1. 1 Device Controller I/O units typically consist of A mechanical component: the device itself An electronic component: the device controller or adapter. Interface between controller and device is a very low level interface. Example: Disk controller converts the serial bit stream, coming off the drive into a block of bytes, and performs error correction.

2. 2 Input/ Output Problems Wide variety of peripherals Delivering different amounts of data At different speeds In different formats All slower than CPU and RAM External devices are not generally connected directly into the computer bus structure Need I/ O modules Interface to CPU and Memory Interface to one or more peripherals

3. 3 External Devices Human readable Screen, printer, keyboard Machine-readable Monitoring and control Communication Modem Network Interface Card (NIC)

4. 4 I/ O Module Function Control & Timing CPU Communication Device Communication Data Buffering Error Detection

5. 5 I/O Steps CPU checks I/O module device status I/O module returns status If ready, CPU requests data transfer I/O module gets data from device I/O module transfers data to CPU Variations for output, DMA, etc.

6. 6 I/ O Module Decisions Hide or reveal device properties to CPU Support multiple or single device Control device functions or leave for CPU

7. 7 Input Output Techniques Programmed Interrupt driven Direct Memory Access (DMA)

8. 8 Programmed I/O CPU requests I/O operation I/O module performs operation I/O module sets status bits CPU checks status bits periodically I/O module does not inform CPU directly I/O module does not interrupt CPU CPU must wait

9. 9 I/ O Commands CPU issues address Identifies module (& device if >1 per module) CPU issues command Control - telling module what to do e. g. spin up disk Test - check status e. g. power? Error? Read/ Write Module transfers data via buffer from/ to device CPU is in direct control of the operation

10. 10 I/O Addressing To give a command to an I/O device, the processor must be able to address the device and supply commands Two Methods are used to address the device Memory mapped I/O Isolated I/O

11. 11 Memory Mapped I/O Portions of the address space are assigned to I/O devices i.e I/O devices and memory share a single address space Processor treats the status and data registers of I/O module as memory locations Reads and Writes to these locations (Registers) are interpreted as commands to the I/O device

12. 12 Memory-Mapped I/O (1) (a) Separate I/O and memory space (b) Memory-mapped I/O (c) Hybrid

13. 13 Memory-Mapped I/O (2) (a) A single-bus architecture (b) A dual-bus memory architecture

14. 14 CPU Viewpoint Issue read command Do other work Check for interrupt at end of each instruction cycle If interrupted: - Save context (registers) Process interrupt Fetch data & store

15. 15 Isolated I/O If the system bus is equipped with separate memory read and write, and input and output command lines, then Command line specifies whether the address on the bus is related to a memory location or an I/O device Can have as many I/O devices as memory locations Because address space for I/O is isolated from memory, this approach is know as Isolated I/O

16. 16 Programmed I/O: Adv. & Disadv. Advantages of Programmed I/O Simple to implement Requires very little special software or hardware Disadvantages: Speed difference between CPU and the peripheral devices -- orders of magnitude: programmed I/O wastes an enormous amount of CPU cycles Very inefficient CPU slowed to the speed of the peripheral

17. 17 Interrupt Driven I/O Basic Operation CPU issues read command I/O module gets data from peripheral whilst CPU does other work I/O module interrupts CPU CPU requests data I/O module transfers data

18. 18 Interrupts Connections between devices and interrupt controller actually use interrupt lines on the bus rather than dedicated wires

19. 19 Host-controller interface: Interrupts CPU hardware has the interrupt report line that the CPU senses after executing every instruction device raises an interrupt CPU catches the interrupt and saves the state (e.g., Instruction pointer) CPU dispatches the interrupt handler interrupt handler determines cause, services the device and clears the interrupt Why interrupts? Real life analogy for interrupt An alarm sets off when the food/laundry is ready So you can do other things in between

20. 20 Support for Interrupts Need the ability to defer interrupt handling during critical processing Need efficient way to dispatch the proper device Interrupt comes with an address (offset in interrupt vector) that selects a specific interrupt handling Need multilevel interrupts - interrupt priority level

21. 21 Interrupt Handler At boot time, OS probes the hardware buses to determine what devices are present install corresponding interrupt handlers into the interrupt vector During I/O interrupt, controller signals that device is ready

22. 22 Direct Memory Access Interrupt driven and programmed I/ O require active CPU intervention Transfer rate is limited CPU is tied up DMA is the answer DMA takes the CPU out of the I/ O task except for initialization Large amounts of data can be transferred between memory and the peripheral without severely impacting CPU performance

23. 23 Function and Operation DMA Function Additional Module (hardware) on bus DMA controller takes over from CPU for I/ O DMA Operation CPU tells DMA controller: - Read/ Write Device address Starting address of memory block for data Amount of data to be transferred CPU carries on with other work DMA controller deals with transfer DMA controller sends interrupt when finished

24. 24 DMA Transfer - Cycle Stealing DMA controller takes over bus for a cycle Transfer of one word of data Not an interrupt CPU does not switch context CPU suspended just before it accesses bus i. e. before an operand or data fetch or a data write Slows down CPU but not as much as CPU doing transfer

25. 25 DMA Configurations (1) Single Bus, Detached DMA controller Each transfer uses bus twice I/O to DMA then DMA to memory CPU is suspended twice CPU DMA Controller I/O Device I/O Device Main Memory

26. 26 DMA Configurations (2) Single Bus, Integrated DMA controller Controller may support >1 device Each transfer uses bus once DMA to memory CPU is suspended once CPU DMA Controller I/O Device I/O Device Main Memory DMA Controller I/O Device

27. 27 DMA Configurations (3) Separate I/O Bus Bus supports all DMA enabled devices Each transfer uses bus once DMA to memory CPU is suspended once CPU DMA Controller I/O Device I/O Device Main Memory I/O Device I/O Device

28. 28 Direct Memory Access (DMA) Direct memory access (DMA) Assists in exchange of data between CPU and I/O controller CPU can request data from I/O controller byte by byte – but this might be inefficient (e.g. for disk data transfer) Uses a special purpose processor, called a DMA controller

29. 29 DMA-CPU Protocol Use disk DMA as an example CPU programs DMA controller, sets registers to specify source/destination addresses, byte count and control information (e.g., read/write) and goes on with other work DMA controller proceeds to operate the memory bus directly without help of main CPU – request from I/O controller to move data to memory Disk controller transfers data to main memory Disk controller acks transfer to DMA controller

30. 30 Direct Memory Access (DMA) Operation of a DMA transfer

31. 31 DMA Issues Handshaking between DMA controller and the device controller Cycle stealing DMA controller takes away CPU cycles when it uses CPU memory bus, hence blocks the CPU from accessing the memory In general DMA controller improves the total system performance

32. 32 Discussion Tradeoffs between Programmed I/O Interrupt-driven I/O I/O using DMA Which one is the fastest for a single I/O request? Which one gives the highest throughput?

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