doc/man1/genpkey.pod - third_party/openssl - Git at Google

 =pod

 =head1 NAME

 genpkey - generate a private key

 =head1 SYNOPSIS

 B<openssl> B<genpkey>
 [B<-help>]
 [B<-out filename>]
 [B<-outform PEM|DER>]
 [B<-pass arg>]
 [B<-cipher>]
 [B<-engine id>]
 [B<-paramfile file>]
 [B<-algorithm alg>]
 [B<-pkeyopt opt:value>]
 [B<-genparam>]
 [B<-text>]

 =head1 DESCRIPTION

 The B<genpkey> command generates a private key.

 =head1 OPTIONS

 =over 4

 =item B<-help>

 Print out a usage message.

 =item B<-out filename>

 Output the key to the specified file. If this argument is not specified then
 standard output is used.

 =item B<-outform DER|PEM>

 This specifies the output format DER or PEM.

 =item B<-pass arg>

 the output file password source. For more information about the format of B<arg>
 see the B<PASS PHRASE ARGUMENTS> section in L<openssl(1)>.

 =item B<-cipher>

 This option encrypts the private key with the supplied cipher. Any algorithm
 name accepted by EVP_get_cipherbyname() is acceptable such as B<des3>.

 =item B<-engine id>

 specifying an engine (by its unique B<id> string) will cause B<genpkey>
 to attempt to obtain a functional reference to the specified engine,
 thus initialising it if needed. The engine will then be set as the default
 for all available algorithms. If used this option should precede all other
 options.

 =item B<-algorithm alg>

 public key algorithm to use such as RSA, DSA or DH. If used this option must
 precede any B<-pkeyopt> options. The options B<-paramfile> and B<-algorithm>
 are mutually exclusive.

 =item B<-pkeyopt opt:value>

 set the public key algorithm option B<opt> to B<value>. The precise set of
 options supported depends on the public key algorithm used and its
 implementation. See B<KEY GENERATION OPTIONS> below for more details.

 =item B<-genparam>

 generate a set of parameters instead of a private key. If used this option must
 precede any B<-algorithm>, B<-paramfile> or B<-pkeyopt> options.

 =item B<-paramfile filename>

 Some public key algorithms generate a private key based on a set of parameters.
 They can be supplied using this option. If this option is used the public key
 algorithm used is determined by the parameters. If used this option must
 precede any B<-pkeyopt> options. The options B<-paramfile> and B<-algorithm>
 are mutually exclusive.

 =item B<-text>

 Print an (unencrypted) text representation of private and public keys and
 parameters along with the PEM or DER structure.

 =back

 =head1 KEY GENERATION OPTIONS

 The options supported by each algorithm and indeed each implementation of an
 algorithm can vary. The options for the OpenSSL implementations are detailed
 below.

 =head1 RSA KEY GENERATION OPTIONS

 =over 4

 =item B<rsa_keygen_bits:numbits>

 The number of bits in the generated key. If not specified 1024 is used.

 =item B<rsa_keygen_pubexp:value>

 The RSA public exponent value. This can be a large decimal or
 hexadecimal value if preceded by B<0x>. Default value is 65537.

 =back

 =head1 RSA-PSS KEY GENERATION OPTIONS

 Note: by default an B<RSA-PSS> key has no parameter restrictions.

 =over 4

 =item B<rsa_keygen_bits:numbits>, B<rsa_keygen_pubexp:value>

 These options have the same meaning as the B<RSA> algorithm.

 =item B<rsa_pss_keygen_md:digest>

 If set the key is restricted and can only use B<digest> for signing.

 =item B<rsa_pss_keygen_mgf1_md:digest>

 If set the key is restricted and can only use B<digest> as it's MGF1
 parameter.

 =item B<rsa_pss_keygen_saltlen:len>

 If set the key is restricted and B<len> specifies the minimum salt length.

 =back

 =head1 DSA PARAMETER GENERATION OPTIONS

 =over 4

 =item B<dsa_paramgen_bits:numbits>

 The number of bits in the generated parameters. If not specified 1024 is used.

 =back

 =head1 DH PARAMETER GENERATION OPTIONS

 =over 4

 =item B<dh_paramgen_prime_len:numbits>

 The number of bits in the prime parameter B<p>.

 =item B<dh_paramgen_generator:value>

 The value to use for the generator B<g>.

 =item B<dh_rfc5114:num>

 If this option is set then the appropriate RFC5114 parameters are used
 instead of generating new parameters. The value B<num> can take the
 values 1, 2 or 3 corresponding to RFC5114 DH parameters consisting of
 1024 bit group with 160 bit subgroup, 2048 bit group with 224 bit subgroup
 and 2048 bit group with 256 bit subgroup as mentioned in RFC5114 sections
 2.1, 2.2 and 2.3 respectively.

 =back

 =head1 EC PARAMETER GENERATION OPTIONS

 The EC parameter generation options below can also
 be supplied as EC key generation options. This can (for example) generate a
 key from a named curve without the need to use an explicit parameter file.

 =over 4

 =item B<ec_paramgen_curve:curve>

 the EC curve to use. OpenSSL supports NIST curve names such as "P-256".

 =item B<ec_param_enc:encoding>

 the encoding to use for parameters. The "encoding" parameter must be either
 "named_curve" or "explicit".

 =back

 =head1 GOST2001 KEY GENERATION AND PARAMETER OPTIONS

 Gost 2001 support is not enabled by default. To enable this algorithm,
 one should load the ccgost engine in the OpenSSL configuration file.
 See README.gost file in the engines/ccgost directory of the source
 distribution for more details.

 Use of a parameter file for the GOST R 34.10 algorithm is optional.
 Parameters can be specified during key generation directly as well as
 during generation of parameter file.

 =over 4

 =item B<paramset:name>

 Specifies GOST R 34.10-2001 parameter set according to RFC 4357.
 Parameter set can be specified using abbreviated name, object short name or
 numeric OID. Following parameter sets are supported:

   paramset   OID               Usage
   A          1.2.643.2.2.35.1  Signature
   B          1.2.643.2.2.35.2  Signature
   C          1.2.643.2.2.35.3  Signature
   XA         1.2.643.2.2.36.0  Key exchange
   XB         1.2.643.2.2.36.1  Key exchange
   test       1.2.643.2.2.35.0  Test purposes

 =back

 =head1 X25519 KEY GENERATION OPTIONS

 The X25519 algorithm does not currently support any key generation options.


 =head1 NOTES

 The use of the genpkey program is encouraged over the algorithm specific
 utilities because additional algorithm options and ENGINE provided algorithms
 can be used.

 =head1 EXAMPLES

 Generate an RSA private key using default parameters:

  openssl genpkey -algorithm RSA -out key.pem

 Encrypt output private key using 128 bit AES and the passphrase "hello":

  openssl genpkey -algorithm RSA -out key.pem -aes-128-cbc -pass pass:hello

 Generate a 2048 bit RSA key using 3 as the public exponent:

  openssl genpkey -algorithm RSA -out key.pem -pkeyopt rsa_keygen_bits:2048 \
                                                 -pkeyopt rsa_keygen_pubexp:3

 Generate 1024 bit DSA parameters:

  openssl genpkey -genparam -algorithm DSA -out dsap.pem \
                                                 -pkeyopt dsa_paramgen_bits:1024

 Generate DSA key from parameters:

  openssl genpkey -paramfile dsap.pem -out dsakey.pem

 Generate 1024 bit DH parameters:

  openssl genpkey -genparam -algorithm DH -out dhp.pem \
                                         -pkeyopt dh_paramgen_prime_len:1024

 Output RFC5114 2048 bit DH parameters with 224 bit subgroup:

  openssl genpkey -genparam -algorithm DH -out dhp.pem -pkeyopt dh_rfc5114:2

 Generate DH key from parameters:

  openssl genpkey -paramfile dhp.pem -out dhkey.pem

 Generate EC parameters:

  openssl genpkey -genparam -algorithm EC -out ecp.pem \
         -pkeyopt ec_paramgen_curve:secp384r1 \
         -pkeyopt ec_param_enc:named_curve

 Generate EC key from parameters:

  openssl genpkey -paramfile ecp.pem -out eckey.pem

 Generate EC key directly:

  openssl genpkey -algorithm EC -out eckey.pem \
         -pkeyopt ec_paramgen_curve:P-384 \
         -pkeyopt ec_param_enc:named_curve

 Generate an X25519 private key:

  openssl genpkey -algorithm X25519 -out xkey.pem

 =head1 HISTORY

 The ability to use NIST curve names, and to generate an EC key directly,
 were added in OpenSSL 1.0.2.

 =head1 COPYRIGHT

 Copyright 2006-2016 The OpenSSL Project Authors. All Rights Reserved.

 Licensed under the OpenSSL license (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

	genpkey - generate a private key

	=head1 SYNOPSIS

	B<openssl> B<genpkey>
	[B<-help>]
	[B<-out filename>]
	[B<-outform PEM\|DER>]
	[B<-pass arg>]
	[B<-cipher>]
	[B<-engine id>]
	[B<-paramfile file>]
	[B<-algorithm alg>]
	[B<-pkeyopt opt:value>]
	[B<-genparam>]
	[B<-text>]

	=head1 DESCRIPTION

	The B<genpkey> command generates a private key.

	=head1 OPTIONS

	=over 4

	=item B<-help>

	Print out a usage message.

	=item B<-out filename>

	Output the key to the specified file. If this argument is not specified then
	standard output is used.

	=item B<-outform DER\|PEM>

	This specifies the output format DER or PEM.

	=item B<-pass arg>

	the output file password source. For more information about the format of B<arg>
	see the B<PASS PHRASE ARGUMENTS> section in L<openssl(1)>.

	=item B<-cipher>

	This option encrypts the private key with the supplied cipher. Any algorithm
	name accepted by EVP_get_cipherbyname() is acceptable such as B<des3>.

	=item B<-engine id>

	specifying an engine (by its unique B<id> string) will cause B<genpkey>
	to attempt to obtain a functional reference to the specified engine,
	thus initialising it if needed. The engine will then be set as the default
	for all available algorithms. If used this option should precede all other
	options.

	=item B<-algorithm alg>

	public key algorithm to use such as RSA, DSA or DH. If used this option must
	precede any B<-pkeyopt> options. The options B<-paramfile> and B<-algorithm>
	are mutually exclusive.

	=item B<-pkeyopt opt:value>

	set the public key algorithm option B<opt> to B<value>. The precise set of
	options supported depends on the public key algorithm used and its
	implementation. See B<KEY GENERATION OPTIONS> below for more details.

	=item B<-genparam>

	generate a set of parameters instead of a private key. If used this option must
	precede any B<-algorithm>, B<-paramfile> or B<-pkeyopt> options.

	=item B<-paramfile filename>

	Some public key algorithms generate a private key based on a set of parameters.
	They can be supplied using this option. If this option is used the public key
	algorithm used is determined by the parameters. If used this option must
	precede any B<-pkeyopt> options. The options B<-paramfile> and B<-algorithm>
	are mutually exclusive.

	=item B<-text>

	Print an (unencrypted) text representation of private and public keys and
	parameters along with the PEM or DER structure.

	=back

	=head1 KEY GENERATION OPTIONS

	The options supported by each algorithm and indeed each implementation of an
	algorithm can vary. The options for the OpenSSL implementations are detailed
	below.

	=head1 RSA KEY GENERATION OPTIONS

	=over 4

	=item B<rsa_keygen_bits:numbits>

	The number of bits in the generated key. If not specified 1024 is used.

	=item B<rsa_keygen_pubexp:value>

	The RSA public exponent value. This can be a large decimal or
	hexadecimal value if preceded by B<0x>. Default value is 65537.

	=back

	=head1 RSA-PSS KEY GENERATION OPTIONS

	Note: by default an B<RSA-PSS> key has no parameter restrictions.

	=over 4

	=item B<rsa_keygen_bits:numbits>, B<rsa_keygen_pubexp:value>

	These options have the same meaning as the B<RSA> algorithm.

	=item B<rsa_pss_keygen_md:digest>

	If set the key is restricted and can only use B<digest> for signing.

	=item B<rsa_pss_keygen_mgf1_md:digest>

	If set the key is restricted and can only use B<digest> as it's MGF1
	parameter.

	=item B<rsa_pss_keygen_saltlen:len>

	If set the key is restricted and B<len> specifies the minimum salt length.

	=back

	=head1 DSA PARAMETER GENERATION OPTIONS

	=over 4

	=item B<dsa_paramgen_bits:numbits>

	The number of bits in the generated parameters. If not specified 1024 is used.

	=back

	=head1 DH PARAMETER GENERATION OPTIONS

	=over 4

	=item B<dh_paramgen_prime_len:numbits>

	The number of bits in the prime parameter B<p>.

	=item B<dh_paramgen_generator:value>

	The value to use for the generator B<g>.

	=item B<dh_rfc5114:num>

	If this option is set then the appropriate RFC5114 parameters are used
	instead of generating new parameters. The value B<num> can take the
	values 1, 2 or 3 corresponding to RFC5114 DH parameters consisting of
	1024 bit group with 160 bit subgroup, 2048 bit group with 224 bit subgroup
	and 2048 bit group with 256 bit subgroup as mentioned in RFC5114 sections
	2.1, 2.2 and 2.3 respectively.

	=back

	=head1 EC PARAMETER GENERATION OPTIONS

	The EC parameter generation options below can also
	be supplied as EC key generation options. This can (for example) generate a
	key from a named curve without the need to use an explicit parameter file.

	=over 4

	=item B<ec_paramgen_curve:curve>

	the EC curve to use. OpenSSL supports NIST curve names such as "P-256".

	=item B<ec_param_enc:encoding>

	the encoding to use for parameters. The "encoding" parameter must be either
	"named_curve" or "explicit".

	=back

	=head1 GOST2001 KEY GENERATION AND PARAMETER OPTIONS

	Gost 2001 support is not enabled by default. To enable this algorithm,
	one should load the ccgost engine in the OpenSSL configuration file.
	See README.gost file in the engines/ccgost directory of the source
	distribution for more details.

	Use of a parameter file for the GOST R 34.10 algorithm is optional.
	Parameters can be specified during key generation directly as well as
	during generation of parameter file.

	=over 4

	=item B<paramset:name>

	Specifies GOST R 34.10-2001 parameter set according to RFC 4357.
	Parameter set can be specified using abbreviated name, object short name or
	numeric OID. Following parameter sets are supported:

	paramset OID Usage
	A 1.2.643.2.2.35.1 Signature
	B 1.2.643.2.2.35.2 Signature
	C 1.2.643.2.2.35.3 Signature
	XA 1.2.643.2.2.36.0 Key exchange
	XB 1.2.643.2.2.36.1 Key exchange
	test 1.2.643.2.2.35.0 Test purposes

	=back

	=head1 X25519 KEY GENERATION OPTIONS

	The X25519 algorithm does not currently support any key generation options.


	=head1 NOTES

	The use of the genpkey program is encouraged over the algorithm specific
	utilities because additional algorithm options and ENGINE provided algorithms
	can be used.

	=head1 EXAMPLES

	Generate an RSA private key using default parameters:

	openssl genpkey -algorithm RSA -out key.pem

	Encrypt output private key using 128 bit AES and the passphrase "hello":

	openssl genpkey -algorithm RSA -out key.pem -aes-128-cbc -pass pass:hello

	Generate a 2048 bit RSA key using 3 as the public exponent:

	openssl genpkey -algorithm RSA -out key.pem -pkeyopt rsa_keygen_bits:2048 \
	-pkeyopt rsa_keygen_pubexp:3

	Generate 1024 bit DSA parameters:

	openssl genpkey -genparam -algorithm DSA -out dsap.pem \
	-pkeyopt dsa_paramgen_bits:1024

	Generate DSA key from parameters:

	openssl genpkey -paramfile dsap.pem -out dsakey.pem

	Generate 1024 bit DH parameters:

	openssl genpkey -genparam -algorithm DH -out dhp.pem \
	-pkeyopt dh_paramgen_prime_len:1024

	Output RFC5114 2048 bit DH parameters with 224 bit subgroup:

	openssl genpkey -genparam -algorithm DH -out dhp.pem -pkeyopt dh_rfc5114:2

	Generate DH key from parameters:

	openssl genpkey -paramfile dhp.pem -out dhkey.pem

	Generate EC parameters:

	openssl genpkey -genparam -algorithm EC -out ecp.pem \
	-pkeyopt ec_paramgen_curve:secp384r1 \
	-pkeyopt ec_param_enc:named_curve

	Generate EC key from parameters:

	openssl genpkey -paramfile ecp.pem -out eckey.pem

	Generate EC key directly:

	openssl genpkey -algorithm EC -out eckey.pem \
	-pkeyopt ec_paramgen_curve:P-384 \
	-pkeyopt ec_param_enc:named_curve

	Generate an X25519 private key:

	openssl genpkey -algorithm X25519 -out xkey.pem

	=head1 HISTORY

	The ability to use NIST curve names, and to generate an EC key directly,
	were added in OpenSSL 1.0.2.

	=head1 COPYRIGHT

	Copyright 2006-2016 The OpenSSL Project Authors. All Rights Reserved.

	Licensed under the OpenSSL license (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