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Table Of Contents  The TCP/IP Guide
 9  TCP/IP Lower-Layer (Interface, Internet and Transport) Protocols (OSI Layers 2, 3 and 4)
      9  TCP/IP Transport Layer Protocols
           9  Transmission Control Protocol (TCP) and User Datagram Protocol (UDP)
                9  TCP/IP Transmission Control Protocol (TCP)
                     9  TCP Message Formatting and Data Transfer

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TCP Maximum Segment Size (MSS) and Relationship to IP Datagram Size
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TCP Immediate Data Transfer: "Push" Function
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TCP Sliding Window Data Transfer and Acknowledgement Mechanics
(Page 2 of 6)

Send (SND) Pointers

Both the client and server in the connection must keep track of the stream it is transmitting and the one it is receiving from the other device. This is done using a set of special variables called pointers, that carve the byte stream into the categories above. The four transmit categories are divided using three pointers. Two of the pointers are absolute (refer to a specific sequence number) while one is an offset that is added to one of the absolute pointers, as follows (refer to Figure 219):

  • Send Unacknowledged (SND.UNA): The sequence number of the first byte of data that has been sent but not yet acknowledged. This marks the first byte of Transmit Category #2; all previous sequence numbers refer to bytes in Transmit Category #1.

  • Send Next (SND.NXT): The sequence number of the next byte of data to be sent to the other device (the server in this case). This marks the first byte of Transmit Category #3.

  • Send Window (SND.WND): The size of the send window. Recall that the window specifies the total number of bytes that any device may have “outstanding” (unacknowledged) at any one time. Thus, adding the sequence number of the first unacknowledged byte (SND.UNA) and the send window (SND.WND) marks the first byte of Transmit Category #4.

    Figure 219: TCP Transmission Categories, Send Window and Pointers

    This diagram is the same as Figure 207, but shows the TCP send pointers. SND.UNA points to the start of Transmit Category #2, SND.NXT points to the start of Transmit Category #3, and SND.WND is the size of the send window. The size of the usable window can be calculated as shown from those three pointers.

     


Another way of looking at these pointers is how they indicate the number of bytes a transmitting device can send at any point in time; that is, the number of bytes in Transmit Category #3. The start of Transmit Category #3 is marked by SND.NXT. The end is marked by the first byte of Transmit Category #4, given by SND.UNA+SND.WND. Thus, the number of bytes in Transmit Category #3 is given by the following formula:

SND.UNA + SND.WND - SND.NXT

This is called the usable window, since it indicates how many bytes the transmitter can use at any point in time. When data is acknowledged, this causes bytes to move from Transmit Category #2 to Category #1, by increasing the value of SND.UNA. Assuming that the send window size doesn't change, this causes the window to slide to the right, permitting more data to be sent.

Key Concept: The TCP sliding windows scheme uses three pointers that keep track of which bytes are in each of the four transmit categories. SND.UNA points to the first unacknowledged byte and indicates the start of Transmit Category #2; SND.NXT points to the next byte of data to be sent and marks the start of Transmit Category #3. SND.WND contains the size of the send window; it is added to SND.NXT to mark the start of Transmit Category #4. Adding SND.WND to SND.UNA and then subtracting SND.NXT yields the current size of the usable transmit window.



Previous Topic/Section
TCP Maximum Segment Size (MSS) and Relationship to IP Datagram Size
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3456
Next Page
TCP Immediate Data Transfer: "Push" Function
Next Topic/Section

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