use std::collections::HashMap; use crate::{ parse, AbstractSyntaxTree, Analyzer, AnalyzerError, Identifier, Node, ParseError, ReservedIdentifier, Span, Statement, Value, ValueError, }; pub fn run( input: &str, variables: &mut HashMap, ) -> Result, VmError> { let abstract_syntax_tree = parse(input)?; let analyzer = Analyzer::new(&abstract_syntax_tree, variables); analyzer.analyze()?; let mut vm = Vm::new(abstract_syntax_tree); vm.run(variables) } pub struct Vm { abstract_tree: AbstractSyntaxTree, } impl Vm { pub fn new(abstract_tree: AbstractSyntaxTree) -> Self { Self { abstract_tree } } pub fn run( &mut self, variables: &mut HashMap, ) -> Result, VmError> { let mut previous_value = None; while let Some(node) = self.abstract_tree.nodes.pop_front() { previous_value = self.run_node(node, variables)?; } Ok(previous_value) } fn run_node( &self, node: Node, variables: &mut HashMap, ) -> Result, VmError> { match node.statement { Statement::BuiltInValue(node) => self.run_node(*node, variables), Statement::Constant(value) => Ok(Some(value.clone())), Statement::Identifier(_) => Ok(None), Statement::ReservedIdentifier(_) => Ok(None), Statement::Add(left, right) => { let left_span = left.span; let left = if let Some(value) = self.run_node(*left, variables)? { value } else { return Err(VmError::ExpectedValue { position: left_span, }); }; let right_span = right.span; let right = if let Some(value) = self.run_node(*right, variables)? { value } else { return Err(VmError::ExpectedValue { position: right_span, }); }; let sum = left.add(&right)?; Ok(Some(sum)) } Statement::Assign(left, right) => { let identifier = if let Statement::Identifier(identifier) = &left.statement { identifier } else { return Err(VmError::ExpectedIdentifier { position: left.span, }); }; let right_span = right.span; let value = if let Some(value) = self.run_node(*right, variables)? { value } else { return Err(VmError::ExpectedValue { position: right_span, }); }; variables.insert(identifier.clone(), value); Ok(None) } Statement::List(nodes) => { let values = nodes .into_iter() .map(|node| { let span = node.span; if let Some(value) = self.run_node(node, variables)? { Ok(value) } else { Err(VmError::ExpectedValue { position: span }) } }) .collect::, VmError>>()?; Ok(Some(Value::list(values))) } Statement::Multiply(_, _) => todo!(), Statement::PropertyAccess(left, right) => { let left_span = left.span; let left = if let Some(value) = self.run_node(*left, variables)? { value } else { return Err(VmError::ExpectedValue { position: left_span, }); }; let right_span = right.span; if let Statement::ReservedIdentifier(reserved) = &right.statement { match reserved { ReservedIdentifier::IsEven => { if let Some(integer) = left.as_integer() { return Ok(Some(Value::boolean(integer % 2 == 0))); } else { return Err(VmError::ExpectedInteger { position: right_span, }); } } ReservedIdentifier::IsOdd => { if let Some(integer) = left.as_integer() { return Ok(Some(Value::boolean(integer % 2 != 0))); } else { return Err(VmError::ExpectedInteger { position: right_span, }); } } ReservedIdentifier::Length => { if let Some(list) = left.as_list() { return Ok(Some(Value::integer(list.len() as i64))); } else { return Err(VmError::ExpectedList { position: right_span, }); } } } } if let (Some(list), Statement::Constant(value)) = (left.as_list(), &right.statement) { if let Some(index) = value.as_integer() { let value = list.get(index as usize).cloned(); return Ok(value); } } Err(VmError::ExpectedIdentifierOrInteger { position: right_span, }) } } } } #[derive(Clone, Debug, PartialEq)] pub enum VmError { AnaylyzerError(AnalyzerError), ParseError(ParseError), ValueError(ValueError), // Anaylsis Failures // These should be prevented by running the analyzer before the VM ExpectedIdentifier { position: Span }, ExpectedIdentifierOrInteger { position: Span }, ExpectedInteger { position: Span }, ExpectedList { position: Span }, ExpectedValue { position: Span }, } impl From for VmError { fn from(error: AnalyzerError) -> Self { Self::AnaylyzerError(error) } } impl From for VmError { fn from(error: ParseError) -> Self { Self::ParseError(error) } } impl From for VmError { fn from(error: ValueError) -> Self { Self::ValueError(error) } } #[cfg(test)] mod tests { use super::*; #[test] fn boolean() { let input = "true"; assert_eq!( run(input, &mut HashMap::new()), Ok(Some(Value::boolean(true))) ); } #[test] fn is_even() { let input = "42.is_even"; assert_eq!( run(input, &mut HashMap::new()), Ok(Some(Value::boolean(true))) ); } #[test] fn is_odd() { let input = "42.is_odd"; assert_eq!( run(input, &mut HashMap::new()), Ok(Some(Value::boolean(false))) ); } #[test] fn list_access() { let input = "[1, 2, 3].1"; assert_eq!(run(input, &mut HashMap::new()), Ok(Some(Value::integer(2)))); } #[test] fn property_access() { let input = "[1, 2, 3].length"; assert_eq!(run(input, &mut HashMap::new()), Ok(Some(Value::integer(3)))); } #[test] fn add() { let input = "1 + 2"; assert_eq!(run(input, &mut HashMap::new()), Ok(Some(Value::integer(3)))); } #[test] fn add_multiple() { let input = "1 + 2 + 3"; assert_eq!(run(input, &mut HashMap::new()), Ok(Some(Value::integer(6)))); } }