nordic-dev.net/rust
nordic-dev.net/rust
2
0
Fork 0
mirror of https://github.com/rust-lang/rust.git synced 2025-06-21 03:57:38 +00:00
Code Issues Packages Projects Releases Wiki Activity
db03a2deb0
rust/compiler/rustc_mir_dataflow/src/elaborate_drops.rs
Yuri Astrakhan 5160f8f843 Spellchecking compiler comments 
This PR cleans up the rest of the spelling mistakes in the compiler comments. This PR does not change any literal or code spelling issues.
2022-03-30 15:14:15 -04:00

1044 lines
38 KiB
Rust
Raw Blame History

use rustc_hir as hir;
use rustc_hir::lang_items::LangItem;
use rustc_index::vec::Idx;
use rustc_middle::mir::patch::MirPatch;
use rustc_middle::mir::*;
use rustc_middle::traits::Reveal;
use rustc_middle::ty::subst::SubstsRef;
use rustc_middle::ty::util::IntTypeExt;
use rustc_middle::ty::{self, Ty, TyCtxt};
use rustc_target::abi::VariantIdx;
use std::{fmt, iter};
/// The value of an inserted drop flag.
#[derive(Debug, PartialEq, Eq, Copy, Clone)]
pub enum DropFlagState {
/// The tracked value is initialized and needs to be dropped when leaving its scope.
Present,
/// The tracked value is uninitialized or was moved out of and does not need to be dropped when
/// leaving its scope.
Absent,
}
impl DropFlagState {
pub fn value(self) -> bool {
match self {
DropFlagState::Present => true,
DropFlagState::Absent => false,
}
}
}
/// Describes how/if a value should be dropped.
#[derive(Debug)]
pub enum DropStyle {
/// The value is already dead at the drop location, no drop will be executed.
Dead,
/// The value is known to always be initialized at the drop location, drop will always be
/// executed.
Static,
/// Whether the value needs to be dropped depends on its drop flag.
Conditional,
/// An "open" drop is one where only the fields of a value are dropped.
///
/// For example, this happens when moving out of a struct field: The rest of the struct will be
/// dropped in such an "open" drop. It is also used to generate drop glue for the individual
/// components of a value, for example for dropping array elements.
Open,
}
/// Which drop flags to affect/check with an operation.
#[derive(Debug)]
pub enum DropFlagMode {
/// Only affect the top-level drop flag, not that of any contained fields.
Shallow,
/// Affect all nested drop flags in addition to the top-level one.
Deep,
}
/// Describes if unwinding is necessary and where to unwind to if a panic occurs.
#[derive(Copy, Clone, Debug)]
pub enum Unwind {
/// Unwind to this block.
To(BasicBlock),
/// Already in an unwind path, any panic will cause an abort.
InCleanup,
}
impl Unwind {
fn is_cleanup(self) -> bool {
match self {
Unwind::To(..) => false,
Unwind::InCleanup => true,
}
}
fn into_option(self) -> Option<BasicBlock> {
match self {
Unwind::To(bb) => Some(bb),
Unwind::InCleanup => None,
}
}
fn map<F>(self, f: F) -> Self
where
F: FnOnce(BasicBlock) -> BasicBlock,
{
match self {
Unwind::To(bb) => Unwind::To(f(bb)),
Unwind::InCleanup => Unwind::InCleanup,
}
}
}
pub trait DropElaborator<'a, 'tcx>: fmt::Debug {
/// The type representing paths that can be moved out of.
///
/// Users can move out of individual fields of a struct, such as `a.b.c`. This type is used to
/// represent such move paths. Sometimes tracking individual move paths is not necessary, in
/// which case this may be set to (for example) `()`.
type Path: Copy + fmt::Debug;
// Accessors
fn patch(&mut self) -> &mut MirPatch<'tcx>;
fn body(&self) -> &'a Body<'tcx>;
fn tcx(&self) -> TyCtxt<'tcx>;
fn param_env(&self) -> ty::ParamEnv<'tcx>;
// Drop logic
/// Returns how `path` should be dropped, given `mode`.
fn drop_style(&self, path: Self::Path, mode: DropFlagMode) -> DropStyle;
/// Returns the drop flag of `path` as a MIR `Operand` (or `None` if `path` has no drop flag).
fn get_drop_flag(&mut self, path: Self::Path) -> Option<Operand<'tcx>>;
/// Modifies the MIR patch so that the drop flag of `path` (if any) is cleared at `location`.
///
/// If `mode` is deep, drop flags of all child paths should also be cleared by inserting
/// additional statements.
fn clear_drop_flag(&mut self, location: Location, path: Self::Path, mode: DropFlagMode);
// Subpaths
/// Returns the subpath of a field of `path` (or `None` if there is no dedicated subpath).
///
/// If this returns `None`, `field` will not get a dedicated drop flag.
fn field_subpath(&self, path: Self::Path, field: Field) -> Option<Self::Path>;
/// Returns the subpath of a dereference of `path` (or `None` if there is no dedicated subpath).
///
/// If this returns `None`, `*path` will not get a dedicated drop flag.
///
/// This is only relevant for `Box<T>`, where the contained `T` can be moved out of the box.
fn deref_subpath(&self, path: Self::Path) -> Option<Self::Path>;
/// Returns the subpath of downcasting `path` to one of its variants.
///
/// If this returns `None`, the downcast of `path` will not get a dedicated drop flag.
fn downcast_subpath(&self, path: Self::Path, variant: VariantIdx) -> Option<Self::Path>;
/// Returns the subpath of indexing a fixed-size array `path`.
///
/// If this returns `None`, elements of `path` will not get a dedicated drop flag.
///
/// This is only relevant for array patterns, which can move out of individual array elements.
fn array_subpath(&self, path: Self::Path, index: u64, size: u64) -> Option<Self::Path>;
}
#[derive(Debug)]
struct DropCtxt<'l, 'b, 'tcx, D>
where
D: DropElaborator<'b, 'tcx>,
{
elaborator: &'l mut D,
source_info: SourceInfo,
place: Place<'tcx>,
path: D::Path,
succ: BasicBlock,
unwind: Unwind,
}
/// "Elaborates" a drop of `place`/`path` and patches `bb`'s terminator to execute it.
///
/// The passed `elaborator` is used to determine what should happen at the drop terminator. It
/// decides whether the drop can be statically determined or whether it needs a dynamic drop flag,
/// and whether the drop is "open", ie. should be expanded to drop all subfields of the dropped
/// value.
///
/// When this returns, the MIR patch in the `elaborator` contains the necessary changes.
pub fn elaborate_drop<'b, 'tcx, D>(
elaborator: &mut D,
source_info: SourceInfo,
place: Place<'tcx>,
path: D::Path,
succ: BasicBlock,
unwind: Unwind,
bb: BasicBlock,
) where
D: DropElaborator<'b, 'tcx>,
'tcx: 'b,
{
DropCtxt { elaborator, source_info, place, path, succ, unwind }.elaborate_drop(bb)
}
impl<'l, 'b, 'tcx, D> DropCtxt<'l, 'b, 'tcx, D>
where
D: DropElaborator<'b, 'tcx>,
'tcx: 'b,
{
fn place_ty(&self, place: Place<'tcx>) -> Ty<'tcx> {
place.ty(self.elaborator.body(), self.tcx()).ty
}
fn tcx(&self) -> TyCtxt<'tcx> {
self.elaborator.tcx()
}
/// This elaborates a single drop instruction, located at `bb`, and
/// patches over it.
///
/// The elaborated drop checks the drop flags to only drop what
/// is initialized.
///
/// In addition, the relevant drop flags also need to be cleared
/// to avoid double-drops. However, in the middle of a complex
/// drop, one must avoid clearing some of the flags before they
/// are read, as that would cause a memory leak.
///
/// In particular, when dropping an ADT, multiple fields may be
/// joined together under the `rest` subpath. They are all controlled
/// by the primary drop flag, but only the last rest-field dropped
/// should clear it (and it must also not clear anything else).
//
// FIXME: I think we should just control the flags externally,
// and then we do not need this machinery.
pub fn elaborate_drop(&mut self, bb: BasicBlock) {
debug!("elaborate_drop({:?}, {:?})", bb, self);
let style = self.elaborator.drop_style(self.path, DropFlagMode::Deep);
debug!("elaborate_drop({:?}, {:?}): live - {:?}", bb, self, style);
match style {
DropStyle::Dead => {
self.elaborator
.patch()
.patch_terminator(bb, TerminatorKind::Goto { target: self.succ });
}
DropStyle::Static => {
self.elaborator.patch().patch_terminator(
bb,
TerminatorKind::Drop {
place: self.place,
target: self.succ,
unwind: self.unwind.into_option(),
},
);
}
DropStyle::Conditional => {
let drop_bb = self.complete_drop(self.succ, self.unwind);
self.elaborator
.patch()
.patch_terminator(bb, TerminatorKind::Goto { target: drop_bb });
}
DropStyle::Open => {
let drop_bb = self.open_drop();
self.elaborator
.patch()
.patch_terminator(bb, TerminatorKind::Goto { target: drop_bb });
}
}
}
/// Returns the place and move path for each field of `variant`,
/// (the move path is `None` if the field is a rest field).
fn move_paths_for_fields(
&self,
base_place: Place<'tcx>,
variant_path: D::Path,
variant: &'tcx ty::VariantDef,
substs: SubstsRef<'tcx>,
) -> Vec<(Place<'tcx>, Option<D::Path>)> {
variant
.fields
.iter()
.enumerate()
.map(|(i, f)| {
let field = Field::new(i);
let subpath = self.elaborator.field_subpath(variant_path, field);
let tcx = self.tcx();
assert_eq!(self.elaborator.param_env().reveal(), Reveal::All);
let field_ty =
tcx.normalize_erasing_regions(self.elaborator.param_env(), f.ty(tcx, substs));
(tcx.mk_place_field(base_place, field, field_ty), subpath)
})
.collect()
}
fn drop_subpath(
&mut self,
place: Place<'tcx>,
path: Option<D::Path>,
succ: BasicBlock,
unwind: Unwind,
) -> BasicBlock {
if let Some(path) = path {
debug!("drop_subpath: for std field {:?}", place);
DropCtxt {
elaborator: self.elaborator,
source_info: self.source_info,
path,
place,
succ,
unwind,
}
.elaborated_drop_block()
} else {
debug!("drop_subpath: for rest field {:?}", place);
DropCtxt {
elaborator: self.elaborator,
source_info: self.source_info,
place,
succ,
unwind,
// Using `self.path` here to condition the drop on
// our own drop flag.
path: self.path,
}
.complete_drop(succ, unwind)
}
}
/// Creates one-half of the drop ladder for a list of fields, and return
/// the list of steps in it in reverse order, with the first step
/// dropping 0 fields and so on.
///
/// `unwind_ladder` is such a list of steps in reverse order,
/// which is called if the matching step of the drop glue panics.
fn drop_halfladder(
&mut self,
unwind_ladder: &[Unwind],
mut succ: BasicBlock,
fields: &[(Place<'tcx>, Option<D::Path>)],
) -> Vec<BasicBlock> {
iter::once(succ)
.chain(fields.iter().rev().zip(unwind_ladder).map(|(&(place, path), &unwind_succ)| {
succ = self.drop_subpath(place, path, succ, unwind_succ);
succ
}))
.collect()
}
fn drop_ladder_bottom(&mut self) -> (BasicBlock, Unwind) {
// Clear the "master" drop flag at the end. This is needed
// because the "master" drop protects the ADT's discriminant,
// which is invalidated after the ADT is dropped.
(self.drop_flag_reset_block(DropFlagMode::Shallow, self.succ, self.unwind), self.unwind)
}
/// Creates a full drop ladder, consisting of 2 connected half-drop-ladders
///
/// For example, with 3 fields, the drop ladder is
///
/// .d0:
/// ELAB(drop location.0 [target=.d1, unwind=.c1])
/// .d1:
/// ELAB(drop location.1 [target=.d2, unwind=.c2])
/// .d2:
/// ELAB(drop location.2 [target=`self.succ`, unwind=`self.unwind`])
/// .c1:
/// ELAB(drop location.1 [target=.c2])
/// .c2:
/// ELAB(drop location.2 [target=`self.unwind`])
///
/// NOTE: this does not clear the master drop flag, so you need
/// to point succ/unwind on a `drop_ladder_bottom`.
fn drop_ladder(
&mut self,
fields: Vec<(Place<'tcx>, Option<D::Path>)>,
succ: BasicBlock,
unwind: Unwind,
) -> (BasicBlock, Unwind) {
debug!("drop_ladder({:?}, {:?})", self, fields);
let mut fields = fields;
fields.retain(|&(place, _)| {
self.place_ty(place).needs_drop(self.tcx(), self.elaborator.param_env())
});
debug!("drop_ladder - fields needing drop: {:?}", fields);
let unwind_ladder = vec![Unwind::InCleanup; fields.len() + 1];
let unwind_ladder: Vec<_> = if let Unwind::To(target) = unwind {
let halfladder = self.drop_halfladder(&unwind_ladder, target, &fields);
halfladder.into_iter().map(Unwind::To).collect()
} else {
unwind_ladder
};
let normal_ladder = self.drop_halfladder(&unwind_ladder, succ, &fields);
(*normal_ladder.last().unwrap(), *unwind_ladder.last().unwrap())
}
fn open_drop_for_tuple(&mut self, tys: &[Ty<'tcx>]) -> BasicBlock {
debug!("open_drop_for_tuple({:?}, {:?})", self, tys);
let fields = tys
.iter()
.enumerate()
.map(|(i, &ty)| {
(
self.tcx().mk_place_field(self.place, Field::new(i), ty),
self.elaborator.field_subpath(self.path, Field::new(i)),
)
})
.collect();
let (succ, unwind) = self.drop_ladder_bottom();
self.drop_ladder(fields, succ, unwind).0
}
fn open_drop_for_box(&mut self, adt: ty::AdtDef<'tcx>, substs: SubstsRef<'tcx>) -> BasicBlock {
debug!("open_drop_for_box({:?}, {:?}, {:?})", self, adt, substs);
let interior = self.tcx().mk_place_deref(self.place);
let interior_path = self.elaborator.deref_subpath(self.path);
let succ = self.box_free_block(adt, substs, self.succ, self.unwind);
let unwind_succ =
self.unwind.map(|unwind| self.box_free_block(adt, substs, unwind, Unwind::InCleanup));
self.drop_subpath(interior, interior_path, succ, unwind_succ)
}
fn open_drop_for_adt(&mut self, adt: ty::AdtDef<'tcx>, substs: SubstsRef<'tcx>) -> BasicBlock {
debug!("open_drop_for_adt({:?}, {:?}, {:?})", self, adt, substs);
if adt.variants().is_empty() {
return self.elaborator.patch().new_block(BasicBlockData {
statements: vec![],
terminator: Some(Terminator {
source_info: self.source_info,
kind: TerminatorKind::Unreachable,
}),
is_cleanup: self.unwind.is_cleanup(),
});
}
let skip_contents =
adt.is_union() || Some(adt.did()) == self.tcx().lang_items().manually_drop();
let contents_drop = if skip_contents {
(self.succ, self.unwind)
} else {
self.open_drop_for_adt_contents(adt, substs)
};
if adt.has_dtor(self.tcx()) {
self.destructor_call_block(contents_drop)
} else {
contents_drop.0
}
}
fn open_drop_for_adt_contents(
&mut self,
adt: ty::AdtDef<'tcx>,
substs: SubstsRef<'tcx>,
) -> (BasicBlock, Unwind) {
let (succ, unwind) = self.drop_ladder_bottom();
if !adt.is_enum() {
let fields = self.move_paths_for_fields(
self.place,
self.path,
&adt.variant(VariantIdx::new(0)),
substs,
);
self.drop_ladder(fields, succ, unwind)
} else {
self.open_drop_for_multivariant(adt, substs, succ, unwind)
}
}
fn open_drop_for_multivariant(
&mut self,
adt: ty::AdtDef<'tcx>,
substs: SubstsRef<'tcx>,
succ: BasicBlock,
unwind: Unwind,
) -> (BasicBlock, Unwind) {
let mut values = Vec::with_capacity(adt.variants().len());
let mut normal_blocks = Vec::with_capacity(adt.variants().len());
let mut unwind_blocks =
if unwind.is_cleanup() { None } else { Some(Vec::with_capacity(adt.variants().len())) };
let mut have_otherwise_with_drop_glue = false;
let mut have_otherwise = false;
let tcx = self.tcx();
for (variant_index, discr) in adt.discriminants(tcx) {
let variant = &adt.variant(variant_index);
let subpath = self.elaborator.downcast_subpath(self.path, variant_index);
if let Some(variant_path) = subpath {
let base_place = tcx.mk_place_elem(
self.place,
ProjectionElem::Downcast(Some(variant.name), variant_index),
);
let fields = self.move_paths_for_fields(base_place, variant_path, &variant, substs);
values.push(discr.val);
if let Unwind::To(unwind) = unwind {
// We can't use the half-ladder from the original
// drop ladder, because this breaks the
// "funclet can't have 2 successor funclets"
// requirement from MSVC:
//
// switch unwind-switch
// / \ / \
// v1.0 v2.0 v2.0-unwind v1.0-unwind
// | | / |
// v1.1-unwind v2.1-unwind |
// ^ |
// \-------------------------------/
//
// Create a duplicate half-ladder to avoid that. We
// could technically only do this on MSVC, but I
// I want to minimize the divergence between MSVC
// and non-MSVC.
let unwind_blocks = unwind_blocks.as_mut().unwrap();
let unwind_ladder = vec![Unwind::InCleanup; fields.len() + 1];
let halfladder = self.drop_halfladder(&unwind_ladder, unwind, &fields);
unwind_blocks.push(halfladder.last().cloned().unwrap());
}
let (normal, _) = self.drop_ladder(fields, succ, unwind);
normal_blocks.push(normal);
} else {
have_otherwise = true;
let param_env = self.elaborator.param_env();
let have_field_with_drop_glue = variant
.fields
.iter()
.any(|field| field.ty(tcx, substs).needs_drop(tcx, param_env));
if have_field_with_drop_glue {
have_otherwise_with_drop_glue = true;
}
}
}
if !have_otherwise {
values.pop();
} else if !have_otherwise_with_drop_glue {
normal_blocks.push(self.goto_block(succ, unwind));
if let Unwind::To(unwind) = unwind {
unwind_blocks.as_mut().unwrap().push(self.goto_block(unwind, Unwind::InCleanup));
}
} else {
normal_blocks.push(self.drop_block(succ, unwind));
if let Unwind::To(unwind) = unwind {
unwind_blocks.as_mut().unwrap().push(self.drop_block(unwind, Unwind::InCleanup));
}
}
(
self.adt_switch_block(adt, normal_blocks, &values, succ, unwind),
unwind.map(|unwind| {
self.adt_switch_block(
adt,
unwind_blocks.unwrap(),
&values,
unwind,
Unwind::InCleanup,
)
}),
)
}
fn adt_switch_block(
&mut self,
adt: ty::AdtDef<'tcx>,
blocks: Vec<BasicBlock>,
values: &[u128],
succ: BasicBlock,
unwind: Unwind,
) -> BasicBlock {
// If there are multiple variants, then if something
// is present within the enum the discriminant, tracked
// by the rest path, must be initialized.
//
// Additionally, we do not want to switch on the
// discriminant after it is free-ed, because that
// way lies only trouble.
let discr_ty = adt.repr().discr_type().to_ty(self.tcx());
let discr = Place::from(self.new_temp(discr_ty));
let discr_rv = Rvalue::Discriminant(self.place);
let switch_block = BasicBlockData {
statements: vec![self.assign(discr, discr_rv)],
terminator: Some(Terminator {
source_info: self.source_info,
kind: TerminatorKind::SwitchInt {
discr: Operand::Move(discr),
switch_ty: discr_ty,
targets: SwitchTargets::new(
values.iter().copied().zip(blocks.iter().copied()),
*blocks.last().unwrap(),
),
},
}),
is_cleanup: unwind.is_cleanup(),
};
let switch_block = self.elaborator.patch().new_block(switch_block);
self.drop_flag_test_block(switch_block, succ, unwind)
}
fn destructor_call_block(&mut self, (succ, unwind): (BasicBlock, Unwind)) -> BasicBlock {
debug!("destructor_call_block({:?}, {:?})", self, succ);
let tcx = self.tcx();
let drop_trait = tcx.require_lang_item(LangItem::Drop, None);
let drop_fn = tcx.associated_item_def_ids(drop_trait)[0];
let ty = self.place_ty(self.place);
let substs = tcx.mk_substs_trait(ty, &[]);
let ref_ty =
tcx.mk_ref(tcx.lifetimes.re_erased, ty::TypeAndMut { ty, mutbl: hir::Mutability::Mut });
let ref_place = self.new_temp(ref_ty);
let unit_temp = Place::from(self.new_temp(tcx.mk_unit()));
let result = BasicBlockData {
statements: vec![self.assign(
Place::from(ref_place),
Rvalue::Ref(
tcx.lifetimes.re_erased,
BorrowKind::Mut { allow_two_phase_borrow: false },
self.place,
),
)],
terminator: Some(Terminator {
kind: TerminatorKind::Call {
func: Operand::function_handle(tcx, drop_fn, substs, self.source_info.span),
args: vec![Operand::Move(Place::from(ref_place))],
destination: Some((unit_temp, succ)),
cleanup: unwind.into_option(),
from_hir_call: true,
fn_span: self.source_info.span,
},
source_info: self.source_info,
}),
is_cleanup: unwind.is_cleanup(),
};
self.elaborator.patch().new_block(result)
}
/// Create a loop that drops an array:
///
/// ```text
/// loop-block:
/// can_go = cur == length_or_end
/// if can_go then succ else drop-block
/// drop-block:
/// if ptr_based {
/// ptr = cur
/// cur = cur.offset(1)
/// } else {
/// ptr = &raw mut P[cur]
/// cur = cur + 1
/// }
/// drop(ptr)
/// ```
fn drop_loop(
&mut self,
succ: BasicBlock,
cur: Local,
length_or_end: Place<'tcx>,
ety: Ty<'tcx>,
unwind: Unwind,
ptr_based: bool,
) -> BasicBlock {
let copy = |place: Place<'tcx>| Operand::Copy(place);
let move_ = |place: Place<'tcx>| Operand::Move(place);
let tcx = self.tcx();
let ptr_ty = tcx.mk_ptr(ty::TypeAndMut { ty: ety, mutbl: hir::Mutability::Mut });
let ptr = Place::from(self.new_temp(ptr_ty));
let can_go = Place::from(self.new_temp(tcx.types.bool));
let one = self.constant_usize(1);
let (ptr_next, cur_next) = if ptr_based {
(
Rvalue::Use(copy(cur.into())),
Rvalue::BinaryOp(BinOp::Offset, Box::new((move_(cur.into()), one))),
)
} else {
(
Rvalue::AddressOf(Mutability::Mut, tcx.mk_place_index(self.place, cur)),
Rvalue::BinaryOp(BinOp::Add, Box::new((move_(cur.into()), one))),
)
};
let drop_block = BasicBlockData {
statements: vec![self.assign(ptr, ptr_next), self.assign(Place::from(cur), cur_next)],
is_cleanup: unwind.is_cleanup(),
terminator: Some(Terminator {
source_info: self.source_info,
// this gets overwritten by drop elaboration.
kind: TerminatorKind::Unreachable,
}),
};
let drop_block = self.elaborator.patch().new_block(drop_block);
let loop_block = BasicBlockData {
statements: vec![self.assign(
can_go,
Rvalue::BinaryOp(
BinOp::Eq,
Box::new((copy(Place::from(cur)), copy(length_or_end))),
),
)],
is_cleanup: unwind.is_cleanup(),
terminator: Some(Terminator {
source_info: self.source_info,
kind: TerminatorKind::if_(tcx, move_(can_go), succ, drop_block),
}),
};
let loop_block = self.elaborator.patch().new_block(loop_block);
self.elaborator.patch().patch_terminator(
drop_block,
TerminatorKind::Drop {
place: tcx.mk_place_deref(ptr),
target: loop_block,
unwind: unwind.into_option(),
},
);
loop_block
}
fn open_drop_for_array(&mut self, ety: Ty<'tcx>, opt_size: Option<u64>) -> BasicBlock {
debug!("open_drop_for_array({:?}, {:?})", ety, opt_size);
// if size_of::<ety>() == 0 {
// index_based_loop
// } else {
// ptr_based_loop
// }
let tcx = self.tcx();
if let Some(size) = opt_size {
let fields: Vec<(Place<'tcx>, Option<D::Path>)> = (0..size)
.map(|i| {
(
tcx.mk_place_elem(
self.place,
ProjectionElem::ConstantIndex {
offset: i,
min_length: size,
from_end: false,
},
),
self.elaborator.array_subpath(self.path, i, size),
)
})
.collect();
if fields.iter().any(|(_, path)| path.is_some()) {
let (succ, unwind) = self.drop_ladder_bottom();
return self.drop_ladder(fields, succ, unwind).0;
}
}
let move_ = |place: Place<'tcx>| Operand::Move(place);
let elem_size = Place::from(self.new_temp(tcx.types.usize));
let len = Place::from(self.new_temp(tcx.types.usize));
let base_block = BasicBlockData {
statements: vec![
self.assign(elem_size, Rvalue::NullaryOp(NullOp::SizeOf, ety)),
self.assign(len, Rvalue::Len(self.place)),
],
is_cleanup: self.unwind.is_cleanup(),
terminator: Some(Terminator {
source_info: self.source_info,
kind: TerminatorKind::SwitchInt {
discr: move_(elem_size),
switch_ty: tcx.types.usize,
targets: SwitchTargets::static_if(
0,
self.drop_loop_pair(ety, false, len),
self.drop_loop_pair(ety, true, len),
),
},
}),
};
self.elaborator.patch().new_block(base_block)
}
/// Creates a pair of drop-loops of `place`, which drops its contents, even
/// in the case of 1 panic. If `ptr_based`, creates a pointer loop,
/// otherwise create an index loop.
fn drop_loop_pair(
&mut self,
ety: Ty<'tcx>,
ptr_based: bool,
length: Place<'tcx>,
) -> BasicBlock {
debug!("drop_loop_pair({:?}, {:?})", ety, ptr_based);
let tcx = self.tcx();
let iter_ty = if ptr_based { tcx.mk_mut_ptr(ety) } else { tcx.types.usize };
let cur = self.new_temp(iter_ty);
let length_or_end = if ptr_based { Place::from(self.new_temp(iter_ty)) } else { length };
let unwind = self.unwind.map(|unwind| {
self.drop_loop(unwind, cur, length_or_end, ety, Unwind::InCleanup, ptr_based)
});
let loop_block = self.drop_loop(self.succ, cur, length_or_end, ety, unwind, ptr_based);
let cur = Place::from(cur);
let drop_block_stmts = if ptr_based {
let tmp_ty = tcx.mk_mut_ptr(self.place_ty(self.place));
let tmp = Place::from(self.new_temp(tmp_ty));
// tmp = &raw mut P;
// cur = tmp as *mut T;
// end = Offset(cur, len);
vec![
self.assign(tmp, Rvalue::AddressOf(Mutability::Mut, self.place)),
self.assign(cur, Rvalue::Cast(CastKind::Misc, Operand::Move(tmp), iter_ty)),
self.assign(
length_or_end,
Rvalue::BinaryOp(
BinOp::Offset,
Box::new((Operand::Copy(cur), Operand::Move(length))),
),
),
]
} else {
// cur = 0 (length already pushed)
let zero = self.constant_usize(0);
vec![self.assign(cur, Rvalue::Use(zero))]
};
let drop_block = self.elaborator.patch().new_block(BasicBlockData {
statements: drop_block_stmts,
is_cleanup: unwind.is_cleanup(),
terminator: Some(Terminator {
source_info: self.source_info,
kind: TerminatorKind::Goto { target: loop_block },
}),
});
// FIXME(#34708): handle partially-dropped array/slice elements.
let reset_block = self.drop_flag_reset_block(DropFlagMode::Deep, drop_block, unwind);
self.drop_flag_test_block(reset_block, self.succ, unwind)
}
/// The slow-path - create an "open", elaborated drop for a type
/// which is moved-out-of only partially, and patch `bb` to a jump
/// to it. This must not be called on ADTs with a destructor,
/// as these can't be moved-out-of, except for `Box<T>`, which is
/// special-cased.
///
/// This creates a "drop ladder" that drops the needed fields of the
/// ADT, both in the success case or if one of the destructors fail.
fn open_drop(&mut self) -> BasicBlock {
let ty = self.place_ty(self.place);
match ty.kind() {
ty::Closure(_, substs) => {
let tys: Vec<_> = substs.as_closure().upvar_tys().collect();
self.open_drop_for_tuple(&tys)
}
// Note that `elaborate_drops` only drops the upvars of a generator,
// and this is ok because `open_drop` here can only be reached
// within that own generator's resume function.
// This should only happen for the self argument on the resume function.
// It effectively only contains upvars until the generator transformation runs.
// See librustc_body/transform/generator.rs for more details.
ty::Generator(_, substs, _) => {
let tys: Vec<_> = substs.as_generator().upvar_tys().collect();
self.open_drop_for_tuple(&tys)
}
ty::Tuple(fields) => self.open_drop_for_tuple(fields),
ty::Adt(def, substs) => {
if def.is_box() {
self.open_drop_for_box(*def, substs)
} else {
self.open_drop_for_adt(*def, substs)
}
}
ty::Dynamic(..) => self.complete_drop(self.succ, self.unwind),
ty::Array(ety, size) => {
let size = size.try_eval_usize(self.tcx(), self.elaborator.param_env());
self.open_drop_for_array(*ety, size)
}
ty::Slice(ety) => self.open_drop_for_array(*ety, None),
_ => bug!("open drop from non-ADT `{:?}`", ty),
}
}
fn complete_drop(&mut self, succ: BasicBlock, unwind: Unwind) -> BasicBlock {
debug!("complete_drop(succ={:?}, unwind={:?})", succ, unwind);
let drop_block = self.drop_block(succ, unwind);
self.drop_flag_test_block(drop_block, succ, unwind)
}
/// Creates a block that resets the drop flag. If `mode` is deep, all children drop flags will
/// also be cleared.
fn drop_flag_reset_block(
&mut self,
mode: DropFlagMode,
succ: BasicBlock,
unwind: Unwind,
) -> BasicBlock {
debug!("drop_flag_reset_block({:?},{:?})", self, mode);
if unwind.is_cleanup() {
// The drop flag isn't read again on the unwind path, so don't
// bother setting it.
return succ;
}
let block = self.new_block(unwind, TerminatorKind::Goto { target: succ });
let block_start = Location { block, statement_index: 0 };
self.elaborator.clear_drop_flag(block_start, self.path, mode);
block
}
fn elaborated_drop_block(&mut self) -> BasicBlock {
debug!("elaborated_drop_block({:?})", self);
let blk = self.drop_block(self.succ, self.unwind);
self.elaborate_drop(blk);
blk
}
/// Creates a block that frees the backing memory of a `Box` if its drop is required (either
/// statically or by checking its drop flag).
///
/// The contained value will not be dropped.
fn box_free_block(
&mut self,
adt: ty::AdtDef<'tcx>,
substs: SubstsRef<'tcx>,
target: BasicBlock,
unwind: Unwind,
) -> BasicBlock {
let block = self.unelaborated_free_block(adt, substs, target, unwind);
self.drop_flag_test_block(block, target, unwind)
}
/// Creates a block that frees the backing memory of a `Box` (without dropping the contained
/// value).
fn unelaborated_free_block(
&mut self,
adt: ty::AdtDef<'tcx>,
substs: SubstsRef<'tcx>,
target: BasicBlock,
unwind: Unwind,
) -> BasicBlock {
let tcx = self.tcx();
let unit_temp = Place::from(self.new_temp(tcx.mk_unit()));
let free_func = tcx.require_lang_item(LangItem::BoxFree, Some(self.source_info.span));
let args = adt
.variant(VariantIdx::new(0))
.fields
.iter()
.enumerate()
.map(|(i, f)| {
let field = Field::new(i);
let field_ty = f.ty(tcx, substs);
Operand::Move(tcx.mk_place_field(self.place, field, field_ty))
})
.collect();
let call = TerminatorKind::Call {
func: Operand::function_handle(tcx, free_func, substs, self.source_info.span),
args,
destination: Some((unit_temp, target)),
cleanup: None,
from_hir_call: false,
fn_span: self.source_info.span,
}; // FIXME(#43234)
let free_block = self.new_block(unwind, call);
let block_start = Location { block: free_block, statement_index: 0 };
self.elaborator.clear_drop_flag(block_start, self.path, DropFlagMode::Shallow);
free_block
}
fn drop_block(&mut self, target: BasicBlock, unwind: Unwind) -> BasicBlock {
let block =
TerminatorKind::Drop { place: self.place, target, unwind: unwind.into_option() };
self.new_block(unwind, block)
}
fn goto_block(&mut self, target: BasicBlock, unwind: Unwind) -> BasicBlock {
let block = TerminatorKind::Goto { target };
self.new_block(unwind, block)
}
/// Returns the block to jump to in order to test the drop flag and execute the drop.
///
/// Depending on the required `DropStyle`, this might be a generated block with an `if`
/// terminator (for dynamic/open drops), or it might be `on_set` or `on_unset` itself, in case
/// the drop can be statically determined.
fn drop_flag_test_block(
&mut self,
on_set: BasicBlock,
on_unset: BasicBlock,
unwind: Unwind,
) -> BasicBlock {
let style = self.elaborator.drop_style(self.path, DropFlagMode::Shallow);
debug!(
"drop_flag_test_block({:?},{:?},{:?},{:?}) - {:?}",
self, on_set, on_unset, unwind, style
);
match style {
DropStyle::Dead => on_unset,
DropStyle::Static => on_set,
DropStyle::Conditional | DropStyle::Open => {
let flag = self.elaborator.get_drop_flag(self.path).unwrap();
let term = TerminatorKind::if_(self.tcx(), flag, on_set, on_unset);
self.new_block(unwind, term)
}
}
}
fn new_block(&mut self, unwind: Unwind, k: TerminatorKind<'tcx>) -> BasicBlock {
self.elaborator.patch().new_block(BasicBlockData {
statements: vec![],
terminator: Some(Terminator { source_info: self.source_info, kind: k }),
is_cleanup: unwind.is_cleanup(),
})
}
fn new_temp(&mut self, ty: Ty<'tcx>) -> Local {
self.elaborator.patch().new_temp(ty, self.source_info.span)
}
fn constant_usize(&self, val: u16) -> Operand<'tcx> {
Operand::Constant(Box::new(Constant {
span: self.source_info.span,
user_ty: None,
literal: ty::Const::from_usize(self.tcx(), val.into()).into(),
}))
}
fn assign(&self, lhs: Place<'tcx>, rhs: Rvalue<'tcx>) -> Statement<'tcx> {
Statement {
source_info: self.source_info,
kind: StatementKind::Assign(Box::new((lhs, rhs))),
}
}
}
Reference in New Issue View Git Blame Copy Permalink