//! Errors emitted by codegen_ssa use std::borrow::Cow; use std::ffi::OsString; use std::io::Error; use std::path::{Path, PathBuf}; use std::process::ExitStatus; use rustc_errors::codes::*; use rustc_errors::{ Diag, DiagArgValue, DiagCtxtHandle, Diagnostic, EmissionGuarantee, IntoDiagArg, Level, msg, }; use rustc_macros::{Diagnostic, Subdiagnostic}; use rustc_middle::ty::layout::LayoutError; use rustc_middle::ty::{FloatTy, Ty}; use rustc_span::{Span, Symbol}; use crate::assert_module_sources::CguReuse; use crate::back::command::Command; #[derive(Diagnostic)] #[diag( "CGU-reuse for `{$cgu_user_name}` is `{$actual_reuse}` but should be {$at_least -> [one] {\"at least \"} *[other] {\"\"} }`{$expected_reuse}`" )] pub(crate) struct IncorrectCguReuseType<'a> { #[primary_span] pub span: Span, pub cgu_user_name: &'a str, pub actual_reuse: CguReuse, pub expected_reuse: CguReuse, pub at_least: u8, } #[derive(Diagnostic)] #[diag("CGU-reuse for `{$cgu_user_name}` is (mangled: `{$cgu_name}`) was not recorded")] pub(crate) struct CguNotRecorded<'a> { pub cgu_user_name: &'a str, pub cgu_name: &'a str, } #[derive(Diagnostic)] #[diag("found CGU-reuse attribute but `-Zquery-dep-graph` was not specified")] pub(crate) struct MissingQueryDepGraph { #[primary_span] pub span: Span, } #[derive(Diagnostic)] #[diag( "found malformed codegen unit name `{$user_path}`. codegen units names must always start with the name of the crate (`{$crate_name}` in this case)" )] pub(crate) struct MalformedCguName<'a> { #[primary_span] pub span: Span, pub user_path: &'a str, pub crate_name: &'a str, } #[derive(Diagnostic)] #[diag("no module named `{$user_path}` (mangled: {$cgu_name}). available modules: {$cgu_names}")] pub(crate) struct NoModuleNamed<'a> { #[primary_span] pub span: Span, pub user_path: &'a str, pub cgu_name: Symbol, pub cgu_names: String, } #[derive(Diagnostic)] #[diag("failed to write lib.def file: {$error}")] pub(crate) struct LibDefWriteFailure { pub error: Error, } #[derive(Diagnostic)] #[diag("failed to write version script: {$error}")] pub(crate) struct VersionScriptWriteFailure { pub error: Error, } #[derive(Diagnostic)] #[diag("failed to write symbols file: {$error}")] pub(crate) struct SymbolFileWriteFailure { pub error: Error, } #[derive(Diagnostic)] #[diag("`as-needed` modifier not implemented yet for ld64")] pub(crate) struct Ld64UnimplementedModifier; #[derive(Diagnostic)] #[diag("`as-needed` modifier not supported for current linker")] pub(crate) struct LinkerUnsupportedModifier; #[derive(Diagnostic)] #[diag("exporting symbols not implemented yet for L4Bender")] pub(crate) struct L4BenderExportingSymbolsUnimplemented; #[derive(Diagnostic)] #[diag("error enumerating natvis directory: {$error}")] pub(crate) struct NoNatvisDirectory { pub error: Error, } #[derive(Diagnostic)] #[diag("cached cgu {$cgu_name} should have an object file, but doesn't")] pub(crate) struct NoSavedObjectFile<'a> { pub cgu_name: &'a str, } #[derive(Diagnostic)] #[diag("`#[track_caller]` requires Rust ABI", code = E0737)] pub(crate) struct RequiresRustAbi { #[primary_span] pub span: Span, } #[derive(Diagnostic)] #[diag("unable to copy {$source_file} to {$output_path}: {$error}")] pub(crate) struct CopyPathBuf { pub source_file: PathBuf, pub output_path: PathBuf, pub error: Error, } // Reports Paths using `Debug` implementation rather than Path's `Display` implementation. #[derive(Diagnostic)] #[diag("could not copy {$from} to {$to}: {$error}")] pub(crate) struct CopyPath<'a> { from: DebugArgPath<'a>, to: DebugArgPath<'a>, error: Error, } impl<'a> CopyPath<'a> { pub(crate) fn new(from: &'a Path, to: &'a Path, error: Error) -> CopyPath<'a> { CopyPath { from: DebugArgPath(from), to: DebugArgPath(to), error } } } struct DebugArgPath<'a>(pub &'a Path); impl IntoDiagArg for DebugArgPath<'_> { fn into_diag_arg(self, _: &mut Option) -> rustc_errors::DiagArgValue { DiagArgValue::Str(Cow::Owned(format!("{:?}", self.0))) } } #[derive(Diagnostic)] #[diag( "option `-o` or `--emit` is used to write binary output type `{$shorthand}` to stdout, but stdout is a tty" )] pub(crate) struct BinaryOutputToTty { pub shorthand: &'static str, } #[derive(Diagnostic)] #[diag("ignoring emit path because multiple .{$extension} files were produced")] pub(crate) struct IgnoringEmitPath { pub extension: &'static str, } #[derive(Diagnostic)] #[diag("ignoring -o because multiple .{$extension} files were produced")] pub(crate) struct IgnoringOutput { pub extension: &'static str, } #[derive(Diagnostic)] #[diag("couldn't create a temp dir: {$error}")] pub(crate) struct CreateTempDir { pub error: Error, } #[derive(Diagnostic)] #[diag("failed to add native library {$library_path}: {$error}")] pub(crate) struct AddNativeLibrary { pub library_path: PathBuf, pub error: Error, } #[derive(Diagnostic)] #[diag( "multiple declarations of external function `{$function}` from library `{$library_name}` have different calling conventions" )] pub(crate) struct MultipleExternalFuncDecl<'a> { #[primary_span] pub span: Span, pub function: Symbol, pub library_name: &'a str, } #[derive(Diagnostic)] pub enum LinkRlibError { #[diag("could not find formats for rlibs")] MissingFormat, #[diag("could not find rlib for: `{$crate_name}`, found rmeta (metadata) file")] OnlyRmetaFound { crate_name: Symbol }, #[diag("could not find rlib for: `{$crate_name}`")] NotFound { crate_name: Symbol }, #[diag( "`{$ty1}` and `{$ty2}` do not have equivalent dependency formats (`{$list1}` vs `{$list2}`)" )] IncompatibleDependencyFormats { ty1: String, ty2: String, list1: String, list2: String }, } pub(crate) struct ThorinErrorWrapper(pub thorin::Error); impl Diagnostic<'_, G> for ThorinErrorWrapper { fn into_diag(self, dcx: DiagCtxtHandle<'_>, level: Level) -> Diag<'_, G> { let build = |msg| Diag::new(dcx, level, msg); match self.0 { thorin::Error::ReadInput(_) => build(msg!("failed to read input file")), thorin::Error::ParseFileKind(_) => { build(msg!("failed to parse input file kind")) } thorin::Error::ParseObjectFile(_) => { build(msg!("failed to parse input object file")) } thorin::Error::ParseArchiveFile(_) => { build(msg!("failed to parse input archive file")) } thorin::Error::ParseArchiveMember(_) => { build(msg!("failed to parse archive member")) } thorin::Error::InvalidInputKind => build(msg!("input is not an archive or elf object")), thorin::Error::DecompressData(_) => build(msg!("failed to decompress compressed section")), thorin::Error::NamelessSection(_, offset) => { build(msg!("section without name at offset {$offset}")) .with_arg("offset", format!("0x{offset:08x}")) } thorin::Error::RelocationWithInvalidSymbol(section, offset) => { build(msg!("relocation with invalid symbol for section `{$section}` at offset {$offset}")) .with_arg("section", section) .with_arg("offset", format!("0x{offset:08x}")) } thorin::Error::MultipleRelocations(section, offset) => { build(msg!("multiple relocations for section `{$section}` at offset {$offset}")) .with_arg("section", section) .with_arg("offset", format!("0x{offset:08x}")) } thorin::Error::UnsupportedRelocation(section, offset) => { build(msg!("unsupported relocation for section {$section} at offset {$offset}")) .with_arg("section", section) .with_arg("offset", format!("0x{offset:08x}")) } thorin::Error::MissingDwoName(id) => build(msg!("missing path attribute to DWARF object ({$id})")) .with_arg("id", format!("0x{id:08x}")), thorin::Error::NoCompilationUnits => { build(msg!("input object has no compilation units")) } thorin::Error::NoDie => build(msg!("no top-level debugging information entry in compilation/type unit")), thorin::Error::TopLevelDieNotUnit => { build(msg!("top-level debugging information entry is not a compilation/type unit")) } thorin::Error::MissingRequiredSection(section) => { build(msg!("input object missing required section `{$section}`")) .with_arg("section", section) } thorin::Error::ParseUnitAbbreviations(_) => { build(msg!("failed to parse unit abbreviations")) } thorin::Error::ParseUnitAttribute(_) => { build(msg!("failed to parse unit attribute")) } thorin::Error::ParseUnitHeader(_) => { build(msg!("failed to parse unit header")) } thorin::Error::ParseUnit(_) => build(msg!("failed to parse unit")), thorin::Error::IncompatibleIndexVersion(section, format, actual) => { build(msg!("incompatible `{$section}` index version: found version {$actual}, expected version {$format}")) .with_arg("section", section) .with_arg("actual", actual) .with_arg("format", format) } thorin::Error::OffsetAtIndex(_, index) => { build(msg!("read offset at index {$index} of `.debug_str_offsets.dwo` section")).with_arg("index", index) } thorin::Error::StrAtOffset(_, offset) => { build(msg!("read string at offset {$offset} of `.debug_str.dwo` section")) .with_arg("offset", format!("0x{offset:08x}")) } thorin::Error::ParseIndex(_, section) => { build(msg!("failed to parse `{$section}` index section")).with_arg("section", section) } thorin::Error::UnitNotInIndex(unit) => { build(msg!("unit {$unit} from input package is not in its index")) .with_arg("unit", format!("0x{unit:08x}")) } thorin::Error::RowNotInIndex(_, row) => { build(msg!("row {$row} found in index's hash table not present in index")).with_arg("row", row) } thorin::Error::SectionNotInRow => build(msg!("section not found in unit's row in index")), thorin::Error::EmptyUnit(unit) => build(msg!("unit {$unit} in input DWARF object with no data")) .with_arg("unit", format!("0x{unit:08x}")), thorin::Error::MultipleDebugInfoSection => { build(msg!("multiple `.debug_info.dwo` sections")) } thorin::Error::MultipleDebugTypesSection => { build(msg!("multiple `.debug_types.dwo` sections in a package")) } thorin::Error::NotSplitUnit => build(msg!("regular compilation unit in object (missing dwo identifier)")), thorin::Error::DuplicateUnit(unit) => build(msg!("duplicate split compilation unit ({$unit})")) .with_arg("unit", format!("0x{unit:08x}")), thorin::Error::MissingReferencedUnit(unit) => { build(msg!("unit {$unit} referenced by executable was not found")) .with_arg("unit", format!("0x{unit:08x}")) } thorin::Error::NoOutputObjectCreated => { build(msg!("no output object was created from inputs")) } thorin::Error::MixedInputEncodings => { build(msg!("input objects have mixed encodings")) } thorin::Error::Io(e) => { build(msg!("{$error}")).with_arg("error", format!("{e}")) } thorin::Error::ObjectRead(e) => { build(msg!("{$error}")).with_arg("error", format!("{e}")) } thorin::Error::ObjectWrite(e) => { build(msg!("{$error}")).with_arg("error", format!("{e}")) } thorin::Error::GimliRead(e) => { build(msg!("{$error}")).with_arg("error", format!("{e}")) } thorin::Error::GimliWrite(e) => { build(msg!("{$error}")).with_arg("error", format!("{e}")) } _ => unimplemented!("Untranslated thorin error"), } } } pub(crate) struct LinkingFailed<'a> { pub linker_path: &'a Path, pub exit_status: ExitStatus, pub command: Command, pub escaped_output: String, pub verbose: bool, pub sysroot_dir: PathBuf, } impl Diagnostic<'_, G> for LinkingFailed<'_> { fn into_diag(mut self, dcx: DiagCtxtHandle<'_>, level: Level) -> Diag<'_, G> { let mut diag = Diag::new(dcx, level, msg!("linking with `{$linker_path}` failed: {$exit_status}")); diag.arg("linker_path", format!("{}", self.linker_path.display())); diag.arg("exit_status", format!("{}", self.exit_status)); let contains_undefined_ref = self.escaped_output.contains("undefined reference to"); if self.verbose { diag.note(format!("{:?}", self.command)); } else { self.command.env_clear(); enum ArgGroup { Regular(OsString), Objects(usize), Rlibs(PathBuf, Vec), } // Omit rust object files and fold rlibs in the error by default to make linker errors a // bit less verbose. let orig_args = self.command.take_args(); let mut args: Vec = vec![]; for arg in orig_args { if arg.as_encoded_bytes().ends_with(b".rcgu.o") { if let Some(ArgGroup::Objects(n)) = args.last_mut() { *n += 1; } else { args.push(ArgGroup::Objects(1)); } } else if arg.as_encoded_bytes().ends_with(b".rlib") { let rlib_path = Path::new(&arg); let dir = rlib_path.parent().unwrap(); let filename = rlib_path.file_stem().unwrap().to_owned(); if let Some(ArgGroup::Rlibs(parent, rlibs)) = args.last_mut() { if parent == dir { rlibs.push(filename); } else { args.push(ArgGroup::Rlibs(dir.to_owned(), vec![filename])); } } else { args.push(ArgGroup::Rlibs(dir.to_owned(), vec![filename])); } } else { args.push(ArgGroup::Regular(arg)); } } let crate_hash = regex::bytes::Regex::new(r"-[0-9a-f]+").unwrap(); self.command.args(args.into_iter().map(|arg_group| { match arg_group { // SAFETY: we are only matching on ASCII, not any surrogate pairs, so any replacements we do will still be valid. ArgGroup::Regular(arg) => unsafe { use bstr::ByteSlice; OsString::from_encoded_bytes_unchecked( arg.as_encoded_bytes().replace( self.sysroot_dir.as_os_str().as_encoded_bytes(), b"", ), ) }, ArgGroup::Objects(n) => OsString::from(format!("<{n} object files omitted>")), ArgGroup::Rlibs(mut dir, rlibs) => { let is_sysroot_dir = match dir.strip_prefix(&self.sysroot_dir) { Ok(short) => { dir = Path::new("").join(short); true } Err(_) => false, }; let mut arg = dir.into_os_string(); arg.push("/"); let needs_braces = rlibs.len() >= 2; if needs_braces { arg.push("{"); } let mut first = true; for mut rlib in rlibs { if !first { arg.push(","); } first = false; if is_sysroot_dir { // SAFETY: Regex works one byte at a type, and our regex will not match surrogate pairs (because it only matches ascii). rlib = unsafe { OsString::from_encoded_bytes_unchecked( crate_hash .replace(rlib.as_encoded_bytes(), b"-*") .into_owned(), ) }; } arg.push(rlib); } if needs_braces { arg.push("}"); } arg.push(".rlib"); arg } } })); diag.note(format!("{:?}", self.command).trim_start_matches("env -i").to_owned()); diag.note("some arguments are omitted. use `--verbose` to show all linker arguments"); } diag.note(self.escaped_output); // Trying to match an error from OS linkers // which by now we have no way to translate. if contains_undefined_ref { diag.note(msg!("some `extern` functions couldn't be found; some native libraries may need to be installed or have their path specified")) .note(msg!("use the `-l` flag to specify native libraries to link")); if rustc_session::utils::was_invoked_from_cargo() { diag.note(msg!("use the `cargo:rustc-link-lib` directive to specify the native libraries to link with Cargo (see https://doc.rust-lang.org/cargo/reference/build-scripts.html#rustc-link-lib)")); } } diag } } #[derive(Diagnostic)] #[diag("`link.exe` returned an unexpected error")] pub(crate) struct LinkExeUnexpectedError; pub(crate) struct LinkExeStatusStackBufferOverrun; impl<'a, G: EmissionGuarantee> Diagnostic<'a, G> for LinkExeStatusStackBufferOverrun { fn into_diag(self, dcx: rustc_errors::DiagCtxtHandle<'a>, level: Level) -> Diag<'a, G> { let mut diag = Diag::new(dcx, level, msg!("0xc0000409 is `STATUS_STACK_BUFFER_OVERRUN`")); diag.note(msg!( "this may have been caused by a program abort and not a stack buffer overrun" )); diag.note(msg!("consider checking the Application Event Log for Windows Error Reporting events to see the fail fast error code")); diag } } #[derive(Diagnostic)] #[diag("the Visual Studio build tools may need to be repaired using the Visual Studio installer")] pub(crate) struct RepairVSBuildTools; #[derive(Diagnostic)] #[diag("or a necessary component may be missing from the \"C++ build tools\" workload")] pub(crate) struct MissingCppBuildToolComponent; #[derive(Diagnostic)] #[diag("in the Visual Studio installer, ensure the \"C++ build tools\" workload is selected")] pub(crate) struct SelectCppBuildToolWorkload; #[derive(Diagnostic)] #[diag("you may need to install Visual Studio build tools with the \"C++ build tools\" workload")] pub(crate) struct VisualStudioNotInstalled; #[derive(Diagnostic)] #[diag("linker `{$linker_path}` not found")] #[note("{$error}")] pub(crate) struct LinkerNotFound { pub linker_path: PathBuf, pub error: Error, } #[derive(Diagnostic)] #[diag("could not exec the linker `{$linker_path}`")] #[note("{$error}")] #[note("{$command_formatted}")] pub(crate) struct UnableToExeLinker { pub linker_path: PathBuf, pub error: Error, pub command_formatted: String, } #[derive(Diagnostic)] #[diag("the msvc targets depend on the msvc linker but `link.exe` was not found")] pub(crate) struct MsvcMissingLinker; #[derive(Diagnostic)] #[diag( "the self-contained linker was requested, but it wasn't found in the target's sysroot, or in rustc's sysroot" )] pub(crate) struct SelfContainedLinkerMissing; #[derive(Diagnostic)] #[diag( "please ensure that Visual Studio 2017 or later, or Build Tools for Visual Studio were installed with the Visual C++ option" )] pub(crate) struct CheckInstalledVisualStudio; #[derive(Diagnostic)] #[diag("VS Code is a different product, and is not sufficient")] pub(crate) struct InsufficientVSCodeProduct; #[derive(Diagnostic)] #[diag("target requires explicitly specifying a cpu with `-C target-cpu`")] pub(crate) struct CpuRequired; #[derive(Diagnostic)] #[diag("processing debug info with `dsymutil` failed: {$status}")] #[note("{$output}")] pub(crate) struct ProcessingDymutilFailed { pub status: ExitStatus, pub output: String, } #[derive(Diagnostic)] #[diag("unable to run `dsymutil`: {$error}")] pub(crate) struct UnableToRunDsymutil { pub error: Error, } #[derive(Diagnostic)] #[diag("stripping debug info with `{$util}` failed: {$status}")] #[note("{$output}")] pub(crate) struct StrippingDebugInfoFailed<'a> { pub util: &'a str, pub status: ExitStatus, pub output: String, } #[derive(Diagnostic)] #[diag("unable to run `{$util}`: {$error}")] pub(crate) struct UnableToRun<'a> { pub util: &'a str, pub error: Error, } #[derive(Diagnostic)] #[diag("couldn't extract file stem from specified linker")] pub(crate) struct LinkerFileStem; #[derive(Diagnostic)] #[diag( "link against the following native artifacts when linking against this static library. The order and any duplication can be significant on some platforms" )] pub(crate) struct StaticLibraryNativeArtifacts; #[derive(Diagnostic)] #[diag( "native artifacts to link against have been written to {$path}. The order and any duplication can be significant on some platforms" )] pub(crate) struct StaticLibraryNativeArtifactsToFile<'a> { pub path: &'a Path, } #[derive(Diagnostic)] #[diag("can only use link script when linking with GNU-like linker")] pub(crate) struct LinkScriptUnavailable; #[derive(Diagnostic)] #[diag("failed to write link script to {$path}: {$error}")] pub(crate) struct LinkScriptWriteFailure { pub path: PathBuf, pub error: Error, } #[derive(Diagnostic)] #[diag("failed to write {$path}: {$error}")] pub(crate) struct FailedToWrite { pub path: PathBuf, pub error: Error, } #[derive(Diagnostic)] #[diag("unable to write debugger visualizer file `{$path}`: {$error}")] pub(crate) struct UnableToWriteDebuggerVisualizer { pub path: PathBuf, pub error: Error, } #[derive(Diagnostic)] #[diag("failed to build archive from rlib at `{$path}`: {$error}")] pub(crate) struct RlibArchiveBuildFailure { pub path: PathBuf, pub error: Error, } #[derive(Diagnostic)] // Public for ArchiveBuilderBuilder::extract_bundled_libs pub enum ExtractBundledLibsError<'a> { #[diag("failed to open file '{$rlib}': {$error}")] OpenFile { rlib: &'a Path, error: Box }, #[diag("failed to mmap file '{$rlib}': {$error}")] MmapFile { rlib: &'a Path, error: Box }, #[diag("failed to parse archive '{$rlib}': {$error}")] ParseArchive { rlib: &'a Path, error: Box }, #[diag("failed to read entry '{$rlib}': {$error}")] ReadEntry { rlib: &'a Path, error: Box }, #[diag("failed to get data from archive member '{$rlib}': {$error}")] ArchiveMember { rlib: &'a Path, error: Box }, #[diag("failed to convert name '{$rlib}': {$error}")] ConvertName { rlib: &'a Path, error: Box }, #[diag("failed to write file '{$rlib}': {$error}")] WriteFile { rlib: &'a Path, error: Box }, #[diag("failed to write file '{$rlib}': {$error}")] ExtractSection { rlib: &'a Path, error: Box }, } #[derive(Diagnostic)] #[diag("failed to read file: {$message}")] pub(crate) struct ReadFileError { pub message: std::io::Error, } #[derive(Diagnostic)] #[diag("option `-C link-self-contained` is not supported on this target")] pub(crate) struct UnsupportedLinkSelfContained; #[derive(Diagnostic)] #[diag("failed to build archive at `{$path}`: {$error}")] pub(crate) struct ArchiveBuildFailure { pub path: PathBuf, pub error: std::io::Error, } #[derive(Diagnostic)] #[diag("don't know how to build archive of type: {$kind}")] pub(crate) struct UnknownArchiveKind<'a> { pub kind: &'a str, } #[derive(Diagnostic)] #[diag("linking static libraries is not supported for BPF")] pub(crate) struct BpfStaticlibNotSupported; #[derive(Diagnostic)] #[diag("entry symbol `main` declared multiple times")] #[help( "did you use `#[no_mangle]` on `fn main`? Use `#![no_main]` to suppress the usual Rust-generated entry point" )] pub(crate) struct MultipleMainFunctions { #[primary_span] pub span: Span, } #[derive(Diagnostic)] #[diag("could not evaluate shuffle_indices at compile time")] pub(crate) struct ShuffleIndicesEvaluation { #[primary_span] pub span: Span, } #[derive(Diagnostic)] pub enum InvalidMonomorphization<'tcx> { #[diag("invalid monomorphization of `{$name}` intrinsic: expected basic integer type, found `{$ty}`", code = E0511)] BasicIntegerType { #[primary_span] span: Span, name: Symbol, ty: Ty<'tcx>, }, #[diag("invalid monomorphization of `{$name}` intrinsic: expected basic integer or pointer type, found `{$ty}`", code = E0511)] BasicIntegerOrPtrType { #[primary_span] span: Span, name: Symbol, ty: Ty<'tcx>, }, #[diag("invalid monomorphization of `{$name}` intrinsic: expected basic float type, found `{$ty}`", code = E0511)] BasicFloatType { #[primary_span] span: Span, name: Symbol, ty: Ty<'tcx>, }, #[diag("invalid monomorphization of `float_to_int_unchecked` intrinsic: expected basic float type, found `{$ty}`", code = E0511)] FloatToIntUnchecked { #[primary_span] span: Span, ty: Ty<'tcx>, }, #[diag("invalid monomorphization of `{$name}` intrinsic: unsupported element type `{$f_ty}` of floating-point vector `{$in_ty}`", code = E0511)] FloatingPointVector { #[primary_span] span: Span, name: Symbol, f_ty: FloatTy, in_ty: Ty<'tcx>, }, #[diag("invalid monomorphization of `{$name}` intrinsic: `{$in_ty}` is not a floating-point type", code = E0511)] FloatingPointType { #[primary_span] span: Span, name: Symbol, in_ty: Ty<'tcx>, }, #[diag("invalid monomorphization of `{$name}` intrinsic: unrecognized intrinsic `{$name}`", code = E0511)] UnrecognizedIntrinsic { #[primary_span] span: Span, name: Symbol, }, #[diag("invalid monomorphization of `{$name}` intrinsic: expected SIMD argument type, found non-SIMD `{$ty}`", code = E0511)] SimdArgument { #[primary_span] span: Span, name: Symbol, ty: Ty<'tcx>, }, #[diag("invalid monomorphization of `{$name}` intrinsic: expected SIMD input type, found non-SIMD `{$ty}`", code = E0511)] SimdInput { #[primary_span] span: Span, name: Symbol, ty: Ty<'tcx>, }, #[diag("invalid monomorphization of `{$name}` intrinsic: expected SIMD first type, found non-SIMD `{$ty}`", code = E0511)] SimdFirst { #[primary_span] span: Span, name: Symbol, ty: Ty<'tcx>, }, #[diag("invalid monomorphization of `{$name}` intrinsic: expected SIMD second type, found non-SIMD `{$ty}`", code = E0511)] SimdSecond { #[primary_span] span: Span, name: Symbol, ty: Ty<'tcx>, }, #[diag("invalid monomorphization of `{$name}` intrinsic: expected SIMD third type, found non-SIMD `{$ty}`", code = E0511)] SimdThird { #[primary_span] span: Span, name: Symbol, ty: Ty<'tcx>, }, #[diag("invalid monomorphization of `{$name}` intrinsic: expected SIMD return type, found non-SIMD `{$ty}`", code = E0511)] SimdReturn { #[primary_span] span: Span, name: Symbol, ty: Ty<'tcx>, }, #[diag("invalid monomorphization of `{$name}` intrinsic: invalid bitmask `{$mask_ty}`, expected `u{$expected_int_bits}` or `[u8; {$expected_bytes}]`", code = E0511)] InvalidBitmask { #[primary_span] span: Span, name: Symbol, mask_ty: Ty<'tcx>, expected_int_bits: u64, expected_bytes: u64, }, #[diag("invalid monomorphization of `{$name}` intrinsic: expected return type with length {$in_len} (same as input type `{$in_ty}`), found `{$ret_ty}` with length {$out_len}", code = E0511)] ReturnLengthInputType { #[primary_span] span: Span, name: Symbol, in_len: u64, in_ty: Ty<'tcx>, ret_ty: Ty<'tcx>, out_len: u64, }, #[diag("invalid monomorphization of `{$name}` intrinsic: expected second argument with length {$in_len} (same as input type `{$in_ty}`), found `{$arg_ty}` with length {$out_len}", code = E0511)] SecondArgumentLength { #[primary_span] span: Span, name: Symbol, in_len: u64, in_ty: Ty<'tcx>, arg_ty: Ty<'tcx>, out_len: u64, }, #[diag("invalid monomorphization of `{$name}` intrinsic: expected third argument with length {$in_len} (same as input type `{$in_ty}`), found `{$arg_ty}` with length {$out_len}", code = E0511)] ThirdArgumentLength { #[primary_span] span: Span, name: Symbol, in_len: u64, in_ty: Ty<'tcx>, arg_ty: Ty<'tcx>, out_len: u64, }, #[diag("invalid monomorphization of `{$name}` intrinsic: expected return type with integer elements, found `{$ret_ty}` with non-integer `{$out_ty}`", code = E0511)] ReturnIntegerType { #[primary_span] span: Span, name: Symbol, ret_ty: Ty<'tcx>, out_ty: Ty<'tcx>, }, #[diag("invalid monomorphization of `{$name}` intrinsic: simd_shuffle index must be a SIMD vector of `u32`, got `{$ty}`", code = E0511)] SimdShuffle { #[primary_span] span: Span, name: Symbol, ty: Ty<'tcx>, }, #[diag("invalid monomorphization of `{$name}` intrinsic: expected return type of length {$in_len}, found `{$ret_ty}` with length {$out_len}", code = E0511)] ReturnLength { #[primary_span] span: Span, name: Symbol, in_len: u64, ret_ty: Ty<'tcx>, out_len: u64, }, #[diag("invalid monomorphization of `{$name}` intrinsic: expected return element type `{$in_elem}` (element of input `{$in_ty}`), found `{$ret_ty}` with element type `{$out_ty}`", code = E0511)] ReturnElement { #[primary_span] span: Span, name: Symbol, in_elem: Ty<'tcx>, in_ty: Ty<'tcx>, ret_ty: Ty<'tcx>, out_ty: Ty<'tcx>, }, #[diag("invalid monomorphization of `{$name}` intrinsic: SIMD index #{$arg_idx} is out of bounds (limit {$total_len})", code = E0511)] SimdIndexOutOfBounds { #[primary_span] span: Span, name: Symbol, arg_idx: u64, total_len: u128, }, #[diag("invalid monomorphization of `{$name}` intrinsic: expected inserted type `{$in_elem}` (element of input `{$in_ty}`), found `{$out_ty}`", code = E0511)] InsertedType { #[primary_span] span: Span, name: Symbol, in_elem: Ty<'tcx>, in_ty: Ty<'tcx>, out_ty: Ty<'tcx>, }, #[diag("invalid monomorphization of `{$name}` intrinsic: expected return type `{$in_elem}` (element of input `{$in_ty}`), found `{$ret_ty}`", code = E0511)] ReturnType { #[primary_span] span: Span, name: Symbol, in_elem: Ty<'tcx>, in_ty: Ty<'tcx>, ret_ty: Ty<'tcx>, }, #[diag("invalid monomorphization of `{$name}` intrinsic: expected return type `{$in_ty}`, found `{$ret_ty}`", code = E0511)] ExpectedReturnType { #[primary_span] span: Span, name: Symbol, in_ty: Ty<'tcx>, ret_ty: Ty<'tcx>, }, #[diag("invalid monomorphization of `{$name}` intrinsic: mismatched lengths: mask length `{$m_len}` != other vector length `{$v_len}`", code = E0511)] MismatchedLengths { #[primary_span] span: Span, name: Symbol, m_len: u64, v_len: u64, }, #[diag("invalid monomorphization of `{$name}` intrinsic: expected mask element type to be an integer, found `{$ty}`", code = E0511)] MaskWrongElementType { #[primary_span] span: Span, name: Symbol, ty: Ty<'tcx>, }, #[diag("invalid monomorphization of `{$name}` intrinsic: cannot return `{$ret_ty}`, expected `u{$expected_int_bits}` or `[u8; {$expected_bytes}]`", code = E0511)] CannotReturn { #[primary_span] span: Span, name: Symbol, ret_ty: Ty<'tcx>, expected_int_bits: u64, expected_bytes: u64, }, #[diag("invalid monomorphization of `{$name}` intrinsic: expected element type `{$expected_element}` of second argument `{$second_arg}` to be a pointer to the element type `{$in_elem}` of the first argument `{$in_ty}`, found `{$expected_element}` != `{$mutability} {$in_elem}`", code = E0511)] ExpectedElementType { #[primary_span] span: Span, name: Symbol, expected_element: Ty<'tcx>, second_arg: Ty<'tcx>, in_elem: Ty<'tcx>, in_ty: Ty<'tcx>, mutability: ExpectedPointerMutability, }, #[diag("invalid monomorphization of `{$name}` intrinsic: unsupported {$symbol} from `{$in_ty}` with element `{$in_elem}` of size `{$size}` to `{$ret_ty}`", code = E0511)] UnsupportedSymbolOfSize { #[primary_span] span: Span, name: Symbol, symbol: Symbol, in_ty: Ty<'tcx>, in_elem: Ty<'tcx>, size: u64, ret_ty: Ty<'tcx>, }, #[diag("invalid monomorphization of `{$name}` intrinsic: unsupported {$symbol} from `{$in_ty}` with element `{$in_elem}` to `{$ret_ty}`", code = E0511)] UnsupportedSymbol { #[primary_span] span: Span, name: Symbol, symbol: Symbol, in_ty: Ty<'tcx>, in_elem: Ty<'tcx>, ret_ty: Ty<'tcx>, }, #[diag("invalid monomorphization of `{$name}` intrinsic: cannot cast wide pointer `{$ty}`", code = E0511)] CastWidePointer { #[primary_span] span: Span, name: Symbol, ty: Ty<'tcx>, }, #[diag("invalid monomorphization of `{$name}` intrinsic: expected pointer, got `{$ty}`", code = E0511)] ExpectedPointer { #[primary_span] span: Span, name: Symbol, ty: Ty<'tcx>, }, #[diag("invalid monomorphization of `{$name}` intrinsic: expected `usize`, got `{$ty}`", code = E0511)] ExpectedUsize { #[primary_span] span: Span, name: Symbol, ty: Ty<'tcx>, }, #[diag("invalid monomorphization of `{$name}` intrinsic: unsupported cast from `{$in_ty}` with element `{$in_elem}` to `{$ret_ty}` with element `{$out_elem}`", code = E0511)] UnsupportedCast { #[primary_span] span: Span, name: Symbol, in_ty: Ty<'tcx>, in_elem: Ty<'tcx>, ret_ty: Ty<'tcx>, out_elem: Ty<'tcx>, }, #[diag("invalid monomorphization of `{$name}` intrinsic: unsupported operation on `{$in_ty}` with element `{$in_elem}`", code = E0511)] UnsupportedOperation { #[primary_span] span: Span, name: Symbol, in_ty: Ty<'tcx>, in_elem: Ty<'tcx>, }, #[diag("invalid monomorphization of `{$name}` intrinsic: expected element type `{$expected_element}` of vector type `{$vector_type}` to be a signed or unsigned integer type", code = E0511)] ExpectedVectorElementType { #[primary_span] span: Span, name: Symbol, expected_element: Ty<'tcx>, vector_type: Ty<'tcx>, }, #[diag("invalid monomorphization of `{$name}` intrinsic: expected non-scalable type, found scalable type `{$ty}`", code = E0511)] NonScalableType { #[primary_span] span: Span, name: Symbol, ty: Ty<'tcx>, }, } pub enum ExpectedPointerMutability { Mut, Not, } impl IntoDiagArg for ExpectedPointerMutability { fn into_diag_arg(self, _: &mut Option) -> DiagArgValue { match self { ExpectedPointerMutability::Mut => DiagArgValue::Str(Cow::Borrowed("*mut")), ExpectedPointerMutability::Not => DiagArgValue::Str(Cow::Borrowed("*_")), } } } #[derive(Diagnostic)] #[diag("`#[target_feature(..)]` cannot be applied to safe trait method")] pub(crate) struct TargetFeatureSafeTrait { #[primary_span] #[label("cannot be applied to safe trait method")] pub span: Span, #[label("not an `unsafe` function")] pub def: Span, } #[derive(Diagnostic)] #[diag("target feature `{$feature}` cannot be enabled with `#[target_feature]`: {$reason}")] pub struct ForbiddenTargetFeatureAttr<'a> { #[primary_span] pub span: Span, pub feature: &'a str, pub reason: &'a str, } #[derive(Diagnostic)] #[diag("failed to get layout for {$ty}: {$err}")] pub struct FailedToGetLayout<'tcx> { #[primary_span] pub span: Span, pub ty: Ty<'tcx>, pub err: LayoutError<'tcx>, } #[derive(Diagnostic)] #[diag( "dlltool could not create import library with {$dlltool_path} {$dlltool_args}: {$stdout} {$stderr}" )] pub(crate) struct DlltoolFailImportLibrary<'a> { pub dlltool_path: Cow<'a, str>, pub dlltool_args: String, pub stdout: Cow<'a, str>, pub stderr: Cow<'a, str>, } #[derive(Diagnostic)] #[diag("error writing .DEF file: {$error}")] pub(crate) struct ErrorWritingDEFFile { pub error: std::io::Error, } #[derive(Diagnostic)] #[diag("error calling dlltool '{$dlltool_path}': {$error}")] pub(crate) struct ErrorCallingDllTool<'a> { pub dlltool_path: Cow<'a, str>, pub error: std::io::Error, } #[derive(Diagnostic)] #[diag("failed to create remark directory: {$error}")] pub(crate) struct ErrorCreatingRemarkDir { pub error: std::io::Error, } #[derive(Diagnostic)] #[diag( "`compiler_builtins` cannot call functions through upstream monomorphizations; encountered invalid call from `{$caller}` to `{$callee}`" )] pub struct CompilerBuiltinsCannotCall { pub caller: String, pub callee: String, #[primary_span] pub span: Span, } #[derive(Diagnostic)] #[diag("error creating import library for {$lib_name}: {$error}")] pub(crate) struct ErrorCreatingImportLibrary<'a> { pub lib_name: &'a str, pub error: String, } #[derive(Diagnostic)] #[diag("using host's `strip` binary to cross-compile to AIX which is not guaranteed to work")] pub(crate) struct AixStripNotUsed; #[derive(Diagnostic, Debug)] pub(crate) enum XcrunError { #[diag("invoking `{$command_formatted}` to find {$sdk_name}.sdk failed: {$error}")] FailedInvoking { sdk_name: &'static str, command_formatted: String, error: std::io::Error }, #[diag("failed running `{$command_formatted}` to find {$sdk_name}.sdk")] #[note("{$stdout}{$stderr}")] Unsuccessful { sdk_name: &'static str, command_formatted: String, stdout: String, stderr: String, }, } #[derive(Diagnostic, Debug)] #[diag("output of `xcrun` while finding {$sdk_name}.sdk")] #[note("{$stderr}")] pub(crate) struct XcrunSdkPathWarning { pub sdk_name: &'static str, pub stderr: String, } #[derive(Diagnostic)] #[diag("enabling the `neon` target feature on the current target is unsound due to ABI issues")] pub(crate) struct Aarch64SoftfloatNeon; #[derive(Diagnostic)] #[diag("unknown feature specified for `-Ctarget-feature`: `{$feature}`")] #[note("features must begin with a `+` to enable or `-` to disable it")] pub(crate) struct UnknownCTargetFeaturePrefix<'a> { pub feature: &'a str, } #[derive(Subdiagnostic)] pub(crate) enum PossibleFeature<'a> { #[help("you might have meant: `{$rust_feature}`")] Some { rust_feature: &'a str }, #[help("consider filing a feature request")] None, } #[derive(Diagnostic)] #[diag("unknown and unstable feature specified for `-Ctarget-feature`: `{$feature}`")] #[note( "it is still passed through to the codegen backend, but use of this feature might be unsound and the behavior of this feature can change in the future" )] pub(crate) struct UnknownCTargetFeature<'a> { pub feature: &'a str, #[subdiagnostic] pub rust_feature: PossibleFeature<'a>, } #[derive(Diagnostic)] #[diag("unstable feature specified for `-Ctarget-feature`: `{$feature}`")] #[note("this feature is not stably supported; its behavior can change in the future")] pub(crate) struct UnstableCTargetFeature<'a> { pub feature: &'a str, } #[derive(Diagnostic)] #[diag("target feature `{$feature}` cannot be {$enabled} with `-Ctarget-feature`: {$reason}")] #[note( "this was previously accepted by the compiler but is being phased out; it will become a hard error in a future release!" )] #[note("for more information, see issue #116344 ")] pub(crate) struct ForbiddenCTargetFeature<'a> { pub feature: &'a str, pub enabled: &'a str, pub reason: &'a str, } pub struct TargetFeatureDisableOrEnable<'a> { pub features: &'a [&'a str], pub span: Option, pub missing_features: Option, } #[derive(Subdiagnostic)] #[help("add the missing features in a `target_feature` attribute")] pub struct MissingFeatures; impl Diagnostic<'_, G> for TargetFeatureDisableOrEnable<'_> { fn into_diag(self, dcx: DiagCtxtHandle<'_>, level: Level) -> Diag<'_, G> { let mut diag = Diag::new( dcx, level, msg!("the target features {$features} must all be either enabled or disabled together"), ); if let Some(span) = self.span { diag.span(span); }; if let Some(missing_features) = self.missing_features { diag.subdiagnostic(missing_features); } diag.arg("features", self.features.join(", ")); diag } } #[derive(Diagnostic)] #[diag("the feature named `{$feature}` is not valid for this target")] pub(crate) struct FeatureNotValid<'a> { pub feature: &'a str, #[primary_span] #[label("`{$feature}` is not valid for this target")] pub span: Span, #[help("consider removing the leading `+` in the feature name")] pub plus_hint: bool, } #[derive(Diagnostic)] #[diag("lto can only be run for executables, cdylibs and static library outputs")] pub(crate) struct LtoDisallowed; #[derive(Diagnostic)] #[diag("lto cannot be used for `dylib` crate type without `-Zdylib-lto`")] pub(crate) struct LtoDylib; #[derive(Diagnostic)] #[diag("lto cannot be used for `proc-macro` crate type without `-Zdylib-lto`")] pub(crate) struct LtoProcMacro; #[derive(Diagnostic)] #[diag("cannot prefer dynamic linking when performing LTO")] #[note("only 'staticlib', 'bin', and 'cdylib' outputs are supported with LTO")] pub(crate) struct DynamicLinkingWithLTO;