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Overview of Pegasus An Open-Source WBEM implementation

Agenda. Overview -What (and why)is Pegasus?The Pegasus EnvironmentThe Pegasus Software ArchitecturePegasus Status TodayPlansThe Pegasus ProjectPegasus and ???A Challenge for the Future. 1. Overview. What is Pegasus?. Pegasus is an open-source reference implementation of the DMTF WBEM specifi

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Overview of Pegasus An Open-Source WBEM implementation

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    1. Overview of Pegasus An Open-Source WBEM implementation 12 June 2001 Michael Brasher (m.brasher@bmc.com) Karl Schopmeyer(k.schopmeyer@opengroup.org)

    2. Agenda Overview -What (and why)is Pegasus? The Pegasus Environment The Pegasus Software Architecture Pegasus Status Today Plans The Pegasus Project Pegasus and ??? A Challenge for the Future

    4. What is Pegasus? Pegasus is an open-source reference implementation of the DMTF WBEM specifications Pegasus is a work project of the TOG Enterprise Management Forum Pegasus is a platform for building application management Pegasus is a function-rich, production-quality open-source implementation designed to be used in high volume server implementations.

    5. Why Produce Pegasus? Demonstrate manageability concepts. Provide additional standards for WBEM Provide a working implementation of WBEM technologies Provide an effective modular implementation Support other TOG manageability standards Base Platform for Open Group Application management Projects

    6. Origins of Pegasus Pegasus was initiated in 2000 by the Open Group in collaboration with: BMC Software IBM Tivoli Systems

    7. Key Pegasus Objectives Open source MIT License, open availability Portable Code designed for portability Efficient and Lightweight Implemented in C++ Standards Based DMTF CIM/WBEM compliant Modular and extensible Use both internal and external modularity

    8. Pegasus Working Group Philosophy Manageability not management The working groups objective is not to manage systems but to make them manageable by promoting a standard instrumentation environment The actual management of systems is left to systems management vendors No standards without implementation The process of implementation provides a rigorous process for testing the validity of standards Therefore all standards must be validated by implementation

    9. Major Objectives of Pegasus Standards Based and Compliant DMTF CIM/WBEM Interoperable DMTF cim-xml Interface Efficient and Lightweight Implemented in C++ Portable NT, Linux, and others planned Modular Replaceable modules for function change and growth Extensible Manageability Service extensions

    10. Open Source Code and documentation freely available Open Group and Source Forge MIT source License Open to contributions

    11. Portable Designed for multi-platform, mulit-os, multi-compilers. Platforms today UNIX (AIX, HPUX, Solaris) Linux Windows Platforms (NT, 2000, 9x) Compaq Himalaya (Tandem)

    12. Efficient and Lightweight Core written in C++ Designed for execution efficiency

    13. Standards Based Based on DMTF CIM and CIM-XML specifications Open Group is active partner in DMTF Growth through participation in specification growth Commitment to continue DMTF compliance

    14. Modular and Extensible Minimize core object broker. Maximize extensibility through plug-in components Component types Providers Provider interfaces Clients Repositories (additional repository handlers) Manageability service extensions Protocol Adapters Modules (extend and modify core functions)

    16. Pegasus Architecture

    17. Key Interoperability Interfaces

    18. The CIM Operations

    19. Operations Routing Class Operations Routed to the Class Repository Instance Operations To Provider if Provider Qualifier exists To Instance repository if no Provider Instance routing at Class Level Today Issues Routing at instance level

    20. Key Characteristics Open source Available Today Portable Designed to build and run on wide variety of platforms C++ core C++ CIM Objects C++ Operation/Provider/Service/Repository interfaces Modular and extensible Modular components to extend the core Manageability service extensions to extend functionality Light weight

    21. Modularity and Extensibility Providers Grow with DMTF provider concepts Provider Interfaces Protocol Adapters (connectors) Client - Xml-cim today (Soap, etc. in future) Provider, service, repository, etc. Modules Modularize core so it can be extended and modified through attachable modules Manageability Service Extensions Think super providers

    22. Building A Modular Manageability Environmnent

    23. Pegasus Manageability Environment

    24. Provider Interoperability In the classical architecture, interoperability is only supported between the client and server. In addition, the Pegasus architecture aims to support provider/server interoperability. Goal Write a provider once and run it under any CIM server implementation. Provider/Server Interoperability: Participating in efforts to standardize the Provider/Server protocol. Proposing provider API standards. Writing adapters enabling Pegasus providers to run under other CIM servers. Adapters enabling other providers to run under Pegasus

    25. Important Provider Interfaces SUN WBEM Provider Interface Java based Classes, etc. similar to Pegasus C Provider Interface Sun has a specification here. We will support multiple provider interfaces and language bindings.

    26. In-Process and Out-of-process Providers Today Pegasus based on shared Library Providers Extend to Internal Providers IPC based Providers Providers in Remotes systems Objectives: Write Provider once and compile/link for different environments Technique Use connectors as basis for provider/CIMOM communication Issues Security, discovery

    27. Modules The core server functions are organized into loadable modules. Standard APIs are defined for each module. Alternative implementations can be provided later without recompiling the Pegasus server.

    28. Manageability Service Extensions Super Providers Access to the Core Broker

    29. Example Services Indication Management service. Query engine service. Class repository service. Instance repository service.

    30. Connectors (Protocol Adapters) Functions Adapt to different protocols Characteristics Protocol Encoding Security Discovery Examples Xml-CIM Local Protocols Soap WMI

    31. Pegasus Interfaces Common Interface base for Clients, providers, services, connectors Based on CIM Operations over HTTP Additional functions for each interface Interfaces separated from implementation

    33. Introduction

    34. Programming Language Support The Pegasus core is implemented in C++ and hence client and provider interface are provided for C++. An integrated JVM is planned to allow providers to be developed in Java. Of course it is possible to use existing Java clients to interact with the Pegasus CIMOM.

    35. Major Components

    36. Topics Communication. Representation of CIM Elements. The Client Interface. The CIM Object Manager. The Provider Interface. The Repository Interface.

    37. Communication

    38. Pathways of Communication

    39. Component Location A component may be located in one of three places with respect to the CIM Server. In-process. Local out-of-process (on the same machine). Remote out-of-process (on another machine). For example, a provider may be in-process, local, or remote.

    40. Component Location in Pegasus Today

    41. Possible Communication Mechanisms Components could potentially communicate with the CIM Server using the following mechanisms: CIM/HTTP (remote). Proprietary TCP-based protocol (remote). Direct call (in process). Shared memory (local). Named pipes (local).

    42. Communication Mechanisms in Pegasus

    43. Client Communication Uses CIM/HTTP as sole protocol. Asynchronous socket I/O. An efficient XML parser. Fast enough to eliminate the need for a proprietary protocol.

    44. An Efficient XML Parser No memory heap usage during parsing. Modifies message in place to avoid copying. Non-validating parser (loose validation).

    45. HTTP Implementation Uses asynchronous socket I/O in conjunction with message queues to achieve optimal throughput. Provides entry points to adding web server capabilities such as putting and getting of documents (to support remote upgrade and deployment later on).

    46. Proposals Support out-of-process providers (local and remote). Support out-of-process repositories (local and remote). Location independent provider development.

    47. Representation of CIM Elements Representing CIM Elements in Pegasus with C++

    48. CIM Data Types in C++ Uint8 Sint8 Uint16 Sint16 Uint32 Sint32 Uint64 Sint64 Real32 Real64 Boolean Char16 String CIMDateTime CIMReference

    49. CIM Values in C++ CIM values (property, parameter, and qualifier values) are represented using the CIMValue class. This class: Encapsulates a union of all CIM data types. Has a type member indicating the type currently being represented. Provides access/modifier methods overloaded for each CIM data type.

    50. CIM Elements in C++ CIMClass CIMInstance CIMProperty CIMMethod CIMParameter CIMQualifierDecl CIMQualifier

    51. Class Declaration Example (Part 1) Consider the following MOF class declaration: class Alarm { [key] uint64 id; string message = none; };

    52. Class Declaration Example (Part 2) This class is defined in C++ as follows: CIMClass alarmClass(Alarm); CIMProperty id(id, Uint32(0)); id.addQualifier(CIMQualifier(key, true)); CIMProperty message(message, none); alarmClass.addProperty(id); alarmClass.addProperty(message);

    53. Class Declaration Example (Part 3) Or more succinctly like this: CIMClass alarmClass(Alarm); alarmClass .addProperty(CIMProperty(id, Uint32(0)) .addQualifier(CIMQualifier(key, true))) .addProperty(CIMProperty(message, none));

    54. Property Iteration Example: The properties of a class may be iterated like this: CIMClass c; for (Uint32 i = c.getPropertyCount(); i < n; i++) { CIMProperty p = c.getProperty(i); }

    55. The Client Interface

    56. The Client Interface

    57. The Client Interface A C++ interface for interacting with the Pegasus Server (or any CIM Server). Uses CIM/HTTP to communicate. Provides a method for each CIM operation defined in the CIM Operations over HTTP, V1.0 specification.

    58. The CIM Operations GetClass GetInstance DeleteClass DeleteInstance CreateClass CreateInstance ModifyClass ModifyInstance EnumerateClasses EnumerateClassNames EnumerateInstances EnumerateInstanceNames ExecQuery Associators AssociatorNames References ReferenceNames GetProperty SetProperty GetQualifier SetQualifier InvokeMethod

    59. CIM Operation Example

    60. Client Connection Example A client connects to the CIM Server on the host called saturn at port 5988 like this: Selector selector; CIMClient client(&selector); client.connect(saturn:5988);

    61. GetClass Example A client gets a class like this: CIMClass alarmClass = client.getClass(root/cimv2, Alarm);

    62. Client Proposals Asynchronous Interface APIs Interface independent of local/remote client

    63. The CIM Object Manager

    64. The Pegasus CIMOM

    65. Request Lifecycle (Part I)

    66. Request Lifecycle (Part II)

    67. CIMOM Modules Channel - Implements transport mechanism (e.g., TCP). Protocol - Implement application protocol (e.g., HTTP). Encodings - Implements encoding and decoding of messages (e.g., CIM-XML). Dispatcher - Dispatches messages to provider(s)/repository. Repository - Implements CIM Repository. Aggregator - Aggregates results.

    68. Module Concept (Proposed) The internal CIMOM architecture is being refined into a set of modules. Each module handles part of the request lifecycle. Alternative implementations may be provided for each module type. New module implementations can be used to modify or refine the behavior of the CIMOM and to facilitate porting.

    69. Module Implementations (Proposed) Channel - provide a named-pipe implementation. Protocol - provide a proprietary binary protocol. Encodings - provide a binary encoding scheme. Repository - provide a relational-based implementation. Traffic Encryption - SSL implementation. Authentication Challange and response

    70. Module Definition and Loading (Proposed) Modules implement one of the module interfaces (e.g., Repository). Modules are configured as dynamic libraries. Modules listed in modules file. Modules loaded by CIMOM on startup.

    71. Channel Module Example A channel connects two endpoints and enables them to communicate. Uses acceptor/connector pattern from ACE Wrappers. Pegasus provides a TCP implementation which works on Windows and Unix. Other implementations could be provided for named pipes, SNA, or for TCP on other platforms.

    72. The Channel Module

    73. The Provider Interface

    74. The Provider Interface

    75. The Provider Interface The provider interface is defined by the CIMProvider class. The provider interface has a method for each CIM operation in the CIM Operations over HTTP, V1.0 specification. CIMProvider is a base provider interface (more refined provider interfaces are being developed).

    76. CIMProvider Methods getClass() getInstance() deleteClass() deleteInstance() createClass() createInstance() modifyClass() modifyInstance() enumerateClasses() enumerateClassNames() enumerateInstances() enumerateInstanceNames() execQuery() Associators() associatorNames() references() referenceNames() getProperty() setProperty() getQualifier() setQualifier() invokeMethod()

    77. Example of modifyInstance() Method The provider developer derives from CIMProvider and overrides the modifyInstance() method. class MyProvider : public CIMProvider { }; virtual void MyProvider::modifyInstance( const String& nameSpace, CIMInstance& modifiedInstance) { // Modify the instance here! }

    78. Provider Registration and Loading Providers are configured as dynamic libraries with an entry point function for creating the provider instance. The provider() qualifier is placed on the corresponding class in the repository (this qualifier specifies the library name containing the provider implementation) . The provider is loaded on demand (when instances of that class are requested).

    79. Refined Provider Interfaces (Work in Progress) Refined provider interfaces are now being developed. The CIM operations are being assigned to different types of providers: Instance provider Method provider Query provider Event provider Association provider

    80. Provider Interface Managers (Planned) Provider Interface Managers map the base provider interface onto one or more other provider interfaces. This scheme may be used to: Refine the base provider interface into several provider interfaces (as mentioned above). Map the provider interface onto other language provider interfaces (e.g., Java, Perl, Tcl).

    81. Provider Proposals Interoperability with SUN Wbem providers proposal We are extending other interoperability ideas

    82. The Repository Interface

    83. The Repository Interface

    84. The Repository Interface Defines the interface to manipulating the CIM repository. Alternative implementations of this interface may be provided. Pegasus provides a simple default implementation.

    85. The Default Repository Implementation Each CIM object is stored in its own file. CIM objects are encoded as XML in files. Namespaces are represented using file system directories. Single reader/writer at a time. Example: the class X (subclass of Y) which resides in the root/cimv2 namespace would be stored in this file: <repository_root>/root#cimv20/classes/X.Y

    86. The Default Repository Limitations Adequate for classes and qualifiers (which tend to be few). Okay for a few hundred instances. Not intended to scale to thousands of instances (uses a lot of disk space due to internal fragmentation). Good for scenario in which a few instances come from the repository and many instances come from providers.

    87. Alternative Repository Modules Repository modules may be developed to achieve a highly scalable repository. Possibilities include: Basing repository on a relational database. Basing repository on Unix DB. Making the repository remote. Improving space utilization of existing implementation by storing objects in binary format (rather than as XML).

    88. New Default Repository Implementation (Proposed) A new repository implementation is under consideration to improve scalability: Encode objects in binary on disk (rather than XML). This will reduce size by three to one. Combine like objects into a single file rather than separate files (this will reduce internal fragmentation). Provide a fast indexing scheme for keys (disk hashing or B+-Trees). This will improve lookup time.

    90. Status Today Phase 1 almost complete (0.98 today) Phase 1 CIMOM including HTTP Server and CIM-xml Protocol Provider interfaces and dispatch Repository with Instances, Classes, Associations C++ CIM Object Model representation Admin and support functions MOF Compiler Client Interface and test clients Test providers and beginning of some real providers Integrated unit and client server tests (regression) Beta level code quality Needs More testing

    91. CIM Functionality Missing From Phase 1 Events Security WQL and Query

    92. Important Tasks Phase 1 Testing Pegasus Interoperability More Providers for testing and Demos Better Clients Documentation Binary Release

    93. Planned Extensions CIMOM Functions Security Indications Threading Async CIM Operations APIs More Modularity Enhance Service Configuration Expanding Provider Characteristics Out-of-Process Providers WBEM Functions Discovery CIMOM Object Manager Characteristics Provider Registration and Operations Clients Object Browser Protocol Adapters Add protocol Adapters Providers Test Sample Implementations Platforms Easier portability More platforms

    94. Phase 2 Priority tasks Threaded Model Basic Indications Support CIM Object Manager Capabilities Reporting Discovery Demonstration Additional Modularization

    96. Overview of the Project Active project of the Enterprise Management Forum of the Open Group Produce Pegasus open-source Implementation Core, clients, providers, repositories SDKs (Provider and Client) Documentation for use and development Specifications for major Interfaces Continue support and growth of Pegasus Portability New functions New Standards requirements New Providers Tools

    97. Pegasus Status Today Phase 1 of 4+ Phases Version 0.98 Available Source Code available today Preliminary documentation available Multiple users evaluating today Tested on the platforms defined

    98. Pegasus Project Phases Phase 1 (June 2001) Goals Model Validation Client and Provider development Basic Environment Core model Cim-xml Operations Class and instance repositories Providers Phase 2 Goals Production Environment Additions Threading Configuration Security Service Extensions Indications Phase 3 Remote Providers Discovery Other extensions including other Language Interfaces (ex. Java connector)

    99. Participants BMC Software Compaq Computer Focal Point Hermes Softlab Hewlett Packard IBM SIAC The Open Group Research Institute Management Forum Tivoli

    100. Working Together Open Source but coordinated Executive Committee controls strategy Single Architect Work from Proposals Agree to objectives before doing the work Regular, Stable Releases Developers style guides Project scheduling and planning

    101. Additional Activities Providers Clients Growth of functionality with DMTF Discovery Provider standardization (registration, interfaces) Next generation interoperability

    102. Pegasus Manageability Environment

    103. Pegasus and Other Manageability Projects AIC Application and Control AIC as a Pegasus Provider ARM Applications Response Measurement ARM and DMTF DAP Information as Pegasus Provider Other possible Providers JMX (Java) SNMP (mapping already defined) DMI (mapping already defined)

    105. CIMOMs - Basic Concepts Tool to create Management Interoperability Infrastructure for manageability Manageability interoperability Xml-cim today, ??? Tomorrow Instrumentation Interoperability Many providers, few CIMOMs Lots of applications limited numbers of providers

    106. However We do not make money off of infrastructure If we dont have common interfaces we will not have interoperability. CIM is not Easy. Creating complete and Correct CIM environments is not easy There is a lot of work to do with a common environment and much more with many different environments

    107. The Alternatives Creating a common interoperability environment Management Manageability xmp-cim Providers APIs and protocols Provider building Common object implementations The choice Build a common structure with contributions Everybody does their own thing. (Many incompatible and incomplete WBEM Implentations

    108. WBEMsource Consortium Consortium to create common WBEM manageability In fomative stages today About 10 involved organizations today Sun, Compaq,IBM, Tivoli, Open Group, SNIA, Caldera, Novell, Nokia, Intel Open Group Proposing to host Announced at JavaOne 2001

    109. WBEMsource Objectives

    110. The Challenge!!! Can we create a common WBEM infrastructure? OR do we all go our own way?

    111. Where to Get More Information Pegasus is public and Open Source www.opengroup.org/management/pegasus Pegasus WEB Site Source Code Builds on Linux and Windows Snapshots and CVS Binary Release Documentation Pegasus Working Group

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