[people/ms/u-boot.git] / doc / README.drivers.eth

-----------------------
 Ethernet Driver Guide
-----------------------

The networking stack in Das U-Boot is designed for multiple network devices
to be easily added and controlled at runtime.  This guide is meant for people
who wish to review the net driver stack with an eye towards implementing your
own ethernet device driver.  Here we will describe a new pseudo 'APE' driver.

------------------
 Driver Functions
------------------

All functions you will be implementing in this document have the return value
meaning of 0 for success and non-zero for failure.

 ----------
  Register
 ----------

When U-Boot initializes, it will call the common function eth_initialize().
This will in turn call the board-specific board_eth_init() (or if that fails,
the cpu-specific cpu_eth_init()).  These board-specific functions can do random
system handling, but ultimately they will call the driver-specific register
function which in turn takes care of initializing that particular instance.

Keep in mind that you should code the driver to avoid storing state in global
data as someone might want to hook up two of the same devices to one board.
Any such information that is specific to an interface should be stored in a
private, driver-defined data structure and pointed to by eth->priv (see below).

So the call graph at this stage would look something like:
board_init()
	eth_initialize()
		board_eth_init() / cpu_eth_init()
			driver_register()
				initialize eth_device
				eth_register()

At this point in time, the only thing you need to worry about is the driver's
register function.  The pseudo code would look something like:
int ape_register(bd_t *bis, int iobase)
{
	struct ape_priv *priv;
	struct eth_device *dev;

	priv = malloc(sizeof(*priv));
	if (priv == NULL)
		return 1;

	dev = malloc(sizeof(*dev));
	if (dev == NULL) {
		free(priv);
		return 1;
	}

	/* setup whatever private state you need */

	memset(dev, 0, sizeof(*dev));
	sprintf(dev->name, "APE");

	/* if your device has dedicated hardware storage for the
	 * MAC, read it and initialize dev->enetaddr with it
	 */
	ape_mac_read(dev->enetaddr);

	dev->iobase = iobase;
	dev->priv = priv;
	dev->init = ape_init;
	dev->halt = ape_halt;
	dev->send = ape_send;
	dev->recv = ape_recv;

	eth_register(dev);

#ifdef CONFIG_CMD_MII)
	miiphy_register(dev->name, ape_mii_read, ape_mii_write);
#endif

	return 1;
}

The exact arguments needed to initialize your device are up to you.  If you
need to pass more/less arguments, that's fine.  You should also add the
prototype for your new register function to include/netdev.h.

The return value for this function should be as follows:
< 0 - failure (hardware failure, not probe failure)
>=0 - number of interfaces detected

You might notice that many drivers seem to use xxx_initialize() rather than
xxx_register().  This is the old naming convention and should be avoided as it
causes confusion with the driver-specific init function.

Other than locating the MAC address in dedicated hardware storage, you should
not touch the hardware in anyway.  That step is handled in the driver-specific
init function.  Remember that we are only registering the device here, we are
not checking its state or doing random probing.

 -----------
  Callbacks
 -----------

Now that we've registered with the ethernet layer, we can start getting some
real work done.  You will need four functions:
	int ape_init(struct eth_device *dev, bd_t *bis);
	int ape_send(struct eth_device *dev, volatile void *packet, int length);
	int ape_recv(struct eth_device *dev);
	int ape_halt(struct eth_device *dev);

The init function checks the hardware (probing/identifying) and gets it ready
for send/recv operations.  You often do things here such as resetting the MAC
and/or PHY, and waiting for the link to autonegotiate.  You should also take
the opportunity to program the device's MAC address with the dev->enetaddr
member.  This allows the rest of U-Boot to dynamically change the MAC address
and have the new settings be respected.

The send function does what you think -- transmit the specified packet whose
size is specified by length (in bytes).  You should not return until the
transmission is complete, and you should leave the state such that the send
function can be called multiple times in a row.

The recv function should process packets as long as the hardware has them
readily available before returning.  i.e. you should drain the hardware fifo.
For each packet you receive, you should call the NetReceive() function on it
along with the packet length.  The common code sets up packet buffers for you
already in the .bss (NetRxPackets), so there should be no need to allocate your
own.  This doesn't mean you must use the NetRxPackets array however; you're
free to call the NetReceive() function with any buffer you wish.  So the pseudo
code here would look something like:
int ape_recv(struct eth_device *dev)
{
	int length, i = 0;
	...
	while (packets_are_available()) {
		...
		length = ape_get_packet(&NetRxPackets[i]);
		...
		NetReceive(&NetRxPackets[i], length);
		...
		if (++i >= PKTBUFSRX)
			i = 0;
		...
	}
	...
	return 0;
}

The halt function should turn off / disable the hardware and place it back in
its reset state.  It can be called at any time (before any call to the related
init function), so make sure it can handle this sort of thing.

So the call graph at this stage would look something like:
some net operation (ping / tftp / whatever...)
	eth_init()
		dev->init()
	eth_send()
		dev->send()
	eth_rx()
		dev->recv()
	eth_halt()
		dev->halt()

-----------------------------
 CONFIG_MII / CONFIG_CMD_MII
-----------------------------

If your device supports banging arbitrary values on the MII bus (pretty much
every device does), you should add support for the mii command.  Doing so is
fairly trivial and makes debugging mii issues a lot easier at runtime.

After you have called eth_register() in your driver's register function, add
a call to miiphy_register() like so:
#if defined(CONFIG_MII) || defined(CONFIG_CMD_MII)
	miiphy_register(dev->name, mii_read, mii_write);
#endif

And then define the mii_read and mii_write functions if you haven't already.
Their syntax is straightforward:
	int mii_read(char *devname, uchar addr, uchar reg, ushort *val);
	int mii_write(char *devname, uchar addr, uchar reg, ushort val);

The read function should read the register 'reg' from the phy at address 'addr'
and store the result in the pointer 'val'.  The implementation for the write
function should logically follow.
Commit	Line	Data
1f1e774e MF	1	-----------------------
	2	Ethernet Driver Guide
	3	-----------------------
	4
	5	The networking stack in Das U-Boot is designed for multiple network devices
	6	to be easily added and controlled at runtime. This guide is meant for people
	7	who wish to review the net driver stack with an eye towards implementing your
	8	own ethernet device driver. Here we will describe a new pseudo 'APE' driver.
	9
	10	------------------
	11	Driver Functions
	12	------------------
	13
	14	All functions you will be implementing in this document have the return value
	15	meaning of 0 for success and non-zero for failure.
	16
	17	----------
	18	Register
	19	----------
	20
	21	When U-Boot initializes, it will call the common function eth_initialize().
	22	This will in turn call the board-specific board_eth_init() (or if that fails,
	23	the cpu-specific cpu_eth_init()). These board-specific functions can do random
	24	system handling, but ultimately they will call the driver-specific register
	25	function which in turn takes care of initializing that particular instance.
	26
	27	Keep in mind that you should code the driver to avoid storing state in global
99dbd4ef BW	28	data as someone might want to hook up two of the same devices to one board.
	29	Any such information that is specific to an interface should be stored in a
	30	private, driver-defined data structure and pointed to by eth->priv (see below).
1f1e774e MF	31
	32	So the call graph at this stage would look something like:
	33	board_init()
	34	eth_initialize()
	35	board_eth_init() / cpu_eth_init()
	36	driver_register()
	37	initialize eth_device
	38	eth_register()
	39
	40	At this point in time, the only thing you need to worry about is the driver's
	41	register function. The pseudo code would look something like:
	42	int ape_register(bd_t *bis, int iobase)
	43	{
	44	struct ape_priv *priv;
	45	struct eth_device *dev;
	46
	47	priv = malloc(sizeof(*priv));
	48	if (priv == NULL)
	49	return 1;
	50
	51	dev = malloc(sizeof(*dev));
	52	if (dev == NULL) {
	53	free(priv);
	54	return 1;
	55	}
	56
	57	/* setup whatever private state you need */
	58
	59	memset(dev, 0, sizeof(*dev));
	60	sprintf(dev->name, "APE");
	61
	62	/* if your device has dedicated hardware storage for the
	63	* MAC, read it and initialize dev->enetaddr with it
	64	*/
	65	ape_mac_read(dev->enetaddr);
	66
	67	dev->iobase = iobase;
	68	dev->priv = priv;
	69	dev->init = ape_init;
	70	dev->halt = ape_halt;
	71	dev->send = ape_send;
	72	dev->recv = ape_recv;
	73
	74	eth_register(dev);
	75
	76	#ifdef CONFIG_CMD_MII)
	77	miiphy_register(dev->name, ape_mii_read, ape_mii_write);
	78	#endif
	79
99dbd4ef	80	return 1;
1f1e774e MF	81	}
	82
	83	The exact arguments needed to initialize your device are up to you. If you
	84	need to pass more/less arguments, that's fine. You should also add the
99dbd4ef BW	85	prototype for your new register function to include/netdev.h.
	86
	87	The return value for this function should be as follows:
	88	< 0 - failure (hardware failure, not probe failure)
	89	>=0 - number of interfaces detected
	90
4946775c	91	You might notice that many drivers seem to use xxx_initialize() rather than
99dbd4ef BW	92	xxx_register(). This is the old naming convention and should be avoided as it
99dbd4ef BW	93	causes confusion with the driver-specific init function.
1f1e774e MF	94
	95	Other than locating the MAC address in dedicated hardware storage, you should
	96	not touch the hardware in anyway. That step is handled in the driver-specific
	97	init function. Remember that we are only registering the device here, we are
	98	not checking its state or doing random probing.
	99
	100	-----------
	101	Callbacks
	102	-----------
	103
	104	Now that we've registered with the ethernet layer, we can start getting some
	105	real work done. You will need four functions:
	106	int ape_init(struct eth_device dev, bd_t bis);
	107	int ape_send(struct eth_device dev, volatile void packet, int length);
	108	int ape_recv(struct eth_device *dev);
	109	int ape_halt(struct eth_device *dev);
	110
	111	The init function checks the hardware (probing/identifying) and gets it ready
	112	for send/recv operations. You often do things here such as resetting the MAC
	113	and/or PHY, and waiting for the link to autonegotiate. You should also take
	114	the opportunity to program the device's MAC address with the dev->enetaddr
	115	member. This allows the rest of U-Boot to dynamically change the MAC address
	116	and have the new settings be respected.
	117
	118	The send function does what you think -- transmit the specified packet whose
	119	size is specified by length (in bytes). You should not return until the
	120	transmission is complete, and you should leave the state such that the send
	121	function can be called multiple times in a row.
	122
	123	The recv function should process packets as long as the hardware has them
	124	readily available before returning. i.e. you should drain the hardware fifo.
e5c5d9e0 MF	125	For each packet you receive, you should call the NetReceive() function on it
	126	along with the packet length. The common code sets up packet buffers for you
	127	already in the .bss (NetRxPackets), so there should be no need to allocate your
	128	own. This doesn't mean you must use the NetRxPackets array however; you're
	129	free to call the NetReceive() function with any buffer you wish. So the pseudo
	130	code here would look something like:
1f1e774e MF	131	int ape_recv(struct eth_device *dev)
	132	{
	133	int length, i = 0;
	134	...
	135	while (packets_are_available()) {
	136	...
	137	length = ape_get_packet(&NetRxPackets[i]);
	138	...
	139	NetReceive(&NetRxPackets[i], length);
	140	...
	141	if (++i >= PKTBUFSRX)
	142	i = 0;
	143	...
	144	}
	145	...
	146	return 0;
	147	}
	148
	149	The halt function should turn off / disable the hardware and place it back in
e5c5d9e0 MF	150	its reset state. It can be called at any time (before any call to the related
e5c5d9e0 MF	151	init function), so make sure it can handle this sort of thing.
1f1e774e MF	152
	153	So the call graph at this stage would look something like:
	154	some net operation (ping / tftp / whatever...)
	155	eth_init()
	156	dev->init()
	157	eth_send()
	158	dev->send()
	159	eth_rx()
	160	dev->recv()
	161	eth_halt()
	162	dev->halt()
	163
	164	-----------------------------
	165	CONFIG_MII / CONFIG_CMD_MII
	166	-----------------------------
	167
	168	If your device supports banging arbitrary values on the MII bus (pretty much
	169	every device does), you should add support for the mii command. Doing so is
	170	fairly trivial and makes debugging mii issues a lot easier at runtime.
	171
	172	After you have called eth_register() in your driver's register function, add
	173	a call to miiphy_register() like so:
	174	#if defined(CONFIG_MII) \|\| defined(CONFIG_CMD_MII)
	175	miiphy_register(dev->name, mii_read, mii_write);
	176	#endif
	177
	178	And then define the mii_read and mii_write functions if you haven't already.
	179	Their syntax is straightforward:
	180	int mii_read(char devname, uchar addr, uchar reg, ushort val);
	181	int mii_write(char *devname, uchar addr, uchar reg, ushort val);
	182
	183	The read function should read the register 'reg' from the phy at address 'addr'
	184	and store the result in the pointer 'val'. The implementation for the write
	185	function should logically follow.