wazee: April 2020

Sunday, April 26, 2020

CEH: 10 Hacking Tools For Hackers

There are a lot of hacking tools available over the internet but mostly we need some of them. In this blog you'll learn about hacking tools which are typically used in the world of hacking by penetration testers.

SmartWhois

SmartWhois is an information-gathering program that allows you to find all available information about an IP address, hostname, or domain, including country, state or province, city, name of the network provider, administrator, and technical support contact information. SmartWhois is a graphical version of the basic Whois program.

SocksChain

SocksChain is a tool that gives a hacker the ability to attack through a chain of proxy servers. The main purpose of doing this is to hide the hacker's real IP address and therefore minimize the chance of detection. When a hacker works through several proxy servers in series, it's much harder to locate the hacker. Tracking the attacker's IP address through the logs of several proxy servers is complex and tedious work. If one of the proxy servers' log files is lost or incomplete, the chain is broken, and the hacker's IP address remains anonymous.

NeoTrace, VisualRoute, and VisualLookout

NeoTrace, VisualRoute, and VisualLookout are all packet-tracking tools with a GUI or visual interface. They plot the path the packets travel on a map and can visually identify the locations of routers and other internet working devices. These tools operate similarly to traceroute and perform the same information gathering; however, they provide a visual representation of the results.

Visualware's eMailTrackerPro

Visualware's eMailTrackerPro ( www.emailtrackerpro.com/ ) and MailTracking ( http://mailtracking.com/ ) are tools that allow an ethical hacker to track email messages. When you use these tools to send an email, forward an email, reply to an email, or modify an email, the resulting actions and tracks of the original email are logged. The sender is notified of all actions performed on the tracked email by an automatically generated email.

IPEye

IPEye is a TCP port scanner that can do SYN, FIN, Null, and XMAS scans. It's a command line tool.
IPEye probes the ports on a target system and responds with closed, reject, drop, or open. Closed means there is a computer on the other end, but it doesn't listen at the port. Reject means a firewall is rejecting the connection to the port (sending a reset back). Drop means a firewall is dropping everything to the port, or there is no computer on the other end. Open means some kind of service is listening at the port. These responses help a hacker identify what type of system is responding.

IPSecScan

IPSecScan is a tool that can scan either a single IP address or a range of addresses looking for systems that are IPSec enabled that means the system has IPSec enabled while disabled means that it either has IPSec disabled, the compatibility issue or the configuration issue that not reveal to you that it has IPSec enabled. Indeterminable means that the scanner isn't sure if IPSec is enabled or disabled.

Icmpenum

Icmpenum uses not only ICMP Echo packets to probe networks, but also ICMP Timestamp and ICMP Information packets. Furthermore, it supports spoofing and sniffing for reply packets. Icmpenum is great for scanning networks when the firewall blocks ICMP Echo packets but fails to block Timestamp or Information packets.

SNMP Scanner

SNMP Scanner allows you to scan a range or list of hosts performing ping, DNS, and Simple Network Management Protocol (SNMP) queries. This tool helps you to find out the current information about the device of SNMP nodes in the given network.

hping2 tool

The hping2 tool is notable because it contains a host of other features besides OS fingerprinting such as TCP, User Datagram Protocol (UDP), ICMP, and raw-IP ping protocols, traceroute mode, and the ability to send files between the source and target system.

THC-Scan, PhoneSweep, and TeleSweep

THC-Scan, PhoneSweep, and TeleSweep are tools that identify phone numbers and can dial a target to make a connection with a computer modem. These tools generally work by using a predetermined list of common usernames and passwords in an attempt to gain access to the system. Most remote-access dial-in connections aren't secured with a password or use very rudimentary security.

KillShot: A PenTesting Framework, Information Gathering Tool And Website Vulnerabilities Scanner

Why should i use KillShot?
You can use this tool to Spider your website and get important information and gather information automaticaly using whatweb-host-traceroute-dig-fierce-wafw00f or to Identify the cms and to find the vulnerability in your website using Cms Exploit Scanner && WebApp Vul Scanner Also You can use killshot to Scan automaticly multiple type of scan with nmap and unicorn . And With this tool You can Generate PHP Simple Backdoors upload it manual and connect to the target using killshot

This Tool Bearing A simple Ruby Fuzzer Tested on VULSERV.exe and Linux Log clear script To change the content of login paths Spider can help you to find parametre of the site and scan XSS and SQL.

Use Shodan By targ option
CreateAccount Here Register and get Your aip Shodan AIP And Add your shodan AIP to aip.txt < only your aip should be show in the aip.txt > Use targ To search about Vulnrable Targets in shodan databases.

Use targ To scan Ip of servers fast with Shodan.

KillShot's Installation
For Linux users, open your Terminal and enter these commands: If you're a Windows user, follow these steps:

First, you must download and run Ruby-lang setup file from RubyInstaller.org, choose Add Ruby executables to your PATH and Use UTF-8 as default external encoding.

Then, download and install curl (32-bit or 64-bit) from Curl.haxx.se/windows. After that, go to Nmap.org/download.html to download and install the lastest Nmap version.

Download killshot-master.zip and unzip it.

Open CMD or PowerShell window at the KillShot folder you've just unzipped and enter these commands:

ruby setup.rb
ruby killshot.rb

KillShot usage examples

Easy and fast use of KillShot:

Use KillShot to detect and scan CMS vulnerabilities (Joomla and WordPress) and scan for XSS and SQL:

References: Vulnrabilities are taken from

Exploit Database - Exploits for Penetration Testers, Researchers, and Ethical Hackers

Sploitus | Exploit & Hacktool Search Engine

CXSECURITY.COM Free Security List

Download KillShot

Wednesday, April 22, 2020

Reversing Some C++ Io Operations

In general decompilers are not friendly with c++ let's analyse a simple program to get familiar with it.
Let's implement a simple code that loads a file into a vector and then save the vector with following functions:

err
load
save
main

Lets identify the typical way in C++ to print to stdout with the operator "<<"

The basic_ostream is initialized writing the word "error" to the cout, and then the operator<< again to add the endl.

The Main function simply calls "vec = load(filename)" but the compiler modified it and passed the vector pointer as a parámeter. Then it bulds and prints "loaded " << size << " users".
And finally saves the vector to /tmp/pwd and print "saved".
Most of the mess is basically the operator "<<" to concat and print values.
Also note that the vectors and strings are automatically deallocated when exit the function.

And here is the code:

Let's take a look to the load function, which iterates the ifs.getline() and push to the vector.
First of all there is a mess on the function definition, __return_storage_ptr is the vector.
the ifstream object ifs is initialized as a basic_ifstream and then operator! checks if it wasn't possible to open the file and in that case calls err()
We see the memset and a loop, getline read a cstr like line from the file, and then is converted to a string before pushing it to the vector. lVar1 is the stack canary value.

In this situations dont obfuscate with the vector pointer vec initialization at the begining, in this case the logic is quite clear.

The function save is a bit more tricky, but it's no more than a vector iteration and ofs writing.
Looping a simple "for (auto s : *vec)" in the decompiler is quite dense, but we can see clearly two write, the second write DAT_0010400b is a "\n"

As we see, save implememtation is quite straightforward.

How To Install And Config Modlishka Tool - Most Advance Reverse Proxy Phishing

How To Connect Database With PHP | Cool Interface Software | Tutorial 2

Welcome to my 2nd tutorial of PHP and MYSQL. In the previous video I've discussed How to download and install a server PHP and also How to create databases and How to create tables in the databases in the form of rows and columns.

In this video I've discussed multiple ways to connect database with PHP such as by using variables etc. First of all you have need to install a cool interface software for coding. I suggested you to download any one of them such as Dreamweaver, Notepad++, Sublime Text Editor and Atom etc. I'm using sublime text editor in this series of tutorial.

Syntax of PHP

<?php

//type here the code

How to save the PHP file

You should save your PHP file in the root directory of the server. In XAMPP the "htdocs" is the root directory of the server. In WAMPP "www" is the root directory. Now how to save the file?

Step 1:

Press CTRL + S button to safe the file.

Step 2:

Go to the server location where it has been installed. By default it is installed in Local Disk C. Got C drive.

Step 3:

Go to XAMPP directory.

Step 4:

Go to htdocs diretory.

Step 5:

Save a file there with extension ".php". You can create a different folders for different projects in htdocs directory. So first create the folder in htdocs and then save your files in the folder.

How to Run PHP Script

Step 1:

Open a XAMPP control panel and start Apache and Mysql services.

Step 2:

Open your web browser.

Step 3:

Type localhost/yourFolderName/yourFileName.php and hit enter. For example: localhost/myFolder/index.php.

Related news

Monday, April 20, 2020

Top 5 Best TV Series Based On Hacking & Technology 2018

Top 5 Best TV Series Based On Hacking And Technology 2018

Well, if you are a tech fanatic then you will love watching TV shows which are based on hacking and technology. If you are a tech geek, then you will know that hacking stuff in movies/serials always generates glamor and mystery and adds that special oomph factor to the movie or Tv SHOW.

However, there are not much movies/ or TV serials made on hacking and technology. Technology is rapidly becoming the key point in human lives. The previous year we have seen how hackers had made their marks on giant companies. So, in this article, we are going to discuss top TV shows which have to hack as the central theme. So, have a look at the list.

#1 Mr. Robot

Mr. Robot: Best TV Series Based On Hacking & Technology 2018

Well, the reason why I listed Mr. Robot on the top is because this show has millions of followers and this is the first show that portrays an elite hacker. The elite hacker group uses computers, smartphones and many other technologies to penetrate secure network to take down evil corporation while being anonymous. The show displays the life of a young programmer named Elliot who works as a cyber-security engineer and a vigilante hacker by night.

#2 Silicon Valley

Silicon Valley

This TV series displays the tech and hacking with a bit of comic touch. The series shows the competition between techies in the high-tech gold rush of modern Silicon Valley. What's more interesting is the people who are more qualified are least successful whereas underdogs are making it big. This show is running successfully for three years now.

Read more;- How To Hack Any Game On Your Android Smartphones

#3 The IT Crowd

The IT Crowd

The IT Crowd is very popular series and is running successfully for eight years from 2006 to 2013. It is not like Mr.Robot it has its moments of hacks. The series shows the comedic adventures of a rag-tag group of technical support workers at a large corporation.

#4 Person Of Interest

Person Of Interest

It is one of the best TV series made till now. You will get to see the humor, twists, and lots of other things. In this show and intelligent programmer built and AI (Artificial intelligence) that helps to stop the crimes in the city. The show will definitely give you chills.

Read more;- Top 5 Free Online Courses To Learn Artificial Intelligence

#5 Chuck

Chuck: Best TV Series Based On Hacking & Technology 2018

The TV series was somehow popular and ran from 2007 to 2013. The show shows the character of a young hacker and nerd who accidentally downloads US Govt, secrets into his brain and there is where the story starts CIA and NSA agents protect him and at the same time exploit him.

Continue reading

HOW TO BOOST UP BROWSING SPEED?

Internet speed is the most cared factor when you buy an internet connection. What if still, you face a slow speed browsing problem? No worries, as I came with a solution to this problem. I will let you know how to boost up browsing speed. It's very simple to follow.

SO, HOW TO BOOST UP BROWSING SPEED?

There can be many ways you can get a speedy browsing whether you use paid service or free hacks. I am going to share this free speed hack with you.

STEPS TO FOLLOW

Navigate to Control Panel > Network and Internet Options > Network and Sharing Center.
Now look for the active internet connection to which you're currently connected to.
Open up Connection Properties of your active connection.
Click on IPv4 and open its Properties.
Here you will notice your DNS, you just need to change your DNS address with the following DNS.
Preferred DNS server: 208.67.222.222
Alternate DNS server: 208.67.220.220
Once done, save it and no configure it for IPv6. Just change the IPv6 DNS with the following DNS.
Preferred DNS server: 2620:0:ccc::2
Alternate DNS server: 2620:0:CCD::2
Finally, save and you're done with it.

That's all. You have successfully learned how to boost up browsing speed. Hope it will work for you. Enjoy speedy internet..!

More information

Practical Bleichenbacher Attacks On IPsec IKE

We found out that reusing a key pair across different versions and modes of IPsec IKE can lead to cross-protocol authentication bypasses, enabling the impersonation of a victim host or network by attackers. These vulnerabilities existed in implementations by Cisco, Huawei, and others.

This week at the USENIX Security conference, I will present our research paper on IPsec attacks: The Dangers of Key Reuse: Practical Attacks on IPsec IKE written by Martin Grothe, Jörg Schwenk, and me from Ruhr University Bochum as well as Adam Czubak and Marcin Szymanek from the University of Opole [alternative link to the paper]. This blog post is intended for people who like to get a comprehensive summary of our findings rather than to read a long research paper.

IPsec and Internet Key Exchange (IKE)

IPsec enables cryptographic protection of IP packets. It is commonly used to build VPNs (Virtual Private Networks). For key establishment, the IKE protocol is used. IKE exists in two versions, each with different modes, different phases, several authentication methods, and conﬁguration options. Therefore, IKE is one of the most complex cryptographic protocols in use.

In version 1 of IKE (IKEv1), four authentication methods are available for Phase 1, in which initial authenticated keying material is established: Two public key encryption based methods, one signature based method, and a PSK (Pre-Shared Key) based method.

Attacks on IKE implementations

With our attacks we can impersonate an IKE device: If the attack is successful, we share a set of (falsely) authenticated symmetric keys with the victim device, and can successfully complete the handshake – this holds for both IKEv1 and IKEv2. The attacks are based on Bleichenbacher oracles in the IKEv1 implementations of four large network equipment manufacturers: Cisco, Huawei, Clavister, and ZyXEL. These Bleichenbacher oracles can also be used to forge digital signatures, which breaks the signature based IKEv1 and IKEv2 variants. Those who are unfamiliar with Bleichenbacher attacks may read this post by our colleague Juraj Somorovsky for an explanation.

The affected hardware test devices by Huawei, Cisco, and ZyXEL in our network lab.

We show that the strength of these oracles is sufficient to break all handshake variants in IKEv1 and IKEv2 (except those based on PSKs) when given access to powerful network equipment. We furthermore demonstrate that key reuse across protocols as implemented in certain network equipment carries high security risks.

We additionally show that both PSK based modes can be broken with an offline dictionary attack if the PSK has low entropy. Such an attack was previously only documented for one of those modes (edit: see this comment). We thus show attacks against all authentication modes in both IKEv1 and IKEv2 under reasonable assumptions.

The relationship between IKEv1 Phase 1, Phase 2, and IPsec ESP. Multiple simultaneous Phase 2 connections can be established from a single Phase 1 connection. Grey parts are encrypted, either with IKE derived keys (light grey) or with IPsec keys (dark grey). The numbers at the curly brackets denote the number of messages to be exchanged in the protocol.

Where's the bug?

The public key encryption (PKE) based authentication mode of IKE requires that both parties exchanged their public keys securely beforehand (e. g. with certiﬁcates during an earlier handshake with signature based authentication). RFC 2409 advertises this mode of authentication with a plausibly deniable exchange to raise the privacy level. In this mode, messages three and four of the handshake exchange encrypted nonces and identities. They are encrypted using the public key of the respective other party. The encoding format for the ciphertexts is PKCS #1 v1.5.

Bleichenbacher attacks are adaptive chosen ciphertext attacks against RSA-PKCS #1 v1.5. Though the attack has been known for two decades, it is a common pitfall for developers. The mandatory use of PKCS #1 v1.5 in the PKE authentication methods raised suspicion of whether implementations resist Bleichenbacher attacks.

PKE authentication is available and fully functional in Cisco's IOS operating system. In Clavister's cOS and ZyXEL's ZyWALL USG devices, PKE is not ofﬁcially available. There is no documentation and no conﬁguration option for it and it is therefore not fully functional. Nevertheless, these implementations processed messages using PKE authentication in our tests.

Huawei implements a revised mode of the PKE mode mentioned in the RFC that saves one private key operation per peer (we call it RPKE mode). It is available in certain Huawei devices including the Secospace USG2000 series.

We were able to conﬁrm the existence of Bleichenbacher oracles in all these implementations. Here are the CVE entries and security advisories by the vendors (I will add links once they are available):

Cisco: CVE-2018-0131, Security Advisory
Huawei: CVE-2017-17305, Security Advisory
Clavister: CVE-2018-8753, Security Advisory
Zyxel: CVE-2018-9129, Security Advisory

On an abstract level, these oracles work as follows: If we replace the ciphertext of the nonce in the third handshake message with a modiﬁed RSA ciphertext, the responder will either indicate an error (Cisco, Clavister, and ZyXEL) or silently abort (Huawei) if the ciphertext is not PKCS #1 v1.5 compliant. Otherwise, the responder continues with the fourth message (Cisco and Huawei) or return an error notiﬁcation with a different message (Clavister and ZyXEL) if the ciphertext is in fact PKCS #1 v1.5 compliant. Each time we learn that the ciphertext was valid, we can advance the Bleichenbacher attack one more step.

A Bleichenbacher Attack Against PKE

If a Bleichenbacher oracle is discovered in a TLS implementation, then TLS-RSA is broken since one can compute the Premaster Secret and the TLS session keys without any time limit on the usage of the oracle. For IKEv1, the situation is more difﬁcult: Even if there is a strong Bleichenbacher oracle in PKE and RPKE mode, our attack must succeed within the lifetime of the IKEv1 Phase 1 session, since a Diffie-Hellman key exchange during the handshake provides an additional layer of security that is not present in TLS-RSA. For example, for Cisco this time limit is currently ﬁxed to 60 seconds for IKEv1 and 240 seconds for IKEv2.

To phrase it differently: In TLS-RSA, a Bleichenbacher oracle allows to perform an ex post attack to break the conﬁdentiality of the TLS session later on, whereas in IKEv1 a Bleichenbacher oracle only can be used to perform an online attack to impersonate one of the two parties in real time.

Bleichenbacher attack against IKEv1 PKE based authentication.

The figure above depicts a direct attack on IKEv1 PKE:

The attackers initiate an IKEv1 PKE based key exchange with Responder A and adhere to the protocol until receiving the fourth message. They extract the encrypted nonce from this message, and record the other public values of the handshake.
The attackers keep the IKE handshake with Responder A alive as long as the responder allows. For Cisco and ZyXEL we know that handshakes are cancelled after 60 seconds, Clavister and Huawei do so after 30 seconds.
The attackers initiate several parallel PKE based key exchanges to Responder B.

In each of these exchanges, they send and receive the ﬁrst two messages according to the protocol speciﬁcations.
In the third message, they include a modiﬁed version of the encrypted nonce according to the the Bleichenbacher attack methodology.
They wait until they receive an answer or they can reliably determine that this message will not be sent (timeout or reception of a repeated second handshake message).

After receiving enough answers from Responder B, the attackers can compute the plaintext of the nonce.
The attackers now have all the information to complete the key derivation and the handshake. They thus can impersonate Responder B to Responder A.

Key Reuse

Maintaining individual keys and key pairs for each protocol version, mode, and authentication method of IKE is difﬁcult to achieve in practice. It is oftentimes simply not supported by implementations. This is the case with the implementations by Clavister and ZyXEL, for example. Thus, it is common practice to have only one RSA key pair for the whole IKE protocol family. The actual security of the protocol family in this case crucially depends on its cross-ciphersuite and cross-version security. In fact, our Huawei test device reuses its RSA key pair even for SSH host identification, which further exposes this key pair.

A Cross-Protocol Version Attack with Digital Signature Based Authentication

Signature Forgery Using Bleichenbacher's Attack

It is well known that in the case of RSA, performing a decryption and creating a signature is mathematically the same operation. Bleichenbacher's original paper already mentioned that the attack could also be used to forge signatures over attacker-chosen data. In two papers that my colleagues at our chair have published, this has been exploited for attacks on XML-based Web Services, TLS 1.3, and Google's QUIC protocol. The ROBOT paper used this attack to forge a signature from Facebook's web servers as proof of exploitability.

IKEv2 With Digital Signatures

Digital signature based authentication is supported by both IKEv1 and IKEv2. We focus here on IKEv2 because on Cisco routers, an IKEv2 handshake may take up to four minutes. This more relaxed timer compared to IKEv1 makes it an interesting attack target.

I promised that this blogpost will only give a comprehensive summary, therefore I am skipping all the details about IKEv2 here. It is enough to know that the structure of IKEv2 is fundamentally different from IKEv1.

If you're familiar with IT-security, then you will believe me that if digital signatures are used for authentication, it is not particularly good if an attacker can get a signature over attacker chosen data. We managed to develop an attack that exploits an IKEv1 Bleichenbacher oracle at some peer A to get a signature that can be used to break the IKEv2 authentication at another peer B. This requires that peer A reuses its key pair for IKEv2 also for IKEv1. For the details, please read our paper [alternative link to the paper].

Evaluation and Results

For testing the attack, we used a Cisco ASR 1001-X router running IOS XE in version 03.16.02.S with IOS version 15.5(3)S2. Unfortunately, Cisco's implementation is not optimized for throughput. From our observations we assume that all cryptographic calculations for IKE are done by the device's CPU despite it having a hardware accelerator for cryptography. One can easily overload the device's CPU for several seconds with a standard PC bursting handshake messages, even with the default limit for concurrent handshakes. And even if the CPU load is kept below 100 %, we nevertheless observed packet loss.

For the decryption attack on Cisco's IKEv1 responder, we need to ﬁnish the Bleichenbacher attack in 60 seconds. If the public key of our ASR 1001-X router is 1024 bits long, we measured an average of 850 responses to Bleichenbacher requests per second. Therefore, an attack must succeed with at most 51,000 Bleichenbacher requests.

But another limit is the management of Security Associations (SAs). There is a global limit of 900 Phase 1 SAs under negotiation per Cisco device in the default conﬁguration. If this number is exceeded, one is blocked. Thus, one cannot start individual handshakes for each Bleichenbacher request to issue. Instead, SAs have to be reused as long as their error counter allows. Furthermore, establishing SAs with Cisco IOS is really slow. During the attack, the negotiations in the first two messages of IKEv1 require more time than the actual Bleichenbacher attack.

We managed to perform a successful decryption attack against our ASR 1001-X router with approximately 19,000 Bleichenbacher requests. However, due to the necessary SA negotiations, the attack took 13 minutes.

For the statistics and for the attack evaluation of digital signature forgery, we used a simulator with an oracle that behaves exactly as the ones by Cisco, Clavister, and ZyXEL. We found that about 26% of attacks against IKEv1 could be successful based on the cryptographic performance of our Cisco device. For digital signature forgery, about 22% of attacks could be successful under the same assumptions.

Note that (without a patched IOS), only non-cryptographic performance issues prevented a succesful attack on our Cisco device. There might be faster devices that do not suffer from this. Also note that a too slow Bleichenbacher attack does not permanently lock out attackers. If a timeout occurs, they can just start over with a new attack using fresh values hoping to require fewer requests. If the victim has deployed multiple responders sharing one key pair (e. g. for load balancing), this could also be leveraged to speed up an attack.

Responsible Disclosure

We reported our ﬁndings to Cisco, Huawei, Clavister, and ZyXEL. Cisco published ﬁxes with IOS XE versions 16.3.6, 16.6.3, and 16.7.1. They further informed us that the PKE mode will be removed with the next major release.

Huawei published ﬁrmware version V300R001C10SPH702 for the Secospace USG2000 series that removes the Bleichenbacher oracle and the crash bugs we identiﬁed. Customers who use other affected Huawei devices will be contacted directly by their support team as part of a need-to-know strategy.

Clavister removed the vulnerable authentication method with cOS version 12.00.09. ZyXEL responded that our ZyWALL USG 100 test device is from a legacy model series that is end-of-support. Therefore, these devices will not receive a ﬁx. For the successor models, the patched ﬁrmware version ZLD 4.32 (Release Notes) is available.

FAQs

Why don't you have a cool name for this attack?
The attack itself already has a name, it's Bleichenbacher's attack. We just show how Bleichenbacher attacks can be applied to IKE and how they can break the protocol's security. So, if you like, call it IPsec-Bleichenbacher or IKE-Bleichenbacher.
Do you have a logo for the attack?
No.
My machine was running a vulnerable firmware. Have I been attacked?
We have no indication that the attack was ever used in the wild. However, if you are still concerned, check your logs. The attack is not silent. If your machine was used for a Bleichenbacher attack, there should be many log entries about decryption errors. If your machine was the one that got tricked (Responder A in our figures), then you could probably find log entries about unfinished handshake attempts.
Where can I learn more?
First of all, you can read the paper [alternative link to the paper]. Second, you can watch the presentation, either live at the conference or later on this page.
What else does the paper contain?
The paper contains a lot more details than this blogpost. It explains all authentication methods including IKEv2 and it gives message flow diagrams of the protocols. There, we describe a variant of the attack that uses the Bleichenbacher oracles to forge signatures to target IKEv2. Furthermore, we describe the quirks of Huawei's implementation including crash bugs that could allow for Denial-of-Service attacks. Last but not least, it describes a dictionary attack against the PSK mode of authentication that is covered in a separate blogpost.