This document is a proposed interface for deciding at build time which cryptographic mechanisms to include in the PSA Cryptography interface.
This is currently a proposal for Mbed TLS. It is not currently on track for standardization in PSA.
Time-stamp: “2020/11/26 09:30:50 GMT”
The PSA Cryptography API specification specifies the interface between a PSA Cryptography implementation and an application. The interface defines a number of categories of cryptographic algorithms (hashes, MAC, signatures, etc.). In each category, a typical implementation offers many algorithms (e.g. for signatures: RSA-PKCS#1v1.5, RSA-PSS, ECDSA). When building the implementation for a specific use case, it is often desirable to include only a subset of the available cryptographic mechanisms, primarily in order to reduce the code footprint of the compiled system.
The present document proposes a way for an application using the PSA cryptography interface to declare which mechanisms it requires.
Mbed TLS offers a way to select which cryptographic mechanisms are included in a build through its configuration file (config.h
). This mechanism is based on two main sets of symbols: MBEDTLS_xxx_C
controls the availability of the mechanism to the application, and MBEDTLS_xxx_ALT
controls the availability of an alternative implementation, so the software implementation is only included if MBEDTLS_xxx_C
is defined but not MBEDTLS_xxx_ALT
.
In the PSA cryptography interface, the core (built-in implementations of cryptographic mechanisms) can be augmented with drivers. Transparent drivers replace the built-in implementation of a cryptographic mechanism (or, with fallback, the built-in implementation is tried if the driver only has partial support for the mechanism). Opaque drivers implement cryptographic mechanisms on keys which are stored in a separate domain such as a secure element, for which the core only does key management and dispatch using wrapped key blobs or key identifiers.
The current model is difficult to adapt to the PSA interface for several reasons. The MBEDTLS_xxx_ALT
symbols are somewhat inconsistent, and in particular do not work well for asymmetric cryptography. For example, many parts of the ECC code have no MBEDTLS_xxx_ALT
symbol, so a platform with ECC acceleration that can perform all ECDSA and ECDH operations in the accelerator would still embark the bignum
module and large parts of the ecp_curves
, ecp
and ecdsa
modules. Also the availability of a transparent driver for a mechanism does not translate directly to MBEDTLS_xxx
symbols.
[Req.interface] The application can declare which cryptographic mechanisms it needs.
[Req.inclusion] If the application does not require a mechanism, a suitably configured Mbed TLS build must not include it. The granularity of mechanisms must work for typical use cases and has acceptable limitations.
[Req.drivers] If a PSA driver is available in the build, a suitably configured Mbed TLS build must not include the corresponding software code (unless a software fallback is needed).
[Req.c] The configuration mechanism consists of C preprocessor definitions, and the build does not require tools other than a C compiler. This is necessary to allow building an application and Mbed TLS in development environments that do not allow third-party tools.
[Req.adaptability] The implementation of the mechanism must be adaptable with future evolution of the PSA cryptography specifications and Mbed TLS. Therefore the interface must remain sufficiently simple and abstract.
[Limitation.matrix] If a mechanism is defined by a combination of algorithms and key types, for example a block cipher mode (CBC, CTR, CFB, …) and a block permutation (AES, CAMELLIA, ARIA, …), there is no requirement to include only specific combinations.
[Limitation.direction] For mechanisms that have multiple directions (for example encrypt/decrypt, sign/verify), there is no requirement to include only one direction.
[Limitation.size] There is no requirement to include only support for certain key sizes.
[Limitation.multipart] Where there are multiple ways to perform an operation, for example single-part and multi-part, there is no mechanism to select only one or a subset of the possible ways.
The PSA Crypto configuration file psa/crypto_config.h
defines a series of symbols of the form PSA_WANT_xxx
where xxx
describes the feature that the symbol enables. The symbols are documented in the section “PSA Crypto configuration symbols” below.
The symbol MBEDTLS_PSA_CRYPTO_CONFIG
in mbedtls/config.h
determines whether psa/crypto_config.h
is used.
MBEDTLS_PSA_CRYPTO_CONFIG
is unset, which is the default at least in Mbed TLS 2.x versions, things are as they are today: the PSA subsystem includes generic code unconditionally, and includes support for specific mechanisms conditionally based on the existing MBEDTLS_xxx_
symbols.MBEDTLS_PSA_CRYPTO_CONFIG
is set, the necessary software implementations of cryptographic algorithms are included based on both the content of the PSA Crypto configuration file and the Mbed TLS configuration file. For example, the code in aes.c
is enabled if either mbedtls/config.h
contains MBEDTLS_AES_C
or psa/crypto_config.h
contains PSA_WANT_KEY_TYPE_AES
.A PSA Crypto configuration symbol is a C preprocessor symbol whose name starts with PSA_WANT_
.
1
, the corresponding feature is included.The presence of a symbol PSA_WANT_xxx
in the Mbed TLS configuration determines whether a feature is available through the PSA API. These symbols should be used in any place that requires conditional compilation based on the availability of a cryptographic mechanism through the PSA API, including:
MBEDTLS_USE_PSA_CRYPTO
, for example in TLS to determine which cipher suites to enable.If a feature is not requested for inclusion in the PSA Crypto configuration file, it may still be included in the build, either because the feature has been requested in some other way, or because the library does not support the exclusion of this feature. Mbed TLS should make a best effort to support the exclusion of all features, but in some cases this may be judged too much effort for too little benefit.
For each constant or constructor macro of the form PSA_KEY_TYPE_xxx
, the symbol PSA_WANT_KEY_TYPE_xxx
indicates that support for this key type is desired.
For asymmetric cryptography, PSA_WANT_KEY_TYPE_xxx_KEY_PAIR
determines whether private-key operations are desired, and PSA_WANT_KEY_TYPE_xxx_PUBLIC_KEY
determines whether public-key operations are desired. PSA_WANT_KEY_TYPE_xxx_KEY_PAIR
implicitly enables PSA_WANT_KEY_TYPE_xxx_PUBLIC_KEY
: there is no way to only include private-key operations (which typically saves little code).
For elliptic curve key types, only the specified curves are included. To include a curve, include a symbol of the form PSA_WANT_ECC_family_size
. For example: PSA_WANT_ECC_SECP_R1_256
for secp256r1, PSA_WANT_ECC_MONTGOMERY_CURVE25519
. It is an error to require an ECC key type but no curve, and Mbed TLS will reject this at compile time.
For each constant or constructor macro of the form PSA_ALG_xxx
, the symbol PSA_WANT_ALG_xxx
indicates that support for this algorithm is desired.
For parametrized algorithms, the PSA_WANT_ALG_xxx
symbol indicates whether the base mechanism is supported. Parameters must themselves be included through their own PSA_WANT_ALG_xxx
symbols. It is an error to include a base mechanism without at least one possible parameter, and Mbed TLS will reject this at compile time. For example, PSA_WANT_ALG_ECDSA
requires the inclusion of randomized ECDSA for all hash algorithms whose corresponding symbol PSA_WANT_ALG_xxx
is enabled.
In addition to the configuration symbols, we need two parallel or mostly parallel sets of symbols:
MBEDTLS_PSA_ACCEL_xxx
indicates whether a fully-featured, fallback-free transparent driver is available.MBEDTLS_PSA_BUILTIN_xxx
indicates whether the software implementation is needed.MBEDTLS_PSA_ACCEL_xxx
is one of the outputs of the transpilation of a driver description, alongside the glue code for calling the drivers.
MBEDTLS_PSA_BUILTIN_xxx
is enabled when PSA_WANT_xxx
is enabled and MBEDTLS_PSA_ACCEL_xxx
is disabled.
These symbols are not part of the public interface of Mbed TLS towards applications or to drivers, regardless of whether the symbols are actually visible.
When MBEDTLS_PSA_CRYPTO_CONFIG
is set, the header file mbedtls/config.h
needs to define all the MBEDTLS_xxx_C
configuration symbols, including the ones deduced from the PSA Crypto configuration. It does this by including the new header file mbedtls/config_psa.h
, which defines the MBEDTLS_PSA_BUILTIN_xxx
symbols and deduces the corresponding MBEDTLS_xxx_C
(and other) symbols.
mbedtls/config_psa.h
includes psa/crypto_config.h
, the user-editable file that defines application requirements.
When MBEDTLS_PSA_CRYPTO_CONFIG
is not set, the configuration of Mbed TLS works as before, and the inclusion of non-PSA code only depends on MBEDTLS_xxx
symbols defined (or not) in mbedtls/config.h
. Furthermore, the new header file mbedtls/config_psa.h
deduces PSA configuration symbols (PSA_WANT_xxx
, MBEDTLS_PSA_BUILTIN_xxx
) from classic configuration symbols (MBEDTLS_xxx
).
The PSA_WANT_xxx
definitions in mbedtls/config_psa.h
are needed not only to build the PSA parts of the library, but also to build code that uses these parts. This includes structure definitions in psa/crypto_struct.h
, size calculations in psa/crypto_sizes.h
, and application code that's specific to a given cryptographic mechanism. In Mbed TLS itself, code under MBEDTLS_USE_PSA_CRYPTO
and conditional compilation guards in tests and sample programs need PSA_WANT_xxx
.
Since some existing applications use a handwritten mbedtls/config.h
or an edited copy of mbedtls/config.h
from an earlier version of Mbed TLS, mbedtls/config_psa.h
must be included via an already existing header that is not mbedtls/config.h
, so it is included via psa/crypto.h
(for example from psa/crypto_platform.h
).
Whether MBEDTLS_PSA_CRYPTO_CONFIG
is set or not, mbedtls/config_psa.h
includes mbedtls/crypto_drivers.h
, a header file generated by the transpilation of the driver descriptions. It defines MBEDTLS_PSA_ACCEL_xxx
symbols according to the availability of transparent drivers without fallback.
The following table summarizes where symbols are defined depending on the configuration mode.
Symbols | With MBEDTLS_PSA_CRYPTO_CONFIG | Without MBEDTLS_PSA_CRYPTO_CONFIG |
---|---|---|
MBEDTLS_xxx_C | mbedtls/config.h (U) or | mbedtls/config.h (U) |
mbedtls/config_psa.h (D) | ||
PSA_WANT_xxx | psa/crypto_config.h (U) | mbedtls/config_psa.h (D) |
MBEDTLS_PSA_BUILTIN_xxx | mbedtls/config_psa.h (D) | mbedtls/config_psa.h (D) |
MBEDTLS_PSA_ACCEL_xxx | mbedtls/crypto_drivers.h (G) | N/A |
Ideally, the MBEDTLS_PSA_ACCEL_xxx
and MBEDTLS_PSA_BUILTIN_xxx
symbols should not be visible to application code or driver code, since they are not part of the public interface of the library. However these symbols are needed to deduce whether to include library modules (for example MBEDTLS_AES_C
has to be enabled if MBEDTLS_PSA_BUILTIN_KEY_TYPE_AES
is enabled), which makes it difficult to keep them private.
The header file library/psa_check_config.h
applies sanity checks to the configuration, throwing #error
if something is wrong.
A mechanism similar to mbedtls/check_config.h
detects errors such as enabling ECDSA but no curve.
Since configuration symbols must be undefined or 1, any other value should trigger an #error
.
A lot of the preprocessor symbol manipulation is systematic calculations that analyze the configuration. mbedtls/config_psa.h
and library/psa_check_config.h
should be generated automatically, in the same manner as version_features.c
.
An entry point can be eliminated entirely if no algorithm requires it.
Code that is specific to certain key types or to certain algorithms must be guarded by the applicable symbols: PSA_WANT_xxx
for code that is independent of the application, and MBEDTLS_PSA_BUILTIN_xxx
for code that calls an Mbed TLS software implementation.
At the time of writing, the preferred configuration mechanism for a PSA service is in JSON syntax. The translation from JSON to build instructions is not specified by PSA.
For PSA Crypto, the preferred configuration mechanism would be similar to capability specifications of transparent drivers. The same JSON properties that are used to mean “this driver can perform that mechanism” in a driver description would be used to mean “the application wants to perform that mechanism” in the application configuration.
The JSON capability language allows a more fine-grained selection than the C mechanism proposed here. For example, it allows requesting only single-part mechanisms, only certain key sizes, or only certain combinations of algorithms and key types.
The JSON capability language can be translated approximately to the boolean symbol mechanism proposed here. The approximation considers a feature to be enabled if any part of it is enabled. For example, if there is a capability for AES-CTR and one for CAMELLIA-GCM, the translation to boolean symbols will also include AES-GCM and CAMELLIA-CTR. If there is a capability for AES-128, the translation will also include AES-192 and AES-256.
The boolean symbol mechanism proposed here can be translated to a list of JSON capabilities: for each included algorithm, include a capability with that algorithm, the key types that apply to that algorithm, no size restriction, and all the entry points that apply to that algorithm.
The names of elliptic curve symbols are a bit weird: SECP_R1_256
instead of SECP256R1
. Should we make them more classical, but less systematic?
What does it mean to have PSA_WANT_ALG_ECDSA
enabled but with only Curve25519? Is it a mandatory error?
Way to request only specific groups? Not a priority: constrained devices don't do FFDH. Specify it as may change in future versions.
The two mechanisms have very different designs. Is there serious potential for confusion? Do we understand how the combinations work?
Is it realistic to mandate a compile-time error if a key type is required, but no matching algorithm, or vice versa? Is it always the right thing, for example if there is an opaque driver that manipulates this key type?
If a mechanism should only be supported in an opaque driver, what does the core need to know about it? Do we have all the information we need?
This is especially relevant to suppress a mechanism completely if there is no matching algorithm. For example, if there is no transparent implementation of RSA or ECDSA, psa_sign_hash
and psa_verify_hash
may still be needed if there is an opaque signature driver.
Is this proposal decently testable? There are a lot of combinations. What combinations should we test?