2989fea88a
This commit implements the `unused_generic_params` query, an initial version of polymorphization which detects when an item does not use generic parameters and is being needlessly monomorphized as a result. Signed-off-by: David Wood <david@davidtw.co>
436 lines
15 KiB
Rust
436 lines
15 KiB
Rust
use rustc_data_structures::stable_hasher::{HashStable, StableHasher};
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use rustc_hir::def_id::CrateNum;
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use rustc_hir::definitions::{DefPathData, DisambiguatedDefPathData};
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use rustc_middle::ich::NodeIdHashingMode;
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use rustc_middle::mir::interpret::{ConstValue, Scalar};
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use rustc_middle::ty::print::{PrettyPrinter, Print, Printer};
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use rustc_middle::ty::subst::{GenericArg, GenericArgKind};
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use rustc_middle::ty::{self, Instance, Ty, TyCtxt, TypeFoldable};
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use rustc_middle::util::common::record_time;
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use log::debug;
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use std::fmt::{self, Write};
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use std::mem::{self, discriminant};
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pub(super) fn mangle(
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tcx: TyCtxt<'tcx>,
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instance: Instance<'tcx>,
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instantiating_crate: Option<CrateNum>,
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) -> String {
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let def_id = instance.def_id();
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// We want to compute the "type" of this item. Unfortunately, some
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// kinds of items (e.g., closures) don't have an entry in the
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// item-type array. So walk back up the find the closest parent
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// that DOES have an entry.
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let mut ty_def_id = def_id;
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let instance_ty;
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loop {
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let key = tcx.def_key(ty_def_id);
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match key.disambiguated_data.data {
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DefPathData::TypeNs(_) | DefPathData::ValueNs(_) => {
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instance_ty = tcx.type_of(ty_def_id);
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break;
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}
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_ => {
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// if we're making a symbol for something, there ought
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// to be a value or type-def or something in there
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// *somewhere*
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ty_def_id.index = key.parent.unwrap_or_else(|| {
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bug!(
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"finding type for {:?}, encountered def-id {:?} with no \
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parent",
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def_id,
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ty_def_id
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);
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});
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}
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}
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}
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// Erase regions because they may not be deterministic when hashed
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// and should not matter anyhow.
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let instance_ty = tcx.erase_regions(&instance_ty);
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let hash = get_symbol_hash(tcx, instance, instance_ty, instantiating_crate);
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let mut printer = SymbolPrinter { tcx, path: SymbolPath::new(), keep_within_component: false }
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.print_def_path(def_id, &[])
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.unwrap();
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if let ty::InstanceDef::VtableShim(..) = instance.def {
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let _ = printer.write_str("{{vtable-shim}}");
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}
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if let ty::InstanceDef::ReifyShim(..) = instance.def {
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let _ = printer.write_str("{{reify-shim}}");
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}
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printer.path.finish(hash)
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}
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fn get_symbol_hash<'tcx>(
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tcx: TyCtxt<'tcx>,
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// instance this name will be for
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instance: Instance<'tcx>,
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// type of the item, without any generic
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// parameters substituted; this is
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// included in the hash as a kind of
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// safeguard.
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item_type: Ty<'tcx>,
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instantiating_crate: Option<CrateNum>,
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) -> u64 {
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let def_id = instance.def_id();
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let substs = instance.substs;
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debug!("get_symbol_hash(def_id={:?}, parameters={:?})", def_id, substs);
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let mut hasher = StableHasher::new();
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let mut hcx = tcx.create_stable_hashing_context();
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record_time(&tcx.sess.perf_stats.symbol_hash_time, || {
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// the main symbol name is not necessarily unique; hash in the
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// compiler's internal def-path, guaranteeing each symbol has a
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// truly unique path
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tcx.def_path_hash(def_id).hash_stable(&mut hcx, &mut hasher);
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// Include the main item-type. Note that, in this case, the
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// assertions about `needs_subst` may not hold, but this item-type
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// ought to be the same for every reference anyway.
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assert!(!item_type.has_erasable_regions());
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hcx.while_hashing_spans(false, |hcx| {
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hcx.with_node_id_hashing_mode(NodeIdHashingMode::HashDefPath, |hcx| {
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item_type.hash_stable(hcx, &mut hasher);
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});
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});
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// If this is a function, we hash the signature as well.
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// This is not *strictly* needed, but it may help in some
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// situations, see the `run-make/a-b-a-linker-guard` test.
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if let ty::FnDef(..) = item_type.kind {
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item_type.fn_sig(tcx).hash_stable(&mut hcx, &mut hasher);
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}
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// also include any type parameters (for generic items)
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assert!(!substs.has_erasable_regions());
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substs.hash_stable(&mut hcx, &mut hasher);
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if let Some(instantiating_crate) = instantiating_crate {
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tcx.original_crate_name(instantiating_crate)
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.as_str()
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.hash_stable(&mut hcx, &mut hasher);
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tcx.crate_disambiguator(instantiating_crate).hash_stable(&mut hcx, &mut hasher);
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}
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// We want to avoid accidental collision between different types of instances.
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// Especially, `VtableShim`s and `ReifyShim`s may overlap with their original
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// instances without this.
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discriminant(&instance.def).hash_stable(&mut hcx, &mut hasher);
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});
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// 64 bits should be enough to avoid collisions.
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hasher.finish::<u64>()
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}
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// Follow C++ namespace-mangling style, see
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// http://en.wikipedia.org/wiki/Name_mangling for more info.
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//
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// It turns out that on macOS you can actually have arbitrary symbols in
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// function names (at least when given to LLVM), but this is not possible
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// when using unix's linker. Perhaps one day when we just use a linker from LLVM
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// we won't need to do this name mangling. The problem with name mangling is
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// that it seriously limits the available characters. For example we can't
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// have things like &T in symbol names when one would theoretically
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// want them for things like impls of traits on that type.
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//
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// To be able to work on all platforms and get *some* reasonable output, we
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// use C++ name-mangling.
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#[derive(Debug)]
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struct SymbolPath {
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result: String,
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temp_buf: String,
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}
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impl SymbolPath {
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fn new() -> Self {
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let mut result =
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SymbolPath { result: String::with_capacity(64), temp_buf: String::with_capacity(16) };
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result.result.push_str("_ZN"); // _Z == Begin name-sequence, N == nested
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result
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}
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fn finalize_pending_component(&mut self) {
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if !self.temp_buf.is_empty() {
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let _ = write!(self.result, "{}{}", self.temp_buf.len(), self.temp_buf);
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self.temp_buf.clear();
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}
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}
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fn finish(mut self, hash: u64) -> String {
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self.finalize_pending_component();
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// E = end name-sequence
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let _ = write!(self.result, "17h{:016x}E", hash);
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self.result
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}
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}
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struct SymbolPrinter<'tcx> {
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tcx: TyCtxt<'tcx>,
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path: SymbolPath,
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// When `true`, `finalize_pending_component` isn't used.
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// This is needed when recursing into `path_qualified`,
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// or `path_generic_args`, as any nested paths are
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// logically within one component.
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keep_within_component: bool,
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}
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// HACK(eddyb) this relies on using the `fmt` interface to get
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// `PrettyPrinter` aka pretty printing of e.g. types in paths,
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// symbol names should have their own printing machinery.
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impl Printer<'tcx> for SymbolPrinter<'tcx> {
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type Error = fmt::Error;
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type Path = Self;
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type Region = Self;
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type Type = Self;
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type DynExistential = Self;
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type Const = Self;
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fn tcx(&self) -> TyCtxt<'tcx> {
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self.tcx
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}
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fn print_region(self, _region: ty::Region<'_>) -> Result<Self::Region, Self::Error> {
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Ok(self)
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}
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fn print_type(self, ty: Ty<'tcx>) -> Result<Self::Type, Self::Error> {
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match ty.kind {
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// Print all nominal types as paths (unlike `pretty_print_type`).
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ty::FnDef(def_id, substs)
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| ty::Opaque(def_id, substs)
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| ty::Projection(ty::ProjectionTy { item_def_id: def_id, substs })
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| ty::Closure(def_id, substs)
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| ty::Generator(def_id, substs, _) => self.print_def_path(def_id, substs),
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_ => self.pretty_print_type(ty),
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}
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}
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fn print_dyn_existential(
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mut self,
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predicates: &'tcx ty::List<ty::ExistentialPredicate<'tcx>>,
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) -> Result<Self::DynExistential, Self::Error> {
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let mut first = true;
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for p in predicates {
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if !first {
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write!(self, "+")?;
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}
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first = false;
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self = p.print(self)?;
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}
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Ok(self)
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}
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fn print_const(mut self, ct: &'tcx ty::Const<'tcx>) -> Result<Self::Const, Self::Error> {
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// only print integers
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if let ty::ConstKind::Value(ConstValue::Scalar(Scalar::Raw { .. })) = ct.val {
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if ct.ty.is_integral() {
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return self.pretty_print_const(ct, true);
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}
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}
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self.write_str("_")?;
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Ok(self)
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}
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fn path_crate(mut self, cnum: CrateNum) -> Result<Self::Path, Self::Error> {
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self.write_str(&self.tcx.original_crate_name(cnum).as_str())?;
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Ok(self)
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}
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fn path_qualified(
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self,
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self_ty: Ty<'tcx>,
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trait_ref: Option<ty::TraitRef<'tcx>>,
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) -> Result<Self::Path, Self::Error> {
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// Similar to `pretty_path_qualified`, but for the other
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// types that are printed as paths (see `print_type` above).
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match self_ty.kind {
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ty::FnDef(..)
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| ty::Opaque(..)
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| ty::Projection(_)
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| ty::Closure(..)
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| ty::Generator(..)
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if trait_ref.is_none() =>
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{
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self.print_type(self_ty)
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}
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_ => self.pretty_path_qualified(self_ty, trait_ref),
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}
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}
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fn path_append_impl(
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self,
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print_prefix: impl FnOnce(Self) -> Result<Self::Path, Self::Error>,
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_disambiguated_data: &DisambiguatedDefPathData,
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self_ty: Ty<'tcx>,
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trait_ref: Option<ty::TraitRef<'tcx>>,
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) -> Result<Self::Path, Self::Error> {
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self.pretty_path_append_impl(
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|mut cx| {
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cx = print_prefix(cx)?;
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if cx.keep_within_component {
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// HACK(eddyb) print the path similarly to how `FmtPrinter` prints it.
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cx.write_str("::")?;
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} else {
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cx.path.finalize_pending_component();
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}
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Ok(cx)
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},
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self_ty,
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trait_ref,
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)
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}
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fn path_append(
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mut self,
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print_prefix: impl FnOnce(Self) -> Result<Self::Path, Self::Error>,
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disambiguated_data: &DisambiguatedDefPathData,
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) -> Result<Self::Path, Self::Error> {
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self = print_prefix(self)?;
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// Skip `::{{constructor}}` on tuple/unit structs.
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if let DefPathData::Ctor = disambiguated_data.data {
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return Ok(self);
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}
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if self.keep_within_component {
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// HACK(eddyb) print the path similarly to how `FmtPrinter` prints it.
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self.write_str("::")?;
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} else {
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self.path.finalize_pending_component();
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}
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self.write_str(&disambiguated_data.data.as_symbol().as_str())?;
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Ok(self)
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}
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fn path_generic_args(
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mut self,
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print_prefix: impl FnOnce(Self) -> Result<Self::Path, Self::Error>,
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args: &[GenericArg<'tcx>],
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) -> Result<Self::Path, Self::Error> {
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self = print_prefix(self)?;
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let args = args.iter().cloned().filter(|arg| match arg.unpack() {
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GenericArgKind::Lifetime(_) => false,
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_ => true,
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});
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if args.clone().next().is_some() {
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self.generic_delimiters(|cx| cx.comma_sep(args))
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} else {
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Ok(self)
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}
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}
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}
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impl PrettyPrinter<'tcx> for SymbolPrinter<'tcx> {
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fn region_should_not_be_omitted(&self, _region: ty::Region<'_>) -> bool {
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false
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}
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fn comma_sep<T>(mut self, mut elems: impl Iterator<Item = T>) -> Result<Self, Self::Error>
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where
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T: Print<'tcx, Self, Output = Self, Error = Self::Error>,
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{
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if let Some(first) = elems.next() {
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self = first.print(self)?;
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for elem in elems {
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self.write_str(",")?;
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self = elem.print(self)?;
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}
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}
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Ok(self)
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}
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fn generic_delimiters(
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mut self,
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f: impl FnOnce(Self) -> Result<Self, Self::Error>,
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) -> Result<Self, Self::Error> {
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write!(self, "<")?;
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let kept_within_component = mem::replace(&mut self.keep_within_component, true);
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self = f(self)?;
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self.keep_within_component = kept_within_component;
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write!(self, ">")?;
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Ok(self)
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}
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}
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impl fmt::Write for SymbolPrinter<'_> {
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fn write_str(&mut self, s: &str) -> fmt::Result {
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// Name sanitation. LLVM will happily accept identifiers with weird names, but
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// gas doesn't!
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// gas accepts the following characters in symbols: a-z, A-Z, 0-9, ., _, $
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// NVPTX assembly has more strict naming rules than gas, so additionally, dots
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// are replaced with '$' there.
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for c in s.chars() {
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if self.path.temp_buf.is_empty() {
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match c {
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'a'..='z' | 'A'..='Z' | '_' => {}
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_ => {
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// Underscore-qualify anything that didn't start as an ident.
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self.path.temp_buf.push('_');
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}
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}
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}
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match c {
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// Escape these with $ sequences
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'@' => self.path.temp_buf.push_str("$SP$"),
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'*' => self.path.temp_buf.push_str("$BP$"),
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'&' => self.path.temp_buf.push_str("$RF$"),
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'<' => self.path.temp_buf.push_str("$LT$"),
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'>' => self.path.temp_buf.push_str("$GT$"),
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'(' => self.path.temp_buf.push_str("$LP$"),
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')' => self.path.temp_buf.push_str("$RP$"),
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',' => self.path.temp_buf.push_str("$C$"),
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'-' | ':' | '.' if self.tcx.has_strict_asm_symbol_naming() => {
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// NVPTX doesn't support these characters in symbol names.
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self.path.temp_buf.push('$')
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}
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// '.' doesn't occur in types and functions, so reuse it
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// for ':' and '-'
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'-' | ':' => self.path.temp_buf.push('.'),
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// Avoid crashing LLVM in certain (LTO-related) situations, see #60925.
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'm' if self.path.temp_buf.ends_with(".llv") => self.path.temp_buf.push_str("$u6d$"),
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// These are legal symbols
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'a'..='z' | 'A'..='Z' | '0'..='9' | '_' | '.' | '$' => self.path.temp_buf.push(c),
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_ => {
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self.path.temp_buf.push('$');
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for c in c.escape_unicode().skip(1) {
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match c {
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'{' => {}
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'}' => self.path.temp_buf.push('$'),
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c => self.path.temp_buf.push(c),
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}
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}
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}
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}
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}
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Ok(())
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}
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}
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