use alloc::fmt; use alloc::vec::Vec; use core::convert::TryInto; use core::str; use super::{CoffCommon, SectionTable}; use crate::endian::{LittleEndian as LE, U32Bytes}; use crate::pe; use crate::pod::{bytes_of_slice, Pod}; use crate::read::util::StringTable; use crate::read::{ self, Bytes, ObjectSymbol, ObjectSymbolTable, ReadError, ReadRef, Result, SectionIndex, SymbolFlags, SymbolIndex, SymbolKind, SymbolMap, SymbolMapEntry, SymbolScope, SymbolSection, }; /// A table of symbol entries in a COFF or PE file. /// /// Also includes the string table used for the symbol names. #[derive(Debug)] pub struct SymbolTable<'data, R = &'data [u8]> where R: ReadRef<'data>, { symbols: &'data [pe::ImageSymbolBytes], strings: StringTable<'data, R>, } impl<'data, R: ReadRef<'data>> Default for SymbolTable<'data, R> { fn default() -> Self { Self { symbols: &[], strings: StringTable::default(), } } } impl<'data, R: ReadRef<'data>> SymbolTable<'data, R> { /// Read the symbol table. pub fn parse(header: &pe::ImageFileHeader, data: R) -> Result { // The symbol table may not be present. let mut offset = header.pointer_to_symbol_table.get(LE).into(); let (symbols, strings) = if offset != 0 { let symbols = data .read_slice(&mut offset, header.number_of_symbols.get(LE) as usize) .read_error("Invalid COFF symbol table offset or size")?; // Note: don't update data when reading length; the length includes itself. let length = data .read_at::>(offset) .read_error("Missing COFF string table")? .get(LE); let str_end = offset .checked_add(length as u64) .read_error("Invalid COFF string table length")?; let strings = StringTable::new(data, offset, str_end); (symbols, strings) } else { (&[][..], StringTable::default()) }; Ok(SymbolTable { symbols, strings }) } /// Return the string table used for the symbol names. #[inline] pub fn strings(&self) -> StringTable<'data, R> { self.strings } /// Return true if the symbol table is empty. #[inline] pub fn is_empty(&self) -> bool { self.symbols.is_empty() } /// The number of symbol table entries. /// /// This includes auxiliary symbol table entries. #[inline] pub fn len(&self) -> usize { self.symbols.len() } /// Iterate over the symbols. #[inline] pub fn iter<'table>(&'table self) -> SymbolIterator<'data, 'table, R> { SymbolIterator { symbols: self, index: 0, } } /// Return the symbol table entry at the given index. #[inline] pub fn symbol(&self, index: usize) -> Result<&'data pe::ImageSymbol> { self.get::(index, 0) } /// Return the auxiliary function symbol for the symbol table entry at the given index. /// /// Note that the index is of the symbol, not the first auxiliary record. #[inline] pub fn aux_function(&self, index: usize) -> Result<&'data pe::ImageAuxSymbolFunction> { self.get::(index, 1) } /// Return the auxiliary section symbol for the symbol table entry at the given index. /// /// Note that the index is of the symbol, not the first auxiliary record. #[inline] pub fn aux_section(&self, index: usize) -> Result<&'data pe::ImageAuxSymbolSection> { self.get::(index, 1) } /// Return the auxiliary file name for the symbol table entry at the given index. /// /// Note that the index is of the symbol, not the first auxiliary record. pub fn aux_file_name(&self, index: usize, aux_count: u8) -> Result<&'data [u8]> { let entries = index .checked_add(1) .and_then(|x| Some(x..x.checked_add(aux_count.into())?)) .and_then(|x| self.symbols.get(x)) .read_error("Invalid COFF symbol index")?; let bytes = bytes_of_slice(entries); // The name is padded with nulls. Ok(match memchr::memchr(b'\0', bytes) { Some(end) => &bytes[..end], None => bytes, }) } /// Return the symbol table entry or auxiliary record at the given index and offset. pub fn get(&self, index: usize, offset: usize) -> Result<&'data T> { let bytes = index .checked_add(offset) .and_then(|x| self.symbols.get(x)) .read_error("Invalid COFF symbol index")?; Bytes(&bytes.0[..]) .read() .read_error("Invalid COFF symbol data") } /// Construct a map from addresses to a user-defined map entry. pub fn map Option>( &self, f: F, ) -> SymbolMap { let mut symbols = Vec::with_capacity(self.symbols.len()); for (_, symbol) in self.iter() { if !symbol.is_definition() { continue; } if let Some(entry) = f(symbol) { symbols.push(entry); } } SymbolMap::new(symbols) } } /// An iterator for symbol entries in a COFF or PE file. /// /// Yields the index and symbol structure for each symbol. #[derive(Debug)] pub struct SymbolIterator<'data, 'table, R = &'data [u8]> where R: ReadRef<'data>, { symbols: &'table SymbolTable<'data, R>, index: usize, } impl<'data, 'table, R: ReadRef<'data>> Iterator for SymbolIterator<'data, 'table, R> { type Item = (usize, &'data pe::ImageSymbol); fn next(&mut self) -> Option { let index = self.index; let symbol = self.symbols.symbol(index).ok()?; self.index += 1 + symbol.number_of_aux_symbols as usize; Some((index, symbol)) } } impl pe::ImageSymbol { /// Parse a COFF symbol name. /// /// `strings` must be the string table used for symbol names. pub fn name<'data, R: ReadRef<'data>>( &'data self, strings: StringTable<'data, R>, ) -> Result<&'data [u8]> { if self.name[0] == 0 { // If the name starts with 0 then the last 4 bytes are a string table offset. let offset = u32::from_le_bytes(self.name[4..8].try_into().unwrap()); strings .get(offset) .read_error("Invalid COFF symbol name offset") } else { // The name is inline and padded with nulls. Ok(match memchr::memchr(b'\0', &self.name) { Some(end) => &self.name[..end], None => &self.name[..], }) } } /// Return the symbol address. /// /// This takes into account the image base and the section address. pub fn address(&self, image_base: u64, sections: &SectionTable) -> Result { let section_number = self.section_number.get(LE) as usize; let section = sections.section(section_number)?; let virtual_address = u64::from(section.virtual_address.get(LE)); let value = u64::from(self.value.get(LE)); Ok(image_base + virtual_address + value) } /// Return true if the symbol is a definition of a function or data object. pub fn is_definition(&self) -> bool { let section_number = self.section_number.get(LE); if section_number == pe::IMAGE_SYM_UNDEFINED { return false; } match self.storage_class { pe::IMAGE_SYM_CLASS_STATIC => { // Exclude section symbols. !(self.value.get(LE) == 0 && self.number_of_aux_symbols > 0) } pe::IMAGE_SYM_CLASS_EXTERNAL | pe::IMAGE_SYM_CLASS_WEAK_EXTERNAL => true, _ => false, } } /// Return true if the symbol has an auxiliary file name. pub fn has_aux_file_name(&self) -> bool { self.number_of_aux_symbols > 0 && self.storage_class == pe::IMAGE_SYM_CLASS_FILE } /// Return true if the symbol has an auxiliary function symbol. pub fn has_aux_function(&self) -> bool { self.number_of_aux_symbols > 0 && self.derived_type() == pe::IMAGE_SYM_DTYPE_FUNCTION } /// Return true if the symbol has an auxiliary section symbol. pub fn has_aux_section(&self) -> bool { self.number_of_aux_symbols > 0 && self.storage_class == pe::IMAGE_SYM_CLASS_STATIC && self.value.get(LE) == 0 } } /// A symbol table of a `CoffFile`. #[derive(Debug, Clone, Copy)] pub struct CoffSymbolTable<'data, 'file, R = &'data [u8]> where R: ReadRef<'data>, { pub(crate) file: &'file CoffCommon<'data, R>, } impl<'data, 'file, R: ReadRef<'data>> read::private::Sealed for CoffSymbolTable<'data, 'file, R> {} impl<'data, 'file, R: ReadRef<'data>> ObjectSymbolTable<'data> for CoffSymbolTable<'data, 'file, R> { type Symbol = CoffSymbol<'data, 'file, R>; type SymbolIterator = CoffSymbolIterator<'data, 'file, R>; fn symbols(&self) -> Self::SymbolIterator { CoffSymbolIterator { file: self.file, index: 0, } } fn symbol_by_index(&self, index: SymbolIndex) -> Result { let symbol = self.file.symbols.symbol(index.0)?; Ok(CoffSymbol { file: self.file, index, symbol, }) } } /// An iterator over the symbols of a `CoffFile`. pub struct CoffSymbolIterator<'data, 'file, R = &'data [u8]> where R: ReadRef<'data>, { pub(crate) file: &'file CoffCommon<'data, R>, pub(crate) index: usize, } impl<'data, 'file, R: ReadRef<'data>> fmt::Debug for CoffSymbolIterator<'data, 'file, R> { fn fmt(&self, f: &mut fmt::Formatter<'_>) -> fmt::Result { f.debug_struct("CoffSymbolIterator").finish() } } impl<'data, 'file, R: ReadRef<'data>> Iterator for CoffSymbolIterator<'data, 'file, R> { type Item = CoffSymbol<'data, 'file, R>; fn next(&mut self) -> Option { let index = self.index; let symbol = self.file.symbols.symbol(index).ok()?; self.index += 1 + symbol.number_of_aux_symbols as usize; Some(CoffSymbol { file: self.file, index: SymbolIndex(index), symbol, }) } } /// A symbol of a `CoffFile`. #[derive(Debug, Clone, Copy)] pub struct CoffSymbol<'data, 'file, R = &'data [u8]> where R: ReadRef<'data>, { pub(crate) file: &'file CoffCommon<'data, R>, pub(crate) index: SymbolIndex, pub(crate) symbol: &'data pe::ImageSymbol, } impl<'data, 'file, R: ReadRef<'data>> read::private::Sealed for CoffSymbol<'data, 'file, R> {} impl<'data, 'file, R: ReadRef<'data>> ObjectSymbol<'data> for CoffSymbol<'data, 'file, R> { #[inline] fn index(&self) -> SymbolIndex { self.index } fn name_bytes(&self) -> read::Result<&'data [u8]> { if self.symbol.has_aux_file_name() { self.file .symbols .aux_file_name(self.index.0, self.symbol.number_of_aux_symbols) } else { self.symbol.name(self.file.symbols.strings()) } } fn name(&self) -> read::Result<&'data str> { let name = self.name_bytes()?; str::from_utf8(name) .ok() .read_error("Non UTF-8 COFF symbol name") } fn address(&self) -> u64 { // Only return an address for storage classes that we know use an address. match self.symbol.storage_class { pe::IMAGE_SYM_CLASS_STATIC | pe::IMAGE_SYM_CLASS_WEAK_EXTERNAL | pe::IMAGE_SYM_CLASS_LABEL => {} pe::IMAGE_SYM_CLASS_EXTERNAL => { if self.symbol.section_number.get(LE) == pe::IMAGE_SYM_UNDEFINED { // Undefined or common data, neither of which have an address. return 0; } } _ => return 0, } self.symbol .address(self.file.image_base, &self.file.sections) .unwrap_or(0) } fn size(&self) -> u64 { match self.symbol.storage_class { pe::IMAGE_SYM_CLASS_STATIC => { // Section symbols may duplicate the size from the section table. if self.symbol.has_aux_section() { if let Ok(aux) = self.file.symbols.aux_section(self.index.0) { u64::from(aux.length.get(LE)) } else { 0 } } else { 0 } } pe::IMAGE_SYM_CLASS_EXTERNAL => { if self.symbol.section_number.get(LE) == pe::IMAGE_SYM_UNDEFINED { // For undefined symbols, symbol.value is 0 and the size is 0. // For common data, symbol.value is the size. u64::from(self.symbol.value.get(LE)) } else if self.symbol.has_aux_function() { // Function symbols may have a size. if let Ok(aux) = self.file.symbols.aux_function(self.index.0) { u64::from(aux.total_size.get(LE)) } else { 0 } } else { 0 } } // Most symbols don't have sizes. _ => 0, } } fn kind(&self) -> SymbolKind { let derived_kind = if self.symbol.derived_type() == pe::IMAGE_SYM_DTYPE_FUNCTION { SymbolKind::Text } else { SymbolKind::Data }; match self.symbol.storage_class { pe::IMAGE_SYM_CLASS_STATIC => { if self.symbol.value.get(LE) == 0 && self.symbol.number_of_aux_symbols > 0 { SymbolKind::Section } else { derived_kind } } pe::IMAGE_SYM_CLASS_EXTERNAL | pe::IMAGE_SYM_CLASS_WEAK_EXTERNAL => derived_kind, pe::IMAGE_SYM_CLASS_SECTION => SymbolKind::Section, pe::IMAGE_SYM_CLASS_FILE => SymbolKind::File, pe::IMAGE_SYM_CLASS_LABEL => SymbolKind::Label, _ => SymbolKind::Unknown, } } fn section(&self) -> SymbolSection { match self.symbol.section_number.get(LE) { pe::IMAGE_SYM_UNDEFINED => { if self.symbol.storage_class == pe::IMAGE_SYM_CLASS_EXTERNAL && self.symbol.value.get(LE) == 0 { SymbolSection::Undefined } else { SymbolSection::Common } } pe::IMAGE_SYM_ABSOLUTE => SymbolSection::Absolute, pe::IMAGE_SYM_DEBUG => { if self.symbol.storage_class == pe::IMAGE_SYM_CLASS_FILE { SymbolSection::None } else { SymbolSection::Unknown } } index if index > 0 => SymbolSection::Section(SectionIndex(index.into())), _ => SymbolSection::Unknown, } } #[inline] fn is_undefined(&self) -> bool { self.symbol.storage_class == pe::IMAGE_SYM_CLASS_EXTERNAL && self.symbol.section_number.get(LE) == pe::IMAGE_SYM_UNDEFINED && self.symbol.value.get(LE) == 0 } #[inline] fn is_definition(&self) -> bool { self.symbol.is_definition() } #[inline] fn is_common(&self) -> bool { self.symbol.storage_class == pe::IMAGE_SYM_CLASS_EXTERNAL && self.symbol.section_number.get(LE) == pe::IMAGE_SYM_UNDEFINED && self.symbol.value.get(LE) != 0 } #[inline] fn is_weak(&self) -> bool { self.symbol.storage_class == pe::IMAGE_SYM_CLASS_WEAK_EXTERNAL } #[inline] fn scope(&self) -> SymbolScope { match self.symbol.storage_class { pe::IMAGE_SYM_CLASS_EXTERNAL | pe::IMAGE_SYM_CLASS_WEAK_EXTERNAL => { // TODO: determine if symbol is exported SymbolScope::Linkage } _ => SymbolScope::Compilation, } } #[inline] fn is_global(&self) -> bool { match self.symbol.storage_class { pe::IMAGE_SYM_CLASS_EXTERNAL | pe::IMAGE_SYM_CLASS_WEAK_EXTERNAL => true, _ => false, } } #[inline] fn is_local(&self) -> bool { !self.is_global() } fn flags(&self) -> SymbolFlags { if self.symbol.has_aux_section() { if let Ok(aux) = self.file.symbols.aux_section(self.index.0) { // TODO: use high_number for bigobj let number = aux.number.get(LE) as usize; return SymbolFlags::CoffSection { selection: aux.selection, associative_section: if number == 0 { None } else { Some(SectionIndex(number)) }, }; } } SymbolFlags::None } }