use serde::{Deserialize, Serialize}; use tree_sitter::Node; use crate::{AbstractTree, Error, Map, Result, Type, Value, ValueNode, BUILT_IN_FUNCTIONS}; use super::expression::Expression; #[derive(Debug, Clone, Serialize, Deserialize, Eq, PartialEq, PartialOrd, Ord)] pub struct FunctionCall { function_expression: Expression, arguments: Vec, } impl FunctionCall { pub fn new(function_expression: Expression, arguments: Vec) -> Self { Self { function_expression, arguments, } } } impl AbstractTree for FunctionCall { fn from_syntax_node(source: &str, node: Node, context: &Map) -> Result { debug_assert_eq!("function_call", node.kind()); let expression_node = node.child(1).unwrap(); let function_expression = Expression::from_syntax_node(source, expression_node, context)?; 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)?; arguments.push(expression); } } let function_type = function_expression.expected_type(context)?; if let Type::Function { parameter_types, return_type, } = function_type { let argument_type_pairs = arguments.iter().zip(parameter_types.iter()); for (argument, r#type) in argument_type_pairs { let argument_type = argument.expected_type(context)?; r#type.check(&argument_type, context, node, source)?; } } let function_call = FunctionCall { function_expression, arguments, }; Ok(function_call) } fn run(&self, source: &str, context: &Map) -> Result { let value = match &self.function_expression { Expression::Value(value_node) => value_node.run(source, context)?, Expression::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.clone())); } } Expression::Index(index) => index.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::Yield(r#yield) => r#yield.run(source, context)?, }; value.as_function()?.call(&self.arguments, source, context) } fn expected_type(&self, context: &Map) -> Result { match &self.function_expression { Expression::Value(value_node) => { if let ValueNode::Function(function) = value_node { let return_type = function.return_type()?.clone(); Ok(return_type) } else { value_node.expected_type(context) } } Expression::Identifier(identifier) => identifier.expected_type(context), Expression::Index(index) => index.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::Yield(r#yield) => r#yield.expected_type(context), } } } #[cfg(test)] mod tests { use crate::{evaluate, Value}; #[test] fn evaluate_function_call() { assert_eq!( evaluate( " foobar <(str) -> str> = fn |message| { message } (foobar 'Hiya') ", ), Ok(Value::String("Hiya".to_string())) ); } #[test] fn evaluate_callback() { assert_eq!( evaluate( " foobar <(() -> str) -> str> = fn |cb| { (cb) } (foobar fn || { 'Hiya' }) ", ), Ok(Value::String("Hiya".to_string())) ); } #[test] fn evaluate_built_in_function_call() { assert_eq!(evaluate("(output 'Hiya')"), Ok(Value::Empty)); } }