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jeff:rewrite
jeff:parser_experiment
jeff:0.4.4
jeff:0.4.3
jeff:variables
jeff:docs
jeff:type_arguments
jeff:tests
jeff:memory_management
jeff:fancy_errors
jeff:enums_and_structs
jeff:as
jeff:context
jeff:identifier_overhaul
jeff:major_clean_up
jeff:reedline
jeff:recursion
jeff:range
jeff:type_definition
jeff:custom_types
jeff:mutation
jeff:gui
jeff:tui
jeff:option
jeff:packages
jeff:map_types
jeff:0.3.8
jeff:0.3.8-type_system
jeff:0.3.8-built_in_functions
jeff:0.3.7
jeff:0.3.6-types
jeff:0.3.6
jeff:0.3.6-std
jeff:0.3.6-yield
jeff:0.3.6-index
jeff:0.3.6-async
jeff:0.3.3
jeff:tree_sitter_parser
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compare: jeff:gui
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jeff:dev
jeff:main
jeff:rewrite-4
jeff:rewrite-3
jeff:rewrite-2
jeff:rewrite
jeff:parser_experiment
jeff:0.4.4
jeff:0.4.3
jeff:variables
jeff:docs
jeff:type_arguments
jeff:tests
jeff:memory_management
jeff:fancy_errors
jeff:enums_and_structs
jeff:as
jeff:context
jeff:identifier_overhaul
jeff:major_clean_up
jeff:reedline
jeff:recursion
jeff:range
jeff:type_definition
jeff:custom_types
jeff:mutation
jeff:gui
jeff:tui
jeff:option
jeff:packages
jeff:map_types
jeff:0.3.8
jeff:0.3.8-type_system
jeff:0.3.8-built_in_functions
jeff:0.3.7
jeff:0.3.6-types
jeff:0.3.6
jeff:0.3.6-std
jeff:0.3.6-yield
jeff:0.3.6-index
jeff:0.3.6-async
jeff:0.3.3
jeff:tree_sitter_parser

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Cargo.toml
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[workspace]
members = ["dust-lang", "dust-shell"]
default-members = ["dust-lang"]
resolver = "2"
[workspace.package]
authors = ["Jeff Anderson"]
[package]
name = "dust-lang"
description = "General purpose programming language"
version = "0.4.0"
repository = "https://git.jeffa.io/jeff/dust.git"
edition = "2021"
license = "MIT"
readme = "README.md"
repository = "https://git.jeffa.io/jeff/dust.git"
authors = ["Jeff Anderson"]
[[bin]]
name = "dust"
path = "src/main.rs"
[profile.dev]
opt-level = 1
[profile.dev.package."*"]
opt-level = 3
[dependencies]
ansi_term = "0.12.1"
clap = { version = "4.4.4", features = ["derive"] }
csv = "1.2.2"
egui = "0.24.1"
eframe = { version = "0.24.1", default-features = false, features = [
"accesskit",
"default_fonts",
"glow",
"persistence",
] }
libc = "0.2.148"
log = "0.4.20"
rand = "0.8.5"
rayon = "1.8.0"
reqwest = { version = "0.11.20", features = ["blocking", "json"] }
rustyline = { version = "12.0.0", features = ["derive", "with-file-history"] }
serde = { version = "1.0.188", features = ["derive"] }
serde_json = "1.0.107"
toml = "0.8.1"
tree-sitter = "0.20.10"
[target.'cfg(not(target_arch = "wasm32"))'.dependencies]
env_logger = "0.10"
[target.'cfg(target_arch = "wasm32")'.dependencies]
wasm-bindgen-futures = "0.4"
[build-dependencies]
cc = "1.0"

317
README.md
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# Dust
Dust is a high-level interpreted programming language with static types that focuses on ease of use,
performance and correctness.
Dust is a general purpose programming language that emphasises concurrency and correctness.
A basic dust program:
```dust
output("Hello world!")
```
Dust can do two (or more) things at the same time with effortless concurrency:
```dust
async {
output('will this one finish first?')
output('or will this one?')
}
```
You can make *any* block, i.e. `{}`, run its statements in parallel by changing it to `async {}`.
```dust
if random_boolean() {
output("Do something...")
} else async {
output("Do something else instead...")
output("And another thing at the same time...")
}
```
Dust is an interpreted, strictly typed language with first class functions. It emphasises concurrency by allowing any group of statements to be executed in parallel. Dust includes built-in tooling to import and export data in a variety of formats, including JSON, TOML, YAML and CSV.
<!--toc:start-->
- [Dust](#dust)
- [Features](#features)
- [Usage](#usage)
- [Installation](#installation)
- [Benchmarks](#benchmarks)
- [Implementation](#implementation)
- [The Dust Programming Language](#the-dust-programming-language)
- [Declaring Variables](#declaring-variables)
- [Lists](#lists)
- [Maps](#maps)
- [Loops](#loops)
- [Functions](#functions)
- [Option](#option)
- [Concurrency](#concurrency)
- [Acknowledgements](#acknowledgements)
<!--toc:end-->
## Features
- Simplicity: Dust is designed to be easy to learn.
- Speed: Dust is built on [Tree Sitter] and [Rust] to prioritize performance and correctness. See [Benchmarks] below.
- Concurrency: Safe, effortless parallel code using thread pools.
- Safety: Written in safe, stable Rust.
- Correctness: Type checking makes it easy to write good code.
## Usage
Dust is an experimental project under active development. At this stage, features come and go and the API is always changing. It should not be considered for serious use yet.
```sh
cargo install dust-lang
dust -c "output('Hello world!')"
```
```txt
General purpose programming language
Usage: dust [OPTIONS] [PATH]
Arguments:
[PATH] Location of the file to run
Options:
-c, --command <COMMAND> Dust source code to evaluate
-i, --input <INPUT> Data to assign to the "input" variable
-p, --input-path <INPUT_PATH> A path to file whose contents will be assigned to the "input" variable
-t, --tree Show the syntax tree
-h, --help Print help
-V, --version Print version
```
## Installation
You must have the default rust toolchain installed and up-to-date. Install [rustup] if it is not already installed. Run `cargo install dust-lang` then run `dust` to start the interactive shell. Use `dust --help` to see the full command line options.
To build from source, clone the repository and build the parser. To do so, enter the `tree-sitter-dust` directory and run `tree-sitter-generate`. In the project root, run `cargo run` to start the shell. To see other command line options, use `cargo run -- --help`.
## Benchmarks
Dust is at a very early development stage but performs strongly in preliminary benchmarks. The examples given were tested using [Hyperfine] on a single-core cloud instance with 1024 MB RAM. Each test was run 1000 times. The test script is shown below. Each test asks the program to read a JSON file and count the objects. Dust is a command line shell, programming language and data manipulation tool so three appropriate targets were chosen for comparison: nushell, NodeJS and jq. The programs produced identical output with the exception that NodeJS printed in color.
For the first test, a file with four entries was used.
| Command | Mean [ms] | Min [ms] | Max [ms]
|:---|---:|---:|---:|
| Dust | 3.1 ± 0.5 | 2.4 | 8.4 |
| jq | 33.7 ± 2.2 | 30.0 | 61.8 |
| NodeJS | 226.4 ± 13.1 | 197.6 | 346.2 |
| Nushell | 51.6 ± 3.7 | 45.4 | 104.3 |
The second set of data is from the GitHub API, it consists of 100 commits from the jq GitHub repo.
| Command | Mean [ms] | Min [ms] | Max [ms] |
|:---|---:|---:|---:|
| Dust | 6.8 ± 0.6 | 5.7 | 12.0 | 2.20 ± 0.40 |
| jq | 43.3 ± 3.6 | 37.6 | 81.6 | 13.95 ± 2.49 |
| NodeJS | 224.9 ± 12.3 | 194.8 | 298.5 |
| Nushell | 59.2 ± 5.7 | 49.7 | 125.0 | 19.11 ± 3.55 |
This data came from CERN, it is a massive file of 100,000 entries.
| Command | Mean [ms] | Min [ms] | Max [ms] |
|:---|---:|---:|---:|
| Dust | 1080.8 ± 38.7 | 975.3 | 1326.6 |
| jq | 1305.3 ± 64.3 | 1159.7 | 1925.1 |
| NodeJS | 1850.5 ± 72.5 | 1641.9 | 2395.1 |
| Nushell | 1850.5 ± 86.2 | 1625.5 | 2400.7 |
The tests were run after 5 warmup runs and the cache was cleared before each run.
```sh
hyperfine \
--shell none \
--warmup 5 \
--prepare "rm -rf /root/.cache" \
--runs 1000 \
--parameter-list data_path seaCreatures.json,jq_data.json,dielectron.json \
--export-markdown test_output.md \
"dust -c '(length (from_json input))' -p {data_path}" \
"jq 'length' {data_path}" \
"node --eval \"require('node:fs').readFile('{data_path}',(err,data)=>{console.log(JSON.parse(data).length)})\"" \
"nu -c 'open {data_path} | length'"
```
## Implementation
Dust is implemented in Rust and is divided into several parts, primarily the lexer, compiler, and
virtual machine. All of Dust's components are designed with performance in mind and the codebase
uses as few dependencies as possible.
Dust is formally defined as a Tree Sitter grammar in the tree-sitter-dust directory. Tree sitter generates a parser, written in C, from a set of rules defined in JavaScript. Dust itself is a rust binary that calls the C parser using FFI.
### Lexer
Tests are written in three places: in the Rust library, in Dust as examples and in the Tree Sitter test format. Generally, features are added by implementing and testing the syntax in the tree-sitter-dust repository, then writing library tests to evaluate the new syntax. Implementation tests run the Dust files in the "examples" directory and should be used to demonstrate and verify that features work together.
The lexer emits tokens from the source code. Dust makes extensive use of Rust's zero-copy
capabilities to avoid unnecessary allocations when creating tokens. A token, depending on its type,
may contain a reference to some data from the source code. The data is only copied in the case of an
error, because it improves the usability of the codebase for errors to own their data when possible.
In a successfully executed program, no part of the source code is copied unless it is a string
literal or identifier.
Tree Sitter generates a concrete syntax tree, which Dust traverses to create an abstract syntax tree that can run the Dust code. The CST generation is an extra step but it allows easy testing of the parser, defining the language in one file and makes the syntax easy to modify and expand. Because it uses Tree Sitter, developer-friendly features like syntax highlighting and code navigation are already available in any text editor that supports Tree Sitter.
### Compiler
## The Dust Programming Language
The compiler creates a chunk, which contains all of the data needed by the virtual machine to run a
Dust program. It does so by emitting bytecode instructions, constants and locals while parsing the
tokens, which are generated one at a time by the lexer.
Dust is easy to learn. Aside from this guide, the best way to learn Dust is to read the examples and tests to get a better idea of what it can do.
#### Parsing
### Declaring Variables
Dust's compiler uses a custom Pratt parser, a kind of recursive descent parser, to translate a
sequence of tokens into a chunk.
Variables have two parts: a key and a value. The key is always a string. The value can be any of the following data types:
#### Optimizing
- string
- integer
- float
- boolean
- list
- map
- option
- function
When generating instructions for a register-based virtual machine, there are opportunities to
optimize the generated code, usually by consolidating register use or reusing registers within an
expression. While it is best to output optimal code in the first place, it is not always possible.
Dust's compiler has a simple peephole optimizer that can be used to modify isolated sections of the
instruction list through a mutable reference.
Here are some examples of variables in dust.
### Instructions
```dust
string = "foobar"
integer = 42
float = 42.42
list = [1 2 string integer float] # Commas are optional when writing lists.
map = {
key = 'value'
}
```
### Virtual Machine
Note that strings can be wrapped with any kind of quote: single, double or backticks. Numbers are always integers by default. Floats are declared by adding a decimal. If you divide integers or do any kind of math with a float, you will create a float value.
## Previous Implementations
Dust enforces strict type checking, but you don't usually need to write the type, dust can figure it out on its own. The **number** and **any** types are special types that allow you to relax the type bounds.
## Inspiration
```dust
string <str> = "foobar"
integer <int> = 42
float <float> = 42.42
- [The Implementation of Lua 5.0](https://www.lua.org/doc/jucs05.pdf)
- [A No-Frills Introduction to Lua 5.1 VM Instructions](https://www.mcours.net/cours/pdf/hasclic3/hasssclic818.pdf)
- [Crafting Interpreters](https://craftinginterpreters.com/)
numbers <[number]> = [integer float]
stuff <[any]> = [string integer float]
```
### Lists
Lists are sequential collections. They can be built by grouping values with square brackets. Commas are optional. Values can be indexed by their position using a colon `:` followed by an integer. Dust lists are zero-indexed.
```dust
list = [true 41 "Ok"]
assert_equal(list:0 true)
the_answer = list:1 + 1
assert_equal(the_answer, 42) # You can use commas when passing values a function.
```
### Maps
Maps are flexible collections with arbitrary key-value pairs, similar to JSON objects. A map is created with a pair of curly braces and its entries are variables declared inside those braces. Map contents can be accessed using a colon `:`.
```dust
reminder = {
message = "Buy milk"
tags = ["groceries", "home"]
}
output(reminder:message)
```
### Loops
A **while** loop continues until a predicate is false.
```dust
i = 0
while i < 10 {
output(i)
i += 1
}
```
A **for** loop operates on a list without mutating it or the items inside. It does not return a value.
```dust
list = [ 1, 2, 3 ]
for number in list {
output(number + 1)
}
```
### Functions
Functions are first-class values in dust, so they are assigned to variables like any other value.
```dust
# This simple function has no arguments and no return value.
say_hi = () <none> {
output("hi")
}
# This function has one argument and will return a value.
add_one = (fn number <num>) <num> {
number + 1
}
say_hi()
assert_equal(add_one(3), 4)
```
You don't need commas when listing arguments and you don't need to add whitespace inside the function body but doing so may make your code easier to read.
### Option
An **option** represents a value that may not be present. It has two variants: **some** and **none**. Dust includes built-in functions to work with option values: `is_none`, `is_some` and `either_or`.
```dust
say_something = (message <option(str)>) <str> {
either_or(message, "hiya")
}
say_something(some("goodbye"))
# goodbye
say_something(none)
# hiya
```
### Concurrency
Dust features effortless concurrency anywhere in your code. Any block of code can be made to run its contents asynchronously. Dust's concurrency is written in safe Rust and uses a thread pool whose size depends on the number of cores available.
```dust
# An async block will run each statement in its own thread.
async {
output(random_integer())
output(random_float())
output(random_boolean())
}
```
```dust
data = async {
output("Reading a file...")
read("examples/assets/faithful.csv")
}
```
## Acknowledgements
Dust began as a fork of [evalexpr]. Some of the original code is still in place but the project has dramatically changed and no longer uses any of its parsing or interpreting.
[Tree Sitter]: https://tree-sitter.github.io/tree-sitter/
[Rust]: https://rust-lang.org
[evalexpr]: https://github.com/ISibboI/evalexpr
[rustup]: https://rustup.rs
[Hyperfine]: https://github.com/sharkdp/hyperfine

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assets/config.json5 Normal file
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{
"keybindings": {
"Home": {
"<q>": "Quit", // Quit the application
"<Ctrl-d>": "Quit", // Another way to quit
"<Ctrl-c>": "Quit", // Yet another way to quit
"<Ctrl-z>": "Suspend", // Suspend the application
"<up>": "Up",
"<down>": "Down",
"<left>": "Left",
"<right>": "Right",
},
}
}

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build.rs Normal file
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fn main() {
let src_dir = std::path::Path::new("tree-sitter-dust/src");
let mut c_config = cc::Build::new();
c_config.include(src_dir);
c_config
.flag_if_supported("-Wno-unused-parameter")
.flag_if_supported("-Wno-unused-but-set-variable")
.flag_if_supported("-Wno-trigraphs");
let parser_path = src_dir.join("parser.c");
c_config.file(&parser_path);
c_config.compile("parser");
println!("cargo:rerun-if-changed={}", parser_path.to_str().unwrap());
}

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dust-lang/Cargo.toml
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[package]
name = "dust-lang"
description = "Interpreter library for the Dust programming language"
version = "0.5.0"
authors.workspace = true
edition.workspace = true
license.workspace = true
readme.workspace = true
repository.workspace = true
[dependencies]
annotate-snippets = "0.11.4"
colored = "2.1.0"
log = "0.4.22"
rand = "0.8.5"
serde = { version = "1.0.203", features = ["derive"] }
serde_json = "1.0.117"
getrandom = { version = "0.2", features = [
"js",
] } # Indirect dependency, for wasm builds
[dev-dependencies]
env_logger = "0.11.5"

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dust-lang/src/chunk.rs
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//! In-memory representation of a Dust program or function.
//!
//! A chunk consists of a sequence of instructions and their positions, a list of constants, and a
//! list of locals that can be executed by the Dust virtual machine. Chunks have a name when they
//! belong to a named function.
use std::{
cmp::Ordering,
fmt::{self, Debug, Display, Formatter},
};
use serde::{Deserialize, Serialize};
use crate::{Disassembler, Instruction, Operation, Span, Type, Value};
/// In-memory representation of a Dust program or function.
///
/// See the [module-level documentation](index.html) for more information.
#[derive(Clone, PartialOrd, Ord, Serialize, Deserialize)]
pub struct Chunk {
name: Option<String>,
pub is_poisoned: bool,
instructions: Vec<(Instruction, Span)>,
constants: Vec<Value>,
locals: Vec<Local>,
current_scope: Scope,
block_index: u8,
}
impl Chunk {
pub fn new(name: Option<String>) -> Self {
Self {
name,
is_poisoned: false,
instructions: Vec::new(),
constants: Vec::new(),
locals: Vec::new(),
current_scope: Scope::default(),
block_index: 0,
}
}
pub fn with_data(
name: Option<String>,
instructions: Vec<(Instruction, Span)>,
constants: Vec<Value>,
locals: Vec<Local>,
) -> Self {
Self {
name,
is_poisoned: false,
instructions,
constants,
locals,
current_scope: Scope::default(),
block_index: 0,
}
}
pub fn name(&self) -> Option<&String> {
self.name.as_ref()
}
pub fn set_name(&mut self, name: String) {
self.name = Some(name);
}
pub fn len(&self) -> usize {
self.instructions.len()
}
pub fn is_empty(&self) -> bool {
self.instructions.is_empty()
}
pub fn constants(&self) -> &Vec<Value> {
&self.constants
}
pub fn constants_mut(&mut self) -> &mut Vec<Value> {
&mut self.constants
}
pub fn take_constants(self) -> Vec<Value> {
self.constants
}
pub fn instructions(&self) -> &Vec<(Instruction, Span)> {
&self.instructions
}
pub fn instructions_mut(&mut self) -> &mut Vec<(Instruction, Span)> {
&mut self.instructions
}
pub fn get_instruction(&self, index: usize) -> Result<&(Instruction, Span), ChunkError> {
self.instructions
.get(index)
.ok_or(ChunkError::InstructionIndexOutOfBounds { index })
}
pub fn locals(&self) -> &Vec<Local> {
&self.locals
}
pub fn locals_mut(&mut self) -> &mut Vec<Local> {
&mut self.locals
}
pub fn get_local(&self, index: u8) -> Result<&Local, ChunkError> {
self.locals
.get(index as usize)
.ok_or(ChunkError::LocalIndexOutOfBounds {
index: index as usize,
})
}
pub fn get_local_mut(&mut self, index: u8) -> Result<&mut Local, ChunkError> {
self.locals
.get_mut(index as usize)
.ok_or(ChunkError::LocalIndexOutOfBounds {
index: index as usize,
})
}
pub fn current_scope(&self) -> Scope {
self.current_scope
}
pub fn get_constant(&self, index: u8) -> Result<&Value, ChunkError> {
self.constants
.get(index as usize)
.ok_or(ChunkError::ConstantIndexOutOfBounds {
index: index as usize,
})
}
pub fn push_or_get_constant(&mut self, value: Value) -> u8 {
if let Some(index) = self
.constants
.iter()
.position(|constant| constant == &value)
{
return index as u8;
}
self.constants.push(value);
(self.constants.len() - 1) as u8
}
pub fn get_identifier(&self, local_index: u8) -> Option<String> {
self.locals.get(local_index as usize).and_then(|local| {
self.constants
.get(local.identifier_index as usize)
.map(|value| value.to_string())
})
}
pub fn begin_scope(&mut self) {
self.block_index += 1;
self.current_scope.block_index = self.block_index;
self.current_scope.depth += 1;
}
pub fn end_scope(&mut self) {
self.current_scope.depth -= 1;
if self.current_scope.depth == 0 {
self.current_scope.block_index = 0;
} else {
self.current_scope.block_index -= 1;
}
}
pub fn expect_not_poisoned(&self) -> Result<(), ChunkError> {
if self.is_poisoned {
Err(ChunkError::PoisonedChunk)
} else {
Ok(())
}
}
pub fn get_constant_type(&self, constant_index: u8) -> Option<Type> {
self.constants
.get(constant_index as usize)
.map(|value| value.r#type())
}
pub fn get_local_type(&self, local_index: u8) -> Option<Type> {
self.locals.get(local_index as usize)?.r#type.clone()
}
pub fn get_register_type(&self, register_index: u8) -> Option<Type> {
let local_type_option = self
.locals
.iter()
.find(|local| local.register_index == register_index)
.map(|local| local.r#type.clone());
if let Some(local_type) = local_type_option {
return local_type;
}
self.instructions
.iter()
.enumerate()
.find_map(|(index, (instruction, _))| {
if let Operation::LoadList = instruction.operation() {
if instruction.a() == register_index {
let mut length = (instruction.c() - instruction.b() + 1) as usize;
let mut item_type = Type::Any;
let distance_to_end = self.len() - index;
for (instruction, _) in self
.instructions()
.iter()
.rev()
.skip(distance_to_end)
.take(length)
{
if let Operation::Close = instruction.operation() {
length -= (instruction.c() - instruction.b()) as usize;
} else if let Type::Any = item_type {
item_type = instruction.yielded_type(self).unwrap_or(Type::Any);
}
}
return Some(Type::List {
item_type: Box::new(item_type),
length,
});
}
}
if instruction.yields_value() && instruction.a() == register_index {
instruction.yielded_type(self)
} else {
None
}
})
}
pub fn return_type(&self) -> Option<Type> {
let returns_value = self
.instructions()
.last()
.map(|(instruction, _)| {
debug_assert!(matches!(instruction.operation(), Operation::Return));
instruction.b_as_boolean()
})
.unwrap_or(false);
if returns_value {
self.instructions.iter().rev().find_map(|(instruction, _)| {
if instruction.yields_value() {
instruction.yielded_type(self)
} else {
None
}
})
} else {
None
}
}
pub fn disassembler(&self) -> Disassembler {
Disassembler::new(self)
}
}
impl Display for Chunk {
fn fmt(&self, f: &mut fmt::Formatter) -> fmt::Result {
let disassembler = self.disassembler().styled(false);
write!(f, "{}", disassembler.disassemble())
}
}
impl Debug for Chunk {
fn fmt(&self, f: &mut fmt::Formatter) -> fmt::Result {
let disassembly = self.disassembler().styled(false).disassemble();
if cfg!(debug_assertions) {
write!(f, "\n{}", disassembly)
} else {
write!(f, "{}", disassembly)
}
}
}
impl Eq for Chunk {}
impl PartialEq for Chunk {
fn eq(&self, other: &Self) -> bool {
self.instructions == other.instructions
&& self.constants == other.constants
&& self.locals == other.locals
}
}
/// A scoped variable.
#[derive(Debug, Clone, Eq, PartialEq, PartialOrd, Ord, Serialize, Deserialize)]
pub struct Local {
/// The index of the identifier in the constants table.
pub identifier_index: u8,
/// The expected type of the local's value.
pub r#type: Option<Type>,
/// Whether the local is mutable.
pub is_mutable: bool,
/// Scope where the variable was declared.
pub scope: Scope,
/// Expected location of a local's value.
pub register_index: u8,
}
impl Local {
/// Creates a new Local instance.
pub fn new(
identifier_index: u8,
r#type: Option<Type>,
mutable: bool,
scope: Scope,
register_index: u8,
) -> Self {
Self {
identifier_index,
r#type,
is_mutable: mutable,
scope,
register_index,
}
}
}
/// Variable locality, as defined by its depth and block index.
///
/// The `block index` is a unique identifier for a block within a chunk. It is used to differentiate
/// between blocks that are not nested together but have the same depth, i.e. sibling scopes. If the
/// `block_index` is 0, then the scope is the root scope of the chunk. The `block_index` is always 0
/// when the `depth` is 0. See [Chunk::begin_scope][] and [Chunk::end_scope][] to see how scopes are
/// incremented and decremented.
#[derive(Debug, Clone, Copy, Default, Eq, PartialEq, PartialOrd, Ord, Serialize, Deserialize)]
pub struct Scope {
/// Level of block nesting.
pub depth: u8,
/// Index of the block in the chunk.
pub block_index: u8,
}
impl Scope {
pub fn new(depth: u8, block_index: u8) -> Self {
Self { depth, block_index }
}
pub fn contains(&self, other: &Self) -> bool {
match self.depth.cmp(&other.depth) {
Ordering::Less => false,
Ordering::Greater => self.block_index >= other.block_index,
Ordering::Equal => self.block_index == other.block_index,
}
}
}
impl Display for Scope {
fn fmt(&self, f: &mut fmt::Formatter) -> fmt::Result {
write!(f, "({}, {})", self.depth, self.block_index)
}
}
/// Errors that can occur when using a [`Chunk`].
#[derive(Clone, Debug, PartialEq)]
pub enum ChunkError {
ConstantIndexOutOfBounds { index: usize },
InstructionIndexOutOfBounds { index: usize },
LocalIndexOutOfBounds { index: usize },
PoisonedChunk,
}
impl Display for ChunkError {
fn fmt(&self, f: &mut Formatter) -> fmt::Result {
match self {
ChunkError::ConstantIndexOutOfBounds { index } => {
write!(f, "Constant index {} out of bounds", index)
}
ChunkError::InstructionIndexOutOfBounds { index } => {
write!(f, "Instruction index {} out of bounds", index)
}
ChunkError::LocalIndexOutOfBounds { index } => {
write!(f, "Local index {} out of bounds", index)
}
ChunkError::PoisonedChunk => write!(f, "Chunk is poisoned"),
}
}
}

1977
dust-lang/src/compiler.rs
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366
dust-lang/src/disassembler.rs
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@ -1,366 +0,0 @@
//! Tool for disassembling chunks into a human-readable format.
//!
//! A disassembler can be created by calling [Chunk::disassembler][] or by instantiating one with
//! [Disassembler::new][].
//!
//! # Options
//!
//! The disassembler can be customized with the 'styled' option, which will apply ANSI color codes
//! to the output.
//!
//! # Output
//!
//! The output of [Disassembler::disassemble] is a string that can be printed to the console or
//! written to a file. Below is an example of the disassembly for a simple "Hello, world!" program.
//!
//! ```text
//! ┌──────────────────────────────────────────────────────────────────────────────┐
//! │ <file name omitted> │
//! │ │
//! │ write_line("Hello, world!") │
//! │ │
//! │ 3 instructions, 1 constants, 0 locals, returns none │
//! │ │
//! │ Instructions │
//! │ ------------ │
//! │ i BYTECODE OPERATION INFO TYPE POSITION │
//! │--- -------- ------------- -------------------- ---------------- ------------ │
//! │ 0 03 LOAD_CONSTANT R0 = C0 str (11, 26) │
//! │ 1 1390117 CALL_NATIVE write_line(R0) (0, 27) │
//! │ 2 18 RETURN (27, 27) │
//! │┈┈┈┈┈┈┈┈┈┈┈┈┈┈┈┈┈┈┈┈┈┈┈┈┈┈┈┈┈┈┈┈┈┈┈┈┈┈┈┈┈┈┈┈┈┈┈┈┈┈┈┈┈┈┈┈┈┈┈┈┈┈┈┈┈┈┈┈┈┈┈┈┈┈┈┈┈┈│
//! │ Locals │
//! │ ------ │
//! │ i IDENTIFIER TYPE MUTABLE SCOPE REGISTER │
//! │ --- ---------- ---------------- ------- ------- -------- │
//! │┈┈┈┈┈┈┈┈┈┈┈┈┈┈┈┈┈┈┈┈┈┈┈┈┈┈┈┈┈┈┈┈┈┈┈┈┈┈┈┈┈┈┈┈┈┈┈┈┈┈┈┈┈┈┈┈┈┈┈┈┈┈┈┈┈┈┈┈┈┈┈┈┈┈┈┈┈┈│
//! │ Constants │
//! │ --------- │
//! │ i VALUE │
//! │ --- --------------- │
//! │ 0 Hello, world! │
//! └──────────────────────────────────────────────────────────────────────────────┘
//! ```
use std::env::current_exe;
use colored::Colorize;
use crate::{Chunk, ConcreteValue, Local, Value};
const INSTRUCTION_HEADER: [&str; 4] = [
"Instructions",
"------------",
" i BYTECODE OPERATION INFO TYPE POSITION ",
"--- -------- ------------- -------------------- ---------------- ----------",
];
const CONSTANT_HEADER: [&str; 4] = [
"Constants",
"---------",
" i VALUE ",
"--- ---------------",
];
const LOCAL_HEADER: [&str; 4] = [
"Locals",
"------",
" i IDENTIFIER TYPE MUTABLE SCOPE REGISTER",
"--- ---------- ---------------- ------- ------- --------",
];
/// Builder that constructs a human-readable representation of a chunk.
///
/// See the [module-level documentation](index.html) for more information.
pub struct Disassembler<'a> {
output: String,
chunk: &'a Chunk,
source: Option<&'a str>,
// Options
styled: bool,
indent: usize,
}
impl<'a> Disassembler<'a> {
pub fn new(chunk: &'a Chunk) -> Self {
Self {
output: String::new(),
chunk,
source: None,
styled: false,
indent: 0,
}
}
/// The default width of the disassembly output. To correctly align the output, this should
/// return the width of the longest line that the disassembler is guaranteed to produce.
pub fn default_width() -> usize {
let longest_line = INSTRUCTION_HEADER[3];
longest_line.chars().count().max(80)
}
pub fn source(mut self, source: &'a str) -> Self {
self.source = Some(source);
self
}
pub fn styled(mut self, styled: bool) -> Self {
self.styled = styled;
self
}
pub fn indent(mut self, indent: usize) -> Self {
self.indent = indent;
self
}
fn push(
&mut self,
text: &str,
center: bool,
style_bold: bool,
style_dim: bool,
add_border: bool,
) {
let width = Disassembler::default_width();
let characters = text.chars().collect::<Vec<char>>();
let content_width = if add_border { width - 2 } else { width };
let (line_characters, remainder) = characters
.split_at_checked(content_width)
.unwrap_or((characters.as_slice(), &[]));
let (left_pad_length, right_pad_length) = {
let extra_space = content_width.saturating_sub(characters.len());
if center {
(extra_space / 2, extra_space / 2 + extra_space % 2)
} else {
(0, extra_space)
}
};
let content = if style_bold {
line_characters
.iter()
.collect::<String>()
.bold()
.to_string()
} else if style_dim {
line_characters
.iter()
.collect::<String>()
.dimmed()
.to_string()
} else {
line_characters.iter().collect::<String>()
};
let length_before_content = self.output.chars().count();
for _ in 0..self.indent {
self.output.push_str("");
}
if add_border {
self.output.push('│');
}
self.output.push_str(&" ".repeat(left_pad_length));
self.output.push_str(&content);
self.output.push_str(&" ".repeat(right_pad_length));
let length_after_content = self.output.chars().count();
let line_length = length_after_content - length_before_content;
if line_length < content_width - 1 {
self.output
.push_str(&" ".repeat(content_width - line_length));
}
if add_border {
self.output.push('│');
}
self.output.push('\n');
if !remainder.is_empty() {
self.push(
remainder.iter().collect::<String>().as_str(),
center,
style_bold,
style_dim,
add_border,
);
}
}
fn push_header(&mut self, header: &str) {
self.push(header, true, self.styled, false, true);
}
fn push_details(&mut self, details: &str) {
self.push(details, true, false, false, true);
}
fn push_border(&mut self, border: &str) {
self.push(border, false, false, false, false);
}
fn push_empty(&mut self) {
self.push("", false, false, false, true);
}
pub fn disassemble(mut self) -> String {
let width = Disassembler::default_width();
let top_border = "".to_string() + &"".repeat(width - 2) + "";
let section_border = "".to_string() + &"".repeat(width - 2) + "";
let bottom_border = "".to_string() + &"".repeat(width - 2) + "";
let name_display = self
.chunk
.name()
.map(|identifier| identifier.to_string())
.unwrap_or_else(|| {
current_exe()
.map(|path| path.to_string_lossy().to_string())
.unwrap_or("Chunk Disassembly".to_string())
});
self.push_border(&top_border);
self.push_header(&name_display);
if let Some(source) = self.source {
self.push_empty();
self.push_details(
&source
.replace(" ", "")
.replace("\n\n", " ")
.replace('\n', " "),
);
self.push_empty();
}
let info_line = format!(
"{} instructions, {} constants, {} locals, returns {}",
self.chunk.len(),
self.chunk.constants().len(),
self.chunk.locals().len(),
self.chunk
.return_type()
.map(|r#type| r#type.to_string())
.unwrap_or("none".to_string())
);
self.push(&info_line, true, false, true, true);
self.push_empty();
for line in INSTRUCTION_HEADER {
self.push_header(line);
}
for (index, (instruction, position)) in self.chunk.instructions().iter().enumerate() {
let bytecode = format!("{:02X}", u32::from(instruction));
let operation = instruction.operation().to_string();
let info = instruction.disassembly_info(self.chunk);
let type_display = instruction
.yielded_type(self.chunk)
.map(|r#type| {
let type_string = r#type.to_string();
if type_string.len() > 16 {
format!("{type_string:.13}...")
} else {
type_string
}
})
.unwrap_or(String::with_capacity(0));
let position = position.to_string();
let instruction_display = format!(
"{index:^3} {bytecode:>8} {operation:13} {info:^20} {type_display:^16} {position:10}"
);
self.push_details(&instruction_display);
}
self.push_border(&section_border);
for line in LOCAL_HEADER {
self.push_header(line);
}
for (
index,
Local {
identifier_index,
r#type,
scope,
register_index,
is_mutable: mutable,
},
) in self.chunk.locals().iter().enumerate()
{
let identifier_display = self
.chunk
.constants()
.get(*identifier_index as usize)
.map(|value| value.to_string())
.unwrap_or_else(|| "unknown".to_string());
let type_display = r#type
.as_ref()
.map(|r#type| {
let type_string = r#type.to_string();
if type_string.len() > 16 {
format!("{type_string:.13}...")
} else {
type_string
}
})
.unwrap_or("unknown".to_string());
let local_display = format!(
"{index:^3} {identifier_display:10} {type_display:16} {mutable:7} {scope:7} {register_index:8}"
);
self.push_details(&local_display);
}
self.push_border(&section_border);
for line in CONSTANT_HEADER {
self.push_header(line);
}
for (index, value) in self.chunk.constants().iter().enumerate() {
let value_display = {
let value_string = value.to_string();
if value_string.len() > 15 {
format!("{value_string:.12}...")
} else {
value_string
}
};
let constant_display = format!("{index:^3} {value_display:^15}");
self.push_details(&constant_display);
if let Value::Concrete(ConcreteValue::Function(function)) = value {
let function_disassembly = function
.chunk()
.disassembler()
.styled(self.styled)
.indent(self.indent + 1)
.disassemble();
self.output.push_str(&function_disassembly);
}
}
self.push_border(&bottom_border);
let _ = self.output.trim_end_matches('\n');
self.output
}
}

66
dust-lang/src/dust_error.rs
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@ -1,66 +0,0 @@
//! Top-level Dust errors with source code annotations.
use annotate_snippets::{Level, Renderer, Snippet};
use crate::{vm::VmError, CompileError, Span};
/// A top-level error that can occur during the execution of Dust code.
///
/// This error can display nicely formatted messages with source code annotations.
#[derive(Debug, PartialEq)]
pub enum DustError<'src> {
Compile {
error: CompileError,
source: &'src str,
},
Runtime {
error: VmError,
source: &'src str,
},
}
impl<'src> DustError<'src> {
pub fn report(&self) -> String {
let mut report = String::new();
let renderer = Renderer::styled();
match self {
DustError::Runtime { error, source } => {
let position = error.position();
let label = format!("{}: {}", VmError::title(), error.description());
let details = error
.details()
.unwrap_or_else(|| "While running this code".to_string());
let message = Level::Error.title(&label).snippet(
Snippet::source(source)
.fold(false)
.annotation(Level::Error.span(position.0..position.1).label(&details)),
);
report.push_str(&renderer.render(message).to_string());
}
DustError::Compile { error, source } => {
let position = error.position();
let label = format!("{}: {}", CompileError::title(), error.description());
let details = error
.details()
.unwrap_or_else(|| "While parsing this code".to_string());
let message = Level::Error.title(&label).snippet(
Snippet::source(source)
.fold(false)
.annotation(Level::Error.span(position.0..position.1).label(&details)),
);
report.push_str(&renderer.render(message).to_string());
}
}
report
}
}
pub trait AnnotatedError {
fn title() -> &'static str;
fn description(&self) -> &'static str;
fn details(&self) -> Option<String>;
fn position(&self) -> Span;
}

224
dust-lang/src/formatter.rs
View File

@ -1,224 +0,0 @@
//! Formatting tools
use std::mem::replace;
use colored::{ColoredString, Colorize, CustomColor};
use crate::{CompileError, DustError, LexError, Lexer, Token};
pub fn format(source: &str, line_numbers: bool, colored: bool) -> Result<String, DustError> {
let lexer = Lexer::new(source);
let formatted = Formatter::new(lexer)
.line_numbers(line_numbers)
.colored(colored)
.format()
.map_err(|error| DustError::Compile {
error: CompileError::Lex(error),
source,
})?;
Ok(formatted)
}
#[derive(Debug)]
pub struct Formatter<'src> {
lexer: Lexer<'src>,
output_lines: Vec<(String, LineKind, usize)>,
next_line: String,
indent: usize,
current_token: Token<'src>,
previous_token: Token<'src>,
// Options
line_numbers: bool,
colored: bool,
}
impl<'src> Formatter<'src> {
pub fn new(mut lexer: Lexer<'src>) -> Self {
let (current_token, _) = lexer.next_token().unwrap();
Self {
lexer,
output_lines: Vec::new(),
next_line: String::new(),
indent: 0,
current_token,
previous_token: Token::Eof,
line_numbers: false,
colored: false,
}
}
pub fn line_numbers(mut self, line_numbers: bool) -> Self {
self.line_numbers = line_numbers;
self
}
pub fn colored(mut self, colored: bool) -> Self {
self.colored = colored;
self
}
pub fn format(&mut self) -> Result<String, LexError> {
let mut line_kind = LineKind::Empty;
self.advance()?;
while self.current_token != Token::Eof {
use Token::*;
if self.current_token.is_expression() && line_kind != LineKind::Assignment {
line_kind = LineKind::Expression;
}
match self.current_token {
Boolean(boolean) => {
self.push_colored(boolean.red());
}
Byte(byte) => {
self.push_colored(byte.green());
}
Character(character) => {
self.push_colored(
character
.to_string()
.custom_color(CustomColor::new(225, 150, 150)),
);
}
Float(float) => {
self.push_colored(float.yellow());
}
Identifier(identifier) => {
self.push_colored(identifier.blue());
self.next_line.push(' ');
}
Integer(integer) => {
self.push_colored(integer.cyan());
}
String(string) => {
self.push_colored(string.magenta());
}
LeftCurlyBrace => {
self.next_line.push_str(self.current_token.as_str());
self.commit_line(LineKind::OpenBlock);
self.indent += 1;
}
RightCurlyBrace => {
self.commit_line(LineKind::CloseBlock);
self.next_line.push_str(self.current_token.as_str());
self.indent -= 1;
}
Semicolon => {
if line_kind != LineKind::Assignment {
line_kind = LineKind::Statement;
}
self.next_line.push_str(self.current_token.as_str());
self.commit_line(line_kind);
}
Let => {
line_kind = LineKind::Assignment;
self.push_colored(self.current_token.as_str().bold());
self.next_line.push(' ');
}
Break | Loop | Return | While => {
line_kind = LineKind::Statement;
self.push_colored(self.current_token.as_str().bold());
self.next_line.push(' ');
}
token => {
self.next_line.push_str(token.as_str());
self.next_line.push(' ');
}
}
}
let mut previous_index = 0;
let mut current_index = 1;
while current_index < self.output_lines.len() {
let (_, previous, _) = &self.output_lines[previous_index];
let (_, current, _) = &self.output_lines[current_index];
match (previous, current) {
(LineKind::Empty, _)
| (_, LineKind::Empty)
| (LineKind::OpenBlock, _)
| (_, LineKind::CloseBlock) => {}
(left, right) if left == right => {}
_ => {
self.output_lines
.insert(current_index, ("".to_string(), LineKind::Empty, 0));
}
}
previous_index += 1;
current_index += 1;
}
let formatted = String::with_capacity(
self.output_lines
.iter()
.fold(0, |total, (line, _, _)| total + line.len()),
);
Ok(self.output_lines.iter().enumerate().fold(
formatted,
|acc, (index, (line, _, indent))| {
let index = if index == 0 {
format!("{:<3}| ", index + 1).dimmed()
} else {
format!("\n{:<3}| ", index + 1).dimmed()
};
let left_pad = " ".repeat(*indent);
format!("{}{}{}{}", acc, index, left_pad, line)
},
))
}
fn advance(&mut self) -> Result<(), LexError> {
if self.lexer.is_eof() {
return Ok(());
}
let (new_token, position) = self.lexer.next_token()?;
log::info!(
"Parsing {} at {}",
new_token.to_string().bold(),
position.to_string()
);
self.previous_token = replace(&mut self.current_token, new_token);
Ok(())
}
fn push_colored(&mut self, colored: ColoredString) {
self.next_line.push_str(&format!("{}", colored));
}
fn commit_line(&mut self, line_kind: LineKind) {
self.output_lines
.push((self.next_line.clone(), line_kind, self.indent));
self.next_line.clear();
}
}
#[derive(Debug, Clone, Copy, PartialEq)]
pub enum LineKind {
Empty,
Assignment,
Expression,
Statement,
OpenBlock,
CloseBlock,
}

902
dust-lang/src/instruction.rs
View File

@ -1,902 +0,0 @@
//! An operation and its arguments for the Dust virtual machine.
//!
//! Each instruction is a 32-bit unsigned integer that is divided into five fields:
//! - Bits 0-6: The operation code.
//! - Bit 7: A flag indicating whether the B argument is a constant.
//! - Bit 8: A flag indicating whether the C argument is a constant.
//! - Bits 9-16: The A argument,
//! - Bits 17-24: The B argument.
//! - Bits 25-32: The C argument.
//!
//! Be careful when working with instructions directly. When modifying an instruction, be sure to
//! account for the fact that setting the A, B, or C arguments to 0 will have no effect. It is
//! usually best to remove instructions and insert new ones in their place instead of mutating them.
use serde::{Deserialize, Serialize};
use crate::{Chunk, NativeFunction, Operation, Type};
/// An operation and its arguments for the Dust virtual machine.
///
/// See the [module-level documentation](index.html) for more information.
#[derive(Debug, Clone, Copy, Eq, PartialEq, PartialOrd, Ord, Hash, Serialize, Deserialize)]
pub struct Instruction(u32);
impl Instruction {
pub fn with_operation(operation: Operation) -> Instruction {
Instruction(operation as u32)
}
pub fn r#move(to_register: u8, from_register: u8) -> Instruction {
let mut instruction = Instruction(Operation::Move as u32);
instruction.set_a(to_register);
instruction.set_b(from_register);
instruction
}
pub fn close(from_register: u8, to_register: u8) -> Instruction {
let mut instruction = Instruction(Operation::Close as u32);
instruction.set_b(from_register);
instruction.set_c(to_register);
instruction
}
pub fn load_boolean(to_register: u8, value: bool, skip: bool) -> Instruction {
let mut instruction = Instruction(Operation::LoadBoolean as u32);
instruction.set_a(to_register);
instruction.set_b_to_boolean(value);
instruction.set_c_to_boolean(skip);
instruction
}
pub fn load_constant(to_register: u8, constant_index: u8, skip: bool) -> Instruction {
let mut instruction = Instruction(Operation::LoadConstant as u32);
instruction.set_a(to_register);
instruction.set_b(constant_index);
instruction.set_c_to_boolean(skip);
instruction
}
pub fn load_list(to_register: u8, start_register: u8) -> Instruction {
let mut instruction = Instruction(Operation::LoadList as u32);
instruction.set_a(to_register);
instruction.set_b(start_register);
instruction
}
pub fn load_self(to_register: u8) -> Instruction {
let mut instruction = Instruction(Operation::LoadSelf as u32);
instruction.set_a(to_register);
instruction
}
pub fn define_local(to_register: u8, local_index: u8, is_mutable: bool) -> Instruction {
let mut instruction = Instruction(Operation::DefineLocal as u32);
instruction.set_a(to_register);
instruction.set_b(local_index);
instruction.set_c(if is_mutable { 1 } else { 0 });
instruction
}
pub fn get_local(to_register: u8, local_index: u8) -> Instruction {
let mut instruction = Instruction(Operation::GetLocal as u32);
instruction.set_a(to_register);
instruction.set_b(local_index);
instruction
}
pub fn set_local(from_register: u8, local_index: u8) -> Instruction {
let mut instruction = Instruction(Operation::SetLocal as u32);
instruction.set_a(from_register);
instruction.set_b(local_index);
instruction
}
pub fn add(to_register: u8, left_index: u8, right_index: u8) -> Instruction {
let mut instruction = Instruction(Operation::Add as u32);
instruction.set_a(to_register);
instruction.set_b(left_index);
instruction.set_c(right_index);
instruction
}
pub fn subtract(to_register: u8, left_index: u8, right_index: u8) -> Instruction {
let mut instruction = Instruction(Operation::Subtract as u32);
instruction.set_a(to_register);
instruction.set_b(left_index);
instruction.set_c(right_index);
instruction
}
pub fn multiply(to_register: u8, left_index: u8, right_index: u8) -> Instruction {
let mut instruction = Instruction(Operation::Multiply as u32);
instruction.set_a(to_register);
instruction.set_b(left_index);
instruction.set_c(right_index);
instruction
}
pub fn divide(to_register: u8, left_index: u8, right_index: u8) -> Instruction {
let mut instruction = Instruction(Operation::Divide as u32);
instruction.set_a(to_register);
instruction.set_b(left_index);
instruction.set_c(right_index);
instruction
}
pub fn modulo(to_register: u8, left_index: u8, right_index: u8) -> Instruction {
let mut instruction = Instruction(Operation::Modulo as u32);
instruction.set_a(to_register);
instruction.set_b(left_index);
instruction.set_c(right_index);
instruction
}
pub fn test(to_register: u8, test_value: bool) -> Instruction {
let mut instruction = Instruction(Operation::Test as u32);
instruction.set_a(to_register);
instruction.set_c_to_boolean(test_value);
instruction
}
pub fn test_set(to_register: u8, argument_index: u8, test_value: bool) -> Instruction {
let mut instruction = Instruction(Operation::TestSet as u32);
instruction.set_a(to_register);
instruction.set_b(argument_index);
instruction.set_c_to_boolean(test_value);
instruction
}
pub fn equal(comparison_boolean: bool, left_index: u8, right_index: u8) -> Instruction {
let mut instruction = Instruction(Operation::Equal as u32);
instruction.set_a_to_boolean(comparison_boolean);
instruction.set_b(left_index);
instruction.set_c(right_index);
instruction
}
pub fn less(comparison_boolean: bool, left_index: u8, right_index: u8) -> Instruction {
let mut instruction = Instruction(Operation::Less as u32);
instruction.set_a_to_boolean(comparison_boolean);
instruction.set_b(left_index);
instruction.set_c(right_index);
instruction
}
pub fn less_equal(comparison_boolean: bool, left_index: u8, right_index: u8) -> Instruction {
let mut instruction = Instruction(Operation::LessEqual as u32);
instruction.set_a_to_boolean(comparison_boolean);
instruction.set_b(left_index);
instruction.set_c(right_index);
instruction
}
pub fn negate(to_register: u8, from_index: u8) -> Instruction {
let mut instruction = Instruction(Operation::Negate as u32);
instruction.set_a(to_register);
instruction.set_b(from_index);
instruction
}
pub fn not(to_register: u8, from_index: u8) -> Instruction {
let mut instruction = Instruction(Operation::Not as u32);
instruction.set_a(to_register);
instruction.set_b(from_index);
instruction
}
pub fn jump(jump_offset: u8, is_positive: bool) -> Instruction {
let mut instruction = Instruction(Operation::Jump as u32);
instruction.set_b(jump_offset);
instruction.set_c_to_boolean(is_positive);
instruction
}
pub fn call(to_register: u8, function_register: u8, argument_count: u8) -> Instruction {
let mut instruction = Instruction(Operation::Call as u32);
instruction.set_a(to_register);
instruction.set_b(function_register);
instruction.set_c(argument_count);
instruction
}
pub fn call_native(
to_register: u8,
native_fn: NativeFunction,
argument_count: u8,
) -> Instruction {
let mut instruction = Instruction(Operation::CallNative as u32);
let native_fn_byte = native_fn as u8;
instruction.set_a(to_register);
instruction.set_b(native_fn_byte);
instruction.set_c(argument_count);
instruction
}
pub fn r#return(should_return_value: bool) -> Instruction {
let mut instruction = Instruction(Operation::Return as u32);
instruction.set_b_to_boolean(should_return_value);
instruction
}
pub fn operation(&self) -> Operation {
Operation::from((self.0 & 0b0000_0000_0011_1111) as u8)
}
pub fn set_operation(&mut self, operation: Operation) {
self.0 |= u8::from(operation) as u32;
}
pub fn data(&self) -> (Operation, u8, u8, u8, bool, bool) {
(
self.operation(),
self.a(),
self.b(),
self.c(),
self.b_is_constant(),
self.c_is_constant(),
)
}
pub fn a(&self) -> u8 {
(self.0 >> 24) as u8
}
pub fn b(&self) -> u8 {
(self.0 >> 16) as u8
}
pub fn c(&self) -> u8 {
(self.0 >> 8) as u8
}
pub fn a_as_boolean(&self) -> bool {
self.a() != 0
}
pub fn b_as_boolean(&self) -> bool {
self.b() != 0
}
pub fn c_as_boolean(&self) -> bool {
self.c() != 0
}
pub fn set_a_to_boolean(&mut self, boolean: bool) -> &mut Self {
self.set_a(if boolean { 1 } else { 0 });
self
}
pub fn set_b_to_boolean(&mut self, boolean: bool) -> &mut Self {
self.set_b(if boolean { 1 } else { 0 });
self
}
pub fn set_c_to_boolean(&mut self, boolean: bool) -> &mut Self {
self.set_c(if boolean { 1 } else { 0 });
self
}
pub fn set_a(&mut self, to_register: u8) {
self.0 |= (to_register as u32) << 24;
}
pub fn set_b(&mut self, argument: u8) {
self.0 |= (argument as u32) << 16;
}
pub fn set_c(&mut self, argument: u8) {
self.0 |= (argument as u32) << 8;
}
pub fn b_is_constant(&self) -> bool {
self.0 & 0b1000_0000 != 0
}
pub fn c_is_constant(&self) -> bool {
self.0 & 0b0100_0000 != 0
}
pub fn set_b_is_constant(&mut self) -> &mut Self {
self.0 |= 0b1000_0000;
self
}
pub fn set_c_is_constant(&mut self) -> &mut Self {
self.0 |= 0b0100_0000;
self
}
pub fn yields_value(&self) -> bool {
match self.operation() {
Operation::Add
| Operation::Call
| Operation::Divide
| Operation::GetLocal
| Operation::LoadBoolean
| Operation::LoadConstant
| Operation::LoadList
| Operation::LoadSelf
| Operation::Modulo
| Operation::Multiply
| Operation::Negate
| Operation::Not
| Operation::Subtract => true,
Operation::CallNative => {
let native_function = NativeFunction::from(self.b());
native_function.r#type().return_type.is_some()
}
_ => false,
}
}
pub fn yielded_type(&self, chunk: &Chunk) -> Option<Type> {
use Operation::*;
match self.operation() {
Add | Divide | Modulo | Multiply | Subtract => {
if self.b_is_constant() {
chunk.get_constant_type(self.b())
} else {
chunk.get_register_type(self.b())
}
}
LoadBoolean | Not => Some(Type::Boolean),
Negate => {
if self.b_is_constant() {
chunk.get_constant_type(self.b())
} else {
chunk.get_register_type(self.b())
}
}
LoadConstant => chunk.get_constant_type(self.b()),
LoadList => chunk.get_register_type(self.a()),
GetLocal => chunk.get_local_type(self.b()),
CallNative => {
let native_function = NativeFunction::from(self.b());
native_function.r#type().return_type.map(|boxed| *boxed)
}
_ => None,
}
}
pub fn disassembly_info(&self, chunk: &Chunk) -> String {
let format_arguments = || {
let first_argument = if self.b_is_constant() {
format!("C{}", self.b())
} else {
format!("R{}", self.b())
};
let second_argument = if self.c_is_constant() {
format!("C{}", self.c())
} else {
format!("R{}", self.c())
};
(first_argument, second_argument)
};
match self.operation() {
Operation::Move => format!("R{} = R{}", self.a(), self.b()),
Operation::Close => {
let from_register = self.b();
let to_register = self.c().saturating_sub(1);
format!("R{from_register}..=R{to_register}")
}
Operation::LoadBoolean => {
let to_register = self.a();
let boolean = self.b_as_boolean();
let jump = self.c_as_boolean();
if jump {
format!("R{to_register} = {boolean} && SKIP")
} else {
format!("R{to_register} = {boolean}")
}
}
Operation::LoadConstant => {
let register_index = self.a();
let constant_index = self.b();
let jump = self.c_as_boolean();
if jump {
format!("R{register_index} = C{constant_index} && SKIP")
} else {
format!("R{register_index} = C{constant_index}")
}
}
Operation::LoadList => {
let to_register = self.a();
let first_index = self.b();
let last_index = self.c();
format!("R{to_register} = [R{first_index}..=R{last_index}]",)
}
Operation::LoadSelf => {
let to_register = self.a();
let name = chunk
.name()
.map(|idenifier| idenifier.as_str())
.unwrap_or("self");
format!("R{to_register} = {name}")
}
Operation::DefineLocal => {
let to_register = self.a();
let local_index = self.b();
let identifier_display = match chunk.get_identifier(local_index) {
Some(identifier) => identifier.to_string(),
None => "???".to_string(),
};
let mutable_display = if self.c_as_boolean() { "mut" } else { "" };
format!("R{to_register} = L{local_index} {mutable_display} {identifier_display}")
}
Operation::GetLocal => {
let local_index = self.b();
format!("R{} = L{}", self.a(), local_index)
}
Operation::SetLocal => {
let local_index = self.b();
let identifier_display = match chunk.get_identifier(local_index) {
Some(identifier) => identifier.to_string(),
None => "???".to_string(),
};
format!("L{} = R{} {}", local_index, self.a(), identifier_display)
}
Operation::Add => {
let to_register = self.a();
let (first_argument, second_argument) = format_arguments();
format!("R{to_register} = {first_argument} + {second_argument}",)
}
Operation::Subtract => {
let to_register = self.a();
let (first_argument, second_argument) = format_arguments();
format!("R{to_register} = {first_argument} - {second_argument}",)
}
Operation::Multiply => {
let to_register = self.a();
let (first_argument, second_argument) = format_arguments();
format!("R{to_register} = {first_argument} * {second_argument}",)
}
Operation::Divide => {
let to_register = self.a();
let (first_argument, second_argument) = format_arguments();
format!("R{to_register} = {first_argument} / {second_argument}",)
}
Operation::Modulo => {
let to_register = self.a();
let (first_argument, second_argument) = format_arguments();
format!("R{to_register} = {first_argument} % {second_argument}",)
}
Operation::Test => {
let to_register = self.a();
let test_value = self.c_as_boolean();
format!("if R{to_register} != {test_value} {{ SKIP }}")
}
Operation::TestSet => {
let to_register = self.a();
let argument = format!("R{}", self.b());
let test_value = self.c_as_boolean();
let bang = if test_value { "" } else { "!" };
format!("if {bang}R{to_register} {{ R{to_register} = R{argument} }}",)
}
Operation::Equal => {
let comparison_symbol = if self.a_as_boolean() { "==" } else { "!=" };
let (first_argument, second_argument) = format_arguments();
format!("if {first_argument} {comparison_symbol} {second_argument} {{ SKIP }}")
}
Operation::Less => {
let comparison_symbol = if self.a_as_boolean() { "<" } else { ">=" };
let (first_argument, second_argument) = format_arguments();
format!("if {first_argument} {comparison_symbol} {second_argument} {{ SKIP }}")
}
Operation::LessEqual => {
let comparison_symbol = if self.a_as_boolean() { "<=" } else { ">" };
let (first_argument, second_argument) = format_arguments();
format!("if {first_argument} {comparison_symbol} {second_argument} {{ SKIP }}")
}
Operation::Negate => {
let to_register = self.a();
let argument = if self.b_is_constant() {
format!("C{}", self.b())
} else {
format!("R{}", self.b())
};
format!("R{to_register} = -{argument}")
}
Operation::Not => {
let to_register = self.a();
let argument = if self.b_is_constant() {
format!("C{}", self.b())
} else {
format!("R{}", self.b())
};
format!("R{to_register} = !{argument}")
}
Operation::Jump => {
let jump_distance = self.b();
let is_positive = self.c_as_boolean();
if is_positive {
format!("JUMP +{jump_distance}")
} else {
format!("JUMP -{jump_distance}")
}
}
Operation::Call => {
let to_register = self.a();
let function_register = self.b();
let argument_count = self.c();
let mut output = format!("R{to_register} = R{function_register}(");
if argument_count != 0 {
let first_argument = function_register + 1;
for (index, register) in
(first_argument..first_argument + argument_count).enumerate()
{
if index > 0 {
output.push_str(", ");
}
output.push_str(&format!("R{}", register));
}
}
output.push(')');
output
}
Operation::CallNative => {
let to_register = self.a();
let native_function = NativeFunction::from(self.b());
let argument_count = self.c();
let mut output = String::new();
let native_function_name = native_function.as_str();
if native_function.r#type().return_type.is_some() {
output.push_str(&format!("R{} = {}(", to_register, native_function_name));
} else {
output.push_str(&format!("{}(", native_function_name));
}
if argument_count != 0 {
let first_argument = to_register.saturating_sub(argument_count);
for (index, register) in (first_argument..to_register).enumerate() {
if index > 0 {
output.push_str(", ");
}
output.push_str(&format!("R{}", register));
}
}
output.push(')');
output
}
Operation::Return => {
let should_return_value = self.b_as_boolean();
if should_return_value {
"->".to_string()
} else {
"".to_string()
}
}
}
}
}
impl From<&Instruction> for u32 {
fn from(instruction: &Instruction) -> Self {
instruction.0
}
}
#[cfg(test)]
mod tests {
use super::*;
#[test]
fn r#move() {
let mut instruction = Instruction::r#move(0, 1);
instruction.set_b_is_constant();
instruction.set_c_is_constant();
assert_eq!(instruction.operation(), Operation::Move);
assert_eq!(instruction.a(), 0);
assert_eq!(instruction.b(), 1);
assert!(instruction.b_is_constant());
assert!(instruction.b_is_constant());
}
#[test]
fn close() {
let instruction = Instruction::close(1, 2);
assert_eq!(instruction.operation(), Operation::Close);
assert_eq!(instruction.b(), 1);
assert_eq!(instruction.c(), 2);
}
#[test]
fn load_boolean() {
let instruction = Instruction::load_boolean(4, true, true);
assert_eq!(instruction.operation(), Operation::LoadBoolean);
assert_eq!(instruction.a(), 4);
assert!(instruction.a_as_boolean());
assert!(instruction.c_as_boolean());
}
#[test]
fn load_constant() {
let mut instruction = Instruction::load_constant(0, 1, true);
instruction.set_b_is_constant();
instruction.set_c_is_constant();
assert_eq!(instruction.operation(), Operation::LoadConstant);
assert_eq!(instruction.a(), 0);
assert_eq!(instruction.b(), 1);
assert!(instruction.b_is_constant());
assert!(instruction.b_is_constant());
assert!(instruction.c_as_boolean());
}
#[test]
fn load_list() {
let instruction = Instruction::load_list(0, 1);
assert_eq!(instruction.operation(), Operation::LoadList);
assert_eq!(instruction.a(), 0);
assert_eq!(instruction.b(), 1);
}
#[test]
fn load_self() {
let instruction = Instruction::load_self(10);
assert_eq!(instruction.operation(), Operation::LoadSelf);
assert_eq!(instruction.a(), 10);
}
#[test]
fn declare_local() {
let mut instruction = Instruction::define_local(0, 1, true);
instruction.set_b_is_constant();
assert_eq!(instruction.operation(), Operation::DefineLocal);
assert_eq!(instruction.a(), 0);
assert_eq!(instruction.b(), 1);
assert_eq!(instruction.c(), true as u8);
assert!(instruction.b_is_constant());
}
#[test]
fn add() {
let mut instruction = Instruction::add(1, 1, 0);
instruction.set_b_is_constant();
assert_eq!(instruction.operation(), Operation::Add);
assert_eq!(instruction.a(), 1);
assert_eq!(instruction.b(), 1);
assert_eq!(instruction.c(), 0);
assert!(instruction.b_is_constant());
}
#[test]
fn subtract() {
let mut instruction = Instruction::subtract(0, 1, 2);
instruction.set_b_is_constant();
instruction.set_c_is_constant();
assert_eq!(instruction.operation(), Operation::Subtract);
assert_eq!(instruction.a(), 0);
assert_eq!(instruction.b(), 1);
assert_eq!(instruction.c(), 2);
assert!(instruction.b_is_constant());
assert!(instruction.b_is_constant());
}
#[test]
fn multiply() {
let mut instruction = Instruction::multiply(0, 1, 2);
instruction.set_b_is_constant();
instruction.set_c_is_constant();
assert_eq!(instruction.operation(), Operation::Multiply);
assert_eq!(instruction.a(), 0);
assert_eq!(instruction.b(), 1);
assert_eq!(instruction.c(), 2);
assert!(instruction.b_is_constant());
assert!(instruction.b_is_constant());
}
#[test]
fn divide() {
let mut instruction = Instruction::divide(0, 1, 2);
instruction.set_b_is_constant();
instruction.set_c_is_constant();
assert_eq!(instruction.operation(), Operation::Divide);
assert_eq!(instruction.a(), 0);
assert_eq!(instruction.b(), 1);
assert_eq!(instruction.c(), 2);
assert!(instruction.b_is_constant());
assert!(instruction.b_is_constant());
}
#[test]
fn and() {
let instruction = Instruction::test(4, true);
assert_eq!(instruction.operation(), Operation::Test);
assert_eq!(instruction.a(), 4);
assert!(instruction.c_as_boolean());
}
#[test]
fn or() {
let instruction = Instruction::test_set(4, 1, true);
assert_eq!(instruction.operation(), Operation::TestSet);
assert_eq!(instruction.a(), 4);
assert_eq!(instruction.b(), 1);
assert!(instruction.c_as_boolean());
}
#[test]
fn equal() {
let mut instruction = Instruction::equal(true, 1, 2);
instruction.set_b_is_constant();
instruction.set_c_is_constant();
assert_eq!(instruction.operation(), Operation::Equal);
assert!(instruction.a_as_boolean());
assert_eq!(instruction.b(), 1);
assert_eq!(instruction.c(), 2);
assert!(instruction.b_is_constant());
assert!(instruction.b_is_constant());
}
#[test]
fn negate() {
let mut instruction = Instruction::negate(0, 1);
instruction.set_b_is_constant();
instruction.set_c_is_constant();
assert_eq!(instruction.operation(), Operation::Negate);
assert_eq!(instruction.a(), 0);
assert_eq!(instruction.b(), 1);
assert!(instruction.b_is_constant());
assert!(instruction.b_is_constant());
}
#[test]
fn not() {
let mut instruction = Instruction::not(0, 1);
instruction.set_b_is_constant();
instruction.set_c_is_constant();
assert_eq!(instruction.operation(), Operation::Not);
assert_eq!(instruction.a(), 0);
assert_eq!(instruction.b(), 1);
assert!(instruction.b_is_constant());
assert!(instruction.b_is_constant());
}
#[test]
fn jump() {
let instruction = Instruction::jump(4, true);
assert_eq!(instruction.operation(), Operation::Jump);
assert_eq!(instruction.b(), 4);
assert!(instruction.c_as_boolean());
}
#[test]
fn call() {
let instruction = Instruction::call(1, 3, 4);
assert_eq!(instruction.operation(), Operation::Call);
assert_eq!(instruction.a(), 1);
assert_eq!(instruction.b(), 3);
assert_eq!(instruction.c(), 4);
}
#[test]
fn r#return() {
let instruction = Instruction::r#return(true);
assert_eq!(instruction.operation(), Operation::Return);
assert!(instruction.b_as_boolean());
}
}

1476
dust-lang/src/lexer.rs
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44
dust-lang/src/lib.rs
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@ -1,44 +0,0 @@
//! The Dust programming language library.
pub mod chunk;
pub mod compiler;
pub mod disassembler;
pub mod dust_error;
pub mod formatter;
pub mod instruction;
pub mod lexer;
pub mod native_function;
pub mod operation;
pub mod optimizer;
pub mod token;
pub mod r#type;
pub mod value;
pub mod vm;
pub use crate::chunk::{Chunk, ChunkError, Local, Scope};
pub use crate::compiler::{compile, CompileError, Compiler};
pub use crate::disassembler::Disassembler;
pub use crate::dust_error::{AnnotatedError, DustError};
pub use crate::formatter::{format, Formatter};
pub use crate::instruction::Instruction;
pub use crate::lexer::{lex, LexError, Lexer};
pub use crate::native_function::{NativeFunction, NativeFunctionError};
pub use crate::operation::Operation;
pub use crate::optimizer::{optimize, Optimizer};
pub use crate::r#type::{EnumType, FunctionType, RangeableType, StructType, Type, TypeConflict};
pub use crate::token::{Token, TokenKind, TokenOwned};
pub use crate::value::{ConcreteValue, Function, Value, ValueError};
pub use crate::vm::{run, Vm, VmError};
use std::fmt::Display;
use serde::{Deserialize, Serialize};
#[derive(Clone, Copy, Debug, Eq, PartialEq, PartialOrd, Ord, Hash, Serialize, Deserialize)]
pub struct Span(pub usize, pub usize);
impl Display for Span {
fn fmt(&self, f: &mut std::fmt::Formatter<'_>) -> std::fmt::Result {
write!(f, "({}, {})", self.0, self.1)
}
}

418
dust-lang/src/native_function.rs
View File

@ -1,418 +0,0 @@
//! Built-in functions that implement extended functionality.
//!
//! Native functions are used either to implement features that are not possible to implement in
//! Dust itself or that are more efficient to implement in Rust.
use std::{
fmt::{self, Display, Formatter},
io::{self, stdin, stdout, Write},
string::{self},
};
use serde::{Deserialize, Serialize};
use crate::{
AnnotatedError, ConcreteValue, FunctionType, Instruction, Span, Type, Value, Vm, VmError,
};
macro_rules! define_native_function {
($(($name:ident, $byte:literal, $str:expr, $type:expr)),*) => {
/// A dust-native function.
///
/// See the [module-level documentation](index.html) for more information.
#[derive(Clone, Debug, Eq, PartialEq, PartialOrd, Ord, Serialize, Deserialize)]
pub enum NativeFunction {
$(
$name = $byte as isize,
)*
}
impl NativeFunction {
pub fn as_str(&self) -> &'static str {
match self {
$(
NativeFunction::$name => $str,
)*
}
}
#[allow(clippy::should_implement_trait)]
pub fn from_str(string: &str) -> Option<Self> {
match string {
$(
$str => Some(NativeFunction::$name),
)*
_ => None,
}
}
pub fn r#type(&self) -> FunctionType {
match self {
$(
NativeFunction::$name => $type,
)*
}
}
pub fn returns_value(&self) -> bool {
match self {
$(
NativeFunction::$name => $type.return_type.is_some(),
)*
}
}
}
impl From<u8> for NativeFunction {
fn from(byte: u8) -> Self {
match byte {
$(
$byte => NativeFunction::$name,
)*
_ => {
if cfg!(test) {
panic!("Invalid native function byte: {}", byte)
} else {
NativeFunction::Panic
}
}
}
}
}
impl From<NativeFunction> for u8 {
fn from(native_function: NativeFunction) -> Self {
match native_function {
$(
NativeFunction::$name => $byte,
)*
}
}
}
};
}
define_native_function! {
// Assertion
(
Assert,
0_u8,
"assert",
FunctionType {
type_parameters: None,
value_parameters: None,
return_type: None
}
),
// (AssertEqual, 1_u8, "assert_equal", false),
// (AssertNotEqual, 2_u8, "assert_not_equal", false),
(
Panic,
3_u8,
"panic",
FunctionType {
type_parameters: None,
value_parameters: None,
return_type: Some(Box::new(Type::Any))
}
),
// // Type conversion
// (Parse, 4_u8, "parse", true),
// (ToByte, 5_u8, "to_byte", true),
// (ToFloat, 6_u8, "to_float", true),
// (ToInteger, 7_u8, "to_integer", true),
(
ToString,
8_u8,
"to_string",
FunctionType {
type_parameters: None,
value_parameters: Some(vec![(0, Type::Any)]),
return_type: Some(Box::new(Type::String { length: None }))
}
),
// // List and string
// (All, 9_u8, "all", true),
// (Any, 10_u8, "any", true),
// (Append, 11_u8, "append", false),
// (Contains, 12_u8, "contains", true),
// (Dedup, 13_u8, "dedup", false),
// (EndsWith, 14_u8, "ends_with", true),
// (Find, 15_u8, "find", true),
// (Get, 16_u8, "get", true),
// (IndexOf, 17_u8, "index_of", true),
// (Length, 18_u8, "length", true),
// (Prepend, 19_u8, "prepend", false),
// (Replace, 20_u8, "replace", false),
// (Set, 21_u8, "set", false),
// (StartsWith, 22_u8, "starts_with", true),
// (Slice, 23_u8, "slice", true),
// (Sort, 24_u8, "sort", false),
// (Split, 25_u8, "split", true),
// // List
// (Flatten, 26_u8, "flatten", false),
// (Join, 27_u8, "join", true),
// (Map, 28_u8, "map", true),
// (Reduce, 29_u8, "reduce", true),
// (Remove, 30_u8, "remove", false),
// (Reverse, 31_u8, "reverse", false),
// (Unzip, 32_u8, "unzip", true),
// (Zip, 33_u8, "zip", true),
// // String
// (Bytes, 34_u8, "bytes", true),
// (CharAt, 35_u8, "char_at", true),
// (CharCodeAt, 36_u8, "char_code_at", true),
// (Chars, 37_u8, "chars", true),
// (Format, 38_u8, "format", true),
// (Repeat, 39_u8, "repeat", true),
// (SplitAt, 40_u8, "split_at", true),
// (SplitLines, 41_u8, "split_lines", true),
// (SplitWhitespace, 42_u8, "split_whitespace", true),
// (ToLowerCase, 43_u8, "to_lower_case", true),
// (ToUpperCase, 44_u8, "to_upper_case", true),
// (Trim, 45_u8, "trim", true),
// (TrimEnd, 46_u8, "trim_end", true),
// (TrimStart, 47_u8, "trim_start", true),
// // I/O
// // Read
// (Read, 48_u8, "read", true),
// (ReadFile, 49_u8, "read_file", true),
(
ReadLine,
50_u8,
"read_line",
FunctionType {
type_parameters: None,
value_parameters: None,
return_type: Some(Box::new(Type::String { length: None }))
}
),
// (ReadTo, 51_u8, "read_to", false),
// (ReadUntil, 52_u8, "read_until", true),
// // Write
// (AppendFile, 53_u8, "append_file", false),
// (PrependFile, 54_u8, "prepend_file", false),
(
Write,
55_u8,
"write",
FunctionType {
type_parameters: None,
value_parameters: Some(vec![(0, Type::String { length: None })]),
return_type: None
}
),
// (WriteFile, 56_u8, "write_file", false),
(
WriteLine,
57_u8,
"write_line",
FunctionType {
type_parameters: None,
value_parameters: Some(vec![(0, Type::String { length: None })]),
return_type: None
}
)
// // Random
// (Random, 58_u8, "random", true),
// (RandomInRange, 59_u8, "random_in_range", true)
}
impl NativeFunction {
pub fn call(
&self,
instruction: Instruction,
vm: &Vm,
position: Span,
) -> Result<Option<Value>, VmError> {
let to_register = instruction.a();
let argument_count = instruction.c();
let return_value = match self {
NativeFunction::Panic => {
let message = if argument_count == 0 {
None
} else {
let mut message = String::new();
for argument_index in 0..argument_count {
if argument_index != 0 {
message.push(' ');
}
let argument = vm.open_register(argument_index, position)?;
message.push_str(&argument.to_string());
}
Some(message)
};
return Err(VmError::NativeFunction(NativeFunctionError::Panic {
message,
position,
}));
}
// Type conversion
NativeFunction::ToString => {
let mut string = String::new();
for argument_index in 0..argument_count {
let argument = vm.open_register(argument_index, position)?;
string.push_str(&argument.to_string());
}
Some(Value::Concrete(ConcreteValue::String(string)))
}
// I/O
NativeFunction::ReadLine => {
let mut buffer = String::new();
stdin().read_line(&mut buffer).map_err(|io_error| {
VmError::NativeFunction(NativeFunctionError::Io {
error: io_error.kind(),
position,
})
})?;
buffer = buffer.trim_end_matches('\n').to_string();
Some(Value::Concrete(ConcreteValue::String(buffer)))
}
NativeFunction::Write => {
let to_register = instruction.a();
let mut stdout = stdout();
let map_err = |io_error: io::Error| {
VmError::NativeFunction(NativeFunctionError::Io {
error: io_error.kind(),
position,
})
};
let first_argument = to_register.saturating_sub(argument_count);
let last_argument = to_register.saturating_sub(1);
for argument_index in first_argument..=last_argument {
if argument_index != first_argument {
stdout.write(b" ").map_err(map_err)?;
}
let argument_string = vm.open_register(argument_index, position)?.to_string();
stdout
.write_all(argument_string.as_bytes())
.map_err(map_err)?;
}
None
}
NativeFunction::WriteLine => {
let mut stdout = stdout();
let map_err = |io_error: io::Error| {
VmError::NativeFunction(NativeFunctionError::Io {
error: io_error.kind(),
position,
})
};
let first_index = to_register.saturating_sub(argument_count);
let arguments = vm.open_nonempty_registers(first_index..to_register, position)?;
for (index, argument) in arguments.into_iter().enumerate() {
if index != 0 {
stdout.write(b" ").map_err(map_err)?;
}
if let Value::Concrete(ConcreteValue::String(string)) = argument {
let bytes = string.as_bytes();
stdout.write_all(bytes).map_err(map_err)?;
} else {
let bytes = argument.to_string().into_bytes();
stdout.write_all(&bytes).map_err(map_err)?;
}
}
stdout.write(b"\n").map_err(map_err)?;
None
}
_ => todo!(),
};
Ok(return_value)
}
}
impl Display for NativeFunction {
fn fmt(&self, f: &mut Formatter) -> fmt::Result {
write!(f, "{}", self.as_str())
}
}
#[derive(Debug, Clone, PartialEq)]
pub enum NativeFunctionError {
ExpectedArgumentCount {
expected: usize,
found: usize,
position: Span,
},
Panic {
message: Option<String>,
position: Span,
},
Parse {
error: string::ParseError,
position: Span,
},
Io {
error: io::ErrorKind,
position: Span,
},
}
impl AnnotatedError for NativeFunctionError {
fn title() -> &'static str {
"Native Function Error"
}
fn description(&self) -> &'static str {
match self {
NativeFunctionError::ExpectedArgumentCount { .. } => {
"Expected a different number of arguments"
}
NativeFunctionError::Panic { .. } => "Explicit panic",
NativeFunctionError::Parse { .. } => "Failed to parse value",
NativeFunctionError::Io { .. } => "I/O error",
}
}
fn details(&self) -> Option<String> {
match self {
NativeFunctionError::ExpectedArgumentCount {
expected, found, ..
} => Some(format!("Expected {} arguments, found {}", expected, found)),
NativeFunctionError::Panic { message, .. } => message.clone(),
NativeFunctionError::Parse { error, .. } => Some(format!("{}", error)),
NativeFunctionError::Io { error, .. } => Some(format!("{}", error)),
}
}
fn position(&self) -> Span {
match self {
NativeFunctionError::ExpectedArgumentCount { position, .. } => *position,
NativeFunctionError::Panic { position, .. } => *position,
NativeFunctionError::Parse { position, .. } => *position,
NativeFunctionError::Io { position, .. } => *position,
}
}
}

110
dust-lang/src/operation.rs
View File

@ -1,110 +0,0 @@
//! Part of an [Instruction][crate::Instruction], which can be executed by the Dust virtual machine.
//!
//! !!! Warning !!!
//! The byte values of the operations matter. The seventh and eighth bits must be zero so that the
//! [Instruction][crate::Instruction] type can use them as flags.
use std::fmt::{self, Display, Formatter};
macro_rules! define_operation {
($(($name:ident, $byte:literal, $str:expr, $type:expr)),*) => {
/// Part of an [Instruction][crate::Instruction], which can be executed by the Dust virtual machine.)
///
/// See the [module-level documentation](index.html) for more information.
#[derive(Clone, Copy, Debug, PartialEq)]
pub enum Operation {
$(
$name = $byte as isize,
)*
}
impl From<u8> for Operation {
fn from(byte: u8) -> Self {
match byte {
$(
$byte => Operation::$name,
)*
_ => {
if cfg!(test) {
panic!("Invalid operation byte: {}", byte)
} else {
Operation::Return
}
}
}
}
}
impl From<Operation> for u8 {
fn from(operation: Operation) -> Self {
match operation {
$(
Operation::$name => $byte,
)*
}
}
}
impl Display for Operation {
fn fmt(&self, f: &mut Formatter) -> fmt::Result {
match self {
$(
Operation::$name => write!(f, "{}", $str),
)*
}
}
}
}
}
define_operation! {
(Move, 0b0000_0000, "MOVE", None),
(Close, 0b000_0001, "CLOSE", None),
(LoadBoolean, 0b0000_0010, "LOAD_BOOLEAN", None),
(LoadConstant, 0b0000_0011, "LOAD_CONSTANT", None),
(LoadList, 0b0000_0100, "LOAD_LIST", None),
(LoadSelf, 0b0000_0101, "LOAD_SELF", None),
(DefineLocal, 0b0000_0110, "DEFINE_LOCAL", None),
(GetLocal, 0b0000_0111, "GET_LOCAL", None),
(SetLocal, 0b0000_1000, "SET_LOCAL", None),
(Add, 0b0000_1001, "ADD", None),
(Subtract, 0b0000_1010, "SUBTRACT", None),
(Multiply, 0b0000_1011, "MULTIPLY", None),
(Divide, 0b0000_1100, "DIVIDE", None),
(Modulo, 0b0000_1101, "MODULO", None),
(Test, 0b0000_1110, "TEST", None),
(TestSet, 0b0000_1111, "TEST_SET", None),
(Equal, 0b0001_0000, "EQUAL", None),
(Less, 0b0001_0001, "LESS", None),
(LessEqual, 0b0001_0010, "LESS_EQUAL", None),
(Negate, 0b0001_0011, "NEGATE", None),
(Not, 0b0001_0100, "NOT", None),
(Jump, 0b0001_0101, "JUMP", None),
(Call, 0b0001_0110, "CALL", None),
(CallNative, 0b0001_0111, "CALL_NATIVE", None),
(Return, 0b0001_1000, "RETURN", None)
}
impl Operation {
pub fn is_math(&self) -> bool {
matches!(
self,
Operation::Add
| Operation::Subtract
| Operation::Multiply
| Operation::Divide
| Operation::Modulo
)
}
pub fn is_comparison(&self) -> bool {
matches!(
self,
Operation::Equal | Operation::Less | Operation::LessEqual
)
}
pub fn is_test(&self) -> bool {
matches!(self, Operation::Test | Operation::TestSet)
}
}

96
dust-lang/src/optimizer.rs
View File

@ -1,96 +0,0 @@
//! Tools used by the compiler to optimize a chunk's bytecode.
use std::{iter::Map, slice::Iter};
use crate::{Instruction, Operation, Span};
type MapToOperation = fn(&(Instruction, Span)) -> Operation;
type OperationIter<'iter> = Map<Iter<'iter, (Instruction, Span)>, MapToOperation>;
/// Performs optimizations on a subset of instructions.
pub fn optimize(instructions: &mut [(Instruction, Span)]) -> usize {
Optimizer::new(instructions).optimize()
}
/// An instruction optimizer that mutably borrows instructions from a chunk.
#[derive(Debug, Eq, PartialEq, PartialOrd, Ord)]
pub struct Optimizer<'chunk> {
instructions: &'chunk mut [(Instruction, Span)],
}
impl<'chunk> Optimizer<'chunk> {
/// Creates a new optimizer with a mutable reference to some of a chunk's instructions.
pub fn new(instructions: &'chunk mut [(Instruction, Span)]) -> Self {
Self { instructions }
}
/// Potentially mutates the instructions to optimize them.
pub fn optimize(&mut self) -> usize {
let mut optimizations = 0;
if matches!(
self.get_operations(),
Some([
Operation::Equal | Operation::Less | Operation::LessEqual,
Operation::Jump,
Operation::LoadBoolean | Operation::LoadConstant,
Operation::LoadBoolean | Operation::LoadConstant,
])
) {
self.optimize_comparison();
optimizations += 1;
}
optimizations
}
/// Optimizes a comparison operation.
///
/// The instructions must be in the following order:
/// - `Operation::Equal | Operation::Less | Operation::LessEqual`
/// - `Operation::Jump`
/// - `Operation::LoadBoolean | Operation::LoadConstant`
/// - `Operation::LoadBoolean | Operation::LoadConstant`
fn optimize_comparison(&mut self) {
log::debug!("Optimizing comparison");
let first_loader_register = {
let first_loader = &mut self.instructions[2].0;
first_loader.set_c_to_boolean(true);
first_loader.a()
};
let second_loader = &mut self.instructions[3].0;
let mut second_loader_new = Instruction::with_operation(second_loader.operation());
second_loader_new.set_a(first_loader_register);
second_loader_new.set_b(second_loader.b());
second_loader_new.set_c(second_loader.c());
second_loader_new.set_b_to_boolean(second_loader.b_is_constant());
second_loader_new.set_c_to_boolean(second_loader.c_is_constant());
*second_loader = second_loader_new;
}
fn operations_iter(&self) -> OperationIter {
self.instructions
.iter()
.map(|(instruction, _)| instruction.operation())
}
fn get_operations<const COUNT: usize>(&self) -> Option<[Operation; COUNT]> {
if self.instructions.len() < COUNT {
return None;
}
let mut n_operations = [Operation::Return; COUNT];
for (nth, operation) in n_operations.iter_mut().zip(self.operations_iter()) {
*nth = operation;
}
Some(n_operations)
}
}

642
dust-lang/src/token.rs
View File

@ -1,642 +0,0 @@
//! Token, TokenOwned and TokenKind types.
use std::fmt::{self, Display, Formatter};
use serde::{Deserialize, Serialize};
macro_rules! define_tokens {
($($variant:ident $(($data_type:ty))?),+ $(,)?) => {
/// Source token.
///
/// This is a borrowed type, i.e. some variants contain references to the source text.
#[derive(Debug, Clone, Copy, Eq, PartialEq, PartialOrd, Ord, Default, Serialize, Deserialize)]
pub enum Token<'src> {
#[default]
Eof,
$(
$variant $(($data_type))?,
)*
}
#[derive(Debug, PartialEq, Clone)]
/// Data-less representation of a source token.
///
/// If a [Token] borrows from the source text, its TokenKind omits the data.
pub enum TokenKind {
Eof,
$(
$variant,
)*
}
};
}
define_tokens! {
// Hard-coded values
Boolean(&'src str),
Byte(&'src str),
Character(char),
Float(&'src str),
Identifier(&'src str),
Integer(&'src str),
String(&'src str),
// Keywords
Async,
Bool,
Break,
Else,
FloatKeyword,
Fn,
If,
Int,
Let,
Loop,
Map,
Mut,
Return,
Str,
Struct,
While,
// Symbols
ArrowThin,
BangEqual,
Bang,
Colon,
Comma,
Dot,
DoubleAmpersand,
DoubleDot,
DoubleEqual,
DoublePipe,
Equal,
Greater,
GreaterEqual,
LeftCurlyBrace,
LeftParenthesis,
LeftSquareBrace,
Less,
LessEqual,
Minus,
MinusEqual,
Percent,
PercentEqual,
Plus,
PlusEqual,
RightCurlyBrace,
RightParenthesis,
RightSquareBrace,
Semicolon,
Slash,
SlashEqual,
Star,
StarEqual,
}
impl<'src> Token<'src> {
#[allow(clippy::len_without_is_empty)]
pub fn len(&self) -> usize {
match self {
Token::Eof => 0,
Token::Boolean(text) => text.len(),
Token::Byte(_) => 3,
Token::Character(_) => 3,
Token::Float(text) => text.len(),
Token::Identifier(text) => text.len(),
Token::Integer(text) => text.len(),
Token::String(text) => text.len() + 2,
Token::Async => 5,
Token::ArrowThin => 2,
Token::Bool => 4,
Token::Break => 5,
Token::Else => 4,
Token::FloatKeyword => 5,
Token::Fn => 2,
Token::If => 2,
Token::Int => 3,
Token::Let => 3,
Token::Loop => 4,
Token::Map => 3,
Token::Mut => 3,
Token::Str => 3,
Token::Struct => 6,
Token::While => 5,
Token::BangEqual => 2,
Token::Bang => 1,
Token::Colon => 1,
Token::Comma => 1,
Token::Dot => 1,
Token::DoubleAmpersand => 2,
Token::DoubleDot => 2,
Token::DoubleEqual => 2,
Token::DoublePipe => 2,
Token::Equal => 1,
Token::Greater => 1,
Token::GreaterEqual => 2,
Token::LeftCurlyBrace => 1,
Token::LeftParenthesis => 1,
Token::LeftSquareBrace => 1,
Token::Less => 1,
Token::LessEqual => 2,
Token::Minus => 1,
Token::MinusEqual => 2,
Token::Percent => 1,
Token::PercentEqual => 2,
Token::Plus => 1,
Token::PlusEqual => 2,
Token::Return => 6,
Token::RightCurlyBrace => 1,
Token::RightParenthesis => 1,
Token::RightSquareBrace => 1,
Token::Semicolon => 1,
Token::Slash => 1,
Token::SlashEqual => 2,
Token::Star => 1,
Token::StarEqual => 2,
}
}
pub fn as_str(&self) -> &str {
match self {
Token::Eof => "",
Token::Boolean(text) => text,
Token::Byte(text) => text,
Token::Character(_) => "character token",
Token::Float(text) => text,
Token::Identifier(text) => text,
Token::Integer(text) => text,
Token::String(text) => text,
Token::Async => "async",
Token::ArrowThin => "->",
Token::Bool => "bool",
Token::Break => "break",
Token::Else => "else",
Token::FloatKeyword => "float",
Token::Fn => "fn",
Token::If => "if",
Token::Int => "int",
Token::Let => "let",
Token::Loop => "loop",
Token::Map => "map",
Token::Mut => "mut",
Token::Str => "str",
Token::Struct => "struct",
Token::While => "while",
Token::BangEqual => "!=",
Token::Bang => "!",
Token::Colon => ":",
Token::Comma => ",",
Token::Dot => ".",
Token::DoubleAmpersand => "&&",
Token::DoubleDot => "..",
Token::DoubleEqual => "==",
Token::DoublePipe => "||",
Token::Equal => "=",
Token::Greater => ">",
Token::GreaterEqual => ">=",
Token::LeftCurlyBrace => "{",
Token::LeftParenthesis => "(",
Token::LeftSquareBrace => "[",
Token::Less => "<",
Token::LessEqual => "<=",
Token::Minus => "-",
Token::MinusEqual => "-=",
Token::Percent => "%",
Token::PercentEqual => "%=",
Token::Plus => "+",
Token::PlusEqual => "+=",
Token::Return => "return",
Token::RightCurlyBrace => "}",
Token::RightParenthesis => ")",
Token::RightSquareBrace => "]",
Token::Semicolon => ";",
Token::Slash => "/",
Token::SlashEqual => "/=",
Token::Star => "*",
Token::StarEqual => "*=",
}
}
pub fn to_owned(&self) -> TokenOwned {
match self {
Token::ArrowThin => TokenOwned::ArrowThin,
Token::Async => TokenOwned::Async,
Token::BangEqual => TokenOwned::BangEqual,
Token::Bang => TokenOwned::Bang,
Token::Bool => TokenOwned::Bool,
Token::Boolean(boolean) => TokenOwned::Boolean(boolean.to_string()),
Token::Break => TokenOwned::Break,
Token::Byte(byte) => TokenOwned::Byte(byte.to_string()),
Token::Character(character) => TokenOwned::Character(*character),
Token::Colon => TokenOwned::Colon,
Token::Comma => TokenOwned::Comma,
Token::Dot => TokenOwned::Dot,
Token::DoubleAmpersand => TokenOwned::DoubleAmpersand,
Token::DoubleDot => TokenOwned::DoubleDot,
Token::DoubleEqual => TokenOwned::DoubleEqual,
Token::DoublePipe => TokenOwned::DoublePipe,
Token::Else => TokenOwned::Else,
Token::Eof => TokenOwned::Eof,
Token::Equal => TokenOwned::Equal,
Token::Float(float) => TokenOwned::Float(float.to_string()),
Token::FloatKeyword => TokenOwned::FloatKeyword,
Token::Fn => TokenOwned::Fn,
Token::Greater => TokenOwned::Greater,
Token::GreaterEqual => TokenOwned::GreaterOrEqual,
Token::Identifier(text) => TokenOwned::Identifier(text.to_string()),
Token::If => TokenOwned::If,
Token::Int => TokenOwned::Int,
Token::Integer(integer) => TokenOwned::Integer(integer.to_string()),
Token::LeftCurlyBrace => TokenOwned::LeftCurlyBrace,
Token::LeftParenthesis => TokenOwned::LeftParenthesis,
Token::LeftSquareBrace => TokenOwned::LeftSquareBrace,
Token::Let => TokenOwned::Let,
Token::Less => TokenOwned::Less,
Token::LessEqual => TokenOwned::LessOrEqual,
Token::Loop => TokenOwned::Loop,
Token::Map => TokenOwned::Map,
Token::Minus => TokenOwned::Minus,
Token::MinusEqual => TokenOwned::MinusEqual,
Token::Mut => TokenOwned::Mut,
Token::Percent => TokenOwned::Percent,
Token::PercentEqual => TokenOwned::PercentEqual,
Token::Plus => TokenOwned::Plus,
Token::PlusEqual => TokenOwned::PlusEqual,
Token::Return => TokenOwned::Return,
Token::RightCurlyBrace => TokenOwned::RightCurlyBrace,
Token::RightParenthesis => TokenOwned::RightParenthesis,
Token::RightSquareBrace => TokenOwned::RightSquareBrace,
Token::Semicolon => TokenOwned::Semicolon,
Token::Star => TokenOwned::Star,
Token::StarEqual => TokenOwned::StarEqual,
Token::Slash => TokenOwned::Slash,
Token::SlashEqual => TokenOwned::SlashEqual,
Token::String(text) => TokenOwned::String(text.to_string()),
Token::Str => TokenOwned::Str,
Token::Struct => TokenOwned::Struct,
Token::While => TokenOwned::While,
}
}
pub fn kind(&self) -> TokenKind {
match self {
Token::ArrowThin => TokenKind::ArrowThin,
Token::Async => TokenKind::Async,
Token::BangEqual => TokenKind::BangEqual,
Token::Bang => TokenKind::Bang,
Token::Bool => TokenKind::Bool,
Token::Boolean(_) => TokenKind::Boolean,
Token::Break => TokenKind::Break,
Token::Byte(_) => TokenKind::Byte,
Token::Character(_) => TokenKind::Character,
Token::Colon => TokenKind::Colon,
Token::Comma => TokenKind::Comma,
Token::Dot => TokenKind::Dot,
Token::DoubleAmpersand => TokenKind::DoubleAmpersand,
Token::DoubleDot => TokenKind::DoubleDot,
Token::DoubleEqual => TokenKind::DoubleEqual,
Token::DoublePipe => TokenKind::DoublePipe,
Token::Else => TokenKind::Else,
Token::Eof => TokenKind::Eof,
Token::Equal => TokenKind::Equal,
Token::Float(_) => TokenKind::Float,
Token::FloatKeyword => TokenKind::FloatKeyword,
Token::Fn => TokenKind::Fn,
Token::Greater => TokenKind::Greater,
Token::GreaterEqual => TokenKind::GreaterEqual,
Token::Identifier(_) => TokenKind::Identifier,
Token::If => TokenKind::If,
Token::Int => TokenKind::Int,
Token::Integer(_) => TokenKind::Integer,
Token::LeftCurlyBrace => TokenKind::LeftCurlyBrace,
Token::LeftParenthesis => TokenKind::LeftParenthesis,
Token::LeftSquareBrace => TokenKind::LeftSquareBrace,
Token::Let => TokenKind::Let,
Token::Less => TokenKind::Less,
Token::LessEqual => TokenKind::LessEqual,
Token::Loop => TokenKind::Loop,
Token::Map => TokenKind::Map,
Token::Minus => TokenKind::Minus,
Token::MinusEqual => TokenKind::MinusEqual,
Token::Mut => TokenKind::Mut,
Token::Percent => TokenKind::Percent,
Token::PercentEqual => TokenKind::PercentEqual,
Token::Plus => TokenKind::Plus,
Token::PlusEqual => TokenKind::PlusEqual,
Token::Return => TokenKind::Return,
Token::RightCurlyBrace => TokenKind::RightCurlyBrace,
Token::RightParenthesis => TokenKind::RightParenthesis,
Token::RightSquareBrace => TokenKind::RightSquareBrace,
Token::Semicolon => TokenKind::Semicolon,
Token::Star => TokenKind::Star,
Token::StarEqual => TokenKind::StarEqual,
Token::Slash => TokenKind::Slash,
Token::SlashEqual => TokenKind::SlashEqual,
Token::Str => TokenKind::Str,
Token::String(_) => TokenKind::String,
Token::Struct => TokenKind::Struct,
Token::While => TokenKind::While,
}
}
/// Returns true if the token yields a value, begins an expression or is an expression operator.
pub fn is_expression(&self) -> bool {
matches!(
self,
Token::Boolean(_)
| Token::Byte(_)
| Token::Character(_)
| Token::Float(_)
| Token::Identifier(_)
| Token::Integer(_)
| Token::String(_)
| Token::Break
| Token::If
| Token::Return
| Token::Map
| Token::Loop
| Token::Struct
| Token::BangEqual
| Token::DoubleAmpersand
| Token::DoubleEqual
| Token::DoublePipe
| Token::Equal
| Token::Greater
| Token::GreaterEqual
| Token::LeftCurlyBrace
| Token::LeftParenthesis
| Token::LeftSquareBrace
| Token::Less
| Token::LessEqual
| Token::Minus
| Token::MinusEqual
| Token::Percent
| Token::PercentEqual
| Token::Plus
| Token::PlusEqual
| Token::Slash
| Token::SlashEqual
| Token::Star
| Token::StarEqual
)
}
}
impl<'src> Display for Token<'src> {
fn fmt(&self, f: &mut Formatter) -> fmt::Result {
match self {
Token::ArrowThin => write!(f, "->"),
Token::Async => write!(f, "async"),
Token::BangEqual => write!(f, "!="),
Token::Bang => write!(f, "!"),
Token::Bool => write!(f, "bool"),
Token::Boolean(value) => write!(f, "{value}"),
Token::Break => write!(f, "break"),
Token::Byte(value) => write!(f, "{value}"),
Token::Character(value) => write!(f, "{value}"),
Token::Colon => write!(f, ":"),
Token::Comma => write!(f, ","),
Token::Dot => write!(f, "."),
Token::DoubleAmpersand => write!(f, "&&"),
Token::DoubleDot => write!(f, ".."),
Token::DoubleEqual => write!(f, "=="),
Token::DoublePipe => write!(f, "||"),
Token::Else => write!(f, "else"),
Token::Eof => write!(f, "EOF"),
Token::Equal => write!(f, "="),
Token::Float(value) => write!(f, "{value}"),
Token::FloatKeyword => write!(f, "float"),
Token::Fn => write!(f, "fn"),
Token::Greater => write!(f, ">"),
Token::GreaterEqual => write!(f, ">="),
Token::Identifier(value) => write!(f, "{value}"),
Token::If => write!(f, "if"),
Token::Int => write!(f, "int"),
Token::Integer(value) => write!(f, "{value}"),
Token::LeftCurlyBrace => write!(f, "{{"),
Token::LeftParenthesis => write!(f, "("),
Token::LeftSquareBrace => write!(f, "["),
Token::Let => write!(f, "let"),
Token::Less => write!(f, "<"),
Token::LessEqual => write!(f, "<="),
Token::Loop => write!(f, "loop"),
Token::Map => write!(f, "map"),
Token::Minus => write!(f, "-"),
Token::MinusEqual => write!(f, "-="),
Token::Mut => write!(f, "mut"),
Token::Percent => write!(f, "%"),
Token::PercentEqual => write!(f, "%="),
Token::Plus => write!(f, "+"),
Token::PlusEqual => write!(f, "+="),
Token::Return => write!(f, "return"),
Token::RightCurlyBrace => write!(f, "}}"),
Token::RightParenthesis => write!(f, ")"),
Token::RightSquareBrace => write!(f, "]"),
Token::Semicolon => write!(f, ";"),
Token::Slash => write!(f, "/"),
Token::SlashEqual => write!(f, "/="),
Token::Star => write!(f, "*"),
Token::StarEqual => write!(f, "*="),
Token::Str => write!(f, "str"),
Token::String(value) => write!(f, "{value}"),
Token::Struct => write!(f, "struct"),
Token::While => write!(f, "while"),
}
}
}
/// Owned representation of a source token.
///
/// If a [Token] borrows from the source text, its TokenOwned omits the data.
#[derive(Debug, PartialEq, Clone)]
pub enum TokenOwned {
Eof,
Identifier(String),
// Hard-coded values
Boolean(String),
Byte(String),
Character(char),
Float(String),
Integer(String),
String(String),
// Keywords
Async,
Bool,
Break,
Else,
FloatKeyword,
Fn,
If,
Int,
Let,
Loop,
Map,
Mut,
Return,
Str,
While,
// Symbols
ArrowThin,
Bang,
BangEqual,
Colon,
Comma,
Dot,
DoubleAmpersand,
DoubleDot,
DoubleEqual,
DoublePipe,
Equal,
Greater,
GreaterOrEqual,
LeftCurlyBrace,
LeftParenthesis,
LeftSquareBrace,
Less,
LessOrEqual,
Minus,
MinusEqual,
Percent,
PercentEqual,
Plus,
PlusEqual,
RightCurlyBrace,
RightParenthesis,
RightSquareBrace,
Semicolon,
Star,
StarEqual,
Struct,
Slash,
SlashEqual,
}
impl Display for TokenOwned {
fn fmt(&self, f: &mut Formatter<'_>) -> fmt::Result {
match self {
TokenOwned::ArrowThin => Token::ArrowThin.fmt(f),
TokenOwned::Async => Token::Async.fmt(f),
TokenOwned::Bang => Token::Bang.fmt(f),
TokenOwned::BangEqual => Token::BangEqual.fmt(f),
TokenOwned::Bool => Token::Bool.fmt(f),
TokenOwned::Boolean(boolean) => Token::Boolean(boolean).fmt(f),
TokenOwned::Break => Token::Break.fmt(f),
TokenOwned::Byte(byte) => Token::Byte(byte).fmt(f),
TokenOwned::Character(character) => Token::Character(*character).fmt(f),
TokenOwned::Colon => Token::Colon.fmt(f),
TokenOwned::Comma => Token::Comma.fmt(f),
TokenOwned::Dot => Token::Dot.fmt(f),
TokenOwned::DoubleAmpersand => Token::DoubleAmpersand.fmt(f),
TokenOwned::DoubleDot => Token::DoubleDot.fmt(f),
TokenOwned::DoubleEqual => Token::DoubleEqual.fmt(f),
TokenOwned::DoublePipe => Token::DoublePipe.fmt(f),
TokenOwned::Else => Token::Else.fmt(f),
TokenOwned::Eof => Token::Eof.fmt(f),
TokenOwned::Equal => Token::Equal.fmt(f),
TokenOwned::Float(float) => Token::Float(float).fmt(f),
TokenOwned::FloatKeyword => Token::FloatKeyword.fmt(f),
TokenOwned::Fn => Token::Fn.fmt(f),
TokenOwned::Greater => Token::Greater.fmt(f),
TokenOwned::GreaterOrEqual => Token::GreaterEqual.fmt(f),
TokenOwned::Identifier(text) => Token::Identifier(text).fmt(f),
TokenOwned::If => Token::If.fmt(f),
TokenOwned::Int => Token::Int.fmt(f),
TokenOwned::Integer(integer) => Token::Integer(integer).fmt(f),
TokenOwned::LeftCurlyBrace => Token::LeftCurlyBrace.fmt(f),
TokenOwned::LeftParenthesis => Token::LeftParenthesis.fmt(f),
TokenOwned::LeftSquareBrace => Token::LeftSquareBrace.fmt(f),
TokenOwned::Let => Token::Let.fmt(f),
TokenOwned::Less => Token::Less.fmt(f),
TokenOwned::LessOrEqual => Token::LessEqual.fmt(f),
TokenOwned::Loop => Token::Loop.fmt(f),
TokenOwned::Map => Token::Map.fmt(f),
TokenOwned::Minus => Token::Minus.fmt(f),
TokenOwned::MinusEqual => Token::MinusEqual.fmt(f),
TokenOwned::Mut => Token::Mut.fmt(f),
TokenOwned::Percent => Token::Percent.fmt(f),
TokenOwned::PercentEqual => Token::PercentEqual.fmt(f),
TokenOwned::Plus => Token::Plus.fmt(f),
TokenOwned::PlusEqual => Token::PlusEqual.fmt(f),
TokenOwned::Return => Token::Return.fmt(f),
TokenOwned::RightCurlyBrace => Token::RightCurlyBrace.fmt(f),
TokenOwned::RightParenthesis => Token::RightParenthesis.fmt(f),
TokenOwned::RightSquareBrace => Token::RightSquareBrace.fmt(f),
TokenOwned::Semicolon => Token::Semicolon.fmt(f),
TokenOwned::Star => Token::Star.fmt(f),
TokenOwned::StarEqual => Token::StarEqual.fmt(f),
TokenOwned::Slash => Token::Slash.fmt(f),
TokenOwned::SlashEqual => Token::SlashEqual.fmt(f),
TokenOwned::Str => Token::Str.fmt(f),
TokenOwned::String(string) => Token::String(string).fmt(f),
TokenOwned::Struct => Token::Struct.fmt(f),
TokenOwned::While => Token::While.fmt(f),
}
}
}
impl Display for TokenKind {
fn fmt(&self, f: &mut Formatter<'_>) -> fmt::Result {
match self {
TokenKind::ArrowThin => Token::ArrowThin.fmt(f),
TokenKind::Async => Token::Async.fmt(f),
TokenKind::Bang => Token::Bang.fmt(f),
TokenKind::BangEqual => Token::BangEqual.fmt(f),
TokenKind::Bool => Token::Bool.fmt(f),
TokenKind::Boolean => write!(f, "boolean value"),
TokenKind::Break => Token::Break.fmt(f),
TokenKind::Byte => write!(f, "byte value"),
TokenKind::Character => write!(f, "character value"),
TokenKind::Colon => Token::Colon.fmt(f),
TokenKind::Comma => Token::Comma.fmt(f),
TokenKind::Dot => Token::Dot.fmt(f),
TokenKind::DoubleAmpersand => Token::DoubleAmpersand.fmt(f),
TokenKind::DoubleDot => Token::DoubleDot.fmt(f),
TokenKind::DoubleEqual => Token::DoubleEqual.fmt(f),
TokenKind::DoublePipe => Token::DoublePipe.fmt(f),
TokenKind::Else => Token::Else.fmt(f),
TokenKind::Eof => Token::Eof.fmt(f),
TokenKind::Equal => Token::Equal.fmt(f),
TokenKind::Float => write!(f, "float value"),
TokenKind::FloatKeyword => Token::FloatKeyword.fmt(f),
TokenKind::Fn => Token::Fn.fmt(f),
TokenKind::Greater => Token::Greater.fmt(f),
TokenKind::GreaterEqual => Token::GreaterEqual.fmt(f),
TokenKind::Identifier => write!(f, "identifier"),
TokenKind::If => Token::If.fmt(f),
TokenKind::Int => Token::Int.fmt(f),
TokenKind::Integer => write!(f, "integer value"),
TokenKind::LeftCurlyBrace => Token::LeftCurlyBrace.fmt(f),
TokenKind::LeftParenthesis => Token::LeftParenthesis.fmt(f),
TokenKind::LeftSquareBrace => Token::LeftSquareBrace.fmt(f),
TokenKind::Let => Token::Let.fmt(f),
TokenKind::Less => Token::Less.fmt(f),
TokenKind::LessEqual => Token::LessEqual.fmt(f),
TokenKind::Loop => Token::Loop.fmt(f),
TokenKind::Map => Token::Map.fmt(f),
TokenKind::Minus => Token::Minus.fmt(f),
TokenKind::MinusEqual => Token::MinusEqual.fmt(f),
TokenKind::Mut => Token::Mut.fmt(f),
TokenKind::Percent => Token::Percent.fmt(f),
TokenKind::PercentEqual => Token::PercentEqual.fmt(f),
TokenKind::Plus => Token::Plus.fmt(f),
TokenKind::PlusEqual => Token::PlusEqual.fmt(f),
TokenKind::Return => Token::Return.fmt(f),
TokenKind::RightCurlyBrace => Token::RightCurlyBrace.fmt(f),
TokenKind::RightParenthesis => Token::RightParenthesis.fmt(f),
TokenKind::RightSquareBrace => Token::RightSquareBrace.fmt(f),
TokenKind::Semicolon => Token::Semicolon.fmt(f),
TokenKind::Star => Token::Star.fmt(f),
TokenKind::StarEqual => Token::StarEqual.fmt(f),
TokenKind::Str => Token::Str.fmt(f),
TokenKind::Slash => Token::Slash.fmt(f),
TokenKind::SlashEqual => Token::SlashEqual.fmt(f),
TokenKind::String => write!(f, "string value"),
TokenKind::Struct => Token::Struct.fmt(f),
TokenKind::While => Token::While.fmt(f),
}
}
}

659
dust-lang/src/type.rs
View File

@ -1,659 +0,0 @@
//! Value types and conflict handling.
use std::{
cmp::Ordering,
collections::HashMap,
fmt::{self, Display, Formatter},
};
use serde::{Deserialize, Serialize};
/// Description of a kind of value.
#[derive(Clone, Debug, Eq, PartialEq, Serialize, Deserialize)]
pub enum Type {
Any,
Boolean,
Byte,
Character,
Enum(EnumType),
Float,
Function(FunctionType),
Generic {
identifier_index: u8,
concrete_type: Option<Box<Type>>,
},
Integer,
List {
item_type: Box<Type>,
length: usize,
},
ListEmpty,
ListOf {
item_type: Box<Type>,
},
Map {
pairs: HashMap<u8, Type>,
},
Number,
Range {
r#type: RangeableType,
},
String {
length: Option<usize>,
},
Struct(StructType),
Tuple {
fields: Option<Vec<Type>>,
},
}
impl Type {
/// Returns a concrete type, either the type itself or the concrete type of a generic type.
pub fn concrete_type(&self) -> &Type {
if let Type::Generic {
concrete_type: Some(concrete_type),
..
} = self
{
concrete_type.concrete_type()
} else {
self
}
}
/// Checks that the type is compatible with another type.
pub fn check(&self, other: &Type) -> Result<(), TypeConflict> {
match (self.concrete_type(), other.concrete_type()) {
(Type::Any, _)
| (_, Type::Any)
| (Type::Boolean, Type::Boolean)
| (Type::Byte, Type::Byte)
| (Type::Character, Type::Character)
| (Type::Float, Type::Float)
| (Type::Integer, Type::Integer)
| (Type::String { .. }, Type::String { .. }) => return Ok(()),
(
Type::Generic {
concrete_type: left,
..
},
Type::Generic {
concrete_type: right,
..
},
) => match (left, right) {
(Some(left), Some(right)) => {
if left.check(right).is_ok() {
return Ok(());
}
}
(None, None) => {
return Ok(());
}
_ => {}
},
(Type::Generic { concrete_type, .. }, other)
| (other, Type::Generic { concrete_type, .. }) => {
if let Some(concrete_type) = concrete_type {
if other == concrete_type.as_ref() {
return Ok(());
}
}
}
(Type::Struct(left_struct_type), Type::Struct(right_struct_type)) => {
if left_struct_type == right_struct_type {
return Ok(());
}
}
(
Type::List {
item_type: left_type,
length: left_length,
},
Type::List {
item_type: right_type,
length: right_length,
},
) => {
if left_length != right_length {
return Err(TypeConflict {
actual: other.clone(),
expected: self.clone(),
});
}
if left_type.check(right_type).is_err() {
return Err(TypeConflict {
actual: other.clone(),
expected: self.clone(),
});
}
return Ok(());
}
(
Type::ListOf {
item_type: left_type,
},
Type::ListOf {
item_type: right_type,
},
) => {
if left_type.check(right_type).is_err() {
return Err(TypeConflict {
actual: other.clone(),
expected: self.clone(),
});
}
}
(
Type::List {
item_type: list_item_type,
..
},
Type::ListOf {
item_type: list_of_item_type,
},
)
| (
Type::ListOf {
item_type: list_of_item_type,
},
Type::List {
item_type: list_item_type,
..
},
) => {
// TODO: This is a hack, remove it.
if let Type::Any = **list_of_item_type {
return Ok(());
}
if list_item_type.check(list_of_item_type).is_err() {
return Err(TypeConflict {
actual: other.clone(),
expected: self.clone(),
});
}
}
(
Type::Function(FunctionType {
type_parameters: left_type_parameters,
value_parameters: left_value_parameters,
return_type: left_return,
}),
Type::Function(FunctionType {
type_parameters: right_type_parameters,
value_parameters: right_value_parameters,
return_type: right_return,
}),
) => {
if left_return != right_return
|| left_type_parameters != right_type_parameters
|| left_value_parameters != right_value_parameters
{
return Err(TypeConflict {
actual: other.clone(),
expected: self.clone(),
});
}
return Ok(());
}
(Type::Range { r#type: left_type }, Type::Range { r#type: right_type }) => {
if left_type == right_type {
return Ok(());
}
}
(Type::Number, Type::Number | Type::Integer | Type::Float)
| (Type::Integer | Type::Float, Type::Number) => {
return Ok(());
}
_ => {}
}
Err(TypeConflict {
actual: other.clone(),
expected: self.clone(),
})
}
}
impl Display for Type {
fn fmt(&self, f: &mut Formatter) -> fmt::Result {
match self {
Type::Any => write!(f, "any"),
Type::Boolean => write!(f, "bool"),
Type::Byte => write!(f, "byte"),
Type::Character => write!(f, "char"),
Type::Enum(EnumType { name, .. }) => write!(f, "{name}"),
Type::Float => write!(f, "float"),
Type::Function(function_type) => write!(f, "{function_type}"),
Type::Generic { concrete_type, .. } => {
match concrete_type.clone().map(|r#box| *r#box) {
Some(Type::Generic {
identifier_index: identifier,
..
}) => write!(f, "{identifier}"),
Some(concrete_type) => write!(f, "implied to be {concrete_type}"),
None => write!(f, "unknown"),
}
}
Type::Integer => write!(f, "int"),
Type::List { item_type, length } => write!(f, "[{item_type}; {length}]"),
Type::ListEmpty => write!(f, "[]"),
Type::ListOf { item_type } => write!(f, "[{item_type}]"),
Type::Map { pairs } => {
write!(f, "map ")?;
write!(f, "{{")?;
for (index, (key, value)) in pairs.iter().enumerate() {
write!(f, "{key}: {value}")?;
if index != pairs.len() - 1 {
write!(f, ", ")?;
}
}
write!(f, "}}")
}
Type::Number => write!(f, "num"),
Type::Range { r#type } => write!(f, "{type} range"),
Type::String { .. } => write!(f, "str"),
Type::Struct(struct_type) => write!(f, "{struct_type}"),
Type::Tuple { fields } => {
if let Some(fields) = fields {
write!(f, "(")?;
for (index, r#type) in fields.iter().enumerate() {
write!(f, "{type}")?;
if index != fields.len() - 1 {
write!(f, ", ")?;
}
}
write!(f, ")")
} else {
write!(f, "tuple")
}
}
}
}
}
impl PartialOrd for Type {
fn partial_cmp(&self, other: &Self) -> Option<Ordering> {
Some(self.cmp(other))
}
}
impl Ord for Type {
fn cmp(&self, other: &Self) -> Ordering {
match (self, other) {
(Type::Any, Type::Any) => Ordering::Equal,
(Type::Any, _) => Ordering::Greater,
(Type::Boolean, Type::Boolean) => Ordering::Equal,
(Type::Boolean, _) => Ordering::Greater,
(Type::Byte, Type::Byte) => Ordering::Equal,
(Type::Byte, _) => Ordering::Greater,
(Type::Character, Type::Character) => Ordering::Equal,
(Type::Character, _) => Ordering::Greater,
(Type::Enum(left_enum), Type::Enum(right_enum)) => left_enum.cmp(right_enum),
(Type::Enum(_), _) => Ordering::Greater,
(Type::Float, Type::Float) => Ordering::Equal,
(Type::Float, _) => Ordering::Greater,
(Type::Function(left_function), Type::Function(right_function)) => {
left_function.cmp(right_function)
}
(Type::Function(_), _) => Ordering::Greater,
(Type::Generic { .. }, Type::Generic { .. }) => Ordering::Equal,
(Type::Generic { .. }, _) => Ordering::Greater,
(Type::Integer, Type::Integer) => Ordering::Equal,
(Type::Integer, _) => Ordering::Greater,
(
Type::List {
item_type: left_item_type,
length: left_length,
},
Type::List {
item_type: right_item_type,
length: right_length,
},
) => {
if left_length == right_length {
left_item_type.cmp(right_item_type)
} else {
left_length.cmp(right_length)
}
}
(Type::List { .. }, _) => Ordering::Greater,
(Type::ListEmpty, Type::ListEmpty) => Ordering::Equal,
(Type::ListEmpty, _) => Ordering::Greater,
(
Type::ListOf {
item_type: left_item_type,
},
Type::ListOf {
item_type: right_item_type,
},
) => left_item_type.cmp(right_item_type),
(Type::ListOf { .. }, _) => Ordering::Greater,
(Type::Map { pairs: left_pairs }, Type::Map { pairs: right_pairs }) => {
left_pairs.iter().cmp(right_pairs.iter())
}
(Type::Map { .. }, _) => Ordering::Greater,
(Type::Number, Type::Number) => Ordering::Equal,
(Type::Number, _) => Ordering::Greater,
(Type::Range { r#type: left_type }, Type::Range { r#type: right_type }) => {
left_type.cmp(right_type)
}
(Type::Range { .. }, _) => Ordering::Greater,
(Type::String { length: left }, Type::String { length: right }) => left.cmp(right),
(Type::String { .. }, _) => Ordering::Greater,
(Type::Struct(left_struct), Type::Struct(right_struct)) => {
left_struct.cmp(right_struct)
}
(Type::Struct(_), _) => Ordering::Greater,
(Type::Tuple { fields: left }, Type::Tuple { fields: right }) => left.cmp(right),
(Type::Tuple { .. }, _) => Ordering::Greater,
}
}
}
#[derive(Clone, Debug, Eq, PartialEq, PartialOrd, Ord, Serialize, Deserialize)]
pub struct FunctionType {
pub type_parameters: Option<Vec<u8>>,
pub value_parameters: Option<Vec<(u8, Type)>>,
pub return_type: Option<Box<Type>>,
}
impl Display for FunctionType {
fn fmt(&self, f: &mut Formatter<'_>) -> fmt::Result {
write!(f, "fn ")?;
if let Some(type_parameters) = &self.type_parameters {
write!(f, "<")?;
for (index, type_parameter) in type_parameters.iter().enumerate() {
if index > 0 {
write!(f, ", ")?;
}
write!(f, "{type_parameter}")?;
}
write!(f, ">")?;
}
write!(f, "(")?;
if let Some(value_parameters) = &self.value_parameters {
for (index, (identifier, r#type)) in value_parameters.iter().enumerate() {
if index > 0 {
write!(f, ", ")?;
}
write!(f, "{identifier}: {type}")?;
}
}
write!(f, ")")?;
if let Some(return_type) = &self.return_type {
write!(f, " -> {return_type}")?;
}
Ok(())
}
}
#[derive(Clone, Debug, Eq, PartialEq, Serialize, Deserialize)]
pub enum StructType {
Unit { name: u8 },
Tuple { name: u8, fields: Vec<Type> },
Fields { name: u8, fields: HashMap<u8, Type> },
}
impl StructType {
pub fn name(&self) -> u8 {
match self {
StructType::Unit { name } => *name,
StructType::Tuple { name, .. } => *name,
StructType::Fields { name, .. } => *name,
}
}
}
impl Display for StructType {
fn fmt(&self, f: &mut Formatter<'_>) -> fmt::Result {
match self {
StructType::Unit { name } => write!(f, "{name}"),
StructType::Tuple { name, fields } => {
write!(f, "{name}(")?;
for (index, field) in fields.iter().enumerate() {
write!(f, "{field}")?;
if index != fields.len() - 1 {
write!(f, ", ")?;
}
}
write!(f, ")")
}
StructType::Fields { name, fields } => {
write!(f, "{name} {{")?;
for (index, (identifier, r#type)) in fields.iter().enumerate() {
write!(f, "{identifier}: {type}")?;
if index != fields.len() - 1 {
write!(f, ", ")?;
}
}
write!(f, "}}")
}
}
}
}
impl PartialOrd for StructType {
fn partial_cmp(&self, other: &Self) -> Option<Ordering> {
Some(self.cmp(other))
}
}
impl Ord for StructType {
fn cmp(&self, other: &Self) -> Ordering {
match (self, other) {
(StructType::Unit { name: left_name }, StructType::Unit { name: right_name }) => {
left_name.cmp(right_name)
}
(StructType::Unit { .. }, _) => Ordering::Greater,
(
StructType::Tuple {
name: left_name,
fields: left_fields,
},
StructType::Tuple {
name: right_name,
fields: right_fields,
},
) => {
let name_cmp = left_name.cmp(right_name);
if name_cmp == Ordering::Equal {
left_fields.cmp(right_fields)
} else {
name_cmp
}
}
(StructType::Tuple { .. }, _) => Ordering::Greater,
(
StructType::Fields {
name: left_name,
fields: left_fields,
},
StructType::Fields {
name: right_name,
fields: right_fields,
},
) => {
let name_cmp = left_name.cmp(right_name);
if name_cmp == Ordering::Equal {
let len_cmp = left_fields.len().cmp(&right_fields.len());
if len_cmp == Ordering::Equal {
left_fields.iter().cmp(right_fields.iter())
} else {
len_cmp
}
} else {
name_cmp
}
}
(StructType::Fields { .. }, _) => Ordering::Greater,
}
}
}
#[derive(Clone, Debug, Eq, PartialEq, PartialOrd, Ord, Serialize, Deserialize)]
pub struct EnumType {
pub name: u8,
pub variants: Vec<StructType>,
}
impl Display for EnumType {
fn fmt(&self, f: &mut Formatter<'_>) -> fmt::Result {
let EnumType { name, variants } = self;
write!(f, "enum {name} {{ ")?;
for (index, variant) in variants.iter().enumerate() {
write!(f, "{variant}")?;
if index != self.variants.len() - 1 {
write!(f, ", ")?;
}
}
write!(f, " }}")
}
}
#[derive(Clone, Debug, Eq, PartialEq, PartialOrd, Ord, Serialize, Deserialize)]
pub enum RangeableType {
Byte,
Character,
Float,
Integer,
}
impl Display for RangeableType {
fn fmt(&self, f: &mut Formatter<'_>) -> fmt::Result {
match self {
RangeableType::Byte => Type::Byte.fmt(f),
RangeableType::Character => Type::Character.fmt(f),
RangeableType::Float => Type::Float.fmt(f),
RangeableType::Integer => Type::Integer.fmt(f),
}
}
}
#[derive(Clone, Debug, Eq, PartialEq, Serialize, Deserialize)]
pub struct TypeConflict {
pub expected: Type,
pub actual: Type,
}
#[cfg(test)]
mod tests {
use super::*;
#[test]
fn check_type_any() {
let foo = Type::Any;
let bar = Type::Any;
foo.check(&bar).unwrap();
}
#[test]
fn check_type_boolean() {
let foo = Type::Boolean;
let bar = Type::Boolean;
foo.check(&bar).unwrap();
}
#[test]
fn check_type_byte() {
let foo = Type::Byte;
let bar = Type::Byte;
foo.check(&bar).unwrap();
}
#[test]
fn check_type_character() {
let foo = Type::Character;
let bar = Type::Character;
foo.check(&bar).unwrap();
}
#[test]
fn errors() {
let foo = Type::Integer;
let bar = Type::String { length: None };
assert_eq!(
foo.check(&bar),
Err(TypeConflict {
actual: bar.clone(),
expected: foo.clone()
})
);
assert_eq!(
bar.check(&foo),
Err(TypeConflict {
actual: foo.clone(),
expected: bar.clone()
})
);
let types = [
Type::Boolean,
Type::Float,
Type::Integer,
Type::List {
item_type: Box::new(Type::Integer),
length: 42,
},
Type::Range {
r#type: RangeableType::Integer,
},
Type::String { length: None },
];
for left in types.clone() {
for right in types.clone() {
if left == right {
continue;
}
assert_eq!(
left.check(&right),
Err(TypeConflict {
actual: right.clone(),
expected: left.clone()
})
);
}
}
}
}

767
dust-lang/src/value.rs
View File

@ -1,767 +0,0 @@
//! Dust value representation
//!
//! # Examples
//!
//! Each type of value has a corresponding method for instantiation:
//!
//! ```
//! # use dust_lang::Value;
//! let boolean = Value::boolean(true);
//! let float = Value::float(3.14);
//! let integer = Value::integer(42);
//! let string = Value::string("Hello, world!");
//! ```
//!
//! Values have a type, which can be retrieved using the `r#type` method:
//!
//! ```
//! # use dust_lang::*;
//! let value = Value::integer(42);
//!
//! assert_eq!(value.r#type(), Type::Integer);
//! ```
use std::{
cmp::Ordering,
fmt::{self, Debug, Display, Formatter},
ops::{Range, RangeInclusive},
};
use serde::{Deserialize, Serialize};
use crate::{Chunk, FunctionType, RangeableType, Type};
/// Dust value representation
///
/// See the [module-level documentation][self] for more.
#[derive(Debug, Eq, PartialEq, PartialOrd, Ord, Serialize, Deserialize)]
pub enum Value {
Concrete(ConcreteValue),
Abstract(AbstractValue),
}
impl Value {
pub fn boolean(value: bool) -> Self {
Value::Concrete(ConcreteValue::Boolean(value))
}
pub fn byte(value: u8) -> Self {
Value::Concrete(ConcreteValue::Byte(value))
}
pub fn character(value: char) -> Self {
Value::Concrete(ConcreteValue::Character(value))
}
pub fn float(value: f64) -> Self {
Value::Concrete(ConcreteValue::Float(value))
}
pub fn function(body: Chunk, r#type: FunctionType) -> Self {
Value::Concrete(ConcreteValue::Function(Function {
chunk: body,
r#type: Type::Function(r#type),
}))
}
pub fn integer<T: Into<i64>>(into_i64: T) -> Self {
Value::Concrete(ConcreteValue::Integer(into_i64.into()))
}
pub fn list<T: Into<Vec<Value>>>(items: T) -> Self {
Value::Concrete(ConcreteValue::List(items.into()))
}
pub fn abstract_list(start: u8, end: u8, item_type: Type) -> Self {
Value::Abstract(AbstractValue::List {
start,
end,
item_type,
})
}
pub fn string<T: ToString>(to_string: T) -> Self {
Value::Concrete(ConcreteValue::String(to_string.to_string()))
}
pub fn as_string(&self) -> Option<&String> {
if let Value::Concrete(ConcreteValue::String(string)) = self {
Some(string)
} else {
None
}
}
pub fn is_function(&self) -> bool {
matches!(self, Value::Concrete(ConcreteValue::Function(_)))
}
pub fn r#type(&self) -> Type {
match self {
Value::Concrete(data) => data.r#type(),
Value::Abstract(AbstractValue::List {
start,
end,
item_type,
}) => {
let length = (end - start + 1) as usize;
Type::List {
length,
item_type: Box::new(item_type.clone()),
}
}
}
}
pub fn add(&self, other: &Value) -> Result<Value, ValueError> {
use ConcreteValue::*;
use Value::*;
let sum = match (self, other) {
(Concrete(Byte(left)), Concrete(Byte(right))) => {
Value::byte(left.saturating_add(*right))
}
(Concrete(Float(left)), Concrete(Float(right))) => Value::float(left + right),
(Concrete(Integer(left)), Concrete(Integer(right))) => {
Value::integer(left.saturating_add(*right))
}
(Concrete(String(left)), Concrete(String(right))) => {
Value::string(format!("{}{}", left, right))
}
_ => return Err(ValueError::CannotAdd(self.clone(), other.clone())),
};
Ok(sum)
}
pub fn subtract(&self, other: &Value) -> Result<Value, ValueError> {
use ConcreteValue::*;
use Value::*;
let different = match (self, other) {
(Concrete(Byte(left)), Concrete(Byte(right))) => {
Value::byte(left.saturating_sub(*right))
}
(Concrete(Float(left)), Concrete(Float(right))) => Value::float(left - right),
(Concrete(Integer(left)), Concrete(Integer(right))) => {
Value::integer(left.saturating_sub(*right))
}
_ => return Err(ValueError::CannotSubtract(self.clone(), other.clone())),
};
Ok(different)
}
pub fn multiply(&self, other: &Value) -> Result<Value, ValueError> {
use ConcreteValue::*;
use Value::*;
let product = match (self, other) {
(Concrete(Byte(left)), Concrete(Byte(right))) => {
Value::byte(left.saturating_mul(*right))
}
(Concrete(Float(left)), Concrete(Float(right))) => Value::float(left * right),
(Concrete(Integer(left)), Concrete(Integer(right))) => {
Value::integer(left.saturating_mul(*right))
}
_ => return Err(ValueError::CannotAdd(self.clone(), other.clone())),
};
Ok(product)
}
pub fn divide(&self, other: &Value) -> Result<Value, ValueError> {
use ConcreteValue::*;
use Value::*;
let product = match (self, other) {
(Concrete(Byte(left)), Concrete(Byte(right))) => {
Value::byte(left.saturating_div(*right))
}
(Concrete(Float(left)), Concrete(Float(right))) => Value::float(left / right),
(Concrete(Integer(left)), Concrete(Integer(right))) => {
Value::integer(left.saturating_div(*right))
}
_ => return Err(ValueError::CannotDivide(self.clone(), other.clone())),
};
Ok(product)
}
pub fn modulo(&self, other: &Value) -> Result<Value, ValueError> {
use ConcreteValue::*;
use Value::*;
let product = match (self, other) {
(Concrete(Byte(left)), Concrete(Byte(right))) => Value::byte(left % right),
(Concrete(Float(left)), Concrete(Float(right))) => Value::float(left % right),
(Concrete(Integer(left)), Concrete(Integer(right))) => Value::integer(left % right),
_ => return Err(ValueError::CannotModulo(self.clone(), other.clone())),
};
Ok(product)
}
pub fn less_than(&self, other: &Value) -> Result<Value, ValueError> {
let (left, right) = match (self, other) {
(Value::Concrete(left), Value::Concrete(right)) => (left, right),
_ => return Err(ValueError::CannotCompare(self.clone(), other.clone())),
};
Ok(Value::boolean(left < right))
}
pub fn less_than_or_equal(&self, other: &Value) -> Result<Value, ValueError> {
let (left, right) = match (self, other) {
(Value::Concrete(left), Value::Concrete(right)) => (left, right),
_ => return Err(ValueError::CannotCompare(self.clone(), other.clone())),
};
Ok(Value::boolean(left <= right))
}
pub fn equal(&self, other: &Value) -> Result<Value, ValueError> {
let (left, right) = match (self, other) {
(Value::Concrete(left), Value::Concrete(right)) => (left, right),
_ => return Err(ValueError::CannotCompare(self.clone(), other.clone())),
};
Ok(Value::boolean(left == right))
}
pub fn negate(&self) -> Result<Value, ValueError> {
use ConcreteValue::*;
use Value::*;
let negated = match self {
Concrete(Integer(integer)) => Value::integer(-integer),
Concrete(Float(float)) => Value::float(-float),
_ => return Err(ValueError::CannotNot(self.clone())),
};
Ok(negated)
}
pub fn not(&self) -> Result<Value, ValueError> {
use ConcreteValue::*;
use Value::*;
let not = match self {
Concrete(Boolean(boolean)) => Value::boolean(!boolean),
Concrete(Byte(byte)) => Value::byte(!byte),
Concrete(Integer(integer)) => Value::integer(!integer),
_ => return Err(ValueError::CannotNot(self.clone())),
};
Ok(not)
}
}
impl From<bool> for Value {
fn from(value: bool) -> Self {
Value::boolean(value)
}
}
impl From<u8> for Value {
fn from(value: u8) -> Self {
Value::byte(value)
}
}
impl From<char> for Value {
fn from(value: char) -> Self {
Value::character(value)
}
}
impl From<f64> for Value {
fn from(value: f64) -> Self {
Value::float(value)
}
}
impl From<i32> for Value {
fn from(value: i32) -> Self {
Value::integer(value as i64)
}
}
impl From<i64> for Value {
fn from(value: i64) -> Self {
Value::integer(value)
}
}
impl From<String> for Value {
fn from(value: String) -> Self {
Value::string(value)
}
}
impl From<&str> for Value {
fn from(str: &str) -> Self {
Value::string(str)
}
}
impl Clone for Value {
fn clone(&self) -> Self {
log::trace!("Cloning value {self}");
match self {
Value::Abstract(object) => Value::Abstract(object.clone()),
Value::Concrete(concrete) => Value::Concrete(concrete.clone()),
}
}
}
impl Display for Value {
fn fmt(&self, f: &mut Formatter) -> fmt::Result {
match self {
Value::Abstract(object) => write!(f, "{object}"),
Value::Concrete(concrete) => write!(f, "{concrete}"),
}
}
}
/// Value representation that can be resolved to a concrete value by the VM.
#[derive(Clone, Debug, PartialEq, Eq, PartialOrd, Ord, Serialize, Deserialize)]
pub enum AbstractValue {
List { start: u8, end: u8, item_type: Type },
}
impl Display for AbstractValue {
fn fmt(&self, f: &mut Formatter<'_>) -> fmt::Result {
match self {
AbstractValue::List { start, end, .. } => {
write!(f, "List [R{}..=R{}]", start, end)
}
}
}
}
#[derive(Clone, Debug, PartialEq, Deserialize, Serialize)]
pub enum ConcreteValue {
Boolean(bool),
Byte(u8),
Character(char),
Float(f64),
Function(Function),
Integer(i64),
List(Vec<Value>),
Range(RangeValue),
String(String),
}
impl ConcreteValue {
pub fn r#type(&self) -> Type {
match self {
ConcreteValue::Boolean(_) => Type::Boolean,
ConcreteValue::Byte(_) => Type::Byte,
ConcreteValue::Character(_) => Type::Character,
ConcreteValue::Float(_) => Type::Float,
ConcreteValue::Function(Function { r#type, .. }) => r#type.clone(),
ConcreteValue::Integer(_) => Type::Integer,
ConcreteValue::List(list) => Type::List {
item_type: list
.first()
.map(|value| Box::new(value.r#type()))
.unwrap_or_else(|| Box::new(Type::Any)),
length: list.len(),
},
ConcreteValue::Range(range) => range.r#type(),
ConcreteValue::String(string) => Type::String {
length: Some(string.len()),
},
}
}
pub fn is_rangeable(&self) -> bool {
matches!(
self,
ConcreteValue::Integer(_)
| ConcreteValue::Float(_)
| ConcreteValue::Character(_)
| ConcreteValue::Byte(_)
)
}
}
impl Display for ConcreteValue {
fn fmt(&self, f: &mut Formatter) -> fmt::Result {
match self {
ConcreteValue::Boolean(boolean) => write!(f, "{boolean}"),
ConcreteValue::Byte(byte) => write!(f, "0x{byte:02x}"),
ConcreteValue::Character(character) => write!(f, "{character}"),
ConcreteValue::Float(float) => {
write!(f, "{float}")?;
if float.fract() == 0.0 {
write!(f, ".0")?;
}
Ok(())
}
ConcreteValue::Function(Function { r#type, .. }) => {
write!(f, "{}", r#type)
}
ConcreteValue::Integer(integer) => write!(f, "{integer}"),
ConcreteValue::List(items) => {
write!(f, "[")?;
for (index, item) in items.iter().enumerate() {
if index > 0 {
write!(f, ", ")?;
}
write!(f, "{item}")?;
}
write!(f, "]")
}
ConcreteValue::Range(range_value) => {
write!(f, "{range_value}")
}
ConcreteValue::String(string) => write!(f, "{string}"),
}
}
}
impl Eq for ConcreteValue {}
impl PartialOrd for ConcreteValue {
fn partial_cmp(&self, other: &Self) -> Option<Ordering> {
Some(self.cmp(other))
}
}
impl Ord for ConcreteValue {
fn cmp(&self, other: &Self) -> Ordering {
match (self, other) {
(ConcreteValue::Boolean(left), ConcreteValue::Boolean(right)) => left.cmp(right),
(ConcreteValue::Boolean(_), _) => Ordering::Greater,
(ConcreteValue::Byte(left), ConcreteValue::Byte(right)) => left.cmp(right),
(ConcreteValue::Byte(_), _) => Ordering::Greater,
(ConcreteValue::Character(left), ConcreteValue::Character(right)) => left.cmp(right),
(ConcreteValue::Character(_), _) => Ordering::Greater,
(ConcreteValue::Float(left), ConcreteValue::Float(right)) => {
if left.is_nan() && right.is_nan() {
Ordering::Equal
} else if left.is_nan() {
Ordering::Less
} else if right.is_nan() {
Ordering::Greater
} else {
left.partial_cmp(right).unwrap()
}
}
(ConcreteValue::Float(_), _) => Ordering::Greater,
(ConcreteValue::Function(left), ConcreteValue::Function(right)) => left.cmp(right),
(ConcreteValue::Function(_), _) => Ordering::Greater,
(ConcreteValue::Integer(left), ConcreteValue::Integer(right)) => left.cmp(right),
(ConcreteValue::Integer(_), _) => Ordering::Greater,
(ConcreteValue::List(left), ConcreteValue::List(right)) => left.cmp(right),
(ConcreteValue::List(_), _) => Ordering::Greater,
(ConcreteValue::Range(left), ConcreteValue::Range(right)) => left.cmp(right),
(ConcreteValue::Range(_), _) => Ordering::Greater,
(ConcreteValue::String(left), ConcreteValue::String(right)) => left.cmp(right),
(ConcreteValue::String(_), _) => Ordering::Greater,
}
}
}
#[derive(Clone, Debug, Eq, PartialEq, PartialOrd, Ord, Serialize, Deserialize)]
pub struct Function {
chunk: Chunk,
r#type: Type,
}
impl Function {
pub fn new(chunk: Chunk, r#type: Type) -> Self {
Self { chunk, r#type }
}
pub fn chunk(&self) -> &Chunk {
&self.chunk
}
pub fn chunk_mut(&mut self) -> &mut Chunk {
&mut self.chunk
}
pub fn take_chunk(self) -> Chunk {
self.chunk
}
pub fn r#type(&self) -> &Type {
&self.r#type
}
}
impl Display for Function {
fn fmt(&self, f: &mut Formatter) -> fmt::Result {
write!(f, "{}", self.r#type)
}
}
#[derive(Clone, Debug, PartialEq, Serialize, Deserialize)]
pub enum RangeValue {
ByteRange(Range<u8>),
ByteRangeInclusive(RangeInclusive<u8>),
CharacterRange(Range<char>),
CharacterRangeInclusive(RangeInclusive<char>),
FloatRange(Range<f64>),
FloatRangeInclusive(RangeInclusive<f64>),
IntegerRange(Range<i64>),
IntegerRangeInclusive(RangeInclusive<i64>),
}
impl RangeValue {
pub fn r#type(&self) -> Type {
let inner_type = match self {
RangeValue::ByteRange(_) => RangeableType::Byte,
RangeValue::ByteRangeInclusive(_) => RangeableType::Byte,
RangeValue::CharacterRange(_) => RangeableType::Character,
RangeValue::CharacterRangeInclusive(_) => RangeableType::Character,
RangeValue::FloatRange(_) => RangeableType::Float,
RangeValue::FloatRangeInclusive(_) => RangeableType::Float,
RangeValue::IntegerRange(_) => RangeableType::Integer,
RangeValue::IntegerRangeInclusive(_) => RangeableType::Integer,
};
Type::Range { r#type: inner_type }
}
}
impl From<Range<u8>> for RangeValue {
fn from(range: Range<u8>) -> Self {
RangeValue::ByteRange(range)
}
}
impl From<RangeInclusive<u8>> for RangeValue {
fn from(range: RangeInclusive<u8>) -> Self {
RangeValue::ByteRangeInclusive(range)
}
}
impl From<Range<char>> for RangeValue {
fn from(range: Range<char>) -> Self {
RangeValue::CharacterRange(range)
}
}
impl From<RangeInclusive<char>> for RangeValue {
fn from(range: RangeInclusive<char>) -> Self {
RangeValue::CharacterRangeInclusive(range)
}
}
impl From<Range<f64>> for RangeValue {
fn from(range: Range<f64>) -> Self {
RangeValue::FloatRange(range)
}
}
impl From<RangeInclusive<f64>> for RangeValue {
fn from(range: RangeInclusive<f64>) -> Self {
RangeValue::FloatRangeInclusive(range)
}
}
impl From<Range<i32>> for RangeValue {
fn from(range: Range<i32>) -> Self {
RangeValue::IntegerRange(range.start as i64..range.end as i64)
}
}
impl From<RangeInclusive<i32>> for RangeValue {
fn from(range: RangeInclusive<i32>) -> Self {
RangeValue::IntegerRangeInclusive(*range.start() as i64..=*range.end() as i64)
}
}
impl From<Range<i64>> for RangeValue {
fn from(range: Range<i64>) -> Self {
RangeValue::IntegerRange(range)
}
}
impl From<RangeInclusive<i64>> for RangeValue {
fn from(range: RangeInclusive<i64>) -> Self {
RangeValue::IntegerRangeInclusive(range)
}
}
impl Display for RangeValue {
fn fmt(&self, f: &mut Formatter) -> fmt::Result {
match self {
RangeValue::ByteRange(range) => write!(f, "{}..{}", range.start, range.end),
RangeValue::ByteRangeInclusive(range) => {
write!(f, "{}..={}", range.start(), range.end())
}
RangeValue::CharacterRange(range) => write!(f, "{}..{}", range.start, range.end),
RangeValue::CharacterRangeInclusive(range) => {
write!(f, "{}..={}", range.start(), range.end())
}
RangeValue::FloatRange(range) => write!(f, "{}..{}", range.start, range.end),
RangeValue::FloatRangeInclusive(range) => {
write!(f, "{}..={}", range.start(), range.end())
}
RangeValue::IntegerRange(range) => write!(f, "{}..{}", range.start, range.end),
RangeValue::IntegerRangeInclusive(range) => {
write!(f, "{}..={}", range.start(), range.end())
}
}
}
}
impl Eq for RangeValue {}
impl PartialOrd for RangeValue {
fn partial_cmp(&self, other: &Self) -> Option<Ordering> {
Some(self.cmp(other))
}
}
impl Ord for RangeValue {
fn cmp(&self, other: &Self) -> Ordering {
match (self, other) {
(RangeValue::ByteRange(left), RangeValue::ByteRange(right)) => {
let start_cmp = left.start.cmp(&right.start);
if start_cmp != Ordering::Equal {
start_cmp
} else {
left.end.cmp(&right.end)
}
}
(RangeValue::ByteRange(_), _) => Ordering::Greater,
(RangeValue::ByteRangeInclusive(left), RangeValue::ByteRangeInclusive(right)) => {
let start_cmp = left.start().cmp(right.start());
if start_cmp != Ordering::Equal {
start_cmp
} else {
left.end().cmp(right.end())
}
}
(RangeValue::ByteRangeInclusive(_), _) => Ordering::Greater,
(RangeValue::CharacterRange(left), RangeValue::CharacterRange(right)) => {
let start_cmp = left.start.cmp(&right.start);
if start_cmp != Ordering::Equal {
start_cmp
} else {
left.end.cmp(&right.end)
}
}
(RangeValue::CharacterRange(_), _) => Ordering::Greater,
(
RangeValue::CharacterRangeInclusive(left),
RangeValue::CharacterRangeInclusive(right),
) => {
let start_cmp = left.start().cmp(right.start());
if start_cmp != Ordering::Equal {
start_cmp
} else {
left.end().cmp(right.end())
}
}
(RangeValue::CharacterRangeInclusive(_), _) => Ordering::Greater,
(RangeValue::FloatRange(left), RangeValue::FloatRange(right)) => {
let start_cmp = left.start.to_bits().cmp(&right.start.to_bits());
if start_cmp != Ordering::Equal {
start_cmp
} else {
left.end.to_bits().cmp(&right.end.to_bits())
}
}
(RangeValue::FloatRange(_), _) => Ordering::Greater,
(RangeValue::FloatRangeInclusive(left), RangeValue::FloatRangeInclusive(right)) => {
let start_cmp = left.start().to_bits().cmp(&right.start().to_bits());
if start_cmp != Ordering::Equal {
start_cmp
} else {
left.end().to_bits().cmp(&right.end().to_bits())
}
}
(RangeValue::FloatRangeInclusive(_), _) => Ordering::Greater,
(RangeValue::IntegerRange(left), RangeValue::IntegerRange(right)) => {
let start_cmp = left.start.cmp(&right.start);
if start_cmp != Ordering::Equal {
start_cmp
} else {
left.end.cmp(&right.end)
}
}
(RangeValue::IntegerRange(_), _) => Ordering::Greater,
(RangeValue::IntegerRangeInclusive(left), RangeValue::IntegerRangeInclusive(right)) => {
let start_cmp = left.start().cmp(right.start());
if start_cmp != Ordering::Equal {
start_cmp
} else {
left.end().cmp(right.end())
}
}
(RangeValue::IntegerRangeInclusive(_), _) => Ordering::Greater,
}
}
}
#[derive(Clone, Debug, PartialEq)]
pub enum ValueError {
CannotAdd(Value, Value),
CannotAnd(Value, Value),
CannotCompare(Value, Value),
CannotDivide(Value, Value),
CannotModulo(Value, Value),
CannotMultiply(Value, Value),
CannotNegate(Value),
CannotNot(Value),
CannotSubtract(Value, Value),
CannotOr(Value, Value),
}
impl Display for ValueError {
fn fmt(&self, f: &mut Formatter<'_>) -> fmt::Result {
match self {
ValueError::CannotAdd(left, right) => {
write!(f, "Cannot add {left} and {right}")
}
ValueError::CannotAnd(left, right) => {
write!(f, "Cannot use logical AND operation on {left} and {right}")
}
ValueError::CannotCompare(left, right) => {
write!(f, "Cannot compare {left} and {right}")
}
ValueError::CannotDivide(left, right) => {
write!(f, "Cannot divide {left} by {right}")
}
ValueError::CannotModulo(left, right) => {
write!(f, "Cannot use modulo operation on {left} and {right}")
}
ValueError::CannotMultiply(left, right) => {
write!(f, "Cannot multiply {left} by {right}")
}
ValueError::CannotNegate(value) => {
write!(f, "Cannot negate {value}")
}
ValueError::CannotNot(value) => {
write!(f, "Cannot use logical NOT operation on {value}")
}
ValueError::CannotSubtract(left, right) => {
write!(f, "Cannot subtract {right} from {left}")
}
ValueError::CannotOr(left, right) => {
write!(f, "Cannot use logical OR operation on {left} and {right}")
}
}
}
}

765
dust-lang/src/vm.rs
View File

@ -1,765 +0,0 @@
//! Virtual machine and errors
use std::{
cmp::Ordering,
fmt::{self, Display, Formatter},
ops::Range,
};
use crate::{
compile, value::ConcreteValue, AnnotatedError, Chunk, ChunkError, DustError, FunctionType,
Instruction, Local, NativeFunction, NativeFunctionError, Operation, Span, Type, Value,
ValueError,
};
pub fn run(source: &str) -> Result<Option<Value>, DustError> {
let mut chunk = compile(source)?;
let mut vm = Vm::new(&mut chunk, None);
vm.run()
.map(|option| option.cloned())
.map_err(|error| DustError::Runtime { error, source })
}
pub fn run_and_display_output(source: &str) {
match run(source) {
Ok(Some(value)) => println!("{}", value),
Ok(None) => {}
Err(error) => eprintln!("{}", error.report()),
}
}
/// Dust virtual machine.
///
/// See the [module-level documentation](index.html) for more information.
#[derive(Debug, Eq, PartialEq)]
pub struct Vm<'chunk, 'parent> {
ip: usize,
chunk: &'chunk mut Chunk,
stack: Vec<Register>,
last_assigned_register: Option<u8>,
parent: Option<&'parent Vm<'chunk, 'parent>>,
}
impl<'chunk, 'parent> Vm<'chunk, 'parent> {
const STACK_LIMIT: usize = u16::MAX as usize;
pub fn new(chunk: &'chunk mut Chunk, parent: Option<&'parent Vm<'chunk, 'parent>>) -> Self {
Self {
ip: 0,
chunk,
stack: Vec::new(),
last_assigned_register: None,
parent,
}
}
pub fn run(&mut self) -> Result<Option<&Value>, VmError> {
// DRY helper to get constant or register values for binary operations
fn get_arguments<'a>(
vm: &'a mut Vm,
instruction: Instruction,
position: Span,
) -> Result<(&'a Value, &'a Value), VmError> {
let left = if instruction.b_is_constant() {
vm.get_constant(instruction.b(), position)?
} else {
vm.open_register(instruction.b(), position)?
};
let right = if instruction.c_is_constant() {
vm.get_constant(instruction.c(), position)?
} else {
vm.open_register(instruction.c(), position)?
};
Ok((left, right))
}
while let Ok((instruction, position)) = self.read(Span(0, 0)).copied() {
log::info!(
"{} | {} | {} | {}",
self.ip - 1,
position,
instruction.operation(),
instruction.disassembly_info(self.chunk)
);
match instruction.operation() {
Operation::Move => {
let to_register = instruction.a();
let from_register = instruction.b();
let from_register_has_value = self
.stack
.get(from_register as usize)
.is_some_and(|register| !matches!(register, Register::Empty));
if from_register_has_value {
self.set_register(
to_register,
Register::StackPointer(from_register),
position,
)?;
}
}
Operation::Close => {
let from_register = instruction.b();
let to_register = instruction.c();
if self.stack.len() < to_register as usize {
return Err(VmError::StackUnderflow { position });
}
for register_index in from_register..to_register {
self.stack[register_index as usize] = Register::Empty;
}
}
Operation::LoadBoolean => {
let to_register = instruction.a();
let boolean = instruction.b_as_boolean();
let jump = instruction.c_as_boolean();
let value = Value::boolean(boolean);
self.set_register(to_register, Register::Value(value), position)?;
if jump {
self.ip += 1;
}
}
Operation::LoadConstant => {
let to_register = instruction.a();
let from_constant = instruction.b();
let jump = instruction.c_as_boolean();
self.set_register(
to_register,
Register::ConstantPointer(from_constant),
position,
)?;
if jump {
self.ip += 1
}
}
Operation::LoadList => {
let to_register = instruction.a();
let start_register = instruction.b();
let item_type = (start_register..to_register)
.find_map(|register_index| {
if let Ok(value) = self.open_register(register_index, position) {
Some(value.r#type())
} else {
None
}
})
.unwrap_or(Type::Any);
let value = Value::abstract_list(start_register, to_register, item_type);
self.set_register(to_register, Register::Value(value), position)?;
}
Operation::LoadSelf => {
let to_register = instruction.a();
let value = Value::function(
self.chunk.clone(),
FunctionType {
type_parameters: None,
value_parameters: None,
return_type: None,
},
);
self.set_register(to_register, Register::Value(value), position)?;
}
Operation::DefineLocal => {
let from_register = instruction.a();
let to_local = instruction.b();
self.define_local(to_local, from_register, position)?;
}
Operation::GetLocal => {
let to_register = instruction.a();
let local_index = instruction.b();
let local = self.get_local(local_index, position)?;
self.set_register(
to_register,
Register::StackPointer(local.register_index),
position,
)?;
}
Operation::SetLocal => {
let register = instruction.a();
let local_index = instruction.b();
self.define_local(local_index, register, position)?;
}
Operation::Add => {
let to_register = instruction.a();
let (left, right) = get_arguments(self, instruction, position)?;
let sum = left
.add(right)
.map_err(|error| VmError::Value { error, position })?;
self.set_register(to_register, Register::Value(sum), position)?;
}
Operation::Subtract => {
let to_register = instruction.a();
let (left, right) = get_arguments(self, instruction, position)?;
let difference = left
.subtract(right)
.map_err(|error| VmError::Value { error, position })?;
self.set_register(to_register, Register::Value(difference), position)?;
}
Operation::Multiply => {
let to_register = instruction.a();
let (left, right) = get_arguments(self, instruction, position)?;
let product = left
.multiply(right)
.map_err(|error| VmError::Value { error, position })?;
self.set_register(to_register, Register::Value(product), position)?;
}
Operation::Divide => {
let to_register = instruction.a();
let (left, right) = get_arguments(self, instruction, position)?;
let quotient = left
.divide(right)
.map_err(|error| VmError::Value { error, position })?;
self.set_register(to_register, Register::Value(quotient), position)?;
}
Operation::Modulo => {
let to_register = instruction.a();
let (left, right) = get_arguments(self, instruction, position)?;
let remainder = left
.modulo(right)
.map_err(|error| VmError::Value { error, position })?;
self.set_register(to_register, Register::Value(remainder), position)?;
}
Operation::Test => {
let register = instruction.a();
let test_value = instruction.c_as_boolean();
let value = self.open_register(register, position)?;
let boolean = if let Value::Concrete(ConcreteValue::Boolean(boolean)) = value {
*boolean
} else {
return Err(VmError::ExpectedBoolean {
found: value.clone(),
position,
});
};
if boolean != test_value {
self.ip += 1;
}
}
Operation::TestSet => todo!(),
Operation::Equal => {
debug_assert_eq!(
self.get_instruction(self.ip, position)?.0.operation(),
Operation::Jump
);
let (left, right) = get_arguments(self, instruction, position)?;
let equal_result = left
.equal(right)
.map_err(|error| VmError::Value { error, position })?;
let boolean =
if let Value::Concrete(ConcreteValue::Boolean(boolean)) = equal_result {
boolean
} else {
return Err(VmError::ExpectedBoolean {
found: equal_result.clone(),
position,
});
};
let compare_to = instruction.a_as_boolean();
if boolean == compare_to {
self.ip += 1;
} else {
let (jump, _) = self.get_instruction(self.ip, position)?;
let jump_distance = jump.a();
let is_positive = jump.b_as_boolean();
let new_ip = if is_positive {
self.ip + jump_distance as usize
} else {
self.ip - jump_distance as usize
};
self.ip = new_ip;
}
}
Operation::Less => {
debug_assert_eq!(
self.get_instruction(self.ip, position)?.0.operation(),
Operation::Jump
);
let (left, right) = get_arguments(self, instruction, position)?;
let less_result = left
.less_than(right)
.map_err(|error| VmError::Value { error, position })?;
let boolean =
if let Value::Concrete(ConcreteValue::Boolean(boolean)) = less_result {
boolean
} else {
return Err(VmError::ExpectedBoolean {
found: less_result.clone(),
position,
});
};
let compare_to = instruction.a_as_boolean();
if boolean == compare_to {
self.ip += 1;
} else {
let jump = self.get_instruction(self.ip, position)?.0;
let jump_distance = jump.a();
let is_positive = jump.b_as_boolean();
let new_ip = if is_positive {
self.ip + jump_distance as usize
} else {
self.ip - jump_distance as usize
};
self.ip = new_ip;
}
}
Operation::LessEqual => {
debug_assert_eq!(
self.get_instruction(self.ip, position)?.0.operation(),
Operation::Jump
);
let (left, right) = get_arguments(self, instruction, position)?;
let less_or_equal_result = left
.less_than_or_equal(right)
.map_err(|error| VmError::Value { error, position })?;
let boolean = if let Value::Concrete(ConcreteValue::Boolean(boolean)) =
less_or_equal_result
{
boolean
} else {
return Err(VmError::ExpectedBoolean {
found: less_or_equal_result.clone(),
position,
});
};
let compare_to = instruction.a_as_boolean();
if boolean == compare_to {
self.ip += 1;
} else {
let jump = self.get_instruction(self.ip, position)?.0;
let jump_distance = jump.a();
let is_positive = jump.b_as_boolean();
let new_ip = if is_positive {
self.ip + jump_distance as usize
} else {
self.ip - jump_distance as usize
};
self.ip = new_ip;
}
}
Operation::Negate => {
let value = if instruction.b_is_constant() {
self.get_constant(instruction.b(), position)?
} else {
self.open_register(instruction.b(), position)?
};
let negated = value
.negate()
.map_err(|error| VmError::Value { error, position })?;
self.set_register(instruction.a(), Register::Value(negated), position)?;
}
Operation::Not => {
let value = if instruction.b_is_constant() {
self.get_constant(instruction.b(), position)?
} else {
self.open_register(instruction.b(), position)?
};
let not = value
.not()
.map_err(|error| VmError::Value { error, position })?;
self.set_register(instruction.a(), Register::Value(not), position)?;
}
Operation::Jump => {
let jump_distance = instruction.b();
let is_positive = instruction.c_as_boolean();
let new_ip = if is_positive {
self.ip + jump_distance as usize
} else {
self.ip - jump_distance as usize - 1
};
self.ip = new_ip;
}
Operation::Call => {
let to_register = instruction.a();
let function_register = instruction.b();
let argument_count = instruction.c();
let value = self.open_register(function_register, position)?.clone();
let mut function =
if let Value::Concrete(ConcreteValue::Function(function)) = value {
function
} else {
return Err(VmError::ExpectedFunction {
found: value,
position,
});
};
let mut function_vm = Vm::new(function.chunk_mut(), Some(self));
let first_argument_index = function_register + 1;
for argument_index in
first_argument_index..first_argument_index + argument_count
{
let top_of_stack = function_vm.stack.len() as u8;
function_vm.set_register(
top_of_stack,
Register::ParentStackPointer(argument_index),
position,
)?
}
let return_value = function_vm.run()?.cloned();
if let Some(value) = return_value {
self.set_register(to_register, Register::Value(value), position)?;
}
}
Operation::CallNative => {
let native_function = NativeFunction::from(instruction.b());
let return_value = native_function.call(instruction, self, position)?;
if let Some(value) = return_value {
let to_register = instruction.a();
self.set_register(to_register, Register::Value(value), position)?;
}
}
Operation::Return => {
let should_return_value = instruction.b_as_boolean();
if !should_return_value {
return Ok(None);
}
let return_value = if let Some(register_index) = self.last_assigned_register {
self.open_register(register_index, position)?
} else {
return Err(VmError::StackUnderflow { position });
};
return Ok(Some(return_value));
}
}
}
Ok(None)
}
fn set_register(
&mut self,
to_register: u8,
register: Register,
position: Span,
) -> Result<(), VmError> {
self.last_assigned_register = Some(to_register);
let length = self.stack.len();
let to_register = to_register as usize;
if length == Self::STACK_LIMIT {
return Err(VmError::StackOverflow { position });
}
match to_register.cmp(&length) {
Ordering::Less => {
log::trace!("Change R{to_register} to {register}");
self.stack[to_register] = register;
Ok(())
}
Ordering::Equal => {
log::trace!("Set R{to_register} to {register}");
self.stack.push(register);
Ok(())
}
Ordering::Greater => {
let difference = to_register - length;
for index in 0..difference {
log::trace!("Set R{index} to {register}");
self.stack.push(Register::Empty);
}
log::trace!("Set R{to_register} to {register}");
self.stack.push(register);
Ok(())
}
}
}
fn get_constant(&self, index: u8, position: Span) -> Result<&Value, VmError> {
self.chunk
.get_constant(index)
.map_err(|error| VmError::Chunk { error, position })
}
pub fn open_register(&self, register_index: u8, position: Span) -> Result<&Value, VmError> {
let register_index = register_index as usize;
let register =
self.stack
.get(register_index)
.ok_or_else(|| VmError::RegisterIndexOutOfBounds {
index: register_index,
position,
})?;
match register {
Register::Value(value) => Ok(value),
Register::StackPointer(register_index) => self.open_register(*register_index, position),
Register::ConstantPointer(constant_index) => {
self.get_constant(*constant_index, position)
}
Register::ParentStackPointer(register_index) => {
let parent = self
.parent
.as_ref()
.ok_or(VmError::ExpectedParent { position })?;
parent.open_register(*register_index, position)
}
Register::ParentConstantPointer(constant_index) => {
let parent = self
.parent
.as_ref()
.ok_or(VmError::ExpectedParent { position })?;
parent.get_constant(*constant_index, position)
}
Register::Empty => Err(VmError::EmptyRegister {
index: register_index,
position,
}),
}
}
pub fn open_nonempty_registers(
&self,
register_index_range: Range<u8>,
position: Span,
) -> Result<Vec<&Value>, VmError> {
let mut values = Vec::with_capacity(register_index_range.len());
for register_index in register_index_range.clone() {
let register_index = register_index as usize;
let register = self.stack.get(register_index).ok_or_else(|| {
VmError::RegisterIndexOutOfBounds {
index: register_index,
position,
}
})?;
let value = match register {
Register::Value(value) => value,
Register::StackPointer(register_index) => {
self.open_register(*register_index, position)?
}
Register::ConstantPointer(constant_index) => {
self.get_constant(*constant_index, position)?
}
Register::ParentStackPointer(register_index) => {
let parent = self
.parent
.as_ref()
.ok_or(VmError::ExpectedParent { position })?;
parent.open_register(*register_index, position)?
}
Register::ParentConstantPointer(constant_index) => {
let parent = self
.parent
.as_ref()
.ok_or(VmError::ExpectedParent { position })?;
parent.get_constant(*constant_index, position)?
}
Register::Empty => continue,
};
values.push(value);
}
if values.is_empty() {
Err(VmError::EmptyRegisters {
indexes: register_index_range,
position,
})
} else {
Ok(values)
}
}
fn read(&mut self, position: Span) -> Result<&(Instruction, Span), VmError> {
self.chunk
.expect_not_poisoned()
.map_err(|error| VmError::Chunk { error, position })?;
let max_ip = self.chunk.len() - 1;
if self.ip > max_ip {
return self.get_instruction(max_ip, position);
} else {
self.ip += 1;
}
self.get_instruction(self.ip - 1, position)
}
fn define_local(
&mut self,
local_index: u8,
register_index: u8,
position: Span,
) -> Result<(), VmError> {
let local = self
.chunk
.get_local_mut(local_index)
.map_err(|error| VmError::Chunk { error, position })?;
log::debug!("Define local L{}", local_index);
local.register_index = register_index;
Ok(())
}
fn get_local(&self, local_index: u8, position: Span) -> Result<&Local, VmError> {
self.chunk
.get_local(local_index)
.map_err(|error| VmError::Chunk { error, position })
}
fn get_instruction(
&self,
index: usize,
position: Span,
) -> Result<&(Instruction, Span), VmError> {
self.chunk
.get_instruction(index)
.map_err(|error| VmError::Chunk { error, position })
}
}
#[derive(Debug, Eq, PartialEq)]
enum Register {
Empty,
Value(Value),
StackPointer(u8),
ConstantPointer(u8),
ParentStackPointer(u8),
ParentConstantPointer(u8),
}
impl Display for Register {
fn fmt(&self, f: &mut Formatter) -> fmt::Result {
match self {
Self::Empty => write!(f, "empty"),
Self::Value(value) => write!(f, "{}", value),
Self::StackPointer(index) => write!(f, "R{}", index),
Self::ConstantPointer(index) => write!(f, "C{}", index),
Self::ParentStackPointer(index) => write!(f, "PR{}", index),
Self::ParentConstantPointer(index) => write!(f, "PC{}", index),
}
}
}
#[derive(Clone, Debug, PartialEq)]
pub enum VmError {
// Stack errors
StackOverflow { position: Span },
StackUnderflow { position: Span },
// Register errors
EmptyRegister { index: usize, position: Span },
EmptyRegisters { indexes: Range<u8>, position: Span },
RegisterIndexOutOfBounds { index: usize, position: Span },
// Execution errors
ExpectedBoolean { found: Value, position: Span },
ExpectedFunction { found: Value, position: Span },
ExpectedParent { position: Span },
// Wrappers for foreign errors
Chunk { error: ChunkError, position: Span },
NativeFunction(NativeFunctionError),
Value { error: ValueError, position: Span },
}
impl AnnotatedError for VmError {
fn title() -> &'static str {
"Runtime Error"
}
fn description(&self) -> &'static str {
match self {
Self::Chunk { .. } => "Chunk error",
Self::EmptyRegister { .. } => "Empty register",
Self::EmptyRegisters { .. } => "Empty registers",
Self::ExpectedBoolean { .. } => "Expected boolean",
Self::ExpectedFunction { .. } => "Expected function",
Self::ExpectedParent { .. } => "Expected parent",
Self::NativeFunction(error) => error.description(),
Self::RegisterIndexOutOfBounds { .. } => "Register index out of bounds",
Self::StackOverflow { .. } => "Stack overflow",
Self::StackUnderflow { .. } => "Stack underflow",
Self::Value { .. } => "Value error",
}
}
fn details(&self) -> Option<String> {
match self {
Self::Chunk { error, .. } => Some(error.to_string()),
Self::EmptyRegister { index, .. } => Some(format!("Register R{index} is empty")),
Self::EmptyRegisters { indexes: range, .. } => Some(format!(
"Registers R{} to R{} are empty",
range.start, range.end
)),
Self::ExpectedFunction { found, .. } => Some(format!("{found} is not a function")),
Self::RegisterIndexOutOfBounds { index, .. } => {
Some(format!("Register {index} does not exist"))
}
Self::NativeFunction(error) => error.details(),
Self::Value { error, .. } => Some(error.to_string()),
_ => None,
}
}
fn position(&self) -> Span {
match self {
Self::Chunk { position, .. } => *position,
Self::EmptyRegister { position, .. } => *position,
Self::EmptyRegisters { position, .. } => *position,
Self::ExpectedBoolean { position, .. } => *position,
Self::ExpectedFunction { position, .. } => *position,
Self::ExpectedParent { position } => *position,
Self::NativeFunction(error) => error.position(),
Self::RegisterIndexOutOfBounds { position, .. } => *position,
Self::StackOverflow { position } => *position,
Self::StackUnderflow { position } => *position,
Self::Value { position, .. } => *position,
}
}
}

66
dust-lang/tests/basic.rs
View File

@ -1,66 +0,0 @@
use dust_lang::*;
#[test]
fn constant() {
let source = "42";
assert_eq!(
compile(source),
Ok(Chunk::with_data(
None,
vec![
(Instruction::load_constant(0, 0, false), Span(0, 2)),
(Instruction::r#return(true), Span(2, 2))
],
vec![Value::integer(42)],
vec![]
))
);
assert_eq!(run(source), Ok(Some(Value::integer(42))));
}
#[test]
fn empty() {
let source = "";
assert_eq!(
compile(source),
Ok(Chunk::with_data(
None,
vec![(Instruction::r#return(false), Span(0, 0))],
vec![],
vec![]
))
);
assert_eq!(run(source), Ok(None));
}
#[test]
fn parentheses_precedence() {
let source = "(1 + 2) * 3";
assert_eq!(
compile(source),
Ok(Chunk::with_data(
None,
vec![
(
*Instruction::add(0, 0, 1)
.set_b_is_constant()
.set_c_is_constant(),
Span(3, 4)
),
(
*Instruction::multiply(1, 0, 2).set_c_is_constant(),
Span(8, 9)
),
(Instruction::r#return(true), Span(11, 11)),
],
vec![Value::integer(1), Value::integer(2), Value::integer(3)],
vec![]
))
);
assert_eq!(run(source), Ok(Some(Value::integer(9))));
}

169
dust-lang/tests/comparison.rs
View File

@ -1,169 +0,0 @@
use dust_lang::*;
#[test]
fn equal() {
let source = "1 == 2";
assert_eq!(
compile(source),
Ok(Chunk::with_data(
None,
vec![
(
*Instruction::equal(true, 0, 1)
.set_b_is_constant()
.set_c_is_constant(),
Span(2, 4)
),
(Instruction::jump(1, true), Span(2, 4)),
(Instruction::load_boolean(0, true, true), Span(2, 4)),
(Instruction::load_boolean(0, false, false), Span(2, 4)),
(Instruction::r#return(true), Span(6, 6)),
],
vec![Value::integer(1), Value::integer(2)],
vec![]
)),
);
assert_eq!(run(source), Ok(Some(Value::boolean(false))));
}
#[test]
fn greater() {
let source = "1 > 2";
assert_eq!(
compile(source),
Ok(Chunk::with_data(
None,
vec![
(
*Instruction::less_equal(false, 0, 1)
.set_b_is_constant()
.set_c_is_constant(),
Span(2, 3)
),
(Instruction::jump(1, true), Span(2, 3)),
(Instruction::load_boolean(0, true, true), Span(2, 3)),
(Instruction::load_boolean(0, false, false), Span(2, 3)),
(Instruction::r#return(true), Span(5, 5)),
],
vec![Value::integer(1), Value::integer(2)],
vec![]
)),
);
assert_eq!(run(source), Ok(Some(Value::boolean(false))));
}
#[test]
fn greater_than_or_equal() {
let source = "1 >= 2";
assert_eq!(
compile(source),
Ok(Chunk::with_data(
None,
vec![
(
*Instruction::less(false, 0, 1)
.set_b_is_constant()
.set_c_is_constant(),
Span(2, 4)
),
(Instruction::jump(1, true), Span(2, 4)),
(Instruction::load_boolean(0, true, true), Span(2, 4)),
(Instruction::load_boolean(0, false, false), Span(2, 4)),
(Instruction::r#return(true), Span(6, 6)),
],
vec![Value::integer(1), Value::integer(2)],
vec![]
)),
);
assert_eq!(run(source), Ok(Some(Value::boolean(false))));
}
#[test]
fn less_than() {
let source = "1 < 2";
assert_eq!(
compile(source),
Ok(Chunk::with_data(
None,
vec![
(
*Instruction::less(true, 0, 1)
.set_b_is_constant()
.set_c_is_constant(),
Span(2, 3)
),
(Instruction::jump(1, true), Span(2, 3)),
(Instruction::load_boolean(0, true, true), Span(2, 3)),
(Instruction::load_boolean(0, false, false), Span(2, 3)),
(Instruction::r#return(true), Span(5, 5)),
],
vec![Value::integer(1), Value::integer(2)],
vec![]
)),
);
assert_eq!(run(source), Ok(Some(Value::boolean(true))));
}
#[test]
fn less_than_or_equal() {
let source = "1 <= 2";
assert_eq!(
compile(source),
Ok(Chunk::with_data(
None,
vec![
(
*Instruction::less_equal(true, 0, 1)
.set_b_is_constant()
.set_c_is_constant(),
Span(2, 4)
),
(Instruction::jump(1, true), Span(2, 4)),
(Instruction::load_boolean(0, true, true), Span(2, 4)),
(Instruction::load_boolean(0, false, false), Span(2, 4)),
(Instruction::r#return(true), Span(6, 6)),
],
vec![Value::integer(1), Value::integer(2)],
vec![]
)),
);
assert_eq!(run(source), Ok(Some(Value::boolean(true))));
}
#[test]
fn not_equal() {
let source = "1 != 2";
assert_eq!(
compile(source),
Ok(Chunk::with_data(
None,
vec![
(
*Instruction::equal(false, 0, 1)
.set_b_is_constant()
.set_c_is_constant(),
Span(2, 4)
),
(Instruction::jump(1, true), Span(2, 4)),
(Instruction::load_boolean(0, true, true), Span(2, 4)),
(Instruction::load_boolean(0, false, false), Span(2, 4)),
(Instruction::r#return(true), Span(6, 6)),
],
vec![Value::integer(1), Value::integer(2)],
vec![]
)),
);
assert_eq!(run(source), Ok(Some(Value::boolean(true))));
}

420
dust-lang/tests/control_flow.rs
View File

@ -1,420 +0,0 @@
use dust_lang::*;
#[test]
fn equality_assignment_long() {
let source = "let a = if 4 == 4 { true } else { false }; a";
assert_eq!(
compile(source),
Ok(Chunk::with_data(
None,
vec![
(
*Instruction::equal(true, 0, 0)
.set_b_is_constant()
.set_c_is_constant(),
Span(13, 15)
),
(Instruction::jump(1, true), Span(18, 19)),
(Instruction::load_boolean(0, true, true), Span(20, 24)),
(Instruction::load_boolean(0, false, false), Span(34, 39)),
(Instruction::define_local(0, 0, false), Span(4, 5)),
(Instruction::get_local(1, 0), Span(43, 44)),
(Instruction::r#return(true), Span(44, 44)),
],
vec![Value::integer(4), Value::string("a")],
vec![Local::new(
1,
None,
false,
Scope {
depth: 0,
block_index: 0
},
0
)]
)),
);
assert_eq!(run(source), Ok(Some(Value::boolean(true))));
}
#[test]
fn equality_assignment_short() {
let source = "let a = 4 == 4 a";
assert_eq!(
compile(source),
Ok(Chunk::with_data(
None,
vec![
(
*Instruction::equal(true, 0, 0)
.set_b_is_constant()
.set_c_is_constant(),
Span(10, 12)
),
(Instruction::jump(1, true), Span(10, 12)),
(Instruction::load_boolean(0, true, true), Span(10, 12)),
(Instruction::load_boolean(0, false, false), Span(10, 12)),
(Instruction::define_local(0, 0, false), Span(4, 5)),
(Instruction::get_local(1, 0), Span(15, 16)),
(Instruction::r#return(true), Span(16, 16)),
],
vec![Value::integer(4), Value::string("a")],
vec![Local::new(1, None, false, Scope::default(), 0)]
)),
);
assert_eq!(run(source), Ok(Some(Value::boolean(true))));
}
#[test]
fn if_else_assigment_false() {
let source = r#"
let a = if 4 == 3 {
1; 2; 3; 4;
panic()
} else {
1; 2; 3; 4;
42
};
a"#;
assert_eq!(
compile(source),
Ok(Chunk::with_data(
None,
vec![
(
*Instruction::equal(true, 0, 1)
.set_b_is_constant()
.set_c_is_constant(),
Span(22, 24)
),
(Instruction::jump(6, true), Span(27, 28)),
(Instruction::load_constant(0, 2, false), Span(41, 42)),
(Instruction::load_constant(1, 3, false), Span(44, 45)),
(Instruction::load_constant(2, 1, false), Span(47, 48)),
(Instruction::load_constant(3, 0, false), Span(50, 51)),
(
Instruction::call_native(4, NativeFunction::Panic, 0),
Span(65, 72)
),
(Instruction::jump(5, true), Span(138, 139)),
(Instruction::load_constant(5, 2, false), Span(102, 103)),
(Instruction::load_constant(6, 3, false), Span(105, 106)),
(Instruction::load_constant(7, 1, false), Span(108, 109)),
(Instruction::load_constant(8, 0, false), Span(111, 112)),
(Instruction::load_constant(9, 4, false), Span(126, 128)),
(Instruction::r#move(9, 4), Span(138, 139)),
(Instruction::define_local(9, 0, false), Span(13, 14)),
(Instruction::get_local(10, 0), Span(148, 149)),
(Instruction::r#return(true), Span(149, 149)),
],
vec![
Value::integer(4),
Value::integer(3),
Value::integer(1),
Value::integer(2),
Value::integer(42),
Value::string("a")
],
vec![Local::new(5, None, false, Scope::default(), 0)]
)),
);
assert_eq!(run(source), Ok(Some(Value::integer(42))));
}
#[test]
fn if_else_assigment_true() {
let source = r#"
let a = if 4 == 4 {
1; 2; 3; 4;
42
} else {
1; 2; 3; 4;
panic()
};
a"#;
assert_eq!(
compile(source),
Ok(Chunk::with_data(
None,
vec![
(
*Instruction::equal(true, 0, 0)
.set_b_is_constant()
.set_c_is_constant(),
Span(22, 24)
),
(Instruction::jump(6, true), Span(27, 28)),
(Instruction::load_constant(0, 1, false), Span(41, 42)),
(Instruction::load_constant(1, 2, false), Span(44, 45)),
(Instruction::load_constant(2, 3, false), Span(47, 48)),
(Instruction::load_constant(3, 0, false), Span(50, 51)),
(Instruction::load_constant(4, 4, false), Span(65, 67)),
(Instruction::jump(5, true), Span(138, 139)),
(Instruction::load_constant(5, 1, false), Span(97, 98)),
(Instruction::load_constant(6, 2, false), Span(100, 101)),
(Instruction::load_constant(7, 3, false), Span(103, 104)),
(Instruction::load_constant(8, 0, false), Span(106, 107)),
(
Instruction::call_native(9, NativeFunction::Panic, 0),
Span(121, 128)
),
(Instruction::r#move(9, 4), Span(138, 139)),
(Instruction::define_local(9, 0, false), Span(13, 14)),
(Instruction::get_local(10, 0), Span(148, 149)),
(Instruction::r#return(true), Span(149, 149)),
],
vec![
Value::integer(4),
Value::integer(1),
Value::integer(2),
Value::integer(3),
Value::integer(42),
Value::string("a")
],
vec![Local::new(5, None, false, Scope::default(), 0)]
)),
);
assert_eq!(run(source), Ok(Some(Value::integer(42))));
}
#[test]
fn if_else_complex() {
let source = "
if 1 == 1 {
1; 2; 3; 4;
} else {
1; 2; 3; 4;
}";
assert_eq!(
compile(source),
Ok(Chunk::with_data(
None,
vec![
(
*Instruction::equal(true, 0, 0)
.set_b_is_constant()
.set_c_is_constant(),
Span(14, 16)
),
(Instruction::jump(5, true), Span(19, 20)),
(Instruction::load_constant(0, 0, false), Span(33, 34)),
(Instruction::load_constant(1, 1, false), Span(36, 37)),
(Instruction::load_constant(2, 2, false), Span(39, 40)),
(Instruction::load_constant(3, 3, false), Span(42, 43)),
(Instruction::jump(4, true), Span(95, 95)),
(Instruction::load_constant(4, 0, false), Span(74, 75)),
(Instruction::load_constant(5, 1, false), Span(77, 78)),
(Instruction::load_constant(6, 2, false), Span(80, 81)),
(Instruction::load_constant(7, 3, false), Span(83, 84)),
(Instruction::r#move(7, 3), Span(95, 95)),
(Instruction::r#return(false), Span(95, 95)),
],
vec![
Value::integer(1),
Value::integer(2),
Value::integer(3),
Value::integer(4),
],
vec![]
))
);
assert_eq!(run(source), Ok(None));
}
// #[test]
// fn if_else_nested() {
// let source = r#"
// if 0 == 1 {
// if 0 == 2 {
// 1;
// } else {
// 2;
// }
// } else {
// if 0 == 3 {
// 3;
// } else {
// 4;
// }
// }"#;
// assert_eq!(
// parse(source),
// Ok(Chunk::with_data(
// None,
// vec![
// (
// *Instruction::equal(true, 0, 1)
// .set_b_is_constant()
// .set_c_is_constant(),
// Span(14, 16)
// ),
// (Instruction::jump(7, true), Span(14, 16)),
// (
// *Instruction::equal(true, 0, 2)
// .set_b_is_constant()
// .set_c_is_constant(),
// Span(38, 41)
// ),
// (Instruction::jump(3, true), Span(38, 41)),
// (Instruction::load_constant(0, 1, false), Span(61, 62)),
// (Instruction::jump(1, true1), Span(95, 95)),
// (
// *Instruction::equal(true, 0, 3)
// .set_b_is_constant()
// .set_c_is_constant(),
// Span(77, 79)
// ),
// (Instruction::jump(3, true), Span(77, 79)),
// (Instruction::load_constant(0, 2, false), Span(94, 95)),
// (Instruction::jump(1, true1), Span(95, 95)),
// (Instruction::load_constant(0, 3, false), Span(114, 115)),
// (Instruction::jump(1, true1), Span(95, 95)),
// (Instruction::load_constant(0, 4, false), Span(134, 135)),
// (Instruction::r#return(true), Span(146, 146)),
// ],
// vec![
// Value::integer(0),
// Value::integer(1),
// Value::integer(0),
// Value::integer(2),
// Value::integer(1),
// Value::integer(0),
// Value::integer(3),
// Value::integer(3),
// Value::integer(4)
// ],
// vec![]
// ))
// );
// assert_eq!(run(source), Ok(Some(Value::integer(4))));
// }
#[test]
fn if_else_false() {
let source = "if 1 == 2 { panic() } else { 42 }";
assert_eq!(
compile(source),
Ok(Chunk::with_data(
None,
vec![
(
*Instruction::equal(true, 0, 1)
.set_b_is_constant()
.set_c_is_constant(),
Span(5, 7)
),
(Instruction::jump(1, true), Span(10, 11)),
(
Instruction::call_native(0, NativeFunction::Panic, 0),
Span(12, 19)
),
(Instruction::load_constant(1, 2, true), Span(29, 31)),
(Instruction::r#move(1, 0), Span(33, 33)),
(Instruction::r#return(true), Span(33, 33)),
],
vec![Value::integer(1), Value::integer(2), Value::integer(42)],
vec![]
)),
);
assert_eq!(run(source), Ok(Some(Value::integer(42))));
}
#[test]
fn if_else_true() {
let source = "if 1 == 1 { 42 } else { panic() }";
assert_eq!(
compile(source),
Ok(Chunk::with_data(
None,
vec![
(
*Instruction::equal(true, 0, 0)
.set_b_is_constant()
.set_c_is_constant(),
Span(5, 7)
),
(Instruction::jump(1, true), Span(10, 11)),
(Instruction::load_constant(0, 1, true), Span(12, 14)),
(
Instruction::call_native(1, NativeFunction::Panic, 0),
Span(24, 31)
),
(Instruction::r#move(1, 0), Span(33, 33)),
(Instruction::r#return(true), Span(33, 33))
],
vec![Value::integer(1), Value::integer(42)],
vec![]
)),
);
assert_eq!(run(source), Ok(Some(Value::integer(42))));
}
#[test]
fn if_false() {
let source = "if 1 == 2 { 2 }";
assert_eq!(
compile(source),
Ok(Chunk::with_data(
None,
vec![
(
*Instruction::equal(true, 0, 1)
.set_b_is_constant()
.set_c_is_constant(),
Span(5, 7)
),
(Instruction::jump(1, true), Span(10, 11)),
(Instruction::load_constant(0, 1, false), Span(12, 13)),
(Instruction::r#return(false), Span(15, 15))
],
vec![Value::integer(1), Value::integer(2)],
vec![]
)),
);
assert_eq!(run(source), Ok(None));
}
#[test]
fn if_true() {
let source = "if 1 == 1 { 2 }";
assert_eq!(
compile(source),
Ok(Chunk::with_data(
None,
vec![
(
*Instruction::equal(true, 0, 0)
.set_b_is_constant()
.set_c_is_constant(),
Span(5, 7)
),
(Instruction::jump(1, true), Span(10, 11)),
(Instruction::load_constant(0, 1, false), Span(12, 13)),
(Instruction::r#return(false), Span(15, 15))
],
vec![Value::integer(1), Value::integer(2)],
vec![]
)),
);
assert_eq!(run(source), Ok(None));
}

126
dust-lang/tests/functions.rs
View File

@ -1,126 +0,0 @@
use dust_lang::*;
#[test]
fn function() {
let source = "fn(a: int, b: int) -> int { a + b }";
assert_eq!(
run(source),
Ok(Some(Value::function(
Chunk::with_data(
None,
vec![
(Instruction::add(2, 0, 1), Span(30, 31)),
(Instruction::r#return(true), Span(35, 35)),
],
vec![Value::string("a"), Value::string("b"),],
vec![
Local::new(0, Some(Type::Integer), false, Scope::default(), 0),
Local::new(1, Some(Type::Integer), false, Scope::default(), 1)
]
),
FunctionType {
type_parameters: None,
value_parameters: Some(vec![(0, Type::Integer), (1, Type::Integer)]),
return_type: Some(Box::new(Type::Integer)),
}
)))
);
}
#[test]
fn function_call() {
let source = "fn(a: int, b: int) -> int { a + b }(1, 2)";
assert_eq!(
compile(source),
Ok(Chunk::with_data(
None,
vec![
(Instruction::load_constant(0, 0, false), Span(0, 36)),
(Instruction::load_constant(1, 1, false), Span(36, 37)),
(Instruction::load_constant(2, 2, false), Span(39, 40)),
(Instruction::call(3, 0, 2), Span(35, 41)),
(Instruction::r#return(true), Span(41, 41)),
],
vec![
Value::function(
Chunk::with_data(
None,
vec![
(Instruction::add(2, 0, 1), Span(30, 31)),
(Instruction::r#return(true), Span(35, 36)),
],
vec![Value::string("a"), Value::string("b"),],
vec![
Local::new(0, Some(Type::Integer), false, Scope::default(), 0),
Local::new(1, Some(Type::Integer), false, Scope::default(), 1)
]
),
FunctionType {
type_parameters: None,
value_parameters: Some(vec![(0, Type::Integer), (1, Type::Integer)]),
return_type: Some(Box::new(Type::Integer)),
}
),
Value::integer(1),
Value::integer(2)
],
vec![]
)),
);
assert_eq!(run(source), Ok(Some(Value::integer(3))));
}
#[test]
fn function_declaration() {
let source = "fn add (a: int, b: int) -> int { a + b }";
assert_eq!(
compile(source),
Ok(Chunk::with_data(
None,
vec![
(Instruction::load_constant(0, 1, false), Span(0, 40)),
(Instruction::define_local(0, 0, false), Span(3, 6)),
(Instruction::r#return(false), Span(40, 40))
],
vec![
Value::string("add"),
Value::function(
Chunk::with_data(
None,
vec![
(Instruction::add(2, 0, 1), Span(35, 36)),
(Instruction::r#return(true), Span(40, 40)),
],
vec![Value::string("a"), Value::string("b")],
vec![
Local::new(0, Some(Type::Integer), false, Scope::default(), 0),
Local::new(1, Some(Type::Integer), false, Scope::default(), 1)
]
),
FunctionType {
type_parameters: None,
value_parameters: Some(vec![(0, Type::Integer), (1, Type::Integer)]),
return_type: Some(Box::new(Type::Integer)),
},
)
],
vec![Local::new(
0,
Some(Type::Function(FunctionType {
type_parameters: None,
value_parameters: Some(vec![(0, Type::Integer), (1, Type::Integer)]),
return_type: Some(Box::new(Type::Integer)),
})),
false,
Scope::default(),
0
),],
)),
);
assert_eq!(run(source), Ok(None));
}

127
dust-lang/tests/lists.rs
View File

@ -1,127 +0,0 @@
use dust_lang::*;
#[test]
fn empty_list() {
let source = "[]";
assert_eq!(
compile(source),
Ok(Chunk::with_data(
None,
vec![
(Instruction::load_list(0, 0), Span(0, 2)),
(Instruction::r#return(true), Span(2, 2)),
],
vec![],
vec![]
)),
);
assert_eq!(run(source), Ok(Some(Value::abstract_list(0, 0, Type::Any))));
}
#[test]
fn list() {
let source = "[1, 2, 3]";
assert_eq!(
compile(source),
Ok(Chunk::with_data(
None,
vec![
(Instruction::load_constant(0, 0, false), Span(1, 2)),
(Instruction::load_constant(1, 1, false), Span(4, 5)),
(Instruction::load_constant(2, 2, false), Span(7, 8)),
(Instruction::load_list(3, 0), Span(0, 9)),
(Instruction::r#return(true), Span(9, 9)),
],
vec![Value::integer(1), Value::integer(2), Value::integer(3)],
vec![]
)),
);
assert_eq!(
run(source),
Ok(Some(Value::abstract_list(0, 3, Type::Integer)))
);
}
#[test]
fn list_with_complex_expression() {
let source = "[1, 2 + 3 - 4 * 5]";
assert_eq!(
compile(source),
Ok(Chunk::with_data(
None,
vec![
(Instruction::load_constant(0, 0, false), Span(1, 2)),
(
*Instruction::add(1, 1, 2)
.set_b_is_constant()
.set_c_is_constant(),
Span(6, 7)
),
(
*Instruction::multiply(2, 3, 4)
.set_b_is_constant()
.set_c_is_constant(),
Span(14, 15)
),
(Instruction::subtract(3, 1, 2), Span(10, 11)),
(Instruction::close(1, 3), Span(17, 18)),
(Instruction::load_list(4, 0), Span(0, 18)),
(Instruction::r#return(true), Span(18, 18)),
],
vec![
Value::integer(1),
Value::integer(2),
Value::integer(3),
Value::integer(4),
Value::integer(5)
],
vec![]
)),
);
assert_eq!(
run(source),
Ok(Some(Value::abstract_list(0, 4, Type::Integer)))
);
}
#[test]
fn list_with_simple_expression() {
let source = "[1, 2 + 3, 4]";
assert_eq!(
compile(source),
Ok(Chunk::with_data(
None,
vec![
(Instruction::load_constant(0, 0, false), Span(1, 2)),
(
*Instruction::add(1, 1, 2)
.set_b_is_constant()
.set_c_is_constant(),
Span(6, 7)
),
(Instruction::load_constant(2, 3, false), Span(11, 12)),
(Instruction::load_list(3, 0), Span(0, 13)),
(Instruction::r#return(true), Span(13, 13)),
],
vec![
Value::integer(1),
Value::integer(2),
Value::integer(3),
Value::integer(4),
],
vec![]
)),
);
assert_eq!(
run(source),
Ok(Some(Value::abstract_list(0, 3, Type::Integer)))
);
}

77
dust-lang/tests/logic.rs
View File

@ -1,77 +0,0 @@
use dust_lang::*;
#[test]
fn and() {
let source = "true && false";
assert_eq!(
compile(source),
Ok(Chunk::with_data(
None,
vec![
(Instruction::load_boolean(0, true, false), Span(0, 4)),
(Instruction::test(0, false), Span(5, 7)),
(Instruction::jump(1, true), Span(5, 7)),
(Instruction::load_boolean(1, false, false), Span(8, 13)),
(Instruction::r#return(true), Span(13, 13)),
],
vec![],
vec![]
))
);
assert_eq!(run(source), Ok(Some(Value::boolean(false))));
}
#[test]
fn or() {
let source = "true || false";
assert_eq!(
compile(source),
Ok(Chunk::with_data(
None,
vec![
(Instruction::load_boolean(0, true, false), Span(0, 4)),
(Instruction::test(0, true), Span(5, 7)),
(Instruction::jump(1, true), Span(5, 7)),
(Instruction::load_boolean(1, false, false), Span(8, 13)),
(Instruction::r#return(true), Span(13, 13)),
],
vec![],
vec![]
))
);
assert_eq!(run(source), Ok(Some(Value::boolean(true))));
}
#[test]
fn variable_and() {
let source = "let a = true; let b = false; a && b";
assert_eq!(
compile(source),
Ok(Chunk::with_data(
None,
vec![
(Instruction::load_boolean(0, true, false), Span(8, 12)),
(Instruction::define_local(0, 0, false), Span(4, 5)),
(Instruction::load_boolean(1, false, false), Span(22, 27)),
(Instruction::define_local(1, 1, false), Span(18, 19)),
(Instruction::get_local(2, 0), Span(29, 30)),
(Instruction::test(2, false), Span(31, 33)),
(Instruction::jump(1, true), Span(31, 33)),
(Instruction::get_local(3, 1), Span(34, 35)),
(Instruction::r#return(true), Span(35, 35)),
],
vec![Value::string("a"), Value::string("b"),],
vec![
Local::new(0, None, false, Scope::default(), 0),
Local::new(1, None, false, Scope::default(), 1),
]
))
);
assert_eq!(run(source), Ok(Some(Value::boolean(false))));
}

35
dust-lang/tests/loops.rs
View File

@ -1,35 +0,0 @@
use dust_lang::*;
#[test]
fn r#while() {
let source = "let mut x = 0; while x < 5 { x = x + 1 } x";
assert_eq!(
compile(source),
Ok(Chunk::with_data(
None,
vec![
(Instruction::load_constant(0, 0, false), Span(12, 13)),
(Instruction::define_local(0, 0, true), Span(8, 9)),
(
*Instruction::less(true, 0, 2).set_c_is_constant(),
Span(23, 24)
),
(Instruction::jump(2, true), Span(41, 42)),
(*Instruction::add(0, 0, 3).set_c_is_constant(), Span(39, 40)),
(Instruction::jump(3, false), Span(41, 42)),
(Instruction::get_local(1, 0), Span(41, 42)),
(Instruction::r#return(true), Span(42, 42)),
],
vec![
Value::integer(0),
Value::string("x"),
Value::integer(5),
Value::integer(1),
],
vec![Local::new(1, None, true, Scope::default(), 0),]
)),
);
assert_eq!(run(source), Ok(Some(Value::integer(5))));
}

324
dust-lang/tests/math.rs
View File

@ -1,324 +0,0 @@
use dust_lang::*;
#[test]
fn add() {
let source = "1 + 2";
assert_eq!(
compile(source),
Ok(Chunk::with_data(
None,
vec![
(
*Instruction::add(0, 0, 1)
.set_b_is_constant()
.set_c_is_constant(),
Span(2, 3)
),
(Instruction::r#return(true), Span(5, 5))
],
vec![Value::integer(1), Value::integer(2)],
vec![]
))
);
assert_eq!(run(source), Ok(Some(Value::integer(3))));
}
#[test]
fn add_assign() {
let source = "let mut a = 1; a += 2; a";
assert_eq!(
compile(source),
Ok(Chunk::with_data(
None,
vec![
(Instruction::load_constant(0, 0, false), Span(12, 13)),
(Instruction::define_local(0, 0, true), Span(8, 9)),
(*Instruction::add(0, 0, 2).set_c_is_constant(), Span(17, 19)),
(Instruction::get_local(1, 0), Span(23, 24)),
(Instruction::r#return(true), Span(24, 24))
],
vec![Value::integer(1), Value::string("a"), Value::integer(2)],
vec![Local::new(1, None, true, Scope::default(), 0)]
))
);
assert_eq!(run(source), Ok(Some(Value::integer(3))));
}
#[test]
fn add_assign_expects_mutable_variable() {
let source = "1 += 2";
assert_eq!(
compile(source),
Err(DustError::Compile {
error: CompileError::ExpectedMutableVariable {
found: Token::Integer("1").to_owned(),
position: Span(0, 1)
},
source
})
);
}
// #[test]
// fn add_expects_integer_float_or_string() {
// let source = "true + false";
// assert_eq!(
// parse(source),
// Err(DustError::Parse {
// error: ParseError::ExpectedIntegerFloatOrString {
// found: Token::True,
// position: Span(0, 3)
// },
// source
// })
// );
// }
#[test]
fn divide() {
let source = "2 / 2";
assert_eq!(
compile(source),
Ok(Chunk::with_data(
None,
vec![
(
*Instruction::divide(0, 0, 0)
.set_b_is_constant()
.set_c_is_constant(),
Span(2, 3)
),
(Instruction::r#return(true), Span(5, 5))
],
vec![Value::integer(2)],
vec![]
))
);
assert_eq!(run(source), Ok(Some(Value::integer(1))));
}
#[test]
fn divide_assign() {
let source = "let mut a = 2; a /= 2; a";
assert_eq!(
compile(source),
Ok(Chunk::with_data(
None,
vec![
(Instruction::load_constant(0, 0, false), Span(12, 13)),
(Instruction::define_local(0, 0, true), Span(8, 9)),
(
*Instruction::divide(0, 0, 0).set_c_is_constant(),
Span(17, 19)
),
(Instruction::get_local(1, 0), Span(23, 24)),
(Instruction::r#return(true), Span(24, 24))
],
vec![Value::integer(2), Value::string("a")],
vec![Local::new(1, None, true, Scope::default(), 0)]
))
);
assert_eq!(run(source), Ok(Some(Value::integer(1))));
}
#[test]
fn divide_assign_expects_mutable_variable() {
let source = "1 -= 2";
assert_eq!(
compile(source),
Err(DustError::Compile {
error: CompileError::ExpectedMutableVariable {
found: Token::Integer("1").to_owned(),
position: Span(0, 1)
},
source
})
);
}
#[test]
fn math_operator_precedence() {
let source = "1 + 2 - 3 * 4 / 5";
assert_eq!(
compile(source),
Ok(Chunk::with_data(
None,
vec![
(
*Instruction::add(0, 0, 1)
.set_b_is_constant()
.set_c_is_constant(),
Span(2, 3)
),
(
*Instruction::multiply(1, 2, 3)
.set_b_is_constant()
.set_c_is_constant(),
Span(10, 11)
),
(
*Instruction::divide(2, 1, 4).set_c_is_constant(),
Span(14, 15)
),
(Instruction::subtract(3, 0, 2), Span(6, 7)),
(Instruction::r#return(true), Span(17, 17)),
],
vec![
Value::integer(1),
Value::integer(2),
Value::integer(3),
Value::integer(4),
Value::integer(5),
],
vec![]
))
);
assert_eq!(run(source), Ok(Some(Value::integer(1))));
}
#[test]
fn multiply() {
let source = "1 * 2";
assert_eq!(
compile(source),
Ok(Chunk::with_data(
None,
vec![
(
*Instruction::multiply(0, 0, 1)
.set_b_is_constant()
.set_c_is_constant(),
Span(2, 3)
),
(Instruction::r#return(true), Span(5, 5)),
],
vec![Value::integer(1), Value::integer(2)],
vec![]
))
);
assert_eq!(run(source), Ok(Some(Value::integer(2))));
}
#[test]
fn multiply_assign() {
let source = "let mut a = 2; a *= 3 a";
assert_eq!(
compile(source),
Ok(Chunk::with_data(
None,
vec![
(Instruction::load_constant(0, 0, false), Span(12, 13)),
(Instruction::define_local(0, 0, true), Span(8, 9)),
(
*Instruction::multiply(0, 0, 2).set_c_is_constant(),
Span(17, 19)
),
(Instruction::get_local(1, 0), Span(22, 23)),
(Instruction::r#return(true), Span(23, 23))
],
vec![Value::integer(2), Value::string("a"), Value::integer(3)],
vec![Local::new(1, None, true, Scope::default(), 0),]
))
);
assert_eq!(run(source), Ok(Some(Value::integer(6))));
}
#[test]
fn multiply_assign_expects_mutable_variable() {
let source = "1 *= 2";
assert_eq!(
compile(source),
Err(DustError::Compile {
error: CompileError::ExpectedMutableVariable {
found: Token::Integer("1").to_owned(),
position: Span(0, 1)
},
source
})
);
}
#[test]
fn subtract() {
let source = "1 - 2";
assert_eq!(
compile(source),
Ok(Chunk::with_data(
None,
vec![
(
*Instruction::subtract(0, 0, 1)
.set_b_is_constant()
.set_c_is_constant(),
Span(2, 3)
),
(Instruction::r#return(true), Span(5, 5)),
],
vec![Value::integer(1), Value::integer(2)],
vec![]
))
);
assert_eq!(run(source), Ok(Some(Value::integer(-1))));
}
#[test]
fn subtract_assign() {
let source = "let mut x = 42; x -= 2; x";
assert_eq!(
compile(source),
Ok(Chunk::with_data(
None,
vec![
(Instruction::load_constant(0, 0, false), Span(12, 14)),
(Instruction::define_local(0, 0, true), Span(8, 9)),
(
*Instruction::subtract(0, 0, 2).set_c_is_constant(),
Span(18, 20)
),
(Instruction::get_local(1, 0), Span(24, 25)),
(Instruction::r#return(true), Span(25, 25)),
],
vec![Value::integer(42), Value::string("x"), Value::integer(2)],
vec![Local::new(1, None, true, Scope::default(), 0)]
)),
);
assert_eq!(run(source), Ok(Some(Value::integer(40))));
}
#[test]
fn subtract_assign_expects_mutable_variable() {
let source = "1 -= 2";
assert_eq!(
compile(source),
Err(DustError::Compile {
error: CompileError::ExpectedMutableVariable {
found: Token::Integer("1").to_owned(),
position: Span(0, 1)
},
source
})
);
}

59
dust-lang/tests/native_functions.rs
View File

@ -1,59 +0,0 @@
use dust_lang::*;
#[test]
fn panic() {
let source = "panic(\"Goodbye world!\", 42)";
assert_eq!(
compile(source),
Ok(Chunk::with_data(
None,
vec![
(Instruction::load_constant(0, 0, false), Span(6, 22)),
(Instruction::load_constant(1, 1, false), Span(24, 26)),
(
Instruction::call_native(2, NativeFunction::Panic, 2),
Span(0, 27)
),
(Instruction::r#return(true), Span(27, 27))
],
vec![Value::string("Goodbye world!"), Value::integer(42)],
vec![]
)),
);
assert_eq!(
run(source),
Err(DustError::Runtime {
error: VmError::NativeFunction(NativeFunctionError::Panic {
message: Some("Goodbye world! 42".to_string()),
position: Span(0, 27)
}),
source
})
)
}
#[test]
fn to_string() {
let source = "to_string(42)";
assert_eq!(
compile(source),
Ok(Chunk::with_data(
None,
vec![
(Instruction::load_constant(0, 0, false), Span(10, 12)),
(
Instruction::call_native(1, NativeFunction::ToString, 1),
Span(0, 13)
),
(Instruction::r#return(true), Span(13, 13))
],
vec![Value::integer(42)],
vec![]
)),
);
assert_eq!(run(source), Ok(Some(Value::string("42"))))
}

244
dust-lang/tests/scopes.rs
View File

@ -1,244 +0,0 @@
use dust_lang::*;
#[test]
fn allow_access_to_parent_scope() {
let source = r#"
let x = 1;
{
x
}
"#;
assert_eq!(run(source), Ok(Some(Value::integer(1))));
}
#[test]
fn block_scope() {
let source = "
let a = 0;
{
let b = 42;
{
let c = 1;
}
let d = 2;
}
let e = 1;
";
assert_eq!(
compile(source),
Ok(Chunk::with_data(
None,
vec![
(Instruction::load_constant(0, 0, false), Span(17, 18)),
(Instruction::define_local(0, 0, false), Span(13, 14)),
(Instruction::load_constant(1, 2, false), Span(50, 52)),
(Instruction::define_local(1, 1, false), Span(46, 47)),
(Instruction::load_constant(2, 4, false), Span(92, 93)),
(Instruction::define_local(2, 2, false), Span(88, 89)),
(Instruction::load_constant(3, 6, false), Span(129, 130)),
(Instruction::define_local(3, 3, false), Span(125, 126)),
(Instruction::load_constant(4, 4, false), Span(158, 159)),
(Instruction::define_local(4, 4, false), Span(154, 155)),
(Instruction::r#return(false), Span(165, 165))
],
vec![
Value::integer(0),
Value::string("a"),
Value::integer(42),
Value::string("b"),
Value::integer(1),
Value::string("c"),
Value::integer(2),
Value::string("d"),
Value::string("e"),
],
vec![
Local::new(1, None, false, Scope::new(0, 0), 0),
Local::new(3, None, false, Scope::new(1, 1), 1),
Local::new(5, None, false, Scope::new(2, 2), 2),
Local::new(7, None, false, Scope::new(1, 1), 3),
Local::new(8, None, false, Scope::new(0, 0), 4),
]
)),
);
assert_eq!(run(source), Ok(None));
}
#[test]
fn multiple_block_scopes() {
let source = "
let a = 0;
{
let b = 42;
{
let c = 1;
}
let d = 2;
}
let q = 42;
{
let b = 42;
{
let c = 1;
}
let d = 2;
}
let e = 1;
";
assert_eq!(
compile(source),
Ok(Chunk::with_data(
None,
vec![
(Instruction::load_constant(0, 0, false), Span(17, 18)),
(Instruction::define_local(0, 0, false), Span(13, 14)),
(Instruction::load_constant(1, 2, false), Span(50, 52)),
(Instruction::define_local(1, 1, false), Span(46, 47)),
(Instruction::load_constant(2, 4, false), Span(92, 93)),
(Instruction::define_local(2, 2, false), Span(88, 89)),
(Instruction::load_constant(3, 6, false), Span(129, 130)),
(Instruction::define_local(3, 3, false), Span(125, 126)),
(Instruction::load_constant(4, 2, false), Span(158, 160)),
(Instruction::define_local(4, 4, false), Span(154, 155)),
(Instruction::load_constant(5, 2, false), Span(192, 194)),
(Instruction::define_local(5, 5, false), Span(188, 189)),
(Instruction::load_constant(6, 4, false), Span(234, 235)),
(Instruction::define_local(6, 6, false), Span(230, 231)),
(Instruction::load_constant(7, 6, false), Span(271, 272)),
(Instruction::define_local(7, 7, false), Span(267, 268)),
(Instruction::load_constant(8, 4, false), Span(300, 301)),
(Instruction::define_local(8, 8, false), Span(296, 297)),
(Instruction::r#return(false), Span(307, 307))
],
vec![
Value::integer(0),
Value::string("a"),
Value::integer(42),
Value::string("b"),
Value::integer(1),
Value::string("c"),
Value::integer(2),
Value::string("d"),
Value::string("q"),
Value::string("e"),
],
vec![
Local::new(1, None, false, Scope::new(0, 0), 0),
Local::new(3, None, false, Scope::new(1, 1), 1),
Local::new(5, None, false, Scope::new(2, 2), 2),
Local::new(7, None, false, Scope::new(1, 1), 3),
Local::new(8, None, false, Scope::new(0, 0), 4),
Local::new(3, None, false, Scope::new(1, 3), 5),
Local::new(5, None, false, Scope::new(2, 4), 6),
Local::new(7, None, false, Scope::new(1, 3), 7),
Local::new(9, None, false, Scope::new(0, 0), 8),
]
)),
);
assert_eq!(run(source), Ok(None));
}
#[test]
fn disallow_access_to_child_scope() {
let source = r#"
{
let x = 1;
}
x
"#;
assert_eq!(
run(source),
Err(DustError::Compile {
error: CompileError::VariableOutOfScope {
identifier: "x".to_string(),
position: Span(52, 53),
variable_scope: Scope::new(1, 1),
access_scope: Scope::new(0, 0),
},
source
})
);
}
#[test]
fn disallow_access_to_child_scope_nested() {
let source = r#"
{
{
let x = 1;
}
x
}
"#;
assert_eq!(
run(source),
Err(DustError::Compile {
error: CompileError::VariableOutOfScope {
identifier: "x".to_string(),
position: Span(78, 79),
variable_scope: Scope::new(2, 2),
access_scope: Scope::new(1, 1),
},
source
})
);
}
#[test]
fn disallow_access_to_sibling_scope() {
let source = r#"
{
let x = 1;
}
{
x
}
"#;
assert_eq!(
run(source),
Err(DustError::Compile {
error: CompileError::VariableOutOfScope {
identifier: "x".to_string(),
variable_scope: Scope::new(1, 1),
access_scope: Scope::new(1, 2),
position: Span(66, 67),
},
source
})
);
}
#[test]
fn disallow_access_to_sibling_scope_nested() {
let source = r#"
{
{
let x = 1;
}
{
x
}
}
"#;
assert_eq!(
run(source),
Err(DustError::Compile {
error: CompileError::VariableOutOfScope {
identifier: "x".to_string(),
variable_scope: Scope::new(2, 2),
access_scope: Scope::new(2, 3),
position: Span(96, 97),
},
source
})
);
}

42
dust-lang/tests/unary_operations.rs
View File

@ -1,42 +0,0 @@
use dust_lang::*;
#[test]
fn negate() {
let source = "-(42)";
assert_eq!(
compile(source),
Ok(Chunk::with_data(
None,
vec![
(*Instruction::negate(0, 0).set_b_is_constant(), Span(0, 1)),
(Instruction::r#return(true), Span(5, 5)),
],
vec![Value::integer(42)],
vec![]
)),
);
assert_eq!(run(source), Ok(Some(Value::integer(-42))));
}
#[test]
fn not() {
let source = "!true";
assert_eq!(
compile(source),
Ok(Chunk::with_data(
None,
vec![
(Instruction::load_boolean(0, true, false), Span(1, 5)),
(Instruction::not(1, 0), Span(0, 1)),
(Instruction::r#return(true), Span(5, 5)),
],
vec![],
vec![]
)),
);
assert_eq!(run(source), Ok(Some(Value::boolean(false))));
}

63
dust-lang/tests/variables.rs
View File

@ -1,63 +0,0 @@
use dust_lang::*;
#[test]
fn define_local() {
let source = "let x = 42;";
assert_eq!(
compile(source),
Ok(Chunk::with_data(
None,
vec![
(Instruction::load_constant(0, 0, false), Span(8, 10)),
(Instruction::define_local(0, 0, false), Span(4, 5)),
(Instruction::r#return(false), Span(11, 11))
],
vec![Value::integer(42), Value::string("x")],
vec![Local::new(1, None, false, Scope::default(), 0)]
)),
);
assert_eq!(run(source), Ok(None));
}
#[test]
fn let_statement_expects_identifier() {
let source = "let 1 = 2";
assert_eq!(
compile(source),
Err(DustError::Compile {
error: CompileError::ExpectedToken {
expected: TokenKind::Identifier,
found: Token::Integer("1").to_owned(),
position: Span(4, 5)
},
source
})
);
}
#[test]
fn set_local() {
let source = "let mut x = 41; x = 42; x";
assert_eq!(
compile(source),
Ok(Chunk::with_data(
None,
vec![
(Instruction::load_constant(0, 0, false), Span(12, 14)),
(Instruction::define_local(0, 0, true), Span(8, 9)),
(Instruction::load_constant(1, 2, false), Span(20, 22)),
(Instruction::set_local(1, 0), Span(16, 17)),
(Instruction::get_local(2, 0), Span(24, 25)),
(Instruction::r#return(true), Span(25, 25)),
],
vec![Value::integer(41), Value::string("x"), Value::integer(42)],
vec![Local::new(1, None, true, Scope::default(), 0)]
)),
);
assert_eq!(run(source), Ok(Some(Value::integer(42))));
}

15
dust-shell/Cargo.toml
View File

@ -1,15 +0,0 @@
[package]
name = "dust-shell"
version = "0.1.0"
authors.workspace = true
edition.workspace = true
license.workspace = true
readme.workspace = true
repository.workspace = true
[dependencies]
clap = { version = "4.5.14", features = ["derive"] }
colored = "2.1.0"
dust-lang = { path = "../dust-lang" }
env_logger = "0.11.5"
log = "0.4.22"

138
dust-shell/src/main.rs
View File

@ -1,138 +0,0 @@
use std::{fs::read_to_string, io::Write};
use clap::Parser;
use colored::Colorize;
use dust_lang::{compile, format, run};
use log::{Level, LevelFilter};
#[derive(Parser)]
struct Cli {
/// Source code sent via command line
#[arg(short, long)]
command: Option<String>,
/// Whether to output formatted source code
#[arg(short, long)]
format: bool,
/// Whether to output line numbers in formatted source code
#[arg(long)]
format_line_numbers: Option<bool>,
/// Whether to output colors in formatted source code
#[arg(long)]
format_colored: Option<bool>,
/// Whether to output the disassembled chunk
#[arg(short, long)]
parse: bool,
/// Whether to style the disassembled chunk
#[arg(long)]
style_disassembly: Option<bool>,
/// Log level
#[arg(short, long)]
log: Option<LevelFilter>,
/// Path to a source code file
path: Option<String>,
}
fn main() {
let args = Cli::parse();
let mut logger = env_logger::builder();
logger.format(|buf, record| {
let level_display = match record.level() {
Level::Info => "INFO".bold().white(),
Level::Debug => "DEBUG".bold().blue(),
Level::Warn => "WARN".bold().yellow(),
Level::Error => "ERROR".bold().red(),
Level::Trace => "TRACE".bold().purple(),
};
let module = record
.module_path()
.map(|path| path.split("::").last().unwrap_or(path))
.unwrap_or("unknown")
.dimmed();
let display = format!("{level_display:5} {module:^6} {args}", args = record.args());
writeln!(buf, "{display}")
});
if let Some(level) = args.log {
logger.filter_level(level).init();
} else {
logger.parse_env("DUST_LOG").init();
}
let source = if let Some(path) = &args.path {
&read_to_string(path).expect("Failed to read file")
} else if let Some(command) = &args.command {
command
} else {
eprintln!("No input provided");
return;
};
if args.format {
let line_numbers = args.format_line_numbers.unwrap_or(true);
let colored = args.format_colored.unwrap_or(true);
log::info!("Formatting source");
match format(source, line_numbers, colored) {
Ok(formatted) => println!("{}", formatted),
Err(error) => {
eprintln!("{}", error.report());
}
}
}
if args.parse {
let styled = args.style_disassembly.unwrap_or(true);
log::info!("Parsing source");
match compile(source) {
Ok(chunk) => {
let disassembly = chunk
.disassembler()
.source(source)
.styled(styled)
.disassemble();
println!("{}", disassembly);
}
Err(error) => {
eprintln!("{}", error.report());
}
}
}
if args.format || args.parse {
return;
}
match run(source) {
Ok(Some(value)) => println!("{}", value),
Ok(None) => {}
Err(error) => {
eprintln!("{}", error.report());
}
}
}
#[cfg(test)]
mod tests {
use clap::CommandFactory;
use super::*;
#[test]
fn verify_cli() {
Cli::command().debug_assert();
}
}

5
examples/assets/count.js
View File

@ -1,5 +0,0 @@
var i = 0;
while (i < 10000) {
i++;
}

6
examples/assets/data.json
View File

@ -1,6 +0,0 @@
[
{ "name": "Sammy", "type": "shark", "clams": 5 },
{ "name": "Bubbles", "type": "orca", "clams": 3 },
{ "name": "Splish", "type": "dolphin", "clams": 2 },
{ "name": "Splash", "type": "dolphin", "clams": 2 }
]

11
examples/assets/fibonacci.js
View File

@ -1,11 +0,0 @@
function fib(n) {
if (n <= 0) {
return 0;
} else if (n === 1) {
return 1;
} else {
return fib(n - 1) + fib(n - 2);
}
}
console.log(fib(25));

6
examples/assets/read-data.js Normal file
View File

@ -0,0 +1,6 @@
const fs = require('node:fs');
const data = fs.readFileSync("examples/assets/jq_data.json");
const items = JSON.parse(data);
const output = items.map((item) => item:commit:committer:name);
console.log(output)

19
examples/async.ds Normal file
View File

@ -0,0 +1,19 @@
create_random_numbers = (count <int>) <none> {
numbers = []
while length(numbers) < count {
numbers += random_integer()
}
output("Made " + length(numbers) + " numbers.")
}
output("This will print first.")
async {
create_random_numbers(1000)
create_random_numbers(100)
create_random_numbers(10)
}
output("This will print last.")

21
examples/async_count.ds
View File

@ -1,21 +0,0 @@
count_slowly = fn (
multiplier: int,
) {
i = 0
while i < 10 {
sleep_time = i * multiplier;
thread.sleep(sleep_time)
thread.write_line(i as str)
i += 1
}
}
async {
count_slowly(50)
count_slowly(100)
count_slowly(200)
count_slowly(250)
}

11
examples/async_download.ds Normal file
View File

@ -0,0 +1,11 @@
cast = download("https://api.sampleapis.com/futurama/cast")
characters = download("https://api.sampleapis.com/futurama/characters")
episodes = download("https://api.sampleapis.com/futurama/episodes")
async {
cast_len = length(from_json(cast))
characters_len = length(from_json(characters))
episodes_len = length(from_json(episodes))
}
output ([cast_len, characters_len, episodes_len])

54
examples/clue_solver.ds Normal file
View File

@ -0,0 +1,54 @@
cards = {
rooms = ['Library' 'Kitchen' 'Conservatory']
suspects = ['White' 'Green' 'Scarlett']
weapons = ['Rope' 'Lead_Pipe' 'Knife']
}
is_ready_to_solve = (cards <map>) <bool> {
(length(cards:suspects) == 1)
&& (length(cards:rooms) == 1)
&& (length(cards:weapons) == 1)
}
remove_card = (cards <map>, opponent_card <str>) <none> {
cards:rooms -= opponent_card
cards:suspects -= opponent_card
cards:weapons -= opponent_card
}
make_guess = (cards <map>, current_room <str>) <none> {
if is_ready_to_solve(cards) {
output(
'I accuse '
+ cards:suspects:0
+ ' in the '
+ cards:rooms:0
+ ' with the '
+ cards:weapons:0
+ '!'
)
} else {
output(
'I question '
+ random(cards:suspects)
+ ' in the '
+ current_room
+ ' with the '
+ random(cards:weapons)
+ '.'
)
}
}
take_turn = (cards <map>, opponent_card <str>, current_room <str>) <none> {
remove_card(cards opponent_card)
make_guess(cards current_room)
}
take_turn(cards 'Rope' 'Kitchen')
take_turn(cards 'Library' 'Kitchen')
take_turn(cards 'Conservatory' 'Kitchen')
take_turn(cards 'White' 'Kitchen')
take_turn(cards 'Green' 'Kitchen')
take_turn(cards 'Knife' 'Kitchen')

5
examples/count.ds
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@ -1,5 +0,0 @@
let mut i = 0;
while i < 10000 {
i += 1;
}

9
examples/download.ds Normal file
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@ -0,0 +1,9 @@
cast = (download "https://api.sampleapis.com/futurama/cast")
characters = (download "https://api.sampleapis.com/futurama/characters")
episodes = (download "https://api.sampleapis.com/futurama/episodes")
cast_len = (length (from_json cast))
characters_len = (length (from_json characters))
episodes_len = (length (from_json episodes))
(output [cast_len, characters_len, episodes_len])

10
examples/fetch.ds Normal file
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@ -0,0 +1,10 @@
raw_data = download("https://api.sampleapis.com/futurama/cast")
cast_data = from_json(raw_data)
names = []
for cast_member in cast_data {
names += cast_member:name
}
assert_equal("Billy West", names:0)

13
examples/fibonacci.ds
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@ -1,8 +1,9 @@
fn fib (n: int) -> int {
if n <= 0 { return 0 }
if n == 1 { return 1 }
fib(n - 1) + fib(n - 2)
fib = (i <int>) <int> {
if i <= 1 {
1
} else {
fib(i - 1) + fib(i - 2)
}
}
write_line(fib(25))
fib(8)

24
examples/fizzbuzz.ds
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@ -1,20 +1,18 @@
let mut count = 1
count = 1
while count <= 15 {
let divides_by_3 = count % 3 == 0
let divides_by_5 = count % 5 == 0
divides_by_3 = count % 3 == 0
divides_by_5 = count % 5 == 0
let output = if divides_by_3 && divides_by_5 {
"fizzbuzz"
} else if divides_by_3 {
"fizz"
if divides_by_3 && divides_by_5 {
output('fizzbuzz')
} else if divides_by_3 {
output('fizz')
} else if divides_by_5 {
"buzz"
} else {
to_string(count)
output('buzz')
} else {
output(count)
}
write_line(output)
count += 1
}

6
examples/for_loop.ds Normal file
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@ -0,0 +1,6 @@
list = [1 2 3]
for i in list {
i += 1
output(i)
}

19
examples/guessing_game.ds
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@ -1,19 +0,0 @@
write_line("Guess the number.")
let secret_number = random(0..100);
loop {
write_line("Input your guess.")
let input = io.read_line();
let guess = int.parse(input);
if guess < secret_number {
io.write_line("Too low!")
} else if guess > secret_number {
io.write_line("Too high!")
} else {
io.write_line("You win!")
break
}
}

7
examples/hello_world.ds
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@ -1,6 +1 @@
write_line("Hello, world!")
write_line("Enter your name...")
let name = read_line()
write_line("Hello " + name + "!")
output('Hello, world!')

12
examples/jq_data.ds Normal file
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@ -0,0 +1,12 @@
data = from_json(read('examples/assets/jq_data.json'))
new_data = []
for commit_data in data {
new_data += {
message = commit_data:commit:message
name = commit_data:commit:committer:name
}
}
new_data

4
examples/json_length.ds
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@ -1,4 +0,0 @@
input = fs.read_file('examples/assets/data.json')
data = json.parse(input)
length(data)

9
examples/list.ds Normal file
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@ -0,0 +1,9 @@
numbers = [1, 2, 3]
x = numbers:0
y = numbers:1
z = numbers:2
assert_equal(x + y, z)
numbers

11
examples/map.ds Normal file
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@ -0,0 +1,11 @@
dictionary = {
dust = "awesome"
answer = 42
}
output(
'Dust is '
+ dictionary:dust
+ '! The answer is '
+ dictionary:answer
)

12
examples/match.ds Normal file
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@ -0,0 +1,12 @@
foo_or_bar = match (random_boolean) {
true => "foo"
false => "bar"
}
num = match (random_integer) {
1 => "one",
2 => { "two" },
* => "neither",
}
[foo_or_bar, num]

22
examples/option.ds Normal file
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@ -0,0 +1,22 @@
create_user = (fn email <str>, name <option(str)>) <map> {
{
email = email
username = (either_or name email)
}
}
(assert_equal
{
email = "bob@example.com"
username = "bob"
},
(create_user "bob@example.com" some("bob"))
)
(assert_equal
{
email = "sue@example.com"
username = "sue@example.com"
},
(create_user "sue@example.com" none)
)

13
examples/random.ds Normal file
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@ -0,0 +1,13 @@
stuff = [
random_integer()
random_integer()
random_integer()
random_float()
random_float()
random_float()
random_boolean()
random_boolean()
random_boolean()
]
random(stuff)

19
examples/sea_creatures.ds Normal file
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@ -0,0 +1,19 @@
raw_data = read('examples/assets/seaCreatures.json')
sea_creatures = from_json(raw_data)
data = {
creatures = []
total_clams = 0
dolphin_clams = 0
}
for creature in sea_creatures {
data:creatures += creature:name
data:total_clams += creature:clams
if creature:type == 'dolphin' {
data:dolphin_clams += creature:clams
}
}
data

20
examples/type_inference.ds
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@ -1,20 +0,0 @@
// This function returns its argument.
foo = fn <T>(x: T) -> T { x }
// Use turbofish to supply type information.
bar = foo::<str>("hi")
// Use type annotation
baz: str = foo("hi")
// The `json.parse` function takes a string and returns the specified type
// Use turbofish
x = json.parse::<int>("1")
// Use type annotation
x: int = json.parse("1")
x: int = {
json.parse("1")
}

10
examples/variables.ds Normal file
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@ -0,0 +1,10 @@
x = 1
y = "hello dust!"
z = 42.0
list = [3, 2, x]
big_list = [x, y, z, list]
foo = {
x = "bar"
y = 42
z = 0
}

6
examples/while_loop.ds Normal file
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@ -0,0 +1,6 @@
i = 0
while i < 10 {
output(i)
i += 1
}

13
examples/yield.ds Normal file
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@ -0,0 +1,13 @@
add_one = (numbers <[int]>) <[int]> {
new_numbers = []
for number in numbers {
new_numbers += number + 1
}
new_numbers
}
foo = [1, 2, 3] -> add_one
assert_equal([2 3 4] foo)

17
scripts/bench.fish Executable file
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@ -0,0 +1,17 @@
#!/usr/bin/fish
# This script is has the following prerequisites (aside from fish):
# - hyperfine
# - dust (can be installed with "cargo install dust-lang")
# - jq
# - nodejs
# - nushell
# - dielectron.json (can be downloaded from https://opendata.cern.ch/record/304)
hyperfine \
--shell none \
--parameter-list data_path examples/assets/seaCreatures.json,examples/assets/jq_data.json,dielectron.json \
--warmup 3 \
"dust -c 'length(from_json(input))' -p {data_path}" \
"jq 'length' {data_path}" \
"node --eval \"require('node:fs').readFile('{data_path}', (err, data)=>{console.log(JSON.parse(data).length)})\"" \
"nu -c 'open {data_path} | length'"

8
scripts/build_debug.fish Executable file
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@ -0,0 +1,8 @@
#!/usr/bin/fish
# Build the project in debug mode.
cd tree-sitter-dust/
tree-sitter generate --debug-build --no-bindings
cd ..
cargo build

8
scripts/build_release.fish Executable file
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@ -0,0 +1,8 @@
#!/bin/fish
# Build the project in release mode.
cd tree-sitter-dust/
tree-sitter generate --no-bindings
cd ..
cargo build --release

9
scripts/test.fish Executable file
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@ -0,0 +1,9 @@
#!/usr/bin/fish
# Build the project in debug mode.
cd tree-sitter-dust/
tree-sitter generate --debug-build --no-bindings
tree-sitter test
cd ..
cargo test

152
src/abstract_tree/assignment.rs Normal file
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use serde::{Deserialize, Serialize};
use tree_sitter::Node;
use crate::{AbstractTree, Error, Identifier, Map, Result, Statement, Type, TypeDefinition, Value};
#[derive(Debug, Clone, Serialize, Deserialize, Eq, PartialEq, PartialOrd, Ord)]
pub struct Assignment {
identifier: Identifier,
type_definition: Option<TypeDefinition>,
operator: AssignmentOperator,
statement: Statement,
}
#[derive(Debug, Clone, Serialize, Deserialize, Eq, PartialEq, PartialOrd, Ord)]
pub enum AssignmentOperator {
Equal,
PlusEqual,
MinusEqual,
}
impl AbstractTree for Assignment {
fn from_syntax_node(source: &str, node: Node, context: &Map) -> Result<Self> {
Error::expect_syntax_node(source, "assignment", node)?;
let child_count = node.child_count();
let identifier_node = node.child(0).unwrap();
let identifier = Identifier::from_syntax_node(source, identifier_node, context)?;
let identifier_type = identifier.expected_type(context)?;
let type_node = node.child(1).unwrap();
let type_definition = if type_node.kind() == "type_definition" {
Some(TypeDefinition::from_syntax_node(
source, type_node, context,
)?)
} else {
None
};
let operator_node = node.child(child_count - 2).unwrap().child(0).unwrap();
let operator = match operator_node.kind() {
"=" => AssignmentOperator::Equal,
"+=" => AssignmentOperator::PlusEqual,
"-=" => AssignmentOperator::MinusEqual,
_ => {
return Err(Error::UnexpectedSyntaxNode {
expected: "=, += or -=".to_string(),
actual: operator_node.kind().to_string(),
location: operator_node.start_position(),
relevant_source: source[operator_node.byte_range()].to_string(),
})
}
};
let statement_node = node.child(child_count - 1).unwrap();
let statement = Statement::from_syntax_node(source, statement_node, context)?;
let statement_type = statement.expected_type(context)?;
if let Some(type_definition) = &type_definition {
match operator {
AssignmentOperator::Equal => {
type_definition
.inner()
.check(&statement_type)
.map_err(|error| error.at_node(statement_node, source))?;
}
AssignmentOperator::PlusEqual => {
if let Type::List(item_type) = type_definition.inner() {
item_type
.check(&statement_type)
.map_err(|error| error.at_node(statement_node, source))?;
} else {
type_definition
.inner()
.check(&identifier_type)
.map_err(|error| error.at_node(identifier_node, source))?;
}
}
AssignmentOperator::MinusEqual => todo!(),
}
} else {
match operator {
AssignmentOperator::Equal => {}
AssignmentOperator::PlusEqual => {
if let Type::List(item_type) = identifier_type {
println!("{item_type} {statement_type}");
item_type
.check(&statement_type)
.map_err(|error| error.at_node(statement_node, source))?;
}
}
AssignmentOperator::MinusEqual => todo!(),
}
}
let variable_key = identifier.inner().clone();
let variable_type = if let Some(definition) = &type_definition {
definition.inner().clone()
} else if let Some((_, r#type)) = context.variables()?.get(identifier.inner()) {
r#type.clone()
} else {
statement_type
};
context.set(variable_key, Value::none(), Some(variable_type))?;
Ok(Assignment {
identifier,
type_definition,
operator,
statement,
})
}
fn run(&self, source: &str, context: &Map) -> Result<Value> {
let key = self.identifier.inner();
let value = self.statement.run(source, context)?;
let new_value = match self.operator {
AssignmentOperator::PlusEqual => {
if let Some((mut previous_value, _)) = context.variables()?.get(key).cloned() {
previous_value += value;
previous_value
} else {
return Err(Error::VariableIdentifierNotFound(key.clone()));
}
}
AssignmentOperator::MinusEqual => {
if let Some((mut previous_value, _)) = context.variables()?.get(key).cloned() {
previous_value -= value;
previous_value
} else {
return Err(Error::VariableIdentifierNotFound(key.clone()));
}
}
AssignmentOperator::Equal => value,
};
if let Some(type_defintion) = &self.type_definition {
context.set(key.clone(), new_value, Some(type_defintion.inner().clone()))?;
} else {
context.set(key.clone(), new_value, None)?;
}
Ok(Value::none())
}
fn expected_type(&self, _context: &Map) -> Result<Type> {
Ok(Type::None)
}
}

109
src/abstract_tree/block.rs Normal file
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use std::sync::RwLock;
use rayon::prelude::*;
use serde::{Deserialize, Serialize};
use tree_sitter::Node;
use crate::{AbstractTree, Error, Map, Result, Statement, Type, Value};
/// Abstract representation of a block.
///
/// A block is almost identical to the root except that it must have curly
/// braces and can optionally be asynchronous. A block evaluates to the value of
/// its final statement but an async block will short-circuit if a statement
/// results in an error. Note that this will be the first statement to encounter
/// an error at runtime, not necessarilly the first statement as they are
/// written.
#[derive(Debug, Clone, Serialize, Deserialize, Eq, PartialEq, PartialOrd, Ord)]
pub struct Block {
is_async: bool,
statements: Vec<Statement>,
}
impl AbstractTree for Block {
fn from_syntax_node(source: &str, node: Node, context: &Map) -> Result<Self> {
Error::expect_syntax_node(source, "block", node)?;
let first_child = node.child(0).unwrap();
let is_async = first_child.kind() == "async";
let statement_count = if is_async {
node.child_count() - 3
} else {
node.child_count() - 2
};
let mut statements = Vec::with_capacity(statement_count);
for index in 1..node.child_count() - 1 {
let child_node = node.child(index).unwrap();
if child_node.kind() == "statement" {
let statement = Statement::from_syntax_node(source, child_node, context)?;
statements.push(statement);
}
}
Ok(Block {
is_async,
statements,
})
}
fn run(&self, source: &str, context: &Map) -> Result<Value> {
if self.is_async {
let statements = &self.statements;
let final_result = RwLock::new(Ok(Value::none()));
statements
.into_par_iter()
.enumerate()
.find_map_first(|(index, statement)| {
let result = statement.run(source, context);
let is_last_statement = index == statements.len() - 1;
let is_return_statement = if let Statement::Return(_) = statement {
true
} else {
false
};
if is_return_statement || result.is_err() {
Some(result)
} else if is_last_statement {
let get_write_lock = final_result.write();
match get_write_lock {
Ok(mut final_result) => {
*final_result = result;
None
}
Err(error) => Some(Err(error.into())),
}
} else {
None
}
})
.unwrap_or(final_result.into_inner()?)
} else {
let mut prev_result = None;
for statement in &self.statements {
if let Statement::Return(inner_statement) = statement {
return inner_statement.run(source, context);
}
prev_result = Some(statement.run(source, context));
}
prev_result.unwrap_or(Ok(Value::none()))
}
}
fn expected_type(&self, context: &Map) -> Result<Type> {
if let Some(statement) = self.statements.last() {
statement.expected_type(context)
} else {
Ok(Type::None)
}
}
}

91
src/abstract_tree/expression.rs Normal file
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@ -0,0 +1,91 @@
use serde::{Deserialize, Serialize};
use tree_sitter::Node;
use crate::{
value_node::ValueNode, AbstractTree, Error, Identifier, Index, Map, Result, Type, Value, Yield,
};
use super::{function_call::FunctionCall, logic::Logic, math::Math};
/// Abstract representation of an expression statement.
///
/// Unlike statements, which can involve complex logic, an expression is
/// expected to evaluate to a value. However, an expression can still contain
/// nested statements and may evaluate to an empty value.
#[derive(Debug, Clone, Serialize, Deserialize, Eq, PartialEq, PartialOrd, Ord)]
pub enum Expression {
Value(ValueNode),
Identifier(Identifier),
Index(Box<Index>),
Math(Box<Math>),
Logic(Box<Logic>),
FunctionCall(Box<FunctionCall>),
Yield(Box<Yield>),
}
impl AbstractTree for Expression {
fn from_syntax_node(source: &str, node: Node, context: &Map) -> Result<Self> {
Error::expect_syntax_node(source, "expression", node)?;
let child = if node.child(0).unwrap().is_named() {
node.child(0).unwrap()
} else {
node.child(1).unwrap()
};
let expression = match child.kind() {
"value" => Expression::Value(ValueNode::from_syntax_node(source, child, context)?),
"identifier" => {
Expression::Identifier(Identifier::from_syntax_node(source, child, context)?)
}
"index" => {
Expression::Index(Box::new(Index::from_syntax_node(source, child, context)?))
}
"math" => Expression::Math(Box::new(Math::from_syntax_node(source, child, context)?)),
"logic" => {
Expression::Logic(Box::new(Logic::from_syntax_node(source, child, context)?))
}
"function_call" => Expression::FunctionCall(Box::new(FunctionCall::from_syntax_node(
source, child, context,
)?)),
"yield" => {
Expression::Yield(Box::new(Yield::from_syntax_node(source, child, context)?))
}
_ => {
return Err(Error::UnexpectedSyntaxNode {
expected: "value_node, identifier, index, math, logic, function_call or yield"
.to_string(),
actual: child.kind().to_string(),
location: child.start_position(),
relevant_source: source[child.byte_range()].to_string(),
})
}
};
Ok(expression)
}
fn run(&self, source: &str, context: &Map) -> Result<Value> {
match self {
Expression::Value(value_node) => value_node.run(source, context),
Expression::Identifier(identifier) => identifier.run(source, context),
Expression::Math(math) => math.run(source, context),
Expression::Logic(logic) => logic.run(source, context),
Expression::FunctionCall(function_call) => function_call.run(source, context),
Expression::Index(index) => index.run(source, context),
Expression::Yield(r#yield) => r#yield.run(source, context),
}
}
fn expected_type(&self, context: &Map) -> Result<Type> {
match self {
Expression::Value(value_node) => value_node.expected_type(context),
Expression::Identifier(identifier) => identifier.expected_type(context),
Expression::Math(math) => math.expected_type(context),
Expression::Logic(logic) => logic.expected_type(context),
Expression::FunctionCall(function_call) => function_call.expected_type(context),
Expression::Index(index) => index.expected_type(context),
Expression::Yield(r#yield) => r#yield.expected_type(context),
}
}
}

80
src/abstract_tree/for.rs Normal file
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use rayon::prelude::*;
use serde::{Deserialize, Serialize};
use tree_sitter::Node;
use crate::{AbstractTree, Block, Error, Expression, Identifier, Map, Result, Type, Value};
/// Abstract representation of a for loop statement.
#[derive(Debug, Clone, Serialize, Deserialize, Eq, PartialEq, PartialOrd, Ord)]
pub struct For {
is_async: bool,
item_id: Identifier,
collection: Expression,
block: Block,
}
impl AbstractTree for For {
fn from_syntax_node(source: &str, node: Node, context: &Map) -> Result<Self> {
Error::expect_syntax_node(source, "for", node)?;
let for_node = node.child(0).unwrap();
let is_async = match for_node.kind() {
"for" => false,
"async for" => true,
_ => {
return Err(Error::UnexpectedSyntaxNode {
expected: "for or async for".to_string(),
actual: for_node.kind().to_string(),
location: for_node.start_position(),
relevant_source: source[for_node.byte_range()].to_string(),
})
}
};
let identifier_node = node.child(1).unwrap();
let identifier = Identifier::from_syntax_node(source, identifier_node, context)?;
let expression_node = node.child(3).unwrap();
let expression = Expression::from_syntax_node(source, expression_node, context)?;
let item_node = node.child(4).unwrap();
let item = Block::from_syntax_node(source, item_node, context)?;
Ok(For {
is_async,
item_id: identifier,
collection: expression,
block: item,
})
}
fn run(&self, source: &str, context: &Map) -> Result<Value> {
let expression_run = self.collection.run(source, context)?;
let values = expression_run.as_list()?.items();
let key = self.item_id.inner();
if self.is_async {
values.par_iter().try_for_each(|value| {
let iter_context = Map::clone_from(context)?;
iter_context.set(key.clone(), value.clone(), None)?;
self.block.run(source, &iter_context).map(|_value| ())
})?;
} else {
let loop_context = Map::clone_from(context)?;
for value in values.iter() {
loop_context.set(key.clone(), value.clone(), None)?;
self.block.run(source, &loop_context)?;
}
}
Ok(Value::none())
}
fn expected_type(&self, _context: &Map) -> Result<Type> {
Ok(Type::None)
}
}

164
src/abstract_tree/function_call.rs Normal file
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use serde::{Deserialize, Serialize};
use tree_sitter::Node;
use crate::{
AbstractTree, Error, Expression, FunctionExpression, Map, Result, Type, Value,
BUILT_IN_FUNCTIONS,
};
#[derive(Debug, Clone, Serialize, Deserialize, Eq, PartialEq, PartialOrd, Ord)]
pub struct FunctionCall {
function_expression: FunctionExpression,
arguments: Vec<Expression>,
}
impl FunctionCall {
pub fn new(function_expression: FunctionExpression, arguments: Vec<Expression>) -> Self {
Self {
function_expression,
arguments,
}
}
}
impl AbstractTree for FunctionCall {
fn from_syntax_node(source: &str, node: Node, context: &Map) -> Result<Self> {
Error::expect_syntax_node(source, "function_call", node)?;
let function_node = node.child(0).unwrap();
let function_expression =
FunctionExpression::from_syntax_node(source, function_node, context)?;
let function_type = function_expression.expected_type(context)?;
let mut minimum_parameter_count = 0;
let mut arguments = Vec::new();
for index in 2..node.child_count() - 1 {
let child = node.child(index).unwrap();
if child.is_named() {
let expression = Expression::from_syntax_node(source, child, context)?;
let expression_type = expression.expected_type(context)?;
let argument_index = arguments.len();
if let Type::Function {
parameter_types, ..
} = &function_type
{
if let Some(r#type) = parameter_types.get(argument_index) {
if let Type::Option(_) = r#type {
} else {
minimum_parameter_count += 1;
}
r#type
.check(&expression_type)
.map_err(|error| error.at_node(child, source))?;
}
}
arguments.push(expression);
}
}
if let Type::Function {
parameter_types: _, ..
} = &function_type
{
if arguments.len() < minimum_parameter_count {
return Err(Error::ExpectedFunctionArgumentMinimum {
source: source[function_node.byte_range()].to_string(),
minumum_expected: minimum_parameter_count,
actual: arguments.len(),
});
}
}
Ok(FunctionCall {
function_expression,
arguments,
})
}
fn run(&self, source: &str, context: &Map) -> Result<Value> {
let value = match &self.function_expression {
FunctionExpression::Identifier(identifier) => {
let key = identifier.inner();
for built_in_function in BUILT_IN_FUNCTIONS {
if key == built_in_function.name() {
let mut arguments = Vec::with_capacity(self.arguments.len());
for expression in &self.arguments {
let value = expression.run(source, context)?;
arguments.push(value);
}
return built_in_function.run(&arguments, context);
}
}
let variables = context.variables()?;
if let Some((value, _)) = variables.get(key) {
value.clone()
} else {
return Err(Error::FunctionIdentifierNotFound(
identifier.inner().clone(),
));
}
}
FunctionExpression::FunctionCall(function_call) => {
function_call.run(source, context)?
}
FunctionExpression::Value(value_node) => value_node.run(source, context)?,
FunctionExpression::Index(index) => index.run(source, context)?,
FunctionExpression::Yield(r#yield) => r#yield.run(source, context)?,
};
let mut arguments = Vec::with_capacity(self.arguments.len());
for expression in &self.arguments {
let value = expression.run(source, context)?;
arguments.push(value);
}
value.as_function()?.call(&arguments, source, context)
}
fn expected_type(&self, context: &Map) -> Result<Type> {
match &self.function_expression {
FunctionExpression::Identifier(identifier) => {
for built_in_function in BUILT_IN_FUNCTIONS {
if identifier.inner() == built_in_function.name() {
if let Type::Function {
parameter_types: _,
return_type,
} = built_in_function.r#type()
{
return Ok(*return_type);
}
}
}
let identifier_type = identifier.expected_type(context)?;
if let Type::Function {
parameter_types: _,
return_type,
} = &identifier_type
{
Ok(*return_type.clone())
} else {
Ok(identifier_type)
}
}
FunctionExpression::FunctionCall(function_call) => function_call.expected_type(context),
FunctionExpression::Value(value_node) => value_node.expected_type(context),
FunctionExpression::Index(index) => index.expected_type(context),
FunctionExpression::Yield(r#yield) => r#yield.expected_type(context),
}
}
}

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use serde::{Deserialize, Serialize};
use tree_sitter::Node;
use crate::{
AbstractTree, Error, FunctionCall, Identifier, Index, Map, Result, Type, Value, ValueNode,
Yield,
};
#[derive(Debug, Clone, Serialize, Deserialize, Eq, PartialEq, PartialOrd, Ord)]
pub enum FunctionExpression {
Identifier(Identifier),
FunctionCall(Box<FunctionCall>),
Value(ValueNode),
Index(Index),
Yield(Box<Yield>),
}
impl AbstractTree for FunctionExpression {
fn from_syntax_node(source: &str, node: Node, context: &Map) -> Result<Self> {
Error::expect_syntax_node(source, "function_expression", node)?;
let child = node.child(0).unwrap();
let function_expression = match child.kind() {
"identifier" => FunctionExpression::Identifier(Identifier::from_syntax_node(
source, child, context,
)?),
"function_call" => FunctionExpression::FunctionCall(Box::new(
FunctionCall::from_syntax_node(source, child, context)?,
)),
"value" => {
FunctionExpression::Value(ValueNode::from_syntax_node(source, child, context)?)
}
"index" => FunctionExpression::Index(Index::from_syntax_node(source, child, context)?),
"yield" => FunctionExpression::Yield(Box::new(Yield::from_syntax_node(
source, child, context,
)?)),
_ => {
return Err(Error::UnexpectedSyntaxNode {
expected: "identifier, function call, value or index".to_string(),
actual: child.kind().to_string(),
location: child.start_position(),
relevant_source: source[child.byte_range()].to_string(),
})
}
};
Ok(function_expression)
}
fn run(&self, source: &str, context: &Map) -> Result<Value> {
match self {
FunctionExpression::Identifier(identifier) => identifier.run(source, context),
FunctionExpression::FunctionCall(function_call) => function_call.run(source, context),
FunctionExpression::Value(value_node) => value_node.run(source, context),
FunctionExpression::Index(index) => index.run(source, context),
FunctionExpression::Yield(r#yield) => r#yield.run(source, context),
}
}
fn expected_type(&self, context: &Map) -> Result<Type> {
match self {
FunctionExpression::Identifier(identifier) => identifier.expected_type(context),
FunctionExpression::FunctionCall(function_call) => function_call.expected_type(context),
FunctionExpression::Value(value_node) => value_node.expected_type(context),
FunctionExpression::Index(index) => index.expected_type(context),
FunctionExpression::Yield(r#yield) => r#yield.expected_type(context),
}
}
}

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use serde::{Deserialize, Serialize};
use tree_sitter::Node;
use crate::{AbstractTree, Error, Map, Result, Type, Value, BUILT_IN_FUNCTIONS};
/// A string by which a variable is known to a context.
///
/// Every variable is a key-value pair. An identifier holds the key part of that
/// pair. Its inner value can be used to retrieve a Value instance from a Map.
#[derive(Debug, Clone, Serialize, Deserialize, Eq, PartialEq, PartialOrd, Ord)]
pub struct Identifier(String);
impl Identifier {
pub fn new(inner: String) -> Self {
Identifier(inner)
}
pub fn take_inner(self) -> String {
self.0
}
pub fn inner(&self) -> &String {
&self.0
}
}
impl AbstractTree for Identifier {
fn from_syntax_node(source: &str, node: Node, _context: &Map) -> Result<Self> {
Error::expect_syntax_node(source, "identifier", node)?;
let text = &source[node.byte_range()];
if text.is_empty() {
println!("{node:?}");
}
debug_assert!(!text.is_empty());
Ok(Identifier(text.to_string()))
}
fn run(&self, _source: &str, context: &Map) -> Result<Value> {
if let Some((value, _)) = context.variables()?.get(&self.0) {
Ok(value.clone())
} else {
Err(Error::VariableIdentifierNotFound(self.inner().clone()))
}
}
fn expected_type(&self, context: &Map) -> Result<Type> {
if let Some((_value, r#type)) = context.variables()?.get(&self.0) {
Ok(r#type.clone())
} else {
for built_in_function in BUILT_IN_FUNCTIONS {
if self.0 == built_in_function.name() {
return Ok(built_in_function.r#type());
}
}
Ok(Type::None)
}
}
}

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use serde::{Deserialize, Serialize};
use tree_sitter::Node;
use crate::{AbstractTree, Block, Expression, Map, Result, Type, Value};
#[derive(Debug, Clone, Serialize, Deserialize, Eq, PartialEq, PartialOrd, Ord)]
pub struct IfElse {
if_expression: Expression,
if_block: Block,
else_if_expressions: Vec<Expression>,
else_if_blocks: Vec<Block>,
else_block: Option<Block>,
}
impl AbstractTree for IfElse {
fn from_syntax_node(source: &str, node: Node, context: &Map) -> Result<Self> {
let if_expression_node = node.child(0).unwrap().child(1).unwrap();
let if_expression = Expression::from_syntax_node(source, if_expression_node, context)?;
let if_block_node = node.child(0).unwrap().child(2).unwrap();
let if_block = Block::from_syntax_node(source, if_block_node, context)?;
let child_count = node.child_count();
let mut else_if_expressions = Vec::new();
let mut else_if_blocks = Vec::new();
let mut else_block = None;
for index in 1..child_count {
let child = node.child(index).unwrap();
if child.kind() == "else_if" {
let expression_node = child.child(1).unwrap();
let expression = Expression::from_syntax_node(source, expression_node, context)?;
else_if_expressions.push(expression);
let block_node = child.child(2).unwrap();
let block = Block::from_syntax_node(source, block_node, context)?;
else_if_blocks.push(block);
}
if child.kind() == "else" {
let else_node = child.child(1).unwrap();
else_block = Some(Block::from_syntax_node(source, else_node, context)?);
}
}
Ok(IfElse {
if_expression,
if_block,
else_if_expressions,
else_if_blocks,
else_block,
})
}
fn run(&self, source: &str, context: &Map) -> Result<Value> {
let if_boolean = self.if_expression.run(source, context)?.as_boolean()?;
if if_boolean {
self.if_block.run(source, context)
} else {
let expressions = &self.else_if_expressions;
for (index, expression) in expressions.iter().enumerate() {
let if_boolean = expression.run(source, context)?.as_boolean()?;
if if_boolean {
let block = self.else_if_blocks.get(index).unwrap();
return block.run(source, context);
}
}
if let Some(block) = &self.else_block {
block.run(source, context)
} else {
Ok(Value::none())
}
}
}
fn expected_type(&self, context: &Map) -> Result<Type> {
self.if_block.expected_type(context)
}
}

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use serde::{Deserialize, Serialize};
use tree_sitter::Node;
use crate::{AbstractTree, Error, Expression, List, Map, Result, Type, Value};
/// Abstract representation of an index expression.
///
/// An index is a means of accessing values stored in list, maps and strings.
#[derive(Debug, Clone, Serialize, Deserialize, Eq, PartialEq, PartialOrd, Ord)]
pub struct Index {
pub collection: Expression,
pub index: Expression,
pub index_end: Option<Expression>,
}
impl AbstractTree for Index {
fn from_syntax_node(source: &str, node: Node, context: &Map) -> Result<Self> {
Error::expect_syntax_node(source, "index", node)?;
let collection_node = node.child(0).unwrap();
let collection = Expression::from_syntax_node(source, collection_node, context)?;
let index_node = node.child(2).unwrap();
let index = Expression::from_syntax_node(source, index_node, context)?;
let index_end_node = node.child(4);
let index_end = if let Some(index_end_node) = index_end_node {
Some(Expression::from_syntax_node(
source,
index_end_node,
context,
)?)
} else {
None
};
Ok(Index {
collection,
index,
index_end,
})
}
fn run(&self, source: &str, context: &Map) -> Result<Value> {
let collection = self.collection.run(source, context)?;
match collection {
Value::List(list) => {
let index = self.index.run(source, context)?.as_integer()? as usize;
let item = if let Some(index_end) = &self.index_end {
let index_end = index_end.run(source, context)?.as_integer()? as usize;
let sublist = list.items()[index..=index_end].to_vec();
Value::List(List::with_items(sublist))
} else {
list.items().get(index).cloned().unwrap_or_default()
};
Ok(item)
}
Value::Map(map) => {
let value = if let Expression::Identifier(identifier) = &self.index {
let key = identifier.inner();
map.variables()?
.get(key)
.map(|(value, _)| value.clone())
.unwrap_or_default()
} else {
let value = self.index.run(source, context)?;
let key = value.as_string()?;
map.variables()?
.get(key)
.map(|(value, _)| value.clone())
.unwrap_or_default()
};
Ok(value)
}
Value::String(string) => {
let index = self.index.run(source, context)?.as_integer()? as usize;
let item = string.chars().nth(index).unwrap_or_default();
Ok(Value::String(item.to_string()))
}
_ => Err(Error::ExpectedCollection { actual: collection }),
}
}
fn expected_type(&self, context: &Map) -> Result<Type> {
match self.collection.expected_type(context)? {
Type::List(item_type) => Ok(*item_type.clone()),
Type::Map => Ok(Type::Any),
Type::None => Ok(Type::None),
_ => todo!(),
}
}
}

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use serde::{Deserialize, Serialize};
use tree_sitter::Node;
use crate::{AbstractTree, Error, Index, Map, Result, Statement, Type, Value};
#[derive(Debug, Clone, Serialize, Deserialize, Eq, PartialEq, PartialOrd, Ord)]
pub struct IndexAssignment {
index: Index,
operator: AssignmentOperator,
statement: Statement,
}
#[derive(Debug, Clone, Serialize, Deserialize, Eq, PartialEq, PartialOrd, Ord)]
pub enum AssignmentOperator {
Equal,
PlusEqual,
MinusEqual,
}
impl AbstractTree for IndexAssignment {
fn from_syntax_node(source: &str, node: Node, context: &Map) -> Result<Self> {
Error::expect_syntax_node(source, "index_assignment", node)?;
let index_node = node.child(0).unwrap();
let index = Index::from_syntax_node(source, index_node, context)?;
let operator_node = node.child(1).unwrap().child(0).unwrap();
let operator = match operator_node.kind() {
"=" => AssignmentOperator::Equal,
"+=" => AssignmentOperator::PlusEqual,
"-=" => AssignmentOperator::MinusEqual,
_ => {
return Err(Error::UnexpectedSyntaxNode {
expected: "=, += or -=".to_string(),
actual: operator_node.kind().to_string(),
location: operator_node.start_position(),
relevant_source: source[operator_node.byte_range()].to_string(),
})
}
};
let statement_node = node.child(2).unwrap();
let statement = Statement::from_syntax_node(source, statement_node, context)?;
Ok(IndexAssignment {
index,
operator,
statement,
})
}
fn run(&self, source: &str, context: &Map) -> Result<Value> {
let index_collection = self.index.collection.run(source, context)?;
let index_context = index_collection.as_map().unwrap_or(context);
let index_key = if let crate::Expression::Identifier(identifier) = &self.index.index {
identifier.inner()
} else {
return Err(Error::VariableIdentifierNotFound(
self.index.index.run(source, context)?.to_string(),
));
};
let value = self.statement.run(source, context)?;
let new_value = match self.operator {
AssignmentOperator::PlusEqual => {
if let Some((mut previous_value, _)) =
index_context.variables()?.get(index_key).cloned()
{
previous_value += value;
previous_value
} else {
Value::none()
}
}
AssignmentOperator::MinusEqual => {
if let Some((mut previous_value, _)) =
index_context.variables()?.get(index_key).cloned()
{
previous_value -= value;
previous_value
} else {
Value::none()
}
}
AssignmentOperator::Equal => value,
};
index_context.set(index_key.clone(), new_value, None)?;
Ok(Value::none())
}
fn expected_type(&self, _context: &Map) -> Result<Type> {
Ok(Type::None)
}
}

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use serde::{Deserialize, Serialize};
use tree_sitter::Node;
use crate::{AbstractTree, Error, Expression, Map, Result, Type, Value};
/// Abstract representation of a logic expression.
#[derive(Debug, Clone, Serialize, Deserialize, Eq, PartialEq, PartialOrd, Ord)]
pub struct Logic {
left: Expression,
operator: LogicOperator,
right: Expression,
}
impl AbstractTree for Logic {
fn from_syntax_node(source: &str, node: Node, context: &Map) -> Result<Self> {
Error::expect_syntax_node(source, "logic", node)?;
let first_node = node.child(0).unwrap();
let (left_node, operator_node, right_node) = {
if first_node.is_named() {
(
first_node,
node.child(1).unwrap().child(0).unwrap(),
node.child(2).unwrap(),
)
} else {
(
node.child(1).unwrap(),
node.child(2).unwrap().child(0).unwrap(),
node.child(3).unwrap(),
)
}
};
let left = Expression::from_syntax_node(source, left_node, context)?;
let operator = match operator_node.kind() {
"==" => LogicOperator::Equal,
"!=" => LogicOperator::NotEqual,
"&&" => LogicOperator::And,
"||" => LogicOperator::Or,
">" => LogicOperator::Greater,
"<" => LogicOperator::Less,
">=" => LogicOperator::GreaterOrEqual,
"<=" => LogicOperator::LessOrEqaul,
_ => {
return Err(Error::UnexpectedSyntaxNode {
expected: "==, !=, &&, ||, >, <, >= or <=".to_string(),
actual: operator_node.kind().to_string(),
location: operator_node.start_position(),
relevant_source: source[operator_node.byte_range()].to_string(),
})
}
};
let right = Expression::from_syntax_node(source, right_node, context)?;
Ok(Logic {
left,
operator,
right,
})
}
fn run(&self, source: &str, context: &Map) -> Result<Value> {
let left = self.left.run(source, context)?;
let right = self.right.run(source, context)?;
let result = match self.operator {
LogicOperator::Equal => {
if let (Ok(left_num), Ok(right_num)) = (left.as_number(), right.as_number()) {
left_num == right_num
} else {
left == right
}
}
LogicOperator::NotEqual => {
if let (Ok(left_num), Ok(right_num)) = (left.as_number(), right.as_number()) {
left_num != right_num
} else {
left != right
}
}
LogicOperator::And => left.as_boolean()? && right.as_boolean()?,
LogicOperator::Or => left.as_boolean()? || right.as_boolean()?,
LogicOperator::Greater => left > right,
LogicOperator::Less => left < right,
LogicOperator::GreaterOrEqual => left >= right,
LogicOperator::LessOrEqaul => left <= right,
};
Ok(Value::Boolean(result))
}
fn expected_type(&self, _context: &Map) -> Result<Type> {
Ok(Type::Boolean)
}
}
#[derive(Debug, Clone, Serialize, Deserialize, Eq, PartialEq, PartialOrd, Ord)]
pub enum LogicOperator {
Equal,
NotEqual,
And,
Or,
Greater,
Less,
GreaterOrEqual,
LessOrEqaul,
}

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//! Pattern matching.
//!
//! Note that this module is called "match" but is escaped as "r#match" because
//! "match" is a keyword in Rust.
use serde::{Deserialize, Serialize};
use tree_sitter::Node;
use crate::{AbstractTree, Error, Expression, Map, Result, Statement, Type, Value};
/// Abstract representation of a match statement.
#[derive(Debug, Clone, Serialize, Deserialize, Eq, PartialEq, PartialOrd, Ord)]
pub struct Match {
matcher: Expression,
options: Vec<(Expression, Statement)>,
fallback: Option<Box<Statement>>,
}
impl AbstractTree for Match {
fn from_syntax_node(source: &str, node: Node, context: &Map) -> Result<Self> {
Error::expect_syntax_node(source, "match", node)?;
let matcher_node = node.child(1).unwrap();
let matcher = Expression::from_syntax_node(source, matcher_node, context)?;
let mut options = Vec::new();
let mut previous_expression = None;
let mut next_statement_is_fallback = false;
let mut fallback = None;
for index in 2..node.child_count() {
let child = node.child(index).unwrap();
if child.kind() == "*" {
next_statement_is_fallback = true;
}
if child.kind() == "expression" {
previous_expression = Some(Expression::from_syntax_node(source, child, context)?);
}
if child.kind() == "statement" {
let statement = Statement::from_syntax_node(source, child, context)?;
if next_statement_is_fallback {
fallback = Some(Box::new(statement));
next_statement_is_fallback = false;
} else if let Some(expression) = &previous_expression {
options.push((expression.clone(), statement));
}
}
}
Ok(Match {
matcher,
options,
fallback,
})
}
fn run(&self, source: &str, context: &Map) -> Result<Value> {
let matcher_value = self.matcher.run(source, context)?;
for (expression, statement) in &self.options {
let option_value = expression.run(source, context)?;
if matcher_value == option_value {
return statement.run(source, context);
}
}
if let Some(fallback) = &self.fallback {
fallback.run(source, context)
} else {
Ok(Value::none())
}
}
fn expected_type(&self, context: &Map) -> Result<Type> {
let (_, first_statement) = self.options.first().unwrap();
first_statement.expected_type(context)
}
}

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use serde::{Deserialize, Serialize};
use tree_sitter::Node;
use crate::{AbstractTree, Error, Expression, Map, Result, Type, Value};
/// Abstract representation of a math operation.
///
/// Dust currently supports the four basic operations and the modulo (or
/// remainder) operator.
#[derive(Debug, Clone, Serialize, Deserialize, Eq, PartialEq, PartialOrd, Ord)]
pub struct Math {
left: Expression,
operator: MathOperator,
right: Expression,
}
impl AbstractTree for Math {
fn from_syntax_node(source: &str, node: Node, context: &Map) -> Result<Self> {
Error::expect_syntax_node(source, "math", node)?;
let left_node = node.child(0).unwrap();
let left = Expression::from_syntax_node(source, left_node, context)?;
let operator_node = node.child(1).unwrap().child(0).unwrap();
let operator = match operator_node.kind() {
"+" => MathOperator::Add,
"-" => MathOperator::Subtract,
"*" => MathOperator::Multiply,
"/" => MathOperator::Divide,
"%" => MathOperator::Modulo,
_ => {
return Err(Error::UnexpectedSyntaxNode {
expected: "+, -, *, / or %".to_string(),
actual: operator_node.kind().to_string(),
location: operator_node.start_position(),
relevant_source: source[operator_node.byte_range()].to_string(),
})
}
};
let right_node = node.child(2).unwrap();
let right = Expression::from_syntax_node(source, right_node, context)?;
Ok(Math {
left,
operator,
right,
})
}
fn run(&self, source: &str, context: &Map) -> Result<Value> {
let left = self.left.run(source, context)?;
let right = self.right.run(source, context)?;
let value = match self.operator {
MathOperator::Add => left + right,
MathOperator::Subtract => left - right,
MathOperator::Multiply => left * right,
MathOperator::Divide => left / right,
MathOperator::Modulo => left % right,
}?;
Ok(value)
}
fn expected_type(&self, context: &Map) -> Result<Type> {
self.left.expected_type(context)
}
}
#[derive(Debug, Clone, Serialize, Deserialize, Eq, PartialEq, PartialOrd, Ord)]
pub enum MathOperator {
Add,
Subtract,
Multiply,
Divide,
Modulo,
}

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//! Abstract, executable representations of corresponding items found in Dust
//! source code. The types that implement [AbstractTree] are inteded to be
//! created by an [Evaluator].
//!
//! When adding new lanugage features, first extend the grammar to recognize new
//! syntax nodes. Then add a new AbstractTree type using the existing types as
//! examples.
pub mod assignment;
pub mod block;
pub mod expression;
pub mod r#for;
pub mod function_call;
pub mod function_expression;
pub mod identifier;
pub mod if_else;
pub mod index;
pub mod index_assignment;
pub mod logic;
pub mod r#match;
pub mod math;
pub mod statement;
pub mod type_definition;
pub mod value_node;
pub mod r#while;
pub mod r#yield;
pub use {
assignment::*, block::*, expression::*, function_call::*, function_expression::*,
identifier::*, if_else::*, index::*, index_assignment::IndexAssignment, logic::*, math::*,
r#for::*, r#match::*, r#while::*, r#yield::*, statement::*, type_definition::*, value_node::*,
};
use tree_sitter::Node;
use crate::{Error, Map, Result, Value};
pub struct Root {
statements: Vec<Statement>,
}
impl AbstractTree for Root {
fn from_syntax_node(source: &str, node: Node, context: &Map) -> Result<Self> {
Error::expect_syntax_node(source, "root", node)?;
let statement_count = node.child_count();
let mut statements = Vec::with_capacity(statement_count);
for index in 0..statement_count {
let statement_node = node.child(index).unwrap();
let statement = Statement::from_syntax_node(source, statement_node, context)?;
statements.push(statement);
}
Ok(Root { statements })
}
fn run(&self, source: &str, context: &Map) -> Result<Value> {
let mut value = Value::none();
for statement in &self.statements {
if let Statement::Return(inner_statement) = statement {
return inner_statement.run(source, context);
} else {
value = statement.run(source, context)?;
}
}
Ok(value)
}
fn expected_type(&self, context: &Map) -> Result<Type> {
self.statements.last().unwrap().expected_type(context)
}
}
/// This trait is implemented by the Evaluator's internal types to form an
/// executable tree that resolves to a single value.
pub trait AbstractTree: Sized {
/// Interpret the syntax tree at the given node and return the abstraction.
///
/// This function is used to convert nodes in the Tree Sitter concrete
/// syntax tree into executable nodes in an abstract tree. This function is
/// where the tree should be traversed by accessing sibling and child nodes.
/// Each node in the CST should be traversed only once.
///
/// If necessary, the source code can be accessed directly by getting the
/// node's byte range.
fn from_syntax_node(source: &str, node: Node, context: &Map) -> Result<Self>;
/// Execute dust code by traversing the tree.
fn run(&self, source: &str, context: &Map) -> Result<Value>;
fn expected_type(&self, context: &Map) -> Result<Type>;
}

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use serde::{Deserialize, Serialize};
use tree_sitter::Node;
use crate::{
AbstractTree, Assignment, Block, Error, Expression, For, IfElse, IndexAssignment, Map, Match,
Result, Type, Value, While,
};
/// Abstract representation of a statement.
#[derive(Debug, Clone, Serialize, Deserialize, Eq, PartialEq, PartialOrd, Ord)]
pub enum Statement {
Assignment(Box<Assignment>),
Expression(Expression),
IfElse(Box<IfElse>),
Match(Match),
While(Box<While>),
Block(Box<Block>),
Return(Box<Statement>),
For(Box<For>),
IndexAssignment(Box<IndexAssignment>),
}
impl AbstractTree for Statement {
fn from_syntax_node(source: &str, node: Node, context: &Map) -> Result<Self> {
Error::expect_syntax_node(source, "statement", node)?;
let child = node.child(0).unwrap();
match child.kind() {
"assignment" => Ok(Statement::Assignment(Box::new(
Assignment::from_syntax_node(source, child, context)?,
))),
"expression" => Ok(Statement::Expression(Expression::from_syntax_node(
source, child, context,
)?)),
"if_else" => Ok(Statement::IfElse(Box::new(IfElse::from_syntax_node(
source, child, context,
)?))),
"while" => Ok(Statement::While(Box::new(While::from_syntax_node(
source, child, context,
)?))),
"block" => Ok(Statement::Block(Box::new(Block::from_syntax_node(
source, child, context,
)?))),
"for" => Ok(Statement::For(Box::new(For::from_syntax_node(
source, child, context,
)?))),
"index_assignment" => Ok(Statement::IndexAssignment(Box::new(
IndexAssignment::from_syntax_node(source, child, context)?,
))),
"match" => Ok(Statement::Match(Match::from_syntax_node(
source, child, context,
)?)),
"return" => {
let statement_node = child.child(1).unwrap();
Ok(Statement::Return(Box::new(Statement::from_syntax_node(source, statement_node, context)?)))
},
_ => Err(Error::UnexpectedSyntaxNode {
expected:
"assignment, index assignment, expression, block, return, if...else, while, for or match".to_string(),
actual: child.kind().to_string(),
location: child.start_position(),
relevant_source: source[child.byte_range()].to_string(),
}),
}
}
fn run(&self, source: &str, context: &Map) -> Result<Value> {
match self {
Statement::Assignment(assignment) => assignment.run(source, context),
Statement::Expression(expression) => expression.run(source, context),
Statement::IfElse(if_else) => if_else.run(source, context),
Statement::Match(r#match) => r#match.run(source, context),
Statement::While(r#while) => r#while.run(source, context),
Statement::Block(block) => block.run(source, context),
Statement::For(r#for) => r#for.run(source, context),
Statement::IndexAssignment(index_assignment) => index_assignment.run(source, context),
Statement::Return(statement) => statement.run(source, context),
}
}
fn expected_type(&self, context: &Map) -> Result<Type> {
match self {
Statement::Assignment(assignment) => assignment.expected_type(context),
Statement::Expression(expression) => expression.expected_type(context),
Statement::IfElse(if_else) => if_else.expected_type(context),
Statement::Match(r#match) => r#match.expected_type(context),
Statement::While(r#while) => r#while.expected_type(context),
Statement::Block(block) => block.expected_type(context),
Statement::For(r#for) => r#for.expected_type(context),
Statement::IndexAssignment(index_assignment) => index_assignment.expected_type(context),
Statement::Return(statement) => statement.expected_type(context),
}
}
}

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use std::fmt::{self, Display, Formatter};
use serde::{Deserialize, Serialize};
use tree_sitter::Node;
use crate::{AbstractTree, Error, Map, Result, Value};
#[derive(Debug, Clone, Serialize, Deserialize, Eq, PartialEq, PartialOrd, Ord)]
pub struct TypeDefinition {
r#type: Type,
}
impl TypeDefinition {
pub fn new(r#type: Type) -> Self {
Self { r#type }
}
pub fn inner(&self) -> &Type {
&self.r#type
}
pub fn take_inner(self) -> Type {
self.r#type
}
}
impl AbstractTree for TypeDefinition {
fn from_syntax_node(source: &str, node: Node, context: &Map) -> Result<Self> {
Error::expect_syntax_node(source, "type_definition", node)?;
let type_node = node.child(1).unwrap();
let r#type = Type::from_syntax_node(source, type_node, context)?;
Ok(TypeDefinition { r#type })
}
fn run(&self, source: &str, context: &Map) -> Result<Value> {
self.r#type.run(source, context)
}
fn expected_type(&self, context: &Map) -> Result<Type> {
self.r#type.expected_type(context)
}
}
impl Display for TypeDefinition {
fn fmt(&self, f: &mut Formatter<'_>) -> fmt::Result {
write!(f, "<{}>", self.r#type)
}
}
#[derive(Debug, Clone, Serialize, Deserialize, Eq, PartialEq, PartialOrd, Ord)]
pub enum Type {
Any,
Boolean,
Float,
Function {
parameter_types: Vec<Type>,
return_type: Box<Type>,
},
Integer,
List(Box<Type>),
Map,
None,
Number,
String,
Option(Box<Type>),
}
impl Type {
pub fn check(&self, other: &Type) -> Result<()> {
match (self, other) {
(Type::Any, _)
| (_, Type::Any)
| (Type::Boolean, Type::Boolean)
| (Type::Float, Type::Float)
| (Type::Integer, Type::Integer)
| (Type::Map, Type::Map)
| (Type::Number, Type::Number)
| (Type::Number, Type::Integer)
| (Type::Number, Type::Float)
| (Type::Integer, Type::Number)
| (Type::Float, Type::Number)
| (Type::None, Type::None)
| (Type::String, Type::String) => Ok(()),
(Type::Option(left), Type::Option(right)) => {
if left == right {
Ok(())
} else if let Type::Any = left.as_ref() {
Ok(())
} else if let Type::Any = right.as_ref() {
Ok(())
} else {
Err(Error::TypeCheck {
expected: self.clone(),
actual: other.clone(),
})
}
}
(Type::Option(_), Type::None) | (Type::None, Type::Option(_)) => Ok(()),
(Type::List(self_item_type), Type::List(other_item_type)) => {
if self_item_type.check(other_item_type).is_err() {
Err(Error::TypeCheck {
expected: self.clone(),
actual: other.clone(),
})
} else {
Ok(())
}
}
(
Type::Function {
parameter_types: self_parameter_types,
return_type: self_return_type,
},
Type::Function {
parameter_types: other_parameter_types,
return_type: other_return_type,
},
) => {
let parameter_type_pairs = self_parameter_types
.iter()
.zip(other_parameter_types.iter());
for (self_parameter_type, other_parameter_type) in parameter_type_pairs {
if self_parameter_type.check(other_parameter_type).is_err() {
return Err(Error::TypeCheck {
expected: self.clone(),
actual: other.clone(),
});
}
}
if self_return_type.check(other_return_type).is_err() {
Err(Error::TypeCheck {
expected: self.clone(),
actual: other.clone(),
})
} else {
Ok(())
}
}
_ => Err(Error::TypeCheck {
expected: self.clone(),
actual: other.clone(),
}),
}
}
}
impl AbstractTree for Type {
fn from_syntax_node(source: &str, node: Node, _context: &Map) -> Result<Self> {
Error::expect_syntax_node(source, "type", node)?;
let type_node = node.child(0).unwrap();
let r#type = match type_node.kind() {
"[" => {
let item_type_node = node.child(1).unwrap();
let item_type = Type::from_syntax_node(source, item_type_node, _context)?;
Type::List(Box::new(item_type))
}
"any" => Type::Any,
"bool" => Type::Boolean,
"float" => Type::Float,
"(" => {
let child_count = node.child_count();
let mut parameter_types = Vec::new();
for index in 1..child_count - 2 {
let child = node.child(index).unwrap();
if child.is_named() {
let parameter_type = Type::from_syntax_node(source, child, _context)?;
parameter_types.push(parameter_type);
}
}
let final_node = node.child(child_count - 1).unwrap();
let return_type = if final_node.is_named() {
Type::from_syntax_node(source, final_node, _context)?
} else {
Type::None
};
Type::Function {
parameter_types,
return_type: Box::new(return_type),
}
}
"int" => Type::Integer,
"map" => Type::Map,
"num" => Type::Number,
"none" => Type::None,
"str" => Type::String,
"option" => {
let inner_type_node = node.child(2).unwrap();
let inner_type = Type::from_syntax_node(source, inner_type_node, _context)?;
Type::Option(Box::new(inner_type))
}
_ => {
return Err(Error::UnexpectedSyntaxNode {
expected: "any, bool, float, function, int, list, map, num, str or option"
.to_string(),
actual: type_node.kind().to_string(),
location: type_node.start_position(),
relevant_source: source[type_node.byte_range()].to_string(),
})
}
};
Ok(r#type)
}
fn run(&self, _source: &str, _context: &Map) -> Result<Value> {
Ok(Value::none())
}
fn expected_type(&self, _context: &Map) -> Result<Type> {
Ok(Type::None)
}
}
impl Display for Type {
fn fmt(&self, f: &mut Formatter<'_>) -> fmt::Result {
match self {
Type::Any => write!(f, "any"),
Type::Boolean => write!(f, "bool"),
Type::Float => write!(f, "float"),
Type::Function {
parameter_types,
return_type,
} => {
write!(f, "(")?;
for parameter_type in parameter_types {
write!(f, "{parameter_type}")?;
if parameter_type != parameter_types.last().unwrap() {
write!(f, " ")?;
}
}
write!(f, ")")?;
write!(f, " -> {return_type}")
}
Type::Integer => write!(f, "int"),
Type::List(item_type) => write!(f, "[{item_type}]"),
Type::Map => write!(f, "map"),
Type::Number => write!(f, "num"),
Type::None => write!(f, "none"),
Type::String => write!(f, "str"),
Type::Option(inner_type) => {
write!(f, "option({})", inner_type)
}
}
}
}

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use std::collections::BTreeMap;
use serde::{Deserialize, Serialize};
use tree_sitter::Node;
use crate::{
AbstractTree, Block, Error, Expression, Function, Identifier, List, Map, Result, Statement,
Type, TypeDefinition, Value,
};
#[derive(Debug, Clone, Serialize, Deserialize, Eq, PartialEq, PartialOrd, Ord)]
pub enum ValueNode {
Boolean(String),
Float(String),
Function(Function),
Integer(String),
String(String),
List(Vec<Expression>),
Option(Option<Box<Expression>>),
Map(BTreeMap<String, (Statement, Option<Type>)>),
}
impl AbstractTree for ValueNode {
fn from_syntax_node(source: &str, node: Node, context: &Map) -> Result<Self> {
Error::expect_syntax_node(source, "value", node)?;
let child = node.child(0).unwrap();
let value_node = match child.kind() {
"boolean" => ValueNode::Boolean(source[child.byte_range()].to_string()),
"float" => ValueNode::Float(source[child.byte_range()].to_string()),
"function" => {
let child_count = child.child_count();
let mut parameters = Vec::new();
let mut parameter_types = Vec::new();
for index in 1..child_count - 3 {
let child = child.child(index).unwrap();
if child.kind() == "identifier" {
let identifier = Identifier::from_syntax_node(source, child, context)?;
parameters.push(identifier);
}
if child.kind() == "type_definition" {
let type_definition =
TypeDefinition::from_syntax_node(source, child, context)?;
parameter_types.push(type_definition.take_inner());
}
}
let function_context = Map::clone_from(context)?;
for (parameter_name, parameter_type) in
parameters.iter().zip(parameter_types.iter())
{
function_context.set(
parameter_name.inner().clone(),
Value::none(),
Some(parameter_type.clone()),
)?;
}
let return_type_node = child.child(child_count - 2).unwrap();
let return_type =
TypeDefinition::from_syntax_node(source, return_type_node, context)?;
let body_node = child.child(child_count - 1).unwrap();
let body = Block::from_syntax_node(source, body_node, &function_context)?;
return_type.inner().check(&body.expected_type(context)?)?;
let r#type = Type::Function {
parameter_types,
return_type: Box::new(return_type.take_inner()),
};
ValueNode::Function(Function::new(parameters, body, Some(r#type)))
}
"integer" => ValueNode::Integer(source[child.byte_range()].to_string()),
"string" => {
let without_quotes = child.start_byte() + 1..child.end_byte() - 1;
ValueNode::String(source[without_quotes].to_string())
}
"list" => {
let mut expressions = Vec::new();
for index in 1..child.child_count() - 1 {
let current_node = child.child(index).unwrap();
if current_node.is_named() {
let expression =
Expression::from_syntax_node(source, current_node, context)?;
expressions.push(expression);
}
}
ValueNode::List(expressions)
}
"map" => {
let mut child_nodes = BTreeMap::new();
let mut current_key = "".to_string();
let mut current_type = None;
for index in 0..child.child_count() - 1 {
let child_syntax_node = child.child(index).unwrap();
if child_syntax_node.kind() == "identifier" {
current_key =
Identifier::from_syntax_node(source, child_syntax_node, context)?
.take_inner();
current_type = None;
}
if child_syntax_node.kind() == "type_definition" {
current_type = Some(
TypeDefinition::from_syntax_node(source, child_syntax_node, context)?
.take_inner(),
);
}
if child_syntax_node.kind() == "statement" {
let statement =
Statement::from_syntax_node(source, child_syntax_node, context)?;
if let Some(type_definition) = &current_type {
type_definition.check(&statement.expected_type(context)?)?;
}
child_nodes.insert(current_key.clone(), (statement, current_type.clone()));
}
}
ValueNode::Map(child_nodes)
}
"option" => {
let first_grandchild = child.child(0).unwrap();
if first_grandchild.kind() == "none" {
ValueNode::Option(None)
} else {
let expression_node = child.child(2).unwrap();
let expression =
Expression::from_syntax_node(source, expression_node, context)?;
ValueNode::Option(Some(Box::new(expression)))
}
}
_ => {
return Err(Error::UnexpectedSyntaxNode {
expected: "string, integer, float, boolean, list, map, or option".to_string(),
actual: child.kind().to_string(),
location: child.start_position(),
relevant_source: source[child.byte_range()].to_string(),
})
}
};
Ok(value_node)
}
fn run(&self, source: &str, context: &Map) -> Result<Value> {
let value = match self {
ValueNode::Boolean(value_source) => Value::Boolean(value_source.parse().unwrap()),
ValueNode::Float(value_source) => Value::Float(value_source.parse().unwrap()),
ValueNode::Function(function) => Value::Function(function.clone()),
ValueNode::Integer(value_source) => Value::Integer(value_source.parse().unwrap()),
ValueNode::String(value_source) => Value::String(value_source.parse().unwrap()),
ValueNode::List(expressions) => {
let mut values = Vec::with_capacity(expressions.len());
for node in expressions {
let value = node.run(source, context)?;
values.push(value);
}
Value::List(List::with_items(values))
}
ValueNode::Option(option) => {
let option_value = if let Some(expression) = option {
Some(Box::new(expression.run(source, context)?))
} else {
None
};
Value::Option(option_value)
}
ValueNode::Map(key_statement_pairs) => {
let map = Map::new();
{
for (key, (statement, r#type)) in key_statement_pairs {
let value = statement.run(source, context)?;
map.set(key.clone(), value, r#type.clone())?;
}
}
Value::Map(map)
}
};
Ok(value)
}
fn expected_type(&self, context: &Map) -> Result<Type> {
let type_definition = match self {
ValueNode::Boolean(_) => Type::Boolean,
ValueNode::Float(_) => Type::Float,
ValueNode::Function(function) => function.r#type().clone(),
ValueNode::Integer(_) => Type::Integer,
ValueNode::String(_) => Type::String,
ValueNode::List(expressions) => {
let mut previous_type = None;
for expression in expressions {
let expression_type = expression.expected_type(context)?;
if let Some(previous) = previous_type {
if expression_type != previous {
return Ok(Type::List(Box::new(Type::Any)));
}
}
previous_type = Some(expression_type);
}
if let Some(previous) = previous_type {
Type::List(Box::new(previous))
} else {
Type::List(Box::new(Type::Any))
}
}
ValueNode::Option(option) => {
if let Some(expression) = option {
Type::Option(Box::new(expression.expected_type(context)?))
} else {
Type::None
}
}
ValueNode::Map(_) => Type::Map,
};
Ok(type_definition)
}
}

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use serde::{Deserialize, Serialize};
use tree_sitter::Node;
use crate::{AbstractTree, Block, Error, Expression, Map, Result, Type, Value};
/// Abstract representation of a while loop.
///
/// While executes its block repeatedly until its expression evaluates to true.
#[derive(Debug, Clone, Serialize, Deserialize, Eq, PartialEq, PartialOrd, Ord)]
pub struct While {
expression: Expression,
block: Block,
}
impl AbstractTree for While {
fn from_syntax_node(source: &str, node: Node, context: &Map) -> crate::Result<Self> {
Error::expect_syntax_node(source, "while", node)?;
let expression_node = node.child(1).unwrap();
let expression = Expression::from_syntax_node(source, expression_node, context)?;
let block_node = node.child(2).unwrap();
let block = Block::from_syntax_node(source, block_node, context)?;
Ok(While { expression, block })
}
fn run(&self, source: &str, context: &Map) -> Result<Value> {
while self.expression.run(source, context)?.as_boolean()? {
self.block.run(source, context)?;
}
Ok(Value::none())
}
fn expected_type(&self, context: &Map) -> Result<Type> {
self.block.expected_type(context)
}
}

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use serde::{Deserialize, Serialize};
use tree_sitter::Node;
use crate::{
function_expression::FunctionExpression, AbstractTree, Error, Expression, FunctionCall, Map,
Result, Type, Value,
};
/// Abstract representation of a yield expression.
///
/// Yield is an alternate means of calling and passing values to a function.
#[derive(Debug, Clone, Serialize, Deserialize, Eq, PartialEq, PartialOrd, Ord)]
pub struct Yield {
call: FunctionCall,
}
impl AbstractTree for Yield {
fn from_syntax_node(source: &str, node: Node, context: &Map) -> Result<Self> {
Error::expect_syntax_node(source, "yield", node)?;
let input_node = node.child(0).unwrap();
let input = Expression::from_syntax_node(source, input_node, context)?;
let function_node = node.child(2).unwrap();
let function_expression =
FunctionExpression::from_syntax_node(source, function_node, context)?;
let mut arguments = Vec::new();
arguments.push(input);
for index in 3..node.child_count() - 1 {
let child = node.child(index).unwrap();
if child.is_named() {
let expression = Expression::from_syntax_node(source, child, context)?;
arguments.push(expression);
}
}
let call = FunctionCall::new(function_expression, arguments);
Ok(Yield { call })
}
fn run(&self, source: &str, context: &Map) -> Result<Value> {
self.call.run(source, context)
}
fn expected_type(&self, context: &Map) -> Result<Type> {
self.call.expected_type(context)
}
}

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use std::{fs::read_to_string, path::PathBuf};
use dust_lang::{Interpreter, Map, Result, Value};
use egui::{Align, Color32, Layout, RichText};
use serde::{Deserialize, Serialize};
#[derive(Deserialize, Serialize)]
pub struct App {
path: String,
source: String,
context: Map,
#[serde(skip)]
interpreter: Interpreter,
output: Result<Value>,
}
impl App {
pub fn new(cc: &eframe::CreationContext<'_>, path: PathBuf) -> Self {
fn create_app(path: PathBuf) -> App {
let context = Map::new();
let mut interpreter = Interpreter::new(context.clone());
let read_source = read_to_string(&path);
let source = if let Ok(source) = read_source {
source
} else {
String::new()
};
let output = interpreter.run(&source);
App {
path: path.to_string_lossy().to_string(),
source,
context,
interpreter,
output,
}
}
cc.egui_ctx.set_zoom_factor(1.2);
if path.is_file() {
create_app(path)
} else {
if let Some(storage) = cc.storage {
return eframe::get_value(storage, eframe::APP_KEY)
.unwrap_or_else(|| create_app(path));
} else {
create_app(path)
}
}
}
}
impl eframe::App for App {
/// Called by the frame work to save state before shutdown.
fn save(&mut self, storage: &mut dyn eframe::Storage) {
eframe::set_value(storage, eframe::APP_KEY, self);
}
/// Called each time the UI needs repainting, which may be many times per second.
fn update(&mut self, ctx: &egui::Context, _frame: &mut eframe::Frame) {
egui::TopBottomPanel::top("top_panel").show(ctx, |ui| {
egui::menu::bar(ui, |ui| {
if ui.button("Quit").clicked() {
ctx.send_viewport_cmd(egui::ViewportCommand::Close);
}
ui.add_space(16.0);
egui::widgets::global_dark_light_mode_buttons(ui);
ui.with_layout(Layout::right_to_left(Align::Max), |ui| {
egui::warn_if_debug_build(ui);
ui.hyperlink_to("source code", "https://git.jeffa.io/jeff/dust");
});
});
});
egui::CentralPanel::default().show(ctx, |ui| {
ui.with_layout(Layout::left_to_right(Align::Min), |ui| {
ui.with_layout(Layout::top_down(Align::Min).with_main_justify(true), |ui| {
ui.with_layout(Layout::left_to_right(Align::Min), |ui| {
ui.text_edit_singleline(&mut self.path);
if ui.button("read").clicked() {
self.source = read_to_string(&self.path).unwrap();
}
if ui.button("run").clicked() {
self.output = self.interpreter.run(&self.source);
}
});
ui.code_editor(&mut self.source);
});
match &self.output {
Ok(value) => {
display_value(value, ui);
}
Err(error) => {
ui.label(error.to_string());
}
}
});
});
}
}
fn display_value(value: &Value, ui: &mut egui::Ui) {
match value {
Value::List(list) => {
ui.collapsing("list", |ui| {
for value in list.items().iter() {
display_value(value, ui);
}
});
}
Value::Map(_) => todo!(),
Value::Function(function) => {
ui.label(function.to_string());
}
Value::String(string) => {
ui.label(RichText::new(string).color(Color32::GREEN));
}
Value::Float(float) => {
ui.label(float.to_string());
}
Value::Integer(integer) => {
ui.label(RichText::new(integer.to_string()).color(Color32::BLUE));
}
Value::Boolean(boolean) => {
ui.label(RichText::new(boolean.to_string()).color(Color32::RED));
}
Value::Option(_) => todo!(),
}
}

35
src/bin/gui/main.rs Normal file
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#![cfg_attr(not(debug_assertions), windows_subsystem = "windows")]
use std::path::PathBuf;
use clap::Parser;
mod app;
#[derive(Parser)]
struct Args {
// Path to the file to read.
path: Option<PathBuf>,
}
fn main() -> eframe::Result<()> {
env_logger::init();
let path = if let Some(path) = Args::parse().path {
path
} else {
PathBuf::new()
};
let native_options = eframe::NativeOptions {
viewport: egui::ViewportBuilder::default()
.with_inner_size([400.0, 300.0])
.with_min_inner_size([300.0, 220.0]),
..Default::default()
};
eframe::run_native(
"Dust GUI",
native_options,
Box::new(|cc| Box::new(app::App::new(cc, path))),
)
}

57
src/built_in_functions/assert.rs Normal file
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use crate::{BuiltInFunction, Error, Map, Result, Type, Value};
pub struct Assert;
impl BuiltInFunction for Assert {
fn name(&self) -> &'static str {
"assert"
}
fn run(&self, arguments: &[Value], _context: &Map) -> Result<Value> {
for argument in arguments {
if !argument.as_boolean()? {
return Err(Error::AssertFailed);
}
}
Ok(Value::none())
}
fn r#type(&self) -> Type {
Type::Function {
parameter_types: vec![Type::Any],
return_type: Box::new(Type::None),
}
}
}
pub struct AssertEqual;
impl BuiltInFunction for AssertEqual {
fn name(&self) -> &'static str {
"assert_equal"
}
fn run(&self, arguments: &[Value], _context: &Map) -> Result<Value> {
Error::expect_argument_amount(self, 2, arguments.len())?;
let left = arguments.get(0).unwrap();
let right = arguments.get(1).unwrap();
if left == right {
Ok(Value::none())
} else {
Err(Error::AssertEqualFailed {
expected: left.clone(),
actual: right.clone(),
})
}
}
fn r#type(&self) -> Type {
Type::Function {
parameter_types: vec![Type::Any, Type::Any],
return_type: Box::new(Type::Boolean),
}
}
}

24
src/built_in_functions/collections.rs Normal file
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use crate::{BuiltInFunction, Error, Map, Result, Type, Value};
pub struct Length;
impl BuiltInFunction for Length {
fn name(&self) -> &'static str {
"length"
}
fn run(&self, arguments: &[Value], _context: &Map) -> Result<Value> {
Error::expect_argument_amount(self, 1, arguments.len())?;
let length = arguments.first().unwrap().as_list()?.items().len();
Ok(Value::Integer(length as i64))
}
fn r#type(&self) -> Type {
Type::Function {
parameter_types: vec![Type::List(Box::new(Type::Any))],
return_type: Box::new(Type::Integer),
}
}
}

67
src/built_in_functions/commands.rs Normal file
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use std::process::Command;
use crate::{BuiltInFunction, Error, Map, Result, Type, Value};
pub struct Raw;
impl BuiltInFunction for Raw {
fn name(&self) -> &'static str {
"raw"
}
fn run(&self, arguments: &[Value], _context: &Map) -> Result<Value> {
Error::expect_argument_amount(self, 2, arguments.len())?;
let program = arguments.first().unwrap().as_string()?;
let command_arguments = arguments.get(1).unwrap().as_list()?;
let mut command = Command::new(program);
for argument in command_arguments.items().iter() {
command.arg(argument.as_string()?);
}
let output = command.spawn()?.wait_with_output()?.stdout;
Ok(Value::String(String::from_utf8(output)?))
}
fn r#type(&self) -> crate::Type {
Type::Function {
parameter_types: vec![Type::String, Type::List(Box::new(Type::String))],
return_type: Box::new(Type::String),
}
}
}
pub struct Sh;
impl BuiltInFunction for Sh {
fn name(&self) -> &'static str {
"sh"
}
fn run(&self, arguments: &[Value], _context: &Map) -> Result<Value> {
let command_text = arguments.first().unwrap().as_string()?;
let mut command = Command::new("sh");
command.arg("-c");
command.arg(command_text);
let extra_command_text = arguments.get(1).unwrap_or_default().as_option()?;
if let Some(text) = extra_command_text {
command.args(["--", text.as_string()?]);
}
let output = command.spawn()?.wait_with_output()?.stdout;
Ok(Value::String(String::from_utf8(output)?))
}
fn r#type(&self) -> crate::Type {
Type::Function {
parameter_types: vec![Type::String, Type::Option(Box::new(Type::String))],
return_type: Box::new(Type::String),
}
}
}

49
src/built_in_functions/data_formats.rs Normal file
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use crate::{BuiltInFunction, Error, Map, Result, Type, Value};
pub struct FromJson;
impl BuiltInFunction for FromJson {
fn name(&self) -> &'static str {
"from_json"
}
fn run(&self, arguments: &[Value], _context: &Map) -> Result<Value> {
Error::expect_argument_amount(self, 1, arguments.len())?;
let json_string = arguments.first().unwrap().as_string()?;
let value = serde_json::from_str(json_string)?;
Ok(value)
}
fn r#type(&self) -> Type {
Type::Function {
parameter_types: vec![Type::String],
return_type: Box::new(Type::Any),
}
}
}
pub struct ToJson;
impl BuiltInFunction for ToJson {
fn name(&self) -> &'static str {
"to_json"
}
fn run(&self, arguments: &[Value], _context: &Map) -> Result<Value> {
Error::expect_argument_amount(self, 1, arguments.len())?;
let value = arguments.first().unwrap();
let json_string = serde_json::to_string(&value)?;
Ok(Value::String(json_string))
}
fn r#type(&self) -> Type {
Type::Function {
parameter_types: vec![Type::Any],
return_type: Box::new(Type::String),
}
}
}

105
src/built_in_functions/fs.rs Normal file
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use std::{
fs::{read_dir, read_to_string, write, File},
io::Write as IoWrite,
path::PathBuf,
};
use crate::{BuiltInFunction, List, Map, Result, Type, Value};
pub struct Read;
impl BuiltInFunction for Read {
fn name(&self) -> &'static str {
"read"
}
fn run(&self, arguments: &[Value], _context: &Map) -> Result<Value> {
let path_string = arguments.first().unwrap_or_default().as_string()?;
let path = PathBuf::from(path_string);
if path.is_dir() {
let files = List::new();
for entry in read_dir(&path)? {
let entry = entry?;
let file_data = Map::new();
let name = entry.file_name().to_string_lossy().to_string();
let metadata = entry.metadata()?;
let created = metadata.created()?.elapsed()?.as_secs() as i64;
let modified = metadata.modified()?.elapsed()?.as_secs() as i64;
file_data.set("name".to_string(), Value::String(name), None)?;
file_data.set("created".to_string(), Value::Integer(created), None)?;
file_data.set("modified".to_string(), Value::Integer(modified), None)?;
files.items_mut().push(Value::Map(file_data));
}
return Ok(Value::List(files));
}
let file_content = read_to_string(path)?;
Ok(Value::String(file_content))
}
fn r#type(&self) -> Type {
Type::Function {
parameter_types: vec![Type::String],
return_type: Box::new(Type::String),
}
}
}
pub struct Write;
impl BuiltInFunction for Write {
fn name(&self) -> &'static str {
"write"
}
fn run(&self, arguments: &[Value], _context: &Map) -> Result<Value> {
let file_content = arguments.first().unwrap_or_default().as_string()?;
let path = arguments.get(1).unwrap_or_default().as_string()?;
write(path, file_content)?;
Ok(Value::none())
}
fn r#type(&self) -> Type {
Type::Function {
parameter_types: vec![Type::String],
return_type: Box::new(Type::None),
}
}
}
pub struct Append;
impl BuiltInFunction for Append {
fn name(&self) -> &'static str {
"append"
}
fn run(&self, arguments: &[Value], _context: &Map) -> Result<Value> {
let file_content = arguments.get(0).unwrap_or_default().as_string()?;
let path = arguments.get(1).unwrap_or_default().as_string()?;
File::options()
.append(true)
.create(true)
.open(path)?
.write_all(file_content.as_bytes())?;
Ok(Value::none())
}
fn r#type(&self) -> Type {
Type::Function {
parameter_types: vec![Type::String, Type::String],
return_type: Box::new(Type::None),
}
}
}

30
src/built_in_functions/map.rs Normal file
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//! Functions related to [Map][crate::Map] values.
use crate::{BuiltInFunction, List, Map, Result, Type, Value};
pub struct Keys;
impl BuiltInFunction for Keys {
fn name(&self) -> &'static str {
"keys"
}
fn run(&self, arguments: &[Value], _context: &Map) -> Result<Value> {
let map = arguments.first().unwrap_or_default().as_map()?;
let variables = map.variables()?;
let mut keys = Vec::with_capacity(variables.len());
for (key, _) in variables.iter() {
keys.push(Value::String(key.clone()))
}
Ok(Value::List(List::with_items(keys)))
}
fn r#type(&self) -> Type {
Type::Function {
parameter_types: vec![Type::Map],
return_type: Box::new(Type::List(Box::new(Type::String))),
}
}
}

48
src/built_in_functions/mod.rs Normal file
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/// Built-in functions that are available to all Dust programs.
use crate::{Map, Result, Type, Value};
mod assert;
mod collections;
mod commands;
mod data_formats;
mod fs;
mod network;
mod option;
mod output;
mod packages;
mod random;
mod r#type;
/// All built-in functions recognized by the interpreter.
///
/// This is the public interface to access built-in functions by iterating over
/// the references it holds.
pub const BUILT_IN_FUNCTIONS: [&dyn BuiltInFunction; 21] = [
&assert::Assert,
&assert::AssertEqual,
&collections::Length,
&commands::Raw,
&commands::Sh,
&data_formats::FromJson,
&data_formats::ToJson,
&fs::Read,
&fs::Write,
&fs::Append,
&network::Download,
&option::EitherOr,
&option::IsNone,
&option::IsSome,
&output::Output,
&packages::InstallPackages,
&random::Random,
&random::RandomBoolean,
&random::RandomFloat,
&random::RandomInteger,
&r#type::TypeFunction,
];
pub trait BuiltInFunction {
fn name(&self) -> &'static str;
fn run(&self, arguments: &[Value], context: &Map) -> Result<Value>;
fn r#type(&self) -> Type;
}

27
src/built_in_functions/network.rs Normal file
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use reqwest::blocking::get;
use crate::{BuiltInFunction, Error, Map, Result, Type, Value};
pub struct Download;
impl BuiltInFunction for Download {
fn name(&self) -> &'static str {
"download"
}
fn run(&self, arguments: &[Value], _context: &Map) -> Result<Value> {
Error::expect_argument_amount(self, 1, arguments.len())?;
let url = arguments.first().unwrap().as_string()?;
let response = get(url)?;
Ok(Value::String(response.text()?))
}
fn r#type(&self) -> Type {
Type::Function {
parameter_types: vec![Type::String],
return_type: Box::new(Type::String),
}
}
}

69
src/built_in_functions/option.rs Normal file
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use crate::{BuiltInFunction, Map, Result, Type, Value};
pub struct EitherOr;
impl BuiltInFunction for EitherOr {
fn name(&self) -> &'static str {
"either_or"
}
fn run(&self, arguments: &[Value], _context: &Map) -> Result<Value> {
let option = arguments.first().unwrap_or_default().as_option()?;
let value = if let Some(value) = option {
*value.clone()
} else {
arguments.get(1).unwrap_or_default().clone()
};
Ok(value)
}
fn r#type(&self) -> Type {
Type::Function {
parameter_types: vec![Type::Option(Box::new(Type::Any)), Type::Any],
return_type: Box::new(Type::Boolean),
}
}
}
pub struct IsNone;
impl BuiltInFunction for IsNone {
fn name(&self) -> &'static str {
"is_none"
}
fn run(&self, arguments: &[Value], _context: &Map) -> Result<Value> {
let option = arguments.first().unwrap_or_default().as_option()?;
Ok(Value::Boolean(option.is_none()))
}
fn r#type(&self) -> Type {
Type::Function {
parameter_types: vec![Type::Option(Box::new(Type::Any))],
return_type: Box::new(Type::Boolean),
}
}
}
pub struct IsSome;
impl BuiltInFunction for IsSome {
fn name(&self) -> &'static str {
"is_some"
}
fn run(&self, arguments: &[Value], _context: &Map) -> Result<Value> {
let option = arguments.first().unwrap_or_default().as_option()?;
Ok(Value::Boolean(option.is_some()))
}
fn r#type(&self) -> Type {
Type::Function {
parameter_types: vec![Type::Option(Box::new(Type::Any))],
return_type: Box::new(Type::Boolean),
}
}
}

26
src/built_in_functions/output.rs Normal file
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use crate::{BuiltInFunction, Error, Map, Result, Type, Value};
pub struct Output;
impl BuiltInFunction for Output {
fn name(&self) -> &'static str {
"output"
}
fn run(&self, arguments: &[Value], _context: &Map) -> Result<Value> {
Error::expect_argument_amount(self, 1, arguments.len())?;
let value = arguments.first().unwrap();
println!("{value}");
Ok(Value::default())
}
fn r#type(&self) -> Type {
Type::Function {
parameter_types: vec![Type::Any],
return_type: Box::new(Type::None),
}
}
}

35
src/built_in_functions/packages.rs Normal file
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use std::process::Command;
use crate::{BuiltInFunction, Error, Map, Result, Type, Value};
pub struct InstallPackages;
impl BuiltInFunction for InstallPackages {
fn name(&self) -> &'static str {
"install_packages"
}
fn run(&self, arguments: &[Value], _context: &Map) -> Result<Value> {
Error::expect_argument_amount(self, 1, arguments.len())?;
let mut command = Command::new("sudo");
let argument_list = arguments.first().unwrap().as_list()?;
command.args(["dnf", "-y", "install"]);
for argument in argument_list.items().iter() {
command.arg(argument.as_string()?);
}
command.spawn()?.wait()?;
Ok(Value::none())
}
fn r#type(&self) -> Type {
Type::Function {
parameter_types: vec![Type::List(Box::new(Type::String))],
return_type: Box::new(Type::None),
}
}
}

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