1==================================
2VFIO - "Virtual Function I/O" [1]_
3==================================
4
5Many modern systems now provide DMA and interrupt remapping facilities
6to help ensure I/O devices behave within the boundaries they've been
7allotted.  This includes x86 hardware with AMD-Vi and Intel VT-d,
8POWER systems with Partitionable Endpoints (PEs) and embedded PowerPC
9systems such as Freescale PAMU.  The VFIO driver is an IOMMU/device
10agnostic framework for exposing direct device access to userspace, in
11a secure, IOMMU protected environment.  In other words, this allows
12safe [2]_, non-privileged, userspace drivers.
13
14Why do we want that?  Virtual machines often make use of direct device
15access ("device assignment") when configured for the highest possible
16I/O performance.  From a device and host perspective, this simply
17turns the VM into a userspace driver, with the benefits of
18significantly reduced latency, higher bandwidth, and direct use of
19bare-metal device drivers [3]_.
20
21Some applications, particularly in the high performance computing
22field, also benefit from low-overhead, direct device access from
23userspace.  Examples include network adapters (often non-TCP/IP based)
24and compute accelerators.  Prior to VFIO, these drivers had to either
25go through the full development cycle to become proper upstream
26driver, be maintained out of tree, or make use of the UIO framework,
27which has no notion of IOMMU protection, limited interrupt support,
28and requires root privileges to access things like PCI configuration
29space.
30
31The VFIO driver framework intends to unify these, replacing both the
32KVM PCI specific device assignment code as well as provide a more
33secure, more featureful userspace driver environment than UIO.
34
35Groups, Devices, and IOMMUs
36---------------------------
37
38Devices are the main target of any I/O driver.  Devices typically
39create a programming interface made up of I/O access, interrupts,
40and DMA.  Without going into the details of each of these, DMA is
41by far the most critical aspect for maintaining a secure environment
42as allowing a device read-write access to system memory imposes the
43greatest risk to the overall system integrity.
44
45To help mitigate this risk, many modern IOMMUs now incorporate
46isolation properties into what was, in many cases, an interface only
47meant for translation (ie. solving the addressing problems of devices
48with limited address spaces).  With this, devices can now be isolated
49from each other and from arbitrary memory access, thus allowing
50things like secure direct assignment of devices into virtual machines.
51
52This isolation is not always at the granularity of a single device
53though.  Even when an IOMMU is capable of this, properties of devices,
54interconnects, and IOMMU topologies can each reduce this isolation.
55For instance, an individual device may be part of a larger multi-
56function enclosure.  While the IOMMU may be able to distinguish
57between devices within the enclosure, the enclosure may not require
58transactions between devices to reach the IOMMU.  Examples of this
59could be anything from a multi-function PCI device with backdoors
60between functions to a non-PCI-ACS (Access Control Services) capable
61bridge allowing redirection without reaching the IOMMU.  Topology
62can also play a factor in terms of hiding devices.  A PCIe-to-PCI
63bridge masks the devices behind it, making transaction appear as if
64from the bridge itself.  Obviously IOMMU design plays a major factor
65as well.
66
67Therefore, while for the most part an IOMMU may have device level
68granularity, any system is susceptible to reduced granularity.  The
69IOMMU API therefore supports a notion of IOMMU groups.  A group is
70a set of devices which is isolatable from all other devices in the
71system.  Groups are therefore the unit of ownership used by VFIO.
72
73While the group is the minimum granularity that must be used to
74ensure secure user access, it's not necessarily the preferred
75granularity.  In IOMMUs which make use of page tables, it may be
76possible to share a set of page tables between different groups,
77reducing the overhead both to the platform (reduced TLB thrashing,
78reduced duplicate page tables), and to the user (programming only
79a single set of translations).  For this reason, VFIO makes use of
80a container class, which may hold one or more groups.  A container
81is created by simply opening the /dev/vfio/vfio character device.
82
83On its own, the container provides little functionality, with all
84but a couple version and extension query interfaces locked away.
85The user needs to add a group into the container for the next level
86of functionality.  To do this, the user first needs to identify the
87group associated with the desired device.  This can be done using
88the sysfs links described in the example below.  By unbinding the
89device from the host driver and binding it to a VFIO driver, a new
90VFIO group will appear for the group as /dev/vfio/$GROUP, where
91$GROUP is the IOMMU group number of which the device is a member.
92If the IOMMU group contains multiple devices, each will need to
93be bound to a VFIO driver before operations on the VFIO group
94are allowed (it's also sufficient to only unbind the device from
95host drivers if a VFIO driver is unavailable; this will make the
96group available, but not that particular device).  TBD - interface
97for disabling driver probing/locking a device.
98
99Once the group is ready, it may be added to the container by opening
100the VFIO group character device (/dev/vfio/$GROUP) and using the
101VFIO_GROUP_SET_CONTAINER ioctl, passing the file descriptor of the
102previously opened container file.  If desired and if the IOMMU driver
103supports sharing the IOMMU context between groups, multiple groups may
104be set to the same container.  If a group fails to set to a container
105with existing groups, a new empty container will need to be used
106instead.
107
108With a group (or groups) attached to a container, the remaining
109ioctls become available, enabling access to the VFIO IOMMU interfaces.
110Additionally, it now becomes possible to get file descriptors for each
111device within a group using an ioctl on the VFIO group file descriptor.
112
113The VFIO device API includes ioctls for describing the device, the I/O
114regions and their read/write/mmap offsets on the device descriptor, as
115well as mechanisms for describing and registering interrupt
116notifications.
117
118VFIO Usage Example
119------------------
120
121Assume user wants to access PCI device 0000:06:0d.0::
122
123	$ readlink /sys/bus/pci/devices/0000:06:0d.0/iommu_group
124	../../../../kernel/iommu_groups/26
125
126This device is therefore in IOMMU group 26.  This device is on the
127pci bus, therefore the user will make use of vfio-pci to manage the
128group::
129
130	# modprobe vfio-pci
131
132Binding this device to the vfio-pci driver creates the VFIO group
133character devices for this group::
134
135	$ lspci -n -s 0000:06:0d.0
136	06:0d.0 0401: 1102:0002 (rev 08)
137	# echo 0000:06:0d.0 > /sys/bus/pci/devices/0000:06:0d.0/driver/unbind
138	# echo 1102 0002 > /sys/bus/pci/drivers/vfio-pci/new_id
139
140Now we need to look at what other devices are in the group to free
141it for use by VFIO::
142
143	$ ls -l /sys/bus/pci/devices/0000:06:0d.0/iommu_group/devices
144	total 0
145	lrwxrwxrwx. 1 root root 0 Apr 23 16:13 0000:00:1e.0 ->
146		../../../../devices/pci0000:00/0000:00:1e.0
147	lrwxrwxrwx. 1 root root 0 Apr 23 16:13 0000:06:0d.0 ->
148		../../../../devices/pci0000:00/0000:00:1e.0/0000:06:0d.0
149	lrwxrwxrwx. 1 root root 0 Apr 23 16:13 0000:06:0d.1 ->
150		../../../../devices/pci0000:00/0000:00:1e.0/0000:06:0d.1
151
152This device is behind a PCIe-to-PCI bridge [4]_, therefore we also
153need to add device 0000:06:0d.1 to the group following the same
154procedure as above.  Device 0000:00:1e.0 is a bridge that does
155not currently have a host driver, therefore it's not required to
156bind this device to the vfio-pci driver (vfio-pci does not currently
157support PCI bridges).
158
159The final step is to provide the user with access to the group if
160unprivileged operation is desired (note that /dev/vfio/vfio provides
161no capabilities on its own and is therefore expected to be set to
162mode 0666 by the system)::
163
164	# chown user:user /dev/vfio/26
165
166The user now has full access to all the devices and the iommu for this
167group and can access them as follows::
168
169	int container, group, device, i;
170	struct vfio_group_status group_status =
171					{ .argsz = sizeof(group_status) };
172	struct vfio_iommu_type1_info iommu_info = { .argsz = sizeof(iommu_info) };
173	struct vfio_iommu_type1_dma_map dma_map = { .argsz = sizeof(dma_map) };
174	struct vfio_device_info device_info = { .argsz = sizeof(device_info) };
175
176	/* Create a new container */
177	container = open("/dev/vfio/vfio", O_RDWR);
178
179	if (ioctl(container, VFIO_GET_API_VERSION) != VFIO_API_VERSION)
180		/* Unknown API version */
181
182	if (!ioctl(container, VFIO_CHECK_EXTENSION, VFIO_TYPE1_IOMMU))
183		/* Doesn't support the IOMMU driver we want. */
184
185	/* Open the group */
186	group = open("/dev/vfio/26", O_RDWR);
187
188	/* Test the group is viable and available */
189	ioctl(group, VFIO_GROUP_GET_STATUS, &group_status);
190
191	if (!(group_status.flags & VFIO_GROUP_FLAGS_VIABLE))
192		/* Group is not viable (ie, not all devices bound for vfio) */
193
194	/* Add the group to the container */
195	ioctl(group, VFIO_GROUP_SET_CONTAINER, &container);
196
197	/* Enable the IOMMU model we want */
198	ioctl(container, VFIO_SET_IOMMU, VFIO_TYPE1_IOMMU);
199
200	/* Get addition IOMMU info */
201	ioctl(container, VFIO_IOMMU_GET_INFO, &iommu_info);
202
203	/* Allocate some space and setup a DMA mapping */
204	dma_map.vaddr = mmap(0, 1024 * 1024, PROT_READ | PROT_WRITE,
205			     MAP_PRIVATE | MAP_ANONYMOUS, 0, 0);
206	dma_map.size = 1024 * 1024;
207	dma_map.iova = 0; /* 1MB starting at 0x0 from device view */
208	dma_map.flags = VFIO_DMA_MAP_FLAG_READ | VFIO_DMA_MAP_FLAG_WRITE;
209
210	ioctl(container, VFIO_IOMMU_MAP_DMA, &dma_map);
211
212	/* Get a file descriptor for the device */
213	device = ioctl(group, VFIO_GROUP_GET_DEVICE_FD, "0000:06:0d.0");
214
215	/* Test and setup the device */
216	ioctl(device, VFIO_DEVICE_GET_INFO, &device_info);
217
218	for (i = 0; i < device_info.num_regions; i++) {
219		struct vfio_region_info reg = { .argsz = sizeof(reg) };
220
221		reg.index = i;
222
223		ioctl(device, VFIO_DEVICE_GET_REGION_INFO, &reg);
224
225		/* Setup mappings... read/write offsets, mmaps
226		 * For PCI devices, config space is a region */
227	}
228
229	for (i = 0; i < device_info.num_irqs; i++) {
230		struct vfio_irq_info irq = { .argsz = sizeof(irq) };
231
232		irq.index = i;
233
234		ioctl(device, VFIO_DEVICE_GET_IRQ_INFO, &irq);
235
236		/* Setup IRQs... eventfds, VFIO_DEVICE_SET_IRQS */
237	}
238
239	/* Gratuitous device reset and go... */
240	ioctl(device, VFIO_DEVICE_RESET);
241
242IOMMUFD and vfio_iommu_type1
243----------------------------
244
245IOMMUFD is the new user API to manage I/O page tables from userspace.
246It intends to be the portal of delivering advanced userspace DMA
247features (nested translation [5]_, PASID [6]_, etc.) while also providing
248a backwards compatibility interface for existing VFIO_TYPE1v2_IOMMU use
249cases.  Eventually the vfio_iommu_type1 driver, as well as the legacy
250vfio container and group model is intended to be deprecated.
251
252The IOMMUFD backwards compatibility interface can be enabled two ways.
253In the first method, the kernel can be configured with
254CONFIG_IOMMUFD_VFIO_CONTAINER, in which case the IOMMUFD subsystem
255transparently provides the entire infrastructure for the VFIO
256container and IOMMU backend interfaces.  The compatibility mode can
257also be accessed if the VFIO container interface, ie. /dev/vfio/vfio is
258simply symlink'd to /dev/iommu.  Note that at the time of writing, the
259compatibility mode is not entirely feature complete relative to
260VFIO_TYPE1v2_IOMMU (ex. DMA mapping MMIO) and does not attempt to
261provide compatibility to the VFIO_SPAPR_TCE_IOMMU interface.  Therefore
262it is not generally advisable at this time to switch from native VFIO
263implementations to the IOMMUFD compatibility interfaces.
264
265Long term, VFIO users should migrate to device access through the cdev
266interface described below, and native access through the IOMMUFD
267provided interfaces.
268
269VFIO Device cdev
270----------------
271
272Traditionally user acquires a device fd via VFIO_GROUP_GET_DEVICE_FD
273in a VFIO group.
274
275With CONFIG_VFIO_DEVICE_CDEV=y the user can now acquire a device fd
276by directly opening a character device /dev/vfio/devices/vfioX where
277"X" is the number allocated uniquely by VFIO for registered devices.
278cdev interface does not support noiommu devices, so user should use
279the legacy group interface if noiommu is wanted.
280
281The cdev only works with IOMMUFD.  Both VFIO drivers and applications
282must adapt to the new cdev security model which requires using
283VFIO_DEVICE_BIND_IOMMUFD to claim DMA ownership before starting to
284actually use the device.  Once BIND succeeds then a VFIO device can
285be fully accessed by the user.
286
287VFIO device cdev doesn't rely on VFIO group/container/iommu drivers.
288Hence those modules can be fully compiled out in an environment
289where no legacy VFIO application exists.
290
291So far SPAPR does not support IOMMUFD yet.  So it cannot support device
292cdev either.
293
294vfio device cdev access is still bound by IOMMU group semantics, ie. there
295can be only one DMA owner for the group.  Devices belonging to the same
296group can not be bound to multiple iommufd_ctx or shared between native
297kernel and vfio bus driver or other driver supporting the driver_managed_dma
298flag.  A violation of this ownership requirement will fail at the
299VFIO_DEVICE_BIND_IOMMUFD ioctl, which gates full device access.
300
301Device cdev Example
302-------------------
303
304Assume user wants to access PCI device 0000:6a:01.0::
305
306	$ ls /sys/bus/pci/devices/0000:6a:01.0/vfio-dev/
307	vfio0
308
309This device is therefore represented as vfio0.  The user can verify
310its existence::
311
312	$ ls -l /dev/vfio/devices/vfio0
313	crw------- 1 root root 511, 0 Feb 16 01:22 /dev/vfio/devices/vfio0
314	$ cat /sys/bus/pci/devices/0000:6a:01.0/vfio-dev/vfio0/dev
315	511:0
316	$ ls -l /dev/char/511\:0
317	lrwxrwxrwx 1 root root 21 Feb 16 01:22 /dev/char/511:0 -> ../vfio/devices/vfio0
318
319Then provide the user with access to the device if unprivileged
320operation is desired::
321
322	$ chown user:user /dev/vfio/devices/vfio0
323
324Finally the user could get cdev fd by::
325
326	cdev_fd = open("/dev/vfio/devices/vfio0", O_RDWR);
327
328An opened cdev_fd doesn't give the user any permission of accessing
329the device except binding the cdev_fd to an iommufd.  After that point
330then the device is fully accessible including attaching it to an
331IOMMUFD IOAS/HWPT to enable userspace DMA::
332
333	struct vfio_device_bind_iommufd bind = {
334		.argsz = sizeof(bind),
335		.flags = 0,
336	};
337	struct iommu_ioas_alloc alloc_data  = {
338		.size = sizeof(alloc_data),
339		.flags = 0,
340	};
341	struct vfio_device_attach_iommufd_pt attach_data = {
342		.argsz = sizeof(attach_data),
343		.flags = 0,
344	};
345	struct iommu_ioas_map map = {
346		.size = sizeof(map),
347		.flags = IOMMU_IOAS_MAP_READABLE |
348			 IOMMU_IOAS_MAP_WRITEABLE |
349			 IOMMU_IOAS_MAP_FIXED_IOVA,
350		.__reserved = 0,
351	};
352
353	iommufd = open("/dev/iommu", O_RDWR);
354
355	bind.iommufd = iommufd;
356	ioctl(cdev_fd, VFIO_DEVICE_BIND_IOMMUFD, &bind);
357
358	ioctl(iommufd, IOMMU_IOAS_ALLOC, &alloc_data);
359	attach_data.pt_id = alloc_data.out_ioas_id;
360	ioctl(cdev_fd, VFIO_DEVICE_ATTACH_IOMMUFD_PT, &attach_data);
361
362	/* Allocate some space and setup a DMA mapping */
363	map.user_va = (int64_t)mmap(0, 1024 * 1024, PROT_READ | PROT_WRITE,
364				    MAP_PRIVATE | MAP_ANONYMOUS, 0, 0);
365	map.iova = 0; /* 1MB starting at 0x0 from device view */
366	map.length = 1024 * 1024;
367	map.ioas_id = alloc_data.out_ioas_id;;
368
369	ioctl(iommufd, IOMMU_IOAS_MAP, &map);
370
371	/* Other device operations as stated in "VFIO Usage Example" */
372
373VFIO User API
374-------------------------------------------------------------------------------
375
376Please see include/uapi/linux/vfio.h for complete API documentation.
377
378VFIO bus driver API
379-------------------------------------------------------------------------------
380
381VFIO bus drivers, such as vfio-pci make use of only a few interfaces
382into VFIO core.  When devices are bound and unbound to the driver,
383Following interfaces are called when devices are bound to and
384unbound from the driver::
385
386	int vfio_register_group_dev(struct vfio_device *device);
387	int vfio_register_emulated_iommu_dev(struct vfio_device *device);
388	void vfio_unregister_group_dev(struct vfio_device *device);
389
390The driver should embed the vfio_device in its own structure and use
391vfio_alloc_device() to allocate the structure, and can register
392@init/@release callbacks to manage any private state wrapping the
393vfio_device::
394
395	vfio_alloc_device(dev_struct, member, dev, ops);
396	void vfio_put_device(struct vfio_device *device);
397
398vfio_register_group_dev() indicates to the core to begin tracking the
399iommu_group of the specified dev and register the dev as owned by a VFIO bus
400driver. Once vfio_register_group_dev() returns it is possible for userspace to
401start accessing the driver, thus the driver should ensure it is completely
402ready before calling it. The driver provides an ops structure for callbacks
403similar to a file operations structure::
404
405	struct vfio_device_ops {
406		char	*name;
407		int	(*init)(struct vfio_device *vdev);
408		void	(*release)(struct vfio_device *vdev);
409		int	(*bind_iommufd)(struct vfio_device *vdev,
410					struct iommufd_ctx *ictx, u32 *out_device_id);
411		void	(*unbind_iommufd)(struct vfio_device *vdev);
412		int	(*attach_ioas)(struct vfio_device *vdev, u32 *pt_id);
413		void	(*detach_ioas)(struct vfio_device *vdev);
414		int	(*open_device)(struct vfio_device *vdev);
415		void	(*close_device)(struct vfio_device *vdev);
416		ssize_t	(*read)(struct vfio_device *vdev, char __user *buf,
417				size_t count, loff_t *ppos);
418		ssize_t	(*write)(struct vfio_device *vdev, const char __user *buf,
419			 size_t count, loff_t *size);
420		long	(*ioctl)(struct vfio_device *vdev, unsigned int cmd,
421				 unsigned long arg);
422		int	(*mmap)(struct vfio_device *vdev, struct vm_area_struct *vma);
423		void	(*request)(struct vfio_device *vdev, unsigned int count);
424		int	(*match)(struct vfio_device *vdev, char *buf);
425		void	(*dma_unmap)(struct vfio_device *vdev, u64 iova, u64 length);
426		int	(*device_feature)(struct vfio_device *device, u32 flags,
427					  void __user *arg, size_t argsz);
428	};
429
430Each function is passed the vdev that was originally registered
431in the vfio_register_group_dev() or vfio_register_emulated_iommu_dev()
432call above. This allows the bus driver to obtain its private data using
433container_of().
434
435::
436
437	- The init/release callbacks are issued when vfio_device is initialized
438	  and released.
439
440	- The open/close device callbacks are issued when the first
441	  instance of a file descriptor for the device is created (eg.
442	  via VFIO_GROUP_GET_DEVICE_FD) for a user session.
443
444	- The ioctl callback provides a direct pass through for some VFIO_DEVICE_*
445	  ioctls.
446
447	- The [un]bind_iommufd callbacks are issued when the device is bound to
448	  and unbound from iommufd.
449
450	- The [de]attach_ioas callback is issued when the device is attached to
451	  and detached from an IOAS managed by the bound iommufd. However, the
452	  attached IOAS can also be automatically detached when the device is
453	  unbound from iommufd.
454
455	- The read/write/mmap callbacks implement the device region access defined
456	  by the device's own VFIO_DEVICE_GET_REGION_INFO ioctl.
457
458	- The request callback is issued when device is going to be unregistered,
459	  such as when trying to unbind the device from the vfio bus driver.
460
461	- The dma_unmap callback is issued when a range of iovas are unmapped
462	  in the container or IOAS attached by the device. Drivers which make
463	  use of the vfio page pinning interface must implement this callback in
464	  order to unpin pages within the dma_unmap range. Drivers must tolerate
465	  this callback even before calls to open_device().
466
467PPC64 sPAPR implementation note
468-------------------------------
469
470This implementation has some specifics:
471
4721) On older systems (POWER7 with P5IOC2/IODA1) only one IOMMU group per
473   container is supported as an IOMMU table is allocated at the boot time,
474   one table per a IOMMU group which is a Partitionable Endpoint (PE)
475   (PE is often a PCI domain but not always).
476
477   Newer systems (POWER8 with IODA2) have improved hardware design which allows
478   to remove this limitation and have multiple IOMMU groups per a VFIO
479   container.
480
4812) The hardware supports so called DMA windows - the PCI address range
482   within which DMA transfer is allowed, any attempt to access address space
483   out of the window leads to the whole PE isolation.
484
4853) PPC64 guests are paravirtualized but not fully emulated. There is an API
486   to map/unmap pages for DMA, and it normally maps 1..32 pages per call and
487   currently there is no way to reduce the number of calls. In order to make
488   things faster, the map/unmap handling has been implemented in real mode
489   which provides an excellent performance which has limitations such as
490   inability to do locked pages accounting in real time.
491
4924) According to sPAPR specification, A Partitionable Endpoint (PE) is an I/O
493   subtree that can be treated as a unit for the purposes of partitioning and
494   error recovery. A PE may be a single or multi-function IOA (IO Adapter), a
495   function of a multi-function IOA, or multiple IOAs (possibly including
496   switch and bridge structures above the multiple IOAs). PPC64 guests detect
497   PCI errors and recover from them via EEH RTAS services, which works on the
498   basis of additional ioctl commands.
499
500   So 4 additional ioctls have been added:
501
502	VFIO_IOMMU_SPAPR_TCE_GET_INFO
503		returns the size and the start of the DMA window on the PCI bus.
504
505	VFIO_IOMMU_ENABLE
506		enables the container. The locked pages accounting
507		is done at this point. This lets user first to know what
508		the DMA window is and adjust rlimit before doing any real job.
509
510	VFIO_IOMMU_DISABLE
511		disables the container.
512
513	VFIO_EEH_PE_OP
514		provides an API for EEH setup, error detection and recovery.
515
516   The code flow from the example above should be slightly changed::
517
518	struct vfio_eeh_pe_op pe_op = { .argsz = sizeof(pe_op), .flags = 0 };
519
520	.....
521	/* Add the group to the container */
522	ioctl(group, VFIO_GROUP_SET_CONTAINER, &container);
523
524	/* Enable the IOMMU model we want */
525	ioctl(container, VFIO_SET_IOMMU, VFIO_SPAPR_TCE_IOMMU)
526
527	/* Get addition sPAPR IOMMU info */
528	vfio_iommu_spapr_tce_info spapr_iommu_info;
529	ioctl(container, VFIO_IOMMU_SPAPR_TCE_GET_INFO, &spapr_iommu_info);
530
531	if (ioctl(container, VFIO_IOMMU_ENABLE))
532		/* Cannot enable container, may be low rlimit */
533
534	/* Allocate some space and setup a DMA mapping */
535	dma_map.vaddr = mmap(0, 1024 * 1024, PROT_READ | PROT_WRITE,
536			     MAP_PRIVATE | MAP_ANONYMOUS, 0, 0);
537
538	dma_map.size = 1024 * 1024;
539	dma_map.iova = 0; /* 1MB starting at 0x0 from device view */
540	dma_map.flags = VFIO_DMA_MAP_FLAG_READ | VFIO_DMA_MAP_FLAG_WRITE;
541
542	/* Check here is .iova/.size are within DMA window from spapr_iommu_info */
543	ioctl(container, VFIO_IOMMU_MAP_DMA, &dma_map);
544
545	/* Get a file descriptor for the device */
546	device = ioctl(group, VFIO_GROUP_GET_DEVICE_FD, "0000:06:0d.0");
547
548	....
549
550	/* Gratuitous device reset and go... */
551	ioctl(device, VFIO_DEVICE_RESET);
552
553	/* Make sure EEH is supported */
554	ioctl(container, VFIO_CHECK_EXTENSION, VFIO_EEH);
555
556	/* Enable the EEH functionality on the device */
557	pe_op.op = VFIO_EEH_PE_ENABLE;
558	ioctl(container, VFIO_EEH_PE_OP, &pe_op);
559
560	/* You're suggested to create additional data struct to represent
561	 * PE, and put child devices belonging to same IOMMU group to the
562	 * PE instance for later reference.
563	 */
564
565	/* Check the PE's state and make sure it's in functional state */
566	pe_op.op = VFIO_EEH_PE_GET_STATE;
567	ioctl(container, VFIO_EEH_PE_OP, &pe_op);
568
569	/* Save device state using pci_save_state().
570	 * EEH should be enabled on the specified device.
571	 */
572
573	....
574
575	/* Inject EEH error, which is expected to be caused by 32-bits
576	 * config load.
577	 */
578	pe_op.op = VFIO_EEH_PE_INJECT_ERR;
579	pe_op.err.type = EEH_ERR_TYPE_32;
580	pe_op.err.func = EEH_ERR_FUNC_LD_CFG_ADDR;
581	pe_op.err.addr = 0ul;
582	pe_op.err.mask = 0ul;
583	ioctl(container, VFIO_EEH_PE_OP, &pe_op);
584
585	....
586
587	/* When 0xFF's returned from reading PCI config space or IO BARs
588	 * of the PCI device. Check the PE's state to see if that has been
589	 * frozen.
590	 */
591	ioctl(container, VFIO_EEH_PE_OP, &pe_op);
592
593	/* Waiting for pending PCI transactions to be completed and don't
594	 * produce any more PCI traffic from/to the affected PE until
595	 * recovery is finished.
596	 */
597
598	/* Enable IO for the affected PE and collect logs. Usually, the
599	 * standard part of PCI config space, AER registers are dumped
600	 * as logs for further analysis.
601	 */
602	pe_op.op = VFIO_EEH_PE_UNFREEZE_IO;
603	ioctl(container, VFIO_EEH_PE_OP, &pe_op);
604
605	/*
606	 * Issue PE reset: hot or fundamental reset. Usually, hot reset
607	 * is enough. However, the firmware of some PCI adapters would
608	 * require fundamental reset.
609	 */
610	pe_op.op = VFIO_EEH_PE_RESET_HOT;
611	ioctl(container, VFIO_EEH_PE_OP, &pe_op);
612	pe_op.op = VFIO_EEH_PE_RESET_DEACTIVATE;
613	ioctl(container, VFIO_EEH_PE_OP, &pe_op);
614
615	/* Configure the PCI bridges for the affected PE */
616	pe_op.op = VFIO_EEH_PE_CONFIGURE;
617	ioctl(container, VFIO_EEH_PE_OP, &pe_op);
618
619	/* Restored state we saved at initialization time. pci_restore_state()
620	 * is good enough as an example.
621	 */
622
623	/* Hopefully, error is recovered successfully. Now, you can resume to
624	 * start PCI traffic to/from the affected PE.
625	 */
626
627	....
628
6295) There is v2 of SPAPR TCE IOMMU. It deprecates VFIO_IOMMU_ENABLE/
630   VFIO_IOMMU_DISABLE and implements 2 new ioctls:
631   VFIO_IOMMU_SPAPR_REGISTER_MEMORY and VFIO_IOMMU_SPAPR_UNREGISTER_MEMORY
632   (which are unsupported in v1 IOMMU).
633
634   PPC64 paravirtualized guests generate a lot of map/unmap requests,
635   and the handling of those includes pinning/unpinning pages and updating
636   mm::locked_vm counter to make sure we do not exceed the rlimit.
637   The v2 IOMMU splits accounting and pinning into separate operations:
638
639   - VFIO_IOMMU_SPAPR_REGISTER_MEMORY/VFIO_IOMMU_SPAPR_UNREGISTER_MEMORY ioctls
640     receive a user space address and size of the block to be pinned.
641     Bisecting is not supported and VFIO_IOMMU_UNREGISTER_MEMORY is expected to
642     be called with the exact address and size used for registering
643     the memory block. The userspace is not expected to call these often.
644     The ranges are stored in a linked list in a VFIO container.
645
646   - VFIO_IOMMU_MAP_DMA/VFIO_IOMMU_UNMAP_DMA ioctls only update the actual
647     IOMMU table and do not do pinning; instead these check that the userspace
648     address is from pre-registered range.
649
650   This separation helps in optimizing DMA for guests.
651
6526) sPAPR specification allows guests to have an additional DMA window(s) on
653   a PCI bus with a variable page size. Two ioctls have been added to support
654   this: VFIO_IOMMU_SPAPR_TCE_CREATE and VFIO_IOMMU_SPAPR_TCE_REMOVE.
655   The platform has to support the functionality or error will be returned to
656   the userspace. The existing hardware supports up to 2 DMA windows, one is
657   2GB long, uses 4K pages and called "default 32bit window"; the other can
658   be as big as entire RAM, use different page size, it is optional - guests
659   create those in run-time if the guest driver supports 64bit DMA.
660
661   VFIO_IOMMU_SPAPR_TCE_CREATE receives a page shift, a DMA window size and
662   a number of TCE table levels (if a TCE table is going to be big enough and
663   the kernel may not be able to allocate enough of physically contiguous
664   memory). It creates a new window in the available slot and returns the bus
665   address where the new window starts. Due to hardware limitation, the user
666   space cannot choose the location of DMA windows.
667
668   VFIO_IOMMU_SPAPR_TCE_REMOVE receives the bus start address of the window
669   and removes it.
670
671-------------------------------------------------------------------------------
672
673.. [1] VFIO was originally an acronym for "Virtual Function I/O" in its
674   initial implementation by Tom Lyon while as Cisco.  We've since
675   outgrown the acronym, but it's catchy.
676
677.. [2] "safe" also depends upon a device being "well behaved".  It's
678   possible for multi-function devices to have backdoors between
679   functions and even for single function devices to have alternative
680   access to things like PCI config space through MMIO registers.  To
681   guard against the former we can include additional precautions in the
682   IOMMU driver to group multi-function PCI devices together
683   (iommu=group_mf).  The latter we can't prevent, but the IOMMU should
684   still provide isolation.  For PCI, SR-IOV Virtual Functions are the
685   best indicator of "well behaved", as these are designed for
686   virtualization usage models.
687
688.. [3] As always there are trade-offs to virtual machine device
689   assignment that are beyond the scope of VFIO.  It's expected that
690   future IOMMU technologies will reduce some, but maybe not all, of
691   these trade-offs.
692
693.. [4] In this case the device is below a PCI bridge, so transactions
694   from either function of the device are indistinguishable to the iommu::
695
696	-[0000:00]-+-1e.0-[06]--+-0d.0
697				\-0d.1
698
699	00:1e.0 PCI bridge: Intel Corporation 82801 PCI Bridge (rev 90)
700
701.. [5] Nested translation is an IOMMU feature which supports two stage
702   address translations.  This improves the address translation efficiency
703   in IOMMU virtualization.
704
705.. [6] PASID stands for Process Address Space ID, introduced by PCI
706   Express.  It is a prerequisite for Shared Virtual Addressing (SVA)
707   and Scalable I/O Virtualization (Scalable IOV).
708