# 2D Array in MIPS

I've searched online and on this site and I can not find a good example of implementing a 2D Array in MIPS. I would like to be able to see an example of how to go through the array in order to place data at a specific index and how to print the array out like shown below.

Such as a 5x5 array where \$ would be the data in each index.

``````  a b c d e
1 \$ \$ \$ \$ \$
2 \$ \$ \$ \$ \$
3 \$ \$ \$ \$ \$
4 \$ \$ \$ \$ \$
5 \$ \$ \$ \$ \$
``````

You can set up a 2D array in terms of a 1D array. You just need to correctly map elements from the 1D array to the 2D array. This site has pictures:

http://www.plantation-productions.com/Webster/www.artofasm.com/Windows/HTML/Arraysa2.html#1010609

You can use a standard format for addressing each cell. For example:

``````      a  b  c  d  e

1     0  1  2  3  4
2     5  6  7  8  9
3    10 11 12 13 14
4    15 16 17 18 19
5    20 21 22 23 24
``````

You should be able to see the pattern :) In general, if there are M columns and N rows, the cell at row i, column j (zero-indexed) can be accessed at point i * M + j - 1

• Normally id draw something out but was feeling lazy :/ – Foo Bah Feb 2 '11 at 23:44
• using the mapping in my revised response, you can access an arbitrary point in the 2D array by using the standard array access techniques – Foo Bah Feb 3 '11 at 0:09

All you need to know about 2 Dimensional arrays:

1. Allocate
2. Implement nested loops

To allocate you you need to calculate ( #row X #column ) X #byte needed

regarding number of bytes you need 1 for char, 4 integer, 4 single precision float, 8 for double precision float. For example:

To dynamically allocate array of 150 double precision elements such that 15 rows and 10 column :

``````li  \$t1,15
li  \$t2,10
mul \$a0, \$t1, \$t2
sll \$a0, \$a0, 3   # multiply number of elements by 2^3 = 8
# because each double precision floating point number takes 8 bytes
li  \$v0, 9
syscall
move \$s0,\$v0   # save array address in \$s0
``````

To get address of index (3,4) :

• Row major : 8 X (10 X 3 + 4) = 272 , then add it to the base address
• Column major : 8 X (15 X 4 + 3) = 504, then add it to the base address

Side note: I used shift left logical instead of multiply because shifting (`sll`) in MIPS takes 1 clock cycle but `mul` instruction takes 33 clock cycles. Thus, improving efficiency of the code.

Update / Edit (it has been over 3 years past since I wrote this answer, so I will improve my answer):

The pseudo-code to iterate through 2 dimensional matrix of integers (not doubles) in row-major format is the following:

``````for (int i = 0; i < array height; i++) {
for (int j = 0; j < array width; j++) {

prompt and read array value

row index = i
column index = j

memory[array base address + 4 * (array width * row index + column index)] = array value
}
}
``````

However, pseudo-code to iterate through 2 dimensional matrix of integers (not doubles) in column-major format is the following:

``````for (int i = 0; i < array height; i++) {
for (int j = 0; j < array width; j++) {

prompt and read array value

row index = i
column index = j

memory[array base address + 4 * (array height * column index + row index)] = array value
}
}
``````

Note: As we can see, the structure of the loop stays the same but the address calculation part has been slightly changed. Now implementing the above pseudo-codes are straightforward. We need 2 nested loops. Assuming:

``````\$t0 <-- base address of array (or matrix or 2 dimensional array)
\$t1 <-- height of matrix
\$t2 <-- width of matrix
i <---- row index
j <---- column index
``````

Implementation of reading values into row-major matrix:

``````        .data
read_row_matrix_prompt_p:   .asciiz "Enter an integer: "
###########################################################

.text
li \$t3, 0               # initialize outer-loop counter to 0

bge \$t3, \$t1, read_row_matrix_loop_outer_end

li \$t4, 0               # initialize inner-loop counter to 0

bge \$t4, \$t2, read_row_matrix_loop_inner_end

mul \$t5, \$t3, \$t2       # \$t5 <-- width * i
add \$t5, \$t5, \$t4       # \$t5 <-- width * i + j
sll \$t5, \$t5, 2         # \$t5 <-- 2^2 * (width * i + j)
add \$t5, \$t0, \$t5       # \$t5 <-- base address + (2^2 * (width * i + j))

li \$v0, 4               # prompt for number
syscall

li \$v0, 5               # read a integer number
syscall

sw \$v0, 0(\$t5)          # store input number into array

addiu \$t4, \$t4, 1       # increment inner-loop counter

b read_row_matrix_loop_inner    # branch unconditionally back to beginning of the inner loop

addiu \$t3, \$t3, 1       # increment outer-loop counter

b read_row_matrix_loop_outer    # branch unconditionally back to beginning of the outer loop

``````

Implementation of reading values into column-major matrix:

``````   .data
read_col_matrix_prompt_p:   .asciiz "Enter an integer: "
###########################################################

.text
li \$t3, 0               # initialize outer-loop counter to 0

bge \$t3, \$t1, read_col_matrix_loop_outer_end

li \$t4, 0               # initialize inner-loop counter to 0

bge \$t4, \$t2, read_col_matrix_loop_inner_end

mul \$t5, \$t4, \$t1       # \$t5 <-- height * j
add \$t5, \$t5, \$t3       # \$t5 <-- height * j + i
sll \$t5, \$t5, 2         # \$t5 <-- 2^2 * (height * j + i)
add \$t5, \$t0, \$t5       # \$t5 <-- base address + (2^2 * (height * j + i))

li \$v0, 4               # prompt for number
syscall

li \$v0, 5               # read a integer number
syscall

sw \$v0, 0(\$t5)          # store input number into array

addiu \$t4, \$t4, 1       # increment inner-loop counter

b read_col_matrix_loop_inner    # branch unconditionally back to beginning of the inner loop