ApCoCoA-1:HowTo:Run ApCoCoA on a Computing Server
This HowTo shows you how to run ApCoCoA on a Linux server with terminal.
- Download ApCoCoA QT and unzip the file. (This HowTo takes ApCoCoA 1.9.0 as an example.)
wget http://www.apcocoa.org/download/apcocoa/linux-x86_64/apcocoa-1.9.0-QT-linux-x86_64.tgz tar xzvf apcocoa-1.9.0-QT-linux-x86_64.tgz
- Recommend to use a tool like "screen" (http://www.gnu.org/software/screen/screen.html) or "tmux" (http://tmux.sourceforge.net/) which allows you to run apcocoa(server) in the background, so that you can log off from the terminal session without having to stop the program.
Go to the folder ApCoCoA-1.9.0. The contents in the folder are as follows.
In the following, assume that you are working at the directory ApCoCoA-1.9.0/.
ApCoCoA with Text Interface
Run the following command at terminal to start the ApCoCoA text interface.
You can run any (Ap)CoCoA command in this interface.
In many cases you also need to run the ApCoCoAServer. Here, assume that you have some terminal tools, like "screen", "tmux", etc., to create new terminal sessions, and that you are able to switch between terminal sessions without having to stop the running program.
Create a new terminal session for the ApCoCoAServer and run the following command to start the ApCoCoAServer.
Observe that the ApCoCoAServer is running on the default port 49344 (0xc0c0). One can change the port number to n by using option -p as follows.
./ApCoCoAServer -p n
Now let us switch to the terminal session for the ApCoCoA text interface again. Execute the following commands.
X:="xy"; M:=["xxx","yxy","xyx"]; NCo.IsFinite(X, M); -- Check whether <x,y>/<x^3,yxy,xyx> is finite
The function NCo.IsFinite uses the ApCoCoAServer. You will get the following result in the ApCoCoA text interface.
And you can see the following message in the terminal session for the ApCoCoAServer.
ApCoCoA Program Files
Sometimes it is useful to write commands or functions in ApCoCoA program files.
For example, the following function computes Fibonacci numbers. Assume that we write the function in a ApCoCoA program file, say test.coc, in the directory ApCoCoA-1.9.0/.
Define Fib(N) If N<=1 Then Return 0; Elif N=2 Then Return 1; Else Return Fib(N-2)+Fib(N-1); EndIf; EndDefine;
Using the following command, ApCoCoA process
Then we can process the file as batch files and then ask ApCoCoA to process them when it starts.
For example, we have a presentation for SL(3,8) as follows. and we wa put the following commands in a file named SL_3_8.coc.
/* SL(3,8) has a presentation with generators a, b, c, d, e and the following relators a^2, b^2, c^7, de, ed, (cb)^2, (ba)^3, (acac^6)^2, c^2ac^6ac^5ac, dbe^2, (ce)^2cd^2 aead(ae)^2babd^2, eadae^2babd^2(ae)^2babd^2, ec^6daecdc^6aca, ec^6daecec^6d^2ae^2cd^2, ec^6daecec^6d^2ae^2cd^2. The following commands check whether the last relator, i.e. ec^6daecec^6d^2ae^2cd^2 can be rewritten by the others, via Groebner basis techniques. */ Use ZZ/(2)[a,b,c,d,e]; G:=[[[a^2], ], [[b^2], ], [[c^7], ], [[d, e], ], [[e, d], ], [[c, b, c, b], ], [[b, a, b, a, b, a], ], [[a, c, a, c^6, a, c, a, c^6], ], [[c^2, a, c^6, a, c^5, a, c], ], [[b, d, b, e^2], ], [[c, e, c, e, c, d^2], ], [[a, e, a, d, a, e, a, e, b, a, b, d^2], ], [[e, a, d, a, e^2, b, a, b, d^2, a, e, a, e, b, a, b, d^2], ], [[e, c^6, d, a, e, c, d, c^6, a, c, a], ]]; F:=[ [e,c^6, d, a, e, c, e, c^6, d^2, a, e^2, c, d^2] ]; Gb:=NC.GB(G,31,1,100,5000); NC.NR(F,Gb);