from Nikolai Golovchenko
;-----------------------------------------------------------
;d0, d1, d2, ...dn - counters
;d0 = 0..3 - least significant 2 bits
;d1,...dn = 0..255 - more significant 8, 16, 24, ... bits
;
;Total Delay =
;= d0+4*d1+4*256*d2+4*256*256*d3...+4*256^(n-1)*dn + overhead
;
;Overhead depends on a number of counters, see below
;First preincrement all counters except d0
;overhead = n cycles
incf d1, f
incf d2, f
...
incf dn, f
;2 bit delay (d0 - 1 cycle resolution)
;overhead += 4 cycles
comf d0, w
andlw 0x03
addwf PCL, f
Delay64Mx
Delay256Kx
nop
Delay1Kx
nop
Delay4x
nop
;8 bit delay (d1 - 4 cycle resolution)
;overhead += 2 cycles
decfsz d1, f
goto Delay4x
;8 bit delay (d2 - 1024 cycle resolution)
;overhead += 3 cycles
decf d1, f
;change d1 to 255, so previous loop
;(from Delay4x) will take
;255*4-1=1019 cycles
;we need to add 5 more cycles to get 1024.
;4 cycles are in this loop and
;another 1 cycle is a nop above
decfsz d2, f
goto Delay1Kx
;8 bit delay (d3 - 262144 cycle resolution)
;overhead += 3 cycles
decf d2, f
;previous two loops (from Delay4x) will take
;1019+255*1024-1=262138 cycles
;we need to add 6 more cycles to get 262144.
;4 cycles are in this loop and
;another 2 cycles are above - two nops
decfsz d3, f
goto Delay256Kx
;8 bit delay (d4 - 262144*256 cycle resolution)
;overhead += 4 cycles
decf d3, f
;previous two loops (from Delay4x) will take
;262138+255*262144-1 cycles
;we need to add 7 more cycles to get 4*256^3.
;5 cycles are in this loop and
;another 2 cycles are above - two nops
nop
decfsz d4, f
goto Delay64Mx
;at this point we have a 34 bit one cycle resolution delay!
;Total Delay = overhead + 0..1.7e10 cycles
;overhead = 4+4+2+3+3+4 = 20 cycles
;-----------------------------------------------------------
And the same for a SX chip:
;-----------------------------------------------------------
;d0, d1, d2, ...dn - counters
;d0 = 0..3 - least significant 2 bits
;d1,...dn = 0..255 - more significant 8, 16, 24, ... bits
;
;Total Delay =
;= d0+4*d1+4*256*d2+4*256*256*d3...+4*256^(n-1)*dn + overhead
;
;Overhead depends on a number of counters, see below
;First preincrement all counters except d0
;overhead = n cycles
inc d1
inc d2
...
inc dn
;2 bit delay (d0 - 1 cycle resolution)
;overhead += 5 cycles
mov w, /d0
and #$03
add PC, w
Delay256Kx
nop
Delay64Mx
nop
Delay1Kx
nop
;8 bit delay (d1 - 4 cycle resolution)
;overhead += 2 cycles
Delay4x
decsz d1
jmp Delay4x
;8 bit delay (d2 - 1024 cycle resolution)
;overhead += 3 cycles
dec d1
;change d1 to 255, so previous loop
;(from Delay4x) will take
;255*4-2=1018 cycles
;we need to add 6 more cycles to get 1024.
;5 cycles are in this loop and
;another 1 cycle is a nop above
decsz d2
jmp Delay1Kx
;8 bit delay (d3 - 262144 cycle resolution)
;overhead += 3 cycles
dec d2
;previous two loops (from Delay4x) will take
;1018+255*1024-2=262136 cycles
;we need to add 8 more cycles to get 262144.
;5 cycles are in this loop and
;another 3 cycles are above - three nops
decsz d3
jmp Delay256Kx
;8 bit delay (d4 - 262144*256 cycle resolution)
;overhead += 6 cycles
dec d3
;previous two loops (from Delay4x) will take
;262136+255*262144-2 cycles
;we need to add 10 more cycles to get 4*256^3.
;8 cycles are in this loop and
;another 2 cycles are above - two nops
jmp $+1
decsz d4
jmp Delay64Mx
;at this point we have a 34 bit one cycle resolution delay!
;Total Delay = overhead + 0..1.7e10 cycles
;overhead = 4+5+2+3+3+6 = 23 cycles
;-----------------------------------------------------------
This is probably too small for SX :)
Code:
The PIC delay routine above works correctly only if d3 and d4 are zero (the same is probably true for the SX version as well). The problem lies in how the routine is extended by adding another loop. Basically, every time a loop is appended, it adds at least 2 cycles, which must be subtracted. Sometimes, it can be done by moving the jump target by 2 nops down, but when there are no more nops, it can be done by subtracting one from d1, which subtracts 4 cycles. So d1 is decremented, a new loop adds 3 cycles and subtracts 4, which is -1 overall. So the jump should include an additional nop.
The corrected PIC version is below:
; preincrement counters except d0
incf d1, f
incf d2, f
incf d3, f
incf d4, f
; Let Delay = 0 at this point
comf d0, w
andlw 0x03
addwf PCL, f
nop
Delay2 nop
Delay1 nop
; Delay = 4 + d0
Delay0 decfsz d1, f
goto Delay1
; Delay = 6 + d0 + 4 * d1
decf d1, f
decfsz d2, f
goto Delay2
; Delay = 9 + d0 + 4 * (d1 + 256 * d2)
decfsz d3, f
goto Delay0
; Delay = 11 + d0 + 4 * (d1 + 256 * d2 + 256^2 * d3)
decf d1, f
decfsz d4, f
goto Delay1
; Delay = 14 + d0 + 4 * (d1 + 256 * d2 + 256^2 * d3 + 256^3 * d4)
; This can be extended like this:
;
; decf d1, f
; decfsz d5, f
; goto Delay2
;
; decfsz d6, f
; goto Delay0
;
; decf d1, f
; decfsz d7, f
; goto Delay1
;
; decf d1, f
; decfsz d8, f
; goto Delay2
;
; decfsz d9, f
; goto Delay0
+
| file: /Techref/microchip/delay/xb1crnm-ng.htm, 7KB, , updated: 2005/3/28 21:03, local time: 2025/4/27 18:30,
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