/// The raw contents of the `.debug_loc` section. #[derive(Debug, Default, Clone, Copy)] pubstruct DebugLoc<R> { pub(crate) section: R,
}
impl<'input, Endian> DebugLoc<EndianSlice<'input, Endian>> where
Endian: Endianity,
{ /// Construct a new `DebugLoc` instance from the data in the `.debug_loc` /// section. /// /// It is the caller's responsibility to read the `.debug_loc` section and /// present it as a `&[u8]` slice. That means using some ELF loader on /// Linux, a Mach-O loader on macOS, etc. /// /// ``` /// use gimli::{DebugLoc, LittleEndian}; /// /// # let buf = [0x00, 0x01, 0x02, 0x03]; /// # let read_debug_loc_section_somehow = || &buf; /// let debug_loc = DebugLoc::new(read_debug_loc_section_somehow(), LittleEndian); /// ``` pubfn new(section: &'input [u8], endian: Endian) -> Self { Self::from(EndianSlice::new(section, endian))
}
}
impl<T> DebugLoc<T> { /// Create a `DebugLoc` section that references the data in `self`. /// /// This is useful when `R` implements `Reader` but `T` does not. /// /// Used by `DwarfSections::borrow`. pub(crate) fn borrow<'a, F, R>(&'a self, mut borrow: F) -> DebugLoc<R> where
F: FnMut(&'a T) -> R,
{
borrow(&self.section).into()
}
}
/// The `DebugLocLists` struct represents the DWARF data /// found in the `.debug_loclists` section. #[derive(Debug, Default, Clone, Copy)] pubstruct DebugLocLists<R> {
section: R,
}
impl<'input, Endian> DebugLocLists<EndianSlice<'input, Endian>> where
Endian: Endianity,
{ /// Construct a new `DebugLocLists` instance from the data in the `.debug_loclists` /// section. /// /// It is the caller's responsibility to read the `.debug_loclists` section and /// present it as a `&[u8]` slice. That means using some ELF loader on /// Linux, a Mach-O loader on macOS, etc. /// /// ``` /// use gimli::{DebugLocLists, LittleEndian}; /// /// # let buf = [0x00, 0x01, 0x02, 0x03]; /// # let read_debug_loclists_section_somehow = || &buf; /// let debug_loclists = DebugLocLists::new(read_debug_loclists_section_somehow(), LittleEndian); /// ``` pubfn new(section: &'input [u8], endian: Endian) -> Self { Self::from(EndianSlice::new(section, endian))
}
}
impl<T> DebugLocLists<T> { /// Create a `DebugLocLists` section that references the data in `self`. /// /// This is useful when `R` implements `Reader` but `T` does not. /// /// Used by `DwarfSections::borrow`. pub(crate) fn borrow<'a, F, R>(&'a self, mut borrow: F) -> DebugLocLists<R> where
F: FnMut(&'a T) -> R,
{
borrow(&self.section).into()
}
}
impl<Offset> DebugLocListsBase<Offset> where
Offset: ReaderOffset,
{ /// Returns a `DebugLocListsBase` with the default value of DW_AT_loclists_base /// for the given `Encoding` and `DwarfFileType`. pubfn default_for_encoding_and_file(
encoding: Encoding,
file_type: DwarfFileType,
) -> DebugLocListsBase<Offset> { if encoding.version >= 5 && file_type == DwarfFileType::Dwo { // In .dwo files, the compiler omits the DW_AT_loclists_base attribute (because there is // only a single unit in the file) but we must skip past the header, which the attribute // would normally do for us.
DebugLocListsBase(Offset::from_u8(LocListsHeader::size_for_encoding(encoding)))
} else {
DebugLocListsBase(Offset::from_u8(0))
}
}
}
/// The DWARF data found in `.debug_loc` and `.debug_loclists` sections. #[derive(Debug, Default, Clone, Copy)] pubstruct LocationLists<R> {
debug_loc: DebugLoc<R>,
debug_loclists: DebugLocLists<R>,
}
impl<R> LocationLists<R> { /// Construct a new `LocationLists` instance from the data in the `.debug_loc` and /// `.debug_loclists` sections. pubfn new(debug_loc: DebugLoc<R>, debug_loclists: DebugLocLists<R>) -> LocationLists<R> {
LocationLists {
debug_loc,
debug_loclists,
}
}
}
impl<T> LocationLists<T> { /// Create a `LocationLists` that references the data in `self`. /// /// This is useful when `R` implements `Reader` but `T` does not. /// /// Used by `Dwarf::borrow`. pubfn borrow<'a, F, R>(&'a self, mut borrow: F) -> LocationLists<R> where
F: FnMut(&'a T) -> R,
{
LocationLists {
debug_loc: borrow(&self.debug_loc.section).into(),
debug_loclists: borrow(&self.debug_loclists.section).into(),
}
}
}
impl<R: Reader> LocationLists<R> { /// Iterate over the `LocationListEntry`s starting at the given offset. /// /// The `unit_encoding` must match the compilation unit that the /// offset was contained in. /// /// The `base_address` should be obtained from the `DW_AT_low_pc` attribute in the /// `DW_TAG_compile_unit` entry for the compilation unit that contains this location /// list. /// /// Can be [used with /// `FallibleIterator`](./index.html#using-with-fallibleiterator). pubfn locations(
&self,
offset: LocationListsOffset<R::Offset>,
unit_encoding: Encoding,
base_address: u64,
debug_addr: &DebugAddr<R>,
debug_addr_base: DebugAddrBase<R::Offset>,
) -> Result<LocListIter<R>> {
Ok(LocListIter::new( self.raw_locations(offset, unit_encoding)?,
base_address,
debug_addr.clone(),
debug_addr_base,
))
}
/// Similar to `locations`, but with special handling for .dwo files. /// This should only been used when this `LocationLists` was loaded from a /// .dwo file. pubfn locations_dwo(
&self,
offset: LocationListsOffset<R::Offset>,
unit_encoding: Encoding,
base_address: u64,
debug_addr: &DebugAddr<R>,
debug_addr_base: DebugAddrBase<R::Offset>,
) -> Result<LocListIter<R>> {
Ok(LocListIter::new( self.raw_locations_dwo(offset, unit_encoding)?,
base_address,
debug_addr.clone(),
debug_addr_base,
))
}
/// Iterate over the raw `LocationListEntry`s starting at the given offset. /// /// The `unit_encoding` must match the compilation unit that the /// offset was contained in. /// /// This iterator does not perform any processing of the location entries, /// such as handling base addresses. /// /// Can be [used with /// `FallibleIterator`](./index.html#using-with-fallibleiterator). pubfn raw_locations(
&self,
offset: LocationListsOffset<R::Offset>,
unit_encoding: Encoding,
) -> Result<RawLocListIter<R>> { let (mut input, format) = if unit_encoding.version <= 4 {
(self.debug_loc.section.clone(), LocListsFormat::Bare)
} else {
(self.debug_loclists.section.clone(), LocListsFormat::Lle)
};
input.skip(offset.0)?;
Ok(RawLocListIter::new(input, unit_encoding, format))
}
/// Similar to `raw_locations`, but with special handling for .dwo files. /// This should only been used when this `LocationLists` was loaded from a /// .dwo file. pubfn raw_locations_dwo(
&self,
offset: LocationListsOffset<R::Offset>,
unit_encoding: Encoding,
) -> Result<RawLocListIter<R>> { letmut input = if unit_encoding.version <= 4 { // In the GNU split dwarf extension the locations are present in the // .debug_loc section but are encoded with the DW_LLE values used // for the DWARF 5 .debug_loclists section. self.debug_loc.section.clone()
} else { self.debug_loclists.section.clone()
};
input.skip(offset.0)?;
Ok(RawLocListIter::new(
input,
unit_encoding,
LocListsFormat::Lle,
))
}
/// Returns the `.debug_loclists` offset at the given `base` and `index`. /// /// The `base` must be the `DW_AT_loclists_base` value from the compilation unit DIE. /// This is an offset that points to the first entry following the header. /// /// The `index` is the value of a `DW_FORM_loclistx` attribute. pubfn get_offset(
&self,
unit_encoding: Encoding,
base: DebugLocListsBase<R::Offset>,
index: DebugLocListsIndex<R::Offset>,
) -> Result<LocationListsOffset<R::Offset>> { let format = unit_encoding.format; let input = &mutself.debug_loclists.section.clone();
input.skip(base.0)?;
input.skip(R::Offset::from_u64(
index.0.into_u64() * u64::from(format.word_size()),
)?)?;
input
.read_offset(format)
.map(|x| LocationListsOffset(base.0 + x))
}
/// Call `Reader::lookup_offset_id` for each section, and return the first match. pubfn lookup_offset_id(&self, id: ReaderOffsetId) -> Option<(SectionId, R::Offset)> { self.debug_loc
.lookup_offset_id(id)
.or_else(|| self.debug_loclists.lookup_offset_id(id))
}
}
#[derive(Debug, Clone, Copy, PartialEq, Eq)] enum LocListsFormat { /// The bare location list format used before DWARF 5.
Bare, /// The DW_LLE encoded range list format used in DWARF 5 and the non-standard GNU /// split dwarf extension.
Lle,
}
/// A raw iterator over a location list. /// /// This iterator does not perform any processing of the location entries, /// such as handling base addresses. #[derive(Debug)] pubstruct RawLocListIter<R: Reader> {
input: R,
encoding: Encoding,
format: LocListsFormat,
}
/// A raw entry in .debug_loclists. #[derive(Clone, Debug)] pubenum RawLocListEntry<R: Reader> { /// A location from DWARF version <= 4.
AddressOrOffsetPair { /// Start of range. May be an address or an offset.
begin: u64, /// End of range. May be an address or an offset.
end: u64, /// expression
data: Expression<R>,
}, /// DW_LLE_base_address
BaseAddress { /// base address
addr: u64,
}, /// DW_LLE_base_addressx
BaseAddressx { /// base address
addr: DebugAddrIndex<R::Offset>,
}, /// DW_LLE_startx_endx
StartxEndx { /// start of range
begin: DebugAddrIndex<R::Offset>, /// end of range
end: DebugAddrIndex<R::Offset>, /// expression
data: Expression<R>,
}, /// DW_LLE_startx_length
StartxLength { /// start of range
begin: DebugAddrIndex<R::Offset>, /// length of range
length: u64, /// expression
data: Expression<R>,
}, /// DW_LLE_offset_pair
OffsetPair { /// start of range
begin: u64, /// end of range
end: u64, /// expression
data: Expression<R>,
}, /// DW_LLE_default_location
DefaultLocation { /// expression
data: Expression<R>,
}, /// DW_LLE_start_end
StartEnd { /// start of range
begin: u64, /// end of range
end: u64, /// expression
data: Expression<R>,
}, /// DW_LLE_start_length
StartLength { /// start of range
begin: u64, /// length of range
length: u64, /// expression
data: Expression<R>,
},
}
fn parse_data<R: Reader>(input: &mut R, encoding: Encoding) -> Result<Expression<R>> { if encoding.version >= 5 { let len = R::Offset::from_u64(input.read_uleb128()?)?;
Ok(Expression(input.split(len)?))
} else { // In the GNU split-dwarf extension this is a fixed 2 byte value. let len = R::Offset::from_u16(input.read_u16()?);
Ok(Expression(input.split(len)?))
}
}
impl<R: Reader> RawLocListEntry<R> { /// Parse a location list entry from `.debug_loclists` fn parse(input: &mut R, encoding: Encoding, format: LocListsFormat) -> Result<Option<Self>> {
Ok(match format {
LocListsFormat::Bare => { let range = RawRange::parse(input, encoding.address_size)?; if range.is_end() {
None
} elseif range.is_base_address(encoding.address_size) {
Some(RawLocListEntry::BaseAddress { addr: range.end })
} else { let len = R::Offset::from_u16(input.read_u16()?); let data = Expression(input.split(len)?);
Some(RawLocListEntry::AddressOrOffsetPair {
begin: range.begin,
end: range.end,
data,
})
}
}
LocListsFormat::Lle => match constants::DwLle(input.read_u8()?) {
constants::DW_LLE_end_of_list => None,
constants::DW_LLE_base_addressx => Some(RawLocListEntry::BaseAddressx {
addr: DebugAddrIndex(input.read_uleb128().and_then(R::Offset::from_u64)?),
}),
constants::DW_LLE_startx_endx => Some(RawLocListEntry::StartxEndx {
begin: DebugAddrIndex(input.read_uleb128().and_then(R::Offset::from_u64)?),
end: DebugAddrIndex(input.read_uleb128().and_then(R::Offset::from_u64)?),
data: parse_data(input, encoding)?,
}),
constants::DW_LLE_startx_length => Some(RawLocListEntry::StartxLength {
begin: DebugAddrIndex(input.read_uleb128().and_then(R::Offset::from_u64)?),
length: if encoding.version >= 5 {
input.read_uleb128()?
} else { // In the GNU split-dwarf extension this is a fixed 4 byte value.
input.read_u32()? as u64
},
data: parse_data(input, encoding)?,
}),
constants::DW_LLE_offset_pair => Some(RawLocListEntry::OffsetPair {
begin: input.read_uleb128()?,
end: input.read_uleb128()?,
data: parse_data(input, encoding)?,
}),
constants::DW_LLE_default_location => Some(RawLocListEntry::DefaultLocation {
data: parse_data(input, encoding)?,
}),
constants::DW_LLE_base_address => Some(RawLocListEntry::BaseAddress {
addr: input.read_address(encoding.address_size)?,
}),
constants::DW_LLE_start_end => Some(RawLocListEntry::StartEnd {
begin: input.read_address(encoding.address_size)?,
end: input.read_address(encoding.address_size)?,
data: parse_data(input, encoding)?,
}),
constants::DW_LLE_start_length => Some(RawLocListEntry::StartLength {
begin: input.read_address(encoding.address_size)?,
length: input.read_uleb128()?,
data: parse_data(input, encoding)?,
}),
entry => { return Err(Error::UnknownLocListsEntry(entry));
}
},
})
}
}
/// Advance the iterator to the next location. pubfn next(&mutself) -> Result<Option<RawLocListEntry<R>>> { ifself.input.is_empty() { return Ok(None);
}
/// An iterator over a location list. /// /// This iterator internally handles processing of base address selection entries /// and list end entries. Thus, it only returns location entries that are valid /// and already adjusted for the base address. #[derive(Debug)] pubstruct LocListIter<R: Reader> {
raw: RawLocListIter<R>,
base_address: u64,
debug_addr: DebugAddr<R>,
debug_addr_base: DebugAddrBase<R::Offset>,
}
/// Advance the iterator to the next location. pubfn next(&mutself) -> Result<Option<LocationListEntry<R>>> { loop { let raw_loc = matchself.raw.next()? {
Some(loc) => loc,
None => return Ok(None),
};
let loc = self.convert_raw(raw_loc)?; if loc.is_some() { return Ok(loc);
}
}
}
/// Return the next raw location. /// /// The raw location should be passed to `convert_raw`. #[doc(hidden)] pubfn next_raw(&mutself) -> Result<Option<RawLocListEntry<R>>> { self.raw.next()
}
/// Convert a raw location into a location, and update the state of the iterator. /// /// The raw location should have been obtained from `next_raw`. #[doc(hidden)] pubfn convert_raw(
&mutself,
raw_loc: RawLocListEntry<R>,
) -> Result<Option<LocationListEntry<R>>> { let mask = !0 >> (64 - self.raw.encoding.address_size * 8); let tombstone = ifself.raw.encoding.version <= 4 {
mask - 1
} else {
mask
};
let (range, data) = match raw_loc {
RawLocListEntry::BaseAddress { addr } => { self.base_address = addr; return Ok(None);
}
RawLocListEntry::BaseAddressx { addr } => { self.base_address = self.get_address(addr)?; return Ok(None);
}
RawLocListEntry::StartxEndx { begin, end, data } => { let begin = self.get_address(begin)?; let end = self.get_address(end)?;
(Range { begin, end }, data)
}
RawLocListEntry::StartxLength {
begin,
length,
data,
} => { let begin = self.get_address(begin)?; let end = begin.wrapping_add(length) & mask;
(Range { begin, end }, data)
}
RawLocListEntry::DefaultLocation { data } => (
Range {
begin: 0,
end: u64::max_value(),
},
data,
),
RawLocListEntry::AddressOrOffsetPair { begin, end, data }
| RawLocListEntry::OffsetPair { begin, end, data } => { ifself.base_address == tombstone { return Ok(None);
} letmut range = Range { begin, end };
range.add_base_address(self.base_address, self.raw.encoding.address_size);
(range, data)
}
RawLocListEntry::StartEnd { begin, end, data } => (Range { begin, end }, data),
RawLocListEntry::StartLength {
begin,
length,
data,
} => { let end = begin.wrapping_add(length) & mask;
(Range { begin, end }, data)
}
};
/// A location list entry from the `.debug_loc` or `.debug_loclists` sections. #[derive(Debug, Clone, Copy, PartialEq, Eq, Hash)] pubstruct LocationListEntry<R: Reader> { /// The address range that this location is valid for. pub range: Range,
/// The data containing a single location description. pub data: Expression<R>,
}
#[cfg(test)] mod tests { usesuper::*; usecrate::common::Format; usecrate::endianity::LittleEndian; usecrate::read::{EndianSlice, Range}; usecrate::test_util::GimliSectionMethods; use test_assembler::{Endian, Label, LabelMaker, Section};
#[test] fn test_loclists_32() { let tombstone = !0u32; let encoding = Encoding {
format: Format::Dwarf32,
version: 5,
address_size: 4,
};
let section = Section::with_endian(Endian::Little)
.L32(0x0300_0000)
.L32(0x0301_0300)
.L32(0x0301_0400)
.L32(0x0301_0500)
.L32(tombstone)
.L32(0x0301_0600); let buf = section.get_contents().unwrap(); let debug_addr = &DebugAddr::from(EndianSlice::new(&buf, LittleEndian)); let debug_addr_base = DebugAddrBase(0);
let start = Label::new(); let first = Label::new(); let size = Label::new(); #[rustfmt::skip] let section = Section::with_endian(Endian::Little) // Header
.mark(&start)
.L32(&size)
.L16(encoding.version)
.L8(encoding.address_size)
.L8(0)
.L32(0)
.mark(&first) // OffsetPair
.L8(4).uleb(0x10200).uleb(0x10300).uleb(4).L32(2) // A base address selection followed by an OffsetPair.
.L8(6).L32(0x0200_0000)
.L8(4).uleb(0x10400).uleb(0x10500).uleb(4).L32(3) // An empty OffsetPair followed by a normal OffsetPair.
.L8(4).uleb(0x10600).uleb(0x10600).uleb(4).L32(4)
.L8(4).uleb(0x10800).uleb(0x10900).uleb(4).L32(5) // A StartEnd
.L8(7).L32(0x201_0a00).L32(0x201_0b00).uleb(4).L32(6) // A StartLength
.L8(8).L32(0x201_0c00).uleb(0x100).uleb(4).L32(7) // An OffsetPair that starts at 0.
.L8(4).uleb(0).uleb(1).uleb(4).L32(8) // An OffsetPair that ends at -1.
.L8(6).L32(0)
.L8(4).uleb(0).uleb(0xffff_ffff).uleb(4).L32(9) // A DefaultLocation
.L8(5).uleb(4).L32(10) // A BaseAddressx + OffsetPair
.L8(1).uleb(0)
.L8(4).uleb(0x10100).uleb(0x10200).uleb(4).L32(11) // A StartxEndx
.L8(2).uleb(1).uleb(2).uleb(4).L32(12) // A StartxLength
.L8(3).uleb(3).uleb(0x100).uleb(4).L32(13)
// Tombstone entries, all of which should be ignored. // A BaseAddressx that is a tombstone.
.L8(1).uleb(4)
.L8(4).uleb(0x11100).uleb(0x11200).uleb(4).L32(20) // A BaseAddress that is a tombstone.
.L8(6).L32(tombstone)
.L8(4).uleb(0x11300).uleb(0x11400).uleb(4).L32(21) // A StartxEndx that is a tombstone.
.L8(2).uleb(4).uleb(5).uleb(4).L32(22) // A StartxLength that is a tombstone.
.L8(3).uleb(4).uleb(0x100).uleb(4).L32(23) // A StartEnd that is a tombstone.
.L8(7).L32(tombstone).L32(0x201_1500).uleb(4).L32(24) // A StartLength that is a tombstone.
.L8(8).L32(tombstone).uleb(0x100).uleb(4).L32(25) // A StartEnd (not ignored)
.L8(7).L32(0x201_1600).L32(0x201_1700).uleb(4).L32(26)
// A range end.
.L8(0) // Some extra data.
.L32(0xffff_ffff);
size.set_const((§ion.here() - &start - 4) as u64);
let buf = section.get_contents().unwrap(); let debug_loc = DebugLoc::new(&[], LittleEndian); let debug_loclists = DebugLocLists::new(&buf, LittleEndian); let loclists = LocationLists::new(debug_loc, debug_loclists); let offset = LocationListsOffset((&first - &start) as usize); letmut locations = loclists
.locations(offset, encoding, 0x0100_0000, debug_addr, debug_addr_base)
.unwrap();
// A normal location.
assert_eq!(
locations.next(),
Ok(Some(LocationListEntry {
range: Range {
begin: 0x0101_0200,
end: 0x0101_0300,
},
data: Expression(EndianSlice::new(&[2, 0, 0, 0], LittleEndian)),
}))
);
// A base address selection followed by a normal location.
assert_eq!(
locations.next(),
Ok(Some(LocationListEntry {
range: Range {
begin: 0x0201_0400,
end: 0x0201_0500,
},
data: Expression(EndianSlice::new(&[3, 0, 0, 0], LittleEndian)),
}))
);
// An empty location range followed by a normal location.
assert_eq!(
locations.next(),
Ok(Some(LocationListEntry {
range: Range {
begin: 0x0201_0600,
end: 0x0201_0600,
},
data: Expression(EndianSlice::new(&[4, 0, 0, 0], LittleEndian)),
}))
);
assert_eq!(
locations.next(),
Ok(Some(LocationListEntry {
range: Range {
begin: 0x0201_0800,
end: 0x0201_0900,
},
data: Expression(EndianSlice::new(&[5, 0, 0, 0], LittleEndian)),
}))
);
// A normal location.
assert_eq!(
locations.next(),
Ok(Some(LocationListEntry {
range: Range {
begin: 0x0201_0a00,
end: 0x0201_0b00,
},
data: Expression(EndianSlice::new(&[6, 0, 0, 0], LittleEndian)),
}))
);
// A normal location.
assert_eq!(
locations.next(),
Ok(Some(LocationListEntry {
range: Range {
begin: 0x0201_0c00,
end: 0x0201_0d00,
},
data: Expression(EndianSlice::new(&[7, 0, 0, 0], LittleEndian)),
}))
);
// A location range that starts at 0.
assert_eq!(
locations.next(),
Ok(Some(LocationListEntry {
range: Range {
begin: 0x0200_0000,
end: 0x0200_0001,
},
data: Expression(EndianSlice::new(&[8, 0, 0, 0], LittleEndian)),
}))
);
// A location range that ends at -1.
assert_eq!(
locations.next(),
Ok(Some(LocationListEntry {
range: Range {
begin: 0x0000_0000,
end: 0xffff_ffff,
},
data: Expression(EndianSlice::new(&[9, 0, 0, 0], LittleEndian)),
}))
);
// A StartEnd location following the tombstones
assert_eq!(
locations.next(),
Ok(Some(LocationListEntry {
range: Range {
begin: 0x0201_1600,
end: 0x0201_1700,
},
data: Expression(EndianSlice::new(&[26, 0, 0, 0], LittleEndian)),
}))
);
// A location list end.
assert_eq!(locations.next(), Ok(None));
// An offset at the end of buf. letmut locations = loclists
.locations(
LocationListsOffset(buf.len()),
encoding, 0x0100_0000,
debug_addr,
debug_addr_base,
)
.unwrap();
assert_eq!(locations.next(), Ok(None));
}
#[test] fn test_loclists_64() { let tombstone = !0u64; let encoding = Encoding {
format: Format::Dwarf64,
version: 5,
address_size: 8,
};
let section = Section::with_endian(Endian::Little)
.L64(0x0300_0000)
.L64(0x0301_0300)
.L64(0x0301_0400)
.L64(0x0301_0500)
.L64(tombstone)
.L64(0x0301_0600); let buf = section.get_contents().unwrap(); let debug_addr = &DebugAddr::from(EndianSlice::new(&buf, LittleEndian)); let debug_addr_base = DebugAddrBase(0);
let start = Label::new(); let first = Label::new(); let size = Label::new(); #[rustfmt::skip] let section = Section::with_endian(Endian::Little) // Header
.mark(&start)
.L32(0xffff_ffff)
.L64(&size)
.L16(encoding.version)
.L8(encoding.address_size)
.L8(0)
.L32(0)
.mark(&first) // OffsetPair
.L8(4).uleb(0x10200).uleb(0x10300).uleb(4).L32(2) // A base address selection followed by an OffsetPair.
.L8(6).L64(0x0200_0000)
.L8(4).uleb(0x10400).uleb(0x10500).uleb(4).L32(3) // An empty OffsetPair followed by a normal OffsetPair.
.L8(4).uleb(0x10600).uleb(0x10600).uleb(4).L32(4)
.L8(4).uleb(0x10800).uleb(0x10900).uleb(4).L32(5) // A StartEnd
.L8(7).L64(0x201_0a00).L64(0x201_0b00).uleb(4).L32(6) // A StartLength
.L8(8).L64(0x201_0c00).uleb(0x100).uleb(4).L32(7) // An OffsetPair that starts at 0.
.L8(4).uleb(0).uleb(1).uleb(4).L32(8) // An OffsetPair that ends at -1.
.L8(6).L64(0)
.L8(4).uleb(0).uleb(0xffff_ffff).uleb(4).L32(9) // A DefaultLocation
.L8(5).uleb(4).L32(10) // A BaseAddressx + OffsetPair
.L8(1).uleb(0)
.L8(4).uleb(0x10100).uleb(0x10200).uleb(4).L32(11) // A StartxEndx
.L8(2).uleb(1).uleb(2).uleb(4).L32(12) // A StartxLength
.L8(3).uleb(3).uleb(0x100).uleb(4).L32(13)
// Tombstone entries, all of which should be ignored. // A BaseAddressx that is a tombstone.
.L8(1).uleb(4)
.L8(4).uleb(0x11100).uleb(0x11200).uleb(4).L32(20) // A BaseAddress that is a tombstone.
.L8(6).L64(tombstone)
.L8(4).uleb(0x11300).uleb(0x11400).uleb(4).L32(21) // A StartxEndx that is a tombstone.
.L8(2).uleb(4).uleb(5).uleb(4).L32(22) // A StartxLength that is a tombstone.
.L8(3).uleb(4).uleb(0x100).uleb(4).L32(23) // A StartEnd that is a tombstone.
.L8(7).L64(tombstone).L64(0x201_1500).uleb(4).L32(24) // A StartLength that is a tombstone.
.L8(8).L64(tombstone).uleb(0x100).uleb(4).L32(25) // A StartEnd (not ignored)
.L8(7).L64(0x201_1600).L64(0x201_1700).uleb(4).L32(26)
// A range end.
.L8(0) // Some extra data.
.L32(0xffff_ffff);
size.set_const((§ion.here() - &start - 12) as u64);
let buf = section.get_contents().unwrap(); let debug_loc = DebugLoc::new(&[], LittleEndian); let debug_loclists = DebugLocLists::new(&buf, LittleEndian); let loclists = LocationLists::new(debug_loc, debug_loclists); let offset = LocationListsOffset((&first - &start) as usize); letmut locations = loclists
.locations(offset, encoding, 0x0100_0000, debug_addr, debug_addr_base)
.unwrap();
// A normal location.
assert_eq!(
locations.next(),
Ok(Some(LocationListEntry {
range: Range {
begin: 0x0101_0200,
end: 0x0101_0300,
},
data: Expression(EndianSlice::new(&[2, 0, 0, 0], LittleEndian)),
}))
);
// A base address selection followed by a normal location.
assert_eq!(
locations.next(),
Ok(Some(LocationListEntry {
range: Range {
begin: 0x0201_0400,
end: 0x0201_0500,
},
data: Expression(EndianSlice::new(&[3, 0, 0, 0], LittleEndian)),
}))
);
// An empty location range followed by a normal location.
assert_eq!(
locations.next(),
Ok(Some(LocationListEntry {
range: Range {
begin: 0x0201_0600,
end: 0x0201_0600,
},
data: Expression(EndianSlice::new(&[4, 0, 0, 0], LittleEndian)),
}))
);
assert_eq!(
locations.next(),
Ok(Some(LocationListEntry {
range: Range {
begin: 0x0201_0800,
end: 0x0201_0900,
},
data: Expression(EndianSlice::new(&[5, 0, 0, 0], LittleEndian)),
}))
);
// A normal location.
assert_eq!(
locations.next(),
Ok(Some(LocationListEntry {
range: Range {
begin: 0x0201_0a00,
end: 0x0201_0b00,
},
data: Expression(EndianSlice::new(&[6, 0, 0, 0], LittleEndian)),
}))
);
// A normal location.
assert_eq!(
locations.next(),
Ok(Some(LocationListEntry {
range: Range {
begin: 0x0201_0c00,
end: 0x0201_0d00,
},
data: Expression(EndianSlice::new(&[7, 0, 0, 0], LittleEndian)),
}))
);
// A location range that starts at 0.
assert_eq!(
locations.next(),
Ok(Some(LocationListEntry {
range: Range {
begin: 0x0200_0000,
end: 0x0200_0001,
},
data: Expression(EndianSlice::new(&[8, 0, 0, 0], LittleEndian)),
}))
);
// A location range that ends at -1.
assert_eq!(
locations.next(),
Ok(Some(LocationListEntry {
range: Range {
begin: 0x0000_0000,
end: 0xffff_ffff,
},
data: Expression(EndianSlice::new(&[9, 0, 0, 0], LittleEndian)),
}))
);
// A StartEnd location following the tombstones
assert_eq!(
locations.next(),
Ok(Some(LocationListEntry {
range: Range {
begin: 0x0201_1600,
end: 0x0201_1700,
},
data: Expression(EndianSlice::new(&[26, 0, 0, 0], LittleEndian)),
}))
);
// A location list end.
assert_eq!(locations.next(), Ok(None));
// An offset at the end of buf. letmut locations = loclists
.locations(
LocationListsOffset(buf.len()),
encoding, 0x0100_0000,
debug_addr,
debug_addr_base,
)
.unwrap();
assert_eq!(locations.next(), Ok(None));
}
#[test] fn test_location_list_32() { let tombstone = !0u32 - 1; let start = Label::new(); let first = Label::new(); #[rustfmt::skip] let section = Section::with_endian(Endian::Little) // A location before the offset.
.mark(&start)
.L32(0x10000).L32(0x10100).L16(4).L32(1)
.mark(&first) // A normal location.
.L32(0x10200).L32(0x10300).L16(4).L32(2) // A base address selection followed by a normal location.
.L32(0xffff_ffff).L32(0x0200_0000)
.L32(0x10400).L32(0x10500).L16(4).L32(3) // An empty location range followed by a normal location.
.L32(0x10600).L32(0x10600).L16(4).L32(4)
.L32(0x10800).L32(0x10900).L16(4).L32(5) // A location range that starts at 0.
.L32(0).L32(1).L16(4).L32(6) // A location range that ends at -1.
.L32(0xffff_ffff).L32(0x0000_0000)
.L32(0).L32(0xffff_ffff).L16(4).L32(7) // A normal location with tombstone.
.L32(tombstone).L32(tombstone).L16(4).L32(8) // A base address selection with tombstone followed by a normal location.
.L32(0xffff_ffff).L32(tombstone)
.L32(0x10a00).L32(0x10b00).L16(4).L32(9) // A location list end.
.L32(0).L32(0) // Some extra data.
.L32(0);
let buf = section.get_contents().unwrap(); let debug_loc = DebugLoc::new(&buf, LittleEndian); let debug_loclists = DebugLocLists::new(&[], LittleEndian); let loclists = LocationLists::new(debug_loc, debug_loclists); let offset = LocationListsOffset((&first - &start) as usize); let debug_addr = &DebugAddr::from(EndianSlice::new(&[], LittleEndian)); let debug_addr_base = DebugAddrBase(0); let encoding = Encoding {
format: Format::Dwarf32,
version: 4,
address_size: 4,
}; letmut locations = loclists
.locations(offset, encoding, 0x0100_0000, debug_addr, debug_addr_base)
.unwrap();
// A normal location.
assert_eq!(
locations.next(),
Ok(Some(LocationListEntry {
range: Range {
begin: 0x0101_0200,
end: 0x0101_0300,
},
data: Expression(EndianSlice::new(&[2, 0, 0, 0], LittleEndian)),
}))
);
// A base address selection followed by a normal location.
assert_eq!(
locations.next(),
Ok(Some(LocationListEntry {
range: Range {
begin: 0x0201_0400,
end: 0x0201_0500,
},
data: Expression(EndianSlice::new(&[3, 0, 0, 0], LittleEndian)),
}))
);
// An empty location range followed by a normal location.
assert_eq!(
locations.next(),
Ok(Some(LocationListEntry {
range: Range {
begin: 0x0201_0600,
end: 0x0201_0600,
},
data: Expression(EndianSlice::new(&[4, 0, 0, 0], LittleEndian)),
}))
);
assert_eq!(
locations.next(),
Ok(Some(LocationListEntry {
range: Range {
begin: 0x0201_0800,
end: 0x0201_0900,
},
data: Expression(EndianSlice::new(&[5, 0, 0, 0], LittleEndian)),
}))
);
// A location range that starts at 0.
assert_eq!(
locations.next(),
Ok(Some(LocationListEntry {
range: Range {
begin: 0x0200_0000,
end: 0x0200_0001,
},
data: Expression(EndianSlice::new(&[6, 0, 0, 0], LittleEndian)),
}))
);
// A location range that ends at -1.
assert_eq!(
locations.next(),
Ok(Some(LocationListEntry {
range: Range {
begin: 0x0000_0000,
end: 0xffff_ffff,
},
data: Expression(EndianSlice::new(&[7, 0, 0, 0], LittleEndian)),
}))
);
// A location list end.
assert_eq!(locations.next(), Ok(None));
// An offset at the end of buf. letmut locations = loclists
.locations(
LocationListsOffset(buf.len()),
encoding, 0x0100_0000,
debug_addr,
debug_addr_base,
)
.unwrap();
assert_eq!(locations.next(), Ok(None));
}
#[test] fn test_location_list_64() { let tombstone = !0u64 - 1; let start = Label::new(); let first = Label::new(); #[rustfmt::skip] let section = Section::with_endian(Endian::Little) // A location before the offset.
.mark(&start)
.L64(0x10000).L64(0x10100).L16(4).L32(1)
.mark(&first) // A normal location.
.L64(0x10200).L64(0x10300).L16(4).L32(2) // A base address selection followed by a normal location.
.L64(0xffff_ffff_ffff_ffff).L64(0x0200_0000)
.L64(0x10400).L64(0x10500).L16(4).L32(3) // An empty location range followed by a normal location.
.L64(0x10600).L64(0x10600).L16(4).L32(4)
.L64(0x10800).L64(0x10900).L16(4).L32(5) // A location range that starts at 0.
.L64(0).L64(1).L16(4).L32(6) // A location range that ends at -1.
.L64(0xffff_ffff_ffff_ffff).L64(0x0000_0000)
.L64(0).L64(0xffff_ffff_ffff_ffff).L16(4).L32(7) // A normal location with tombstone.
.L64(tombstone).L64(tombstone).L16(4).L32(8) // A base address selection with tombstone followed by a normal location.
.L64(0xffff_ffff_ffff_ffff).L64(tombstone)
.L64(0x10a00).L64(0x10b00).L16(4).L32(9) // A location list end.
.L64(0).L64(0) // Some extra data.
.L64(0);
let buf = section.get_contents().unwrap(); let debug_loc = DebugLoc::new(&buf, LittleEndian); let debug_loclists = DebugLocLists::new(&[], LittleEndian); let loclists = LocationLists::new(debug_loc, debug_loclists); let offset = LocationListsOffset((&first - &start) as usize); let debug_addr = &DebugAddr::from(EndianSlice::new(&[], LittleEndian)); let debug_addr_base = DebugAddrBase(0); let encoding = Encoding {
format: Format::Dwarf64,
version: 4,
address_size: 8,
}; letmut locations = loclists
.locations(offset, encoding, 0x0100_0000, debug_addr, debug_addr_base)
.unwrap();
// A normal location.
assert_eq!(
locations.next(),
Ok(Some(LocationListEntry {
range: Range {
begin: 0x0101_0200,
end: 0x0101_0300,
},
data: Expression(EndianSlice::new(&[2, 0, 0, 0], LittleEndian)),
}))
);
// A base address selection followed by a normal location.
assert_eq!(
locations.next(),
Ok(Some(LocationListEntry {
range: Range {
begin: 0x0201_0400,
end: 0x0201_0500,
},
data: Expression(EndianSlice::new(&[3, 0, 0, 0], LittleEndian)),
}))
);
// An empty location range followed by a normal location.
assert_eq!(
locations.next(),
Ok(Some(LocationListEntry {
range: Range {
begin: 0x0201_0600,
end: 0x0201_0600,
},
data: Expression(EndianSlice::new(&[4, 0, 0, 0], LittleEndian)),
}))
);
assert_eq!(
locations.next(),
Ok(Some(LocationListEntry {
range: Range {
begin: 0x0201_0800,
end: 0x0201_0900,
},
data: Expression(EndianSlice::new(&[5, 0, 0, 0], LittleEndian)),
}))
);
// A location range that starts at 0.
assert_eq!(
locations.next(),
Ok(Some(LocationListEntry {
range: Range {
begin: 0x0200_0000,
end: 0x0200_0001,
},
data: Expression(EndianSlice::new(&[6, 0, 0, 0], LittleEndian)),
}))
);
// A location range that ends at -1.
assert_eq!(
locations.next(),
Ok(Some(LocationListEntry {
range: Range {
begin: 0x0,
end: 0xffff_ffff_ffff_ffff,
},
data: Expression(EndianSlice::new(&[7, 0, 0, 0], LittleEndian)),
}))
);
// A location list end.
assert_eq!(locations.next(), Ok(None));
// An offset at the end of buf. letmut locations = loclists
.locations(
LocationListsOffset(buf.len()),
encoding, 0x0100_0000,
debug_addr,
debug_addr_base,
)
.unwrap();
assert_eq!(locations.next(), Ok(None));
}
#[test] fn test_locations_invalid() { #[rustfmt::skip] let section = Section::with_endian(Endian::Little) // An invalid location range.
.L32(0x20000).L32(0x10000).L16(4).L32(1) // An invalid range after wrapping.
.L32(0x20000).L32(0xff01_0000).L16(4).L32(2);
let buf = section.get_contents().unwrap(); let debug_loc = DebugLoc::new(&buf, LittleEndian); let debug_loclists = DebugLocLists::new(&[], LittleEndian); let loclists = LocationLists::new(debug_loc, debug_loclists); let debug_addr = &DebugAddr::from(EndianSlice::new(&[], LittleEndian)); let debug_addr_base = DebugAddrBase(0); let encoding = Encoding {
format: Format::Dwarf32,
version: 4,
address_size: 4,
};
#[test] fn test_get_offset() { for format in [Format::Dwarf32, Format::Dwarf64] { let encoding = Encoding {
format,
version: 5,
address_size: 4,
};
let zero = Label::new(); let length = Label::new(); let start = Label::new(); let first = Label::new(); let end = Label::new(); letmut section = Section::with_endian(Endian::Little)
.mark(&zero)
.initial_length(format, &length, &start)
.D16(encoding.version)
.D8(encoding.address_size)
.D8(0)
.D32(20)
.mark(&first); for i in0..20 {
section = section.word(format.word_size(), 1000 + i);
}
section = section.mark(&end);
length.set_const((&end - &start) as u64); let section = section.get_contents().unwrap();
let debug_loc = DebugLoc::from(EndianSlice::new(&[], LittleEndian)); let debug_loclists = DebugLocLists::from(EndianSlice::new(§ion, LittleEndian)); let locations = LocationLists::new(debug_loc, debug_loclists);
let base = DebugLocListsBase((&first - &zero) as usize);
assert_eq!(
locations.get_offset(encoding, base, DebugLocListsIndex(0)),
Ok(LocationListsOffset(base.0 + 1000))
);
assert_eq!(
locations.get_offset(encoding, base, DebugLocListsIndex(19)),
Ok(LocationListsOffset(base.0 + 1019))
);
}
}
#[test] fn test_loclists_gnu_v4_split_dwarf() { #[rustfmt::skip] let buf = [ 0x03, // DW_LLE_startx_length 0x00, // ULEB encoded b7 0x08, 0x00, 0x00, 0x00, // Fixed 4 byte length of 8 0x03, 0x00, // Fixed two byte length of the location 0x11, 0x00, // DW_OP_constu 0 0x9f, // DW_OP_stack_value // Padding data //0x99, 0x99, 0x99, 0x99
]; let data_buf = [0x11, 0x00, 0x9f]; let expected_data = EndianSlice::new(&data_buf, LittleEndian); let debug_loc = DebugLoc::new(&buf, LittleEndian); let debug_loclists = DebugLocLists::new(&[], LittleEndian); let loclists = LocationLists::new(debug_loc, debug_loclists); let debug_addr =
&DebugAddr::from(EndianSlice::new(&[0x01, 0x02, 0x03, 0x04], LittleEndian)); let debug_addr_base = DebugAddrBase(0); let encoding = Encoding {
format: Format::Dwarf32,
version: 4,
address_size: 4,
};
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