/* $OpenBSD: rnd.c,v 1.221 2020/06/15 14:52:19 deraadt Exp $ */ /* * Copyright (c) 2011,2020 Theo de Raadt. * Copyright (c) 2008 Damien Miller. * Copyright (c) 1996, 1997, 2000-2002 Michael Shalayeff. * Copyright (c) 2013 Markus Friedl. * Copyright Theodore Ts'o, 1994, 1995, 1996, 1997, 1998, 1999. * All rights reserved. * * Redistribution and use in source and binary forms, with or without * modification, are permitted provided that the following conditions * are met: * 1. Redistributions of source code must retain the above copyright * notice, and the entire permission notice in its entirety, * including the disclaimer of warranties. * 2. Redistributions in binary form must reproduce the above copyright * notice, this list of conditions and the following disclaimer in the * documentation and/or other materials provided with the distribution. * 3. The name of the author may not be used to endorse or promote * products derived from this software without specific prior * written permission. * * ALTERNATIVELY, this product may be distributed under the terms of * the GNU Public License, in which case the provisions of the GPL are * required INSTEAD OF the above restrictions. (This clause is * necessary due to a potential bad interaction between the GPL and * the restrictions contained in a BSD-style copyright.) * * THIS SOFTWARE IS PROVIDED ``AS IS'' AND ANY EXPRESS OR IMPLIED * WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES * OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE * DISCLAIMED. IN NO EVENT SHALL THE AUTHOR BE LIABLE FOR ANY DIRECT, * INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES * (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR * SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) * HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, * STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) * ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED * OF THE POSSIBILITY OF SUCH DAMAGE. */ /* * The bootblocks pre-fill the kernel .openbsd.randomdata section with seed * material (on-disk from previous boot, hopefully mixed with a hardware rng). * The first arc4random(9) call initializes this seed material as a chacha * state. Calls can be done early in kernel bootstrap code -- early use is * encouraged. * * After the kernel timeout subsystem is initialized, random_start() prepares * the entropy collection mechanism enqueue_randomness() and timeout-driven * mixing into the chacha state. The first submissions come from device * probes, later on interrupt-time submissions are more common. Entropy * data (and timing information) get mixed over the entropy input ring * rnd_event_space[] -- the goal is to collect damage. * * Based upon timeouts, a selection of the entropy ring rnd_event_space[] * CRC bit-distributed and XOR mixed into entropy_pool[]. * * From time to time, entropy_pool[] is SHA512-whitened, mixed with time * information again, XOR'd with the inner and outer states of the existing * chacha state, to create a new chacha state. * * During early boot (until cold=0), enqueue operations are immediately * dequeued, and mixed into the chacha. */ #include #include #include #include #include #include #include #include #include #include #include #define KEYSTREAM_ONLY #include #include /* * For the purposes of better mixing, we use the CRC-32 polynomial as * well to make a twisted Generalized Feedback Shift Register * * (See M. Matsumoto & Y. Kurita, 1992. Twisted GFSR generators. ACM * Transactions on Modeling and Computer Simulation 2(3):179-194. * Also see M. Matsumoto & Y. Kurita, 1994. Twisted GFSR generators * II. ACM Transactions on Modeling and Computer Simulation 4:254-266) */ /* * Stirring polynomials over GF(2) for various pool sizes. Used in * add_entropy_words() below. * * The polynomial terms are chosen to be evenly spaced (minimum RMS * distance from evenly spaced; except for the last tap, which is 1 to * get the twisting happening as fast as possible. * * The resultant polynomial is: * 2^POOLWORDS + 2^POOL_TAP1 + 2^POOL_TAP2 + 2^POOL_TAP3 + 2^POOL_TAP4 + 1 */ #define POOLWORDS 2048 #define POOLBYTES (POOLWORDS*4) #define POOLMASK (POOLWORDS - 1) #define POOL_TAP1 1638 #define POOL_TAP2 1231 #define POOL_TAP3 819 #define POOL_TAP4 411 /* * Raw entropy collection from device drivers; at interrupt context or not. * enqueue_randomness() is used to submit data into the entropy input ring. */ #define QEVLEN 128 /* must be a power of 2 */ #define QEVCONSUME 8 /* how many events to consume a time */ #define KEYSZ 32 #define IVSZ 8 #define BLOCKSZ 64 #define RSBUFSZ (16*BLOCKSZ) #define EBUFSIZE KEYSZ + IVSZ struct rand_event { u_int re_time; u_int re_val; } rnd_event_space[QEVLEN]; u_int rnd_event_cons; u_int rnd_event_prod; int rnd_cold = 1; int rnd_slowextract = 1; void rnd_reinit(void *v); /* timeout to start reinit */ void rnd_init(void *); /* actually do the reinit */ static u_int32_t entropy_pool[POOLWORDS]; u_int32_t entropy_pool0[POOLWORDS] __attribute__((section(".openbsd.randomdata"))); void dequeue_randomness(void *); void add_entropy_words(const u_int32_t *, u_int); void extract_entropy(u_int8_t *) __attribute__((__bounded__(__minbytes__,1,EBUFSIZE))); struct timeout rnd_timeout = TIMEOUT_INITIALIZER(dequeue_randomness, NULL); int filt_randomread(struct knote *, long); void filt_randomdetach(struct knote *); int filt_randomwrite(struct knote *, long); static void _rs_seed(u_char *, size_t); static void _rs_clearseed(const void *p, size_t s); const struct filterops randomread_filtops = { .f_flags = FILTEROP_ISFD, .f_attach = NULL, .f_detach = filt_randomdetach, .f_event = filt_randomread, }; const struct filterops randomwrite_filtops = { .f_flags = FILTEROP_ISFD, .f_attach = NULL, .f_detach = filt_randomdetach, .f_event = filt_randomwrite, }; /* * This function mixes entropy and timing into the entropy input ring. */ void enqueue_randomness(u_int val) { struct rand_event *rep; int e; e = (atomic_inc_int_nv(&rnd_event_prod) - 1) & (QEVLEN-1); rep = &rnd_event_space[e]; rep->re_time += cpu_rnd_messybits(); rep->re_val += val; if (rnd_cold) { dequeue_randomness(NULL); rnd_init(NULL); if (!cold) rnd_cold = 0; } else if (!timeout_pending(&rnd_timeout) && (rnd_event_prod - rnd_event_cons) > QEVCONSUME) { rnd_slowextract = min(rnd_slowextract * 2, 5000); timeout_add_msec(&rnd_timeout, rnd_slowextract * 10); } } /* * This function merges entropy ring information into the buffer using * a polynomial to spread the bits. */ void add_entropy_words(const u_int32_t *buf, u_int n) { /* derived from IEEE 802.3 CRC-32 */ static const u_int32_t twist_table[8] = { 0x00000000, 0x3b6e20c8, 0x76dc4190, 0x4db26158, 0xedb88320, 0xd6d6a3e8, 0x9b64c2b0, 0xa00ae278 }; static u_int entropy_add_ptr; static u_char entropy_input_rotate; for (; n--; buf++) { u_int32_t w = (*buf << entropy_input_rotate) | (*buf >> ((32 - entropy_input_rotate) & 31)); u_int i = entropy_add_ptr = (entropy_add_ptr - 1) & POOLMASK; /* * Normally, we add 7 bits of rotation to the pool. * At the beginning of the pool, add an extra 7 bits * rotation, so that successive passes spread the * input bits across the pool evenly. */ entropy_input_rotate = (entropy_input_rotate + (i ? 7 : 14)) & 31; /* XOR pool contents corresponding to polynomial terms */ w ^= entropy_pool[(i + POOL_TAP1) & POOLMASK] ^ entropy_pool[(i + POOL_TAP2) & POOLMASK] ^ entropy_pool[(i + POOL_TAP3) & POOLMASK] ^ entropy_pool[(i + POOL_TAP4) & POOLMASK] ^ entropy_pool[(i + 1) & POOLMASK] ^ entropy_pool[i]; /* + 2^POOLWORDS */ entropy_pool[i] = (w >> 3) ^ twist_table[w & 7]; } } /* * Pulls entropy out of the queue and merges it into the poll with the * CRC. This takes a mix of fresh entries from the producer end of the * queue and entries from the consumer end of the queue which are * likely to have collected more damage. */ /* ARGSUSED */ void dequeue_randomness(void *v) { u_int32_t buf[2]; u_int startp, startc, i; if (!rnd_cold) timeout_del(&rnd_timeout); /* Some very new damage */ startp = rnd_event_prod - QEVCONSUME; for (i = 0; i < QEVCONSUME; i++) { u_int e = (startp + i) & (QEVLEN-1); buf[0] = rnd_event_space[e].re_time; buf[1] = rnd_event_space[e].re_val; add_entropy_words(buf, 2); } /* and some probably more damaged */ startc = rnd_event_cons; for (i = 0; i < QEVCONSUME; i++) { u_int e = (startc + i) & (QEVLEN-1); buf[0] = rnd_event_space[e].re_time; buf[1] = rnd_event_space[e].re_val; add_entropy_words(buf, 2); } rnd_event_cons = startp + QEVCONSUME; } /* * Grabs a chunk from the entropy_pool[] and slams it through SHA512 when * requested. */ void extract_entropy(u_int8_t *buf) { static u_int32_t extract_pool[POOLWORDS]; u_char digest[SHA512_DIGEST_LENGTH]; SHA2_CTX shactx; #if SHA512_DIGEST_LENGTH < EBUFSIZE #error "need more bigger hash output" #endif /* * INTENTIONALLY not protected by any lock. Races during * memcpy() result in acceptable input data; races during * SHA512Update() would create nasty data dependencies. We * do not rely on this as a benefit, but if it happens, cool. */ memcpy(extract_pool, entropy_pool, sizeof(extract_pool)); /* Hash the pool to get the output */ SHA512Init(&shactx); SHA512Update(&shactx, (u_int8_t *)extract_pool, sizeof(extract_pool)); SHA512Final(digest, &shactx); /* Copy data to destination buffer */ memcpy(buf, digest, EBUFSIZE); /* * Modify pool so next hash will produce different results. * During boot-time enqueue/dequeue stage, avoid recursion. */ if (!rnd_cold) enqueue_randomness(extract_pool[0]); dequeue_randomness(NULL); /* Wipe data from memory */ explicit_bzero(extract_pool, sizeof(extract_pool)); explicit_bzero(digest, sizeof(digest)); } /* random keystream by ChaCha */ struct mutex rndlock = MUTEX_INITIALIZER(IPL_HIGH); struct timeout rndreinit_timeout = TIMEOUT_INITIALIZER(rnd_reinit, NULL); struct task rnd_task = TASK_INITIALIZER(rnd_init, NULL); static chacha_ctx rs; /* chacha context for random keystream */ /* keystream blocks (also chacha seed from boot) */ static u_char rs_buf[RSBUFSZ]; u_char rs_buf0[RSBUFSZ] __attribute__((section(".openbsd.randomdata"))); static size_t rs_have; /* valid bytes at end of rs_buf */ static size_t rs_count; /* bytes till reseed */ void suspend_randomness(void) { struct timespec ts; getnanotime(&ts); enqueue_randomness(ts.tv_sec); enqueue_randomness(ts.tv_nsec); dequeue_randomness(NULL); rs_count = 0; arc4random_buf(entropy_pool, sizeof(entropy_pool)); } void resume_randomness(char *buf, size_t buflen) { struct timespec ts; if (buf && buflen) _rs_seed(buf, buflen); getnanotime(&ts); enqueue_randomness(ts.tv_sec); enqueue_randomness(ts.tv_nsec); dequeue_randomness(NULL); rs_count = 0; } static inline void _rs_rekey(u_char *dat, size_t datlen); static inline void _rs_init(u_char *buf, size_t n) { KASSERT(n >= KEYSZ + IVSZ); chacha_keysetup(&rs, buf, KEYSZ * 8); chacha_ivsetup(&rs, buf + KEYSZ, NULL); } static void _rs_seed(u_char *buf, size_t n) { _rs_rekey(buf, n); /* invalidate rs_buf */ rs_have = 0; memset(rs_buf, 0, sizeof(rs_buf)); rs_count = 1600000; } static void _rs_stir(int do_lock) { struct timespec ts; u_int8_t buf[EBUFSIZE], *p; int i; /* * Use SHA512 PRNG data and a system timespec; early in the boot * process this is the best we can do -- some architectures do * not collect entropy very well during this time, but may have * clock information which is better than nothing. */ extract_entropy(buf); nanotime(&ts); for (p = (u_int8_t *)&ts, i = 0; i < sizeof(ts); i++) buf[i] ^= p[i]; if (do_lock) mtx_enter(&rndlock); _rs_seed(buf, sizeof(buf)); if (do_lock) mtx_leave(&rndlock); explicit_bzero(buf, sizeof(buf)); /* encourage fast-dequeue again */ rnd_slowextract = 1; } static inline void _rs_stir_if_needed(size_t len) { static int rs_initialized; if (!rs_initialized) { memcpy(entropy_pool, entropy_pool0, sizeof(entropy_pool)); memcpy(rs_buf, rs_buf0, sizeof(rs_buf)); /* seeds cannot be cleaned yet, random_start() will do so */ _rs_init(rs_buf, KEYSZ + IVSZ); rs_count = 1024 * 1024 * 1024; /* until main() runs */ rs_initialized = 1; } else if (rs_count <= len) _rs_stir(0); else rs_count -= len; } static void _rs_clearseed(const void *p, size_t s) { struct kmem_dyn_mode kd_avoidalias; vaddr_t va = trunc_page((vaddr_t)p); vsize_t off = (vaddr_t)p - va; vsize_t len; vaddr_t rwva; paddr_t pa; while (s > 0) { pmap_extract(pmap_kernel(), va, &pa); memset(&kd_avoidalias, 0, sizeof(kd_avoidalias)); kd_avoidalias.kd_prefer = pa; kd_avoidalias.kd_waitok = 1; rwva = (vaddr_t)km_alloc(PAGE_SIZE, &kv_any, &kp_none, &kd_avoidalias); if (!rwva) panic("_rs_clearseed"); pmap_kenter_pa(rwva, pa, PROT_READ | PROT_WRITE); pmap_update(pmap_kernel()); len = MIN(s, PAGE_SIZE - off); explicit_bzero((void *)(rwva + off), len); pmap_kremove(rwva, PAGE_SIZE); km_free((void *)rwva, PAGE_SIZE, &kv_any, &kp_none); va += PAGE_SIZE; s -= len; off = 0; } } static inline void _rs_rekey(u_char *dat, size_t datlen) { #ifndef KEYSTREAM_ONLY memset(rs_buf, 0, sizeof(rs_buf)); #endif /* fill rs_buf with the keystream */ chacha_encrypt_bytes(&rs, rs_buf, rs_buf, sizeof(rs_buf)); /* mix in optional user provided data */ if (dat) { size_t i, m; m = MIN(datlen, KEYSZ + IVSZ); for (i = 0; i < m; i++) rs_buf[i] ^= dat[i]; } /* immediately reinit for backtracking resistance */ _rs_init(rs_buf, KEYSZ + IVSZ); memset(rs_buf, 0, KEYSZ + IVSZ); rs_have = sizeof(rs_buf) - KEYSZ - IVSZ; } static inline void _rs_random_buf(void *_buf, size_t n) { u_char *buf = (u_char *)_buf; size_t m; _rs_stir_if_needed(n); while (n > 0) { if (rs_have > 0) { m = MIN(n, rs_have); memcpy(buf, rs_buf + sizeof(rs_buf) - rs_have, m); memset(rs_buf + sizeof(rs_buf) - rs_have, 0, m); buf += m; n -= m; rs_have -= m; } if (rs_have == 0) _rs_rekey(NULL, 0); } } static inline void _rs_random_u32(u_int32_t *val) { _rs_stir_if_needed(sizeof(*val)); if (rs_have < sizeof(*val)) _rs_rekey(NULL, 0); memcpy(val, rs_buf + sizeof(rs_buf) - rs_have, sizeof(*val)); memset(rs_buf + sizeof(rs_buf) - rs_have, 0, sizeof(*val)); rs_have -= sizeof(*val); } /* Return one word of randomness from a ChaCha20 generator */ u_int32_t arc4random(void) { u_int32_t ret; mtx_enter(&rndlock); _rs_random_u32(&ret); mtx_leave(&rndlock); return ret; } /* * Fill a buffer of arbitrary length with ChaCha20-derived randomness. */ void arc4random_buf(void *buf, size_t n) { mtx_enter(&rndlock); _rs_random_buf(buf, n); mtx_leave(&rndlock); } /* * Allocate a new ChaCha20 context for the caller to use. */ struct arc4random_ctx * arc4random_ctx_new() { char keybuf[KEYSZ + IVSZ]; chacha_ctx *ctx = malloc(sizeof(chacha_ctx), M_TEMP, M_WAITOK); arc4random_buf(keybuf, KEYSZ + IVSZ); chacha_keysetup(ctx, keybuf, KEYSZ * 8); chacha_ivsetup(ctx, keybuf + KEYSZ, NULL); explicit_bzero(keybuf, sizeof(keybuf)); return (struct arc4random_ctx *)ctx; } /* * Free a ChaCha20 context created by arc4random_ctx_new() */ void arc4random_ctx_free(struct arc4random_ctx *ctx) { explicit_bzero(ctx, sizeof(chacha_ctx)); free(ctx, M_TEMP, sizeof(chacha_ctx)); } /* * Use a given ChaCha20 context to fill a buffer */ void arc4random_ctx_buf(struct arc4random_ctx *ctx, void *buf, size_t n) { #ifndef KEYSTREAM_ONLY memset(buf, 0, n); #endif chacha_encrypt_bytes((chacha_ctx *)ctx, buf, buf, n); } /* * Calculate a uniformly distributed random number less than upper_bound * avoiding "modulo bias". * * Uniformity is achieved by generating new random numbers until the one * returned is outside the range [0, 2**32 % upper_bound). This * guarantees the selected random number will be inside * [2**32 % upper_bound, 2**32) which maps back to [0, upper_bound) * after reduction modulo upper_bound. */ u_int32_t arc4random_uniform(u_int32_t upper_bound) { u_int32_t r, min; if (upper_bound < 2) return 0; /* 2**32 % x == (2**32 - x) % x */ min = -upper_bound % upper_bound; /* * This could theoretically loop forever but each retry has * p > 0.5 (worst case, usually far better) of selecting a * number inside the range we need, so it should rarely need * to re-roll. */ for (;;) { r = arc4random(); if (r >= min) break; } return r % upper_bound; } /* ARGSUSED */ void rnd_init(void *null) { _rs_stir(1); } /* * Called by timeout to mark arc4 for stirring, */ void rnd_reinit(void *v) { task_add(systq, &rnd_task); /* 10 minutes, per dm@'s suggestion */ timeout_add_sec(&rndreinit_timeout, 10 * 60); } /* * Start periodic services inside the random subsystem, which pull * entropy forward, hash it, and re-seed the random stream as needed. */ void random_start(int goodseed) { extern char etext[]; #if !defined(NO_PROPOLICE) extern long __guard_local; if (__guard_local == 0) printf("warning: no entropy supplied by boot loader\n"); #endif _rs_clearseed(entropy_pool0, sizeof(entropy_pool0)); _rs_clearseed(rs_buf0, sizeof(rs_buf0)); /* Message buffer may contain data from previous boot */ if (msgbufp->msg_magic == MSG_MAGIC) add_entropy_words((u_int32_t *)msgbufp->msg_bufc, msgbufp->msg_bufs / sizeof(u_int32_t)); add_entropy_words((u_int32_t *)etext - 32*1024, 8192/sizeof(u_int32_t)); dequeue_randomness(NULL); rnd_init(NULL); rnd_reinit(NULL); if (goodseed) printf("random: good seed from bootblocks\n"); else { /* XXX kernel should work harder here */ printf("random: boothowto does not indicate good seed\n"); } } int randomopen(dev_t dev, int flag, int mode, struct proc *p) { return 0; } int randomclose(dev_t dev, int flag, int mode, struct proc *p) { return 0; } /* * Maximum number of bytes to serve directly from the main ChaCha * pool. Larger requests are served from a discrete ChaCha instance keyed * from the main pool. */ #define RND_MAIN_MAX_BYTES 2048 int randomread(dev_t dev, struct uio *uio, int ioflag) { struct arc4random_ctx *lctx = NULL; size_t total = uio->uio_resid; u_char *buf; int ret = 0; if (uio->uio_resid == 0) return 0; buf = malloc(POOLBYTES, M_TEMP, M_WAITOK); if (total > RND_MAIN_MAX_BYTES) lctx = arc4random_ctx_new(); while (ret == 0 && uio->uio_resid > 0) { size_t n = ulmin(POOLBYTES, uio->uio_resid); if (lctx != NULL) arc4random_ctx_buf(lctx, buf, n); else arc4random_buf(buf, n); ret = uiomove(buf, n, uio); if (ret == 0 && uio->uio_resid > 0) yield(); } if (lctx != NULL) arc4random_ctx_free(lctx); explicit_bzero(buf, POOLBYTES); free(buf, M_TEMP, POOLBYTES); return ret; } int randomwrite(dev_t dev, struct uio *uio, int flags) { int ret = 0, newdata = 0; u_int32_t *buf; if (uio->uio_resid == 0) return 0; buf = malloc(POOLBYTES, M_TEMP, M_WAITOK); while (ret == 0 && uio->uio_resid > 0) { size_t n = ulmin(POOLBYTES, uio->uio_resid); ret = uiomove(buf, n, uio); if (ret != 0) break; while (n % sizeof(u_int32_t)) ((u_int8_t *)buf)[n++] = 0; add_entropy_words(buf, n / 4); if (uio->uio_resid > 0) yield(); newdata = 1; } if (newdata) rnd_init(NULL); explicit_bzero(buf, POOLBYTES); free(buf, M_TEMP, POOLBYTES); return ret; } int randomkqfilter(dev_t dev, struct knote *kn) { switch (kn->kn_filter) { case EVFILT_READ: kn->kn_fop = &randomread_filtops; break; case EVFILT_WRITE: kn->kn_fop = &randomwrite_filtops; break; default: return (EINVAL); } return (0); } void filt_randomdetach(struct knote *kn) { } int filt_randomread(struct knote *kn, long hint) { kn->kn_data = RND_MAIN_MAX_BYTES; return (1); } int filt_randomwrite(struct knote *kn, long hint) { kn->kn_data = POOLBYTES; return (1); } int randomioctl(dev_t dev, u_long cmd, caddr_t data, int flag, struct proc *p) { switch (cmd) { case FIOASYNC: /* No async flag in softc so this is a no-op. */ break; case FIONBIO: /* Handled in the upper FS layer. */ break; default: return ENOTTY; } return 0; } int sys_getentropy(struct proc *p, void *v, register_t *retval) { struct sys_getentropy_args /* { syscallarg(void *) buf; syscallarg(size_t) nbyte; } */ *uap = v; char buf[256]; int error; if (SCARG(uap, nbyte) > sizeof(buf)) return (EIO); arc4random_buf(buf, SCARG(uap, nbyte)); if ((error = copyout(buf, SCARG(uap, buf), SCARG(uap, nbyte))) != 0) return (error); explicit_bzero(buf, sizeof(buf)); retval[0] = 0; return (0); }