[mirror_qemu.git] / docs / amd-memory-encryption.txt

Secure Encrypted Virtualization (SEV) is a feature found on AMD processors.

SEV is an extension to the AMD-V architecture which supports running encrypted
virtual machine (VMs) under the control of KVM. Encrypted VMs have their pages
(code and data) secured such that only the guest itself has access to the
unencrypted version. Each encrypted VM is associated with a unique encryption
key; if its data is accessed to a different entity using a different key the
encrypted guests data will be incorrectly decrypted, leading to unintelligible
data.

The key management of this feature is handled by separate processor known as
AMD secure processor (AMD-SP) which is present in AMD SOCs. Firmware running
inside the AMD-SP provide commands to support common VM lifecycle. This
includes commands for launching, snapshotting, migrating and debugging the
encrypted guest. Those SEV command can be issued via KVM_MEMORY_ENCRYPT_OP
ioctls.

Launching
---------
Boot images (such as bios) must be encrypted before guest can be booted.
MEMORY_ENCRYPT_OP ioctl provides commands to encrypt the images :LAUNCH_START,
LAUNCH_UPDATE_DATA, LAUNCH_MEASURE and LAUNCH_FINISH. These four commands
together generate a fresh memory encryption key for the VM, encrypt the boot
images and provide a measurement than can be used as an attestation of the
successful launch.

LAUNCH_START is called first to create a cryptographic launch context within
the firmware. To create this context, guest owner must provides guest policy,
its public Diffie-Hellman key (PDH) and session parameters. These inputs
should be treated as binary blob and must be passed as-is to the SEV firmware.

The guest policy is passed as plaintext and hypervisor may able to read it
but should not modify it (any modification of the policy bits will result
in bad measurement). The guest policy is a 4-byte data structure containing
several flags that restricts what can be done on running SEV guest.
See KM Spec section 3 and 6.2 for more details.

The guest policy can be provided via the 'policy' property (see below)

# ${QEMU} \
   sev-guest,id=sev0,policy=0x1...\

Guest owners provided DH certificate and session parameters will be used to
establish a cryptographic session with the guest owner to negotiate keys used
for the attestation.

The DH certificate and session blob can be provided via 'dh-cert-file' and
'session-file' property (see below

# ${QEMU} \
     sev-guest,id=sev0,dh-cert-file=<file1>,session-file=<file2>

LAUNCH_UPDATE_DATA encrypts the memory region using the cryptographic context
created via LAUNCH_START command. If required, this command can be called
multiple times to encrypt different memory regions. The command also calculates
the measurement of the memory contents as it encrypts.

LAUNCH_MEASURE command can be used to retrieve the measurement of encrypted
memory. This measurement is a signature of the memory contents that can be
sent to the guest owner as an attestation that the memory was encrypted
correctly by the firmware. The guest owner may wait to provide the guest
confidential information until it can verify the attestation measurement.
Since the guest owner knows the initial contents of the guest at boot, the
attestation measurement can be verified by comparing it to what the guest owner
expects.

LAUNCH_FINISH command finalizes the guest launch and destroy's the cryptographic
context.

See SEV KM API Spec [1] 'Launching a guest' usage flow (Appendix A) for the
complete flow chart.

To launch a SEV guest

# ${QEMU} \
    -machine ...,memory-encryption=sev0 \
    -object sev-guest,id=sev0,cbitpos=47,reduced-phys-bits=1

Debugging
-----------
Since memory contents of SEV guest is encrypted hence hypervisor access to the
guest memory will get a cipher text. If guest policy allows debugging, then
hypervisor can use DEBUG_DECRYPT and DEBUG_ENCRYPT commands access the guest
memory region for debug purposes.  This is not supported in QEMU yet.

Snapshot/Restore
-----------------
TODO

Live Migration
----------------
TODO

References
-----------------

AMD Memory Encryption whitepaper:
http://amd-dev.wpengine.netdna-cdn.com/wordpress/media/2013/12/AMD_Memory_Encryption_Whitepaper_v7-Public.pdf

Secure Encrypted Virtualization Key Management:
[1] http://support.amd.com/TechDocs/55766_SEV-KM API_Specification.pdf

KVM Forum slides:
http://www.linux-kvm.org/images/7/74/02x08A-Thomas_Lendacky-AMDs_Virtualizatoin_Memory_Encryption_Technology.pdf

AMD64 Architecture Programmer's Manual:
   http://support.amd.com/TechDocs/24593.pdf
   SME is section 7.10
   SEV is section 15.34
Commit	Line	Data
9b02f7bf BS	1	Secure Encrypted Virtualization (SEV) is a feature found on AMD processors.
	2
	3	SEV is an extension to the AMD-V architecture which supports running encrypted
	4	virtual machine (VMs) under the control of KVM. Encrypted VMs have their pages
	5	(code and data) secured such that only the guest itself has access to the
	6	unencrypted version. Each encrypted VM is associated with a unique encryption
	7	key; if its data is accessed to a different entity using a different key the
	8	encrypted guests data will be incorrectly decrypted, leading to unintelligible
	9	data.
	10
	11	The key management of this feature is handled by separate processor known as
	12	AMD secure processor (AMD-SP) which is present in AMD SOCs. Firmware running
	13	inside the AMD-SP provide commands to support common VM lifecycle. This
	14	includes commands for launching, snapshotting, migrating and debugging the
	15	encrypted guest. Those SEV command can be issued via KVM_MEMORY_ENCRYPT_OP
	16	ioctls.
	17
	18	Launching
	19	---------
	20	Boot images (such as bios) must be encrypted before guest can be booted.
	21	MEMORY_ENCRYPT_OP ioctl provides commands to encrypt the images :LAUNCH_START,
	22	LAUNCH_UPDATE_DATA, LAUNCH_MEASURE and LAUNCH_FINISH. These four commands
	23	together generate a fresh memory encryption key for the VM, encrypt the boot
	24	images and provide a measurement than can be used as an attestation of the
	25	successful launch.
	26
	27	LAUNCH_START is called first to create a cryptographic launch context within
	28	the firmware. To create this context, guest owner must provides guest policy,
	29	its public Diffie-Hellman key (PDH) and session parameters. These inputs
	30	should be treated as binary blob and must be passed as-is to the SEV firmware.
	31
	32	The guest policy is passed as plaintext and hypervisor may able to read it
	33	but should not modify it (any modification of the policy bits will result
	34	in bad measurement). The guest policy is a 4-byte data structure containing
	35	several flags that restricts what can be done on running SEV guest.
	36	See KM Spec section 3 and 6.2 for more details.
	37
a9b4942f BS	38	The guest policy can be provided via the 'policy' property (see below)
	39
	40	# ${QEMU} \
	41	sev-guest,id=sev0,policy=0x1...\
	42
9b02f7bf BS	43	Guest owners provided DH certificate and session parameters will be used to
	44	establish a cryptographic session with the guest owner to negotiate keys used
	45	for the attestation.
	46
a9b4942f BS	47	The DH certificate and session blob can be provided via 'dh-cert-file' and
	48	'session-file' property (see below
	49
	50	# ${QEMU} \
	51	sev-guest,id=sev0,dh-cert-file=<file1>,session-file=<file2>
	52
9b02f7bf BS	53	LAUNCH_UPDATE_DATA encrypts the memory region using the cryptographic context
	54	created via LAUNCH_START command. If required, this command can be called
	55	multiple times to encrypt different memory regions. The command also calculates
	56	the measurement of the memory contents as it encrypts.
	57
	58	LAUNCH_MEASURE command can be used to retrieve the measurement of encrypted
	59	memory. This measurement is a signature of the memory contents that can be
	60	sent to the guest owner as an attestation that the memory was encrypted
	61	correctly by the firmware. The guest owner may wait to provide the guest
	62	confidential information until it can verify the attestation measurement.
	63	Since the guest owner knows the initial contents of the guest at boot, the
	64	attestation measurement can be verified by comparing it to what the guest owner
	65	expects.
	66
	67	LAUNCH_FINISH command finalizes the guest launch and destroy's the cryptographic
	68	context.
	69
	70	See SEV KM API Spec [1] 'Launching a guest' usage flow (Appendix A) for the
	71	complete flow chart.
	72
a9b4942f BS	73	To launch a SEV guest
	74
	75	# ${QEMU} \
	76	-machine ...,memory-encryption=sev0 \
	77	-object sev-guest,id=sev0,cbitpos=47,reduced-phys-bits=1
	78
9b02f7bf BS	79	Debugging
	80	-----------
	81	Since memory contents of SEV guest is encrypted hence hypervisor access to the
	82	guest memory will get a cipher text. If guest policy allows debugging, then
	83	hypervisor can use DEBUG_DECRYPT and DEBUG_ENCRYPT commands access the guest
	84	memory region for debug purposes. This is not supported in QEMU yet.
	85
	86	Snapshot/Restore
	87	-----------------
	88	TODO
	89
	90	Live Migration
	91	----------------
	92	TODO
	93
	94	References
	95	-----------------
	96
	97	AMD Memory Encryption whitepaper:
	98	http://amd-dev.wpengine.netdna-cdn.com/wordpress/media/2013/12/AMD_Memory_Encryption_Whitepaper_v7-Public.pdf
	99
806be373	100	Secure Encrypted Virtualization Key Management:
9b02f7bf BS	101	[1] http://support.amd.com/TechDocs/55766_SEV-KM API_Specification.pdf
	102
	103	KVM Forum slides:
	104	http://www.linux-kvm.org/images/7/74/02x08A-Thomas_Lendacky-AMDs_Virtualizatoin_Memory_Encryption_Technology.pdf
	105
	106	AMD64 Architecture Programmer's Manual:
	107	http://support.amd.com/TechDocs/24593.pdf
	108	SME is section 7.10
	109	SEV is section 15.34