180 lines
3.6 KiB
ArmAsm
180 lines
3.6 KiB
ArmAsm
; FP registers in zero page
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FR0 = $d4
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FRE = $da
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FR1 = $e0
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FR2 = $e6
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FRX = $ec
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.code
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.export start
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; 2 + 8 * byte cycles
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.macro neg bytes, arg
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sec ; 2 cyc
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.repeat bytes, byte ; 8 * byte cycles
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lda #00 ; 2 cyc
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sbc arg + byte ; 3 cyc
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sta arg + byte ; 3 cyc
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.endrepeat
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.endmacro
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; 18 cycles
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.macro neg16 arg
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neg 2, arg
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.endmacro
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; 34 cycles
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.macro neg32 arg
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neg 4, arg
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.endmacro
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; inner loop for imul16
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; bitnum < 8: 25 or 41 cycles
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; bitnum >= 8: 30 or 46 cycles
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.macro bitmul16 arg1, arg2, result, bitnum
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.local zero
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.local one
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.local next
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; does 16-bit adds
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; arg1 must be 0 or positive
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; arg2 must be 0 or positive
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; 7 cycles up to the branch
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; check if arg1 has 0 or 1 bit in this place
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; 5 cycles either way
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.if bitnum < 8
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lda arg1 ; 3 cyc
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and #(1 << bitnum) ; 2 cyc
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.else
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lda arg1 + 1 ; 3 cyc
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and #(1 << (bitnum - 8)) ; 2 cyc
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.endif
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bne one ; 2 cyc
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zero: ; 18 cyc, 23 cyc
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lsr result + 3 ; 5 cyc
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jmp next ; 3 cyc
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one: ; 32 cyc, 37 cyc
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; 16-bit add on the top bits
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clc ; 2 cyc
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lda result + 2 ; 3 cyc
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adc arg2 ; 3 cyc
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sta result + 2 ; 3 cyc
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lda result + 3 ; 3 cyc
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adc arg2 + 1 ; 3 cyc
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ror a ; 2 cyc
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sta result + 3 ; 3 cyc
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next:
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ror result + 2 ; 5 cyc
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ror result + 1 ; 5 cyc
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.if bitnum >= 8
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; we can save 5 cycles * 8 bits = 40 cycles total by skipping this byte
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; when it's all uninitialized data
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ror result ; 5 cyc
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.endif
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.endmacro
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; 5 to 25 cycles
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.macro check_sign arg
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; Check sign bit and flip argument to postive,
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; keeping a count of sign bits in the X register.
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.local positive
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lda arg + 1 ; 3 cyc
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bpl positive ; 2 cyc
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neg16 arg ; 18 cyc
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inx ; 2 cyc
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positive:
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.endmacro
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; min 470 cycles
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; max 780 cycles
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.proc imul16
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arg1 = FR0 ; 16-bit arg (clobbered)
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arg2 = FR1 ; 16-bit arg (clobbered)
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result = FR2 ; 32-bit result
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ldx #0 ; 2 cyc
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; counts the number of sign bits in X
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check_sign arg1 ; 5 to 25 cyc
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check_sign arg2 ; 5 to 25 cyc
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; zero out the 32-bit temp's top 16 bits
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lda #0 ; 2 cyc
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sta result + 2 ; 3 cyc
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sta result + 3 ; 3 cyc
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; the bottom two bytes will get cleared by the shifts
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; unrolled loop for maximum speed, at the cost
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; of a larger routine
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; 440 to 696 cycles
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.repeat 16, bitnum
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; bitnum < 8: 25 or 41 cycles
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; bitnum >= 8: 30 or 46 cycles
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bitmul16 arg1, arg2, result, bitnum
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.endrepeat
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; In case of mixed input signs, return a negative result.
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cpx #1 ; 2 cyc
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bne positive_result ; 2 cyc
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neg32 result ; 34 cyc
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positive_result:
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rts ; 6 cyc
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.endproc
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.proc iter
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; (cx and cy should be pre-scaled to 6.26 fixed point)
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; zx = 0
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; zy = 0
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; zx_2 = 0
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; zy_2 = 0
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; zx_zy = 0
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; still working on the fixed-point
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loop:
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; iters++
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; 6.26:
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; zx = zx_2 + zy_2 + cx
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; zy = zx_zy + zx_zy + cy
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; round to 6.10.
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; 12.20:
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; zx_2 = zx * zx
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; zy_2 = zy * zy
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; dist = zx_2 + zy_2
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; if dist >= 4 break, else continue iterating
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; round zx_2, zy_2, dist to 6.26
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; if may be in the lake, look for looping output with a small buffer
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; as an optimization vs running to max iters
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.endproc
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.proc start
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looplong:
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; FR0 = 5
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; FR1 = -3
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lda #5
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sta FR0
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lda #0
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sta FR0 + 1
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lda #$fd
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sta FR1
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lda #$ff
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sta FR1 + 1
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jsr imul16
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; should have 32-bit -15 in FR2
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loop:
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jmp loop
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.endproc
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