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CPU Chips and Pinouts

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Intel Chipset 875P. Pentium II Bus Layout. Old and New Layouts. Bus Trends ... Hence the idea of a chipset. Bus only allows one signaler at a time ... – PowerPoint PPT presentation

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Title: CPU Chips and Pinouts


1
CPU Chips and Pinouts
  • A CPU is a VLSI chip
  • All chips have some pinout as its interface
  • CPU pins typically grouped by function
  • data
  • bus control and arbitration
  • coprocessor coordination
  • status and snooping

2
Generic CPU Pinout
3
The Bus
  • Its just a bunch of wires
  • Perhaps the second most important component in
    the whole system
  • Motherboards not just built around CPU
  • CPUs come with buddies called chipsets

4
A Really Simple Bus Layout
5
A Simple Bus Layout
6
Intel Chipset 875P
7
Pentium II Bus Layout
8
Old and New Layouts
9
Bus Trends
  • Typically multiple buses in one system
  • Trend is to create appropriate layers
  • Each layer coordinates components with similar
    speed
  • Then next problem is how to coordinate multiple
    components

10
Bus Arbitration
  • Sometimes CPU chip contains arbitration
  • Other times a separate chip handles this
  • Hence the idea of a chipset
  • Bus only allows one signaler at a time
  • Key arbitration mechanism is priority list
  • Highest priority component always wins
  • Smarter buses will prevent starvation

11
Arbitration Example Daisy Chaining
12
Arbitration via Priority Encoder
13
Handling Input/Output
  • I/O is just another bus in the system, but
  • Other issues are also important for I/O
  • data transfers
  • CPU interaction with I/O component
  • Three ways to address these other issues
  • programmed I/O
  • interrupt-driven I/O
  • direct memory access (DMA) p. 103, 385

14
Programmed I/O Example
  • Programmed implies software-driven
  • Step 1 CPU issues request for read operation
  • Step 2
  • device begin read operation
  • CPU begins polling device to see if finished
  • Steps 3 through n
  • device works on and completes read operation
  • CPU periodically checks device status register
  • Steps n1 through nm CPU copies data to RAM

15
Interrupt-Driven I/O Example
  • Interrupt informs CPU of I/O completion
  • CPU has interrupt status register
  • checks status register at end of each instruction
    cycle
  • better than running an instruction to check
    status
  • Step 1 CPU issues request for read operation
  • Step 2 CPU changes tasks I/O device begins read
  • Steps 3 through n device does read operation
  • Steps n1 through nm CPU copies data to RAM

16
Interrupt Vectors
17
Interrupt Masks
  • Chooses which interrupts can be serviced
  • Mask changes based on current situation
  • Mask typically enforced as AND gates to
    enable/disable interrupt signal

18
DMA Example
  • I/O device writes directly to RAM
  • CPU doesnt have to do copy to RAM
  • Step 1 CPU issues request for read operation
  • Step 2 CPU changes tasks I/O device begins read
  • Steps 3 through n device does read operation
  • Steps n1 through nm DMA copies data to RAM

19
DMA Controller
20
Memory-mapped I/O
  • Done using chip select signal of I/O controller
  • I/O chips are typically grouped together
  • Individual chip chosen via chip select signal
  • Memory-mapped I/O controllers are different
  • Grouped with memory chips
  • CPU treats it like a memory chip
  • A memory address may not correspond to RAM
  • Address points to information on an I/O device
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