vcpu.h (7632B)
1/* SPDX-License-Identifier: MIT */ 2/****************************************************************************** 3 * vcpu.h 4 * 5 * VCPU initialisation, query, and hotplug. 6 * 7 * Copyright (c) 2005, Keir Fraser <keir@xensource.com> 8 */ 9 10#ifndef __XEN_PUBLIC_VCPU_H__ 11#define __XEN_PUBLIC_VCPU_H__ 12 13/* 14 * Prototype for this hypercall is: 15 * int vcpu_op(int cmd, int vcpuid, void *extra_args) 16 * @cmd == VCPUOP_??? (VCPU operation). 17 * @vcpuid == VCPU to operate on. 18 * @extra_args == Operation-specific extra arguments (NULL if none). 19 */ 20 21/* 22 * Initialise a VCPU. Each VCPU can be initialised only once. A 23 * newly-initialised VCPU will not run until it is brought up by VCPUOP_up. 24 * 25 * @extra_arg == pointer to vcpu_guest_context structure containing initial 26 * state for the VCPU. 27 */ 28#define VCPUOP_initialise 0 29 30/* 31 * Bring up a VCPU. This makes the VCPU runnable. This operation will fail 32 * if the VCPU has not been initialised (VCPUOP_initialise). 33 */ 34#define VCPUOP_up 1 35 36/* 37 * Bring down a VCPU (i.e., make it non-runnable). 38 * There are a few caveats that callers should observe: 39 * 1. This operation may return, and VCPU_is_up may return false, before the 40 * VCPU stops running (i.e., the command is asynchronous). It is a good 41 * idea to ensure that the VCPU has entered a non-critical loop before 42 * bringing it down. Alternatively, this operation is guaranteed 43 * synchronous if invoked by the VCPU itself. 44 * 2. After a VCPU is initialised, there is currently no way to drop all its 45 * references to domain memory. Even a VCPU that is down still holds 46 * memory references via its pagetable base pointer and GDT. It is good 47 * practise to move a VCPU onto an 'idle' or default page table, LDT and 48 * GDT before bringing it down. 49 */ 50#define VCPUOP_down 2 51 52/* Returns 1 if the given VCPU is up. */ 53#define VCPUOP_is_up 3 54 55/* 56 * Return information about the state and running time of a VCPU. 57 * @extra_arg == pointer to vcpu_runstate_info structure. 58 */ 59#define VCPUOP_get_runstate_info 4 60struct vcpu_runstate_info { 61 /* VCPU's current state (RUNSTATE_*). */ 62 int state; 63 /* When was current state entered (system time, ns)? */ 64 uint64_t state_entry_time; 65 /* 66 * Update indicator set in state_entry_time: 67 * When activated via VMASST_TYPE_runstate_update_flag, set during 68 * updates in guest memory mapped copy of vcpu_runstate_info. 69 */ 70#define XEN_RUNSTATE_UPDATE (1ULL << 63) 71 /* 72 * Time spent in each RUNSTATE_* (ns). The sum of these times is 73 * guaranteed not to drift from system time. 74 */ 75 uint64_t time[4]; 76}; 77DEFINE_GUEST_HANDLE_STRUCT(vcpu_runstate_info); 78 79/* VCPU is currently running on a physical CPU. */ 80#define RUNSTATE_running 0 81 82/* VCPU is runnable, but not currently scheduled on any physical CPU. */ 83#define RUNSTATE_runnable 1 84 85/* VCPU is blocked (a.k.a. idle). It is therefore not runnable. */ 86#define RUNSTATE_blocked 2 87 88/* 89 * VCPU is not runnable, but it is not blocked. 90 * This is a 'catch all' state for things like hotplug and pauses by the 91 * system administrator (or for critical sections in the hypervisor). 92 * RUNSTATE_blocked dominates this state (it is the preferred state). 93 */ 94#define RUNSTATE_offline 3 95 96/* 97 * Register a shared memory area from which the guest may obtain its own 98 * runstate information without needing to execute a hypercall. 99 * Notes: 100 * 1. The registered address may be virtual or physical, depending on the 101 * platform. The virtual address should be registered on x86 systems. 102 * 2. Only one shared area may be registered per VCPU. The shared area is 103 * updated by the hypervisor each time the VCPU is scheduled. Thus 104 * runstate.state will always be RUNSTATE_running and 105 * runstate.state_entry_time will indicate the system time at which the 106 * VCPU was last scheduled to run. 107 * @extra_arg == pointer to vcpu_register_runstate_memory_area structure. 108 */ 109#define VCPUOP_register_runstate_memory_area 5 110struct vcpu_register_runstate_memory_area { 111 union { 112 GUEST_HANDLE(vcpu_runstate_info) h; 113 struct vcpu_runstate_info *v; 114 uint64_t p; 115 } addr; 116}; 117 118/* 119 * Set or stop a VCPU's periodic timer. Every VCPU has one periodic timer 120 * which can be set via these commands. Periods smaller than one millisecond 121 * may not be supported. 122 */ 123#define VCPUOP_set_periodic_timer 6 /* arg == vcpu_set_periodic_timer_t */ 124#define VCPUOP_stop_periodic_timer 7 /* arg == NULL */ 125struct vcpu_set_periodic_timer { 126 uint64_t period_ns; 127}; 128DEFINE_GUEST_HANDLE_STRUCT(vcpu_set_periodic_timer); 129 130/* 131 * Set or stop a VCPU's single-shot timer. Every VCPU has one single-shot 132 * timer which can be set via these commands. 133 */ 134#define VCPUOP_set_singleshot_timer 8 /* arg == vcpu_set_singleshot_timer_t */ 135#define VCPUOP_stop_singleshot_timer 9 /* arg == NULL */ 136struct vcpu_set_singleshot_timer { 137 uint64_t timeout_abs_ns; 138 uint32_t flags; /* VCPU_SSHOTTMR_??? */ 139}; 140DEFINE_GUEST_HANDLE_STRUCT(vcpu_set_singleshot_timer); 141 142/* Flags to VCPUOP_set_singleshot_timer. */ 143 /* Require the timeout to be in the future (return -ETIME if it's passed). */ 144#define _VCPU_SSHOTTMR_future (0) 145#define VCPU_SSHOTTMR_future (1U << _VCPU_SSHOTTMR_future) 146 147/* 148 * Register a memory location in the guest address space for the 149 * vcpu_info structure. This allows the guest to place the vcpu_info 150 * structure in a convenient place, such as in a per-cpu data area. 151 * The pointer need not be page aligned, but the structure must not 152 * cross a page boundary. 153 */ 154#define VCPUOP_register_vcpu_info 10 /* arg == struct vcpu_info */ 155struct vcpu_register_vcpu_info { 156 uint64_t mfn; /* mfn of page to place vcpu_info */ 157 uint32_t offset; /* offset within page */ 158 uint32_t rsvd; /* unused */ 159}; 160DEFINE_GUEST_HANDLE_STRUCT(vcpu_register_vcpu_info); 161 162/* Send an NMI to the specified VCPU. @extra_arg == NULL. */ 163#define VCPUOP_send_nmi 11 164 165/* 166 * Get the physical ID information for a pinned vcpu's underlying physical 167 * processor. The physical ID informmation is architecture-specific. 168 * On x86: id[31:0]=apic_id, id[63:32]=acpi_id. 169 * This command returns -EINVAL if it is not a valid operation for this VCPU. 170 */ 171#define VCPUOP_get_physid 12 /* arg == vcpu_get_physid_t */ 172struct vcpu_get_physid { 173 uint64_t phys_id; 174}; 175DEFINE_GUEST_HANDLE_STRUCT(vcpu_get_physid); 176#define xen_vcpu_physid_to_x86_apicid(physid) ((uint32_t)(physid)) 177#define xen_vcpu_physid_to_x86_acpiid(physid) ((uint32_t)((physid) >> 32)) 178 179/* 180 * Register a memory location to get a secondary copy of the vcpu time 181 * parameters. The master copy still exists as part of the vcpu shared 182 * memory area, and this secondary copy is updated whenever the master copy 183 * is updated (and using the same versioning scheme for synchronisation). 184 * 185 * The intent is that this copy may be mapped (RO) into userspace so 186 * that usermode can compute system time using the time info and the 187 * tsc. Usermode will see an array of vcpu_time_info structures, one 188 * for each vcpu, and choose the right one by an existing mechanism 189 * which allows it to get the current vcpu number (such as via a 190 * segment limit). It can then apply the normal algorithm to compute 191 * system time from the tsc. 192 * 193 * @extra_arg == pointer to vcpu_register_time_info_memory_area structure. 194 */ 195#define VCPUOP_register_vcpu_time_memory_area 13 196DEFINE_GUEST_HANDLE_STRUCT(vcpu_time_info); 197struct vcpu_register_time_memory_area { 198 union { 199 GUEST_HANDLE(vcpu_time_info) h; 200 struct pvclock_vcpu_time_info *v; 201 uint64_t p; 202 } addr; 203}; 204DEFINE_GUEST_HANDLE_STRUCT(vcpu_register_time_memory_area); 205 206#endif /* __XEN_PUBLIC_VCPU_H__ */