Difference between revisions of "Byte Battle"
m (→Palettes) |
(Add raytraced tunnel to the examples.) |
||
(47 intermediate revisions by 2 users not shown) | |||
Line 1: | Line 1: | ||
− | == | + | == Byte Battles == |
− | + | Byte Battles are a form of live coding, similar to Shader Showdowns, where two contestants compete in writing a visual effect in 25 minutes. The coding environment is the [[Fantasy Consoles|TIC-80 fantasy console]]. However, unlike Shader Showdowns, there is an additional limit: the final code should be 256 characters or less. This requires the contestants to use efficient code (e.g. single letter variables) and to minimize the code (e.g. remove the whitespace), all within the time limit. Unlike in normal TIC-80 sizecoding, there is no compression, so every character counts. | |
== General notation in this article == | == General notation in this article == | ||
Line 19: | Line 19: | ||
== Basic optimizations == | == Basic optimizations == | ||
− | * Functions, that are called three or more times should be aliased. For example, <code>e=elli</code> with <code>e()e()e()</code> is 3 characters shorter than <code>elli()elli()elli()</code>. Functions with 5 character names may already benefit from aliasing with two calls: <code>r=rectb</code> with <code>r()r()</code> is 1 character shorter than <code>rectb()rectb()</code>. | + | * Functions, that are called three or more times should be aliased. For example, <code>e=elli</code> with <code>e()e()e()</code> is 3 characters shorter than <code>elli()elli()elli()</code>. Functions with 5-character-long names may already benefit from aliasing with two calls: <code>r=rectb</code> with <code>r()r()</code> is 1 character shorter than <code>rectb()rectb()</code>. |
− | * <code>t=0</code> with <code>t=t+. | + | * <code>t=0</code> with <code>t=t+.01</code> is 1 character shorter than <code>t=time()*.6</code>. |
* <code>for i=0,32639 do x=i%240y=i/240 end</code> is 2-3 characters shorter than <code>for y=0,135 do for x=0,239 do end end</code>. | * <code>for i=0,32639 do x=i%240y=i/240 end</code> is 2-3 characters shorter than <code>for y=0,135 do for x=0,239 do end end</code>. | ||
* <code>(x*x+y*y)^.5</code> is 6 characters shorter than <code>math.sqrt(x*x+y*y)</code>. | * <code>(x*x+y*y)^.5</code> is 6 characters shorter than <code>math.sqrt(x*x+y*y)</code>. | ||
− | * <code>s(w-11)</code> and <code>s(w+8)</code> both approximate <code>math.cos(w)</code>, so only <code>math.sin</code> needs to be aliased. <code>s(w-11)</code> is | + | * <code>s(w-11)</code> and <code>s(w+8)</code> both approximate <code>math.cos(w)</code>, so only <code>math.sin</code> needs to be aliased. <code>s(w-11)</code> is far more accurate, with the cost of one more character. |
− | |||
== One-lining == | == One-lining == | ||
Line 47: | Line 46: | ||
As a rule of thumb, one-lining and using the load trick can bring a ~ 275 character code down to 256. | As a rule of thumb, one-lining and using the load trick can bring a ~ 275 character code down to 256. | ||
− | <code>load</code> can be | + | Any arguments passes to a function defined with <code>load</code> can be fetched with the ellipsis (<code>...</code>). For example, <code>SCN=function(x)poke(16320,x)end</code> can be implemented as: |
<syntaxhighlight lang="lua"> | <syntaxhighlight lang="lua"> | ||
− | SCN=load' | + | SCN=load'poke(16320,...)' |
</syntaxhighlight> | </syntaxhighlight> | ||
+ | |||
+ | This saves 6 characters. Multiple arguments can be fetched with <code>x,y=...</code>. | ||
'''Warning: The backslash causes problems when using the load trick.''' In particular, if you have a string with escaped characters in the original code e.g. <code>print("foo\nbar")</code>, then this needs to be double-escaped: <code>load'print("foo\\nbar")'</code> | '''Warning: The backslash causes problems when using the load trick.''' In particular, if you have a string with escaped characters in the original code e.g. <code>print("foo\nbar")</code>, then this needs to be double-escaped: <code>load'print("foo\\nbar")'</code> | ||
− | |||
== Dithering == | == Dithering == | ||
Line 65: | Line 65: | ||
| || || [[File:No dithering.png]] || No dithering | | || || [[File:No dithering.png]] || No dithering | ||
|- | |- | ||
− | | <code>s(i)* | + | | <code>i%.7</code> || 4 || [[File:Modulo dithering.png]] || |
+ | |- | ||
+ | | <code>i^2.5%1</code> || 7 || [[File:Power dithering.png]] || "random" dithering | ||
+ | |- | ||
+ | | <code>s(i)*i%1</code> || 8 || [[File:Random dithering.png]] || also "random" dithering | ||
|- | |- | ||
− | | <code>i*481/960%1</code> || 11 || [[File:Chess dithering.png]] || | + | | <code>i*481/960%1</code> || 11 || [[File:Chess dithering.png]] || <code>(x/2+y/4)%1</code> if you have x&y. <code>i*25/96%1</code> or <code>i*97/192</code> if desperate. |
|- | |- | ||
| <code>(x*2-y%2)%4/4</code> || 13 || [[File:Block dithering.png]] || 2x2 block dithering | | <code>(x*2-y%2)%4/4</code> || 13 || [[File:Block dithering.png]] || 2x2 block dithering | ||
|- | |- | ||
| <code>(i*2-i//80%2)%4/4</code> || 17 || [[File:Block dithering from i.png]] || 2x2 block dithering (almost), from i only | | <code>(i*2-i//80%2)%4/4</code> || 17 || [[File:Block dithering from i.png]] || 2x2 block dithering (almost), from i only | ||
+ | |- | ||
+ | | <code>(x*2-y%2)%4/4+((x&2)-y//2%2)%4/16</code> || 33 || [[File:Block4 dithering exp.png]] || 4x4 with dithering matrix defined by an expression | ||
+ | |- | ||
+ | | <code>('0415627326158473'):sub(p,p)/8</code> || 44 || [[File:Block4 dithering.png]] || 4x4 with data-defined dithering matrix, <code>p</code> defined as <code>p=y%4*4+x%4+1</code> | ||
|} | |} | ||
Line 86: | Line 94: | ||
end | end | ||
</syntaxhighlight> | </syntaxhighlight> | ||
− | |||
== Palettes == | == Palettes == | ||
Line 93: | Line 100: | ||
{| | {| | ||
− | ! Expression | + | ! Expression || Length || Result || Notes |
+ | |- | ||
+ | | <code>poke(16320+j,j*5)</code> || 17 || [[File:Gray palette.png]] || | ||
+ | |- | ||
+ | | <code>poke(16320+j,j%3*j*5)</code> || 21 || [[File:Blue-green-cyan palette.png]] || Good for objects & background | ||
+ | |- | ||
+ | | <code>poke(16320+j,j%3*j/.4)</code> || 22 || [[File:Blue palette.png]] || Use <code>(j+1)%3</code>, <code>(j+2)%3</code> or <code>2*j%3</code> for different colors | ||
+ | |- | ||
+ | | <code>poke(16320+j,s(j)^2*255)</code> || 24 || [[File:Rainbow palette.png]] || Change the phase of the palette with s(j+p) | ||
+ | |- | ||
+ | | <code>poke(16320+j,s(j)^2*j*6)</code> || 24 || [[File:Rainbow faded palette.png]] || Change the phase of the palette with s(j+p) | ||
|- | |- | ||
− | | <code>poke(16320+j,j* | + | | <code>poke(16320+j,s(j/15)*255)</code> || 25 || [[File:Blue-brown palette.png]] || <code>s(j/15)^2</code> is less bright |
|- | |- | ||
− | | <code>poke(16320+j,j%3* | + | | <code>poke(16320+j,s(j-j%-3)^2*255)</code> || 29 || [[File:Green-beige palette.png]] || <code>j%3*2</code> for a more blue/beige variant, <code>-j%3*4</code> for beige/blue variant |
|- | |- | ||
− | | <code>poke(16320+j, | + | | <code>poke(16320+j,255/(1+2^(4+j%3-j/5)))</code> || 35 || [[File:Bright beige palette.png]] || <code>2*j%3</code> for a pink variant |
|- | |- | ||
− | | <code>poke(16320+j,j | + | | <code>poke(16320+j,255/(1+2^(5-j%3-j/5)))</code> || 35 || [[File:Bright blue palette.png]] || <code>2*j%3</code> for a green variant |
|- | |- | ||
− | | <code>poke(16320+j,s(j/15)*255)</code> || | + | | <code>poke(16320+j,s(j/15+s(j%3*3))^2*255)</code>|| 37 || [[File:Green-purple palette.png]] || Cyclic, based on [https://iquilezles.org/www/articles/palettes/palettes.htm] |
|} | |} | ||
+ | |||
+ | The last one is an entire family of palettes. You can replace <code>s(j%3*3)</code> with any function that depends on <code>j%3</code>; this ensures the palette remains cyclic. Some ideas for tweaking the palettes: | ||
+ | * Invert the colors by adding a <code>-1-</code> in the expression | ||
+ | * Flip the blue/red channels & have the entire palette running backwards by using <code>poke(16367-j,...)</code> | ||
+ | * Abuse the default Sweetie 16 palette, by only setting some of the RGB channels, while keeping others as they are. For example, setting all the blue channels to zero: <code>poke(16322+j*3,0)</code>. Here <code>j</code> is between 0 and 15. | ||
Code for testing palettes: | Code for testing palettes: | ||
Line 119: | Line 141: | ||
== Motion blur == | == Motion blur == | ||
− | In TIC-80 API, the <code>pix</code> and <code>poke4</code> functions round numbers towards zero. This can be abused for a motion blur: <code>poke4(i,peek4(i)-.9)</code> maps colors 1 to 15 into one lower value, but value 0 stays | + | In TIC-80 API, the <code>pix</code> and <code>poke4</code> functions round numbers towards zero. This can be abused for a motion blur: <code>poke4(i,peek4(i)-.9)</code> maps colors 1 to 15 into one lower value, but value 0 stays as it is. Like so: |
<syntaxhighlight lang="lua"> | <syntaxhighlight lang="lua"> | ||
Line 128: | Line 150: | ||
end | end | ||
</syntaxhighlight> | </syntaxhighlight> | ||
− | |||
== Updating only some pixels == | == Updating only some pixels == | ||
− | Pixel-based, especially raycasting and raymarching, can become excessively slow. A simple trick to update only ~ half of the pixels, giving a dithered/motion blur look and making the update smoother: | + | Pixel-based effects, especially raycasting and raymarching, can become excessively slow. A simple trick to update only ~ half of the pixels, giving a dithered/motion blur look and making the update smoother: |
<syntaxhighlight lang="lua"> | <syntaxhighlight lang="lua"> | ||
Line 142: | Line 163: | ||
− | == | + | == Examples of effects == |
− | The | + | The effects have not been crunched to keep them readable. |
+ | |||
+ | === Plasma === | ||
+ | |||
+ | <syntaxhighlight lang="lua"> | ||
+ | function TIC() | ||
+ | t=time()/499 | ||
+ | for i=0,32639 do | ||
+ | x=i%240 | ||
+ | y=i/240 | ||
+ | v=s(x/50+t)+s(y/22+t)+s(x/32) | ||
+ | poke4(i,v*2%8) | ||
+ | end | ||
+ | end | ||
+ | s=math.sin | ||
+ | </syntaxhighlight> | ||
+ | |||
+ | === Rotozoomer === | ||
+ | |||
+ | <syntaxhighlight lang="lua"> | ||
+ | function TIC() | ||
+ | t=time()/999 | ||
+ | a=s(t-11) | ||
+ | b=s(t) | ||
+ | for i=0,32639 do | ||
+ | x=i%240-120 | ||
+ | y=i/240-68 | ||
+ | u=a*x-b*y | ||
+ | v=b*x+a*y | ||
+ | poke4(i,(u//1~v//1)//16) | ||
+ | end | ||
+ | end | ||
+ | s=math.sin | ||
+ | </syntaxhighlight> | ||
+ | |||
+ | === Tunnel === | ||
+ | |||
+ | <syntaxhighlight lang="lua"> | ||
+ | function TIC() | ||
+ | t=time()/199 | ||
+ | for i=0,32639 do | ||
+ | x=i%240-s(t/7)*99-120 | ||
+ | y=i/240-s(t/9)*49-68 | ||
+ | u=math.atan2(y,x)*6/6.29 | ||
+ | v=99/(x*x+y*y)^.5+t | ||
+ | poke4(i,u//1~v//1) | ||
+ | end | ||
+ | end | ||
+ | s=math.sin | ||
+ | </syntaxhighlight> | ||
+ | |||
+ | === Raytracer === | ||
+ | |||
+ | The raytraced geometry is a tunnel (cylinder). Note that the texture creates both positive and negative values, but applying the distance based fog to both values makes them darker, due to the way the palette is set. | ||
+ | |||
+ | <syntaxhighlight lang="lua"> | ||
+ | function TIC() | ||
+ | t=time()/199 | ||
+ | for i=0,32639 do | ||
+ | -- set palette so scaling color based | ||
+ | -- on distance works | ||
+ | j=i%48 | ||
+ | poke(16320+j,s(j/15)*255) | ||
+ | -- ray (u,v,w), not normalized! | ||
+ | u=i%240/120-1 | ||
+ | v=i/32639-.5 | ||
+ | w=1 | ||
+ | -- rotate camera | ||
+ | a=s(t/23)*3 | ||
+ | u,w=u*s(a+8)+w*s(a),w*s(a+8)-u*s(a) | ||
+ | -- find where ray hits tunnel wall | ||
+ | d=1/(u*u+v*v)^.5 | ||
+ | z=d*w+t/9 -- move camera with time | ||
+ | q=math.atan2(u,v) | ||
+ | -- tunnel texture ("plasma") | ||
+ | c=s(q*5+s(z)*2)*s(z*2+s(q*3)*3) | ||
+ | poke4(i,c*.8^d*9) -- distance based fog | ||
+ | end | ||
+ | end | ||
+ | s=math.sin | ||
+ | </syntaxhighlight> | ||
+ | |||
+ | === Raymarcher === | ||
+ | |||
+ | The map is a bunch of repeated spheres here. | ||
<syntaxhighlight lang="lua"> | <syntaxhighlight lang="lua"> | ||
Line 173: | Line 278: | ||
end | end | ||
</syntaxhighlight> | </syntaxhighlight> | ||
− | |||
== Additional Resources == | == Additional Resources == | ||
* Code from past bytebattles https://livecode.demozoo.org/ | * Code from past bytebattles https://livecode.demozoo.org/ |
Latest revision as of 03:46, 19 December 2022
Contents
Byte Battles
Byte Battles are a form of live coding, similar to Shader Showdowns, where two contestants compete in writing a visual effect in 25 minutes. The coding environment is the TIC-80 fantasy console. However, unlike Shader Showdowns, there is an additional limit: the final code should be 256 characters or less. This requires the contestants to use efficient code (e.g. single letter variables) and to minimize the code (e.g. remove the whitespace), all within the time limit. Unlike in normal TIC-80 sizecoding, there is no compression, so every character counts.
General notation in this article
Symbol | Meaning |
---|---|
i |
Pixel index |
s |
Alias for math.sin |
x |
Pixel x-coordinate |
y |
Pixel y-coordinate |
Basic optimizations
- Functions, that are called three or more times should be aliased. For example,
e=elli
withe()e()e()
is 3 characters shorter thanelli()elli()elli()
. Functions with 5-character-long names may already benefit from aliasing with two calls:r=rectb
withr()r()
is 1 character shorter thanrectb()rectb()
. -
t=0
witht=t+.01
is 1 character shorter thant=time()*.6
. -
for i=0,32639 do x=i%240y=i/240 end
is 2-3 characters shorter thanfor y=0,135 do for x=0,239 do end end
. -
(x*x+y*y)^.5
is 6 characters shorter thanmath.sqrt(x*x+y*y)
. -
s(w-11)
ands(w+8)
both approximatemath.cos(w)
, so onlymath.sin
needs to be aliased.s(w-11)
is far more accurate, with the cost of one more character.
One-lining
Most whitespace can be removed from LUA code. For example: x=0y=0
is valid. All new lines can be removed or replaced with space, making the whole code a single line:
function TIC()for i=0,32639 do poke4(i,i)end end
Warning: Letters a-f
and A-F
after a number cause problems. a=0b=0
is not valid code. It is advisable to only used one letter variables in the ranges g-z
and G-Z
from the start; this will make eventual one-lining easier.
Load-function
Function load
takes a string of code and returns a function with no named arguments, with the code as its body. It's particularly useful for shortening the TIC function after one-lining:
TIC=load'for i=0,32639 do poke4(i,i)end'
As a rule of thumb, one-lining and using the load trick can bring a ~ 275 character code down to 256.
Any arguments passes to a function defined with load
can be fetched with the ellipsis (...
). For example, SCN=function(x)poke(16320,x)end
can be implemented as:
SCN=load'poke(16320,...)'
This saves 6 characters. Multiple arguments can be fetched with x,y=...
.
Warning: The backslash causes problems when using the load trick. In particular, if you have a string with escaped characters in the original code e.g. print("foo\nbar")
, then this needs to be double-escaped: load'print("foo\\nbar")'
Dithering
If you have a floating point color value, TIC-80 pix
and poke4
functions round it (toward zero). To add dithering, add a small value, between 0 and 1, to the color. The best technique depends whether you have x
and y
available or only i
and how many bytes you can spare:
A quick example demonstrating the 2x2 block dithering:
function TIC()
cls()
for i=0,2399 do
x=i%240
y=i//240
poke4(i,x/30+(x*2-y%2)%4/4)
end
end
Palettes
The following palettes assume that j
goes from 0 to 47. Usually there's no need to make a new loop for this: just reuse another loop with j=i%48
.
Expression | Length | Result | Notes |
---|---|---|---|
poke(16320+j,j*5) |
17 | ||
poke(16320+j,j%3*j*5) |
21 | Good for objects & background | |
poke(16320+j,j%3*j/.4) |
22 | Use (j+1)%3 , (j+2)%3 or 2*j%3 for different colors
| |
poke(16320+j,s(j)^2*255) |
24 | Change the phase of the palette with s(j+p) | |
poke(16320+j,s(j)^2*j*6) |
24 | Change the phase of the palette with s(j+p) | |
poke(16320+j,s(j/15)*255) |
25 | s(j/15)^2 is less bright
| |
poke(16320+j,s(j-j%-3)^2*255) |
29 | j%3*2 for a more blue/beige variant, -j%3*4 for beige/blue variant
| |
poke(16320+j,255/(1+2^(4+j%3-j/5))) |
35 | 2*j%3 for a pink variant
| |
poke(16320+j,255/(1+2^(5-j%3-j/5))) |
35 | 2*j%3 for a green variant
| |
poke(16320+j,s(j/15+s(j%3*3))^2*255) |
37 | Cyclic, based on [1] |
The last one is an entire family of palettes. You can replace s(j%3*3)
with any function that depends on j%3
; this ensures the palette remains cyclic. Some ideas for tweaking the palettes:
- Invert the colors by adding a
-1-
in the expression - Flip the blue/red channels & have the entire palette running backwards by using
poke(16367-j,...)
- Abuse the default Sweetie 16 palette, by only setting some of the RGB channels, while keeping others as they are. For example, setting all the blue channels to zero:
poke(16322+j*3,0)
. Herej
is between 0 and 15.
Code for testing palettes:
function TIC()
cls()
for j=0,47 do poke(16320+j,s(j/15)*255)end
for c=0,15 do rect(c*5,0,5,5,c)end
end
s=math.sin
Motion blur
In TIC-80 API, the pix
and poke4
functions round numbers towards zero. This can be abused for a motion blur: poke4(i,peek4(i)-.9)
maps colors 1 to 15 into one lower value, but value 0 stays as it is. Like so:
function TIC()
t=time()/9
circ(t%240,t%136,9,15)
for i=0,32639 do poke4(i,peek4(i)-.9)end
end
Updating only some pixels
Pixel-based effects, especially raycasting and raymarching, can become excessively slow. A simple trick to update only ~ half of the pixels, giving a dithered/motion blur look and making the update smoother:
function TIC()
t=time()/499
for i=t%2,32639,1.9 do poke4(i,i/4e3+t)end
end
Examples of effects
The effects have not been crunched to keep them readable.
Plasma
function TIC()
t=time()/499
for i=0,32639 do
x=i%240
y=i/240
v=s(x/50+t)+s(y/22+t)+s(x/32)
poke4(i,v*2%8)
end
end
s=math.sin
Rotozoomer
function TIC()
t=time()/999
a=s(t-11)
b=s(t)
for i=0,32639 do
x=i%240-120
y=i/240-68
u=a*x-b*y
v=b*x+a*y
poke4(i,(u//1~v//1)//16)
end
end
s=math.sin
Tunnel
function TIC()
t=time()/199
for i=0,32639 do
x=i%240-s(t/7)*99-120
y=i/240-s(t/9)*49-68
u=math.atan2(y,x)*6/6.29
v=99/(x*x+y*y)^.5+t
poke4(i,u//1~v//1)
end
end
s=math.sin
Raytracer
The raytraced geometry is a tunnel (cylinder). Note that the texture creates both positive and negative values, but applying the distance based fog to both values makes them darker, due to the way the palette is set.
function TIC()
t=time()/199
for i=0,32639 do
-- set palette so scaling color based
-- on distance works
j=i%48
poke(16320+j,s(j/15)*255)
-- ray (u,v,w), not normalized!
u=i%240/120-1
v=i/32639-.5
w=1
-- rotate camera
a=s(t/23)*3
u,w=u*s(a+8)+w*s(a),w*s(a+8)-u*s(a)
-- find where ray hits tunnel wall
d=1/(u*u+v*v)^.5
z=d*w+t/9 -- move camera with time
q=math.atan2(u,v)
-- tunnel texture ("plasma")
c=s(q*5+s(z)*2)*s(z*2+s(q*3)*3)
poke4(i,c*.8^d*9) -- distance based fog
end
end
s=math.sin
Raymarcher
The map is a bunch of repeated spheres here.
function TIC()
for i=0,32639 do
-- ray (u,v,w), not normalized!
u=i%240/120-1
v=i/32639-.5
w=1
-- camera origo (x,y,z)
x=3
y=0
z=time()/999 -- camera moves with time
j=0
repeat
X=x%6-3 -- domain repetition
Y=y%6-3
Z=z%6-3
-- ray not normalized=>reduce scale
m=(X*X+Y*Y+Z*Z)^.5/2-1
x=x+m*u
y=y+m*v
z=z+m*w
j=j+1
until j>15 or m<.1
poke4(i,j)
end
end
Additional Resources
- Code from past bytebattles https://livecode.demozoo.org/