Random number generator/Linear feedback shift register (advanced): Difference between revisions

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(Created page as a place for more advanced commentary on the LFSR example.)
 
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Further commentary on the [[Random number generator#Linear feedback shift register|linear feedback shift register]] example at [[random number generator]].
Further commentary on the [[Random number generator#Linear feedback shift register|linear feedback shift register]] example at [[random number generator]].
These are excerpted from the following source on github: [https://github.com/bbbradsmith/prng_6502 prng_6502]


== Basic version ==
== Basic version ==
<pre>
<pre>
prng:
prng:
ldx #8    ; iteration count
ldy #8    ; iteration count
lda seed+0
lda seed+0
:
:
Line 10: Line 12:
rol seed+1
rol seed+1
bcc :+
bcc :+
eor #$2D   ; apply XOR feedback whenever a 1 bit is shifted out
eor #$39   ; apply XOR feedback whenever a 1 bit is shifted out
:
:
dex
dey
bne :--
bne :--
sta seed+0
sta seed+0
Line 20: Line 22:


== Sacrifice entropy for speed ==
== Sacrifice entropy for speed ==
The iteration count stored in X can be reduced to speed up the generator, at the expense of quality of randomness. Each iteration effectively generators one more bit of entropy, so 8 iterations are needed for an 8-bit random number. If you intend to use fewer bits of the result (e.g. use AND to mask the result), or if you are satisfied with less randomness, you can reduce X, or even parameterize it:
The iteration count stored in Y can be reduced to speed up the generator, at the expense of quality of randomness. Each iteration effectively generators one more bit of entropy, so 8 iterations are needed for an 8-bit random number. If you intend to use fewer bits of the result (e.g. use AND to mask the result), or if you are satisfied with less randomness, you can reduce Y, or even parameterize it:


<pre>
<pre>
; X as a parameter specifies number of random bits to generate (1 to 8)
; Y as a parameter specifies number of random bits to generate (1 to 8)
prng:
prng:
lda seed+0
lda seed+0
Line 30: Line 32:
rol seed+1
rol seed+1
bcc :+
bcc :+
eor #$2D
eor #$39
:
:
dex
dey
bne @bitloop
bne @bitloop
sta seed+0
sta seed+0
Line 39: Line 41:
</pre>
</pre>


Alternatively this loop could be unrolled with 8 entry points, saving the need to use X or load it as a parameter.
Alternatively this loop could be unrolled with 8 entry points, saving the need to use Y or load it as a parameter.
 
== Simple 24 and 32 bit LFSR ==
 
By adding an extra byte or two to the seed variable, and choosing an appropriate polynomial to XOR with, we can extend the sequence length significantly with only one additonal ROL per byte (+40 cycles).
 
This 24-bit version has a sequence length of 16777215: 21 bytes, 173-181 cycles.
 
<pre>.zeropage
seed: .res 3 ; 24-bit
 
.code
prng:
ldy #8
lda seed+0
:
asl
rol seed+1
rol seed+2
bcc :+
eor #$1B
:
dey
bne :--
sta seed+0
cmp #0
rts
</pre>
 
This 32-bit version has a sequence length of 4294967295: 23 bytes, 213-221 cycles.
 
<pre>.zeropage
seed: .res 4 ; 32-bit
 
.code
prng:
ldy #8
lda seed+0
:
asl
rol seed+1
rol seed+2
rol seed+3
bcc :+
eor #$C5
:
dey
bne :--
sta seed+0
cmp #0
rts
</pre>
 
Even longer sequences are possible, but it's not likely to be practical, as it would already take approximately 7 days for an NTSC NES to complete this 32 bit LFSR cycle if doing nothing else.
 
== Overlapped 24 and 32 bit LFSR ==
 
With an XOR-feedback that contains only four bits, we can shift and feed back 8 bits at once in a more complex overlapped operation that essentially applies 4 16-bit XOR operations to the lower two bytes of the seed. (One XOR for each feedback bit.) With some careful rearrangement this can do 8 iterations at once very efficiently.
 
24-bit overlapped: 38 bytes, 73 cycles.
<pre>
prng:
; rotate the middle byte left
ldy seed+1 ; will move to seed+2 at the end
; compute seed+1 ($1B>>1 = %1101)
lda seed+2
lsr
lsr
lsr
lsr
sta seed+1 ; reverse: %1011
lsr
lsr
eor seed+1
lsr
eor seed+1
eor seed+0
sta seed+1
; compute seed+0 ($1B = %00011011)
lda seed+2
asl
eor seed+2
asl
asl
eor seed+2
asl
eor seed+2
sty seed+2 ; finish rotating byte 1 into 2
sta seed+0
rts</pre>
 
32-bit overlapped: 44 bytes, 83 cycles.
<pre>
prng:
; rotate the middle bytes left
ldy seed+2 ; will move to seed+3 at the end
lda seed+1
sta seed+2
; compute seed+1 ($C5>>1 = %1100010)
lda seed+3 ; original high byte
lsr
sta seed+1 ; reverse: 100011
lsr
lsr
lsr
lsr
eor seed+1
lsr
eor seed+1
eor seed+0 ; combine with original low byte
sta seed+1
; compute seed+0 ($C5 = %11000101)
lda seed+3 ; original high byte
asl
eor seed+3
asl
asl
asl
asl
eor seed+3
asl
asl
eor seed+3
sty seed+3 ; finish rotating byte 2 into 3
sta seed+0
rts
</pre>


Because the 16-bit LFSR has a repeating cycle of 65535 values, groups of 6, 5, or 3 bits will reduce the length of its output sequence. This should be avoided, if possible.
A note about the chosen polynomials: several XOR-feedback values are available that will produce a maximal-length LFSR period<ref>[https://github.com/bbbradsmith/prng_6502/blob/master/utils/polyfind.txt List of possible 1-byte XOR values for maximal-length Galois LFSR]</ref>. $39, $2D, and $C5 are chosen because they contain the minimum number of bits, in a compact arrangement that allows a fast overlapped computation.


== 24 and 32 bit LFSR ==
== References ==
<References/>
* [http://forums.nesdev.org/viewtopic.php?p=196569#p196569 32-bit LFSR PRNG] by jroatch


TODO
== Additional Resource ==
* http://users.ece.cmu.edu/~koopman/lfsr/index.html - a source for maximal polynomials for LFSRs of many lengths.

Latest revision as of 17:05, 20 February 2021

Further commentary on the linear feedback shift register example at random number generator.

These are excerpted from the following source on github: prng_6502

Basic version

prng:
	ldy #8     ; iteration count
	lda seed+0
:
	asl        ; shift the register
	rol seed+1
	bcc :+
	eor #$39   ; apply XOR feedback whenever a 1 bit is shifted out
:
	dey
	bne :--
	sta seed+0
	cmp #0     ; reload flags
	rts

Sacrifice entropy for speed

The iteration count stored in Y can be reduced to speed up the generator, at the expense of quality of randomness. Each iteration effectively generators one more bit of entropy, so 8 iterations are needed for an 8-bit random number. If you intend to use fewer bits of the result (e.g. use AND to mask the result), or if you are satisfied with less randomness, you can reduce Y, or even parameterize it: 

; Y as a parameter specifies number of random bits to generate (1 to 8)
prng:
	lda seed+0
@bitloop:
	asl
	rol seed+1
	bcc :+
	eor #$39
:
	dey
	bne @bitloop
	sta seed+0
	cmp #0
	rts

Alternatively this loop could be unrolled with 8 entry points, saving the need to use Y or load it as a parameter.

Simple 24 and 32 bit LFSR

By adding an extra byte or two to the seed variable, and choosing an appropriate polynomial to XOR with, we can extend the sequence length significantly with only one additonal ROL per byte (+40 cycles).

This 24-bit version has a sequence length of 16777215: 21 bytes, 173-181 cycles. 

.zeropage
seed: .res 3 ; 24-bit

.code
prng:
	ldy #8
	lda seed+0
:
	asl
	rol seed+1
	rol seed+2
	bcc :+
	eor #$1B
:
	dey
	bne :--
	sta seed+0
	cmp #0
	rts

This 32-bit version has a sequence length of 4294967295: 23 bytes, 213-221 cycles. 

.zeropage
seed: .res 4 ; 32-bit

.code
prng:
	ldy #8
	lda seed+0
:
	asl
	rol seed+1
	rol seed+2
	rol seed+3
	bcc :+
	eor #$C5
:
	dey
	bne :--
	sta seed+0
	cmp #0
	rts

Even longer sequences are possible, but it's not likely to be practical, as it would already take approximately 7 days for an NTSC NES to complete this 32 bit LFSR cycle if doing nothing else.

Overlapped 24 and 32 bit LFSR

With an XOR-feedback that contains only four bits, we can shift and feed back 8 bits at once in a more complex overlapped operation that essentially applies 4 16-bit XOR operations to the lower two bytes of the seed. (One XOR for each feedback bit.) With some careful rearrangement this can do 8 iterations at once very efficiently.

24-bit overlapped: 38 bytes, 73 cycles. 

prng:
	; rotate the middle byte left
	ldy seed+1 ; will move to seed+2 at the end
	; compute seed+1 ($1B>>1 = %1101)
	lda seed+2
	lsr
	lsr
	lsr
	lsr
	sta seed+1 ; reverse: %1011
	lsr
	lsr
	eor seed+1
	lsr
	eor seed+1
	eor seed+0
	sta seed+1
	; compute seed+0 ($1B = %00011011)
	lda seed+2
	asl
	eor seed+2
	asl
	asl
	eor seed+2
	asl
	eor seed+2
	sty seed+2 ; finish rotating byte 1 into 2
	sta seed+0
	rts

32-bit overlapped: 44 bytes, 83 cycles. 

prng:
	; rotate the middle bytes left
	ldy seed+2 ; will move to seed+3 at the end
	lda seed+1
	sta seed+2
	; compute seed+1 ($C5>>1 = %1100010)
	lda seed+3 ; original high byte
	lsr
	sta seed+1 ; reverse: 100011
	lsr
	lsr
	lsr
	lsr
	eor seed+1
	lsr
	eor seed+1
	eor seed+0 ; combine with original low byte
	sta seed+1
	; compute seed+0 ($C5 = %11000101)
	lda seed+3 ; original high byte
	asl
	eor seed+3
	asl
	asl
	asl
	asl
	eor seed+3
	asl
	asl
	eor seed+3
	sty seed+3 ; finish rotating byte 2 into 3
	sta seed+0
	rts

A note about the chosen polynomials: several XOR-feedback values are available that will produce a maximal-length LFSR period[1]. $39, $2D, and $C5 are chosen because they contain the minimum number of bits, in a compact arrangement that allows a fast overlapped computation.

References

  1. List of possible 1-byte XOR values for maximal-length Galois LFSR

Additional Resource

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