v2.5
The Trusted Computing Group (TCG) specifies Hardware Requirements for a Device Identifier Composition Engine (DICE) which provides the context for this document. We'll call this TCG document the TCG DICE specification. Concepts like a Unique Device Secret (UDS) and a Compound Device Identifier (CDI) are used as defined in the TCG DICE specification.
This document uses the term hardware to refer to anything that is immutable by design after manufacturing. Code in mask ROM, for example, is hardware. The terms firmware, software and program are all interchangeable; they all refer to mutable code. Often we say firmware for code that runs early in boot, and program for a particular unit of code, but it's really all software.
For those not familiar with DICE, here is a quick primer on the concepts:
DICE can be implemented with a simple HMAC with the UDS as the key, attributes of the target code or system as the input, and the output is the CDI. However, for a particular implementation there are questions that need to be addressed such as “what is in the input, exactly?”, and “how should we use the CDI once we have it?”. That's where this profile comes in, it fills in many of these details.
This document specifies a DICE profile suitable for use in a variety of products and platforms. The TCG DICE specification intentionally allows for flexibility in implementation; this document specifies many of these implementation details. This document also fills in various details the TCG DICE specification considers out of scope. In particular, this document specifies:
Known specializations of this profile include:
The main goals of this document are:
This document is not intended to:
This architecture diagram shows the first DICE transition from hardware to software, and uses the UDS in the derivation of both the Attestation CDI and Sealing CDI. Subsequent DICE transitions would use the current CDI values in place of the UDS to compute the subsequent CDI values. See Layering Details. See the Cryptography section for details on the primitives referenced in the diagram.
This design is motivated by two use cases: attestation and sealing. Attestation allows a computing device or program to provide verifiable evidence of its identity and operating state, including hardware identity, software image, security-relevant configuration, operating environment, etc. Sealing allows a computing device or program to encrypt data in such a way that it can only be decrypted by the same device or program operating in the same state as at the time of encryption.
With this design, sealing only works well in combination with some kind of verified boot system. For a more sophisticated example of sealing key generation, see Appendix C: Versioned Sealing Keys.
For attestation, DICE inputs should represent all security-relevant properties of the target program. The target program is the program to which control will be passed, along with DICE outputs, after the DICE computations are complete. This profile defines the following types of input, each of which is represented by a fixed length value:
Code (64 bytes) - This input is computed by hashing the target code. This is the traditional input described most clearly in the TCG DICE specification. If a software image is too large to load and hash entirely, then a descriptor of the code (like the root hash of a hash tree) may be used instead. Note that this approach requires additional ongoing enforcement to verify pages as they are loaded. A canonical example of this is dm-verity.
Configuration Data (64 bytes) - This input is a catch-all for any security-relevant configuration or environment properties that characterize the integrity of the system and can be used by an external party to validate its identity and/or its operating state. This may capture verified boot authority selection, device mode, boot location, chip status information, instance identifiers, etc. This value may or may not be a hash of the actual configuration data. When it is a hash, the original data must also be included in certificates. It's ok for this input to be not stable, it may change from one boot to the next.
Authority Data (64 bytes) - This input is computed by hashing a representation of the verified boot trusted authority. For example, this may be a public key, a hash of a public key, or a hash of a descriptor containing a set of public keys. For many SoCs, this representation of the trusted authority is programmed into one-time-programmable (OTP) memory. If a code authorization mechanism is disabled or not supported, this input should be 64 zero bytes. If multiple public keys are supported with runtime selection, this input value must represent all of them. (This is so the value remains stable across a key change, the actual key that was used during boot should be included in the configuration data input value). The authority input value is designed to be stable, it is very unlikely to change during a device lifecycle.
Mode Decision (1 byte) - This input value is a single-byte mode value. Valid mode values are: 0: Not Configured, 1: Normal, 2: Debug, 3: Recovery. The mode is determined at runtime based on the other inputs, and only the other inputs. This input is designed to capture a configuration signal in a stable way, and to reflect important decisions a device makes at runtime. In the sealing use case, this enables data to be sealed separately under each mode. See Mode Value Details.
Hidden Inputs (64 bytes) - This optional input value is hidden in the sense that it does not appear in any certificate. It is used for both attestation and sealing CDI derivation so it is expected to be stable; it should not change under normal operation except when that change is an intentional part of the device lifecycle. If not used, this value should be all zero bytes. While this value can be anything, intended use cases include:
The TCG DICE specification refers to a single CDI, but this profile defines multiple CDIs with different characteristics which can be used for different use cases:
This profile requires the generation of a CDI certificate as part of the DICE flow. The subject key pair is derived from the Attestation CDI value for the target code. The authority key pair which signs the certificate is derived from the UDS or, after the initial hardware to software transition, from the Attestation CDI value for the current code (see Layering Details). The DICE flow outputs the CDI values and the generated certificate; the private key associated with the certificate may be optionally passed along with the CDI values to avoid the need for re-derivation by the target code. The UDS-derived public key is certified by an external authority during manufacturing to complete the certificate chain. See Certificate Details.
As an example, if the CDI private key were used to sign a leaf certificate for an attestation key, the certificate chain may look like this:
The TCG DICE specification outlines a four stage flow: measure, compute CDI, lock UDS, and transfer control. This profile expands on this to include operations for CDI certification. The expanded flow has the following steps:
This profile requires three cryptographic primitives: a hash function, a key derivation function, and an asymmetric digital signature. The recommended defaults are SHA-512, HKDF (using SHA-512) and Ed25519. Since Ed25519 uses SHA-512 under the hood, using this combination means implementing only one hash function. See below for the full list of acceptable algorithms.
The following pseudocode operations are used throughout this document:
# A hash function. The input can be any length. hash = H(input) # Random salt values used as the 'salt' KDF argument (hex encoded). ASYM_SALT = 63B6A04D2C077FC10F639F21DA793844356CC2B0B441B3A77124035C03F8E1BE 6035D31F282821A7450A02222AB1B3CFF1679B05AB1CA5D1AFFB789CCD2B0B3B ID_SALT = DBDBAEBC8020DA9FF0DD5A24C83AA5A54286DFC263031E329B4DA148430659FE 62CDB5B7E1E00FC680306711EB444AF77209359496FCFF1DB9520BA51C7B29EA # A KDF operation with the given desired output length, input key material, # salt, and info. output = KDF(length, ikm, salt, info) # An asymmetric key pair derivation, either Ed25519 or ECDSA. # * The private key is derived using KDF(32, input, ASYM_SALT, "Key Pair"). # * The public key is derived from the private key (per the chosen algorithm). private_key, public_key = ASYM_KDF(input)
Each CDI value is 32 bytes in length and is computed using a KDF operation with the UDS or previous CDI value as the input key material argument and the relevant input measurement as the salt argument. The KDF info argument differs for each type of CDI.
The Attestation CDI input measurement is derived from the combination of all input values. The input values are hashed in this order: code, config, authority, mode, hidden.
CDI_Attest = KDF(32, UDS, H(code + config + authority + mode + hidden), "CDI_Attest")
The Sealing CDI input measurement is similar but is derived from only the stable inputs. The input values are hashed in this order: authority, mode, hidden.
CDI_Seal = KDF(32, UDS, H(authority + mode + hidden), "CDI_Seal")
There are two key pair derivations; one to derive from the UDS, and the other to derive from the Attestation CDI. When deriving from the UDS, the KDF input is simply the UDS.
UDS_Private, UDS_Public = ASYM_KDF(UDS)
When deriving from Attestation CDI, the KDF input is simply the CDI_Attest value.
CDI_Private, CDI_Public = ASYM_KDF(CDI_Attest)
Note: It is important that these two derivations remain consistent except for the input key material; this is what makes layering possible.
There are a few cases where the DICE needs to generate an identifier for use in certificates. To ensure these identifiers are deterministic and require no additional DICE inputs, the identifiers are derived from the associated public key. The identifiers are 20 octets so they fit in the RFC 5280 serialNumber field constraints and the X520SerialNumber type when hex encoded. The big-endian high-order bit is cleared so the ASN.1 integer representation is always positive without padding.
UDS_ID = KDF(20, UDS_Public, ID_SALT, "ID") CDI_ID = KDF(20, CDI_Public, ID_SALT, "ID")
Note: Like the public key derivations, it is important that the ID derivations remain consistent except for the input key material. This is because these are used in certificate issuer and subject fields and need to match when layering.
Acceptable hash algorithms are:
HKDF can be used with any acceptable hash algorithm. The KDF inputs map exactly to HKDF parameters, by design. This is the recommended default.
Per the HKDF specification the extract step can be skipped in some cases, and since all KDFs used in this specification use cryptographically strong ikm values, doing so is acceptable here.
A DRBG can be used to implement the KDF operation. Depending on the DRBG implementation this may require UDS and CDI values larger than 256 bits to provide both nonce and entropy inputs when instantiating the DRBG. The DRBG should be instantiated with a security strength of 256 bits. The sequence of DRBG functions {instantiate, generate, uninstantiate}, are used as a KDF operation. The mapping of inputs is as shown in the following table.
HKDF Input | Corresponding DRBG Input |
---|---|
ikm | Instantiate: Entropy Input and Nonce |
salt | Generate: Additional Input |
info | Instantiate: Personalization String |
The OpenTitan Key Manager can be used as a KDF. See the OpenTitan documentation for details.
The KDFs described in NIST's SP800-108 can be used.
Ed25519 is the recommended default.
When deriving Ed25519 key pairs, using the output of ASYM_KDF directly as the private key is acceptable.
ECDSA can be used instead of Ed25519. When signing the CDI certificate, the random k required by ECDSA may be generated deterministically per RFC6979. One weakness of Ed25519 is that implementations may be susceptible to error injection (example). Another disadvantage of Ed25519 is that it is not [currently] FIPS 140-2 certifiable. In any case, either algorithm is acceptable for this profile.
The following NIST curves are acceptable for use with ECDSA:
When deriving ECDSA key pairs the output of ASYM_KDF cannot be used directly. Following the process described in RFC 6979 is recommended. In this process the seed, in this case the output of ASYM_KDF, is used to seed an HMAC_DRBG instance and then the private key is generated from the DRBG. See the RFC for details.
This DICE profile is designed to be layered. That is, software that receives CDI values can in turn execute a DICE flow using those CDI values in place of the UDS value. The certificate generated by the next DICE layer can chain to the certificate generated by the previous DICE layer because the asymmetric key derivation is consistent across layers for authority and subject keys.
When computing CDI values, the previous Attestation CDI or Sealing CDI is used as the input key material instead of the hardware UDS:
CDI_Attest[n+1] = KDF(32, CDI_Attest[n], H(code + config + authority + mode + hidden), "CDI_Attest") CDI_Seal[n+1] = KDF(32, CDI_Seal[n], H(authority + mode + hidden), "CDI_Seal")
Just like the UDS is locked in the DICE flow, previous layer CDIs must be destroyed, locked, or otherwise protected before control is passed to the next layer. Layer[n+1] must never obtain access to CDI[n] values and must not be able to use CDI[n] in any computation. For example, a layer[n] program cannot offer a service that uses CDI[n] to layer[n+1] programs. In some cases a layer[n] program will stay active and spawn multiple programs (for example, a kernel, TEE, or hypervisor). In these cases the CDI[n] values must be protected from all layer[n+1] programs for the duration they are in operation, and must be destroyed when no longer needed.
When generating certificates, the authority is the previous CDI key pair and the certificates chain together. So the certificate chain may look like this:
In addition to the requirements described in the TCG DICE specification, this profile requires the following:
In this scheme, the UDS and an associated certificate are pre-generated and injected during a manufacturing process in a controlled environment appropriate for the implementation or product. The pre-generation infrastructure does not retain UDS values after provisioning. This approach is designed to balance the risks and costs associated with provisioning between security and scale. Rationale is not described here in detail, but the primary benefits are:
Note: If the UDS is integrated with an SoC at the time of SoC manufacture, the issuer may be the SoC vendor. If the UDS is integrated at the time of device manufacture, the issuer may be the OEM.
In some cases, it may be feasible and preferable to install a CA for UDS provisioning during an SoC or device manufacturing stage. In this scheme, the UDS is derived on-chip from internal and external entropy, at least 256 bits each. Internal entropy may be generated using a PUF, or generated once using an internal hardware TRNG and stored, for example, in OTP memory. External entropy is injected once during manufacturing and stored, for example, in OTP memory. The UDS is derived at runtime on every boot from the combined entropy. The UDS derivation (i.e. conditioning) from internal and external entropy uses a KDF:
UDS = KDF(32, internal_entropy, external_entropy, "UDS")
With this provisioning scheme, the device must output UDS_Public so provisioning software can read the public key and issue a certificate.
All steps occur during manufacturing.
In some cases, the certificate may not need to be stored on the device or the device may not be capable of storing a certificate. In this scheme the UDS is derived in the same way as Provisioning Scheme 2, and the UDS_Public key must similarly be output by the device. A SHA-512 hash of the UDS_Public key is retained in a secure database by the manufacturer.
The manufacturer then operates or coordinates with an online CA to provide on-demand certification of UDS public keys. Acceptable approaches include but are not limited to:
The CA issues certificates for any valid UDS public key without requiring proof-of-possession from the caller, only requiring a signal of approval from the manufacturer. This allows a certificate chain to be requested by a CDI certificate verifier that received an incomplete chain from a device. The UDS certificate may be cached indefinitely by the device or by a verifier.
The following table describes the semantics of each mode.
Mode | Value | Description |
---|---|---|
Not Configured | 0 | This mode indicates that at least one security mechanism has not been configured. This mode also acts as a catch-all for configurations which do not fit the other modes. Invalid mode values -- values not defined here -- should be treated like this mode. |
Normal | 1 | This mode indicates the device is operating normally under secure configuration. This may mean, for example: Verified boot is enabled, verified boot authorities used for development or debug have been disabled, debug ports or other debug facilities have been disabled, and the device booted software from the normal primary source, for example, eMMC, not USB, network, or removable storage. |
Debug | 2 | This mode indicates at least one criteria for Normal mode is not met and the device is not in a secure state. |
Recovery | 3 | This mode indicates a recovery or maintenance mode of some kind. This may mean software is being loaded from an alternate source, or the device is configured to trigger recovery logic instead of a normal boot flow. |
The format and meaning of the 64-byte configuration input value is implementation dependent and may be a hash of more configuration data. Implementers may choose to use the following convention for the configuration input which covers a set of common security-relevant configuration.
Field | Byte/Bits (MSB=0) | Description |
---|---|---|
Verified Boot Enabled | 0/0 | This bit indicates whether a verified boot feature is enabled. The bit is set if enabled, clear if disabled or not supported. |
Verified Boot Authority Enabled | 0/1-7 | These bits indicate which of the verified boot authorities available are enabled. The bit is set if the authority is enabled, clear if disabled. If a verified boot system is disabled or not supported, all bits are clear. The mapping of these bits to particular authorities is implementation dependent. |
Debug Ports Enabled | 1 | The bits of this byte each indicate that a debug port or feature is enabled. A bit is set if the port or feature is enabled, clear if disabled. The mapping of these bits to particular ports or features is implementation dependent. |
Boot Source | 2 | This value indicates the boot source; that is, where the target software was loaded from. The mapping of this value to particular boot sources is implementation dependent but by convention 0 is used for the default boot source. |
Version | 3-4 | This value encodes target software version information. The format and interpretation of this value is implementation dependent. |
Reserved | 5-31 | These are reserved for future versions of this profile. |
Implementation Specific | 32-63 | An implementation can use these bytes to represent any other security-relevant configuration. |
This profile allows for two certificate options: standard X.509, or CBOR. The certificate type does not need to be consistent for all certificates in a certificate chain. Any certificate in the chain may be any type. Attestation infrastructure may place additional constraints on certificate type, but this profile does not.
Regardless of type, UDS and CDI certificates are always semantically CA certificates to enable use cases for certifying subsequent DICE layers or certifying attestation keys of some kind; the UDS_Private and CDI_Private keys are not intended to be used for any purpose other than signing certificates. In particular, this means CDI_Private should not participate directly in attestation protocols, but should rather certify an attestation key. If a target software component does not launch additional software, the pathLenConstraint field can be set to zero so certification of a subsequent CDI_Public is not possible.
When UDS and CDI certificates are standard X.509 certificates, they follow the profile specified in RFC 5280. When they are CBOR, they follow the IETF CBOR Web Token (CWT) specification, and the CBOR Object Signing and Encryption (COSE) specification.
X.509 UDS certificates generally follow RFC 5280. The following table describes all standard fields of a UDS certificate's tbsCertificate field that this profile requires. Fields omitted are implementation dependent, but must not break the ability to chain to a CDI Certificate.
Field | Description |
---|---|
version | v3 |
subject | “SERIALNUMBER=<UDS_ID>” where UDS_ID is hex encoded lower case |
subjectPublicKeyInfo | When using Ed25519, the info per RFC 8410 and RFC 8032 |
extensions | The standard extensions described below are included. |
Extension | Critical | Description |
---|---|---|
subjectKeyIdentifier | non-critical | Set to UDS_ID |
keyUsage | critical | Contains only keyCertSign |
basicConstraints | critical | The cA field is set to TRUE. The pathLenConstraint field is normally not included, but may be included and set to zero if it is known that no additional DICE layers exist. |
X.509 CDI certificates generally follow RFC 5280. All standard fields of a CDI certificate and the tbsCertificate field are described in the following table. Notably, this certificate can be generated deterministically given a CDI_Public key and the DICE input value details.
Field | Description |
---|---|
signatureAlgorithm | When using Ed25519, id-Ed25519 per RFC 8410 |
signatureValue | When using Ed25519, 64 byte Ed25519 signature per RFC 8032, using UDS_Private or the current CDI_Private as the signing key |
version | v3 |
serialNumber | CDI_ID in ASN.1 INTEGER form |
signature | When using Ed25519, id-Ed25519 per RFC 8410 |
issuer | “SERIALNUMBER=<UDS_ID>” where UDS_ID is hex encoded lower case. When layering, UDS_ID becomes CDI_ID of the current layer. |
validity | The DICE is not expected to have a reliable source of time when generating a certificate. The validity values are populated as follows: notBefore can be any time known to be in the past; in the absence of a better value, “180322235959Z” can be used which is the date of publication of the TCG DICE specification, and notAfter is set to the standard value used to indicate no well-known expiry date, “99991231235959Z”. |
subject | “SERIALNUMBER=<CDI_ID>” where CDI_ID is hex encoded lower case. When layering this is the CDI_ID of the next layer. |
subjectPublicKeyInfo | When using Ed25519, the info per RFC 8410 and RFC 8032 |
issuerUniqueID | Omitted |
subjectUniqueID | Omitted |
extensions | Standard extensions are included as well as a custom extension which holds information about the measurements used to derive CDI values. Both are described below. |
Extension | Critical | Description |
---|---|---|
authorityKeyIdentifier | non-critical | Contains only keyIdentifier set to UDS_ID |
subjectKeyIdentifier | non-critical | Set to CDI_ID |
keyUsage | critical | Contains only keyCertSign |
basicConstraints | critical | The cA field is set to TRUE. The pathLenConstraint field is normally not included, but may be included and set to zero if it is known that no additional DICE layers exist. |
Field | Value |
---|---|
extnID | 1.3.6.1.4.1.11129.2.1.24 (The 1.3.6.1.4.1 is the enterprise number, the 11129.2.1 is google.googleSecurity.certificateExtensions, and 24 is diceAttestationData assigned for this profile). |
critical | TRUE |
extnValue | A OpenDiceInput sequence |
The custom extension follows this ASN.1 format:
Mode ::= INTEGER (0..3) OpenDiceInput ::= SEQUENCE { codeHash [0] EXPLICIT OCTET STRING OPTIONAL, codeDescriptor [1] EXPLICIT OCTET STRING OPTIONAL, configurationHash [2] EXPLICIT OCTET STRING OPTIONAL, configurationDescriptor [3] EXPLICIT OCTET STRING OPTIONAL, authorityHash [4] EXPLICIT OCTET STRING OPTIONAL, authorityDescriptor [5] EXPLICIT OCTET STRING OPTIONAL, mode [6] EXPLICIT Mode OPTIONAL, profileName [7] EXPLICIT UTF8String OPTIONAL, }
All fields are explicitly tagged and optional to allow for flexibility and extensibility in the format itself. The actual semantics are as follows:
A CBOR UDS certificate is a standard signed CWT. The following table lists all field constraints required by this profile in addition to the standard. The certificate is untagged, and it must be a COSE_Sign1 message.
Field | Description |
---|---|
iss | Required: The value is implementation dependent. |
sub | Required: The value must be “<UDS_ID>” where UDS_ID is hex encoded lower case. |
The following table lists additional entries in the CWT. Note these have the same labels and semantics as the corresponding fields in CBOR CDI certificates.
Field | CBOR Label |
---|---|
subjectPublicKey | -4670552 |
keyUsage | -4670553 |
The subjectPublicKey field contains the public key associated with the subject in the form of a COSE_Key structure encoded to a CBOR byte string.
The keyUsage field contains a CBOR byte string the bits of which correspond to the X.509 KeyUsage bits in little-endian byte order (i.e. bit 0 is the low-order bit of the first byte). For UDS certificates this should have only the keyCertSign bit set.
A CBOR CDI certificate is a standard signed CWT with additional fields. The certificate is untagged, and it must be a COSE_Sign1 message. The following table lists all constraints on standard fields required by this profile.
Field | Description |
---|---|
iss | Required: The value must be “<UDS_ID>” where UDS_ID is hex encoded lower case. When layering, UDS_ID becomes CDI_ID of the current layer. |
sub | Required: The value must be “<CDI_ID>” where CDI_ID is hex encoded lower case. When layering this is the CDI_ID of the next layer. |
exp | Omitted when a reliable time source is not available |
nbf | Omitted when a reliable time source is not available |
iat | Omitted when a reliable time source is not available |
The following table lists additional entries in the CWT. By convention, the private fields in the map are labeled using negative integers starting at -4670545.
Field | CBOR Label | Major Type |
---|---|---|
codeHash | -4670545 | 2 (bstr) |
codeDescriptor | -4670546 | 2 (bstr) |
configurationHash | -4670547 | 2 (bstr) |
configurationDescriptor | -4670548 | 2 (bstr) |
authorityHash | -4670549 | 2 (bstr) |
authorityDescriptor | -4670550 | 2 (bstr) |
mode | -4670551 | 2 (bstr) |
subjectPublicKey | -4670552 | 2 (bstr) |
keyUsage | -4670553 | 2 (bstr) |
profileName | -4670554 | 3 (tstr) |
The subjectPublicKey field contains the public key associated with the subject in the form of a COSE_Key structure encoded to a CBOR byte string.
The keyUsage field contains a CBOR byte string the bits of which correspond to the X.509 KeyUsage bits in little-endian byte order (i.e. bit 0 is the low-order bit of the first byte). For CDI certificates this should have only the keyCertSign bit set.
All other fields have identical semantics to their counterparts in the X.509 custom extension. The mode field is encoded as a byte string holding a single byte. The advantage of using a byte string as opposed to an integer type is a consistent encoding size for all possible values.
This profile requires hardware changes to implement fully. However, there is still value in implementing it in software on top of existing hardware. Depending on the existing hardware capabilities, the security of the DICE root may be equivalent to a full hardware implementation.
If hardware supports a standard DICE mechanism but does not support this profile directly, this profile can be implemented in firmware and can use the firmware CDI from the standard DICE as a UDS. The provisioned certificate would then cover both the hardware and the firmware implementing this profile.
However, this only works if the firmware that implements this profile is unmodified during normal operation. It becomes a ROM extension in the sense that if it is modified, the firmware CDI changes, and the certificate chain provisioned for the device is no longer valid. In an ARM Trusted Firmware architecture, it would likely be BL2 firmware that implements this profile.
If the firmware implementing this profile is the first firmware to run on the system, this approach has equivalent security to a full hardware implementation.
If hardware supports a lockable persistent storage mechanism early in boot, this profile can be implemented in firmware and can use a secret stored using this mechanism as a UDS. This firmware should run as early in boot as possible. The storage could be lockable OTP memory, lockable NVRAM, a one-time derivation, or similar. Security chips like a TPM or SE often have an appropriate capability.
However, this only works along with a robust verified boot system to verify the firmware that implements this profile and any other firmware that runs before it. It also has the downside that changes to the firmware, or any other firmware that runs before it, are not reflected in the CDIs.
The security of this approach is not equivalent to a full hardware implementation, but may still be acceptable for many applications. If the firmware implementing this profile is the first firmware to run on the system, this approach has equivalent security to a full hardware implementation which employs a hardware modification mechanism like an FPGA or microcode.
This approach can also be used later in boot, for example in a TEE. However, the more code that runs without being covered by a DICE flow, the lower the security of the implementation.
With a robust verified boot system, there are many other possible implementations as long as (1) A UDS can be made available by some means early in boot, and (2) that UDS can be made subsequently unavailable until the next boot. These implementations meet the requirements of the TCG DICE specification as an updatable DICE per section 6.2.
The following is a list of capabilities that a full hardware implementation must have. This is intended for the convenience of hardware designers, and is not intended to add any additional requirements or constraints.
A versioned sealing key is a key that is derived from a secret seed and one or more software versions. The versions cannot be higher than the current software version. In other words, a versioned sealing key can be derived for the current software version and each previous version, but not for future versions. These keys can be used to seal data in a rollback-protected way, that is, in a way that current and future software can unseal but older software cannot. Each time software is upgraded, the data can be re-sealed to be bound to the latest version.
The Sealing CDIs derived by using DICE in layers as described in this profile are not versioned; rather they are stable across versions. To achieve versioned sealing keys, an additional hardware mechanism is required: a versioned KDF (V-KDF). There are many possible implementations but in general it must be possible to seed the V-KDF with one or more secrets that it will not expose, and one or more maximum versions that it will not allow to be subsequently modified. After seeding, the V-KDF accepts version info as input (likely along with other inputs), and the output is a key that may be used as a versioned sealing key.
Given such a V-KDF, versioned keys can be derived from a Sealing CDI by adding a few steps to precede the DICE flow:
VKDF_SEED = KDF(32, CDI_Seal_or_UDS, H(authority + mode + hidden), "VKDF_SEED")
Note that the V-KDF seed is derived from the current sealing CDI; this value is not passed to target code but is locked / destroyed as part of the DICE flow. As a result the target code can only generate versioned keys as seeded by the previous layer.
When multiple layers are involved, the V-KDF should use the seed inputs cumulatively: