1.. _mm_concepts: 2 3================= 4Concepts overview 5================= 6 7The memory management in Linux is a complex system that evolved over the 8years and included more and more functionality to support a variety of 9systems from MMU-less microcontrollers to supercomputers. The memory 10management for systems without an MMU is called ``nommu`` and it 11definitely deserves a dedicated document, which hopefully will be 12eventually written. Yet, although some of the concepts are the same, 13here we assume that an MMU is available and a CPU can translate a virtual 14address to a physical address. 15 16.. contents:: :local: 17 18Virtual Memory Primer 19===================== 20 21The physical memory in a computer system is a limited resource and 22even for systems that support memory hotplug there is a hard limit on 23the amount of memory that can be installed. The physical memory is not 24necessarily contiguous; it might be accessible as a set of distinct 25address ranges. Besides, different CPU architectures, and even 26different implementations of the same architecture have different views 27of how these address ranges are defined. 28 29All this makes dealing directly with physical memory quite complex and 30to avoid this complexity a concept of virtual memory was developed. 31 32The virtual memory abstracts the details of physical memory from the 33application software, allows to keep only needed information in the 34physical memory (demand paging) and provides a mechanism for the 35protection and controlled sharing of data between processes. 36 37With virtual memory, each and every memory access uses a virtual 38address. When the CPU decodes the an instruction that reads (or 39writes) from (or to) the system memory, it translates the `virtual` 40address encoded in that instruction to a `physical` address that the 41memory controller can understand. 42 43The physical system memory is divided into page frames, or pages. The 44size of each page is architecture specific. Some architectures allow 45selection of the page size from several supported values; this 46selection is performed at the kernel build time by setting an 47appropriate kernel configuration option. 48 49Each physical memory page can be mapped as one or more virtual 50pages. These mappings are described by page tables that allow 51translation from a virtual address used by programs to the physical 52memory address. The page tables are organized hierarchically. 53 54The tables at the lowest level of the hierarchy contain physical 55addresses of actual pages used by the software. The tables at higher 56levels contain physical addresses of the pages belonging to the lower 57levels. The pointer to the top level page table resides in a 58register. When the CPU performs the address translation, it uses this 59register to access the top level page table. The high bits of the 60virtual address are used to index an entry in the top level page 61table. That entry is then used to access the next level in the 62hierarchy with the next bits of the virtual address as the index to 63that level page table. The lowest bits in the virtual address define 64the offset inside the actual page. 65 66Huge Pages 67========== 68 69The address translation requires several memory accesses and memory 70accesses are slow relatively to CPU speed. To avoid spending precious 71processor cycles on the address translation, CPUs maintain a cache of 72such translations called Translation Lookaside Buffer (or 73TLB). Usually TLB is pretty scarce resource and applications with 74large memory working set will experience performance hit because of 75TLB misses. 76 77Many modern CPU architectures allow mapping of the memory pages 78directly by the higher levels in the page table. For instance, on x86, 79it is possible to map 2M and even 1G pages using entries in the second 80and the third level page tables. In Linux such pages are called 81`huge`. Usage of huge pages significantly reduces pressure on TLB, 82improves TLB hit-rate and thus improves overall system performance. 83 84There are two mechanisms in Linux that enable mapping of the physical 85memory with the huge pages. The first one is `HugeTLB filesystem`, or 86hugetlbfs. It is a pseudo filesystem that uses RAM as its backing 87store. For the files created in this filesystem the data resides in 88the memory and mapped using huge pages. The hugetlbfs is described at 89:ref:`Documentation/admin-guide/mm/hugetlbpage.rst <hugetlbpage>`. 90 91Another, more recent, mechanism that enables use of the huge pages is 92called `Transparent HugePages`, or THP. Unlike the hugetlbfs that 93requires users and/or system administrators to configure what parts of 94the system memory should and can be mapped by the huge pages, THP 95manages such mappings transparently to the user and hence the 96name. See 97:ref:`Documentation/admin-guide/mm/transhuge.rst <admin_guide_transhuge>` 98for more details about THP. 99 100Zones 101===== 102 103Often hardware poses restrictions on how different physical memory 104ranges can be accessed. In some cases, devices cannot perform DMA to 105all the addressable memory. In other cases, the size of the physical 106memory exceeds the maximal addressable size of virtual memory and 107special actions are required to access portions of the memory. Linux 108groups memory pages into `zones` according to their possible 109usage. For example, ZONE_DMA will contain memory that can be used by 110devices for DMA, ZONE_HIGHMEM will contain memory that is not 111permanently mapped into kernel's address space and ZONE_NORMAL will 112contain normally addressed pages. 113 114The actual layout of the memory zones is hardware dependent as not all 115architectures define all zones, and requirements for DMA are different 116for different platforms. 117 118Nodes 119===== 120 121Many multi-processor machines are NUMA - Non-Uniform Memory Access - 122systems. In such systems the memory is arranged into banks that have 123different access latency depending on the "distance" from the 124processor. Each bank is referred to as a `node` and for each node Linux 125constructs an independent memory management subsystem. A node has its 126own set of zones, lists of free and used pages and various statistics 127counters. You can find more details about NUMA in 128:ref:`Documentation/vm/numa.rst <numa>` and in 129:ref:`Documentation/admin-guide/mm/numa_memory_policy.rst <numa_memory_policy>`. 130 131Page cache 132========== 133 134The physical memory is volatile and the common case for getting data 135into the memory is to read it from files. Whenever a file is read, the 136data is put into the `page cache` to avoid expensive disk access on 137the subsequent reads. Similarly, when one writes to a file, the data 138is placed in the page cache and eventually gets into the backing 139storage device. The written pages are marked as `dirty` and when Linux 140decides to reuse them for other purposes, it makes sure to synchronize 141the file contents on the device with the updated data. 142 143Anonymous Memory 144================ 145 146The `anonymous memory` or `anonymous mappings` represent memory that 147is not backed by a filesystem. Such mappings are implicitly created 148for program's stack and heap or by explicit calls to mmap(2) system 149call. Usually, the anonymous mappings only define virtual memory areas 150that the program is allowed to access. The read accesses will result 151in creation of a page table entry that references a special physical 152page filled with zeroes. When the program performs a write, a regular 153physical page will be allocated to hold the written data. The page 154will be marked dirty and if the kernel decides to repurpose it, 155the dirty page will be swapped out. 156 157Reclaim 158======= 159 160Throughout the system lifetime, a physical page can be used for storing 161different types of data. It can be kernel internal data structures, 162DMA'able buffers for device drivers use, data read from a filesystem, 163memory allocated by user space processes etc. 164 165Depending on the page usage it is treated differently by the Linux 166memory management. The pages that can be freed at any time, either 167because they cache the data available elsewhere, for instance, on a 168hard disk, or because they can be swapped out, again, to the hard 169disk, are called `reclaimable`. The most notable categories of the 170reclaimable pages are page cache and anonymous memory. 171 172In most cases, the pages holding internal kernel data and used as DMA 173buffers cannot be repurposed, and they remain pinned until freed by 174their user. Such pages are called `unreclaimable`. However, in certain 175circumstances, even pages occupied with kernel data structures can be 176reclaimed. For instance, in-memory caches of filesystem metadata can 177be re-read from the storage device and therefore it is possible to 178discard them from the main memory when system is under memory 179pressure. 180 181The process of freeing the reclaimable physical memory pages and 182repurposing them is called (surprise!) `reclaim`. Linux can reclaim 183pages either asynchronously or synchronously, depending on the state 184of the system. When the system is not loaded, most of the memory is free 185and allocation requests will be satisfied immediately from the free 186pages supply. As the load increases, the amount of the free pages goes 187down and when it reaches a certain threshold (high watermark), an 188allocation request will awaken the ``kswapd`` daemon. It will 189asynchronously scan memory pages and either just free them if the data 190they contain is available elsewhere, or evict to the backing storage 191device (remember those dirty pages?). As memory usage increases even 192more and reaches another threshold - min watermark - an allocation 193will trigger `direct reclaim`. In this case allocation is stalled 194until enough memory pages are reclaimed to satisfy the request. 195 196Compaction 197========== 198 199As the system runs, tasks allocate and free the memory and it becomes 200fragmented. Although with virtual memory it is possible to present 201scattered physical pages as virtually contiguous range, sometimes it is 202necessary to allocate large physically contiguous memory areas. Such 203need may arise, for instance, when a device driver requires a large 204buffer for DMA, or when THP allocates a huge page. Memory `compaction` 205addresses the fragmentation issue. This mechanism moves occupied pages 206from the lower part of a memory zone to free pages in the upper part 207of the zone. When a compaction scan is finished free pages are grouped 208together at the beginning of the zone and allocations of large 209physically contiguous areas become possible. 210 211Like reclaim, the compaction may happen asynchronously in the ``kcompactd`` 212daemon or synchronously as a result of a memory allocation request. 213 214OOM killer 215========== 216 217It is possible that on a loaded machine memory will be exhausted and the 218kernel will be unable to reclaim enough memory to continue to operate. In 219order to save the rest of the system, it invokes the `OOM killer`. 220 221The `OOM killer` selects a task to sacrifice for the sake of the overall 222system health. The selected task is killed in a hope that after it exits 223enough memory will be freed to continue normal operation. 224