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2022 2023 2024 2025 2026 2027 2028 2029 2030 2031 2032 2033 2034 2035 2036 2037 2038 2039 2040 2041 2042 2043 2044 2045 2046 2047 2048 2049 2050 2051 2052 2053 2054 | /* * linux/mm/page_alloc.c * * Manages the free list, the system allocates free pages here. * Note that kmalloc() lives in slab.c * * Copyright (C) 1991, 1992, 1993, 1994 Linus Torvalds * Swap reorganised 29.12.95, Stephen Tweedie * Support of BIGMEM added by Gerhard Wichert, Siemens AG, July 1999 * Reshaped it to be a zoned allocator, Ingo Molnar, Red Hat, 1999 * Discontiguous memory support, Kanoj Sarcar, SGI, Nov 1999 * Zone balancing, Kanoj Sarcar, SGI, Jan 2000 * Per cpu hot/cold page lists, bulk allocation, Martin J. Bligh, Sept 2002 * (lots of bits borrowed from Ingo Molnar & Andrew Morton) */ #include <linux/config.h> #include <linux/stddef.h> #include <linux/mm.h> #include <linux/swap.h> #include <linux/interrupt.h> #include <linux/pagemap.h> #include <linux/bootmem.h> #include <linux/compiler.h> #include <linux/module.h> #include <linux/suspend.h> #include <linux/pagevec.h> #include <linux/blkdev.h> #include <linux/slab.h> #include <linux/notifier.h> #include <linux/topology.h> #include <linux/sysctl.h> #include <linux/cpu.h> #include <asm/tlbflush.h> DECLARE_BITMAP(node_online_map, MAX_NUMNODES); struct pglist_data *pgdat_list; unsigned long totalram_pages; unsigned long totalhigh_pages; long nr_swap_pages; int numnodes = 1; int sysctl_lower_zone_protection = 0; EXPORT_SYMBOL(totalram_pages); EXPORT_SYMBOL(nr_swap_pages); /* * Used by page_zone() to look up the address of the struct zone whose * id is encoded in the upper bits of page->flags */ struct zone *zone_table[1 << (ZONES_SHIFT + NODES_SHIFT)]; EXPORT_SYMBOL(zone_table); static char *zone_names[MAX_NR_ZONES] = { "DMA", "Normal", "HighMem" }; int min_free_kbytes = 1024; static unsigned long __initdata nr_kernel_pages; static unsigned long __initdata nr_all_pages; /* * Temporary debugging check for pages not lying within a given zone. */ static int bad_range(struct zone *zone, struct page *page) { if (page_to_pfn(page) >= zone->zone_start_pfn + zone->spanned_pages) return 1; if (page_to_pfn(page) < zone->zone_start_pfn) return 1; if (zone != page_zone(page)) return 1; return 0; } static void bad_page(const char *function, struct page *page) { printk(KERN_EMERG "Bad page state at %s (in process '%s', page %p)\n", function, current->comm, page); printk(KERN_EMERG "flags:0x%08lx mapping:%p mapcount:%d count:%d\n", (unsigned long)page->flags, page->mapping, (int)page->mapcount, page_count(page)); printk(KERN_EMERG "Backtrace:\n"); dump_stack(); printk(KERN_EMERG "Trying to fix it up, but a reboot is needed\n"); page->flags &= ~(1 << PG_private | 1 << PG_locked | 1 << PG_lru | 1 << PG_active | 1 << PG_dirty | 1 << PG_maplock | 1 << PG_anon | 1 << PG_swapcache | 1 << PG_writeback); set_page_count(page, 0); page->mapping = NULL; page->mapcount = 0; } #ifndef CONFIG_HUGETLB_PAGE #define prep_compound_page(page, order) do { } while (0) #define destroy_compound_page(page, order) do { } while (0) #else /* * Higher-order pages are called "compound pages". They are structured thusly: * * The first PAGE_SIZE page is called the "head page". * * The remaining PAGE_SIZE pages are called "tail pages". * * All pages have PG_compound set. All pages have their ->private pointing at * the head page (even the head page has this). * * The first tail page's ->mapping, if non-zero, holds the address of the * compound page's put_page() function. * * The order of the allocation is stored in the first tail page's ->index * This is only for debug at present. This usage means that zero-order pages * may not be compound. */ static void prep_compound_page(struct page *page, unsigned long order) { int i; int nr_pages = 1 << order; page[1].mapping = NULL; page[1].index = order; for (i = 0; i < nr_pages; i++) { struct page *p = page + i; SetPageCompound(p); p->private = (unsigned long)page; } } static void destroy_compound_page(struct page *page, unsigned long order) { int i; int nr_pages = 1 << order; if (!PageCompound(page)) return; if (page[1].index != order) bad_page(__FUNCTION__, page); for (i = 0; i < nr_pages; i++) { struct page *p = page + i; if (!PageCompound(p)) bad_page(__FUNCTION__, page); if (p->private != (unsigned long)page) bad_page(__FUNCTION__, page); ClearPageCompound(p); } } #endif /* CONFIG_HUGETLB_PAGE */ /* * Freeing function for a buddy system allocator. * * The concept of a buddy system is to maintain direct-mapped table * (containing bit values) for memory blocks of various "orders". * The bottom level table contains the map for the smallest allocatable * units of memory (here, pages), and each level above it describes * pairs of units from the levels below, hence, "buddies". * At a high level, all that happens here is marking the table entry * at the bottom level available, and propagating the changes upward * as necessary, plus some accounting needed to play nicely with other * parts of the VM system. * At each level, we keep one bit for each pair of blocks, which * is set to 1 iff only one of the pair is allocated. So when we * are allocating or freeing one, we can derive the state of the * other. That is, if we allocate a small block, and both were * free, the remainder of the region must be split into blocks. * If a block is freed, and its buddy is also free, then this * triggers coalescing into a block of larger size. * * -- wli */ static inline void __free_pages_bulk (struct page *page, struct page *base, struct zone *zone, struct free_area *area, unsigned int order) { unsigned long page_idx, index, mask; if (order) destroy_compound_page(page, order); mask = (~0UL) << order; page_idx = page - base; if (page_idx & ~mask) BUG(); index = page_idx >> (1 + order); zone->free_pages += 1 << order; while (order < MAX_ORDER-1) { struct page *buddy1, *buddy2; BUG_ON(area >= zone->free_area + MAX_ORDER); if (!__test_and_change_bit(index, area->map)) /* * the buddy page is still allocated. */ break; /* Move the buddy up one level. */ buddy1 = base + (page_idx ^ (1 << order)); buddy2 = base + page_idx; BUG_ON(bad_range(zone, buddy1)); BUG_ON(bad_range(zone, buddy2)); list_del(&buddy1->lru); mask <<= 1; order++; area++; index >>= 1; page_idx &= mask; } list_add(&(base + page_idx)->lru, &area->free_list); } static inline void free_pages_check(const char *function, struct page *page) { if ( page_mapped(page) || page->mapping != NULL || page_count(page) != 0 || (page->flags & ( 1 << PG_lru | 1 << PG_private | 1 << PG_locked | 1 << PG_active | 1 << PG_reclaim | 1 << PG_slab | 1 << PG_maplock | 1 << PG_anon | 1 << PG_swapcache | 1 << PG_writeback ))) bad_page(function, page); if (PageDirty(page)) ClearPageDirty(page); } /* * Frees a list of pages. * Assumes all pages on list are in same zone, and of same order. * count is the number of pages to free, or 0 for all on the list. * * If the zone was previously in an "all pages pinned" state then look to * see if this freeing clears that state. * * And clear the zone's pages_scanned counter, to hold off the "all pages are * pinned" detection logic. */ static int free_pages_bulk(struct zone *zone, int count, struct list_head *list, unsigned int order) { unsigned long flags; struct free_area *area; struct page *base, *page = NULL; int ret = 0; base = zone->zone_mem_map; area = zone->free_area + order; spin_lock_irqsave(&zone->lock, flags); zone->all_unreclaimable = 0; zone->pages_scanned = 0; while (!list_empty(list) && count--) { page = list_entry(list->prev, struct page, lru); /* have to delete it as __free_pages_bulk list manipulates */ list_del(&page->lru); __free_pages_bulk(page, base, zone, area, order); ret++; } spin_unlock_irqrestore(&zone->lock, flags); return ret; } void __free_pages_ok(struct page *page, unsigned int order) { LIST_HEAD(list); int i; mod_page_state(pgfree, 1 << order); for (i = 0 ; i < (1 << order) ; ++i) free_pages_check(__FUNCTION__, page + i); list_add(&page->lru, &list); kernel_map_pages(page, 1<<order, 0); free_pages_bulk(page_zone(page), 1, &list, order); } #define MARK_USED(index, order, area) \ __change_bit((index) >> (1+(order)), (area)->map) /* * The order of subdivision here is critical for the IO subsystem. * Please do not alter this order without good reasons and regression * testing. Specifically, as large blocks of memory are subdivided, * the order in which smaller blocks are delivered depends on the order * they're subdivided in this function. This is the primary factor * influencing the order in which pages are delivered to the IO * subsystem according to empirical testing, and this is also justified * by considering the behavior of a buddy system containing a single * large block of memory acted on by a series of small allocations. * This behavior is a critical factor in sglist merging's success. * * -- wli */ static inline struct page * expand(struct zone *zone, struct page *page, unsigned long index, int low, int high, struct free_area *area) { unsigned long size = 1 << high; while (high > low) { area--; high--; size >>= 1; BUG_ON(bad_range(zone, &page[size])); list_add(&page[size].lru, &area->free_list); MARK_USED(index + size, high, area); } return page; } static inline void set_page_refs(struct page *page, int order) { #ifdef CONFIG_MMU set_page_count(page, 1); #else int i; /* * We need to reference all the pages for this order, otherwise if * anyone accesses one of the pages with (get/put) it will be freed. */ for (i = 0; i < (1 << order); i++) set_page_count(page+i, 1); #endif /* CONFIG_MMU */ } /* * This page is about to be returned from the page allocator */ static void prep_new_page(struct page *page, int order) { if (page->mapping || page_mapped(page) || (page->flags & ( 1 << PG_private | 1 << PG_locked | 1 << PG_lru | 1 << PG_active | 1 << PG_dirty | 1 << PG_reclaim | 1 << PG_maplock | 1 << PG_anon | 1 << PG_swapcache | 1 << PG_writeback ))) bad_page(__FUNCTION__, page); page->flags &= ~(1 << PG_uptodate | 1 << PG_error | 1 << PG_referenced | 1 << PG_arch_1 | 1 << PG_checked | 1 << PG_mappedtodisk); page->private = 0; set_page_refs(page, order); } /* * Do the hard work of removing an element from the buddy allocator. * Call me with the zone->lock already held. */ static struct page *__rmqueue(struct zone *zone, unsigned int order) { struct free_area * area; unsigned int current_order; struct page *page; unsigned int index; for (current_order = order; current_order < MAX_ORDER; ++current_order) { area = zone->free_area + current_order; if (list_empty(&area->free_list)) continue; page = list_entry(area->free_list.next, struct page, lru); list_del(&page->lru); index = page - zone->zone_mem_map; if (current_order != MAX_ORDER-1) MARK_USED(index, current_order, area); zone->free_pages -= 1UL << order; return expand(zone, page, index, order, current_order, area); } return NULL; } /* * Obtain a specified number of elements from the buddy allocator, all under * a single hold of the lock, for efficiency. Add them to the supplied list. * Returns the number of new pages which were placed at *list. */ static int rmqueue_bulk(struct zone *zone, unsigned int order, unsigned long count, struct list_head *list) { unsigned long flags; int i; int allocated = 0; struct page *page; spin_lock_irqsave(&zone->lock, flags); for (i = 0; i < count; ++i) { page = __rmqueue(zone, order); if (page == NULL) break; allocated++; list_add_tail(&page->lru, list); } spin_unlock_irqrestore(&zone->lock, flags); return allocated; } #if defined(CONFIG_PM) || defined(CONFIG_HOTPLUG_CPU) static void __drain_pages(unsigned int cpu) { struct zone *zone; int i; for_each_zone(zone) { struct per_cpu_pageset *pset; pset = &zone->pageset[cpu]; for (i = 0; i < ARRAY_SIZE(pset->pcp); i++) { struct per_cpu_pages *pcp; pcp = &pset->pcp[i]; pcp->count -= free_pages_bulk(zone, pcp->count, &pcp->list, 0); } } } #endif /* CONFIG_PM || CONFIG_HOTPLUG_CPU */ #ifdef CONFIG_PM int is_head_of_free_region(struct page *page) { struct zone *zone = page_zone(page); unsigned long flags; int order; struct list_head *curr; /* * Should not matter as we need quiescent system for * suspend anyway, but... */ spin_lock_irqsave(&zone->lock, flags); for (order = MAX_ORDER - 1; order >= 0; --order) list_for_each(curr, &zone->free_area[order].free_list) if (page == list_entry(curr, struct page, lru)) { spin_unlock_irqrestore(&zone->lock, flags); return 1 << order; } spin_unlock_irqrestore(&zone->lock, flags); return 0; } /* * Spill all of this CPU's per-cpu pages back into the buddy allocator. */ void drain_local_pages(void) { unsigned long flags; local_irq_save(flags); __drain_pages(smp_processor_id()); local_irq_restore(flags); } #endif /* CONFIG_PM */ static void zone_statistics(struct zonelist *zonelist, struct zone *z) { #ifdef CONFIG_NUMA unsigned long flags; int cpu; pg_data_t *pg = z->zone_pgdat; pg_data_t *orig = zonelist->zones[0]->zone_pgdat; struct per_cpu_pageset *p; local_irq_save(flags); cpu = smp_processor_id(); p = &z->pageset[cpu]; if (pg == orig) { z->pageset[cpu].numa_hit++; } else { p->numa_miss++; zonelist->zones[0]->pageset[cpu].numa_foreign++; } if (pg == NODE_DATA(numa_node_id())) p->local_node++; else p->other_node++; local_irq_restore(flags); #endif } /* * Free a 0-order page */ static void FASTCALL(free_hot_cold_page(struct page *page, int cold)); static void fastcall free_hot_cold_page(struct page *page, int cold) { struct zone *zone = page_zone(page); struct per_cpu_pages *pcp; unsigned long flags; kernel_map_pages(page, 1, 0); inc_page_state(pgfree); free_pages_check(__FUNCTION__, page); pcp = &zone->pageset[get_cpu()].pcp[cold]; local_irq_save(flags); if (pcp->count >= pcp->high) pcp->count -= free_pages_bulk(zone, pcp->batch, &pcp->list, 0); list_add(&page->lru, &pcp->list); pcp->count++; local_irq_restore(flags); put_cpu(); } void fastcall free_hot_page(struct page *page) { free_hot_cold_page(page, 0); } void fastcall free_cold_page(struct page *page) { free_hot_cold_page(page, 1); } /* * Really, prep_compound_page() should be called from __rmqueue_bulk(). But * we cheat by calling it from here, in the order > 0 path. Saves a branch * or two. */ static struct page * buffered_rmqueue(struct zone *zone, int order, int gfp_flags) { unsigned long flags; struct page *page = NULL; int cold = !!(gfp_flags & __GFP_COLD); if (order == 0) { struct per_cpu_pages *pcp; pcp = &zone->pageset[get_cpu()].pcp[cold]; local_irq_save(flags); if (pcp->count <= pcp->low) pcp->count += rmqueue_bulk(zone, 0, pcp->batch, &pcp->list); if (pcp->count) { page = list_entry(pcp->list.next, struct page, lru); list_del(&page->lru); pcp->count--; } local_irq_restore(flags); put_cpu(); } if (page == NULL) { spin_lock_irqsave(&zone->lock, flags); page = __rmqueue(zone, order); spin_unlock_irqrestore(&zone->lock, flags); } if (page != NULL) { BUG_ON(bad_range(zone, page)); mod_page_state_zone(zone, pgalloc, 1 << order); prep_new_page(page, order); if (order && (gfp_flags & __GFP_COMP)) prep_compound_page(page, order); } return page; } /* * This is the 'heart' of the zoned buddy allocator. * * Herein lies the mysterious "incremental min". That's the * * local_low = z->pages_low; * min += local_low; * * thing. The intent here is to provide additional protection to low zones for * allocation requests which _could_ use higher zones. So a GFP_HIGHMEM * request is not allowed to dip as deeply into the normal zone as a GFP_KERNEL * request. This preserves additional space in those lower zones for requests * which really do need memory from those zones. It means that on a decent * sized machine, GFP_HIGHMEM and GFP_KERNEL requests basically leave the DMA * zone untouched. */ struct page * fastcall __alloc_pages(unsigned int gfp_mask, unsigned int order, struct zonelist *zonelist) { const int wait = gfp_mask & __GFP_WAIT; unsigned long min; struct zone **zones; struct page *page; struct reclaim_state reclaim_state; struct task_struct *p = current; int i; int alloc_type; int do_retry; might_sleep_if(wait); zones = zonelist->zones; /* the list of zones suitable for gfp_mask */ if (zones[0] == NULL) /* no zones in the zonelist */ return NULL; alloc_type = zone_idx(zones[0]); /* Go through the zonelist once, looking for a zone with enough free */ for (i = 0; zones[i] != NULL; i++) { struct zone *z = zones[i]; min = (1<<order) + z->protection[alloc_type]; /* * We let real-time tasks dip their real-time paws a little * deeper into reserves. */ if (rt_task(p)) min -= z->pages_low >> 1; if (z->free_pages >= min || (!wait && z->free_pages >= z->pages_high)) { page = buffered_rmqueue(z, order, gfp_mask); if (page) { zone_statistics(zonelist, z); goto got_pg; } } } /* we're somewhat low on memory, failed to find what we needed */ for (i = 0; zones[i] != NULL; i++) wakeup_kswapd(zones[i]); /* Go through the zonelist again, taking __GFP_HIGH into account */ for (i = 0; zones[i] != NULL; i++) { struct zone *z = zones[i]; min = (1<<order) + z->protection[alloc_type]; if (gfp_mask & __GFP_HIGH) min -= z->pages_low >> 2; if (rt_task(p)) min -= z->pages_low >> 1; if (z->free_pages >= min || (!wait && z->free_pages >= z->pages_high)) { page = buffered_rmqueue(z, order, gfp_mask); if (page) { zone_statistics(zonelist, z); goto got_pg; } } } /* here we're in the low on memory slow path */ rebalance: if ((p->flags & (PF_MEMALLOC | PF_MEMDIE)) && !in_interrupt()) { /* go through the zonelist yet again, ignoring mins */ for (i = 0; zones[i] != NULL; i++) { struct zone *z = zones[i]; page = buffered_rmqueue(z, order, gfp_mask); if (page) { zone_statistics(zonelist, z); goto got_pg; } } goto nopage; } /* Atomic allocations - we can't balance anything */ if (!wait) goto nopage; p->flags |= PF_MEMALLOC; reclaim_state.reclaimed_slab = 0; p->reclaim_state = &reclaim_state; try_to_free_pages(zones, gfp_mask, order); p->reclaim_state = NULL; p->flags &= ~PF_MEMALLOC; /* go through the zonelist yet one more time */ for (i = 0; zones[i] != NULL; i++) { struct zone *z = zones[i]; min = (1UL << order) + z->protection[alloc_type]; if (z->free_pages >= min || (!wait && z->free_pages >= z->pages_high)) { page = buffered_rmqueue(z, order, gfp_mask); if (page) { zone_statistics(zonelist, z); goto got_pg; } } } /* * Don't let big-order allocations loop unless the caller explicitly * requests that. Wait for some write requests to complete then retry. * * In this implementation, __GFP_REPEAT means __GFP_NOFAIL, but that * may not be true in other implementations. */ do_retry = 0; if (!(gfp_mask & __GFP_NORETRY)) { if ((order <= 3) || (gfp_mask & __GFP_REPEAT)) do_retry = 1; if (gfp_mask & __GFP_NOFAIL) do_retry = 1; } if (do_retry) { blk_congestion_wait(WRITE, HZ/50); goto rebalance; } nopage: if (!(gfp_mask & __GFP_NOWARN) && printk_ratelimit()) { printk(KERN_WARNING "%s: page allocation failure." " order:%d, mode:0x%x\n", p->comm, order, gfp_mask); dump_stack(); } return NULL; got_pg: kernel_map_pages(page, 1 << order, 1); return page; } EXPORT_SYMBOL(__alloc_pages); /* * Common helper functions. */ fastcall unsigned long __get_free_pages(unsigned int gfp_mask, unsigned int order) { struct page * page; page = alloc_pages(gfp_mask, order); if (!page) return 0; return (unsigned long) page_address(page); } EXPORT_SYMBOL(__get_free_pages); fastcall unsigned long get_zeroed_page(unsigned int gfp_mask) { struct page * page; /* * get_zeroed_page() returns a 32-bit address, which cannot represent * a highmem page */ BUG_ON(gfp_mask & __GFP_HIGHMEM); page = alloc_pages(gfp_mask, 0); if (page) { void *address = page_address(page); clear_page(address); return (unsigned long) address; } return 0; } EXPORT_SYMBOL(get_zeroed_page); void __pagevec_free(struct pagevec *pvec) { int i = pagevec_count(pvec); while (--i >= 0) free_hot_cold_page(pvec->pages[i], pvec->cold); } fastcall void __free_pages(struct page *page, unsigned int order) { if (!PageReserved(page) && put_page_testzero(page)) { if (order == 0) free_hot_page(page); else __free_pages_ok(page, order); } } EXPORT_SYMBOL(__free_pages); fastcall void free_pages(unsigned long addr, unsigned int order) { if (addr != 0) { BUG_ON(!virt_addr_valid(addr)); __free_pages(virt_to_page(addr), order); } } EXPORT_SYMBOL(free_pages); /* * Total amount of free (allocatable) RAM: */ unsigned int nr_free_pages(void) { unsigned int sum = 0; struct zone *zone; for_each_zone(zone) sum += zone->free_pages; return sum; } EXPORT_SYMBOL(nr_free_pages); unsigned int nr_used_zone_pages(void) { unsigned int pages = 0; struct zone *zone; for_each_zone(zone) pages += zone->nr_active + zone->nr_inactive; return pages; } #ifdef CONFIG_NUMA unsigned int nr_free_pages_pgdat(pg_data_t *pgdat) { unsigned int i, sum = 0; for (i = 0; i < MAX_NR_ZONES; i++) sum += pgdat->node_zones[i].free_pages; return sum; } #endif static unsigned int nr_free_zone_pages(int offset) { pg_data_t *pgdat; unsigned int sum = 0; for_each_pgdat(pgdat) { struct zonelist *zonelist = pgdat->node_zonelists + offset; struct zone **zonep = zonelist->zones; struct zone *zone; for (zone = *zonep++; zone; zone = *zonep++) { unsigned long size = zone->present_pages; unsigned long high = zone->pages_high; if (size > high) sum += size - high; } } return sum; } /* * Amount of free RAM allocatable within ZONE_DMA and ZONE_NORMAL */ unsigned int nr_free_buffer_pages(void) { return nr_free_zone_pages(GFP_USER & GFP_ZONEMASK); } /* * Amount of free RAM allocatable within all zones */ unsigned int nr_free_pagecache_pages(void) { return nr_free_zone_pages(GFP_HIGHUSER & GFP_ZONEMASK); } #ifdef CONFIG_HIGHMEM unsigned int nr_free_highpages (void) { pg_data_t *pgdat; unsigned int pages = 0; for_each_pgdat(pgdat) pages += pgdat->node_zones[ZONE_HIGHMEM].free_pages; return pages; } #endif #ifdef CONFIG_NUMA static void show_node(struct zone *zone) { printk("Node %d ", zone->zone_pgdat->node_id); } #else #define show_node(zone) do { } while (0) #endif /* * Accumulate the page_state information across all CPUs. * The result is unavoidably approximate - it can change * during and after execution of this function. */ DEFINE_PER_CPU(struct page_state, page_states) = {0}; EXPORT_PER_CPU_SYMBOL(page_states); atomic_t nr_pagecache = ATOMIC_INIT(0); EXPORT_SYMBOL(nr_pagecache); #ifdef CONFIG_SMP DEFINE_PER_CPU(long, nr_pagecache_local) = 0; #endif void __get_page_state(struct page_state *ret, int nr) { int cpu = 0; memset(ret, 0, sizeof(*ret)); while (cpu < NR_CPUS) { unsigned long *in, *out, off; if (!cpu_possible(cpu)) { cpu++; continue; } in = (unsigned long *)&per_cpu(page_states, cpu); cpu++; if (cpu < NR_CPUS && cpu_possible(cpu)) prefetch(&per_cpu(page_states, cpu)); out = (unsigned long *)ret; for (off = 0; off < nr; off++) *out++ += *in++; } } void get_page_state(struct page_state *ret) { int nr; nr = offsetof(struct page_state, GET_PAGE_STATE_LAST); nr /= sizeof(unsigned long); __get_page_state(ret, nr + 1); } void get_full_page_state(struct page_state *ret) { __get_page_state(ret, sizeof(*ret) / sizeof(unsigned long)); } unsigned long __read_page_state(unsigned offset) { unsigned long ret = 0; int cpu; for (cpu = 0; cpu < NR_CPUS; cpu++) { unsigned long in; if (!cpu_possible(cpu)) continue; in = (unsigned long)&per_cpu(page_states, cpu) + offset; ret += *((unsigned long *)in); } return ret; } void get_zone_counts(unsigned long *active, unsigned long *inactive, unsigned long *free) { struct zone *zone; *active = 0; *inactive = 0; *free = 0; for_each_zone(zone) { *active += zone->nr_active; *inactive += zone->nr_inactive; *free += zone->free_pages; } } void si_meminfo(struct sysinfo *val) { val->totalram = totalram_pages; val->sharedram = 0; val->freeram = nr_free_pages(); val->bufferram = nr_blockdev_pages(); #ifdef CONFIG_HIGHMEM val->totalhigh = totalhigh_pages; val->freehigh = nr_free_highpages(); #else val->totalhigh = 0; val->freehigh = 0; #endif val->mem_unit = PAGE_SIZE; } EXPORT_SYMBOL(si_meminfo); #ifdef CONFIG_NUMA void si_meminfo_node(struct sysinfo *val, int nid) { pg_data_t *pgdat = NODE_DATA(nid); val->totalram = pgdat->node_present_pages; val->freeram = nr_free_pages_pgdat(pgdat); val->totalhigh = pgdat->node_zones[ZONE_HIGHMEM].present_pages; val->freehigh = pgdat->node_zones[ZONE_HIGHMEM].free_pages; val->mem_unit = PAGE_SIZE; } #endif #define K(x) ((x) << (PAGE_SHIFT-10)) /* * Show free area list (used inside shift_scroll-lock stuff) * We also calculate the percentage fragmentation. We do this by counting the * memory on each free list with the exception of the first item on the list. */ void show_free_areas(void) { struct page_state ps; int cpu, temperature; unsigned long active; unsigned long inactive; unsigned long free; struct zone *zone; for_each_zone(zone) { show_node(zone); printk("%s per-cpu:", zone->name); if (!zone->present_pages) { printk(" empty\n"); continue; } else printk("\n"); for (cpu = 0; cpu < NR_CPUS; ++cpu) { struct per_cpu_pageset *pageset; if (!cpu_possible(cpu)) continue; pageset = zone->pageset + cpu; for (temperature = 0; temperature < 2; temperature++) printk("cpu %d %s: low %d, high %d, batch %d\n", cpu, temperature ? "cold" : "hot", pageset->pcp[temperature].low, pageset->pcp[temperature].high, pageset->pcp[temperature].batch); } } get_page_state(&ps); get_zone_counts(&active, &inactive, &free); printk("\nFree pages: %11ukB (%ukB HighMem)\n", K(nr_free_pages()), K(nr_free_highpages())); printk("Active:%lu inactive:%lu dirty:%lu writeback:%lu " "unstable:%lu free:%u slab:%lu mapped:%lu pagetables:%lu\n", active, inactive, ps.nr_dirty, ps.nr_writeback, ps.nr_unstable, nr_free_pages(), ps.nr_slab, ps.nr_mapped, ps.nr_page_table_pages); for_each_zone(zone) { int i; show_node(zone); printk("%s" " free:%lukB" " min:%lukB" " low:%lukB" " high:%lukB" " active:%lukB" " inactive:%lukB" " present:%lukB" "\n", zone->name, K(zone->free_pages), K(zone->pages_min), K(zone->pages_low), K(zone->pages_high), K(zone->nr_active), K(zone->nr_inactive), K(zone->present_pages) ); printk("protections[]:"); for (i = 0; i < MAX_NR_ZONES; i++) printk(" %lu", zone->protection[i]); printk("\n"); } for_each_zone(zone) { struct list_head *elem; unsigned long nr, flags, order, total = 0; show_node(zone); printk("%s: ", zone->name); if (!zone->present_pages) { printk("empty\n"); continue; } spin_lock_irqsave(&zone->lock, flags); for (order = 0; order < MAX_ORDER; order++) { nr = 0; list_for_each(elem, &zone->free_area[order].free_list) ++nr; total += nr << order; printk("%lu*%lukB ", nr, K(1UL) << order); } spin_unlock_irqrestore(&zone->lock, flags); printk("= %lukB\n", K(total)); } show_swap_cache_info(); } /* * Builds allocation fallback zone lists. */ static int __init build_zonelists_node(pg_data_t *pgdat, struct zonelist *zonelist, int j, int k) { switch (k) { struct zone *zone; default: BUG(); case ZONE_HIGHMEM: zone = pgdat->node_zones + ZONE_HIGHMEM; if (zone->present_pages) { #ifndef CONFIG_HIGHMEM BUG(); #endif zonelist->zones[j++] = zone; } case ZONE_NORMAL: zone = pgdat->node_zones + ZONE_NORMAL; if (zone->present_pages) zonelist->zones[j++] = zone; case ZONE_DMA: zone = pgdat->node_zones + ZONE_DMA; if (zone->present_pages) zonelist->zones[j++] = zone; } return j; } #ifdef CONFIG_NUMA #define MAX_NODE_LOAD (numnodes) static int __initdata node_load[MAX_NUMNODES]; /** * find_next_best_node - find the next node that should appear in a given * node's fallback list * @node: node whose fallback list we're appending * @used_node_mask: pointer to the bitmap of already used nodes * * We use a number of factors to determine which is the next node that should * appear on a given node's fallback list. The node should not have appeared * already in @node's fallback list, and it should be the next closest node * according to the distance array (which contains arbitrary distance values * from each node to each node in the system), and should also prefer nodes * with no CPUs, since presumably they'll have very little allocation pressure * on them otherwise. * It returns -1 if no node is found. */ static int __init find_next_best_node(int node, void *used_node_mask) { int i, n, val; int min_val = INT_MAX; int best_node = -1; for (i = 0; i < numnodes; i++) { cpumask_t tmp; /* Start from local node */ n = (node+i)%numnodes; /* Don't want a node to appear more than once */ if (test_bit(n, used_node_mask)) continue; /* Use the distance array to find the distance */ val = node_distance(node, n); /* Give preference to headless and unused nodes */ tmp = node_to_cpumask(n); if (!cpus_empty(tmp)) val += PENALTY_FOR_NODE_WITH_CPUS; /* Slight preference for less loaded node */ val *= (MAX_NODE_LOAD*MAX_NUMNODES); val += node_load[n]; if (val < min_val) { min_val = val; best_node = n; } } if (best_node >= 0) set_bit(best_node, used_node_mask); return best_node; } static void __init build_zonelists(pg_data_t *pgdat) { int i, j, k, node, local_node; int prev_node, load; struct zonelist *zonelist; DECLARE_BITMAP(used_mask, MAX_NUMNODES); /* initialize zonelists */ for (i = 0; i < GFP_ZONETYPES; i++) { zonelist = pgdat->node_zonelists + i; memset(zonelist, 0, sizeof(*zonelist)); zonelist->zones[0] = NULL; } /* NUMA-aware ordering of nodes */ local_node = pgdat->node_id; load = numnodes; prev_node = local_node; bitmap_zero(used_mask, MAX_NUMNODES); while ((node = find_next_best_node(local_node, used_mask)) >= 0) { /* * We don't want to pressure a particular node. * So adding penalty to the first node in same * distance group to make it round-robin. */ if (node_distance(local_node, node) != node_distance(local_node, prev_node)) node_load[node] += load; prev_node = node; load--; for (i = 0; i < GFP_ZONETYPES; i++) { zonelist = pgdat->node_zonelists + i; for (j = 0; zonelist->zones[j] != NULL; j++); k = ZONE_NORMAL; if (i & __GFP_HIGHMEM) k = ZONE_HIGHMEM; if (i & __GFP_DMA) k = ZONE_DMA; j = build_zonelists_node(NODE_DATA(node), zonelist, j, k); zonelist->zones[j] = NULL; } } } #else /* CONFIG_NUMA */ static void __init build_zonelists(pg_data_t *pgdat) { int i, j, k, node, local_node; local_node = pgdat->node_id; for (i = 0; i < GFP_ZONETYPES; i++) { struct zonelist *zonelist; zonelist = pgdat->node_zonelists + i; memset(zonelist, 0, sizeof(*zonelist)); j = 0; k = ZONE_NORMAL; if (i & __GFP_HIGHMEM) k = ZONE_HIGHMEM; if (i & __GFP_DMA) k = ZONE_DMA; j = build_zonelists_node(pgdat, zonelist, j, k); /* * Now we build the zonelist so that it contains the zones * of all the other nodes. * We don't want to pressure a particular node, so when * building the zones for node N, we make sure that the * zones coming right after the local ones are those from * node N+1 (modulo N) */ for (node = local_node + 1; node < numnodes; node++) j = build_zonelists_node(NODE_DATA(node), zonelist, j, k); for (node = 0; node < local_node; node++) j = build_zonelists_node(NODE_DATA(node), zonelist, j, k); zonelist->zones[j] = NULL; } } #endif /* CONFIG_NUMA */ void __init build_all_zonelists(void) { int i; for(i = 0 ; i < numnodes ; i++) build_zonelists(NODE_DATA(i)); printk("Built %i zonelists\n", numnodes); } /* * Helper functions to size the waitqueue hash table. * Essentially these want to choose hash table sizes sufficiently * large so that collisions trying to wait on pages are rare. * But in fact, the number of active page waitqueues on typical * systems is ridiculously low, less than 200. So this is even * conservative, even though it seems large. * * The constant PAGES_PER_WAITQUEUE specifies the ratio of pages to * waitqueues, i.e. the size of the waitq table given the number of pages. */ #define PAGES_PER_WAITQUEUE 256 static inline unsigned long wait_table_size(unsigned long pages) { unsigned long size = 1; pages /= PAGES_PER_WAITQUEUE; while (size < pages) size <<= 1; /* * Once we have dozens or even hundreds of threads sleeping * on IO we've got bigger problems than wait queue collision. * Limit the size of the wait table to a reasonable size. */ size = min(size, 4096UL); return max(size, 4UL); } /* * This is an integer logarithm so that shifts can be used later * to extract the more random high bits from the multiplicative * hash function before the remainder is taken. */ static inline unsigned long wait_table_bits(unsigned long size) { return ffz(~size); } #define LONG_ALIGN(x) (((x)+(sizeof(long))-1)&~((sizeof(long))-1)) static void __init calculate_zone_totalpages(struct pglist_data *pgdat, unsigned long *zones_size, unsigned long *zholes_size) { unsigned long realtotalpages, totalpages = 0; int i; for (i = 0; i < MAX_NR_ZONES; i++) totalpages += zones_size[i]; pgdat->node_spanned_pages = totalpages; realtotalpages = totalpages; if (zholes_size) for (i = 0; i < MAX_NR_ZONES; i++) realtotalpages -= zholes_size[i]; pgdat->node_present_pages = realtotalpages; printk("On node %d totalpages: %lu\n", pgdat->node_id, realtotalpages); } /* * Initially all pages are reserved - free ones are freed * up by free_all_bootmem() once the early boot process is * done. Non-atomic initialization, single-pass. */ void __init memmap_init_zone(struct page *start, unsigned long size, int nid, unsigned long zone, unsigned long start_pfn) { struct page *page; for (page = start; page < (start + size); page++) { set_page_zone(page, NODEZONE(nid, zone)); set_page_count(page, 0); SetPageReserved(page); INIT_LIST_HEAD(&page->lru); #ifdef WANT_PAGE_VIRTUAL /* The shift won't overflow because ZONE_NORMAL is below 4G. */ if (!is_highmem(zone)) set_page_address(page, __va(start_pfn << PAGE_SHIFT)); #endif start_pfn++; } } #ifndef __HAVE_ARCH_MEMMAP_INIT #define memmap_init(start, size, nid, zone, start_pfn) \ memmap_init_zone((start), (size), (nid), (zone), (start_pfn)) #endif /* * Set up the zone data structures: * - mark all pages reserved * - mark all memory queues empty * - clear the memory bitmaps */ static void __init free_area_init_core(struct pglist_data *pgdat, unsigned long *zones_size, unsigned long *zholes_size) { unsigned long i, j; const unsigned long zone_required_alignment = 1UL << (MAX_ORDER-1); int cpu, nid = pgdat->node_id; struct page *lmem_map = pgdat->node_mem_map; unsigned long zone_start_pfn = pgdat->node_start_pfn; pgdat->nr_zones = 0; init_waitqueue_head(&pgdat->kswapd_wait); for (j = 0; j < MAX_NR_ZONES; j++) { struct zone *zone = pgdat->node_zones + j; unsigned long size, realsize; unsigned long batch; zone_table[NODEZONE(nid, j)] = zone; realsize = size = zones_size[j]; if (zholes_size) realsize -= zholes_size[j]; if (j == ZONE_DMA || j == ZONE_NORMAL) nr_kernel_pages += realsize; nr_all_pages += realsize; zone->spanned_pages = size; zone->present_pages = realsize; zone->name = zone_names[j]; spin_lock_init(&zone->lock); spin_lock_init(&zone->lru_lock); zone->zone_pgdat = pgdat; zone->free_pages = 0; zone->temp_priority = zone->prev_priority = DEF_PRIORITY; /* * The per-cpu-pages pools are set to around 1000th of the * size of the zone. But no more than 1/4 of a meg - there's * no point in going beyond the size of L2 cache. * * OK, so we don't know how big the cache is. So guess. */ batch = zone->present_pages / 1024; if (batch * PAGE_SIZE > 256 * 1024) batch = (256 * 1024) / PAGE_SIZE; batch /= 4; /* We effectively *= 4 below */ if (batch < 1) batch = 1; for (cpu = 0; cpu < NR_CPUS; cpu++) { struct per_cpu_pages *pcp; pcp = &zone->pageset[cpu].pcp[0]; /* hot */ pcp->count = 0; pcp->low = 2 * batch; pcp->high = 6 * batch; pcp->batch = 1 * batch; INIT_LIST_HEAD(&pcp->list); pcp = &zone->pageset[cpu].pcp[1]; /* cold */ pcp->count = 0; pcp->low = 0; pcp->high = 2 * batch; pcp->batch = 1 * batch; INIT_LIST_HEAD(&pcp->list); } printk(" %s zone: %lu pages, LIFO batch:%lu\n", zone_names[j], realsize, batch); INIT_LIST_HEAD(&zone->active_list); INIT_LIST_HEAD(&zone->inactive_list); zone->nr_scan_active = 0; zone->nr_scan_inactive = 0; zone->nr_active = 0; zone->nr_inactive = 0; if (!size) continue; /* * The per-page waitqueue mechanism uses hashed waitqueues * per zone. */ zone->wait_table_size = wait_table_size(size); zone->wait_table_bits = wait_table_bits(zone->wait_table_size); zone->wait_table = (wait_queue_head_t *) alloc_bootmem_node(pgdat, zone->wait_table_size * sizeof(wait_queue_head_t)); for(i = 0; i < zone->wait_table_size; ++i) init_waitqueue_head(zone->wait_table + i); pgdat->nr_zones = j+1; zone->zone_mem_map = lmem_map; zone->zone_start_pfn = zone_start_pfn; if ((zone_start_pfn) & (zone_required_alignment-1)) printk("BUG: wrong zone alignment, it will crash\n"); memmap_init(lmem_map, size, nid, j, zone_start_pfn); zone_start_pfn += size; lmem_map += size; for (i = 0; ; i++) { unsigned long bitmap_size; INIT_LIST_HEAD(&zone->free_area[i].free_list); if (i == MAX_ORDER-1) { zone->free_area[i].map = NULL; break; } /* * Page buddy system uses "index >> (i+1)", * where "index" is at most "size-1". * * The extra "+3" is to round down to byte * size (8 bits per byte assumption). Thus * we get "(size-1) >> (i+4)" as the last byte * we can access. * * The "+1" is because we want to round the * byte allocation up rather than down. So * we should have had a "+7" before we shifted * down by three. Also, we have to add one as * we actually _use_ the last bit (it's [0,n] * inclusive, not [0,n[). * * So we actually had +7+1 before we shift * down by 3. But (n+8) >> 3 == (n >> 3) + 1 * (modulo overflows, which we do not have). * * Finally, we LONG_ALIGN because all bitmap * operations are on longs. */ bitmap_size = (size-1) >> (i+4); bitmap_size = LONG_ALIGN(bitmap_size+1); zone->free_area[i].map = (unsigned long *) alloc_bootmem_node(pgdat, bitmap_size); } } } void __init free_area_init_node(int nid, struct pglist_data *pgdat, struct page *node_mem_map, unsigned long *zones_size, unsigned long node_start_pfn, unsigned long *zholes_size) { unsigned long size; pgdat->node_id = nid; pgdat->node_start_pfn = node_start_pfn; calculate_zone_totalpages(pgdat, zones_size, zholes_size); if (!node_mem_map) { size = (pgdat->node_spanned_pages + 1) * sizeof(struct page); node_mem_map = alloc_bootmem_node(pgdat, size); } pgdat->node_mem_map = node_mem_map; free_area_init_core(pgdat, zones_size, zholes_size); } #ifndef CONFIG_DISCONTIGMEM static bootmem_data_t contig_bootmem_data; struct pglist_data contig_page_data = { .bdata = &contig_bootmem_data }; EXPORT_SYMBOL(contig_page_data); void __init free_area_init(unsigned long *zones_size) { free_area_init_node(0, &contig_page_data, NULL, zones_size, __pa(PAGE_OFFSET) >> PAGE_SHIFT, NULL); mem_map = contig_page_data.node_mem_map; } #endif #ifdef CONFIG_PROC_FS #include <linux/seq_file.h> static void *frag_start(struct seq_file *m, loff_t *pos) { pg_data_t *pgdat; loff_t node = *pos; for (pgdat = pgdat_list; pgdat && node; pgdat = pgdat->pgdat_next) --node; return pgdat; } static void *frag_next(struct seq_file *m, void *arg, loff_t *pos) { pg_data_t *pgdat = (pg_data_t *)arg; (*pos)++; return pgdat->pgdat_next; } static void frag_stop(struct seq_file *m, void *arg) { } /* * This walks the freelist for each zone. Whilst this is slow, I'd rather * be slow here than slow down the fast path by keeping stats - mjbligh */ static int frag_show(struct seq_file *m, void *arg) { pg_data_t *pgdat = (pg_data_t *)arg; struct zone *zone; struct zone *node_zones = pgdat->node_zones; unsigned long flags; int order; for (zone = node_zones; zone - node_zones < MAX_NR_ZONES; ++zone) { if (!zone->present_pages) continue; spin_lock_irqsave(&zone->lock, flags); seq_printf(m, "Node %d, zone %8s ", pgdat->node_id, zone->name); for (order = 0; order < MAX_ORDER; ++order) { unsigned long nr_bufs = 0; struct list_head *elem; list_for_each(elem, &(zone->free_area[order].free_list)) ++nr_bufs; seq_printf(m, "%6lu ", nr_bufs); } spin_unlock_irqrestore(&zone->lock, flags); seq_putc(m, '\n'); } return 0; } struct seq_operations fragmentation_op = { .start = frag_start, .next = frag_next, .stop = frag_stop, .show = frag_show, }; static char *vmstat_text[] = { "nr_dirty", "nr_writeback", "nr_unstable", "nr_page_table_pages", "nr_mapped", "nr_slab", "pgpgin", "pgpgout", "pswpin", "pswpout", "pgalloc_high", "pgalloc_normal", "pgalloc_dma", "pgfree", "pgactivate", "pgdeactivate", "pgfault", "pgmajfault", "pgrefill_high", "pgrefill_normal", "pgrefill_dma", "pgsteal_high", "pgsteal_normal", "pgsteal_dma", "pgscan_kswapd_high", "pgscan_kswapd_normal", "pgscan_kswapd_dma", "pgscan_direct_high", "pgscan_direct_normal", "pgscan_direct_dma", "pginodesteal", "slabs_scanned", "kswapd_steal", "kswapd_inodesteal", "pageoutrun", "allocstall", "pgrotated", }; static void *vmstat_start(struct seq_file *m, loff_t *pos) { struct page_state *ps; if (*pos >= ARRAY_SIZE(vmstat_text)) return NULL; ps = kmalloc(sizeof(*ps), GFP_KERNEL); m->private = ps; if (!ps) return ERR_PTR(-ENOMEM); get_full_page_state(ps); ps->pgpgin /= 2; /* sectors -> kbytes */ ps->pgpgout /= 2; return (unsigned long *)ps + *pos; } static void *vmstat_next(struct seq_file *m, void *arg, loff_t *pos) { (*pos)++; if (*pos >= ARRAY_SIZE(vmstat_text)) return NULL; return (unsigned long *)m->private + *pos; } static int vmstat_show(struct seq_file *m, void *arg) { unsigned long *l = arg; unsigned long off = l - (unsigned long *)m->private; seq_printf(m, "%s %lu\n", vmstat_text[off], *l); return 0; } static void vmstat_stop(struct seq_file *m, void *arg) { kfree(m->private); m->private = NULL; } struct seq_operations vmstat_op = { .start = vmstat_start, .next = vmstat_next, .stop = vmstat_stop, .show = vmstat_show, }; #endif /* CONFIG_PROC_FS */ #ifdef CONFIG_HOTPLUG_CPU static int page_alloc_cpu_notify(struct notifier_block *self, unsigned long action, void *hcpu) { int cpu = (unsigned long)hcpu; long *count; if (action == CPU_DEAD) { /* Drain local pagecache count. */ count = &per_cpu(nr_pagecache_local, cpu); atomic_add(*count, &nr_pagecache); *count = 0; local_irq_disable(); __drain_pages(cpu); local_irq_enable(); } return NOTIFY_OK; } #endif /* CONFIG_HOTPLUG_CPU */ void __init page_alloc_init(void) { hotcpu_notifier(page_alloc_cpu_notify, 0); } static unsigned long higherzone_val(struct zone *z, int max_zone, int alloc_type) { int z_idx = zone_idx(z); struct zone *higherzone; unsigned long pages; /* there is no higher zone to get a contribution from */ if (z_idx == MAX_NR_ZONES-1) return 0; higherzone = &z->zone_pgdat->node_zones[z_idx+1]; /* We always start with the higher zone's protection value */ pages = higherzone->protection[alloc_type]; /* * We get a lower-zone-protection contribution only if there are * pages in the higher zone and if we're not the highest zone * in the current zonelist. e.g., never happens for GFP_DMA. Happens * only for ZONE_DMA in a GFP_KERNEL allocation and happens for ZONE_DMA * and ZONE_NORMAL for a GFP_HIGHMEM allocation. */ if (higherzone->present_pages && z_idx < alloc_type) pages += higherzone->pages_low * sysctl_lower_zone_protection; return pages; } /* * setup_per_zone_protection - called whenver min_free_kbytes or * sysctl_lower_zone_protection changes. Ensures that each zone * has a correct pages_protected value, so an adequate number of * pages are left in the zone after a successful __alloc_pages(). * * This algorithm is way confusing. I tries to keep the same behavior * as we had with the incremental min iterative algorithm. */ static void setup_per_zone_protection(void) { struct pglist_data *pgdat; struct zone *zones, *zone; int max_zone; int i, j; for_each_pgdat(pgdat) { zones = pgdat->node_zones; for (i = 0, max_zone = 0; i < MAX_NR_ZONES; i++) if (zones[i].present_pages) max_zone = i; /* * For each of the different allocation types: * GFP_DMA -> GFP_KERNEL -> GFP_HIGHMEM */ for (i = 0; i < GFP_ZONETYPES; i++) { /* * For each of the zones: * ZONE_HIGHMEM -> ZONE_NORMAL -> ZONE_DMA */ for (j = MAX_NR_ZONES-1; j >= 0; j--) { zone = &zones[j]; /* * We never protect zones that don't have memory * in them (j>max_zone) or zones that aren't in * the zonelists for a certain type of * allocation (j>i). We have to assign these to * zero because the lower zones take * contributions from the higher zones. */ if (j > max_zone || j > i) { zone->protection[i] = 0; continue; } /* * The contribution of the next higher zone */ zone->protection[i] = higherzone_val(zone, max_zone, i); zone->protection[i] += zone->pages_low; } } } } /* * setup_per_zone_pages_min - called when min_free_kbytes changes. Ensures * that the pages_{min,low,high} values for each zone are set correctly * with respect to min_free_kbytes. */ static void setup_per_zone_pages_min(void) { unsigned long pages_min = min_free_kbytes >> (PAGE_SHIFT - 10); unsigned long lowmem_pages = 0; struct zone *zone; unsigned long flags; /* Calculate total number of !ZONE_HIGHMEM pages */ for_each_zone(zone) { if (!is_highmem(zone)) lowmem_pages += zone->present_pages; } for_each_zone(zone) { spin_lock_irqsave(&zone->lru_lock, flags); if (is_highmem(zone)) { /* * Often, highmem doesn't need to reserve any pages. * But the pages_min/low/high values are also used for * batching up page reclaim activity so we need a * decent value here. */ int min_pages; min_pages = zone->present_pages / 1024; if (min_pages < SWAP_CLUSTER_MAX) min_pages = SWAP_CLUSTER_MAX; if (min_pages > 128) min_pages = 128; zone->pages_min = min_pages; } else { /* if it's a lowmem zone, reserve a number of pages * proportionate to the zone's size. */ zone->pages_min = (pages_min * zone->present_pages) / lowmem_pages; } zone->pages_low = zone->pages_min * 2; zone->pages_high = zone->pages_min * 3; spin_unlock_irqrestore(&zone->lru_lock, flags); } } /* * Initialise min_free_kbytes. * * For small machines we want it small (128k min). For large machines * we want it large (16MB max). But it is not linear, because network * bandwidth does not increase linearly with machine size. We use * * min_free_kbytes = sqrt(lowmem_kbytes) * * which yields * * 16MB: 128k * 32MB: 181k * 64MB: 256k * 128MB: 362k * 256MB: 512k * 512MB: 724k * 1024MB: 1024k * 2048MB: 1448k * 4096MB: 2048k * 8192MB: 2896k * 16384MB: 4096k */ static int __init init_per_zone_pages_min(void) { unsigned long lowmem_kbytes; lowmem_kbytes = nr_free_buffer_pages() * (PAGE_SIZE >> 10); min_free_kbytes = int_sqrt(lowmem_kbytes); if (min_free_kbytes < 128) min_free_kbytes = 128; if (min_free_kbytes > 16384) min_free_kbytes = 16384; setup_per_zone_pages_min(); setup_per_zone_protection(); return 0; } module_init(init_per_zone_pages_min) /* * min_free_kbytes_sysctl_handler - just a wrapper around proc_dointvec() so * that we can call two helper functions whenever min_free_kbytes * changes. */ int min_free_kbytes_sysctl_handler(ctl_table *table, int write, struct file *file, void __user *buffer, size_t *length) { proc_dointvec(table, write, file, buffer, length); setup_per_zone_pages_min(); setup_per_zone_protection(); return 0; } /* * lower_zone_protection_sysctl_handler - just a wrapper around * proc_dointvec() so that we can call setup_per_zone_protection() * whenever sysctl_lower_zone_protection changes. */ int lower_zone_protection_sysctl_handler(ctl_table *table, int write, struct file *file, void __user *buffer, size_t *length) { proc_dointvec_minmax(table, write, file, buffer, length); setup_per_zone_protection(); return 0; } /* * allocate a large system hash table from bootmem * - it is assumed that the hash table must contain an exact power-of-2 * quantity of entries */ void *__init alloc_large_system_hash(const char *tablename, unsigned long bucketsize, unsigned long numentries, int scale, int consider_highmem, unsigned int *_hash_shift, unsigned int *_hash_mask) { unsigned long mem, max, log2qty, size; void *table; /* round applicable memory size up to nearest megabyte */ mem = consider_highmem ? nr_all_pages : nr_kernel_pages; mem += (1UL << (20 - PAGE_SHIFT)) - 1; mem >>= 20 - PAGE_SHIFT; mem <<= 20 - PAGE_SHIFT; /* limit to 1 bucket per 2^scale bytes of low memory (rounded up to * nearest power of 2 in size) */ if (scale > PAGE_SHIFT) mem >>= (scale - PAGE_SHIFT); else mem <<= (PAGE_SHIFT - scale); mem = 1UL << (long_log2(mem) + 1); /* limit allocation size */ max = (1UL << (PAGE_SHIFT + MAX_SYS_HASH_TABLE_ORDER)) / bucketsize; if (max > mem) max = mem; /* allow the kernel cmdline to have a say */ if (!numentries || numentries > max) numentries = max; log2qty = long_log2(numentries); do { size = bucketsize << log2qty; table = (void *) alloc_bootmem(size); } while (!table && size > PAGE_SIZE); if (!table) panic("Failed to allocate %s hash table\n", tablename); printk("%s hash table entries: %d (order: %d, %lu bytes)\n", tablename, (1U << log2qty), long_log2(size) - PAGE_SHIFT, size); if (_hash_shift) *_hash_shift = log2qty; if (_hash_mask) *_hash_mask = (1 << log2qty) - 1; return table; } |