// SPDX-License-Identifier: GPL-2.0-only #include #include #include #include #include #include #include #include #include "kvm_util.h" static struct kvm_vm *vm1; static struct kvm_vm *vm2; static int __eventfd; static bool done; /* * KVM de-assigns based on eventfd *and* GSI, but requires unique eventfds when * assigning (the API isn't symmetrical). Abuse the oddity and use a per-task * GSI base to avoid false failures due to cross-task de-assign, i.e. so that * the secondary doesn't de-assign the primary's eventfd and cause assign to * unexpectedly succeed on the primary. */ #define GSI_BASE_PRIMARY 0x20 #define GSI_BASE_SECONDARY 0x30 static void juggle_eventfd_secondary(struct kvm_vm *vm, int eventfd) { int r, i; /* * The secondary task can encounter EBADF since the primary can close * the eventfd at any time. And because the primary can recreate the * eventfd, at the safe fd in the file table, the secondary can also * encounter "unexpected" success, e.g. if the close+recreate happens * between the first and second assignments. The secondary's role is * mostly to antagonize KVM, not to detect bugs. */ for (i = 0; i < 2; i++) { r = __kvm_irqfd(vm, GSI_BASE_SECONDARY, eventfd, 0); TEST_ASSERT(!r || errno == EBUSY || errno == EBADF, "Wanted success, EBUSY, or EBADF, r = %d, errno = %d", r, errno); /* De-assign should succeed unless the eventfd was closed. */ r = __kvm_irqfd(vm, GSI_BASE_SECONDARY + i, eventfd, KVM_IRQFD_FLAG_DEASSIGN); TEST_ASSERT(!r || errno == EBADF, "De-assign should succeed unless the fd was closed"); } } static void *secondary_irqfd_juggler(void *ign) { while (!READ_ONCE(done)) { juggle_eventfd_secondary(vm1, READ_ONCE(__eventfd)); juggle_eventfd_secondary(vm2, READ_ONCE(__eventfd)); } return NULL; } static void juggle_eventfd_primary(struct kvm_vm *vm, int eventfd) { int r1, r2; /* * At least one of the assigns should fail. KVM disallows assigning a * single eventfd to multiple GSIs (or VMs), so it's possible that both * assignments can fail, too. */ r1 = __kvm_irqfd(vm, GSI_BASE_PRIMARY, eventfd, 0); TEST_ASSERT(!r1 || errno == EBUSY, "Wanted success or EBUSY, r = %d, errno = %d", r1, errno); r2 = __kvm_irqfd(vm, GSI_BASE_PRIMARY + 1, eventfd, 0); TEST_ASSERT(r1 || (r2 && errno == EBUSY), "Wanted failure (EBUSY), r1 = %d, r2 = %d, errno = %d", r1, r2, errno); /* * De-assign should always succeed, even if the corresponding assign * failed. */ kvm_irqfd(vm, GSI_BASE_PRIMARY, eventfd, KVM_IRQFD_FLAG_DEASSIGN); kvm_irqfd(vm, GSI_BASE_PRIMARY + 1, eventfd, KVM_IRQFD_FLAG_DEASSIGN); } int main(int argc, char *argv[]) { pthread_t racing_thread; int r, i; /* Create "full" VMs, as KVM_IRQFD requires an in-kernel IRQ chip. */ vm1 = vm_create(1); vm2 = vm_create(1); WRITE_ONCE(__eventfd, kvm_new_eventfd()); kvm_irqfd(vm1, 10, __eventfd, 0); r = __kvm_irqfd(vm1, 11, __eventfd, 0); TEST_ASSERT(r && errno == EBUSY, "Wanted EBUSY, r = %d, errno = %d", r, errno); r = __kvm_irqfd(vm2, 12, __eventfd, 0); TEST_ASSERT(r && errno == EBUSY, "Wanted EBUSY, r = %d, errno = %d", r, errno); /* * De-assign all eventfds, along with multiple eventfds that were never * assigned. KVM's ABI is that de-assign is allowed so long as the * eventfd itself is valid. */ kvm_irqfd(vm1, 11, READ_ONCE(__eventfd), KVM_IRQFD_FLAG_DEASSIGN); kvm_irqfd(vm1, 12, READ_ONCE(__eventfd), KVM_IRQFD_FLAG_DEASSIGN); kvm_irqfd(vm1, 13, READ_ONCE(__eventfd), KVM_IRQFD_FLAG_DEASSIGN); kvm_irqfd(vm1, 14, READ_ONCE(__eventfd), KVM_IRQFD_FLAG_DEASSIGN); kvm_irqfd(vm1, 10, READ_ONCE(__eventfd), KVM_IRQFD_FLAG_DEASSIGN); close(__eventfd); pthread_create(&racing_thread, NULL, secondary_irqfd_juggler, vm2); for (i = 0; i < 10000; i++) { WRITE_ONCE(__eventfd, kvm_new_eventfd()); juggle_eventfd_primary(vm1, __eventfd); juggle_eventfd_primary(vm2, __eventfd); close(__eventfd); } WRITE_ONCE(done, true); pthread_join(racing_thread, NULL); }