// run-pass // We disable tail merging here because it can't preserve debuginfo and thus // potentially breaks the backtraces. Also, subtle changes can decide whether // tail merging succeeds, so the test might work today but fail tomorrow due to a // seemingly completely unrelated change. // Unfortunately, LLVM has no "disable" option for this, so we have to set // "enable" to 0 instead. // compile-flags:-g -Copt-level=0 -Cllvm-args=-enable-tail-merge=0 // compile-flags:-Cforce-frame-pointers=yes // compile-flags:-Cstrip=none // ignore-pretty issue #37195 // ignore-emscripten spawning processes is not supported // ignore-sgx no processes // ignore-fuchsia Backtrace not symbolized, trace different line alignment use std::env; #[path = "backtrace-debuginfo-aux.rs"] mod aux; macro_rules! pos { () => ((file!(), line!())) } macro_rules! dump_and_die { ($($pos:expr),*) => ({ // FIXME(#18285): we cannot include the current position because // the macro span takes over the last frame's file/line. // // You might also be wondering why a major platform, // i686-pc-windows-msvc, is located in here. Some of the saga can be // found on #62897, but the tl;dr; is that it appears that if the // standard library doesn't have debug information or frame pointers, // which it doesn't by default on the test builders, then the stack // walking routines in dbghelp will randomly terminate the stack trace // in libstd without going further. Presumably the addition of frame // pointers and/or debuginfo fixes this since tests always work with // nightly compilers (which have debuginfo). In general though this test // is replicated in rust-lang/backtrace-rs and has extensive coverage // there, even on i686-pc-windows-msvc. We do the best we can in // rust-lang/rust to test it as well, but sometimes we just gotta keep // landing PRs. if cfg!(any(target_os = "android", all(target_os = "linux", target_arch = "arm"), all(target_env = "msvc", target_arch = "x86"), target_os = "freebsd", target_os = "dragonfly", target_os = "openbsd")) { // skip these platforms as this support isn't implemented yet. } else { dump_filelines(&[$($pos),*]); panic!(); } }) } // we can't use a function as it will alter the backtrace macro_rules! check { ($counter:expr; $($pos:expr),*) => ({ if *$counter == 0 { dump_and_die!($($pos),*) } else { *$counter -= 1; } }) } type Pos = (&'static str, u32); // this goes to stdout and each line has to be occurred // in the following backtrace to stderr with a correct order. fn dump_filelines(filelines: &[Pos]) { for &(file, line) in filelines.iter().rev() { // extract a basename let basename = file.split(&['/', '\\'][..]).last().unwrap(); println!("{}:{}", basename, line); } } #[inline(never)] fn inner(counter: &mut i32, main_pos: Pos, outer_pos: Pos) { check!(counter; main_pos, outer_pos); check!(counter; main_pos, outer_pos); let inner_pos = pos!(); aux::callback(|aux_pos| { check!(counter; main_pos, outer_pos, inner_pos, aux_pos); }); let inner_pos = pos!(); aux::callback_inlined(|aux_pos| { check!(counter; main_pos, outer_pos, inner_pos, aux_pos); }); } // We emit the wrong location for the caller here when inlined on MSVC #[cfg_attr(not(target_env = "msvc"), inline(always))] #[cfg_attr(target_env = "msvc", inline(never))] fn inner_inlined(counter: &mut i32, main_pos: Pos, outer_pos: Pos) { check!(counter; main_pos, outer_pos); check!(counter; main_pos, outer_pos); // Again, disable inlining for MSVC. #[cfg_attr(not(target_env = "msvc"), inline(always))] #[cfg_attr(target_env = "msvc", inline(never))] fn inner_further_inlined(counter: &mut i32, main_pos: Pos, outer_pos: Pos, inner_pos: Pos) { check!(counter; main_pos, outer_pos, inner_pos); } inner_further_inlined(counter, main_pos, outer_pos, pos!()); let inner_pos = pos!(); aux::callback(|aux_pos| { check!(counter; main_pos, outer_pos, inner_pos, aux_pos); }); let inner_pos = pos!(); aux::callback_inlined(|aux_pos| { check!(counter; main_pos, outer_pos, inner_pos, aux_pos); }); // this tests a distinction between two independent calls to the inlined function. // (un)fortunately, LLVM somehow merges two consecutive such calls into one node. inner_further_inlined(counter, main_pos, outer_pos, pos!()); } #[inline(never)] fn outer(mut counter: i32, main_pos: Pos) { inner(&mut counter, main_pos, pos!()); inner_inlined(&mut counter, main_pos, pos!()); } fn check_trace(output: &str, error: &str) -> Result<(), String> { // reverse the position list so we can start with the last item (which was the first line) let mut remaining: Vec<&str> = output.lines().map(|s| s.trim()).rev().collect(); if !error.contains("stack backtrace") { return Err(format!("no backtrace found in stderr:\n{}", error)) } for line in error.lines() { if !remaining.is_empty() && line.contains(remaining.last().unwrap()) { remaining.pop(); } } if !remaining.is_empty() { return Err(format!("trace does not match position list\n\ still need to find {:?}\n\n\ --- stdout\n{}\n\ --- stderr\n{}", remaining, output, error)) } Ok(()) } fn run_test(me: &str) { use std::str; use std::process::Command; let mut i = 0; let mut errors = Vec::new(); loop { let out = Command::new(me) .env("RUST_BACKTRACE", "full") .arg(i.to_string()).output().unwrap(); let output = str::from_utf8(&out.stdout).unwrap(); let error = str::from_utf8(&out.stderr).unwrap(); if out.status.success() { assert!(output.contains("done."), "bad output for successful run: {}", output); break; } else { if let Err(e) = check_trace(output, error) { errors.push(e); } } i += 1; } if errors.len() > 0 { for error in errors { println!("---------------------------------------"); println!("{}", error); } panic!("found some errors"); } } #[inline(never)] fn main() { let args: Vec = env::args().collect(); if args.len() >= 2 { let case = args[1].parse().unwrap(); eprintln!("test case {}", case); outer(case, pos!()); println!("done."); } else { run_test(&args[0]); } }