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<!-- Copyright (C) 2003 Red Hat, Inc.                                -->
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>Scheduler Control</TITLE
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>eCos Reference Manual</TH
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NAME="KERNEL-SCHEDCONTROL">Scheduler Control</H1
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><DIV
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CLASS="REFNAMEDIV"
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><A
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NAME="AEN1784"
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></A
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><H2
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>Name</H2
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>cyg_scheduler_start, cyg_scheduler_lock, cyg_scheduler_unlock, cyg_scheduler_safe_lock, cyg_scheduler_read_lock&nbsp;--&nbsp;Control the state of the scheduler</DIV
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><DIV
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CLASS="REFSYNOPSISDIV"
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><A
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NAME="AEN1791"><H2
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>Synopsis</H2
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NAME="AEN1792"><P
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></P
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><TABLE
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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_scheduler_start</CODE
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>(void);</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_scheduler_lock</CODE
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>(void);</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_scheduler_unlock</CODE
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>(void);</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_ucount32 cyg_scheduler_read_lock</CODE
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>(void);</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-SCHEDCONTROL-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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><TT
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CLASS="FUNCTION"
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>cyg_scheduler_start</TT
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> should only be called once,
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to mark the end of system initialization. In typical configurations it
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is called automatically by the system startup, but some applications
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may bypass the standard startup in which case
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<TT
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CLASS="FUNCTION"
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>cyg_scheduler_start</TT
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> will have to be called
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explicitly. The call will enable system interrupts, allowing I/O
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operations to commence. Then the scheduler will be invoked and control
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will be transferred to the highest priority runnable thread. The call
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will never return.
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      </P
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><P
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>The various data structures inside the eCos kernel must be protected
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against concurrent updates. Consider a call to
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<TT
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CLASS="FUNCTION"
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>cyg_semaphore_post</TT
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> which causes a thread to be
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woken up: the semaphore data structure must be updated to remove the
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thread from its queue; the scheduler data structure must also be
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updated to mark the thread as runnable; it is possible that the newly
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runnable thread has a higher priority than the current one, in which
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case preemption is required. If in the middle of the semaphore post
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call an interrupt occurred and the interrupt handler tried to
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manipulate the same data structures, for example by making another
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thread runnable, then it is likely that the structures will be left in
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an inconsistent state and the system will fail.
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      </P
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><P
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>To prevent such problems the kernel contains a special lock known as
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the scheduler lock. A typical kernel function such as
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<TT
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CLASS="FUNCTION"
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>cyg_semaphore_post</TT
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> will claim the scheduler lock,
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do all its manipulation of kernel data structures, and then release
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the scheduler lock. The current thread cannot be preempted while it
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holds the scheduler lock. If an interrupt occurs and a DSR is supposed
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to run to signal that some event has occurred, that DSR is postponed
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until the scheduler unlock operation. This prevents concurrent updates
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of kernel data structures.
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      </P
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><P
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>The kernel exports three routines for manipulating the scheduler lock.
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<TT
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CLASS="FUNCTION"
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>cyg_scheduler_lock</TT
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> can be called to claim the
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lock. On return it is guaranteed that the current thread will not be
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preempted, and that no other code is manipulating any kernel data
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structures. <TT
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CLASS="FUNCTION"
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>cyg_scheduler_unlock</TT
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> can be used to
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release the lock, which may cause the current thread to be preempted.
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<TT
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CLASS="FUNCTION"
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>cyg_scheduler_read_lock</TT
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> can be used to query the
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current state of the scheduler lock. This function should never be
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needed because well-written code should always know whether or not the
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scheduler is currently locked, but may prove useful during debugging.
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      </P
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><P
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>The implementation of the scheduler lock involves a simple counter.
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Code can call <TT
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CLASS="FUNCTION"
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>cyg_scheduler_lock</TT
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> multiple times,
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causing the counter to be incremented each time, as long as
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<TT
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CLASS="FUNCTION"
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>cyg_scheduler_unlock</TT
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> is called the same number of
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times. This behaviour is different from mutexes where an attempt by a
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thread to lock a mutex multiple times will result in deadlock or an
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assertion failure.
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      </P
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><P
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>Typical application code should not use the scheduler lock. Instead
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other synchronization primitives such as mutexes and semaphores should
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be used. While the scheduler is locked the current thread cannot be
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preempted, so any higher priority threads will not be able to run.
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Also no DSRs can run, so device drivers may not be able to service
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I/O requests. However there is one situation where locking the
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scheduler is appropriate: if some data structure needs to be shared
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between an application thread and a DSR associated with some interrupt
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source, the thread can use the scheduler lock to prevent concurrent
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invocations of the DSR and then safely manipulate the structure. It is
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desirable that the scheduler lock is held for only a short period of
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time, typically some tens of instructions. In exceptional cases there
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may also be some performance-critical code where it is more
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appropriate to use the scheduler lock rather than a mutex, because the
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former is more efficient.
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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-SCHEDCONTROL-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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><TT
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CLASS="FUNCTION"
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>cyg_scheduler_start</TT
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> can only be called during
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system initialization, since it marks the end of that phase. The
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remaining functions may be called from thread or DSR context. Locking
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the scheduler from inside the DSR has no practical effect because the
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lock is claimed automatically by the interrupt subsystem before
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running DSRs, but allows functions to be shared between normal thread
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code and DSRs.
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      </P
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