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www.dbebooks.com - Free Books & magazines 70779ffirs.qxd:WileyRed 9/17/07 12:11 PM Page i The Web Application Hacker’s Handbook Discovering and Exploiting Security Flaws Dafydd Stuttard Marcus Pinto Wiley Publishing, Inc 70779ffirs.qxd:WileyRed 9/17/07 12:11 PM Page ii 70779ffirs.qxd:WileyRed 9/17/07 12:11 PM Page i The Web Application Hacker’s Handbook Discovering and Exploiting Security Flaws Dafydd Stuttard Marcus Pinto Wiley Publishing, Inc 70779ffirs.qxd:WileyRed 9/17/07 12:11 PM Page ii The Web Application Hacker’s Handbook: Discovering and Exploiting Security Flaws Published by Wiley Publishing, Inc 10475 Crosspoint Boulevard Indianapolis, IN 46256 www.wiley.com Copyright © 2008 by Dafydd Stuttard and Marcus Pinto Published by Wiley Publishing, Inc., Indianapolis, Indiana Published simultaneously in Canada ISBN: 978-0-470-17077-9 Manufactured in the United States of America 10 No part of this publication may be reproduced, stored in a retrieval system or transmitted in any form or by any means, electronic, mechanical, photocopying, recording, scanning or otherwise, except as permitted under Sections 107 or 108 of the 1976 United States Copyright Act, without either the prior written permission of the Publisher, or authorization through payment of the appropriate per-copy fee to the Copyright Clearance Center, 222 Rosewood Drive, Danvers, MA 01923, (978) 750-8400, fax (978) 646-8600 Requests to the Publisher for permission should be addressed to the Legal Department, Wiley Publishing, Inc., 10475 Crosspoint Blvd., Indianapolis, IN 46256, (317) 572-3447, fax (317) 572-4355, or online at http://www.wiley.com/go/permissions Limit of Liability/Disclaimer of Warranty: The publisher and the author make no representations or warranties with respect to the accuracy or completeness of the contents of this work and specifically disclaim all warranties, including without limitation warranties of fitness for a particular purpose No warranty may be created or extended by sales or promotional materials The advice and strategies contained herein may not be suitable for every situation This work is sold with the understanding that the publisher is not engaged in rendering legal, accounting, or other professional services If professional assistance is required, the services of a competent professional person should be sought Neither the publisher nor the author shall be liable for damages arising herefrom The fact that an organization or Website is referred to in this work as a citation and/or a potential source of further information does not mean that the author or the publisher endorses the information the organization or Website may provide or recommendations it may make Further, readers should be aware that Internet Websites listed in this work may have changed or disappeared between when this work was written and when it is read For general information on our other products and services or to obtain technical support, please contact our Customer Care Department within the U.S at (800) 762-2974, outside the U.S at (317) 572-3993 or fax (317) 572-4002 Library of Congress Cataloging-in-Publication Data Stuttard, Dafydd, 1972The web application hacker's handbook : discovering and exploiting security flaws / Dafydd Stuttard, Marcus Pinto p cm Includes index ISBN 978-0-470-17077-9 (pbk.) Internet Security measures Computer security I Pinto, Marcus, 1978- II Title TK5105.875.I57S85 2008 005.8 dc22 2007029983 Trademarks: Wiley and related trade dress are registered trademarks of Wiley Publishing, Inc., in the United States and other countries, and may not be used without written permission All other trademarks are the property of their respective owners Wiley Publishing, Inc., is not associated with any product or vendor mentioned in this book Wiley also publishes its books in a variety of electronic formats Some content that appears in print may not be available in electronic books 70779ffirs.qxd:WileyRed 9/17/07 12:11 PM Page iii About the Authors Dafydd Stuttard is a Principal Security Consultant at Next Generation Security Software, where he leads the web application security competency He has nine years’ experience in security consulting and specializes in the penetration testing of web applications and compiled software Dafydd has worked with numerous banks, retailers, and other enterprises to help secure their web applications, and has provided security consulting to several software manufacturers and governments to help secure their compiled software Dafydd is an accomplished programmer in several languages, and his interests include developing tools to facilitate all kinds of software security testing Dafydd has developed and presented training courses at the Black Hat security conferences around the world Under the alias “PortSwigger,” Dafydd created the popular Burp Suite of web application hacking tools Dafydd holds master’s and doctorate degrees in philosophy from the University of Oxford Marcus Pinto is a Principal Security Consultant at Next Generation Security Software, where he leads the database competency development team, and has lead the development of NGS’ primary training courses He has eight years’ experience in security consulting and specializes in penetration testing of web applications and supporting architectures Marcus has worked with numerous banks, retailers, and other enterprises to help secure their web applications, and has provided security consulting to the development projects of several security-critical applications He has worked extensively with large-scale web application deployments in the financial services industry Marcus has developed and presented database and web application training courses at the Black Hat and other security conferences around the world Marcus holds a master’s degree in physics from the University of Cambridge iii 70779ffirs.qxd:WileyRed 9/17/07 12:11 PM Page iv Credits Executive Editor Carol Long Vice President and Executive Publisher Joseph B Wikert Development Editor Adaobi Obi Tulton Project Coordinator, Cover Lynsey Osborn Production Editor Christine O’Connor Compositor Happenstance Type-O-Rama Copy Editor Foxxe Editorial Services Proofreader Kathryn Duggan Editorial Manager Mary Beth Wakefield Indexer Johnna VanHoose Dinse Production Manager Tim Tate Anniversary Logo Design Richard Pacifico Vice President and Executive Group Publisher Richard Swadley iv 70779toc.qxd:WileyRed 9/16/07 5:07 PM Page v Contents Acknowledgments Introduction Chapter xxv Web Application (In)security The Evolution of Web Applications Common Web Application Functions Benefits of Web Applications Web Application Security “This Site Is Secure” The Core Security Problem: Users Can Submit Arbitrary Input Key Problem Factors Immature Security Awareness In-House Development Deceptive Simplicity Rapidly Evolving Threat Profile Resource and Time Constraints Overextended Technologies The New Security Perimeter The Future of Web Application Security Chapter xxiii 9 9 10 10 10 10 12 Chapter Summary 13 Core Defense Mechanisms Handling User Access 15 16 Authentication Session Management Access Control Handling User Input Varieties of Input Approaches to Input Handling 16 17 18 19 20 21 v 70779toc.qxd:WileyRed vi 9/16/07 5:07 PM Page vi Contents “Reject Known Bad” “Accept Known Good” Sanitization Safe Data Handling Semantic Checks Boundary Validation Multistep Validation and Canonicalization Handling Attackers Chapter 21 21 22 22 23 23 26 27 Handling Errors Maintaining Audit Logs Alerting Administrators Reacting to Attacks 27 29 30 31 Managing the Application Chapter Summary Questions 32 33 34 Web Application Technologies The HTTP Protocol 35 35 HTTP Requests HTTP Responses HTTP Methods URLs HTTP Headers General Headers Request Headers Response Headers Cookies Status Codes HTTPS HTTP Proxies HTTP Authentication Web Functionality Server-Side Functionality The Java Platform ASP.NET PHP Client-Side Functionality HTML Hyperlinks Forms JavaScript Thick Client Components State and Sessions Encoding Schemes URL Encoding Unicode Encoding 36 37 38 40 41 41 41 42 43 44 45 46 47 47 48 49 50 50 51 51 51 52 54 54 55 56 56 57 70779toc.qxd:WileyRed 9/16/07 5:07 PM Page vii Contents HTML Encoding Base64 Encoding Hex Encoding Chapter Next Steps Questions 59 59 Mapping the Application Enumerating Content and Functionality 61 62 Web Spidering User-Directed Spidering Discovering Hidden Content Brute-Force Techniques Inference from Published Content Use of Public Information Leveraging the Web Server Application Pages vs Functional Paths Discovering Hidden Parameters 62 65 67 67 70 72 75 76 79 Analyzing the Application Identifying Entry Points for User Input Identifying Server-Side Technologies Banner Grabbing HTTP Fingerprinting File Extensions Directory Names Session Tokens Third-Party Code Components Identifying Server-Side Functionality Dissecting Requests Extrapolating Application Behavior Mapping the Attack Surface Chapter 57 58 59 79 80 82 82 82 84 86 86 87 88 88 90 91 Chapter Summary Questions 92 93 Bypassing Client-Side Controls Transmitting Data via the Client 95 95 Hidden Form Fields HTTP Cookies URL Parameters The Referer Header Opaque Data The ASP.NET ViewState Capturing User Data: HTML Forms Length Limits Script-Based Validation Disabled Elements Capturing User Data: Thick-Client Components Java Applets 96 99 99 100 101 102 106 106 108 110 111 112 vii 70779c20.qxd:WileyRed 722 9/14/07 Chapter 20 ■ 3:15 PM Page 722 A Web Application Hacker’s Methodology 11.1 Test for Default Credentials 11.1.1 Review the results of your application mapping exercises to identify the web server and other technologies in use that may contain accessible administrative interfaces 11.1.2 Perform a port scan of the web server to identify any administrative interfaces running on a different port than the main target application 11.1.3 For any identified interfaces, consult the manufacturer’s documentation and common default password listings to obtain default credentials 11.1.4 If the default credentials not work, use the steps listed in Section to attempt to guess valid credentials 11.1.5 If you gain access to an administrative interface, review the available functionality and determine whether this can be used to further compromise the host and attack the main application 11.2 Test for Default Content 11.2.1 Review the results of your Nikto scan (step 1.4.1) to identify any default content that may be present on the server but not an integral part of the application 11.2.2 Use search engines and other resources to identify default content and functionality included within the technologies you know to be in use If feasible, carry out a local installation of these and review them for any default functionality that you may be able to leverage in your attack 11.2.3 Examine the default content for any functionality or vulnerabilities that you may be able to leverage to attack the server or the application 11.3 Test for Dangerous HTTP Methods 11.3.1 Use the OPTIONS method to list the HTTP methods that the server states are available Note that different methods may be enabled in different directories You can perform a vulnerability scan in Paros to perform this check for you 11.3.2 Try each reported method manually to confirm whether it can in fact be used 70779c20.qxd:WileyRed 9/14/07 3:15 PM Page 723 Chapter 20 ■ A Web Application Hacker’s Methodology 11.3.3 If you find that some WebDAV methods are enabled, use a WebDAVenabled client for further investigation, such as Microsoft FrontPage or the Open as Web Folder option within Internet Explorer 11.4 Test for Proxy Functionality 11.4.1 Using both GET and CONNECT requests, try to use the web server as a proxy to connect to other servers on the Internet, and retrieve content from them 11.4.2 Using both techniques, attempt to connect to different IP addresses and ports within the hosting infrastructure 11.4.3 Using both techniques, attempt to connect to common port numbers on the web server itself, by specifying 127.0.0.1 as the target host in the request 11.5 Test for Virtual Hosting Misconfiguration 11.5.1 Submit GET requests to the root directory using the following: ■■ The correct Host header ■■ A bogus Host header ■■ The server’s IP address in the Host header ■■ No Host header (use HTTP/1.0 only) 11.5.2 Compare the responses to these requests A common result is that directory listings are obtained when the server’s IP address is used in the Host header You may also find that different default content is accessible 11.5.3 If different behavior is observed, repeat the application mapping exercises described in step using the hostname that generated different results Be sure to perform a Nikto scan using the -vhost option, to identify any default content that may have been overlooked during initial application mapping 11.6 Test for Web Server Software Bugs 11.6.1 Run Nessus and any other similar scanners you have available, to identify any known vulnerabilities in the web server software you are attacking 723 70779c20.qxd:WileyRed 724 9/14/07 Chapter 20 ■ 3:15 PM Page 724 A Web Application Hacker’s Methodology 11.6.2 Review resources such as Security Focus, Bugtraq, and Full Disclosure to find details of any recently discovered vulnerabilities that may not have been fixed on your target 11.6.3 If the application was developed by a third party, investigate whether it ships with its own web server (often an open source server), and if so, investigate this for any vulnerabilities Be aware that in this case, the server’s standard banner may well have been modified 11.6.4 If possible, consider performing a local installation of the software you are attacking, and carry out your own testing to find new vulnerabilities that have not been discovered or widely circulated 12 Miscellaneous Checks 12.1 Test for DOM-based attacks 12.2 Test for frame injection 12.3 Test for local privacy vulnerabilities 12.4 Follow up information leakage 12.5 Test for weak SSL ciphers Figure 20-13: Miscellaneous checks 12.1 Check for DOM-Based Attacks 12.1.1 Perform a brief code review of every piece of JavaScript received from the application to identify any XSS or redirection vulnerabilities that can be triggered by using a crafted URL to introduce malicious 70779c20.qxd:WileyRed 9/14/07 3:15 PM Page 725 Chapter 20 ■ A Web Application Hacker’s Methodology data into the DOM of the relevant page Include all standalone JavaScript files and scripts contained within HTML pages (both static and dynamically generated) 12.1.2 Identify all uses of the following APIs, which may be used to access DOM data that is controllable via a crafted URL: document.location document.URL document.URLUnencoded document.referrer window.location 12.1.3 Trace the relevant data through the code to identify what actions are performed with it If the data (or a manipulated form of it) is passed to one of the following APIs, then the application may be vulnerable to XSS: document.write() document.writeln() document.body.innerHtml eval() window.execScript() window.setInterval() window.setTimeout() 12.1.4 If the data is passed to one of the following APIs, then the application may be vulnerable to a redirection attack: document.location document.URL document.open() window.location.href window.navigate() window.open() 12.2 Check for Frame Injection 12.2.1 If the application uses frames, review the HTML source of the main browser window, which should contain the code for the frameset Look for tags which contain a name attribute If any are found, then the application is potentially vulnerable to frame injection 12.2.2 If the names used for frames appear to be highly cryptic or random, access the application several times from different browsers, and review whether the frame names change If they do, and there is no way to predict the names of other users’ frames, then the application is probably not vulnerable 725 70779c20.qxd:WileyRed 726 9/14/07 Chapter 20 ■ 3:15 PM Page 726 A Web Application Hacker’s Methodology 12.3 Check for Local Privacy Vulnerabilities 12.3.1 Review the logs created by your intercepting proxy to identify all the Set-Cookie directives received from the application during your testing If any of these contains an expires attribute with a date that is in the future, the cookie will be stored by users’ browsers until that date Review the contents of any persistent cookies for sensitive data 12.3.2 If a persistent cookie is set that contains any sensitive data, then a local attacker may be able to capture this data Even if the data is encrypted, an attacker who captures it will be able to resubmit the cookie to the application, and gain access to any data or functionality that this allows 12.3.3 If any application pages containing sensitive data are accessed over HTTP, look for any cache directives within the server’s responses If any of the following directives not exist (either within the HTTP headers or within HTML meta-tags), then the page concerned may be cached by one or more browsers: Expires: Cache-control: no-cache Pragma: no-cache 12.3.4 Identify any instances within the application in which sensitive data is transmitted via a URL parameter If any cases exist, examine the browser history to verify that this data has been stored there 12.3.5 For all forms that are used to capture sensitive data from the user (such as credit card details), review the HTML source for the form If the attribute autocomplete=off is not set, either within the form tag or the tag for the individual input field, then data entered will be stored within browsers that support autocomplete provided that the user has not disabled this 12.4 Follow Up Any Information Leakage 12.4.1 In all of your probing of the target application, monitor its responses for error messages that may contain useful information about the cause of the error, the technologies in use, and the application’s internal structure and functionality 12.4.2 If you receive any unusual error messages, investigate these using standard search engines You can use various advanced search features to narrow down your results For example: "unable to retrieve" filetype:php 70779c20.qxd:WileyRed 9/14/07 3:15 PM Page 727 Chapter 20 ■ A Web Application Hacker’s Methodology 12.4.3 Review the search results, looking both for any discussion about the error message and for any other web sites in which the same message has appeared Other applications may produce the same message in a more verbose context, enabling you to better understand what kind of conditions give rise to the error Use the search engine cache to retrieve examples of error messages that no longer appear within the live application 12.4.4 Use Google code search to locate any publicly available code that may be responsible for a particular error message Search for snippets of error messages that may be hard-coded into the application’s source code You can also use various advanced search features to specify the code language and other details, if these are known For example: unable\ to\ retrieve lang:php package:mail 12.4.5 If you receive error messages with stack traces containing the names of library and third-party code components, search for these names on both types of search engine 12.5 Check for Weak SSL Ciphers 12.5.1 If the application uses SSL for any of its communications, use the tool THCSSLCheck to list the ciphers and protocols supported 12.5.2 If any weak or obsolete ciphers and protocols are supported, then a suitably positioned attacker may be able to perform an attack to downgrade or decipher the SSL communications of an application user, gaining access to their sensitive data 12.5.3 Some web servers advertise certain weak ciphers and protocols as supported but refuse to actually complete a handshake using these if a client requests them This can lead to false positives when using the THCSSLCheck tool You can use the Opera browser to attempt to perform a complete handshake using specified weak protocols, to confirm whether these can actually be used to access the application 727 70779c20.qxd:WileyRed 9/14/07 3:15 PM Page 728 70779bindex.qxd:WileyRed 9/14/07 3:16 PM Page 729 Index 302 Found, 68 400 Bad Request, 69 403 Forbidden, 69 401 Unauthorized, 69 500 Internal Server Error, 69 A access controls, 18–19, 217 attacking, 224–228 broken, horizontal, 218 insecure methods, 223–224 securing, 228–234 testing insecure access control methods, 698 limited access, 697–698 multiple accounts, 697 requirements, 696–697 vertical, 218 vulnerabilities, 218–219 identifier-based functions, 220–221 insecure access control methods, 223–224 multistage functions, 222 static files, 222–223 unprotected functionality, 219–220 Accipiter DirectServer, 568 ActiveX controls, 119–120 attacking, 454–455 exported functions, 122 inputs processed by controls, 123–124 managed code, decompiling, 123–124 reverse engineering, 120–122 vulnerabilities finding, 455–456 preventing, 456–457 administrators, alerting, 30–31 AJAX (Asynchronous JavaScript and XML), 54, 389–390 leveraging, 461–463 asynchronous off-site requests, 463–464 alerting administrators, 30–31 Alibaba, 568 Allaire JRun directory listing vulnerability, 569 analyzing applications identifying data entry points, 673 identifying functionality, 673 identifying the technologies used, 673–674 mapping attack surface, 674 anti-DNS pinning, 464–466 DNS pinning, 466 attacks against, 466–467 Apache, chunked encoding overflow, 567 application pages, functional paths and, 76–78 application service providers See ASPs applications analyzing identifying data entry points, 673 identifying functionality, 673 identifying the technologies used, 673–674 mapping the attack surface, 674 mapping content default content and, 671 hidden content and, 670–671 identifier-specified functions, 671–672 public resources and, 670 test for debug parameters, 672 visible content, 669–670 arbitrary redirection, 583–584 testing for, 706 architecture, tiered, 535–536 applying defense in depth, 542 attacking tiers, 539–540 exploiting trust relationships between tiers, 537–538 minimizing trust relationships, 540–541 segregating different components, 541–542 subverting tiers, 538–539 archives, hidden content and, 73 ASP, code injection and, 302–303 ASP.NET, 50 APIs, dangerous, 596–600 environment, configuring, 600–601 session interaction, 595–596 user-supplied data, identifying, 594–595 ViewState, 102–106 ASPs (application service providers), 542–543 shared application services, 543–544 attack surfaces, 91–92 attackers alerting administrators, 30–31 audit logs and, 29–30 error handling, 27–29 reacting to attacks, 31–32 audit logs, 29–30 729 70779bindex.qxd:WileyRed 730 Index ■ 9/14/07 3:16 PM Page 730 A–C authentication, 16–17 ACEGI, 49 broken, design flaws brute-forcible login, 136–138 incomplete credential validation, 152 insecure distribution of credentials, 155 passwords, 135–136 passwords, change functionality, 144–145 passwords, forgotten functionality, 145–147 passwords, predictable initial, 154–155 remember me functionality, 148–149 user impersonation functionality, 149–151 usernames, non-unique, 152–153 usernames, predictable, 154 verbose failure messages, 139–141 vulnerable transmission of credentials, 142–143 HTTP, 47, 178–179 implementation flaws fail-open login mechanism, 156–157 insecure storage of credentials, 161 multistage login mechanisms, defects, 157–161 JAAS, 49 securing account recovery function, 170–171 brute-force attack prevention, 167–169 credentials, handling secretively, 163–164 credentials, strong, 162–163 credentials, validating, 164–166 information leakage prevention, 166–167 log, 172 monitor, 172 notify, 172 password change function, 170 smartcards and, 176 technologies, 134–135 authentication mechanism, testing account recovery function, 682 check for unsafe distribution of credentials, 685 check for unsafe transmission of credentials, 684–685 exploit any vulnerabilities to gain unauthorized access, 687–688 impersonation function, 683 logic flaws, 685–686 multistage mechanisms, 686–687 password quality, 680 predictability of auto-generated credentials, 684 remember me function, 682–683 resilience to password guessing, 681 understanding mechanism, 680 username enumeration, 680–681 username uniqueness, 683–684 autocomplete, 460 B backdoor passwords, 584–585 banner grabbing, 82 Base64 encoding, 58 Basic authentication, HTTP, 47 bespoke automation attack scripting, 476–477 Burp Intruder, 491–501 enumerating identifiers approach, 474 hit detection, 474–476 HTTP status code, 474 location header, 475 response body, 475 response length, 475 set-cookie header, 475 time delays, 476 fuzzing and, 487–491 harvesting data, 484–487 JAttack, 477–483 uses for, 472–473 black-box testing, 578–579 blocked characters, bypassing filters and, 267 blocked strings, bypassing filters and, 268 boundary validation, 23–25 browsing history, 459 brute-forcible login, 136–138 buffer overflows detecting vulnerabilities, 527–528 heap overflows, 523–524 off-by-one vulnerabilities, 524–527 stack overflows, 522–523 vulnerabilities, 585–586 web server vulnerabilities, 566–567 Burp Intruder, 69, 491–492 application fuzzing, 500–501 enumerating identifiers, 495–498 harvesting information, 498–500 payloads choosing, 493–494 positioning, 492–493 response analysis, 494–495 Burp Proxy, 97, 105 Burp Spider, 62 Burp Suite, 643–644 bypassing filters blocked characters, 267 blocked strings, 268 circumventing validation, 267 defective filters, 269–270 dynamic execution, 268–269 SQL comments, 268 bypassing login, injecting into SQL, 243–244 C cached web content, 458–459 canonicalization, 26–27 vulnerabilities, web server, 568–571 capturing user data HTML forms disabled elements, 110–111 length limits, 106–108 script-based validation, 108–110 thick-client components, 111–112 ActiveX controls, 119–124 Java applets, 112–119 Shockwave Flash Objects, 124–128 circumventing validation, bypassing filters and, 267 Cisco ACS Acme.server, 568 client, transmitting data via, 95–96 ASP.NET ViewState, 102–106 form fields, hidden, 96–98 HTTP cookies, 99 opaque data, 101–102 Referer header, 100–101 URL parameters, 99–100 client-side attack, escalating attack other network hosts, 398 capturing clipboard contents, 396 enumerating currently used applications, 397 exploit browser vulnerabilities, 399 logging keystrokes, 396 port scanning local network, 397–398 stealing history and search queries, 396 client-side controls, testing client-side controls over user input, 676 thick-client components, 677–679 transmission of data via client, 675–676 client-side data alerting, 131 logging, 131 transmitting data via client, 128–129 validating client-generated data, 129–130 client-side information leakage, 517 70779bindex.qxd:WileyRed 9/14/07 3:16 PM Page 731 Index clipboard, capturing contents, 396 code, tools for browsing, 619–620 code injection, 237 bypassing filters blocked characters, 267 blocked strings, 268 circumventing validation, 267 defective filters, 269–270 dynamic execution, 268–269 SQL comments, 268 compiled languages, 238 fingerprinting database, 255–256 inference, 277–278 Absinthe, 278–282 conditional errors, 282–283 time delays, 283–285 interpreted languages, 238–239 LDAP, 326–327 flaws, 329–330 modifying search filter, 328–329 preventing, 330 query attributes, 327–328 ODBC error messages, 262–266 OS command ASP and, 302–303 injection flaws, 304–307 Perl and, 300–302 preventing, 307 out-of-band channels, 274–275 MS-SQL, 275 MySQL, 276–277 Oracle, 275–276 retrieving data as numbers, 273–274 second-order SQL injection, 271–272 SMTP, 321–322 command injection, 323–324 email header manipulation, 322–323 flaws, 324–325 preventing, 325–326 SOAP, 313–316 SQL, 240–241 bugs, 244–247 bypassing login, 243–244 DELETE statements, 250 exploiting basic vulnerability, 241–243 INSERT statements, 248–249 preventing, 296–300 SELECT statements, 248 UNION operator, 250–255 UPDATE statements, 249–250 web scripting languages dynamic execution vulnerabilities, 307–310 file inclusion vulnerabilities, 310–312 script injection vulnerabilities, preventing, 312 XPath, 316–317 blind, 319–320 flaws, 320–321 preventing, 321 subverting application logic, 317–318 code review black-box testing, 578–579 methodology, 579–580 white-box testing, 578–579 command injection, SMTP, 323–324 comments, source code, 586–587 common functions of web applications, 3–4 COMRaider, 122 configuration vulnerable default content, 555–558 default credentials, 554–555 web server, securing, 565–566 content, default, 555–558 Cookie header, HTTP request, 37 cookies domain restrictions, 203–205 HTTP, 43–44, 99 path restrictions, 205–206 persistent, 458 scope, 695–696 session tokens and, 178 credentials default, 554–555 incomplete validation, 152 insecure distribution, 155 insecure storage, 161 vulnerable transmission, 142–143 cross-site scripting, 580–581 See XSS (cross-site scripting) custom, scripts, Stunnel, 663–664 D data handling, safe, 22–23 data sanitization, 22 database error messages, 510 Database object relational mapping, Hibernate, 49 databases attacking MS-SQL and, 286–287 MySQL and, 288–289 Oracle and, 288 code components calls to dangerous functions, 618–619 SQL injection, 617–618 data extraction MS-SQL, 260–262 Oracle, 257–260 fingerprinting, code injection and, 255–256 debug messages, 508–509 debugging breakpoint, 121 functionality, 555–556 OllyDbg, 120 defective filters, bypassing filters and, 268–269 ■ C–E DELETE statements (SQL), code injection, 250 design flaws in authentication mechanisms brute-forcible login, 136–138 incomplete credential validation, 152 insecure distribution of credentials, 155 passwords, 135–136 change functionality, 144–145 forgotten functionality, 145–147 predictable initial, 154–155 remember me functionality, 148–149 user impersonation functionality, 149–151 usernames non-unique, 152–153 predictable, 154 verbose failure messages, 139–141 vulnerable transmission of credentials, 142–143 Digest authentication, HTTP, 47 directory listings, web server, 559–560 directory names, 86 DOM-based attacks, checking for, 724–725 DOM-based XSS vulnerabilities, 386–388 domain restrictions, cookies, 203–205 dynamic execution, bypassing filters and, 268–269 E EJB (Enterprise Java Bean), 49 elements, HTML forms, disabled, 110–111 email, XSS attacks and, 388 encoding Base64, 58 hex, 59 HTML, 57–58 Unicode, 57 URL, 56 vulnerabilities, web server, 568–571 Enterprise Java Bean (EJB), 49 entry points for user input, identifying, 80–81 enumeration, identifiers, bespoke automation and, 472, 473–483 environments, shared attacking, 544–549 securing, 549–551 ERP (enterprise planning) software, error handling, 27–29 error messages, 505–506 database messages, 509–511 debug messages, 508–509 731 70779bindex.qxd:WileyRed 732 Index ■ 9/14/07 3:16 PM E–I engineering informative, 512–513 information leakage and, 516–517 public information, 511–512 script error messages, 506–507 server messages, 509–511 stack traces, 507–508 exported functions, 122 F fail-open login mechanism, 156–157 failure messages, verbose, 139–141 fields, hidden in forms, 96–98 file extensions, 84–86 file inclusion, testing for, 711 files, static, 222–223 fingerprinting database, code injection and, 255–256 Firefox, 624–626 Flash VM, 125 format string vulnerabilities, 531–532, 586 detecting, 532–533 forms, 52–53 fields, hidden, 96–98 HTML, length limits, 106–108 parsing, web spidering, 62 frame injection, 438–439 checking for, 725 exploiting, 439–440 preventing, 440 function-specific input vulnerabilities, testing for LDAP injection, 715–716 native software vulnerabilities, 713–714 SMTP injection, 712–713 SOAP injection, 715 XPath injection, 716–717 functions exported, 122 identifier-based, 220–221 multistage, 222 web server configuration, 557–558 fuzzing, bespoke automation and, 472, 487–491 G GET method, HTTP, 38 getObsScore method, 112–113 H Page 732 harvesting data, bespoke automation and, 472, 484–487 HEAD method, HTTP, 39 heap overflows, 523–524 hex encoding, 59 Hibernate, Database object relational mapping, 49 hidden content, discovering, 67 brute-force, 67–70 inference, 70–72 leveraging the web server, 75–76 public information, use of, 72–74 hidden parameters, 79 hijacking, session tokens, client exposure to, 201–202 history, stealing, 396 horizontal access controls, 218 horizontal privilege escalation, 218 Host header, HTTP request, 37 hosting shared, 542–543 virtual hosting, 543 HTML (hypertext markup language), 51 encoding, 57–58 forms disabled elements, 110–111 length limits, 106–108 parsing, 62 script-based validation, 108–110 HTTP authentication, 178–179 HTTP cookies, 99 HTTP fingerprinting, 82–83 HTTP header injection, 705–706 HTTP response splitting, 436–438 injecting cookies, 435–436 vulnerabilities exploiting, 434–438 preventing, 434–438 HTTP (Hypertext Transfer Protocol), 4–5, 35–36 authentication, 47 cookies, 43–44 headers general, 41 request, 41–42 response, 42 tamper-proof, 101 HTTPS, 45–46 methods GET, 38 HEAD, 39 OPTIONS, 40 POST, 39 PUT, 40 TRACE, 39–40 proxies, 46 requests, 36–37 headers, 41–42 Referer header, 99–100 responses, 37–38 headers, 42 status codes, 44–45 URLs, 40–41 HTTP methods, web server, 560–562 Hydra, 660 hyperlinks, 51–52 I identifier-based functions, 220–221 identifiers, enumerating, bespoke automation and, 472, 473–483 implementation flaws fail-open login mechanism, 156–157 insecure storage of credentials, 161 multistage login mechanisms, defects, 157–161 incomplete credential validation, 152 inference, 514–516 information leakage, follow up, 726–727 preventing generic error messages, 516–517 minimizing client-side, 517 protecting sensitive information, 517 initial passwords, predictable, 154–155 injecting code See code injection input, validation, 23–25 input-based vulnerabilities, testing for file inclusion, 711 fuzz all request parameters, 699–702 OS command injection, 707–708 path traversal, 709–710 script injection, 711 SQL injection, 702–704 XSS injection, 704–707 input handling accept known good, 21–22 reject known bad, 21 safe data handling, 22–23 sanitization, 22 semantic checks, 23 insecure distribution of credentials, 155 insecure storage of credentials, 161 INSERT statements (SQL), code injection and, 248–249 integer overflows, 529 integer vulnerabilities, 586 detecting, 530–531 integer overflows, 529 signedness errors, 529–530 integrated testing suites, 627–628 application fuzzers and scanners, 636–637 Burp Suite, 643–644 feature comparison, 640–643 intercepting proxies alternatives to, 646–647, 646–648 browser configuration, 628–629 common features, 631–633 intercepting proxies and HTTPS, 629–631 70779bindex.qxd:WileyRed 9/14/07 3:16 PM Page 733 Index Tamper Data, 647–648 TamperIE, 647–648 manual request tools, 637–639 shared functions and utilities, 639–640 Paros, 644–645 web application spiders, 633–636 WebScarab, 645–646 intercepting server responses, 107 Internet Explorer, 624 interpreted languages, code injection and, 238–239 iPlanet search overflow, 567 ISAPI extensions, 567 J JAR (Java ARchive) files, 116 JAttack, 477–483 Java APIs, dangerous, 589–592 bytecode decompiling, 114–117 obfuscation, 117–119 environment, configuring, 593–594 session interaction, 589 user-supplied data, identifying, 587–589 web containers, 49 Java applets, JAR files, 116 Java Platform, Enterprise Edition, 49–50 Java Servlets, 49 JavaScript, 54, 616–617 JSON (JavaScript Object Notation), 446 attacks against implementing callback function, 448–449 overriding array constructor, 447–448 hijacking, 446–447 preventing, 450 vulnerabilities, 449 K keystrokes, logging, 396 L LDAP code injection, 326–327 flaws, 329–330 modifying search filter, 328–329 preventing, 330 query attributes, 327–328 injection, testing for, 715–716 local network, port scanning, 397–398 local privacy attacks autocomplete, 460 browsing history, 459 cached web content, 458–459 cookies, persistent, 458 preventing, 460–461 local privacy vulnerabilities, checking for, 726 logging, 131 Log4J, 49 session token disclosure, 196–198 logic flaws abusing a search function example, 365–366 avoiding, 370–372 beating a business limit example, 360–362 breaking the bank example, 356–359 cheating on bulk discounts example, 362–363 erasing an audit trail example, 359–360 escaping from escaping example, 363–364 fooling password change function example, 351–352 nature of, 350 proceeding to checkout example, 352–354 racing against the login, 368–370 rolling your own insurance example, 354–356 snarfing debug messages example, 366–368 testing for handling of incomplete input, 718–719 key attack surface, 717 multistage processes, 718 transaction logic, 719–720 trust boundaries, 719 login brute-forcible, 136–138 bypassing, 243–244 fail-open login mechanism, 156–157 multistage login mechanisms, defects in, 157–161 sessions and, 176 Log4J, logging, 49 M mapping, session tokens, 198–200 mapping application content default content and, 670–671 hidden content and, 670–671 identifier-specified functions, 671–672 public resources and, 670 test for debug parameters, 672 visible content and, 669–670 McAfee Epolicy Orcestrator, 568 Microsoft IIS ISAPI extensions, 567 Unicode path traversal vulnerabilities, 569–570 WebDav overflow, 567 ■ I–P minimizing client-side information leakage, 517 multistage functions, 222 multistage login mechanisms, defects in, 157–161 multistep validation, 26–27 MySpace, XSS attack, 388 N native software bugs buffer overflow vulnerabilities, 585–586 format string vulnerabilities, 586 integer vulnerabilities, 586 native software vulnerabilities, testing for buffer overflows, 713 format string vulnerabilities, 714 integer vulnerabilities, 714 networks hosts, attacking, 398 port scanning, 397–398 session token disclosure, 192–195 Nikto, 660 non-unique usernames, 152–153 NTLM authentication, HTTP, 47 O ODBC error messages, 262–263 column names, enumerating, 263–265 extracting arbitrary data, 265 recursion, 266 table names, enumerating, 263–265 off-by-one vulnerabilities, 524–527 OllyDbg, 120 opaque data, 101–102 Opera, 626–627 OPTIONS method, HTTP, 40 Oracle PL/SQL exclusion list bypasses, 570–571 OS command injection, 584 testing for, 707–708 OS commands, code injection, 300–307 P parameters, URL parameters, 99–100 Paros, 62, 97, 644–645 parsing, HTML forms, web spidering, 62 passwords backdoor, 584–585 bad, 135–136 change functionality, 144–145 forgotten functionality, 145–147 initial, predictable, 154–155 733 70779bindex.qxd:WileyRed 734 Index ■ 9/14/07 3:16 PM P–S path traversal, 582–583 testing for, 709–710 vulnerabilities circumventing obstacles to attacks, 339–343 common, 333–334 custom encoding, 342–343 detecting, 336–339 exploiting, 344 preventing, 344–346 targets for attack, locating, 335–336 web server, 568 per-page tokens, 211 Perl, 611–612 APIs, dangerous, 613–615 code injection and, 302–303 environment, configuring, 615–616 session interaction, 613 user-supplied data, identifying, 612 phishing scams, 383 PHP, 50–51 APIs, dangerous, 604–609 environment, configuring, 609–611 session interaction, 603 user-supplied data, identifying, 601–603 POJO (Plain Old Java Object), 49 port scanning network, 397–398 POST method, HTTP, 39 Pragma header, HTTP response, 38 predictable initial passwords, 154–155 Presentation layer SiteMesh, 49 Tapestry, 49 protecting sensitive information, 517 proxies HTTP, 46 web servers as, 562–564 public information, error messages, 511–512 published information, gathering, 513–514 PUT method, HTTP, 40 R Page 734 redirection attacks, 428 absolute prefix, 432 blocking absolute URLs, 431 vulnerabilities finding and exploiting, 429–433 preventing, 433–434 Referer header, HTTP request, 37, 99–100 reflected request parameters, 704 reflected XSS, 379, 705 remember me functionality, 148–149 request forgery, 440–441 OSRF (on-site request forgery), 441–442 XSRF (cross-site request forgery), 442–446 flaws, exploiting, 443–444 flaws, preventing, 444–446 reverse engineering, 120–122 robots.txt, 62 S safe data handling, 22–23 same origin policy, 381 sample functionality, 556–557 sanitizing input, 22 script-based validation, 108–110 script injection, testing for, 711 scripting, cross-site, scripts, custom, 661–662 Curl, 662–663 Netcat, 663 Wget, 662 search engines, hidden content and, 72 search queries, stealing, 396 security, future of, 12 problem factors, 9–10 SELECT statements (SQL), code injection and, 248 semantic checks, 23 sensitive information, protecting, 517 server error messages, 509 Server header, HTTP response, 38 server responses, intercepting, 107 server-side functionality application behavior, 90–91 requests, 88–90 server-side technologies banner grabbing, 82 directory names and, 86 file extensions and, 84–86 HTTP fingerprinting, 82–83 session tokens and, 86 third-party code components and, 87–88 session fixation, 450–452, 694 vulnerabilities finding and exploiting, 452–453 preventing, 453–454 session management, 17–18, 175–176 alerts, 211–212 logging, 211–212 monitoring, 211–212 securing strong tokens, 206–208 token protection, 208–211 session management mechanism, testing, 688 check cookie scope, 695–696 check for disclosure of tokens in logs, 692 check for insecure transmission of tokens, 691–692 check for session fixation, 694 7check for XSRF, 694–695 check mapping of tokens to sessions, 692–693 test session termination, 693–694 testing tokens for meaning, 689–690 testing tokens for predictability, 690–691 understanding mechanism, 689 session termination, testing, 693–694 session tokens, 86 concurrent logins, 209 disclosure in logs, 196–198 disclosure on network, 192–195 generation, weaknesses in, 180–191 handling, weaknesses in, 191–192 hijacking, client exposure to, 201–202 logout functionality, 209 mapping, 198–200 meaningful, 180–182 per-page, 211 predictable, 182–183 concealed sequences, 184–185 random number generation, 187–191 time dependency, 185–187 SSL and, 192 structured, 181 transmitting to URL, 209 sessionless state mechanisms, 179 sessions, 55, 176 alternatives to, 178–180 HTTP authentication and, 178–179 identifiers, 177 login, 176 sessionless state mechanisms, 179 termination, 200–201 tokens, 177 cookies and, 178 Set-Cookie header, HTTP response, 38, 203 shared application services, 543–544 shared environments attacking attacks against mechanisms, 545–546 attacks between applications, 546–549 securing secure customer access, 549–550 segregating components in shared application, 551 segregating customer functionality, 550 70779bindex.qxd:WileyRed 9/14/07 3:16 PM Page 735 Index shared hosting, 542–543 virtual hosting, 543 vulnerabilities segregation between ASPhosted applications, 721 segregation in shared infrastructures, 720 Shockwave Flash objects, 123–124 signedness errors, 529–530 SiteMesh, Presentation Layer, 49 smartcards, authentication and, 176 SMTP, code injection, 321–322 command injection, 323–324 email header manipulation, 322–323 flaws, 324–325 preventing, 325–326 SMTP injection, testing for, 712–713 SOAP code injection, 313–316 injection, testing for, 715 software native bugs buffer overflow vulnerabilities, 585–586 format string vulnerabilities, 586 integer vulnerabilities, 586 security hardening, 573 source code, comments, 586–587 spidering See web spidering SQL (Structured Query Language) code injection, 240–241 bugs, 244–247 bypassing login, 243–244 DELETE statements, 250 exploiting a basic vulnerability, 241–243 INSERT statements, 248–249 preventing, 296–300 SELECT statements, 248 UNION operator, 250–255 UPDATE statements, 249–250 comments, bypassing filters and, 268 error messages, 292–295 injection, 6, 581–582 testing for, 702–704 syntax reference, 289–291 SSL (Secure Socket Layer), 6, ciphers, weak, 727 session tokens and, 192 stack overflows, 522–523 stack traces, 507–508 state, 55, 176–177 sessionless state mechanisms, 179 static files, 222–223 status codes, HTTP responses, 44–45 stored attacks, testing for, 706–707 T Tapestry, Presentation Layer, 49 termination, sessions, 200–201 testing access controls insecure access control methods, 698 limited access, 697–698 multiple accounts, 697 requirements, 696–697 testing authentication mechanism account recovery function, 682 check for unsafe distribution of credentials, 685 check for unsafe transmission of credentials, 684–685 exploit any vulnerabilities to gain unauthorized access, 687–688 impersonation function, 683 logic flaws, fail-open conditions, 685–686 multistage mechanisms, 686–687 password quality, 680 predictability of auto-generated credentials, 684 remember me function, 682–683 resilience to password guessing, 681 understand mechanism, 680 username enumeration, 680–681 username uniqueness, 683–684 testing client-side controls client-side controls over user input, 676 thick-client components ActiveX controls, 678 Java applets, 677 Shockwave Flash objects, 678–679 transmission of data via the client, 675–676 testing for function-specific input vulnerabilities LDAP injection, 715–716 native software vulnerabilities, 713–714 SMTP injection, 712–713 SOAP injection, 715 XPath injection, 716–717 testing for input-based vulnerabilities fuzz all request parameters, 699–702 test for file inclusion, 711 test for OS command injection, 707–708 test for path traversal, 709–710 test for script injection, 711 test for SQL injection, 702–704 test for XSS injection arbitrary redirection, 706 HTTP header injection, 705–706 ■ S–T reflected request parameters, 704 reflected XSS, 705 stored attacks, 706–707 testing for logic flaws handling of incomplete input, 718–719 key attack surface, 717 multistage processes, 718 transaction logic, 719–720 trust boundaries, 719 testing session management mechanism, 688 check cookie scope, 695–696 check for disclosure of tokens in logs, 692 check for insecure transmission of tokens, 691–692 check for session fixation, 694 check for XSRF, 694–695 check mapping of tokens to sessions, 692–693 test session termination, 693–694 test tokens for meaning, 689–690 test tokens for predictability, 690–691 understanding mechanism, 689 thick-client components, 54–55, 111–112 ActiveX controls, 119–120 decompiling managed code, 124 exported functions, 122 inputs, fixing, 123–124 reverse engineering, 120–122 Java applets, 112–114 bytecode obfuscation, 117–119 decompiling Java bytecode, 114–117 third-party code components, 87–88 tiered architectures, 535–536 attacking attacking tiers, 539–540 exploiting trust relationships between tiers, 537–538 subverting tiers, 538–539 securing applying defense in depth, 542 minimizing trust relationships, 540–541 segregating different components, 541–542 tokens See session tokens disclosure in logs, 692 insecure transmission, 691–692 mapping to sessions, 692–693 strong, session management and, 206–208 testing for meaning, 689–690 testing for predictability, 690–691 transmitting, HTTPS, 208–209 735 70779bindex.qxd:WileyRed 736 Index ■ 9/14/07 3:16 PM T–X TRACE method, HTTP, 39 transaction logic, 719–720 Trojans, XSS and, 392–393 trust boundaries, 719 U Unicode encoding, 57 UNION operator (SQL), code injection, 250–255 unprotected functionality, 219 UPDATE statements (SQL), code injection, 249–250 URLs, 40–41 ASCII characters, 56 encoding, 56 parameters, 99–100 user access access control, 18–19 authentication, 16–17 session management, 17–18 user actions, inducing, 394 User-Agent header, HTTP request, 37 user-directed web spidering, 65–66 user impersonation functionality, 149–151 user input, 19–20 canonicalization, 26–27 entry points, identifying, 80–81 input, validation, 23–25 input handling accept known good, 21–22 reject known bad, 21 safe data handling, 22–23 sanitization, 22 semantic checks, 23 types, 20–21 validation boundary validation, 23–25 multistep, 26–27 usernames authentication and, 139 non-unique, 152–153 predictable, 154 users, input, 8–9 V Page 736 validation boundary validation, 23–25 canonicalization, 26–27 multistep, 26–27 script-based, 108–110 vendor patches, software, 572 verbose failure messages, 139–141 vertical access controls, 218 vertical privilege escalation, 218 ViewState (ASP.NET), 102–106 virtual hosting, 543 misconfigured, 564–565 vulnerability scanners challenges faced by, 653–656 limitations, 651–653 using, 658–659 vulnerabilities detected, 649–651 vulnerable transmission of credentials, 142–143 W web applications benefits of, 4–5 common functions, 3–4 evolution of, 2–5 managing, 32–33 web browsers exploitation frameworks, 467–469 Firefox, 624–626 Internet Explorer, 624 Opera, 626–627 vulnerabilities, 399 web server buffer overflow, vulnerabilities, 566–567 configuration debug functionality, 555–556 default content, 555–558 default credentials, 554–555 functions, 557–558 sample functionality, 556–557 securing, 565–566 directory listings, 559–560 encoding and canonicalization vulnerabilities, 568–571 flaws, finding, 571–572 HTTP methods, dangerous, 560–562 path traversal vulnerabilities, 568 as proxy, 562–564 software, securing, 572–574 virtual hosting, misconfigured, 564–565 vulnerabilities, 721 dangerous HTTP methods, 722–723 default content, 722 default credentials, 722 proxy functionality, 723 virtual hosting misconfiguration, 723 web server software bugs, 723–724 web sites, web spidering, 62–64 user-directed, 65–66 WebDAV (Web-based Distributed Authoring and Versioning), 561 WebScarab, 62, 97, 645–646 white-box testing, 578–579 X XPath code injection, 316–317 blind, 319–320 flaws, 320–321 preventing, 321 subverting application logic, 317–318 injection, testing for, 716–717 XSRF, 694–695 XSS (cross-site scripting), 6, 376–377 chaining, 390–391 client-side attack, escalating attack other network hosts, 398 clipboard contents, 396 currently used applications, 397 exploit browser vulnerabilities, 399 history and search queries, 396 keystrokes, 396 port scanning local network, 397–398 cross-site tracing, 421–423 delivery mechanisms reflected and DOM-based attacks, 399–400 stored attacks, 400–401 entry points, 405 HttpOnly cookies, 421–423 inducing user actions and, 394 injection, testing for, 704–707 length limits, 411–413 nonstandard content encoding US-ASCII, 414 UTF-7, 414 UTF-16, 414 preventing attacks, 423–428 real-world attacks, 388–390 reflected, 379 request methods, 413–414 sanitization, 409–411 signature-based filters, 406–409 trojans and, 392–393 trust relationships, exploiting, 394–395 virtual defacement and, 391–392 vulnerabilities, 377–379 DOM-based, 386–388 exploiting, 379–383 finding and exploiting DOMbased, 417–421 finding and exploiting reflected, 401–415 finding and exploiting stored, 415–417 stored, 383–386 ... Chapter xxv Web Application (In )security The Evolution of Web Applications Common Web Application Functions Benefits of Web Applications Web Application Security “This Site Is Secure” The Core Security. .. i The Web Application Hacker’s Handbook Discovering and Exploiting Security Flaws Dafydd Stuttard Marcus Pinto Wiley Publishing, Inc 70779ffirs.qxd:WileyRed 9/17/07 12:11 PM Page ii The Web Application. .. practical guide to discovering and exploiting security flaws in web applications By web application we mean an application that is accessed by using a web browser to communicate with a web server We

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