Bithacks: Difference between revisions
(Modified formatting to allow linking to individual sections and let the site automatically generate a table of contents.) |
(→Clear High Byte of Accumulator: clearing high byte would be tdc xba. Or just lda #$0000.) |
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<small>As this list grows tricks here will be consolidated into their own sections. Clever optimization tricks that aren't necessarily what someone might personally call a "bithack" are okay here as well!</small> | <small>As this list grows tricks here will be consolidated into their own sections. Clever optimization tricks that aren't necessarily what someone might personally call a "bithack" are okay here as well!</small> | ||
== Clear | == Clear Low Byte of Accumulator == | ||
''1 byte / 2 cycles'' | ''1 byte / 2 cycles'' | ||
<br> | <br> | ||
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<u>outputs:</u> A | <u>outputs:</u> A | ||
<pre> | <pre> | ||
; "Trashes" A but clears | ; "Trashes" A but clears low byte | ||
TDC | TDC | ||
</pre> | </pre> |
Revision as of 19:25, 25 April 2021
Bithacks are optimization tricks that utilize information in bits and bit manipulation
to accomplish their tasks. Usually they work in a slightly non-obvious way, (the most famous being the fast inverse sqrt), and bit manipulation in general is harder on the 65c816. To that end here is a collection of some useful tricks.
Note: cycle counts are intended to be a worst case measure.
Math Bithacks
Signed Division By 2
3 bytes / 4 cycles
inputs: A
outputs: A
CMP #$80 ROR
Signed Division By 2n
6+n bytes / 6+2n cycles
inputs: A
outputs: A
; signed division by two, n times macro SignedDiv_2N(n) LSR #<n> BIT.b #$80>><n> BEQ ?positive ORA.b #$FF00>><n> ; sign extension ?positive: endmacro ; -1 cycle and +n bytes, but must have N flag set before use macro SignedDiv_2N(n) BMI ?negative LSR #<n> BRA ?end ?negative: LSR #<n> ORA.b #$FF00>><n> ; sign extension ?end: endmacro
Absolute Value
5 bytes / 6 cycles
inputs: A, (N Flag)
outputs: A
macro abs() BPL ?plus EOR #$FF INC ?plus: ; only 3 cycles if branch taken endmacro
Absolute Value (SEC)
4 bytes / 4 cycles
inputs: A, (Carry Set)
outputs: A
; compared to the branching version this is 1 byte smaller ; it's either 2 cycles slower/faster depending on branch taken EOR #$7F ; SEC ; the instant you add this in it becomes worse than the branching version SBC #$7F
Magnitude/Extents Check
~7 bytes / 12 cycles
inputs: A
outputs: (none)
; asks "Is [A] on the zero-side of value [X] or the far side?" ; good for magnitude checks, smaller *AND* faster than alternatives ; NOTE: in the event that it is exactly [X] it will have that value at branch ; doesn't need to be an indexed CMP but is most useful this way ; this can be used to combine the BPL and BMI checks for both signs into one SEC : SBC Extents,x EOR Extents,x BMI .zero_side .far_side: ; do things .zero_side: ; do things Extents: db -$23, $23
Misc. Tricks
As this list grows tricks here will be consolidated into their own sections. Clever optimization tricks that aren't necessarily what someone might personally call a "bithack" are okay here as well!
Clear Low Byte of Accumulator
1 byte / 2 cycles
inputs: (none)
outputs: A
; "Trashes" A but clears low byte TDC
Direction/Facing As Index
4 bytes / 6 cycles
inputs: A
outputs: A
; Ever wonder why facing flags are 0=right and 1=left? This is why. It's incredibly cheap. ASL ROL AND #$01
Skip Dead Code
1-2 bytes / 2-3 cycles
inputs: (none)
outputs: (none)
; If you need to skip one byte of dead code (due to a hijack or whatever reason) you can use: NOP ; 1 byte, 2 cycles ; But if you need to skip just 2 bytes the most efficient is: ; NOTE: many times WDM is used as a breakpoint for debugging so only do this as a final pass to speed up your code! WDM ; 2 bytes, 2 cycles ; Finally, if you need to skip a large amount of dead code you can use BRA/JMP instead ; JMP is as fast as BRA on the SNES CPU, but will be slightly slower on SA-1, and 1 cycle slower on SPC. So BRA is recommended ; (The extra byte used for JMP in this case doesn't matter) BRA + ; 2 bytes, 3 cycles ; dead code +
Check 3 Conditions
2 bytes / 2 cycles
inputs: A
outputs: (none)
; just the opcode as normal here (not counting the conditions), using any operand that's not immediate (#) ; it's worth noting that you can do up to 3 tests with a single opcode though! ; Just As A Reminder: the V & N flag are set by the *operand* to BIT not the result of the AND! BIT $00 BMI .bit7_set BVS .bit6_set BNE .bit5_set ; assuming #$20 is in $00 .bit7_set: .bit6_set: .bit5_set: