5 The memory API models the memory and I/O buses and controllers of a QEMU
6 machine. It attempts to allow modelling of:
9 - memory-mapped I/O (MMIO)
10 - memory controllers that can dynamically reroute physical memory regions
11 to different destinations
13 The memory model provides support for
15 - tracking RAM changes by the guest
16 - setting up coalesced memory for kvm
17 - setting up ioeventfd regions for kvm
19 Memory is modelled as an acyclic graph of MemoryRegion objects. Sinks
20 (leaves) are RAM and MMIO regions, while other nodes represent
21 buses, memory controllers, and memory regions that have been rerouted.
23 In addition to MemoryRegion objects, the memory API provides AddressSpace
24 objects for every root and possibly for intermediate MemoryRegions too.
25 These represent memory as seen from the CPU or a device's viewpoint.
30 There are multiple types of memory regions (all represented by a single C type
33 - RAM: a RAM region is simply a range of host memory that can be made available
35 You typically initialize these with memory_region_init_ram(). Some special
36 purposes require the variants memory_region_init_resizeable_ram(),
37 memory_region_init_ram_from_file(), or memory_region_init_ram_ptr().
39 - MMIO: a range of guest memory that is implemented by host callbacks;
40 each read or write causes a callback to be called on the host.
41 You initialize these with memory_region_init_io(), passing it a
42 MemoryRegionOps structure describing the callbacks.
44 - ROM: a ROM memory region works like RAM for reads (directly accessing
45 a region of host memory), and forbids writes. You initialize these with
46 memory_region_init_rom().
48 - ROM device: a ROM device memory region works like RAM for reads
49 (directly accessing a region of host memory), but like MMIO for
50 writes (invoking a callback). You initialize these with
51 memory_region_init_rom_device().
53 - IOMMU region: an IOMMU region translates addresses of accesses made to it
54 and forwards them to some other target memory region. As the name suggests,
55 these are only needed for modelling an IOMMU, not for simple devices.
56 You initialize these with memory_region_init_iommu().
58 - container: a container simply includes other memory regions, each at
59 a different offset. Containers are useful for grouping several regions
60 into one unit. For example, a PCI BAR may be composed of a RAM region
63 A container's subregions are usually non-overlapping. In some cases it is
64 useful to have overlapping regions; for example a memory controller that
65 can overlay a subregion of RAM with MMIO or ROM, or a PCI controller
66 that does not prevent card from claiming overlapping BARs.
68 You initialize a pure container with memory_region_init().
70 - alias: a subsection of another region. Aliases allow a region to be
71 split apart into discontiguous regions. Examples of uses are memory banks
72 used when the guest address space is smaller than the amount of RAM
73 addressed, or a memory controller that splits main memory to expose a "PCI
74 hole". Aliases may point to any type of region, including other aliases,
75 but an alias may not point back to itself, directly or indirectly.
76 You initialize these with memory_region_init_alias().
78 - reservation region: a reservation region is primarily for debugging.
79 It claims I/O space that is not supposed to be handled by QEMU itself.
80 The typical use is to track parts of the address space which will be
81 handled by the host kernel when KVM is enabled. You initialize these
82 by passing a NULL callback parameter to memory_region_init_io().
84 It is valid to add subregions to a region which is not a pure container
85 (that is, to an MMIO, RAM or ROM region). This means that the region
86 will act like a container, except that any addresses within the container's
87 region which are not claimed by any subregion are handled by the
88 container itself (ie by its MMIO callbacks or RAM backing). However
89 it is generally possible to achieve the same effect with a pure container
90 one of whose subregions is a low priority "background" region covering
91 the whole address range; this is often clearer and is preferred.
92 Subregions cannot be added to an alias region.
97 Where the memory region is backed by host memory (RAM, ROM and
98 ROM device memory region types), this host memory needs to be
99 copied to the destination on migration. These APIs which allocate
100 the host memory for you will also register the memory so it is
103 - memory_region_init_ram()
104 - memory_region_init_rom()
105 - memory_region_init_rom_device()
107 For most devices and boards this is the correct thing. If you
108 have a special case where you need to manage the migration of
109 the backing memory yourself, you can call the functions:
111 - memory_region_init_ram_nomigrate()
112 - memory_region_init_rom_nomigrate()
113 - memory_region_init_rom_device_nomigrate()
115 which only initialize the MemoryRegion and leave handling
116 migration to the caller.
120 - memory_region_init_resizeable_ram()
121 - memory_region_init_ram_from_file()
122 - memory_region_init_ram_from_fd()
123 - memory_region_init_ram_ptr()
124 - memory_region_init_ram_device_ptr()
126 are for special cases only, and so they do not automatically
127 register the backing memory for migration; the caller must
128 manage migration if necessary.
133 Regions are assigned names by the constructor. For most regions these are
134 only used for debugging purposes, but RAM regions also use the name to identify
135 live migration sections. This means that RAM region names need to have ABI
141 A region is created by one of the memory_region_init*() functions and
142 attached to an object, which acts as its owner or parent. QEMU ensures
143 that the owner object remains alive as long as the region is visible to
144 the guest, or as long as the region is in use by a virtual CPU or another
145 device. For example, the owner object will not die between an
146 address_space_map operation and the corresponding address_space_unmap.
148 After creation, a region can be added to an address space or a
149 container with memory_region_add_subregion(), and removed using
150 memory_region_del_subregion().
152 Various region attributes (read-only, dirty logging, coalesced mmio,
153 ioeventfd) can be changed during the region lifecycle. They take effect
154 as soon as the region is made visible. This can be immediately, later,
157 Destruction of a memory region happens automatically when the owner
160 If however the memory region is part of a dynamically allocated data
161 structure, you should call object_unparent() to destroy the memory region
162 before the data structure is freed. For an example see VFIOMSIXInfo
163 and VFIOQuirk in hw/vfio/pci.c.
165 You must not destroy a memory region as long as it may be in use by a
166 device or CPU. In order to do this, as a general rule do not create or
167 destroy memory regions dynamically during a device's lifetime, and only
168 call object_unparent() in the memory region owner's instance_finalize
169 callback. The dynamically allocated data structure that contains the
170 memory region then should obviously be freed in the instance_finalize
173 If you break this rule, the following situation can happen:
175 - the memory region's owner had a reference taken via memory_region_ref
176 (for example by address_space_map)
178 - the region is unparented, and has no owner anymore
180 - when address_space_unmap is called, the reference to the memory region's
184 There is an exception to the above rule: it is okay to call
185 object_unparent at any time for an alias or a container region. It is
186 therefore also okay to create or destroy alias and container regions
187 dynamically during a device's lifetime.
189 This exceptional usage is valid because aliases and containers only help
190 QEMU building the guest's memory map; they are never accessed directly.
191 memory_region_ref and memory_region_unref are never called on aliases
192 or containers, and the above situation then cannot happen. Exploiting
193 this exception is rarely necessary, and therefore it is discouraged,
194 but nevertheless it is used in a few places.
196 For regions that "have no owner" (NULL is passed at creation time), the
197 machine object is actually used as the owner. Since instance_finalize is
198 never called for the machine object, you must never call object_unparent
199 on regions that have no owner, unless they are aliases or containers.
202 Overlapping regions and priority
203 --------------------------------
204 Usually, regions may not overlap each other; a memory address decodes into
205 exactly one target. In some cases it is useful to allow regions to overlap,
206 and sometimes to control which of an overlapping regions is visible to the
207 guest. This is done with memory_region_add_subregion_overlap(), which
208 allows the region to overlap any other region in the same container, and
209 specifies a priority that allows the core to decide which of two regions at
210 the same address are visible (highest wins).
211 Priority values are signed, and the default value is zero. This means that
212 you can use memory_region_add_subregion_overlap() both to specify a region
213 that must sit 'above' any others (with a positive priority) and also a
214 background region that sits 'below' others (with a negative priority).
216 If the higher priority region in an overlap is a container or alias, then
217 the lower priority region will appear in any "holes" that the higher priority
218 region has left by not mapping subregions to that area of its address range.
219 (This applies recursively -- if the subregions are themselves containers or
220 aliases that leave holes then the lower priority region will appear in these
223 For example, suppose we have a container A of size 0x8000 with two subregions
224 B and C. B is a container mapped at 0x2000, size 0x4000, priority 2; C is
225 an MMIO region mapped at 0x0, size 0x6000, priority 1. B currently has two
226 of its own subregions: D of size 0x1000 at offset 0 and E of size 0x1000 at
227 offset 0x2000. As a diagram::
229 0 1000 2000 3000 4000 5000 6000 7000 8000
230 |------|------|------|------|------|------|------|------|
232 C: [CCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCC]
237 The regions that will be seen within this address range then are::
239 [CCCCCCCCCCCC][DDDDD][CCCCC][EEEEE][CCCCC]
241 Since B has higher priority than C, its subregions appear in the flat map
242 even where they overlap with C. In ranges where B has not mapped anything
245 If B had provided its own MMIO operations (ie it was not a pure container)
246 then these would be used for any addresses in its range not handled by
247 D or E, and the result would be::
249 [CCCCCCCCCCCC][DDDDD][BBBBB][EEEEE][BBBBB]
251 Priority values are local to a container, because the priorities of two
252 regions are only compared when they are both children of the same container.
253 This means that the device in charge of the container (typically modelling
254 a bus or a memory controller) can use them to manage the interaction of
255 its child regions without any side effects on other parts of the system.
256 In the example above, the priorities of D and E are unimportant because
257 they do not overlap each other. It is the relative priority of B and C
258 that causes D and E to appear on top of C: D and E's priorities are never
259 compared against the priority of C.
263 The memory core uses the following rules to select a memory region when the
264 guest accesses an address:
266 - all direct subregions of the root region are matched against the address, in
267 descending priority order
269 - if the address lies outside the region offset/size, the subregion is
271 - if the subregion is a leaf (RAM or MMIO), the search terminates, returning
273 - if the subregion is a container, the same algorithm is used within the
274 subregion (after the address is adjusted by the subregion offset)
275 - if the subregion is an alias, the search is continued at the alias target
276 (after the address is adjusted by the subregion offset and alias offset)
277 - if a recursive search within a container or alias subregion does not
278 find a match (because of a "hole" in the container's coverage of its
279 address range), then if this is a container with its own MMIO or RAM
280 backing the search terminates, returning the container itself. Otherwise
281 we continue with the next subregion in priority order
283 - if none of the subregions match the address then the search terminates
291 system_memory: container@0-2^48-1
293 +---- lomem: alias@0-0xdfffffff ---> #ram (0-0xdfffffff)
295 +---- himem: alias@0x100000000-0x11fffffff ---> #ram (0xe0000000-0xffffffff)
297 +---- vga-window: alias@0xa0000-0xbffff ---> #pci (0xa0000-0xbffff)
300 +---- pci-hole: alias@0xe0000000-0xffffffff ---> #pci (0xe0000000-0xffffffff)
304 +--- vga-area: container@0xa0000-0xbffff
306 | +--- alias@0x00000-0x7fff ---> #vram (0x010000-0x017fff)
308 | +--- alias@0x08000-0xffff ---> #vram (0x020000-0x027fff)
310 +---- vram: ram@0xe1000000-0xe1ffffff
312 +---- vga-mmio: mmio@0xe2000000-0xe200ffff
314 ram: ram@0x00000000-0xffffffff
316 This is a (simplified) PC memory map. The 4GB RAM block is mapped into the
317 system address space via two aliases: "lomem" is a 1:1 mapping of the first
318 3.5GB; "himem" maps the last 0.5GB at address 4GB. This leaves 0.5GB for the
319 so-called PCI hole, that allows a 32-bit PCI bus to exist in a system with
322 The memory controller diverts addresses in the range 640K-768K to the PCI
323 address space. This is modelled using the "vga-window" alias, mapped at a
324 higher priority so it obscures the RAM at the same addresses. The vga window
325 can be removed by programming the memory controller; this is modelled by
326 removing the alias and exposing the RAM underneath.
328 The pci address space is not a direct child of the system address space, since
329 we only want parts of it to be visible (we accomplish this using aliases).
330 It has two subregions: vga-area models the legacy vga window and is occupied
331 by two 32K memory banks pointing at two sections of the framebuffer.
332 In addition the vram is mapped as a BAR at address e1000000, and an additional
333 BAR containing MMIO registers is mapped after it.
335 Note that if the guest maps a BAR outside the PCI hole, it would not be
336 visible as the pci-hole alias clips it to a 0.5GB range.
341 MMIO regions are provided with ->read() and ->write() callbacks,
342 which are sufficient for most devices. Some devices change behaviour
343 based on the attributes used for the memory transaction, or need
344 to be able to respond that the access should provoke a bus error
345 rather than completing successfully; those devices can use the
346 ->read_with_attrs() and ->write_with_attrs() callbacks instead.
348 In addition various constraints can be supplied to control how these
349 callbacks are called:
351 - .valid.min_access_size, .valid.max_access_size define the access sizes
352 (in bytes) which the device accepts; accesses outside this range will
353 have device and bus specific behaviour (ignored, or machine check)
354 - .valid.unaligned specifies that the *device being modelled* supports
355 unaligned accesses; if false, unaligned accesses will invoke the
356 appropriate bus or CPU specific behaviour.
357 - .impl.min_access_size, .impl.max_access_size define the access sizes
358 (in bytes) supported by the *implementation*; other access sizes will be
359 emulated using the ones available. For example a 4-byte write will be
360 emulated using four 1-byte writes, if .impl.max_access_size = 1.
361 - .impl.unaligned specifies that the *implementation* supports unaligned
362 accesses; if false, unaligned accesses will be emulated by two aligned
368 .. kernel-doc:: include/exec/memory.h