Change from V2 to V3: o Updates for clear_page on various platforms o Performance measurements on i386 (2x PIII-450 384M RAM) o Port patches to 2.6.10-bk7 o Add scrub_load so that a high load prevents scrubd from running (So that people may feel better about this approach. Set by default to 999 so its off. The typical result of not running kscrubd under high loads is to slow the system down even further since zeroing large consecutive areas of memory is more efficient than zeroing page size chunks. Memory subsystems are typically optimized for linear accesses and reach their peak performance if large areas of memory are written to) o Various fixes The patches increasing the page fault rate (introduction of atomic pte operations and anticipatory prefaulting) do so by reducing the locking overhead and are therefore mainly of interest for applications running in SMP systems with a high number of cpus. The single thread performance does just show minor increases. Only the performance of multi-threaded applications increases significantly. The most expensive operation in the page fault handler is (apart of SMP locking overhead) the zeroing of the page that is also done in the page fault handler. This zeroing means that all cachelines of the faulted page (on Altix that means all 128 cachelines of 128 byte each) must be loaded and later written back. This patch allows to avoid having to load all cachelines if only a part of the cachelines of that page is needed immediately after the fault. Doing so will only be effective for sparsely accessed memory which is typical for anonymous memory and pte maps. Prezeroed pages will only be used for those purposes. Unzeroed pages will be used as usual for file mapping, page caching etc etc. Others have also thought that prezeroing could be a benefit and have tried provide a way to provide zeroed pages to the page fault handler: http://marc.theaimsgroup.com/?t=109914559100004&r=1&w=2 http://marc.theaimsgroup.com/?t=109777267500005&r=1&w=2 http://marc.theaimsgroup.com/?l=linux-kernel&m=104931944213955&w=2 However, these attempt have tried to zero pages that are like to be used soon (and that may have recently been accessed). Elements of these pages are thus already in the cpu caches. Approaches like that will only shift processing to somewhere else and not bring any performance benefits. Prezeroing only makes sense for pages that are not currently needed and that are not in the cpu caches. Pages that have recently been touched and that soon will be touched again are better hot zeroed since the zeroing will largely be done to cachelines already in the cpu caches. The patch makes prezeroing very effective by: 1. Aggregating zeroing operations to only apply to pages of higher order, which results in many pages that will later become zero 0 to be zeroed in one step. For that purpose the existing clear_page function is extended and made to take an additional argument specifying the order of the page to be cleared. 2. Hardware support for offloading zeroing from the cpu. This avoids the invalidation of the cpu caches by extensive zeroing operations. The scrub daemon is invoked when a unzeroed page of a certain order has been generated so that its worth running it. If no higher order pages are present then the logic will favor hot zeroing rather than simply shifting processing around. kscrubd typically runs only for a fraction of a second and sleeps for long periods of time even under memory benchmarking. kscrubd performs short bursts of zeroing when needed and tries to stay out off the processor as much as possible. The result is a significant increase of the page fault performance even for single threaded applications (i386 2x PIII-450 384M RAM allocating 256M in each run): w/o patch: Gb Rep Threads User System Wall flt/cpu/s fault/wsec 0 1 1 0.006s 0.389s 0.039s157455.320 157070.694 0 1 2 0.007s 0.607s 0.032s101476.689 190350.885 w/patch Gb Rep Threads User System Wall flt/cpu/s fault/wsec 0 1 1 0.008s 0.083s 0.009s672151.422 664045.899 0 1 2 0.005s 0.129s 0.008s459629.796 741857.373 The performance can only be upheld if enough zeroed pages are available. In a heavy memory intensive benchmark the system may run out of these very fast but the efficient algorithm for page zeroing still makes this a winner (2 way system with 384MB RAM, no hardware zeroing support). In the following measurement the test is repeated 10 times allocating 256M each in rapid succession which would deplete the pool of zeroed pages quickly): w/o patch: Gb Rep Threads User System Wall flt/cpu/s fault/wsec 0 10 1 0.058s 3.913s 3.097s157335.774 157076.932 0 10 2 0.063s 6.139s 3.027s100756.788 190572.486 w/patch Gb Rep Threads User System Wall flt/cpu/s fault/wsec 0 10 1 0.059s 1.828s 1.089s330913.517 330225.515 0 10 2 0.082s 1.951s 1.094s307172.100 320680.232 Note that zeroing of pages makes no sense if the application touches all cache lines of a page allocated (there is no influence of prezeroing on benchmarks like lmbench for that reason) since the extensive caching of modern cpus means that the zeroes written to a hot zeroed page will then be overwritten by the application in the cpu cache and thus the zeros will never make it to memory! The test program used above only touches one 128 byte cache line of a 16k page (ia64). Sparsely populated and accessed areas are typical for lots of applications. Here is another test in order to gauge the influence of the number of cache lines touched on the performance of the prezero enhancements: Gb Rep Thr CLine User System Wall flt/cpu/s fault/wsec 1 1 1 1 0.01s 0.12s 0.01s500813.853 497925.891 1 1 1 2 0.01s 0.11s 0.01s493453.103 472877.725 1 1 1 4 0.02s 0.10s 0.01s479351.658 471507.415 1 1 1 8 0.01s 0.13s 0.01s424742.054 416725.013 1 1 1 16 0.05s 0.12s 0.01s347715.359 336983.834 1 1 1 32 0.12s 0.13s 0.02s258112.286 256246.731 1 1 1 64 0.24s 0.14s 0.03s169896.381 168189.283 1 1 1 128 0.49s 0.14s 0.06s102300.257 101674.435 The benefits of prezeroing are reduced to minimal quantities if all cachelines of a page are touched. Prezeroing can only be effective if the whole page is not immediately used after the page fault. The patch is composed of 3 parts: [1/4] Introduce __GFP_ZERO Modifies the page allocator to be able to take the __GFP_ZERO flag and returns zeroed memory on request. Modifies locations throughout the linux sources that retrieve a page and then zero it to request a zeroed page. [2/4] Architecture specific clear_page updates Adds second order argument to clear_page and updates all arches. Note: The two first pages may be used alone if no zeroing engine is wanted. [3/4] Page Zeroing Adds management of ZEROED and NOT_ZEROED pages and a background daemon called scrubd. scrubd is disabled by default but can be enabled by writing an order number to /proc/sys/vm/scrub_start. If a page is coalesced of that order or higher then the scrub daemon will start zeroing until all pages of order /proc/sys/vm/scrub_stop and higher are zeroed and then go back to sleep. In an SMP environment the scrub daemon is typically running on the most idle cpu. Thus a single threaded application running on one cpu may have the other cpu zeroing pages for it etc. The scrub daemon is hardly noticable and usually finished zeroing quickly since most processors are optimized for linear memory filling. [4/4] SGI Altix Block Transfer Engine Support Implements a driver to shift the zeroing off the cpu into hardware. With hardware support there will be minimal impact of zeroing on the performance of the system.