docs/use-psa-crypto.md - mirror/mbed-tls - TrustedFirmware Git Browser

 This document describes the compile-time configuration option
 `MBEDTLS_USE_PSA_CRYPTO` from a user's perspective, more specifically its
 current effects as well as the parts that aren't covered yet.

 Current effects
 ===============

 General limitations
 -------------------

 Compile-time: enabling `MBEDTLS_USE_PSA_CRYPTO` requires
 `MBEDTLS_ECP_RESTARTABLE` and
 `MBEDTLS_PSA_CRYPTO_KEY_ID_ENCODES_OWNER` to be disabled.

 Effect: `MBEDTLS_USE_PSA_CRYPTO` currently has no effect on TLS 1.3 (which is
 itself experimental and only partially supported so far): TLS 1.3 always uses
 the legacy APIs even when this option is set.

 Stability: any API that's only available when `MBEDTLS_USE_PSA_CRYPTO` is
 defined is considered experimental and may change in incompatible ways at any
 time. Said otherwise, these APIs are explicitly excluded from the usual API
 stability promises.

 New APIs / API extensions
 -------------------------

 Some of these APIs are meant for the application to use in place of
 pre-existing APIs, in order to get access to the benefits; in the sub-sections
 below these are indicated by "Use in (X.509 and) TLS: opt-in", meaning that
 this requires changes to the application code for the (X.509 and) TLS layers
 to pick up the improvements.

 Some of these APIs are mostly meant for internal use by the TLS (and X.509)
 layers; they are indicated below by "Use in (X.509 and) TLS: automatic",
 meaning that no changes to the application code are required for the TLS (and
 X.509) layers to pick up the improvements.

 ### PSA-held (opaque) keys in the PK layer

 There is a new API function `mbedtls_pk_setup_opaque()` that can be used to
 wrap a PSA keypair into a PK context. The key can be used for private-key
 operations and its public part can be exported.

 Benefits: isolation of long-term secrets, use of PSA Crypto drivers.

 Limitations: only for private keys, only ECC. (That is, only ECDSA signature
 generation. Note: currently this will use randomized ECDSA while Mbed TLS uses
 deterministic ECDSA by default.) The following operations are not supported
 with a context set this way, while they would be available with a normal
 `ECKEY` context: `mbedtls_pk_verify()`, `mbedtls_pk_check_pair()`,
 `mbedtls_pk_debug()`.

 Use in X.509 and TLS: opt-in. The application needs to construct the PK context
 using the new API in order to get the benefits; it can then pass the
 resulting context to the following existing APIs:

 - `mbedtls_ssl_conf_own_cert()` or `mbedtls_ssl_set_hs_own_cert()` to use the
   key together with a certificate for ECDSA-based key exchanges (note: while
 this is supported on both sides, it's currently only tested client-side);
 - `mbedtls_x509write_csr_set_key()` to generate a CSR (certificate signature
   request).

 In the TLS and X.509 API, there are two other functions which accept a key or
 keypair as a PK context: `mbedtls_x509write_crt_set_subject_key()` and
 `mbedtls_x509write_crt_set_issuer_key()`. Use of opaque contexts here probably
 works but is so far untested.

 ### PSA-held (opaque) keys for TLS pre-shared keys (PSK)

 There are two new API functions `mbedtls_ssl_conf_psk_opaque()` and
 `mbedtls_ssl_set_hs_psk_opaque()`. Call one of these from an application to
 register a PSA key for use with a PSK key exchange.

 Benefits: isolation of long-term secrets.

 Limitations: the key can only be used with "pure"
 PSK key exchanges (ciphersuites starting with `TLS_PSK_WITH_`), to the
 exclusion of RSA-PSK, DHE-PSK and ECDHE-PSK key exchanges. It is the responsibility of
 the user to make sure that when provisioning an opaque pre-shared key, the
 only PSK ciphersuites that can be negotiated are "pure" PSK; other XXX-PSK key
 exchanges will result in a handshake failure with the handshake function
 returning `MBEDTLS_ERR_SSL_FEATURE_UNAVAILABLE`.

 Use in TLS: opt-in. The application needs to register the key using the new
 APIs to get the benefits.

 ### PSA-based operations in the Cipher layer

 There is a new API function `mbedtls_cipher_setup_psa()` to set up a context
 that will call PSA to store the key and perform the operations.

 Benefits: use of PSA Crypto drivers; partial isolation of short-term secrets
 (still generated outside of PSA, but then held by PSA).

 Limitations: the key is still passed in the clear by the application. The
 multi-part APIs are not supported, only the one-shot APIs. The only modes
 supported are ECB, CBC without padding, GCM and CCM (this excludes stream
 ciphers and ChachaPoly); the only cipher supported is AES (this excludes Aria,
 Camellia, and ChachaPoly). (Note: ECB is currently not tested.) (Note: it is
 possible to perform multiple one-shot operations with the same context;
 however this is not unit-tested, only tested via usage in TLS.)

 Use in TLS: automatic. Used when the cipher and mode is supported (with
 gracious fallback to the legacy API otherwise) in all places where a cipher is
 used. There are two such places: in `ssl_tls.c` for record protection, and in
 `ssl_ticket.c` for protecting tickets we issue.

 Internal changes
 ----------------

 All of these internal changes are active as soon as `MBEDTLS_USE_PSA_CRYPTO`
 is enabled, no change required on the application side.

 ### TLS: cipher operations based on PSA

 See "PSA-based operations in the Cipher layer" above.

 ### PK layer: ECDSA verification based on PSA

 Scope: `mbedtls_pk_verify()` will call to PSA for ECDSA signature
 verification.

 Benefits: use of PSA Crypto drivers.

 Use in TLS and X.509: in all places where an ECDSA signature is verified.

 ### TLS: ECDHE computation based on PSA

 Scope: Client-side, for ECDHE-RSA and ECDHE-ECDSA key exchanges, the
 computation of the ECDHE key exchange is done by PSA.

 Limitations: client-side only, ECDHE-PSK not covered

 Benefits: use of PSA Crypto drivers.

 ### TLS: handshake hashes and PRF computed with PSA

 Scope: with TLS 1.2, the following are computed with PSA:
 - the running handshake hashes;
 - the hash of the ServerKeyExchange part that is signed;
 - the `verify_data` part of the Finished message;
 - the TLS PRF.

 Benefits: use of PSA Crypto drivers.

 ### X.509: some hashes computed with PSA

 Scope: the following hashes are computed with PSA:
 - when verifying a certificate chain, hash of the child for verifying the
   parent's signature;
 - when writing a CSR, hash of the request for self-signing the request.

 Benefits: use of PSA Crypto drivers.

 Parts that are not covered yet
 ==============================

 This is only a high-level overview, grouped by theme

 TLS: 1.3 experimental support
 -----------------------------

 No part of the experimental support for TLS 1.3 is covered at the moment.

 TLS: key exchanges / asymmetric crypto
 --------------------------------------

 The following key exchanges are not covered at all:

 - RSA
 - DHE-RSA
 - DHE-PSK
 - RSA-PSK
 - ECDHE-PSK
 - ECDH-RSA
 - ECDH-ECDSA
 - ECJPAKE

 The following key exchanges are only partially covered:

 - ECDHE-RSA: RSA operations are not covered and, server-side, the ECDHE
   operation isn't either
 - ECDHE-ECDSA: server-side, the ECDHE operation isn't covered. (ECDSA
   signature generation is only covered if using `mbedtls_pk_setup_opaque()`.)

 PSK if covered when the application uses `mbedtls_ssl_conf_psk_opaque()` or
 `mbedtls_ssl_set_hs_psk_opaque()`.

 TLS: symmetric crypto
 ---------------------

 - some ciphers not supported via PSA yet: ARIA, Camellia, ChachaPoly (silent
   fallback to the legacy APIs)
 - the HMAC part of the CBC and NULL ciphersuites
 - the HMAC computation in `ssl_cookie.c`

 X.509
 -----

 - most hash operations are still done via the legacy API, except the few that
   are documented above as using PSA
 - RSA PKCS#1 v1.5 signature generation (from PSA-held keys)
 - RSA PKCS#1 v1.5 signature verification
 - RSA-PSS signature verification
	This document describes the compile-time configuration option
	`MBEDTLS_USE_PSA_CRYPTO` from a user's perspective, more specifically its
	current effects as well as the parts that aren't covered yet.

	Current effects
	===============

	General limitations
	-------------------

	Compile-time: enabling `MBEDTLS_USE_PSA_CRYPTO` requires
	`MBEDTLS_ECP_RESTARTABLE` and
	`MBEDTLS_PSA_CRYPTO_KEY_ID_ENCODES_OWNER` to be disabled.

	Effect: `MBEDTLS_USE_PSA_CRYPTO` currently has no effect on TLS 1.3 (which is
	itself experimental and only partially supported so far): TLS 1.3 always uses
	the legacy APIs even when this option is set.

	Stability: any API that's only available when `MBEDTLS_USE_PSA_CRYPTO` is
	defined is considered experimental and may change in incompatible ways at any
	time. Said otherwise, these APIs are explicitly excluded from the usual API
	stability promises.

	New APIs / API extensions
	-------------------------

	Some of these APIs are meant for the application to use in place of
	pre-existing APIs, in order to get access to the benefits; in the sub-sections
	below these are indicated by "Use in (X.509 and) TLS: opt-in", meaning that
	this requires changes to the application code for the (X.509 and) TLS layers
	to pick up the improvements.

	Some of these APIs are mostly meant for internal use by the TLS (and X.509)
	layers; they are indicated below by "Use in (X.509 and) TLS: automatic",
	meaning that no changes to the application code are required for the TLS (and
	X.509) layers to pick up the improvements.

	### PSA-held (opaque) keys in the PK layer

	There is a new API function `mbedtls_pk_setup_opaque()` that can be used to
	wrap a PSA keypair into a PK context. The key can be used for private-key
	operations and its public part can be exported.

	Benefits: isolation of long-term secrets, use of PSA Crypto drivers.

	Limitations: only for private keys, only ECC. (That is, only ECDSA signature
	generation. Note: currently this will use randomized ECDSA while Mbed TLS uses
	deterministic ECDSA by default.) The following operations are not supported
	with a context set this way, while they would be available with a normal
	`ECKEY` context: `mbedtls_pk_verify()`, `mbedtls_pk_check_pair()`,
	`mbedtls_pk_debug()`.

	Use in X.509 and TLS: opt-in. The application needs to construct the PK context
	using the new API in order to get the benefits; it can then pass the
	resulting context to the following existing APIs:

	- `mbedtls_ssl_conf_own_cert()` or `mbedtls_ssl_set_hs_own_cert()` to use the
	key together with a certificate for ECDSA-based key exchanges (note: while
	this is supported on both sides, it's currently only tested client-side);
	- `mbedtls_x509write_csr_set_key()` to generate a CSR (certificate signature
	request).

	In the TLS and X.509 API, there are two other functions which accept a key or
	keypair as a PK context: `mbedtls_x509write_crt_set_subject_key()` and
	`mbedtls_x509write_crt_set_issuer_key()`. Use of opaque contexts here probably
	works but is so far untested.

	### PSA-held (opaque) keys for TLS pre-shared keys (PSK)

	There are two new API functions `mbedtls_ssl_conf_psk_opaque()` and
	`mbedtls_ssl_set_hs_psk_opaque()`. Call one of these from an application to
	register a PSA key for use with a PSK key exchange.

	Benefits: isolation of long-term secrets.

	Limitations: the key can only be used with "pure"
	PSK key exchanges (ciphersuites starting with `TLS_PSK_WITH_`), to the
	exclusion of RSA-PSK, DHE-PSK and ECDHE-PSK key exchanges. It is the responsibility of
	the user to make sure that when provisioning an opaque pre-shared key, the
	only PSK ciphersuites that can be negotiated are "pure" PSK; other XXX-PSK key
	exchanges will result in a handshake failure with the handshake function
	returning `MBEDTLS_ERR_SSL_FEATURE_UNAVAILABLE`.

	Use in TLS: opt-in. The application needs to register the key using the new
	APIs to get the benefits.

	### PSA-based operations in the Cipher layer

	There is a new API function `mbedtls_cipher_setup_psa()` to set up a context
	that will call PSA to store the key and perform the operations.

	Benefits: use of PSA Crypto drivers; partial isolation of short-term secrets
	(still generated outside of PSA, but then held by PSA).

	Limitations: the key is still passed in the clear by the application. The
	multi-part APIs are not supported, only the one-shot APIs. The only modes
	supported are ECB, CBC without padding, GCM and CCM (this excludes stream
	ciphers and ChachaPoly); the only cipher supported is AES (this excludes Aria,
	Camellia, and ChachaPoly). (Note: ECB is currently not tested.) (Note: it is
	possible to perform multiple one-shot operations with the same context;
	however this is not unit-tested, only tested via usage in TLS.)

	Use in TLS: automatic. Used when the cipher and mode is supported (with
	gracious fallback to the legacy API otherwise) in all places where a cipher is
	used. There are two such places: in `ssl_tls.c` for record protection, and in
	`ssl_ticket.c` for protecting tickets we issue.

	Internal changes
	----------------

	All of these internal changes are active as soon as `MBEDTLS_USE_PSA_CRYPTO`
	is enabled, no change required on the application side.

	### TLS: cipher operations based on PSA

	See "PSA-based operations in the Cipher layer" above.

	### PK layer: ECDSA verification based on PSA

	Scope: `mbedtls_pk_verify()` will call to PSA for ECDSA signature
	verification.

	Benefits: use of PSA Crypto drivers.

	Use in TLS and X.509: in all places where an ECDSA signature is verified.

	### TLS: ECDHE computation based on PSA

	Scope: Client-side, for ECDHE-RSA and ECDHE-ECDSA key exchanges, the
	computation of the ECDHE key exchange is done by PSA.

	Limitations: client-side only, ECDHE-PSK not covered

	Benefits: use of PSA Crypto drivers.

	### TLS: handshake hashes and PRF computed with PSA

	Scope: with TLS 1.2, the following are computed with PSA:
	- the running handshake hashes;
	- the hash of the ServerKeyExchange part that is signed;
	- the `verify_data` part of the Finished message;
	- the TLS PRF.

	Benefits: use of PSA Crypto drivers.

	### X.509: some hashes computed with PSA

	Scope: the following hashes are computed with PSA:
	- when verifying a certificate chain, hash of the child for verifying the
	parent's signature;
	- when writing a CSR, hash of the request for self-signing the request.

	Benefits: use of PSA Crypto drivers.

	Parts that are not covered yet
	==============================

	This is only a high-level overview, grouped by theme

	TLS: 1.3 experimental support
	-----------------------------

	No part of the experimental support for TLS 1.3 is covered at the moment.

	TLS: key exchanges / asymmetric crypto
	--------------------------------------

	The following key exchanges are not covered at all:

	- RSA
	- DHE-RSA
	- DHE-PSK
	- RSA-PSK
	- ECDHE-PSK
	- ECDH-RSA
	- ECDH-ECDSA
	- ECJPAKE

	The following key exchanges are only partially covered:

	- ECDHE-RSA: RSA operations are not covered and, server-side, the ECDHE
	operation isn't either
	- ECDHE-ECDSA: server-side, the ECDHE operation isn't covered. (ECDSA
	signature generation is only covered if using `mbedtls_pk_setup_opaque()`.)

	PSK if covered when the application uses `mbedtls_ssl_conf_psk_opaque()` or
	`mbedtls_ssl_set_hs_psk_opaque()`.

	TLS: symmetric crypto
	---------------------

	- some ciphers not supported via PSA yet: ARIA, Camellia, ChachaPoly (silent
	fallback to the legacy APIs)
	- the HMAC part of the CBC and NULL ciphersuites
	- the HMAC computation in `ssl_cookie.c`

	X.509
	-----

	- most hash operations are still done via the legacy API, except the few that
	are documented above as using PSA
	- RSA PKCS#1 v1.5 signature generation (from PSA-held keys)
	- RSA PKCS#1 v1.5 signature verification
	- RSA-PSS signature verification