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authorPaul Jackson <pj@sgi.com>2006-12-06 23:31:48 -0500
committerLinus Torvalds <torvalds@woody.osdl.org>2006-12-07 11:39:20 -0500
commit9276b1bc96a132f4068fdee00983c532f43d3a26 (patch)
tree04d64444cf6558632cfc7514b5437578b5e616af /include/linux
parent89689ae7f95995723fbcd5c116c47933a3bb8b13 (diff)
[PATCH] memory page_alloc zonelist caching speedup
Optimize the critical zonelist scanning for free pages in the kernel memory allocator by caching the zones that were found to be full recently, and skipping them. Remembers the zones in a zonelist that were short of free memory in the last second. And it stashes a zone-to-node table in the zonelist struct, to optimize that conversion (minimize its cache footprint.) Recent changes: This differs in a significant way from a similar patch that I posted a week ago. Now, instead of having a nodemask_t of recently full nodes, I have a bitmask of recently full zones. This solves a problem that last weeks patch had, which on systems with multiple zones per node (such as DMA zone) would take seeing any of these zones full as meaning that all zones on that node were full. Also I changed names - from "zonelist faster" to "zonelist cache", as that seemed to better convey what we're doing here - caching some of the key zonelist state (for faster access.) See below for some performance benchmark results. After all that discussion with David on why I didn't need them, I went and got some ;). I wanted to verify that I had not hurt the normal case of memory allocation noticeably. At least for my one little microbenchmark, I found (1) the normal case wasn't affected, and (2) workloads that forced scanning across multiple nodes for memory improved up to 10% fewer System CPU cycles and lower elapsed clock time ('sys' and 'real'). Good. See details, below. I didn't have the logic in get_page_from_freelist() for various full nodes and zone reclaim failures correct. That should be fixed up now - notice the new goto labels zonelist_scan, this_zone_full, and try_next_zone, in get_page_from_freelist(). There are two reasons I persued this alternative, over some earlier proposals that would have focused on optimizing the fake numa emulation case by caching the last useful zone: 1) Contrary to what I said before, we (SGI, on large ia64 sn2 systems) have seen real customer loads where the cost to scan the zonelist was a problem, due to many nodes being full of memory before we got to a node we could use. Or at least, I think we have. This was related to me by another engineer, based on experiences from some time past. So this is not guaranteed. Most likely, though. The following approach should help such real numa systems just as much as it helps fake numa systems, or any combination thereof. 2) The effort to distinguish fake from real numa, using node_distance, so that we could cache a fake numa node and optimize choosing it over equivalent distance fake nodes, while continuing to properly scan all real nodes in distance order, was going to require a nasty blob of zonelist and node distance munging. The following approach has no new dependency on node distances or zone sorting. See comment in the patch below for a description of what it actually does. Technical details of note (or controversy): - See the use of "zlc_active" and "did_zlc_setup" below, to delay adding any work for this new mechanism until we've looked at the first zone in zonelist. I figured the odds of the first zone having the memory we needed were high enough that we should just look there, first, then get fancy only if we need to keep looking. - Some odd hackery was needed to add items to struct zonelist, while not tripping up the custom zonelists built by the mm/mempolicy.c code for MPOL_BIND. My usual wordy comments below explain this. Search for "MPOL_BIND". - Some per-node data in the struct zonelist is now modified frequently, with no locking. Multiple CPU cores on a node could hit and mangle this data. The theory is that this is just performance hint data, and the memory allocator will work just fine despite any such mangling. The fields at risk are the struct 'zonelist_cache' fields 'fullzones' (a bitmask) and 'last_full_zap' (unsigned long jiffies). It should all be self correcting after at most a one second delay. - This still does a linear scan of the same lengths as before. All I've optimized is making the scan faster, not algorithmically shorter. It is now able to scan a compact array of 'unsigned short' in the case of many full nodes, so one cache line should cover quite a few nodes, rather than each node hitting another one or two new and distinct cache lines. - If both Andi and Nick don't find this too complicated, I will be (pleasantly) flabbergasted. - I removed the comment claiming we only use one cachline's worth of zonelist. We seem, at least in the fake numa case, to have put the lie to that claim. - I pay no attention to the various watermarks and such in this performance hint. A node could be marked full for one watermark, and then skipped over when searching for a page using a different watermark. I think that's actually quite ok, as it will tend to slightly increase the spreading of memory over other nodes, away from a memory stressed node. =============== Performance - some benchmark results and analysis: This benchmark runs a memory hog program that uses multiple threads to touch alot of memory as quickly as it can. Multiple runs were made, touching 12, 38, 64 or 90 GBytes out of the total 96 GBytes on the system, and using 1, 19, 37, or 55 threads (on a 56 CPU system.) System, user and real (elapsed) timings were recorded for each run, shown in units of seconds, in the table below. Two kernels were tested - 2.6.18-mm3 and the same kernel with this zonelist caching patch added. The table also shows the percentage improvement the zonelist caching sys time is over (lower than) the stock *-mm kernel. number 2.6.18-mm3 zonelist-cache delta (< 0 good) percent GBs N ------------ -------------- ---------------- systime mem threads sys user real sys user real sys user real better 12 1 153 24 177 151 24 176 -2 0 -1 1% 12 19 99 22 8 99 22 8 0 0 0 0% 12 37 111 25 6 112 25 6 1 0 0 -0% 12 55 115 25 5 110 23 5 -5 -2 0 4% 38 1 502 74 576 497 73 570 -5 -1 -6 0% 38 19 426 78 48 373 76 39 -53 -2 -9 12% 38 37 544 83 36 547 82 36 3 -1 0 -0% 38 55 501 77 23 511 80 24 10 3 1 -1% 64 1 917 125 1042 890 124 1014 -27 -1 -28 2% 64 19 1118 138 119 965 141 103 -153 3 -16 13% 64 37 1202 151 94 1136 150 81 -66 -1 -13 5% 64 55 1118 141 61 1072 140 58 -46 -1 -3 4% 90 1 1342 177 1519 1275 174 1450 -67 -3 -69 4% 90 19 2392 199 192 2116 189 176 -276 -10 -16 11% 90 37 3313 238 175 2972 225 145 -341 -13 -30 10% 90 55 1948 210 104 1843 213 100 -105 3 -4 5% Notes: 1) This test ran a memory hog program that started a specified number N of threads, and had each thread allocate and touch 1/N'th of the total memory to be used in the test run in a single loop, writing a constant word to memory, one store every 4096 bytes. Watching this test during some earlier trial runs, I would see each of these threads sit down on one CPU and stay there, for the remainder of the pass, a different CPU for each thread. 2) The 'real' column is not comparable to the 'sys' or 'user' columns. The 'real' column is seconds wall clock time elapsed, from beginning to end of that test pass. The 'sys' and 'user' columns are total CPU seconds spent on that test pass. For a 19 thread test run, for example, the sum of 'sys' and 'user' could be up to 19 times the number of 'real' elapsed wall clock seconds. 3) Tests were run on a fresh, single-user boot, to minimize the amount of memory already in use at the start of the test, and to minimize the amount of background activity that might interfere. 4) Tests were done on a 56 CPU, 28 Node system with 96 GBytes of RAM. 5) Notice that the 'real' time gets large for the single thread runs, even though the measured 'sys' and 'user' times are modest. I'm not sure what that means - probably something to do with it being slow for one thread to be accessing memory along ways away. Perhaps the fake numa system, running ostensibly the same workload, would not show this substantial degradation of 'real' time for one thread on many nodes -- lets hope not. 6) The high thread count passes (one thread per CPU - on 55 of 56 CPUs) ran quite efficiently, as one might expect. Each pair of threads needed to allocate and touch the memory on the node the two threads shared, a pleasantly parallizable workload. 7) The intermediate thread count passes, when asking for alot of memory forcing them to go to a few neighboring nodes, improved the most with this zonelist caching patch. Conclusions: * This zonelist cache patch probably makes little difference one way or the other for most workloads on real numa hardware, if those workloads avoid heavy off node allocations. * For memory intensive workloads requiring substantial off-node allocations on real numa hardware, this patch improves both kernel and elapsed timings up to ten per-cent. * For fake numa systems, I'm optimistic, but will have to leave that up to Rohit Seth to actually test (once I get him a 2.6.18 backport.) Signed-off-by: Paul Jackson <pj@sgi.com> Cc: Rohit Seth <rohitseth@google.com> Cc: Christoph Lameter <clameter@engr.sgi.com> Cc: David Rientjes <rientjes@cs.washington.edu> Cc: Paul Menage <menage@google.com> Signed-off-by: Andrew Morton <akpm@osdl.org> Signed-off-by: Linus Torvalds <torvalds@osdl.org>
Diffstat (limited to 'include/linux')
-rw-r--r--include/linux/cpuset.h2
-rw-r--r--include/linux/mmzone.h85
2 files changed, 82 insertions, 5 deletions
diff --git a/include/linux/cpuset.h b/include/linux/cpuset.h
index 4d8adf663681..748d2c996631 100644
--- a/include/linux/cpuset.h
+++ b/include/linux/cpuset.h
@@ -23,6 +23,7 @@ extern void cpuset_fork(struct task_struct *p);
23extern void cpuset_exit(struct task_struct *p); 23extern void cpuset_exit(struct task_struct *p);
24extern cpumask_t cpuset_cpus_allowed(struct task_struct *p); 24extern cpumask_t cpuset_cpus_allowed(struct task_struct *p);
25extern nodemask_t cpuset_mems_allowed(struct task_struct *p); 25extern nodemask_t cpuset_mems_allowed(struct task_struct *p);
26#define cpuset_current_mems_allowed (current->mems_allowed)
26void cpuset_init_current_mems_allowed(void); 27void cpuset_init_current_mems_allowed(void);
27void cpuset_update_task_memory_state(void); 28void cpuset_update_task_memory_state(void);
28#define cpuset_nodes_subset_current_mems_allowed(nodes) \ 29#define cpuset_nodes_subset_current_mems_allowed(nodes) \
@@ -83,6 +84,7 @@ static inline nodemask_t cpuset_mems_allowed(struct task_struct *p)
83 return node_possible_map; 84 return node_possible_map;
84} 85}
85 86
87#define cpuset_current_mems_allowed (node_online_map)
86static inline void cpuset_init_current_mems_allowed(void) {} 88static inline void cpuset_init_current_mems_allowed(void) {}
87static inline void cpuset_update_task_memory_state(void) {} 89static inline void cpuset_update_task_memory_state(void) {}
88#define cpuset_nodes_subset_current_mems_allowed(nodes) (1) 90#define cpuset_nodes_subset_current_mems_allowed(nodes) (1)
diff --git a/include/linux/mmzone.h b/include/linux/mmzone.h
index e06683e2bea3..09bf9d8d7b72 100644
--- a/include/linux/mmzone.h
+++ b/include/linux/mmzone.h
@@ -288,19 +288,94 @@ struct zone {
288 */ 288 */
289#define DEF_PRIORITY 12 289#define DEF_PRIORITY 12
290 290
291/* Maximum number of zones on a zonelist */
292#define MAX_ZONES_PER_ZONELIST (MAX_NUMNODES * MAX_NR_ZONES)
293
294#ifdef CONFIG_NUMA
295/*
296 * We cache key information from each zonelist for smaller cache
297 * footprint when scanning for free pages in get_page_from_freelist().
298 *
299 * 1) The BITMAP fullzones tracks which zones in a zonelist have come
300 * up short of free memory since the last time (last_fullzone_zap)
301 * we zero'd fullzones.
302 * 2) The array z_to_n[] maps each zone in the zonelist to its node
303 * id, so that we can efficiently evaluate whether that node is
304 * set in the current tasks mems_allowed.
305 *
306 * Both fullzones and z_to_n[] are one-to-one with the zonelist,
307 * indexed by a zones offset in the zonelist zones[] array.
308 *
309 * The get_page_from_freelist() routine does two scans. During the
310 * first scan, we skip zones whose corresponding bit in 'fullzones'
311 * is set or whose corresponding node in current->mems_allowed (which
312 * comes from cpusets) is not set. During the second scan, we bypass
313 * this zonelist_cache, to ensure we look methodically at each zone.
314 *
315 * Once per second, we zero out (zap) fullzones, forcing us to
316 * reconsider nodes that might have regained more free memory.
317 * The field last_full_zap is the time we last zapped fullzones.
318 *
319 * This mechanism reduces the amount of time we waste repeatedly
320 * reexaming zones for free memory when they just came up low on
321 * memory momentarilly ago.
322 *
323 * The zonelist_cache struct members logically belong in struct
324 * zonelist. However, the mempolicy zonelists constructed for
325 * MPOL_BIND are intentionally variable length (and usually much
326 * shorter). A general purpose mechanism for handling structs with
327 * multiple variable length members is more mechanism than we want
328 * here. We resort to some special case hackery instead.
329 *
330 * The MPOL_BIND zonelists don't need this zonelist_cache (in good
331 * part because they are shorter), so we put the fixed length stuff
332 * at the front of the zonelist struct, ending in a variable length
333 * zones[], as is needed by MPOL_BIND.
334 *
335 * Then we put the optional zonelist cache on the end of the zonelist
336 * struct. This optional stuff is found by a 'zlcache_ptr' pointer in
337 * the fixed length portion at the front of the struct. This pointer
338 * both enables us to find the zonelist cache, and in the case of
339 * MPOL_BIND zonelists, (which will just set the zlcache_ptr to NULL)
340 * to know that the zonelist cache is not there.
341 *
342 * The end result is that struct zonelists come in two flavors:
343 * 1) The full, fixed length version, shown below, and
344 * 2) The custom zonelists for MPOL_BIND.
345 * The custom MPOL_BIND zonelists have a NULL zlcache_ptr and no zlcache.
346 *
347 * Even though there may be multiple CPU cores on a node modifying
348 * fullzones or last_full_zap in the same zonelist_cache at the same
349 * time, we don't lock it. This is just hint data - if it is wrong now
350 * and then, the allocator will still function, perhaps a bit slower.
351 */
352
353
354struct zonelist_cache {
355 DECLARE_BITMAP(fullzones, MAX_ZONES_PER_ZONELIST); /* zone full? */
356 unsigned short z_to_n[MAX_ZONES_PER_ZONELIST]; /* zone->nid */
357 unsigned long last_full_zap; /* when last zap'd (jiffies) */
358};
359#else
360struct zonelist_cache;
361#endif
362
291/* 363/*
292 * One allocation request operates on a zonelist. A zonelist 364 * One allocation request operates on a zonelist. A zonelist
293 * is a list of zones, the first one is the 'goal' of the 365 * is a list of zones, the first one is the 'goal' of the
294 * allocation, the other zones are fallback zones, in decreasing 366 * allocation, the other zones are fallback zones, in decreasing
295 * priority. 367 * priority.
296 * 368 *
297 * Right now a zonelist takes up less than a cacheline. We never 369 * If zlcache_ptr is not NULL, then it is just the address of zlcache,
298 * modify it apart from boot-up, and only a few indices are used, 370 * as explained above. If zlcache_ptr is NULL, there is no zlcache.
299 * so despite the zonelist table being relatively big, the cache
300 * footprint of this construct is very small.
301 */ 371 */
372
302struct zonelist { 373struct zonelist {
303 struct zone *zones[MAX_NUMNODES * MAX_NR_ZONES + 1]; // NULL delimited 374 struct zonelist_cache *zlcache_ptr; // NULL or &zlcache
375 struct zone *zones[MAX_ZONES_PER_ZONELIST + 1]; // NULL delimited
376#ifdef CONFIG_NUMA
377 struct zonelist_cache zlcache; // optional ...
378#endif
304}; 379};
305 380
306#ifdef CONFIG_ARCH_POPULATES_NODE_MAP 381#ifdef CONFIG_ARCH_POPULATES_NODE_MAP