1.. SPDX-License-Identifier: GPL-2.0 2 3.. _physical_memory_model: 4 5===================== 6Physical Memory Model 7===================== 8 9Physical memory in a system may be addressed in different ways. The 10simplest case is when the physical memory starts at address 0 and 11spans a contiguous range up to the maximal address. It could be, 12however, that this range contains small holes that are not accessible 13for the CPU. Then there could be several contiguous ranges at 14completely distinct addresses. And, don't forget about NUMA, where 15different memory banks are attached to different CPUs. 16 17Linux abstracts this diversity using one of the two memory models: 18FLATMEM and SPARSEMEM. Each architecture defines what 19memory models it supports, what the default memory model is and 20whether it is possible to manually override that default. 21 22All the memory models track the status of physical page frames using 23struct page arranged in one or more arrays. 24 25Regardless of the selected memory model, there exists one-to-one 26mapping between the physical page frame number (PFN) and the 27corresponding `struct page`. 28 29Each memory model defines :c:func:`pfn_to_page` and :c:func:`page_to_pfn` 30helpers that allow the conversion from PFN to `struct page` and vice 31versa. 32 33FLATMEM 34======= 35 36The simplest memory model is FLATMEM. This model is suitable for 37non-NUMA systems with contiguous, or mostly contiguous, physical 38memory. 39 40In the FLATMEM memory model, there is a global `mem_map` array that 41maps the entire physical memory. For most architectures, the holes 42have entries in the `mem_map` array. The `struct page` objects 43corresponding to the holes are never fully initialized. 44 45To allocate the `mem_map` array, architecture specific setup code should 46call :c:func:`free_area_init` function. Yet, the mappings array is not 47usable until the call to :c:func:`memblock_free_all` that hands all the 48memory to the page allocator. 49 50An architecture may free parts of the `mem_map` array that do not cover the 51actual physical pages. In such case, the architecture specific 52:c:func:`pfn_valid` implementation should take the holes in the 53`mem_map` into account. 54 55With FLATMEM, the conversion between a PFN and the `struct page` is 56straightforward: `PFN - ARCH_PFN_OFFSET` is an index to the 57`mem_map` array. 58 59The `ARCH_PFN_OFFSET` defines the first page frame number for 60systems with physical memory starting at address different from 0. 61 62SPARSEMEM 63========= 64 65SPARSEMEM is the most versatile memory model available in Linux and it 66is the only memory model that supports several advanced features such 67as hot-plug and hot-remove of the physical memory, alternative memory 68maps for non-volatile memory devices and deferred initialization of 69the memory map for larger systems. 70 71The SPARSEMEM model presents the physical memory as a collection of 72sections. A section is represented with struct mem_section 73that contains `section_mem_map` that is, logically, a pointer to an 74array of struct pages. However, it is stored with some other magic 75that aids the sections management. The section size and maximal number 76of section is specified using `SECTION_SIZE_BITS` and 77`MAX_PHYSMEM_BITS` constants defined by each architecture that 78supports SPARSEMEM. While `MAX_PHYSMEM_BITS` is an actual width of a 79physical address that an architecture supports, the 80`SECTION_SIZE_BITS` is an arbitrary value. 81 82The maximal number of sections is denoted `NR_MEM_SECTIONS` and 83defined as 84 85.. math:: 86 87 NR\_MEM\_SECTIONS = 2 ^ {(MAX\_PHYSMEM\_BITS - SECTION\_SIZE\_BITS)} 88 89The `mem_section` objects are arranged in a two-dimensional array 90called `mem_sections`. The size and placement of this array depend 91on `CONFIG_SPARSEMEM_EXTREME` and the maximal possible number of 92sections: 93 94* When `CONFIG_SPARSEMEM_EXTREME` is disabled, the `mem_sections` 95 array is static and has `NR_MEM_SECTIONS` rows. Each row holds a 96 single `mem_section` object. 97* When `CONFIG_SPARSEMEM_EXTREME` is enabled, the `mem_sections` 98 array is dynamically allocated. Each row contains PAGE_SIZE worth of 99 `mem_section` objects and the number of rows is calculated to fit 100 all the memory sections. 101 102The architecture setup code should call sparse_init() to 103initialize the memory sections and the memory maps. 104 105With SPARSEMEM there are two possible ways to convert a PFN to the 106corresponding `struct page` - a "classic sparse" and "sparse 107vmemmap". The selection is made at build time and it is determined by 108the value of `CONFIG_SPARSEMEM_VMEMMAP`. 109 110The classic sparse encodes the section number of a page in page->flags 111and uses high bits of a PFN to access the section that maps that page 112frame. Inside a section, the PFN is the index to the array of pages. 113 114The sparse vmemmap uses a virtually mapped memory map to optimize 115pfn_to_page and page_to_pfn operations. There is a global `struct 116page *vmemmap` pointer that points to a virtually contiguous array of 117`struct page` objects. A PFN is an index to that array and the 118offset of the `struct page` from `vmemmap` is the PFN of that 119page. 120 121To use vmemmap, an architecture has to reserve a range of virtual 122addresses that will map the physical pages containing the memory 123map and make sure that `vmemmap` points to that range. In addition, 124the architecture should implement :c:func:`vmemmap_populate` method 125that will allocate the physical memory and create page tables for the 126virtual memory map. If an architecture does not have any special 127requirements for the vmemmap mappings, it can use default 128:c:func:`vmemmap_populate_basepages` provided by the generic memory 129management. 130 131The virtually mapped memory map allows storing `struct page` objects 132for persistent memory devices in pre-allocated storage on those 133devices. This storage is represented with struct vmem_altmap 134that is eventually passed to vmemmap_populate() through a long chain 135of function calls. The vmemmap_populate() implementation may use the 136`vmem_altmap` along with :c:func:`vmemmap_alloc_block_buf` helper to 137allocate memory map on the persistent memory device. 138 139ZONE_DEVICE 140=========== 141The `ZONE_DEVICE` facility builds upon `SPARSEMEM_VMEMMAP` to offer 142`struct page` `mem_map` services for device driver identified physical 143address ranges. The "device" aspect of `ZONE_DEVICE` relates to the fact 144that the page objects for these address ranges are never marked online, 145and that a reference must be taken against the device, not just the page 146to keep the memory pinned for active use. `ZONE_DEVICE`, via 147:c:func:`devm_memremap_pages`, performs just enough memory hotplug to 148turn on :c:func:`pfn_to_page`, :c:func:`page_to_pfn`, and 149:c:func:`get_user_pages` service for the given range of pfns. Since the 150page reference count never drops below 1 the page is never tracked as 151free memory and the page's `struct list_head lru` space is repurposed 152for back referencing to the host device / driver that mapped the memory. 153 154While `SPARSEMEM` presents memory as a collection of sections, 155optionally collected into memory blocks, `ZONE_DEVICE` users have a need 156for smaller granularity of populating the `mem_map`. Given that 157`ZONE_DEVICE` memory is never marked online it is subsequently never 158subject to its memory ranges being exposed through the sysfs memory 159hotplug api on memory block boundaries. The implementation relies on 160this lack of user-api constraint to allow sub-section sized memory 161ranges to be specified to :c:func:`arch_add_memory`, the top-half of 162memory hotplug. Sub-section support allows for 2MB as the cross-arch 163common alignment granularity for :c:func:`devm_memremap_pages`. 164 165The users of `ZONE_DEVICE` are: 166 167* pmem: Map platform persistent memory to be used as a direct-I/O target 168 via DAX mappings. 169 170* hmm: Extend `ZONE_DEVICE` with `->page_fault()` and `->page_free()` 171 event callbacks to allow a device-driver to coordinate memory management 172 events related to device-memory, typically GPU memory. See 173 Documentation/mm/hmm.rst. 174 175* p2pdma: Create `struct page` objects to allow peer devices in a 176 PCI/-E topology to coordinate direct-DMA operations between themselves, 177 i.e. bypass host memory. 178