Chapter One Introduction to Pipelined Processors

1. Chapter One Introduction to Pipelined Processors

2. Principle of Designing Pipeline Processors (Design Problems of Pipeline Processors)

3. Instruction Prefetch and Branch Handling • The instructions in computer programs can be classified into 4 types: • Arithmetic/Load Operations (60%) • Store Type Instructions (15%) • Branch Type Instructions (5%) • Conditional Branch Type (Yes – 12% and No – 8%)

4. Instruction Prefetch and Branch Handling • Arithmetic/Load Operations (60%) : • These operations require one or two operand fetches. • The execution of different operations requires a different number of pipeline cycles

5. Instruction Prefetch and Branch Handling • Store Type Instructions (15%) : • It requires a memory access to store the data. • Branch Type Instructions (5%) : • It corresponds to an unconditional jump.

6. Instruction Prefetch and Branch Handling • Conditional Branch Type (Yes – 12% and No – 8%) : • Yes path requires the calculation of the new address • No path proceeds to next sequential instruction.

7. Instruction Prefetch and Branch Handling • Arithmetic-load and store instructions do not alter the execution order of the program. • Branch instructions and Interrupts cause some damaging effects on the performance of pipeline computers.

8. Interrupts • When instruction I is being executed,the occurrence of an interrupt postpones instruction I+1 until ISR is serviced. • There are two types of interrupt: • Precise : caused by illegal operation codes and can be detected at decoding stage • Imprecise: caused by defaults from storage, address and execution functions

9. Handling Interrupts • Precise: Since decoding is the first stage, instruction I prohibits I+1 from entering the pipeline and all preceding instructions are executed before ISR • Imprecise : No new instructions are allowed and all incomplete instructions whether they precede or follow are executed before ISR.

10. Handling Example – Interrupt System of Cray1

11. Cray-1 System • The interrupt system is built around an exchange package. • When an interrupt occurs, the Cray-1 saves 8 scalar registers, 8 address registers, program counter and monitor flags. • These are packed into 16 words and swapped with a block whose address is specified by a hardware exchange address register • Since exchange package does not have all state information, software interrupt handler have to store remaining states

12. Instruction Prefetch and Branch Handling • In general, the higher the percentage of branch type instructions in a program, the slower a program will run on a pipeline processor.

13. Effect of Branching on Pipeline Performance • Consider a linear pipeline of 5 stages Fetch Instruction Store Results Fetch Operands Execute Decode

14. Overlapped Execution of Instruction without branching I1 I2 I3 I4 I5 I6 I7 I8

15. I5 is a branch instruction I1 I2 I3 I4 I5 I6 I7 I8

16. Estimation of the effect of branching on an n-segment instruction pipeline

17. Estimation of the effect of branching • Consider an instruction cycle with n pipeline clock periods. • Let • p – probability of conditional branch (20%) • q – probability that a branch is successful (60% of 20%) (12/20=0.6)

18. Estimation of the effect of branching • Suppose there are m instructions • Then no. of instructions of successful branches = mxpxq (mx0.2x0.6) • Delay of (n-1)/n is required for each successful branch to flush pipeline.

19. Estimation of the effect of branching • Thus, the total instruction cycle required for m instructions =

20. Estimation of the effect of branching • As m becomes large , the average no. of instructions per instruction cycle is given as = ?

21. Estimation of the effect of branching • As m becomes large , the average no. of instructions per instruction cycle is given as

22. Estimation of the effect of branching • When p =0, the above measure reduces to n, which is ideal. • In reality, it is always less than n.

23. Solution = ?

24. Multiple Prefetch Buffers • Buffers can be used to match the instruction fetch rate to pipeline consumption rate • Sequential Buffers: for in-sequence pipelining • Target Buffers: instructions from a branch target (for out-of-sequence pipelining)

25. Multiple Prefetch Buffers • A conditional branch cause both sequential and target to fill and based on condition one is selected and other is discarded

26. Data Buffering and Busing Structures

27. Speeding up of pipeline segments • The processing speed of pipeline segments are usually unequal. • Consider the example given below: S1 S2 S3 T1 T2 T3

28. Speeding up of pipeline segments • If T1 = T3 = T and T2 = 3T, S2 becomes the bottleneck and we need to remove it • How? • One method is to subdivide the bottleneck • Two divisions possible are:

29. Speeding up of pipeline segments • First Method: S1 S3 T T 2T T

30. Speeding up of pipeline segments • First Method: S1 S3 T T 2T T

31. Speeding up of pipeline segments • Second Method: S1 S3 T T T T T

32. Speeding up of pipeline segments • If the bottleneck is not sub-divisible, we can duplicate S2 in parallel S2 3T S1 S2 S3 3T T T S2 3T

33. Speeding up of pipeline segments • Control and Synchronization is more complex in parallel segments

34. Data Buffering • Instruction and data buffering provides a continuous flow to pipeline units • Example: 4X TI ASC

35. Example: 4X TI ASC • In this system it uses a memory buffer unit (MBU) which • Supply arithmetic unit with a continuous stream of operands • Store results in memory • The MBU has three double buffers X, Y and Z (one octet per buffer) • X,Y for input and Z for output

36. Example: 4X TI ASC • This provides pipeline processing at high rate and alleviate bandwidth mismatch problem between memory and arithmetic pipeline

37. Busing Structures • PBLM: Ideally subfunctions in pipeline should be independent, else the pipeline must be halted till dependency is removed. • SOLN: An efficient internal busing structure. • Example : TI ASC

38. Example : TI ASC • In TI ASC, once instruction dependency is recognized, update capability is incorporated by transferring contents of Z buffer to X or Y buffer.