//! Parse the Linux vDSO. //! //! The following code is transliterated from //! tools/testing/selftests/vDSO/parse_vdso.c in Linux 5.11, which is licensed //! with Creative Commons Zero License, version 1.0, //! available at <https://creativecommons.org/publicdomain/zero/1.0/legalcode> //! //! # Safety //! //! Parsing the vDSO involves a lot of raw pointer manipulation. This //! implementation follows Linux's reference implementation, and adds several //! additional safety checks. #![allow(unsafe_code)]
usesuper::c; usecrate::ffi::CStr; usecrate::utils::check_raw_pointer; use core::ffi::c_void; use core::mem::size_of; use core::ptr::{null, null_mut}; use linux_raw_sys::elf::*;
pub(super) struct Vdso { // Load information
load_addr: *const Elf_Ehdr,
load_end: *const c_void, // the end of the `PT_LOAD` segment
pv_offset: usize, // recorded paddr - recorded vaddr
// Version table
versym: *const u16,
verdef: *const Elf_Verdef,
}
// Straight from the ELF specification. fn elf_hash(name: &CStr) -> u32 { letmut h: u32 = 0; for b in name.to_bytes() {
h = (h << 4).wrapping_add(u32::from(*b)); let g = h & 0xf000_0000; if g != 0 {
h ^= g >> 24;
}
h &= !g;
}
h
}
/// Create a `Vdso` value by parsing the vDSO at the `sysinfo_ehdr` address. fn init_from_sysinfo_ehdr() -> Option<Vdso> { // SAFETY: The auxv initialization code does extensive checks to ensure // that the value we get really is an `AT_SYSINFO_EHDR` value from the // kernel. unsafe { let hdr = super::param::auxv::sysinfo_ehdr();
// If the platform doesn't provide a `AT_SYSINFO_EHDR`, we can't locate // the vDSO. if hdr.is_null() { return None;
}
let hdr = &*hdr; let pt = check_raw_pointer::<Elf_Phdr>(vdso.base_plus(hdr.e_phoff)? as *mut _)?.as_ptr(); letmut dyn_: *const Elf_Dyn = null(); letmut num_dyn = 0;
// We need two things from the segment table: the load offset // and the dynamic table. letmut found_vaddr = false; for i in0..hdr.e_phnum { let phdr = &*pt.add(i as usize); if phdr.p_flags & PF_W != 0 { // Don't trust any vDSO that claims to be loading writable // segments into memory. return None;
} if phdr.p_type == PT_LOAD && !found_vaddr { // The segment should be readable and executable, because it // contains the symbol table and the function bodies. if phdr.p_flags & (PF_R | PF_X) != (PF_R | PF_X) { return None;
}
found_vaddr = true;
vdso.load_end = vdso.base_plus(phdr.p_offset.checked_add(phdr.p_memsz)?)?;
vdso.pv_offset = phdr.p_offset.wrapping_sub(phdr.p_vaddr);
} elseif phdr.p_type == PT_DYNAMIC { // If `p_offset` is zero, it's more likely that we're looking // at memory that has been zeroed than that the kernel has // somehow aliased the `Ehdr` and the `Elf_Dyn` array. if phdr.p_offset < size_of::<Elf_Ehdr>() { return None;
}
dyn_ = check_raw_pointer::<Elf_Dyn>(vdso.base_plus(phdr.p_offset)? as *mut _)?
.as_ptr();
num_dyn = phdr.p_memsz / size_of::<Elf_Dyn>();
} elseif phdr.p_type == PT_INTERP || phdr.p_type == PT_GNU_RELRO { // Don't trust any ELF image that has an “interpreter” or // that uses RELRO, which is likely to be a user ELF image // rather and not the kernel vDSO. return None;
}
}
if !found_vaddr || dyn_.is_null() { return None; // Failed
}
// Fish out the useful bits of the dynamic table. letmut hash: *const u32 = null();
vdso.symstrings = null();
vdso.symtab = null();
vdso.versym = null();
vdso.verdef = null(); letmut i = 0; loop { if i == num_dyn { return None;
} let d = &*dyn_.add(i); match d.d_tag {
DT_STRTAB => {
vdso.symstrings =
check_raw_pointer::<u8>(vdso.addr_from_elf(d.d_un.d_ptr)? as *mut _)?
.as_ptr();
}
DT_SYMTAB => {
vdso.symtab =
check_raw_pointer::<Elf_Sym>(vdso.addr_from_elf(d.d_un.d_ptr)? as *mut _)?
.as_ptr();
}
DT_HASH => {
hash = check_raw_pointer::<u32>(vdso.addr_from_elf(d.d_un.d_ptr)? as *mut _)?
.as_ptr();
}
DT_VERSYM => {
vdso.versym =
check_raw_pointer::<u16>(vdso.addr_from_elf(d.d_un.d_ptr)? as *mut _)?
.as_ptr();
}
DT_VERDEF => {
vdso.verdef = check_raw_pointer::<Elf_Verdef>(
vdso.addr_from_elf(d.d_un.d_ptr)? as *mut _,
)?
.as_ptr();
}
DT_SYMENT => { if d.d_un.d_ptr != size_of::<Elf_Sym>() { return None; // Failed
}
}
DT_NULL => break,
_ => {}
}
i = i.checked_add(1)?;
} // The upstream code checks `symstrings`, `symtab`, and `hash` for // null; here, `check_raw_pointer` has already done that.
if vdso.verdef.is_null() {
vdso.versym = null();
}
impl Vdso { /// Parse the vDSO. /// /// Returns `None` if the vDSO can't be located or if it doesn't conform to /// our expectations. #[inline] pub(super) fn new() -> Option<Self> {
init_from_sysinfo_ehdr()
}
/// Check the version for a symbol. /// /// # Safety /// /// The raw pointers inside `self` must be valid. unsafefn match_version(&self, mut ver: u16, name: &CStr, hash: u32) -> bool { // This is a helper function to check if the version indexed by // ver matches name (which hashes to hash). // // The version definition table is a mess, and I don't know how // to do this in better than linear time without allocating memory // to build an index. I also don't know why the table has // variable size entries in the first place. // // For added fun, I can't find a comprehensible specification of how // to parse all the weird flags in the table. // // So I just parse the whole table every time.
// First step: find the version definition
ver &= 0x7fff; // Apparently bit 15 means "hidden" letmut def = self.verdef; loop { if (*def).vd_version != VER_DEF_CURRENT { returnfalse; // Failed
}
if ((*def).vd_flags & VER_FLG_BASE) == 0 && ((*def).vd_ndx & 0x7fff) == ver { break;
}
if (*def).vd_next == 0 { returnfalse; // No definition.
}
def = def
.cast::<u8>()
.add((*def).vd_next as usize)
.cast::<Elf_Verdef>();
}
// Now figure out whether it matches. let aux = &*(def.cast::<u8>())
.add((*def).vd_aux as usize)
.cast::<Elf_Verdaux>();
(*def).vd_hash == hash
&& (name == CStr::from_ptr(self.symstrings.add(aux.vda_name as usize).cast()))
}
/// Look up a symbol in the vDSO. pub(super) fn sym(&self, version: &CStr, name: &CStr) -> *mut c::c_void { let ver_hash = elf_hash(version); let name_hash = elf_hash(name);
// SAFETY: The pointers in `self` must be valid. unsafe { letmut chain = *self.bucket.add((name_hash % self.nbucket) as usize);
while chain != STN_UNDEF { let sym = &*self.symtab.add(chain as usize);
// Check for a defined global or weak function w/ right name. // // The reference parser in Linux's parse_vdso.c requires // symbols to have type `STT_FUNC`, but on powerpc64, the vDSO // uses `STT_NOTYPE`, so allow that too. if (ELF_ST_TYPE(sym.st_info) != STT_FUNC &&
ELF_ST_TYPE(sym.st_info) != STT_NOTYPE)
|| (ELF_ST_BIND(sym.st_info) != STB_GLOBAL
&& ELF_ST_BIND(sym.st_info) != STB_WEAK)
|| sym.st_shndx == SHN_UNDEF
|| sym.st_shndx == SHN_ABS
|| ELF_ST_VISIBILITY(sym.st_other) != STV_DEFAULT
|| (name != CStr::from_ptr(self.symstrings.add(sym.st_name as usize).cast())) // Check symbol version.
|| (!self.versym.is_null()
&& !self.match_version(*self.versym.add(chain as usize), version, ver_hash))
{
chain = *self.chain.add(chain as usize); continue;
}
let sum = self.addr_from_elf(sym.st_value).unwrap();
assert!(
sum as usize >= self.load_addr as usize
&& sum as usize <= self.load_end as usize
); return sum as *mut c::c_void;
}
}
null_mut()
}
/// Add the given address to the vDSO base address. unsafefn base_plus(&self, offset: usize) -> Option<*const c_void> { // Check for overflow. let _ = (self.load_addr as usize).checked_add(offset)?; // Add the offset to the base.
Some(self.load_addr.cast::<u8>().add(offset).cast())
}
/// Translate an ELF-address-space address into a usable virtual address. unsafefn addr_from_elf(&self, elf_addr: usize) -> Option<*const c_void> { self.base_plus(elf_addr.wrapping_add(self.pv_offset))
}
}
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