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Clean up and fix tests

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This commit is contained in:
Jeff 2023-09-29 17:57:55 -04:00
parent dd939db924
commit d2d2ea1c57
2 changed files with 47 additions and 17 deletions
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63
src/interface.rs
View File

@ -1,6 +1,6 @@
//! The top level of Dust's API with functions to interpret Dust code. //! The top level of Dust's API with functions to interpret Dust code.
use tree_sitter::{Node, Parser, Tree, TreeCursor}; use tree_sitter::{Node, Parser, Tree as TSTree, TreeCursor};
use crate::{language, Error, Result, Value, VariableMap}; use crate::{language, Error, Result, Value, VariableMap};
@ -55,20 +55,40 @@ pub fn eval_with_context(source: &str, context: &mut VariableMap) -> Vec<Result<
results results
} }
pub trait EvaluatorTree: 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 new(node: Node, source: &str) -> Result<Self>;
/// Execute dust code by traversing the tree
fn run(
&self,
context: &mut VariableMap,
cursor: &mut TreeCursor,
source: &str,
) -> Vec<Result<Value>>;
}
/// A collection of statements and comments interpreted from a syntax tree. /// A collection of statements and comments interpreted from a syntax tree.
/// ///
/// The Evaluator turns a tree sitter concrete syntax tree into a vector of /// The Evaluator turns a tree sitter concrete syntax tree into a vector of
/// trees that can be run to execute the source code. Each of these trees is an /// abstract trees called [Item][]s that can be run to execute the source code.
/// [Item][] in the evaluator.
#[derive(Debug)] #[derive(Debug)]
pub struct Evaluator { pub struct Evaluator {
items: Vec<Item>, items: Vec<Item>,
} }
impl Evaluator { impl Evaluator {
fn new(tree: Tree, source: &str) -> Result<Self> { fn new(tree_sitter_tree: TSTree, source: &str) -> Result<Self> {
let root_node = tree.root_node(); let root_node = tree_sitter_tree.root_node();
let mut cursor = tree.walk(); let mut cursor = tree_sitter_tree.walk();
let mut items = Vec::new(); let mut items = Vec::new();
for (index, node) in root_node.children(&mut cursor).enumerate() { for (index, node) in root_node.children(&mut cursor).enumerate() {
@ -76,6 +96,7 @@ impl Evaluator {
items.push(item); items.push(item);
// This iterator will run forever without this check.
if index == root_node.child_count() - 1 { if index == root_node.child_count() - 1 {
break; break;
} }
@ -144,6 +165,11 @@ impl Item {
} }
} }
/// Representation of a statement in the .
///
/// Items are either comments, which do nothing, or statements, which can be run
/// to produce a single value or interact with a context by creating or
/// referencing variables.
#[derive(Debug)] #[derive(Debug)]
pub enum Statement { pub enum Statement {
Open(Expression), Open(Expression),
@ -290,6 +316,10 @@ impl Operation {
} }
} }
/// Respresentation of an if-then-else logic gate.
///
/// A ControlFlow instance represents work to be done when the "run" method is
/// called.
#[derive(Debug)] #[derive(Debug)]
pub struct ControlFlow { pub struct ControlFlow {
if_expression: Expression, if_expression: Expression,
@ -299,6 +329,7 @@ pub struct ControlFlow {
impl ControlFlow { impl ControlFlow {
fn new(node: Node, source: &str) -> Result<Self> { fn new(node: Node, source: &str) -> Result<Self> {
// Skip the child nodes for the keywords "if", "then" and "else".
let second_child = node.child(1).unwrap(); let second_child = node.child(1).unwrap();
let fourth_child = node.child(3).unwrap(); let fourth_child = node.child(3).unwrap();
let sixth_child = node.child(5); let sixth_child = node.child(5);
@ -345,8 +376,8 @@ mod tests {
#[test] #[test]
fn evaluate_empty() { fn evaluate_empty() {
assert_eq!(eval("()"), vec![Ok(Value::Empty)]); assert_eq!(eval("()"), vec![Ok(Value::Empty)]);
assert_eq!(eval("1;"), vec![Ok(Value::Empty)]); assert_eq!(eval("x = 9"), vec![Ok(Value::Empty)]);
assert_eq!(eval("'foobar';"), vec![Ok(Value::Empty)]); assert_eq!(eval("y = 'foobar'"), vec![Ok(Value::Empty)]);
} }
#[test] #[test]
@ -376,7 +407,7 @@ mod tests {
#[test] #[test]
fn evaluate_list() { fn evaluate_list() {
assert_eq!( assert_eq!(
eval("(1, 2, 'foobar')"), eval("[1, 2, 'foobar']"),
vec![Ok(Value::List(vec![ vec![Ok(Value::List(vec![
Value::Integer(1), Value::Integer(1),
Value::Integer(2), Value::Integer(2),
@ -392,10 +423,8 @@ mod tests {
output number output number
}"; }";
assert_eq!( todo!();
eval("{ x = 1, foo = 'bar' }"), // assert_eq!("", vec![Ok(Value::Function(Function::new(function_str)))]);
vec![Ok(Value::Function(Function::new(function_str)))]
);
} }
#[test] #[test]
@ -406,7 +435,7 @@ mod tests {
map.set_value("foo", Value::String("bar".to_string())) map.set_value("foo", Value::String("bar".to_string()))
.unwrap(); .unwrap();
assert_eq!(eval("{ x = 1, foo = 'bar' }"), vec![Ok(Value::Map(map))]); assert_eq!(eval("map { x = 1 foo = 'bar' }"), vec![Ok(Value::Map(map))]);
} }
#[test] #[test]
@ -427,9 +456,9 @@ mod tests {
eval( eval(
" "
table <messages, numbers> { table <messages, numbers> {
('hiya', 42) ['hiya', 42]
('foo', 57) ['foo', 57]
('bar', 99.99) ['bar', 99.99]
} }
" "
), ),

1
src/value/mod.rs
View File

@ -133,6 +133,7 @@ impl Value {
Ok(Value::Table(table)) Ok(Value::Table(table))
} }
"map" => todo!(),
"empty" => Ok(Value::Empty), "empty" => Ok(Value::Empty),
_ => Err(Error::UnexpectedSourceNode { _ => Err(Error::UnexpectedSourceNode {
expected: "integer, string, boolean, float, list or empty", expected: "integer, string, boolean, float, list or empty",