Motorola 6806800C08B manual Simple Software Upgrade, System Resource Monitoring Service

Page 35

Simple Software Upgrade

NetPlane Core Services

 

 

HCD is scoped to one chassis and there are two instances of HCD in a chassis: one active and one stand-by. The main tasks of HCD are:

zPerforming HPI discovery sequence to realize the physical entities in the chassis

zPublishing HPI events

zExecuting HPI APIs

zSupporting those parts of the HPI MIB which are scoped to the chassis which the HCS is responsible for

2.6.2.1.3HPI Adaption Private Library (HPL)

The HPI Adaption Private Library (HPL) is an NCS-internal private library that is used by the SPSv and AvSv to communicate its wishes to the HCD.

2.6.3Simple Software Upgrade

The Simple Software Upgrade (SSU) service allows to upgrade software components in the Avantellis system. This includes the upgrade of kernel, PCS software, NCS software and customer applications.

2.6.3.1Basic Functionality

The SSU supports the upgrade of software components on system controller blades. The images are booted from disk. The upgrade itself is controlled and managed via CLI commands.

Note that for the upgrade of software components on payload blades, mechanisms like DHCP and netboot are used.

2.6.3.2Architecture

The main component of the SSU is the Simple Software Upgrade Node (SUND). It manages the software upgrade on the respective system manager node it resides on. It furthermore handles SSU CLI commands which are issued to trigger the software upgrade.

For details about the SSU service, refer to the Simple Software Upgrade Programmer’s Reference.

2.6.4System Resource Monitoring Service

The System Resource Monitoring Service (SRMSv) service oversees system resource utilization by applications and notifies those applications of resource consumption events. Monitoring takes place at node-level.

The SRMSv is implemented as a bundle of System Resource Monitoring Agent (SRMA) and System Resource Monitoring Node Director (SRMND). There is no central director.

For further details about this service refer to the System Resource Monitoring Service programmer’s Reference

NetPlane Core Services Overview User’s Guide (6806800C08B)

35

Page 34 Page 36
Image 35
Page 34 Page 36
Contents NetPlane Core Services Overview Trademarks Contents NetPlane Core Services Overview User’s Guide 6806800C08B ContentsList of Tables Page Avantellis Main Software Components List of FiguresPage Abbreviations Overview of ContentsAbout this Manual HPM About this Manual Abbreviation DefinitionBold ConventionsNotation Description Part Number Edition Description Summary of ChangesComments and Suggestions About this Manual Notation DescriptionAvantellis 3000 Series Overview IntroductionIntroduction Avantellis 3000 Series Software ArchitectureNetPlane Software Carrier Grade Linux Operating System Introduction Carrier Grade Linux Operating SystemPage Architectural Overview NetPlane Core ServicesCorresponding SAF AIS NCS Service Name Services Description NCS ServicesNetPlane Core Services NCS Services Leap Portability Layer Message Distribution ServiceMessage Distribution Service NetPlane Core Services NCS Service Name DescriptionNCS Directors Distribution of NCS Services in the Avantellis SystemNetPlane Core Services System Description System DescriptionNCS Directors NCS Directors NetPlane Core ServicesSample Applications NetPlane Core Services NCS ServersNCS Servers System Description System Description NetPlane Core ServicesDescription Category Management AccessNetPlane Core ServicesManagement Access Management Access NetPlane Core Services Management Access Information FlowNetPlane Core Services SAF-Compliant NCS Services SAF-Compliant NCS ServicesAvailability Service Availability Manager Availability Service NetPlane Core ServicesAvailability Director Availability Agent Checkpoint ServiceNetPlane Core Services Checkpoint Service Availability Node DirectorCheckpoint Director Checkpoint Service NetPlane Core ServicesCheckpoint Agent Message Queue ServiceCheckpoint Node Director Message Queue Node Director Event Distribution ServiceEvent Distribution Service NetPlane Core Services Message Queue DirectorEvent Distribution Agent Global Lock ServiceNetPlane Core Services Global Lock Service Event Distribution ServerGlobal Lock Node Director Motorola Complementary NCS ServicesDistributed Tracing Service Global Locking DirectorArchitecture HPI Integration ServiceDistributed Trace Server Distributed Trace AgentHPI Adaption Private Library HPL Simple Software UpgradeSystem Resource Monitoring Service Simple Software Upgrade NetPlane Core ServicesPersistent Store Server Persistent Store-Restore ServiceSystem Description Parser Management Access ServicesPSSv Command Execution Functions Management Access Services NetPlane Core ServicesObject Access Agent Management Access AgentSnmp Management Access Point Message-Based Checkpointing ServiceManagement Access Server Command Line Interpreter Management Access PointInterface Service Interface Agents Message Distribution ServiceInterface Director Interface Node DirectorNetPlane Core Services Message Distribution Service Message Distribution Service Software ComponentsImplementation Notes Cancelling Application ThreadsLeap Portability Layer NetPlane Core Services Leap Portability LayerPage Introduction Toolkit InstallationToolkit Contents NCS ToolkitNCS Toolkit Building the Samples Make CommandsBuilding the Samples Development Host PrerequisitesParameters Make CommandsNCS ToolkitNCS Toolkit Running the Sample programs Running the Sample programsTarget Prerequisites Running the Sample Programs Setting LdlibrarypathSetting Ldlibrarypath NCS Toolkit Page Document Title Publication Number Related DocumentationMotorola Embedded Communications Computing Documents Document Title Version/Source Related SpecificationsRelated Documentation Related Specifications

6806800C08B specifications

The Motorola 68000 microprocessor, particularly the revision marked as 68000C08B, stands out as a seminal component in the evolution of computing technology. Introduced in 1979, the 68000 architecture laid the groundwork for many advanced systems, influencing a multitude of platforms, from personal computers to game consoles.

The Motorola 68000C08B features a 16-bit data bus and a 24-bit address bus, allowing for a memory addressing capability of up to 16 MB. This architecture was pioneering for its time, enabling more extensive and complex software applications than its predecessors. The C08 revision particularly emphasized optimizing power consumption while maintaining performance, making it ideal for embedded systems and portable devices.

One of the 68000's key characteristics is its unique register set, which allows for a versatile range of operations. It consists of 8 general-purpose data registers and 8 address registers. The architecture supports both integer and floating-point operations, thanks to an integrated instruction set that facilitates complex mathematical computations, crucial for applications in graphics and gaming.

In terms of performance, the 68000 processor operates at clock speeds ranging from 8 MHz to 16 MHz, depending on the specific variant. The instruction set architecture (ISA) is known for its orthogonality, meaning that most instructions can be used interchangeably across different registers. This design simplicity allows for efficient coding and faster execution times, a significant advantage for developers.

Another remarkable feature of the 68000C08B is its capability for multitasking and improved context switching. Its advanced memory management, combined with support for virtual memory in later implementations, catered to the needs of operating systems and real-time applications, making it suitable for both consumer electronics and industrial machinery.

The Motorola 68000 family also supports a variety of peripherals, enhancing its flexibility as a microcontroller. This compatibility allowed manufacturers to create diverse product lines, from keypads and mice to modems and hard drives.

In summary, the Motorola 68000C08B microprocessor not only advanced the landscape of computer technology in the late 20th century but also helped set the stage for future innovations through its architecture, performance capabilities, and versatility in numerous applications. Its legacy continues to influence modern computing paradigms, ensuring the 68000 remains an essential chapter in the history of microprocessors.
Top Page Image Contents