FreeBSD manual
download PDF document: vr.4.pdf
VR(4) FreeBSD Kernel Interfaces Manual VR(4)
NAME
vr - VIA Technologies Rhine I/II/III Ethernet device driver
SYNOPSIS
To compile this driver into the kernel, place the following lines in your
kernel configuration file:
device miibus
device vr
Alternatively, to load the driver as a module at boot time, place the
following line in loader.conf(5):
if_vr_load="YES"
DESCRIPTION
The vr driver provides support for PCI Ethernet adapters and embedded
controllers based on the VIA Technologies VT3043 Rhine I, VT86C100A Rhine
II, and VT6105/VT6105M Rhine III Fast Ethernet controller chips.
The VIA Rhine chips use bus master DMA and have a descriptor layout
designed to resemble that of the DEC 21x4x "tulip" chips. The register
layout is different however and the receive filter in the Rhine chips is
much simpler and is programmed through registers rather than by
downloading a special setup frame through the transmit DMA engine.
Transmit and receive DMA buffers must be longword aligned. The Rhine
chips are meant to be interfaced with external physical layer devices via
an MII bus. They support both 10 and 100Mbps speeds in either full or
half duplex.
The vr driver supports the following media types:
autoselect Enable autoselection of the media type and options.
The user can manually override the autoselected
mode by adding media options to the /etc/rc.conf
file.
10baseT/UTP Set 10Mbps operation. The mediaopt option can also
be used to select either full-duplex or half-duplex
modes.
100baseTX Set 100Mbps (Fast Ethernet) operation. The
mediaopt option can also be used to select either
full-duplex or half-duplex modes.
The vr driver supports the following media options:
full-duplex Force full duplex operation.
half-duplex Force half duplex operation.
Note that the 100baseTX media type is only available if supported by the
adapter. For more information on configuring this device, see
ifconfig(8).
HARDWARE
The vr driver supports VIA Technologies Rhine I, Rhine II, and Rhine III
SYSCTL VARIABLES
The following variables are available as sysctl(8) variables:
dev.vr.%d.stats
Display lots of useful MAC counters maintained in the driver.
DIAGNOSTICS
vr%d: couldn't map memory A fatal initialization error has occurred.
vr%d: couldn't map interrupt A fatal initialization error has occurred.
vr%d: watchdog timeout The device has stopped responding to the network,
or there is a problem with the network connection (cable).
vr%d: no memory for rx list The driver failed to allocate an mbuf for
the receiver ring.
vr%d: no memory for tx list The driver failed to allocate an mbuf for
the transmitter ring when allocating a pad buffer or collapsing an mbuf
chain into a cluster.
vr%d: chip is in D3 power state -- setting to D0 This message applies
only to adapters which support power management. Some operating systems
place the controller in low power mode when shutting down, and some PCI
BIOSes fail to bring the chip out of this state before configuring it.
The controller loses all of its PCI configuration in the D3 state, so if
the BIOS does not set it back to full power mode in time, it will not be
able to configure it correctly. The driver tries to detect this
condition and bring the adapter back to the D0 (full power) state, but
this may not be enough to return the driver to a fully operational
condition. If you see this message at boot time and the driver fails to
attach the device as a network interface, you will have to perform second
warm boot to have the device properly configured.
Note that this condition only occurs when warm booting from another
operating system. If you power down your system prior to booting
FreeBSD, the card should be configured correctly.
SEE ALSO
altq(4), arp(4), miibus(4), netintro(4), ng_ether(4), polling(4),
ifconfig(8)
The VIA Technologies VT86C100A data sheet, http://www.via.com.tw.
HISTORY
The vr device driver first appeared in FreeBSD 3.0.
AUTHORS
The vr driver was written by Bill Paul <wpaul@ctr.columbia.edu>.
BUGS
The vr driver always copies transmit mbuf chains into longword-aligned
buffers prior to transmission in order to pacify the Rhine chips. If
buffers are not aligned correctly, the chip will round the supplied
buffer address and begin DMAing from the wrong location. This buffer
copying impairs transmit performance on slower systems but cannot be
avoided. On faster machines (e.g. a Pentium II), the performance impact
is much less noticeable.