--- language: "MIPS Assembly" filename: MIPS.asm contributors: - ["Stanley Lim", "https://github.com/Spiderpig86"] --- The MIPS (Microprocessor without Interlocked Pipeline Stages) Assembly language is designed to work with the MIPS microprocessor paradigm designed by J. L. Hennessy in 1981. These RISC processors are used in embedded systems such as gateways and routers. [Read More](https://en.wikipedia.org/wiki/MIPS_architecture) ```assembly # Comments are denoted with a '#' # Everything that occurs after a '#' will be ignored by the assembler's lexer. # Programs typically contain a .data and .text sections .data # Section where data is stored in memory (allocated in RAM), similar to variables in higher level languages # Declarations follow a ( label: .type value(s) ) form of declaration hello_world .asciiz "Hello World\n" # Declare a null terminated string num1: .word 42 # Integers are referred to as words # (32 bit value) arr1: .word 1, 2, 3, 4, 5 # Array of words arr2: .byte 'a', 'b' # Array of chars (1 byte each) buffer: .space 60 # Allocates space in the RAM # (not cleared to 0) # Datatype sizes _byte: .byte 'a' # 1 byte _halfword: .half 53 # 2 bytes _word: .word 3 # 4 bytes _float: .float 3.14 # 4 bytes _double: .double 7.0 # 8 bytes .align 2 # Memory alignment of data, where # number indicates byte alignment in # powers of 2. (.align 2 represents # word alignment since 2^2 = 4 bytes) .text # Section that contains instructions # and program logic .globl _main # Declares an instruction label as # global, making it accessible to # other files _main: # MIPS programs execute instructions # sequentially, where the code under # this label will be executed firsts # Let's print "hello world" la $a0, hello_world # Load address of string stored in # memory li $v0, 4 # Load the syscall value (indicating # type of functionality) syscall # Perform the specified syscall with # the given argument ($a0) # Registers (used to hold data during program execution) # $t0 - $t9 # Temporary registers used for # intermediate calculations inside # subroutines (not saved across # function calls) # $s0 - $s7 # Saved registers where values are # saved across subroutine calls. # Typically saved in stack # $a0 - $a3 # Argument registers for passing in # arguments for subroutines # $v0 - $v1 # Return registers for returning # values to caller function # Types of load/store instructions la $t0, label # Copy the address of a value in # memory specified by the label into # register $t0 lw $t0, label # Copy a word value from memory lw $t1, 4($s0) # Copy a word value from an address # stored in a register with an offset # of 4 bytes (addr + 4) lb $t2, label # Copy a byte value to the lower order # portion of the register $t2 lb $t2, 0($s0) # Copy a byte value from the source # address in $s0 with offset 0 # Same idea with 'lh' for halfwords sw $t0, label # Store word value into memory address # mapped by label sw $t0, 8($s0) # Store word value into address # specified in $s0 and offset of 8 bytes # Same idea using 'sb' and 'sh' for bytes and halfwords. 'sa' does not exist ### Math ### _math: # Remember to load your values into a register lw $t0, num # From the data section li $t0, 5 # Or from an immediate (constant) li $t1, 6 add $t2, $t0, $t1 # $t2 = $t0 + $t1 sub $t2, $t0, $t1 # $t2 = $t0 - $t1 mul $t2, $t0, $t1 # $t2 = $t0 * $t1 div $t2, $t0, $t1 # $t2 = $t0 / $t1 (Might not be # supported in some versons of MARS) div $t0, $t1 # Performs $t0 / $t1. Get the quotient # using 'mflo' and remainder using 'mfhi' # Bitwise Shifting sll $t0, $t0, 2 # Bitwise shift to the left with # immediate (constant value) of 2 sllv $t0, $t1, $t2 # Shift left by a variable amount in # register srl $t0, $t0, 5 # Bitwise shift to the right (does # not sign preserve, sign-extends with 0) srlv $t0, $t1, $t2 # Shift right by a variable amount in # a register sra $t0, $t0, 7 # Bitwise arithmetic shift to the right # (preserves sign) srav $t0, $t1, $t2 # Shift right by a variable amount # in a register # Bitwise operators and $t0, $t1, $t2 # Bitwise AND andi $t0, $t1, 0xFFF # Bitwise AND with immediate or $t0, $t1, $t2 # Bitwise OR ori $t0, $t1, 0xFFF # Bitwise OR with immediate xor $t0, $t1, $t2 # Bitwise XOR xori $t0, $t1, 0xFFF # Bitwise XOR with immediate nor $t0, $t1, $t2 # Bitwise NOR ## BRANCHING ## _branching: # The basic format of these branching instructions typically follow #