Subnet Masks

An IP address has two components, the network address and the host address. A subnet mask separates the IP address into the network and host addresses (<network><host>). Subnetting further divides the host part of an IP address into a subnet and host address (<network><subnet><host>) if additional subnetwork is needed. Use the Subnet Calculator to retrieve subnetwork information from IP address and Subnet Mask. It is called a subnet mask because it is used to identify network address of an IP address by perfoming a bitwise AND operation on the netmask.

A Subnet mask is a 32-bit number that masks an IP address, and divides the IP address into network address and host address. Subnet Mask is made by setting network bits to all "1"s and setting host bits to all "0"s. Within a given network, two host addresses are reserved for special purpose, and cannot be assigned to hosts. The "0" address is assigned a network address and "255" is assigned to a broadcast address, and they cannot be assigned to hosts.

Examples of commonly used netmasks for classed networks are 8-bits (Class A), 16-bits (Class B) and 24-bits (Class C), and classless networks are as follows:

Class

Address

# of IP

Netmask (Binary)

Netmask (Decimal)

CIDR

/4

240,435,456

11110000 00000000 00000000 00000000

240.0.0.0

CIDR

/5

134,217,728

11111000 00000000 00000000 00000000

248.0.0.0

CIDR

/6

67,108,864

11111100 00000000 00000000 00000000

252.0.0.0

CIDR

/7

33,554,432

11111110 00000000 00000000 00000000

254.0.0.0

A

/8

16,777,216

11111111 00000000 00000000 00000000

255.0.0.0

CIDR

/9

8,388,608

11111111 10000000 00000000 00000000

255.128.0.0

CIDR

/10

4,194,304

11111111 11000000 00000000 00000000

255.192.0.0

CIDR

/11

2,097,152

11111111 11100000 00000000 00000000

255.224.0.0

CIDR

/12

1,048,576

11111111 11110000 00000000 00000000

255.240.0.0

CIDR

/13

524,288

11111111 11111000 00000000 00000000

255.248.0.0

CIDR

/14

262,144

11111111 11111100 00000000 00000000

255.252.0.0

CIDR

/15

131,072

11111111 11111110 00000000 00000000

255.254.0.0

B

/16

65,534

11111111 11111111 00000000 00000000

255.255.0.0

CIDR

/17

32,768

11111111 11111111 10000000 00000000

255.255.128.0

CIDR

/18

16,384

11111111 11111111 11000000 00000000

255.255.192.0

CIDR

/19

8,192

11111111 11111111 11100000 00000000

255.255.224.0

CIDR

/20

4,096

11111111 11111111 11110000 00000000

255.255.240.0

CIDR

/21

2,048

11111111 11111111 11111000 00000000

255.255.248.0

CIDR

/22

1,024

11111111 11111111 11111100 00000000

255.255.252.0

CIDR

/23

512

11111111 11111111 11111110 00000000

255.255.254.0

C

/24

256

11111111 11111111 11111111 00000000

255.255.255.0

CIDR

/25

128

11111111 11111111 11111111 10000000

255.255.255.128

CIDR

/26

64

11111111 11111111 11111111 11000000

255.255.255.192

CIDR

/27

32

11111111 11111111 11111111 11100000

255.255.255.224

CIDR

/28

16

11111111 11111111 11111111 11110000

255.255.255.240

CIDR

/29

8

11111111 11111111 11111111 11111000

255.255.255.248

CIDR

/30

4

11111111 11111111 11111111 11111100

255.255.255.252


Subnetting an IP network is to separate a big network into smaller multiple networks for reorganization and security purposes. All nodes (hosts) in a subnetwork see all packets transmitted by any node in a network. Performance of a network is adversely affected under heavy traffic load due to collisions and retransmissions.

Applying a subnet mask to an IP address separates network address from host address. The network bits are represented by the 1's in the mask, and the host bits are represented by 0's. Performing a bitwise logical AND operation on the IP address with the subnet mask produces the network address. For example, applying the Class C subnet mask to our IP address 216.3.128.12 produces the following network address:

IP:   1101 1000 . 0000 0011 . 1000 0000 . 0000 1100  (216.003.128.012)

 

Mask: 1111 1111 . 1111 1111 . 1111 1111 . 0000 0000  (255.255.255.000)

     ---------------------------------------------

     1101 1000 . 0000 0011 . 1000 0000 . 0000 0000  (216.003.128.000)


Subnetting Network
Here is another scenario where subnetting is needed. Pretend that a web host with a Class C network needs to divide the network so that parts of the network can be leased to its customers. Let's assume that a host has a network address of 216.3.128.0 (as shown in the example above). Let's say that we're going to divide the network into 2 and dedicate the first half to itself, and the other half to its customers.

  216 .   3 . 128 . (0000 0000)  (1st half assigned to the web host)

 

  216 .   3 . 128 . (1000 0000)  (2nd half assigned to the customers)

The web host will have the subnet mask of 216.3.128.128 (/25). Now, we'll further divide the 2nd half into eight block of 16 IP addresses.

  216 .   3 . 128 . (1000 0000)  Customer 1 -- Gets 16 IPs (14 usable)

 

  216 .   3 . 128 . (1001 0000)  Customer 2 -- Gets 16 IPs (14 usable)

 

  216 .   3 . 128 . (1010 0000)  Customer 3 -- Gets 16 IPs (14 usable)

 

  216 .   3 . 128 . (1011 0000)  Customer 4 -- Gets 16 IPs (14 usable)

 

  216 .   3 . 128 . (1100 0000)  Customer 5 -- Gets 16 IPs (14 usable)

 

  216 .   3 . 128 . (1101 0000)  Customer 6 -- Gets 16 IPs (14 usable)

 

  216 .   3 . 128 . (1110 0000)  Customer 7 -- Gets 16 IPs (14 usable)

 

  216 .   3 . 128 . (1111 0000)  Customer 8 -- Gets 16 IPs (14 usable)

255 . 255 . 255 . (1111 0000)  (Subnet mask of 255.255.255.240)

You may use Subnet Calculator to ease your calculation.

CIDR - Classless Inter Domain Routing
C
lassless InterDomain Routing (CIDR) was invented to keep the Internet from running out of IP Addresses. The IPv4, a 32-bit, addresses have a limit of 4,294,967,296 (232) unique IP addresses. The classful address scheme (Class A, B and C) of allocating IP addresses in 8-bit increments can be very wasteful. With classful addressing scheme, a minimum number of IP addresses allocated to an organization is 256 (Class C). Giving 256 IP addresses to an organization only requiring 15 IP addresses is wasteful. Also, an organization requiring more than 256 IP addresses (let's say 1,000 IP addresses) is assigned a Class B, which allocates 65,536 IP addresses. Similarly, an organization requiring more than 65,636 (65,634 usable IPs) is assigned a Class A network, which allocates 16,777,216 (16.7 Million) IP addresses. This type of address allocation is very wasteful.

With CIDR, a network of IP addresses is allocated in 1-bit increments as opposed to 8-bits in classful network. The use of a CIDR notated address can easily represent classful addresses (Class A = /8, Class B = /16, and Class C = /24). The number next to the slash (i.e. /8) represents the number of bits assigned to the network address. The example shown above can be illustrated with CIDR as follows:

  216.3.128.12, with subnet mask of 255.255.255.128 is written as

  216.3.128.12/25

  Similarly, the 8 customers with the block of 16 IP addresses can be

  written as:

 

  216.3.128.129/28, 216.3.128.130/28, and etc.

With an introduction of CIDR addressing scheme, IP addresses are more efficiently allocated to ISPs and customers; and hence there is less risk of IP addresses running out anytime soon. For detailed specification on CIDR, please review RFC 1519. With introduction of additional gaming, medical, applicance and telecom devices requiring static IP addresses in addition to more than 6.5 billion (July 2006 est.) world population, the IPv4 addresses with CIDR addressing scheme will eventually run out. To solve shortage of IPv4 addresses, the IPv6 (128-bit) address scheme was introduced in 1993.