use super::{AllocId, InterpResult}; use rustc_macros::HashStable; use rustc_target::abi::{HasDataLayout, Size}; use std::fmt; //////////////////////////////////////////////////////////////////////////////// // Pointer arithmetic //////////////////////////////////////////////////////////////////////////////// pub trait PointerArithmetic: HasDataLayout { // These are not supposed to be overridden. #[inline(always)] fn pointer_size(&self) -> Size { self.data_layout().pointer_size } #[inline(always)] fn max_size_of_val(&self) -> Size { Size::from_bytes(self.machine_isize_max()) } #[inline] fn machine_usize_max(&self) -> u64 { self.pointer_size().unsigned_int_max().try_into().unwrap() } #[inline] fn machine_isize_min(&self) -> i64 { self.pointer_size().signed_int_min().try_into().unwrap() } #[inline] fn machine_isize_max(&self) -> i64 { self.pointer_size().signed_int_max().try_into().unwrap() } #[inline] fn machine_usize_to_isize(&self, val: u64) -> i64 { let val = val as i64; // Now wrap-around into the machine_isize range. if val > self.machine_isize_max() { // This can only happen if the ptr size is < 64, so we know max_usize_plus_1 fits into // i64. debug_assert!(self.pointer_size().bits() < 64); let max_usize_plus_1 = 1u128 << self.pointer_size().bits(); val - i64::try_from(max_usize_plus_1).unwrap() } else { val } } /// Helper function: truncate given value-"overflowed flag" pair to pointer size and /// update "overflowed flag" if there was an overflow. /// This should be called by all the other methods before returning! #[inline] fn truncate_to_ptr(&self, (val, over): (u64, bool)) -> (u64, bool) { let val = u128::from(val); let max_ptr_plus_1 = 1u128 << self.pointer_size().bits(); (u64::try_from(val % max_ptr_plus_1).unwrap(), over || val >= max_ptr_plus_1) } #[inline] fn overflowing_offset(&self, val: u64, i: u64) -> (u64, bool) { // We do not need to check if i fits in a machine usize. If it doesn't, // either the wrapping_add will wrap or res will not fit in a pointer. let res = val.overflowing_add(i); self.truncate_to_ptr(res) } #[inline] fn overflowing_signed_offset(&self, val: u64, i: i64) -> (u64, bool) { // We need to make sure that i fits in a machine isize. let n = i.unsigned_abs(); if i >= 0 { let (val, over) = self.overflowing_offset(val, n); (val, over || i > self.machine_isize_max()) } else { let res = val.overflowing_sub(n); let (val, over) = self.truncate_to_ptr(res); (val, over || i < self.machine_isize_min()) } } #[inline] fn offset<'tcx>(&self, val: u64, i: u64) -> InterpResult<'tcx, u64> { let (res, over) = self.overflowing_offset(val, i); if over { throw_ub!(PointerArithOverflow) } else { Ok(res) } } #[inline] fn signed_offset<'tcx>(&self, val: u64, i: i64) -> InterpResult<'tcx, u64> { let (res, over) = self.overflowing_signed_offset(val, i); if over { throw_ub!(PointerArithOverflow) } else { Ok(res) } } } impl PointerArithmetic for T {} /// This trait abstracts over the kind of provenance that is associated with a `Pointer`. It is /// mostly opaque; the `Machine` trait extends it with some more operations that also have access to /// some global state. /// The `Debug` rendering is used to distplay bare provenance, and for the default impl of `fmt`. pub trait Provenance: Copy + fmt::Debug { /// Says whether the `offset` field of `Pointer`s with this provenance is the actual physical address. /// - If `false`, the offset *must* be relative. This means the bytes representing a pointer are /// different from what the Abstract Machine prescribes, so the interpreter must prevent any /// operation that would inspect the underlying bytes of a pointer, such as ptr-to-int /// transmutation. A `ReadPointerAsBytes` error will be raised in such situations. /// - If `true`, the interpreter will permit operations to inspect the underlying bytes of a /// pointer, and implement ptr-to-int transmutation by stripping provenance. const OFFSET_IS_ADDR: bool; /// Determines how a pointer should be printed. /// /// Default impl is only good for when `OFFSET_IS_ADDR == true`. fn fmt(ptr: &Pointer, f: &mut fmt::Formatter<'_>) -> fmt::Result where Self: Sized, { assert!(Self::OFFSET_IS_ADDR); let (prov, addr) = ptr.into_parts(); // address is absolute write!(f, "{:#x}", addr.bytes())?; if f.alternate() { write!(f, "{prov:#?}")?; } else { write!(f, "{prov:?}")?; } Ok(()) } /// If `OFFSET_IS_ADDR == false`, provenance must always be able to /// identify the allocation this ptr points to (i.e., this must return `Some`). /// Otherwise this function is best-effort (but must agree with `Machine::ptr_get_alloc`). /// (Identifying the offset in that allocation, however, is harder -- use `Memory::ptr_get_alloc` for that.) fn get_alloc_id(self) -> Option; /// Defines the 'join' of provenance: what happens when doing a pointer load and different bytes have different provenance. fn join(left: Option, right: Option) -> Option; } impl Provenance for AllocId { // With the `AllocId` as provenance, the `offset` is interpreted *relative to the allocation*, // so ptr-to-int casts are not possible (since we do not know the global physical offset). const OFFSET_IS_ADDR: bool = false; fn fmt(ptr: &Pointer, f: &mut fmt::Formatter<'_>) -> fmt::Result { // Forward `alternate` flag to `alloc_id` printing. if f.alternate() { write!(f, "{:#?}", ptr.provenance)?; } else { write!(f, "{:?}", ptr.provenance)?; } // Print offset only if it is non-zero. if ptr.offset.bytes() > 0 { write!(f, "+{:#x}", ptr.offset.bytes())?; } Ok(()) } fn get_alloc_id(self) -> Option { Some(self) } fn join(_left: Option, _right: Option) -> Option { panic!("merging provenance is not supported when `OFFSET_IS_ADDR` is false") } } /// Represents a pointer in the Miri engine. /// /// Pointers are "tagged" with provenance information; typically the `AllocId` they belong to. #[derive(Copy, Clone, Eq, PartialEq, TyEncodable, TyDecodable, Hash)] #[derive(HashStable)] pub struct Pointer { pub(super) offset: Size, // kept private to avoid accidental misinterpretation (meaning depends on `Prov` type) pub provenance: Prov, } static_assert_size!(Pointer, 16); // `Option` pointers are also passed around quite a bit // (but not stored in permanent machine state). static_assert_size!(Pointer>, 16); // We want the `Debug` output to be readable as it is used by `derive(Debug)` for // all the Miri types. impl fmt::Debug for Pointer { fn fmt(&self, f: &mut fmt::Formatter<'_>) -> fmt::Result { Provenance::fmt(self, f) } } impl fmt::Debug for Pointer> { fn fmt(&self, f: &mut fmt::Formatter<'_>) -> fmt::Result { match self.provenance { Some(prov) => Provenance::fmt(&Pointer::new(prov, self.offset), f), None => write!(f, "{:#x}[noalloc]", self.offset.bytes()), } } } impl fmt::Display for Pointer> { fn fmt(&self, f: &mut fmt::Formatter<'_>) -> fmt::Result { if self.provenance.is_none() && self.offset.bytes() == 0 { write!(f, "null pointer") } else { fmt::Debug::fmt(self, f) } } } /// Produces a `Pointer` that points to the beginning of the `Allocation`. impl From for Pointer { #[inline(always)] fn from(alloc_id: AllocId) -> Self { Pointer::new(alloc_id, Size::ZERO) } } impl From> for Pointer> { #[inline(always)] fn from(ptr: Pointer) -> Self { let (prov, offset) = ptr.into_parts(); Pointer::new(Some(prov), offset) } } impl Pointer> { /// Convert this pointer that *might* have a provenance into a pointer that *definitely* has a /// provenance, or an absolute address. /// /// This is rarely what you want; call `ptr_try_get_alloc_id` instead. pub fn into_pointer_or_addr(self) -> Result, Size> { match self.provenance { Some(prov) => Ok(Pointer::new(prov, self.offset)), None => Err(self.offset), } } /// Returns the absolute address the pointer points to. /// Only works if Prov::OFFSET_IS_ADDR is true! pub fn addr(self) -> Size where Prov: Provenance, { assert!(Prov::OFFSET_IS_ADDR); self.offset } } impl Pointer> { #[inline(always)] pub fn from_addr(addr: u64) -> Self { Pointer { provenance: None, offset: Size::from_bytes(addr) } } #[inline(always)] pub fn null() -> Self { Pointer::from_addr(0) } } impl<'tcx, Prov> Pointer { #[inline(always)] pub fn new(provenance: Prov, offset: Size) -> Self { Pointer { provenance, offset } } /// Obtain the constituents of this pointer. Not that the meaning of the offset depends on the type `Prov`! /// This function must only be used in the implementation of `Machine::ptr_get_alloc`, /// and when a `Pointer` is taken apart to be stored efficiently in an `Allocation`. #[inline(always)] pub fn into_parts(self) -> (Prov, Size) { (self.provenance, self.offset) } pub fn map_provenance(self, f: impl FnOnce(Prov) -> Prov) -> Self { Pointer { provenance: f(self.provenance), ..self } } #[inline] pub fn offset(self, i: Size, cx: &impl HasDataLayout) -> InterpResult<'tcx, Self> { Ok(Pointer { offset: Size::from_bytes(cx.data_layout().offset(self.offset.bytes(), i.bytes())?), ..self }) } #[inline] pub fn overflowing_offset(self, i: Size, cx: &impl HasDataLayout) -> (Self, bool) { let (res, over) = cx.data_layout().overflowing_offset(self.offset.bytes(), i.bytes()); let ptr = Pointer { offset: Size::from_bytes(res), ..self }; (ptr, over) } #[inline(always)] pub fn wrapping_offset(self, i: Size, cx: &impl HasDataLayout) -> Self { self.overflowing_offset(i, cx).0 } #[inline] pub fn signed_offset(self, i: i64, cx: &impl HasDataLayout) -> InterpResult<'tcx, Self> { Ok(Pointer { offset: Size::from_bytes(cx.data_layout().signed_offset(self.offset.bytes(), i)?), ..self }) } #[inline] pub fn overflowing_signed_offset(self, i: i64, cx: &impl HasDataLayout) -> (Self, bool) { let (res, over) = cx.data_layout().overflowing_signed_offset(self.offset.bytes(), i); let ptr = Pointer { offset: Size::from_bytes(res), ..self }; (ptr, over) } #[inline(always)] pub fn wrapping_signed_offset(self, i: i64, cx: &impl HasDataLayout) -> Self { self.overflowing_signed_offset(i, cx).0 } }