sanitizer
Sanitizers are tools that help detect and prevent various types of bugs and vulnerabilities in software. They are available in compilers and work by instrumenting the code to add additional runtime checks. While they provide powerful tools for identifying bugs or security issues, it's important to note that using sanitizers can introduce runtime overhead and might not catch all possible issues. Therefore, they are typically used alongside other best practices in software development, such as testing and fuzzing, to ensure the highest level of software quality and security.
The tracking issues for this feature are:
This feature allows for use of one of following sanitizers:
-
Those intended for testing or fuzzing (but not production use):
- AddressSanitizer a fast memory error detector.
- HWAddressSanitizer a memory error detector similar to AddressSanitizer, but based on partial hardware assistance.
- LeakSanitizer a run-time memory leak detector.
- MemorySanitizer a detector of uninitialized reads.
- ThreadSanitizer a fast data race detector.
-
Those that apart from testing, may be used in production:
- ControlFlowIntegrity LLVM Control Flow Integrity (CFI) provides forward-edge control flow protection.
- DataFlowSanitizer a generic dynamic data flow analysis framework.
- KernelControlFlowIntegrity LLVM Kernel Control Flow Integrity (KCFI) provides forward-edge control flow protection for operating systems kernels.
- MemTagSanitizer fast memory error detector based on Armv8.5-A Memory Tagging Extension.
- SafeStack provides backward-edge control flow protection by separating the stack into safe and unsafe regions.
- ShadowCallStack provides backward-edge control flow protection (aarch64 only).
To enable a sanitizer compile with -Zsanitizer=address
, -Zsanitizer=cfi
,
-Zsanitizer=dataflow
,-Zsanitizer=hwaddress
, -Zsanitizer=leak
,
-Zsanitizer=memory
, -Zsanitizer=memtag
, -Zsanitizer=shadow-call-stack
, or
-Zsanitizer=thread
. You might also need the --target
and build-std
flags.
Example:
$ RUSTFLAGS=-Zsanitizer=address cargo build -Zbuild-std --target x86_64-unknown-linux-gnu
Additional options for sanitizers can be passed to LLVM command line argument
processor via LLVM arguments using llvm-args
codegen option (e.g.,
-Cllvm-args=-dfsan-combine-pointer-labels-on-load=false
). See the sanitizer
documentation for more information about additional options.
AddressSanitizer
AddressSanitizer is a memory error detector. It can detect the following types of bugs:
- Out of bound accesses to heap, stack and globals
- Use after free
- Use after return (runtime flag
ASAN_OPTIONS=detect_stack_use_after_return=1
) - Use after scope
- Double-free, invalid free
- Memory leaks
The memory leak detection is enabled by default on Linux, and can be enabled
with runtime flag ASAN_OPTIONS=detect_leaks=1
on macOS.
AddressSanitizer is supported on the following targets:
aarch64-apple-darwin
aarch64-unknown-fuchsia
aarch64-unknown-linux-gnu
x86_64-apple-darwin
x86_64-unknown-fuchsia
x86_64-unknown-freebsd
x86_64-unknown-linux-gnu
AddressSanitizer works with non-instrumented code although it will impede its ability to detect some bugs. It is not expected to produce false positive reports.
See the Clang AddressSanitizer documentation for more details.
Examples
Stack buffer overflow:
fn main() { let xs = [0, 1, 2, 3]; let _y = unsafe { *xs.as_ptr().offset(4) }; }
$ export RUSTFLAGS=-Zsanitizer=address RUSTDOCFLAGS=-Zsanitizer=address
$ cargo run -Zbuild-std --target x86_64-unknown-linux-gnu
==37882==ERROR: AddressSanitizer: stack-buffer-overflow on address 0x7ffe400e6250 at pc 0x5609a841fb20 bp 0x7ffe400e6210 sp 0x7ffe400e6208
READ of size 4 at 0x7ffe400e6250 thread T0
#0 0x5609a841fb1f in example::main::h628ffc6626ed85b2 /.../src/main.rs:3:23
...
Address 0x7ffe400e6250 is located in stack of thread T0 at offset 48 in frame
#0 0x5609a841f8af in example::main::h628ffc6626ed85b2 /.../src/main.rs:1
This frame has 1 object(s):
[32, 48) 'xs' (line 2) <== Memory access at offset 48 overflows this variable
HINT: this may be a false positive if your program uses some custom stack unwind mechanism, swapcontext or vfork
(longjmp and C++ exceptions *are* supported)
SUMMARY: AddressSanitizer: stack-buffer-overflow /.../src/main.rs:3:23 in example::main::h628ffc6626ed85b2
Shadow bytes around the buggy address:
0x100048014bf0: 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00
0x100048014c00: 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00
0x100048014c10: 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00
0x100048014c20: 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00
0x100048014c30: 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00
=>0x100048014c40: 00 00 00 00 f1 f1 f1 f1 00 00[f3]f3 00 00 00 00
0x100048014c50: 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00
0x100048014c60: 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00
0x100048014c70: f1 f1 f1 f1 00 00 f3 f3 00 00 00 00 00 00 00 00
0x100048014c80: 00 00 00 00 00 00 00 00 00 00 00 00 f1 f1 f1 f1
0x100048014c90: 00 00 f3 f3 00 00 00 00 00 00 00 00 00 00 00 00
Shadow byte legend (one shadow byte represents 8 application bytes):
Addressable: 00
Partially addressable: 01 02 03 04 05 06 07
Heap left redzone: fa
Freed heap region: fd
Stack left redzone: f1
Stack mid redzone: f2
Stack right redzone: f3
Stack after return: f5
Stack use after scope: f8
Global redzone: f9
Global init order: f6
Poisoned by user: f7
Container overflow: fc
Array cookie: ac
Intra object redzone: bb
ASan internal: fe
Left alloca redzone: ca
Right alloca redzone: cb
Shadow gap: cc
==37882==ABORTING
Use of a stack object after its scope has already ended:
static mut P: *mut usize = std::ptr::null_mut(); fn main() { unsafe { { let mut x = 0; P = &mut x; } std::ptr::write_volatile(P, 123); } }
$ export RUSTFLAGS=-Zsanitizer=address RUSTDOCFLAGS=-Zsanitizer=address
$ cargo run -Zbuild-std --target x86_64-unknown-linux-gnu
=================================================================
==39249==ERROR: AddressSanitizer: stack-use-after-scope on address 0x7ffc7ed3e1a0 at pc 0x55c98b262a8e bp 0x7ffc7ed3e050 sp 0x7ffc7ed3e048
WRITE of size 8 at 0x7ffc7ed3e1a0 thread T0
#0 0x55c98b262a8d in core::ptr::write_volatile::he21f1df5a82f329a /.../src/rust/src/libcore/ptr/mod.rs:1048:5
#1 0x55c98b262cd2 in example::main::h628ffc6626ed85b2 /.../src/main.rs:9:9
...
Address 0x7ffc7ed3e1a0 is located in stack of thread T0 at offset 32 in frame
#0 0x55c98b262bdf in example::main::h628ffc6626ed85b2 /.../src/main.rs:3
This frame has 1 object(s):
[32, 40) 'x' (line 6) <== Memory access at offset 32 is inside this variable
HINT: this may be a false positive if your program uses some custom stack unwind mechanism, swapcontext or vfork
(longjmp and C++ exceptions *are* supported)
SUMMARY: AddressSanitizer: stack-use-after-scope /.../src/rust/src/libcore/ptr/mod.rs:1048:5 in core::ptr::write_volatile::he21f1df5a82f329a
Shadow bytes around the buggy address:
0x10000fd9fbe0: 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00
0x10000fd9fbf0: 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00
0x10000fd9fc00: 00 00 00 00 00 00 00 00 00 00 00 00 f1 f1 f1 f1
0x10000fd9fc10: f8 f8 f3 f3 00 00 00 00 00 00 00 00 00 00 00 00
0x10000fd9fc20: 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00
=>0x10000fd9fc30: f1 f1 f1 f1[f8]f3 f3 f3 00 00 00 00 00 00 00 00
0x10000fd9fc40: 00 00 00 00 00 00 00 00 00 00 00 00 f1 f1 f1 f1
0x10000fd9fc50: 00 00 f3 f3 00 00 00 00 00 00 00 00 00 00 00 00
0x10000fd9fc60: 00 00 00 00 00 00 00 00 f1 f1 f1 f1 00 00 f3 f3
0x10000fd9fc70: 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00
0x10000fd9fc80: 00 00 00 00 f1 f1 f1 f1 00 00 f3 f3 00 00 00 00
Shadow byte legend (one shadow byte represents 8 application bytes):
Addressable: 00
Partially addressable: 01 02 03 04 05 06 07
Heap left redzone: fa
Freed heap region: fd
Stack left redzone: f1
Stack mid redzone: f2
Stack right redzone: f3
Stack after return: f5
Stack use after scope: f8
Global redzone: f9
Global init order: f6
Poisoned by user: f7
Container overflow: fc
Array cookie: ac
Intra object redzone: bb
ASan internal: fe
Left alloca redzone: ca
Right alloca redzone: cb
Shadow gap: cc
==39249==ABORTING
ControlFlowIntegrity
The LLVM CFI support in the Rust compiler provides forward-edge control flow protection for both Rust-compiled code only and for C or C++ and Rust -compiled code mixed-language binaries, also known as “mixed binaries” (i.e., for when C or C++ and Rust -compiled code share the same virtual address space), by aggregating function pointers in groups identified by their return and parameter types.
LLVM CFI can be enabled with -Zsanitizer=cfi
and requires LTO (i.e.,
-Clinker-plugin-lto
or -Clto
). Cross-language LLVM CFI can be enabled with
-Zsanitizer=cfi
, and requires the -Zsanitizer-cfi-normalize-integers
option
to be used with Clang -fsanitize-cfi-icall-experimental-normalize-integers
option for cross-language LLVM CFI support, and proper (i.e., non-rustc) LTO
(i.e., -Clinker-plugin-lto
).
It is recommended to rebuild the standard library with CFI enabled by using the
Cargo build-std feature (i.e., -Zbuild-std
) when enabling CFI.
See the Clang ControlFlowIntegrity documentation for more details.
Example 1: Redirecting control flow using an indirect branch/call to an invalid destination
#![feature(naked_functions)]
use std::arch::asm;
use std::mem;
fn add_one(x: i32) -> i32 {
x + 1
}
#[naked]
pub extern "C" fn add_two(x: i32) {
// x + 2 preceded by a landing pad/nop block
unsafe {
asm!(
"
nop
nop
nop
nop
nop
nop
nop
nop
nop
lea eax, [rdi+2]
ret
",
options(noreturn)
);
}
}
fn do_twice(f: fn(i32) -> i32, arg: i32) -> i32 {
f(arg) + f(arg)
}
fn main() {
let answer = do_twice(add_one, 5);
println!("The answer is: {}", answer);
println!("With CFI enabled, you should not see the next answer");
let f: fn(i32) -> i32 = unsafe {
// Offset 0 is a valid branch/call destination (i.e., the function entry
// point), but offsets 1-8 within the landing pad/nop block are invalid
// branch/call destinations (i.e., within the body of the function).
mem::transmute::<*const u8, fn(i32) -> i32>((add_two as *const u8).offset(5))
};
let next_answer = do_twice(f, 5);
println!("The next answer is: {}", next_answer);
}
Fig. 1. Redirecting control flow using an indirect branch/call to an invalid destination (i.e., within the body of the function).
$ cargo run --release
Compiling rust-cfi-1 v0.1.0 (/home/rcvalle/rust-cfi-1)
Finished release [optimized] target(s) in 0.42s
Running `target/release/rust-cfi-1`
The answer is: 12
With CFI enabled, you should not see the next answer
The next answer is: 14
$
Fig. 2. Build and execution of Fig. 1 with LLVM CFI disabled.
$ RUSTFLAGS="-Clinker-plugin-lto -Clinker=clang -Clink-arg=-fuse-ld=lld -Zsanitizer=cfi" cargo run -Zbuild-std -Zbuild-std-features --release --target x86_64-unknown-linux-gnu
...
Compiling rust-cfi-1 v0.1.0 (/home/rcvalle/rust-cfi-1)
Finished release [optimized] target(s) in 1m 08s
Running `target/x86_64-unknown-linux-gnu/release/rust-cfi-1`
The answer is: 12
With CFI enabled, you should not see the next answer
Illegal instruction
$
Fig. 3. Build and execution of Fig. 1 with LLVM CFI enabled.
When LLVM CFI is enabled, if there are any attempts to change/hijack control flow using an indirect branch/call to an invalid destination, the execution is terminated (see Fig. 3).
Example 2: Redirecting control flow using an indirect branch/call to a function with a different number of parameters
use std::mem; fn add_one(x: i32) -> i32 { x + 1 } fn add_two(x: i32, _y: i32) -> i32 { x + 2 } fn do_twice(f: fn(i32) -> i32, arg: i32) -> i32 { f(arg) + f(arg) } fn main() { let answer = do_twice(add_one, 5); println!("The answer is: {}", answer); println!("With CFI enabled, you should not see the next answer"); let f: fn(i32) -> i32 = unsafe { mem::transmute::<*const u8, fn(i32) -> i32>(add_two as *const u8) }; let next_answer = do_twice(f, 5); println!("The next answer is: {}", next_answer); }
Fig. 4. Redirecting control flow using an indirect branch/call to a function with a different number of parameters than arguments intended/passed in the call/branch site.
$ cargo run --release
Compiling rust-cfi-2 v0.1.0 (/home/rcvalle/rust-cfi-2)
Finished release [optimized] target(s) in 0.43s
Running `target/release/rust-cfi-2`
The answer is: 12
With CFI enabled, you should not see the next answer
The next answer is: 14
$
Fig. 5. Build and execution of Fig. 4 with LLVM CFI disabled.
$ RUSTFLAGS="-Clinker-plugin-lto -Clinker=clang -Clink-arg=-fuse-ld=lld -Zsanitizer=cfi" cargo run -Zbuild-std -Zbuild-std-features --release --target x86_64-unknown-linux-gnu
...
Compiling rust-cfi-2 v0.1.0 (/home/rcvalle/rust-cfi-2)
Finished release [optimized] target(s) in 1m 08s
Running `target/x86_64-unknown-linux-gnu/release/rust-cfi-2`
The answer is: 12
With CFI enabled, you should not see the next answer
Illegal instruction
$
Fig. 6. Build and execution of Fig. 4 with LLVM CFI enabled.
When LLVM CFI is enabled, if there are any attempts to change/hijack control flow using an indirect branch/call to a function with different number of parameters than arguments intended/passed in the call/branch site, the execution is also terminated (see Fig. 6).
Example 3: Redirecting control flow using an indirect branch/call to a function with different return and parameter types
use std::mem; fn add_one(x: i32) -> i32 { x + 1 } fn add_two(x: i64) -> i64 { x + 2 } fn do_twice(f: fn(i32) -> i32, arg: i32) -> i32 { f(arg) + f(arg) } fn main() { let answer = do_twice(add_one, 5); println!("The answer is: {}", answer); println!("With CFI enabled, you should not see the next answer"); let f: fn(i32) -> i32 = unsafe { mem::transmute::<*const u8, fn(i32) -> i32>(add_two as *const u8) }; let next_answer = do_twice(f, 5); println!("The next answer is: {}", next_answer); }
Fig. 7. Redirecting control flow using an indirect branch/call to a function with different return and parameter types than the return type expected and arguments intended/passed at the call/branch site.
$ cargo run --release
Compiling rust-cfi-3 v0.1.0 (/home/rcvalle/rust-cfi-3)
Finished release [optimized] target(s) in 0.44s
Running `target/release/rust-cfi-3`
The answer is: 12
With CFI enabled, you should not see the next answer
The next answer is: 14
$
Fig. 8. Build and execution of Fig. 7 with LLVM CFI disabled.
$ RUSTFLAGS="-Clinker-plugin-lto -Clinker=clang -Clink-arg=-fuse-ld=lld -Zsanitizer=cfi" cargo run -Zbuild-std -Zbuild-std-features --release --target x86_64-unknown-linux-gnu
...
Compiling rust-cfi-3 v0.1.0 (/home/rcvalle/rust-cfi-3)
Finished release [optimized] target(s) in 1m 07s
Running `target/x86_64-unknown-linux-gnu/release/rust-cfi-3`
The answer is: 12
With CFI enabled, you should not see the next answer
Illegal instruction
$
Fig. 9. Build and execution of Fig. 7 with LLVM CFI enabled.
When LLVM CFI is enabled, if there are any attempts to change/hijack control flow using an indirect branch/call to a function with different return and parameter types than the return type expected and arguments intended/passed in the call/branch site, the execution is also terminated (see Fig. 9).
Example 4: Redirecting control flow using an indirect branch/call to a function with different return and parameter types across the FFI boundary
int
do_twice(int (*fn)(int), int arg)
{
return fn(arg) + fn(arg);
}
Fig. 10. Example C library.
use std::mem;
#[link(name = "foo")]
extern "C" {
fn do_twice(f: unsafe extern "C" fn(i32) -> i32, arg: i32) -> i32;
}
unsafe extern "C" fn add_one(x: i32) -> i32 {
x + 1
}
unsafe extern "C" fn add_two(x: i64) -> i64 {
x + 2
}
fn main() {
let answer = unsafe { do_twice(add_one, 5) };
println!("The answer is: {}", answer);
println!("With CFI enabled, you should not see the next answer");
let f: unsafe extern "C" fn(i32) -> i32 = unsafe {
mem::transmute::<*const u8, unsafe extern "C" fn(i32) -> i32>(add_two as *const u8)
};
let next_answer = unsafe { do_twice(f, 5) };
println!("The next answer is: {}", next_answer);
}
Fig. 11. Redirecting control flow using an indirect branch/call to a function with different return and parameter types than the return type expected and arguments intended/passed in the call/branch site, across the FFI boundary.
$ make
mkdir -p target/release
clang -I. -Isrc -Wall -c src/foo.c -o target/release/libfoo.o
llvm-ar rcs target/release/libfoo.a target/release/libfoo.o
RUSTFLAGS="-L./target/release -Clinker=clang -Clink-arg=-fuse-ld=lld" cargo build --release
Compiling rust-cfi-4 v0.1.0 (/home/rcvalle/rust-cfi-4)
Finished release [optimized] target(s) in 0.49s
$ ./target/release/rust-cfi-4
The answer is: 12
With CFI enabled, you should not see the next answer
The next answer is: 14
$
Fig. 12. Build and execution of Figs. 10–11 with LLVM CFI disabled.
$ make
mkdir -p target/release
clang -I. -Isrc -Wall -flto -fsanitize=cfi -fsanitize-cfi-icall-experimental-normalize-integers -fvisibility=hidden -c -emit-llvm src/foo.c -o target/release/libfoo.bc
llvm-ar rcs target/release/libfoo.a target/release/libfoo.bc
RUSTFLAGS="-L./target/release -Clinker-plugin-lto -Clinker=clang -Clink-arg=-fuse-ld=lld -Zsanitizer=cfi -Zsanitizer-cfi-normalize-integers" cargo build -Zbuild-std -Zbuild-std-features --release --target x86_64-unknown-linux-gnu
...
Compiling rust-cfi-4 v0.1.0 (/home/rcvalle/rust-cfi-4)
Finished release [optimized] target(s) in 1m 06s
$ ./target/x86_64-unknown-linux-gnu/release/rust-cfi-4
The answer is: 12
With CFI enabled, you should not see the next answer
Illegal instruction
$
Fig. 13. Build and execution of FIgs. 10–11 with LLVM CFI enabled.
When LLVM CFI is enabled, if there are any attempts to redirect control flow using an indirect branch/call to a function with different return and parameter types than the return type expected and arguments intended/passed in the call/branch site, even across the FFI boundary and for extern "C" function types indirectly called (i.e., callbacks/function pointers) across the FFI boundary, the execution is also terminated (see Fig. 13).
HWAddressSanitizer
HWAddressSanitizer is a newer variant of AddressSanitizer that consumes much less memory.
HWAddressSanitizer is supported on the following targets:
aarch64-linux-android
aarch64-unknown-linux-gnu
HWAddressSanitizer requires tagged-globals
target feature to instrument
globals. To enable this target feature compile with -C target-feature=+tagged-globals
See the Clang HWAddressSanitizer documentation for more details.
Example
Heap buffer overflow:
fn main() { let xs = vec![0, 1, 2, 3]; let _y = unsafe { *xs.as_ptr().offset(4) }; }
$ rustc main.rs -Zsanitizer=hwaddress -C target-feature=+tagged-globals -C
linker=aarch64-linux-gnu-gcc -C link-arg=-fuse-ld=lld --target
aarch64-unknown-linux-gnu
$ ./main
==241==ERROR: HWAddressSanitizer: tag-mismatch on address 0xefdeffff0050 at pc 0xaaaae0ae4a98
READ of size 4 at 0xefdeffff0050 tags: 2c/00 (ptr/mem) in thread T0
#0 0xaaaae0ae4a94 (/.../main+0x54a94)
...
[0xefdeffff0040,0xefdeffff0060) is a small allocated heap chunk; size: 32 offset: 16
0xefdeffff0050 is located 0 bytes to the right of 16-byte region [0xefdeffff0040,0xefdeffff0050)
allocated here:
#0 0xaaaae0acb80c (/.../main+0x3b80c)
...
Thread: T0 0xeffe00002000 stack: [0xffffc28ad000,0xffffc30ad000) sz: 8388608 tls: [0xffffaa10a020,0xffffaa10a7d0)
Memory tags around the buggy address (one tag corresponds to 16 bytes):
0xfefcefffef80: 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00
0xfefcefffef90: 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00
0xfefcefffefa0: 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00
0xfefcefffefb0: 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00
0xfefcefffefc0: 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00
0xfefcefffefd0: 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00
0xfefcefffefe0: 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00
0xfefcefffeff0: 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00
=>0xfefceffff000: d7 d7 05 00 2c [00] 00 00 00 00 00 00 00 00 00 00
0xfefceffff010: 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00
0xfefceffff020: 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00
0xfefceffff030: 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00
0xfefceffff040: 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00
0xfefceffff050: 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00
0xfefceffff060: 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00
0xfefceffff070: 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00
0xfefceffff080: 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00
Tags for short granules around the buggy address (one tag corresponds to 16 bytes):
0xfefcefffeff0: .. .. .. .. .. .. .. .. .. .. .. .. .. .. .. ..
=>0xfefceffff000: .. .. 8c .. .. [..] .. .. .. .. .. .. .. .. .. ..
0xfefceffff010: .. .. .. .. .. .. .. .. .. .. .. .. .. .. .. ..
See https://clang.llvm.org/docs/HardwareAssistedAddressSanitizerDesign.html#short-granules for a description of short granule tags
Registers where the failure occurred (pc 0xaaaae0ae4a98):
x0 2c00efdeffff0050 x1 0000000000000004 x2 0000000000000004 x3 0000000000000000
x4 0000fffefc30ac37 x5 000000000000005d x6 00000ffffc30ac37 x7 0000efff00000000
x8 2c00efdeffff0050 x9 0200efff00000000 x10 0000000000000000 x11 0200efff00000000
x12 0200effe00000310 x13 0200effe00000310 x14 0000000000000008 x15 5d00ffffc30ac360
x16 0000aaaae0ad062c x17 0000000000000003 x18 0000000000000001 x19 0000ffffc30ac658
x20 4e00ffffc30ac6e0 x21 0000aaaae0ac5e10 x22 0000000000000000 x23 0000000000000000
x24 0000000000000000 x25 0000000000000000 x26 0000000000000000 x27 0000000000000000
x28 0000000000000000 x29 0000ffffc30ac5a0 x30 0000aaaae0ae4a98
SUMMARY: HWAddressSanitizer: tag-mismatch (/.../main+0x54a94)
KernelControlFlowIntegrity
The LLVM Kernel Control Flow Integrity (CFI) support to the Rust compiler initially provides forward-edge control flow protection for operating systems kernels for Rust-compiled code only by aggregating function pointers in groups identified by their return and parameter types. (See LLVM commit cff5bef "KCFI sanitizer".)
Forward-edge control flow protection for C or C++ and Rust -compiled code "mixed binaries" (i.e., for when C or C++ and Rust -compiled code share the same virtual address space) will be provided in later work by defining and using compatible type identifiers (see Type metadata in the design document in the tracking issue #89653).
LLVM KCFI can be enabled with -Zsanitizer=kcfi
.
LLVM KCFI is supported on the following targets:
aarch64-linux-android
aarch64-unknown-linux-gnu
x86_64-linux-android
x86_64-unknown-linux-gnu
See the Clang KernelControlFlowIntegrity documentation for more details.
DataFlowSanitizer
DataFlowSanitizer is a generalised dynamic data flow analysis.
Unlike other Sanitizer tools, this tool is not designed to detect a specific class of bugs on its own. Instead, it provides a generic dynamic data flow analysis framework to be used by clients to help detect application-specific issues within their own code.
DataFlowSanitizer is supported on the following targets:
x86_64-unknown-linux-gnu
See the Clang DataFlowSanitizer documentation for more details.
KernelAddressSanitizer
KernelAddressSanitizer (KASAN) is a freestanding version of AddressSanitizer which is suitable for detecting memory errors in programs which do not have a runtime environment, such as operating system kernels. KernelAddressSanitizer requires manual implementation of the underlying functions used for tracking KernelAddressSanitizer state.
KernelAddressSanitizer is supported on the following targets:
aarch64-unknown-none
riscv64gc-unknown-none-elf
riscv64imac-unknown-none-elf
x86_64-unknown-none
See the Linux Kernel's KernelAddressSanitizer documentation for more details.
LeakSanitizer
LeakSanitizer is run-time memory leak detector.
LeakSanitizer is supported on the following targets:
aarch64-apple-darwin
aarch64-unknown-linux-gnu
x86_64-apple-darwin
x86_64-unknown-linux-gnu
See the Clang LeakSanitizer documentation for more details.
MemorySanitizer
MemorySanitizer is detector of uninitialized reads.
MemorySanitizer is supported on the following targets:
aarch64-unknown-linux-gnu
x86_64-unknown-freebsd
x86_64-unknown-linux-gnu
MemorySanitizer requires all program code to be instrumented. C/C++ dependencies
need to be recompiled using Clang with -fsanitize=memory
option. Failing to
achieve that will result in false positive reports.
See the Clang MemorySanitizer documentation for more details.
Example
Detecting the use of uninitialized memory. The -Zbuild-std
flag rebuilds and
instruments the standard library, and is strictly necessary for the correct
operation of the tool. The -Zsanitizer-memory-track-origins
enables tracking
of the origins of uninitialized memory:
use std::mem::MaybeUninit; fn main() { unsafe { let a = MaybeUninit::<[usize; 4]>::uninit(); let a = a.assume_init(); println!("{}", a[2]); } }
$ export \
RUSTFLAGS='-Zsanitizer=memory -Zsanitizer-memory-track-origins' \
RUSTDOCFLAGS='-Zsanitizer=memory -Zsanitizer-memory-track-origins'
$ cargo clean
$ cargo run -Zbuild-std --target x86_64-unknown-linux-gnu
==9416==WARNING: MemorySanitizer: use-of-uninitialized-value
#0 0x560c04f7488a in core::fmt::num::imp::fmt_u64::haa293b0b098501ca $RUST/build/x86_64-unknown-linux-gnu/stage1/lib/rustlib/src/rust/src/libcore/fmt/num.rs:202:16
...
Uninitialized value was stored to memory at
#0 0x560c04ae898a in __msan_memcpy.part.0 $RUST/src/llvm-project/compiler-rt/lib/msan/msan_interceptors.cc:1558:3
#1 0x560c04b2bf88 in memory::main::hd2333c1899d997f5 $CWD/src/main.rs:6:16
Uninitialized value was created by an allocation of 'a' in the stack frame of function '_ZN6memory4main17hd2333c1899d997f5E'
#0 0x560c04b2bc50 in memory::main::hd2333c1899d997f5 $CWD/src/main.rs:3
MemTagSanitizer
MemTagSanitizer detects a similar class of errors as AddressSanitizer and HardwareAddressSanitizer, but with lower overhead suitable for use as hardening for production binaries.
MemTagSanitizer is supported on the following targets:
aarch64-linux-android
aarch64-unknown-linux-gnu
MemTagSanitizer requires hardware support and the mte
target feature.
To enable this target feature compile with -C target-feature="+mte"
.
See the LLVM MemTagSanitizer documentation for more details.
SafeStack
SafeStack provides backward edge control flow protection by separating the stack into data which is only accessed safely (the safe stack) and all other data (the unsafe stack).
SafeStack can be enabled with the -Zsanitizer=safestack
option and is supported on the following targets:
x86_64-unknown-linux-gnu
See the Clang SafeStack documentation for more details.
ShadowCallStack
ShadowCallStack provides backward edge control flow protection by storing a function's return address in a separately allocated 'shadow call stack' and loading the return address from that shadow call stack.
ShadowCallStack requires a platform ABI which reserves x18
as the instrumentation makes use of this register.
ShadowCallStack can be enabled with -Zsanitizer=shadow-call-stack
option and is supported on the following targets:
aarch64-linux-android
A runtime must be provided by the application or operating system.
See the Clang ShadowCallStack documentation for more details.
ThreadSanitizer
ThreadSanitizer is a data race detection tool. It is supported on the following targets:
aarch64-apple-darwin
aarch64-unknown-linux-gnu
x86_64-apple-darwin
x86_64-unknown-freebsd
x86_64-unknown-linux-gnu
To work correctly ThreadSanitizer needs to be "aware" of all synchronization
operations in a program. It generally achieves that through combination of
library interception (for example synchronization performed through
pthread_mutex_lock
/ pthread_mutex_unlock
) and compile time instrumentation
(e.g. atomic operations). Using it without instrumenting all the program code
can lead to false positive reports.
ThreadSanitizer does not support atomic fences std::sync::atomic::fence
,
nor synchronization performed using inline assembly code.
See the Clang ThreadSanitizer documentation for more details.
Example
static mut A: usize = 0; fn main() { let t = std::thread::spawn(|| { unsafe { A += 1 }; }); unsafe { A += 1 }; t.join().unwrap(); }
$ export RUSTFLAGS=-Zsanitizer=thread RUSTDOCFLAGS=-Zsanitizer=thread
$ cargo run -Zbuild-std --target x86_64-unknown-linux-gnu
==================
WARNING: ThreadSanitizer: data race (pid=10574)
Read of size 8 at 0x5632dfe3d030 by thread T1:
#0 example::main::_$u7b$$u7b$closure$u7d$$u7d$::h23f64b0b2f8c9484 ../src/main.rs:5:18 (example+0x86cec)
...
Previous write of size 8 at 0x5632dfe3d030 by main thread:
#0 example::main::h628ffc6626ed85b2 /.../src/main.rs:7:14 (example+0x868c8)
...
#11 main <null> (example+0x86a1a)
Location is global 'example::A::h43ac149ddf992709' of size 8 at 0x5632dfe3d030 (example+0x000000bd9030)
Instrumentation of external dependencies and std
The sanitizers to varying degrees work correctly with partially instrumented code. On the one extreme is LeakSanitizer that doesn't use any compile time instrumentation, on the other is MemorySanitizer that requires that all program code to be instrumented (failing to achieve that will inevitably result in false positives).
It is strongly recommended to combine sanitizers with recompiled and
instrumented standard library, for example using cargo -Zbuild-std
functionality.
Build scripts and procedural macros
Use of sanitizers together with build scripts and procedural macros is technically possible, but in almost all cases it would be best avoided. This is especially true for procedural macros which would require an instrumented version of rustc.
In more practical terms when using cargo always remember to pass --target
flag, so that rustflags will not be applied to build scripts and procedural
macros.
Symbolizing the Reports
Sanitizers produce symbolized stacktraces when llvm-symbolizer binary is in PATH
.