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* 'for-linus' of master.kernel.org:/home/rmk/linux-2.6-arm: (100 commits) ARM: Eliminate decompressor -Dstatic= PIC hack ARM: 5958/1: ARM: U300: fix inverted clk round rate ARM: 5956/1: misplaced parentheses ARM: 5955/1: ep93xx: move timer defines into core.c and document ARM: 5954/1: ep93xx: move gpio interrupt support to gpio.c ARM: 5953/1: ep93xx: fix broken build of clock.c ARM: 5952/1: ARM: MM: Add ARM_L1_CACHE_SHIFT_6 for handle inside each ARCH Kconfig ARM: 5949/1: NUC900 add gpio virtual memory map ARM: 5948/1: Enable timer0 to time4 clock support for nuc910 ARM: 5940/2: ARM: MMCI: remove custom DBG macro and printk ARM: make_coherent(): fix problems with highpte, part 2 MM: Pass a PTE pointer to update_mmu_cache() rather than the PTE itself ARM: 5945/1: ep93xx: include correct irq.h in core.c ARM: 5933/1: amba-pl011: support hardware flow control ARM: 5930/1: Add PKMAP area description to memory.txt. ARM: 5929/1: Add checks to detect overlap of memory regions. ARM: 5928/1: Change type of VMALLOC_END to unsigned long. ARM: 5927/1: Make delimiters of DMA area globally visibly. ARM: 5926/1: Add "Virtual kernel memory..." printout. ARM: 5920/1: OMAP4: Enable L2 Cache ... Fix up trivial conflict in arch/arm/mach-mx25/clock.c
404 lines
17 KiB
Plaintext
404 lines
17 KiB
Plaintext
Cache and TLB Flushing
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Under Linux
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David S. Miller <davem@redhat.com>
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This document describes the cache/tlb flushing interfaces called
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by the Linux VM subsystem. It enumerates over each interface,
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describes it's intended purpose, and what side effect is expected
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after the interface is invoked.
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The side effects described below are stated for a uniprocessor
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implementation, and what is to happen on that single processor. The
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SMP cases are a simple extension, in that you just extend the
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definition such that the side effect for a particular interface occurs
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on all processors in the system. Don't let this scare you into
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thinking SMP cache/tlb flushing must be so inefficient, this is in
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fact an area where many optimizations are possible. For example,
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if it can be proven that a user address space has never executed
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on a cpu (see vma->cpu_vm_mask), one need not perform a flush
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for this address space on that cpu.
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First, the TLB flushing interfaces, since they are the simplest. The
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"TLB" is abstracted under Linux as something the cpu uses to cache
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virtual-->physical address translations obtained from the software
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page tables. Meaning that if the software page tables change, it is
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possible for stale translations to exist in this "TLB" cache.
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Therefore when software page table changes occur, the kernel will
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invoke one of the following flush methods _after_ the page table
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changes occur:
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1) void flush_tlb_all(void)
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The most severe flush of all. After this interface runs,
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any previous page table modification whatsoever will be
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visible to the cpu.
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This is usually invoked when the kernel page tables are
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changed, since such translations are "global" in nature.
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2) void flush_tlb_mm(struct mm_struct *mm)
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This interface flushes an entire user address space from
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the TLB. After running, this interface must make sure that
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any previous page table modifications for the address space
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'mm' will be visible to the cpu. That is, after running,
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there will be no entries in the TLB for 'mm'.
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This interface is used to handle whole address space
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page table operations such as what happens during
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fork, and exec.
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3) void flush_tlb_range(struct vm_area_struct *vma,
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unsigned long start, unsigned long end)
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Here we are flushing a specific range of (user) virtual
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address translations from the TLB. After running, this
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interface must make sure that any previous page table
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modifications for the address space 'vma->vm_mm' in the range
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'start' to 'end-1' will be visible to the cpu. That is, after
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running, here will be no entries in the TLB for 'mm' for
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virtual addresses in the range 'start' to 'end-1'.
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The "vma" is the backing store being used for the region.
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Primarily, this is used for munmap() type operations.
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The interface is provided in hopes that the port can find
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a suitably efficient method for removing multiple page
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sized translations from the TLB, instead of having the kernel
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call flush_tlb_page (see below) for each entry which may be
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modified.
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4) void flush_tlb_page(struct vm_area_struct *vma, unsigned long addr)
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This time we need to remove the PAGE_SIZE sized translation
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from the TLB. The 'vma' is the backing structure used by
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Linux to keep track of mmap'd regions for a process, the
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address space is available via vma->vm_mm. Also, one may
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test (vma->vm_flags & VM_EXEC) to see if this region is
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executable (and thus could be in the 'instruction TLB' in
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split-tlb type setups).
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After running, this interface must make sure that any previous
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page table modification for address space 'vma->vm_mm' for
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user virtual address 'addr' will be visible to the cpu. That
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is, after running, there will be no entries in the TLB for
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'vma->vm_mm' for virtual address 'addr'.
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This is used primarily during fault processing.
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5) void update_mmu_cache(struct vm_area_struct *vma,
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unsigned long address, pte_t *ptep)
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At the end of every page fault, this routine is invoked to
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tell the architecture specific code that a translation
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now exists at virtual address "address" for address space
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"vma->vm_mm", in the software page tables.
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A port may use this information in any way it so chooses.
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For example, it could use this event to pre-load TLB
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translations for software managed TLB configurations.
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The sparc64 port currently does this.
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6) void tlb_migrate_finish(struct mm_struct *mm)
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This interface is called at the end of an explicit
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process migration. This interface provides a hook
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to allow a platform to update TLB or context-specific
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information for the address space.
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The ia64 sn2 platform is one example of a platform
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that uses this interface.
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Next, we have the cache flushing interfaces. In general, when Linux
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is changing an existing virtual-->physical mapping to a new value,
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the sequence will be in one of the following forms:
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1) flush_cache_mm(mm);
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change_all_page_tables_of(mm);
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flush_tlb_mm(mm);
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2) flush_cache_range(vma, start, end);
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change_range_of_page_tables(mm, start, end);
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flush_tlb_range(vma, start, end);
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3) flush_cache_page(vma, addr, pfn);
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set_pte(pte_pointer, new_pte_val);
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flush_tlb_page(vma, addr);
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The cache level flush will always be first, because this allows
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us to properly handle systems whose caches are strict and require
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a virtual-->physical translation to exist for a virtual address
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when that virtual address is flushed from the cache. The HyperSparc
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cpu is one such cpu with this attribute.
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The cache flushing routines below need only deal with cache flushing
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to the extent that it is necessary for a particular cpu. Mostly,
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these routines must be implemented for cpus which have virtually
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indexed caches which must be flushed when virtual-->physical
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translations are changed or removed. So, for example, the physically
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indexed physically tagged caches of IA32 processors have no need to
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implement these interfaces since the caches are fully synchronized
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and have no dependency on translation information.
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Here are the routines, one by one:
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1) void flush_cache_mm(struct mm_struct *mm)
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This interface flushes an entire user address space from
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the caches. That is, after running, there will be no cache
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lines associated with 'mm'.
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This interface is used to handle whole address space
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page table operations such as what happens during exit and exec.
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2) void flush_cache_dup_mm(struct mm_struct *mm)
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This interface flushes an entire user address space from
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the caches. That is, after running, there will be no cache
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lines associated with 'mm'.
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This interface is used to handle whole address space
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page table operations such as what happens during fork.
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This option is separate from flush_cache_mm to allow some
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optimizations for VIPT caches.
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3) void flush_cache_range(struct vm_area_struct *vma,
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unsigned long start, unsigned long end)
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Here we are flushing a specific range of (user) virtual
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addresses from the cache. After running, there will be no
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entries in the cache for 'vma->vm_mm' for virtual addresses in
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the range 'start' to 'end-1'.
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The "vma" is the backing store being used for the region.
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Primarily, this is used for munmap() type operations.
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The interface is provided in hopes that the port can find
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a suitably efficient method for removing multiple page
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sized regions from the cache, instead of having the kernel
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call flush_cache_page (see below) for each entry which may be
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modified.
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4) void flush_cache_page(struct vm_area_struct *vma, unsigned long addr, unsigned long pfn)
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This time we need to remove a PAGE_SIZE sized range
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from the cache. The 'vma' is the backing structure used by
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Linux to keep track of mmap'd regions for a process, the
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address space is available via vma->vm_mm. Also, one may
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test (vma->vm_flags & VM_EXEC) to see if this region is
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executable (and thus could be in the 'instruction cache' in
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"Harvard" type cache layouts).
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The 'pfn' indicates the physical page frame (shift this value
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left by PAGE_SHIFT to get the physical address) that 'addr'
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translates to. It is this mapping which should be removed from
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the cache.
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After running, there will be no entries in the cache for
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'vma->vm_mm' for virtual address 'addr' which translates
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to 'pfn'.
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This is used primarily during fault processing.
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5) void flush_cache_kmaps(void)
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This routine need only be implemented if the platform utilizes
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highmem. It will be called right before all of the kmaps
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are invalidated.
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After running, there will be no entries in the cache for
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the kernel virtual address range PKMAP_ADDR(0) to
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PKMAP_ADDR(LAST_PKMAP).
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This routing should be implemented in asm/highmem.h
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6) void flush_cache_vmap(unsigned long start, unsigned long end)
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void flush_cache_vunmap(unsigned long start, unsigned long end)
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Here in these two interfaces we are flushing a specific range
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of (kernel) virtual addresses from the cache. After running,
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there will be no entries in the cache for the kernel address
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space for virtual addresses in the range 'start' to 'end-1'.
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The first of these two routines is invoked after map_vm_area()
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has installed the page table entries. The second is invoked
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before unmap_kernel_range() deletes the page table entries.
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There exists another whole class of cpu cache issues which currently
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require a whole different set of interfaces to handle properly.
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The biggest problem is that of virtual aliasing in the data cache
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of a processor.
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Is your port susceptible to virtual aliasing in it's D-cache?
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Well, if your D-cache is virtually indexed, is larger in size than
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PAGE_SIZE, and does not prevent multiple cache lines for the same
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physical address from existing at once, you have this problem.
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If your D-cache has this problem, first define asm/shmparam.h SHMLBA
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properly, it should essentially be the size of your virtually
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addressed D-cache (or if the size is variable, the largest possible
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size). This setting will force the SYSv IPC layer to only allow user
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processes to mmap shared memory at address which are a multiple of
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this value.
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NOTE: This does not fix shared mmaps, check out the sparc64 port for
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one way to solve this (in particular SPARC_FLAG_MMAPSHARED).
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Next, you have to solve the D-cache aliasing issue for all
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other cases. Please keep in mind that fact that, for a given page
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mapped into some user address space, there is always at least one more
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mapping, that of the kernel in it's linear mapping starting at
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PAGE_OFFSET. So immediately, once the first user maps a given
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physical page into its address space, by implication the D-cache
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aliasing problem has the potential to exist since the kernel already
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maps this page at its virtual address.
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void copy_user_page(void *to, void *from, unsigned long addr, struct page *page)
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void clear_user_page(void *to, unsigned long addr, struct page *page)
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These two routines store data in user anonymous or COW
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pages. It allows a port to efficiently avoid D-cache alias
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issues between userspace and the kernel.
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For example, a port may temporarily map 'from' and 'to' to
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kernel virtual addresses during the copy. The virtual address
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for these two pages is chosen in such a way that the kernel
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load/store instructions happen to virtual addresses which are
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of the same "color" as the user mapping of the page. Sparc64
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for example, uses this technique.
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The 'addr' parameter tells the virtual address where the
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user will ultimately have this page mapped, and the 'page'
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parameter gives a pointer to the struct page of the target.
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If D-cache aliasing is not an issue, these two routines may
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simply call memcpy/memset directly and do nothing more.
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void flush_dcache_page(struct page *page)
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Any time the kernel writes to a page cache page, _OR_
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the kernel is about to read from a page cache page and
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user space shared/writable mappings of this page potentially
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exist, this routine is called.
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NOTE: This routine need only be called for page cache pages
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which can potentially ever be mapped into the address
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space of a user process. So for example, VFS layer code
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handling vfs symlinks in the page cache need not call
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this interface at all.
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The phrase "kernel writes to a page cache page" means,
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specifically, that the kernel executes store instructions
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that dirty data in that page at the page->virtual mapping
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of that page. It is important to flush here to handle
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D-cache aliasing, to make sure these kernel stores are
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visible to user space mappings of that page.
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The corollary case is just as important, if there are users
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which have shared+writable mappings of this file, we must make
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sure that kernel reads of these pages will see the most recent
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stores done by the user.
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If D-cache aliasing is not an issue, this routine may
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simply be defined as a nop on that architecture.
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There is a bit set aside in page->flags (PG_arch_1) as
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"architecture private". The kernel guarantees that,
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for pagecache pages, it will clear this bit when such
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a page first enters the pagecache.
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This allows these interfaces to be implemented much more
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efficiently. It allows one to "defer" (perhaps indefinitely)
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the actual flush if there are currently no user processes
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mapping this page. See sparc64's flush_dcache_page and
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update_mmu_cache implementations for an example of how to go
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about doing this.
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The idea is, first at flush_dcache_page() time, if
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page->mapping->i_mmap is an empty tree and ->i_mmap_nonlinear
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an empty list, just mark the architecture private page flag bit.
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Later, in update_mmu_cache(), a check is made of this flag bit,
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and if set the flush is done and the flag bit is cleared.
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IMPORTANT NOTE: It is often important, if you defer the flush,
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that the actual flush occurs on the same CPU
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as did the cpu stores into the page to make it
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dirty. Again, see sparc64 for examples of how
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to deal with this.
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void copy_to_user_page(struct vm_area_struct *vma, struct page *page,
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unsigned long user_vaddr,
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void *dst, void *src, int len)
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void copy_from_user_page(struct vm_area_struct *vma, struct page *page,
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unsigned long user_vaddr,
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void *dst, void *src, int len)
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When the kernel needs to copy arbitrary data in and out
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of arbitrary user pages (f.e. for ptrace()) it will use
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these two routines.
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Any necessary cache flushing or other coherency operations
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that need to occur should happen here. If the processor's
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instruction cache does not snoop cpu stores, it is very
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likely that you will need to flush the instruction cache
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for copy_to_user_page().
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void flush_anon_page(struct vm_area_struct *vma, struct page *page,
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unsigned long vmaddr)
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When the kernel needs to access the contents of an anonymous
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page, it calls this function (currently only
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get_user_pages()). Note: flush_dcache_page() deliberately
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doesn't work for an anonymous page. The default
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implementation is a nop (and should remain so for all coherent
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architectures). For incoherent architectures, it should flush
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the cache of the page at vmaddr.
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void flush_kernel_dcache_page(struct page *page)
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When the kernel needs to modify a user page is has obtained
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with kmap, it calls this function after all modifications are
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complete (but before kunmapping it) to bring the underlying
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page up to date. It is assumed here that the user has no
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incoherent cached copies (i.e. the original page was obtained
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from a mechanism like get_user_pages()). The default
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implementation is a nop and should remain so on all coherent
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architectures. On incoherent architectures, this should flush
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the kernel cache for page (using page_address(page)).
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void flush_icache_range(unsigned long start, unsigned long end)
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When the kernel stores into addresses that it will execute
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out of (eg when loading modules), this function is called.
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If the icache does not snoop stores then this routine will need
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to flush it.
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void flush_icache_page(struct vm_area_struct *vma, struct page *page)
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All the functionality of flush_icache_page can be implemented in
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flush_dcache_page and update_mmu_cache. In 2.7 the hope is to
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remove this interface completely.
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The final category of APIs is for I/O to deliberately aliased address
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ranges inside the kernel. Such aliases are set up by use of the
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vmap/vmalloc API. Since kernel I/O goes via physical pages, the I/O
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subsystem assumes that the user mapping and kernel offset mapping are
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the only aliases. This isn't true for vmap aliases, so anything in
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the kernel trying to do I/O to vmap areas must manually manage
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coherency. It must do this by flushing the vmap range before doing
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I/O and invalidating it after the I/O returns.
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void flush_kernel_vmap_range(void *vaddr, int size)
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flushes the kernel cache for a given virtual address range in
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the vmap area. This is to make sure that any data the kernel
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modified in the vmap range is made visible to the physical
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page. The design is to make this area safe to perform I/O on.
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Note that this API does *not* also flush the offset map alias
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of the area.
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void invalidate_kernel_vmap_range(void *vaddr, int size) invalidates
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the cache for a given virtual address range in the vmap area
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which prevents the processor from making the cache stale by
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speculatively reading data while the I/O was occurring to the
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physical pages. This is only necessary for data reads into the
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vmap area.
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