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use super::ScalarInt;
use crate::mir::interpret::{AllocId, Scalar};
use crate::ty::{self, Ty, TyCtxt};
use rustc_macros::{HashStable, TyDecodable, TyEncodable};
#[derive(Copy, Clone, Debug, Hash, TyEncodable, TyDecodable, Eq, PartialEq, Ord, PartialOrd)]
#[derive(HashStable)]
/// This datastructure is used to represent the value of constants used in the type system.
///
/// We explicitly choose a different datastructure from the way values are processed within
/// CTFE, as in the type system equal values (according to their `PartialEq`) must also have
/// equal representation (`==` on the rustc data structure, e.g. `ValTree`) and vice versa.
/// Since CTFE uses `AllocId` to represent pointers, it often happens that two different
/// `AllocId`s point to equal values. So we may end up with different representations for
/// two constants whose value is `&42`. Furthermore any kind of struct that has padding will
/// have arbitrary values within that padding, even if the values of the struct are the same.
///
/// `ValTree` does not have this problem with representation, as it only contains integers or
/// lists of (nested) `ValTree`.
pub enum ValTree<'tcx> {
/// ZSTs, integers, `bool`, `char` are represented as scalars.
/// See the `ScalarInt` documentation for how `ScalarInt` guarantees that equal values
/// of these types have the same representation.
Leaf(ScalarInt),
//SliceOrStr(ValSlice<'tcx>),
// dont use SliceOrStr for now
/// The fields of any kind of aggregate. Structs, tuples and arrays are represented by
/// listing their fields' values in order.
/// Enums are represented by storing their discriminant as a field, followed by all
/// the fields of the variant.
Branch(&'tcx [ValTree<'tcx>]),
}
impl<'tcx> ValTree<'tcx> {
pub fn zst() -> Self {
Self::Branch(&[])
}
#[inline]
pub fn unwrap_leaf(self) -> ScalarInt {
match self {
Self::Leaf(s) => s,
_ => bug!("expected leaf, got {:?}", self),
}
}
#[inline]
pub fn unwrap_branch(self) -> &'tcx [Self] {
match self {
Self::Branch(branch) => branch,
_ => bug!("expected branch, got {:?}", self),
}
}
pub fn from_raw_bytes<'a>(tcx: TyCtxt<'tcx>, bytes: &'a [u8]) -> Self {
let branches = bytes.iter().map(|b| Self::Leaf(ScalarInt::from(*b)));
let interned = tcx.arena.alloc_from_iter(branches);
Self::Branch(interned)
}
pub fn from_scalar_int(i: ScalarInt) -> Self {
Self::Leaf(i)
}
pub fn try_to_scalar(self) -> Option<Scalar<AllocId>> {
self.try_to_scalar_int().map(Scalar::Int)
}
pub fn try_to_scalar_int(self) -> Option<ScalarInt> {
match self {
Self::Leaf(s) => Some(s),
Self::Branch(_) => None,
}
}
pub fn try_to_machine_usize(self, tcx: TyCtxt<'tcx>) -> Option<u64> {
self.try_to_scalar_int().map(|s| s.try_to_machine_usize(tcx).ok()).flatten()
}
/// Get the values inside the ValTree as a slice of bytes. This only works for
/// constants with types &str, &[u8], or [u8; _].
pub fn try_to_raw_bytes(self, tcx: TyCtxt<'tcx>, ty: Ty<'tcx>) -> Option<&'tcx [u8]> {
match ty.kind() {
ty::Ref(_, inner_ty, _) => match inner_ty.kind() {
// `&str` can be interpreted as raw bytes
ty::Str => {}
// `&[u8]` can be interpreted as raw bytes
ty::Slice(slice_ty) if *slice_ty == tcx.types.u8 => {}
// other `&_` can't be interpreted as raw bytes
_ => return None,
},
// `[u8; N]` can be interpreted as raw bytes
ty::Array(array_ty, _) if *array_ty == tcx.types.u8 => {}
// Otherwise, type cannot be interpreted as raw bytes
_ => return None,
}
Some(tcx.arena.alloc_from_iter(
self.unwrap_branch().into_iter().map(|v| v.unwrap_leaf().try_to_u8().unwrap()),
))
}
}
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