Search icon CANCEL
Subscription
0
Cart icon
Your Cart (0 item)
Close icon
You have no products in your basket yet
Arrow left icon
Explore Products
Best Sellers
New Releases
Books
Videos
Audiobooks
Learning Hub
Conferences
Free Learning
Arrow right icon
Arrow up icon
GO TO TOP
Python Penetration Testing Essentials

You're reading from   Python Penetration Testing Essentials Techniques for ethical hacking with Python

Arrow left icon
Product type Paperback
Published in May 2018
Publisher
ISBN-13 9781789138962
Length 230 pages
Edition 2nd Edition
Languages
Arrow right icon
Author (1):
Arrow left icon
Mohit Raj Mohit Raj
Author Profile Icon Mohit Raj
Mohit Raj
Arrow right icon
View More author details
Toc

Table of Contents (11) Chapters Close

Preface 1. Python with Penetration Testing and Networking FREE CHAPTER 2. Scanning Pentesting 3. Sniffing and Penetration Testing 4. Network Attacks and Prevention 5. Wireless Pentesting 6. Honeypot – Building Traps for Attackers 7. Foot Printing a Web Server and a Web Application 8. Client-Side and DDoS Attacks 9. Pentesting SQL and XSS 10. Other Books You May Enjoy

Network sockets

A network socket address contains an IP address and port number. In a very simple way, a socket is a way to talk to other computers. By means of a socket, a process can communicate with another process over the network.

In order to create a socket, use the socket.socket() that is available in the socket module. The general syntax of a socket function is as follows:

s = socket.socket (socket_family, socket_type, protocol=0)

Here is the description of the parameters:

socket_family: socket.AF_INET, PF_PACKET

AF_INET is the address family for IPv4. PF_PACKET operates at the device driver layer. The pcap library for Linux uses PF_PACKET. You will see more details on PF_PACKET in Chapter 3, Sniffing and Penetration Testing. These arguments represent the address families and the protocol of the transport layer:

Socket_type : socket.SOCK_DGRAM, socket.SOCK_RAW,socket.SOCK_STREAM

The socket.SOCK_DGRAM argument depicts that UDP is unreliable and connectionless, and socket.SOCK_STREAM depicts that TCP is reliable and a two-way, connection-based service. We will discuss socket.SOCK_RAW in Chapter 3, Sniffing and Penetration Testing:

protocol

Generally, we leave this argument; it takes 0 if it's not specified. We will see the use of this argument in Chapter 3, Sniffing and Penetration Testing.

Server socket methods

In a client-server architecture, there is one centralized server that provides service, and many clients request and receive service from the centralized server. Here are some methods you need to know:

  • socket.bind(address): This method is used to connect the address (IP address, port number) to the socket. The socket must be open before connecting to the address.
  • socket.listen(q): This method starts the TCP listener. The q argument defines the maximum number of lined-up connections.
  • socket.accept(): The use of this method is to accept the connection from the client. Before using this method, the socket.bind(address) and socket.listen(q) methods must be used. The socket.accept() method returns two values, client_socket and address, where client_socket is a new socket object used to send and receive data over the connection, and address is the address of the client. You will see examples of this later.

Client socket methods

The only method dedicated to the client is the following:

  • socket.connect(address): This method connects the client to the server. The address argument is the address of the server.

General socket methods

The general socket methods are as follows:

  • socket.recv(bufsize): This method receives a TCP message from the socket. The bufsize argument defines the maximum data it can receive at any one time.
  • socket.recvfrom(bufsize): This method receives data from the socket. The method returns a pair of values, the first value gives the received data, and the second value gives the address of the socket sending the data.
  • socket.recv_into(buffer): This method receives data less than or equal to buffer. The buffer parameter is created by the bytearray() method. We will discuss this in an example later.
  • socket.recvfrom_into(buffer): This method obtains data from the socket and writes it into the buffer. The return value is a pair (nbytes, address), where nbytes is the number of bytes received, and the address is the address of the socket sending the data.
Be careful while using the socket.recv from_into(buffer) method in older versions of Python. Buffer overflow vulnerability has been found in this method. The name of this vulnerability is CVE-2014-1912, and its vulnerability was published on February 27, 2014. Buffer overflow in the socket.recvfrom_into function in Modules/socketmodule.c in Python 2.5 before 2.7.7, 3.x before 3.3.4, and 3.4.x before 3.4rc1, allows remote attackers to execute arbitrary code via a crafted string.
  • socket.send(bytes): This method is used to send data to the socket. Before sending the data, ensure that the socket is connected to a remote machine. It returns the number of bytes sent.
  • socket.sendto(data, address): This method is used to send data to the socket. Generally, we use this method in UDP. UDP is a connectionless protocol; therefore, the socket should not be connected to a remote machine, and the address argument specifies the address of the remote machine. The returned value tells us the number of bytes sent.
  • socket.sendall(data): As the name implies, this method sends all data to the socket. Before sending the data, ensure that the socket is connected to a remote machine. This method ceaselessly transfers data until an error is seen. If an error is seen, an exception will rise, and socket.close() will close the socket.

Now, it is time for the practical; no more mundane theory.

Moving on to the practical

First, we will make a server-side program that offers a connection to the client and sends a message to the client. Run server1.py:

import socket
host = "192.168.0.1" #Server address
port = 12345  #Port of Server
s = socket.socket(socket.AF_INET, socket.SOCK_STREAM)
s.bind((host,port)) #bind server 
s.listen(2) 
conn, addr = s.accept()  
print addr, "Now Connected"
conn.send("Thank you for connecting")
conn.close()

The preceding code is very simple; it is minimal code on the server side.

First, import the socket module and define the host and port number, 192.168.0.1 is the server's IP address. Socket.AF_INET defines the IPv4 protocol's family. Socket.SOCK_STREAM defines the TCP connection. The s.bind((host,port)) statement takes only one argument. It binds the socket to the host and port number. The s.listen(2) statement listens to the connection and waits for the client. The conn, addr = s.accept() statement returns two values: conn and addr. The conn socket is the client socket, as we discussed earlier. The conn.send() function sends the message to the client. Finally, conn.close() closes the socket. From the following examples and screenshot, you will understand conn better.

This is the output of the server1.py program:

  G:PythonNetworking>python server1.py

Now, the server is in the listening mode and is waiting for the client.

Let's see the client-side code. Run client1.py:

import socket
s = socket.socket(socket.AF_INET, socket.SOCK_STREAM)
host = "192.168.0.1"  # server address
port =12345  #server port 
s.connect((host,port)) 
print s.recv(1024)
s.send("Hello Server")
s.close()

In the preceding code, there are two new methods, s.connect((host,port)), which connects the client to the server, and s.recv(1024), which receives the strings sent by the server.

The output of client.py and the response of the server is shown in the following screenshot:

The preceding screenshot of the output shows that the server accepted the connection from 192.168.0.11. Don't get confused by seeing port 1789; it is the random port of the client. When the server sends a message to the client, it uses the conn socket, as mentioned earlier, and this conn socket contains the client IP address and port number.

The following diagram shows how the client accepts a connection from the server. The server is in listening mode, and the client connects to the server. When you run the server and client program again, the random port gets changed. For the client, the server port, 12345, is the destination port, and for the server, the client random port, 1789, is the destination port:

TCP communication

You can extend the functionality of the server using the while loop, as shown in the following program. Run the server2.py program:

import socket 
host = "192.168.0.1"
port = 12345
s = socket.socket(socket.AF_INET, socket.SOCK_STREAM)
s.bind((host,port))
s.listen(2)
while True:
  conn, addr = s.accept()
  print addr, "Now Connected"
  conn.send("Thank you for connecting")
  conn.close()

The preceding code is the same as the previous one, except the infinite while loop has been added.

Run the server2.py program, and from the client, run client1.py.

The output of server2.py is shown here:

One server can give service to many clients. The while loop keeps the server program alive and does not allow the code to end. You can set a connection limit to the while loop; for example, set while i>10 and increment i with each connection.

Before proceeding to the next example, the concept of bytearray should be understood. The bytearray array is a mutable sequence of unsigned integers in the range of 0 to 255. You can delete, insert, or replace arbitrary values or slices. The bytearray array's objects can be created by calling the built-in bytearray array.

The general syntax of bytearray is as follows:

bytearray([source[, encoding[, errors]]])

Let's illustrate this with an example:

>>> m = bytearray("Mohit Mohit")
>>> m[1]
111
>>> m[0]
77
>>> m[:5]= "Hello"
>>> m
bytearray(b'Hello Mohit')
>>>

This is an example of slicing the bytearray.

Now, let's look at the split operation on bytearray():

>>> m = bytearray("Hello Mohit")
>>> m
bytearray(b'Hello Mohit')
>>> m.split()
[bytearray(b'Hello'), bytearray(b'Mohit')]

The following is the append operation on bytearray():

>>> m.append(33)
>>> m
bytearray(b'Hello Mohit!')
>>> bytearray(b'Hello World!')

The next example is of s.recv_into(buff). In this example, we will use bytearray() to create a buffer to store data.

First, run the server-side code. Run server3.py:

import socket
host = "192.168.0.1"
port = 12345
s = socket.socket(socket.AF_INET, socket.SOCK_STREAM)
s.bind((host, port))
s.listen(1)
conn, addr = s.accept()
print "connected by", addr
conn.send("Thanks")
conn.close()

The preceding program is the same as the previous one. In this program, the server sends Thanks; six characters.

Let's run the client-side program. Run client3.py:

import socket
host = "192.168.0.1"
port = 12345
s = socket.socket(socket.AF_INET, socket.SOCK_STREAM)
s.connect((host, port))
buf = bytearray("-" * 30) # buffer created
print "Number of Bytes ",s.recv_into(buf) 
print buf
s.close

In the preceding program, a buf parameter is created using bytearray(). The s.recv_into(buf) statement gives us the number of bytes received. The buf parameter gives us the string received.

The output of client3.py and server3.py is shown in the following screenshot:

Our client program successfully received 6 bytes of the string, Thanks. You must have an idea of bytearray() by now. I hope you will remember it.

This time, I will create a UDP socket.

Run udp1.py, and we will discuss the code line by line:

import socket
host = "192.168.0.1"
port = 12346
s = socket.socket(socket.AF_INET, socket.SOCK_DGRAM)
s.bind((host,port))
data, addr = s.recvfrom(1024)
print "received from ",addr
print "obtained ", data
s.close()

socket.SOCK_DGRAM creates a UDP socket, and data, addr = s.recvfrom(1024) returns two things, the first is the data and the second is the address of the source.

Now, see the client-side preparations. Run udp2.py:

import socket
host = "192.168.0.1"
port = 12346
s = socket.socket(socket.AF_INET, socket.SOCK_DGRAM)
print s.sendto("hello all",(host,port))
s.close()

Here, I used the UDP socket and the s.sendto() method, as you can see in the definition of socket.sendto(). You will know that UDP is a connectionless protocol, so there is no need to establish a connection here.

The following screenshot shows the output of udp1.py (the UDP server) and udp2.py (the UDP client):

The server program successfully received data.

Let's assume that a server is running and that there is no client start connection, and that the server will have been listening. So, to avoid this situation, use socket.settimeout(value).

Generally, we give a value as an integer; if I give 5 as the value, this would mean wait for five seconds. If the operation doesn't complete within five seconds, then a timeout exception would be raised. You can also provide a non-negative float value.

For example, let's look at the following code:

import socket
host = "192.168.0.1"
port = 12346
s = socket.socket(socket.AF_INET, socket.SOCK_DGRAM)
s.bind((host,port))
s.settimeout(5)
data, addr = s.recvfrom(1024)
print "recevied from ",addr
print "obtained ", data
s.close()

I added one extra line, that is, s.settimeout(5). The program waits for five seconds; only after that will it give us an error message. Run udptime1.py.

The output is shown in the following screenshot:

The program shows an error; however, it does not look good if it gives an error message. The program should handle the exceptions.

Socket exceptions

In order to handle exceptions, we'll use the try and except blocks. The following example will tell you how to handle the exceptions. Run udptime2.py:

import socket
host = "192.168.0.1"
port = 12346
s = socket.socket(socket.AF_INET, socket.SOCK_DGRAM)
try:
  
  s.bind((host,port))
  s.settimeout(5)
  data, addr = s.recvfrom(1024)
  print "recevied from ",addr
  print "obtained ", data
  s.close()
  
except socket.timeout :
  print "Client not connected"
  s.close()

The output is shown in the following screenshot:

In the try block, I put my code, and from the except block, a customized message is printed if any exception occurs.

Different types of exceptions are defined in Python's socket library for different errors. These exceptions are described here:

  • exception socket.herror: This block catches the address-related error.
  • exception socket.timeout: This block catches the exception when a timeout on a socket occurs, which has been enabled by settimeout(). In the previous example, you can see that we used socket.timeout.
  • exception socket.gaierror: This block catches any exception that is raised due to getaddrinfo() and getnameinfo().
  • exception socket.error: This block catches any socket-related errors. If you are not sure about any exception, you could use this. In other words, you can say that it is a generic block and can catch any type of exception.

Downloading the example code

You can download the example code files from your account at http://www.packtpub.com for all of the Packt Publishing books you have purchased. If you purchased this book elsewhere, you can visit http://www.packtpub.com/support and register to have the files emailed directly to you.

Useful socket methods

So far, you have gained knowledge of socket and client-server architecture. At this level, you can make a small program of networks. However, the aim of this book is to test the network and gather information. Python offers very beautiful as well as useful methods to gather information. First, import the socket and then use these methods:

  • socket.gethostbyname(hostname): This method converts a hostname to the IPv4 address format. The IPv4 address is returned in the form of a string. Here is an example:
       >>> import socket>>>   
socket.gethostbyname('thapar.edu')'220.227.15.55'>>>>>>
socket.gethostbyname('google.com')'173.194.126.64'>>>

I know you are thinking about the nslookup command. Later, you will see more magic.

  • socket.gethostbyname_ex(name): This method converts a hostname to the IPv4 address pattern. However, the advantage over the previous method is that it gives all the IP addresses of the domain name. It returns a tuple (hostname, canonical name, and IP_addrlist) where the hostname is given by us, the canonical name is a (possibly empty) list of canonical hostnames of the server for the same address, and IP_addrlist is a list of all of the available IP addresses of the same hostname. Often, one domain name is hosted on many IP addresses to balance the load of the server. Unfortunately, this method does not work for IPv6. I hope you are well-acquainted with tuples, lists, and dictionaries. Let's look at an example:
       >>> socket.gethostbyname_ex('thapar.edu')('thapar.edu', [],  
['14.139.242.100', '220.227.15.55'])>>>
socket.gethostbyname_ex('google.com')>>>('google.com', [],
['173.194.36.64', '173.194.36.71', '173.194.36.73',
'173.194.36.70',
'173.194.36.78', '173.194.36.66', '173.194.36.65',
'173.194.36.68',
'173.194.36.69', '173.194.36.72', '173.194.36.67'])>>>

It returns many IP addresses for a single domain name. This means that one domain such as thapar.edu or google.com runs on multiple IPs.

  • socket.gethostname(): This returns the hostname of the system where the Python interpreter is currently running:
      >>> socket.gethostname()'eXtreme'

To glean the current machine's IP address by using the socket module, you can use the following trick using gethostbyname(gethostname()):

      >>> socket.gethostbyname(socket.gethostname())'192.168.10.1'>>>

You know that our computer has many interfaces. If you want to know the IP address of all of the interfaces, use the extended interface:.

      >>> socket.gethostbyname_ex(socket.gethostname())('eXtreme', [],   
['10.0.0.10', '192.168.10.1', '192.168.0.1'])>>>

It returns one tuple containing three elements, the first is the machine name, the second is a list of aliases for the hostname (empty, in this case,) and the third is the list of the IP addresses of interfaces.

  • socket.getfqdn([name]): This is used to find the fully qualified domain name if it's available. The fully qualified domain name consists of a host and domain name; for example, beta might be the hostname, and example.com might be the domain name. The fully qualified domain name (FQDN) becomes beta.example.com:
      >>> socket.getfqdn('facebook.com')'edge-star-shv-12-   
frc3.facebook.com'

In the preceding example, edge-star-shv-12-frc3 is the hostname, and facebook.com is the domain name. In the following example, FQDN is not available for thapar.edu:

      >>> socket.getfqdn('thapar.edu')'thapar.edu'

If the name argument is blank, it returns the current machine name:

      >>> socket.getfqdn()'eXtreme'>>>
  • socket.gethostbyaddr(ip_address): This is like a reverse lookup for the name. It returns a tuple (hostname, canonical name, and IP_addrlist) where hostname is the hostname that responds to the given ip_address, the canonical name is a (possibly empty) list of canonical names of the same address, and IP_addrlist is a list of IP addresses for the same network interface on the same host:
      >>> socket.gethostbyaddr('173.194.36.71')('del01s06-in-
f7.1e100.net', [], ['173.194.36.71'])>>>
socket.gethostbyaddr('119.18.50.66')Traceback (most recent call
last): File "<pyshell#9>", line 1, in <module>
socket.gethostbyaddr('119.18.50.66')herror: [Errno 11004] host
not found

It shows an error in the last query because reverse DNS lookup is not present.

  • socket.getservbyname(servicename[, protocol_name]): This converts any protocol name to the corresponding port number. The Protocol name is optional, either TCP or UDP. For example, the DNS service uses TCP as well as UDP connections. If the protocol name is not given, any protocol could match:
      >>> import socket>>> socket.getservbyname('http')80>>>   
socket.getservbyname('smtp','tcp')25>>>
  • socket.getservbyport(port[, protocol_name]): This converts an internet port number to the corresponding service name. The protocol name is optional, either TCP or UDP:
      >>> socket.getservbyport(80)'http'>>>    
socket.getservbyport(23)'telnet'>>>
socket.getservbyport(445)'microsoft-ds'>>>
  • socket.connect_ex(address): This method returns an error indicator. If successful, it returns 0; otherwise, it returns the errno variable. You can take advantage of this function to scan the ports. Run the connect_ex.py program:
      import socket
      rmip ='127.0.0.1'
      portlist = [22,23,80,912,135,445,20]

      for port in portlist:
      sock= socket.socket(socket.AF_INET,socket.SOCK_STREAM)
      result = sock.connect_ex((rmip,port))
      print port,":", result
      sock.close()

The output is shown in the following screenshot:

The preceding program output shows that ports 80 ,912 ,135 , and 445 are open. This is a rudimentary port scanner. The program is using the IP address 127.0.0.1; this is a loopback address, so it is impossible to have any connectivity issues. However, when you have issues, perform this on another device with a large port list. This time, you will have to use socket.settimeout(value):

socket.getaddrinfo(host, port[, family[, socktype[, proto[, flags]]]])

This socket method converts the host and port arguments into a sequence of five tuples.

Let's take a look at the following example:

   >>> import socket
   >>> socket.getaddrinfo('www.thapar.edu', 'http')
   [(2, 1, 0, '', ('220.227.15.47', 80)), (2, 1, 0, '',  
('14.139.242.100', 80))]
>>>

Output 2 represents the family, 1 represents the socket type, 0 represents the protocol, '' represents the canonical name, and ('220.227.15.47', 80) represents the 2 socket address. However, this number is difficult to comprehend. Open the directory of the socket.

Use the following code to find the result in a readable form:

import socket
def get_protnumber(prefix):
  return dict( (getattr(socket, a), a)
    for a in dir(socket)
      if a.startswith(prefix))

proto_fam = get_protnumber('AF_')
types = get_protnumber('SOCK_')
protocols = get_protnumber('IPPROTO_')

for res in socket.getaddrinfo('www.thapar.edu', 'http'):

  family, socktype, proto, canonname, sockaddr = res

  print 'Family        :', proto_fam[family]
  print 'Type          :', types[socktype]
  print 'Protocol      :', protocols[proto]
  print 'Canonical name:', canonname
  print 'Socket address:', sockaddr

The output of the code is shown in the following screenshot:

The upper part makes a dictionary using the AF_, SOCK_, and IPPROTO_ prefixes that map the protocol number to their names. This dictionary is formed by the list comprehension technique.

The upper part of the code might be confusing sometimes, but we can execute the code separately as follows:

  >>> dict(( getattr(socket,n),n) for n in dir(socket) if 
n.startswith('AF_'))
{0: 'AF_UNSPEC', 2: 'AF_INET', 6: 'AF_IPX', 11: 'AF_SNA', 12:
'AF_DECnet', 16: 'AF_APPLETALK', 23: 'AF_INET6', 26: 'AF_IRDA'}

Now, this is easy to understand. This code is usually used to get the protocol number:

for res in socket.getaddrinfo('www.thapar.edu', 'http'):

The preceding line of code returns the five values, as discussed in the definition. These values are then matched with their corresponding dictionary.

You have been reading a chapter from
Python Penetration Testing Essentials - Second Edition
Published in: May 2018
Publisher:
ISBN-13: 9781789138962
Register for a free Packt account to unlock a world of extra content!
A free Packt account unlocks extra newsletters, articles, discounted offers, and much more. Start advancing your knowledge today.
Unlock this book and the full library FREE for 7 days
Get unlimited access to 7000+ expert-authored eBooks and videos courses covering every tech area you can think of
Renews at $19.99/month. Cancel anytime
Banner background image