# lw in MIPS (also a bit C)

I have a homework question and it is troubling me. It goes like

``````sll \$t0, \$s0, 2    // \$t0 = \$s0 << 2;

add \$t1, \$t0, \$s2  // \$t1 = \$t + \$s2;

lw  \$s3, \$0(\$t1)
``````

I'm confused about the `\$0`, does it have the same effect as 0?

What value would the result give?

It is a question asking me to translate mips into c, where \$s0 is represented as variable name a, \$s1 b, \$s2 c etc.

The answer for this section is supposed to be `d = c[a];`, but i really dont see why.

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In MIPS, `\$0` or `\$zero` is the 0th indexed and first register, and has value 0. See here.

Although that looks like a typo, since `lw` uses a 16-bit offset, which isn't the value from a register but rather a constant (recall that a register is 32 bits). So it should actually be `lw \$s3, 0(\$t1)`.

The reason the code performs `d = c[a]` might seem simpler if I translate the MIPS into pseudo C-code:

``````\$t0 = a*4
\$t1 = \$t0 + c (= c + a*4)
d = *(c + a*4)
``````

So we end up loading into `d` the value in memory at location `c + 4a`, which is the base address of the array `c`, and the index of the element we want, `a`. We multiply by four because the type of the array is obviously a 4-byte long type, for example a 4-byte integer, so we need to jump `4*a` bytes from the beginning of the array to reach the appropriate point in memory.

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oh it all make sense now!! I thought c as a normal value instead of address so cannot think up how the address of c pop out all out of a sudden. but yea after write in the pseudo C code form it become very clear to me now. Thank you a lot! – lynnyilu Jun 7 '11 at 13:35
@lynnyilu, a pleasure :) – davin Jun 7 '11 at 13:37