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[Date Prev][Date Next][Thread Prev][Thread Next][Date Index][Thread Index] [Xen-devel] [PATCH 2/6] xen: add per-node bucks to page allocator
This patch adds a per-node bucket to the heap structure in Xen. During
heap initialization the patch determines which bucket to place the
memory. We reserve guard pages between node boundaries in the case that
said boundary isn't already guarded by the MAX_ORDER boundary to prevent
the buddy allocator from merging pages between nodes.
--
Ryan Harper
Software Engineer; Linux Technology Center
IBM Corp., Austin, Tx
(512) 838-9253 T/L: 678-9253
ryanh@xxxxxxxxxx
diffstat output:
common/page_alloc.c | 211 +++++++++++++++++++++++++++++++++++++++++-----------
include/xen/mm.h | 7 +
2 files changed, 173 insertions(+), 45 deletions(-)
Signed-off-by: Ryan Harper <ryanh@xxxxxxxxxx>
---
NUMA-ify Xen heap and page allocator
diff -r e87b07e5fddd xen/common/page_alloc.c
--- a/xen/common/page_alloc.c Tue Aug 15 11:36:36 2006 -0500
+++ b/xen/common/page_alloc.c Tue Aug 15 11:37:51 2006 -0500
@@ -4,6 +4,7 @@
* Simple buddy heap allocator for Xen.
*
* Copyright (c) 2002-2004 K A Fraser
+ * Copyright (c) 2006 IBM Ryan Harper <ryanh@xxxxxxxxxx>
*
* This program is free software; you can redistribute it and/or modify
* it under the terms of the GNU General Public License as published by
@@ -34,6 +35,8 @@
#include <xen/keyhandler.h>
#include <xen/perfc.h>
#include <asm/page.h>
+#include <asm/numa.h>
+#include <asm/topology.h>
/*
* Comma-separated list of hexadecimal page numbers containing bad bytes.
@@ -247,22 +250,23 @@ unsigned long alloc_boot_pages(unsigned
#define pfn_dom_zone_type(_pfn) \
(((_pfn) <= MAX_DMADOM_PFN) ? MEMZONE_DMADOM : MEMZONE_DOM)
-static struct list_head heap[NR_ZONES][MAX_ORDER+1];
-
-static unsigned long avail[NR_ZONES];
+static struct list_head heap[NR_ZONES][MAX_NUMNODES][MAX_ORDER+1];
+
+static unsigned long avail[NR_ZONES][MAX_NUMNODES];
static DEFINE_SPINLOCK(heap_lock);
void end_boot_allocator(void)
{
- unsigned long i, j;
+ unsigned long i, j, k;
int curr_free = 0, next_free = 0;
memset(avail, 0, sizeof(avail));
for ( i = 0; i < NR_ZONES; i++ )
- for ( j = 0; j <= MAX_ORDER; j++ )
- INIT_LIST_HEAD(&heap[i][j]);
+ for ( j = 0; j < MAX_NUMNODES; j++ )
+ for ( k = 0; k <= MAX_ORDER; k++ )
+ INIT_LIST_HEAD(&heap[i][j][k]);
/* Pages that are free now go to the domain sub-allocator. */
for ( i = 0; i < max_page; i++ )
@@ -272,29 +276,59 @@ void end_boot_allocator(void)
if ( next_free )
map_alloc(i+1, 1); /* prevent merging in free_heap_pages() */
if ( curr_free )
- free_heap_pages(pfn_dom_zone_type(i), mfn_to_page(i), 0);
- }
-}
-
-/* Hand the specified arbitrary page range to the specified heap zone. */
+ init_heap_pages(pfn_dom_zone_type(i), mfn_to_page(i), 1);
+ }
+}
+
+/*
+ * Hand the specified arbitrary page range to the specified heap zone
+ * checking the node_id of the previous page. If they differ and the
+ * latter is not on a MAX_ORDER boundary, then we reserve the page by
+ * not freeing it to the buddy allocator.
+ */
+#define MAX_ORDER_ALIGNED (1UL << (MAX_ORDER))
void init_heap_pages(
unsigned int zone, struct page_info *pg, unsigned long nr_pages)
{
+ unsigned int nid_curr,nid_prev;
unsigned long i;
ASSERT(zone < NR_ZONES);
+ if ( likely(page_to_mfn(pg) != 0) )
+ nid_prev = phys_to_nid(page_to_maddr(pg-1));
+ else
+ nid_prev = phys_to_nid(page_to_maddr(pg));
+
for ( i = 0; i < nr_pages; i++ )
- free_heap_pages(zone, pg+i, 0);
-}
-
+ {
+ nid_curr = phys_to_nid(page_to_maddr(pg+i));
+
+ /*
+ * free pages of the same node, or if they differ, but are on a
+ * MAX_ORDER alignement boundary (which already get reserved)
+ */
+ if ( (nid_curr == nid_prev) || (page_to_maddr(pg+i) &
+ MAX_ORDER_ALIGNED) )
+ free_heap_pages(zone, pg+i, 0);
+ else
+ printk("Reserving non-aligned node boundary @ mfn %lu\n",
+ page_to_mfn(pg+i));
+
+ nid_prev = nid_curr;
+ }
+}
/* Allocate 2^@order contiguous pages. */
-struct page_info *alloc_heap_pages(unsigned int zone, unsigned int order)
-{
- int i;
+struct page_info *alloc_heap_pages(unsigned int zone, unsigned int cpu,
+ unsigned int order)
+{
+ unsigned int i,j, node = cpu_to_node(cpu), num_nodes = num_online_nodes();
+ unsigned int request = (1UL << order);
struct page_info *pg;
+ ASSERT(node >= 0);
+ ASSERT(node < num_nodes);
ASSERT(zone < NR_ZONES);
if ( unlikely(order > MAX_ORDER) )
@@ -302,29 +336,46 @@ struct page_info *alloc_heap_pages(unsig
spin_lock(&heap_lock);
- /* Find smallest order which can satisfy the request. */
- for ( i = order; i <= MAX_ORDER; i++ )
- if ( !list_empty(&heap[zone][i]) )
- goto found;
+ /* start with requested node, but exhaust all node memory
+ * in requested zone before failing, only calc new node
+ * value if we fail to find memory in target node, this avoids
+ * needless computation on fast-path */
+ for ( i = 0; i < num_nodes; i++ )
+ {
+ /* check if target node can support the allocation */
+ if ( avail[zone][node] >= request )
+ {
+ /* Find smallest order which can satisfy the request. */
+ for ( j = order; j <= MAX_ORDER; j++ )
+ {
+ if ( !list_empty(&heap[zone][node][j]) )
+ goto found;
+ }
+ }
+ /* pick next node, wrapping around if needed */
+ if ( ++node == num_nodes )
+ node = 0;
+ }
/* No suitable memory blocks. Fail the request. */
spin_unlock(&heap_lock);
return NULL;
found:
- pg = list_entry(heap[zone][i].next, struct page_info, list);
+ pg = list_entry(heap[zone][node][j].next, struct page_info, list);
list_del(&pg->list);
/* We may have to halve the chunk a number of times. */
- while ( i != order )
- {
- PFN_ORDER(pg) = --i;
- list_add_tail(&pg->list, &heap[zone][i]);
- pg += 1 << i;
+ while ( j != order )
+ {
+ PFN_ORDER(pg) = --j;
+ list_add_tail(&pg->list, &heap[zone][node][j]);
+ pg += 1 << j;
}
- map_alloc(page_to_mfn(pg), 1 << order);
- avail[zone] -= 1 << order;
+ map_alloc(page_to_mfn(pg), request);
+ ASSERT(avail[zone][node] >= request);
+ avail[zone][node] -= request;
spin_unlock(&heap_lock);
@@ -337,14 +388,17 @@ void free_heap_pages(
unsigned int zone, struct page_info *pg, unsigned int order)
{
unsigned long mask;
+ int node = phys_to_nid(page_to_maddr(pg));
ASSERT(zone < NR_ZONES);
ASSERT(order <= MAX_ORDER);
+ ASSERT(node >= 0);
+ ASSERT(node < num_online_nodes());
spin_lock(&heap_lock);
map_free(page_to_mfn(pg), 1 << order);
- avail[zone] += 1 << order;
+ avail[zone][node] += 1 << order;
/* Merge chunks as far as possible. */
while ( order < MAX_ORDER )
@@ -370,10 +424,13 @@ void free_heap_pages(
}
order++;
+
+ /* after merging, pg should be in the same node */
+ ASSERT(phys_to_nid(page_to_maddr(pg)) == node );
}
PFN_ORDER(pg) = order;
- list_add_tail(&pg->list, &heap[zone][order]);
+ list_add_tail(&pg->list, &heap[zone][node][order]);
spin_unlock(&heap_lock);
}
@@ -466,7 +523,7 @@ void *alloc_xenheap_pages(unsigned int o
int i;
local_irq_save(flags);
- pg = alloc_heap_pages(MEMZONE_XEN, order);
+ pg = alloc_heap_pages(MEMZONE_XEN, smp_processor_id(), order);
local_irq_restore(flags);
if ( unlikely(pg == NULL) )
@@ -580,8 +637,9 @@ int assign_pages(
}
-struct page_info *alloc_domheap_pages(
- struct domain *d, unsigned int order, unsigned int memflags)
+struct page_info *__alloc_domheap_pages(
+ struct domain *d, unsigned int cpu, unsigned int order,
+ unsigned int memflags)
{
struct page_info *pg = NULL;
cpumask_t mask;
@@ -591,17 +649,17 @@ struct page_info *alloc_domheap_pages(
if ( !(memflags & MEMF_dma) )
{
- pg = alloc_heap_pages(MEMZONE_DOM, order);
+ pg = alloc_heap_pages(MEMZONE_DOM, cpu, order);
/* Failure? Then check if we can fall back to the DMA pool. */
if ( unlikely(pg == NULL) &&
((order > MAX_ORDER) ||
- (avail[MEMZONE_DMADOM] <
+ (avail_heap_pages(MEMZONE_DMADOM,-1) <
(lowmem_emergency_pool_pages + (1UL << order)))) )
return NULL;
}
if ( pg == NULL )
- if ( (pg = alloc_heap_pages(MEMZONE_DMADOM, order)) == NULL )
+ if ( (pg = alloc_heap_pages(MEMZONE_DMADOM, cpu, order)) == NULL )
return NULL;
mask = pg->u.free.cpumask;
@@ -638,6 +696,13 @@ struct page_info *alloc_domheap_pages(
}
return pg;
+}
+
+inline struct page_info *alloc_domheap_pages(
+ struct domain *d, unsigned int order, unsigned int flags)
+{
+ return __alloc_domheap_pages(d, smp_processor_id(), order, flags);
+
}
@@ -714,13 +779,27 @@ void free_domheap_pages(struct page_info
}
+unsigned long avail_heap_pages(int zone, int node)
+{
+ int i,j, num_nodes = num_online_nodes();
+ unsigned long free_pages = 0;
+
+ for (i=0; i<NR_ZONES; i++)
+ if ( (zone == -1) || (zone == i) )
+ for (j=0; j < num_nodes; j++)
+ if ( (node == -1) || (node == j) )
+ free_pages += avail[i][j];
+
+ return free_pages;
+}
+
unsigned long avail_domheap_pages(void)
{
unsigned long avail_nrm, avail_dma;
-
- avail_nrm = avail[MEMZONE_DOM];
-
- avail_dma = avail[MEMZONE_DMADOM];
+
+ avail_nrm = avail_heap_pages(MEMZONE_DOM,-1);
+
+ avail_dma = avail_heap_pages(MEMZONE_DMADOM,-1);
if ( avail_dma > lowmem_emergency_pool_pages )
avail_dma -= lowmem_emergency_pool_pages;
else
@@ -729,6 +808,10 @@ unsigned long avail_domheap_pages(void)
return avail_nrm + avail_dma;
}
+unsigned long avail_nodeheap_pages(int node)
+{
+ return avail_heap_pages(-1, node);
+}
static void pagealloc_keyhandler(unsigned char key)
{
@@ -736,9 +819,9 @@ static void pagealloc_keyhandler(unsigne
printk(" Xen heap: %lukB free\n"
" DMA heap: %lukB free\n"
" Dom heap: %lukB free\n",
- avail[MEMZONE_XEN]<<(PAGE_SHIFT-10),
- avail[MEMZONE_DMADOM]<<(PAGE_SHIFT-10),
- avail[MEMZONE_DOM]<<(PAGE_SHIFT-10));
+ avail_heap_pages(MEMZONE_XEN, -1) << (PAGE_SHIFT-10),
+ avail_heap_pages(MEMZONE_DMADOM, -1) <<(PAGE_SHIFT-10),
+ avail_heap_pages(MEMZONE_DOM, -1) <<(PAGE_SHIFT-10));
}
@@ -805,6 +888,46 @@ unsigned long avail_scrub_pages(void)
{
return scrub_pages;
}
+
+static unsigned long count_bucket(struct list_head* l, int order)
+{
+ unsigned long total_pages = 0;
+ int pages = 1 << order;
+ struct page_info *pg;
+
+ list_for_each_entry(pg, l, list)
+ total_pages += pages;
+
+ return total_pages;
+}
+
+static void dump_heap(unsigned char key)
+{
+ s_time_t now = NOW();
+ int i,j,k;
+ unsigned long total;
+
+ printk("'%c' pressed -> dumping heap info (now-0x%X:%08X)\n", key,
+ (u32)(now>>32), (u32)now);
+
+ for (i=0; i<NR_ZONES; i++ )
+ for (j=0;j<MAX_NUMNODES;j++)
+ for (k=0;k<=MAX_ORDER;k++)
+ if ( !list_empty(&heap[i][j][k]) )
+ {
+ total = count_bucket(&heap[i][j][k], k);
+ printk("heap[%d][%d][%d]-> %lu pages\n",
+ i, j, k, total);
+ }
+}
+
+static __init int register_heap_trigger(void)
+{
+ register_keyhandler('H', dump_heap, "dump heap info");
+ return 0;
+}
+__initcall(register_heap_trigger);
+
static __init int page_scrub_init(void)
{
diff -r e87b07e5fddd xen/include/xen/mm.h
--- a/xen/include/xen/mm.h Tue Aug 15 11:36:36 2006 -0500
+++ b/xen/include/xen/mm.h Tue Aug 15 11:37:51 2006 -0500
@@ -45,7 +45,8 @@ void end_boot_allocator(void);
/* Generic allocator. These functions are *not* interrupt-safe. */
void init_heap_pages(
unsigned int zone, struct page_info *pg, unsigned long nr_pages);
-struct page_info *alloc_heap_pages(unsigned int zone, unsigned int order);
+struct page_info *alloc_heap_pages(
+ unsigned int zone, unsigned int cpu, unsigned int order);
void free_heap_pages(
unsigned int zone, struct page_info *pg, unsigned int order);
void scrub_heap_pages(void);
@@ -61,8 +62,12 @@ void init_domheap_pages(paddr_t ps, padd
void init_domheap_pages(paddr_t ps, paddr_t pe);
struct page_info *alloc_domheap_pages(
struct domain *d, unsigned int order, unsigned int memflags);
+struct page_info *__alloc_domheap_pages(
+ struct domain *d, unsigned int cpu, unsigned int order,
+ unsigned int memflags);
void free_domheap_pages(struct page_info *pg, unsigned int order);
unsigned long avail_domheap_pages(void);
+unsigned long avail_heap_pages(int zone, int node);
#define alloc_domheap_page(d) (alloc_domheap_pages(d,0,0))
#define free_domheap_page(p) (free_domheap_pages(p,0))
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