[linux-2.6-block.git] / Documentation / x86 / amd-memory-encryption.rst

.. SPDX-License-Identifier: GPL-2.0

=====================
AMD Memory Encryption
=====================

Secure Memory Encryption (SME) and Secure Encrypted Virtualization (SEV) are
features found on AMD processors.

SME provides the ability to mark individual pages of memory as encrypted using
the standard x86 page tables.  A page that is marked encrypted will be
automatically decrypted when read from DRAM and encrypted when written to
DRAM.  SME can therefore be used to protect the contents of DRAM from physical
attacks on the system.

SEV enables running encrypted virtual machines (VMs) in which the code and data
of the guest VM are secured so that a decrypted version is available only
within the VM itself. SEV guest VMs have the concept of private and shared
memory. Private memory is encrypted with the guest-specific key, while shared
memory may be encrypted with hypervisor key. When SME is enabled, the hypervisor
key is the same key which is used in SME.

A page is encrypted when a page table entry has the encryption bit set (see
below on how to determine its position).  The encryption bit can also be
specified in the cr3 register, allowing the PGD table to be encrypted. Each
successive level of page tables can also be encrypted by setting the encryption
bit in the page table entry that points to the next table. This allows the full
page table hierarchy to be encrypted. Note, this means that just because the
encryption bit is set in cr3, doesn't imply the full hierarchy is encrypted.
Each page table entry in the hierarchy needs to have the encryption bit set to
achieve that. So, theoretically, you could have the encryption bit set in cr3
so that the PGD is encrypted, but not set the encryption bit in the PGD entry
for a PUD which results in the PUD pointed to by that entry to not be
encrypted.

When SEV is enabled, instruction pages and guest page tables are always treated
as private. All the DMA operations inside the guest must be performed on shared
memory. Since the memory encryption bit is controlled by the guest OS when it
is operating in 64-bit or 32-bit PAE mode, in all other modes the SEV hardware
forces the memory encryption bit to 1.

Support for SME and SEV can be determined through the CPUID instruction. The
CPUID function 0x8000001f reports information related to SME::

	0x8000001f[eax]:
		Bit[0] indicates support for SME
		Bit[1] indicates support for SEV
	0x8000001f[ebx]:
		Bits[5:0]  pagetable bit number used to activate memory
			   encryption
		Bits[11:6] reduction in physical address space, in bits, when
			   memory encryption is enabled (this only affects
			   system physical addresses, not guest physical
			   addresses)

If support for SME is present, MSR 0xc00100010 (MSR_K8_SYSCFG) can be used to
determine if SME is enabled and/or to enable memory encryption::

	0xc0010010:
		Bit[23]   0 = memory encryption features are disabled
			  1 = memory encryption features are enabled

If SEV is supported, MSR 0xc0010131 (MSR_AMD64_SEV) can be used to determine if
SEV is active::

	0xc0010131:
		Bit[0]	  0 = memory encryption is not active
			  1 = memory encryption is active

Linux relies on BIOS to set this bit if BIOS has determined that the reduction
in the physical address space as a result of enabling memory encryption (see
CPUID information above) will not conflict with the address space resource
requirements for the system.  If this bit is not set upon Linux startup then
Linux itself will not set it and memory encryption will not be possible.

The state of SME in the Linux kernel can be documented as follows:

	- Supported:
	  The CPU supports SME (determined through CPUID instruction).

	- Enabled:
	  Supported and bit 23 of MSR_K8_SYSCFG is set.

	- Active:
	  Supported, Enabled and the Linux kernel is actively applying
	  the encryption bit to page table entries (the SME mask in the
	  kernel is non-zero).

SME can also be enabled and activated in the BIOS. If SME is enabled and
activated in the BIOS, then all memory accesses will be encrypted and it will
not be necessary to activate the Linux memory encryption support.  If the BIOS
merely enables SME (sets bit 23 of the MSR_K8_SYSCFG), then Linux can activate
memory encryption by default (CONFIG_AMD_MEM_ENCRYPT_ACTIVE_BY_DEFAULT=y) or
by supplying mem_encrypt=on on the kernel command line.  However, if BIOS does
not enable SME, then Linux will not be able to activate memory encryption, even
if configured to do so by default or the mem_encrypt=on command line parameter
is specified.
Commit	Line	Data
0c7180f2 CD	1	.. SPDX-License-Identifier: GPL-2.0
	2
	3	=====================
	4	AMD Memory Encryption
	5	=====================
	6
33e63acc BS	7	Secure Memory Encryption (SME) and Secure Encrypted Virtualization (SEV) are
33e63acc BS	8	features found on AMD processors.
c262f3b9 TL	9
	10	SME provides the ability to mark individual pages of memory as encrypted using
	11	the standard x86 page tables. A page that is marked encrypted will be
	12	automatically decrypted when read from DRAM and encrypted when written to
	13	DRAM. SME can therefore be used to protect the contents of DRAM from physical
	14	attacks on the system.
	15
33e63acc BS	16	SEV enables running encrypted virtual machines (VMs) in which the code and data
	17	of the guest VM are secured so that a decrypted version is available only
	18	within the VM itself. SEV guest VMs have the concept of private and shared
	19	memory. Private memory is encrypted with the guest-specific key, while shared
	20	memory may be encrypted with hypervisor key. When SME is enabled, the hypervisor
	21	key is the same key which is used in SME.
	22
c262f3b9 TL	23	A page is encrypted when a page table entry has the encryption bit set (see
	24	below on how to determine its position). The encryption bit can also be
	25	specified in the cr3 register, allowing the PGD table to be encrypted. Each
	26	successive level of page tables can also be encrypted by setting the encryption
	27	bit in the page table entry that points to the next table. This allows the full
	28	page table hierarchy to be encrypted. Note, this means that just because the
33e63acc	29	encryption bit is set in cr3, doesn't imply the full hierarchy is encrypted.
c262f3b9 TL	30	Each page table entry in the hierarchy needs to have the encryption bit set to
	31	achieve that. So, theoretically, you could have the encryption bit set in cr3
	32	so that the PGD is encrypted, but not set the encryption bit in the PGD entry
	33	for a PUD which results in the PUD pointed to by that entry to not be
	34	encrypted.
	35
33e63acc BS	36	When SEV is enabled, instruction pages and guest page tables are always treated
	37	as private. All the DMA operations inside the guest must be performed on shared
	38	memory. Since the memory encryption bit is controlled by the guest OS when it
	39	is operating in 64-bit or 32-bit PAE mode, in all other modes the SEV hardware
	40	forces the memory encryption bit to 1.
	41
	42	Support for SME and SEV can be determined through the CPUID instruction. The
0c7180f2	43	CPUID function 0x8000001f reports information related to SME::
c262f3b9 TL	44
	45	0x8000001f[eax]:
	46	Bit[0] indicates support for SME
33e63acc	47	Bit[1] indicates support for SEV
c262f3b9 TL	48	0x8000001f[ebx]:
	49	Bits[5:0] pagetable bit number used to activate memory
	50	encryption
	51	Bits[11:6] reduction in physical address space, in bits, when
	52	memory encryption is enabled (this only affects
	53	system physical addresses, not guest physical
	54	addresses)
	55
	56	If support for SME is present, MSR 0xc00100010 (MSR_K8_SYSCFG) can be used to
0c7180f2	57	determine if SME is enabled and/or to enable memory encryption::
c262f3b9 TL	58
	59	0xc0010010:
	60	Bit[23] 0 = memory encryption features are disabled
	61	1 = memory encryption features are enabled
	62
33e63acc	63	If SEV is supported, MSR 0xc0010131 (MSR_AMD64_SEV) can be used to determine if
0c7180f2	64	SEV is active::
33e63acc BS	65
	66	0xc0010131:
	67	Bit[0] 0 = memory encryption is not active
	68	1 = memory encryption is active
	69
c262f3b9 TL	70	Linux relies on BIOS to set this bit if BIOS has determined that the reduction
	71	in the physical address space as a result of enabling memory encryption (see
	72	CPUID information above) will not conflict with the address space resource
	73	requirements for the system. If this bit is not set upon Linux startup then
	74	Linux itself will not set it and memory encryption will not be possible.
	75
	76	The state of SME in the Linux kernel can be documented as follows:
0c7180f2	77
c262f3b9 TL	78	- Supported:
	79	The CPU supports SME (determined through CPUID instruction).
	80
	81	- Enabled:
	82	Supported and bit 23 of MSR_K8_SYSCFG is set.
	83
	84	- Active:
	85	Supported, Enabled and the Linux kernel is actively applying
	86	the encryption bit to page table entries (the SME mask in the
	87	kernel is non-zero).
	88
	89	SME can also be enabled and activated in the BIOS. If SME is enabled and
	90	activated in the BIOS, then all memory accesses will be encrypted and it will
	91	not be necessary to activate the Linux memory encryption support. If the BIOS
	92	merely enables SME (sets bit 23 of the MSR_K8_SYSCFG), then Linux can activate
	93	memory encryption by default (CONFIG_AMD_MEM_ENCRYPT_ACTIVE_BY_DEFAULT=y) or
	94	by supplying mem_encrypt=on on the kernel command line. However, if BIOS does
	95	not enable SME, then Linux will not be able to activate memory encryption, even
	96	if configured to do so by default or the mem_encrypt=on command line parameter
	97	is specified.