TangentAutomaton V.1.2.2

1. --One Dimensional Cellular Automaton
2. --Adapted from "dominic"'s Lua CA written to use LOVE.
3. --Original version can be found here: http://blog.signalsondisplay.com/?p=60
4. --The only thing I borrowed from his version is the algorithm computer.
5. -----------------------------------------------------------------------------
6. --Tangent Automaton V. 1.2.2
7. --Notes:
8. --Added the ability to define a custom seed to start with.
9.  
10. width = 64 --Set your desired width here!
11. debug = false --Do you want debugging messages?
12. random = false --Start with a randomly generated seed?
13. seed = true --Start with a pre-defined seed?
14. center = false --Start with one center cell?
15.  
16. seeddata={} --Put your seed information here!
17.  
18. height = width / 2
19.  
20. t=true
21. f=false
22.  
23. states = {}
24. rulegiven={}
25. mt={}
26. for i = 1, width do states[i] = 0 end
27. states[width / 2] = 1
28. output={}
29.  
30. ruletable= --The rule lookup table.
31. {
32.     {t,t,t},
33.     {t,t,f},
34.     {t,f,t},
35.     {t,f,f},
36.     {f,t,t},
37.     {f,t,f},
38.     {f,f,t},
39.     {f,f,f}
40. }
41.  
42. function dectobin(input)
43.     conversion={1,2,4,8,16,32,64,128} --I'll make this into 2^n eventually.
44.     output={0,0,0,0,0,0,0,0} --The output table, keeping it like this for now.
45.     i=8 --Starting number to decrement from
46.     for h=1,8 do --It's 8 bit!
47.         input=input-conversion[i] --Grabs the number to convert, and subtracts it from the lookup table.
48.         if debug then print(input) end
49.         if input <0 then --If it's less than 0 (negative)...
50.             input=input+conversion[i] --...undo that subtraction.
51.         else --If it isn't less than 0 (greater than or equal to)...
52.             output[h]=1 --...set the output bit high (change "h" to "i" to swap endianess).
53.         end
54.         i=i-1 --The simple decrementer
55.     end
56. end
57.  
58. ruletable= --My second rule lookup table. I have no idea why I have two.
59. {
60.     {true,true,true},
61.     {true,true,false},
62.     {true,false,true},
63.     {true,false,false},
64.     {false,true,true},
65.     {false,true,false},
66.     {false,false,true},
67.     {false,false,false}
68. }
69.  
70. rule={} --Sets up the actual table the algorithm looks at.
71.  
72. function grabrule() --This function decodes the given rule.
73.     userinput=io.read() --Gets the user's input.
74.     dectobin(userinput) --Sends the input to get decoded into binary.
75.     rulegiven=output --Takes that binary number and sticks it into "rulegiven".
76.     if debug then print(#rulegiven) end
77.     --print(string.len(userinput)) --I might re-implement this later. For now, You'll have to use the decimal system.
78.     --for i=1,string.len(userinput) do
79.     --  rulegiven[i]=string.sub(userinput,i,i)
80.     --end
81.  
82.     if #rulegiven~=8 then --Rather pointless warning since an 8-bit number is ALWAYS created...
83.         print("You must enter an 8-bit number!")
84.     end
85.  
86.     if debug then --more debugging
87.         for j=1,#rulegiven do
88.             io.write(rulegiven[j].." ")
89.         end
90.         io.write("\n")
91.     end
92.  
93.     for k=1,#rulegiven do --This will turn the binary into bollean logic.
94.         if rulegiven[k]==1 then --If the bit is 1...
95.         rulegiven[k]=true --...set it to true (rather pointless, since I could combine this with the next part of the program).
96.         else
97.             rulegiven[k]=false --This is rather pointless, since it's set to "false" by default.
98.         end
99.     end
100.  
101.     rulecounter=1 --A temporary number that helps with keeping the rule table from skipping ahead.
102.  
103.     for i=1,#rulegiven do --For as many rules as there are given...
104.         if rulegiven[i]then --...if the state of the rule is true...
105.             rule[rulecounter]=ruletable[i] --...look at the lookup table, and stick that value into "rule".
106.             rulecounter=rulecounter+1 --Decrements the counter for the "rule" table.
107.         end
108.     end
109. end
110.  
111. function grabseed() --This function asks for an input, and stores it to "state"
112.     seedgiven={} --I always store "binary" data in a table.
113.     print("Please enter a starting seed in binary!")
114.     print("Note: This seed will be placed in the center of the algorithm.")
115.     inputseed=io.read() --Asks for the seed.
116.     for i=1,string.len(inputseed) do --This loop chops the user input up, and stuffs it into my table.
117.         seedgiven[i]=string.sub(inputseed,i,i)
118.     end
119.     for i=1,#seedgiven do --Appearently, it's a string, and I need numbers.
120.         if seedgiven[i]=="1" then --If the string is a "1"...
121.             seedgiven[i]=1 --...make it into a number 1...
122.         else
123.             seedgiven[i]=0 --...else it's a 0.
124.         end
125.     end
126.     bitshift=((width-#seedgiven)/2) --To find how much the data should be shifted, the lenght of the given seed is subtracted from the width, then divided by 2.
127.     bitshift=math.floor(bitshift) --If it's an odd number, it gets rounded down.
128.     j=bitshift --To keep the two numbers synced.
129.     for i=1,#seedgiven do --This stores the given string into the "states" table.
130.         states[j]=seedgiven[i]
131.         j=j+1 --To keep j and i in sync.
132.     end
133.    
134. end
135.  
136.  
137. function compute_next_gen(index) --Here's where all the computation happens.
138.     --mt[1][(#states / 2)+1]="#"
139.     current_gen = {} --This table stores the current information to get computed.
140.     for i = 1, #states do --This just stores the data from the current bit into the p, c, and n registers.
141.         p = states[i - 1] == 1
142.         c = states[i] == 1
143.         n = states[i + 1] == 1
144.         current_gen[i] = 0 --Once that's done, it sets the gen back to 0 to do the actual computation.
145.         for j = 1, #rule do --It computes for as many rules it is given.
146.             if (p == rule[j][1] and c == rule[j][2] and n == rule[j][3]) then --If it complies with the rules...
147.                 current_gen[i] = 1 --...set the current cell to an "on" state.
148.                 mt[index+1][i + 1]="#" --Stores it in my matrix.
149.             end
150.         end
151.     end
152.     states = current_gen
153. end
154.  
155. print("Please take a look at the top of this script to configure it!")
156.  
157. if seed then
158.     grabseed()
159.     grabrule()
160. elseif center then
161.     grabrule()
162. elseif random then
163.     grabrule()
164. end
165.  
166.  
167. for i=1,height+1 do --This loop sets up my matrix with a spacing character.
168.     mt[i] = {}
169.     for j=1,width+1 do
170.         mt[i][j] = " "
171.     end
172. end
173.  
174. --for i=1,width do
175. --  states[i]=math.random(0,1)
176. --end
177.  
178. for i=1,width do
179.     if states[i]==1 then
180.         mt[1][i+1]="#"
181.     else
182.         mt[1][i+1]=" "
183.     end
184. end
185.  
186. if debug then print("This automaton uses "..#rule.." rules.") end --Disregard this, it's for debugging.
187. if debug then
188.     for a=1,#rule do
189.         for b=1,3 do
190.             if rule[a][b] then
191.                 io.write("true")
192.             else
193.                 io.write("false")
194.             end
195.         end
196.         io.write("\n")
197.     end
198. end
199.  
200. for i = 1, height do --This runs the computation function for the desired height.
201.     compute_next_gen(i)
202. end
203.  
204. for a=1,height do --This loop actually prints out my matrix, displaying the pretty pattern!
205.     for b=1,width do
206.         io.write(mt[a][b])
207.     end
208.     io.write("\n")
209. end