| blob | 54ca8b23cde3f1aa5550d2806087300227531070 |
1 /*
2 * random.c -- A strong random number generator
3 *
4 * Copyright Matt Mackall <mpm@selenic.com>, 2003, 2004, 2005
5 *
6 * Copyright Theodore Ts'o, 1994, 1995, 1996, 1997, 1998, 1999. All
7 * rights reserved.
8 *
9 * Redistribution and use in source and binary forms, with or without
10 * modification, are permitted provided that the following conditions
11 * are met:
12 * 1. Redistributions of source code must retain the above copyright
13 * notice, and the entire permission notice in its entirety,
14 * including the disclaimer of warranties.
15 * 2. Redistributions in binary form must reproduce the above copyright
16 * notice, this list of conditions and the following disclaimer in the
17 * documentation and/or other materials provided with the distribution.
18 * 3. The name of the author may not be used to endorse or promote
19 * products derived from this software without specific prior
20 * written permission.
21 *
22 * ALTERNATIVELY, this product may be distributed under the terms of
23 * the GNU General Public License, in which case the provisions of the GPL are
24 * required INSTEAD OF the above restrictions. (This clause is
25 * necessary due to a potential bad interaction between the GPL and
26 * the restrictions contained in a BSD-style copyright.)
27 *
28 * THIS SOFTWARE IS PROVIDED ``AS IS'' AND ANY EXPRESS OR IMPLIED
29 * WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES
30 * OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE, ALL OF
31 * WHICH ARE HEREBY DISCLAIMED. IN NO EVENT SHALL THE AUTHOR BE
32 * LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR
33 * CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT
34 * OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR
35 * BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF
36 * LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
37 * (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE
38 * USE OF THIS SOFTWARE, EVEN IF NOT ADVISED OF THE POSSIBILITY OF SUCH
39 * DAMAGE.
40 */
42 /*
43 * (now, with legal B.S. out of the way.....)
44 *
45 * This routine gathers environmental noise from device drivers, etc.,
46 * and returns good random numbers, suitable for cryptographic use.
47 * Besides the obvious cryptographic uses, these numbers are also good
48 * for seeding TCP sequence numbers, and other places where it is
49 * desirable to have numbers which are not only random, but hard to
50 * predict by an attacker.
51 *
52 * Theory of operation
53 * ===================
54 *
55 * Computers are very predictable devices. Hence it is extremely hard
56 * to produce truly random numbers on a computer --- as opposed to
57 * pseudo-random numbers, which can easily generated by using a
58 * algorithm. Unfortunately, it is very easy for attackers to guess
59 * the sequence of pseudo-random number generators, and for some
60 * applications this is not acceptable. So instead, we must try to
61 * gather "environmental noise" from the computer's environment, which
62 * must be hard for outside attackers to observe, and use that to
63 * generate random numbers. In a Unix environment, this is best done
64 * from inside the kernel.
65 *
66 * Sources of randomness from the environment include inter-keyboard
67 * timings, inter-interrupt timings from some interrupts, and other
68 * events which are both (a) non-deterministic and (b) hard for an
69 * outside observer to measure. Randomness from these sources are
70 * added to an "entropy pool", which is mixed using a CRC-like function.
71 * This is not cryptographically strong, but it is adequate assuming
72 * the randomness is not chosen maliciously, and it is fast enough that
73 * the overhead of doing it on every interrupt is very reasonable.
74 * As random bytes are mixed into the entropy pool, the routines keep
75 * an *estimate* of how many bits of randomness have been stored into
76 * the random number generator's internal state.
77 *
78 * When random bytes are desired, they are obtained by taking the SHA
79 * hash of the contents of the "entropy pool". The SHA hash avoids
80 * exposing the internal state of the entropy pool. It is believed to
81 * be computationally infeasible to derive any useful information
82 * about the input of SHA from its output. Even if it is possible to
83 * analyze SHA in some clever way, as long as the amount of data
84 * returned from the generator is less than the inherent entropy in
85 * the pool, the output data is totally unpredictable. For this
86 * reason, the routine decreases its internal estimate of how many
87 * bits of "true randomness" are contained in the entropy pool as it
88 * outputs random numbers.
89 *
90 * If this estimate goes to zero, the routine can still generate
91 * random numbers; however, an attacker may (at least in theory) be
92 * able to infer the future output of the generator from prior
93 * outputs. This requires successful cryptanalysis of SHA, which is
94 * not believed to be feasible, but there is a remote possibility.
95 * Nonetheless, these numbers should be useful for the vast majority
96 * of purposes.
97 *
98 * Exported interfaces ---- output
99 * ===============================
100 *
101 * There are three exported interfaces; the first is one designed to
102 * be used from within the kernel:
103 *
104 * void get_random_bytes(void *buf, int nbytes);
105 *
106 * This interface will return the requested number of random bytes,
107 * and place it in the requested buffer.
108 *
109 * The two other interfaces are two character devices /dev/random and
110 * /dev/urandom. /dev/random is suitable for use when very high
111 * quality randomness is desired (for example, for key generation or
112 * one-time pads), as it will only return a maximum of the number of
113 * bits of randomness (as estimated by the random number generator)
114 * contained in the entropy pool.
115 *
116 * The /dev/urandom device does not have this limit, and will return
117 * as many bytes as are requested. As more and more random bytes are
118 * requested without giving time for the entropy pool to recharge,
119 * this will result in random numbers that are merely cryptographically
120 * strong. For many applications, however, this is acceptable.
121 *
122 * Exported interfaces ---- input
123 * ==============================
124 *
125 * The current exported interfaces for gathering environmental noise
126 * from the devices are:
127 *
128 * void add_input_randomness(unsigned int type, unsigned int code,
129 * unsigned int value);
130 * void add_interrupt_randomness(int irq);
131 * void add_disk_randomness(struct gendisk *disk);
132 *
133 * add_input_randomness() uses the input layer interrupt timing, as well as
134 * the event type information from the hardware.
135 *
136 * add_interrupt_randomness() uses the inter-interrupt timing as random
137 * inputs to the entropy pool. Note that not all interrupts are good
138 * sources of randomness! For example, the timer interrupts is not a
139 * good choice, because the periodicity of the interrupts is too
140 * regular, and hence predictable to an attacker. Network Interface
141 * Controller interrupts are a better measure, since the timing of the
142 * NIC interrupts are more unpredictable.
143 *
144 * add_disk_randomness() uses what amounts to the seek time of block
145 * layer request events, on a per-disk_devt basis, as input to the
146 * entropy pool. Note that high-speed solid state drives with very low
147 * seek times do not make for good sources of entropy, as their seek
148 * times are usually fairly consistent.
149 *
150 * All of these routines try to estimate how many bits of randomness a
151 * particular randomness source. They do this by keeping track of the
152 * first and second order deltas of the event timings.
153 *
154 * Ensuring unpredictability at system startup
155 * ============================================
156 *
157 * When any operating system starts up, it will go through a sequence
158 * of actions that are fairly predictable by an adversary, especially
159 * if the start-up does not involve interaction with a human operator.
160 * This reduces the actual number of bits of unpredictability in the
161 * entropy pool below the value in entropy_count. In order to
162 * counteract this effect, it helps to carry information in the
163 * entropy pool across shut-downs and start-ups. To do this, put the
164 * following lines an appropriate script which is run during the boot
165 * sequence:
166 *
167 * echo "Initializing random number generator..."
168 * random_seed=/var/run/random-seed
169 * # Carry a random seed from start-up to start-up
170 * # Load and then save the whole entropy pool
171 * if [ -f $random_seed ]; then
172 * cat $random_seed >/dev/urandom
173 * else
174 * touch $random_seed
175 * fi
176 * chmod 600 $random_seed
177 * dd if=/dev/urandom of=$random_seed count=1 bs=512
178 *
179 * and the following lines in an appropriate script which is run as
180 * the system is shutdown:
181 *
182 * # Carry a random seed from shut-down to start-up
183 * # Save the whole entropy pool
184 * echo "Saving random seed..."
185 * random_seed=/var/run/random-seed
186 * touch $random_seed
187 * chmod 600 $random_seed
188 * dd if=/dev/urandom of=$random_seed count=1 bs=512
189 *
190 * For example, on most modern systems using the System V init
191 * scripts, such code fragments would be found in
192 * /etc/rc.d/init.d/random. On older Linux systems, the correct script
193 * location might be in /etc/rcb.d/rc.local or /etc/rc.d/rc.0.
194 *
195 * Effectively, these commands cause the contents of the entropy pool
196 * to be saved at shut-down time and reloaded into the entropy pool at
197 * start-up. (The 'dd' in the addition to the bootup script is to
198 * make sure that /etc/random-seed is different for every start-up,
199 * even if the system crashes without executing rc.0.) Even with
200 * complete knowledge of the start-up activities, predicting the state
201 * of the entropy pool requires knowledge of the previous history of
202 * the system.
203 *
204 * Configuring the /dev/random driver under Linux
205 * ==============================================
206 *
207 * The /dev/random driver under Linux uses minor numbers 8 and 9 of
208 * the /dev/mem major number (#1). So if your system does not have
209 * /dev/random and /dev/urandom created already, they can be created
210 * by using the commands:
211 *
212 * mknod /dev/random c 1 8
213 * mknod /dev/urandom c 1 9
214 *
215 * Acknowledgements:
216 * =================
217 *
218 * Ideas for constructing this random number generator were derived
219 * from Pretty Good Privacy's random number generator, and from private
220 * discussions with Phil Karn. Colin Plumb provided a faster random
221 * number generator, which speed up the mixing function of the entropy
222 * pool, taken from PGPfone. Dale Worley has also contributed many
223 * useful ideas and suggestions to improve this driver.
224 *
225 * Any flaws in the design are solely my responsibility, and should
226 * not be attributed to the Phil, Colin, or any of authors of PGP.
227 *
228 * Further background information on this topic may be obtained from
229 * RFC 1750, "Randomness Recommendations for Security", by Donald
230 * Eastlake, Steve Crocker, and Jeff Schiller.
231 */
233 #include <linux/utsname.h>
234 #include <linux/module.h>
235 #include <linux/kernel.h>
236 #include <linux/major.h>
237 #include <linux/string.h>
238 #include <linux/fcntl.h>
239 #include <linux/slab.h>
240 #include <linux/random.h>
241 #include <linux/poll.h>
242 #include <linux/init.h>
243 #include <linux/fs.h>
244 #include <linux/genhd.h>
245 #include <linux/interrupt.h>
246 #include <linux/mm.h>
247 #include <linux/spinlock.h>
248 #include <linux/percpu.h>
249 #include <linux/cryptohash.h>
250 #include <linux/fips.h>
252 #ifdef CONFIG_GENERIC_HARDIRQS
253 # include <linux/irq.h>
254 #endif
256 #include <asm/processor.h>
257 #include <asm/uaccess.h>
258 #include <asm/irq.h>
259 #include <asm/io.h>
261 /*
262 * Configuration information
263 */
264 #define INPUT_POOL_WORDS 128
265 #define OUTPUT_POOL_WORDS 32
266 #define SEC_XFER_SIZE 512
267 #define EXTRACT_SIZE 10
269 /*
270 * The minimum number of bits of entropy before we wake up a read on
271 * /dev/random. Should be enough to do a significant reseed.
272 */
275 /*
276 * If the entropy count falls under this number of bits, then we
277 * should wake up processes which are selecting or polling on write
278 * access to /dev/random.
279 */
282 /*
283 * When the input pool goes over trickle_thresh, start dropping most
284 * samples to avoid wasting CPU time and reduce lock contention.
285 */
291 /*
292 * A pool of size .poolwords is stirred with a primitive polynomial
293 * of degree .poolwords over GF(2). The taps for various sizes are
294 * defined below. They are chosen to be evenly spaced (minimum RMS
295 * distance from evenly spaced; the numbers in the comments are a
296 * scaled squared error sum) except for the last tap, which is 1 to
297 * get the twisting happening as fast as possible.
298 */
303 /* x^128 + x^103 + x^76 + x^51 +x^25 + x + 1 -- 105 */
305 /* x^32 + x^26 + x^20 + x^14 + x^7 + x + 1 -- 15 */
307 #if 0
308 /* x^2048 + x^1638 + x^1231 + x^819 + x^411 + x + 1 -- 115 */
311 /* x^1024 + x^817 + x^615 + x^412 + x^204 + x + 1 -- 290 */
314 /* x^1024 + x^819 + x^616 + x^410 + x^207 + x^2 + 1 -- 115 */
317 /* x^512 + x^411 + x^308 + x^208 + x^104 + x + 1 -- 225 */
320 /* x^512 + x^409 + x^307 + x^206 + x^102 + x^2 + 1 -- 95 */
322 /* x^512 + x^409 + x^309 + x^205 + x^103 + x^2 + 1 -- 95 */
325 /* x^256 + x^205 + x^155 + x^101 + x^52 + x + 1 -- 125 */
328 /* x^128 + x^103 + x^78 + x^51 + x^27 + x^2 + 1 -- 70 */
331 /* x^64 + x^52 + x^39 + x^26 + x^14 + x + 1 -- 15 */
333 #endif
334 };
336 #define POOLBITS poolwords*32
337 #define POOLBYTES poolwords*4
339 /*
340 * For the purposes of better mixing, we use the CRC-32 polynomial as
341 * well to make a twisted Generalized Feedback Shift Reigster
342 *
343 * (See M. Matsumoto & Y. Kurita, 1992. Twisted GFSR generators. ACM
344 * Transactions on Modeling and Computer Simulation 2(3):179-194.
345 * Also see M. Matsumoto & Y. Kurita, 1994. Twisted GFSR generators
346 * II. ACM Transactions on Mdeling and Computer Simulation 4:254-266)
347 *
348 * Thanks to Colin Plumb for suggesting this.
349 *
350 * We have not analyzed the resultant polynomial to prove it primitive;
351 * in fact it almost certainly isn't. Nonetheless, the irreducible factors
352 * of a random large-degree polynomial over GF(2) are more than large enough
353 * that periodicity is not a concern.
354 *
355 * The input hash is much less sensitive than the output hash. All
356 * that we want of it is that it be a good non-cryptographic hash;
357 * i.e. it not produce collisions when fed "random" data of the sort
358 * we expect to see. As long as the pool state differs for different
359 * inputs, we have preserved the input entropy and done a good job.
360 * The fact that an intelligent attacker can construct inputs that
361 * will produce controlled alterations to the pool's state is not
362 * important because we don't consider such inputs to contribute any
363 * randomness. The only property we need with respect to them is that
364 * the attacker can't increase his/her knowledge of the pool's state.
365 * Since all additions are reversible (knowing the final state and the
366 * input, you can reconstruct the initial state), if an attacker has
367 * any uncertainty about the initial state, he/she can only shuffle
368 * that uncertainty about, but never cause any collisions (which would
369 * decrease the uncertainty).
370 *
371 * The chosen system lets the state of the pool be (essentially) the input
372 * modulo the generator polymnomial. Now, for random primitive polynomials,
373 * this is a universal class of hash functions, meaning that the chance
374 * of a collision is limited by the attacker's knowledge of the generator
375 * polynomail, so if it is chosen at random, an attacker can never force
376 * a collision. Here, we use a fixed polynomial, but we *can* assume that
377 * ###--> it is unknown to the processes generating the input entropy. <-###
378 * Because of this important property, this is a good, collision-resistant
379 * hash; hash collisions will occur no more often than chance.
380 */
382 /*
383 * Static global variables
384 */
389 #if 0
392 #define DEBUG_ENT(fmt, arg...) do { \
393 if (debug) \
395 fmt,\
396 input_pool.entropy_count,\
397 blocking_pool.entropy_count,\
398 nonblocking_pool.entropy_count,\
399 ## arg); } while (0)
400 #else
401 #define DEBUG_ENT(fmt, arg...) do {} while (0)
402 #endif
404 /**********************************************************************
405 *
406 * OS independent entropy store. Here are the functions which handle
407 * storing entropy in an entropy pool.
408 *
409 **********************************************************************/
413 /* read-only data: */
420 /* read-write data: */
421 spinlock_t lock;
426 };
438 };
447 };
455 };
457 /*
458 * This function adds bytes into the entropy "pool". It does not
459 * update the entropy estimate. The caller should call
460 * credit_entropy_bits if this is appropriate.
461 *
462 * The pool is stirred with a primitive polynomial of the appropriate
463 * degree, and then twisted. We twist by three bits at a time because
464 * it's cheap to do so and helps slightly in the expected case where
465 * the entropy is concentrated in the low-order bits.
466 */
469 {
477 __u32 w;
480 /* Taps are constant, so we can load them without holding r->lock. */
491 /* mix one byte at a time to simplify size handling and churn faster */
496 /* XOR in the various taps */
504 /* Mix the result back in with a twist */
507 /*
508 * Normally, we add 7 bits of rotation to the pool.
509 * At the beginning of the pool, add an extra 7 bits
510 * rotation, so that successive passes spread the
511 * input bits across the pool evenly.
512 */
514 }
524 }
527 {
529 }
531 /*
532 * Credit (or debit) the entropy store with n bits of entropy
533 */
535 {
554 /* should we wake readers? */
558 }
560 }
562 /*********************************************************************
563 *
564 * Entropy input management
565 *
566 *********************************************************************/
568 /* There is one of these per entropy source */
570 cycles_t last_time;
573 };
575 #ifndef CONFIG_GENERIC_HARDIRQS
580 {
582 }
586 {
588 }
590 #else
593 {
599 }
603 {
609 }
610 #endif
614 /*
615 * This function adds entropy to the entropy "pool" by using timing
616 * delays. It uses the timer_rand_state structure to make an estimate
617 * of how many bits of entropy this call has added to the pool.
618 *
619 * The number "num" is also added to the pool - it should somehow describe
620 * the type of event which just happened. This is currently 0-255 for
621 * keyboard scan codes, and 256 upwards for interrupts.
622 *
623 */
625 {
634 /* if over the trickle threshold, use only 1 in 4096 samples */
641 /* Use arch random value, fall back to cycles */
648 /*
649 * Calculate number of bits of randomness we probably added.
650 * We take into account the first, second and third-order deltas
651 * in order to make our estimate.
652 */
675 /*
676 * delta is now minimum absolute delta.
677 * Round down by 1 bit on general principles,
678 * and limit entropy entimate to 12 bits.
679 */
682 }
683 out:
685 }
689 {
692 /* ignore autorepeat and the like */
700 }
704 {
714 }
716 #ifdef CONFIG_BLOCK
718 {
721 /* first major is 1, so we get >= 0x200 here */
726 }
727 #endif
729 /*********************************************************************
730 *
731 * Entropy extraction routines
732 *
733 *********************************************************************/
738 /*
739 * This utility inline function is responsible for transferring entropy
740 * from the primary pool to the secondary extraction pool. We make
741 * sure we pull enough for a 'catastrophic reseed'.
742 */
744 {
749 /* If we're limited, always leave two wakeup worth's BITS */
753 /* pull at least as many as BYTES as wakeup BITS */
755 /* but never more than the buffer size */
766 }
767 }
769 /*
770 * These functions extracts randomness from the "entropy pool", and
771 * returns it in a buffer.
772 *
773 * The min parameter specifies the minimum amount we can pull before
774 * failing to avoid races that defeat catastrophic reseeding while the
775 * reserved parameter indicates how much entropy we must leave in the
776 * pool after each pull to avoid starving other readers.
777 *
778 * Note: extract_entropy() assumes that .poolwords is a multiple of 16 words.
779 */
783 {
786 /* Hold lock while accounting */
793 /* Can we pull enough? */
797 /* If limited, never pull more than available */
803 else
809 }
810 }
818 }
821 {
826 /* Generate a hash across the pool, 16 words (512 bits) at a time */
831 /*
832 * We mix the hash back into the pool to prevent backtracking
833 * attacks (where the attacker knows the state of the pool
834 * plus the current outputs, and attempts to find previous
835 * ouputs), unless the hash function can be inverted. By
836 * mixing at least a SHA1 worth of hash data back, we make
837 * brute-forcing the feedback as hard as brute-forcing the
838 * hash.
839 */
842 /*
843 * To avoid duplicates, we atomically extract a portion of the
844 * pool while mixing, and hash one final time.
845 */
850 /*
851 * In case the hash function has some recognizable output
852 * pattern, we fold it in half. Thus, we always feed back
853 * twice as much data as we output.
854 */
860 }
864 {
881 }
887 }
889 /* Wipe data just returned from memory */
893 }
897 {
910 }
912 }
919 }
924 }
926 /* Wipe data just returned from memory */
930 }
932 /*
933 * This function is the exported kernel interface. It returns some
934 * number of good random numbers, suitable for seeding TCP sequence
935 * numbers, etc.
936 */
938 {
951 }
954 }
957 /*
958 * init_std_data - initialize pool with system data
959 *
960 * @r: pool to initialize
961 *
962 * This function clears the pool's entropy count and mixes some system
963 * data into the pool to prepare it for use. The pool is not cleared
964 * as that can only decrease the entropy in the pool.
965 */
967 {
969 ktime_t now;
982 }
984 }
987 {
992 }
996 {
1004 /*
1005 * If kzalloc returns null, we just won't use that entropy
1006 * source.
1007 */
1011 }
1013 #ifdef CONFIG_BLOCK
1015 {
1018 /*
1019 * If kzalloc returns null, we just won't use that entropy
1020 * source.
1021 */
1025 }
1026 #endif
1028 static ssize_t
1030 {
1052 }
1058 random_read_wakeup_thresh);
1065 }
1068 }
1073 }
1078 /* like a named pipe */
1079 }
1082 }
1084 static ssize_t
1086 {
1088 }
1090 static unsigned int
1092 {
1103 }
1105 static int
1107 {
1122 }
1125 }
1129 {
1140 }
1143 {
1150 /* inherently racy, no point locking */
1171 size);
1178 /* Clear the entropy pool counters. */
1185 }
1186 }
1189 {
1191 }
1200 };
1208 };
1210 /***************************************************************
1211 * Random UUID interface
1212 *
1213 * Used here for a Boot ID, but can be useful for other kernel
1214 * drivers.
1215 ***************************************************************/
1217 /*
1218 * Generate random UUID
1219 */
1221 {
1223 /* Set UUID version to 4 --- truly random generation */
1225 /* Set the UUID variant to DCE */
1227 }
1230 /********************************************************************
1231 *
1232 * Sysctl interface
1233 *
1234 ********************************************************************/
1236 #ifdef CONFIG_SYSCTL
1238 #include <linux/sysctl.h>
1245 /*
1246 * These functions is used to return both the bootid UUID, and random
1247 * UUID. The difference is in whether table->data is NULL; if it is,
1248 * then a new UUID is generated and returned to the user.
1249 *
1250 * If the user accesses this via the proc interface, it will be returned
1251 * as an ASCII string in the standard UUID format. If accesses via the
1252 * sysctl system call, it is returned as 16 bytes of binary data.
1253 */
1256 {
1257 ctl_table fake_table;
1264 }
1274 }
1277 ctl_table random_table[] = {
1278 {
1284 },
1285 {
1291 },
1292 {
1300 },
1301 {
1309 },
1310 {
1316 },
1317 {
1322 },
1323 { }
1324 };
1330 {
1333 }
1336 /*
1337 * Get a random word for internal kernel use only. Similar to urandom but
1338 * with the goal of minimal entropy pool depletion. As a result, the random
1339 * value is not cryptographically secure but for several uses the cost of
1340 * depleting entropy is too high
1341 */
1344 {
1359 }
1361 /*
1362 * randomize_range() returns a start address such that
1363 *
1364 * [...... <range> .....]
1365 * start end
1366 *
1367 * a <range> with size "len" starting at the return value is inside in the
1368 * area defined by [start, end], but is otherwise randomized.
1369 */
1370 unsigned long
1372 {
1378 }