@@ -1,7 +1,7 @@
/******************************************************************************
* arch/x86/mm/p2m-pod.c
*
- * Populate-on-demand p2m entries.
+ * Populate-on-demand p2m entries.
*
* Copyright (c) 2009-2011 Citrix Systems, Inc.
*
@@ -76,7 +76,7 @@ p2m_pod_cache_add(struct p2m_domain *p2m,
__func__, mfn_x(mfn), order, ((1UL << order) - 1));
return -1;
}
-
+
for(i=0; i < 1 << order ; i++) {
struct domain * od;
@@ -223,8 +223,8 @@ p2m_pod_set_cache_target(struct p2m_domain *p2m, unsigned long pod_target, int p
/* If we can't allocate a superpage, try singleton pages */
order = PAGE_ORDER_4K;
goto retry;
- }
-
+ }
+
printk("%s: Unable to allocate page for PoD cache (target=%lu cache=%ld)\n",
__func__, pod_target, p2m->pod.count);
ret = -ENOMEM;
@@ -272,7 +272,7 @@ p2m_pod_set_cache_target(struct p2m_domain *p2m, unsigned long pod_target, int p
if ( test_and_clear_bit(_PGT_pinned, &(page+i)->u.inuse.type_info) )
put_page_and_type(page+i);
-
+
if ( test_and_clear_bit(_PGC_allocated, &(page+i)->count_info) )
put_page(page+i);
@@ -296,7 +296,7 @@ out:
* definitions:
* + M: static_max
* + B: number of pages the balloon driver has ballooned down to.
- * + P: Number of populated pages.
+ * + P: Number of populated pages.
* + T: Old target
* + T': New target
*
@@ -311,10 +311,10 @@ out:
* the remainder of the ram to the guest OS.
* T <T'<B : Increase PoD cache size.
* T'<T<=B : Here we have a choice. We can decrease the size of the cache,
- * get the memory right away. However, that means every time we
- * reduce the memory target we risk the guest attempting to populate the
+ * get the memory right away. However, that means every time we
+ * reduce the memory target we risk the guest attempting to populate the
* memory before the balloon driver has reached its new target. Safer to
- * never reduce the cache size here, but only when the balloon driver frees
+ * never reduce the cache size here, but only when the balloon driver frees
* PoD ranges.
*
* If there are many zero pages, we could reach the target also by doing
@@ -511,7 +511,7 @@ p2m_pod_decrease_reservation(struct domain *d,
long pod, nonpod, ram;
gfn_lock(p2m, gpfn, order);
- pod_lock(p2m);
+ pod_lock(p2m);
/* If we don't have any outstanding PoD entries, let things take their
* course */
@@ -629,7 +629,7 @@ p2m_pod_decrease_reservation(struct domain *d,
nonpod -= n;
ram -= n;
}
- }
+ }
/* If there are no more non-PoD entries, tell decrease_reservation() that
* there's nothing left to do. */
@@ -682,7 +682,7 @@ p2m_pod_zero_check_superpage(struct p2m_domain *p2m, unsigned long gfn)
if ( paging_mode_shadow(d) )
max_ref++;
- /* NOTE: this is why we don't enforce deadlock constraints between p2m
+ /* NOTE: this is why we don't enforce deadlock constraints between p2m
* and pod locks */
gfn_lock(p2m, gfn, SUPERPAGE_ORDER);
@@ -690,7 +690,7 @@ p2m_pod_zero_check_superpage(struct p2m_domain *p2m, unsigned long gfn)
* and aligned, and mapping them. */
for ( i = 0; i < SUPERPAGE_PAGES; i += n )
{
- p2m_access_t a;
+ p2m_access_t a;
unsigned int cur_order;
unsigned long k;
const struct page_info *page;
@@ -807,7 +807,7 @@ p2m_pod_zero_check_superpage(struct p2m_domain *p2m, unsigned long gfn)
out_reset:
if ( reset )
p2m_set_entry(p2m, gfn, mfn0, 9, type0, p2m->default_access);
-
+
out:
gfn_unlock(p2m, gfn, SUPERPAGE_ORDER);
return ret;
@@ -836,8 +836,8 @@ p2m_pod_zero_check(struct p2m_domain *p2m, unsigned long *gfns, int count)
/* If this is ram, and not a pagetable or from the xen heap, and probably not mapped
elsewhere, map it; otherwise, skip. */
if ( p2m_is_ram(types[i])
- && ( (mfn_to_page(mfns[i])->count_info & PGC_allocated) != 0 )
- && ( (mfn_to_page(mfns[i])->count_info & (PGC_page_table|PGC_xen_heap)) == 0 )
+ && ( (mfn_to_page(mfns[i])->count_info & PGC_allocated) != 0 )
+ && ( (mfn_to_page(mfns[i])->count_info & (PGC_page_table|PGC_xen_heap)) == 0 )
&& ( (mfn_to_page(mfns[i])->count_info & PGC_count_mask) <= max_ref ) )
map[i] = map_domain_page(mfns[i]);
else
@@ -915,7 +915,7 @@ p2m_pod_zero_check(struct p2m_domain *p2m, unsigned long *gfns, int count)
t.mfn = mfn_x(mfns[i]);
t.d = d->domain_id;
t.order = 0;
-
+
__trace_var(TRC_MEM_POD_ZERO_RECLAIM, 0, sizeof(t), &t);
}
@@ -924,7 +924,7 @@ p2m_pod_zero_check(struct p2m_domain *p2m, unsigned long *gfns, int count)
p2m->pod.entry_count++;
}
}
-
+
}
#define POD_SWEEP_LIMIT 1024
@@ -1046,12 +1046,12 @@ p2m_pod_demand_populate(struct p2m_domain *p2m, unsigned long gfn,
pod_lock(p2m);
/* This check is done with the pod lock held. This will make sure that
- * even if d->is_dying changes under our feet, p2m_pod_empty_cache()
+ * even if d->is_dying changes under our feet, p2m_pod_empty_cache()
* won't start until we're done. */
if ( unlikely(d->is_dying) )
goto out_fail;
-
+
/* Because PoD does not have cache list for 1GB pages, it has to remap
* 1GB region to 2MB chunks for a retry. */
if ( order == PAGE_ORDER_1G )
@@ -1107,7 +1107,7 @@ p2m_pod_demand_populate(struct p2m_domain *p2m, unsigned long gfn,
set_gpfn_from_mfn(mfn_x(mfn) + i, gfn_aligned + i);
paging_mark_dirty(d, mfn_add(mfn, i));
}
-
+
p2m->pod.entry_count -= (1 << order);
BUG_ON(p2m->pod.entry_count < 0);
@@ -1124,7 +1124,7 @@ p2m_pod_demand_populate(struct p2m_domain *p2m, unsigned long gfn,
t.mfn = mfn_x(mfn);
t.d = d->domain_id;
t.order = order;
-
+
__trace_var(TRC_MEM_POD_POPULATE, 0, sizeof(t), &t);
}
@@ -1161,7 +1161,7 @@ remap_and_retry:
t.gfn = gfn;
t.d = d->domain_id;
-
+
__trace_var(TRC_MEM_POD_SUPERPAGE_SPLINTER, 0, sizeof(t), &t);
}