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NAME

     VNET — network subsystem virtualization infrastructure

SYNOPSIS

     options VIMAGE
     options VNET_DEBUG

     #include <sys/vnet.h>

   Constants and Global Variables
     VNET_SETNAME VNET_SYMPREFIX

     extern struct vnet *vnet0;

   Variable Declaration
     VNET(name);

     VNET_NAME(name);

     VNET_DECLARE(type, name);

     VNET_DEFINE(type, name);

     VNET_DEFINE_STATIC(type, name);

     #define V_name  VNET(name)

   Virtual Instance Selection
     CRED_TO_VNET(struct ucred *);

     TD_TO_VNET(struct thread *);

     P_TO_VNET(struct proc *);

     IS_DEFAULT_VNET(struct vnet *);

     VNET_ASSERT(exp, msg);

     CURVNET_SET(struct vnet *);

     CURVNET_SET_QUIET(struct vnet *);

     CURVNET_RESTORE();

     VNET_ITERATOR_DECL(struct vnet *);

     VNET_FOREACH(struct vnet *);

   Locking
     VNET_LIST_RLOCK();

     VNET_LIST_RUNLOCK();

     VNET_LIST_RLOCK_NOSLEEP();

     VNET_LIST_RUNLOCK_NOSLEEP();

   Startup and Teardown Functions
     struct vnet *
     vnet_alloc(void);

     void
     vnet_destroy(struct vnet *);

     VNET_SYSINIT(ident, enum sysinit_sub_id subsystem, enum sysinit_elem_order order,
           sysinit_cfunc_t func, const void *arg);

     VNET_SYSUNINIT(ident, enum sysinit_sub_id subsystem, enum sysinit_elem_order order,
           sysinit_cfunc_t func, const void *arg);

   Eventhandlers
     VNET_GLOBAL_EVENTHANDLER_REGISTER(const char *name, void *func, void *arg, int priority);

     VNET_GLOBAL_EVENTHANDLER_REGISTER_TAG(eventhandler_tag tag, const char *name, void *func,
           void *arg, int priority);

   Sysctl Handling
     SYSCTL_VNET_INT(parent, nbr, name, access, ptr, val, descr);

     SYSCTL_VNET_PROC(parent, nbr, name, access, ptr, arg, handler, fmt, descr);

     SYSCTL_VNET_STRING(parent, nbr, name, access, arg, len, descr);

     SYSCTL_VNET_STRUCT(parent, nbr, name, access, ptr, type, descr);

     SYSCTL_VNET_UINT(parent, nbr, name, access, ptr, val, descr);

     VNET_SYSCTL_ARG(req, arg1);

DESCRIPTION

     VNET is the name of a technique to virtualize the network stack.  The basic idea is to
     change global resources most notably variables into per network stack resources and have
     functions, sysctls, eventhandlers, etc. access and handle them in the context of the correct
     instance.  Each (virtual) network stack is attached to a prison, with vnet0 being the
     unrestricted default network stack of the base system.

     The global defines for VNET_SETNAME and VNET_SYMPREFIX are shared with kvm(3) to access
     internals for debugging reasons.

   Variable Declaration
     Variables are virtualized by using the VNET_DEFINE() macro rather than writing them out as
     type name.  One can still use static initialization, e.g.,

           VNET_DEFINE(int, foo) = 1;

     Variables declared with the static keyword can use the VNET_DEFINE_STATIC() macro, e.g.,

           VNET_DEFINE_STATIC(SLIST_HEAD(, bar), bars);

     Static initialization is not possible when the virtualized variable would need to be
     referenced, e.g., with “TAILQ_HEAD_INITIALIZER()”.  In that case a VNET_SYSINIT() based
     initialization function must be used.

     External variables have to be declared using the VNET_DECLARE() macro.  In either case the
     convention is to define another macro, that is then used throughout the implementation to
     access that variable.  The variable name is usually prefixed by V_ to express that it is
     virtualized.  The VNET() macro will then translate accesses to that variable to the copy of
     the currently selected instance (see the Virtual instance selection section):

           #define   V_name    VNET(name)

     NOTE: Do not confuse this with the convention used by VFS(9).

     The VNET_NAME() macro returns the offset within the memory region of the virtual network
     stack instance.  It is usually only used with SYSCTL_VNET_*() macros.

   Virtual Instance Selection
     There are three different places where the current virtual network stack pointer is stored
     and can be taken from:

           1.   a prison:
                      (struct prison *)->pr_vnet

                For convenience the following macros are provided:
                      CRED_TO_VNET(struct ucred *)
                      TD_TO_VNET(struct thread *)
                      P_TO_VNET(struct proc *)

           2.   a socket:
                      (struct socket *)->so_vnet

           3.   an interface:
                      (struct ifnet *)->if_vnet

     In addition the currently active instance is cached in “curthread->td_vnet” which is usually
     only accessed through the curvnet macro.

     To set the correct context of the current virtual network instance, use the CURVNET_SET() or
     CURVNET_SET_QUIET() macros.  The CURVNET_SET_QUIET() version will not record vnet recursions
     in case the kernel was compiled with options VNET_DEBUG and should thus only be used in well
     known cases, where recursion is unavoidable.  Both macros will save the previous state on
     the stack and it must be restored with the CURVNET_RESTORE() macro.

     NOTE: As the previous state is saved on the stack, you cannot have multiple CURVNET_SET()
     calls in the same block.

     NOTE: As the previous state is saved on the stack, a CURVNET_RESTORE() call has to be in the
     same block as the CURVNET_SET() call or in a subblock with the same idea of the saved
     instances as the outer block.

     NOTE: As each macro is a set of operations and, as previously explained, cannot be put into
     its own block when defined, one cannot conditionally set the current vnet context.  The
     following will not work:

           if (condition)
                   CURVNET_SET(vnet);

     nor would this work:

           if (condition) {
                   CURVNET_SET(vnet);
           }
           CURVNET_RESTORE();

     Sometimes one needs to loop over all virtual instances, for example to update virtual from
     global state, to run a function from a callout(9) for each instance, etc.  For those cases
     the VNET_ITERATOR_DECL() and VNET_FOREACH() macros are provided.  The former macro defines
     the variable that iterates over the loop, and the latter loops over all of the virtual
     network stack instances.  See Locking for how to savely traverse the list of all virtual
     instances.

     The IS_DEFAULT_VNET() macro provides a safe way to check whether the currently active
     instance is the unrestricted default network stack of the base system (vnet0).

     The VNET_ASSERT() macro provides a way to conditionally add assertions that are only active
     with options VIMAGE compiled in and either options VNET_DEBUG or options INVARIANTS enabled
     as well.  It uses the same semantics as KASSERT(9).

   Locking
     For public access to the list of virtual network stack instances e.g., by the VNET_FOREACH()
     macro, read locks are provided.  Macros are used to abstract from the actual type of the
     locks.  If a caller may sleep while traversing the list, it must use the VNET_LIST_RLOCK()
     and VNET_LIST_RUNLOCK() macros.  Otherwise, the caller can use VNET_LIST_RLOCK_NOSLEEP() and
     VNET_LIST_RUNLOCK_NOSLEEP().

   Startup and Teardown Functions
     To start or tear down a virtual network stack instance the internal functions vnet_alloc()
     and vnet_destroy() are provided and called from the jail framework.  They run the publicly
     provided methods to handle network stack startup and teardown.

     For public control, the system startup interface has been enhanced to not only handle a
     system boot but to also handle a virtual network stack startup and teardown.  To the base
     system the VNET_SYSINIT() and VNET_SYSUNINIT() macros look exactly as if there were no
     virtual network stack.  In fact, if options VIMAGE is not compiled in they are compiled to
     the standard SYSINIT() macros.  In addition to that they are run for each virtual network
     stack when starting or, in reverse order, when shutting down.

   Eventhandlers
     Eventhandlers can be handled in two ways:

           1.   save the tags returned in each virtual instance and properly free the
                eventhandlers on teardown using those, or
           2.   use one eventhandler that will iterate over all virtual network stack instances.

     For the first case one can just use the normal EVENTHANDLER(9) functions, while for the
     second case the VNET_GLOBAL_EVENTHANDLER_REGISTER() and
     VNET_GLOBAL_EVENTHANDLER_REGISTER_TAG() macros are provided.  These differ in that
     VNET_GLOBAL_EVENTHANDLER_REGISTER_TAG() takes an extra first argument that will carry the
     tag upon return.  Eventhandlers registered with either of these will not run func directly
     but func will be called from an internal iterator function for each vnet.  Both macros can
     only be used for eventhandlers that do not take additional arguments, as the variadic
     arguments from an EVENTHANDLER_INVOKE(9) call will be ignored.

   Sysctl Handling
     A sysctl(9) can be virtualized by using one of the SYSCTL_VNET_*() macros.

     They take the same arguments as the standard sysctl(9) functions, with the only difference,
     that the ptr argument has to be passed as ‘&VNET_NAME(foo)’ instead of ‘&foo’ so that the
     variable can be selected from the correct memory region of the virtual network stack
     instance of the caller.

     For the very rare case a sysctl handler function would want to handle arg1 itself the
     VNET_SYSCTL_ARG(req, arg1) is provided that will translate the arg1 argument to the correct
     memory address in the virtual network stack context of the caller.

SEE ALSO

     jail(2), kvm(3), EVENTHANDLER(9), KASSERT(9), sysctl(9)

     Marko Zec, Implementing a Clonable Network Stack in the FreeBSD Kernel, USENIX ATC'03, June
     2003, Boston

HISTORY

     The virtual network stack implementation first appeared in FreeBSD 8.0.

AUTHORS

     The VNET framework has been designed and implemented at the University of Zagreb by Marko
     Zec, and later extended and refined by Bjoern A. Zeeb and Robert Watson, under contract to
     the FreeBSD Foundation.

     This manual page was written by Bjoern A. Zeeb, CK Software GmbH, under sponsorship from the
     FreeBSD Foundation.