1145 lines
34 KiB
Groff
1145 lines
34 KiB
Groff
.\" Copyright (c) 2011-2014 Matteo Landi, Luigi Rizzo, Universita` di Pisa
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.\" All rights reserved.
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.\"
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.\" Redistribution and use in source and binary forms, with or without
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.\" modification, are permitted provided that the following conditions
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.\" are met:
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.\" 1. Redistributions of source code must retain the above copyright
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.\" notice, this list of conditions and the following disclaimer.
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.\" 2. Redistributions in binary form must reproduce the above copyright
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.\" notice, this list of conditions and the following disclaimer in the
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.\" documentation and/or other materials provided with the distribution.
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.\"
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.\" THIS SOFTWARE IS PROVIDED BY THE AUTHOR AND CONTRIBUTORS ``AS IS'' AND
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.\" ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
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.\" IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE
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.\" ARE DISCLAIMED. IN NO EVENT SHALL THE AUTHOR OR CONTRIBUTORS BE LIABLE
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.\" FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL
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.\" DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS
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.\" OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION)
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.\" HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT
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.\" LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY
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.\" OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF
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.\" SUCH DAMAGE.
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.\"
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.\" This document is derived in part from the enet man page (enet.4)
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.\" distributed with 4.3BSD Unix.
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.\"
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.\" $FreeBSD$
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.\"
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.Dd December 14, 2015
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.Dt NETMAP 4
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.Os
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.Sh NAME
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.Nm netmap
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.Nd a framework for fast packet I/O
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.br
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.Nm VALE
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.Nd a fast VirtuAl Local Ethernet using the netmap API
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.br
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.Nm netmap pipes
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.Nd a shared memory packet transport channel
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.Sh SYNOPSIS
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.Cd device netmap
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.Sh DESCRIPTION
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.Nm
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is a framework for extremely fast and efficient packet I/O
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for userspace and kernel clients, and for Virtual Machines.
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It runs on
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.Fx
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Linux and some versions of Windows, and supports a variety of
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.Nm netmap ports ,
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including
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.Bl -tag -width XXXX
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.It Nm physical NIC ports
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to access individual queues of network interfaces;
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.It Nm host ports
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to inject packets into the host stack;
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.It Nm VALE ports
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implementing a very fast and modular in-kernel software switch/dataplane;
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.It Nm netmap pipes
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a shared memory packet transport channel;
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.It Nm netmap monitors
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a mechanism similar to
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.Xr bpf
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to capture traffic
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.El
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.Pp
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All these
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.Nm netmap ports
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are accessed interchangeably with the same API,
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and are at least one order of magnitude faster than
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standard OS mechanisms
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(sockets, bpf, tun/tap interfaces, native switches, pipes).
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With suitably fast hardware (NICs, PCIe buses, CPUs),
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packet I/O using
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.Nm
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on supported NICs
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reaches 14.88 million packets per second (Mpps)
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with much less than one core on 10 Gbit/s NICs;
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35-40 Mpps on 40 Gbit/s NICs (limited by the hardware);
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about 20 Mpps per core for VALE ports;
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and over 100 Mpps for
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.Nm netmap pipes.
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NICs without native
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.Nm
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support can still use the API in emulated mode,
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which uses unmodified device drivers and is 3-5 times faster than
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.Xr bpf
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or raw sockets.
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.Pp
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Userspace clients can dynamically switch NICs into
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.Nm
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mode and send and receive raw packets through
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memory mapped buffers.
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Similarly,
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.Nm VALE
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switch instances and ports,
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.Nm netmap pipes
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and
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.Nm netmap monitors
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can be created dynamically,
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providing high speed packet I/O between processes,
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virtual machines, NICs and the host stack.
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.Pp
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.Nm
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supports both non-blocking I/O through
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.Xr ioctl 2 ,
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synchronization and blocking I/O through a file descriptor
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and standard OS mechanisms such as
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.Xr select 2 ,
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.Xr poll 2 ,
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.Xr epoll 2 ,
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and
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.Xr kqueue 2 .
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All types of
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.Nm netmap ports
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and the
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.Nm VALE switch
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are implemented by a single kernel module, which also emulates the
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.Nm
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API over standard drivers.
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For best performance,
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.Nm
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requires native support in device drivers.
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A list of such devices is at the end of this document.
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.Pp
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In the rest of this (long) manual page we document
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various aspects of the
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.Nm
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and
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.Nm VALE
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architecture, features and usage.
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.Sh ARCHITECTURE
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.Nm
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supports raw packet I/O through a
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.Em port ,
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which can be connected to a physical interface
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.Em ( NIC ) ,
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to the host stack,
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or to a
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.Nm VALE
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switch.
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Ports use preallocated circular queues of buffers
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.Em ( rings )
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residing in an mmapped region.
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There is one ring for each transmit/receive queue of a
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NIC or virtual port.
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An additional ring pair connects to the host stack.
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.Pp
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After binding a file descriptor to a port, a
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.Nm
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client can send or receive packets in batches through
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the rings, and possibly implement zero-copy forwarding
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between ports.
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.Pp
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All NICs operating in
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.Nm
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mode use the same memory region,
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accessible to all processes who own
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.Pa /dev/netmap
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file descriptors bound to NICs.
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Independent
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.Nm VALE
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and
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.Nm netmap pipe
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ports
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by default use separate memory regions,
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but can be independently configured to share memory.
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.Sh ENTERING AND EXITING NETMAP MODE
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The following section describes the system calls to create
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and control
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.Nm netmap
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ports (including
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.Nm VALE
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and
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.Nm netmap pipe
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ports).
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Simpler, higher level functions are described in section
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.Xr LIBRARIES .
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.Pp
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Ports and rings are created and controlled through a file descriptor,
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created by opening a special device
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.Dl fd = open("/dev/netmap");
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and then bound to a specific port with an
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.Dl ioctl(fd, NIOCREGIF, (struct nmreq *)arg);
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.Pp
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.Nm
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has multiple modes of operation controlled by the
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.Vt struct nmreq
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argument.
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.Va arg.nr_name
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specifies the netmap port name, as follows:
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.Bl -tag -width XXXX
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.It Dv OS network interface name (e.g. 'em0', 'eth1', ... )
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the data path of the NIC is disconnected from the host stack,
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and the file descriptor is bound to the NIC (one or all queues),
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or to the host stack;
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.It Dv valeSSS:PPP
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the file descriptor is bound to port PPP of VALE switch SSS.
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Switch instances and ports are dynamically created if necessary.
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.br
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Both SSS and PPP have the form [0-9a-zA-Z_]+ , the string
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cannot exceed IFNAMSIZ characters, and PPP cannot
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be the name of any existing OS network interface.
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.El
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.Pp
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On return,
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.Va arg
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indicates the size of the shared memory region,
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and the number, size and location of all the
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.Nm
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data structures, which can be accessed by mmapping the memory
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.Dl char *mem = mmap(0, arg.nr_memsize, fd);
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.Pp
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Non-blocking I/O is done with special
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.Xr ioctl 2
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.Xr select 2
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and
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.Xr poll 2
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on the file descriptor permit blocking I/O.
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.Xr epoll 2
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and
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.Xr kqueue 2
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are not supported on
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.Nm
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file descriptors.
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.Pp
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While a NIC is in
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.Nm
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mode, the OS will still believe the interface is up and running.
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OS-generated packets for that NIC end up into a
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.Nm
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ring, and another ring is used to send packets into the OS network stack.
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A
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.Xr close 2
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on the file descriptor removes the binding,
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and returns the NIC to normal mode (reconnecting the data path
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to the host stack), or destroys the virtual port.
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.Sh DATA STRUCTURES
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The data structures in the mmapped memory region are detailed in
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.In sys/net/netmap.h ,
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which is the ultimate reference for the
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.Nm
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API.
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The main structures and fields are indicated below:
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.Bl -tag -width XXX
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.It Dv struct netmap_if (one per interface)
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.Bd -literal
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struct netmap_if {
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...
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const uint32_t ni_flags; /* properties */
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...
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const uint32_t ni_tx_rings; /* NIC tx rings */
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const uint32_t ni_rx_rings; /* NIC rx rings */
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uint32_t ni_bufs_head; /* head of extra bufs list */
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...
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};
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.Ed
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.Pp
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Indicates the number of available rings
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.Pa ( struct netmap_rings )
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and their position in the mmapped region.
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The number of tx and rx rings
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.Pa ( ni_tx_rings , ni_rx_rings )
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normally depends on the hardware.
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NICs also have an extra tx/rx ring pair connected to the host stack.
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.Em NIOCREGIF
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can also request additional unbound buffers in the same memory space,
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to be used as temporary storage for packets.
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.Pa ni_bufs_head
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contains the index of the first of these free rings,
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which are connected in a list (the first uint32_t of each
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buffer being the index of the next buffer in the list).
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A
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.Dv 0
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indicates the end of the list.
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.It Dv struct netmap_ring (one per ring)
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.Bd -literal
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struct netmap_ring {
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...
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const uint32_t num_slots; /* slots in each ring */
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const uint32_t nr_buf_size; /* size of each buffer */
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...
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uint32_t head; /* (u) first buf owned by user */
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uint32_t cur; /* (u) wakeup position */
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const uint32_t tail; /* (k) first buf owned by kernel */
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...
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uint32_t flags;
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struct timeval ts; /* (k) time of last rxsync() */
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...
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struct netmap_slot slot[0]; /* array of slots */
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}
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.Ed
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.Pp
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Implements transmit and receive rings, with read/write
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pointers, metadata and an array of
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.Em slots
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describing the buffers.
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.It Dv struct netmap_slot (one per buffer)
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.Bd -literal
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struct netmap_slot {
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uint32_t buf_idx; /* buffer index */
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uint16_t len; /* packet length */
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uint16_t flags; /* buf changed, etc. */
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uint64_t ptr; /* address for indirect buffers */
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};
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.Ed
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.Pp
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Describes a packet buffer, which normally is identified by
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an index and resides in the mmapped region.
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.It Dv packet buffers
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Fixed size (normally 2 KB) packet buffers allocated by the kernel.
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.El
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.Pp
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The offset of the
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.Pa struct netmap_if
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in the mmapped region is indicated by the
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.Pa nr_offset
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field in the structure returned by
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.Dv NIOCREGIF .
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From there, all other objects are reachable through
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relative references (offsets or indexes).
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Macros and functions in
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.In net/netmap_user.h
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help converting them into actual pointers:
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.Pp
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.Dl struct netmap_if *nifp = NETMAP_IF(mem, arg.nr_offset);
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.Dl struct netmap_ring *txr = NETMAP_TXRING(nifp, ring_index);
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.Dl struct netmap_ring *rxr = NETMAP_RXRING(nifp, ring_index);
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.Pp
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.Dl char *buf = NETMAP_BUF(ring, buffer_index);
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.Sh RINGS, BUFFERS AND DATA I/O
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.Va Rings
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are circular queues of packets with three indexes/pointers
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.Va ( head , cur , tail ) ;
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one slot is always kept empty.
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The ring size
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.Va ( num_slots )
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should not be assumed to be a power of two.
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.Pp
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.Va head
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is the first slot available to userspace;
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.br
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.Va cur
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is the wakeup point:
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select/poll will unblock when
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.Va tail
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passes
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.Va cur ;
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.br
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.Va tail
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is the first slot reserved to the kernel.
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.Pp
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Slot indexes
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.Em must
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only move forward;
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for convenience, the function
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.Dl nm_ring_next(ring, index)
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returns the next index modulo the ring size.
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.Pp
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.Va head
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and
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.Va cur
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are only modified by the user program;
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.Va tail
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is only modified by the kernel.
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The kernel only reads/writes the
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.Vt struct netmap_ring
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slots and buffers
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during the execution of a netmap-related system call.
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The only exception are slots (and buffers) in the range
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.Va tail\ . . . head-1 ,
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that are explicitly assigned to the kernel.
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.Pp
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.Ss TRANSMIT RINGS
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On transmit rings, after a
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.Nm
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system call, slots in the range
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.Va head\ . . . tail-1
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are available for transmission.
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User code should fill the slots sequentially
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and advance
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.Va head
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and
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.Va cur
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past slots ready to transmit.
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.Va cur
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may be moved further ahead if the user code needs
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more slots before further transmissions (see
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.Sx SCATTER GATHER I/O ) .
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.Pp
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At the next NIOCTXSYNC/select()/poll(),
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slots up to
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.Va head-1
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are pushed to the port, and
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.Va tail
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may advance if further slots have become available.
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Below is an example of the evolution of a TX ring:
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.Bd -literal
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after the syscall, slots between cur and tail are (a)vailable
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head=cur tail
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| |
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v v
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TX [.....aaaaaaaaaaa.............]
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user creates new packets to (T)ransmit
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head=cur tail
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| |
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v v
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TX [.....TTTTTaaaaaa.............]
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NIOCTXSYNC/poll()/select() sends packets and reports new slots
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head=cur tail
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| |
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v v
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TX [..........aaaaaaaaaaa........]
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.Ed
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.Pp
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.Fn select
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and
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.Fn poll
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will block if there is no space in the ring, i.e.
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.Dl ring->cur == ring->tail
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and return when new slots have become available.
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.Pp
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High speed applications may want to amortize the cost of system calls
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by preparing as many packets as possible before issuing them.
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.Pp
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A transmit ring with pending transmissions has
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.Dl ring->head != ring->tail + 1 (modulo the ring size).
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The function
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.Va int nm_tx_pending(ring)
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implements this test.
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.Ss RECEIVE RINGS
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On receive rings, after a
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.Nm
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system call, the slots in the range
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.Va head\& . . . tail-1
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contain received packets.
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User code should process them and advance
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.Va head
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and
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.Va cur
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past slots it wants to return to the kernel.
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.Va cur
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may be moved further ahead if the user code wants to
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wait for more packets
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without returning all the previous slots to the kernel.
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.Pp
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At the next NIOCRXSYNC/select()/poll(),
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slots up to
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.Va head-1
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are returned to the kernel for further receives, and
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.Va tail
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may advance to report new incoming packets.
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.br
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|
Below is an example of the evolution of an RX ring:
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.Bd -literal
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after the syscall, there are some (h)eld and some (R)eceived slots
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head cur tail
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|
| | |
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v v v
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RX [..hhhhhhRRRRRRRR..........]
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user advances head and cur, releasing some slots and holding others
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head cur tail
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|
| | |
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v v v
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RX [..*****hhhRRRRRR...........]
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|
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NICRXSYNC/poll()/select() recovers slots and reports new packets
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head cur tail
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|
| | |
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v v v
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RX [.......hhhRRRRRRRRRRRR....]
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.Ed
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.Sh SLOTS AND PACKET BUFFERS
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Normally, packets should be stored in the netmap-allocated buffers
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assigned to slots when ports are bound to a file descriptor.
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One packet is fully contained in a single buffer.
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.Pp
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The following flags affect slot and buffer processing:
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|
.Bl -tag -width XXX
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.It NS_BUF_CHANGED
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.Em must
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|
be used when the
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.Va buf_idx
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|
in the slot is changed.
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|
This can be used to implement
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|
zero-copy forwarding, see
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.Sx ZERO-COPY FORWARDING .
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|
.It NS_REPORT
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|
reports when this buffer has been transmitted.
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|
Normally,
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.Nm
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|
notifies transmit completions in batches, hence signals
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|
can be delayed indefinitely.
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|
This flag helps detect
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|
when packets have been sent and a file descriptor can be closed.
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|
.It NS_FORWARD
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|
When a ring is in 'transparent' mode (see
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|
.Sx TRANSPARENT MODE ) ,
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|
packets marked with this flag are forwarded to the other endpoint
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|
at the next system call, thus restoring (in a selective way)
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|
the connection between a NIC and the host stack.
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|
.It NS_NO_LEARN
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|
tells the forwarding code that the source MAC address for this
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|
packet must not be used in the learning bridge code.
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|
.It NS_INDIRECT
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|
indicates that the packet's payload is in a user-supplied buffer
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|
whose user virtual address is in the 'ptr' field of the slot.
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|
The size can reach 65535 bytes.
|
|
.br
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|
This is only supported on the transmit ring of
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|
.Nm VALE
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|
ports, and it helps reducing data copies in the interconnection
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|
of virtual machines.
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|
.It NS_MOREFRAG
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|
indicates that the packet continues with subsequent buffers;
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|
the last buffer in a packet must have the flag clear.
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|
.El
|
|
.Sh SCATTER GATHER I/O
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|
Packets can span multiple slots if the
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|
.Va NS_MOREFRAG
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|
flag is set in all but the last slot.
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|
The maximum length of a chain is 64 buffers.
|
|
This is normally used with
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|
.Nm VALE
|
|
ports when connecting virtual machines, as they generate large
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|
TSO segments that are not split unless they reach a physical device.
|
|
.Pp
|
|
NOTE: The length field always refers to the individual
|
|
fragment; there is no place with the total length of a packet.
|
|
.Pp
|
|
On receive rings the macro
|
|
.Va NS_RFRAGS(slot)
|
|
indicates the remaining number of slots for this packet,
|
|
including the current one.
|
|
Slots with a value greater than 1 also have NS_MOREFRAG set.
|
|
.Sh IOCTLS
|
|
.Nm
|
|
uses two ioctls (NIOCTXSYNC, NIOCRXSYNC)
|
|
for non-blocking I/O.
|
|
They take no argument.
|
|
Two more ioctls (NIOCGINFO, NIOCREGIF) are used
|
|
to query and configure ports, with the following argument:
|
|
.Bd -literal
|
|
struct nmreq {
|
|
char nr_name[IFNAMSIZ]; /* (i) port name */
|
|
uint32_t nr_version; /* (i) API version */
|
|
uint32_t nr_offset; /* (o) nifp offset in mmap region */
|
|
uint32_t nr_memsize; /* (o) size of the mmap region */
|
|
uint32_t nr_tx_slots; /* (i/o) slots in tx rings */
|
|
uint32_t nr_rx_slots; /* (i/o) slots in rx rings */
|
|
uint16_t nr_tx_rings; /* (i/o) number of tx rings */
|
|
uint16_t nr_rx_rings; /* (i/o) number of rx rings */
|
|
uint16_t nr_ringid; /* (i/o) ring(s) we care about */
|
|
uint16_t nr_cmd; /* (i) special command */
|
|
uint16_t nr_arg1; /* (i/o) extra arguments */
|
|
uint16_t nr_arg2; /* (i/o) extra arguments */
|
|
uint32_t nr_arg3; /* (i/o) extra arguments */
|
|
uint32_t nr_flags /* (i/o) open mode */
|
|
...
|
|
};
|
|
.Ed
|
|
.Pp
|
|
A file descriptor obtained through
|
|
.Pa /dev/netmap
|
|
also supports the ioctl supported by network devices, see
|
|
.Xr netintro 4 .
|
|
.Bl -tag -width XXXX
|
|
.It Dv NIOCGINFO
|
|
returns EINVAL if the named port does not support netmap.
|
|
Otherwise, it returns 0 and (advisory) information
|
|
about the port.
|
|
Note that all the information below can change before the
|
|
interface is actually put in netmap mode.
|
|
.Bl -tag -width XX
|
|
.It Pa nr_memsize
|
|
indicates the size of the
|
|
.Nm
|
|
memory region.
|
|
NICs in
|
|
.Nm
|
|
mode all share the same memory region,
|
|
whereas
|
|
.Nm VALE
|
|
ports have independent regions for each port.
|
|
.It Pa nr_tx_slots , nr_rx_slots
|
|
indicate the size of transmit and receive rings.
|
|
.It Pa nr_tx_rings , nr_rx_rings
|
|
indicate the number of transmit
|
|
and receive rings.
|
|
Both ring number and sizes may be configured at runtime
|
|
using interface-specific functions (e.g.
|
|
.Xr ethtool
|
|
).
|
|
.El
|
|
.It Dv NIOCREGIF
|
|
binds the port named in
|
|
.Va nr_name
|
|
to the file descriptor.
|
|
For a physical device this also switches it into
|
|
.Nm
|
|
mode, disconnecting
|
|
it from the host stack.
|
|
Multiple file descriptors can be bound to the same port,
|
|
with proper synchronization left to the user.
|
|
.Pp
|
|
The recommended way to bind a file descriptor to a port is
|
|
to use function
|
|
.Va nm_open(..)
|
|
(see
|
|
.Xr LIBRARIES )
|
|
which parses names to access specific port types and
|
|
enable features.
|
|
In the following we document the main features.
|
|
.Pp
|
|
.Dv NIOCREGIF can also bind a file descriptor to one endpoint of a
|
|
.Em netmap pipe ,
|
|
consisting of two netmap ports with a crossover connection.
|
|
A netmap pipe share the same memory space of the parent port,
|
|
and is meant to enable configuration where a master process acts
|
|
as a dispatcher towards slave processes.
|
|
.Pp
|
|
To enable this function, the
|
|
.Pa nr_arg1
|
|
field of the structure can be used as a hint to the kernel to
|
|
indicate how many pipes we expect to use, and reserve extra space
|
|
in the memory region.
|
|
.Pp
|
|
On return, it gives the same info as NIOCGINFO,
|
|
with
|
|
.Pa nr_ringid
|
|
and
|
|
.Pa nr_flags
|
|
indicating the identity of the rings controlled through the file
|
|
descriptor.
|
|
.Pp
|
|
.Va nr_flags
|
|
.Va nr_ringid
|
|
selects which rings are controlled through this file descriptor.
|
|
Possible values of
|
|
.Pa nr_flags
|
|
are indicated below, together with the naming schemes
|
|
that application libraries (such as the
|
|
.Nm nm_open
|
|
indicated below) can use to indicate the specific set of rings.
|
|
In the example below, "netmap:foo" is any valid netmap port name.
|
|
.Bl -tag -width XXXXX
|
|
.It NR_REG_ALL_NIC "netmap:foo"
|
|
(default) all hardware ring pairs
|
|
.It NR_REG_SW "netmap:foo^"
|
|
the ``host rings'', connecting to the host stack.
|
|
.It NR_REG_NIC_SW "netmap:foo+"
|
|
all hardware rings and the host rings
|
|
.It NR_REG_ONE_NIC "netmap:foo-i"
|
|
only the i-th hardware ring pair, where the number is in
|
|
.Pa nr_ringid ;
|
|
.It NR_REG_PIPE_MASTER "netmap:foo{i"
|
|
the master side of the netmap pipe whose identifier (i) is in
|
|
.Pa nr_ringid ;
|
|
.It NR_REG_PIPE_SLAVE "netmap:foo}i"
|
|
the slave side of the netmap pipe whose identifier (i) is in
|
|
.Pa nr_ringid .
|
|
.Pp
|
|
The identifier of a pipe must be thought as part of the pipe name,
|
|
and does not need to be sequential.
|
|
On return the pipe
|
|
will only have a single ring pair with index 0,
|
|
irrespective of the value of
|
|
.Va i.
|
|
.El
|
|
.Pp
|
|
By default, a
|
|
.Xr poll 2
|
|
or
|
|
.Xr select 2
|
|
call pushes out any pending packets on the transmit ring, even if
|
|
no write events are specified.
|
|
The feature can be disabled by or-ing
|
|
.Va NETMAP_NO_TX_POLL
|
|
to the value written to
|
|
.Va nr_ringid.
|
|
When this feature is used,
|
|
packets are transmitted only on
|
|
.Va ioctl(NIOCTXSYNC)
|
|
or select()/poll() are called with a write event (POLLOUT/wfdset) or a full ring.
|
|
.Pp
|
|
When registering a virtual interface that is dynamically created to a
|
|
.Xr vale 4
|
|
switch, we can specify the desired number of rings (1 by default,
|
|
and currently up to 16) on it using nr_tx_rings and nr_rx_rings fields.
|
|
.It Dv NIOCTXSYNC
|
|
tells the hardware of new packets to transmit, and updates the
|
|
number of slots available for transmission.
|
|
.It Dv NIOCRXSYNC
|
|
tells the hardware of consumed packets, and asks for newly available
|
|
packets.
|
|
.El
|
|
.Sh SELECT, POLL, EPOLL, KQUEUE.
|
|
.Xr select 2
|
|
and
|
|
.Xr poll 2
|
|
on a
|
|
.Nm
|
|
file descriptor process rings as indicated in
|
|
.Sx TRANSMIT RINGS
|
|
and
|
|
.Sx RECEIVE RINGS ,
|
|
respectively when write (POLLOUT) and read (POLLIN) events are requested.
|
|
Both block if no slots are available in the ring
|
|
.Va ( ring->cur == ring->tail ) .
|
|
Depending on the platform,
|
|
.Xr epoll 2
|
|
and
|
|
.Xr kqueue 2
|
|
are supported too.
|
|
.Pp
|
|
Packets in transmit rings are normally pushed out
|
|
(and buffers reclaimed) even without
|
|
requesting write events.
|
|
Passing the
|
|
.Dv NETMAP_NO_TX_POLL
|
|
flag to
|
|
.Em NIOCREGIF
|
|
disables this feature.
|
|
By default, receive rings are processed only if read
|
|
events are requested.
|
|
Passing the
|
|
.Dv NETMAP_DO_RX_POLL
|
|
flag to
|
|
.Em NIOCREGIF updates receive rings even without read events.
|
|
Note that on epoll and kqueue,
|
|
.Dv NETMAP_NO_TX_POLL
|
|
and
|
|
.Dv NETMAP_DO_RX_POLL
|
|
only have an effect when some event is posted for the file descriptor.
|
|
.Sh LIBRARIES
|
|
The
|
|
.Nm
|
|
API is supposed to be used directly, both because of its simplicity and
|
|
for efficient integration with applications.
|
|
.Pp
|
|
For convenience, the
|
|
.In net/netmap_user.h
|
|
header provides a few macros and functions to ease creating
|
|
a file descriptor and doing I/O with a
|
|
.Nm
|
|
port.
|
|
These are loosely modeled after the
|
|
.Xr pcap 3
|
|
API, to ease porting of libpcap-based applications to
|
|
.Nm .
|
|
To use these extra functions, programs should
|
|
.Dl #define NETMAP_WITH_LIBS
|
|
before
|
|
.Dl #include <net/netmap_user.h>
|
|
.Pp
|
|
The following functions are available:
|
|
.Bl -tag -width XXXXX
|
|
.It Va struct nm_desc * nm_open(const char *ifname, const struct nmreq *req, uint64_t flags, const struct nm_desc *arg)
|
|
similar to
|
|
.Xr pcap_open ,
|
|
binds a file descriptor to a port.
|
|
.Bl -tag -width XX
|
|
.It Va ifname
|
|
is a port name, in the form "netmap:PPP" for a NIC and "valeSSS:PPP" for a
|
|
.Nm VALE
|
|
port.
|
|
.It Va req
|
|
provides the initial values for the argument to the NIOCREGIF ioctl.
|
|
The nm_flags and nm_ringid values are overwritten by parsing
|
|
ifname and flags, and other fields can be overridden through
|
|
the other two arguments.
|
|
.It Va arg
|
|
points to a struct nm_desc containing arguments (e.g. from a previously
|
|
open file descriptor) that should override the defaults.
|
|
The fields are used as described below
|
|
.It Va flags
|
|
can be set to a combination of the following flags:
|
|
.Va NETMAP_NO_TX_POLL ,
|
|
.Va NETMAP_DO_RX_POLL
|
|
(copied into nr_ringid);
|
|
.Va NM_OPEN_NO_MMAP (if arg points to the same memory region,
|
|
avoids the mmap and uses the values from it);
|
|
.Va NM_OPEN_IFNAME (ignores ifname and uses the values in arg);
|
|
.Va NM_OPEN_ARG1 ,
|
|
.Va NM_OPEN_ARG2 ,
|
|
.Va NM_OPEN_ARG3 (uses the fields from arg);
|
|
.Va NM_OPEN_RING_CFG (uses the ring number and sizes from arg).
|
|
.El
|
|
.It Va int nm_close(struct nm_desc *d)
|
|
closes the file descriptor, unmaps memory, frees resources.
|
|
.It Va int nm_inject(struct nm_desc *d, const void *buf, size_t size)
|
|
similar to pcap_inject(), pushes a packet to a ring, returns the size
|
|
of the packet is successful, or 0 on error;
|
|
.It Va int nm_dispatch(struct nm_desc *d, int cnt, nm_cb_t cb, u_char *arg)
|
|
similar to pcap_dispatch(), applies a callback to incoming packets
|
|
.It Va u_char * nm_nextpkt(struct nm_desc *d, struct nm_pkthdr *hdr)
|
|
similar to pcap_next(), fetches the next packet
|
|
.El
|
|
.Sh SUPPORTED DEVICES
|
|
.Nm
|
|
natively supports the following devices:
|
|
.Pp
|
|
On FreeBSD:
|
|
.Xr cxgbe 4 ,
|
|
.Xr em 4 ,
|
|
.Xr igb 4 ,
|
|
.Xr ixgbe 4 ,
|
|
.Xr ixl 4 ,
|
|
.Xr lem 4 ,
|
|
.Xr re 4 .
|
|
.Pp
|
|
On Linux
|
|
.Xr e1000 4 ,
|
|
.Xr e1000e 4 ,
|
|
.Xr i40e 4 ,
|
|
.Xr igb 4 ,
|
|
.Xr ixgbe 4 ,
|
|
.Xr r8169 4 .
|
|
.Pp
|
|
NICs without native support can still be used in
|
|
.Nm
|
|
mode through emulation.
|
|
Performance is inferior to native netmap
|
|
mode but still significantly higher than various raw socket types
|
|
(bpf, PF_PACKET, etc.).
|
|
Note that for slow devices (such as 1 Gbit/s and slower NICs,
|
|
or several 10 Gbit/s NICs whose hardware is unable to sustain line rate),
|
|
emulated and native mode will likely have similar or same throughput.
|
|
.br
|
|
When emulation is in use, packet sniffer programs such as tcpdump
|
|
could see received packets before they are diverted by netmap. This behaviour
|
|
is not intentional, being just an artifact of the implementation of emulation.
|
|
Note that in case the netmap application subsequently moves packets received
|
|
from the emulated adapter onto the host RX ring, the sniffer will intercept
|
|
those packets again, since the packets are injected to the host stack as they
|
|
were received by the network interface.
|
|
.Pp
|
|
Emulation is also available for devices with native netmap support,
|
|
which can be used for testing or performance comparison.
|
|
The sysctl variable
|
|
.Va dev.netmap.admode
|
|
globally controls how netmap mode is implemented.
|
|
.Sh SYSCTL VARIABLES AND MODULE PARAMETERS
|
|
Some aspect of the operation of
|
|
.Nm
|
|
are controlled through sysctl variables on FreeBSD
|
|
.Em ( dev.netmap.* )
|
|
and module parameters on Linux
|
|
.Em ( /sys/module/netmap_lin/parameters/* ) :
|
|
.Bl -tag -width indent
|
|
.It Va dev.netmap.admode: 0
|
|
Controls the use of native or emulated adapter mode.
|
|
.br
|
|
0 uses the best available option;
|
|
.br
|
|
1 forces native mode and fails if not available;
|
|
.br
|
|
2 forces emulated hence never fails.
|
|
.It Va dev.netmap.generic_ringsize: 1024
|
|
Ring size used for emulated netmap mode
|
|
.It Va dev.netmap.generic_mit: 100000
|
|
Controls interrupt moderation for emulated mode
|
|
.It Va dev.netmap.mmap_unreg: 0
|
|
.It Va dev.netmap.fwd: 0
|
|
Forces NS_FORWARD mode
|
|
.It Va dev.netmap.flags: 0
|
|
.It Va dev.netmap.txsync_retry: 2
|
|
.It Va dev.netmap.no_pendintr: 1
|
|
Forces recovery of transmit buffers on system calls
|
|
.It Va dev.netmap.mitigate: 1
|
|
Propagates interrupt mitigation to user processes
|
|
.It Va dev.netmap.no_timestamp: 0
|
|
Disables the update of the timestamp in the netmap ring
|
|
.It Va dev.netmap.verbose: 0
|
|
Verbose kernel messages
|
|
.It Va dev.netmap.buf_num: 163840
|
|
.It Va dev.netmap.buf_size: 2048
|
|
.It Va dev.netmap.ring_num: 200
|
|
.It Va dev.netmap.ring_size: 36864
|
|
.It Va dev.netmap.if_num: 100
|
|
.It Va dev.netmap.if_size: 1024
|
|
Sizes and number of objects (netmap_if, netmap_ring, buffers)
|
|
for the global memory region.
|
|
The only parameter worth modifying is
|
|
.Va dev.netmap.buf_num
|
|
as it impacts the total amount of memory used by netmap.
|
|
.It Va dev.netmap.buf_curr_num: 0
|
|
.It Va dev.netmap.buf_curr_size: 0
|
|
.It Va dev.netmap.ring_curr_num: 0
|
|
.It Va dev.netmap.ring_curr_size: 0
|
|
.It Va dev.netmap.if_curr_num: 0
|
|
.It Va dev.netmap.if_curr_size: 0
|
|
Actual values in use.
|
|
.It Va dev.netmap.bridge_batch: 1024
|
|
Batch size used when moving packets across a
|
|
.Nm VALE
|
|
switch.
|
|
Values above 64 generally guarantee good
|
|
performance.
|
|
.El
|
|
.Sh SYSTEM CALLS
|
|
.Nm
|
|
uses
|
|
.Xr select 2 ,
|
|
.Xr poll 2 ,
|
|
.Xr epoll 2
|
|
and
|
|
.Xr kqueue 2
|
|
to wake up processes when significant events occur, and
|
|
.Xr mmap 2
|
|
to map memory.
|
|
.Xr ioctl 2
|
|
is used to configure ports and
|
|
.Nm VALE switches .
|
|
.Pp
|
|
Applications may need to create threads and bind them to
|
|
specific cores to improve performance, using standard
|
|
OS primitives, see
|
|
.Xr pthread 3 .
|
|
In particular,
|
|
.Xr pthread_setaffinity_np 3
|
|
may be of use.
|
|
.Sh EXAMPLES
|
|
.Ss TEST PROGRAMS
|
|
.Nm
|
|
comes with a few programs that can be used for testing or
|
|
simple applications.
|
|
See the
|
|
.Pa examples/
|
|
directory in
|
|
.Nm
|
|
distributions, or
|
|
.Pa tools/tools/netmap/
|
|
directory in
|
|
.Fx
|
|
distributions.
|
|
.Pp
|
|
.Xr pkt-gen
|
|
is a general purpose traffic source/sink.
|
|
.Pp
|
|
As an example
|
|
.Dl pkt-gen -i ix0 -f tx -l 60
|
|
can generate an infinite stream of minimum size packets, and
|
|
.Dl pkt-gen -i ix0 -f rx
|
|
is a traffic sink.
|
|
Both print traffic statistics, to help monitor
|
|
how the system performs.
|
|
.Pp
|
|
.Xr pkt-gen
|
|
has many options can be uses to set packet sizes, addresses,
|
|
rates, and use multiple send/receive threads and cores.
|
|
.Pp
|
|
.Xr bridge
|
|
is another test program which interconnects two
|
|
.Nm
|
|
ports.
|
|
It can be used for transparent forwarding between
|
|
interfaces, as in
|
|
.Dl bridge -i ix0 -i ix1
|
|
or even connect the NIC to the host stack using netmap
|
|
.Dl bridge -i ix0 -i ix0
|
|
.Ss USING THE NATIVE API
|
|
The following code implements a traffic generator
|
|
.Pp
|
|
.Bd -literal -compact
|
|
#include <net/netmap_user.h>
|
|
\&...
|
|
void sender(void)
|
|
{
|
|
struct netmap_if *nifp;
|
|
struct netmap_ring *ring;
|
|
struct nmreq nmr;
|
|
struct pollfd fds;
|
|
|
|
fd = open("/dev/netmap", O_RDWR);
|
|
bzero(&nmr, sizeof(nmr));
|
|
strcpy(nmr.nr_name, "ix0");
|
|
nmr.nm_version = NETMAP_API;
|
|
ioctl(fd, NIOCREGIF, &nmr);
|
|
p = mmap(0, nmr.nr_memsize, fd);
|
|
nifp = NETMAP_IF(p, nmr.nr_offset);
|
|
ring = NETMAP_TXRING(nifp, 0);
|
|
fds.fd = fd;
|
|
fds.events = POLLOUT;
|
|
for (;;) {
|
|
poll(&fds, 1, -1);
|
|
while (!nm_ring_empty(ring)) {
|
|
i = ring->cur;
|
|
buf = NETMAP_BUF(ring, ring->slot[i].buf_index);
|
|
... prepare packet in buf ...
|
|
ring->slot[i].len = ... packet length ...
|
|
ring->head = ring->cur = nm_ring_next(ring, i);
|
|
}
|
|
}
|
|
}
|
|
.Ed
|
|
.Ss HELPER FUNCTIONS
|
|
A simple receiver can be implemented using the helper functions
|
|
.Bd -literal -compact
|
|
#define NETMAP_WITH_LIBS
|
|
#include <net/netmap_user.h>
|
|
\&...
|
|
void receiver(void)
|
|
{
|
|
struct nm_desc *d;
|
|
struct pollfd fds;
|
|
u_char *buf;
|
|
struct nm_pkthdr h;
|
|
...
|
|
d = nm_open("netmap:ix0", NULL, 0, 0);
|
|
fds.fd = NETMAP_FD(d);
|
|
fds.events = POLLIN;
|
|
for (;;) {
|
|
poll(&fds, 1, -1);
|
|
while ( (buf = nm_nextpkt(d, &h)) )
|
|
consume_pkt(buf, h->len);
|
|
}
|
|
nm_close(d);
|
|
}
|
|
.Ed
|
|
.Ss ZERO-COPY FORWARDING
|
|
Since physical interfaces share the same memory region,
|
|
it is possible to do packet forwarding between ports
|
|
swapping buffers.
|
|
The buffer from the transmit ring is used
|
|
to replenish the receive ring:
|
|
.Bd -literal -compact
|
|
uint32_t tmp;
|
|
struct netmap_slot *src, *dst;
|
|
...
|
|
src = &src_ring->slot[rxr->cur];
|
|
dst = &dst_ring->slot[txr->cur];
|
|
tmp = dst->buf_idx;
|
|
dst->buf_idx = src->buf_idx;
|
|
dst->len = src->len;
|
|
dst->flags = NS_BUF_CHANGED;
|
|
src->buf_idx = tmp;
|
|
src->flags = NS_BUF_CHANGED;
|
|
rxr->head = rxr->cur = nm_ring_next(rxr, rxr->cur);
|
|
txr->head = txr->cur = nm_ring_next(txr, txr->cur);
|
|
...
|
|
.Ed
|
|
.Ss ACCESSING THE HOST STACK
|
|
The host stack is for all practical purposes just a regular ring pair,
|
|
which you can access with the netmap API (e.g. with
|
|
.Dl nm_open("netmap:eth0^", ... ) ;
|
|
All packets that the host would send to an interface in
|
|
.Nm
|
|
mode end up into the RX ring, whereas all packets queued to the
|
|
TX ring are send up to the host stack.
|
|
.Ss VALE SWITCH
|
|
A simple way to test the performance of a
|
|
.Nm VALE
|
|
switch is to attach a sender and a receiver to it,
|
|
e.g. running the following in two different terminals:
|
|
.Dl pkt-gen -i vale1:a -f rx # receiver
|
|
.Dl pkt-gen -i vale1:b -f tx # sender
|
|
The same example can be used to test netmap pipes, by simply
|
|
changing port names, e.g.
|
|
.Dl pkt-gen -i vale2:x{3 -f rx # receiver on the master side
|
|
.Dl pkt-gen -i vale2:x}3 -f tx # sender on the slave side
|
|
.Pp
|
|
The following command attaches an interface and the host stack
|
|
to a switch:
|
|
.Dl vale-ctl -h vale2:em0
|
|
Other
|
|
.Nm
|
|
clients attached to the same switch can now communicate
|
|
with the network card or the host.
|
|
.Sh SEE ALSO
|
|
.Pa http://info.iet.unipi.it/~luigi/netmap/
|
|
.Pp
|
|
Luigi Rizzo, Revisiting network I/O APIs: the netmap framework,
|
|
Communications of the ACM, 55 (3), pp.45-51, March 2012
|
|
.Pp
|
|
Luigi Rizzo, netmap: a novel framework for fast packet I/O,
|
|
Usenix ATC'12, June 2012, Boston
|
|
.Pp
|
|
Luigi Rizzo, Giuseppe Lettieri,
|
|
VALE, a switched ethernet for virtual machines,
|
|
ACM CoNEXT'12, December 2012, Nice
|
|
.Pp
|
|
Luigi Rizzo, Giuseppe Lettieri, Vincenzo Maffione,
|
|
Speeding up packet I/O in virtual machines,
|
|
ACM/IEEE ANCS'13, October 2013, San Jose
|
|
.Sh AUTHORS
|
|
.An -nosplit
|
|
The
|
|
.Nm
|
|
framework has been originally designed and implemented at the
|
|
Universita` di Pisa in 2011 by
|
|
.An Luigi Rizzo ,
|
|
and further extended with help from
|
|
.An Matteo Landi ,
|
|
.An Gaetano Catalli ,
|
|
.An Giuseppe Lettieri ,
|
|
and
|
|
.An Vincenzo Maffione .
|
|
.Pp
|
|
.Nm
|
|
and
|
|
.Nm VALE
|
|
have been funded by the European Commission within FP7 Projects
|
|
CHANGE (257422) and OPENLAB (287581).
|
|
.Sh CAVEATS
|
|
No matter how fast the CPU and OS are,
|
|
achieving line rate on 10G and faster interfaces
|
|
requires hardware with sufficient performance.
|
|
Several NICs are unable to sustain line rate with
|
|
small packet sizes.
|
|
Insufficient PCIe or memory bandwidth
|
|
can also cause reduced performance.
|
|
.Pp
|
|
Another frequent reason for low performance is the use
|
|
of flow control on the link: a slow receiver can limit
|
|
the transmit speed.
|
|
Be sure to disable flow control when running high
|
|
speed experiments.
|
|
.Ss SPECIAL NIC FEATURES
|
|
.Nm
|
|
is orthogonal to some NIC features such as
|
|
multiqueue, schedulers, packet filters.
|
|
.Pp
|
|
Multiple transmit and receive rings are supported natively
|
|
and can be configured with ordinary OS tools,
|
|
such as
|
|
.Xr ethtool
|
|
or
|
|
device-specific sysctl variables.
|
|
The same goes for Receive Packet Steering (RPS)
|
|
and filtering of incoming traffic.
|
|
.Pp
|
|
.Nm
|
|
.Em does not use
|
|
features such as
|
|
.Em checksum offloading , TCP segmentation offloading ,
|
|
.Em encryption , VLAN encapsulation/decapsulation ,
|
|
etc.
|
|
When using netmap to exchange packets with the host stack,
|
|
make sure to disable these features.
|