This text is a work in progress—highly subject to change—and may not accurately describe any released version of the Apache™ Subversion® software. Bookmarking or otherwise referring others to this page is probably not such a smart idea. Please visit http://www.svnbook.com/ for stable versions of this book.
The Apache HTTP Server is a “heavy-duty” network server that Subversion can leverage. Via a custom module, httpd makes Subversion repositories available to clients via the WebDAV/DeltaV[64] protocol, which is an extension to HTTP 1.1. This protocol takes the ubiquitous HTTP protocol that is the core of the World Wide Web, and adds writing—specifically, versioned writing—capabilities. The result is a standardized, robust system that is conveniently packaged as part of the Apache 2.0 software, supported by numerous operating systems and third-party products, and doesn't require network administrators to open up yet another custom port.[65] While an Apache-Subversion server has more features than svnserve, it's also a bit more difficult to set up. With flexibility often comes more complexity.
Much of the following discussion includes references to Apache configuration directives. While some examples are given of the use of these directives, describing them in full is outside the scope of this chapter. The Apache team maintains excellent documentation, publicly available on their web site at https://httpd.apache.org. For example, a general reference for the configuration directives is located at https://httpd.apache.org/docs/current/mod/directives.html.
Also, as you make changes to your Apache setup, it is likely
that somewhere along the way a mistake will be made. If you are
not already familiar with Apache's logging subsystem, you should
become aware of it. In your httpd.conf
file are directives that specify the on-disk locations of the
access and error logs generated by Apache (the
CustomLog
and ErrorLog
directives, respectively).
Subversion's mod_dav_svn uses Apache's error
logging interface as well. You can always browse the contents
of those files for information that might reveal the source of a
problem that is not clearly noticeable otherwise.
To network your repository over HTTP, you basically need four components, available in two packages. You'll need Apache httpd 2.0 or newer, the mod_dav DAV module that comes with it, Subversion, and the mod_dav_svn filesystem provider module distributed with Subversion. Once you have all of those components, the process of networking your repository is as simple as:
Getting httpd up and running with the mod_dav module
Installing the mod_dav_svn backend to mod_dav, which uses Subversion's libraries to access the repository
Configuring your httpd.conf
file to export (or expose) the repository
You can accomplish the first two items either by
compiling httpd and Subversion from
source code or by installing prebuilt binary packages of
them on your system. For the most up-to-date information on
how to compile Subversion for use with the Apache HTTP Server,
as well as how to compile and configure Apache itself for
this purpose, see the INSTALL
file in
the top level of the Subversion source code tree.
Once you have all the necessary components installed on
your system, all that remains is the configuration of Apache
via its httpd.conf
file. Instruct Apache
to load the mod_dav_svn module using the
LoadModule
directive. This directive must
precede any other Subversion-related configuration items. If
your Apache was installed using the default layout, your
mod_dav_svn module should have been
installed in the modules
subdirectory of
the Apache install location (often
/usr/local/apache2
). The
LoadModule
directive has a simple syntax,
mapping a named module to the location of a shared library on
disk:
LoadModule dav_svn_module modules/mod_dav_svn.so
Apache interprets the LoadModule
configuration item's library path as relative to its own
server root. If configured as previously shown, Apache will
look for the Subversion DAV module shared library in its
own modules/
subdirectory. Depending on
how Subversion was installed on your system, you might need to
specify a different path for this library altogether, perhaps
even an absolute path such as in the following example:
LoadModule dav_svn_module C:/Subversion/libexec/mod_dav_svn.so
Note that if mod_dav was compiled as a
shared object (instead of statically linked directly to the
httpd binary), you'll need a similar
LoadModule
statement for it, too. Be sure
that it comes before the mod_dav_svn line:
LoadModule dav_module modules/mod_dav.so LoadModule dav_svn_module modules/mod_dav_svn.so
At a later location in your configuration file, you now
need to tell Apache where you keep your Subversion repository
(or repositories). The Location
directive
has an XML-like notation, starting with an opening tag and
ending with a closing tag, with various other configuration
directives in the middle. The purpose of the
Location
directive is to instruct Apache to
do something special when handling requests that are directed
at a given URL or one of its children. In the case of
Subversion, you want Apache to simply hand off support for
URLs that point at versioned resources to the DAV layer. You
can instruct Apache to delegate the handling of all URLs whose
path portions (the part of the URL that follows the server's
name and the optional port number) begin with
/repos/
to a DAV provider whose
repository is located at
/var/svn/repository
using the
following httpd.conf
syntax:
<Location /repos> DAV svn SVNPath /var/svn/repository </Location>
If you plan to support multiple Subversion repositories
that will reside in the same parent directory on your local
disk, you can use an alternative
directive—SVNParentPath
—to
indicate that common parent directory. For example, if you
know you will be creating multiple Subversion repositories in
a directory /var/svn
that would be
accessed via URLs such as
http://my.server.com/svn/repos1
,
http://my.server.com/svn/repos2
, and so on, you
could use the httpd.conf
configuration
syntax in the following example:
<Location /svn> DAV svn # Automatically map any "/svn/foo" URL to repository /var/svn/foo SVNParentPath /var/svn </Location>
Using this syntax, Apache will delegate the
handling of all URLs whose path portions begin with
/svn/
to the Subversion DAV provider,
which will then assume that any items in the directory
specified by the SVNParentPath
directive
are actually Subversion repositories. This is a particularly
convenient syntax in that, unlike the use of the
SVNPath
directive, you don't have to
restart Apache to add or remove hosted repositories.
Be sure that when you define your new
Location
, it doesn't overlap with other
exported locations. For example, if your main
DocumentRoot
is exported to
/www
, do not export a Subversion
repository in <Location /www/repos>
.
If a request comes in for the URI
/www/repos/foo.c
, Apache won't know
whether to look for a file repos/foo.c
in
the DocumentRoot
, or whether to delegate
mod_dav_svn to return
foo.c
from the Subversion repository.
The result is often an error from the server of the form
301 Moved Permanently
.
At this stage, you should strongly consider the question of permissions. If you've been running Apache for some time now as your regular web server, you probably already have a collection of content—web pages, scripts, and such. These items have already been configured with a set of permissions that allows them to work with Apache, or more appropriately, that allows Apache to work with those files. Apache, when used as a Subversion server, will also need the correct permissions to read and write to your Subversion repository.
You will need to determine a permission system setup that
satisfies Subversion's requirements without messing up any
previously existing web page or script installations. This
might mean changing the permissions on your Subversion
repository to match those in use by other things that Apache
serves for you, or it could mean using the
User
and Group
directives in httpd.conf
to specify that
Apache should run as the user and group that owns your
Subversion repository. There is no single correct way to set
up your permissions, and each administrator will have
different reasons for doing things a certain way. Just be
aware that permission-related problems are perhaps the most
common oversight when configuring a Subversion repository for
use with Apache.
At this point, if you configured
httpd.conf
to contain something such as the
following:
<Location /svn> DAV svn SVNParentPath /var/svn </Location>
your repository is “anonymously”
accessible to the world. Until you configure some
authentication and authorization policies, the Subversion
repositories that you make available via the
Location
directive will be generally
accessible to everyone. In other words:
Anyone can use a Subversion client to check out a working copy of a repository URL (or any of its subdirectories).
Anyone can interactively browse the repository's latest revision simply by pointing a web browser to the repository URL.
Anyone can commit to the repository.
Of course, you might have already set up a pre-commit hook script to prevent commits (see the section called “Implementing Repository Hooks”). But as you read on, you'll see that it's also possible to use Apache's built-in methods to restrict access in specific ways.
Tip | |
---|---|
Requiring authentication defends against invalid users directly accessing the repository, but does not guard the privacy of valid users' network activity. See the section called “Protecting network traffic with SSL” for how to configure your server to support SSL encryption, which can provide that extra layer of protection. |
The easiest way to authenticate a client is via the HTTP Basic authentication mechanism, which simply uses a username and password to verify a user's identity. Apache provides the htpasswd utility[66] for managing files containing usernames and passwords.
Warning | |
---|---|
Basic authentication is extremely insecure, because it sends passwords over the network in very nearly plain text. See the section called “Digest authentication” for details on using the much safer Digest mechanism. |
First, create a password file and grant access to users Harry and Sally:
$ ### First time: use -c to create the file $ ### Use -m to use MD5 encryption of the password, which is more secure $ htpasswd -c -m /etc/svn-auth.htpasswd harry New password: ***** Re-type new password: ***** Adding password for user harry $ htpasswd -m /etc/svn-auth.htpasswd sally New password: ******* Re-type new password: ******* Adding password for user sally $
Next, ensure that Apache has access to the modules which
provide the Basic authentication and related
functionality: mod_auth_basic,
mod_authn_file, and
mod_authz_user. In many cases, these
modules are compiled into httpd itself,
but if not, you might need to explicitly load one or more of
them using the LoadModule
directive:
LoadModule auth_basic_module modules/mod_auth_basic.so LoadModule authn_file_module modules/mod_authn_file.so LoadModule authz_user_module moduels/mod_authz_user.so
After ensuring the Apache has access to the required
functionality, you'll need to add some more directives
inside the <Location>
block to tell
Apache what type of authentication you wish to use, and just
how to do so:
<Location /svn> DAV svn SVNParentPath /var/svn # Authentication: Basic AuthName "Subversion repository" AuthType Basic AuthBasicProvider file AuthUserFile /etc/svn-auth.htpasswd </Location>
These directives work as follows:
AuthName
is an arbitrary name
that you choose for the authentication domain. Most
browsers display this name in the dialog box when
prompting for username and password.
AuthType
specifies the type of
authentication to use.
AuthBasicProvider
specifies the
Basic authentication provider to use for the location.
In our example, we wish to consult a local password
file.
AuthUserFile
specifies the
location of the password file to use.
However, this <Location>
block
doesn't yet do anything useful. It merely tells Apache that
if authorization were required, it
should challenge the Subversion client for a username and
password. (When authorization is required, Apache requires
authentication as well.) What's missing here, however, are
directives that tell Apache which sorts
of client requests require authorization; currently, none do.
The simplest thing is to specify that all
requests require authorization by adding
Require valid-user
to the block:
<Location /svn> DAV svn SVNParentPath /var/svn # Authentication: Basic AuthName "Subversion repository" AuthType Basic AuthBasicProvider file AuthUserFile /etc/svn-auth.htpasswd # Authorization: Authenticated users only Require valid-user </Location>
Refer to the section called “Authorization Options”
for more detail on the Require
directive
and other ways to set authorization policies.
Note | |
---|---|
The default value of the
|
Digest authentication is an improvement on Basic authentication which allows the server to verify a client's identity without sending the password over the network unprotected. Both client and server create a non-reversible MD5 hash of the username, password, requested URI, and a nonce (number used once) provided by the server and changed each time authentication is required. The client sends its hash to the server, and the server then verifies that the hashes match.
Configuring Apache to use Digest authentication is straightforward. You'll need to ensure that the mod_auth_digest module is available (instead of mod_auth_basic), and then make a few small variations on our prior example:
<Location /svn> DAV svn SVNParentPath /var/svn # Authentication: Digest AuthName "Subversion repository" AuthType Digest AuthDigestProvider file AuthUserFile /etc/svn-auth.htdigest # Authorization: Authenticated users only Require valid-user </Location>
Notice that AuthType
is now set to
Digest
, and we specify a different path
for AuthUserFile
. Digest authentication
uses a different file format than Basic authentication,
created and managed using Apache's htdigest
utility[67] rather than htpasswd.
Digest authentication also has the additional concept of a
“realm”, which must match the value of the
AuthName
directive.
Note | |
---|---|
For Digest authentication, the authentication provider
is selected using the |
The password file can be created as follows:
$ ### First time: use -c to create the file $ htdigest -c /etc/svn-auth.htdigest "Subversion repository" harry Adding password for harry in realm Subversion repository. New password: ***** Re-type new password: ***** $ htdigest /etc/svn-auth.htdigest "Subversion repository" sally Adding user sally in realm Subversion repository New password: ******* Re-type new password: ******* $
At this point, you've configured authentication, but not authorization. Apache is able to challenge clients and confirm identities, but it has not been told how to allow or restrict access to the clients bearing those identities. This section describes two strategies for controlling access to your repositories.
The simplest form of access control is to authorize certain users for either read-only access to a repository or read/write access to a repository.
You can restrict access on all repository operations by
adding Require valid-user
directly inside
the <Location>
block. The example
from the section called “Digest authentication”
allows only clients that successfully authenticate to do
anything with the Subversion repository:
<Location /svn> DAV svn SVNParentPath /var/svn # Authentication: Digest AuthName "Subversion repository" AuthType Digest AuthUserFile /etc/svn-auth.htdigest # Authorization: Authenticated users only Require valid-user </Location>
Sometimes you don't need to run such a tight ship. For
example, the server hosting Subversion's own source code at
https://svn.apache.org/repos/asf/subversion/ allows
anyone in the world to perform read-only repository tasks (such as
checking out working copies and browsing the repository),
but restricts write operations to authenticated users. The
Limit
and LimitExcept
directives allow for this type of selective restriction.
Like the Location
directive, these blocks
have starting and ending tags, and you would nest them
inside your <Location>
block.
The parameters present on the Limit
and LimitExcept
directives are HTTP
request types that are affected by that block. For example,
to allow anonymous read-only operations, you would use the
LimitExcept
directive (passing the
GET
, PROPFIND
,
OPTIONS
, and REPORT
request type parameters) and place the previously mentioned
Require valid-user
directive inside the
<LimitExcept>
block instead of just
inside the <Location>
block.
<Location /svn> DAV svn SVNParentPath /var/svn # Authentication: Digest AuthName "Subversion repository" AuthType Digest AuthUserFile /etc/svn-auth.htdigest # Authorization: Authenticated users only for non-read-only # (write) operations; allow anonymous reads <LimitExcept GET PROPFIND OPTIONS REPORT> Require valid-user </LimitExcept> </Location>
These are only a few simple examples. For more in-depth
information about Apache access control and the
Require
directive, take a look at the
Security
section of the Apache
documentation's tutorials collection at https://httpd.apache.org/docs-2.0/misc/tutorials.html.
It's possible to set up finer-grained permissions using mod_authz_svn. This Apache module grabs the various opaque URLs passing from client to server, asks mod_dav_svn to decode them, and then possibly vetoes requests based on access policies defined in a configuration file.
If you've built Subversion from source code,
mod_authz_svn is automatically built
and installed alongside mod_dav_svn.
Many binary distributions install it automatically as well.
To verify that it's installed correctly, make sure it comes
right after mod_dav_svn's
LoadModule
directive in
httpd.conf
:
LoadModule dav_module modules/mod_dav.so LoadModule dav_svn_module modules/mod_dav_svn.so LoadModule authz_svn_module modules/mod_authz_svn.so
To activate this module, you need to configure your
<Location>
block to use the
AuthzSVNAccessFile
directive which specifies
a single file containing the permissions policy for paths within
your repositories. Beginning with Subversion 1.7, you can
also use AuthzSVNReposRelativeAccessFile
directive to specify a per repository access file.
(In a moment, we'll discuss the format of that file.)
Apache is flexible, so you have the option to configure your block in one of three general patterns. To begin, choose one of these basic configuration patterns. (The following examples are very simple; look at Apache's own documentation for much more detail on Apache authentication and authorization options.)
The most open approach is to allow access to everyone. This means Apache never sends authentication challenges, and all users are treated as “anonymous”. (See Example 6.2, “A sample configuration for anonymous access”.)
Example 6.2. A sample configuration for anonymous access
<Location /repos> DAV svn SVNParentPath /var/svn # Authentication: None # Authorization: Path-based access control AuthzSVNAccessFile /path/to/access/file </Location>
On the opposite end of the paranoia scale, you can
configure Apache to authenticate all clients.
This block unconditionally requires authentication via the
Require valid-user
directive, and defines
a means to authenticate valid users. (See
Example 6.3, “A sample configuration for authenticated access”.)
Example 6.3. A sample configuration for authenticated access
<Location /repos> DAV svn SVNParentPath /var/svn # Authentication: Digest AuthName "Subversion repository" AuthType Digest AuthUserFile /etc/svn-auth.htdigest # Authorization: Path-based access control; authenticated users only AuthzSVNAccessFile /path/to/access/file Require valid-user </Location>
A third very popular pattern is to allow a combination
of authenticated and anonymous access. For example, many
administrators want to allow anonymous users to read certain
repository directories, but restrict access to more
sensitive areas to authenticated users. In this setup, all
users start out accessing the repository anonymously. If
your access control policy demands a real username at any
point, Apache will demand authentication from the client.
To do this, use both the Satisfy Any
and Require valid-user
directives. (See
Example 6.4, “A sample configuration for mixed
authenticated/anonymous access”.)
Example 6.4. A sample configuration for mixed authenticated/anonymous access
<Location /repos> DAV svn SVNParentPath /var/svn # Authentication: Digest AuthName "Subversion repository" AuthType Digest AuthUserFile /etc/svn-auth.htdigest # Authorization: Path-based access control; try anonymous access # first, but authenticate if necessary AuthzSVNAccessFile /path/to/access/file Satisfy Any Require valid-user </Location>
The next step is to create the authorization file containing access rules for particular paths within the repository. We describe how later in this chapter, in the section called “Path-Based Authorization”.
The mod_dav_svn module goes through a
lot of work to make sure that data you've marked
“unreadable” doesn't get accidentally leaked.
This means it needs to closely monitor all of the paths
and file-contents returned by commands such as svn
checkout and svn update.
If these commands encounter a path that isn't
readable according to some authorization policy, the
path is typically omitted altogether. In the case of
history or rename tracing—for example, running a command such
as svn cat -r OLD foo.c
on a file that
was renamed long ago—the rename tracking will simply
halt if one of the object's former names is determined to be
read-restricted.
All of this path checking can sometimes be quite
expensive, especially in the case of svn
log. When retrieving a list of revisions, the
server looks at every changed path in each revision and
checks it for readability. If an unreadable path is
discovered, it's omitted from the list of the revision's
changed paths (normally seen with
the --verbose
(-v
) option),
and the whole log message is suppressed. Needless to say,
this can be time-consuming on revisions that affect a large
number of files. This is the cost of security: even if you
haven't configured a module such as
mod_authz_svn at all, the
mod_dav_svn module is still asking Apache
httpd to run authorization checks on
every path. The mod_dav_svn module has
no idea what authorization modules have been installed, so
all it can do is ask Apache to invoke whatever might be
present.
On the other hand, there's also an escape hatch of
sorts, which allows you to trade security features for
speed. If you're not enforcing any sort of per-directory
authorization (i.e., not using
mod_authz_svn or similar module),
you can disable all of this path checking. In your
httpd.conf
file, use the
SVNPathAuthz
directive as shown in
Example 6.5, “Disabling path checks altogether”.
Example 6.5. Disabling path checks altogether
<Location /repos> DAV svn SVNParentPath /var/svn SVNPathAuthz off </Location>
The SVNPathAuthz
directive
is “on” by default. When
set to “off,” all path-based authorization
checking is disabled;
mod_dav_svn stops invoking authorization
checks on every path it discovers.
Beginning with Subversion 1.8, access files can be stored inside a Subversion repository. It is possible to store the access file in the same repository to which the access rules are being applied, or you can store it in an entirely different repository. This approach enables versioning features of Subversion for the path-based authorization configuration.
Both AuthzSVNAccessFile
and
AuthzSVNReposRelativeAccessFile
configuration
directives allow to specify in-repository access file's location.
The directives accept absolute file://
URLs
and repository relative URLs (one which begins with
^/
).
For example, it is possible to specify an absolute URL to in-repository access file as shown in Example 6.6, “Using single versioned in repo access file”.
Example 6.6. Using single versioned in repo access file
<Location /repos> DAV svn SVNParentPath /var/svn AuthzSVNAccessFile file:///var/svn/authzrepo/authz </Location>
You can also specify a relative URL to an in repository access file as demonstrated in Example 6.7, “Using per repository in repo access files”.
Example 6.7. Using per repository in repo access files
<Location /repos> DAV svn SVNParentPath /var/svn AuthzSVNReposRelativeAccessFile ^/authz </Location>
Connecting to a repository via http://
means that all Subversion activity is sent across the network
in the clear. This means that actions such as checkouts,
commits, and updates could potentially be intercepted by an
unauthorized party “sniffing” network traffic.
Encrypting traffic using SSL is a good way to protect
potentially sensitive information over the network.
If a Subversion client is compiled to use OpenSSL,
it gains the ability to speak to an Apache server via
https://
URLs, so all traffic is encrypted
with a per-connection session key. The WebDAV library used by
the Subversion client is not only able to verify server
certificates, but can also supply client certificates when
challenged by the server.
It's beyond the scope of this book to describe how to generate client and server SSL certificates and how to configure Apache to use them. Many other references, including Apache's own documentation (https://httpd.apache.org/docs/current/ssl/), describe the process.
Tip | |
---|---|
SSL certificates from well-known entities generally cost money, but at a bare minimum, you can configure Apache to use a self-signed certificate generated with a tool such as OpenSSL (https://www.openssl.org).[68] |
When connecting to Apache via https://
,
a Subversion client can receive two different types of
responses:
A server certificate
A challenge for a client certificate
When the client receives a server certificate, it needs to verify that the server is who it claims to be. OpenSSL does this by examining the signer of the server certificate, or certificate authority (CA). If OpenSSL is unable to automatically trust the CA, or if some other problem occurs (such as an expired certificate or hostname mismatch), the Subversion command-line client will ask you whether you want to trust the server certificate anyway:
$ svn list https://host.example.com/repos/project Error validating server certificate for 'https://host.example.com:443': - The certificate is not issued by a trusted authority. Use the fingerprint to validate the certificate manually! Certificate information: - Hostname: host.example.com - Valid: from Jan 30 19:23:56 2004 GMT until Jan 30 19:23:56 2006 GMT - Issuer: CA, example.com, Sometown, California, US - Fingerprint: 7d:e1:a9:34:33:39:ba:6a:e9:a5:c4:22:98:7b:76:5c:92:a0:9c:7b (R)eject, accept (t)emporarily or accept (p)ermanently?
This dialogue is essentially the same question you may
have seen coming from your web browser (which is just
another HTTP client like Subversion). If you choose the
(p)
ermanent option, Subversion will
cache the server certificate in your private runtime
auth/
area, just as your username and
password are cached (see the section called “Caching credentials”), and will
automatically trust the certificate in the future.
Your runtime servers
file also gives
you the ability to make your Subversion client automatically
trust specific CAs, either globally or on a per-host basis.
Simply set the ssl-authority-files
variable to a semicolon-separated list of PEM-encoded CA
certificates:
[global] ssl-authority-files = /path/to/CAcert1.pem;/path/to/CAcert2.pem
Many OpenSSL installations also have a predefined set
of “default” CAs that are nearly universally
trusted. To make the Subversion client automatically trust
these standard authorities, set the
ssl-trust-default-ca
variable to
true
.
If the client receives a challenge for a certificate, the server is asking the client to prove its identity. The client must send back a certificate signed by a CA that the server trusts, along with a challenge response which proves that the client owns the private key associated with the certificate. The private key and certificate are usually stored in an encrypted format on disk, protected by a passphrase. When Subversion receives this challenge, it will ask you for the path to the encrypted file and the passphrase that protects it:
$ svn list https://host.example.com/repos/project Authentication realm: https://host.example.com:443 Client certificate filename: /path/to/my/cert.p12 Passphrase for '/path/to/my/cert.p12': ********
Notice that the client credentials are stored in a
.p12
file. To use a client certificate
with Subversion, it must be in PKCS#12 format, which is a
portable standard. Most web browsers are able to import
and export certificates in that format. Another option
is to use the OpenSSL command-line tools to convert
existing certificates into PKCS#12.
The runtime servers
file also
allows you to automate this challenge on a per-host basis.
If you set the ssl-client-cert-file
and ssl-client-cert-password
variables,
Subversion can automatically respond to a client
certificate challenge without prompting you:
[groups] examplehost = host.example.com [examplehost] ssl-client-cert-file = /path/to/my/cert.p12 ssl-client-cert-password = somepassword
More security-conscious folk might want to exclude
ssl-client-cert-password
to avoid
storing the passphrase in the clear on disk.
The Apache HTTP Server is built for performance, but you
can improve upon its default configuration to get even better
results out of your Subversion service offering. In this
section, we'll recommend some specific configuration changes
to consider. Understand, however, that some of
the httpd.conf
configuration options
we'll be discussing herein affect the general behavior of your
server, not merely the Subversion service. As such, you need
to consider the full breadth of your HTTP service offering to
discern how modifications to these settings for Subversion's
sake may affect your other services.
By default, the Apache HTTP Server is configured to
enable the re-use of a single server connection for multiple
requests. That's very beneficial for Subversion, because
unlike many HTTP-based applications, Subversion can very
quickly generate hundreds or thousands of requests against
the server for a single operation, and the cost of opening a
new connection to the server is non-trivial. Subversion
wants to squeeze as many requests as possible out of a
single connection before that connection is terminated by
the server. The KeepAlive
directive is the
boolean flag which enables or disables this connection
re-use facility, and as we indicated previously, by default
its value is On
.
But there's another directive which limits the number of
requests a client is allowed to submit on a single
connection: the MaxKeepAliveRequests
directive. The default value for that option
is 100
. This was probably sufficient for
older versions of Subversion, but Subversion 1.8 employs a
different HTTP communications library (called Serf) which
prefers to pipeline several smaller requests for specific bits
of information rather than asking the server to transmit
huge chunks of data in a single response. We recommend that
you increase the value of the
MaxKeepAliveRequests
option
to at least 1000
.
# # KeepAlive: Whether or not to allow persistent connections (more than # one request per connection). Set to "Off" to deactivate. # KeepAlive On # # MaxKeepAliveRequests: The maximum number of requests to allow # during a persistent connection. Set to 0 to allow an unlimited amount. # We recommend you leave this number high, for maximum performance. # MaxKeepAliveRequests 1000
The biggest difference between the way that Subversion
1.8 clients and pre-1.8 clients behave is in how update-style
operations (svn checkout, svn
update, svn switch, etc.) are
handled. Older clients which used the Neon HTTP library for
communications preferred to ask the server for the entire
payload of information required from the server in a single
request. Admins will have noticed that in their server
logs, there would be some initial handshaking operations,
and then a REPORT
request with a massive
response. That response was the entire checkout/update
dataset!
Subversion clients which use the Serf HTTP
library—which includes all clients built atop the
Subversion 1.8—still send the REPORT
request, but with slightly different flags set inside that
request. These flags ask the server not to send all the
data for the operation, but to instead send only a checklist
of other more specific things that the client needs to
subsequently fetch from the server in order to complete that
operation. In the server's access_log
,
that REPORT
is followed by many smaller
requests (GET
s and, in older versions of
Subversion, PROPFIND
s).
There are pros and cons to each approach. As we've
mentioned, the so-called bulk updates generate considerably
less information in the server logs, but a given Apache HTTP
Server child process is completely consumed for the duration
of what could be a lengthy operation. Non-bulk updates
offer opportunities for setting up content caches (which
themselves can improve performance), but generate server log
traffic which is whole orders of magnitude larger than the
bulk update approach. So, for one reason or another,
administrators may desire to exert a little more control
over which approach the clients use. Subversion 1.6
introduced the SVNAllowBulkUpdates
mod_dav_svn directive—a simple
boolean flag—to allow admins to specify whether the
server was allowed to honor bulk update requests. In
Subversion 1.8, this directive has expanded to include
a Prefer
value in addition to the
On
and Off
values it
already supported. When SVNAllowBulkUpdates
is set to Prefer
, supporting clients (1.8
or newer) will try to use the bulk update approach unless
otherwise configured.
We've covered most of the authentication and authorization options for Apache and mod_dav_svn. But there are a few other nice features that Apache provides.
One of the most useful benefits of an Apache/WebDAV
configuration for your Subversion repository is that your
versioned files and directories are immediately available
for viewing via a regular web browser. Since Subversion
uses URLs to identify versioned resources, those URLs used
for HTTP-based repository access can be typed directly into
a web browser. Your browser will issue an
HTTP GET
request for that URL; based on
whether that URL represents a versioned directory or
file, mod_dav_svn will respond with a
directory listing or with file contents.
If the URLs do not contain any information about which version of the resource you wish to see, mod_dav_svn will answer with the youngest version. This functionality has the wonderful side effect that you can pass around Subversion URLs to your peers as references to documents, and those URLs will always point at the latest manifestation of that document. Of course, you can even use the URLs as hyperlinks from other web sites, too.
As of Subversion 1.6, mod_dav_svn
supports a public URI syntax for examining older revisions
of both files and directories. The syntax uses the query
string portion of the URL to specify either or both of a
peg revision and operative revision, which Subversion will
then use to determine which version of the file or
directory to display to your web browser. Add the query
string name/value pair
p=
,
where PEGREV
PEGREV
is a revision
number, to specify the peg revision you wish to apply to the
request. Use
r=
,
where REV
REV
is a revision number, to
specify an operative revision.
For example, if you wish to see the latest version of a
README.txt
file located in your
project's /trunk
, point your web
browser to that file's repository URL, which might look
something like the following:
http://host.example.com/repos/project/trunk/README.txt
If you now wish to see some older version of that file, add an operative revision to the URL's query string:
http://host.example.com/repos/project/trunk/README.txt?r=1234
What if the thing you're trying to view no longer exists in the youngest revision of the repository? That's where a peg revision is handy:
http://host.example.com/repos/project/trunk/deleted-thing.txt?p=321
And of course, you can combine peg revision and operative revision specifiers to fine-tune the exact item you wish to view:
http://host.example.com/repos/project/trunk/renamed-thing.txt?p=123&r=21
The previous URL would display revision 21 of the
object which, in revision 123, was located
at /trunk/renamed-thing.txt
in the
repository. See the section called “Peg and Operative Revisions” for a
detailed explanation of these “peg revision”
and “operative revision” concepts. They can
be a bit tricky to wrap your head around.
Beginning with Subversion 1.8, mod_dav_svn
has the ability to substitute keywords. When
mod_dav_svn
finds the query argument kw=1
added to
the URL of a file, it will expand keywords when delivering
the file's content. Omitting the kw
parameter or using any value besides 1
for that parameter will cause Subversion to use its
default behavior, which is to deliver the file's content
without any keywords expanded.
Because keyword substitution is typically performed by the Subversion client as part of its working copy administration and management, this is a handy way to get the server to deliver a keyword-expanded form of your versioned file without the use of a working copy.
For example, if you wish to see the latest version of a
README.txt
file located in your
project's /trunk
with keywords
expanded, add the query argument kw=1
to the
URL:
http://host.example.com/repos/project/trunk/README.txt?kw=1
As with client-side keyword expansion, only those keywords
which are explicitly designated for expansion via the
svn:keywords
property set on the file itself
will be expanded. See
the section called “Keyword Substitution” for a
detailed description of the keyword substitution feature.
As a reminder, mod_dav_svn offers only a limited repository browsing experience. You can see directory listings and file contents, but no revision properties (such as commit log messages) or file/directory properties. For folks who require more extensive browsing of repositories and their history, there are several third-party software packages which offer this. Some examples include ViewVC (https://viewvc.org), Trac (https://trac.edgewall.org) and WebSVN (https://websvnphp.github.io). These third-party tools don't affect mod_dav_svn's built-in “browseability”, and generally offer a much wider set of features, including the display of the aforementioned property sets, display of content differences between file revisions, and so on.
When browsing a Subversion repository, the web browser
gets a clue about how to render a file's contents by
looking at the Content-Type:
header
returned in Apache's response to the
HTTP GET
request. The value of this
header is some sort of MIME type. By default, Apache will
tell the web browsers that all repository files are of
the “default” MIME type,
typically text/plain
. This can be
frustrating, however, if a user wishes repository files to
render as something more meaningful—for example,
it might be nice to have a foo.html
file
in the repository actually render as HTML when
browsing.
To make this happen, you need only to make sure that
your files have the proper svn:mime-type
set. We discuss this in more detail in
the section called “File Content Type”,
and you can even configure your client to automatically
attach proper svn:mime-type
properties
to files entering the repository for the first time; see
the section called “Automatic Property Setting”.
Continuing our example, if one were to set
the svn:mime-type
property
to text/html
on
file foo.html
, Apache would properly
tell your web browser to render the file as HTML. One
could also attach proper image/*
MIME-type properties to image files and ultimately get an
entire web site to be viewable directly from a repository!
There's generally no problem with this, as long as the web
site doesn't contain any dynamically generated
content.
You generally will get more use out of URLs to
versioned files—after all, that's where the
interesting content tends to lie. But you might have
occasion to browse a Subversion directory listing, where
you'll quickly note that the generated HTML used to
display that listing is very basic, and certainly not
intended to be aesthetically pleasing (or even
interesting). To enable customization of these directory
displays, Subversion provides an XML index feature. A
single SVNIndexXSLT
directive in your
repository's Location
block of
httpd.conf
will
instruct mod_dav_svn to generate XML
output when displaying a directory listing, and to
reference the XSLT stylesheet of your choice:
<Location /svn> DAV svn SVNParentPath /var/svn SVNIndexXSLT "/svnindex.xsl" … </Location>
Using the SVNIndexXSLT
directive
and a creative XSLT stylesheet, you can make your
directory listings match the color schemes and imagery
used in other parts of your web site. Or, if you'd
prefer, you can use the sample stylesheets provided in the
Subversion source distribution's
tools/xslt/
directory.
Keep in mind that the path provided to the
SVNIndexXSLT
directive is actually a
URL path—browsers need to be able to read your
stylesheets to make use of them!
If you're serving a collection of repositories from a
single URL via the SVNParentPath
directive, then it's also possible to have Apache display
all available repositories to a web browser. Just
activate the SVNListParentPath
directive:
<Location /svn> DAV svn SVNParentPath /var/svn SVNListParentPath on … </Location>
If a user now points her web browser to the
URL http://host.example.com/svn/
,
she'll see a list of all Subversion repositories sitting
in /var/svn
. Obviously, this can be
a security problem, so this feature is turned off by
default.
Because Apache is an HTTP server at heart, it contains
fantastically flexible logging features. It's beyond the
scope of this book to discuss all of the ways logging can be
configured, but we should point out that even the most
generic httpd.conf
file will cause
Apache to produce two logs:
error_log
and access_log
. These logs may appear
in different places, but are typically created in the
logging area of your Apache installation. (On Unix, they
often live
in /usr/local/apache2/logs/
.)
The error_log
describes any internal
errors that Apache runs into as it works.
The access_log
file records every
incoming HTTP request received by Apache. This makes it
easy to see, for example, which IP addresses Subversion
clients are coming from, how often particular clients use
the server, which users are authenticating properly, and
which requests succeed or fail.
Unfortunately, because HTTP is a stateless protocol,
even the simplest Subversion client operation generates
multiple network requests. It's very difficult to look at
the access_log
and deduce what the
client was doing—most operations look like a series
of cryptic PROPPATCH
, GET
,
PUT
, and REPORT
requests. To make things worse, many client operations send
nearly identical series of requests, so it's even harder to
tell them apart.
mod_dav_svn, however, can come to your aid. By activating an “operational logging” feature, you can ask mod_dav_svn to create a separate log file describing what sort of high-level operations your clients are performing.
To do this, you need to make use of
Apache's CustomLog
directive (which is
explained in more detail in Apache's own documentation).
Be sure to invoke this
directive outside your
Subversion Location
block:
<Location /svn> DAV svn … </Location> CustomLog logs/svn_logfile "%t %u %{SVN-ACTION}e" env=SVN-ACTION
In this example, we're asking Apache to create a special
logfile, svn_logfile
, in the standard
Apache logs
directory.
The %t
and %u
variables are replaced by the time and username of the
request, respectively. The really important parts are the
two instances of SVN-ACTION
.
When Apache sees that variable, it substitutes the value of
the SVN-ACTION
environment variable,
which is automatically set by mod_dav_svn
whenever it detects a high-level client action.
So, instead of having to interpret a
traditional access_log
like
this:
[26/Jan/2007:22:25:29 -0600] "PROPFIND /svn/calc/!svn/vcc/default HTTP/1.1" 207 398 [26/Jan/2007:22:25:29 -0600] "PROPFIND /svn/calc/!svn/bln/59 HTTP/1.1" 207 449 [26/Jan/2007:22:25:29 -0600] "PROPFIND /svn/calc HTTP/1.1" 207 647 [26/Jan/2007:22:25:29 -0600] "REPORT /svn/calc/!svn/vcc/default HTTP/1.1" 200 607 [26/Jan/2007:22:25:31 -0600] "OPTIONS /svn/calc HTTP/1.1" 200 188 [26/Jan/2007:22:25:31 -0600] "MKACTIVITY /svn/calc/!svn/act/e6035ef7-5df0-4ac0-b811-4be7c823f998 HTTP/1.1" 201 227 …
you can peruse a much more
intelligible svn_logfile
like
this:
[26/Jan/2007:22:24:20 -0600] - get-dir /tags r1729 props [26/Jan/2007:22:24:27 -0600] - update /trunk r1729 depth=infinity [26/Jan/2007:22:25:29 -0600] - status /trunk/foo r1729 depth=infinity [26/Jan/2007:22:25:31 -0600] sally commit r1730
In addition to the SVN-ACTION
environment variable, mod_dav_svn also
populates the SVN-REPOS
and SVN-REPOS-NAME
variables, which carry
the filesystem path to the repository and the basename
thereof, respectively. You might wish to include references
to one or both of these variables in
your CustomLog
format string, too,
especially if you are combining usage information from
multiple repositories into a single log file. For an
exhaustive list of all actions logged, see
the section called “High-level Logging”.
Obviously, the more information that Apache logs about your Subversion activities, the more disk space on your server those logs consume. It is non uncommon for high-traffic Subversion servers to generate many gigabytes of log information daily. Obviously, logs are only valuable if they can be meaningfully processed, and huge log files can quickly become unwieldy. There are various standard approaches to Apache HTTP Server log management which are outside the scope of this book. Administrators are encouraged to use the log rotation and archival approach which works best for them.
But what if Subversion is simply generating too much log information to be useful? For example, in the section called “Bulk updates”, we mentioned that certain approaches that Subversion clients may take to checkouts and other update-style operations can cause rapid growth of your server logs as requests for individual pieces of the update data set are individually logged (whereas in previous version of Subversion, they might not have been). In this case, you might consider using some Apache configuration magic to selectively silence some of that log activity.
Apache HTTP Server's
mod_setenvif module offers
a SetEnvIf
directive which is handy for
conditionally setting environment variables. And as it
turns out, the CustomLog
directive can be
told to conditionally log requests based on the state of
environment variables. The following is a sample
configuration which instructs the server
to not log GET
and PROPFIND
requests aimed at private
Subversion URLs.
# Matches everything, just to initialize the "in_repos" variable. SetEnvIf Request_URI "^" in_repos=0 # Set "in_repos" if this is a request for a private Subversion URL. SetEnvIf Request_URI "/!svn/" in_repos=1 # Set "do_not_log" for non-public request types we don't care to log. SetEnvIf Request_Method "GET" do_not_log SetEnvIf Request_Method "PROPFIND" do_not_log # Unset "do_not_log" for URLs that aren't private Subversion URLs. SetEnvIf in_repos 0 !do_not_log # Log requests, but only if "do_not_log" isn't set. CustomLog logs/access_log env=!do_not_log
Using this configuration, httpd would
still log GET
requests aimed at public
Subversion URLs. These are the sorts of requests generated
by a web browser as someone navigates the repository
directly. But GET
and PROPFIND
requests aimed at so-called
“private” Subversion URLs—which are the very sorts of
requests used to fetch each and every individual file during
a checkout operation—won't get logged.
One of the nice advantages of using Apache as a Subversion server is that it can be set up for simple replication. For example, suppose that your team is distributed across four offices around the globe. The Subversion repository can exist only in one of those offices, which means the other three offices will not enjoy accessing it—they're likely to experience significantly slower traffic and response times when updating and committing code. A powerful solution is to set up a system consisting of one master Apache server and several slave Apache servers. If you place a slave server in each office, users can check out a working copy from whichever slave is closest to them. All read requests go to their local slave. Write requests get automatically routed to the single master server. When the commit completes, the master then automatically “pushes” the new revision to each slave server using the svnsync replication tool.
This configuration creates a huge perceptual speed increase for your users, because Subversion client traffic is typically 80–90% read requests. And if those requests are coming from a local server, it's a huge win.
In this section, we'll walk you through a standard setup of this single-master/multiple-slave system. However, keep in mind that your servers must be running at least Apache 2.2.0 (with mod_proxy loaded) and Subversion 1.5 (mod_dav_svn).
Note | |
---|---|
Ours is just one example of how you might setup a Subversion write-through proxy configuration. There are other approaches. For example, rather than having the master server push changes out to every slave server, the slaves could periodically pull those changes from the master. Or perhaps the master could push changes to a single slave, which then pushes the same change to the next slave, and so on down the line. Administrators are encouraged to use this section for basic understanding of what happens in a Subversion WebDAV proxy deployment scenario, and then implement the specific approach that works best for their organization. |
First, configure your master server's
httpd.conf
file in the usual way.
Make the repository available at a certain URI location,
and configure authentication and authorization however
you'd like. After that's done, configure each of your
“slave” servers in the exact same way, but
add the special SVNMasterURI
directive
to the block:
<Location /svn> DAV svn SVNPath /var/svn/repos SVNMasterURI http://master.example.com/svn … </Location>
This new directive tells a slave server to redirect all write requests to the master. (This is done automatically via Apache's mod_proxy module.) Ordinary read requests, however, are still serviced by the slaves. Be sure that your master and slave servers all have matching authentication and authorization configurations; if they fall out of sync, it can lead to big headaches.
Next, we need to deal with the problem of infinite recursion. With the current configuration, imagine what will happen when a Subversion client performs a commit to the master server. After the commit completes, the server uses svnsync to replicate the new revision to each slave. But because svnsync appears to be just another Subversion client performing a commit, the slave will immediately attempt to proxy the incoming write request back to the master! Hilarity ensues.
The solution to this problem is to have the master
push revisions to a different
<Location>
on the slaves. This
location is configured to not proxy
write requests at all, but to accept normal commits from
(and only from) the master's IP address:
<Location /svn-proxy-sync> DAV svn SVNPath /var/svn/repos Order deny,allow Deny from all # Only let the server's IP address access this Location: Allow from 10.20.30.40 … </Location>
Now that you've configured
your Location
blocks on master and
slaves, you need to configure the master to replicate to
the slaves. Our walkthough uses svnsync,
which is covered in more detail in
the section called “Replication with svnsync”.
First, make sure that each slave repository has a pre-revprop-change hook script which allows remote revision property changes. (This is standard procedure for being on the receiving end of svnsync.) Then log into the master server and configure each of the slave repository URIs to receive data from the master repository on the local disk:
$ svnsync init http://slave1.example.com/svn-proxy-sync \ file:///var/svn/repos Copied properties for revision 0. $ svnsync init http://slave2.example.com/svn-proxy-sync \ file:///var/svn/repos Copied properties for revision 0. $ svnsync init http://slave3.example.com/svn-proxy-sync \ file:///var/svn/repos Copied properties for revision 0. # Perform the initial replication $ svnsync sync http://slave1.example.com/svn-proxy-sync \ file:///var/svn/repos Transmitting file data .... Committed revision 1. Copied properties for revision 1. Transmitting file data ....... Committed revision 2. Copied properties for revision 2. … $ svnsync sync http://slave2.example.com/svn-proxy-sync \ file:///var/svn/repos Transmitting file data .... Committed revision 1. Copied properties for revision 1. Transmitting file data ....... Committed revision 2. Copied properties for revision 2. … $ svnsync sync http://slave3.example.com/svn-proxy-sync \ file:///var/svn/repos Transmitting file data .... Committed revision 1. Copied properties for revision 1. Transmitting file data ....... Committed revision 2. Copied properties for revision 2. …
After this is done, we configure the master server's post-commit hook script to invoke svnsync on each slave server:
#!/bin/sh # Post-commit script to replicate newly committed revision to slaves svnsync sync http://slave1.example.com/svn-proxy-sync \ file:///var/svn/repos > /dev/null 2>&1 & svnsync sync http://slave2.example.com/svn-proxy-sync \ file:///var/svn/repos > /dev/null 2>&1 & svnsync sync http://slave3.example.com/svn-proxy-sync \ file:///var/svn/repos > /dev/null 2>&1 &
The extra bits on the end of each line aren't necessary, but they're a sneaky way to allow the sync commands to run in the background so that the Subversion client isn't left waiting forever for the commit to finish. In addition to this post-commit hook, you'll need a post-revprop-change hook as well so that when a user, say, modifies a log message, the slave servers get that change also:
#!/bin/sh # Post-revprop-change script to replicate revprop-changes to slaves REV=${2} svnsync copy-revprops http://slave1.example.com/svn-proxy-sync \ file:///var/svn/repos \ -r ${REV} > /dev/null 2>&1 & svnsync copy-revprops http://slave2.example.com/svn-proxy-sync \ file:///var/svn/repos \ -r ${REV} > /dev/null 2>&1 & svnsync copy-revprops http://slave3.example.com/svn-proxy-sync \ file:///var/svn/repos \ -r ${REV} > /dev/null 2>&1 &
The only thing we've left out here is what to do about user-level locks (of the svn lock variety). Locks are enforced by the master server during commit operations; but all the information about locks is distributed during read operations such as svn update and svn status by the slave server. As such, a fully functioning proxy setup needs to perfectly replicate lock information from the master server to the slave servers. Unfortunately, most of the mechanisms that one might employ to accomplish this replication fall short in one way or another[69]. Many teams don't use Subversion's locking features at all, so this may be a nonissue for you. Sadly, for those teams which do use locks, we have no recommendations on how to gracefully work around this shortcoming.
Your master/slave replication system should now be ready to use. A couple of words of warning are in order, however. Remember that this replication isn't entirely robust in the face of computer or network crashes. For example, if one of the automated svnsync commands fails to complete for some reason, the slaves will begin to fall behind. For example, your remote users will see that they've committed revision 100, but then when they run svn update, their local server will tell them that revision 100 doesn't yet exist! Of course, the problem will be automatically fixed the next time another commit happens and the subsequent svnsync is successful—the sync will replicate all waiting revisions. But still, you may want to set up some sort of out-of-band monitoring to notice synchronization failures and force svnsync to run when things go wrong.
Another limitation of the write-through proxy deployment model involves version mismatches—of the version of Subversion which is installed, that is—between the master and slave servers. Each new release of Subversion may (and often does) add new features to the network protocol used between the clients and servers. Since feature negotiation happens against the slave, it is the slave's protocol version and feature set which is used. But write operations are passed through to the master server quite literally. Therefore, there is a risk that the slave server will answer a feature negotiation request from the client in way that is true for the slave, but untrue for the master if the master is running an older version of Subversion. This could result in the client trying to use a new feature that the master doesn't understand, and failing.
Subversion 1.8 helps to mitigate this problem via the
introduction of a new Apache configuration
directive, SVNMasterVersion
. By
configuring each of your slave servers
with SVNMasterVersion
set to the
release version of the Subversion instance which is
running on your master server, the slave servers can more
accurately negotiate feature support with the
client.
Unfortunately, Subversion 1.7 doesn't offer
the SVNMasterVersion
configuration
directive and is known to have some specific problems
along these lines. If you are deploying a Subversion 1.7
slave server in front of a pre-1.7 master, you'll want to
configure your slave server's
Subversion <Location>
block with
the SVNAdvertiseV2Protocol Off
directive.
Tip | |
---|---|
For the best results possible, try to run the same version of Subversion on your master and slave servers. |
Several of the features already provided by Apache in
its role as a robust web server can be leveraged for
increased functionality or security in Subversion as well.
The Subversion client is able to use SSL (the Secure Sockets
Layer, discussed earlier). If your Subversion client is
built to support SSL, it can access your Apache server
using https://
and enjoy a high-quality
encrypted network session.
Equally useful are other features of the Apache and Subversion relationship, such as the ability to specify a custom port (instead of the default HTTP port 80) or a virtual domain name by which the Subversion repository should be accessed, or the ability to access the repository through an HTTP proxy.
Finally, because mod_dav_svn is speaking a subset of the WebDAV/DeltaV protocol, it's possible to access the repository via third-party DAV clients. Most modern operating systems (Win32, OS X, and Linux) have the built-in ability to mount a DAV server as a standard network “shared folder.” This is a complicated topic, but also wondrous when implemented. For details, read Appendix C, WebDAV and Autoversioning.
Note that there are a number of other small tweaks one
can make to mod_dav_svn that perhaps do
not merit extensive coverage. For those interested,
however, we provide a complete list of
all httpd.conf
directives
to which mod_dav_svn responds in
the section called “mod_dav_svn configuration directives”.
In the previous sections, we've mentioned numerous
directives that administrators can use in their
httpd.conf
files to enable and configure
their Subversion server offering, introducing each directive
as we also introduce the functionality it toggles. In this
section, we'll quickly summarize all the
configuration directives supported by both of the Apache HTTP
Server modules which are provided as part of the standard
Subversion distribution.
The following configuration directives are recognized and supported by Subversion's Apache HTTP Server module, mod_dav_svn.
DAV svn
Must be included in any
Directory
or Location
block for a Subversion repository. It
tells httpd to use the Subversion
backend for mod_dav to handle all
requests.
SVNActivitiesDB
directory-path
Specifies the location in the filesystem where the
activities database should be stored. By default,
mod_dav_svn creates and uses a
directory in the repository
called dav/activities.d
. The
path specified with this option must be an absolute
path.
If specified for
an SVNParentPath
area, mod_dav_svn appends the
basename of the repository to the path specified here.
For example:
<Location /svn> DAV svn # any "/svn/foo" URL will map to a repository in # /net/svn.nfs/repositories/foo SVNParentPath "/net/svn.nfs/repositories" # any "/svn/foo" URL will map to an activities db in # /var/db/svn/activities/foo SVNActivitiesDB "/var/db/svn/activities" </Location>
SVNAdvertiseV2Protocol On|Off
New to Subversion 1.7, this toggles
whether mod_dav_svn advertises its
support for the new version of its HTTP protocol also
introduced in that version. Most admins will not wish
to use this directive (which is On
by default), choosing instead to enjoy the performance
benefits that the new protocol offers. However, when
configuring a server as a write-through proxy to
another server which does not support the new
protocol, set this directive's value
to Off
.
SVNAllowBulkUpdates On|Off|Prefer
Toggles support for all-inclusive responses to
update-style requests. Subversion clients use
REPORT
requests to get information
about directory tree checkouts and updates from
mod_dav_svn. They can ask the
server to send that information in one of two ways:
with the entirety of the tree's information in one
massive (bulk) response, or with a
skelta (a skeletal
representation of a tree delta) which contains just
enough information for the client to know what
additional data to fetch from the
server using subsequent requests. When this directive
is included with a value of Off
,
mod_dav_svn will only ever respond
to these REPORT
requests with
skelta responses, regardless of the type of responses
requested by the client.
The default value of this directive is
On
, which permits the server to
reply to update requests using the style of response
(bulk or skelta) requested by the client. Beginning
in Subversion 1.8, this directive also accepts a value
of Prefer
, which is similar
to On
but additionally causes the
server to announce to clients that it
prefers to handle bulk update
requests.
Most folks won't need to use this directive at
all. It primarily exists for administrators who
wish—for security or auditing reasons—to
force Subversion clients to fetch individually all the
files and directories needed for updates and
checkouts, thus leaving an audit trail of
GET
and PROPFIND
requests in Apache's logs.
SVNAutoversioning On|Off
When its value is
On
, allows write requests from
WebDAV clients to result in automatic commits. A
generic log message is auto-generated and attached to
each revision. If you enable autoversioning, you'll
likely want to set ModMimeUsePathInfo
On
so that mod_mime can
set svn:mime-type
to the correct
MIME type automatically (as best as
mod_mime is able to, of course).
For more information, see Appendix C, WebDAV and Autoversioning. The default value of this
directive is Off
.
SVNCacheFullTexts On|Off
When set to On
, this tells
Subversion to cache content fulltexts if sufficient
in-memory cache is available, which could offer a
significant performance benefit to the server. (See
also the SVNInMemoryCacheSize
directive.) The default value of this directive
is Off
.
SVNCacheTextDeltas On|Off
When set to On
, this tells
Subversion to cache content deltas if sufficient
in-memory cache is available, which could offer a
significant performance benefit to the server. (See
also the SVNInMemoryCacheSize
directive.) The default value of this directive
is Off
.
SVNCompressionLevel
level
Specifies the compression level used when sending
file content over the network. A value
of 0
disables compression
altogether, and 9
is the maximum
value. 5
is the default
value.
SVNHooksEnv
file-path
Specifies the location of the Subversion repository hook script environment configuration file. This file is used to describe the initial environment in which repository hook scripts are executed. For more on this feature, see the section called “Hook script environment configuration”.
SVNIndexXSLT
directory-path
Specifies the URI of an XSL transformation for directory indexes. This directive is optional.
SVNInMemoryCacheSize
size
Specifies the maximum size (in kbytes) per process
of Subversion's in-memory object cache. The default
value is 16384
; use a value
of 0
to deactivate this cache
altogether.
SVNListParentPath On|Off
When set to On
, allows
a GET
of SVNParentPath
, which results in
a listing of all repositories under that path. The
default setting is
Off
.
SVNMasterURI
url
Specifies a URI to the master Subversion repository (used for a write-through proxy).
SVNMasterVersion
X.Y
Specifies the release version number of the Subversion instance which is serving the master repository (used for a write-through proxy).
SVNParentPath
directory-path
Specifies the location in the filesystem of a
parent directory whose child directories are
Subversion repositories. In a configuration block for
a Subversion repository, either this directive or
SVNPath
must be present, but not
both.
SVNPath
directory-path
Specifies the location in the
filesystem for a Subversion repository's files. In a
configuration block for a Subversion repository,
either this directive or
SVNParentPath
must be present, but
not both.
SVNPathAuthz On|Off|short_circuit
Controls path-based authorization by enabling
subrequests (On
), disabling
subrequests (Off
; see the section called “Disabling path-based checks”),
or querying mod_authz_svn directly
(short_circuit
). The default
value of this directive is On
.
SVNReposName
name
Specifies the name of a Subversion repository for
use in HTTP GET
responses. This
value will be prepended to the title of all directory
listings (which are served when you navigate to a
Subversion repository with a web browser). This
directive is optional.
Note | |
---|---|
Subversion will not use the repository name as configured via this directive when trying to match rules in access control files. The repository names used in that file's syntax are always derived from the repository URL. See the section called “Getting Started with Path-Based Access Control” for details. |
SVNSpecialURI
component
Specifies the URI component (namespace) for
special Subversion resources. The default is
!svn
, and most
administrators will never use this directive. Set
this only if there is a pressing need to have a file
named !svn
in your repository.
If you change this on a server already in use, it will
break all of the outstanding working copies, and your
users will hunt you down with pitchforks and flaming
torches.
SVNUseUTF8 On|Off
When set to On
,
mod_dav_svn will communicate with
hook scripts using repository root paths encoded in
UTF-8, and will expect those scripts to likewise
generate output (such as error messages) encoded in
UTF-8. The default value of this option
is Off
, which means
that mod_dav_svn assumes a 7-bit
ASCII encoding for its hook script interactions. This
option is available as of Subversion 1.8.
Note | |
---|---|
Administrators should ensure that the character set and encoding expectations of hook scripts match all the ways they might be invoked. For example, if one repository is served by both httpd and svnserve, svnserve should also be configured to use UTF-8 (by setting an appropriate locale in its environment) if this option is enabled for mod_dav_svn. Also, local filesystem paths containing non-ASCII characters which will be accessed by those scripts (such as repository root paths) must be properly encoded in the filesystem to match the scripts' expectations. |
The following configuration directives are provided by mod_authz_svn, Subversion's path-based authorization Apache HTTP Server module. For an in-depth description of using path-based authorization in Subversion, see the section called “Path-Based Authorization”.
AuthzForceUsernameCase Upper|Lower
Set to Upper
or Lower
to perform case conversion
of the specified sort on the authenticated username
before checking it for authorization. While usernames
are compared in a case-sensitive fashion against those
referenced in the authorization rules file, this
directive can at least normalize variably-cased
usernames into something consistent.
AuthzSVNAccessFile
file-path
Consult file-path
for
access rules describing the permissions for paths in
Subversion repository. In a configuration
block for a Subversion repository or a colletion of repositories,
either this directive or
AuthzSVNReposRelativeAccessFile
can be
present, but not both.
Beginning with Subversion 1.8,
AuthzSVNAccessFile
accepts a URL to a file
stored inside a Subversion repository—either the
same repository to which the access rules are
being applied, or an entirely different repository.
AuthzSVNAnonymous On|Off
Set to Off
to disable two
special-case behaviours of this module: interaction
with the Satisfy Any
directive and
enforcement of the authorization policy even when no
Require
directives are present.
The default value of this directive is
On
.
AuthzSVNAuthoritative On|Off
Set to Off
to allow access
control to be passed along to lower modules. The
default value of this directive is
On
.
AuthzSVNNoAuthWhenAnonymousAllowed On|Off
Set to On
to suppress
authentication and authorization for requests which
anonymous users are allowed to perform. The default
value of this directive is
On
.
AuthzSVNReposRelativeAccessFile
file-path
Consult file-path
for
access rules describing the permissions for paths in
Subversion repository. Unlike
AuthzSVNAccessFile
, the path specified
for AuthzSVNReposRelativeAccessFile
is
relative to the conf/
directory in
the repository on
filesystem. In other words, the file-path
specifies a per repository file that must be accessible by
the relative path for all repositories in a configuration block.
In a configuration block for a Subversion repository or a collection
of repositories either this directive or
AuthzSVNAccessFile
can be present, but not both.
This option is available as of Subversion 1.7.
Beginning with Subversion 1.8,
AuthzSVNReposRelativeAccessFile
accepts a
URL to a file
stored inside a Subversion repository—either the
same repository to which the access rules are
being applied, or an entirely different repository.
[65] They really hate doing that.
[68] While self-signed certificates are still vulnerable to a “man-in-the-middle” attack (before a client sees the certificate for the first time), such an attack is much more difficult for a casual observer to pull off, compared to sniffing unprotected passwords.
[69] https://subversion.apache.org/issue3457 tracks these problems.