j
is a j-type instruction and has the following format: opcode - address
which are 6 bits and 26 bits respectively.
The first 6 bits, the opcode
for a j
instruction is 000010
The next 26 bits for the address are a bit trickier. First you will need the address of the label you are referring to. In your example, since the instruction address of slt
is 0xFFFFFF00
, counting up by 4 everytime, the instruction address of loopEnd (which is instruction j loop
) will be 0xFFFFFF2C
.
So now we have the address of the target instruction 0xFFFFFF2C
, but this is 32 bits while we only have 26 bits to use for the target address in a J-type instruction. This is dealt with by dropping the first hex digit and dropping the last 2 binary digits. The first hex digit the address that will actually be jumped to will be the same as the current instruction (F
in your case). We can drop the last 2 binary digits because instruction addresses are always multiples of 4, so we don't need the precision of 0, 1, 2, 3 that the last 2 binary digits give us, they will always be 00
for an instruction address.
Combining all this for your example:
0xFFFFFF2C
-> 0x FFFFF2C
-> convert to binary
1111_1111_1111_1111_1111_0010_1100
-> 1111_1111_1111_1111_1111_0010_10
Now we combine the opcode with the interpreted instruction address:
000010_11111111111111111111001010
And that is the machine code for j loopend
TL;DR
- Get opcode for the jump instruction
- Get address at label in hex
- Drop the first hex digit of address
- Convert to binary
- Drop the last two bits
- Combine opcode and interpreted address
as
and thenobjdump
to find out? Seems like the fastest and easiest way to me.loopEnd
in the code you pasted, which makes it impossible to calculate the branch target address.