compiler/rustc_session/src/output.rs - toolchain/rustc - Git at Google

 //! Related to out filenames of compilation (e.g. binaries).
 use crate::config::{self, CrateType, Input, OutFileName, OutputFilenames, OutputType};
 use crate::errors::{
     self, CrateNameDoesNotMatch, CrateNameEmpty, CrateNameInvalid, FileIsNotWriteable,
     InvalidCharacterInCrateName, InvalidCrateNameHelp,
 };
 use crate::Session;
 use rustc_ast::{self as ast, attr};
 use rustc_errors::FatalError;
 use rustc_span::symbol::sym;
 use rustc_span::{Span, Symbol};
 use std::path::Path;

 pub fn out_filename(
     sess: &Session,
     crate_type: CrateType,
     outputs: &OutputFilenames,
     crate_name: Symbol,
 ) -> OutFileName {
     let default_filename = filename_for_input(sess, crate_type, crate_name, outputs);
     let out_filename = outputs
         .outputs
         .get(&OutputType::Exe)
         .and_then(|s| s.to_owned())
         .or_else(|| outputs.single_output_file.clone())
         .unwrap_or(default_filename);

     if let OutFileName::Real(ref path) = out_filename {
         check_file_is_writeable(path, sess);
     }

     out_filename
 }

 /// Make sure files are writeable. Mac, FreeBSD, and Windows system linkers
 /// check this already -- however, the Linux linker will happily overwrite a
 /// read-only file. We should be consistent.
 pub fn check_file_is_writeable(file: &Path, sess: &Session) {
     if !is_writeable(file) {
         sess.dcx().emit_fatal(FileIsNotWriteable { file });
     }
 }

 fn is_writeable(p: &Path) -> bool {
     match p.metadata() {
         Err(..) => true,
         Ok(m) => !m.permissions().readonly(),
     }
 }

 pub fn find_crate_name(sess: &Session, attrs: &[ast::Attribute]) -> Symbol {
     let validate = |s: Symbol, span: Option<Span>| {
         validate_crate_name(sess, s, span);
         s
     };

     // Look in attributes 100% of the time to make sure the attribute is marked
     // as used. After doing this, however, we still prioritize a crate name from
     // the command line over one found in the #[crate_name] attribute. If we
     // find both we ensure that they're the same later on as well.
     let attr_crate_name =
         attr::find_by_name(attrs, sym::crate_name).and_then(|at| at.value_str().map(|s| (at, s)));

     if let Some(ref s) = sess.opts.crate_name {
         let s = Symbol::intern(s);
         if let Some((attr, name)) = attr_crate_name {
             if name != s {
                 sess.dcx().emit_err(CrateNameDoesNotMatch { span: attr.span, s, name });
             }
         }
         return validate(s, None);
     }

     if let Some((attr, s)) = attr_crate_name {
         return validate(s, Some(attr.span));
     }
     if let Input::File(ref path) = sess.io.input {
         if let Some(s) = path.file_stem().and_then(|s| s.to_str()) {
             if s.starts_with('-') {
                 sess.dcx().emit_err(CrateNameInvalid { s });
             } else {
                 return validate(Symbol::intern(&s.replace('-', "_")), None);
             }
         }
     }

     Symbol::intern("rust_out")
 }

 pub fn validate_crate_name(sess: &Session, s: Symbol, sp: Option<Span>) {
     let mut err_count = 0;
     {
         if s.is_empty() {
             err_count += 1;
             sess.dcx().emit_err(CrateNameEmpty { span: sp });
         }
         for c in s.as_str().chars() {
             if c.is_alphanumeric() {
                 continue;
             }
             if c == '_' {
                 continue;
             }
             err_count += 1;
             sess.dcx().emit_err(InvalidCharacterInCrateName {
                 span: sp,
                 character: c,
                 crate_name: s,
                 crate_name_help: if sp.is_none() {
                     Some(InvalidCrateNameHelp::AddCrateName)
                 } else {
                     None
                 },
             });
         }
     }

     if err_count > 0 {
         FatalError.raise();
     }
 }

 pub fn filename_for_metadata(sess: &Session, outputs: &OutputFilenames) -> OutFileName {
     let out_filename = outputs.path(OutputType::Metadata);
     if let OutFileName::Real(ref path) = out_filename {
         check_file_is_writeable(path, sess);
     }
     out_filename
 }

 pub fn filename_for_input(
     sess: &Session,
     crate_type: CrateType,
     crate_name: Symbol,
     outputs: &OutputFilenames,
 ) -> OutFileName {
     let libname = format!("{}{}", crate_name, sess.opts.cg.extra_filename);

     match crate_type {
         CrateType::Rlib => {
             OutFileName::Real(outputs.out_directory.join(&format!("lib{libname}.rlib")))
         }
         CrateType::Cdylib | CrateType::ProcMacro | CrateType::Dylib => {
             let (prefix, suffix) = (&sess.target.dll_prefix, &sess.target.dll_suffix);
             OutFileName::Real(outputs.out_directory.join(&format!("{prefix}{libname}{suffix}")))
         }
         CrateType::Staticlib => {
             let (prefix, suffix) = (&sess.target.staticlib_prefix, &sess.target.staticlib_suffix);
             OutFileName::Real(outputs.out_directory.join(&format!("{prefix}{libname}{suffix}")))
         }
         CrateType::Executable => {
             let suffix = &sess.target.exe_suffix;
             let out_filename = outputs.path(OutputType::Exe);
             if let OutFileName::Real(ref path) = out_filename {
                 if suffix.is_empty() {
                     out_filename
                 } else {
                     OutFileName::Real(path.with_extension(&suffix[1..]))
                 }
             } else {
                 out_filename
             }
         }
     }
 }

 /// Returns default crate type for target
 ///
 /// Default crate type is used when crate type isn't provided neither
 /// through cmd line arguments nor through crate attributes
 ///
 /// It is CrateType::Executable for all platforms but iOS as there is no
 /// way to run iOS binaries anyway without jailbreaking and
 /// interaction with Rust code through static library is the only
 /// option for now
 pub fn default_output_for_target(sess: &Session) -> CrateType {
     if !sess.target.executables { CrateType::Staticlib } else { CrateType::Executable }
 }

 /// Checks if target supports crate_type as output
 pub fn invalid_output_for_target(sess: &Session, crate_type: CrateType) -> bool {
     if let CrateType::Cdylib | CrateType::Dylib | CrateType::ProcMacro = crate_type {
         if !sess.target.dynamic_linking {
             return true;
         }
         if sess.crt_static(Some(crate_type)) && !sess.target.crt_static_allows_dylibs {
             return true;
         }
     }
     if let CrateType::ProcMacro | CrateType::Dylib = crate_type
         && sess.target.only_cdylib
     {
         return true;
     }
     if let CrateType::Executable = crate_type
         && !sess.target.executables
     {
         return true;
     }

     false
 }

 pub const CRATE_TYPES: &[(Symbol, CrateType)] = &[
     (sym::rlib, CrateType::Rlib),
     (sym::dylib, CrateType::Dylib),
     (sym::cdylib, CrateType::Cdylib),
     (sym::lib, config::default_lib_output()),
     (sym::staticlib, CrateType::Staticlib),
     (sym::proc_dash_macro, CrateType::ProcMacro),
     (sym::bin, CrateType::Executable),
 ];

 pub fn categorize_crate_type(s: Symbol) -> Option<CrateType> {
     Some(CRATE_TYPES.iter().find(|(key, _)| *key == s)?.1)
 }

 pub fn collect_crate_types(session: &Session, attrs: &[ast::Attribute]) -> Vec<CrateType> {
     // If we're generating a test executable, then ignore all other output
     // styles at all other locations
     if session.opts.test {
         return vec![CrateType::Executable];
     }

     // Only check command line flags if present. If no types are specified by
     // command line, then reuse the empty `base` Vec to hold the types that
     // will be found in crate attributes.
     // JUSTIFICATION: before wrapper fn is available
     #[allow(rustc::bad_opt_access)]
     let mut base = session.opts.crate_types.clone();
     if base.is_empty() {
         let attr_types = attrs.iter().filter_map(|a| {
             if a.has_name(sym::crate_type)
                 && let Some(s) = a.value_str()
             {
                 categorize_crate_type(s)
             } else {
                 None
             }
         });
         base.extend(attr_types);
         if base.is_empty() {
             base.push(default_output_for_target(session));
         } else {
             base.sort();
             base.dedup();
         }
     }

     base.retain(|crate_type| {
         if invalid_output_for_target(session, *crate_type) {
             session.dcx().emit_warn(errors::UnsupportedCrateTypeForTarget {
                 crate_type: *crate_type,
                 target_triple: &session.opts.target_triple,
             });
             false
         } else {
             true
         }
     });

     base
 }
	//! Related to out filenames of compilation (e.g. binaries).
	use crate::config::{self, CrateType, Input, OutFileName, OutputFilenames, OutputType};
	use crate::errors::{
	self, CrateNameDoesNotMatch, CrateNameEmpty, CrateNameInvalid, FileIsNotWriteable,
	InvalidCharacterInCrateName, InvalidCrateNameHelp,
	};
	use crate::Session;
	use rustc_ast::{self as ast, attr};
	use rustc_errors::FatalError;
	use rustc_span::symbol::sym;
	use rustc_span::{Span, Symbol};
	use std::path::Path;

	pub fn out_filename(
	sess: &Session,
	crate_type: CrateType,
	outputs: &OutputFilenames,
	crate_name: Symbol,
	) -> OutFileName {
	let default_filename = filename_for_input(sess, crate_type, crate_name, outputs);
	let out_filename = outputs
	.outputs
	.get(&OutputType::Exe)
	.and_then(\|s\| s.to_owned())
	.or_else(\|\| outputs.single_output_file.clone())
	.unwrap_or(default_filename);

	if let OutFileName::Real(ref path) = out_filename {
	check_file_is_writeable(path, sess);
	}

	out_filename
	}

	/// Make sure files are writeable. Mac, FreeBSD, and Windows system linkers
	/// check this already -- however, the Linux linker will happily overwrite a
	/// read-only file. We should be consistent.
	pub fn check_file_is_writeable(file: &Path, sess: &Session) {
	if !is_writeable(file) {
	sess.dcx().emit_fatal(FileIsNotWriteable { file });
	}
	}

	fn is_writeable(p: &Path) -> bool {
	match p.metadata() {
	Err(..) => true,
	Ok(m) => !m.permissions().readonly(),
	}
	}

	pub fn find_crate_name(sess: &Session, attrs: &[ast::Attribute]) -> Symbol {
	let validate = \|s: Symbol, span: Option<Span>\| {
	validate_crate_name(sess, s, span);
	s
	};

	// Look in attributes 100% of the time to make sure the attribute is marked
	// as used. After doing this, however, we still prioritize a crate name from
	// the command line over one found in the #[crate_name] attribute. If we
	// find both we ensure that they're the same later on as well.
	let attr_crate_name =
	attr::find_by_name(attrs, sym::crate_name).and_then(\|at\| at.value_str().map(\|s\| (at, s)));

	if let Some(ref s) = sess.opts.crate_name {
	let s = Symbol::intern(s);
	if let Some((attr, name)) = attr_crate_name {
	if name != s {
	sess.dcx().emit_err(CrateNameDoesNotMatch { span: attr.span, s, name });
	}
	}
	return validate(s, None);
	}

	if let Some((attr, s)) = attr_crate_name {
	return validate(s, Some(attr.span));
	}
	if let Input::File(ref path) = sess.io.input {
	if let Some(s) = path.file_stem().and_then(\|s\| s.to_str()) {
	if s.starts_with('-') {
	sess.dcx().emit_err(CrateNameInvalid { s });
	} else {
	return validate(Symbol::intern(&s.replace('-', "_")), None);
	}
	}
	}

	Symbol::intern("rust_out")
	}

	pub fn validate_crate_name(sess: &Session, s: Symbol, sp: Option<Span>) {
	let mut err_count = 0;
	{
	if s.is_empty() {
	err_count += 1;
	sess.dcx().emit_err(CrateNameEmpty { span: sp });
	}
	for c in s.as_str().chars() {
	if c.is_alphanumeric() {
	continue;
	}
	if c == '_' {
	continue;
	}
	err_count += 1;
	sess.dcx().emit_err(InvalidCharacterInCrateName {
	span: sp,
	character: c,
	crate_name: s,
	crate_name_help: if sp.is_none() {
	Some(InvalidCrateNameHelp::AddCrateName)
	} else {
	None
	},
	});
	}
	}

	if err_count > 0 {
	FatalError.raise();
	}
	}

	pub fn filename_for_metadata(sess: &Session, outputs: &OutputFilenames) -> OutFileName {
	let out_filename = outputs.path(OutputType::Metadata);
	if let OutFileName::Real(ref path) = out_filename {
	check_file_is_writeable(path, sess);
	}
	out_filename
	}

	pub fn filename_for_input(
	sess: &Session,
	crate_type: CrateType,
	crate_name: Symbol,
	outputs: &OutputFilenames,
	) -> OutFileName {
	let libname = format!("{}{}", crate_name, sess.opts.cg.extra_filename);

	match crate_type {
	CrateType::Rlib => {
	OutFileName::Real(outputs.out_directory.join(&format!("lib{libname}.rlib")))
	}
	CrateType::Cdylib \| CrateType::ProcMacro \| CrateType::Dylib => {
	let (prefix, suffix) = (&sess.target.dll_prefix, &sess.target.dll_suffix);
	OutFileName::Real(outputs.out_directory.join(&format!("{prefix}{libname}{suffix}")))
	}
	CrateType::Staticlib => {
	let (prefix, suffix) = (&sess.target.staticlib_prefix, &sess.target.staticlib_suffix);
	OutFileName::Real(outputs.out_directory.join(&format!("{prefix}{libname}{suffix}")))
	}
	CrateType::Executable => {
	let suffix = &sess.target.exe_suffix;
	let out_filename = outputs.path(OutputType::Exe);
	if let OutFileName::Real(ref path) = out_filename {
	if suffix.is_empty() {
	out_filename
	} else {
	OutFileName::Real(path.with_extension(&suffix[1..]))
	}
	} else {
	out_filename
	}
	}
	}
	}

	/// Returns default crate type for target
	///
	/// Default crate type is used when crate type isn't provided neither
	/// through cmd line arguments nor through crate attributes
	///
	/// It is CrateType::Executable for all platforms but iOS as there is no
	/// way to run iOS binaries anyway without jailbreaking and
	/// interaction with Rust code through static library is the only
	/// option for now
	pub fn default_output_for_target(sess: &Session) -> CrateType {
	if !sess.target.executables { CrateType::Staticlib } else { CrateType::Executable }
	}

	/// Checks if target supports crate_type as output
	pub fn invalid_output_for_target(sess: &Session, crate_type: CrateType) -> bool {
	if let CrateType::Cdylib \| CrateType::Dylib \| CrateType::ProcMacro = crate_type {
	if !sess.target.dynamic_linking {
	return true;
	}
	if sess.crt_static(Some(crate_type)) && !sess.target.crt_static_allows_dylibs {
	return true;
	}
	}
	if let CrateType::ProcMacro \| CrateType::Dylib = crate_type
	&& sess.target.only_cdylib
	{
	return true;
	}
	if let CrateType::Executable = crate_type
	&& !sess.target.executables
	{
	return true;
	}

	false
	}

	pub const CRATE_TYPES: &[(Symbol, CrateType)] = &[
	(sym::rlib, CrateType::Rlib),
	(sym::dylib, CrateType::Dylib),
	(sym::cdylib, CrateType::Cdylib),
	(sym::lib, config::default_lib_output()),
	(sym::staticlib, CrateType::Staticlib),
	(sym::proc_dash_macro, CrateType::ProcMacro),
	(sym::bin, CrateType::Executable),
	];

	pub fn categorize_crate_type(s: Symbol) -> Option<CrateType> {
	Some(CRATE_TYPES.iter().find(\|(key, _)\| *key == s)?.1)
	}

	pub fn collect_crate_types(session: &Session, attrs: &[ast::Attribute]) -> Vec<CrateType> {
	// If we're generating a test executable, then ignore all other output
	// styles at all other locations
	if session.opts.test {
	return vec![CrateType::Executable];
	}

	// Only check command line flags if present. If no types are specified by
	// command line, then reuse the empty `base` Vec to hold the types that
	// will be found in crate attributes.
	// JUSTIFICATION: before wrapper fn is available
	#[allow(rustc::bad_opt_access)]
	let mut base = session.opts.crate_types.clone();
	if base.is_empty() {
	let attr_types = attrs.iter().filter_map(\|a\| {
	if a.has_name(sym::crate_type)
	&& let Some(s) = a.value_str()
	{
	categorize_crate_type(s)
	} else {
	None
	}
	});
	base.extend(attr_types);
	if base.is_empty() {
	base.push(default_output_for_target(session));
	} else {
	base.sort();
	base.dedup();
	}
	}

	base.retain(\|crate_type\| {
	if invalid_output_for_target(session, *crate_type) {
	session.dcx().emit_warn(errors::UnsupportedCrateTypeForTarget {
	crate_type: *crate_type,
	target_triple: &session.opts.target_triple,
	});
	false
	} else {
	true
	}
	});

	base
	}