NAME
ossl-guide-libcrypto-introduction, crypto - OpenSSL Guide: An introduction to libcrypto
INTRODUCTION
The OpenSSL cryptography library ("libcrypto") enables access to a wide range of cryptographic algorithms used in various Internet standards. The services provided by this library are used by the OpenSSL implementations of TLS and CMS, and they have also been used to implement many other third party products and protocols.
The functionality includes symmetric encryption, public key cryptography, key agreement, certificate handling, cryptographic hash functions, cryptographic pseudo-random number generators, message authentication codes (MACs), key derivation functions (KDFs), and various utilities.
Algorithms
Cryptographic primitives such as the SHA256 digest, or AES
encryption are referred to in OpenSSL as
"algorithms". Each algorithm may have multiple
implementations available for use. For example the RSA
algorithm is available as a "default"
implementation suitable for general use, and a
"fips" implementation which has been validated to
FIPS 140 standards for situations where that is important.
It is also possible that a third party could add additional
implementations such as in a hardware security module
(HSM).
Algorithms are implemented in providers. See ossl-guide-libraries-introduction(7) for information about providers.
Operations
Different algorithms can be grouped together by their
purpose. For example there are algorithms for encryption,
and different algorithms for digesting data. These different
groups are known as "operations" in OpenSSL. Each
operation has a different set of functions associated with
it. For example to perform an encryption operation using AES
(or any other encryption algorithm) you would use the
encryption functions detailed on the
EVP_EncryptInit(3) page. Or to perform a digest
operation using SHA256 then you would use the digesting
functions on the EVP_DigestInit(3) page.
ALGORITHM FETCHING
In order to use an algorithm an implementation for it must first be "fetched". Fetching is the process of looking through the available implementations, applying selection criteria (via a property query string), and finally choosing the implementation that will be used.
Two types of fetching are supported by OpenSSL - "Explicit fetching" and "Implicit fetching".
Explicit
fetching
Explicit fetching involves directly calling a specific API
to fetch an algorithm implementation from a provider. This
fetched object can then be passed to other APIs. These
explicit fetching functions usually have the name
"APINAME_fetch", where "APINAME" is the
name of the operation. For example EVP_MD_fetch(3)
can be used to explicitly fetch a digest algorithm
implementation. The user is responsible for freeing the
object returned from the "APINAME_fetch" function
using "APINAME_free" when it is no longer
needed.
These fetching
functions follow a fairly common pattern, where three
arguments are passed:
The library context
See OSSL_LIB_CTX(3) for a more detailed description. This may be NULL to signify the default (global) library context, or a context created by the user. Only providers loaded in this library context (see OSSL_PROVIDER_load(3)) will be considered by the fetching function. In case no provider has been loaded in this library context then the default provider will be loaded as a fallback (see OSSL_PROVIDER-default(7)).
An identifier
For all currently implemented fetching functions this is the algorithm name. Each provider supports a list of algorithm implementations. See the provider specific documentation for information on the algorithm implementations available in each provider: "OPERATIONS AND ALGORITHMS" in OSSL_PROVIDER-default(7), "OPERATIONS AND ALGORITHMS" in OSSL_PROVIDER-FIPS(7), "OPERATIONS AND ALGORITHMS" in OSSL_PROVIDER-legacy(7) and "OPERATIONS AND ALGORITHMS" in OSSL_PROVIDER-base(7).
Note, while providers may register algorithms against a list of names using a string with a colon separated list of names, fetching algorithms using that format is currently unsupported.
A property query string
The property query string used to guide selection of the algorithm implementation. See "PROPERTY QUERY STRINGS" in ossl-guide-libraries-introduction(7).
The algorithm implementation that is fetched can then be used with other diverse functions that use them. For example the EVP_DigestInit_ex(3) function takes as a parameter an EVP_MD object which may have been returned from an earlier call to EVP_MD_fetch(3).
Implicit
fetching
OpenSSL has a number of functions that return an algorithm
object with no associated implementation, such as
EVP_sha256(3), EVP_aes_128_cbc(3),
EVP_get_cipherbyname(3) or
EVP_get_digestbyname(3). These are present for
compatibility with OpenSSL before version 3.0 where explicit
fetching was not available.
When they are used with functions like EVP_DigestInit_ex(3) or EVP_CipherInit_ex(3), the actual implementation to be used is fetched implicitly using default search criteria (which uses NULL for the library context and property query string).
In some cases implicit fetching can also occur when a NULL algorithm parameter is supplied. In this case an algorithm implementation is implicitly fetched using default search criteria and an algorithm name that is consistent with the context in which it is being used.
Functions that use an EVP_PKEY_CTX or an EVP_PKEY(3), such as EVP_DigestSignInit(3), all fetch the implementations implicitly. Usually the algorithm to fetch is determined based on the type of key that is being used and the function that has been called.
Performance
If you perform the same operation many times with the same
algorithm then it is recommended to use a single explicit
fetch of the algorithm and then reuse the explicitly fetched
algorithm each subsequent time. This will typically be
faster than implicitly fetching the algorithm every time you
use it. See an example of Explicit fetching in "USING
ALGORITHMS IN APPLICATIONS".
Prior to OpenSSL 3.0, functions such as EVP_sha256() which return a "const" object were used directly to indicate the algorithm to use in various function calls. If you pass the return value of one of these convenience functions to an operation then you are using implicit fetching. If you are converting an application that worked with an OpenSSL version prior to OpenSSL 3.0 then consider changing instances of implicit fetching to explicit fetching instead.
If an explicitly fetched object is not passed to an operation, then any implicit fetch will use an internally cached prefetched object, but it will still be slower than passing the explicitly fetched object directly.
The following
functions can be used for explicit fetching:
EVP_MD_fetch(3)
Fetch a message digest/hashing algorithm implementation.
Fetch a symmetric cipher algorithm implementation.
Fetch a Key Derivation Function (KDF) algorithm implementation.
Fetch a Message Authentication Code (MAC) algorithm implementation.
Fetch a Key Encapsulation Mechanism (KEM) algorithm implementation
Fetch an encoder algorithm implementation (e.g. to encode keys to a specified format).
Fetch a decoder algorithm implementation (e.g. to decode keys from a specified format).
Fetch a Pseudo Random Number Generator (PRNG) algorithm implementation.
See "OPERATIONS AND ALGORITHMS" in OSSL_PROVIDER-default(7), "OPERATIONS AND ALGORITHMS" in OSSL_PROVIDER-FIPS(7), "OPERATIONS AND ALGORITHMS" in OSSL_PROVIDER-legacy(7) and "OPERATIONS AND ALGORITHMS" in OSSL_PROVIDER-base(7) for a list of algorithm names that can be fetched.
FETCHING EXAMPLES
The following section provides a series of examples of fetching algorithm implementations.
Fetch any available implementation of SHA2-256 in the default context. Note that some algorithms have aliases. So "SHA256" and "SHA2-256" are synonymous:
EVP_MD *md =
EVP_MD_fetch(NULL, "SHA2-256", NULL);
...
EVP_MD_free(md);
Fetch any available implementation of AES-128-CBC in the default context:
EVP_CIPHER
*cipher = EVP_CIPHER_fetch(NULL, "AES-128-CBC",
NULL);
...
EVP_CIPHER_free(cipher);
Fetch an implementation of SHA2-256 from the default provider in the default context:
EVP_MD *md =
EVP_MD_fetch(NULL, "SHA2-256",
"provider=default");
...
EVP_MD_free(md);
Fetch an implementation of SHA2-256 that is not from the default provider in the default context:
EVP_MD *md =
EVP_MD_fetch(NULL, "SHA2-256",
"provider!=default");
...
EVP_MD_free(md);
Fetch an implementation of SHA2-256 that is preferably from the FIPS provider in the default context:
EVP_MD *md =
EVP_MD_fetch(NULL, "SHA2-256",
"provider=?fips");
...
EVP_MD_free(md);
Fetch an implementation of SHA2-256 from the default provider in the specified library context:
EVP_MD *md =
EVP_MD_fetch(libctx, "SHA2-256",
"provider=default");
...
EVP_MD_free(md);
Load the legacy provider into the default context and then fetch an implementation of WHIRLPOOL from it:
/* This only
needs to be done once - usually at application start up */
OSSL_PROVIDER *legacy = OSSL_PROVIDER_load(NULL,
"legacy");
EVP_MD *md = EVP_MD_fetch(NULL, "WHIRLPOOL",
"provider=legacy");
...
EVP_MD_free(md);
Note that in the above example the property string "provider=legacy" is optional since, assuming no other providers have been loaded, the only implementation of the "whirlpool" algorithm is in the "legacy" provider. Also note that the default provider should be explicitly loaded if it is required in addition to other providers:
/* This only
needs to be done once - usually at application start up */
OSSL_PROVIDER *legacy = OSSL_PROVIDER_load(NULL,
"legacy");
OSSL_PROVIDER *default = OSSL_PROVIDER_load(NULL,
"default");
EVP_MD *md_whirlpool = EVP_MD_fetch(NULL,
"whirlpool", NULL);
EVP_MD *md_sha256 = EVP_MD_fetch(NULL, "SHA2-256",
NULL);
...
EVP_MD_free(md_whirlpool);
EVP_MD_free(md_sha256);
USING ALGORITHMS IN APPLICATIONS
Cryptographic algorithms are made available to applications through use of the "EVP" APIs. Each of the various operations such as encryption, digesting, message authentication codes, etc., have a set of EVP function calls that can be invoked to use them. See the evp(7) page for further details.
Most of these follow a common pattern. A "context" object is first created. For example for a digest operation you would use an EVP_MD_CTX, and for an encryption/decryption operation you would use an EVP_CIPHER_CTX. The operation is then initialised ready for use via an "init" function - optionally passing in a set of parameters (using the OSSL_PARAM(3) type) to configure how the operation should behave. Next data is fed into the operation in a series of "update" calls. The operation is finalised using a "final" call which will typically provide some kind of output. Finally the context is cleaned up and freed.
The following shows a complete example for doing this process for digesting data using SHA256. The process is similar for other operations such as encryption/decryption, signatures, message authentication codes, etc. Additional examples can be found in the OpenSSL demos (see "DEMO APPLICATIONS" in ossl-guide-libraries-introduction(7)).
#include
<stdio.h>
#include <openssl/evp.h>
#include <openssl/bio.h>
#include <openssl/err.h>
int main(void)
{
EVP_MD_CTX *ctx = NULL;
EVP_MD *sha256 = NULL;
const unsigned char msg[] = {
0x00, 0x01, 0x02, 0x03
};
unsigned int len = 0;
unsigned char *outdigest = NULL;
int ret = 1;
/* Create a context for the digest operation */
ctx = EVP_MD_CTX_new();
if (ctx == NULL)
goto err;
/*
* Fetch the SHA256 algorithm implementation for doing the
digest. We're
* using the "default" library context here (first
NULL parameter), and
* we're not supplying any particular search criteria for our
SHA256
* implementation (second NULL parameter). Any SHA256
implementation will
* do.
* In a larger application this fetch would just be done
once, and could
* be used for multiple calls to other operations such as
EVP_DigestInit_ex().
*/
sha256 = EVP_MD_fetch(NULL, "SHA256", NULL);
if (sha256 == NULL)
goto err;
/* Initialise the digest operation */
if (!EVP_DigestInit_ex(ctx, sha256, NULL))
goto err;
/*
* Pass the message to be digested. This can be passed in
over multiple
* EVP_DigestUpdate calls if necessary
*/
if (!EVP_DigestUpdate(ctx, msg, sizeof(msg)))
goto err;
/* Allocate the output buffer */
outdigest = OPENSSL_malloc(EVP_MD_get_size(sha256));
if (outdigest == NULL)
goto err;
/* Now calculate the digest itself */
if (!EVP_DigestFinal_ex(ctx, outdigest, &len))
goto err;
/* Print out the digest result */
BIO_dump_fp(stdout, outdigest, len);
ret = 0;
err:
/* Clean up all the resources we allocated */
OPENSSL_free(outdigest);
EVP_MD_free(sha256);
EVP_MD_CTX_free(ctx);
if (ret != 0)
ERR_print_errors_fp(stderr);
return ret;
}
ENCODING AND DECODING KEYS
Many algorithms require the use of a key. Keys can be generated dynamically using the EVP APIs (for example see EVP_PKEY_Q_keygen(3)). However it is often necessary to save or load keys (or their associated parameters) to or from some external format such as PEM or DER (see openssl-glossary(7)). OpenSSL uses encoders and decoders to perform this task.
Encoders and decoders are just algorithm implementations in the same way as any other algorithm implementation in OpenSSL. They are implemented by providers. The OpenSSL encoders and decoders are available in the default provider. They are also duplicated in the base provider.
For information about encoders see OSSL_ENCODER_CTX_new_for_pkey(3). For information about decoders see OSSL_DECODER_CTX_new_for_pkey(3).
As well as using encoders/decoders directly there are also some helper functions that can be used for certain well known and commonly used formats. For example see PEM_read_PrivateKey(3) and PEM_write_PrivateKey(3) for information about reading and writing key data from PEM encoded files.
FURTHER READING
See ossl-guide-libssl-introduction(7) for an introduction to using "libssl".
SEE ALSO
openssl(1), ssl(7), evp(7), OSSL_LIB_CTX(3), openssl-threads(7), property(7), OSSL_PROVIDER-default(7), OSSL_PROVIDER-base(7), OSSL_PROVIDER-FIPS(7), OSSL_PROVIDER-legacy(7), OSSL_PROVIDER-null(7), openssl-glossary(7), provider(7)
COPYRIGHT
Copyright 2000-2024 The OpenSSL Project Authors. All Rights Reserved.
Licensed under the Apache License 2.0 (the "License"). You may not use this file except in compliance with the License. You can obtain a copy in the file LICENSE in the source distribution or at <https://www.openssl.org/source/license.html>.