/* * arch/sh/mm/cache-sh5.c * * Original version Copyright (C) 2000, 2001 Paolo Alberelli * Second version Copyright (C) benedict.gaster@superh.com 2002 * Third version Copyright Richard.Curnow@superh.com 2003 * Hacks to third version Copyright (C) 2003 Paul Mundt * * This file is subject to the terms and conditions of the GNU General Public * License. See the file "COPYING" in the main directory of this archive * for more details. */ #include #include #include #include #include #include #include #include #include #include #include #include #include /* for flush_itlb_range */ #include /* This function is in entry.S */ extern unsigned long switch_and_save_asid(unsigned long new_asid); /* Wired TLB entry for the D-cache */ static unsigned long long dtlb_cache_slot; /** * sh64_cache_init() * * This is pretty much just a straightforward clone of the SH * detect_cpu_and_cache_system(). * * This function is responsible for setting up all of the cache * info dynamically as well as taking care of CPU probing and * setting up the relevant subtype data. * * FIXME: For the time being, we only really support the SH5-101 * out of the box, and don't support dynamic probing for things * like the SH5-103 or even cut2 of the SH5-101. Implement this * later! */ int __init sh64_cache_init(void) { /* * First, setup some sane values for the I-cache. */ cpu_data->icache.ways = 4; cpu_data->icache.sets = 256; cpu_data->icache.linesz = L1_CACHE_BYTES; /* * FIXME: This can probably be cleaned up a bit as well.. for example, * do we really need the way shift _and_ the way_step_shift ?? Judging * by the existing code, I would guess no.. is there any valid reason * why we need to be tracking this around? */ cpu_data->icache.way_shift = 13; cpu_data->icache.entry_shift = 5; cpu_data->icache.set_shift = 4; cpu_data->icache.way_step_shift = 16; cpu_data->icache.asid_shift = 2; /* * way offset = cache size / associativity, so just don't factor in * associativity in the first place.. */ cpu_data->icache.way_ofs = cpu_data->icache.sets * cpu_data->icache.linesz; cpu_data->icache.asid_mask = 0x3fc; cpu_data->icache.idx_mask = 0x1fe0; cpu_data->icache.epn_mask = 0xffffe000; cpu_data->icache.flags = 0; /* * Next, setup some sane values for the D-cache. * * On the SH5, these are pretty consistent with the I-cache settings, * so we just copy over the existing definitions.. these can be fixed * up later, especially if we add runtime CPU probing. * * Though in the meantime it saves us from having to duplicate all of * the above definitions.. */ cpu_data->dcache = cpu_data->icache; /* * Setup any cache-related flags here */ #if defined(CONFIG_DCACHE_WRITE_THROUGH) set_bit(SH_CACHE_MODE_WT, &(cpu_data->dcache.flags)); #elif defined(CONFIG_DCACHE_WRITE_BACK) set_bit(SH_CACHE_MODE_WB, &(cpu_data->dcache.flags)); #endif /* * We also need to reserve a slot for the D-cache in the DTLB, so we * do this now .. */ dtlb_cache_slot = sh64_get_wired_dtlb_entry(); return 0; } #ifdef CONFIG_DCACHE_DISABLED #define sh64_dcache_purge_all() do { } while (0) #define sh64_dcache_purge_coloured_phy_page(paddr, eaddr) do { } while (0) #define sh64_dcache_purge_user_range(mm, start, end) do { } while (0) #define sh64_dcache_purge_phy_page(paddr) do { } while (0) #define sh64_dcache_purge_virt_page(mm, eaddr) do { } while (0) #define sh64_dcache_purge_kernel_range(start, end) do { } while (0) #define sh64_dcache_wback_current_user_range(start, end) do { } while (0) #endif /*##########################################################################*/ /* From here onwards, a rewrite of the implementation, by Richard.Curnow@superh.com. The major changes in this compared to the old version are; 1. use more selective purging through OCBP instead of using ALLOCO to purge by natural replacement. This avoids purging out unrelated cache lines that happen to be in the same set. 2. exploit the APIs copy_user_page and clear_user_page better 3. be more selective about I-cache purging, in particular use invalidate_all more sparingly. */ /*########################################################################## SUPPORT FUNCTIONS ##########################################################################*/ /****************************************************************************/ /* The following group of functions deal with mapping and unmapping a temporary page into the DTLB slot that have been set aside for our exclusive use. */ /* In order to accomplish this, we use the generic interface for adding and removing a wired slot entry as defined in arch/sh/mm/tlb-sh5.c */ /****************************************************************************/ static unsigned long slot_own_flags; static inline void sh64_setup_dtlb_cache_slot(unsigned long eaddr, unsigned long asid, unsigned long paddr) { local_irq_save(slot_own_flags); sh64_setup_tlb_slot(dtlb_cache_slot, eaddr, asid, paddr); } static inline void sh64_teardown_dtlb_cache_slot(void) { sh64_teardown_tlb_slot(dtlb_cache_slot); local_irq_restore(slot_own_flags); } /****************************************************************************/ #ifndef CONFIG_ICACHE_DISABLED static void __inline__ sh64_icache_inv_all(void) { unsigned long long addr, flag, data; unsigned int flags; addr=ICCR0; flag=ICCR0_ICI; data=0; /* Make this a critical section for safety (probably not strictly necessary.) */ local_irq_save(flags); /* Without %1 it gets unexplicably wrong */ asm volatile("getcfg %3, 0, %0\n\t" "or %0, %2, %0\n\t" "putcfg %3, 0, %0\n\t" "synci" : "=&r" (data) : "0" (data), "r" (flag), "r" (addr)); local_irq_restore(flags); } static void sh64_icache_inv_kernel_range(unsigned long start, unsigned long end) { /* Invalidate range of addresses [start,end] from the I-cache, where * the addresses lie in the kernel superpage. */ unsigned long long ullend, addr, aligned_start; #if (NEFF == 32) aligned_start = (unsigned long long)(signed long long)(signed long) start; #else #error "NEFF != 32" #endif aligned_start &= L1_CACHE_ALIGN_MASK; addr = aligned_start; #if (NEFF == 32) ullend = (unsigned long long) (signed long long) (signed long) end; #else #error "NEFF != 32" #endif while (addr <= ullend) { asm __volatile__ ("icbi %0, 0" : : "r" (addr)); addr += L1_CACHE_BYTES; } } static void sh64_icache_inv_user_page(struct vm_area_struct *vma, unsigned long eaddr) { /* If we get called, we know that vma->vm_flags contains VM_EXEC. Also, eaddr is page-aligned. */ unsigned long long addr, end_addr; unsigned long flags = 0; unsigned long running_asid, vma_asid; addr = eaddr; end_addr = addr + PAGE_SIZE; /* Check whether we can use the current ASID for the I-cache invalidation. For example, if we're called via access_process_vm->flush_cache_page->here, (e.g. when reading from /proc), 'running_asid' will be that of the reader, not of the victim. Also, note the risk that we might get pre-empted between the ASID compare and blocking IRQs, and before we regain control, the pid->ASID mapping changes. However, the whole cache will get invalidated when the mapping is renewed, so the worst that can happen is that the loop below ends up invalidating somebody else's cache entries. */ running_asid = get_asid(); vma_asid = (vma->vm_mm->context & MMU_CONTEXT_ASID_MASK); if (running_asid != vma_asid) { local_irq_save(flags); switch_and_save_asid(vma_asid); } while (addr < end_addr) { /* Worth unrolling a little */ asm __volatile__("icbi %0, 0" : : "r" (addr)); asm __volatile__("icbi %0, 32" : : "r" (addr)); asm __volatile__("icbi %0, 64" : : "r" (addr)); asm __volatile__("icbi %0, 96" : : "r" (addr)); addr += 128; } if (running_asid != vma_asid) { switch_and_save_asid(running_asid); local_irq_restore(flags); } } /****************************************************************************/ static void sh64_icache_inv_user_page_range(struct mm_struct *mm, unsigned long start, unsigned long end) { /* Used for invalidating big chunks of I-cache, i.e. assume the range is whole pages. If 'start' or 'end' is not page aligned, the code is conservative and invalidates to the ends of the enclosing pages. This is functionally OK, just a performance loss. */ /* See the comments below in sh64_dcache_purge_user_range() regarding the choice of algorithm. However, for the I-cache option (2) isn't available because there are no physical tags so aliases can't be resolved. The icbi instruction has to be used through the user mapping. Because icbi is cheaper than ocbp on a cache hit, it would be cheaper to use the selective code for a large range than is possible with the D-cache. Just assume 64 for now as a working figure. */ int n_pages; if (!mm) return; n_pages = ((end - start) >> PAGE_SHIFT); if (n_pages >= 64) { sh64_icache_inv_all(); } else { unsigned long aligned_start; unsigned long eaddr; unsigned long after_last_page_start; unsigned long mm_asid, current_asid; unsigned long long flags = 0ULL; mm_asid = mm->context & MMU_CONTEXT_ASID_MASK; current_asid = get_asid(); if (mm_asid != current_asid) { /* Switch ASID and run the invalidate loop under cli */ local_irq_save(flags); switch_and_save_asid(mm_asid); } aligned_start = start & PAGE_MASK; after_last_page_start = PAGE_SIZE + ((end - 1) & PAGE_MASK); while (aligned_start < after_last_page_start) { struct vm_area_struct *vma; unsigned long vma_end; vma = find_vma(mm, aligned_start); if (!vma || (aligned_start <= vma->vm_end)) { /* Avoid getting stuck in an error condition */ aligned_start += PAGE_SIZE; continue; } vma_end = vma->vm_end; if (vma->vm_flags & VM_EXEC) { /* Executable */ eaddr = aligned_start; while (eaddr < vma_end) { sh64_icache_inv_user_page(vma, eaddr); eaddr += PAGE_SIZE; } } aligned_start = vma->vm_end; /* Skip to start of next region */ } if (mm_asid != current_asid) { switch_and_save_asid(current_asid); local_irq_restore(flags); } } } static void sh64_icache_inv_user_small_range(struct mm_struct *mm, unsigned long start, int len) { /* Invalidate a small range of user context I-cache, not necessarily page (or even cache-line) aligned. */ unsigned long long eaddr = start; unsigned long long eaddr_end = start + len; unsigned long current_asid, mm_asid; unsigned long long flags; unsigned long long epage_start; /* Since this is used inside ptrace, the ASID in the mm context typically won't match current_asid. We'll have to switch ASID to do this. For safety, and given that the range will be small, do all this under cli. Note, there is a hazard that the ASID in mm->context is no longer actually associated with mm, i.e. if the mm->context has started a new cycle since mm was last active. However, this is just a performance issue: all that happens is that we invalidate lines belonging to another mm, so the owning process has to refill them when that mm goes live again. mm itself can't have any cache entries because there will have been a flush_cache_all when the new mm->context cycle started. */ /* Align to start of cache line. Otherwise, suppose len==8 and start was at 32N+28 : the last 4 bytes wouldn't get invalidated. */ eaddr = start & L1_CACHE_ALIGN_MASK; eaddr_end = start + len; local_irq_save(flags); mm_asid = mm->context & MMU_CONTEXT_ASID_MASK; current_asid = switch_and_save_asid(mm_asid); epage_start = eaddr & PAGE_MASK; while (eaddr < eaddr_end) { asm __volatile__("icbi %0, 0" : : "r" (eaddr)); eaddr += L1_CACHE_BYTES; } switch_and_save_asid(current_asid); local_irq_restore(flags); } static void sh64_icache_inv_current_user_range(unsigned long start, unsigned long end) { /* The icbi instruction never raises ITLBMISS. i.e. if there's not a cache hit on the virtual tag the instruction ends there, without a TLB lookup. */ unsigned long long aligned_start; unsigned long long ull_end; unsigned long long addr; ull_end = end; /* Just invalidate over the range using the natural addresses. TLB miss handling will be OK (TBC). Since it's for the current process, either we're already in the right ASID context, or the ASIDs have been recycled since we were last active in which case we might just invalidate another processes I-cache entries : no worries, just a performance drop for him. */ aligned_start = start & L1_CACHE_ALIGN_MASK; addr = aligned_start; while (addr < ull_end) { asm __volatile__ ("icbi %0, 0" : : "r" (addr)); asm __volatile__ ("nop"); asm __volatile__ ("nop"); addr += L1_CACHE_BYTES; } } #endif /* !CONFIG_ICACHE_DISABLED */ /****************************************************************************/ #ifndef CONFIG_DCACHE_DISABLED /* Buffer used as the target of alloco instructions to purge data from cache sets by natural eviction. -- RPC */ #define DUMMY_ALLOCO_AREA_SIZE L1_CACHE_SIZE_BYTES + (1024 * 4) static unsigned char dummy_alloco_area[DUMMY_ALLOCO_AREA_SIZE] __cacheline_aligned = { 0, }; /****************************************************************************/ static void __inline__ sh64_dcache_purge_sets(int sets_to_purge_base, int n_sets) { /* Purge all ways in a particular block of sets, specified by the base set number and number of sets. Can handle wrap-around, if that's needed. */ int dummy_buffer_base_set; unsigned long long eaddr, eaddr0, eaddr1; int j; int set_offset; dummy_buffer_base_set = ((int)&dummy_alloco_area & cpu_data->dcache.idx_mask) >> cpu_data->dcache.entry_shift; set_offset = sets_to_purge_base - dummy_buffer_base_set; for (j=0; jdcache.sets - 1); eaddr0 = (unsigned long long)dummy_alloco_area + (set_offset << cpu_data->dcache.entry_shift); /* Do one alloco which hits the required set per cache way. For write-back mode, this will purge the #ways resident lines. There's little point unrolling this loop because the allocos stall more if they're too close together. */ eaddr1 = eaddr0 + cpu_data->dcache.way_ofs * cpu_data->dcache.ways; for (eaddr=eaddr0; eaddrdcache.way_ofs) { asm __volatile__ ("alloco %0, 0" : : "r" (eaddr)); asm __volatile__ ("synco"); /* TAKum03020 */ } eaddr1 = eaddr0 + cpu_data->dcache.way_ofs * cpu_data->dcache.ways; for (eaddr=eaddr0; eaddrdcache.way_ofs) { /* Load from each address. Required because alloco is a NOP if the cache is write-through. Write-through is a config option. */ if (test_bit(SH_CACHE_MODE_WT, &(cpu_data->dcache.flags))) *(volatile unsigned char *)(int)eaddr; } } /* Don't use OCBI to invalidate the lines. That costs cycles directly. If the dummy block is just left resident, it will naturally get evicted as required. */ return; } /****************************************************************************/ static void sh64_dcache_purge_all(void) { /* Purge the entire contents of the dcache. The most efficient way to achieve this is to use alloco instructions on a region of unused memory equal in size to the cache, thereby causing the current contents to be discarded by natural eviction. The alternative, namely reading every tag, setting up a mapping for the corresponding page and doing an OCBP for the line, would be much more expensive. */ sh64_dcache_purge_sets(0, cpu_data->dcache.sets); return; } /****************************************************************************/ static void sh64_dcache_purge_kernel_range(unsigned long start, unsigned long end) { /* Purge the range of addresses [start,end] from the D-cache. The addresses lie in the superpage mapping. There's no harm if we overpurge at either end - just a small performance loss. */ unsigned long long ullend, addr, aligned_start; #if (NEFF == 32) aligned_start = (unsigned long long)(signed long long)(signed long) start; #else #error "NEFF != 32" #endif aligned_start &= L1_CACHE_ALIGN_MASK; addr = aligned_start; #if (NEFF == 32) ullend = (unsigned long long) (signed long long) (signed long) end; #else #error "NEFF != 32" #endif while (addr <= ullend) { asm __volatile__ ("ocbp %0, 0" : : "r" (addr)); addr += L1_CACHE_BYTES; } return; } /* Assumes this address (+ (2**n_synbits) pages up from it) aren't used for anything else in the kernel */ #define MAGIC_PAGE0_START 0xffffffffec000000ULL static void sh64_dcache_purge_coloured_phy_page(unsigned long paddr, unsigned long eaddr) { /* Purge the physical page 'paddr' from the cache. It's known that any cache lines requiring attention have the same page colour as the the address 'eaddr'. This relies on the fact that the D-cache matches on physical tags when no virtual tag matches. So we create an alias for the original page and purge through that. (Alternatively, we could have done this by switching ASID to match the original mapping and purged through that, but that involves ASID switching cost + probably a TLBMISS + refill anyway.) */ unsigned long long magic_page_start; unsigned long long magic_eaddr, magic_eaddr_end; magic_page_start = MAGIC_PAGE0_START + (eaddr & CACHE_OC_SYN_MASK); /* As long as the kernel is not pre-emptible, this doesn't need to be under cli/sti. */ sh64_setup_dtlb_cache_slot(magic_page_start, get_asid(), paddr); magic_eaddr = magic_page_start; magic_eaddr_end = magic_eaddr + PAGE_SIZE; while (magic_eaddr < magic_eaddr_end) { /* Little point in unrolling this loop - the OCBPs are blocking and won't go any quicker (i.e. the loop overhead is parallel to part of the OCBP execution.) */ asm __volatile__ ("ocbp %0, 0" : : "r" (magic_eaddr)); magic_eaddr += L1_CACHE_BYTES; } sh64_teardown_dtlb_cache_slot(); } /****************************************************************************/ static void sh64_dcache_purge_phy_page(unsigned long paddr) { /* Pure a page given its physical start address, by creating a temporary 1 page mapping and purging across that. Even if we know the virtual address (& vma or mm) of the page, the method here is more elegant because it avoids issues of coping with page faults on the purge instructions (i.e. no special-case code required in the critical path in the TLB miss handling). */ unsigned long long eaddr_start, eaddr, eaddr_end; int i; /* As long as the kernel is not pre-emptible, this doesn't need to be under cli/sti. */ eaddr_start = MAGIC_PAGE0_START; for (i=0; i < (1 << CACHE_OC_N_SYNBITS); i++) { sh64_setup_dtlb_cache_slot(eaddr_start, get_asid(), paddr); eaddr = eaddr_start; eaddr_end = eaddr + PAGE_SIZE; while (eaddr < eaddr_end) { asm __volatile__ ("ocbp %0, 0" : : "r" (eaddr)); eaddr += L1_CACHE_BYTES; } sh64_teardown_dtlb_cache_slot(); eaddr_start += PAGE_SIZE; } } static void sh64_dcache_purge_user_pages(struct mm_struct *mm, unsigned long addr, unsigned long end) { pgd_t *pgd; pmd_t *pmd; pte_t *pte; pte_t entry; spinlock_t *ptl; unsigned long paddr; if (!mm) return; /* No way to find physical address of page */ pgd = pgd_offset(mm, addr); if (pgd_bad(*pgd)) return; pmd = pmd_offset(pgd, addr); if (pmd_none(*pmd) || pmd_bad(*pmd)) return; pte = pte_offset_map_lock(mm, pmd, addr, &ptl); do { entry = *pte; if (pte_none(entry) || !pte_present(entry)) continue; paddr = pte_val(entry) & PAGE_MASK; sh64_dcache_purge_coloured_phy_page(paddr, addr); } while (pte++, addr += PAGE_SIZE, addr != end); pte_unmap_unlock(pte - 1, ptl); } /****************************************************************************/ static void sh64_dcache_purge_user_range(struct mm_struct *mm, unsigned long start, unsigned long end) { /* There are at least 5 choices for the implementation of this, with pros (+), cons(-), comments(*): 1. ocbp each line in the range through the original user's ASID + no lines spuriously evicted - tlbmiss handling (must either handle faults on demand => extra special-case code in tlbmiss critical path), or map the page in advance (=> flush_tlb_range in advance to avoid multiple hits) - ASID switching - expensive for large ranges 2. temporarily map each page in the range to a special effective address and ocbp through the temporary mapping; relies on the fact that SH-5 OCB* always do TLB lookup and match on ptags (they never look at the etags) + no spurious evictions - expensive for large ranges * surely cheaper than (1) 3. walk all the lines in the cache, check the tags, if a match occurs create a page mapping to ocbp the line through + no spurious evictions - tag inspection overhead - (especially for small ranges) - potential cost of setting up/tearing down page mapping for every line that matches the range * cost partly independent of range size 4. walk all the lines in the cache, check the tags, if a match occurs use 4 * alloco to purge the line (+3 other probably innocent victims) by natural eviction + no tlb mapping overheads - spurious evictions - tag inspection overhead 5. implement like flush_cache_all + no tag inspection overhead - spurious evictions - bad for small ranges (1) can be ruled out as more expensive than (2). (2) appears best for small ranges. The choice between (3), (4) and (5) for large ranges and the range size for the large/small boundary need benchmarking to determine. For now use approach (2) for small ranges and (5) for large ones. */ int n_pages; n_pages = ((end - start) >> PAGE_SHIFT); if (n_pages >= 64 || ((start ^ (end - 1)) & PMD_MASK)) { #if 1 sh64_dcache_purge_all(); #else unsigned long long set, way; unsigned long mm_asid = mm->context & MMU_CONTEXT_ASID_MASK; for (set = 0; set < cpu_data->dcache.sets; set++) { unsigned long long set_base_config_addr = CACHE_OC_ADDRESS_ARRAY + (set << cpu_data->dcache.set_shift); for (way = 0; way < cpu_data->dcache.ways; way++) { unsigned long long config_addr = set_base_config_addr + (way << cpu_data->dcache.way_step_shift); unsigned long long tag0; unsigned long line_valid; asm __volatile__("getcfg %1, 0, %0" : "=r" (tag0) : "r" (config_addr)); line_valid = tag0 & SH_CACHE_VALID; if (line_valid) { unsigned long cache_asid; unsigned long epn; cache_asid = (tag0 & cpu_data->dcache.asid_mask) >> cpu_data->dcache.asid_shift; /* The next line needs some explanation. The virtual tags encode bits [31:13] of the virtual address, bit [12] of the 'tag' being implied by the cache set index. */ epn = (tag0 & cpu_data->dcache.epn_mask) | ((set & 0x80) << cpu_data->dcache.entry_shift); if ((cache_asid == mm_asid) && (start <= epn) && (epn < end)) { /* TODO : could optimise this call by batching multiple adjacent sets together. */ sh64_dcache_purge_sets(set, 1); break; /* Don't waste time inspecting other ways for this set */ } } } } #endif } else { /* Small range, covered by a single page table page */ start &= PAGE_MASK; /* should already be so */ end = PAGE_ALIGN(end); /* should already be so */ sh64_dcache_purge_user_pages(mm, start, end); } return; } static void sh64_dcache_wback_current_user_range(unsigned long start, unsigned long end) { unsigned long long aligned_start; unsigned long long ull_end; unsigned long long addr; ull_end = end; /* Just wback over the range using the natural addresses. TLB miss handling will be OK (TBC) : the range has just been written to by the signal frame setup code, so the PTEs must exist. Note, if we have CONFIG_PREEMPT and get preempted inside this loop, it doesn't matter, even if the pid->ASID mapping changes whilst we're away. In that case the cache will have been flushed when the mapping was renewed. So the writebacks below will be nugatory (and we'll doubtless have to fault the TLB entry/ies in again with the new ASID), but it's a rare case. */ aligned_start = start & L1_CACHE_ALIGN_MASK; addr = aligned_start; while (addr < ull_end) { asm __volatile__ ("ocbwb %0, 0" : : "r" (addr)); addr += L1_CACHE_BYTES; } } /****************************************************************************/ /* These *MUST* lie in an area of virtual address space that's otherwise unused. */ #define UNIQUE_EADDR_START 0xe0000000UL #define UNIQUE_EADDR_END 0xe8000000UL static unsigned long sh64_make_unique_eaddr(unsigned long user_eaddr, unsigned long paddr) { /* Given a physical address paddr, and a user virtual address user_eaddr which will eventually be mapped to it, create a one-off kernel-private eaddr mapped to the same paddr. This is used for creating special destination pages for copy_user_page and clear_user_page */ static unsigned long current_pointer = UNIQUE_EADDR_START; unsigned long coloured_pointer; if (current_pointer == UNIQUE_EADDR_END) { sh64_dcache_purge_all(); current_pointer = UNIQUE_EADDR_START; } coloured_pointer = (current_pointer & ~CACHE_OC_SYN_MASK) | (user_eaddr & CACHE_OC_SYN_MASK); sh64_setup_dtlb_cache_slot(coloured_pointer, get_asid(), paddr); current_pointer += (PAGE_SIZE << CACHE_OC_N_SYNBITS); return coloured_pointer; } /****************************************************************************/ static void sh64_copy_user_page_coloured(void *to, void *from, unsigned long address) { void *coloured_to; /* Discard any existing cache entries of the wrong colour. These are present quite often, if the kernel has recently used the page internally, then given it up, then it's been allocated to the user. */ sh64_dcache_purge_coloured_phy_page(__pa(to), (unsigned long) to); coloured_to = (void *) sh64_make_unique_eaddr(address, __pa(to)); sh64_page_copy(from, coloured_to); sh64_teardown_dtlb_cache_slot(); } static void sh64_clear_user_page_coloured(void *to, unsigned long address) { void *coloured_to; /* Discard any existing kernel-originated lines of the wrong colour (as above) */ sh64_dcache_purge_coloured_phy_page(__pa(to), (unsigned long) to); coloured_to = (void *) sh64_make_unique_eaddr(address, __pa(to)); sh64_page_clear(coloured_to); sh64_teardown_dtlb_cache_slot(); } #endif /* !CONFIG_DCACHE_DISABLED */ /****************************************************************************/ /*########################################################################## EXTERNALLY CALLABLE API. ##########################################################################*/ /* These functions are described in Documentation/cachetlb.txt. Each one of these functions varies in behaviour depending on whether the I-cache and/or D-cache are configured out. Note that the Linux term 'flush' corresponds to what is termed 'purge' in the sh/sh64 jargon for the D-cache, i.e. write back dirty data then invalidate the cache lines, and 'invalidate' for the I-cache. */ #undef FLUSH_TRACE void flush_cache_all(void) { /* Invalidate the entire contents of both caches, after writing back to memory any dirty data from the D-cache. */ sh64_dcache_purge_all(); sh64_icache_inv_all(); } /****************************************************************************/ void flush_cache_mm(struct mm_struct *mm) { /* Invalidate an entire user-address space from both caches, after writing back dirty data (e.g. for shared mmap etc). */ /* This could be coded selectively by inspecting all the tags then doing 4*alloco on any set containing a match (as for flush_cache_range), but fork/exit/execve (where this is called from) are expensive anyway. */ /* Have to do a purge here, despite the comments re I-cache below. There could be odd-coloured dirty data associated with the mm still in the cache - if this gets written out through natural eviction after the kernel has reused the page there will be chaos. */ sh64_dcache_purge_all(); /* The mm being torn down won't ever be active again, so any Icache lines tagged with its ASID won't be visible for the rest of the lifetime of this ASID cycle. Before the ASID gets reused, there will be a flush_cache_all. Hence we don't need to touch the I-cache. This is similar to the lack of action needed in flush_tlb_mm - see fault.c. */ } /****************************************************************************/ void flush_cache_range(struct vm_area_struct *vma, unsigned long start, unsigned long end) { struct mm_struct *mm = vma->vm_mm; /* Invalidate (from both caches) the range [start,end) of virtual addresses from the user address space specified by mm, after writing back any dirty data. Note, 'end' is 1 byte beyond the end of the range to flush. */ sh64_dcache_purge_user_range(mm, start, end); sh64_icache_inv_user_page_range(mm, start, end); } /****************************************************************************/ void flush_cache_page(struct vm_area_struct *vma, unsigned long eaddr, unsigned long pfn) { /* Invalidate any entries in either cache for the vma within the user address space vma->vm_mm for the page starting at virtual address 'eaddr'. This seems to be used primarily in breaking COW. Note, the I-cache must be searched too in case the page in question is both writable and being executed from (e.g. stack trampolines.) Note, this is called with pte lock held. */ sh64_dcache_purge_phy_page(pfn << PAGE_SHIFT); if (vma->vm_flags & VM_EXEC) { sh64_icache_inv_user_page(vma, eaddr); } } /****************************************************************************/ #ifndef CONFIG_DCACHE_DISABLED void copy_user_page(void *to, void *from, unsigned long address, struct page *page) { /* 'from' and 'to' are kernel virtual addresses (within the superpage mapping of the physical RAM). 'address' is the user virtual address where the copy 'to' will be mapped after. This allows a custom mapping to be used to ensure that the new copy is placed in the right cache sets for the user to see it without having to bounce it out via memory. Note however : the call to flush_page_to_ram in (generic)/mm/memory.c:(break_cow) undoes all this good work in that one very important case! TBD : can we guarantee that on every call, any cache entries for 'from' are in the same colour sets as 'address' also? i.e. is this always used just to deal with COW? (I suspect not). */ /* There are two possibilities here for when the page 'from' was last accessed: * by the kernel : this is OK, no purge required. * by the/a user (e.g. for break_COW) : need to purge. If the potential user mapping at 'address' is the same colour as 'from' there is no need to purge any cache lines from the 'from' page mapped into cache sets of colour 'address'. (The copy will be accessing the page through 'from'). */ if (((address ^ (unsigned long) from) & CACHE_OC_SYN_MASK) != 0) { sh64_dcache_purge_coloured_phy_page(__pa(from), address); } if (((address ^ (unsigned long) to) & CACHE_OC_SYN_MASK) == 0) { /* No synonym problem on destination */ sh64_page_copy(from, to); } else { sh64_copy_user_page_coloured(to, from, address); } /* Note, don't need to flush 'from' page from the cache again - it's done anyway by the generic code */ } void clear_user_page(void *to, unsigned long address, struct page *page) { /* 'to' is a kernel virtual address (within the superpage mapping of the physical RAM). 'address' is the user virtual address where the 'to' page will be mapped after. This allows a custom mapping to be used to ensure that the new copy is placed in the right cache sets for the user to see it without having to bounce it out via memory. */ if (((address ^ (unsigned long) to) & CACHE_OC_SYN_MASK) == 0) { /* No synonym problem on destination */ sh64_page_clear(to); } else { sh64_clear_user_page_coloured(to, address); } } #endif /* !CONFIG_DCACHE_DISABLED */ /****************************************************************************/ void flush_dcache_page(struct page *page) { sh64_dcache_purge_phy_page(page_to_phys(page)); wmb(); } /****************************************************************************/ void flush_icache_range(unsigned long start, unsigned long end) { /* Flush the range [start,end] of kernel virtual adddress space from the I-cache. The corresponding range must be purged from the D-cache also because the SH-5 doesn't have cache snooping between the caches. The addresses will be visible through the superpage mapping, therefore it's guaranteed that there no cache entries for the range in cache sets of the wrong colour. Primarily used for cohering the I-cache after a module has been loaded. */ /* We also make sure to purge the same range from the D-cache since flush_page_to_ram() won't be doing this for us! */ sh64_dcache_purge_kernel_range(start, end); wmb(); sh64_icache_inv_kernel_range(start, end); } /****************************************************************************/ void flush_icache_user_range(struct vm_area_struct *vma, struct page *page, unsigned long addr, int len) { /* Flush the range of user (defined by vma->vm_mm) address space starting at 'addr' for 'len' bytes from the cache. The range does not straddle a page boundary, the unique physical page containing the range is 'page'. This seems to be used mainly for invalidating an address range following a poke into the program text through the ptrace() call from another process (e.g. for BRK instruction insertion). */ sh64_dcache_purge_coloured_phy_page(page_to_phys(page), addr); mb(); if (vma->vm_flags & VM_EXEC) { sh64_icache_inv_user_small_range(vma->vm_mm, addr, len); } } /*########################################################################## ARCH/SH64 PRIVATE CALLABLE API. ##########################################################################*/ void flush_cache_sigtramp(unsigned long start, unsigned long end) { /* For the address range [start,end), write back the data from the D-cache and invalidate the corresponding region of the I-cache for the current process. Used to flush signal trampolines on the stack to make them executable. */ sh64_dcache_wback_current_user_range(start, end); wmb(); sh64_icache_inv_current_user_range(start, end); }