xref: /freebsd/share/man/man4/random.4 (revision 3c4ba5f55438f7afd4f4b0b56f88f2bb505fd6a6)
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24.\" $FreeBSD$
25.\"
26.Dd April 19, 2019
27.Dt RANDOM 4
28.Os
29.Sh NAME
30.Nm random
31.Nd the entropy device
32.Sh SYNOPSIS
33.Cd "options RANDOM_LOADABLE"
34.Cd "options RANDOM_ENABLE_ETHER"
35.Cd "options RANDOM_ENABLE_UMA"
36.Sh DESCRIPTION
37The
38.Nm
39device returns an endless supply of random bytes when read.
40.Pp
41The generator will start in an
42.Em unseeded
43state, and will block reads until it is seeded for the first time.
44.Pp
45To provide prompt access to the random device at boot time,
46.Fx
47automatically saves some entropy data in
48.Pa /boot/entropy
49for the
50.Xr loader 8
51to provide to the kernel.
52Additional entropy is regularly saved in
53.Pa /var/db/entropy .
54This saved entropy is sufficient to unblock the random device on devices with
55writeable media.
56.Pp
57Embedded applications without writable media must determine their own scheme
58for re-seeding the random device on boot, or accept that the device
59will remain unseeded and block reads indefinitely.
60See
61.Sx SECURITY CONSIDERATIONS
62for more detail.
63.Pp
64In addition to
65.Xr read 2 ,
66the direct output of the abstract kernel entropy device can be read with
67.Xr getrandom 2 ,
68.Xr getentropy 3 ,
69or the
70.Xr sysctl 8
71pseudo-variable
72.Va kern.arandom .
73.Pp
74To see the current settings of the software
75.Nm
76device, use the command line:
77.Pp
78.Dl "sysctl kern.random"
79.Pp
80which results in something like:
81.Bd -literal -offset indent
82kern.random.block_seeded_status: 0
83kern.random.fortuna.minpoolsize: 64
84kern.random.harvest.mask_symbolic: ENABLEDSOURCE,[DISABLEDSOURCE],...,CACHED
85kern.random.harvest.mask_bin: 00000010000000111011111
86kern.random.harvest.mask: 66015
87kern.random.use_chacha20_cipher: 0
88kern.random.random_sources: 'Intel Secure Key RNG'
89kern.random.initial_seeding.bypass_before_seeding: 1
90kern.random.initial_seeding.read_random_bypassed_before_seeding: 0
91kern.random.initial_seeding.arc4random_bypassed_before_seeding: 0
92kern.random.initial_seeding.disable_bypass_warnings: 0
93.Ed
94.Pp
95Other than
96.Va kern.random.block_seeded_status ,
97.Va kern.random.fortuna.minpoolsize ,
98and
99.Va kern.random.harvest.mask ,
100all settings are read-only via
101.Xr sysctl 8 .
102.Pp
103The
104.Pa kern.random.fortuna.minpoolsize
105sysctl is used
106to set the seed threshold.
107A smaller number gives a faster seed,
108but a less secure one.
109In practice,
110values between 64 and 256
111are acceptable.
112.Pp
113The
114.Va kern.random.harvest.mask
115bitmask is used to select
116the possible entropy sources.
117A 0 (zero) value means
118the corresponding source
119is not considered
120as an entropy source.
121Set the bit to 1 (one)
122if you wish to use
123that source.
124The
125.Va kern.random.harvest.mask_bin
126and
127.Va kern.random.harvest.mask_symbolic
128sysctls
129can be used to confirm
130settings in a human readable form.
131Disabled items
132in the latter
133are listed in square brackets.
134See
135.Xr random_harvest 9
136for more on the harvesting of entropy.
137.Sh FILES
138.Bl -tag -width ".Pa /dev/urandom"
139.It Pa /dev/random
140.It Pa /dev/urandom
141.El
142.Sh DIAGNOSTICS
143The following tunables are related to initial seeding of the
144.Nm
145device:
146.Bl -tag -width 4
147.It Va kern.random.initial_seeding.bypass_before_seeding
148Defaults to 1 (on).
149When set, the system will bypass the
150.Nm
151device prior to initial seeding.
152On is
153.Em unsafe ,
154but provides availability on many systems that lack early sources
155of entropy, or cannot load
156.Pa /boot/entropy
157sufficiently early in boot for
158.Nm
159consumers.
160When unset (0), the system will block
161.Xr read_random 9
162and
163.Xr arc4random 9
164requests if and until the
165.Nm
166device is initially seeded.
167.It Va kern.random.initial_seeding.disable_bypass_warnings
168Defaults to 0 (off).
169When set non-zero, disables warnings in dmesg when the
170.Nm
171device is bypassed.
172.El
173.Pp
174The following read-only
175.Xr sysctl 8
176variables allow programmatic diagnostic of whether
177.Nm
178device bypass occurred during boot.
179If they are set (non-zero), the specific functional unit bypassed the strong
180.Nm
181device output and either produced no output
182.Xr ( read_random 9 )
183or seeded itself with minimal, non-cryptographic entropy
184.Xr ( arc4random 9 ) .
185.Bl -bullet
186.It
187.Va kern.random.initial_seeding.read_random_bypassed_before_seeding
188.It
189.Va kern.random.initial_seeding.arc4random_bypassed_before_seeding
190.El
191.Sh SEE ALSO
192.Xr getrandom 2 ,
193.Xr arc4random 3 ,
194.Xr getentropy 3 ,
195.Xr random 3 ,
196.Xr sysctl 8 ,
197.Xr random 9
198.Rs
199.%A Ferguson
200.%A Schneier
201.%A Kohno
202.%B Cryptography Engineering
203.%I Wiley
204.%O ISBN 978-0-470-47424-2
205.Re
206.Sh HISTORY
207A
208.Nm
209device appeared in
210.Fx 2.2 .
211The implementation was changed to the
212.Em Yarrow algorithm in
213.Fx 5.0 .
214In
215.Fx 11.0 ,
216the Fortuna algorithm was introduced as the default.
217In
218.Fx 12.0 ,
219Yarrow was removed entirely.
220.Sh AUTHORS
221.An -nosplit
222The current
223.Nm
224code was authored by
225.An Mark R V Murray ,
226with significant contributions from many people.
227.Pp
228The
229.Em Fortuna
230algorithm was designed by
231.An Niels Ferguson ,
232.An Bruce Schneier ,
233and
234.An Tadayoshi Kohno .
235.Sh CAVEATS
236When
237.Cd "options RANDOM_LOADABLE"
238is enabled,
239the
240.Pa /dev/random
241device is not created
242until an "algorithm module"
243is loaded.
244The only module built by default is
245.Em random_fortuna .
246Loadable random modules
247are less efficient
248than their compiled-in equivalents.
249This is because some functions
250must be locked against
251load and unload events,
252and also must be indirect calls
253to allow for removal.
254.Pp
255When
256.Cd "options RANDOM_ENABLE_UMA"
257is enabled,
258the
259.Pa /dev/random
260device will obtain entropy
261from the zone allocator.
262This is a very high rate source with significant performance impact.
263Therefore, it is disabled by default.
264.Pp
265When
266.Cd "options RANDOM_ENABLE_ETHER"
267is enabled, the
268.Nm
269device will obtain entropy from
270.Vt mbuf
271structures passing through the network stack.
272This source is both extremely expensive and a poor source of entropy, so it is
273disabled by default.
274.Sh SECURITY CONSIDERATIONS
275The initial seeding
276of random number generators
277is a bootstrapping problem
278that needs very careful attention.
279When writable media is available, the
280.Em Fortuna
281paper describes a robust system for rapidly reseeding the device.
282.Pp
283In some embedded cases, it may be difficult to find enough randomness to seed a
284random number generator until a system is fully operational.
285In these cases, is the responsibility of the system architect to ensure that
286blocking is acceptable, or that the random device is seeded.
287(This advice does not apply to typical consumer systems.)
288.Pp
289To emulate embedded systems, developers may set the
290.Va kern.random.block_seeded_status
291tunable to 1 to verify boot does not require early availability of the
292.Nm
293device.
294