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c5a3b7e790
Add an ASN1 FAQ because I'm sick of answering it :-)
1195 lines
43 KiB
Plaintext
1195 lines
43 KiB
Plaintext
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This is some preliminary documentation for OpenSSL.
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Contents:
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OpenSSL X509V3 extension configuration
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X509V3 Extension code: programmers guide
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PKCS#12 Library
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==============================================================================
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OpenSSL X509V3 extension configuration
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==============================================================================
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OpenSSL X509V3 extension configuration: preliminary documentation.
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INTRODUCTION.
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For OpenSSL 0.9.2 the extension code has be considerably enhanced. It is now
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possible to add and print out common X509 V3 certificate and CRL extensions.
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BEGINNERS NOTE
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For most simple applications you don't need to know too much about extensions:
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the default openssl.cnf values will usually do sensible things.
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If you want to know more you can initially quickly look through the sections
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describing how the standard OpenSSL utilities display and add extensions and
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then the list of supported extensions.
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For more technical information about the meaning of extensions see:
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http://www.imc.org/ietf-pkix/
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http://home.netscape.com/eng/security/certs.html
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PRINTING EXTENSIONS.
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Extension values are automatically printed out for supported extensions.
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openssl x509 -in cert.pem -text
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openssl crl -in crl.pem -text
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will give information in the extension printout, for example:
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X509v3 extensions:
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X509v3 Basic Constraints:
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CA:TRUE
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X509v3 Subject Key Identifier:
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73:FE:F7:59:A7:E1:26:84:44:D6:44:36:EE:79:1A:95:7C:B1:4B:15
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X509v3 Authority Key Identifier:
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keyid:73:FE:F7:59:A7:E1:26:84:44:D6:44:36:EE:79:1A:95:7C:B1:4B:15, DirName:/C=AU/ST=Some-State/O=Internet Widgits Pty Ltd/Email=email@1.address/Email=email@2.address, serial:00
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X509v3 Key Usage:
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Certificate Sign, CRL Sign
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X509v3 Subject Alternative Name:
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email:email@1.address, email:email@2.address
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CONFIGURATION FILES.
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The OpenSSL utilities 'ca' and 'req' can now have extension sections listing
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which certificate extensions to include. In each case a line:
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x509_extensions = extension_section
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indicates which section contains the extensions. In the case of 'req' the
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extension section is used when the -x509 option is present to create a
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self signed root certificate.
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The 'x509' utility also supports extensions when it signs a certificate.
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The -extfile option is used to set the configuration file containing the
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extensions. In this case a line with:
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extensions = extension_section
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in the nameless (default) section is used. If no such line is included then
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it uses the default section.
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You can also add extensions to CRLs: a line
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crl_extensions = crl_extension_section
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will include extensions when the -gencrl option is used with the 'ca' utility.
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You can add any extension to a CRL but of the supported extensions only
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issuerAltName and authorityKeyIdentifier make any real sense. Note: these are
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CRL extensions NOT CRL *entry* extensions which cannot currently be generated.
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CRL entry extensions can be displayed.
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NB. At this time Netscape Communicator rejects V2 CRLs: to get an old V1 CRL
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you should not include a crl_extensions line in the configuration file.
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As with all configuration files you can use the inbuilt environment expansion
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to allow the values to be passed in the environment. Therefore if you have
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several extension sections used for different purposes you can have a line:
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x509_extensions = $ENV::ENV_EXT
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and set the ENV_EXT environment variable before calling the relevant utility.
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EXTENSION SYNTAX.
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Extensions have the basic form:
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extension_name=[critical,] extension_options
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the use of the critical option makes the extension critical. Extreme caution
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should be made when using the critical flag. If an extension is marked
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as critical then any client that does not understand the extension should
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reject it as invalid. Some broken software will reject certificates which
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have *any* critical extensions (these violates PKIX but we have to live
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with it).
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There are three main types of extension: string extensions, multi-valued
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extensions, and raw extensions.
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String extensions simply have a string which contains either the value itself
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or how it is obtained.
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For example:
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nsComment="This is a Comment"
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Multi-valued extensions have a short form and a long form. The short form
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is a list of names and values:
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basicConstraints=critical,CA:true,pathlen:1
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The long form allows the values to be placed in a separate section:
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basicConstraints=critical,@bs_section
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[bs_section]
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CA=true
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pathlen=1
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Both forms are equivalent. However it should be noted that in some cases the
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same name can appear multiple times, for example,
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subjectAltName=email:steve@here,email:steve@there
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in this case an equivalent long form is:
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subjectAltName=@alt_section
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[alt_section]
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email.1=steve@here
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email.2=steve@there
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This is because the configuration file code cannot handle the same name
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occurring twice in the same section.
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The syntax of raw extensions is governed by the extension code: it can
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for example contain data in multiple sections. The correct syntax to
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use is defined by the extension code itself: check out the certificate
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policies extension for an example.
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In addition it is also possible to use the word DER to include arbitrary
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data in any extension.
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1.2.3.4=critical,DER:01:02:03:04
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1.2.3.4=DER:01020304
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The value following DER is a hex dump of the DER encoding of the extension
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Any extension can be placed in this form to override the default behaviour.
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For example:
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basicConstraints=critical,DER:00:01:02:03
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WARNING: DER should be used with caution. It is possible to create totally
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invalid extensions unless care is taken.
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CURRENTLY SUPPORTED EXTENSIONS.
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If you aren't sure about extensions then they can be largely ignored: its only
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when you want to do things like restrict certificate usage when you need to
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worry about them.
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The only extension that a beginner might want to look at is Basic Constraints.
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If in addition you want to try Netscape object signing the you should also
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look at Netscape Certificate Type.
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Literal String extensions.
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In each case the 'value' of the extension is placed directly in the
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extension. Currently supported extensions in this category are: nsBaseUrl,
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nsRevocationUrl, nsCaRevocationUrl, nsRenewalUrl, nsCaPolicyUrl,
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nsSslServerName and nsComment.
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For example:
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nsComment="This is a test comment"
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Bit Strings.
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Bit string extensions just consist of a list of supported bits, currently
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two extensions are in this category: PKIX keyUsage and the Netscape specific
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nsCertType.
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nsCertType (netscape certificate type) takes the flags: client, server, email,
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objsign, reserved, sslCA, emailCA, objCA.
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keyUsage (PKIX key usage) takes the flags: digitalSignature, nonRepudiation,
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keyEncipherment, dataEncipherment, keyAgreement, keyCertSign, cRLSign,
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encipherOnly, decipherOnly.
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For example:
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nsCertType=server
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keyUsage=digitalSignature, nonRepudiation
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Hints on Netscape Certificate Type.
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Other than Basic Constraints this is the only extension a beginner might
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want to use, if you want to try Netscape object signing, otherwise it can
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be ignored.
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If you want a certificate that can be used just for object signing then:
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nsCertType=objsign
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will do the job. If you want to use it as a normal end user and server
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certificate as well then
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nsCertType=objsign,email,server
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is more appropriate. You cannot use a self signed certificate for object
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signing (well Netscape signtool can but it cheats!) so you need to create
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a CA certificate and sign an end user certificate with it.
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Side note: If you want to conform to the Netscape specifications then you
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should really also set:
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nsCertType=objCA
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in the *CA* certificate for just an object signing CA and
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nsCertType=objCA,emailCA,sslCA
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for everything. Current Netscape software doesn't enforce this so it can
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be omitted.
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Basic Constraints.
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This is generally the only extension you need to worry about for simple
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applications. If you want your certificate to be usable as a CA certificate
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(in addition to an end user certificate) then you set this to:
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basicConstraints=CA:TRUE
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if you want to be certain the certificate cannot be used as a CA then do:
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basicConstraints=CA:FALSE
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The rest of this section describes more advanced usage.
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Basic constraints is a multi-valued extension that supports a CA and an
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optional pathlen option. The CA option takes the values true and false and
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pathlen takes an integer. Note if the CA option is false the pathlen option
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should be omitted.
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The pathlen parameter indicates the maximum number of CAs that can appear
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below this one in a chain. So if you have a CA with a pathlen of zero it can
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only be used to sign end user certificates and not further CAs. This all
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assumes that the software correctly interprets this extension of course.
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Examples:
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basicConstraints=CA:TRUE
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basicConstraints=critical,CA:TRUE, pathlen:0
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NOTE: for a CA to be considered valid it must have the CA option set to
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TRUE. An end user certificate MUST NOT have the CA value set to true.
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According to PKIX recommendations it should exclude the extension entirely,
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however some software may require CA set to FALSE for end entity certificates.
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Extended Key Usage.
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This extensions consists of a list of usages.
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These can either be object short names of the dotted numerical form of OIDs.
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While any OID can be used only certain values make sense. In particular the
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following PKIX, NS and MS values are meaningful:
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Value Meaning
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----- -------
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serverAuth SSL/TLS Web Server Authentication.
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clientAuth SSL/TLS Web Client Authentication.
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codeSigning Code signing.
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emailProtection E-mail Protection (S/MIME).
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timeStamping Trusted Timestamping
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msCodeInd Microsoft Individual Code Signing (authenticode)
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msCodeCom Microsoft Commercial Code Signing (authenticode)
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msCTLSign Microsoft Trust List Signing
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msSGC Microsoft Server Gated Crypto
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msEFS Microsoft Encrypted File System
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nsSGC Netscape Server Gated Crypto
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For example, under IE5 a CA can be used for any purpose: by including a list
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of the above usages the CA can be restricted to only authorised uses.
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Note: software packages may place additional interpretations on certificate
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use, in particular some usages may only work for selected CAs. Don't for example
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expect just including msSGC or nsSGC will automatically mean that a certificate
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can be used for SGC ("step up" encryption) otherwise anyone could use it.
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Examples:
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extendedKeyUsage=critical,codeSigning,1.2.3.4
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extendedKeyUsage=nsSGC,msSGC
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Subject Key Identifier.
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This is really a string extension and can take two possible values. Either
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a hex string giving details of the extension value to include or the word
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'hash' which then automatically follow PKIX guidelines in selecting and
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appropriate key identifier. The use of the hex string is strongly discouraged.
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Example: subjectKeyIdentifier=hash
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Authority Key Identifier.
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The authority key identifier extension permits two options. keyid and issuer:
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both can take the optional value "always".
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If the keyid option is present an attempt is made to copy the subject key
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identifier from the parent certificate. If the value "always" is present
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then an error is returned if the option fails.
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The issuer option copies the issuer and serial number from the issuer
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certificate. Normally this will only be done if the keyid option fails or
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is not included: the "always" flag will always include the value.
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Subject Alternative Name.
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The subject alternative name extension allows various literal values to be
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included in the configuration file. These include "email" (an email address)
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"URI" a uniform resource indicator, "DNS" (a DNS domain name), RID (a
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registered ID: OBJECT IDENTIFIER) and IP (and IP address).
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Also the email option include a special 'copy' value. This will automatically
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include and email addresses contained in the certificate subject name in
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the extension.
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Examples:
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subjectAltName=email:copy,email:my@other.address,URL:http://my.url.here/
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subjectAltName=email:my@other.address,RID:1.2.3.4
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Issuer Alternative Name.
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The issuer alternative name option supports all the literal options of
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subject alternative name. It does *not* support the email:copy option because
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that would not make sense. It does support an additional issuer:copy option
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that will copy all the subject alternative name values from the issuer
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certificate (if possible).
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Example:
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issuserAltName = issuer:copy
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Authority Info Access.
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The authority information access extension gives details about how to access
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certain information relating to the CA. Its syntax is accessOID;location
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where 'location' has the same syntax as subject alternative name (except
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that email:copy is not supported). accessOID can be any valid OID but only
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certain values are meaningful for example OCSP and caIssuers. OCSP gives the
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location of an OCSP responder: this is used by Netscape PSM and other software.
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Example:
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authorityInfoAccess = OCSP;URI:http://ocsp.my.host/
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authorityInfoAccess = caIssuers;URI:http://my.ca/ca.html
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CRL distribution points.
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This is a multi-valued extension that supports all the literal options of
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subject alternative name. Of the few software packages that currently interpret
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this extension most only interpret the URI option.
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Currently each option will set a new DistributionPoint with the fullName
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field set to the given value.
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Other fields like cRLissuer and reasons cannot currently be set or displayed:
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at this time no examples were available that used these fields.
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If you see this extension with <UNSUPPORTED> when you attempt to print it out
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or it doesn't appear to display correctly then let me know, including the
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certificate (mail me at steve@openssl.org) .
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Examples:
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crlDistributionPoints=URI:http://www.myhost.com/myca.crl
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crlDistributionPoints=URI:http://www.my.com/my.crl,URI:http://www.oth.com/my.crl
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Certificate Policies.
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This is a RAW extension. It attempts to display the contents of this extension:
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unfortunately this extension is often improperly encoded.
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The certificate policies extension will rarely be used in practice: few
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software packages interpret it correctly or at all. IE5 does partially
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support this extension: but it needs the 'ia5org' option because it will
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only correctly support a broken encoding. Of the options below only the
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policy OID, explicitText and CPS options are displayed with IE5.
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All the fields of this extension can be set by using the appropriate syntax.
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If you follow the PKIX recommendations of not including any qualifiers and just
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using only one OID then you just include the value of that OID. Multiple OIDs
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can be set separated by commas, for example:
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certificatePolicies= 1.2.4.5, 1.1.3.4
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If you wish to include qualifiers then the policy OID and qualifiers need to
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be specified in a separate section: this is done by using the @section syntax
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instead of a literal OID value.
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The section referred to must include the policy OID using the name
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policyIdentifier, cPSuri qualifiers can be included using the syntax:
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CPS.nnn=value
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userNotice qualifiers can be set using the syntax:
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userNotice.nnn=@notice
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The value of the userNotice qualifier is specified in the relevant section.
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This section can include explicitText, organization and noticeNumbers
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options. explicitText and organization are text strings, noticeNumbers is a
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comma separated list of numbers. The organization and noticeNumbers options
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(if included) must BOTH be present. If you use the userNotice option with IE5
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then you need the 'ia5org' option at the top level to modify the encoding:
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otherwise it will not be interpreted properly.
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Example:
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certificatePolicies=ia5org,1.2.3.4,1.5.6.7.8,@polsect
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[polsect]
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policyIdentifier = 1.3.5.8
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CPS.1="http://my.host.name/"
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CPS.2="http://my.your.name/"
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userNotice.1=@notice
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[notice]
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explicitText="Explicit Text Here"
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organization="Organisation Name"
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noticeNumbers=1,2,3,4
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TECHNICAL NOTE: the ia5org option changes the type of the 'organization' field,
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according to PKIX it should be of type DisplayText but Verisign uses an
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IA5STRING and IE5 needs this too.
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Display only extensions.
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Some extensions are only partially supported and currently are only displayed
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but cannot be set. These include private key usage period, CRL number, and
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CRL reason.
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==============================================================================
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X509V3 Extension code: programmers guide
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==============================================================================
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The purpose of the extension code is twofold. It allows an extension to be
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created from a string or structure describing its contents and it prints out an
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extension in a human or machine readable form.
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1. Initialisation and cleanup.
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No special initialisation is needed before calling the extension functions.
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You used to have to call X509V3_add_standard_extensions(); but this is no longer
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required and this function no longer does anything.
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void X509V3_EXT_cleanup(void);
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This function should be called to cleanup the extension code if any custom
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extensions have been added. If no custom extensions have been added then this
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call does nothing. After this call all custom extension code is freed up but
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you can still use the standard extensions.
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2. Printing and parsing extensions.
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The simplest way to print out extensions is via the standard X509 printing
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routines: if you use the standard X509_print() function, the supported
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extensions will be printed out automatically.
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The following functions allow finer control over extension display:
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int X509V3_EXT_print(BIO *out, X509_EXTENSION *ext, int flag, int indent);
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int X509V3_EXT_print_fp(FILE *out, X509_EXTENSION *ext, int flag, int indent);
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These two functions print out an individual extension to a BIO or FILE pointer.
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Currently the flag argument is unused and should be set to 0. The 'indent'
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argument is the number of spaces to indent each line.
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void *X509V3_EXT_d2i(X509_EXTENSION *ext);
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This function parses an extension and returns its internal structure. The
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precise structure you get back depends on the extension being parsed. If the
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extension if basicConstraints you will get back a pointer to a
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BASIC_CONSTRAINTS structure. Check out the source in crypto/x509v3 for more
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details about the structures returned. The returned structure should be freed
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after use using the relevant free function, BASIC_CONSTRAINTS_free() for
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example.
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3. Generating extensions.
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An extension will typically be generated from a configuration file, or some
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other kind of configuration database.
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int X509V3_EXT_add_conf(LHASH *conf, X509V3_CTX *ctx, char *section,
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X509 *cert);
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int X509V3_EXT_CRL_add_conf(LHASH *conf, X509V3_CTX *ctx, char *section,
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X509_CRL *crl);
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These functions add all the extensions in the given section to the given
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|
certificate or CRL. They will normally be called just before the certificate
|
|
or CRL is due to be signed. Both return 0 on error on non zero for success.
|
|
|
|
In each case 'conf' is the LHASH pointer of the configuration file to use
|
|
and 'section' is the section containing the extension details.
|
|
|
|
See the 'context functions' section for a description of the ctx parameter.
|
|
|
|
|
|
X509_EXTENSION *X509V3_EXT_conf(LHASH *conf, X509V3_CTX *ctx, char *name,
|
|
char *value);
|
|
|
|
This function returns an extension based on a name and value pair, if the
|
|
pair will not need to access other sections in a config file (or there is no
|
|
config file) then the 'conf' parameter can be set to NULL.
|
|
|
|
X509_EXTENSION *X509V3_EXT_conf_nid(char *conf, X509V3_CTX *ctx, int nid,
|
|
char *value);
|
|
|
|
This function creates an extension in the same way as X509V3_EXT_conf() but
|
|
takes the NID of the extension rather than its name.
|
|
|
|
For example to produce basicConstraints with the CA flag and a path length of
|
|
10:
|
|
|
|
x = X509V3_EXT_conf_nid(NULL, NULL, NID_basic_constraints,"CA:TRUE,pathlen:10");
|
|
|
|
|
|
X509_EXTENSION *X509V3_EXT_i2d(int ext_nid, int crit, void *ext_struc);
|
|
|
|
This function sets up an extension from its internal structure. The ext_nid
|
|
parameter is the NID of the extension and 'crit' is the critical flag.
|
|
|
|
4. Context functions.
|
|
|
|
The following functions set and manipulate an extension context structure.
|
|
The purpose of the extension context is to allow the extension code to
|
|
access various structures relating to the "environment" of the certificate:
|
|
for example the issuers certificate or the certificate request.
|
|
|
|
void X509V3_set_ctx(X509V3_CTX *ctx, X509 *issuer, X509 *subject,
|
|
X509_REQ *req, X509_CRL *crl, int flags);
|
|
|
|
This function sets up an X509V3_CTX structure with details of the certificate
|
|
environment: specifically the issuers certificate, the subject certificate,
|
|
the certificate request and the CRL: if these are not relevant or not
|
|
available then they can be set to NULL. The 'flags' parameter should be set
|
|
to zero.
|
|
|
|
X509V3_set_ctx_test(ctx)
|
|
|
|
This macro is used to set the 'ctx' structure to a 'test' value: this is to
|
|
allow the syntax of an extension (or configuration file) to be tested.
|
|
|
|
X509V3_set_ctx_nodb(ctx)
|
|
|
|
This macro is used when no configuration database is present.
|
|
|
|
void X509V3_set_conf_lhash(X509V3_CTX *ctx, LHASH *lhash);
|
|
|
|
This function is used to set the configuration database when it is an LHASH
|
|
structure: typically a configuration file.
|
|
|
|
The following functions are used to access a configuration database: they
|
|
should only be used in RAW extensions.
|
|
|
|
char * X509V3_get_string(X509V3_CTX *ctx, char *name, char *section);
|
|
|
|
This function returns the value of the parameter "name" in "section", or NULL
|
|
if there has been an error.
|
|
|
|
void X509V3_string_free(X509V3_CTX *ctx, char *str);
|
|
|
|
This function frees up the string returned by the above function.
|
|
|
|
STACK_OF(CONF_VALUE) * X509V3_get_section(X509V3_CTX *ctx, char *section);
|
|
|
|
This function returns a whole section as a STACK_OF(CONF_VALUE) .
|
|
|
|
void X509V3_section_free( X509V3_CTX *ctx, STACK_OF(CONF_VALUE) *section);
|
|
|
|
This function frees up the STACK returned by the above function.
|
|
|
|
Note: it is possible to use the extension code with a custom configuration
|
|
database. To do this the "db_meth" element of the X509V3_CTX structure should
|
|
be set to an X509V3_CTX_METHOD structure. This structure contains the following
|
|
function pointers:
|
|
|
|
char * (*get_string)(void *db, char *section, char *value);
|
|
STACK_OF(CONF_VALUE) * (*get_section)(void *db, char *section);
|
|
void (*free_string)(void *db, char * string);
|
|
void (*free_section)(void *db, STACK_OF(CONF_VALUE) *section);
|
|
|
|
these will be called and passed the 'db' element in the X509V3_CTX structure
|
|
to access the database. If a given function is not implemented or not required
|
|
it can be set to NULL.
|
|
|
|
5. String helper functions.
|
|
|
|
There are several "i2s" and "s2i" functions that convert structures to and
|
|
from ASCII strings. In all the "i2s" cases the returned string should be
|
|
freed using Free() after use. Since some of these are part of other extension
|
|
code they may take a 'method' parameter. Unless otherwise stated it can be
|
|
safely set to NULL.
|
|
|
|
char *i2s_ASN1_OCTET_STRING(X509V3_EXT_METHOD *method, ASN1_OCTET_STRING *oct);
|
|
|
|
This returns a hex string from an ASN1_OCTET_STRING.
|
|
|
|
char * i2s_ASN1_INTEGER(X509V3_EXT_METHOD *meth, ASN1_INTEGER *aint);
|
|
char * i2s_ASN1_ENUMERATED(X509V3_EXT_METHOD *meth, ASN1_ENUMERATED *aint);
|
|
|
|
These return a string decimal representations of an ASN1_INTEGER and an
|
|
ASN1_ENUMERATED type, respectively.
|
|
|
|
ASN1_OCTET_STRING *s2i_ASN1_OCTET_STRING(X509V3_EXT_METHOD *method,
|
|
X509V3_CTX *ctx, char *str);
|
|
|
|
This converts an ASCII hex string to an ASN1_OCTET_STRING.
|
|
|
|
ASN1_INTEGER * s2i_ASN1_INTEGER(X509V3_EXT_METHOD *meth, char *value);
|
|
|
|
This converts a decimal ASCII string into an ASN1_INTEGER.
|
|
|
|
6. Multi valued extension helper functions.
|
|
|
|
The following functions can be used to manipulate STACKs of CONF_VALUE
|
|
structures, as used by multi valued extensions.
|
|
|
|
int X509V3_get_value_bool(CONF_VALUE *value, int *asn1_bool);
|
|
|
|
This function expects a boolean value in 'value' and sets 'asn1_bool' to
|
|
it. That is it sets it to 0 for FALSE or 0xff for TRUE. The following
|
|
strings are acceptable: "TRUE", "true", "Y", "y", "YES", "yes", "FALSE"
|
|
"false", "N", "n", "NO" or "no".
|
|
|
|
int X509V3_get_value_int(CONF_VALUE *value, ASN1_INTEGER **aint);
|
|
|
|
This accepts a decimal integer of arbitrary length and sets an ASN1_INTEGER.
|
|
|
|
int X509V3_add_value(const char *name, const char *value,
|
|
STACK_OF(CONF_VALUE) **extlist);
|
|
|
|
This simply adds a string name and value pair.
|
|
|
|
int X509V3_add_value_uchar(const char *name, const unsigned char *value,
|
|
STACK_OF(CONF_VALUE) **extlist);
|
|
|
|
The same as above but for an unsigned character value.
|
|
|
|
int X509V3_add_value_bool(const char *name, int asn1_bool,
|
|
STACK_OF(CONF_VALUE) **extlist);
|
|
|
|
This adds either "TRUE" or "FALSE" depending on the value of 'asn1_bool'
|
|
|
|
int X509V3_add_value_bool_nf(char *name, int asn1_bool,
|
|
STACK_OF(CONF_VALUE) **extlist);
|
|
|
|
This is the same as above except it adds nothing if asn1_bool is FALSE.
|
|
|
|
int X509V3_add_value_int(const char *name, ASN1_INTEGER *aint,
|
|
STACK_OF(CONF_VALUE) **extlist);
|
|
|
|
This function adds the value of the ASN1_INTEGER in decimal form.
|
|
|
|
7. Other helper functions.
|
|
|
|
<to be added>
|
|
|
|
ADDING CUSTOM EXTENSIONS.
|
|
|
|
Currently there are three types of supported extensions.
|
|
|
|
String extensions are simple strings where the value is placed directly in the
|
|
extensions, and the string returned is printed out.
|
|
|
|
Multi value extensions are passed a STACK_OF(CONF_VALUE) name and value pairs
|
|
or return a STACK_OF(CONF_VALUE).
|
|
|
|
Raw extensions are just passed a BIO or a value and it is the extensions
|
|
responsibility to handle all the necessary printing.
|
|
|
|
There are two ways to add an extension. One is simply as an alias to an already
|
|
existing extension. An alias is an extension that is identical in ASN1 structure
|
|
to an existing extension but has a different OBJECT IDENTIFIER. This can be
|
|
done by calling:
|
|
|
|
int X509V3_EXT_add_alias(int nid_to, int nid_from);
|
|
|
|
'nid_to' is the new extension NID and 'nid_from' is the already existing
|
|
extension NID.
|
|
|
|
Alternatively an extension can be written from scratch. This involves writing
|
|
the ASN1 code to encode and decode the extension and functions to print out and
|
|
generate the extension from strings. The relevant functions are then placed in
|
|
a X509V3_EXT_METHOD structure and int X509V3_EXT_add(X509V3_EXT_METHOD *ext);
|
|
called.
|
|
|
|
The X509V3_EXT_METHOD structure is described below.
|
|
|
|
strut {
|
|
int ext_nid;
|
|
int ext_flags;
|
|
X509V3_EXT_NEW ext_new;
|
|
X509V3_EXT_FREE ext_free;
|
|
X509V3_EXT_D2I d2i;
|
|
X509V3_EXT_I2D i2d;
|
|
X509V3_EXT_I2S i2s;
|
|
X509V3_EXT_S2I s2i;
|
|
X509V3_EXT_I2V i2v;
|
|
X509V3_EXT_V2I v2i;
|
|
X509V3_EXT_R2I r2i;
|
|
X509V3_EXT_I2R i2r;
|
|
|
|
void *usr_data;
|
|
};
|
|
|
|
The elements have the following meanings.
|
|
|
|
ext_nid is the NID of the object identifier of the extension.
|
|
|
|
ext_flags is set of flags. Currently the only external flag is
|
|
X509V3_EXT_MULTILINE which means a multi valued extensions
|
|
should be printed on separate lines.
|
|
|
|
usr_data is an extension specific pointer to any relevant data. This
|
|
allows extensions to share identical code but have different
|
|
uses. An example of this is the bit string extension which uses
|
|
usr_data to contain a list of the bit names.
|
|
|
|
All the remaining elements are function pointers.
|
|
|
|
ext_new is a pointer to a function that allocates memory for the
|
|
extension ASN1 structure: for example ASN1_OBJECT_new().
|
|
|
|
ext_free is a pointer to a function that free up memory of the extension
|
|
ASN1 structure: for example ASN1_OBJECT_free().
|
|
|
|
d2i is the standard ASN1 function that converts a DER buffer into
|
|
the internal ASN1 structure: for example d2i_ASN1_IA5STRING().
|
|
|
|
i2d is the standard ASN1 function that converts the internal
|
|
structure into the DER representation: for example
|
|
i2d_ASN1_IA5STRING().
|
|
|
|
The remaining functions are depend on the type of extension. One i2X and
|
|
one X2i should be set and the rest set to NULL. The types set do not need
|
|
to match up, for example the extension could be set using the multi valued
|
|
v2i function and printed out using the raw i2r.
|
|
|
|
All functions have the X509V3_EXT_METHOD passed to them in the 'method'
|
|
parameter and an X509V3_CTX structure. Extension code can then access the
|
|
parent structure via the 'method' parameter to for example make use of the value
|
|
of usr_data. If the code needs to use detail relating to the request it can
|
|
use the 'ctx' parameter.
|
|
|
|
A note should be given here about the 'flags' member of the 'ctx' parameter.
|
|
If it has the value CTX_TEST then the configuration syntax is being checked
|
|
and no actual certificate or CRL exists. Therefore any attempt in the config
|
|
file to access such information should silently succeed. If the syntax is OK
|
|
then it should simply return a (possibly bogus) extension, otherwise it
|
|
should return NULL.
|
|
|
|
char *i2s(struct v3_ext_method *method, void *ext);
|
|
|
|
This function takes the internal structure in the ext parameter and returns
|
|
a Malloc'ed string representing its value.
|
|
|
|
void * s2i(struct v3_ext_method *method, struct v3_ext_ctx *ctx, char *str);
|
|
|
|
This function takes the string representation in the ext parameter and returns
|
|
an allocated internal structure: ext_free() will be used on this internal
|
|
structure after use.
|
|
|
|
i2v and v2i handle a STACK_OF(CONF_VALUE):
|
|
|
|
typedef struct
|
|
{
|
|
char *section;
|
|
char *name;
|
|
char *value;
|
|
} CONF_VALUE;
|
|
|
|
Only the name and value members are currently used.
|
|
|
|
STACK_OF(CONF_VALUE) * i2v(struct v3_ext_method *method, void *ext);
|
|
|
|
This function is passed the internal structure in the ext parameter and
|
|
returns a STACK of CONF_VALUE structures. The values of name, value,
|
|
section and the structure itself will be freed up with Free after use.
|
|
Several helper functions are available to add values to this STACK.
|
|
|
|
void * v2i(struct v3_ext_method *method, struct v3_ext_ctx *ctx,
|
|
STACK_OF(CONF_VALUE) *values);
|
|
|
|
This function takes a STACK_OF(CONF_VALUE) structures and should set the
|
|
values of the external structure. This typically uses the name element to
|
|
determine which structure element to set and the value element to determine
|
|
what to set it to. Several helper functions are available for this
|
|
purpose (see above).
|
|
|
|
int i2r(struct v3_ext_method *method, void *ext, BIO *out, int indent);
|
|
|
|
This function is passed the internal extension structure in the ext parameter
|
|
and sends out a human readable version of the extension to out. The 'indent'
|
|
parameter should be noted to determine the necessary amount of indentation
|
|
needed on the output.
|
|
|
|
void * r2i(struct v3_ext_method *method, struct v3_ext_ctx *ctx, char *str);
|
|
|
|
This is just passed the string representation of the extension. It is intended
|
|
to be used for more elaborate extensions where the standard single and multi
|
|
valued options are insufficient. They can use the 'ctx' parameter to parse the
|
|
configuration database themselves. See the context functions section for details
|
|
of how to do this.
|
|
|
|
Note: although this type takes the same parameters as the "r2s" function there
|
|
is a subtle difference. Whereas an "r2i" function can access a configuration
|
|
database an "s2i" function MUST NOT. This is so the internal code can safely
|
|
assume that an "s2i" function will work without a configuration database.
|
|
|
|
==============================================================================
|
|
PKCS#12 Library
|
|
==============================================================================
|
|
|
|
This section describes the internal PKCS#12 support. There are very few
|
|
differences between the old external library and the new internal code at
|
|
present. This may well change because the external library will not be updated
|
|
much in future.
|
|
|
|
This version now includes a couple of high level PKCS#12 functions which
|
|
generally "do the right thing" and should make it much easier to handle PKCS#12
|
|
structures.
|
|
|
|
HIGH LEVEL FUNCTIONS.
|
|
|
|
For most applications you only need concern yourself with the high level
|
|
functions. They can parse and generate simple PKCS#12 files as produced by
|
|
Netscape and MSIE or indeed any compliant PKCS#12 file containing a single
|
|
private key and certificate pair.
|
|
|
|
1. Initialisation and cleanup.
|
|
|
|
No special initialisation is needed for the internal PKCS#12 library: the
|
|
standard SSLeay_add_all_algorithms() is sufficient. If you do not wish to
|
|
add all algorithms (you should at least add SHA1 though) then you can manually
|
|
initialise the PKCS#12 library with:
|
|
|
|
PKCS12_PBE_add();
|
|
|
|
The memory allocated by the PKCS#12 library is freed up when EVP_cleanup() is
|
|
called or it can be directly freed with:
|
|
|
|
EVP_PBE_cleanup();
|
|
|
|
after this call (or EVP_cleanup() ) no more PKCS#12 library functions should
|
|
be called.
|
|
|
|
2. I/O functions.
|
|
|
|
i2d_PKCS12_bio(bp, p12)
|
|
|
|
This writes out a PKCS12 structure to a BIO.
|
|
|
|
i2d_PKCS12_fp(fp, p12)
|
|
|
|
This is the same but for a FILE pointer.
|
|
|
|
d2i_PKCS12_bio(bp, p12)
|
|
|
|
This reads in a PKCS12 structure from a BIO.
|
|
|
|
d2i_PKCS12_fp(fp, p12)
|
|
|
|
This is the same but for a FILE pointer.
|
|
|
|
3. High level functions.
|
|
|
|
3.1 Parsing with PKCS12_parse().
|
|
|
|
int PKCS12_parse(PKCS12 *p12, char *pass, EVP_PKEY **pkey, X509 **cert,
|
|
STACK **ca);
|
|
|
|
This function takes a PKCS12 structure and a password (ASCII, null terminated)
|
|
and returns the private key, the corresponding certificate and any CA
|
|
certificates. If any of these is not required it can be passed as a NULL.
|
|
The 'ca' parameter should be either NULL, a pointer to NULL or a valid STACK
|
|
structure. Typically to read in a PKCS#12 file you might do:
|
|
|
|
p12 = d2i_PKCS12_fp(fp, NULL);
|
|
PKCS12_parse(p12, password, &pkey, &cert, NULL); /* CAs not wanted */
|
|
PKCS12_free(p12);
|
|
|
|
3.2 PKCS#12 creation with PKCS12_create().
|
|
|
|
PKCS12 *PKCS12_create(char *pass, char *name, EVP_PKEY *pkey, X509 *cert,
|
|
STACK *ca, int nid_key, int nid_cert, int iter,
|
|
int mac_iter, int keytype);
|
|
|
|
This function will create a PKCS12 structure from a given password, name,
|
|
private key, certificate and optional STACK of CA certificates. The remaining
|
|
5 parameters can be set to 0 and sensible defaults will be used.
|
|
|
|
The parameters nid_key and nid_cert are the key and certificate encryption
|
|
algorithms, iter is the encryption iteration count, mac_iter is the MAC
|
|
iteration count and keytype is the type of private key. If you really want
|
|
to know what these last 5 parameters do then read the low level section.
|
|
|
|
Typically to create a PKCS#12 file the following could be used:
|
|
|
|
p12 = PKCS12_create(pass, "My Certificate", pkey, cert, NULL, 0,0,0,0,0);
|
|
i2d_PKCS12_fp(fp, p12);
|
|
PKCS12_free(p12);
|
|
|
|
3.3 Changing a PKCS#12 structure password.
|
|
|
|
int PKCS12_newpass(PKCS12 *p12, char *oldpass, char *newpass);
|
|
|
|
This changes the password of an already existing PKCS#12 structure. oldpass
|
|
is the old password and newpass is the new one. An error occurs if the old
|
|
password is incorrect.
|
|
|
|
LOW LEVEL FUNCTIONS.
|
|
|
|
In some cases the high level functions do not provide the necessary
|
|
functionality. For example if you want to generate or parse more complex
|
|
PKCS#12 files. The sample pkcs12 application uses the low level functions
|
|
to display details about the internal structure of a PKCS#12 file.
|
|
|
|
Introduction.
|
|
|
|
This is a brief description of how a PKCS#12 file is represented internally:
|
|
some knowledge of PKCS#12 is assumed.
|
|
|
|
A PKCS#12 object contains several levels.
|
|
|
|
At the lowest level is a PKCS12_SAFEBAG. This can contain a certificate, a
|
|
CRL, a private key, encrypted or unencrypted, a set of safebags (so the
|
|
structure can be nested) or other secrets (not documented at present).
|
|
A safebag can optionally have attributes, currently these are: a unicode
|
|
friendlyName (a Unicode string) or a localKeyID (a string of bytes).
|
|
|
|
At the next level is an authSafe which is a set of safebags collected into
|
|
a PKCS#7 ContentInfo. This can be just plain data, or encrypted itself.
|
|
|
|
At the top level is the PKCS12 structure itself which contains a set of
|
|
authSafes in an embedded PKCS#7 Contentinfo of type data. In addition it
|
|
contains a MAC which is a kind of password protected digest to preserve
|
|
integrity (so any unencrypted stuff below can't be tampered with).
|
|
|
|
The reason for these levels is so various objects can be encrypted in various
|
|
ways. For example you might want to encrypt a set of private keys with
|
|
triple-DES and then include the related certificates either unencrypted or
|
|
with lower encryption. Yes it's the dreaded crypto laws at work again which
|
|
allow strong encryption on private keys and only weak encryption on other
|
|
stuff.
|
|
|
|
To build one of these things you turn all certificates and keys into safebags
|
|
(with optional attributes). You collect the safebags into (one or more) STACKS
|
|
and convert these into authsafes (encrypted or unencrypted). The authsafes
|
|
are collected into a STACK and added to a PKCS12 structure. Finally a MAC
|
|
inserted.
|
|
|
|
Pulling one apart is basically the reverse process. The MAC is verified against
|
|
the given password. The authsafes are extracted and each authsafe split into
|
|
a set of safebags (possibly involving decryption). Finally the safebags are
|
|
decomposed into the original keys and certificates and the attributes used to
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match up private key and certificate pairs.
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Anyway here are the functions that do the dirty work.
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1. Construction functions.
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1.1 Safebag functions.
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M_PKCS12_x5092certbag(x509)
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This macro takes an X509 structure and returns a certificate bag. The
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X509 structure can be freed up after calling this function.
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M_PKCS12_x509crl2certbag(crl)
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As above but for a CRL.
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PKCS8_PRIV_KEY_INFO *PKEY2PKCS8(EVP_PKEY *pkey)
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Take a private key and convert it into a PKCS#8 PrivateKeyInfo structure.
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Works for both RSA and DSA private keys. NB since the PKCS#8 PrivateKeyInfo
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structure contains a private key data in plain text form it should be free'd
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up as soon as it has been encrypted for security reasons (freeing up the
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structure zeros out the sensitive data). This can be done with
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PKCS8_PRIV_KEY_INFO_free().
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PKCS8_add_keyusage(PKCS8_PRIV_KEY_INFO *p8, int usage)
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This sets the key type when a key is imported into MSIE or Outlook 98. Two
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values are currently supported: KEY_EX and KEY_SIG. KEY_EX is an exchange type
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key that can also be used for signing but its size is limited in the export
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versions of MS software to 512 bits, it is also the default. KEY_SIG is a
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signing only key but the keysize is unlimited (well 16K is supposed to work).
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If you are using the domestic version of MSIE then you can ignore this because
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KEY_EX is not limited and can be used for both.
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PKCS12_SAFEBAG *PKCS12_MAKE_KEYBAG(PKCS8_PRIV_KEY_INFO *p8)
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Convert a PKCS8 private key structure into a keybag. This routine embeds the
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p8 structure in the keybag so p8 should not be freed up or used after it is
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called. The p8 structure will be freed up when the safebag is freed.
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PKCS12_SAFEBAG *PKCS12_MAKE_SHKEYBAG(int pbe_nid, unsigned char *pass, int passlen, unsigned char *salt, int saltlen, int iter, PKCS8_PRIV_KEY_INFO *p8)
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Convert a PKCS#8 structure into a shrouded key bag (encrypted). p8 is not
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embedded and can be freed up after use.
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int PKCS12_add_localkeyid(PKCS12_SAFEBAG *bag, unsigned char *name, int namelen)
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int PKCS12_add_friendlyname(PKCS12_SAFEBAG *bag, unsigned char *name, int namelen)
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Add a local key id or a friendlyname to a safebag.
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1.2 Authsafe functions.
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PKCS7 *PKCS12_pack_p7data(STACK *sk)
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Take a stack of safebags and convert them into an unencrypted authsafe. The
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stack of safebags can be freed up after calling this function.
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PKCS7 *PKCS12_pack_p7encdata(int pbe_nid, unsigned char *pass, int passlen, unsigned char *salt, int saltlen, int iter, STACK *bags);
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As above but encrypted.
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1.3 PKCS12 functions.
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PKCS12 *PKCS12_init(int mode)
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Initialise a PKCS12 structure (currently mode should be NID_pkcs7_data).
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M_PKCS12_pack_authsafes(p12, safes)
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This macro takes a STACK of authsafes and adds them to a PKCS#12 structure.
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int PKCS12_set_mac(PKCS12 *p12, unsigned char *pass, int passlen, unsigned char *salt, int saltlen, int iter, EVP_MD *md_type);
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Add a MAC to a PKCS12 structure. If EVP_MD is NULL use SHA-1, the spec suggests
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that SHA-1 should be used.
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2. Extraction Functions.
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2.1 Safebags.
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M_PKCS12_bag_type(bag)
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Return the type of "bag". Returns one of the following
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NID_keyBag
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NID_pkcs8ShroudedKeyBag 7
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NID_certBag 8
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NID_crlBag 9
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NID_secretBag 10
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NID_safeContentsBag 11
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M_PKCS12_cert_bag_type(bag)
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Returns type of certificate bag, following are understood.
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NID_x509Certificate 14
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NID_sdsiCertificate 15
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M_PKCS12_crl_bag_type(bag)
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Returns crl bag type, currently only NID_crlBag is recognised.
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M_PKCS12_certbag2x509(bag)
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This macro extracts an X509 certificate from a certificate bag.
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M_PKCS12_certbag2x509crl(bag)
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As above but for a CRL.
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EVP_PKEY * PKCS82PKEY(PKCS8_PRIV_KEY_INFO *p8)
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Extract a private key from a PKCS8 private key info structure.
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M_PKCS12_decrypt_skey(bag, pass, passlen)
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Decrypt a shrouded key bag and return a PKCS8 private key info structure.
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Works with both RSA and DSA keys
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char *PKCS12_get_friendlyname(bag)
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Returns the friendlyName of a bag if present or NULL if none. The returned
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string is a null terminated ASCII string allocated with Malloc(). It should
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thus be freed up with Free() after use.
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2.2 AuthSafe functions.
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M_PKCS12_unpack_p7data(p7)
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Extract a STACK of safe bags from a PKCS#7 data ContentInfo.
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#define M_PKCS12_unpack_p7encdata(p7, pass, passlen)
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As above but for an encrypted content info.
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2.3 PKCS12 functions.
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M_PKCS12_unpack_authsafes(p12)
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Extract a STACK of authsafes from a PKCS12 structure.
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M_PKCS12_mac_present(p12)
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Check to see if a MAC is present.
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int PKCS12_verify_mac(PKCS12 *p12, unsigned char *pass, int passlen)
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Verify a MAC on a PKCS12 structure. Returns an error if MAC not present.
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Notes.
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1. All the function return 0 or NULL on error.
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2. Encryption based functions take a common set of parameters. These are
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described below.
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pass, passlen
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ASCII password and length. The password on the MAC is called the "integrity
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password" the encryption password is called the "privacy password" in the
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PKCS#12 documentation. The passwords do not have to be the same. If -1 is
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passed for the length it is worked out by the function itself (currently
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this is sometimes done whatever is passed as the length but that may change).
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salt, saltlen
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A 'salt' if salt is NULL a random salt is used. If saltlen is also zero a
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default length is used.
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iter
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Iteration count. This is a measure of how many times an internal function is
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called to encrypt the data. The larger this value is the longer it takes, it
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makes dictionary attacks on passwords harder. NOTE: Some implementations do
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not support an iteration count on the MAC. If the password for the MAC and
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encryption is the same then there is no point in having a high iteration
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count for encryption if the MAC has no count. The MAC could be attacked
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and the password used for the main decryption.
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pbe_nid
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This is the NID of the password based encryption method used. The following are
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supported.
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NID_pbe_WithSHA1And128BitRC4
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NID_pbe_WithSHA1And40BitRC4
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NID_pbe_WithSHA1And3_Key_TripleDES_CBC
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NID_pbe_WithSHA1And2_Key_TripleDES_CBC
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NID_pbe_WithSHA1And128BitRC2_CBC
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NID_pbe_WithSHA1And40BitRC2_CBC
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Which you use depends on the implementation you are exporting to. "Export
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|
grade" (i.e. cryptographically challenged) products cannot support all
|
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algorithms. Typically you may be able to use any encryption on shrouded key
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bags but they must then be placed in an unencrypted authsafe. Other authsafes
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may only support 40bit encryption. Of course if you are using SSLeay
|
|
throughout you can strongly encrypt everything and have high iteration counts
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on everything.
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3. For decryption routines only the password and length are needed.
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4. Unlike the external version the nid's of objects are the values of the
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constants: that is NID_certBag is the real nid, therefore there is no
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PKCS12_obj_offset() function. Note the object constants are not the same as
|
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those of the external version. If you use these constants then you will need
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to recompile your code.
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5. With the exception of PKCS12_MAKE_KEYBAG(), after calling any function or
|
|
macro of the form PKCS12_MAKE_SOMETHING(other) the "other" structure can be
|
|
reused or freed up safely.
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