Kernel-3.10.0-957.el7_can

============================================================================

can.txt

Readme file for the Controller Area Network Protocol Family (aka Socket CAN)

This file contains

1 Overview / What is Socket CAN

2 Motivation / Why using the socket API

3 Socket CAN concept
3.1 receive lists
3.2 local loopback of sent frames
3.3 network security issues (capabilities)
3.4 network problem notifications

4 How to use Socket CAN
4.1 RAW protocol sockets with can_filters (SOCK_RAW)
4.1.1 RAW socket option CAN_RAW_FILTER
4.1.2 RAW socket option CAN_RAW_ERR_FILTER
4.1.3 RAW socket option CAN_RAW_LOOPBACK
4.1.4 RAW socket option CAN_RAW_RECV_OWN_MSGS
4.1.5 RAW socket option CAN_RAW_FD_FRAMES
4.1.6 RAW socket option CAN_RAW_JOIN_FILTERS
4.1.7 RAW socket returned message flags
4.2 Broadcast Manager protocol sockets (SOCK_DGRAM)
4.3 connected transport protocols (SOCK_SEQPACKET)
4.4 unconnected transport protocols (SOCK_DGRAM)

5 Socket CAN core module
5.1 can.ko module params
5.2 procfs content
5.3 writing own CAN protocol modules

6 CAN network drivers
6.1 general settings
6.2 local loopback of sent frames
6.3 CAN controller hardware filters
6.4 The virtual CAN driver (vcan)
6.5 The CAN network device driver interface
6.5.1 Netlink interface to set/get devices properties
6.5.2 Setting the CAN bit-timing
6.5.3 Starting and stopping the CAN network device
6.6 CAN FD (flexible data rate) driver support
6.7 supported CAN hardware

7 Socket CAN resources

8 Credits

============================================================================

  1. Overview / What is Socket CAN

The socketcan package is an implementation of CAN protocols
(Controller Area Network) for Linux. CAN is a networking technology
which has widespread use in automation, embedded devices, and
automotive fields. While there have been other CAN implementations
for Linux based on character devices, Socket CAN uses the Berkeley
socket API, the Linux network stack and implements the CAN device
drivers as network interfaces. The CAN socket API has been designed
as similar as possible to the TCP/IP protocols to allow programmers,
familiar with network programming, to easily learn how to use CAN
sockets.

  1. Motivation / Why using the socket API

There have been CAN implementations for Linux before Socket CAN so the
question arises, why we have started another project. Most existing
implementations come as a device driver for some CAN hardware, they
are based on character devices and provide comparatively little
functionality. Usually, there is only a hardware-specific device
driver which provides a character device interface to send and
receive raw CAN frames, directly to/from the controller hardware.
Queueing of frames and higher-level transport protocols like ISO-TP
have to be implemented in user space applications. Also, most
character-device implementations support only one single process to
open the device at a time, similar to a serial interface. Exchanging
the CAN controller requires employment of another device driver and
often the need for adaption of large parts of the application to the
new driver’s API.

Socket CAN was designed to overcome all of these limitations. A new
protocol family has been implemented which provides a socket interface
to user space applications and which builds upon the Linux network
layer, so to use all of the provided queueing functionality. A device
driver for CAN controller hardware registers itself with the Linux
network layer as a network device, so that CAN frames from the
controller can be passed up to the network layer and on to the CAN
protocol family module and also vice-versa. Also, the protocol family
module provides an API for transport protocol modules to register, so
that any number of transport protocols can be loaded or unloaded
dynamically. In fact, the can core module alone does not provide any
protocol and cannot be used without loading at least one additional
protocol module. Multiple sockets can be opened at the same time,
on different or the same protocol module and they can listen/send
frames on different or the same CAN IDs. Several sockets listening on
the same interface for frames with the same CAN ID are all passed the
same received matching CAN frames. An application wishing to
communicate using a specific transport protocol, e.g. ISO-TP, just
selects that protocol when opening the socket, and then can read and
write application data byte streams, without having to deal with
CAN-IDs, frames, etc.

Similar functionality visible from user-space could be provided by a
character device, too, but this would lead to a technically inelegant
solution for a couple of reasons:

  • Intricate usage. Instead of passing a protocol argument to
    socket(2) and using bind(2) to select a CAN interface and CAN ID, an
    application would have to do all these operations using ioctl(2)s.

  • Code duplication. A character device cannot make use of the Linux
    network queueing code, so all that code would have to be duplicated
    for CAN networking.

  • Abstraction. In most existing character-device implementations, the
    hardware-specific device driver for a CAN controller directly
    provides the character device for the application to work with.
    This is at least very unusual in Unix systems for both, char and
    block devices. For example you don’t have a character device for a
    certain UART of a serial interface, a certain sound chip in your
    computer, a SCSI or IDE controller providing access to your hard
    disk or tape streamer device. Instead, you have abstraction layers
    which provide a unified character or block device interface to the
    application on the one hand, and a interface for hardware-specific
    device drivers on the other hand. These abstractions are provided
    by subsystems like the tty layer, the audio subsystem or the SCSI
    and IDE subsystems for the devices mentioned above.

    The easiest way to implement a CAN device driver is as a character
    device without such a (complete) abstraction layer, as is done by most
    existing drivers. The right way, however, would be to add such a
    layer with all the functionality like registering for certain CAN
    IDs, supporting several open file descriptors and (de)multiplexing
    CAN frames between them, (sophisticated) queueing of CAN frames, and
    providing an API for device drivers to register with. However, then
    it would be no more difficult, or may be even easier, to use the
    networking framework provided by the Linux kernel, and this is what
    Socket CAN does.

    The use of the networking framework of the Linux kernel is just the
    natural and most appropriate way to implement CAN for Linux.

  1. Socket CAN concept

As described in chapter 2 it is the main goal of Socket CAN to
provide a socket interface to user space applications which builds
upon the Linux network layer. In contrast to the commonly known
TCP/IP and ethernet networking, the CAN bus is a broadcast-only(!)
medium that has no MAC-layer addressing like ethernet. The CAN-identifier
(can_id) is used for arbitration on the CAN-bus. Therefore the CAN-IDs
have to be chosen uniquely on the bus. When designing a CAN-ECU
network the CAN-IDs are mapped to be sent by a specific ECU.
For this reason a CAN-ID can be treated best as a kind of source address.

3.1 receive lists

The network transparent access of multiple applications leads to the
problem that different applications may be interested in the same
CAN-IDs from the same CAN network interface. The Socket CAN core
module - which implements the protocol family CAN - provides several
high efficient receive lists for this reason. If e.g. a user space
application opens a CAN RAW socket, the raw protocol module itself
requests the (range of) CAN-IDs from the Socket CAN core that are
requested by the user. The subscription and unsubscription of
CAN-IDs can be done for specific CAN interfaces or for all(!) known
CAN interfaces with the can_rx_(un)register() functions provided to
CAN protocol modules by the SocketCAN core (see chapter 5).
To optimize the CPU usage at runtime the receive lists are split up
into several specific lists per device that match the requested
filter complexity for a given use-case.

3.2 local loopback of sent frames

As known from other networking concepts the data exchanging
applications may run on the same or different nodes without any
change (except for the according addressing information):

     ___   ___   ___                   _______   ___
    | _ | | _ | | _ |                 | _   _ | | _ |
    ||A|| ||B|| ||C||                 ||A| |B|| ||C||
    |___| |___| |___|                 |_______| |___|
      |     |     |                       |       |
    -----------------(1)- CAN bus -(2)---------------

To ensure that application A receives the same information in the
example (2) as it would receive in example (1) there is need for
some kind of local loopback of the sent CAN frames on the appropriate
node.

The Linux network devices (by default) just can handle the
transmission and reception of media dependent frames. Due to the
arbitration on the CAN bus the transmission of a low prio CAN-ID
may be delayed by the reception of a high prio CAN frame. To
reflect the correct* traffic on the node the loopback of the sent
data has to be performed right after a successful transmission. If
the CAN network interface is not capable of performing the loopback for
some reason the SocketCAN core can do this task as a fallback solution.
See chapter 6.2 for details (recommended).

The loopback functionality is enabled by default to reflect standard
networking behaviour for CAN applications. Due to some requests from
the RT-SocketCAN group the loopback optionally may be disabled for each
separate socket. See sockopts from the CAN RAW sockets in chapter 4.1.

  • = you really like to have this when you’re running analyser tools
    like ‘candump’ or ‘cansniffer’ on the (same) node.

3.3 network security issues (capabilities)

The Controller Area Network is a local field bus transmitting only
broadcast messages without any routing and security concepts.
In the majority of cases the user application has to deal with
raw CAN frames. Therefore it might be reasonable NOT to restrict
the CAN access only to the user root, as known from other networks.
Since the currently implemented CAN_RAW and CAN_BCM sockets can only
send and receive frames to/from CAN interfaces it does not affect
security of others networks to allow all users to access the CAN.
To enable non-root users to access CAN_RAW and CAN_BCM protocol
sockets the Kconfig options CAN_RAW_USER and/or CAN_BCM_USER may be
selected at kernel compile time.

3.4 network problem notifications

The use of the CAN bus may lead to several problems on the physical
and media access control layer. Detecting and logging of these lower
layer problems is a vital requirement for CAN users to identify
hardware issues on the physical transceiver layer as well as
arbitration problems and error frames caused by the different
ECUs. The occurrence of detected errors are important for diagnosis
and have to be logged together with the exact timestamp. For this
reason the CAN interface driver can generate so called Error Message
Frames that can optionally be passed to the user application in the
same way as other CAN frames. Whenever an error on the physical layer
or the MAC layer is detected (e.g. by the CAN controller) the driver
creates an appropriate error message frame. Error messages frames can
be requested by the user application using the common CAN filter
mechanisms. Inside this filter definition the (interested) type of
errors may be selected. The reception of error messages is disabled
by default. The format of the CAN error message frame is briefly
described in the Linux header file “include/linux/can/error.h”.

  1. How to use Socket CAN

Like TCP/IP, you first need to open a socket for communicating over a
CAN network. Since Socket CAN implements a new protocol family, you
need to pass PF_CAN as the first argument to the socket(2) system
call. Currently, there are two CAN protocols to choose from, the raw
socket protocol and the broadcast manager (BCM). So to open a socket,
you would write

s = socket(PF_CAN, SOCK_RAW, CAN_RAW);

and

s = socket(PF_CAN, SOCK_DGRAM, CAN_BCM);

respectively. After the successful creation of the socket, you would
normally use the bind(2) system call to bind the socket to a CAN
interface (which is different from TCP/IP due to different addressing

  • see chapter 3). After binding (CAN_RAW) or connecting (CAN_BCM)
    the socket, you can read(2) and write(2) from/to the socket or use
    send(2), sendto(2), sendmsg(2) and the recv* counterpart operations
    on the socket as usual. There are also CAN specific socket options
    described below.

    The basic CAN frame structure and the sockaddr structure are defined
    in include/linux/can.h:

    struct can_frame {

        canid_t can_id;  /* 32 bit CAN_ID + EFF/RTR/ERR flags */
        __u8    can_dlc; /* frame payload length in byte (0 .. 8) */
        __u8    data[8] __attribute__((aligned(8)));
    

    };

    The alignment of the (linear) payload data[] to a 64bit boundary
    allows the user to define own structs and unions to easily access the
    CAN payload. There is no given byteorder on the CAN bus by
    default. A read(2) system call on a CAN_RAW socket transfers a
    struct can_frame to the user space.

    The sockaddr_can structure has an interface index like the
    PF_PACKET socket, that also binds to a specific interface:

    struct sockaddr_can {

        sa_family_t can_family;
        int         can_ifindex;
        union {
                /* transport protocol class address info (e.g. ISOTP) */
                struct { canid_t rx_id, tx_id; } tp;
    
                /* reserved for future CAN protocols address information */
        } can_addr;
    

    };

    To determine the interface index an appropriate ioctl() has to
    be used (example for CAN_RAW sockets without error checking):

    int s;
    struct sockaddr_can addr;
    struct ifreq ifr;

    s = socket(PF_CAN, SOCK_RAW, CAN_RAW);

    strcpy(ifr.ifr_name, “can0” );
    ioctl(s, SIOCGIFINDEX, &ifr);

    addr.can_family = AF_CAN;
    addr.can_ifindex = ifr.ifr_ifindex;

    bind(s, (struct sockaddr *)&addr, sizeof(addr));

    (..)

    To bind a socket to all(!) CAN interfaces the interface index must
    be 0 (zero). In this case the socket receives CAN frames from every
    enabled CAN interface. To determine the originating CAN interface
    the system call recvfrom(2) may be used instead of read(2). To send
    on a socket that is bound to ‘any’ interface sendto(2) is needed to
    specify the outgoing interface.

    Reading CAN frames from a bound CAN_RAW socket (see above) consists
    of reading a struct can_frame:

    struct can_frame frame;

    nbytes = read(s, &frame, sizeof(struct can_frame));

    if (nbytes < 0) {

        perror("can raw socket read");
        return 1;
    

    }

    /* paranoid check … */
    if (nbytes < sizeof(struct can_frame)) {

        fprintf(stderr, "read: incomplete CAN frame\n");
        return 1;
    

    }

    /* do something with the received CAN frame */

    Writing CAN frames can be done similarly, with the write(2) system call:

    nbytes = write(s, &frame, sizeof(struct can_frame));

    When the CAN interface is bound to ‘any’ existing CAN interface
    (addr.can_ifindex = 0) it is recommended to use recvfrom(2) if the
    information about the originating CAN interface is needed:

    struct sockaddr_can addr;
    struct ifreq ifr;
    socklen_t len = sizeof(addr);
    struct can_frame frame;

    nbytes = recvfrom(s, &frame, sizeof(struct can_frame),

                  0, (struct sockaddr*)&addr, &len);
    

    /* get interface name of the received CAN frame */
    ifr.ifr_ifindex = addr.can_ifindex;
    ioctl(s, SIOCGIFNAME, &ifr);
    printf(“Received a CAN frame from interface %s”, ifr.ifr_name);

    To write CAN frames on sockets bound to ‘any’ CAN interface the
    outgoing interface has to be defined certainly.

    strcpy(ifr.ifr_name, “can0”);
    ioctl(s, SIOCGIFINDEX, &ifr);
    addr.can_ifindex = ifr.ifr_ifindex;
    addr.can_family = AF_CAN;

    nbytes = sendto(s, &frame, sizeof(struct can_frame),

                0, (struct sockaddr*)&addr, sizeof(addr));
    

    Remark about CAN FD (flexible data rate) support:

    Generally the handling of CAN FD is very similar to the formerly described
    examples. The new CAN FD capable CAN controllers support two different
    bitrates for the arbitration phase and the payload phase of the CAN FD frame
    and up to 64 bytes of payload. This extended payload length breaks all the
    kernel interfaces (ABI) which heavily rely on the CAN frame with fixed eight
    bytes of payload (struct can_frame) like the CAN_RAW socket. Therefore e.g.
    the CAN_RAW socket supports a new socket option CAN_RAW_FD_FRAMES that
    switches the socket into a mode that allows the handling of CAN FD frames
    and (legacy) CAN frames simultaneously (see section 4.1.5).

    The struct canfd_frame is defined in include/linux/can.h:

    struct canfd_frame {

        canid_t can_id;  /* 32 bit CAN_ID + EFF/RTR/ERR flags */
        __u8    len;     /* frame payload length in byte (0 .. 64) */
        __u8    flags;   /* additional flags for CAN FD */
        __u8    __res0;  /* reserved / padding */
        __u8    __res1;  /* reserved / padding */
        __u8    data[64] __attribute__((aligned(8)));
    

    };

    The struct canfd_frame and the existing struct can_frame have the can_id,
    the payload length and the payload data at the same offset inside their
    structures. This allows to handle the different structures very similar.
    When the content of a struct can_frame is copied into a struct canfd_frame
    all structure elements can be used as-is - only the data[] becomes extended.

    When introducing the struct canfd_frame it turned out that the data length
    code (DLC) of the struct can_frame was used as a length information as the
    length and the DLC has a 1:1 mapping in the range of 0 .. 8. To preserve
    the easy handling of the length information the canfd_frame.len element
    contains a plain length value from 0 .. 64. So both canfd_frame.len and
    can_frame.can_dlc are equal and contain a length information and no DLC.
    For details about the distinction of CAN and CAN FD capable devices and
    the mapping to the bus-relevant data length code (DLC), see chapter 6.6.

    The length of the two CAN(FD) frame structures define the maximum transfer
    unit (MTU) of the CAN(FD) network interface and skbuff data length. Two
    definitions are specified for CAN specific MTUs in include/linux/can.h :

    #define CAN_MTU (sizeof(struct can_frame)) == 16 => ‘legacy’ CAN frame
    #define CANFD_MTU (sizeof(struct canfd_frame)) == 72 => CAN FD frame

4.1 RAW protocol sockets with can_filters (SOCK_RAW)

Using CAN_RAW sockets is extensively comparable to the commonly
known access to CAN character devices. To meet the new possibilities
provided by the multi user SocketCAN approach, some reasonable
defaults are set at RAW socket binding time:

  • The filters are set to exactly one filter receiving everything

  • The socket only receives valid data frames (=> no error message frames)

  • The loopback of sent CAN frames is enabled (see chapter 3.2)

  • The socket does not receive its own sent frames (in loopback mode)

    These default settings may be changed before or after binding the socket.
    To use the referenced definitions of the socket options for CAN_RAW
    sockets, include <linux/can/raw.h>.

4.1.1 RAW socket option CAN_RAW_FILTER

The reception of CAN frames using CAN_RAW sockets can be controlled
by defining 0 .. n filters with the CAN_RAW_FILTER socket option.

The CAN filter structure is defined in include/linux/can.h:

struct can_filter {
        canid_t can_id;
        canid_t can_mask;
};

A filter matches, when

<received_can_id> & mask == can_id & mask

which is analogous to known CAN controllers hardware filter semantics.
The filter can be inverted in this semantic, when the CAN_INV_FILTER
bit is set in can_id element of the can_filter structure. In
contrast to CAN controller hardware filters the user may set 0 .. n
receive filters for each open socket separately:

struct can_filter rfilter[2];

rfilter[0].can_id   = 0x123;
rfilter[0].can_mask = CAN_SFF_MASK;
rfilter[1].can_id   = 0x200;
rfilter[1].can_mask = 0x700;

setsockopt(s, SOL_CAN_RAW, CAN_RAW_FILTER, &rfilter, sizeof(rfilter));

To disable the reception of CAN frames on the selected CAN_RAW socket:

setsockopt(s, SOL_CAN_RAW, CAN_RAW_FILTER, NULL, 0);

To set the filters to zero filters is quite obsolete as not read
data causes the raw socket to discard the received CAN frames. But
having this ‘send only’ use-case we may remove the receive list in the
Kernel to save a little (really a very little!) CPU usage.

4.1.2 RAW socket option CAN_RAW_ERR_FILTER

As described in chapter 3.4 the CAN interface driver can generate so
called Error Message Frames that can optionally be passed to the user
application in the same way as other CAN frames. The possible
errors are divided into different error classes that may be filtered
using the appropriate error mask. To register for every possible
error condition CAN_ERR_MASK can be used as value for the error mask.
The values for the error mask are defined in linux/can/error.h .

can_err_mask_t err_mask = ( CAN_ERR_TX_TIMEOUT | CAN_ERR_BUSOFF );

setsockopt(s, SOL_CAN_RAW, CAN_RAW_ERR_FILTER,
           &err_mask, sizeof(err_mask));

4.1.3 RAW socket option CAN_RAW_LOOPBACK

To meet multi user needs the local loopback is enabled by default
(see chapter 3.2 for details). But in some embedded use-cases
(e.g. when only one application uses the CAN bus) this loopback
functionality can be disabled (separately for each socket):

int loopback = 0; /* 0 = disabled, 1 = enabled (default) */

setsockopt(s, SOL_CAN_RAW, CAN_RAW_LOOPBACK, &loopback, sizeof(loopback));

4.1.4 RAW socket option CAN_RAW_RECV_OWN_MSGS

When the local loopback is enabled, all the sent CAN frames are
looped back to the open CAN sockets that registered for the CAN
frames’ CAN-ID on this given interface to meet the multi user
needs. The reception of the CAN frames on the same socket that was
sending the CAN frame is assumed to be unwanted and therefore
disabled by default. This default behaviour may be changed on
demand:

int recv_own_msgs = 1; /* 0 = disabled (default), 1 = enabled */

setsockopt(s, SOL_CAN_RAW, CAN_RAW_RECV_OWN_MSGS,
           &recv_own_msgs, sizeof(recv_own_msgs));

4.1.5 RAW socket option CAN_RAW_FD_FRAMES

CAN FD support in CAN_RAW sockets can be enabled with a new socket option
CAN_RAW_FD_FRAMES which is off by default. When the new socket option is
not supported by the CAN_RAW socket (e.g. on older kernels), switching the
CAN_RAW_FD_FRAMES option returns the error -ENOPROTOOPT.

Once CAN_RAW_FD_FRAMES is enabled the application can send both CAN frames
and CAN FD frames. OTOH the application has to handle CAN and CAN FD frames
when reading from the socket.

CAN_RAW_FD_FRAMES enabled:  CAN_MTU and CANFD_MTU are allowed
CAN_RAW_FD_FRAMES disabled: only CAN_MTU is allowed (default)

Example:
[ remember: CANFD_MTU == sizeof(struct canfd_frame) ]

struct canfd_frame cfd;

nbytes = read(s, &cfd, CANFD_MTU);

if (nbytes == CANFD_MTU) {
        printf("got CAN FD frame with length %d\n", cfd.len);
    /* cfd.flags contains valid data */
} else if (nbytes == CAN_MTU) {
        printf("got legacy CAN frame with length %d\n", cfd.len);
    /* cfd.flags is undefined */
} else {
        fprintf(stderr, "read: invalid CAN(FD) frame\n");
        return 1;
}

/* the content can be handled independently from the received MTU size */

printf("can_id: %X data length: %d data: ", cfd.can_id, cfd.len);
for (i = 0; i < cfd.len; i++)
        printf("%02X ", cfd.data[i]);

When reading with size CANFD_MTU only returns CAN_MTU bytes that have
been received from the socket a legacy CAN frame has been read into the
provided CAN FD structure. Note that the canfd_frame.flags data field is
not specified in the struct can_frame and therefore it is only valid in
CANFD_MTU sized CAN FD frames.

As long as the payload length is <=8 the received CAN frames from CAN FD
capable CAN devices can be received and read by legacy sockets too. When
user-generated CAN FD frames have a payload length <=8 these can be send
by legacy CAN network interfaces too. Sending CAN FD frames with payload
length > 8 to a legacy CAN network interface returns an -EMSGSIZE error.

Implementation hint for new CAN applications:

To build a CAN FD aware application use struct canfd_frame as basic CAN
data structure for CAN_RAW based applications. When the application is
executed on an older Linux kernel and switching the CAN_RAW_FD_FRAMES
socket option returns an error: No problem. You’ll get legacy CAN frames
or CAN FD frames and can process them the same way.

When sending to CAN devices make sure that the device is capable to handle
CAN FD frames by checking if the device maximum transfer unit is CANFD_MTU.
The CAN device MTU can be retrieved e.g. with a SIOCGIFMTU ioctl() syscall.

4.1.6 RAW socket option CAN_RAW_JOIN_FILTERS

The CAN_RAW socket can set multiple CAN identifier specific filters that
lead to multiple filters in the af_can.c filter processing. These filters
are indenpendent from each other which leads to logical OR’ed filters when
applied (see 4.1.1).

This socket option joines the given CAN filters in the way that only CAN
frames are passed to user space that matched all given CAN filters. The
semantic for the applied filters is therefore changed to a logical AND.

This is useful especially when the filterset is a combination of filters
where the CAN_INV_FILTER flag is set in order to notch single CAN IDs or
CAN ID ranges from the incoming traffic.

4.1.7 RAW socket returned message flags

When using recvmsg() call, the msg->msg_flags may contain following flags:

MSG_DONTROUTE: set when the received frame was created on the local host.

MSG_CONFIRM: set when the frame was sent via the socket it is received on.
  This flag can be interpreted as a 'transmission confirmation' when the
  CAN driver supports the echo of frames on driver level, see 3.2 and 6.2.
  In order to receive such messages, CAN_RAW_RECV_OWN_MSGS must be set.

4.2 Broadcast Manager protocol sockets (SOCK_DGRAM)
4.3 connected transport protocols (SOCK_SEQPACKET)
4.4 unconnected transport protocols (SOCK_DGRAM)

  1. Socket CAN core module

The Socket CAN core module implements the protocol family
PF_CAN. CAN protocol modules are loaded by the core module at
runtime. The core module provides an interface for CAN protocol
modules to subscribe needed CAN IDs (see chapter 3.1).

5.1 can.ko module params

  • stats_timer: To calculate the Socket CAN core statistics
    (e.g. current/maximum frames per second) this 1 second timer is
    invoked at can.ko module start time by default. This timer can be
    disabled by using stattimer=0 on the module commandline.

  • debug: (removed since SocketCAN SVN r546)

5.2 procfs content

As described in chapter 3.1 the Socket CAN core uses several filter
lists to deliver received CAN frames to CAN protocol modules. These
receive lists, their filters and the count of filter matches can be
checked in the appropriate receive list. All entries contain the
device and a protocol module identifier:

foo@bar:~$ cat /proc/net/can/rcvlist_all

receive list 'rx_all':
  (vcan3: no entry)
  (vcan2: no entry)
  (vcan1: no entry)
  device   can_id   can_mask  function  userdata   matches  ident
   vcan0     000    00000000  f88e6370  f6c6f400         0  raw
  (any: no entry)

In this example an application requests any CAN traffic from vcan0.

rcvlist_all - list for unfiltered entries (no filter operations)
rcvlist_eff - list for single extended frame (EFF) entries
rcvlist_err - list for error message frames masks
rcvlist_fil - list for mask/value filters
rcvlist_inv - list for mask/value filters (inverse semantic)
rcvlist_sff - list for single standard frame (SFF) entries

Additional procfs files in /proc/net/can

stats       - Socket CAN core statistics (rx/tx frames, match ratios, ...)
reset_stats - manual statistic reset
version     - prints the Socket CAN core version and the ABI version

5.3 writing own CAN protocol modules

To implement a new protocol in the protocol family PF_CAN a new
protocol has to be defined in include/linux/can.h .
The prototypes and definitions to use the Socket CAN core can be
accessed by including include/linux/can/core.h .
In addition to functions that register the CAN protocol and the
CAN device notifier chain there are functions to subscribe CAN
frames received by CAN interfaces and to send CAN frames:

can_rx_register   - subscribe CAN frames from a specific interface
can_rx_unregister - unsubscribe CAN frames from a specific interface
can_send          - transmit a CAN frame (optional with local loopback)

For details see the kerneldoc documentation in net/can/af_can.c or
the source code of net/can/raw.c or net/can/bcm.c .

  1. CAN network drivers

Writing a CAN network device driver is much easier than writing a
CAN character device driver. Similar to other known network device
drivers you mainly have to deal with:

  • TX: Put the CAN frame from the socket buffer to the CAN controller.

  • RX: Put the CAN frame from the CAN controller to the socket buffer.

    See e.g. at Documentation/networking/netdevices.txt . The differences
    for writing CAN network device driver are described below:

6.1 general settings

dev->type  = ARPHRD_CAN; /* the netdevice hardware type */
dev->flags = IFF_NOARP;  /* CAN has no arp */

dev->mtu = CAN_MTU; /* sizeof(struct can_frame) -> legacy CAN interface */

or alternative, when the controller supports CAN with flexible data rate:
dev->mtu = CANFD_MTU; /* sizeof(struct canfd_frame) -> CAN FD interface */

The struct can_frame or struct canfd_frame is the payload of each socket
buffer (skbuff) in the protocol family PF_CAN.

6.2 local loopback of sent frames

As described in chapter 3.2 the CAN network device driver should
support a local loopback functionality similar to the local echo
e.g. of tty devices. In this case the driver flag IFF_ECHO has to be
set to prevent the PF_CAN core from locally echoing sent frames
(aka loopback) as fallback solution:

dev->flags = (IFF_NOARP | IFF_ECHO);

6.3 CAN controller hardware filters

To reduce the interrupt load on deep embedded systems some CAN
controllers support the filtering of CAN IDs or ranges of CAN IDs.
These hardware filter capabilities vary from controller to
controller and have to be identified as not feasible in a multi-user
networking approach. The use of the very controller specific
hardware filters could make sense in a very dedicated use-case, as a
filter on driver level would affect all users in the multi-user
system. The high efficient filter sets inside the PF_CAN core allow
to set different multiple filters for each socket separately.
Therefore the use of hardware filters goes to the category ‘handmade
tuning on deep embedded systems’. The author is running a MPC603e
@133MHz with four SJA1000 CAN controllers from 2002 under heavy bus
load without any problems …

6.4 The virtual CAN driver (vcan)

Similar to the network loopback devices, vcan offers a virtual local
CAN interface. A full qualified address on CAN consists of

  • a unique CAN Identifier (CAN ID)

  • the CAN bus this CAN ID is transmitted on (e.g. can0)

    so in common use cases more than one virtual CAN interface is needed.

    The virtual CAN interfaces allow the transmission and reception of CAN
    frames without real CAN controller hardware. Virtual CAN network
    devices are usually named ‘vcanX’, like vcan0 vcan1 vcan2 …
    When compiled as a module the virtual CAN driver module is called vcan.ko

    Since Linux Kernel version 2.6.24 the vcan driver supports the Kernel
    netlink interface to create vcan network devices. The creation and
    removal of vcan network devices can be managed with the ip(8) tool:

  • Create a virtual CAN network interface:
    $ ip link add type vcan

  • Create a virtual CAN network interface with a specific name ‘vcan42’:
    $ ip link add dev vcan42 type vcan

  • Remove a (virtual CAN) network interface ‘vcan42’:
    $ ip link del vcan42

6.5 The CAN network device driver interface

The CAN network device driver interface provides a generic interface
to setup, configure and monitor CAN network devices. The user can then
configure the CAN device, like setting the bit-timing parameters, via
the netlink interface using the program “ip” from the “IPROUTE2”
utility suite. The following chapter describes briefly how to use it.
Furthermore, the interface uses a common data structure and exports a
set of common functions, which all real CAN network device drivers
should use. Please have a look to the SJA1000 or MSCAN driver to
understand how to use them. The name of the module is can-dev.ko.

6.5.1 Netlink interface to set/get devices properties

The CAN device must be configured via netlink interface. The supported
netlink message types are defined and briefly described in
“include/linux/can/netlink.h”. CAN link support for the program “ip”
of the IPROUTE2 utility suite is available and it can be used as shown
below:

  • Setting CAN device properties:

    $ ip link set can0 type can help
    Usage: ip link set DEVICE type can

    [ bitrate BITRATE [ sample-point SAMPLE-POINT] ] |
    [ tq TQ prop-seg PROP_SEG phase-seg1 PHASE-SEG1
       phase-seg2 PHASE-SEG2 [ sjw SJW ] ]
    
    [ loopback { on | off } ]
    [ listen-only { on | off } ]
    [ triple-sampling { on | off } ]
    
    [ restart-ms TIME-MS ]
    [ restart ]
    
    Where: BITRATE       := { 1..1000000 }
           SAMPLE-POINT  := { 0.000..0.999 }
           TQ            := { NUMBER }
           PROP-SEG      := { 1..8 }
           PHASE-SEG1    := { 1..8 }
           PHASE-SEG2    := { 1..8 }
           SJW           := { 1..4 }
           RESTART-MS    := { 0 | NUMBER }
    
  • Display CAN device details and statistics:

    $ ip -details -statistics link show can0
    2: can0: <NOARP,UP,LOWER_UP,ECHO> mtu 16 qdisc pfifo_fast state UP qlen 10
    link/can
    can state ERROR-ACTIVE restart-ms 100
    bitrate 125000 sample_point 0.875
    tq 125 prop-seg 6 phase-seg1 7 phase-seg2 2 sjw 1
    sja1000: tseg1 1..16 tseg2 1..8 sjw 1..4 brp 1..64 brp-inc 1
    clock 8000000
    re-started bus-errors arbit-lost error-warn error-pass bus-off
    41 17457 0 41 42 41
    RX: bytes packets errors dropped overrun mcast
    140859 17608 17457 0 0 0
    TX: bytes packets errors dropped carrier collsns
    861 112 0 41 0 0

    More info to the above output:


    Shows the list of selected CAN controller modes: LOOPBACK,
    LISTEN-ONLY, or TRIPLE-SAMPLING.

    “state ERROR-ACTIVE”
    The current state of the CAN controller: “ERROR-ACTIVE”,
    “ERROR-WARNING”, “ERROR-PASSIVE”, “BUS-OFF” or “STOPPED”

    “restart-ms 100”
    Automatic restart delay time. If set to a non-zero value, a
    restart of the CAN controller will be triggered automatically
    in case of a bus-off condition after the specified delay time
    in milliseconds. By default it’s off.

    “bitrate 125000 sample_point 0.875”
    Shows the real bit-rate in bits/sec and the sample-point in the
    range 0.000..0.999. If the calculation of bit-timing parameters
    is enabled in the kernel (CONFIG_CAN_CALC_BITTIMING=y), the
    bit-timing can be defined by setting the “bitrate” argument.
    Optionally the “sample-point” can be specified. By default it’s
    0.000 assuming CIA-recommended sample-points.

    “tq 125 prop-seg 6 phase-seg1 7 phase-seg2 2 sjw 1”
    Shows the time quanta in ns, propagation segment, phase buffer
    segment 1 and 2 and the synchronisation jump width in units of
    tq. They allow to define the CAN bit-timing in a hardware
    independent format as proposed by the Bosch CAN 2.0 spec (see
    chapter 8 of http://www.semiconductors.bosch.de/pdf/can2spec.pdf).

    “sja1000: tseg1 1..16 tseg2 1..8 sjw 1..4 brp 1..64 brp-inc 1
    clock 8000000”
    Shows the bit-timing constants of the CAN controller, here the
    “sja1000”. The minimum and maximum values of the time segment 1
    and 2, the synchronisation jump width in units of tq, the
    bitrate pre-scaler and the CAN system clock frequency in Hz.
    These constants could be used for user-defined (non-standard)
    bit-timing calculation algorithms in user-space.

    “re-started bus-errors arbit-lost error-warn error-pass bus-off”
    Shows the number of restarts, bus and arbitration lost errors,
    and the state changes to the error-warning, error-passive and
    bus-off state. RX overrun errors are listed in the “overrun”
    field of the standard network statistics.

6.5.2 Setting the CAN bit-timing

The CAN bit-timing parameters can always be defined in a hardware
independent format as proposed in the Bosch CAN 2.0 specification
specifying the arguments “tq”, “prop_seg”, “phase_seg1”, “phase_seg2”
and “sjw”:

$ ip link set canX type can tq 125 prop-seg 6 \
            phase-seg1 7 phase-seg2 2 sjw 1

If the kernel option CONFIG_CAN_CALC_BITTIMING is enabled, CIA
recommended CAN bit-timing parameters will be calculated if the bit-
rate is specified with the argument “bitrate”:

$ ip link set canX type can bitrate 125000

Note that this works fine for the most common CAN controllers with
standard bit-rates but may fail for exotic bit-rates or CAN system
clock frequencies. Disabling CONFIG_CAN_CALC_BITTIMING saves some
space and allows user-space tools to solely determine and set the
bit-timing parameters. The CAN controller specific bit-timing
constants can be used for that purpose. They are listed by the
following command:

$ ip -details link show can0
...
  sja1000: clock 8000000 tseg1 1..16 tseg2 1..8 sjw 1..4 brp 1..64 brp-inc 1

6.5.3 Starting and stopping the CAN network device

A CAN network device is started or stopped as usual with the command
“ifconfig canX up/down” or “ip link set canX up/down”. Be aware that
you must define proper bit-timing parameters for real CAN devices
before you can start it to avoid error-prone default settings:

$ ip link set canX up type can bitrate 125000

A device may enter the “bus-off” state if too much errors occurred on
the CAN bus. Then no more messages are received or sent. An automatic
bus-off recovery can be enabled by setting the “restart-ms” to a
non-zero value, e.g.:

$ ip link set canX type can restart-ms 100

Alternatively, the application may realize the “bus-off” condition
by monitoring CAN error message frames and do a restart when
appropriate with the command:

$ ip link set canX type can restart

Note that a restart will also create a CAN error message frame (see
also chapter 3.4).

6.6 CAN FD (flexible data rate) driver support

CAN FD capable CAN controllers support two different bitrates for the
arbitration phase and the payload phase of the CAN FD frame. Therefore a
second bittiming has to be specified in order to enable the CAN FD bitrate.

Additionally CAN FD capable CAN controllers support up to 64 bytes of
payload. The representation of this length in can_frame.can_dlc and
canfd_frame.len for userspace applications and inside the Linux network
layer is a plain value from 0 .. 64 instead of the CAN ‘data length code’.
The data length code was a 1:1 mapping to the payload length in the legacy
CAN frames anyway. The payload length to the bus-relevant DLC mapping is
only performed inside the CAN drivers, preferably with the helper
functions can_dlc2len() and can_len2dlc().

The CAN netdevice driver capabilities can be distinguished by the network
devices maximum transfer unit (MTU):

MTU = 16 (CAN_MTU) => sizeof(struct can_frame) => ‘legacy’ CAN device
MTU = 72 (CANFD_MTU) => sizeof(struct canfd_frame) => CAN FD capable device

The CAN device MTU can be retrieved e.g. with a SIOCGIFMTU ioctl() syscall.
N.B. CAN FD capable devices can also handle and send legacy CAN frames.

FIXME: Add details about the CAN FD controller configuration when available.

6.7 Supported CAN hardware

Please check the “Kconfig” file in “drivers/net/can” to get an actual
list of the support CAN hardware. On the Socket CAN project website
(see chapter 7) there might be further drivers available, also for
older kernel versions.

  1. Socket CAN resources

You can find further resources for Socket CAN like user space tools,
support for old kernel versions, more drivers, mailing lists, etc.
at the BerliOS OSS project website for Socket CAN:

http://developer.berlios.de/projects/socketcan

If you have questions, bug fixes, etc., don’t hesitate to post them to
the Socketcan-Users mailing list. But please search the archives first.

  1. Credits

Oliver Hartkopp (PF_CAN core, filters, drivers, bcm, SJA1000 driver)
Urs Thuermann (PF_CAN core, kernel integration, socket interfaces, raw, vcan)
Jan Kizka (RT-SocketCAN core, Socket-API reconciliation)
Wolfgang Grandegger (RT-SocketCAN core & drivers, Raw Socket-API reviews,
CAN device driver interface, MSCAN driver)
Robert Schwebel (design reviews, PTXdist integration)
Marc Kleine-Budde (design reviews, Kernel 2.6 cleanups, drivers)
Benedikt Spranger (reviews)
Thomas Gleixner (LKML reviews, coding style, posting hints)
Andrey Volkov (kernel subtree structure, ioctls, MSCAN driver)
Matthias Brukner (first SJA1000 CAN netdevice implementation Q2/2003)
Klaus Hitschler (PEAK driver integration)
Uwe Koppe (CAN netdevices with PF_PACKET approach)
Michael Schulze (driver layer loopback requirement, RT CAN drivers review)
Pavel Pisa (Bit-timing calculation)
Sascha Hauer (SJA1000 platform driver)
Sebastian Haas (SJA1000 EMS PCI driver)
Markus Plessing (SJA1000 EMS PCI driver)
Per Dalen (SJA1000 Kvaser PCI driver)
Sam Ravnborg (reviews, coding style, kbuild help)