SSL_CTX_SET_TMP_RSA_CALLBACK.POD(3) | Library Functions Manual | SSL_CTX_SET_TMP_RSA_CALLBACK.POD(3) |

`SSL_CTX_set_tmp_rsa_callback`

,
`SSL_CTX_set_tmp_rsa`

,
`SSL_CTX_need_tmp_RSA`

,
`SSL_set_tmp_rsa_callback`

,
`SSL_set_tmp_rsa`

,
`SSL_need_tmp_rsa`

— handle
RSA keys for ephemeral key exchange

```
#include
<openssl/ssl.h>
```

`void`

`SSL_CTX_set_tmp_rsa_callback`

(`SSL_CTX
*ctx`, `RSA *(*tmp_rsa_callback)(SSL *ssl, int
is_export, int keylength)`);

`long`

`SSL_CTX_set_tmp_rsa`

(`SSL_CTX
*ctx`, `RSA
*rsa`);

`long`

`SSL_CTX_need_tmp_RSA`

(`SSL_CTX
*ctx`);

`void`

`SSL_set_tmp_rsa_callback`

(`SSL_CTX
*ctx`, `RSA *(*tmp_rsa_callback)(SSL *ssl, int
is_export, int keylength)`);

`long`

`SSL_set_tmp_rsa`

(`SSL
*ssl`, `RSA
*rsa`);

`long`

`SSL_need_tmp_rsa`

(`SSL
*ssl`);

`RSA *`

`(*tmp_rsa_callback)`

(`SSL
*ssl`, `int
is_export`, `int
keylength`);

`SSL_CTX_set_tmp_rsa_callback`

()
sets the callback function for `ctx` to be used when a
temporary/ephemeral RSA key is required to
`tmp_rsa_callback`. The callback is inherited by all
`SSL` objects newly created from
`ctx` with
SSL_new(3). Already created
SSL objects are not affected.

`SSL_CTX_set_tmp_rsa`

()
sets the temporary/ephemeral RSA key to be used to be
`rsa`. The key is inherited by all
`SSL` objects newly created from
`ctx` with
SSL_new(3). Already created
SSL objects are not affected.

`SSL_CTX_need_tmp_RSA`

()
returns 1, if a temporary/ephemeral RSA key is needed for RSA-based
strength-limited ‘exportable’ ciphersuites because a RSA key
with a keysize larger than 512 bits is installed.

`SSL_set_tmp_rsa_callback`

()
sets the callback only for `ssl`.

`SSL_set_tmp_rsa`

()
sets the key only for `ssl`.

`SSL_need_tmp_rsa`

()
returns 1, if a temporary/ephemeral RSA key is needed for RSA-based
strength-limited ‘exportable’ ciphersuites because a RSA key
with a keysize larger than 512 bits is installed.

These functions apply to SSL/TLS servers only.

When using a cipher with RSA authentication, an ephemeral RSA key exchange can take place. In this case the session data are negotiated using the ephemeral/temporary RSA key and the RSA key supplied and certified by the certificate chain is only used for signing.

Under previous export restrictions, ciphers with RSA keys shorter (512 bits) than the usual key length of 1024 bits were created. To use these ciphers with RSA keys of usual length, an ephemeral key exchange must be performed, as the normal (certified) key cannot be directly used.

Using ephemeral RSA key exchange yields forward secrecy, as the connection can only be decrypted when the RSA key is known. By generating a temporary RSA key inside the server application that is lost when the application is left, it becomes impossible for an attacker to decrypt past sessions, even if he gets hold of the normal (certified) RSA key, as this key was used for signing only. The downside is that creating a RSA key is computationally expensive.

Additionally, the use of ephemeral RSA key exchange is only allowed in the TLS standard when the RSA key can be used for signing only, that is, for export ciphers. Using ephemeral RSA key exchange for other purposes violates the standard and can break interoperability with clients. It is therefore strongly recommended to not use ephemeral RSA key exchange and use DHE (Ephemeral Diffie-Hellman) key exchange instead in order to achieve forward secrecy (see SSL_CTX_set_tmp_dh_callback(3)).

On OpenSSL servers ephemeral RSA key exchange is therefore
disabled by default and must be explicitly enabled using the
`SSL_OP_EPHEMERAL_RSA`

option of
SSL_CTX_set_options(3),
violating the TLS/SSL standard. When ephemeral RSA key exchange is required
for export ciphers, it will automatically be used without this option!

An application may either directly specify the key or can supply
the key via a callback function. The callback approach has the advantage
that the callback may generate the key only in case it is actually needed.
However, as the generation of a RSA key is costly, it will lead to a
significant delay in the handshake procedure. Another advantage of the
callback function is that it can supply keys of different size (e.g., for
`SSL_OP_EPHEMERAL_RSA`

usage) while the explicit
setting of the key is only useful for key size of 512 bits to satisfy the
export restricted ciphers and does give away key length if a longer key
would be allowed.

The `tmp_rsa_callback` is called with the
`keylength` needed and the
`is_export` information. The
`is_export` flag is set when the ephemeral RSA key
exchange is performed with an export cipher.

`SSL_CTX_set_tmp_rsa_callback`

() and
`SSL_set_tmp_rsa_callback`

() do not return diagnostic
output.

`SSL_CTX_set_tmp_rsa`

() and
`SSL_set_tmp_rsa`

() return 1 on success and 0 on
failure. Check the error queue to find out the reason of failure.

`SSL_CTX_need_tmp_RSA`

() and
`SSL_need_tmp_rsa`

() return 1 if a temporary RSA key
is needed and 0 otherwise.

Generate temporary RSA keys to prepare ephemeral RSA key exchange. As the generation of a RSA key costs a lot of computer time, they are saved for later reuse. For demonstration purposes, two keys for 512 bits and 1024 bits respectively are generated.

... /* Set up ephemeral RSA stuff */ RSA *rsa_512 = NULL; RSA *rsa_1024 = NULL; rsa_512 = RSA_generate_key(512, RSA_F4, NULL, NULL); if (rsa_512 == NULL) evaluate_error_queue(); rsa_1024 = RSA_generate_key(1024, RSA_F4, NULL, NULL); if (rsa_1024 == NULL) evaluate_error_queue(); ... RSA * tmp_rsa_callback(SSL *s, int is_export, int keylength) { RSA *rsa_tmp = NULL; switch (keylength) { case 512: if (rsa_512) rsa_tmp = rsa_512; else { /* * generate on the fly, * should not happen in this example */ rsa_tmp = RSA_generate_key(keylength, RSA_F4, NULL, NULL); rsa_512 = rsa_tmp; /* Remember for later reuse */ } break; case 1024: if (rsa_1024) rsa_tmp = rsa_1024; else should_not_happen_in_this_example(); break; default: /* * Generating a key on the fly is very costly, * so use what is there */ if (rsa_1024) rsa_tmp = rsa_1024; else /* Use at least a shorter key */ rsa_tmp = rsa_512; } return rsa_tmp; }

openssl(1), ssl(3), SSL_CTX_set_cipher_list(3), SSL_CTX_set_options(3), SSL_CTX_set_tmp_dh_callback(3), SSL_new(3)

December 6, 2016 | OpenBSD-6.1 |