vendor/gimli/examples/simple_line.rs - toolchain/rustc - Git at Google

 //! A simple example of parsing `.debug_line`.

 use object::{Object, ObjectSection};
 use std::{borrow, env, fs, path};

 fn main() {
     for path in env::args().skip(1) {
         let file = fs::File::open(&path).unwrap();
         let mmap = unsafe { memmap::Mmap::map(&file).unwrap() };
         let object = object::File::parse(&*mmap).unwrap();
         let endian = if object.is_little_endian() {
             gimli::RunTimeEndian::Little
         } else {
             gimli::RunTimeEndian::Big
         };
         dump_file(&object, endian).unwrap();
     }
 }

 fn dump_file(object: &object::File, endian: gimli::RunTimeEndian) -> Result<(), gimli::Error> {
     // Load a section and return as `Cow<[u8]>`.
     let load_section = |id: gimli::SectionId| -> Result<borrow::Cow<[u8]>, gimli::Error> {
         match object.section_by_name(id.name()) {
             Some(ref section) => Ok(section
                 .uncompressed_data()
                 .unwrap_or(borrow::Cow::Borrowed(&[][..]))),
             None => Ok(borrow::Cow::Borrowed(&[][..])),
         }
     };
     // Load a supplementary section. We don't have a supplementary object file,
     // so always return an empty slice.
     let load_section_sup = |_| Ok(borrow::Cow::Borrowed(&[][..]));

     // Load all of the sections.
     let dwarf_cow = gimli::Dwarf::load(&load_section, &load_section_sup)?;

     // Borrow a `Cow<[u8]>` to create an `EndianSlice`.
     let borrow_section: &dyn for<'a> Fn(
         &'a borrow::Cow<[u8]>,
     ) -> gimli::EndianSlice<'a, gimli::RunTimeEndian> =
         &|section| gimli::EndianSlice::new(&*section, endian);

     // Create `EndianSlice`s for all of the sections.
     let dwarf = dwarf_cow.borrow(&borrow_section);

     // Iterate over the compilation units.
     let mut iter = dwarf.units();
     while let Some(header) = iter.next()? {
         println!(
             "Line number info for unit at <.debug_info+0x{:x}>",
             header.offset().0
         );
         let unit = dwarf.unit(header)?;

         // Get the line program for the compilation unit.
         if let Some(program) = unit.line_program.clone() {
             let comp_dir = if let Some(ref dir) = unit.comp_dir {
                 path::PathBuf::from(dir.to_string_lossy().into_owned())
             } else {
                 path::PathBuf::new()
             };

             // Iterate over the line program rows.
             let mut rows = program.rows();
             while let Some((header, row)) = rows.next_row()? {
                 if row.end_sequence() {
                     // End of sequence indicates a possible gap in addresses.
                     println!("{:x} end-sequence", row.address());
                 } else {
                     // Determine the path. Real applications should cache this for performance.
                     let mut path = path::PathBuf::new();
                     if let Some(file) = row.file(header) {
                         path = comp_dir.clone();
                         if let Some(dir) = file.directory(header) {
                             path.push(dwarf.attr_string(&unit, dir)?.to_string_lossy().as_ref());
                         }
                         path.push(
                             dwarf
                                 .attr_string(&unit, file.path_name())?
                                 .to_string_lossy()
                                 .as_ref(),
                         );
                     }

                     // Determine line/column. DWARF line/column is never 0, so we use that
                     // but other applications may want to display this differently.
                     let line = row.line().unwrap_or(0);
                     let column = match row.column() {
                         gimli::ColumnType::LeftEdge => 0,
                         gimli::ColumnType::Column(x) => x,
                     };

                     println!("{:x} {}:{}:{}", row.address(), path.display(), line, column);
                 }
             }
         }
     }
     Ok(())
 }
	//! A simple example of parsing `.debug_line`.

	use object::{Object, ObjectSection};
	use std::{borrow, env, fs, path};

	fn main() {
	for path in env::args().skip(1) {
	let file = fs::File::open(&path).unwrap();
	let mmap = unsafe { memmap::Mmap::map(&file).unwrap() };
	let object = object::File::parse(&*mmap).unwrap();
	let endian = if object.is_little_endian() {
	gimli::RunTimeEndian::Little
	} else {
	gimli::RunTimeEndian::Big
	};
	dump_file(&object, endian).unwrap();
	}
	}

	fn dump_file(object: &object::File, endian: gimli::RunTimeEndian) -> Result<(), gimli::Error> {
	// Load a section and return as `Cow<[u8]>`.
	let load_section = \|id: gimli::SectionId\| -> Result<borrow::Cow<[u8]>, gimli::Error> {
	match object.section_by_name(id.name()) {
	Some(ref section) => Ok(section
	.uncompressed_data()
	.unwrap_or(borrow::Cow::Borrowed(&[][..]))),
	None => Ok(borrow::Cow::Borrowed(&[][..])),
	}
	};
	// Load a supplementary section. We don't have a supplementary object file,
	// so always return an empty slice.
	let load_section_sup = \|_\| Ok(borrow::Cow::Borrowed(&[][..]));

	// Load all of the sections.
	let dwarf_cow = gimli::Dwarf::load(&load_section, &load_section_sup)?;

	// Borrow a `Cow<[u8]>` to create an `EndianSlice`.
	let borrow_section: &dyn for<'a> Fn(
	&'a borrow::Cow<[u8]>,
	) -> gimli::EndianSlice<'a, gimli::RunTimeEndian> =
	&\|section\| gimli::EndianSlice::new(&*section, endian);

	// Create `EndianSlice`s for all of the sections.
	let dwarf = dwarf_cow.borrow(&borrow_section);

	// Iterate over the compilation units.
	let mut iter = dwarf.units();
	while let Some(header) = iter.next()? {
	println!(
	"Line number info for unit at <.debug_info+0x{:x}>",
	header.offset().0
	);
	let unit = dwarf.unit(header)?;

	// Get the line program for the compilation unit.
	if let Some(program) = unit.line_program.clone() {
	let comp_dir = if let Some(ref dir) = unit.comp_dir {
	path::PathBuf::from(dir.to_string_lossy().into_owned())
	} else {
	path::PathBuf::new()
	};

	// Iterate over the line program rows.
	let mut rows = program.rows();
	while let Some((header, row)) = rows.next_row()? {
	if row.end_sequence() {
	// End of sequence indicates a possible gap in addresses.
	println!("{:x} end-sequence", row.address());
	} else {
	// Determine the path. Real applications should cache this for performance.
	let mut path = path::PathBuf::new();
	if let Some(file) = row.file(header) {
	path = comp_dir.clone();
	if let Some(dir) = file.directory(header) {
	path.push(dwarf.attr_string(&unit, dir)?.to_string_lossy().as_ref());
	}
	path.push(
	dwarf
	.attr_string(&unit, file.path_name())?
	.to_string_lossy()
	.as_ref(),
	);
	}

	// Determine line/column. DWARF line/column is never 0, so we use that
	// but other applications may want to display this differently.
	let line = row.line().unwrap_or(0);
	let column = match row.column() {
	gimli::ColumnType::LeftEdge => 0,
	gimli::ColumnType::Column(x) => x,
	};

	println!("{:x} {}:{}:{}", row.address(), path.display(), line, column);
	}
	}
	}
	}
	Ok(())
	}