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aya/aya-obj/src/obj.rs

2660 lines
84 KiB
Rust

//! Object file loading, parsing, and relocation.
use alloc::{
borrow::ToOwned,
collections::BTreeMap,
ffi::CString,
string::{String, ToString},
vec::Vec,
};
use core::{ffi::CStr, mem, ptr, str::FromStr};
use log::debug;
use object::{
read::{Object as ElfObject, ObjectSection, Section as ObjSection},
Endianness, ObjectSymbol, ObjectSymbolTable, RelocationTarget, SectionIndex, SectionKind,
SymbolKind,
};
use crate::{
btf::BtfFeatures,
generated::{BPF_CALL, BPF_JMP, BPF_K},
maps::{BtfMap, LegacyMap, Map, MINIMUM_MAP_SIZE},
programs::XdpAttachType,
relocation::*,
util::HashMap,
};
#[cfg(not(feature = "std"))]
use crate::std;
use crate::{
btf::{Btf, BtfError, BtfExt, BtfType},
generated::{bpf_insn, bpf_map_info, bpf_map_type::BPF_MAP_TYPE_ARRAY, BPF_F_RDONLY_PROG},
maps::{bpf_map_def, BtfMapDef, PinningType},
programs::{CgroupSockAddrAttachType, CgroupSockAttachType, CgroupSockoptAttachType},
};
use core::slice::from_raw_parts_mut;
use crate::btf::{Array, DataSecEntry, FuncSecInfo, LineSecInfo};
const KERNEL_VERSION_ANY: u32 = 0xFFFF_FFFE;
/// Features implements BPF and BTF feature detection
#[derive(Default, Debug)]
#[allow(missing_docs)]
pub struct Features {
bpf_name: bool,
bpf_probe_read_kernel: bool,
bpf_perf_link: bool,
bpf_global_data: bool,
bpf_cookie: bool,
btf: Option<BtfFeatures>,
}
impl Features {
#[doc(hidden)]
pub fn new(
bpf_name: bool,
bpf_probe_read_kernel: bool,
bpf_perf_link: bool,
bpf_global_data: bool,
bpf_cookie: bool,
btf: Option<BtfFeatures>,
) -> Self {
Self {
bpf_name,
bpf_probe_read_kernel,
bpf_perf_link,
bpf_global_data,
bpf_cookie,
btf,
}
}
/// Returns whether BPF program names are supported.
pub fn bpf_name(&self) -> bool {
self.bpf_name
}
/// Returns whether the bpf_probe_read_kernel helper is supported.
pub fn bpf_probe_read_kernel(&self) -> bool {
self.bpf_probe_read_kernel
}
/// Returns whether bpf_links are supported for Kprobes/Uprobes/Tracepoints.
pub fn bpf_perf_link(&self) -> bool {
self.bpf_perf_link
}
/// Returns whether BPF program global data is supported.
pub fn bpf_global_data(&self) -> bool {
self.bpf_global_data
}
/// Returns whether BPF program cookie is supported.
pub fn bpf_cookie(&self) -> bool {
self.bpf_cookie
}
/// If BTF is supported, returns which BTF features are supported.
pub fn btf(&self) -> Option<&BtfFeatures> {
self.btf.as_ref()
}
}
/// The loaded object file representation
#[derive(Clone, Debug)]
pub struct Object {
/// The endianness
pub endianness: Endianness,
/// Program license
pub license: CString,
/// Kernel version
pub kernel_version: Option<u32>,
/// Program BTF
pub btf: Option<Btf>,
/// Program BTF.ext
pub btf_ext: Option<BtfExt>,
/// Referenced maps
pub maps: HashMap<String, Map>,
/// A hash map of programs, using the program names parsed
/// in [ProgramSection]s as keys.
pub programs: HashMap<String, Program>,
/// Functions
pub functions: BTreeMap<(usize, u64), Function>,
pub(crate) relocations: HashMap<SectionIndex, HashMap<u64, Relocation>>,
pub(crate) symbol_table: HashMap<usize, Symbol>,
pub(crate) symbols_by_section: HashMap<SectionIndex, Vec<usize>>,
pub(crate) section_infos: HashMap<String, (SectionIndex, u64)>,
// symbol_offset_by_name caches symbols that could be referenced from a
// BTF VAR type so the offsets can be fixed up
pub(crate) symbol_offset_by_name: HashMap<String, u64>,
}
/// An eBPF program
#[derive(Debug, Clone)]
pub struct Program {
/// The license
pub license: CString,
/// The kernel version
pub kernel_version: Option<u32>,
/// The section containing the program
pub section: ProgramSection,
/// The section index of the program
pub section_index: usize,
/// The address of the program
pub address: u64,
}
impl Program {
/// The key used by [Object::functions]
pub fn function_key(&self) -> (usize, u64) {
(self.section_index, self.address)
}
}
/// An eBPF function
#[derive(Debug, Clone)]
pub struct Function {
/// The address
pub address: u64,
/// The function name
pub name: String,
/// The section index
pub section_index: SectionIndex,
/// The section offset
pub section_offset: usize,
/// The eBPF byte code instructions
pub instructions: Vec<bpf_insn>,
/// The function info
pub func_info: FuncSecInfo,
/// The line info
pub line_info: LineSecInfo,
/// Function info record size
pub func_info_rec_size: usize,
/// Line info record size
pub line_info_rec_size: usize,
}
/// Section types containing eBPF programs
///
/// # Section Name Parsing
///
/// Section types are parsed from the section name strings.
///
/// In order for Aya to treat a section as a [ProgramSection],
/// there are a few requirements:
/// - The section must be an executable code section.
/// - The section name must conform to [Program Types and ELF Sections].
///
/// [Program Types and ELF Sections]: https://docs.kernel.org/bpf/libbpf/program_types.html
///
/// # Unsupported Sections
///
/// Currently, the following section names are not supported yet:
/// - `flow_dissector`: `BPF_PROG_TYPE_FLOW_DISSECTOR`
/// - `ksyscall+` or `kretsyscall+`
/// - `usdt+`
/// - `kprobe.multi+` or `kretprobe.multi+`: `BPF_TRACE_KPROBE_MULTI`
/// - `lsm_cgroup+`
/// - `lwt_in`, `lwt_out`, `lwt_seg6local`, `lwt_xmit`
/// - `raw_tp.w+`, `raw_tracepoint.w+`
/// - `action`
/// - `sk_reuseport/migrate`, `sk_reuseport`
/// - `syscall`
/// - `struct_ops+`
/// - `fmod_ret+`, `fmod_ret.s+`
/// - `iter+`, `iter.s+`
#[derive(Debug, Clone)]
#[allow(missing_docs)]
pub enum ProgramSection {
KRetProbe,
KProbe,
UProbe {
sleepable: bool,
},
URetProbe {
sleepable: bool,
},
TracePoint,
SocketFilter,
Xdp {
frags: bool,
attach_type: XdpAttachType,
},
SkMsg,
SkSkbStreamParser,
SkSkbStreamVerdict,
SockOps,
SchedClassifier,
CgroupSkb,
CgroupSkbIngress,
CgroupSkbEgress,
CgroupSockAddr {
attach_type: CgroupSockAddrAttachType,
},
CgroupSysctl,
CgroupSockopt {
attach_type: CgroupSockoptAttachType,
},
LircMode2,
PerfEvent,
RawTracePoint,
Lsm {
sleepable: bool,
},
BtfTracePoint,
FEntry {
sleepable: bool,
},
FExit {
sleepable: bool,
},
Extension,
SkLookup,
CgroupSock {
attach_type: CgroupSockAttachType,
},
CgroupDevice,
}
impl FromStr for ProgramSection {
type Err = ParseError;
fn from_str(section: &str) -> Result<ProgramSection, ParseError> {
use ProgramSection::*;
// parse the common case, eg "xdp/program_name" or
// "sk_skb/stream_verdict/program_name"
let mut pieces = section.split('/');
let mut next = || {
pieces
.next()
.ok_or_else(|| ParseError::InvalidProgramSection {
section: section.to_owned(),
})
};
let kind = next()?;
Ok(match kind {
"kprobe" => KProbe,
"kretprobe" => KRetProbe,
"uprobe" => UProbe { sleepable: false },
"uprobe.s" => UProbe { sleepable: true },
"uretprobe" => URetProbe { sleepable: false },
"uretprobe.s" => URetProbe { sleepable: true },
"xdp" | "xdp.frags" => Xdp {
frags: kind == "xdp.frags",
attach_type: match pieces.next() {
None => XdpAttachType::Interface,
Some("cpumap") => XdpAttachType::CpuMap,
Some("devmap") => XdpAttachType::DevMap,
Some(_) => {
return Err(ParseError::InvalidProgramSection {
section: section.to_owned(),
})
}
},
},
"tp_btf" => BtfTracePoint,
"tracepoint" | "tp" => TracePoint,
"socket" => SocketFilter,
"sk_msg" => SkMsg,
"sk_skb" => {
let name = next()?;
match name {
"stream_parser" => SkSkbStreamParser,
"stream_verdict" => SkSkbStreamVerdict,
_ => {
return Err(ParseError::InvalidProgramSection {
section: section.to_owned(),
})
}
}
}
"sockops" => SockOps,
"classifier" => SchedClassifier,
"cgroup_skb" => {
let name = next()?;
match name {
"ingress" => CgroupSkbIngress,
"egress" => CgroupSkbEgress,
_ => {
return Err(ParseError::InvalidProgramSection {
section: section.to_owned(),
})
}
}
}
"cgroup" => {
let name = next()?;
match name {
"skb" => CgroupSkb,
"sysctl" => CgroupSysctl,
"dev" => CgroupDevice,
"getsockopt" => CgroupSockopt {
attach_type: CgroupSockoptAttachType::Get,
},
"setsockopt" => CgroupSockopt {
attach_type: CgroupSockoptAttachType::Set,
},
"sock" => CgroupSock {
attach_type: CgroupSockAttachType::default(),
},
"post_bind4" => CgroupSock {
attach_type: CgroupSockAttachType::PostBind4,
},
"post_bind6" => CgroupSock {
attach_type: CgroupSockAttachType::PostBind6,
},
"sock_create" => CgroupSock {
attach_type: CgroupSockAttachType::SockCreate,
},
"sock_release" => CgroupSock {
attach_type: CgroupSockAttachType::SockRelease,
},
"bind4" => CgroupSockAddr {
attach_type: CgroupSockAddrAttachType::Bind4,
},
"bind6" => CgroupSockAddr {
attach_type: CgroupSockAddrAttachType::Bind6,
},
"connect4" => CgroupSockAddr {
attach_type: CgroupSockAddrAttachType::Connect4,
},
"connect6" => CgroupSockAddr {
attach_type: CgroupSockAddrAttachType::Connect6,
},
"getpeername4" => CgroupSockAddr {
attach_type: CgroupSockAddrAttachType::GetPeerName4,
},
"getpeername6" => CgroupSockAddr {
attach_type: CgroupSockAddrAttachType::GetPeerName6,
},
"getsockname4" => CgroupSockAddr {
attach_type: CgroupSockAddrAttachType::GetSockName4,
},
"getsockname6" => CgroupSockAddr {
attach_type: CgroupSockAddrAttachType::GetSockName6,
},
"sendmsg4" => CgroupSockAddr {
attach_type: CgroupSockAddrAttachType::UDPSendMsg4,
},
"sendmsg6" => CgroupSockAddr {
attach_type: CgroupSockAddrAttachType::UDPSendMsg6,
},
"recvmsg4" => CgroupSockAddr {
attach_type: CgroupSockAddrAttachType::UDPRecvMsg4,
},
"recvmsg6" => CgroupSockAddr {
attach_type: CgroupSockAddrAttachType::UDPRecvMsg6,
},
_ => {
return Err(ParseError::InvalidProgramSection {
section: section.to_owned(),
});
}
}
}
"lirc_mode2" => LircMode2,
"perf_event" => PerfEvent,
"raw_tp" | "raw_tracepoint" => RawTracePoint,
"lsm" => Lsm { sleepable: false },
"lsm.s" => Lsm { sleepable: true },
"fentry" => FEntry { sleepable: false },
"fentry.s" => FEntry { sleepable: true },
"fexit" => FExit { sleepable: false },
"fexit.s" => FExit { sleepable: true },
"freplace" => Extension,
"sk_lookup" => SkLookup,
_ => {
return Err(ParseError::InvalidProgramSection {
section: section.to_owned(),
})
}
})
}
}
impl Object {
/// Parses the binary data as an object file into an [Object]
pub fn parse(data: &[u8]) -> Result<Object, ParseError> {
let obj = object::read::File::parse(data).map_err(ParseError::ElfError)?;
let endianness = obj.endianness();
let license = if let Some(section) = obj.section_by_name("license") {
parse_license(Section::try_from(&section)?.data)?
} else {
CString::new("GPL").unwrap()
};
let kernel_version = if let Some(section) = obj.section_by_name("version") {
parse_version(Section::try_from(&section)?.data, endianness)?
} else {
None
};
let mut bpf_obj = Object::new(endianness, license, kernel_version);
if let Some(symbol_table) = obj.symbol_table() {
for symbol in symbol_table.symbols() {
let name = symbol
.name()
.ok()
.map(String::from)
.ok_or(BtfError::InvalidSymbolName)?;
let sym = Symbol {
index: symbol.index().0,
name: Some(name.clone()),
section_index: symbol.section().index().map(|i| i.0),
address: symbol.address(),
size: symbol.size(),
is_definition: symbol.is_definition(),
kind: symbol.kind(),
};
bpf_obj.symbol_table.insert(symbol.index().0, sym);
if let Some(section_idx) = symbol.section().index() {
bpf_obj
.symbols_by_section
.entry(section_idx)
.or_default()
.push(symbol.index().0);
}
if symbol.is_global() || symbol.kind() == SymbolKind::Data {
bpf_obj.symbol_offset_by_name.insert(name, symbol.address());
}
}
}
// .BTF and .BTF.ext sections must be parsed first
// as they're required to prepare function and line information
// when parsing program sections
if let Some(s) = obj.section_by_name(".BTF") {
bpf_obj.parse_section(Section::try_from(&s)?)?;
if let Some(s) = obj.section_by_name(".BTF.ext") {
bpf_obj.parse_section(Section::try_from(&s)?)?;
}
}
for s in obj.sections() {
if let Ok(name) = s.name() {
if name == ".BTF" || name == ".BTF.ext" {
continue;
}
}
bpf_obj.parse_section(Section::try_from(&s)?)?;
}
Ok(bpf_obj)
}
fn new(endianness: Endianness, license: CString, kernel_version: Option<u32>) -> Object {
Object {
endianness,
license,
kernel_version,
btf: None,
btf_ext: None,
maps: HashMap::new(),
programs: HashMap::new(),
functions: BTreeMap::new(),
relocations: HashMap::new(),
symbol_table: HashMap::new(),
symbols_by_section: HashMap::new(),
section_infos: HashMap::new(),
symbol_offset_by_name: HashMap::new(),
}
}
/// Patches map data
pub fn patch_map_data(
&mut self,
globals: HashMap<&str, (&[u8], bool)>,
) -> Result<(), ParseError> {
let symbols: HashMap<String, &Symbol> = self
.symbol_table
.iter()
.filter(|(_, s)| s.name.is_some())
.map(|(_, s)| (s.name.as_ref().unwrap().clone(), s))
.collect();
for (name, (data, must_exist)) in globals {
if let Some(symbol) = symbols.get(name) {
if data.len() as u64 != symbol.size {
return Err(ParseError::InvalidGlobalData {
name: name.to_string(),
sym_size: symbol.size,
data_size: data.len(),
});
}
let (_, map) = self
.maps
.iter_mut()
// assumption: there is only one map created per section where we're trying to
// patch data. this assumption holds true for the .rodata section at least
.find(|(_, m)| symbol.section_index == Some(m.section_index()))
.ok_or_else(|| ParseError::MapNotFound {
index: symbol.section_index.unwrap_or(0),
})?;
let start = symbol.address as usize;
let end = start + symbol.size as usize;
if start > end || end > map.data().len() {
return Err(ParseError::InvalidGlobalData {
name: name.to_string(),
sym_size: symbol.size,
data_size: data.len(),
});
}
map.data_mut().splice(start..end, data.iter().cloned());
} else if must_exist {
return Err(ParseError::SymbolNotFound {
name: name.to_owned(),
});
}
}
Ok(())
}
fn parse_btf(&mut self, section: &Section) -> Result<(), BtfError> {
self.btf = Some(Btf::parse(section.data, self.endianness)?);
Ok(())
}
fn parse_btf_ext(&mut self, section: &Section) -> Result<(), BtfError> {
self.btf_ext = Some(BtfExt::parse(
section.data,
self.endianness,
self.btf.as_ref().unwrap(),
)?);
Ok(())
}
fn parse_programs(&mut self, section: &Section) -> Result<(), ParseError> {
let program_section = ProgramSection::from_str(section.name)?;
let syms =
self.symbols_by_section
.get(&section.index)
.ok_or(ParseError::NoSymbolsForSection {
section_name: section.name.to_string(),
})?;
for symbol_index in syms {
let symbol = self
.symbol_table
.get(symbol_index)
.expect("all symbols in symbols_by_section are also in symbol_table");
let Some(name) = symbol.name.as_ref() else {
continue;
};
if name.is_empty() {
continue;
}
let (p, f) =
self.parse_program(section, program_section.clone(), name.to_string(), symbol)?;
let key = p.function_key();
self.programs.insert(f.name.clone(), p);
self.functions.insert(key, f);
}
Ok(())
}
fn parse_program(
&self,
section: &Section,
program_section: ProgramSection,
name: String,
symbol: &Symbol,
) -> Result<(Program, Function), ParseError> {
let offset = symbol.address as usize - section.address as usize;
let (func_info, line_info, func_info_rec_size, line_info_rec_size) =
get_func_and_line_info(self.btf_ext.as_ref(), symbol, section, offset, true);
let start = symbol.address as usize;
let end = (symbol.address + symbol.size) as usize;
let function = Function {
name: name.to_owned(),
address: symbol.address,
section_index: section.index,
section_offset: start,
instructions: copy_instructions(&section.data[start..end])?,
func_info,
line_info,
func_info_rec_size,
line_info_rec_size,
};
Ok((
Program {
license: self.license.clone(),
kernel_version: self.kernel_version,
section: program_section.clone(),
section_index: section.index.0,
address: symbol.address,
},
function,
))
}
fn parse_text_section(&mut self, section: Section) -> Result<(), ParseError> {
let mut symbols_by_address = HashMap::new();
for sym in self.symbol_table.values() {
if sym.is_definition
&& sym.kind == SymbolKind::Text
&& sym.section_index == Some(section.index.0)
{
if symbols_by_address.contains_key(&sym.address) {
return Err(ParseError::SymbolTableConflict {
section_index: section.index.0,
address: sym.address,
});
}
symbols_by_address.insert(sym.address, sym);
}
}
let mut offset = 0;
while offset < section.data.len() {
let address = section.address + offset as u64;
let sym = symbols_by_address
.get(&address)
.ok_or(ParseError::UnknownSymbol {
section_index: section.index.0,
address,
})?;
if sym.size == 0 {
return Err(ParseError::InvalidSymbol {
index: sym.index,
name: sym.name.clone(),
});
}
let (func_info, line_info, func_info_rec_size, line_info_rec_size) =
get_func_and_line_info(self.btf_ext.as_ref(), sym, &section, offset, false);
self.functions.insert(
(section.index.0, sym.address),
Function {
address,
name: sym.name.clone().unwrap(),
section_index: section.index,
section_offset: offset,
instructions: copy_instructions(
&section.data[offset..offset + sym.size as usize],
)?,
func_info,
line_info,
func_info_rec_size,
line_info_rec_size,
},
);
offset += sym.size as usize;
}
if !section.relocations.is_empty() {
self.relocations.insert(
section.index,
section
.relocations
.into_iter()
.map(|rel| (rel.offset, rel))
.collect(),
);
}
Ok(())
}
fn parse_btf_maps(&mut self, section: &Section) -> Result<(), ParseError> {
if self.btf.is_none() {
return Err(ParseError::NoBTF);
}
let btf = self.btf.as_ref().unwrap();
let maps: HashMap<&String, usize> = self
.symbols_by_section
.get(&section.index)
.ok_or(ParseError::NoSymbolsForSection {
section_name: section.name.to_owned(),
})?
.iter()
.filter_map(|s| {
let symbol = self.symbol_table.get(s).unwrap();
symbol.name.as_ref().map(|name| (name, symbol.index))
})
.collect();
for t in btf.types() {
if let BtfType::DataSec(datasec) = &t {
let type_name = match btf.type_name(t) {
Ok(name) => name,
_ => continue,
};
if type_name == section.name {
// each btf_var_secinfo contains a map
for info in &datasec.entries {
let (map_name, def) = parse_btf_map_def(btf, info)?;
let symbol_index =
maps.get(&map_name)
.ok_or_else(|| ParseError::SymbolNotFound {
name: map_name.to_string(),
})?;
self.maps.insert(
map_name,
Map::Btf(BtfMap {
def,
section_index: section.index.0,
symbol_index: *symbol_index,
data: Vec::new(),
}),
);
}
}
}
}
Ok(())
}
// Parses multiple map definition contained in a single `maps` section (which is
// different from `.maps` which is used for BTF). We can tell where each map is
// based on the symbol table.
fn parse_maps_section<'a, I: Iterator<Item = &'a usize>>(
&self,
maps: &mut HashMap<String, Map>,
section: &Section,
symbols: I,
) -> Result<(), ParseError> {
let mut have_symbols = false;
// each symbol in the section is a separate map
for i in symbols {
let sym = self.symbol_table.get(i).ok_or(ParseError::SymbolNotFound {
name: i.to_string(),
})?;
let start = sym.address as usize;
let end = start + sym.size as usize;
let data = &section.data[start..end];
let name = sym
.name
.as_ref()
.ok_or(ParseError::MapSymbolNameNotFound { i: *i })?;
let def = parse_map_def(name, data)?;
maps.insert(
name.to_string(),
Map::Legacy(LegacyMap {
section_index: section.index.0,
section_kind: section.kind,
symbol_index: Some(sym.index),
def,
data: Vec::new(),
}),
);
have_symbols = true;
}
if !have_symbols {
return Err(ParseError::NoSymbolsForSection {
section_name: section.name.to_owned(),
});
}
Ok(())
}
fn parse_section(&mut self, section: Section) -> Result<(), ParseError> {
self.section_infos
.insert(section.name.to_owned(), (section.index, section.size));
match section.kind {
BpfSectionKind::Data | BpfSectionKind::Rodata | BpfSectionKind::Bss => {
self.maps
.insert(section.name.to_string(), parse_data_map_section(&section)?);
}
BpfSectionKind::Text => self.parse_text_section(section)?,
BpfSectionKind::Btf => self.parse_btf(&section)?,
BpfSectionKind::BtfExt => self.parse_btf_ext(&section)?,
BpfSectionKind::BtfMaps => self.parse_btf_maps(&section)?,
BpfSectionKind::Maps => {
// take out self.maps so we can borrow the iterator below
// without cloning or collecting
let mut maps = mem::take(&mut self.maps);
// extract the symbols for the .maps section, we'll need them
// during parsing
let symbols = self
.symbols_by_section
.get(&section.index)
.ok_or(ParseError::NoSymbolsForSection {
section_name: section.name.to_owned(),
})?
.iter();
let res = self.parse_maps_section(&mut maps, &section, symbols);
// put the maps back
self.maps = maps;
res?
}
BpfSectionKind::Program => {
self.parse_programs(&section)?;
if !section.relocations.is_empty() {
self.relocations.insert(
section.index,
section
.relocations
.into_iter()
.map(|rel| (rel.offset, rel))
.collect(),
);
}
}
BpfSectionKind::Undefined | BpfSectionKind::License | BpfSectionKind::Version => {}
}
Ok(())
}
/// Sanitize BPF functions.
pub fn sanitize_functions(&mut self, features: &Features) {
for function in self.functions.values_mut() {
function.sanitize(features);
}
}
}
fn insn_is_helper_call(ins: &bpf_insn) -> bool {
let klass = (ins.code & 0x07) as u32;
let op = (ins.code & 0xF0) as u32;
let src = (ins.code & 0x08) as u32;
klass == BPF_JMP && op == BPF_CALL && src == BPF_K && ins.src_reg() == 0 && ins.dst_reg() == 0
}
const BPF_FUNC_PROBE_READ: i32 = 4;
const BPF_FUNC_PROBE_READ_STR: i32 = 45;
const BPF_FUNC_PROBE_READ_USER: i32 = 112;
const BPF_FUNC_PROBE_READ_KERNEL: i32 = 113;
const BPF_FUNC_PROBE_READ_USER_STR: i32 = 114;
const BPF_FUNC_PROBE_READ_KERNEL_STR: i32 = 115;
impl Function {
fn sanitize(&mut self, features: &Features) {
for inst in &mut self.instructions {
if !insn_is_helper_call(inst) {
continue;
}
match inst.imm {
BPF_FUNC_PROBE_READ_USER | BPF_FUNC_PROBE_READ_KERNEL
if !features.bpf_probe_read_kernel =>
{
inst.imm = BPF_FUNC_PROBE_READ;
}
BPF_FUNC_PROBE_READ_USER_STR | BPF_FUNC_PROBE_READ_KERNEL_STR
if !features.bpf_probe_read_kernel =>
{
inst.imm = BPF_FUNC_PROBE_READ_STR;
}
_ => {}
}
}
}
}
/// Errors caught during parsing the object file
#[derive(Debug, thiserror::Error)]
#[allow(missing_docs)]
pub enum ParseError {
#[error("error parsing ELF data")]
ElfError(object::read::Error),
/// Error parsing BTF object
#[error("BTF error")]
BtfError(#[from] BtfError),
#[error("invalid license `{data:?}`: missing NULL terminator")]
MissingLicenseNullTerminator { data: Vec<u8> },
#[error("invalid license `{data:?}`")]
InvalidLicense { data: Vec<u8> },
#[error("invalid kernel version `{data:?}`")]
InvalidKernelVersion { data: Vec<u8> },
#[error("error parsing section with index {index}")]
SectionError {
index: usize,
error: object::read::Error,
},
#[error("unsupported relocation target")]
UnsupportedRelocationTarget,
#[error("invalid program section `{section}`")]
InvalidProgramSection { section: String },
#[error("invalid program code")]
InvalidProgramCode,
#[error("error parsing map `{name}`")]
InvalidMapDefinition { name: String },
#[error("two or more symbols in section `{section_index}` have the same address {address:#X}")]
SymbolTableConflict { section_index: usize, address: u64 },
#[error("unknown symbol in section `{section_index}` at address {address:#X}")]
UnknownSymbol { section_index: usize, address: u64 },
#[error("invalid symbol, index `{index}` name: {}", .name.as_ref().unwrap_or(&"[unknown]".into()))]
InvalidSymbol { index: usize, name: Option<String> },
#[error("symbol {name} has size `{sym_size}`, but provided data is of size `{data_size}`")]
InvalidGlobalData {
name: String,
sym_size: u64,
data_size: usize,
},
#[error("symbol with name {name} not found in the symbols table")]
SymbolNotFound { name: String },
#[error("map for section with index {index} not found")]
MapNotFound { index: usize },
#[error("the map number {i} in the `maps` section doesn't have a symbol name")]
MapSymbolNameNotFound { i: usize },
#[error("no symbols found in the {section_name} section")]
NoSymbolsForSection { section_name: String },
/// No BTF parsed for object
#[error("no BTF parsed for object")]
NoBTF,
}
/// The kind of an ELF section.
#[derive(Debug, Copy, Clone, Eq, PartialEq)]
pub enum BpfSectionKind {
/// Undefined
Undefined,
/// `maps`
Maps,
/// `.maps`
BtfMaps,
/// A program section
Program,
/// `.data`
Data,
/// `.rodata`
Rodata,
/// `.bss`
Bss,
/// `.text`
Text,
/// `.BTF`
Btf,
/// `.BTF.ext`
BtfExt,
/// `license`
License,
/// `version`
Version,
}
impl BpfSectionKind {
fn from_name(name: &str) -> BpfSectionKind {
if name.starts_with("license") {
BpfSectionKind::License
} else if name.starts_with("version") {
BpfSectionKind::Version
} else if name.starts_with("maps") {
BpfSectionKind::Maps
} else if name.starts_with(".maps") {
BpfSectionKind::BtfMaps
} else if name.starts_with(".text") {
BpfSectionKind::Text
} else if name.starts_with(".bss") {
BpfSectionKind::Bss
} else if name.starts_with(".data") {
BpfSectionKind::Data
} else if name.starts_with(".rodata") {
BpfSectionKind::Rodata
} else if name == ".BTF" {
BpfSectionKind::Btf
} else if name == ".BTF.ext" {
BpfSectionKind::BtfExt
} else {
BpfSectionKind::Undefined
}
}
}
#[derive(Debug)]
struct Section<'a> {
index: SectionIndex,
kind: BpfSectionKind,
address: u64,
name: &'a str,
data: &'a [u8],
size: u64,
relocations: Vec<Relocation>,
}
impl<'data, 'file, 'a> TryFrom<&'a ObjSection<'data, 'file>> for Section<'a> {
type Error = ParseError;
fn try_from(section: &'a ObjSection) -> Result<Section<'a>, ParseError> {
let index = section.index();
let map_err = |error| ParseError::SectionError {
index: index.0,
error,
};
let name = section.name().map_err(map_err)?;
let kind = match BpfSectionKind::from_name(name) {
BpfSectionKind::Undefined => {
if section.kind() == SectionKind::Text && section.size() > 0 {
BpfSectionKind::Program
} else {
BpfSectionKind::Undefined
}
}
k => k,
};
Ok(Section {
index,
kind,
address: section.address(),
name,
data: section.data().map_err(map_err)?,
size: section.size(),
relocations: section
.relocations()
.map(|(offset, r)| {
Ok(Relocation {
symbol_index: match r.target() {
RelocationTarget::Symbol(index) => index.0,
_ => return Err(ParseError::UnsupportedRelocationTarget),
},
offset,
size: r.size(),
})
})
.collect::<Result<Vec<_>, _>>()?,
})
}
}
fn parse_license(data: &[u8]) -> Result<CString, ParseError> {
if data.len() < 2 {
return Err(ParseError::InvalidLicense {
data: data.to_vec(),
});
}
if data[data.len() - 1] != 0 {
return Err(ParseError::MissingLicenseNullTerminator {
data: data.to_vec(),
});
}
Ok(CStr::from_bytes_with_nul(data)
.map_err(|_| ParseError::InvalidLicense {
data: data.to_vec(),
})?
.to_owned())
}
fn parse_version(data: &[u8], endianness: object::Endianness) -> Result<Option<u32>, ParseError> {
let data = match data.len() {
4 => data.try_into().unwrap(),
_ => {
return Err(ParseError::InvalidKernelVersion {
data: data.to_vec(),
})
}
};
let v = match endianness {
object::Endianness::Big => u32::from_be_bytes(data),
object::Endianness::Little => u32::from_le_bytes(data),
};
Ok(if v == KERNEL_VERSION_ANY {
None
} else {
Some(v)
})
}
// Gets an integer value from a BTF map defintion K/V pair.
// type_id should be a PTR to an ARRAY.
// the value is encoded in the array nr_elems field.
fn get_map_field(btf: &Btf, type_id: u32) -> Result<u32, BtfError> {
let pty = match &btf.type_by_id(type_id)? {
BtfType::Ptr(pty) => pty,
other => {
return Err(BtfError::UnexpectedBtfType {
type_id: other.btf_type().unwrap_or(0),
})
}
};
// Safety: union
let arr = match &btf.type_by_id(pty.btf_type)? {
BtfType::Array(Array { array, .. }) => array,
other => {
return Err(BtfError::UnexpectedBtfType {
type_id: other.btf_type().unwrap_or(0),
})
}
};
Ok(arr.len)
}
// Parsed '.bss' '.data' and '.rodata' sections. These sections are arrays of
// bytes and are relocated based on their section index.
fn parse_data_map_section(section: &Section) -> Result<Map, ParseError> {
let (def, data) = match section.kind {
BpfSectionKind::Bss | BpfSectionKind::Data | BpfSectionKind::Rodata => {
let def = bpf_map_def {
map_type: BPF_MAP_TYPE_ARRAY as u32,
key_size: mem::size_of::<u32>() as u32,
// We need to use section.size here since
// .bss will always have data.len() == 0
value_size: section.size as u32,
max_entries: 1,
map_flags: if section.kind == BpfSectionKind::Rodata {
BPF_F_RDONLY_PROG
} else {
0
},
..Default::default()
};
(def, section.data.to_vec())
}
_ => unreachable!(),
};
Ok(Map::Legacy(LegacyMap {
section_index: section.index.0,
section_kind: section.kind,
// Data maps don't require symbols to be relocated
symbol_index: None,
def,
data,
}))
}
fn parse_map_def(name: &str, data: &[u8]) -> Result<bpf_map_def, ParseError> {
if data.len() < MINIMUM_MAP_SIZE {
return Err(ParseError::InvalidMapDefinition {
name: name.to_owned(),
});
}
if data.len() < mem::size_of::<bpf_map_def>() {
let mut map_def = bpf_map_def::default();
unsafe {
let map_def_ptr =
from_raw_parts_mut(&mut map_def as *mut bpf_map_def as *mut u8, data.len());
map_def_ptr.copy_from_slice(data);
}
Ok(map_def)
} else {
Ok(unsafe { ptr::read_unaligned(data.as_ptr() as *const bpf_map_def) })
}
}
fn parse_btf_map_def(btf: &Btf, info: &DataSecEntry) -> Result<(String, BtfMapDef), BtfError> {
let ty = match btf.type_by_id(info.btf_type)? {
BtfType::Var(var) => var,
other => {
return Err(BtfError::UnexpectedBtfType {
type_id: other.btf_type().unwrap_or(0),
})
}
};
let map_name = btf.string_at(ty.name_offset)?;
let mut map_def = BtfMapDef::default();
// Safety: union
let root_type = btf.resolve_type(ty.btf_type)?;
let s = match btf.type_by_id(root_type)? {
BtfType::Struct(s) => s,
other => {
return Err(BtfError::UnexpectedBtfType {
type_id: other.btf_type().unwrap_or(0),
})
}
};
for m in &s.members {
match btf.string_at(m.name_offset)?.as_ref() {
"type" => {
map_def.map_type = get_map_field(btf, m.btf_type)?;
}
"key" => {
if let BtfType::Ptr(pty) = btf.type_by_id(m.btf_type)? {
// Safety: union
let t = pty.btf_type;
map_def.key_size = btf.type_size(t)? as u32;
map_def.btf_key_type_id = t;
} else {
return Err(BtfError::UnexpectedBtfType {
type_id: m.btf_type,
});
}
}
"key_size" => {
map_def.key_size = get_map_field(btf, m.btf_type)?;
}
"value" => {
if let BtfType::Ptr(pty) = btf.type_by_id(m.btf_type)? {
let t = pty.btf_type;
map_def.value_size = btf.type_size(t)? as u32;
map_def.btf_value_type_id = t;
} else {
return Err(BtfError::UnexpectedBtfType {
type_id: m.btf_type,
});
}
}
"value_size" => {
map_def.value_size = get_map_field(btf, m.btf_type)?;
}
"max_entries" => {
map_def.max_entries = get_map_field(btf, m.btf_type)?;
}
"map_flags" => {
map_def.map_flags = get_map_field(btf, m.btf_type)?;
}
"pinning" => {
let pinning = get_map_field(btf, m.btf_type)?;
map_def.pinning = PinningType::try_from(pinning).unwrap_or_else(|_| {
debug!("{} is not a valid pin type. using PIN_NONE", pinning);
PinningType::None
});
}
other => {
debug!("skipping unknown map section: {}", other);
continue;
}
}
}
Ok((map_name.to_string(), map_def))
}
/// Parses a [bpf_map_info] into a [Map].
pub fn parse_map_info(info: bpf_map_info, pinned: PinningType) -> Map {
if info.btf_key_type_id != 0 {
Map::Btf(BtfMap {
def: BtfMapDef {
map_type: info.type_,
key_size: info.key_size,
value_size: info.value_size,
max_entries: info.max_entries,
map_flags: info.map_flags,
pinning: pinned,
btf_key_type_id: info.btf_key_type_id,
btf_value_type_id: info.btf_value_type_id,
},
section_index: 0,
symbol_index: 0,
data: Vec::new(),
})
} else {
Map::Legacy(LegacyMap {
def: bpf_map_def {
map_type: info.type_,
key_size: info.key_size,
value_size: info.value_size,
max_entries: info.max_entries,
map_flags: info.map_flags,
pinning: pinned,
id: info.id,
},
section_index: 0,
symbol_index: None,
section_kind: BpfSectionKind::Undefined,
data: Vec::new(),
})
}
}
/// Copies a block of eBPF instructions
pub fn copy_instructions(data: &[u8]) -> Result<Vec<bpf_insn>, ParseError> {
if data.len() % mem::size_of::<bpf_insn>() > 0 {
return Err(ParseError::InvalidProgramCode);
}
let instructions = data
.chunks_exact(mem::size_of::<bpf_insn>())
.map(|d| unsafe { ptr::read_unaligned(d.as_ptr() as *const bpf_insn) })
.collect::<Vec<_>>();
Ok(instructions)
}
fn get_func_and_line_info(
btf_ext: Option<&BtfExt>,
symbol: &Symbol,
section: &Section,
offset: usize,
rewrite_insn_off: bool,
) -> (FuncSecInfo, LineSecInfo, usize, usize) {
btf_ext
.map(|btf_ext| {
let instruction_offset = (offset / INS_SIZE) as u32;
let symbol_size_instructions = (symbol.size as usize / INS_SIZE) as u32;
let mut func_info = btf_ext.func_info.get(section.name);
func_info.func_info.retain_mut(|f| {
let retain = f.insn_off == instruction_offset;
if retain && rewrite_insn_off {
f.insn_off = 0;
}
retain
});
let mut line_info = btf_ext.line_info.get(section.name);
line_info
.line_info
.retain_mut(|l| match l.insn_off.checked_sub(instruction_offset) {
None => false,
Some(insn_off) => {
let retain = insn_off < symbol_size_instructions;
if retain && rewrite_insn_off {
l.insn_off = insn_off
}
retain
}
});
(
func_info,
line_info,
btf_ext.func_info_rec_size(),
btf_ext.line_info_rec_size(),
)
})
.unwrap_or_default()
}
#[cfg(test)]
mod tests {
use alloc::vec;
use assert_matches::assert_matches;
use object::Endianness;
use super::*;
use crate::maps::PinningType;
const FAKE_INS_LEN: u64 = 8;
fn fake_section<'a>(
kind: BpfSectionKind,
name: &'a str,
data: &'a [u8],
index: Option<usize>,
) -> Section<'a> {
let idx = index.unwrap_or(0);
Section {
index: SectionIndex(idx),
kind,
address: 0,
name,
data,
size: data.len() as u64,
relocations: Vec::new(),
}
}
fn fake_ins() -> bpf_insn {
bpf_insn {
code: 0,
_bitfield_align_1: [],
_bitfield_1: bpf_insn::new_bitfield_1(0, 0),
off: 0,
imm: 0,
}
}
fn fake_sym(obj: &mut Object, section_index: usize, address: u64, name: &str, size: u64) {
let idx = obj.symbol_table.len();
obj.symbol_table.insert(
idx + 1,
Symbol {
index: idx + 1,
section_index: Some(section_index),
name: Some(name.to_string()),
address,
size,
is_definition: false,
kind: SymbolKind::Text,
},
);
obj.symbols_by_section
.entry(SectionIndex(section_index))
.or_default()
.push(idx + 1);
}
fn bytes_of<T>(val: &T) -> &[u8] {
// Safety: This is for testing only
unsafe { crate::util::bytes_of(val) }
}
#[test]
fn test_parse_generic_error() {
assert_matches!(Object::parse(&b"foo"[..]), Err(ParseError::ElfError(_)))
}
#[test]
fn test_parse_license() {
assert_matches!(parse_license(b""), Err(ParseError::InvalidLicense { .. }));
assert_matches!(parse_license(b"\0"), Err(ParseError::InvalidLicense { .. }));
assert_matches!(
parse_license(b"GPL"),
Err(ParseError::MissingLicenseNullTerminator { .. })
);
assert_eq!(parse_license(b"GPL\0").unwrap().to_str().unwrap(), "GPL");
}
#[test]
fn test_parse_version() {
assert_matches!(
parse_version(b"", Endianness::Little),
Err(ParseError::InvalidKernelVersion { .. })
);
assert_matches!(
parse_version(b"123", Endianness::Little),
Err(ParseError::InvalidKernelVersion { .. })
);
assert_matches!(
parse_version(&0xFFFF_FFFEu32.to_le_bytes(), Endianness::Little),
Ok(None)
);
assert_matches!(
parse_version(&0xFFFF_FFFEu32.to_be_bytes(), Endianness::Big),
Ok(None)
);
assert_matches!(
parse_version(&1234u32.to_le_bytes(), Endianness::Little),
Ok(Some(1234))
);
}
#[test]
fn test_parse_map_def_error() {
assert_matches!(
parse_map_def("foo", &[]),
Err(ParseError::InvalidMapDefinition { .. })
);
}
#[test]
fn test_parse_map_short() {
let def = bpf_map_def {
map_type: 1,
key_size: 2,
value_size: 3,
max_entries: 4,
map_flags: 5,
id: 0,
pinning: PinningType::None,
};
assert_eq!(
parse_map_def("foo", &bytes_of(&def)[..MINIMUM_MAP_SIZE]).unwrap(),
def
);
}
#[test]
fn test_parse_map_def() {
let def = bpf_map_def {
map_type: 1,
key_size: 2,
value_size: 3,
max_entries: 4,
map_flags: 5,
id: 6,
pinning: PinningType::ByName,
};
assert_eq!(parse_map_def("foo", bytes_of(&def)).unwrap(), def);
}
#[test]
fn test_parse_map_def_with_padding() {
let def = bpf_map_def {
map_type: 1,
key_size: 2,
value_size: 3,
max_entries: 4,
map_flags: 5,
id: 6,
pinning: PinningType::ByName,
};
let mut buf = [0u8; 128];
unsafe { ptr::write_unaligned(buf.as_mut_ptr() as *mut _, def) };
assert_eq!(parse_map_def("foo", &buf).unwrap(), def);
}
#[test]
fn test_parse_map_data() {
let map_data = b"map data";
assert_matches!(
parse_data_map_section(
&fake_section(
BpfSectionKind::Data,
".bss",
map_data,
None,
),
),
Ok(Map::Legacy(LegacyMap {
section_index: 0,
section_kind: BpfSectionKind::Data,
symbol_index: None,
def: bpf_map_def {
map_type: _map_type,
key_size: 4,
value_size,
max_entries: 1,
map_flags: 0,
id: 0,
pinning: PinningType::None,
},
data,
})) if data == map_data && value_size == map_data.len() as u32
)
}
fn fake_obj() -> Object {
Object::new(Endianness::Little, CString::new("GPL").unwrap(), None)
}
#[test]
fn sanitizes_empty_btf_files_to_none() {
let mut obj = fake_obj();
obj.parse_section(fake_section(
BpfSectionKind::Btf,
".BTF",
&[
159, 235, 1, 0, 24, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 1, 0, 0, 0, 0,
],
None,
))
.unwrap();
obj.parse_section(fake_section(
BpfSectionKind::BtfExt,
".BTF.ext",
&[
159, 235, 1, 0, 24, 0, 0, 0, 0, 0, 0, 0, 4, 0, 0, 0, 4, 0, 0, 0, 4, 0, 0, 0, 8, 0,
0, 0, 16, 0, 0, 0,
],
None,
))
.unwrap();
let btf = obj.fixup_and_sanitize_btf(&BtfFeatures::default()).unwrap();
assert!(btf.is_none());
}
#[test]
fn test_parse_program_error() {
let mut obj = fake_obj();
fake_sym(&mut obj, 0, 0, "foo", 1);
assert_matches!(
obj.parse_programs(&fake_section(
BpfSectionKind::Program,
"kprobe/foo",
&42u32.to_ne_bytes(),
None,
),),
Err(ParseError::InvalidProgramCode)
);
}
#[test]
fn test_parse_program() {
let mut obj = fake_obj();
fake_sym(&mut obj, 0, 0, "foo", FAKE_INS_LEN);
obj.parse_programs(&fake_section(
BpfSectionKind::Program,
"kprobe/foo",
bytes_of(&fake_ins()),
None,
))
.unwrap();
let prog_foo = obj.programs.get("foo").unwrap();
assert_matches!(prog_foo, Program {
license,
kernel_version: None,
section: ProgramSection::KProbe { .. },
..
} => assert_eq!(license.to_str().unwrap(), "GPL"));
assert_matches!(
obj.functions.get(&prog_foo.function_key()),
Some(Function {
name,
address: 0,
section_index: SectionIndex(0),
section_offset: 0,
instructions,
..}) if name == "foo" && instructions.len() == 1
)
}
#[test]
fn test_parse_section_map() {
let mut obj = fake_obj();
fake_sym(&mut obj, 0, 0, "foo", mem::size_of::<bpf_map_def>() as u64);
assert_matches!(
obj.parse_section(fake_section(
BpfSectionKind::Maps,
"maps/foo",
bytes_of(&bpf_map_def {
map_type: 1,
key_size: 2,
value_size: 3,
max_entries: 4,
map_flags: 5,
..Default::default()
}),
None,
)),
Ok(())
);
assert!(obj.maps.get("foo").is_some());
}
#[test]
fn test_parse_multiple_program_in_same_section() {
let mut obj = fake_obj();
fake_sym(&mut obj, 0, 0, "foo", FAKE_INS_LEN);
fake_sym(&mut obj, 0, FAKE_INS_LEN, "bar", FAKE_INS_LEN);
let insns = [fake_ins(), fake_ins()];
let data = bytes_of(&insns);
obj.parse_programs(&fake_section(BpfSectionKind::Program, "kprobe", data, None))
.unwrap();
let prog_foo = obj.programs.get("foo").unwrap();
let function_foo = obj.functions.get(&prog_foo.function_key()).unwrap();
let prog_bar = obj.programs.get("bar").unwrap();
let function_bar = obj.functions.get(&prog_bar.function_key()).unwrap();
assert_matches!(prog_foo, Program {
license,
kernel_version: None,
section: ProgramSection::KProbe { .. },
..
} => assert_eq!(license.to_str().unwrap(), "GPL"));
assert_matches!(
function_foo,
Function {
name,
address: 0,
section_index: SectionIndex(0),
section_offset: 0,
instructions,
..
} if name == "foo" && instructions.len() == 1
);
assert_matches!(prog_bar, Program {
license,
kernel_version: None,
section: ProgramSection::KProbe { .. },
..
} => assert_eq!(license.to_str().unwrap(), "GPL"));
assert_matches!(
function_bar,
Function {
name,
address: 8,
section_index: SectionIndex(0),
section_offset: 8,
instructions,
..
} if name == "bar" && instructions.len() == 1
);
}
#[test]
fn test_parse_section_multiple_maps() {
let mut obj = fake_obj();
fake_sym(&mut obj, 0, 0, "foo", mem::size_of::<bpf_map_def>() as u64);
fake_sym(&mut obj, 0, 28, "bar", mem::size_of::<bpf_map_def>() as u64);
fake_sym(&mut obj, 0, 60, "baz", mem::size_of::<bpf_map_def>() as u64);
let def = &bpf_map_def {
map_type: 1,
key_size: 2,
value_size: 3,
max_entries: 4,
map_flags: 5,
..Default::default()
};
let map_data = bytes_of(def).to_vec();
let mut buf = vec![];
buf.extend(&map_data);
buf.extend(&map_data);
// throw in some padding
buf.extend([0, 0, 0, 0]);
buf.extend(&map_data);
assert_matches!(
obj.parse_section(fake_section(
BpfSectionKind::Maps,
"maps",
buf.as_slice(),
None
)),
Ok(())
);
assert!(obj.maps.get("foo").is_some());
assert!(obj.maps.get("bar").is_some());
assert!(obj.maps.get("baz").is_some());
for map in obj.maps.values() {
assert_matches!(map, Map::Legacy(m) => {
assert_eq!(&m.def, def);
})
}
}
#[test]
fn test_parse_section_data() {
let mut obj = fake_obj();
assert_matches!(
obj.parse_section(fake_section(
BpfSectionKind::Data,
".bss",
b"map data",
None
)),
Ok(())
);
assert!(obj.maps.get(".bss").is_some());
assert_matches!(
obj.parse_section(fake_section(
BpfSectionKind::Data,
".rodata",
b"map data",
None
)),
Ok(())
);
assert!(obj.maps.get(".rodata").is_some());
assert_matches!(
obj.parse_section(fake_section(
BpfSectionKind::Data,
".rodata.boo",
b"map data",
None
)),
Ok(())
);
assert!(obj.maps.get(".rodata.boo").is_some());
assert_matches!(
obj.parse_section(fake_section(
BpfSectionKind::Data,
".data",
b"map data",
None
)),
Ok(())
);
assert!(obj.maps.get(".data").is_some());
assert_matches!(
obj.parse_section(fake_section(
BpfSectionKind::Data,
".data.boo",
b"map data",
None
)),
Ok(())
);
assert!(obj.maps.get(".data.boo").is_some());
}
#[test]
fn test_parse_section_kprobe() {
let mut obj = fake_obj();
fake_sym(&mut obj, 0, 0, "foo", FAKE_INS_LEN);
assert_matches!(
obj.parse_section(fake_section(
BpfSectionKind::Program,
"kprobe/foo",
bytes_of(&fake_ins()),
None
)),
Ok(())
);
assert_matches!(
obj.programs.get("foo"),
Some(Program {
section: ProgramSection::KProbe { .. },
..
})
);
}
#[test]
fn test_parse_section_uprobe() {
let mut obj = fake_obj();
fake_sym(&mut obj, 0, 0, "foo", FAKE_INS_LEN);
assert_matches!(
obj.parse_section(fake_section(
BpfSectionKind::Program,
"uprobe/foo",
bytes_of(&fake_ins()),
None
)),
Ok(())
);
assert_matches!(
obj.programs.get("foo"),
Some(Program {
section: ProgramSection::UProbe { .. },
..
})
);
}
#[test]
fn test_parse_section_uprobe_sleepable() {
let mut obj = fake_obj();
fake_sym(&mut obj, 0, 0, "foo", FAKE_INS_LEN);
assert_matches!(
obj.parse_section(fake_section(
BpfSectionKind::Program,
"uprobe.s/foo",
bytes_of(&fake_ins()),
None
)),
Ok(())
);
assert_matches!(
obj.programs.get("foo"),
Some(Program {
section: ProgramSection::UProbe {
sleepable: true,
..
},
..
})
);
}
#[test]
fn test_parse_section_uretprobe() {
let mut obj = fake_obj();
fake_sym(&mut obj, 0, 0, "foo", FAKE_INS_LEN);
assert_matches!(
obj.parse_section(fake_section(
BpfSectionKind::Program,
"uretprobe/foo",
bytes_of(&fake_ins()),
None
)),
Ok(())
);
assert_matches!(
obj.programs.get("foo"),
Some(Program {
section: ProgramSection::URetProbe { .. },
..
})
);
}
#[test]
fn test_parse_section_uretprobe_sleepable() {
let mut obj = fake_obj();
fake_sym(&mut obj, 0, 0, "foo", FAKE_INS_LEN);
assert_matches!(
obj.parse_section(fake_section(
BpfSectionKind::Program,
"uretprobe.s/foo",
bytes_of(&fake_ins()),
None
)),
Ok(())
);
assert_matches!(
obj.programs.get("foo"),
Some(Program {
section: ProgramSection::URetProbe {
sleepable: true,
..
},
..
})
);
}
#[test]
fn test_parse_section_trace_point() {
let mut obj = fake_obj();
fake_sym(&mut obj, 0, 0, "foo", FAKE_INS_LEN);
fake_sym(&mut obj, 1, 0, "bar", FAKE_INS_LEN);
assert_matches!(
obj.parse_section(fake_section(
BpfSectionKind::Program,
"tracepoint/foo",
bytes_of(&fake_ins()),
None
)),
Ok(())
);
assert_matches!(
obj.programs.get("foo"),
Some(Program {
section: ProgramSection::TracePoint { .. },
..
})
);
assert_matches!(
obj.parse_section(fake_section(
BpfSectionKind::Program,
"tp/foo/bar",
bytes_of(&fake_ins()),
Some(1),
)),
Ok(())
);
assert_matches!(
obj.programs.get("bar"),
Some(Program {
section: ProgramSection::TracePoint { .. },
..
})
);
}
#[test]
fn test_parse_section_socket_filter() {
let mut obj = fake_obj();
fake_sym(&mut obj, 0, 0, "foo", FAKE_INS_LEN);
assert_matches!(
obj.parse_section(fake_section(
BpfSectionKind::Program,
"socket/foo",
bytes_of(&fake_ins()),
None
)),
Ok(())
);
assert_matches!(
obj.programs.get("foo"),
Some(Program {
section: ProgramSection::SocketFilter { .. },
..
})
);
}
#[test]
fn test_parse_section_xdp() {
let mut obj = fake_obj();
fake_sym(&mut obj, 0, 0, "foo", FAKE_INS_LEN);
assert_matches!(
obj.parse_section(fake_section(
BpfSectionKind::Program,
"xdp",
bytes_of(&fake_ins()),
None
)),
Ok(())
);
assert_matches!(
obj.programs.get("foo"),
Some(Program {
section: ProgramSection::Xdp { frags: false, .. },
..
})
);
}
#[test]
fn test_parse_section_xdp_frags() {
let mut obj = fake_obj();
fake_sym(&mut obj, 0, 0, "foo", FAKE_INS_LEN);
assert_matches!(
obj.parse_section(fake_section(
BpfSectionKind::Program,
"xdp.frags",
bytes_of(&fake_ins()),
None
)),
Ok(())
);
assert_matches!(
obj.programs.get("foo"),
Some(Program {
section: ProgramSection::Xdp { frags: true, .. },
..
})
);
}
#[test]
fn test_parse_section_raw_tp() {
let mut obj = fake_obj();
fake_sym(&mut obj, 0, 0, "foo", FAKE_INS_LEN);
fake_sym(&mut obj, 1, 0, "bar", FAKE_INS_LEN);
assert_matches!(
obj.parse_section(fake_section(
BpfSectionKind::Program,
"raw_tp/foo",
bytes_of(&fake_ins()),
None
)),
Ok(())
);
assert_matches!(
obj.programs.get("foo"),
Some(Program {
section: ProgramSection::RawTracePoint { .. },
..
})
);
assert_matches!(
obj.parse_section(fake_section(
BpfSectionKind::Program,
"raw_tracepoint/bar",
bytes_of(&fake_ins()),
Some(1)
)),
Ok(())
);
assert_matches!(
obj.programs.get("bar"),
Some(Program {
section: ProgramSection::RawTracePoint { .. },
..
})
);
}
#[test]
fn test_parse_section_lsm() {
let mut obj = fake_obj();
fake_sym(&mut obj, 0, 0, "foo", FAKE_INS_LEN);
assert_matches!(
obj.parse_section(fake_section(
BpfSectionKind::Program,
"lsm/foo",
bytes_of(&fake_ins()),
None
)),
Ok(())
);
assert_matches!(
obj.programs.get("foo"),
Some(Program {
section: ProgramSection::Lsm {
sleepable: false,
..
},
..
})
);
}
#[test]
fn test_parse_section_lsm_sleepable() {
let mut obj = fake_obj();
fake_sym(&mut obj, 0, 0, "foo", FAKE_INS_LEN);
assert_matches!(
obj.parse_section(fake_section(
BpfSectionKind::Program,
"lsm.s/foo",
bytes_of(&fake_ins()),
None
)),
Ok(())
);
assert_matches!(
obj.programs.get("foo"),
Some(Program {
section: ProgramSection::Lsm {
sleepable: true,
..
},
..
})
);
}
#[test]
fn test_parse_section_btf_tracepoint() {
let mut obj = fake_obj();
fake_sym(&mut obj, 0, 0, "foo", FAKE_INS_LEN);
assert_matches!(
obj.parse_section(fake_section(
BpfSectionKind::Program,
"tp_btf/foo",
bytes_of(&fake_ins()),
None
)),
Ok(())
);
assert_matches!(
obj.programs.get("foo"),
Some(Program {
section: ProgramSection::BtfTracePoint { .. },
..
})
);
}
#[test]
fn test_parse_section_skskb_unnamed() {
let mut obj = fake_obj();
fake_sym(&mut obj, 0, 0, "stream_parser", FAKE_INS_LEN);
assert_matches!(
obj.parse_section(fake_section(
BpfSectionKind::Program,
"sk_skb/stream_parser",
bytes_of(&fake_ins()),
None
)),
Ok(())
);
assert_matches!(
obj.programs.get("stream_parser"),
Some(Program {
section: ProgramSection::SkSkbStreamParser { .. },
..
})
);
}
#[test]
fn test_parse_section_skskb_named() {
let mut obj = fake_obj();
fake_sym(&mut obj, 0, 0, "my_parser", FAKE_INS_LEN);
assert_matches!(
obj.parse_section(fake_section(
BpfSectionKind::Program,
"sk_skb/stream_parser/my_parser",
bytes_of(&fake_ins()),
None
)),
Ok(())
);
assert_matches!(
obj.programs.get("my_parser"),
Some(Program {
section: ProgramSection::SkSkbStreamParser { .. },
..
})
);
}
#[test]
fn test_parse_section_fentry() {
let mut obj = fake_obj();
fake_sym(&mut obj, 0, 0, "foo", FAKE_INS_LEN);
assert_matches!(
obj.parse_section(fake_section(
BpfSectionKind::Program,
"fentry/foo",
bytes_of(&fake_ins()),
None
)),
Ok(())
);
assert_matches!(
obj.programs.get("foo"),
Some(Program {
section: ProgramSection::FEntry { .. },
..
})
);
}
#[test]
fn test_parse_section_fentry_sleepable() {
let mut obj = fake_obj();
fake_sym(&mut obj, 0, 0, "foo", FAKE_INS_LEN);
assert_matches!(
obj.parse_section(fake_section(
BpfSectionKind::Program,
"fentry.s/foo",
bytes_of(&fake_ins()),
None
)),
Ok(())
);
assert_matches!(
obj.programs.get("foo"),
Some(Program {
section: ProgramSection::FEntry {
sleepable: true,
..
},
..
})
);
}
#[test]
fn test_parse_section_fexit() {
let mut obj = fake_obj();
fake_sym(&mut obj, 0, 0, "foo", FAKE_INS_LEN);
assert_matches!(
obj.parse_section(fake_section(
BpfSectionKind::Program,
"fexit/foo",
bytes_of(&fake_ins()),
None
)),
Ok(())
);
assert_matches!(
obj.programs.get("foo"),
Some(Program {
section: ProgramSection::FExit { .. },
..
})
);
}
#[test]
fn test_parse_section_fexit_sleepable() {
let mut obj = fake_obj();
fake_sym(&mut obj, 0, 0, "foo", FAKE_INS_LEN);
assert_matches!(
obj.parse_section(fake_section(
BpfSectionKind::Program,
"fexit.s/foo",
bytes_of(&fake_ins()),
None
)),
Ok(())
);
assert_matches!(
obj.programs.get("foo"),
Some(Program {
section: ProgramSection::FExit {
sleepable: true,
..
},
..
})
);
}
#[test]
fn test_parse_section_cgroup_skb_ingress_unnamed() {
let mut obj = fake_obj();
fake_sym(&mut obj, 0, 0, "ingress", FAKE_INS_LEN);
assert_matches!(
obj.parse_section(fake_section(
BpfSectionKind::Program,
"cgroup_skb/ingress",
bytes_of(&fake_ins()),
None
)),
Ok(())
);
assert_matches!(
obj.programs.get("ingress"),
Some(Program {
section: ProgramSection::CgroupSkbIngress { .. },
..
})
);
}
#[test]
fn test_parse_section_cgroup_skb_ingress_named() {
let mut obj = fake_obj();
fake_sym(&mut obj, 0, 0, "foo", FAKE_INS_LEN);
assert_matches!(
obj.parse_section(fake_section(
BpfSectionKind::Program,
"cgroup_skb/ingress/foo",
bytes_of(&fake_ins()),
None
)),
Ok(())
);
assert_matches!(
obj.programs.get("foo"),
Some(Program {
section: ProgramSection::CgroupSkbIngress { .. },
..
})
);
}
#[test]
fn test_parse_section_cgroup_skb_no_direction_unamed() {
let mut obj = fake_obj();
fake_sym(&mut obj, 0, 0, "skb", FAKE_INS_LEN);
assert_matches!(
obj.parse_section(fake_section(
BpfSectionKind::Program,
"cgroup/skb",
bytes_of(&fake_ins()),
None
)),
Ok(())
);
assert_matches!(
obj.programs.get("skb"),
Some(Program {
section: ProgramSection::CgroupSkb { .. },
..
})
);
}
#[test]
fn test_parse_section_cgroup_skb_no_direction_named() {
let mut obj = fake_obj();
fake_sym(&mut obj, 0, 0, "foo", FAKE_INS_LEN);
assert_matches!(
obj.parse_section(fake_section(
BpfSectionKind::Program,
"cgroup/skb/foo",
bytes_of(&fake_ins()),
None
)),
Ok(())
);
assert_matches!(
obj.programs.get("foo"),
Some(Program {
section: ProgramSection::CgroupSkb { .. },
..
})
);
}
#[test]
fn test_parse_section_sock_addr_named() {
let mut obj = fake_obj();
fake_sym(&mut obj, 0, 0, "foo", FAKE_INS_LEN);
assert_matches!(
obj.parse_section(fake_section(
BpfSectionKind::Program,
"cgroup/connect4/foo",
bytes_of(&fake_ins()),
None
)),
Ok(())
);
assert_matches!(
obj.programs.get("foo"),
Some(Program {
section: ProgramSection::CgroupSockAddr {
attach_type: CgroupSockAddrAttachType::Connect4,
..
},
..
})
);
}
#[test]
fn test_parse_section_sock_addr_unnamed() {
let mut obj = fake_obj();
fake_sym(&mut obj, 0, 0, "connect4", FAKE_INS_LEN);
assert_matches!(
obj.parse_section(fake_section(
BpfSectionKind::Program,
"cgroup/connect4",
bytes_of(&fake_ins()),
None
)),
Ok(())
);
assert_matches!(
obj.programs.get("connect4"),
Some(Program {
section: ProgramSection::CgroupSockAddr {
attach_type: CgroupSockAddrAttachType::Connect4,
..
},
..
})
);
}
#[test]
fn test_parse_section_sockopt_named() {
let mut obj = fake_obj();
fake_sym(&mut obj, 0, 0, "foo", FAKE_INS_LEN);
assert_matches!(
obj.parse_section(fake_section(
BpfSectionKind::Program,
"cgroup/getsockopt/foo",
bytes_of(&fake_ins()),
None
)),
Ok(())
);
assert_matches!(
obj.programs.get("foo"),
Some(Program {
section: ProgramSection::CgroupSockopt {
attach_type: CgroupSockoptAttachType::Get,
..
},
..
})
);
}
#[test]
fn test_parse_section_sockopt_unnamed() {
let mut obj = fake_obj();
fake_sym(&mut obj, 0, 0, "getsockopt", FAKE_INS_LEN);
assert_matches!(
obj.parse_section(fake_section(
BpfSectionKind::Program,
"cgroup/getsockopt",
bytes_of(&fake_ins()),
None
)),
Ok(())
);
assert_matches!(
obj.programs.get("getsockopt"),
Some(Program {
section: ProgramSection::CgroupSockopt {
attach_type: CgroupSockoptAttachType::Get,
..
},
..
})
);
}
#[test]
fn test_patch_map_data() {
let mut obj = fake_obj();
obj.maps.insert(
".rodata".to_owned(),
Map::Legacy(LegacyMap {
def: bpf_map_def {
map_type: BPF_MAP_TYPE_ARRAY as u32,
key_size: mem::size_of::<u32>() as u32,
value_size: 3,
max_entries: 1,
map_flags: BPF_F_RDONLY_PROG,
id: 1,
pinning: PinningType::None,
},
section_index: 1,
section_kind: BpfSectionKind::Rodata,
symbol_index: Some(1),
data: vec![0, 0, 0],
}),
);
obj.symbol_table.insert(
1,
Symbol {
index: 1,
section_index: Some(1),
name: Some("my_config".to_owned()),
address: 0,
size: 3,
is_definition: true,
kind: SymbolKind::Data,
},
);
let test_data: &[u8] = &[1, 2, 3];
obj.patch_map_data(HashMap::from([
("my_config", (test_data, true)),
("optional_variable", (test_data, false)),
]))
.unwrap();
let map = obj.maps.get(".rodata").unwrap();
assert_eq!(test_data, map.data());
}
#[test]
fn test_parse_btf_map_section() {
let mut obj = fake_obj();
fake_sym(&mut obj, 0, 0, "map_1", 0);
fake_sym(&mut obj, 0, 0, "map_2", 0);
// generated from:
// objcopy --dump-section .BTF=test.btf ./target/bpfel-unknown-none/debug/multimap-btf.bpf.o
// hexdump -v -e '7/1 "0x%02X, " 1/1 " 0x%02X,\n"' test.btf
let data: &[u8] = &[
0x9F, 0xEB, 0x01, 0x00, 0x18, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0xF0, 0x01,
0x00, 0x00, 0xF0, 0x01, 0x00, 0x00, 0xCC, 0x01, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00,
0x00, 0x00, 0x00, 0x02, 0x03, 0x00, 0x00, 0x00, 0x01, 0x00, 0x00, 0x00, 0x00, 0x00,
0x00, 0x01, 0x04, 0x00, 0x00, 0x00, 0x20, 0x00, 0x00, 0x01, 0x00, 0x00, 0x00, 0x00,
0x00, 0x00, 0x00, 0x03, 0x00, 0x00, 0x00, 0x00, 0x02, 0x00, 0x00, 0x00, 0x04, 0x00,
0x00, 0x00, 0x02, 0x00, 0x00, 0x00, 0x05, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x01,
0x04, 0x00, 0x00, 0x00, 0x20, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00,
0x00, 0x02, 0x06, 0x00, 0x00, 0x00, 0x19, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x08,
0x07, 0x00, 0x00, 0x00, 0x1F, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x01, 0x04, 0x00,
0x00, 0x00, 0x20, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x02,
0x09, 0x00, 0x00, 0x00, 0x2C, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x08, 0x0A, 0x00,
0x00, 0x00, 0x32, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x01, 0x08, 0x00, 0x00, 0x00,
0x40, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x02, 0x0C, 0x00,
0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x03, 0x00, 0x00, 0x00, 0x00,
0x02, 0x00, 0x00, 0x00, 0x04, 0x00, 0x00, 0x00, 0x01, 0x00, 0x00, 0x00, 0x00, 0x00,
0x00, 0x00, 0x04, 0x00, 0x00, 0x04, 0x20, 0x00, 0x00, 0x00, 0x45, 0x00, 0x00, 0x00,
0x01, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x4A, 0x00, 0x00, 0x00, 0x05, 0x00,
0x00, 0x00, 0x40, 0x00, 0x00, 0x00, 0x4E, 0x00, 0x00, 0x00, 0x08, 0x00, 0x00, 0x00,
0x80, 0x00, 0x00, 0x00, 0x54, 0x00, 0x00, 0x00, 0x0B, 0x00, 0x00, 0x00, 0xC0, 0x00,
0x00, 0x00, 0x60, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x0E, 0x0D, 0x00, 0x00, 0x00,
0x01, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x04, 0x00, 0x00, 0x04, 0x20, 0x00,
0x00, 0x00, 0x45, 0x00, 0x00, 0x00, 0x01, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00,
0x4A, 0x00, 0x00, 0x00, 0x05, 0x00, 0x00, 0x00, 0x40, 0x00, 0x00, 0x00, 0x4E, 0x00,
0x00, 0x00, 0x08, 0x00, 0x00, 0x00, 0x80, 0x00, 0x00, 0x00, 0x54, 0x00, 0x00, 0x00,
0x0B, 0x00, 0x00, 0x00, 0xC0, 0x00, 0x00, 0x00, 0x66, 0x00, 0x00, 0x00, 0x00, 0x00,
0x00, 0x0E, 0x0F, 0x00, 0x00, 0x00, 0x01, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00,
0x00, 0x00, 0x00, 0x02, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x01, 0x00,
0x00, 0x0D, 0x02, 0x00, 0x00, 0x00, 0x6C, 0x00, 0x00, 0x00, 0x11, 0x00, 0x00, 0x00,
0x70, 0x00, 0x00, 0x00, 0x01, 0x00, 0x00, 0x0C, 0x12, 0x00, 0x00, 0x00, 0xB0, 0x01,
0x00, 0x00, 0x00, 0x00, 0x00, 0x01, 0x01, 0x00, 0x00, 0x00, 0x08, 0x00, 0x00, 0x01,
0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x03, 0x00, 0x00, 0x00, 0x00, 0x14, 0x00,
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];
let btf_section = fake_section(BpfSectionKind::Btf, ".BTF", data, None);
obj.parse_section(btf_section).unwrap();
let map_section = fake_section(BpfSectionKind::BtfMaps, ".maps", &[], None);
obj.parse_section(map_section).unwrap();
let map = obj.maps.get("map_1").unwrap();
assert_matches!(map, Map::Btf(m) => {
assert_eq!(m.def.key_size, 4);
assert_eq!(m.def.value_size, 8);
assert_eq!(m.def.max_entries, 1);
});
}
}