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145 lines
6.5 KiB
Markdown
145 lines
6.5 KiB
Markdown
---
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language: Wolfram
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contributors:
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- ["hyphz", "http://github.com/hyphz/"]
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filename: learnwolfram.nb
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---
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The Wolfram Language is the underlying language originally used in Mathematica,
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but now available for use in multiple contexts.
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Wolfram Language has several interfaces:
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* The command line kernel interface on Raspberry Pi (just called _The Wolfram Language_)
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which runs interactively and can't produce graphical input.
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* _Mathematica_ which is a rich text/maths editor with interactive Wolfram built in:
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Pressing <kbd>shift</kbd> + <kbd>Return</kbd> on a "code cell"
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creates an output cell with the result, which is not dynamic.
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* _Wolfram Workbench_ which is Eclipse interfaced to the Wolfram Language backend.
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The code in this example can be typed in to any interface and edited with Wolfram Workbench.
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Loading directly into Mathematica may be awkward because the file contains no cell formatting information
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(which would make the file a huge mess to read as text) - it can be viewed/edited but may require some setting up.
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```mathematica
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(* This is a comment *)
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(* In Mathematica instead of using these comments you can create a text cell
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and annotate your code with nicely typeset text and images *)
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(* Typing an expression returns the result *)
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2*2 (* 4 *)
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5+8 (* 13 *)
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(* Function Call *)
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(* Note, function names (and everything else) are case sensitive *)
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Sin[Pi/2] (* 1 *)
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(* Alternate Syntaxes for Function Call with one parameter *)
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Sin@(Pi/2) (* 1 *)
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(Pi/2) // Sin (* 1 *)
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(* Every syntax in WL has some equivalent as a function call *)
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Times[2, 2] (* 4 *)
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Plus[5, 8] (* 13 *)
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(* Using a variable for the first time defines it and makes it global *)
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x = 5 (* 5 *)
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x == 5 (* True, C-style assignment and equality testing *)
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x (* 5 *)
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x = x + 5 (* 10 *)
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x (* 10 *)
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Set[x, 20] (* I wasn't kidding when I said EVERYTHING has a function equivalent *)
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x (* 20 *)
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(* Because WL is based on a computer algebra system, *)
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(* using undefined variables is fine, they just obstruct evaluation *)
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cow + 5 (* 5 + cow, cow is undefined so can't evaluate further *)
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cow + 5 + 10 (* 15 + cow, it'll evaluate what it can *)
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% (* 15 + cow, % fetches the last return *)
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% - cow (* 15, undefined variable cow cancelled out *)
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moo = cow + 5 (* Beware, moo now holds an expression, not a number! *)
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(* Defining a function *)
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Double[x_] := x * 2 (* Note := to prevent immediate evaluation of the RHS
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And _ after x to indicate no pattern matching constraints *)
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Double[10] (* 20 *)
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Double[Sin[Pi/2]] (* 2 *)
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Double @ Sin @ (Pi/2) (* 2, @-syntax avoids queues of close brackets *)
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(Pi/2) // Sin // Double(* 2, //-syntax lists functions in execution order *)
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(* For imperative-style programming use ; to separate statements *)
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(* Discards any output from LHS and runs RHS *)
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MyFirst[] := (Print@"Hello"; Print@"World") (* Note outer parens are critical
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;'s precedence is lower than := *)
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MyFirst[] (* Hello World *)
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(* C-Style For Loop *)
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PrintTo[x_] := For[y=0, y<x, y++, (Print[y])] (* Start, test, incr, body *)
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PrintTo[5] (* 0 1 2 3 4 *)
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(* While Loop *)
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x = 0; While[x < 2, (Print@x; x++)] (* While loop with test and body *)
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(* If and conditionals *)
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x = 8; If[x==8, Print@"Yes", Print@"No"] (* Condition, true case, else case *)
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Switch[x, 2, Print@"Two", 8, Print@"Yes"] (* Value match style switch *)
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Which[x==2, Print@"No", x==8, Print@"Yes"] (* Elif style switch *)
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(* Variables other than parameters are global by default, even inside functions *)
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y = 10 (* 10, global variable y *)
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PrintTo[5] (* 0 1 2 3 4 *)
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y (* 5, global y clobbered by loop counter inside PrintTo *)
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x = 20 (* 20, global variable x *)
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PrintTo[5] (* 0 1 2 3 4 *)
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x (* 20, x in PrintTo is a parameter and automatically local *)
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(* Local variables are declared using the Module metafunction *)
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(* Version with local variable *)
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BetterPrintTo[x_] := Module[{y}, (For[y=0, y<x, y++, (Print@y)])]
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y = 20 (* Global variable y *)
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BetterPrintTo[5] (* 0 1 2 3 4 *)
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y (* 20, that's better *)
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(* Module actually lets us declare any scope we like *)
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Module[{count}, count=0; (* Declare scope of this variable count *)
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(IncCount[] := ++count); (* These functions are inside that scope *)
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(DecCount[] := --count)]
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count (* count - global variable count is not defined *)
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IncCount[] (* 1, using the count variable inside the scope *)
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IncCount[] (* 2, incCount updates it *)
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DecCount[] (* 1, so does decCount *)
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count (* count - still no global variable by that name *)
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(* Lists *)
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myList = {1, 2, 3, 4} (* {1, 2, 3, 4} *)
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myList[[1]] (* 1 - note list indexes start at 1, not 0 *)
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Map[Double, myList] (* {2, 4, 6, 8} - functional style list map function *)
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Double /@ myList (* {2, 4, 6, 8} - Abbreviated syntax for above *)
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Scan[Print, myList] (* 1 2 3 4 - imperative style loop over list *)
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Fold[Plus, 0, myList] (* 10 (0+1+2+3+4) *)
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FoldList[Plus, 0, myList] (* {0, 1, 3, 6, 10} - fold storing intermediate results *)
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Append[myList, 5] (* {1, 2, 3, 4, 5} - note myList is not updated *)
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Prepend[myList, 5] (* {5, 1, 2, 3, 4} - add "myList = " if you want it to be *)
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Join[myList, {3, 4}] (* {1, 2, 3, 4, 3, 4} *)
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myList[[2]] = 5 (* {1, 5, 3, 4} - this does update myList *)
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(* Associations, aka Dictionaries/Hashes *)
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myHash = <|"Green" -> 2, "Red" -> 1|> (* Create an association *)
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myHash[["Green"]] (* 2, use it *)
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myHash[["Green"]] := 5 (* 5, update it *)
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myHash[["Puce"]] := 3.5 (* 3.5, extend it *)
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KeyDropFrom[myHash, "Green"] (* Wipes out key Green *)
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Keys[myHash] (* {Red, Puce} *)
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Values[myHash] (* {1, 3.5} *)
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(* And you can't do any demo of Wolfram without showing this off *)
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Manipulate[y^2, {y, 0, 20}] (* Return a reactive user interface that displays y^2
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and allows y to be adjusted between 0-20 with a slider.
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Only works on graphical frontends *)
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```
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##Ready For More?
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* [Wolfram Language Documentation Center](http://reference.wolfram.com/language/)
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