/* $OpenBSD: vmm.c,v 1.112 2023/05/13 23:15:28 dv Exp $ */ /* * Copyright (c) 2015 Mike Larkin * * Permission to use, copy, modify, and distribute this software for any * purpose with or without fee is hereby granted, provided that the above * copyright notice and this permission notice appear in all copies. * * THE SOFTWARE IS PROVIDED "AS IS" AND THE AUTHOR DISCLAIMS ALL WARRANTIES * WITH REGARD TO THIS SOFTWARE INCLUDING ALL IMPLIED WARRANTIES OF * MERCHANTABILITY AND FITNESS. IN NO EVENT SHALL THE AUTHOR BE LIABLE FOR * ANY SPECIAL, DIRECT, INDIRECT, OR CONSEQUENTIAL DAMAGES OR ANY DAMAGES * WHATSOEVER RESULTING FROM LOSS OF USE, DATA OR PROFITS, WHETHER IN AN * ACTION OF CONTRACT, NEGLIGENCE OR OTHER TORTIOUS ACTION, ARISING OUT OF * OR IN CONNECTION WITH THE USE OR PERFORMANCE OF THIS SOFTWARE. */ #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include "vmd.h" #include "vmm.h" #include "atomicio.h" void vmm_sighdlr(int, short, void *); int vmm_start_vm(struct imsg *, uint32_t *, pid_t *); int vmm_dispatch_parent(int, struct privsep_proc *, struct imsg *); void vmm_run(struct privsep *, struct privsep_proc *, void *); void vmm_dispatch_vm(int, short, void *); int terminate_vm(struct vm_terminate_params *); int get_info_vm(struct privsep *, struct imsg *, int); int opentap(char *); extern struct vmd *env; static struct privsep_proc procs[] = { { "parent", PROC_PARENT, vmm_dispatch_parent }, }; void vmm(struct privsep *ps, struct privsep_proc *p) { proc_run(ps, p, procs, nitems(procs), vmm_run, NULL); } void vmm_run(struct privsep *ps, struct privsep_proc *p, void *arg) { if (config_init(ps->ps_env) == -1) fatal("failed to initialize configuration"); /* * We aren't root, so we can't chroot(2). Use unveil(2) instead. */ if (unveil(env->argv0, "x") == -1) fatal("unveil %s", env->argv0); if (unveil(NULL, NULL) == -1) fatal("unveil lock"); /* * pledge in the vmm process: * stdio - for malloc and basic I/O including events. * vmm - for the vmm ioctls and operations. * proc, exec - for forking and execing new vm's. * sendfd - for sending send/recv fds to vm proc. * recvfd - for disks, interfaces and other fds. */ if (pledge("stdio vmm sendfd recvfd proc exec", NULL) == -1) fatal("pledge"); signal_del(&ps->ps_evsigchld); signal_set(&ps->ps_evsigchld, SIGCHLD, vmm_sighdlr, ps); signal_add(&ps->ps_evsigchld, NULL); } int vmm_dispatch_parent(int fd, struct privsep_proc *p, struct imsg *imsg) { struct privsep *ps = p->p_ps; int res = 0, cmd = 0, verbose; struct vmd_vm *vm = NULL; struct vm_terminate_params vtp; struct vmop_id vid; struct vmop_result vmr; struct vmop_create_params vmc; struct vmop_addr_result var; uint32_t id = 0, peerid = imsg->hdr.peerid; pid_t pid = 0; unsigned int mode, flags; switch (imsg->hdr.type) { case IMSG_VMDOP_START_VM_REQUEST: res = config_getvm(ps, imsg); if (res == -1) { res = errno; cmd = IMSG_VMDOP_START_VM_RESPONSE; } break; case IMSG_VMDOP_START_VM_CDROM: res = config_getcdrom(ps, imsg); if (res == -1) { res = errno; cmd = IMSG_VMDOP_START_VM_RESPONSE; } break; case IMSG_VMDOP_START_VM_DISK: res = config_getdisk(ps, imsg); if (res == -1) { res = errno; cmd = IMSG_VMDOP_START_VM_RESPONSE; } break; case IMSG_VMDOP_START_VM_IF: res = config_getif(ps, imsg); if (res == -1) { res = errno; cmd = IMSG_VMDOP_START_VM_RESPONSE; } break; case IMSG_VMDOP_START_VM_END: res = vmm_start_vm(imsg, &id, &pid); /* Check if the ID can be mapped correctly */ if (res == 0 && (id = vm_id2vmid(id, NULL)) == 0) res = ENOENT; cmd = IMSG_VMDOP_START_VM_RESPONSE; break; case IMSG_VMDOP_TERMINATE_VM_REQUEST: IMSG_SIZE_CHECK(imsg, &vid); memcpy(&vid, imsg->data, sizeof(vid)); id = vid.vid_id; flags = vid.vid_flags; DPRINTF("%s: recv'ed TERMINATE_VM for %d", __func__, id); cmd = IMSG_VMDOP_TERMINATE_VM_RESPONSE; if (id == 0) { res = ENOENT; } else if ((vm = vm_getbyvmid(id)) != NULL) { if (flags & VMOP_FORCE) { vtp.vtp_vm_id = vm_vmid2id(vm->vm_vmid, vm); vm->vm_state |= VM_STATE_SHUTDOWN; (void)terminate_vm(&vtp); res = 0; } else if (!(vm->vm_state & VM_STATE_SHUTDOWN)) { log_debug("%s: sending shutdown request" " to vm %d", __func__, id); /* * Request reboot but mark the VM as shutting * down. This way we can terminate the VM after * the triple fault instead of reboot and * avoid being stuck in the ACPI-less powerdown * ("press any key to reboot") of the VM. */ vm->vm_state |= VM_STATE_SHUTDOWN; if (imsg_compose_event(&vm->vm_iev, IMSG_VMDOP_VM_REBOOT, 0, 0, -1, NULL, 0) == -1) res = errno; else res = 0; } else { /* * VM is currently being shutdown. * Check to see if the VM process is still * active. If not, return VMD_VM_STOP_INVALID. */ if (vm_vmid2id(vm->vm_vmid, vm) == 0) { log_debug("%s: no vm running anymore", __func__); res = VMD_VM_STOP_INVALID; } } } else { /* VM doesn't exist, cannot stop vm */ log_debug("%s: cannot stop vm that is not running", __func__); res = VMD_VM_STOP_INVALID; } break; case IMSG_VMDOP_GET_INFO_VM_REQUEST: res = get_info_vm(ps, imsg, 0); cmd = IMSG_VMDOP_GET_INFO_VM_END_DATA; break; case IMSG_VMDOP_CONFIG: config_getconfig(env, imsg); break; case IMSG_CTL_RESET: IMSG_SIZE_CHECK(imsg, &mode); memcpy(&mode, imsg->data, sizeof(mode)); if (mode & CONFIG_VMS) { /* Terminate and remove all VMs */ vmm_shutdown(); mode &= ~CONFIG_VMS; } config_getreset(env, imsg); break; case IMSG_CTL_VERBOSE: IMSG_SIZE_CHECK(imsg, &verbose); memcpy(&verbose, imsg->data, sizeof(verbose)); log_setverbose(verbose); /* Forward message to each VM process */ TAILQ_FOREACH(vm, env->vmd_vms, vm_entry) { imsg_compose_event(&vm->vm_iev, imsg->hdr.type, imsg->hdr.peerid, imsg->hdr.pid, -1, &verbose, sizeof(verbose)); } break; case IMSG_VMDOP_PAUSE_VM: IMSG_SIZE_CHECK(imsg, &vid); memcpy(&vid, imsg->data, sizeof(vid)); id = vid.vid_id; if ((vm = vm_getbyvmid(id)) == NULL) { res = ENOENT; cmd = IMSG_VMDOP_PAUSE_VM_RESPONSE; break; } imsg_compose_event(&vm->vm_iev, imsg->hdr.type, imsg->hdr.peerid, imsg->hdr.pid, imsg->fd, &vid, sizeof(vid)); break; case IMSG_VMDOP_UNPAUSE_VM: IMSG_SIZE_CHECK(imsg, &vid); memcpy(&vid, imsg->data, sizeof(vid)); id = vid.vid_id; if ((vm = vm_getbyvmid(id)) == NULL) { res = ENOENT; cmd = IMSG_VMDOP_UNPAUSE_VM_RESPONSE; break; } imsg_compose_event(&vm->vm_iev, imsg->hdr.type, imsg->hdr.peerid, imsg->hdr.pid, imsg->fd, &vid, sizeof(vid)); break; case IMSG_VMDOP_SEND_VM_REQUEST: IMSG_SIZE_CHECK(imsg, &vid); memcpy(&vid, imsg->data, sizeof(vid)); id = vid.vid_id; if ((vm = vm_getbyvmid(id)) == NULL) { res = ENOENT; close(imsg->fd); cmd = IMSG_VMDOP_START_VM_RESPONSE; break; } imsg_compose_event(&vm->vm_iev, imsg->hdr.type, imsg->hdr.peerid, imsg->hdr.pid, imsg->fd, &vid, sizeof(vid)); break; case IMSG_VMDOP_RECEIVE_VM_REQUEST: IMSG_SIZE_CHECK(imsg, &vmc); memcpy(&vmc, imsg->data, sizeof(vmc)); if (vm_register(ps, &vmc, &vm, imsg->hdr.peerid, vmc.vmc_owner.uid) != 0) { res = errno; cmd = IMSG_VMDOP_START_VM_RESPONSE; break; } vm->vm_tty = imsg->fd; vm->vm_state |= VM_STATE_RECEIVED; vm->vm_state |= VM_STATE_PAUSED; break; case IMSG_VMDOP_RECEIVE_VM_END: if ((vm = vm_getbyvmid(imsg->hdr.peerid)) == NULL) { res = ENOENT; close(imsg->fd); cmd = IMSG_VMDOP_START_VM_RESPONSE; break; } vm->vm_receive_fd = imsg->fd; res = vmm_start_vm(imsg, &id, &pid); /* Check if the ID can be mapped correctly */ if ((id = vm_id2vmid(id, NULL)) == 0) res = ENOENT; cmd = IMSG_VMDOP_START_VM_RESPONSE; break; case IMSG_VMDOP_PRIV_GET_ADDR_RESPONSE: IMSG_SIZE_CHECK(imsg, &var); memcpy(&var, imsg->data, sizeof(var)); if ((vm = vm_getbyvmid(var.var_vmid)) == NULL) { res = ENOENT; break; } /* Forward hardware address details to the guest vm */ imsg_compose_event(&vm->vm_iev, imsg->hdr.type, imsg->hdr.peerid, imsg->hdr.pid, imsg->fd, &var, sizeof(var)); break; case IMSG_VMDOP_RECEIVE_VMM_FD: if (env->vmd_fd > -1) fatalx("already received vmm fd"); env->vmd_fd = imsg->fd; /* Get and terminate all running VMs */ get_info_vm(ps, NULL, 1); break; default: return (-1); } switch (cmd) { case 0: break; case IMSG_VMDOP_START_VM_RESPONSE: if (res != 0) { /* Remove local reference if it exists */ if ((vm = vm_getbyvmid(imsg->hdr.peerid)) != NULL) { log_debug("%s: removing vm, START_VM_RESPONSE", __func__); vm_remove(vm, __func__); } } if (id == 0) id = imsg->hdr.peerid; /* FALLTHROUGH */ case IMSG_VMDOP_PAUSE_VM_RESPONSE: case IMSG_VMDOP_UNPAUSE_VM_RESPONSE: case IMSG_VMDOP_TERMINATE_VM_RESPONSE: memset(&vmr, 0, sizeof(vmr)); vmr.vmr_result = res; vmr.vmr_id = id; vmr.vmr_pid = pid; if (proc_compose_imsg(ps, PROC_PARENT, -1, cmd, peerid, -1, &vmr, sizeof(vmr)) == -1) return (-1); break; default: if (proc_compose_imsg(ps, PROC_PARENT, -1, cmd, peerid, -1, &res, sizeof(res)) == -1) return (-1); break; } return (0); } void vmm_sighdlr(int sig, short event, void *arg) { struct privsep *ps = arg; int status, ret = 0; uint32_t vmid; pid_t pid; struct vmop_result vmr; struct vmd_vm *vm; struct vm_terminate_params vtp; log_debug("%s: handling signal %d", __func__, sig); switch (sig) { case SIGCHLD: do { pid = waitpid(-1, &status, WNOHANG); if (pid <= 0) continue; if (WIFEXITED(status) || WIFSIGNALED(status)) { vm = vm_getbypid(pid); if (vm == NULL) { /* * If the VM is gone already, it * got terminated via a * IMSG_VMDOP_TERMINATE_VM_REQUEST. */ continue; } if (WIFEXITED(status)) ret = WEXITSTATUS(status); /* Don't reboot on pending shutdown */ if (ret == EAGAIN && (vm->vm_state & VM_STATE_SHUTDOWN)) ret = 0; vmid = vm->vm_params.vmc_params.vcp_id; vtp.vtp_vm_id = vmid; if (terminate_vm(&vtp) == 0) log_debug("%s: terminated vm %s" " (id %d)", __func__, vm->vm_params.vmc_params.vcp_name, vm->vm_vmid); memset(&vmr, 0, sizeof(vmr)); vmr.vmr_result = ret; vmr.vmr_id = vm_id2vmid(vmid, vm); if (proc_compose_imsg(ps, PROC_PARENT, -1, IMSG_VMDOP_TERMINATE_VM_EVENT, vm->vm_peerid, -1, &vmr, sizeof(vmr)) == -1) log_warnx("could not signal " "termination of VM %u to " "parent", vm->vm_vmid); vm_remove(vm, __func__); } else fatalx("unexpected cause of SIGCHLD"); } while (pid > 0 || (pid == -1 && errno == EINTR)); break; default: fatalx("unexpected signal"); } } /* * vmm_shutdown * * Terminate VMs on shutdown to avoid "zombie VM" processes. */ void vmm_shutdown(void) { struct vm_terminate_params vtp; struct vmd_vm *vm, *vm_next; TAILQ_FOREACH_SAFE(vm, env->vmd_vms, vm_entry, vm_next) { vtp.vtp_vm_id = vm_vmid2id(vm->vm_vmid, vm); /* XXX suspend or request graceful shutdown */ (void)terminate_vm(&vtp); vm_remove(vm, __func__); } } /* * vmm_pipe * * Create a new imsg control channel between vmm parent and a VM * (can be called on both sides). */ int vmm_pipe(struct vmd_vm *vm, int fd, void (*cb)(int, short, void *)) { struct imsgev *iev = &vm->vm_iev; if (fcntl(fd, F_SETFL, O_NONBLOCK) == -1) { log_warn("failed to set nonblocking mode on vm pipe"); return (-1); } imsg_init(&iev->ibuf, fd); iev->handler = cb; iev->data = vm; imsg_event_add(iev); return (0); } /* * vmm_dispatch_vm * * imsg callback for messages that are received from a VM child process. */ void vmm_dispatch_vm(int fd, short event, void *arg) { struct vmd_vm *vm = arg; struct vmop_result vmr; struct imsgev *iev = &vm->vm_iev; struct imsgbuf *ibuf = &iev->ibuf; struct imsg imsg; ssize_t n; unsigned int i; if (event & EV_READ) { if ((n = imsg_read(ibuf)) == -1 && errno != EAGAIN) fatal("%s: imsg_read", __func__); if (n == 0) { /* This pipe is dead, so remove the event handler */ event_del(&iev->ev); return; } } if (event & EV_WRITE) { if ((n = msgbuf_write(&ibuf->w)) == -1 && errno != EAGAIN) fatal("%s: msgbuf_write fd %d", __func__, ibuf->fd); if (n == 0) { /* This pipe is dead, so remove the event handler */ event_del(&iev->ev); return; } } for (;;) { if ((n = imsg_get(ibuf, &imsg)) == -1) fatal("%s: imsg_get", __func__); if (n == 0) break; DPRINTF("%s: got imsg %d from %s", __func__, imsg.hdr.type, vm->vm_params.vmc_params.vcp_name); switch (imsg.hdr.type) { case IMSG_VMDOP_VM_SHUTDOWN: vm->vm_state |= VM_STATE_SHUTDOWN; break; case IMSG_VMDOP_VM_REBOOT: vm->vm_state &= ~VM_STATE_SHUTDOWN; break; case IMSG_VMDOP_SEND_VM_RESPONSE: IMSG_SIZE_CHECK(&imsg, &vmr); case IMSG_VMDOP_PAUSE_VM_RESPONSE: case IMSG_VMDOP_UNPAUSE_VM_RESPONSE: for (i = 0; i < nitems(procs); i++) { if (procs[i].p_id == PROC_PARENT) { proc_forward_imsg(procs[i].p_ps, &imsg, PROC_PARENT, -1); break; } } break; default: fatalx("%s: got invalid imsg %d from %s", __func__, imsg.hdr.type, vm->vm_params.vmc_params.vcp_name); } imsg_free(&imsg); } imsg_event_add(iev); } /* * terminate_vm * * Requests vmm(4) to terminate the VM whose ID is provided in the * supplied vm_terminate_params structure (vtp->vtp_vm_id) * * Parameters * vtp: vm_terminate_params struct containing the ID of the VM to terminate * * Return values: * 0: success * !0: ioctl to vmm(4) failed (eg, ENOENT if the supplied VM is not valid) */ int terminate_vm(struct vm_terminate_params *vtp) { if (ioctl(env->vmd_fd, VMM_IOC_TERM, vtp) == -1) return (errno); return (0); } /* * opentap * * Opens the next available tap device, up to MAX_TAP. * * Parameters * ifname: a buffer of at least IF_NAMESIZE bytes. * * Returns a file descriptor to the tap node opened, or -1 if no tap * devices were available. */ int opentap(char *ifname) { int i, fd; char path[PATH_MAX]; for (i = 0; i < MAX_TAP; i++) { snprintf(path, PATH_MAX, "/dev/tap%d", i); fd = open(path, O_RDWR | O_NONBLOCK); if (fd != -1) { snprintf(ifname, IF_NAMESIZE, "tap%d", i); return (fd); } } strlcpy(ifname, "tap", IF_NAMESIZE); return (-1); } /* * vmm_start_vm * * Prepares and fork+execs a new VM process. * * Parameters: * imsg: The VM data structure that is including the VM create parameters. * id: Returns the VM id as reported by the kernel and obtained from the VM. * pid: Returns the VM pid to the parent. * * Return values: * 0: success * !0: failure - typically an errno indicating the source of the failure */ int vmm_start_vm(struct imsg *imsg, uint32_t *id, pid_t *pid) { struct vm_create_params *vcp; struct vmd_vm *vm; char *nargv[8], num[32], vmm_fd[32]; int fd, ret = EINVAL; int fds[2]; pid_t vm_pid; size_t i, j, sz; if ((vm = vm_getbyvmid(imsg->hdr.peerid)) == NULL) { log_warnx("%s: can't find vm", __func__); ret = ENOENT; goto err; } vcp = &vm->vm_params.vmc_params; if (!(vm->vm_state & VM_STATE_RECEIVED)) { if ((vm->vm_tty = imsg->fd) == -1) { log_warnx("%s: can't get tty", __func__); goto err; } } if (socketpair(AF_UNIX, SOCK_STREAM, PF_UNSPEC, fds) == -1) fatal("socketpair"); /* Keep our channel open after exec. */ if (fcntl(fds[1], F_SETFD, 0)) { ret = errno; log_warn("%s: fcntl", __func__); goto err; } /* Start child vmd for this VM (fork, chroot, drop privs) */ vm_pid = fork(); if (vm_pid == -1) { log_warn("%s: start child failed", __func__); ret = EIO; goto err; } if (vm_pid > 0) { /* Parent */ vm->vm_pid = vm_pid; close_fd(fds[1]); /* Send the details over the pipe to the child. */ sz = atomicio(vwrite, fds[0], vm, sizeof(*vm)); if (sz != sizeof(*vm)) { log_warnx("%s: failed to send config for vm '%s'", __func__, vcp->vcp_name); ret = EIO; /* Defer error handling until after fd closing. */ } /* As the parent/vmm process, we no longer need these fds. */ for (i = 0 ; i < vm->vm_params.vmc_ndisks; i++) { for (j = 0; j < VM_MAX_BASE_PER_DISK; j++) { if (close_fd(vm->vm_disks[i][j]) == 0) vm->vm_disks[i][j] = -1; } } for (i = 0 ; i < vm->vm_params.vmc_nnics; i++) { if (close_fd(vm->vm_ifs[i].vif_fd) == 0) vm->vm_ifs[i].vif_fd = -1; } if (close_fd(vm->vm_kernel) == 0) vm->vm_kernel = -1; if (close_fd(vm->vm_cdrom) == 0) vm->vm_cdrom = -1; if (close_fd(vm->vm_tty) == 0) vm->vm_tty = -1; /* Deferred error handling from sending the vm struct. */ if (ret == EIO) goto err; /* Read back the kernel-generated vm id from the child */ sz = atomicio(read, fds[0], &vcp->vcp_id, sizeof(vcp->vcp_id)); if (sz != sizeof(vcp->vcp_id)) { log_debug("%s: failed to receive vm id from vm %s", __func__, vcp->vcp_name); /* vmd could not allocate memory for the vm. */ ret = ENOMEM; goto err; } /* Check for an invalid id. This indicates child failure. */ if (vcp->vcp_id == 0) goto err; *id = vcp->vcp_id; *pid = vm->vm_pid; /* Wire up our pipe into the event handling. */ if (vmm_pipe(vm, fds[0], vmm_dispatch_vm) == -1) fatal("setup vm pipe"); return (0); } else { /* Child. Create a new session. */ if (setsid() == -1) fatal("setsid"); close_fd(fds[0]); close_fd(PROC_PARENT_SOCK_FILENO); /* Detach from terminal. */ if (!env->vmd_debug && (fd = open("/dev/null", O_RDWR, 0)) != -1) { dup2(fd, STDIN_FILENO); dup2(fd, STDOUT_FILENO); dup2(fd, STDERR_FILENO); if (fd > 2) close(fd); } /* Toggle all fds to not close on exec. */ for (i = 0 ; i < vm->vm_params.vmc_ndisks; i++) for (j = 0; j < VM_MAX_BASE_PER_DISK; j++) if (vm->vm_disks[i][j] != -1) fcntl(vm->vm_disks[i][j], F_SETFD, 0); for (i = 0 ; i < vm->vm_params.vmc_nnics; i++) fcntl(vm->vm_ifs[i].vif_fd, F_SETFD, 0); if (vm->vm_kernel != -1) fcntl(vm->vm_kernel, F_SETFD, 0); if (vm->vm_cdrom != -1) fcntl(vm->vm_cdrom, F_SETFD, 0); if (vm->vm_tty != -1) fcntl(vm->vm_tty, F_SETFD, 0); fcntl(env->vmd_fd, F_SETFD, 0); /* vmm device fd */ /* * Prepare our new argv for execvp(2) with the fd of our open * pipe to the parent/vmm process as an argument. */ memset(&nargv, 0, sizeof(nargv)); memset(num, 0, sizeof(num)); snprintf(num, sizeof(num), "%d", fds[1]); memset(vmm_fd, 0, sizeof(vmm_fd)); snprintf(vmm_fd, sizeof(vmm_fd), "%d", env->vmd_fd); nargv[0] = env->argv0; nargv[1] = "-V"; nargv[2] = num; nargv[3] = "-n"; nargv[4] = "-i"; nargv[5] = vmm_fd; if (env->vmd_verbose) { nargv[6] = "-v"; nargv[7] = NULL; } else nargv[6] = NULL; /* Control resumes in vmd main(). */ execvp(nargv[0], nargv); ret = errno; log_warn("execvp %s", nargv[0]); _exit(ret); /* NOTREACHED */ } return (0); err: if (!vm->vm_from_config) vm_remove(vm, __func__); return (ret); } /* * get_info_vm * * Returns a list of VMs known to vmm(4). * * Parameters: * ps: the privsep context. * imsg: the received imsg including the peer id. * terminate: terminate the listed vm. * * Return values: * 0: success * !0: failure (eg, ENOMEM, EIO or another error code from vmm(4) ioctl) */ int get_info_vm(struct privsep *ps, struct imsg *imsg, int terminate) { int ret; size_t ct, i; struct vm_info_params vip; struct vm_info_result *info; struct vm_terminate_params vtp; struct vmop_info_result vir; /* * We issue the VMM_IOC_INFO ioctl twice, once with an input * buffer size of 0, which results in vmm(4) returning the * number of bytes required back to us in vip.vip_size, * and then we call it again after malloc'ing the required * number of bytes. * * It is possible that we could fail a second time (e.g. if * another VM was created in the instant between the two * ioctls, but in that case the caller can just try again * as vmm(4) will return a zero-sized list in that case. */ vip.vip_size = 0; info = NULL; ret = 0; memset(&vir, 0, sizeof(vir)); /* First ioctl to see how many bytes needed (vip.vip_size) */ if (ioctl(env->vmd_fd, VMM_IOC_INFO, &vip) == -1) return (errno); if (vip.vip_info_ct != 0) return (EIO); info = malloc(vip.vip_size); if (info == NULL) return (ENOMEM); /* Second ioctl to get the actual list */ vip.vip_info = info; if (ioctl(env->vmd_fd, VMM_IOC_INFO, &vip) == -1) { ret = errno; free(info); return (ret); } /* Return info */ ct = vip.vip_size / sizeof(struct vm_info_result); for (i = 0; i < ct; i++) { if (terminate) { vtp.vtp_vm_id = info[i].vir_id; if ((ret = terminate_vm(&vtp)) != 0) break; log_debug("%s: terminated vm %s (id %d)", __func__, info[i].vir_name, info[i].vir_id); continue; } memcpy(&vir.vir_info, &info[i], sizeof(vir.vir_info)); vir.vir_info.vir_id = vm_id2vmid(info[i].vir_id, NULL); if (proc_compose_imsg(ps, PROC_PARENT, -1, IMSG_VMDOP_GET_INFO_VM_DATA, imsg->hdr.peerid, -1, &vir, sizeof(vir)) == -1) { ret = EIO; break; } } free(info); return (ret); }