2 * Copyright (c) 2016 Thomas Pornin <pornin@bolet.org>
4 * Permission is hereby granted, free of charge, to any person obtaining
5 * a copy of this software and associated documentation files (the
6 * "Software"), to deal in the Software without restriction, including
7 * without limitation the rights to use, copy, modify, merge, publish,
8 * distribute, sublicense, and/or sell copies of the Software, and to
9 * permit persons to whom the Software is furnished to do so, subject to
10 * the following conditions:
12 * The above copyright notice and this permission notice shall be
13 * included in all copies or substantial portions of the Software.
15 * THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND,
16 * EXPRESS OR IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF
17 * MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND
18 * NONINFRINGEMENT. IN NO EVENT SHALL THE AUTHORS OR COPYRIGHT HOLDERS
19 * BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER LIABILITY, WHETHER IN AN
20 * ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, OUT OF OR IN
21 * CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE
28 * A "profile" is an initialisation function for a SSL context, that
29 * configures a list of cipher suites and algorithm implementations.
30 * While BearSSL comes with a few predefined profiles, you might one
31 * to define you own, using the example below as guidance.
33 * Each individual initialisation call sets a parameter or an algorithm
34 * support. Setting a specific algorithm pulls in the implementation of
35 * that algorithm in the compiled binary, as per static linking
36 * behaviour. Removing some of this calls will then reduce total code
37 * footprint, but also mechanically prevents some features to be
38 * supported (protocol versions and cipher suites).
40 * The two below define profiles for the client and the server contexts,
41 * respectively. Of course, in a typical size-constrained application,
42 * you would use one or the other, not both, to avoid pulling in code
47 example_client_profile(br_ssl_client_context
*cc
48 /* and possibly some other arguments */)
51 * A list of cipher suites, by preference (first is most
52 * preferred). The list below contains all cipher suites supported
53 * by BearSSL; trim it done to your needs.
55 static const uint16_t suites
[] = {
56 BR_TLS_ECDHE_ECDSA_WITH_CHACHA20_POLY1305_SHA256
,
57 BR_TLS_ECDHE_RSA_WITH_CHACHA20_POLY1305_SHA256
,
58 BR_TLS_ECDHE_ECDSA_WITH_AES_128_GCM_SHA256
,
59 BR_TLS_ECDHE_RSA_WITH_AES_128_GCM_SHA256
,
60 BR_TLS_ECDHE_ECDSA_WITH_AES_256_GCM_SHA384
,
61 BR_TLS_ECDHE_RSA_WITH_AES_256_GCM_SHA384
,
62 BR_TLS_ECDHE_ECDSA_WITH_AES_128_CBC_SHA256
,
63 BR_TLS_ECDHE_RSA_WITH_AES_128_CBC_SHA256
,
64 BR_TLS_ECDHE_ECDSA_WITH_AES_256_CBC_SHA384
,
65 BR_TLS_ECDHE_RSA_WITH_AES_256_CBC_SHA384
,
66 BR_TLS_ECDHE_ECDSA_WITH_AES_128_CBC_SHA
,
67 BR_TLS_ECDHE_RSA_WITH_AES_128_CBC_SHA
,
68 BR_TLS_ECDHE_ECDSA_WITH_AES_256_CBC_SHA
,
69 BR_TLS_ECDHE_RSA_WITH_AES_256_CBC_SHA
,
70 BR_TLS_ECDH_ECDSA_WITH_AES_128_GCM_SHA256
,
71 BR_TLS_ECDH_RSA_WITH_AES_128_GCM_SHA256
,
72 BR_TLS_ECDH_ECDSA_WITH_AES_256_GCM_SHA384
,
73 BR_TLS_ECDH_RSA_WITH_AES_256_GCM_SHA384
,
74 BR_TLS_ECDH_ECDSA_WITH_AES_128_CBC_SHA256
,
75 BR_TLS_ECDH_RSA_WITH_AES_128_CBC_SHA256
,
76 BR_TLS_ECDH_ECDSA_WITH_AES_256_CBC_SHA384
,
77 BR_TLS_ECDH_RSA_WITH_AES_256_CBC_SHA384
,
78 BR_TLS_ECDH_ECDSA_WITH_AES_128_CBC_SHA
,
79 BR_TLS_ECDH_RSA_WITH_AES_128_CBC_SHA
,
80 BR_TLS_ECDH_ECDSA_WITH_AES_256_CBC_SHA
,
81 BR_TLS_ECDH_RSA_WITH_AES_256_CBC_SHA
,
82 BR_TLS_RSA_WITH_AES_128_GCM_SHA256
,
83 BR_TLS_RSA_WITH_AES_256_GCM_SHA384
,
84 BR_TLS_RSA_WITH_AES_128_CBC_SHA256
,
85 BR_TLS_RSA_WITH_AES_256_CBC_SHA256
,
86 BR_TLS_RSA_WITH_AES_128_CBC_SHA
,
87 BR_TLS_RSA_WITH_AES_256_CBC_SHA
,
88 BR_TLS_ECDHE_ECDSA_WITH_3DES_EDE_CBC_SHA
,
89 BR_TLS_ECDHE_RSA_WITH_3DES_EDE_CBC_SHA
,
90 BR_TLS_ECDH_ECDSA_WITH_3DES_EDE_CBC_SHA
,
91 BR_TLS_ECDH_RSA_WITH_3DES_EDE_CBC_SHA
,
92 BR_TLS_RSA_WITH_3DES_EDE_CBC_SHA
96 * Client context must be cleared at some point. This sets
97 * every value and pointer to 0 or NULL.
99 br_ssl_client_zero(cc
);
102 * Define minimum and maximum protocol versions. Supported
108 br_ssl_engine_set_versions(&cc
->eng
, BR_TLS10
, BR_TLS12
);
111 * Set the PRF implementation(s).
112 * For TLS 1.0 and 1.1, the "prf10" is needed.
113 * For TLS 1.2, this depends on the cipher suite:
114 * -- cipher suites with a name ending in "SHA384" need "prf_sha384";
115 * -- all others need "prf_sha256".
117 * Note that a cipher suite like TLS_RSA_WITH_AES_128_CBC_SHA will
118 * use SHA-1 for the per-record MAC (that's what the final "SHA"
119 * means), but still SHA-256 for the PRF when selected along with
120 * the TLS-1.2 protocol version.
122 br_ssl_engine_set_prf10(&cc
->eng
, &br_tls10_prf
);
123 br_ssl_engine_set_prf_sha256(&cc
->eng
, &br_tls12_sha256_prf
);
124 br_ssl_engine_set_prf_sha384(&cc
->eng
, &br_tls12_sha384_prf
);
127 * Set hash functions for the engine. Required hash functions
128 * depend on the protocol and cipher suite:
130 * -- TLS 1.0 and 1.1 require both MD5 and SHA-1.
131 * -- With TLS 1.2, cipher suites with a name ending in "SHA384"
133 * -- With TLS 1.2, cipher suites with a name ending in "SHA256"
135 * -- With TLS 1.2, cipher suites with a name ending in "SHA"
136 * require both SHA-256 and SHA-1.
138 * Moreover, these hash functions are also used to compute
139 * hashes supporting signatures on the server side (for ECDHE_*
140 * cipher suites), and on the client side (for client
141 * certificates, except in the case of full static ECDH). In TLS
142 * 1.0 and 1.1, SHA-1 (and also MD5) will be used, but with TLS
143 * 1.2 these hash functions are negotiated between client and
144 * server; SHA-256 and/or SHA-384 should be sufficient in
147 * Note that with current implementations, SHA-224 and SHA-256
148 * share the same file, so if you use one, you may have the other
149 * one with no additional overhead. Similarly, SHA-384 and SHA-512
150 * share the same implementation code.
152 br_ssl_engine_set_hash(&cc
->eng
, br_md5_ID
, &br_md5_vtable
);
153 br_ssl_engine_set_hash(&cc
->eng
, br_sha1_ID
, &br_sha1_vtable
);
154 br_ssl_engine_set_hash(&cc
->eng
, br_sha224_ID
, &br_sha224_vtable
);
155 br_ssl_engine_set_hash(&cc
->eng
, br_sha256_ID
, &br_sha256_vtable
);
156 br_ssl_engine_set_hash(&cc
->eng
, br_sha384_ID
, &br_sha384_vtable
);
157 br_ssl_engine_set_hash(&cc
->eng
, br_sha512_ID
, &br_sha512_vtable
);
160 * Set the cipher suites. All specified cipher suite MUST be
161 * supported, and the relevant algorithms MUST have been
162 * configured (failure to provide needed implementations may
163 * trigger unwanted behaviours like segfaults or overflows).
165 br_ssl_engine_set_suites(&cc
->eng
, suites
,
166 (sizeof suites
) / (sizeof suites
[0]));
169 * Public-key algorithm implementations.
171 * -- RSA public core ("rsapub") is needed for "RSA" key exchange
172 * (cipher suites whose name starts with TLS_RSA).
174 * -- RSA signature verification ("rsavrfy") is needed for
175 * "ECDHE_RSA" cipher suites (not ECDH_RSA).
177 * -- Elliptic curve implementation ("ec") is needed for cipher
178 * suites that use elliptic curves (both "ECDH" and "ECDHE"
181 * -- ECDSA signature verification is needed for "ECDHE_ECDSA"
182 * cipher suites (but not for ECDHE_RSA, ECDH_ECDSA or ECDH_RSA).
184 * Normally, you use the "default" implementations, obtained
185 * through relevant function calls. These functions return
186 * implementations that are deemed "best" for the current
187 * platform, where "best" means "fastest within constant-time
188 * implementations". Selecting the default implementation is a
189 * mixture of compile-time and runtime checks.
191 * Nevertheless, specific implementations may be selected
192 * explicitly, e.g. to use code which is slower but with a
195 * The RSA code comes in three variants, called "i15", "i31" and
196 * "i32". The "i31" code is somewhat faster than the "i32" code.
197 * Usually, "i31" is faster than "i15", except on some specific
198 * architectures (ARM Cortex M0, M0+, M1 and M3) where the "i15"
199 * should be preferred (the "i15" code is constant-time, while
200 * the "i31" is not, and the "i15" code is faster anyway).
202 * ECDSA code also comes in "i15" and "i31" variants. As in the
203 * case of RSA, the "i31" code is faster, except on the small
204 * ARM Cortex M, where the "i15" code is faster and safer.
206 * There are no less than 10 elliptic curve implementations:
208 * - ec_c25519_i15, ec_c25519_i31, ec_c25519_m15 and ec_c25519_m31
209 * implement Curve25519.
211 * - ec_p256_m15 and ec_p256_m31 implement NIST curve P-256.
213 * - ec_prime_i15 and ec_prime_i31 implement NIST curves P-256,
216 * - ec_all_m15 is an aggregate implementation that uses
217 * ec_c25519_m15, ec_p256_m15 and ec_prime_i15.
219 * - ec_all_m31 is an aggregate implementation that uses
220 * ec_c25519_m31, ec_p256_m31 and ec_prime_i31.
222 * For a given curve, "m15" is faster than "i15" (but possibly
223 * with a larger code footprint) and "m31" is faster than "i31"
224 * (there again with a larger code footprint). For best
225 * performance, use ec_all_m31, except on the small ARM Cortex M
226 * where ec_all_m15 should be used. Referencing the other
227 * implementations directly will result in smaller code, but
228 * support for fewer curves and possibly lower performance.
230 br_ssl_client_set_default_rsapub(cc
);
231 br_ssl_engine_set_default_rsavrfy(&cc
->eng
);
232 br_ssl_engine_set_default_ecdsa(&cc
->eng
);
233 /* Alternate: set implementations explicitly.
234 br_ssl_client_set_rsapub(cc, &br_rsa_i31_public);
235 br_ssl_client_set_rsavrfy(cc, &br_rsa_i31_pkcs1_vrfy);
236 br_ssl_engine_set_ec(&cc->eng, &br_ec_all_m31);
237 br_ssl_engine_set_ecdsa(&cc->eng, &br_ecdsa_i31_vrfy_asn1);
242 * -- Cipher suites in AES_128_CBC, AES_256_CBC and 3DES_EDE_CBC
243 * need the CBC record handler ("set_cbc").
244 * -- Cipher suites in AES_128_GCM and AES_256_GCM need the GCM
245 * record handler ("set_gcm").
246 * -- Cipher suites in CHACHA20_POLY1305 need the ChaCha20+Poly1305
247 * record handler ("set_chapol").
249 br_ssl_engine_set_cbc(&cc
->eng
,
250 &br_sslrec_in_cbc_vtable
,
251 &br_sslrec_out_cbc_vtable
);
252 br_ssl_engine_set_gcm(&cc
->eng
,
253 &br_sslrec_in_gcm_vtable
,
254 &br_sslrec_out_gcm_vtable
);
255 br_ssl_engine_set_chapol(&cc
->eng
,
256 &br_sslrec_in_chapol_vtable
,
257 &br_sslrec_out_chapol_vtable
);
260 * Symmetric encryption:
261 * -- AES_128_CBC and AES_256_CBC require an "aes_cbc" implementation
262 * (actually two implementations, for encryption and decryption).
263 * -- 3DES_EDE_CBC requires a "des_cbc" implementation
264 * (actually two implementations, for encryption and decryption).
265 * -- AES_128_GCM and AES_256_GCM require an "aes_ctr" imeplementation
266 * and also a GHASH implementation.
268 * Two 3DES implementations are provided:
270 * des_tab Classical table-based implementation; it is
273 * dest_ct Constant-time DES/3DES implementation. It is
274 * slower than des_tab.
276 * Four AES implementations are provided:
278 * aes_ct Constant-time AES implementation, for 32-bit
281 * aes_ct64 Constant-time AES implementation, for 64-bit
282 * systems. It actually also runs on 32-bit systems,
283 * but, on such systems, it yields larger code and
284 * slightly worse performance. On 64-bit systems,
285 * aes_ct64 is about twice faster than aes_ct for
286 * CTR processing (GCM encryption and decryption),
287 * and for CBC (decryption only).
289 * aes_small Smallest implementation provided, but also the
290 * slowest, and it is not constant-time. Use it
291 * only if desperate for code size.
293 * aes_big Classical table-based AES implementation. This
294 * is decently fast and still resonably compact,
295 * but it is not constant-time.
297 * aes_x86ni Very fast implementation that uses the AES-NI
298 * opcodes on recent x86 CPU. But it may not be
299 * compiled in the library if the compiler or
300 * architecture is not supported; and the CPU
301 * may also not support the opcodes. Selection
302 * functions are provided to test for availability
303 * of the code and the opcodes.
305 * Whether having constant-time implementations is absolutely
306 * required for security depends on the context (in particular
307 * whether the target architecture actually has cache memory),
308 * and while side-channel analysis for non-constant-time AES
309 * code has been demonstrated in lab conditions, it certainly
310 * does not apply to all actual usages, and it has never been
311 * spotted in the wild. It is still considered cautious to use
312 * constant-time code by default, and to consider the other
313 * implementations only if duly measured performance issues make
316 br_ssl_engine_set_aes_cbc(&cc
->eng
,
317 &br_aes_ct_cbcenc_vtable
,
318 &br_aes_ct_cbcdec_vtable
);
319 br_ssl_engine_set_aes_ctr(&cc
->eng
,
320 &br_aes_ct_ctr_vtable
);
321 /* Alternate: aes_ct64
322 br_ssl_engine_set_aes_cbc(&cc->eng,
323 &br_aes_ct64_cbcenc_vtable,
324 &br_aes_ct64_cbcdec_vtable);
325 br_ssl_engine_set_aes_ctr(&cc->eng,
326 &br_aes_ct64_ctr_vtable);
328 /* Alternate: aes_small
329 br_ssl_engine_set_aes_cbc(&cc->eng,
330 &br_aes_small_cbcenc_vtable,
331 &br_aes_small_cbcdec_vtable);
332 br_ssl_engine_set_aes_ctr(&cc->eng,
333 &br_aes_small_ctr_vtable);
335 /* Alternate: aes_big
336 br_ssl_engine_set_aes_cbc(&cc->eng,
337 &br_aes_big_cbcenc_vtable,
338 &br_aes_big_cbcdec_vtable);
339 br_ssl_engine_set_aes_ctr(&cc->eng,
340 &br_aes_big_ctr_vtable);
342 br_ssl_engine_set_des_cbc(&cc
->eng
,
343 &br_des_ct_cbcenc_vtable
,
344 &br_des_ct_cbcdec_vtable
);
345 /* Alternate: des_tab
346 br_ssl_engine_set_des_cbc(&cc->eng,
347 &br_des_tab_cbcenc_vtable,
348 &br_des_tab_cbcdec_vtable);
352 * GHASH is needed for AES_128_GCM and AES_256_GCM. Three
353 * implementations are provided:
355 * ctmul Uses 32-bit multiplications with a 64-bit result.
357 * ctmul32 Uses 32-bit multiplications with a 32-bit result.
359 * ctmul64 Uses 64-bit multiplications with a 64-bit result.
361 * On 64-bit platforms, ctmul64 is the smallest and fastest of
362 * the three. On 32-bit systems, ctmul should be preferred. The
363 * ctmul32 implementation is meant to be used for the specific
364 * 32-bit systems that do not have a 32x32->64 multiplier (i.e.
365 * the ARM Cortex-M0 and Cortex-M0+).
367 * These implementations are all constant-time as long as the
368 * underlying multiplication opcode is constant-time (which is
369 * true for all modern systems, but not for older architectures
370 * such that ARM9 or 80486).
372 br_ssl_engine_set_ghash(&cc
->eng
,
374 /* Alternate: ghash_ctmul32
375 br_ssl_engine_set_ghash(&cc->eng,
378 /* Alternate: ghash_ctmul64
379 br_ssl_engine_set_ghash(&cc->eng,
385 * For a client, the normal case is to validate the server
386 * certificate with regards to a set of trust anchors. This
387 * entails using a br_x509_minimal_context structure, configured
388 * with the relevant algorithms, as shown below.
390 * Alternatively, the client could "know" the intended server
391 * public key through an out-of-band mechanism, in which case
392 * a br_x509_knownkey_context is appropriate, for a much reduced
395 * We assume here that the following extra parameters have been
398 * xc engine context (br_x509_minimal_context *)
399 * trust_anchors trust anchors (br_x509_trust_anchor *)
400 * trust_anchors_num number of trust anchors (size_t)
404 * The X.509 engine needs a hash function for processing the
405 * subject and issuer DN of certificates and trust anchors. Any
406 * supported hash function is appropriate; here we use SHA-256.
409 br_x509_minimal_init(xc
, &br_sha256_vtable
,
410 trust_anchors
, trust_anchors_num
);
413 * Set suites and asymmetric crypto implementations. We use the
414 * "i31" code for RSA (it is somewhat faster than the "i32"
415 * implementation). These implementations are used for
416 * signature verification on certificates, but not for the
417 * SSL-specific usage of the server's public key. For instance,
418 * if the server has an EC public key but the rest of the chain
419 * (intermediate CA, root...) use RSA, then you would need only
420 * the RSA verification function below.
422 br_x509_minimal_set_rsa(xc
, &br_rsa_i31_pkcs1_vrfy
);
423 br_x509_minimal_set_ecdsa(xc
,
424 &br_ec_prime_i31
, &br_ecdsa_i31_vrfy_asn1
);
427 * Set supported hash functions. These are for signatures on
428 * certificates. There again, you only need the hash functions
429 * that are actually used in certificates, but if a given
430 * function was included for the SSL engine, you may as well
433 * Note: the engine explicitly rejects signatures that use MD5.
434 * Thus, there is no need for MD5 here.
436 br_ssl_engine_set_hash(xc
, br_sha1_ID
, &br_sha1_vtable
);
437 br_ssl_engine_set_hash(xc
, br_sha224_ID
, &br_sha224_vtable
);
438 br_ssl_engine_set_hash(xc
, br_sha256_ID
, &br_sha256_vtable
);
439 br_ssl_engine_set_hash(xc
, br_sha384_ID
, &br_sha384_vtable
);
440 br_ssl_engine_set_hash(xc
, br_sha512_ID
, &br_sha512_vtable
);
443 * Link the X.509 engine in the SSL engine.
445 br_ssl_engine_set_x509(&cc
->eng
, &xc
->vtable
);
450 * Example server profile. Most of it is shared with the client
451 * profile, so see the comments in the client function for details.
453 * This example function assumes a server with a (unique) RSA private
454 * key, so the list of cipher suites is trimmed down for RSA.
457 example_server_profile(br_ssl_server_context
*cc
,
458 const br_x509_certificate
*chain
, size_t chain_len
,
459 const br_rsa_private_key
*sk
)
461 static const uint16_t suites
[] = {
462 BR_TLS_ECDHE_RSA_WITH_AES_128_GCM_SHA256
,
463 BR_TLS_ECDHE_RSA_WITH_AES_256_GCM_SHA384
,
464 BR_TLS_ECDHE_RSA_WITH_AES_128_CBC_SHA256
,
465 BR_TLS_ECDHE_RSA_WITH_AES_256_CBC_SHA384
,
466 BR_TLS_ECDHE_RSA_WITH_AES_128_CBC_SHA
,
467 BR_TLS_ECDHE_RSA_WITH_AES_256_CBC_SHA
,
468 BR_TLS_RSA_WITH_AES_128_GCM_SHA256
,
469 BR_TLS_RSA_WITH_AES_256_GCM_SHA384
,
470 BR_TLS_RSA_WITH_AES_128_CBC_SHA256
,
471 BR_TLS_RSA_WITH_AES_256_CBC_SHA256
,
472 BR_TLS_RSA_WITH_AES_128_CBC_SHA
,
473 BR_TLS_RSA_WITH_AES_256_CBC_SHA
,
474 BR_TLS_ECDHE_RSA_WITH_3DES_EDE_CBC_SHA
,
475 BR_TLS_RSA_WITH_3DES_EDE_CBC_SHA
478 br_ssl_server_zero(cc
);
479 br_ssl_engine_set_versions(&cc
->eng
, BR_TLS10
, BR_TLS12
);
481 br_ssl_engine_set_prf10(&cc
->eng
, &br_tls10_prf
);
482 br_ssl_engine_set_prf_sha256(&cc
->eng
, &br_tls12_sha256_prf
);
483 br_ssl_engine_set_prf_sha384(&cc
->eng
, &br_tls12_sha384_prf
);
486 * Apart from the requirements listed in the client side, these
487 * hash functions are also used by the server to compute its
488 * signature on ECDHE parameters. Which functions are needed
489 * depends on what the client may support; furthermore, the
490 * client may fail to send the relevant extension, in which
491 * case the server will default to whatever it can (as per the
492 * standard, it should be SHA-1 in that case).
494 br_ssl_engine_set_hash(&cc
->eng
, br_md5_ID
, &br_md5_vtable
);
495 br_ssl_engine_set_hash(&cc
->eng
, br_sha1_ID
, &br_sha1_vtable
);
496 br_ssl_engine_set_hash(&cc
->eng
, br_sha224_ID
, &br_sha224_vtable
);
497 br_ssl_engine_set_hash(&cc
->eng
, br_sha256_ID
, &br_sha256_vtable
);
498 br_ssl_engine_set_hash(&cc
->eng
, br_sha384_ID
, &br_sha384_vtable
);
499 br_ssl_engine_set_hash(&cc
->eng
, br_sha512_ID
, &br_sha512_vtable
);
501 br_ssl_engine_set_suites(&cc
->eng
, suites
,
502 (sizeof suites
) / (sizeof suites
[0]));
505 * Elliptic curve implementation is used for ECDHE suites (but
508 br_ssl_engine_set_ec(&cc
->eng
, &br_ec_prime_i31
);
511 * Set the "server policy": handler for the certificate chain
512 * and private key operations. Here, we indicate that the RSA
513 * private key is fit for both signing and decrypting, and we
514 * provide the two relevant implementations.
516 * BR_KEYTYPE_KEYX allows TLS_RSA_*, BR_KEYTYPE_SIGN allows
519 br_ssl_server_set_single_rsa(cc
, chain
, chain_len
, sk
,
520 BR_KEYTYPE_KEYX
| BR_KEYTYPE_SIGN
,
521 br_rsa_i31_private
, br_rsa_i31_pkcs1_sign
);
523 * If the server used an EC private key, this call would look
526 br_ssl_server_set_single_ec(cc, chain, chain_len, sk,
527 BR_KEYTYPE_KEYX | BR_KEYTYPE_SIGN,
528 cert_issuer_key_type,
529 &br_ec_prime_i31, br_ecdsa_i31_sign_asn1);
531 * Note the tricky points:
533 * -- "ECDH" cipher suites use only the EC code (&br_ec_prime_i31);
534 * the ECDHE_ECDSA cipher suites need both the EC code and
535 * the ECDSA signature implementation.
537 * -- For "ECDH" (not "ECDHE") cipher suites, the engine must
538 * know the key type (RSA or EC) for the intermediate CA that
539 * issued the server's certificate; this is an artefact of
540 * how the protocol is defined. BearSSL won't try to decode
541 * the server's certificate to obtain that information (it
542 * could do that, the code is there, but it would increase the
543 * footprint). So this must be provided by the caller.
545 * -- BR_KEYTYPE_KEYX allows ECDH, BR_KEYTYPE_SIGN allows
549 br_ssl_engine_set_cbc(&cc
->eng
,
550 &br_sslrec_in_cbc_vtable
,
551 &br_sslrec_out_cbc_vtable
);
552 br_ssl_engine_set_gcm(&cc
->eng
,
553 &br_sslrec_in_gcm_vtable
,
554 &br_sslrec_out_gcm_vtable
);
556 br_ssl_engine_set_aes_cbc(&cc
->eng
,
557 &br_aes_ct_cbcenc_vtable
,
558 &br_aes_ct_cbcdec_vtable
);
559 br_ssl_engine_set_aes_ctr(&cc
->eng
,
560 &br_aes_ct_ctr_vtable
);
561 /* Alternate: aes_ct64
562 br_ssl_engine_set_aes_cbc(&cc->eng,
563 &br_aes_ct64_cbcenc_vtable,
564 &br_aes_ct64_cbcdec_vtable);
565 br_ssl_engine_set_aes_ctr(&cc->eng,
566 &br_aes_ct64_ctr_vtable);
568 /* Alternate: aes_small
569 br_ssl_engine_set_aes_cbc(&cc->eng,
570 &br_aes_small_cbcenc_vtable,
571 &br_aes_small_cbcdec_vtable);
572 br_ssl_engine_set_aes_ctr(&cc->eng,
573 &br_aes_small_ctr_vtable);
575 /* Alternate: aes_big
576 br_ssl_engine_set_aes_cbc(&cc->eng,
577 &br_aes_big_cbcenc_vtable,
578 &br_aes_big_cbcdec_vtable);
579 br_ssl_engine_set_aes_ctr(&cc->eng,
580 &br_aes_big_ctr_vtable);
582 br_ssl_engine_set_des_cbc(&cc
->eng
,
583 &br_des_ct_cbcenc_vtable
,
584 &br_des_ct_cbcdec_vtable
);
585 /* Alternate: des_tab
586 br_ssl_engine_set_des_cbc(&cc->eng,
587 &br_des_tab_cbcenc_vtable,
588 &br_des_tab_cbcdec_vtable);
591 br_ssl_engine_set_ghash(&cc
->eng
,
593 /* Alternate: ghash_ctmul32
594 br_ssl_engine_set_ghash(&cc->eng,
597 /* Alternate: ghash_ctmul64
598 br_ssl_engine_set_ghash(&cc->eng,