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#![ allow(non_camel_case_types, non_upper_case_globals) ]
use std ::mem ;
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use byteorder ::{ ByteOrder , LittleEndian } ;
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pub const DW_EH_PE_omit : u8 = 0xFF ;
pub const DW_EH_PE_absptr : u8 = 0x00 ;
pub const DW_EH_PE_uleb128 : u8 = 0x01 ;
pub const DW_EH_PE_udata2 : u8 = 0x02 ;
pub const DW_EH_PE_udata4 : u8 = 0x03 ;
pub const DW_EH_PE_udata8 : u8 = 0x04 ;
pub const DW_EH_PE_sleb128 : u8 = 0x09 ;
pub const DW_EH_PE_sdata2 : u8 = 0x0A ;
pub const DW_EH_PE_sdata4 : u8 = 0x0B ;
pub const DW_EH_PE_sdata8 : u8 = 0x0C ;
pub const DW_EH_PE_pcrel : u8 = 0x10 ;
pub const DW_EH_PE_textrel : u8 = 0x20 ;
pub const DW_EH_PE_datarel : u8 = 0x30 ;
pub const DW_EH_PE_funcrel : u8 = 0x40 ;
pub const DW_EH_PE_aligned : u8 = 0x50 ;
pub const DW_EH_PE_indirect : u8 = 0x80 ;
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pub struct DwarfReader < ' a > {
pub slice : & ' a [ u8 ] ,
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pub virt_addr : u32 ,
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base_slice : & ' a [ u8 ] ,
base_virt_addr : u32 ,
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}
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impl < ' a > DwarfReader < ' a > {
pub fn new ( slice : & [ u8 ] , virt_addr : u32 ) -> DwarfReader {
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DwarfReader { slice , virt_addr , base_slice : slice , base_virt_addr : virt_addr }
}
/// Creates a new instance from another instance of [DwarfReader], optionally removing any
/// offsets previously applied to the other instance.
pub fn from_reader ( other : & DwarfReader < ' a > , reset_offset : bool ) -> DwarfReader < ' a > {
if reset_offset {
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DwarfReader ::new ( other . base_slice , other . base_virt_addr )
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} else {
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DwarfReader ::new ( other . slice , other . virt_addr )
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}
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}
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pub fn offset ( & mut self , offset : u32 ) {
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self . slice = & self . slice [ offset as usize .. ] ;
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self . virt_addr = self . virt_addr . wrapping_add ( offset ) ;
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}
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/// ULEB128 and SLEB128 encodings are defined in Section 7.6 - "Variable Length Data" of the
/// [DWARF-4 Manual](https://dwarfstd.org/doc/DWARF4.pdf).
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pub fn read_uleb128 ( & mut self ) -> u64 {
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let mut shift : usize = 0 ;
let mut result : u64 = 0 ;
let mut byte : u8 ;
loop {
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byte = self . read_u8 ( ) ;
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result | = u64 ::from ( byte & 0x7F ) < < shift ;
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shift + = 7 ;
if byte & 0x80 = = 0 {
break ;
}
}
result
}
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pub fn read_sleb128 ( & mut self ) -> i64 {
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let mut shift : u32 = 0 ;
let mut result : u64 = 0 ;
let mut byte : u8 ;
loop {
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byte = self . read_u8 ( ) ;
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result | = u64 ::from ( byte & 0x7F ) < < shift ;
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shift + = 7 ;
if byte & 0x80 = = 0 {
break ;
}
}
// sign-extend
if shift < u64 ::BITS & & ( byte & 0x40 ) ! = 0 {
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result | = ( ! 0 u64 ) < < shift ;
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}
result as i64
}
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pub fn read_u8 ( & mut self ) -> u8 {
let val = self . slice [ 0 ] ;
self . slice = & self . slice [ 1 .. ] ;
val
}
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}
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macro_rules ! impl_read_fn {
( $( $type : ty , $byteorder_fn : ident ) ; * ) = > {
impl < ' a > DwarfReader < ' a > {
$(
pub fn $byteorder_fn ( & mut self ) -> $type {
let val = LittleEndian ::$byteorder_fn ( self . slice ) ;
self . slice = & self . slice [ mem ::size_of ::< $type > ( ) .. ] ;
val
}
) *
}
}
}
impl_read_fn! (
u16 , read_u16 ;
u32 , read_u32 ;
u64 , read_u64 ;
i16 , read_i16 ;
i32 , read_i32 ;
i64 , read_i64
) ;
pub struct DwarfWriter < ' a > {
pub slice : & ' a mut [ u8 ] ,
pub offset : usize ,
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}
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impl < ' a > DwarfWriter < ' a > {
pub fn new ( slice : & mut [ u8 ] ) -> DwarfWriter {
DwarfWriter { slice , offset : 0 }
}
pub fn write_u8 ( & mut self , data : u8 ) {
self . slice [ self . offset ] = data ;
self . offset + = 1 ;
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}
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pub fn write_u32 ( & mut self , data : u32 ) {
LittleEndian ::write_u32 ( & mut self . slice [ self . offset .. ] , data ) ;
self . offset + = 4 ;
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}
}
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fn read_encoded_pointer ( reader : & mut DwarfReader , encoding : u8 ) -> Result < usize , ( ) > {
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if encoding = = DW_EH_PE_omit {
return Err ( ( ) ) ;
}
// DW_EH_PE_aligned implies it's an absolute pointer value
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// However, we are linking library for 32-bits architecture
// The size of variable should be 4 bytes instead
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if encoding = = DW_EH_PE_aligned {
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let shifted_virt_addr = round_up ( reader . virt_addr as usize , mem ::size_of ::< u32 > ( ) ) ? ;
let addr_inc = shifted_virt_addr - reader . virt_addr as usize ;
reader . slice = & reader . slice [ addr_inc .. ] ;
reader . virt_addr = shifted_virt_addr as u32 ;
return Ok ( reader . read_u32 ( ) as usize ) ;
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}
match encoding & 0x0F {
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DW_EH_PE_absptr | DW_EH_PE_udata4 = > Ok ( reader . read_u32 ( ) as usize ) ,
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DW_EH_PE_uleb128 = > Ok ( reader . read_uleb128 ( ) as usize ) ,
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DW_EH_PE_udata2 = > Ok ( reader . read_u16 ( ) as usize ) ,
DW_EH_PE_udata8 = > Ok ( reader . read_u64 ( ) as usize ) ,
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DW_EH_PE_sleb128 = > Ok ( reader . read_sleb128 ( ) as usize ) ,
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DW_EH_PE_sdata2 = > Ok ( reader . read_i16 ( ) as usize ) ,
DW_EH_PE_sdata4 = > Ok ( reader . read_i32 ( ) as usize ) ,
DW_EH_PE_sdata8 = > Ok ( reader . read_i64 ( ) as usize ) ,
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_ = > Err ( ( ) ) ,
}
}
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fn read_encoded_pointer_with_pc ( reader : & mut DwarfReader , encoding : u8 ) -> Result < usize , ( ) > {
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let entry_virt_addr = reader . virt_addr ;
let mut result = read_encoded_pointer ( reader , encoding ) ? ;
// DW_EH_PE_aligned implies it's an absolute pointer value
if encoding = = DW_EH_PE_aligned {
return Ok ( result ) ;
}
result = match encoding & 0x70 {
DW_EH_PE_pcrel = > result . wrapping_add ( entry_virt_addr as usize ) ,
// .eh_frame normally would not have these kinds of relocations
// These would not be supported by a dedicated linker relocation schemes for RISC-V
DW_EH_PE_textrel | DW_EH_PE_datarel | DW_EH_PE_funcrel | DW_EH_PE_aligned = > {
unimplemented! ( )
}
// Other values should be impossible
_ = > unreachable! ( ) ,
} ;
if encoding & DW_EH_PE_indirect ! = 0 {
// There should not be a need for indirect addressing, as assembly code from
// the dynamic library should not be freely moved relative to the EH frame.
unreachable! ( )
}
Ok ( result )
}
#[ inline ]
fn round_up ( unrounded : usize , align : usize ) -> Result < usize , ( ) > {
if align . is_power_of_two ( ) {
Ok ( ( unrounded + align - 1 ) & ! ( align - 1 ) )
} else {
Err ( ( ) )
}
}
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/// Minimalistic structure to store everything needed for parsing FDEs to synthesize `.eh_frame_hdr`
/// section.
///
/// Refer to [The Linux Standard Base Core Specification, Generic Part](https://refspecs.linuxfoundation.org/LSB_5.0.0/LSB-Core-generic/LSB-Core-generic/ehframechpt.html)
/// for more information.
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pub struct EH_Frame < ' a > {
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reader : DwarfReader < ' a > ,
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}
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impl < ' a > EH_Frame < ' a > {
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/// Creates an [EH_Frame] using the bytes in the `.eh_frame` section and its address in the ELF
/// file.
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pub fn new ( eh_frame_slice : & [ u8 ] , eh_frame_addr : u32 ) -> EH_Frame {
EH_Frame { reader : DwarfReader ::new ( eh_frame_slice , eh_frame_addr ) }
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}
/// Returns an [Iterator] over all Call Frame Information (CFI) records.
pub fn cfi_records ( & self ) -> CFI_Records < ' a > {
let reader = DwarfReader ::from_reader ( & self . reader , true ) ;
let len = reader . slice . len ( ) ;
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CFI_Records { reader , available : len }
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}
}
/// A single Call Frame Information (CFI) record.
///
/// From the [specification](https://refspecs.linuxfoundation.org/LSB_5.0.0/LSB-Core-generic/LSB-Core-generic/ehframechpt.html):
///
/// > Each CFI record contains a Common Information Entry (CIE) record followed by 1 or more Frame
/// Description Entry (FDE) records.
pub struct CFI_Record < ' a > {
// It refers to the augmentation data that corresponds to 'R' in the augmentation string
fde_pointer_encoding : u8 ,
fde_reader : DwarfReader < ' a > ,
}
impl < ' a > CFI_Record < ' a > {
pub fn from_reader ( cie_reader : & mut DwarfReader < ' a > ) -> Result < CFI_Record < ' a > , ( ) > {
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let length = cie_reader . read_u32 ( ) ;
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let fde_reader = match length {
// eh_frame with 0 lengths means the CIE is terminated
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0 = > panic! ( " Cannot create an EH_Frame from a termination CIE " ) ,
// length == u32::MAX means that the length is only representable with 64 bits,
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// which does not make sense in a system with 32-bit address.
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0xFFFF_FFFF = > unimplemented! ( ) ,
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_ = > {
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let mut fde_reader = DwarfReader ::from_reader ( cie_reader , false ) ;
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fde_reader . offset ( length ) ;
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fde_reader
}
} ;
// Routine check on the .eh_frame well-formness, in terms of CIE ID & Version args.
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let cie_ptr = cie_reader . read_u32 ( ) ;
assert_eq! ( cie_ptr , 0 ) ;
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assert_eq! ( cie_reader . read_u8 ( ) , 1 ) ;
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// Parse augmentation string
// The first character must be 'z', there is no way to proceed otherwise
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assert_eq! ( cie_reader . read_u8 ( ) , b 'z' ) ;
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// Establish a pointer that skips ahead of the string
// Skip code/data alignment factors & return address register along the way as well
// We only tackle the case where 'z' and 'R' are part of the augmentation string, otherwise
// we cannot get the addresses to make .eh_frame_hdr
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let mut aug_data_reader = DwarfReader ::from_reader ( cie_reader , false ) ;
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let mut aug_str_len = 0 ;
loop {
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if aug_data_reader . read_u8 ( ) = = b '\0' {
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break ;
}
aug_str_len + = 1 ;
}
if aug_str_len = = 0 {
unimplemented! ( ) ;
}
aug_data_reader . read_uleb128 ( ) ; // Code alignment factor
aug_data_reader . read_sleb128 ( ) ; // Data alignment factor
aug_data_reader . read_uleb128 ( ) ; // Return address register
aug_data_reader . read_uleb128 ( ) ; // Augmentation data length
let mut fde_pointer_encoding = DW_EH_PE_omit ;
for _ in 0 .. aug_str_len {
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match cie_reader . read_u8 ( ) {
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b 'L' = > {
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aug_data_reader . read_u8 ( ) ;
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}
b 'P' = > {
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let encoding = aug_data_reader . read_u8 ( ) ;
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read_encoded_pointer ( & mut aug_data_reader , encoding ) ? ;
}
b 'R' = > {
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fde_pointer_encoding = aug_data_reader . read_u8 ( ) ;
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}
// Other characters are not supported
_ = > unimplemented! ( ) ,
}
}
assert_ne! ( fde_pointer_encoding , DW_EH_PE_omit ) ;
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Ok ( CFI_Record { fde_pointer_encoding , fde_reader } )
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}
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/// Returns a [DwarfReader] initialized to the first Frame Description Entry (FDE) of this CFI
/// record.
pub fn get_fde_reader ( & self ) -> DwarfReader < ' a > {
DwarfReader ::from_reader ( & self . fde_reader , true )
}
/// Returns an [Iterator] over all Frame Description Entries (FDEs).
pub fn fde_records ( & self ) -> FDE_Records < ' a > {
let reader = self . get_fde_reader ( ) ;
let len = reader . slice . len ( ) ;
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FDE_Records { pointer_encoding : self . fde_pointer_encoding , reader , available : len }
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}
}
/// [Iterator] over Call Frame Information (CFI) records in an
/// [Exception Handling (EH) frame][EH_Frame].
pub struct CFI_Records < ' a > {
reader : DwarfReader < ' a > ,
available : usize ,
}
impl < ' a > Iterator for CFI_Records < ' a > {
type Item = CFI_Record < ' a > ;
fn next ( & mut self ) -> Option < Self ::Item > {
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loop {
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if self . available = = 0 {
return None ;
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}
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let mut this_reader = DwarfReader ::from_reader ( & self . reader , false ) ;
// Remove the length of the header and the content from the counter
let length = self . reader . read_u32 ( ) ;
let length = match length {
// eh_frame with 0-length means the CIE is terminated
0 = > return None ,
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0xFFFF_FFFF = > unimplemented! ( " CIE entries larger than 4 bytes not supported " ) ,
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other = > other ,
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} as usize ;
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// Remove the length of the header and the content from the counter
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self . available - = length + mem ::size_of ::< u32 > ( ) ;
let mut next_reader = DwarfReader ::from_reader ( & self . reader , false ) ;
next_reader . offset ( length as u32 ) ;
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let cie_ptr = self . reader . read_u32 ( ) ;
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self . reader = next_reader ;
// Skip this record if it is a FDE
if cie_ptr = = 0 {
// Rewind back to the start of the CFI Record
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return Some ( CFI_Record ::from_reader ( & mut this_reader ) . ok ( ) . unwrap ( ) ) ;
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}
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}
}
}
/// [Iterator] over Frame Description Entries (FDEs) in an
/// [Exception Handling (EH) frame][EH_Frame].
pub struct FDE_Records < ' a > {
pointer_encoding : u8 ,
reader : DwarfReader < ' a > ,
available : usize ,
}
impl < ' a > Iterator for FDE_Records < ' a > {
type Item = ( u32 , u32 ) ;
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fn next ( & mut self ) -> Option < Self ::Item > {
// Parse each FDE to obtain the starting address that the FDE applies to
// Send the FDE offset and the mentioned address to a callback that write up the
// .eh_frame_hdr section
if self . available = = 0 {
return None ;
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}
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// Remove the length of the header and the content from the counter
let length = match self . reader . read_u32 ( ) {
// eh_frame with 0-length means the CIE is terminated
0 = > return None ,
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0xFFFF_FFFF = > unimplemented! ( " CIE entries larger than 4 bytes not supported " ) ,
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other = > other ,
} as usize ;
// Remove the length of the header and the content from the counter
self . available - = length + mem ::size_of ::< u32 > ( ) ;
let mut next_fde_reader = DwarfReader ::from_reader ( & self . reader , false ) ;
next_fde_reader . offset ( length as u32 ) ;
let cie_ptr = self . reader . read_u32 ( ) ;
let next_val = if cie_ptr ! = 0 {
let pc_begin = read_encoded_pointer_with_pc ( & mut self . reader , self . pointer_encoding )
. expect ( " Failed to read PC Begin " ) ;
Some ( ( pc_begin as u32 , self . reader . virt_addr ) )
} else {
None
} ;
self . reader = next_fde_reader ;
next_val
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}
}
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pub struct EH_Frame_Hdr < ' a > {
fde_writer : DwarfWriter < ' a > ,
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eh_frame_hdr_addr : u32 ,
fdes : Vec < ( u32 , u32 ) > ,
}
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impl < ' a > EH_Frame_Hdr < ' a > {
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/// Create a [EH_Frame_Hdr] object, and write out the fixed fields of `.eh_frame_hdr` to memory.
///
/// Load address is not known at this point.
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pub fn new (
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eh_frame_hdr_slice : & mut [ u8 ] ,
eh_frame_hdr_addr : u32 ,
eh_frame_addr : u32 ,
) -> EH_Frame_Hdr {
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let mut writer = DwarfWriter ::new ( eh_frame_hdr_slice ) ;
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writer . write_u8 ( 1 ) ; // version
writer . write_u8 ( 0x1B ) ; // eh_frame_ptr_enc - PC-relative 4-byte signed value
writer . write_u8 ( 0x03 ) ; // fde_count_enc - 4-byte unsigned value
writer . write_u8 ( 0x3B ) ; // table_enc - .eh_frame_hdr section-relative 4-byte signed value
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let eh_frame_offset = eh_frame_addr . wrapping_sub (
eh_frame_hdr_addr + writer . offset as u32 + ( ( mem ::size_of ::< u8 > ( ) as u32 ) * 4 ) ,
) ;
writer . write_u32 ( eh_frame_offset ) ; // eh_frame_ptr
writer . write_u32 ( 0 ) ; // `fde_count`, will be written in finalize_fde
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EH_Frame_Hdr { fde_writer : writer , eh_frame_hdr_addr , fdes : Vec ::new ( ) }
}
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/// The offset of the `fde_count` value relative to the start of the `.eh_frame_hdr` section in
/// bytes.
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fn fde_count_offset ( ) -> usize {
8
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}
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pub fn add_fde ( & mut self , init_loc : u32 , addr : u32 ) {
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self . fdes . push ( (
init_loc . wrapping_sub ( self . eh_frame_hdr_addr ) ,
addr . wrapping_sub ( self . eh_frame_hdr_addr ) ,
) ) ;
}
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pub fn finalize_fde ( mut self ) {
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self . fdes
. sort_by ( | ( left_init_loc , _ ) , ( right_init_loc , _ ) | left_init_loc . cmp ( right_init_loc ) ) ;
for ( init_loc , addr ) in & self . fdes {
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self . fde_writer . write_u32 ( * init_loc ) ;
self . fde_writer . write_u32 ( * addr ) ;
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}
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LittleEndian ::write_u32 (
& mut self . fde_writer . slice [ Self ::fde_count_offset ( ) .. ] ,
self . fdes . len ( ) as u32 ,
) ;
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}
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pub fn size_from_eh_frame ( eh_frame : & [ u8 ] ) -> usize {
// The virtual address of the EH frame does not matter in this case
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// Calculation of size does not involve modifying any headers
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let mut reader = DwarfReader ::new ( eh_frame , 0 ) ;
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let mut fde_count = 0 ;
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while ! reader . slice . is_empty ( ) {
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// The original length field should be able to hold the entire value.
// The device memory space is limited to 32-bits addresses anyway.
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let entry_length = reader . read_u32 ( ) ;
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if entry_length = = 0 | | entry_length = = 0xFFFF_FFFF {
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unimplemented! ( )
}
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// This slot stores the CIE ID (for CIE)/CIE Pointer (for FDE).
// This value must be non-zero for FDEs.
let cie_ptr = reader . read_u32 ( ) ;
if cie_ptr ! = 0 {
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fde_count + = 1 ;
}
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reader . offset ( entry_length - mem ::size_of ::< u32 > ( ) as u32 ) ;
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}
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12 + fde_count * 8
}
}