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use crate::syntax::map::{DupTreeMap, DupTreeSet};
use crate::syntax::visitor::{self, ExprKindMutVisitor, ExprKindVisitor};
use crate::syntax::*;
pub type Integer = isize;
pub type Natural = usize;
pub type Double = NaiveDouble;
/// Double with bitwise equality
#[derive(Debug, Copy, Clone)]
pub struct NaiveDouble(f64);
/// Constants for a pure type system
#[derive(Debug, Copy, Clone, PartialEq, Eq, PartialOrd, Ord, Hash)]
pub enum Const {
Type,
Kind,
Sort,
}
/// Bound variable
///
/// The `Label` field is the variable's name (i.e. \"`x`\").
/// The `Int` field is a DeBruijn index.
/// See dhall-lang/standard/semantics.md for details
#[derive(Debug, Clone, PartialEq, Eq, Hash)]
pub struct V(pub Label, pub usize);
// Definition order must match precedence order for
// pretty-printing to work correctly
#[derive(Debug, Copy, Clone, PartialEq, Eq, PartialOrd, Ord, Hash)]
pub enum BinOp {
/// `x ? y`
ImportAlt,
/// `x || y`
BoolOr,
/// `x + y`
NaturalPlus,
/// `x ++ y`
TextAppend,
/// `x # y`
ListAppend,
/// `x && y`
BoolAnd,
/// `x ∧ y`
RecursiveRecordMerge,
/// `x ⫽ y`
RightBiasedRecordMerge,
/// `x ⩓ y`
RecursiveRecordTypeMerge,
/// `x * y`
NaturalTimes,
/// `x == y`
BoolEQ,
/// `x != y`
BoolNE,
/// x === y
Equivalence,
}
/// Built-ins
#[derive(Debug, Copy, Clone, PartialEq, Eq, Hash)]
pub enum Builtin {
Bool,
Natural,
Integer,
Double,
Text,
List,
Optional,
OptionalNone,
NaturalBuild,
NaturalFold,
NaturalIsZero,
NaturalEven,
NaturalOdd,
NaturalToInteger,
NaturalShow,
NaturalSubtract,
IntegerToDouble,
IntegerShow,
IntegerNegate,
IntegerClamp,
DoubleShow,
ListBuild,
ListFold,
ListLength,
ListHead,
ListLast,
ListIndexed,
ListReverse,
OptionalFold,
OptionalBuild,
TextShow,
}
// Each node carries an annotation.
#[derive(Debug, Clone)]
pub struct Expr<Embed> {
kind: Box<ExprKind<Expr<Embed>, Embed>>,
span: Span,
}
pub type UnspannedExpr<Embed> = ExprKind<Expr<Embed>, Embed>;
/// Syntax tree for expressions
// Having the recursion out of the enum definition enables writing
// much more generic code and improves pattern-matching behind
// smart pointers.
#[derive(Debug, Clone, PartialEq, Eq, Hash)]
pub enum ExprKind<SubExpr, Embed> {
Const(Const),
/// `x`
/// `x@n`
Var(V),
/// `λ(x : A) -> b`
Lam(Label, SubExpr, SubExpr),
/// `A -> B`
/// `∀(x : A) -> B`
Pi(Label, SubExpr, SubExpr),
/// `f a`
App(SubExpr, SubExpr),
/// `let x = r in e`
/// `let x : t = r in e`
Let(Label, Option<SubExpr>, SubExpr, SubExpr),
/// `x : t`
Annot(SubExpr, SubExpr),
/// `assert : t`
Assert(SubExpr),
/// Built-in values
Builtin(Builtin),
// Binary operations
BinOp(BinOp, SubExpr, SubExpr),
/// `True`
BoolLit(bool),
/// `if x then y else z`
BoolIf(SubExpr, SubExpr, SubExpr),
/// `1`
NaturalLit(Natural),
/// `+2`
IntegerLit(Integer),
/// `3.24`
DoubleLit(Double),
/// `"Some ${interpolated} text"`
TextLit(InterpolatedText<SubExpr>),
/// `[] : t`
EmptyListLit(SubExpr),
/// `[x, y, z]`
NEListLit(Vec<SubExpr>),
/// `Some e`
SomeLit(SubExpr),
/// `{ k1 : t1, k2 : t1 }`
RecordType(DupTreeMap<Label, SubExpr>),
/// `{ k1 = v1, k2 = v2 }`
RecordLit(DupTreeMap<Label, SubExpr>),
/// `< k1 : t1, k2 >`
UnionType(DupTreeMap<Label, Option<SubExpr>>),
/// `merge x y : t`
Merge(SubExpr, SubExpr, Option<SubExpr>),
/// `toMap x : t`
ToMap(SubExpr, Option<SubExpr>),
/// `e.x`
Field(SubExpr, Label),
/// `e.{ x, y, z }`
Projection(SubExpr, DupTreeSet<Label>),
/// `e.(t)`
ProjectionByExpr(SubExpr, SubExpr),
/// `x::y`
Completion(SubExpr, SubExpr),
/// `./some/path`
Import(Import<SubExpr>),
/// Embeds the result of resolving an import
Embed(Embed),
}
impl<SE, E> ExprKind<SE, E> {
pub fn traverse_ref_maybe_binder<'a, SE2, Err>(
&'a self,
visit: impl FnMut(Option<&'a Label>, &'a SE) -> Result<SE2, Err>,
) -> Result<ExprKind<SE2, E>, Err>
where
E: Clone,
{
visitor::TraverseRefMaybeBinderVisitor(visit).visit(self)
}
pub fn traverse_ref_with_special_handling_of_binders<'a, SE2, Err>(
&'a self,
mut visit_subexpr: impl FnMut(&'a SE) -> Result<SE2, Err>,
mut visit_under_binder: impl FnMut(&'a Label, &'a SE) -> Result<SE2, Err>,
) -> Result<ExprKind<SE2, E>, Err>
where
E: Clone,
{
self.traverse_ref_maybe_binder(|l, x| match l {
None => visit_subexpr(x),
Some(l) => visit_under_binder(l, x),
})
}
pub(crate) fn traverse_ref<'a, SE2, Err>(
&'a self,
mut visit_subexpr: impl FnMut(&'a SE) -> Result<SE2, Err>,
) -> Result<ExprKind<SE2, E>, Err>
where
E: Clone,
{
self.traverse_ref_maybe_binder(|_, e| visit_subexpr(e))
}
fn traverse_mut<'a, Err>(
&'a mut self,
visit_subexpr: impl FnMut(&'a mut SE) -> Result<(), Err>,
) -> Result<(), Err> {
visitor::TraverseMutVisitor { visit_subexpr }.visit(self)
}
pub fn map_ref_maybe_binder<'a, SE2>(
&'a self,
mut map: impl FnMut(Option<&'a Label>, &'a SE) -> SE2,
) -> ExprKind<SE2, E>
where
E: Clone,
{
trivial_result(self.traverse_ref_maybe_binder(|l, x| Ok(map(l, x))))
}
pub fn map_ref_with_special_handling_of_binders<'a, SE2>(
&'a self,
mut map_subexpr: impl FnMut(&'a SE) -> SE2,
mut map_under_binder: impl FnMut(&'a Label, &'a SE) -> SE2,
) -> ExprKind<SE2, E>
where
E: Clone,
{
self.map_ref_maybe_binder(|l, x| match l {
None => map_subexpr(x),
Some(l) => map_under_binder(l, x),
})
}
pub fn map_ref<'a, SE2>(
&'a self,
mut map_subexpr: impl FnMut(&'a SE) -> SE2,
) -> ExprKind<SE2, E>
where
E: Clone,
{
self.map_ref_maybe_binder(|_, e| map_subexpr(e))
}
pub fn map_mut<'a>(&'a mut self, mut map_subexpr: impl FnMut(&'a mut SE)) {
trivial_result(self.traverse_mut(|x| Ok(map_subexpr(x))))
}
}
impl<E> Expr<E> {
pub fn as_ref(&self) -> &UnspannedExpr<E> {
&self.kind
}
pub fn span(&self) -> Span {
self.span.clone()
}
pub fn new(kind: UnspannedExpr<E>, span: Span) -> Self {
Expr {
kind: Box::new(kind),
span,
}
}
pub fn rewrap<E2>(&self, kind: UnspannedExpr<E2>) -> Expr<E2> {
Expr {
kind: Box::new(kind),
span: self.span.clone(),
}
}
pub fn traverse_resolve_mut<Err, F1>(
&mut self,
f: &mut F1,
) -> Result<(), Err>
where
E: Clone,
F1: FnMut(Import<Expr<E>>) -> Result<E, Err>,
{
match self.kind.as_mut() {
ExprKind::BinOp(BinOp::ImportAlt, l, r) => {
let garbage_expr = ExprKind::BoolLit(false);
let new_self = if l.traverse_resolve_mut(f).is_ok() {
l
} else {
r.traverse_resolve_mut(f)?;
r
};
*self.kind =
std::mem::replace(new_self.kind.as_mut(), garbage_expr);
}
_ => {
self.kind.traverse_mut(|e| e.traverse_resolve_mut(f))?;
if let ExprKind::Import(import) = self.kind.as_mut() {
let garbage_import = Import {
mode: ImportMode::Code,
location: ImportLocation::Missing,
hash: None,
};
// Move out of &mut import
let import = std::mem::replace(import, garbage_import);
*self.kind = ExprKind::Embed(f(import)?);
}
}
}
Ok(())
}
}
pub fn trivial_result<T>(x: Result<T, !>) -> T {
match x {
Ok(x) => x,
Err(e) => e,
}
}
impl PartialEq for NaiveDouble {
fn eq(&self, other: &Self) -> bool {
self.0.to_bits() == other.0.to_bits()
}
}
impl Eq for NaiveDouble {}
impl std::hash::Hash for NaiveDouble {
fn hash<H>(&self, state: &mut H)
where
H: std::hash::Hasher,
{
self.0.to_bits().hash(state)
}
}
impl From<f64> for NaiveDouble {
fn from(x: f64) -> Self {
NaiveDouble(x)
}
}
impl From<NaiveDouble> for f64 {
fn from(x: NaiveDouble) -> f64 {
x.0
}
}
impl From<Label> for V {
fn from(x: Label) -> V {
V(x, 0)
}
}
impl<Embed: PartialEq> std::cmp::PartialEq for Expr<Embed> {
fn eq(&self, other: &Self) -> bool {
self.kind == other.kind
}
}
impl<Embed: Eq> std::cmp::Eq for Expr<Embed> {}
impl<Embed: std::hash::Hash> std::hash::Hash for Expr<Embed> {
fn hash<H>(&self, state: &mut H)
where
H: std::hash::Hasher,
{
self.kind.hash(state)
}
}
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