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257 lines
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ReStructuredText
=======================
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Z8530 Programming Guide
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=======================
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:Author: Alan Cox
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Introduction
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============
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The Z85x30 family synchronous/asynchronous controller chips are used on
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a large number of cheap network interface cards. The kernel provides a
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core interface layer that is designed to make it easy to provide WAN
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services using this chip.
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The current driver only support synchronous operation. Merging the
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asynchronous driver support into this code to allow any Z85x30 device to
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be used as both a tty interface and as a synchronous controller is a
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project for Linux post the 2.4 release
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Driver Modes
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============
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The Z85230 driver layer can drive Z8530, Z85C30 and Z85230 devices in
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three different modes. Each mode can be applied to an individual channel
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on the chip (each chip has two channels).
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The PIO synchronous mode supports the most common Z8530 wiring. Here the
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chip is interface to the I/O and interrupt facilities of the host
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machine but not to the DMA subsystem. When running PIO the Z8530 has
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extremely tight timing requirements. Doing high speeds, even with a
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Z85230 will be tricky. Typically you should expect to achieve at best
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9600 baud with a Z8C530 and 64Kbits with a Z85230.
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The DMA mode supports the chip when it is configured to use dual DMA
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channels on an ISA bus. The better cards tend to support this mode of
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operation for a single channel. With DMA running the Z85230 tops out
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when it starts to hit ISA DMA constraints at about 512Kbits. It is worth
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noting here that many PC machines hang or crash when the chip is driven
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fast enough to hold the ISA bus solid.
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Transmit DMA mode uses a single DMA channel. The DMA channel is used for
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transmission as the transmit FIFO is smaller than the receive FIFO. it
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gives better performance than pure PIO mode but is nowhere near as ideal
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as pure DMA mode.
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Using the Z85230 driver
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=======================
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The Z85230 driver provides the back end interface to your board. To
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configure a Z8530 interface you need to detect the board and to identify
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its ports and interrupt resources. It is also your problem to verify the
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resources are available.
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Having identified the chip you need to fill in a struct z8530_dev,
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which describes each chip. This object must exist until you finally
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shutdown the board. Firstly zero the active field. This ensures nothing
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goes off without you intending it. The irq field should be set to the
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interrupt number of the chip. (Each chip has a single interrupt source
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rather than each channel). You are responsible for allocating the
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interrupt line. The interrupt handler should be set to
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:c:func:`z8530_interrupt()`. The device id should be set to the
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z8530_dev structure pointer. Whether the interrupt can be shared or not
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is board dependent, and up to you to initialise.
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The structure holds two channel structures. Initialise chanA.ctrlio and
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chanA.dataio with the address of the control and data ports. You can or
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this with Z8530_PORT_SLEEP to indicate your interface needs the 5uS
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delay for chip settling done in software. The PORT_SLEEP option is
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architecture specific. Other flags may become available on future
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platforms, eg for MMIO. Initialise the chanA.irqs to &z8530_nop to
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start the chip up as disabled and discarding interrupt events. This
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ensures that stray interrupts will be mopped up and not hang the bus.
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Set chanA.dev to point to the device structure itself. The private and
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name field you may use as you wish. The private field is unused by the
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Z85230 layer. The name is used for error reporting and it may thus make
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sense to make it match the network name.
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Repeat the same operation with the B channel if your chip has both
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channels wired to something useful. This isn't always the case. If it is
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not wired then the I/O values do not matter, but you must initialise
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chanB.dev.
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If your board has DMA facilities then initialise the txdma and rxdma
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fields for the relevant channels. You must also allocate the ISA DMA
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channels and do any necessary board level initialisation to configure
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them. The low level driver will do the Z8530 and DMA controller
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programming but not board specific magic.
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Having initialised the device you can then call
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:c:func:`z8530_init()`. This will probe the chip and reset it into
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a known state. An identification sequence is then run to identify the
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chip type. If the checks fail to pass the function returns a non zero
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error code. Typically this indicates that the port given is not valid.
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After this call the type field of the z8530_dev structure is
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initialised to either Z8530, Z85C30 or Z85230 according to the chip
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found.
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Once you have called z8530_init you can also make use of the utility
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function :c:func:`z8530_describe()`. This provides a consistent
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reporting format for the Z8530 devices, and allows all the drivers to
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provide consistent reporting.
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Attaching Network Interfaces
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============================
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If you wish to use the network interface facilities of the driver, then
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you need to attach a network device to each channel that is present and
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in use. In addition to use the generic HDLC you need to follow some
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additional plumbing rules. They may seem complex but a look at the
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example hostess_sv11 driver should reassure you.
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The network device used for each channel should be pointed to by the
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netdevice field of each channel. The hdlc-> priv field of the network
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device points to your private data - you will need to be able to find
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your private data from this.
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The way most drivers approach this particular problem is to create a
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structure holding the Z8530 device definition and put that into the
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private field of the network device. The network device fields of the
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channels then point back to the network devices.
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If you wish to use the generic HDLC then you need to register the HDLC
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device.
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Before you register your network device you will also need to provide
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suitable handlers for most of the network device callbacks. See the
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network device documentation for more details on this.
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Configuring And Activating The Port
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===================================
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The Z85230 driver provides helper functions and tables to load the port
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registers on the Z8530 chips. When programming the register settings for
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a channel be aware that the documentation recommends initialisation
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orders. Strange things happen when these are not followed.
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:c:func:`z8530_channel_load()` takes an array of pairs of
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initialisation values in an array of u8 type. The first value is the
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Z8530 register number. Add 16 to indicate the alternate register bank on
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the later chips. The array is terminated by a 255.
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The driver provides a pair of public tables. The z8530_hdlc_kilostream
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table is for the UK 'Kilostream' service and also happens to cover most
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other end host configurations. The z8530_hdlc_kilostream_85230 table
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is the same configuration using the enhancements of the 85230 chip. The
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configuration loaded is standard NRZ encoded synchronous data with HDLC
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bitstuffing. All of the timing is taken from the other end of the link.
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When writing your own tables be aware that the driver internally tracks
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register values. It may need to reload values. You should therefore be
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sure to set registers 1-7, 9-11, 14 and 15 in all configurations. Where
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the register settings depend on DMA selection the driver will update the
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bits itself when you open or close. Loading a new table with the
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interface open is not recommended.
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There are three standard configurations supported by the core code. In
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PIO mode the interface is programmed up to use interrupt driven PIO.
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This places high demands on the host processor to avoid latency. The
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driver is written to take account of latency issues but it cannot avoid
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latencies caused by other drivers, notably IDE in PIO mode. Because the
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drivers allocate buffers you must also prevent MTU changes while the
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port is open.
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Once the port is open it will call the rx_function of each channel
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whenever a completed packet arrived. This is invoked from interrupt
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context and passes you the channel and a network buffer (struct
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sk_buff) holding the data. The data includes the CRC bytes so most
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users will want to trim the last two bytes before processing the data.
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This function is very timing critical. When you wish to simply discard
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data the support code provides the function
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:c:func:`z8530_null_rx()` to discard the data.
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To active PIO mode sending and receiving the ``z8530_sync_open`` is called.
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This expects to be passed the network device and the channel. Typically
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this is called from your network device open callback. On a failure a
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non zero error status is returned.
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The :c:func:`z8530_sync_close()` function shuts down a PIO
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channel. This must be done before the channel is opened again and before
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the driver shuts down and unloads.
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The ideal mode of operation is dual channel DMA mode. Here the kernel
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driver will configure the board for DMA in both directions. The driver
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also handles ISA DMA issues such as controller programming and the
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memory range limit for you. This mode is activated by calling the
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:c:func:`z8530_sync_dma_open()` function. On failure a non zero
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error value is returned. Once this mode is activated it can be shut down
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by calling the :c:func:`z8530_sync_dma_close()`. You must call
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the close function matching the open mode you used.
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The final supported mode uses a single DMA channel to drive the transmit
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side. As the Z85C30 has a larger FIFO on the receive channel this tends
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to increase the maximum speed a little. This is activated by calling the
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``z8530_sync_txdma_open``. This returns a non zero error code on failure. The
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:c:func:`z8530_sync_txdma_close()` function closes down the Z8530
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interface from this mode.
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Network Layer Functions
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=======================
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The Z8530 layer provides functions to queue packets for transmission.
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The driver internally buffers the frame currently being transmitted and
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one further frame (in order to keep back to back transmission running).
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Any further buffering is up to the caller.
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The function :c:func:`z8530_queue_xmit()` takes a network buffer
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in sk_buff format and queues it for transmission. The caller must
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provide the entire packet with the exception of the bitstuffing and CRC.
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This is normally done by the caller via the generic HDLC interface
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layer. It returns 0 if the buffer has been queued and non zero values
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for queue full. If the function accepts the buffer it becomes property
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of the Z8530 layer and the caller should not free it.
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The function :c:func:`z8530_get_stats()` returns a pointer to an
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internally maintained per interface statistics block. This provides most
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of the interface code needed to implement the network layer get_stats
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callback.
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Porting The Z8530 Driver
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========================
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The Z8530 driver is written to be portable. In DMA mode it makes
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assumptions about the use of ISA DMA. These are probably warranted in
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most cases as the Z85230 in particular was designed to glue to PC type
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machines. The PIO mode makes no real assumptions.
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Should you need to retarget the Z8530 driver to another architecture the
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only code that should need changing are the port I/O functions. At the
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moment these assume PC I/O port accesses. This may not be appropriate
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for all platforms. Replacing :c:func:`z8530_read_port()` and
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``z8530_write_port`` is intended to be all that is required to port
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this driver layer.
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Known Bugs And Assumptions
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==========================
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Interrupt Locking
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The locking in the driver is done via the global cli/sti lock. This
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makes for relatively poor SMP performance. Switching this to use a
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per device spin lock would probably materially improve performance.
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Occasional Failures
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We have reports of occasional failures when run for very long
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periods of time and the driver starts to receive junk frames. At the
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moment the cause of this is not clear.
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Public Functions Provided
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=========================
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.. kernel-doc:: drivers/net/wan/z85230.c
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:export:
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Internal Functions
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==================
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.. kernel-doc:: drivers/net/wan/z85230.c
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:internal:
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