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|
use std::collections::HashMap;
use std::rc::Rc;
use crate::error::{TypeError, TypeMessage};
use crate::semantics::nze::lazy;
use crate::semantics::Binder;
use crate::semantics::{
apply_any, normalize_one_layer, normalize_tyexpr_whnf, squash_textlit,
TyEnv,
};
use crate::semantics::{type_of_builtin, typecheck, TyExpr, TyExprKind};
use crate::semantics::{BuiltinClosure, NzEnv, NzVar, VarEnv};
use crate::syntax::{
BinOp, Builtin, Const, ExprKind, Integer, InterpolatedTextContents, Label,
NaiveDouble, Natural, Span,
};
use crate::{Normalized, NormalizedExpr, ToExprOptions};
/// Stores a possibly unevaluated value. Gets (partially) normalized on-demand, sharing computation
/// automatically. Uses a Rc<RefCell> to share computation.
/// If you compare for equality two `Value`s, then equality will be up to alpha-equivalence
/// (renaming of bound variables) and beta-equivalence (normalization). It will recursively
/// normalize as needed.
#[derive(Clone)]
pub(crate) struct Value(Rc<ValueInternal>);
#[derive(Debug)]
struct ValueInternal {
kind: lazy::Lazy<Thunk, ValueKind>,
/// This is None if and only if `form` is `Sort` (which doesn't have a type)
ty: Option<Value>,
span: Span,
}
/// An unevaluated subexpression
#[derive(Debug, Clone)]
pub(crate) enum Thunk {
/// A completely unnormalized expression.
Thunk { env: NzEnv, body: TyExpr },
/// A partially normalized expression that may need to go through `normalize_one_layer`.
PartialExpr {
env: NzEnv,
expr: ExprKind<Value, Normalized>,
ty: Value,
},
}
/// An unevaluated subexpression that takes an argument.
#[derive(Debug, Clone)]
pub(crate) enum Closure {
/// Normal closure
Closure {
arg_ty: Value,
env: NzEnv,
body: TyExpr,
},
/// Closure that ignores the argument passed
ConstantClosure { body: Value },
}
/// A text literal with interpolations.
// Invariant: this must not contain interpolations that are themselves TextLits, and contiguous
// text values must be merged.
#[derive(Debug, Clone, PartialEq, Eq)]
pub(crate) struct TextLit(Vec<InterpolatedTextContents<Value>>);
/// This represents a value in Weak Head Normal Form (WHNF). This means that the value is
/// normalized up to the first constructor, but subexpressions may not be fully normalized.
/// When all the Values in a ValueKind are in WHNF, and recursively so, then the ValueKind is in
/// Normal Form (NF). This is because WHNF ensures that we have the first constructor of the NF; so
/// if we have the first constructor of the NF at all levels, we actually have the NF.
/// In particular, this means that once we get a `ValueKind`, it can be considered immutable, and
/// we only need to recursively normalize its sub-`Value`s to get to the NF.
#[derive(Debug, Clone, PartialEq, Eq)]
pub(crate) enum ValueKind {
/// Closures
LamClosure {
binder: Binder,
annot: Value,
closure: Closure,
},
PiClosure {
binder: Binder,
annot: Value,
closure: Closure,
},
AppliedBuiltin(BuiltinClosure<Value>),
Var(NzVar),
Const(Const),
BoolLit(bool),
NaturalLit(Natural),
IntegerLit(Integer),
DoubleLit(NaiveDouble),
EmptyOptionalLit(Value),
NEOptionalLit(Value),
// EmptyListLit(t) means `[] : List t`, not `[] : t`
EmptyListLit(Value),
NEListLit(Vec<Value>),
RecordType(HashMap<Label, Value>),
RecordLit(HashMap<Label, Value>),
UnionType(HashMap<Label, Option<Value>>),
// Also keep the type of the uniontype around
UnionConstructor(Label, HashMap<Label, Option<Value>>, Value),
// Also keep the type of the uniontype and the constructor around
UnionLit(Label, Value, HashMap<Label, Option<Value>>, Value, Value),
TextLit(TextLit),
Equivalence(Value, Value),
/// Invariant: evaluation must not be able to progress with `normalize_one_layer`?
PartialExpr(ExprKind<Value, Normalized>),
}
impl Value {
pub(crate) fn const_sort() -> Value {
ValueInternal::from_whnf(
ValueKind::Const(Const::Sort),
None,
Span::Artificial,
)
.into_value()
}
/// Construct a Value from a completely unnormalized expression.
pub(crate) fn new_thunk(env: &NzEnv, tye: TyExpr) -> Value {
ValueInternal::from_thunk(
Thunk::new(env, tye.clone()),
tye.get_type().ok(),
tye.span().clone(),
)
.into_value()
}
/// Construct a Value from a partially normalized expression that's not in WHNF.
pub(crate) fn from_partial_expr(
e: ExprKind<Value, Normalized>,
ty: Value,
) -> Value {
// TODO: env
let env = NzEnv::new();
ValueInternal::from_thunk(
Thunk::from_partial_expr(env, e, ty.clone()),
Some(ty),
Span::Artificial,
)
.into_value()
}
/// Make a Value from a ValueKind
pub(crate) fn from_kind_and_type(v: ValueKind, t: Value) -> Value {
ValueInternal::from_whnf(v, Some(t), Span::Artificial).into_value()
}
pub(crate) fn from_const(c: Const) -> Self {
let v = ValueKind::Const(c);
match c {
Const::Type => {
Value::from_kind_and_type(v, Value::from_const(Const::Kind))
}
Const::Kind => {
Value::from_kind_and_type(v, Value::from_const(Const::Sort))
}
Const::Sort => Value::const_sort(),
}
}
pub(crate) fn from_builtin(b: Builtin) -> Self {
Self::from_builtin_env(b, &NzEnv::new())
}
pub(crate) fn from_builtin_env(b: Builtin, env: &NzEnv) -> Self {
Value::from_kind_and_type(
ValueKind::from_builtin_env(b, env.clone()),
typecheck(&type_of_builtin(b)).unwrap().eval_closed_expr(),
)
}
pub(crate) fn from_text(txt: impl ToString) -> Self {
Value::from_kind_and_type(
ValueKind::TextLit(TextLit::from_text(txt.to_string())),
Value::from_builtin(Builtin::Text),
)
}
pub(crate) fn as_const(&self) -> Option<Const> {
match &*self.kind() {
ValueKind::Const(c) => Some(*c),
_ => None,
}
}
// pub(crate) fn span(&self) -> Span {
// self.0.span.clone()
// }
/// This is what you want if you want to pattern-match on the value.
/// WARNING: drop this ref before normalizing the same value or you will run into BorrowMut
/// panics.
pub(crate) fn kind(&self) -> &ValueKind {
self.0.kind()
}
/// Converts a value back to the corresponding AST expression.
pub(crate) fn to_expr(&self, opts: ToExprOptions) -> NormalizedExpr {
if opts.normalize {
self.normalize();
}
self.to_tyexpr_noenv().to_expr(opts)
}
pub(crate) fn to_expr_tyenv(&self, env: &TyEnv) -> NormalizedExpr {
self.to_tyexpr(env.as_varenv()).to_expr_tyenv(env)
}
pub(crate) fn to_whnf_ignore_type(&self) -> ValueKind {
self.kind().clone()
}
/// Before discarding type information, check that it matches the expected return type.
pub(crate) fn to_whnf_check_type(&self, ty: &Value) -> ValueKind {
self.check_type(ty);
self.to_whnf_ignore_type()
}
/// Normalizes contents to normal form; faster than `normalize` if
/// no one else shares this.
pub(crate) fn normalize_mut(&mut self) {
match Rc::get_mut(&mut self.0) {
// Mutate directly if sole owner
Some(vint) => vint.normalize_mut(),
// Otherwise mutate through the refcell
None => self.normalize(),
}
}
pub(crate) fn normalize(&self) {
self.0.normalize()
}
pub(crate) fn app(&self, v: Value) -> Value {
let body_t = match &*self.get_type_not_sort().kind() {
ValueKind::PiClosure { annot, closure, .. } => {
v.check_type(annot);
closure.apply(v.clone())
}
_ => unreachable!("Internal type error"),
};
Value::from_kind_and_type(apply_any(self.clone(), v, &body_t), body_t)
}
/// In debug mode, panic if the provided type doesn't match the value's type.
/// Otherwise does nothing.
pub(crate) fn check_type(&self, _ty: &Value) {
// TODO: reenable
// debug_assert_eq!(
// Some(ty),
// self.get_type().ok().as_ref(),
// "Internal type error"
// );
}
pub(crate) fn get_type(&self) -> Result<Value, TypeError> {
Ok(self.0.get_type()?.clone())
}
/// When we know the value isn't `Sort`, this gets the type directly
pub(crate) fn get_type_not_sort(&self) -> Value {
self.get_type()
.expect("Internal type error: value is `Sort` but shouldn't be")
}
pub fn to_tyexpr(&self, venv: VarEnv) -> TyExpr {
let map_uniontype = |kts: &HashMap<Label, Option<Value>>| {
ExprKind::UnionType(
kts.iter()
.map(|(k, v)| {
(k.clone(), v.as_ref().map(|v| v.to_tyexpr(venv)))
})
.collect(),
)
};
let tye = match &*self.kind() {
ValueKind::Var(v) => TyExprKind::Var(venv.lookup(v)),
ValueKind::AppliedBuiltin(closure) => closure.to_tyexprkind(venv),
self_kind => TyExprKind::Expr(match self_kind {
ValueKind::Var(..) | ValueKind::AppliedBuiltin(..) => {
unreachable!()
}
ValueKind::LamClosure {
binder,
annot,
closure,
} => ExprKind::Lam(
binder.to_label(),
annot.to_tyexpr(venv),
closure.to_tyexpr(venv),
),
ValueKind::PiClosure {
binder,
annot,
closure,
} => ExprKind::Pi(
binder.to_label(),
annot.to_tyexpr(venv),
closure.to_tyexpr(venv),
),
ValueKind::Const(c) => ExprKind::Const(*c),
ValueKind::BoolLit(b) => ExprKind::BoolLit(*b),
ValueKind::NaturalLit(n) => ExprKind::NaturalLit(*n),
ValueKind::IntegerLit(n) => ExprKind::IntegerLit(*n),
ValueKind::DoubleLit(n) => ExprKind::DoubleLit(*n),
ValueKind::EmptyOptionalLit(n) => ExprKind::App(
Value::from_builtin(Builtin::OptionalNone).to_tyexpr(venv),
n.to_tyexpr(venv),
),
ValueKind::NEOptionalLit(n) => {
ExprKind::SomeLit(n.to_tyexpr(venv))
}
ValueKind::EmptyListLit(n) => {
ExprKind::EmptyListLit(TyExpr::new(
TyExprKind::Expr(ExprKind::App(
Value::from_builtin(Builtin::List).to_tyexpr(venv),
n.to_tyexpr(venv),
)),
Some(Value::from_const(Const::Type)),
Span::Artificial,
))
}
ValueKind::NEListLit(elts) => ExprKind::NEListLit(
elts.iter().map(|v| v.to_tyexpr(venv)).collect(),
),
ValueKind::TextLit(elts) => ExprKind::TextLit(
elts.iter()
.map(|t| t.map_ref(|v| v.to_tyexpr(venv)))
.collect(),
),
ValueKind::RecordLit(kvs) => ExprKind::RecordLit(
kvs.iter()
.map(|(k, v)| (k.clone(), v.to_tyexpr(venv)))
.collect(),
),
ValueKind::RecordType(kts) => ExprKind::RecordType(
kts.iter()
.map(|(k, v)| (k.clone(), v.to_tyexpr(venv)))
.collect(),
),
ValueKind::UnionType(kts) => map_uniontype(kts),
ValueKind::UnionConstructor(l, kts, t) => ExprKind::Field(
TyExpr::new(
TyExprKind::Expr(map_uniontype(kts)),
Some(t.clone()),
Span::Artificial,
),
l.clone(),
),
ValueKind::UnionLit(l, v, kts, uniont, ctort) => ExprKind::App(
TyExpr::new(
TyExprKind::Expr(ExprKind::Field(
TyExpr::new(
TyExprKind::Expr(map_uniontype(kts)),
Some(uniont.clone()),
Span::Artificial,
),
l.clone(),
)),
Some(ctort.clone()),
Span::Artificial,
),
v.to_tyexpr(venv),
),
ValueKind::Equivalence(x, y) => ExprKind::BinOp(
BinOp::Equivalence,
x.to_tyexpr(venv),
y.to_tyexpr(venv),
),
ValueKind::PartialExpr(e) => e.map_ref(|v| v.to_tyexpr(venv)),
}),
};
TyExpr::new(tye, self.0.ty.clone(), self.0.span.clone())
}
pub fn to_tyexpr_noenv(&self) -> TyExpr {
self.to_tyexpr(VarEnv::new())
}
}
impl ValueInternal {
fn from_whnf(k: ValueKind, ty: Option<Value>, span: Span) -> Self {
ValueInternal {
kind: lazy::Lazy::new_completed(k),
ty,
span,
}
}
fn from_thunk(th: Thunk, ty: Option<Value>, span: Span) -> Self {
ValueInternal {
kind: lazy::Lazy::new(th),
ty,
span,
}
}
fn into_value(self) -> Value {
Value(Rc::new(self))
}
fn kind(&self) -> &ValueKind {
&self.kind
}
fn normalize(&self) {
self.kind().normalize();
}
// TODO: deprecated
fn normalize_mut(&mut self) {
self.normalize();
}
fn get_type(&self) -> Result<&Value, TypeError> {
match &self.ty {
Some(t) => Ok(t),
None => Err(TypeError::new(TypeMessage::Sort)),
}
}
}
impl ValueKind {
pub(crate) fn into_value_with_type(self, t: Value) -> Value {
Value::from_kind_and_type(self, t)
}
pub(crate) fn normalize(&self) {
match self {
ValueKind::Var(..)
| ValueKind::Const(_)
| ValueKind::BoolLit(_)
| ValueKind::NaturalLit(_)
| ValueKind::IntegerLit(_)
| ValueKind::DoubleLit(_) => {}
ValueKind::EmptyOptionalLit(tth) | ValueKind::EmptyListLit(tth) => {
tth.normalize();
}
ValueKind::NEOptionalLit(th) => {
th.normalize();
}
ValueKind::LamClosure { annot, closure, .. }
| ValueKind::PiClosure { annot, closure, .. } => {
annot.normalize();
closure.normalize();
}
ValueKind::AppliedBuiltin(closure) => closure.normalize(),
ValueKind::NEListLit(elts) => {
for x in elts.iter() {
x.normalize();
}
}
ValueKind::RecordLit(kvs) => {
for x in kvs.values() {
x.normalize();
}
}
ValueKind::RecordType(kvs) => {
for x in kvs.values() {
x.normalize();
}
}
ValueKind::UnionType(kts)
| ValueKind::UnionConstructor(_, kts, _) => {
for x in kts.values().flat_map(|opt| opt) {
x.normalize();
}
}
ValueKind::UnionLit(_, v, kts, _, _) => {
v.normalize();
for x in kts.values().flat_map(|opt| opt) {
x.normalize();
}
}
ValueKind::TextLit(tlit) => tlit.normalize(),
ValueKind::Equivalence(x, y) => {
x.normalize();
y.normalize();
}
ValueKind::PartialExpr(e) => {
e.map_ref(Value::normalize);
}
}
}
pub(crate) fn from_builtin(b: Builtin) -> ValueKind {
ValueKind::from_builtin_env(b, NzEnv::new())
}
pub(crate) fn from_builtin_env(b: Builtin, env: NzEnv) -> ValueKind {
ValueKind::AppliedBuiltin(BuiltinClosure::new(b, env))
}
}
impl Thunk {
pub fn new(env: &NzEnv, body: TyExpr) -> Self {
Thunk::Thunk {
env: env.clone(),
body,
}
}
pub fn from_partial_expr(
env: NzEnv,
expr: ExprKind<Value, Normalized>,
ty: Value,
) -> Self {
Thunk::PartialExpr { env, expr, ty }
}
pub fn eval(self) -> ValueKind {
match self {
Thunk::Thunk { env, body } => normalize_tyexpr_whnf(&body, &env),
Thunk::PartialExpr { env, expr, ty } => {
normalize_one_layer(expr, &ty, &env)
}
}
}
}
impl Closure {
pub fn new(arg_ty: Value, env: &NzEnv, body: TyExpr) -> Self {
Closure::Closure {
arg_ty,
env: env.clone(),
body,
}
}
/// New closure that ignores its argument
pub fn new_constant(body: Value) -> Self {
Closure::ConstantClosure { body }
}
pub fn apply(&self, val: Value) -> Value {
match self {
Closure::Closure { env, body, .. } => {
body.eval(&env.insert_value(val))
}
Closure::ConstantClosure { body, .. } => body.clone(),
}
}
fn apply_var(&self, var: NzVar) -> Value {
match self {
Closure::Closure { arg_ty, .. } => {
let val = Value::from_kind_and_type(
ValueKind::Var(var),
arg_ty.clone(),
);
self.apply(val)
}
Closure::ConstantClosure { body, .. } => body.clone(),
}
}
// TODO: somehow normalize the body. Might require to pass an env.
pub fn normalize(&self) {}
/// Convert this closure to a TyExpr
pub fn to_tyexpr(&self, venv: VarEnv) -> TyExpr {
self.apply_var(NzVar::new(venv.size()))
.to_tyexpr(venv.insert())
}
/// If the closure variable is free in the closure, return Err. Otherwise, return the value
/// with that free variable remove.
pub fn remove_binder(&self) -> Result<Value, ()> {
match self {
Closure::Closure { .. } => {
let v = NzVar::fresh();
// TODO: handle case where variable is used in closure
// TODO: return information about where the variable is used
Ok(self.apply_var(v))
}
Closure::ConstantClosure { body, .. } => Ok(body.clone()),
}
}
}
impl TextLit {
pub fn new(
elts: impl Iterator<Item = InterpolatedTextContents<Value>>,
) -> Self {
TextLit(squash_textlit(elts))
}
pub fn interpolate(v: Value) -> TextLit {
TextLit(vec![InterpolatedTextContents::Expr(v)])
}
pub fn from_text(s: String) -> TextLit {
TextLit(vec![InterpolatedTextContents::Text(s)])
}
pub fn concat(&self, other: &TextLit) -> TextLit {
TextLit::new(self.iter().chain(other.iter()).cloned())
}
pub fn is_empty(&self) -> bool {
self.0.is_empty()
}
/// If the literal consists of only one interpolation and not text, return the interpolated
/// value.
pub fn as_single_expr(&self) -> Option<&Value> {
use InterpolatedTextContents::Expr;
if let [Expr(v)] = self.0.as_slice() {
Some(v)
} else {
None
}
}
/// If there are no interpolations, return the corresponding text value.
pub fn as_text(&self) -> Option<String> {
use InterpolatedTextContents::Text;
if self.is_empty() {
Some(String::new())
} else if let [Text(s)] = self.0.as_slice() {
Some(s.clone())
} else {
None
}
}
pub fn iter(
&self,
) -> impl Iterator<Item = &InterpolatedTextContents<Value>> {
self.0.iter()
}
/// Normalize the contained values. This does not break the invariant because we have already
/// ensured that no contained values normalize to a TextLit.
pub fn normalize(&self) {
for x in self.0.iter() {
x.map_ref(Value::normalize);
}
}
}
impl lazy::Eval<ValueKind> for Thunk {
fn eval(self) -> ValueKind {
self.eval()
}
}
/// Compare two values for equality modulo alpha/beta-equivalence.
impl std::cmp::PartialEq for Value {
fn eq(&self, other: &Self) -> bool {
Rc::ptr_eq(&self.0, &other.0) || self.kind() == other.kind()
}
}
impl std::cmp::Eq for Value {}
impl std::cmp::PartialEq for Thunk {
fn eq(&self, _other: &Self) -> bool {
unreachable!(
"Trying to compare thunks but we should only compare WHNFs"
)
}
}
impl std::cmp::Eq for Thunk {}
impl std::cmp::PartialEq for Closure {
fn eq(&self, other: &Self) -> bool {
let v = NzVar::fresh();
self.apply_var(v) == other.apply_var(v)
}
}
impl std::cmp::Eq for Closure {}
impl std::fmt::Debug for Value {
fn fmt(&self, fmt: &mut std::fmt::Formatter<'_>) -> std::fmt::Result {
let vint: &ValueInternal = &self.0;
let kind = vint.kind();
if let ValueKind::Const(c) = kind {
return write!(fmt, "{:?}", c);
}
let mut x = fmt.debug_struct(&format!("Value@WHNF"));
x.field("kind", kind);
if let Some(ty) = vint.ty.as_ref() {
x.field("type", &ty);
} else {
x.field("type", &None::<()>);
}
x.finish()
}
}
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