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1 <?xml version="1.0" encoding="utf-8"?> |
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2 <!-- Copyright (c) 2007-2010 Nokia Corporation and/or its subsidiary(-ies) All rights reserved. --> |
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3 <!-- This component and the accompanying materials are made available under the terms of the License |
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4 "Eclipse Public License v1.0" which accompanies this distribution, |
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5 and is available at the URL "http://www.eclipse.org/legal/epl-v10.html". --> |
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6 <!-- Initial Contributors: |
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7 Nokia Corporation - initial contribution. |
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8 Contributors: |
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9 --> |
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10 <!DOCTYPE concept |
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11 PUBLIC "-//OASIS//DTD DITA Concept//EN" "concept.dtd"> |
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12 <concept id="GUID-2700AAC8-A034-5E7D-B0E0-26B49E68BB18" xml:lang="en"><title>Personality Layer for Real Time Applications</title><shortdesc>A base port can add a software layer called a personality |
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13 layer to the Kernel to provide an emulation of a real time operating |
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14 system (RTOS)</shortdesc><prolog><metadata><keywords/></metadata></prolog><conbody> |
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15 <p>. You can provide a personality layer so that a phone can run existing |
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16 protocol stacks, for example, mobile telephony signalling stacks, |
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17 or Bluetooth stacks, on the same CPU that runs the Symbian platform |
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18 applications. </p> |
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19 <p>Such protocol stacks, often referred to as Real Time Applications |
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20 (RTA), almost always run on an RTOS, and the aim of the personality |
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21 layer is to provide the same API as the RTOS, or at least as much |
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22 of it as is required by the RTA. The RTA can then run, using the Kernel |
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23 Architecture 2 Nanokernel layer as the underlying real time kernel. </p> |
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24 <p>The following diagram illustrates the point simply. </p> |
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25 <fig id="GUID-AA5502A3-37BE-5A73-A8D9-1B18DDCC8C96"> |
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26 <image href="GUID-058FAE44-DF72-53E2-BE62-EDC840A7C87F_d0e25110_href.png" placement="inline"/> |
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27 </fig> |
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28 <p>There is sample code at <filepath>...\e32\personality\...</filepath> that you should refer to while reading this. </p> |
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29 <section id="GUID-D1217729-E0E4-5A02-A02F-524EA9F1D679"><title>RTOS |
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30 environment features</title> <p>As a basis for emulating an RTOS, |
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31 the RTOS is assumed to provide the following features: </p> <ul> |
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32 <li id="GUID-107CEB20-80DA-5AF8-A116-C5FA5E437993"><p>Threads </p> </li> |
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33 <li id="GUID-496701DC-E711-5509-B593-5B5A51A7DFC2"><p>Thread synchronisation/communication </p> </li> |
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34 <li id="GUID-5ADDB09E-7528-50E0-8661-C64C91AF32CA"><p>Thread scheduling |
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35 following a hardware interrupt </p> </li> |
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36 <li id="GUID-4856FE5E-95E6-5455-B226-9314071F948E"><p>Timer management |
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37 functionality </p> </li> |
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38 <li id="GUID-C721F13B-14F9-5E01-9721-19E9475A421B"><p>Memory management. </p> </li> |
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39 </ul> <p><b>Threads</b> </p> <p>Threads are independent units of execution, |
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40 usually scheduled on a strict highest-priority-first basis. There |
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41 are generally a fixed number of priorities. Round robin scheduling |
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42 of equal priority threads may be available but is usually not used |
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43 in real time applications. Dynamic creation and destruction of threads |
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44 may or may not be possible. </p> <p><b>Thread synchronisation/communication</b> </p> <p>Typical examples |
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45 of such thread synchronisation and communication mechanisms are semaphores, |
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46 message queues and event flags. </p> <p>There is wide variation between |
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47 systems as to which primitives are provided and what features they |
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48 support. Again, dynamic creation and destruction of such synchronisation |
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49 and communication objects may or may not be supported. Mutual exclusion |
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50 protection is often achieved by simply disabling interrupts, or occasionally |
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51 by disabling rescheduling. </p> <p><b>Thread scheduling following a hardware interrupt</b> </p> <p>This |
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52 is usually achieved by allowing interrupt service routines (ISRs) |
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53 to make system calls which perform operations such as signalling a |
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54 semaphore, posting a message to a queue or setting event flags, which |
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55 would cause a thread waiting on the semaphore, message queue or event |
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56 flag to run. </p> <p>Some systems don't allow ISRs to perform these |
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57 operations directly but require them to queue some kind of deferred |
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58 function call. This is a function which runs at a lower priority than |
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59 hardware interrupts (i.e. with interrupts enabled) but at a higher |
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60 priority than any thread - for example a Nucleus Plus HISR. The deferred |
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61 function call then performs the operation which causes thread rescheduling. </p> <p><b>Timer management functionality</b> </p> <p>A timer management |
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62 function is usually also provided, allowing several software timers |
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63 to be driven from a single hardware timer. On expiry, a software timer |
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64 may call a supplied timer handler, post a message to a queue or set |
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65 an event flag. </p> <p><b>Memory management</b> </p> <p>An RTOS often provides memory management, |
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66 usually in the form of fixed size block management as that allows |
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67 real time allocation and deallocation. Some RTOSs may also support |
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68 full variable size block management. However most RTOSs do not support |
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69 use of a hardware MMU and, even if the RTOS supports it (for example |
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70 OSE does), the real time applications under consideration do not make |
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71 use of such support since they are generally written to run on hardware |
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72 without an MMU. </p> </section> |
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73 </conbody></concept> |