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27.Dd April 3, 2019
28.Dt INTRO 4
29.Os
30.Sh NAME
31.Nm intro
32.Nd introduction to devices and device drivers
33.Sh DESCRIPTION
34This section contains information related to devices, device drivers
35and miscellaneous hardware.
36.Ss The device abstraction
37Device is a term used mostly for hardware-related stuff that belongs
38to the system, like disks, printers, or a graphics display with its
39keyboard.
40There are also so-called
41.Em pseudo-devices
42where a device driver emulates the behaviour of a device in software
43without any particular underlying hardware.
44A typical example for
45the latter class is
46.Pa /dev/mem ,
47a mechanism whereby the physical memory can be accessed using file
48access semantics.
49.Pp
50The device abstraction generally provides a common set of system
51calls, which are dispatched to the corresponding device driver by the
52upper layers of the kernel.
53The set of system calls available for devices is chosen from
54.Xr open 2 ,
55.Xr close 2 ,
56.Xr read 2 ,
57.Xr write 2 ,
58.Xr ioctl 2 ,
59.Xr select 2 ,
60and
61.Xr mmap 2 .
62Not all drivers implement all system calls; for example, calling
63.Xr mmap 2
64on a keyboard device is not likely to be useful.
65.Pp
66Aspects of the device abstraction have changed significantly in
67.Fx
68over the past two decades.
69The section
70.Sx Historical Notes
71describes some of the more important differences.
72.Ss Accessing Devices
73Most of the devices in
74.Fx
75are accessed through
76.Em device nodes ,
77sometimes also called
78.Em special files .
79They are located within instances of the
80.Xr devfs 5
81filesystem, which is conventionally mounted on the directory
82.Pa /dev
83in the file system hierarchy
84(see also
85.Xr hier 7 ) .
86.Pp
87The
88.Xr devfs 5
89filesystem creates or removes device nodes automatically according to
90the physical hardware recognized as present at any given time.
91For pseudo-devices, device nodes may be created and removed dynamically
92as required, depending on the nature of the device.
93.Pp
94Access restrictions to device nodes are usually subject to the regular
95file permissions of the device node entry, instead of being enforced
96directly by the drivers in the kernel.
97But since device nodes are not stored persistently between reboots,
98those file permissions are set at boot time from rules specified in
99.Xr devfs.conf 5 ,
100or dynamically according to rules defined in
101.Xr devfs.rules 5
102or set using the
103.Xr devfs 8
104command.
105In the latter case, different rules may be used to make different sets
106of devices visible within different instances of the
107.Xr devfs 5
108filesystem, which may be used, for example, to prevent jailed
109subsystems from accessing unsafe devices.
110Manual changes to device
111node permissions may still be made, but will not persist.
112.Ss Drivers without device nodes
113Drivers for network devices do not use device nodes in order to be
114accessed.
115Their selection is based on other decisions inside the
116kernel, and instead of calling
117.Xr open 2 ,
118use of a network device is generally introduced by using the system
119call
120.Xr socket 2 .
121.Ss Configuring a driver into the kernel
122For each kernel, there is a configuration file that is used as a base
123to select the facilities and drivers for that kernel, and to tune
124several options.
125See
126.Xr config 8
127for a detailed description of the files involved.
128The individual manual pages in this section provide a sample line for the
129configuration file in their synopsis portions.
130See also the files
131.Pa /usr/src/sys/conf/NOTES
132and
133.Pa /usr/src/sys/${ARCH}/conf/NOTES .
134.Pp
135Drivers need not be statically compiled into the kernel; they may also be
136loaded as modules, in which case any device nodes they provide will appear
137only after the module is loaded (and has attached to suitable hardware,
138if applicable).
139.Ss Historical Notes
140Prior to
141.Fx 6.0 ,
142device nodes could be created in the traditional way as persistent
143entries in the file system.
144While such entries can still be created, they no longer function to
145access devices.
146.Pp
147Prior to
148.Fx 5.0 ,
149devices for disk and tape drives existed in two variants, known as
150.Em block
151and
152.Em character
153devices, or to use better terms, buffered and unbuffered
154(raw)
155devices.
156The traditional names are reflected by the letters
157.Dq Li b
158and
159.Dq Li c
160as the file type identification in the output of
161.Dq Li ls -l .
162Raw devices were traditionally named with a prefix of
163.Dq Li r ,
164for example
165.Pa /dev/rda0
166would denote the raw version of the disk whose buffered device was
167.Pa /dev/da0 .
168.Em This is no longer the case ;
169all disk devices are now
170.Dq raw
171in the traditional sense, even though they are not given
172.Dq Li r
173prefixes, and
174.Dq buffered
175devices no longer exist at all.
176.Pp
177Buffered devices were accessed through a buffer cache maintained by
178the operating system; historically this was the system's primary disk
179cache, but in
180.Fx
181this was rendered obsolete by the introduction of unified virtual
182memory management.
183Buffered devices could be read or written at any
184byte position, with the buffer mechanism handling the reading and
185writing of disk blocks.
186In contrast, raw disk devices can be read or
187written only at positions and lengths that are multiples of the
188underlying device block size, and
189.Xr write 2
190calls are
191.Em synchronous ,
192not returning to the caller until the data has been handed off to the
193device.
194.Sh SEE ALSO
195.Xr close 2 ,
196.Xr ioctl 2 ,
197.Xr mmap 2 ,
198.Xr open 2 ,
199.Xr read 2 ,
200.Xr select 2 ,
201.Xr socket 2 ,
202.Xr write 2 ,
203.Xr devfs 5 ,
204.Xr hier 7 ,
205.Xr config 8
206.Sh HISTORY
207This manual page first appeared in
208.Fx 2.1 .
209.Sh AUTHORS
210.An -nosplit
211This man page has been rewritten by
212.An Andrew Gierth
213from an earlier version written by
214.An J\(:org Wunsch
215with initial input by
216.An David E. O'Brien .
217