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//! Mono Item Collection
//! ====================
//!
//! This module is responsible for discovering all items that will contribute
//! to code generation of the crate. The important part here is that it not only
//! needs to find syntax-level items (functions, structs, etc) but also all
//! their monomorphized instantiations. Every non-generic, non-const function
//! maps to one LLVM artifact. Every generic function can produce
//! from zero to N artifacts, depending on the sets of type arguments it
//! is instantiated with.
//! This also applies to generic items from other crates: A generic definition
//! in crate X might produce monomorphizations that are compiled into crate Y.
//! We also have to collect these here.
//!
//! The following kinds of "mono items" are handled here:
//!
//! - Functions
//! - Methods
//! - Closures
//! - Statics
//! - Drop glue
//!
//! The following things also result in LLVM artifacts, but are not collected
//! here, since we instantiate them locally on demand when needed in a given
//! codegen unit:
//!
//! - Constants
//! - VTables
//! - Object Shims
//!
//!
//! General Algorithm
//! -----------------
//! Let's define some terms first:
//!
//! - A "mono item" is something that results in a function or global in
//! the LLVM IR of a codegen unit. Mono items do not stand on their
//! own, they can use other mono items. For example, if function
//! `foo()` calls function `bar()` then the mono item for `foo()`
//! uses the mono item for function `bar()`. In general, the
//! definition for mono item A using a mono item B is that
//! the LLVM artifact produced for A uses the LLVM artifact produced
//! for B.
//!
//! - Mono items and the uses between them form a directed graph,
//! where the mono items are the nodes and uses form the edges.
//! Let's call this graph the "mono item graph".
//!
//! - The mono item graph for a program contains all mono items
//! that are needed in order to produce the complete LLVM IR of the program.
//!
//! The purpose of the algorithm implemented in this module is to build the
//! mono item graph for the current crate. It runs in two phases:
//!
//! 1. Discover the roots of the graph by traversing the HIR of the crate.
//! 2. Starting from the roots, find uses by inspecting the MIR
//! representation of the item corresponding to a given node, until no more
//! new nodes are found.
//!
//! ### Discovering roots
//! The roots of the mono item graph correspond to the public non-generic
//! syntactic items in the source code. We find them by walking the HIR of the
//! crate, and whenever we hit upon a public function, method, or static item,
//! we create a mono item consisting of the items DefId and, since we only
//! consider non-generic items, an empty type-substitution set. (In eager
//! collection mode, during incremental compilation, all non-generic functions
//! are considered as roots, as well as when the `-Clink-dead-code` option is
//! specified. Functions marked `#[no_mangle]` and functions called by inlinable
//! functions also always act as roots.)
//!
//! ### Finding uses
//! Given a mono item node, we can discover uses by inspecting its MIR. We walk
//! the MIR to find other mono items used by each mono item. Since the mono
//! item we are currently at is always monomorphic, we also know the concrete
//! type arguments of its used mono items. The specific forms a use can take in
//! MIR are quite diverse. Here is an overview:
//!
//! #### Calling Functions/Methods
//! The most obvious way for one mono item to use another is a
//! function or method call (represented by a CALL terminator in MIR). But
//! calls are not the only thing that might introduce a use between two
//! function mono items, and as we will see below, they are just a
//! specialization of the form described next, and consequently will not get any
//! special treatment in the algorithm.
//!
//! #### Taking a reference to a function or method
//! A function does not need to actually be called in order to be used by
//! another function. It suffices to just take a reference in order to introduce
//! an edge. Consider the following example:
//!
//! ```
//! # use core::fmt::Display;
//! fn print_val<T: Display>(x: T) {
//! println!("{}", x);
//! }
//!
//! fn call_fn(f: &dyn Fn(i32), x: i32) {
//! f(x);
//! }
//!
//! fn main() {
//! let print_i32 = print_val::<i32>;
//! call_fn(&print_i32, 0);
//! }
//! ```
//! The MIR of none of these functions will contain an explicit call to
//! `print_val::<i32>`. Nonetheless, in order to mono this program, we need
//! an instance of this function. Thus, whenever we encounter a function or
//! method in operand position, we treat it as a use of the current
//! mono item. Calls are just a special case of that.
//!
//! #### Drop glue
//! Drop glue mono items are introduced by MIR drop-statements. The
//! generated mono item will have additional drop-glue item uses if the
//! type to be dropped contains nested values that also need to be dropped. It
//! might also have a function item use for the explicit `Drop::drop`
//! implementation of its type.
//!
//! #### Unsizing Casts
//! A subtle way of introducing use edges is by casting to a trait object.
//! Since the resulting fat-pointer contains a reference to a vtable, we need to
//! instantiate all object-safe methods of the trait, as we need to store
//! pointers to these functions even if they never get called anywhere. This can
//! be seen as a special case of taking a function reference.
//!
//!
//! Interaction with Cross-Crate Inlining
//! -------------------------------------
//! The binary of a crate will not only contain machine code for the items
//! defined in the source code of that crate. It will also contain monomorphic
//! instantiations of any extern generic functions and of functions marked with
//! `#[inline]`.
//! The collection algorithm handles this more or less mono. If it is
//! about to create a mono item for something with an external `DefId`,
//! it will take a look if the MIR for that item is available, and if so just
//! proceed normally. If the MIR is not available, it assumes that the item is
//! just linked to and no node is created; which is exactly what we want, since
//! no machine code should be generated in the current crate for such an item.
//!
//! Eager and Lazy Collection Mode
//! ------------------------------
//! Mono item collection can be performed in one of two modes:
//!
//! - Lazy mode means that items will only be instantiated when actually
//! used. The goal is to produce the least amount of machine code
//! possible.
//!
//! - Eager mode is meant to be used in conjunction with incremental compilation
//! where a stable set of mono items is more important than a minimal
//! one. Thus, eager mode will instantiate drop-glue for every drop-able type
//! in the crate, even if no drop call for that type exists (yet). It will
//! also instantiate default implementations of trait methods, something that
//! otherwise is only done on demand.
//!
//!
//! Open Issues
//! -----------
//! Some things are not yet fully implemented in the current version of this
//! module.
//!
//! ### Const Fns
//! Ideally, no mono item should be generated for const fns unless there
//! is a call to them that cannot be evaluated at compile time. At the moment
//! this is not implemented however: a mono item will be produced
//! regardless of whether it is actually needed or not.
use rustc_data_structures::fx::{FxHashMap, FxHashSet};
use rustc_data_structures::sync::{par_for_each_in, MTLock, MTLockRef};
use rustc_hir as hir;
use rustc_hir::def::DefKind;
use rustc_hir::def_id::{DefId, DefIdMap, LocalDefId};
use rustc_hir::lang_items::LangItem;
use rustc_middle::mir::interpret::{AllocId, ErrorHandled, GlobalAlloc, Scalar};
use rustc_middle::mir::mono::{InstantiationMode, MonoItem};
use rustc_middle::mir::visit::Visitor as MirVisitor;
use rustc_middle::mir::{self, Local, Location};
use rustc_middle::query::TyCtxtAt;
use rustc_middle::ty::adjustment::{CustomCoerceUnsized, PointerCoercion};
use rustc_middle::ty::print::with_no_trimmed_paths;
use rustc_middle::ty::{
self, AssocKind, GenericParamDefKind, Instance, InstanceDef, Ty, TyCtxt, TypeFoldable,
TypeVisitableExt, VtblEntry,
};
use rustc_middle::ty::{GenericArgKind, GenericArgs};
use rustc_middle::{middle::codegen_fn_attrs::CodegenFnAttrFlags, mir::visit::TyContext};
use rustc_session::config::EntryFnType;
use rustc_session::lint::builtin::LARGE_ASSIGNMENTS;
use rustc_session::Limit;
use rustc_span::source_map::{dummy_spanned, respan, Span, Spanned, DUMMY_SP};
use rustc_span::symbol::{sym, Ident};
use rustc_target::abi::Size;
use std::path::PathBuf;
use crate::errors::{
EncounteredErrorWhileInstantiating, LargeAssignmentsLint, NoOptimizedMir, RecursionLimit,
TypeLengthLimit,
};
#[derive(PartialEq)]
pub enum MonoItemCollectionMode {
Eager,
Lazy,
}
pub struct UsageMap<'tcx> {
// Maps every mono item to the mono items used by it.
used_map: FxHashMap<MonoItem<'tcx>, Vec<MonoItem<'tcx>>>,
// Maps every mono item to the mono items that use it.
user_map: FxHashMap<MonoItem<'tcx>, Vec<MonoItem<'tcx>>>,
}
type MonoItems<'tcx> = Vec<Spanned<MonoItem<'tcx>>>;
impl<'tcx> UsageMap<'tcx> {
fn new() -> UsageMap<'tcx> {
UsageMap { used_map: FxHashMap::default(), user_map: FxHashMap::default() }
}
fn record_used<'a>(
&mut self,
user_item: MonoItem<'tcx>,
used_items: &'a [Spanned<MonoItem<'tcx>>],
) where
'tcx: 'a,
{
let used_items: Vec<_> = used_items.iter().map(|item| item.node).collect();
for &used_item in used_items.iter() {
self.user_map.entry(used_item).or_default().push(user_item);
}
assert!(self.used_map.insert(user_item, used_items).is_none());
}
pub fn get_user_items(&self, item: MonoItem<'tcx>) -> &[MonoItem<'tcx>] {
self.user_map.get(&item).map(|items| items.as_slice()).unwrap_or(&[])
}
/// Internally iterate over all inlined items used by `item`.
pub fn for_each_inlined_used_item<F>(&self, tcx: TyCtxt<'tcx>, item: MonoItem<'tcx>, mut f: F)
where
F: FnMut(MonoItem<'tcx>),
{
let used_items = self.used_map.get(&item).unwrap();
for used_item in used_items.iter() {
let is_inlined = used_item.instantiation_mode(tcx) == InstantiationMode::LocalCopy;
if is_inlined {
f(*used_item);
}
}
}
}
#[instrument(skip(tcx, mode), level = "debug")]
pub fn collect_crate_mono_items(
tcx: TyCtxt<'_>,
mode: MonoItemCollectionMode,
) -> (FxHashSet<MonoItem<'_>>, UsageMap<'_>) {
let _prof_timer = tcx.prof.generic_activity("monomorphization_collector");
let roots =
tcx.sess.time("monomorphization_collector_root_collections", || collect_roots(tcx, mode));
debug!("building mono item graph, beginning at roots");
let mut visited = MTLock::new(FxHashSet::default());
let mut usage_map = MTLock::new(UsageMap::new());
let recursion_limit = tcx.recursion_limit();
{
let visited: MTLockRef<'_, _> = &mut visited;
let usage_map: MTLockRef<'_, _> = &mut usage_map;
tcx.sess.time("monomorphization_collector_graph_walk", || {
par_for_each_in(roots, |root| {
let mut recursion_depths = DefIdMap::default();
collect_items_rec(
tcx,
dummy_spanned(root),
visited,
&mut recursion_depths,
recursion_limit,
usage_map,
);
});
});
}
(visited.into_inner(), usage_map.into_inner())
}
// Find all non-generic items by walking the HIR. These items serve as roots to
// start monomorphizing from.
#[instrument(skip(tcx, mode), level = "debug")]
fn collect_roots(tcx: TyCtxt<'_>, mode: MonoItemCollectionMode) -> Vec<MonoItem<'_>> {
debug!("collecting roots");
let mut roots = Vec::new();
{
let entry_fn = tcx.entry_fn(());
debug!("collect_roots: entry_fn = {:?}", entry_fn);
let mut collector = RootCollector { tcx, mode, entry_fn, output: &mut roots };
let crate_items = tcx.hir_crate_items(());
for id in crate_items.items() {
collector.process_item(id);
}
for id in crate_items.impl_items() {
collector.process_impl_item(id);
}
collector.push_extra_entry_roots();
}
// We can only codegen items that are instantiable - items all of
// whose predicates hold. Luckily, items that aren't instantiable
// can't actually be used, so we can just skip codegenning them.
roots
.into_iter()
.filter_map(|Spanned { node: mono_item, .. }| {
mono_item.is_instantiable(tcx).then_some(mono_item)
})
.collect()
}
/// Collect all monomorphized items reachable from `starting_point`, and emit a note diagnostic if a
/// post-monomorphization error is encountered during a collection step.
#[instrument(skip(tcx, visited, recursion_depths, recursion_limit, usage_map), level = "debug")]
fn collect_items_rec<'tcx>(
tcx: TyCtxt<'tcx>,
starting_item: Spanned<MonoItem<'tcx>>,
visited: MTLockRef<'_, FxHashSet<MonoItem<'tcx>>>,
recursion_depths: &mut DefIdMap<usize>,
recursion_limit: Limit,
usage_map: MTLockRef<'_, UsageMap<'tcx>>,
) {
if !visited.lock_mut().insert(starting_item.node) {
// We've been here already, no need to search again.
return;
}
let mut used_items = Vec::new();
let recursion_depth_reset;
// Post-monomorphization errors MVP
//
// We can encounter errors while monomorphizing an item, but we don't have a good way of
// showing a complete stack of spans ultimately leading to collecting the erroneous one yet.
// (It's also currently unclear exactly which diagnostics and information would be interesting
// to report in such cases)
//
// This leads to suboptimal error reporting: a post-monomorphization error (PME) will be
// shown with just a spanned piece of code causing the error, without information on where
// it was called from. This is especially obscure if the erroneous mono item is in a
// dependency. See for example issue #85155, where, before minimization, a PME happened two
// crates downstream from libcore's stdarch, without a way to know which dependency was the
// cause.
//
// If such an error occurs in the current crate, its span will be enough to locate the
// source. If the cause is in another crate, the goal here is to quickly locate which mono
// item in the current crate is ultimately responsible for causing the error.
//
// To give at least _some_ context to the user: while collecting mono items, we check the
// error count. If it has changed, a PME occurred, and we trigger some diagnostics about the
// current step of mono items collection.
//
// FIXME: don't rely on global state, instead bubble up errors. Note: this is very hard to do.
let error_count = tcx.sess.diagnostic().err_count();
match starting_item.node {
MonoItem::Static(def_id) => {
let instance = Instance::mono(tcx, def_id);
// Sanity check whether this ended up being collected accidentally
debug_assert!(should_codegen_locally(tcx, &instance));
let ty = instance.ty(tcx, ty::ParamEnv::reveal_all());
visit_drop_use(tcx, ty, true, starting_item.span, &mut used_items);
recursion_depth_reset = None;
if let Ok(alloc) = tcx.eval_static_initializer(def_id) {
for &id in alloc.inner().provenance().ptrs().values() {
collect_alloc(tcx, id, &mut used_items);
}
}
if tcx.needs_thread_local_shim(def_id) {
used_items.push(respan(
starting_item.span,
MonoItem::Fn(Instance {
def: InstanceDef::ThreadLocalShim(def_id),
args: GenericArgs::empty(),
}),
));
}
}
MonoItem::Fn(instance) => {
// Sanity check whether this ended up being collected accidentally
debug_assert!(should_codegen_locally(tcx, &instance));
// Keep track of the monomorphization recursion depth
recursion_depth_reset = Some(check_recursion_limit(
tcx,
instance,
starting_item.span,
recursion_depths,
recursion_limit,
));
check_type_length_limit(tcx, instance);
rustc_data_structures::stack::ensure_sufficient_stack(|| {
collect_used_items(tcx, instance, &mut used_items);
});
}
MonoItem::GlobalAsm(item_id) => {
recursion_depth_reset = None;
let item = tcx.hir().item(item_id);
if let hir::ItemKind::GlobalAsm(asm) = item.kind {
for (op, op_sp) in asm.operands {
match op {
hir::InlineAsmOperand::Const { .. } => {
// Only constants which resolve to a plain integer
// are supported. Therefore the value should not
// depend on any other items.
}
hir::InlineAsmOperand::SymFn { anon_const } => {
let fn_ty =
tcx.typeck_body(anon_const.body).node_type(anon_const.hir_id);
visit_fn_use(tcx, fn_ty, false, *op_sp, &mut used_items, &[]);
}
hir::InlineAsmOperand::SymStatic { path: _, def_id } => {
let instance = Instance::mono(tcx, *def_id);
if should_codegen_locally(tcx, &instance) {
trace!("collecting static {:?}", def_id);
used_items.push(dummy_spanned(MonoItem::Static(*def_id)));
}
}
hir::InlineAsmOperand::In { .. }
| hir::InlineAsmOperand::Out { .. }
| hir::InlineAsmOperand::InOut { .. }
| hir::InlineAsmOperand::SplitInOut { .. } => {
span_bug!(*op_sp, "invalid operand type for global_asm!")
}
}
}
} else {
span_bug!(item.span, "Mismatch between hir::Item type and MonoItem type")
}
}
}
// Check for PMEs and emit a diagnostic if one happened. To try to show relevant edges of the
// mono item graph.
if tcx.sess.diagnostic().err_count() > error_count
&& starting_item.node.is_generic_fn(tcx)
&& starting_item.node.is_user_defined()
{
let formatted_item = with_no_trimmed_paths!(starting_item.node.to_string());
tcx.sess.emit_note(EncounteredErrorWhileInstantiating {
span: starting_item.span,
formatted_item,
});
}
usage_map.lock_mut().record_used(starting_item.node, &used_items);
for used_item in used_items {
collect_items_rec(tcx, used_item, visited, recursion_depths, recursion_limit, usage_map);
}
if let Some((def_id, depth)) = recursion_depth_reset {
recursion_depths.insert(def_id, depth);
}
}
/// Format instance name that is already known to be too long for rustc.
/// Show only the first 2 types if it is longer than 32 characters to avoid blasting
/// the user's terminal with thousands of lines of type-name.
///
/// If the type name is longer than before+after, it will be written to a file.
fn shrunk_instance_name<'tcx>(
tcx: TyCtxt<'tcx>,
instance: &Instance<'tcx>,
) -> (String, Option<PathBuf>) {
let s = instance.to_string();
// Only use the shrunk version if it's really shorter.
// This also avoids the case where before and after slices overlap.
if s.chars().nth(33).is_some() {
let shrunk = format!("{}", ty::ShortInstance(instance, 4));
if shrunk == s {
return (s, None);
}
let path = tcx.output_filenames(()).temp_path_ext("long-type.txt", None);
let written_to_path = std::fs::write(&path, s).ok().map(|_| path);
(shrunk, written_to_path)
} else {
(s, None)
}
}
fn check_recursion_limit<'tcx>(
tcx: TyCtxt<'tcx>,
instance: Instance<'tcx>,
span: Span,
recursion_depths: &mut DefIdMap<usize>,
recursion_limit: Limit,
) -> (DefId, usize) {
let def_id = instance.def_id();
let recursion_depth = recursion_depths.get(&def_id).cloned().unwrap_or(0);
debug!(" => recursion depth={}", recursion_depth);
let adjusted_recursion_depth = if Some(def_id) == tcx.lang_items().drop_in_place_fn() {
// HACK: drop_in_place creates tight monomorphization loops. Give
// it more margin.
recursion_depth / 4
} else {
recursion_depth
};
// Code that needs to instantiate the same function recursively
// more than the recursion limit is assumed to be causing an
// infinite expansion.
if !recursion_limit.value_within_limit(adjusted_recursion_depth) {
let def_span = tcx.def_span(def_id);
let def_path_str = tcx.def_path_str(def_id);
let (shrunk, written_to_path) = shrunk_instance_name(tcx, &instance);
let mut path = PathBuf::new();
let was_written = if let Some(written_to_path) = written_to_path {
path = written_to_path;
Some(())
} else {
None
};
tcx.sess.emit_fatal(RecursionLimit {
span,
shrunk,
def_span,
def_path_str,
was_written,
path,
});
}
recursion_depths.insert(def_id, recursion_depth + 1);
(def_id, recursion_depth)
}
fn check_type_length_limit<'tcx>(tcx: TyCtxt<'tcx>, instance: Instance<'tcx>) {
let type_length = instance
.args
.iter()
.flat_map(|arg| arg.walk())
.filter(|arg| match arg.unpack() {
GenericArgKind::Type(_) | GenericArgKind::Const(_) => true,
GenericArgKind::Lifetime(_) => false,
})
.count();
debug!(" => type length={}", type_length);
// Rust code can easily create exponentially-long types using only a
// polynomial recursion depth. Even with the default recursion
// depth, you can easily get cases that take >2^60 steps to run,
// which means that rustc basically hangs.
//
// Bail out in these cases to avoid that bad user experience.
if !tcx.type_length_limit().value_within_limit(type_length) {
let (shrunk, written_to_path) = shrunk_instance_name(tcx, &instance);
let span = tcx.def_span(instance.def_id());
let mut path = PathBuf::new();
let was_written = if let Some(path2) = written_to_path {
path = path2;
Some(())
} else {
None
};
tcx.sess.emit_fatal(TypeLengthLimit { span, shrunk, was_written, path, type_length });
}
}
struct MirUsedCollector<'a, 'tcx> {
tcx: TyCtxt<'tcx>,
body: &'a mir::Body<'tcx>,
output: &'a mut MonoItems<'tcx>,
instance: Instance<'tcx>,
/// Spans for move size lints already emitted. Helps avoid duplicate lints.
move_size_spans: Vec<Span>,
/// If true, we should temporarily skip move size checks, because we are
/// processing an operand to a `skip_move_check_fns` function call.
skip_move_size_check: bool,
/// Set of functions for which it is OK to move large data into.
skip_move_check_fns: Vec<DefId>,
}
impl<'a, 'tcx> MirUsedCollector<'a, 'tcx> {
pub fn monomorphize<T>(&self, value: T) -> T
where
T: TypeFoldable<TyCtxt<'tcx>>,
{
debug!("monomorphize: self.instance={:?}", self.instance);
self.instance.instantiate_mir_and_normalize_erasing_regions(
self.tcx,
ty::ParamEnv::reveal_all(),
ty::EarlyBinder::bind(value),
)
}
fn check_move_size(&mut self, limit: usize, operand: &mir::Operand<'tcx>, location: Location) {
let limit = Size::from_bytes(limit);
let ty = operand.ty(self.body, self.tcx);
let ty = self.monomorphize(ty);
let Ok(layout) = self.tcx.layout_of(ty::ParamEnv::reveal_all().and(ty)) else { return };
if layout.size <= limit {
return;
}
debug!(?layout);
let source_info = self.body.source_info(location);
debug!(?source_info);
for span in &self.move_size_spans {
if span.overlaps(source_info.span) {
return;
}
}
let lint_root = source_info.scope.lint_root(&self.body.source_scopes);
debug!(?lint_root);
let Some(lint_root) = lint_root else {
// This happens when the issue is in a function from a foreign crate that
// we monomorphized in the current crate. We can't get a `HirId` for things
// in other crates.
// FIXME: Find out where to report the lint on. Maybe simply crate-level lint root
// but correct span? This would make the lint at least accept crate-level lint attributes.
return;
};
self.tcx.emit_spanned_lint(
LARGE_ASSIGNMENTS,
lint_root,
source_info.span,
LargeAssignmentsLint {
span: source_info.span,
size: layout.size.bytes(),
limit: limit.bytes(),
},
);
self.move_size_spans.push(source_info.span);
}
}
impl<'a, 'tcx> MirVisitor<'tcx> for MirUsedCollector<'a, 'tcx> {
fn visit_rvalue(&mut self, rvalue: &mir::Rvalue<'tcx>, location: Location) {
debug!("visiting rvalue {:?}", *rvalue);
let span = self.body.source_info(location).span;
match *rvalue {
// When doing an cast from a regular pointer to a fat pointer, we
// have to instantiate all methods of the trait being cast to, so we
// can build the appropriate vtable.
mir::Rvalue::Cast(
mir::CastKind::PointerCoercion(PointerCoercion::Unsize),
ref operand,
target_ty,
)
| mir::Rvalue::Cast(mir::CastKind::DynStar, ref operand, target_ty) => {
let target_ty = self.monomorphize(target_ty);
let source_ty = operand.ty(self.body, self.tcx);
let source_ty = self.monomorphize(source_ty);
let (source_ty, target_ty) =
find_vtable_types_for_unsizing(self.tcx.at(span), source_ty, target_ty);
// This could also be a different Unsize instruction, like
// from a fixed sized array to a slice. But we are only
// interested in things that produce a vtable.
if (target_ty.is_trait() && !source_ty.is_trait())
|| (target_ty.is_dyn_star() && !source_ty.is_dyn_star())
{
create_mono_items_for_vtable_methods(
self.tcx,
target_ty,
source_ty,
span,
self.output,
);
}
}
mir::Rvalue::Cast(
mir::CastKind::PointerCoercion(PointerCoercion::ReifyFnPointer),
ref operand,
_,
) => {
let fn_ty = operand.ty(self.body, self.tcx);
let fn_ty = self.monomorphize(fn_ty);
visit_fn_use(
self.tcx,
fn_ty,
false,
span,
&mut self.output,
&self.skip_move_check_fns,
);
}
mir::Rvalue::Cast(
mir::CastKind::PointerCoercion(PointerCoercion::ClosureFnPointer(_)),
ref operand,
_,
) => {
let source_ty = operand.ty(self.body, self.tcx);
let source_ty = self.monomorphize(source_ty);
match *source_ty.kind() {
ty::Closure(def_id, args) => {
let instance = Instance::resolve_closure(
self.tcx,
def_id,
args,
ty::ClosureKind::FnOnce,
)
.expect("failed to normalize and resolve closure during codegen");
if should_codegen_locally(self.tcx, &instance) {
self.output.push(create_fn_mono_item(self.tcx, instance, span));
}
}
_ => bug!(),
}
}
mir::Rvalue::ThreadLocalRef(def_id) => {
assert!(self.tcx.is_thread_local_static(def_id));
let instance = Instance::mono(self.tcx, def_id);
if should_codegen_locally(self.tcx, &instance) {
trace!("collecting thread-local static {:?}", def_id);
self.output.push(respan(span, MonoItem::Static(def_id)));
}
}
_ => { /* not interesting */ }
}
self.super_rvalue(rvalue, location);
}
/// This does not walk the constant, as it has been handled entirely here and trying
/// to walk it would attempt to evaluate the `ty::Const` inside, which doesn't necessarily
/// work, as some constants cannot be represented in the type system.
#[instrument(skip(self), level = "debug")]
fn visit_constant(&mut self, constant: &mir::ConstOperand<'tcx>, location: Location) {
let const_ = self.monomorphize(constant.const_);
let param_env = ty::ParamEnv::reveal_all();
let val = match const_.eval(self.tcx, param_env, None) {
Ok(v) => v,
Err(ErrorHandled::Reported(..)) => return,
Err(ErrorHandled::TooGeneric(..)) => span_bug!(
self.body.source_info(location).span,
"collection encountered polymorphic constant: {:?}",
const_
),
};
collect_const_value(self.tcx, val, self.output);
MirVisitor::visit_ty(self, const_.ty(), TyContext::Location(location));
}
fn visit_terminator(&mut self, terminator: &mir::Terminator<'tcx>, location: Location) {
debug!("visiting terminator {:?} @ {:?}", terminator, location);
let source = self.body.source_info(location).span;
let tcx = self.tcx;
let push_mono_lang_item = |this: &mut Self, lang_item: LangItem| {
let instance = Instance::mono(tcx, tcx.require_lang_item(lang_item, Some(source)));
if should_codegen_locally(tcx, &instance) {
this.output.push(create_fn_mono_item(tcx, instance, source));
}
};
match terminator.kind {
mir::TerminatorKind::Call { ref func, .. } => {
let callee_ty = func.ty(self.body, tcx);
let callee_ty = self.monomorphize(callee_ty);
self.skip_move_size_check = visit_fn_use(
self.tcx,
callee_ty,
true,
source,
&mut self.output,
&self.skip_move_check_fns,
)
}
mir::TerminatorKind::Drop { ref place, .. } => {
let ty = place.ty(self.body, self.tcx).ty;
let ty = self.monomorphize(ty);
visit_drop_use(self.tcx, ty, true, source, self.output);
}
mir::TerminatorKind::InlineAsm { ref operands, .. } => {
for op in operands {
match *op {
mir::InlineAsmOperand::SymFn { ref value } => {
let fn_ty = self.monomorphize(value.const_.ty());
visit_fn_use(self.tcx, fn_ty, false, source, &mut self.output, &[]);
}
mir::InlineAsmOperand::SymStatic { def_id } => {
let instance = Instance::mono(self.tcx, def_id);
if should_codegen_locally(self.tcx, &instance) {
trace!("collecting asm sym static {:?}", def_id);
self.output.push(respan(source, MonoItem::Static(def_id)));
}
}
_ => {}
}
}
}
mir::TerminatorKind::Assert { ref msg, .. } => {
let lang_item = match &**msg {
mir::AssertKind::BoundsCheck { .. } => LangItem::PanicBoundsCheck,
_ => LangItem::Panic,
};
push_mono_lang_item(self, lang_item);
}
mir::TerminatorKind::UnwindTerminate(reason) => {
push_mono_lang_item(self, reason.lang_item());
}
mir::TerminatorKind::Goto { .. }
| mir::TerminatorKind::SwitchInt { .. }
| mir::TerminatorKind::UnwindResume
| mir::TerminatorKind::Return
| mir::TerminatorKind::Unreachable => {}
mir::TerminatorKind::GeneratorDrop
| mir::TerminatorKind::Yield { .. }
| mir::TerminatorKind::FalseEdge { .. }
| mir::TerminatorKind::FalseUnwind { .. } => bug!(),
}
if let Some(mir::UnwindAction::Terminate(reason)) = terminator.unwind() {
push_mono_lang_item(self, reason.lang_item());
}
self.super_terminator(terminator, location);
self.skip_move_size_check = false;
}
fn visit_operand(&mut self, operand: &mir::Operand<'tcx>, location: Location) {
self.super_operand(operand, location);
let move_size_limit = self.tcx.move_size_limit().0;
if move_size_limit > 0 && !self.skip_move_size_check {
self.check_move_size(move_size_limit, operand, location);
}
}
fn visit_local(
&mut self,
_place_local: Local,
_context: mir::visit::PlaceContext,
_location: Location,
) {
}
}
fn visit_drop_use<'tcx>(
tcx: TyCtxt<'tcx>,
ty: Ty<'tcx>,
is_direct_call: bool,
source: Span,
output: &mut MonoItems<'tcx>,
) {
let instance = Instance::resolve_drop_in_place(tcx, ty);
visit_instance_use(tcx, instance, is_direct_call, source, output);
}
fn visit_fn_use<'tcx>(
tcx: TyCtxt<'tcx>,
ty: Ty<'tcx>,
is_direct_call: bool,
source: Span,
output: &mut MonoItems<'tcx>,
skip_move_check_fns: &[DefId],
) -> bool {
let mut skip_move_size_check = false;
if let ty::FnDef(def_id, args) = *ty.kind() {
skip_move_size_check = skip_move_check_fns.contains(&def_id);
let instance = if is_direct_call {
ty::Instance::expect_resolve(tcx, ty::ParamEnv::reveal_all(), def_id, args)
} else {
match ty::Instance::resolve_for_fn_ptr(tcx, ty::ParamEnv::reveal_all(), def_id, args) {
Some(instance) => instance,
_ => bug!("failed to resolve instance for {ty}"),
}
};
visit_instance_use(tcx, instance, is_direct_call, source, output);
}
skip_move_size_check
}
fn visit_instance_use<'tcx>(
tcx: TyCtxt<'tcx>,
instance: ty::Instance<'tcx>,
is_direct_call: bool,
source: Span,
output: &mut MonoItems<'tcx>,
) {
debug!("visit_item_use({:?}, is_direct_call={:?})", instance, is_direct_call);
if !should_codegen_locally(tcx, &instance) {
return;
}
match instance.def {
ty::InstanceDef::Virtual(..) | ty::InstanceDef::Intrinsic(_) => {
if !is_direct_call {
bug!("{:?} being reified", instance);
}
}
ty::InstanceDef::ThreadLocalShim(..) => {
bug!("{:?} being reified", instance);
}
ty::InstanceDef::DropGlue(_, None) => {
// Don't need to emit noop drop glue if we are calling directly.
if !is_direct_call {
output.push(create_fn_mono_item(tcx, instance, source));
}
}
ty::InstanceDef::DropGlue(_, Some(_))
| ty::InstanceDef::VTableShim(..)
| ty::InstanceDef::ReifyShim(..)
| ty::InstanceDef::ClosureOnceShim { .. }
| ty::InstanceDef::Item(..)
| ty::InstanceDef::FnPtrShim(..)
| ty::InstanceDef::CloneShim(..)
| ty::InstanceDef::FnPtrAddrShim(..) => {
output.push(create_fn_mono_item(tcx, instance, source));
}
}
}
/// Returns `true` if we should codegen an instance in the local crate, or returns `false` if we
/// can just link to the upstream crate and therefore don't need a mono item.
fn should_codegen_locally<'tcx>(tcx: TyCtxt<'tcx>, instance: &Instance<'tcx>) -> bool {
let Some(def_id) = instance.def.def_id_if_not_guaranteed_local_codegen() else {
return true;
};
if tcx.is_foreign_item(def_id) {
// Foreign items are always linked against, there's no way of instantiating them.
return false;
}
if def_id.is_local() {
// Local items cannot be referred to locally without monomorphizing them locally.
return true;
}
if tcx.is_reachable_non_generic(def_id)
|| instance.polymorphize(tcx).upstream_monomorphization(tcx).is_some()
{
// We can link to the item in question, no instance needed in this crate.
return false;
}
if let DefKind::Static(_) = tcx.def_kind(def_id) {
// We cannot monomorphize statics from upstream crates.
return false;
}
if !tcx.is_mir_available(def_id) {
tcx.sess.emit_fatal(NoOptimizedMir {
span: tcx.def_span(def_id),
crate_name: tcx.crate_name(def_id.krate),
});
}
true
}
/// For a given pair of source and target type that occur in an unsizing coercion,
/// this function finds the pair of types that determines the vtable linking
/// them.
///
/// For example, the source type might be `&SomeStruct` and the target type
/// might be `&dyn SomeTrait` in a cast like:
///
/// ```rust,ignore (not real code)
/// let src: &SomeStruct = ...;
/// let target = src as &dyn SomeTrait;
/// ```
///
/// Then the output of this function would be (SomeStruct, SomeTrait) since for
/// constructing the `target` fat-pointer we need the vtable for that pair.
///
/// Things can get more complicated though because there's also the case where
/// the unsized type occurs as a field:
///
/// ```rust
/// struct ComplexStruct<T: ?Sized> {
/// a: u32,
/// b: f64,
/// c: T
/// }
/// ```
///
/// In this case, if `T` is sized, `&ComplexStruct<T>` is a thin pointer. If `T`
/// is unsized, `&SomeStruct` is a fat pointer, and the vtable it points to is
/// for the pair of `T` (which is a trait) and the concrete type that `T` was
/// originally coerced from:
///
/// ```rust,ignore (not real code)
/// let src: &ComplexStruct<SomeStruct> = ...;
/// let target = src as &ComplexStruct<dyn SomeTrait>;
/// ```
///
/// Again, we want this `find_vtable_types_for_unsizing()` to provide the pair
/// `(SomeStruct, SomeTrait)`.
///
/// Finally, there is also the case of custom unsizing coercions, e.g., for
/// smart pointers such as `Rc` and `Arc`.
fn find_vtable_types_for_unsizing<'tcx>(
tcx: TyCtxtAt<'tcx>,
source_ty: Ty<'tcx>,
target_ty: Ty<'tcx>,
) -> (Ty<'tcx>, Ty<'tcx>) {
let ptr_vtable = |inner_source: Ty<'tcx>, inner_target: Ty<'tcx>| {
let param_env = ty::ParamEnv::reveal_all();
let type_has_metadata = |ty: Ty<'tcx>| -> bool {
if ty.is_sized(tcx.tcx, param_env) {
return false;
}
let tail = tcx.struct_tail_erasing_lifetimes(ty, param_env);
match tail.kind() {
ty::Foreign(..) => false,
ty::Str | ty::Slice(..) | ty::Dynamic(..) => true,
_ => bug!("unexpected unsized tail: {:?}", tail),
}
};
if type_has_metadata(inner_source) {
(inner_source, inner_target)
} else {
tcx.struct_lockstep_tails_erasing_lifetimes(inner_source, inner_target, param_env)
}
};
match (&source_ty.kind(), &target_ty.kind()) {
(&ty::Ref(_, a, _), &ty::Ref(_, b, _) | &ty::RawPtr(ty::TypeAndMut { ty: b, .. }))
| (&ty::RawPtr(ty::TypeAndMut { ty: a, .. }), &ty::RawPtr(ty::TypeAndMut { ty: b, .. })) => {
ptr_vtable(*a, *b)
}
(&ty::Adt(def_a, _), &ty::Adt(def_b, _)) if def_a.is_box() && def_b.is_box() => {
ptr_vtable(source_ty.boxed_ty(), target_ty.boxed_ty())
}
// T as dyn* Trait
(_, &ty::Dynamic(_, _, ty::DynStar)) => ptr_vtable(source_ty, target_ty),
(&ty::Adt(source_adt_def, source_args), &ty::Adt(target_adt_def, target_args)) => {
assert_eq!(source_adt_def, target_adt_def);
let CustomCoerceUnsized::Struct(coerce_index) =
crate::custom_coerce_unsize_info(tcx, source_ty, target_ty);
let source_fields = &source_adt_def.non_enum_variant().fields;
let target_fields = &target_adt_def.non_enum_variant().fields;
assert!(
coerce_index.index() < source_fields.len()
&& source_fields.len() == target_fields.len()
);
find_vtable_types_for_unsizing(
tcx,
source_fields[coerce_index].ty(*tcx, source_args),
target_fields[coerce_index].ty(*tcx, target_args),
)
}
_ => bug!(
"find_vtable_types_for_unsizing: invalid coercion {:?} -> {:?}",
source_ty,
target_ty
),
}
}
#[instrument(skip(tcx), level = "debug", ret)]
fn create_fn_mono_item<'tcx>(
tcx: TyCtxt<'tcx>,
instance: Instance<'tcx>,
source: Span,
) -> Spanned<MonoItem<'tcx>> {
let def_id = instance.def_id();
if tcx.sess.opts.unstable_opts.profile_closures && def_id.is_local() && tcx.is_closure(def_id) {
crate::util::dump_closure_profile(tcx, instance);
}
respan(source, MonoItem::Fn(instance.polymorphize(tcx)))
}
/// Creates a `MonoItem` for each method that is referenced by the vtable for
/// the given trait/impl pair.
fn create_mono_items_for_vtable_methods<'tcx>(
tcx: TyCtxt<'tcx>,
trait_ty: Ty<'tcx>,
impl_ty: Ty<'tcx>,
source: Span,
output: &mut MonoItems<'tcx>,
) {
assert!(!trait_ty.has_escaping_bound_vars() && !impl_ty.has_escaping_bound_vars());
if let ty::Dynamic(ref trait_ty, ..) = trait_ty.kind() {
if let Some(principal) = trait_ty.principal() {
let poly_trait_ref = principal.with_self_ty(tcx, impl_ty);
assert!(!poly_trait_ref.has_escaping_bound_vars());
// Walk all methods of the trait, including those of its supertraits
let entries = tcx.vtable_entries(poly_trait_ref);
let methods = entries
.iter()
.filter_map(|entry| match entry {
VtblEntry::MetadataDropInPlace
| VtblEntry::MetadataSize
| VtblEntry::MetadataAlign
| VtblEntry::Vacant => None,
VtblEntry::TraitVPtr(_) => {
// all super trait items already covered, so skip them.
None
}
VtblEntry::Method(instance) => {
Some(*instance).filter(|instance| should_codegen_locally(tcx, instance))
}
})
.map(|item| create_fn_mono_item(tcx, item, source));
output.extend(methods);
}
// Also add the destructor.
visit_drop_use(tcx, impl_ty, false, source, output);
}
}
//=-----------------------------------------------------------------------------
// Root Collection
//=-----------------------------------------------------------------------------
struct RootCollector<'a, 'tcx> {
tcx: TyCtxt<'tcx>,
mode: MonoItemCollectionMode,
output: &'a mut MonoItems<'tcx>,
entry_fn: Option<(DefId, EntryFnType)>,
}
impl<'v> RootCollector<'_, 'v> {
fn process_item(&mut self, id: hir::ItemId) {
match self.tcx.def_kind(id.owner_id) {
DefKind::Enum | DefKind::Struct | DefKind::Union => {
if self.mode == MonoItemCollectionMode::Eager
&& self.tcx.generics_of(id.owner_id).count() == 0
{
debug!("RootCollector: ADT drop-glue for `{id:?}`",);
let ty = self.tcx.type_of(id.owner_id.to_def_id()).no_bound_vars().unwrap();
visit_drop_use(self.tcx, ty, true, DUMMY_SP, self.output);
}
}
DefKind::GlobalAsm => {
debug!(
"RootCollector: ItemKind::GlobalAsm({})",
self.tcx.def_path_str(id.owner_id)
);
self.output.push(dummy_spanned(MonoItem::GlobalAsm(id)));
}
DefKind::Static(..) => {
let def_id = id.owner_id.to_def_id();
debug!("RootCollector: ItemKind::Static({})", self.tcx.def_path_str(def_id));
self.output.push(dummy_spanned(MonoItem::Static(def_id)));
}
DefKind::Const => {
// const items only generate mono items if they are
// actually used somewhere. Just declaring them is insufficient.
// but even just declaring them must collect the items they refer to
if let Ok(val) = self.tcx.const_eval_poly(id.owner_id.to_def_id()) {
collect_const_value(self.tcx, val, &mut self.output);
}
}
DefKind::Impl { .. } => {
if self.mode == MonoItemCollectionMode::Eager {
create_mono_items_for_default_impls(self.tcx, id, self.output);
}
}
DefKind::Fn => {
self.push_if_root(id.owner_id.def_id);
}
_ => {}
}
}
fn process_impl_item(&mut self, id: hir::ImplItemId) {
if matches!(self.tcx.def_kind(id.owner_id), DefKind::AssocFn) {
self.push_if_root(id.owner_id.def_id);
}
}
fn is_root(&self, def_id: LocalDefId) -> bool {
!item_requires_monomorphization(self.tcx, def_id)
&& match self.mode {
MonoItemCollectionMode::Eager => true,
MonoItemCollectionMode::Lazy => {
self.entry_fn.and_then(|(id, _)| id.as_local()) == Some(def_id)
|| self.tcx.is_reachable_non_generic(def_id)
|| self
.tcx
.codegen_fn_attrs(def_id)
.flags
.contains(CodegenFnAttrFlags::RUSTC_STD_INTERNAL_SYMBOL)
}
}
}
/// If `def_id` represents a root, pushes it onto the list of
/// outputs. (Note that all roots must be monomorphic.)
#[instrument(skip(self), level = "debug")]
fn push_if_root(&mut self, def_id: LocalDefId) {
if self.is_root(def_id) {
debug!("found root");
let instance = Instance::mono(self.tcx, def_id.to_def_id());
self.output.push(create_fn_mono_item(self.tcx, instance, DUMMY_SP));
}
}
/// As a special case, when/if we encounter the
/// `main()` function, we also have to generate a
/// monomorphized copy of the start lang item based on
/// the return type of `main`. This is not needed when
/// the user writes their own `start` manually.
fn push_extra_entry_roots(&mut self) {
let Some((main_def_id, EntryFnType::Main { .. })) = self.entry_fn else {
return;
};
let start_def_id = self.tcx.require_lang_item(LangItem::Start, None);
let main_ret_ty = self.tcx.fn_sig(main_def_id).no_bound_vars().unwrap().output();
// Given that `main()` has no arguments,
// then its return type cannot have
// late-bound regions, since late-bound
// regions must appear in the argument
// listing.
let main_ret_ty = self.tcx.normalize_erasing_regions(
ty::ParamEnv::reveal_all(),
main_ret_ty.no_bound_vars().unwrap(),
);
let start_instance = Instance::resolve(
self.tcx,
ty::ParamEnv::reveal_all(),
start_def_id,
self.tcx.mk_args(&[main_ret_ty.into()]),
)
.unwrap()
.unwrap();
self.output.push(create_fn_mono_item(self.tcx, start_instance, DUMMY_SP));
}
}
fn item_requires_monomorphization(tcx: TyCtxt<'_>, def_id: LocalDefId) -> bool {
let generics = tcx.generics_of(def_id);
generics.requires_monomorphization(tcx)
}
#[instrument(level = "debug", skip(tcx, output))]
fn create_mono_items_for_default_impls<'tcx>(
tcx: TyCtxt<'tcx>,
item: hir::ItemId,
output: &mut MonoItems<'tcx>,
) {
let polarity = tcx.impl_polarity(item.owner_id);
if matches!(polarity, ty::ImplPolarity::Negative) {
return;
}
if tcx.generics_of(item.owner_id).own_requires_monomorphization() {
return;
}
let Some(trait_ref) = tcx.impl_trait_ref(item.owner_id) else {
return;
};
// Lifetimes never affect trait selection, so we are allowed to eagerly
// instantiate an instance of an impl method if the impl (and method,
// which we check below) is only parameterized over lifetime. In that case,
// we use the ReErased, which has no lifetime information associated with
// it, to validate whether or not the impl is legal to instantiate at all.
let only_region_params = |param: &ty::GenericParamDef, _: &_| match param.kind {
GenericParamDefKind::Lifetime => tcx.lifetimes.re_erased.into(),
GenericParamDefKind::Const { is_host_effect: true, .. } => tcx.consts.true_.into(),
GenericParamDefKind::Type { .. } | GenericParamDefKind::Const { .. } => {
unreachable!(
"`own_requires_monomorphization` check means that \
we should have no type/const params"
)
}
};
let impl_args = GenericArgs::for_item(tcx, item.owner_id.to_def_id(), only_region_params);
let trait_ref = trait_ref.instantiate(tcx, impl_args);
// Unlike 'lazy' monomorphization that begins by collecting items transitively
// called by `main` or other global items, when eagerly monomorphizing impl
// items, we never actually check that the predicates of this impl are satisfied
// in a empty reveal-all param env (i.e. with no assumptions).
//
// Even though this impl has no type or const substitutions, because we don't
// consider higher-ranked predicates such as `for<'a> &'a mut [u8]: Copy` to
// be trivially false. We must now check that the impl has no impossible-to-satisfy
// predicates.
if tcx.subst_and_check_impossible_predicates((item.owner_id.to_def_id(), impl_args)) {
return;
}
let param_env = ty::ParamEnv::reveal_all();
let trait_ref = tcx.normalize_erasing_regions(param_env, trait_ref);
let overridden_methods = tcx.impl_item_implementor_ids(item.owner_id);
for method in tcx.provided_trait_methods(trait_ref.def_id) {
if overridden_methods.contains_key(&method.def_id) {
continue;
}
if tcx.generics_of(method.def_id).own_requires_monomorphization() {
continue;
}
// As mentioned above, the method is legal to eagerly instantiate if it
// only has lifetime substitutions. This is validated by
let args = trait_ref.args.extend_to(tcx, method.def_id, only_region_params);
let instance = ty::Instance::expect_resolve(tcx, param_env, method.def_id, args);
let mono_item = create_fn_mono_item(tcx, instance, DUMMY_SP);
if mono_item.node.is_instantiable(tcx) && should_codegen_locally(tcx, &instance) {
output.push(mono_item);
}
}
}
/// Scans the CTFE alloc in order to find function calls, closures, and drop-glue.
fn collect_alloc<'tcx>(tcx: TyCtxt<'tcx>, alloc_id: AllocId, output: &mut MonoItems<'tcx>) {
match tcx.global_alloc(alloc_id) {
GlobalAlloc::Static(def_id) => {
assert!(!tcx.is_thread_local_static(def_id));
let instance = Instance::mono(tcx, def_id);
if should_codegen_locally(tcx, &instance) {
trace!("collecting static {:?}", def_id);
output.push(dummy_spanned(MonoItem::Static(def_id)));
}
}
GlobalAlloc::Memory(alloc) => {
trace!("collecting {:?} with {:#?}", alloc_id, alloc);
for &inner in alloc.inner().provenance().ptrs().values() {
rustc_data_structures::stack::ensure_sufficient_stack(|| {
collect_alloc(tcx, inner, output);
});
}
}
GlobalAlloc::Function(fn_instance) => {
if should_codegen_locally(tcx, &fn_instance) {
trace!("collecting {:?} with {:#?}", alloc_id, fn_instance);
output.push(create_fn_mono_item(tcx, fn_instance, DUMMY_SP));
}
}
GlobalAlloc::VTable(ty, trait_ref) => {
let alloc_id = tcx.vtable_allocation((ty, trait_ref));
collect_alloc(tcx, alloc_id, output)
}
}
}
fn add_assoc_fn<'tcx>(
tcx: TyCtxt<'tcx>,
def_id: Option<DefId>,
fn_ident: Ident,
skip_move_check_fns: &mut Vec<DefId>,
) {
if let Some(def_id) = def_id.and_then(|def_id| assoc_fn_of_type(tcx, def_id, fn_ident)) {
skip_move_check_fns.push(def_id);
}
}
fn assoc_fn_of_type<'tcx>(tcx: TyCtxt<'tcx>, def_id: DefId, fn_ident: Ident) -> Option<DefId> {
for impl_def_id in tcx.inherent_impls(def_id) {
if let Some(new) = tcx.associated_items(impl_def_id).find_by_name_and_kind(
tcx,
fn_ident,
AssocKind::Fn,
def_id,
) {
return Some(new.def_id);
}
}
return None;
}
/// Scans the MIR in order to find function calls, closures, and drop-glue.
#[instrument(skip(tcx, output), level = "debug")]
fn collect_used_items<'tcx>(
tcx: TyCtxt<'tcx>,
instance: Instance<'tcx>,
output: &mut MonoItems<'tcx>,
) {
let body = tcx.instance_mir(instance.def);
let mut skip_move_check_fns = vec![];
if tcx.move_size_limit().0 > 0 {
add_assoc_fn(
tcx,
tcx.lang_items().owned_box(),
Ident::from_str("new"),
&mut skip_move_check_fns,
);
add_assoc_fn(
tcx,
tcx.get_diagnostic_item(sym::Arc),
Ident::from_str("new"),
&mut skip_move_check_fns,
);
add_assoc_fn(
tcx,
tcx.get_diagnostic_item(sym::Rc),
Ident::from_str("new"),
&mut skip_move_check_fns,
);
}
// Here we rely on the visitor also visiting `required_consts`, so that we evaluate them
// and abort compilation if any of them errors.
MirUsedCollector {
tcx,
body: &body,
output,
instance,
move_size_spans: vec![],
skip_move_size_check: false,
skip_move_check_fns,
}
.visit_body(&body);
}
#[instrument(skip(tcx, output), level = "debug")]
fn collect_const_value<'tcx>(
tcx: TyCtxt<'tcx>,
value: mir::ConstValue<'tcx>,
output: &mut MonoItems<'tcx>,
) {
match value {
mir::ConstValue::Scalar(Scalar::Ptr(ptr, _size)) => {
collect_alloc(tcx, ptr.provenance, output)
}
mir::ConstValue::Indirect { alloc_id, .. } => collect_alloc(tcx, alloc_id, output),
mir::ConstValue::Slice { data, meta: _ } => {
for &id in data.inner().provenance().ptrs().values() {
collect_alloc(tcx, id, output);
}
}
_ => {}
}
}