firmware/lib/vboot_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.
  *
  * Functions for loading a kernel from disk.
  * (Firmware portion)
  */

 #include "sysincludes.h"

 #include "cgptlib.h"
 #include "cgptlib_internal.h"
 #include "region.h"
 #include "gbb_access.h"
 #include "gbb_header.h"
 #include "gpt_misc.h"
 #include "load_kernel_fw.h"
 #include "utility.h"
 #include "vboot_api.h"
 #include "vboot_common.h"
 #include "vboot_kernel.h"

 #define KBUF_SIZE 65536  /* Bytes to read at start of kernel partition */
 #define LOWEST_TPM_VERSION 0xffffffff

 typedef enum BootMode {
 	kBootRecovery = 0,  /* Recovery firmware, any dev switch position */
 	kBootNormal = 1,    /* Normal boot - kernel must be verified */
 	kBootDev = 2        /* Developer boot - self-signed kernel ok */
 } BootMode;

 VbError_t LoadKernel(LoadKernelParams *params, VbCommonParams *cparams)
 {
 	VbSharedDataHeader *shared =
 		(VbSharedDataHeader *)params->shared_data_blob;
 	VbSharedDataKernelCall *shcall = NULL;
 	VbNvContext* vnc = params->nv_context;
 	VbPublicKey* kernel_subkey = NULL;
 	int free_kernel_subkey = 0;
 	GptData gpt;
 	uint64_t part_start, part_size;
 	uint64_t blba;
 	uint64_t kbuf_sectors;
 	uint8_t* kbuf = NULL;
 	int found_partitions = 0;
 	int good_partition = -1;
 	int good_partition_key_block_valid = 0;
 	uint32_t lowest_version = LOWEST_TPM_VERSION;
 	int rec_switch, dev_switch;
 	BootMode boot_mode;
 	uint32_t require_official_os = 0;
 	uint32_t body_toread;
 	uint8_t *body_readptr;

 	VbError_t retval = VBERROR_UNKNOWN;
 	int recovery = VBNV_RECOVERY_LK_UNSPECIFIED;

 	/* Sanity Checks */
 	if (!params->bytes_per_lba ||
 	    !params->streaming_lba_count) {
 		VBDEBUG(("LoadKernel() called with invalid params\n"));
 		retval = VBERROR_INVALID_PARAMETER;
 		goto LoadKernelExit;
 	}

 	/* Clear output params in case we fail */
 	params->partition_number = 0;
 	params->bootloader_address = 0;
 	params->bootloader_size = 0;
 	params->flags = 0;

 	/* Calculate switch positions and boot mode */
 	rec_switch = (BOOT_FLAG_RECOVERY & params->boot_flags ? 1 : 0);
 	dev_switch = (BOOT_FLAG_DEVELOPER & params->boot_flags ? 1 : 0);
 	if (rec_switch) {
 		boot_mode = kBootRecovery;
 	} else if (dev_switch) {
 		boot_mode = kBootDev;
 		VbNvGet(vnc, VBNV_DEV_BOOT_SIGNED_ONLY, &require_official_os);
 	} else {
 		boot_mode = kBootNormal;
 	}

 	/*
 	 * Set up tracking for this call.  This wraps around if called many
 	 * times, so we need to initialize the call entry each time.
 	 */
 	shcall = shared->lk_calls + (shared->lk_call_count
 				     & (VBSD_MAX_KERNEL_CALLS - 1));
 	Memset(shcall, 0, sizeof(VbSharedDataKernelCall));
 	shcall->boot_flags = (uint32_t)params->boot_flags;
 	shcall->boot_mode = boot_mode;
 	shcall->sector_size = (uint32_t)params->bytes_per_lba;
 	shcall->sector_count = params->streaming_lba_count;
 	shared->lk_call_count++;

 	/* Initialization */
 	blba = params->bytes_per_lba;
 	kbuf_sectors = KBUF_SIZE / blba;
 	if (0 == kbuf_sectors) {
 		VBDEBUG(("LoadKernel() called with sector size > KBUF_SIZE\n"));
 		retval = VBERROR_INVALID_PARAMETER;
 		goto LoadKernelExit;
 	}

 	if (kBootRecovery == boot_mode) {
 		/* Use the recovery key to verify the kernel */
 		retval = VbGbbReadRecoveryKey(cparams, &kernel_subkey);
 		if (VBERROR_SUCCESS != retval)
 			goto LoadKernelExit;
 		free_kernel_subkey = 1;
 	} else {
 		/* Use the kernel subkey passed from LoadFirmware(). */
 		kernel_subkey = &shared->kernel_subkey;
 	}

 	/* Read GPT data */
 	gpt.sector_bytes = (uint32_t)blba;
 	gpt.streaming_drive_sectors = params->streaming_lba_count;
 	gpt.gpt_drive_sectors = params->gpt_lba_count;
 	gpt.flags = params->boot_flags & BOOT_FLAG_EXTERNAL_GPT
 			? GPT_FLAG_EXTERNAL : 0;
 	if (0 != AllocAndReadGptData(params->disk_handle, &gpt)) {
 		VBDEBUG(("Unable to read GPT data\n"));
 		shcall->check_result = VBSD_LKC_CHECK_GPT_READ_ERROR;
 		goto bad_gpt;
 	}

 	/* Initialize GPT library */
 	if (GPT_SUCCESS != GptInit(&gpt)) {
 		VBDEBUG(("Error parsing GPT\n"));
 		shcall->check_result = VBSD_LKC_CHECK_GPT_PARSE_ERROR;
 		goto bad_gpt;
 	}

 	/* Allocate kernel header buffers */
 	kbuf = (uint8_t*)VbExMalloc(KBUF_SIZE);
 	if (!kbuf)
 		goto bad_gpt;

         /* Loop over candidate kernel partitions */
         while (GPT_SUCCESS ==
 	       GptNextKernelEntry(&gpt, &part_start, &part_size)) {
 		VbSharedDataKernelPart *shpart = NULL;
 		VbKeyBlockHeader *key_block;
 		VbKernelPreambleHeader *preamble;
 		RSAPublicKey *data_key = NULL;
 		VbExStream_t stream = NULL;
 		uint64_t key_version;
 		uint32_t combined_version;
 		uint64_t body_offset;
 		int key_block_valid = 1;

 		VBDEBUG(("Found kernel entry at %" PRIu64 " size %" PRIu64 "\n",
 			 part_start, part_size));

 		/*
 		 * Set up tracking for this partition.  This wraps around if
 		 * called many times, so initialize the partition entry each
 		 * time.
 		 */
 		shpart = shcall->parts + (shcall->kernel_parts_found
 					  & (VBSD_MAX_KERNEL_PARTS - 1));
 		Memset(shpart, 0, sizeof(VbSharedDataKernelPart));
 		shpart->sector_start = part_start;
 		shpart->sector_count = part_size;
 		/*
 		 * TODO: GPT partitions start at 1, but cgptlib starts them at
 		 * 0.  Adjust here, until cgptlib is fixed.
 		 */
 		shpart->gpt_index = (uint8_t)(gpt.current_kernel + 1);
 		shcall->kernel_parts_found++;

 		/* Found at least one kernel partition. */
 		found_partitions++;

 		/* Set up the stream */
 		if (VbExStreamOpen(params->disk_handle,
 				   part_start, part_size, &stream)) {
 			VBDEBUG(("Partition error getting stream.\n"));
 			shpart->check_result = VBSD_LKP_CHECK_TOO_SMALL;
 			goto bad_kernel;
 		}

 		if (0 != VbExStreamRead(stream, KBUF_SIZE, kbuf)) {
 			VBDEBUG(("Unable to read start of partition.\n"));
 			shpart->check_result = VBSD_LKP_CHECK_READ_START;
 			goto bad_kernel;
 		}

 		/* Verify the key block. */
 		key_block = (VbKeyBlockHeader*)kbuf;
 		if (0 != KeyBlockVerify(key_block, KBUF_SIZE,
 					kernel_subkey, 0)) {
 			VBDEBUG(("Verifying key block signature failed.\n"));
 			shpart->check_result = VBSD_LKP_CHECK_KEY_BLOCK_SIG;
 			key_block_valid = 0;

 			/* If not in developer mode, this kernel is bad. */
 			if (kBootDev != boot_mode)
 				goto bad_kernel;

 			/*
 			 * In developer mode, we can explictly disallow
 			 * self-signed kernels
 			 */
 			if (require_official_os) {
 				VBDEBUG(("Self-signed kernels not enabled.\n"));
 				shpart->check_result =
 					VBSD_LKP_CHECK_SELF_SIGNED;
 				goto bad_kernel;
 			}

 			/*
 			 * Allow the kernel if the SHA-512 hash of the key
 			 * block is valid.
 			 */
 			if (0 != KeyBlockVerify(key_block, KBUF_SIZE,
 						kernel_subkey, 1)) {
 				VBDEBUG(("Verifying key block hash failed.\n"));
 				shpart->check_result =
 					VBSD_LKP_CHECK_KEY_BLOCK_HASH;
 				goto bad_kernel;
 			}
 		}

 		/* 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))) {
 			VBDEBUG(("Key block developer flag mismatch.\n"));
 			shpart->check_result = VBSD_LKP_CHECK_DEV_MISMATCH;
 			key_block_valid = 0;
 		}
 		if (!(key_block->key_block_flags &
 		      (rec_switch ? KEY_BLOCK_FLAG_RECOVERY_1 :
 		       KEY_BLOCK_FLAG_RECOVERY_0))) {
 			VBDEBUG(("Key block recovery flag mismatch.\n"));
 			shpart->check_result = VBSD_LKP_CHECK_REC_MISMATCH;
 			key_block_valid = 0;
 		}

 		/* Check for rollback of key version except in recovery mode. */
 		key_version = key_block->data_key.key_version;
 		if (kBootRecovery != boot_mode) {
 			if (key_version < (shared->kernel_version_tpm >> 16)) {
 				VBDEBUG(("Key version too old.\n"));
 				shpart->check_result =
 					VBSD_LKP_CHECK_KEY_ROLLBACK;
 				key_block_valid = 0;
 			}
 			if (key_version > 0xFFFF) {
 				/*
 				 * Key version is stored in 16 bits in the TPM,
 				 * so key versions greater than 0xFFFF can't be
 				 * stored properly.
 				 */
 				VBDEBUG(("Key version > 0xFFFF.\n"));
 				shpart->check_result =
 					VBSD_LKP_CHECK_KEY_ROLLBACK;
 				key_block_valid = 0;
 			}
 		}

 		/* If not in developer mode, key block required to be valid. */
 		if (kBootDev != boot_mode && !key_block_valid) {
 			VBDEBUG(("Key block is invalid.\n"));
 			goto bad_kernel;
 		}

 		/* Get key for preamble/data verification from the key block. */
 		data_key = PublicKeyToRSA(&key_block->data_key);
 		if (!data_key) {
 			VBDEBUG(("Data key bad.\n"));
 			shpart->check_result = VBSD_LKP_CHECK_DATA_KEY_PARSE;
 			goto bad_kernel;
 		}

 		/* Verify the preamble, which follows the key block */
 		preamble = (VbKernelPreambleHeader *)
 			(kbuf + key_block->key_block_size);
 		if ((0 != VerifyKernelPreamble(
 					preamble,
 					KBUF_SIZE - key_block->key_block_size,
 					data_key))) {
 			VBDEBUG(("Preamble verification failed.\n"));
 			shpart->check_result = VBSD_LKP_CHECK_VERIFY_PREAMBLE;
 			goto bad_kernel;
 		}

 		/*
 		 * If the key block is valid and we're not in recovery mode,
 		 * check for rollback of the kernel version.
 		 */
 		combined_version = (uint32_t)(
 				(key_version << 16) |
 				(preamble->kernel_version & 0xFFFF));
 		shpart->combined_version = combined_version;
 		if (key_block_valid && kBootRecovery != boot_mode) {
 			if (combined_version < shared->kernel_version_tpm) {
 				VBDEBUG(("Kernel version too low.\n"));
 				shpart->check_result =
 					VBSD_LKP_CHECK_KERNEL_ROLLBACK;
 				/*
 				 * If not in developer mode, kernel version
 				 * must be valid.
 				 */
 				if (kBootDev != boot_mode)
 					goto bad_kernel;
 			}
 		}

 		VBDEBUG(("Kernel preamble is good.\n"));
 		shpart->check_result = VBSD_LKP_CHECK_PREAMBLE_VALID;

 		/* Check for lowest version from a valid header. */
 		if (key_block_valid && lowest_version > combined_version)
 			lowest_version = combined_version;
 		else {
 			VBDEBUG(("Key block valid: %d\n", key_block_valid));
 			VBDEBUG(("Combined version: %u\n",
 				 (unsigned) combined_version));
 		}

 		/*
 		 * If we already have a good kernel, no need to read another
 		 * one; we only needed to look at the versions to check for
 		 * rollback.  So skip to the next kernel preamble.
 		 */
 		if (-1 != good_partition) {
 			VbExStreamClose(stream);
 			stream = NULL;
 			continue;
 		}

 		body_offset = key_block->key_block_size +
 			preamble->preamble_size;

 		/*
 		 * Make sure the kernel starts at or before what we already
 		 * read into kbuf.
 		 *
 		 * We could deal with a larger offset by reading and discarding
 		 * the data in between the vblock and the kernel data.
 		 */
 		if (body_offset > KBUF_SIZE) {
 			shpart->check_result = VBSD_LKP_CHECK_BODY_OFFSET;
 			VBDEBUG(("Kernel body offset is %d > 64KB.\n",
 				 (int)body_offset));
 			goto bad_kernel;
 		}

 		if (!params->kernel_buffer) {
 			/* Get kernel load address and size from the header. */
 			params->kernel_buffer =
 				(void *)((long)preamble->body_load_address);
 			params->kernel_buffer_size =
 				preamble->body_signature.data_size;
 		} else if (preamble->body_signature.data_size >
 			   params->kernel_buffer_size) {
 			VBDEBUG(("Kernel body doesn't fit in memory.\n"));
 			shpart->check_result = VBSD_LKP_CHECK_BODY_EXCEEDS_MEM;
 			goto bad_kernel;
 		}

 		/*
 		 * Body signature data size is 64 bit and toread is 32 bit so
 		 * this could technically cause us to read less data.  That's
 		 * fine, because a 4 GB kernel is implausible, and if we did
 		 * have one that big, we'd simply read too little data and fail
 		 * to verify it.
 		 */
 		body_toread = preamble->body_signature.data_size;
 		body_readptr = params->kernel_buffer;

 		/*
 		 * If we've already read part of the kernel, copy that to the
 		 * beginning of the kernel buffer.
 		 */
 		if (body_offset < KBUF_SIZE) {
 			uint32_t body_copied = KBUF_SIZE - body_offset;

 			/* If the kernel is tiny, don't over-copy */
 			if (body_copied > body_toread)
 				body_copied = body_toread;

 			Memcpy(body_readptr, kbuf + body_offset, body_copied);
 			body_toread -= body_copied;
 			body_readptr += body_copied;
 		}

 		/* Read the kernel data */
 		if (body_toread &&
 		    0 != VbExStreamRead(stream, body_toread, body_readptr)) {
 			VBDEBUG(("Unable to read kernel data.\n"));
 			shpart->check_result = VBSD_LKP_CHECK_READ_DATA;
 			goto bad_kernel;
 		}

 		/* Close the stream; we're done with it */
 		VbExStreamClose(stream);
 		stream = NULL;

 		/* Verify kernel data */
 		if (0 != VerifyData((const uint8_t *)params->kernel_buffer,
 				    params->kernel_buffer_size,
 				    &preamble->body_signature, data_key)) {
 			VBDEBUG(("Kernel data verification failed.\n"));
 			shpart->check_result = VBSD_LKP_CHECK_VERIFY_DATA;
 			goto bad_kernel;
 		}

 		/* Done with the kernel signing key, so can free it now */
 		RSAPublicKeyFree(data_key);
 		data_key = NULL;

 		/*
 		 * If we're still here, the kernel is valid.  Save the first
 		 * good partition we find; that's the one we'll boot.
 		 */
 		VBDEBUG(("Partition is good.\n"));
 		shpart->check_result = VBSD_LKP_CHECK_KERNEL_GOOD;
 		if (key_block_valid)
 			shpart->flags |= VBSD_LKP_FLAG_KEY_BLOCK_VALID;

 		good_partition_key_block_valid = key_block_valid;
 		/*
 		 * TODO: GPT partitions start at 1, but cgptlib starts them at
 		 * 0.  Adjust here, until cgptlib is fixed.
 		 */
 		good_partition = gpt.current_kernel + 1;
 		params->partition_number = gpt.current_kernel + 1;
 		GetCurrentKernelUniqueGuid(&gpt, &params->partition_guid);
 		/*
 		 * TODO: GetCurrentKernelUniqueGuid() should take a destination
 		 * size, or the dest should be a struct, so we know it's big
 		 * enough.
 		 */
 		params->bootloader_address = preamble->bootloader_address;
 		params->bootloader_size = preamble->bootloader_size;
 		if (VbKernelHasFlags(preamble) == VBOOT_SUCCESS)
 			params->flags = preamble->flags;

 		/* Update GPT to note this is the kernel we're trying */
 		GptUpdateKernelEntry(&gpt, GPT_UPDATE_ENTRY_TRY);

 		/*
 		 * If we're in recovery mode or we're about to boot a
 		 * dev-signed kernel, there's no rollback protection, so we can
 		 * stop at the first valid kernel.
 		 */
 		if (kBootRecovery == boot_mode || !key_block_valid) {
 			VBDEBUG(("In recovery mode or dev-signed kernel\n"));
 			break;
 		}

 		/*
 		 * Otherwise, we do care about the key index in the TPM.  If
 		 * the good partition's key version is the same as the tpm,
 		 * then the TPM doesn't need updating; we can stop now.
 		 * Otherwise, we'll check all the other headers to see if they
 		 * contain a newer key.
 		 */
 		if (combined_version == shared->kernel_version_tpm) {
 			VBDEBUG(("Same kernel version\n"));
 			break;
 		}

 		/* Continue, so that we skip the error handling code below */
 		continue;

 	bad_kernel:
 		/* Handle errors parsing this kernel */
 		if (NULL != stream)
 			VbExStreamClose(stream);
 		if (NULL != data_key)
 			RSAPublicKeyFree(data_key);

 		VBDEBUG(("Marking kernel as invalid.\n"));
 		GptUpdateKernelEntry(&gpt, GPT_UPDATE_ENTRY_BAD);


         } /* while(GptNextKernelEntry) */

  bad_gpt:

 	/* Free kernel buffer */
 	if (kbuf)
 		VbExFree(kbuf);

 	/* Write and free GPT data */
 	WriteAndFreeGptData(params->disk_handle, &gpt);

 	/* Handle finding a good partition */
 	if (good_partition >= 0) {
 		VBDEBUG(("Good_partition >= 0\n"));
 		shcall->check_result = VBSD_LKC_CHECK_GOOD_PARTITION;
 		shared->kernel_version_lowest = lowest_version;
 		/*
 		 * Sanity check - only store a new TPM version if we found one.
 		 * If lowest_version is still at its initial value, we didn't
 		 * find one; for example, we're in developer mode and just
 		 * didn't look.
 		 */
 		if (lowest_version != LOWEST_TPM_VERSION &&
 		    lowest_version > shared->kernel_version_tpm)
 			shared->kernel_version_tpm = lowest_version;

 		/* Success! */
 		retval = VBERROR_SUCCESS;
 	} else if (found_partitions > 0) {
 		shcall->check_result = VBSD_LKC_CHECK_INVALID_PARTITIONS;
 		recovery = VBNV_RECOVERY_RW_INVALID_OS;
 		retval = VBERROR_INVALID_KERNEL_FOUND;
 	} else {
 		shcall->check_result = VBSD_LKC_CHECK_NO_PARTITIONS;
 		recovery = VBNV_RECOVERY_RW_NO_OS;
 		retval = VBERROR_NO_KERNEL_FOUND;
 	}

  LoadKernelExit:

 	/* Store recovery request, if any */
 	VbNvSet(vnc, VBNV_RECOVERY_REQUEST, VBERROR_SUCCESS != retval ?
 		recovery : VBNV_RECOVERY_NOT_REQUESTED);

 	/*
 	 * If LoadKernel() was called with bad parameters, shcall may not be
 	 * initialized.
 	 */
 	if (shcall)
 		shcall->return_code = (uint8_t)retval;

 	/* Save whether the good partition's key block was fully verified */
 	if (good_partition_key_block_valid)
 		shared->flags |= VBSD_KERNEL_KEY_VERIFIED;

 	/* Store how much shared data we used, if any */
 	params->shared_data_size = shared->data_used;

 	if (free_kernel_subkey)
 		VbExFree(kernel_subkey);

 	return retval;
 }
	/* 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.
	*
	* Functions for loading a kernel from disk.
	* (Firmware portion)
	*/

	#include "sysincludes.h"

	#include "cgptlib.h"
	#include "cgptlib_internal.h"
	#include "region.h"
	#include "gbb_access.h"
	#include "gbb_header.h"
	#include "gpt_misc.h"
	#include "load_kernel_fw.h"
	#include "utility.h"
	#include "vboot_api.h"
	#include "vboot_common.h"
	#include "vboot_kernel.h"

	#define KBUF_SIZE 65536 /* Bytes to read at start of kernel partition */
	#define LOWEST_TPM_VERSION 0xffffffff

	typedef enum BootMode {
	kBootRecovery = 0, /* Recovery firmware, any dev switch position */
	kBootNormal = 1, /* Normal boot - kernel must be verified */
	kBootDev = 2 /* Developer boot - self-signed kernel ok */
	} BootMode;

	VbError_t LoadKernel(LoadKernelParams params, VbCommonParams cparams)
	{
	VbSharedDataHeader *shared =
	(VbSharedDataHeader *)params->shared_data_blob;
	VbSharedDataKernelCall *shcall = NULL;
	VbNvContext* vnc = params->nv_context;
	VbPublicKey* kernel_subkey = NULL;
	int free_kernel_subkey = 0;
	GptData gpt;
	uint64_t part_start, part_size;
	uint64_t blba;
	uint64_t kbuf_sectors;
	uint8_t* kbuf = NULL;
	int found_partitions = 0;
	int good_partition = -1;
	int good_partition_key_block_valid = 0;
	uint32_t lowest_version = LOWEST_TPM_VERSION;
	int rec_switch, dev_switch;
	BootMode boot_mode;
	uint32_t require_official_os = 0;
	uint32_t body_toread;
	uint8_t *body_readptr;

	VbError_t retval = VBERROR_UNKNOWN;
	int recovery = VBNV_RECOVERY_LK_UNSPECIFIED;

	/* Sanity Checks */
	if (!params->bytes_per_lba \|\|
	!params->streaming_lba_count) {
	VBDEBUG(("LoadKernel() called with invalid params\n"));
	retval = VBERROR_INVALID_PARAMETER;
	goto LoadKernelExit;
	}

	/* Clear output params in case we fail */
	params->partition_number = 0;
	params->bootloader_address = 0;
	params->bootloader_size = 0;
	params->flags = 0;

	/* Calculate switch positions and boot mode */
	rec_switch = (BOOT_FLAG_RECOVERY & params->boot_flags ? 1 : 0);
	dev_switch = (BOOT_FLAG_DEVELOPER & params->boot_flags ? 1 : 0);
	if (rec_switch) {
	boot_mode = kBootRecovery;
	} else if (dev_switch) {
	boot_mode = kBootDev;
	VbNvGet(vnc, VBNV_DEV_BOOT_SIGNED_ONLY, &require_official_os);
	} else {
	boot_mode = kBootNormal;
	}

	/*
	* Set up tracking for this call. This wraps around if called many
	* times, so we need to initialize the call entry each time.
	*/
	shcall = shared->lk_calls + (shared->lk_call_count
	& (VBSD_MAX_KERNEL_CALLS - 1));
	Memset(shcall, 0, sizeof(VbSharedDataKernelCall));
	shcall->boot_flags = (uint32_t)params->boot_flags;
	shcall->boot_mode = boot_mode;
	shcall->sector_size = (uint32_t)params->bytes_per_lba;
	shcall->sector_count = params->streaming_lba_count;
	shared->lk_call_count++;

	/* Initialization */
	blba = params->bytes_per_lba;
	kbuf_sectors = KBUF_SIZE / blba;
	if (0 == kbuf_sectors) {
	VBDEBUG(("LoadKernel() called with sector size > KBUF_SIZE\n"));
	retval = VBERROR_INVALID_PARAMETER;
	goto LoadKernelExit;
	}

	if (kBootRecovery == boot_mode) {
	/* Use the recovery key to verify the kernel */
	retval = VbGbbReadRecoveryKey(cparams, &kernel_subkey);
	if (VBERROR_SUCCESS != retval)
	goto LoadKernelExit;
	free_kernel_subkey = 1;
	} else {
	/* Use the kernel subkey passed from LoadFirmware(). */
	kernel_subkey = &shared->kernel_subkey;
	}

	/* Read GPT data */
	gpt.sector_bytes = (uint32_t)blba;
	gpt.streaming_drive_sectors = params->streaming_lba_count;
	gpt.gpt_drive_sectors = params->gpt_lba_count;
	gpt.flags = params->boot_flags & BOOT_FLAG_EXTERNAL_GPT
	? GPT_FLAG_EXTERNAL : 0;
	if (0 != AllocAndReadGptData(params->disk_handle, &gpt)) {
	VBDEBUG(("Unable to read GPT data\n"));
	shcall->check_result = VBSD_LKC_CHECK_GPT_READ_ERROR;
	goto bad_gpt;
	}

	/* Initialize GPT library */
	if (GPT_SUCCESS != GptInit(&gpt)) {
	VBDEBUG(("Error parsing GPT\n"));
	shcall->check_result = VBSD_LKC_CHECK_GPT_PARSE_ERROR;
	goto bad_gpt;
	}

	/* Allocate kernel header buffers */
	kbuf = (uint8_t*)VbExMalloc(KBUF_SIZE);
	if (!kbuf)
	goto bad_gpt;

	/* Loop over candidate kernel partitions */
	while (GPT_SUCCESS ==
	GptNextKernelEntry(&gpt, &part_start, &part_size)) {
	VbSharedDataKernelPart *shpart = NULL;
	VbKeyBlockHeader *key_block;
	VbKernelPreambleHeader *preamble;
	RSAPublicKey *data_key = NULL;
	VbExStream_t stream = NULL;
	uint64_t key_version;
	uint32_t combined_version;
	uint64_t body_offset;
	int key_block_valid = 1;

	VBDEBUG(("Found kernel entry at %" PRIu64 " size %" PRIu64 "\n",
	part_start, part_size));

	/*
	* Set up tracking for this partition. This wraps around if
	* called many times, so initialize the partition entry each
	* time.
	*/
	shpart = shcall->parts + (shcall->kernel_parts_found
	& (VBSD_MAX_KERNEL_PARTS - 1));
	Memset(shpart, 0, sizeof(VbSharedDataKernelPart));
	shpart->sector_start = part_start;
	shpart->sector_count = part_size;
	/*
	* TODO: GPT partitions start at 1, but cgptlib starts them at
	* 0. Adjust here, until cgptlib is fixed.
	*/
	shpart->gpt_index = (uint8_t)(gpt.current_kernel + 1);
	shcall->kernel_parts_found++;

	/* Found at least one kernel partition. */
	found_partitions++;

	/* Set up the stream */
	if (VbExStreamOpen(params->disk_handle,
	part_start, part_size, &stream)) {
	VBDEBUG(("Partition error getting stream.\n"));
	shpart->check_result = VBSD_LKP_CHECK_TOO_SMALL;
	goto bad_kernel;
	}

	if (0 != VbExStreamRead(stream, KBUF_SIZE, kbuf)) {
	VBDEBUG(("Unable to read start of partition.\n"));
	shpart->check_result = VBSD_LKP_CHECK_READ_START;
	goto bad_kernel;
	}

	/* Verify the key block. */
	key_block = (VbKeyBlockHeader*)kbuf;
	if (0 != KeyBlockVerify(key_block, KBUF_SIZE,
	kernel_subkey, 0)) {
	VBDEBUG(("Verifying key block signature failed.\n"));
	shpart->check_result = VBSD_LKP_CHECK_KEY_BLOCK_SIG;
	key_block_valid = 0;

	/* If not in developer mode, this kernel is bad. */
	if (kBootDev != boot_mode)
	goto bad_kernel;

	/*
	* In developer mode, we can explictly disallow
	* self-signed kernels
	*/
	if (require_official_os) {
	VBDEBUG(("Self-signed kernels not enabled.\n"));
	shpart->check_result =
	VBSD_LKP_CHECK_SELF_SIGNED;
	goto bad_kernel;
	}

	/*
	* Allow the kernel if the SHA-512 hash of the key
	* block is valid.
	*/
	if (0 != KeyBlockVerify(key_block, KBUF_SIZE,
	kernel_subkey, 1)) {
	VBDEBUG(("Verifying key block hash failed.\n"));
	shpart->check_result =
	VBSD_LKP_CHECK_KEY_BLOCK_HASH;
	goto bad_kernel;
	}
	}

	/* 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))) {
	VBDEBUG(("Key block developer flag mismatch.\n"));
	shpart->check_result = VBSD_LKP_CHECK_DEV_MISMATCH;
	key_block_valid = 0;
	}
	if (!(key_block->key_block_flags &
	(rec_switch ? KEY_BLOCK_FLAG_RECOVERY_1 :
	KEY_BLOCK_FLAG_RECOVERY_0))) {
	VBDEBUG(("Key block recovery flag mismatch.\n"));
	shpart->check_result = VBSD_LKP_CHECK_REC_MISMATCH;
	key_block_valid = 0;
	}

	/* Check for rollback of key version except in recovery mode. */
	key_version = key_block->data_key.key_version;
	if (kBootRecovery != boot_mode) {
	if (key_version < (shared->kernel_version_tpm >> 16)) {
	VBDEBUG(("Key version too old.\n"));
	shpart->check_result =
	VBSD_LKP_CHECK_KEY_ROLLBACK;
	key_block_valid = 0;
	}
	if (key_version > 0xFFFF) {
	/*
	* Key version is stored in 16 bits in the TPM,
	* so key versions greater than 0xFFFF can't be
	* stored properly.
	*/
	VBDEBUG(("Key version > 0xFFFF.\n"));
	shpart->check_result =
	VBSD_LKP_CHECK_KEY_ROLLBACK;
	key_block_valid = 0;
	}
	}

	/* If not in developer mode, key block required to be valid. */
	if (kBootDev != boot_mode && !key_block_valid) {
	VBDEBUG(("Key block is invalid.\n"));
	goto bad_kernel;
	}

	/* Get key for preamble/data verification from the key block. */
	data_key = PublicKeyToRSA(&key_block->data_key);
	if (!data_key) {
	VBDEBUG(("Data key bad.\n"));
	shpart->check_result = VBSD_LKP_CHECK_DATA_KEY_PARSE;
	goto bad_kernel;
	}

	/* Verify the preamble, which follows the key block */
	preamble = (VbKernelPreambleHeader *)
	(kbuf + key_block->key_block_size);
	if ((0 != VerifyKernelPreamble(
	preamble,
	KBUF_SIZE - key_block->key_block_size,
	data_key))) {
	VBDEBUG(("Preamble verification failed.\n"));
	shpart->check_result = VBSD_LKP_CHECK_VERIFY_PREAMBLE;
	goto bad_kernel;
	}

	/*
	* If the key block is valid and we're not in recovery mode,
	* check for rollback of the kernel version.
	*/
	combined_version = (uint32_t)(
	(key_version << 16) \|
	(preamble->kernel_version & 0xFFFF));
	shpart->combined_version = combined_version;
	if (key_block_valid && kBootRecovery != boot_mode) {
	if (combined_version < shared->kernel_version_tpm) {
	VBDEBUG(("Kernel version too low.\n"));
	shpart->check_result =
	VBSD_LKP_CHECK_KERNEL_ROLLBACK;
	/*
	* If not in developer mode, kernel version
	* must be valid.
	*/
	if (kBootDev != boot_mode)
	goto bad_kernel;
	}
	}

	VBDEBUG(("Kernel preamble is good.\n"));
	shpart->check_result = VBSD_LKP_CHECK_PREAMBLE_VALID;

	/* Check for lowest version from a valid header. */
	if (key_block_valid && lowest_version > combined_version)
	lowest_version = combined_version;
	else {
	VBDEBUG(("Key block valid: %d\n", key_block_valid));
	VBDEBUG(("Combined version: %u\n",
	(unsigned) combined_version));
	}

	/*
	* If we already have a good kernel, no need to read another
	* one; we only needed to look at the versions to check for
	* rollback. So skip to the next kernel preamble.
	*/
	if (-1 != good_partition) {
	VbExStreamClose(stream);
	stream = NULL;
	continue;
	}

	body_offset = key_block->key_block_size +
	preamble->preamble_size;

	/*
	* Make sure the kernel starts at or before what we already
	* read into kbuf.
	*
	* We could deal with a larger offset by reading and discarding
	* the data in between the vblock and the kernel data.
	*/
	if (body_offset > KBUF_SIZE) {
	shpart->check_result = VBSD_LKP_CHECK_BODY_OFFSET;
	VBDEBUG(("Kernel body offset is %d > 64KB.\n",
	(int)body_offset));
	goto bad_kernel;
	}

	if (!params->kernel_buffer) {
	/* Get kernel load address and size from the header. */
	params->kernel_buffer =
	(void *)((long)preamble->body_load_address);
	params->kernel_buffer_size =
	preamble->body_signature.data_size;
	} else if (preamble->body_signature.data_size >
	params->kernel_buffer_size) {
	VBDEBUG(("Kernel body doesn't fit in memory.\n"));
	shpart->check_result = VBSD_LKP_CHECK_BODY_EXCEEDS_MEM;
	goto bad_kernel;
	}

	/*
	* Body signature data size is 64 bit and toread is 32 bit so
	* this could technically cause us to read less data. That's
	* fine, because a 4 GB kernel is implausible, and if we did
	* have one that big, we'd simply read too little data and fail
	* to verify it.
	*/
	body_toread = preamble->body_signature.data_size;
	body_readptr = params->kernel_buffer;

	/*
	* If we've already read part of the kernel, copy that to the
	* beginning of the kernel buffer.
	*/
	if (body_offset < KBUF_SIZE) {
	uint32_t body_copied = KBUF_SIZE - body_offset;

	/* If the kernel is tiny, don't over-copy */
	if (body_copied > body_toread)
	body_copied = body_toread;

	Memcpy(body_readptr, kbuf + body_offset, body_copied);
	body_toread -= body_copied;
	body_readptr += body_copied;
	}

	/* Read the kernel data */
	if (body_toread &&
	0 != VbExStreamRead(stream, body_toread, body_readptr)) {
	VBDEBUG(("Unable to read kernel data.\n"));
	shpart->check_result = VBSD_LKP_CHECK_READ_DATA;
	goto bad_kernel;
	}

	/* Close the stream; we're done with it */
	VbExStreamClose(stream);
	stream = NULL;

	/* Verify kernel data */
	if (0 != VerifyData((const uint8_t *)params->kernel_buffer,
	params->kernel_buffer_size,
	&preamble->body_signature, data_key)) {
	VBDEBUG(("Kernel data verification failed.\n"));
	shpart->check_result = VBSD_LKP_CHECK_VERIFY_DATA;
	goto bad_kernel;
	}

	/* Done with the kernel signing key, so can free it now */
	RSAPublicKeyFree(data_key);
	data_key = NULL;

	/*
	* If we're still here, the kernel is valid. Save the first
	* good partition we find; that's the one we'll boot.
	*/
	VBDEBUG(("Partition is good.\n"));
	shpart->check_result = VBSD_LKP_CHECK_KERNEL_GOOD;
	if (key_block_valid)
	shpart->flags \|= VBSD_LKP_FLAG_KEY_BLOCK_VALID;

	good_partition_key_block_valid = key_block_valid;
	/*
	* TODO: GPT partitions start at 1, but cgptlib starts them at
	* 0. Adjust here, until cgptlib is fixed.
	*/
	good_partition = gpt.current_kernel + 1;
	params->partition_number = gpt.current_kernel + 1;
	GetCurrentKernelUniqueGuid(&gpt, &params->partition_guid);
	/*
	* TODO: GetCurrentKernelUniqueGuid() should take a destination
	* size, or the dest should be a struct, so we know it's big
	* enough.
	*/
	params->bootloader_address = preamble->bootloader_address;
	params->bootloader_size = preamble->bootloader_size;
	if (VbKernelHasFlags(preamble) == VBOOT_SUCCESS)
	params->flags = preamble->flags;

	/* Update GPT to note this is the kernel we're trying */
	GptUpdateKernelEntry(&gpt, GPT_UPDATE_ENTRY_TRY);

	/*
	* If we're in recovery mode or we're about to boot a
	* dev-signed kernel, there's no rollback protection, so we can
	* stop at the first valid kernel.
	*/
	if (kBootRecovery == boot_mode \|\| !key_block_valid) {
	VBDEBUG(("In recovery mode or dev-signed kernel\n"));
	break;
	}

	/*
	* Otherwise, we do care about the key index in the TPM. If
	* the good partition's key version is the same as the tpm,
	* then the TPM doesn't need updating; we can stop now.
	* Otherwise, we'll check all the other headers to see if they
	* contain a newer key.
	*/
	if (combined_version == shared->kernel_version_tpm) {
	VBDEBUG(("Same kernel version\n"));
	break;
	}

	/* Continue, so that we skip the error handling code below */
	continue;

	bad_kernel:
	/* Handle errors parsing this kernel */
	if (NULL != stream)
	VbExStreamClose(stream);
	if (NULL != data_key)
	RSAPublicKeyFree(data_key);

	VBDEBUG(("Marking kernel as invalid.\n"));
	GptUpdateKernelEntry(&gpt, GPT_UPDATE_ENTRY_BAD);


	} /* while(GptNextKernelEntry) */

	bad_gpt:

	/* Free kernel buffer */
	if (kbuf)
	VbExFree(kbuf);

	/* Write and free GPT data */
	WriteAndFreeGptData(params->disk_handle, &gpt);

	/* Handle finding a good partition */
	if (good_partition >= 0) {
	VBDEBUG(("Good_partition >= 0\n"));
	shcall->check_result = VBSD_LKC_CHECK_GOOD_PARTITION;
	shared->kernel_version_lowest = lowest_version;
	/*
	* Sanity check - only store a new TPM version if we found one.
	* If lowest_version is still at its initial value, we didn't
	* find one; for example, we're in developer mode and just
	* didn't look.
	*/
	if (lowest_version != LOWEST_TPM_VERSION &&
	lowest_version > shared->kernel_version_tpm)
	shared->kernel_version_tpm = lowest_version;

	/* Success! */
	retval = VBERROR_SUCCESS;
	} else if (found_partitions > 0) {
	shcall->check_result = VBSD_LKC_CHECK_INVALID_PARTITIONS;
	recovery = VBNV_RECOVERY_RW_INVALID_OS;
	retval = VBERROR_INVALID_KERNEL_FOUND;
	} else {
	shcall->check_result = VBSD_LKC_CHECK_NO_PARTITIONS;
	recovery = VBNV_RECOVERY_RW_NO_OS;
	retval = VBERROR_NO_KERNEL_FOUND;
	}

	LoadKernelExit:

	/* Store recovery request, if any */
	VbNvSet(vnc, VBNV_RECOVERY_REQUEST, VBERROR_SUCCESS != retval ?
	recovery : VBNV_RECOVERY_NOT_REQUESTED);

	/*
	* If LoadKernel() was called with bad parameters, shcall may not be
	* initialized.
	*/
	if (shcall)
	shcall->return_code = (uint8_t)retval;

	/* Save whether the good partition's key block was fully verified */
	if (good_partition_key_block_valid)
	shared->flags \|= VBSD_KERNEL_KEY_VERIFIED;

	/* Store how much shared data we used, if any */
	params->shared_data_size = shared->data_used;

	if (free_kernel_subkey)
	VbExFree(kernel_subkey);

	return retval;
	}