// SPDX-License-Identifier: GPL-2.0-only #define _GNU_SOURCE /* for program_invocation_short_name */ #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include "kvm_util.h" #include "processor.h" #include "test_util.h" #define VCPU_ID 0 static __thread volatile struct rseq __rseq = { .cpu_id = RSEQ_CPU_ID_UNINITIALIZED, }; /* * Use an arbitrary, bogus signature for configuring rseq, this test does not * actually enter an rseq critical section. */ #define RSEQ_SIG 0xdeadbeef /* * Any bug related to task migration is likely to be timing-dependent; perform * a large number of migrations to reduce the odds of a false negative. */ #define NR_TASK_MIGRATIONS 100000 static pthread_t migration_thread; static cpu_set_t possible_mask; static int min_cpu, max_cpu; static bool done; static atomic_t seq_cnt; static void guest_code(void) { for (;;) GUEST_SYNC(0); } static void sys_rseq(int flags) { int r; r = syscall(__NR_rseq, &__rseq, sizeof(__rseq), flags, RSEQ_SIG); TEST_ASSERT(!r, "rseq failed, errno = %d (%s)", errno, strerror(errno)); } static int next_cpu(int cpu) { /* * Advance to the next CPU, skipping those that weren't in the original * affinity set. Sadly, there is no CPU_SET_FOR_EACH, and cpu_set_t's * data storage is considered as opaque. Note, if this task is pinned * to a small set of discontigous CPUs, e.g. 2 and 1023, this loop will * burn a lot cycles and the test will take longer than normal to * complete. */ do { cpu++; if (cpu > max_cpu) { cpu = min_cpu; TEST_ASSERT(CPU_ISSET(cpu, &possible_mask), "Min CPU = %d must always be usable", cpu); break; } } while (!CPU_ISSET(cpu, &possible_mask)); return cpu; } static void *migration_worker(void *__rseq_tid) { pid_t rseq_tid = (pid_t)(unsigned long)__rseq_tid; cpu_set_t allowed_mask; int r, i, cpu; CPU_ZERO(&allowed_mask); for (i = 0, cpu = min_cpu; i < NR_TASK_MIGRATIONS; i++, cpu = next_cpu(cpu)) { CPU_SET(cpu, &allowed_mask); /* * Bump the sequence count twice to allow the reader to detect * that a migration may have occurred in between rseq and sched * CPU ID reads. An odd sequence count indicates a migration * is in-progress, while a completely different count indicates * a migration occurred since the count was last read. */ atomic_inc(&seq_cnt); /* * Ensure the odd count is visible while sched_getcpu() isn't * stable, i.e. while changing affinity is in-progress. */ smp_wmb(); r = sched_setaffinity(rseq_tid, sizeof(allowed_mask), &allowed_mask); TEST_ASSERT(!r, "sched_setaffinity failed, errno = %d (%s)", errno, strerror(errno)); smp_wmb(); atomic_inc(&seq_cnt); CPU_CLR(cpu, &allowed_mask); /* * Wait 1-10us before proceeding to the next iteration and more * specifically, before bumping seq_cnt again. A delay is * needed on three fronts: * * 1. To allow sched_setaffinity() to prompt migration before * ioctl(KVM_RUN) enters the guest so that TIF_NOTIFY_RESUME * (or TIF_NEED_RESCHED, which indirectly leads to handling * NOTIFY_RESUME) is handled in KVM context. * * If NOTIFY_RESUME/NEED_RESCHED is set after KVM enters * the guest, the guest will trigger a IO/MMIO exit all the * way to userspace and the TIF flags will be handled by * the generic "exit to userspace" logic, not by KVM. The * exit to userspace is necessary to give the test a chance * to check the rseq CPU ID (see #2). * * Alternatively, guest_code() could include an instruction * to trigger an exit that is handled by KVM, but any such * exit requires architecture specific code. * * 2. To let ioctl(KVM_RUN) make its way back to the test * before the next round of migration. The test's check on * the rseq CPU ID must wait for migration to complete in * order to avoid false positive, thus any kernel rseq bug * will be missed if the next migration starts before the * check completes. * * 3. To ensure the read-side makes efficient forward progress, * e.g. if sched_getcpu() involves a syscall. Stalling the * read-side means the test will spend more time waiting for * sched_getcpu() to stabilize and less time trying to hit * the timing-dependent bug. * * Because any bug in this area is likely to be timing-dependent, * run with a range of delays at 1us intervals from 1us to 10us * as a best effort to avoid tuning the test to the point where * it can hit _only_ the original bug and not detect future * regressions. * * The original bug can reproduce with a delay up to ~500us on * x86-64, but starts to require more iterations to reproduce * as the delay creeps above ~10us, and the average runtime of * each iteration obviously increases as well. Cap the delay * at 10us to keep test runtime reasonable while minimizing * potential coverage loss. * * The lower bound for reproducing the bug is likely below 1us, * e.g. failures occur on x86-64 with nanosleep(0), but at that * point the overhead of the syscall likely dominates the delay. * Use usleep() for simplicity and to avoid unnecessary kernel * dependencies. */ usleep((i % 10) + 1); } done = true; return NULL; } static int calc_min_max_cpu(void) { int i, cnt, nproc; if (CPU_COUNT(&possible_mask) < 2) return -EINVAL; /* * CPU_SET doesn't provide a FOR_EACH helper, get the min/max CPU that * this task is affined to in order to reduce the time spent querying * unusable CPUs, e.g. if this task is pinned to a small percentage of * total CPUs. */ nproc = get_nprocs_conf(); min_cpu = -1; max_cpu = -1; cnt = 0; for (i = 0; i < nproc; i++) { if (!CPU_ISSET(i, &possible_mask)) continue; if (min_cpu == -1) min_cpu = i; max_cpu = i; cnt++; } return (cnt < 2) ? -EINVAL : 0; } int main(int argc, char *argv[]) { int r, i, snapshot; struct kvm_vm *vm; u32 cpu, rseq_cpu; /* Tell stdout not to buffer its content */ setbuf(stdout, NULL); r = sched_getaffinity(0, sizeof(possible_mask), &possible_mask); TEST_ASSERT(!r, "sched_getaffinity failed, errno = %d (%s)", errno, strerror(errno)); if (calc_min_max_cpu()) { print_skip("Only one usable CPU, task migration not possible"); exit(KSFT_SKIP); } sys_rseq(0); /* * Create and run a dummy VM that immediately exits to userspace via * GUEST_SYNC, while concurrently migrating the process by setting its * CPU affinity. */ vm = vm_create_default(VCPU_ID, 0, guest_code); ucall_init(vm, NULL); pthread_create(&migration_thread, NULL, migration_worker, (void *)(unsigned long)syscall(SYS_gettid)); for (i = 0; !done; i++) { vcpu_run(vm, VCPU_ID); TEST_ASSERT(get_ucall(vm, VCPU_ID, NULL) == UCALL_SYNC, "Guest failed?"); /* * Verify rseq's CPU matches sched's CPU. Ensure migration * doesn't occur between sched_getcpu() and reading the rseq * cpu_id by rereading both if the sequence count changes, or * if the count is odd (migration in-progress). */ do { /* * Drop bit 0 to force a mismatch if the count is odd, * i.e. if a migration is in-progress. */ snapshot = atomic_read(&seq_cnt) & ~1; /* * Ensure reading sched_getcpu() and rseq.cpu_id * complete in a single "no migration" window, i.e. are * not reordered across the seq_cnt reads. */ smp_rmb(); cpu = sched_getcpu(); rseq_cpu = READ_ONCE(__rseq.cpu_id); smp_rmb(); } while (snapshot != atomic_read(&seq_cnt)); TEST_ASSERT(rseq_cpu == cpu, "rseq CPU = %d, sched CPU = %d\n", rseq_cpu, cpu); } /* * Sanity check that the test was able to enter the guest a reasonable * number of times, e.g. didn't get stalled too often/long waiting for * sched_getcpu() to stabilize. A 2:1 migration:KVM_RUN ratio is a * fairly conservative ratio on x86-64, which can do _more_ KVM_RUNs * than migrations given the 1us+ delay in the migration task. */ TEST_ASSERT(i > (NR_TASK_MIGRATIONS / 2), "Only performed %d KVM_RUNs, task stalled too much?\n", i); pthread_join(migration_thread, NULL); kvm_vm_free(vm); sys_rseq(RSEQ_FLAG_UNREGISTER); return 0; }