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d3fa72e455
Pass struct dev pointer to dma_cache_sync() dma_cache_sync() is ill-designed in that it does not have a struct device pointer argument which makes proper support for systems that consist of a mix of coherent and non-coherent DMA devices hard. Change dma_cache_sync to take a struct device pointer as first argument and fix all its callers to pass it. Signed-off-by: Ralf Baechle <ralf@linux-mips.org> Cc: James Bottomley <James.Bottomley@steeleye.com> Cc: "David S. Miller" <davem@davemloft.net> Cc: Greg KH <greg@kroah.com> Signed-off-by: Andrew Morton <akpm@osdl.org> Signed-off-by: Linus Torvalds <torvalds@osdl.org>
550 lines
21 KiB
Plaintext
550 lines
21 KiB
Plaintext
Dynamic DMA mapping using the generic device
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============================================
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James E.J. Bottomley <James.Bottomley@HansenPartnership.com>
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This document describes the DMA API. For a more gentle introduction
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phrased in terms of the pci_ equivalents (and actual examples) see
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DMA-mapping.txt
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This API is split into two pieces. Part I describes the API and the
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corresponding pci_ API. Part II describes the extensions to the API
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for supporting non-consistent memory machines. Unless you know that
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your driver absolutely has to support non-consistent platforms (this
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is usually only legacy platforms) you should only use the API
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described in part I.
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Part I - pci_ and dma_ Equivalent API
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-------------------------------------
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To get the pci_ API, you must #include <linux/pci.h>
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To get the dma_ API, you must #include <linux/dma-mapping.h>
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Part Ia - Using large dma-coherent buffers
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------------------------------------------
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void *
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dma_alloc_coherent(struct device *dev, size_t size,
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dma_addr_t *dma_handle, int flag)
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void *
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pci_alloc_consistent(struct pci_dev *dev, size_t size,
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dma_addr_t *dma_handle)
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Consistent memory is memory for which a write by either the device or
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the processor can immediately be read by the processor or device
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without having to worry about caching effects. (You may however need
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to make sure to flush the processor's write buffers before telling
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devices to read that memory.)
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This routine allocates a region of <size> bytes of consistent memory.
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it also returns a <dma_handle> which may be cast to an unsigned
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integer the same width as the bus and used as the physical address
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base of the region.
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Returns: a pointer to the allocated region (in the processor's virtual
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address space) or NULL if the allocation failed.
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Note: consistent memory can be expensive on some platforms, and the
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minimum allocation length may be as big as a page, so you should
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consolidate your requests for consistent memory as much as possible.
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The simplest way to do that is to use the dma_pool calls (see below).
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The flag parameter (dma_alloc_coherent only) allows the caller to
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specify the GFP_ flags (see kmalloc) for the allocation (the
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implementation may chose to ignore flags that affect the location of
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the returned memory, like GFP_DMA). For pci_alloc_consistent, you
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must assume GFP_ATOMIC behaviour.
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void
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dma_free_coherent(struct device *dev, size_t size, void *cpu_addr
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dma_addr_t dma_handle)
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void
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pci_free_consistent(struct pci_dev *dev, size_t size, void *cpu_addr
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dma_addr_t dma_handle)
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Free the region of consistent memory you previously allocated. dev,
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size and dma_handle must all be the same as those passed into the
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consistent allocate. cpu_addr must be the virtual address returned by
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the consistent allocate
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Part Ib - Using small dma-coherent buffers
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------------------------------------------
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To get this part of the dma_ API, you must #include <linux/dmapool.h>
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Many drivers need lots of small dma-coherent memory regions for DMA
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descriptors or I/O buffers. Rather than allocating in units of a page
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or more using dma_alloc_coherent(), you can use DMA pools. These work
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much like a struct kmem_cache, except that they use the dma-coherent allocator
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not __get_free_pages(). Also, they understand common hardware constraints
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for alignment, like queue heads needing to be aligned on N byte boundaries.
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struct dma_pool *
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dma_pool_create(const char *name, struct device *dev,
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size_t size, size_t align, size_t alloc);
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struct pci_pool *
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pci_pool_create(const char *name, struct pci_device *dev,
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size_t size, size_t align, size_t alloc);
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The pool create() routines initialize a pool of dma-coherent buffers
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for use with a given device. It must be called in a context which
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can sleep.
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The "name" is for diagnostics (like a struct kmem_cache name); dev and size
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are like what you'd pass to dma_alloc_coherent(). The device's hardware
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alignment requirement for this type of data is "align" (which is expressed
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in bytes, and must be a power of two). If your device has no boundary
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crossing restrictions, pass 0 for alloc; passing 4096 says memory allocated
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from this pool must not cross 4KByte boundaries.
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void *dma_pool_alloc(struct dma_pool *pool, int gfp_flags,
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dma_addr_t *dma_handle);
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void *pci_pool_alloc(struct pci_pool *pool, int gfp_flags,
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dma_addr_t *dma_handle);
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This allocates memory from the pool; the returned memory will meet the size
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and alignment requirements specified at creation time. Pass GFP_ATOMIC to
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prevent blocking, or if it's permitted (not in_interrupt, not holding SMP locks)
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pass GFP_KERNEL to allow blocking. Like dma_alloc_coherent(), this returns
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two values: an address usable by the cpu, and the dma address usable by the
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pool's device.
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void dma_pool_free(struct dma_pool *pool, void *vaddr,
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dma_addr_t addr);
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void pci_pool_free(struct pci_pool *pool, void *vaddr,
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dma_addr_t addr);
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This puts memory back into the pool. The pool is what was passed to
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the pool allocation routine; the cpu and dma addresses are what
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were returned when that routine allocated the memory being freed.
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void dma_pool_destroy(struct dma_pool *pool);
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void pci_pool_destroy(struct pci_pool *pool);
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The pool destroy() routines free the resources of the pool. They must be
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called in a context which can sleep. Make sure you've freed all allocated
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memory back to the pool before you destroy it.
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Part Ic - DMA addressing limitations
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------------------------------------
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int
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dma_supported(struct device *dev, u64 mask)
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int
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pci_dma_supported(struct device *dev, u64 mask)
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Checks to see if the device can support DMA to the memory described by
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mask.
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Returns: 1 if it can and 0 if it can't.
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Notes: This routine merely tests to see if the mask is possible. It
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won't change the current mask settings. It is more intended as an
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internal API for use by the platform than an external API for use by
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driver writers.
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int
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dma_set_mask(struct device *dev, u64 mask)
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int
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pci_set_dma_mask(struct pci_device *dev, u64 mask)
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Checks to see if the mask is possible and updates the device
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parameters if it is.
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Returns: 0 if successful and a negative error if not.
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u64
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dma_get_required_mask(struct device *dev)
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After setting the mask with dma_set_mask(), this API returns the
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actual mask (within that already set) that the platform actually
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requires to operate efficiently. Usually this means the returned mask
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is the minimum required to cover all of memory. Examining the
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required mask gives drivers with variable descriptor sizes the
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opportunity to use smaller descriptors as necessary.
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Requesting the required mask does not alter the current mask. If you
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wish to take advantage of it, you should issue another dma_set_mask()
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call to lower the mask again.
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Part Id - Streaming DMA mappings
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--------------------------------
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dma_addr_t
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dma_map_single(struct device *dev, void *cpu_addr, size_t size,
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enum dma_data_direction direction)
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dma_addr_t
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pci_map_single(struct device *dev, void *cpu_addr, size_t size,
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int direction)
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Maps a piece of processor virtual memory so it can be accessed by the
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device and returns the physical handle of the memory.
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The direction for both api's may be converted freely by casting.
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However the dma_ API uses a strongly typed enumerator for its
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direction:
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DMA_NONE = PCI_DMA_NONE no direction (used for
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debugging)
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DMA_TO_DEVICE = PCI_DMA_TODEVICE data is going from the
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memory to the device
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DMA_FROM_DEVICE = PCI_DMA_FROMDEVICE data is coming from
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the device to the
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memory
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DMA_BIDIRECTIONAL = PCI_DMA_BIDIRECTIONAL direction isn't known
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Notes: Not all memory regions in a machine can be mapped by this
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API. Further, regions that appear to be physically contiguous in
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kernel virtual space may not be contiguous as physical memory. Since
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this API does not provide any scatter/gather capability, it will fail
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if the user tries to map a non physically contiguous piece of memory.
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For this reason, it is recommended that memory mapped by this API be
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obtained only from sources which guarantee to be physically contiguous
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(like kmalloc).
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Further, the physical address of the memory must be within the
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dma_mask of the device (the dma_mask represents a bit mask of the
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addressable region for the device. i.e. if the physical address of
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the memory anded with the dma_mask is still equal to the physical
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address, then the device can perform DMA to the memory). In order to
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ensure that the memory allocated by kmalloc is within the dma_mask,
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the driver may specify various platform dependent flags to restrict
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the physical memory range of the allocation (e.g. on x86, GFP_DMA
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guarantees to be within the first 16Mb of available physical memory,
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as required by ISA devices).
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Note also that the above constraints on physical contiguity and
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dma_mask may not apply if the platform has an IOMMU (a device which
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supplies a physical to virtual mapping between the I/O memory bus and
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the device). However, to be portable, device driver writers may *not*
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assume that such an IOMMU exists.
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Warnings: Memory coherency operates at a granularity called the cache
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line width. In order for memory mapped by this API to operate
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correctly, the mapped region must begin exactly on a cache line
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boundary and end exactly on one (to prevent two separately mapped
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regions from sharing a single cache line). Since the cache line size
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may not be known at compile time, the API will not enforce this
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requirement. Therefore, it is recommended that driver writers who
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don't take special care to determine the cache line size at run time
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only map virtual regions that begin and end on page boundaries (which
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are guaranteed also to be cache line boundaries).
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DMA_TO_DEVICE synchronisation must be done after the last modification
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of the memory region by the software and before it is handed off to
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the driver. Once this primitive is used. Memory covered by this
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primitive should be treated as read only by the device. If the device
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may write to it at any point, it should be DMA_BIDIRECTIONAL (see
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below).
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DMA_FROM_DEVICE synchronisation must be done before the driver
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accesses data that may be changed by the device. This memory should
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be treated as read only by the driver. If the driver needs to write
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to it at any point, it should be DMA_BIDIRECTIONAL (see below).
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DMA_BIDIRECTIONAL requires special handling: it means that the driver
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isn't sure if the memory was modified before being handed off to the
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device and also isn't sure if the device will also modify it. Thus,
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you must always sync bidirectional memory twice: once before the
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memory is handed off to the device (to make sure all memory changes
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are flushed from the processor) and once before the data may be
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accessed after being used by the device (to make sure any processor
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cache lines are updated with data that the device may have changed.
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void
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dma_unmap_single(struct device *dev, dma_addr_t dma_addr, size_t size,
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enum dma_data_direction direction)
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void
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pci_unmap_single(struct pci_dev *hwdev, dma_addr_t dma_addr,
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size_t size, int direction)
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Unmaps the region previously mapped. All the parameters passed in
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must be identical to those passed in (and returned) by the mapping
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API.
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dma_addr_t
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dma_map_page(struct device *dev, struct page *page,
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unsigned long offset, size_t size,
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enum dma_data_direction direction)
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dma_addr_t
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pci_map_page(struct pci_dev *hwdev, struct page *page,
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unsigned long offset, size_t size, int direction)
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void
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dma_unmap_page(struct device *dev, dma_addr_t dma_address, size_t size,
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enum dma_data_direction direction)
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void
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pci_unmap_page(struct pci_dev *hwdev, dma_addr_t dma_address,
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size_t size, int direction)
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API for mapping and unmapping for pages. All the notes and warnings
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for the other mapping APIs apply here. Also, although the <offset>
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and <size> parameters are provided to do partial page mapping, it is
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recommended that you never use these unless you really know what the
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cache width is.
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int
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dma_mapping_error(dma_addr_t dma_addr)
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int
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pci_dma_mapping_error(dma_addr_t dma_addr)
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In some circumstances dma_map_single and dma_map_page will fail to create
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a mapping. A driver can check for these errors by testing the returned
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dma address with dma_mapping_error(). A non zero return value means the mapping
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could not be created and the driver should take appropriate action (eg
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reduce current DMA mapping usage or delay and try again later).
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int
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dma_map_sg(struct device *dev, struct scatterlist *sg,
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int nents, enum dma_data_direction direction)
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int
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pci_map_sg(struct pci_dev *hwdev, struct scatterlist *sg,
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int nents, int direction)
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Maps a scatter gather list from the block layer.
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Returns: the number of physical segments mapped (this may be shorted
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than <nents> passed in if the block layer determines that some
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elements of the scatter/gather list are physically adjacent and thus
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may be mapped with a single entry).
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Please note that the sg cannot be mapped again if it has been mapped once.
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The mapping process is allowed to destroy information in the sg.
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As with the other mapping interfaces, dma_map_sg can fail. When it
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does, 0 is returned and a driver must take appropriate action. It is
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critical that the driver do something, in the case of a block driver
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aborting the request or even oopsing is better than doing nothing and
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corrupting the filesystem.
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With scatterlists, you use the resulting mapping like this:
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int i, count = dma_map_sg(dev, sglist, nents, direction);
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struct scatterlist *sg;
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for (i = 0, sg = sglist; i < count; i++, sg++) {
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hw_address[i] = sg_dma_address(sg);
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hw_len[i] = sg_dma_len(sg);
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}
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where nents is the number of entries in the sglist.
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The implementation is free to merge several consecutive sglist entries
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into one (e.g. with an IOMMU, or if several pages just happen to be
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physically contiguous) and returns the actual number of sg entries it
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mapped them to. On failure 0, is returned.
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Then you should loop count times (note: this can be less than nents times)
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and use sg_dma_address() and sg_dma_len() macros where you previously
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accessed sg->address and sg->length as shown above.
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void
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dma_unmap_sg(struct device *dev, struct scatterlist *sg,
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int nhwentries, enum dma_data_direction direction)
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void
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pci_unmap_sg(struct pci_dev *hwdev, struct scatterlist *sg,
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int nents, int direction)
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unmap the previously mapped scatter/gather list. All the parameters
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must be the same as those and passed in to the scatter/gather mapping
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API.
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Note: <nents> must be the number you passed in, *not* the number of
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physical entries returned.
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void
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dma_sync_single(struct device *dev, dma_addr_t dma_handle, size_t size,
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enum dma_data_direction direction)
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void
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pci_dma_sync_single(struct pci_dev *hwdev, dma_addr_t dma_handle,
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size_t size, int direction)
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void
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dma_sync_sg(struct device *dev, struct scatterlist *sg, int nelems,
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enum dma_data_direction direction)
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void
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pci_dma_sync_sg(struct pci_dev *hwdev, struct scatterlist *sg,
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int nelems, int direction)
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synchronise a single contiguous or scatter/gather mapping. All the
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parameters must be the same as those passed into the single mapping
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API.
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Notes: You must do this:
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- Before reading values that have been written by DMA from the device
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(use the DMA_FROM_DEVICE direction)
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- After writing values that will be written to the device using DMA
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(use the DMA_TO_DEVICE) direction
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- before *and* after handing memory to the device if the memory is
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DMA_BIDIRECTIONAL
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See also dma_map_single().
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Part II - Advanced dma_ usage
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-----------------------------
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Warning: These pieces of the DMA API have no PCI equivalent. They
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should also not be used in the majority of cases, since they cater for
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unlikely corner cases that don't belong in usual drivers.
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If you don't understand how cache line coherency works between a
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processor and an I/O device, you should not be using this part of the
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API at all.
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void *
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dma_alloc_noncoherent(struct device *dev, size_t size,
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dma_addr_t *dma_handle, int flag)
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Identical to dma_alloc_coherent() except that the platform will
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choose to return either consistent or non-consistent memory as it sees
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fit. By using this API, you are guaranteeing to the platform that you
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have all the correct and necessary sync points for this memory in the
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driver should it choose to return non-consistent memory.
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Note: where the platform can return consistent memory, it will
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guarantee that the sync points become nops.
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Warning: Handling non-consistent memory is a real pain. You should
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only ever use this API if you positively know your driver will be
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required to work on one of the rare (usually non-PCI) architectures
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that simply cannot make consistent memory.
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void
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dma_free_noncoherent(struct device *dev, size_t size, void *cpu_addr,
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dma_addr_t dma_handle)
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free memory allocated by the nonconsistent API. All parameters must
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be identical to those passed in (and returned by
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dma_alloc_noncoherent()).
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int
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dma_is_consistent(struct device *dev, dma_addr_t dma_handle)
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returns true if the device dev is performing consistent DMA on the memory
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area pointed to by the dma_handle.
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int
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dma_get_cache_alignment(void)
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returns the processor cache alignment. This is the absolute minimum
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alignment *and* width that you must observe when either mapping
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memory or doing partial flushes.
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Notes: This API may return a number *larger* than the actual cache
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line, but it will guarantee that one or more cache lines fit exactly
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into the width returned by this call. It will also always be a power
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of two for easy alignment
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void
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dma_sync_single_range(struct device *dev, dma_addr_t dma_handle,
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unsigned long offset, size_t size,
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enum dma_data_direction direction)
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does a partial sync. starting at offset and continuing for size. You
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must be careful to observe the cache alignment and width when doing
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anything like this. You must also be extra careful about accessing
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memory you intend to sync partially.
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void
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dma_cache_sync(struct device *dev, void *vaddr, size_t size,
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enum dma_data_direction direction)
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Do a partial sync of memory that was allocated by
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dma_alloc_noncoherent(), starting at virtual address vaddr and
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continuing on for size. Again, you *must* observe the cache line
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boundaries when doing this.
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int
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dma_declare_coherent_memory(struct device *dev, dma_addr_t bus_addr,
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dma_addr_t device_addr, size_t size, int
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flags)
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Declare region of memory to be handed out by dma_alloc_coherent when
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it's asked for coherent memory for this device.
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bus_addr is the physical address to which the memory is currently
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assigned in the bus responding region (this will be used by the
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platform to perform the mapping)
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device_addr is the physical address the device needs to be programmed
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with actually to address this memory (this will be handed out as the
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dma_addr_t in dma_alloc_coherent())
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size is the size of the area (must be multiples of PAGE_SIZE).
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flags can be or'd together and are
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DMA_MEMORY_MAP - request that the memory returned from
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dma_alloc_coherent() be directly writable.
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DMA_MEMORY_IO - request that the memory returned from
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dma_alloc_coherent() be addressable using read/write/memcpy_toio etc.
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One or both of these flags must be present
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DMA_MEMORY_INCLUDES_CHILDREN - make the declared memory be allocated by
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dma_alloc_coherent of any child devices of this one (for memory residing
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on a bridge).
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DMA_MEMORY_EXCLUSIVE - only allocate memory from the declared regions.
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Do not allow dma_alloc_coherent() to fall back to system memory when
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it's out of memory in the declared region.
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The return value will be either DMA_MEMORY_MAP or DMA_MEMORY_IO and
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must correspond to a passed in flag (i.e. no returning DMA_MEMORY_IO
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if only DMA_MEMORY_MAP were passed in) for success or zero for
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failure.
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Note, for DMA_MEMORY_IO returns, all subsequent memory returned by
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dma_alloc_coherent() may no longer be accessed directly, but instead
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must be accessed using the correct bus functions. If your driver
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isn't prepared to handle this contingency, it should not specify
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DMA_MEMORY_IO in the input flags.
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As a simplification for the platforms, only *one* such region of
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memory may be declared per device.
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For reasons of efficiency, most platforms choose to track the declared
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region only at the granularity of a page. For smaller allocations,
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you should use the dma_pool() API.
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void
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dma_release_declared_memory(struct device *dev)
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Remove the memory region previously declared from the system. This
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API performs *no* in-use checking for this region and will return
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unconditionally having removed all the required structures. It is the
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drivers job to ensure that no parts of this memory region are
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currently in use.
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void *
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dma_mark_declared_memory_occupied(struct device *dev,
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dma_addr_t device_addr, size_t size)
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This is used to occupy specific regions of the declared space
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(dma_alloc_coherent() will hand out the first free region it finds).
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device_addr is the *device* address of the region requested
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size is the size (and should be a page sized multiple).
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The return value will be either a pointer to the processor virtual
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address of the memory, or an error (via PTR_ERR()) if any part of the
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region is occupied.
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