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Some code was not converted by coccinelle, somehow. I manually fixed up the remaining, and comments, README docs. Signed-off-by: Masahiro Yamada <masahiroy@kernel.org> [trini: Add arch/arm/mach-davinci/include/mach/sdmmc_defs.h and include/fdt_support.h] Signed-off-by: Tom Rini <trini@konsulko.com>
321 lines
12 KiB
ReStructuredText
321 lines
12 KiB
ReStructuredText
Ethernet Driver Guide
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=======================
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The networking stack in Das U-Boot is designed for multiple network devices
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to be easily added and controlled at runtime. This guide is meant for people
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who wish to review the net driver stack with an eye towards implementing your
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own ethernet device driver. Here we will describe a new pseudo 'APE' driver.
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Most existing drivers do already - and new network driver MUST - use the
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U-Boot core driver model. Generic information about this can be found in
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doc/driver-model/design.rst, this document will thus focus on the network
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specific code parts.
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Some drivers are still using the old Ethernet interface, differences between
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the two and hints about porting will be handled at the end.
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Driver framework
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------------------
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A network driver following the driver model must declare itself using
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the UCLASS_ETH .id field in the U-Boot driver struct:
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.. code-block:: c
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U_BOOT_DRIVER(eth_ape) = {
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.name = "eth_ape",
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.id = UCLASS_ETH,
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.of_match = eth_ape_ids,
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.ofdata_to_platdata = eth_ape_ofdata_to_platdata,
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.probe = eth_ape_probe,
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.ops = ð_ape_ops,
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.priv_auto_alloc_size = sizeof(struct eth_ape_priv),
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.platdata_auto_alloc_size = sizeof(struct eth_ape_pdata),
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.flags = DM_FLAG_ALLOC_PRIV_DMA,
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};
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struct eth_ape_priv contains runtime per-instance data, like buffers, pointers
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to current descriptors, current speed settings, pointers to PHY related data
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(like struct mii_dev) and so on. Declaring its size in .priv_auto_alloc_size
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will let the driver framework allocate it at the right time.
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It can be retrieved using a dev_get_priv(dev) call.
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struct eth_ape_pdata contains static platform data, like the MMIO base address,
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a hardware variant, the MAC address. ``struct eth_pdata eth_pdata``
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as the first member of this struct helps to avoid duplicated code.
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If you don't need any more platform data beside the standard member,
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just use sizeof(struct eth_pdata) for the platdata_auto_alloc_size.
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PCI devices add a line pointing to supported vendor/device ID pairs:
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.. code-block:: c
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static struct pci_device_id supported[] = {
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{ PCI_DEVICE(PCI_VENDOR_ID_APE, 0x4223) },
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{}
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};
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U_BOOT_PCI_DEVICE(eth_ape, supported);
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It is also possible to declare support for a whole class of PCI devices::
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{ PCI_DEVICE_CLASS(PCI_CLASS_SYSTEM_SDHCI << 8, 0xffff00) },
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Device probing and instantiation will be handled by the driver model framework,
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so follow the guidelines there. The probe() function would initialise the
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platform specific parts of the hardware, like clocks, resets, GPIOs, the MDIO
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bus. Also it would take care of any special PHY setup (power rails, enable
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bits for internal PHYs, etc.).
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Driver methods
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----------------
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The real work will be done in the driver method functions the driver provides
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by defining the members of struct eth_ops:
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.. code-block:: c
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struct eth_ops {
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int (*start)(struct udevice *dev);
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int (*send)(struct udevice *dev, void *packet, int length);
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int (*recv)(struct udevice *dev, int flags, uchar **packetp);
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int (*free_pkt)(struct udevice *dev, uchar *packet, int length);
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void (*stop)(struct udevice *dev);
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int (*mcast)(struct udevice *dev, const u8 *enetaddr, int join);
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int (*write_hwaddr)(struct udevice *dev);
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int (*read_rom_hwaddr)(struct udevice *dev);
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};
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An up-to-date version of this struct together with more information can be
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found in include/net.h.
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Only start, stop, send and recv are required, the rest are optional and are
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handled by generic code or ignored if not provided.
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The **start** function initialises the hardware and gets it ready for send/recv
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operations. You often do things here such as resetting the MAC
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and/or PHY, and waiting for the link to autonegotiate. You should also take
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the opportunity to program the device's MAC address with the enetaddr member
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of the generic struct eth_pdata (which would be the first member of your
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own platdata struct). This allows the rest of U-Boot to dynamically change
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the MAC address and have the new settings be respected.
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The **send** function does what you think -- transmit the specified packet
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whose size is specified by length (in bytes). The packet buffer can (and
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will!) be reused for subsequent calls to send(), so it must be no longer
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used when the send() function returns. The easiest way to achieve this is
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to wait until the transmission is complete. Alternatively, if supported by
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the hardware, just waiting for the buffer to be consumed (by some DMA engine)
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might be an option as well.
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Another way of consuming the buffer could be to copy the data to be send,
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then just queue the copied packet (for instance handing it over to a DMA
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engine), and return immediately afterwards.
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In any case you should leave the state such that the send function can be
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called multiple times in a row.
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The **recv** function polls for availability of a new packet. If none is
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available, it must return with -EAGAIN.
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If a packet has been received, make sure it is accessible to the CPU
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(invalidate caches if needed), then write its address to the packetp pointer,
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and return the length. If there is an error (receive error, too short or too
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long packet), return 0 if you require the packet to be cleaned up normally,
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or a negative error code otherwise (cleanup not necessary or already done).
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The U-Boot network stack will then process the packet.
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If **free_pkt** is defined, U-Boot will call it after a received packet has
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been processed, so the packet buffer can be freed or recycled. Typically you
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would hand it back to the hardware to acquire another packet. free_pkt() will
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be called after recv(), for the same packet, so you don't necessarily need
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to infer the buffer to free from the ``packet`` pointer, but can rely on that
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being the last packet that recv() handled.
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The common code sets up packet buffers for you already in the .bss
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(net_rx_packets), so there should be no need to allocate your own. This doesn't
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mean you must use the net_rx_packets array however; you're free to use any
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buffer you wish.
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The **stop** function should turn off / disable the hardware and place it back
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in its reset state. It can be called at any time (before any call to the
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related start() function), so make sure it can handle this sort of thing.
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The (optional) **write_hwaddr** function should program the MAC address stored
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in pdata->enetaddr into the Ethernet controller.
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So the call graph at this stage would look something like:
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.. code-block:: c
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(some net operation (ping / tftp / whatever...))
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eth_init()
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ops->start()
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eth_send()
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ops->send()
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eth_rx()
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ops->recv()
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(process packet)
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if (ops->free_pkt)
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ops->free_pkt()
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eth_halt()
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ops->stop()
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CONFIG_PHYLIB / CONFIG_CMD_MII
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--------------------------------
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If your device supports banging arbitrary values on the MII bus (pretty much
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every device does), you should add support for the mii command. Doing so is
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fairly trivial and makes debugging mii issues a lot easier at runtime.
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In your driver's ``probe()`` function, add a call to mdio_alloc() and
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mdio_register() like so:
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.. code-block:: c
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bus = mdio_alloc();
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if (!bus) {
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...
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return -ENOMEM;
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}
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bus->read = ape_mii_read;
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bus->write = ape_mii_write;
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mdio_register(bus);
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And then define the mii_read and mii_write functions if you haven't already.
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Their syntax is straightforward::
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int mii_read(struct mii_dev *bus, int addr, int devad, int reg);
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int mii_write(struct mii_dev *bus, int addr, int devad, int reg,
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u16 val);
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The read function should read the register 'reg' from the phy at address 'addr'
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and return the result to its caller. The implementation for the write function
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should logically follow.
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................................................................
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Legacy network drivers
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------------------------
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!!! WARNING !!!
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This section below describes the old way of doing things. No new Ethernet
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drivers should be implemented this way. All new drivers should be written
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against the U-Boot core driver model, as described above.
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The actual callback functions are fairly similar, the differences are:
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- ``start()`` is called ``init()``
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- ``stop()`` is called ``halt()``
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- The ``recv()`` function must loop until all packets have been received, for
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each packet it must call the net_process_received_packet() function,
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handing it over the pointer and the length. Afterwards it should free
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the packet, before checking for new data.
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For porting an old driver to the new driver model, split the existing recv()
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function into the actual new recv() function, just fetching **one** packet,
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remove the call to net_process_received_packet(), then move the packet
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cleanup into the ``free_pkt()`` function.
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Registering the driver and probing a device is handled very differently,
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follow the recommendations in the driver model design documentation for
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instructions on how to port this over. For the records, the old way of
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initialising a network driver is as follows:
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Old network driver registration
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~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
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When U-Boot initializes, it will call the common function eth_initialize().
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This will in turn call the board-specific board_eth_init() (or if that fails,
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the cpu-specific cpu_eth_init()). These board-specific functions can do random
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system handling, but ultimately they will call the driver-specific register
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function which in turn takes care of initializing that particular instance.
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Keep in mind that you should code the driver to avoid storing state in global
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data as someone might want to hook up two of the same devices to one board.
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Any such information that is specific to an interface should be stored in a
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private, driver-defined data structure and pointed to by eth->priv (see below).
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So the call graph at this stage would look something like:
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.. code-block:: c
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board_init()
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eth_initialize()
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board_eth_init() / cpu_eth_init()
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driver_register()
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initialize eth_device
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eth_register()
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At this point in time, the only thing you need to worry about is the driver's
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register function. The pseudo code would look something like:
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.. code-block:: c
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int ape_register(struct bd_info *bis, int iobase)
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{
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struct ape_priv *priv;
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struct eth_device *dev;
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struct mii_dev *bus;
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priv = malloc(sizeof(*priv));
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if (priv == NULL)
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return -ENOMEM;
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dev = malloc(sizeof(*dev));
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if (dev == NULL) {
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free(priv);
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return -ENOMEM;
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}
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/* setup whatever private state you need */
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memset(dev, 0, sizeof(*dev));
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sprintf(dev->name, "APE");
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/*
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* if your device has dedicated hardware storage for the
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* MAC, read it and initialize dev->enetaddr with it
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*/
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ape_mac_read(dev->enetaddr);
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dev->iobase = iobase;
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dev->priv = priv;
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dev->init = ape_init;
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dev->halt = ape_halt;
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dev->send = ape_send;
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dev->recv = ape_recv;
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dev->write_hwaddr = ape_write_hwaddr;
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eth_register(dev);
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#ifdef CONFIG_PHYLIB
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bus = mdio_alloc();
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if (!bus) {
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free(priv);
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free(dev);
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return -ENOMEM;
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}
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bus->read = ape_mii_read;
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bus->write = ape_mii_write;
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mdio_register(bus);
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#endif
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return 1;
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}
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The exact arguments needed to initialize your device are up to you. If you
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need to pass more/less arguments, that's fine. You should also add the
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prototype for your new register function to include/netdev.h.
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The return value for this function should be as follows:
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< 0 - failure (hardware failure, not probe failure)
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>=0 - number of interfaces detected
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You might notice that many drivers seem to use xxx_initialize() rather than
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xxx_register(). This is the old naming convention and should be avoided as it
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causes confusion with the driver-specific init function.
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Other than locating the MAC address in dedicated hardware storage, you should
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not touch the hardware in anyway. That step is handled in the driver-specific
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init function. Remember that we are only registering the device here, we are
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not checking its state or doing random probing.
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