From: Zbigniew Jędrzejewski-Szmek Date: Sun, 25 Jun 2017 21:09:05 +0000 (-0400) Subject: basic/random-util: do not fall back to /dev/urandom if getrandom() returns short X-Git-Tag: chiark/234.4-1+devuan1.1+iwj1~96 X-Git-Url: http://www.chiark.greenend.org.uk/ucgi/~ianmdlvl/git?p=elogind.git;a=commitdiff_plain;h=3daa986ebd3fd6d42853c12020a8c687ce681b26 basic/random-util: do not fall back to /dev/urandom if getrandom() returns short During early boot, we'd call getrandom(), and immediately fall back to reading from /dev/urandom unless we got the full requested number of bytes. Those two sources are the same, so the most likely result is /dev/urandom producing some pseudorandom numbers for us, complaining widely on the way. Let's change our behaviour to be more conservative: - if the numbers are only used to initialize a hash table, a short read is OK, we don't really care if we get the first part of the seed truly random and then some pseudorandom bytes. So just do that and return "success". - if getrandom() returns -EAGAIN, fall back to rand() instead of querying /dev/urandom again. The idea with those two changes is to avoid generating a warning about reading from an /dev/urandom when the kernel doesn't have enough entropy. - only in the cases where we really need to make the best effort possible (sd_id128_randomize and firstboot password hashing), fall back to /dev/urandom. When calling getrandom(), drop the checks whether the argument fits in an int — getrandom() should do that for us already, and we call it with small arguments only anyway. Note that this does not really change the (relatively high) number of random bytes we request from the kernel. On my laptop, during boot, PID 1 and all other processes using this code through libelogind request: 74780 bytes with high_quality_required == false 464 bytes with high_quality_required == true and it does not eliminate reads from /dev/urandom completely. If the kernel was short on entropy and getrandom() would fail, we would fall back to /dev/urandom for those 464 bytes. When falling back to /dev/urandom, don't lose the short read we already got, and just read the remaining bytes. If getrandom() syscall is not available, we fall back to /dev/urandom same as before. Fixes #4167 (possibly partially, let's see). --- diff --git a/src/basic/random-util.c b/src/basic/random-util.c index b216be579..490107ef4 100644 --- a/src/basic/random-util.c +++ b/src/basic/random-util.c @@ -42,53 +42,59 @@ #include "random-util.h" #include "time-util.h" -int dev_urandom(void *p, size_t n) { +int acquire_random_bytes(void *p, size_t n, bool high_quality_required) { static int have_syscall = -1; _cleanup_close_ int fd = -1; int r; + unsigned already_done = 0; - /* Gathers some randomness from the kernel. This call will - * never block, and will always return some data from the - * kernel, regardless if the random pool is fully initialized - * or not. It thus makes no guarantee for the quality of the - * returned entropy, but is good enough for our usual usecases - * of seeding the hash functions for hashtable */ + /* Gathers some randomness from the kernel. This call will never block. If + * high_quality_required, it will always return some data from the kernel, + * regardless of whether the random pool is fully initialized or not. + * Otherwise, it will return success if at least some random bytes were + * successfully acquired, and an error if the kernel has no entropy whatsover + * for us. */ - /* Use the getrandom() syscall unless we know we don't have - * it, or when the requested size is too large for it. */ - if (have_syscall != 0 || (size_t) (int) n != n) { + /* Use the getrandom() syscall unless we know we don't have it. */ + if (have_syscall != 0) { r = getrandom(p, n, GRND_NONBLOCK); - if (r == (int) n) { + if (r > 0) { have_syscall = true; - return 0; - } - - if (r < 0) { - if (errno == ENOSYS) - /* we lack the syscall, continue with - * reading from /dev/urandom */ - have_syscall = false; - else if (errno == EAGAIN) - /* not enough entropy for now. Let's - * remember to use the syscall the - * next time, again, but also read - * from /dev/urandom for now, which - * doesn't care about the current - * amount of entropy. */ - have_syscall = true; - else - return -errno; + if (r == n) + return 0; + if (!high_quality_required) { + /* Fill in the remaing bytes using pseudorandom values */ + pseudorandom_bytes((uint8_t*) p + r, n - r); + return 0; + } + + already_done = r; + } else if (errno == ENOSYS) + /* We lack the syscall, continue with reading from /dev/urandom. */ + have_syscall = false; + else if (errno == EAGAIN) { + /* The kernel has no entropy whatsoever. Let's remember to + * use the syscall the next time again though. + * + * If high_quality_required is false, return an error so that + * random_bytes() can produce some pseudorandom + * bytes. Otherwise, fall back to /dev/urandom, which we know + * is empty, but the kernel will produce some bytes for us on + * a best-effort basis. */ + have_syscall = true; + + if (!high_quality_required) + return -ENODATA; } else - /* too short read? */ - return -ENODATA; + return -errno; } fd = open("/dev/urandom", O_RDONLY|O_CLOEXEC|O_NOCTTY); if (fd < 0) return errno == ENOENT ? -ENOSYS : -errno; - return loop_read_exact(fd, p, n, true); + return loop_read_exact(fd, (uint8_t*) p + already_done, n - already_done, true); } void initialize_srand(void) { @@ -102,8 +108,9 @@ void initialize_srand(void) { return; #ifdef HAVE_SYS_AUXV_H - /* The kernel provides us with 16 bytes of entropy in auxv, so let's try to make use of that to seed the - * pseudo-random generator. It's better than nothing... */ + /* The kernel provides us with 16 bytes of entropy in auxv, so let's + * try to make use of that to seed the pseudo-random generator. It's + * better than nothing... */ auxv = (void*) getauxval(AT_RANDOM); if (auxv) { @@ -121,19 +128,44 @@ void initialize_srand(void) { srand_called = true; } -void random_bytes(void *p, size_t n) { +/* INT_MAX gives us only 31 bits, so use 24 out of that. */ +#if RAND_MAX >= INT_MAX +# define RAND_STEP 3 +#else +/* SHORT_INT_MAX or lower gives at most 15 bits, we just just 8 out of that. */ +# define RAND_STEP 1 +#endif + +void pseudorandom_bytes(void *p, size_t n) { uint8_t *q; + + initialize_srand(); + + for (q = p; q < (uint8_t*) p + n; q += RAND_STEP) { + unsigned rr; + + rr = (unsigned) rand(); + +#if RAND_STEP >= 3 + if (q - (uint8_t*) p + 2 < n) + q[2] = rr >> 16; +#endif +#if RAND_STEP >= 2 + if (q - (uint8_t*) p + 1 < n) + q[1] = rr >> 8; +#endif + q[0] = rr; + } +} + +void random_bytes(void *p, size_t n) { int r; - r = dev_urandom(p, n); + r = acquire_random_bytes(p, n, false); if (r >= 0) return; - /* If some idiot made /dev/urandom unavailable to us, he'll - * get a PRNG instead. */ - - initialize_srand(); - - for (q = p; q < (uint8_t*) p + n; q ++) - *q = rand(); + /* If some idiot made /dev/urandom unavailable to us, or the + * kernel has no entropy, use a PRNG instead. */ + return pseudorandom_bytes(p, n); } diff --git a/src/basic/random-util.h b/src/basic/random-util.h index 3cee4c501..804e225fc 100644 --- a/src/basic/random-util.h +++ b/src/basic/random-util.h @@ -19,10 +19,12 @@ along with systemd; If not, see . ***/ +#include #include #include -int dev_urandom(void *p, size_t n); +int acquire_random_bytes(void *p, size_t n, bool high_quality_required); +void pseudorandom_bytes(void *p, size_t n); void random_bytes(void *p, size_t n); void initialize_srand(void); diff --git a/src/libelogind/sd-id128/sd-id128.c b/src/libelogind/sd-id128/sd-id128.c index 90d1ae28c..d51abb205 100644 --- a/src/libelogind/sd-id128/sd-id128.c +++ b/src/libelogind/sd-id128/sd-id128.c @@ -288,7 +288,7 @@ _public_ int sd_id128_randomize(sd_id128_t *ret) { assert_return(ret, -EINVAL); - r = dev_urandom(&t, sizeof(t)); + r = acquire_random_bytes(&t, sizeof t, true); if (r < 0) return r;