From patchwork Mon Oct 19 19:30:02 2020 Content-Type: text/plain; charset="utf-8" MIME-Version: 1.0 Content-Transfer-Encoding: 8bit X-Patchwork-Submitter: Stephan Mueller X-Patchwork-Id: 11845073 X-Patchwork-Delegate: herbert@gondor.apana.org.au Return-Path: X-Spam-Checker-Version: SpamAssassin 3.4.0 (2014-02-07) on aws-us-west-2-korg-lkml-1.web.codeaurora.org X-Spam-Level: X-Spam-Status: No, score=-9.8 required=3.0 tests=BAYES_00,DKIM_SIGNED, DKIM_VALID,DKIM_VALID_AU,HEADER_FROM_DIFFERENT_DOMAINS,INCLUDES_PATCH, MAILING_LIST_MULTI,SIGNED_OFF_BY,SPF_HELO_NONE,SPF_PASS,URIBL_BLOCKED autolearn=unavailable autolearn_force=no version=3.4.0 Received: from mail.kernel.org (mail.kernel.org [198.145.29.99]) by smtp.lore.kernel.org (Postfix) with ESMTP id A5A0FC43457 for ; Mon, 19 Oct 2020 19:53:44 +0000 (UTC) Received: from vger.kernel.org (vger.kernel.org [23.128.96.18]) by mail.kernel.org (Postfix) with ESMTP id 07698222C2 for ; Mon, 19 Oct 2020 19:53:44 +0000 (UTC) Authentication-Results: mail.kernel.org; dkim=pass (2048-bit key) header.d=chronox.de header.i=@chronox.de header.b="mkkT8txJ" Received: (majordomo@vger.kernel.org) by vger.kernel.org via listexpand id S1731409AbgJSTxa (ORCPT ); Mon, 19 Oct 2020 15:53:30 -0400 Received: from mo4-p04-ob.smtp.rzone.de ([81.169.146.177]:24392 "EHLO mo4-p04-ob.smtp.rzone.de" rhost-flags-OK-OK-OK-OK) by vger.kernel.org with ESMTP id S1731511AbgJSTx2 (ORCPT ); Mon, 19 Oct 2020 15:53:28 -0400 DKIM-Signature: v=1; a=rsa-sha256; c=relaxed/relaxed; t=1603137184; s=strato-dkim-0002; d=chronox.de; h=References:In-Reply-To:Message-ID:Date:Subject:Cc:To:From: X-RZG-CLASS-ID:X-RZG-AUTH:From:Subject:Sender; bh=mqEiS7KsSuBd+cDJlxPXLw5iY+BsRCRa6sb3xjg2RNg=; b=mkkT8txJuc1XI692teGTI7eu6k4wQhZYc/6R+gVKk3fHI8n9Wgg8lH0zRlbzeIzgdz 5OsSHw+0UxBUlLin9Tfefy+zS6mJoEcrZ/Tzess+41BsWB7zWPHG75HYrPX2VazvGLiY G/+61UHxn2TapiglZGXGOytRWOBjZ2UR9+Lyj2WKhrm++dAAuejh07XsgV87pWyo8nCu Byz56Ch++PLf77ZkUaXrbFskae35VSHhT/+Eu1R3YhUuYvKvSpivsoCSXuPR8n7WXTOE tyb9+3L0MXzXoVeDwQAfvm1sZ0aUA3IywKXLCUqqsXVNPn680o54fj9i1onEWAdZ/m4I qPZQ== X-RZG-AUTH: ":P2ERcEykfu11Y98lp/T7+hdri+uKZK8TKWEqNyiHySGSa9k9xmwdNnzGHXPbJPSb3t0=" X-RZG-CLASS-ID: mo00 Received: from positron.chronox.de by smtp.strato.de (RZmta 47.2.1 DYNA|AUTH) with ESMTPSA id C0b627w9JJpvU6y (using TLSv1.3 with cipher TLS_AES_256_GCM_SHA384 (256 bits)) (Client did not present a certificate); Mon, 19 Oct 2020 21:51:57 +0200 (CEST) From: Stephan =?iso-8859-1?q?M=FCller?= To: Torsten Duwe Cc: Willy Tarreau , "Theodore Y. Ts'o" , linux-crypto@vger.kernel.org, Nicolai Stange , LKML , Arnd Bergmann , Greg Kroah-Hartman , "Eric W. Biederman" , "Alexander E. Patrakov" , "Ahmed S. Darwish" , Matthew Garrett , Vito Caputo , Andreas Dilger , Jan Kara , Ray Strode , William Jon McCann , zhangjs , Andy Lutomirski , Florian Weimer , Lennart Poettering , Peter Matthias , Marcelo Henrique Cerri , Neil Horman , Randy Dunlap , Julia Lawall , Dan Carpenter , Andy Lavr , Eric Biggers , "Jason A. Donenfeld" , Petr Tesarik Subject: [PATCH v36 01/13] Linux Random Number Generator Date: Mon, 19 Oct 2020 21:30:02 +0200 Message-ID: <7822885.T7Z3S40VBb@positron.chronox.de> In-Reply-To: <3073852.aeNJFYEL58@positron.chronox.de> References: <20200921075857.4424-1-nstange@suse.de> <20201016172619.GA18410@lst.de> <3073852.aeNJFYEL58@positron.chronox.de> MIME-Version: 1.0 Precedence: bulk List-ID: X-Mailing-List: linux-crypto@vger.kernel.org In an effort to provide a flexible implementation for a random number generator that also delivers entropy during early boot time, allows replacement of the deterministic random number generation mechanism, implement the various components in separate code for easier maintenance, and provide compliance to SP800-90[A|B|C], introduce the Linux Random Number Generator (LRNG) framework. The general design is as follows. Additional implementation details are given in [1]. The LRNG consists of the following components: 1. The LRNG implements a DRNG. The DRNG always generates the requested amount of output. When using the SP800-90A terminology it operates without prediction resistance. The secondary DRNG maintains a counter of how many bytes were generated since last re-seed and a timer of the elapsed time since last re-seed. If either the counter or the timer reaches a threshold, the secondary DRNG is seeded from the entropy pool. In case the Linux kernel detects a NUMA system, one secondary DRNG instance per NUMA node is maintained. 2. The DRNG is seeded by concatenating the data from the following sources: (a) the output of the entropy pool, (b) the Jitter RNG if available and enabled, and (c) the CPU-based noise source such as Intel RDRAND if available and enabled. The entropy estimate of the data of all noise sources are added to form the entropy estimate of the data used to seed the DRNG with. The LRNG ensures, however, that the DRNG after seeding is at maximum the security strength of the DRNG. The LRNG is designed such that none of these noise sources can dominate the other noise sources to provide seed data to the DRNG during due to the following: (a) During boot time, the amount of received interrupts are the trigger points to (re)seed the DRNG. (b) At runtime, the available entropy from the slow noise source is concatenated with a pre-defined amount of data from the fast noise sources. In addition, each DRNG reseed operation triggers external noise source providers to deliver one block of data. 3. The entropy pool accumulates entropy obtained from certain events, which will henceforth be collectively called "slow noise sources". The entropy pool collects noise data from slow noise sources. Any data received by the LRNG from the slow noise sources is inserted into a per-CPU entropy pool using a hash operation that can be changed during runtime. Per default, SHA-256 is used. (a) When an interrupt occurs, the high-resolution time stamp is mixed into the per-CPU entropy pool. This time stamp is credited with heuristically implied entropy. (b) HID event data like the key stroke or the mouse coordinates are mixed into the per-CPU entropy pool. This data is not credited with entropy by the LRNG. (c) Device drivers may provide data that is mixed into an auxiliary pool using the same hash that is used to process the per-CPU entropy pool. This data is not credited with entropy by the LRNG. Any data provided from user space by either writing to /dev/random, /dev/urandom or the IOCTL of RNDADDENTROPY on both device files are always injected into the auxiliary pool. In addition, when a hardware random number generator covered by the Linux kernel HW generator framework wants to deliver random numbers, it is injected into the auxiliary pool as well. HW generator noise source is handled separately from the other noise source due to the fact that the HW generator framework may decide by itself when to deliver data whereas the other noise sources always requested for data driven by the LRNG operation. Similarly any user space provided data is inserted into the entropy pool. When seed data for the DRNG is to be generated, all per-CPU entropy pools and the auxiliary pool are hashed. The message digest forms the new auxiliary pool state. At the same time, this data is used for seeding the DRNG. To speed up the interrupt handling code of the LRNG, the time stamp collected for an interrupt event is truncated to the 8 least significant bits. 64 truncated time stamps are concatenated and then jointly inserted into the per-CPU entropy pool. During boot time, until the fully seeded stage is reached, each time stamp with its 32 least significant bits is are concatenated. When 16 such events are received, they are injected into the per-CPU entropy pool. The LRNG allows the DRNG mechanism to be changed at runtime. Per default, a ChaCha20-based DRNG is used. The ChaCha20-DRNG implemented for the LRNG is also provided as a stand-alone user space deterministic random number generator. The LRNG also offers an SP800-90A DRBG based on the Linux kernel crypto API DRBG implementation. The processing of entropic data from the noise source before injecting them into the DRNG is performed with the following mathematical operations: 1. Truncation: The received time stamps are truncated to 8 least significant bits (or 32 least significant bits during boot time) 2. Concatenation: The received and truncated time stamps as well as auxiliary 32 bit words are concatenated to fill the per-CPU data array that is capable of holding 64 8-bit words. 3. Hashing: A set of concatenated time stamp data received from the interrupts are hashed together with the current existing per-CPU entropy pool state. The resulting message digest is the new per-CPU entropy pool state. 4. Hashing: When new data is added to the auxiliary pool, the data is hashed together with the auxiliary pool to form a new auxiliary pool state. 5. Hashing: A message digest of all per-CPU entropy pools and the auxiliary pool is calculated which forms the new auxiliary pool state. At the same time, this message digest is used to fill the slow noise source output buffer discussed in the following. 6. Truncation: The most-significant bits (MSB) defined by the requested number of bits (commonly equal to the security strength of the DRBG) or the entropy available transported with the buffer (which is the minimum of the message digest size and the available entropy in all entropy pools and the auxiliary pool), whatever is smaller, are obtained from the slow noise source output buffer. 7. Concatenation: The temporary seed buffer used to seed the DRNG is a concatenation of the slow noise source buffer, the Jitter RNG output, the CPU noise source output, and the current time. The DRNG always tries to seed itself with 256 bits of entropy, except during boot. In any case, if the noise sources cannot deliver that amount, the available entropy is used and the DRNG keeps track on how much entropy it was seeded with. The entropy implied by the LRNG available in the entropy pool may be too conservative. To ensure that during boot time all available entropy from the entropy pool is transferred to the DRNG, the hash_df function always generates 256 data bits during boot to seed the DRNG. During boot, the DRNG is seeded as follows: 1. The DRNG is reseeded from the entropy pool and potentially the fast noise sources if the entropy pool has collected at least 32 bits of entropy from the interrupt noise source. The goal of this step is to ensure that the DRNG receives some initial entropy as early as possible. In addition it receives the entropy available from the fast noise sources. 2. The DRNG is reseeded from the entropy pool and potentially the fast noise sources if all noise sources collectively can provide at least 128 bits of entropy. 3. The DRNG is reseeded from the entropy pool and potentially the fast noise sources if all noise sources collectivel can provide at least 256 bits. At the time of the reseeding steps, the DRNG requests as much entropy as is available in order to skip certain steps and reach the seeding level of 256 bits. This may imply that one or more of the aforementioned steps are skipped. In all listed steps, the DRNG is (re)seeded with a number of random bytes from the entropy pool that is at most the amount of entropy present in the entropy pool. This means that when the entropy pool contains 128 or 256 bits of entropy, the DRNG is seeded with that amount of entropy as well. Before the DRNG is seeded with 256 bits of entropy in step 3, requests of random data from /dev/random and the getrandom system call are not processed. The hash operation providing random data from the entropy pools will always require that all entropy sources collectively can deliver at least 128 entropy bits. The DRNG operates as deterministic random number generator with the following properties: * The maximum number of random bytes that can be generated with one DRNG generate operation is limited to 4096 bytes. When longer random numbers are requested, multiple DRNG generate operations are performed. The ChaCha20 DRNG as well as the SP800-90A DRBGs implement an update of their state after completing a generate request for backtracking resistance. * The secondary DRNG is reseeded with whatever entropy is available – in the worst case where no additional entropy can be provided by the noise sources, the DRNG is not re-seeded and continues its operation to try to reseed again after again the expiry of one of these thresholds: - If the last reseeding of the secondary DRNG is more than 600 seconds ago, or - 2^20 DRNG generate operations are performed, whatever comes first, or - the secondary DRNG is forced to reseed before the next generation of random numbers if data has been injected into the LRNG by writing data into /dev/random or /dev/urandom. The chosen values prevent high-volume requests from user space to cause frequent reseeding operations which drag down the performance of the DRNG. With the automatic reseeding after 600 seconds, the LRNG is triggered to reseed itself before the first request after a suspend that put the hardware to sleep for longer than 600 seconds. To support smaller devices including IoT environments, this patch allows reducing the runtime memory footprint of the LRNG at compile time by selecting smaller collection data sizes. When selecting the compilation of a kernel for a small environment, prevent the allocation of a buffer up to 4096 bytes to serve user space requests. In this case, the stack variable of 64 bytes is used to serve all user space requests. The LRNG has the following properties: * internal noise source: interrupts timing with fast boot time seeding * high performance of interrupt handling code: The LRNG impact on the interrupt handling has been reduced to a minimum. On one example system, the LRNG interrupt handling code in its fastest configuration executes within an average 55 cycles whereas the existing /dev/random on the same device takes about 97 cycles when measuring the execution time of add_interrupt_randomness(). * use of almost never contended lock for hashing operation to collect raw entropy supporting concurrency-free use of massive parallel systems - worst case rate of contention is the number of DRNG reseeds, usually: number of NUMA nodes contentions per 5 minutes. * use of standalone ChaCha20 based RNG with the option to use a different DRNG selectable at compile time * instantiate one DRNG per NUMA node * support for runtime switchable output DRNGs * use of runtime-switchable hash for conditioning implementation following widely accepted approach * compile-time selectable collection size * support of small systems by allowing the reduction of the runtime memory needs Further details including the rationale for the design choices and properties of the LRNG together with testing is provided at [1]. In addition, the documentation explains the conducted regression tests to verify that the LRNG is API and ABI compatible with the existing /dev/random implementation. [1] https://www.chronox.de/lrng.html CC: Torsten Duwe CC: "Eric W. Biederman" CC: "Alexander E. Patrakov" CC: "Ahmed S. Darwish" CC: "Theodore Y. Ts'o" CC: Willy Tarreau CC: Matthew Garrett CC: Vito Caputo CC: Andreas Dilger CC: Jan Kara CC: Ray Strode CC: William Jon McCann CC: zhangjs CC: Andy Lutomirski CC: Florian Weimer CC: Lennart Poettering CC: Nicolai Stange Mathematical aspects Reviewed-by: "Peter, Matthias" Reviewed-by: Marcelo Henrique Cerri Reviewed-by: Roman Drahtmueller Tested-by: Roman Drahtmüller Tested-by: Marcelo Henrique Cerri Tested-by: Neil Horman Signed-off-by: Stephan Mueller --- MAINTAINERS | 7 + drivers/char/Kconfig | 2 + drivers/char/Makefile | 9 +- drivers/char/lrng/Kconfig | 72 +++ drivers/char/lrng/Makefile | 9 + drivers/char/lrng/lrng_archrandom.c | 93 ++++ drivers/char/lrng/lrng_aux.c | 136 ++++++ drivers/char/lrng/lrng_chacha20.c | 352 +++++++++++++++ drivers/char/lrng/lrng_chacha20.h | 29 ++ drivers/char/lrng/lrng_drng.c | 406 +++++++++++++++++ drivers/char/lrng/lrng_interfaces.c | 651 ++++++++++++++++++++++++++++ drivers/char/lrng/lrng_internal.h | 420 ++++++++++++++++++ drivers/char/lrng/lrng_pool.c | 457 +++++++++++++++++++ drivers/char/lrng/lrng_sw_noise.c | 466 ++++++++++++++++++++ drivers/char/lrng/lrng_sw_noise.h | 56 +++ include/linux/lrng.h | 79 ++++ 16 files changed, 3243 insertions(+), 1 deletion(-) create mode 100644 drivers/char/lrng/Kconfig create mode 100644 drivers/char/lrng/Makefile create mode 100644 drivers/char/lrng/lrng_archrandom.c create mode 100644 drivers/char/lrng/lrng_aux.c create mode 100644 drivers/char/lrng/lrng_chacha20.c create mode 100644 drivers/char/lrng/lrng_chacha20.h create mode 100644 drivers/char/lrng/lrng_drng.c create mode 100644 drivers/char/lrng/lrng_interfaces.c create mode 100644 drivers/char/lrng/lrng_internal.h create mode 100644 drivers/char/lrng/lrng_pool.c create mode 100644 drivers/char/lrng/lrng_sw_noise.c create mode 100644 drivers/char/lrng/lrng_sw_noise.h create mode 100644 include/linux/lrng.h diff --git a/MAINTAINERS b/MAINTAINERS index 867157311dc8..750c9fa43cc7 100644 --- a/MAINTAINERS +++ b/MAINTAINERS @@ -10110,6 +10110,13 @@ F: Documentation/litmus-tests/ F: Documentation/memory-barriers.txt F: tools/memory-model/ +LINUX RANDOM NUMBER GENERATOR (LRNG) DRIVER +M: Stephan Mueller +S: Maintained +W: https://www.chronox.de/lrng.html +F: drivers/char/lrng/* +F: include/linux/lrng.h + LIS3LV02D ACCELEROMETER DRIVER M: Eric Piel S: Maintained diff --git a/drivers/char/Kconfig b/drivers/char/Kconfig index b1bd336761b1..8a5b8a2db2c7 100644 --- a/drivers/char/Kconfig +++ b/drivers/char/Kconfig @@ -470,6 +470,8 @@ config ADI and SSM (Silicon Secured Memory). Intended consumers of this driver include crash and makedumpfile. +source "drivers/char/lrng/Kconfig" + endmenu config RANDOM_TRUST_CPU diff --git a/drivers/char/Makefile b/drivers/char/Makefile index ffce287ef415..2110d3e28cf2 100644 --- a/drivers/char/Makefile +++ b/drivers/char/Makefile @@ -3,7 +3,14 @@ # Makefile for the kernel character device drivers. # -obj-y += mem.o random.o +obj-y += mem.o + +ifeq ($(CONFIG_LRNG),y) + obj-y += lrng/ +else + obj-y += random.o +endif + obj-$(CONFIG_TTY_PRINTK) += ttyprintk.o obj-y += misc.o obj-$(CONFIG_ATARI_DSP56K) += dsp56k.o diff --git a/drivers/char/lrng/Kconfig b/drivers/char/lrng/Kconfig new file mode 100644 index 000000000000..fbbcf2ef43b6 --- /dev/null +++ b/drivers/char/lrng/Kconfig @@ -0,0 +1,72 @@ +# SPDX-License-Identifier: GPL-2.0 +# +# Linux Random Number Generator configuration +# + +menuconfig LRNG + bool "Linux Random Number Generator" + select CRYPTO_LIB_SHA256 if CRYPTO + help + The Linux Random Number Generator (LRNG) is the replacement + of the existing /dev/random provided with drivers/char/random.c. + It generates entropy from different noise sources and + delivers significant entropy during boot. + +if LRNG + +choice + prompt "LRNG Entropy Collection Pool Size" + default LRNG_COLLECTION_SIZE_64 + help + Select the size of the LRNG entropy collection pool + storing data without performing a compression operation. + The larger the collection size is, the faster the + average interrupt handling will be. However, on the + other hand the time until the LRNG received full entropy + during boot time is longer because entropy is only awarded + to events once they are compressed. The collection + size represents the number of bytes of the per-CPU + memory used to batch up entropy event data. + + The default value is good for regular operations. Choose + larger sizes for servers whose boot time is of less + interest. Runtime memory is precious, choose a smaller + size. + + The collection size is unrelated to the entropy rate + or the amount of entropy the LRNG can process. + + config LRNG_COLLECTION_SIZE_16 + bool "16 interrupt events" + + config LRNG_COLLECTION_SIZE_32 + bool "32 interrupt events" + + config LRNG_COLLECTION_SIZE_64 + bool "64 interrupt events (default)" + + config LRNG_COLLECTION_SIZE_128 + bool "128 interrupt events" + + config LRNG_COLLECTION_SIZE_256 + bool "256 interrupt events" + + config LRNG_COLLECTION_SIZE_512 + bool "512 interrupt events" + + config LRNG_COLLECTION_SIZE_1024 + bool "1024 interrupt events" + +endchoice + +config LRNG_COLLECTION_SIZE + int + default 16 if LRNG_COLLECTION_SIZE_16 + default 32 if LRNG_COLLECTION_SIZE_32 + default 64 if LRNG_COLLECTION_SIZE_64 + default 128 if LRNG_COLLECTION_SIZE_128 + default 256 if LRNG_COLLECTION_SIZE_256 + default 512 if LRNG_COLLECTION_SIZE_512 + default 1024 if LRNG_COLLECTION_SIZE_1024 + +endif # LRNG diff --git a/drivers/char/lrng/Makefile b/drivers/char/lrng/Makefile new file mode 100644 index 000000000000..e72e01c15bb9 --- /dev/null +++ b/drivers/char/lrng/Makefile @@ -0,0 +1,9 @@ +# SPDX-License-Identifier: GPL-2.0 +# +# Makefile for the Linux Random Number Generator. +# + +obj-y += lrng_pool.o lrng_aux.o \ + lrng_sw_noise.o lrng_archrandom.o \ + lrng_drng.o lrng_chacha20.o \ + lrng_interfaces.o diff --git a/drivers/char/lrng/lrng_archrandom.c b/drivers/char/lrng/lrng_archrandom.c new file mode 100644 index 000000000000..5e81c4e856d5 --- /dev/null +++ b/drivers/char/lrng/lrng_archrandom.c @@ -0,0 +1,93 @@ +// SPDX-License-Identifier: GPL-2.0 OR BSD-2-Clause +/* + * LRNG Fast Noise Source: CPU-based noise source + * + * Copyright (C) 2016 - 2020, Stephan Mueller + */ + +#define pr_fmt(fmt) KBUILD_MODNAME ": " fmt + +#include + +#include "lrng_internal.h" + +/* + * Estimated entropy of data is a 32th of LRNG_DRNG_SECURITY_STRENGTH_BITS. + * As we have no ability to review the implementation of those noise sources, + * it is prudent to have a conservative estimate here. + */ +#define LRNG_ARCHRANDOM_DEFAULT_STRENGTH (LRNG_DRNG_SECURITY_STRENGTH_BITS>>5) +#define LRNG_ARCHRANDOM_TRUST_CPU_STRENGTH LRNG_DRNG_SECURITY_STRENGTH_BITS +#ifdef CONFIG_RANDOM_TRUST_CPU +static u32 archrandom = LRNG_ARCHRANDOM_TRUST_CPU_STRENGTH; +#else +static u32 archrandom = LRNG_ARCHRANDOM_DEFAULT_STRENGTH; +#endif +module_param(archrandom, uint, 0644); +MODULE_PARM_DESC(archrandom, "Entropy in bits of 256 data bits from CPU noise source (e.g. RDRAND)"); + +static int __init lrng_parse_trust_cpu(char *arg) +{ + int ret; + bool trust_cpu = false; + + ret = kstrtobool(arg, &trust_cpu); + if (ret) + return ret; + + if (trust_cpu) + archrandom = LRNG_ARCHRANDOM_TRUST_CPU_STRENGTH; + else + archrandom = LRNG_ARCHRANDOM_DEFAULT_STRENGTH; + + return 0; +} +early_param("random.trust_cpu", lrng_parse_trust_cpu); + +/** + * lrng_get_arch() - Get CPU noise source entropy + * + * @outbuf: buffer to store entropy of size LRNG_DRNG_SECURITY_STRENGTH_BYTES + * + * Return: + * * > 0 on success where value provides the added entropy in bits + * * 0 if no fast source was available + */ +u32 lrng_get_arch(u8 *outbuf) +{ + u32 i, ent_bits = archrandom; + + /* operate on full blocks */ + BUILD_BUG_ON(LRNG_DRNG_SECURITY_STRENGTH_BYTES % sizeof(unsigned long)); + /* ensure we have aligned buffers */ + BUILD_BUG_ON(LRNG_KCAPI_ALIGN % sizeof(unsigned long)); + + if (!ent_bits) + return 0; + + for (i = 0; i < LRNG_DRNG_SECURITY_STRENGTH_BYTES; + i += sizeof(unsigned long)) { + if (!arch_get_random_seed_long((unsigned long *)(outbuf + i)) && + !arch_get_random_long((unsigned long *)(outbuf + i))) { + archrandom = 0; + return 0; + } + } + + /* Obtain entropy statement -- cap entropy to buffer size in bits */ + ent_bits = min_t(u32, ent_bits, LRNG_DRNG_SECURITY_STRENGTH_BITS); + pr_debug("obtained %u bits of entropy from CPU RNG noise source\n", + ent_bits); + return ent_bits; +} + +u32 lrng_slow_noise_req_entropy(u32 required_entropy_bits) +{ + u32 arch_ent_bits = min_t(u32, archrandom, + LRNG_DRNG_SECURITY_STRENGTH_BITS); + u32 fast_noise_entropy = arch_ent_bits + lrng_jent_entropylevel(); + + if (fast_noise_entropy > required_entropy_bits) + return 0; + return (required_entropy_bits - fast_noise_entropy); +} diff --git a/drivers/char/lrng/lrng_aux.c b/drivers/char/lrng/lrng_aux.c new file mode 100644 index 000000000000..9f46c5707517 --- /dev/null +++ b/drivers/char/lrng/lrng_aux.c @@ -0,0 +1,136 @@ +// SPDX-License-Identifier: GPL-2.0 OR BSD-2-Clause +/* + * LRNG auxiliary interfaces + * + * Copyright (C) 2019 Stephan Mueller + * Copyright (C) 2017 Jason A. Donenfeld . All + * Rights Reserved. + * Copyright (C) 2016 Jason Cooper + */ + +#include +#include + +#include "lrng_internal.h" + +struct batched_entropy { + union { + u64 entropy_u64[LRNG_DRNG_BLOCKSIZE / sizeof(u64)]; + u32 entropy_u32[LRNG_DRNG_BLOCKSIZE / sizeof(u32)]; + }; + unsigned int position; + spinlock_t batch_lock; +}; + +/* + * Get a random word for internal kernel use only. The quality of the random + * number is as good as /dev/urandom, but there is no backtrack protection, + * with the goal of being quite fast and not depleting entropy. + */ +static DEFINE_PER_CPU(struct batched_entropy, batched_entropy_u64) = { + .batch_lock = __SPIN_LOCK_UNLOCKED(batched_entropy_u64.lock), +}; + +u64 get_random_u64(void) +{ + u64 ret; + unsigned long flags; + struct batched_entropy *batch; + + lrng_debug_report_seedlevel("get_random_u64"); + + batch = raw_cpu_ptr(&batched_entropy_u64); + spin_lock_irqsave(&batch->batch_lock, flags); + if (batch->position % ARRAY_SIZE(batch->entropy_u64) == 0) { + lrng_drng_get_atomic((u8 *)batch->entropy_u64, + LRNG_DRNG_BLOCKSIZE); + batch->position = 0; + } + ret = batch->entropy_u64[batch->position++]; + spin_unlock_irqrestore(&batch->batch_lock, flags); + return ret; +} +EXPORT_SYMBOL(get_random_u64); + +static DEFINE_PER_CPU(struct batched_entropy, batched_entropy_u32) = { + .batch_lock = __SPIN_LOCK_UNLOCKED(batched_entropy_u32.lock), +}; + +u32 get_random_u32(void) +{ + u32 ret; + unsigned long flags; + struct batched_entropy *batch; + + lrng_debug_report_seedlevel("get_random_u32"); + + batch = raw_cpu_ptr(&batched_entropy_u32); + spin_lock_irqsave(&batch->batch_lock, flags); + if (batch->position % ARRAY_SIZE(batch->entropy_u32) == 0) { + lrng_drng_get_atomic((u8 *)batch->entropy_u32, + LRNG_DRNG_BLOCKSIZE); + batch->position = 0; + } + ret = batch->entropy_u32[batch->position++]; + spin_unlock_irqrestore(&batch->batch_lock, flags); + return ret; +} +EXPORT_SYMBOL(get_random_u32); + +/* + * It's important to invalidate all potential batched entropy that might + * be stored before the crng is initialized, which we can do lazily by + * simply resetting the counter to zero so that it's re-extracted on the + * next usage. + */ +void invalidate_batched_entropy(void) +{ + int cpu; + unsigned long flags; + + for_each_possible_cpu(cpu) { + struct batched_entropy *batched_entropy; + + batched_entropy = per_cpu_ptr(&batched_entropy_u32, cpu); + spin_lock_irqsave(&batched_entropy->batch_lock, flags); + batched_entropy->position = 0; + spin_unlock(&batched_entropy->batch_lock); + + batched_entropy = per_cpu_ptr(&batched_entropy_u64, cpu); + spin_lock(&batched_entropy->batch_lock); + batched_entropy->position = 0; + spin_unlock_irqrestore(&batched_entropy->batch_lock, flags); + } +} + +/** + * randomize_page - Generate a random, page aligned address + * @start: The smallest acceptable address the caller will take. + * @range: The size of the area, starting at @start, within which the + * random address must fall. + * + * If @start + @range would overflow, @range is capped. + * + * NOTE: Historical use of randomize_range, which this replaces, presumed that + * @start was already page aligned. We now align it regardless. + * + * Return: A page aligned address within [start, start + range). On error, + * @start is returned. + */ +unsigned long randomize_page(unsigned long start, unsigned long range) +{ + if (!PAGE_ALIGNED(start)) { + range -= PAGE_ALIGN(start) - start; + start = PAGE_ALIGN(start); + } + + if (start > ULONG_MAX - range) + range = ULONG_MAX - start; + + range >>= PAGE_SHIFT; + + if (range == 0) + return start; + + return start + (get_random_long() % range << PAGE_SHIFT); +} diff --git a/drivers/char/lrng/lrng_chacha20.c b/drivers/char/lrng/lrng_chacha20.c new file mode 100644 index 000000000000..1019e0024676 --- /dev/null +++ b/drivers/char/lrng/lrng_chacha20.c @@ -0,0 +1,352 @@ +// SPDX-License-Identifier: GPL-2.0 OR BSD-2-Clause +/* + * Backend for the LRNG providing the cryptographic primitives using + * ChaCha20 cipher implementations. + * + * Copyright (C) 2016 - 2020, Stephan Mueller + */ + +#define pr_fmt(fmt) KBUILD_MODNAME ": " fmt + +#include +#include +#include +#include +#include + +#include "lrng_chacha20.h" +#include "lrng_internal.h" + +/******************************* ChaCha20 DRNG *******************************/ + +#define CHACHA_BLOCK_WORDS (CHACHA_BLOCK_SIZE / sizeof(u32)) + +struct chacha20_state { + struct chacha20_block block; +}; + +/* + * Have a static memory blocks for the ChaCha20 DRNG instance to avoid calling + * kmalloc too early in the boot cycle. For subsequent allocation requests, + * such as per-NUMA-node DRNG instances, kmalloc will be used. + */ +struct chacha20_state chacha20 __latent_entropy; + +/** + * Update of the ChaCha20 state by either using an unused buffer part or by + * generating one ChaCha20 block which is half of the state of the ChaCha20. + * The block is XORed into the key part of the state. This shall ensure + * backtracking resistance as well as a proper mix of the ChaCha20 state once + * the key is injected. + */ +static void lrng_chacha20_update(struct chacha20_state *chacha20_state, + __le32 *buf, u32 used_words) +{ + struct chacha20_block *chacha20 = &chacha20_state->block; + u32 i; + __le32 tmp[CHACHA_BLOCK_WORDS]; + + BUILD_BUG_ON(sizeof(struct chacha20_block) != CHACHA_BLOCK_SIZE); + BUILD_BUG_ON(CHACHA_BLOCK_SIZE != 2 * CHACHA_KEY_SIZE); + + if (used_words > CHACHA_KEY_SIZE_WORDS) { + chacha20_block(&chacha20->constants[0], (u8 *)tmp); + for (i = 0; i < CHACHA_KEY_SIZE_WORDS; i++) + chacha20->key.u[i] ^= le32_to_cpu(tmp[i]); + memzero_explicit(tmp, sizeof(tmp)); + } else { + for (i = 0; i < CHACHA_KEY_SIZE_WORDS; i++) + chacha20->key.u[i] ^= le32_to_cpu(buf[i + used_words]); + } + + /* Deterministic increment of nonce as required in RFC 7539 chapter 4 */ + chacha20->nonce[0]++; + if (chacha20->nonce[0] == 0) + chacha20->nonce[1]++; + if (chacha20->nonce[1] == 0) + chacha20->nonce[2]++; + + /* Leave counter untouched as it is start value is undefined in RFC */ +} + +/* + * Seed the ChaCha20 DRNG by injecting the input data into the key part of + * the ChaCha20 state. If the input data is longer than the ChaCha20 key size, + * perform a ChaCha20 operation after processing of key size input data. + * This operation shall spread out the entropy into the ChaCha20 state before + * new entropy is injected into the key part. + */ +static int lrng_cc20_drng_seed_helper(void *drng, const u8 *inbuf, u32 inbuflen) +{ + struct chacha20_state *chacha20_state = (struct chacha20_state *)drng; + struct chacha20_block *chacha20 = &chacha20_state->block; + + while (inbuflen) { + u32 i, todo = min_t(u32, inbuflen, CHACHA_KEY_SIZE); + + for (i = 0; i < todo; i++) + chacha20->key.b[i] ^= inbuf[i]; + + /* Break potential dependencies between the inbuf key blocks */ + lrng_chacha20_update(chacha20_state, NULL, + CHACHA_BLOCK_WORDS); + inbuf += todo; + inbuflen -= todo; + } + + return 0; +} + +/* + * Chacha20 DRNG generation of random numbers: the stream output of ChaCha20 + * is the random number. After the completion of the generation of the + * stream, the entire ChaCha20 state is updated. + * + * Note, as the ChaCha20 implements a 32 bit counter, we must ensure + * that this function is only invoked for at most 2^32 - 1 ChaCha20 blocks + * before a reseed or an update happens. This is ensured by the variable + * outbuflen which is a 32 bit integer defining the number of bytes to be + * generated by the ChaCha20 DRNG. At the end of this function, an update + * operation is invoked which implies that the 32 bit counter will never be + * overflown in this implementation. + */ +static int lrng_cc20_drng_generate_helper(void *drng, u8 *outbuf, u32 outbuflen) +{ + struct chacha20_state *chacha20_state = (struct chacha20_state *)drng; + struct chacha20_block *chacha20 = &chacha20_state->block; + __le32 aligned_buf[CHACHA_BLOCK_WORDS]; + u32 ret = outbuflen, used = CHACHA_BLOCK_WORDS; + int zeroize_buf = 0; + + while (outbuflen >= CHACHA_BLOCK_SIZE) { + chacha20_block(&chacha20->constants[0], outbuf); + outbuf += CHACHA_BLOCK_SIZE; + outbuflen -= CHACHA_BLOCK_SIZE; + } + + if (outbuflen) { + chacha20_block(&chacha20->constants[0], (u8 *)aligned_buf); + memcpy(outbuf, aligned_buf, outbuflen); + used = ((outbuflen + sizeof(aligned_buf[0]) - 1) / + sizeof(aligned_buf[0])); + zeroize_buf = 1; + } + + lrng_chacha20_update(chacha20_state, aligned_buf, used); + + if (zeroize_buf) + memzero_explicit(aligned_buf, sizeof(aligned_buf)); + + return ret; +} + +void lrng_cc20_init_state(struct chacha20_state *state) +{ + struct chacha20_block *chacha20 = &state->block; + unsigned long v; + u32 i; + + lrng_cc20_init_rfc7539(chacha20); + + for (i = 0; i < CHACHA_KEY_SIZE_WORDS; i++) { + chacha20->key.u[i] ^= jiffies; + chacha20->key.u[i] ^= random_get_entropy(); + if (arch_get_random_seed_long(&v) || arch_get_random_long(&v)) + chacha20->key.u[i] ^= v; + } + + for (i = 0; i < 3; i++) { + chacha20->nonce[i] ^= jiffies; + chacha20->nonce[i] ^= random_get_entropy(); + if (arch_get_random_seed_long(&v) || arch_get_random_long(&v)) + chacha20->nonce[i] ^= v; + } + + lrng_chacha20_update(state, NULL, CHACHA_BLOCK_WORDS); + pr_info("ChaCha20 core initialized\n"); +} + +void __init lrng_cc20_init_state_boot(struct chacha20_state *state) +{ + struct chacha20_block *chacha20 = &state->block; + unsigned long v; + u32 i; + + for (i = 0; i < CHACHA_KEY_SIZE_WORDS; i++) { + if (arch_get_random_seed_long_early(&v) || + arch_get_random_long_early(&v)) + chacha20->key.u[i] ^= v; + } + + for (i = 0; i < 3; i++) { + if (arch_get_random_seed_long_early(&v) || + arch_get_random_long_early(&v)) + chacha20->nonce[i] ^= v; + } + + lrng_chacha20_update(state, NULL, CHACHA_BLOCK_WORDS); +} + +/* + * Allocation of the DRNG state + */ +static void *lrng_cc20_drng_alloc(u32 sec_strength) +{ + struct chacha20_state *state = NULL; + + if (sec_strength > CHACHA_KEY_SIZE) { + pr_err("Security strength of ChaCha20 DRNG (%u bits) lower than requested by LRNG (%u bits)\n", + CHACHA_KEY_SIZE * 8, sec_strength * 8); + return ERR_PTR(-EINVAL); + } + if (sec_strength < CHACHA_KEY_SIZE) + pr_warn("Security strength of ChaCha20 DRNG (%u bits) higher than requested by LRNG (%u bits)\n", + CHACHA_KEY_SIZE * 8, sec_strength * 8); + + state = kmalloc(sizeof(struct chacha20_state), GFP_KERNEL); + if (!state) + return ERR_PTR(-ENOMEM); + pr_debug("memory for ChaCha20 core allocated\n"); + + lrng_cc20_init_state(state); + + return state; +} + +static void lrng_cc20_drng_dealloc(void *drng) +{ + struct chacha20_state *chacha20_state = (struct chacha20_state *)drng; + + if (drng == &chacha20) { + memzero_explicit(chacha20_state, sizeof(*chacha20_state)); + pr_debug("static ChaCha20 core zeroized\n"); + return; + } + + pr_debug("ChaCha20 core zeroized and freed\n"); + kfree_sensitive(chacha20_state); +} + +/******************************* Hash Operation *******************************/ + +#ifdef CONFIG_CRYPTO_LIB_SHA256 + +static u32 lrng_cc20_hash_digestsize(void *hash) +{ + return SHA256_DIGEST_SIZE; +} + +static int lrng_cc20_hash_init(struct shash_desc *shash, void *hash) +{ + /* + * We do not need a TFM - we only need sufficient space for + * struct sha1_state on the stack. + */ + sha256_init(shash_desc_ctx(shash)); + return 0; +} + +static int lrng_cc20_hash_update(struct shash_desc *shash, + const u8 *inbuf, u32 inbuflen) +{ + sha256_update(shash_desc_ctx(shash), inbuf, inbuflen); + return 0; +} + +static int lrng_cc20_hash_final(struct shash_desc *shash, u8 *digest) +{ + sha256_final(shash_desc_ctx(shash), digest); + return 0; +} + +static const char *lrng_cc20_hash_name(void) +{ + const char *cc20_hash_name = "SHA-256"; + return cc20_hash_name; +} + +#else /* CONFIG_CRYPTO_LIB_SHA256 */ + +#include + +/* + * If the SHA-256 support is not compiled, we fall back to SHA-1 that is always + * compiled and present in the kernel. + */ +static u32 lrng_cc20_hash_digestsize(void *hash) +{ + return SHA1_DIGEST_SIZE; +} + +static void lrng_sha1_block_fn(struct sha1_state *sctx, const u8 *src, + int blocks) +{ + u32 temp[SHA1_WORKSPACE_WORDS]; + + while (blocks--) { + sha1_transform(sctx->state, src, temp); + src += SHA1_BLOCK_SIZE; + } + memzero_explicit(temp, sizeof(temp)); +} + +static int lrng_cc20_hash_init(struct shash_desc *shash, void *hash) +{ + /* + * We do not need a TFM - we only need sufficient space for + * struct sha1_state on the stack. + */ + sha1_base_init(shash); + return 0; +} + +static int lrng_cc20_hash_update(struct shash_desc *shash, + const u8 *inbuf, u32 inbuflen) +{ + return sha1_base_do_update(shash, inbuf, inbuflen, lrng_sha1_block_fn); +} + +static int lrng_cc20_hash_final(struct shash_desc *shash, u8 *digest) +{ + return sha1_base_do_finalize(shash, lrng_sha1_block_fn) ?: + sha1_base_finish(shash, digest); +} + +static const char *lrng_cc20_hash_name(void) +{ + const char *cc20_hash_name = "SHA-1"; + return cc20_hash_name; +} + +#endif /* CONFIG_CRYPTO_LIB_SHA256 */ + +static void *lrng_cc20_hash_alloc(void) +{ + pr_info("Hash %s allocated\n", lrng_cc20_hash_name()); + return NULL; +} + +static void lrng_cc20_hash_dealloc(void *hash) +{ +} + +static const char *lrng_cc20_drng_name(void) +{ + const char *cc20_drng_name = "ChaCha20 DRNG"; + return cc20_drng_name; +} + +const struct lrng_crypto_cb lrng_cc20_crypto_cb = { + .lrng_drng_name = lrng_cc20_drng_name, + .lrng_hash_name = lrng_cc20_hash_name, + .lrng_drng_alloc = lrng_cc20_drng_alloc, + .lrng_drng_dealloc = lrng_cc20_drng_dealloc, + .lrng_drng_seed_helper = lrng_cc20_drng_seed_helper, + .lrng_drng_generate_helper = lrng_cc20_drng_generate_helper, + .lrng_hash_alloc = lrng_cc20_hash_alloc, + .lrng_hash_dealloc = lrng_cc20_hash_dealloc, + .lrng_hash_digestsize = lrng_cc20_hash_digestsize, + .lrng_hash_init = lrng_cc20_hash_init, + .lrng_hash_update = lrng_cc20_hash_update, + .lrng_hash_final = lrng_cc20_hash_final, +}; diff --git a/drivers/char/lrng/lrng_chacha20.h b/drivers/char/lrng/lrng_chacha20.h new file mode 100644 index 000000000000..2340b12a56a4 --- /dev/null +++ b/drivers/char/lrng/lrng_chacha20.h @@ -0,0 +1,29 @@ +/* SPDX-License-Identifier: GPL-2.0 OR BSD-2-Clause */ +/* + * LRNG ChaCha20 definitions + * + * Copyright (C) 2016 - 2020, Stephan Mueller + */ + +#include + +/* State according to RFC 7539 section 2.3 */ +struct chacha20_block { + u32 constants[4]; + union { +#define CHACHA_KEY_SIZE_WORDS (CHACHA_KEY_SIZE / sizeof(u32)) + u32 u[CHACHA_KEY_SIZE_WORDS]; + u8 b[CHACHA_KEY_SIZE]; + } key; + u32 counter; + u32 nonce[3]; +}; + +static inline void lrng_cc20_init_rfc7539(struct chacha20_block *chacha20) +{ + /* String "expand 32-byte k" */ + chacha20->constants[0] = 0x61707865; + chacha20->constants[1] = 0x3320646e; + chacha20->constants[2] = 0x79622d32; + chacha20->constants[3] = 0x6b206574; +} diff --git a/drivers/char/lrng/lrng_drng.c b/drivers/char/lrng/lrng_drng.c new file mode 100644 index 000000000000..0c4e4893297e --- /dev/null +++ b/drivers/char/lrng/lrng_drng.c @@ -0,0 +1,406 @@ +// SPDX-License-Identifier: GPL-2.0 OR BSD-2-Clause +/* + * LRNG DRNG processing + * + * Copyright (C) 2016 - 2020, Stephan Mueller + */ + +#define pr_fmt(fmt) KBUILD_MODNAME ": " fmt + +#include + +#include "lrng_internal.h" + +/* + * Maximum number of seconds between DRNG reseed intervals of the DRNG. Note, + * this is enforced with the next request of random numbers from the + * DRNG. Setting this value to zero implies a reseeding attempt before every + * generated random number. + */ +int lrng_drng_reseed_max_time = 600; + +static atomic_t lrng_avail = ATOMIC_INIT(0); + +DEFINE_MUTEX(lrng_crypto_cb_update); + +/* DRNG for /dev/urandom, getrandom(2), get_random_bytes */ +static struct lrng_drng lrng_drng_init = { + .drng = &chacha20, + .crypto_cb = &lrng_cc20_crypto_cb, + .lock = __MUTEX_INITIALIZER(lrng_drng_init.lock), + .spin_lock = __SPIN_LOCK_UNLOCKED(lrng_drng_init.spin_lock), + .hash_lock = __RW_LOCK_UNLOCKED(lrng_drng_init.hash_lock) +}; + +/* + * DRNG for get_random_bytes when called in atomic context. This + * DRNG will always use the ChaCha20 DRNG. It will never benefit from a + * DRNG switch like the "regular" DRNG. If there was no DRNG switch, the atomic + * DRNG is identical to the "regular" DRNG. + * + * The reason for having this is due to the fact that DRNGs other than + * the ChaCha20 DRNG may sleep. + */ +static struct lrng_drng lrng_drng_atomic = { + .drng = &chacha20, + .crypto_cb = &lrng_cc20_crypto_cb, + .spin_lock = __SPIN_LOCK_UNLOCKED(lrng_drng_atomic.spin_lock), + .hash_lock = __RW_LOCK_UNLOCKED(lrng_drng_atomic.hash_lock) +}; + +/********************************** Helper ************************************/ + +bool lrng_get_available(void) +{ + return likely(atomic_read(&lrng_avail)); +} + +void lrng_set_available(void) +{ + atomic_set(&lrng_avail, 1); +} + +struct lrng_drng *lrng_drng_init_instance(void) +{ + return &lrng_drng_init; +} + +struct lrng_drng *lrng_drng_atomic_instance(void) +{ + return &lrng_drng_atomic; +} + +void lrng_drng_reset(struct lrng_drng *drng) +{ + atomic_set(&drng->requests, LRNG_DRNG_RESEED_THRESH); + drng->last_seeded = jiffies; + drng->fully_seeded = false; + drng->force_reseed = true; + pr_debug("reset DRNG\n"); +} + +/* Initialize the default DRNG during boot */ +static void lrng_drngs_init_cc20(void) +{ + unsigned long flags = 0; + + if (lrng_get_available()) + return; + + lrng_drng_lock(&lrng_drng_init, &flags); + if (lrng_get_available()) { + lrng_drng_unlock(&lrng_drng_init, &flags); + return; + } + + lrng_drng_reset(&lrng_drng_init); + lrng_cc20_init_state(&chacha20); + lrng_state_init_seed_work(); + lrng_drng_unlock(&lrng_drng_init, &flags); + + lrng_drng_lock(&lrng_drng_atomic, &flags); + lrng_drng_reset(&lrng_drng_atomic); + /* + * We do not initialize the state of the atomic DRNG as it is identical + * to the DRNG at this point. + */ + lrng_drng_unlock(&lrng_drng_atomic, &flags); + + lrng_set_available(); +} + +/************************* Random Number Generation ***************************/ + +/* Inject a data buffer into the DRNG */ +static void lrng_drng_inject(struct lrng_drng *drng, + const u8 *inbuf, u32 inbuflen) +{ + const char *drng_type = unlikely(drng == &lrng_drng_atomic) ? + "atomic" : "regular"; + unsigned long flags = 0; + + BUILD_BUG_ON(LRNG_DRNG_RESEED_THRESH > INT_MAX); + pr_debug("seeding %s DRNG with %u bytes\n", drng_type, inbuflen); + lrng_drng_lock(drng, &flags); + if (drng->crypto_cb->lrng_drng_seed_helper(drng->drng, + inbuf, inbuflen) < 0) { + pr_warn("seeding of %s DRNG failed\n", drng_type); + atomic_set(&drng->requests, 1); + } else { + pr_debug("%s DRNG stats since last seeding: %lu secs; generate calls: %d\n", + drng_type, + (time_after(jiffies, drng->last_seeded) ? + (jiffies - drng->last_seeded) : 0) / HZ, + (LRNG_DRNG_RESEED_THRESH - + atomic_read(&drng->requests))); + drng->last_seeded = jiffies; + atomic_set(&drng->requests, LRNG_DRNG_RESEED_THRESH); + drng->force_reseed = false; + + if (drng->drng == lrng_drng_atomic.drng) { + lrng_drng_atomic.last_seeded = jiffies; + atomic_set(&lrng_drng_atomic.requests, + LRNG_DRNG_RESEED_THRESH); + lrng_drng_atomic.force_reseed = false; + } + } + lrng_drng_unlock(drng, &flags); +} + +/* + * Perform the seeding of the DRNG with data from noise source + */ +static inline int _lrng_drng_seed(struct lrng_drng *drng) +{ + struct entropy_buf seedbuf __aligned(LRNG_KCAPI_ALIGN); + u32 total_entropy_bits; + int ret; + + total_entropy_bits = lrng_fill_seed_buffer(drng, &seedbuf); + + /* Allow the seeding operation to be called again */ + lrng_pool_unlock(); + lrng_init_ops(total_entropy_bits); + ret = total_entropy_bits >> 3; + + lrng_drng_inject(drng, (u8 *)&seedbuf, sizeof(seedbuf)); + memzero_explicit(&seedbuf, sizeof(seedbuf)); + + if (ret >= (int)(lrng_security_strength() >> 3)) + drng->fully_seeded = true; + + return ret; +} + +static int lrng_drng_get(struct lrng_drng *drng, u8 *outbuf, u32 outbuflen); +static void lrng_drng_seed(struct lrng_drng *drng) +{ + int ret = _lrng_drng_seed(drng); + + BUILD_BUG_ON(LRNG_MIN_SEED_ENTROPY_BITS > + LRNG_DRNG_SECURITY_STRENGTH_BITS); + + /* + * Reseed atomic DRNG from current DRNG, + * + * We can obtain random numbers from DRNG as the lock type + * chosen by lrng_drng_get is usable with the current caller. + */ + if ((drng->drng != lrng_drng_atomic.drng) && + (lrng_drng_atomic.force_reseed || + atomic_read(&lrng_drng_atomic.requests) <= 0 || + time_after(jiffies, lrng_drng_atomic.last_seeded + + lrng_drng_reseed_max_time * HZ))) { + u8 seedbuf[LRNG_DRNG_SECURITY_STRENGTH_BYTES] + __aligned(LRNG_KCAPI_ALIGN); + + ret = lrng_drng_get(drng, seedbuf, sizeof(seedbuf)); + + if (ret < 0) { + pr_warn("Error generating random numbers for atomic DRNG: %d\n", + ret); + } else { + lrng_drng_inject(&lrng_drng_atomic, seedbuf, ret); + } + memzero_explicit(&seedbuf, sizeof(seedbuf)); + } +} + +static inline void _lrng_drng_seed_work(struct lrng_drng *drng, u32 node) +{ + pr_debug("reseed triggered by interrupt noise source for DRNG on NUMA node %d\n", + node); + lrng_drng_seed(drng); + if (drng->fully_seeded) { + /* Prevent reseed storm */ + drng->last_seeded += node * 100 * HZ; + /* Prevent draining of pool on idle systems */ + lrng_drng_reseed_max_time += 100; + } +} + +/* + * DRNG reseed trigger: Kernel thread handler triggered by the schedule_work() + */ +void lrng_drng_seed_work(struct work_struct *dummy) +{ + struct lrng_drng **lrng_drng = lrng_drng_instances(); + u32 node; + + if (lrng_drng) { + for_each_online_node(node) { + struct lrng_drng *drng = lrng_drng[node]; + + if (drng && !drng->fully_seeded) { + _lrng_drng_seed_work(drng, node); + goto out; + } + } + lrng_pool_all_numa_nodes_seeded(); + } else { + if (!lrng_drng_init.fully_seeded) + _lrng_drng_seed_work(&lrng_drng_init, 0); + } + +out: + /* Allow the seeding operation to be called again */ + lrng_pool_unlock(); +} + +/* Force all DRNGs to reseed before next generation */ +void lrng_drng_force_reseed(void) +{ + struct lrng_drng **lrng_drng = lrng_drng_instances(); + u32 node; + + if (!lrng_drng) { + lrng_drng_init.force_reseed = true; + pr_debug("force reseed of initial DRNG\n"); + return; + } + for_each_online_node(node) { + struct lrng_drng *drng = lrng_drng[node]; + + if (!drng) + continue; + + drng->force_reseed = true; + pr_debug("force reseed of DRNG on node %u\n", node); + } + lrng_drng_atomic.force_reseed = true; +} + +/** + * lrng_drng_get() - Get random data out of the DRNG which is reseeded + * frequently. + * + * @outbuf: buffer for storing random data + * @outbuflen: length of outbuf + * + * Return: + * * < 0 in error case (DRNG generation or update failed) + * * >=0 returning the returned number of bytes + */ +static int lrng_drng_get(struct lrng_drng *drng, u8 *outbuf, u32 outbuflen) +{ + unsigned long flags = 0; + u32 processed = 0; + + if (!outbuf || !outbuflen) + return 0; + + outbuflen = min_t(size_t, outbuflen, INT_MAX); + + lrng_drngs_init_cc20(); + + while (outbuflen) { + u32 todo = min_t(u32, outbuflen, LRNG_DRNG_MAX_REQSIZE); + int ret; + + /* All but the atomic DRNG are seeded during generation */ + if (atomic_dec_and_test(&drng->requests) || + drng->force_reseed || + time_after(jiffies, drng->last_seeded + + lrng_drng_reseed_max_time * HZ)) { + if (likely(drng != &lrng_drng_atomic)) { + if (lrng_pool_trylock()) + atomic_set(&drng->requests, 1); + else + lrng_drng_seed(drng); + } + } + + lrng_drng_lock(drng, &flags); + ret = drng->crypto_cb->lrng_drng_generate_helper( + drng->drng, outbuf + processed, todo); + lrng_drng_unlock(drng, &flags); + if (ret <= 0) { + pr_warn("getting random data from DRNG failed (%d)\n", + ret); + return -EFAULT; + } + processed += ret; + outbuflen -= ret; + } + + return processed; +} + +int lrng_drng_get_atomic(u8 *outbuf, u32 outbuflen) +{ + return lrng_drng_get(&lrng_drng_atomic, outbuf, outbuflen); +} + +int lrng_drng_get_sleep(u8 *outbuf, u32 outbuflen) +{ + struct lrng_drng **lrng_drng = lrng_drng_instances(); + struct lrng_drng *drng = &lrng_drng_init; + int node = numa_node_id(); + + might_sleep(); + + if (lrng_drng && lrng_drng[node] && lrng_drng[node]->fully_seeded) + drng = lrng_drng[node]; + + return lrng_drng_get(drng, outbuf, outbuflen); +} + +/* Reset LRNG such that all existing entropy is gone */ +static void _lrng_reset(struct work_struct *work) +{ + struct lrng_drng **lrng_drng = lrng_drng_instances(); + unsigned long flags = 0; + + if (!lrng_drng) { + lrng_drng_lock(&lrng_drng_init, &flags); + lrng_drng_reset(&lrng_drng_init); + lrng_drng_unlock(&lrng_drng_init, &flags); + } else { + u32 node; + + for_each_online_node(node) { + struct lrng_drng *drng = lrng_drng[node]; + + if (!drng) + continue; + lrng_drng_lock(drng, &flags); + lrng_drng_reset(drng); + lrng_drng_unlock(drng, &flags); + } + } + lrng_set_entropy_thresh(LRNG_INIT_ENTROPY_BITS); + + lrng_reset_state(); +} + +static DECLARE_WORK(lrng_reset_work, _lrng_reset); + +void lrng_reset(void) +{ + schedule_work(&lrng_reset_work); +} + +/***************************** Initialize LRNG *******************************/ + +void __init lrng_drng_init_early(void) +{ + unsigned long flags = 0; + + lrng_drng_lock(&lrng_drng_init, &flags); + lrng_cc20_init_state_boot(&chacha20); + lrng_drng_unlock(&lrng_drng_init, &flags); +} + +static int __init lrng_init(void) +{ + lrng_drngs_init_cc20(); + + lrng_drngs_numa_alloc(); + return 0; +} + +late_initcall(lrng_init); + +MODULE_LICENSE("Dual BSD/GPL"); +MODULE_AUTHOR("Stephan Mueller "); +MODULE_DESCRIPTION("Linux Random Number Generator"); diff --git a/drivers/char/lrng/lrng_interfaces.c b/drivers/char/lrng/lrng_interfaces.c new file mode 100644 index 000000000000..19d01d3f7492 --- /dev/null +++ b/drivers/char/lrng/lrng_interfaces.c @@ -0,0 +1,651 @@ +// SPDX-License-Identifier: GPL-2.0 OR BSD-2-Clause +/* + * LRNG User and kernel space interfaces + * + * Copyright (C) 2016 - 2020, Stephan Mueller + */ + +#define pr_fmt(fmt) KBUILD_MODNAME ": " fmt + +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include + +#define CREATE_TRACE_POINTS +#include + +#include "lrng_internal.h" + +/* + * If the entropy count falls under this number of bits, then we + * should wake up processes which are selecting or polling on write + * access to /dev/random. + */ +u32 lrng_write_wakeup_bits = LRNG_WRITE_WAKEUP_ENTROPY; + +static LIST_HEAD(lrng_ready_list); +static DEFINE_SPINLOCK(lrng_ready_list_lock); + +static DECLARE_WAIT_QUEUE_HEAD(lrng_write_wait); +static DECLARE_WAIT_QUEUE_HEAD(lrng_init_wait); +static struct fasync_struct *fasync; + +struct ctl_table random_table[]; + +/********************************** Helper ***********************************/ + +/* Is the DRNG seed level too low? */ +static inline bool lrng_need_entropy(void) +{ + return (lrng_avail_aux_entropy() < lrng_write_wakeup_bits); +} + +void lrng_writer_wakeup(void) +{ + if (lrng_need_entropy() && wq_has_sleeper(&lrng_write_wait)) { + wake_up_interruptible(&lrng_write_wait); + kill_fasync(&fasync, SIGIO, POLL_OUT); + } +} + +void lrng_init_wakeup(void) +{ + wake_up_all(&lrng_init_wait); + kill_fasync(&fasync, SIGIO, POLL_IN); +} + +/** + * lrng_process_ready_list() - Ping all kernel internal callers waiting until + * the DRNG is at least minimally seeded to inform that the DRNG reached that + * seed level. + * + * When the SP800-90B testing is enabled, the ping only happens if the SP800-90B + * startup health tests are completed. This implies that kernel internal + * callers always have an SP800-90B compliant noise source when being + * pinged. + */ +void lrng_process_ready_list(void) +{ + unsigned long flags; + struct random_ready_callback *rdy, *tmp; + + if (!lrng_sp80090b_startup_complete()) + return; + + spin_lock_irqsave(&lrng_ready_list_lock, flags); + list_for_each_entry_safe(rdy, tmp, &lrng_ready_list, list) { + struct module *owner = rdy->owner; + + list_del_init(&rdy->list); + rdy->func(rdy); + module_put(owner); + } + spin_unlock_irqrestore(&lrng_ready_list_lock, flags); +} + +void lrng_debug_report_seedlevel(const char *name) +{ +#ifdef CONFIG_WARN_ALL_UNSEEDED_RANDOM + static void *previous = NULL; + void *caller = (void *) _RET_IP_; + + if (READ_ONCE(previous) == caller) + return; + + if (!lrng_state_min_seeded()) + pr_notice("%pS %s called without reaching mimimally seeded level (available entropy %u)\n", + caller, name, lrng_avail_entropy()); + + WRITE_ONCE(previous, caller); +#endif +} + +/************************ LRNG kernel input interfaces ************************/ + +/** + * add_hwgenerator_randomness() - Interface for in-kernel drivers of true + * hardware RNGs. + * + * Those devices may produce endless random bits and will be throttled + * when our pool is full. + * + * @buffer: buffer holding the entropic data from HW noise sources to be used to + * insert into entropy pool. + * @count: length of buffer + * @entropy_bits: amount of entropy in buffer (value is in bits) + */ +void add_hwgenerator_randomness(const char *buffer, size_t count, + size_t entropy_bits) +{ + /* + * Suspend writing if we are fully loaded with entropy. + * We'll be woken up again once below lrng_write_wakeup_thresh, + * or when the calling thread is about to terminate. + */ + wait_event_interruptible(lrng_write_wait, + lrng_need_entropy() || + lrng_state_exseed_allow(lrng_noise_source_hw) || + kthread_should_stop()); + lrng_state_exseed_set(lrng_noise_source_hw, false); + lrng_pool_insert_aux(buffer, count, entropy_bits); +} +EXPORT_SYMBOL_GPL(add_hwgenerator_randomness); + +/** + * add_bootloader_randomness() - Handle random seed passed by bootloader. + * + * If the seed is trustworthy, it would be regarded as hardware RNGs. Otherwise + * it would be regarded as device data. + * The decision is controlled by CONFIG_RANDOM_TRUST_BOOTLOADER. + * + * @buf: buffer holding the entropic data from HW noise sources to be used to + * insert into entropy pool. + * @size: length of buffer + */ +void add_bootloader_randomness(const void *buf, unsigned int size) +{ + if (IS_ENABLED(CONFIG_RANDOM_TRUST_BOOTLOADER)) + add_hwgenerator_randomness(buf, size, size * 8); + else + add_device_randomness(buf, size); +} +EXPORT_SYMBOL_GPL(add_bootloader_randomness); + +/* + * Callback for HID layer -- use the HID event values to stir the entropy pool + */ +void add_input_randomness(unsigned int type, unsigned int code, + unsigned int value) +{ + static unsigned char last_value; + + /* ignore autorepeat and the like */ + if (value == last_value) + return; + + last_value = value; + + lrng_pcpu_array_add_u32((type << 4) ^ code ^ (code >> 4) ^ value); +} +EXPORT_SYMBOL_GPL(add_input_randomness); + +/** + * add_device_randomness() - Add device- or boot-specific data to the entropy + * pool to help initialize it. + * + * None of this adds any entropy; it is meant to avoid the problem of + * the entropy pool having similar initial state across largely + * identical devices. + * + * @buf: buffer holding the entropic data from HW noise sources to be used to + * insert into entropy pool. + * @size: length of buffer + */ +void add_device_randomness(const void *buf, unsigned int size) +{ + lrng_pool_insert_aux((u8 *)buf, size, 0); +} +EXPORT_SYMBOL(add_device_randomness); + +#ifdef CONFIG_BLOCK +void rand_initialize_disk(struct gendisk *disk) { } +void add_disk_randomness(struct gendisk *disk) { } +EXPORT_SYMBOL(add_disk_randomness); +#endif + +/** + * del_random_ready_callback() - Delete a previously registered readiness + * callback function. + * + * @rdy: callback definition that was registered initially + */ +void del_random_ready_callback(struct random_ready_callback *rdy) +{ + unsigned long flags; + struct module *owner = NULL; + + spin_lock_irqsave(&lrng_ready_list_lock, flags); + if (!list_empty(&rdy->list)) { + list_del_init(&rdy->list); + owner = rdy->owner; + } + spin_unlock_irqrestore(&lrng_ready_list_lock, flags); + + module_put(owner); +} +EXPORT_SYMBOL(del_random_ready_callback); + +/** + * add_random_ready_callback() - Add a callback function that will be invoked + * when the DRNG is mimimally seeded. + * + * @rdy: callback definition to be invoked when the LRNG is seeded + * + * Return: + * * 0 if callback is successfully added + * * -EALREADY if pool is already initialised (callback not called) + * * -ENOENT if module for callback is not alive + */ +int add_random_ready_callback(struct random_ready_callback *rdy) +{ + struct module *owner; + unsigned long flags; + int err = -EALREADY; + + if (likely(lrng_state_min_seeded())) + return err; + + owner = rdy->owner; + if (!try_module_get(owner)) + return -ENOENT; + + spin_lock_irqsave(&lrng_ready_list_lock, flags); + if (lrng_state_min_seeded()) + goto out; + + owner = NULL; + + list_add(&rdy->list, &lrng_ready_list); + err = 0; + +out: + spin_unlock_irqrestore(&lrng_ready_list_lock, flags); + + module_put(owner); + + return err; +} +EXPORT_SYMBOL(add_random_ready_callback); + +/*********************** LRNG kernel output interfaces ************************/ + +/** + * get_random_bytes() - Provider of cryptographic strong random numbers for + * kernel-internal usage. + * + * This function is appropriate for all in-kernel use cases. However, + * it will always use the ChaCha20 DRNG. + * + * @buf: buffer to store the random bytes + * @nbytes: size of the buffer + */ +void get_random_bytes(void *buf, int nbytes) +{ + lrng_drng_get_atomic((u8 *)buf, (u32)nbytes); + lrng_debug_report_seedlevel("get_random_bytes"); +} +EXPORT_SYMBOL(get_random_bytes); + +/** + * get_random_bytes_full() - Provider of cryptographic strong random numbers + * for kernel-internal usage. + * + * This function is appropriate only for non-atomic use cases as this + * function may sleep. Though, it provides access to the full functionality + * of LRNG including the switchable DRNG support, that may support other + * DRNGs such as the SP800-90A DRBG. + * + * @buf: buffer to store the random bytes + * @nbytes: size of the buffer + */ +void get_random_bytes_full(void *buf, int nbytes) +{ + lrng_drng_get_sleep((u8 *)buf, (u32)nbytes); + lrng_debug_report_seedlevel("get_random_bytes_full"); +} +EXPORT_SYMBOL(get_random_bytes_full); + +/** + * wait_for_random_bytes() - Wait for the LRNG to be seeded and thus + * guaranteed to supply cryptographically secure random numbers. + * + * This applies to: the /dev/urandom device, the get_random_bytes function, + * and the get_random_{u32,u64,int,long} family of functions. Using any of + * these functions without first calling this function forfeits the guarantee + * of security. + * + * Return: + * * 0 if the LRNG has been seeded. + * * -ERESTARTSYS if the function was interrupted by a signal. + */ +int wait_for_random_bytes(void) +{ + if (likely(lrng_state_min_seeded())) + return 0; + return wait_event_interruptible(lrng_init_wait, + lrng_state_min_seeded()); +} +EXPORT_SYMBOL(wait_for_random_bytes); + +/** + * get_random_bytes_arch() - This function will use the architecture-specific + * hardware random number generator if it is available. + * + * The arch-specific hw RNG will almost certainly be faster than what we can + * do in software, but it is impossible to verify that it is implemented + * securely (as opposed, to, say, the AES encryption of a sequence number using + * a key known by the NSA). So it's useful if we need the speed, but only if + * we're willing to trust the hardware manufacturer not to have put in a back + * door. + * + * @buf: buffer allocated by caller to store the random data in + * @nbytes: length of outbuf + * + * Return: number of bytes filled in. + */ +int __must_check get_random_bytes_arch(void *buf, int nbytes) +{ + u8 *p = buf; + + while (nbytes) { + unsigned long v; + int chunk = min_t(int, nbytes, sizeof(unsigned long)); + + if (!arch_get_random_long(&v)) + break; + + memcpy(p, &v, chunk); + p += chunk; + nbytes -= chunk; + } + + if (nbytes) + lrng_drng_get_atomic((u8 *)p, (u32)nbytes); + + return nbytes; +} +EXPORT_SYMBOL(get_random_bytes_arch); + +/* + * Returns whether or not the LRNG has been seeded. + * + * Returns: true if the urandom pool has been seeded. + * false if the urandom pool has not been seeded. + */ +bool rng_is_initialized(void) +{ + return lrng_state_operational(); +} +EXPORT_SYMBOL(rng_is_initialized); + +/************************ LRNG user output interfaces *************************/ + +static ssize_t lrng_read_common(char __user *buf, size_t nbytes) +{ + ssize_t ret = 0; + u8 tmpbuf[LRNG_DRNG_BLOCKSIZE] __aligned(LRNG_KCAPI_ALIGN); + u8 *tmp_large = NULL, *tmp = tmpbuf; + u32 tmplen = sizeof(tmpbuf); + + if (nbytes == 0) + return 0; + + /* + * Satisfy large read requests -- as the common case are smaller + * request sizes, such as 16 or 32 bytes, avoid a kmalloc overhead for + * those by using the stack variable of tmpbuf. + */ + if (!CONFIG_BASE_SMALL && (nbytes > sizeof(tmpbuf))) { + tmplen = min_t(u32, nbytes, LRNG_DRNG_MAX_REQSIZE); + tmp_large = kmalloc(tmplen + LRNG_KCAPI_ALIGN, GFP_KERNEL); + if (!tmp_large) + tmplen = sizeof(tmpbuf); + else + tmp = PTR_ALIGN(tmp_large, LRNG_KCAPI_ALIGN); + } + + while (nbytes) { + u32 todo = min_t(u32, nbytes, tmplen); + int rc = 0; + + /* Reschedule if we received a large request. */ + if ((tmp_large) && need_resched()) { + if (signal_pending(current)) { + if (ret == 0) + ret = -ERESTARTSYS; + break; + } + schedule(); + } + + rc = lrng_drng_get_sleep(tmp, todo); + if (rc <= 0) { + if (rc < 0) + ret = rc; + break; + } + if (copy_to_user(buf, tmp, rc)) { + ret = -EFAULT; + break; + } + + nbytes -= rc; + buf += rc; + ret += rc; + } + + /* Wipe data just returned from memory */ + if (tmp_large) + kfree_sensitive(tmp_large); + else + memzero_explicit(tmpbuf, sizeof(tmpbuf)); + + return ret; +} + +static ssize_t +lrng_read_common_block(int nonblock, char __user *buf, size_t nbytes) +{ + if (nbytes == 0) + return 0; + + if (unlikely(!lrng_state_operational())) { + int ret; + + if (nonblock) + return -EAGAIN; + + ret = wait_event_interruptible(lrng_init_wait, + lrng_state_operational()); + if (unlikely(ret)) + return ret; + } + + return lrng_read_common(buf, nbytes); +} + +static ssize_t lrng_drng_read_block(struct file *file, char __user *buf, + size_t nbytes, loff_t *ppos) +{ + return lrng_read_common_block(file->f_flags & O_NONBLOCK, buf, nbytes); +} + +static __poll_t lrng_random_poll(struct file *file, poll_table *wait) +{ + __poll_t mask; + + poll_wait(file, &lrng_init_wait, wait); + poll_wait(file, &lrng_write_wait, wait); + mask = 0; + if (lrng_state_operational()) + mask |= EPOLLIN | EPOLLRDNORM; + if (lrng_need_entropy() || + lrng_state_exseed_allow(lrng_noise_source_user)) + mask |= EPOLLOUT | EPOLLWRNORM; + return mask; +} + +static ssize_t lrng_drng_write_common(const char __user *buffer, size_t count, + u32 entropy_bits) +{ + ssize_t ret = 0; + u8 buf[64] __aligned(LRNG_KCAPI_ALIGN); + const char __user *p = buffer; + u32 orig_entropy_bits = entropy_bits; + + if (!lrng_get_available()) + return -EAGAIN; + + count = min_t(size_t, count, INT_MAX); + while (count > 0) { + size_t bytes = min_t(size_t, count, sizeof(buf)); + u32 ent = min_t(u32, bytes<<3, entropy_bits); + + if (copy_from_user(&buf, p, bytes)) + return -EFAULT; + /* Inject data into entropy pool */ + lrng_pool_insert_aux(buf, bytes, ent); + + count -= bytes; + p += bytes; + ret += bytes; + entropy_bits -= ent; + + cond_resched(); + } + + /* Force reseed of DRNG during next data request. */ + if (!orig_entropy_bits) + lrng_drng_force_reseed(); + + return ret; +} + +static ssize_t lrng_drng_read(struct file *file, char __user *buf, + size_t nbytes, loff_t *ppos) +{ + if (!lrng_state_min_seeded()) + pr_notice_ratelimited("%s - use of insufficiently seeded DRNG (%zu bytes read)\n", + current->comm, nbytes); + else if (!lrng_state_operational()) + pr_debug_ratelimited("%s - use of not fully seeded DRNG (%zu bytes read)\n", + current->comm, nbytes); + + return lrng_read_common(buf, nbytes); +} + +static ssize_t lrng_drng_write(struct file *file, const char __user *buffer, + size_t count, loff_t *ppos) +{ + return lrng_drng_write_common(buffer, count, 0); +} + +static long lrng_ioctl(struct file *f, unsigned int cmd, unsigned long arg) +{ + u32 digestsize_bits; + int size, ent_count_bits; + int __user *p = (int __user *)arg; + + switch (cmd) { + case RNDGETENTCNT: + ent_count_bits = lrng_avail_entropy(); + if (put_user(ent_count_bits, p)) + return -EFAULT; + return 0; + case RNDADDTOENTCNT: + if (!capable(CAP_SYS_ADMIN)) + return -EPERM; + if (get_user(ent_count_bits, p)) + return -EFAULT; + ent_count_bits = (int)lrng_avail_entropy() + ent_count_bits; + if (ent_count_bits < 0) + ent_count_bits = 0; + digestsize_bits = lrng_get_digestsize(); + if (ent_count_bits > digestsize_bits) + ent_count_bits = digestsize_bits; + lrng_pool_set_entropy(ent_count_bits); + return 0; + case RNDADDENTROPY: + if (!capable(CAP_SYS_ADMIN)) + return -EPERM; + if (get_user(ent_count_bits, p++)) + return -EFAULT; + if (ent_count_bits < 0) + return -EINVAL; + if (get_user(size, p++)) + return -EFAULT; + if (size < 0) + return -EINVAL; + lrng_state_exseed_set(lrng_noise_source_user, false); + /* there cannot be more entropy than data */ + ent_count_bits = min(ent_count_bits, size<<3); + return lrng_drng_write_common((const char __user *)p, size, + ent_count_bits); + case RNDZAPENTCNT: + case RNDCLEARPOOL: + /* Clear the entropy pool counter. */ + if (!capable(CAP_SYS_ADMIN)) + return -EPERM; + lrng_pool_set_entropy(0); + return 0; + case RNDRESEEDCRNG: + /* + * We leave the capability check here since it is present + * in the upstream's RNG implementation. Yet, user space + * can trigger a reseed as easy as writing into /dev/random + * or /dev/urandom where no privilege is needed. + */ + if (!capable(CAP_SYS_ADMIN)) + return -EPERM; + /* Force a reseed of all DRNGs */ + lrng_drng_force_reseed(); + return 0; + default: + return -EINVAL; + } +} + +static int lrng_fasync(int fd, struct file *filp, int on) +{ + return fasync_helper(fd, filp, on, &fasync); +} + +const struct file_operations random_fops = { + .read = lrng_drng_read_block, + .write = lrng_drng_write, + .poll = lrng_random_poll, + .unlocked_ioctl = lrng_ioctl, + .compat_ioctl = compat_ptr_ioctl, + .fasync = lrng_fasync, + .llseek = noop_llseek, +}; + +const struct file_operations urandom_fops = { + .read = lrng_drng_read, + .write = lrng_drng_write, + .unlocked_ioctl = lrng_ioctl, + .compat_ioctl = compat_ptr_ioctl, + .fasync = lrng_fasync, + .llseek = noop_llseek, +}; + +SYSCALL_DEFINE3(getrandom, char __user *, buf, size_t, count, + unsigned int, flags) +{ + if (flags & ~(GRND_NONBLOCK|GRND_RANDOM|GRND_INSECURE)) + return -EINVAL; + + /* + * Requesting insecure and blocking randomness at the same time makes + * no sense. + */ + if ((flags & + (GRND_INSECURE|GRND_RANDOM)) == (GRND_INSECURE|GRND_RANDOM)) + return -EINVAL; + + if (count > INT_MAX) + count = INT_MAX; + + if (flags & GRND_INSECURE) + return lrng_drng_read(NULL, buf, count, NULL); + + return lrng_read_common_block(flags & GRND_NONBLOCK, buf, count); +} diff --git a/drivers/char/lrng/lrng_internal.h b/drivers/char/lrng/lrng_internal.h new file mode 100644 index 000000000000..f9b80ce42341 --- /dev/null +++ b/drivers/char/lrng/lrng_internal.h @@ -0,0 +1,420 @@ +/* SPDX-License-Identifier: GPL-2.0 OR BSD-2-Clause */ +/* + * Copyright (C) 2018 - 2020, Stephan Mueller + */ + +#ifndef _LRNG_INTERNAL_H +#define _LRNG_INTERNAL_H + +#include +#include +#include +#include +#include + +/*************************** General LRNG parameter ***************************/ + +/* Security strength of LRNG -- this must match DRNG security strength */ +#define LRNG_DRNG_SECURITY_STRENGTH_BYTES 32 +#define LRNG_DRNG_SECURITY_STRENGTH_BITS (LRNG_DRNG_SECURITY_STRENGTH_BYTES * 8) +#define LRNG_DRNG_BLOCKSIZE 64 /* Maximum of DRNG block sizes */ + +/* + * SP800-90A defines a maximum request size of 1<<16 bytes. The given value is + * considered a safer margin. + * + * This value is allowed to be changed. + */ +#define LRNG_DRNG_MAX_REQSIZE (1<<12) + +/* + * SP800-90A defines a maximum number of requests between reseeds of 2^48. + * The given value is considered a much safer margin, balancing requests for + * frequent reseeds with the need to conserve entropy. This value MUST NOT be + * larger than INT_MAX because it is used in an atomic_t. + * + * This value is allowed to be changed. + */ +#define LRNG_DRNG_RESEED_THRESH (1<<20) + +/* + * Number of interrupts to be recorded to assume that DRNG security strength + * bits of entropy are received. + * Note: a value below the DRNG security strength should not be defined as this + * may imply the DRNG can never be fully seeded in case other noise + * sources are unavailable. + * + * This value is allowed to be changed. + */ +#define LRNG_IRQ_ENTROPY_BITS LRNG_DRNG_SECURITY_STRENGTH_BITS + +/* + * Min required seed entropy is 128 bits covering the minimum entropy + * requirement of SP800-131A and the German BSI's TR02102. + * + * This value is allowed to be changed. + */ +#define LRNG_FULL_SEED_ENTROPY_BITS LRNG_DRNG_SECURITY_STRENGTH_BITS +#define LRNG_MIN_SEED_ENTROPY_BITS 128 +#define LRNG_INIT_ENTROPY_BITS 32 + +/* + * Wakeup value + * + * This value is allowed to be changed but must not be larger than the + * digest size of the hash operation used update the aux_pool. + */ +#ifdef CONFIG_CRYPTO_LIB_SHA256 +# define LRNG_ATOMIC_DIGEST_SIZE SHA256_DIGEST_SIZE +#else +# define LRNG_ATOMIC_DIGEST_SIZE SHA1_DIGEST_SIZE +#endif +#define LRNG_WRITE_WAKEUP_ENTROPY LRNG_ATOMIC_DIGEST_SIZE + +/* + * If the switching support is configured, we must provide support up to + * the largest digest size. Without switching support, we know it is only + * the built-in digest size. + */ +#ifdef CONFIG_LRNG_DRNG_SWITCH +# define LRNG_MAX_DIGESTSIZE 64 +#else +# define LRNG_MAX_DIGESTSIZE LRNG_ATOMIC_DIGEST_SIZE +#endif + +/* + * Oversampling factor of IRQ events to obtain + * LRNG_DRNG_SECURITY_STRENGTH_BYTES. This factor is used when a + * high-resolution time stamp is not available. In this case, jiffies and + * register contents are used to fill the entropy pool. These noise sources + * are much less entropic than the high-resolution timer. The entropy content + * is the entropy content assumed with LRNG_IRQ_ENTROPY_BITS divided by + * LRNG_IRQ_OVERSAMPLING_FACTOR. + * + * This value is allowed to be changed. + */ +#define LRNG_IRQ_OVERSAMPLING_FACTOR 10 + +/* + * Alignmask which should cover all cipher implementations + * WARNING: If this is changed to a value larger than 8, manual + * alignment is necessary as older versions of GCC may not be capable + * of aligning stack variables at boundaries greater than 8. + * In this case, PTR_ALIGN must be used. + */ +#define LRNG_KCAPI_ALIGN 8 + +/************************ Default DRNG implementation *************************/ + +extern struct chacha20_state chacha20; +extern const struct lrng_crypto_cb lrng_cc20_crypto_cb; +void lrng_cc20_init_state(struct chacha20_state *state); +void lrng_cc20_init_state_boot(struct chacha20_state *state); + +/********************************** /proc *************************************/ + +static inline void lrng_pool_inc_numa_node(void) { } + +/****************************** LRNG interfaces *******************************/ + +extern u32 lrng_write_wakeup_bits; +extern int lrng_drng_reseed_max_time; + +void lrng_writer_wakeup(void); +void lrng_init_wakeup(void); +void lrng_debug_report_seedlevel(const char *name); +void lrng_process_ready_list(void); + +/* External interface to use of the switchable DRBG inside the kernel */ +void get_random_bytes_full(void *buf, int nbytes); + +/************************** Jitter RNG Noise Source ***************************/ + +#ifdef CONFIG_LRNG_JENT +u32 lrng_get_jent(u8 *outbuf, unsigned int outbuflen); +u32 lrng_jent_entropylevel(void); +#else /* CONFIG_CRYPTO_JITTERENTROPY */ +static inline u32 lrng_get_jent(u8 *outbuf, unsigned int outbuflen) {return 0; } +static inline u32 lrng_jent_entropylevel(void) { return 0; } +#endif /* CONFIG_CRYPTO_JITTERENTROPY */ + +/*************************** CPU-based Noise Source ***************************/ + +u32 lrng_get_arch(u8 *outbuf); +u32 lrng_slow_noise_req_entropy(u32 required_entropy_bits); + +/****************************** DRNG processing *******************************/ + +/* Secondary DRNG state handle */ +struct lrng_drng { + void *drng; /* DRNG handle */ + void *hash; /* Hash handle */ + const struct lrng_crypto_cb *crypto_cb; /* Crypto callbacks */ + atomic_t requests; /* Number of DRNG requests */ + unsigned long last_seeded; /* Last time it was seeded */ + bool fully_seeded; /* Is DRNG fully seeded? */ + bool force_reseed; /* Force a reseed */ + + /* Lock write operations on DRNG state, DRNG replacement of crypto_cb */ + struct mutex lock; + spinlock_t spin_lock; + /* Lock hash replacement of crypto_cb */ + rwlock_t hash_lock; +}; + +extern struct mutex lrng_crypto_cb_update; + +struct lrng_drng *lrng_drng_init_instance(void); +struct lrng_drng *lrng_drng_atomic_instance(void); + +static __always_inline bool lrng_drng_is_atomic(struct lrng_drng *drng) +{ + return (drng->drng == lrng_drng_atomic_instance()->drng); +} + +/* Lock the DRNG */ +static __always_inline void lrng_drng_lock(struct lrng_drng *drng, + unsigned long *flags) + __acquires(&drng->spin_lock) +{ + /* Use spin lock in case the atomic DRNG context is used */ + if (lrng_drng_is_atomic(drng)) { + spin_lock_irqsave(&drng->spin_lock, *flags); + + /* + * In case a lock transition happened while we were spinning, + * catch this case and use the new lock type. + */ + if (!lrng_drng_is_atomic(drng)) { + spin_unlock_irqrestore(&drng->spin_lock, *flags); + __acquire(&drng->spin_lock); + mutex_lock(&drng->lock); + } + } else { + __acquire(&drng->spin_lock); + mutex_lock(&drng->lock); + } +} + +/* Unlock the DRNG */ +static __always_inline void lrng_drng_unlock(struct lrng_drng *drng, + unsigned long *flags) + __releases(&drng->spin_lock) +{ + if (lrng_drng_is_atomic(drng)) { + spin_unlock_irqrestore(&drng->spin_lock, *flags); + } else { + mutex_unlock(&drng->lock); + __release(&drng->spin_lock); + } +} + +void lrng_reset(void); +void lrng_drng_init_early(void); +bool lrng_get_available(void); +void lrng_set_available(void); +void lrng_drng_reset(struct lrng_drng *drng); +int lrng_drng_get_atomic(u8 *outbuf, u32 outbuflen); +int lrng_drng_get_sleep(u8 *outbuf, u32 outbuflen); +void lrng_drng_force_reseed(void); +void lrng_drng_seed_work(struct work_struct *dummy); + +static inline struct lrng_drng **lrng_drng_instances(void) { return NULL; } +static inline void lrng_drngs_numa_alloc(void) { return; } + +/************************** Entropy pool management ***************************/ + +enum lrng_external_noise_source { + lrng_noise_source_hw, + lrng_noise_source_user +}; + +/* Status information about IRQ noise source */ +struct lrng_irq_info { + atomic_t num_events_thresh; /* Reseed threshold */ + atomic_t reseed_in_progress; /* Flag for on executing reseed */ + bool irq_highres_timer; /* Is high-resolution timer available? */ + u32 irq_entropy_bits; /* LRNG_IRQ_ENTROPY_BITS? */ +}; + +/* + * This is the entropy pool used by the slow noise source. Its size should + * be at least as large as LRNG_DRNG_SECURITY_STRENGTH_BITS. + * + * The aux pool array is aligned to 8 bytes to comfort the kernel crypto API + * cipher implementations of the hash functions used to read the pool: for some + * accelerated implementations, we need an alignment to avoid a realignment + * which involves memcpy(). The alignment to 8 bytes should satisfy all crypto + * implementations. + */ +struct lrng_pool { + /* + * Storage for aux data - hash output buffer + */ + u8 aux_pool[LRNG_MAX_DIGESTSIZE]; + atomic_t aux_entropy_bits; + /* All NUMA DRNGs seeded? */ + bool all_online_numa_node_seeded; + + /* Digest size of used hash */ + atomic_t digestsize; + /* IRQ noise source status info */ + struct lrng_irq_info irq_info; + + /* Serialize read of entropy pool and update of aux pool */ + spinlock_t lock; +}; + +u32 lrng_entropy_to_data(u32 entropy_bits); +u32 lrng_data_to_entropy(u32 irqnum); +u32 lrng_avail_aux_entropy(void); +void lrng_set_digestsize(u32 digestsize); +u32 lrng_get_digestsize(void); + +/* Obtain the security strength of the LRNG in bits */ +static inline u32 lrng_security_strength(void) +{ + /* + * We use a hash to read the entropy in the entropy pool. According to + * SP800-90B table 1, the entropy can be at most the digest size. + * Considering this together with the last sentence in section 3.1.5.1.2 + * the security strength of a (approved) hash is equal to its output + * size. On the other hand the entropy cannot be larger than the + * security strength of the used DRBG. + */ + return min_t(u32, LRNG_FULL_SEED_ENTROPY_BITS, + lrng_get_digestsize()); +} + +void lrng_set_entropy_thresh(u32 new); +void lrng_reset_state(void); + +void lrng_pcpu_reset(void); +u32 lrng_pcpu_avail_irqs(void); + +static inline u32 lrng_pcpu_avail_entropy(void) +{ + return lrng_data_to_entropy(lrng_pcpu_avail_irqs()); +} + +static inline u32 lrng_avail_entropy(void) +{ + return lrng_pcpu_avail_entropy() + lrng_avail_aux_entropy(); +} + +u32 lrng_pcpu_pool_hash(struct lrng_drng *drng, struct lrng_pool *pool, + u8 *outbuf, u32 requested_bits, bool fully_seeded); +void lrng_pcpu_array_add_u32(u32 data); + +bool lrng_state_exseed_allow(enum lrng_external_noise_source source); +void lrng_state_exseed_set(enum lrng_external_noise_source source, bool type); +void lrng_state_init_seed_work(void); +bool lrng_state_min_seeded(void); +bool lrng_state_fully_seeded(void); +bool lrng_state_operational(void); + +int lrng_pool_trylock(void); +void lrng_pool_unlock(void); +void lrng_pool_all_numa_nodes_seeded(void); +bool lrng_pool_highres_timer(void); +void lrng_pool_set_entropy(u32 entropy_bits); +int lrng_pool_insert_aux(const u8 *inbuf, u32 inbuflen, u32 entropy_bits); +void lrng_pool_add_irq(void); + +struct entropy_buf { + u8 a[LRNG_DRNG_SECURITY_STRENGTH_BYTES]; + u8 b[LRNG_DRNG_SECURITY_STRENGTH_BYTES]; + u8 c[LRNG_DRNG_SECURITY_STRENGTH_BYTES]; + u32 now; +}; + +int lrng_fill_seed_buffer(struct lrng_drng *drng, + struct entropy_buf *entropy_buf); +void lrng_init_ops(u32 seed_bits); + +/************************** Health Test linking code **************************/ + +enum lrng_health_res { + lrng_health_pass, /* Health test passes on time stamp */ + lrng_health_fail_use, /* Time stamp unhealthy, but mix in */ + lrng_health_fail_drop /* Time stamp unhealthy, drop it */ +}; + +#ifdef CONFIG_LRNG_HEALTH_TESTS +bool lrng_sp80090b_startup_complete(void); +bool lrng_sp80090b_compliant(void); + +enum lrng_health_res lrng_health_test(u32 now_time); +void lrng_health_disable(void); + +#else /* CONFIG_LRNG_HEALTH_TESTS */ +static inline bool lrng_sp80090b_startup_complete(void) { return true; } +static inline bool lrng_sp80090b_compliant(void) { return false; } + +static inline enum lrng_health_res +lrng_health_test(u32 now_time) { return lrng_health_pass; } +static inline void lrng_health_disable(void) { } +#endif /* CONFIG_LRNG_HEALTH_TESTS */ + +/****************************** Helper code ***********************************/ + +static inline u32 atomic_read_u32(atomic_t *v) +{ + return (u32)atomic_read(v); +} + +/*************************** Auxiliary functions ******************************/ + +void invalidate_batched_entropy(void); + +/***************************** Testing code ***********************************/ + +#ifdef CONFIG_LRNG_RAW_HIRES_ENTROPY +bool lrng_raw_hires_entropy_store(u32 value); +#else /* CONFIG_LRNG_RAW_HIRES_ENTROPY */ +static inline bool lrng_raw_hires_entropy_store(u32 value) { return false; } +#endif /* CONFIG_LRNG_RAW_HIRES_ENTROPY */ + +#ifdef CONFIG_LRNG_RAW_JIFFIES_ENTROPY +bool lrng_raw_jiffies_entropy_store(u32 value); +#else /* CONFIG_LRNG_RAW_JIFFIES_ENTROPY */ +static inline bool lrng_raw_jiffies_entropy_store(u32 value) { return false; } +#endif /* CONFIG_LRNG_RAW_JIFFIES_ENTROPY */ + +#ifdef CONFIG_LRNG_RAW_IRQ_ENTROPY +bool lrng_raw_irq_entropy_store(u32 value); +#else /* CONFIG_LRNG_RAW_IRQ_ENTROPY */ +static inline bool lrng_raw_irq_entropy_store(u32 value) { return false; } +#endif /* CONFIG_LRNG_RAW_IRQ_ENTROPY */ + +#ifdef CONFIG_LRNG_RAW_IRQFLAGS_ENTROPY +bool lrng_raw_irqflags_entropy_store(u32 value); +#else /* CONFIG_LRNG_RAW_IRQFLAGS_ENTROPY */ +static inline bool lrng_raw_irqflags_entropy_store(u32 value) { return false; } +#endif /* CONFIG_LRNG_RAW_IRQFLAGS_ENTROPY */ + +#ifdef CONFIG_LRNG_RAW_RETIP_ENTROPY +bool lrng_raw_retip_entropy_store(u32 value); +#else /* CONFIG_LRNG_RAW_RETIP_ENTROPY */ +static inline bool lrng_raw_retip_entropy_store(u32 value) { return false; } +#endif /* CONFIG_LRNG_RAW_RETIP_ENTROPY */ + +#ifdef CONFIG_LRNG_RAW_REGS_ENTROPY +bool lrng_raw_regs_entropy_store(u32 value); +#else /* CONFIG_LRNG_RAW_REGS_ENTROPY */ +static inline bool lrng_raw_regs_entropy_store(u32 value) { return false; } +#endif /* CONFIG_LRNG_RAW_REGS_ENTROPY */ + +#ifdef CONFIG_LRNG_RAW_ARRAY +bool lrng_raw_array_entropy_store(u32 value); +#else /* CONFIG_LRNG_RAW_ARRAY */ +static inline bool lrng_raw_array_entropy_store(u32 value) { return false; } +#endif /* CONFIG_LRNG_RAW_ARRAY */ + +#ifdef CONFIG_LRNG_IRQ_PERF +bool lrng_perf_time(u32 start); +#else /* CONFIG_LRNG_IRQ_PERF */ +static inline bool lrng_perf_time(u32 start) { return false; } +#endif /*CONFIG_LRNG_IRQ_PERF */ + +#endif /* _LRNG_INTERNAL_H */ diff --git a/drivers/char/lrng/lrng_pool.c b/drivers/char/lrng/lrng_pool.c new file mode 100644 index 000000000000..4a7cc94884e4 --- /dev/null +++ b/drivers/char/lrng/lrng_pool.c @@ -0,0 +1,457 @@ +// SPDX-License-Identifier: GPL-2.0 OR BSD-2-Clause +/* + * LRNG Entropy pool management + * + * Copyright (C) 2016 - 2020, Stephan Mueller + */ + +#define pr_fmt(fmt) KBUILD_MODNAME ": " fmt + +#include +#include +#include +#include +#include +#include + +#include "lrng_internal.h" + +struct lrng_state { + bool lrng_operational; /* Is DRNG operational? */ + bool lrng_fully_seeded; /* Is DRNG fully seeded? */ + bool lrng_min_seeded; /* Is DRNG minimally seeded? */ + + /* + * To ensure that external entropy providers cannot dominate the + * internal noise sources but yet cannot be dominated by internal + * noise sources, the following booleans are intended to allow + * external to provide seed once when a DRNG reseed occurs. This + * triggering of external noise source is performed even when the + * entropy pool has sufficient entropy. + */ + bool lrng_seed_hw; /* Allow HW to provide seed */ + bool lrng_seed_user; /* Allow user space to provide seed */ + + struct work_struct lrng_seed_work; /* (re)seed work queue */ +}; + +static struct lrng_pool lrng_pool __aligned(LRNG_KCAPI_ALIGN) = { + .aux_entropy_bits = ATOMIC_INIT(0), + .digestsize = ATOMIC_INIT(LRNG_ATOMIC_DIGEST_SIZE), + .irq_info = { + .irq_entropy_bits = LRNG_IRQ_ENTROPY_BITS, + .num_events_thresh = ATOMIC_INIT(LRNG_INIT_ENTROPY_BITS), + /* Sample IRQ pointer data at least during boot */ + .irq_highres_timer = false }, + .lock = __SPIN_LOCK_UNLOCKED(lrng_pool.lock) +}; + +static struct lrng_state lrng_state = { false, false, false, true, true }; + +/********************************** Helper ***********************************/ + +/* External entropy provider is allowed to provide seed data */ +bool lrng_state_exseed_allow(enum lrng_external_noise_source source) +{ + if (source == lrng_noise_source_hw) + return lrng_state.lrng_seed_hw; + return lrng_state.lrng_seed_user; +} + +/* Enable / disable external entropy provider to furnish seed */ +void lrng_state_exseed_set(enum lrng_external_noise_source source, bool type) +{ + if (source == lrng_noise_source_hw) + lrng_state.lrng_seed_hw = type; + else + lrng_state.lrng_seed_user = type; +} + +static inline void lrng_state_exseed_allow_all(void) +{ + lrng_state_exseed_set(lrng_noise_source_hw, true); + lrng_state_exseed_set(lrng_noise_source_user, true); +} + +/* Initialize the seed work queue */ +void lrng_state_init_seed_work(void) +{ + INIT_WORK(&lrng_state.lrng_seed_work, lrng_drng_seed_work); +} + +/* Convert entropy in bits into number of IRQs with the same entropy content. */ +u32 lrng_entropy_to_data(u32 entropy_bits) +{ + return ((entropy_bits * lrng_pool.irq_info.irq_entropy_bits) / + LRNG_DRNG_SECURITY_STRENGTH_BITS); +} + +/* Convert number of IRQs into entropy value. */ +u32 lrng_data_to_entropy(u32 irqnum) +{ + return ((irqnum * LRNG_DRNG_SECURITY_STRENGTH_BITS) / + lrng_pool.irq_info.irq_entropy_bits); +} + +/* Entropy in bits present in aux pool */ +u32 lrng_avail_aux_entropy(void) +{ + /* Cap available entropy with max entropy */ + return min_t(u32, atomic_read_u32(&lrng_pool.digestsize) << 3, + atomic_read_u32(&lrng_pool.aux_entropy_bits)); +} + +/* Set the digest size of the used hash in bytes */ +void lrng_set_digestsize(u32 digestsize) +{ + atomic_set(&lrng_pool.digestsize, digestsize); +} + +/* Obtain the digest size provided by the used hash in bits */ +u32 lrng_get_digestsize(void) +{ + return atomic_read_u32(&lrng_pool.digestsize) << 3; +} + +/* Set new entropy threshold for reseeding during boot */ +void lrng_set_entropy_thresh(u32 new_entropy_bits) +{ + atomic_set(&lrng_pool.irq_info.num_events_thresh, + lrng_entropy_to_data(new_entropy_bits)); +} + +/* + * Reading of the LRNG pool is only allowed by one caller. The reading is + * only performed to (re)seed DRNGs. Thus, if this "lock" is already taken, + * the reseeding operation is in progress. The caller is not intended to wait + * but continue with its other operation. + */ +int lrng_pool_trylock(void) +{ + return atomic_cmpxchg(&lrng_pool.irq_info.reseed_in_progress, 0, 1); +} + +void lrng_pool_unlock(void) +{ + atomic_set(&lrng_pool.irq_info.reseed_in_progress, 0); +} + +/* + * Reset LRNG state - the entropy counters are reset, but the data that may + * or may not have entropy remains in the pools as this data will not hurt. + */ +void lrng_reset_state(void) +{ + atomic_set(&lrng_pool.aux_entropy_bits, 0); + lrng_pcpu_reset(); + lrng_state.lrng_operational = false; + lrng_state.lrng_fully_seeded = false; + lrng_state.lrng_min_seeded = false; + lrng_pool.all_online_numa_node_seeded = false; + pr_debug("reset LRNG\n"); +} + +/* Set flag that all DRNGs are fully seeded */ +void lrng_pool_all_numa_nodes_seeded(void) +{ + lrng_pool.all_online_numa_node_seeded = true; +} + +/* Return boolean whether LRNG reached minimally seed level */ +bool lrng_state_min_seeded(void) +{ + return lrng_state.lrng_min_seeded; +} + +/* Return boolean whether LRNG reached fully seed level */ +bool lrng_state_fully_seeded(void) +{ + return lrng_state.lrng_fully_seeded; +} + +/* Return boolean whether LRNG is considered fully operational */ +bool lrng_state_operational(void) +{ + return lrng_state.lrng_operational; +} + +/* Return boolean whether LRNG identified presence of high-resolution timer */ +bool lrng_pool_highres_timer(void) +{ + return lrng_pool.irq_info.irq_highres_timer; +} + +/* Set entropy content in user-space controllable aux pool */ +void lrng_pool_set_entropy(u32 entropy_bits) +{ + atomic_set(&lrng_pool.aux_entropy_bits, entropy_bits); +} + +static void lrng_pool_configure(bool highres_timer, u32 irq_entropy_bits) +{ + struct lrng_irq_info *irq_info = &lrng_pool.irq_info; + + irq_info->irq_highres_timer = highres_timer; + if (irq_info->irq_entropy_bits != irq_entropy_bits) { + irq_info->irq_entropy_bits = irq_entropy_bits; + /* Reset the threshold based on new oversampling factor. */ + lrng_set_entropy_thresh(atomic_read_u32( + &irq_info->num_events_thresh)); + } +} + +static int __init lrng_init_time_source(void) +{ + if (random_get_entropy() || random_get_entropy()) { + /* + * As the highres timer is identified here, previous interrupts + * obtained during boot time are treated like a lowres-timer + * would have been present. + */ + lrng_pool_configure(true, LRNG_IRQ_ENTROPY_BITS); + } else { + lrng_health_disable(); + lrng_pool_configure(false, LRNG_IRQ_ENTROPY_BITS * + LRNG_IRQ_OVERSAMPLING_FACTOR); + pr_warn("operating without high-resolution timer and applying IRQ oversampling factor %u\n", + LRNG_IRQ_OVERSAMPLING_FACTOR); + } + + return 0; +} + +core_initcall(lrng_init_time_source); + +/** + * lrng_init_ops() - Set seed stages of LRNG + * + * Set the slow noise source reseed trigger threshold. The initial threshold + * is set to the minimum data size that can be read from the pool: a word. Upon + * reaching this value, the next seed threshold of 128 bits is set followed + * by 256 bits. + * + * @entropy_bits: size of entropy currently injected into DRNG + */ +void lrng_init_ops(u32 seed_bits) +{ + struct lrng_state *state = &lrng_state; + + if (state->lrng_operational) + return; + + /* DRNG is seeded with full security strength */ + if (state->lrng_fully_seeded) { + state->lrng_operational = lrng_sp80090b_startup_complete(); + lrng_process_ready_list(); + lrng_init_wakeup(); + } else if (seed_bits >= lrng_security_strength()) { + invalidate_batched_entropy(); + state->lrng_fully_seeded = true; + state->lrng_operational = lrng_sp80090b_startup_complete(); + state->lrng_min_seeded = true; + pr_info("LRNG fully seeded with %u bits of entropy\n", + seed_bits); + lrng_set_entropy_thresh(lrng_security_strength()); + lrng_process_ready_list(); + lrng_init_wakeup(); + + } else if (!state->lrng_min_seeded) { + + /* DRNG is seeded with at least 128 bits of entropy */ + if (seed_bits >= LRNG_MIN_SEED_ENTROPY_BITS) { + invalidate_batched_entropy(); + state->lrng_min_seeded = true; + pr_info("LRNG minimally seeded with %u bits of entropy\n", + seed_bits); + lrng_set_entropy_thresh( + lrng_slow_noise_req_entropy( + lrng_security_strength())); + lrng_process_ready_list(); + lrng_init_wakeup(); + + /* DRNG is seeded with at least LRNG_INIT_ENTROPY_BITS bits */ + } else if (seed_bits >= LRNG_INIT_ENTROPY_BITS) { + pr_info("LRNG initial entropy level %u bits of entropy\n", + seed_bits); + lrng_set_entropy_thresh( + lrng_slow_noise_req_entropy( + LRNG_MIN_SEED_ENTROPY_BITS)); + } + } +} + +int __init rand_initialize(void) +{ + struct seed { + ktime_t time; + unsigned long data[(LRNG_MAX_DIGESTSIZE / + sizeof(unsigned long))]; + struct new_utsname utsname; + } seed __aligned(LRNG_KCAPI_ALIGN); + unsigned int i; + + lrng_drng_init_early(); + + BUILD_BUG_ON(LRNG_MAX_DIGESTSIZE % sizeof(unsigned long)); + + seed.time = ktime_get_real(); + + for (i = 0; i < ARRAY_SIZE(seed.data); i++) { + if (!arch_get_random_seed_long_early(&(seed.data[i])) && + !arch_get_random_long_early(&seed.data[i])) + seed.data[i] = random_get_entropy(); + } + memcpy(&seed.utsname, utsname(), sizeof(*(utsname()))); + + lrng_pool_insert_aux((u8 *)&seed, sizeof(seed), 0); + memzero_explicit(&seed, sizeof(seed)); + + return 0; +} + +/* + * Insert data into auxiliary pool by hashing the input data together with + * the auxiliary pool. The message digest is the new state of the auxiliary + * pool. + */ +int lrng_pool_insert_aux(const u8 *inbuf, u32 inbuflen, u32 entropy_bits) +{ + SHASH_DESC_ON_STACK(shash, NULL); + struct lrng_drng *drng = lrng_drng_init_instance(); + const struct lrng_crypto_cb *crypto_cb; + struct lrng_pool *pool = &lrng_pool; + unsigned long flags, flags2; + void *hash; + u32 digestsize; + int ret; + + if (entropy_bits > (inbuflen << 3)) + entropy_bits = (inbuflen << 3); + + read_lock_irqsave(&drng->hash_lock, flags); + + crypto_cb = drng->crypto_cb; + hash = drng->hash; + digestsize = crypto_cb->lrng_hash_digestsize(hash); + + spin_lock_irqsave(&pool->lock, flags2); + ret = crypto_cb->lrng_hash_init(shash, hash) ?: + /* Hash auxiliary pool ... */ + crypto_cb->lrng_hash_update(shash, pool->aux_pool, digestsize) ?: + /* ... together with input data ... */ + crypto_cb->lrng_hash_update(shash, inbuf, inbuflen) ?: + /* ... to form mew auxiliary pool state. */ + crypto_cb->lrng_hash_final(shash, pool->aux_pool); + if (ret) + goto out; + + /* + * Cap the available entropy to the hash output size compliant to + * SP800-90B section 3.1.5.1 table 1. + */ + entropy_bits += atomic_read_u32(&pool->aux_entropy_bits); + if (entropy_bits > digestsize << 3) + entropy_bits = digestsize << 3; + atomic_set(&pool->aux_entropy_bits, entropy_bits); + +out: + spin_unlock_irqrestore(&pool->lock, flags2); + read_unlock_irqrestore(&drng->hash_lock, flags); + + return ret; +} + +/* Hot code path during boot - mix data into entropy pool during boot */ +void lrng_pool_add_irq(void) +{ + /* + * Once all DRNGs are fully seeded, the interrupt noise + * sources will not trigger any reseeding any more. + */ + if (likely(lrng_pool.all_online_numa_node_seeded)) + return; + + /* Only try to reseed if the DRNG is alive. */ + if (!lrng_get_available()) + return; + + /* Only trigger the DRNG reseed if we have collected enough IRQs. */ + if (lrng_pcpu_avail_irqs() < + atomic_read_u32(&lrng_pool.irq_info.num_events_thresh)) + return; + + /* Ensure that the seeding only occurs once at any given time. */ + if (lrng_pool_trylock()) + return; + + /* Seed the DRNG with IRQ noise. */ + schedule_work(&lrng_state.lrng_seed_work); +} + +/************************* Get data from entropy pool *************************/ + +static u32 lrng_get_pool(struct lrng_drng *drng, u8 *outbuf, + u32 requested_entropy_bits) +{ + struct lrng_pool *pool = &lrng_pool; + struct lrng_state *state = &lrng_state; + unsigned long flags; + + /* We operate on the non-atomic part of the pool */ + spin_lock_irqsave(&pool->lock, flags); + requested_entropy_bits = lrng_pcpu_pool_hash(drng, &lrng_pool, + outbuf, + requested_entropy_bits, + state->lrng_fully_seeded); + spin_unlock_irqrestore(&pool->lock, flags); + + return requested_entropy_bits; +} + +/* Fill the seed buffer with data from the noise sources */ +int lrng_fill_seed_buffer(struct lrng_drng *drng, + struct entropy_buf *entropy_buf) +{ + struct lrng_state *state = &lrng_state; + u32 total_entropy_bits = 0; + + /* Guarantee that requested bits is a multiple of bytes */ + BUILD_BUG_ON(LRNG_DRNG_SECURITY_STRENGTH_BITS % 8); + + /* Require at least 128 bits of entropy for any reseed. */ + if (state->lrng_fully_seeded && + (lrng_avail_entropy() < + lrng_slow_noise_req_entropy(LRNG_MIN_SEED_ENTROPY_BITS))) + goto wakeup; + + /* + * Concatenate the output of the noise sources. This would be the + * spot to add an entropy extractor logic if desired. Note, this + * has the ability to collect entropy equal or larger than the DRNG + * strength. + */ + total_entropy_bits = lrng_get_pool(drng, entropy_buf->a, + LRNG_DRNG_SECURITY_STRENGTH_BITS); + total_entropy_bits += lrng_get_arch(entropy_buf->b); + total_entropy_bits += lrng_get_jent(entropy_buf->c, + LRNG_DRNG_SECURITY_STRENGTH_BYTES); + + /* also reseed the DRNG with the current time stamp */ + entropy_buf->now = random_get_entropy(); + + /* allow external entropy provider to provide seed */ + lrng_state_exseed_allow_all(); + +wakeup: + /* + * Shall we wake up user space writers? This location covers + * ensures that the user space provider does not dominate the internal + * noise sources since in case the first call of this function finds + * sufficient entropy in the entropy pool, it will not trigger the + * wakeup. This implies that when the next /dev/urandom read happens, + * the entropy pool is drained. + */ + lrng_writer_wakeup(); + + return total_entropy_bits; +} diff --git a/drivers/char/lrng/lrng_sw_noise.c b/drivers/char/lrng/lrng_sw_noise.c new file mode 100644 index 000000000000..2ea613499dfd --- /dev/null +++ b/drivers/char/lrng/lrng_sw_noise.c @@ -0,0 +1,466 @@ +// SPDX-License-Identifier: GPL-2.0 OR BSD-2-Clause +/* + * LRNG Slow Noise Source: Interrupt data collection and random data generation + * + * Copyright (C) 2016 - 2020, Stephan Mueller + */ + +#define pr_fmt(fmt) KBUILD_MODNAME ": " fmt + +#include +#include +#include +#include +#include + +#include "lrng_internal.h" +#include "lrng_sw_noise.h" + +/* Per-CPU array holding concatenated entropy events */ +static DEFINE_PER_CPU(u32 [LRNG_DATA_ARRAY_SIZE], lrng_pcpu_array) + __aligned(LRNG_KCAPI_ALIGN); +static DEFINE_PER_CPU(u32, lrng_pcpu_array_ptr) = 0; +static DEFINE_PER_CPU(atomic_t, lrng_pcpu_array_irqs) = ATOMIC_INIT(0); + +/* Per-CPU entropy pool with compressed entropy events */ +static DEFINE_PER_CPU(u8 [LRNG_MAX_DIGESTSIZE], lrng_pcpu_pool) + __aligned(LRNG_KCAPI_ALIGN); +/* + * Lock to allow other CPUs to read the pool - as this is only done during + * reseed which is infrequent, this lock is hardly contended. + */ +static DEFINE_PER_CPU(spinlock_t, lrng_pcpu_lock); +static DEFINE_PER_CPU(bool, lrng_pcpu_lock_init) = false; + +static inline bool lrng_pcpu_pool_online(int cpu) +{ + return per_cpu(lrng_pcpu_lock_init, cpu); +} + +/* + * Reset all per-CPU pools - reset entropy estimator but leave the pool data + * that may or may not have entropy unchanged. + */ +void lrng_pcpu_reset(void) +{ + int cpu; + + for_each_online_cpu(cpu) + atomic_set(per_cpu_ptr(&lrng_pcpu_array_irqs, cpu), 0); +} + +/* Return number of unused IRQs present in all per-CPU pools. */ +u32 lrng_pcpu_avail_irqs(void) +{ + u32 digestsize_irqs, irq = 0; + int cpu; + + /* Obtain the cap of maximum numbers of IRQs we count */ + digestsize_irqs = lrng_entropy_to_data(lrng_get_digestsize()); + + for_each_online_cpu(cpu) { + if (!lrng_pcpu_pool_online(cpu)) + continue; + irq += min_t(u32, digestsize_irqs, + atomic_read_u32(per_cpu_ptr(&lrng_pcpu_array_irqs, + cpu))); + } + + return irq; +} + +/** + * Hash all per-CPU pools and the auxiliary pool to form a new auxiliary pool + * state. The message digest is at the same time the new state of the aux pool + * to ensure backtracking resistance and the seed data used for seeding a DRNG. + * The function will only copy as much data as entropy is available into the + * caller-provided output buffer. + * + * This function handles the translation from the number of received interrupts + * into an entropy statement. The conversion depends on LRNG_IRQ_ENTROPY_BITS + * which defines how many interrupts must be received to obtain 256 bits of + * entropy. With this value, the function lrng_data_to_entropy converts a given + * data size (received interrupts, requested amount of data, etc.) into an + * entropy statement. lrng_entropy_to_data does the reverse. + * + * Both functions are agnostic about the type of data: when the number of + * interrupts is processed by these functions, the resulting entropy value is in + * bits as we assume the entropy of interrupts is measured in bits. When data is + * processed, the entropy value is in bytes as the data is measured in bytes. + * + * lrng_pool->lock must be held by caller as we update a non-atomic pool part. + * + * @drng: DRNG state providing the crypto callbacks to use + * @pool: global entropy pool holding the aux pool + * @outbuf: buffer to store data in with size LRNG_DRNG_SECURITY_STRENGTH_BYTES + * @requested_bits: amount of data to be generated + * @fully_seeded: indicator whether LRNG is fully seeded + * @return: amount of collected entropy in bits. + */ +u32 lrng_pcpu_pool_hash(struct lrng_drng *drng, struct lrng_pool *pool, + u8 *outbuf, u32 requested_bits, bool fully_seeded) +{ + SHASH_DESC_ON_STACK(shash, NULL); + const struct lrng_crypto_cb *crypto_cb; + unsigned long flags; + u32 digestsize_bits, found_ent_bits, found_irqs, unused_bits = 0, + collected_ent_bits = 0, collected_irqs = 0, requested_irqs, + digestsize_irqs; + int ret, cpu; + void *hash; + + read_lock_irqsave(&drng->hash_lock, flags); + + crypto_cb = drng->crypto_cb; + hash = drng->hash; + digestsize_bits = crypto_cb->lrng_hash_digestsize(hash) << 3; + digestsize_irqs = lrng_entropy_to_data(digestsize_bits); + + ret = crypto_cb->lrng_hash_init(shash, hash); + if (ret) + goto err; + + /* Deduct entropy counter from aux pool */ + found_ent_bits = atomic_xchg_relaxed(&pool->aux_entropy_bits, 0); + /* Cap entropy by security strength of used digest */ + found_ent_bits = min_t(u32, digestsize_bits, found_ent_bits); + + /* Harvest entropy from aux pool */ + ret = crypto_cb->lrng_hash_update(shash, (u8 *)pool, sizeof(*pool)); + if (ret) + goto err; + + /* We collected that amount of entropy */ + collected_ent_bits += found_ent_bits; + /* We collected too much entropy and put the overflow back */ + if (collected_ent_bits > requested_bits) { + /* Amount of bits we collected too much */ + unused_bits = collected_ent_bits - requested_bits; + + /* Store that for logging */ + found_ent_bits -= unused_bits; + /* Put entropy back */ + atomic_add(found_ent_bits, &pool->aux_entropy_bits); + /* Fix collected entropy */ + collected_ent_bits = requested_bits; + } + pr_debug("%u bits of entropy used from aux pool, %u bits of entropy remaining\n", + found_ent_bits, unused_bits); + + requested_irqs = lrng_entropy_to_data(requested_bits - + collected_ent_bits); + + /* + * Harvest entropy from each per-CPU hash state - even though we may + * have collected sufficient entropy, we will hash all per-CPU pools. + */ + for_each_online_cpu(cpu) { + unsigned long flags2; + spinlock_t *lock = per_cpu_ptr(&lrng_pcpu_lock, cpu); + u32 pcpu_unused_irqs = 0; + u8 *pcpu_pool = per_cpu_ptr(lrng_pcpu_pool, cpu); + + /* If pool is not online, then no entropy is present. */ + if (!lrng_pcpu_pool_online(cpu)) + continue; + + /* Obtain entropy statement like for the aux pool */ + found_irqs = atomic_xchg_relaxed( + per_cpu_ptr(&lrng_pcpu_array_irqs, cpu), 0); + /* Cap to maximum amount of data we can hold */ + found_irqs = min_t(u32, found_irqs, digestsize_irqs); + + spin_lock_irqsave(lock, flags2); + ret = crypto_cb->lrng_hash_update(shash, pcpu_pool, + LRNG_MAX_DIGESTSIZE); + spin_unlock_irqrestore(lock, flags2); + + if (ret) + goto err; + + collected_irqs += found_irqs; + if (collected_irqs > requested_irqs) { + pcpu_unused_irqs = collected_irqs - requested_irqs; + atomic_add_return_relaxed(pcpu_unused_irqs, + per_cpu_ptr(&lrng_pcpu_array_irqs, cpu)); + collected_irqs = requested_irqs; + } + pr_debug("%u interrupts used from entropy pool of CPU %d, %u interrupts remain unused\n", + found_irqs - pcpu_unused_irqs, cpu, pcpu_unused_irqs); + } + + ret = crypto_cb->lrng_hash_final(shash, pool->aux_pool); + if (ret) + goto err; + + read_unlock_irqrestore(&drng->hash_lock, flags); + + collected_ent_bits += lrng_data_to_entropy(collected_irqs); + + /* + * Truncate to available entropy as implicitly allowed by SP800-90B + * section 3.1.5.1.1 table 1 which awards truncated hashes full + * entropy. + * + * During boot time, we read requested_bits data with + * collected_ent_bits entropy. In case our conservative entropy + * estimate underestimates the available entropy we can transport as + * much available entropy as possible. The entropy pool does not + * operate compliant to the German AIS 21/31 NTG.1 yet. + */ + memcpy(outbuf, pool->aux_pool, fully_seeded ? collected_ent_bits >> 3 : + requested_bits >> 3); + + pr_debug("obtained %u bits of entropy\n", collected_ent_bits); + + return collected_ent_bits; + +err: + read_unlock_irqrestore(&drng->hash_lock, flags); + return 0; +} + +/* Compress the lrng_pcpu_array array into lrng_pcp_pool */ +static inline void lrng_pcpu_array_compress(void) +{ + SHASH_DESC_ON_STACK(shash, NULL); + struct lrng_drng **lrng_drng = lrng_drng_instances(); + struct lrng_drng *drng = lrng_drng_init_instance(); + const struct lrng_crypto_cb *crypto_cb; + spinlock_t *lock = this_cpu_ptr(&lrng_pcpu_lock); + unsigned long flags, flags2; + int node = numa_node_id(); + void *hash; + u8 *pcpu_pool = this_cpu_ptr(lrng_pcpu_pool); + + /* Get NUMA-node local hash instance */ + if (lrng_drng && lrng_drng[node]) + drng = lrng_drng[node]; + + if (unlikely(!this_cpu_read(lrng_pcpu_lock_init))) { + spin_lock_init(lock); + this_cpu_write(lrng_pcpu_lock_init, true); + } + + read_lock_irqsave(&drng->hash_lock, flags); + spin_lock_irqsave(lock, flags2); + + crypto_cb = drng->crypto_cb; + hash = drng->hash; + + if (crypto_cb->lrng_hash_init(shash, hash) || + /* Hash entire per-CPU data array content ... */ + crypto_cb->lrng_hash_update(shash, + (u8 *)this_cpu_ptr(lrng_pcpu_array), + LRNG_DATA_ARRAY_SIZE * sizeof(u32)) || + /* ... together with per-CPU entropy pool ... */ + crypto_cb->lrng_hash_update(shash, pcpu_pool, + LRNG_MAX_DIGESTSIZE) || + /* ... to form new per-CPU entropy pool state. */ + crypto_cb->lrng_hash_final(shash, pcpu_pool)) + pr_warn_ratelimited("Hashing of entropy data failed\n"); + + spin_unlock_irqrestore(lock, flags2); + read_unlock_irqrestore(&drng->hash_lock, flags); +} + +/* Compress data array into hash */ +static inline void lrng_pcpu_array_to_hash(u32 ptr) +{ + u32 *array = this_cpu_ptr(lrng_pcpu_array); + + if (ptr < LRNG_DATA_WORD_MASK) + return; + + if (lrng_raw_array_entropy_store(*array)) { + u32 i; + + /* + * If we fed even a part of the array to external analysis, we + * mark that the entire array and the per-CPU pool to have no + * entropy. This is due to the non-IID property of the data as + * we do not fully know whether the existing dependencies + * diminish the entropy beyond to what we expect it has. + */ + atomic_set(this_cpu_ptr(&lrng_pcpu_array_irqs), 0); + + for (i = 1; i < LRNG_DATA_ARRAY_SIZE; i++) + lrng_raw_array_entropy_store(*(array + i)); + } else { + lrng_pcpu_array_compress(); + /* Ping pool handler about received entropy */ + lrng_pool_add_irq(); + } + + memset(array, 0, LRNG_DATA_ARRAY_SIZE * sizeof(u32)); +} + +/* + * Concatenate full 32 bit word at the end of time array even when current + * ptr is not aligned to sizeof(data). + */ +static inline void _lrng_pcpu_array_add_u32(u32 data) +{ + /* Increment pointer by number of slots taken for input value */ + u32 pre_ptr, mask, ptr = this_cpu_add_return(lrng_pcpu_array_ptr, + LRNG_DATA_SLOTS_PER_UINT); + + /* + * This function injects a unit into the array - guarantee that + * array unit size is equal to data type of input data. + */ + BUILD_BUG_ON(LRNG_DATA_ARRAY_MEMBER_BITS != (sizeof(data) << 3)); + + /* + * The following logic requires at least two units holding + * the data as otherwise the pointer would immediately wrap when + * injection an u32 word. + */ + BUILD_BUG_ON(LRNG_DATA_NUM_VALUES <= LRNG_DATA_SLOTS_PER_UINT); + + /* ptr to previous unit */ + pre_ptr = (ptr - LRNG_DATA_SLOTS_PER_UINT) & LRNG_DATA_WORD_MASK; + ptr &= LRNG_DATA_WORD_MASK; + + /* mask to split data into the two parts for the two units */ + mask = ((1 << (pre_ptr & (LRNG_DATA_SLOTS_PER_UINT - 1)) * + LRNG_DATA_SLOTSIZE_BITS)) - 1; + + /* MSB of data go into previous unit */ + this_cpu_or(lrng_pcpu_array[lrng_data_idx2array(pre_ptr)], + data & ~mask); + + /* Invoke compression as we just filled data array completely */ + if (unlikely(pre_ptr > ptr)) + lrng_pcpu_array_to_hash(LRNG_DATA_WORD_MASK); + + /* LSB of data go into current unit */ + this_cpu_write(lrng_pcpu_array[lrng_data_idx2array(ptr)], + data & mask); + + if (likely(pre_ptr <= ptr)) + lrng_pcpu_array_to_hash(ptr); +} + +/* Concatenate a 32-bit word at the end of the per-CPU array */ +void lrng_pcpu_array_add_u32(u32 data) +{ + _lrng_pcpu_array_add_u32(data); +} + +/* Concatenate data of max LRNG_DATA_SLOTSIZE_MASK at the end of time array */ +static inline void lrng_pcpu_array_add_slot(u32 data) +{ + /* Get slot */ + u32 ptr = this_cpu_inc_return(lrng_pcpu_array_ptr) & + LRNG_DATA_WORD_MASK; + + BUILD_BUG_ON(LRNG_DATA_ARRAY_MEMBER_BITS % LRNG_DATA_SLOTSIZE_BITS); + /* Ensure consistency of values */ + BUILD_BUG_ON(LRNG_DATA_ARRAY_MEMBER_BITS != + sizeof(lrng_pcpu_array[0]) << 3); + + /* Store data into slot */ + this_cpu_or(lrng_pcpu_array[lrng_data_idx2array(ptr)], + lrng_data_slot_val(data, lrng_data_idx2slot(ptr))); + + lrng_pcpu_array_to_hash(ptr); +} + +/* + * Batching up of entropy in per-CPU array before injecting into entropy pool. + * + * The random32_data is solely to be used for the external random32 PRNG. + */ +static inline void lrng_time_process(u32 random32_data) +{ + u32 now_time = random_get_entropy(); + u32 now_time_masked = now_time & LRNG_DATA_SLOTSIZE_MASK; + enum lrng_health_res health_test; + + /* During boot time, we process the full time stamp */ + if (unlikely(!lrng_state_fully_seeded())) { + + /* Seed random32 PRNG with data not used by LRNG. */ + this_cpu_add(net_rand_state.s1, random32_data); + + if (lrng_raw_hires_entropy_store(now_time)) + goto out; + + health_test = lrng_health_test(now_time); + if (health_test > lrng_health_fail_use) + goto out; + + if (health_test == lrng_health_pass) + atomic_inc_return(this_cpu_ptr(&lrng_pcpu_array_irqs)); + + _lrng_pcpu_array_add_u32(now_time); + } else { + /* Runtime operation */ + if (lrng_raw_hires_entropy_store(now_time_masked)) + goto out; + + /* Seed random32 PRNG with data not used by LRNG. */ + this_cpu_add(net_rand_state.s1, + (now_time & ~LRNG_DATA_SLOTSIZE_MASK) ^ random32_data); + + health_test = lrng_health_test(now_time_masked); + if (health_test > lrng_health_fail_use) + goto out; + + /* Interrupt delivers entropy if health test passes */ + if (health_test == lrng_health_pass) + atomic_inc_return(this_cpu_ptr(&lrng_pcpu_array_irqs)); + + lrng_pcpu_array_add_slot(now_time_masked); + } + +out: + lrng_perf_time(now_time); +} + +/* Hot code path - Callback for interrupt handler */ +void add_interrupt_randomness(int irq, int irq_flg) +{ + u32 tmp; + + if (lrng_pool_highres_timer()) { + tmp = lrng_raw_irq_entropy_store(irq) ? 0 : irq; + tmp ^= lrng_raw_irqflags_entropy_store(irq_flg) ? 0 : irq_flg; + tmp ^= lrng_raw_retip_entropy_store(_RET_IP_) ? 0 : _RET_IP_; + lrng_time_process(tmp); + } else { + struct pt_regs *regs = get_irq_regs(); + static atomic_t reg_idx = ATOMIC_INIT(0); + u64 ip; + + if (regs) { + u32 *ptr = (u32 *)regs; + int reg_ptr = atomic_add_return_relaxed(1, ®_idx); + size_t n = (sizeof(struct pt_regs) / sizeof(u32)); + + ip = instruction_pointer(regs); + tmp = *(ptr + (reg_ptr % n)); + tmp = lrng_raw_regs_entropy_store(tmp) ? 0 : tmp; + _lrng_pcpu_array_add_u32(tmp); + } else { + ip = _RET_IP_; + } + + lrng_time_process(lrng_raw_retip_entropy_store(ip) ? 0 : ip); + + /* + * The XOR operation combining the different values is not + * considered to destroy entropy since the entirety of all + * processed values delivers the entropy (and not each + * value separately of the other values). + */ + ip >>= 32; + tmp = lrng_raw_jiffies_entropy_store(jiffies) ? 0 : jiffies; + tmp ^= lrng_raw_irq_entropy_store(irq) ? 0 : irq; + tmp ^= lrng_raw_irqflags_entropy_store(irq_flg) ? 0 : irq_flg; + tmp ^= lrng_raw_retip_entropy_store(ip) ? 0 : ip; + _lrng_pcpu_array_add_u32(tmp); + } +} +EXPORT_SYMBOL(add_interrupt_randomness); diff --git a/drivers/char/lrng/lrng_sw_noise.h b/drivers/char/lrng/lrng_sw_noise.h new file mode 100644 index 000000000000..ec9d78ba5128 --- /dev/null +++ b/drivers/char/lrng/lrng_sw_noise.h @@ -0,0 +1,56 @@ +/* SPDX-License-Identifier: GPL-2.0 OR BSD-2-Clause */ +/* + * LRNG Slow Noise Source: Time stamp array handling + * + * Copyright (C) 2016 - 2020, Stephan Mueller + */ + +/* + * To limit the impact on the interrupt handling, the LRNG concatenates + * entropic LSB parts of the time stamps in a per-CPU array and only + * injects them into the entropy pool when the array is full. + */ + +/* Store multiple integers in one u32 */ +#define LRNG_DATA_SLOTSIZE_BITS (8) +#define LRNG_DATA_SLOTSIZE_MASK ((1 << LRNG_DATA_SLOTSIZE_BITS) - 1) +#define LRNG_DATA_ARRAY_MEMBER_BITS (4 << 3) /* ((sizeof(u32)) << 3) */ +#define LRNG_DATA_SLOTS_PER_UINT (LRNG_DATA_ARRAY_MEMBER_BITS / \ + LRNG_DATA_SLOTSIZE_BITS) + +/* + * Number of time values to store in the array - in small environments + * only one atomic_t variable per CPU is used. + */ +#define LRNG_DATA_NUM_VALUES (CONFIG_LRNG_COLLECTION_SIZE) +/* Mask of LSB of time stamp to store */ +#define LRNG_DATA_WORD_MASK (LRNG_DATA_NUM_VALUES - 1) + +#define LRNG_DATA_SLOTS_MASK (LRNG_DATA_SLOTS_PER_UINT - 1) +#define LRNG_DATA_ARRAY_SIZE (LRNG_DATA_NUM_VALUES / \ + LRNG_DATA_SLOTS_PER_UINT) + +/* Starting bit index of slot */ +static inline unsigned int lrng_data_slot2bitindex(unsigned int slot) +{ + return (LRNG_DATA_SLOTSIZE_BITS * slot); +} + +/* Convert index into the array index */ +static inline unsigned int lrng_data_idx2array(unsigned int idx) +{ + return idx / LRNG_DATA_SLOTS_PER_UINT; +} + +/* Convert index into the slot of a given array index */ +static inline unsigned int lrng_data_idx2slot(unsigned int idx) +{ + return idx & LRNG_DATA_SLOTS_MASK; +} + +/* Convert value into slot value */ +static inline unsigned int lrng_data_slot_val(unsigned int val, + unsigned int slot) +{ + return val << lrng_data_slot2bitindex(slot); +} diff --git a/include/linux/lrng.h b/include/linux/lrng.h new file mode 100644 index 000000000000..3dee5b769236 --- /dev/null +++ b/include/linux/lrng.h @@ -0,0 +1,79 @@ +/* SPDX-License-Identifier: GPL-2.0 OR BSD-2-Clause */ +/* + * Copyright (C) 2018 - 2020, Stephan Mueller + */ + +#ifndef _LRNG_H +#define _LRNG_H + +#include +#include +#include + +/** + * struct lrng_crypto_cb - cryptographic callback functions + * @lrng_drng_name Name of DRNG + * @lrng_hash_name Name of Hash used for reading entropy pool + * @lrng_drng_alloc: Allocate DRNG -- the provided integer should be + * used for sanity checks. + * return: allocated data structure or PTR_ERR on + * error + * @lrng_drng_dealloc: Deallocate DRNG + * @lrng_drng_seed_helper: Seed the DRNG with data of arbitrary length + * drng: is pointer to data structure allocated + * with lrng_drng_alloc + * return: >= 0 on success, < 0 on error + * @lrng_drng_generate_helper: Generate random numbers from the DRNG with + * arbitrary length + * @lrng_hash_alloc: Allocate the hash for reading the entropy pool + * return: allocated data structure (NULL is + * success too) or ERR_PTR on error + * @lrng_hash_dealloc: Deallocate Hash + * @lrng_hash_digestsize: Return the digestsize for the used hash to read + * out entropy pool + * hash: is pointer to data structure allocated + * with lrng_hash_alloc + * return: size of digest of hash in bytes + * @lrng_hash_init: Initialize hash + * hash: is pointer to data structure allocated + * with lrng_hash_alloc + * return: 0 on success, < 0 on error + * @lrng_hash_update: Update hash operation + * hash: is pointer to data structure allocated + * with lrng_hash_alloc + * return: 0 on success, < 0 on error + * @lrng_hash_final Final hash operation + * hash: is pointer to data structure allocated + * with lrng_hash_alloc + * return: 0 on success, < 0 on error + * + * Assumptions: + * + * 1. Hash operation will not sleep + * 2. The hash' volatile state information is provided with *shash by caller. + */ +struct lrng_crypto_cb { + const char *(*lrng_drng_name)(void); + const char *(*lrng_hash_name)(void); + void *(*lrng_drng_alloc)(u32 sec_strength); + void (*lrng_drng_dealloc)(void *drng); + int (*lrng_drng_seed_helper)(void *drng, const u8 *inbuf, u32 inbuflen); + int (*lrng_drng_generate_helper)(void *drng, u8 *outbuf, u32 outbuflen); + void *(*lrng_hash_alloc)(void); + void (*lrng_hash_dealloc)(void *hash); + u32 (*lrng_hash_digestsize)(void *hash); + int (*lrng_hash_init)(struct shash_desc *shash, void *hash); + int (*lrng_hash_update)(struct shash_desc *shash, const u8 *inbuf, + u32 inbuflen); + int (*lrng_hash_final)(struct shash_desc *shash, u8 *digest); +}; + +/* Register cryptographic backend */ +#ifdef CONFIG_LRNG_DRNG_SWITCH +int lrng_set_drng_cb(const struct lrng_crypto_cb *cb); +#else /* CONFIG_LRNG_DRNG_SWITCH */ +static inline int +lrng_set_drng_cb(const struct lrng_crypto_cb *cb) { return -EOPNOTSUPP; } +#endif /* CONFIG_LRNG_DRNG_SWITCH */ + +#endif /* _LRNG_H */