f1a0c4aa09
The patch adds functionality required for cache maintenance. The AArch64 architecture mandates non-aliasing VIPT or PIPT D-cache and VIPT (may have aliases) or ASID-tagged VIVT I-cache. Cache maintenance operations are automatically broadcast in hardware between CPUs. Signed-off-by: Will Deacon <will.deacon@arm.com> Signed-off-by: Catalin Marinas <catalin.marinas@arm.com> Acked-by: Tony Lindgren <tony@atomide.com> Acked-by: Nicolas Pitre <nico@linaro.org> Acked-by: Olof Johansson <olof@lixom.net> Acked-by: Santosh Shilimkar <santosh.shilimkar@ti.com> Acked-by: Arnd Bergmann <arnd@arndb.de>
169 lines
4.6 KiB
ArmAsm
169 lines
4.6 KiB
ArmAsm
/*
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* Cache maintenance
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*
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* Copyright (C) 2001 Deep Blue Solutions Ltd.
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* Copyright (C) 2012 ARM Ltd.
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*
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* This program is free software; you can redistribute it and/or modify
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* it under the terms of the GNU General Public License version 2 as
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* published by the Free Software Foundation.
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*
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* This program is distributed in the hope that it will be useful,
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* but WITHOUT ANY WARRANTY; without even the implied warranty of
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* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
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* GNU General Public License for more details.
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*
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* You should have received a copy of the GNU General Public License
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* along with this program. If not, see <http://www.gnu.org/licenses/>.
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*/
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#include <linux/linkage.h>
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#include <linux/init.h>
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#include <asm/assembler.h>
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#include "proc-macros.S"
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/*
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* __flush_dcache_all()
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*
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* Flush the whole D-cache.
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*
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* Corrupted registers: x0-x7, x9-x11
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*/
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ENTRY(__flush_dcache_all)
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dsb sy // ensure ordering with previous memory accesses
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mrs x0, clidr_el1 // read clidr
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and x3, x0, #0x7000000 // extract loc from clidr
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lsr x3, x3, #23 // left align loc bit field
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cbz x3, finished // if loc is 0, then no need to clean
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mov x10, #0 // start clean at cache level 0
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loop1:
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add x2, x10, x10, lsr #1 // work out 3x current cache level
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lsr x1, x0, x2 // extract cache type bits from clidr
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and x1, x1, #7 // mask of the bits for current cache only
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cmp x1, #2 // see what cache we have at this level
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b.lt skip // skip if no cache, or just i-cache
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save_and_disable_irqs x9 // make CSSELR and CCSIDR access atomic
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msr csselr_el1, x10 // select current cache level in csselr
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isb // isb to sych the new cssr&csidr
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mrs x1, ccsidr_el1 // read the new ccsidr
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restore_irqs x9
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and x2, x1, #7 // extract the length of the cache lines
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add x2, x2, #4 // add 4 (line length offset)
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mov x4, #0x3ff
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and x4, x4, x1, lsr #3 // find maximum number on the way size
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clz x5, x4 // find bit position of way size increment
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mov x7, #0x7fff
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and x7, x7, x1, lsr #13 // extract max number of the index size
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loop2:
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mov x9, x4 // create working copy of max way size
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loop3:
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lsl x6, x9, x5
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orr x11, x10, x6 // factor way and cache number into x11
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lsl x6, x7, x2
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orr x11, x11, x6 // factor index number into x11
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dc cisw, x11 // clean & invalidate by set/way
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subs x9, x9, #1 // decrement the way
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b.ge loop3
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subs x7, x7, #1 // decrement the index
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b.ge loop2
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skip:
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add x10, x10, #2 // increment cache number
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cmp x3, x10
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b.gt loop1
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finished:
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mov x10, #0 // swith back to cache level 0
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msr csselr_el1, x10 // select current cache level in csselr
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dsb sy
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isb
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ret
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ENDPROC(__flush_dcache_all)
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/*
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* flush_cache_all()
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*
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* Flush the entire cache system. The data cache flush is now achieved
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* using atomic clean / invalidates working outwards from L1 cache. This
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* is done using Set/Way based cache maintainance instructions. The
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* instruction cache can still be invalidated back to the point of
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* unification in a single instruction.
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*/
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ENTRY(flush_cache_all)
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mov x12, lr
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bl __flush_dcache_all
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mov x0, #0
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ic ialluis // I+BTB cache invalidate
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ret x12
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ENDPROC(flush_cache_all)
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/*
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* flush_icache_range(start,end)
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*
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* Ensure that the I and D caches are coherent within specified region.
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* This is typically used when code has been written to a memory region,
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* and will be executed.
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*
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* - start - virtual start address of region
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* - end - virtual end address of region
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*/
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ENTRY(flush_icache_range)
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/* FALLTHROUGH */
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/*
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* __flush_cache_user_range(start,end)
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*
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* Ensure that the I and D caches are coherent within specified region.
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* This is typically used when code has been written to a memory region,
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* and will be executed.
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*
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* - start - virtual start address of region
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* - end - virtual end address of region
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*/
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ENTRY(__flush_cache_user_range)
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dcache_line_size x2, x3
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sub x3, x2, #1
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bic x4, x0, x3
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1:
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USER(9f, dc cvau, x4 ) // clean D line to PoU
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add x4, x4, x2
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cmp x4, x1
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b.lo 1b
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dsb sy
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icache_line_size x2, x3
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sub x3, x2, #1
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bic x4, x0, x3
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1:
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USER(9f, ic ivau, x4 ) // invalidate I line PoU
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add x4, x4, x2
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cmp x4, x1
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b.lo 1b
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9: // ignore any faulting cache operation
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dsb sy
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isb
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ret
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ENDPROC(flush_icache_range)
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ENDPROC(__flush_cache_user_range)
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/*
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* __flush_kern_dcache_page(kaddr)
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*
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* Ensure that the data held in the page kaddr is written back to the
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* page in question.
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*
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* - kaddr - kernel address
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* - size - size in question
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*/
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ENTRY(__flush_dcache_area)
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dcache_line_size x2, x3
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add x1, x0, x1
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sub x3, x2, #1
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bic x0, x0, x3
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1: dc civac, x0 // clean & invalidate D line / unified line
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add x0, x0, x2
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cmp x0, x1
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b.lo 1b
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dsb sy
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ret
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ENDPROC(__flush_dcache_area)
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