src/security/vboot/secdata_tpm.c - mirrors/cros/chromiumos/third_party/coreboot - Git at Google

 /* SPDX-License-Identifier: BSD-3-Clause */

 /*
  * Functions for querying, manipulating and locking rollback indices
  * stored in the TPM NVRAM.
  */

 #include <security/vboot/antirollback.h>
 #include <security/vboot/tpm_common.h>
 #include <security/tpm/tspi.h>
 #include <security/tpm/tss.h>
 #include <security/tpm/tss/tcg-1.2/tss_structures.h>
 #include <vb2_api.h>
 #include <console/console.h>

 #ifdef FOR_TEST
 #include <stdio.h>
 #define VBDEBUG(format, args...) printf(format, ## args)
 #else
 #define VBDEBUG(format, args...) \
 	printk(BIOS_INFO, "%s():%d: " format,  __func__, __LINE__, ## args)
 #endif

 #define RETURN_ON_FAILURE(tpm_cmd) do {				\
 		uint32_t result_;					\
 		if ((result_ = (tpm_cmd)) != TPM_SUCCESS) {		\
 			VBDEBUG("Antirollback: %08x returned by " #tpm_cmd \
 				 "\n", (int)result_);			\
 			return result_;					\
 		}							\
 	} while (0)

 static uint32_t safe_write(uint32_t index, const void *data, uint32_t length);

 static uint32_t read_space_firmware(struct vb2_context *ctx)
 {
 	RETURN_ON_FAILURE(tlcl_read(FIRMWARE_NV_INDEX,
 				    ctx->secdata_firmware,
 				    VB2_SECDATA_FIRMWARE_SIZE));
 	return TPM_SUCCESS;
 }

 uint32_t antirollback_read_space_kernel(struct vb2_context *ctx)
 {
 	if (!CONFIG(TPM2)) {
 		/*
 		 * Before reading the kernel space, verify its permissions. If
 		 * the kernel space has the wrong permission, we give up. This
 		 * will need to be fixed by the recovery kernel. We will have
 		 * to worry about this because at any time (even with PP turned
 		 * off) the TPM owner can remove and redefine a PP-protected
 		 * space (but not write to it).
 		 */
 		uint32_t perms;

 		RETURN_ON_FAILURE(tlcl_get_permissions(KERNEL_NV_INDEX,
 						       &perms));
 		if (perms != TPM_NV_PER_PPWRITE) {
 			printk(BIOS_ERR,
 			       "TPM: invalid secdata_kernel permissions\n");
 			return TPM_E_CORRUPTED_STATE;
 		}
 	}

 	uint8_t size = VB2_SECDATA_KERNEL_MIN_SIZE;

 	RETURN_ON_FAILURE(tlcl_read(KERNEL_NV_INDEX, ctx->secdata_kernel,
 				    size));

 	if (vb2api_secdata_kernel_check(ctx, &size)
 	    == VB2_ERROR_SECDATA_KERNEL_INCOMPLETE)
 		/* Re-read. vboot will run the check and handle errors. */
 		RETURN_ON_FAILURE(tlcl_read(KERNEL_NV_INDEX,
 					    ctx->secdata_kernel, size));

 	return TPM_SUCCESS;
 }

 static uint32_t read_space_rec_hash(uint8_t *data)
 {
 	RETURN_ON_FAILURE(tlcl_read(REC_HASH_NV_INDEX, data,
 				    REC_HASH_NV_SIZE));
 	return TPM_SUCCESS;
 }

 /*
  * This is used to initialize the TPM space for recovery hash after defining
  * it. Since there is no data available to calculate hash at the point where TPM
  * space is defined, initialize it to all 0s.
  */
 static const uint8_t rec_hash_data[REC_HASH_NV_SIZE] = { };

 #if CONFIG(TPM2)
 /*
  * Different sets of NVRAM space attributes apply to the "ro" spaces,
  * i.e. those which should not be possible to delete or modify once
  * the RO exits, and the rest of the NVRAM spaces.
  */
 static const TPMA_NV ro_space_attributes = {
 	.TPMA_NV_PPWRITE = 1,
 	.TPMA_NV_AUTHREAD = 1,
 	.TPMA_NV_PPREAD = 1,
 	.TPMA_NV_PLATFORMCREATE = 1,
 	.TPMA_NV_WRITE_STCLEAR = 1,
 	.TPMA_NV_POLICY_DELETE = 1,
 };

 static const TPMA_NV rw_space_attributes = {
 	.TPMA_NV_PPWRITE = 1,
 	.TPMA_NV_AUTHREAD = 1,
 	.TPMA_NV_PPREAD = 1,
 	.TPMA_NV_PLATFORMCREATE = 1,
 };

 /*
  * This policy digest was obtained using TPM2_PolicyPCR
  * selecting only PCR_0 with a value of all zeros.
  */
 static const uint8_t pcr0_unchanged_policy[] = {
 	0x09, 0x93, 0x3C, 0xCE, 0xEB, 0xB4, 0x41, 0x11, 0x18, 0x81, 0x1D,
 	0xD4, 0x47, 0x78, 0x80, 0x08, 0x88, 0x86, 0x62, 0x2D, 0xD7, 0x79,
 	0x94, 0x46, 0x62, 0x26, 0x68, 0x8E, 0xEE, 0xE6, 0x6A, 0xA1};

 /* Nothing special in the TPM2 path yet. */
 static uint32_t safe_write(uint32_t index, const void *data, uint32_t length)
 {
 	return tlcl_write(index, data, length);
 }

 static uint32_t set_space(const char *name, uint32_t index, const void *data,
 			  uint32_t length, const TPMA_NV nv_attributes,
 			  const uint8_t *nv_policy, size_t nv_policy_size)
 {
 	uint32_t rv;

 	rv = tlcl_define_space(index, length, nv_attributes, nv_policy,
 			       nv_policy_size);
 	if (rv == TPM_E_NV_DEFINED) {
 		/*
 		 * Continue with writing: it may be defined, but not written
 		 * to. In that case a subsequent tlcl_read() would still return
 		 * TPM_E_BADINDEX on TPM 2.0. The cases when some non-firmware
 		 * space is defined while the firmware space is not there
 		 * should be rare (interrupted initialization), so no big harm
 		 * in writing once again even if it was written already.
 		 */
 		VBDEBUG("%s: %s space already exists\n", __func__, name);
 		rv = TPM_SUCCESS;
 	}

 	if (rv != TPM_SUCCESS)
 		return rv;

 	return safe_write(index, data, length);
 }

 static uint32_t set_firmware_space(const void *firmware_blob)
 {
 	return set_space("firmware", FIRMWARE_NV_INDEX, firmware_blob,
 			 VB2_SECDATA_FIRMWARE_SIZE, ro_space_attributes,
 			 pcr0_unchanged_policy, sizeof(pcr0_unchanged_policy));
 }

 static uint32_t set_kernel_space(const void *kernel_blob)
 {
 	return set_space("kernel", KERNEL_NV_INDEX, kernel_blob,
 			 VB2_SECDATA_KERNEL_SIZE, rw_space_attributes, NULL, 0);
 }

 static uint32_t set_rec_hash_space(const uint8_t *data)
 {
 	return set_space("MRC Hash", REC_HASH_NV_INDEX, data,
 			 REC_HASH_NV_SIZE,
 			 ro_space_attributes, pcr0_unchanged_policy,
 			 sizeof(pcr0_unchanged_policy));
 }

 static uint32_t _factory_initialize_tpm(struct vb2_context *ctx)
 {
 	vb2api_secdata_kernel_create(ctx);

 	RETURN_ON_FAILURE(tlcl_force_clear());

 	/*
 	 * Of all NVRAM spaces defined by this function the firmware space
 	 * must be defined last, because its existence is considered an
 	 * indication that TPM factory initialization was successfully
 	 * completed.
 	 */
 	RETURN_ON_FAILURE(set_kernel_space(ctx->secdata_kernel));

 	if (CONFIG(VBOOT_HAS_REC_HASH_SPACE))
 		RETURN_ON_FAILURE(set_rec_hash_space(rec_hash_data));

 	RETURN_ON_FAILURE(set_firmware_space(ctx->secdata_firmware));

 	return TPM_SUCCESS;
 }

 uint32_t antirollback_lock_space_firmware(void)
 {
 	return tlcl_lock_nv_write(FIRMWARE_NV_INDEX);
 }

 uint32_t antirollback_lock_space_rec_hash(void)
 {
 	return tlcl_lock_nv_write(REC_HASH_NV_INDEX);
 }

 #else

 /**
  * Like tlcl_write(), but checks for write errors due to hitting the 64-write
  * limit and clears the TPM when that happens.  This can only happen when the
  * TPM is unowned, so it is OK to clear it (and we really have no choice).
  * This is not expected to happen frequently, but it could happen.
  */

 static uint32_t safe_write(uint32_t index, const void *data, uint32_t length)
 {
 	uint32_t result = tlcl_write(index, data, length);
 	if (result == TPM_E_MAXNVWRITES) {
 		RETURN_ON_FAILURE(tpm_clear_and_reenable());
 		return tlcl_write(index, data, length);
 	} else {
 		return result;
 	}
 }

 /**
  * Similarly to safe_write(), this ensures we don't fail a DefineSpace because
  * we hit the TPM write limit. This is even less likely to happen than with
  * writes because we only define spaces once at initialization, but we'd
  * rather be paranoid about this.
  */
 static uint32_t safe_define_space(uint32_t index, uint32_t perm, uint32_t size)
 {
 	uint32_t result = tlcl_define_space(index, perm, size);
 	if (result == TPM_E_MAXNVWRITES) {
 		RETURN_ON_FAILURE(tpm_clear_and_reenable());
 		return tlcl_define_space(index, perm, size);
 	} else {
 		return result;
 	}
 }

 static uint32_t set_rec_hash_space(const uint8_t *data)
 {
 	RETURN_ON_FAILURE(safe_define_space(REC_HASH_NV_INDEX,
 					    TPM_NV_PER_GLOBALLOCK |
 					    TPM_NV_PER_PPWRITE,
 					    REC_HASH_NV_SIZE));
 	RETURN_ON_FAILURE(safe_write(REC_HASH_NV_INDEX, data,
 				     REC_HASH_NV_SIZE));

 	return TPM_SUCCESS;
 }

 static uint32_t _factory_initialize_tpm(struct vb2_context *ctx)
 {
 	TPM_PERMANENT_FLAGS pflags;
 	uint32_t result;

 	vb2api_secdata_kernel_create_v0(ctx);

 	result = tlcl_get_permanent_flags(&pflags);
 	if (result != TPM_SUCCESS)
 		return result;

 	/*
 	 * TPM may come from the factory without physical presence finalized.
 	 * Fix if necessary.
 	 */
 	VBDEBUG("TPM: physicalPresenceLifetimeLock=%d\n",
 		 pflags.physicalPresenceLifetimeLock);
 	if (!pflags.physicalPresenceLifetimeLock) {
 		VBDEBUG("TPM: Finalizing physical presence\n");
 		RETURN_ON_FAILURE(tlcl_finalize_physical_presence());
 	}

 	/*
 	 * The TPM will not enforce the NV authorization restrictions until the
 	 * execution of a TPM_NV_DefineSpace with the handle of
 	 * TPM_NV_INDEX_LOCK.  Here we create that space if it doesn't already
 	 * exist. */
 	VBDEBUG("TPM: nvLocked=%d\n", pflags.nvLocked);
 	if (!pflags.nvLocked) {
 		VBDEBUG("TPM: Enabling NV locking\n");
 		RETURN_ON_FAILURE(tlcl_set_nv_locked());
 	}

 	/* Clear TPM owner, in case the TPM is already owned for some reason. */
 	VBDEBUG("TPM: Clearing owner\n");
 	RETURN_ON_FAILURE(tpm_clear_and_reenable());

 	/* Define and write secdata_kernel space. */
 	RETURN_ON_FAILURE(safe_define_space(KERNEL_NV_INDEX,
 					    TPM_NV_PER_PPWRITE,
 					    VB2_SECDATA_KERNEL_SIZE_V02));
 	RETURN_ON_FAILURE(safe_write(KERNEL_NV_INDEX,
 				     ctx->secdata_kernel,
 				     VB2_SECDATA_KERNEL_SIZE_V02));

 	/* Define and write secdata_firmware space. */
 	RETURN_ON_FAILURE(safe_define_space(FIRMWARE_NV_INDEX,
 					    TPM_NV_PER_GLOBALLOCK |
 					    TPM_NV_PER_PPWRITE,
 					    VB2_SECDATA_FIRMWARE_SIZE));
 	RETURN_ON_FAILURE(safe_write(FIRMWARE_NV_INDEX,
 				     ctx->secdata_firmware,
 					VB2_SECDATA_FIRMWARE_SIZE));

 	/* Define and set rec hash space, if available. */
 	if (CONFIG(VBOOT_HAS_REC_HASH_SPACE))
 		RETURN_ON_FAILURE(set_rec_hash_space(rec_hash_data));

 	return TPM_SUCCESS;
 }

 uint32_t antirollback_lock_space_firmware(void)
 {
 	return tlcl_set_global_lock();
 }

 uint32_t antirollback_lock_space_rec_hash(void)
 {
 	/*
 	 * Nothing needs to be done here, since global lock is already set while
 	 * locking firmware space.
 	 */
 	return TPM_SUCCESS;
 }
 #endif

 /**
  * Perform one-time initializations.
  *
  * Create the NVRAM spaces, and set their initial values as needed.  Sets the
  * nvLocked bit and ensures the physical presence command is enabled and
  * locked.
  */
 static uint32_t factory_initialize_tpm(struct vb2_context *ctx)
 {
 	uint32_t result;

 	/*
 	 * Set initial values of secdata_firmware space.
 	 * kernel space is created in _factory_initialize_tpm().
 	 */
 	vb2api_secdata_firmware_create(ctx);

 	VBDEBUG("TPM: factory initialization\n");

 	/*
 	 * Do a full test.  This only happens the first time the device is
 	 * turned on in the factory, so performance is not an issue.  This is
 	 * almost certainly not necessary, but it gives us more confidence
 	 * about some code paths below that are difficult to
 	 * test---specifically the ones that set lifetime flags, and are only
 	 * executed once per physical TPM.
 	 */
 	result = tlcl_self_test_full();
 	if (result != TPM_SUCCESS)
 		return result;

 	result = _factory_initialize_tpm(ctx);
 	if (result != TPM_SUCCESS)
 		return result;

 	/* _factory_initialize_tpm() writes initial secdata values to TPM
 	   immediately, so let vboot know that it's up to date now. */
 	ctx->flags &= ~(VB2_CONTEXT_SECDATA_FIRMWARE_CHANGED |
 			VB2_CONTEXT_SECDATA_KERNEL_CHANGED);

 	VBDEBUG("TPM: factory initialization successful\n");

 	return TPM_SUCCESS;
 }

 uint32_t antirollback_read_space_firmware(struct vb2_context *ctx)
 {
 	uint32_t rv;

 	/* Read the firmware space. */
 	rv = read_space_firmware(ctx);
 	if (rv == TPM_E_BADINDEX) {
 		/* This seems the first time we've run. Initialize the TPM. */
 		VBDEBUG("TPM: Not initialized yet.\n");
 		RETURN_ON_FAILURE(factory_initialize_tpm(ctx));
 	} else if (rv != TPM_SUCCESS) {
 		VBDEBUG("TPM: Firmware space in a bad state; giving up.\n");
 		return TPM_E_CORRUPTED_STATE;
 	}

 	return TPM_SUCCESS;
 }

 uint32_t antirollback_write_space_firmware(struct vb2_context *ctx)
 {
 	if (CONFIG(CR50_IMMEDIATELY_COMMIT_FW_SECDATA))
 		tlcl_cr50_enable_nvcommits();
 	return safe_write(FIRMWARE_NV_INDEX, ctx->secdata_firmware,
 			  VB2_SECDATA_FIRMWARE_SIZE);
 }

 uint32_t antirollback_write_space_kernel(struct vb2_context *ctx)
 {
 	/* Learn the expected size. */
 	uint8_t size = VB2_SECDATA_KERNEL_MIN_SIZE;
 	vb2api_secdata_kernel_check(ctx, &size);

 	return safe_write(KERNEL_NV_INDEX, ctx->secdata_kernel, size);
 }

 uint32_t antirollback_read_space_rec_hash(uint8_t *data, uint32_t size)
 {
 	if (size != REC_HASH_NV_SIZE) {
 		VBDEBUG("TPM: Incorrect buffer size for rec hash. "
 			"(Expected=0x%x Actual=0x%x).\n", REC_HASH_NV_SIZE,
 			size);
 		return TPM_E_READ_FAILURE;
 	}
 	return read_space_rec_hash(data);
 }

 uint32_t antirollback_write_space_rec_hash(const uint8_t *data, uint32_t size)
 {
 	uint8_t spc_data[REC_HASH_NV_SIZE];
 	uint32_t rv;

 	if (size != REC_HASH_NV_SIZE) {
 		VBDEBUG("TPM: Incorrect buffer size for rec hash. "
 			"(Expected=0x%x Actual=0x%x).\n", REC_HASH_NV_SIZE,
 			size);
 		return TPM_E_WRITE_FAILURE;
 	}

 	rv = read_space_rec_hash(spc_data);
 	if (rv == TPM_E_BADINDEX) {
 		/*
 		 * If space is not defined already for recovery hash, define
 		 * new space.
 		 */
 		VBDEBUG("TPM: Initializing recovery hash space.\n");
 		return set_rec_hash_space(data);
 	}

 	if (rv != TPM_SUCCESS)
 		return rv;

 	return safe_write(REC_HASH_NV_INDEX, data, size);
 }

 vb2_error_t vb2ex_tpm_clear_owner(struct vb2_context *ctx)
 {
 	uint32_t rv;
 	printk(BIOS_INFO, "Clearing TPM owner\n");
 	rv = tpm_clear_and_reenable();
 	if (rv)
 		return VB2_ERROR_EX_TPM_CLEAR_OWNER;
 	return VB2_SUCCESS;
 }
	/* SPDX-License-Identifier: BSD-3-Clause */

	/*
	* Functions for querying, manipulating and locking rollback indices
	* stored in the TPM NVRAM.
	*/

	#include <security/vboot/antirollback.h>
	#include <security/vboot/tpm_common.h>
	#include <security/tpm/tspi.h>
	#include <security/tpm/tss.h>
	#include <security/tpm/tss/tcg-1.2/tss_structures.h>
	#include <vb2_api.h>
	#include <console/console.h>

	#ifdef FOR_TEST
	#include <stdio.h>
	#define VBDEBUG(format, args...) printf(format, ## args)
	#else
	#define VBDEBUG(format, args...) \
	printk(BIOS_INFO, "%s():%d: " format, __func__, __LINE__, ## args)
	#endif

	#define RETURN_ON_FAILURE(tpm_cmd) do { \
	uint32_t result_; \
	if ((result_ = (tpm_cmd)) != TPM_SUCCESS) { \
	VBDEBUG("Antirollback: %08x returned by " #tpm_cmd \
	"\n", (int)result_); \
	return result_; \
	} \
	} while (0)

	static uint32_t safe_write(uint32_t index, const void *data, uint32_t length);

	static uint32_t read_space_firmware(struct vb2_context *ctx)
	{
	RETURN_ON_FAILURE(tlcl_read(FIRMWARE_NV_INDEX,
	ctx->secdata_firmware,
	VB2_SECDATA_FIRMWARE_SIZE));
	return TPM_SUCCESS;
	}

	uint32_t antirollback_read_space_kernel(struct vb2_context *ctx)
	{
	if (!CONFIG(TPM2)) {
	/*
	* Before reading the kernel space, verify its permissions. If
	* the kernel space has the wrong permission, we give up. This
	* will need to be fixed by the recovery kernel. We will have
	* to worry about this because at any time (even with PP turned
	* off) the TPM owner can remove and redefine a PP-protected
	* space (but not write to it).
	*/
	uint32_t perms;

	RETURN_ON_FAILURE(tlcl_get_permissions(KERNEL_NV_INDEX,
	&perms));
	if (perms != TPM_NV_PER_PPWRITE) {
	printk(BIOS_ERR,
	"TPM: invalid secdata_kernel permissions\n");
	return TPM_E_CORRUPTED_STATE;
	}
	}

	uint8_t size = VB2_SECDATA_KERNEL_MIN_SIZE;

	RETURN_ON_FAILURE(tlcl_read(KERNEL_NV_INDEX, ctx->secdata_kernel,
	size));

	if (vb2api_secdata_kernel_check(ctx, &size)
	== VB2_ERROR_SECDATA_KERNEL_INCOMPLETE)
	/* Re-read. vboot will run the check and handle errors. */
	RETURN_ON_FAILURE(tlcl_read(KERNEL_NV_INDEX,
	ctx->secdata_kernel, size));

	return TPM_SUCCESS;
	}

	static uint32_t read_space_rec_hash(uint8_t *data)
	{
	RETURN_ON_FAILURE(tlcl_read(REC_HASH_NV_INDEX, data,
	REC_HASH_NV_SIZE));
	return TPM_SUCCESS;
	}

	/*
	* This is used to initialize the TPM space for recovery hash after defining
	* it. Since there is no data available to calculate hash at the point where TPM
	* space is defined, initialize it to all 0s.
	*/
	static const uint8_t rec_hash_data[REC_HASH_NV_SIZE] = { };

	#if CONFIG(TPM2)
	/*
	* Different sets of NVRAM space attributes apply to the "ro" spaces,
	* i.e. those which should not be possible to delete or modify once
	* the RO exits, and the rest of the NVRAM spaces.
	*/
	static const TPMA_NV ro_space_attributes = {
	.TPMA_NV_PPWRITE = 1,
	.TPMA_NV_AUTHREAD = 1,
	.TPMA_NV_PPREAD = 1,
	.TPMA_NV_PLATFORMCREATE = 1,
	.TPMA_NV_WRITE_STCLEAR = 1,
	.TPMA_NV_POLICY_DELETE = 1,
	};

	static const TPMA_NV rw_space_attributes = {
	.TPMA_NV_PPWRITE = 1,
	.TPMA_NV_AUTHREAD = 1,
	.TPMA_NV_PPREAD = 1,
	.TPMA_NV_PLATFORMCREATE = 1,
	};

	/*
	* This policy digest was obtained using TPM2_PolicyPCR
	* selecting only PCR_0 with a value of all zeros.
	*/
	static const uint8_t pcr0_unchanged_policy[] = {
	0x09, 0x93, 0x3C, 0xCE, 0xEB, 0xB4, 0x41, 0x11, 0x18, 0x81, 0x1D,
	0xD4, 0x47, 0x78, 0x80, 0x08, 0x88, 0x86, 0x62, 0x2D, 0xD7, 0x79,
	0x94, 0x46, 0x62, 0x26, 0x68, 0x8E, 0xEE, 0xE6, 0x6A, 0xA1};

	/* Nothing special in the TPM2 path yet. */
	static uint32_t safe_write(uint32_t index, const void *data, uint32_t length)
	{
	return tlcl_write(index, data, length);
	}

	static uint32_t set_space(const char name, uint32_t index, const void data,
	uint32_t length, const TPMA_NV nv_attributes,
	const uint8_t *nv_policy, size_t nv_policy_size)
	{
	uint32_t rv;

	rv = tlcl_define_space(index, length, nv_attributes, nv_policy,
	nv_policy_size);
	if (rv == TPM_E_NV_DEFINED) {
	/*
	* Continue with writing: it may be defined, but not written
	* to. In that case a subsequent tlcl_read() would still return
	* TPM_E_BADINDEX on TPM 2.0. The cases when some non-firmware
	* space is defined while the firmware space is not there
	* should be rare (interrupted initialization), so no big harm
	* in writing once again even if it was written already.
	*/
	VBDEBUG("%s: %s space already exists\n", __func__, name);
	rv = TPM_SUCCESS;
	}

	if (rv != TPM_SUCCESS)
	return rv;

	return safe_write(index, data, length);
	}

	static uint32_t set_firmware_space(const void *firmware_blob)
	{
	return set_space("firmware", FIRMWARE_NV_INDEX, firmware_blob,
	VB2_SECDATA_FIRMWARE_SIZE, ro_space_attributes,
	pcr0_unchanged_policy, sizeof(pcr0_unchanged_policy));
	}

	static uint32_t set_kernel_space(const void *kernel_blob)
	{
	return set_space("kernel", KERNEL_NV_INDEX, kernel_blob,
	VB2_SECDATA_KERNEL_SIZE, rw_space_attributes, NULL, 0);
	}

	static uint32_t set_rec_hash_space(const uint8_t *data)
	{
	return set_space("MRC Hash", REC_HASH_NV_INDEX, data,
	REC_HASH_NV_SIZE,
	ro_space_attributes, pcr0_unchanged_policy,
	sizeof(pcr0_unchanged_policy));
	}

	static uint32_t _factory_initialize_tpm(struct vb2_context *ctx)
	{
	vb2api_secdata_kernel_create(ctx);

	RETURN_ON_FAILURE(tlcl_force_clear());

	/*
	* Of all NVRAM spaces defined by this function the firmware space
	* must be defined last, because its existence is considered an
	* indication that TPM factory initialization was successfully
	* completed.
	*/
	RETURN_ON_FAILURE(set_kernel_space(ctx->secdata_kernel));

	if (CONFIG(VBOOT_HAS_REC_HASH_SPACE))
	RETURN_ON_FAILURE(set_rec_hash_space(rec_hash_data));

	RETURN_ON_FAILURE(set_firmware_space(ctx->secdata_firmware));

	return TPM_SUCCESS;
	}

	uint32_t antirollback_lock_space_firmware(void)
	{
	return tlcl_lock_nv_write(FIRMWARE_NV_INDEX);
	}

	uint32_t antirollback_lock_space_rec_hash(void)
	{
	return tlcl_lock_nv_write(REC_HASH_NV_INDEX);
	}

	#else

	/**
	* Like tlcl_write(), but checks for write errors due to hitting the 64-write
	* limit and clears the TPM when that happens. This can only happen when the
	* TPM is unowned, so it is OK to clear it (and we really have no choice).
	* This is not expected to happen frequently, but it could happen.
	*/

	static uint32_t safe_write(uint32_t index, const void *data, uint32_t length)
	{
	uint32_t result = tlcl_write(index, data, length);
	if (result == TPM_E_MAXNVWRITES) {
	RETURN_ON_FAILURE(tpm_clear_and_reenable());
	return tlcl_write(index, data, length);
	} else {
	return result;
	}
	}

	/**
	* Similarly to safe_write(), this ensures we don't fail a DefineSpace because
	* we hit the TPM write limit. This is even less likely to happen than with
	* writes because we only define spaces once at initialization, but we'd
	* rather be paranoid about this.
	*/
	static uint32_t safe_define_space(uint32_t index, uint32_t perm, uint32_t size)
	{
	uint32_t result = tlcl_define_space(index, perm, size);
	if (result == TPM_E_MAXNVWRITES) {
	RETURN_ON_FAILURE(tpm_clear_and_reenable());
	return tlcl_define_space(index, perm, size);
	} else {
	return result;
	}
	}

	static uint32_t set_rec_hash_space(const uint8_t *data)
	{
	RETURN_ON_FAILURE(safe_define_space(REC_HASH_NV_INDEX,
	TPM_NV_PER_GLOBALLOCK \|
	TPM_NV_PER_PPWRITE,
	REC_HASH_NV_SIZE));
	RETURN_ON_FAILURE(safe_write(REC_HASH_NV_INDEX, data,
	REC_HASH_NV_SIZE));

	return TPM_SUCCESS;
	}

	static uint32_t _factory_initialize_tpm(struct vb2_context *ctx)
	{
	TPM_PERMANENT_FLAGS pflags;
	uint32_t result;

	vb2api_secdata_kernel_create_v0(ctx);

	result = tlcl_get_permanent_flags(&pflags);
	if (result != TPM_SUCCESS)
	return result;

	/*
	* TPM may come from the factory without physical presence finalized.
	* Fix if necessary.
	*/
	VBDEBUG("TPM: physicalPresenceLifetimeLock=%d\n",
	pflags.physicalPresenceLifetimeLock);
	if (!pflags.physicalPresenceLifetimeLock) {
	VBDEBUG("TPM: Finalizing physical presence\n");
	RETURN_ON_FAILURE(tlcl_finalize_physical_presence());
	}

	/*
	* The TPM will not enforce the NV authorization restrictions until the
	* execution of a TPM_NV_DefineSpace with the handle of
	* TPM_NV_INDEX_LOCK. Here we create that space if it doesn't already
	* exist. */
	VBDEBUG("TPM: nvLocked=%d\n", pflags.nvLocked);
	if (!pflags.nvLocked) {
	VBDEBUG("TPM: Enabling NV locking\n");
	RETURN_ON_FAILURE(tlcl_set_nv_locked());
	}

	/* Clear TPM owner, in case the TPM is already owned for some reason. */
	VBDEBUG("TPM: Clearing owner\n");
	RETURN_ON_FAILURE(tpm_clear_and_reenable());

	/* Define and write secdata_kernel space. */
	RETURN_ON_FAILURE(safe_define_space(KERNEL_NV_INDEX,
	TPM_NV_PER_PPWRITE,
	VB2_SECDATA_KERNEL_SIZE_V02));
	RETURN_ON_FAILURE(safe_write(KERNEL_NV_INDEX,
	ctx->secdata_kernel,
	VB2_SECDATA_KERNEL_SIZE_V02));

	/* Define and write secdata_firmware space. */
	RETURN_ON_FAILURE(safe_define_space(FIRMWARE_NV_INDEX,
	TPM_NV_PER_GLOBALLOCK \|
	TPM_NV_PER_PPWRITE,
	VB2_SECDATA_FIRMWARE_SIZE));
	RETURN_ON_FAILURE(safe_write(FIRMWARE_NV_INDEX,
	ctx->secdata_firmware,
	VB2_SECDATA_FIRMWARE_SIZE));

	/* Define and set rec hash space, if available. */
	if (CONFIG(VBOOT_HAS_REC_HASH_SPACE))
	RETURN_ON_FAILURE(set_rec_hash_space(rec_hash_data));

	return TPM_SUCCESS;
	}

	uint32_t antirollback_lock_space_firmware(void)
	{
	return tlcl_set_global_lock();
	}

	uint32_t antirollback_lock_space_rec_hash(void)
	{
	/*
	* Nothing needs to be done here, since global lock is already set while
	* locking firmware space.
	*/
	return TPM_SUCCESS;
	}
	#endif

	/**
	* Perform one-time initializations.
	*
	* Create the NVRAM spaces, and set their initial values as needed. Sets the
	* nvLocked bit and ensures the physical presence command is enabled and
	* locked.
	*/
	static uint32_t factory_initialize_tpm(struct vb2_context *ctx)
	{
	uint32_t result;

	/*
	* Set initial values of secdata_firmware space.
	* kernel space is created in _factory_initialize_tpm().
	*/
	vb2api_secdata_firmware_create(ctx);

	VBDEBUG("TPM: factory initialization\n");

	/*
	* Do a full test. This only happens the first time the device is
	* turned on in the factory, so performance is not an issue. This is
	* almost certainly not necessary, but it gives us more confidence
	* about some code paths below that are difficult to
	* test---specifically the ones that set lifetime flags, and are only
	* executed once per physical TPM.
	*/
	result = tlcl_self_test_full();
	if (result != TPM_SUCCESS)
	return result;

	result = _factory_initialize_tpm(ctx);
	if (result != TPM_SUCCESS)
	return result;

	/* _factory_initialize_tpm() writes initial secdata values to TPM
	immediately, so let vboot know that it's up to date now. */
	ctx->flags &= ~(VB2_CONTEXT_SECDATA_FIRMWARE_CHANGED \|
	VB2_CONTEXT_SECDATA_KERNEL_CHANGED);

	VBDEBUG("TPM: factory initialization successful\n");

	return TPM_SUCCESS;
	}

	uint32_t antirollback_read_space_firmware(struct vb2_context *ctx)
	{
	uint32_t rv;

	/* Read the firmware space. */
	rv = read_space_firmware(ctx);
	if (rv == TPM_E_BADINDEX) {
	/* This seems the first time we've run. Initialize the TPM. */
	VBDEBUG("TPM: Not initialized yet.\n");
	RETURN_ON_FAILURE(factory_initialize_tpm(ctx));
	} else if (rv != TPM_SUCCESS) {
	VBDEBUG("TPM: Firmware space in a bad state; giving up.\n");
	return TPM_E_CORRUPTED_STATE;
	}

	return TPM_SUCCESS;
	}

	uint32_t antirollback_write_space_firmware(struct vb2_context *ctx)
	{
	if (CONFIG(CR50_IMMEDIATELY_COMMIT_FW_SECDATA))
	tlcl_cr50_enable_nvcommits();
	return safe_write(FIRMWARE_NV_INDEX, ctx->secdata_firmware,
	VB2_SECDATA_FIRMWARE_SIZE);
	}

	uint32_t antirollback_write_space_kernel(struct vb2_context *ctx)
	{
	/* Learn the expected size. */
	uint8_t size = VB2_SECDATA_KERNEL_MIN_SIZE;
	vb2api_secdata_kernel_check(ctx, &size);

	return safe_write(KERNEL_NV_INDEX, ctx->secdata_kernel, size);
	}

	uint32_t antirollback_read_space_rec_hash(uint8_t *data, uint32_t size)
	{
	if (size != REC_HASH_NV_SIZE) {
	VBDEBUG("TPM: Incorrect buffer size for rec hash. "
	"(Expected=0x%x Actual=0x%x).\n", REC_HASH_NV_SIZE,
	size);
	return TPM_E_READ_FAILURE;
	}
	return read_space_rec_hash(data);
	}

	uint32_t antirollback_write_space_rec_hash(const uint8_t *data, uint32_t size)
	{
	uint8_t spc_data[REC_HASH_NV_SIZE];
	uint32_t rv;

	if (size != REC_HASH_NV_SIZE) {
	VBDEBUG("TPM: Incorrect buffer size for rec hash. "
	"(Expected=0x%x Actual=0x%x).\n", REC_HASH_NV_SIZE,
	size);
	return TPM_E_WRITE_FAILURE;
	}

	rv = read_space_rec_hash(spc_data);
	if (rv == TPM_E_BADINDEX) {
	/*
	* If space is not defined already for recovery hash, define
	* new space.
	*/
	VBDEBUG("TPM: Initializing recovery hash space.\n");
	return set_rec_hash_space(data);
	}

	if (rv != TPM_SUCCESS)
	return rv;

	return safe_write(REC_HASH_NV_INDEX, data, size);
	}

	vb2_error_t vb2ex_tpm_clear_owner(struct vb2_context *ctx)
	{
	uint32_t rv;
	printk(BIOS_INFO, "Clearing TPM owner\n");
	rv = tpm_clear_and_reenable();
	if (rv)
	return VB2_ERROR_EX_TPM_CLEAR_OWNER;
	return VB2_SUCCESS;
	}