It's depends on endianess of your machine. If your machine is little endian it prints FA(Your's is little endian right?). If your machine is big endian it prints 10.

**Storing Words in Memory**
We've defined a word to mean 32 bits. This is the same as 4 bytes. Integers, single-precision floating point numbers, and MIPS instructions are all 32 bits long. How can we store these values into memory? After all, each memory address can store a single byte, not 4 bytes.

The answer is simple. We split the 32 bit quantity into 4 bytes. For example, suppose we have a 32 bit quantity, written as `90AB12CD16`

, which is hexadecimal. Since each hex digit is 4 bits, we need 8 hex digits to represent the 32 bit value.

So, the 4 bytes are: `90, AB, 12, CD`

where each byte requires 2 hex digits.

It turns out there are two ways to store this in memory.
**Big Endian**
In big endian, you store the most significant byte in the smallest address. Here's how it would look:

```
Address Value
1000 90
1001 AB
1002 12
1003 CD
```

**Little Endian**
In little endian, you store the least significant byte in the smallest address. Here's how it would look:

```
Address Value
1000 CD
1001 12
1002 AB
1003 90
```

Notice that this is in the reverse order compared to big endian. To remember which is which, recall whether the least significant byte is stored first (thus, little endian) or the most significant byte is stored first (thus, big endian).

Notice I used "byte" instead of "bit" in least significant bit. I sometimes abbreciated this as LSB and MSB, with the 'B' capitalized to refer to byte and use the lowercase 'b' to represent bit. I only refer to most and least significant byte when it comes to endianness.