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>Spinlocks</TITLE
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>eCos Reference Manual</TH
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><H1
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><A
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NAME="KERNEL-SPINLOCKS">Spinlocks</H1
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><DIV
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CLASS="REFNAMEDIV"
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><A
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NAME="AEN1693"
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></A
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><H2
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>Name</H2
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>cyg_spinlock_create, cyg_spinlock_destroy, cyg_spinlock_spin, cyg_spinlock_clear, cyg_spinlock_test, cyg_spinlock_spin_intsave, cyg_spinlock_clear_intsave&nbsp;--&nbsp;Low-level Synchronization Primitive</DIV
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><DIV
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CLASS="REFSYNOPSISDIV"
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><A
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NAME="AEN1702"><H2
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>Synopsis</H2
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><DIV
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CLASS="FUNCSYNOPSIS"
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><A
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NAME="AEN1703"><P
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></P
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><TABLE
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BORDER="5"
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BGCOLOR="#E0E0F0"
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WIDTH="70%"
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><TR
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><TD
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><PRE
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CLASS="FUNCSYNOPSISINFO"
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>#include &lt;cyg/kernel/kapi.h&gt;
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        </PRE
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></TD
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></TR
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></TABLE
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><P
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><CODE
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><CODE
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CLASS="FUNCDEF"
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>void cyg_spinlock_init</CODE
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>(cyg_spinlock_t* lock, cyg_bool_t locked);</CODE
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></P
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><P
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><CODE
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><CODE
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CLASS="FUNCDEF"
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>void cyg_spinlock_destroy</CODE
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>(cyg_spinlock_t* lock);</CODE
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></P
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><P
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><CODE
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><CODE
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CLASS="FUNCDEF"
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>void cyg_spinlock_spin</CODE
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>(cyg_spinlock_t* lock);</CODE
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></P
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><P
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><CODE
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><CODE
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CLASS="FUNCDEF"
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>void cyg_spinlock_clear</CODE
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>(cyg_spinlock_t* lock);</CODE
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></P
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><P
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><CODE
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><CODE
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CLASS="FUNCDEF"
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>cyg_bool_t cyg_spinlock_try</CODE
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>(cyg_spinlock_t* lock);</CODE
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></P
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><P
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><CODE
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><CODE
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CLASS="FUNCDEF"
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>cyg_bool_t cyg_spinlock_test</CODE
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>(cyg_spinlock_t* lock);</CODE
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></P
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><P
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><CODE
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><CODE
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CLASS="FUNCDEF"
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>void cyg_spinlock_spin_intsave</CODE
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>(cyg_spinlock_t* lock, cyg_addrword_t* istate);</CODE
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></P
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><P
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><CODE
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><CODE
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CLASS="FUNCDEF"
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>void cyg_spinlock_clear_intsave</CODE
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>(cyg_spinlock_t* lock, cyg_addrword_t istate);</CODE
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></P
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><P
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></P
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></DIV
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></DIV
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><DIV
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CLASS="REFSECT1"
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><A
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NAME="KERNEL-SPINLOCKS-DESCRIPTION"
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></A
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><H2
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>Description</H2
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><P
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>Spinlocks provide an additional synchronization primitive for
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applications running on SMP systems. They operate at a lower level
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than the other primitives such as mutexes, and for most purposes the
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higher-level primitives should be preferred. However there are some
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circumstances where a spinlock is appropriate, especially when
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interrupt handlers and threads need to share access to hardware, and
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on SMP systems the kernel implementation itself depends on spinlocks.
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      </P
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><P
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>Essentially a spinlock is just a simple flag. When code tries to claim
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a spinlock it checks whether or not the flag is already set. If not
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then the flag is set and the operation succeeds immediately. The exact
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implementation of this is hardware-specific, for example it may use a
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test-and-set instruction to guarantee the desired behaviour even if
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several processors try to access the spinlock at the exact same time.
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If it is not possible to claim a spinlock then the current thead spins
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in a tight loop, repeatedly checking the flag until it is clear. This
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behaviour is very different from other synchronization primitives such
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as mutexes, where contention would cause a thread to be suspended. The
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assumption is that a spinlock will only be held for a very short time.
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If claiming a spinlock could cause the current thread to be suspended
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then spinlocks could not be used inside interrupt handlers, which is
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not acceptable.
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      </P
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><P
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>This does impose a constraint on any code which uses spinlocks.
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Specifically it is important that spinlocks are held only for a short
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period of time, typically just some dozens of instructions. Otherwise
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another processor could be blocked on the spinlock for a long time,
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unable to do any useful work. It is also important that a thread which
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owns a spinlock does not get preempted because that might cause
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another processor to spin for a whole timeslice period, or longer. One
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way of achieving this is to disable interrupts on the current
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processor, and the function
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<TT
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CLASS="FUNCTION"
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>cyg_spinlock_spin_intsave</TT
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> is provided to
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facilitate this.
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      </P
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><P
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>Spinlocks should not be used on single-processor systems. Consider a
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high priority thread which attempts to claim a spinlock already held
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by a lower priority thread: it will just loop forever and the lower
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priority thread will never get another chance to run and release the
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spinlock. Even if the two threads were running at the same priority,
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the one attempting to claim the spinlock would spin until it was
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timesliced and a lot of cpu time would be wasted. If an interrupt
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handler tried to claim a spinlock owned by a thread, the interrupt
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handler would loop forever. Therefore spinlocks are only appropriate
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for SMP systems where the current owner of a spinlock can continue
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running on a different processor.
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      </P
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><P
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>Before a spinlock can be used it must be initialized by a call to
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<TT
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CLASS="FUNCTION"
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>cyg_spinlock_init</TT
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>. This takes two arguments, a
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pointer to a <TT
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CLASS="FUNCTION"
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>cyg_spinlock_t</TT
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> data structure, and
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a flag to specify whether the spinlock starts off locked or unlocked.
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If a spinlock is no longer required then it can be destroyed by a call
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to <TT
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CLASS="FUNCTION"
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>cyg_spinlock_destroy</TT
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>.
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      </P
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><P
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>There are two routines for claiming a spinlock:
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<TT
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CLASS="FUNCTION"
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>cyg_spinlock_spin</TT
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> and
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<TT
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CLASS="FUNCTION"
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>cyg_spinlock_spin_intsave</TT
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>. The former can be used
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when it is known the current code will not be preempted, for example
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because it is running in an interrupt handler or because interrupts
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are disabled. The latter will disable interrupts in addition to
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claiming the spinlock, so is safe to use in all circumstances. The
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previous interrupt state is returned via the second argument, and
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should be used in a subsequent call to
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<TT
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CLASS="FUNCTION"
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>cyg_spinlock_clear_intsave</TT
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>.
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      </P
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><P
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>Similarly there are two routines for releasing a spinlock:
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<TT
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CLASS="FUNCTION"
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>cyg_spinlock_clear</TT
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> and
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<TT
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CLASS="FUNCTION"
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>cyg_spinlock_clear_intsave</TT
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>. Typically
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the former will be used if the spinlock was claimed by a call to
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<TT
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CLASS="FUNCTION"
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>cyg_spinlock_spin</TT
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>, and the latter when
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<TT
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CLASS="FUNCTION"
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>cyg_spinlock_intsave</TT
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> was used.
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      </P
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><P
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>There are two additional routines.
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<TT
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CLASS="FUNCTION"
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>cyg_spinlock_try</TT
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> is a non-blocking version of
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<TT
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CLASS="FUNCTION"
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>cyg_spinlock_spin</TT
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>: if possible the lock will be
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claimed and the function will return <TT
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CLASS="LITERAL"
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>true</TT
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>; otherwise the function
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will return immediately with failure.
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<TT
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CLASS="FUNCTION"
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>cyg_spinlock_test</TT
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> can be used to find out whether
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or not the spinlock is currently locked. This function must be used
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with care because, especially on a multiprocessor system, the state of
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the spinlock can change at any time.
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      </P
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><P
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>Spinlocks should only be held for a short period of time, and
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attempting to claim a spinlock will never cause a thread to be
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suspended. This means that there is no need to worry about priority
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inversion problems, and concepts such as priority ceilings and
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inheritance do not apply.
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      </P
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></DIV
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><DIV
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CLASS="REFSECT1"
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><A
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NAME="KERNEL-SPINLOCKS-CONTEXT"
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></A
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><H2
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>Valid contexts</H2
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><P
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>All of the spinlock functions can be called from any context,
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including ISR and DSR context. Typically
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<TT
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CLASS="FUNCTION"
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>cyg_spinlock_init</TT
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> is only called during system
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initialization.
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