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ID82C37A Datasheet(PDF) 8 Page - Harris Corporation |
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ID82C37A Datasheet(HTML) 8 Page - Harris Corporation |
8 / 23 page 4-199 82C37A S24 state). It should be noted that an external EOP cannot cause the channel 0 Address and Word Count registers to autoinitialize, even if the Mode register is programmed for autoinitialization. An external EOP will autoinitialize the channel 1 registers, if so programmed. Data comparators in block search schemes may use the EOP input to terminate the service when a match is found. The timing of memory-to- memory transfers is found in Figure 13. Memory-to-memory operations can be detected as an active AEN with no DACK outputs. Priority - The 82C37A has two types of priority encoding available as software selectable options. The first is Fixed Priority which fixes the channels in priority order based upon the descending value of their numbers. The channel with the lowest priority is 3 followed by 2, 1 and the highest priority channel, 0. After the recognition of any one channel for ser- vice, the other channels are prevented from interfering with the service until it is completed. The second scheme is Rotating Priority. The last channel to get service becomes the lowest priority channel with the others rotating accordingly. The next lower channel from the channel serviced has highest priority on the following request. Priority rotates every time control of the system busses is returned to the processor. Rotating Priority With Rotating Priority in a single chip DMA system, any device requesting service is guaranteed to be recognized after no more than three higher priority services have occurred. This prevents any one channel from monopolizing the system. Regardless of which priority scheme is chosen, priority is evaluated every time a HLDA is returned to the 82C37A. Compressed Timing - In order to achieve even greater throughput where system characteristics permit, the 82C37A can compress the transfer time to two clock cycles. From Figure 12 it can be seen that state S3 is used to extend the access time of the read pulse. By removing state S3, the read pulse width is made equal to the write pulse width and a transfer consists only of state S2 to change the address and state S4 to perform the read/write. S1 states will still occur when A8-A15 need updating (see Address Generation). Timing for compressed transfers is found in Figure 15. EOP will output in S2 if compressed timing is selected. Compressed timing is not allowed for memory-to- memory transfers. Address Generation - In order to reduce pin count, the 82C37A multiplexes the eight higher order address bits on the data lines. State S1 is used to output the higher order address bits to an external latch from which they may be placed on the address bus. The falling edge of Address Strobe (ADSTB) is used to load these bits from the data lines to the latch. Address Enable (AEN) is used to enable the bits onto the address bus through a three-state enable. The lower order address bits are output by the 82C37A directly. Lines A0-A7 should be connected to the address bus. Figure 12 shows the time relationships between CLK, AEN, ADSTB, DB0-DB7 and A0-A7. During Block and Demand Transfer mode service, which include multiple transfers, the addresses generated will be sequential. For many transfers the data held in the external address latch will remain the same. This data need only change when a carry or borrow from A7 to A8 takes place in the normal sequence of addresses. To save time and speed transfers, the 82C37A executes S1 states only when updating of A8-A15 in the latch is necessary. This means for long services, S1 states and Address Strobes may occur only once every 256 transfers, a savings of 255 clock cycles for each 256 transfers. Programming The 82C37A will accept programming from the host processor anytime that HLDA is inactive, and at least one rising clock edge has occurred after HLDA went low. It is the responsibility of the host to assure that programming and HLDA are mutually exclusive. Note that a problem can occur if a DMA request occurs on an unmasked channel while the 82C37A is being pro- grammed. For instance, the CPU may be starting to repro- gram the two byte Address register of channel 1 when channel 1 receives a DMA request. If the 82C37A is enabled (bit 2 in the Command register is 0), and channel 1 is unmasked, a DMA service will occur after only one byte of the Address register has been reprogrammed. This condi- tion can be avoided by disabling the controller (setting bit 2 in the Command register) or masking the channel before programming any of its registers. Once the programming is complete, the controller can be enabled/unmasked. After power-up it is suggested that all internal locations be loaded with some known value, even if some channels are unused. This will aid in debugging. Register Description Current Address Register - Each channel has a 16-bit Current Address register. This register holds the value of the address used during DMA transfers. The address is auto- matically incremented or decremented by one after each transfer and the values of the address are stored in the Cur- rent Address register during the transfer. This register is writ- ten or read by the microprocessor in successive 8-bit bytes. See Figure 6 for programming information. It may also be reinitialized by an Autoinitialize back to its original value. Autoinitialize takes place only after an EOP. In memory-to- memory mode, the channel 0 Current Address register can be prevented from incrementing or decrementing by setting the address hold bit in the Command register. 1st SERVICE 0 1 2 3 Highest Lowest 2nd SERVICE 2 3 0 1 Service 3rd SERVICE 3 0 1 2 Service Request Service |
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