| mod_ssl |
  | |
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Introduction |
Compatibility
| |
 |
| ``Try to understand everything, but believe nothing!''
|
| Unknown
|
 his chapter provides a reference to all configuration
directives and additional user visible features mod_ssl provides.
It's intended as the official resource when you want to know how a
particilar mod_ssl functionality is actually configured or
activated. Each directive is documented similar to the way standard
Apache directives are documented in the official Apache
documentation set, i.e. for each directive especially the syntax,
default and context where applicable is given.
Notice that there are three major classes of directives which are
used by mod_ssl: First Global Directives (i.e. directives
with context ``server config''), which can occur inside the server
config files but only outside of any sectioning commands like
<VirtualHost>. Second Per-Server Directives (i.e.
those with context ``server config, virtual host''), which can occur
inside the server config files both outside (for the main/default
server) and inside <VirtualHost> sections. |
|
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And third Per-Directory Directives (i.e. those with context
``server config, virtual host, directory, .htaccess''), which can pretty
much occur everywhere. Especially both inside the server config files and
the per-directory .htaccess files. The three classes are
subsets of each other, i.e. directives from the per-directory class can
also be used in the per-server and global context, and directives from the
per-server class can also be used the in the global context.
Additional directives and environment variables provided by mod_ssl
(via on-the-fly mapping) for backward compatiblity to other Apache SSL
solutions are documented in the Compatibility
chapter.
The most visible and
error-prone things of mod_ssl are its configuration directives. So we
document them in great detail here to assist you in setting up the best
possible configuration of your SSL-aware webserver.
When Apache starts up it has to read the various Certificate (see SSLCertificateFile)
and Private Key (see SSLCertificateKeyFile)
files of the SSL-enabled virtual servers. Because for security reasons the
Private Key files are usually encrypted, mod_ssl needs to query the
administrator for a Pass Phrase in order to decrypt those files. This
query can be done in two ways which can be configured by type:
builtin
This is the default where an interactive terminal dialog occurs at
startup time just before Apache detaches from the terminal. Here the
administrator has to manually enter the Pass Phrase for each encrypted
Private Key file. Because a lot of SSL-enabled virtual hosts can be
configured, the following reuse-scheme is used to minimize the dialog:
When a Private Key file is encrypted, all known Pass Phrases (at the
beginning there are none, of course) are tried. If one of those known
Pass Phrases succeeds no dialog pops up for this particular Private Key
file. If none succeeded, another Pass Phrase is queried on the terminal
and remembered for the next round (where it perhaps can be reused).
This scheme allows mod_ssl to be maximally flexible (because for N
encrypted Private Key files you can use N different Pass
Phrases - but then you have to enter all of them, of course) while
minimizing the terminal dialog (i.e. when you use a single Pass Phrase
for all N Private Key files this Pass Phrase is queried only once).
exec:/path/to/program
Here an external program is configured which is called at startup for
each encrypted Private Key file. It is called with two arguments (the
first is of the form ``servername:portnumber'', the second
is either ``RSA'' or ``DSA''), which indicate
for which server and algorithm it has to print the corresponding Pass
Phrase to stdout. The intent is that this external program
first runs security checks to make sure that the system is not
compromised by an attacker, and only when these checks were passed
successfully it provides the Pass Phrase.
Both these security checks, and the way the Pass Phrase is
determined, can be as complex as you like. Mod_ssl just defines the
interface: an executable program which provides the Pass Phrase on
stdout. Nothing more or less! So, if you're really paranoid
about security, here is your interface. Anything else has to be left as
an exercise to the administrator, because local security requirements
are so different.
The reuse-algorithm above is used here, too. In other words: The
external program is called only once per unique Pass Phrase.
Example:
SSLPassPhraseDialog exec:/usr/local/apache/sbin/pp-filter
This configures the SSL engine's semaphore (aka. lock) which is used
for mutual exclusion of operations which have to be done in a synchronized
way between the pre-forked Apache server processes. This directive can
only be used in the global server context because it's only useful to have
one global mutex.
The following Mutex types are available:
none
This is the default where no Mutex is used at all. Use it at your own
risk. But because currently the Mutex is mainly used for synchronizing
write access to the SSL Session Cache you can live without it as long as
you accept a sometimes garbled Session Cache. So it's not recommended to
leave this the default. Instead configure a real Mutex.
file:/path/to/mutex
This is the portable and (under Unix) always provided Mutex variant
where a physical (lock-)file is used as the Mutex. Always use a local
disk filesystem for /path/to/mutex and never a file
residing on a NFS- or AFS-filesystem. Note: Internally, the Process ID
(PID) of the Apache parent process is automatically appended to
/path/to/mutex to make it unique, so you don't have to
worry about conflicts yourself. Notice that this type of mutex is not
available under the Win32 environment. There you have to use the
semaphore mutex.
sem
This is the most elegant but also most non-portable Mutex variant
where a SysV IPC Semaphore (under Unix) and a Windows Mutex (under
Win32) is used when possible. It is only available when the underlying
platform supports it.
Example:
SSLMutex file:/usr/local/apache/logs/ssl_mutex
This configures one or more sources for seeding the Pseudo Random
Number Generator (PRNG) in OpenSSL at startup time (context is
startup) and/or just before a new SSL connection is
established (context is connect). This directive can
only be used in the global server context because the PRNG is a global
facility.
The following source variants are available:
builtin
This is the always available builtin seeding source. It's usage
consumes minimum CPU cycles under runtime and hence can be always used
without drawbacks. The source used for seeding the PRNG contains of the
current time, the current process id and (when applicable) a randomly
choosen 1KB extract of the inter-process scoreboard structure of Apache.
The drawback is that this is not really a strong source and at startup
time (where the scoreboard is still not available) this source just
produces a few bytes of entropy. So you should always, at least for the
startup, use an additional seeding source.
file:/path/to/source
This variant uses an external file /path/to/source as
the source for seeding the PRNG. When bytes is specified, only
the first bytes number of bytes of the file form the entropy
(and bytes is given to /path/to/source as the
first argument). When bytes is not specified the whole file
forms the entropy (and 0 is given to
/path/to/source as the first argument). Use this especially
at startup time, for instance with an available /dev/random
and/or /dev/urandom devices (which usually exist on modern
Unix derivates like FreeBSD and Linux).
But be careful: Usually /dev/random provides
only as much entropy data as it actually has, i.e. when you request 512
bytes of entropy, but the device currently has only 100 bytes available
two things can happen: On some platforms you receive only the 100 bytes
while on other platforms the read blocks until enough bytes are
available (which can take a long time). Here using an existing
/dev/urandom is better, because it never blocks and
actually gives the amount of requested data. The drawback is just that
the quality of the received data may not be the best.
On some platforms like FreeBSD one can even control how the entropy
is actually generated, i.e. by which system interrupts. More details one
can find under rndcontrol(8) on those platforms. Alternatively,
when your system lacks such a random device, you can use tool like EGD (Entropy Gathering
Daemon) and run it's client program with the
exec:/path/to/program/ variant (see below) or use
egd:/path/to/egd-socket (see below).
exec:/path/to/program
This variant uses an external executable
/path/to/program as the source for seeding the PRNG. When
bytes is specified, only the first bytes number of
bytes of its stdout contents form the entropy. When
bytes is not specified, the entirety of the data produced on
stdout form the entropy. Use this only at startup time when
you need a very strong seeding with the help of an external program (for
instance as in the example above with the truerand utility
you can find in the mod_ssl distribution which is based on the AT&T
truerand library). Using this in the connection context slows
down the server too dramatically, of course. So usually you should avoid
using external programs in that context.
egd:/path/to/egd-socket (Unix only)
This variant uses the Unix domain socket of the external Entropy
Gathering Daemon (EGD) (see http://www.lothar.com/tech/crypto/)
to seed the PRNG. Use this if no random device exists on your platform.
Example:
SSLRandomSeed startup builtin
SSLRandomSeed startup file:/dev/random
SSLRandomSeed startup file:/dev/urandom 1024
SSLRandomSeed startup exec:/usr/local/bin/truerand 16
SSLRandomSeed connect builtin
SSLRandomSeed connect file:/dev/random
SSLRandomSeed connect file:/dev/urandom 1024
This configures the storage type of the global/inter-process SSL
Session Cache. This cache is an optional facility which speeds up parallel
request processing. For requests to the same server process (via HTTP
keep-alive), OpenSSL already caches the SSL session information locally.
But because modern clients request inlined images and other data via
parallel requests (usually up to four parallel requests are common) those
requests are served by different pre-forked server processes.
Here an inter-process cache helps to avoid unneccessary session
handshakes.
The following two storage types are currently supported:
none
This is the default and just disables the global/inter-process
Session Cache. There is no drawback in functionality, but a noticeable
speed penalty can be observed.
dbm:/path/to/datafile
This makes use of a DBM hashfile on the local disk to synchronize the
local OpenSSL memory caches of the server processes. The slight increase
in I/O on the server results in a visible request speedup for your
clients, so this type of storage is generally recommended.
shm:/path/to/datafile[(size)]
This makes use of a high-performance hash table (approx. size
bytes in size) inside a shared memory segment in RAM (established via
/path/to/datafile) to synchronize the local OpenSSL memory
caches of the server processes. This storage type is not available on
all platforms. See the mod_ssl INSTALL document for details
on how to build Apache+EAPI with shared memory support.
Examples:
SSLSessionCache dbm:/usr/local/apache/logs/ssl_gcache_data
SSLSessionCache shm:/usr/local/apache/logs/ssl_gcache_data(512000)
| Name:
|
SSLSessionCacheTimeout |
| Description: |
Number of seconds before an SSL session expires in
the Session Cache |
| Syntax: |
SSLSessionCacheTimeout
seconds |
| Default: |
SSLSessionCacheTimeout 300 |
| Context: |
server config, virtual host |
| Override: |
Not applicable |
| Status: |
Extension |
| Module: |
mod_ssl |
| Compatibility:
|
mod_ssl 2.0
| | |
This directive sets the timeout in seconds for the information stored
in the global/inter-process SSL Session Cache and the OpenSSL internal
memory cache. It can be set as low as 15 for testing, but should be set to
higher values like 300 in real life.
Example:
SSLSessionCacheTimeout 600
This directive toggles the usage of the SSL/TLS Protocol Engine. This
is usually used inside a <VirtualHost> section to enable SSL/TLS for
a particular virtual host. By default the SSL/TLS Protocol Engine is
disabled for both the main server and all configured virtual hosts.
Example:
<VirtualHost _default_:443>
SSLEngine on
...
</VirtualHost>
This directive can be used to control the SSL protocol flavors mod_ssl
should use when establishing its server environment. Clients then can only
connect with one of the provided protocols.
The available (case-insensitive) protocols are:
SSLv2
This is the Secure Sockets Layer (SSL) protocol, version 2.0. It is
the original SSL protocol as designed by Netscape Corporation.
SSLv3
This is the Secure Sockets Layer (SSL) protocol, version 3.0. It is
the successor to SSLv2 and the currently (as of February 1999) de-facto
standardized SSL protocol from Netscape Corporation. It's supported by
almost all popular browsers.
TLSv1
This is the Transport Layer Security (TLS) protocol, version 1.0. It
is the successor to SSLv3 and currently (as of February 1999) still
under construction by the Internet Engineering Task Force (IETF). It's
still not supported by any popular browsers.
All
This is a shortcut for ``+SSLv2 +SSLv3 +TLSv1'' and a
convinient way for enabling all protocols except one when used in
combination with the minus sign on a protocol as the example above
shows.
Example:
# enable SSLv3 and TLSv1, but not SSLv2
SSLProtocol all -SSLv2
| Name:
|
SSLCipherSuite |
| Description: |
Cipher Suite available for negotiation in SSL
handshake |
| Syntax: |
SSLCipherSuite
cipher-spec |
| Default: |
SSLCipherSuite
ALL:!ADH:RC4+RSA:+HIGH:+MEDIUM:+LOW:+SSLv2:+EXP |
| Context: |
server config, virtual host, directory,
.htaccess |
| Override: |
AuthConfig |
| Status: |
Extension |
| Module: |
mod_ssl |
| Compatibility:
|
mod_ssl 2.1
| | |
This complex directive uses a colon-separated cipher-spec
string consisting of OpenSSL cipher specifications to configure the Cipher
Suite the client is permitted to negotiate in the SSL handshake phase.
Notice that this directive can be used both in per-server and
per-directory context. In per-server context it applies to the standard
SSL handshake when a connection is established. In per-directory context
it forces a SSL renegotation with the reconfigured Cipher Suite after the
HTTP request was read but before the HTTP response is sent.
An SSL cipher specification in cipher-spec is composed of 4
major attributes plus a few extra minor ones:
- Key Exchange Algorithm:
RSA or Diffie-Hellman variants.
- Authentication Algorithm:
RSA, Diffie-Hellman, DSS or
none.
- Cipher/Encryption Algorithm:
DES, Triple-DES, RC4, RC2,
IDEA or none.
- MAC Digest Algorithm:
MD5, SHA or SHA1. An SSL
cipher can also be an export cipher and is either a SSLv2 or SSLv3/TLSv1
cipher (here TLSv1 is equivalent to SSLv3). To specify which ciphers to
use, one can either specify all the Ciphers, one at a time, or use aliases
to specify the preference and order for the ciphers (see Table
1).
Table 1: OpenSSL Cipher Specification
Tags
| Tag |
Description |
| Key Exchange Algorithm: |
kRSA |
RSA key exchange |
kDHr |
Diffie-Hellman key exchange with RSA key |
kDHd |
Diffie-Hellman key exchange with DSA key |
kEDH |
Ephemeral (temp.key) Diffie-Hellman key exchange (no
cert) |
| Authentication Algorithm: |
aNULL |
No authentication |
aRSA |
RSA authentication |
aDSS |
DSS authentication |
aDH |
Diffie-Hellman authentication |
| Cipher Encoding
Algorithm: |
eNULL |
No encoding |
DES |
DES encoding |
3DES |
Triple-DES encoding |
RC4 |
RC4 encoding |
RC2 |
RC2 encoding |
IDEA |
IDEA encoding |
| MAC Digest Algorithm: |
MD5 |
MD5 hash function |
SHA1 |
SHA1 hash function |
SHA |
SHA hash function |
| Aliases: |
SSLv2 |
all SSL version 2.0 ciphers |
SSLv3 |
all SSL version 3.0 ciphers |
TLSv1 |
all TLS version 1.0 ciphers |
EXP |
all export ciphers |
EXP40 |
all 40-bit export ciphers only |
EXP56 |
all 56-bit export ciphers only |
LOW |
all low strength ciphers (no export, single
DES) |
MEDIUM |
all ciphers with 128 bit encryption |
HIGH |
all ciphers using Triple-DES |
RSA |
all ciphers using RSA key exchange |
DH |
all ciphers using Diffie-Hellman key exchange |
EDH |
all ciphers using Ephemeral Diffie-Hellman key
exchange |
ADH |
all ciphers using Anonymous Diffie-Hellman key
exchange |
DSS |
all ciphers using DSS authentication |
NULL |
all ciphers using no
encryption | | |
Now where this becomes interesting is that these can be put together to
specify the order and ciphers you wish to use. To speed this up there are
also aliases (SSLv2, SSLv3, TLSv1, EXP, LOW, MEDIUM, HIGH)
for certain groups of ciphers. These tags can be joined together with
prefixes to form the cipher-spec. Available prefixes are:
- none: add cipher to list
+: add ciphers to list and pull them to current
location in list
-: remove cipher from list (can be added later again)
!: kill cipher from list completely (can not be
added later again) A simpler way to look at all of this is to
use the ``openssl ciphers -v'' command which provides a nice
way to successively create the correct cipher-spec string. The
default cipher-spec string is
``ALL:!ADH:RC4+RSA:+HIGH:+MEDIUM:+LOW:+SSLv2:+EXP'' which
means the following: first, remove from consideration any ciphers that do
not authenticate, i.e. for SSL only the Anonymous Diffie-Hellman ciphers.
Next, use ciphers using RC4 and RSA. Next include the high, medium and
then the low security ciphers. Finally pull all SSLv2 and export
ciphers to the end of the list.
$ openssl ciphers -v 'ALL:!ADH:RC4+RSA:+HIGH:+MEDIUM:+LOW:+SSLv2:+EXP'
NULL-SHA SSLv3 Kx=RSA Au=RSA Enc=None Mac=SHA1
NULL-MD5 SSLv3 Kx=RSA Au=RSA Enc=None Mac=MD5
EDH-RSA-DES-CBC3-SHA SSLv3 Kx=DH Au=RSA Enc=3DES(168) Mac=SHA1
... ... ... ... ...
EXP-RC4-MD5 SSLv3 Kx=RSA(512) Au=RSA Enc=RC4(40) Mac=MD5 export
EXP-RC2-CBC-MD5 SSLv2 Kx=RSA(512) Au=RSA Enc=RC2(40) Mac=MD5 export
EXP-RC4-MD5 SSLv2 Kx=RSA(512) Au=RSA Enc=RC4(40) Mac=MD5 export
The complete list of particular RSA & DH ciphers
for SSL is given in Table
2.
Example:
SSLCipherSuite RSA:!EXP:!NULL:+HIGH:+MEDIUM:-LOW
Table 2: Particular SSL Ciphers
| Cipher-Tag |
Protocol |
Key Ex. |
Auth. |
Enc. |
MAC |
Type |
| RSA Ciphers: |
DES-CBC3-SHA |
SSLv3 |
RSA |
RSA |
3DES(168) |
SHA1 |
|
DES-CBC3-MD5 |
SSLv2 |
RSA |
RSA |
3DES(168) |
MD5 |
|
IDEA-CBC-SHA |
SSLv3 |
RSA |
RSA |
IDEA(128) |
SHA1 |
|
RC4-SHA |
SSLv3 |
RSA |
RSA |
RC4(128) |
SHA1 |
|
RC4-MD5 |
SSLv3 |
RSA |
RSA |
RC4(128) |
MD5 |
|
IDEA-CBC-MD5 |
SSLv2 |
RSA |
RSA |
IDEA(128) |
MD5 |
|
RC2-CBC-MD5 |
SSLv2 |
RSA |
RSA |
RC2(128) |
MD5 |
|
RC4-MD5 |
SSLv2 |
RSA |
RSA |
RC4(128) |
MD5 |
|
DES-CBC-SHA |
SSLv3 |
RSA |
RSA |
DES(56) |
SHA1 |
|
RC4-64-MD5 |
SSLv2 |
RSA |
RSA |
RC4(64) |
MD5 |
|
DES-CBC-MD5 |
SSLv2 |
RSA |
RSA |
DES(56) |
MD5 |
|
EXP-DES-CBC-SHA |
SSLv3 |
RSA(512) |
RSA |
DES(40) |
SHA1 |
export |
EXP-RC2-CBC-MD5 |
SSLv3 |
RSA(512) |
RSA |
RC2(40) |
MD5 |
export |
EXP-RC4-MD5 |
SSLv3 |
RSA(512) |
RSA |
RC4(40) |
MD5 |
export |
EXP-RC2-CBC-MD5 |
SSLv2 |
RSA(512) |
RSA |
RC2(40) |
MD5 |
export |
EXP-RC4-MD5 |
SSLv2 |
RSA(512) |
RSA |
RC4(40) |
MD5 |
export |
NULL-SHA |
SSLv3 |
RSA |
RSA |
None |
SHA1 |
|
NULL-MD5 |
SSLv3 |
RSA |
RSA |
None |
MD5 |
|
| Diffie-Hellman Ciphers: |
ADH-DES-CBC3-SHA |
SSLv3 |
DH |
None |
3DES(168) |
SHA1 |
|
ADH-DES-CBC-SHA |
SSLv3 |
DH |
None |
DES(56) |
SHA1 |
|
ADH-RC4-MD5 |
SSLv3 |
DH |
None |
RC4(128) |
MD5 |
|
EDH-RSA-DES-CBC3-SHA |
SSLv3 |
DH |
RSA |
3DES(168) |
SHA1 |
|
EDH-DSS-DES-CBC3-SHA |
SSLv3 |
DH |
DSS |
3DES(168) |
SHA1 |
|
EDH-RSA-DES-CBC-SHA |
SSLv3 |
DH |
RSA |
DES(56) |
SHA1 |
|
EDH-DSS-DES-CBC-SHA |
SSLv3 |
DH |
DSS |
DES(56) |
SHA1 |
|
EXP-EDH-RSA-DES-CBC-SHA |
SSLv3 |
DH(512) |
RSA |
DES(40) |
SHA1 |
export |
EXP-EDH-DSS-DES-CBC-SHA |
SSLv3 |
DH(512) |
DSS |
DES(40) |
SHA1 |
export |
EXP-ADH-DES-CBC-SHA |
SSLv3 |
DH(512) |
None |
DES(40) |
SHA1 |
export |
EXP-ADH-RC4-MD5 |
SSLv3 |
DH(512) |
None |
RC4(40) |
MD5 |
export | | |
This directive points to the PEM-encoded Certificate file for the
server and optionally also to the corresponding RSA or DSA Private Key
file for it (contained in the same file). If the contained Private Key is
encrypted the Pass Phrase dialog is forced at startup time. This directive
can be used up to two times (referencing different filenames) when both a
RSA and a DSA based server certificate is used in parallel.
Example:
SSLCertificateFile /usr/local/apache/conf/ssl.crt/server.crt
This directive points to the PEM-encoded Private Key file for the
server. If the Private Key is not combined with the Certificate in the
SSLCertificateFile, use this additional directive to point to
the file with the stand-alone Private Key. When
SSLCertificateFile is used and the file contains both the
Certificate and the Private Key this directive need not be used. But we
strongly discourage this practice. Instead we recommend you to separate
the Certificate and the Private Key. If the contained Private Key is
encrypted, the Pass Phrase dialog is forced at startup time. This
directive can be used up to two times (referencing different filenames)
when both a RSA and a DSA based private key is used in parallel.
Example:
SSLCertificateKeyFile /usr/local/apache/conf/ssl.key/server.key
This directive sets the optional all-in-one file where you can
assemble the certificates of Certification Authorities (CA) which form the
certificate chain of the server certificate. This starts with the issuing
CA certificate of of the server certificate and can range up to the root
CA certificate. Such a file is simply the concatenation of the various
PEM-encoded CA Certificate files, usually in certificate chain order.
This should be used alternatively and/or additionally to SSLCACertificatePath
for explicitly constructing the server certificate chain which is sent to
the browser in addition to the server certificate. It is especially useful
to avoid conflicts with CA certificates when using client authentication.
Because although placing a CA certificate of the server certificate chain
into SSLCACertificatePath
has the same effect for the certificate chain construction, it has the
side-effect that client certificates issued by this same CA certificate
are also accepted on client authentication. That's usually not one expect.
But be careful: Providing the certificate chain works only if you are
using a single (either RSA or DSA) based server certificate.
If you are using a coupled RSA+DSA certificate pair, this will work only
if actually both certificates use the same certificate chain. Else
the browsers will be confused in this situation.
Example:
SSLCertificateChainFile /usr/local/apache/conf/ssl.crt/ca.crt
This directive sets the directory where you keep the Certificates of
Certification Authorities (CAs) whose clients you deal with. These are
used to verify the client certificate on Client Authentication.
The files in this directory have to be PEM-encoded and are accessed
through hash filenames. So usually you can't just place the Certificate
files there: you also have to create symbolic links named
hash-value.N. And you should always make sure this
directory contains the appropriate symbolic links. Use the
Makefile which comes with mod_ssl to accomplish this task.
Example:
SSLCACertificatePath /usr/local/apache/conf/ssl.crt/
This directive sets the all-in-one file where you can assemble
the Certificates of Certification Authorities (CA) whose clients
you deal with. These are used for Client Authentication. Such a file is
simply the concatenation of the various PEM-encoded Certificate files, in
order of preference. This can be used alternatively and/or additionally to
SSLCACertificatePath.
Example:
SSLCACertificateFile /usr/local/apache/conf/ssl.crt/ca-bundle-client.crt
This directive sets the directory where you keep the Certificate
Revocation Lists (CRL) of Certification Authorities (CAs) whose clients
you deal with. These are used to revoke the client certificate on Client
Authentication.
The files in this directory have to be PEM-encoded and are accessed
through hash filenames. So usually you have not only to place the CRL
files there. Additionally you have to create symbolic links named
hash-value.rN. And you should always make sure this
directory contains the appropriate symbolic links. Use the
Makefile which comes with mod_ssl to accomplish this task.
Example:
SSLCARevocationPath /usr/local/apache/conf/ssl.crl/
This directive sets the all-in-one file where you can assemble
the Certificate Revocation Lists (CRL) of Certification Authorities (CA)
whose clients you deal with. These are used for Client
Authentication. Such a file is simply the concatenation of the various
PEM-encoded CRL files, in order of preference. This can be used
alternatively and/or additionally to SSLCARevocationPath.
Example:
SSLCARevocationFile /usr/local/apache/conf/ssl.crl/ca-bundle-client.crl
This directive sets the Certificate verification level for the Client
Authentication. Notice that this directive can be used both in per-server
and per-directory context. In per-server context it applies to the client
authentication process used in the standard SSL handshake when a
connection is established. In per-directory context it forces a SSL
renegotation with the reconfigured client verification level after the
HTTP request was read but before the HTTP response is sent.
The following levels are available for level:
- none: no client Certificate is required at all
- optional: the client may present a valid
Certificate
- require: the client has to present a valid
Certificate
- optional_no_ca: the client may present a valid
Certificate
but it need not to be (successfully) verifiable.
In practice only levels none and
require are really interesting, because level
optional doesn't work with all browsers and level
optional_no_ca is actually against the idea of
authentication (but can be used to establish SSL test pages, etc.)
Example:
SSLVerifyClient require
This directive sets how deeply mod_ssl should verify before deciding
that the clients don't have a valid certificate. Notice that this
directive can be used both in per-server and per-directory context. In
per-server context it applies to the client authentication process used in
the standard SSL handshake when a connection is established. In
per-directory context it forces a SSL renegotation with the reconfigured
client verification depth after the HTTP request was read but before the
HTTP response is sent.
The depth actually is the maximum number of intermediate certificate
issuers, i.e. the number of CA certificates which are max allowed to be
followed while verifying the client certificate. A depth of 0 means that
self-signed client certificates are accepted only, the default depth of 1
means the client certificate can be self-signed or has to be signed by a
CA which is directly known to the server (i.e. the CA's certificate is
under SSLCACertificatePath), etc.
Example:
SSLVerifyDepth 10
This directive sets the name of the dedicated SSL protocol engine
logfile. Error type messages are additionally duplicated to the general
Apache error log file (directive ErrorLog). Put this
somewhere where it cannot be used for symlink attacks on a real server
(i.e. somewhere where only root can write). If the filename does
not begin with a slash ('/') then it is assumed to be
relative to the Server Root. If filename begins with a
bar ('|') then the following string is assumed to be a path
to an executable program to which a reliable pipe can be established. The
directive should occur only once per virtual server config.
Example:
SSLLog /usr/local/apache/logs/ssl_engine_log
This directive sets the verbosity degree of the dedicated SSL protocol
engine logfile. The level is one of the following (in ascending
order where higher levels include lower levels):
none
no dedicated SSL logging is done, but messages
of level ``error'' are still written to the general Apache
error logfile.
error
log messages of error type only, i.e. messages
which show fatal situations (processing is stopped). Those messages are
also duplicated to the general Apache error logfile.
warn
log also warning messages, i.e. messages which
show non-fatal problems (processing is continued).
info
log also informational messages, i.e. messages
which show major processing steps.
trace
log also trace messages, i.e. messages which
show minor processing steps.
debug
log also debugging messages, i.e. messages
which show development and low-level I/O information.
Example:
SSLLogLevel warn
This directive can be used to control various run-time options on a
per-directory basis. Normally, if multiple SSLOptions could
apply to a directory, then the most specific one is taken completely; the
options are not merged. However if all the options on the
SSLOptions directive are preceded by a plus (+)
or minus (-) symbol, the options are merged. Any options
preceded by a + are added to the options currently in force,
and any options preceded by a - are removed from the options
currently in force.
The available options are:
StdEnvVars
When this option is enabled, the standard set of SSL related CGI/SSI
environment variables are created. This per default is disabled for
performance reasons, because the information extraction step is a rather
expensive operation. So one usually enables this option for CGI and SSI
requests only.
CompatEnvVars
When this option is enabled, additional CGI/SSI environment variables
are created for backward compatibility to other Apache SSL solutions.
Look in the Compatibility
chapter for details on the particular variables generated.
ExportCertData
When this option is enabled, additional CGI/SSI environment variables
are created: SSL_SERVER_CERT, SSL_CLIENT_CERT
and SSL_CLIENT_CERT_CHAINn (with n =
0,1,2,..). These contain the PEM-encoded X.509 Certificates of server
and client for the current HTTPS connection and can be used by CGI
scripts for deeper Certificate checking. Additionally all other
certificates of the client certificate chain are provided, too. This
bloats up the environment a little bit which is why you have to use this
option to enable it on demand.
FakeBasicAuth
When this option is enabled, the Subject Distinguished Name (DN) of
the Client X509 Certificate is translated into a HTTP Basic
Authorization username. This means that the standard Apache
authentication methods can be used for access control. The user name is
just the Subject of the Client's X509 Certificate (can be determined by
running OpenSSL's openssl x509 command: openssl x509
-noout -subject -in certificate.crt). Note
that no password is obtained from the user. Every entry in the user file
needs this password: ``xxj31ZMTZzkVA'', which is the
DES-encrypted version of the word `password''. Those who
live under MD5-based encryption (for instance under FreeBSD or BSD/OS,
etc.) should use the following MD5 hash of the same word:
``$1$OXLyS...$Owx8s2/m9/gfkcRVXzgoE/''.
StrictRequire
This forces forbidden access when SSLRequireSSL
or SSLRequire successfully decided that access should be
forbidden. Usually the default is that in the case where a
``Satisfy any'' directive is used, and other access
restrictions are passed, denial of access due to
SSLRequireSSL or SSLRequire is overridden
(because that's how the Apache Satisfy mechanism should work.)
But for strict access restriction you can use SSLRequireSSL
and/or SSLRequire in combination with an ``SSLOptions
+StrictRequire''. Then an additional ``Satisfy Any''
has no chance once mod_ssl has decided to deny access.
OptRenegotiate
This enables optimized SSL connection renegotiation handling when SSL
directives are used in per-directory context. By default a strict scheme
is enabled where every per-directory reconfiguration of SSL
parameters causes a full SSL renegotiation handshake. When this
option is used mod_ssl tries to avoid unnecessary handshakes by doing
more granular (but still safe) parameter checks. Nevertheless these
granular checks sometimes maybe not what the user expects, so enable
this on a per-directory basis only, please.
Example:
SSLOptions +FakeBasicAuth -StrictRequire
<Files ~ "\.(cgi|shtml)$">
SSLOptions +StdEnvVars +CompatEnvVars -ExportCertData
<Files>
This directive forbids access unless HTTP over SSL (i.e. HTTPS) is
enabled for the current connection. This is very handy inside the
SSL-enabled virtual host or directories for defending against
configuration errors that expose stuff that should be protected. When this
directive is present all requests are denied which are not using SSL.
Example:
SSLRequireSSL
This directive specifies a general access requirement which has to be
fulfilled in order to allow access. It's a very powerful directive because
the requirement specification is an arbitrarily complex boolean expression
containing any number of access checks.
The expression must match the following syntax (given as a BNF
grammar notation):
expr ::= "true" | "false"
| "!" expr
| expr "&&" expr
| expr "||" expr
| "(" expr ")"
| comp
comp ::= word "==" word | word "eq" word
| word "!=" word | word "ne" word
| word "<" word | word "lt" word
| word "<=" word | word "le" word
| word ">" word | word "gt" word
| word ">=" word | word "ge" word
| word "in" "{" wordlist "}"
| word "=~" regex
| word "!~" regex
wordlist ::= word
| wordlist "," word
word ::= digit
| cstring
| variable
| function
digit ::= [0-9]+
cstring ::= "..."
variable ::= "%{" varname "}"
function ::= funcname "(" funcargs ")"
while for varname any variable from Table
3 can be used. Finally for funcname the following
functions are available:
Notice that
expression is first parsed into an internal machine
representation and then evaluated in a second step. Actually, in Global
and Per-Server Class context expression is parsed at startup time
and at runtime only the machine representation is executed. For
Per-Directory context this is different: here expression has to
be parsed and immediately executed for every request.
Example:
SSLRequire ( %{SSL_CIPHER} !~ m/^(EXP|NULL)-/ \
and %{SSL_CLIENT_S_DN_O} eq "Snake Oil, Ltd." \
and %{SSL_CLIENT_S_DN_OU} in {"Staff", "CA", "Dev"} \
and %{TIME_WDAY} >= 1 and %{TIME_WDAY} <= 5 \
and %{TIME_HOUR} >= 8 and %{TIME_HOUR} <= 20 ) \
or %{REMOTE_ADDR} =~ m/^192\.76\.162\.[0-9]+$/
Table 3: Available Variables for
SSLRequire
Standard CGI/1.0 and Apache variables: HTTP_USER_AGENT PATH_INFO AUTH_TYPE
HTTP_REFERER QUERY_STRING SERVER_SOFTWARE
HTTP_COOKIE REMOTE_HOST API_VERSION
HTTP_FORWARDED REMOTE_IDENT TIME_YEAR
HTTP_HOST IS_SUBREQ TIME_MON
HTTP_PROXY_CONNECTION DOCUMENT_ROOT TIME_DAY
HTTP_ACCEPT SERVER_ADMIN TIME_HOUR
HTTP:headername SERVER_NAME TIME_MIN
THE_REQUEST SERVER_PORT TIME_SEC
REQUEST_METHOD SERVER_PROTOCOL TIME_WDAY
REQUEST_SCHEME REMOTE_ADDR TIME
REQUEST_URI REMOTE_USER ENV:variablename
REQUEST_FILENAME
SSL-related variables: HTTPS SSL_CLIENT_M_VERSION SSL_SERVER_M_VERSION
SSL_CLIENT_M_SERIAL SSL_SERVER_M_SERIAL
SSL_PROTOCOL SSL_CLIENT_V_START SSL_SERVER_V_START
SSL_SESSION_ID SSL_CLIENT_V_END SSL_SERVER_V_END
SSL_CIPHER SSL_CLIENT_S_DN SSL_SERVER_S_DN
SSL_CIPHER_EXPORT SSL_CLIENT_S_DN_C SSL_SERVER_S_DN_C
SSL_CIPHER_ALGKEYSIZE SSL_CLIENT_S_DN_ST SSL_SERVER_S_DN_ST
SSL_CIPHER_USEKEYSIZE SSL_CLIENT_S_DN_L SSL_SERVER_S_DN_L
SSL_VERSION_LIBRARY SSL_CLIENT_S_DN_O SSL_SERVER_S_DN_O
SSL_VERSION_INTERFACE SSL_CLIENT_S_DN_OU SSL_SERVER_S_DN_OU
SSL_CLIENT_S_DN_CN SSL_SERVER_S_DN_CN
SSL_CLIENT_S_DN_T SSL_SERVER_S_DN_T
SSL_CLIENT_S_DN_I SSL_SERVER_S_DN_I
SSL_CLIENT_S_DN_G SSL_SERVER_S_DN_G
SSL_CLIENT_S_DN_S SSL_SERVER_S_DN_S
SSL_CLIENT_S_DN_D SSL_SERVER_S_DN_D
SSL_CLIENT_S_DN_UID SSL_SERVER_S_DN_UID
SSL_CLIENT_S_DN_Email SSL_SERVER_S_DN_Email
SSL_CLIENT_I_DN SSL_SERVER_I_DN
SSL_CLIENT_I_DN_C SSL_SERVER_I_DN_C
SSL_CLIENT_I_DN_ST SSL_SERVER_I_DN_ST
SSL_CLIENT_I_DN_L SSL_SERVER_I_DN_L
SSL_CLIENT_I_DN_O SSL_SERVER_I_DN_O
SSL_CLIENT_I_DN_OU SSL_SERVER_I_DN_OU
SSL_CLIENT_I_DN_CN SSL_SERVER_I_DN_CN
SSL_CLIENT_I_DN_T SSL_SERVER_I_DN_T
SSL_CLIENT_I_DN_I SSL_SERVER_I_DN_I
SSL_CLIENT_I_DN_G SSL_SERVER_I_DN_G
SSL_CLIENT_I_DN_S SSL_SERVER_I_DN_S
SSL_CLIENT_I_DN_D SSL_SERVER_I_DN_D
SSL_CLIENT_I_DN_UID SSL_SERVER_I_DN_UID
SSL_CLIENT_I_DN_Email SSL_SERVER_I_DN_Email
SSL_CLIENT_A_SIG SSL_SERVER_A_SIG
SSL_CLIENT_A_KEY SSL_SERVER_A_KEY
SSL_CLIENT_CERT SSL_SERVER_CERT
SSL_CLIENT_CERT_CHAINn
SSL_CLIENT_VERIFY
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This module provides a lot
of SSL information as additional environment variables to the SSI and CGI
namespace. The generated variables are listed in Table
4. For backward compatibility the information can be made available
under different names, too. Look in the Compatibility
chapter for details on the compatibility variables.
Table 4: SSI/CGI Environment
Variables
| Variable Name: |
Value Type: |
Description: |
HTTPS |
flag |
HTTPS is being used. |
SSL_PROTOCOL |
string |
The SSL protocol version (SSLv2, SSLv3, TLSv1) |
SSL_SESSION_ID |
string |
The hex-encoded SSL session id |
SSL_CIPHER |
string |
The cipher specification name |
SSL_CIPHER_EXPORT |
string |
true if cipher is an export
cipher |
SSL_CIPHER_USEKEYSIZE |
number |
Number of cipher bits (actually used) |
SSL_CIPHER_ALGKEYSIZE |
number |
Number of cipher bits (possible) |
SSL_VERSION_INTERFACE |
string |
The mod_ssl program version |
SSL_VERSION_LIBRARY |
string |
The OpenSSL program version |
SSL_CLIENT_M_VERSION |
string |
The version of the client certificate |
SSL_CLIENT_M_SERIAL |
string |
The serial of the client certificate |
SSL_CLIENT_S_DN |
string |
Subject DN in client's certificate |
SSL_CLIENT_S_DN_x509 |
string |
Component of client's Subject DN |
SSL_CLIENT_I_DN |
string |
Issuer DN of client's certificate |
SSL_CLIENT_I_DN_x509 |
string |
Component of client's Issuer DN |
SSL_CLIENT_V_START |
string |
Validity of client's certificate (start time) |
SSL_CLIENT_V_END |
string |
Validity of client's certificate (end time) |
SSL_CLIENT_A_SIG |
string |
Algorithm used for the signature of client's
certificate |
SSL_CLIENT_A_KEY |
string |
Algorithm used for the public key of client's
certificate |
SSL_CLIENT_CERT |
string |
PEM-encoded client certificate |
SSL_CLIENT_CERT_CHAINn |
string |
PEM-encoded certificates in client certificate
chain |
SSL_CLIENT_VERIFY |
string |
NONE, SUCCESS, GENEROUS
or FAILED:reason |
SSL_SERVER_M_VERSION |
string |
The version of the server certificate |
SSL_SERVER_M_SERIAL |
string |
The serial of the server certificate |
SSL_SERVER_S_DN |
string |
Subject DN in server's certificate |
SSL_SERVER_S_DN_x509 |
string |
Component of server's Subject DN |
SSL_SERVER_I_DN |
string |
Issuer DN of server's certificate |
SSL_SERVER_I_DN_x509 |
string |
Component of server's Issuer DN |
SSL_SERVER_V_START |
string |
Validity of server's certificate (start time) |
SSL_SERVER_V_END |
string |
Validity of server's certificate (end time) |
SSL_SERVER_A_SIG |
string |
Algorithm used for the signature of server's
certificate |
SSL_SERVER_A_KEY |
string |
Algorithm used for the public key of server's
certificate |
SSL_SERVER_CERT |
string |
PEM-encoded server certificate | [
where x509 is a component of a X.509 DN:
C,ST,L,O,OU,CN,T,I,G,S,D,UID,Email ]
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When mod_ssl is built into
Apache or at least loaded (under DSO situation) additional functions exist
for the Custom
Log Format of mod_log_config.
First there is an additional
``%{varname}x'' eXtension format
function which can be used to expand any variables provided by any module,
especially those provided by mod_ssl which can you find in Table
4.
For backward compatibility there is additionally a special
``%{name}c'' cryptography format
function provided. Information about this function is provided in the Compatibility
chapter.
Example:
CustomLog logs/ssl_request_log \
"%t %h %{SSL_PROTOCOL}x %{SSL_CIPHER}x \"%r\" %b"
Introduction |
Compatibility
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