linux/arch/mips/mm/c-r4k.c
NeilBrown 55a2aa08b3
MIPS: c-r4k: Fix data corruption related to cache coherence
When DMA will be performed to a MIPS32 1004K CPS, the L1-cache for the
range needs to be flushed and invalidated first.
The code currently takes one of two approaches.
1/ If the range is less than the size of the dcache, then HIT type
   requests flush/invalidate cache lines for the particular addresses.
   HIT-type requests a globalised by the CPS so this is safe on SMP.

2/ If the range is larger than the size of dcache, then INDEX type
   requests flush/invalidate the whole cache. INDEX type requests affect
   the local cache only. CPS does not propagate them in any way. So this
   invalidation is not safe on SMP CPS systems.

Data corruption due to '2' can quite easily be demonstrated by
repeatedly "echo 3 > /proc/sys/vm/drop_caches" and then sha1sum a file
that is several times the size of available memory. Dropping caches
means that large contiguous extents (large than dcache) are more likely.

This was not a problem before Linux-4.8 because option 2 was never used
if CONFIG_MIPS_CPS was defined. The commit which removed that apparently
didn't appreciate the full consequence of the change.

We could, in theory, globalize the INDEX based flush by sending an IPI
to other cores. These cache invalidation routines can be called with
interrupts disabled and synchronous IPI require interrupts to be
enabled. Asynchronous IPI may not trigger writeback soon enough. So we
cannot use IPI in practice.

We can already test if IPI would be needed for an INDEX operation with
r4k_op_needs_ipi(R4K_INDEX). If this is true then we mustn't try the
INDEX approach as we cannot use IPI. If this is false (e.g. when there
is only one core and hence one L1 cache) then it is safe to use the
INDEX approach without IPI.

This patch avoids options 2 if r4k_op_needs_ipi(R4K_INDEX), and so
eliminates the corruption.

Fixes: c00ab4896e ("MIPS: Remove cpu_has_safe_index_cacheops")
Signed-off-by: NeilBrown <neil@brown.name>
Cc: Ralf Baechle <ralf@linux-mips.org>
Cc: Paul Burton <paul.burton@mips.com>
Cc: linux-mips@linux-mips.org
Cc: <stable@vger.kernel.org> # 4.8+
Patchwork: https://patchwork.linux-mips.org/patch/19259/
Signed-off-by: James Hogan <jhogan@kernel.org>
2018-05-14 23:52:40 +01:00

2044 lines
53 KiB
C

/*
* 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.
*
* Copyright (C) 1996 David S. Miller (davem@davemloft.net)
* Copyright (C) 1997, 1998, 1999, 2000, 2001, 2002 Ralf Baechle (ralf@gnu.org)
* Copyright (C) 1999, 2000 Silicon Graphics, Inc.
*/
#include <linux/cpu_pm.h>
#include <linux/hardirq.h>
#include <linux/init.h>
#include <linux/highmem.h>
#include <linux/kernel.h>
#include <linux/linkage.h>
#include <linux/preempt.h>
#include <linux/sched.h>
#include <linux/smp.h>
#include <linux/mm.h>
#include <linux/export.h>
#include <linux/bitops.h>
#include <asm/bcache.h>
#include <asm/bootinfo.h>
#include <asm/cache.h>
#include <asm/cacheops.h>
#include <asm/cpu.h>
#include <asm/cpu-features.h>
#include <asm/cpu-type.h>
#include <asm/io.h>
#include <asm/page.h>
#include <asm/pgtable.h>
#include <asm/r4kcache.h>
#include <asm/sections.h>
#include <asm/mmu_context.h>
#include <asm/war.h>
#include <asm/cacheflush.h> /* for run_uncached() */
#include <asm/traps.h>
#include <asm/dma-coherence.h>
#include <asm/mips-cps.h>
/*
* Bits describing what cache ops an SMP callback function may perform.
*
* R4K_HIT - Virtual user or kernel address based cache operations. The
* active_mm must be checked before using user addresses, falling
* back to kmap.
* R4K_INDEX - Index based cache operations.
*/
#define R4K_HIT BIT(0)
#define R4K_INDEX BIT(1)
/**
* r4k_op_needs_ipi() - Decide if a cache op needs to be done on every core.
* @type: Type of cache operations (R4K_HIT or R4K_INDEX).
*
* Decides whether a cache op needs to be performed on every core in the system.
* This may change depending on the @type of cache operation, as well as the set
* of online CPUs, so preemption should be disabled by the caller to prevent CPU
* hotplug from changing the result.
*
* Returns: 1 if the cache operation @type should be done on every core in
* the system.
* 0 if the cache operation @type is globalized and only needs to
* be performed on a simple CPU.
*/
static inline bool r4k_op_needs_ipi(unsigned int type)
{
/* The MIPS Coherence Manager (CM) globalizes address-based cache ops */
if (type == R4K_HIT && mips_cm_present())
return false;
/*
* Hardware doesn't globalize the required cache ops, so SMP calls may
* be needed, but only if there are foreign CPUs (non-siblings with
* separate caches).
*/
/* cpu_foreign_map[] undeclared when !CONFIG_SMP */
#ifdef CONFIG_SMP
return !cpumask_empty(&cpu_foreign_map[0]);
#else
return false;
#endif
}
/*
* Special Variant of smp_call_function for use by cache functions:
*
* o No return value
* o collapses to normal function call on UP kernels
* o collapses to normal function call on systems with a single shared
* primary cache.
* o doesn't disable interrupts on the local CPU
*/
static inline void r4k_on_each_cpu(unsigned int type,
void (*func)(void *info), void *info)
{
preempt_disable();
if (r4k_op_needs_ipi(type))
smp_call_function_many(&cpu_foreign_map[smp_processor_id()],
func, info, 1);
func(info);
preempt_enable();
}
/*
* Must die.
*/
static unsigned long icache_size __read_mostly;
static unsigned long dcache_size __read_mostly;
static unsigned long vcache_size __read_mostly;
static unsigned long scache_size __read_mostly;
/*
* Dummy cache handling routines for machines without boardcaches
*/
static void cache_noop(void) {}
static struct bcache_ops no_sc_ops = {
.bc_enable = (void *)cache_noop,
.bc_disable = (void *)cache_noop,
.bc_wback_inv = (void *)cache_noop,
.bc_inv = (void *)cache_noop
};
struct bcache_ops *bcops = &no_sc_ops;
#define cpu_is_r4600_v1_x() ((read_c0_prid() & 0xfffffff0) == 0x00002010)
#define cpu_is_r4600_v2_x() ((read_c0_prid() & 0xfffffff0) == 0x00002020)
#define R4600_HIT_CACHEOP_WAR_IMPL \
do { \
if (R4600_V2_HIT_CACHEOP_WAR && cpu_is_r4600_v2_x()) \
*(volatile unsigned long *)CKSEG1; \
if (R4600_V1_HIT_CACHEOP_WAR) \
__asm__ __volatile__("nop;nop;nop;nop"); \
} while (0)
static void (*r4k_blast_dcache_page)(unsigned long addr);
static inline void r4k_blast_dcache_page_dc32(unsigned long addr)
{
R4600_HIT_CACHEOP_WAR_IMPL;
blast_dcache32_page(addr);
}
static inline void r4k_blast_dcache_page_dc64(unsigned long addr)
{
blast_dcache64_page(addr);
}
static inline void r4k_blast_dcache_page_dc128(unsigned long addr)
{
blast_dcache128_page(addr);
}
static void r4k_blast_dcache_page_setup(void)
{
unsigned long dc_lsize = cpu_dcache_line_size();
switch (dc_lsize) {
case 0:
r4k_blast_dcache_page = (void *)cache_noop;
break;
case 16:
r4k_blast_dcache_page = blast_dcache16_page;
break;
case 32:
r4k_blast_dcache_page = r4k_blast_dcache_page_dc32;
break;
case 64:
r4k_blast_dcache_page = r4k_blast_dcache_page_dc64;
break;
case 128:
r4k_blast_dcache_page = r4k_blast_dcache_page_dc128;
break;
default:
break;
}
}
#ifndef CONFIG_EVA
#define r4k_blast_dcache_user_page r4k_blast_dcache_page
#else
static void (*r4k_blast_dcache_user_page)(unsigned long addr);
static void r4k_blast_dcache_user_page_setup(void)
{
unsigned long dc_lsize = cpu_dcache_line_size();
if (dc_lsize == 0)
r4k_blast_dcache_user_page = (void *)cache_noop;
else if (dc_lsize == 16)
r4k_blast_dcache_user_page = blast_dcache16_user_page;
else if (dc_lsize == 32)
r4k_blast_dcache_user_page = blast_dcache32_user_page;
else if (dc_lsize == 64)
r4k_blast_dcache_user_page = blast_dcache64_user_page;
}
#endif
static void (* r4k_blast_dcache_page_indexed)(unsigned long addr);
static void r4k_blast_dcache_page_indexed_setup(void)
{
unsigned long dc_lsize = cpu_dcache_line_size();
if (dc_lsize == 0)
r4k_blast_dcache_page_indexed = (void *)cache_noop;
else if (dc_lsize == 16)
r4k_blast_dcache_page_indexed = blast_dcache16_page_indexed;
else if (dc_lsize == 32)
r4k_blast_dcache_page_indexed = blast_dcache32_page_indexed;
else if (dc_lsize == 64)
r4k_blast_dcache_page_indexed = blast_dcache64_page_indexed;
else if (dc_lsize == 128)
r4k_blast_dcache_page_indexed = blast_dcache128_page_indexed;
}
void (* r4k_blast_dcache)(void);
EXPORT_SYMBOL(r4k_blast_dcache);
static void r4k_blast_dcache_setup(void)
{
unsigned long dc_lsize = cpu_dcache_line_size();
if (dc_lsize == 0)
r4k_blast_dcache = (void *)cache_noop;
else if (dc_lsize == 16)
r4k_blast_dcache = blast_dcache16;
else if (dc_lsize == 32)
r4k_blast_dcache = blast_dcache32;
else if (dc_lsize == 64)
r4k_blast_dcache = blast_dcache64;
else if (dc_lsize == 128)
r4k_blast_dcache = blast_dcache128;
}
/* force code alignment (used for TX49XX_ICACHE_INDEX_INV_WAR) */
#define JUMP_TO_ALIGN(order) \
__asm__ __volatile__( \
"b\t1f\n\t" \
".align\t" #order "\n\t" \
"1:\n\t" \
)
#define CACHE32_UNROLL32_ALIGN JUMP_TO_ALIGN(10) /* 32 * 32 = 1024 */
#define CACHE32_UNROLL32_ALIGN2 JUMP_TO_ALIGN(11)
static inline void blast_r4600_v1_icache32(void)
{
unsigned long flags;
local_irq_save(flags);
blast_icache32();
local_irq_restore(flags);
}
static inline void tx49_blast_icache32(void)
{
unsigned long start = INDEX_BASE;
unsigned long end = start + current_cpu_data.icache.waysize;
unsigned long ws_inc = 1UL << current_cpu_data.icache.waybit;
unsigned long ws_end = current_cpu_data.icache.ways <<
current_cpu_data.icache.waybit;
unsigned long ws, addr;
CACHE32_UNROLL32_ALIGN2;
/* I'm in even chunk. blast odd chunks */
for (ws = 0; ws < ws_end; ws += ws_inc)
for (addr = start + 0x400; addr < end; addr += 0x400 * 2)
cache32_unroll32(addr|ws, Index_Invalidate_I);
CACHE32_UNROLL32_ALIGN;
/* I'm in odd chunk. blast even chunks */
for (ws = 0; ws < ws_end; ws += ws_inc)
for (addr = start; addr < end; addr += 0x400 * 2)
cache32_unroll32(addr|ws, Index_Invalidate_I);
}
static inline void blast_icache32_r4600_v1_page_indexed(unsigned long page)
{
unsigned long flags;
local_irq_save(flags);
blast_icache32_page_indexed(page);
local_irq_restore(flags);
}
static inline void tx49_blast_icache32_page_indexed(unsigned long page)
{
unsigned long indexmask = current_cpu_data.icache.waysize - 1;
unsigned long start = INDEX_BASE + (page & indexmask);
unsigned long end = start + PAGE_SIZE;
unsigned long ws_inc = 1UL << current_cpu_data.icache.waybit;
unsigned long ws_end = current_cpu_data.icache.ways <<
current_cpu_data.icache.waybit;
unsigned long ws, addr;
CACHE32_UNROLL32_ALIGN2;
/* I'm in even chunk. blast odd chunks */
for (ws = 0; ws < ws_end; ws += ws_inc)
for (addr = start + 0x400; addr < end; addr += 0x400 * 2)
cache32_unroll32(addr|ws, Index_Invalidate_I);
CACHE32_UNROLL32_ALIGN;
/* I'm in odd chunk. blast even chunks */
for (ws = 0; ws < ws_end; ws += ws_inc)
for (addr = start; addr < end; addr += 0x400 * 2)
cache32_unroll32(addr|ws, Index_Invalidate_I);
}
static void (* r4k_blast_icache_page)(unsigned long addr);
static void r4k_blast_icache_page_setup(void)
{
unsigned long ic_lsize = cpu_icache_line_size();
if (ic_lsize == 0)
r4k_blast_icache_page = (void *)cache_noop;
else if (ic_lsize == 16)
r4k_blast_icache_page = blast_icache16_page;
else if (ic_lsize == 32 && current_cpu_type() == CPU_LOONGSON2)
r4k_blast_icache_page = loongson2_blast_icache32_page;
else if (ic_lsize == 32)
r4k_blast_icache_page = blast_icache32_page;
else if (ic_lsize == 64)
r4k_blast_icache_page = blast_icache64_page;
else if (ic_lsize == 128)
r4k_blast_icache_page = blast_icache128_page;
}
#ifndef CONFIG_EVA
#define r4k_blast_icache_user_page r4k_blast_icache_page
#else
static void (*r4k_blast_icache_user_page)(unsigned long addr);
static void r4k_blast_icache_user_page_setup(void)
{
unsigned long ic_lsize = cpu_icache_line_size();
if (ic_lsize == 0)
r4k_blast_icache_user_page = (void *)cache_noop;
else if (ic_lsize == 16)
r4k_blast_icache_user_page = blast_icache16_user_page;
else if (ic_lsize == 32)
r4k_blast_icache_user_page = blast_icache32_user_page;
else if (ic_lsize == 64)
r4k_blast_icache_user_page = blast_icache64_user_page;
}
#endif
static void (* r4k_blast_icache_page_indexed)(unsigned long addr);
static void r4k_blast_icache_page_indexed_setup(void)
{
unsigned long ic_lsize = cpu_icache_line_size();
if (ic_lsize == 0)
r4k_blast_icache_page_indexed = (void *)cache_noop;
else if (ic_lsize == 16)
r4k_blast_icache_page_indexed = blast_icache16_page_indexed;
else if (ic_lsize == 32) {
if (R4600_V1_INDEX_ICACHEOP_WAR && cpu_is_r4600_v1_x())
r4k_blast_icache_page_indexed =
blast_icache32_r4600_v1_page_indexed;
else if (TX49XX_ICACHE_INDEX_INV_WAR)
r4k_blast_icache_page_indexed =
tx49_blast_icache32_page_indexed;
else if (current_cpu_type() == CPU_LOONGSON2)
r4k_blast_icache_page_indexed =
loongson2_blast_icache32_page_indexed;
else
r4k_blast_icache_page_indexed =
blast_icache32_page_indexed;
} else if (ic_lsize == 64)
r4k_blast_icache_page_indexed = blast_icache64_page_indexed;
}
void (* r4k_blast_icache)(void);
EXPORT_SYMBOL(r4k_blast_icache);
static void r4k_blast_icache_setup(void)
{
unsigned long ic_lsize = cpu_icache_line_size();
if (ic_lsize == 0)
r4k_blast_icache = (void *)cache_noop;
else if (ic_lsize == 16)
r4k_blast_icache = blast_icache16;
else if (ic_lsize == 32) {
if (R4600_V1_INDEX_ICACHEOP_WAR && cpu_is_r4600_v1_x())
r4k_blast_icache = blast_r4600_v1_icache32;
else if (TX49XX_ICACHE_INDEX_INV_WAR)
r4k_blast_icache = tx49_blast_icache32;
else if (current_cpu_type() == CPU_LOONGSON2)
r4k_blast_icache = loongson2_blast_icache32;
else
r4k_blast_icache = blast_icache32;
} else if (ic_lsize == 64)
r4k_blast_icache = blast_icache64;
else if (ic_lsize == 128)
r4k_blast_icache = blast_icache128;
}
static void (* r4k_blast_scache_page)(unsigned long addr);
static void r4k_blast_scache_page_setup(void)
{
unsigned long sc_lsize = cpu_scache_line_size();
if (scache_size == 0)
r4k_blast_scache_page = (void *)cache_noop;
else if (sc_lsize == 16)
r4k_blast_scache_page = blast_scache16_page;
else if (sc_lsize == 32)
r4k_blast_scache_page = blast_scache32_page;
else if (sc_lsize == 64)
r4k_blast_scache_page = blast_scache64_page;
else if (sc_lsize == 128)
r4k_blast_scache_page = blast_scache128_page;
}
static void (* r4k_blast_scache_page_indexed)(unsigned long addr);
static void r4k_blast_scache_page_indexed_setup(void)
{
unsigned long sc_lsize = cpu_scache_line_size();
if (scache_size == 0)
r4k_blast_scache_page_indexed = (void *)cache_noop;
else if (sc_lsize == 16)
r4k_blast_scache_page_indexed = blast_scache16_page_indexed;
else if (sc_lsize == 32)
r4k_blast_scache_page_indexed = blast_scache32_page_indexed;
else if (sc_lsize == 64)
r4k_blast_scache_page_indexed = blast_scache64_page_indexed;
else if (sc_lsize == 128)
r4k_blast_scache_page_indexed = blast_scache128_page_indexed;
}
static void (* r4k_blast_scache)(void);
static void r4k_blast_scache_setup(void)
{
unsigned long sc_lsize = cpu_scache_line_size();
if (scache_size == 0)
r4k_blast_scache = (void *)cache_noop;
else if (sc_lsize == 16)
r4k_blast_scache = blast_scache16;
else if (sc_lsize == 32)
r4k_blast_scache = blast_scache32;
else if (sc_lsize == 64)
r4k_blast_scache = blast_scache64;
else if (sc_lsize == 128)
r4k_blast_scache = blast_scache128;
}
static inline void local_r4k___flush_cache_all(void * args)
{
switch (current_cpu_type()) {
case CPU_LOONGSON2:
case CPU_LOONGSON3:
case CPU_R4000SC:
case CPU_R4000MC:
case CPU_R4400SC:
case CPU_R4400MC:
case CPU_R10000:
case CPU_R12000:
case CPU_R14000:
case CPU_R16000:
/*
* These caches are inclusive caches, that is, if something
* is not cached in the S-cache, we know it also won't be
* in one of the primary caches.
*/
r4k_blast_scache();
break;
case CPU_BMIPS5000:
r4k_blast_scache();
__sync();
break;
default:
r4k_blast_dcache();
r4k_blast_icache();
break;
}
}
static void r4k___flush_cache_all(void)
{
r4k_on_each_cpu(R4K_INDEX, local_r4k___flush_cache_all, NULL);
}
/**
* has_valid_asid() - Determine if an mm already has an ASID.
* @mm: Memory map.
* @type: R4K_HIT or R4K_INDEX, type of cache op.
*
* Determines whether @mm already has an ASID on any of the CPUs which cache ops
* of type @type within an r4k_on_each_cpu() call will affect. If
* r4k_on_each_cpu() does an SMP call to a single VPE in each core, then the
* scope of the operation is confined to sibling CPUs, otherwise all online CPUs
* will need to be checked.
*
* Must be called in non-preemptive context.
*
* Returns: 1 if the CPUs affected by @type cache ops have an ASID for @mm.
* 0 otherwise.
*/
static inline int has_valid_asid(const struct mm_struct *mm, unsigned int type)
{
unsigned int i;
const cpumask_t *mask = cpu_present_mask;
/* cpu_sibling_map[] undeclared when !CONFIG_SMP */
#ifdef CONFIG_SMP
/*
* If r4k_on_each_cpu does SMP calls, it does them to a single VPE in
* each foreign core, so we only need to worry about siblings.
* Otherwise we need to worry about all present CPUs.
*/
if (r4k_op_needs_ipi(type))
mask = &cpu_sibling_map[smp_processor_id()];
#endif
for_each_cpu(i, mask)
if (cpu_context(i, mm))
return 1;
return 0;
}
static void r4k__flush_cache_vmap(void)
{
r4k_blast_dcache();
}
static void r4k__flush_cache_vunmap(void)
{
r4k_blast_dcache();
}
/*
* Note: flush_tlb_range() assumes flush_cache_range() sufficiently flushes
* whole caches when vma is executable.
*/
static inline void local_r4k_flush_cache_range(void * args)
{
struct vm_area_struct *vma = args;
int exec = vma->vm_flags & VM_EXEC;
if (!has_valid_asid(vma->vm_mm, R4K_INDEX))
return;
/*
* If dcache can alias, we must blast it since mapping is changing.
* If executable, we must ensure any dirty lines are written back far
* enough to be visible to icache.
*/
if (cpu_has_dc_aliases || (exec && !cpu_has_ic_fills_f_dc))
r4k_blast_dcache();
/* If executable, blast stale lines from icache */
if (exec)
r4k_blast_icache();
}
static void r4k_flush_cache_range(struct vm_area_struct *vma,
unsigned long start, unsigned long end)
{
int exec = vma->vm_flags & VM_EXEC;
if (cpu_has_dc_aliases || exec)
r4k_on_each_cpu(R4K_INDEX, local_r4k_flush_cache_range, vma);
}
static inline void local_r4k_flush_cache_mm(void * args)
{
struct mm_struct *mm = args;
if (!has_valid_asid(mm, R4K_INDEX))
return;
/*
* Kludge alert. For obscure reasons R4000SC and R4400SC go nuts if we
* only flush the primary caches but R1x000 behave sane ...
* R4000SC and R4400SC indexed S-cache ops also invalidate primary
* caches, so we can bail out early.
*/
if (current_cpu_type() == CPU_R4000SC ||
current_cpu_type() == CPU_R4000MC ||
current_cpu_type() == CPU_R4400SC ||
current_cpu_type() == CPU_R4400MC) {
r4k_blast_scache();
return;
}
r4k_blast_dcache();
}
static void r4k_flush_cache_mm(struct mm_struct *mm)
{
if (!cpu_has_dc_aliases)
return;
r4k_on_each_cpu(R4K_INDEX, local_r4k_flush_cache_mm, mm);
}
struct flush_cache_page_args {
struct vm_area_struct *vma;
unsigned long addr;
unsigned long pfn;
};
static inline void local_r4k_flush_cache_page(void *args)
{
struct flush_cache_page_args *fcp_args = args;
struct vm_area_struct *vma = fcp_args->vma;
unsigned long addr = fcp_args->addr;
struct page *page = pfn_to_page(fcp_args->pfn);
int exec = vma->vm_flags & VM_EXEC;
struct mm_struct *mm = vma->vm_mm;
int map_coherent = 0;
pgd_t *pgdp;
pud_t *pudp;
pmd_t *pmdp;
pte_t *ptep;
void *vaddr;
/*
* If owns no valid ASID yet, cannot possibly have gotten
* this page into the cache.
*/
if (!has_valid_asid(mm, R4K_HIT))
return;
addr &= PAGE_MASK;
pgdp = pgd_offset(mm, addr);
pudp = pud_offset(pgdp, addr);
pmdp = pmd_offset(pudp, addr);
ptep = pte_offset(pmdp, addr);
/*
* If the page isn't marked valid, the page cannot possibly be
* in the cache.
*/
if (!(pte_present(*ptep)))
return;
if ((mm == current->active_mm) && (pte_val(*ptep) & _PAGE_VALID))
vaddr = NULL;
else {
/*
* Use kmap_coherent or kmap_atomic to do flushes for
* another ASID than the current one.
*/
map_coherent = (cpu_has_dc_aliases &&
page_mapcount(page) &&
!Page_dcache_dirty(page));
if (map_coherent)
vaddr = kmap_coherent(page, addr);
else
vaddr = kmap_atomic(page);
addr = (unsigned long)vaddr;
}
if (cpu_has_dc_aliases || (exec && !cpu_has_ic_fills_f_dc)) {
vaddr ? r4k_blast_dcache_page(addr) :
r4k_blast_dcache_user_page(addr);
if (exec && !cpu_icache_snoops_remote_store)
r4k_blast_scache_page(addr);
}
if (exec) {
if (vaddr && cpu_has_vtag_icache && mm == current->active_mm) {
int cpu = smp_processor_id();
if (cpu_context(cpu, mm) != 0)
drop_mmu_context(mm, cpu);
} else
vaddr ? r4k_blast_icache_page(addr) :
r4k_blast_icache_user_page(addr);
}
if (vaddr) {
if (map_coherent)
kunmap_coherent();
else
kunmap_atomic(vaddr);
}
}
static void r4k_flush_cache_page(struct vm_area_struct *vma,
unsigned long addr, unsigned long pfn)
{
struct flush_cache_page_args args;
args.vma = vma;
args.addr = addr;
args.pfn = pfn;
r4k_on_each_cpu(R4K_HIT, local_r4k_flush_cache_page, &args);
}
static inline void local_r4k_flush_data_cache_page(void * addr)
{
r4k_blast_dcache_page((unsigned long) addr);
}
static void r4k_flush_data_cache_page(unsigned long addr)
{
if (in_atomic())
local_r4k_flush_data_cache_page((void *)addr);
else
r4k_on_each_cpu(R4K_HIT, local_r4k_flush_data_cache_page,
(void *) addr);
}
struct flush_icache_range_args {
unsigned long start;
unsigned long end;
unsigned int type;
bool user;
};
static inline void __local_r4k_flush_icache_range(unsigned long start,
unsigned long end,
unsigned int type,
bool user)
{
if (!cpu_has_ic_fills_f_dc) {
if (type == R4K_INDEX ||
(type & R4K_INDEX && end - start >= dcache_size)) {
r4k_blast_dcache();
} else {
R4600_HIT_CACHEOP_WAR_IMPL;
if (user)
protected_blast_dcache_range(start, end);
else
blast_dcache_range(start, end);
}
}
if (type == R4K_INDEX ||
(type & R4K_INDEX && end - start > icache_size))
r4k_blast_icache();
else {
switch (boot_cpu_type()) {
case CPU_LOONGSON2:
protected_loongson2_blast_icache_range(start, end);
break;
default:
if (user)
protected_blast_icache_range(start, end);
else
blast_icache_range(start, end);
break;
}
}
}
static inline void local_r4k_flush_icache_range(unsigned long start,
unsigned long end)
{
__local_r4k_flush_icache_range(start, end, R4K_HIT | R4K_INDEX, false);
}
static inline void local_r4k_flush_icache_user_range(unsigned long start,
unsigned long end)
{
__local_r4k_flush_icache_range(start, end, R4K_HIT | R4K_INDEX, true);
}
static inline void local_r4k_flush_icache_range_ipi(void *args)
{
struct flush_icache_range_args *fir_args = args;
unsigned long start = fir_args->start;
unsigned long end = fir_args->end;
unsigned int type = fir_args->type;
bool user = fir_args->user;
__local_r4k_flush_icache_range(start, end, type, user);
}
static void __r4k_flush_icache_range(unsigned long start, unsigned long end,
bool user)
{
struct flush_icache_range_args args;
unsigned long size, cache_size;
args.start = start;
args.end = end;
args.type = R4K_HIT | R4K_INDEX;
args.user = user;
/*
* Indexed cache ops require an SMP call.
* Consider if that can or should be avoided.
*/
preempt_disable();
if (r4k_op_needs_ipi(R4K_INDEX) && !r4k_op_needs_ipi(R4K_HIT)) {
/*
* If address-based cache ops don't require an SMP call, then
* use them exclusively for small flushes.
*/
size = end - start;
cache_size = icache_size;
if (!cpu_has_ic_fills_f_dc) {
size *= 2;
cache_size += dcache_size;
}
if (size <= cache_size)
args.type &= ~R4K_INDEX;
}
r4k_on_each_cpu(args.type, local_r4k_flush_icache_range_ipi, &args);
preempt_enable();
instruction_hazard();
}
static void r4k_flush_icache_range(unsigned long start, unsigned long end)
{
return __r4k_flush_icache_range(start, end, false);
}
static void r4k_flush_icache_user_range(unsigned long start, unsigned long end)
{
return __r4k_flush_icache_range(start, end, true);
}
#if defined(CONFIG_DMA_NONCOHERENT) || defined(CONFIG_DMA_MAYBE_COHERENT)
static void r4k_dma_cache_wback_inv(unsigned long addr, unsigned long size)
{
/* Catch bad driver code */
BUG_ON(size == 0);
preempt_disable();
if (cpu_has_inclusive_pcaches) {
if (size >= scache_size)
r4k_blast_scache();
else
blast_scache_range(addr, addr + size);
preempt_enable();
__sync();
return;
}
/*
* Either no secondary cache or the available caches don't have the
* subset property so we have to flush the primary caches
* explicitly.
* If we would need IPI to perform an INDEX-type operation, then
* we have to use the HIT-type alternative as IPI cannot be used
* here due to interrupts possibly being disabled.
*/
if (!r4k_op_needs_ipi(R4K_INDEX) && size >= dcache_size) {
r4k_blast_dcache();
} else {
R4600_HIT_CACHEOP_WAR_IMPL;
blast_dcache_range(addr, addr + size);
}
preempt_enable();
bc_wback_inv(addr, size);
__sync();
}
static void r4k_dma_cache_inv(unsigned long addr, unsigned long size)
{
/* Catch bad driver code */
BUG_ON(size == 0);
preempt_disable();
if (cpu_has_inclusive_pcaches) {
if (size >= scache_size)
r4k_blast_scache();
else {
/*
* There is no clearly documented alignment requirement
* for the cache instruction on MIPS processors and
* some processors, among them the RM5200 and RM7000
* QED processors will throw an address error for cache
* hit ops with insufficient alignment. Solved by
* aligning the address to cache line size.
*/
blast_inv_scache_range(addr, addr + size);
}
preempt_enable();
__sync();
return;
}
if (!r4k_op_needs_ipi(R4K_INDEX) && size >= dcache_size) {
r4k_blast_dcache();
} else {
R4600_HIT_CACHEOP_WAR_IMPL;
blast_inv_dcache_range(addr, addr + size);
}
preempt_enable();
bc_inv(addr, size);
__sync();
}
#endif /* CONFIG_DMA_NONCOHERENT || CONFIG_DMA_MAYBE_COHERENT */
struct flush_cache_sigtramp_args {
struct mm_struct *mm;
struct page *page;
unsigned long addr;
};
/*
* While we're protected against bad userland addresses we don't care
* very much about what happens in that case. Usually a segmentation
* fault will dump the process later on anyway ...
*/
static void local_r4k_flush_cache_sigtramp(void *args)
{
struct flush_cache_sigtramp_args *fcs_args = args;
unsigned long addr = fcs_args->addr;
struct page *page = fcs_args->page;
struct mm_struct *mm = fcs_args->mm;
int map_coherent = 0;
void *vaddr;
unsigned long ic_lsize = cpu_icache_line_size();
unsigned long dc_lsize = cpu_dcache_line_size();
unsigned long sc_lsize = cpu_scache_line_size();
/*
* If owns no valid ASID yet, cannot possibly have gotten
* this page into the cache.
*/
if (!has_valid_asid(mm, R4K_HIT))
return;
if (mm == current->active_mm) {
vaddr = NULL;
} else {
/*
* Use kmap_coherent or kmap_atomic to do flushes for
* another ASID than the current one.
*/
map_coherent = (cpu_has_dc_aliases &&
page_mapcount(page) &&
!Page_dcache_dirty(page));
if (map_coherent)
vaddr = kmap_coherent(page, addr);
else
vaddr = kmap_atomic(page);
addr = (unsigned long)vaddr + (addr & ~PAGE_MASK);
}
R4600_HIT_CACHEOP_WAR_IMPL;
if (!cpu_has_ic_fills_f_dc) {
if (dc_lsize)
vaddr ? flush_dcache_line(addr & ~(dc_lsize - 1))
: protected_writeback_dcache_line(
addr & ~(dc_lsize - 1));
if (!cpu_icache_snoops_remote_store && scache_size)
vaddr ? flush_scache_line(addr & ~(sc_lsize - 1))
: protected_writeback_scache_line(
addr & ~(sc_lsize - 1));
}
if (ic_lsize)
vaddr ? flush_icache_line(addr & ~(ic_lsize - 1))
: protected_flush_icache_line(addr & ~(ic_lsize - 1));
if (vaddr) {
if (map_coherent)
kunmap_coherent();
else
kunmap_atomic(vaddr);
}
if (MIPS4K_ICACHE_REFILL_WAR) {
__asm__ __volatile__ (
".set push\n\t"
".set noat\n\t"
".set "MIPS_ISA_LEVEL"\n\t"
#ifdef CONFIG_32BIT
"la $at,1f\n\t"
#endif
#ifdef CONFIG_64BIT
"dla $at,1f\n\t"
#endif
"cache %0,($at)\n\t"
"nop; nop; nop\n"
"1:\n\t"
".set pop"
:
: "i" (Hit_Invalidate_I));
}
if (MIPS_CACHE_SYNC_WAR)
__asm__ __volatile__ ("sync");
}
static void r4k_flush_cache_sigtramp(unsigned long addr)
{
struct flush_cache_sigtramp_args args;
int npages;
down_read(&current->mm->mmap_sem);
npages = get_user_pages_fast(addr, 1, 0, &args.page);
if (npages < 1)
goto out;
args.mm = current->mm;
args.addr = addr;
r4k_on_each_cpu(R4K_HIT, local_r4k_flush_cache_sigtramp, &args);
put_page(args.page);
out:
up_read(&current->mm->mmap_sem);
}
static void r4k_flush_icache_all(void)
{
if (cpu_has_vtag_icache)
r4k_blast_icache();
}
struct flush_kernel_vmap_range_args {
unsigned long vaddr;
int size;
};
static inline void local_r4k_flush_kernel_vmap_range_index(void *args)
{
/*
* Aliases only affect the primary caches so don't bother with
* S-caches or T-caches.
*/
r4k_blast_dcache();
}
static inline void local_r4k_flush_kernel_vmap_range(void *args)
{
struct flush_kernel_vmap_range_args *vmra = args;
unsigned long vaddr = vmra->vaddr;
int size = vmra->size;
/*
* Aliases only affect the primary caches so don't bother with
* S-caches or T-caches.
*/
R4600_HIT_CACHEOP_WAR_IMPL;
blast_dcache_range(vaddr, vaddr + size);
}
static void r4k_flush_kernel_vmap_range(unsigned long vaddr, int size)
{
struct flush_kernel_vmap_range_args args;
args.vaddr = (unsigned long) vaddr;
args.size = size;
if (size >= dcache_size)
r4k_on_each_cpu(R4K_INDEX,
local_r4k_flush_kernel_vmap_range_index, NULL);
else
r4k_on_each_cpu(R4K_HIT, local_r4k_flush_kernel_vmap_range,
&args);
}
static inline void rm7k_erratum31(void)
{
const unsigned long ic_lsize = 32;
unsigned long addr;
/* RM7000 erratum #31. The icache is screwed at startup. */
write_c0_taglo(0);
write_c0_taghi(0);
for (addr = INDEX_BASE; addr <= INDEX_BASE + 4096; addr += ic_lsize) {
__asm__ __volatile__ (
".set push\n\t"
".set noreorder\n\t"
".set mips3\n\t"
"cache\t%1, 0(%0)\n\t"
"cache\t%1, 0x1000(%0)\n\t"
"cache\t%1, 0x2000(%0)\n\t"
"cache\t%1, 0x3000(%0)\n\t"
"cache\t%2, 0(%0)\n\t"
"cache\t%2, 0x1000(%0)\n\t"
"cache\t%2, 0x2000(%0)\n\t"
"cache\t%2, 0x3000(%0)\n\t"
"cache\t%1, 0(%0)\n\t"
"cache\t%1, 0x1000(%0)\n\t"
"cache\t%1, 0x2000(%0)\n\t"
"cache\t%1, 0x3000(%0)\n\t"
".set pop\n"
:
: "r" (addr), "i" (Index_Store_Tag_I), "i" (Fill));
}
}
static inline int alias_74k_erratum(struct cpuinfo_mips *c)
{
unsigned int imp = c->processor_id & PRID_IMP_MASK;
unsigned int rev = c->processor_id & PRID_REV_MASK;
int present = 0;
/*
* Early versions of the 74K do not update the cache tags on a
* vtag miss/ptag hit which can occur in the case of KSEG0/KUSEG
* aliases. In this case it is better to treat the cache as always
* having aliases. Also disable the synonym tag update feature
* where available. In this case no opportunistic tag update will
* happen where a load causes a virtual address miss but a physical
* address hit during a D-cache look-up.
*/
switch (imp) {
case PRID_IMP_74K:
if (rev <= PRID_REV_ENCODE_332(2, 4, 0))
present = 1;
if (rev == PRID_REV_ENCODE_332(2, 4, 0))
write_c0_config6(read_c0_config6() | MIPS_CONF6_SYND);
break;
case PRID_IMP_1074K:
if (rev <= PRID_REV_ENCODE_332(1, 1, 0)) {
present = 1;
write_c0_config6(read_c0_config6() | MIPS_CONF6_SYND);
}
break;
default:
BUG();
}
return present;
}
static void b5k_instruction_hazard(void)
{
__sync();
__sync();
__asm__ __volatile__(
" nop; nop; nop; nop; nop; nop; nop; nop\n"
" nop; nop; nop; nop; nop; nop; nop; nop\n"
" nop; nop; nop; nop; nop; nop; nop; nop\n"
" nop; nop; nop; nop; nop; nop; nop; nop\n"
: : : "memory");
}
static char *way_string[] = { NULL, "direct mapped", "2-way",
"3-way", "4-way", "5-way", "6-way", "7-way", "8-way",
"9-way", "10-way", "11-way", "12-way",
"13-way", "14-way", "15-way", "16-way",
};
static void probe_pcache(void)
{
struct cpuinfo_mips *c = &current_cpu_data;
unsigned int config = read_c0_config();
unsigned int prid = read_c0_prid();
int has_74k_erratum = 0;
unsigned long config1;
unsigned int lsize;
switch (current_cpu_type()) {
case CPU_R4600: /* QED style two way caches? */
case CPU_R4700:
case CPU_R5000:
case CPU_NEVADA:
icache_size = 1 << (12 + ((config & CONF_IC) >> 9));
c->icache.linesz = 16 << ((config & CONF_IB) >> 5);
c->icache.ways = 2;
c->icache.waybit = __ffs(icache_size/2);
dcache_size = 1 << (12 + ((config & CONF_DC) >> 6));
c->dcache.linesz = 16 << ((config & CONF_DB) >> 4);
c->dcache.ways = 2;
c->dcache.waybit= __ffs(dcache_size/2);
c->options |= MIPS_CPU_CACHE_CDEX_P;
break;
case CPU_R5432:
case CPU_R5500:
icache_size = 1 << (12 + ((config & CONF_IC) >> 9));
c->icache.linesz = 16 << ((config & CONF_IB) >> 5);
c->icache.ways = 2;
c->icache.waybit= 0;
dcache_size = 1 << (12 + ((config & CONF_DC) >> 6));
c->dcache.linesz = 16 << ((config & CONF_DB) >> 4);
c->dcache.ways = 2;
c->dcache.waybit = 0;
c->options |= MIPS_CPU_CACHE_CDEX_P | MIPS_CPU_PREFETCH;
break;
case CPU_TX49XX:
icache_size = 1 << (12 + ((config & CONF_IC) >> 9));
c->icache.linesz = 16 << ((config & CONF_IB) >> 5);
c->icache.ways = 4;
c->icache.waybit= 0;
dcache_size = 1 << (12 + ((config & CONF_DC) >> 6));
c->dcache.linesz = 16 << ((config & CONF_DB) >> 4);
c->dcache.ways = 4;
c->dcache.waybit = 0;
c->options |= MIPS_CPU_CACHE_CDEX_P;
c->options |= MIPS_CPU_PREFETCH;
break;
case CPU_R4000PC:
case CPU_R4000SC:
case CPU_R4000MC:
case CPU_R4400PC:
case CPU_R4400SC:
case CPU_R4400MC:
case CPU_R4300:
icache_size = 1 << (12 + ((config & CONF_IC) >> 9));
c->icache.linesz = 16 << ((config & CONF_IB) >> 5);
c->icache.ways = 1;
c->icache.waybit = 0; /* doesn't matter */
dcache_size = 1 << (12 + ((config & CONF_DC) >> 6));
c->dcache.linesz = 16 << ((config & CONF_DB) >> 4);
c->dcache.ways = 1;
c->dcache.waybit = 0; /* does not matter */
c->options |= MIPS_CPU_CACHE_CDEX_P;
break;
case CPU_R10000:
case CPU_R12000:
case CPU_R14000:
case CPU_R16000:
icache_size = 1 << (12 + ((config & R10K_CONF_IC) >> 29));
c->icache.linesz = 64;
c->icache.ways = 2;
c->icache.waybit = 0;
dcache_size = 1 << (12 + ((config & R10K_CONF_DC) >> 26));
c->dcache.linesz = 32;
c->dcache.ways = 2;
c->dcache.waybit = 0;
c->options |= MIPS_CPU_PREFETCH;
break;
case CPU_VR4133:
write_c0_config(config & ~VR41_CONF_P4K);
case CPU_VR4131:
/* Workaround for cache instruction bug of VR4131 */
if (c->processor_id == 0x0c80U || c->processor_id == 0x0c81U ||
c->processor_id == 0x0c82U) {
config |= 0x00400000U;
if (c->processor_id == 0x0c80U)
config |= VR41_CONF_BP;
write_c0_config(config);
} else
c->options |= MIPS_CPU_CACHE_CDEX_P;
icache_size = 1 << (10 + ((config & CONF_IC) >> 9));
c->icache.linesz = 16 << ((config & CONF_IB) >> 5);
c->icache.ways = 2;
c->icache.waybit = __ffs(icache_size/2);
dcache_size = 1 << (10 + ((config & CONF_DC) >> 6));
c->dcache.linesz = 16 << ((config & CONF_DB) >> 4);
c->dcache.ways = 2;
c->dcache.waybit = __ffs(dcache_size/2);
break;
case CPU_VR41XX:
case CPU_VR4111:
case CPU_VR4121:
case CPU_VR4122:
case CPU_VR4181:
case CPU_VR4181A:
icache_size = 1 << (10 + ((config & CONF_IC) >> 9));
c->icache.linesz = 16 << ((config & CONF_IB) >> 5);
c->icache.ways = 1;
c->icache.waybit = 0; /* doesn't matter */
dcache_size = 1 << (10 + ((config & CONF_DC) >> 6));
c->dcache.linesz = 16 << ((config & CONF_DB) >> 4);
c->dcache.ways = 1;
c->dcache.waybit = 0; /* does not matter */
c->options |= MIPS_CPU_CACHE_CDEX_P;
break;
case CPU_RM7000:
rm7k_erratum31();
icache_size = 1 << (12 + ((config & CONF_IC) >> 9));
c->icache.linesz = 16 << ((config & CONF_IB) >> 5);
c->icache.ways = 4;
c->icache.waybit = __ffs(icache_size / c->icache.ways);
dcache_size = 1 << (12 + ((config & CONF_DC) >> 6));
c->dcache.linesz = 16 << ((config & CONF_DB) >> 4);
c->dcache.ways = 4;
c->dcache.waybit = __ffs(dcache_size / c->dcache.ways);
c->options |= MIPS_CPU_CACHE_CDEX_P;
c->options |= MIPS_CPU_PREFETCH;
break;
case CPU_LOONGSON2:
icache_size = 1 << (12 + ((config & CONF_IC) >> 9));
c->icache.linesz = 16 << ((config & CONF_IB) >> 5);
if (prid & 0x3)
c->icache.ways = 4;
else
c->icache.ways = 2;
c->icache.waybit = 0;
dcache_size = 1 << (12 + ((config & CONF_DC) >> 6));
c->dcache.linesz = 16 << ((config & CONF_DB) >> 4);
if (prid & 0x3)
c->dcache.ways = 4;
else
c->dcache.ways = 2;
c->dcache.waybit = 0;
break;
case CPU_LOONGSON3:
config1 = read_c0_config1();
lsize = (config1 >> 19) & 7;
if (lsize)
c->icache.linesz = 2 << lsize;
else
c->icache.linesz = 0;
c->icache.sets = 64 << ((config1 >> 22) & 7);
c->icache.ways = 1 + ((config1 >> 16) & 7);
icache_size = c->icache.sets *
c->icache.ways *
c->icache.linesz;
c->icache.waybit = 0;
lsize = (config1 >> 10) & 7;
if (lsize)
c->dcache.linesz = 2 << lsize;
else
c->dcache.linesz = 0;
c->dcache.sets = 64 << ((config1 >> 13) & 7);
c->dcache.ways = 1 + ((config1 >> 7) & 7);
dcache_size = c->dcache.sets *
c->dcache.ways *
c->dcache.linesz;
c->dcache.waybit = 0;
if ((prid & PRID_REV_MASK) >= PRID_REV_LOONGSON3A_R2)
c->options |= MIPS_CPU_PREFETCH;
break;
case CPU_CAVIUM_OCTEON3:
/* For now lie about the number of ways. */
c->icache.linesz = 128;
c->icache.sets = 16;
c->icache.ways = 8;
c->icache.flags |= MIPS_CACHE_VTAG;
icache_size = c->icache.sets * c->icache.ways * c->icache.linesz;
c->dcache.linesz = 128;
c->dcache.ways = 8;
c->dcache.sets = 8;
dcache_size = c->dcache.sets * c->dcache.ways * c->dcache.linesz;
c->options |= MIPS_CPU_PREFETCH;
break;
default:
if (!(config & MIPS_CONF_M))
panic("Don't know how to probe P-caches on this cpu.");
/*
* So we seem to be a MIPS32 or MIPS64 CPU
* So let's probe the I-cache ...
*/
config1 = read_c0_config1();
lsize = (config1 >> 19) & 7;
/* IL == 7 is reserved */
if (lsize == 7)
panic("Invalid icache line size");
c->icache.linesz = lsize ? 2 << lsize : 0;
c->icache.sets = 32 << (((config1 >> 22) + 1) & 7);
c->icache.ways = 1 + ((config1 >> 16) & 7);
icache_size = c->icache.sets *
c->icache.ways *
c->icache.linesz;
c->icache.waybit = __ffs(icache_size/c->icache.ways);
if (config & MIPS_CONF_VI)
c->icache.flags |= MIPS_CACHE_VTAG;
/*
* Now probe the MIPS32 / MIPS64 data cache.
*/
c->dcache.flags = 0;
lsize = (config1 >> 10) & 7;
/* DL == 7 is reserved */
if (lsize == 7)
panic("Invalid dcache line size");
c->dcache.linesz = lsize ? 2 << lsize : 0;
c->dcache.sets = 32 << (((config1 >> 13) + 1) & 7);
c->dcache.ways = 1 + ((config1 >> 7) & 7);
dcache_size = c->dcache.sets *
c->dcache.ways *
c->dcache.linesz;
c->dcache.waybit = __ffs(dcache_size/c->dcache.ways);
c->options |= MIPS_CPU_PREFETCH;
break;
}
/*
* Processor configuration sanity check for the R4000SC erratum
* #5. With page sizes larger than 32kB there is no possibility
* to get a VCE exception anymore so we don't care about this
* misconfiguration. The case is rather theoretical anyway;
* presumably no vendor is shipping his hardware in the "bad"
* configuration.
*/
if ((prid & PRID_IMP_MASK) == PRID_IMP_R4000 &&
(prid & PRID_REV_MASK) < PRID_REV_R4400 &&
!(config & CONF_SC) && c->icache.linesz != 16 &&
PAGE_SIZE <= 0x8000)
panic("Improper R4000SC processor configuration detected");
/* compute a couple of other cache variables */
c->icache.waysize = icache_size / c->icache.ways;
c->dcache.waysize = dcache_size / c->dcache.ways;
c->icache.sets = c->icache.linesz ?
icache_size / (c->icache.linesz * c->icache.ways) : 0;
c->dcache.sets = c->dcache.linesz ?
dcache_size / (c->dcache.linesz * c->dcache.ways) : 0;
/*
* R1x000 P-caches are odd in a positive way. They're 32kB 2-way
* virtually indexed so normally would suffer from aliases. So
* normally they'd suffer from aliases but magic in the hardware deals
* with that for us so we don't need to take care ourselves.
*/
switch (current_cpu_type()) {
case CPU_20KC:
case CPU_25KF:
case CPU_I6400:
case CPU_I6500:
case CPU_SB1:
case CPU_SB1A:
case CPU_XLR:
c->dcache.flags |= MIPS_CACHE_PINDEX;
break;
case CPU_R10000:
case CPU_R12000:
case CPU_R14000:
case CPU_R16000:
break;
case CPU_74K:
case CPU_1074K:
has_74k_erratum = alias_74k_erratum(c);
/* Fall through. */
case CPU_M14KC:
case CPU_M14KEC:
case CPU_24K:
case CPU_34K:
case CPU_1004K:
case CPU_INTERAPTIV:
case CPU_P5600:
case CPU_PROAPTIV:
case CPU_M5150:
case CPU_QEMU_GENERIC:
case CPU_P6600:
case CPU_M6250:
if (!(read_c0_config7() & MIPS_CONF7_IAR) &&
(c->icache.waysize > PAGE_SIZE))
c->icache.flags |= MIPS_CACHE_ALIASES;
if (!has_74k_erratum && (read_c0_config7() & MIPS_CONF7_AR)) {
/*
* Effectively physically indexed dcache,
* thus no virtual aliases.
*/
c->dcache.flags |= MIPS_CACHE_PINDEX;
break;
}
default:
if (has_74k_erratum || c->dcache.waysize > PAGE_SIZE)
c->dcache.flags |= MIPS_CACHE_ALIASES;
}
/* Physically indexed caches don't suffer from virtual aliasing */
if (c->dcache.flags & MIPS_CACHE_PINDEX)
c->dcache.flags &= ~MIPS_CACHE_ALIASES;
switch (current_cpu_type()) {
case CPU_20KC:
/*
* Some older 20Kc chips doesn't have the 'VI' bit in
* the config register.
*/
c->icache.flags |= MIPS_CACHE_VTAG;
break;
case CPU_ALCHEMY:
case CPU_I6400:
case CPU_I6500:
c->icache.flags |= MIPS_CACHE_IC_F_DC;
break;
case CPU_BMIPS5000:
c->icache.flags |= MIPS_CACHE_IC_F_DC;
/* Cache aliases are handled in hardware; allow HIGHMEM */
c->dcache.flags &= ~MIPS_CACHE_ALIASES;
break;
case CPU_LOONGSON2:
/*
* LOONGSON2 has 4 way icache, but when using indexed cache op,
* one op will act on all 4 ways
*/
c->icache.ways = 1;
}
printk("Primary instruction cache %ldkB, %s, %s, linesize %d bytes.\n",
icache_size >> 10,
c->icache.flags & MIPS_CACHE_VTAG ? "VIVT" : "VIPT",
way_string[c->icache.ways], c->icache.linesz);
printk("Primary data cache %ldkB, %s, %s, %s, linesize %d bytes\n",
dcache_size >> 10, way_string[c->dcache.ways],
(c->dcache.flags & MIPS_CACHE_PINDEX) ? "PIPT" : "VIPT",
(c->dcache.flags & MIPS_CACHE_ALIASES) ?
"cache aliases" : "no aliases",
c->dcache.linesz);
}
static void probe_vcache(void)
{
struct cpuinfo_mips *c = &current_cpu_data;
unsigned int config2, lsize;
if (current_cpu_type() != CPU_LOONGSON3)
return;
config2 = read_c0_config2();
if ((lsize = ((config2 >> 20) & 15)))
c->vcache.linesz = 2 << lsize;
else
c->vcache.linesz = lsize;
c->vcache.sets = 64 << ((config2 >> 24) & 15);
c->vcache.ways = 1 + ((config2 >> 16) & 15);
vcache_size = c->vcache.sets * c->vcache.ways * c->vcache.linesz;
c->vcache.waybit = 0;
c->vcache.waysize = vcache_size / c->vcache.ways;
pr_info("Unified victim cache %ldkB %s, linesize %d bytes.\n",
vcache_size >> 10, way_string[c->vcache.ways], c->vcache.linesz);
}
/*
* If you even _breathe_ on this function, look at the gcc output and make sure
* it does not pop things on and off the stack for the cache sizing loop that
* executes in KSEG1 space or else you will crash and burn badly. You have
* been warned.
*/
static int probe_scache(void)
{
unsigned long flags, addr, begin, end, pow2;
unsigned int config = read_c0_config();
struct cpuinfo_mips *c = &current_cpu_data;
if (config & CONF_SC)
return 0;
begin = (unsigned long) &_stext;
begin &= ~((4 * 1024 * 1024) - 1);
end = begin + (4 * 1024 * 1024);
/*
* This is such a bitch, you'd think they would make it easy to do
* this. Away you daemons of stupidity!
*/
local_irq_save(flags);
/* Fill each size-multiple cache line with a valid tag. */
pow2 = (64 * 1024);
for (addr = begin; addr < end; addr = (begin + pow2)) {
unsigned long *p = (unsigned long *) addr;
__asm__ __volatile__("nop" : : "r" (*p)); /* whee... */
pow2 <<= 1;
}
/* Load first line with zero (therefore invalid) tag. */
write_c0_taglo(0);
write_c0_taghi(0);
__asm__ __volatile__("nop; nop; nop; nop;"); /* avoid the hazard */
cache_op(Index_Store_Tag_I, begin);
cache_op(Index_Store_Tag_D, begin);
cache_op(Index_Store_Tag_SD, begin);
/* Now search for the wrap around point. */
pow2 = (128 * 1024);
for (addr = begin + (128 * 1024); addr < end; addr = begin + pow2) {
cache_op(Index_Load_Tag_SD, addr);
__asm__ __volatile__("nop; nop; nop; nop;"); /* hazard... */
if (!read_c0_taglo())
break;
pow2 <<= 1;
}
local_irq_restore(flags);
addr -= begin;
scache_size = addr;
c->scache.linesz = 16 << ((config & R4K_CONF_SB) >> 22);
c->scache.ways = 1;
c->scache.waybit = 0; /* does not matter */
return 1;
}
static void __init loongson2_sc_init(void)
{
struct cpuinfo_mips *c = &current_cpu_data;
scache_size = 512*1024;
c->scache.linesz = 32;
c->scache.ways = 4;
c->scache.waybit = 0;
c->scache.waysize = scache_size / (c->scache.ways);
c->scache.sets = scache_size / (c->scache.linesz * c->scache.ways);
pr_info("Unified secondary cache %ldkB %s, linesize %d bytes.\n",
scache_size >> 10, way_string[c->scache.ways], c->scache.linesz);
c->options |= MIPS_CPU_INCLUSIVE_CACHES;
}
static void __init loongson3_sc_init(void)
{
struct cpuinfo_mips *c = &current_cpu_data;
unsigned int config2, lsize;
config2 = read_c0_config2();
lsize = (config2 >> 4) & 15;
if (lsize)
c->scache.linesz = 2 << lsize;
else
c->scache.linesz = 0;
c->scache.sets = 64 << ((config2 >> 8) & 15);
c->scache.ways = 1 + (config2 & 15);
scache_size = c->scache.sets *
c->scache.ways *
c->scache.linesz;
/* Loongson-3 has 4 cores, 1MB scache for each. scaches are shared */
scache_size *= 4;
c->scache.waybit = 0;
c->scache.waysize = scache_size / c->scache.ways;
pr_info("Unified secondary cache %ldkB %s, linesize %d bytes.\n",
scache_size >> 10, way_string[c->scache.ways], c->scache.linesz);
if (scache_size)
c->options |= MIPS_CPU_INCLUSIVE_CACHES;
return;
}
extern int r5k_sc_init(void);
extern int rm7k_sc_init(void);
extern int mips_sc_init(void);
static void setup_scache(void)
{
struct cpuinfo_mips *c = &current_cpu_data;
unsigned int config = read_c0_config();
int sc_present = 0;
/*
* Do the probing thing on R4000SC and R4400SC processors. Other
* processors don't have a S-cache that would be relevant to the
* Linux memory management.
*/
switch (current_cpu_type()) {
case CPU_R4000SC:
case CPU_R4000MC:
case CPU_R4400SC:
case CPU_R4400MC:
sc_present = run_uncached(probe_scache);
if (sc_present)
c->options |= MIPS_CPU_CACHE_CDEX_S;
break;
case CPU_R10000:
case CPU_R12000:
case CPU_R14000:
case CPU_R16000:
scache_size = 0x80000 << ((config & R10K_CONF_SS) >> 16);
c->scache.linesz = 64 << ((config >> 13) & 1);
c->scache.ways = 2;
c->scache.waybit= 0;
sc_present = 1;
break;
case CPU_R5000:
case CPU_NEVADA:
#ifdef CONFIG_R5000_CPU_SCACHE
r5k_sc_init();
#endif
return;
case CPU_RM7000:
#ifdef CONFIG_RM7000_CPU_SCACHE
rm7k_sc_init();
#endif
return;
case CPU_LOONGSON2:
loongson2_sc_init();
return;
case CPU_LOONGSON3:
loongson3_sc_init();
return;
case CPU_CAVIUM_OCTEON3:
case CPU_XLP:
/* don't need to worry about L2, fully coherent */
return;
default:
if (c->isa_level & (MIPS_CPU_ISA_M32R1 | MIPS_CPU_ISA_M32R2 |
MIPS_CPU_ISA_M32R6 | MIPS_CPU_ISA_M64R1 |
MIPS_CPU_ISA_M64R2 | MIPS_CPU_ISA_M64R6)) {
#ifdef CONFIG_MIPS_CPU_SCACHE
if (mips_sc_init ()) {
scache_size = c->scache.ways * c->scache.sets * c->scache.linesz;
printk("MIPS secondary cache %ldkB, %s, linesize %d bytes.\n",
scache_size >> 10,
way_string[c->scache.ways], c->scache.linesz);
}
#else
if (!(c->scache.flags & MIPS_CACHE_NOT_PRESENT))
panic("Dunno how to handle MIPS32 / MIPS64 second level cache");
#endif
return;
}
sc_present = 0;
}
if (!sc_present)
return;
/* compute a couple of other cache variables */
c->scache.waysize = scache_size / c->scache.ways;
c->scache.sets = scache_size / (c->scache.linesz * c->scache.ways);
printk("Unified secondary cache %ldkB %s, linesize %d bytes.\n",
scache_size >> 10, way_string[c->scache.ways], c->scache.linesz);
c->options |= MIPS_CPU_INCLUSIVE_CACHES;
}
void au1x00_fixup_config_od(void)
{
/*
* c0_config.od (bit 19) was write only (and read as 0)
* on the early revisions of Alchemy SOCs. It disables the bus
* transaction overlapping and needs to be set to fix various errata.
*/
switch (read_c0_prid()) {
case 0x00030100: /* Au1000 DA */
case 0x00030201: /* Au1000 HA */
case 0x00030202: /* Au1000 HB */
case 0x01030200: /* Au1500 AB */
/*
* Au1100 errata actually keeps silence about this bit, so we set it
* just in case for those revisions that require it to be set according
* to the (now gone) cpu table.
*/
case 0x02030200: /* Au1100 AB */
case 0x02030201: /* Au1100 BA */
case 0x02030202: /* Au1100 BC */
set_c0_config(1 << 19);
break;
}
}
/* CP0 hazard avoidance. */
#define NXP_BARRIER() \
__asm__ __volatile__( \
".set noreorder\n\t" \
"nop; nop; nop; nop; nop; nop;\n\t" \
".set reorder\n\t")
static void nxp_pr4450_fixup_config(void)
{
unsigned long config0;
config0 = read_c0_config();
/* clear all three cache coherency fields */
config0 &= ~(0x7 | (7 << 25) | (7 << 28));
config0 |= (((_page_cachable_default >> _CACHE_SHIFT) << 0) |
((_page_cachable_default >> _CACHE_SHIFT) << 25) |
((_page_cachable_default >> _CACHE_SHIFT) << 28));
write_c0_config(config0);
NXP_BARRIER();
}
static int cca = -1;
static int __init cca_setup(char *str)
{
get_option(&str, &cca);
return 0;
}
early_param("cca", cca_setup);
static void coherency_setup(void)
{
if (cca < 0 || cca > 7)
cca = read_c0_config() & CONF_CM_CMASK;
_page_cachable_default = cca << _CACHE_SHIFT;
pr_debug("Using cache attribute %d\n", cca);
change_c0_config(CONF_CM_CMASK, cca);
/*
* c0_status.cu=0 specifies that updates by the sc instruction use
* the coherency mode specified by the TLB; 1 means cachable
* coherent update on write will be used. Not all processors have
* this bit and; some wire it to zero, others like Toshiba had the
* silly idea of putting something else there ...
*/
switch (current_cpu_type()) {
case CPU_R4000PC:
case CPU_R4000SC:
case CPU_R4000MC:
case CPU_R4400PC:
case CPU_R4400SC:
case CPU_R4400MC:
clear_c0_config(CONF_CU);
break;
/*
* We need to catch the early Alchemy SOCs with
* the write-only co_config.od bit and set it back to one on:
* Au1000 rev DA, HA, HB; Au1100 AB, BA, BC, Au1500 AB
*/
case CPU_ALCHEMY:
au1x00_fixup_config_od();
break;
case PRID_IMP_PR4450:
nxp_pr4450_fixup_config();
break;
}
}
static void r4k_cache_error_setup(void)
{
extern char __weak except_vec2_generic;
extern char __weak except_vec2_sb1;
switch (current_cpu_type()) {
case CPU_SB1:
case CPU_SB1A:
set_uncached_handler(0x100, &except_vec2_sb1, 0x80);
break;
default:
set_uncached_handler(0x100, &except_vec2_generic, 0x80);
break;
}
}
void r4k_cache_init(void)
{
extern void build_clear_page(void);
extern void build_copy_page(void);
struct cpuinfo_mips *c = &current_cpu_data;
probe_pcache();
probe_vcache();
setup_scache();
r4k_blast_dcache_page_setup();
r4k_blast_dcache_page_indexed_setup();
r4k_blast_dcache_setup();
r4k_blast_icache_page_setup();
r4k_blast_icache_page_indexed_setup();
r4k_blast_icache_setup();
r4k_blast_scache_page_setup();
r4k_blast_scache_page_indexed_setup();
r4k_blast_scache_setup();
#ifdef CONFIG_EVA
r4k_blast_dcache_user_page_setup();
r4k_blast_icache_user_page_setup();
#endif
/*
* Some MIPS32 and MIPS64 processors have physically indexed caches.
* This code supports virtually indexed processors and will be
* unnecessarily inefficient on physically indexed processors.
*/
if (c->dcache.linesz && cpu_has_dc_aliases)
shm_align_mask = max_t( unsigned long,
c->dcache.sets * c->dcache.linesz - 1,
PAGE_SIZE - 1);
else
shm_align_mask = PAGE_SIZE-1;
__flush_cache_vmap = r4k__flush_cache_vmap;
__flush_cache_vunmap = r4k__flush_cache_vunmap;
flush_cache_all = cache_noop;
__flush_cache_all = r4k___flush_cache_all;
flush_cache_mm = r4k_flush_cache_mm;
flush_cache_page = r4k_flush_cache_page;
flush_cache_range = r4k_flush_cache_range;
__flush_kernel_vmap_range = r4k_flush_kernel_vmap_range;
flush_cache_sigtramp = r4k_flush_cache_sigtramp;
flush_icache_all = r4k_flush_icache_all;
local_flush_data_cache_page = local_r4k_flush_data_cache_page;
flush_data_cache_page = r4k_flush_data_cache_page;
flush_icache_range = r4k_flush_icache_range;
local_flush_icache_range = local_r4k_flush_icache_range;
__flush_icache_user_range = r4k_flush_icache_user_range;
__local_flush_icache_user_range = local_r4k_flush_icache_user_range;
#if defined(CONFIG_DMA_NONCOHERENT) || defined(CONFIG_DMA_MAYBE_COHERENT)
# if defined(CONFIG_DMA_PERDEV_COHERENT)
if (0) {
# else
if ((coherentio == IO_COHERENCE_ENABLED) ||
((coherentio == IO_COHERENCE_DEFAULT) && hw_coherentio)) {
# endif
_dma_cache_wback_inv = (void *)cache_noop;
_dma_cache_wback = (void *)cache_noop;
_dma_cache_inv = (void *)cache_noop;
} else {
_dma_cache_wback_inv = r4k_dma_cache_wback_inv;
_dma_cache_wback = r4k_dma_cache_wback_inv;
_dma_cache_inv = r4k_dma_cache_inv;
}
#endif
build_clear_page();
build_copy_page();
/*
* We want to run CMP kernels on core with and without coherent
* caches. Therefore, do not use CONFIG_MIPS_CMP to decide whether
* or not to flush caches.
*/
local_r4k___flush_cache_all(NULL);
coherency_setup();
board_cache_error_setup = r4k_cache_error_setup;
/*
* Per-CPU overrides
*/
switch (current_cpu_type()) {
case CPU_BMIPS4350:
case CPU_BMIPS4380:
/* No IPI is needed because all CPUs share the same D$ */
flush_data_cache_page = r4k_blast_dcache_page;
break;
case CPU_BMIPS5000:
/* We lose our superpowers if L2 is disabled */
if (c->scache.flags & MIPS_CACHE_NOT_PRESENT)
break;
/* I$ fills from D$ just by emptying the write buffers */
flush_cache_page = (void *)b5k_instruction_hazard;
flush_cache_range = (void *)b5k_instruction_hazard;
flush_cache_sigtramp = (void *)b5k_instruction_hazard;
local_flush_data_cache_page = (void *)b5k_instruction_hazard;
flush_data_cache_page = (void *)b5k_instruction_hazard;
flush_icache_range = (void *)b5k_instruction_hazard;
local_flush_icache_range = (void *)b5k_instruction_hazard;
/* Optimization: an L2 flush implicitly flushes the L1 */
current_cpu_data.options |= MIPS_CPU_INCLUSIVE_CACHES;
break;
case CPU_LOONGSON3:
/* Loongson-3 maintains cache coherency by hardware */
__flush_cache_all = cache_noop;
__flush_cache_vmap = cache_noop;
__flush_cache_vunmap = cache_noop;
__flush_kernel_vmap_range = (void *)cache_noop;
flush_cache_mm = (void *)cache_noop;
flush_cache_page = (void *)cache_noop;
flush_cache_range = (void *)cache_noop;
flush_cache_sigtramp = (void *)cache_noop;
flush_icache_all = (void *)cache_noop;
flush_data_cache_page = (void *)cache_noop;
local_flush_data_cache_page = (void *)cache_noop;
break;
}
}
static int r4k_cache_pm_notifier(struct notifier_block *self, unsigned long cmd,
void *v)
{
switch (cmd) {
case CPU_PM_ENTER_FAILED:
case CPU_PM_EXIT:
coherency_setup();
break;
}
return NOTIFY_OK;
}
static struct notifier_block r4k_cache_pm_notifier_block = {
.notifier_call = r4k_cache_pm_notifier,
};
int __init r4k_cache_init_pm(void)
{
return cpu_pm_register_notifier(&r4k_cache_pm_notifier_block);
}
arch_initcall(r4k_cache_init_pm);