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     hhook, hhook_head_register, hhook_head_deregister, hhook_head_deregister_lookup,
     hhook_run_hooks, HHOOKS_RUN_IF, HHOOKS_RUN_LOOKUP_IF — Helper Hook Framework


     #include <sys/hhook.h>

     typedef int
     (*hhook_func_t)(int32_t hhook_type, int32_t hhook_id, void *udata, void *ctx_data,
         void *hdata, struct osd *hosd);

     int hhook_head_register(int32_t hhook_type, int32_t hhook_id, struct hhook_head **hhh,
         uint32_t flags);

     int hhook_head_deregister(struct hhook_head *hhh);

     int hhook_head_deregister_lookup(int32_t hhook_type, int32_t hhook_id);

     void hhook_run_hooks(struct hhook_head *hhh, void *ctx_data, struct osd *hosd);

     HHOOKS_RUN_IF(hhh, ctx_data, hosd);

     HHOOKS_RUN_LOOKUP_IF(hhook_type, hhook_id, ctx_data, hosd);


     hhook provides a framework for managing and running arbitrary hook functions at defined hook
     points within the kernel.  The KPI was inspired by pfil(9), and in many respects can be
     thought of as a more generic superset of pfil.

     The khelp(9) and hhook frameworks are tightly integrated.  Khelp is responsible for
     registering and deregistering Khelp module hook functions with hhook points.  The KPI
     functions used by khelp(9) to do this are not documented here as they are not relevant to
     consumers wishing to instantiate hook points.

   Information for Khelp Module Implementors
     Khelp modules indirectly interact with hhook by defining appropriate hook functions for
     insertion into hook points.  Hook functions must conform to the hhook_func_t function
     pointer declaration outlined in the SYNOPSIS.

     The hhook_type and hhook_id arguments identify the hook point which has called into the hook
     function.  These are useful when a single hook function is registered for multiple hook
     points and wants to know which hook point has called into it.  <sys/hhook.h> lists available
     hhook_type defines and subsystems which export hook points are responsible for defining the
     hhook_id value in appropriate header files.

     The udata argument will be passed to the hook function if it was specified in the struct
     hookinfo at hook registration time.

     The ctx_data argument contains context specific data from the hook point call site.  The
     data type passed is subsystem dependent.

     The hdata argument is a pointer to the persistent per-object storage allocated for use by
     the module if required.  The pointer will only ever be NULL if the module did not request
     per-object storage.

     The hosd argument can be used with the khelp(9) framework's khelp_get_osd() function to
     access data belonging to a different Khelp module.

     Khelp modules instruct the Khelp framework to register their hook functions with hhook
     points by creating a struct hookinfo per hook point, which contains the following members:

           struct hookinfo {
                   hhook_func_t    hook_func;
                   struct helper   *hook_helper;
                   void            *hook_udata;
                   int32_t         hook_id;
                   int32_t         hook_type;

     Khelp modules are responsible for setting all members of the struct except hook_helper which
     is handled by the Khelp framework.

   Creating and Managing Hook Points
     Kernel subsystems that wish to provide hhook points typically need to make four and possibly
     five key changes to their implementation:

     ·   Define a list of hhook_id mappings in an appropriate subsystem header.

     ·   Register each hook point with the hhook_head_register() function during initialisation
         of the subsystem.

     ·   Select or create a standardised data type to pass to hook functions as contextual data.

     ·   Add a call to HHOOKS_RUN_IF() or HHOOKS_RUN_IF_LOOKUP() at the point in the subsystem's
         code where the hook point should be executed.

     ·   If the subsystem can be dynamically added/removed at runtime, each hook point registered
         with the hhook_head_register() function when the subsystem was initialised needs to be
         deregistered with the hhook_head_deregister() or hhook_head_deregister_lookup()
         functions when the subsystem is being deinitialised prior to removal.

     The hhook_head_register() function registers a hook point with the hhook framework.  The
     hook_type argument defines the high level type for the hook point.  Valid types are defined
     in <sys/hhook.h> and new types should be added as required.  The hook_id argument specifies
     a unique, subsystem specific identifier for the hook point.  The hhh argument will, if not
     NULL, be used to store a reference to the struct hhook_head created as part of the
     registration process.  Subsystems will generally want to store a local copy of the struct
     hhook_head so that they can use the HHOOKS_RUN_IF() macro to instantiate hook points.  The
     HHOOK_WAITOK flag may be passed in via the flags argument if malloc(9) is allowed to sleep
     waiting for memory to become available.  If the hook point is within a virtualised subsystem
     (e.g. the network stack), the HHOOK_HEADISINVNET flag should be passed in via the flags
     argument so that the struct hhook_head created during the registration process will be added
     to a virtualised list.

     The hhook_head_deregister() function deregisters a previously registered hook point from the
     hhook framework.  The hhh argument is the pointer to the struct hhook_head returned by
     hhoook_head_register() when the hook point was registered.

     The hhook_head_deregister_lookup() function can be used instead of hhook_head_deregister()
     in situations where the caller does not have a cached copy of the struct hhook_head and
     wants to deregister a hook point using the appropriate hook_type and hook_id identifiers

     The hhook_run_hooks() function should normally not be called directly and should instead be
     called indirectly via the HHOOKS_RUN_IF() macro.  However, there may be circumstances where
     it is preferable to call the function directly, and so it is documented here for
     completeness.  The hhh argument references the hhook point to call all registered hook
     functions for.  The ctx_data argument specifies a pointer to the contextual hook point data
     to pass into the hook functions.  The hosd argument should be the pointer to the appropriate
     object's struct osd if the subsystem provides the ability for Khelp modules to associate
     per-object data.  Subsystems which do not should pass NULL.

     The HHOOKS_RUN_IF() macro is the preferred way to implement hook points.  It only calls the
     hhook_run_hooks() function if at least one hook function is registered for the hook point.
     By checking for registered hook functions, the macro minimises the cost associated with
     adding hook points to frequently used code paths by reducing to a simple if test in the
     common case where no hook functions are registered.  The arguments are as described for the
     hhook_run_hooks() function.

     The HHOOKS_RUN_IF_LOOKUP() macro performs the same function as the HHOOKS_RUN_IF() macro,
     but performs an additional step to look up the struct hhook_head for the specified hook_type
     and hook_id identifiers.  It should not be used except in code paths which are infrequently
     executed because of the reference counting overhead associated with the look up.


     Each struct hhook_head protects its internal list of hook functions with a rmlock(9).
     Therefore, anytime hhook_run_hooks() is called directly or indirectly via the
     HHOOKS_RUN_IF() or HHOOKS_RUN_IF_LOOKUP() macros, a non-sleepable read lock will be acquired
     and held across the calls to all registered hook functions.


     hhook_head_register() returns 0 if no errors occurred.  It returns EEXIST if a hook point
     with the same hook_type and hook_id is already registered.  It returns EINVAL if the
     HHOOK_HEADISINVNET flag is not set in flags because the implementation does not yet support
     hook points in non-virtualised subsystems (see the BUGS section for details).  It returns
     ENOMEM if malloc(9) failed to allocate memory for the new struct hhook_head.

     hhook_head_deregister() and hhook_head_deregister_lookup() return 0 if no errors occurred.
     They return ENOENT if hhh is NULL.  They return EBUSY if the reference count of hhh is
     greater than one.


     A well commented example Khelp module can be found at:

     The tcp(4) implementation provides two hhook points which are called for packets
     sent/received when a connection is in the established phase.  Search for HHOOK in the
     following files: sys/netinet/tcp_var.h, sys/netinet/tcp_input.c, sys/netinet/tcp_output.c
     and sys/netinet/tcp_subr.c.




     Development and testing of this software were made possible in part by grants from the
     FreeBSD Foundation and Cisco University Research Program Fund at Community Foundation
     Silicon Valley.


     The hhook framework first appeared in FreeBSD 9.0.

     The hhook framework was first released in 2010 by Lawrence Stewart whilst studying at
     Swinburne University of Technology's Centre for Advanced Internet Architectures, Melbourne,
     Australia.  More details are available at:


     The hhook framework was written by Lawrence Stewart <>.

     This manual page was written by David Hayes <> and Lawrence Stewart