[Date Prev][Date Next][Thread Prev][Thread Next][Date Index][Thread Index] [Xen-changelog] [xen master] spread boot time page scrubbing across all available CPU's
commit 7430a86de0c9bd126b441570e459f6e06413cbf6 Author: Malcolm Crossley <malcolm.crossley@xxxxxxxxxx> AuthorDate: Mon Jun 16 12:02:00 2014 +0200 Commit: Jan Beulich <jbeulich@xxxxxxxx> CommitDate: Mon Jun 16 12:02:00 2014 +0200 spread boot time page scrubbing across all available CPU's The page scrubbing is done in 128MB chunks in lockstep across all the non-SMT CPU's. This allows for the boot CPU to hold the heap_lock whilst each chunk is being scrubbed and then release the heap_lock when the CPU's are finished scrubing their individual chunk. This allows for the heap_lock to not be held continously and for pending softirqs are to be serviced periodically across the CPU's. The page scrub memory chunks are allocated to the CPU's in a NUMA aware fashion to reduce socket interconnect overhead and improve performance. Specifically in the first phase we scrub at the same time on all the NUMA nodes that have CPUs - we also weed out the SMT threads so that we only use cores (that gives a 50% boost). The second phase is for NUMA nodes that have no CPUs - for that we use the closest NUMA node's CPUs (non-SMT again) to do the job. This patch reduces the boot page scrub time on a 128GB 64 core AMD Opteron 6386 machine from 49 seconds to 3 seconds. On a IvyBridge-EX 8 socket box with 1.5TB it cuts it down from 15 minutes to 63 seconds. Signed-off-by: Malcolm Crossley <malcolm.crossley@xxxxxxxxxx> Signed-off-by: Konrad Rzeszutek Wilk <konrad.wilk@xxxxxxxxxx> Reviewed-by: Tim Deegan <tim@xxxxxxx> Reviewed-by: Andrew Cooper <andrew.cooper3@xxxxxxxxxx> --- docs/misc/xen-command-line.markdown | 10 ++ xen/common/page_alloc.c | 214 ++++++++++++++++++++++++++++++++--- xen/include/asm-arm/numa.h | 1 + 3 files changed, 207 insertions(+), 18 deletions(-) diff --git a/docs/misc/xen-command-line.markdown b/docs/misc/xen-command-line.markdown index 25829fe..94f04bd 100644 --- a/docs/misc/xen-command-line.markdown +++ b/docs/misc/xen-command-line.markdown @@ -198,6 +198,16 @@ Scrub free RAM during boot. This is a safety feature to prevent accidentally leaking sensitive VM data into other VMs if Xen crashes and reboots. +### `bootscrub_chunk` +> `= <size>` + +> Default: `128M` + +Maximum RAM block size chunks to be scrubbed whilst holding the page heap lock +and not running softirqs. Reduce this if softirqs are not being run frequently +enough. Setting this to a high value may cause boot failure, particularly if +the NMI watchdog is also enabled. + ### cachesize > `= <size>` diff --git a/xen/common/page_alloc.c b/xen/common/page_alloc.c index 601319c..1b2d541 100644 --- a/xen/common/page_alloc.c +++ b/xen/common/page_alloc.c @@ -65,6 +65,13 @@ static bool_t opt_bootscrub __initdata = 1; boolean_param("bootscrub", opt_bootscrub); /* + * bootscrub_chunk -> Amount of bytes to scrub lockstep on non-SMT CPUs + * on all NUMA nodes. + */ +static unsigned long __initdata opt_bootscrub_chunk = MB(128); +size_param("bootscrub_chunk", opt_bootscrub_chunk); + +/* * Bit width of the DMA heap -- used to override NUMA-node-first. * allocation strategy, which can otherwise exhaust low memory. */ @@ -90,6 +97,16 @@ static struct bootmem_region { } *__initdata bootmem_region_list; static unsigned int __initdata nr_bootmem_regions; +struct scrub_region { + unsigned long offset; + unsigned long start; + unsigned long per_cpu_sz; + unsigned long rem; + cpumask_t cpus; +}; +static struct scrub_region __initdata region[MAX_NUMNODES]; +static unsigned long __initdata chunk_size; + static void __init boot_bug(int line) { panic("Boot BUG at %s:%d", __FILE__, line); @@ -1256,42 +1273,203 @@ void __init end_boot_allocator(void) printk("\n"); } +static void __init smp_scrub_heap_pages(void *data) +{ + unsigned long mfn, start, end; + struct page_info *pg; + struct scrub_region *r; + unsigned int temp_cpu, node, cpu_idx = 0; + unsigned int cpu = smp_processor_id(); + + if ( data ) + r = data; + else + { + node = cpu_to_node(cpu); + if ( node == NUMA_NO_NODE ) + return; + r = ®ion[node]; + } + + /* Determine the current CPU's index into CPU's linked to this node. */ + for_each_cpu ( temp_cpu, &r->cpus ) + { + if ( cpu == temp_cpu ) + break; + cpu_idx++; + } + + /* Calculate the starting mfn for this CPU's memory block. */ + start = r->start + (r->per_cpu_sz * cpu_idx) + r->offset; + + /* Calculate the end mfn into this CPU's memory block for this iteration. */ + if ( r->offset + chunk_size >= r->per_cpu_sz ) + { + end = r->start + (r->per_cpu_sz * cpu_idx) + r->per_cpu_sz; + + if ( r->rem && (cpumask_weight(&r->cpus) - 1 == cpu_idx) ) + end += r->rem; + } + else + end = start + chunk_size; + + for ( mfn = start; mfn < end; mfn++ ) + { + pg = mfn_to_page(mfn); + + /* Check the mfn is valid and page is free. */ + if ( !mfn_valid(mfn) || !page_state_is(pg, free) ) + continue; + + scrub_one_page(pg); + } +} + +static int __init find_non_smt(unsigned int node, cpumask_t *dest) +{ + cpumask_t node_cpus; + unsigned int i, cpu; + + cpumask_and(&node_cpus, &node_to_cpumask(node), &cpu_online_map); + cpumask_clear(dest); + for_each_cpu ( i, &node_cpus ) + { + if ( cpumask_intersects(dest, per_cpu(cpu_sibling_mask, i)) ) + continue; + cpu = cpumask_first(per_cpu(cpu_sibling_mask, i)); + cpumask_set_cpu(cpu, dest); + } + return cpumask_weight(dest); +} + /* - * Scrub all unallocated pages in all heap zones. This function is more - * convoluted than appears necessary because we do not want to continuously - * hold the lock while scrubbing very large memory areas. + * Scrub all unallocated pages in all heap zones. This function uses all + * online cpu's to scrub the memory in parallel. */ void __init scrub_heap_pages(void) { - unsigned long mfn; - struct page_info *pg; + cpumask_t node_cpus, all_worker_cpus; + unsigned int i, j; + unsigned long offset, max_per_cpu_sz = 0; + unsigned long start, end; + unsigned long rem = 0; + int last_distance, best_node; + int cpus; if ( !opt_bootscrub ) return; - printk("Scrubbing Free RAM: "); + cpumask_clear(&all_worker_cpus); + /* Scrub block size. */ + chunk_size = opt_bootscrub_chunk >> PAGE_SHIFT; + if ( chunk_size == 0 ) + chunk_size = MB(128) >> PAGE_SHIFT; - for ( mfn = first_valid_mfn; mfn < max_page; mfn++ ) + /* Round #0 - figure out amounts and which CPUs to use. */ + for_each_online_node ( i ) { + if ( !node_spanned_pages(i) ) + continue; + /* Calculate Node memory start and end address. */ + start = max(node_start_pfn(i), first_valid_mfn); + end = min(node_start_pfn(i) + node_spanned_pages(i), max_page); + /* Just in case NODE has 1 page and starts below first_valid_mfn. */ + end = max(end, start); + /* CPUs that are online and on this node (if none, that it is OK). */ + cpus = find_non_smt(i, &node_cpus); + cpumask_or(&all_worker_cpus, &all_worker_cpus, &node_cpus); + if ( cpus <= 0 ) + { + /* No CPUs on this node. Round #2 will take of it. */ + rem = 0; + region[i].per_cpu_sz = (end - start); + } + else + { + rem = (end - start) % cpus; + region[i].per_cpu_sz = (end - start) / cpus; + if ( region[i].per_cpu_sz > max_per_cpu_sz ) + max_per_cpu_sz = region[i].per_cpu_sz; + } + region[i].start = start; + region[i].rem = rem; + cpumask_copy(®ion[i].cpus, &node_cpus); + } + + printk("Scrubbing Free RAM on %d nodes using %d CPUs\n", num_online_nodes(), + cpumask_weight(&all_worker_cpus)); + + /* Round: #1 - do NUMA nodes with CPUs. */ + for ( offset = 0; offset < max_per_cpu_sz; offset += chunk_size ) + { + for_each_online_node ( i ) + region[i].offset = offset; + process_pending_softirqs(); - pg = mfn_to_page(mfn); + spin_lock(&heap_lock); + on_selected_cpus(&all_worker_cpus, smp_scrub_heap_pages, NULL, 1); + spin_unlock(&heap_lock); - /* Quick lock-free check. */ - if ( !mfn_valid(mfn) || !page_state_is(pg, free) ) + printk("."); + } + + /* + * Round #2: NUMA nodes with no CPUs get scrubbed with CPUs on the node + * closest to us and with CPUs. + */ + for_each_online_node ( i ) + { + node_cpus = node_to_cpumask(i); + + if ( !cpumask_empty(&node_cpus) ) continue; - /* Every 100MB, print a progress dot. */ - if ( (mfn % ((100*1024*1024)/PAGE_SIZE)) == 0 ) - printk("."); + last_distance = INT_MAX; + best_node = first_node(node_online_map); + /* Figure out which NODE CPUs are close. */ + for_each_online_node ( j ) + { + int distance; - spin_lock(&heap_lock); + if ( cpumask_empty(&node_to_cpumask(j)) ) + continue; - /* Re-check page status with lock held. */ - if ( page_state_is(pg, free) ) - scrub_one_page(pg); + distance = __node_distance(i, j); + if ( distance < last_distance ) + { + last_distance = distance; + best_node = j; + } + } + /* + * Use CPUs from best node, and if there are no CPUs on the + * first node (the default) use the BSP. + */ + cpus = find_non_smt(best_node, &node_cpus); + if ( cpus == 0 ) + { + cpumask_set_cpu(smp_processor_id(), &node_cpus); + cpus = 1; + } + /* We already have the node information from round #0. */ + region[i].rem = region[i].per_cpu_sz % cpus; + region[i].per_cpu_sz /= cpus; + max_per_cpu_sz = region[i].per_cpu_sz; + cpumask_copy(®ion[i].cpus, &node_cpus); - spin_unlock(&heap_lock); + for ( offset = 0; offset < max_per_cpu_sz; offset += chunk_size ) + { + region[i].offset = offset; + + process_pending_softirqs(); + + spin_lock(&heap_lock); + on_selected_cpus(&node_cpus, smp_scrub_heap_pages, ®ion[i], 1); + spin_unlock(&heap_lock); + + printk("."); + } } printk("done.\n"); diff --git a/xen/include/asm-arm/numa.h b/xen/include/asm-arm/numa.h index cb8f2ba..2c019d7 100644 --- a/xen/include/asm-arm/numa.h +++ b/xen/include/asm-arm/numa.h @@ -12,6 +12,7 @@ static inline __attribute__((pure)) int phys_to_nid(paddr_t addr) /* XXX: implement NUMA support */ #define node_spanned_pages(nid) (total_pages) +#define node_start_pfn(nid) (frametable_base_mfn) #define __node_distance(a, b) (20) #endif /* __ARCH_ARM_NUMA_H */ -- generated by git-patchbot for /home/xen/git/xen.git#master _______________________________________________ Xen-changelog mailing list Xen-changelog@xxxxxxxxxxxxx http://lists.xensource.com/xen-changelog
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