phonet.txt 8.4 KB
Newer Older
1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23
Linux Phonet protocol family
============================

Introduction
------------

Phonet is a packet protocol used by Nokia cellular modems for both IPC
and RPC. With the Linux Phonet socket family, Linux host processes can
receive and send messages from/to the modem, or any other external
device attached to the modem. The modem takes care of routing.

Phonet packets can be exchanged through various hardware connections
depending on the device, such as:
  - USB with the CDC Phonet interface,
  - infrared,
  - Bluetooth,
  - an RS232 serial port (with a dedicated "FBUS" line discipline),
  - the SSI bus with some TI OMAP processors.


Packets format
--------------

24
Phonet packets have a common header as follows:
25 26 27 28 29 30 31 32 33 34 35

  struct phonethdr {
    uint8_t  pn_media;  /* Media type (link-layer identifier) */
    uint8_t  pn_rdev;   /* Receiver device ID */
    uint8_t  pn_sdev;   /* Sender device ID */
    uint8_t  pn_res;    /* Resource ID or function */
    uint16_t pn_length; /* Big-endian message byte length (minus 6) */
    uint8_t  pn_robj;   /* Receiver object ID */
    uint8_t  pn_sobj;   /* Sender object ID */
  };

36 37 38
On Linux, the link-layer header includes the pn_media byte (see below).
The next 7 bytes are part of the network-layer header.

39
The device ID is split: the 6 higher-order bits constitute the device
40 41
address, while the 2 lower-order bits are used for multiplexing, as are
the 8-bit object identifiers. As such, Phonet can be considered as a
42 43 44
network layer with 6 bits of address space and 10 bits for transport
protocol (much like port numbers in IP world).

45 46
The modem always has address number zero. All other device have a their
own 6-bit address.
47 48 49 50 51 52 53 54


Link layer
----------

Phonet links are always point-to-point links. The link layer header
consists of a single Phonet media type byte. It uniquely identifies the
link through which the packet is transmitted, from the modem's
55 56 57 58 59 60 61 62 63 64 65 66
perspective. Each Phonet network device shall prepend and set the media
type byte as appropriate. For convenience, a common phonet_header_ops
link-layer header operations structure is provided. It sets the
media type according to the network device hardware address.

Linux Phonet network interfaces support a dedicated link layer packets
type (ETH_P_PHONET) which is out of the Ethernet type range. They can
only send and receive Phonet packets.

The virtual TUN tunnel device driver can also be used for Phonet. This
requires IFF_TUN mode, _without_ the IFF_NO_PI flag. In this case,
there is no link-layer header, so there is no Phonet media type byte.
67 68 69 70 71 72 73 74 75 76 77 78 79 80 81 82 83 84 85 86 87 88 89 90 91 92 93 94 95 96 97 98 99 100 101 102 103 104 105 106 107 108 109 110 111 112 113 114

Note that Phonet interfaces are not allowed to re-order packets, so
only the (default) Linux FIFO qdisc should be used with them.


Network layer
-------------

The Phonet socket address family maps the Phonet packet header:

  struct sockaddr_pn {
    sa_family_t spn_family;    /* AF_PHONET */
    uint8_t     spn_obj;       /* Object ID */
    uint8_t     spn_dev;       /* Device ID */
    uint8_t     spn_resource;  /* Resource or function */
    uint8_t     spn_zero[...]; /* Padding */
  };

The resource field is only used when sending and receiving;
It is ignored by bind() and getsockname().


Low-level datagram protocol
---------------------------

Applications can send Phonet messages using the Phonet datagram socket
protocol from the PF_PHONET family. Each socket is bound to one of the
2^10 object IDs available, and can send and receive packets with any
other peer.

  struct sockaddr_pn addr = { .spn_family = AF_PHONET, };
  ssize_t len;
  socklen_t addrlen = sizeof(addr);
  int fd;

  fd = socket(PF_PHONET, SOCK_DGRAM, 0);
  bind(fd, (struct sockaddr *)&addr, sizeof(addr));
  /* ... */

  sendto(fd, msg, msglen, 0, (struct sockaddr *)&addr, sizeof(addr));
  len = recvfrom(fd, buf, sizeof(buf), 0,
                 (struct sockaddr *)&addr, &addrlen);

This protocol follows the SOCK_DGRAM connection-less semantics.
However, connect() and getpeername() are not supported, as they did
not seem useful with Phonet usages (could be added easily).


115 116 117 118 119 120 121 122 123 124 125 126 127 128 129 130
Resource subscription
---------------------

A Phonet datagram socket can be subscribed to any number of 8-bits
Phonet resources, as follow:

  uint32_t res = 0xXX;
  ioctl(fd, SIOCPNADDRESOURCE, &res);

Subscription is similarly cancelled using the SIOCPNDELRESOURCE I/O
control request, or when the socket is closed.

Note that no more than one socket can be subcribed to any given
resource at a time. If not, ioctl() will return EBUSY.


131 132 133 134 135 136 137 138 139 140 141 142 143 144 145 146 147 148 149 150 151 152 153 154 155 156 157 158 159 160 161 162 163 164
Phonet Pipe protocol
--------------------

The Phonet Pipe protocol is a simple sequenced packets protocol
with end-to-end congestion control. It uses the passive listening
socket paradigm. The listening socket is bound to an unique free object
ID. Each listening socket can handle up to 255 simultaneous
connections, one per accept()'d socket.

  int lfd, cfd;

  lfd = socket(PF_PHONET, SOCK_SEQPACKET, PN_PROTO_PIPE);
  listen (lfd, INT_MAX);

  /* ... */
  cfd = accept(lfd, NULL, NULL);
  for (;;)
  {
    char buf[...];
    ssize_t len = read(cfd, buf, sizeof(buf));

    /* ... */

    write(cfd, msg, msglen);
  }

Connections are established between two endpoints by a "third party"
application. This means that both endpoints are passive; so connect()
is not possible.

WARNING:
When polling a connected pipe socket for writability, there is an
intrinsic race condition whereby writability might be lost between the
polling and the writing system calls. In this case, the socket will
R
Randy Macleod 已提交
165 166
block until write becomes possible again, unless non-blocking mode
is enabled.
167 168 169 170 171 172 173 174 175 176 177 178 179 180 181 182 183 184


The pipe protocol provides two socket options at the SOL_PNPIPE level:

  PNPIPE_ENCAP accepts one integer value (int) of:

    PNPIPE_ENCAP_NONE: The socket operates normally (default).

    PNPIPE_ENCAP_IP: The socket is used as a backend for a virtual IP
      interface. This requires CAP_NET_ADMIN capability. GPRS data
      support on Nokia modems can use this. Note that the socket cannot
      be reliably poll()'d or read() from while in this mode.

  PNPIPE_IFINDEX is a read-only integer value. It contains the
    interface index of the network interface created by PNPIPE_ENCAP,
    or zero if encapsulation is off.


185 186 187 188 189 190 191 192 193 194 195 196 197 198 199 200 201 202 203 204 205 206 207 208 209 210 211 212 213 214 215 216 217 218 219 220 221 222 223 224 225 226 227 228 229 230 231 232 233 234 235 236 237
Phonet Pipe-controller Implementation
-------------------------------------

Phonet Pipe-controller is enabled by selecting the CONFIG_PHONET_PIPECTRLR Kconfig
option. It is useful when communicating with those Nokia Modems which do not
implement Pipe controller in them e.g. Nokia Slim Modem used in ST-Ericsson
U8500 platform.

The implementation is based on the Data Connection Establishment Sequence
depicted in 'Nokia Wireless Modem API - Wireless_modem_user_guide.pdf'
document.

It allows a phonet sequenced socket (host-pep) to initiate a Pipe connection
between itself and a remote pipe-end point (e.g. modem).

The implementation adds socket options at SOL_PNPIPE level:

 PNPIPE_CREATE
	It accepts an integer argument where-in
		lower order 16 bits: pn_dev and pn_port pair for remote pep.
		higher order 16 bits: 8 bit pipe-handle

	It sends a PNS_PEP_CONNECT_REQ on sequenced socket itself. On getting
	PNS_PEP_CONNECT_RESP, it sends PNS_PEP_CONNECT_REQ to remote pep. On
	getting response from remote pep, it selects the best possible Flow
	control mechanism supported by remote-pep (modem) and then it sends
	PNS_PEP_CREATED_IND to the sequenced socket and to the remote pep.

	It then updates the pipe state associated with the sequenced socket to
	be PIPE_DISABLED.

  PNPIPE_ENABLE
	It follows the same sequence as above for enabling a pipe by sending
	PNS_PEP_ENABLE_REQ initially and then sending PNS_PEP_ENABLED_IND after
	getting responses from sequenced socket and remote-pep.
	It will also update the pipe state associated with the sequenced socket
	to PIPE_ENABLED.

   PNPIPE_DESTROY
	This will send out PNS_PEP_DISCONNECT_REQ on the sequenced socket and
	the remote pep.
	It will also update the pipe state associated with the sequenced socket
	to PIPE_IDLE

   PNPIPE_INQ
	This getsocktopt allows the user-space running on the sequenced socket
	to examine the pipe state associated with that socket ie. whether the
	pipe is created (PIPE_DISABLED) or enabled (PIPE_ENABLED) or disabled
	(PIPE_DISABLED) or no pipe exists (PIPE_IDLE).

After a pipe has been created and enabled successfully, the Pipe data can be
exchanged between the host-pep and remote-pep (modem).

238 239 240 241 242 243 244
Authors
-------

Linux Phonet was initially written by Sakari Ailus.
Other contributors include Mikä Liljeberg, Andras Domokos,
Carlos Chinea and Rémi Denis-Courmont.
Copyright (C) 2008 Nokia Corporation.