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202 lines
8.1 KiB
ReStructuredText
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.. Copyright 2001 Matthew Wilcox
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..
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.. This documentation is free software; you can redistribute
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.. it and/or modify it under the terms of the GNU General Public
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.. License as published by the Free Software Foundation; either
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.. version 2 of the License, or (at your option) any later
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.. version.
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===============================
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Bus-Independent Device Accesses
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===============================
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:Author: Matthew Wilcox
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:Author: Alan Cox
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Introduction
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============
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Linux provides an API which abstracts performing IO across all busses
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and devices, allowing device drivers to be written independently of bus
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type.
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Memory Mapped IO
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================
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Getting Access to the Device
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----------------------------
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The most widely supported form of IO is memory mapped IO. That is, a
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part of the CPU's address space is interpreted not as accesses to
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memory, but as accesses to a device. Some architectures define devices
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to be at a fixed address, but most have some method of discovering
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devices. The PCI bus walk is a good example of such a scheme. This
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document does not cover how to receive such an address, but assumes you
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are starting with one. Physical addresses are of type unsigned long.
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This address should not be used directly. Instead, to get an address
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suitable for passing to the accessor functions described below, you
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should call :c:func:`ioremap()`. An address suitable for accessing
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the device will be returned to you.
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After you've finished using the device (say, in your module's exit
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routine), call :c:func:`iounmap()` in order to return the address
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space to the kernel. Most architectures allocate new address space each
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time you call :c:func:`ioremap()`, and they can run out unless you
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call :c:func:`iounmap()`.
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Accessing the device
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--------------------
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The part of the interface most used by drivers is reading and writing
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memory-mapped registers on the device. Linux provides interfaces to read
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and write 8-bit, 16-bit, 32-bit and 64-bit quantities. Due to a
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historical accident, these are named byte, word, long and quad accesses.
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Both read and write accesses are supported; there is no prefetch support
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at this time.
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The functions are named readb(), readw(), readl(), readq(),
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readb_relaxed(), readw_relaxed(), readl_relaxed(), readq_relaxed(),
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writeb(), writew(), writel() and writeq().
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Some devices (such as framebuffers) would like to use larger transfers than
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8 bytes at a time. For these devices, the :c:func:`memcpy_toio()`,
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:c:func:`memcpy_fromio()` and :c:func:`memset_io()` functions are
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provided. Do not use memset or memcpy on IO addresses; they are not
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guaranteed to copy data in order.
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The read and write functions are defined to be ordered. That is the
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compiler is not permitted to reorder the I/O sequence. When the ordering
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can be compiler optimised, you can use __readb() and friends to
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indicate the relaxed ordering. Use this with care.
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While the basic functions are defined to be synchronous with respect to
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each other and ordered with respect to each other the busses the devices
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sit on may themselves have asynchronicity. In particular many authors
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are burned by the fact that PCI bus writes are posted asynchronously. A
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driver author must issue a read from the same device to ensure that
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writes have occurred in the specific cases the author cares. This kind
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of property cannot be hidden from driver writers in the API. In some
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cases, the read used to flush the device may be expected to fail (if the
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card is resetting, for example). In that case, the read should be done
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from config space, which is guaranteed to soft-fail if the card doesn't
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respond.
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The following is an example of flushing a write to a device when the
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driver would like to ensure the write's effects are visible prior to
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continuing execution::
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static inline void
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qla1280_disable_intrs(struct scsi_qla_host *ha)
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{
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struct device_reg *reg;
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reg = ha->iobase;
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/* disable risc and host interrupts */
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WRT_REG_WORD(®->ictrl, 0);
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/*
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* The following read will ensure that the above write
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* has been received by the device before we return from this
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* function.
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*/
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RD_REG_WORD(®->ictrl);
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ha->flags.ints_enabled = 0;
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}
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In addition to write posting, on some large multiprocessing systems
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(e.g. SGI Challenge, Origin and Altix machines) posted writes won't be
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strongly ordered coming from different CPUs. Thus it's important to
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properly protect parts of your driver that do memory-mapped writes with
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locks and use the :c:func:`mmiowb()` to make sure they arrive in the
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order intended. Issuing a regular readX() will also ensure write ordering,
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but should only be used when the
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driver has to be sure that the write has actually arrived at the device
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(not that it's simply ordered with respect to other writes), since a
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full readX() is a relatively expensive operation.
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Generally, one should use :c:func:`mmiowb()` prior to releasing a spinlock
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that protects regions using :c:func:`writeb()` or similar functions that
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aren't surrounded by readb() calls, which will ensure ordering
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and flushing. The following pseudocode illustrates what might occur if
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write ordering isn't guaranteed via :c:func:`mmiowb()` or one of the
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readX() functions::
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CPU A: spin_lock_irqsave(&dev_lock, flags)
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CPU A: ...
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CPU A: writel(newval, ring_ptr);
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CPU A: spin_unlock_irqrestore(&dev_lock, flags)
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...
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CPU B: spin_lock_irqsave(&dev_lock, flags)
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CPU B: writel(newval2, ring_ptr);
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CPU B: ...
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CPU B: spin_unlock_irqrestore(&dev_lock, flags)
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In the case above, newval2 could be written to ring_ptr before newval.
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Fixing it is easy though::
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CPU A: spin_lock_irqsave(&dev_lock, flags)
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CPU A: ...
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CPU A: writel(newval, ring_ptr);
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CPU A: mmiowb(); /* ensure no other writes beat us to the device */
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CPU A: spin_unlock_irqrestore(&dev_lock, flags)
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...
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CPU B: spin_lock_irqsave(&dev_lock, flags)
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CPU B: writel(newval2, ring_ptr);
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CPU B: ...
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CPU B: mmiowb();
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CPU B: spin_unlock_irqrestore(&dev_lock, flags)
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See tg3.c for a real world example of how to use :c:func:`mmiowb()`
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PCI ordering rules also guarantee that PIO read responses arrive after any
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outstanding DMA writes from that bus, since for some devices the result of
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a readb() call may signal to the driver that a DMA transaction is
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complete. In many cases, however, the driver may want to indicate that the
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next readb() call has no relation to any previous DMA writes
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performed by the device. The driver can use readb_relaxed() for
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these cases, although only some platforms will honor the relaxed
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semantics. Using the relaxed read functions will provide significant
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performance benefits on platforms that support it. The qla2xxx driver
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provides examples of how to use readX_relaxed(). In many cases, a majority
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of the driver's readX() calls can safely be converted to readX_relaxed()
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calls, since only a few will indicate or depend on DMA completion.
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Port Space Accesses
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===================
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Port Space Explained
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--------------------
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Another form of IO commonly supported is Port Space. This is a range of
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addresses separate to the normal memory address space. Access to these
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addresses is generally not as fast as accesses to the memory mapped
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addresses, and it also has a potentially smaller address space.
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Unlike memory mapped IO, no preparation is required to access port
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space.
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Accessing Port Space
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--------------------
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Accesses to this space are provided through a set of functions which
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allow 8-bit, 16-bit and 32-bit accesses; also known as byte, word and
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long. These functions are :c:func:`inb()`, :c:func:`inw()`,
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:c:func:`inl()`, :c:func:`outb()`, :c:func:`outw()` and
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:c:func:`outl()`.
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Some variants are provided for these functions. Some devices require
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that accesses to their ports are slowed down. This functionality is
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provided by appending a ``_p`` to the end of the function.
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There are also equivalents to memcpy. The :c:func:`ins()` and
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:c:func:`outs()` functions copy bytes, words or longs to the given
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port.
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Public Functions Provided
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=========================
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.. kernel-doc:: arch/x86/include/asm/io.h
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:internal:
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.. kernel-doc:: lib/pci_iomap.c
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:export:
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