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book

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[book]
title = "Deimos Lang"
authors = ["Jesse Brault"]
language = "en"

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# Introduction
Greetings! This is the manual for **Deimos Lang**, a programming language created by Jesse Brault. Deimos has the
planned following features:
- Basic object-oriented features and semantics, including interfaces, classes, and records.
- Enumerated (union) types like Rust/OCaml.
- Traits, which function similar to Rust traits or Haskell type-classes.
- Closures, including those with delegates like Groovy or Kotlin.
- Compile-time metaprogramming with template-like constructs.
- The usual imperative constructs: if/else, for/while loops, etc.
- Functional features, borrowed from languages such as OCaml, Rust, Haskell:
pattern matching, persistent data structures, and tail recursion.
- Static name-resolution and type-checking, with compiler type-inference as much as possible.
- Optional fully-dynamic dispatch via `dyn` keyword, providing runtime method/property lookup like Groovy or Ruby.
- A fast foreign-function interface FFI for calling native Rust functions.
Deimos is compiled for the **Deimos Virtual Machine** (DVM), a VM like those of Java and Lua in spirit but with a Rust
implementation and access to the rest of the Rust (and C, via Rust) ecosystem. The ultimate goal is to be able to run
Deimos and Lua side-by-side on the DVM, allowing applications both a statically typed language like Deimos to function
alongside and interface with a much more relaxed language like Lua.
## Hello, World!
Since it's standard practice to offer the classic Hello World program, let's get started!
```deimos
fn main()
println("Hello, World!")
end
```
Sometimes we just need to dump a string to the terminal, so `println` is available by default in all scopes. Indeed, all
items in the `std::core` module are imported by default to each file/module. In this case, the fully-qualified name of
`println` is `std::core::println`, and is located in the `print.dm` file under `std/core`:
```deimos
pub extern fn println(message: Any) -> Void
```
Here, `println` is declared as an `extern` function, meaning its implementation is provided by a native function at
runtime. We can also see that it takes one parameter of type `Any`—where `Any` is the catchall super-type of all types
in the language. `Void` takes its usual meaning.

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# Summary
[Introduction](README.md)
- [Getting Started](getting_started.md)
- [Implementing Array List](./impl_array_list.md)

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# Chapter 1: Getting Started
Deimos can be run both interactively via a read-eval-print loop (REPL) or by compiling and running a given source file.
## REPL
The REPL allows interactive programming similar to classic functional languages as well as Ruby. To start the REPL, run:
```
dm repl
```
### Basics
All statements and expressions in the REPL are scoped under a synthetic function; in other words, variables persist
through each input:
```
> let x = 2
> x
2
> let y = 3
> x + y
5
```
In addition to statements and expressions, functions can be defined in scope:
```
> fn double(x: Int) x * 2 end
> double(4)
8
```
Note that variables in the "top" scope are not available inside defined functions:
```
> let x = 7
> fn doubleX() x * 2 end
Error: Symbol x could not be found.
```
This requires the use of closures, which can "capture" variables in their containing scope:
```
> let x = 42
> let doubleX = { x * 2 }
> doubleX()
84
```
Note the difference in syntax between function declarations and closure declarations. As we will later see, closures are
powerful constructs.
### Introduction to Classes
Classes can also be defined in the REPL:
```
> class Dog \
pub name: String \
pub ctor(name: String) \
self.name = name \
end \
end
```
A few things are going on here. First, note the use the backslash to indicate that we are not done with our input
(normally, a newline without a preceding backslash will cause the interpreter to consume everything input so far). Next,
note our syntax for declaring a class, with hints of Rust and Ruby:
- `class` keyword: the usual meaning
- `pub` keyword: makes a property or method available outside the class (i.e., non-private)
- `: Type` annotations: indicates the type of a property, parameter, or variable.
- `ctor` keyword: marks a constructor. *Note: Classes can only have **one** constructor*.
- `self` keyword, followed by property name: like the usual construct in OOP languages.
Once we've defined our class, we can use it:
```
> let bear = Dog("Bear")
> let skye = Dog("Skye")
> bear.name
Bear
> skye.name
Skye
```
Note above how we construct instances of the class by "calling" the class, exactly like we do in Kotlin.
#### Class Declaration Short Form
The above class example is a bit verbose; Deimos offers the following equivalent, inspired by Kotlin:
```
class Dog(pub name: String) end
```
This is especially useful in the REPL, where we may just want to declare a data type for doing some data processing.
```
> class Point(pub x: Int, pub y: Int) end
> fn double(p: Point) Point(p.x * 2, p.y * 2) end
> let a = Point(3, 4)
> double(a)
Point(6, 8)
> let b = Point(5, 6)
> double(double(b))
Point(20, 24)
```
## Compiling and Running Files
To compile and run a file, do:
```
dm run <your file name here>.dm
```
Note that the `.dm` extension is required in the command name (unlike `java`).
The above command will compile and immediately run the file. In order for a Deimos file to be executable, it must
contain a `main` function like the following:
```
fn main()
println("Hello, Deimos!")
end
```
Unlike the REPL, statements and expressions are not allowed in the top-level scope; they must be contained in a function
or method:
```
let x = 10 // ERROR! Will not parse.
```
However, functions, classes, and other top-level constructs are allowed:
```
fn double(p: Point) -> Point
Point(p.x * 2, p.y * 2)
end
class Point(x: Int, y: Int) end
fn main()
let a = Point(1, 2)
let b = Point(3, 4)
println(double(a)) // Point(2, 4)
println(double(b)) // Point(6, 8)
end
```
```
let f = { a, b -> a + b } << 4
let x = f(5)
println(x) // 9
```

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# Implementing Array List
```
trait Map<T>
fn <U> map(f: fn (T) -> U) -> Self<U>
end
trait Index<I>
type Output
op fn [] (index: I) -> Self::Output
end
trait Cons<T>
fn cons(t: T) -> Self<T>
fn head() -> Option<T>
fn tail() -> Self<T>
end
trait Default
static fn default() -> Self
end
int Iterable<T>
fn iter() -> Iterator<T>
def fn each(f: fn (T) -> Void)
for t in self
f(t)
end
end
end
int Iterator<T>
fn next() -> Option<T>
end
#[intrinsic]
class Array<T> : Iterable<T>
pub extern static fn <T: Default> sized(size: Size) -> Array<T>
#[intrinsic]
pub fn len() -> Size end
#[intrinsic]
pub fn getAt(index: Size) -> T end
pub fn iter()
let mut i = 0
let iterator = {
if i < len() then
let next = Some(getAt(i))
i++
next
else
None
end
}
iterator
end
end
record Range<T>(start: T, end: T) end
impl<T> Index<Size> for Array<T>
type Output = T
#[inline]
op fn [] (index) = getAt(index)
end
impl<T> Index<Range<Size>> for Array<T>
type Output = Self<T>
op fn [] (range)
let ts = Self(range.end() - range.start())
for i in range do
ts[i] = self[i]
end
ts
end
end
impl<T: Default> Cons<T> for Array<T>
fn cons(t)
let ts = Array::<T>(len() + 1)
ts[0] = t
for i in 0..len() do
ts[i + 1] = self[i]
end
ts
end
fn head(t)
if len() > 0 then
self[0]
else
[]
end
end
fn tail()
if len() > 0 then
self[1..]
else
[]
end
end
end
int List<T> : Iterable<T>
fn len() -> Size
fn getAt(index: Size) -> Option<T>
fn slice(range: Range<Size>) -> Self<T>
mut fn add(t: T) -> Void
mut fn addAll(ts: Iterable<T>) -> Void
def mut op fn << (t: T) -> Void = add(t)
def mut op fn << (ts: Iterable<T>) -> Void = addAll(ts)
mut fn insert(t: T, index: Size) -> Void
def fn iter()
let mut i = 0
let iterator = {
if i < len() then
let next = getAt(i)
i++
next
else
None
end
}
iterator
end
end
impl<T> Map<T> for List<T>
fn map(f) = match self
[] => [],
head :: tail => f(head) :: tail.map(f)
end
end
impl<T> Cons<T> for List<T>
fn cons(t)
let l = ArrayList(self.len() + 1)
l << t
l += self
l
end
end
impl<T> Index<Size> for List<T>
type Output = Option<T>
op fn [] (index) = getAt(index)
end
impl<T> Index<Range<Size>> for List<T>
type Output = Self<T>
op fn [] (range) = slice(range)
end
int UnsafeIterable<T>
fn iter() -> UnsafeIterator<T>
end
int UnsafeIterator<T>
unsafe fn next() -> Option<T> throws NullPointerException
def fn tryNext() -> Result<Option<T>, NullPointerException>
try
Ok(next())
catch e: NullPointerException
Err(e)
end
end
end
#[intrinsic]
class MaybeUninitArray<T> : UnsafeIterable<T>
pub extern static fn <T> sized(size: Size) -> Self<T>
#[intrinsic]
pub fn len() -> Size end
#[intrinsic]
pub unsafe fn getAt(index: Size) -> T throws NullPointerException end
class MaybeUninitIterator<T>(parent: MaybeUninitArray<T>) : UnsafeIterator<T>
mut i: Size = 0
pub unsafe fn next() -> Option<T> throws NullPointerException
if i < parent.len()
let next = parent.getAt(i)
i++
next
else
None
end
end
end
pub unsafe fn iter()
MaybeUninitIterator(self)
end
end
class ArrayList<T> : List<T>
#[get]
mut len: Size = 0
mut ts = {% if T has Default then %}
Array<T>
{% else %}
MaybeUninitArray<T>
{% end %}
pub ctor(capacity: Size)
ts = {% if T has Default then %}
Array::sized::<T>(capacity)
%{ else %}
MaybeUninitArray::sized::<T>(capacity)
{% end %}
end
pub fn getAt(index)
{% if T has Default then %}
index < len ? Some(ts[index]) : None
{% else %}
if index < len then
try
Some(ts[index])
catch e: NullPointerException
None
end
else
None
end
{% end %}
end
pub fn slice(range)
/* some implementation */
end
mut fn maybeGrow()
if len + 1 == ts.len() then
let newSize = len * 2 // or whatever factor
let newTs = {% if T has Default then %}
Array::sized::<T>(newSize)
{% else %}
MaybeUninitArray::sized::<T>(newSize)
{% end %}
for i in 0..ts.len() do
newTs[i] = ts[i]
end
ts = newTs
end
end
pub mut fn add(t)
maybeGrow()
ts[len] = t
len++
end
pub mut fn addAll(ts)
ts.each { add(it) }
end
pub mut fn insert(t, i)
maybeGrow()
let mut previous = None
for i in i..len() do
match previous with
Some(p) => do
let cur = ts[i]
ts[i] = p
previous = Some(cur)
end
None => do
previous = Some(ts[i])
end
end
end
ts[i] = t
len++
end
end
```