Merge pull request #175 from dave-tucker/merge_fixup_sanitize

aya: Merge Fixup and Sanitzation to single step
pull/179/head
Dave Tucker 3 years ago committed by GitHub
commit 1904aeaef9
No known key found for this signature in database
GPG Key ID: 4AEE18F83AFDEB23

@ -310,13 +310,10 @@ impl<'a> BpfLoader<'a> {
// fixup btf
let section_data = obj.section_sizes.clone();
let symbol_offsets = obj.symbol_offset_by_name.clone();
obj_btf.fixup(&section_data, &symbol_offsets)?;
let btf = obj_btf.sanitize(&self.features)?;
obj_btf.fixup_and_sanitize(&section_data, &symbol_offsets, &self.features)?;
// load btf to the kernel
let raw_btf = btf.to_bytes();
let fd = load_btf(raw_btf)?;
Some(fd)
let raw_btf = obj_btf.to_bytes();
Some(load_btf(raw_btf)?)
} else {
None
}

@ -170,7 +170,7 @@ pub enum BtfError {
pub struct Btf {
header: btf_header,
strings: Vec<u8>,
types: Vec<BtfType>,
types: BtfTypes,
_endianness: Endianness,
}
@ -188,11 +188,15 @@ impl Btf {
str_len: 0x00,
},
strings: vec![0],
types: vec![BtfType::Unknown],
types: BtfTypes::default(),
_endianness: Endianness::default(),
}
}
pub(crate) fn types(&self) -> impl Iterator<Item = &BtfType> {
self.types.types.iter()
}
pub(crate) fn add_string(&mut self, name: String) -> u32 {
let str = CString::new(name).unwrap();
let name_off = self.strings.len();
@ -256,7 +260,7 @@ impl Btf {
header: &btf_header,
data: &[u8],
endianness: Endianness,
) -> Result<Vec<BtfType>, BtfError> {
) -> Result<BtfTypes, BtfError> {
let hdr_len = header.hdr_len as usize;
let type_off = header.type_off as usize;
let type_len = header.type_len as usize;
@ -266,7 +270,7 @@ impl Btf {
}
let mut data = &data[base..base + type_len];
let mut types = vec![BtfType::Unknown];
let mut types = BtfTypes::default();
while !data.is_empty() {
// Safety:
// read() reads POD values from ELF, which is sound, but the values can still contain
@ -305,34 +309,11 @@ impl Btf {
}
pub(crate) fn type_by_id(&self, type_id: u32) -> Result<&BtfType, BtfError> {
self.types
.get(type_id as usize)
.ok_or(BtfError::UnknownBtfType { type_id })
}
pub(crate) fn types(&self) -> impl Iterator<Item = &BtfType> {
self.types.iter()
self.types.type_by_id(type_id)
}
pub(crate) fn resolve_type(&self, root_type_id: u32) -> Result<u32, BtfError> {
let mut type_id = root_type_id;
for _ in 0..MAX_RESOLVE_DEPTH {
let ty = self.type_by_id(type_id)?;
use BtfType::*;
match ty {
Volatile(ty) | Const(ty) | Restrict(ty) | Typedef(ty) | TypeTag(ty) => {
// Safety: union
type_id = unsafe { ty.__bindgen_anon_1.type_ };
continue;
}
_ => return Ok(type_id),
}
}
Err(BtfError::MaximumTypeDepthReached {
type_id: root_type_id,
})
self.types.resolve_type(root_type_id)
}
pub(crate) fn type_name(&self, ty: &BtfType) -> Result<Option<Cow<'_, str>>, BtfError> {
@ -375,7 +356,7 @@ impl Btf {
let mut type_id = root_type_id;
let mut n_elems = 1;
for _ in 0..MAX_RESOLVE_DEPTH {
let ty = self.type_by_id(type_id)?;
let ty = self.types.type_by_id(type_id)?;
use BtfType::*;
let size = match ty {
@ -422,60 +403,84 @@ impl Btf {
// Safety: btf_header is POD
let mut buf = unsafe { bytes_of::<btf_header>(&self.header).to_vec() };
// Skip the first type since it's always BtfType::Unknown for type_by_id to work
for t in self.types().skip(1) {
let b = t.to_bytes();
buf.put(b.as_slice())
}
buf.extend(self.types.to_bytes());
buf.put(self.strings.as_slice());
buf
}
pub(crate) fn fixup(
pub(crate) fn fixup_and_sanitize(
&mut self,
section_sizes: &HashMap<String, u64>,
symbol_offsets: &HashMap<String, u64>,
features: &Features,
) -> Result<(), BtfError> {
let mut types = self.types.split_off(0);
for t in &mut types {
let mut types = mem::take(&mut self.types);
for i in 0..types.types.len() {
let t = &types.types[i];
let kind = t.kind()?.unwrap_or_default();
// datasec sizes aren't set by llvm
// we need to fix them here before loading the btf to the kernel
match t {
BtfType::Ptr(mut ty) => {
// Rust emits names for pointer types, which the kernel doesn't like
// While I figure out if this needs fixing in the Kernel or LLVM, we'll
// do a fixup here
ty.name_off = 0;
// Fixup PTR for Rust
// LLVM emits names for Rust pointer types, which the kernel doesn't like
// While I figure out if this needs fixing in the Kernel or LLVM, we'll
// do a fixup here
BtfType::Ptr(ty) => {
let mut fixed_ty = *ty;
fixed_ty.name_off = 0;
types.types[i] = BtfType::Ptr(fixed_ty)
}
// Sanitize VAR if they are not supported
BtfType::Var(ty, _) if !features.btf_datasec => {
types.types[i] = BtfType::new_int(ty.name_off, 1, 0, 0);
}
// Sanitize DATASEC if they are not supported
BtfType::DataSec(ty, data) if !features.btf_datasec => {
debug!("{}: not supported. replacing with STRUCT", kind);
let mut members = vec![];
for member in data {
let mt = types.type_by_id(member.type_).unwrap();
members.push(btf_member {
name_off: mt.btf_type().unwrap().name_off,
type_: member.type_,
offset: member.offset * 8,
})
}
types.types[i] = BtfType::new_struct(ty.name_off, members, 0);
}
BtfType::DataSec(mut ty, data) => {
// Fixup DATASEC
// DATASEC sizes aren't always set by LLVM
// we need to fix them here before loading the btf to the kernel
BtfType::DataSec(ty, data) if features.btf_datasec => {
// Start DataSec Fixups
let sec_name = self.string_at(ty.name_off)?;
let name = sec_name.to_string();
// There are cases when the compiler does indeed populate the
// size. If we hit this case, push to the types vector and
// continue
// There are some cases when the compiler does indeed populate the
// size
if unsafe { ty.__bindgen_anon_1.size > 0 } {
debug!("{} {}: fixup not required", kind, name);
continue;
}
let mut fixed_ty = *ty;
let mut fixed_data = data.clone();
// We need to get the size of the section from the ELF file
// Fortunately, we cached these when parsing it initially
// and we can this up by name in section_sizes
if let Some(size) = section_sizes.get(&name) {
debug!("{} {}: fixup size to {}", kind, name, size);
ty.__bindgen_anon_1.size = *size as u32;
} else {
return Err(BtfError::UnknownSectionSize { section_name: name });
}
let size =
section_sizes
.get(&name)
.ok_or_else(|| BtfError::UnknownSectionSize {
section_name: name.clone(),
})?;
debug!("{} {}: fixup size to {}", kind, name, size);
fixed_ty.__bindgen_anon_1.size = *size as u32;
// The Vec<btf_var_secinfo> contains BTF_KIND_VAR sections
// that need to have their offsets adjusted. To do this,
// we need to get the offset from the ELF file.
// This was also cached during initial parsing and
// we can query by name in symbol_offsets
for d in data {
let var_type = self.type_by_id(d.type_)?;
for d in &mut fixed_data {
let var_type = types.type_by_id(d.type_)?;
let var_kind = var_type.kind()?.unwrap();
if let BtfType::Var(vty, var) = var_type {
let var_name = self.string_at(vty.name_off)?.to_string();
@ -501,135 +506,76 @@ impl Btf {
return Err(BtfError::InvalidDatasec);
}
}
types.types[i] = BtfType::DataSec(fixed_ty, fixed_data);
}
BtfType::FuncProto(_ty, params) => {
// Fixup FUNC_PROTO
BtfType::FuncProto(ty, params) if features.btf_func => {
let mut params = params.clone();
for (i, mut param) in params.iter_mut().enumerate() {
if param.name_off == 0 && param.type_ != 0 {
param.name_off = self.add_string(format!("param{}", i));
}
}
types.types[i] = BtfType::FuncProto(*ty, params);
}
// The type does not need fixing up
_ => {}
}
}
self.types = types;
Ok(())
}
pub(crate) fn sanitize(&self, features: &Features) -> Result<Btf, BtfError> {
let mut btf = Btf::new();
btf.strings = self.strings.to_vec();
btf.header.str_len = btf.strings.len() as u32;
// Skip the first type as it's only there
// to make type_by_id work
for t in &self.types[1..] {
let kind = t.kind()?.unwrap_or_default();
match t {
BtfType::Var(ty, vars) => {
if !features.btf_datasec {
debug!("{}: not supported. replacing with INT", kind);
let int_type = BtfType::new_int(ty.name_off, 1, 0, 0);
btf.add_type(int_type);
} else {
btf.add_type(BtfType::Var(*ty, *vars));
}
// Sanitize FUNC_PROTO
BtfType::FuncProto(ty, vars) if !features.btf_func => {
debug!("{}: not supported. replacing with ENUM", kind);
let members: Vec<btf_enum> = vars
.iter()
.map(|p| btf_enum {
name_off: p.name_off,
val: p.type_ as i32,
})
.collect();
let enum_type = BtfType::new_enum(ty.name_off, members);
types.types[i] = enum_type;
}
BtfType::DataSec(ty, data) => {
if !features.btf_datasec {
debug!("{}: not supported. replacing with STRUCT", kind);
let members: Vec<btf_member> = data
.iter()
.map(|p| -> btf_member {
let mt = self.type_by_id(p.type_).unwrap();
btf_member {
name_off: mt.btf_type().unwrap().name_off,
type_: p.type_,
offset: p.offset * 8,
}
})
.collect();
let struct_type = BtfType::new_struct(ty.name_off, members, 0);
btf.add_type(struct_type);
} else {
btf.add_type(BtfType::DataSec(*ty, data.to_vec()));
}
}
BtfType::FuncProto(ty, vars) => {
if !features.btf_func {
debug!("{}: not supported. replacing with ENUM", kind);
let members: Vec<btf_enum> = vars
.iter()
.map(|p| -> btf_enum {
btf_enum {
name_off: p.name_off,
val: p.type_ as i32,
}
})
.collect();
let enum_type = BtfType::new_enum(ty.name_off, members);
btf.add_type(enum_type);
} else {
btf.add_type(BtfType::FuncProto(*ty, vars.to_vec()));
}
// Sanitize FUNC
BtfType::Func(ty) if !features.btf_func => {
debug!("{}: not supported. replacing with TYPEDEF", kind);
let typedef_type =
BtfType::new_typedef(ty.name_off, unsafe { ty.__bindgen_anon_1.type_ });
types.types[i] = typedef_type;
}
BtfType::Func(mut ty) => {
if !features.btf_func {
debug!("{}: not supported. replacing with TYPEDEF", kind);
let typedef_type =
BtfType::new_typedef(ty.name_off, unsafe { ty.__bindgen_anon_1.type_ });
btf.add_type(typedef_type);
} else if type_vlen(&ty) == btf_func_linkage::BTF_FUNC_GLOBAL as usize
&& !features.btf_func_global
{
// Sanitize BTF_FUNC_GLOBAL
BtfType::Func(ty) if !features.btf_func_global => {
let mut fixed_ty = *ty;
if type_vlen(ty) == btf_func_linkage::BTF_FUNC_GLOBAL as usize {
debug!(
"{}: BTF_FUNC_GLOBAL not supported. replacing with BTF_FUNC_STATIC",
kind
);
ty.info = (ty.info & 0xFFFF0000)
fixed_ty.info = (ty.info & 0xFFFF0000)
| (btf_func_linkage::BTF_FUNC_STATIC as u32) & 0xFFFF;
btf.add_type(BtfType::Func(ty));
} else {
btf.add_type(BtfType::Func(ty));
}
types.types[i] = BtfType::Func(fixed_ty);
}
BtfType::Float(ty) => {
if !features.btf_float {
debug!("{}: not supported. replacing with STRUCT", kind);
let struct_ty =
BtfType::new_struct(0, vec![], unsafe { ty.__bindgen_anon_1.size });
btf.add_type(struct_ty);
} else {
btf.add_type(BtfType::Float(*ty));
}
}
BtfType::DeclTag(ty, btf_decl_tag) => {
if !features.btf_decl_tag {
debug!("{}: not supported. replacing with INT", kind);
let int_type = BtfType::new_int(ty.name_off, 1, 0, 0);
btf.add_type(int_type);
} else {
btf.add_type(BtfType::DeclTag(*ty, *btf_decl_tag));
}
// Sanitize FLOAT
BtfType::Float(ty) if !features.btf_float => {
debug!("{}: not supported. replacing with STRUCT", kind);
let struct_ty =
BtfType::new_struct(0, vec![], unsafe { ty.__bindgen_anon_1.size });
types.types[i] = struct_ty;
}
BtfType::TypeTag(ty) => {
if !features.btf_type_tag {
debug!("{}: not supported. replacing with CONST", kind);
let const_type = BtfType::new_const(unsafe { ty.__bindgen_anon_1.type_ });
btf.add_type(const_type);
} else {
btf.add_type(BtfType::TypeTag(*ty));
}
// Sanitize DECL_TAG
BtfType::DeclTag(ty, _) if !features.btf_decl_tag => {
debug!("{}: not supported. replacing with INT", kind);
let int_type = BtfType::new_int(ty.name_off, 1, 0, 0);
types.types[i] = int_type;
}
// The type does not need sanitizing
ty => {
btf.add_type(ty.clone());
// Sanitize TYPE_TAG
BtfType::TypeTag(ty) if !features.btf_type_tag => {
debug!("{}: not supported. replacing with CONST", kind);
let const_type = BtfType::new_const(unsafe { ty.__bindgen_anon_1.type_ });
types.types[i] = const_type;
}
// The type does not need fixing up or sanitization
_ => {}
}
}
Ok(btf)
self.types = types;
Ok(())
}
}
@ -857,6 +803,67 @@ impl<'a> Iterator for SecInfoIter<'a> {
}
}
/// BtfTypes allows for access and manipulation of a
/// collection of BtfType objects
#[derive(Debug, Clone)]
pub(crate) struct BtfTypes {
pub(crate) types: Vec<BtfType>,
}
impl Default for BtfTypes {
fn default() -> Self {
Self {
types: vec![BtfType::Unknown],
}
}
}
impl BtfTypes {
pub(crate) fn to_bytes(&self) -> Vec<u8> {
let mut buf = vec![];
for t in self.types.iter().skip(1) {
let b = t.to_bytes();
buf.put(b.as_slice())
}
buf
}
pub(crate) fn len(&self) -> usize {
self.types.len()
}
pub(crate) fn push(&mut self, value: BtfType) {
self.types.push(value)
}
pub(crate) fn type_by_id(&self, type_id: u32) -> Result<&BtfType, BtfError> {
self.types
.get(type_id as usize)
.ok_or(BtfError::UnknownBtfType { type_id })
}
pub(crate) fn resolve_type(&self, root_type_id: u32) -> Result<u32, BtfError> {
let mut type_id = root_type_id;
for _ in 0..MAX_RESOLVE_DEPTH {
let ty = self.type_by_id(type_id)?;
use BtfType::*;
match ty {
Volatile(ty) | Const(ty) | Restrict(ty) | Typedef(ty) | TypeTag(ty) => {
// Safety: union
type_id = unsafe { ty.__bindgen_anon_1.type_ };
continue;
}
_ => return Ok(type_id),
}
}
Err(BtfError::MaximumTypeDepthReached {
type_id: root_type_id,
})
}
}
#[derive(Debug)]
pub(crate) struct SecInfo<'a> {
sec_name_off: u32,
@ -866,7 +873,9 @@ pub(crate) struct SecInfo<'a> {
#[cfg(test)]
mod tests {
use crate::generated::{btf_param, btf_var_secinfo, BTF_INT_SIGNED, BTF_VAR_STATIC};
use crate::generated::{
btf_param, btf_var_secinfo, BTF_INT_SIGNED, BTF_VAR_GLOBAL_EXTERN, BTF_VAR_STATIC,
};
use super::*;
@ -984,15 +993,68 @@ mod tests {
}
#[test]
fn test_sanitize_btf() {
fn test_fixup_ptr() {
let mut btf = Btf::new();
let name_offset = btf.add_string("int".to_string());
let int_type = BtfType::new_int(name_offset, 4, BTF_INT_SIGNED, 0);
let int_type_id = btf.add_type(int_type);
let int_type_id = btf.add_type(BtfType::new_int(name_offset, 4, BTF_INT_SIGNED, 0));
let name_offset = btf.add_string("&mut int".to_string());
let ptr_type_id = btf.add_type(BtfType::new_ptr(name_offset, int_type_id));
let features = Features {
..Default::default()
};
btf.fixup_and_sanitize(&HashMap::new(), &HashMap::new(), &features)
.unwrap();
if let BtfType::Ptr(fixed) = btf.type_by_id(ptr_type_id).unwrap() {
assert!(
fixed.name_off == 0,
"expected offset 0, got {}",
fixed.name_off
)
} else {
panic!("not a ptr")
}
// Ensure we can convert to bytes and back again
let raw = btf.to_bytes();
Btf::parse(&raw, Endianness::default()).unwrap();
}
#[test]
fn test_sanitize_var() {
let mut btf = Btf::new();
let name_offset = btf.add_string("int".to_string());
let int_type_id = btf.add_type(BtfType::new_int(name_offset, 4, BTF_INT_SIGNED, 0));
let name_offset = btf.add_string("&mut int".to_string());
let var_type_id = btf.add_type(BtfType::new_var(name_offset, int_type_id, BTF_VAR_STATIC));
let features = Features {
btf_datasec: false,
..Default::default()
};
btf.fixup_and_sanitize(&HashMap::new(), &HashMap::new(), &features)
.unwrap();
if let BtfType::Int(fixed, _) = btf.type_by_id(var_type_id).unwrap() {
assert!(fixed.name_off == name_offset)
} else {
panic!("not an int")
}
// Ensure we can convert to bytes and back again
let raw = btf.to_bytes();
Btf::parse(&raw, Endianness::default()).unwrap();
}
#[test]
fn test_sanitize_datasec() {
let mut btf = Btf::new();
let name_offset = btf.add_string("int".to_string());
let int_type_id = btf.add_type(BtfType::new_int(name_offset, 4, BTF_INT_SIGNED, 0));
let name_offset = btf.add_string("foo".to_string());
let var_type = BtfType::new_var(name_offset, int_type_id, BTF_VAR_STATIC);
let var_type_id = btf.add_type(var_type);
let var_type_id = btf.add_type(BtfType::new_var(name_offset, int_type_id, BTF_VAR_STATIC));
let name_offset = btf.add_string(".data".to_string());
let variables = vec![btf_var_secinfo {
@ -1000,171 +1062,293 @@ mod tests {
offset: 0,
size: 4,
}];
let datasec_type = BtfType::new_datasec(name_offset, variables, 4);
btf.add_type(datasec_type);
let datasec_type_id = btf.add_type(BtfType::new_datasec(name_offset, variables, 0));
let name_offset = btf.add_string("float".to_string());
let float_type = BtfType::new_float(name_offset, 16);
btf.add_type(float_type);
let features = Features {
btf_datasec: false,
..Default::default()
};
btf.fixup_and_sanitize(&HashMap::new(), &HashMap::new(), &features)
.unwrap();
if let BtfType::Struct(fixed, members) = btf.type_by_id(datasec_type_id).unwrap() {
assert!(fixed.name_off == name_offset);
assert!(members.len() == 1);
assert!(members[0].type_ == var_type_id);
assert!(members[0].offset == 0)
} else {
panic!("not a struct")
}
// Ensure we can convert to bytes and back again
let raw = btf.to_bytes();
Btf::parse(&raw, Endianness::default()).unwrap();
}
#[test]
fn test_fixup_datasec() {
let mut btf = Btf::new();
let name_offset = btf.add_string("int".to_string());
let int_type_id = btf.add_type(BtfType::new_int(name_offset, 4, BTF_INT_SIGNED, 0));
let name_offset = btf.add_string("foo".to_string());
let var_type_id = btf.add_type(BtfType::new_var(
name_offset,
int_type_id,
BTF_VAR_GLOBAL_EXTERN,
));
let name_offset = btf.add_string(".data".to_string());
let variables = vec![btf_var_secinfo {
type_: var_type_id,
offset: 0,
size: 4,
}];
let datasec_type_id = btf.add_type(BtfType::new_datasec(name_offset, variables, 0));
let features = Features {
btf_datasec: true,
..Default::default()
};
btf.fixup_and_sanitize(
&HashMap::from([(".data".to_string(), 32u64)]),
&HashMap::from([("foo".to_string(), 64u64)]),
&features,
)
.unwrap();
if let BtfType::DataSec(fixed, sec_info) = btf.type_by_id(datasec_type_id).unwrap() {
assert!(fixed.name_off == name_offset);
assert!(unsafe { fixed.__bindgen_anon_1.size } == 32);
assert!(sec_info.len() == 1);
assert!(sec_info[0].type_ == var_type_id);
assert!(
sec_info[0].offset == 64,
"expected 64, got {}",
sec_info[0].offset
)
} else {
panic!("not a datasec")
}
// Ensure we can convert to bytes and back again
let raw = btf.to_bytes();
Btf::parse(&raw, Endianness::default()).unwrap();
}
#[test]
fn test_sanitize_func_and_proto() {
let mut btf = Btf::new();
let name_offset = btf.add_string("int".to_string());
let int_type_id = btf.add_type(BtfType::new_int(name_offset, 4, BTF_INT_SIGNED, 0));
let a_name = btf.add_string("a".to_string());
let b_name = btf.add_string("b".to_string());
let params = vec![
btf_param {
name_off: a_name,
name_off: btf.add_string("a".to_string()),
type_: int_type_id,
},
btf_param {
name_off: b_name,
name_off: btf.add_string("b".to_string()),
type_: int_type_id,
},
];
let func_proto = BtfType::new_func_proto(params, int_type_id);
let func_proto_type_id = btf.add_type(func_proto);
let func_proto_type_id = btf.add_type(BtfType::new_func_proto(params, int_type_id));
let inc = btf.add_string("inc".to_string());
let func_type_id = btf.add_type(BtfType::new_func(
inc,
func_proto_type_id,
btf_func_linkage::BTF_FUNC_STATIC,
));
let features = Features {
btf_func: false,
..Default::default()
};
btf.fixup_and_sanitize(&HashMap::new(), &HashMap::new(), &features)
.unwrap();
if let BtfType::Enum(fixed, vars) = btf.type_by_id(func_proto_type_id).unwrap() {
assert!(fixed.name_off == 0);
assert!(vars.len() == 2);
assert!(btf.string_at(vars[0].name_off).unwrap() == "a");
assert!(vars[0].val == int_type_id as i32);
assert!(btf.string_at(vars[1].name_off).unwrap() == "b");
assert!(vars[1].val == int_type_id as i32);
} else {
panic!("not an emum")
}
let add = btf.add_string("static".to_string());
let func = BtfType::new_func(add, func_proto_type_id, btf_func_linkage::BTF_FUNC_STATIC);
btf.add_type(func);
if let BtfType::Typedef(fixed) = btf.type_by_id(func_type_id).unwrap() {
assert!(fixed.name_off == inc);
assert!(unsafe { fixed.__bindgen_anon_1.type_ } == func_proto_type_id);
} else {
panic!("not a typedef")
}
// Ensure we can convert to bytes and back again
let raw = btf.to_bytes();
Btf::parse(&raw, Endianness::default()).unwrap();
}
#[test]
fn test_fixup_func_proto() {
let mut btf = Btf::new();
let name_offset = btf.add_string("int".to_string());
let int_type = BtfType::new_int(name_offset, 4, BTF_INT_SIGNED, 0);
let int_type_id = btf.add_type(int_type);
let c_name = btf.add_string("c".to_string());
let d_name = btf.add_string("d".to_string());
let params = vec![
btf_param {
name_off: c_name,
name_off: 0,
type_: int_type_id,
},
btf_param {
name_off: d_name,
name_off: 0,
type_: int_type_id,
},
];
let func_proto = BtfType::new_func_proto(params, int_type_id);
let func_proto_type_id = btf.add_type(func_proto);
let add = btf.add_string("global".to_string());
let func = BtfType::new_func(add, func_proto_type_id, btf_func_linkage::BTF_FUNC_GLOBAL);
btf.add_type(func);
let features = Features {
btf_func: true,
..Default::default()
};
btf.fixup_and_sanitize(&HashMap::new(), &HashMap::new(), &features)
.unwrap();
if let BtfType::FuncProto(_, vars) = btf.type_by_id(func_proto_type_id).unwrap() {
assert!(btf.string_at(vars[0].name_off).unwrap() == "param0");
assert!(btf.string_at(vars[1].name_off).unwrap() == "param1");
} else {
panic!("not a func_proto")
}
// Ensure we can convert to bytes and back again
let raw = btf.to_bytes();
Btf::parse(&raw, Endianness::default()).unwrap();
}
#[test]
fn test_sanitize_func_global() {
let mut btf = Btf::new();
let name_offset = btf.add_string("int".to_string());
let int_type_id = btf.add_type(BtfType::new_int(name_offset, 4, BTF_INT_SIGNED, 0));
let params = vec![
btf_param {
name_off: btf.add_string("a".to_string()),
type_: int_type_id,
},
btf_param {
name_off: btf.add_string("b".to_string()),
type_: int_type_id,
},
];
let func_proto_type_id = btf.add_type(BtfType::new_func_proto(params, int_type_id));
let inc = btf.add_string("inc".to_string());
let func_type_id = btf.add_type(BtfType::new_func(
inc,
func_proto_type_id,
btf_func_linkage::BTF_FUNC_GLOBAL,
));
let features = Features {
btf_func: true,
btf_func_global: false,
..Default::default()
};
btf.fixup_and_sanitize(&HashMap::new(), &HashMap::new(), &features)
.unwrap();
if let BtfType::Func(fixed) = btf.type_by_id(func_type_id).unwrap() {
assert!(type_vlen(fixed) == btf_func_linkage::BTF_FUNC_STATIC as usize);
} else {
panic!("not a func")
}
// Ensure we can convert to bytes and back again
let raw = btf.to_bytes();
Btf::parse(&raw, Endianness::default()).unwrap();
}
#[test]
fn test_sanitize_float() {
let mut btf = Btf::new();
let name_offset = btf.add_string("float".to_string());
let float_type_id = btf.add_type(BtfType::new_float(name_offset, 16));
let features = Features {
btf_float: false,
..Default::default()
};
btf.fixup_and_sanitize(&HashMap::new(), &HashMap::new(), &features)
.unwrap();
if let BtfType::Struct(fixed, _) = btf.type_by_id(float_type_id).unwrap() {
assert!(fixed.name_off == 0);
assert!(unsafe { fixed.__bindgen_anon_1.size } == 16);
} else {
panic!("not a struct")
}
// Ensure we can convert to bytes and back again
let raw = btf.to_bytes();
Btf::parse(&raw, Endianness::default()).unwrap();
}
#[test]
fn test_sanitize_decl_tag() {
let mut btf = Btf::new();
let name_offset = btf.add_string("int".to_string());
let type_tag = BtfType::new_type_tag(name_offset, int_type_id);
btf.add_type(type_tag);
let int_type_id = btf.add_type(BtfType::new_int(name_offset, 4, BTF_INT_SIGNED, 0));
let name_offset = btf.add_string("foo".to_string());
let var_type_id = btf.add_type(BtfType::new_var(name_offset, int_type_id, BTF_VAR_STATIC));
let name_offset = btf.add_string("decl_tag".to_string());
let decl_tag = BtfType::new_decl_tag(name_offset, var_type_id, -1);
btf.add_type(decl_tag);
let cases = HashMap::from([
(
"noop",
Features {
bpf_name: true,
btf: true,
btf_func: true,
btf_func_global: true,
btf_datasec: true,
btf_float: true,
btf_decl_tag: true,
btf_type_tag: true,
},
),
(
"no datasec",
Features {
bpf_name: true,
btf: true,
btf_func: true,
btf_func_global: true,
btf_datasec: false,
btf_float: true,
btf_decl_tag: true,
btf_type_tag: true,
},
),
(
"no float",
Features {
bpf_name: true,
btf: true,
btf_func: true,
btf_func_global: true,
btf_datasec: true,
btf_float: false,
btf_decl_tag: true,
btf_type_tag: true,
},
),
(
"no func",
Features {
bpf_name: true,
btf: true,
btf_func: false,
btf_func_global: true,
btf_datasec: true,
btf_float: true,
btf_decl_tag: true,
btf_type_tag: true,
},
),
(
"no global func",
Features {
bpf_name: true,
btf: true,
btf_func: true,
btf_func_global: false,
btf_datasec: true,
btf_float: true,
btf_decl_tag: true,
btf_type_tag: true,
},
),
(
"no decl tag",
Features {
bpf_name: true,
btf: true,
btf_func: true,
btf_func_global: true,
btf_datasec: true,
btf_float: true,
btf_decl_tag: false,
btf_type_tag: true,
},
),
(
"no type tag",
Features {
bpf_name: true,
btf: true,
btf_func: true,
btf_func_global: true,
btf_datasec: true,
btf_float: true,
btf_decl_tag: true,
btf_type_tag: false,
},
),
(
"all off",
Features {
bpf_name: true,
btf: true,
btf_func: false,
btf_func_global: false,
btf_datasec: false,
btf_float: false,
btf_decl_tag: false,
btf_type_tag: false,
},
),
]);
for (name, features) in cases {
println!("[CASE] Sanitize {}", name);
let new_btf = btf.sanitize(&features).unwrap();
let raw_new_btf = new_btf.to_bytes();
Btf::parse(&raw_new_btf, Endianness::default()).unwrap();
let decl_tag_type_id = btf.add_type(BtfType::new_decl_tag(name_offset, var_type_id, -1));
let features = Features {
btf_decl_tag: false,
..Default::default()
};
btf.fixup_and_sanitize(&HashMap::new(), &HashMap::new(), &features)
.unwrap();
if let BtfType::Int(fixed, _) = btf.type_by_id(decl_tag_type_id).unwrap() {
assert!(fixed.name_off == name_offset);
assert!(unsafe { fixed.__bindgen_anon_1.size } == 1);
} else {
panic!("not an int")
}
// Ensure we can convert to bytes and back again
let raw = btf.to_bytes();
Btf::parse(&raw, Endianness::default()).unwrap();
}
#[test]
fn test_sanitize_type_tag() {
let mut btf = Btf::new();
let int_type_id = btf.add_type(BtfType::new_int(0, 4, BTF_INT_SIGNED, 0));
let name_offset = btf.add_string("int".to_string());
let type_tag_type = btf.add_type(BtfType::new_type_tag(name_offset, int_type_id));
btf.add_type(BtfType::new_ptr(0, type_tag_type));
let features = Features {
btf_type_tag: false,
..Default::default()
};
btf.fixup_and_sanitize(&HashMap::new(), &HashMap::new(), &features)
.unwrap();
if let BtfType::Const(fixed) = btf.type_by_id(type_tag_type).unwrap() {
assert!(unsafe { fixed.__bindgen_anon_1.type_ } == int_type_id);
} else {
panic!("not a const")
}
// Ensure we can convert to bytes and back again
let raw = btf.to_bytes();
Btf::parse(&raw, Endianness::default()).unwrap();
}
}

@ -448,10 +448,10 @@ impl BtfType {
BtfType::TypeTag(btf_type)
}
pub(crate) fn new_ptr(type_: u32) -> BtfType {
pub(crate) fn new_ptr(name_off: u32, type_: u32) -> BtfType {
let info = (BTF_KIND_PTR) << 24;
let mut btf_type = unsafe { std::mem::zeroed::<btf_type>() };
btf_type.name_off = 0;
btf_type.name_off = name_off;
btf_type.info = info;
btf_type.__bindgen_anon_1.type_ = type_;
BtfType::Ptr(btf_type)

@ -710,7 +710,7 @@ pub(crate) fn is_btf_type_tag_supported() -> bool {
let type_tag = BtfType::new_type_tag(name_offset, int_type_id);
let type_tag_type = btf.add_type(type_tag);
btf.add_type(BtfType::new_ptr(type_tag_type));
btf.add_type(BtfType::new_ptr(0, type_tag_type));
let btf_bytes = btf.to_bytes();

Loading…
Cancel
Save