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183 lines
7.6 KiB
Factor
183 lines
7.6 KiB
Factor
---
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language: factor
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contributors:
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- ["hyphz", "http://github.com/hyphz/"]
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filename: learnfactor.factor
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---
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Factor is a modern stack-based language, based on Forth, created by Slava Pestov.
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Code in this file can be typed into Factor, but not directly imported because the vocabulary and import header would make the beginning thoroughly confusing.
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```factor
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! This is a comment
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! Like Forth, all programming is done by manipulating the stack.
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! Stating a literal value pushes it onto the stack.
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5 2 3 56 76 23 65 ! No output, but stack is printed out in interactive mode
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! Those numbers get added to the stack, from left to right.
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! .s prints out the stack non-destructively.
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.s ! 5 2 3 56 76 23 65
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! Arithmetic works by manipulating data on the stack.
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5 4 + ! No output
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! `.` pops the top result from the stack and prints it.
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. ! 9
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! More examples of arithmetic:
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6 7 * . ! 42
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1360 23 - . ! 1337
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12 12 / . ! 1
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13 2 mod . ! 1
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99 neg . ! -99
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-99 abs . ! 99
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52 23 max . ! 52
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52 23 min . ! 23
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! A number of words are provided to manipulate the stack, collectively known as shuffle words.
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3 dup - ! duplicate the top item (1st now equals 2nd): 3 - 3
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2 5 swap / ! swap the top with the second element: 5 / 2
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4 0 drop 2 / ! remove the top item (don't print to screen): 4 / 2
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1 2 3 nip .s ! remove the second item (similar to drop): 1 3
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1 2 clear .s ! wipe out the entire stack
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1 2 3 4 over .s ! duplicate the second item to the top: 1 2 3 4 3
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1 2 3 4 2 pick .s ! duplicate the third item to the top: 1 2 3 4 2 3
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! Creating Words
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! The `:` word sets Factor into compile mode until it sees the `;` word.
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: square ( n -- n ) dup * ; ! No output
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5 square . ! 25
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! We can view what a word does too.
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! \ suppresses evaluation of a word and pushes its identifier on the stack instead.
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\ square see ! : square ( n -- n ) dup * ;
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! After the name of the word to create, the declaration between brackets gives the stack effect.
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! We can use whatever names we like inside the declaration:
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: weirdsquare ( camel -- llama ) dup * ;
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! Provided their count matches the word's stack effect:
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: doubledup ( a -- b ) dup dup ; ! Error: Stack effect declaration is wrong
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: doubledup ( a -- a a a ) dup dup ; ! Ok
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: weirddoubledup ( i -- am a fish ) dup dup ; ! Also Ok
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! Where Factor differs from Forth is in the use of quotations.
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! A quotation is a block of code that is pushed on the stack as a value.
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! [ starts quotation mode; ] ends it.
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[ 2 + ] ! Quotation that adds 2 is left on the stack
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4 swap call . ! 6
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! And thus, higher order words. TONS of higher order words.
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2 3 [ 2 + ] dip .s ! Pop top stack value, run quotation, push it back: 4 3
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3 4 [ + ] keep .s ! Copy top stack value, run quotation, push the copy: 7 4
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1 [ 2 + ] [ 3 + ] bi .s ! Run each quotation on the top value, push both results: 3 4
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4 3 1 [ + ] [ + ] bi .s ! Quotations in a bi can pull values from deeper on the stack: 4 5 ( 1+3 1+4 )
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1 2 [ 2 + ] bi@ .s ! Run the quotation on first and second values
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2 [ + ] curry ! Inject the given value at the start of the quotation: [ 2 + ] is left on the stack
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! Conditionals
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! Any value is true except the built-in value f.
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! A built-in value t does exist, but its use isn't essential.
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! Conditionals are higher order words as with the combinators above.
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5 [ "Five is true" . ] when ! Five is true
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0 [ "Zero is true" . ] when ! Zero is true
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f [ "F is true" . ] when ! No output
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f [ "F is false" . ] unless ! F is false
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2 [ "Two is true" . ] [ "Two is false" . ] if ! Two is true
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! By default the conditionals consume the value under test, but starred variants
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! leave it alone if it's true:
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5 [ . ] when* ! 5
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f [ . ] when* ! No output, empty stack, f is consumed because it's false
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! Loops
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! You've guessed it.. these are higher order words too.
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5 [ . ] each-integer ! 0 1 2 3 4
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4 3 2 1 0 5 [ + . ] each-integer ! 0 2 4 6 8
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5 [ "Hello" . ] times ! Hello Hello Hello Hello Hello
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! Here's a list:
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{ 2 4 6 8 } ! Goes on the stack as one item
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! Loop through the list:
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{ 2 4 6 8 } [ 1 + . ] each ! Prints 3 5 7 9
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{ 2 4 6 8 } [ 1 + ] map ! Leaves { 3 5 7 9 } on stack
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! Loop reducing or building lists:
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{ 1 2 3 4 5 } [ 2 mod 0 = ] filter ! Keeps only list members for which quotation yields true: { 2 4 }
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{ 2 4 6 8 } 0 [ + ] reduce . ! Like "fold" in functional languages: prints 20 (0+2+4+6+8)
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{ 2 4 6 8 } 0 [ + ] accumulate . . ! Like reduce but keeps the intermediate values in a list: prints { 0 2 6 12 } then 20
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1 5 [ 2 * dup ] replicate . ! Loops the quotation 5 times and collects the results in a list: { 2 4 8 16 32 }
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1 [ dup 100 < ] [ 2 * dup ] produce ! Loops the second quotation until the first returns false and collects the results: { 2 4 8 16 32 64 128 }
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! If all else fails, a general purpose while loop:
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1 [ dup 10 < ] [ "Hello" . 1 + ] while ! Prints "Hello" 10 times
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! Yes, it's hard to read
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! That's what all those variant loops are for
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! Variables
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! Usually Factor programs are expected to keep all data on the stack.
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! Using named variables makes refactoring harder (and it's called Factor for a reason)
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! Global variables, if you must:
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SYMBOL: name ! Creates name as an identifying word
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"Bob" name set-global ! No output
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name get-global . ! "Bob"
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! Named local variables are considered an extension but are available
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! In a quotation..
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[| m n ! Quotation captures top two stack values into m and n
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| m n + ] ! Read them
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! Or in a word..
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:: lword ( -- ) ! Note double colon to invoke lexical variable extension
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2 :> c ! Declares immutable variable c to hold 2
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c . ; ! Print it out
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! In a word declared this way, the input side of the stack declaration
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! becomes meaningful and gives the variable names stack values are captured into
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:: double ( a -- result ) a 2 * ;
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! Variables are declared mutable by ending their name with a shriek
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:: mword2 ( a! -- x y ) ! Capture top of stack in mutable variable a
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a ! Push a
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a 2 * a! ! Multiply a by 2 and store result back in a
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a ; ! Push new value of a
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5 mword2 ! Stack: 5 10
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! Lists and Sequences
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! We saw above how to push a list onto the stack
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0 { 1 2 3 4 } nth ! Access a particular member of a list: 1
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10 { 1 2 3 4 } nth ! Error: sequence index out of bounds
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1 { 1 2 3 4 } ?nth ! Same as nth if index is in bounds: 2
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10 { 1 2 3 4 } ?nth ! No error if out of bounds: f
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{ "at" "the" "beginning" } "Append" prefix ! { "Append" "at" "the" "beginning" }
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{ "Append" "at" "the" } "end" suffix ! { "Append" "at" "the" "end" }
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"in" 1 { "Insert" "the" "middle" } insert-nth ! { "Insert" "in" "the" "middle" }
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"Concat" "enate" append ! "Concatenate" - strings are sequences too
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"Concatenate" "Reverse " prepend ! "Reverse Concatenate"
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{ "Concatenate " "seq " "of " "seqs" } concat ! "Concatenate seq of seqs"
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{ "Connect" "subseqs" "with" "separators" } " " join ! "Connect subseqs with separators"
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! And if you want to get meta, quotations are sequences and can be dismantled..
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0 [ 2 + ] nth ! 2
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1 [ 2 + ] nth ! +
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[ 2 + ] \ - suffix ! Quotation [ 2 + - ]
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```
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##Ready For More?
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* [Factor Documentation](http://docs.factorcode.org/content/article-help.home.html)
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