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When host rescinds the device, the UIO driver will clear the interrupt state and notify application. The read (or write) on the interrupt FD will then fail with -EIO. This is simpler than adding lots extra uevent stuff inside UIO. Signed-off-by: Stephen Hemminger <sthemmin@microsoft.com> Signed-off-by: Greg Kroah-Hartman <gregkh@linuxfoundation.org>
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718 lines
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=======================
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The Userspace I/O HOWTO
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=======================
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:Author: Hans-Jürgen Koch Linux developer, Linutronix
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:Date: 2006-12-11
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About this document
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===================
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Translations
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------------
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If you know of any translations for this document, or you are interested
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in translating it, please email me hjk@hansjkoch.de.
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Preface
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-------
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For many types of devices, creating a Linux kernel driver is overkill.
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All that is really needed is some way to handle an interrupt and provide
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access to the memory space of the device. The logic of controlling the
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device does not necessarily have to be within the kernel, as the device
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does not need to take advantage of any of other resources that the
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kernel provides. One such common class of devices that are like this are
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for industrial I/O cards.
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To address this situation, the userspace I/O system (UIO) was designed.
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For typical industrial I/O cards, only a very small kernel module is
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needed. The main part of the driver will run in user space. This
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simplifies development and reduces the risk of serious bugs within a
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kernel module.
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Please note that UIO is not an universal driver interface. Devices that
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are already handled well by other kernel subsystems (like networking or
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serial or USB) are no candidates for an UIO driver. Hardware that is
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ideally suited for an UIO driver fulfills all of the following:
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- The device has memory that can be mapped. The device can be
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controlled completely by writing to this memory.
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- The device usually generates interrupts.
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- The device does not fit into one of the standard kernel subsystems.
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Acknowledgments
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---------------
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I'd like to thank Thomas Gleixner and Benedikt Spranger of Linutronix,
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who have not only written most of the UIO code, but also helped greatly
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writing this HOWTO by giving me all kinds of background information.
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Feedback
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--------
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Find something wrong with this document? (Or perhaps something right?) I
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would love to hear from you. Please email me at hjk@hansjkoch.de.
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About UIO
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=========
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If you use UIO for your card's driver, here's what you get:
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- only one small kernel module to write and maintain.
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- develop the main part of your driver in user space, with all the
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tools and libraries you're used to.
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- bugs in your driver won't crash the kernel.
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- updates of your driver can take place without recompiling the kernel.
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How UIO works
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-------------
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Each UIO device is accessed through a device file and several sysfs
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attribute files. The device file will be called ``/dev/uio0`` for the
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first device, and ``/dev/uio1``, ``/dev/uio2`` and so on for subsequent
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devices.
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``/dev/uioX`` is used to access the address space of the card. Just use
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:c:func:`mmap()` to access registers or RAM locations of your card.
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Interrupts are handled by reading from ``/dev/uioX``. A blocking
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:c:func:`read()` from ``/dev/uioX`` will return as soon as an
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interrupt occurs. You can also use :c:func:`select()` on
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``/dev/uioX`` to wait for an interrupt. The integer value read from
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``/dev/uioX`` represents the total interrupt count. You can use this
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number to figure out if you missed some interrupts.
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For some hardware that has more than one interrupt source internally,
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but not separate IRQ mask and status registers, there might be
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situations where userspace cannot determine what the interrupt source
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was if the kernel handler disables them by writing to the chip's IRQ
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register. In such a case, the kernel has to disable the IRQ completely
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to leave the chip's register untouched. Now the userspace part can
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determine the cause of the interrupt, but it cannot re-enable
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interrupts. Another cornercase is chips where re-enabling interrupts is
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a read-modify-write operation to a combined IRQ status/acknowledge
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register. This would be racy if a new interrupt occurred simultaneously.
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To address these problems, UIO also implements a write() function. It is
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normally not used and can be ignored for hardware that has only a single
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interrupt source or has separate IRQ mask and status registers. If you
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need it, however, a write to ``/dev/uioX`` will call the
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:c:func:`irqcontrol()` function implemented by the driver. You have
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to write a 32-bit value that is usually either 0 or 1 to disable or
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enable interrupts. If a driver does not implement
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:c:func:`irqcontrol()`, :c:func:`write()` will return with
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``-ENOSYS``.
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To handle interrupts properly, your custom kernel module can provide its
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own interrupt handler. It will automatically be called by the built-in
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handler.
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For cards that don't generate interrupts but need to be polled, there is
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the possibility to set up a timer that triggers the interrupt handler at
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configurable time intervals. This interrupt simulation is done by
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calling :c:func:`uio_event_notify()` from the timer's event
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handler.
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Each driver provides attributes that are used to read or write
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variables. These attributes are accessible through sysfs files. A custom
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kernel driver module can add its own attributes to the device owned by
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the uio driver, but not added to the UIO device itself at this time.
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This might change in the future if it would be found to be useful.
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The following standard attributes are provided by the UIO framework:
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- ``name``: The name of your device. It is recommended to use the name
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of your kernel module for this.
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- ``version``: A version string defined by your driver. This allows the
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user space part of your driver to deal with different versions of the
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kernel module.
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- ``event``: The total number of interrupts handled by the driver since
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the last time the device node was read.
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These attributes appear under the ``/sys/class/uio/uioX`` directory.
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Please note that this directory might be a symlink, and not a real
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directory. Any userspace code that accesses it must be able to handle
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this.
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Each UIO device can make one or more memory regions available for memory
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mapping. This is necessary because some industrial I/O cards require
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access to more than one PCI memory region in a driver.
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Each mapping has its own directory in sysfs, the first mapping appears
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as ``/sys/class/uio/uioX/maps/map0/``. Subsequent mappings create
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directories ``map1/``, ``map2/``, and so on. These directories will only
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appear if the size of the mapping is not 0.
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Each ``mapX/`` directory contains four read-only files that show
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attributes of the memory:
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- ``name``: A string identifier for this mapping. This is optional, the
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string can be empty. Drivers can set this to make it easier for
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userspace to find the correct mapping.
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- ``addr``: The address of memory that can be mapped.
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- ``size``: The size, in bytes, of the memory pointed to by addr.
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- ``offset``: The offset, in bytes, that has to be added to the pointer
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returned by :c:func:`mmap()` to get to the actual device memory.
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This is important if the device's memory is not page aligned.
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Remember that pointers returned by :c:func:`mmap()` are always
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page aligned, so it is good style to always add this offset.
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From userspace, the different mappings are distinguished by adjusting
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the ``offset`` parameter of the :c:func:`mmap()` call. To map the
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memory of mapping N, you have to use N times the page size as your
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offset::
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offset = N * getpagesize();
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Sometimes there is hardware with memory-like regions that can not be
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mapped with the technique described here, but there are still ways to
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access them from userspace. The most common example are x86 ioports. On
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x86 systems, userspace can access these ioports using
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:c:func:`ioperm()`, :c:func:`iopl()`, :c:func:`inb()`,
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:c:func:`outb()`, and similar functions.
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Since these ioport regions can not be mapped, they will not appear under
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``/sys/class/uio/uioX/maps/`` like the normal memory described above.
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Without information about the port regions a hardware has to offer, it
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becomes difficult for the userspace part of the driver to find out which
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ports belong to which UIO device.
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To address this situation, the new directory
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``/sys/class/uio/uioX/portio/`` was added. It only exists if the driver
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wants to pass information about one or more port regions to userspace.
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If that is the case, subdirectories named ``port0``, ``port1``, and so
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on, will appear underneath ``/sys/class/uio/uioX/portio/``.
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Each ``portX/`` directory contains four read-only files that show name,
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start, size, and type of the port region:
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- ``name``: A string identifier for this port region. The string is
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optional and can be empty. Drivers can set it to make it easier for
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userspace to find a certain port region.
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- ``start``: The first port of this region.
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- ``size``: The number of ports in this region.
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- ``porttype``: A string describing the type of port.
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Writing your own kernel module
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==============================
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Please have a look at ``uio_cif.c`` as an example. The following
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paragraphs explain the different sections of this file.
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struct uio_info
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---------------
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This structure tells the framework the details of your driver, Some of
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the members are required, others are optional.
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- ``const char *name``: Required. The name of your driver as it will
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appear in sysfs. I recommend using the name of your module for this.
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- ``const char *version``: Required. This string appears in
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``/sys/class/uio/uioX/version``.
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- ``struct uio_mem mem[ MAX_UIO_MAPS ]``: Required if you have memory
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that can be mapped with :c:func:`mmap()`. For each mapping you
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need to fill one of the ``uio_mem`` structures. See the description
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below for details.
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- ``struct uio_port port[ MAX_UIO_PORTS_REGIONS ]``: Required if you
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want to pass information about ioports to userspace. For each port
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region you need to fill one of the ``uio_port`` structures. See the
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description below for details.
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- ``long irq``: Required. If your hardware generates an interrupt, it's
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your modules task to determine the irq number during initialization.
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If you don't have a hardware generated interrupt but want to trigger
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the interrupt handler in some other way, set ``irq`` to
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``UIO_IRQ_CUSTOM``. If you had no interrupt at all, you could set
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``irq`` to ``UIO_IRQ_NONE``, though this rarely makes sense.
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- ``unsigned long irq_flags``: Required if you've set ``irq`` to a
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hardware interrupt number. The flags given here will be used in the
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call to :c:func:`request_irq()`.
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- ``int (*mmap)(struct uio_info *info, struct vm_area_struct *vma)``:
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Optional. If you need a special :c:func:`mmap()`
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function, you can set it here. If this pointer is not NULL, your
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:c:func:`mmap()` will be called instead of the built-in one.
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- ``int (*open)(struct uio_info *info, struct inode *inode)``:
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Optional. You might want to have your own :c:func:`open()`,
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e.g. to enable interrupts only when your device is actually used.
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- ``int (*release)(struct uio_info *info, struct inode *inode)``:
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Optional. If you define your own :c:func:`open()`, you will
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probably also want a custom :c:func:`release()` function.
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- ``int (*irqcontrol)(struct uio_info *info, s32 irq_on)``:
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Optional. If you need to be able to enable or disable interrupts
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from userspace by writing to ``/dev/uioX``, you can implement this
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function. The parameter ``irq_on`` will be 0 to disable interrupts
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and 1 to enable them.
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Usually, your device will have one or more memory regions that can be
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mapped to user space. For each region, you have to set up a
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``struct uio_mem`` in the ``mem[]`` array. Here's a description of the
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fields of ``struct uio_mem``:
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- ``const char *name``: Optional. Set this to help identify the memory
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region, it will show up in the corresponding sysfs node.
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- ``int memtype``: Required if the mapping is used. Set this to
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``UIO_MEM_PHYS`` if you you have physical memory on your card to be
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mapped. Use ``UIO_MEM_LOGICAL`` for logical memory (e.g. allocated
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with :c:func:`kmalloc()`). There's also ``UIO_MEM_VIRTUAL`` for
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virtual memory.
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- ``phys_addr_t addr``: Required if the mapping is used. Fill in the
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address of your memory block. This address is the one that appears in
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sysfs.
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- ``resource_size_t size``: Fill in the size of the memory block that
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``addr`` points to. If ``size`` is zero, the mapping is considered
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unused. Note that you *must* initialize ``size`` with zero for all
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unused mappings.
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- ``void *internal_addr``: If you have to access this memory region
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from within your kernel module, you will want to map it internally by
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using something like :c:func:`ioremap()`. Addresses returned by
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this function cannot be mapped to user space, so you must not store
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it in ``addr``. Use ``internal_addr`` instead to remember such an
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address.
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Please do not touch the ``map`` element of ``struct uio_mem``! It is
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used by the UIO framework to set up sysfs files for this mapping. Simply
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leave it alone.
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Sometimes, your device can have one or more port regions which can not
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be mapped to userspace. But if there are other possibilities for
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userspace to access these ports, it makes sense to make information
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about the ports available in sysfs. For each region, you have to set up
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a ``struct uio_port`` in the ``port[]`` array. Here's a description of
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the fields of ``struct uio_port``:
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- ``char *porttype``: Required. Set this to one of the predefined
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constants. Use ``UIO_PORT_X86`` for the ioports found in x86
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architectures.
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- ``unsigned long start``: Required if the port region is used. Fill in
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the number of the first port of this region.
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- ``unsigned long size``: Fill in the number of ports in this region.
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If ``size`` is zero, the region is considered unused. Note that you
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*must* initialize ``size`` with zero for all unused regions.
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Please do not touch the ``portio`` element of ``struct uio_port``! It is
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used internally by the UIO framework to set up sysfs files for this
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region. Simply leave it alone.
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Adding an interrupt handler
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---------------------------
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What you need to do in your interrupt handler depends on your hardware
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and on how you want to handle it. You should try to keep the amount of
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code in your kernel interrupt handler low. If your hardware requires no
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action that you *have* to perform after each interrupt, then your
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handler can be empty.
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If, on the other hand, your hardware *needs* some action to be performed
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after each interrupt, then you *must* do it in your kernel module. Note
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that you cannot rely on the userspace part of your driver. Your
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userspace program can terminate at any time, possibly leaving your
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hardware in a state where proper interrupt handling is still required.
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There might also be applications where you want to read data from your
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hardware at each interrupt and buffer it in a piece of kernel memory
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you've allocated for that purpose. With this technique you could avoid
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loss of data if your userspace program misses an interrupt.
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A note on shared interrupts: Your driver should support interrupt
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sharing whenever this is possible. It is possible if and only if your
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driver can detect whether your hardware has triggered the interrupt or
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not. This is usually done by looking at an interrupt status register. If
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your driver sees that the IRQ bit is actually set, it will perform its
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actions, and the handler returns IRQ_HANDLED. If the driver detects
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that it was not your hardware that caused the interrupt, it will do
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nothing and return IRQ_NONE, allowing the kernel to call the next
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possible interrupt handler.
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If you decide not to support shared interrupts, your card won't work in
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computers with no free interrupts. As this frequently happens on the PC
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platform, you can save yourself a lot of trouble by supporting interrupt
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sharing.
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Using uio_pdrv for platform devices
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-----------------------------------
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In many cases, UIO drivers for platform devices can be handled in a
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generic way. In the same place where you define your
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``struct platform_device``, you simply also implement your interrupt
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handler and fill your ``struct uio_info``. A pointer to this
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``struct uio_info`` is then used as ``platform_data`` for your platform
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device.
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You also need to set up an array of ``struct resource`` containing
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addresses and sizes of your memory mappings. This information is passed
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to the driver using the ``.resource`` and ``.num_resources`` elements of
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``struct platform_device``.
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You now have to set the ``.name`` element of ``struct platform_device``
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to ``"uio_pdrv"`` to use the generic UIO platform device driver. This
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driver will fill the ``mem[]`` array according to the resources given,
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and register the device.
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The advantage of this approach is that you only have to edit a file you
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need to edit anyway. You do not have to create an extra driver.
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Using uio_pdrv_genirq for platform devices
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------------------------------------------
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Especially in embedded devices, you frequently find chips where the irq
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pin is tied to its own dedicated interrupt line. In such cases, where
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you can be really sure the interrupt is not shared, we can take the
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concept of ``uio_pdrv`` one step further and use a generic interrupt
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handler. That's what ``uio_pdrv_genirq`` does.
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The setup for this driver is the same as described above for
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``uio_pdrv``, except that you do not implement an interrupt handler. The
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``.handler`` element of ``struct uio_info`` must remain ``NULL``. The
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``.irq_flags`` element must not contain ``IRQF_SHARED``.
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You will set the ``.name`` element of ``struct platform_device`` to
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``"uio_pdrv_genirq"`` to use this driver.
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The generic interrupt handler of ``uio_pdrv_genirq`` will simply disable
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the interrupt line using :c:func:`disable_irq_nosync()`. After
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doing its work, userspace can reenable the interrupt by writing
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0x00000001 to the UIO device file. The driver already implements an
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:c:func:`irq_control()` to make this possible, you must not
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implement your own.
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Using ``uio_pdrv_genirq`` not only saves a few lines of interrupt
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handler code. You also do not need to know anything about the chip's
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internal registers to create the kernel part of the driver. All you need
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to know is the irq number of the pin the chip is connected to.
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Using uio_dmem_genirq for platform devices
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------------------------------------------
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In addition to statically allocated memory ranges, they may also be a
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desire to use dynamically allocated regions in a user space driver. In
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particular, being able to access memory made available through the
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dma-mapping API, may be particularly useful. The ``uio_dmem_genirq``
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driver provides a way to accomplish this.
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This driver is used in a similar manner to the ``"uio_pdrv_genirq"``
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driver with respect to interrupt configuration and handling.
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Set the ``.name`` element of ``struct platform_device`` to
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``"uio_dmem_genirq"`` to use this driver.
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When using this driver, fill in the ``.platform_data`` element of
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``struct platform_device``, which is of type
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``struct uio_dmem_genirq_pdata`` and which contains the following
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elements:
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- ``struct uio_info uioinfo``: The same structure used as the
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``uio_pdrv_genirq`` platform data
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- ``unsigned int *dynamic_region_sizes``: Pointer to list of sizes of
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dynamic memory regions to be mapped into user space.
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- ``unsigned int num_dynamic_regions``: Number of elements in
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``dynamic_region_sizes`` array.
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The dynamic regions defined in the platform data will be appended to the
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`` mem[] `` array after the platform device resources, which implies
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that the total number of static and dynamic memory regions cannot exceed
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``MAX_UIO_MAPS``.
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The dynamic memory regions will be allocated when the UIO device file,
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``/dev/uioX`` is opened. Similar to static memory resources, the memory
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region information for dynamic regions is then visible via sysfs at
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``/sys/class/uio/uioX/maps/mapY/*``. The dynamic memory regions will be
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|
freed when the UIO device file is closed. When no processes are holding
|
|
the device file open, the address returned to userspace is ~0.
|
|
|
|
Writing a driver in userspace
|
|
=============================
|
|
|
|
Once you have a working kernel module for your hardware, you can write
|
|
the userspace part of your driver. You don't need any special libraries,
|
|
your driver can be written in any reasonable language, you can use
|
|
floating point numbers and so on. In short, you can use all the tools
|
|
and libraries you'd normally use for writing a userspace application.
|
|
|
|
Getting information about your UIO device
|
|
-----------------------------------------
|
|
|
|
Information about all UIO devices is available in sysfs. The first thing
|
|
you should do in your driver is check ``name`` and ``version`` to make
|
|
sure your talking to the right device and that its kernel driver has the
|
|
version you expect.
|
|
|
|
You should also make sure that the memory mapping you need exists and
|
|
has the size you expect.
|
|
|
|
There is a tool called ``lsuio`` that lists UIO devices and their
|
|
attributes. It is available here:
|
|
|
|
http://www.osadl.org/projects/downloads/UIO/user/
|
|
|
|
With ``lsuio`` you can quickly check if your kernel module is loaded and
|
|
which attributes it exports. Have a look at the manpage for details.
|
|
|
|
The source code of ``lsuio`` can serve as an example for getting
|
|
information about an UIO device. The file ``uio_helper.c`` contains a
|
|
lot of functions you could use in your userspace driver code.
|
|
|
|
mmap() device memory
|
|
--------------------
|
|
|
|
After you made sure you've got the right device with the memory mappings
|
|
you need, all you have to do is to call :c:func:`mmap()` to map the
|
|
device's memory to userspace.
|
|
|
|
The parameter ``offset`` of the :c:func:`mmap()` call has a special
|
|
meaning for UIO devices: It is used to select which mapping of your
|
|
device you want to map. To map the memory of mapping N, you have to use
|
|
N times the page size as your offset::
|
|
|
|
offset = N * getpagesize();
|
|
|
|
N starts from zero, so if you've got only one memory range to map, set
|
|
``offset = 0``. A drawback of this technique is that memory is always
|
|
mapped beginning with its start address.
|
|
|
|
Waiting for interrupts
|
|
----------------------
|
|
|
|
After you successfully mapped your devices memory, you can access it
|
|
like an ordinary array. Usually, you will perform some initialization.
|
|
After that, your hardware starts working and will generate an interrupt
|
|
as soon as it's finished, has some data available, or needs your
|
|
attention because an error occurred.
|
|
|
|
``/dev/uioX`` is a read-only file. A :c:func:`read()` will always
|
|
block until an interrupt occurs. There is only one legal value for the
|
|
``count`` parameter of :c:func:`read()`, and that is the size of a
|
|
signed 32 bit integer (4). Any other value for ``count`` causes
|
|
:c:func:`read()` to fail. The signed 32 bit integer read is the
|
|
interrupt count of your device. If the value is one more than the value
|
|
you read the last time, everything is OK. If the difference is greater
|
|
than one, you missed interrupts.
|
|
|
|
You can also use :c:func:`select()` on ``/dev/uioX``.
|
|
|
|
Generic PCI UIO driver
|
|
======================
|
|
|
|
The generic driver is a kernel module named uio_pci_generic. It can
|
|
work with any device compliant to PCI 2.3 (circa 2002) and any compliant
|
|
PCI Express device. Using this, you only need to write the userspace
|
|
driver, removing the need to write a hardware-specific kernel module.
|
|
|
|
Making the driver recognize the device
|
|
--------------------------------------
|
|
|
|
Since the driver does not declare any device ids, it will not get loaded
|
|
automatically and will not automatically bind to any devices, you must
|
|
load it and allocate id to the driver yourself. For example::
|
|
|
|
modprobe uio_pci_generic
|
|
echo "8086 10f5" > /sys/bus/pci/drivers/uio_pci_generic/new_id
|
|
|
|
If there already is a hardware specific kernel driver for your device,
|
|
the generic driver still won't bind to it, in this case if you want to
|
|
use the generic driver (why would you?) you'll have to manually unbind
|
|
the hardware specific driver and bind the generic driver, like this::
|
|
|
|
echo -n 0000:00:19.0 > /sys/bus/pci/drivers/e1000e/unbind
|
|
echo -n 0000:00:19.0 > /sys/bus/pci/drivers/uio_pci_generic/bind
|
|
|
|
You can verify that the device has been bound to the driver by looking
|
|
for it in sysfs, for example like the following::
|
|
|
|
ls -l /sys/bus/pci/devices/0000:00:19.0/driver
|
|
|
|
Which if successful should print::
|
|
|
|
.../0000:00:19.0/driver -> ../../../bus/pci/drivers/uio_pci_generic
|
|
|
|
Note that the generic driver will not bind to old PCI 2.2 devices. If
|
|
binding the device failed, run the following command::
|
|
|
|
dmesg
|
|
|
|
and look in the output for failure reasons.
|
|
|
|
Things to know about uio_pci_generic
|
|
------------------------------------
|
|
|
|
Interrupts are handled using the Interrupt Disable bit in the PCI
|
|
command register and Interrupt Status bit in the PCI status register.
|
|
All devices compliant to PCI 2.3 (circa 2002) and all compliant PCI
|
|
Express devices should support these bits. uio_pci_generic detects
|
|
this support, and won't bind to devices which do not support the
|
|
Interrupt Disable Bit in the command register.
|
|
|
|
On each interrupt, uio_pci_generic sets the Interrupt Disable bit.
|
|
This prevents the device from generating further interrupts until the
|
|
bit is cleared. The userspace driver should clear this bit before
|
|
blocking and waiting for more interrupts.
|
|
|
|
Writing userspace driver using uio_pci_generic
|
|
------------------------------------------------
|
|
|
|
Userspace driver can use pci sysfs interface, or the libpci library that
|
|
wraps it, to talk to the device and to re-enable interrupts by writing
|
|
to the command register.
|
|
|
|
Example code using uio_pci_generic
|
|
----------------------------------
|
|
|
|
Here is some sample userspace driver code using uio_pci_generic::
|
|
|
|
#include <stdlib.h>
|
|
#include <stdio.h>
|
|
#include <unistd.h>
|
|
#include <sys/types.h>
|
|
#include <sys/stat.h>
|
|
#include <fcntl.h>
|
|
#include <errno.h>
|
|
|
|
int main()
|
|
{
|
|
int uiofd;
|
|
int configfd;
|
|
int err;
|
|
int i;
|
|
unsigned icount;
|
|
unsigned char command_high;
|
|
|
|
uiofd = open("/dev/uio0", O_RDONLY);
|
|
if (uiofd < 0) {
|
|
perror("uio open:");
|
|
return errno;
|
|
}
|
|
configfd = open("/sys/class/uio/uio0/device/config", O_RDWR);
|
|
if (configfd < 0) {
|
|
perror("config open:");
|
|
return errno;
|
|
}
|
|
|
|
/* Read and cache command value */
|
|
err = pread(configfd, &command_high, 1, 5);
|
|
if (err != 1) {
|
|
perror("command config read:");
|
|
return errno;
|
|
}
|
|
command_high &= ~0x4;
|
|
|
|
for(i = 0;; ++i) {
|
|
/* Print out a message, for debugging. */
|
|
if (i == 0)
|
|
fprintf(stderr, "Started uio test driver.\n");
|
|
else
|
|
fprintf(stderr, "Interrupts: %d\n", icount);
|
|
|
|
/****************************************/
|
|
/* Here we got an interrupt from the
|
|
device. Do something to it. */
|
|
/****************************************/
|
|
|
|
/* Re-enable interrupts. */
|
|
err = pwrite(configfd, &command_high, 1, 5);
|
|
if (err != 1) {
|
|
perror("config write:");
|
|
break;
|
|
}
|
|
|
|
/* Wait for next interrupt. */
|
|
err = read(uiofd, &icount, 4);
|
|
if (err != 4) {
|
|
perror("uio read:");
|
|
break;
|
|
}
|
|
|
|
}
|
|
return errno;
|
|
}
|
|
|
|
Generic Hyper-V UIO driver
|
|
==========================
|
|
|
|
The generic driver is a kernel module named uio_hv_generic. It
|
|
supports devices on the Hyper-V VMBus similar to uio_pci_generic on
|
|
PCI bus.
|
|
|
|
Making the driver recognize the device
|
|
--------------------------------------
|
|
|
|
Since the driver does not declare any device GUID's, it will not get
|
|
loaded automatically and will not automatically bind to any devices, you
|
|
must load it and allocate id to the driver yourself. For example, to use
|
|
the network device class GUID::
|
|
|
|
modprobe uio_hv_generic
|
|
echo "f8615163-df3e-46c5-913f-f2d2f965ed0e" > /sys/bus/vmbus/drivers/uio_hv_generic/new_id
|
|
|
|
If there already is a hardware specific kernel driver for the device,
|
|
the generic driver still won't bind to it, in this case if you want to
|
|
use the generic driver for a userspace library you'll have to manually unbind
|
|
the hardware specific driver and bind the generic driver, using the device specific GUID
|
|
like this::
|
|
|
|
echo -n ed963694-e847-4b2a-85af-bc9cfc11d6f3 > /sys/bus/vmbus/drivers/hv_netvsc/unbind
|
|
echo -n ed963694-e847-4b2a-85af-bc9cfc11d6f3 > /sys/bus/vmbus/drivers/uio_hv_generic/bind
|
|
|
|
You can verify that the device has been bound to the driver by looking
|
|
for it in sysfs, for example like the following::
|
|
|
|
ls -l /sys/bus/vmbus/devices/ed963694-e847-4b2a-85af-bc9cfc11d6f3/driver
|
|
|
|
Which if successful should print::
|
|
|
|
.../ed963694-e847-4b2a-85af-bc9cfc11d6f3/driver -> ../../../bus/vmbus/drivers/uio_hv_generic
|
|
|
|
Things to know about uio_hv_generic
|
|
-----------------------------------
|
|
|
|
On each interrupt, uio_hv_generic sets the Interrupt Disable bit. This
|
|
prevents the device from generating further interrupts until the bit is
|
|
cleared. The userspace driver should clear this bit before blocking and
|
|
waiting for more interrupts.
|
|
|
|
When host rescinds a device, the interrupt file descriptor is marked down
|
|
and any reads of the interrupt file descriptor will return -EIO. Similar
|
|
to a closed socket or disconnected serial device.
|
|
|
|
The vmbus device regions are mapped into uio device resources:
|
|
0) Channel ring buffers: guest to host and host to guest
|
|
1) Guest to host interrupt signalling pages
|
|
2) Guest to host monitor page
|
|
3) Network receive buffer region
|
|
4) Network send buffer region
|
|
|
|
Further information
|
|
===================
|
|
|
|
- `OSADL homepage. <http://www.osadl.org>`_
|
|
|
|
- `Linutronix homepage. <http://www.linutronix.de>`_
|