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linux/arch/powerpc/include/asm/io.h
Linus Torvalds eb0ece1602 - The 6 patch series "Enable strict percpu address space checks" from 
Uros Bizjak uses x86 named address space qualifiers to provide
   compile-time checking of percpu area accesses.
 
   This has caused a small amount of fallout - two or three issues were
   reported.  In all cases the calling code was founf to be incorrect.
 
 - The 4 patch series "Some cleanup for memcg" from Chen Ridong
   implements some relatively monir cleanups for the memcontrol code.
 
 - The 17 patch series "mm: fixes for device-exclusive entries (hmm)"
   from David Hildenbrand fixes a boatload of issues which David found then
   using device-exclusive PTE entries when THP is enabled.  More work is
   needed, but this makes thins better - our own HMM selftests now succeed.
 
 - The 2 patch series "mm: zswap: remove z3fold and zbud" from Yosry
   Ahmed remove the z3fold and zbud implementations.  They have been
   deprecated for half a year and nobody has complained.
 
 - The 5 patch series "mm: further simplify VMA merge operation" from
   Lorenzo Stoakes implements numerous simplifications in this area.  No
   runtime effects are anticipated.
 
 - The 4 patch series "mm/madvise: remove redundant mmap_lock operations
   from process_madvise()" from SeongJae Park rationalizes the locking in
   the madvise() implementation.  Performance gains of 20-25% were observed
   in one MADV_DONTNEED microbenchmark.
 
 - The 12 patch series "Tiny cleanup and improvements about SWAP code"
   from Baoquan He contains a number of touchups to issues which Baoquan
   noticed when working on the swap code.
 
 - The 2 patch series "mm: kmemleak: Usability improvements" from Catalin
   Marinas implements a couple of improvements to the kmemleak user-visible
   output.
 
 - The 2 patch series "mm/damon/paddr: fix large folios access and
   schemes handling" from Usama Arif provides a couple of fixes for DAMON's
   handling of large folios.
 
 - The 3 patch series "mm/damon/core: fix wrong and/or useless
   damos_walk() behaviors" from SeongJae Park fixes a few issues with the
   accuracy of kdamond's walking of DAMON regions.
 
 - The 3 patch series "expose mapping wrprotect, fix fb_defio use" from
   Lorenzo Stoakes changes the interaction between framebuffer deferred-io
   and core MM.  No functional changes are anticipated - this is
   preparatory work for the future removal of page structure fields.
 
 - The 4 patch series "mm/damon: add support for hugepage_size DAMOS
   filter" from Usama Arif adds a DAMOS filter which permits the filtering
   by huge page sizes.
 
 - The 4 patch series "mm: permit guard regions for file-backed/shmem
   mappings" from Lorenzo Stoakes extends the guard region feature from its
   present "anon mappings only" state.  The feature now covers shmem and
   file-backed mappings.
 
 - The 4 patch series "mm: batched unmap lazyfree large folios during
   reclamation" from Barry Song cleans up and speeds up the unmapping for
   pte-mapped large folios.
 
 - The 18 patch series "reimplement per-vma lock as a refcount" from
   Suren Baghdasaryan puts the vm_lock back into the vma.  Our reasons for
   pulling it out were largely bogus and that change made the code more
   messy.  This patchset provides small (0-10%) improvements on one
   microbenchmark.
 
 - The 5 patch series "Docs/mm/damon: misc DAMOS filters documentation
   fixes and improves" from SeongJae Park does some maintenance work on the
   DAMON docs.
 
 - The 27 patch series "hugetlb/CMA improvements for large systems" from
   Frank van der Linden addresses a pile of issues which have been observed
   when using CMA on large machines.
 
 - The 2 patch series "mm/damon: introduce DAMOS filter type for unmapped
   pages" from SeongJae Park enables users of DMAON/DAMOS to filter my the
   page's mapped/unmapped status.
 
 - The 19 patch series "zsmalloc/zram: there be preemption" from Sergey
   Senozhatsky teaches zram to run its compression and decompression
   operations preemptibly.
 
 - The 12 patch series "selftests/mm: Some cleanups from trying to run
   them" from Brendan Jackman fixes a pile of unrelated issues which
   Brendan encountered while runnimg our selftests.
 
 - The 2 patch series "fs/proc/task_mmu: add guard region bit to pagemap"
   from Lorenzo Stoakes permits userspace to use /proc/pid/pagemap to
   determine whether a particular page is a guard page.
 
 - The 7 patch series "mm, swap: remove swap slot cache" from Kairui Song
   removes the swap slot cache from the allocation path - it simply wasn't
   being effective.
 
 - The 5 patch series "mm: cleanups for device-exclusive entries (hmm)"
   from David Hildenbrand implements a number of unrelated cleanups in this
   code.
 
 - The 5 patch series "mm: Rework generic PTDUMP configs" from Anshuman
   Khandual implements a number of preparatoty cleanups to the
   GENERIC_PTDUMP Kconfig logic.
 
 - The 8 patch series "mm/damon: auto-tune aggregation interval" from
   SeongJae Park implements a feedback-driven automatic tuning feature for
   DAMON's aggregation interval tuning.
 
 - The 5 patch series "Fix lazy mmu mode" from Ryan Roberts fixes some
   issues in powerpc, sparc and x86 lazy MMU implementations.  Ryan did
   this in preparation for implementing lazy mmu mode for arm64 to optimize
   vmalloc.
 
 - The 2 patch series "mm/page_alloc: Some clarifications for migratetype
   fallback" from Brendan Jackman reworks some commentary to make the code
   easier to follow.
 
 - The 3 patch series "page_counter cleanup and size reduction" from
   Shakeel Butt cleans up the page_counter code and fixes a size increase
   which we accidentally added late last year.
 
 - The 3 patch series "Add a command line option that enables control of
   how many threads should be used to allocate huge pages" from Thomas
   Prescher does that.  It allows the careful operator to significantly
   reduce boot time by tuning the parallalization of huge page
   initialization.
 
 - The 3 patch series "Fix calculations in trace_balance_dirty_pages()
   for cgwb" from Tang Yizhou fixes the tracing output from the dirty page
   balancing code.
 
 - The 9 patch series "mm/damon: make allow filters after reject filters
   useful and intuitive" from SeongJae Park improves the handling of allow
   and reject filters.  Behaviour is made more consistent and the
   documention is updated accordingly.
 
 - The 5 patch series "Switch zswap to object read/write APIs" from Yosry
   Ahmed updates zswap to the new object read/write APIs and thus permits
   the removal of some legacy code from zpool and zsmalloc.
 
 - The 6 patch series "Some trivial cleanups for shmem" from Baolin Wang
   does as it claims.
 
 - The 20 patch series "fs/dax: Fix ZONE_DEVICE page reference counts"
   from Alistair Popple regularizes the weird ZONE_DEVICE page refcount
   handling in DAX, permittig the removal of a number of special-case
   checks.
 
 - The 4 patch series "refactor mremap and fix bug" from Lorenzo Stoakes
   is a preparatoty refactoring and cleanup of the mremap() code.
 
 - The 20 patch series "mm: MM owner tracking for large folios (!hugetlb)
   + CONFIG_NO_PAGE_MAPCOUNT" from David Hildenbrand reworks the manner in
   which we determine whether a large folio is known to be mapped
   exclusively into a single MM.
 
 - The 8 patch series "mm/damon: add sysfs dirs for managing DAMOS
   filters based on handling layers" from SeongJae Park adds a couple of
   new sysfs directories to ease the management of DAMON/DAMOS filters.
 
 - The 13 patch series "arch, mm: reduce code duplication in mem_init()"
   from Mike Rapoport consolidates many per-arch implementations of
   mem_init() into code generic code, where that is practical.
 
 - The 13 patch series "mm/damon/sysfs: commit parameters online via
   damon_call()" from SeongJae Park continues the cleaning up of sysfs
   access to DAMON internal data.
 
 - The 3 patch series "mm: page_ext: Introduce new iteration API" from
   Luiz Capitulino reworks the page_ext initialization to fix a boot-time
   crash which was observed with an unusual combination of compile and
   cmdline options.
 
 - The 8 patch series "Buddy allocator like (or non-uniform) folio split"
   from Zi Yan reworks the code to split a folio into smaller folios.  The
   main benefit is lessened memory consumption: fewer post-split folios are
   generated.
 
 - The 2 patch series "Minimize xa_node allocation during xarry split"
   from Zi Yan reduces the number of xarray xa_nodes which are generated
   during an xarray split.
 
 - The 2 patch series "drivers/base/memory: Two cleanups" from Gavin Shan
   performs some maintenance work on the drivers/base/memory code.
 
 - The 3 patch series "Add tracepoints for lowmem reserves, watermarks
   and totalreserve_pages" from Martin Liu adds some more tracepoints to
   the page allocator code.
 
 - The 4 patch series "mm/madvise: cleanup requests validations and
   classifications" from SeongJae Park cleans up some warts which SeongJae
   observed during his earlier madvise work.
 
 - The 3 patch series "mm/hwpoison: Fix regressions in memory failure
   handling" from Shuai Xue addresses two quite serious regressions which
   Shuai has observed in the memory-failure implementation.
 
 - The 5 patch series "mm: reliable huge page allocator" from Johannes
   Weiner makes huge page allocations cheaper and more reliable by reducing
   fragmentation.
 
 - The 5 patch series "Minor memcg cleanups & prep for memdescs" from
   Matthew Wilcox is preparatory work for the future implementation of
   memdescs.
 
 - The 4 patch series "track memory used by balloon drivers" from Nico
   Pache introduces a way to track memory used by our various balloon
   drivers.
 
 - The 2 patch series "mm/damon: introduce DAMOS filter type for active
   pages" from Nhat Pham permits users to filter for active/inactive pages,
   separately for file and anon pages.
 
 - The 2 patch series "Adding Proactive Memory Reclaim Statistics" from
   Hao Jia separates the proactive reclaim statistics from the direct
   reclaim statistics.
 
 - The 2 patch series "mm/vmscan: don't try to reclaim hwpoison folio"
   from Jinjiang Tu fixes our handling of hwpoisoned pages within the
   reclaim code.
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Merge tag 'mm-stable-2025-03-30-16-52' of git://git.kernel.org/pub/scm/linux/kernel/git/akpm/mm

Pull MM updates from Andrew Morton:

 - The series "Enable strict percpu address space checks" from Uros
   Bizjak uses x86 named address space qualifiers to provide
   compile-time checking of percpu area accesses.

   This has caused a small amount of fallout - two or three issues were
   reported. In all cases the calling code was found to be incorrect.

 - The series "Some cleanup for memcg" from Chen Ridong implements some
   relatively monir cleanups for the memcontrol code.

 - The series "mm: fixes for device-exclusive entries (hmm)" from David
   Hildenbrand fixes a boatload of issues which David found then using
   device-exclusive PTE entries when THP is enabled. More work is
   needed, but this makes thins better - our own HMM selftests now
   succeed.

 - The series "mm: zswap: remove z3fold and zbud" from Yosry Ahmed
   remove the z3fold and zbud implementations. They have been deprecated
   for half a year and nobody has complained.

 - The series "mm: further simplify VMA merge operation" from Lorenzo
   Stoakes implements numerous simplifications in this area. No runtime
   effects are anticipated.

 - The series "mm/madvise: remove redundant mmap_lock operations from
   process_madvise()" from SeongJae Park rationalizes the locking in the
   madvise() implementation. Performance gains of 20-25% were observed
   in one MADV_DONTNEED microbenchmark.

 - The series "Tiny cleanup and improvements about SWAP code" from
   Baoquan He contains a number of touchups to issues which Baoquan
   noticed when working on the swap code.

 - The series "mm: kmemleak: Usability improvements" from Catalin
   Marinas implements a couple of improvements to the kmemleak
   user-visible output.

 - The series "mm/damon/paddr: fix large folios access and schemes
   handling" from Usama Arif provides a couple of fixes for DAMON's
   handling of large folios.

 - The series "mm/damon/core: fix wrong and/or useless damos_walk()
   behaviors" from SeongJae Park fixes a few issues with the accuracy of
   kdamond's walking of DAMON regions.

 - The series "expose mapping wrprotect, fix fb_defio use" from Lorenzo
   Stoakes changes the interaction between framebuffer deferred-io and
   core MM. No functional changes are anticipated - this is preparatory
   work for the future removal of page structure fields.

 - The series "mm/damon: add support for hugepage_size DAMOS filter"
   from Usama Arif adds a DAMOS filter which permits the filtering by
   huge page sizes.

 - The series "mm: permit guard regions for file-backed/shmem mappings"
   from Lorenzo Stoakes extends the guard region feature from its
   present "anon mappings only" state. The feature now covers shmem and
   file-backed mappings.

 - The series "mm: batched unmap lazyfree large folios during
   reclamation" from Barry Song cleans up and speeds up the unmapping
   for pte-mapped large folios.

 - The series "reimplement per-vma lock as a refcount" from Suren
   Baghdasaryan puts the vm_lock back into the vma. Our reasons for
   pulling it out were largely bogus and that change made the code more
   messy. This patchset provides small (0-10%) improvements on one
   microbenchmark.

 - The series "Docs/mm/damon: misc DAMOS filters documentation fixes and
   improves" from SeongJae Park does some maintenance work on the DAMON
   docs.

 - The series "hugetlb/CMA improvements for large systems" from Frank
   van der Linden addresses a pile of issues which have been observed
   when using CMA on large machines.

 - The series "mm/damon: introduce DAMOS filter type for unmapped pages"
   from SeongJae Park enables users of DMAON/DAMOS to filter my the
   page's mapped/unmapped status.

 - The series "zsmalloc/zram: there be preemption" from Sergey
   Senozhatsky teaches zram to run its compression and decompression
   operations preemptibly.

 - The series "selftests/mm: Some cleanups from trying to run them" from
   Brendan Jackman fixes a pile of unrelated issues which Brendan
   encountered while runnimg our selftests.

 - The series "fs/proc/task_mmu: add guard region bit to pagemap" from
   Lorenzo Stoakes permits userspace to use /proc/pid/pagemap to
   determine whether a particular page is a guard page.

 - The series "mm, swap: remove swap slot cache" from Kairui Song
   removes the swap slot cache from the allocation path - it simply
   wasn't being effective.

 - The series "mm: cleanups for device-exclusive entries (hmm)" from
   David Hildenbrand implements a number of unrelated cleanups in this
   code.

 - The series "mm: Rework generic PTDUMP configs" from Anshuman Khandual
   implements a number of preparatoty cleanups to the GENERIC_PTDUMP
   Kconfig logic.

 - The series "mm/damon: auto-tune aggregation interval" from SeongJae
   Park implements a feedback-driven automatic tuning feature for
   DAMON's aggregation interval tuning.

 - The series "Fix lazy mmu mode" from Ryan Roberts fixes some issues in
   powerpc, sparc and x86 lazy MMU implementations. Ryan did this in
   preparation for implementing lazy mmu mode for arm64 to optimize
   vmalloc.

 - The series "mm/page_alloc: Some clarifications for migratetype
   fallback" from Brendan Jackman reworks some commentary to make the
   code easier to follow.

 - The series "page_counter cleanup and size reduction" from Shakeel
   Butt cleans up the page_counter code and fixes a size increase which
   we accidentally added late last year.

 - The series "Add a command line option that enables control of how
   many threads should be used to allocate huge pages" from Thomas
   Prescher does that. It allows the careful operator to significantly
   reduce boot time by tuning the parallalization of huge page
   initialization.

 - The series "Fix calculations in trace_balance_dirty_pages() for cgwb"
   from Tang Yizhou fixes the tracing output from the dirty page
   balancing code.

 - The series "mm/damon: make allow filters after reject filters useful
   and intuitive" from SeongJae Park improves the handling of allow and
   reject filters. Behaviour is made more consistent and the documention
   is updated accordingly.

 - The series "Switch zswap to object read/write APIs" from Yosry Ahmed
   updates zswap to the new object read/write APIs and thus permits the
   removal of some legacy code from zpool and zsmalloc.

 - The series "Some trivial cleanups for shmem" from Baolin Wang does as
   it claims.

 - The series "fs/dax: Fix ZONE_DEVICE page reference counts" from
   Alistair Popple regularizes the weird ZONE_DEVICE page refcount
   handling in DAX, permittig the removal of a number of special-case
   checks.

 - The series "refactor mremap and fix bug" from Lorenzo Stoakes is a
   preparatoty refactoring and cleanup of the mremap() code.

 - The series "mm: MM owner tracking for large folios (!hugetlb) +
   CONFIG_NO_PAGE_MAPCOUNT" from David Hildenbrand reworks the manner in
   which we determine whether a large folio is known to be mapped
   exclusively into a single MM.

 - The series "mm/damon: add sysfs dirs for managing DAMOS filters based
   on handling layers" from SeongJae Park adds a couple of new sysfs
   directories to ease the management of DAMON/DAMOS filters.

 - The series "arch, mm: reduce code duplication in mem_init()" from
   Mike Rapoport consolidates many per-arch implementations of
   mem_init() into code generic code, where that is practical.

 - The series "mm/damon/sysfs: commit parameters online via
   damon_call()" from SeongJae Park continues the cleaning up of sysfs
   access to DAMON internal data.

 - The series "mm: page_ext: Introduce new iteration API" from Luiz
   Capitulino reworks the page_ext initialization to fix a boot-time
   crash which was observed with an unusual combination of compile and
   cmdline options.

 - The series "Buddy allocator like (or non-uniform) folio split" from
   Zi Yan reworks the code to split a folio into smaller folios. The
   main benefit is lessened memory consumption: fewer post-split folios
   are generated.

 - The series "Minimize xa_node allocation during xarry split" from Zi
   Yan reduces the number of xarray xa_nodes which are generated during
   an xarray split.

 - The series "drivers/base/memory: Two cleanups" from Gavin Shan
   performs some maintenance work on the drivers/base/memory code.

 - The series "Add tracepoints for lowmem reserves, watermarks and
   totalreserve_pages" from Martin Liu adds some more tracepoints to the
   page allocator code.

 - The series "mm/madvise: cleanup requests validations and
   classifications" from SeongJae Park cleans up some warts which
   SeongJae observed during his earlier madvise work.

 - The series "mm/hwpoison: Fix regressions in memory failure handling"
   from Shuai Xue addresses two quite serious regressions which Shuai
   has observed in the memory-failure implementation.

 - The series "mm: reliable huge page allocator" from Johannes Weiner
   makes huge page allocations cheaper and more reliable by reducing
   fragmentation.

 - The series "Minor memcg cleanups & prep for memdescs" from Matthew
   Wilcox is preparatory work for the future implementation of memdescs.

 - The series "track memory used by balloon drivers" from Nico Pache
   introduces a way to track memory used by our various balloon drivers.

 - The series "mm/damon: introduce DAMOS filter type for active pages"
   from Nhat Pham permits users to filter for active/inactive pages,
   separately for file and anon pages.

 - The series "Adding Proactive Memory Reclaim Statistics" from Hao Jia
   separates the proactive reclaim statistics from the direct reclaim
   statistics.

 - The series "mm/vmscan: don't try to reclaim hwpoison folio" from
   Jinjiang Tu fixes our handling of hwpoisoned pages within the reclaim
   code.

* tag 'mm-stable-2025-03-30-16-52' of git://git.kernel.org/pub/scm/linux/kernel/git/akpm/mm: (431 commits)
  mm/page_alloc: remove unnecessary __maybe_unused in order_to_pindex()
  x86/mm: restore early initialization of high_memory for 32-bits
  mm/vmscan: don't try to reclaim hwpoison folio
  mm/hwpoison: introduce folio_contain_hwpoisoned_page() helper
  cgroup: docs: add pswpin and pswpout items in cgroup v2 doc
  mm: vmscan: split proactive reclaim statistics from direct reclaim statistics
  selftests/mm: speed up split_huge_page_test
  selftests/mm: uffd-unit-tests support for hugepages > 2M
  docs/mm/damon/design: document active DAMOS filter type
  mm/damon: implement a new DAMOS filter type for active pages
  fs/dax: don't disassociate zero page entries
  MM documentation: add "Unaccepted" meminfo entry
  selftests/mm: add commentary about 9pfs bugs
  fork: use __vmalloc_node() for stack allocation
  docs/mm: Physical Memory: Populate the "Zones" section
  xen: balloon: update the NR_BALLOON_PAGES state
  hv_balloon: update the NR_BALLOON_PAGES state
  balloon_compaction: update the NR_BALLOON_PAGES state
  meminfo: add a per node counter for balloon drivers
  mm: remove references to folio in __memcg_kmem_uncharge_page()
  ...
2025-04-01 09:29:18 -07:00

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/* SPDX-License-Identifier: GPL-2.0-or-later */
#ifndef _ASM_POWERPC_IO_H
#define _ASM_POWERPC_IO_H
#ifdef __KERNEL__
/*
*/
/* Check of existence of legacy devices */
extern int check_legacy_ioport(unsigned long base_port);
#define I8042_DATA_REG 0x60
#define FDC_BASE 0x3f0
#if defined(CONFIG_PPC64) && defined(CONFIG_PCI)
extern struct pci_dev *isa_bridge_pcidev;
/*
* has legacy ISA devices ?
*/
#define arch_has_dev_port() (isa_bridge_pcidev != NULL || isa_io_special)
#endif
#include <linux/device.h>
#include <linux/compiler.h>
#include <linux/mm.h>
#include <asm/page.h>
#include <asm/byteorder.h>
#include <asm/synch.h>
#include <asm/delay.h>
#include <asm/mmiowb.h>
#include <asm/mmu.h>
#define SIO_CONFIG_RA 0x398
#define SIO_CONFIG_RD 0x399
/* 32 bits uses slightly different variables for the various IO
* bases. Most of this file only uses _IO_BASE though which we
* define properly based on the platform
*/
#ifndef CONFIG_PCI
#define _IO_BASE POISON_POINTER_DELTA
#define _ISA_MEM_BASE 0
#define PCI_DRAM_OFFSET 0
#elif defined(CONFIG_PPC32)
#define _IO_BASE isa_io_base
#define _ISA_MEM_BASE isa_mem_base
#define PCI_DRAM_OFFSET pci_dram_offset
#else
#define _IO_BASE pci_io_base
#define _ISA_MEM_BASE isa_mem_base
#define PCI_DRAM_OFFSET 0
#endif
extern unsigned long isa_io_base;
extern unsigned long pci_io_base;
extern unsigned long pci_dram_offset;
extern resource_size_t isa_mem_base;
/* Boolean set by platform if PIO accesses are suppored while _IO_BASE
* is not set or addresses cannot be translated to MMIO. This is typically
* set when the platform supports "special" PIO accesses via a non memory
* mapped mechanism, and allows things like the early udbg UART code to
* function.
*/
extern bool isa_io_special;
#ifdef CONFIG_PPC32
#ifdef CONFIG_PPC_INDIRECT_PIO
#error CONFIG_PPC_INDIRECT_PIO is not yet supported on 32 bits
#endif
#endif
/*
*
* Low level MMIO accessors
*
* This provides the non-bus specific accessors to MMIO. Those are PowerPC
* specific and thus shouldn't be used in generic code. The accessors
* provided here are:
*
* in_8, in_le16, in_be16, in_le32, in_be32, in_le64, in_be64
* out_8, out_le16, out_be16, out_le32, out_be32, out_le64, out_be64
* _insb, _insw, _insl, _outsb, _outsw, _outsl
*
* Those operate directly on a kernel virtual address. Note that the prototype
* for the out_* accessors has the arguments in opposite order from the usual
* linux PCI accessors. Unlike those, they take the address first and the value
* next.
*/
/* -mprefixed can generate offsets beyond range, fall back hack */
#ifdef CONFIG_PPC_KERNEL_PREFIXED
#define DEF_MMIO_IN_X(name, size, insn) \
static inline u##size name(const volatile u##size __iomem *addr) \
{ \
u##size ret; \
__asm__ __volatile__("sync;"#insn" %0,0,%1;twi 0,%0,0;isync" \
: "=r" (ret) : "r" (addr) : "memory"); \
return ret; \
}
#define DEF_MMIO_OUT_X(name, size, insn) \
static inline void name(volatile u##size __iomem *addr, u##size val) \
{ \
__asm__ __volatile__("sync;"#insn" %1,0,%0" \
: : "r" (addr), "r" (val) : "memory"); \
mmiowb_set_pending(); \
}
#define DEF_MMIO_IN_D(name, size, insn) \
static inline u##size name(const volatile u##size __iomem *addr) \
{ \
u##size ret; \
__asm__ __volatile__("sync;"#insn" %0,0(%1);twi 0,%0,0;isync"\
: "=r" (ret) : "b" (addr) : "memory"); \
return ret; \
}
#define DEF_MMIO_OUT_D(name, size, insn) \
static inline void name(volatile u##size __iomem *addr, u##size val) \
{ \
__asm__ __volatile__("sync;"#insn" %1,0(%0)" \
: : "b" (addr), "r" (val) : "memory"); \
mmiowb_set_pending(); \
}
#else
#define DEF_MMIO_IN_X(name, size, insn) \
static inline u##size name(const volatile u##size __iomem *addr) \
{ \
u##size ret; \
__asm__ __volatile__("sync;"#insn" %0,%y1;twi 0,%0,0;isync" \
: "=r" (ret) : "Z" (*addr) : "memory"); \
return ret; \
}
#define DEF_MMIO_OUT_X(name, size, insn) \
static inline void name(volatile u##size __iomem *addr, u##size val) \
{ \
__asm__ __volatile__("sync;"#insn" %1,%y0" \
: "=Z" (*addr) : "r" (val) : "memory"); \
mmiowb_set_pending(); \
}
#define DEF_MMIO_IN_D(name, size, insn) \
static inline u##size name(const volatile u##size __iomem *addr) \
{ \
u##size ret; \
__asm__ __volatile__("sync;"#insn"%U1%X1 %0,%1;twi 0,%0,0;isync"\
: "=r" (ret) : "m<>" (*addr) : "memory"); \
return ret; \
}
#define DEF_MMIO_OUT_D(name, size, insn) \
static inline void name(volatile u##size __iomem *addr, u##size val) \
{ \
__asm__ __volatile__("sync;"#insn"%U0%X0 %1,%0" \
: "=m<>" (*addr) : "r" (val) : "memory"); \
mmiowb_set_pending(); \
}
#endif
DEF_MMIO_IN_D(in_8, 8, lbz);
DEF_MMIO_OUT_D(out_8, 8, stb);
#ifdef __BIG_ENDIAN__
DEF_MMIO_IN_D(in_be16, 16, lhz);
DEF_MMIO_IN_D(in_be32, 32, lwz);
DEF_MMIO_IN_X(in_le16, 16, lhbrx);
DEF_MMIO_IN_X(in_le32, 32, lwbrx);
DEF_MMIO_OUT_D(out_be16, 16, sth);
DEF_MMIO_OUT_D(out_be32, 32, stw);
DEF_MMIO_OUT_X(out_le16, 16, sthbrx);
DEF_MMIO_OUT_X(out_le32, 32, stwbrx);
#else
DEF_MMIO_IN_X(in_be16, 16, lhbrx);
DEF_MMIO_IN_X(in_be32, 32, lwbrx);
DEF_MMIO_IN_D(in_le16, 16, lhz);
DEF_MMIO_IN_D(in_le32, 32, lwz);
DEF_MMIO_OUT_X(out_be16, 16, sthbrx);
DEF_MMIO_OUT_X(out_be32, 32, stwbrx);
DEF_MMIO_OUT_D(out_le16, 16, sth);
DEF_MMIO_OUT_D(out_le32, 32, stw);
#endif /* __BIG_ENDIAN */
#ifdef __powerpc64__
#ifdef __BIG_ENDIAN__
DEF_MMIO_OUT_D(out_be64, 64, std);
DEF_MMIO_IN_D(in_be64, 64, ld);
/* There is no asm instructions for 64 bits reverse loads and stores */
static inline u64 in_le64(const volatile u64 __iomem *addr)
{
return swab64(in_be64(addr));
}
static inline void out_le64(volatile u64 __iomem *addr, u64 val)
{
out_be64(addr, swab64(val));
}
#else
DEF_MMIO_OUT_D(out_le64, 64, std);
DEF_MMIO_IN_D(in_le64, 64, ld);
/* There is no asm instructions for 64 bits reverse loads and stores */
static inline u64 in_be64(const volatile u64 __iomem *addr)
{
return swab64(in_le64(addr));
}
static inline void out_be64(volatile u64 __iomem *addr, u64 val)
{
out_le64(addr, swab64(val));
}
#endif
#endif /* __powerpc64__ */
/*
* Low level IO stream instructions are defined out of line for now
*/
extern void _insb(const volatile u8 __iomem *addr, void *buf, long count);
extern void _outsb(volatile u8 __iomem *addr,const void *buf,long count);
extern void _insw(const volatile u16 __iomem *addr, void *buf, long count);
extern void _outsw(volatile u16 __iomem *addr, const void *buf, long count);
extern void _insl(const volatile u32 __iomem *addr, void *buf, long count);
extern void _outsl(volatile u32 __iomem *addr, const void *buf, long count);
/*
* memset_io, memcpy_toio, memcpy_fromio base implementations are out of line
*/
extern void _memset_io(volatile void __iomem *addr, int c, unsigned long n);
extern void _memcpy_fromio(void *dest, const volatile void __iomem *src,
unsigned long n);
extern void _memcpy_toio(volatile void __iomem *dest, const void *src,
unsigned long n);
/*
*
* PCI and standard ISA accessors
*
* Those are globally defined linux accessors for devices on PCI or ISA
* busses. They follow the Linux defined semantics. The current implementation
* for PowerPC is as close as possible to the x86 version of these, and thus
* provides fairly heavy weight barriers for the non-raw versions
*
* In addition, they support a hook mechanism when CONFIG_PPC_INDIRECT_PIO
* is set allowing the platform to provide its own implementation of some
* of the accessors.
*/
/*
* Include the EEH definitions when EEH is enabled only so they don't get
* in the way when building for 32 bits
*/
#ifdef CONFIG_EEH
#include <asm/eeh.h>
#endif
#define _IO_PORT(port) ((volatile void __iomem *)(_IO_BASE + (port)))
#ifdef __powerpc64__
/*
* Real mode versions of raw accessors. Those instructions are only supposed
* to be used in hypervisor real mode as per the architecture spec.
*/
static inline void __raw_rm_writeb(u8 val, volatile void __iomem *paddr)
{
__asm__ __volatile__(".machine push; \
.machine power6; \
stbcix %0,0,%1; \
.machine pop;"
: : "r" (val), "r" (paddr) : "memory");
}
static inline void __raw_rm_writew(u16 val, volatile void __iomem *paddr)
{
__asm__ __volatile__(".machine push; \
.machine power6; \
sthcix %0,0,%1; \
.machine pop;"
: : "r" (val), "r" (paddr) : "memory");
}
static inline void __raw_rm_writel(u32 val, volatile void __iomem *paddr)
{
__asm__ __volatile__(".machine push; \
.machine power6; \
stwcix %0,0,%1; \
.machine pop;"
: : "r" (val), "r" (paddr) : "memory");
}
static inline void __raw_rm_writeq(u64 val, volatile void __iomem *paddr)
{
__asm__ __volatile__(".machine push; \
.machine power6; \
stdcix %0,0,%1; \
.machine pop;"
: : "r" (val), "r" (paddr) : "memory");
}
static inline void __raw_rm_writeq_be(u64 val, volatile void __iomem *paddr)
{
__raw_rm_writeq((__force u64)cpu_to_be64(val), paddr);
}
static inline u8 __raw_rm_readb(volatile void __iomem *paddr)
{
u8 ret;
__asm__ __volatile__(".machine push; \
.machine power6; \
lbzcix %0,0, %1; \
.machine pop;"
: "=r" (ret) : "r" (paddr) : "memory");
return ret;
}
static inline u16 __raw_rm_readw(volatile void __iomem *paddr)
{
u16 ret;
__asm__ __volatile__(".machine push; \
.machine power6; \
lhzcix %0,0, %1; \
.machine pop;"
: "=r" (ret) : "r" (paddr) : "memory");
return ret;
}
static inline u32 __raw_rm_readl(volatile void __iomem *paddr)
{
u32 ret;
__asm__ __volatile__(".machine push; \
.machine power6; \
lwzcix %0,0, %1; \
.machine pop;"
: "=r" (ret) : "r" (paddr) : "memory");
return ret;
}
static inline u64 __raw_rm_readq(volatile void __iomem *paddr)
{
u64 ret;
__asm__ __volatile__(".machine push; \
.machine power6; \
ldcix %0,0, %1; \
.machine pop;"
: "=r" (ret) : "r" (paddr) : "memory");
return ret;
}
#endif /* __powerpc64__ */
/*
*
* PCI PIO and MMIO accessors.
*
*
* On 32 bits, PIO operations have a recovery mechanism in case they trigger
* machine checks (which they occasionally do when probing non existing
* IO ports on some platforms, like PowerMac and 8xx).
* I always found it to be of dubious reliability and I am tempted to get
* rid of it one of these days. So if you think it's important to keep it,
* please voice up asap. We never had it for 64 bits and I do not intend
* to port it over
*/
#ifdef CONFIG_PPC32
#define __do_in_asm(name, op) \
static inline unsigned int name(unsigned int port) \
{ \
unsigned int x; \
__asm__ __volatile__( \
"sync\n" \
"0:" op " %0,0,%1\n" \
"1: twi 0,%0,0\n" \
"2: isync\n" \
"3: nop\n" \
"4:\n" \
".section .fixup,\"ax\"\n" \
"5: li %0,-1\n" \
" b 4b\n" \
".previous\n" \
EX_TABLE(0b, 5b) \
EX_TABLE(1b, 5b) \
EX_TABLE(2b, 5b) \
EX_TABLE(3b, 5b) \
: "=&r" (x) \
: "r" (port + _IO_BASE) \
: "memory"); \
return x; \
}
#define __do_out_asm(name, op) \
static inline void name(unsigned int val, unsigned int port) \
{ \
__asm__ __volatile__( \
"sync\n" \
"0:" op " %0,0,%1\n" \
"1: sync\n" \
"2:\n" \
EX_TABLE(0b, 2b) \
EX_TABLE(1b, 2b) \
: : "r" (val), "r" (port + _IO_BASE) \
: "memory"); \
}
__do_in_asm(_rec_inb, "lbzx")
__do_in_asm(_rec_inw, "lhbrx")
__do_in_asm(_rec_inl, "lwbrx")
__do_out_asm(_rec_outb, "stbx")
__do_out_asm(_rec_outw, "sthbrx")
__do_out_asm(_rec_outl, "stwbrx")
#endif /* CONFIG_PPC32 */
/* The "__do_*" operations below provide the actual "base" implementation
* for each of the defined accessors. Some of them use the out_* functions
* directly, some of them still use EEH, though we might change that in the
* future. Those macros below provide the necessary argument swapping and
* handling of the IO base for PIO.
*
* They are themselves used by the macros that define the actual accessors
* and can be used by the hooks if any.
*
* Note that PIO operations are always defined in terms of their corresonding
* MMIO operations. That allows platforms like iSeries who want to modify the
* behaviour of both to only hook on the MMIO version and get both. It's also
* possible to hook directly at the toplevel PIO operation if they have to
* be handled differently
*/
#ifdef CONFIG_EEH
#define __do_readb(addr) eeh_readb(addr)
#define __do_readw(addr) eeh_readw(addr)
#define __do_readl(addr) eeh_readl(addr)
#define __do_readq(addr) eeh_readq(addr)
#define __do_readw_be(addr) eeh_readw_be(addr)
#define __do_readl_be(addr) eeh_readl_be(addr)
#define __do_readq_be(addr) eeh_readq_be(addr)
#else /* CONFIG_EEH */
#define __do_readb(addr) in_8(addr)
#define __do_readw(addr) in_le16(addr)
#define __do_readl(addr) in_le32(addr)
#define __do_readq(addr) in_le64(addr)
#define __do_readw_be(addr) in_be16(addr)
#define __do_readl_be(addr) in_be32(addr)
#define __do_readq_be(addr) in_be64(addr)
#endif /* !defined(CONFIG_EEH) */
#ifdef CONFIG_PPC32
#define __do_outb(val, port) _rec_outb(val, port)
#define __do_outw(val, port) _rec_outw(val, port)
#define __do_outl(val, port) _rec_outl(val, port)
#define __do_inb(port) _rec_inb(port)
#define __do_inw(port) _rec_inw(port)
#define __do_inl(port) _rec_inl(port)
#else /* CONFIG_PPC32 */
#define __do_outb(val, port) writeb(val,_IO_PORT(port));
#define __do_outw(val, port) writew(val,_IO_PORT(port));
#define __do_outl(val, port) writel(val,_IO_PORT(port));
#define __do_inb(port) readb(_IO_PORT(port));
#define __do_inw(port) readw(_IO_PORT(port));
#define __do_inl(port) readl(_IO_PORT(port));
#endif /* !CONFIG_PPC32 */
#ifdef CONFIG_EEH
#define __do_readsb(a, b, n) eeh_readsb(a, (b), (n))
#define __do_readsw(a, b, n) eeh_readsw(a, (b), (n))
#define __do_readsl(a, b, n) eeh_readsl(a, (b), (n))
#else /* CONFIG_EEH */
#define __do_readsb(a, b, n) _insb(a, (b), (n))
#define __do_readsw(a, b, n) _insw(a, (b), (n))
#define __do_readsl(a, b, n) _insl(a, (b), (n))
#endif /* !CONFIG_EEH */
#define __do_writesb(a, b, n) _outsb(a, (b), (n))
#define __do_writesw(a, b, n) _outsw(a, (b), (n))
#define __do_writesl(a, b, n) _outsl(a, (b), (n))
#define __do_insb(p, b, n) readsb(_IO_PORT(p), (b), (n))
#define __do_insw(p, b, n) readsw(_IO_PORT(p), (b), (n))
#define __do_insl(p, b, n) readsl(_IO_PORT(p), (b), (n))
#define __do_outsb(p, b, n) writesb(_IO_PORT(p),(b),(n))
#define __do_outsw(p, b, n) writesw(_IO_PORT(p),(b),(n))
#define __do_outsl(p, b, n) writesl(_IO_PORT(p),(b),(n))
#ifdef CONFIG_EEH
#define __do_memcpy_fromio(dst, src, n) \
eeh_memcpy_fromio(dst, src, n)
#else /* CONFIG_EEH */
#define __do_memcpy_fromio(dst, src, n) \
_memcpy_fromio(dst, src, n)
#endif /* !CONFIG_EEH */
static inline u8 readb(const volatile void __iomem *addr)
{
return __do_readb(addr);
}
#define readb readb
static inline u16 readw(const volatile void __iomem *addr)
{
return __do_readw(addr);
}
#define readw readw
static inline u32 readl(const volatile void __iomem *addr)
{
return __do_readl(addr);
}
#define readl readl
static inline u16 readw_be(const volatile void __iomem *addr)
{
return __do_readw_be(addr);
}
static inline u32 readl_be(const volatile void __iomem *addr)
{
return __do_readl_be(addr);
}
static inline void writeb(u8 val, volatile void __iomem *addr)
{
out_8(addr, val);
}
#define writeb writeb
static inline void writew(u16 val, volatile void __iomem *addr)
{
out_le16(addr, val);
}
#define writew writew
static inline void writel(u32 val, volatile void __iomem *addr)
{
out_le32(addr, val);
}
#define writel writel
static inline void writew_be(u16 val, volatile void __iomem *addr)
{
out_be16(addr, val);
}
static inline void writel_be(u32 val, volatile void __iomem *addr)
{
out_be32(addr, val);
}
static inline void readsb(const volatile void __iomem *a, void *b, unsigned long c)
{
__do_readsb(a, b, c);
}
#define readsb readsb
static inline void readsw(const volatile void __iomem *a, void *b, unsigned long c)
{
__do_readsw(a, b, c);
}
#define readsw readsw
static inline void readsl(const volatile void __iomem *a, void *b, unsigned long c)
{
__do_readsl(a, b, c);
}
#define readsl readsl
static inline void writesb(volatile void __iomem *a, const void *b, unsigned long c)
{
__do_writesb(a, b, c);
}
#define writesb writesb
static inline void writesw(volatile void __iomem *a, const void *b, unsigned long c)
{
__do_writesw(a, b, c);
}
#define writesw writesw
static inline void writesl(volatile void __iomem *a, const void *b, unsigned long c)
{
__do_writesl(a, b, c);
}
#define writesl writesl
static inline void memset_io(volatile void __iomem *a, int c, unsigned long n)
{
_memset_io(a, c, n);
}
#define memset_io memset_io
static inline void memcpy_fromio(void *d, const volatile void __iomem *s, unsigned long n)
{
__do_memcpy_fromio(d, s, n);
}
#define memcpy_fromio memcpy_fromio
static inline void memcpy_toio(volatile void __iomem *d, const void *s, unsigned long n)
{
_memcpy_toio(d, s, n);
}
#define memcpy_toio memcpy_toio
#ifdef __powerpc64__
static inline u64 readq(const volatile void __iomem *addr)
{
return __do_readq(addr);
}
static inline u64 readq_be(const volatile void __iomem *addr)
{
return __do_readq_be(addr);
}
static inline void writeq(u64 val, volatile void __iomem *addr)
{
out_le64(addr, val);
}
static inline void writeq_be(u64 val, volatile void __iomem *addr)
{
out_be64(addr, val);
}
#endif /* __powerpc64__ */
#ifdef CONFIG_PPC_INDIRECT_PIO
#define DEF_PCI_HOOK(x) x
#else
#define DEF_PCI_HOOK(x) NULL
#endif
/* Structure containing all the hooks */
extern struct ppc_pci_io {
#define DEF_PCI_AC_RET(name, ret, at, al) ret (*name) at;
#define DEF_PCI_AC_NORET(name, at, al) void (*name) at;
#include <asm/io-defs.h>
#undef DEF_PCI_AC_RET
#undef DEF_PCI_AC_NORET
} ppc_pci_io;
/* The inline wrappers */
#define DEF_PCI_AC_RET(name, ret, at, al) \
static inline ret name at \
{ \
if (DEF_PCI_HOOK(ppc_pci_io.name) != NULL) \
return ppc_pci_io.name al; \
return __do_##name al; \
}
#define DEF_PCI_AC_NORET(name, at, al) \
static inline void name at \
{ \
if (DEF_PCI_HOOK(ppc_pci_io.name) != NULL) \
ppc_pci_io.name al; \
else \
__do_##name al; \
}
#include <asm/io-defs.h>
#undef DEF_PCI_AC_RET
#undef DEF_PCI_AC_NORET
// Signal to asm-generic/io.h that we have implemented these.
#define inb inb
#define inw inw
#define inl inl
#define outb outb
#define outw outw
#define outl outl
#define insb insb
#define insw insw
#define insl insl
#define outsb outsb
#define outsw outsw
#define outsl outsl
#ifdef __powerpc64__
#define readq readq
#define writeq writeq
#endif
/*
* We don't do relaxed operations yet, at least not with this semantic
*/
#define readb_relaxed(addr) readb(addr)
#define readw_relaxed(addr) readw(addr)
#define readl_relaxed(addr) readl(addr)
#define readq_relaxed(addr) readq(addr)
#define writeb_relaxed(v, addr) writeb(v, addr)
#define writew_relaxed(v, addr) writew(v, addr)
#define writel_relaxed(v, addr) writel(v, addr)
#define writeq_relaxed(v, addr) writeq(v, addr)
#ifndef CONFIG_GENERIC_IOMAP
/*
* Here comes the implementation of the IOMAP interfaces.
*/
static inline unsigned int ioread16be(const void __iomem *addr)
{
return readw_be(addr);
}
#define ioread16be ioread16be
static inline unsigned int ioread32be(const void __iomem *addr)
{
return readl_be(addr);
}
#define ioread32be ioread32be
#ifdef __powerpc64__
static inline u64 ioread64be(const void __iomem *addr)
{
return readq_be(addr);
}
#define ioread64be ioread64be
#endif /* __powerpc64__ */
static inline void iowrite16be(u16 val, void __iomem *addr)
{
writew_be(val, addr);
}
#define iowrite16be iowrite16be
static inline void iowrite32be(u32 val, void __iomem *addr)
{
writel_be(val, addr);
}
#define iowrite32be iowrite32be
#ifdef __powerpc64__
static inline void iowrite64be(u64 val, void __iomem *addr)
{
writeq_be(val, addr);
}
#define iowrite64be iowrite64be
#endif /* __powerpc64__ */
struct pci_dev;
void pci_iounmap(struct pci_dev *dev, void __iomem *addr);
#define pci_iounmap pci_iounmap
void __iomem *ioport_map(unsigned long port, unsigned int len);
#define ioport_map ioport_map
#endif
static inline void iosync(void)
{
__asm__ __volatile__ ("sync" : : : "memory");
}
/* Enforce in-order execution of data I/O.
* No distinction between read/write on PPC; use eieio for all three.
* Those are fairly week though. They don't provide a barrier between
* MMIO and cacheable storage nor do they provide a barrier vs. locks,
* they only provide barriers between 2 __raw MMIO operations and
* possibly break write combining.
*/
#define iobarrier_rw() eieio()
#define iobarrier_r() eieio()
#define iobarrier_w() eieio()
/*
* output pause versions need a delay at least for the
* w83c105 ide controller in a p610.
*/
#define inb_p(port) inb(port)
#define outb_p(val, port) (udelay(1), outb((val), (port)))
#define inw_p(port) inw(port)
#define outw_p(val, port) (udelay(1), outw((val), (port)))
#define inl_p(port) inl(port)
#define outl_p(val, port) (udelay(1), outl((val), (port)))
#define IO_SPACE_LIMIT ~(0UL)
/**
* ioremap - map bus memory into CPU space
* @address: bus address of the memory
* @size: size of the resource to map
*
* ioremap performs a platform specific sequence of operations to
* make bus memory CPU accessible via the readb/readw/readl/writeb/
* writew/writel functions and the other mmio helpers. The returned
* address is not guaranteed to be usable directly as a virtual
* address.
*
* We provide a few variations of it:
*
* * ioremap is the standard one and provides non-cacheable guarded mappings
* and can be hooked by the platform via ppc_md
*
* * ioremap_prot allows to specify the page flags as an argument and can
* also be hooked by the platform via ppc_md.
*
* * ioremap_wc enables write combining
*
* * ioremap_wt enables write through
*
* * ioremap_coherent maps coherent cached memory
*
* * iounmap undoes such a mapping and can be hooked
*
* * __ioremap_caller is the same as above but takes an explicit caller
* reference rather than using __builtin_return_address(0)
*
*/
extern void __iomem *ioremap(phys_addr_t address, unsigned long size);
#define ioremap ioremap
#define ioremap_prot ioremap_prot
extern void __iomem *ioremap_wc(phys_addr_t address, unsigned long size);
#define ioremap_wc ioremap_wc
#ifdef CONFIG_PPC32
void __iomem *ioremap_wt(phys_addr_t address, unsigned long size);
#define ioremap_wt ioremap_wt
#endif
void __iomem *ioremap_coherent(phys_addr_t address, unsigned long size);
#define ioremap_cache(addr, size) \
ioremap_prot((addr), (size), PAGE_KERNEL)
#define iounmap iounmap
void __iomem *ioremap_phb(phys_addr_t paddr, unsigned long size);
int early_ioremap_range(unsigned long ea, phys_addr_t pa,
unsigned long size, pgprot_t prot);
extern void __iomem *__ioremap_caller(phys_addr_t, unsigned long size,
pgprot_t prot, void *caller);
/*
* When CONFIG_PPC_INDIRECT_PIO is set, we use the generic iomap implementation
* which needs some additional definitions here. They basically allow PIO
* space overall to be 1GB. This will work as long as we never try to use
* iomap to map MMIO below 1GB which should be fine on ppc64
*/
#define HAVE_ARCH_PIO_SIZE 1
#define PIO_OFFSET 0x00000000UL
#define PIO_MASK (FULL_IO_SIZE - 1)
#define PIO_RESERVED (FULL_IO_SIZE)
#define mmio_read16be(addr) readw_be(addr)
#define mmio_read32be(addr) readl_be(addr)
#define mmio_read64be(addr) readq_be(addr)
#define mmio_write16be(val, addr) writew_be(val, addr)
#define mmio_write32be(val, addr) writel_be(val, addr)
#define mmio_write64be(val, addr) writeq_be(val, addr)
#define mmio_insb(addr, dst, count) readsb(addr, dst, count)
#define mmio_insw(addr, dst, count) readsw(addr, dst, count)
#define mmio_insl(addr, dst, count) readsl(addr, dst, count)
#define mmio_outsb(addr, src, count) writesb(addr, src, count)
#define mmio_outsw(addr, src, count) writesw(addr, src, count)
#define mmio_outsl(addr, src, count) writesl(addr, src, count)
/**
* virt_to_phys - map virtual addresses to physical
* @address: address to remap
*
* The returned physical address is the physical (CPU) mapping for
* the memory address given. It is only valid to use this function on
* addresses directly mapped or allocated via kmalloc.
*
* This function does not give bus mappings for DMA transfers. In
* almost all conceivable cases a device driver should not be using
* this function
*/
static inline unsigned long virt_to_phys(const volatile void * address)
{
WARN_ON(IS_ENABLED(CONFIG_DEBUG_VIRTUAL) && !virt_addr_valid(address));
return __pa((unsigned long)address);
}
#define virt_to_phys virt_to_phys
/**
* phys_to_virt - map physical address to virtual
* @address: address to remap
*
* The returned virtual address is a current CPU mapping for
* the memory address given. It is only valid to use this function on
* addresses that have a kernel mapping
*
* This function does not handle bus mappings for DMA transfers. In
* almost all conceivable cases a device driver should not be using
* this function
*/
static inline void * phys_to_virt(unsigned long address)
{
return (void *)__va(address);
}
#define phys_to_virt phys_to_virt
/*
* 32 bits still uses virt_to_bus() for its implementation of DMA
* mappings se we have to keep it defined here. We also have some old
* drivers (shame shame shame) that use bus_to_virt() and haven't been
* fixed yet so I need to define it here.
*/
#ifdef CONFIG_PPC32
static inline unsigned long virt_to_bus(volatile void * address)
{
if (address == NULL)
return 0;
return __pa(address) + PCI_DRAM_OFFSET;
}
#define virt_to_bus virt_to_bus
static inline void * bus_to_virt(unsigned long address)
{
if (address == 0)
return NULL;
return __va(address - PCI_DRAM_OFFSET);
}
#define bus_to_virt bus_to_virt
#endif /* CONFIG_PPC32 */
/* access ports */
#define setbits32(_addr, _v) out_be32((_addr), in_be32(_addr) | (_v))
#define clrbits32(_addr, _v) out_be32((_addr), in_be32(_addr) & ~(_v))
#define setbits16(_addr, _v) out_be16((_addr), in_be16(_addr) | (_v))
#define clrbits16(_addr, _v) out_be16((_addr), in_be16(_addr) & ~(_v))
#define setbits8(_addr, _v) out_8((_addr), in_8(_addr) | (_v))
#define clrbits8(_addr, _v) out_8((_addr), in_8(_addr) & ~(_v))
/* Clear and set bits in one shot. These macros can be used to clear and
* set multiple bits in a register using a single read-modify-write. These
* macros can also be used to set a multiple-bit bit pattern using a mask,
* by specifying the mask in the 'clear' parameter and the new bit pattern
* in the 'set' parameter.
*/
#define clrsetbits(type, addr, clear, set) \
out_##type((addr), (in_##type(addr) & ~(clear)) | (set))
#ifdef __powerpc64__
#define clrsetbits_be64(addr, clear, set) clrsetbits(be64, addr, clear, set)
#define clrsetbits_le64(addr, clear, set) clrsetbits(le64, addr, clear, set)
#endif
#define clrsetbits_be32(addr, clear, set) clrsetbits(be32, addr, clear, set)
#define clrsetbits_le32(addr, clear, set) clrsetbits(le32, addr, clear, set)
#define clrsetbits_be16(addr, clear, set) clrsetbits(be16, addr, clear, set)
#define clrsetbits_le16(addr, clear, set) clrsetbits(le16, addr, clear, set)
#define clrsetbits_8(addr, clear, set) clrsetbits(8, addr, clear, set)
#include <asm-generic/io.h>
#ifdef __powerpc64__
static inline void __raw_writeq_be(unsigned long v, volatile void __iomem *addr)
{
__raw_writeq((__force unsigned long)cpu_to_be64(v), addr);
}
#define __raw_writeq_be __raw_writeq_be
#endif // __powerpc64__
#endif /* __KERNEL__ */
#endif /* _ASM_POWERPC_IO_H */
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