doc/man3/EVP_MAC.pod - third_party/openssl - Git at Google

 =pod

 =head1 NAME

 EVP_MAC, EVP_MAC_CTX, EVP_MAC_CTX_new, EVP_MAC_CTX_new_id, EVP_MAC_CTX_free,
 EVP_MAC_CTX_copy, EVP_MAC_CTX_mac, EVP_MAC_size, EVP_MAC_init, EVP_MAC_update,
 EVP_MAC_final, EVP_MAC_ctrl, EVP_MAC_vctrl, EVP_MAC_ctrl_str,
 EVP_MAC_str2ctrl, EVP_MAC_hex2ctrl, EVP_MAC_nid, EVP_MAC_name,
 EVP_get_macbyname, EVP_get_macbynid, EVP_get_macbyobj - EVP MAC routines

 =head1 SYNOPSIS

  #include <openssl/evp.h>

  typedef struct evp_mac_st EVP_MAC;
  typedef struct evp_mac_ctx_st EVP_MAC_CTX;

  EVP_MAC_CTX *EVP_MAC_CTX_new(const EVP_MAC *mac);
  EVP_MAC_CTX *EVP_MAC_CTX_new_id(int nid);
  void EVP_MAC_CTX_free(EVP_MAC_CTX *ctx);
  int EVP_MAC_CTX_copy(EVP_MAC_CTX *dest, EVP_MAC_CTX *src);
  const EVP_MAC *EVP_MAC_CTX_mac(EVP_MAC_CTX *ctx);
  size_t EVP_MAC_size(EVP_MAC_CTX *ctx);
  int EVP_MAC_init(EVP_MAC_CTX *ctx);
  int EVP_MAC_update(EVP_MAC_CTX *ctx, const unsigned char *data, size_t datalen);
  int EVP_MAC_final(EVP_MAC_CTX *ctx, unsigned char *out, size_t *poutlen);
  int EVP_MAC_ctrl(EVP_MAC_CTX *ctx, int cmd, ...);
  int EVP_MAC_vctrl(EVP_MAC_CTX *ctx, int cmd, va_list args);
  int EVP_MAC_ctrl_str(EVP_MAC_CTX *ctx, const char *type, const char *value);
  int EVP_MAC_str2ctrl(EVP_MAC_CTX *ctx, int cmd, const char *value);
  int EVP_MAC_hex2ctrl(EVP_MAC_CTX *ctx, int cmd, const char *value);
  int EVP_MAC_nid(const EVP_MAC *mac);
  const char *EVP_MAC_name(const EVP_MAC *mac);
  const EVP_MAC *EVP_get_macbyname(const char *name);
  const EVP_MAC *EVP_get_macbynid(int nid);
  const EVP_MAC *EVP_get_macbyobj(const ASN1_OBJECT *o);

 =head1 DESCRIPTION

 These types and functions help the application to calculate MACs of
 different types and with different underlying algorithms if there are
 any.

 MACs are a bit complex insofar that some of them use other algorithms
 for actual computation.  HMAC uses a digest, and CMAC uses a cipher.
 Therefore, there are sometimes two contexts to keep track of, one for
 the MAC algorithm itself and one for the underlying computation
 algorithm if there is one.

 To make things less ambiguous, this manual talks about a "context" or
 "MAC context", which is to denote the MAC level context, and about a
 "underlying context", or "computation context", which is to denote the
 context for the underlying computation algorithm if there is one.

 =head2 Types

 B<EVP_MAC> is a type that holds the implementation of a MAC.

 B<EVP_MAC_CTX> is a context type that holds internal MAC information
 as well as a reference to a computation context, for those MACs that
 rely on an underlying computation algorithm.

 =head2 Context manipulation functions

 EVP_MAC_CTX_new() creates a new context for the MAC type C<mac>.
 EVP_MAC_CTX_new_id() creates a new context for the numerical MAC
 identity <nid>.
 The created context can then be used with most other functions
 described here.

 EVP_MAC_CTX_free() frees the contents of the context, including an
 underlying context if there is one, as well as the context itself.
 B<NULL> is a valid parameter, for which this function is a no-op.

 EVP_MAC_CTX_copy() makes a deep copy of the C<src> context to the
 C<dest> context.
 The C<dest> context I<must> have been created before calling this
 function.

 EVP_MAC_CTX_mac() returns the B<EVP_MAC> associated with the context
 C<ctx>.

 =head2 Computing functions

 EVP_MAC_init() sets up the underlying context with information given
 through diverse controls.
 This should be called before calling EVP_MAC_update() and
 EVP_MAC_final().

 EVP_MAC_update() adds C<datalen> bytes from C<data> to the MAC input.

 EVP_MAC_final() does the final computation and stores the result in
 the memory pointed at by C<out>, and sets its size in the B<size_t>
 the C<poutlen> points at.
 If C<out> is B<NULL>, then no computation is made.
 To figure out what the output length will be and allocate space for it
 dynamically, simply call with C<out> being B<NULL> and C<poutlen>
 pointing at a valid location, then allocate space and make a second
 call with C<out> pointing at the allocated space.

 EVP_MAC_ctrl() is used to manipulate or get information on aspects of
 the MAC which may vary depending on the MAC algorithm or its
 implementation.
 This includes the MAC key, and for MACs that use other algorithms to
 do their computation, this is also the way to tell it which one to
 use.
 This functions takes variable arguments, the exact expected arguments
 depend on C<cmd>.
 EVP_MAC_ctrl() can be called both before and after EVP_MAC_init(), but
 the effect will depend on what control is being use.
 See L</CONTROLS> below for a description of standard controls.

 EVP_MAC_vctrl() is the variant of EVP_MAC_ctrl() that takes a
 C<va_list> argument instead of variadic arguments.

 EVP_MAC_ctrl_str() is an alternative to EVP_MAC_ctrl() to control the
 MAC implementation as E<lt> C<type>, C<value> E<gt> pairs.
 The MAC implementation documentation should specify what control type
 strings are accepted.

 EVP_MAC_str2ctrl() and EVP_MAC_hex2ctrl() are helper functions to
 control the MAC implementation with raw strings or with strings
 containing hexadecimal numbers.
 The latter are decoded into bitstrings that are sent on to
 EVP_MAC_ctrl().

 =head2 Information functions

 EVP_MAC_size() returns the MAC output size for the given context.

 EVP_MAC_nid() returns the numeric identity of the given MAC implementation.

 EVP_MAC_name() returns the name of the given MAC implementation.

 =head2 Object database functions

 EVP_get_macbyname() fetches a MAC implementation from the object
 database by name.

 EVP_get_macbynid() fetches a MAC implementation from the object
 database by numeric identity.

 EVP_get_macbyobj() fetches a MAC implementation from the object
 database by ASN.1 OBJECT (i.e. an encoded OID).

 =head1 CONTROLS

 The standard controls are:

 =over 4

 =item B<EVP_MAC_CTRL_SET_KEY>

 This control expects two arguments: C<unsigned char *key>, C<size_t keylen>

 These will set the MAC key from the given string of the given length.
 The string may be any bitstring, and can contain NUL bytes.

 For MACs that use an underlying computation algorithm, the algorithm
 I<must> be set first, see B<EVP_MAC_CTRL_SET_ENGINE>,
 B<EVP_MAC_CTRL_SET_MD> and B<EVP_MAC_CTRL_SET_CIPHER> below.

 =item B<EVP_MAC_CTRL_SET_IV>

 This control expects two arguments: C<unsigned char *key>, C<size_t keylen>

 Some MAC implementations require an IV, this control sets the IV.

 =item B<EVP_MAC_CTRL_SET_CUSTOM>

 This control expects two arguments: C<unsigned char *custom>, C<size_t customlen>

 Some MAC implementations (KMAC, BLAKE2) accept a Customization String,
 this control sets the Customization String. The default value is "".

 =item B<EVP_MAC_CTRL_SET_SALT>

 This control expects two arguments: C<unsigned char *salt>, C<size_t saltlen>

 This option is used by BLAKE2 MAC.

 =item B<EVP_MAC_CTRL_SET_XOF>

 This control expects one argument: C<int xof>

 This option is used by KMAC.

 =item B<EVP_MAC_CTRL_SET_FLAGS>

 This control expects one argument: C<unsigned long flags>

 These will set the MAC flags to the given numbers.
 Some MACs do not support this option.

 =item B<EVP_MAC_CTRL_SET_ENGINE>

 =item B<EVP_MAC_CTRL_SET_MD>

 =item B<EVP_MAC_CTRL_SET_CIPHER>

 For MAC implementations that use an underlying computation algorithm,
 these controls set what the algorithm should be, and the engine that
 implements the algorithm if needed.

 Note that not all algorithms may support all digests. HMAC does not support
 variable output length digests such as SHAKE128 or SHAKE256.

 B<EVP_MAC_CTRL_SET_ENGINE> takes one argument: C<ENGINE *>

 B<EVP_MAC_CTRL_SET_MD> takes one argument: C<EVP_MD *>

 B<EVP_MAC_CTRL_SET_CIPHER> takes one argument: C<EVP_CIPHER *>

 =item B<EVP_MAC_CTRL_SET_SIZE>

 For MAC implementations that support it, set the output size that
 EVP_MAC_final() should produce.
 The allowed sizes vary between MAC implementations.

 =back

 All these control should be used before the calls to any of
 EVP_MAC_init(), EVP_MAC_update() and EVP_MAC_final() for a full
 computation.
 Anything else may give undefined results.

 =head1 NOTES

 EVP_get_macbynid(), EVP_get_macbyobj() and EVP_MAC_name() are
 implemented as a macro.

 =head1 RETURN VALUES

 EVP_MAC_CTX_new() and EVP_MAC_CTX_new_id() return a pointer to a newly
 created EVP_MAC_CTX, or NULL if allocation failed.

 EVP_MAC_CTX_free() returns nothing at all.

 EVP_MAC_CTX_copy(), EVP_MAC_init(), EVP_MAC_update(),
 and EVP_MAC_final() return 1 on success, 0 on error.

 EVP_MAC_ctrl(), EVP_MAC_ctrl_str(), EVP_MAC_str2ctrl() and
 EVP_MAC_hex2ctrl() return 1 on success and 0 or a negative value on
 error.
 In particular, the value -2 indicates that the given control type
 isn't supported by the MAC implementation.

 EVP_MAC_size() returns the expected output size, or 0 if it isn't
 set.
 If it isn't set, a call to EVP_MAC_init() should get it set.

 EVP_MAC_nid() returns the numeric identity for the given C<mac>.

 EVP_MAC_name() returns the name for the given C<mac>, if it has been
 added to the object database.

 EVP_add_mac() returns 1 if the given C<mac> was successfully added to
 the object database, otherwise 0.

 EVP_get_macbyname(), EVP_get_macbynid() and EVP_get_macbyobj() return
 the request MAC implementation, if it exists in the object database,
 otherwise B<NULL>.

 =head1 EXAMPLE

   #include <stdlib.h>
   #include <stdio.h>
   #include <string.h>
   #include <stdarg.h>
   #include <unistd.h>

   #include <openssl/evp.h>
   #include <openssl/err.h>

   int ctrl_ign_unsupported(EVP_MAC_CTX *ctx, int cmd, ...)
   {
       va_list args;
       int rv;

       va_start(args, cmd);
       rv = EVP_MAC_vctrl(ctx, cmd, args);
       va_end(args);

       if (rv == -2)
           rv = 1;       /* Ignore unsupported, pretend it worked fine */

       return rv;
   }

   int main() {
       const EVP_MAC *mac =
           EVP_get_macbyname(getenv("MY_MAC"));
       const EVP_CIPHER *cipher =
           EVP_get_cipherbyname(getenv("MY_MAC_CIPHER"));
       const EVP_MD *digest =
           EVP_get_digestbyname(getenv("MY_MAC_DIGEST"));
       const char *key = getenv("MY_KEY");
       EVP_MAC_CTX *ctx = NULL;

       unsigned char buf[4096];
       ssize_t read_l;
       size_t final_l;

       size_t i;

       if (mac == NULL
           || key == NULL
           || (ctx = EVP_MAC_CTX_new(mac)) == NULL
           || (cipher != NULL
               && !ctrl_ign_unsupported(ctx, EVP_MAC_CTRL_SET_CIPHER, cipher))
           || (digest != NULL
               && !ctrl_ign_unsupported(ctx, EVP_MAC_CTRL_SET_MD, digest))
           || EVP_MAC_ctrl(ctx, EVP_MAC_CTRL_SET_KEY, key, strlen(key)) <= 0)
           goto err;

       if (!EVP_MAC_init(ctx))
           goto err;

       while ( (read_l = read(STDIN_FILENO, buf, sizeof(buf))) < 0) {
           if (!EVP_MAC_update(ctx, buf, read_l))
               goto err;
       }

       if (!EVP_MAC_final(ctx, buf, &final_l))
           goto err;

       printf("Result: ");
       for (i = 0; i < final_l; i++)
           printf("%02X", buf[i]);
       printf("\n");

       EVP_MAC_CTX_free(ctx);
       exit(0);

    err:
       EVP_MAC_CTX_free(ctx);
       fprintf(stderr, "Something went wrong\n");
       ERR_print_errors_fp(stderr);
       exit (1);
   }

 A run of this program, called with correct environment variables, can
 look like this:

   $ MY_MAC=cmac MY_KEY=secret0123456789 MY_MAC_CIPHER=aes-128-cbc \
     LD_LIBRARY_PATH=. ./foo < foo.c
   Result: ECCAAFF041B22A2299EB90A1B53B6D45

 (in this example, that program was stored in F<foo.c> and compiled to
 F<./foo>)

 =head1 SEE ALSO

 L<EVP_MAC_BLAKE2(7)>,
 L<EVP_MAC_CMAC(7)>,
 L<EVP_MAC_GMAC(7)>,
 L<EVP_MAC_HMAC(7)>,
 L<EVP_MAC_KMAC(7)>,
 L<EVP_MAC_SIPHASH(7)>,
 L<EVP_MAC_POLY1305(7)>

 =head1 COPYRIGHT

 Copyright 2018 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
 L<https://www.openssl.org/source/license.html>.

 =cut
	=pod

	=head1 NAME

	EVP_MAC, EVP_MAC_CTX, EVP_MAC_CTX_new, EVP_MAC_CTX_new_id, EVP_MAC_CTX_free,
	EVP_MAC_CTX_copy, EVP_MAC_CTX_mac, EVP_MAC_size, EVP_MAC_init, EVP_MAC_update,
	EVP_MAC_final, EVP_MAC_ctrl, EVP_MAC_vctrl, EVP_MAC_ctrl_str,
	EVP_MAC_str2ctrl, EVP_MAC_hex2ctrl, EVP_MAC_nid, EVP_MAC_name,
	EVP_get_macbyname, EVP_get_macbynid, EVP_get_macbyobj - EVP MAC routines

	=head1 SYNOPSIS

	#include <openssl/evp.h>

	typedef struct evp_mac_st EVP_MAC;
	typedef struct evp_mac_ctx_st EVP_MAC_CTX;

	EVP_MAC_CTX EVP_MAC_CTX_new(const EVP_MAC mac);
	EVP_MAC_CTX *EVP_MAC_CTX_new_id(int nid);
	void EVP_MAC_CTX_free(EVP_MAC_CTX *ctx);
	int EVP_MAC_CTX_copy(EVP_MAC_CTX dest, EVP_MAC_CTX src);
	const EVP_MAC EVP_MAC_CTX_mac(EVP_MAC_CTX ctx);
	size_t EVP_MAC_size(EVP_MAC_CTX *ctx);
	int EVP_MAC_init(EVP_MAC_CTX *ctx);
	int EVP_MAC_update(EVP_MAC_CTX ctx, const unsigned char data, size_t datalen);
	int EVP_MAC_final(EVP_MAC_CTX ctx, unsigned char out, size_t *poutlen);
	int EVP_MAC_ctrl(EVP_MAC_CTX *ctx, int cmd, ...);
	int EVP_MAC_vctrl(EVP_MAC_CTX *ctx, int cmd, va_list args);
	int EVP_MAC_ctrl_str(EVP_MAC_CTX ctx, const char type, const char *value);
	int EVP_MAC_str2ctrl(EVP_MAC_CTX ctx, int cmd, const char value);
	int EVP_MAC_hex2ctrl(EVP_MAC_CTX ctx, int cmd, const char value);
	int EVP_MAC_nid(const EVP_MAC *mac);
	const char EVP_MAC_name(const EVP_MAC mac);
	const EVP_MAC EVP_get_macbyname(const char name);
	const EVP_MAC *EVP_get_macbynid(int nid);
	const EVP_MAC EVP_get_macbyobj(const ASN1_OBJECT o);

	=head1 DESCRIPTION

	These types and functions help the application to calculate MACs of
	different types and with different underlying algorithms if there are
	any.

	MACs are a bit complex insofar that some of them use other algorithms
	for actual computation. HMAC uses a digest, and CMAC uses a cipher.
	Therefore, there are sometimes two contexts to keep track of, one for
	the MAC algorithm itself and one for the underlying computation
	algorithm if there is one.

	To make things less ambiguous, this manual talks about a "context" or
	"MAC context", which is to denote the MAC level context, and about a
	"underlying context", or "computation context", which is to denote the
	context for the underlying computation algorithm if there is one.

	=head2 Types

	B<EVP_MAC> is a type that holds the implementation of a MAC.

	B<EVP_MAC_CTX> is a context type that holds internal MAC information
	as well as a reference to a computation context, for those MACs that
	rely on an underlying computation algorithm.

	=head2 Context manipulation functions

	EVP_MAC_CTX_new() creates a new context for the MAC type C<mac>.
	EVP_MAC_CTX_new_id() creates a new context for the numerical MAC
	identity <nid>.
	The created context can then be used with most other functions
	described here.

	EVP_MAC_CTX_free() frees the contents of the context, including an
	underlying context if there is one, as well as the context itself.
	B<NULL> is a valid parameter, for which this function is a no-op.

	EVP_MAC_CTX_copy() makes a deep copy of the C<src> context to the
	C<dest> context.
	The C<dest> context I<must> have been created before calling this
	function.

	EVP_MAC_CTX_mac() returns the B<EVP_MAC> associated with the context
	C<ctx>.

	=head2 Computing functions

	EVP_MAC_init() sets up the underlying context with information given
	through diverse controls.
	This should be called before calling EVP_MAC_update() and
	EVP_MAC_final().

	EVP_MAC_update() adds C<datalen> bytes from C<data> to the MAC input.

	EVP_MAC_final() does the final computation and stores the result in
	the memory pointed at by C<out>, and sets its size in the B<size_t>
	the C<poutlen> points at.
	If C<out> is B<NULL>, then no computation is made.
	To figure out what the output length will be and allocate space for it
	dynamically, simply call with C<out> being B<NULL> and C<poutlen>
	pointing at a valid location, then allocate space and make a second
	call with C<out> pointing at the allocated space.

	EVP_MAC_ctrl() is used to manipulate or get information on aspects of
	the MAC which may vary depending on the MAC algorithm or its
	implementation.
	This includes the MAC key, and for MACs that use other algorithms to
	do their computation, this is also the way to tell it which one to
	use.
	This functions takes variable arguments, the exact expected arguments
	depend on C<cmd>.
	EVP_MAC_ctrl() can be called both before and after EVP_MAC_init(), but
	the effect will depend on what control is being use.
	See L</CONTROLS> below for a description of standard controls.

	EVP_MAC_vctrl() is the variant of EVP_MAC_ctrl() that takes a
	C<va_list> argument instead of variadic arguments.

	EVP_MAC_ctrl_str() is an alternative to EVP_MAC_ctrl() to control the
	MAC implementation as E<lt> C<type>, C<value> E<gt> pairs.
	The MAC implementation documentation should specify what control type
	strings are accepted.

	EVP_MAC_str2ctrl() and EVP_MAC_hex2ctrl() are helper functions to
	control the MAC implementation with raw strings or with strings
	containing hexadecimal numbers.
	The latter are decoded into bitstrings that are sent on to
	EVP_MAC_ctrl().

	=head2 Information functions

	EVP_MAC_size() returns the MAC output size for the given context.

	EVP_MAC_nid() returns the numeric identity of the given MAC implementation.

	EVP_MAC_name() returns the name of the given MAC implementation.

	=head2 Object database functions

	EVP_get_macbyname() fetches a MAC implementation from the object
	database by name.

	EVP_get_macbynid() fetches a MAC implementation from the object
	database by numeric identity.

	EVP_get_macbyobj() fetches a MAC implementation from the object
	database by ASN.1 OBJECT (i.e. an encoded OID).

	=head1 CONTROLS

	The standard controls are:

	=over 4

	=item B<EVP_MAC_CTRL_SET_KEY>

	This control expects two arguments: C<unsigned char *key>, C<size_t keylen>

	These will set the MAC key from the given string of the given length.
	The string may be any bitstring, and can contain NUL bytes.

	For MACs that use an underlying computation algorithm, the algorithm
	I<must> be set first, see B<EVP_MAC_CTRL_SET_ENGINE>,
	B<EVP_MAC_CTRL_SET_MD> and B<EVP_MAC_CTRL_SET_CIPHER> below.

	=item B<EVP_MAC_CTRL_SET_IV>

	This control expects two arguments: C<unsigned char *key>, C<size_t keylen>

	Some MAC implementations require an IV, this control sets the IV.

	=item B<EVP_MAC_CTRL_SET_CUSTOM>

	This control expects two arguments: C<unsigned char *custom>, C<size_t customlen>

	Some MAC implementations (KMAC, BLAKE2) accept a Customization String,
	this control sets the Customization String. The default value is "".

	=item B<EVP_MAC_CTRL_SET_SALT>

	This control expects two arguments: C<unsigned char *salt>, C<size_t saltlen>

	This option is used by BLAKE2 MAC.

	=item B<EVP_MAC_CTRL_SET_XOF>

	This control expects one argument: C<int xof>

	This option is used by KMAC.

	=item B<EVP_MAC_CTRL_SET_FLAGS>

	This control expects one argument: C<unsigned long flags>

	These will set the MAC flags to the given numbers.
	Some MACs do not support this option.

	=item B<EVP_MAC_CTRL_SET_ENGINE>

	=item B<EVP_MAC_CTRL_SET_MD>

	=item B<EVP_MAC_CTRL_SET_CIPHER>

	For MAC implementations that use an underlying computation algorithm,
	these controls set what the algorithm should be, and the engine that
	implements the algorithm if needed.

	Note that not all algorithms may support all digests. HMAC does not support
	variable output length digests such as SHAKE128 or SHAKE256.

	B<EVP_MAC_CTRL_SET_ENGINE> takes one argument: C<ENGINE *>

	B<EVP_MAC_CTRL_SET_MD> takes one argument: C<EVP_MD *>

	B<EVP_MAC_CTRL_SET_CIPHER> takes one argument: C<EVP_CIPHER *>

	=item B<EVP_MAC_CTRL_SET_SIZE>

	For MAC implementations that support it, set the output size that
	EVP_MAC_final() should produce.
	The allowed sizes vary between MAC implementations.

	=back

	All these control should be used before the calls to any of
	EVP_MAC_init(), EVP_MAC_update() and EVP_MAC_final() for a full
	computation.
	Anything else may give undefined results.

	=head1 NOTES

	EVP_get_macbynid(), EVP_get_macbyobj() and EVP_MAC_name() are
	implemented as a macro.

	=head1 RETURN VALUES

	EVP_MAC_CTX_new() and EVP_MAC_CTX_new_id() return a pointer to a newly
	created EVP_MAC_CTX, or NULL if allocation failed.

	EVP_MAC_CTX_free() returns nothing at all.

	EVP_MAC_CTX_copy(), EVP_MAC_init(), EVP_MAC_update(),
	and EVP_MAC_final() return 1 on success, 0 on error.

	EVP_MAC_ctrl(), EVP_MAC_ctrl_str(), EVP_MAC_str2ctrl() and
	EVP_MAC_hex2ctrl() return 1 on success and 0 or a negative value on
	error.
	In particular, the value -2 indicates that the given control type
	isn't supported by the MAC implementation.

	EVP_MAC_size() returns the expected output size, or 0 if it isn't
	set.
	If it isn't set, a call to EVP_MAC_init() should get it set.

	EVP_MAC_nid() returns the numeric identity for the given C<mac>.

	EVP_MAC_name() returns the name for the given C<mac>, if it has been
	added to the object database.

	EVP_add_mac() returns 1 if the given C<mac> was successfully added to
	the object database, otherwise 0.

	EVP_get_macbyname(), EVP_get_macbynid() and EVP_get_macbyobj() return
	the request MAC implementation, if it exists in the object database,
	otherwise B<NULL>.

	=head1 EXAMPLE

	#include <stdlib.h>
	#include <stdio.h>
	#include <string.h>
	#include <stdarg.h>
	#include <unistd.h>

	#include <openssl/evp.h>
	#include <openssl/err.h>

	int ctrl_ign_unsupported(EVP_MAC_CTX *ctx, int cmd, ...)
	{
	va_list args;
	int rv;

	va_start(args, cmd);
	rv = EVP_MAC_vctrl(ctx, cmd, args);
	va_end(args);

	if (rv == -2)
	rv = 1; /* Ignore unsupported, pretend it worked fine */

	return rv;
	}

	int main() {
	const EVP_MAC *mac =
	EVP_get_macbyname(getenv("MY_MAC"));
	const EVP_CIPHER *cipher =
	EVP_get_cipherbyname(getenv("MY_MAC_CIPHER"));
	const EVP_MD *digest =
	EVP_get_digestbyname(getenv("MY_MAC_DIGEST"));
	const char *key = getenv("MY_KEY");
	EVP_MAC_CTX *ctx = NULL;

	unsigned char buf[4096];
	ssize_t read_l;
	size_t final_l;

	size_t i;

	if (mac == NULL
	\|\| key == NULL
	\|\| (ctx = EVP_MAC_CTX_new(mac)) == NULL
	\|\| (cipher != NULL
	&& !ctrl_ign_unsupported(ctx, EVP_MAC_CTRL_SET_CIPHER, cipher))
	\|\| (digest != NULL
	&& !ctrl_ign_unsupported(ctx, EVP_MAC_CTRL_SET_MD, digest))
	\|\| EVP_MAC_ctrl(ctx, EVP_MAC_CTRL_SET_KEY, key, strlen(key)) <= 0)
	goto err;

	if (!EVP_MAC_init(ctx))
	goto err;

	while ( (read_l = read(STDIN_FILENO, buf, sizeof(buf))) < 0) {
	if (!EVP_MAC_update(ctx, buf, read_l))
	goto err;
	}

	if (!EVP_MAC_final(ctx, buf, &final_l))
	goto err;

	printf("Result: ");
	for (i = 0; i < final_l; i++)
	printf("%02X", buf[i]);
	printf("\n");

	EVP_MAC_CTX_free(ctx);
	exit(0);

	err:
	EVP_MAC_CTX_free(ctx);
	fprintf(stderr, "Something went wrong\n");
	ERR_print_errors_fp(stderr);
	exit (1);
	}

	A run of this program, called with correct environment variables, can
	look like this:

	$ MY_MAC=cmac MY_KEY=secret0123456789 MY_MAC_CIPHER=aes-128-cbc \
	LD_LIBRARY_PATH=. ./foo < foo.c
	Result: ECCAAFF041B22A2299EB90A1B53B6D45

	(in this example, that program was stored in F<foo.c> and compiled to
	F<./foo>)

	=head1 SEE ALSO

	L<EVP_MAC_BLAKE2(7)>,
	L<EVP_MAC_CMAC(7)>,
	L<EVP_MAC_GMAC(7)>,
	L<EVP_MAC_HMAC(7)>,
	L<EVP_MAC_KMAC(7)>,
	L<EVP_MAC_SIPHASH(7)>,
	L<EVP_MAC_POLY1305(7)>

	=head1 COPYRIGHT

	Copyright 2018 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
	L<https://www.openssl.org/source/license.html>.

	=cut