xref: /linux/Documentation/target/tcmu-design.rst (revision c532de5a67a70f8533d495f8f2aaa9a0491c3ad0)
1====================
2TCM Userspace Design
3====================
4
5
6.. Contents:
7
8   1) Design
9     a) Background
10     b) Benefits
11     c) Design constraints
12     d) Implementation overview
13        i. Mailbox
14        ii. Command ring
15        iii. Data Area
16     e) Device discovery
17     f) Device events
18     g) Other contingencies
19   2) Writing a user pass-through handler
20     a) Discovering and configuring TCMU uio devices
21     b) Waiting for events on the device(s)
22     c) Managing the command ring
23   3) A final note
24
25
26Design
27======
28
29TCM is another name for LIO, an in-kernel iSCSI target (server).
30Existing TCM targets run in the kernel.  TCMU (TCM in Userspace)
31allows userspace programs to be written which act as iSCSI targets.
32This document describes the design.
33
34The existing kernel provides modules for different SCSI transport
35protocols.  TCM also modularizes the data storage.  There are existing
36modules for file, block device, RAM or using another SCSI device as
37storage.  These are called "backstores" or "storage engines".  These
38built-in modules are implemented entirely as kernel code.
39
40Background
41----------
42
43In addition to modularizing the transport protocol used for carrying
44SCSI commands ("fabrics"), the Linux kernel target, LIO, also modularizes
45the actual data storage as well. These are referred to as "backstores"
46or "storage engines". The target comes with backstores that allow a
47file, a block device, RAM, or another SCSI device to be used for the
48local storage needed for the exported SCSI LUN. Like the rest of LIO,
49these are implemented entirely as kernel code.
50
51These backstores cover the most common use cases, but not all. One new
52use case that other non-kernel target solutions, such as tgt, are able
53to support is using Gluster's GLFS or Ceph's RBD as a backstore. The
54target then serves as a translator, allowing initiators to store data
55in these non-traditional networked storage systems, while still only
56using standard protocols themselves.
57
58If the target is a userspace process, supporting these is easy. tgt,
59for example, needs only a small adapter module for each, because the
60modules just use the available userspace libraries for RBD and GLFS.
61
62Adding support for these backstores in LIO is considerably more
63difficult, because LIO is entirely kernel code. Instead of undertaking
64the significant work to port the GLFS or RBD APIs and protocols to the
65kernel, another approach is to create a userspace pass-through
66backstore for LIO, "TCMU".
67
68
69Benefits
70--------
71
72In addition to allowing relatively easy support for RBD and GLFS, TCMU
73will also allow easier development of new backstores. TCMU combines
74with the LIO loopback fabric to become something similar to FUSE
75(Filesystem in Userspace), but at the SCSI layer instead of the
76filesystem layer. A SUSE, if you will.
77
78The disadvantage is there are more distinct components to configure, and
79potentially to malfunction. This is unavoidable, but hopefully not
80fatal if we're careful to keep things as simple as possible.
81
82Design constraints
83------------------
84
85- Good performance: high throughput, low latency
86- Cleanly handle if userspace:
87
88   1) never attaches
89   2) hangs
90   3) dies
91   4) misbehaves
92
93- Allow future flexibility in user & kernel implementations
94- Be reasonably memory-efficient
95- Simple to configure & run
96- Simple to write a userspace backend
97
98
99Implementation overview
100-----------------------
101
102The core of the TCMU interface is a memory region that is shared
103between kernel and userspace. Within this region is: a control area
104(mailbox); a lockless producer/consumer circular buffer for commands
105to be passed up, and status returned; and an in/out data buffer area.
106
107TCMU uses the pre-existing UIO subsystem. UIO allows device driver
108development in userspace, and this is conceptually very close to the
109TCMU use case, except instead of a physical device, TCMU implements a
110memory-mapped layout designed for SCSI commands. Using UIO also
111benefits TCMU by handling device introspection (e.g. a way for
112userspace to determine how large the shared region is) and signaling
113mechanisms in both directions.
114
115There are no embedded pointers in the memory region. Everything is
116expressed as an offset from the region's starting address. This allows
117the ring to still work if the user process dies and is restarted with
118the region mapped at a different virtual address.
119
120See target_core_user.h for the struct definitions.
121
122The Mailbox
123-----------
124
125The mailbox is always at the start of the shared memory region, and
126contains a version, details about the starting offset and size of the
127command ring, and head and tail pointers to be used by the kernel and
128userspace (respectively) to put commands on the ring, and indicate
129when the commands are completed.
130
131version - 1 (userspace should abort if otherwise)
132
133flags:
134    - TCMU_MAILBOX_FLAG_CAP_OOOC:
135	indicates out-of-order completion is supported.
136	See "The Command Ring" for details.
137
138cmdr_off
139	The offset of the start of the command ring from the start
140	of the memory region, to account for the mailbox size.
141cmdr_size
142	The size of the command ring. This does *not* need to be a
143	power of two.
144cmd_head
145	Modified by the kernel to indicate when a command has been
146	placed on the ring.
147cmd_tail
148	Modified by userspace to indicate when it has completed
149	processing of a command.
150
151The Command Ring
152----------------
153
154Commands are placed on the ring by the kernel incrementing
155mailbox.cmd_head by the size of the command, modulo cmdr_size, and
156then signaling userspace via uio_event_notify(). Once the command is
157completed, userspace updates mailbox.cmd_tail in the same way and
158signals the kernel via a 4-byte write(). When cmd_head equals
159cmd_tail, the ring is empty -- no commands are currently waiting to be
160processed by userspace.
161
162TCMU commands are 8-byte aligned. They start with a common header
163containing "len_op", a 32-bit value that stores the length, as well as
164the opcode in the lowest unused bits. It also contains cmd_id and
165flags fields for setting by the kernel (kflags) and userspace
166(uflags).
167
168Currently only two opcodes are defined, TCMU_OP_CMD and TCMU_OP_PAD.
169
170When the opcode is CMD, the entry in the command ring is a struct
171tcmu_cmd_entry. Userspace finds the SCSI CDB (Command Data Block) via
172tcmu_cmd_entry.req.cdb_off. This is an offset from the start of the
173overall shared memory region, not the entry. The data in/out buffers
174are accessible via the req.iov[] array. iov_cnt contains the number of
175entries in iov[] needed to describe either the Data-In or Data-Out
176buffers. For bidirectional commands, iov_cnt specifies how many iovec
177entries cover the Data-Out area, and iov_bidi_cnt specifies how many
178iovec entries immediately after that in iov[] cover the Data-In
179area. Just like other fields, iov.iov_base is an offset from the start
180of the region.
181
182When completing a command, userspace sets rsp.scsi_status, and
183rsp.sense_buffer if necessary. Userspace then increments
184mailbox.cmd_tail by entry.hdr.length (mod cmdr_size) and signals the
185kernel via the UIO method, a 4-byte write to the file descriptor.
186
187If TCMU_MAILBOX_FLAG_CAP_OOOC is set for mailbox->flags, kernel is
188capable of handling out-of-order completions. In this case, userspace can
189handle command in different order other than original. Since kernel would
190still process the commands in the same order it appeared in the command
191ring, userspace need to update the cmd->id when completing the
192command(a.k.a steal the original command's entry).
193
194When the opcode is PAD, userspace only updates cmd_tail as above --
195it's a no-op. (The kernel inserts PAD entries to ensure each CMD entry
196is contiguous within the command ring.)
197
198More opcodes may be added in the future. If userspace encounters an
199opcode it does not handle, it must set UNKNOWN_OP bit (bit 0) in
200hdr.uflags, update cmd_tail, and proceed with processing additional
201commands, if any.
202
203The Data Area
204-------------
205
206This is shared-memory space after the command ring. The organization
207of this area is not defined in the TCMU interface, and userspace
208should access only the parts referenced by pending iovs.
209
210
211Device Discovery
212----------------
213
214Other devices may be using UIO besides TCMU. Unrelated user processes
215may also be handling different sets of TCMU devices. TCMU userspace
216processes must find their devices by scanning sysfs
217class/uio/uio*/name. For TCMU devices, these names will be of the
218format::
219
220	tcm-user/<hba_num>/<device_name>/<subtype>/<path>
221
222where "tcm-user" is common for all TCMU-backed UIO devices. <hba_num>
223and <device_name> allow userspace to find the device's path in the
224kernel target's configfs tree. Assuming the usual mount point, it is
225found at::
226
227	/sys/kernel/config/target/core/user_<hba_num>/<device_name>
228
229This location contains attributes such as "hw_block_size", that
230userspace needs to know for correct operation.
231
232<subtype> will be a userspace-process-unique string to identify the
233TCMU device as expecting to be backed by a certain handler, and <path>
234will be an additional handler-specific string for the user process to
235configure the device, if needed. The name cannot contain ':', due to
236LIO limitations.
237
238For all devices so discovered, the user handler opens /dev/uioX and
239calls mmap()::
240
241	mmap(NULL, size, PROT_READ|PROT_WRITE, MAP_SHARED, fd, 0)
242
243where size must be equal to the value read from
244/sys/class/uio/uioX/maps/map0/size.
245
246
247Device Events
248-------------
249
250If a new device is added or removed, a notification will be broadcast
251over netlink, using a generic netlink family name of "TCM-USER" and a
252multicast group named "config". This will include the UIO name as
253described in the previous section, as well as the UIO minor
254number. This should allow userspace to identify both the UIO device and
255the LIO device, so that after determining the device is supported
256(based on subtype) it can take the appropriate action.
257
258
259Other contingencies
260-------------------
261
262Userspace handler process never attaches:
263
264- TCMU will post commands, and then abort them after a timeout period
265  (30 seconds.)
266
267Userspace handler process is killed:
268
269- It is still possible to restart and re-connect to TCMU
270  devices. Command ring is preserved. However, after the timeout period,
271  the kernel will abort pending tasks.
272
273Userspace handler process hangs:
274
275- The kernel will abort pending tasks after a timeout period.
276
277Userspace handler process is malicious:
278
279- The process can trivially break the handling of devices it controls,
280  but should not be able to access kernel memory outside its shared
281  memory areas.
282
283
284Writing a user pass-through handler (with example code)
285=======================================================
286
287A user process handing a TCMU device must support the following:
288
289a) Discovering and configuring TCMU uio devices
290b) Waiting for events on the device(s)
291c) Managing the command ring: Parsing operations and commands,
292   performing work as needed, setting response fields (scsi_status and
293   possibly sense_buffer), updating cmd_tail, and notifying the kernel
294   that work has been finished
295
296First, consider instead writing a plugin for tcmu-runner. tcmu-runner
297implements all of this, and provides a higher-level API for plugin
298authors.
299
300TCMU is designed so that multiple unrelated processes can manage TCMU
301devices separately. All handlers should make sure to only open their
302devices, based opon a known subtype string.
303
304a) Discovering and configuring TCMU UIO devices::
305
306      /* error checking omitted for brevity */
307
308      int fd, dev_fd;
309      char buf[256];
310      unsigned long long map_len;
311      void *map;
312
313      fd = open("/sys/class/uio/uio0/name", O_RDONLY);
314      ret = read(fd, buf, sizeof(buf));
315      close(fd);
316      buf[ret-1] = '\0'; /* null-terminate and chop off the \n */
317
318      /* we only want uio devices whose name is a format we expect */
319      if (strncmp(buf, "tcm-user", 8))
320	exit(-1);
321
322      /* Further checking for subtype also needed here */
323
324      fd = open(/sys/class/uio/%s/maps/map0/size, O_RDONLY);
325      ret = read(fd, buf, sizeof(buf));
326      close(fd);
327      str_buf[ret-1] = '\0'; /* null-terminate and chop off the \n */
328
329      map_len = strtoull(buf, NULL, 0);
330
331      dev_fd = open("/dev/uio0", O_RDWR);
332      map = mmap(NULL, map_len, PROT_READ|PROT_WRITE, MAP_SHARED, dev_fd, 0);
333
334
335      b) Waiting for events on the device(s)
336
337      while (1) {
338        char buf[4];
339
340        int ret = read(dev_fd, buf, 4); /* will block */
341
342        handle_device_events(dev_fd, map);
343      }
344
345
346c) Managing the command ring::
347
348      #include <linux/target_core_user.h>
349
350      int handle_device_events(int fd, void *map)
351      {
352        struct tcmu_mailbox *mb = map;
353        struct tcmu_cmd_entry *ent = (void *) mb + mb->cmdr_off + mb->cmd_tail;
354        int did_some_work = 0;
355
356        /* Process events from cmd ring until we catch up with cmd_head */
357        while (ent != (void *)mb + mb->cmdr_off + mb->cmd_head) {
358
359          if (tcmu_hdr_get_op(ent->hdr.len_op) == TCMU_OP_CMD) {
360            uint8_t *cdb = (void *)mb + ent->req.cdb_off;
361            bool success = true;
362
363            /* Handle command here. */
364            printf("SCSI opcode: 0x%x\n", cdb[0]);
365
366            /* Set response fields */
367            if (success)
368              ent->rsp.scsi_status = SCSI_NO_SENSE;
369            else {
370              /* Also fill in rsp->sense_buffer here */
371              ent->rsp.scsi_status = SCSI_CHECK_CONDITION;
372            }
373          }
374          else if (tcmu_hdr_get_op(ent->hdr.len_op) != TCMU_OP_PAD) {
375            /* Tell the kernel we didn't handle unknown opcodes */
376            ent->hdr.uflags |= TCMU_UFLAG_UNKNOWN_OP;
377          }
378          else {
379            /* Do nothing for PAD entries except update cmd_tail */
380          }
381
382          /* update cmd_tail */
383          mb->cmd_tail = (mb->cmd_tail + tcmu_hdr_get_len(&ent->hdr)) % mb->cmdr_size;
384          ent = (void *) mb + mb->cmdr_off + mb->cmd_tail;
385          did_some_work = 1;
386        }
387
388        /* Notify the kernel that work has been finished */
389        if (did_some_work) {
390          uint32_t buf = 0;
391
392          write(fd, &buf, 4);
393        }
394
395        return 0;
396      }
397
398
399A final note
400============
401
402Please be careful to return codes as defined by the SCSI
403specifications. These are different than some values defined in the
404scsi/scsi.h include file. For example, CHECK CONDITION's status code
405is 2, not 1.
406