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diff --git a/docs-xml/Samba3-ByExample/SBE-Appendix2.xml b/docs-xml/Samba3-ByExample/SBE-Appendix2.xml deleted file mode 100644 index dd8ca0398d1..00000000000 --- a/docs-xml/Samba3-ByExample/SBE-Appendix2.xml +++ /dev/null @@ -1,1283 +0,0 @@ -<?xml version="1.0" encoding="iso-8859-1"?> -<!DOCTYPE chapter PUBLIC "-//Samba-Team//DTD DocBook V4.2-Based Variant V1.0//EN" "http://www.samba.org/samba/DTD/samba-doc"> -<chapter id="primer"> - <title>Networking Primer</title> - - <para> - You are about to use the equivalent of a microscope to look at the information - that runs through the veins of a Windows network. We do more to observe the information than - to interrogate it. When you are done with this primer, you should have a good understanding - of the types of information that flow over the network. Do not worry, this is not - a biology lesson. We won't lose you in unnecessary detail. Think to yourself, <quote>This - is easy,</quote> then tackle each exercise without fear. - </para> - - <para> - Samba can be configured with a minimum of complexity. Simplicity should be mastered - before you get too deeply into complexities. Let's get moving: we have work to do. - </para> - -<sect1> - <title>Requirements and Notes</title> - <para> - Successful completion of this primer requires two Microsoft Windows 9x/Me Workstations - as well as two Microsoft Windows XP Professional Workstations, each equipped with an Ethernet - card connected using a hub. Also required is one additional server (either Windows - NT4 Server, Windows 2000 Server, or a Samba on UNIX/Linux server) running a network - sniffer and analysis application (Wireshark is a good choice). All work should be undertaken - on a quiet network where there is no other traffic. It is best to use a dedicated hub - with only the machines under test connected at the time of the exercises. - </para> - - <para><indexterm> - <primary>Wireshark</primary> - </indexterm> - Wireshark (formerly Ethereal) has become the network protocol analyzer of choice for many network administrators. - You may find more information regarding this tool from the - <ulink url="http://www.wireshark.org">Wireshark</ulink> Web site. Wireshark installation - files for Windows may be obtained from the Wireshark Web site. Wireshark is provided with - SUSE and Red Hat Linux distributions, as well as with many other Linux distributions. It may - not be installed on your system by default. If it is not installed, you may also need - to install the <command>libpcap</command> software before you can install or use Wireshark. - Please refer to the instructions for your operating system or to the Wireshark Web site - for information regarding the installation and operation of Wireshark. - </para> - - <para> - To obtain <command>Wireshark</command> for your system, please visit the Wireshark - <ulink url="http://www.wireshark.org/download.html">download site</ulink>. - </para> - - <note><para> - The successful completion of this chapter requires that you capture network traffic - using <command>Wireshark</command>. It is recommended that you use a hub, not an - Ethernet switch. It is necessary for the device used to act as a repeater, not as a - filter. Ethernet switches may filter out traffic that is not directed at the machine - that is used to monitor traffic; this would not allow you to complete the projects. - </para></note> - - <para> - <indexterm><primary>network</primary><secondary>captures</secondary></indexterm> - Do not worry too much if you do not have access to all this equipment; network captures - from the exercises are provided on the enclosed CD-ROM. This makes it possible to dive directly - into the analytical part of the exercises if you so desire. - </para> - - <para><indexterm> - <primary>network</primary> - <secondary>sniffer</secondary> - </indexterm><indexterm> - <primary>protocol analysis</primary> - </indexterm> - Please do not be alarmed at the use of a high-powered analysis tool (Wireshark) in this - primer. We expose you only to a minimum of detail necessary to complete - the exercises. If you choose to use any other network sniffer and protocol - analysis tool, be advised that it may not allow you to examine the contents of - recently added security protocols used by Windows 200x/XP. - </para> - - <para> - You could just skim through the exercises and try to absorb the key points made. - The exercises provide all the information necessary to convince the die-hard network - engineer. You possibly do not require so much convincing and may just want to move on, - in which case you should at least read <link linkend="chap01conc"/>. - </para> - - <para> - <link linkend="chap01qa"/> also provides useful information - that may help you to avoid significantly time-consuming networking problems. - </para> -</sect1> - -<sect1> - <title>Introduction</title> - - <para> - The purpose of this chapter is to create familiarity with key aspects of Microsoft Windows - network computing. If you want a solid technical grounding, do not gloss over these exercises. - The points covered are recurrent issues on the Samba mailing lists. - </para> - - <para><indexterm> - <primary>network</primary> - <secondary>broadcast</secondary> - </indexterm> - You can see from these exercises that Windows networking involves quite a lot of network - broadcast traffic. You can look into the contents of some packets, but only to see - some particular information that the Windows client sends to a server in the course of - establishing a network connection. - </para> - - <para> - To many people, browsing is everything that happens when one uses Microsoft Internet Explorer. - It is only when you start looking at network traffic and noting the protocols - and types of information that are used that you can begin to appreciate the complexities of - Windows networking and, more importantly, what needs to be configured so that it can work. - Detailed information regarding browsing is provided in the recommended - preparatory reading. - </para> - - <para> - Recommended preparatory reading: <emphasis>The Official Samba HOWTO and Reference Guide, Second - Edition</emphasis> (TOSHARG2) Chapter 9, <quote>Network Browsing,</quote> and Chapter 3, - <quote>Server Types and Security Modes.</quote> - </para> - - <sect2> - <title>Assignment Tasks</title> - - <para><indexterm> - <primary>browsing</primary> - </indexterm> - You are about to witness how Microsoft Windows computer networking functions. The - exercises step through identification of how a client machine establishes a - connection to a remote Windows server. You observe how Windows machines find - each other (i.e., how browsing works) and how the two key types of user identification - (share mode security and user mode security) are affected. - </para> - - <para><indexterm> - <primary>network</primary> - <secondary>analyzer</secondary> - </indexterm> - The networking protocols used by MS Windows networking when working with Samba - use TCP/IP as the transport protocol. The protocols that are specific to Windows - networking are encapsulated in TCP/IP. The network analyzer we use (Wireshark) - is able to show you the contents of the TCP/IP packets (or messages). - </para> - - <procedure id="chap01tasks"> - <title>Diagnostic Tasks</title> - - <step><para><indexterm> - <primary>network</primary> - <secondary>trace</secondary> - </indexterm><indexterm> - <primary>host announcement</primary> - </indexterm><indexterm> - <primary>name resolution</primary> - </indexterm> - Examine network traces to witness SMB broadcasts, host announcements, - and name resolution processes. - </para></step> - - <step><para> - Examine network traces to witness how share mode security functions. - </para></step> - - <step><para> - Examine network traces to witness the use of user mode security. - </para></step> - - <step><para> - Review traces of network logons for a Windows 9x/Me client as well as - a domain logon for a Windows XP Professional client. - </para></step> - </procedure> - - </sect2> -</sect1> - -<sect1> - <title>Exercises</title> - - <para> - <indexterm><primary>wireshark</primary></indexterm> - You are embarking on a course of discovery. The first part of the exercise requires - two MS Windows 9x/Me systems. We called one machine <constant>WINEPRESSME</constant> and the - other <constant>MILGATE98</constant>. Each needs an IP address; we used <literal>10.1.1.10</literal> - and <literal>10.1.1.11</literal>. The test machines need to be networked via a <emphasis>hub</emphasis>. A UNIX/Linux - machine is required to run <command>Wireshark</command> to enable the network activity to be captured. - It is important that the machine from which network activity is captured must not interfere with - the operation of the Windows workstations. It is helpful for this machine to be passive (does not - send broadcast information) to the network. - </para> - - <para> - For these exercises, our test environment consisted of a SUSE 9.2 Professional Linux Workstation running - VMWare 4.5. The following VMWare images were prepared: - </para> - - <itemizedlist> - <listitem><para>Windows 98 &smbmdash; name: MILGATE98</para></listitem> - <listitem><para>Windows Me &smbmdash; name: WINEPRESSME</para></listitem> - <listitem><para>Windows XP Professional &smbmdash; name: LightrayXP</para></listitem> - <listitem><para>Samba-3.0.20 running on a SUSE Enterprise Linux 9</para></listitem> - </itemizedlist> - - <para> - Choose a workgroup name (MIDEARTH) for each exercise. - </para> - - <para> - <indexterm><primary>ethereal</primary></indexterm> - The network captures provided on the CD-ROM included with this book were captured using <constant>Ethereal</constant> - version <literal>0.10.6</literal>. A later version suffices without problems (i.e. you should be using Wireshark), but an earlier version may not - expose all the information needed. Each capture file has been decoded and listed as a trace file. A summary of all - packets has also been included. This makes it possible for you to do all the studying you like without the need to - perform the time-consuming equipment configuration and test work. This is a good time to point out that the value - that can be derived from this book really does warrant your taking sufficient time to practice each exercise with - care and attention to detail. - </para> - - <sect2> - <title>Single-Machine Broadcast Activity</title> - - <para> - In this section, we start a single Windows 9x/Me machine, then monitor network activity for 30 minutes. - </para> - - <procedure> - <title>Monitoring Windows 9x Steps</title> - - <step><para> - Start the machine from which network activity will be monitored (using <command>Wireshark</command>). - Launch <command>Wireshark</command>, click - <menuchoice> - <guimenu>Capture</guimenu> - <guimenuitem>Start</guimenuitem> - </menuchoice>. - </para> - - <para> - Click the following: - <orderedlist> - <listitem><para>Update list of packets in real time</para></listitem> - <listitem><para>Automatic scrolling in live capture</para></listitem> - <listitem><para>Enable MAC name resolution</para></listitem> - <listitem><para>Enable network name resolution</para></listitem> - <listitem><para>Enable transport name resolution</para></listitem> - </orderedlist> - Click <guibutton>OK</guibutton>. - </para></step> - - <step><para> - Start the Windows 9x/Me machine to be monitored. Let it run for a full 30 minutes. While monitoring, - do not press any keyboard keys, do not click any on-screen icons or menus, and do not answer any dialog boxes. - </para></step> - - <step><para> - At the conclusion of 30 minutes, stop the capture. Save the capture to a file so you can go back to it later. - Leave this machine running in preparation for the task in <link linkend="secondmachine"/>. - </para></step> - - <step><para> - Analyze the capture. Identify each discrete message type that was captured. Note what transport protocol - was used. Identify the timing between messages of identical types. - </para></step> - - </procedure> - - <sect3> - <title>Findings</title> - - <para> - The summary of the first 10 minutes of the packet capture should look like <link linkend="pktcap01"/>. - A screenshot of a later stage of the same capture is shown in <link linkend="pktcap02"/>. - </para> - - <figure id="pktcap01"> - <title>Windows Me &smbmdash; Broadcasts &smbmdash; The First 10 Minutes</title> - <imagefile scale="40">WINREPRESSME-Capture</imagefile> - </figure> - - <figure id="pktcap02"> - <title>Windows Me &smbmdash; Later Broadcast Sample</title> - <imagefile scale="42">WINREPRESSME-Capture2</imagefile> - </figure> - - <para><indexterm> - <primary>Local Master Browser</primary> - <see>LMB</see> - </indexterm><indexterm> - <primary>LMB</primary> - </indexterm> - Broadcast messages observed are shown in <link linkend="capsstats01"/>. - Actual observations vary a little, but not by much. - Early in the startup process, the Windows Me machine broadcasts its name for two reasons: - first to ensure that its name would not result in a name clash, and second to establish its - presence with the Local Master Browser (LMB). - </para> - - <table id="capsstats01"> - <title>Windows Me &smbmdash; Startup Broadcast Capture Statistics</title> - <tgroup cols="4"> - <colspec align="left" colwidth="3*"/> - <colspec align="center"/> - <colspec align="center"/> - <colspec align="left" colwidth="3*"/> - <thead> - <row> - <entry>Message</entry> - <entry>Type</entry> - <entry>Num</entry> - <entry>Notes</entry> - </row> - </thead> - <tbody> - <row> - <entry>WINEPRESSME<00></entry> - <entry>Reg</entry> - <entry>8</entry> - <entry>4 lots of 2, 0.6 sec apart</entry> - </row> - <row> - <entry>WINEPRESSME<03></entry> - <entry>Reg</entry> - <entry>8</entry> - <entry>4 lots of 2, 0.6 sec apart</entry> - </row> - <row> - <entry>WINEPRESSME<20></entry> - <entry>Reg</entry> - <entry>8</entry> - <entry>4 lots of 2, 0.75 sec apart</entry> - </row> - <row> - <entry>MIDEARTH<00></entry> - <entry>Reg</entry> - <entry>8</entry> - <entry>4 lots of 2, 0.75 sec apart</entry> - </row> - <row> - <entry>MIDEARTH<1d></entry> - <entry>Reg</entry> - <entry>8</entry> - <entry>4 lots of 2, 0.75 sec apart</entry> - </row> - <row> - <entry>MIDEARTH<1e></entry> - <entry>Reg</entry> - <entry>8</entry> - <entry>4 lots of 2, 0.75 sec apart</entry> - </row> - <row> - <entry>MIDEARTH<1b></entry> - <entry>Qry</entry> - <entry>84</entry> - <entry>300 sec apart at stable operation</entry> - </row> - <row> - <entry>__MSBROWSE__</entry> - <entry>Reg</entry> - <entry>8</entry> - <entry>Registered after winning election to Browse Master</entry> - </row> - <row> - <entry>JHT<03></entry> - <entry>Reg</entry> - <entry>8</entry> - <entry>4 x 2. This is the name of the user that logged onto Windows</entry> - </row> - <row> - <entry>Host Announcement WINEPRESSME</entry> - <entry>Ann</entry> - <entry>2</entry> - <entry>Observed at 10 sec</entry> - </row> - <row> - <entry>Domain/Workgroup Announcement MIDEARTH</entry> - <entry>Ann</entry> - <entry>18</entry> - <entry>300 sec apart at stable operation</entry> - </row> - <row> - <entry>Local Master Announcement WINEPRESSME</entry> - <entry>Ann</entry> - <entry>18</entry> - <entry>300 sec apart at stable operation</entry> - </row> - <row> - <entry>Get Backup List Request</entry> - <entry>Qry</entry> - <entry>12</entry> - <entry>6 x 2 early in startup, 0.5 sec apart</entry> - </row> - <row> - <entry>Browser Election Request</entry> - <entry>Ann</entry> - <entry>10</entry> - <entry>5 x 2 early in startup</entry> - </row> - <row> - <entry>Request Announcement WINEPRESSME</entry> - <entry>Ann</entry> - <entry>4</entry> - <entry>Early in startup</entry> - </row> - </tbody> - </tgroup> - </table> - - <para><indexterm> - <primary>election</primary> - </indexterm><indexterm> - <primary>browse master</primary> - </indexterm> - From the packet trace, it should be noted that no messages were propagated over TCP/IP; - all messages employed UDP/IP. When steady-state operation has been achieved, there is a cycle - of various announcements, re-election of a browse master, and name queries. These create - the symphony of announcements by which network browsing is made possible. - </para> - - <para><indexterm> - <primary>CIFS</primary> - </indexterm> - For detailed information regarding the precise behavior of the CIFS/SMB protocols, - refer to the book <quote>Implementing CIFS: The Common Internet File System,</quote> - by Christopher Hertel, (Prentice Hall PTR, ISBN: 013047116X). - </para> - - </sect3> - - </sect2> - - <sect2 id="secondmachine"> - <title>Second Machine Startup Broadcast Interaction</title> - - <para> - At this time, the machine you used to capture the single-system startup trace should still be running. - The objective of this task is to identify the interaction of two machines in respect to broadcast activity. - </para> - - <procedure> - <title>Monitoring of Second Machine Activity</title> - - <step><para> - On the machine from which network activity will be monitored (using <command>Wireshark</command>), - launch <command>Wireshark</command> and click - <menuchoice> - <guimenu>Capture</guimenu> - <guimenuitem>Start</guimenuitem> - </menuchoice>. - </para> - - <para> - Click: - <orderedlist> - <listitem><para>Update list of packets in real time</para></listitem> - <listitem><para>Automatic scrolling in live capture</para></listitem> - <listitem><para>Enable MAC name resolution</para></listitem> - <listitem><para>Enable network name resolution</para></listitem> - <listitem><para>Enable transport name resolution</para></listitem> - </orderedlist> - Click <guibutton>OK</guibutton>. - </para></step> - - <step><para> - Start the second Windows 9x/Me machine. Let it run for 15 to 20 minutes. While monitoring, do not press - any keyboard keys, do not click any on-screen icons or menus, and do not answer any dialog boxes. - </para></step> - - <step><para> - At the conclusion of the capture time, stop the capture. Be sure to save the captured data so you - can examine the network data capture again at a later date should that be necessary. - </para></step> - - <step><para> - Analyze the capture trace, taking note of the transport protocols used, the types of messages observed, - and what interaction took place between the two machines. Leave both machines running for the next task. - </para></step> - </procedure> - - <sect3> - <title>Findings</title> - - <para> - <link linkend="capsstats02"/> summarizes capture statistics observed. As in the previous case, - all announcements used UDP/IP broadcasts. Also, as was observed with the last example, the second - Windows 9x/Me machine broadcasts its name on startup to ensure that there exists no name clash - (i.e., the name is already registered by another machine) on the network segment. Those wishing - to explore the inner details of the precise mechanism of how this functions should refer to - <quote>Implementing CIFS: The Common Internet File System.</quote> - </para> - - <table id="capsstats02"> - <title>Second Machine (Windows 98) &smbmdash; Capture Statistics</title> - <tgroup cols="4"> - <colspec align="left" colwidth="3*"/> - <colspec align="center"/> - <colspec align="center"/> - <colspec align="left" colwidth="3*"/> - <thead> - <row> - <entry>Message</entry> - <entry>Type</entry> - <entry>Num</entry> - <entry>Notes</entry> - </row> - </thead> - <tbody> - <row> - <entry>MILGATE98<00></entry> - <entry>Reg</entry> - <entry>8</entry> - <entry>4 lots of 2, 0.6 sec apart</entry> - </row> - <row> - <entry>MILGATE98<03></entry> - <entry>Reg</entry> - <entry>8</entry> - <entry>4 lots of 2, 0.6 sec apart</entry> - </row> - <row> - <entry>MILGATE98<20></entry> - <entry>Reg</entry> - <entry>8</entry> - <entry>4 lots of 2, 0.75 sec apart</entry> - </row> - <row> - <entry>MIDEARTH<00></entry> - <entry>Reg</entry> - <entry>8</entry> - <entry>4 lots of 2, 0.75 sec apart</entry> - </row> - <row> - <entry>MIDEARTH<1d></entry> - <entry>Reg</entry> - <entry>8</entry> - <entry>4 lots of 2, 0.75 sec apart</entry> - </row> - <row> - <entry>MIDEARTH<1e></entry> - <entry>Reg</entry> - <entry>8</entry> - <entry>4 lots of 2, 0.75 sec apart</entry> - </row> - <row> - <entry>MIDEARTH<1b></entry> - <entry>Qry</entry> - <entry>18</entry> - <entry>900 sec apart at stable operation</entry> - </row> - <row> - <entry>JHT<03></entry> - <entry>Reg</entry> - <entry>2</entry> - <entry>This is the name of the user that logged onto Windows</entry> - </row> - <row> - <entry>Host Announcement MILGATE98</entry> - <entry>Ann</entry> - <entry>14</entry> - <entry>Every 120 sec</entry> - </row> - <row> - <entry>Domain/Workgroup Announcement MIDEARTH</entry> - <entry>Ann</entry> - <entry>6</entry> - <entry>900 sec apart at stable operation</entry> - </row> - <row> - <entry>Local Master Announcement WINEPRESSME</entry> - <entry>Ann</entry> - <entry>6</entry> - <entry>Insufficient detail to determine frequency</entry> - </row> - </tbody> - </tgroup> - </table> - - <para> - <indexterm><primary>host announcement</primary></indexterm> - <indexterm><primary>Local Master Announcement</primary></indexterm> - <indexterm><primary>Workgroup Announcement</primary></indexterm> - Observation of the contents of Host Announcements, Domain/Workgroup Announcements, - and Local Master Announcements is instructive. These messages convey a significant - level of detail regarding the nature of each machine that is on the network. An example - dissection of a Host Announcement is given in <link linkend="hostannounce"/>. - </para> - - - <figure id="hostannounce"> - <title>Typical Windows 9x/Me Host Announcement</title> - <imagefile scale="41">HostAnnouncment</imagefile> - </figure> - </sect3> - - </sect2> - - <sect2> - <title>Simple Windows Client Connection Characteristics</title> - - <para> - The purpose of this exercise is to discover how Microsoft Windows clients create (establish) - connections with remote servers. The methodology involves analysis of a key aspect of how - Windows clients access remote servers: the session setup protocol. - </para> - - <procedure> - <title>Client Connection Exploration Steps</title> - - <step><para> - Configure a Windows 9x/Me machine (MILGATE98) with a share called <constant>Stuff</constant>. - Create a <parameter>Full Access</parameter> control password on this share. - </para></step> - - <step><para> - Configure another Windows 9x/Me machine (WINEPRESSME) as a client. Make sure that it exports - no shared resources. - </para></step> - - <step><para> - Start both Windows 9x/Me machines and allow them to stabilize for 10 minutes. Log on to both - machines using a user name (JHT) of your choice. Wait approximately 2 minutes before proceeding. - </para></step> - - <step><para> - Start Wireshark (or the network sniffer of your choice). - </para></step> - - <step><para> - From the WINEPRESSME machine, right-click <guimenu>Network Neighborhood</guimenu>, select - <guimenuitem>Explore</guimenuitem>, select - <menuchoice> - <guimenuitem>My Network Places</guimenuitem> - <guimenuitem>Entire Network</guimenuitem> - <guimenuitem>MIDEARTH</guimenuitem> - <guimenuitem>MILGATE98</guimenuitem> - <guimenuitem>Stuff</guimenuitem> - </menuchoice>. - Enter the password you set for the <constant>Full Control</constant> mode for the - <constant>Stuff</constant> share. - </para></step> - - <step><para> - When the share called <constant>Stuff</constant> is being displayed, stop the capture. - Save the captured data in case it is needed for later analysis. - </para></step> - - <step><para> - <indexterm><primary>session setup</primary></indexterm> - From the top of the packets captured, scan down to locate the first packet that has - interpreted as <constant>Session Setup AndX, User: anonymous; Tree Connect AndX, - Path: \\MILGATE98\IPC$</constant>. - </para></step> - - <step><para><indexterm> - <primary>Session Setup</primary> - </indexterm><indexterm> - <primary>Tree Connect</primary> - </indexterm> - In the dissection (analysis) panel, expand the <constant>SMB, Session Setup AndX Request, - and Tree Connect AndX Request</constant>. Examine both operations. Identify the name of - the user Account and what password was used. The Account name should be empty. - This is a <constant>NULL</constant> session setup packet. - </para></step> - - <step><para> - Return to the packet capture sequence. There will be a number of packets that have been - decoded of the type <constant>Session Setup AndX</constant>. Locate the last such packet - that was targeted at the <constant>\\MILGATE98\IPC$</constant> service. - </para></step> - - <step><para> - <indexterm><primary>password length</primary></indexterm> - <indexterm><primary>User Mode</primary></indexterm> - Dissect this packet as per the previous one. This packet should have a password length - of 24 (characters) and should have a password field, the contents of which is a - long hexadecimal number. Observe the name in the Account field. This is a User Mode - session setup packet. - </para></step> - </procedure> - - <sect3> - <title>Findings and Comments</title> - - <para> - <indexterm><primary>IPC$</primary></indexterm> - The <constant>IPC$</constant> share serves a vital purpose<footnote><para>TOSHARG2, Sect 4.5.1</para></footnote> - in SMB/CIFS-based networking. A Windows client connects to this resource to obtain the list of - resources that are available on the server. The server responds with the shares and print queues that - are available. In most but not all cases, the connection is made with a <constant>NULL</constant> - username and a <constant>NULL</constant> password. - </para> - - <para> - <indexterm><primary>account credentials</primary></indexterm> - The two packets examined are material evidence of how Windows clients may - interoperate with Samba. Samba requires every connection setup to be authenticated using - valid UNIX account credentials (UID/GID). This means that even a <constant>NULL</constant> - session setup can be established only by automatically mapping it to a valid UNIX - account. - </para> - - <para> - <indexterm><primary>NULL session</primary></indexterm><indexterm> - <primary>guest account</primary> - </indexterm> - <indexterm><primary>nobody</primary></indexterm> - Samba has a special name for the <constant>NULL</constant>, or empty, user account: - it calls it the <smbconfoption name="guest account"/>. The - default value of this parameter is <constant>nobody</constant>; however, this can be - changed to map the function of the guest account to any other UNIX identity. Some - UNIX administrators prefer to map this account to the system default anonymous - FTP account. A sample NULL Session Setup AndX packet dissection is shown in - <link linkend="nullconnect"/>. - </para> - - <figure id="nullconnect"> - <title>Typical Windows 9x/Me NULL SessionSetUp AndX Request</title> - - <imagefile scale="41">NullConnect</imagefile> - </figure> - - <para> - <indexterm><primary>nobody</primary></indexterm> - <indexterm><primary>/etc/passwd</primary></indexterm> - <indexterm><primary>guest account</primary></indexterm> - When a UNIX/Linux system does not have a <constant>nobody</constant> user account - (<filename>/etc/passwd</filename>), the operation of the <constant>NULL</constant> - account cannot validate and thus connections that utilize the guest account - fail. This breaks all ability to browse the Samba server and is a common - problem reported on the Samba mailing list. A sample User Mode session setup AndX - is shown in <link linkend="userconnect"/>. - </para> - - <figure id="userconnect"> - <title>Typical Windows 9x/Me User SessionSetUp AndX Request</title> - <imagefile scale="41">UserConnect</imagefile> - </figure> - - <para> - <indexterm><primary>encrypted</primary></indexterm> - The User Mode connection packet contains the account name and the domain name. - The password is provided in Microsoft encrypted form, and its length is shown - as 24 characters. This is the length of Microsoft encrypted passwords. - </para> - - </sect3> - - </sect2> - - <sect2> - <title>Windows 200x/XP Client Interaction with Samba</title> - - <para> - By now you may be asking, <quote>Why did you choose to work with Windows 9x/Me?</quote> - </para> - - <para> - First, we want to demonstrate the simple case. This book is not intended to be a detailed treatise - on the Windows networking protocols, but rather to provide prescriptive guidance for deployment of Samba. - Second, by starting out with the simple protocol, it can be demonstrated that the more complex case mostly - follows the same principles. - </para> - - <para> - The following exercise demonstrates the case that even MS Windows XP Professional with up-to-date service - updates also uses the <constant>NULL</constant> account, as well as user accounts. Simply follow the procedure - to complete this exercise. - </para> - - <para> - To complete this exercise, you need a Windows XP Professional client that has been configured as - a domain member of either a Samba-controlled domain or a Windows NT4 or 200x Active Directory domain. - Here we do not provide details for how to configure this, as full coverage is provided earlier in this book. - </para> - - <procedure> - <title>Steps to Explore Windows XP Pro Connection Set-up</title> - - <step><para> - Start your domain controller. Also, start the Wireshark monitoring machine, launch Wireshark, - and then wait for the next step to complete. - </para></step> - - <step><para> - Start the Windows XP Client and wait 5 minutes before proceeding. - </para></step> - - <step><para> - On the machine from which network activity will be monitored (using <command>Wireshark</command>), - launch <command>Wireshark</command> and click - <menuchoice> - <guimenu>Capture</guimenu> - <guimenuitem>Start</guimenuitem> - </menuchoice>. - </para> - - <para> - Click: - <orderedlist> - <listitem><para>Update list of packets in real time</para></listitem> - <listitem><para>Automatic scrolling in live capture</para></listitem> - <listitem><para>Enable MAC name resolution</para></listitem> - <listitem><para>Enable network name resolution</para></listitem> - <listitem><para>Enable transport name resolution</para></listitem> - </orderedlist> - Click <guibutton>OK</guibutton>. - </para></step> - - <step><para> - On the Windows XP Professional client, press <guimenu>Ctrl-Alt-Delete</guimenu> to bring - up the domain logon screen. Log in using valid credentials for a domain user account. - </para></step> - - <step><para> - Now proceed to connect to the domain controller as follows: - <menuchoice> - <guimenu>Start</guimenu> - <guimenuitem>(right-click) My Network Places</guimenuitem> - <guimenuitem>Explore</guimenuitem> - <guimenuitem>{Left Panel} [+] Entire Network</guimenuitem> - <guimenuitem>{Left Panel} [+] Microsoft Windows Network</guimenuitem> - <guimenuitem>{Left Panel} [+] Midearth</guimenuitem> - <guimenuitem>{Left Panel} [+] Frodo</guimenuitem> - <guimenuitem>{Left Panel} [+] data</guimenuitem> - </menuchoice>. Close the explorer window. - </para> - - <para> - In this step, our domain name is <constant>Midearth</constant>, the domain controller is called - <constant>Frodo</constant>, and we have connected to a share called <constant>data</constant>. - </para></step> - - <step><para> - Stop the capture on the <command>Wireshark</command> monitoring machine. Be sure to save the captured data - to a file so that you can refer to it again later. - </para></step> - - <step><para> - If desired, the Windows XP Professional client and the domain controller are no longer needed for exercises - in this chapter. - </para></step> - - <step><para> - <indexterm><primary>NTLMSSP_AUTH</primary></indexterm> - <indexterm><primary>session setup</primary></indexterm> - From the top of the packets captured, scan down to locate the first packet that has - interpreted as <constant>Session Setup AndX Request, NTLMSSP_AUTH</constant>. - </para></step> - - <step><para> - <indexterm><primary>GSS-API</primary></indexterm> - <indexterm><primary>SPNEGO</primary></indexterm> - <indexterm><primary>NTLMSSP</primary></indexterm> - In the dissection (analysis) panel, expand the <constant>SMB, Session Setup AndX Request</constant>. - Expand the packet decode information, beginning at the <constant>Security Blob:</constant> - entry. Expand the <constant>GSS-API -> SPNEGO -> netTokenTarg -> responseToken -> NTLMSSP</constant> - keys. This should reveal that this is a <constant>NULL</constant> session setup packet. - The <constant>User name: NULL</constant> so indicates. An example decode is shown in - <link linkend="XPCap01"/>. - </para></step> - - <step><para> - Return to the packet capture sequence. There will be a number of packets that have been - decoded of the type <constant>Session Setup AndX Request</constant>. Click the last such packet that - has been decoded as <constant>Session Setup AndX Request, NTLMSSP_AUTH</constant>. - </para></step> - - <step><para> - <indexterm><primary>encrypted password</primary></indexterm> - In the dissection (analysis) panel, expand the <constant>SMB, Session Setup AndX Request</constant>. - Expand the packet decode information, beginning at the <constant>Security Blob:</constant> - entry. Expand the <constant>GSS-API -> SPNEGO -> netTokenTarg -> responseToken -> NTLMSSP</constant> - keys. This should reveal that this is a <constant>User Mode</constant> session setup packet. - The <constant>User name: jht</constant> so indicates. An example decode is shown in - <link linkend="XPCap02"/>. In this case the user name was <constant>jht</constant>. This packet - decode includes the <constant>Lan Manager Response:</constant> and the <constant>NTLM Response:</constant>. - The values of these two parameters are the Microsoft encrypted password hashes: respectively, the LanMan - password and then the NT (case-preserving) password hash. - </para></step> - - <step><para> - <indexterm><primary>password length</primary></indexterm> - <indexterm><primary>User Mode</primary></indexterm> - The passwords are 24-character hexadecimal numbers. This packet confirms that this is a User Mode - session setup packet. - </para></step> - - </procedure> - - <figure id="XPCap01"> - <title>Typical Windows XP NULL Session Setup AndX Request</title> - <imagefile scale="50">WindowsXP-NullConnection</imagefile> - </figure> - - <figure id="XPCap02"> - <title>Typical Windows XP User Session Setup AndX Request</title> - <imagefile scale="50">WindowsXP-UserConnection</imagefile> - </figure> - - <sect3> - <title>Discussion</title> - - <para><indexterm> - <primary>NULL-Session</primary> - </indexterm> - This exercise demonstrates that, while the specific protocol for the Session Setup AndX is handled - in a more sophisticated manner by recent MS Windows clients, the underlying rules or principles - remain the same. Thus it is demonstrated that MS Windows XP Professional clients still use a - <constant>NULL-Session</constant> connection to query and locate resources on an advanced network - technology server (one using Windows NT4/200x or Samba). It also demonstrates that an authenticated - connection must be made before resources can be used. - </para> - - </sect3> - - </sect2> - - <sect2> - <title>Conclusions to Exercises</title> - - <para> - In summary, the following points have been established in this chapter: - </para> - - <itemizedlist> - <listitem><para> - When NetBIOS over TCP/IP protocols are enabled, MS Windows networking employs broadcast-oriented messaging protocols to provide knowledge of network services. - </para></listitem> - - <listitem><para> - Network browsing protocols query information stored on browse masters that manage - information provided by NetBIOS Name Registrations and by way of ongoing host - announcements and workgroup announcements. - </para></listitem> - - <listitem><para> - All Samba servers must be configured with a mechanism for mapping the <constant>NULL-Session</constant> - to a valid but nonprivileged UNIX system account. - </para></listitem> - - <listitem><para> - The use of Microsoft encrypted passwords is built right into the fabric of Windows - networking operations. Such passwords cannot be provided from the UNIX <filename>/etc/passwd</filename> - database and thus must be stored elsewhere on the UNIX system in a manner that Samba can - use. Samba-2.x permitted such encrypted passwords to be stored in the <constant>smbpasswd</constant> - file or in an LDAP database. Samba permits use of multiple <parameter>passdb backend</parameter> - databases in concurrent deployment. Refer to <emphasis>TOSHARG2</emphasis>, Chapter 10, <quote>Account Information Databases.</quote> - </para></listitem> - </itemizedlist> - - </sect2> - -</sect1> - -<sect1 id="chap01conc"> - <title>Dissection and Discussion</title> - - <para> - <indexterm><primary>guest account</primary></indexterm> - The exercises demonstrate the use of the <constant>guest</constant> account, the way that - MS Windows clients and servers resolve computer names to a TCP/IP address, and how connections - between a client and a server are established. - </para> - - <para> - Those wishing background information regarding NetBIOS name types should refer to - the Microsoft knowledgebase article - <ulink url="http://support.microsoft.com/support/kb/articles/Q102/78/8.asp">Q102878.</ulink> - </para> - - <sect2> - <title>Technical Issues</title> - - <para> - <indexterm><primary>guest account</primary></indexterm> - Network browsing involves SMB broadcast announcements, SMB enumeration requests, - connections to the <constant>IPC$</constant> share, share enumerations, and SMB connection - setup processes. The use of anonymous connections to a Samba server involve the use of - the <parameter>guest account</parameter> that must map to a valid UNIX UID. - </para> - - </sect2> - -</sect1> - -<sect1 id="chap01qa"> - <title>Questions and Answers</title> - - <para> - The questions and answers given in this section are designed to highlight important aspects of Microsoft - Windows networking. - </para> - - <qandaset defaultlabel="chap01qa" type="number"> - <qandaentry> - <question> - - <para> - What is the significance of the MIDEARTH<1b> type query? - </para> - - </question> - <answer> - - <para> - <indexterm><primary>Domain Master Browser</primary><see>DMB</see></indexterm> - <indexterm><primary>DMB</primary></indexterm> - This is a broadcast announcement by which the Windows machine is attempting to - locate a Domain Master Browser (DMB) in the event that it might exist on the network. - Refer to <emphasis>TOSHARG2,</emphasis> Chapter 9, Section 9.7, <quote>Technical Overview of Browsing,</quote> - for details regarding the function of the DMB and its role in network browsing. - </para> - - </answer> - </qandaentry> - - <qandaentry> - <question> - - <para> - What is the significance of the MIDEARTH<1d> type name registration? - </para> - - </question> - <answer> - - <para> - <indexterm><primary>Local Master Browser</primary><see>LMB</see></indexterm> - <indexterm><primary>LMB</primary></indexterm> - This name registration records the machine IP addresses of the LMBs. - Network clients can query this name type to obtain a list of browser servers from the - master browser. - </para> - - <para> - The LMB is responsible for monitoring all host announcements on the local network and for - collating the information contained within them. Using this information, it can provide answers to other Windows - network clients that request information such as: - </para> - - <itemizedlist> - <listitem><para> - The list of machines known to the LMB (i.e., the browse list) - </para></listitem> - - <listitem><para> - The IP addresses of all domain controllers known for the domain - </para></listitem> - - <listitem><para> - The IP addresses of LMBs - </para></listitem> - - <listitem><para> - The IP address of the DMB (if one exists) - </para></listitem> - - <listitem><para> - The IP address of the LMB on the local segment - </para></listitem> - </itemizedlist> - - </answer> - </qandaentry> - - <qandaentry> - <question> - - <para> - What is the role and significance of the <01><02>__MSBROWSE__<02><01> - name registration? - </para> - - </question> - <answer> - - <para> - <indexterm><primary>Browse Master</primary></indexterm> - This name is registered by the browse master to broadcast and receive domain announcements. - Its scope is limited to the local network segment, or subnet. By querying this name type, - master browsers on networks that have multiple domains can find the names of master browsers - for each domain. - </para> - - </answer> - </qandaentry> - - <qandaentry> - <question> - - <para> - What is the significance of the MIDEARTH<1e> type name registration? - </para> - - </question> - <answer> - - <para> - <indexterm><primary>Browser Election Service</primary></indexterm> - This name is registered by all browse masters in a domain or workgroup. The registration - name type is known as the Browser Election Service. Master browsers register themselves - with this name type so that DMBs can locate them to perform cross-subnet - browse list updates. This name type is also used to initiate elections for Master Browsers. - </para> - - </answer> - </qandaentry> - - <qandaentry> - <question> - - <para> - <indexterm><primary>guest account</primary></indexterm> - What is the significance of the <parameter>guest account</parameter> in smb.conf? - </para> - - </question> - <answer> - - <para> - This parameter specifies the default UNIX account to which MS Windows networking - NULL session connections are mapped. The default name for the UNIX account used for - this mapping is called <constant>nobody</constant>. If the UNIX/Linux system that - is hosting Samba does not have a <constant>nobody</constant> account and an alternate - mapping has not been specified, network browsing will not work at all. - </para> - - <para> - It should be noted that the <parameter>guest account</parameter> is essential to - Samba operation. Either the operating system must have an account called <constant>nobody</constant> - or there must be an entry in the &smb.conf; file with a valid UNIX account, such as - <smbconfoption name="guest account">ftp</smbconfoption>. - </para> - - </answer> - </qandaentry> - - <qandaentry> - <question> - - <para> - Is it possible to reduce network broadcast activity with Samba? - </para> - - </question> - <answer> - - <para> - <indexterm><primary>WINS</primary></indexterm> - <indexterm><primary>NetBIOS</primary></indexterm> - Yes, there are two ways to do this. The first involves use of WINS (See <emphasis>TOSHARG2</emphasis>, Chapter 9, - Section 9.5, <quote>WINS &smbmdash; The Windows Inter-networking Name Server</quote>); the - alternate method involves disabling the use of NetBIOS over TCP/IP. This second method requires - a correctly configured DNS server (see <emphasis>TOSHARG2</emphasis>, Chapter 9, Section 9.3, <quote>Discussion</quote>). - </para> - - <para> - <indexterm><primary>broadcast</primary></indexterm> - <indexterm><primary>NetBIOS</primary><secondary>Node Type</secondary></indexterm> - <indexterm><primary>Hybrid</primary></indexterm> - The use of WINS reduces network broadcast traffic. The reduction is greatest when all network - clients are configured to operate in <parameter>Hybrid Mode</parameter>. This can be effected through - use of DHCP to set the NetBIOS node type to type 8 for all network clients. Additionally, it is - beneficial to configure Samba to use <smbconfoption name="name resolve order">wins host cast</smbconfoption>. - </para> - - <note><para> - Use of SMB without NetBIOS is possible only on Windows 200x/XP Professional clients and servers, as - well as with Samba. - </para></note> - - </answer> - </qandaentry> - - <qandaentry> - <question> - - <para> - Can I just use plain-text passwords with Samba? - </para> - - </question> - <answer> - - <para> - Yes, you can configure Samba to use plain-text passwords, though this does create a few problems. - </para> - - <para> - First, the use of <filename>/etc/passwd</filename>-based plain-text passwords requires that registry - modifications be made on all MS Windows client machines to enable plain-text passwords support. This - significantly diminishes the security of MS Windows client operation. Many network administrators - are bitterly opposed to doing this. - </para> - - <para> - Second, Microsoft has not maintained plain-text password support since the default setting was made - disabling this. When network connections are dropped by the client, it is not possible to re-establish - the connection automatically. Users need to log off and then log on again. Plain-text password support - may interfere with recent enhancements that are part of the Microsoft move toward a more secure computing - environment. - </para> - - <para> - Samba supports Microsoft encrypted passwords. Be advised not to reintroduce plain-text password handling. - Just create user accounts by running <command>smbpasswd -a 'username'</command> - </para> - - <para> - It is not possible to add a user to the <parameter>passdb backend</parameter> database unless there is - a UNIX system account for that user. On systems that run <command>winbindd</command> to access the Samba - PDC/BDC to provide Windows user and group accounts, the <parameter>idmap uid, idmap gid</parameter> ranges - set in the &smb.conf; file provide the local UID/GIDs needed for local identity management purposes. - </para> - - </answer> - </qandaentry> - - <qandaentry> - <question> - - <para> - What parameter in the &smb.conf; file is used to enable the use of encrypted passwords? - </para> - - </question> - <answer> - - <para> - The parameter in the &smb.conf; file that controls this behavior is known as <parameter>encrypt - passwords</parameter>. The default setting for this in Samba is <constant>Yes (Enabled)</constant>. - </para> - - </answer> - </qandaentry> - - <qandaentry> - <question> - - <para> - Is it necessary to specify <smbconfoption name="encrypt passwords">Yes</smbconfoption> - when Samba is configured as a domain member? - </para> - - </question> - <answer> - - <para> - No. This is the default behavior. - </para> - - </answer> - </qandaentry> - - <qandaentry> - <question> - - <para> - Is it necessary to specify a <parameter>guest account</parameter> when Samba is configured - as a domain member server? - </para> - - </question> - <answer> - - <para> - Yes. This is a local function on the server. The default setting is to use the UNIX account - <constant>nobody</constant>. If this account does not exist on the UNIX server, then it is - necessary to provide a <smbconfoption name="guest account">an_account</smbconfoption>, - where <constant>an_account</constant> is a valid local UNIX user account. - </para> - - </answer> - </qandaentry> - </qandaset> - -</sect1> - -</chapter> - |