Restore #![no_builtins]
crates participation in LTO.
After #113716, we can make `#![no_builtins]` crates participate in LTO again. `#![no_builtins]` with LTO does not result in undefined references to the error.
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e20cb77021
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@ -510,8 +510,7 @@ fn link_staticlib<'a>(
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&codegen_results.crate_info,
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Some(CrateType::Staticlib),
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&mut |cnum, path| {
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let lto = are_upstream_rust_objects_already_included(sess)
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&& !ignored_for_lto(sess, &codegen_results.crate_info, cnum);
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let lto = are_upstream_rust_objects_already_included(sess);
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let native_libs = codegen_results.crate_info.native_libraries[&cnum].iter();
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let relevant = native_libs.clone().filter(|lib| relevant_lib(sess, &lib));
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@ -1250,24 +1249,6 @@ fn find_sanitizer_runtime(sess: &Session, filename: &str) -> PathBuf {
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}
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}
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/// Returns a boolean indicating whether the specified crate should be ignored
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/// during LTO.
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///
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/// Crates ignored during LTO are not lumped together in the "massive object
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/// file" that we create and are linked in their normal rlib states. See
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/// comments below for what crates do not participate in LTO.
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///
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/// It's unusual for a crate to not participate in LTO. Typically only
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/// compiler-specific and unstable crates have a reason to not participate in
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/// LTO.
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pub fn ignored_for_lto(sess: &Session, info: &CrateInfo, cnum: CrateNum) -> bool {
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// If our target enables builtin function lowering in LLVM then the
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// crates providing these functions don't participate in LTO (e.g.
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// no_builtins or compiler builtins crates).
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!sess.target.no_builtins
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&& (info.compiler_builtins == Some(cnum) || info.is_no_builtins.contains(&cnum))
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}
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/// This functions tries to determine the appropriate linker (and corresponding LinkerFlavor) to use
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pub fn linker_and_flavor(sess: &Session) -> (PathBuf, LinkerFlavor) {
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fn infer_from(
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@ -2733,10 +2714,6 @@ fn rehome_sysroot_lib_dir<'a>(sess: &'a Session, lib_dir: &Path) -> PathBuf {
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// symbols). We must continue to include the rest of the rlib, however, as
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// it may contain static native libraries which must be linked in.
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//
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// (*) Crates marked with `#![no_builtins]` don't participate in LTO and
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// their bytecode wasn't included. The object files in those libraries must
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// still be passed to the linker.
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//
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// Note, however, that if we're not doing LTO we can just pass the rlib
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// blindly to the linker (fast) because it's fine if it's not actually
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// included as we're at the end of the dependency chain.
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@ -2762,9 +2739,7 @@ fn add_static_crate<'a>(
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cmd.link_rlib(&rlib_path);
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};
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if !are_upstream_rust_objects_already_included(sess)
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|| ignored_for_lto(sess, &codegen_results.crate_info, cnum)
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{
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if !are_upstream_rust_objects_already_included(sess) {
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link_upstream(cratepath);
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return;
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}
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@ -2778,8 +2753,6 @@ fn add_static_crate<'a>(
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let canonical_name = name.replace('-', "_");
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let upstream_rust_objects_already_included =
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are_upstream_rust_objects_already_included(sess);
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let is_builtins =
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sess.target.no_builtins || !codegen_results.crate_info.is_no_builtins.contains(&cnum);
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let mut archive = archive_builder_builder.new_archive_builder(sess);
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if let Err(error) = archive.add_archive(
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@ -2796,9 +2769,8 @@ fn add_static_crate<'a>(
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// If we're performing LTO and this is a rust-generated object
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// file, then we don't need the object file as it's part of the
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// LTO module. Note that `#![no_builtins]` is excluded from LTO,
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// though, so we let that object file slide.
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if upstream_rust_objects_already_included && is_rust_object && is_builtins {
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// LTO module.
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if upstream_rust_objects_already_included && is_rust_object {
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return true;
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}
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@ -149,23 +149,12 @@ macro_rules! if_regular {
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let emit_obj = if !should_emit_obj {
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EmitObj::None
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} else if sess.target.obj_is_bitcode
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|| (sess.opts.cg.linker_plugin_lto.enabled() && !no_builtins)
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{
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} else if sess.target.obj_is_bitcode || sess.opts.cg.linker_plugin_lto.enabled() {
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// This case is selected if the target uses objects as bitcode, or
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// if linker plugin LTO is enabled. In the linker plugin LTO case
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// the assumption is that the final link-step will read the bitcode
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// and convert it to object code. This may be done by either the
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// native linker or rustc itself.
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//
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// Note, however, that the linker-plugin-lto requested here is
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// explicitly ignored for `#![no_builtins]` crates. These crates are
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// specifically ignored by rustc's LTO passes and wouldn't work if
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// loaded into the linker. These crates define symbols that LLVM
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// lowers intrinsics to, and these symbol dependencies aren't known
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// until after codegen. As a result any crate marked
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// `#![no_builtins]` is assumed to not participate in LTO and
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// instead goes on to generate object code.
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EmitObj::Bitcode
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} else if need_bitcode_in_object(tcx) {
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EmitObj::ObjectCode(BitcodeSection::Full)
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@ -1040,9 +1029,6 @@ fn start_executing_work<B: ExtraBackendMethods>(
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let mut each_linked_rlib_for_lto = Vec::new();
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drop(link::each_linked_rlib(crate_info, None, &mut |cnum, path| {
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if link::ignored_for_lto(sess, crate_info, cnum) {
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return;
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}
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each_linked_rlib_for_lto.push((cnum, path.to_path_buf()));
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}));
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@ -885,9 +885,7 @@ pub fn new(tcx: TyCtxt<'_>, target_cpu: String) -> CrateInfo {
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// If global LTO is enabled then almost everything (*) is glued into a single object file,
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// so this logic is not necessary and can cause issues on some targets (due to weak lang
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// item symbols being "privatized" to that object file), so we disable it.
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// (*) Native libs, and `#[compiler_builtins]` and `#[no_builtins]` crates are not glued,
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// and we assume that they cannot define weak lang items. This is not currently enforced
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// by the compiler, but that's ok because all this stuff is unstable anyway.
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// (*) Native libs are not glued, and we assume that they cannot define weak lang items.
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let target = &tcx.sess.target;
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if !are_upstream_rust_objects_already_included(tcx.sess) {
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let missing_weak_lang_items: FxHashSet<Symbol> = info
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@ -1,9 +1,15 @@
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include ../tools.mk
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# only-x86_64
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# We want to check that `no_builtins` is correctly participating in LTO.
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# First, verify that the `foo::foo` symbol can be found when linking.
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# Next, verify that `memcpy` can be customized using `no_builtins` under LTO.
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# Others will use the built-in memcpy.
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all:
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# Compile a `#![no_builtins]` rlib crate
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$(RUSTC) no_builtins.rs
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# Build an executable that depends on that crate using LTO. The no_builtins crate doesn't
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# participate in LTO, so its rlib must be explicitly linked into the final binary. Verify this by
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# grepping the linker arguments.
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$(RUSTC) main.rs -C lto --print link-args | $(CGREP) 'libno_builtins.rlib'
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$(RUSTC) -C linker-plugin-lto -C opt-level=2 -C debuginfo=0 foo.rs
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$(RUSTC) -C linker-plugin-lto -C opt-level=2 -C debuginfo=0 no_builtins.rs
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$(RUSTC) main.rs -C lto -C opt-level=2 -C debuginfo=0 -C save-temps -C metadata=1 -C codegen-units=1
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$(LLVM_BIN_DIR)/llvm-dis $(TMPDIR)/main.main.*-cgu.0.rcgu.lto.input.bc -o $(TMPDIR)/lto.ll
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cat "$(TMPDIR)"/lto.ll | "$(LLVM_FILECHECK)" filecheck.lto.txt
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tests/run-make/no-builtins-lto/filecheck.lto.txt
Normal file
17
tests/run-make/no-builtins-lto/filecheck.lto.txt
Normal file
@ -0,0 +1,17 @@
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CHECK: define{{.*}} void @bar
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CHECK-NEXT: call void @no_builtins
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CHECK-NEXT: call void @llvm.memcpy
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CHECK: define{{.*}} i32 @main
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CHECK: call void @bar
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CHECK: define{{.*}} void @foo
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CHECK-NEXT: call void @llvm.memcpy
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CHECK: define{{.*}} void @no_builtins
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CHECK-SAME: #[[ATTR:[0-9]+]] {
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CHECK: call void @foo
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CHECK-NEXT: call{{.*}} @memcpy
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CHECK: attributes #[[ATTR]]
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CHECK-SAME: no-builtins
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tests/run-make/no-builtins-lto/foo.rs
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33
tests/run-make/no-builtins-lto/foo.rs
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@ -0,0 +1,33 @@
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#![feature(lang_items, no_core)]
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#![no_std]
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#![no_core]
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#![crate_type = "lib"]
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#[inline(never)]
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#[no_mangle]
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pub unsafe fn foo(dest: *mut u8, src: *const u8) {
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// should call `@llvm.memcpy`.
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memcpy(dest, src, 1024);
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}
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#[no_mangle]
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#[inline(never)]
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pub unsafe extern "C" fn memcpy(dest: *mut u8, src: *const u8, _n: usize) -> *mut u8 {
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*dest = 0;
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return src as *mut u8;
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}
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#[lang = "sized"]
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trait Sized {}
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#[lang = "copy"]
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trait Copy {}
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impl Copy for *mut u8 {}
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impl Copy for *const u8 {}
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#[lang = "drop_in_place"]
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#[allow(unconditional_recursion)]
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pub unsafe fn drop_in_place<T: ?Sized>(to_drop: *mut T) {
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// Code here does not matter - this is replaced by the
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// real drop glue by the compiler.
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drop_in_place(to_drop);
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}
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@ -1,3 +1,28 @@
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extern crate no_builtins;
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#![feature(no_core, start, lang_items)]
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#![no_std]
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// We use `no_core` to reduce the LTO products is small enough.
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#![no_core]
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fn main() {}
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extern crate no_builtins;
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extern crate foo;
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#[link(name = "c")]
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extern "C" {}
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#[start]
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fn main(_: isize, p: *const *const u8) -> isize {
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// Make sure the symbols are retained.
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unsafe { bar(*p as *mut u8, *p); }
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0
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}
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#[no_mangle]
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#[inline(never)]
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pub unsafe extern "C" fn bar(dest: *mut u8, src: *const u8) {
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no_builtins::no_builtins(dest, src);
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// should call `@llvm.memcpy`
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foo::memcpy(dest, src, 1024);
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}
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#[lang = "eh_personality"]
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fn eh_personality() {}
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@ -1,2 +1,15 @@
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#![feature(lang_items, no_core)]
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#![no_std]
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#![no_core]
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#![crate_type = "lib"]
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#![no_builtins]
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extern crate foo;
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#[no_mangle]
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pub unsafe fn no_builtins(dest: *mut u8, src: *const u8) {
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// There should be no "undefined reference to `foo::foo'".
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foo::foo(dest, src);
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// should call `@memcpy` instead of `@llvm.memcpy`.
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foo::memcpy(dest, src, 1024);
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}
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