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use alloc::vec::Vec;
use core::fmt::Debug;
use core::{mem, str};
use core::convert::TryInto;
use crate::endian::{LittleEndian as LE, U32};
use crate::pe;
use crate::pod::{self, Pod};
use crate::read::coff::{CoffCommon, CoffSymbol, CoffSymbolIterator, CoffSymbolTable, SymbolTable};
use crate::read::{
self, Architecture, ByteString, Bytes, CodeView, ComdatKind, Error, Export, FileFlags, Import,
NoDynamicRelocationIterator, Object, ObjectComdat, ObjectKind, ReadError, ReadRef, Result,
SectionIndex, SubArchitecture, SymbolIndex,
};
use super::{
DataDirectories, ExportTable, ImageThunkData, ImportTable, PeSection, PeSectionIterator,
PeSegment, PeSegmentIterator, RichHeaderInfo, SectionTable,
};
/// A PE32 (32-bit) image file.
///
/// This is a file that starts with [`pe::ImageNtHeaders32`], and corresponds
/// to [`crate::FileKind::Pe32`].
pub type PeFile32<'data, R = &'data [u8]> = PeFile<'data, pe::ImageNtHeaders32, R>;
/// A PE32+ (64-bit) image file.
///
/// This is a file that starts with [`pe::ImageNtHeaders64`], and corresponds
/// to [`crate::FileKind::Pe64`].
pub type PeFile64<'data, R = &'data [u8]> = PeFile<'data, pe::ImageNtHeaders64, R>;
/// A PE image file.
///
/// Most functionality is provided by the [`Object`] trait implementation.
#[derive(Debug)]
pub struct PeFile<'data, Pe, R = &'data [u8]>
where
Pe: ImageNtHeaders,
R: ReadRef<'data>,
{
pub(super) dos_header: &'data pe::ImageDosHeader,
pub(super) nt_headers: &'data Pe,
pub(super) data_directories: DataDirectories<'data>,
pub(super) common: CoffCommon<'data, R>,
pub(super) data: R,
}
impl<'data, Pe, R> PeFile<'data, Pe, R>
where
Pe: ImageNtHeaders,
R: ReadRef<'data>,
{
/// Parse the raw PE file data.
pub fn parse(data: R) -> Result<Self> {
let dos_header = pe::ImageDosHeader::parse(data)?;
let mut offset = dos_header.nt_headers_offset().into();
let (nt_headers, data_directories) = Pe::parse(data, &mut offset)?;
let sections = nt_headers.sections(data, offset)?;
let coff_symbols = nt_headers.symbols(data);
let image_base = nt_headers.optional_header().image_base();
Ok(PeFile {
dos_header,
nt_headers,
data_directories,
common: CoffCommon {
sections,
// We do not want to prevent parsing the rest of the PE file for a corrupt COFF header, but rather return an empty symbol table
symbols: coff_symbols.unwrap_or_default(),
image_base,
},
data,
})
}
/// Returns this binary data.
pub fn data(&self) -> R {
self.data
}
/// Return the DOS header of this file.
pub fn dos_header(&self) -> &'data pe::ImageDosHeader {
self.dos_header
}
/// Return the NT Headers of this file.
pub fn nt_headers(&self) -> &'data Pe {
self.nt_headers
}
/// Returns information about the rich header of this file (if any).
pub fn rich_header_info(&self) -> Option<RichHeaderInfo<'_>> {
RichHeaderInfo::parse(self.data, self.dos_header.nt_headers_offset().into())
}
/// Returns the section table of this binary.
pub fn section_table(&self) -> SectionTable<'data> {
self.common.sections
}
/// Returns the data directories of this file.
pub fn data_directories(&self) -> DataDirectories<'data> {
self.data_directories
}
/// Returns the data directory at the given index.
pub fn data_directory(&self, id: usize) -> Option<&'data pe::ImageDataDirectory> {
self.data_directories.get(id)
}
/// Returns the export table of this file.
///
/// The export table is located using the data directory.
pub fn export_table(&self) -> Result<Option<ExportTable<'data>>> {
self.data_directories
.export_table(self.data, &self.common.sections)
}
/// Returns the import table of this file.
///
/// The import table is located using the data directory.
pub fn import_table(&self) -> Result<Option<ImportTable<'data>>> {
self.data_directories
.import_table(self.data, &self.common.sections)
}
pub(super) fn section_alignment(&self) -> u64 {
u64::from(self.nt_headers.optional_header().section_alignment())
}
}
impl<'data, Pe, R> read::private::Sealed for PeFile<'data, Pe, R>
where
Pe: ImageNtHeaders,
R: ReadRef<'data>,
{
}
impl<'data, Pe, R> Object<'data> for PeFile<'data, Pe, R>
where
Pe: ImageNtHeaders,
R: ReadRef<'data>,
{
type Segment<'file> = PeSegment<'data, 'file, Pe, R> where Self: 'file, 'data: 'file;
type SegmentIterator<'file> = PeSegmentIterator<'data, 'file, Pe, R> where Self: 'file, 'data: 'file;
type Section<'file> = PeSection<'data, 'file, Pe, R> where Self: 'file, 'data: 'file;
type SectionIterator<'file> = PeSectionIterator<'data, 'file, Pe, R> where Self: 'file, 'data: 'file;
type Comdat<'file> = PeComdat<'data, 'file, Pe, R> where Self: 'file, 'data: 'file;
type ComdatIterator<'file> = PeComdatIterator<'data, 'file, Pe, R> where Self: 'file, 'data: 'file;
type Symbol<'file> = CoffSymbol<'data, 'file, R> where Self: 'file, 'data: 'file;
type SymbolIterator<'file> = CoffSymbolIterator<'data, 'file, R> where Self: 'file, 'data: 'file;
type SymbolTable<'file> = CoffSymbolTable<'data, 'file, R> where Self: 'file, 'data: 'file;
type DynamicRelocationIterator<'file> = NoDynamicRelocationIterator where Self: 'file, 'data: 'file;
fn architecture(&self) -> Architecture {
match self.nt_headers.file_header().machine.get(LE) {
pe::IMAGE_FILE_MACHINE_ARMNT => Architecture::Arm,
pe::IMAGE_FILE_MACHINE_ARM64 | pe::IMAGE_FILE_MACHINE_ARM64EC => Architecture::Aarch64,
pe::IMAGE_FILE_MACHINE_I386 => Architecture::I386,
pe::IMAGE_FILE_MACHINE_AMD64 => Architecture::X86_64,
_ => Architecture::Unknown,
}
}
fn sub_architecture(&self) -> Option<SubArchitecture> {
match self.nt_headers.file_header().machine.get(LE) {
pe::IMAGE_FILE_MACHINE_ARM64EC => Some(SubArchitecture::Arm64EC),
_ => None,
}
}
#[inline]
fn is_little_endian(&self) -> bool {
// Only little endian is supported.
true
}
#[inline]
fn is_64(&self) -> bool {
self.nt_headers.is_type_64()
}
fn kind(&self) -> ObjectKind {
let characteristics = self.nt_headers.file_header().characteristics.get(LE);
if characteristics & pe::IMAGE_FILE_DLL != 0 {
ObjectKind::Dynamic
} else if characteristics & pe::IMAGE_FILE_SYSTEM != 0 {
ObjectKind::Unknown
} else {
ObjectKind::Executable
}
}
fn segments(&self) -> PeSegmentIterator<'data, '_, Pe, R> {
PeSegmentIterator {
file: self,
iter: self.common.sections.iter(),
}
}
fn section_by_name_bytes<'file>(
&'file self,
section_name: &[u8],
) -> Option<PeSection<'data, 'file, Pe, R>> {
self.common
.sections
.section_by_name(self.common.symbols.strings(), section_name)
.map(|(index, section)| PeSection {
file: self,
index,
section,
})
}
fn section_by_index(&self, index: SectionIndex) -> Result<PeSection<'data, '_, Pe, R>> {
let section = self.common.sections.section(index)?;
Ok(PeSection {
file: self,
index,
section,
})
}
fn sections(&self) -> PeSectionIterator<'data, '_, Pe, R> {
PeSectionIterator {
file: self,
iter: self.common.sections.iter().enumerate(),
}
}
fn comdats(&self) -> PeComdatIterator<'data, '_, Pe, R> {
PeComdatIterator { file: self }
}
fn symbol_by_index(&self, index: SymbolIndex) -> Result<CoffSymbol<'data, '_, R>> {
let symbol = self.common.symbols.symbol(index)?;
Ok(CoffSymbol {
file: &self.common,
index,
symbol,
})
}
fn symbols(&self) -> CoffSymbolIterator<'data, '_, R> {
CoffSymbolIterator::new(&self.common)
}
fn symbol_table(&self) -> Option<CoffSymbolTable<'data, '_, R>> {
Some(CoffSymbolTable { file: &self.common })
}
fn dynamic_symbols(&self) -> CoffSymbolIterator<'data, '_, R> {
CoffSymbolIterator::empty(&self.common)
}
fn dynamic_symbol_table(&self) -> Option<CoffSymbolTable<'data, '_, R>> {
None
}
fn dynamic_relocations(&self) -> Option<NoDynamicRelocationIterator> {
None
}
fn imports(&self) -> Result<Vec<Import<'data>>> {
let mut imports = Vec::new();
if let Some(import_table) = self.import_table()? {
let mut import_descs = import_table.descriptors()?;
while let Some(import_desc) = import_descs.next()? {
let library = import_table.name(import_desc.name.get(LE))?;
let mut first_thunk = import_desc.original_first_thunk.get(LE);
if first_thunk == 0 {
first_thunk = import_desc.first_thunk.get(LE);
}
let mut thunks = import_table.thunks(first_thunk)?;
while let Some(thunk) = thunks.next::<Pe>()? {
if !thunk.is_ordinal() {
let (_hint, name) = import_table.hint_name(thunk.address())?;
imports.push(Import {
library: ByteString(library),
name: ByteString(name),
});
}
}
}
}
Ok(imports)
}
fn exports(&self) -> Result<Vec<Export<'data>>> {
let mut exports = Vec::new();
if let Some(export_table) = self.export_table()? {
for (name_pointer, address_index) in export_table.name_iter() {
let name = export_table.name_from_pointer(name_pointer)?;
let address = export_table.address_by_index(address_index.into())?;
if !export_table.is_forward(address) {
exports.push(Export {
name: ByteString(name),
address: self.common.image_base.wrapping_add(address.into()),
})
}
}
}
Ok(exports)
}
fn pdb_info(&self) -> Result<Option<CodeView<'_>>> {
let data_dir = match self.data_directory(pe::IMAGE_DIRECTORY_ENTRY_DEBUG) {
Some(data_dir) => data_dir,
None => return Ok(None),
};
let debug_data = data_dir.data(self.data, &self.common.sections)?;
let debug_dirs = pod::slice_from_all_bytes::<pe::ImageDebugDirectory>(debug_data)
.read_error("Invalid PE debug dir size")?;
for debug_dir in debug_dirs {
if debug_dir.typ.get(LE) != pe::IMAGE_DEBUG_TYPE_CODEVIEW {
continue;
}
let info = self
.data
.read_slice_at::<u8>(
debug_dir.pointer_to_raw_data.get(LE) as u64,
debug_dir.size_of_data.get(LE) as usize,
)
.read_error("Invalid CodeView Info address")?;
let mut info = Bytes(info);
let sig = info
.read_bytes(4)
.read_error("Invalid CodeView signature")?;
if sig.0 != b"RSDS" {
continue;
}
let guid: [u8; 16] = info
.read_bytes(16)
.read_error("Invalid CodeView GUID")?
.0
.try_into()
.unwrap();
let age = info.read::<U32<LE>>().read_error("Invalid CodeView Age")?;
let path = info
.read_string()
.read_error("Invalid CodeView file path")?;
return Ok(Some(CodeView {
path: ByteString(path),
guid,
age: age.get(LE),
}));
}
Ok(None)
}
fn has_debug_symbols(&self) -> bool {
self.section_by_name(".debug_info").is_some()
}
fn relative_address_base(&self) -> u64 {
self.common.image_base
}
fn entry(&self) -> u64 {
u64::from(self.nt_headers.optional_header().address_of_entry_point())
.wrapping_add(self.common.image_base)
}
fn flags(&self) -> FileFlags {
FileFlags::Coff {
characteristics: self.nt_headers.file_header().characteristics.get(LE),
}
}
}
/// An iterator for the COMDAT section groups in a [`PeFile32`].
pub type PeComdatIterator32<'data, 'file, R = &'data [u8]> =
PeComdatIterator<'data, 'file, pe::ImageNtHeaders32, R>;
/// An iterator for the COMDAT section groups in a [`PeFile64`].
pub type PeComdatIterator64<'data, 'file, R = &'data [u8]> =
PeComdatIterator<'data, 'file, pe::ImageNtHeaders64, R>;
/// An iterator for the COMDAT section groups in a [`PeFile`].
///
/// This is a stub that doesn't implement any functionality.
#[derive(Debug)]
pub struct PeComdatIterator<'data, 'file, Pe, R = &'data [u8]>
where
Pe: ImageNtHeaders,
R: ReadRef<'data>,
{
#[allow(unused)]
file: &'file PeFile<'data, Pe, R>,
}
impl<'data, 'file, Pe, R> Iterator for PeComdatIterator<'data, 'file, Pe, R>
where
Pe: ImageNtHeaders,
R: ReadRef<'data>,
{
type Item = PeComdat<'data, 'file, Pe, R>;
#[inline]
fn next(&mut self) -> Option<Self::Item> {
None
}
}
/// A COMDAT section group in a [`PeFile32`].
pub type PeComdat32<'data, 'file, R = &'data [u8]> =
PeComdat<'data, 'file, pe::ImageNtHeaders32, R>;
/// A COMDAT section group in a [`PeFile64`].
pub type PeComdat64<'data, 'file, R = &'data [u8]> =
PeComdat<'data, 'file, pe::ImageNtHeaders64, R>;
/// A COMDAT section group in a [`PeFile`].
///
/// This is a stub that doesn't implement any functionality.
#[derive(Debug)]
pub struct PeComdat<'data, 'file, Pe, R = &'data [u8]>
where
Pe: ImageNtHeaders,
R: ReadRef<'data>,
{
#[allow(unused)]
file: &'file PeFile<'data, Pe, R>,
}
impl<'data, 'file, Pe, R> read::private::Sealed for PeComdat<'data, 'file, Pe, R>
where
Pe: ImageNtHeaders,
R: ReadRef<'data>,
{
}
impl<'data, 'file, Pe, R> ObjectComdat<'data> for PeComdat<'data, 'file, Pe, R>
where
Pe: ImageNtHeaders,
R: ReadRef<'data>,
{
type SectionIterator = PeComdatSectionIterator<'data, 'file, Pe, R>;
#[inline]
fn kind(&self) -> ComdatKind {
unreachable!();
}
#[inline]
fn symbol(&self) -> SymbolIndex {
unreachable!();
}
#[inline]
fn name_bytes(&self) -> Result<&'data [u8]> {
unreachable!();
}
#[inline]
fn name(&self) -> Result<&'data str> {
unreachable!();
}
#[inline]
fn sections(&self) -> Self::SectionIterator {
unreachable!();
}
}
/// An iterator for the sections in a COMDAT section group in a [`PeFile32`].
pub type PeComdatSectionIterator32<'data, 'file, R = &'data [u8]> =
PeComdatSectionIterator<'data, 'file, pe::ImageNtHeaders32, R>;
/// An iterator for the sections in a COMDAT section group in a [`PeFile64`].
pub type PeComdatSectionIterator64<'data, 'file, R = &'data [u8]> =
PeComdatSectionIterator<'data, 'file, pe::ImageNtHeaders64, R>;
/// An iterator for the sections in a COMDAT section group in a [`PeFile`].
///
/// This is a stub that doesn't implement any functionality.
#[derive(Debug)]
pub struct PeComdatSectionIterator<'data, 'file, Pe, R = &'data [u8]>
where
Pe: ImageNtHeaders,
R: ReadRef<'data>,
{
#[allow(unused)]
file: &'file PeFile<'data, Pe, R>,
}
impl<'data, 'file, Pe, R> Iterator for PeComdatSectionIterator<'data, 'file, Pe, R>
where
Pe: ImageNtHeaders,
R: ReadRef<'data>,
{
type Item = SectionIndex;
fn next(&mut self) -> Option<Self::Item> {
None
}
}
impl pe::ImageDosHeader {
/// Read the DOS header.
///
/// Also checks that the `e_magic` field in the header is valid.
pub fn parse<'data, R: ReadRef<'data>>(data: R) -> read::Result<&'data Self> {
// DOS header comes first.
let dos_header = data
.read_at::<pe::ImageDosHeader>(0)
.read_error("Invalid DOS header size or alignment")?;
if dos_header.e_magic.get(LE) != pe::IMAGE_DOS_SIGNATURE {
return Err(Error("Invalid DOS magic"));
}
Ok(dos_header)
}
/// Return the file offset of the nt_headers.
#[inline]
pub fn nt_headers_offset(&self) -> u32 {
self.e_lfanew.get(LE)
}
}
/// Find the optional header and read its `magic` field.
///
/// It can be useful to know this magic value before trying to
/// fully parse the NT headers.
pub fn optional_header_magic<'data, R: ReadRef<'data>>(data: R) -> Result<u16> {
let dos_header = pe::ImageDosHeader::parse(data)?;
// NT headers are at an offset specified in the DOS header.
let offset = dos_header.nt_headers_offset().into();
// It doesn't matter which NT header type is used for the purpose
// of reading the optional header magic.
let nt_headers = data
.read_at::<pe::ImageNtHeaders32>(offset)
.read_error("Invalid NT headers offset, size, or alignment")?;
if nt_headers.signature() != pe::IMAGE_NT_SIGNATURE {
return Err(Error("Invalid PE magic"));
}
Ok(nt_headers.optional_header().magic())
}
/// A trait for generic access to [`pe::ImageNtHeaders32`] and [`pe::ImageNtHeaders64`].
#[allow(missing_docs)]
pub trait ImageNtHeaders: Debug + Pod {
type ImageOptionalHeader: ImageOptionalHeader;
type ImageThunkData: ImageThunkData;
/// Return true if this type is a 64-bit header.
///
/// This is a property of the type, not a value in the header data.
fn is_type_64(&self) -> bool;
/// Return true if the magic field in the optional header is valid.
fn is_valid_optional_magic(&self) -> bool;
/// Return the signature
fn signature(&self) -> u32;
/// Return the file header.
fn file_header(&self) -> &pe::ImageFileHeader;
/// Return the optional header.
fn optional_header(&self) -> &Self::ImageOptionalHeader;
// Provided methods.
/// Read the NT headers, including the data directories.
///
/// `data` must be for the entire file.
///
/// `offset` must be headers offset, which can be obtained from [`pe::ImageDosHeader::nt_headers_offset`].
/// It is updated to point after the optional header, which is where the section headers are located.
///
/// Also checks that the `signature` and `magic` fields in the headers are valid.
fn parse<'data, R: ReadRef<'data>>(
data: R,
offset: &mut u64,
) -> read::Result<(&'data Self, DataDirectories<'data>)> {
// Note that this does not include the data directories in the optional header.
let nt_headers = data
.read::<Self>(offset)
.read_error("Invalid PE headers offset or size")?;
if nt_headers.signature() != pe::IMAGE_NT_SIGNATURE {
return Err(Error("Invalid PE magic"));
}
if !nt_headers.is_valid_optional_magic() {
return Err(Error("Invalid PE optional header magic"));
}
// Read the rest of the optional header, and then read the data directories from that.
let optional_data_size =
u64::from(nt_headers.file_header().size_of_optional_header.get(LE))
.checked_sub(mem::size_of::<Self::ImageOptionalHeader>() as u64)
.read_error("PE optional header size is too small")?;
let optional_data = data
.read_bytes(offset, optional_data_size)
.read_error("Invalid PE optional header size")?;
let data_directories = DataDirectories::parse(
optional_data,
nt_headers.optional_header().number_of_rva_and_sizes(),
)?;
Ok((nt_headers, data_directories))
}
/// Read the section table.
///
/// `data` must be for the entire file.
/// `offset` must be after the optional file header.
#[inline]
fn sections<'data, R: ReadRef<'data>>(
&self,
data: R,
offset: u64,
) -> read::Result<SectionTable<'data>> {
SectionTable::parse(self.file_header(), data, offset)
}
/// Read the COFF symbol table and string table.
///
/// `data` must be the entire file data.
#[inline]
fn symbols<'data, R: ReadRef<'data>>(&self, data: R) -> read::Result<SymbolTable<'data, R>> {
SymbolTable::parse(self.file_header(), data)
}
}
/// A trait for generic access to [`pe::ImageOptionalHeader32`] and [`pe::ImageOptionalHeader64`].
#[allow(missing_docs)]
pub trait ImageOptionalHeader: Debug + Pod {
// Standard fields.
fn magic(&self) -> u16;
fn major_linker_version(&self) -> u8;
fn minor_linker_version(&self) -> u8;
fn size_of_code(&self) -> u32;
fn size_of_initialized_data(&self) -> u32;
fn size_of_uninitialized_data(&self) -> u32;
fn address_of_entry_point(&self) -> u32;
fn base_of_code(&self) -> u32;
fn base_of_data(&self) -> Option<u32>;
// NT additional fields.
fn image_base(&self) -> u64;
fn section_alignment(&self) -> u32;
fn file_alignment(&self) -> u32;
fn major_operating_system_version(&self) -> u16;
fn minor_operating_system_version(&self) -> u16;
fn major_image_version(&self) -> u16;
fn minor_image_version(&self) -> u16;
fn major_subsystem_version(&self) -> u16;
fn minor_subsystem_version(&self) -> u16;
fn win32_version_value(&self) -> u32;
fn size_of_image(&self) -> u32;
fn size_of_headers(&self) -> u32;
fn check_sum(&self) -> u32;
fn subsystem(&self) -> u16;
fn dll_characteristics(&self) -> u16;
fn size_of_stack_reserve(&self) -> u64;
fn size_of_stack_commit(&self) -> u64;
fn size_of_heap_reserve(&self) -> u64;
fn size_of_heap_commit(&self) -> u64;
fn loader_flags(&self) -> u32;
fn number_of_rva_and_sizes(&self) -> u32;
}
impl ImageNtHeaders for pe::ImageNtHeaders32 {
type ImageOptionalHeader = pe::ImageOptionalHeader32;
type ImageThunkData = pe::ImageThunkData32;
#[inline]
fn is_type_64(&self) -> bool {
false
}
#[inline]
fn is_valid_optional_magic(&self) -> bool {
self.optional_header.magic.get(LE) == pe::IMAGE_NT_OPTIONAL_HDR32_MAGIC
}
#[inline]
fn signature(&self) -> u32 {
self.signature.get(LE)
}
#[inline]
fn file_header(&self) -> &pe::ImageFileHeader {
&self.file_header
}
#[inline]
fn optional_header(&self) -> &Self::ImageOptionalHeader {
&self.optional_header
}
}
impl ImageOptionalHeader for pe::ImageOptionalHeader32 {
#[inline]
fn magic(&self) -> u16 {
self.magic.get(LE)
}
#[inline]
fn major_linker_version(&self) -> u8 {
self.major_linker_version
}
#[inline]
fn minor_linker_version(&self) -> u8 {
self.minor_linker_version
}
#[inline]
fn size_of_code(&self) -> u32 {
self.size_of_code.get(LE)
}
#[inline]
fn size_of_initialized_data(&self) -> u32 {
self.size_of_initialized_data.get(LE)
}
#[inline]
fn size_of_uninitialized_data(&self) -> u32 {
self.size_of_uninitialized_data.get(LE)
}
#[inline]
fn address_of_entry_point(&self) -> u32 {
self.address_of_entry_point.get(LE)
}
#[inline]
fn base_of_code(&self) -> u32 {
self.base_of_code.get(LE)
}
#[inline]
fn base_of_data(&self) -> Option<u32> {
Some(self.base_of_data.get(LE))
}
#[inline]
fn image_base(&self) -> u64 {
self.image_base.get(LE).into()
}
#[inline]
fn section_alignment(&self) -> u32 {
self.section_alignment.get(LE)
}
#[inline]
fn file_alignment(&self) -> u32 {
self.file_alignment.get(LE)
}
#[inline]
fn major_operating_system_version(&self) -> u16 {
self.major_operating_system_version.get(LE)
}
#[inline]
fn minor_operating_system_version(&self) -> u16 {
self.minor_operating_system_version.get(LE)
}
#[inline]
fn major_image_version(&self) -> u16 {
self.major_image_version.get(LE)
}
#[inline]
fn minor_image_version(&self) -> u16 {
self.minor_image_version.get(LE)
}
#[inline]
fn major_subsystem_version(&self) -> u16 {
self.major_subsystem_version.get(LE)
}
#[inline]
fn minor_subsystem_version(&self) -> u16 {
self.minor_subsystem_version.get(LE)
}
#[inline]
fn win32_version_value(&self) -> u32 {
self.win32_version_value.get(LE)
}
#[inline]
fn size_of_image(&self) -> u32 {
self.size_of_image.get(LE)
}
#[inline]
fn size_of_headers(&self) -> u32 {
self.size_of_headers.get(LE)
}
#[inline]
fn check_sum(&self) -> u32 {
self.check_sum.get(LE)
}
#[inline]
fn subsystem(&self) -> u16 {
self.subsystem.get(LE)
}
#[inline]
fn dll_characteristics(&self) -> u16 {
self.dll_characteristics.get(LE)
}
#[inline]
fn size_of_stack_reserve(&self) -> u64 {
self.size_of_stack_reserve.get(LE).into()
}
#[inline]
fn size_of_stack_commit(&self) -> u64 {
self.size_of_stack_commit.get(LE).into()
}
#[inline]
fn size_of_heap_reserve(&self) -> u64 {
self.size_of_heap_reserve.get(LE).into()
}
#[inline]
fn size_of_heap_commit(&self) -> u64 {
self.size_of_heap_commit.get(LE).into()
}
#[inline]
fn loader_flags(&self) -> u32 {
self.loader_flags.get(LE)
}
#[inline]
fn number_of_rva_and_sizes(&self) -> u32 {
self.number_of_rva_and_sizes.get(LE)
}
}
impl ImageNtHeaders for pe::ImageNtHeaders64 {
type ImageOptionalHeader = pe::ImageOptionalHeader64;
type ImageThunkData = pe::ImageThunkData64;
#[inline]
fn is_type_64(&self) -> bool {
true
}
#[inline]
fn is_valid_optional_magic(&self) -> bool {
self.optional_header.magic.get(LE) == pe::IMAGE_NT_OPTIONAL_HDR64_MAGIC
}
#[inline]
fn signature(&self) -> u32 {
self.signature.get(LE)
}
#[inline]
fn file_header(&self) -> &pe::ImageFileHeader {
&self.file_header
}
#[inline]
fn optional_header(&self) -> &Self::ImageOptionalHeader {
&self.optional_header
}
}
impl ImageOptionalHeader for pe::ImageOptionalHeader64 {
#[inline]
fn magic(&self) -> u16 {
self.magic.get(LE)
}
#[inline]
fn major_linker_version(&self) -> u8 {
self.major_linker_version
}
#[inline]
fn minor_linker_version(&self) -> u8 {
self.minor_linker_version
}
#[inline]
fn size_of_code(&self) -> u32 {
self.size_of_code.get(LE)
}
#[inline]
fn size_of_initialized_data(&self) -> u32 {
self.size_of_initialized_data.get(LE)
}
#[inline]
fn size_of_uninitialized_data(&self) -> u32 {
self.size_of_uninitialized_data.get(LE)
}
#[inline]
fn address_of_entry_point(&self) -> u32 {
self.address_of_entry_point.get(LE)
}
#[inline]
fn base_of_code(&self) -> u32 {
self.base_of_code.get(LE)
}
#[inline]
fn base_of_data(&self) -> Option<u32> {
None
}
#[inline]
fn image_base(&self) -> u64 {
self.image_base.get(LE)
}
#[inline]
fn section_alignment(&self) -> u32 {
self.section_alignment.get(LE)
}
#[inline]
fn file_alignment(&self) -> u32 {
self.file_alignment.get(LE)
}
#[inline]
fn major_operating_system_version(&self) -> u16 {
self.major_operating_system_version.get(LE)
}
#[inline]
fn minor_operating_system_version(&self) -> u16 {
self.minor_operating_system_version.get(LE)
}
#[inline]
fn major_image_version(&self) -> u16 {
self.major_image_version.get(LE)
}
#[inline]
fn minor_image_version(&self) -> u16 {
self.minor_image_version.get(LE)
}
#[inline]
fn major_subsystem_version(&self) -> u16 {
self.major_subsystem_version.get(LE)
}
#[inline]
fn minor_subsystem_version(&self) -> u16 {
self.minor_subsystem_version.get(LE)
}
#[inline]
fn win32_version_value(&self) -> u32 {
self.win32_version_value.get(LE)
}
#[inline]
fn size_of_image(&self) -> u32 {
self.size_of_image.get(LE)
}
#[inline]
fn size_of_headers(&self) -> u32 {
self.size_of_headers.get(LE)
}
#[inline]
fn check_sum(&self) -> u32 {
self.check_sum.get(LE)
}
#[inline]
fn subsystem(&self) -> u16 {
self.subsystem.get(LE)
}
#[inline]
fn dll_characteristics(&self) -> u16 {
self.dll_characteristics.get(LE)
}
#[inline]
fn size_of_stack_reserve(&self) -> u64 {
self.size_of_stack_reserve.get(LE)
}
#[inline]
fn size_of_stack_commit(&self) -> u64 {
self.size_of_stack_commit.get(LE)
}
#[inline]
fn size_of_heap_reserve(&self) -> u64 {
self.size_of_heap_reserve.get(LE)
}
#[inline]
fn size_of_heap_commit(&self) -> u64 {
self.size_of_heap_commit.get(LE)
}
#[inline]
fn loader_flags(&self) -> u32 {
self.loader_flags.get(LE)
}
#[inline]
fn number_of_rva_and_sizes(&self) -> u32 {
self.number_of_rva_and_sizes.get(LE)
}
}