/* $NetBSD: octeon_rnm.c,v 1.15.4.1 2023/07/30 11:39:33 martin Exp $ */ /* * Copyright (c) 2007 Internet Initiative Japan, Inc. * 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, this list of conditions and the following disclaimer. * 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. * * THIS SOFTWARE IS PROVIDED BY THE REGENTS AND CONTRIBUTORS ``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 REGENTS OR CONTRIBUTORS 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. */ /* * Cavium Octeon Random Number Generator / Random Number Memory `RNM' * * The RNM unit consists of: * * 1. 128 ring oscillators * 2. an LFSR/SHA-1 conditioner * 3. a 512-byte FIFO * * When the unit is enabled, there are three modes of operation: * * (a) deterministic: the ring oscillators are disabled and the * LFSR/SHA-1 conditioner operates on fixed inputs to give * reproducible results for testing, * * (b) conditioned entropy: the ring oscillators are enabled and * samples from them are fed through the LFSR/SHA-1 * conditioner before being put into the FIFO, and * * (c) raw entropy: the ring oscillators are enabled, and a group * of eight of them selected at any one time is sampled and * fed into the FIFO. * * Details: * * - The FIFO is refilled whenever we read out of it, either with * a load address or an IOBDMA operation. * * - The conditioner takes 81 cycles to produce a 64-bit block of * output in the FIFO whether in deterministic or conditioned * entropy mode, each block consisting of the first 64 bits of a * SHA-1 hash. * * - A group of eight ring oscillators take 8 cycles to produce a * 64-bit block of output in the FIFO in raw entropy mode, each * block consisting of eight consecutive samples from each RO in * parallel. * * The first sample of each RO always seems to be zero. Further, * consecutive samples from a single ring oscillator are not * independent, so naive debiasing like a von Neumann extractor * falls flat on its face. And parallel ring oscillators powered * by the same source may not be independent either, if they end * up locked. * * We read out one FIFO's worth of raw samples from groups of 8 * ring oscillators at a time, of 128 total, by going through them * round robin. We take 32 consecutive samples from each ring * oscillator in a group of 8 in parallel before we count one bit * of entropy. To get 256 bits of entropy, we read 4Kbit of data * from each of two 8-RO groups. * * We could use the on-board LFSR/SHA-1 conditioner like the Linux * driver written by Cavium does, but it's not clear how many RO * samples go into the conditioner, and our entropy pool is a * perfectly good conditioner itself, so it seems there is little * advantage -- other than expedience -- to using the LFSR/SHA-1 * conditioner. All the manual says is that it samples 125 of the * 128 ROs. But the Cavium SHA-1 CPU instruction is advertised to * have a latency of 100 cycles, so it seems implausible that much * more than one sample from each RO could be squeezed in there. * * The hardware exposes only 64 bits of each SHA-1 hash, and the * Linux driver uses 32 bits of that -- which, if treated as full * entropy, would mean an assessment of 3.9 bits of RO samples to * get 1 bit of entropy, whereas we take 256 bits of RO samples to * get one bit of entropy, so this seems reasonably conservative. * * Reference: Cavium Networks OCTEON Plus CN50XX Hardware Reference * Manual, CN50XX-HM-0.99E PRELIMINARY, July 2008. */ #include __KERNEL_RCSID(0, "$NetBSD: octeon_rnm.c,v 1.15.4.1 2023/07/30 11:39:33 martin Exp $"); #include #include #include #include #include #include #include #include #include #include #include #include //#define OCTRNM_DEBUG #define ENT_DELAY_CLOCK 8 /* cycles for each 64-bit RO sample batch */ #define LFSR_DELAY_CLOCK 81 /* cycles to fill LFSR buffer */ #define SHA1_DELAY_CLOCK 81 /* cycles to compute SHA-1 output */ #define NROGROUPS 16 #define RNG_FIFO_WORDS (512/sizeof(uint64_t)) struct octrnm_softc { uint64_t sc_sample[RNG_FIFO_WORDS]; bus_space_tag_t sc_bust; bus_space_handle_t sc_regh; krndsource_t sc_rndsrc; /* /dev/random source */ unsigned sc_rogroup; }; static int octrnm_match(device_t, struct cfdata *, void *); static void octrnm_attach(device_t, device_t, void *); static void octrnm_rng(size_t, void *); static void octrnm_reset(struct octrnm_softc *); static void octrnm_conditioned_deterministic(struct octrnm_softc *); static void octrnm_conditioned_entropy(struct octrnm_softc *); static void octrnm_raw_entropy(struct octrnm_softc *, unsigned); static uint64_t octrnm_load(struct octrnm_softc *); static void octrnm_iobdma(struct octrnm_softc *, uint64_t *, unsigned); static void octrnm_delay(uint32_t); CFATTACH_DECL_NEW(octrnm, sizeof(struct octrnm_softc), octrnm_match, octrnm_attach, NULL, NULL); static int octrnm_match(device_t parent, struct cfdata *cf, void *aux) { struct iobus_attach_args *aa = aux; if (strcmp(cf->cf_name, aa->aa_name) != 0) return 0; if (cf->cf_unit != aa->aa_unitno) return 0; return 1; } static void octrnm_attach(device_t parent, device_t self, void *aux) { struct octrnm_softc *sc = device_private(self); struct iobus_attach_args *aa = aux; uint64_t bist_status, sample, expected = UINT64_C(0xd654ff35fadf866b); aprint_normal("\n"); /* Map the device registers, all two of them. */ sc->sc_bust = aa->aa_bust; if (bus_space_map(aa->aa_bust, aa->aa_unit->addr, RNM_SIZE, 0, &sc->sc_regh) != 0) { aprint_error_dev(self, "unable to map device\n"); return; } /* Verify that the built-in self-test succeeded. */ bist_status = bus_space_read_8(sc->sc_bust, sc->sc_regh, RNM_BIST_STATUS_OFFSET); if (bist_status) { aprint_error_dev(self, "RNG built in self test failed: %#lx\n", bist_status); return; } /* * Reset the core, enable the RNG engine without entropy, wait * 81 cycles for it to produce a single sample, and draw the * deterministic sample to test. * * XXX Verify that the output matches the SHA-1 computation * described by the data sheet, not just a known answer. */ octrnm_reset(sc); octrnm_conditioned_deterministic(sc); octrnm_delay(LFSR_DELAY_CLOCK + SHA1_DELAY_CLOCK); sample = octrnm_load(sc); if (sample != expected) aprint_error_dev(self, "self-test: read %016"PRIx64"," " expected %016"PRIx64, sample, expected); /* * Reset the core again to clear the FIFO, and enable the RNG * engine with entropy exposed directly. Start from the first * group of ring oscillators; as we gather samples we will * rotate through the rest of them. */ octrnm_reset(sc); sc->sc_rogroup = 0; octrnm_raw_entropy(sc, sc->sc_rogroup); octrnm_delay(ENT_DELAY_CLOCK*RNG_FIFO_WORDS); /* Attach the rndsource. */ rndsource_setcb(&sc->sc_rndsrc, octrnm_rng, sc); rnd_attach_source(&sc->sc_rndsrc, device_xname(self), RND_TYPE_RNG, RND_FLAG_DEFAULT | RND_FLAG_HASCB); } static void octrnm_rng(size_t nbytes, void *vsc) { const unsigned BPB = 256; /* bits of data per bit of entropy */ struct octrnm_softc *sc = vsc; uint64_t *samplepos; size_t needed = NBBY*nbytes; unsigned i; /* Sample the ring oscillators round-robin. */ while (needed) { /* * Switch to the next RO group once we drain the FIFO. * By the time rnd_add_data is done, we will have * processed all 512 bytes of the FIFO. We assume it * takes at least one cycle per byte (realistically, * more like ~80cpb to draw from the FIFO and then * process it with rnd_add_data), so there is no need * for any other delays. */ sc->sc_rogroup++; sc->sc_rogroup %= NROGROUPS; octrnm_raw_entropy(sc, sc->sc_rogroup); /* * Gather quarter the FIFO at a time -- we are limited * to 128 bytes because of limits on the CVMSEG buffer. */ CTASSERT(sizeof sc->sc_sample == 512); CTASSERT(__arraycount(sc->sc_sample) == RNG_FIFO_WORDS); for (samplepos = sc->sc_sample, i = 0; i < 4; i++) { octrnm_iobdma(sc, samplepos, RNG_FIFO_WORDS / 4); samplepos += RNG_FIFO_WORDS / 4; } #ifdef OCTRNM_DEBUG hexdump(printf, "rnm", sc->sc_sample, sizeof sc->sc_sample); #endif rnd_add_data_sync(&sc->sc_rndsrc, sc->sc_sample, sizeof sc->sc_sample, NBBY*sizeof(sc->sc_sample)/BPB); needed -= MIN(needed, MAX(1, NBBY*sizeof(sc->sc_sample)/BPB)); /* Now's a good time to yield. */ preempt_point(); } /* Zero the sample. */ explicit_memset(sc->sc_sample, 0, sizeof sc->sc_sample); } /* * octrnm_reset(sc) * * Reset the RNM unit, disabling it and clearing the FIFO. */ static void octrnm_reset(struct octrnm_softc *sc) { bus_space_write_8(sc->sc_bust, sc->sc_regh, RNM_CTL_STATUS_OFFSET, RNM_CTL_STATUS_RNG_RST|RNM_CTL_STATUS_RNM_RST); } /* * octrnm_conditioned_deterministic(sc) * * Switch the RNM unit into the deterministic LFSR/SHA-1 mode with * no entropy, for the next data loaded into the FIFO. */ static void octrnm_conditioned_deterministic(struct octrnm_softc *sc) { bus_space_write_8(sc->sc_bust, sc->sc_regh, RNM_CTL_STATUS_OFFSET, RNM_CTL_STATUS_RNG_EN); } /* * octrnm_conditioned_entropy(sc) * * Switch the RNM unit to generate ring oscillator samples * conditioned with an LFSR/SHA-1, for the next data loaded into * the FIFO. */ static void __unused octrnm_conditioned_entropy(struct octrnm_softc *sc) { bus_space_write_8(sc->sc_bust, sc->sc_regh, RNM_CTL_STATUS_OFFSET, RNM_CTL_STATUS_RNG_EN|RNM_CTL_STATUS_ENT_EN); } /* * octrnm_raw_entropy(sc, rogroup) * * Switch the RNM unit to generate raw ring oscillator samples * from the specified group of eight ring oscillator. */ static void octrnm_raw_entropy(struct octrnm_softc *sc, unsigned rogroup) { uint64_t ctl = 0; ctl |= RNM_CTL_STATUS_RNG_EN; /* enable FIFO */ ctl |= RNM_CTL_STATUS_ENT_EN; /* enable entropy source */ ctl |= RNM_CTL_STATUS_EXP_ENT; /* expose entropy without LFSR/SHA-1 */ ctl |= __SHIFTIN(rogroup, RNM_CTL_STATUS_ENT_SEL_MASK); bus_space_write_8(sc->sc_bust, sc->sc_regh, RNM_CTL_STATUS_OFFSET, ctl); } /* * octrnm_load(sc) * * Load a single 64-bit word out of the FIFO. */ static uint64_t octrnm_load(struct octrnm_softc *sc) { uint64_t addr = OCTEON_ADDR_IO_DID(RNM_MAJOR_DID, RNM_SUB_DID); return octeon_xkphys_read_8(addr); } /* * octrnm_iobdma(sc, buf, nwords) * * Load nwords, at most 32, out of the FIFO into buf. */ static void octrnm_iobdma(struct octrnm_softc *sc, uint64_t *buf, unsigned nwords) { /* ``scraddr'' part is index in 64-bit words, not address */ size_t scraddr = OCTEON_CVMSEG_OFFSET(csm_rnm); uint64_t iobdma = IOBDMA_CREATE(RNM_MAJOR_DID, RNM_SUB_DID, scraddr / sizeof(uint64_t), nwords, 0); KASSERT(nwords < 128); /* iobdma address restriction */ KASSERT(nwords <= CVMSEG_LM_RNM_SIZE); /* size of CVMSEG LM buffer */ octeon_iobdma_write_8(iobdma); OCTEON_SYNCIOBDMA; for (; nwords --> 0; scraddr += 8) *buf++ = octeon_cvmseg_read_8(scraddr); } /* * octrnm_delay(ncycles) * * Wait ncycles, at most UINT32_MAX/2 so we behave reasonably even * if the cycle counter rolls over. */ static void octrnm_delay(uint32_t ncycles) { uint32_t deadline = mips3_cp0_count_read() + ncycles; KASSERT(ncycles <= UINT32_MAX/2); while ((deadline - mips3_cp0_count_read()) < ncycles) continue; }