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Revision: 1.3
Committed: Sun Mar 21 23:58:13 2004 UTC (20 years, 9 months ago) by tdb
Branch: MAIN
Changes since 1.2: +89 -40 lines
Log Message:
Commit new website. The old site is tagged, so this won't change the live
site... but it does move HEAD on to the new site.

Too many changes to list really. General points are:

- Moved to a XHTML CSS compliant site.
- Reorganised the site into a more multi-project based look.
- Removed a lot of cruft.

Still to do:

- Fix all the zillions of bugs stopping the whole site from validating :-)
- Tidy up the HTML in terms of layout and indentation.

Thanks to AJ for his help this weekend in doing this.

File Contents

# Content
1 <!DOCTYPE html PUBLIC "-//W3C//DTD XHTML 1.0 Strict//EN"
2 "http://www.w3.org/TR/xhtml1/DTD/xhtml1-strict.dtd">
3
4 <html>
5
6 <head>
7 <title>CMS Features</title>
8 <!--#include virtual="/style.inc" -->
9 </head>
10
11 <body>
12
13 <div id="container">
14
15 <div id="main">
16
17 <!--#include virtual="/header.inc" -->
18
19 <div id="contents">
20
21 <h1 class="top">CMS Features</h1>
22
23 <h2>Problem Specification</h2>
24
25 <h3>Original Problem</h3>
26
27 <p>
28 This is the original specification given to us when we
29 started the project. The i-scream central monitoring
30 system meets this specification, and aims to extend it
31 further. This is, however, where it all began.
32 </p>
33
34 <h3>Centralised Machine Monitoring</h3>
35
36 <p>
37 The Computer Science department has a number of different machines
38 running a variety of different operating systems. One of the tasks
39 of the systems administrators is to make sure that the machines
40 don't run out of resources. This involves watching processor loads,
41 available disk space, swap space, etc.
42 </p>
43
44 <p>
45 It isn't practicle to monitor a large number of machines by logging
46 on and running commands such as 'uptime' on the unix machines, or
47 by using performance monitor for NT servers. Thus this project is
48 to write monitoring software for each platform supported which
49 reports resource usage back to one centralized location. System
50 Administrators would then be able to monitor all machines from this
51 centralised location.
52 </p>
53
54 <p>
55 Once this basic functionality is implemented it could usefully be
56 expanded to include logging of resource usage to identify longterm
57 trends/problems, alerter services which can directly contact
58 sysadmins (or even the general public) to bring attention to problem
59 areas. Ideally it should be possible to run multiple instances of
60 the reporting tool (with all instances being updated in realtime)
61 and to to be able to run the reporting tool as both as stand alone
62 application and embeded in a web page.
63 </p>
64
65 <p>
66 This project will require you to write code for the unix and Win32
67 APIs using C and knowledge of how the underlying operating systems
68 manage resources. It will also require some network/distributed
69 systems code and a GUI front end for the reporting tool. It is
70 important for students undertaking this project to understand the
71 importance of writing efficient and small code as the end product
72 will really be most useful when machines start run out of processing
73 power/memory/disk.
74 </p>
75
76 <p>
77 John Cinnamond (email jc) whose idea this is, will provide technical
78 support for the project.
79 </p>
80
81 <h2>Features</h2>
82
83 <h3>Key Features of The System</h3>
84
85 <ul>
86 <li>A centrally stored, dynamically reloaded, system wide configuration system</li>
87 <li>A totally extendable monitoring system, nothing except the Host (which
88 generates the data) and the Clients (which view it) know any details about
89 the data being sent, allowing data to be modified without changes to the
90 server architecture.</li>
91 <li>Central server and reporting tools all Java based for multi-platform portability</li>
92 <li>Distribution of core server components over CORBA to allow appropriate components
93 to run independently and to allow new components to be written to conform with the
94 CORBA interfaces.</li>
95 <li>Use of CORBA to create a hierarchical set of data entry points to the system
96 allowing the system to handle event storms and remote office locations.</li>
97 <li>One location for all system messages, despite being distributed.</li>
98 <li>XML data protocol used to make data processing and analysing easily extendable</li>
99 <li>A stateless server which can be moved and restarted at will, while Hosts,
100 Clients, and reporting tools are unaffected and simply reconnect when the
101 server is available again.</li>
102 <li>Simple and open end protocols to allow easy extension and platform porting of Hosts
103 and Clients.</li>
104 <li>Self monitoring, as all data queues within the system can be monitored and raise
105 alerts to warn of event storms and impending failures (should any occur).</li>
106 <li>A variety of web based information displays based on Java/SQL reporting and
107 PHP on-the-fly page generation to show the latest alerts and data</li>
108 <li>Large overhead monitor Helpdesk style displays for latest Alerting information</li>
109 </ul>
110
111 <h3>An Overview of the i-scream Central Monitoring System</h3>
112
113 <p>
114 The i-scream system monitors status and performance information
115 obtained from machines feeding data into it and then displays
116 this information in a variety of ways.
117 </p>
118
119 <p>
120 This data is obtained through the running of small applications
121 on the reporting machines. These applications are known as
122 "Hosts". The i-scream system provides a range of hosts which are
123 designed to be small and lightweight in their configuration and
124 operation. See the website and appropriate documentation to
125 locate currently available Host applications. These hosts are
126 simply told where to contact the server at which point they are
127 totally autonomous. They are able to obtain configuration from
128 the server, detect changes in their configuration, send data
129 packets (via UDP) containing monitoring information, and send
130 so called "Heartbeat" packets (via TCP) periodically to indicate
131 to the server that they are still alive.
132 </p>
133
134 <p>
135 It is then fed into the i-scream server. The server then splits
136 the data two ways. First it places the data in a database system,
137 typically MySQL based, for later extraction and processing by the
138 i-scream report generation tools. It then passes it onto to
139 real-time "Clients" which handle the data as it enters the system.
140 The system itself has an internal real-time client called the "Local
141 Client" which has a series of Monitors running which can analyse the
142 data. One of these Monitors also feeds the data off to a file
143 repository, which is updated as new data comes in for each machine,
144 this data is then read and displayed by the i-scream web services
145 to provide a web interface to the data. The system also allows TCP
146 connections by non-local clients (such as the i-scream supplied
147 Conient), these applications provide a real-time view of the data
148 as it flows through the system.
149 </p>
150
151 <p>
152 The final section of the system links the Local Client Monitors to
153 an alerting system. These Monitors can be configured to detect
154 changes in the data past threshold levels. When a threshold is
155 breached an alert is raised. This alert is then escalated as the
156 alert persists through four live levels, NOTICE, WARNING, CAUTION
157 and CRITICAL. The alerting system keeps an eye on the level and
158 when a certain level is reached, certain alerting mechanisms fire
159 through whatever medium they are configured to send.
160 </p>
161 </div>
162
163 <!--#include virtual="/footer.inc" -->
164
165 </div>
166
167 <!--#include virtual="/menu.inc" -->
168
169 </div>
170
171 </body>
172 </html>