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887 lines
24 KiB
Markdown
887 lines
24 KiB
Markdown
---
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language: Gleam
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contributors:
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- ["Antonio Ognio", "https://github.com/aognio/"]
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filename: learngleam.gleam
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---
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Gleam is a new language for Erlang's BEAM virtual machine that relies on the
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power of a robust type system, the expressiveness of functional programming,
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and the highly concurrent fault-tolerant Erlang runtime using familiar and
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modern syntax inspired by languages like OCaml, Rust and Elixir.
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Being a pretty modern development, Gleam comes with a compiler, a build tool,
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a code formatter, several editor integrations, and a package manager.
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Being part of the larger BEAM ecosystem, the programs created with Gleam can
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also make use of thousands of published packages written in Erlang or Elixir.
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The design of the language is very concise so it features no null values,
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no exceptions, clear error messages, and a practical type system.
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JavaScript is additionally supported as a compile target, so you can run Gleam
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code in browser or any other JS-enabled runtime. When using this feature,
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TypeScript definitions get created, so you can interact with your Gleam code
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confidently, even from the outside.
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```
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//// This comment with four slashes is a module-level.
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//// This kind of comments are used to describe the whole module.
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import gleam/bool
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import gleam/io
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import gleam/int
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import gleam/float
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import gleam/list
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import gleam/iterator
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import gleam/option.{type Option, None, Some}
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import gleam/result
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import gleam/string
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import gleam/string as text
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// A type's name always starts with a capital letter, contrasting to variables
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// and functions, which start with a lowercase letter.
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// When the pub keyword is used the type alias is public and can be referred to
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// by other modules.
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pub type UserId =
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Int
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pub fn main() {
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io.println("Hello from learnxinmyminutes.com!")
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// io.println("This statement got commented out by a two slashes comment.!")
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// Modules are the units in which all Gleam code gets organized.
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// In a module you will find a bunch of definitions of types, functions, etc.
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// that seem to belong together.
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// For example, the gleam/io module contains a variety of functions for
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// printing, like println.
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// All gleam code is in some module or other, whose name comes from the name
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// of the file it's in.
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// For example, gleam/io is in a file called io.gleam in a directory called
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// gleam.
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// Gleam has a robust static type system that helps you as you write and edit
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// code, catching mistakes and showing you where to make changes.
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// io.println(10)
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// If you uncomment the previous line you'll get a compile time error reported
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// as the io.println function only works with strings, not ints.
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// The compile will output an error that looks like this:
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// error: Type mismatch
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// ┌─ /home/contributor/learnxinmyminutes/src/learnxinmyminutes.gleam:21:14
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// │
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// 21 │ io.println(10)
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// │ ^^
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//
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// Expected type:
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//
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// String
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//
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// Found type:
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//
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// Int
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// Working with numbers
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// When running on the Erlang virtual machine ints have no maximum and minimum
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// size.
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// When running on JavaScript runtimes ints are represented using JavaScript's
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// 64 bit floating point numbers.
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// Int arithmetic
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io.debug(1 + 1)
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io.debug(5 - 1)
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io.debug(5 / 2)
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io.debug(3 * 3)
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io.debug(5 % 2)
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// Int comparisons
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io.debug(2 > 1)
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io.debug(2 < 1)
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io.debug(2 >= 1)
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io.debug(2 <= 1)
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// Equality works for any type and is checked structurally, meaning that two
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// values are equal if they have the same structure rather than if they are at
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// the same memory location.
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io.debug(1 == 1)
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// True
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io.debug(2 != 2)
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// False
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// Standard library int functions
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io.debug(int.min(142, 137))
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// 137
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io.debug(int.clamp(-80, min: 0, max: 100))
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// 0
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io.debug(int.base_parse("10", 2))
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// Ok(2)
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// Binary, octal, and hex Int literals
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io.debug(0b00001111)
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io.debug(0o17)
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io.debug(0xF)
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// Use underscores to enhance integer readability
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io.debug(1_000_000)
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// Gleam's numerical operators are not overloaded, so there are dedicated
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// operators for working with floats.
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// Float arithmetic
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io.debug(1.0 +. 1.5)
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io.debug(5.0 -. 1.5)
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io.debug(5.0 /. 2.5)
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io.debug(3.0 *. 3.5)
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// Float comparisons
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io.debug(2.2 >. 1.3)
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io.debug(2.2 <. 1.3)
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io.debug(2.2 >=. 1.3)
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io.debug(2.2 <=. 1.3)
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// Floats are represented as 64-bit floating point numbers on both the Erlang
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// and JavaScript runtimes.
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// The floating point behaviour is native to their respective runtimes, so
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// their exact behaviour will be slightly different on the two runtimes.
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// Under the JavaScript runtime, exceeding the maximum (or minimum)
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// representable value for a floating point value will result in Infinity
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// (or -Infinity). Should you try to divide two infinities you will get NaN
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// as a result.
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// When running on the BEAM any overflow will raise an error. So there is no
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// NaN or Infinity float value in the Erlang runtime.
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// Division by zero is not an error
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io.debug(3.14 /. 0.0)
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// 0.0
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// Standard library float functions
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io.debug(float.max(2.0, 9.5))
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// 9.5
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io.debug(float.ceiling(5.4))
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// 6.0
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// Underscores for floats are also supported
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io.debug(10_000.01)
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// Division by zero will not overflow but is instead defined to be zero.
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// Working with strings
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io.debug("⭐ Gleam ⭐ - 별")
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io.debug(
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"this
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is
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a
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multi
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line
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string",
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)
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io.debug("\u{1F600}")
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// Outputs a smiley 😀
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// Double quote can be escaped
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io.println("\"X\" marks the spot")
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// String concatenation
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io.debug("One " <> "Two")
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// String functions
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io.debug(text.reverse("1 2 3 4 5"))
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io.debug(text.append("abc", "def"))
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io.println(text.reverse("!desrever tog gnirts sihT"))
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// Outputs "This string got reversed!"
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// Several escape sequences are supported:
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// \" - double quote
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// \\ - backslash
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// \f - form feed
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// \n - newline
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// \r - carriage return
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// \t - tab
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// Bool operators
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// The || and && operators work by short-circuiting
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io.debug(True && False)
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// False
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io.debug(True && True)
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// True
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io.debug(False || False)
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// False
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io.debug(False || True)
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// True
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// Bool functions
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io.debug(bool.to_string(True))
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// "True"
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io.debug(bool.to_int(False))
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// 0
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// Assignments
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let x = "Original value"
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io.debug(x)
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// Assign `y` to the value of `x`
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let y = x
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io.debug(y)
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// Assign `x` to a new value
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let x = "New value"
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io.debug(x)
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// The `y` still refers to the original value
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io.debug(y)
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// In Gleam variable and function names are written in snake_case.
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let answer_to_the_universe = 42
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io.debug(answer_to_the_universe)
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let and_everything = answer_to_the_universe
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// Now using a variable produces a warning
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// warning: Unused variable
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// ┌─ /home/contributor/learnxinmyminutes/src/learnxinmyminutes.gleam:199:7
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// │
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// 199 │ let and_everything = answer_to_the_universe
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// │ ^^^^^^^^^^^^^^ This variable is never used
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// Hint: You can ignore it with an underscore: `_and_everything`.
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// Type annotations
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let _name: String = "Gleam"
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let _is_cool: Bool = True
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let _version: Int = 1
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// Useful for documentation purposes but they do not change how the compiler
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// type checks the code beyond making sure the annotation matches the type,
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// otherwise you get an error.
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// let _has_wrong_type_annotation: Int = True
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// error: Type mismatch
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// ┌─ /home/contributor/learnxinmyminutes/src/learnxinmyminutes.gleam:219:41
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// │
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// 219 │ let _has_wrong_type_annotation: Int = True
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// │ ^^^^
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//
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// Expected type:
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//
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// Int
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//
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// Found type:
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//
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// Bool
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// Type aliases
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let one: UserId = 1
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// Refer to the beginning of the file for the definition of the UserId type
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let two: Int = 2
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// Aliases are just for creating more readable code and more precise
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// documentation.
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// Under the hood they are still values of the same type so operations
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// still work
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io.debug(one + two)
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// 3
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// Blocks: scoping and value
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let radius = {
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let value = 100.0
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value
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}
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// io.debug(value) // <- This will not compile because "value" is out of scope
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let area = 3.14159 *. radius *. radius
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io.debug(area)
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// Use blocks to group operations instead of parenthesis
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let n1 = { 3 + 2 } * 5
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let n2 = 3 + { 2 * 5 }
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io.debug(n1 != n2)
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// True
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// Lists
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// Nephews of Scrooge McDuck
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let nephews = ["Huey", "Dewey", "Louie"]
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io.debug(nephews)
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// ["Huey", "Dewey", "Louie"]
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// Immutably prepend so the original list is not changed
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io.debug(["Donald", ..nephews])
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// ["Donald", "Huey", "Dewey", "Louie"]
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// Some standard library functions for lists
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list.each(nephews, io.println)
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// Huey
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// Dewey
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// Louie
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io.debug(list.drop(nephews, 2))
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// ["Louie"]
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more_examples()
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more_function_examples()
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generic_typing_examples()
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beloved_pipelines_demo()
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labels_in_function_calls()
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showcase_flow_control()
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more_on_recursion()
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more_on_pattern_matching()
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showcase_types()
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more_on_types()
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more_on_callbacks()
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showcase_externals()
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showcase_panic()
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}
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// The fn keyword is used to define new functions.
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fn multiply(a: Int, b: Int) -> Int {
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// No explicit return
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// The last expression gets returned
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a * b
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}
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// The double and multiply functions are defined without the pub keyword.
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// This makes them private functions, they can only be used within this module.
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// If another module attempted to use them it would result in a compiler error.
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fn double(a: Int) -> Int {
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multiply(a, 2)
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}
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// Only public functions are exported and can be called from outside the module.
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// Type annotations are optional for function arguments and return values
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// but are considered good practice for clarity and in order to encourage
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// intentional and thoughtful design.
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pub fn is_leap_year(year: Int) -> Bool {
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{ year % 4 == 0 } && { { year % 100 != 0 } || { year % 400 == 0 } }
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}
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fn more_examples() {
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// Debug also returns a value so its output is the return value of
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// this function
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io.debug(double(10))
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// 20
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io.debug(is_leap_year(2000))
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// True
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}
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// Gleam supports higher-order functions:
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// They can be assigned to variables, passed as arguments to other functions
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// or even be returned as values from blocks or other functions
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fn call_func_on_int(func: fn(Int) -> Int, value: Int) -> Int {
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func(value)
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}
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fn more_function_examples() -> Int {
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io.debug(call_func_on_int(double, 2))
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// 4
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let square = fn(x: Int) -> Int { x * x }
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io.debug(square(3))
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// 9
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// Calling an anonymous function immediately after defining it
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io.debug(fn(x: Int) { x + 1 }(1))
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// Closure example
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let make_adder = fn(n: Int) -> fn(Int) -> Int {
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fn(argument: Int) -> Int { argument + n }
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}
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let adder_of_fives = make_adder(5)
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io.debug(adder_of_fives(10))
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// 15
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// Anonymous functions can be used interchangeably with named functions.
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io.debug(call_func_on_int(fn(x: Int) -> Int { x + 100 }, 900))
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// 1000
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// Let's create a function decorator
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let twice = fn(wrapped_func: fn(Int) -> Int) -> fn(Int) -> Int {
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fn(argument: Int) -> Int { wrapped_func(wrapped_func(argument)) }
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}
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let quadruple = twice(double)
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io.debug(quadruple(1))
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let quadruple_2 = fn(a: Int) -> Int { multiply(4, a) }
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io.debug(quadruple_2(2))
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// 8
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// A function capture is a shorthand syntax for creating anonymous functions
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// that takes one argument and immediately calls another function with that
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// argument
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let quadruple_3 = multiply(4, _)
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io.debug(quadruple_3(4))
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// 16
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}
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// Generic functions are supported using type variables.
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fn generic_twice(func: fn(value) -> value, argument: value) -> value {
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func(func(argument))
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}
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// In generic_twice value was the type variable.
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// In generic_twice_decorator the_type is the type variable.
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// As in any other variable you get to choose the name.
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fn generic_twice_decorator(
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func: fn(the_type) -> the_type,
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) -> fn(the_type) -> the_type {
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fn(argument: the_type) -> the_type { func(func(argument)) }
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}
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fn generic_typing_examples() {
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let double_integers = fn(a: Int) -> Int { a * 2 }
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let double_floats = fn(a: Float) -> Float { a *. 2.0 }
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io.debug(generic_twice(double_integers, 3))
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io.debug(generic_twice(double_floats, 3.0))
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let quadruple_integers = generic_twice_decorator(double_integers)
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let quadruple_floats = generic_twice_decorator(double_floats)
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io.debug(quadruple_integers(1))
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// 4
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io.debug(quadruple_floats(1.0))
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// 4.0
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}
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// Gleam's pipe operator |> takes the result of the expression on its left
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// and passes it as an argument to the function on its right.
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fn beloved_pipelines_demo() {
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// Let's be honest: you want to use Gleam just for this cool operator, right?
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["hello", "world"]
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|> list.intersperse(" ")
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|> list.append(["!"])
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|> string.concat
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|> string.capitalise
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|> io.debug
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// Match cleaner than this right?
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io.debug(
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string.capitalise(
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string.concat(
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list.append(list.intersperse(["hello", "world"], " "), ["!"]),
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),
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),
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)
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// Solution to the first problem of Project Euler:
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// URL: https://projecteuler.net/problem=1
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// Description: Find the sum of all the multiples of 3 and 5 below 1000.
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iterator.iterate(1, fn(n) { n + 1 })
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|> iterator.take(1000 - 1)
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|> iterator.filter(fn(n) { { n % 3 == 0 } || { n % 5 == 0 } })
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|> iterator.fold(from: 0, with: fn(acc, element) { element + acc })
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|> int.to_string
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|> fn(sum_as_text: String) {
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"Solution to Project Euler's problem #1: " <> sum_as_text
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}
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|> io.debug
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// Solution to Project Euler's problem #1: 233168
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}
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// Labels can be added before each argument
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fn call_func_on_int_with_labels(
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func passed_func: fn(Int) -> Int,
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value n: Int,
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) -> Int {
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passed_func(n)
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}
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// The label and the argument can have the same name
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fn add_one(number number: Int) -> Int {
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number + 1
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}
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fn add_two_integers(first n: Int, second m: Int) -> Int {
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n + m
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}
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fn labels_in_function_calls() -> Int {
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// Since we are labelling the arguments we can switch the order
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// if we want to
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io.debug(call_func_on_int_with_labels(value: 8, func: double))
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io.debug(add_one(number: 1))
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// 2
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io.debug(string.contains(does: "theme", contain: "the"))
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// True
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// Unlabeled arguments must go first
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io.debug(add_two_integers(2, second: 2))
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// 4
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}
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fn showcase_flow_control() {
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// Use case if you want to use pattern-matching in order to
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// select which code to execute.
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// Gleam will make sure all possible values are covered
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// by performing exhaustiveness checks.
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// Otherwise you get compilation errors.
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let puppies = ["Bear", "Frisco", "Ranger"]
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let count = list.length(of: puppies)
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{
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"We have "
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<> int.to_string(count)
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<> " "
|
|
<> // The underscore matches with any other value
|
|
case count {
|
|
1 -> "puppy"
|
|
_ -> "puppies"
|
|
}
|
|
}
|
|
|> io.debug
|
|
|
|
// Gleam allows patterns in case expressions to also assign variables.
|
|
{
|
|
"Puppy count: "
|
|
<> case list.length(puppies) {
|
|
0 -> "None."
|
|
1 -> "Just one."
|
|
other -> "As many as " <> int.to_string(other) <> " puppies."
|
|
}
|
|
}
|
|
|> io.debug
|
|
|
|
// Consider BEAM languages are functional in design and Gleam is no exception
|
|
// so there are no if, for or while constructs available.
|
|
|
|
// Use pattern-matching for conditionals
|
|
let answer = 42
|
|
case answer == 42 {
|
|
True -> {
|
|
io.debug("This is the answer to the universe.")
|
|
}
|
|
False -> {
|
|
io.debug("This is the answer to something else.")
|
|
}
|
|
}
|
|
|
|
// Use recursion instead of looping
|
|
from_one_to_ten(1)
|
|
}
|
|
|
|
// Recursive function
|
|
fn from_one_to_ten(n: Int) {
|
|
io.debug(n)
|
|
case n {
|
|
10 -> Nil
|
|
_ -> from_one_to_ten(n + 1)
|
|
}
|
|
}
|
|
|
|
// In order to avoid memory exhaustion due to creating excessive
|
|
// stack frames when calling functions recursively, Gleam supports
|
|
// "tail call optimisation" which means that the compiler can reuse
|
|
// the stack frame for the current function if a function call is
|
|
// the last thing the function does.
|
|
|
|
pub fn fib(x: Int) -> Int {
|
|
// The public function calls the private tail recursive function
|
|
fib_loop(x, 1)
|
|
}
|
|
|
|
fn fib_loop(x: Int, accumulator: Int) -> Int {
|
|
case x {
|
|
1 -> accumulator
|
|
|
|
// The last thing this function does is call itself
|
|
// In the previous lesson the last thing it did was multiply two ints
|
|
_ -> fib_loop(x - 1, accumulator + x)
|
|
}
|
|
}
|
|
|
|
// Gleam supports pattern-matching the first element and the remainder
|
|
// of a list with the [x, ..y] pattern inside a case expression.
|
|
fn reverse_list(the_list: List(value)) -> List(value) {
|
|
case the_list {
|
|
[head, ..tail] -> list.concat([reverse_list(tail), [head]])
|
|
[] -> []
|
|
}
|
|
}
|
|
|
|
fn more_on_recursion() {
|
|
io.debug(fib(10))
|
|
// 55
|
|
io.debug(reverse_list([1, 2, 3]))
|
|
}
|
|
|
|
fn more_on_pattern_matching() {
|
|
// When pattern-matching on strings the <> operator match on strings
|
|
// with a specific prefix and assigns the reminder to a variable
|
|
io.debug(case "Hello, Lucy" {
|
|
"Hello, " <> name -> "Greetings for " <> name
|
|
_ -> "Potentially no greetings"
|
|
})
|
|
|
|
// Alternative patterns are supported so the same clause is used
|
|
// for multiple values
|
|
let month = 2
|
|
let year = 2024
|
|
let number_of_days = case month {
|
|
2 ->
|
|
case is_leap_year(year) {
|
|
False -> 28
|
|
True -> 29
|
|
}
|
|
4 | 6 | 9 | 11 -> 30
|
|
1 | 3 | 5 | 7 | 8 | 10 | 12 -> 31
|
|
_ -> 0
|
|
}
|
|
io.debug("Number of days: " <> int.to_string(number_of_days))
|
|
// 29
|
|
|
|
// Guards in pattern-matching:
|
|
// When using the if keyword an expression must evaluate to True
|
|
// for the pattern to match.
|
|
let list_starts_with = fn(the_list: List(value), the_value: value) -> Bool {
|
|
case the_list {
|
|
[head, ..] if head == the_value -> True
|
|
_ -> False
|
|
}
|
|
}
|
|
io.debug(list_starts_with([10, 20, 30], 10))
|
|
// True
|
|
}
|
|
|
|
pub type Gender {
|
|
Male
|
|
Female
|
|
Other
|
|
}
|
|
|
|
// Records:
|
|
// - Support variants
|
|
// - Each variant is similar to a struct with fields
|
|
pub type Shape {
|
|
Rectangle(base: Float, height: Float)
|
|
Triangle(base: Float, height: Float)
|
|
}
|
|
|
|
// Records with one variant resemble structs
|
|
pub type Point {
|
|
Point(x: Float, y: Float)
|
|
}
|
|
|
|
fn showcase_types() {
|
|
// Tuples:
|
|
// - Can mix together elements of different types
|
|
// - Their type is implicit e.g. #{1, "Hello"} is of type #{Int, String}
|
|
// - Their elements can be accessed by numeric indexes
|
|
let tuple_01 = #(1, "Ferris", "rustacean", True)
|
|
let tuple_02 = #(1, "Lucy", "starfish", True)
|
|
io.debug(tuple_01)
|
|
io.debug(tuple_01.0)
|
|
// 1
|
|
io.debug(tuple_02.1)
|
|
// Lucy
|
|
let #(_, name, species, _) = tuple_01
|
|
io.debug(name <> " the " <> species)
|
|
|
|
// Pattern-matching with tuples including variable assignment
|
|
case tuple_02 {
|
|
#(_, name, _, True) -> io.debug(name <> " is a mascot.")
|
|
#(_, name, _, False) -> io.debug(name <> " is not a mascot.")
|
|
}
|
|
|
|
// Using a custom type with pattern-matching
|
|
let gender = Other
|
|
io.debug(case gender {
|
|
Male -> "Boy"
|
|
Female -> "Girl"
|
|
_ -> "Undetermined"
|
|
})
|
|
|
|
// Using records
|
|
let rectangle_1 = Rectangle(base: 10.0, height: 20.0)
|
|
io.debug(rectangle_1.height)
|
|
// 10.3
|
|
|
|
let point_1 = Point(x: 3.2, y: 4.3)
|
|
io.debug(point_1)
|
|
|
|
// Updating a record
|
|
let point_2 = Point(..point_1, y: 5.7)
|
|
io.debug(point_2)
|
|
|
|
// In Gleam, values are not nullable.
|
|
// Nil is the only value of its type.
|
|
let some_var = Nil
|
|
let result = io.println("Hello!")
|
|
io.debug(some_var == result)
|
|
// True
|
|
}
|
|
|
|
pub type Mineral {
|
|
Gold
|
|
Silver
|
|
Copper
|
|
}
|
|
|
|
// Generic custom types with contained types as parameters
|
|
pub type Purity(inner_type) {
|
|
Pure(inner_type)
|
|
Impure(inner_type)
|
|
}
|
|
|
|
pub type Beverage {
|
|
Water
|
|
Juice
|
|
}
|
|
|
|
// Existing custom types from the gleam/option and gleam/result modules
|
|
// facilitate working with nullable values and handling potential errors
|
|
pub type Person {
|
|
Person(name: String, nickname: Option(String))
|
|
}
|
|
|
|
pub type DiceError {
|
|
DiceValueOutOfRange
|
|
}
|
|
|
|
fn checked_dice_value(value: Int) -> Result(Int, DiceError) {
|
|
case value {
|
|
1 | 2 | 3 | 4 | 5 | 6 -> Ok(value)
|
|
_ -> Error(DiceValueOutOfRange)
|
|
}
|
|
}
|
|
|
|
fn double_dice_value(value: Int) -> Result(Int, DiceError) {
|
|
case value {
|
|
1 | 2 | 3 -> Ok(value * 2)
|
|
_ -> Error(DiceValueOutOfRange)
|
|
}
|
|
}
|
|
|
|
fn more_on_types() {
|
|
let mineral_sample_01: Purity(Mineral) = Pure(Gold)
|
|
let mineral_sample_02 = Impure(Silver)
|
|
io.debug(mineral_sample_01)
|
|
io.debug(mineral_sample_02)
|
|
|
|
// A glass can be empty or not
|
|
let glass_01: Option(Beverage) = Some(Water)
|
|
let glass_02 = None
|
|
io.debug(glass_01)
|
|
io.debug(glass_02)
|
|
|
|
// A person can have a nickname or not
|
|
let person_01 = Person(name: "John", nickname: Some("The Ripper"))
|
|
let person_02 = Person(name: "Martin", nickname: None)
|
|
io.debug(person_01)
|
|
io.debug(person_02)
|
|
|
|
// Working with functions that return values of type Result
|
|
let dice_01 = 5
|
|
case checked_dice_value(dice_01) {
|
|
Ok(checked_value) ->
|
|
io.debug("The value of " <> int.to_string(checked_value) <> " is OK.")
|
|
Error(DiceValueOutOfRange) ->
|
|
io.debug("The value of the dice is out of range")
|
|
}
|
|
|
|
// Let's attempt to double the value if the resulting value is still
|
|
// a number in any of the sides of the dice.
|
|
// Otherwise, let's put the max value.
|
|
2
|
|
|> checked_dice_value
|
|
|> result.try(double_dice_value)
|
|
|> result.unwrap(or: 6)
|
|
|> io.debug
|
|
}
|
|
|
|
pub fn throw_dice_as_result() {
|
|
Ok(int.random(6) + 1)
|
|
}
|
|
|
|
pub fn sum_dice_values(a: Int, b: Int) {
|
|
Ok(a + b)
|
|
}
|
|
|
|
// Betting on first-class functions and pattern-matching
|
|
// can easily lead to tons of indentation
|
|
fn roll_two_dices_without_use() {
|
|
result.try(throw_dice_as_result(), fn(first_dice) {
|
|
result.try(throw_dice_as_result(), fn(second_dice) {
|
|
result.map(sum_dice_values(first_dice, second_dice), fn(sum) { sum })
|
|
})
|
|
})
|
|
}
|
|
|
|
// The use expression still lets us write code that uses callbacks
|
|
// but cleans up excessive indentation:
|
|
// - A call to higher order function go the right side of the <- operator
|
|
// - The argument names for the callback function go on the left hand side of
|
|
// the <- operator
|
|
// - All the remaining code in the enclosing {} block becomes the body of the
|
|
// callback function.
|
|
fn roll_two_dices_with_use() {
|
|
use first_dice <- result.try(throw_dice_as_result())
|
|
use second_dice <- result.try(throw_dice_as_result())
|
|
use sum <- result.map(sum_dice_values(first_dice, second_dice))
|
|
// This is the remaining code in innermost callback function
|
|
sum
|
|
}
|
|
|
|
fn more_on_callbacks() {
|
|
io.debug(roll_two_dices_without_use())
|
|
io.debug(roll_two_dices_with_use())
|
|
}
|
|
|
|
pub type DateTime
|
|
|
|
// External functions must annotate a return type
|
|
@external(erlang, "calendar", "local_time")
|
|
pub fn now() -> DateTime
|
|
|
|
fn showcase_externals() {
|
|
io.debug(now())
|
|
// #(#(2024, 4, 6), #(14, 4, 16))
|
|
}
|
|
|
|
fn showcase_panic() {
|
|
// We can deliberately abort execution by using the panic keyword
|
|
// in order to make our program crash immediately
|
|
case 3 == 2 {
|
|
True -> panic as "The equality operator is broken!"
|
|
False -> "Equality operator works for integers"
|
|
}
|
|
// Calling a function that uses the todo keyword also crashes
|
|
// homework()
|
|
}
|
|
|
|
pub fn homework() {
|
|
todo
|
|
}
|
|
```
|
|
|
|
## Further reading
|
|
|
|
* [Gleam's official website](https://gleam.run/)
|
|
* [Language tour](https://tour.gleam.run/) - Includes live code editor
|
|
* [Official documentation](https://gleam.run/documentation/)
|
|
* [Gleam's awesome list](https://github.com/gleam-lang/awesome-gleam)
|
|
* [Exercism track for Gleam](https://exercism.org/tracks/gleam)
|
|
|
|
The official docs have cheatsheets for people familiar with:
|
|
|
|
* [Elixir](https://gleam.run/cheatsheets/gleam-for-elixir-users)
|
|
* [Elm](https://gleam.run/cheatsheets/gleam-for-elm-users)
|
|
* [Erlang](https://gleam.run/cheatsheets/gleam-for-erlang-users)
|
|
* [PHP](https://gleam.run/cheatsheets/gleam-for-php-users)
|
|
* [Python](https://gleam.run/cheatsheets/gleam-for-python-users)
|
|
* [Rust](https://gleam.run/cheatsheets/gleam-for-python-users)
|