Documentation/security/secrets/coco.rst - linux/kernel/git/torvalds/linux - Git at Google

 .. SPDX-License-Identifier: GPL-2.0

 ==============================
 Confidential Computing secrets
 ==============================

 This document describes how Confidential Computing secret injection is handled
 from the firmware to the operating system, in the EFI driver and the efi_secret
 kernel module.


 Introduction
 ============

 Confidential Computing (coco) hardware such as AMD SEV (Secure Encrypted
 Virtualization) allows guest owners to inject secrets into the VMs
 memory without the host/hypervisor being able to read them.  In SEV,
 secret injection is performed early in the VM launch process, before the
 guest starts running.

 The efi_secret kernel module allows userspace applications to access these
 secrets via securityfs.


 Secret data flow
 ================

 The guest firmware may reserve a designated memory area for secret injection,
 and publish its location (base GPA and length) in the EFI configuration table
 under a ``LINUX_EFI_COCO_SECRET_AREA_GUID`` entry
 (``adf956ad-e98c-484c-ae11-b51c7d336447``).  This memory area should be marked
 by the firmware as ``EFI_RESERVED_TYPE``, and therefore the kernel should not
 be use it for its own purposes.

 During the VM's launch, the virtual machine manager may inject a secret to that
 area.  In AMD SEV and SEV-ES this is performed using the
 ``KVM_SEV_LAUNCH_SECRET`` command (see [sev]_).  The strucutre of the injected
 Guest Owner secret data should be a GUIDed table of secret values; the binary
 format is described in ``drivers/virt/coco/efi_secret/efi_secret.c`` under
 "Structure of the EFI secret area".

 On kernel start, the kernel's EFI driver saves the location of the secret area
 (taken from the EFI configuration table) in the ``efi.coco_secret`` field.
 Later it checks if the secret area is populated: it maps the area and checks
 whether its content begins with ``EFI_SECRET_TABLE_HEADER_GUID``
 (``1e74f542-71dd-4d66-963e-ef4287ff173b``).  If the secret area is populated,
 the EFI driver will autoload the efi_secret kernel module, which exposes the
 secrets to userspace applications via securityfs.  The details of the
 efi_secret filesystem interface are in [secrets-coco-abi]_.


 Application usage example
 =========================

 Consider a guest performing computations on encrypted files.  The Guest Owner
 provides the decryption key (= secret) using the secret injection mechanism.
 The guest application reads the secret from the efi_secret filesystem and
 proceeds to decrypt the files into memory and then performs the needed
 computations on the content.

 In this example, the host can't read the files from the disk image
 because they are encrypted.  Host can't read the decryption key because
 it is passed using the secret injection mechanism (= secure channel).
 Host can't read the decrypted content from memory because it's a
 confidential (memory-encrypted) guest.

 Here is a simple example for usage of the efi_secret module in a guest
 to which an EFI secret area with 4 secrets was injected during launch::

 	# ls -la /sys/kernel/security/secrets/coco
 	total 0
 	drwxr-xr-x 2 root root 0 Jun 28 11:54 .
 	drwxr-xr-x 3 root root 0 Jun 28 11:54 ..
 	-r--r----- 1 root root 0 Jun 28 11:54 736870e5-84f0-4973-92ec-06879ce3da0b
 	-r--r----- 1 root root 0 Jun 28 11:54 83c83f7f-1356-4975-8b7e-d3a0b54312c6
 	-r--r----- 1 root root 0 Jun 28 11:54 9553f55d-3da2-43ee-ab5d-ff17f78864d2
 	-r--r----- 1 root root 0 Jun 28 11:54 e6f5a162-d67f-4750-a67c-5d065f2a9910

 	# hd /sys/kernel/security/secrets/coco/e6f5a162-d67f-4750-a67c-5d065f2a9910
 	00000000  74 68 65 73 65 2d 61 72  65 2d 74 68 65 2d 6b 61  |these-are-the-ka|
 	00000010  74 61 2d 73 65 63 72 65  74 73 00 01 02 03 04 05  |ta-secrets......|
 	00000020  06 07                                             |..|
 	00000022

 	# rm /sys/kernel/security/secrets/coco/e6f5a162-d67f-4750-a67c-5d065f2a9910

 	# ls -la /sys/kernel/security/secrets/coco
 	total 0
 	drwxr-xr-x 2 root root 0 Jun 28 11:55 .
 	drwxr-xr-x 3 root root 0 Jun 28 11:54 ..
 	-r--r----- 1 root root 0 Jun 28 11:54 736870e5-84f0-4973-92ec-06879ce3da0b
 	-r--r----- 1 root root 0 Jun 28 11:54 83c83f7f-1356-4975-8b7e-d3a0b54312c6
 	-r--r----- 1 root root 0 Jun 28 11:54 9553f55d-3da2-43ee-ab5d-ff17f78864d2


 References
 ==========

 See [sev-api-spec]_ for more info regarding SEV ``LAUNCH_SECRET`` operation.

 .. [sev] Documentation/virt/kvm/x86/amd-memory-encryption.rst
 .. [secrets-coco-abi] Documentation/ABI/testing/securityfs-secrets-coco
 .. [sev-api-spec] https://www.amd.com/system/files/TechDocs/55766_SEV-KM_API_Specification.pdf
	.. SPDX-License-Identifier: GPL-2.0

	==============================
	Confidential Computing secrets
	==============================

	This document describes how Confidential Computing secret injection is handled
	from the firmware to the operating system, in the EFI driver and the efi_secret
	kernel module.


	Introduction
	============

	Confidential Computing (coco) hardware such as AMD SEV (Secure Encrypted
	Virtualization) allows guest owners to inject secrets into the VMs
	memory without the host/hypervisor being able to read them. In SEV,
	secret injection is performed early in the VM launch process, before the
	guest starts running.

	The efi_secret kernel module allows userspace applications to access these
	secrets via securityfs.


	Secret data flow
	================

	The guest firmware may reserve a designated memory area for secret injection,
	and publish its location (base GPA and length) in the EFI configuration table
	under a ``LINUX_EFI_COCO_SECRET_AREA_GUID`` entry
	(``adf956ad-e98c-484c-ae11-b51c7d336447``). This memory area should be marked
	by the firmware as ``EFI_RESERVED_TYPE``, and therefore the kernel should not
	be use it for its own purposes.

	During the VM's launch, the virtual machine manager may inject a secret to that
	area. In AMD SEV and SEV-ES this is performed using the
	``KVM_SEV_LAUNCH_SECRET`` command (see [sev]_). The strucutre of the injected
	Guest Owner secret data should be a GUIDed table of secret values; the binary
	format is described in ``drivers/virt/coco/efi_secret/efi_secret.c`` under
	"Structure of the EFI secret area".

	On kernel start, the kernel's EFI driver saves the location of the secret area
	(taken from the EFI configuration table) in the ``efi.coco_secret`` field.
	Later it checks if the secret area is populated: it maps the area and checks
	whether its content begins with ``EFI_SECRET_TABLE_HEADER_GUID``
	(``1e74f542-71dd-4d66-963e-ef4287ff173b``). If the secret area is populated,
	the EFI driver will autoload the efi_secret kernel module, which exposes the
	secrets to userspace applications via securityfs. The details of the
	efi_secret filesystem interface are in [secrets-coco-abi]_.


	Application usage example
	=========================

	Consider a guest performing computations on encrypted files. The Guest Owner
	provides the decryption key (= secret) using the secret injection mechanism.
	The guest application reads the secret from the efi_secret filesystem and
	proceeds to decrypt the files into memory and then performs the needed
	computations on the content.

	In this example, the host can't read the files from the disk image
	because they are encrypted. Host can't read the decryption key because
	it is passed using the secret injection mechanism (= secure channel).
	Host can't read the decrypted content from memory because it's a
	confidential (memory-encrypted) guest.

	Here is a simple example for usage of the efi_secret module in a guest
	to which an EFI secret area with 4 secrets was injected during launch::

	# ls -la /sys/kernel/security/secrets/coco
	total 0
	drwxr-xr-x 2 root root 0 Jun 28 11:54 .
	drwxr-xr-x 3 root root 0 Jun 28 11:54 ..
	-r--r----- 1 root root 0 Jun 28 11:54 736870e5-84f0-4973-92ec-06879ce3da0b
	-r--r----- 1 root root 0 Jun 28 11:54 83c83f7f-1356-4975-8b7e-d3a0b54312c6
	-r--r----- 1 root root 0 Jun 28 11:54 9553f55d-3da2-43ee-ab5d-ff17f78864d2
	-r--r----- 1 root root 0 Jun 28 11:54 e6f5a162-d67f-4750-a67c-5d065f2a9910

	# hd /sys/kernel/security/secrets/coco/e6f5a162-d67f-4750-a67c-5d065f2a9910
	00000000 74 68 65 73 65 2d 61 72 65 2d 74 68 65 2d 6b 61 \|these-are-the-ka\|
	00000010 74 61 2d 73 65 63 72 65 74 73 00 01 02 03 04 05 \|ta-secrets......\|
	00000020 06 07 \|..\|
	00000022

	# rm /sys/kernel/security/secrets/coco/e6f5a162-d67f-4750-a67c-5d065f2a9910

	# ls -la /sys/kernel/security/secrets/coco
	total 0
	drwxr-xr-x 2 root root 0 Jun 28 11:55 .
	drwxr-xr-x 3 root root 0 Jun 28 11:54 ..
	-r--r----- 1 root root 0 Jun 28 11:54 736870e5-84f0-4973-92ec-06879ce3da0b
	-r--r----- 1 root root 0 Jun 28 11:54 83c83f7f-1356-4975-8b7e-d3a0b54312c6
	-r--r----- 1 root root 0 Jun 28 11:54 9553f55d-3da2-43ee-ab5d-ff17f78864d2


	References
	==========

	See [sev-api-spec]_ for more info regarding SEV ``LAUNCH_SECRET`` operation.

	.. [sev] Documentation/virt/kvm/x86/amd-memory-encryption.rst
	.. [secrets-coco-abi] Documentation/ABI/testing/securityfs-secrets-coco
	.. [sev-api-spec] https://www.amd.com/system/files/TechDocs/55766_SEV-KM_API_Specification.pdf