diff options
Diffstat (limited to 'compiler/rustc_codegen_ssa/src/mir/operand.rs')
-rw-r--r-- | compiler/rustc_codegen_ssa/src/mir/operand.rs | 461 |
1 files changed, 461 insertions, 0 deletions
diff --git a/compiler/rustc_codegen_ssa/src/mir/operand.rs b/compiler/rustc_codegen_ssa/src/mir/operand.rs new file mode 100644 index 000000000..c612634fc --- /dev/null +++ b/compiler/rustc_codegen_ssa/src/mir/operand.rs @@ -0,0 +1,461 @@ +use super::place::PlaceRef; +use super::{FunctionCx, LocalRef}; + +use crate::base; +use crate::glue; +use crate::traits::*; +use crate::MemFlags; + +use rustc_middle::mir; +use rustc_middle::mir::interpret::{ConstValue, Pointer, Scalar}; +use rustc_middle::ty::layout::{LayoutOf, TyAndLayout}; +use rustc_middle::ty::Ty; +use rustc_target::abi::{Abi, Align, Size}; + +use std::fmt; + +/// The representation of a Rust value. The enum variant is in fact +/// uniquely determined by the value's type, but is kept as a +/// safety check. +#[derive(Copy, Clone, Debug)] +pub enum OperandValue<V> { + /// A reference to the actual operand. The data is guaranteed + /// to be valid for the operand's lifetime. + /// The second value, if any, is the extra data (vtable or length) + /// which indicates that it refers to an unsized rvalue. + Ref(V, Option<V>, Align), + /// A single LLVM value. + Immediate(V), + /// A pair of immediate LLVM values. Used by fat pointers too. + Pair(V, V), +} + +/// An `OperandRef` is an "SSA" reference to a Rust value, along with +/// its type. +/// +/// NOTE: unless you know a value's type exactly, you should not +/// generate LLVM opcodes acting on it and instead act via methods, +/// to avoid nasty edge cases. In particular, using `Builder::store` +/// directly is sure to cause problems -- use `OperandRef::store` +/// instead. +#[derive(Copy, Clone)] +pub struct OperandRef<'tcx, V> { + // The value. + pub val: OperandValue<V>, + + // The layout of value, based on its Rust type. + pub layout: TyAndLayout<'tcx>, +} + +impl<V: CodegenObject> fmt::Debug for OperandRef<'_, V> { + fn fmt(&self, f: &mut fmt::Formatter<'_>) -> fmt::Result { + write!(f, "OperandRef({:?} @ {:?})", self.val, self.layout) + } +} + +impl<'a, 'tcx, V: CodegenObject> OperandRef<'tcx, V> { + pub fn new_zst<Bx: BuilderMethods<'a, 'tcx, Value = V>>( + bx: &mut Bx, + layout: TyAndLayout<'tcx>, + ) -> OperandRef<'tcx, V> { + assert!(layout.is_zst()); + OperandRef { + val: OperandValue::Immediate(bx.const_undef(bx.immediate_backend_type(layout))), + layout, + } + } + + pub fn from_const<Bx: BuilderMethods<'a, 'tcx, Value = V>>( + bx: &mut Bx, + val: ConstValue<'tcx>, + ty: Ty<'tcx>, + ) -> Self { + let layout = bx.layout_of(ty); + + if layout.is_zst() { + return OperandRef::new_zst(bx, layout); + } + + let val = match val { + ConstValue::Scalar(x) => { + let Abi::Scalar(scalar) = layout.abi else { + bug!("from_const: invalid ByVal layout: {:#?}", layout); + }; + let llval = bx.scalar_to_backend(x, scalar, bx.immediate_backend_type(layout)); + OperandValue::Immediate(llval) + } + ConstValue::ZeroSized => { + let llval = bx.zst_to_backend(bx.immediate_backend_type(layout)); + OperandValue::Immediate(llval) + } + ConstValue::Slice { data, start, end } => { + let Abi::ScalarPair(a_scalar, _) = layout.abi else { + bug!("from_const: invalid ScalarPair layout: {:#?}", layout); + }; + let a = Scalar::from_pointer( + Pointer::new(bx.tcx().create_memory_alloc(data), Size::from_bytes(start)), + &bx.tcx(), + ); + let a_llval = bx.scalar_to_backend( + a, + a_scalar, + bx.scalar_pair_element_backend_type(layout, 0, true), + ); + let b_llval = bx.const_usize((end - start) as u64); + OperandValue::Pair(a_llval, b_llval) + } + ConstValue::ByRef { alloc, offset } => { + return bx.load_operand(bx.from_const_alloc(layout, alloc, offset)); + } + }; + + OperandRef { val, layout } + } + + /// Asserts that this operand refers to a scalar and returns + /// a reference to its value. + pub fn immediate(self) -> V { + match self.val { + OperandValue::Immediate(s) => s, + _ => bug!("not immediate: {:?}", self), + } + } + + pub fn deref<Cx: LayoutTypeMethods<'tcx>>(self, cx: &Cx) -> PlaceRef<'tcx, V> { + if self.layout.ty.is_box() { + bug!("dereferencing {:?} in codegen", self.layout.ty); + } + + let projected_ty = self + .layout + .ty + .builtin_deref(true) + .unwrap_or_else(|| bug!("deref of non-pointer {:?}", self)) + .ty; + + let (llptr, llextra) = match self.val { + OperandValue::Immediate(llptr) => (llptr, None), + OperandValue::Pair(llptr, llextra) => (llptr, Some(llextra)), + OperandValue::Ref(..) => bug!("Deref of by-Ref operand {:?}", self), + }; + let layout = cx.layout_of(projected_ty); + PlaceRef { llval: llptr, llextra, layout, align: layout.align.abi } + } + + /// If this operand is a `Pair`, we return an aggregate with the two values. + /// For other cases, see `immediate`. + pub fn immediate_or_packed_pair<Bx: BuilderMethods<'a, 'tcx, Value = V>>( + self, + bx: &mut Bx, + ) -> V { + if let OperandValue::Pair(a, b) = self.val { + let llty = bx.cx().backend_type(self.layout); + debug!("Operand::immediate_or_packed_pair: packing {:?} into {:?}", self, llty); + // Reconstruct the immediate aggregate. + let mut llpair = bx.cx().const_undef(llty); + let imm_a = bx.from_immediate(a); + let imm_b = bx.from_immediate(b); + llpair = bx.insert_value(llpair, imm_a, 0); + llpair = bx.insert_value(llpair, imm_b, 1); + llpair + } else { + self.immediate() + } + } + + /// If the type is a pair, we return a `Pair`, otherwise, an `Immediate`. + pub fn from_immediate_or_packed_pair<Bx: BuilderMethods<'a, 'tcx, Value = V>>( + bx: &mut Bx, + llval: V, + layout: TyAndLayout<'tcx>, + ) -> Self { + let val = if let Abi::ScalarPair(a, b) = layout.abi { + debug!("Operand::from_immediate_or_packed_pair: unpacking {:?} @ {:?}", llval, layout); + + // Deconstruct the immediate aggregate. + let a_llval = bx.extract_value(llval, 0); + let a_llval = bx.to_immediate_scalar(a_llval, a); + let b_llval = bx.extract_value(llval, 1); + let b_llval = bx.to_immediate_scalar(b_llval, b); + OperandValue::Pair(a_llval, b_llval) + } else { + OperandValue::Immediate(llval) + }; + OperandRef { val, layout } + } + + pub fn extract_field<Bx: BuilderMethods<'a, 'tcx, Value = V>>( + &self, + bx: &mut Bx, + i: usize, + ) -> Self { + let field = self.layout.field(bx.cx(), i); + let offset = self.layout.fields.offset(i); + + let mut val = match (self.val, self.layout.abi) { + // If the field is ZST, it has no data. + _ if field.is_zst() => { + return OperandRef::new_zst(bx, field); + } + + // Newtype of a scalar, scalar pair or vector. + (OperandValue::Immediate(_) | OperandValue::Pair(..), _) + if field.size == self.layout.size => + { + assert_eq!(offset.bytes(), 0); + self.val + } + + // Extract a scalar component from a pair. + (OperandValue::Pair(a_llval, b_llval), Abi::ScalarPair(a, b)) => { + if offset.bytes() == 0 { + assert_eq!(field.size, a.size(bx.cx())); + OperandValue::Immediate(a_llval) + } else { + assert_eq!(offset, a.size(bx.cx()).align_to(b.align(bx.cx()).abi)); + assert_eq!(field.size, b.size(bx.cx())); + OperandValue::Immediate(b_llval) + } + } + + // `#[repr(simd)]` types are also immediate. + (OperandValue::Immediate(llval), Abi::Vector { .. }) => { + OperandValue::Immediate(bx.extract_element(llval, bx.cx().const_usize(i as u64))) + } + + _ => bug!("OperandRef::extract_field({:?}): not applicable", self), + }; + + match (&mut val, field.abi) { + (OperandValue::Immediate(llval), _) => { + // Bools in union fields needs to be truncated. + *llval = bx.to_immediate(*llval, field); + // HACK(eddyb) have to bitcast pointers until LLVM removes pointee types. + *llval = bx.bitcast(*llval, bx.cx().immediate_backend_type(field)); + } + (OperandValue::Pair(a, b), Abi::ScalarPair(a_abi, b_abi)) => { + // Bools in union fields needs to be truncated. + *a = bx.to_immediate_scalar(*a, a_abi); + *b = bx.to_immediate_scalar(*b, b_abi); + // HACK(eddyb) have to bitcast pointers until LLVM removes pointee types. + *a = bx.bitcast(*a, bx.cx().scalar_pair_element_backend_type(field, 0, true)); + *b = bx.bitcast(*b, bx.cx().scalar_pair_element_backend_type(field, 1, true)); + } + (OperandValue::Pair(..), _) => bug!(), + (OperandValue::Ref(..), _) => bug!(), + } + + OperandRef { val, layout: field } + } +} + +impl<'a, 'tcx, V: CodegenObject> OperandValue<V> { + pub fn store<Bx: BuilderMethods<'a, 'tcx, Value = V>>( + self, + bx: &mut Bx, + dest: PlaceRef<'tcx, V>, + ) { + self.store_with_flags(bx, dest, MemFlags::empty()); + } + + pub fn volatile_store<Bx: BuilderMethods<'a, 'tcx, Value = V>>( + self, + bx: &mut Bx, + dest: PlaceRef<'tcx, V>, + ) { + self.store_with_flags(bx, dest, MemFlags::VOLATILE); + } + + pub fn unaligned_volatile_store<Bx: BuilderMethods<'a, 'tcx, Value = V>>( + self, + bx: &mut Bx, + dest: PlaceRef<'tcx, V>, + ) { + self.store_with_flags(bx, dest, MemFlags::VOLATILE | MemFlags::UNALIGNED); + } + + pub fn nontemporal_store<Bx: BuilderMethods<'a, 'tcx, Value = V>>( + self, + bx: &mut Bx, + dest: PlaceRef<'tcx, V>, + ) { + self.store_with_flags(bx, dest, MemFlags::NONTEMPORAL); + } + + fn store_with_flags<Bx: BuilderMethods<'a, 'tcx, Value = V>>( + self, + bx: &mut Bx, + dest: PlaceRef<'tcx, V>, + flags: MemFlags, + ) { + debug!("OperandRef::store: operand={:?}, dest={:?}", self, dest); + // Avoid generating stores of zero-sized values, because the only way to have a zero-sized + // value is through `undef`, and store itself is useless. + if dest.layout.is_zst() { + return; + } + match self { + OperandValue::Ref(r, None, source_align) => { + if flags.contains(MemFlags::NONTEMPORAL) { + // HACK(nox): This is inefficient but there is no nontemporal memcpy. + let ty = bx.backend_type(dest.layout); + let ptr = bx.pointercast(r, bx.type_ptr_to(ty)); + let val = bx.load(ty, ptr, source_align); + bx.store_with_flags(val, dest.llval, dest.align, flags); + return; + } + base::memcpy_ty(bx, dest.llval, dest.align, r, source_align, dest.layout, flags) + } + OperandValue::Ref(_, Some(_), _) => { + bug!("cannot directly store unsized values"); + } + OperandValue::Immediate(s) => { + let val = bx.from_immediate(s); + bx.store_with_flags(val, dest.llval, dest.align, flags); + } + OperandValue::Pair(a, b) => { + let Abi::ScalarPair(a_scalar, b_scalar) = dest.layout.abi else { + bug!("store_with_flags: invalid ScalarPair layout: {:#?}", dest.layout); + }; + let ty = bx.backend_type(dest.layout); + let b_offset = a_scalar.size(bx).align_to(b_scalar.align(bx).abi); + + let llptr = bx.struct_gep(ty, dest.llval, 0); + let val = bx.from_immediate(a); + let align = dest.align; + bx.store_with_flags(val, llptr, align, flags); + + let llptr = bx.struct_gep(ty, dest.llval, 1); + let val = bx.from_immediate(b); + let align = dest.align.restrict_for_offset(b_offset); + bx.store_with_flags(val, llptr, align, flags); + } + } + } + + pub fn store_unsized<Bx: BuilderMethods<'a, 'tcx, Value = V>>( + self, + bx: &mut Bx, + indirect_dest: PlaceRef<'tcx, V>, + ) { + debug!("OperandRef::store_unsized: operand={:?}, indirect_dest={:?}", self, indirect_dest); + let flags = MemFlags::empty(); + + // `indirect_dest` must have `*mut T` type. We extract `T` out of it. + let unsized_ty = indirect_dest + .layout + .ty + .builtin_deref(true) + .unwrap_or_else(|| bug!("indirect_dest has non-pointer type: {:?}", indirect_dest)) + .ty; + + let OperandValue::Ref(llptr, Some(llextra), _) = self else { + bug!("store_unsized called with a sized value") + }; + + // FIXME: choose an appropriate alignment, or use dynamic align somehow + let max_align = Align::from_bits(128).unwrap(); + let min_align = Align::from_bits(8).unwrap(); + + // Allocate an appropriate region on the stack, and copy the value into it + let (llsize, _) = glue::size_and_align_of_dst(bx, unsized_ty, Some(llextra)); + let lldst = bx.array_alloca(bx.cx().type_i8(), llsize, max_align); + bx.memcpy(lldst, max_align, llptr, min_align, llsize, flags); + + // Store the allocated region and the extra to the indirect place. + let indirect_operand = OperandValue::Pair(lldst, llextra); + indirect_operand.store(bx, indirect_dest); + } +} + +impl<'a, 'tcx, Bx: BuilderMethods<'a, 'tcx>> FunctionCx<'a, 'tcx, Bx> { + fn maybe_codegen_consume_direct( + &mut self, + bx: &mut Bx, + place_ref: mir::PlaceRef<'tcx>, + ) -> Option<OperandRef<'tcx, Bx::Value>> { + debug!("maybe_codegen_consume_direct(place_ref={:?})", place_ref); + + match self.locals[place_ref.local] { + LocalRef::Operand(Some(mut o)) => { + // Moves out of scalar and scalar pair fields are trivial. + for elem in place_ref.projection.iter() { + match elem { + mir::ProjectionElem::Field(ref f, _) => { + o = o.extract_field(bx, f.index()); + } + mir::ProjectionElem::Index(_) + | mir::ProjectionElem::ConstantIndex { .. } => { + // ZSTs don't require any actual memory access. + // FIXME(eddyb) deduplicate this with the identical + // checks in `codegen_consume` and `extract_field`. + let elem = o.layout.field(bx.cx(), 0); + if elem.is_zst() { + o = OperandRef::new_zst(bx, elem); + } else { + return None; + } + } + _ => return None, + } + } + + Some(o) + } + LocalRef::Operand(None) => { + bug!("use of {:?} before def", place_ref); + } + LocalRef::Place(..) | LocalRef::UnsizedPlace(..) => { + // watch out for locals that do not have an + // alloca; they are handled somewhat differently + None + } + } + } + + pub fn codegen_consume( + &mut self, + bx: &mut Bx, + place_ref: mir::PlaceRef<'tcx>, + ) -> OperandRef<'tcx, Bx::Value> { + debug!("codegen_consume(place_ref={:?})", place_ref); + + let ty = self.monomorphized_place_ty(place_ref); + let layout = bx.cx().layout_of(ty); + + // ZSTs don't require any actual memory access. + if layout.is_zst() { + return OperandRef::new_zst(bx, layout); + } + + if let Some(o) = self.maybe_codegen_consume_direct(bx, place_ref) { + return o; + } + + // for most places, to consume them we just load them + // out from their home + let place = self.codegen_place(bx, place_ref); + bx.load_operand(place) + } + + pub fn codegen_operand( + &mut self, + bx: &mut Bx, + operand: &mir::Operand<'tcx>, + ) -> OperandRef<'tcx, Bx::Value> { + debug!("codegen_operand(operand={:?})", operand); + + match *operand { + mir::Operand::Copy(ref place) | mir::Operand::Move(ref place) => { + self.codegen_consume(bx, place.as_ref()) + } + + mir::Operand::Constant(ref constant) => { + // This cannot fail because we checked all required_consts in advance. + self.eval_mir_constant_to_operand(bx, constant).unwrap_or_else(|_err| { + span_bug!(constant.span, "erroneous constant not captured by required_consts") + }) + } + } + } +} |