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linux/Documentation/networking/iso15765-2.rst
Francesco Valla 67711e0425 Documentation: networking: document ISO 15765-2
Document basic concepts, APIs and behaviour of the ISO 15675-2 (ISO-TP)
CAN stack.

Signed-off-by: Francesco Valla <valla.francesco@gmail.com>
Reviewed-by: Bagas Sanjaya <bagasdotme@gmail.com>
Reviewed-by: Vincent Mailhol <mailhol.vincent@wanadoo.fr>
Link: https://lore.kernel.org/all/20240501092413.414700-2-valla.francesco@gmail.com
Signed-off-by: Marc Kleine-Budde <mkl@pengutronix.de>
2024-06-20 11:56:22 +02:00

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13 KiB
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.. SPDX-License-Identifier: (GPL-2.0 OR BSD-3-Clause)
====================
ISO 15765-2 (ISO-TP)
====================
Overview
========
ISO 15765-2, also known as ISO-TP, is a transport protocol specifically defined
for diagnostic communication on CAN. It is widely used in the automotive
industry, for example as the transport protocol for UDSonCAN (ISO 14229-3) or
emission-related diagnostic services (ISO 15031-5).
ISO-TP can be used both on CAN CC (aka Classical CAN) and CAN FD (CAN with
Flexible Datarate) based networks. It is also designed to be compatible with a
CAN network using SAE J1939 as data link layer (however, this is not a
requirement).
Specifications used
-------------------
* ISO 15765-2:2024 : Road vehicles - Diagnostic communication over Controller
Area Network (DoCAN). Part 2: Transport protocol and network layer services.
Addressing
----------
In its simplest form, ISO-TP is based on two kinds of addressing modes for the
nodes connected to the same network:
* physical addressing is implemented by two node-specific addresses and is used
in 1-to-1 communication.
* functional addressing is implemented by one node-specific address and is used
in 1-to-N communication.
Three different addressing formats can be employed:
* "normal" : each address is represented simply by a CAN ID.
* "extended": each address is represented by a CAN ID plus the first byte of
the CAN payload; both the CAN ID and the byte inside the payload shall be
different between two addresses.
* "mixed": each address is represented by a CAN ID plus the first byte of
the CAN payload; the CAN ID is different between two addresses, but the
additional byte is the same.
Transport protocol and associated frame types
---------------------------------------------
When transmitting data using the ISO-TP protocol, the payload can either fit
inside one single CAN message or not, also considering the overhead the protocol
is generating and the optional extended addressing. In the first case, the data
is transmitted at once using a so-called Single Frame (SF). In the second case,
ISO-TP defines a multi-frame protocol, in which the sender provides (through a
First Frame - FF) the PDU length which is to be transmitted and also asks for a
Flow Control (FC) frame, which provides the maximum supported size of a macro
data block (``blocksize``) and the minimum time between the single CAN messages
composing such block (``stmin``). Once this information has been received, the
sender starts to send frames containing fragments of the data payload (called
Consecutive Frames - CF), stopping after every ``blocksize``-sized block to wait
confirmation from the receiver which should then send another Flow Control
frame to inform the sender about its availability to receive more data.
How to Use ISO-TP
=================
As with others CAN protocols, the ISO-TP stack support is built into the
Linux network subsystem for the CAN bus, aka. Linux-CAN or SocketCAN, and
thus follows the same socket API.
Creation and basic usage of an ISO-TP socket
--------------------------------------------
To use the ISO-TP stack, ``#include <linux/can/isotp.h>`` shall be used. A
socket can then be created using the ``PF_CAN`` protocol family, the
``SOCK_DGRAM`` type (as the underlying protocol is datagram-based by design)
and the ``CAN_ISOTP`` protocol:
.. code-block:: C
s = socket(PF_CAN, SOCK_DGRAM, CAN_ISOTP);
After the socket has been successfully created, ``bind(2)`` shall be called to
bind the socket to the desired CAN interface; to do so:
* a TX CAN ID shall be specified as part of the sockaddr supplied to the call
itself.
* a RX CAN ID shall also be specified, unless broadcast flags have been set
through socket option (explained below).
Once bound to an interface, the socket can be read from and written to using
the usual ``read(2)`` and ``write(2)`` system calls, as well as ``send(2)``,
``sendmsg(2)``, ``recv(2)`` and ``recvmsg(2)``.
Unlike the CAN_RAW socket API, only the ISO-TP data field (the actual payload)
is sent and received by the userspace application using these calls. The address
information and the protocol information are automatically filled by the ISO-TP
stack using the configuration supplied during socket creation. In the same way,
the stack will use the transport mechanism when required (i.e., when the size
of the data payload exceeds the MTU of the underlying CAN bus).
The sockaddr structure used for SocketCAN has extensions for use with ISO-TP,
as specified below:
.. code-block:: C
struct sockaddr_can {
sa_family_t can_family;
int can_ifindex;
union {
struct { canid_t rx_id, tx_id; } tp;
...
} can_addr;
}
* ``can_family`` and ``can_ifindex`` serve the same purpose as for other
SocketCAN sockets.
* ``can_addr.tp.rx_id`` specifies the receive (RX) CAN ID and will be used as
a RX filter.
* ``can_addr.tp.tx_id`` specifies the transmit (TX) CAN ID
ISO-TP socket options
---------------------
When creating an ISO-TP socket, reasonable defaults are set. Some options can
be modified with ``setsockopt(2)`` and/or read back with ``getsockopt(2)``.
General options
~~~~~~~~~~~~~~~
General socket options can be passed using the ``CAN_ISOTP_OPTS`` optname:
.. code-block:: C
struct can_isotp_options opts;
ret = setsockopt(s, SOL_CAN_ISOTP, CAN_ISOTP_OPTS, &opts, sizeof(opts))
where the ``can_isotp_options`` structure has the following contents:
.. code-block:: C
struct can_isotp_options {
u32 flags;
u32 frame_txtime;
u8 ext_address;
u8 txpad_content;
u8 rxpad_content;
u8 rx_ext_address;
};
* ``flags``: modifiers to be applied to the default behaviour of the ISO-TP
stack. Following flags are available:
* ``CAN_ISOTP_LISTEN_MODE``: listen only (do not send FC frames); normally
used as a testing feature.
* ``CAN_ISOTP_EXTEND_ADDR``: use the byte specified in ``ext_address`` as an
additional address component. This enables the "mixed" addressing format if
used alone, or the "extended" addressing format if used in conjunction with
``CAN_ISOTP_RX_EXT_ADDR``.
* ``CAN_ISOTP_TX_PADDING``: enable padding for transmitted frames, using
``txpad_content`` as value for the padding bytes.
* ``CAN_ISOTP_RX_PADDING``: enable padding for the received frames, using
``rxpad_content`` as value for the padding bytes.
* ``CAN_ISOTP_CHK_PAD_LEN``: check for correct padding length on the received
frames.
* ``CAN_ISOTP_CHK_PAD_DATA``: check padding bytes on the received frames
against ``rxpad_content``; if ``CAN_ISOTP_RX_PADDING`` is not specified,
this flag is ignored.
* ``CAN_ISOTP_HALF_DUPLEX``: force ISO-TP socket in half duplex mode
(that is, transport mechanism can only be incoming or outgoing at the same
time, not both).
* ``CAN_ISOTP_FORCE_TXSTMIN``: ignore stmin from received FC; normally
used as a testing feature.
* ``CAN_ISOTP_FORCE_RXSTMIN``: ignore CFs depending on rx stmin; normally
used as a testing feature.
* ``CAN_ISOTP_RX_EXT_ADDR``: use ``rx_ext_address`` instead of ``ext_address``
as extended addressing byte on the reception path. If used in conjunction
with ``CAN_ISOTP_EXTEND_ADDR``, this flag effectively enables the "extended"
addressing format.
* ``CAN_ISOTP_WAIT_TX_DONE``: wait until the frame is sent before returning
from ``write(2)`` and ``send(2)`` calls (i.e., blocking write operations).
* ``CAN_ISOTP_SF_BROADCAST``: use 1-to-N functional addressing (cannot be
specified alongside ``CAN_ISOTP_CF_BROADCAST``).
* ``CAN_ISOTP_CF_BROADCAST``: use 1-to-N transmission without flow control
(cannot be specified alongside ``CAN_ISOTP_SF_BROADCAST``).
NOTE: this is not covered by the ISO 15765-2 standard.
* ``CAN_ISOTP_DYN_FC_PARMS``: enable dynamic update of flow control
parameters.
* ``frame_txtime``: frame transmission time (defined as N_As/N_Ar inside the
ISO standard); if ``0``, the default (or the last set value) is used.
To set the transmission time to ``0``, the ``CAN_ISOTP_FRAME_TXTIME_ZERO``
macro (equal to 0xFFFFFFFF) shall be used.
* ``ext_address``: extended addressing byte, used if the
``CAN_ISOTP_EXTEND_ADDR`` flag is specified.
* ``txpad_content``: byte used as padding value for transmitted frames.
* ``rxpad_content``: byte used as padding value for received frames.
* ``rx_ext_address``: extended addressing byte for the reception path, used if
the ``CAN_ISOTP_RX_EXT_ADDR`` flag is specified.
Flow Control options
~~~~~~~~~~~~~~~~~~~~
Flow Control (FC) options can be passed using the ``CAN_ISOTP_RECV_FC`` optname
to provide the communication parameters for receiving ISO-TP PDUs.
.. code-block:: C
struct can_isotp_fc_options fc_opts;
ret = setsockopt(s, SOL_CAN_ISOTP, CAN_ISOTP_RECV_FC, &fc_opts, sizeof(fc_opts));
where the ``can_isotp_fc_options`` structure has the following contents:
.. code-block:: C
struct can_isotp_options {
u8 bs;
u8 stmin;
u8 wftmax;
};
* ``bs``: blocksize provided in flow control frames.
* ``stmin``: minimum separation time provided in flow control frames; can
have the following values (others are reserved):
* 0x00 - 0x7F : 0 - 127 ms
* 0xF1 - 0xF9 : 100 us - 900 us
* ``wftmax``: maximum number of wait frames provided in flow control frames.
Link Layer options
~~~~~~~~~~~~~~~~~~
Link Layer (LL) options can be passed using the ``CAN_ISOTP_LL_OPTS`` optname:
.. code-block:: C
struct can_isotp_ll_options ll_opts;
ret = setsockopt(s, SOL_CAN_ISOTP, CAN_ISOTP_LL_OPTS, &ll_opts, sizeof(ll_opts));
where the ``can_isotp_ll_options`` structure has the following contents:
.. code-block:: C
struct can_isotp_ll_options {
u8 mtu;
u8 tx_dl;
u8 tx_flags;
};
* ``mtu``: generated and accepted CAN frame type, can be equal to ``CAN_MTU``
for classical CAN frames or ``CANFD_MTU`` for CAN FD frames.
* ``tx_dl``: maximum payload length for transmitted frames, can have one value
among: 8, 12, 16, 20, 24, 32, 48, 64. Values above 8 only apply to CAN FD
traffic (i.e.: ``mtu = CANFD_MTU``).
* ``tx_flags``: flags set into ``struct canfd_frame.flags`` at frame creation.
Only applies to CAN FD traffic (i.e.: ``mtu = CANFD_MTU``).
Transmission stmin
~~~~~~~~~~~~~~~~~~
The transmission minimum separation time (stmin) can be forced using the
``CAN_ISOTP_TX_STMIN`` optname and providing an stmin value in microseconds as
a 32bit unsigned integer; this will overwrite the value sent by the receiver in
flow control frames:
.. code-block:: C
uint32_t stmin;
ret = setsockopt(s, SOL_CAN_ISOTP, CAN_ISOTP_TX_STMIN, &stmin, sizeof(stmin));
Reception stmin
~~~~~~~~~~~~~~~
The reception minimum separation time (stmin) can be forced using the
``CAN_ISOTP_RX_STMIN`` optname and providing an stmin value in microseconds as
a 32bit unsigned integer; received Consecutive Frames (CF) which timestamps
differ less than this value will be ignored:
.. code-block:: C
uint32_t stmin;
ret = setsockopt(s, SOL_CAN_ISOTP, CAN_ISOTP_RX_STMIN, &stmin, sizeof(stmin));
Multi-frame transport support
-----------------------------
The ISO-TP stack contained inside the Linux kernel supports the multi-frame
transport mechanism defined by the standard, with the following constraints:
* the maximum size of a PDU is defined by a module parameter, with an hard
limit imposed at build time.
* when a transmission is in progress, subsequent calls to ``write(2)`` will
block, while calls to ``send(2)`` will either block or fail depending on the
presence of the ``MSG_DONTWAIT`` flag.
* no support is present for sending "wait frames": whether a PDU can be fully
received or not is decided when the First Frame is received.
Errors
------
Following errors are reported to userspace:
RX path errors
~~~~~~~~~~~~~~
============ ===============================================================
-ETIMEDOUT timeout of data reception
-EILSEQ sequence number mismatch during a multi-frame reception
-EBADMSG data reception with wrong padding
============ ===============================================================
TX path errors
~~~~~~~~~~~~~~
========== =================================================================
-ECOMM flow control reception timeout
-EMSGSIZE flow control reception overflow
-EBADMSG flow control reception with wrong layout/padding
========== =================================================================
Examples
========
Basic node example
------------------
Following example implements a node using "normal" physical addressing, with
RX ID equal to 0x18DAF142 and a TX ID equal to 0x18DA42F1. All options are left
to their default.
.. code-block:: C
int s;
struct sockaddr_can addr;
int ret;
s = socket(PF_CAN, SOCK_DGRAM, CAN_ISOTP);
if (s < 0)
exit(1);
addr.can_family = AF_CAN;
addr.can_ifindex = if_nametoindex("can0");
addr.tp.tx_id = 0x18DA42F1 | CAN_EFF_FLAG;
addr.tp.rx_id = 0x18DAF142 | CAN_EFF_FLAG;
ret = bind(s, (struct sockaddr *)&addr, sizeof(addr));
if (ret < 0)
exit(1);
/* Data can now be received using read(s, ...) and sent using write(s, ...) */
Additional examples
-------------------
More complete (and complex) examples can be found inside the ``isotp*`` userland
tools, distributed as part of the ``can-utils`` utilities at:
https://github.com/linux-can/can-utils