.. sockets:

Module architecture
^^^^^^^^^^^^^^^^^^^

Sockets
=======

The idea behind the pyroute2 framework is pretty simple. The
library provides socket objects, that have:

* shortcuts to establish netlink connections
* extra methods to run netlink queries
* some magic to handle packet bursts
* another magic to transparently mangle netlink messages

In other sense any netlink socket is just an ordinary socket
with `fileno()`, `recv()`, `sendto()` etc. Of course, one
can use it in `poll()`.

There is an inheritance diagram of netlink sockets, provided
by the library:

.. inheritance-diagram:: pyroute2.iproute.linux.IPRoute
    pyroute2.iproute.linux.IPBatch
    pyroute2.iproute.linux.RawIPRoute
    pyroute2.iproute.bsd.IPRoute
    pyroute2.iproute.RemoteIPRoute
    pyroute2.iwutil.IW
    pyroute2.ipset.IPSet
    pyroute2.netlink.taskstats.TaskStats
    pyroute2.netlink.ipq.IPQSocket
    pyroute2.remote.RemoteSocket
    pyroute2.remote.shell.ShellIPR
    pyroute2.netns.nslink.NetNS
    :parts: 1

under the hood
--------------

Let's assume we use an `IPRoute` object to get the
interface list of the system::

    from pyroute2 import IPRoute
    ipr = IPRoute()
    ipr.get_links()
    ipr.close()

The `get_links()` method is provided by the `IPRouteMixin`
class. It chooses the message to send (`ifinfmsg`), prepares
required fields and passes it to the next layer::

    result.extend(self.nlm_request(msg, RTM_GETLINK, msg_flags))

The `nlm_request()` is a method of the `NetlinkMixin` class.
It wraps the pair request/response in one method. The request
is done via `put()`, response comes with `get()`. These
methods hide under the hood the asynchronous nature of the
netlink protocol, where the response can come whenever --
the time and packet order are not guaranteed. But one can
use the `sequence_number` field of a netlink message to
match responses, and the pair `put()/get()` does it.

cache thread
------------

Sometimes it is preferrable to get incoming messages asap
and parse them only when there is time for that. For that
case the `NetlinkMixin` provides a possibility to start a
dedicated cache thread, that will collect and queue incoming
messages as they arrive. The thread doesn't affect the
socket behaviour: it will behave exactly in the same way,
the only difference is that `recv()` will return already
cached in the userspace message. To start the thread,
one should call `bind()` with `async_cache=True`::

    ipr = IPRoute()
    ipr.bind(async_cache=True)
    ...  # do some stuff
    ipr.close()

message mangling
----------------

An interesting feature of the `IPRSocketMixin` is a netlink
proxy code, that allows to register callbacks for different
message types. The callback API is simple. The callback
must accept the message as a binary data, and must return
a dictionary with two keys, `verdict` and `data`. The
verdict can be:

    * for `sendto()`: `forward`, `return` or `error`
    * for `recv()`: `forward` or `error`

E.g.::

    msg = ifinfmsg(data)
    msg.decode()
    ...  # mangle msg
    msg.reset()
    msg.encode()
    return {'verdict': 'forward',
            'data': msg.buf.getvalue()}

The `error` verdict raises an exception from `data`. The
`forward` verdict causes the `data` to be passed. The
`return` verdict is valid only in `sendto()` callbacks and
means that the `data` should not be passed to the kernel,
but instead it must be returned to the user.

This magic allows the library to transparently support
ovs, teamd, tuntap calls via netlink. The corresponding
callbacks transparently route the call to an external
utility or to `ioctl()` API.

How to register callbacks, see `IPRSocketMixin` init.
The `_sproxy` serves `sendto()` mangling, the `_rproxy`
serves the `recv()` mangling. Later this API can become
public.

Netlink messages
================

To handle the data going through the sockets, the library
uses different message classes. To create a custom message
type, one should inherit:

    * `nlmsg` to create a netlink message class
    * `genlmsg` to create generic netlink message class
    * `nla` to create a NLA class

The messages hierarchy:

.. inheritance-diagram:: pyroute2.netlink.rtnl.ndmsg.ndmsg
    pyroute2.netlink.rtnl.tcmsg.tcmsg
    pyroute2.netlink.rtnl.rtmsg.rtmsg
    pyroute2.netlink.rtnl.fibmsg.fibmsg
    pyroute2.netlink.rtnl.ifaddrmsg.ifaddrmsg
    pyroute2.netlink.rtnl.ifinfmsg.ifinfmsg
    pyroute2.netlink.rtnl.ifinfmsg.ifinfveth
    pyroute2.netlink.taskstats.taskstatsmsg
    pyroute2.netlink.taskstats.tcmd
    pyroute2.netlink.ctrlmsg
    pyroute2.netlink.nl80211.nl80211cmd
    pyroute2.netlink.nfnetlink.ipset.ipset_msg
    pyroute2.netlink.ipq.ipq_mode_msg
    pyroute2.netlink.ipq.ipq_packet_msg
    pyroute2.netlink.ipq.ipq_verdict_msg
    :parts: 1

PF_ROUTE messages
=================

PF_ROUTE socket is used to receive notifications from the BSD
kernel. The PF_ROUTE messages:

.. inheritance-diagram:: pyroute2.bsd.pf_route.freebsd.bsdmsg
    pyroute2.bsd.pf_route.freebsd.if_msg
    pyroute2.bsd.pf_route.freebsd.rt_msg_base
    pyroute2.bsd.pf_route.freebsd.ifa_msg_base
    pyroute2.bsd.pf_route.freebsd.ifma_msg_base
    pyroute2.bsd.pf_route.freebsd.if_announcemsg
    pyroute2.bsd.pf_route.rt_slot
    pyroute2.bsd.pf_route.rt_msg
    pyroute2.bsd.pf_route.ifa_msg
    pyroute2.bsd.pf_route.ifma_msg
    :parts: 1

IPDB
====

The `IPDB` module implements high-level logic to manage
some of the system network settings. It is completely
agnostic to the netlink object's nature, the only requirement
is that the netlink transport must provide RTNL API.

So, using proper mixin classes one can create a custom
RTNL-compatible transport. E.g., this way `IPDB` can work
over `NetNS` objects, providing the network management
within some network namespace — while itself it runs in the
main namespace.

The `IPDB` architecture is not too complicated, but it
implements some useful transaction magic, see `commit()`
methods of the `Transactional` objects.

.. inheritance-diagram:: pyroute2.ipdb.main.IPDB
    pyroute2.ipdb.interfaces.Interface
    pyroute2.ipdb.linkedset.LinkedSet
    pyroute2.ipdb.linkedset.IPaddrSet
    pyroute2.ipdb.routes.NextHopSet
    pyroute2.ipdb.routes.Via
    pyroute2.ipdb.routes.Encap
    pyroute2.ipdb.routes.Metrics
    pyroute2.ipdb.routes.BaseRoute
    pyroute2.ipdb.routes.Route
    pyroute2.ipdb.routes.MPLSRoute
    pyroute2.ipdb.routes.RoutingTable
    pyroute2.ipdb.routes.MPLSTable
    pyroute2.ipdb.routes.RoutingTableSet
    pyroute2.ipdb.rules.Rule
    pyroute2.ipdb.rules.RulesDict
    :parts: 1

Internet protocols
==================

Beside of the netlink protocols, the library implements a
limited set of supplementary internet protocol to play with.

.. inheritance-diagram:: pyroute2.protocols.udpmsg
    pyroute2.protocols.ip4msg
    pyroute2.protocols.udp4_pseudo_header
    pyroute2.protocols.ethmsg
    pyroute2.dhcp.dhcp4msg.dhcp4msg
    :parts: 1
