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383 lines
12 KiB
Markdown
383 lines
12 KiB
Markdown
---
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language: tailspin
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filename: learntailspin.tt
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contributors:
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- ["Torbjörn Gannholm", "https://github.com/tobega/"]
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---
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**Tailspin** works with streams of values in pipelines. You may often feel
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that your program is the machine and that the input data is the program.
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While Tailspin is unlikely to become mainstream, or even production-ready,
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it will change the way you think about programming in a good way.
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```c
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// Comment to end of line
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// Process data in a pipeline with steps separated by ->
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// String literals are delimited by single quotes
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// A bang (!) indicates a sink, or end of the pipe
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// OUT is the standard output object, ::write is the message to write output
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'Hello, World!' -> !OUT::write
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// Output a newline by just entering it in the string (multiline strings)
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'
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' -> !OUT::write
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// Or output the decimal unicode value for newline (10) between $# and ;
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'$#10;' -> !OUT::write
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// Define an immutable named value. Value syntax is very literal.
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def names: ['Adam', 'George', 'Jenny', 'Lucy'];
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// Stream the list to process each name. Note the use of $ to get the value.
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// The current value in the pipeline is always just $
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// String interpolation starts with a $ and ends with ;
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$names... -> 'Hello $;!
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' -> !OUT::write
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// You can also stream in the interpolation and nest interpolations
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// Note the list indexing with parentheses and the slice extraction
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// Note the use of ~ to signify an exclusive bound to the range
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// Outputs 'Hello Adam, George, Jenny and Lucy!'
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'Hello $names(first);$names(first~..~last)... -> ', $;'; and $names(last);!
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' -> !OUT::write
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// Conditionally say different things to different people
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// Matchers (conditional expressions) are delimited by angle brackets
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// A set of matchers, evaluated top down, must be in templates (a function)
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// Here it is an inline templates delimited by \( to \)
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// Note the doubled '' and $$ to get a literal ' and $
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$names... -> \(
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when <='Adam'> do 'What''s up $;?' !
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when <='George'> do 'George, where are the $$10 you owe me?' !
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otherwise 'Hello $;!' !
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\) -> '$;$#10;' -> !OUT::write
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// You can also define templates (functions)
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// A lone ! emits the value into the calling pipeline without returning control
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// The # sends the value to be matched by the matchers
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// Note that templates always take one input value and emit 0 or more outputs
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templates collatz-sequence
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when <..0> do 'The start seed must be a positive integer' !
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when <=1> do $!
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// The ?( to ) allows matching a computed value. Can be concatenated as "and"
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when <?($ mod 2 <=1>)> do
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$ !
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3 * $ + 1 -> #
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otherwise
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$ !
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$ ~/ 2 -> #
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end collatz-sequence
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// Collatz sequence from random start on one line separated by spaces
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1000 -> SYS::randomInt -> $ + 1 -> collatz-sequence -> '$; ' -> !OUT::write
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'
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' -> !OUT::write
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// Collatz sequence formatted ten per line by an indexed list template
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// Note the square brackets creates a list of the enclosed pipeline results
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// The \[i]( to \) defines a templates to apply to each value of a list,
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// the i (or whatever identifier you choose) holds the index
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[1000 -> SYS::randomInt -> $ + 1 -> collatz-sequence]
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-> \[i](
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when <=1|?($i mod 10 <=0>)> do '$;$#10;' !
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otherwise '$; ' !
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\)... -> !OUT::write
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// A range can have an optional stride
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def odd-numbers: [1..100:2];
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// Use mutable state locally. One variable per templates, always called @
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templates product
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@: $(first);
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$(first~..last)... -> @: $@ * $;
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$@ !
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end product
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$odd-numbers(6..8) -> product -> !OUT::write
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'
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' -> !OUT::write
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// Use processor objects to hold mutable state.
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// Note that the outer @ must be referred to by name in inner contexts
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// A sink templates gives no output and is called prefixed by !
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// A source templates takes no input and is called prefixed by $
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processor Product
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@: 1;
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sink accumulate
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@Product: $@Product * $;
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end accumulate
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source result
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$@Product !
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end result
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end Product
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// The processor is a constructor templates. This one called with $ (no input)
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def multiplier: $Product;
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// Call object templates by sending messages with ::
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1..7 -> !multiplier::accumulate
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-1 -> !multiplier::accumulate
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$multiplier::result -> 'The product is $;
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' -> !OUT::write
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// Syntax sugar for a processor implementing the collector interface
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1..7 -> ..=Product -> 'The collected product is $;$#10;' -> !OUT::write
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// Symbol sets (essentially enums) can be defined for finite sets of values
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data colour #{green, red, blue, yellow}
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// Use processor typestates to model state cleanly.
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// The last named mutable state value set determines the typestate
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processor Lamp
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def colours: $;
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@Off: 0;
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state Off
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source switchOn
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@On: $@Off mod $colours::length + 1;
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'Shining a $colours($@On); light$#10;' !
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end switchOn
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end Off
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state On
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source turnOff
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@Off: $@On;
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'Lamp is off$#10;' !
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end turnOff
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end On
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end Lamp
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def myLamp: [colour#green, colour#blue] -> Lamp;
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$myLamp::switchOn -> !OUT::write // Shining a green light
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$myLamp::turnOff -> !OUT::write // Lamp is off
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$myLamp::switchOn -> !OUT::write // Shining a blue light
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$myLamp::turnOff -> !OUT::write // Lamp is off
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$myLamp::switchOn -> !OUT::write // Shining a green light
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// Use regular expressions to test strings
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['banana', 'apple', 'pear', 'cherry']... -> \(
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when <'.*a.*'> do '$; contains an ''a''' !
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otherwise '$; has no ''a''' !
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\) -> '$;
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' -> !OUT::write
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// Use composers with regular expressions and defined rules to parse strings
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composer parse-stock-line
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{inventory-id: <INT> (<WS>), name: <'\w+'> (<WS>), currency: <'.{3}'>,
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unit-price: <INT> (<WS>?) <parts>?}
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rule parts: associated-parts: [<part>+]
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rule part: <'[A-Z]\d+'> (<=','>?)
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end parse-stock-line
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'705 gizmo EUR5 A67,G456,B32' -> parse-stock-line -> !OUT::write
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// {associated-parts: [A67, G456, B32], currency: EUR,
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// inventory-id: 705, name: gizmo, unit-price: 5}
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'
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' -> !OUT::write
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// Stream a string to split it into glyphs.
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// A list can be indexed/sliced by an array of indexes
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// Outputs ['h','e','l','l','o'], indexing arrays/lists starts at 1
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['abcdefghijklmnopqrstuvwxyz'...] -> $([8,5,12,12,15]) -> !OUT::write
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'
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' -> !OUT::write
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// We have used only raw strings above.
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// Strings can have different types as determined by a tag.
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// Comparing different types is an error, unless a wider type bound is set
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// Type bound is given in ´´ and '' means any string value, tagged or raw
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templates get-string-type
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when <´''´ '.*'> do '$; is a raw string' !
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when <´''´ id´'\d+'> do '$; is a numeric id string' !
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when <´''´ =id´'foo'> do 'id foo found' !
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when <´''´ id´'.*'> do '$; is an id' !
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when <´''´ name´'.+'> do '$; is a name' !
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otherwise '$; is not a name or id, nor a raw string' !
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end get-string-type
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[name´'Anna', 'foo', id´'789', city´'London', id´'xzgh', id´'foo']...
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-> get-string-type -> '$;
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' -> !OUT::write
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// Numbers can be raw, tagged or have a unit of measure
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// Type .. is any numeric value, tagged, measure or raw
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templates get-number-type
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when <´..´ =inventory-id´86> do 'inventory-id 86 found' !
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when <´..´ inventory-id´100..> do '$; is an inventory-id >= 100' !
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when <´..´ inventory-id´0..|..inventory-id´0> do '$; is an inventory-id' !
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when <´..´ 0"m"..> do '$; is an m-measure >= 0"m"' !
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when <´..´ ..0|0..> do '$; is a raw number' !
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otherwise '$; is not a positive m-measure nor an inventory-id, nor raw' !
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end get-number-type
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[inventory-id´86, inventory-id´6, 78"m", 5"s", 99, inventory-id´654]...
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-> get-number-type -> '$;
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' -> !OUT::write
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// Measures can be used in arithmetic, "1" is the scalar unit
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// When mixing measures you have to cast to the result measure
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4"m" + 6"m" * 3"1" -> ($ ~/ 2"s")"m/s" -> '$;
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' -> !OUT::write
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// Tagged identifiers must be made into raw numbers when used in arithmetic
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// Then you can cast the result back to a tagged identifier if you like
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inventory-id´300 -> inventory-id´($::raw + 1) -> get-number-type -> '$;
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' -> !OUT::write
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// Fields get auto-typed, tagging raw strings or numbers by default
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// You cannot assign the wrong type to a field
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def item: { inventory-id: 23, name: 'thingy', length: 12"m" };
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'Field inventory-id $item.inventory-id -> get-number-type;
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' -> !OUT::write
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'Field name $item.name -> get-string-type;
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' -> !OUT::write
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'Field length $item.length -> get-number-type;
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' -> !OUT::write
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// You can define types and use as type-tests. This also defines a field.
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// It would be an error to assign a non-standard plate to a standard-plate field
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data standard-plate <'[A-Z]{3}[0-9]{3}'>
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[['Audi', 'XYZ345'], ['BMW', 'I O U']]... -> \(
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when <?($(2) <standard-plate>)> do {make: $(1), standard-plate: $(2)}!
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otherwise {make: $(1), vanity-plate: $(2)}!
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\) -> '$;
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' -> !OUT::write
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// You can define union types
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data age <"years"|"months">
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[ {name: 'Cesar', age: 20"years"},
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{name: 'Francesca', age: 19"years"},
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{name: 'Bobby', age: 11"months"}]...
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-> \(
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// Conditional tests on structures look a lot like literals, with field tests
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when <{age: <13"years"..19"years">}> do '$.name; is a teenager'!
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when <{age: <"months">}> do '$.name; is a baby'!
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// You don't need to handle all cases, 'Cesar' will just be ignored
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\) -> '$;
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' -> !OUT::write
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// Array/list indexes start at 1 by default, but you can choose
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// Slices return whatever overlaps with the actual array
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[1..5] -> $(-2..2) -> '$;
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' -> !OUT::write // Outputs [1,2]
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0:[1..5] -> $(-2..2) -> '$;
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' -> !OUT::write // Outputs [1,2,3]
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-2:[1..5] -> $(-2..2) -> '$;
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' -> !OUT::write // Outputs [1,2,3,4,5]
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// Arrays can have indexes of measures or tagged identifiers
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def game-map: 0"y":[
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1..5 -> 0"x":[
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1..5 -> level´1:[
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1..3 -> {
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level: $,
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terrain-id: 6 -> SYS::randomInt,
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altitude: (10 -> SYS::randomInt)"m"
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}
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]
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]
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];
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// Projections (indexing) can span several dimensions
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$game-map(3"y"; 1"x"..3"x"; level´1; altitude:) -> '$;
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' -> !OUT::write // Gives a list of three altitude values
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// Flatten and do a grouping projection to get stats
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// Count and Max are built-in collector processors
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[$game-map... ... ...] -> $(collect {
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occurences: Count,
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highest-on-level: Max&{by: :(altitude:), select: :(level:)}
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} by $({terrain-id:}))
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-> !OUT::write
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'
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' -> !OUT::write
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// Relations are sets of structures/records.
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// Here we get all unique {level:, terrain-id:, altitude:} combinations
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def location-types: {|$game-map... ... ...|};
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// Projections can re-map structures. Note § is the relative accessor
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$location-types({terrain-id:, foo: §.level::raw * §.altitude})
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-> '$;
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' -> !OUT::write
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// Relational algebra operators can be used on relations
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($location-types join {| {altitude: 3"m"} |})
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-> !OUT::write
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'
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' -> !OUT::write
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// Define your own operators for binary operations
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operator (left dot right)
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$left -> \[i]($ * $right($i)!\)... -> ..=Sum&{of: :()} !
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end dot
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([1,2,3] dot [2,5,8]) -> 'dot product: $;
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' -> !OUT::write
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// Supply parameters to vary templates behaviour
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templates die-rolls&{sides:}
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1..$ -> $sides::raw -> SYS::randomInt -> $ + 1 !
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end die-rolls
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[5 -> die-rolls&{sides:4}] -> '$;
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' -> !OUT::write
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// Pass templates as parameters, maybe with some parameters pre-filled
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source damage-roll&{first:, second:, third:}
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(1 -> first) + (1 -> second) + (1 -> third) !
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end damage-roll
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$damage-roll&{first: die-rolls&{sides:4},
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second: die-rolls&{sides:6}, third: die-rolls&{sides:20}}
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-> 'Damage done is $;
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' -> !OUT::write
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// Write tests inline. Run by --test flag on command line
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// Note the ~ in the matcher means "not",
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// and the array content matcher matches elements < 1 and > 4
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test 'die-rolls'
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assert [100 -> die-rolls&{sides: 4}] <~[<..~1|4~..>]> 'all rolls 1..4'
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end 'die-rolls'
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// Provide modified modules to tests (aka test doubles or mocks)
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// IN is the standard input object and ::lines gets all lines
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source read-numbers
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$IN::lines -> #
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when <'\d+'> do $!
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end read-numbers
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test 'read numbers from input'
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use shadowed core-system/
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processor MockIn
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source lines
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[
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'12a',
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'65',
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'abc'
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]... !
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end lines
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end MockIn
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def IN: $MockIn;
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end core-system/
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assert $read-numbers <=65> 'Only 65 is read'
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end 'read numbers from input'
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// You can work with byte arrays
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composer hexToBytes
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<HEX>
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end hexToBytes
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'1a5c678d' -> hexToBytes -> ($ and [x 07 x]) -> $(last-1..last) -> '$;
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' -> !OUT::write // Outputs 0005
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```
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## Further Reading
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- [Main Tailspin site](https://github.com/tobega/tailspin-v0/)
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- [Tailspin language reference](https://github.com/tobega/tailspin-v0/blob/master/TailspinReference.md)
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