1=pod 2 3=head1 NAME 4 5crypto - OpenSSL cryptographic library 6 7=head1 SYNOPSIS 8 9See the individual manual pages for details. 10 11=head1 DESCRIPTION 12 13The OpenSSL crypto library (C<libcrypto>) implements a wide range of 14cryptographic algorithms used in various Internet standards. The services 15provided by this library are used by the OpenSSL implementations of TLS and 16CMS, and they have also been used to implement many other third party products 17and protocols. 18 19The functionality includes symmetric encryption, public key cryptography, key 20agreement, certificate handling, cryptographic hash functions, cryptographic 21pseudo-random number generators, message authentication codes (MACs), key 22derivation functions (KDFs), and various utilities. 23 24=head2 Algorithms 25 26Cryptographic primitives such as the SHA256 digest, or AES encryption are 27referred to in OpenSSL as "algorithms". Each algorithm may have multiple 28implementations available for use. For example the RSA algorithm is available as 29a "default" implementation suitable for general use, and a "fips" implementation 30which has been validated to FIPS standards for situations where that is 31important. It is also possible that a third party could add additional 32implementations such as in a hardware security module (HSM). 33 34=head2 Operations 35 36Different algorithms can be grouped together by their purpose. For example there 37are algorithms for encryption, and different algorithms for digesting data. 38These different groups are known as "operations" in OpenSSL. Each operation 39has a different set of functions associated with it. For example to perform an 40encryption operation using AES (or any other encryption algorithm) you would use 41the encryption functions detailed on the L<EVP_EncryptInit(3)> page. Or to 42perform a digest operation using SHA256 then you would use the digesting 43functions on the L<EVP_DigestInit(3)> page. 44 45=head2 Providers 46 47A provider in OpenSSL is a component that collects together algorithm 48implementations. In order to use an algorithm you must have at least one 49provider loaded that contains an implementation of it. OpenSSL comes with a 50number of providers and they may also be obtained from third parties. If you 51don't load a provider explicitly (either in program code or via config) then the 52OpenSSL built-in "default" provider will be automatically loaded. 53 54=head2 Library contexts 55 56A library context can be thought of as a "scope" within which configuration 57options take effect. When a provider is loaded, it is only loaded within the 58scope of a given library context. In this way it is possible for different 59components of a complex application to each use a different library context and 60have different providers loaded with different configuration settings. 61 62If an application does not explicitly create a library context then the 63"default" library context will be used. 64 65Library contexts are represented by the B<OSSL_LIB_CTX> type. Many OpenSSL API 66functions take a library context as a parameter. Applications can always pass 67B<NULL> for this parameter to just use the default library context. 68 69The default library context is automatically created the first time it is 70needed. This will automatically load any available configuration file and will 71initialise OpenSSL for use. Unlike in earlier versions of OpenSSL (prior to 721.1.0) no explicit initialisation steps need to be taken. 73 74Similarly when the application exits the default library context is 75automatically destroyed. No explicit de-initialisation steps need to be taken. 76 77See L<OSSL_LIB_CTX(3)> for more information about library contexts. 78See also L</ALGORITHM FETCHING>. 79 80=head2 Multi-threaded applications 81 82As long as OpenSSL has been built with support for threads (the default case 83on most platforms) then most OpenSSL I<functions> are thread-safe in the sense 84that it is safe to call the same function from multiple threads at the same 85time. However most OpenSSL I<data structures> are not thread-safe. For example 86the L<BIO_write(3)> and L<BIO_read(3)> functions are thread safe. However it 87would not be thread safe to call BIO_write() from one thread while calling 88BIO_read() in another where both functions are passed the same B<BIO> object 89since both of them may attempt to make changes to the same B<BIO> object. 90 91There are exceptions to these rules. A small number of functions are not thread 92safe at all. Where this is the case this restriction should be noted in the 93documentation for the function. Similarly some data structures may be partially 94or fully thread safe. For example it is safe to use an B<OSSL_LIB_CTX> in 95multiple threads. 96 97See L<openssl-threads(7)> for a more detailed discussion on OpenSSL threading 98support. 99 100=head1 ALGORITHM FETCHING 101 102In order to use an algorithm an implementation for it must first be "fetched". 103Fetching is the process of looking through the available implementations, 104applying selection criteria (via a property query string), and finally choosing 105the implementation that will be used. 106 107Two types of fetching are supported by OpenSSL - explicit fetching and implicit 108fetching. 109 110=head2 Property query strings 111 112When fetching an algorithm it is possible to specify a property query string to 113guide the selection process. For example a property query string of 114"provider=default" could be used to force the selection to only consider 115algorithm implementations in the default provider. 116 117Property query strings can be specified explicitly as an argument to a function. 118It is also possible to specify a default property query string for the whole 119library context using the L<EVP_set_default_properties(3)> or 120L<EVP_default_properties_enable_fips(3)> functions. Where both 121default properties and function specific properties are specified then they are 122combined. Function specific properties will override default properties where 123there is a conflict. 124 125See L<property(7)> for more information about properties. 126 127=head2 Explicit fetching 128 129Users of the OpenSSL libraries never query a provider directly for an algorithm 130implementation. Instead, the diverse OpenSSL APIs often have explicit fetching 131functions that do the work, and they return an appropriate algorithm object back 132to the user. These functions usually have the name C<APINAME_fetch>, where 133C<APINAME> is the name of the operation. For example L<EVP_MD_fetch(3)> can 134be used to explicitly fetch a digest algorithm implementation. The user is 135responsible for freeing the object returned from the C<APINAME_fetch> function 136using C<APINAME_free> when it is no longer needed. 137 138These fetching functions follow a fairly common pattern, where three 139arguments are passed: 140 141=over 4 142 143=item The library context 144 145See L<OSSL_LIB_CTX(3)> for a more detailed description. 146This may be NULL to signify the default (global) library context, or a 147context created by the user. Only providers loaded in this library context (see 148L<OSSL_PROVIDER_load(3)>) will be considered by the fetching function. In case 149no provider has been loaded in this library context then the default provider 150will be loaded as a fallback (see L<OSSL_PROVIDER-default(7)>). 151 152=item An identifier 153 154For all currently implemented fetching functions this is the algorithm name. 155 156=item A property query string 157 158The property query string used to guide selection of the algorithm 159implementation. 160 161=back 162 163The algorithm implementation that is fetched can then be used with other diverse 164functions that use them. For example the L<EVP_DigestInit_ex(3)> function takes 165as a parameter an B<EVP_MD> object which may have been returned from an earlier 166call to L<EVP_MD_fetch(3)>. 167 168=head2 Implicit fetching 169 170OpenSSL has a number of functions that return an algorithm object with no 171associated implementation, such as L<EVP_sha256(3)>, L<EVP_aes_128_cbc(3)>, 172L<EVP_get_cipherbyname(3)> or L<EVP_get_digestbyname(3)>. These are present for 173compatibility with OpenSSL before version 3.0 where explicit fetching was not 174available. 175 176When they are used with functions like L<EVP_DigestInit_ex(3)> or 177L<EVP_CipherInit_ex(3)>, the actual implementation to be used is 178fetched implicitly using default search criteria. 179 180In some cases implicit fetching can also occur when a NULL algorithm parameter 181is supplied. In this case an algorithm implementation is implicitly fetched 182using default search criteria and an algorithm name that is consistent with 183the context in which it is being used. 184 185Functions that revolve around B<EVP_PKEY_CTX> and L<EVP_PKEY(3)>, such as 186L<EVP_DigestSignInit(3)> and friends, all fetch the implementations 187implicitly. Because these functions involve both an operation type (such as 188L<EVP_SIGNATURE(3)>) and an L<EVP_KEYMGMT(3)> for the L<EVP_PKEY(3)>, they try 189the following: 190 191=over 4 192 193=item 1. 194 195Fetch the operation type implementation from any provider given a library 196context and property string stored in the B<EVP_PKEY_CTX>. 197 198If the provider of the operation type implementation is different from the 199provider of the L<EVP_PKEY(3)>'s L<EVP_KEYMGMT(3)> implementation, try to 200fetch a L<EVP_KEYMGMT(3)> implementation in the same provider as the operation 201type implementation and export the L<EVP_PKEY(3)> to it (effectively making a 202temporary copy of the original key). 203 204If anything in this step fails, the next step is used as a fallback. 205 206=item 2. 207 208As a fallback, try to fetch the operation type implementation from the same 209provider as the original L<EVP_PKEY(3)>'s L<EVP_KEYMGMT(3)>, still using the 210property string from the B<EVP_PKEY_CTX>. 211 212=back 213 214=head2 Performance 215 216If you perform the same operation many times then it is recommended to use 217L</Explicit fetching> to prefetch an algorithm once initially, 218and then pass this created object to any operations that are currently 219using L</Implicit fetching>. 220See an example of Explicit fetching in L</USING ALGORITHMS IN APPLICATIONS>. 221 222Prior to OpenSSL 3.0, constant method tables (such as EVP_sha256()) were used 223directly to access methods. If you pass one of these convenience functions 224to an operation the fixed methods are ignored, and only the name is used to 225internally fetch methods from a provider. 226 227If the prefetched object is not passed to operations, then any implicit 228fetch will use the internally cached prefetched object, but it will 229still be slower than passing the prefetched object directly. 230 231Fetching via a provider offers more flexibility, but it is slower than the 232old method, since it must search for the algorithm in all loaded providers, 233and then populate the method table using provider supplied methods. 234Internally OpenSSL caches similar algorithms on the first fetch 235(so loading a digest caches all digests). 236 237The following methods can be used for prefetching: 238 239=over 4 240 241=item L<EVP_MD_fetch(3)> 242 243=item L<EVP_CIPHER_fetch(3)> 244 245=item L<EVP_KDF_fetch(3)> 246 247=item L<EVP_MAC_fetch(3)> 248 249=item L<EVP_KEM_fetch(3)> 250 251=item L<OSSL_ENCODER_fetch(3)> 252 253=item L<OSSL_DECODER_fetch(3)> 254 255=item L<EVP_RAND_fetch(3)> 256 257=back 258 259The following methods are used internally when performing operations: 260 261=over 4 262 263=item L<EVP_KEYMGMT_fetch(3)> 264 265=item L<EVP_KEYEXCH_fetch(3)> 266 267=item L<EVP_SIGNATURE_fetch(3)> 268 269=item L<OSSL_STORE_LOADER_fetch(3)> 270 271=back 272 273See L<OSSL_PROVIDER-default(7)>, <OSSL_PROVIDER-fips(7)> and 274<OSSL_PROVIDER-legacy(7)>for a list of algorithm names that 275can be fetched. 276 277=head1 FETCHING EXAMPLES 278 279The following section provides a series of examples of fetching algorithm 280implementations. 281 282Fetch any available implementation of SHA2-256 in the default context. Note 283that some algorithms have aliases. So "SHA256" and "SHA2-256" are synonymous: 284 285 EVP_MD *md = EVP_MD_fetch(NULL, "SHA2-256", NULL); 286 ... 287 EVP_MD_free(md); 288 289Fetch any available implementation of AES-128-CBC in the default context: 290 291 EVP_CIPHER *cipher = EVP_CIPHER_fetch(NULL, "AES-128-CBC", NULL); 292 ... 293 EVP_CIPHER_free(cipher); 294 295Fetch an implementation of SHA2-256 from the default provider in the default 296context: 297 298 EVP_MD *md = EVP_MD_fetch(NULL, "SHA2-256", "provider=default"); 299 ... 300 EVP_MD_free(md); 301 302Fetch an implementation of SHA2-256 that is not from the default provider in the 303default context: 304 305 EVP_MD *md = EVP_MD_fetch(NULL, "SHA2-256", "provider!=default"); 306 ... 307 EVP_MD_free(md); 308 309Fetch an implementation of SHA2-256 from the default provider in the specified 310context: 311 312 EVP_MD *md = EVP_MD_fetch(ctx, "SHA2-256", "provider=default"); 313 ... 314 EVP_MD_free(md); 315 316Load the legacy provider into the default context and then fetch an 317implementation of WHIRLPOOL from it: 318 319 /* This only needs to be done once - usually at application start up */ 320 OSSL_PROVIDER *legacy = OSSL_PROVIDER_load(NULL, "legacy"); 321 322 EVP_MD *md = EVP_MD_fetch(NULL, "WHIRLPOOL", "provider=legacy"); 323 ... 324 EVP_MD_free(md); 325 326Note that in the above example the property string "provider=legacy" is optional 327since, assuming no other providers have been loaded, the only implementation of 328the "whirlpool" algorithm is in the "legacy" provider. Also note that the 329default provider should be explicitly loaded if it is required in addition to 330other providers: 331 332 /* This only needs to be done once - usually at application start up */ 333 OSSL_PROVIDER *legacy = OSSL_PROVIDER_load(NULL, "legacy"); 334 OSSL_PROVIDER *default = OSSL_PROVIDER_load(NULL, "default"); 335 336 EVP_MD *md_whirlpool = EVP_MD_fetch(NULL, "whirlpool", NULL); 337 EVP_MD *md_sha256 = EVP_MD_fetch(NULL, "SHA2-256", NULL); 338 ... 339 EVP_MD_free(md_whirlpool); 340 EVP_MD_free(md_sha256); 341 342=head1 OPENSSL PROVIDERS 343 344OpenSSL comes with a set of providers. 345 346The algorithms available in each of these providers may vary due to build time 347configuration options. The L<openssl-list(1)> command can be used to list the 348currently available algorithms. 349 350The names of the algorithms shown from L<openssl-list(1)> can be used as an 351algorithm identifier to the appropriate fetching function. Also see the provider 352specific manual pages linked below for further details about using the 353algorithms available in each of the providers. 354 355As well as the OpenSSL providers third parties can also implement providers. 356For information on writing a provider see L<provider(7)>. 357 358=head2 Default provider 359 360The default provider is built in as part of the F<libcrypto> library and 361contains all of the most commonly used algorithm implementations. Should it be 362needed (if other providers are loaded and offer implementations of the same 363algorithms), the property query string "provider=default" can be used as a 364search criterion for these implementations. The default provider includes all 365of the functionality in the base provider below. 366 367If you don't load any providers at all then the "default" provider will be 368automatically loaded. If you explicitly load any provider then the "default" 369provider would also need to be explicitly loaded if it is required. 370 371See L<OSSL_PROVIDER-default(7)>. 372 373=head2 Base provider 374 375The base provider is built in as part of the F<libcrypto> library and contains 376algorithm implementations for encoding and decoding for OpenSSL keys. 377Should it be needed (if other providers are loaded and offer 378implementations of the same algorithms), the property query string 379"provider=base" can be used as a search criterion for these implementations. 380Some encoding and decoding algorithm implementations are not FIPS algorithm 381implementations in themselves but support algorithms from the FIPS provider and 382are allowed for use in "FIPS mode". The property query string "fips=yes" can be 383used to select such algorithms. 384 385See L<OSSL_PROVIDER-base(7)>. 386 387=head2 FIPS provider 388 389The FIPS provider is a dynamically loadable module, and must therefore 390be loaded explicitly, either in code or through OpenSSL configuration 391(see L<config(5)>). It contains algorithm implementations that have been 392validated according to the FIPS 140-2 standard. Should it be needed (if other 393providers are loaded and offer implementations of the same algorithms), the 394property query string "provider=fips" can be used as a search criterion for 395these implementations. All approved algorithm implementations in the FIPS 396provider can also be selected with the property "fips=yes". The FIPS provider 397may also contain non-approved algorithm implementations and these can be 398selected with the property "fips=no". 399 400See L<OSSL_PROVIDER-FIPS(7)> and L<fips_module(7)>. 401 402=head2 Legacy provider 403 404The legacy provider is a dynamically loadable module, and must therefore 405be loaded explicitly, either in code or through OpenSSL configuration 406(see L<config(5)>). It contains algorithm implementations that are considered 407insecure, or are no longer in common use such as MD2 or RC4. Should it be needed 408(if other providers are loaded and offer implementations of the same algorithms), 409the property "provider=legacy" can be used as a search criterion for these 410implementations. 411 412See L<OSSL_PROVIDER-legacy(7)>. 413 414=head2 Null provider 415 416The null provider is built in as part of the F<libcrypto> library. It contains 417no algorithms in it at all. When fetching algorithms the default provider will 418be automatically loaded if no other provider has been explicitly loaded. To 419prevent that from happening you can explicitly load the null provider. 420 421See L<OSSL_PROVIDER-null(7)>. 422 423=head1 USING ALGORITHMS IN APPLICATIONS 424 425Cryptographic algorithms are made available to applications through use of the 426"EVP" APIs. Each of the various operations such as encryption, digesting, 427message authentication codes, etc., have a set of EVP function calls that can 428be invoked to use them. See the L<evp(7)> page for further details. 429 430Most of these follow a common pattern. A "context" object is first created. For 431example for a digest operation you would use an B<EVP_MD_CTX>, and for an 432encryption/decryption operation you would use an B<EVP_CIPHER_CTX>. The 433operation is then initialised ready for use via an "init" function - optionally 434passing in a set of parameters (using the L<OSSL_PARAM(3)> type) to configure how 435the operation should behave. Next data is fed into the operation in a series of 436"update" calls. The operation is finalised using a "final" call which will 437typically provide some kind of output. Finally the context is cleaned up and 438freed. 439 440The following shows a complete example for doing this process for digesting 441data using SHA256. The process is similar for other operations such as 442encryption/decryption, signatures, message authentication codes, etc. 443 444 #include <stdio.h> 445 #include <openssl/evp.h> 446 #include <openssl/bio.h> 447 #include <openssl/err.h> 448 449 int main(void) 450 { 451 EVP_MD_CTX *ctx = NULL; 452 EVP_MD *sha256 = NULL; 453 const unsigned char msg[] = { 454 0x00, 0x01, 0x02, 0x03 455 }; 456 unsigned int len = 0; 457 unsigned char *outdigest = NULL; 458 int ret = 1; 459 460 /* Create a context for the digest operation */ 461 ctx = EVP_MD_CTX_new(); 462 if (ctx == NULL) 463 goto err; 464 465 /* 466 * Fetch the SHA256 algorithm implementation for doing the digest. We're 467 * using the "default" library context here (first NULL parameter), and 468 * we're not supplying any particular search criteria for our SHA256 469 * implementation (second NULL parameter). Any SHA256 implementation will 470 * do. 471 * In a larger application this fetch would just be done once, and could 472 * be used for multiple calls to other operations such as EVP_DigestInit_ex(). 473 */ 474 sha256 = EVP_MD_fetch(NULL, "SHA256", NULL); 475 if (sha256 == NULL) 476 goto err; 477 478 /* Initialise the digest operation */ 479 if (!EVP_DigestInit_ex(ctx, sha256, NULL)) 480 goto err; 481 482 /* 483 * Pass the message to be digested. This can be passed in over multiple 484 * EVP_DigestUpdate calls if necessary 485 */ 486 if (!EVP_DigestUpdate(ctx, msg, sizeof(msg))) 487 goto err; 488 489 /* Allocate the output buffer */ 490 outdigest = OPENSSL_malloc(EVP_MD_get_size(sha256)); 491 if (outdigest == NULL) 492 goto err; 493 494 /* Now calculate the digest itself */ 495 if (!EVP_DigestFinal_ex(ctx, outdigest, &len)) 496 goto err; 497 498 /* Print out the digest result */ 499 BIO_dump_fp(stdout, outdigest, len); 500 501 ret = 0; 502 503 err: 504 /* Clean up all the resources we allocated */ 505 OPENSSL_free(outdigest); 506 EVP_MD_free(sha256); 507 EVP_MD_CTX_free(ctx); 508 if (ret != 0) 509 ERR_print_errors_fp(stderr); 510 return ret; 511 } 512 513=head1 CONFIGURATION 514 515By default OpenSSL will load a configuration file when it is first used. This 516will set up various configuration settings within the default library context. 517Applications that create their own library contexts may optionally configure 518them with a config file using the L<OSSL_LIB_CTX_load_config(3)> function. 519 520The configuration file can be used to automatically load providers and set up 521default property query strings. 522 523For information on the OpenSSL configuration file format see L<config(5)>. 524 525=head1 ENCODING AND DECODING KEYS 526 527Many algorithms require the use of a key. Keys can be generated dynamically 528using the EVP APIs (for example see L<EVP_PKEY_Q_keygen(3)>). However it is often 529necessary to save or load keys (or their associated parameters) to or from some 530external format such as PEM or DER (see L<openssl-glossary(7)>). OpenSSL uses 531encoders and decoders to perform this task. 532 533Encoders and decoders are just algorithm implementations in the same way as 534any other algorithm implementation in OpenSSL. They are implemented by 535providers. The OpenSSL encoders and decoders are available in the default 536provider. They are also duplicated in the base provider. 537 538For information about encoders see L<OSSL_ENCODER_CTX_new_for_pkey(3)>. For 539information about decoders see L<OSSL_DECODER_CTX_new_for_pkey(3)>. 540 541=head1 LIBRARY CONVENTIONS 542 543Many OpenSSL functions that "get" or "set" a value follow a naming convention 544using the numbers B<0> and B<1>, i.e. "get0", "get1", "set0" and "set1". This 545can also apply to some functions that "add" a value to an existing set, i.e. 546"add0" and "add1". 547 548For example the functions: 549 550 int X509_CRL_add0_revoked(X509_CRL *crl, X509_REVOKED *rev); 551 int X509_add1_trust_object(X509 *x, const ASN1_OBJECT *obj); 552 553In the B<0> version the ownership of the object is passed to (for an add or set) 554or retained by (for a get) the parent object. For example after calling the 555X509_CRL_add0_revoked() function above, ownership of the I<rev> object is passed 556to the I<crl> object. Therefore, after calling this function I<rev> should not 557be freed directly. It will be freed implicitly when I<crl> is freed. 558 559In the B<1> version the ownership of the object is not passed to or retained by 560the parent object. Instead a copy or "up ref" of the object is performed. So 561after calling the X509_add1_trust_object() function above the application will 562still be responsible for freeing the I<obj> value where appropriate. 563 564=head1 SEE ALSO 565 566L<openssl(1)>, L<ssl(7)>, L<evp(7)>, L<OSSL_LIB_CTX(3)>, L<openssl-threads(7)>, 567L<property(7)>, L<OSSL_PROVIDER-default(7)>, L<OSSL_PROVIDER-base(7)>, 568L<OSSL_PROVIDER-FIPS(7)>, L<OSSL_PROVIDER-legacy(7)>, L<OSSL_PROVIDER-null(7)>, 569L<openssl-glossary(7)>, L<provider(7)> 570 571=head1 COPYRIGHT 572 573Copyright 2000-2023 The OpenSSL Project Authors. All Rights Reserved. 574 575Licensed under the Apache License 2.0 (the "License"). You may not use 576this file except in compliance with the License. You can obtain a copy 577in the file LICENSE in the source distribution or at 578L<https://www.openssl.org/source/license.html>. 579 580=cut 581