tests/basic.rs - platform/external/rust/crates/which - Git at Google

 extern crate tempdir;
 extern crate which;

 use std::env;
 use std::ffi::{OsStr, OsString};
 use std::fs;
 use std::io;
 use std::path::{Path, PathBuf};
 use tempdir::TempDir;

 struct TestFixture {
     /// Temp directory.
     pub tempdir: TempDir,
     /// $PATH
     pub paths: OsString,
     /// Binaries created in $PATH
     pub bins: Vec<PathBuf>,
 }

 const SUBDIRS: &'static [&'static str] = &["a", "b", "c"];
 const BIN_NAME: &'static str = "bin";

 #[cfg(unix)]
 fn mk_bin(dir: &Path, path: &str, extension: &str) -> io::Result<PathBuf> {
     use std::os::unix::fs::OpenOptionsExt;
     let bin = dir.join(path).with_extension(extension);
     fs::OpenOptions::new()
         .write(true)
         .create(true)
         .mode(0o666 | (libc::S_IXUSR as u32))
         .open(&bin)
         .and_then(|_f| bin.canonicalize())
 }

 fn touch(dir: &Path, path: &str, extension: &str) -> io::Result<PathBuf> {
     let b = dir.join(path).with_extension(extension);
     fs::File::create(&b).and_then(|_f| b.canonicalize())
 }

 #[cfg(windows)]
 fn mk_bin(dir: &Path, path: &str, extension: &str) -> io::Result<PathBuf> {
     touch(dir, path, extension)
 }

 impl TestFixture {
     // tmp/a/bin
     // tmp/a/bin.exe
     // tmp/a/bin.cmd
     // tmp/b/bin
     // tmp/b/bin.exe
     // tmp/b/bin.cmd
     // tmp/c/bin
     // tmp/c/bin.exe
     // tmp/c/bin.cmd
     pub fn new() -> TestFixture {
         let tempdir = TempDir::new("which_tests").unwrap();
         let mut builder = fs::DirBuilder::new();
         builder.recursive(true);
         let mut paths = vec![];
         let mut bins = vec![];
         for d in SUBDIRS.iter() {
             let p = tempdir.path().join(d);
             builder.create(&p).unwrap();
             bins.push(mk_bin(&p, &BIN_NAME, "").unwrap());
             bins.push(mk_bin(&p, &BIN_NAME, "exe").unwrap());
             bins.push(mk_bin(&p, &BIN_NAME, "cmd").unwrap());
             paths.push(p);
         }
         TestFixture {
             tempdir: tempdir,
             paths: env::join_paths(paths).unwrap(),
             bins: bins,
         }
     }

     #[allow(dead_code)]
     pub fn touch(&self, path: &str, extension: &str) -> io::Result<PathBuf> {
         touch(self.tempdir.path(), &path, &extension)
     }

     pub fn mk_bin(&self, path: &str, extension: &str) -> io::Result<PathBuf> {
         mk_bin(self.tempdir.path(), &path, &extension)
     }
 }

 fn _which<T: AsRef<OsStr>>(f: &TestFixture, path: T) -> which::Result<which::CanonicalPath> {
     which::CanonicalPath::new_in(path, Some(f.paths.clone()), f.tempdir.path())
 }

 #[test]
 #[cfg(unix)]
 fn it_works() {
     use std::process::Command;
     let result = which::Path::new("rustc");
     assert!(result.is_ok());

     let which_result = Command::new("which").arg("rustc").output();

     assert_eq!(
         String::from(result.unwrap().to_str().unwrap()),
         String::from_utf8(which_result.unwrap().stdout)
             .unwrap()
             .trim()
     );
 }

 #[test]
 #[cfg(unix)]
 fn test_which() {
     let f = TestFixture::new();
     assert_eq!(_which(&f, &BIN_NAME).unwrap(), f.bins[0])
 }

 #[test]
 #[cfg(windows)]
 fn test_which() {
     let f = TestFixture::new();
     assert_eq!(_which(&f, &BIN_NAME).unwrap(), f.bins[1])
 }

 #[test]
 #[cfg(unix)]
 fn test_which_extension() {
     let f = TestFixture::new();
     let b = Path::new(&BIN_NAME).with_extension("");
     assert_eq!(_which(&f, &b).unwrap(), f.bins[0])
 }

 #[test]
 #[cfg(windows)]
 fn test_which_extension() {
     let f = TestFixture::new();
     let b = Path::new(&BIN_NAME).with_extension("cmd");
     assert_eq!(_which(&f, &b).unwrap(), f.bins[2])
 }

 #[test]
 fn test_which_not_found() {
     let f = TestFixture::new();
     assert!(_which(&f, "a").is_err());
 }

 #[test]
 fn test_which_second() {
     let f = TestFixture::new();
     let b = f.mk_bin("b/another", env::consts::EXE_EXTENSION).unwrap();
     assert_eq!(_which(&f, "another").unwrap(), b);
 }

 #[test]
 #[cfg(unix)]
 fn test_which_absolute() {
     let f = TestFixture::new();
     assert_eq!(
         _which(&f, &f.bins[3]).unwrap(),
         f.bins[3].canonicalize().unwrap()
     );
 }

 #[test]
 #[cfg(windows)]
 fn test_which_absolute() {
     let f = TestFixture::new();
     assert_eq!(
         _which(&f, &f.bins[4]).unwrap(),
         f.bins[4].canonicalize().unwrap()
     );
 }

 #[test]
 #[cfg(windows)]
 fn test_which_absolute_path_case() {
     // Test that an absolute path with an uppercase extension
     // is accepted.
     let f = TestFixture::new();
     let p = &f.bins[4];
     assert_eq!(_which(&f, &p).unwrap(), f.bins[4].canonicalize().unwrap());
 }

 #[test]
 #[cfg(unix)]
 fn test_which_absolute_extension() {
     let f = TestFixture::new();
     // Don't append EXE_EXTENSION here.
     let b = f.bins[3].parent().unwrap().join(&BIN_NAME);
     assert_eq!(_which(&f, &b).unwrap(), f.bins[3].canonicalize().unwrap());
 }

 #[test]
 #[cfg(windows)]
 fn test_which_absolute_extension() {
     let f = TestFixture::new();
     // Don't append EXE_EXTENSION here.
     let b = f.bins[4].parent().unwrap().join(&BIN_NAME);
     assert_eq!(_which(&f, &b).unwrap(), f.bins[4].canonicalize().unwrap());
 }

 #[test]
 #[cfg(unix)]
 fn test_which_relative() {
     let f = TestFixture::new();
     assert_eq!(
         _which(&f, "b/bin").unwrap(),
         f.bins[3].canonicalize().unwrap()
     );
 }

 #[test]
 #[cfg(windows)]
 fn test_which_relative() {
     let f = TestFixture::new();
     assert_eq!(
         _which(&f, "b/bin").unwrap(),
         f.bins[4].canonicalize().unwrap()
     );
 }

 #[test]
 #[cfg(unix)]
 fn test_which_relative_extension() {
     // test_which_relative tests a relative path without an extension,
     // so test a relative path with an extension here.
     let f = TestFixture::new();
     let b = Path::new("b/bin").with_extension(env::consts::EXE_EXTENSION);
     assert_eq!(_which(&f, &b).unwrap(), f.bins[3].canonicalize().unwrap());
 }

 #[test]
 #[cfg(windows)]
 fn test_which_relative_extension() {
     // test_which_relative tests a relative path without an extension,
     // so test a relative path with an extension here.
     let f = TestFixture::new();
     let b = Path::new("b/bin").with_extension("cmd");
     assert_eq!(_which(&f, &b).unwrap(), f.bins[5].canonicalize().unwrap());
 }

 #[test]
 #[cfg(windows)]
 fn test_which_relative_extension_case() {
     // Test that a relative path with an uppercase extension
     // is accepted.
     let f = TestFixture::new();
     let b = Path::new("b/bin").with_extension("EXE");
     assert_eq!(_which(&f, &b).unwrap(), f.bins[4].canonicalize().unwrap());
 }

 #[test]
 #[cfg(unix)]
 fn test_which_relative_leading_dot() {
     let f = TestFixture::new();
     assert_eq!(
         _which(&f, "./b/bin").unwrap(),
         f.bins[3].canonicalize().unwrap()
     );
 }

 #[test]
 #[cfg(windows)]
 fn test_which_relative_leading_dot() {
     let f = TestFixture::new();
     assert_eq!(
         _which(&f, "./b/bin").unwrap(),
         f.bins[4].canonicalize().unwrap()
     );
 }

 #[test]
 #[cfg(unix)]
 fn test_which_non_executable() {
     // Shouldn't return non-executable files.
     let f = TestFixture::new();
     f.touch("b/another", "").unwrap();
     assert!(_which(&f, "another").is_err());
 }

 #[test]
 #[cfg(unix)]
 fn test_which_absolute_non_executable() {
     // Shouldn't return non-executable files, even if given an absolute path.
     let f = TestFixture::new();
     let b = f.touch("b/another", "").unwrap();
     assert!(_which(&f, &b).is_err());
 }

 #[test]
 #[cfg(unix)]
 fn test_which_relative_non_executable() {
     // Shouldn't return non-executable files.
     let f = TestFixture::new();
     f.touch("b/another", "").unwrap();
     assert!(_which(&f, "b/another").is_err());
 }

 #[test]
 #[cfg(feature = "failure")]
 fn test_failure() {
     let f = TestFixture::new();

     let run = || -> std::result::Result<PathBuf, failure::Error> {
         // Test the conversion to failure
         let p = _which(&f, "./b/bin")?;
         Ok(p.into_path_buf())
     };

     let _ = run();
 }
	extern crate tempdir;
	extern crate which;

	use std::env;
	use std::ffi::{OsStr, OsString};
	use std::fs;
	use std::io;
	use std::path::{Path, PathBuf};
	use tempdir::TempDir;

	struct TestFixture {
	/// Temp directory.
	pub tempdir: TempDir,
	/// $PATH
	pub paths: OsString,
	/// Binaries created in $PATH
	pub bins: Vec<PathBuf>,
	}

	const SUBDIRS: &'static [&'static str] = &["a", "b", "c"];
	const BIN_NAME: &'static str = "bin";

	#[cfg(unix)]
	fn mk_bin(dir: &Path, path: &str, extension: &str) -> io::Result<PathBuf> {
	use std::os::unix::fs::OpenOptionsExt;
	let bin = dir.join(path).with_extension(extension);
	fs::OpenOptions::new()
	.write(true)
	.create(true)
	.mode(0o666 \| (libc::S_IXUSR as u32))
	.open(&bin)
	.and_then(\|_f\| bin.canonicalize())
	}

	fn touch(dir: &Path, path: &str, extension: &str) -> io::Result<PathBuf> {
	let b = dir.join(path).with_extension(extension);
	fs::File::create(&b).and_then(\|_f\| b.canonicalize())
	}

	#[cfg(windows)]
	fn mk_bin(dir: &Path, path: &str, extension: &str) -> io::Result<PathBuf> {
	touch(dir, path, extension)
	}

	impl TestFixture {
	// tmp/a/bin
	// tmp/a/bin.exe
	// tmp/a/bin.cmd
	// tmp/b/bin
	// tmp/b/bin.exe
	// tmp/b/bin.cmd
	// tmp/c/bin
	// tmp/c/bin.exe
	// tmp/c/bin.cmd
	pub fn new() -> TestFixture {
	let tempdir = TempDir::new("which_tests").unwrap();
	let mut builder = fs::DirBuilder::new();
	builder.recursive(true);
	let mut paths = vec![];
	let mut bins = vec![];
	for d in SUBDIRS.iter() {
	let p = tempdir.path().join(d);
	builder.create(&p).unwrap();
	bins.push(mk_bin(&p, &BIN_NAME, "").unwrap());
	bins.push(mk_bin(&p, &BIN_NAME, "exe").unwrap());
	bins.push(mk_bin(&p, &BIN_NAME, "cmd").unwrap());
	paths.push(p);
	}
	TestFixture {
	tempdir: tempdir,
	paths: env::join_paths(paths).unwrap(),
	bins: bins,
	}
	}

	#[allow(dead_code)]
	pub fn touch(&self, path: &str, extension: &str) -> io::Result<PathBuf> {
	touch(self.tempdir.path(), &path, &extension)
	}

	pub fn mk_bin(&self, path: &str, extension: &str) -> io::Result<PathBuf> {
	mk_bin(self.tempdir.path(), &path, &extension)
	}
	}

	fn _which<T: AsRef<OsStr>>(f: &TestFixture, path: T) -> which::Result<which::CanonicalPath> {
	which::CanonicalPath::new_in(path, Some(f.paths.clone()), f.tempdir.path())
	}

	#[test]
	#[cfg(unix)]
	fn it_works() {
	use std::process::Command;
	let result = which::Path::new("rustc");
	assert!(result.is_ok());

	let which_result = Command::new("which").arg("rustc").output();

	assert_eq!(
	String::from(result.unwrap().to_str().unwrap()),
	String::from_utf8(which_result.unwrap().stdout)
	.unwrap()
	.trim()
	);
	}

	#[test]
	#[cfg(unix)]
	fn test_which() {
	let f = TestFixture::new();
	assert_eq!(_which(&f, &BIN_NAME).unwrap(), f.bins[0])
	}

	#[test]
	#[cfg(windows)]
	fn test_which() {
	let f = TestFixture::new();
	assert_eq!(_which(&f, &BIN_NAME).unwrap(), f.bins[1])
	}

	#[test]
	#[cfg(unix)]
	fn test_which_extension() {
	let f = TestFixture::new();
	let b = Path::new(&BIN_NAME).with_extension("");
	assert_eq!(_which(&f, &b).unwrap(), f.bins[0])
	}

	#[test]
	#[cfg(windows)]
	fn test_which_extension() {
	let f = TestFixture::new();
	let b = Path::new(&BIN_NAME).with_extension("cmd");
	assert_eq!(_which(&f, &b).unwrap(), f.bins[2])
	}

	#[test]
	fn test_which_not_found() {
	let f = TestFixture::new();
	assert!(_which(&f, "a").is_err());
	}

	#[test]
	fn test_which_second() {
	let f = TestFixture::new();
	let b = f.mk_bin("b/another", env::consts::EXE_EXTENSION).unwrap();
	assert_eq!(_which(&f, "another").unwrap(), b);
	}

	#[test]
	#[cfg(unix)]
	fn test_which_absolute() {
	let f = TestFixture::new();
	assert_eq!(
	_which(&f, &f.bins[3]).unwrap(),
	f.bins[3].canonicalize().unwrap()
	);
	}

	#[test]
	#[cfg(windows)]
	fn test_which_absolute() {
	let f = TestFixture::new();
	assert_eq!(
	_which(&f, &f.bins[4]).unwrap(),
	f.bins[4].canonicalize().unwrap()
	);
	}

	#[test]
	#[cfg(windows)]
	fn test_which_absolute_path_case() {
	// Test that an absolute path with an uppercase extension
	// is accepted.
	let f = TestFixture::new();
	let p = &f.bins[4];
	assert_eq!(_which(&f, &p).unwrap(), f.bins[4].canonicalize().unwrap());
	}

	#[test]
	#[cfg(unix)]
	fn test_which_absolute_extension() {
	let f = TestFixture::new();
	// Don't append EXE_EXTENSION here.
	let b = f.bins[3].parent().unwrap().join(&BIN_NAME);
	assert_eq!(_which(&f, &b).unwrap(), f.bins[3].canonicalize().unwrap());
	}

	#[test]
	#[cfg(windows)]
	fn test_which_absolute_extension() {
	let f = TestFixture::new();
	// Don't append EXE_EXTENSION here.
	let b = f.bins[4].parent().unwrap().join(&BIN_NAME);
	assert_eq!(_which(&f, &b).unwrap(), f.bins[4].canonicalize().unwrap());
	}

	#[test]
	#[cfg(unix)]
	fn test_which_relative() {
	let f = TestFixture::new();
	assert_eq!(
	_which(&f, "b/bin").unwrap(),
	f.bins[3].canonicalize().unwrap()
	);
	}

	#[test]
	#[cfg(windows)]
	fn test_which_relative() {
	let f = TestFixture::new();
	assert_eq!(
	_which(&f, "b/bin").unwrap(),
	f.bins[4].canonicalize().unwrap()
	);
	}

	#[test]
	#[cfg(unix)]
	fn test_which_relative_extension() {
	// test_which_relative tests a relative path without an extension,
	// so test a relative path with an extension here.
	let f = TestFixture::new();
	let b = Path::new("b/bin").with_extension(env::consts::EXE_EXTENSION);
	assert_eq!(_which(&f, &b).unwrap(), f.bins[3].canonicalize().unwrap());
	}

	#[test]
	#[cfg(windows)]
	fn test_which_relative_extension() {
	// test_which_relative tests a relative path without an extension,
	// so test a relative path with an extension here.
	let f = TestFixture::new();
	let b = Path::new("b/bin").with_extension("cmd");
	assert_eq!(_which(&f, &b).unwrap(), f.bins[5].canonicalize().unwrap());
	}

	#[test]
	#[cfg(windows)]
	fn test_which_relative_extension_case() {
	// Test that a relative path with an uppercase extension
	// is accepted.
	let f = TestFixture::new();
	let b = Path::new("b/bin").with_extension("EXE");
	assert_eq!(_which(&f, &b).unwrap(), f.bins[4].canonicalize().unwrap());
	}

	#[test]
	#[cfg(unix)]
	fn test_which_relative_leading_dot() {
	let f = TestFixture::new();
	assert_eq!(
	_which(&f, "./b/bin").unwrap(),
	f.bins[3].canonicalize().unwrap()
	);
	}

	#[test]
	#[cfg(windows)]
	fn test_which_relative_leading_dot() {
	let f = TestFixture::new();
	assert_eq!(
	_which(&f, "./b/bin").unwrap(),
	f.bins[4].canonicalize().unwrap()
	);
	}

	#[test]
	#[cfg(unix)]
	fn test_which_non_executable() {
	// Shouldn't return non-executable files.
	let f = TestFixture::new();
	f.touch("b/another", "").unwrap();
	assert!(_which(&f, "another").is_err());
	}

	#[test]
	#[cfg(unix)]
	fn test_which_absolute_non_executable() {
	// Shouldn't return non-executable files, even if given an absolute path.
	let f = TestFixture::new();
	let b = f.touch("b/another", "").unwrap();
	assert!(_which(&f, &b).is_err());
	}

	#[test]
	#[cfg(unix)]
	fn test_which_relative_non_executable() {
	// Shouldn't return non-executable files.
	let f = TestFixture::new();
	f.touch("b/another", "").unwrap();
	assert!(_which(&f, "b/another").is_err());
	}

	#[test]
	#[cfg(feature = "failure")]
	fn test_failure() {
	let f = TestFixture::new();

	let run = \|\| -> std::result::Result<PathBuf, failure::Error> {
	// Test the conversion to failure
	let p = _which(&f, "./b/bin")?;
	Ok(p.into_path_buf())
	};

	let _ = run();
	}