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

Subversion Repositories openrisc

[/] [openrisc/] [trunk/] [rtos/] [rtems/] [c/] [src/] [exec/] [score/] [src/] [Unlimited.txt] - Blame information for rev 279

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

Line No. Rev Author Line
1 30 unneback
#
2
#  $Id: Unlimited.txt,v 1.2 2001-09-27 11:59:34 chris Exp $
3
#
4
 
5
This document explains how the unlimited objects support works.  This was
6
written by Chris Johns  of Objective Design Systems as a
7
design document.  This was submitted as part of the patch which added
8
this capability.
9
 
10
Unlimited Local Node Objects
11
============================
12
 
13
1. Why ?
14
 
15
This patch changes the way RTEMS allocates, frees, and manages the
16
'Objects_Control' structure.
17
 
18
The 'Objects_Control' structure is at the root of all objects in
19
RTEMS. The RTEMS and POSIX API allows users to create tasks, message
20
queues, semaphores and other resources. These are all a type of
21
Object. The POSIX API allow similar operations. These also map to
22
Objects.
23
 
24
Currently the number of objects that can be created is a static value
25
loaded into the Configuration table before starting the kernel. The
26
application cannot exceed these limits. Various means are used to tune
27
this value. During development the value is usually set large. This
28
saves having to change it everytime a developer adds a new
29
resource. With a large team of developers the configuration table file
30
can cycle through a large number of revisions. The wasted memory is
31
only recovered when memory runs short. The issue of the configuration
32
table parameters become more important the less memory you have.
33
 
34
The Configuration table requires a calculation to occur at compile
35
time to set the size of the Workspace. The calculation is an
36
estimate. You need to specify an overhead value for memory that can
37
not be calculated. An example of memory that cannot be calculated is
38
stack sizes. This issue is not directly related to allowing unlimited
39
objects how-ever the need to calculate the memory usage for a system
40
in this manner is prone to error.
41
 
42
I would like to see download support added to RTEMS. The kernel
43
configuration being set at boot time means a download application can
44
be limited. This can defeat one of the purposes of using downloaded
45
code, no need to change ROMs. In a system I worked on the cost to
46
change ROMS in a complete system was high and could take a week. This
47
change is the first phase of supporting downloaded applications.
48
 
49
1.1 How do Objects work ?
50
 
51
All applications interact with the super core (c/src/exec/score) via
52
an API. The central structure used in the super core is the
53
`object'. Two application interfaces exist. They are RTEMS and
54
POSIX. Both map to the super core using objects.
55
 
56
An object in RTEMS is a resource which the user (through the API)
57
creates. The different types of objects are referred to as classes of
58
objects. An object is referenced by an id. This is of type `rtems_id'
59
and is a 32bit unsigned integer. The id is unique for each object no
60
matter what class.
61
 
62
Objects are anchored by the `_Object_Information' structure. There is
63
one per type or class of object. A global table of pointers to each
64
information structure for a class of objects is held in
65
`Objects_Information_table'.
66
 
67
Objects consist of 6 main structures. The `_Object_Information' is the
68
root structure. It contains pointers to the `local_table',
69
`name_table', `global_table', the Inactive chain, and the object
70
memory. It also contains the various variables which describe the
71
object. We are only concerned with the `local_table', `name_table',
72
Inactive chain, and the object memory to support unlimited objects.
73
 
74
The `local_table' holds the pointers to open objects. A `local_table
75
entry which is null is free and the object will be sitting on the
76
Inactive chain. The index into the table is based on part of the
77
id. Given an id the you can find the index into the `local_table', and
78
therefore the object. The `local_table' has the entries for the
79
indexes below the minimum_id's index. The minimum_id is always set to
80
1 (the change allows another value to be selected if require). The
81
index of 0 is reserved and never used. This allows any actions using
82
an id of zero to fail or map to a special case.
83
 
84
The `name_table' holds the names of the objects. Each entry in this
85
table is the maximum size the name of the object can be. The size of
86
names is not constrained by the object code (but is by the MP object
87
code, and the API and should be fixed).
88
 
89
The `global_table' and code that uses it has not changed. I did not
90
look at the this code, and I am not farmilar with it.
91
 
92
The Inactive chain stores objects which are free or not
93
allocated. This design saves searching for a free object when
94
allocating therefore providing a deterministic allocation scheme. When
95
the chain is empty a null is returned.
96
 
97
The change documented below basically extends the `local_table' and
98
`name_table' structures at run-time. The memory used be these table
99
is not large compared to the memory for the objects, and so are never
100
reduced in size once extended. The object's memory grows and shrinks
101
depending of the user's usage.
102
 
103
Currently, the user specifies the total number of objects in the
104
Configuration table. The change alters the function of the values in
105
the Configuration table. A flag can be masked on to the value which
106
selects the extending mode. If the user does not set the flag the
107
object code operates with an object ceiling. A small performance
108
overhead will be incurred as the allocate and free routines are now
109
not inlined and a check of the auto_extend flag is made. The remaining
110
value field of the Configuration table entry is total number of
111
objects that can be allocated when not in unlimited mode.
112
 
113
If the user masks the flag on to a value on the Configuration table
114
auto-exdending mode is selected for that class of object. The value
115
becomes the allocation unit size. If there are no free objects the
116
object's tables are extended by the allocation unit number of
117
objects. The object table is shrunk when the user frees objects. The
118
table must have one free allocation block, and at least half the
119
allocation size of another block before the object memory of the free
120
allocation block is returned to the heap. This stops threshold
121
thrashing when objects around the allocation unit size and created and
122
destroyed.
123
 
124
At least one allocation block size of objects is created and never
125
destroyed.
126
 
127
The change to support unlimited objects has extended the object
128
information structure.
129
 
130
The flag, `auto_extend' controls if the object can be automatically
131
extended. The user masks the flag RTEMS_UNLIMITED_FLAGS onto the
132
Configuration table number to select the auto-extend mode. This is
133
passed to the `_Objects_Initialize_information' function in the
134
parameter maximum. The flag is tested for and the auto_extend flag
135
updated to reflect the state of the flag before being stipped from the
136
maximum.
137
 
138
The `allocation_size' is set to the parameter maxium in the function
139
`_Objects_Initialize_information' if `auto_extend' is true. Making the
140
allocation size small causes the memory to be allocated and freed more
141
often. This only effects the performance times for creating a resource
142
such as a task. It does how-ever give you fine grain memory
143
control. If the performance of creating resources is not a problem
144
make the size small.
145
 
146
The size of the object is required to be stored. It is used when
147
extending the object information.
148
 
149
A count of the object on the Inactive list is maintained. This is used
150
during freeing objects. If the count is above 1.5 times the
151
`allocation_size' an attempt is made to shrink the object
152
informtation. Shrinking might not always succeed as a single
153
allocation block might not be free. Random freeing of objects can
154
result in some fragmentation. Any further allocations will use the
155
free objects before extending the object's information tables.
156
 
157
A table of inactive objects per block is maintained. This table, like
158
the `local_table' and `name_table' grows as more blocks are
159
allocated. A check is made of a blocks inactive count when an object
160
which is part of that block is freed. If the total inactive count
161
exceeds 1.5 times the allocation size, and the block's inactive count
162
is the allocation_size, the objects data block is returnd to the
163
workspace heap.
164
 
165
The `objects_blocks' is a table of pointers. The object_block's pointers
166
point to the object's data block. The object's data block is a single
167
allocation of the name space and object space. This was two separate
168
allocations but is now one. The objects_block's table is use to
169
determine if a block is allocated, and the address of the memory block
170
to be returned to the workspace heap when the object informtation
171
space is shrunk.
172
 
173
2.0 Detail Of the Auto-Extend Patch to rtems-4.0.0, Snapshot 19990302
174
 
175
o Configuration table support.
176
 
177
  Added a flag OBJECTS_UNLIMITED_OBJECTS to score/headers/object.h
178
  header file. This is referenced in the file sapi/headers/config.h to
179
  create the flag RTEMS_UNLIMITED_OBJECTS. A macro is provided to take
180
  a resource count and apply the flag. The macro is called
181
  `rtems_resource_unlimited'. The user uses this macro when building a
182
  configuration table. It can be used with the condefs.h header file.
183
 
184
o Object Information Structure
185
 
186
  The object information structure, Objects_Information, has been
187
  extended with the follow fields :
188
 
189
    boolean auto_extend -
190
 
191
      When true the object's information tables can be extended untill
192
      all memory is used. When false the current functionallity is
193
      maintained.
194
 
195
    unsigned32 allocation_size -
196
 
197
      When auto_extend is true, it is the value in the Configuration
198
      table and is the number of objects the object's information
199
      tables are extended or shrunk.
200
 
201
   unsigned32 size -
202
 
203
      The size of the object. It is used to calculate the size of
204
      memory required to be allocated when extending the table.
205
 
206
   unsigned32 inactive -
207
 
208
      The number of elements on the Inactive chain.
209
 
210
   unsigned32 *inactive_per_block -
211
 
212
      Pointer to a table of counts of the inactive objects from a
213
      block on the Inactive chain. It is used to know which blocks are
214
      all free and therefore can be returned to the heap.
215
 
216
   void **object_blocks -
217
 
218
      Pointer to a table of pointers to the object data. The table
219
      holds the pointer used to return a block to the heap when
220
      shrinking the object's information tables.
221
 
222
o Changes to Existing Object Functions
223
 
224
  Two functions prototypes are added. They are :
225
 
226
   _Objects_Extend_information,
227
   _Objects_Shrink_information
228
   _Object_Allocate, and
229
   _Object_Free
230
 
231
  The last were inlined, how-ever now they are not as they are too
232
  complex to implement as macros now.
233
 
234
o Object Inline and Macro Changes
235
 
236
  The functions :
237
 
238
   _Object_Allocate, and
239
   _Object_Free
240
 
241
  are now not inlined. The function :
242
 
243
   _Objects_Get_local_object, and
244
   _Objects_Set_local_object
245
 
246
  have been added. There was no provided interface to allow an API to
247
  get/set an objects local pointer given an index. The POSIX code
248
  should be updated to use this interface.
249
 
250
  The function :
251
 
252
   _Objects_Get_information
253
 
254
  has been moved to be an inline function. It is used in the get
255
  object call which the API uses for every object reference.
256
 
257
o Object Initialisation
258
 
259
  The function _Objects_Initialize_information has been changed to
260
  initialisation of the information structure's fields then call the
261
  new function _Objects_Extend_information.
262
 
263
  The first block of objects is always allocated and never
264
  released. This means with the auto-extend flag set to true the user
265
  still sees the same behaviour expected without this change. That is
266
  the number objects specified in the Configuration table is the
267
  number of object allocated during RTEMS initialisation. If not
268
  enough memory is found during this initial extend a fatal error
269
  occurs. The fatal error only occurs for this case of extending the
270
  object's information tables.
271
 
272
o Object Information Extend
273
 
274
  The _Object_Information_Extend is a new function. It takes some of
275
  the code form the old _Object_Initialize_information function. The
276
  function extends an object's information base.
277
 
278
  Extending the first time is a special case. The function assumes the
279
  maximum index will be less than the minimum index. This means the
280
  minimum index must be greater than 0 at initialisation. The other
281
  special case made is coping the tables from the old location to the
282
  new location. The first block case is trapped and tables are
283
  initialised instead. Workspace allocation for the first block is
284
  tested for an if the first block the allocate or fatal error call is
285
  made. This traps an RTEMS initialise allocation error.
286
 
287
  The remainder of the code deals with all cases of extending the
288
  object's information.
289
 
290
  The current block count is first determined, then a scan of the
291
  object_block table is made to locate a free slot. Blocks can be
292
  freed in any order. The index base for the block is also determined.
293
 
294
  If the index base is greater than the maximum index, the tables must
295
  grow. To grow the tables, a new larger memory block is allocated and
296
  the tables copied. The object's information structure is then
297
  updated to point to the new tables. The tables are allocated in one
298
  memory block from the work-space heap. The single block is then
299
  broken down in the required tables.
300
 
301
  Once the tables are copied, and the new extended parts initialised
302
  the table pointers in the object's information structure are
303
  updated. This is protected by masking interrupts.
304
 
305
  The old table's memory block is returned to the heap.
306
 
307
  The names table and object is allocated. This again is a single
308
  block which is divided.
309
 
310
  The objects are initialised onto a local Inactive chain. They are
311
  then copied to the object's Inactive chain to complete the
312
  initialisation.
313
 
314
o Object Informtation Shrink
315
 
316
  The _Object_Shrink_information function is new. It is required to
317
  scan all the blocks to see which one has no objects allocated. The
318
  last object freed might not belong to a block which is completely
319
  free.
320
 
321
  Once a block is located, the Inactive chain is interated down
322
  looking for objects which belong to the block of object being
323
  released.
324
 
325
  Once the Inactive chain scan is complete the names table and object
326
  memory is returned to the work-space heap and the table references cleared.
327
 
328
  XXX - I am not sure if this should occur if better protection or
329
  different code to provide better protection.
330
 
331
  The information tables do not change size. Once extended they never
332
  shrink.
333
 
334
o Object Allocation
335
 
336
  The _Objects_Allocate attempts to get an object from the Inactive
337
  chain. If auto-extend mode is not enabled no further processing
338
  occurs. The extra overhead for this implemetation is the function is
339
  not inlined and check of a boolean occurs. It should effect the
340
  timing figures.
341
 
342
  If auto-extend is enabled, a further check is made to see if the get
343
  from the Inactive chain suceeded in getting an object. If it failed
344
  a call is made to extend the object's information tables.
345
 
346
  The get from the Inactive chain is retried. The result of this is
347
  returned to the user. A failure here is the users problem.
348
 
349
o Object Free
350
 
351
  The _Objects_Free puts the object back onto the Inactive
352
  chain. Again if auto-extend mode is not enabled no further
353
  processing occurs and performance overhead will low.
354
 
355
  If auto-extend mode is enabled, a check is to see if the number of
356
  Inactive objects is one and a half times the allocation size. If
357
  there are that many free objects an attempt is made to shrink the
358
  object's information.
359
 
360
o Object Index and the Get Function
361
 
362
  The existing code allocates the number of object specified in the
363
  configuration table, how-ever it makes the local_table have one more
364
  element. This is the slot for an id of 0. The 0 slot is always a
365
  NULL providing a simple check for a 0 id for object classes.
366
 
367
  The existing _Objects_Get code removes the minimum id, which I think
368
  could only be 1 from the index, then adds one for the 0 slot.
369
 
370
  This change removes this index adjustment code in _Objects_Get.
371
 
372
  The extend information starts the index count when scanning for free
373
  blocks at the minumun index. This means the base index for a block
374
  will always be adjusted by the minimum index. The extend information
375
  function only ever allocates the allocation size of
376
  objects. Finially the object's local_table size is the maximum plus
377
  the minumum index size. The maximum is really the maximum index.
378
 
379
  This means the values in the object's information structure and
380
  tables do not need the index adjustments which existed before.
381
 
382
o The Test
383
 
384
  A new sample test, unlimited is provided. It attempts to test this
385
  change.
386
 
387
 

powered by: WebSVN 2.1.0

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