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If a name is passed to EVP_<OBJ>_fetch of the form: name1:name2:name3 The names are parsed on the separator ':' and added to the store, but during the lookup in inner_evp_generic_fetch, the subsequent search of the store uses the full name1:name2:name3 string, which fails lookup, and causes subsequent assertion failures in evp_method_id. instead catch the failure in inner_evp_generic_fetch and return an error code if the name_id against a colon separated list of names fails. This provides a graceful error return path without asserts, and leaves room for a future feature in which such formatted names can be parsed and searched for iteratively Add a simple test to verify that providing a colon separated name results in an error indicating an invalid lookup. Reviewed-by: Tomas Mraz <tomas@openssl.org> Reviewed-by: Todd Short <todd.short@me.com> (Merged from https://github.com/openssl/openssl/pull/23110)
403 lines
15 KiB
Plaintext
403 lines
15 KiB
Plaintext
=pod
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=head1 NAME
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ossl-guide-libcrypto-introduction, crypto
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- OpenSSL Guide: An introduction to libcrypto
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=head1 INTRODUCTION
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The OpenSSL cryptography library (C<libcrypto>) enables access to a wide range
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of cryptographic algorithms used in various Internet standards. The services
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provided by this library are used by the OpenSSL implementations of TLS and
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CMS, and they have also been used to implement many other third party products
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and protocols.
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The functionality includes symmetric encryption, public key cryptography, key
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agreement, certificate handling, cryptographic hash functions, cryptographic
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pseudo-random number generators, message authentication codes (MACs), key
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derivation functions (KDFs), and various utilities.
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=head2 Algorithms
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Cryptographic primitives such as the SHA256 digest, or AES encryption are
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referred to in OpenSSL as "algorithms". Each algorithm may have multiple
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implementations available for use. For example the RSA algorithm is available as
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a "default" implementation suitable for general use, and a "fips" implementation
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which has been validated to FIPS 140 standards for situations where that is
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important. It is also possible that a third party could add additional
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implementations such as in a hardware security module (HSM).
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Algorithms are implemented in providers. See
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L<ossl-guide-libraries-introduction(7)> for information about providers.
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=head2 Operations
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Different algorithms can be grouped together by their purpose. For example there
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are algorithms for encryption, and different algorithms for digesting data.
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These different groups are known as "operations" in OpenSSL. Each operation
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has a different set of functions associated with it. For example to perform an
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encryption operation using AES (or any other encryption algorithm) you would use
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the encryption functions detailed on the L<EVP_EncryptInit(3)> page. Or to
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perform a digest operation using SHA256 then you would use the digesting
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functions on the L<EVP_DigestInit(3)> page.
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=head1 ALGORITHM FETCHING
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In order to use an algorithm an implementation for it must first be "fetched".
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Fetching is the process of looking through the available implementations,
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applying selection criteria (via a property query string), and finally choosing
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the implementation that will be used.
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Two types of fetching are supported by OpenSSL - L</Explicit fetching> and
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L</Implicit fetching>.
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=head2 Explicit fetching
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Explicit fetching involves directly calling a specific API to fetch an algorithm
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implementation from a provider. This fetched object can then be passed to other
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APIs. These explicit fetching functions usually have the name C<APINAME_fetch>,
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where C<APINAME> is the name of the operation. For example L<EVP_MD_fetch(3)>
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can be used to explicitly fetch a digest algorithm implementation. The user is
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responsible for freeing the object returned from the C<APINAME_fetch> function
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using C<APINAME_free> when it is no longer needed.
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These fetching functions follow a fairly common pattern, where three
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arguments are passed:
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=over 4
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=item The library context
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See L<OSSL_LIB_CTX(3)> for a more detailed description.
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This may be NULL to signify the default (global) library context, or a
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context created by the user. Only providers loaded in this library context (see
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L<OSSL_PROVIDER_load(3)>) will be considered by the fetching function. In case
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no provider has been loaded in this library context then the default provider
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will be loaded as a fallback (see L<OSSL_PROVIDER-default(7)>).
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=item An identifier
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For all currently implemented fetching functions this is the algorithm name.
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Each provider supports a list of algorithm implementations. See the provider
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specific documentation for information on the algorithm implementations
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available in each provider:
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L<OSSL_PROVIDER-default(7)/OPERATIONS AND ALGORITHMS>,
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L<OSSL_PROVIDER-FIPS(7)/OPERATIONS AND ALGORITHMS>,
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L<OSSL_PROVIDER-legacy(7)/OPERATIONS AND ALGORITHMS> and
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L<OSSL_PROVIDER-base(7)/OPERATIONS AND ALGORITHMS>.
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Note, while providers may register algorithms against a list of names using a
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string with a colon separated list of names, fetching algorithms using that
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format is currently unsupported.
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=item A property query string
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The property query string used to guide selection of the algorithm
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implementation. See
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L<ossl-guide-libraries-introduction(7)/PROPERTY QUERY STRINGS>.
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=back
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The algorithm implementation that is fetched can then be used with other diverse
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functions that use them. For example the L<EVP_DigestInit_ex(3)> function takes
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as a parameter an B<EVP_MD> object which may have been returned from an earlier
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call to L<EVP_MD_fetch(3)>.
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=head2 Implicit fetching
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OpenSSL has a number of functions that return an algorithm object with no
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associated implementation, such as L<EVP_sha256(3)>, L<EVP_aes_128_cbc(3)>,
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L<EVP_get_cipherbyname(3)> or L<EVP_get_digestbyname(3)>. These are present for
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compatibility with OpenSSL before version 3.0 where explicit fetching was not
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available.
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When they are used with functions like L<EVP_DigestInit_ex(3)> or
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L<EVP_CipherInit_ex(3)>, the actual implementation to be used is
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fetched implicitly using default search criteria (which uses NULL for the
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library context and property query string).
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In some cases implicit fetching can also occur when a NULL algorithm parameter
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is supplied. In this case an algorithm implementation is implicitly fetched
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using default search criteria and an algorithm name that is consistent with
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the context in which it is being used.
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Functions that use an B<EVP_PKEY_CTX> or an L<EVP_PKEY(3)>, such as
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L<EVP_DigestSignInit(3)>, all fetch the implementations implicitly. Usually the
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algorithm to fetch is determined based on the type of key that is being used and
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the function that has been called.
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=head2 Performance
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If you perform the same operation many times with the same algorithm then it is
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recommended to use a single explicit fetch of the algorithm and then reuse the
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explicitly fetched algorithm each subsequent time. This will typically be
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faster than implicitly fetching the algorithm every time you use it. See an
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example of Explicit fetching in L</USING ALGORITHMS IN APPLICATIONS>.
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Prior to OpenSSL 3.0, functions such as EVP_sha256() which return a "const"
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object were used directly to indicate the algorithm to use in various function
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calls. If you pass the return value of one of these convenience functions to an
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operation then you are using implicit fetching. If you are converting an
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application that worked with an OpenSSL version prior to OpenSSL 3.0 then
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consider changing instances of implicit fetching to explicit fetching instead.
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If an explicitly fetched object is not passed to an operation, then any implicit
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fetch will use an internally cached prefetched object, but it will
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still be slower than passing the explicitly fetched object directly.
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The following functions can be used for explicit fetching:
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=over 4
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=item L<EVP_MD_fetch(3)>
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Fetch a message digest/hashing algorithm implementation.
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=item L<EVP_CIPHER_fetch(3)>
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Fetch a symmetric cipher algorithm implementation.
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=item L<EVP_KDF_fetch(3)>
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Fetch a Key Derivation Function (KDF) algorithm implementation.
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=item L<EVP_MAC_fetch(3)>
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Fetch a Message Authentication Code (MAC) algorithm implementation.
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=item L<EVP_KEM_fetch(3)>
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Fetch a Key Encapsulation Mechanism (KEM) algorithm implementation
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=item L<OSSL_ENCODER_fetch(3)>
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Fetch an encoder algorithm implementation (e.g. to encode keys to a specified
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format).
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=item L<OSSL_DECODER_fetch(3)>
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Fetch a decoder algorithm implementation (e.g. to decode keys from a specified
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format).
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=item L<EVP_RAND_fetch(3)>
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Fetch a Pseudo Random Number Generator (PRNG) algorithm implementation.
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=back
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See L<OSSL_PROVIDER-default(7)/OPERATIONS AND ALGORITHMS>,
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L<OSSL_PROVIDER-FIPS(7)/OPERATIONS AND ALGORITHMS>,
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L<OSSL_PROVIDER-legacy(7)/OPERATIONS AND ALGORITHMS> and
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L<OSSL_PROVIDER-base(7)/OPERATIONS AND ALGORITHMS> for a list of algorithm names
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that can be fetched.
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=head1 FETCHING EXAMPLES
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The following section provides a series of examples of fetching algorithm
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implementations.
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Fetch any available implementation of SHA2-256 in the default context. Note
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that some algorithms have aliases. So "SHA256" and "SHA2-256" are synonymous:
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EVP_MD *md = EVP_MD_fetch(NULL, "SHA2-256", NULL);
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...
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EVP_MD_free(md);
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Fetch any available implementation of AES-128-CBC in the default context:
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EVP_CIPHER *cipher = EVP_CIPHER_fetch(NULL, "AES-128-CBC", NULL);
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...
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EVP_CIPHER_free(cipher);
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Fetch an implementation of SHA2-256 from the default provider in the default
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context:
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EVP_MD *md = EVP_MD_fetch(NULL, "SHA2-256", "provider=default");
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...
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EVP_MD_free(md);
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Fetch an implementation of SHA2-256 that is not from the default provider in the
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default context:
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EVP_MD *md = EVP_MD_fetch(NULL, "SHA2-256", "provider!=default");
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...
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EVP_MD_free(md);
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Fetch an implementation of SHA2-256 that is preferably from the FIPS provider in
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the default context:
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EVP_MD *md = EVP_MD_fetch(NULL, "SHA2-256", "provider=?fips");
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...
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EVP_MD_free(md);
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Fetch an implementation of SHA2-256 from the default provider in the specified
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library context:
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EVP_MD *md = EVP_MD_fetch(libctx, "SHA2-256", "provider=default");
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...
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EVP_MD_free(md);
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Load the legacy provider into the default context and then fetch an
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implementation of WHIRLPOOL from it:
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/* This only needs to be done once - usually at application start up */
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OSSL_PROVIDER *legacy = OSSL_PROVIDER_load(NULL, "legacy");
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EVP_MD *md = EVP_MD_fetch(NULL, "WHIRLPOOL", "provider=legacy");
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...
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EVP_MD_free(md);
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Note that in the above example the property string "provider=legacy" is optional
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since, assuming no other providers have been loaded, the only implementation of
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the "whirlpool" algorithm is in the "legacy" provider. Also note that the
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default provider should be explicitly loaded if it is required in addition to
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other providers:
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/* This only needs to be done once - usually at application start up */
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OSSL_PROVIDER *legacy = OSSL_PROVIDER_load(NULL, "legacy");
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OSSL_PROVIDER *default = OSSL_PROVIDER_load(NULL, "default");
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EVP_MD *md_whirlpool = EVP_MD_fetch(NULL, "whirlpool", NULL);
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EVP_MD *md_sha256 = EVP_MD_fetch(NULL, "SHA2-256", NULL);
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...
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EVP_MD_free(md_whirlpool);
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EVP_MD_free(md_sha256);
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=head1 USING ALGORITHMS IN APPLICATIONS
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Cryptographic algorithms are made available to applications through use of the
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"EVP" APIs. Each of the various operations such as encryption, digesting,
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message authentication codes, etc., have a set of EVP function calls that can
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be invoked to use them. See the L<evp(7)> page for further details.
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Most of these follow a common pattern. A "context" object is first created. For
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example for a digest operation you would use an B<EVP_MD_CTX>, and for an
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encryption/decryption operation you would use an B<EVP_CIPHER_CTX>. The
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operation is then initialised ready for use via an "init" function - optionally
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passing in a set of parameters (using the L<OSSL_PARAM(3)> type) to configure how
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the operation should behave. Next data is fed into the operation in a series of
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"update" calls. The operation is finalised using a "final" call which will
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typically provide some kind of output. Finally the context is cleaned up and
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freed.
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The following shows a complete example for doing this process for digesting
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data using SHA256. The process is similar for other operations such as
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encryption/decryption, signatures, message authentication codes, etc. Additional
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examples can be found in the OpenSSL demos (see
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L<ossl-guide-libraries-introduction(7)/DEMO APPLICATIONS>).
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#include <stdio.h>
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#include <openssl/evp.h>
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#include <openssl/bio.h>
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#include <openssl/err.h>
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int main(void)
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{
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EVP_MD_CTX *ctx = NULL;
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EVP_MD *sha256 = NULL;
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const unsigned char msg[] = {
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0x00, 0x01, 0x02, 0x03
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};
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unsigned int len = 0;
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unsigned char *outdigest = NULL;
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int ret = 1;
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/* Create a context for the digest operation */
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ctx = EVP_MD_CTX_new();
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if (ctx == NULL)
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goto err;
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/*
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* Fetch the SHA256 algorithm implementation for doing the digest. We're
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* using the "default" library context here (first NULL parameter), and
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* we're not supplying any particular search criteria for our SHA256
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* implementation (second NULL parameter). Any SHA256 implementation will
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* do.
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* In a larger application this fetch would just be done once, and could
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* be used for multiple calls to other operations such as EVP_DigestInit_ex().
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*/
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sha256 = EVP_MD_fetch(NULL, "SHA256", NULL);
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if (sha256 == NULL)
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goto err;
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/* Initialise the digest operation */
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if (!EVP_DigestInit_ex(ctx, sha256, NULL))
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goto err;
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/*
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* Pass the message to be digested. This can be passed in over multiple
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* EVP_DigestUpdate calls if necessary
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*/
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if (!EVP_DigestUpdate(ctx, msg, sizeof(msg)))
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goto err;
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/* Allocate the output buffer */
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outdigest = OPENSSL_malloc(EVP_MD_get_size(sha256));
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if (outdigest == NULL)
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goto err;
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/* Now calculate the digest itself */
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if (!EVP_DigestFinal_ex(ctx, outdigest, &len))
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goto err;
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/* Print out the digest result */
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BIO_dump_fp(stdout, outdigest, len);
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ret = 0;
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err:
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/* Clean up all the resources we allocated */
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OPENSSL_free(outdigest);
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EVP_MD_free(sha256);
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EVP_MD_CTX_free(ctx);
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if (ret != 0)
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ERR_print_errors_fp(stderr);
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return ret;
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}
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=head1 ENCODING AND DECODING KEYS
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Many algorithms require the use of a key. Keys can be generated dynamically
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using the EVP APIs (for example see L<EVP_PKEY_Q_keygen(3)>). However it is often
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necessary to save or load keys (or their associated parameters) to or from some
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external format such as PEM or DER (see L<openssl-glossary(7)>). OpenSSL uses
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encoders and decoders to perform this task.
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Encoders and decoders are just algorithm implementations in the same way as
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any other algorithm implementation in OpenSSL. They are implemented by
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providers. The OpenSSL encoders and decoders are available in the default
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provider. They are also duplicated in the base provider.
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For information about encoders see L<OSSL_ENCODER_CTX_new_for_pkey(3)>. For
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information about decoders see L<OSSL_DECODER_CTX_new_for_pkey(3)>.
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As well as using encoders/decoders directly there are also some helper functions
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that can be used for certain well known and commonly used formats. For example
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see L<PEM_read_PrivateKey(3)> and L<PEM_write_PrivateKey(3)> for information
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about reading and writing key data from PEM encoded files.
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=head1 FURTHER READING
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See L<ossl-guide-libssl-introduction(7)> for an introduction to using C<libssl>.
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=head1 SEE ALSO
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L<openssl(1)>, L<ssl(7)>, L<evp(7)>, L<OSSL_LIB_CTX(3)>, L<openssl-threads(7)>,
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L<property(7)>, L<OSSL_PROVIDER-default(7)>, L<OSSL_PROVIDER-base(7)>,
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L<OSSL_PROVIDER-FIPS(7)>, L<OSSL_PROVIDER-legacy(7)>, L<OSSL_PROVIDER-null(7)>,
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L<openssl-glossary(7)>, L<provider(7)>
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=head1 COPYRIGHT
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Copyright 2000-2023 The OpenSSL Project Authors. All Rights Reserved.
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Licensed under the Apache License 2.0 (the "License"). You may not use
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this file except in compliance with the License. You can obtain a copy
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in the file LICENSE in the source distribution or at
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L<https://www.openssl.org/source/license.html>.
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=cut
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