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author | Linus Torvalds <torvalds@ppc970.osdl.org> | 2005-04-16 15:20:36 -0700 |
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committer | Linus Torvalds <torvalds@ppc970.osdl.org> | 2005-04-16 15:20:36 -0700 |
commit | 1da177e4c3f41524e886b7f1b8a0c1fc7321cac2 (patch) | |
tree | 0bba044c4ce775e45a88a51686b5d9f90697ea9d /Documentation/vm | |
download | linux-1da177e4c3f41524e886b7f1b8a0c1fc7321cac2.tar.gz linux-1da177e4c3f41524e886b7f1b8a0c1fc7321cac2.tar.bz2 linux-1da177e4c3f41524e886b7f1b8a0c1fc7321cac2.zip |
Linux-2.6.12-rc2v2.6.12-rc2
Initial git repository build. I'm not bothering with the full history,
even though we have it. We can create a separate "historical" git
archive of that later if we want to, and in the meantime it's about
3.2GB when imported into git - space that would just make the early
git days unnecessarily complicated, when we don't have a lot of good
infrastructure for it.
Let it rip!
Diffstat (limited to 'Documentation/vm')
-rw-r--r-- | Documentation/vm/balance | 93 | ||||
-rw-r--r-- | Documentation/vm/hugetlbpage.txt | 284 | ||||
-rw-r--r-- | Documentation/vm/locking | 131 | ||||
-rw-r--r-- | Documentation/vm/numa | 41 | ||||
-rw-r--r-- | Documentation/vm/overcommit-accounting | 73 |
5 files changed, 622 insertions, 0 deletions
diff --git a/Documentation/vm/balance b/Documentation/vm/balance new file mode 100644 index 000000000000..bd3d31bc4915 --- /dev/null +++ b/Documentation/vm/balance @@ -0,0 +1,93 @@ +Started Jan 2000 by Kanoj Sarcar <kanoj@sgi.com> + +Memory balancing is needed for non __GFP_WAIT as well as for non +__GFP_IO allocations. + +There are two reasons to be requesting non __GFP_WAIT allocations: +the caller can not sleep (typically intr context), or does not want +to incur cost overheads of page stealing and possible swap io for +whatever reasons. + +__GFP_IO allocation requests are made to prevent file system deadlocks. + +In the absence of non sleepable allocation requests, it seems detrimental +to be doing balancing. Page reclamation can be kicked off lazily, that +is, only when needed (aka zone free memory is 0), instead of making it +a proactive process. + +That being said, the kernel should try to fulfill requests for direct +mapped pages from the direct mapped pool, instead of falling back on +the dma pool, so as to keep the dma pool filled for dma requests (atomic +or not). A similar argument applies to highmem and direct mapped pages. +OTOH, if there is a lot of free dma pages, it is preferable to satisfy +regular memory requests by allocating one from the dma pool, instead +of incurring the overhead of regular zone balancing. + +In 2.2, memory balancing/page reclamation would kick off only when the +_total_ number of free pages fell below 1/64 th of total memory. With the +right ratio of dma and regular memory, it is quite possible that balancing +would not be done even when the dma zone was completely empty. 2.2 has +been running production machines of varying memory sizes, and seems to be +doing fine even with the presence of this problem. In 2.3, due to +HIGHMEM, this problem is aggravated. + +In 2.3, zone balancing can be done in one of two ways: depending on the +zone size (and possibly of the size of lower class zones), we can decide +at init time how many free pages we should aim for while balancing any +zone. The good part is, while balancing, we do not need to look at sizes +of lower class zones, the bad part is, we might do too frequent balancing +due to ignoring possibly lower usage in the lower class zones. Also, +with a slight change in the allocation routine, it is possible to reduce +the memclass() macro to be a simple equality. + +Another possible solution is that we balance only when the free memory +of a zone _and_ all its lower class zones falls below 1/64th of the +total memory in the zone and its lower class zones. This fixes the 2.2 +balancing problem, and stays as close to 2.2 behavior as possible. Also, +the balancing algorithm works the same way on the various architectures, +which have different numbers and types of zones. If we wanted to get +fancy, we could assign different weights to free pages in different +zones in the future. + +Note that if the size of the regular zone is huge compared to dma zone, +it becomes less significant to consider the free dma pages while +deciding whether to balance the regular zone. The first solution +becomes more attractive then. + +The appended patch implements the second solution. It also "fixes" two +problems: first, kswapd is woken up as in 2.2 on low memory conditions +for non-sleepable allocations. Second, the HIGHMEM zone is also balanced, +so as to give a fighting chance for replace_with_highmem() to get a +HIGHMEM page, as well as to ensure that HIGHMEM allocations do not +fall back into regular zone. This also makes sure that HIGHMEM pages +are not leaked (for example, in situations where a HIGHMEM page is in +the swapcache but is not being used by anyone) + +kswapd also needs to know about the zones it should balance. kswapd is +primarily needed in a situation where balancing can not be done, +probably because all allocation requests are coming from intr context +and all process contexts are sleeping. For 2.3, kswapd does not really +need to balance the highmem zone, since intr context does not request +highmem pages. kswapd looks at the zone_wake_kswapd field in the zone +structure to decide whether a zone needs balancing. + +Page stealing from process memory and shm is done if stealing the page would +alleviate memory pressure on any zone in the page's node that has fallen below +its watermark. + +pages_min/pages_low/pages_high/low_on_memory/zone_wake_kswapd: These are +per-zone fields, used to determine when a zone needs to be balanced. When +the number of pages falls below pages_min, the hysteric field low_on_memory +gets set. This stays set till the number of free pages becomes pages_high. +When low_on_memory is set, page allocation requests will try to free some +pages in the zone (providing GFP_WAIT is set in the request). Orthogonal +to this, is the decision to poke kswapd to free some zone pages. That +decision is not hysteresis based, and is done when the number of free +pages is below pages_low; in which case zone_wake_kswapd is also set. + + +(Good) Ideas that I have heard: +1. Dynamic experience should influence balancing: number of failed requests +for a zone can be tracked and fed into the balancing scheme (jalvo@mbay.net) +2. Implement a replace_with_highmem()-like replace_with_regular() to preserve +dma pages. (lkd@tantalophile.demon.co.uk) diff --git a/Documentation/vm/hugetlbpage.txt b/Documentation/vm/hugetlbpage.txt new file mode 100644 index 000000000000..1b9bcd1fe98b --- /dev/null +++ b/Documentation/vm/hugetlbpage.txt @@ -0,0 +1,284 @@ + +The intent of this file is to give a brief summary of hugetlbpage support in +the Linux kernel. This support is built on top of multiple page size support +that is provided by most modern architectures. For example, i386 +architecture supports 4K and 4M (2M in PAE mode) page sizes, ia64 +architecture supports multiple page sizes 4K, 8K, 64K, 256K, 1M, 4M, 16M, +256M and ppc64 supports 4K and 16M. A TLB is a cache of virtual-to-physical +translations. Typically this is a very scarce resource on processor. +Operating systems try to make best use of limited number of TLB resources. +This optimization is more critical now as bigger and bigger physical memories +(several GBs) are more readily available. + +Users can use the huge page support in Linux kernel by either using the mmap +system call or standard SYSv shared memory system calls (shmget, shmat). + +First the Linux kernel needs to be built with CONFIG_HUGETLB_PAGE (present +under Processor types and feature) and CONFIG_HUGETLBFS (present under file +system option on config menu) config options. + +The kernel built with hugepage support should show the number of configured +hugepages in the system by running the "cat /proc/meminfo" command. + +/proc/meminfo also provides information about the total number of hugetlb +pages configured in the kernel. It also displays information about the +number of free hugetlb pages at any time. It also displays information about +the configured hugepage size - this is needed for generating the proper +alignment and size of the arguments to the above system calls. + +The output of "cat /proc/meminfo" will have output like: + +..... +HugePages_Total: xxx +HugePages_Free: yyy +Hugepagesize: zzz KB + +/proc/filesystems should also show a filesystem of type "hugetlbfs" configured +in the kernel. + +/proc/sys/vm/nr_hugepages indicates the current number of configured hugetlb +pages in the kernel. Super user can dynamically request more (or free some +pre-configured) hugepages. +The allocation( or deallocation) of hugetlb pages is posible only if there are +enough physically contiguous free pages in system (freeing of hugepages is +possible only if there are enough hugetlb pages free that can be transfered +back to regular memory pool). + +Pages that are used as hugetlb pages are reserved inside the kernel and can +not be used for other purposes. + +Once the kernel with Hugetlb page support is built and running, a user can +use either the mmap system call or shared memory system calls to start using +the huge pages. It is required that the system administrator preallocate +enough memory for huge page purposes. + +Use the following command to dynamically allocate/deallocate hugepages: + + echo 20 > /proc/sys/vm/nr_hugepages + +This command will try to configure 20 hugepages in the system. The success +or failure of allocation depends on the amount of physically contiguous +memory that is preset in system at this time. System administrators may want +to put this command in one of the local rc init file. This will enable the +kernel to request huge pages early in the boot process (when the possibility +of getting physical contiguous pages is still very high). + +If the user applications are going to request hugepages using mmap system +call, then it is required that system administrator mount a file system of +type hugetlbfs: + + mount none /mnt/huge -t hugetlbfs <uid=value> <gid=value> <mode=value> + <size=value> <nr_inodes=value> + +This command mounts a (pseudo) filesystem of type hugetlbfs on the directory +/mnt/huge. Any files created on /mnt/huge uses hugepages. The uid and gid +options sets the owner and group of the root of the file system. By default +the uid and gid of the current process are taken. The mode option sets the +mode of root of file system to value & 0777. This value is given in octal. +By default the value 0755 is picked. The size option sets the maximum value of +memory (huge pages) allowed for that filesystem (/mnt/huge). The size is +rounded down to HPAGE_SIZE. The option nr_inode sets the maximum number of +inodes that /mnt/huge can use. If the size or nr_inode options are not +provided on command line then no limits are set. For size and nr_inodes +options, you can use [G|g]/[M|m]/[K|k] to represent giga/mega/kilo. For +example, size=2K has the same meaning as size=2048. An example is given at +the end of this document. + +read and write system calls are not supported on files that reside on hugetlb +file systems. + +A regular chown, chgrp and chmod commands (with right permissions) could be +used to change the file attributes on hugetlbfs. + +Also, it is important to note that no such mount command is required if the +applications are going to use only shmat/shmget system calls. Users who +wish to use hugetlb page via shared memory segment should be a member of +a supplementary group and system admin needs to configure that gid into +/proc/sys/vm/hugetlb_shm_group. It is possible for same or different +applications to use any combination of mmaps and shm* calls. Though the +mount of filesystem will be required for using mmaps. + +******************************************************************* + +/* + * Example of using hugepage memory in a user application using Sys V shared + * memory system calls. In this example the app is requesting 256MB of + * memory that is backed by huge pages. The application uses the flag + * SHM_HUGETLB in the shmget system call to inform the kernel that it is + * requesting hugepages. + * + * For the ia64 architecture, the Linux kernel reserves Region number 4 for + * hugepages. That means the addresses starting with 0x800000... will need + * to be specified. Specifying a fixed address is not required on ppc64, + * i386 or x86_64. + * + * Note: The default shared memory limit is quite low on many kernels, + * you may need to increase it via: + * + * echo 268435456 > /proc/sys/kernel/shmmax + * + * This will increase the maximum size per shared memory segment to 256MB. + * The other limit that you will hit eventually is shmall which is the + * total amount of shared memory in pages. To set it to 16GB on a system + * with a 4kB pagesize do: + * + * echo 4194304 > /proc/sys/kernel/shmall + */ +#include <stdlib.h> +#include <stdio.h> +#include <sys/types.h> +#include <sys/ipc.h> +#include <sys/shm.h> +#include <sys/mman.h> + +#ifndef SHM_HUGETLB +#define SHM_HUGETLB 04000 +#endif + +#define LENGTH (256UL*1024*1024) + +#define dprintf(x) printf(x) + +/* Only ia64 requires this */ +#ifdef __ia64__ +#define ADDR (void *)(0x8000000000000000UL) +#define SHMAT_FLAGS (SHM_RND) +#else +#define ADDR (void *)(0x0UL) +#define SHMAT_FLAGS (0) +#endif + +int main(void) +{ + int shmid; + unsigned long i; + char *shmaddr; + + if ((shmid = shmget(2, LENGTH, + SHM_HUGETLB | IPC_CREAT | SHM_R | SHM_W)) < 0) { + perror("shmget"); + exit(1); + } + printf("shmid: 0x%x\n", shmid); + + shmaddr = shmat(shmid, ADDR, SHMAT_FLAGS); + if (shmaddr == (char *)-1) { + perror("Shared memory attach failure"); + shmctl(shmid, IPC_RMID, NULL); + exit(2); + } + printf("shmaddr: %p\n", shmaddr); + + dprintf("Starting the writes:\n"); + for (i = 0; i < LENGTH; i++) { + shmaddr[i] = (char)(i); + if (!(i % (1024 * 1024))) + dprintf("."); + } + dprintf("\n"); + + dprintf("Starting the Check..."); + for (i = 0; i < LENGTH; i++) + if (shmaddr[i] != (char)i) + printf("\nIndex %lu mismatched\n", i); + dprintf("Done.\n"); + + if (shmdt((const void *)shmaddr) != 0) { + perror("Detach failure"); + shmctl(shmid, IPC_RMID, NULL); + exit(3); + } + + shmctl(shmid, IPC_RMID, NULL); + + return 0; +} + +******************************************************************* + +/* + * Example of using hugepage memory in a user application using the mmap + * system call. Before running this application, make sure that the + * administrator has mounted the hugetlbfs filesystem (on some directory + * like /mnt) using the command mount -t hugetlbfs nodev /mnt. In this + * example, the app is requesting memory of size 256MB that is backed by + * huge pages. + * + * For ia64 architecture, Linux kernel reserves Region number 4 for hugepages. + * That means the addresses starting with 0x800000... will need to be + * specified. Specifying a fixed address is not required on ppc64, i386 + * or x86_64. + */ +#include <stdlib.h> +#include <stdio.h> +#include <unistd.h> +#include <sys/mman.h> +#include <fcntl.h> + +#define FILE_NAME "/mnt/hugepagefile" +#define LENGTH (256UL*1024*1024) +#define PROTECTION (PROT_READ | PROT_WRITE) + +/* Only ia64 requires this */ +#ifdef __ia64__ +#define ADDR (void *)(0x8000000000000000UL) +#define FLAGS (MAP_SHARED | MAP_FIXED) +#else +#define ADDR (void *)(0x0UL) +#define FLAGS (MAP_SHARED) +#endif + +void check_bytes(char *addr) +{ + printf("First hex is %x\n", *((unsigned int *)addr)); +} + +void write_bytes(char *addr) +{ + unsigned long i; + + for (i = 0; i < LENGTH; i++) + *(addr + i) = (char)i; +} + +void read_bytes(char *addr) +{ + unsigned long i; + + check_bytes(addr); + for (i = 0; i < LENGTH; i++) + if (*(addr + i) != (char)i) { + printf("Mismatch at %lu\n", i); + break; + } +} + +int main(void) +{ + void *addr; + int fd; + + fd = open(FILE_NAME, O_CREAT | O_RDWR, 0755); + if (fd < 0) { + perror("Open failed"); + exit(1); + } + + addr = mmap(ADDR, LENGTH, PROTECTION, FLAGS, fd, 0); + if (addr == MAP_FAILED) { + perror("mmap"); + unlink(FILE_NAME); + exit(1); + } + + printf("Returned address is %p\n", addr); + check_bytes(addr); + write_bytes(addr); + read_bytes(addr); + + munmap(addr, LENGTH); + close(fd); + unlink(FILE_NAME); + + return 0; +} diff --git a/Documentation/vm/locking b/Documentation/vm/locking new file mode 100644 index 000000000000..c3ef09ae3bb1 --- /dev/null +++ b/Documentation/vm/locking @@ -0,0 +1,131 @@ +Started Oct 1999 by Kanoj Sarcar <kanojsarcar@yahoo.com> + +The intent of this file is to have an uptodate, running commentary +from different people about how locking and synchronization is done +in the Linux vm code. + +page_table_lock & mmap_sem +-------------------------------------- + +Page stealers pick processes out of the process pool and scan for +the best process to steal pages from. To guarantee the existence +of the victim mm, a mm_count inc and a mmdrop are done in swap_out(). +Page stealers hold kernel_lock to protect against a bunch of races. +The vma list of the victim mm is also scanned by the stealer, +and the page_table_lock is used to preserve list sanity against the +process adding/deleting to the list. This also guarantees existence +of the vma. Vma existence is not guaranteed once try_to_swap_out() +drops the page_table_lock. To guarantee the existence of the underlying +file structure, a get_file is done before the swapout() method is +invoked. The page passed into swapout() is guaranteed not to be reused +for a different purpose because the page reference count due to being +present in the user's pte is not released till after swapout() returns. + +Any code that modifies the vmlist, or the vm_start/vm_end/ +vm_flags:VM_LOCKED/vm_next of any vma *in the list* must prevent +kswapd from looking at the chain. + +The rules are: +1. To scan the vmlist (look but don't touch) you must hold the + mmap_sem with read bias, i.e. down_read(&mm->mmap_sem) +2. To modify the vmlist you need to hold the mmap_sem with + read&write bias, i.e. down_write(&mm->mmap_sem) *AND* + you need to take the page_table_lock. +3. The swapper takes _just_ the page_table_lock, this is done + because the mmap_sem can be an extremely long lived lock + and the swapper just cannot sleep on that. +4. The exception to this rule is expand_stack, which just + takes the read lock and the page_table_lock, this is ok + because it doesn't really modify fields anybody relies on. +5. You must be able to guarantee that while holding page_table_lock + or page_table_lock of mm A, you will not try to get either lock + for mm B. + +The caveats are: +1. find_vma() makes use of, and updates, the mmap_cache pointer hint. +The update of mmap_cache is racy (page stealer can race with other code +that invokes find_vma with mmap_sem held), but that is okay, since it +is a hint. This can be fixed, if desired, by having find_vma grab the +page_table_lock. + + +Code that add/delete elements from the vmlist chain are +1. callers of insert_vm_struct +2. callers of merge_segments +3. callers of avl_remove + +Code that changes vm_start/vm_end/vm_flags:VM_LOCKED of vma's on +the list: +1. expand_stack +2. mprotect +3. mlock +4. mremap + +It is advisable that changes to vm_start/vm_end be protected, although +in some cases it is not really needed. Eg, vm_start is modified by +expand_stack(), it is hard to come up with a destructive scenario without +having the vmlist protection in this case. + +The page_table_lock nests with the inode i_mmap_lock and the kmem cache +c_spinlock spinlocks. This is okay, since the kmem code asks for pages after +dropping c_spinlock. The page_table_lock also nests with pagecache_lock and +pagemap_lru_lock spinlocks, and no code asks for memory with these locks +held. + +The page_table_lock is grabbed while holding the kernel_lock spinning monitor. + +The page_table_lock is a spin lock. + +Note: PTL can also be used to guarantee that no new clones using the +mm start up ... this is a loose form of stability on mm_users. For +example, it is used in copy_mm to protect against a racing tlb_gather_mmu +single address space optimization, so that the zap_page_range (from +vmtruncate) does not lose sending ipi's to cloned threads that might +be spawned underneath it and go to user mode to drag in pte's into tlbs. + +swap_list_lock/swap_device_lock +------------------------------- +The swap devices are chained in priority order from the "swap_list" header. +The "swap_list" is used for the round-robin swaphandle allocation strategy. +The #free swaphandles is maintained in "nr_swap_pages". These two together +are protected by the swap_list_lock. + +The swap_device_lock, which is per swap device, protects the reference +counts on the corresponding swaphandles, maintained in the "swap_map" +array, and the "highest_bit" and "lowest_bit" fields. + +Both of these are spinlocks, and are never acquired from intr level. The +locking hierarchy is swap_list_lock -> swap_device_lock. + +To prevent races between swap space deletion or async readahead swapins +deciding whether a swap handle is being used, ie worthy of being read in +from disk, and an unmap -> swap_free making the handle unused, the swap +delete and readahead code grabs a temp reference on the swaphandle to +prevent warning messages from swap_duplicate <- read_swap_cache_async. + +Swap cache locking +------------------ +Pages are added into the swap cache with kernel_lock held, to make sure +that multiple pages are not being added (and hence lost) by associating +all of them with the same swaphandle. + +Pages are guaranteed not to be removed from the scache if the page is +"shared": ie, other processes hold reference on the page or the associated +swap handle. The only code that does not follow this rule is shrink_mmap, +which deletes pages from the swap cache if no process has a reference on +the page (multiple processes might have references on the corresponding +swap handle though). lookup_swap_cache() races with shrink_mmap, when +establishing a reference on a scache page, so, it must check whether the +page it located is still in the swapcache, or shrink_mmap deleted it. +(This race is due to the fact that shrink_mmap looks at the page ref +count with pagecache_lock, but then drops pagecache_lock before deleting +the page from the scache). + +do_wp_page and do_swap_page have MP races in them while trying to figure +out whether a page is "shared", by looking at the page_count + swap_count. +To preserve the sum of the counts, the page lock _must_ be acquired before +calling is_page_shared (else processes might switch their swap_count refs +to the page count refs, after the page count ref has been snapshotted). + +Swap device deletion code currently breaks all the scache assumptions, +since it grabs neither mmap_sem nor page_table_lock. diff --git a/Documentation/vm/numa b/Documentation/vm/numa new file mode 100644 index 000000000000..4b8db1bd3b78 --- /dev/null +++ b/Documentation/vm/numa @@ -0,0 +1,41 @@ +Started Nov 1999 by Kanoj Sarcar <kanoj@sgi.com> + +The intent of this file is to have an uptodate, running commentary +from different people about NUMA specific code in the Linux vm. + +What is NUMA? It is an architecture where the memory access times +for different regions of memory from a given processor varies +according to the "distance" of the memory region from the processor. +Each region of memory to which access times are the same from any +cpu, is called a node. On such architectures, it is beneficial if +the kernel tries to minimize inter node communications. Schemes +for this range from kernel text and read-only data replication +across nodes, and trying to house all the data structures that +key components of the kernel need on memory on that node. + +Currently, all the numa support is to provide efficient handling +of widely discontiguous physical memory, so architectures which +are not NUMA but can have huge holes in the physical address space +can use the same code. All this code is bracketed by CONFIG_DISCONTIGMEM. + +The initial port includes NUMAizing the bootmem allocator code by +encapsulating all the pieces of information into a bootmem_data_t +structure. Node specific calls have been added to the allocator. +In theory, any platform which uses the bootmem allocator should +be able to to put the bootmem and mem_map data structures anywhere +it deems best. + +Each node's page allocation data structures have also been encapsulated +into a pg_data_t. The bootmem_data_t is just one part of this. To +make the code look uniform between NUMA and regular UMA platforms, +UMA platforms have a statically allocated pg_data_t too (contig_page_data). +For the sake of uniformity, the function num_online_nodes() is also defined +for all platforms. As we run benchmarks, we might decide to NUMAize +more variables like low_on_memory, nr_free_pages etc into the pg_data_t. + +The NUMA aware page allocation code currently tries to allocate pages +from different nodes in a round robin manner. This will be changed to +do concentratic circle search, starting from current node, once the +NUMA port achieves more maturity. The call alloc_pages_node has been +added, so that drivers can make the call and not worry about whether +it is running on a NUMA or UMA platform. diff --git a/Documentation/vm/overcommit-accounting b/Documentation/vm/overcommit-accounting new file mode 100644 index 000000000000..21c7b1f8f32b --- /dev/null +++ b/Documentation/vm/overcommit-accounting @@ -0,0 +1,73 @@ +The Linux kernel supports the following overcommit handling modes + +0 - Heuristic overcommit handling. Obvious overcommits of + address space are refused. Used for a typical system. It + ensures a seriously wild allocation fails while allowing + overcommit to reduce swap usage. root is allowed to + allocate slighly more memory in this mode. This is the + default. + +1 - Always overcommit. Appropriate for some scientific + applications. + +2 - Don't overcommit. The total address space commit + for the system is not permitted to exceed swap + a + configurable percentage (default is 50) of physical RAM. + Depending on the percentage you use, in most situations + this means a process will not be killed while accessing + pages but will receive errors on memory allocation as + appropriate. + +The overcommit policy is set via the sysctl `vm.overcommit_memory'. + +The overcommit percentage is set via `vm.overcommit_ratio'. + +The current overcommit limit and amount committed are viewable in +/proc/meminfo as CommitLimit and Committed_AS respectively. + +Gotchas +------- + +The C language stack growth does an implicit mremap. If you want absolute +guarantees and run close to the edge you MUST mmap your stack for the +largest size you think you will need. For typical stack usage this does +not matter much but it's a corner case if you really really care + +In mode 2 the MAP_NORESERVE flag is ignored. + + +How It Works +------------ + +The overcommit is based on the following rules + +For a file backed map + SHARED or READ-only - 0 cost (the file is the map not swap) + PRIVATE WRITABLE - size of mapping per instance + +For an anonymous or /dev/zero map + SHARED - size of mapping + PRIVATE READ-only - 0 cost (but of little use) + PRIVATE WRITABLE - size of mapping per instance + +Additional accounting + Pages made writable copies by mmap + shmfs memory drawn from the same pool + +Status +------ + +o We account mmap memory mappings +o We account mprotect changes in commit +o We account mremap changes in size +o We account brk +o We account munmap +o We report the commit status in /proc +o Account and check on fork +o Review stack handling/building on exec +o SHMfs accounting +o Implement actual limit enforcement + +To Do +----- +o Account ptrace pages (this is hard) |