View Source ssl (ssl v11.2.4)

Interface functions for TLS (Transport Layer Security) and DTLS (Datagram Transport Layer Security).

Note

The application's name is still SSL because the first versions of the TLS protocol were named SSL (Secure Socket Layer). However, no version of the old SSL protocol is supported by this application.

Example:

1> ssl:start(), ssl:connect("google.com", 443, [{verify, verify_peer},
    {cacerts, public_key:cacerts_get()}]).
{ok,{sslsocket, [...]}}

See Examples for detailed usage and more examples of this API.

Special Erlang node configuration for the application can be found in SSL Application.

Summary

Types: Socket

The type for the messages that are delivered to the owner of a TLS/DTLS socket in active mode.

A DTLS protocol version that are no longer supported by default for security reasons.

DTLS protocol version.

If a TLS connection fails a TLS protocol ALERT will be sent/received.

A name or address to a host.

Client hello extensions.

TLS or DTLS protocol version.

Error reason for debug purposes.

Identifies a TLS session prior to TLS-1.3.

A socket that can be used to perform a so-called "START-TLS", which means using an already connected socket previously used for plain TCP traffic and upgrading it to use TLS.

Options for the transport socket.

An opaque reference to the TLS/DTLS connection.

TLS Alert Protocol reasons.

An option that can be supplied to a TLS client.

A TLS protocol version that are no longer supported by default for security reasons.

An option related to the TLS/DTLS protocol.

An option that can be supplied to a TLS server.

TLS protocol version.

Transport option defines a callback module and message tags to handle the underlying transport socket.

Types: Algorithms

Cipher algorithms that can be used for payload encryption.

Filter that allows you to customize cipher suite list.

A list of cipher suites that should be supported.

Cipher suite formats.

Erlang cipher suite representation

TLS-1.3 key exchange configuration.

Hash algorithms used together with signing and encryption functions.

Cipher Suite Key Exchange Algorithm will be any in TLS-1.3 as key exchange is no longer part of cipher suite configuration in TLS-1.3.

Key exchange configuration prior to TLS-1.3.

Supported in TLS-1.3 and TLS-1.2.

SHA2 hash algorithms.

Signature algorithms.

Signature schemes, defined by TLS-1.3, and replacing signature algorithms from TLS-1.2.

Explicitly list acceptable signature algorithms for certificates and handshake messages in the preferred order.

SRP cipher suite configuration prior to TLS-1.3.

Types: Certificates

Claim an intermediate CA in the chain as trusted.

Configuration of the entity certificate and its corresponding key.

Options for using built-in CRL cache support.

The user's private key.

Types: Algorithms Legacy

Cipher algorithms that are no longer supported by default for security reasons.

Hash algorithms that are no longer supported by default for security reasons.

Key exchange configuration prior to TLS-1.3.

Signature algorithms that are no longer supported by default for security reasons.

This is only used for certificate signatures if TLS-1.2 is negotiated, meaning that the peer only supports TLS-1.2, but we also support TLS-1.3.

For backwards compatibility only; do not use.

Types: Client Options

The following options are specific to the client side, or have different semantics for the client and server

Certificate-related options specific to the client side, or with different semantics for the client and server.

Legacy client options.

Options only relevant to TLS versions prior to TLS-1.3.

Options only relevant for TLS-1.3.

Types: Server Options

Options specific to the server side, or with different semantics for the client and server.

Certificate related options for a server.

Legacy server options.

Options only relevant to TLS versions prior to TLS-1.3.

Options only relevant for TLS-1.3.

Types: Client and Server Options

Options common to both client and server side.

Common certificate related options to both client and server.

Common options to client and server only valid for DTLS.

Legacy options considered deprecated in favor of other options, insecure to use, or plainly not relevant anymore.

Options common to client and server side prior to TLS-1.3.

Common options to both client and server for TLS-1.3.

Types: Info

Key value list convening some information about the established connection.

TLS connection keys for which information can be retrieved.

TLS connection information relevant prior to TLS-1.3.

TLS connection information that can be used for NSS key logging.

Server API

Performs the TLS/DTLS server-side handshake.

Performs the TLS/DTLS server-side handshake.

Creates an SSL listen socket.

Accepts an incoming connection request on a listen socket.

Client and Server API

Closes a TLS/DTLS connection.

Closes or downgrades a TLS connection.

Assigns a new controlling process to the SSL socket.

Cancel the handshake with a fatal USER_CANCELED alert.

Continue the TLS handshake, possibly with new, additional, or changed options.

Receives a packet from a socket in passive mode.

Writes Data to SslSocket.

Sets options according to Options for socket SslSocket.

Immediately closes a socket in one or two directions.

TLS-1.3 Only API

Returns all supported groups in TLS 1.3.

Returns default supported groups in TLS 1.3.

Create new session keys.

Pre TLS-1.3 API

Returns a list of all supported elliptic curves, including legacy curves, for all TLS/DTLS versions prior to TLS-1.3.

Returns the elliptic curves supported by default for Version.

Initiates a new handshake.

Utility Functions

Make Deferred suites become the least preferred suites.

Lists all available cipher suites corresponding to Description.

Equivalent to cipher_suites/2, but lists RFC or OpenSSL string names instead of erl_cipher_suite().

Clears the PEM cache.

Returns the most relevant information about the connection.

Returns the requested information items about the connection if they are defined.

Uses a Pseudo-Random Function (PRF prior to TLS-1.3) or a Key Derivation Function (HKDF in TLS-1.3) for a TLS connection to generate and export keying materials.

Removes cipher suites if any of the filter functions returns false for any part of the cipher suite.

Presents the error returned by an SSL function as a printable string.

Gets the values of the specified socket options.

Get statistics for the underlying socket.

Get one or more statistic values for the underlying socket.

Returns the protocol negotiated through ALPN or NPN extensions.

The peer certificate is returned as a DER-encoded binary.

Returns the address and port number of the peer.

Make Preferred suites become the most preferred suites.

Lists all available signature algorithms corresponding to Description.

Returns the local address and port number of socket SslSocket.

Equivalent to start(temporary).

Starts the SSL application.

Stops the SSL application.

Converts an RFC or OpenSSL name string to an erl_cipher_suite/0

Converts an erl_cipher_suite() value to an OpenSSL name string.

Converts an erl_cipher_suite() value to an RFC name string.

Lists information, mainly concerning TLS/DTLS versions, in runtime for debugging and testing purposes.

Deprecated API

Uses the Pseudo-Random Function (PRF) of a TLS session to generate extra key material.

Types: Socket

-type active_msgs() ::
          {ssl, sslsocket(), Data :: binary() | list()} |
          {ssl_closed, sslsocket()} |
          {ssl_error, sslsocket(), Reason :: any()} |
          {ssl_passive, sslsocket()}.

The type for the messages that are delivered to the owner of a TLS/DTLS socket in active mode.

The ssl_passive message is sent only when the socket is in {active, N} mode and the counter has dropped to 0. It indicates that the socket has transitioned to passive ({active, false}) mode.

Link to this type

dtls_legacy_version()

View Source (not exported)
-type dtls_legacy_version() :: dtlsv1.

A DTLS protocol version that are no longer supported by default for security reasons.

Link to this type

dtls_version()

View Source (not exported)
-type dtls_version() :: 'dtlsv1.2' | dtls_legacy_version().

DTLS protocol version.

-type error_alert() :: {tls_alert, {tls_alert(), Description :: string()}}.

If a TLS connection fails a TLS protocol ALERT will be sent/received.

An atom reflecting the raised alert, according to the TLS protocol, and a description string with some further details will be returned.

-type host() :: inet:hostname() | inet:ip_address().

A name or address to a host.

-type protocol_extensions() ::
          #{renegotiation_info => binary(),
            signature_algs => signature_algs(),
            alpn => binary(),
            srp => binary(),
            next_protocol => binary(),
            max_frag_enum => 1..4,
            ec_point_formats => [0..2],
            elliptic_curves => [public_key:oid()],
            sni => inet:hostname()}.

Client hello extensions.

-type protocol_version() :: tls_version() | dtls_version().

TLS or DTLS protocol version.

-type reason() :: term().

Error reason for debug purposes.

Not to be matched.

-type session_id() :: binary().

Identifies a TLS session prior to TLS-1.3.

-type socket() :: gen_tcp:socket().

A socket that can be used to perform a so-called "START-TLS", which means using an already connected socket previously used for plain TCP traffic and upgrading it to use TLS.

Both sides needs to agree on the upgrade.

-type socket_option() :: gen_tcp:connect_option() | gen_tcp:listen_option() | gen_udp:option().

Options for the transport socket.

The default socket options are [{mode, list}, {packet, 0}, {header, 0}, {active, true}].

For valid options, see inet, gen_tcp, and gen_udp in Kernel. Note that stream-oriented options such as packet are only relevant for TLS and not DTLS.

-type sslsocket() :: any().

An opaque reference to the TLS/DTLS connection.

Note that despite being opaque, matching sslsocket() instances is allowed.

-type tls_alert() ::
          close_notify | unexpected_message | bad_record_mac | record_overflow | handshake_failure |
          bad_certificate | unsupported_certificate | certificate_revoked | certificate_expired |
          certificate_unknown | illegal_parameter | unknown_ca | access_denied | decode_error |
          decrypt_error | export_restriction | protocol_version | insufficient_security |
          internal_error | inappropriate_fallback | user_canceled | no_renegotiation |
          unsupported_extension | certificate_unobtainable | unrecognized_name |
          bad_certificate_status_response | bad_certificate_hash_value | unknown_psk_identity |
          no_application_protocol.

TLS Alert Protocol reasons.

-type tls_client_option() :: client_option() | common_option() | socket_option() | transport_option().

An option that can be supplied to a TLS client.

Link to this type

tls_legacy_version()

View Source (not exported)
-type tls_legacy_version() :: tlsv1 | 'tlsv1.1'.

A TLS protocol version that are no longer supported by default for security reasons.

-type tls_option() :: tls_client_option() | tls_server_option().

An option related to the TLS/DTLS protocol.

-type tls_server_option() :: server_option() | common_option() | socket_option() | transport_option().

An option that can be supplied to a TLS server.

Link to this type

tls_version()

View Source (not exported)
-type tls_version() :: 'tlsv1.2' | 'tlsv1.3' | tls_legacy_version().

TLS protocol version.

Link to this type

transport_option()

View Source (not exported)
-type transport_option() ::
          {cb_info,
           {CallbackModule :: atom(), DataTag :: atom(), ClosedTag :: atom(), ErrTag :: atom()}} |
          {cb_info,
           {CallbackModule :: atom(),
            DataTag :: atom(),
            ClosedTag :: atom(),
            ErrTag :: atom(),
            PassiveTag :: atom()}}.

Transport option defines a callback module and message tags to handle the underlying transport socket.

Can be used to customize the transport layer. The tag values should be the values used by the underlying transport in its active mode messages.

Defaults to {gen_tcp, tcp, tcp_closed, tcp_error, tcp_passive} for TLS.

Note

For backward compatibility a tuple of size four will be converted to a tuple of size five, where PassiveTag is the DataTag element with _passive appended.

For TLS the callback module must implement a reliable transport protocol, behave as gen_tcp, and have functions corresponding to inet:setopts/2, inet:getopts/2, inet:peername/1, inet:sockname/1, and inet:port/1. The callback gen_tcp is treated specially and calls inet directly. For DTLS this feature is considered experimental.

Types: Algorithms

-type cipher() ::
          aes_256_gcm | aes_128_gcm | aes_256_ccm | aes_128_ccm | chacha20_poly1305 | aes_256_ccm_8 |
          aes_128_ccm_8 | aes_128_cbc | aes_256_cbc |
          legacy_cipher().

Cipher algorithms that can be used for payload encryption.

-type cipher_filters() ::
          [{key_exchange | cipher | mac | prf,
            fun((kex_algo() | cipher() | hash() | aead | default_prf) -> true | false)}].

Filter that allows you to customize cipher suite list.

Link to this type

cipher_suites()

View Source (not exported)
-type cipher_suites() :: ciphers().

A list of cipher suites that should be supported.

Function ssl:cipher_suites/2 can be used to find all cipher suites that are supported by default and all cipher suites that can be configured.

If you compose your own cipher_suites/0 make sure they are filtered for crypto library support using ssl:filter_cipher_suites/2 .

The following function can help creating customized cipher suite lists:

Note

Note that TLS-1.3 and TLS-1.2 use different sets of cipher suites. To support both versions, cipher suites from both sets need to be included. If the supplied list does not comply with the configured versions or crypto library, that is, resulting in an empty list, the option will fall back to its appropriate default value for the configured versions.

Non-default cipher suites, including anonymous cipher suites (prior to TLS 1.3), are supported for interoperability and testing purposes. These can be used by adding them to your cipher suite list. Note that they also need to be supported and enabled by the peer to be actually used, and they may require additional configuration; see srp_param_type().

-type ciphers() :: [erl_cipher_suite()] | string().

Cipher suite formats.

For backwards compatibility, cipher suites can be configured as a colon-separated string of cipher suite RFC names (or even old OpenSSL names). However, a more flexible approach is to use utility functions together with cipher_filters() if a customized cipher suite option is needed.

-type erl_cipher_suite() ::
          #{key_exchange := kex_algo(),
            cipher := cipher(),
            mac := hash() | aead,
            prf := hash() | default_prf}.

Erlang cipher suite representation

Warning

Enabling cipher suites using RSA as a key exchange algorithm is strongly discouraged (only available prior to TLS-1.3). For some configurations software preventions may exist, and can make them usable if they work, but relying on them to work is risky. There exists more reliable cipher suites that can be used instead.

-type group() ::
          x25519 | x448 | secp256r1 | secp384r1 | secp521r1 | ffdhe2048 | ffdhe3072 | ffdhe4096 |
          ffdhe6144 | ffdhe8192.

TLS-1.3 key exchange configuration.

-type hash() :: sha2() | legacy_hash().

Hash algorithms used together with signing and encryption functions.

-type kex_algo() ::
          ecdhe_ecdsa | ecdh_ecdsa | ecdh_rsa | rsa | dhe_rsa | dhe_dss | srp_rsa | srp_dss | dhe_psk |
          rsa_psk | psk | ecdh_anon | dh_anon | srp_anon | any.

Cipher Suite Key Exchange Algorithm will be any in TLS-1.3 as key exchange is no longer part of cipher suite configuration in TLS-1.3.

-type named_curve() ::
          x25519 | x448 | secp521r1 | brainpoolP512r1 | brainpoolP384r1 | secp384r1 | brainpoolP256r1 |
          secp256r1 |
          legacy_named_curve().

Key exchange configuration prior to TLS-1.3.

Link to this type

rsassa_pss_scheme()

View Source (not exported)
-type rsassa_pss_scheme() ::
          rsa_pss_rsae_sha512 | rsa_pss_rsae_sha384 | rsa_pss_rsae_sha256 | rsa_pss_pss_sha512 |
          rsa_pss_pss_sha384 | rsa_pss_pss_sha256.

Supported in TLS-1.3 and TLS-1.2.

-type sha2() :: sha512 | sha384 | sha256.

SHA2 hash algorithms.

-type sign_algo() :: eddsa | ecdsa | rsa | legacy_sign_algo().

Signature algorithms.

-type sign_scheme() ::
          eddsa_ed25519 | eddsa_ed448 | ecdsa_secp521r1_sha512 | ecdsa_secp384r1_sha384 |
          ecdsa_secp256r1_sha256 | ecdsa_brainpoolP512r1tls13_sha512 |
          ecdsa_brainpoolP384r1tls13_sha384 | ecdsa_brainpoolP256r1tls13_sha256 |
          rsassa_pss_scheme() |
          legacy_sign_scheme().

Signature schemes, defined by TLS-1.3, and replacing signature algorithms from TLS-1.2.

Explicitly list acceptable signature schemes in the preferred order.

Overrides the algorithms supplied in signature_algs option for certificates. In addition to the signature_algorithms extension from TLS 1.2, TLS 1.3 (RFC 5246 Section 4.2.3) adds the signature_algorithms_cert extension which enables having special requirements on the signatures used in the certificates that differs from the requirements on digital signatures as a whole. If this is not required this extension is not needed.

The client will send a signature_algorithms_cert extension (in the client hello message), if TLS version 1.2 (back-ported to TLS 1.2 in 24.1) or later is used, and the signature_algs_cert option is explicitly specified. By default, only the signature_algs extension is sent with the exception of when signature_algs option is not explicitly specified, in which case it will append the rsa_pkcs1_sha1 algorithm to the default value of signature_algs and use it as value for signature_algs_cert to allow certificates to have this signature but still disallow sha1 use in the TLS protocol, since 27.0.1 and 26.2.5.2.

Note

Note that supported signature schemes for TLS-1.2 are legacy_sign_scheme() and rsassa_pss_scheme().

-type signature_algs() :: [{hash(), sign_algo()} | sign_scheme()].

Explicitly list acceptable signature algorithms for certificates and handshake messages in the preferred order.

The client will send its list as the client hello signature_algorithm extension introduced in TLS-1.2; see Section 7.4.1.4.1 in RFC 5246. Before TLS-1.2, these algorithms where implicitly chosen and partly derived from the cipher suite.

In TLS-1.2 a somewhat more explicit negotiation is made possible using a list of {HashAlgo, SignAlgo} tuples.

In TLS-1.3, these algorithm pairs are replaced by signature schemes that are completely decoupled from the cipher suite.

Signature algorithms used for certificates can be overridden by the signature schemes supplied by the signature_algs_cert option.

The TLS-1.2 default is Default_TLS_12_Alg_Pairs interleaved with rsa_pss_schemes since ssl-11.0 (Erlang/OTP 25). pss_pss is preferred over pss_rsae, which in turn is preferred over rsa.

The list for Default_TLS_12_Alg_Pairs is defined as follows:

[
{sha512, ecdsa},
{sha512, rsa},
{sha384, ecdsa},
{sha384, rsa},
{sha256, ecdsa},
{sha256, rsa}
]

Change

  • Support for {md5, rsa} was removed from the TLS-1.2 default in ssl-8.0 (Erlang/OTP 22).
  • Support for {sha, _} (SHA1) and {sha224, _} was removed from the TLS-1.2 default in ssl-11.0 (Erlang/OTP 26).

The list for rsa_pss_schemes is defined as follows:

[rsa_pss_pss_sha512,
rsa_pss_pss_sha384,
rsa_pss_pss_sha256,
rsa_pss_rsae_sha512,
rsa_pss_rsae_sha384,
rsa_pss_rsae_sha256]

The list of TLS_13_Legacy_Schemes is defined as follows:

[
%% Legacy algorithms only applicable to certificate signatures
rsa_pkcs1_sha512, %% Corresponds to {sha512, rsa}
rsa_pkcs1_sha384, %% Corresponds to {sha384, rsa}
rsa_pkcs1_sha256, %% Corresponds to {sha256, rsa}
]

The list of Default_TLS_13_Schemes is defined as follows:

[
%% EDDSA
eddsa_ed25519,
eddsa_ed448

%% ECDSA
ecdsa_secp521r1_sha512,
ecdsa_secp384r1_sha384,
ecdsa_secp256r1_sha256] ++

%% RSASSA-PSS
rsa_pss_schemes()

Change

EDDSA was made highest priority in ssl-10.8 (Erlang/OTP 25).

The TLS-1.3 default is Default_TLS_13_Schemes.

If both TLS-1.3 and TLS-1.2 are supported the default is:

Default_TLS_13_Schemes ++ TLS_13_Legacy_Schemes ++
Default_TLS_12_Alg_Pairs %% not represented in TLS_13_Legacy_Schemes

to ensure that appropriate algorithms can be chosen for the negotiated version.

Note

TLS-1.2 algorithms will not be negotiated for TLS-1.3, but the TLS-1.3 RSASSA-PSS (rsassa_pss_scheme()) signature schemes can be negotiated also for TLS-1.2 from Erlang/OTP 24.1 (fully working from Erlang/OTP 24.1.3). However, if both TLS 1.3 and TLS 1.2 are supported using defaults, and TLS 1.3 is negotiated, the corresponding TLS 1.2 algorithms for TLS 1.3 legacy signature schemes will be treated as legacy schemes and applied only to certificate signatures.

-type srp_param_type() :: srp_8192 | srp_6144 | srp_4096 | srp_3072 | srp_2048 | srp_1536 | srp_1024.

SRP cipher suite configuration prior to TLS-1.3.

Types: Certificates

Link to this type

anchor_fun()

View Source (not exported)
-type anchor_fun() :: fun().

Claim an intermediate CA in the chain as trusted.

fun(Chain::[public_key:der_encoded()]) ->
      {trusted_ca, DerCert::public_key:der_encoded()} | unknown_ca.

TLS then uses public_key:pkix_path_validation/3 with the selected CA as the trusted anchor and verifies the rest of the chain.

-type cert_key_conf() ::
          #{cert => public_key:der_encoded() | [public_key:der_encoded()],
            key => key(),
            certfile => file:filename(),
            keyfile => file:filename(),
            password => iodata() | fun(() -> iodata())}.

Configuration of the entity certificate and its corresponding key.

A certificate (or possibly a list including the certificate and its chain certificates, where the entity certificate must be the first element in the list or the first entry in the file) and its associated key. For the PEM file format, there can also be a password associated with the file containing the key.

For maximum interoperability, the certificates in the chain should be in the correct order, as the chain will be sent as-is to the peer. If chain certificates are not provided, certificates from the configured trusted CA certificates will be used to construct the chain. See client_option_cert() and server_option_cert() for more information.

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crl_cache_opts()

View Source (not exported)
-type crl_cache_opts() :: {Module :: atom(), {DbHandle :: internal | term(), Args :: list()}}.

Options for using built-in CRL cache support.

Specify how to perform lookup and caching of certificate revocation lists (CRLs). Module defaults to ssl_crl_cache with DbHandle being internal, and Args being [].

There are two implementations available:

  • ssl_crl_cache - Implementation 1

    This module maintains a cache of CRLs. CRLs can be added to the cache using ssl_crl_cache:insert/1, and can optionally be automatically fetched through HTTP if the following argument is specified:

  • ssl_crl_hash_dir - Implementation 2

    This module makes use of a directory where CRLs are stored in files named by the hash of the issuer name.

    The file names consist of eight hexadecimal digits followed by .rN, where N is an integer, for example 1a2b3c4d.r0. For the first version of the CRL, N starts at zero, and for each new version, N is incremented by one. The OpenSSL utility c_rehash creates symlinks according to this pattern.

    For a given hash value, this module finds all consecutive .r* files starting from zero, and those files taken together make up the revocation list. CRL files with nextUpdate fields in the past or issued by a different CA that happens to have the same name hash are excluded.

    The following argument is required:

    • {dir, string()}

    Specifies the directory in which the CRLs can be found.

-type key() ::
          {'RSAPrivateKey' | 'DSAPrivateKey' | 'ECPrivateKey' | 'PrivateKeyInfo',
           public_key:der_encoded()} |
          #{algorithm := sign_algo(),
            engine := crypto:engine_ref(),
            key_id := crypto:key_id(),
            password => crypto:password()} |
          #{algorithm := sign_algo(),
            sign_fun := fun(),
            sign_opts => list(),
            encrypt_fun => fun(),
            encrypt_opts => list()}.

The user's private key.

The key can be provided either directly as a DER-encoded entity, indirectly using a crypto engine/provider (with key reference information), or as an Erlang fun (with possible custom options). The latter two options can be used for customized signing with hardware security modules (HSM) or trusted platform modules (TPM).

Types: Algorithms Legacy

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legacy_cipher()

View Source (not exported)
-type legacy_cipher() :: '3des_ede_cbc' | des_cbc | rc4_128.

Cipher algorithms that are no longer supported by default for security reasons.

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legacy_hash()

View Source (not exported)
-type legacy_hash() :: sha224 | sha | md5.

Hash algorithms that are no longer supported by default for security reasons.

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legacy_named_curve()

View Source (not exported)
-type legacy_named_curve() ::
          sect571r1 | sect571k1 | sect409k1 | sect409r1 | sect283k1 | sect283r1 | secp256k1 |
          sect239k1 | sect233k1 | sect233r1 | secp224k1 | secp224r1 | sect193r1 | sect193r2 |
          secp192k1 | secp192r1 | sect163k1 | sect163r1 | sect163r2 | secp160k1 | secp160r1 | secp160r2.

Key exchange configuration prior to TLS-1.3.

These curves have been deprecated by RFC 8422.

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legacy_sign_algo()

View Source (not exported)
-type legacy_sign_algo() :: dsa.

Signature algorithms that are no longer supported by default for security reasons.

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legacy_sign_scheme()

View Source (not exported)
-type legacy_sign_scheme() ::
          rsa_pkcs1_sha512 | rsa_pkcs1_sha384 | rsa_pkcs1_sha256 | ecdsa_sha1 | rsa_pkcs1_sha1.

This is only used for certificate signatures if TLS-1.2 is negotiated, meaning that the peer only supports TLS-1.2, but we also support TLS-1.3.

-type old_cipher_suite() ::
          {kex_algo(), cipher(), hash()} | {kex_algo(), cipher(), hash() | aead, hash()}.

For backwards compatibility only; do not use.

Types: Client Options

Link to this type

client_option()

View Source (not exported)
-type client_option() ::
          client_option_cert() |
          common_option_cert() |
          {alpn_advertised_protocols, AppProtocols :: [AppProto :: binary()]} |
          {max_fragment_length, MaxLen :: undefined | 512 | 1024 | 2048 | 4096} |
          client_option_tls13() |
          common_option_tls13() |
          client_option_pre_tls13() |
          common_option_pre_tls13() |
          common_option_dtls() |
          client_option_legacy() |
          common_option_legacy().

The following options are specific to the client side, or have different semantics for the client and server:

  • {alpn_advertised_protocols, AppProtocols} - Application layer protocol

    The list of protocols supported by the client to be sent to the server to be used for an Application-Layer Protocol Negotiation (ALPN). If the server supports ALPN, it will choose a protocol from this list; otherwise it will fail the connection with a no_application_protocol alert. A server that does not support ALPN will ignore this value. The list of protocols must not contain an empty binary.

  • {max_fragment_length, MaxLen} - Max fragment length extension

    Specifies the maximum fragment length the client is prepared to accept from the server. See RFC 6066.

-type client_option_cert() ::
          {verify, Verify :: verify_peer | verify_none} |
          {cacerts, CACerts :: [public_key:der_encoded()] | [public_key:combined_cert()]} |
          {cacertfile, CACertFile :: file:filename()} |
          {server_name_indication, SNI :: inet:hostname() | disable} |
          {customize_hostname_check, HostNameCheckOpts :: list()} |
          {certificate_authorities, boolean()} |
          {stapling, Stapling :: staple | no_staple | map()}.

Certificate-related options specific to the client side, or with different semantics for the client and server.

  • {verify, Verify} - Verification of certificates

    This option specifies whether certificates are to be verified.

    If Verify is verify_peer, which is the default, it is required to also provide one of the options cacerts or cacertfile in order for the certificate verification to succeed. For example, an HTTPS client can use option {cacerts, public_key:cacerts_get()} to use the trusted CA certificates provided by the operating system.

    If Verify is verify_none, all X.509-certificate path validation errors will be ignored.

    Change

    The default for Verify was changed to verify_peer in Erlang/OTP 26.

  • {cacerts, CACerts} - Trusted certificates

    The DER-encoded trusted certificates. If this option is supplied it overrides option cacertfile.

    Function public_key:cacerts_get/0 can be used to retrieve to the trusted CA certificates provided by the operating system.

  • {cacertfile, CertFile} - End entity certificate

    Path to a file containing PEM-encoded CA certificates. The CA certificates are used during server authentication and when building the client certificate chain.

    Note

    When PEM caching is enabled, files provided with this option will be checked for updates at fixed time intervals specified by the ssl_pem_cache_clean environment parameter.

  • {server_name_indication, SNI} - Server Name Indication extension

    Specify the hostname to be used in TLS Server Name Indication extension. If not specified it will default to the Host argument of connect/3,4 unless it is of type inet:ip_address(). The hostname will also be used in the hostname verification of the peer certificate using public_key:pkix_verify_hostname/2. The special value disable prevents the Server Name Indication extension from being sent and disables the hostname verification check.

  • {customize_hostname_check, HostNameCheckOpts} - Customization option

    Customizes the hostname verification of the peer certificate, as various protocols that use TLS, such as HTTP or LDAP, may require different approaches. For example, here is how to use standard hostname checking for HTTPS implemented in Public_Key:

    {customize_hostname_check, [{match_fun, public_key:pkix_verify_hostname_match_fun(https)}]}

    For futher description of the customize options, see public_key:pkix_verify_hostname/3.

  • {client_certificate_authorities, UseCertAuth} - Inter-op hint option

    If UseCertAuth is set to true, sends the certificate authorities extension in the TLS-1.3 client hello. The default is false. Note that setting UseCertAuth to true can result in a significant overhead if there exists many trusted CA certificates. (Since Erlang/OTP 24.3.)

  • {stapling, Stapling} - Certificate revocation check option

    If Stapling is atom staple or a map, OCSP stapling will be enabled, meaning that an extension of type "status_request" will be included in the client hello to indicate the desire to receive certificate status information.

    If Stapling is set to no_staple (the default), OCSP stapling will be disabled.

    Note

    Even if requested by the client, the OCSP response might not be provided by the server. In such event, SSL will proceed with the handshake and generate a {missing, stapling_response} logger event.

    When Stapling is given as a map, boolean ocsp_nonce key can indicate whether an OCSP nonce should be requested by the client (default is false).

    Note

    The OCSP response can be provided without a nonce value — even if it was requested by the client. In such cases SSL will proceed with the handshake and generate a {missing, ocsp_nonce} logger event.

Link to this type

client_option_legacy()

View Source (not exported)
-type client_option_legacy() ::
          {client_preferred_next_protocols,
           NextAppProtocols ::
               {Precedence :: server | client, ClientPrefs :: [AppProto :: binary()]} |
               {Precedence :: server | client,
                ClientPrefs :: [AppProto :: binary()],
                Default :: (AppProto :: binary())}}.

Legacy client options.

  • {client_preferred_next_protocols, NextAppProtocols} - Next Protocol Negotiation

    ALPN (Application-Layer Protocol Negotiation) deprecates NPN (Next Protocol Negotiation) and this option.

    Indicates that the client wants to perform Next Protocol Negotiation.

    If Precedence is server, the negotiated protocol is the first protocol to be shown on the server advertised list that is also on the client preference list.

    If Precedence is client, the negotiated protocol is the first protocol to be shown on the client preference list that is also on the server advertised list.

    If the client does not support any of the server advertised protocols or the server does not advertise any protocols, the client falls back to the first protocol in its list or to the default protocol (if a default is supplied). If the server does not support Next Protocol Negotiation, the connection terminates if no default protocol is supplied.

Link to this type

client_option_pre_tls13()

View Source (not exported)
-type client_option_pre_tls13() ::
          {reuse_session, SessionRef :: session_id() | {session_id(), SessionData :: binary()}} |
          {reuse_sessions, Reuse :: boolean() | save} |
          {psk_identity, PskID :: string()} |
          {srp_identity, SrpID :: {Username :: string(), Password :: string()}} |
          {fallback, LegacyFallback :: boolean()}.

Options only relevant to TLS versions prior to TLS-1.3.

  • {reuse_session, SessionRef} - Explicit session reuse

    Reuses a specific session.

    Since Erlang/OTP 21.3, if the session was saved earlier using option {reuse_sessions, save}, the session can be referred by its session ID.

    Since Erlang/OTP 22.3, the session can be explicitly specified by its session ID and associated data.

    See also SSL User's Guide, Session Reuse pre TLS 1.3.

  • {reuse_sessions, Reuse} - Enables later session reuse

    When Reuse is set to save, a new connection will be negotiated and saved for later reuse. The session ID can be fetched with connection_information/2 and used with the client option reuse_session.

    When Reuse is set to true, automated session reuse will be performed, if possible. If a new session is created, and is unique in regard to previous stored sessions, it will be saved for possible later reuse.

    Since: OTP 21.3.

  • {psk_identity, PskID} - Option for use with PSK cipher suites

    Specifies the identity the client presents to the server. The matching secret is found by the fun given in the user_lookup_fun option.

  • {srp_identity, SrpID} - Option for use SRP cipher suites

    Specifies the username and password to use to authenticate to the server.

  • {fallback, LegacyFallback} - Inter-op legacy client option

    Send special cipher suite TLS_FALLBACK_SCSV to avoid an undesired TLS version downgrade. Defaults to false.

    Warning

    This option is not needed in normal TLS usage and must not be used to implement new clients. However, legacy clients that retries connections in the following manner:

    ssl:connect(Host, Port, [...{versions, ['tlsv2', 'tlsv1.1', 'tlsv1']}])

    ssl:connect(Host, Port, [...{versions, [tlsv1.1', 'tlsv1']}, {fallback, true}])

    ssl:connect(Host, Port, [...{versions, ['tlsv1']}, {fallback, true}])

    can use it to avoid undesired TLS version downgrade. Note that TLS_FALLBACK_SCSV must also be supported by the server for the prevention to work.

Link to this type

client_option_tls13()

View Source (not exported)
-type client_option_tls13() ::
          {session_tickets, SessionTickets :: disabled | manual | auto} |
          {use_ticket, Tickets :: [binary()]} |
          {early_data, binary()} |
          {middlebox_comp_mode, MiddleBoxMode :: boolean()}.

Options only relevant for TLS-1.3.

  • {session_tickets, SessionTickets} - Use of session tickets

    Configures the session ticket functionality. Allowed values are disabled, manual, and auto. If it is set to manual the client will send the ticket information to user process in a 3-tuple:

    {ssl, session_ticket, {SNI, TicketData}}

    where SNI is the ServerNameIndication and TicketData is the extended ticket data that can be used in subsequent session resumptions.

    If it is set to auto, the client automatically handles received tickets and tries to use them when making new TLS connections (session resumption with pre-shared keys).

    Ticket lifetime, the number of tickets sent by the server, and the maximum number of tickets stored by the server in stateful mode are configured by application variables.

    See also SSL User's Guide, Session Tickets and Session Resumption in TLS 1.3.

  • {use_ticket, Tickets}

    Configures the session tickets to be used for session resumption. It is a mandatory option in manual mode ({session_tickets, manual}).

    Note

    Session tickets are only sent to the user if option session_tickets is set to manual

    This option is supported by TLS-1.3. See also SSL User's Guide, Session Tickets and Session Resumption in TLS 1.3.

  • {early_data, EarlyData}

    Configures the early data to be sent by the client.

    To verify that the server has the intention to process the early data, the following tuple is sent to the user process:

    {ssl, SslSocket, {early_data, Result}}

    where Result is either accepted or rejected.

    Warning

    It is the responsibility of the user to handle rejected EarlyData and to resend when appropriate.

  • {middlebox_comp_mode, MiddleBoxMode}

    Configures the middlebox compatibility mode for a TLS-1.3 connection.

    A significant number of middleboxes misbehave when a TLS-1.3 connection is negotiated. Implementations can increase the chance of making connections through those middleboxes by adapting the TLS-1.3 handshake to resemble that of a TLS-1.2 handshake.

    The middlebox compatibility mode is enabled (true) by default.

Types: Server Options

Link to this type

server_option()

View Source (not exported)
-type server_option() ::
          server_option_cert() |
          common_option_cert() |
          {alpn_preferred_protocols, AppProtocols :: [binary()]} |
          {sni_hosts, SNIHosts :: [{inet:hostname(), [server_option() | common_option()]}]} |
          {sni_fun, SNIFun :: fun((string()) -> [])} |
          server_option_pre_tls13() |
          common_option_pre_tls13() |
          server_option_tls13() |
          common_option_tls13() |
          common_option_dtls() |
          server_option_legacy() |
          common_option_legacy().

Options specific to the server side, or with different semantics for the client and server.

  • {alpn_preferred_protocols, AppProtocols} - Application Layer Protocol Negotiation

    Indicates that the server will try to perform Application-Layer Protocol Negotiation (ALPN).

    The list of protocols is in order of preference. The protocol negotiated will be the first in the list that matches one of the protocols advertised by the client. If no protocol matches, the server will fail the connection with a no_application_protocol alert.

    The negotiated protocol can be retrieved using the negotiated_protocol/1 function.

  • {sni_fun, SNIFun}

    If the server receives a SNI (Server Name Indication) from the client, the given fun SNIFun will be called to retrieve server_option() for the indicated hosts. These options will override previously specified options for that host.

    Note

    The options sni_fun and sni_hosts are mutually exclusive.

  • {sni_hosts, SNIHosts}

    If the server receives a SNI (Server Name Indication) from the client matching a host listed in the sni_hosts option, the specific options for that host will override previously specified options.

    Note

    The options sni_fun and sni_hosts are mutually exclusive.

-type server_option_cert() ::
          {cacerts, CACerts :: [public_key:der_encoded()] | [public_key:combined_cert()]} |
          {cacertfile, CACertFile :: file:filename()} |
          {verify, Verify :: verify_none | verify_peer} |
          {fail_if_no_peer_cert, FailNoPeerCert :: boolean()} |
          {certificate_authorities, ServerCertAuth :: boolean()}.

Certificate related options for a server.

  • {cacerts, CACerts} - Trusted certificates.

    The DER-encoded trusted certificates. If this option is supplied, it overrides the cacertfile option.

  • {verify, Verify} - Verify certificates.

    Client certificates are an optional part of the TLS protocol. A server performs X.509 certificate path validation only in verify_peer mode. By default the server is in verify_none mode and, hence, will not send an certificate request to the client. When using verify_peer you may also want to specify the options fail_if_no_peer_cert and certificate_authorities.

  • {fail_if_no_peer_cert, FailNoPeerCert} - Legacy trade-off option

    Used together with {verify, verify_peer} by an TLS/DTLS server. If set to true, the server fails if the client does not have a certificate to send, that is, sends an empty certificate. If set to false, it fails only if the client sends an invalid certificate (an empty certificate is considered valid). Defaults to false.

  • {certificate_authorities, ServerCertAuth} - Inter-operate hint option

    Determines whether a TLS-1.3 server should include the authorities extension in its certificate request message that is sent when the option verify is set to verify_peer. Defaults to true.

    A reason to exclude the extension would be if the server wants to communicate with clients incapable of sending complete certificate chains that adhere to the extension, but the server still has the capability to recreate a chain that it can verify.

Link to this type

server_option_legacy()

View Source (not exported)
-type server_option_legacy() :: {next_protocols_advertised, NextAppProtocols :: [binary()]}.

Legacy server options.

  • {next_protocols_advertised, NextAppProtocols}

    ALPN (Application-Layer Protocol Negotiation) deprecates NPN (Next Protocol Negotiation) described here.

    List of protocols to send to the client if the client indicates that it supports the Next Protocol extension. The client can select a protocol that is not on this list. The list of protocols must not contain an empty binary. If the server negotiates a Next Protocol, it can be accessed using the negotiated_protocol/1 method.

Link to this type

server_option_pre_tls13()

View Source (not exported)
-type server_option_pre_tls13() ::
          {client_renegotiation, ClientRengotiation :: boolean()} |
          {reuse_sessions, ReuseSessions :: boolean()} |
          {reuse_session, ReuseSession :: fun()} |
          {honor_cipher_order, HonorServerCipherOrder :: boolean()} |
          {honor_ecc_order, HonorServerECCOrder :: boolean()} |
          {dh, DHDer :: public_key:der_encoded()} |
          {dhfile, DhFile :: file:filename()} |
          {psk_identity, PSKHint :: string()}.

Options only relevant to TLS versions prior to TLS-1.3.

  • {client_renegotiation, ClientRengotiation} - DoS attack avoidance option

    In protocols that support client-initiated renegotiation, the resource cost of such an operation is higher for the server than the client. This can act as a vector for denial-of-service (DoS) attacks. The SSL application already takes measures to counter-act such attempts, but client-initiated renegotiation can be completely disabled by setting this option to false. The default value is true. Note that disabling renegotiation can result in long-lived connections becoming unusable due to limits on the number of messages the underlying cipher suite can encipher.

  • {reuse_sessions, ReuseSessions} - Enable session reuse

    The boolean value true specifies that the server will agree to reuse sessions. Setting it to false will result in an empty session table, meaning that no sessions will be reused.

  • {reuse_session, ReuseSession} - Local server reuse policy

    Enables the TLS/DTLS server to have a local policy for deciding whether a session is to be reused. Meaningful only if reuse_sessions is set to true.

    ReuseSession should be a fun:

    fun(SuggestedSessionId, PeerCert, Compression, CipherSuite)

    SuggestedSessionId is a binary(), PeerCert is a DER-encoded certificate, Compression is an enumeration integer, and CipherSuite is of type erl_cipher_suite().

  • {psk_identity, PSKHint} - Inter-operate hint option

    Specifies the server identity hint that the server presents to the client.

  • {honor_cipher_order, HonorServerCipherOrder} - Trade-off option alters protocol defined behavior

    If true, use the server's preference for ECC curve selection. If false (the default), use the client's preference.

  • {honor_ecc_order, HonorServerECCOrder} - Trade-off option alters protocol defined behavior

    If true, use the server's preference for ECC curve selection. If false (the default), use the client's preference.

  • {dh, DHder} - Affects DH key exchange cipher suites

    The DER-encoded Diffie-Hellman parameters. If specified, it overrides option dhfile.

  • {dh_file, DHfile} - Affects DH key exchange cipher suites

    Path to a file containing PEM-encoded Diffie Hellman parameters to be used by the server if a cipher suite using Diffie Hellman key exchange is negotiated. If not specified, default parameters are used.

Link to this type

server_option_tls13()

View Source (not exported)
-type server_option_tls13() ::
          {session_tickets,
           SessionTickets :: disabled | stateful | stateless | stateful_with_cert | stateless_with_cert} |
          {stateless_tickets_seed, TicketSeed :: binary()} |
          {anti_replay,
           '10k' | '100k' |
           {BloomFilterWindowSize :: pos_integer(),
            BloomFilterHashFunctions :: pos_integer(),
            BloomFilterBits :: pos_integer()}} |
          {cookie, Cookie :: boolean()} |
          {early_data, EarlyData :: enabled | disabled}.

Options only relevant for TLS-1.3.

  • {session_tickets, SessionTickets}

    Configures the session ticket functionality. Allowed values for SessionTickets are:

    • disabled
    • stateful
    • stateless
    • stateful_with_cert
    • stateless_with_cert

    If SessionTickets is not set to disabled, session resumption with pre-shared keys is enabled and the server will send stateful or stateless session tickets to the client after successful connections.

    Note

    In pre-shared key session ticket resumption, there is no certificate exchange involved. Therefore, ssl:peercert/1 will not return the peer certificate, as it is only communicated during the initial handshake. To associate the client certificate from the original handshake with the tickets it issues, the server options stateful_with_cert or stateless_with_cert can be used.

    A stateful session ticket is a database reference to internal state information. A stateless session ticket is a self-encrypted binary that contains both cryptographic keying material and state data.

    Warning

    When SessionTickets is set to stateful_with_cert, the client certificate is stored along with the internal state information, leading to increased memory consumption. Conversely, when it is set to stateless_with_cert, the client certificate is encoded in the self-encrypted binary sent to the client, resulting in an increase in payload size.

    See also SSL User's Guide, Session Tickets and Session Resumption in TLS 1.3.

  • {stateless_tickets_seed, TicketSeed} - Option for statless tickets

    Configures the seed used for the encryption of stateless session tickets. Allowed values are any randomly generated binary/0. If this option is not configured, an encryption seed will be randomly generated.

    Warning

    Reusing the ticket encryption seed between multiple server instances enables stateless session tickets to work across multiple server instances, but it breaks anti-replay protection across instances.

    Inaccurate time synchronization between server instances can also affect session ticket freshness checks, potentially causing false negatives as well as false positives.

  • {anti_replay, AntiReplay} - Option for statless tickets

    Configures the server's built-in anti replay feature based on Bloom filters.

    Allowed values for AntiReplay are the pre-defined '10k', '100k', or a custom 3-tuple that defines the properties of the bloom filters: {WindowSize, HashFunctions, Bits}. WindowSize is the number of seconds after the current Bloom filter is rotated and also the window size used for freshness checks of ClientHello. HashFunctions is the number hash functions and Bits is the number of bits in the bit vector. '10k' and '100k' are simple defaults with the following properties:

    • '10k': Bloom filters can hold 10000 elements with 3% probability of false positives. WindowSize: 10, HashFunctions: 5, Bits: 72985 (8.91 KiB).
    • '100k': Bloom filters can hold 100000 elements with 3% probability of false positives. WindowSize: 10, HashFunctions: 5, Bits: 729845 (89.09 KiB).

    See also SSL User's Guide, Anti-Replay Protection in TLS 1.3.

  • {cookie, Cookie} - Option for HelloRetryRequest behavior

    If Cookie is true, which is the default, the server sends a cookie extension in its HelloRetryRequest messages.

    The cookie extension has two main purposes. It allows the server to force the client to demonstrate reachability at their apparent network address (thus providing a measure of DoS protection). This is primarily useful for non-connection-oriented transports. It also allows offloading the server's state to the client. The cookie extension is enabled by default as it is a mandatory extension in RFC8446.

  • {early_data, EarlyData} - Option for accepting or rejecting Early Data

    Configures if the server accepts (enabled) or rejects (disabled) early data sent by a client. The default value is disabled.

Types: Client and Server Options

Link to this type

common_option()

View Source (not exported)
-type common_option() ::
          {protocol, tls | dtls} |
          {handshake, hello | full} |
          {ciphers, cipher_suites()} |
          {signature_algs, signature_algs()} |
          {signature_algs_cert, [sign_scheme()]} |
          {keep_secrets, KeepSecrets :: boolean()} |
          {max_handshake_size, HandshakeSize :: pos_integer()} |
          {versions, [protocol_version()]} |
          {log_level, Level :: logger:level() | none | all} |
          {hibernate_after, HibernateTimeout :: timeout()} |
          {receiver_spawn_opts, SpawnOpts :: [erlang:spawn_opt_option()]} |
          {sender_spawn_opts, SpawnOpts :: [erlang:spawn_opt_option()]}.

Options common to both client and server side.

  • {protocol, Protocol} - Choose TLS or DTLS protocol for the transport layer security.

    Defaults to tls.

  • {handshake, Completion} - Possibly pause handshake at hello stage.

    Defaults to full. If hello is specified the handshake will pause after the hello message, allowing the user to make decisions based on hello extensions before continuing or aborting the handshake by calling handshake_continue/3 or handshake_cancel/1.

  • {keep_secrets, KeepSecrets} - Configures a TLS 1.3 connection for keylogging.

    In order to retrieve keylog information on a TLS 1.3 connection, it must be configured in advance to keep client_random and various handshake secrets.

    The keep_secrets functionality is disabled (false) by default.

    Added in OTP 23.2.

  • {max_handshake_size, HandshakeSize} - Limit the acceptable handshake packet size.

    Used to limit the size of valid TLS handshake packets to avoid DoS attacks.

    Integer (24 bits, unsigned). Defaults to 256*1024.

  • {hibernate_after, HibernateTimeout} - Hibernate inactive connection processes.

    When an integer-value is specified, the TLS/DTLS connection goes into hibernation after the specified number of milliseconds of inactivity, thus reducing its memory footprint. When not specified the process never goes into hibernation.

  • {log_level, Level} - Specifies the log level for a TLS/DTLS connection.

    Alerts are logged on notice level, which is the default level. The level debug triggers verbose logging of TLS/DTLS protocol messages. See also SSL Application

  • {receiver|sender_spawn_opts, SpawnOpts} - Configure erlang spawn opts.

    Configures spawn options of TLS sender and receiver processes.

    Setting up garbage collection options can be helpful for trade-offs between CPU usage and memory usage. See erlang:spawn_opt/2.

    For connections using Erlang distribution, the default sender option is [...{priority, max}]; this priority option cannot be changed. For all connections, ...link is added to receiver and cannot be changed.

Link to this type

common_option_cert()

View Source (not exported)
-type common_option_cert() ::
          {certs_keys, CertsKeys :: [cert_key_conf()]} |
          {depth, AllowedCertChainLen :: pos_integer()} |
          {verify_fun, Verify :: {Verifyfun :: fun(), InitialUserState :: any()}} |
          {cert_policy_opts,
           PolicyOpts ::
               [{policy_set, [public_key:oid()]} |
                {explicit_policy, boolean()} |
                {inhibit_policy_mapping, boolean()} |
                {inhibit_any_policy, boolean()}]} |
          {crl_check, Check :: boolean() | peer | best_effort} |
          {crl_cache, crl_cache_opts()} |
          {partial_chain, anchor_fun()}.

Common certificate related options to both client and server.

  • {certs_keys, CertsKeys} - At least one certificate and key pair.

    A list of a certificate (or possible a certificate and its chain) and the associated key of the certificate that can be used to authenticate the client or the server. The certificate key pair that is considered best and matches negotiated parameters for the connection will be selected.

    The different signature algorithms are prioritized in the following order: eddsa, ecdsa, rsa_pss_pss, rsa, and dsa. If more than one key is supplied for the same signature algorithm, they will be prioritized by strength (except for engine keys; see the next paragraph). This offers flexibility to, for instance, configure a newer certificate that is expected to be used in most cases, and an older but acceptable certificate that will only be used to communicate with legacy systems. Note that there is a trade off between the induced overhead and the flexibility; thus, alternatives should be chosen for good reasons.

    Engine keys will be favored over other keys. As engine keys cannot be inspected, supplying more than one engine key makes no sense.

    When this option is specified it overrides all single certificate and key options. For examples, see the User's Guide.

    Note

    eddsa certificates are only supported by TLS-1.3 implementations that do not support dsa certificates. rsa_pss_pss (RSA certificates using Probabilistic Signature Scheme) are supported in TLS-1.2 and TLS-1.3, but some TLS-1.2 implementations do not support rsa_pss_pss.

  • {depth, AllowedCertChainLen} - Limits the accepted number of certificates in the certificate chain.

    Maximum number of non-self-issued intermediate certificates that can follow the peer certificate in a valid certification path. So, if depth is 0 the PEER must be signed by the trusted ROOT-CA directly; if 1 the path can be PEER, CA, ROOT-CA; if 2 the path can be PEER, CA, CA, ROOT-CA, and so on. The default value is 10. Used to mitigate DoS attack possibilities.

  • {verify_fun, Verify} - Customize certificate path validation

    The verification fun is to be defined as follows:

    fun(OtpCert :: #'OTPCertificate'{},
        Event, InitialUserState :: term()) ->
      {valid, UserState :: term()} |
      {fail, Reason :: term()} | {unknown, UserState :: term()}.
    
    fun(OtpCert :: #'OTPCertificate'{}, DerCert :: public_key:der_encoded(),
        Event, InitialUserState :: term()) ->
      {valid, UserState :: term()} |
      {fail, Reason :: term()} | {unknown, UserState :: term()}.
    
    Types:
          Event = {bad_cert, Reason :: atom() |
                  {revoked, atom()}} |
          {extension, #'Extension'{}} |
                  valid |
                  valid_peer

    The verification fun is called during the X.509-path validation when an error occurs or an extension unknown to the SSL application is encountered. It is also called when a certificate is considered valid by the path validation to allow access to each certificate in the path to the user application. It differentiates between the peer certificate and the CA certificates by using valid_peer or valid as Event argument to the verification fun. See the Public_Key User's Guide for definition of #'OTPCertificate'{} and #'Extension'{}.

    • If the verify callback fun returns {fail, Reason}, the verification process is immediately stopped, an alert is sent to the peer, and the TLS/DTLS handshake terminates.
    • If the verify callback fun returns {valid, UserState}, the verification process continues.
    • If the verify callback fun always returns {valid, UserState}, the TLS/DTLS handshake does not terminate regardless of verification failures, and the connection is established.
    • If called with an extension unknown to the user application, the fun is to return {unknown, UserState}.

    Note that if the fun returns unknown for an extension marked as critical, validation will fail.

    Default option verify_fun in verify_peer mode:

    {fun(_, _, {bad_cert, _} = Reason, _) ->
       {fail, Reason};
        (_, _, {extension, _}, UserState) ->
       {unknown, UserState};
        (_, _, valid, UserState) ->
       {valid, UserState};
        (_, _, valid_peer, UserState) ->
           {valid, UserState}
     end, []}

    Default option verify_fun in mode verify_none:

     {fun(_, _, {bad_cert, _}, UserState) ->
       {valid, UserState};
        (_, _, {extension, #'Extension'{critical = true}}, UserState) ->
       {valid, UserState};
        (_, _, {extension, _}, UserState) ->
       {unknown, UserState};
        (_, _, valid, UserState) ->
       {valid, UserState};
        (_, _, valid_peer, UserState) ->
           {valid, UserState}
     end, []}

    The possible path validation errors are given in the form {bad_cert, Reason}, where Reason is:

    • unknown_ca

      No trusted CA was found in the trusted store. The trusted CA is normally a so-called ROOT CA, which is a self-signed certificate. Trust can be claimed for an intermediate CA (the trusted anchor does not have to be self-signed according to X-509) by using option partial_chain.

    • selfsigned_peer

      The chain consisted only of one self-signed certificate.

    • PKIX X-509-path validation error

      For possible reasons, see public_key:pkix_path_validation/3.

  • {cert_policy_opts, PolicyOpts} - Handle certificate policies.

    Configure X.509 certificate policy handling for the certificate path validation process; see public_key:pkix_path_validation/3 for more details.

  • {cerl_check, Check} - Handle certificate revocation lists.

    Perform CRL (Certificate Revocation List) verification (public_key:pkix_crls_validate/3) on all the certificates during the path validation (public_key:pkix_path_validation/3) of the certificate chain. Check defaults to false.

    The meaning of Check is as follows:

    • false

      No checks are performed.

    • peer

      Check is only performed on the peer certificate.

    • best_effort

      If certificate revocation status cannot be determined it will be accepted as valid.

      The CA certificates specified for the connection will be used to construct the certificate chain validating the CRLs.

      The CRLs will be fetched from a local or external cache. See ssl_crl_cache_api.

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common_option_dtls()

View Source (not exported)
-type common_option_dtls() ::
          {use_srtp, UseSrtp :: #{protection_profiles := [binary()], mki => binary()}}.

Common options to client and server only valid for DTLS.

  • {use_srtp, UseSrtp} - Configures the use_srtp DTLS hello extension.

    In order to negotiate the use of SRTP data protection, clients include an extension of type "use_srtp" in the DTLS extended client hello. This extension MUST only be used when the data being transported is RTP or RTCP.

    The value is a map with a mandatory protection_profiles parameter and an optional mki parameter.

    protection_profiles configures the list of the client's acceptable SRTP Protection Profiles. Each profile is a 2-byte binary. Example: #{protection_profiles => [<<0,2>>, <<0,5>>]}

    mki configures the SRTP Master Key Identifier chosen by the client.

    The srtp_mki field contains the value of the SRTP MKI which is associated with the SRTP master keys derived from this handshake. Each SRTP session MUST have exactly one master key that is used to protect packets at any given time. The client MUST choose the MKI value so that it is distinct from the last MKI value that was used, and it SHOULD make these values unique for the duration of the TLS session.

    Note

    OTP does not handle SRTP, so an external implementations of SRTP encoder/decoder and a packet demultiplexer are needed to make use of the use_srtp extension. See also option transport_option.

    Servers that receive an extended hello containing a "use_srtp" extension can agree to use SRTP by including an extension of type "use_srtp", with the chosen protection profile in the extended server hello. This extension MUST only be used when the data being transported is RTP or RTCP.

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common_option_legacy()

View Source (not exported)
-type common_option_legacy() ::
          {cert, Cert :: public_key:der_encoded() | [public_key:der_encoded()]} |
          {certfile, CertPem :: file:filename()} |
          {key, Key :: key()} |
          {keyfile, KeyPem :: file:filename()} |
          {password, KeyPemPasswd :: iodata() | fun(() -> iodata())} |
          {log_alert, LogAlert :: boolean()} |
          {padding_check, PaddingCheck :: boolean()} |
          {beast_mitigation, one_n_minus_one | zero_n | disabled} |
          {ssl_imp, Imp :: new | old}.

Legacy options considered deprecated in favor of other options, insecure to use, or plainly not relevant anymore.

  • {cert, Certs}

    Use option certs_keys instead.

  • {certfile, CertPem}

    Use option certs_keys instead.

  • {keyfile, KeyPem}

    Use option certs_keys instead.

  • {password, KeyPemPasswd}

    Use option certs_keys instead.

  • {log_alert, LogAlert}

    If LogAlert is false, TLS/DTLS Alert reports are not displayed. Deprecated in OTP 22; use {log_level, Level} instead.

  • {padding_check, PaddingCheck} - Inter-op trade-off option

    Affects TLS-1.0 connections only. If set to false, it disables the block cipher padding check to be able to interoperate with legacy software.

    Warning

    Using {padding_check, false} makes TLS vulnerable to the Poodle attack.

  • {beast_mitigation, BeastMitigation} - Inter-op trade-off option

    Affects TLS-1.0 connections only. Used to change the BEAST mitigation strategy to interoperate with legacy software. Defaults to one_n_minus_one.

    one_n_minus_one - Perform 1/n-1 BEAST mitigation.

    zero_n - Perform 0/n BEAST mitigation.

    disabled - Disable BEAST mitigation.

    Warning

    Using {beast_mitigation, disabled} makes TLS-1.0 vulnerable to the BEAST attack.

  • {ssl_imp, Imp}

    Deprecated since OTP 17; has no effect.

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common_option_pre_tls13()

View Source (not exported)
-type common_option_pre_tls13() ::
          {eccs, NamedCurves :: [named_curve()]} |
          {secure_renegotiate, SecureRenegotiate :: boolean()} |
          {user_lookup_fun, {Lookupfun :: fun(), UserState :: any()}}.

Options common to client and server side prior to TLS-1.3.

  • {eccs, NamedCurves} - Named Elliptic Curves

    Elliptic curves that can be used in pre TLS-1.3 key exchange.

  • {secure_renegotiate, SecureRenegotiate} - Inter-operate trade-off option

    Specifies whether to reject renegotiation attempt that does not live up to RFC 5746. By default, SecureRenegotiate is true, meaning that secure renegotiation is enforced. If SecureRenegotiate is false secure renegotiation will still be used if possible, but it falls back to insecure renegotiation if the peer does not support if RFC 5746.

  • {user_lookup_fun, {LookupFun, UserState}} - PSK/SRP cipher suite option

    The lookup fun is to be defined as follows:

    fun(psk, PSKIdentity :: binary(), UserState :: term()) ->
      {ok, SharedSecret :: binary()} | error;
    fun(srp, Username :: binary(), UserState :: term()) ->
      {ok, {SRPParams :: srp_param_type(), Salt :: binary(),
            DerivedKey :: binary()}} | error.

    For Pre-Shared Key (PSK) cipher suites, the lookup fun is called by the client and server to determine the shared secret. When called by the client, PSKIdentity is the hint presented by the server or undefined. When called by the server, PSKIdentity is the identity presented by the client.

    For Secure Remote Password (SRP), the fun is only used by the server to obtain parameters that it uses to generate its session keys. DerivedKey is to be derived according to RFC 2945 and RFC 5054: crypto:sha([Salt, crypto:sha([Username, <<$:>>, Password])])

-type common_option_tls13() ::
          {supported_groups, [group()]} | {key_update_at, KeyUpdateAt :: pos_integer()}.

Common options to both client and server for TLS-1.3.

  • {supported_groups, Groups} - Key exchange option

    TLS 1.3 introduces the "supported_groups" extension, which is used for negotiating the Diffie-Hellman parameters in a TLS 1.3 handshake. Both client and server can specify a list of parameters that they are willing to use.

    If not specified it will use a default list ([x25519, x448, secp256r1, secp384r1]) that is filtered based on the installed crypto library version.

  • {key_update_at, KeyUpdateAt} - Session key renewal

    Configures the maximum amount of bytes that can be sent on a TLS 1.3 connection before an automatic key update is performed.

    There are cryptographic limits on the amount of plaintext which can be safely encrypted under a given set of keys. The current default ensures that data integrity will not be breached with probability greater than 1/2^57. For more information see Limits on Authenticated Encryption Use in TLS.

Types: Info

-type connection_info() ::
          [{protocol, protocol_version()} |
           {session_resumption, boolean()} |
           {selected_cipher_suite, erl_cipher_suite()} |
           {sni_hostname, term()} |
           {ciphers, [erl_cipher_suite()]}] |
          connection_info_pre_tls13() |
          security_info().

Key value list convening some information about the established connection.

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connection_info_keys()

View Source
-type connection_info_keys() ::
          [protocol | selected_cipher_suite | sni_hostname | session_resumption | ciphers |
           client_random | server_random | master_secret | keylog | session_id | session_data | ecc |
           srp_username].

TLS connection keys for which information can be retrieved.

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connection_info_pre_tls13()

View Source (not exported)
-type connection_info_pre_tls13() ::
          [{session_id, session_id()} |
           {session_data, binary()} |
           {ecc, {named_curve, term()}} |
           {srp_username, term()}].

TLS connection information relevant prior to TLS-1.3.

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security_info()

View Source (not exported)
-type security_info() ::
          [{client_random, binary()} |
           {server_random, binary()} |
           {master_secret, binary()} |
           {keylog, term()}].

TLS connection information that can be used for NSS key logging.

Types: Deprecated

This type is deprecated. the type ssl:prf_random() is deprecated; Only used in deprecated function prf/5 and will no longer be needed..
-type prf_random() :: client_random | server_random.

Client API

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connect(TCPSocket, TLSOptions)

View Source (since OTP R14B)
-spec connect(TCPSocket, TLSOptions) -> {ok, sslsocket()} | {error, Reason}
                 when
                     TCPSocket :: socket(),
                     TLSOptions :: [tls_client_option()],
                     Reason :: closed | {options, any()} | error_alert() | reason().

Equivalent to connect(TCPSocket, TLSOptions, infinity).

Link to this function

connect(TCPSocketOrHost, TLSOptionsOrPort, TimeoutOrTLSOptions)

View Source
-spec connect(TCPSocketOrHost, TLSOptionsOrPort, TimeoutOrTLSOptions) ->
                 {ok, sslsocket()} | {ok, sslsocket(), Ext :: protocol_extensions()} | {error, Reason}
                 when
                     TCPSocketOrHost :: socket() | host(),
                     TLSOptionsOrPort :: [tls_client_option()] | inet:port_number(),
                     TimeoutOrTLSOptions :: [tls_client_option()] | timeout(),
                     Reason :: closed | timeout | {options, any()} | error_alert() | reason().

Opens a TLS/DTLS connection.

connect(TCPSocket, TLSOptions, Timeout).

Upgrades a gen_tcp (or equivalent) connected socket to a TLS socket by performing the client-side TLS handshake.

connect(Host, Port, TLSOptions).

Opens a TLS/DTLS connection to Host, Port. This call is equivalent to:

connect(Host, Port, TLSOptions, infinity).
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connect(Host, Port, TLSOptions, Timeout)

View Source
-spec connect(Host, Port, TLSOptions, Timeout) ->
                 {ok, sslsocket()} | {ok, sslsocket(), Ext :: protocol_extensions()} | {error, Reason}
                 when
                     Host :: host(),
                     Port :: inet:port_number(),
                     TLSOptions :: [tls_client_option()],
                     Timeout :: timeout(),
                     Reason :: closed | timeout | {options, any()} | error_alert() | reason().

Opens a TLS/DTLS connection to Host, Port.

When the verify option is set to verify_peer, the public_key:pkix_verify_hostname/2 check will be performed in addition to the usual X.509-path validation checks. If the check fails, the error {bad_cert, hostname_check_failed} will be propagated to the path validation fun, where it is possible to do customized checks by using the full possibilities of the public_key:pkix_verify_hostname/3 API. When the server_name_indication option is provided, its value (the DNS name) will be used as ReferenceID to public_key:pkix_verify_hostname/2. When no server_name_indication option is given, the Host argument will be used as Server Name Indication extension. The Host argument will also be used for the public_key:pkix_verify_hostname/2 check. If the Host argument is an inet:ip_address() the ReferenceID used for the check will be {ip, Host}; otherwise dns_id will be assumed with a fallback to ip if that fails.

Note

According to good practices, certificates should not use IP addresses as "server names", especially outside a closed network.

If the {handshake, hello} option is used, the handshake is paused after receiving the server hello message and the success response is {ok, SslSocket, Ext} instead of {ok, SslSocket}. Thereafter the handshake is continued or canceled by calling handshake_continue/3 or handshake_cancel/1.

If the active option is set to once, true, or an integer value, the process owning the SSL socket will receive messages of type active_msgs().

Server API

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handshake(HsSocket)

View Source (since OTP 21.0)
-spec handshake(HsSocket) -> {ok, SslSocket} | {ok, SslSocket, Ext} | {error, Reason}
                   when
                       HsSocket :: sslsocket(),
                       SslSocket :: sslsocket(),
                       Ext :: protocol_extensions(),
                       Reason :: closed | timeout | error_alert().

Equivalent to handshake(HsSocket, infinity).

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handshake(HsSocket, OptionsOrTimeout)

View Source (since OTP 21.0)
-spec handshake(HsSocket, OptionsOrTimeout) -> {ok, SslSocket} | {ok, SslSocket, Ext} | {error, Reason}
                   when
                       HsSocket :: sslsocket(),
                       OptionsOrTimeout :: timeout() | [server_option()],
                       SslSocket :: sslsocket(),
                       Ext :: protocol_extensions(),
                       Reason :: closed | timeout | error_alert().

Performs the TLS/DTLS server-side handshake.

If the second argument is a timeout value:

handshake(HsSocket, Timeout).

this call is equivalent to:

handshake(HsSocket, [], Timeout).

Otherwise, if the second argument is a list of options:

handshake(HsSocket, Options).

this call is equivalent to:

handshake(HsSocket, Options, infinity).
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handshake(Socket, Options, Timeout)

View Source (since OTP 21.0)
-spec handshake(Socket, Options, Timeout) -> {ok, SslSocket} | {ok, SslSocket, Ext} | {error, Reason}
                   when
                       Socket :: socket() | sslsocket(),
                       SslSocket :: sslsocket(),
                       Options :: [server_option()],
                       Timeout :: timeout(),
                       Ext :: protocol_extensions(),
                       Reason :: closed | timeout | {options, any()} | error_alert().

Performs the TLS/DTLS server-side handshake.

Returns a new TLS/DTLS socket if the handshake is successful.

If Socket is a ordinary socket(), upgrades a gen_tcp or equivalent socket to an SSL socket by performing the TLS server-side handshake and returning a TLS socket.

Note

The ordinary Socket must be in passive mode ({active, false}) before calling this function and before the client tries to connect with TLS; otherwise, the behavior of this function is undefined. The best way to ensure this is to create the ordinary listen socket in passive mode.

If Socket is an sslsocket(), provides extra TLS/DTLS options to those specified in listen/2 and then performs the TLS/DTLS handshake. Returns a new TLS/DTLS socket if the handshake is successful.

Warning

Not setting the timeout makes the server more vulnerable to Denial of Service (DoS) attacks.

If option {handshake, hello} is specified the handshake is paused after receiving the client hello message and the success response is {ok, SslSocket, Ext} instead of {ok, SslSocket}. Thereafter the handshake is continued or canceled by calling handshake_continue/3 or handshake_cancel/1.

If option active is set to once, true, or an integer value, the process owning the sslsocket() will receive messages of type active_msgs().

-spec listen(Port, Options) -> {ok, ListenSocket} | {error, Reason}
                when
                    Port :: inet:port_number(),
                    Options :: [tls_server_option()],
                    ListenSocket :: sslsocket(),
                    Reason :: {options, any()} | reason().

Creates an SSL listen socket.

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transport_accept(ListenSocket)

View Source
-spec transport_accept(ListenSocket) -> {ok, SslSocket} | {error, Reason}
                          when ListenSocket :: sslsocket(), SslSocket :: sslsocket(), Reason :: reason().

Equivalent to transport_accept(ListenSocket, infinity).

Link to this function

transport_accept(ListenSocket, Timeout)

View Source
-spec transport_accept(ListenSocket, Timeout) -> {ok, SslSocket} | {error, Reason}
                          when
                              ListenSocket :: sslsocket(),
                              Timeout :: timeout(),
                              SslSocket :: sslsocket(),
                              Reason :: reason().

Accepts an incoming connection request on a listen socket.

ListenSocket must be a socket returned from listen/2. The socket returned is to be passed to handshake/1,2,3 to complete the handshake and establish the TLS/DTLS connection.

Warning

Most API functions require that the TLS/DTLS connection is established to work as expected.

The accepted socket inherits the options set for ListenSocket in listen/2.

The default value for Timeout is infinity. If Timeout is specified and no connection is accepted within the given time, {error, timeout} is returned.

Client and Server API

-spec close(SslSocket) -> ok | {error, Reason} when SslSocket :: sslsocket(), Reason :: any().

Closes a TLS/DTLS connection.

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close(SslSocket, How)

View Source (since OTP 18.1)
-spec close(SslSocket, How) -> ok | {ok, port()} | {ok, port(), Data} | {error, Reason}
               when
                   SslSocket :: sslsocket(),
                   How :: timeout() | {NewController :: pid(), timeout()},
                   Data :: binary(),
                   Reason :: any().

Closes or downgrades a TLS connection.

In the latter case the transport connection will be handed over to the NewController process after receiving the TLS close alert from the peer. The returned transport socket will have the following options set: [{active, false}, {packet, 0}, {mode, binary}].

In case of downgrade, the close function might return some binary data that should be treated by the user as the first bytes received on the downgraded connection.

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controlling_process(SslSocket, NewOwner)

View Source
-spec controlling_process(SslSocket, NewOwner) -> ok | {error, Reason}
                             when SslSocket :: sslsocket(), NewOwner :: pid(), Reason :: any().

Assigns a new controlling process to the SSL socket.

A controlling process is the owner of an SSL socket and receives all messages from the socket.

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handshake_cancel(Socket)

View Source (since OTP 21.0)
-spec handshake_cancel(#sslsocket{fd :: term(), pid :: term()}) -> any().

Cancel the handshake with a fatal USER_CANCELED alert.

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handshake_continue(HsSocket, Options)

View Source (since OTP 21.0)
-spec handshake_continue(HsSocket, Options) -> {ok, SslSocket} | {error, Reason}
                            when
                                HsSocket :: sslsocket(),
                                Options :: [tls_client_option() | tls_server_option()],
                                SslSocket :: sslsocket(),
                                Reason :: closed | timeout | error_alert().

Equivalent to handshake_continue(HsSocket, Options, infinity).

Link to this function

handshake_continue(HsSocket, Options, Timeout)

View Source (since OTP 21.0)
-spec handshake_continue(HsSocket, Options, Timeout) -> {ok, SslSocket} | {error, Reason}
                            when
                                HsSocket :: sslsocket(),
                                Options :: [tls_client_option() | tls_server_option()],
                                Timeout :: timeout(),
                                SslSocket :: sslsocket(),
                                Reason :: closed | timeout | error_alert().

Continue the TLS handshake, possibly with new, additional, or changed options.

-spec recv(SslSocket, Length) -> {ok, Data} | {error, reason()}
              when
                  SslSocket :: sslsocket(),
                  Length :: non_neg_integer(),
                  Data :: binary() | list() | HttpPacket,
                  HttpPacket :: any().

Equivalent to recv(Socket, Length, infinity).

Link to this function

recv(SslSocket, Length, Timeout)

View Source
-spec recv(SslSocket, Length, Timeout) -> {ok, Data} | {error, reason()}
              when
                  SslSocket :: sslsocket(),
                  Length :: non_neg_integer(),
                  Data :: binary() | list() | HttpPacket,
                  Timeout :: timeout(),
                  HttpPacket :: any().

Receives a packet from a socket in passive mode.

A closed socket is indicated by return value {error, closed}. Argument Length is meaningful only when the socket is in mode raw and denotes the number of bytes to read. If Length is zero, all available bytes are returned. If Length is greater than zero, exactly Length bytes are returned, or an error; possibly discarding less than Length bytes of data when the socket gets closed from the other side.

Optional argument Timeout specifies a time-out in milliseconds. The default value is infinity.

-spec send(SslSocket, Data) -> ok | {error, reason()} when SslSocket :: sslsocket(), Data :: iodata().

Writes Data to SslSocket.

A notable return value is {error, closed} indicating that the socket is closed.

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setopts(SslSocket, Options)

View Source
-spec setopts(SslSocket, Options) -> ok | {error, reason()}
                 when SslSocket :: sslsocket(), Options :: [gen_tcp:option()].

Sets options according to Options for socket SslSocket.

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shutdown(SslSocket, How)

View Source (since OTP R14B)
-spec shutdown(SslSocket, How) -> ok | {error, reason()}
                  when SslSocket :: sslsocket(), How :: read | write | read_write.

Immediately closes a socket in one or two directions.

How == write means closing the socket for writing, but reading from it is still possible.

To handle siutations where the peer has performed a shutdown on the write side, option {exit_on_close, false} is useful.

TLS-1.3 Only API

Link to this function

groups()

View Source (since OTP 27.0)
-spec groups() -> [group()].

Returns all supported groups in TLS 1.3.

Existed since OTP 22.0; documented as of OTP 27.

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groups(Description)

View Source (since OTP 27.0)
-spec groups(Description) -> [group()] when Description :: default.

Returns default supported groups in TLS 1.3.

Existed since OTP 22.0; documented as of OTP 27.

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update_keys(SslSocket, Type)

View Source (since OTP 22.3)
-spec update_keys(SslSocket, Type) -> ok | {error, reason()}
                     when SslSocket :: sslsocket(), Type :: write | read_write.

Create new session keys.

There are cryptographic limits on the amount of plaintext which can be safely encrypted under a given set of keys. If the amount of data surpasses those limits, a key update is triggered and a new set of keys are installed. See also the key_update_at option in common_option_tls13/0.

This function can be used to explicitly start a key update on a TLS-1.3 connection. There are two types of key updates: if Type is write, only the writing key is updated; if Type is read_write, both the reading and writing keys are updated.

Pre TLS-1.3 API

-spec eccs() -> NamedCurves when NamedCurves :: [named_curve()].

Returns a list of all supported elliptic curves, including legacy curves, for all TLS/DTLS versions prior to TLS-1.3.

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eccs(Version)

View Source (since OTP 19.2)
-spec eccs(Version) -> NamedCurves
              when
                  Version :: 'tlsv1.2' | 'tlsv1.1' | tlsv1 | 'dtlsv1.2' | dtlsv1,
                  NamedCurves :: [named_curve()].

Returns the elliptic curves supported by default for Version.

This is a subset of what eccs/0 returns.

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renegotiate(SslSocket)

View Source (since OTP R14B)
-spec renegotiate(SslSocket) -> ok | {error, reason()} when SslSocket :: sslsocket().

Initiates a new handshake.

A notable return value is {error, renegotiation_rejected} indicating that the peer refused to go through with the renegotiation, but the connection is still active using the previously negotiated session.

TLS-1.3 has removed the renegotiation feature from earlier TLS versions and instead adds a new feature called key update, which replaces the most important part of renegotiation: the refreshing of session keys. This is triggered automatically after reaching a plaintext limit and can be configured using the key_update_at option in common_option_tls13/0.

Utility Functions

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append_cipher_suites(Deferred, Suites)

View Source (since OTP 20.3)
-spec append_cipher_suites(Deferred, Suites) -> ciphers()
                              when Deferred :: ciphers() | cipher_filters(), Suites :: ciphers().

Make Deferred suites become the least preferred suites.

The Deferred suites will be put at the end of the cipher suite list Suites after removing them from Suites if present. Deferred can be a list of cipher suites or a list of filters in which case the filters are used on Suites to extract the deferred cipher list.

Link to this function

cipher_suites(Description, Version)

View Source (since OTP 20.3)
-spec cipher_suites(Description, Version) -> ciphers()
                       when
                           Description :: default | all | exclusive | anonymous | exclusive_anonymous,
                           Version :: protocol_version().

Lists all available cipher suites corresponding to Description.

The exclusive and exclusive_anonymous option will exclusively list cipher suites first supported in Version, whereas the other options are inclusive from the lowest possible version to Version. The all option includes all suites except anonymous suites. No anonymous suites are supported by default.

Note

TLS-1.3 has no overlapping cipher suites with previous TLS versions, meaning that the result of cipher_suites(all, 'tlsv1.3') contains a separate set of suites that can be used with TLS-1.3 and another set that can be used if a lower version is negotiated. The so-called PSK and SRP suites (prior to TLS-1.3) need extra configuration to work; namely the option user_lookup_function. No anonymous suites are supported by TLS-1.3.

Also note that the cipher suites returned by this function are the cipher suites that the OTP SSL application can support provided that they are supported by the crypto library linked with the OTP Crypto application. Use ssl:filter_cipher_suites(Suites, []) to filter the list for the current crypto library. Note that cipher suites may be filtered out because they are too old or too new depending on the crypto library.

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cipher_suites(Description, Version, StringType)

View Source (since OTP 22.0)
-spec cipher_suites(Description, Version, StringType) -> [string()]
                       when
                           Description :: default | all | exclusive | anonymous,
                           Version :: protocol_version(),
                           StringType :: rfc | openssl.

Equivalent to cipher_suites/2, but lists RFC or OpenSSL string names instead of erl_cipher_suite().

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clear_pem_cache()

View Source (since OTP 17.5)
-spec clear_pem_cache() -> ok.

Clears the PEM cache.

PEM files, used by SSL API-functions, are cached for performance reasons. The cache is automatically checked at regular intervals to determine whether any cache entries should be invalidated.

This function provides a way to unconditionally clear the entire cache, thereby forcing a reload of previously cached PEM files.

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connection_information(SslSocket)

View Source (since OTP 18.0)
-spec connection_information(SslSocket) -> {ok, Result} | {error, reason()}
                                when SslSocket :: sslsocket(), Result :: connection_info().

Returns the most relevant information about the connection.

Some items that are undefined will be filtered out. No values that affect the security of the connection will be returned.

Note

The legacy cipher_suite item was removed in OTP 23. Previously it returned the cipher suite in its (undocumented) legacy format. It is replaced by selected_cipher_suite.

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connection_information(SslSocket, Items)

View Source (since OTP 18.0)
-spec connection_information(SslSocket, Items) -> {ok, Result} | {error, reason()}
                                when
                                    SslSocket :: sslsocket(),
                                    Items :: connection_info_keys(),
                                    Result :: connection_info().

Returns the requested information items about the connection if they are defined.

Note that the values for client_random, server_random, master_secret, and keylog affect the security of connection.

In order to retrieve keylog and other secret information from a TLS 1.3 connection, the keep_secrets option must be configured in advance and set to true.

Note

If only undefined options are requested the resulting list can be empty.

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export_key_materials(SslSocket, Labels, Contexts, WantedLengths)

View Source (since OTP 27.0)
-spec export_key_materials(SslSocket, Labels, Contexts, WantedLengths) ->
                              {ok, ExportKeyMaterials} | {error, reason()}
                              when
                                  SslSocket :: sslsocket(),
                                  Labels :: [binary()],
                                  Contexts :: [binary() | no_context],
                                  WantedLengths :: [non_neg_integer()],
                                  ExportKeyMaterials :: [binary()].

Equivalent to export_key_materials(TLSSocket, Labels, Contexts, WantedLengths, true).

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export_key_materials(SslSocket, Labels, Contexts, WantedLengths, ConsumeSecret)

View Source (since OTP 27.0)
-spec export_key_materials(SslSocket, Labels, Contexts, WantedLengths, ConsumeSecret) ->
                              {ok, ExportKeyMaterials} |
                              {error, exporter_master_secret_already_consumed | bad_input}
                              when
                                  SslSocket :: sslsocket(),
                                  Labels :: [binary()],
                                  Contexts :: [binary() | no_context],
                                  WantedLengths :: [non_neg_integer()],
                                  ConsumeSecret :: boolean(),
                                  ExportKeyMaterials :: [binary()].

Uses a Pseudo-Random Function (PRF prior to TLS-1.3) or a Key Derivation Function (HKDF in TLS-1.3) for a TLS connection to generate and export keying materials.

In TLS-1.3, using no_context is equivalent to specifying an empty context (an empty binary). Prior to TLS-1.3, no_context and an empty context will produce different results.

The ConsumeSecret argument is relevant only in TLS-1.3, causing the TLS-1.3 exporter_master_secret to be consumed, thereby making it unavailable and increasing security. Further attempts to call this function will fail.

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filter_cipher_suites(Suites, Filters)

View Source (since OTP 20.3)
-spec filter_cipher_suites(Suites, Filters) -> Ciphers
                              when
                                  Suites :: ciphers(), Filters :: cipher_filters(), Ciphers :: ciphers().

Removes cipher suites if any of the filter functions returns false for any part of the cipher suite.

If no filter function is supplied for some part, the default behavior treats it as a filter function that returns true. For examples, see Customizing cipher suites . Additionally, this function also filters the cipher suites to exclude cipher suites not supported by the crypto library used by the OTP Crypto application, meaning that ssl:filter_cipher_suites(Suites, []) is equivalent to applying only the filters for crypto library support.

-spec format_error(Error) -> ReasonStr when Error :: {error, reason()} | reason(), ReasonStr :: string().

Presents the error returned by an SSL function as a printable string.

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getopts(SslSocket, OptionNames)

View Source
-spec getopts(SslSocket, OptionNames) -> {ok, [gen_tcp:option()]} | {error, reason()}
                 when SslSocket :: sslsocket(), OptionNames :: [gen_tcp:option_name()].

Gets the values of the specified socket options.

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getstat(SslSocket)

View Source (since OTP 19.0)
-spec getstat(SslSocket) -> {ok, OptionValues} | {error, inet:posix()}
                 when SslSocket :: sslsocket(), OptionValues :: [{inet:stat_option(), integer()}].

Get statistics for the underlying socket.

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getstat(SslSocket, Options)

View Source (since OTP 19.0)
-spec getstat(SslSocket, Options) -> {ok, OptionValues} | {error, inet:posix()}
                 when
                     SslSocket :: sslsocket(),
                     Options :: [inet:stat_option()],
                     OptionValues :: [{inet:stat_option(), integer()}].

Get one or more statistic values for the underlying socket.

See inet:getstat/2 for further details.

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negotiated_protocol(SslSocket)

View Source (since OTP 18.0)
-spec negotiated_protocol(SslSocket) -> {ok, Protocol} | {error, Reason}
                             when
                                 SslSocket :: sslsocket(),
                                 Protocol :: binary(),
                                 Reason :: protocol_not_negotiated | closed.

Returns the protocol negotiated through ALPN or NPN extensions.

-spec peercert(SslSocket) -> {ok, Cert} | {error, reason()}
                  when SslSocket :: sslsocket(), Cert :: public_key:der_encoded().

The peer certificate is returned as a DER-encoded binary.

The certificate can be decoded with public_key:pkix_decode_cert/2. Suggested further reading about certificates is Public_Key User's Guide and SSL User's Guide.

-spec peername(SslSocket) -> {ok, {Address, Port}} | {error, reason()}
                  when
                      SslSocket :: sslsocket(), Address :: inet:ip_address(), Port :: inet:port_number().

Returns the address and port number of the peer.

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prepend_cipher_suites(Preferred, Suites)

View Source (since OTP 20.3)
-spec prepend_cipher_suites(Preferred, Suites) -> ciphers()
                               when Preferred :: ciphers() | cipher_filters(), Suites :: ciphers().

Make Preferred suites become the most preferred suites.

The Preferred suites will be put at the head of the cipher suite list Suites after removing them from Suites if present. Preferred can be a list of cipher suites or a list of filters in which case the filters are used on Suites to extract the preferred cipher list.

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signature_algs(Description, Version)

View Source (since OTP 26.0)
-spec signature_algs(Description, Version) -> signature_algs()
                        when Description :: default | all | exclusive, Version :: protocol_version().

Lists all available signature algorithms corresponding to Description.

The exclusive option will exclusively list algorithms or algorithm schemes for that protocol version, whereas the default and all options lists the combined list to support the range of protocols from (D)TLS-1.2, the first version to support configuration of the signature algorithms, to Version.

Example:

1> ssl:signature_algs(default, 'tlsv1.3').
[eddsa_ed25519,eddsa_ed448,ecdsa_secp521r1_sha512,
ecdsa_secp384r1_sha384,ecdsa_secp256r1_sha256,
rsa_pss_pss_sha512,rsa_pss_pss_sha384,rsa_pss_pss_sha256,
rsa_pss_rsae_sha512,rsa_pss_rsae_sha384,rsa_pss_rsae_sha256,
rsa_pkcs1_sha512,rsa_pkcs1_sha384,rsa_pkcs1_sha256,
{sha512,ecdsa},
{sha384,ecdsa},
{sha256,ecdsa}]

2> ssl:signature_algs(all, 'tlsv1.3').
[eddsa_ed25519,eddsa_ed448,ecdsa_secp521r1_sha512,
ecdsa_secp384r1_sha384,ecdsa_secp256r1_sha256,
rsa_pss_pss_sha512,rsa_pss_pss_sha384,rsa_pss_pss_sha256,
rsa_pss_rsae_sha512,rsa_pss_rsae_sha384,rsa_pss_rsae_sha256,
rsa_pkcs1_sha512,rsa_pkcs1_sha384,rsa_pkcs1_sha256,
{sha512,ecdsa},
{sha384,ecdsa},
{sha256,ecdsa},
{sha224,ecdsa},
{sha224,rsa},
{sha,rsa},
{sha,dsa}]

3> ssl:signature_algs(exclusive, 'tlsv1.3').
[eddsa_ed25519,eddsa_ed448,ecdsa_secp521r1_sha512,
ecdsa_secp384r1_sha384,ecdsa_secp256r1_sha256,
rsa_pss_pss_sha512,rsa_pss_pss_sha384,rsa_pss_pss_sha256,
rsa_pss_rsae_sha512,rsa_pss_rsae_sha384,rsa_pss_rsae_sha256]

Note

Some TLS-1-3 scheme names overlap with TLS-1.2 algorithm-tuple-pair-names and then TLS-1.3 names will be used, for example rsa_pkcs1_sha256 instead of {sha256, rsa}. These are legacy algorithms in TLS-1.3 that apply only to certificate signatures in this version of the protocol.

-spec sockname(SslSocket) -> {ok, {Address, Port}} | {error, reason()}
                  when
                      SslSocket :: sslsocket(), Address :: inet:ip_address(), Port :: inet:port_number().

Returns the local address and port number of socket SslSocket.

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start()

View Source (since OTP R14B)
-spec start() -> ok | {error, reason()}.

Equivalent to start(temporary).

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start(Type)

View Source (since OTP R14B)
-spec start(permanent | transient | temporary) -> ok | {error, reason()}.

Starts the SSL application.

-spec stop() -> ok.

Stops the SSL application.

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str_to_suite(CipherSuiteName)

View Source (since OTP 22.0)
-spec str_to_suite(CipherSuiteName) -> erl_cipher_suite() | {error, {not_recognized, CipherSuiteName}}
                      when CipherSuiteName :: string().

Converts an RFC or OpenSSL name string to an erl_cipher_suite/0

Returns an error if the cipher suite is not supported or the name is not a valid cipher suite name.

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suite_to_openssl_str(CipherSuite)

View Source (since OTP 22.0)
-spec suite_to_openssl_str(CipherSuite) -> string() when CipherSuite :: erl_cipher_suite().

Converts an erl_cipher_suite() value to an OpenSSL name string.

PRE TLS-1.3 these names differ for RFC names

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suite_to_str(CipherSuite)

View Source (since OTP 21.0)
-spec suite_to_str(CipherSuite) -> string() when CipherSuite :: erl_cipher_suite().

Converts an erl_cipher_suite() value to an RFC name string.

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versions()

View Source (since OTP R14B)
-spec versions() -> [VersionInfo]
                  when
                      VersionInfo ::
                          {ssl_app, string()} |
                          {supported | available | implemented, [tls_version()]} |
                          {supported_dtls | available_dtls | implemented_dtls, [dtls_version()]}.

Lists information, mainly concerning TLS/DTLS versions, in runtime for debugging and testing purposes.

  • app_vsn - The application version of the SSL application.

  • supported - TLS versions supported with current application environment and crypto library configuration. Overridden by a version option on connect/2,3,4, listen/2, and handshake/2,3. For the negotiated TLS version, see connection_information/1.

  • supported_dtls - DTLS versions supported with current application environment and crypto library configuration. Overridden by a version option on connect/2,3,4, listen/2, and handshake/2,3. For the negotiated DTLS version, see connection_information/1.

  • available - All TLS versions supported with the linked crypto library.

  • available_dtls - All DTLS versions supported with the linked crypto library.

  • implemented - All TLS versions supported by the SSL application if linked with a crypto library with the necessary support.

  • implemented_dtls - All DTLS versions supported by the SSL application if linked with a crypto library with the necessary support.

Deprecated API

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prf(SslSocket, Secret, Label, Seed, WantedLength)

View Source (since OTP R15B01)
This function is deprecated. ssl:prf/5 is deprecated; Use export_key_materials/4 instead. Note that in OTP 28 the 'testing' way of calling this function will no longer be supported..
-spec prf(SslSocket, Secret, Label, Seed, WantedLength) -> {ok, binary()} | {error, reason()}
             when
                 SslSocket :: sslsocket(),
                 Secret :: binary() | master_secret,
                 Label :: binary(),
                 Seed :: [binary() | prf_random()],
                 WantedLength :: non_neg_integer().

Uses the Pseudo-Random Function (PRF) of a TLS session to generate extra key material.

It either takes user-generated values for Secret and Seed or atoms directing it to use a specific value from the session security parameters.

Note

This function is replaced by export_key_materials/4, the officially documented API function since OTP 27, which is equivalent to prf(TLSSocket, master_secret, Label, [client_random, server_random, Context], WantedLength). Other ways of calling this function were for testing purposes only and has no use case. When called in a TLS-1.3 context it will now behave as export_key_materials(TLSSocket, [Label], [Context], [WantedLength]).