-use rustc::ty::{Ty, layout::{Size, LayoutOf}};
-use rustc::mir;
+use log::trace;
+
+use rustc_middle::{mir, ty::Ty};
use crate::*;
pub trait EvalContextExt<'tcx> {
- fn pointer_inbounds(
- &self,
- ptr: Pointer<Tag>
- ) -> InterpResult<'tcx>;
-
fn binary_ptr_op(
&self,
bin_op: mir::BinOp,
- left: ImmTy<'tcx, Tag>,
- right: ImmTy<'tcx, Tag>,
- ) -> InterpResult<'tcx, (Scalar<Tag>, bool)>;
-
- fn ptr_int_arithmetic(
- &self,
- bin_op: mir::BinOp,
- left: Pointer<Tag>,
- right: u128,
- signed: bool,
- ) -> InterpResult<'tcx, (Scalar<Tag>, bool)>;
+ left: &ImmTy<'tcx, Tag>,
+ right: &ImmTy<'tcx, Tag>,
+ ) -> InterpResult<'tcx, (Scalar<Tag>, bool, Ty<'tcx>)>;
- fn ptr_eq(
- &self,
- left: Scalar<Tag>,
- right: Scalar<Tag>,
- ) -> InterpResult<'tcx, bool>;
-
- fn pointer_offset_inbounds(
- &self,
- ptr: Scalar<Tag>,
- pointee_ty: Ty<'tcx>,
- offset: i64,
- ) -> InterpResult<'tcx, Scalar<Tag>>;
+ fn ptr_eq(&self, left: Scalar<Tag>, right: Scalar<Tag>) -> InterpResult<'tcx, bool>;
}
impl<'mir, 'tcx> EvalContextExt<'tcx> for super::MiriEvalContext<'mir, 'tcx> {
- /// Test if the pointer is in-bounds of a live allocation.
- #[inline]
- fn pointer_inbounds(&self, ptr: Pointer<Tag>) -> InterpResult<'tcx> {
- let (size, _align) = self.memory().get_size_and_align(ptr.alloc_id, AllocCheck::Live)?;
- ptr.check_in_alloc(size, CheckInAllocMsg::InboundsTest)
- }
-
fn binary_ptr_op(
&self,
bin_op: mir::BinOp,
- left: ImmTy<'tcx, Tag>,
- right: ImmTy<'tcx, Tag>,
- ) -> InterpResult<'tcx, (Scalar<Tag>, bool)> {
- use rustc::mir::BinOp::*;
+ left: &ImmTy<'tcx, Tag>,
+ right: &ImmTy<'tcx, Tag>,
+ ) -> InterpResult<'tcx, (Scalar<Tag>, bool, Ty<'tcx>)> {
+ use rustc_middle::mir::BinOp::*;
trace!("ptr_op: {:?} {:?} {:?}", *left, bin_op, *right);
- // Operations that support fat pointers
- match bin_op {
+ Ok(match bin_op {
Eq | Ne => {
- let eq = match (*left, *right) {
- (Immediate::Scalar(left), Immediate::Scalar(right)) =>
- self.ptr_eq(left.not_undef()?, right.not_undef()?)?,
- (Immediate::ScalarPair(left1, left2), Immediate::ScalarPair(right1, right2)) =>
- self.ptr_eq(left1.not_undef()?, right1.not_undef()?)? &&
- self.ptr_eq(left2.not_undef()?, right2.not_undef()?)?,
+ // This supports fat pointers.
+ #[rustfmt::skip]
+ let eq = match (**left, **right) {
+ (Immediate::Scalar(left), Immediate::Scalar(right)) => {
+ self.ptr_eq(left.check_init()?, right.check_init()?)?
+ }
+ (Immediate::ScalarPair(left1, left2), Immediate::ScalarPair(right1, right2)) => {
+ self.ptr_eq(left1.check_init()?, right1.check_init()?)?
+ && self.ptr_eq(left2.check_init()?, right2.check_init()?)?
+ }
_ => bug!("Type system should not allow comparing Scalar with ScalarPair"),
};
- return Ok((Scalar::from_bool(if bin_op == Eq { eq } else { !eq }), false));
+ (Scalar::from_bool(if bin_op == Eq { eq } else { !eq }), false, self.tcx.types.bool)
}
- _ => {},
- }
- // Now we expect no more fat pointers.
- let left_layout = left.layout;
- let left = left.to_scalar()?;
- let right_layout = right.layout;
- let right = right.to_scalar()?;
-
- Ok(match bin_op {
- Offset => {
- let pointee_ty = left_layout.ty
- .builtin_deref(true)
- .expect("Offset called on non-ptr type")
- .ty;
- let ptr = self.pointer_offset_inbounds(
- left,
- pointee_ty,
- right.to_isize(self)?,
- )?;
- (ptr, false)
- }
- // These need both to be pointer, and fail if they are not in the same location
- Lt | Le | Gt | Ge | Sub if left.is_ptr() && right.is_ptr() => {
- let left = left.assert_ptr();
- let right = right.assert_ptr();
- if left.alloc_id == right.alloc_id {
- let res = match bin_op {
- Lt => left.offset < right.offset,
- Le => left.offset <= right.offset,
- Gt => left.offset > right.offset,
- Ge => left.offset >= right.offset,
- Sub => {
- // subtract the offsets
- let left_offset = Scalar::from_uint(left.offset.bytes(), self.memory().pointer_size());
- let right_offset = Scalar::from_uint(right.offset.bytes(), self.memory().pointer_size());
- let layout = self.layout_of(self.tcx.types.usize)?;
- return self.binary_op(
- Sub,
- ImmTy::from_scalar(left_offset, layout),
- ImmTy::from_scalar(right_offset, layout),
- )
- }
- _ => bug!("We already established it has to be one of these operators."),
- };
- (Scalar::from_bool(res), false)
- } else {
- // Both are pointers, but from different allocations.
- throw_unsup!(InvalidPointerMath)
- }
- }
- Lt | Le | Gt | Ge if left.is_bits() && right.is_bits() => {
- let left = left.assert_bits(self.memory().pointer_size());
- let right = right.assert_bits(self.memory().pointer_size());
+ Lt | Le | Gt | Ge => {
+ // Just compare the integers.
+ // TODO: Do we really want to *always* do that, even when comparing two live in-bounds pointers?
+ let left = self.force_bits(left.to_scalar()?, left.layout.size)?;
+ let right = self.force_bits(right.to_scalar()?, right.layout.size)?;
let res = match bin_op {
Lt => left < right,
Le => left <= right,
Ge => left >= right,
_ => bug!("We already established it has to be one of these operators."),
};
- Ok((Scalar::from_bool(res), false))
- }
- Gt | Ge if left.is_ptr() && right.is_bits() => {
- // "ptr >[=] integer" can be tested if the integer is small enough.
- let left = left.assert_ptr();
- let right = right.assert_bits(self.memory().pointer_size());
- let (_alloc_size, alloc_align) = self.memory()
- .get_size_and_align(left.alloc_id, AllocCheck::MaybeDead)
- .expect("alloc info with MaybeDead cannot fail");
- let min_ptr_val = u128::from(alloc_align.bytes()) + u128::from(left.offset.bytes());
- let result = match bin_op {
- Gt => min_ptr_val > right,
- Ge => min_ptr_val >= right,
- _ => bug!(),
- };
- if result {
- // Definitely true!
- (Scalar::from_bool(true), false)
- } else {
- // Sorry, can't tell.
- throw_unsup!(InvalidPointerMath)
- }
+ (Scalar::from_bool(res), false, self.tcx.types.bool)
}
- // These work if the left operand is a pointer, and the right an integer
- Add | BitAnd | Sub | Rem if left.is_ptr() && right.is_bits() => {
- // Cast to i128 is fine as we checked the kind to be ptr-sized
- self.ptr_int_arithmetic(
- bin_op,
- left.assert_ptr(),
- right.assert_bits(self.memory().pointer_size()),
- right_layout.abi.is_signed(),
- )?
- }
- // Commutative operators also work if the integer is on the left
- Add | BitAnd if left.is_bits() && right.is_ptr() => {
- // This is a commutative operation, just swap the operands
- self.ptr_int_arithmetic(
- bin_op,
- right.assert_ptr(),
- left.assert_bits(self.memory().pointer_size()),
- left_layout.abi.is_signed(),
- )?
+
+ Offset => {
+ let pointee_ty =
+ left.layout.ty.builtin_deref(true).expect("Offset called on non-ptr type").ty;
+ let ptr = self.ptr_offset_inbounds(
+ left.to_scalar()?,
+ pointee_ty,
+ right.to_scalar()?.to_machine_isize(self)?,
+ )?;
+ (ptr, false, left.layout.ty)
}
- // Nothing else works
- _ => throw_unsup!(InvalidPointerMath),
+
+ _ => bug!("Invalid operator on pointers: {:?}", bin_op),
})
}
- fn ptr_eq(
- &self,
- left: Scalar<Tag>,
- right: Scalar<Tag>,
- ) -> InterpResult<'tcx, bool> {
+ fn ptr_eq(&self, left: Scalar<Tag>, right: Scalar<Tag>) -> InterpResult<'tcx, bool> {
let size = self.pointer_size();
// Just compare the integers.
// TODO: Do we really want to *always* do that, even when comparing two live in-bounds pointers?
let right = self.force_bits(right, size)?;
Ok(left == right)
}
-
- fn ptr_int_arithmetic(
- &self,
- bin_op: mir::BinOp,
- left: Pointer<Tag>,
- right: u128,
- signed: bool,
- ) -> InterpResult<'tcx, (Scalar<Tag>, bool)> {
- use rustc::mir::BinOp::*;
-
- fn map_to_primval((res, over): (Pointer<Tag>, bool)) -> (Scalar<Tag>, bool) {
- (Scalar::Ptr(res), over)
- }
-
- Ok(match bin_op {
- Sub =>
- // The only way this can overflow is by underflowing, so signdeness of the right
- // operands does not matter.
- map_to_primval(left.overflowing_signed_offset(-(right as i128), self)),
- Add if signed =>
- map_to_primval(left.overflowing_signed_offset(right as i128, self)),
- Add if !signed =>
- map_to_primval(left.overflowing_offset(Size::from_bytes(right as u64), self)),
-
- BitAnd if !signed => {
- let ptr_base_align = self.memory().get_size_and_align(left.alloc_id, AllocCheck::MaybeDead)
- .expect("alloc info with MaybeDead cannot fail")
- .1.bytes();
- let base_mask = {
- // FIXME: use `interpret::truncate`, once that takes a `Size` instead of a `Layout`.
- let shift = 128 - self.memory().pointer_size().bits();
- let value = !(ptr_base_align as u128 - 1);
- // Truncate (shift left to drop out leftover values, shift right to fill with zeroes).
- (value << shift) >> shift
- };
- let ptr_size = self.memory().pointer_size();
- trace!("ptr BitAnd, align {}, operand {:#010x}, base_mask {:#010x}",
- ptr_base_align, right, base_mask);
- if right & base_mask == base_mask {
- // Case 1: the base address bits are all preserved, i.e., right is all-1 there.
- let offset = (left.offset.bytes() as u128 & right) as u64;
- (
- Scalar::Ptr(Pointer::new_with_tag(
- left.alloc_id,
- Size::from_bytes(offset),
- left.tag,
- )),
- false,
- )
- } else if right & base_mask == 0 {
- // Case 2: the base address bits are all taken away, i.e., right is all-0 there.
- let v = Scalar::from_uint((left.offset.bytes() as u128) & right, ptr_size);
- (v, false)
- } else {
- throw_unsup!(ReadPointerAsBytes);
- }
- }
-
- Rem if !signed => {
- // Doing modulo a divisor of the alignment is allowed.
- // (Intuition: modulo a divisor leaks less information.)
- let ptr_base_align = self.memory().get_size_and_align(left.alloc_id, AllocCheck::MaybeDead)
- .expect("alloc info with MaybeDead cannot fail")
- .1.bytes();
- let right = right as u64;
- let ptr_size = self.memory().pointer_size();
- if right == 1 {
- // Modulo 1 is always 0.
- (Scalar::from_uint(0u32, ptr_size), false)
- } else if ptr_base_align % right == 0 {
- // The base address would be cancelled out by the modulo operation, so we can
- // just take the modulo of the offset.
- (
- Scalar::from_uint((left.offset.bytes() % right) as u128, ptr_size),
- false,
- )
- } else {
- throw_unsup!(ReadPointerAsBytes);
- }
- }
-
- _ => {
- let msg = format!(
- "unimplemented binary op on pointer {:?}: {:?}, {:?} ({})",
- bin_op,
- left,
- right,
- if signed { "signed" } else { "unsigned" }
- );
- throw_unsup!(Unimplemented(msg));
- }
- })
- }
-
- /// Raises an error if the offset moves the pointer outside of its allocation.
- /// We consider ZSTs their own huge allocation that doesn't overlap with anything (and nothing
- /// moves in there because the size is 0). We also consider the NULL pointer its own separate
- /// allocation, and all the remaining integers pointers their own allocation.
- fn pointer_offset_inbounds(
- &self,
- ptr: Scalar<Tag>,
- pointee_ty: Ty<'tcx>,
- offset: i64,
- ) -> InterpResult<'tcx, Scalar<Tag>> {
- // FIXME: assuming here that type size is less than `i64::max_value()`.
- let pointee_size = self.layout_of(pointee_ty)?.size.bytes() as i64;
- let offset = offset
- .checked_mul(pointee_size)
- .ok_or_else(|| err_panic!(Overflow(mir::BinOp::Mul)))?;
- // Now let's see what kind of pointer this is.
- let ptr = if offset == 0 {
- match ptr {
- Scalar::Ptr(ptr) => ptr,
- Scalar::Raw { .. } => {
- // Offset 0 on an integer. We accept that, pretending there is
- // a little zero-sized allocation here.
- return Ok(ptr);
- }
- }
- } else {
- // Offset > 0. We *require* a pointer.
- self.force_ptr(ptr)?
- };
- // Both old and new pointer must be in-bounds of a *live* allocation.
- // (Of the same allocation, but that part is trivial with our representation.)
- self.pointer_inbounds(ptr)?;
- let ptr = ptr.signed_offset(offset, self)?;
- self.pointer_inbounds(ptr)?;
- Ok(Scalar::Ptr(ptr))
- }
}
projects / rust.git / blobdiff