doc/man1/pkcs12.pod - third_party/openssl - Git at Google

 =pod

 =head1 NAME

 pkcs12 - PKCS#12 file utility

 =head1 SYNOPSIS

 B<openssl> B<pkcs12>
 [B<-help>]
 [B<-export>]
 [B<-chain>]
 [B<-inkey filename>]
 [B<-certfile filename>]
 [B<-name name>]
 [B<-caname name>]
 [B<-in filename>]
 [B<-out filename>]
 [B<-noout>]
 [B<-nomacver>]
 [B<-nocerts>]
 [B<-clcerts>]
 [B<-cacerts>]
 [B<-nokeys>]
 [B<-info>]
 [B<-des | -des3 | -idea | -aes128 | -aes192 | -aes256 | -aria128 | -aria192 | -aria256 | -camellia128 | -camellia192 | -camellia256 | -nodes>]
 [B<-noiter>]
 [B<-maciter | -nomaciter | -nomac>]
 [B<-twopass>]
 [B<-descert>]
 [B<-certpbe cipher>]
 [B<-keypbe cipher>]
 [B<-macalg digest>]
 [B<-keyex>]
 [B<-keysig>]
 [B<-password arg>]
 [B<-passin arg>]
 [B<-passout arg>]
 [B<-rand file(s)>]
 [B<-CAfile file>]
 [B<-CApath dir>]
 [B<-no-CAfile>]
 [B<-no-CApath>]
 [B<-CSP name>]

 =head1 DESCRIPTION

 The B<pkcs12> command allows PKCS#12 files (sometimes referred to as
 PFX files) to be created and parsed. PKCS#12 files are used by several
 programs including Netscape, MSIE and MS Outlook.

 =head1 OPTIONS

 There are a lot of options the meaning of some depends of whether a PKCS#12 file
 is being created or parsed. By default a PKCS#12 file is parsed. A PKCS#12
 file can be created by using the B<-export> option (see below).

 =head1 PARSING OPTIONS

 =over 4

 =item B<-help>

 Print out a usage message.

 =item B<-in filename>

 This specifies filename of the PKCS#12 file to be parsed. Standard input is used
 by default.

 =item B<-out filename>

 The filename to write certificates and private keys to, standard output by
 default.  They are all written in PEM format.

 =item B<-passin arg>

 the PKCS#12 file (i.e. input 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<-passout arg>

 pass phrase source to encrypt any outputted private keys with. For more
 information about the format of B<arg> see the B<PASS PHRASE ARGUMENTS> section
 in L<openssl(1)>.

 =item B<-password arg>

 With -export, -password is equivalent to -passout.
 Otherwise, -password is equivalent to -passin.

 =item B<-noout>

 this option inhibits output of the keys and certificates to the output file
 version of the PKCS#12 file.

 =item B<-clcerts>

 only output client certificates (not CA certificates).

 =item B<-cacerts>

 only output CA certificates (not client certificates).

 =item B<-nocerts>

 no certificates at all will be output.

 =item B<-nokeys>

 no private keys will be output.

 =item B<-info>

 output additional information about the PKCS#12 file structure, algorithms used and
 iteration counts.

 =item B<-des>

 use DES to encrypt private keys before outputting.

 =item B<-des3>

 use triple DES to encrypt private keys before outputting, this is the default.

 =item B<-idea>

 use IDEA to encrypt private keys before outputting.

 =item B<-aes128>, B<-aes192>, B<-aes256>

 use AES to encrypt private keys before outputting.

 =item B<-aria128>, B<-aria192>, B<-aria256>

 use ARIA to encrypt private keys before outputting.

 =item B<-camellia128>, B<-camellia192>, B<-camellia256>

 use Camellia to encrypt private keys before outputting.

 =item B<-nodes>

 don't encrypt the private keys at all.

 =item B<-nomacver>

 don't attempt to verify the integrity MAC before reading the file.

 =item B<-twopass>

 prompt for separate integrity and encryption passwords: most software
 always assumes these are the same so this option will render such
 PKCS#12 files unreadable.

 =back

 =head1 FILE CREATION OPTIONS

 =over 4

 =item B<-export>

 This option specifies that a PKCS#12 file will be created rather than
 parsed.

 =item B<-out filename>

 This specifies filename to write the PKCS#12 file to. Standard output is used
 by default.

 =item B<-in filename>

 The filename to read certificates and private keys from, standard input by
 default.  They must all be in PEM format. The order doesn't matter but one
 private key and its corresponding certificate should be present. If additional
 certificates are present they will also be included in the PKCS#12 file.

 =item B<-inkey filename>

 file to read private key from. If not present then a private key must be present
 in the input file.

 =item B<-name friendlyname>

 This specifies the "friendly name" for the certificate and private key. This
 name is typically displayed in list boxes by software importing the file.

 =item B<-certfile filename>

 A filename to read additional certificates from.

 =item B<-caname friendlyname>

 This specifies the "friendly name" for other certificates. This option may be
 used multiple times to specify names for all certificates in the order they
 appear. Netscape ignores friendly names on other certificates whereas MSIE
 displays them.

 =item B<-pass arg>, B<-passout arg>

 the PKCS#12 file (i.e. 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<-passin password>

 pass phrase source to decrypt any input private keys with. For more information
 about the format of B<arg> see the B<PASS PHRASE ARGUMENTS> section in
 L<openssl(1)>.

 =item B<-chain>

 if this option is present then an attempt is made to include the entire
 certificate chain of the user certificate. The standard CA store is used
 for this search. If the search fails it is considered a fatal error.

 =item B<-descert>

 encrypt the certificate using triple DES, this may render the PKCS#12
 file unreadable by some "export grade" software. By default the private
 key is encrypted using triple DES and the certificate using 40 bit RC2.

 =item B<-keypbe alg>, B<-certpbe alg>

 these options allow the algorithm used to encrypt the private key and
 certificates to be selected. Any PKCS#5 v1.5 or PKCS#12 PBE algorithm name
 can be used (see B<NOTES> section for more information). If a cipher name
 (as output by the B<list-cipher-algorithms> command is specified then it
 is used with PKCS#5 v2.0. For interoperability reasons it is advisable to only
 use PKCS#12 algorithms.

 =item B<-keyex|-keysig>

 specifies that the private key is to be used for key exchange or just signing.
 This option is only interpreted by MSIE and similar MS software. Normally
 "export grade" software will only allow 512 bit RSA keys to be used for
 encryption purposes but arbitrary length keys for signing. The B<-keysig>
 option marks the key for signing only. Signing only keys can be used for
 S/MIME signing, authenticode (ActiveX control signing)  and SSL client
 authentication, however due to a bug only MSIE 5.0 and later support
 the use of signing only keys for SSL client authentication.

 =item B<-macalg digest>

 specify the MAC digest algorithm. If not included them SHA1 will be used.

 =item B<-nomaciter>, B<-noiter>

 these options affect the iteration counts on the MAC and key algorithms.
 Unless you wish to produce files compatible with MSIE 4.0 you should leave
 these options alone.

 To discourage attacks by using large dictionaries of common passwords the
 algorithm that derives keys from passwords can have an iteration count applied
 to it: this causes a certain part of the algorithm to be repeated and slows it
 down. The MAC is used to check the file integrity but since it will normally
 have the same password as the keys and certificates it could also be attacked.
 By default both MAC and encryption iteration counts are set to 2048, using
 these options the MAC and encryption iteration counts can be set to 1, since
 this reduces the file security you should not use these options unless you
 really have to. Most software supports both MAC and key iteration counts.
 MSIE 4.0 doesn't support MAC iteration counts so it needs the B<-nomaciter>
 option.

 =item B<-maciter>

 This option is included for compatibility with previous versions, it used
 to be needed to use MAC iterations counts but they are now used by default.

 =item B<-nomac>

 don't attempt to provide the MAC integrity.

 =item B<-rand file(s)>

 a file or files containing random data used to seed the random number
 generator, or an EGD socket (see L<RAND_egd(3)>).
 Multiple files can be specified separated by an OS-dependent character.
 The separator is B<;> for MS-Windows, B<,> for OpenVMS, and B<:> for
 all others.

 =item B<-CAfile file>

 CA storage as a file.

 =item B<-CApath dir>

 CA storage as a directory. This directory must be a standard certificate
 directory: that is a hash of each subject name (using B<x509 -hash>) should be
 linked to each certificate.

 =item B<-no-CAfile>

 Do not load the trusted CA certificates from the default file location

 =item B<-no-CApath>

 Do not load the trusted CA certificates from the default directory location

 =item B<-CSP name>

 write B<name> as a Microsoft CSP name.

 =back

 =head1 NOTES

 Although there are a large number of options most of them are very rarely
 used. For PKCS#12 file parsing only B<-in> and B<-out> need to be used
 for PKCS#12 file creation B<-export> and B<-name> are also used.

 If none of the B<-clcerts>, B<-cacerts> or B<-nocerts> options are present
 then all certificates will be output in the order they appear in the input
 PKCS#12 files. There is no guarantee that the first certificate present is
 the one corresponding to the private key. Certain software which requires
 a private key and certificate and assumes the first certificate in the
 file is the one corresponding to the private key: this may not always
 be the case. Using the B<-clcerts> option will solve this problem by only
 outputting the certificate corresponding to the private key. If the CA
 certificates are required then they can be output to a separate file using
 the B<-nokeys -cacerts> options to just output CA certificates.

 The B<-keypbe> and B<-certpbe> algorithms allow the precise encryption
 algorithms for private keys and certificates to be specified. Normally
 the defaults are fine but occasionally software can't handle triple DES
 encrypted private keys, then the option B<-keypbe PBE-SHA1-RC2-40> can
 be used to reduce the private key encryption to 40 bit RC2. A complete
 description of all algorithms is contained in the B<pkcs8> manual page.

 Prior 1.1 release passwords containing non-ASCII characters were encoded
 in non-compliant manner, which limited interoperability, in first hand
 with Windows. But switching to standard-compliant password encoding
 poses problem accessing old data protected with broken encoding. For
 this reason even legacy encodings is attempted when reading the
 data. If you use PKCS#12 files in production application you are advised
 to convert the data, because implemented heuristic approach is not
 MT-safe, its sole goal is to facilitate the data upgrade with this
 utility.

 =head1 EXAMPLES

 Parse a PKCS#12 file and output it to a file:

  openssl pkcs12 -in file.p12 -out file.pem

 Output only client certificates to a file:

  openssl pkcs12 -in file.p12 -clcerts -out file.pem

 Don't encrypt the private key:

  openssl pkcs12 -in file.p12 -out file.pem -nodes

 Print some info about a PKCS#12 file:

  openssl pkcs12 -in file.p12 -info -noout

 Create a PKCS#12 file:

  openssl pkcs12 -export -in file.pem -out file.p12 -name "My Certificate"

 Include some extra certificates:

  openssl pkcs12 -export -in file.pem -out file.p12 -name "My Certificate" \
   -certfile othercerts.pem

 =head1 SEE ALSO

 L<pkcs8(1)>

 =head1 COPYRIGHT

 Copyright 2000-2017 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

	pkcs12 - PKCS#12 file utility

	=head1 SYNOPSIS

	B<openssl> B<pkcs12>
	[B<-help>]
	[B<-export>]
	[B<-chain>]
	[B<-inkey filename>]
	[B<-certfile filename>]
	[B<-name name>]
	[B<-caname name>]
	[B<-in filename>]
	[B<-out filename>]
	[B<-noout>]
	[B<-nomacver>]
	[B<-nocerts>]
	[B<-clcerts>]
	[B<-cacerts>]
	[B<-nokeys>]
	[B<-info>]
	[B<-des \| -des3 \| -idea \| -aes128 \| -aes192 \| -aes256 \| -aria128 \| -aria192 \| -aria256 \| -camellia128 \| -camellia192 \| -camellia256 \| -nodes>]
	[B<-noiter>]
	[B<-maciter \| -nomaciter \| -nomac>]
	[B<-twopass>]
	[B<-descert>]
	[B<-certpbe cipher>]
	[B<-keypbe cipher>]
	[B<-macalg digest>]
	[B<-keyex>]
	[B<-keysig>]
	[B<-password arg>]
	[B<-passin arg>]
	[B<-passout arg>]
	[B<-rand file(s)>]
	[B<-CAfile file>]
	[B<-CApath dir>]
	[B<-no-CAfile>]
	[B<-no-CApath>]
	[B<-CSP name>]

	=head1 DESCRIPTION

	The B<pkcs12> command allows PKCS#12 files (sometimes referred to as
	PFX files) to be created and parsed. PKCS#12 files are used by several
	programs including Netscape, MSIE and MS Outlook.

	=head1 OPTIONS

	There are a lot of options the meaning of some depends of whether a PKCS#12 file
	is being created or parsed. By default a PKCS#12 file is parsed. A PKCS#12
	file can be created by using the B<-export> option (see below).

	=head1 PARSING OPTIONS

	=over 4

	=item B<-help>

	Print out a usage message.

	=item B<-in filename>

	This specifies filename of the PKCS#12 file to be parsed. Standard input is used
	by default.

	=item B<-out filename>

	The filename to write certificates and private keys to, standard output by
	default. They are all written in PEM format.

	=item B<-passin arg>

	the PKCS#12 file (i.e. input 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<-passout arg>

	pass phrase source to encrypt any outputted private keys with. For more
	information about the format of B<arg> see the B<PASS PHRASE ARGUMENTS> section
	in L<openssl(1)>.

	=item B<-password arg>

	With -export, -password is equivalent to -passout.
	Otherwise, -password is equivalent to -passin.

	=item B<-noout>

	this option inhibits output of the keys and certificates to the output file
	version of the PKCS#12 file.

	=item B<-clcerts>

	only output client certificates (not CA certificates).

	=item B<-cacerts>

	only output CA certificates (not client certificates).

	=item B<-nocerts>

	no certificates at all will be output.

	=item B<-nokeys>

	no private keys will be output.

	=item B<-info>

	output additional information about the PKCS#12 file structure, algorithms used and
	iteration counts.

	=item B<-des>

	use DES to encrypt private keys before outputting.

	=item B<-des3>

	use triple DES to encrypt private keys before outputting, this is the default.

	=item B<-idea>

	use IDEA to encrypt private keys before outputting.

	=item B<-aes128>, B<-aes192>, B<-aes256>

	use AES to encrypt private keys before outputting.

	=item B<-aria128>, B<-aria192>, B<-aria256>

	use ARIA to encrypt private keys before outputting.

	=item B<-camellia128>, B<-camellia192>, B<-camellia256>

	use Camellia to encrypt private keys before outputting.

	=item B<-nodes>

	don't encrypt the private keys at all.

	=item B<-nomacver>

	don't attempt to verify the integrity MAC before reading the file.

	=item B<-twopass>

	prompt for separate integrity and encryption passwords: most software
	always assumes these are the same so this option will render such
	PKCS#12 files unreadable.

	=back

	=head1 FILE CREATION OPTIONS

	=over 4

	=item B<-export>

	This option specifies that a PKCS#12 file will be created rather than
	parsed.

	=item B<-out filename>

	This specifies filename to write the PKCS#12 file to. Standard output is used
	by default.

	=item B<-in filename>

	The filename to read certificates and private keys from, standard input by
	default. They must all be in PEM format. The order doesn't matter but one
	private key and its corresponding certificate should be present. If additional
	certificates are present they will also be included in the PKCS#12 file.

	=item B<-inkey filename>

	file to read private key from. If not present then a private key must be present
	in the input file.

	=item B<-name friendlyname>

	This specifies the "friendly name" for the certificate and private key. This
	name is typically displayed in list boxes by software importing the file.

	=item B<-certfile filename>

	A filename to read additional certificates from.

	=item B<-caname friendlyname>

	This specifies the "friendly name" for other certificates. This option may be
	used multiple times to specify names for all certificates in the order they
	appear. Netscape ignores friendly names on other certificates whereas MSIE
	displays them.

	=item B<-pass arg>, B<-passout arg>

	the PKCS#12 file (i.e. 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<-passin password>

	pass phrase source to decrypt any input private keys with. For more information
	about the format of B<arg> see the B<PASS PHRASE ARGUMENTS> section in
	L<openssl(1)>.

	=item B<-chain>

	if this option is present then an attempt is made to include the entire
	certificate chain of the user certificate. The standard CA store is used
	for this search. If the search fails it is considered a fatal error.

	=item B<-descert>

	encrypt the certificate using triple DES, this may render the PKCS#12
	file unreadable by some "export grade" software. By default the private
	key is encrypted using triple DES and the certificate using 40 bit RC2.

	=item B<-keypbe alg>, B<-certpbe alg>

	these options allow the algorithm used to encrypt the private key and
	certificates to be selected. Any PKCS#5 v1.5 or PKCS#12 PBE algorithm name
	can be used (see B<NOTES> section for more information). If a cipher name
	(as output by the B<list-cipher-algorithms> command is specified then it
	is used with PKCS#5 v2.0. For interoperability reasons it is advisable to only
	use PKCS#12 algorithms.

	=item B<-keyex\|-keysig>

	specifies that the private key is to be used for key exchange or just signing.
	This option is only interpreted by MSIE and similar MS software. Normally
	"export grade" software will only allow 512 bit RSA keys to be used for
	encryption purposes but arbitrary length keys for signing. The B<-keysig>
	option marks the key for signing only. Signing only keys can be used for
	S/MIME signing, authenticode (ActiveX control signing) and SSL client
	authentication, however due to a bug only MSIE 5.0 and later support
	the use of signing only keys for SSL client authentication.

	=item B<-macalg digest>

	specify the MAC digest algorithm. If not included them SHA1 will be used.

	=item B<-nomaciter>, B<-noiter>

	these options affect the iteration counts on the MAC and key algorithms.
	Unless you wish to produce files compatible with MSIE 4.0 you should leave
	these options alone.

	To discourage attacks by using large dictionaries of common passwords the
	algorithm that derives keys from passwords can have an iteration count applied
	to it: this causes a certain part of the algorithm to be repeated and slows it
	down. The MAC is used to check the file integrity but since it will normally
	have the same password as the keys and certificates it could also be attacked.
	By default both MAC and encryption iteration counts are set to 2048, using
	these options the MAC and encryption iteration counts can be set to 1, since
	this reduces the file security you should not use these options unless you
	really have to. Most software supports both MAC and key iteration counts.
	MSIE 4.0 doesn't support MAC iteration counts so it needs the B<-nomaciter>
	option.

	=item B<-maciter>

	This option is included for compatibility with previous versions, it used
	to be needed to use MAC iterations counts but they are now used by default.

	=item B<-nomac>

	don't attempt to provide the MAC integrity.

	=item B<-rand file(s)>

	a file or files containing random data used to seed the random number
	generator, or an EGD socket (see L<RAND_egd(3)>).
	Multiple files can be specified separated by an OS-dependent character.
	The separator is B<;> for MS-Windows, B<,> for OpenVMS, and B<:> for
	all others.

	=item B<-CAfile file>

	CA storage as a file.

	=item B<-CApath dir>

	CA storage as a directory. This directory must be a standard certificate
	directory: that is a hash of each subject name (using B<x509 -hash>) should be
	linked to each certificate.

	=item B<-no-CAfile>

	Do not load the trusted CA certificates from the default file location

	=item B<-no-CApath>

	Do not load the trusted CA certificates from the default directory location

	=item B<-CSP name>

	write B<name> as a Microsoft CSP name.

	=back

	=head1 NOTES

	Although there are a large number of options most of them are very rarely
	used. For PKCS#12 file parsing only B<-in> and B<-out> need to be used
	for PKCS#12 file creation B<-export> and B<-name> are also used.

	If none of the B<-clcerts>, B<-cacerts> or B<-nocerts> options are present
	then all certificates will be output in the order they appear in the input
	PKCS#12 files. There is no guarantee that the first certificate present is
	the one corresponding to the private key. Certain software which requires
	a private key and certificate and assumes the first certificate in the
	file is the one corresponding to the private key: this may not always
	be the case. Using the B<-clcerts> option will solve this problem by only
	outputting the certificate corresponding to the private key. If the CA
	certificates are required then they can be output to a separate file using
	the B<-nokeys -cacerts> options to just output CA certificates.

	The B<-keypbe> and B<-certpbe> algorithms allow the precise encryption
	algorithms for private keys and certificates to be specified. Normally
	the defaults are fine but occasionally software can't handle triple DES
	encrypted private keys, then the option B<-keypbe PBE-SHA1-RC2-40> can
	be used to reduce the private key encryption to 40 bit RC2. A complete
	description of all algorithms is contained in the B<pkcs8> manual page.

	Prior 1.1 release passwords containing non-ASCII characters were encoded
	in non-compliant manner, which limited interoperability, in first hand
	with Windows. But switching to standard-compliant password encoding
	poses problem accessing old data protected with broken encoding. For
	this reason even legacy encodings is attempted when reading the
	data. If you use PKCS#12 files in production application you are advised
	to convert the data, because implemented heuristic approach is not
	MT-safe, its sole goal is to facilitate the data upgrade with this
	utility.

	=head1 EXAMPLES

	Parse a PKCS#12 file and output it to a file:

	openssl pkcs12 -in file.p12 -out file.pem

	Output only client certificates to a file:

	openssl pkcs12 -in file.p12 -clcerts -out file.pem

	Don't encrypt the private key:

	openssl pkcs12 -in file.p12 -out file.pem -nodes

	Print some info about a PKCS#12 file:

	openssl pkcs12 -in file.p12 -info -noout

	Create a PKCS#12 file:

	openssl pkcs12 -export -in file.pem -out file.p12 -name "My Certificate"

	Include some extra certificates:

	openssl pkcs12 -export -in file.pem -out file.p12 -name "My Certificate" \
	-certfile othercerts.pem

	=head1 SEE ALSO

	L<pkcs8(1)>

	=head1 COPYRIGHT

	Copyright 2000-2017 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