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Here is some MIPS assembly code I wrote to test the jump instruction:

addi $a0, $0, 1
j next
j skip1
add $a0, $a0, $a0
j skip2:
add $a0, $a0, $a0
add $a0, $a0, $a0
j skip3
add $a0, $a0, $a0
add $a0, $a0, $a0
add $a0, $a0, $a0
j loop

When I run the assembler, here's the result:

[0x000000]  0x20040001  # addi $a0, $zero, 1 ($a0 = 1)
[0x000004]  0x08000002  # j 0x0002 (jump to addr 0x0008)
[0x000008]  0x08000004  # j 0x0004 (jump to addr 0x0010)
[0x00000C]  0x00842020  # add $a0, $a0, $a0 ($a0 = $a0 + $a0)
[0x000010]  0x08000007  # j 0x0007 (jump to addr 0x001C)
[0x000014]  0x00842020  # add $a0, $a0, $a0 ($a0 = $a0 + $a0)
[0x000018]  0x00842020  # add $a0, $a0, $a0 ($a0 = $a0 + $a0)
[0x00001C]  0x0800000B  # j 0x000B (jump to addr 0x002C)
[0x000020]  0x00842020  # add $a0, $a0, $a0 ($a0 = $a0 + $a0)
[0x000024]  0x00842020  # add $a0, $a0, $a0 ($a0 = $a0 + $a0)
[0x000028]  0x00842020  # add $a0, $a0, $a0 ($a0 = $a0 + $a0)
[0x00002C]  0x08000008  # j 0x0008 (jump to addr 0x0020)

Looking at the machine code for the jump instructions, this is what I see:

1st jump (just jumps to next instruction) 0x08000002
2nd jump (skips 1 instruction) 0x08000004
3rd jump (skips 2 instructions) 0x08000007
4th jump (skips 3 instructions) 0x0800000B
5th jump (skips 3 instructions backwards) 0x08000008

From looking at these instructions, it looks like the machine code starts with a 08 for the jump instruction, and the number at the end tells the jump instruction where to go. However, I can not figure out how this number is calculated. Also, there is nothing to indicate to me that the 5th jump is a backwards jump.

How is the jump value calculated?

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up vote 7 down vote accepted

Just look into a reference manual for more details about the opcode encoding.

Short version: In a 32 bit instruction you can not include a 32-bit jump destination. The opcoded uses 6 bits, which leaves 26 bits for the instruction. The target address is constructed, by taking the first 4 bits of the instruction following the j instruction, then 26 bits from the jump instruction operand, and finally 2 zero bits are appended (as the instructions are 32 bits, alginment is usefull and allows the omitting of the last two 0s).

To the backward jump: The addresses are absolute, NOT relative, so it only depends on the address of the jump instruction, whether it is a forward or a backward jump.

EDIT: More detailled description: We have at addr x jump instruction j. Lets call the jump operand of j t. t is 26 bit wide. The bit pattern of address of the next instruction is computed as follows:


So the jump is ALWAYS absolute. There are no relative jumps. when the result is smaller than x then it is a backward jump, when it is greater it is a forward jump (and if you want something stupid, you make it equal ;-).

So lets look at the 5th jump of your example:

The first 6 bits of the jump target are: 000000, because the upper 6 bits of the address of the instruction behind the jump are 000000.

The next 26 bits are the lowest 26 bits of the jump instruction, that is 00000000000000000000001000

The last 2 bits are: 00, because the got always appended.

Together we have: 0000000000000000000000000000100000, which is hex 20. And at that address is exactly the label/instruction where the flow should continue.

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This doesn't answer the question about how the relative address is specifying a backwards offset. Usually, the jmp relative value would be negative to accomplish this. Also, the offsets above don't make much sense for jumps. I, like @z-buffer, am also a bit confused by the disassembly... – Michael Dorgan Oct 24 '11 at 15:00
Your edit explains the jump as absolute, but the offsets still don't really line up. There must be something else going on here. +1 still for answering the complete question. – Michael Dorgan Oct 24 '11 at 15:07
@Michael Dorgan: The Backwards jumps is fine as it is: It shows as ...08. That 08 left shifted by two (the two 2 zeros I mentioned) are 32 which is hex 0x20. And the instruction where the jumps goes is 0x..20. So it fits perfectly (same with the other 4 jumps). – flolo Oct 24 '11 at 15:23
All I understood from your answer was that two bits get added at the end. Could you explain in a more mathematical way and show how it works in this case? Also it's not clear from your explanation whether forward jump addresses are relative or not. – node ninja Oct 24 '11 at 15:24
@z-buffer: yes (besides the 6 topmost bits). – flolo Oct 25 '11 at 8:18

In MIPS, J is a J-type instruction:

J-type instructions (Jumps)
3    22
1    65                        0
| op |         target          |

So we have a target that is 26-bits long. It gets combined with the PC of the next instruction as follows:

I+1 PC <- (PC & 0xf0000000) | (target << 2)

It is shifted left 2 bits, since MIPS instructions (ignoring the MIPS16 extension) are 32-bits long, meaning they all start in an address whose lower 2 bits are zero.

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Another way to think of it is, what's the smallest nonzero value you can put into a jump instruction? That would be a 1, and it corresponds to the 2nd instruction in the program, which is at 0x4. So basically it's a jump to the absolute address of the instruction, divided by 4, since the addresses are nth instruction is always (n-1)*4. To divide by 4, you shift right by 2 bits because shifting right n bits divides a number by (2^n). – node ninja Oct 25 '11 at 19:43

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