xref: /openbmc/qemu/docs/nvdimm.txt (revision 3d9569b8)
1QEMU Virtual NVDIMM
2===================
3
4This document explains the usage of virtual NVDIMM (vNVDIMM) feature
5which is available since QEMU v2.6.0.
6
7The current QEMU only implements the persistent memory mode of vNVDIMM
8device and not the block window mode.
9
10Basic Usage
11-----------
12
13The storage of a vNVDIMM device in QEMU is provided by the memory
14backend (i.e. memory-backend-file and memory-backend-ram). A simple
15way to create a vNVDIMM device at startup time is done via the
16following command line options:
17
18 -machine pc,nvdimm
19 -m $RAM_SIZE,slots=$N,maxmem=$MAX_SIZE
20 -object memory-backend-file,id=mem1,share=on,mem-path=$PATH,size=$NVDIMM_SIZE
21 -device nvdimm,id=nvdimm1,memdev=mem1
22
23Where,
24
25 - the "nvdimm" machine option enables vNVDIMM feature.
26
27 - "slots=$N" should be equal to or larger than the total amount of
28   normal RAM devices and vNVDIMM devices, e.g. $N should be >= 2 here.
29
30 - "maxmem=$MAX_SIZE" should be equal to or larger than the total size
31   of normal RAM devices and vNVDIMM devices, e.g. $MAX_SIZE should be
32   >= $RAM_SIZE + $NVDIMM_SIZE here.
33
34 - "object memory-backend-file,id=mem1,share=on,mem-path=$PATH,size=$NVDIMM_SIZE"
35   creates a backend storage of size $NVDIMM_SIZE on a file $PATH. All
36   accesses to the virtual NVDIMM device go to the file $PATH.
37
38   "share=on/off" controls the visibility of guest writes. If
39   "share=on", then guest writes will be applied to the backend
40   file. If another guest uses the same backend file with option
41   "share=on", then above writes will be visible to it as well. If
42   "share=off", then guest writes won't be applied to the backend
43   file and thus will be invisible to other guests.
44
45 - "device nvdimm,id=nvdimm1,memdev=mem1" creates a virtual NVDIMM
46   device whose storage is provided by above memory backend device.
47
48Multiple vNVDIMM devices can be created if multiple pairs of "-object"
49and "-device" are provided.
50
51For above command line options, if the guest OS has the proper NVDIMM
52driver (e.g. "CONFIG_ACPI_NFIT=y" under Linux), it should be able to
53detect a NVDIMM device which is in the persistent memory mode and whose
54size is $NVDIMM_SIZE.
55
56Note:
57
581. Prior to QEMU v2.8.0, if memory-backend-file is used and the actual
59   backend file size is not equal to the size given by "size" option,
60   QEMU will truncate the backend file by ftruncate(2), which will
61   corrupt the existing data in the backend file, especially for the
62   shrink case.
63
64   QEMU v2.8.0 and later check the backend file size and the "size"
65   option. If they do not match, QEMU will report errors and abort in
66   order to avoid the data corruption.
67
682. QEMU v2.6.0 only puts a basic alignment requirement on the "size"
69   option of memory-backend-file, e.g. 4KB alignment on x86.  However,
70   QEMU v.2.7.0 puts an additional alignment requirement, which may
71   require a larger value than the basic one, e.g. 2MB on x86. This
72   change breaks the usage of memory-backend-file that only satisfies
73   the basic alignment.
74
75   QEMU v2.8.0 and later remove the additional alignment on non-s390x
76   architectures, so the broken memory-backend-file can work again.
77
78Label
79-----
80
81QEMU v2.7.0 and later implement the label support for vNVDIMM devices.
82To enable label on vNVDIMM devices, users can simply add
83"label-size=$SZ" option to "-device nvdimm", e.g.
84
85 -device nvdimm,id=nvdimm1,memdev=mem1,label-size=128K
86
87Note:
88
891. The minimal label size is 128KB.
90
912. QEMU v2.7.0 and later store labels at the end of backend storage.
92   If a memory backend file, which was previously used as the backend
93   of a vNVDIMM device without labels, is now used for a vNVDIMM
94   device with label, the data in the label area at the end of file
95   will be inaccessible to the guest. If any useful data (e.g. the
96   meta-data of the file system) was stored there, the latter usage
97   may result guest data corruption (e.g. breakage of guest file
98   system).
99
100Hotplug
101-------
102
103QEMU v2.8.0 and later implement the hotplug support for vNVDIMM
104devices. Similarly to the RAM hotplug, the vNVDIMM hotplug is
105accomplished by two monitor commands "object_add" and "device_add".
106
107For example, the following commands add another 4GB vNVDIMM device to
108the guest:
109
110 (qemu) object_add memory-backend-file,id=mem2,share=on,mem-path=new_nvdimm.img,size=4G
111 (qemu) device_add nvdimm,id=nvdimm2,memdev=mem2
112
113Note:
114
1151. Each hotplugged vNVDIMM device consumes one memory slot. Users
116   should always ensure the memory option "-m ...,slots=N" specifies
117   enough number of slots, i.e.
118     N >= number of RAM devices +
119          number of statically plugged vNVDIMM devices +
120          number of hotplugged vNVDIMM devices
121
1222. The similar is required for the memory option "-m ...,maxmem=M", i.e.
123     M >= size of RAM devices +
124          size of statically plugged vNVDIMM devices +
125          size of hotplugged vNVDIMM devices
126
127Alignment
128---------
129
130QEMU uses mmap(2) to maps vNVDIMM backends and aligns the mapping
131address to the page size (getpagesize(2)) by default. However, some
132types of backends may require an alignment different than the page
133size. In that case, QEMU v2.12.0 and later provide 'align' option to
134memory-backend-file to allow users to specify the proper alignment.
135
136For example, device dax require the 2 MB alignment, so we can use
137following QEMU command line options to use it (/dev/dax0.0) as the
138backend of vNVDIMM:
139
140 -object memory-backend-file,id=mem1,share=on,mem-path=/dev/dax0.0,size=4G,align=2M
141 -device nvdimm,id=nvdimm1,memdev=mem1
142
143Guest Data Persistence
144----------------------
145
146Though QEMU supports multiple types of vNVDIMM backends on Linux,
147the only backend that can guarantee the guest write persistence is:
148
149A. DAX device (e.g., /dev/dax0.0, ) or
150B. DAX file(mounted with dax option)
151
152When using B (A file supporting direct mapping of persistent memory)
153as a backend, write persistence is guaranteed if the host kernel has
154support for the MAP_SYNC flag in the mmap system call (available
155since Linux 4.15 and on certain distro kernels) and additionally
156both 'pmem' and 'share' flags are set to 'on' on the backend.
157
158If these conditions are not satisfied i.e. if either 'pmem' or 'share'
159are not set, if the backend file does not support DAX or if MAP_SYNC
160is not supported by the host kernel, write persistence is not
161guaranteed after a system crash. For compatibility reasons, these
162conditions are ignored if not satisfied. Currently, no way is
163provided to test for them.
164For more details, please reference mmap(2) man page:
165http://man7.org/linux/man-pages/man2/mmap.2.html.
166
167When using other types of backends, it's suggested to set 'unarmed'
168option of '-device nvdimm' to 'on', which sets the unarmed flag of the
169guest NVDIMM region mapping structure.  This unarmed flag indicates
170guest software that this vNVDIMM device contains a region that cannot
171accept persistent writes. In result, for example, the guest Linux
172NVDIMM driver, marks such vNVDIMM device as read-only.
173
174NVDIMM Persistence
175------------------
176
177ACPI 6.2 Errata A added support for a new Platform Capabilities Structure
178which allows the platform to communicate what features it supports related to
179NVDIMM data persistence.  Users can provide a persistence value to a guest via
180the optional "nvdimm-persistence" machine command line option:
181
182    -machine pc,accel=kvm,nvdimm,nvdimm-persistence=cpu
183
184There are currently two valid values for this option:
185
186"mem-ctrl" - The platform supports flushing dirty data from the memory
187             controller to the NVDIMMs in the event of power loss.
188
189"cpu"      - The platform supports flushing dirty data from the CPU cache to
190             the NVDIMMs in the event of power loss.  This implies that the
191             platform also supports flushing dirty data through the memory
192             controller on power loss.
193
194If the vNVDIMM backend is in host persistent memory that can be accessed in
195SNIA NVM Programming Model [1] (e.g., Intel NVDIMM), it's suggested to set
196the 'pmem' option of memory-backend-file to 'on'. When 'pmem' is 'on' and QEMU
197is built with libpmem [2] support (configured with --enable-libpmem), QEMU
198will take necessary operations to guarantee the persistence of its own writes
199to the vNVDIMM backend(e.g., in vNVDIMM label emulation and live migration).
200If 'pmem' is 'on' while there is no libpmem support, qemu will exit and report
201a "lack of libpmem support" message to ensure the persistence is available.
202For example, if we want to ensure the persistence for some backend file,
203use the QEMU command line:
204
205    -object memory-backend-file,id=nv_mem,mem-path=/XXX/yyy,size=4G,pmem=on
206
207References
208----------
209
210[1] NVM Programming Model (NPM)
211	Version 1.2
212    https://www.snia.org/sites/default/files/technical_work/final/NVMProgrammingModel_v1.2.pdf
213[2] Persistent Memory Development Kit (PMDK), formerly known as NVML project, home page:
214    http://pmem.io/pmdk/
215