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  1.. SPDX-License-Identifier: GPL-2.0
  2
  3===========================================
  4Userspace block device driver (ublk driver)
  5===========================================
  6
  7Overview
  8========
  9
 10ublk is a generic framework for implementing block device logic from userspace.
 11The motivation behind it is that moving virtual block drivers into userspace,
 12such as loop, nbd and similar can be very helpful. It can help to implement
 13new virtual block device such as ublk-qcow2 (there are several attempts of
 14implementing qcow2 driver in kernel).
 15
 16Userspace block devices are attractive because:
 17
 18- They can be written many programming languages.
 19- They can use libraries that are not available in the kernel.
 20- They can be debugged with tools familiar to application developers.
 21- Crashes do not kernel panic the machine.
 22- Bugs are likely to have a lower security impact than bugs in kernel
 23  code.
 24- They can be installed and updated independently of the kernel.
 25- They can be used to simulate block device easily with user specified
 26  parameters/setting for test/debug purpose
 27
 28ublk block device (``/dev/ublkb*``) is added by ublk driver. Any IO request
 29on the device will be forwarded to ublk userspace program. For convenience,
 30in this document, ``ublk server`` refers to generic ublk userspace
 31program. ``ublksrv`` [#userspace]_ is one of such implementation. It
 32provides ``libublksrv`` [#userspace_lib]_ library for developing specific
 33user block device conveniently, while also generic type block device is
 34included, such as loop and null. Richard W.M. Jones wrote userspace nbd device
 35``nbdublk`` [#userspace_nbdublk]_  based on ``libublksrv`` [#userspace_lib]_.
 36
 37After the IO is handled by userspace, the result is committed back to the
 38driver, thus completing the request cycle. This way, any specific IO handling
 39logic is totally done by userspace, such as loop's IO handling, NBD's IO
 40communication, or qcow2's IO mapping.
 41
 42``/dev/ublkb*`` is driven by blk-mq request-based driver. Each request is
 43assigned by one queue wide unique tag. ublk server assigns unique tag to each
 44IO too, which is 1:1 mapped with IO of ``/dev/ublkb*``.
 45
 46Both the IO request forward and IO handling result committing are done via
 47``io_uring`` passthrough command; that is why ublk is also one io_uring based
 48block driver. It has been observed that using io_uring passthrough command can
 49give better IOPS than block IO; which is why ublk is one of high performance
 50implementation of userspace block device: not only IO request communication is
 51done by io_uring, but also the preferred IO handling in ublk server is io_uring
 52based approach too.
 53
 54ublk provides control interface to set/get ublk block device parameters.
 55The interface is extendable and kabi compatible: basically any ublk request
 56queue's parameter or ublk generic feature parameters can be set/get via the
 57interface. Thus, ublk is generic userspace block device framework.
 58For example, it is easy to setup a ublk device with specified block
 59parameters from userspace.
 60
 61Using ublk
 62==========
 63
 64ublk requires userspace ublk server to handle real block device logic.
 65
 66Below is example of using ``ublksrv`` to provide ublk-based loop device.
 67
 68- add a device::
 69
 70     ublk add -t loop -f ublk-loop.img
 71
 72- format with xfs, then use it::
 73
 74     mkfs.xfs /dev/ublkb0
 75     mount /dev/ublkb0 /mnt
 76     # do anything. all IOs are handled by io_uring
 77     ...
 78     umount /mnt
 79
 80- list the devices with their info::
 81
 82     ublk list
 83
 84- delete the device::
 85
 86     ublk del -a
 87     ublk del -n $ublk_dev_id
 88
 89See usage details in README of ``ublksrv`` [#userspace_readme]_.
 90
 91Design
 92======
 93
 94Control plane
 95-------------
 96
 97ublk driver provides global misc device node (``/dev/ublk-control``) for
 98managing and controlling ublk devices with help of several control commands:
 99
100- ``UBLK_CMD_ADD_DEV``
101
102  Add a ublk char device (``/dev/ublkc*``) which is talked with ublk server
103  WRT IO command communication. Basic device info is sent together with this
104  command. It sets UAPI structure of ``ublksrv_ctrl_dev_info``,
105  such as ``nr_hw_queues``, ``queue_depth``, and max IO request buffer size,
106  for which the info is negotiated with the driver and sent back to the server.
107  When this command is completed, the basic device info is immutable.
108
109- ``UBLK_CMD_SET_PARAMS`` / ``UBLK_CMD_GET_PARAMS``
110
111  Set or get parameters of the device, which can be either generic feature
112  related, or request queue limit related, but can't be IO logic specific,
113  because the driver does not handle any IO logic. This command has to be
114  sent before sending ``UBLK_CMD_START_DEV``.
115
116- ``UBLK_CMD_START_DEV``
117
118  After the server prepares userspace resources (such as creating I/O handler
119  threads & io_uring for handling ublk IO), this command is sent to the
120  driver for allocating & exposing ``/dev/ublkb*``. Parameters set via
121  ``UBLK_CMD_SET_PARAMS`` are applied for creating the device.
122
123- ``UBLK_CMD_STOP_DEV``
124
125  Halt IO on ``/dev/ublkb*`` and remove the device. When this command returns,
126  ublk server will release resources (such as destroying I/O handler threads &
127  io_uring).
128
129- ``UBLK_CMD_DEL_DEV``
130
131  Remove ``/dev/ublkc*``. When this command returns, the allocated ublk device
132  number can be reused.
133
134- ``UBLK_CMD_GET_QUEUE_AFFINITY``
135
136  When ``/dev/ublkc`` is added, the driver creates block layer tagset, so
137  that each queue's affinity info is available. The server sends
138  ``UBLK_CMD_GET_QUEUE_AFFINITY`` to retrieve queue affinity info. It can
139  set up the per-queue context efficiently, such as bind affine CPUs with IO
140  pthread and try to allocate buffers in IO thread context.
141
142- ``UBLK_CMD_GET_DEV_INFO``
143
144  For retrieving device info via ``ublksrv_ctrl_dev_info``. It is the server's
145  responsibility to save IO target specific info in userspace.
146
147- ``UBLK_CMD_GET_DEV_INFO2``
148  Same purpose with ``UBLK_CMD_GET_DEV_INFO``, but ublk server has to
149  provide path of the char device of ``/dev/ublkc*`` for kernel to run
150  permission check, and this command is added for supporting unprivileged
151  ublk device, and introduced with ``UBLK_F_UNPRIVILEGED_DEV`` together.
152  Only the user owning the requested device can retrieve the device info.
153
154  How to deal with userspace/kernel compatibility:
155
156  1) if kernel is capable of handling ``UBLK_F_UNPRIVILEGED_DEV``
157
158    If ublk server supports ``UBLK_F_UNPRIVILEGED_DEV``:
159
160    ublk server should send ``UBLK_CMD_GET_DEV_INFO2``, given anytime
161    unprivileged application needs to query devices the current user owns,
162    when the application has no idea if ``UBLK_F_UNPRIVILEGED_DEV`` is set
163    given the capability info is stateless, and application should always
164    retrieve it via ``UBLK_CMD_GET_DEV_INFO2``
165
166    If ublk server doesn't support ``UBLK_F_UNPRIVILEGED_DEV``:
167
168    ``UBLK_CMD_GET_DEV_INFO`` is always sent to kernel, and the feature of
169    UBLK_F_UNPRIVILEGED_DEV isn't available for user
170
171  2) if kernel isn't capable of handling ``UBLK_F_UNPRIVILEGED_DEV``
172
173    If ublk server supports ``UBLK_F_UNPRIVILEGED_DEV``:
174
175    ``UBLK_CMD_GET_DEV_INFO2`` is tried first, and will be failed, then
176    ``UBLK_CMD_GET_DEV_INFO`` needs to be retried given
177    ``UBLK_F_UNPRIVILEGED_DEV`` can't be set
178
179    If ublk server doesn't support ``UBLK_F_UNPRIVILEGED_DEV``:
180
181    ``UBLK_CMD_GET_DEV_INFO`` is always sent to kernel, and the feature of
182    ``UBLK_F_UNPRIVILEGED_DEV`` isn't available for user
183
184- ``UBLK_CMD_START_USER_RECOVERY``
185
186  This command is valid if ``UBLK_F_USER_RECOVERY`` feature is enabled. This
187  command is accepted after the old process has exited, ublk device is quiesced
188  and ``/dev/ublkc*`` is released. User should send this command before he starts
189  a new process which re-opens ``/dev/ublkc*``. When this command returns, the
190  ublk device is ready for the new process.
191
192- ``UBLK_CMD_END_USER_RECOVERY``
193
194  This command is valid if ``UBLK_F_USER_RECOVERY`` feature is enabled. This
195  command is accepted after ublk device is quiesced and a new process has
196  opened ``/dev/ublkc*`` and get all ublk queues be ready. When this command
197  returns, ublk device is unquiesced and new I/O requests are passed to the
198  new process.
199
200- user recovery feature description
201
202  Three new features are added for user recovery: ``UBLK_F_USER_RECOVERY``,
203  ``UBLK_F_USER_RECOVERY_REISSUE``, and ``UBLK_F_USER_RECOVERY_FAIL_IO``. To
204  enable recovery of ublk devices after the ublk server exits, the ublk server
205  should specify the ``UBLK_F_USER_RECOVERY`` flag when creating the device. The
206  ublk server may additionally specify at most one of
207  ``UBLK_F_USER_RECOVERY_REISSUE`` and ``UBLK_F_USER_RECOVERY_FAIL_IO`` to
208  modify how I/O is handled while the ublk server is dying/dead (this is called
209  the ``nosrv`` case in the driver code).
210
211  With just ``UBLK_F_USER_RECOVERY`` set, after the ublk server exits,
212  ublk does not delete ``/dev/ublkb*`` during the whole
213  recovery stage and ublk device ID is kept. It is ublk server's
214  responsibility to recover the device context by its own knowledge.
215  Requests which have not been issued to userspace are requeued. Requests
216  which have been issued to userspace are aborted.
217
218  With ``UBLK_F_USER_RECOVERY_REISSUE`` additionally set, after the ublk server
219  exits, contrary to ``UBLK_F_USER_RECOVERY``,
220  requests which have been issued to userspace are requeued and will be
221  re-issued to the new process after handling ``UBLK_CMD_END_USER_RECOVERY``.
222  ``UBLK_F_USER_RECOVERY_REISSUE`` is designed for backends who tolerate
223  double-write since the driver may issue the same I/O request twice. It
224  might be useful to a read-only FS or a VM backend.
225
226  With ``UBLK_F_USER_RECOVERY_FAIL_IO`` additionally set, after the ublk server
227  exits, requests which have issued to userspace are failed, as are any
228  subsequently issued requests. Applications continuously issuing I/O against
229  devices with this flag set will see a stream of I/O errors until a new ublk
230  server recovers the device.
231
232Unprivileged ublk device is supported by passing ``UBLK_F_UNPRIVILEGED_DEV``.
233Once the flag is set, all control commands can be sent by unprivileged
234user. Except for command of ``UBLK_CMD_ADD_DEV``, permission check on
235the specified char device(``/dev/ublkc*``) is done for all other control
236commands by ublk driver, for doing that, path of the char device has to
237be provided in these commands' payload from ublk server. With this way,
238ublk device becomes container-ware, and device created in one container
239can be controlled/accessed just inside this container.
240
241Data plane
242----------
243
244The ublk server should create dedicated threads for handling I/O. Each
245thread should have its own io_uring through which it is notified of new
246I/O, and through which it can complete I/O. These dedicated threads
247should focus on IO handling and shouldn't handle any control &
248management tasks.
249
250The's IO is assigned by a unique tag, which is 1:1 mapping with IO
251request of ``/dev/ublkb*``.
252
253UAPI structure of ``ublksrv_io_desc`` is defined for describing each IO from
254the driver. A fixed mmapped area (array) on ``/dev/ublkc*`` is provided for
255exporting IO info to the server; such as IO offset, length, OP/flags and
256buffer address. Each ``ublksrv_io_desc`` instance can be indexed via queue id
257and IO tag directly.
258
259The following IO commands are communicated via io_uring passthrough command,
260and each command is only for forwarding the IO and committing the result
261with specified IO tag in the command data:
262
263- ``UBLK_IO_FETCH_REQ``
264
265  Sent from the server IO pthread for fetching future incoming IO requests
266  destined to ``/dev/ublkb*``. This command is sent only once from the server
267  IO pthread for ublk driver to setup IO forward environment.
268
269  Once a thread issues this command against a given (qid,tag) pair, the thread
270  registers itself as that I/O's daemon. In the future, only that I/O's daemon
271  is allowed to issue commands against the I/O. If any other thread attempts
272  to issue a command against a (qid,tag) pair for which the thread is not the
273  daemon, the command will fail. Daemons can be reset only be going through
274  recovery.
275
276  The ability for every (qid,tag) pair to have its own independent daemon task
277  is indicated by the ``UBLK_F_PER_IO_DAEMON`` feature. If this feature is not
278  supported by the driver, daemons must be per-queue instead - i.e. all I/Os
279  associated to a single qid must be handled by the same task.
280
281- ``UBLK_IO_COMMIT_AND_FETCH_REQ``
282
283  When an IO request is destined to ``/dev/ublkb*``, the driver stores
284  the IO's ``ublksrv_io_desc`` to the specified mapped area; then the
285  previous received IO command of this IO tag (either ``UBLK_IO_FETCH_REQ``
286  or ``UBLK_IO_COMMIT_AND_FETCH_REQ)`` is completed, so the server gets
287  the IO notification via io_uring.
288
289  After the server handles the IO, its result is committed back to the
290  driver by sending ``UBLK_IO_COMMIT_AND_FETCH_REQ`` back. Once ublkdrv
291  received this command, it parses the result and complete the request to
292  ``/dev/ublkb*``. In the meantime setup environment for fetching future
293  requests with the same IO tag. That is, ``UBLK_IO_COMMIT_AND_FETCH_REQ``
294  is reused for both fetching request and committing back IO result.
295
296- ``UBLK_IO_NEED_GET_DATA``
297
298  With ``UBLK_F_NEED_GET_DATA`` enabled, the WRITE request will be firstly
299  issued to ublk server without data copy. Then, IO backend of ublk server
300  receives the request and it can allocate data buffer and embed its addr
301  inside this new io command. After the kernel driver gets the command,
302  data copy is done from request pages to this backend's buffer. Finally,
303  backend receives the request again with data to be written and it can
304  truly handle the request.
305
306  ``UBLK_IO_NEED_GET_DATA`` adds one additional round-trip and one
307  io_uring_enter() syscall. Any user thinks that it may lower performance
308  should not enable UBLK_F_NEED_GET_DATA. ublk server pre-allocates IO
309  buffer for each IO by default. Any new project should try to use this
310  buffer to communicate with ublk driver. However, existing project may
311  break or not able to consume the new buffer interface; that's why this
312  command is added for backwards compatibility so that existing projects
313  can still consume existing buffers.
314
315- data copy between ublk server IO buffer and ublk block IO request
316
317  The driver needs to copy the block IO request pages into the server buffer
318  (pages) first for WRITE before notifying the server of the coming IO, so
319  that the server can handle WRITE request.
320
321  When the server handles READ request and sends
322  ``UBLK_IO_COMMIT_AND_FETCH_REQ`` to the server, ublkdrv needs to copy
323  the server buffer (pages) read to the IO request pages.
324
325Zero copy
326---------
327
328ublk zero copy relies on io_uring's fixed kernel buffer, which provides
329two APIs: `io_buffer_register_bvec()` and `io_buffer_unregister_bvec`.
330
331ublk adds IO command of `UBLK_IO_REGISTER_IO_BUF` to call
332`io_buffer_register_bvec()` for ublk server to register client request
333buffer into io_uring buffer table, then ublk server can submit io_uring
334IOs with the registered buffer index. IO command of `UBLK_IO_UNREGISTER_IO_BUF`
335calls `io_buffer_unregister_bvec()` to unregister the buffer, which is
336guaranteed to be live between calling `io_buffer_register_bvec()` and
337`io_buffer_unregister_bvec()`. Any io_uring operation which supports this
338kind of kernel buffer will grab one reference of the buffer until the
339operation is completed.
340
341ublk server implementing zero copy or user copy has to be CAP_SYS_ADMIN and
342be trusted, because it is ublk server's responsibility to make sure IO buffer
343filled with data for handling read command, and ublk server has to return
344correct result to ublk driver when handling READ command, and the result
345has to match with how many bytes filled to the IO buffer. Otherwise,
346uninitialized kernel IO buffer will be exposed to client application.
347
348ublk server needs to align the parameter of `struct ublk_param_dma_align`
349with backend for zero copy to work correctly.
350
351For reaching best IO performance, ublk server should align its segment
352parameter of `struct ublk_param_segment` with backend for avoiding
353unnecessary IO split, which usually hurts io_uring performance.
354
355Auto Buffer Registration
356------------------------
357
358The ``UBLK_F_AUTO_BUF_REG`` feature automatically handles buffer registration
359and unregistration for I/O requests, which simplifies the buffer management
360process and reduces overhead in the ublk server implementation.
361
362This is another feature flag for using zero copy, and it is compatible with
363``UBLK_F_SUPPORT_ZERO_COPY``.
364
365Feature Overview
366~~~~~~~~~~~~~~~~
367
368This feature automatically registers request buffers to the io_uring context
369before delivering I/O commands to the ublk server and unregisters them when
370completing I/O commands. This eliminates the need for manual buffer
371registration/unregistration via ``UBLK_IO_REGISTER_IO_BUF`` and
372``UBLK_IO_UNREGISTER_IO_BUF`` commands, then IO handling in ublk server
373can avoid dependency on the two uring_cmd operations.
374
375IOs can't be issued concurrently to io_uring if there is any dependency
376among these IOs. So this way not only simplifies ublk server implementation,
377but also makes concurrent IO handling becomes possible by removing the
378dependency on buffer registration & unregistration commands.
379
380Usage Requirements
381~~~~~~~~~~~~~~~~~~
382
3831. The ublk server must create a sparse buffer table on the same ``io_ring_ctx``
384   used for ``UBLK_IO_FETCH_REQ`` and ``UBLK_IO_COMMIT_AND_FETCH_REQ``. If
385   uring_cmd is issued on a different ``io_ring_ctx``, manual buffer
386   unregistration is required.
387
3882. Buffer registration data must be passed via uring_cmd's ``sqe->addr`` with the
389   following structure::
390
391    struct ublk_auto_buf_reg {
392        __u16 index;      /* Buffer index for registration */
393        __u8 flags;       /* Registration flags */
394        __u8 reserved0;   /* Reserved for future use */
395        __u32 reserved1;  /* Reserved for future use */
396    };
397
398   ublk_auto_buf_reg_to_sqe_addr() is for converting the above structure into
399   ``sqe->addr``.
400
4013. All reserved fields in ``ublk_auto_buf_reg`` must be zeroed.
402
4034. Optional flags can be passed via ``ublk_auto_buf_reg.flags``.
404
405Fallback Behavior
406~~~~~~~~~~~~~~~~~
407
408If auto buffer registration fails:
409
4101. When ``UBLK_AUTO_BUF_REG_FALLBACK`` is enabled:
411
412   - The uring_cmd is completed
413   - ``UBLK_IO_F_NEED_REG_BUF`` is set in ``ublksrv_io_desc.op_flags``
414   - The ublk server must manually deal with the failure, such as, register
415     the buffer manually, or using user copy feature for retrieving the data
416     for handling ublk IO
417
4182. If fallback is not enabled:
419
420   - The ublk I/O request fails silently
421   - The uring_cmd won't be completed
422
423Limitations
424~~~~~~~~~~~
425
426- Requires same ``io_ring_ctx`` for all operations
427- May require manual buffer management in fallback cases
428- io_ring_ctx buffer table has a max size of 16K, which may not be enough
429  in case that too many ublk devices are handled by this single io_ring_ctx
430  and each one has very large queue depth
431
432References
433==========
434
435.. [#userspace] https://github.com/ming1/ubdsrv
436
437.. [#userspace_lib] https://github.com/ming1/ubdsrv/tree/master/lib
438
439.. [#userspace_nbdublk] https://gitlab.com/rwmjones/libnbd/-/tree/nbdublk
440
441.. [#userspace_readme] https://github.com/ming1/ubdsrv/blob/master/README