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SOFTINT(9) NetBSD Kernel Developer's Manual SOFTINT(9)
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softint, softint_establish, softint_disestablish, softint_schedule --
machine-independent software interrupt framework
softint_establish(u_int flags, void (*func)(void *), void *arg);
The software interrupt framework is designed to provide a generic soft-
ware interrupt mechanism which can be used any time a low-priority call-
back is needed.
It allows dynamic registration of software interrupts for loadable driv-
ers and protocol stacks, prioritization and fair queueing of software
interrupts, and allows machine-dependent optimizations to reduce cost.
Four priority levels are provided. In order of priority (lowest to high-
est) the levels are: clock, bio, net, serial. The names are symbolic and
in isolation do not have any direct connection with a particular kind of
device activity: they are only meant as a guide.
The four priority levels map directly to scheduler priority levels, and
where the architecture implements 'fast' software interrupts, they also
map onto interrupt priorities. The interrupt priorities are intended to
be hidden from machine independent code, which should in general use
thread-safe mechanisms to synchronize with software interrupts (for exam-
Software interrupts run with limited machine context. In particular,
they do not possess any address space context. They should not try to
operate on user space addresses, or to use virtual memory facilities
other than those noted as interrupt safe. Unlike hardware interrupts,
software interrupts do have thread context. They may block on synchro-
nization objects, sleep, and resume execution at a later time.
Since software interrupts are a limited resource and run with higher pri-
ority than most other LWPs in the system, all block-and-resume activity
by a software interrupt must be kept short to allow further processing at
that level to continue. By extension, code running with process context
must take care to ensure that any lock that may be taken from a software
interrupt can not be held for more than a short period of time.
The kernel does not allow software interrupts to use facilities or per-
form actions that are likely to block for a significant amount of time.
This means that it's not valid for a software interrupt to sleep on con-
dition variables or to wait for resources to become available (for exam-
The following is a brief description of each function in the framework:
softint_establish(flags, func, arg)
Register a software interrupt. The flags value must contain one
of the following constants, specifing the priority level for the
SOFTINT_CLOCK, SOFTINT_BIO, SOFTINT_NET, SOFTINT_SERIAL
If the constant SOFTINT_MPSAFE is not logically ORed into flags,
the global kernel_lock will automatically be acquired before the
soft interrupt handler is called.
The constant func specifies the function to call when the soft
interrupt is executed. The argument arg will be passed to this
softint_establish() may block in order to allocate memory. If
successful, it returns a non-NULL opaque value to be used as an
argument to softint_schedule() and/or softint_disestablish().
If for some reason it does not succeed, it returns NULL.
Deallocate a software interrupt previously allocated by a call
Schedule a software interrupt previously allocated by a call to
softint_establish() to be executed as soon as that software
interrupt is unblocked. softint_schedule() can safely be called
multiple times before the callback routine is invoked.
Soft interrupt scheduling is CPU-local. A request to dispatch a
soft interrupt will only be serviced on the same CPU where the
request was made. The LWPs (light weight processes) dedicated
to soft interrupt processing are bound to their home CPUs, so if
a soft interrupt handler sleeps and later resumes, it will
always resume on the same CPU.
On a system with multiple processors, multiple instances of the
same soft interrupt handler can be in flight simultaneously (at
most one per-CPU).
mutex(9), rwlock(9), spl(9)
The NetBSD machine-independent software interrupt framework was designed
in 1997 and was implemented by one port in NetBSD 1.3. However, it did
not gain wider implementation until NetBSD 1.5. Between NetBSD 4.0 and
NetBSD 5.0 the framework was re-implemented in a machine-independant way
to provide software interrupts with thread context.
NetBSD 5.0 October 6, 2008 NetBSD 5.0