use std::collections::BTreeMap;
use serde::{Deserialize, Serialize};
use tree_sitter::Node;
use crate::{
AbstractTree, BuiltInValue, 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>)>),
BuiltInValue(BuiltInValue),
}
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" => ValueNode::Function(Function::from_syntax_node(source, child, context)?),
"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) = ¤t_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)))
}
}
"built_in_value" => {
let built_in_value_node = child.child(0).unwrap();
ValueNode::BuiltInValue(BuiltInValue::from_syntax_node(
source,
built_in_value_node,
context,
)?)
}
_ => {
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.clone()),
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)
}
ValueNode::BuiltInValue(built_in_value) => built_in_value.run(source, context)?,
};
Ok(value)
}
fn expected_type(&self, context: &Map) -> Result<Type> {
let r#type = 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,
ValueNode::BuiltInValue(built_in_value) => built_in_value.expected_type(context)?,
};
Ok(r#type)
}
}