398 lines
12 KiB
Rust
398 lines
12 KiB
Rust
// revisions: all strong basic none missing
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// assembly-output: emit-asm
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// ignore-macos slightly different policy on stack protection of arrays
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// ignore-windows stack check code uses different function names
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// ignore-nvptx64 stack protector is not supported
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// ignore-wasm32-bare
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// [all] compile-flags: -Z stack-protector=all
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// [strong] compile-flags: -Z stack-protector=strong
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// [basic] compile-flags: -Z stack-protector=basic
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// [none] compile-flags: -Z stack-protector=none
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// compile-flags: -C opt-level=2 -Z merge-functions=disabled
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#![crate_type = "lib"]
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#![allow(incomplete_features)]
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#![feature(unsized_locals, unsized_fn_params)]
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// CHECK-LABEL: emptyfn:
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#[no_mangle]
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pub fn emptyfn() {
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// all: __stack_chk_fail
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// strong-NOT: __stack_chk_fail
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// basic-NOT: __stack_chk_fail
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// none-NOT: __stack_chk_fail
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// missing-NOT: __stack_chk_fail
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}
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// CHECK-LABEL: array_char
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#[no_mangle]
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pub fn array_char(f: fn(*const char)) {
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let a = ['c'; 1];
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let b = ['d'; 3];
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let c = ['e'; 15];
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f(&a as *const _);
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f(&b as *const _);
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f(&c as *const _);
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// Any type of local array variable leads to stack protection with the
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// "strong" heuristic. The 'basic' heuristic only adds stack protection to
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// functions with local array variables of a byte-sized type, however. Since
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// 'char' is 4 bytes in Rust, this function is not protected by the 'basic'
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// heuristic
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//
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// (This test *also* takes the address of the local stack variables. We
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// cannot know that this isn't what triggers the `strong` heuristic.
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// However, the test strategy of passing the address of a stack array to an
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// external function is sufficient to trigger the `basic` heuristic (see
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// test `array_u8_large()`). Since the `basic` heuristic only checks for the
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// presence of stack-local array variables, we can be confident that this
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// test also captures this part of the `strong` heuristic specification.)
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// all: __stack_chk_fail
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// strong: __stack_chk_fail
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// basic-NOT: __stack_chk_fail
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// none-NOT: __stack_chk_fail
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// missing-NOT: __stack_chk_fail
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}
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// CHECK-LABEL: array_u8_1
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#[no_mangle]
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pub fn array_u8_1(f: fn(*const u8)) {
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let a = [0u8; 1];
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f(&a as *const _);
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// The 'strong' heuristic adds stack protection to functions with local
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// array variables regardless of their size.
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// all: __stack_chk_fail
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// strong: __stack_chk_fail
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// basic-NOT: __stack_chk_fail
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// none-NOT: __stack_chk_fail
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// missing-NOT: __stack_chk_fail
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}
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// CHECK-LABEL: array_u8_small:
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#[no_mangle]
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pub fn array_u8_small(f: fn(*const u8)) {
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let a = [0u8; 2];
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let b = [0u8; 7];
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f(&a as *const _);
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f(&b as *const _);
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// Small arrays do not lead to stack protection by the 'basic' heuristic.
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// all: __stack_chk_fail
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// strong: __stack_chk_fail
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// basic-NOT: __stack_chk_fail
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// none-NOT: __stack_chk_fail
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// missing-NOT: __stack_chk_fail
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}
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// CHECK-LABEL: array_u8_large:
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#[no_mangle]
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pub fn array_u8_large(f: fn(*const u8)) {
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let a = [0u8; 9];
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f(&a as *const _);
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// Since `a` is a byte array with size greater than 8, the basic heuristic
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// will also protect this function.
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// all: __stack_chk_fail
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// strong: __stack_chk_fail
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// basic: __stack_chk_fail
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// none-NOT: __stack_chk_fail
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// missing-NOT: __stack_chk_fail
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}
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#[derive(Copy, Clone)]
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pub struct ByteSizedNewtype(u8);
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// CHECK-LABEL: array_bytesizednewtype_9:
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#[no_mangle]
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pub fn array_bytesizednewtype_9(f: fn(*const ByteSizedNewtype)) {
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let a = [ByteSizedNewtype(0); 9];
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f(&a as *const _);
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// Since `a` is a byte array in the LLVM output, the basic heuristic will
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// also protect this function.
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// all: __stack_chk_fail
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// strong: __stack_chk_fail
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// basic: __stack_chk_fail
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// none-NOT: __stack_chk_fail
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// missing-NOT: __stack_chk_fail
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}
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// CHECK-LABEL: local_var_addr_used_indirectly
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#[no_mangle]
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pub fn local_var_addr_used_indirectly(f: fn(bool)) {
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let a = 5;
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let a_addr = &a as *const _ as usize;
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f(a_addr & 0x10 == 0);
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// This function takes the address of a local variable taken. Although this
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// address is never used as a way to refer to stack memory, the `strong`
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// heuristic adds stack smash protection. This is also the case in C++:
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// ```
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// cat << EOF | clang++ -O2 -fstack-protector-strong -S -x c++ - -o - | grep stack_chk
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// #include <cstdint>
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// void f(void (*g)(bool)) {
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// int32_t x;
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// g((reinterpret_cast<uintptr_t>(&x) & 0x10U) == 0);
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// }
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// EOF
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// ```
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// all: __stack_chk_fail
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// strong: __stack_chk_fail
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// basic-NOT: __stack_chk_fail
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// none-NOT: __stack_chk_fail
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// missing-NOT: __stack_chk_fail
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}
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// CHECK-LABEL: local_string_addr_taken
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#[no_mangle]
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pub fn local_string_addr_taken(f: fn(&String)) {
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let x = String::new();
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f(&x);
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// Taking the address of the local variable `x` leads to stack smash
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// protection with the `strong` heuristic, but not with the `basic`
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// heuristic. It does not matter that the reference is not mut.
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//
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// An interesting note is that a similar function in C++ *would* be
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// protected by the `basic` heuristic, because `std::string` has a char
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// array internally as a small object optimization:
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// ```
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// cat <<EOF | clang++ -O2 -fstack-protector -S -x c++ - -o - | grep stack_chk
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// #include <string>
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// void f(void (*g)(const std::string&)) {
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// std::string x;
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// g(x);
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// }
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// EOF
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// ```
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//
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// all: __stack_chk_fail
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// strong: __stack_chk_fail
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// basic-NOT: __stack_chk_fail
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// none-NOT: __stack_chk_fail
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// missing-NOT: __stack_chk_fail
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}
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pub trait SelfByRef {
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fn f(&self) -> i32;
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}
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impl SelfByRef for i32 {
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fn f(&self) -> i32 {
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return self + 1;
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}
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}
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// CHECK-LABEL: local_var_addr_taken_used_locally_only
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#[no_mangle]
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pub fn local_var_addr_taken_used_locally_only(factory: fn() -> i32, sink: fn(i32)) {
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let x = factory();
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let g = x.f();
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sink(g);
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// Even though the local variable conceptually has its address taken, as
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// it's passed by reference to the trait function, the use of the reference
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// is easily inlined. There is therefore no stack smash protection even with
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// the `strong` heuristic.
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// all: __stack_chk_fail
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// strong-NOT: __stack_chk_fail
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// basic-NOT: __stack_chk_fail
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// none-NOT: __stack_chk_fail
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// missing-NOT: __stack_chk_fail
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}
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pub struct Gigastruct {
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does: u64,
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not: u64,
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have: u64,
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array: u64,
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members: u64
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}
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// CHECK-LABEL: local_large_var_moved
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#[no_mangle]
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pub fn local_large_var_moved(f: fn(Gigastruct)) {
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let x = Gigastruct { does: 0, not: 1, have: 2, array: 3, members: 4 };
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f(x);
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// Even though the local variable conceptually doesn't have its address
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// taken, it's so large that the "move" is implemented with a reference to a
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// stack-local variable in the ABI. Consequently, this function *is*
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// protected by the `strong` heuristic. This is also the case for
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// rvalue-references in C++, regardless of struct size:
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// ```
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// cat <<EOF | clang++ -O2 -fstack-protector-strong -S -x c++ - -o - | grep stack_chk
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// #include <cstdint>
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// #include <utility>
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// void f(void (*g)(uint64_t&&)) {
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// uint64_t x;
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// g(std::move(x));
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// }
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// EOF
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// ```
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// all: __stack_chk_fail
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// strong: __stack_chk_fail
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// basic-NOT: __stack_chk_fail
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// none-NOT: __stack_chk_fail
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// missing-NOT: __stack_chk_fail
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}
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// CHECK-LABEL: local_large_var_cloned
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#[no_mangle]
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pub fn local_large_var_cloned(f: fn(Gigastruct)) {
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f(Gigastruct { does: 0, not: 1, have: 2, array: 3, members: 4 });
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// A new instance of `Gigastruct` is passed to `f()`, without any apparent
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// connection to this stack frame. Still, since instances of `Gigastruct`
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// are sufficiently large, it is allocated in the caller stack frame and
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// passed as a pointer. As such, this function is *also* protected by the
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// `strong` heuristic, just like `local_large_var_moved`. This is also the
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// case for pass-by-value of sufficiently large structs in C++:
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// ```
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// cat <<EOF | clang++ -O2 -fstack-protector-strong -S -x c++ - -o - | grep stack_chk
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// #include <cstdint>
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// #include <utility>
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// struct Gigastruct { uint64_t a, b, c, d, e; };
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// void f(void (*g)(Gigastruct)) {
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// g(Gigastruct{});
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// }
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// EOF
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// ```
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// all: __stack_chk_fail
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// strong: __stack_chk_fail
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// basic-NOT: __stack_chk_fail
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// none-NOT: __stack_chk_fail
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// missing-NOT: __stack_chk_fail
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}
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extern "C" {
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// A call to an external `alloca` function is *not* recognized as an
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// `alloca(3)` operation. This function is a compiler built-in, as the
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// man page explains. Clang translates it to an LLVM `alloca`
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// instruction with a count argument, which is also what the LLVM stack
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// protector heuristics looks for. The man page for `alloca(3)` details
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// a way to avoid using the compiler built-in: pass a -std=c11
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// argument, *and* don't include <alloca.h>. Though this leads to an
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// external alloca() function being called, it doesn't lead to stack
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// protection being included. It even fails with a linker error
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// "undefined reference to `alloca'". Example:
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// ```
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// cat<<EOF | clang -fstack-protector-strong -x c -std=c11 - -o /dev/null
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// #include <stdlib.h>
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// void * alloca(size_t);
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// void f(void (*g)(void*)) {
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// void * p = alloca(10);
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// g(p);
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// }
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// int main() { return 0; }
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// EOF
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// ```
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// The following tests demonstrate that calls to an external `alloca`
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// function in Rust also doesn't trigger stack protection.
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fn alloca(size: usize) -> *mut ();
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}
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// CHECK-LABEL: alloca_small_compile_time_constant_arg
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#[no_mangle]
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pub fn alloca_small_compile_time_constant_arg(f: fn(*mut ())) {
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f(unsafe { alloca(8) });
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// all: __stack_chk_fail
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// strong-NOT: __stack_chk_fail
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// basic-NOT: __stack_chk_fail
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// none-NOT: __stack_chk_fail
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// missing-NOT: __stack_chk_fail
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}
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// CHECK-LABEL: alloca_large_compile_time_constant_arg
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#[no_mangle]
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pub fn alloca_large_compile_time_constant_arg(f: fn(*mut ())) {
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f(unsafe { alloca(9) });
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// all: __stack_chk_fail
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// strong-NOT: __stack_chk_fail
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// basic-NOT: __stack_chk_fail
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// none-NOT: __stack_chk_fail
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// missing-NOT: __stack_chk_fail
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}
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// CHECK-LABEL: alloca_dynamic_arg
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#[no_mangle]
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pub fn alloca_dynamic_arg(f: fn(*mut ()), n: usize) {
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f(unsafe { alloca(n) });
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// all: __stack_chk_fail
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// strong-NOT: __stack_chk_fail
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// basic-NOT: __stack_chk_fail
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// none-NOT: __stack_chk_fail
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// missing-NOT: __stack_chk_fail
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}
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// The question then is: in what ways can Rust code generate array-`alloca`
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// LLVM instructions? This appears to only be generated by
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// rustc_codegen_ssa::traits::Builder::array_alloca() through
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// rustc_codegen_ssa::mir::operand::OperandValue::store_unsized(). FWICT
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// this is support for the "unsized locals" unstable feature:
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// https://doc.rust-lang.org/unstable-book/language-features/unsized-locals.html.
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// CHECK-LABEL: unsized_fn_param
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#[no_mangle]
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pub fn unsized_fn_param(s: [u8], l: bool, f: fn([u8])) {
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let n = if l { 1 } else { 2 };
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f(*Box::<[u8]>::from(&s[0..n])); // slice-copy with Box::from
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// Even though slices are conceptually passed by-value both into this
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// function and into `f()`, this is implemented with pass-by-reference
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// using a suitably constructed fat-pointer (as if the functions
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// accepted &[u8]). This function therefore doesn't need dynamic array
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// alloca, and is therefore not protected by the `strong` or `basic`
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// heuristics.
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// all: __stack_chk_fail
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// strong: __stack_chk_fail
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// basic-NOT: __stack_chk_fail
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// none-NOT: __stack_chk_fail
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// missing-NOT: __stack_chk_fail
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}
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// CHECK-LABEL: unsized_local
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#[no_mangle]
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pub fn unsized_local(s: &[u8], l: bool, f: fn(&mut [u8])) {
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let n = if l { 1 } else { 2 };
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let mut a: [u8] = *Box::<[u8]>::from(&s[0..n]); // slice-copy with Box::from
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f(&mut a);
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// This function allocates a slice as a local variable in its stack
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// frame. Since the size is not a compile-time constant, an array
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// alloca is required, and the function is protected by both the
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// `strong` and `basic` heuristic.
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// all: __stack_chk_fail
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// strong: __stack_chk_fail
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// basic: __stack_chk_fail
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// none-NOT: __stack_chk_fail
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// missing-NOT: __stack_chk_fail
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}
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