OpenCores
URL https://opencores.org/ocsvn/openrisc/openrisc/trunk

Subversion Repositories openrisc

[/] [openrisc/] [trunk/] [rtos/] [ecos-2.0/] [doc/] [html/] [ref/] [kernel-schedcontrol.html] - Blame information for rev 811

Go to most recent revision | Details | Compare with Previous | View Log

Line No. Rev Author Line
1 28 unneback
<!-- Copyright (C) 2003 Red Hat, Inc.                                -->
2
<!-- This material may be distributed only subject to the terms      -->
3
<!-- and conditions set forth in the Open Publication License, v1.0  -->
4
<!-- or later (the latest version is presently available at          -->
5
<!-- http://www.opencontent.org/openpub/).                           -->
6
<!-- Distribution of the work or derivative of the work in any       -->
7
<!-- standard (paper) book form is prohibited unless prior           -->
8
<!-- permission is obtained from the copyright holder.               -->
9
<HTML
10
><HEAD
11
><TITLE
12
>Scheduler Control</TITLE
13
><meta name="MSSmartTagsPreventParsing" content="TRUE">
14
<META
15
NAME="GENERATOR"
16
CONTENT="Modular DocBook HTML Stylesheet Version 1.76b+
17
"><LINK
18
REL="HOME"
19
TITLE="eCos Reference Manual"
20
HREF="ecos-ref.html"><LINK
21
REL="UP"
22
TITLE="The eCos Kernel"
23
HREF="kernel.html"><LINK
24
REL="PREVIOUS"
25
TITLE="Spinlocks"
26
HREF="kernel-spinlocks.html"><LINK
27
REL="NEXT"
28
TITLE="Interrupt Handling"
29
HREF="kernel-interrupts.html"></HEAD
30
><BODY
31
CLASS="REFENTRY"
32
BGCOLOR="#FFFFFF"
33
TEXT="#000000"
34
LINK="#0000FF"
35
VLINK="#840084"
36
ALINK="#0000FF"
37
><DIV
38
CLASS="NAVHEADER"
39
><TABLE
40
SUMMARY="Header navigation table"
41
WIDTH="100%"
42
BORDER="0"
43
CELLPADDING="0"
44
CELLSPACING="0"
45
><TR
46
><TH
47
COLSPAN="3"
48
ALIGN="center"
49
>eCos Reference Manual</TH
50
></TR
51
><TR
52
><TD
53
WIDTH="10%"
54
ALIGN="left"
55
VALIGN="bottom"
56
><A
57
HREF="kernel-spinlocks.html"
58
ACCESSKEY="P"
59
>Prev</A
60
></TD
61
><TD
62
WIDTH="80%"
63
ALIGN="center"
64
VALIGN="bottom"
65
></TD
66
><TD
67
WIDTH="10%"
68
ALIGN="right"
69
VALIGN="bottom"
70
><A
71
HREF="kernel-interrupts.html"
72
ACCESSKEY="N"
73
>Next</A
74
></TD
75
></TR
76
></TABLE
77
><HR
78
ALIGN="LEFT"
79
WIDTH="100%"></DIV
80
><H1
81
><A
82
NAME="KERNEL-SCHEDCONTROL">Scheduler Control</H1
83
><DIV
84
CLASS="REFNAMEDIV"
85
><A
86
NAME="AEN1784"
87
></A
88
><H2
89
>Name</H2
90
>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
91
><DIV
92
CLASS="REFSYNOPSISDIV"
93
><A
94
NAME="AEN1791"><H2
95
>Synopsis</H2
96
><DIV
97
CLASS="FUNCSYNOPSIS"
98
><A
99
NAME="AEN1792"><P
100
></P
101
><TABLE
102
BORDER="5"
103
BGCOLOR="#E0E0F0"
104
WIDTH="70%"
105
><TR
106
><TD
107
><PRE
108
CLASS="FUNCSYNOPSISINFO"
109
>#include &lt;cyg/kernel/kapi.h&gt;
110
        </PRE
111
></TD
112
></TR
113
></TABLE
114
><P
115
><CODE
116
><CODE
117
CLASS="FUNCDEF"
118
>void cyg_scheduler_start</CODE
119
>(void);</CODE
120
></P
121
><P
122
><CODE
123
><CODE
124
CLASS="FUNCDEF"
125
>void cyg_scheduler_lock</CODE
126
>(void);</CODE
127
></P
128
><P
129
><CODE
130
><CODE
131
CLASS="FUNCDEF"
132
>void cyg_scheduler_unlock</CODE
133
>(void);</CODE
134
></P
135
><P
136
><CODE
137
><CODE
138
CLASS="FUNCDEF"
139
>cyg_ucount32 cyg_scheduler_read_lock</CODE
140
>(void);</CODE
141
></P
142
><P
143
></P
144
></DIV
145
></DIV
146
><DIV
147
CLASS="REFSECT1"
148
><A
149
NAME="KERNEL-SCHEDCONTROL-DESCRIPTION"
150
></A
151
><H2
152
>Description</H2
153
><P
154
><TT
155
CLASS="FUNCTION"
156
>cyg_scheduler_start</TT
157
> should only be called once,
158
to mark the end of system initialization. In typical configurations it
159
is called automatically by the system startup, but some applications
160
may bypass the standard startup in which case
161
<TT
162
CLASS="FUNCTION"
163
>cyg_scheduler_start</TT
164
> will have to be called
165
explicitly. The call will enable system interrupts, allowing I/O
166
operations to commence. Then the scheduler will be invoked and control
167
will be transferred to the highest priority runnable thread. The call
168
will never return.
169
      </P
170
><P
171
>The various data structures inside the eCos kernel must be protected
172
against concurrent updates. Consider a call to
173
<TT
174
CLASS="FUNCTION"
175
>cyg_semaphore_post</TT
176
> which causes a thread to be
177
woken up: the semaphore data structure must be updated to remove the
178
thread from its queue; the scheduler data structure must also be
179
updated to mark the thread as runnable; it is possible that the newly
180
runnable thread has a higher priority than the current one, in which
181
case preemption is required. If in the middle of the semaphore post
182
call an interrupt occurred and the interrupt handler tried to
183
manipulate the same data structures, for example by making another
184
thread runnable, then it is likely that the structures will be left in
185
an inconsistent state and the system will fail.
186
      </P
187
><P
188
>To prevent such problems the kernel contains a special lock known as
189
the scheduler lock. A typical kernel function such as
190
<TT
191
CLASS="FUNCTION"
192
>cyg_semaphore_post</TT
193
> will claim the scheduler lock,
194
do all its manipulation of kernel data structures, and then release
195
the scheduler lock. The current thread cannot be preempted while it
196
holds the scheduler lock. If an interrupt occurs and a DSR is supposed
197
to run to signal that some event has occurred, that DSR is postponed
198
until the scheduler unlock operation. This prevents concurrent updates
199
of kernel data structures.
200
      </P
201
><P
202
>The kernel exports three routines for manipulating the scheduler lock.
203
<TT
204
CLASS="FUNCTION"
205
>cyg_scheduler_lock</TT
206
> can be called to claim the
207
lock. On return it is guaranteed that the current thread will not be
208
preempted, and that no other code is manipulating any kernel data
209
structures. <TT
210
CLASS="FUNCTION"
211
>cyg_scheduler_unlock</TT
212
> can be used to
213
release the lock, which may cause the current thread to be preempted.
214
<TT
215
CLASS="FUNCTION"
216
>cyg_scheduler_read_lock</TT
217
> can be used to query the
218
current state of the scheduler lock. This function should never be
219
needed because well-written code should always know whether or not the
220
scheduler is currently locked, but may prove useful during debugging.
221
      </P
222
><P
223
>The implementation of the scheduler lock involves a simple counter.
224
Code can call <TT
225
CLASS="FUNCTION"
226
>cyg_scheduler_lock</TT
227
> multiple times,
228
causing the counter to be incremented each time, as long as
229
<TT
230
CLASS="FUNCTION"
231
>cyg_scheduler_unlock</TT
232
> is called the same number of
233
times. This behaviour is different from mutexes where an attempt by a
234
thread to lock a mutex multiple times will result in deadlock or an
235
assertion failure.
236
      </P
237
><P
238
>Typical application code should not use the scheduler lock. Instead
239
other synchronization primitives such as mutexes and semaphores should
240
be used. While the scheduler is locked the current thread cannot be
241
preempted, so any higher priority threads will not be able to run.
242
Also no DSRs can run, so device drivers may not be able to service
243
I/O requests. However there is one situation where locking the
244
scheduler is appropriate: if some data structure needs to be shared
245
between an application thread and a DSR associated with some interrupt
246
source, the thread can use the scheduler lock to prevent concurrent
247
invocations of the DSR and then safely manipulate the structure. It is
248
desirable that the scheduler lock is held for only a short period of
249
time, typically some tens of instructions. In exceptional cases there
250
may also be some performance-critical code where it is more
251
appropriate to use the scheduler lock rather than a mutex, because the
252
former is more efficient.
253
      </P
254
></DIV
255
><DIV
256
CLASS="REFSECT1"
257
><A
258
NAME="KERNEL-SCHEDCONTROL-CONTEXT"
259
></A
260
><H2
261
>Valid contexts</H2
262
><P
263
><TT
264
CLASS="FUNCTION"
265
>cyg_scheduler_start</TT
266
> can only be called during
267
system initialization, since it marks the end of that phase. The
268
remaining functions may be called from thread or DSR context. Locking
269
the scheduler from inside the DSR has no practical effect because the
270
lock is claimed automatically by the interrupt subsystem before
271
running DSRs, but allows functions to be shared between normal thread
272
code and DSRs.
273
      </P
274
></DIV
275
><DIV
276
CLASS="NAVFOOTER"
277
><HR
278
ALIGN="LEFT"
279
WIDTH="100%"><TABLE
280
SUMMARY="Footer navigation table"
281
WIDTH="100%"
282
BORDER="0"
283
CELLPADDING="0"
284
CELLSPACING="0"
285
><TR
286
><TD
287
WIDTH="33%"
288
ALIGN="left"
289
VALIGN="top"
290
><A
291
HREF="kernel-spinlocks.html"
292
ACCESSKEY="P"
293
>Prev</A
294
></TD
295
><TD
296
WIDTH="34%"
297
ALIGN="center"
298
VALIGN="top"
299
><A
300
HREF="ecos-ref.html"
301
ACCESSKEY="H"
302
>Home</A
303
></TD
304
><TD
305
WIDTH="33%"
306
ALIGN="right"
307
VALIGN="top"
308
><A
309
HREF="kernel-interrupts.html"
310
ACCESSKEY="N"
311
>Next</A
312
></TD
313
></TR
314
><TR
315
><TD
316
WIDTH="33%"
317
ALIGN="left"
318
VALIGN="top"
319
>Spinlocks</TD
320
><TD
321
WIDTH="34%"
322
ALIGN="center"
323
VALIGN="top"
324
><A
325
HREF="kernel.html"
326
ACCESSKEY="U"
327
>Up</A
328
></TD
329
><TD
330
WIDTH="33%"
331
ALIGN="right"
332
VALIGN="top"
333
>Interrupt Handling</TD
334
></TR
335
></TABLE
336
></DIV
337
></BODY
338
></HTML
339
>

powered by: WebSVN 2.1.0

© copyright 1999-2024 OpenCores.org, equivalent to Oliscience, all rights reserved. OpenCores®, registered trademark.