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Traffic class 8-bits Payload length 16-bits
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Flow label 20-bits Next header 8-bits Hop limit 8-bits
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Source address 128-bits Destination address 128-bits
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Figure 5-18 IPv6 header
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Unlike IPv4, the IPv6 header is a fixed length of 40 bytes Additional features are added to the IPv6 packet by using extension headers Most IPv6 packets will not have an extension header, but the ones that have been defined are Hop-by-Hop Options header, Destination Options header, Routing header, Fragment header, Authentication header, and Encapsulating Security Payload header The one new field in the IPv6 header is the Flow Label for sequencing packets The major field deleted in IPv6 is the Header Checksum, whose function is performed for the entire packet at the Data Link layer (Layer 2) when the packet is put within a frame
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A significant part of the IPv6 address space, which is defined in RFC 4291, is subdivided into hierarchical routing domains so that a particular address can carry not only its unique identity, but also the hierarchy of routers leading to it To communicate the 128bit or 16-byte address, it is divided into eight 16-bit blocks, each of which is converted into a four-digit hexadecimal (base 16) number separated by colons Leading zeros are dropped, and if an entire block is zero, that zero can be dropped by having a double colon (::) For example, here is an IPv6 address: 2001:DB8::2F3B:2AA:FF:FE28:9C5A
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The Transmission Control Protocol operates at the Transport layer, which handles connections Its purpose is to assure the reliable delivery of information to a specific destination TCP is a connection-oriented service, in contrast with IP, which is connectionless TCP makes the connection with the final destination and maintains contact with the destination to make sure that the information is correctly received Once a connection is established, though, TCP depends on IP to handle the actual transfer And because IP is connectionless, IP depends on TCP to assure delivery The sending and receiving TCPs (the protocols running in each machine) maintain an ongoing, full-duplex (both can be talking at the same time) dialog throughout a transmission to assure a reliable delivery This begins with the sending TCP making sure that the destination is ready to receive information Once an affirmative answer is received, the sending TCP packages a data message into a segment containing a header with control information and the first part of the data This is then sent to IP, and TCP creates the remaining segments while watching for an acknowledgment that the segments have been received If an acknowledgment is not received for a particular segment, it is re-created and handed off This process continues until the final segment is sent and acknowledged, at which point the sender tells the receiver that it s done In the process of transmission, the two Transport layers are constantly talking to make sure that everything is going smoothly
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NOTE Different and sometimes confusing names are used to refer to pieces of data being transferred through a network, depending on where you are in the OSI model and the protocol you are using Using the TCP/IP protocol and Ethernet with the OSI model, as shown in Figure 5-19 at the top, applications create messages to be sent over a network The message is handed down to the Transport level, where TCP divides the message into segments that include a segment header with port addresses The segments are passed down to the Network layer, where IP packages the segments into datagrams with logical IP addresses The datagrams are sent down to the Data Link layer, where Ethernet encapsulates them into a frame with a physical MAC address The frames are passed to the Physical layer, which sends them over the network to the physical address, where the reverse process takes place Alternatively, in the Transport and Network layers, a piece of information is generically called a packet of information The communication between the sending and receiving TCPs takes place in the segment header, which is shown in Figure 5-20 and explained in the following field list The two protocols use the sequence number, the acknowledgment number, codes,
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