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Move the x86 documentation under Documentation/arch/ as a way of cleaning up the top-level directory and making the structure of our docs more closely match the structure of the source directories it describes. All in-kernel references to the old paths have been updated. Acked-by: Dave Hansen <dave.hansen@linux.intel.com> Cc: linux-arch@vger.kernel.org Cc: x86@kernel.org Cc: Borislav Petkov <bp@alien8.de> Cc: Thomas Gleixner <tglx@linutronix.de> Link: https://lore.kernel.org/lkml/20230315211523.108836-1-corbet@lwn.net/ Signed-off-by: Jonathan Corbet <corbet@lwn.net>
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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 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 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 ioremap(), and they can run out unless you
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call 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 memcpy_toio(),
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memcpy_fromio() and 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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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 inb(), inw(),
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inl(), outb(), outw() and
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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 ins() and
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outs() functions copy bytes, words or longs to the given
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port.
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__iomem pointer tokens
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======================
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The data type for an MMIO address is an ``__iomem`` qualified pointer, such as
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``void __iomem *reg``. On most architectures it is a regular pointer that
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points to a virtual memory address and can be offset or dereferenced, but in
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portable code, it must only be passed from and to functions that explicitly
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operated on an ``__iomem`` token, in particular the ioremap() and
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readl()/writel() functions. The 'sparse' semantic code checker can be used to
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verify that this is done correctly.
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While on most architectures, ioremap() creates a page table entry for an
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uncached virtual address pointing to the physical MMIO address, some
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architectures require special instructions for MMIO, and the ``__iomem`` pointer
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just encodes the physical address or an offsettable cookie that is interpreted
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by readl()/writel().
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Differences between I/O access functions
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========================================
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readq(), readl(), readw(), readb(), writeq(), writel(), writew(), writeb()
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These are the most generic accessors, providing serialization against other
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MMIO accesses and DMA accesses as well as fixed endianness for accessing
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little-endian PCI devices and on-chip peripherals. Portable device drivers
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should generally use these for any access to ``__iomem`` pointers.
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Note that posted writes are not strictly ordered against a spinlock, see
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Documentation/driver-api/io_ordering.rst.
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readq_relaxed(), readl_relaxed(), readw_relaxed(), readb_relaxed(),
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writeq_relaxed(), writel_relaxed(), writew_relaxed(), writeb_relaxed()
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On architectures that require an expensive barrier for serializing against
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DMA, these "relaxed" versions of the MMIO accessors only serialize against
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each other, but contain a less expensive barrier operation. A device driver
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might use these in a particularly performance sensitive fast path, with a
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comment that explains why the usage in a specific location is safe without
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the extra barriers.
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See memory-barriers.txt for a more detailed discussion on the precise ordering
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guarantees of the non-relaxed and relaxed versions.
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ioread64(), ioread32(), ioread16(), ioread8(),
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iowrite64(), iowrite32(), iowrite16(), iowrite8()
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These are an alternative to the normal readl()/writel() functions, with almost
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identical behavior, but they can also operate on ``__iomem`` tokens returned
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for mapping PCI I/O space with pci_iomap() or ioport_map(). On architectures
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that require special instructions for I/O port access, this adds a small
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overhead for an indirect function call implemented in lib/iomap.c, while on
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other architectures, these are simply aliases.
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ioread64be(), ioread32be(), ioread16be()
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iowrite64be(), iowrite32be(), iowrite16be()
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These behave in the same way as the ioread32()/iowrite32() family, but with
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reversed byte order, for accessing devices with big-endian MMIO registers.
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Device drivers that can operate on either big-endian or little-endian
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registers may have to implement a custom wrapper function that picks one or
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the other depending on which device was found.
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Note: On some architectures, the normal readl()/writel() functions
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traditionally assume that devices are the same endianness as the CPU, while
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using a hardware byte-reverse on the PCI bus when running a big-endian kernel.
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Drivers that use readl()/writel() this way are generally not portable, but
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tend to be limited to a particular SoC.
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hi_lo_readq(), lo_hi_readq(), hi_lo_readq_relaxed(), lo_hi_readq_relaxed(),
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ioread64_lo_hi(), ioread64_hi_lo(), ioread64be_lo_hi(), ioread64be_hi_lo(),
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hi_lo_writeq(), lo_hi_writeq(), hi_lo_writeq_relaxed(), lo_hi_writeq_relaxed(),
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iowrite64_lo_hi(), iowrite64_hi_lo(), iowrite64be_lo_hi(), iowrite64be_hi_lo()
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Some device drivers have 64-bit registers that cannot be accessed atomically
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on 32-bit architectures but allow two consecutive 32-bit accesses instead.
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Since it depends on the particular device which of the two halves has to be
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accessed first, a helper is provided for each combination of 64-bit accessors
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with either low/high or high/low word ordering. A device driver must include
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either <linux/io-64-nonatomic-lo-hi.h> or <linux/io-64-nonatomic-hi-lo.h> to
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get the function definitions along with helpers that redirect the normal
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readq()/writeq() to them on architectures that do not provide 64-bit access
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natively.
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__raw_readq(), __raw_readl(), __raw_readw(), __raw_readb(),
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__raw_writeq(), __raw_writel(), __raw_writew(), __raw_writeb()
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These are low-level MMIO accessors without barriers or byteorder changes and
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architecture specific behavior. Accesses are usually atomic in the sense that
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a four-byte __raw_readl() does not get split into individual byte loads, but
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multiple consecutive accesses can be combined on the bus. In portable code, it
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is only safe to use these to access memory behind a device bus but not MMIO
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registers, as there are no ordering guarantees with regard to other MMIO
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accesses or even spinlocks. The byte order is generally the same as for normal
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memory, so unlike the other functions, these can be used to copy data between
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kernel memory and device memory.
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inl(), inw(), inb(), outl(), outw(), outb()
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PCI I/O port resources traditionally require separate helpers as they are
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implemented using special instructions on the x86 architecture. On most other
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architectures, these are mapped to readl()/writel() style accessors
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internally, usually pointing to a fixed area in virtual memory. Instead of an
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``__iomem`` pointer, the address is a 32-bit integer token to identify a port
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number. PCI requires I/O port access to be non-posted, meaning that an outb()
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must complete before the following code executes, while a normal writeb() may
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still be in progress. On architectures that correctly implement this, I/O port
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access is therefore ordered against spinlocks. Many non-x86 PCI host bridge
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implementations and CPU architectures however fail to implement non-posted I/O
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space on PCI, so they can end up being posted on such hardware.
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In some architectures, the I/O port number space has a 1:1 mapping to
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``__iomem`` pointers, but this is not recommended and device drivers should
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not rely on that for portability. Similarly, an I/O port number as described
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in a PCI base address register may not correspond to the port number as seen
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by a device driver. Portable drivers need to read the port number for the
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resource provided by the kernel.
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There are no direct 64-bit I/O port accessors, but pci_iomap() in combination
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with ioread64/iowrite64 can be used instead.
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inl_p(), inw_p(), inb_p(), outl_p(), outw_p(), outb_p()
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On ISA devices that require specific timing, the _p versions of the I/O
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accessors add a small delay. On architectures that do not have ISA buses,
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these are aliases to the normal inb/outb helpers.
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readsq, readsl, readsw, readsb
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writesq, writesl, writesw, writesb
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ioread64_rep, ioread32_rep, ioread16_rep, ioread8_rep
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iowrite64_rep, iowrite32_rep, iowrite16_rep, iowrite8_rep
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insl, insw, insb, outsl, outsw, outsb
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These are helpers that access the same address multiple times, usually to copy
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data between kernel memory byte stream and a FIFO buffer. Unlike the normal
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MMIO accessors, these do not perform a byteswap on big-endian kernels, so the
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first byte in the FIFO register corresponds to the first byte in the memory
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buffer regardless of the architecture.
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Device memory mapping modes
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===========================
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Some architectures support multiple modes for mapping device memory.
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ioremap_*() variants provide a common abstraction around these
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architecture-specific modes, with a shared set of semantics.
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ioremap() is the most common mapping type, and is applicable to typical device
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memory (e.g. I/O registers). Other modes can offer weaker or stronger
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guarantees, if supported by the architecture. From most to least common, they
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are as follows:
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ioremap()
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---------
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The default mode, suitable for most memory-mapped devices, e.g. control
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registers. Memory mapped using ioremap() has the following characteristics:
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* Uncached - CPU-side caches are bypassed, and all reads and writes are handled
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directly by the device
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* No speculative operations - the CPU may not issue a read or write to this
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memory, unless the instruction that does so has been reached in committed
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program flow.
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* No reordering - The CPU may not reorder accesses to this memory mapping with
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respect to each other. On some architectures, this relies on barriers in
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readl_relaxed()/writel_relaxed().
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* No repetition - The CPU may not issue multiple reads or writes for a single
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program instruction.
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* No write-combining - Each I/O operation results in one discrete read or write
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being issued to the device, and multiple writes are not combined into larger
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writes. This may or may not be enforced when using __raw I/O accessors or
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pointer dereferences.
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* Non-executable - The CPU is not allowed to speculate instruction execution
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from this memory (it probably goes without saying, but you're also not
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allowed to jump into device memory).
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On many platforms and buses (e.g. PCI), writes issued through ioremap()
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mappings are posted, which means that the CPU does not wait for the write to
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actually reach the target device before retiring the write instruction.
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On many platforms, I/O accesses must be aligned with respect to the access
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size; failure to do so will result in an exception or unpredictable results.
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ioremap_wc()
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------------
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Maps I/O memory as normal memory with write combining. Unlike ioremap(),
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* The CPU may speculatively issue reads from the device that the program
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didn't actually execute, and may choose to basically read whatever it wants.
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* The CPU may reorder operations as long as the result is consistent from the
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program's point of view.
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* The CPU may write to the same location multiple times, even when the program
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issued a single write.
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* The CPU may combine several writes into a single larger write.
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This mode is typically used for video framebuffers, where it can increase
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performance of writes. It can also be used for other blocks of memory in
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devices (e.g. buffers or shared memory), but care must be taken as accesses are
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not guaranteed to be ordered with respect to normal ioremap() MMIO register
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accesses without explicit barriers.
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On a PCI bus, it is usually safe to use ioremap_wc() on MMIO areas marked as
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``IORESOURCE_PREFETCH``, but it may not be used on those without the flag.
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For on-chip devices, there is no corresponding flag, but a driver can use
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ioremap_wc() on a device that is known to be safe.
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ioremap_wt()
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------------
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Maps I/O memory as normal memory with write-through caching. Like ioremap_wc(),
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but also,
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* The CPU may cache writes issued to and reads from the device, and serve reads
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from that cache.
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This mode is sometimes used for video framebuffers, where drivers still expect
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writes to reach the device in a timely manner (and not be stuck in the CPU
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cache), but reads may be served from the cache for efficiency. However, it is
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rarely useful these days, as framebuffer drivers usually perform writes only,
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for which ioremap_wc() is more efficient (as it doesn't needlessly trash the
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cache). Most drivers should not use this.
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ioremap_np()
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------------
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Like ioremap(), but explicitly requests non-posted write semantics. On some
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architectures and buses, ioremap() mappings have posted write semantics, which
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means that writes can appear to "complete" from the point of view of the
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CPU before the written data actually arrives at the target device. Writes are
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still ordered with respect to other writes and reads from the same device, but
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due to the posted write semantics, this is not the case with respect to other
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devices. ioremap_np() explicitly requests non-posted semantics, which means
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that the write instruction will not appear to complete until the device has
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received (and to some platform-specific extent acknowledged) the written data.
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This mapping mode primarily exists to cater for platforms with bus fabrics that
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require this particular mapping mode to work correctly. These platforms set the
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``IORESOURCE_MEM_NONPOSTED`` flag for a resource that requires ioremap_np()
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semantics and portable drivers should use an abstraction that automatically
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selects it where appropriate (see the `Higher-level ioremap abstractions`_
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section below).
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The bare ioremap_np() is only available on some architectures; on others, it
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always returns NULL. Drivers should not normally use it, unless they are
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platform-specific or they derive benefit from non-posted writes where
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supported, and can fall back to ioremap() otherwise. The normal approach to
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ensure posted write completion is to do a dummy read after a write as
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explained in `Accessing the device`_, which works with ioremap() on all
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platforms.
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ioremap_np() should never be used for PCI drivers. PCI memory space writes are
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always posted, even on architectures that otherwise implement ioremap_np().
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Using ioremap_np() for PCI BARs will at best result in posted write semantics,
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and at worst result in complete breakage.
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Note that non-posted write semantics are orthogonal to CPU-side ordering
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guarantees. A CPU may still choose to issue other reads or writes before a
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non-posted write instruction retires. See the previous section on MMIO access
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functions for details on the CPU side of things.
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ioremap_uc()
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------------
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ioremap_uc() behaves like ioremap() except that on the x86 architecture without
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'PAT' mode, it marks memory as uncached even when the MTRR has designated
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it as cacheable, see Documentation/arch/x86/pat.rst.
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Portable drivers should avoid the use of ioremap_uc().
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ioremap_cache()
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---------------
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ioremap_cache() effectively maps I/O memory as normal RAM. CPU write-back
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caches can be used, and the CPU is free to treat the device as if it were a
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block of RAM. This should never be used for device memory which has side
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effects of any kind, or which does not return the data previously written on
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read.
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It should also not be used for actual RAM, as the returned pointer is an
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``__iomem`` token. memremap() can be used for mapping normal RAM that is outside
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of the linear kernel memory area to a regular pointer.
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Portable drivers should avoid the use of ioremap_cache().
|
|
|
|
Architecture example
|
|
--------------------
|
|
|
|
Here is how the above modes map to memory attribute settings on the ARM64
|
|
architecture:
|
|
|
|
+------------------------+--------------------------------------------+
|
|
| API | Memory region type and cacheability |
|
|
+------------------------+--------------------------------------------+
|
|
| ioremap_np() | Device-nGnRnE |
|
|
+------------------------+--------------------------------------------+
|
|
| ioremap() | Device-nGnRE |
|
|
+------------------------+--------------------------------------------+
|
|
| ioremap_uc() | (not implemented) |
|
|
+------------------------+--------------------------------------------+
|
|
| ioremap_wc() | Normal-Non Cacheable |
|
|
+------------------------+--------------------------------------------+
|
|
| ioremap_wt() | (not implemented; fallback to ioremap) |
|
|
+------------------------+--------------------------------------------+
|
|
| ioremap_cache() | Normal-Write-Back Cacheable |
|
|
+------------------------+--------------------------------------------+
|
|
|
|
Higher-level ioremap abstractions
|
|
=================================
|
|
|
|
Instead of using the above raw ioremap() modes, drivers are encouraged to use
|
|
higher-level APIs. These APIs may implement platform-specific logic to
|
|
automatically choose an appropriate ioremap mode on any given bus, allowing for
|
|
a platform-agnostic driver to work on those platforms without any special
|
|
cases. At the time of this writing, the following ioremap() wrappers have such
|
|
logic:
|
|
|
|
devm_ioremap_resource()
|
|
|
|
Can automatically select ioremap_np() over ioremap() according to platform
|
|
requirements, if the ``IORESOURCE_MEM_NONPOSTED`` flag is set on the struct
|
|
resource. Uses devres to automatically unmap the resource when the driver
|
|
probe() function fails or a device in unbound from its driver.
|
|
|
|
Documented in Documentation/driver-api/driver-model/devres.rst.
|
|
|
|
of_address_to_resource()
|
|
|
|
Automatically sets the ``IORESOURCE_MEM_NONPOSTED`` flag for platforms that
|
|
require non-posted writes for certain buses (see the nonposted-mmio and
|
|
posted-mmio device tree properties).
|
|
|
|
of_iomap()
|
|
|
|
Maps the resource described in a ``reg`` property in the device tree, doing
|
|
all required translations. Automatically selects ioremap_np() according to
|
|
platform requirements, as above.
|
|
|
|
pci_ioremap_bar(), pci_ioremap_wc_bar()
|
|
|
|
Maps the resource described in a PCI base address without having to extract
|
|
the physical address first.
|
|
|
|
pci_iomap(), pci_iomap_wc()
|
|
|
|
Like pci_ioremap_bar()/pci_ioremap_bar(), but also works on I/O space when
|
|
used together with ioread32()/iowrite32() and similar accessors
|
|
|
|
pcim_iomap()
|
|
|
|
Like pci_iomap(), but uses devres to automatically unmap the resource when
|
|
the driver probe() function fails or a device in unbound from its driver
|
|
|
|
Documented in Documentation/driver-api/driver-model/devres.rst.
|
|
|
|
Not using these wrappers may make drivers unusable on certain platforms with
|
|
stricter rules for mapping I/O memory.
|
|
|
|
Generalizing Access to System and I/O Memory
|
|
============================================
|
|
|
|
.. kernel-doc:: include/linux/iosys-map.h
|
|
:doc: overview
|
|
|
|
.. kernel-doc:: include/linux/iosys-map.h
|
|
:internal:
|
|
|
|
Public Functions Provided
|
|
=========================
|
|
|
|
.. kernel-doc:: arch/x86/include/asm/io.h
|
|
:internal:
|
|
|
|
.. kernel-doc:: lib/pci_iomap.c
|
|
:export:
|