crosvm_plugin/crosvm.h - chromiumos/platform/crosvm - Git at Google

 /*
  * Copyright 2017 The Chromium OS Authors. All rights reserved.
  * Use of this source code is governed by a BSD-style license that can be
  * found in the LICENSE file.
  */

 #ifndef __CROSVM_H__
 #define __CROSVM_H__

 #include <assert.h>
 #include <stdint.h>
 #include <stdbool.h>

 #include <linux/kvm.h>

 #ifdef  __cplusplus
 extern "C" {
 #endif

 /*
  * This module is used to implement a plugin for crosvm.
  *
  * A plugin for crosvm interfaces with the virtual machine using the `struct
  * crosvm` object and its child objects. A typical plugin is expected to call
  * `crosvm_connect`, perform some amount of setup with the functions defined
  * here, get a handle to every vcpu using `struct crosvm_vcpu` and then call
  * `crosvm_start`. Each vcpu will then be waited on with `crosvm_vcpu_wait`,
  * each event will be responded to by the plugin, and then the vcpu is resumed
  * with `crosvm_vcpu_resume`. The vcpu state can only be examined and modified
  * between the `crosvm_vcpu_wait` and `crosvm_vcpu_resume` calls. The crosvm
  * connection can be used to modify global virtual machine state at any time,
  * with some structural restrictions after `crosvm_start` is called.
  *
  * In general, functions that return an `int` return 0 on success or a non-
  * negative file descriptor if one is expected. A negative return value is an
  * errno and indicates error. Functions that take a pointer-to-pointer to an
  * opaque structure either return a structure or delete and nullify that
  * structure pointer.
  */

 /*
  * We use Semantic Versioning (http://semver.org/) here, which means that as
  * long as MAJOR is 0, breaking changes can occur, but once MAJOR is non-zero, a
  * breaking change requires a MAJOR version bump. The MINOR number increases as
  * backward compatible functionality is added. The PATCH number increases bug
  * fixes are done. The version numbers indicate here are for the plugin API and
  * do not indicate anything about what version of crosvm is running.
  */
 #define CROSVM_API_MAJOR 0
 #define CROSVM_API_MINOR 17
 #define CROSVM_API_PATCH 0

 enum crosvm_address_space {
   /* I/O port */
   CROSVM_ADDRESS_SPACE_IOPORT = 0,
   /* physical memory space */
   CROSVM_ADDRESS_SPACE_MMIO,
 };

 /* Handle to the parent crosvm process. */
 struct crosvm;

 /* Handle to a register ioeventfd. */
 struct crosvm_io;

 /* Handle to a registered range of shared memory. */
 struct crosvm_memory;

 /* Handle to a registered irqfd. */
 struct crosvm_irq;

 /* Handle to one of the VM's VCPUs. */
 struct crosvm_vcpu;

 /*
  * Connects to the parent crosvm process and returns a new `struct crosvm`
  * interface object.
  *
  * This is the entry point for interfacing with crosvm as a plugin. This should
  * be called before any other function. The returned object is not-thread safe.
  */
 int crosvm_connect(struct crosvm**);

 /*
  * Creates another connection for interfacing with crosvm concurrently.
  *
  * The new connection behaves exactly like the original `struct crosvm` but can
  * be used concurrently on a different thread than the original. Actual
  * execution order of the requests to crosvm is unspecified but every request is
  * completed when the `crosvm_*` call returns.
  *
  * It is invalid to call this after `crosvm_start` is called on any `struct
  * crosvm`.
  */
 int crosvm_new_connection(struct crosvm*, struct crosvm**);

 /*
  * Destroys this connection and tells the parent crosvm process to stop
  * listening for messages from it.
  */
 int crosvm_destroy_connection(struct crosvm**);

 /*
  * Gets an eventfd that is triggered when this plugin should exit.
  *
  * The returned eventfd is owned by the caller but the underlying event is
  * shared and will therefore only trigger once.
  */
 int crosvm_get_shutdown_eventfd(struct crosvm*);

 /*
  * Gets a bool indicating if a KVM_CAP_* enum is supported on this VM
  */
 int crosvm_check_extension(struct crosvm*, uint32_t __extension,
                            bool *has_extension);

 /*
  * Queries x86 cpuid features which are supported by the hardware and
  * kvm.
  */
 int crosvm_get_supported_cpuid(struct crosvm*, uint32_t __entry_count,
                                struct kvm_cpuid_entry2 *__cpuid_entries,
                                uint32_t *__out_count);

 /*
  * Queries x86 cpuid features which are emulated by kvm.
  */
 int crosvm_get_emulated_cpuid(struct crosvm*, uint32_t __entry_count,
                               struct kvm_cpuid_entry2 *__cpuid_entries,
                               uint32_t *__out_count);

 /*
  * Queries kvm for list of supported MSRs.
  */
 int crosvm_get_msr_index_list(struct crosvm*, uint32_t __entry_count,
                               uint32_t *__msr_indices,
                               uint32_t *__out_count);

 /*
  * The network configuration for a crosvm instance.
  */
 struct crosvm_net_config {
   /*
    * The tap device fd. This fd is owned by the caller, and should be closed
    * by the caller when it is no longer in use.
    */
   int tap_fd;
   /* The IPv4 address of the tap interface, in network (big-endian) format. */
   uint32_t host_ip;
   /* The netmask of the tap interface subnet, in network (big-endian) format. */
   uint32_t netmask;
   /* The mac address of the host side of the tap interface. */
   uint8_t host_mac_address[6];
   uint8_t _padding[2];
 };

 #ifdef static_assert
 static_assert(sizeof(struct crosvm_net_config) == 20,
               "extra padding in struct crosvm_net_config");
 #endif

 /*
  * Gets the network configuration.
  */
 int crosvm_net_get_config(struct crosvm*, struct crosvm_net_config*);

 /*
  * Registers a range in the given address space that, when accessed, will block
  * and wait for a crosvm_vcpu_resume call.
  *
  * To unreserve a range previously reserved by this function, pass the |__space|
  * and |__start| of the old reservation with a 0 |__length|.
  */
 int crosvm_reserve_range(struct crosvm*, uint32_t __space, uint64_t __start,
                          uint64_t __length);

 /*
  * Sets the state of the given irq pin.
  */
 int crosvm_set_irq(struct crosvm*, uint32_t __irq_id, bool __active);

 enum crosvm_irq_route_kind {
   /* IRQ pin to GSI route */
   CROSVM_IRQ_ROUTE_IRQCHIP = 0,
   /* MSI address and data to GSI route */
   CROSVM_IRQ_ROUTE_MSI,
 };

 /* One entry in the array of irq routing table */
 struct crosvm_irq_route {
   /* The IRQ number to trigger. */
   uint32_t irq_id;
   /* A `crosvm_irq_route_kind` indicating which union member to use */
   uint32_t kind;
   union {
     struct {
       /*
        * One of KVM_IRQCHIP_PIC_MASTER, KVM_IRQCHIP_PIC_SLAVE, or
        * KVM_IRQCHIP_IOAPIC indicating which irqchip the indicated pin is on.
        */
       uint32_t irqchip;
       /* The pin on the irqchip used to trigger the IRQ. */
       uint32_t pin;
     } irqchip;

     struct {
       /* Address that triggers the irq. */
       uint64_t address;
       /* Data written to `address` that triggers the irq */
       uint32_t data;

       uint8_t _reserved[4];
     } msi;

     uint8_t _reserved[16];
   };
 };

 #ifdef static_assert
 static_assert(sizeof(struct crosvm_irq_route) == 24,
               "extra padding in struct crosvm_irq_route");
 #endif

 /*
  * Sets all the gsi routing entries to those indicated by `routes`.
  *
  * To remove all routing entries, pass NULL for `routes` and 0 to route_count.
  */
 int crosvm_set_irq_routing(struct crosvm*, uint32_t __route_count,
                            const struct crosvm_irq_route* __routes);

 /* Gets the state of interrupt controller in a VM. */
 int crosvm_get_pic_state(struct crosvm *, bool __primary,
                          struct kvm_pic_state *__pic_state);

 /* Sets the state of interrupt controller in a VM. */
 int crosvm_set_pic_state(struct crosvm *, bool __primary,
                          struct kvm_pic_state *__pic_state);

 /* Gets the state of IOAPIC in a VM. */
 int crosvm_get_ioapic_state(struct crosvm *,
                             struct kvm_ioapic_state *__ioapic_state);

 /* Sets the state of IOAPIC in a VM. */
 int crosvm_set_ioapic_state(struct crosvm *,
                             struct kvm_ioapic_state *__ioapic_state);

 /* Gets the state of interrupt controller in a VM. */
 int crosvm_get_pit_state(struct crosvm *, struct kvm_pit_state2 *__pit_state);

 /* Sets the state of interrupt controller in a VM. */
 int crosvm_set_pit_state(struct crosvm *,
                          const struct kvm_pit_state2 *__pit_state);

 /* Gets the current timestamp of kvmclock as seen by the VM. */
 int crosvm_get_clock(struct crosvm *, struct kvm_clock_data *__clock_data);

 /* Sets the current timestamp of kvmclock for the VM. */
 int crosvm_set_clock(struct crosvm *,
                      const struct kvm_clock_data *__clock_data);

 /* Sets the identity map address as in the KVM_SET_IDENTITY_MAP_ADDR ioctl. */
 int crosvm_set_identity_map_addr(struct crosvm*, uint32_t __addr);

 /*
  * Triggers a CROSVM_VCPU_EVENT_KIND_PAUSED event on each vcpu identified
  * |__cpu_mask|.
  *
  * The `user` pointer will be given as the `user` pointer in the `struct
  * crosvm_vcpu_event` returned by crosvm_vcpu_wait.
  */
 int crosvm_pause_vcpus(struct crosvm*, uint64_t __cpu_mask, void* __user);

 /*
  * Call once initialization is done. This indicates that crosvm should proceed
  * with running the VM.
  *
  * After this call, this function is no longer valid to call.
  */
 int crosvm_start(struct crosvm*);

 /*
  * Registers an eventfd that is triggered asynchronously on write in |__space|
  * at the given |__addr|.
  *
  * If |__datamatch| is non-NULL, it must be contain |__length| bytes that will
  * be compared to the bytes being written by the vcpu which will only trigger
  * the eventfd if equal. If datamatch is NULL all writes to the address will
  * trigger the eventfd.
  *
  * On successful registration, returns a non-negative eventfd owned by the
  * caller.
  */
 int crosvm_create_io_event(struct crosvm*, uint32_t __space, uint64_t __addr,
                            uint32_t __len, const uint8_t* __datamatch,
                            struct crosvm_io**);

 /*
  * Destroys the given io event and unregisters it from the VM.
  */
 int crosvm_destroy_io_event(struct crosvm*, struct crosvm_io**);

 /*
  * Gets the eventfd triggered by the given io event.
  *
  * The returned fd is owned by the given `struct crosvm_io` and has a lifetime
  * equal to that handle.
  */
 int crosvm_io_event_fd(struct crosvm_io*);

 /*
  * Creates a shared memory segment backed by a memfd.
  *
  * Inserts non-overlapping memory pages in the guest physical address range
  * specified by |__start| address and |__length| bytes. The memory pages are
  * backed by the memfd |__fd| and are taken starting at |__offset| bytes from
  * the beginning of the memfd.
  *
  * The `memfd_create` syscall |__fd| must be used to create |__fd| and a shrink
  * seal must have been added to |__fd|. The memfd must be at least
  * `__length+__offset` bytes long.
  *
  * If |read_only| is true, attempts by the guest to write to this memory region
  * will trigger an IO access exit.
  *
  * To use the `crosvm_memory_get_dirty_log` method with the returned object,
  * |__dirty_log| must be true.
  */
 int crosvm_create_memory(struct crosvm*, int __fd, uint64_t __offset,
                          uint64_t __length, uint64_t __start,
                          bool __read_only, bool __dirty_log,
                          struct crosvm_memory**);

 /*
  * Destroys the given shared memory and unregisters it from guest physical
  * address space.
  */
 int crosvm_destroy_memory(struct crosvm*, struct crosvm_memory**);

 /*
  * For a given memory region returns a bitmap containing any pages
  * dirtied since the last call to this function.
  *
  * The `log` array must have as many bits as the memory segment has pages.
  */
 int crosvm_memory_get_dirty_log(struct crosvm*, struct crosvm_memory*,
                                 uint8_t* __log);

 /*
  * Creates an irq eventfd that can be used to trigger an irq asynchronously.
  *
  * The irq that will be triggered is identified as pin |__irq_id|.
  */
 int crosvm_create_irq_event(struct crosvm*, uint32_t __irq_id,
                             struct crosvm_irq**);

 /*
  * Unregisters and destroys an irq eventfd.
  */
 int crosvm_destroy_irq_event(struct crosvm*, struct crosvm_irq**);

 /*
  * Gets the eventfd used to trigger the irq
  *
  * The returned fd is owned by the given `struct crosvm_irq` and has a lifetime
  * equal to that handle.
  */
 int crosvm_irq_event_get_fd(const struct crosvm_irq*);

 /*
  * Gets the resample eventfd associated with the crosvm_irq object.
  */
 int crosvm_irq_event_get_resample_fd(const struct crosvm_irq*);

 enum crosvm_vcpu_event_kind {
   /*
    * The first event returned by crosvm_vcpu_wait, indicating the VCPU has been
    * created but not yet started for the first time.
    */
   CROSVM_VCPU_EVENT_KIND_INIT = 0,

   /*
    * Access to an address in a space previously reserved by
    * crosvm_reserve_range.
    */
   CROSVM_VCPU_EVENT_KIND_IO_ACCESS,

   /*
    * A pause on this vcpu (and possibly others) was requested by this plugin in
    * a `crosvm_pause_vcpus` call.
    */
   CROSVM_VCPU_EVENT_KIND_PAUSED,
 };

 struct crosvm_vcpu_event {
   /* Indicates the kind of event and which union member is valid. */
   uint32_t kind;

   uint8_t _padding[4];

   union {
     /* CROSVM_VCPU_EVENT_KIND_IO_ACCESS */
     struct {
       /*
        * One of `enum crosvm_address_space` indicating which address space the
        * access occurred in.
        */
       uint32_t address_space;

       uint8_t _padding[4];

       /* The address that the access occurred at. */
       uint64_t address;

       /*
        * In the case that `is_write` is true, the first `length` bytes are the
        * data being written by the vcpu.
        */
       uint8_t *data;

       /*
        * Number of bytes in the access. In the case that the access is larger
        * than 8 bytes, such as by AVX-512 instructions, multiple vcpu access
        * events are generated serially to cover each 8 byte fragment of the
        * access.
        */
       uint32_t length;

       /*
        * True if the vcpu was attempting to write, false in case of an attempt
        * to read.
        */
       uint8_t is_write;

       uint8_t _reserved[3];
     } io_access;

     /* CROSVM_VCPU_EVENT_KIND_USER */
     void *user;

     uint8_t _reserved[64];
   };
 };

 #ifdef static_assert
 static_assert(sizeof(struct crosvm_vcpu_event) == 72,
               "extra padding in struct crosvm_vcpu_event");
 #endif

 /*
  * Gets the vcpu object for the given |__cpu_id|.
  *
  *
  * The `struct crosvm_vcpu` is owned by `struct crosvm`. Each call with the same
  * `crosvm` and |__cpu_id| will yield the same pointer. The `crosvm_vcpu` does
  * not need to be destroyed or created explicitly.
  *
  * The range of valid |__cpu_id|s is 0 to the number of vcpus - 1. To get every
  * `crosvm_vcpu`, simply call this function iteratively with increasing
  * |__cpu_id| until `-ENOENT` is returned.
  *
  */
 int crosvm_get_vcpu(struct crosvm*, uint32_t __cpu_id, struct crosvm_vcpu**);

 /*
  * Blocks until a vcpu event happens that requires a response.
  *
  * When crosvm_vcpu_wait returns successfully, the event structure is filled
  * with the description of the event that occurred. The vcpu will suspend
  * execution until a matching call to `crosvm_vcpu_resume` is made. Until such a
  * call is made, the vcpu's run structure can be read and written using any
  * `crosvm_vcpu_get` or `crosvm_vcpu_set` function.
  */
 int crosvm_vcpu_wait(struct crosvm_vcpu*, struct crosvm_vcpu_event*);

 /*
  * Resumes execution of a vcpu after a call to `crosvm_vcpu_wait` returns.
  *
  * In the case that the event was a read operation, `data` indicates what the
  * result of that read operation should be. If the read operation was larger
  * than 8 bytes, such as by AVX-512 instructions, this will not actually resume
  * the vcpu, but instead generate another vcpu access event of the next fragment
  * of the read, which can be handled by the next `crosvm_vcpu_wait` call.
  *
  * Once the vcpu event has been responded to sufficiently enough to resume
  * execution, `crosvm_vcpu_resume` should be called. After `crosvm_vcpu_resume`
  * is called, none of the vcpu state operations are valid until the next time
  * `crosvm_vcpu_wait` returns.
  */
 int crosvm_vcpu_resume(struct crosvm_vcpu*);

 /* Gets the state of the vcpu's registers. */
 int crosvm_vcpu_get_regs(struct crosvm_vcpu*, struct kvm_regs*);
 /* Sets the state of the vcpu's registers. */
 int crosvm_vcpu_set_regs(struct crosvm_vcpu*, const struct kvm_regs*);

 /* Gets the state of the vcpu's special registers. */
 int crosvm_vcpu_get_sregs(struct crosvm_vcpu*, struct kvm_sregs*);
 /* Sets the state of the vcpu's special registers. */
 int crosvm_vcpu_set_sregs(struct crosvm_vcpu*, const struct kvm_sregs*);

 /* Gets the state of the vcpu's floating point unint. */
 int crosvm_vcpu_get_fpu(struct crosvm_vcpu*, struct kvm_fpu*);
 /* Sets the state of the vcpu's floating point unint. */
 int crosvm_vcpu_set_fpu(struct crosvm_vcpu*, const struct kvm_fpu*);

 /* Gets the state of the vcpu's debug registers. */
 int crosvm_vcpu_get_debugregs(struct crosvm_vcpu*, struct kvm_debugregs*);
 /* Sets the state of the vcpu's debug registers */
 int crosvm_vcpu_set_debugregs(struct crosvm_vcpu*, const struct kvm_debugregs*);

 /* Gets the state of the vcpu's xcr registers. */
 int crosvm_vcpu_get_xcrs(struct crosvm_vcpu*, struct kvm_xcrs*);
 /* Sets the state of the vcpu's xcr registers. */
 int crosvm_vcpu_set_xcrs(struct crosvm_vcpu*, const struct kvm_xcrs*);

 /* Gets the MSRs of the vcpu indicated by the index field of each entry. */
 int crosvm_vcpu_get_msrs(struct crosvm_vcpu*, uint32_t __msr_count,
                          struct kvm_msr_entry *__msr_entries,
                          uint32_t *__out_count);
 /* Sets the MSRs of the vcpu indicated by the index field of each entry. */
 int crosvm_vcpu_set_msrs(struct crosvm_vcpu*, uint32_t __msr_count,
                          const struct kvm_msr_entry *__msr_entries);

 /* Sets the responses to the cpuid instructions executed on this vcpu, */
 int crosvm_vcpu_set_cpuid(struct crosvm_vcpu*, uint32_t __cpuid_count,
                           const struct kvm_cpuid_entry2 *__cpuid_entries);

 /* Gets state of LAPIC of the VCPU. */
 int crosvm_vcpu_get_lapic_state(struct crosvm_vcpu *,
                                 struct kvm_lapic_state *__lapic_state);
 /* Sets state of LAPIC of the VCPU. */
 int crosvm_vcpu_set_lapic_state(struct crosvm_vcpu *,
                                 const struct kvm_lapic_state *__lapic_state);

 /* Gets the "multiprocessor state" of given VCPU. */
 int crosvm_vcpu_get_mp_state(struct crosvm_vcpu *,
                              struct kvm_mp_state *__mp_state);
 /* Sets the "multiprocessor state" of given VCPU. */
 int crosvm_vcpu_set_mp_state(struct crosvm_vcpu *,
                              const struct kvm_mp_state *__mp_state);

 /* Gets currently pending exceptions, interrupts, NMIs, etc for VCPU. */
 int crosvm_vcpu_get_vcpu_events(struct crosvm_vcpu *,
                                 struct kvm_vcpu_events *);

 /* Sets currently pending exceptions, interrupts, NMIs, etc for VCPU. */
 int crosvm_vcpu_set_vcpu_events(struct crosvm_vcpu *,
                                 const struct kvm_vcpu_events *);

 #ifdef  __cplusplus
 }
 #endif

 #endif
	/*
	* Copyright 2017 The Chromium OS Authors. All rights reserved.
	* Use of this source code is governed by a BSD-style license that can be
	* found in the LICENSE file.
	*/

	#ifndef __CROSVM_H__
	#define __CROSVM_H__

	#include <assert.h>
	#include <stdint.h>
	#include <stdbool.h>

	#include <linux/kvm.h>

	#ifdef __cplusplus
	extern "C" {
	#endif

	/*
	* This module is used to implement a plugin for crosvm.
	*
	* A plugin for crosvm interfaces with the virtual machine using the `struct
	* crosvm` object and its child objects. A typical plugin is expected to call
	* `crosvm_connect`, perform some amount of setup with the functions defined
	* here, get a handle to every vcpu using `struct crosvm_vcpu` and then call
	* `crosvm_start`. Each vcpu will then be waited on with `crosvm_vcpu_wait`,
	* each event will be responded to by the plugin, and then the vcpu is resumed
	* with `crosvm_vcpu_resume`. The vcpu state can only be examined and modified
	* between the `crosvm_vcpu_wait` and `crosvm_vcpu_resume` calls. The crosvm
	* connection can be used to modify global virtual machine state at any time,
	* with some structural restrictions after `crosvm_start` is called.
	*
	* In general, functions that return an `int` return 0 on success or a non-
	* negative file descriptor if one is expected. A negative return value is an
	* errno and indicates error. Functions that take a pointer-to-pointer to an
	* opaque structure either return a structure or delete and nullify that
	* structure pointer.
	*/

	/*
	* We use Semantic Versioning (http://semver.org/) here, which means that as
	* long as MAJOR is 0, breaking changes can occur, but once MAJOR is non-zero, a
	* breaking change requires a MAJOR version bump. The MINOR number increases as
	* backward compatible functionality is added. The PATCH number increases bug
	* fixes are done. The version numbers indicate here are for the plugin API and
	* do not indicate anything about what version of crosvm is running.
	*/
	#define CROSVM_API_MAJOR 0
	#define CROSVM_API_MINOR 17
	#define CROSVM_API_PATCH 0

	enum crosvm_address_space {
	/* I/O port */
	CROSVM_ADDRESS_SPACE_IOPORT = 0,
	/* physical memory space */
	CROSVM_ADDRESS_SPACE_MMIO,
	};

	/* Handle to the parent crosvm process. */
	struct crosvm;

	/* Handle to a register ioeventfd. */
	struct crosvm_io;

	/* Handle to a registered range of shared memory. */
	struct crosvm_memory;

	/* Handle to a registered irqfd. */
	struct crosvm_irq;

	/* Handle to one of the VM's VCPUs. */
	struct crosvm_vcpu;

	/*
	* Connects to the parent crosvm process and returns a new `struct crosvm`
	* interface object.
	*
	* This is the entry point for interfacing with crosvm as a plugin. This should
	* be called before any other function. The returned object is not-thread safe.
	*/
	int crosvm_connect(struct crosvm**);

	/*
	* Creates another connection for interfacing with crosvm concurrently.
	*
	* The new connection behaves exactly like the original `struct crosvm` but can
	* be used concurrently on a different thread than the original. Actual
	* execution order of the requests to crosvm is unspecified but every request is
	* completed when the `crosvm_*` call returns.
	*
	* It is invalid to call this after `crosvm_start` is called on any `struct
	* crosvm`.
	*/
	int crosvm_new_connection(struct crosvm, struct crosvm*);

	/*
	* Destroys this connection and tells the parent crosvm process to stop
	* listening for messages from it.
	*/
	int crosvm_destroy_connection(struct crosvm**);

	/*
	* Gets an eventfd that is triggered when this plugin should exit.
	*
	* The returned eventfd is owned by the caller but the underlying event is
	* shared and will therefore only trigger once.
	*/
	int crosvm_get_shutdown_eventfd(struct crosvm*);

	/*
	* Gets a bool indicating if a KVM_CAP_* enum is supported on this VM
	*/
	int crosvm_check_extension(struct crosvm*, uint32_t __extension,
	bool *has_extension);

	/*
	* Queries x86 cpuid features which are supported by the hardware and
	* kvm.
	*/
	int crosvm_get_supported_cpuid(struct crosvm*, uint32_t __entry_count,
	struct kvm_cpuid_entry2 *__cpuid_entries,
	uint32_t *__out_count);

	/*
	* Queries x86 cpuid features which are emulated by kvm.
	*/
	int crosvm_get_emulated_cpuid(struct crosvm*, uint32_t __entry_count,
	struct kvm_cpuid_entry2 *__cpuid_entries,
	uint32_t *__out_count);

	/*
	* Queries kvm for list of supported MSRs.
	*/
	int crosvm_get_msr_index_list(struct crosvm*, uint32_t __entry_count,
	uint32_t *__msr_indices,
	uint32_t *__out_count);

	/*
	* The network configuration for a crosvm instance.
	*/
	struct crosvm_net_config {
	/*
	* The tap device fd. This fd is owned by the caller, and should be closed
	* by the caller when it is no longer in use.
	*/
	int tap_fd;
	/* The IPv4 address of the tap interface, in network (big-endian) format. */
	uint32_t host_ip;
	/* The netmask of the tap interface subnet, in network (big-endian) format. */
	uint32_t netmask;
	/* The mac address of the host side of the tap interface. */
	uint8_t host_mac_address[6];
	uint8_t _padding[2];
	};

	#ifdef static_assert
	static_assert(sizeof(struct crosvm_net_config) == 20,
	"extra padding in struct crosvm_net_config");
	#endif

	/*
	* Gets the network configuration.
	*/
	int crosvm_net_get_config(struct crosvm, struct crosvm_net_config);

	/*
	* Registers a range in the given address space that, when accessed, will block
	* and wait for a crosvm_vcpu_resume call.
	*
	* To unreserve a range previously reserved by this function, pass the \|__space\|
	* and \|__start\| of the old reservation with a 0 \|__length\|.
	*/
	int crosvm_reserve_range(struct crosvm*, uint32_t __space, uint64_t __start,
	uint64_t __length);

	/*
	* Sets the state of the given irq pin.
	*/
	int crosvm_set_irq(struct crosvm*, uint32_t __irq_id, bool __active);

	enum crosvm_irq_route_kind {
	/* IRQ pin to GSI route */
	CROSVM_IRQ_ROUTE_IRQCHIP = 0,
	/* MSI address and data to GSI route */
	CROSVM_IRQ_ROUTE_MSI,
	};

	/* One entry in the array of irq routing table */
	struct crosvm_irq_route {
	/* The IRQ number to trigger. */
	uint32_t irq_id;
	/* A `crosvm_irq_route_kind` indicating which union member to use */
	uint32_t kind;
	union {
	struct {
	/*
	* One of KVM_IRQCHIP_PIC_MASTER, KVM_IRQCHIP_PIC_SLAVE, or
	* KVM_IRQCHIP_IOAPIC indicating which irqchip the indicated pin is on.
	*/
	uint32_t irqchip;
	/* The pin on the irqchip used to trigger the IRQ. */
	uint32_t pin;
	} irqchip;

	struct {
	/* Address that triggers the irq. */
	uint64_t address;
	/* Data written to `address` that triggers the irq */
	uint32_t data;

	uint8_t _reserved[4];
	} msi;

	uint8_t _reserved[16];
	};
	};

	#ifdef static_assert
	static_assert(sizeof(struct crosvm_irq_route) == 24,
	"extra padding in struct crosvm_irq_route");
	#endif

	/*
	* Sets all the gsi routing entries to those indicated by `routes`.
	*
	* To remove all routing entries, pass NULL for `routes` and 0 to route_count.
	*/
	int crosvm_set_irq_routing(struct crosvm*, uint32_t __route_count,
	const struct crosvm_irq_route* __routes);

	/* Gets the state of interrupt controller in a VM. */
	int crosvm_get_pic_state(struct crosvm *, bool __primary,
	struct kvm_pic_state *__pic_state);

	/* Sets the state of interrupt controller in a VM. */
	int crosvm_set_pic_state(struct crosvm *, bool __primary,
	struct kvm_pic_state *__pic_state);

	/* Gets the state of IOAPIC in a VM. */
	int crosvm_get_ioapic_state(struct crosvm *,
	struct kvm_ioapic_state *__ioapic_state);

	/* Sets the state of IOAPIC in a VM. */
	int crosvm_set_ioapic_state(struct crosvm *,
	struct kvm_ioapic_state *__ioapic_state);

	/* Gets the state of interrupt controller in a VM. */
	int crosvm_get_pit_state(struct crosvm , struct kvm_pit_state2 __pit_state);

	/* Sets the state of interrupt controller in a VM. */
	int crosvm_set_pit_state(struct crosvm *,
	const struct kvm_pit_state2 *__pit_state);

	/* Gets the current timestamp of kvmclock as seen by the VM. */
	int crosvm_get_clock(struct crosvm , struct kvm_clock_data __clock_data);

	/* Sets the current timestamp of kvmclock for the VM. */
	int crosvm_set_clock(struct crosvm *,
	const struct kvm_clock_data *__clock_data);

	/* Sets the identity map address as in the KVM_SET_IDENTITY_MAP_ADDR ioctl. */
	int crosvm_set_identity_map_addr(struct crosvm*, uint32_t __addr);

	/*
	* Triggers a CROSVM_VCPU_EVENT_KIND_PAUSED event on each vcpu identified
	* \|__cpu_mask\|.
	*
	* The `user` pointer will be given as the `user` pointer in the `struct
	* crosvm_vcpu_event` returned by crosvm_vcpu_wait.
	*/
	int crosvm_pause_vcpus(struct crosvm, uint64_t __cpu_mask, void __user);

	/*
	* Call once initialization is done. This indicates that crosvm should proceed
	* with running the VM.
	*
	* After this call, this function is no longer valid to call.
	*/
	int crosvm_start(struct crosvm*);

	/*
	* Registers an eventfd that is triggered asynchronously on write in \|__space\|
	* at the given \|__addr\|.
	*
	* If \|__datamatch\| is non-NULL, it must be contain \|__length\| bytes that will
	* be compared to the bytes being written by the vcpu which will only trigger
	* the eventfd if equal. If datamatch is NULL all writes to the address will
	* trigger the eventfd.
	*
	* On successful registration, returns a non-negative eventfd owned by the
	* caller.
	*/
	int crosvm_create_io_event(struct crosvm*, uint32_t __space, uint64_t __addr,
	uint32_t __len, const uint8_t* __datamatch,
	struct crosvm_io**);

	/*
	* Destroys the given io event and unregisters it from the VM.
	*/
	int crosvm_destroy_io_event(struct crosvm, struct crosvm_io*);

	/*
	* Gets the eventfd triggered by the given io event.
	*
	* The returned fd is owned by the given `struct crosvm_io` and has a lifetime
	* equal to that handle.
	*/
	int crosvm_io_event_fd(struct crosvm_io*);

	/*
	* Creates a shared memory segment backed by a memfd.
	*
	* Inserts non-overlapping memory pages in the guest physical address range
	* specified by \|__start\| address and \|__length\| bytes. The memory pages are
	* backed by the memfd \|__fd\| and are taken starting at \|__offset\| bytes from
	* the beginning of the memfd.
	*
	* The `memfd_create` syscall \|__fd\| must be used to create \|__fd\| and a shrink
	* seal must have been added to \|__fd\|. The memfd must be at least
	* `__length+__offset` bytes long.
	*
	* If \|read_only\| is true, attempts by the guest to write to this memory region
	* will trigger an IO access exit.
	*
	* To use the `crosvm_memory_get_dirty_log` method with the returned object,
	* \|__dirty_log\| must be true.
	*/
	int crosvm_create_memory(struct crosvm*, int __fd, uint64_t __offset,
	uint64_t __length, uint64_t __start,
	bool __read_only, bool __dirty_log,
	struct crosvm_memory**);

	/*
	* Destroys the given shared memory and unregisters it from guest physical
	* address space.
	*/
	int crosvm_destroy_memory(struct crosvm, struct crosvm_memory*);

	/*
	* For a given memory region returns a bitmap containing any pages
	* dirtied since the last call to this function.
	*
	* The `log` array must have as many bits as the memory segment has pages.
	*/
	int crosvm_memory_get_dirty_log(struct crosvm, struct crosvm_memory,
	uint8_t* __log);

	/*
	* Creates an irq eventfd that can be used to trigger an irq asynchronously.
	*
	* The irq that will be triggered is identified as pin \|__irq_id\|.
	*/
	int crosvm_create_irq_event(struct crosvm*, uint32_t __irq_id,
	struct crosvm_irq**);

	/*
	* Unregisters and destroys an irq eventfd.
	*/
	int crosvm_destroy_irq_event(struct crosvm, struct crosvm_irq*);

	/*
	* Gets the eventfd used to trigger the irq
	*
	* The returned fd is owned by the given `struct crosvm_irq` and has a lifetime
	* equal to that handle.
	*/
	int crosvm_irq_event_get_fd(const struct crosvm_irq*);

	/*
	* Gets the resample eventfd associated with the crosvm_irq object.
	*/
	int crosvm_irq_event_get_resample_fd(const struct crosvm_irq*);

	enum crosvm_vcpu_event_kind {
	/*
	* The first event returned by crosvm_vcpu_wait, indicating the VCPU has been
	* created but not yet started for the first time.
	*/
	CROSVM_VCPU_EVENT_KIND_INIT = 0,

	/*
	* Access to an address in a space previously reserved by
	* crosvm_reserve_range.
	*/
	CROSVM_VCPU_EVENT_KIND_IO_ACCESS,

	/*
	* A pause on this vcpu (and possibly others) was requested by this plugin in
	* a `crosvm_pause_vcpus` call.
	*/
	CROSVM_VCPU_EVENT_KIND_PAUSED,
	};

	struct crosvm_vcpu_event {
	/* Indicates the kind of event and which union member is valid. */
	uint32_t kind;

	uint8_t _padding[4];

	union {
	/* CROSVM_VCPU_EVENT_KIND_IO_ACCESS */
	struct {
	/*
	* One of `enum crosvm_address_space` indicating which address space the
	* access occurred in.
	*/
	uint32_t address_space;

	uint8_t _padding[4];

	/* The address that the access occurred at. */
	uint64_t address;

	/*
	* In the case that `is_write` is true, the first `length` bytes are the
	* data being written by the vcpu.
	*/
	uint8_t *data;

	/*
	* Number of bytes in the access. In the case that the access is larger
	* than 8 bytes, such as by AVX-512 instructions, multiple vcpu access
	* events are generated serially to cover each 8 byte fragment of the
	* access.
	*/
	uint32_t length;

	/*
	* True if the vcpu was attempting to write, false in case of an attempt
	* to read.
	*/
	uint8_t is_write;

	uint8_t _reserved[3];
	} io_access;

	/* CROSVM_VCPU_EVENT_KIND_USER */
	void *user;

	uint8_t _reserved[64];
	};
	};

	#ifdef static_assert
	static_assert(sizeof(struct crosvm_vcpu_event) == 72,
	"extra padding in struct crosvm_vcpu_event");
	#endif

	/*
	* Gets the vcpu object for the given \|__cpu_id\|.
	*
	*
	* The `struct crosvm_vcpu` is owned by `struct crosvm`. Each call with the same
	* `crosvm` and \|__cpu_id\| will yield the same pointer. The `crosvm_vcpu` does
	* not need to be destroyed or created explicitly.
	*
	* The range of valid \|__cpu_id\|s is 0 to the number of vcpus - 1. To get every
	* `crosvm_vcpu`, simply call this function iteratively with increasing
	* \|__cpu_id\| until `-ENOENT` is returned.
	*
	*/
	int crosvm_get_vcpu(struct crosvm, uint32_t __cpu_id, struct crosvm_vcpu*);

	/*
	* Blocks until a vcpu event happens that requires a response.
	*
	* When crosvm_vcpu_wait returns successfully, the event structure is filled
	* with the description of the event that occurred. The vcpu will suspend
	* execution until a matching call to `crosvm_vcpu_resume` is made. Until such a
	* call is made, the vcpu's run structure can be read and written using any
	* `crosvm_vcpu_get` or `crosvm_vcpu_set` function.
	*/
	int crosvm_vcpu_wait(struct crosvm_vcpu, struct crosvm_vcpu_event);

	/*
	* Resumes execution of a vcpu after a call to `crosvm_vcpu_wait` returns.
	*
	* In the case that the event was a read operation, `data` indicates what the
	* result of that read operation should be. If the read operation was larger
	* than 8 bytes, such as by AVX-512 instructions, this will not actually resume
	* the vcpu, but instead generate another vcpu access event of the next fragment
	* of the read, which can be handled by the next `crosvm_vcpu_wait` call.
	*
	* Once the vcpu event has been responded to sufficiently enough to resume
	* execution, `crosvm_vcpu_resume` should be called. After `crosvm_vcpu_resume`
	* is called, none of the vcpu state operations are valid until the next time
	* `crosvm_vcpu_wait` returns.
	*/
	int crosvm_vcpu_resume(struct crosvm_vcpu*);

	/* Gets the state of the vcpu's registers. */
	int crosvm_vcpu_get_regs(struct crosvm_vcpu, struct kvm_regs);
	/* Sets the state of the vcpu's registers. */
	int crosvm_vcpu_set_regs(struct crosvm_vcpu, const struct kvm_regs);

	/* Gets the state of the vcpu's special registers. */
	int crosvm_vcpu_get_sregs(struct crosvm_vcpu, struct kvm_sregs);
	/* Sets the state of the vcpu's special registers. */
	int crosvm_vcpu_set_sregs(struct crosvm_vcpu, const struct kvm_sregs);

	/* Gets the state of the vcpu's floating point unint. */
	int crosvm_vcpu_get_fpu(struct crosvm_vcpu, struct kvm_fpu);
	/* Sets the state of the vcpu's floating point unint. */
	int crosvm_vcpu_set_fpu(struct crosvm_vcpu, const struct kvm_fpu);

	/* Gets the state of the vcpu's debug registers. */
	int crosvm_vcpu_get_debugregs(struct crosvm_vcpu, struct kvm_debugregs);
	/* Sets the state of the vcpu's debug registers */
	int crosvm_vcpu_set_debugregs(struct crosvm_vcpu, const struct kvm_debugregs);

	/* Gets the state of the vcpu's xcr registers. */
	int crosvm_vcpu_get_xcrs(struct crosvm_vcpu, struct kvm_xcrs);
	/* Sets the state of the vcpu's xcr registers. */
	int crosvm_vcpu_set_xcrs(struct crosvm_vcpu, const struct kvm_xcrs);

	/* Gets the MSRs of the vcpu indicated by the index field of each entry. */
	int crosvm_vcpu_get_msrs(struct crosvm_vcpu*, uint32_t __msr_count,
	struct kvm_msr_entry *__msr_entries,
	uint32_t *__out_count);
	/* Sets the MSRs of the vcpu indicated by the index field of each entry. */
	int crosvm_vcpu_set_msrs(struct crosvm_vcpu*, uint32_t __msr_count,
	const struct kvm_msr_entry *__msr_entries);

	/* Sets the responses to the cpuid instructions executed on this vcpu, */
	int crosvm_vcpu_set_cpuid(struct crosvm_vcpu*, uint32_t __cpuid_count,
	const struct kvm_cpuid_entry2 *__cpuid_entries);

	/* Gets state of LAPIC of the VCPU. */
	int crosvm_vcpu_get_lapic_state(struct crosvm_vcpu *,
	struct kvm_lapic_state *__lapic_state);
	/* Sets state of LAPIC of the VCPU. */
	int crosvm_vcpu_set_lapic_state(struct crosvm_vcpu *,
	const struct kvm_lapic_state *__lapic_state);

	/* Gets the "multiprocessor state" of given VCPU. */
	int crosvm_vcpu_get_mp_state(struct crosvm_vcpu *,
	struct kvm_mp_state *__mp_state);
	/* Sets the "multiprocessor state" of given VCPU. */
	int crosvm_vcpu_set_mp_state(struct crosvm_vcpu *,
	const struct kvm_mp_state *__mp_state);

	/* Gets currently pending exceptions, interrupts, NMIs, etc for VCPU. */
	int crosvm_vcpu_get_vcpu_events(struct crosvm_vcpu *,
	struct kvm_vcpu_events *);

	/* Sets currently pending exceptions, interrupts, NMIs, etc for VCPU. */
	int crosvm_vcpu_set_vcpu_events(struct crosvm_vcpu *,
	const struct kvm_vcpu_events *);

	#ifdef __cplusplus
	}
	#endif

	#endif