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use std::fmt::{Display}; #[allow(unused_imports)] use std::str::FromStr; use std::ops::{Add, Sub, Mul, Div, Rem, Not}; use crate::table::*; use crate::object::*; use crate::literals::*; #[derive(Debug, Clone, PartialEq)] pub struct Value { value_type: Type, function: fn(Self) -> Self, contents: Contents, list: Vec<Self>, attributes: Table<Self>, } impl Display for Value { fn fmt(&self, _fmt: &mut std::fmt::Formatter) -> Result<(), std::fmt::Error> { self.print(); Ok(()) } } impl Add for Value { type Output = Value; fn add(self, rhs: Self) -> Self::Output { if self.value_type != rhs.value_type { return Value::from_problem(Problem::IncompatibleTypes); } match self.value_type { Type::Num => Value::from_number(self.as_number() + rhs.as_number()), Type::Str => Value::from_string(self.as_string() + &rhs.as_string()), _ => Value::from_problem(Problem::ValueError) } } } impl Sub for Value { type Output = Value; fn sub(self, rhs: Self) -> Self::Output { if self.value_type != rhs.value_type { return Value::from_problem(Problem::IncompatibleTypes); } if self.value_type != Type::Num { return Value::from_problem(Problem::ValueError); } return Value::from_number(self.as_number() - rhs.as_number()) } } impl Mul for Value { type Output = Value; fn mul(self, rhs: Self) -> Self::Output { if self.value_type != rhs.value_type { return Value::from_problem(Problem::IncompatibleTypes); } if self.value_type != Type::Num { return Value::from_problem(Problem::ValueError); } return Value::from_number(self.as_number() * rhs.as_number()) } } impl Div for Value { type Output = Value; fn div(self, rhs: Self) -> Self::Output { if self.value_type != rhs.value_type { return Value::from_problem(Problem::IncompatibleTypes); } if self.value_type != Type::Num { return Value::from_problem(Problem::ValueError); } return Value::from_number(self.as_number() / rhs.as_number()) } } impl Rem for Value { type Output = Value; fn rem(self, rhs: Self) -> Self::Output { if self.value_type != rhs.value_type { return Value::from_problem(Problem::IncompatibleTypes); } if self.value_type != Type::Num { return Value::from_problem(Problem::ValueError); } return Value::from_number(self.as_number() % rhs.as_number()) } } impl Not for Value { type Output = Value; fn not(self) -> Self::Output { match self.value_type { Type::Num => { if self == num("0") { return num("1"); } else { return num("0"); } }, _ => num("0") } } } impl Object for Value { fn new(value_type: Type, contents: Contents) -> Self { Self { value_type: value_type, contents: contents, function: |object: Self| object, list: vec![], attributes: Table::new() } } fn get_type(&self) -> Type {self.value_type.clone()} fn get_list(&self) -> Vec<Self> {self.list.clone()} fn get_contents(&self) -> Contents {self.contents.clone()} fn get_attributes(&self) -> Table<Self> {self.attributes.clone()} fn get_foreign_function(&self) -> fn(Self) -> Self {self.function.clone()} fn set_type(&mut self, value_type: Type) {self.value_type = value_type} fn set_list(&mut self, list: Vec<Self>) {self.list = list} fn set_contents(&mut self, contents: Contents) {self.contents = contents} fn set_attributes(&mut self, attributes: Table<Self>) {self.attributes = attributes} fn set_foreign_function(&mut self, function: fn(Self) -> Self) {self.function = function} }