//! This module implements the backing representation of runtime //! values in the Nix language. use std::cell::Ref; use std::ops::Deref; use std::rc::Rc; use std::{fmt::Display, path::PathBuf}; #[cfg(feature = "arbitrary")] mod arbitrary; mod attrs; mod builtin; mod function; mod list; mod path; mod string; mod thunk; use crate::errors::ErrorKind; use crate::opcode::StackIdx; use crate::vm::VM; pub use attrs::NixAttrs; pub use builtin::Builtin; pub use function::{Closure, Lambda}; pub use list::NixList; pub use path::canon_path; pub use string::NixString; pub use thunk::Thunk; #[warn(variant_size_differences)] #[derive(Clone, Debug, PartialEq)] pub enum Value { Null, Bool(bool), Integer(i64), Float(f64), String(NixString), Path(PathBuf), Attrs(Rc<NixAttrs>), List(NixList), Closure(Closure), Builtin(Builtin), // Internal values that, while they technically exist at runtime, // are never returned to or created directly by users. Thunk(Thunk), AttrNotFound, Blueprint(Rc<Lambda>), DeferredUpvalue(StackIdx), UnresolvedPath(PathBuf), } // Helper macros to generate the to_*/as_* macros while accounting for // thunks. /// Generate an `as_*` method returning a reference to the expected /// type, or a type error. This only works for types that implement /// `Copy`, as returning a reference to an inner thunk value is not /// possible. /// Generate an `as_*/to_*` accessor method that returns either the /// expected type, or a type error. macro_rules! gen_cast { ( $name:ident, $type:ty, $expected:expr, $variant:pat, $result:expr ) => { pub fn $name(&self) -> Result<$type, ErrorKind> { match self { $variant => Ok($result), Value::Thunk(thunk) => Self::$name(&thunk.value()), other => Err(type_error($expected, &other)), } } }; } /// Generate an `is_*` type-checking method. macro_rules! gen_is { ( $name:ident, $variant:pat ) => { pub fn $name(&self) -> bool { match self { $variant => true, Value::Thunk(thunk) => Self::$name(&thunk.value()), _ => false, } } }; } /// Describes what input types are allowed when coercing a `Value` to a string #[derive(Clone, Copy, Debug)] pub enum CoercionKind { /// Only coerce already "stringly" types like strings and paths, but also /// coerce sets that have a `__toString` attribute. Equivalent to /// `!coerceMore` in C++ Nix. Weak, /// Coerce all value types included by `Weak`, but also coerce `null`, /// booleans, integers, floats and lists of coercible types. Equivalent to /// `coerceMore` in C++ Nix. Strong, } /// A reference to a [`Value`] returned by a call to [`Value::force`], whether the value was /// originally a thunk or not. /// /// Implements [`Deref`] to [`Value`], so can generally be used as a [`Value`] pub(crate) enum ForceResult<'a> { ForcedThunk(Ref<'a, Value>), Immediate(&'a Value), } impl<'a> Deref for ForceResult<'a> { type Target = Value; fn deref(&self) -> &Self::Target { match self { ForceResult::ForcedThunk(r) => r, ForceResult::Immediate(v) => v, } } } impl<T> From<T> for Value where T: Into<NixString>, { fn from(t: T) -> Self { Self::String(t.into()) } } /// Constructors impl Value { /// Construct a [`Value::Attrs`] from a [`NixAttrs`]. pub fn attrs(attrs: NixAttrs) -> Self { Self::Attrs(Rc::new(attrs)) } } impl Value { /// Coerce a `Value` to a string. See `CoercionKind` for a rundown of what /// input types are accepted under what circumstances. pub fn coerce_to_string( &self, kind: CoercionKind, vm: &mut VM, ) -> Result<NixString, ErrorKind> { // TODO: eventually, this will need to handle string context and importing // files into the Nix store depending on what context the coercion happens in if let Value::Thunk(t) = self { t.force(vm)?; } match (self, kind) { // deal with thunks (Value::Thunk(t), _) => t.value().coerce_to_string(kind, vm), // coercions that are always done (Value::String(s), _) => Ok(s.clone()), // TODO(sterni): Think about proper encoding handling here. This needs // general consideration anyways, since one current discrepancy between // C++ Nix and Tvix is that the former's strings are arbitrary byte // sequences without NUL bytes, whereas Tvix only allows valid // Unicode. See also b/189. (Value::Path(p), _) => Ok(p.to_string_lossy().into_owned().into()), // Attribute sets can be converted to strings if they either have an // `__toString` attribute which holds a function that receives the // set itself or an `outPath` attribute which should be a string. // `__toString` is preferred. (Value::Attrs(attrs), _) => { match (attrs.select("__toString"), attrs.select("outPath")) { (None, None) => Err(ErrorKind::NotCoercibleToString { from: "set", kind }), (Some(f), _) => { // use a closure here to deal with the thunk borrow we need to do below let call_to_string = |value: &Value, vm: &mut VM| { // Leave self on the stack as an argument to the function call. vm.push(self.clone()); vm.call_value(value)?; let result = vm.pop(); match result { Value::String(s) => Ok(s), // Attribute set coercion actually works // recursively, e.g. you can even return // /another/ set with a __toString attr. _ => result.coerce_to_string(kind, vm), } }; if let Value::Thunk(t) = f { t.force(vm)?; let guard = t.value(); call_to_string(&*guard, vm) } else { call_to_string(f, vm) } } // Similarly to `__toString` we also coerce recursively for `outPath` (None, Some(s)) => s.coerce_to_string(kind, vm), } } // strong coercions (Value::Null, CoercionKind::Strong) | (Value::Bool(false), CoercionKind::Strong) => { Ok("".into()) } (Value::Bool(true), CoercionKind::Strong) => Ok("1".into()), (Value::Integer(i), CoercionKind::Strong) => Ok(format!("{i}").into()), (Value::Float(f), CoercionKind::Strong) => { // contrary to normal Display, coercing a float to a string will // result in unconditional 6 decimal places Ok(format!("{:.6}", f).into()) } // Lists are coerced by coercing their elements and interspersing spaces (Value::List(l), CoercionKind::Strong) => { // TODO(sterni): use intersperse when it becomes available? // https://github.com/rust-lang/rust/issues/79524 l.iter() .map(|v| v.coerce_to_string(kind, vm)) .reduce(|acc, string| { let a = acc?; let s = &string?; Ok(a.concat(&" ".into()).concat(s)) }) // None from reduce indicates empty iterator .unwrap_or_else(|| Ok("".into())) } (Value::Closure(_), _) | (Value::Builtin(_), _) | (Value::Null, _) | (Value::Bool(_), _) | (Value::Integer(_), _) | (Value::Float(_), _) | (Value::List(_), _) => Err(ErrorKind::NotCoercibleToString { from: self.type_of(), kind, }), (Value::AttrNotFound, _) | (Value::Blueprint(_), _) | (Value::DeferredUpvalue(_), _) | (Value::UnresolvedPath(_), _) => { panic!("tvix bug: .coerce_to_string() called on internal value") } } } pub fn type_of(&self) -> &'static str { match self { Value::Null => "null", Value::Bool(_) => "bool", Value::Integer(_) => "int", Value::Float(_) => "float", Value::String(_) => "string", Value::Path(_) => "path", Value::Attrs(_) => "set", Value::List(_) => "list", Value::Closure(_) | Value::Builtin(_) => "lambda", // Internal types Value::Thunk(_) | Value::AttrNotFound | Value::Blueprint(_) | Value::DeferredUpvalue(_) | Value::UnresolvedPath(_) => "internal", } } gen_cast!(as_bool, bool, "bool", Value::Bool(b), *b); gen_cast!(as_int, i64, "int", Value::Integer(x), *x); gen_cast!(to_str, NixString, "string", Value::String(s), s.clone()); gen_cast!(to_attrs, Rc<NixAttrs>, "set", Value::Attrs(a), a.clone()); gen_cast!(to_list, NixList, "list", Value::List(l), l.clone()); gen_cast!(to_closure, Closure, "lambda", Value::Closure(c), c.clone()); gen_is!(is_path, Value::Path(_)); gen_is!(is_number, Value::Integer(_) | Value::Float(_)); gen_is!(is_bool, Value::Bool(_)); /// Compare `self` against `other` for equality using Nix equality semantics. /// /// Takes a reference to the `VM` to allow forcing thunks during comparison pub fn nix_eq(&self, other: &Self, vm: &mut VM) -> Result<bool, ErrorKind> { match (self, other) { // Trivial comparisons (Value::Null, Value::Null) => Ok(true), (Value::Bool(b1), Value::Bool(b2)) => Ok(b1 == b2), (Value::List(l1), Value::List(l2)) => l1.nix_eq(l2, vm), (Value::String(s1), Value::String(s2)) => Ok(s1 == s2), (Value::Path(p1), Value::Path(p2)) => Ok(p1 == p2), // Numerical comparisons (they work between float & int) (Value::Integer(i1), Value::Integer(i2)) => Ok(i1 == i2), (Value::Integer(i), Value::Float(f)) => Ok(*i as f64 == *f), (Value::Float(f1), Value::Float(f2)) => Ok(f1 == f2), (Value::Float(f), Value::Integer(i)) => Ok(*i as f64 == *f), // Optimised attribute set comparison (Value::Attrs(a1), Value::Attrs(a2)) => Ok(Rc::ptr_eq(a1, a2) || a1.nix_eq(a2, vm)?), // If either value is a thunk, the thunk should be forced, and then the resulting value // must be compared instead. (Value::Thunk(lhs), Value::Thunk(rhs)) => { lhs.force(vm)?; rhs.force(vm)?; Ok(*lhs.value() == *rhs.value()) } (Value::Thunk(lhs), rhs) => { lhs.force(vm)?; Ok(&*lhs.value() == rhs) } (lhs, Value::Thunk(rhs)) => { rhs.force(vm)?; Ok(lhs == &*rhs.value()) } // Everything else is either incomparable (e.g. internal // types) or false. // TODO(tazjin): mirror Lambda equality behaviour _ => Ok(false), } } /// Ensure `self` is forced if it is a thunk, and return a reference to the resulting value. pub(crate) fn force(&self, vm: &mut VM) -> Result<ForceResult, ErrorKind> { match self { Self::Thunk(thunk) => { thunk.force(vm)?; Ok(ForceResult::ForcedThunk(thunk.value())) } _ => Ok(ForceResult::Immediate(self)), } } } impl Display for Value { fn fmt(&self, f: &mut std::fmt::Formatter<'_>) -> std::fmt::Result { match self { Value::Null => f.write_str("null"), Value::Bool(true) => f.write_str("true"), Value::Bool(false) => f.write_str("false"), Value::Integer(num) => write!(f, "{}", num), Value::String(s) => s.fmt(f), Value::Path(p) => p.display().fmt(f), Value::Attrs(attrs) => attrs.fmt(f), Value::List(list) => list.fmt(f), Value::Closure(_) => f.write_str("lambda"), // TODO: print position Value::Builtin(builtin) => builtin.fmt(f), // Nix prints floats with a maximum precision of 5 digits // only. Value::Float(num) => { write!(f, "{}", format!("{:.5}", num).trim_end_matches(['.', '0'])) } // Delegate thunk display to the type, as it must handle // the case of already evaluated thunks. Value::Thunk(t) => t.fmt(f), // internal types Value::AttrNotFound => f.write_str("internal[not found]"), Value::Blueprint(_) => f.write_str("internal[blueprint]"), Value::DeferredUpvalue(_) => f.write_str("internal[deferred_upvalue]"), Value::UnresolvedPath(_) => f.write_str("internal[unresolved_path]"), } } } impl From<bool> for Value { fn from(b: bool) -> Self { Value::Bool(b) } } impl From<i64> for Value { fn from(i: i64) -> Self { Self::Integer(i) } } impl From<PathBuf> for Value { fn from(path: PathBuf) -> Self { Self::Path(path) } } impl From<Vec<Value>> for Value { fn from(val: Vec<Value>) -> Self { Self::List(NixList::from(val)) } } impl TryFrom<serde_json::Value> for Value { type Error = ErrorKind; fn try_from(value: serde_json::Value) -> Result<Self, Self::Error> { // TODO(grfn): Replace with a real serde::Deserialize impl (for perf) match value { serde_json::Value::Null => Ok(Self::Null), serde_json::Value::Bool(b) => Ok(Self::Bool(b)), serde_json::Value::Number(n) => { if let Some(i) = n.as_i64() { Ok(Self::Integer(i)) } else if let Some(f) = n.as_f64() { Ok(Self::Float(f)) } else { Err(ErrorKind::FromJsonError(format!( "JSON number not representable as Nix value: {n}" ))) } } serde_json::Value::String(s) => Ok(s.into()), serde_json::Value::Array(a) => Ok(a .into_iter() .map(Value::try_from) .collect::<Result<Vec<_>, _>>()? .into()), serde_json::Value::Object(obj) => { match (obj.len(), obj.get("name"), obj.get("value")) { (2, Some(name), Some(value)) => Ok(Self::attrs(NixAttrs::from_kv( name.clone().try_into()?, value.clone().try_into()?, ))), _ => Ok(Self::attrs(NixAttrs::from_map( obj.into_iter() .map(|(k, v)| Ok((k.into(), v.try_into()?))) .collect::<Result<_, ErrorKind>>()?, ))), } } } } } fn type_error(expected: &'static str, actual: &Value) -> ErrorKind { ErrorKind::TypeError { expected, actual: actual.type_of(), } } #[cfg(test)] mod tests { use super::*; mod nix_eq { use crate::observer::NoOpObserver; use super::*; use proptest::prelude::ProptestConfig; use test_strategy::proptest; #[proptest(ProptestConfig { cases: 5, ..Default::default() })] fn reflexive(x: Value) { let mut observer = NoOpObserver {}; let mut vm = VM::new(Default::default(), &mut observer); assert!(x.nix_eq(&x, &mut vm).unwrap()) } #[proptest(ProptestConfig { cases: 5, ..Default::default() })] fn symmetric(x: Value, y: Value) { let mut observer = NoOpObserver {}; let mut vm = VM::new(Default::default(), &mut observer); assert_eq!( x.nix_eq(&y, &mut vm).unwrap(), y.nix_eq(&x, &mut vm).unwrap() ) } #[proptest(ProptestConfig { cases: 5, ..Default::default() })] fn transitive(x: Value, y: Value, z: Value) { let mut observer = NoOpObserver {}; let mut vm = VM::new(Default::default(), &mut observer); if x.nix_eq(&y, &mut vm).unwrap() && y.nix_eq(&z, &mut vm).unwrap() { assert!(x.nix_eq(&z, &mut vm).unwrap()) } } #[test] fn list_int_float_fungibility() { let mut observer = NoOpObserver {}; let mut vm = VM::new(Default::default(), &mut observer); let v1 = Value::List(NixList::from(vec![Value::Integer(1)])); let v2 = Value::List(NixList::from(vec![Value::Float(1.0)])); assert!(v1.nix_eq(&v2, &mut vm).unwrap()) } } }