linux/arch/sparc/mm/tsb.c
David S. Miller f36391d279 sparc64: Fix race in TLB batch processing.
As reported by Dave Kleikamp, when we emit cross calls to do batched
TLB flush processing we have a race because we do not synchronize on
the sibling cpus completing the cross call.

So meanwhile the TLB batch can be reset (tb->tlb_nr set to zero, etc.)
and either flushes are missed or flushes will flush the wrong
addresses.

Fix this by using generic infrastructure to synchonize on the
completion of the cross call.

This first required getting the flush_tlb_pending() call out from
switch_to() which operates with locks held and interrupts disabled.
The problem is that smp_call_function_many() cannot be invoked with
IRQs disabled and this is explicitly checked for with WARN_ON_ONCE().

We get the batch processing outside of locked IRQ disabled sections by
using some ideas from the powerpc port. Namely, we only batch inside
of arch_{enter,leave}_lazy_mmu_mode() calls.  If we're not in such a
region, we flush TLBs synchronously.

1) Get rid of xcall_flush_tlb_pending and per-cpu type
   implementations.

2) Do TLB batch cross calls instead via:

	smp_call_function_many()
		tlb_pending_func()
			__flush_tlb_pending()

3) Batch only in lazy mmu sequences:

	a) Add 'active' member to struct tlb_batch
	b) Define __HAVE_ARCH_ENTER_LAZY_MMU_MODE
	c) Set 'active' in arch_enter_lazy_mmu_mode()
	d) Run batch and clear 'active' in arch_leave_lazy_mmu_mode()
	e) Check 'active' in tlb_batch_add_one() and do a synchronous
           flush if it's clear.

4) Add infrastructure for synchronous TLB page flushes.

	a) Implement __flush_tlb_page and per-cpu variants, patch
	   as needed.
	b) Likewise for xcall_flush_tlb_page.
	c) Implement smp_flush_tlb_page() to invoke the cross-call.
	d) Wire up global_flush_tlb_page() to the right routine based
           upon CONFIG_SMP

5) It turns out that singleton batches are very common, 2 out of every
   3 batch flushes have only a single entry in them.

   The batch flush waiting is very expensive, both because of the poll
   on sibling cpu completeion, as well as because passing the tlb batch
   pointer to the sibling cpus invokes a shared memory dereference.

   Therefore, in flush_tlb_pending(), if there is only one entry in
   the batch perform a completely asynchronous global_flush_tlb_page()
   instead.

Reported-by: Dave Kleikamp <dave.kleikamp@oracle.com>
Signed-off-by: David S. Miller <davem@davemloft.net>
Acked-by: Dave Kleikamp <dave.kleikamp@oracle.com>
2013-04-19 17:26:26 -04:00

534 lines
14 KiB
C

/* arch/sparc64/mm/tsb.c
*
* Copyright (C) 2006, 2008 David S. Miller <davem@davemloft.net>
*/
#include <linux/kernel.h>
#include <linux/preempt.h>
#include <linux/slab.h>
#include <asm/page.h>
#include <asm/pgtable.h>
#include <asm/mmu_context.h>
#include <asm/tsb.h>
#include <asm/tlb.h>
#include <asm/oplib.h>
extern struct tsb swapper_tsb[KERNEL_TSB_NENTRIES];
static inline unsigned long tsb_hash(unsigned long vaddr, unsigned long hash_shift, unsigned long nentries)
{
vaddr >>= hash_shift;
return vaddr & (nentries - 1);
}
static inline int tag_compare(unsigned long tag, unsigned long vaddr)
{
return (tag == (vaddr >> 22));
}
/* TSB flushes need only occur on the processor initiating the address
* space modification, not on each cpu the address space has run on.
* Only the TLB flush needs that treatment.
*/
void flush_tsb_kernel_range(unsigned long start, unsigned long end)
{
unsigned long v;
for (v = start; v < end; v += PAGE_SIZE) {
unsigned long hash = tsb_hash(v, PAGE_SHIFT,
KERNEL_TSB_NENTRIES);
struct tsb *ent = &swapper_tsb[hash];
if (tag_compare(ent->tag, v))
ent->tag = (1UL << TSB_TAG_INVALID_BIT);
}
}
static void __flush_tsb_one_entry(unsigned long tsb, unsigned long v,
unsigned long hash_shift,
unsigned long nentries)
{
unsigned long tag, ent, hash;
v &= ~0x1UL;
hash = tsb_hash(v, hash_shift, nentries);
ent = tsb + (hash * sizeof(struct tsb));
tag = (v >> 22UL);
tsb_flush(ent, tag);
}
static void __flush_tsb_one(struct tlb_batch *tb, unsigned long hash_shift,
unsigned long tsb, unsigned long nentries)
{
unsigned long i;
for (i = 0; i < tb->tlb_nr; i++)
__flush_tsb_one_entry(tsb, tb->vaddrs[i], hash_shift, nentries);
}
void flush_tsb_user(struct tlb_batch *tb)
{
struct mm_struct *mm = tb->mm;
unsigned long nentries, base, flags;
spin_lock_irqsave(&mm->context.lock, flags);
base = (unsigned long) mm->context.tsb_block[MM_TSB_BASE].tsb;
nentries = mm->context.tsb_block[MM_TSB_BASE].tsb_nentries;
if (tlb_type == cheetah_plus || tlb_type == hypervisor)
base = __pa(base);
__flush_tsb_one(tb, PAGE_SHIFT, base, nentries);
#if defined(CONFIG_HUGETLB_PAGE) || defined(CONFIG_TRANSPARENT_HUGEPAGE)
if (mm->context.tsb_block[MM_TSB_HUGE].tsb) {
base = (unsigned long) mm->context.tsb_block[MM_TSB_HUGE].tsb;
nentries = mm->context.tsb_block[MM_TSB_HUGE].tsb_nentries;
if (tlb_type == cheetah_plus || tlb_type == hypervisor)
base = __pa(base);
__flush_tsb_one(tb, HPAGE_SHIFT, base, nentries);
}
#endif
spin_unlock_irqrestore(&mm->context.lock, flags);
}
void flush_tsb_user_page(struct mm_struct *mm, unsigned long vaddr)
{
unsigned long nentries, base, flags;
spin_lock_irqsave(&mm->context.lock, flags);
base = (unsigned long) mm->context.tsb_block[MM_TSB_BASE].tsb;
nentries = mm->context.tsb_block[MM_TSB_BASE].tsb_nentries;
if (tlb_type == cheetah_plus || tlb_type == hypervisor)
base = __pa(base);
__flush_tsb_one_entry(base, vaddr, PAGE_SHIFT, nentries);
#if defined(CONFIG_HUGETLB_PAGE) || defined(CONFIG_TRANSPARENT_HUGEPAGE)
if (mm->context.tsb_block[MM_TSB_HUGE].tsb) {
base = (unsigned long) mm->context.tsb_block[MM_TSB_HUGE].tsb;
nentries = mm->context.tsb_block[MM_TSB_HUGE].tsb_nentries;
if (tlb_type == cheetah_plus || tlb_type == hypervisor)
base = __pa(base);
__flush_tsb_one_entry(base, vaddr, HPAGE_SHIFT, nentries);
}
#endif
spin_unlock_irqrestore(&mm->context.lock, flags);
}
#define HV_PGSZ_IDX_BASE HV_PGSZ_IDX_8K
#define HV_PGSZ_MASK_BASE HV_PGSZ_MASK_8K
#if defined(CONFIG_HUGETLB_PAGE) || defined(CONFIG_TRANSPARENT_HUGEPAGE)
#define HV_PGSZ_IDX_HUGE HV_PGSZ_IDX_4MB
#define HV_PGSZ_MASK_HUGE HV_PGSZ_MASK_4MB
#endif
static void setup_tsb_params(struct mm_struct *mm, unsigned long tsb_idx, unsigned long tsb_bytes)
{
unsigned long tsb_reg, base, tsb_paddr;
unsigned long page_sz, tte;
mm->context.tsb_block[tsb_idx].tsb_nentries =
tsb_bytes / sizeof(struct tsb);
base = TSBMAP_BASE;
tte = pgprot_val(PAGE_KERNEL_LOCKED);
tsb_paddr = __pa(mm->context.tsb_block[tsb_idx].tsb);
BUG_ON(tsb_paddr & (tsb_bytes - 1UL));
/* Use the smallest page size that can map the whole TSB
* in one TLB entry.
*/
switch (tsb_bytes) {
case 8192 << 0:
tsb_reg = 0x0UL;
#ifdef DCACHE_ALIASING_POSSIBLE
base += (tsb_paddr & 8192);
#endif
page_sz = 8192;
break;
case 8192 << 1:
tsb_reg = 0x1UL;
page_sz = 64 * 1024;
break;
case 8192 << 2:
tsb_reg = 0x2UL;
page_sz = 64 * 1024;
break;
case 8192 << 3:
tsb_reg = 0x3UL;
page_sz = 64 * 1024;
break;
case 8192 << 4:
tsb_reg = 0x4UL;
page_sz = 512 * 1024;
break;
case 8192 << 5:
tsb_reg = 0x5UL;
page_sz = 512 * 1024;
break;
case 8192 << 6:
tsb_reg = 0x6UL;
page_sz = 512 * 1024;
break;
case 8192 << 7:
tsb_reg = 0x7UL;
page_sz = 4 * 1024 * 1024;
break;
default:
printk(KERN_ERR "TSB[%s:%d]: Impossible TSB size %lu, killing process.\n",
current->comm, current->pid, tsb_bytes);
do_exit(SIGSEGV);
}
tte |= pte_sz_bits(page_sz);
if (tlb_type == cheetah_plus || tlb_type == hypervisor) {
/* Physical mapping, no locked TLB entry for TSB. */
tsb_reg |= tsb_paddr;
mm->context.tsb_block[tsb_idx].tsb_reg_val = tsb_reg;
mm->context.tsb_block[tsb_idx].tsb_map_vaddr = 0;
mm->context.tsb_block[tsb_idx].tsb_map_pte = 0;
} else {
tsb_reg |= base;
tsb_reg |= (tsb_paddr & (page_sz - 1UL));
tte |= (tsb_paddr & ~(page_sz - 1UL));
mm->context.tsb_block[tsb_idx].tsb_reg_val = tsb_reg;
mm->context.tsb_block[tsb_idx].tsb_map_vaddr = base;
mm->context.tsb_block[tsb_idx].tsb_map_pte = tte;
}
/* Setup the Hypervisor TSB descriptor. */
if (tlb_type == hypervisor) {
struct hv_tsb_descr *hp = &mm->context.tsb_descr[tsb_idx];
switch (tsb_idx) {
case MM_TSB_BASE:
hp->pgsz_idx = HV_PGSZ_IDX_BASE;
break;
#if defined(CONFIG_HUGETLB_PAGE) || defined(CONFIG_TRANSPARENT_HUGEPAGE)
case MM_TSB_HUGE:
hp->pgsz_idx = HV_PGSZ_IDX_HUGE;
break;
#endif
default:
BUG();
}
hp->assoc = 1;
hp->num_ttes = tsb_bytes / 16;
hp->ctx_idx = 0;
switch (tsb_idx) {
case MM_TSB_BASE:
hp->pgsz_mask = HV_PGSZ_MASK_BASE;
break;
#if defined(CONFIG_HUGETLB_PAGE) || defined(CONFIG_TRANSPARENT_HUGEPAGE)
case MM_TSB_HUGE:
hp->pgsz_mask = HV_PGSZ_MASK_HUGE;
break;
#endif
default:
BUG();
}
hp->tsb_base = tsb_paddr;
hp->resv = 0;
}
}
struct kmem_cache *pgtable_cache __read_mostly;
static struct kmem_cache *tsb_caches[8] __read_mostly;
static const char *tsb_cache_names[8] = {
"tsb_8KB",
"tsb_16KB",
"tsb_32KB",
"tsb_64KB",
"tsb_128KB",
"tsb_256KB",
"tsb_512KB",
"tsb_1MB",
};
void __init pgtable_cache_init(void)
{
unsigned long i;
pgtable_cache = kmem_cache_create("pgtable_cache",
PAGE_SIZE, PAGE_SIZE,
0,
_clear_page);
if (!pgtable_cache) {
prom_printf("pgtable_cache_init(): Could not create!\n");
prom_halt();
}
for (i = 0; i < 8; i++) {
unsigned long size = 8192 << i;
const char *name = tsb_cache_names[i];
tsb_caches[i] = kmem_cache_create(name,
size, size,
0, NULL);
if (!tsb_caches[i]) {
prom_printf("Could not create %s cache\n", name);
prom_halt();
}
}
}
int sysctl_tsb_ratio = -2;
static unsigned long tsb_size_to_rss_limit(unsigned long new_size)
{
unsigned long num_ents = (new_size / sizeof(struct tsb));
if (sysctl_tsb_ratio < 0)
return num_ents - (num_ents >> -sysctl_tsb_ratio);
else
return num_ents + (num_ents >> sysctl_tsb_ratio);
}
/* When the RSS of an address space exceeds tsb_rss_limit for a TSB,
* do_sparc64_fault() invokes this routine to try and grow it.
*
* When we reach the maximum TSB size supported, we stick ~0UL into
* tsb_rss_limit for that TSB so the grow checks in do_sparc64_fault()
* will not trigger any longer.
*
* The TSB can be anywhere from 8K to 1MB in size, in increasing powers
* of two. The TSB must be aligned to it's size, so f.e. a 512K TSB
* must be 512K aligned. It also must be physically contiguous, so we
* cannot use vmalloc().
*
* The idea here is to grow the TSB when the RSS of the process approaches
* the number of entries that the current TSB can hold at once. Currently,
* we trigger when the RSS hits 3/4 of the TSB capacity.
*/
void tsb_grow(struct mm_struct *mm, unsigned long tsb_index, unsigned long rss)
{
unsigned long max_tsb_size = 1 * 1024 * 1024;
unsigned long new_size, old_size, flags;
struct tsb *old_tsb, *new_tsb;
unsigned long new_cache_index, old_cache_index;
unsigned long new_rss_limit;
gfp_t gfp_flags;
if (max_tsb_size > (PAGE_SIZE << MAX_ORDER))
max_tsb_size = (PAGE_SIZE << MAX_ORDER);
new_cache_index = 0;
for (new_size = 8192; new_size < max_tsb_size; new_size <<= 1UL) {
new_rss_limit = tsb_size_to_rss_limit(new_size);
if (new_rss_limit > rss)
break;
new_cache_index++;
}
if (new_size == max_tsb_size)
new_rss_limit = ~0UL;
retry_tsb_alloc:
gfp_flags = GFP_KERNEL;
if (new_size > (PAGE_SIZE * 2))
gfp_flags |= __GFP_NOWARN | __GFP_NORETRY;
new_tsb = kmem_cache_alloc_node(tsb_caches[new_cache_index],
gfp_flags, numa_node_id());
if (unlikely(!new_tsb)) {
/* Not being able to fork due to a high-order TSB
* allocation failure is very bad behavior. Just back
* down to a 0-order allocation and force no TSB
* growing for this address space.
*/
if (mm->context.tsb_block[tsb_index].tsb == NULL &&
new_cache_index > 0) {
new_cache_index = 0;
new_size = 8192;
new_rss_limit = ~0UL;
goto retry_tsb_alloc;
}
/* If we failed on a TSB grow, we are under serious
* memory pressure so don't try to grow any more.
*/
if (mm->context.tsb_block[tsb_index].tsb != NULL)
mm->context.tsb_block[tsb_index].tsb_rss_limit = ~0UL;
return;
}
/* Mark all tags as invalid. */
tsb_init(new_tsb, new_size);
/* Ok, we are about to commit the changes. If we are
* growing an existing TSB the locking is very tricky,
* so WATCH OUT!
*
* We have to hold mm->context.lock while committing to the
* new TSB, this synchronizes us with processors in
* flush_tsb_user() and switch_mm() for this address space.
*
* But even with that lock held, processors run asynchronously
* accessing the old TSB via TLB miss handling. This is OK
* because those actions are just propagating state from the
* Linux page tables into the TSB, page table mappings are not
* being changed. If a real fault occurs, the processor will
* synchronize with us when it hits flush_tsb_user(), this is
* also true for the case where vmscan is modifying the page
* tables. The only thing we need to be careful with is to
* skip any locked TSB entries during copy_tsb().
*
* When we finish committing to the new TSB, we have to drop
* the lock and ask all other cpus running this address space
* to run tsb_context_switch() to see the new TSB table.
*/
spin_lock_irqsave(&mm->context.lock, flags);
old_tsb = mm->context.tsb_block[tsb_index].tsb;
old_cache_index =
(mm->context.tsb_block[tsb_index].tsb_reg_val & 0x7UL);
old_size = (mm->context.tsb_block[tsb_index].tsb_nentries *
sizeof(struct tsb));
/* Handle multiple threads trying to grow the TSB at the same time.
* One will get in here first, and bump the size and the RSS limit.
* The others will get in here next and hit this check.
*/
if (unlikely(old_tsb &&
(rss < mm->context.tsb_block[tsb_index].tsb_rss_limit))) {
spin_unlock_irqrestore(&mm->context.lock, flags);
kmem_cache_free(tsb_caches[new_cache_index], new_tsb);
return;
}
mm->context.tsb_block[tsb_index].tsb_rss_limit = new_rss_limit;
if (old_tsb) {
extern void copy_tsb(unsigned long old_tsb_base,
unsigned long old_tsb_size,
unsigned long new_tsb_base,
unsigned long new_tsb_size);
unsigned long old_tsb_base = (unsigned long) old_tsb;
unsigned long new_tsb_base = (unsigned long) new_tsb;
if (tlb_type == cheetah_plus || tlb_type == hypervisor) {
old_tsb_base = __pa(old_tsb_base);
new_tsb_base = __pa(new_tsb_base);
}
copy_tsb(old_tsb_base, old_size, new_tsb_base, new_size);
}
mm->context.tsb_block[tsb_index].tsb = new_tsb;
setup_tsb_params(mm, tsb_index, new_size);
spin_unlock_irqrestore(&mm->context.lock, flags);
/* If old_tsb is NULL, we're being invoked for the first time
* from init_new_context().
*/
if (old_tsb) {
/* Reload it on the local cpu. */
tsb_context_switch(mm);
/* Now force other processors to do the same. */
preempt_disable();
smp_tsb_sync(mm);
preempt_enable();
/* Now it is safe to free the old tsb. */
kmem_cache_free(tsb_caches[old_cache_index], old_tsb);
}
}
int init_new_context(struct task_struct *tsk, struct mm_struct *mm)
{
#if defined(CONFIG_HUGETLB_PAGE) || defined(CONFIG_TRANSPARENT_HUGEPAGE)
unsigned long huge_pte_count;
#endif
unsigned int i;
spin_lock_init(&mm->context.lock);
mm->context.sparc64_ctx_val = 0UL;
#if defined(CONFIG_HUGETLB_PAGE) || defined(CONFIG_TRANSPARENT_HUGEPAGE)
/* We reset it to zero because the fork() page copying
* will re-increment the counters as the parent PTEs are
* copied into the child address space.
*/
huge_pte_count = mm->context.huge_pte_count;
mm->context.huge_pte_count = 0;
#endif
mm->context.pgtable_page = NULL;
/* copy_mm() copies over the parent's mm_struct before calling
* us, so we need to zero out the TSB pointer or else tsb_grow()
* will be confused and think there is an older TSB to free up.
*/
for (i = 0; i < MM_NUM_TSBS; i++)
mm->context.tsb_block[i].tsb = NULL;
/* If this is fork, inherit the parent's TSB size. We would
* grow it to that size on the first page fault anyways.
*/
tsb_grow(mm, MM_TSB_BASE, get_mm_rss(mm));
#if defined(CONFIG_HUGETLB_PAGE) || defined(CONFIG_TRANSPARENT_HUGEPAGE)
if (unlikely(huge_pte_count))
tsb_grow(mm, MM_TSB_HUGE, huge_pte_count);
#endif
if (unlikely(!mm->context.tsb_block[MM_TSB_BASE].tsb))
return -ENOMEM;
return 0;
}
static void tsb_destroy_one(struct tsb_config *tp)
{
unsigned long cache_index;
if (!tp->tsb)
return;
cache_index = tp->tsb_reg_val & 0x7UL;
kmem_cache_free(tsb_caches[cache_index], tp->tsb);
tp->tsb = NULL;
tp->tsb_reg_val = 0UL;
}
void destroy_context(struct mm_struct *mm)
{
unsigned long flags, i;
struct page *page;
for (i = 0; i < MM_NUM_TSBS; i++)
tsb_destroy_one(&mm->context.tsb_block[i]);
page = mm->context.pgtable_page;
if (page && put_page_testzero(page)) {
pgtable_page_dtor(page);
free_hot_cold_page(page, 0);
}
spin_lock_irqsave(&ctx_alloc_lock, flags);
if (CTX_VALID(mm->context)) {
unsigned long nr = CTX_NRBITS(mm->context);
mmu_context_bmap[nr>>6] &= ~(1UL << (nr & 63));
}
spin_unlock_irqrestore(&ctx_alloc_lock, flags);
}