use std::env;
use std::error;
use std::ffi::OsStr;
use std::fs::{self, File};
use std::io::{self, Write};
use std::path::{Path, PathBuf};
use std::process::{self, Command};
use std::sync::atomic::{AtomicUsize, Ordering};
use std::thread;
use std::time::Duration;
static TEST_DIR: &'static str = "ripgrep-tests";
static NEXT_ID: AtomicUsize = AtomicUsize::new(0);
/// Setup an empty work directory and return a command pointing to the ripgrep
/// executable whose CWD is set to the work directory.
///
/// The name given will be used to create the directory. Generally, it should
/// correspond to the test name.
pub fn setup(test_name: &str) -> (Dir, TestCommand) {
let dir = Dir::new(test_name);
let cmd = dir.command();
(dir, cmd)
}
/// Like `setup`, but uses PCRE2 as the underlying regex engine.
pub fn setup_pcre2(test_name: &str) -> (Dir, TestCommand) {
let mut dir = Dir::new(test_name);
dir.pcre2(true);
let cmd = dir.command();
(dir, cmd)
}
/// Break the given string into lines, sort them and then join them back
/// together. This is useful for testing output from ripgrep that may not
/// always be in the same order.
pub fn sort_lines(lines: &str) -> String {
let mut lines: Vec<&str> = lines.trim().lines().collect();
lines.sort();
format!("{}\n", lines.join("\n"))
}
/// Returns true if and only if the given program can be successfully executed
/// with a `--help` flag.
pub fn cmd_exists(program: &str) -> bool {
Command::new(program).arg("--help").output().is_ok()
}
/// Dir represents a directory in which tests should be run.
///
/// Directories are created from a global atomic counter to avoid duplicates.
#[derive(Clone, Debug)]
pub struct Dir {
/// The directory in which this test executable is running.
root: PathBuf,
/// The directory in which the test should run. If a test needs to create
/// files, they should go in here. This directory is also used as the CWD
/// for any processes created by the test.
dir: PathBuf,
/// Set to true when the test should use PCRE2 as the regex engine.
pcre2: bool,
}
impl Dir {
/// Create a new test working directory with the given name. The name
/// does not need to be distinct for each invocation, but should correspond
/// to a logical grouping of tests.
pub fn new(name: &str) -> Dir {
let id = NEXT_ID.fetch_add(1, Ordering::SeqCst);
let root = env::current_exe()
.unwrap()
.parent()
.expect("executable's directory")
.to_path_buf();
let dir =
env::temp_dir().join(TEST_DIR).join(name).join(&format!("{}", id));
if dir.exists() {
nice_err(&dir, fs::remove_dir_all(&dir));
}
nice_err(&dir, repeat(|| fs::create_dir_all(&dir)));
Dir { root: root, dir: dir, pcre2: false }
}
/// Use PCRE2 for this test.
pub fn pcre2(&mut self, yes: bool) {
self.pcre2 = yes;
}
/// Returns true if and only if this test is configured to use PCRE2 as
/// the regex engine.
pub fn is_pcre2(&self) -> bool {
self.pcre2
}
/// Create a new file with the given name and contents in this directory,
/// or panic on error.
pub fn create<P: AsRef<Path>>(&self, name: P, contents: &str) {
self.create_bytes(name, contents.as_bytes());
}
/// Try to create a new file with the given name and contents in this
/// directory.
#[allow(dead_code)] // unused on Windows
pub fn try_create<P: AsRef<Path>>(
&self,
name: P,
contents: &str,
) -> io::Result<()> {
let path = self.dir.join(name);
self.try_create_bytes(path, contents.as_bytes())
}
/// Create a new file with the given name and size.
pub fn create_size<P: AsRef<Path>>(&self, name: P, filesize: u64) {
let path = self.dir.join(name);
let file = nice_err(&path, File::create(&path));
nice_err(&path, file.set_len(filesize));
}
/// Create a new file with the given name and contents in this directory,
/// or panic on error.
pub fn create_bytes<P: AsRef<Path>>(&self, name: P, contents: &[u8]) {
let path = self.dir.join(&name);
nice_err(&path, self.try_create_bytes(name, contents));
}
/// Try to create a new file with the given name and contents in this
/// directory.
pub fn try_create_bytes<P: AsRef<Path>>(
&self,
name: P,
contents: &[u8],
) -> io::Result<()> {
let path = self.dir.join(name);
let mut file = File::create(path)?;
file.write_all(contents)?;
file.flush()
}
/// Remove a file with the given name from this directory.
pub fn remove<P: AsRef<Path>>(&self, name: P) {
let path = self.dir.join(name);
nice_err(&path, fs::remove_file(&path));
}
/// Create a new directory with the given path (and any directories above
/// it) inside this directory.
pub fn create_dir<P: AsRef<Path>>(&self, path: P) {
let path = self.dir.join(path);
nice_err(&path, repeat(|| fs::create_dir_all(&path)));
}
/// Creates a new command that is set to use the ripgrep executable in
/// this working directory.
///
/// This also:
///
/// * Unsets the `RIPGREP_CONFIG_PATH` environment variable.
/// * Sets the `--path-separator` to `/` so that paths have the same output
/// on all systems. Tests that need to check `--path-separator` itself
/// can simply pass it again to override it.
pub fn command(&self) -> TestCommand {
let mut cmd = self.bin();
cmd.env_remove("RIPGREP_CONFIG_PATH");
cmd.current_dir(&self.dir);
cmd.arg("--path-separator").arg("/");
if self.is_pcre2() {
cmd.arg("--pcre2");
}
TestCommand { dir: self.clone(), cmd: cmd }
}
/// Returns the path to the ripgrep executable.
pub fn bin(&self) -> process::Command {
let rg = self.root.join(format!("../rg{}", env::consts::EXE_SUFFIX));
match cross_runner() {
None => process::Command::new(rg),
Some(runner) => {
let mut cmd = process::Command::new(runner);
cmd.arg(rg);
cmd
}
}
}
/// Returns the path to this directory.
pub fn path(&self) -> &Path {
&self.dir
}
/// Creates a directory symlink to the src with the given target name
/// in this directory.
#[cfg(not(windows))]
pub fn link_dir<S: AsRef<Path>, T: AsRef<Path>>(&self, src: S, target: T) {
use std::os::unix::fs::symlink;
let src = self.dir.join(src);
let target = self.dir.join(target);
let _ = fs::remove_file(&target);
nice_err(&target, symlink(&src, &target));
}
/// Creates a directory symlink to the src with the given target name
/// in this directory.
#[cfg(windows)]
pub fn link_dir<S: AsRef<Path>, T: AsRef<Path>>(&self, src: S, target: T) {
use std::os::windows::fs::symlink_dir;
let src = self.dir.join(src);
let target = self.dir.join(target);
let _ = fs::remove_dir(&target);
nice_err(&target, symlink_dir(&src, &target));
}
/// Creates a file symlink to the src with the given target name
/// in this directory.
#[cfg(not(windows))]
pub fn link_file<S: AsRef<Path>, T: AsRef<Path>>(
&self,
src: S,
target: T,
) {
self.link_dir(src, target);
}
/// Creates a file symlink to the src with the given target name
/// in this directory.
#[cfg(windows)]
#[allow(dead_code)] // unused on Windows
pub fn link_file<S: AsRef<Path>, T: AsRef<Path>>(
&self,
src: S,
target: T,
) {
use std::os::windows::fs::symlink_file;
let src = self.dir.join(src);
let target = self.dir.join(target);
let _ = fs::remove_file(&target);
nice_err(&target, symlink_file(&src, &target));
}
}
/// A simple wrapper around a process::Command with some conveniences.
#[derive(Debug)]
pub struct TestCommand {
/// The dir used to launched this command.
dir: Dir,
/// The actual command we use to control the process.
cmd: Command,
}
impl TestCommand {
/// Returns a mutable reference to the underlying command.
pub fn cmd(&mut self) -> &mut Command {
&mut self.cmd
}
/// Add an argument to pass to the command.
pub fn arg<A: AsRef<OsStr>>(&mut self, arg: A) -> &mut TestCommand {
self.cmd.arg(arg);
self
}
/// Add any number of arguments to the command.
pub fn args<I, A>(&mut self, args: I) -> &mut TestCommand
where
I: IntoIterator<Item = A>,
A: AsRef<OsStr>,
{
self.cmd.args(args);
self
}
/// Set the working directory for this command.
///
/// Note that this does not need to be called normally, since the creation
/// of this TestCommand causes its working directory to be set to the
/// test's directory automatically.
pub fn current_dir<P: AsRef<Path>>(&mut self, dir: P) -> &mut TestCommand {
self.cmd.current_dir(dir);
self
}
/// Runs and captures the stdout of the given command.
pub fn stdout(&mut self) -> String {
let o = self.output();
let stdout = String::from_utf8_lossy(&o.stdout);
match stdout.parse() {
Ok(t) => t,
Err(err) => {
panic!(
"could not convert from string: {:?}\n\n{}",
err, stdout
);
}
}
}
/// Pipe `input` to a command, and collect the output.
pub fn pipe(&mut self, input: &[u8]) -> String {
self.cmd.stdin(process::Stdio::piped());
self.cmd.stdout(process::Stdio::piped());
self.cmd.stderr(process::Stdio::piped());
let mut child = self.cmd.spawn().unwrap();
// Pipe input to child process using a separate thread to avoid
// risk of deadlock between parent and child process.
let mut stdin = child.stdin.take().expect("expected standard input");
let input = input.to_owned();
let worker = thread::spawn(move || stdin.write_all(&input));
let output = self.expect_success(child.wait_with_output().unwrap());
worker.join().unwrap().unwrap();
let stdout = String::from_utf8_lossy(&output.stdout);
match stdout.parse() {
Ok(t) => t,
Err(err) => {
panic!(
"could not convert from string: {:?}\n\n{}",
err, stdout
);
}
}
}
/// Gets the output of a command. If the command failed, then this panics.
pub fn output(&mut self) -> process::Output {
let output = self.cmd.output().unwrap();
self.expect_success(output)
}
/// Runs the command and asserts that it resulted in an error exit code.
pub fn assert_err(&mut self) {
let o = self.cmd.output().unwrap();
if o.status.success() {
panic!(
"\n\n===== {:?} =====\n\
command succeeded but expected failure!\
\n\ncwd: {}\
\n\ndir list: {:?}\
\n\nstatus: {}\
\n\nstdout: {}\n\nstderr: {}\
\n\n=====\n",
self.cmd,
self.dir.dir.display(),
dir_list(&self.dir.dir),
o.status,
String::from_utf8_lossy(&o.stdout),
String::from_utf8_lossy(&o.stderr)
);
}
}
/// Runs the command and asserts that its exit code matches expected exit
/// code.
pub fn assert_exit_code(&mut self, expected_code: i32) {
let code = self.cmd.output().unwrap().status.code().unwrap();
assert_eq!(
expected_code,
code,
"\n\n===== {:?} =====\n\
expected exit code did not match\
\n\ncwd: {}\
\n\ndir list: {:?}\
\n\nexpected: {}\
\n\nfound: {}\
\n\n=====\n",
self.cmd,
self.dir.dir.display(),
dir_list(&self.dir.dir),
expected_code,
code
);
}
/// Runs the command and asserts that something was printed to stderr.
pub fn assert_non_empty_stderr(&mut self) {
let o = self.cmd.output().unwrap();
if o.status.success() || o.stderr.is_empty() {
panic!(
"\n\n===== {:?} =====\n\
command succeeded but expected failure!\
\n\ncwd: {}\
\n\ndir list: {:?}\
\n\nstatus: {}\
\n\nstdout: {}\n\nstderr: {}\
\n\n=====\n",
self.cmd,
self.dir.dir.display(),
dir_list(&self.dir.dir),
o.status,
String::from_utf8_lossy(&o.stdout),
String::from_utf8_lossy(&o.stderr)
);
}
}
fn expect_success(&self, o: process::Output) -> process::Output {
if !o.status.success() {
let suggest = if o.stderr.is_empty() {
"\n\nDid your search end up with no results?".to_string()
} else {
"".to_string()
};
panic!(
"\n\n==========\n\
command failed but expected success!\
{}\
\n\ncommand: {:?}\
\n\ncwd: {}\
\n\ndir list: {:?}\
\n\nstatus: {}\
\n\nstdout: {}\
\n\nstderr: {}\
\n\n==========\n",
suggest,
self.cmd,
self.dir.dir.display(),
dir_list(&self.dir.dir),
o.status,
String::from_utf8_lossy(&o.stdout),
String::from_utf8_lossy(&o.stderr)
);
}
o
}
}
fn nice_err<T, E: error::Error>(path: &Path, res: Result<T, E>) -> T {
match res {
Ok(t) => t,
Err(err) => panic!("{}: {:?}", path.display(), err),
}
}
fn repeat<F: FnMut() -> io::Result<()>>(mut f: F) -> io::Result<()> {
let mut last_err = None;
for _ in 0..10 {
if let Err(err) = f() {
last_err = Some(err);
thread::sleep(Duration::from_millis(500));
} else {
return Ok(());
}
}
Err(last_err.unwrap())
}
/// Return a recursive listing of all files and directories in the given
/// directory. This is useful for debugging transient and odd failures in
/// integration tests.
fn dir_list<P: AsRef<Path>>(dir: P) -> Vec<String> {
walkdir::WalkDir::new(dir)
.follow_links(true)
.into_iter()
.map(|result| result.unwrap().path().to_string_lossy().into_owned())
.collect()
}
/// When running tests with cross, we need to be a bit smarter about how we
/// run our `rg` binary. We can't just run it directly since it might be
/// compiled for a totally different target. Instead, it's likely that `cross`
/// will have setup qemu to run it. While this is integrated into the Rust
/// testing by default, we need to handle it ourselves for integration tests.
///
/// Thankfully, cross sets an environment variable that points to the proper
/// qemu binary that we want to run. So we just search for that env var and
/// return its value if we could find it.
fn cross_runner() -> Option<String> {
for (k, v) in std::env::vars_os() {
let (k, v) = (k.to_string_lossy(), v.to_string_lossy());
if !k.starts_with("CARGO_TARGET_") && !k.ends_with("_RUNNER") {
continue;
}
if !v.starts_with("qemu-") {
continue;
}
return Some(v.into_owned());
}
None
}