CS274: Computer Architecture - Recursion in MIPS
Activity Goals
The goals of this activity are:- To properly use recursion and save the stack
- To diagram a call stack trace for a given program
The Activity
Directions
Consider the activity models and answer the questions provided. First reflect on these questions on your own briefly, before discussing and comparing your thoughts with your group. Appoint one member of your group to discuss your findings with the class, and the rest of the group should help that member prepare their response. Answer each question individually from the activity, and compare with your group to prepare for our whole-class discussion. After class, think about the questions in the reflective prompt and respond to those individually in your notebook. Report out on areas of disagreement or items for which you and your group identified alternative approaches. Write down and report out questions you encountered along the way for group discussion.Model 1: A Recursive Algorithm
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| .data | |
| prompt: .asciiz "Input an integer x:\n" | |
| result: .asciiz "Fact(x) = " | |
| .text | |
| main: | |
| # show prompt | |
| li $v0, 4 | |
| la $a0, prompt | |
| syscall | |
| # read x | |
| li $v0, 5 | |
| syscall | |
| # function call | |
| move $a0, $v0 | |
| jal factorial # jump factorial and save position to $ra | |
| move $t0, $v0 # $t0 = $v0 | |
| # show prompt | |
| li $v0, 4 | |
| la $a0, result | |
| syscall | |
| # print the result | |
| li $v0, 1 # system call #1 - print int | |
| move $a0, $t0 # $a0 = $t0 | |
| syscall # execute | |
| # return 0 | |
| li $v0, 10 # $v0 = 10 | |
| syscall | |
| .text | |
| factorial: | |
| # base case -- still in parent's stack segment | |
| # adjust stack pointer to store return address and argument | |
| addi $sp, $sp, -8 | |
| # save $s0 and $ra | |
| sw $s0, 4($sp) | |
| sw $ra, 0($sp) | |
| bne $a0, 0, else | |
| addi $v0, $zero, 1 # return 1 | |
| j fact_return | |
| else: | |
| # backup $a0 | |
| move $s0, $a0 | |
| addi $a0, $a0, -1 # x -= 1 | |
| jal factorial | |
| # when we get here, we already have Fact(x-1) store in $v0 | |
| multu $s0, $v0 # return x*Fact(x-1) | |
| mflo $v0 | |
| fact_return: | |
| lw $s0, 4($sp) | |
| lw $ra, 0($sp) | |
| addi $sp, $sp, 8 | |
| jr $ra |
Questions
- Draw a call stack for a call to
factorial(3). - What registers did
factorialsave to the stack, and why? In particular, why did it savera? - Remove
rafrom the stack and re-run this program. What happens, and why? - How might one implement the Fibonacci sequence?