *)(kbuf + key_block->key_block_size);
 	struct vb2_kernel_preamble *preamble2 =
 			(struct vb2_kernel_preamble *)
 			(kbuf + key_block->key_block_size);

 	if (VB2_SUCCESS != vb2_verify_kernel_preamble(
 			preamble2,
 			image_size - key_block->key_block_size,
 			&data_key2,
 			&wb)) {
 		VB2_DEBUG("Preamble verification failed.\n");
 		goto fail;
 	}

 	VB2_DEBUG("Kernel preamble is good.\n");

 	/* Verify kernel data */
 	body_offset = key_block->key_block_size + preamble->preamble_size;
 	if (VB2_SUCCESS != vb2_verify_data(
 			(const uint8_t *)(kbuf + body_offset),
 			image_size - body_offset,
 			(struct vb2_signature *)&preamble->body_signature,
 			&data_key2, &wb)) {
 		VB2_DEBUG("Kernel data verification failed.\n");
 		goto fail;
 	}

 	VB2_DEBUG("Kernel is good.\n");

 	/* Fill in output parameters. */
 	kparams->kernel_buffer = kbuf + body_offset;
 	kparams->kernel_buffer_size = image_size - body_offset;
 	kparams->bootloader_address = preamble->bootloader_address;
 	kparams->bootloader_size = preamble->bootloader_size;
 	if (VbKernelHasFlags(preamble) == VBOOT_SUCCESS)
 		kparams->flags = preamble->flags;

 	retval = VBERROR_SUCCESS;

 fail:
 	VbApiKernelFree(cparams);
 	if (NULL != kernel_subkey)
 		free(kernel_subkey);
 	if (NULL != workbuf)
 		free(workbuf);
 	return retval;
 }

 VbError_t VbUnlockDevice(void)
 {
 	VB2_DEBUG("Enabling dev-mode...\n");
 	if (TPM_SUCCESS != SetVirtualDevMode(1))
 		return VBERROR_TPM_SET_BOOT_MODE_STATE;

 	VB2_DEBUG("Mode change will take effect on next reboot.\n");
 	return VBERROR_SUCCESS;
 }

 VbError_t VbLockDevice(void)
 {
 	VbNvLoad();

 	VB2_DEBUG("Storing request to leave dev-mode.\n");
 	VbNvSet(&vnc, VBNV_DISABLE_DEV_REQUEST, 1);

 	VbNvCommit();

 	VB2_DEBUG("Mode change will take effect on next reboot.\n");

 	return VBERROR_SUCCESS;
 }
	/* Copyright (c) 2013 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.
	*
	* High-level firmware wrapper API - entry points for kernel selection
	*/

	#include "sysincludes.h"

	#include "2sysincludes.h"
	#include "2common.h"
	#include "2misc.h"
	#include "2nvstorage.h"
	#include "2rsa.h"
	#include "ec_sync.h"
	#include "gbb_access.h"
	#include "gbb_header.h"
	#include "load_kernel_fw.h"
	#include "region.h"
	#include "rollback_index.h"
	#include "utility.h"
	#include "vb2_common.h"
	#include "vboot_api.h"
	#include "vboot_common.h"
	#include "vboot_kernel.h"
	#include "vboot_nvstorage.h"

	/* Global variables */
	static VbNvContext vnc;
	static struct RollbackSpaceFwmp fwmp;
	static LoadKernelParams lkp;
	static struct vb2_context ctx;
	static uint8_t *unaligned_workbuf;

	#ifdef CHROMEOS_ENVIRONMENT
	/* Global variable accessors for unit tests */

	struct RollbackSpaceFwmp *VbApiKernelGetFwmp(void)
	{
	return &fwmp;
	}

	struct LoadKernelParams *VbApiKernelGetParams(void)
	{
	return &lkp;
	}

	#endif

	/**
	* Set recovery request (called from vboot_api_kernel.c functions only)
	*/
	static void VbSetRecoveryRequest(struct vb2_context *ctx,
	uint32_t recovery_request)
	{
	VB2_DEBUG("VbSetRecoveryRequest(%d)\n", (int)recovery_request);
	vb2_nv_set(ctx, VB2_NV_RECOVERY_REQUEST, recovery_request);
	}

	static void VbNvLoad(void)
	{
	VbExNvStorageRead(vnc.raw);
	VbNvSetup(&vnc);
	}

	static void VbNvCommit(void)
	{
	VbNvTeardown(&vnc);
	if (vnc.raw_changed)
	VbExNvStorageWrite(vnc.raw);
	}

	void vb2_nv_commit(struct vb2_context *ctx)
	{
	/* Copy nvdata back to old vboot1 nv context if needed */
	if (ctx->flags & VB2_CONTEXT_NVDATA_CHANGED) {
	memcpy(vnc.raw, ctx->nvdata, VB2_NVDATA_SIZE);
	vnc.raw_changed = 1;
	ctx->flags &= ~VB2_CONTEXT_NVDATA_CHANGED;
	}

	VbNvCommit();
	}

	uint32_t vb2_get_fwmp_flags(void)
	{
	return fwmp.flags;
	}

	/**
	* Attempt loading a kernel from the specified type(s) of disks.
	*
	* If successful, sets p->disk_handle to the disk for the kernel and returns
	* VBERROR_SUCCESS.
	*
	* @param ctx Vboot context
	* @param cparams Vboot common params
	* @param p Parameters for loading kernel
	* @param get_info_flags Flags to pass to VbExDiskGetInfo()
	* @return VBERROR_SUCCESS, VBERROR_NO_DISK_FOUND if no disks of the specified
	* type were found, or other non-zero VBERROR_ codes for other failures.
	*/
	uint32_t VbTryLoadKernel(struct vb2_context ctx, VbCommonParams cparams,
	uint32_t get_info_flags)
	{
	VbError_t retval = VBERROR_UNKNOWN;
	VbDiskInfo* disk_info = NULL;
	uint32_t disk_count = 0;
	uint32_t i;

	VB2_DEBUG("VbTryLoadKernel() start, get_info_flags=0x%x\n",
	(unsigned)get_info_flags);

	lkp.fwmp = &fwmp;
	lkp.nv_context = &vnc;
	lkp.disk_handle = NULL;

	/* Find disks */
	if (VBERROR_SUCCESS != VbExDiskGetInfo(&disk_info, &disk_count,
	get_info_flags))
	disk_count = 0;

	VB2_DEBUG("VbTryLoadKernel() found %d disks\n", (int)disk_count);
	if (0 == disk_count) {
	VbSetRecoveryRequest(ctx, VBNV_RECOVERY_RW_NO_DISK);
	return VBERROR_NO_DISK_FOUND;
	}

	/* Loop over disks */
	for (i = 0; i < disk_count; i++) {
	VB2_DEBUG("VbTryLoadKernel() trying disk %d\n", (int)i);
	/*
	* Sanity-check what we can. FWIW, VbTryLoadKernel() is always
	* called with only a single bit set in get_info_flags.
	*
	* Ensure 512-byte sectors and non-trivially sized disk (for
	* cgptlib) and that we got a partition with only the flags we
	* asked for.
	*/
	if (512 != disk_info[i].bytes_per_lba \|\|
	16 > disk_info[i].lba_count \|\|
	get_info_flags != (disk_info[i].flags &
	~VB_DISK_FLAG_EXTERNAL_GPT)) {
	VB2_DEBUG(" skipping: bytes_per_lba=%" PRIu64
	" lba_count=%" PRIu64 " flags=0x%x\n",
	disk_info[i].bytes_per_lba,
	disk_info[i].lba_count,
	disk_info[i].flags);
	continue;
	}
	lkp.disk_handle = disk_info[i].handle;
	lkp.bytes_per_lba = disk_info[i].bytes_per_lba;
	lkp.gpt_lba_count = disk_info[i].lba_count;
	lkp.streaming_lba_count = disk_info[i].streaming_lba_count
	?: lkp.gpt_lba_count;
	lkp.boot_flags \|= disk_info[i].flags & VB_DISK_FLAG_EXTERNAL_GPT
	? BOOT_FLAG_EXTERNAL_GPT : 0;
	retval = LoadKernel(ctx, &lkp, cparams);
	VB2_DEBUG("VbTryLoadKernel() LoadKernel() = %d\n", retval);

	/*
	* Stop now if we found a kernel.
	*
	* TODO: If recovery requested, should track the farthest we
	* get, instead of just returning the value from the last disk
	* attempted.
	*/
	if (VBERROR_SUCCESS == retval)
	break;
	}

	/* If we didn't find any good kernels, don't return a disk handle. */
	if (VBERROR_SUCCESS != retval) {
	VbSetRecoveryRequest(ctx, VBNV_RECOVERY_RW_NO_KERNEL);
	lkp.disk_handle = NULL;
	}

	VbExDiskFreeInfo(disk_info, lkp.disk_handle);

	/*
	* Pass through return code. Recovery reason (if any) has already been
	* set by LoadKernel().
	*/
	return retval;
	}

	VbError_t VbBootNormal(struct vb2_context ctx, VbCommonParams cparams)
	{
	VbSharedDataHeader *shared =
	(VbSharedDataHeader *)cparams->shared_data_blob;

	/* Boot from fixed disk only */
	VB2_DEBUG("Entering\n");

	VbError_t rv = VbTryLoadKernel(ctx, cparams, VB_DISK_FLAG_FIXED);

	VB2_DEBUG("Checking if TPM kernel version needs advancing\n");

	if ((1 == shared->firmware_index) && (shared->flags & VBSD_FWB_TRIED)) {
	/*
	* Special cases for when we're trying a new firmware B. These
	* are needed because firmware updates also usually change the
	* kernel key, which means that the B firmware can only boot a
	* new kernel, and the old firmware in A can only boot the
	* previous kernel.
	*
	* Don't advance the TPM if we're trying a new firmware B,
	* because we don't yet know if the new kernel will
	* successfully boot. We still want to be able to fall back to
	* the previous firmware+kernel if the new firmware+kernel
	* fails.
	*
	* If we found only invalid kernels, reboot and try again.
	* This allows us to fall back to the previous firmware+kernel
	* instead of giving up and going to recovery mode right away.
	* We'll still go to recovery mode if we run out of tries and
	* the old firmware can't find a kernel it likes.
	*/
	if (rv == VBERROR_INVALID_KERNEL_FOUND) {
	VB2_DEBUG("Trying FW B; only found invalid kernels.\n");
	VbSetRecoveryRequest(ctx, VBNV_RECOVERY_NOT_REQUESTED);
	}

	return rv;
	}

	if ((shared->kernel_version_tpm > shared->kernel_version_tpm_start) &&
	RollbackKernelWrite(shared->kernel_version_tpm)) {
	VB2_DEBUG("Error writing kernel versions to TPM.\n");
	VbSetRecoveryRequest(ctx, VBNV_RECOVERY_RW_TPM_W_ERROR);
	return VBERROR_TPM_WRITE_KERNEL;
	}

	return rv;
	}

	/* This function is also used by tests */
	void VbApiKernelFree(VbCommonParams *cparams)
	{
	/* VbSelectAndLoadKernel() always allocates this, tests don't */
	if (cparams->gbb) {
	free(cparams->gbb);
	cparams->gbb = NULL;
	}
	if (cparams->bmp) {
	free(cparams->bmp);
	cparams->bmp = NULL;
	}
	}

	static VbError_t vb2_kernel_setup(VbCommonParams *cparams,
	VbSelectAndLoadKernelParams *kparams)
	{
	VbSharedDataHeader *shared =
	(VbSharedDataHeader *)cparams->shared_data_blob;

	/* Start timer */
	shared->timer_vb_select_and_load_kernel_enter = VbExGetTimer();

	/*
	* Set up vboot context.
	*
	* TODO: Propagate this up to higher API levels, and use more of the
	* context fields (e.g. secdatak) and flags.
	*/
	memset(&ctx, 0, sizeof(ctx));

	VbNvLoad();
	memcpy(ctx.nvdata, vnc.raw, VB2_NVDATA_SIZE);

	if (shared->recovery_reason)
	ctx.flags \|= VB2_CONTEXT_RECOVERY_MODE;
	if (shared->flags & VBSD_BOOT_DEV_SWITCH_ON)
	ctx.flags \|= VB2_CONTEXT_DEVELOPER_MODE;

	ctx.workbuf_size = VB2_KERNEL_WORKBUF_RECOMMENDED_SIZE +
	VB2_WORKBUF_ALIGN;

	unaligned_workbuf = ctx.workbuf = malloc(ctx.workbuf_size);
	if (!unaligned_workbuf) {
	VB2_DEBUG("Can't allocate work buffer\n");
	VbSetRecoveryRequest(&ctx, VB2_RECOVERY_RW_SHARED_DATA);
	return VBERROR_INIT_SHARED_DATA;
	}

	if (VB2_SUCCESS != vb2_align(&ctx.workbuf, &ctx.workbuf_size,
	VB2_WORKBUF_ALIGN,
	VB2_KERNEL_WORKBUF_RECOMMENDED_SIZE)) {
	VB2_DEBUG("Can't align work buffer\n");
	VbSetRecoveryRequest(&ctx, VB2_RECOVERY_RW_SHARED_DATA);
	return VBERROR_INIT_SHARED_DATA;
	}

	if (VB2_SUCCESS != vb2_init_context(&ctx)) {
	VB2_DEBUG("Can't init vb2_context\n");
	free(unaligned_workbuf);
	VbSetRecoveryRequest(&ctx, VB2_RECOVERY_RW_SHARED_DATA);
	return VBERROR_INIT_SHARED_DATA;
	}

	struct vb2_shared_data *sd = vb2_get_sd(&ctx);
	sd->recovery_reason = shared->recovery_reason;

	/*
	* If we're in recovery mode just to do memory retraining, all we
	* need to do is reboot.
	*/
	if (shared->recovery_reason == VBNV_RECOVERY_TRAIN_AND_REBOOT) {
	VB2_DEBUG("Reboot after retraining in recovery.\n");
	return VBERROR_REBOOT_REQUIRED;
	}

	/* Fill in params for calls to LoadKernel() */
	memset(&lkp, 0, sizeof(lkp));
	lkp.kernel_buffer = kparams->kernel_buffer;
	lkp.kernel_buffer_size = kparams->kernel_buffer_size;

	/* Clear output params in case we fail */
	kparams->disk_handle = NULL;
	kparams->partition_number = 0;
	kparams->bootloader_address = 0;
	kparams->bootloader_size = 0;
	kparams->flags = 0;
	memset(kparams->partition_guid, 0, sizeof(kparams->partition_guid));

	/* Read GBB header, since we'll needs flags from it */
	cparams->bmp = NULL;
	cparams->gbb = malloc(sizeof(*cparams->gbb));
	uint32_t retval = VbGbbReadHeader_static(cparams, cparams->gbb);
	if (retval)
	return retval;

	/* Read kernel version from the TPM. Ignore errors in recovery mode. */
	if (RollbackKernelRead(&shared->kernel_version_tpm)) {
	VB2_DEBUG("Unable to get kernel versions from TPM\n");
	if (!shared->recovery_reason) {
	VbSetRecoveryRequest(&ctx,
	VBNV_RECOVERY_RW_TPM_R_ERROR);
	return VBERROR_TPM_READ_KERNEL;
	}
	}

	shared->kernel_version_tpm_start = shared->kernel_version_tpm;

	/* Read FWMP. Ignore errors in recovery mode. */
	if (cparams->gbb->flags & GBB_FLAG_DISABLE_FWMP) {
	memset(&fwmp, 0, sizeof(fwmp));
	} else if (RollbackFwmpRead(&fwmp)) {
	VB2_DEBUG("Unable to get FWMP from TPM\n");
	if (!shared->recovery_reason) {
	VbSetRecoveryRequest(&ctx,
	VBNV_RECOVERY_RW_TPM_R_ERROR);
	return VBERROR_TPM_READ_FWMP;
	}
	}

	return VBERROR_SUCCESS;
	}

	static VbError_t vb2_kernel_phase4(VbCommonParams *cparams,
	VbSelectAndLoadKernelParams *kparams)
	{
	VbSharedDataHeader *shared =
	(VbSharedDataHeader *)cparams->shared_data_blob;

	/* Save disk parameters */
	kparams->disk_handle = lkp.disk_handle;
	kparams->partition_number = lkp.partition_number;
	kparams->bootloader_address = lkp.bootloader_address;
	kparams->bootloader_size = lkp.bootloader_size;
	kparams->flags = lkp.flags;
	kparams->kernel_buffer = lkp.kernel_buffer;
	kparams->kernel_buffer_size = lkp.kernel_buffer_size;
	memcpy(kparams->partition_guid, lkp.partition_guid,
	sizeof(kparams->partition_guid));

	/* Lock the kernel versions if not in recovery mode */
	if (!shared->recovery_reason &&
	RollbackKernelLock(shared->recovery_reason)) {
	VB2_DEBUG("Error locking kernel versions.\n");
	VbSetRecoveryRequest(&ctx, VBNV_RECOVERY_RW_TPM_L_ERROR);
	return VBERROR_TPM_LOCK_KERNEL;
	}

	return VBERROR_SUCCESS;
	}

	static void vb2_kernel_cleanup(struct vb2_context ctx, VbCommonParams cparams)
	{
	VbSharedDataHeader *shared =
	(VbSharedDataHeader *)cparams->shared_data_blob;

	/*
	* Clean up vboot context.
	*
	* TODO: This should propagate up to higher levels
	*/

	/* Free buffers */
	free(unaligned_workbuf);
	VbApiKernelFree(cparams);

	vb2_nv_commit(ctx);

	/* Stop timer */
	shared->timer_vb_select_and_load_kernel_exit = VbExGetTimer();
	}

	VbError_t VbSelectAndLoadKernel(VbCommonParams *cparams,
	VbSelectAndLoadKernelParams *kparams)
	{
	VbSharedDataHeader *shared =
	(VbSharedDataHeader *)cparams->shared_data_blob;

	VbError_t retval = vb2_kernel_setup(cparams, kparams);
	if (retval)
	goto VbSelectAndLoadKernel_exit;

	/*
	* Do EC software sync if necessary. This has UI, but it's just a
	* single non-interactive WAIT screen.
	*/
	retval = ec_sync_all(&ctx, cparams);
	if (retval)
	goto VbSelectAndLoadKernel_exit;

	/* Select boot path */
	if (shared->recovery_reason) {
	/* Recovery boot. This has UI. */
	if (kparams->inflags & VB_SALK_INFLAGS_ENABLE_DETACHABLE_UI)
	retval = VbBootRecoveryMenu(&ctx, cparams);
	else
	retval = VbBootRecovery(&ctx, cparams);
	VbExEcEnteringMode(0, VB_EC_RECOVERY);
	} else if (shared->flags & VBSD_BOOT_DEV_SWITCH_ON) {
	/* Developer boot. This has UI. */
	if (kparams->inflags & VB_SALK_INFLAGS_ENABLE_DETACHABLE_UI)
	retval = VbBootDeveloperMenu(&ctx, cparams);
	else
	retval = VbBootDeveloper(&ctx, cparams);
	VbExEcEnteringMode(0, VB_EC_DEVELOPER);
	} else {
	/* Normal boot */
	retval = VbBootNormal(&ctx, cparams);
	VbExEcEnteringMode(0, VB_EC_NORMAL);
	}

	VbSelectAndLoadKernel_exit:

	if (VBERROR_SUCCESS == retval)
	retval = vb2_kernel_phase4(cparams, kparams);

	vb2_kernel_cleanup(&ctx, cparams);

	/* Pass through return value from boot path */
	VB2_DEBUG("Returning %d\n", (int)retval);
	return retval;
	}

	VbError_t VbVerifyMemoryBootImage(VbCommonParams *cparams,
	VbSelectAndLoadKernelParams *kparams,
	void *boot_image,
	size_t image_size)
	{
	VbError_t retval;
	VbPublicKey* kernel_subkey = NULL;
	uint8_t *kbuf;
	VbKeyBlockHeader *key_block;
	VbSharedDataHeader *shared =
	(VbSharedDataHeader *)cparams->shared_data_blob;
	VbKernelPreambleHeader *preamble;
	uint64_t body_offset;
	int hash_only = 0;
	int dev_switch;
	uint32_t allow_fastboot_full_cap = 0;
	uint8_t *workbuf = NULL;
	struct vb2_workbuf wb;

	if ((boot_image == NULL) \|\| (image_size == 0))
	return VBERROR_INVALID_PARAMETER;

	/* Clear output params in case we fail. */
	kparams->disk_handle = NULL;
	kparams->partition_number = 0;
	kparams->bootloader_address = 0;
	kparams->bootloader_size = 0;
	kparams->flags = 0;
	memset(kparams->partition_guid, 0, sizeof(kparams->partition_guid));

	kbuf = boot_image;

	/* Read GBB Header */
	cparams->bmp = NULL;
	cparams->gbb = malloc(sizeof(*cparams->gbb));
	retval = VbGbbReadHeader_static(cparams, cparams->gbb);
	if (VBERROR_SUCCESS != retval) {
	VB2_DEBUG("Gbb read header failed.\n");
	return retval;
	}

	/*
	* We don't care verifying the image if:
	* 1. dev-mode switch is on and
	* 2a. GBB_FLAG_FORCE_DEV_BOOT_FASTBOOT_FULL_CAP is set, or
	* 2b. DEV_BOOT_FASTBOOT_FULL_CAP flag is set in NvStorage
	*
	* Check only the integrity of the image.
	*/
	dev_switch = shared->flags & VBSD_BOOT_DEV_SWITCH_ON;

	VbNvLoad();
	VbNvGet(&vnc, VB2_NV_DEV_BOOT_FASTBOOT_FULL_CAP,
	&allow_fastboot_full_cap);

	if (0 == allow_fastboot_full_cap) {
	allow_fastboot_full_cap = !!(cparams->gbb->flags &
	GBB_FLAG_FORCE_DEV_BOOT_FASTBOOT_FULL_CAP);
	}

	if (dev_switch && allow_fastboot_full_cap) {
	VB2_DEBUG("Only performing integrity-check.\n");
	hash_only = 1;
	} else {
	/* Get recovery key. */
	retval = VbGbbReadRecoveryKey(cparams, &kernel_subkey);
	if (VBERROR_SUCCESS != retval) {
	VB2_DEBUG("Gbb Read Recovery key failed.\n");
	return retval;
	}
	}

	/* If we fail at any step, retval returned would be invalid kernel. */
	retval = VBERROR_INVALID_KERNEL_FOUND;

	/* Allocate work buffer */
	workbuf = (uint8_t *)malloc(VB2_KERNEL_WORKBUF_RECOMMENDED_SIZE);
	if (!workbuf)
	goto fail;
	vb2_workbuf_init(&wb, workbuf, VB2_KERNEL_WORKBUF_RECOMMENDED_SIZE);

	/* Verify the key block. */
	key_block = (VbKeyBlockHeader *)kbuf;
	struct vb2_keyblock keyblock2 = (struct vb2_keyblock )kbuf;
	int rv;
	if (hash_only) {
	rv = vb2_verify_keyblock_hash(keyblock2, image_size, &wb);
	} else {
	/* Unpack kernel subkey */
	struct vb2_public_key kernel_subkey2;
	if (VB2_SUCCESS !=
	vb2_unpack_key(&kernel_subkey2,
	(struct vb2_packed_key *)kernel_subkey)) {
	VB2_DEBUG("Unable to unpack kernel subkey\n");
	goto fail;
	}
	rv = vb2_verify_keyblock(keyblock2, image_size,
	&kernel_subkey2, &wb);
	}

	if (VB2_SUCCESS != rv) {
	VB2_DEBUG("Verifying key block signature/hash failed.\n");
	goto fail;
	}

	/* Check the key block flags against the current boot mode. */
	if (!(key_block->key_block_flags &
	(dev_switch ? KEY_BLOCK_FLAG_DEVELOPER_1 :
	KEY_BLOCK_FLAG_DEVELOPER_0))) {
	VB2_DEBUG("Key block developer flag mismatch.\n");
	if (hash_only == 0)
	goto fail;
	}

	if (!(key_block->key_block_flags & KEY_BLOCK_FLAG_RECOVERY_1)) {
	VB2_DEBUG("Key block recovery flag mismatch.\n");
	if (hash_only == 0)
	goto fail;
	}

	/* Get key for preamble/data verification from the key block. */
	struct vb2_public_key data_key2;
	if (VB2_SUCCESS != vb2_unpack_key(&data_key2, &keyblock2->data_key)) {
	VB2_DEBUG("Unable to unpack kernel data key\n");
	goto fail;
	}

	/* Verify the preamble, which follows the key block */
	preamble = (VbKernelPreambleHeader *)(kbuf + key_block->key_block_size);
	struct vb2_kernel_preamble *preamble2 =
	(struct vb2_kernel_preamble *)
	(kbuf + key_block->key_block_size);

	if (VB2_SUCCESS != vb2_verify_kernel_preamble(
	preamble2,
	image_size - key_block->key_block_size,
	&data_key2,
	&wb)) {
	VB2_DEBUG("Preamble verification failed.\n");
	goto fail;
	}

	VB2_DEBUG("Kernel preamble is good.\n");

	/* Verify kernel data */
	body_offset = key_block->key_block_size + preamble->preamble_size;
	if (VB2_SUCCESS != vb2_verify_data(
	(const uint8_t *)(kbuf + body_offset),
	image_size - body_offset,
	(struct vb2_signature *)&preamble->body_signature,
	&data_key2, &wb)) {
	VB2_DEBUG("Kernel data verification failed.\n");
	goto fail;
	}

	VB2_DEBUG("Kernel is good.\n");

	/* Fill in output parameters. */
	kparams->kernel_buffer = kbuf + body_offset;
	kparams->kernel_buffer_size = image_size - body_offset;
	kparams->bootloader_address = preamble->bootloader_address;
	kparams->bootloader_size = preamble->bootloader_size;
	if (VbKernelHasFlags(preamble) == VBOOT_SUCCESS)
	kparams->flags = preamble->flags;

	retval = VBERROR_SUCCESS;

	fail:
	VbApiKernelFree(cparams);
	if (NULL != kernel_subkey)
	free(kernel_subkey);
	if (NULL != workbuf)
	free(workbuf);
	return retval;
	}

	VbError_t VbUnlockDevice(void)
	{
	VB2_DEBUG("Enabling dev-mode...\n");
	if (TPM_SUCCESS != SetVirtualDevMode(1))
	return VBERROR_TPM_SET_BOOT_MODE_STATE;

	VB2_DEBUG("Mode change will take effect on next reboot.\n");
	return VBERROR_SUCCESS;
	}

	VbError_t VbLockDevice(void)
	{
	VbNvLoad();

	VB2_DEBUG("Storing request to leave dev-mode.\n");
	VbNvSet(&vnc, VBNV_DISABLE_DEV_REQUEST, 1);

	VbNvCommit();

	VB2_DEBUG("Mode change will take effect on next reboot.\n");

	return VBERROR_SUCCESS;
	}