use crate::middle::codegen_fn_attrs::CodegenFnAttrFlags; use crate::ty::normalize_erasing_regions::NormalizationError; use crate::ty::{self, ReprOptions, Ty, TyCtxt, TypeVisitable}; use rustc_errors::{DiagnosticBuilder, Handler, IntoDiagnostic}; use rustc_hir as hir; use rustc_hir::def_id::DefId; use rustc_index::vec::Idx; use rustc_session::config::OptLevel; use rustc_span::{Span, DUMMY_SP}; use rustc_target::abi::call::FnAbi; use rustc_target::abi::*; use rustc_target::spec::{abi::Abi as SpecAbi, HasTargetSpec, PanicStrategy, Target}; use std::cmp::{self}; use std::fmt; use std::num::NonZeroUsize; use std::ops::Bound; pub trait IntegerExt { fn to_ty<'tcx>(&self, tcx: TyCtxt<'tcx>, signed: bool) -> Ty<'tcx>; fn from_int_ty(cx: &C, ity: ty::IntTy) -> Integer; fn from_uint_ty(cx: &C, uty: ty::UintTy) -> Integer; fn repr_discr<'tcx>( tcx: TyCtxt<'tcx>, ty: Ty<'tcx>, repr: &ReprOptions, min: i128, max: i128, ) -> (Integer, bool); } impl IntegerExt for Integer { #[inline] fn to_ty<'tcx>(&self, tcx: TyCtxt<'tcx>, signed: bool) -> Ty<'tcx> { match (*self, signed) { (I8, false) => tcx.types.u8, (I16, false) => tcx.types.u16, (I32, false) => tcx.types.u32, (I64, false) => tcx.types.u64, (I128, false) => tcx.types.u128, (I8, true) => tcx.types.i8, (I16, true) => tcx.types.i16, (I32, true) => tcx.types.i32, (I64, true) => tcx.types.i64, (I128, true) => tcx.types.i128, } } fn from_int_ty(cx: &C, ity: ty::IntTy) -> Integer { match ity { ty::IntTy::I8 => I8, ty::IntTy::I16 => I16, ty::IntTy::I32 => I32, ty::IntTy::I64 => I64, ty::IntTy::I128 => I128, ty::IntTy::Isize => cx.data_layout().ptr_sized_integer(), } } fn from_uint_ty(cx: &C, ity: ty::UintTy) -> Integer { match ity { ty::UintTy::U8 => I8, ty::UintTy::U16 => I16, ty::UintTy::U32 => I32, ty::UintTy::U64 => I64, ty::UintTy::U128 => I128, ty::UintTy::Usize => cx.data_layout().ptr_sized_integer(), } } /// Finds the appropriate Integer type and signedness for the given /// signed discriminant range and `#[repr]` attribute. /// N.B.: `u128` values above `i128::MAX` will be treated as signed, but /// that shouldn't affect anything, other than maybe debuginfo. fn repr_discr<'tcx>( tcx: TyCtxt<'tcx>, ty: Ty<'tcx>, repr: &ReprOptions, min: i128, max: i128, ) -> (Integer, bool) { // Theoretically, negative values could be larger in unsigned representation // than the unsigned representation of the signed minimum. However, if there // are any negative values, the only valid unsigned representation is u128 // which can fit all i128 values, so the result remains unaffected. let unsigned_fit = Integer::fit_unsigned(cmp::max(min as u128, max as u128)); let signed_fit = cmp::max(Integer::fit_signed(min), Integer::fit_signed(max)); if let Some(ity) = repr.int { let discr = Integer::from_attr(&tcx, ity); let fit = if ity.is_signed() { signed_fit } else { unsigned_fit }; if discr < fit { bug!( "Integer::repr_discr: `#[repr]` hint too small for \ discriminant range of enum `{}", ty ) } return (discr, ity.is_signed()); } let at_least = if repr.c() { // This is usually I32, however it can be different on some platforms, // notably hexagon and arm-none/thumb-none tcx.data_layout().c_enum_min_size } else { // repr(Rust) enums try to be as small as possible I8 }; // If there are no negative values, we can use the unsigned fit. if min >= 0 { (cmp::max(unsigned_fit, at_least), false) } else { (cmp::max(signed_fit, at_least), true) } } } pub trait PrimitiveExt { fn to_ty<'tcx>(&self, tcx: TyCtxt<'tcx>) -> Ty<'tcx>; fn to_int_ty<'tcx>(&self, tcx: TyCtxt<'tcx>) -> Ty<'tcx>; } impl PrimitiveExt for Primitive { #[inline] fn to_ty<'tcx>(&self, tcx: TyCtxt<'tcx>) -> Ty<'tcx> { match *self { Int(i, signed) => i.to_ty(tcx, signed), F32 => tcx.types.f32, F64 => tcx.types.f64, Pointer => tcx.mk_mut_ptr(tcx.mk_unit()), } } /// Return an *integer* type matching this primitive. /// Useful in particular when dealing with enum discriminants. #[inline] fn to_int_ty<'tcx>(&self, tcx: TyCtxt<'tcx>) -> Ty<'tcx> { match *self { Int(i, signed) => i.to_ty(tcx, signed), Pointer => tcx.types.usize, F32 | F64 => bug!("floats do not have an int type"), } } } /// The first half of a fat pointer. /// /// - For a trait object, this is the address of the box. /// - For a slice, this is the base address. pub const FAT_PTR_ADDR: usize = 0; /// The second half of a fat pointer. /// /// - For a trait object, this is the address of the vtable. /// - For a slice, this is the length. pub const FAT_PTR_EXTRA: usize = 1; /// The maximum supported number of lanes in a SIMD vector. /// /// This value is selected based on backend support: /// * LLVM does not appear to have a vector width limit. /// * Cranelift stores the base-2 log of the lane count in a 4 bit integer. pub const MAX_SIMD_LANES: u64 = 1 << 0xF; #[derive(Copy, Clone, Debug, HashStable, TyEncodable, TyDecodable)] pub enum LayoutError<'tcx> { Unknown(Ty<'tcx>), SizeOverflow(Ty<'tcx>), NormalizationFailure(Ty<'tcx>, NormalizationError<'tcx>), } impl IntoDiagnostic<'_, !> for LayoutError<'_> { fn into_diagnostic(self, handler: &Handler) -> DiagnosticBuilder<'_, !> { let mut diag = handler.struct_fatal(""); match self { LayoutError::Unknown(ty) => { diag.set_arg("ty", ty); diag.set_primary_message(rustc_errors::fluent::middle_unknown_layout); } LayoutError::SizeOverflow(ty) => { diag.set_arg("ty", ty); diag.set_primary_message(rustc_errors::fluent::middle_values_too_big); } LayoutError::NormalizationFailure(ty, e) => { diag.set_arg("ty", ty); diag.set_arg("failure_ty", e.get_type_for_failure()); diag.set_primary_message(rustc_errors::fluent::middle_cannot_be_normalized); } } diag } } // FIXME: Once the other errors that embed this error have been converted to translateable // diagnostics, this Display impl should be removed. impl<'tcx> fmt::Display for LayoutError<'tcx> { fn fmt(&self, f: &mut fmt::Formatter<'_>) -> fmt::Result { match *self { LayoutError::Unknown(ty) => write!(f, "the type `{}` has an unknown layout", ty), LayoutError::SizeOverflow(ty) => { write!(f, "values of the type `{}` are too big for the current architecture", ty) } LayoutError::NormalizationFailure(t, e) => write!( f, "unable to determine layout for `{}` because `{}` cannot be normalized", t, e.get_type_for_failure() ), } } } #[derive(Clone, Copy)] pub struct LayoutCx<'tcx, C> { pub tcx: C, pub param_env: ty::ParamEnv<'tcx>, } impl<'tcx> LayoutCalculator for LayoutCx<'tcx, TyCtxt<'tcx>> { type TargetDataLayoutRef = &'tcx TargetDataLayout; fn delay_bug(&self, txt: &str) { self.tcx.sess.delay_span_bug(DUMMY_SP, txt); } fn current_data_layout(&self) -> Self::TargetDataLayoutRef { &self.tcx.data_layout } } /// Type size "skeleton", i.e., the only information determining a type's size. /// While this is conservative, (aside from constant sizes, only pointers, /// newtypes thereof and null pointer optimized enums are allowed), it is /// enough to statically check common use cases of transmute. #[derive(Copy, Clone, Debug)] pub enum SizeSkeleton<'tcx> { /// Any statically computable Layout. Known(Size), /// A potentially-fat pointer. Pointer { /// If true, this pointer is never null. non_zero: bool, /// The type which determines the unsized metadata, if any, /// of this pointer. Either a type parameter or a projection /// depending on one, with regions erased. tail: Ty<'tcx>, }, } impl<'tcx> SizeSkeleton<'tcx> { pub fn compute( ty: Ty<'tcx>, tcx: TyCtxt<'tcx>, param_env: ty::ParamEnv<'tcx>, ) -> Result, LayoutError<'tcx>> { debug_assert!(!ty.has_non_region_infer()); // First try computing a static layout. let err = match tcx.layout_of(param_env.and(ty)) { Ok(layout) => { return Ok(SizeSkeleton::Known(layout.size)); } Err(err) => err, }; match *ty.kind() { ty::Ref(_, pointee, _) | ty::RawPtr(ty::TypeAndMut { ty: pointee, .. }) => { let non_zero = !ty.is_unsafe_ptr(); let tail = tcx.struct_tail_erasing_lifetimes(pointee, param_env); match tail.kind() { ty::Param(_) | ty::Alias(ty::Projection, _) => { debug_assert!(tail.has_non_region_param()); Ok(SizeSkeleton::Pointer { non_zero, tail: tcx.erase_regions(tail) }) } _ => bug!( "SizeSkeleton::compute({}): layout errored ({}), yet \ tail `{}` is not a type parameter or a projection", ty, err, tail ), } } ty::Adt(def, substs) => { // Only newtypes and enums w/ nullable pointer optimization. if def.is_union() || def.variants().is_empty() || def.variants().len() > 2 { return Err(err); } // Get a zero-sized variant or a pointer newtype. let zero_or_ptr_variant = |i| { let i = VariantIdx::new(i); let fields = def.variant(i).fields.iter().map(|field| { SizeSkeleton::compute(field.ty(tcx, substs), tcx, param_env) }); let mut ptr = None; for field in fields { let field = field?; match field { SizeSkeleton::Known(size) => { if size.bytes() > 0 { return Err(err); } } SizeSkeleton::Pointer { .. } => { if ptr.is_some() { return Err(err); } ptr = Some(field); } } } Ok(ptr) }; let v0 = zero_or_ptr_variant(0)?; // Newtype. if def.variants().len() == 1 { if let Some(SizeSkeleton::Pointer { non_zero, tail }) = v0 { return Ok(SizeSkeleton::Pointer { non_zero: non_zero || match tcx.layout_scalar_valid_range(def.did()) { (Bound::Included(start), Bound::Unbounded) => start > 0, (Bound::Included(start), Bound::Included(end)) => { 0 < start && start < end } _ => false, }, tail, }); } else { return Err(err); } } let v1 = zero_or_ptr_variant(1)?; // Nullable pointer enum optimization. match (v0, v1) { (Some(SizeSkeleton::Pointer { non_zero: true, tail }), None) | (None, Some(SizeSkeleton::Pointer { non_zero: true, tail })) => { Ok(SizeSkeleton::Pointer { non_zero: false, tail }) } _ => Err(err), } } ty::Alias(..) => { let normalized = tcx.normalize_erasing_regions(param_env, ty); if ty == normalized { Err(err) } else { SizeSkeleton::compute(normalized, tcx, param_env) } } _ => Err(err), } } pub fn same_size(self, other: SizeSkeleton<'tcx>) -> bool { match (self, other) { (SizeSkeleton::Known(a), SizeSkeleton::Known(b)) => a == b, (SizeSkeleton::Pointer { tail: a, .. }, SizeSkeleton::Pointer { tail: b, .. }) => { a == b } _ => false, } } } pub trait HasTyCtxt<'tcx>: HasDataLayout { fn tcx(&self) -> TyCtxt<'tcx>; } pub trait HasParamEnv<'tcx> { fn param_env(&self) -> ty::ParamEnv<'tcx>; } impl<'tcx> HasDataLayout for TyCtxt<'tcx> { #[inline] fn data_layout(&self) -> &TargetDataLayout { &self.data_layout } } impl<'tcx> HasTargetSpec for TyCtxt<'tcx> { fn target_spec(&self) -> &Target { &self.sess.target } } impl<'tcx> HasTyCtxt<'tcx> for TyCtxt<'tcx> { #[inline] fn tcx(&self) -> TyCtxt<'tcx> { *self } } impl<'tcx> HasDataLayout for ty::query::TyCtxtAt<'tcx> { #[inline] fn data_layout(&self) -> &TargetDataLayout { &self.data_layout } } impl<'tcx> HasTargetSpec for ty::query::TyCtxtAt<'tcx> { fn target_spec(&self) -> &Target { &self.sess.target } } impl<'tcx> HasTyCtxt<'tcx> for ty::query::TyCtxtAt<'tcx> { #[inline] fn tcx(&self) -> TyCtxt<'tcx> { **self } } impl<'tcx, C> HasParamEnv<'tcx> for LayoutCx<'tcx, C> { fn param_env(&self) -> ty::ParamEnv<'tcx> { self.param_env } } impl<'tcx, T: HasDataLayout> HasDataLayout for LayoutCx<'tcx, T> { fn data_layout(&self) -> &TargetDataLayout { self.tcx.data_layout() } } impl<'tcx, T: HasTargetSpec> HasTargetSpec for LayoutCx<'tcx, T> { fn target_spec(&self) -> &Target { self.tcx.target_spec() } } impl<'tcx, T: HasTyCtxt<'tcx>> HasTyCtxt<'tcx> for LayoutCx<'tcx, T> { fn tcx(&self) -> TyCtxt<'tcx> { self.tcx.tcx() } } pub trait MaybeResult { type Error; fn from(x: Result) -> Self; fn to_result(self) -> Result; } impl MaybeResult for T { type Error = !; fn from(Ok(x): Result) -> Self { x } fn to_result(self) -> Result { Ok(self) } } impl MaybeResult for Result { type Error = E; fn from(x: Result) -> Self { x } fn to_result(self) -> Result { self } } pub type TyAndLayout<'tcx> = rustc_target::abi::TyAndLayout<'tcx, Ty<'tcx>>; /// Trait for contexts that want to be able to compute layouts of types. /// This automatically gives access to `LayoutOf`, through a blanket `impl`. pub trait LayoutOfHelpers<'tcx>: HasDataLayout + HasTyCtxt<'tcx> + HasParamEnv<'tcx> { /// The `TyAndLayout`-wrapping type (or `TyAndLayout` itself), which will be /// returned from `layout_of` (see also `handle_layout_err`). type LayoutOfResult: MaybeResult>; /// `Span` to use for `tcx.at(span)`, from `layout_of`. // FIXME(eddyb) perhaps make this mandatory to get contexts to track it better? #[inline] fn layout_tcx_at_span(&self) -> Span { DUMMY_SP } /// Helper used for `layout_of`, to adapt `tcx.layout_of(...)` into a /// `Self::LayoutOfResult` (which does not need to be a `Result<...>`). /// /// Most `impl`s, which propagate `LayoutError`s, should simply return `err`, /// but this hook allows e.g. codegen to return only `TyAndLayout` from its /// `cx.layout_of(...)`, without any `Result<...>` around it to deal with /// (and any `LayoutError`s are turned into fatal errors or ICEs). fn handle_layout_err( &self, err: LayoutError<'tcx>, span: Span, ty: Ty<'tcx>, ) -> >>::Error; } /// Blanket extension trait for contexts that can compute layouts of types. pub trait LayoutOf<'tcx>: LayoutOfHelpers<'tcx> { /// Computes the layout of a type. Note that this implicitly /// executes in "reveal all" mode, and will normalize the input type. #[inline] fn layout_of(&self, ty: Ty<'tcx>) -> Self::LayoutOfResult { self.spanned_layout_of(ty, DUMMY_SP) } /// Computes the layout of a type, at `span`. Note that this implicitly /// executes in "reveal all" mode, and will normalize the input type. // FIXME(eddyb) avoid passing information like this, and instead add more // `TyCtxt::at`-like APIs to be able to do e.g. `cx.at(span).layout_of(ty)`. #[inline] fn spanned_layout_of(&self, ty: Ty<'tcx>, span: Span) -> Self::LayoutOfResult { let span = if !span.is_dummy() { span } else { self.layout_tcx_at_span() }; let tcx = self.tcx().at(span); MaybeResult::from( tcx.layout_of(self.param_env().and(ty)) .map_err(|err| self.handle_layout_err(err, span, ty)), ) } } impl<'tcx, C: LayoutOfHelpers<'tcx>> LayoutOf<'tcx> for C {} impl<'tcx> LayoutOfHelpers<'tcx> for LayoutCx<'tcx, TyCtxt<'tcx>> { type LayoutOfResult = Result, LayoutError<'tcx>>; #[inline] fn handle_layout_err(&self, err: LayoutError<'tcx>, _: Span, _: Ty<'tcx>) -> LayoutError<'tcx> { err } } impl<'tcx> LayoutOfHelpers<'tcx> for LayoutCx<'tcx, ty::query::TyCtxtAt<'tcx>> { type LayoutOfResult = Result, LayoutError<'tcx>>; #[inline] fn layout_tcx_at_span(&self) -> Span { self.tcx.span } #[inline] fn handle_layout_err(&self, err: LayoutError<'tcx>, _: Span, _: Ty<'tcx>) -> LayoutError<'tcx> { err } } impl<'tcx, C> TyAbiInterface<'tcx, C> for Ty<'tcx> where C: HasTyCtxt<'tcx> + HasParamEnv<'tcx>, { fn ty_and_layout_for_variant( this: TyAndLayout<'tcx>, cx: &C, variant_index: VariantIdx, ) -> TyAndLayout<'tcx> { let layout = match this.variants { Variants::Single { index } // If all variants but one are uninhabited, the variant layout is the enum layout. if index == variant_index && // Don't confuse variants of uninhabited enums with the enum itself. // For more details see https://github.com/rust-lang/rust/issues/69763. this.fields != FieldsShape::Primitive => { this.layout } Variants::Single { index } => { let tcx = cx.tcx(); let param_env = cx.param_env(); // Deny calling for_variant more than once for non-Single enums. if let Ok(original_layout) = tcx.layout_of(param_env.and(this.ty)) { assert_eq!(original_layout.variants, Variants::Single { index }); } let fields = match this.ty.kind() { ty::Adt(def, _) if def.variants().is_empty() => bug!("for_variant called on zero-variant enum"), ty::Adt(def, _) => def.variant(variant_index).fields.len(), _ => bug!(), }; tcx.intern_layout(LayoutS { variants: Variants::Single { index: variant_index }, fields: match NonZeroUsize::new(fields) { Some(fields) => FieldsShape::Union(fields), None => FieldsShape::Arbitrary { offsets: vec![], memory_index: vec![] }, }, abi: Abi::Uninhabited, largest_niche: None, align: tcx.data_layout.i8_align, size: Size::ZERO, }) } Variants::Multiple { ref variants, .. } => cx.tcx().intern_layout(variants[variant_index].clone()), }; assert_eq!(*layout.variants(), Variants::Single { index: variant_index }); TyAndLayout { ty: this.ty, layout } } fn ty_and_layout_field(this: TyAndLayout<'tcx>, cx: &C, i: usize) -> TyAndLayout<'tcx> { enum TyMaybeWithLayout<'tcx> { Ty(Ty<'tcx>), TyAndLayout(TyAndLayout<'tcx>), } fn field_ty_or_layout<'tcx>( this: TyAndLayout<'tcx>, cx: &(impl HasTyCtxt<'tcx> + HasParamEnv<'tcx>), i: usize, ) -> TyMaybeWithLayout<'tcx> { let tcx = cx.tcx(); let tag_layout = |tag: Scalar| -> TyAndLayout<'tcx> { TyAndLayout { layout: tcx.intern_layout(LayoutS::scalar(cx, tag)), ty: tag.primitive().to_ty(tcx), } }; match *this.ty.kind() { ty::Bool | ty::Char | ty::Int(_) | ty::Uint(_) | ty::Float(_) | ty::FnPtr(_) | ty::Never | ty::FnDef(..) | ty::GeneratorWitness(..) | ty::Foreign(..) | ty::Dynamic(_, _, ty::Dyn) => { bug!("TyAndLayout::field({:?}): not applicable", this) } // Potentially-fat pointers. ty::Ref(_, pointee, _) | ty::RawPtr(ty::TypeAndMut { ty: pointee, .. }) => { assert!(i < this.fields.count()); // Reuse the fat `*T` type as its own thin pointer data field. // This provides information about, e.g., DST struct pointees // (which may have no non-DST form), and will work as long // as the `Abi` or `FieldsShape` is checked by users. if i == 0 { let nil = tcx.mk_unit(); let unit_ptr_ty = if this.ty.is_unsafe_ptr() { tcx.mk_mut_ptr(nil) } else { tcx.mk_mut_ref(tcx.lifetimes.re_static, nil) }; // NOTE(eddyb) using an empty `ParamEnv`, and `unwrap`-ing // the `Result` should always work because the type is // always either `*mut ()` or `&'static mut ()`. return TyMaybeWithLayout::TyAndLayout(TyAndLayout { ty: this.ty, ..tcx.layout_of(ty::ParamEnv::reveal_all().and(unit_ptr_ty)).unwrap() }); } let mk_dyn_vtable = || { tcx.mk_imm_ref(tcx.lifetimes.re_static, tcx.mk_array(tcx.types.usize, 3)) /* FIXME: use actual fn pointers Warning: naively computing the number of entries in the vtable by counting the methods on the trait + methods on all parent traits does not work, because some methods can be not object safe and thus excluded from the vtable. Increase this counter if you tried to implement this but failed to do it without duplicating a lot of code from other places in the compiler: 2 tcx.mk_tup(&[ tcx.mk_array(tcx.types.usize, 3), tcx.mk_array(Option), ]) */ }; let metadata = if let Some(metadata_def_id) = tcx.lang_items().metadata_type() { let metadata = tcx.normalize_erasing_regions( cx.param_env(), tcx.mk_projection(metadata_def_id, [pointee]), ); // Map `Metadata = DynMetadata` back to a vtable, since it // offers better information than `std::ptr::metadata::VTable`, // and we rely on this layout information to trigger a panic in // `std::mem::uninitialized::<&dyn Trait>()`, for example. if let ty::Adt(def, substs) = metadata.kind() && Some(def.did()) == tcx.lang_items().dyn_metadata() && substs.type_at(0).is_trait() { mk_dyn_vtable() } else { metadata } } else { match tcx.struct_tail_erasing_lifetimes(pointee, cx.param_env()).kind() { ty::Slice(_) | ty::Str => tcx.types.usize, ty::Dynamic(_, _, ty::Dyn) => mk_dyn_vtable(), _ => bug!("TyAndLayout::field({:?}): not applicable", this), } }; TyMaybeWithLayout::Ty(metadata) } // Arrays and slices. ty::Array(element, _) | ty::Slice(element) => TyMaybeWithLayout::Ty(element), ty::Str => TyMaybeWithLayout::Ty(tcx.types.u8), // Tuples, generators and closures. ty::Closure(_, ref substs) => field_ty_or_layout( TyAndLayout { ty: substs.as_closure().tupled_upvars_ty(), ..this }, cx, i, ), ty::Generator(def_id, ref substs, _) => match this.variants { Variants::Single { index } => TyMaybeWithLayout::Ty( substs .as_generator() .state_tys(def_id, tcx) .nth(index.as_usize()) .unwrap() .nth(i) .unwrap(), ), Variants::Multiple { tag, tag_field, .. } => { if i == tag_field { return TyMaybeWithLayout::TyAndLayout(tag_layout(tag)); } TyMaybeWithLayout::Ty(substs.as_generator().prefix_tys().nth(i).unwrap()) } }, ty::Tuple(tys) => TyMaybeWithLayout::Ty(tys[i]), // ADTs. ty::Adt(def, substs) => { match this.variants { Variants::Single { index } => { TyMaybeWithLayout::Ty(def.variant(index).fields[i].ty(tcx, substs)) } // Discriminant field for enums (where applicable). Variants::Multiple { tag, .. } => { assert_eq!(i, 0); return TyMaybeWithLayout::TyAndLayout(tag_layout(tag)); } } } ty::Dynamic(_, _, ty::DynStar) => { if i == 0 { TyMaybeWithLayout::Ty(tcx.types.usize) } else if i == 1 { // FIXME(dyn-star) same FIXME as above applies here too TyMaybeWithLayout::Ty( tcx.mk_imm_ref( tcx.lifetimes.re_static, tcx.mk_array(tcx.types.usize, 3), ), ) } else { bug!("no field {i} on dyn*") } } ty::Alias(..) | ty::Bound(..) | ty::Placeholder(..) | ty::Param(_) | ty::Infer(_) | ty::Error(_) => bug!("TyAndLayout::field: unexpected type `{}`", this.ty), } } match field_ty_or_layout(this, cx, i) { TyMaybeWithLayout::Ty(field_ty) => { cx.tcx().layout_of(cx.param_env().and(field_ty)).unwrap_or_else(|e| { bug!( "failed to get layout for `{}`: {},\n\ despite it being a field (#{}) of an existing layout: {:#?}", field_ty, e, i, this ) }) } TyMaybeWithLayout::TyAndLayout(field_layout) => field_layout, } } fn ty_and_layout_pointee_info_at( this: TyAndLayout<'tcx>, cx: &C, offset: Size, ) -> Option { let tcx = cx.tcx(); let param_env = cx.param_env(); let addr_space_of_ty = |ty: Ty<'tcx>| { if ty.is_fn() { cx.data_layout().instruction_address_space } else { AddressSpace::DATA } }; let pointee_info = match *this.ty.kind() { ty::RawPtr(mt) if offset.bytes() == 0 => { tcx.layout_of(param_env.and(mt.ty)).ok().map(|layout| PointeeInfo { size: layout.size, align: layout.align.abi, safe: None, address_space: addr_space_of_ty(mt.ty), }) } ty::FnPtr(fn_sig) if offset.bytes() == 0 => { tcx.layout_of(param_env.and(tcx.mk_fn_ptr(fn_sig))).ok().map(|layout| PointeeInfo { size: layout.size, align: layout.align.abi, safe: None, address_space: cx.data_layout().instruction_address_space, }) } ty::Ref(_, ty, mt) if offset.bytes() == 0 => { let address_space = addr_space_of_ty(ty); let kind = if tcx.sess.opts.optimize == OptLevel::No { // Use conservative pointer kind if not optimizing. This saves us the // Freeze/Unpin queries, and can save time in the codegen backend (noalias // attributes in LLVM have compile-time cost even in unoptimized builds). PointerKind::SharedMutable } else { match mt { hir::Mutability::Not => { if ty.is_freeze(tcx, cx.param_env()) { PointerKind::Frozen } else { PointerKind::SharedMutable } } hir::Mutability::Mut => { // References to self-referential structures should not be considered // noalias, as another pointer to the structure can be obtained, that // is not based-on the original reference. We consider all !Unpin // types to be potentially self-referential here. if ty.is_unpin(tcx, cx.param_env()) { PointerKind::UniqueBorrowed } else { PointerKind::UniqueBorrowedPinned } } } }; tcx.layout_of(param_env.and(ty)).ok().map(|layout| PointeeInfo { size: layout.size, align: layout.align.abi, safe: Some(kind), address_space, }) } _ => { let mut data_variant = match this.variants { // Within the discriminant field, only the niche itself is // always initialized, so we only check for a pointer at its // offset. // // If the niche is a pointer, it's either valid (according // to its type), or null (which the niche field's scalar // validity range encodes). This allows using // `dereferenceable_or_null` for e.g., `Option<&T>`, and // this will continue to work as long as we don't start // using more niches than just null (e.g., the first page of // the address space, or unaligned pointers). Variants::Multiple { tag_encoding: TagEncoding::Niche { untagged_variant, .. }, tag_field, .. } if this.fields.offset(tag_field) == offset => { Some(this.for_variant(cx, untagged_variant)) } _ => Some(this), }; if let Some(variant) = data_variant { // We're not interested in any unions. if let FieldsShape::Union(_) = variant.fields { data_variant = None; } } let mut result = None; if let Some(variant) = data_variant { let ptr_end = offset + Pointer.size(cx); for i in 0..variant.fields.count() { let field_start = variant.fields.offset(i); if field_start <= offset { let field = variant.field(cx, i); result = field.to_result().ok().and_then(|field| { if ptr_end <= field_start + field.size { // We found the right field, look inside it. let field_info = field.pointee_info_at(cx, offset - field_start); field_info } else { None } }); if result.is_some() { break; } } } } // FIXME(eddyb) This should be for `ptr::Unique`, not `Box`. if let Some(ref mut pointee) = result { if let ty::Adt(def, _) = this.ty.kind() { if def.is_box() && offset.bytes() == 0 { pointee.safe = Some(PointerKind::UniqueOwned); } } } result } }; debug!( "pointee_info_at (offset={:?}, type kind: {:?}) => {:?}", offset, this.ty.kind(), pointee_info ); pointee_info } fn is_adt(this: TyAndLayout<'tcx>) -> bool { matches!(this.ty.kind(), ty::Adt(..)) } fn is_never(this: TyAndLayout<'tcx>) -> bool { this.ty.kind() == &ty::Never } fn is_tuple(this: TyAndLayout<'tcx>) -> bool { matches!(this.ty.kind(), ty::Tuple(..)) } fn is_unit(this: TyAndLayout<'tcx>) -> bool { matches!(this.ty.kind(), ty::Tuple(list) if list.len() == 0) } } /// Calculates whether a function's ABI can unwind or not. /// /// This takes two primary parameters: /// /// * `codegen_fn_attr_flags` - these are flags calculated as part of the /// codegen attrs for a defined function. For function pointers this set of /// flags is the empty set. This is only applicable for Rust-defined /// functions, and generally isn't needed except for small optimizations where /// we try to say a function which otherwise might look like it could unwind /// doesn't actually unwind (such as for intrinsics and such). /// /// * `abi` - this is the ABI that the function is defined with. This is the /// primary factor for determining whether a function can unwind or not. /// /// Note that in this case unwinding is not necessarily panicking in Rust. Rust /// panics are implemented with unwinds on most platform (when /// `-Cpanic=unwind`), but this also accounts for `-Cpanic=abort` build modes. /// Notably unwinding is disallowed for more non-Rust ABIs unless it's /// specifically in the name (e.g. `"C-unwind"`). Unwinding within each ABI is /// defined for each ABI individually, but it always corresponds to some form of /// stack-based unwinding (the exact mechanism of which varies /// platform-by-platform). /// /// Rust functions are classified whether or not they can unwind based on the /// active "panic strategy". In other words Rust functions are considered to /// unwind in `-Cpanic=unwind` mode and cannot unwind in `-Cpanic=abort` mode. /// Note that Rust supports intermingling panic=abort and panic=unwind code, but /// only if the final panic mode is panic=abort. In this scenario any code /// previously compiled assuming that a function can unwind is still correct, it /// just never happens to actually unwind at runtime. /// /// This function's answer to whether or not a function can unwind is quite /// impactful throughout the compiler. This affects things like: /// /// * Calling a function which can't unwind means codegen simply ignores any /// associated unwinding cleanup. /// * Calling a function which can unwind from a function which can't unwind /// causes the `abort_unwinding_calls` MIR pass to insert a landing pad that /// aborts the process. /// * This affects whether functions have the LLVM `nounwind` attribute, which /// affects various optimizations and codegen. /// /// FIXME: this is actually buggy with respect to Rust functions. Rust functions /// compiled with `-Cpanic=unwind` and referenced from another crate compiled /// with `-Cpanic=abort` will look like they can't unwind when in fact they /// might (from a foreign exception or similar). #[inline] #[tracing::instrument(level = "debug", skip(tcx))] pub fn fn_can_unwind(tcx: TyCtxt<'_>, fn_def_id: Option, abi: SpecAbi) -> bool { if let Some(did) = fn_def_id { // Special attribute for functions which can't unwind. if tcx.codegen_fn_attrs(did).flags.contains(CodegenFnAttrFlags::NEVER_UNWIND) { return false; } // With `-C panic=abort`, all non-FFI functions are required to not unwind. // // Note that this is true regardless ABI specified on the function -- a `extern "C-unwind"` // function defined in Rust is also required to abort. if tcx.sess.panic_strategy() == PanicStrategy::Abort && !tcx.is_foreign_item(did) { return false; } // With -Z panic-in-drop=abort, drop_in_place never unwinds. // // This is not part of `codegen_fn_attrs` as it can differ between crates // and therefore cannot be computed in core. if tcx.sess.opts.unstable_opts.panic_in_drop == PanicStrategy::Abort { if Some(did) == tcx.lang_items().drop_in_place_fn() { return false; } } } // Otherwise if this isn't special then unwinding is generally determined by // the ABI of the itself. ABIs like `C` have variants which also // specifically allow unwinding (`C-unwind`), but not all platform-specific // ABIs have such an option. Otherwise the only other thing here is Rust // itself, and those ABIs are determined by the panic strategy configured // for this compilation. // // Unfortunately at this time there's also another caveat. Rust [RFC // 2945][rfc] has been accepted and is in the process of being implemented // and stabilized. In this interim state we need to deal with historical // rustc behavior as well as plan for future rustc behavior. // // Historically functions declared with `extern "C"` were marked at the // codegen layer as `nounwind`. This happened regardless of `panic=unwind` // or not. This is UB for functions in `panic=unwind` mode that then // actually panic and unwind. Note that this behavior is true for both // externally declared functions as well as Rust-defined function. // // To fix this UB rustc would like to change in the future to catch unwinds // from function calls that may unwind within a Rust-defined `extern "C"` // function and forcibly abort the process, thereby respecting the // `nounwind` attribute emitted for `extern "C"`. This behavior change isn't // ready to roll out, so determining whether or not the `C` family of ABIs // unwinds is conditional not only on their definition but also whether the // `#![feature(c_unwind)]` feature gate is active. // // Note that this means that unlike historical compilers rustc now, by // default, unconditionally thinks that the `C` ABI may unwind. This will // prevent some optimization opportunities, however, so we try to scope this // change and only assume that `C` unwinds with `panic=unwind` (as opposed // to `panic=abort`). // // Eventually the check against `c_unwind` here will ideally get removed and // this'll be a little cleaner as it'll be a straightforward check of the // ABI. // // [rfc]: https://github.com/rust-lang/rfcs/blob/master/text/2945-c-unwind-abi.md use SpecAbi::*; match abi { C { unwind } | System { unwind } | Cdecl { unwind } | Stdcall { unwind } | Fastcall { unwind } | Vectorcall { unwind } | Thiscall { unwind } | Aapcs { unwind } | Win64 { unwind } | SysV64 { unwind } => { unwind || (!tcx.features().c_unwind && tcx.sess.panic_strategy() == PanicStrategy::Unwind) } PtxKernel | Msp430Interrupt | X86Interrupt | AmdGpuKernel | EfiApi | AvrInterrupt | AvrNonBlockingInterrupt | CCmseNonSecureCall | Wasm | RustIntrinsic | PlatformIntrinsic | Unadjusted => false, Rust | RustCall | RustCold => tcx.sess.panic_strategy() == PanicStrategy::Unwind, } } /// Error produced by attempting to compute or adjust a `FnAbi`. #[derive(Copy, Clone, Debug, HashStable)] pub enum FnAbiError<'tcx> { /// Error produced by a `layout_of` call, while computing `FnAbi` initially. Layout(LayoutError<'tcx>), /// Error produced by attempting to adjust a `FnAbi`, for a "foreign" ABI. AdjustForForeignAbi(call::AdjustForForeignAbiError), } impl<'tcx> From> for FnAbiError<'tcx> { fn from(err: LayoutError<'tcx>) -> Self { Self::Layout(err) } } impl From for FnAbiError<'_> { fn from(err: call::AdjustForForeignAbiError) -> Self { Self::AdjustForForeignAbi(err) } } impl<'tcx> fmt::Display for FnAbiError<'tcx> { fn fmt(&self, f: &mut fmt::Formatter<'_>) -> fmt::Result { match self { Self::Layout(err) => err.fmt(f), Self::AdjustForForeignAbi(err) => err.fmt(f), } } } impl IntoDiagnostic<'_, !> for FnAbiError<'_> { fn into_diagnostic(self, handler: &Handler) -> DiagnosticBuilder<'_, !> { handler.struct_fatal(self.to_string()) } } // FIXME(eddyb) maybe use something like this for an unified `fn_abi_of`, not // just for error handling. #[derive(Debug)] pub enum FnAbiRequest<'tcx> { OfFnPtr { sig: ty::PolyFnSig<'tcx>, extra_args: &'tcx ty::List> }, OfInstance { instance: ty::Instance<'tcx>, extra_args: &'tcx ty::List> }, } /// Trait for contexts that want to be able to compute `FnAbi`s. /// This automatically gives access to `FnAbiOf`, through a blanket `impl`. pub trait FnAbiOfHelpers<'tcx>: LayoutOfHelpers<'tcx> { /// The `&FnAbi`-wrapping type (or `&FnAbi` itself), which will be /// returned from `fn_abi_of_*` (see also `handle_fn_abi_err`). type FnAbiOfResult: MaybeResult<&'tcx FnAbi<'tcx, Ty<'tcx>>>; /// Helper used for `fn_abi_of_*`, to adapt `tcx.fn_abi_of_*(...)` into a /// `Self::FnAbiOfResult` (which does not need to be a `Result<...>`). /// /// Most `impl`s, which propagate `FnAbiError`s, should simply return `err`, /// but this hook allows e.g. codegen to return only `&FnAbi` from its /// `cx.fn_abi_of_*(...)`, without any `Result<...>` around it to deal with /// (and any `FnAbiError`s are turned into fatal errors or ICEs). fn handle_fn_abi_err( &self, err: FnAbiError<'tcx>, span: Span, fn_abi_request: FnAbiRequest<'tcx>, ) -> >>>::Error; } /// Blanket extension trait for contexts that can compute `FnAbi`s. pub trait FnAbiOf<'tcx>: FnAbiOfHelpers<'tcx> { /// Compute a `FnAbi` suitable for indirect calls, i.e. to `fn` pointers. /// /// NB: this doesn't handle virtual calls - those should use `fn_abi_of_instance` /// instead, where the instance is an `InstanceDef::Virtual`. #[inline] fn fn_abi_of_fn_ptr( &self, sig: ty::PolyFnSig<'tcx>, extra_args: &'tcx ty::List>, ) -> Self::FnAbiOfResult { // FIXME(eddyb) get a better `span` here. let span = self.layout_tcx_at_span(); let tcx = self.tcx().at(span); MaybeResult::from(tcx.fn_abi_of_fn_ptr(self.param_env().and((sig, extra_args))).map_err( |err| self.handle_fn_abi_err(err, span, FnAbiRequest::OfFnPtr { sig, extra_args }), )) } /// Compute a `FnAbi` suitable for declaring/defining an `fn` instance, and for /// direct calls to an `fn`. /// /// NB: that includes virtual calls, which are represented by "direct calls" /// to an `InstanceDef::Virtual` instance (of `::fn`). #[inline] #[tracing::instrument(level = "debug", skip(self))] fn fn_abi_of_instance( &self, instance: ty::Instance<'tcx>, extra_args: &'tcx ty::List>, ) -> Self::FnAbiOfResult { // FIXME(eddyb) get a better `span` here. let span = self.layout_tcx_at_span(); let tcx = self.tcx().at(span); MaybeResult::from( tcx.fn_abi_of_instance(self.param_env().and((instance, extra_args))).map_err(|err| { // HACK(eddyb) at least for definitions of/calls to `Instance`s, // we can get some kind of span even if one wasn't provided. // However, we don't do this early in order to avoid calling // `def_span` unconditionally (which may have a perf penalty). let span = if !span.is_dummy() { span } else { tcx.def_span(instance.def_id()) }; self.handle_fn_abi_err(err, span, FnAbiRequest::OfInstance { instance, extra_args }) }), ) } } impl<'tcx, C: FnAbiOfHelpers<'tcx>> FnAbiOf<'tcx> for C {}