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213 lines
5.9 KiB
Markdown
213 lines
5.9 KiB
Markdown
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---
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language: citron
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filename: learncitron.ctr
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contributors:
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- ["AnotherTest", ""]
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lang: en-us
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---
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```ruby
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# Comments start with a '#'
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# All comments encompass a single line
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###########################################
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## 1. Primitive Data types and Operators
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###########################################
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# You have numbers
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3. # 3
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# Numbers are all doubles in interpreted mode
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# Mathematical operator precedence is not respected.
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# binary 'operators' are evaluated in ltr order
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1 + 1. # 2
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8 - 4. # 4
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10 + 2 * 3. # 36
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# Division is always floating division
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35 / 2 # 17.5.
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# Integer division is non-trivial, you may use floor
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(35 / 2) floor # 17.
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# Booleans are primitives
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True.
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False.
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# Boolean messages
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True not. # False
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False not. # True
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1 = 1. # True
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1 !=: 1. # False
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1 < 10. # True
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# Here, `not` is a unary message to the object `Boolean`
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# Messages are comparable to instance method calls
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# And they have three different forms:
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# 1. Unary messages: Length > 1, and they take no arguments:
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False not.
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# 2. Binary Messages: Length = 1, and they take a single argument:
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False & True.
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# 3. Keyword messages: must have at least one ':', they take as many arguments
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# as they have `:` s
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False either: 1 or: 2. # 2
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# Strings
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'This is a string'.
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'There are no character types exposed to the user'.
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# "You cannot use double quotes for strings" <- Error
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# Strins can be summed
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'Hello, ' + 'World!'. # 'Hello, World!'
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# Strings allow access to their characters
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'This is a beautiful string' at: 0. # 'T'
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###########################################
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## intermission: Basic Assignment
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###########################################
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# You may assign values to the current scope:
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var name is value. # assignes `value` into `name`
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# You may also assign values into the current object's namespace
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my name is value. # assigns `value` into the current object's `name` property
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# Please note that these names are checked at compile (read parse if in interpreted mode) time
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# but you may treat them as dynamic assignments anyway
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###########################################
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## 2. Lists(Arrays?) and Tuples
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###########################################
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# Arrays are allowed to have multiple types
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Array new < 1 ; 2 ; 'string' ; Nil. # Array new < 1 ; 2 ; 'string' ; Nil
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# Tuples act like arrays, but are immutable.
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# Any shenanigans degrade them to arrays, however
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[1, 2, 'string']. # [1, 2, 'string']
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# They can interoperate with arrays
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[1, 'string'] + (Array new < 'wat'). # Array new < 1 ; 'string' ; 'wat'
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# Indexing into them
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[1, 2, 3] at: 1. # 2
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# Some array operations
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var arr is Array new < 1 ; 2 ; 3.
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arr head. # 1
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arr tail. # Array new < 2 ; 3.
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arr init. # Array new < 1 ; 2.
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arr last. # 3
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arr push: 4. # Array new < 1 ; 2 ; 3 ; 4.
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arr pop. # 4
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arr pop: 1. # 2, `arr` is rebound to Array new < 1 ; 3.
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# List comprehensions
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[x * 2 + y,, arr, arr + [4, 5],, x > 1]. # Array ← 7 ; 9 ; 10 ; 11
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# fresh variable names are bound as they are encountered,
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# so `x` is bound to the values in `arr`
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# and `y` is bound to the values in `arr + [4, 5]`
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#
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# The general format is: [expr,, bindings*,, predicates*]
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####################################
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## 3. Functions
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####################################
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# A simple function that takes two variables
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var add is {:a:b ^a + b.}.
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# this function will resolve all its names except the formal arguments
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# in the context it is called in.
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# Using the function
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add applyTo: 3 and: 5. # 8
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add applyAll: [3, 5]. # 8
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# Also a (customizable -- more on this later) pseudo-operator allows for a shorthand
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# of function calls
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# By default it is REF[args]
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add[3, 5]. # 8
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# To customize this behaviour, you may simply use a compiler pragma:
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#:callShorthand ()
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# And then you may use the specified operator.
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# Note that the allowed 'operator' can only be made of any of these: []{}()
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# And you may mix-and-match (why would anyone do that?)
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add(3, 5). # 8
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# You may also use functions as operators in the following way:
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3 `add` 5. # 8
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# This call binds as such: add[(3), 5]
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# because the default fixity is left, and the default precedance is 1
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# You may change the precedence/fixity of this operator with a pragma
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#:declare infixr 1 add
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3 `add` 5. # 8
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# now this binds as such: add[3, (5)].
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# There is another form of functions too
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# So far, the functions were resolved in a dynamic fashion
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# But a lexically scoped block is also possible
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var sillyAdd is {\:x:y add[x,y].}.
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# In these blocks, you are not allowed to declare new variables
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# Except with the use of Object::'letEqual:in:`
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# And the last expression is implicitly returned.
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# You may also use a shorthand for lambda expressions
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var mul is \:x:y x * y.
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# These capture the named bindings that are not present in their
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# formal parameters, and retain them. (by ref)
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###########################################
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## 5. Control Flow
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###########################################
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# inline conditional-expressions
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var citron is 1 = 1 either: 'awesome' or: 'awful'. # citron is 'awesome'
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# multiple lines is fine too
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var citron is 1 = 1
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either: 'awesome'
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or: 'awful'.
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# looping
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10 times: {:x
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Pen writeln: x.
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}. # 10. -- side effect: 10 lines in stdout, with numbers 0 through 9 in them
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# Citron properly supports tail-call recursion in lexically scoped blocks
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# So use those to your heart's desire
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# mapping most data structures is as simple as `fmap:`
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[1, 2, 3, 4] fmap: \:x x + 1. # [2, 3, 4, 5]
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# You can use `foldl:accumulator:` to fold a list/tuple
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[1, 2, 3, 4] foldl: (\:acc:x acc * 2 + x) accumulator: 4. # 90
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# That expression is the same as
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(2 * (2 * (2 * (2 * 4 + 1) + 2) + 3) + 4)
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###################################
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## 6. IO
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###################################
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# IO is quite simple
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# With `Pen` being used for console output
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# and Program::'input' and Program::'waitForInput' being used for console input
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Pen writeln: 'Hello, ocean!' # prints 'Hello, ocean!\n' to the terminal
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Pen writeln: Program waitForInput. # reads a line and prints it back
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```
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