--- web/www/cms/features.xhtml 2004/03/21 23:58:13 1.3 +++ web/www/cms/features.xhtml 2004/03/23 23:43:26 1.5 @@ -1,172 +1,187 @@ - - - - - -CMS Features + + + + CMS Features + - - - - -
- -
- + + +
+
- -
- -

CMS Features

- -

Problem Specification

- -

Original Problem

- -

- This is the original specification given to us when we - started the project. The i-scream central monitoring - system meets this specification, and aims to extend it - further. This is, however, where it all began. -

- -

Centralised Machine Monitoring

- -

- The Computer Science department has a number of different machines - running a variety of different operating systems. One of the tasks - of the systems administrators is to make sure that the machines - don't run out of resources. This involves watching processor loads, - available disk space, swap space, etc. -

- -

- It isn't practicle to monitor a large number of machines by logging - on and running commands such as 'uptime' on the unix machines, or - by using performance monitor for NT servers. Thus this project is - to write monitoring software for each platform supported which - reports resource usage back to one centralized location. System - Administrators would then be able to monitor all machines from this - centralised location. -

- -

- Once this basic functionality is implemented it could usefully be - expanded to include logging of resource usage to identify longterm - trends/problems, alerter services which can directly contact - sysadmins (or even the general public) to bring attention to problem - areas. Ideally it should be possible to run multiple instances of - the reporting tool (with all instances being updated in realtime) - and to to be able to run the reporting tool as both as stand alone - application and embeded in a web page. -

- -

- This project will require you to write code for the unix and Win32 - APIs using C and knowledge of how the underlying operating systems - manage resources. It will also require some network/distributed - systems code and a GUI front end for the reporting tool. It is - important for students undertaking this project to understand the - importance of writing efficient and small code as the end product - will really be most useful when machines start run out of processing - power/memory/disk. -

- -

- John Cinnamond (email jc) whose idea this is, will provide technical - support for the project. -

- -

Features

- -

Key Features of The System

- -
    -
  • A centrally stored, dynamically reloaded, system wide configuration system
  • -
  • A totally extendable monitoring system, nothing except the Host (which - generates the data) and the Clients (which view it) know any details about - the data being sent, allowing data to be modified without changes to the - server architecture.
  • -
  • Central server and reporting tools all Java based for multi-platform portability
  • -
  • Distribution of core server components over CORBA to allow appropriate components - to run independently and to allow new components to be written to conform with the - CORBA interfaces.
  • -
  • Use of CORBA to create a hierarchical set of data entry points to the system - allowing the system to handle event storms and remote office locations.
  • -
  • One location for all system messages, despite being distributed.
  • -
  • XML data protocol used to make data processing and analysing easily extendable
  • -
  • A stateless server which can be moved and restarted at will, while Hosts, - Clients, and reporting tools are unaffected and simply reconnect when the - server is available again.
  • -
  • Simple and open end protocols to allow easy extension and platform porting of Hosts - and Clients.
  • -
  • Self monitoring, as all data queues within the system can be monitored and raise - alerts to warn of event storms and impending failures (should any occur).
  • -
  • A variety of web based information displays based on Java/SQL reporting and - PHP on-the-fly page generation to show the latest alerts and data
  • -
  • Large overhead monitor Helpdesk style displays for latest Alerting information
  • -
- -

An Overview of the i-scream Central Monitoring System

- -

- The i-scream system monitors status and performance information - obtained from machines feeding data into it and then displays - this information in a variety of ways. -

- -

- This data is obtained through the running of small applications - on the reporting machines. These applications are known as - "Hosts". The i-scream system provides a range of hosts which are - designed to be small and lightweight in their configuration and - operation. See the website and appropriate documentation to - locate currently available Host applications. These hosts are - simply told where to contact the server at which point they are - totally autonomous. They are able to obtain configuration from - the server, detect changes in their configuration, send data - packets (via UDP) containing monitoring information, and send - so called "Heartbeat" packets (via TCP) periodically to indicate - to the server that they are still alive. -

- -

- It is then fed into the i-scream server. The server then splits - the data two ways. First it places the data in a database system, - typically MySQL based, for later extraction and processing by the - i-scream report generation tools. It then passes it onto to - real-time "Clients" which handle the data as it enters the system. - The system itself has an internal real-time client called the "Local - Client" which has a series of Monitors running which can analyse the - data. One of these Monitors also feeds the data off to a file - repository, which is updated as new data comes in for each machine, - this data is then read and displayed by the i-scream web services - to provide a web interface to the data. The system also allows TCP - connections by non-local clients (such as the i-scream supplied - Conient), these applications provide a real-time view of the data - as it flows through the system. -

- -

- The final section of the system links the Local Client Monitors to - an alerting system. These Monitors can be configured to detect - changes in the data past threshold levels. When a threshold is - breached an alert is raised. This alert is then escalated as the - alert persists through four live levels, NOTICE, WARNING, CAUTION - and CRITICAL. The alerting system keeps an eye on the level and - when a certain level is reached, certain alerting mechanisms fire - through whatever medium they are configured to send. -

-
- +
+

+ CMS Features +

+

+ Problem Specification +

+

+ Original Problem +

+

+ This is the original specification given to us when we + started the project. The i-scream central monitoring system + meets this specification, and aims to extend it further. + This is, however, where it all began. +

+

+ Centralised Machine Monitoring +

+

+ The Computer Science department has a number of different + machines running a variety of different operating systems. + One of the tasks of the systems administrators is to make + sure that the machines don't run out of resources. This + involves watching processor loads, available disk space, + swap space, etc. +

+

+ It isn't practicle to monitor a large number of machines by + logging on and running commands such as 'uptime' on the + unix machines, or by using performance monitor for NT + servers. Thus this project is to write monitoring software + for each platform supported which reports resource usage + back to one centralized location. System Administrators + would then be able to monitor all machines from this + centralised location. +

+

+ Once this basic functionality is implemented it could + usefully be expanded to include logging of resource usage + to identify longterm trends/problems, alerter services + which can directly contact sysadmins (or even the general + public) to bring attention to problem areas. Ideally it + should be possible to run multiple instances of the + reporting tool (with all instances being updated in + realtime) and to to be able to run the reporting tool as + both as stand alone application and embeded in a web page. +

+

+ This project will require you to write code for the unix + and Win32 APIs using C and knowledge of how the underlying + operating systems manage resources. It will also require + some network/distributed systems code and a GUI front end + for the reporting tool. It is important for students + undertaking this project to understand the importance of + writing efficient and small code as the end product will + really be most useful when machines start run out of + processing power/memory/disk. +

+

+ John Cinnamond (email jc) whose idea this is, will provide + technical support for the project. +

+

+ Features +

+

+ Key Features of The System +

+
    +
  • A centrally stored, dynamically reloaded, system wide + configuration system +
  • +
  • A totally extendable monitoring system, nothing except + the Host (which generates the data) and the Clients (which + view it) know any details about the data being sent, + allowing data to be modified without changes to the server + architecture. +
  • +
  • Central server and reporting tools all Java based for + multi-platform portability +
  • +
  • Distribution of core server components over CORBA to + allow appropriate components to run independently and to + allow new components to be written to conform with the + CORBA interfaces. +
  • +
  • Use of CORBA to create a hierarchical set of data entry + points to the system allowing the system to handle event + storms and remote office locations. +
  • +
  • One location for all system messages, despite being + distributed. +
  • +
  • XML data protocol used to make data processing and + analysing easily extendable +
  • +
  • A stateless server which can be moved and restarted at + will, while Hosts, Clients, and reporting tools are + unaffected and simply reconnect when the server is + available again. +
  • +
  • Simple and open end protocols to allow easy extension + and platform porting of Hosts and Clients. +
  • +
  • Self monitoring, as all data queues within the system + can be monitored and raise alerts to warn of event storms + and impending failures (should any occur). +
  • +
  • A variety of web based information displays based on + Java/SQL reporting and PHP on-the-fly page generation to + show the latest alerts and data +
  • +
  • Large overhead monitor Helpdesk style displays for + latest Alerting information +
  • +
+

+ An Overview of the i-scream Central Monitoring System +

+

+ The i-scream system monitors status and performance + information obtained from machines feeding data into it and + then displays this information in a variety of ways. +

+

+ This data is obtained through the running of small + applications on the reporting machines. These applications + are known as "Hosts". The i-scream system provides a range + of hosts which are designed to be small and lightweight in + their configuration and operation. See the website and + appropriate documentation to locate currently available + Host applications. These hosts are simply told where to + contact the server at which point they are totally + autonomous. They are able to obtain configuration from the + server, detect changes in their configuration, send data + packets (via UDP) containing monitoring information, and + send so called "Heartbeat" packets (via TCP) periodically + to indicate to the server that they are still alive. +

+

+ It is then fed into the i-scream server. The server then + splits the data two ways. First it places the data in a + database system, typically MySQL based, for later + extraction and processing by the i-scream report generation + tools. It then passes it onto to real-time "Clients" which + handle the data as it enters the system. The system itself + has an internal real-time client called the "Local Client" + which has a series of Monitors running which can analyse + the data. One of these Monitors also feeds the data off to + a file repository, which is updated as new data comes in + for each machine, this data is then read and displayed by + the i-scream web services to provide a web interface to the + data. The system also allows TCP connections by non-local + clients (such as the i-scream supplied Conient), these + applications provide a real-time view of the data as it + flows through the system. +

+

+ The final section of the system links the Local Client + Monitors to an alerting system. These Monitors can be + configured to detect changes in the data past threshold + levels. When a threshold is breached an alert is raised. + This alert is then escalated as the alert persists through + four live levels, NOTICE, WARNING, CAUTION and CRITICAL. + The alerting system keeps an eye on the level and when a + certain level is reached, certain alerting mechanisms fire + through whatever medium they are configured to send. +

+
- -
- +
- -
- - +
+