use serde::{Deserialize, Serialize}; use strum_macros::EnumIter; use std::fmt::Display; use crate::SyntaxShape; #[derive(Clone, Debug, Default, EnumIter, PartialEq, Eq, Serialize, Deserialize, Hash)] pub enum Type { Any, Binary, Block, Bool, CellPath, Closure, Custom(String), Date, Duration, Error, Filesize, Float, Int, List(Box), ListStream, #[default] Nothing, Number, Range, Record(Vec<(String, Type)>), Signature, String, Table(Vec<(String, Type)>), } impl Type { pub fn is_subtype(&self, other: &Type) -> bool { match (self, other) { (t, u) if t == u => true, (Type::Float, Type::Number) => true, (Type::Int, Type::Number) => true, (_, Type::Any) => true, (Type::List(t), Type::List(u)) if t.is_subtype(u) => true, // List is covariant // TODO: Currently Record types specify their field types. If we are // going to continue to do that, then it might make sense to define // a "structural subtyping" whereby r1 is a subtype of r2 is the // fields of r1 are a "subset" of the fields of r2 (names are a // subset and agree on types). However, if we do that, then we need // a way to specify the supertype of all Records. For now, we define // any Record to be a subtype of any other Record. This allows // Record(vec![]) to be used as an ad-hoc supertype of all Records // in command signatures. This comment applies to Tables also, with // "columns" in place of "fields". (Type::Record(_), Type::Record(_)) => true, (Type::Table(_), Type::Table(_)) => true, _ => false, } } pub fn is_numeric(&self) -> bool { matches!(self, Type::Int | Type::Float | Type::Number) } /// Does this type represent a data structure containing values that can be addressed using 'cell paths'? pub fn accepts_cell_paths(&self) -> bool { matches!(self, Type::List(_) | Type::Record(_) | Type::Table(_)) } pub fn to_shape(&self) -> SyntaxShape { match self { Type::Int => SyntaxShape::Int, Type::Float => SyntaxShape::Number, Type::Range => SyntaxShape::Range, Type::Bool => SyntaxShape::Boolean, Type::String => SyntaxShape::String, Type::Block => SyntaxShape::Block, // FIXME needs more accuracy Type::Closure => SyntaxShape::Closure(None), // FIXME needs more accuracy Type::CellPath => SyntaxShape::CellPath, Type::Duration => SyntaxShape::Duration, Type::Date => SyntaxShape::DateTime, Type::Filesize => SyntaxShape::Filesize, Type::List(x) => SyntaxShape::List(Box::new(x.to_shape())), Type::Number => SyntaxShape::Number, Type::Nothing => SyntaxShape::Nothing, Type::Record(_) => SyntaxShape::Record, Type::Table(_) => SyntaxShape::Table, Type::ListStream => SyntaxShape::List(Box::new(SyntaxShape::Any)), Type::Any => SyntaxShape::Any, Type::Error => SyntaxShape::Any, Type::Binary => SyntaxShape::Binary, Type::Custom(_) => SyntaxShape::Any, Type::Signature => SyntaxShape::Signature, } } } impl Display for Type { fn fmt(&self, f: &mut std::fmt::Formatter<'_>) -> std::fmt::Result { match self { Type::Block => write!(f, "block"), Type::Closure => write!(f, "closure"), Type::Bool => write!(f, "bool"), Type::CellPath => write!(f, "cell path"), Type::Date => write!(f, "date"), Type::Duration => write!(f, "duration"), Type::Filesize => write!(f, "filesize"), Type::Float => write!(f, "float"), Type::Int => write!(f, "int"), Type::Range => write!(f, "range"), Type::Record(fields) => { if fields.is_empty() { write!(f, "record") } else { write!( f, "record<{}>", fields .iter() .map(|(x, y)| format!("{}: {}", x, y)) .collect::>() .join(", "), ) } } Type::Table(columns) => { if columns.is_empty() { write!(f, "table") } else { write!( f, "table<{}>", columns .iter() .map(|(x, y)| format!("{}: {}", x, y)) .collect::>() .join(", ") ) } } Type::List(l) => write!(f, "list<{}>", l), Type::Nothing => write!(f, "nothing"), Type::Number => write!(f, "number"), Type::String => write!(f, "string"), Type::ListStream => write!(f, "list stream"), Type::Any => write!(f, "any"), Type::Error => write!(f, "error"), Type::Binary => write!(f, "binary"), Type::Custom(custom) => write!(f, "{}", custom), Type::Signature => write!(f, "signature"), } } } #[cfg(test)] mod tests { use super::Type; use strum::IntoEnumIterator; mod subtype_relation { use super::*; #[test] fn test_reflexivity() { for ty in Type::iter() { assert!(ty.is_subtype(&ty)); } } #[test] fn test_any_is_top_type() { for ty in Type::iter() { assert!(ty.is_subtype(&Type::Any)); } } #[test] fn test_number_supertype() { assert!(Type::Int.is_subtype(&Type::Number)); assert!(Type::Float.is_subtype(&Type::Number)); } #[test] fn test_list_covariance() { for ty1 in Type::iter() { for ty2 in Type::iter() { let list_ty1 = Type::List(Box::new(ty1.clone())); let list_ty2 = Type::List(Box::new(ty2.clone())); assert_eq!(list_ty1.is_subtype(&list_ty2), ty1.is_subtype(&ty2)); } } } } }