can anyone help me on this exercice on 68000 assembler please? create a program that multiply two long words v1 and v3 unsigned. the product is number on 64 bits. the values v1 qnd v2 are respectively on the data registers D1 and D2 ? thanks for your answers and sorry for my bad english
As long as you multiply unsigned 32-bit quantities, you can use the following way: Theory: if your 32-bit quantities are A and B, split them like this: A=Ah*0x10000+Al, B=Bh*0x10000+Bl, where each of Ah,Al,Bh,Bl is from 0 to 0xFFFF.
A * B = Ah * Bh<<32 + Al * Bh<<16 + Ah * Bl<<16 + Al * Bl
Each of these 4 multiplies is 16bit*16bit->32bit, thus perfectly fitting 68000 mulu.w command.
So the code:
;unsigned d0.l * d1.l -> d2.l:d3.l (d2.l holds high part) move.w d0,d3 mulu.w d1,d3 ;d3.l is Al*Bl now swap d0 swap d1 move.w d0,d2 mulu.w d1,d2 ;d2.l is Ah*Bh now swap d0 move.w d0,d4 mulu.w d1,d4 ;d4 is Al*Bh swap d4 moveq #0,d5 move.w d4,d5 clr.w d4 ; d5:d4 is 0x0000:Nh:Nl:0x0000, where N is Al*Bh add.l d4,d3 addx.l d5,d2 ;add Al*Bh*0x10000 to the partial result in d2:d3 swap d0 swap d1 move.w d0,d4 mulu.w d1,d4 ;d4 is Ah*Bl swap d4 moveq #0,d5 move.w d4,d5 clr.w d4 ; d5:d4 is 0x0000:Nh:Nl:0x0000, where N is Ah*Bl add.l d4,d3 addx.l d5,d2 ;add Ah*Bl*0x10000 to the partial result ;d2:d3 is now the result
Of course, this code has many possibilities for optimization.
You have the problem that the MUL is only 16-bit, which means that if you have a 64-bit result, you need to do it in a sequence of 4 16-bit multiples and additions. You then return the result in two registers, as each register is 32-bits.
Assume you want A x B, and that A is AH and AL, with B as BH and BL You get a series of partial products:
1: BL x AL 2: BL x AH x 2^16 3: BH x 2^16 x AL 4: BH x 2^16 x AH x 2^16
Each of the 4 partial products accumulate in their own section of the 64-bit word, and to make matters more interesting, you need to consider the carries.
What I will present is different from what you need as far as registers, but if you can understand it, you can change it for your exercise. Assume that A6 is the stack, and we’ll return the result in D0 for the high 32-bit word, and D1 for the low 32-bit word. Here’s a snippet of code from my library
umul32: link a6, #0 movem.l d2-d4, -(sp) move.l (multiB,a6), d4 ;B into d4 move.l (multiA,a6), d3 ;A into d3 moveq #0,d2 moveq #0,d1 moveq #0,d0 mshift1: lsr.l #1,d4 ; look for 1 in multiplier bcc.s mshift2 ; branch on 0 add.l d3,d1 ; add shifted A to product addx.l d2,d0 ; add carry if found mshift2: lsl.l #1,d3 ; shift for next iteration roxl.l #1,d2 tst.l d4 ; check for 1s bne.s mshift1 movem.l (sp)+,d2-d4 ulnk a6 move.l (sp),(8,sp) ;clean the 8 entries off the stack addq.l 8, sp rts