src/test.rs - platform/external/rust/crates/unicode-segmentation - Git at Google

 // Copyright 2012-2015 The Rust Project Developers. See the COPYRIGHT
 // file at the top-level directory of this distribution and at
 // http://rust-lang.org/COPYRIGHT.
 //
 // Licensed under the Apache License, Version 2.0 <LICENSE-APACHE or
 // http://www.apache.org/licenses/LICENSE-2.0> or the MIT license
 // <LICENSE-MIT or http://opensource.org/licenses/MIT>, at your
 // option. This file may not be copied, modified, or distributed
 // except according to those terms.

 use super::UnicodeSegmentation;

 use std::prelude::v1::*;

 #[test]
 fn test_graphemes() {
     use testdata::{TEST_SAME, TEST_DIFF};

     pub const EXTRA_DIFF: &'static [(&'static str,
                                      &'static [&'static str],
                                      &'static [&'static str])] = &[
         // Official test suite doesn't include two Prepend chars between two other chars.
         ("\u{20}\u{600}\u{600}\u{20}",
          &["\u{20}", "\u{600}\u{600}\u{20}"],
          &["\u{20}", "\u{600}", "\u{600}", "\u{20}"]),

         // Test for Prepend followed by two Any chars
         ("\u{600}\u{20}\u{20}",
          &["\u{600}\u{20}", "\u{20}"],
          &["\u{600}", "\u{20}", "\u{20}"]),
     ];

     pub const EXTRA_SAME: &'static [(&'static str, &'static [&'static str])] = &[
         // family emoji (more than two emoji joined by ZWJ)
         ("\u{1f468}\u{200d}\u{1f467}\u{200d}\u{1f466}",
          &["\u{1f468}\u{200d}\u{1f467}\u{200d}\u{1f466}"]),
         // cartwheel emoji followed by two fitzpatrick skin tone modifiers
         // (test case from issue #19)
         ("\u{1F938}\u{1F3FE}\u{1F3FE}",
          &["\u{1F938}\u{1F3FE}\u{1F3FE}"]),
     ];

     for &(s, g) in TEST_SAME.iter().chain(EXTRA_SAME) {
         // test forward iterator
         assert!(UnicodeSegmentation::graphemes(s, true).eq(g.iter().cloned()));
         assert!(UnicodeSegmentation::graphemes(s, false).eq(g.iter().cloned()));

         // test reverse iterator
         assert!(UnicodeSegmentation::graphemes(s, true).rev().eq(g.iter().rev().cloned()));
         assert!(UnicodeSegmentation::graphemes(s, false).rev().eq(g.iter().rev().cloned()));
     }

     for &(s, gt, gf) in TEST_DIFF.iter().chain(EXTRA_DIFF) {
         // test forward iterator
         assert!(UnicodeSegmentation::graphemes(s, true).eq(gt.iter().cloned()));
         assert!(UnicodeSegmentation::graphemes(s, false).eq(gf.iter().cloned()));

         // test reverse iterator
         assert!(UnicodeSegmentation::graphemes(s, true).rev().eq(gt.iter().rev().cloned()));
         assert!(UnicodeSegmentation::graphemes(s, false).rev().eq(gf.iter().rev().cloned()));
     }

     // test the indices iterators
     let s = "a̐éö̲\r\n";
     let gr_inds = UnicodeSegmentation::grapheme_indices(s, true).collect::<Vec<(usize, &str)>>();
     let b: &[_] = &[(0, "a̐"), (3, "é"), (6, "ö̲"), (11, "\r\n")];
     assert_eq!(gr_inds, b);
     let gr_inds = UnicodeSegmentation::grapheme_indices(s, true).rev().collect::<Vec<(usize, &str)>>();
     let b: &[_] = &[(11, "\r\n"), (6, "ö̲"), (3, "é"), (0, "a̐")];
     assert_eq!(gr_inds, b);
     let mut gr_inds_iter = UnicodeSegmentation::grapheme_indices(s, true);
     {
         let gr_inds = gr_inds_iter.by_ref();
         let e1 = gr_inds.size_hint();
         assert_eq!(e1, (1, Some(13)));
         let c = gr_inds.count();
         assert_eq!(c, 4);
     }
     let e2 = gr_inds_iter.size_hint();
     assert_eq!(e2, (0, Some(0)));

     // make sure the reverse iterator does the right thing with "\n" at beginning of string
     let s = "\n\r\n\r";
     let gr = UnicodeSegmentation::graphemes(s, true).rev().collect::<Vec<&str>>();
     let b: &[_] = &["\r", "\r\n", "\n"];
     assert_eq!(gr, b);
 }

 #[test]
 fn test_words() {
     use testdata::TEST_WORD;

     // Unicode's official tests don't really test longer chains of flag emoji
     // TODO This could be improved with more tests like flag emoji with interspersed Extend chars and ZWJ
     const EXTRA_TESTS: &'static [(&'static str, &'static [&'static str])] = &[
         ("🇦🇫🇦🇽🇦🇱🇩🇿🇦🇸🇦🇩🇦🇴", &["🇦🇫", "🇦🇽", "🇦🇱", "🇩🇿", "🇦🇸", "🇦🇩", "🇦🇴"]),
         ("🇦🇫🇦🇽🇦🇱🇩🇿🇦🇸🇦🇩🇦", &["🇦🇫", "🇦🇽", "🇦🇱", "🇩🇿", "🇦🇸", "🇦🇩", "🇦"]),
         ("🇦a🇫🇦🇽a🇦🇱🇩🇿🇦🇸🇦🇩🇦", &["🇦", "a", "🇫🇦", "🇽", "a", "🇦🇱", "🇩🇿", "🇦🇸", "🇦🇩", "🇦"]),
         ("\u{1f468}\u{200d}\u{1f468}\u{200d}\u{1f466}",  &["\u{1f468}\u{200d}\u{1f468}\u{200d}\u{1f466}"]),
         ("😌👎🏼",  &["😌", "👎🏼"]),
         // perhaps wrong, spaces should not be included?
         ("hello world", &["hello", " ", "world"]),
         ("🇨🇦🇨🇭🇿🇲🇿 hi", &["🇨🇦", "🇨🇭", "🇿🇲", "🇿", " ", "hi"]),
     ];
     for &(s, w) in TEST_WORD.iter().chain(EXTRA_TESTS.iter()) {
         macro_rules! assert_ {
             ($test:expr, $exp:expr, $name:expr) => {
                 // collect into vector for better diagnostics in failure case
                 let testing = $test.collect::<Vec<_>>();
                 let expected = $exp.collect::<Vec<_>>();
                 assert_eq!(testing, expected, "{} test for testcase ({:?}, {:?}) failed.", $name, s, w)
             }
         }
         // test forward iterator
         assert_!(s.split_word_bounds(),
                 w.iter().cloned(),
                 "Forward word boundaries");

         // test reverse iterator
         assert_!(s.split_word_bounds().rev(),
                 w.iter().rev().cloned(),
                 "Reverse word boundaries");

         // generate offsets from word string lengths
         let mut indices = vec![0];
         for i in w.iter().cloned().map(|s| s.len()).scan(0, |t, n| { *t += n; Some(*t) }) {
             indices.push(i);
         }
         indices.pop();
         let indices = indices;

         // test forward indices iterator
         assert_!(s.split_word_bound_indices().map(|(l,_)| l),
                  indices.iter().cloned(),
                  "Forward word indices");

         // test backward indices iterator
         assert_!(s.split_word_bound_indices().rev().map(|(l,_)| l),
                  indices.iter().rev().cloned(),
                  "Reverse word indices");
     }
 }


 #[test]
 fn test_sentences() {
     use testdata::TEST_SENTENCE;

     for &(s, w) in TEST_SENTENCE.iter() {
         macro_rules! assert_ {
             ($test:expr, $exp:expr, $name:expr) => {
                 // collect into vector for better diagnostics in failure case
                 let testing = $test.collect::<Vec<_>>();
                 let expected = $exp.collect::<Vec<_>>();
                 assert_eq!(testing, expected, "{} test for testcase ({:?}, {:?}) failed.", $name, s, w)
             }
         }

         assert_!(s.split_sentence_bounds(),
                 w.iter().cloned(),
                 "Forward sentence boundaries");
     }
 }

 quickcheck! {
     fn quickcheck_forward_reverse_graphemes_extended(s: String) -> bool {
         let a = s.graphemes(true).collect::<Vec<_>>();
         let mut b = s.graphemes(true).rev().collect::<Vec<_>>();
         b.reverse();
         a == b
     }

     fn quickcheck_forward_reverse_graphemes_legacy(s: String) -> bool {
         let a = s.graphemes(false).collect::<Vec<_>>();
         let mut b = s.graphemes(false).rev().collect::<Vec<_>>();
         b.reverse();
         a == b
     }

     fn quickcheck_join_graphemes(s: String) -> bool {
         let a = s.graphemes(true).collect::<String>();
         let b = s.graphemes(false).collect::<String>();
         a == s && b == s
     }

     fn quickcheck_forward_reverse_words(s: String) -> bool {
         let a = s.split_word_bounds().collect::<Vec<_>>();
         let mut b = s.split_word_bounds().rev().collect::<Vec<_>>();
         b.reverse();
         a == b
     }

     fn quickcheck_join_words(s: String) -> bool {
         let a = s.split_word_bounds().collect::<String>();
         a == s
     }
 }
	// Copyright 2012-2015 The Rust Project Developers. See the COPYRIGHT
	// file at the top-level directory of this distribution and at
	// http://rust-lang.org/COPYRIGHT.
	//
	// Licensed under the Apache License, Version 2.0 <LICENSE-APACHE or
	// http://www.apache.org/licenses/LICENSE-2.0> or the MIT license
	// <LICENSE-MIT or http://opensource.org/licenses/MIT>, at your
	// option. This file may not be copied, modified, or distributed
	// except according to those terms.

	use super::UnicodeSegmentation;

	use std::prelude::v1::*;

	#[test]
	fn test_graphemes() {
	use testdata::{TEST_SAME, TEST_DIFF};

	pub const EXTRA_DIFF: &'static [(&'static str,
	&'static [&'static str],
	&'static [&'static str])] = &[
	// Official test suite doesn't include two Prepend chars between two other chars.
	("\u{20}\u{600}\u{600}\u{20}",
	&["\u{20}", "\u{600}\u{600}\u{20}"],
	&["\u{20}", "\u{600}", "\u{600}", "\u{20}"]),

	// Test for Prepend followed by two Any chars
	("\u{600}\u{20}\u{20}",
	&["\u{600}\u{20}", "\u{20}"],
	&["\u{600}", "\u{20}", "\u{20}"]),
	];

	pub const EXTRA_SAME: &'static [(&'static str, &'static [&'static str])] = &[
	// family emoji (more than two emoji joined by ZWJ)
	("\u{1f468}\u{200d}\u{1f467}\u{200d}\u{1f466}",
	&["\u{1f468}\u{200d}\u{1f467}\u{200d}\u{1f466}"]),
	// cartwheel emoji followed by two fitzpatrick skin tone modifiers
	// (test case from issue #19)
	("\u{1F938}\u{1F3FE}\u{1F3FE}",
	&["\u{1F938}\u{1F3FE}\u{1F3FE}"]),
	];

	for &(s, g) in TEST_SAME.iter().chain(EXTRA_SAME) {
	// test forward iterator
	assert!(UnicodeSegmentation::graphemes(s, true).eq(g.iter().cloned()));
	assert!(UnicodeSegmentation::graphemes(s, false).eq(g.iter().cloned()));

	// test reverse iterator
	assert!(UnicodeSegmentation::graphemes(s, true).rev().eq(g.iter().rev().cloned()));
	assert!(UnicodeSegmentation::graphemes(s, false).rev().eq(g.iter().rev().cloned()));
	}

	for &(s, gt, gf) in TEST_DIFF.iter().chain(EXTRA_DIFF) {
	// test forward iterator
	assert!(UnicodeSegmentation::graphemes(s, true).eq(gt.iter().cloned()));
	assert!(UnicodeSegmentation::graphemes(s, false).eq(gf.iter().cloned()));

	// test reverse iterator
	assert!(UnicodeSegmentation::graphemes(s, true).rev().eq(gt.iter().rev().cloned()));
	assert!(UnicodeSegmentation::graphemes(s, false).rev().eq(gf.iter().rev().cloned()));
	}

	// test the indices iterators
	let s = "a̐éö̲\r\n";
	let gr_inds = UnicodeSegmentation::grapheme_indices(s, true).collect::<Vec<(usize, &str)>>();
	let b: &[_] = &[(0, "a̐"), (3, "é"), (6, "ö̲"), (11, "\r\n")];
	assert_eq!(gr_inds, b);
	let gr_inds = UnicodeSegmentation::grapheme_indices(s, true).rev().collect::<Vec<(usize, &str)>>();
	let b: &[_] = &[(11, "\r\n"), (6, "ö̲"), (3, "é"), (0, "a̐")];
	assert_eq!(gr_inds, b);
	let mut gr_inds_iter = UnicodeSegmentation::grapheme_indices(s, true);
	{
	let gr_inds = gr_inds_iter.by_ref();
	let e1 = gr_inds.size_hint();
	assert_eq!(e1, (1, Some(13)));
	let c = gr_inds.count();
	assert_eq!(c, 4);
	}
	let e2 = gr_inds_iter.size_hint();
	assert_eq!(e2, (0, Some(0)));

	// make sure the reverse iterator does the right thing with "\n" at beginning of string
	let s = "\n\r\n\r";
	let gr = UnicodeSegmentation::graphemes(s, true).rev().collect::<Vec<&str>>();
	let b: &[_] = &["\r", "\r\n", "\n"];
	assert_eq!(gr, b);
	}

	#[test]
	fn test_words() {
	use testdata::TEST_WORD;

	// Unicode's official tests don't really test longer chains of flag emoji
	// TODO This could be improved with more tests like flag emoji with interspersed Extend chars and ZWJ
	const EXTRA_TESTS: &'static [(&'static str, &'static [&'static str])] = &[
	("🇦🇫🇦🇽🇦🇱🇩🇿🇦🇸🇦🇩🇦🇴", &["🇦🇫", "🇦🇽", "🇦🇱", "🇩🇿", "🇦🇸", "🇦🇩", "🇦🇴"]),
	("🇦🇫🇦🇽🇦🇱🇩🇿🇦🇸🇦🇩🇦", &["🇦🇫", "🇦🇽", "🇦🇱", "🇩🇿", "🇦🇸", "🇦🇩", "🇦"]),
	("🇦a🇫🇦🇽a🇦🇱🇩🇿🇦🇸🇦🇩🇦", &["🇦", "a", "🇫🇦", "🇽", "a", "🇦🇱", "🇩🇿", "🇦🇸", "🇦🇩", "🇦"]),
	("\u{1f468}\u{200d}\u{1f468}\u{200d}\u{1f466}", &["\u{1f468}\u{200d}\u{1f468}\u{200d}\u{1f466}"]),
	("😌👎🏼", &["😌", "👎🏼"]),
	// perhaps wrong, spaces should not be included?
	("hello world", &["hello", " ", "world"]),
	("🇨🇦🇨🇭🇿🇲🇿 hi", &["🇨🇦", "🇨🇭", "🇿🇲", "🇿", " ", "hi"]),
	];
	for &(s, w) in TEST_WORD.iter().chain(EXTRA_TESTS.iter()) {
	macro_rules! assert_ {
	($test:expr, $exp:expr, $name:expr) => {
	// collect into vector for better diagnostics in failure case
	let testing = $test.collect::<Vec<_>>();
	let expected = $exp.collect::<Vec<_>>();
	assert_eq!(testing, expected, "{} test for testcase ({:?}, {:?}) failed.", $name, s, w)
	}
	}
	// test forward iterator
	assert_!(s.split_word_bounds(),
	w.iter().cloned(),
	"Forward word boundaries");

	// test reverse iterator
	assert_!(s.split_word_bounds().rev(),
	w.iter().rev().cloned(),
	"Reverse word boundaries");

	// generate offsets from word string lengths
	let mut indices = vec![0];
	for i in w.iter().cloned().map(\|s\| s.len()).scan(0, \|t, n\| { t += n; Some(t) }) {
	indices.push(i);
	}
	indices.pop();
	let indices = indices;

	// test forward indices iterator
	assert_!(s.split_word_bound_indices().map(\|(l,_)\| l),
	indices.iter().cloned(),
	"Forward word indices");

	// test backward indices iterator
	assert_!(s.split_word_bound_indices().rev().map(\|(l,_)\| l),
	indices.iter().rev().cloned(),
	"Reverse word indices");
	}
	}


	#[test]
	fn test_sentences() {
	use testdata::TEST_SENTENCE;

	for &(s, w) in TEST_SENTENCE.iter() {
	macro_rules! assert_ {
	($test:expr, $exp:expr, $name:expr) => {
	// collect into vector for better diagnostics in failure case
	let testing = $test.collect::<Vec<_>>();
	let expected = $exp.collect::<Vec<_>>();
	assert_eq!(testing, expected, "{} test for testcase ({:?}, {:?}) failed.", $name, s, w)
	}
	}

	assert_!(s.split_sentence_bounds(),
	w.iter().cloned(),
	"Forward sentence boundaries");
	}
	}

	quickcheck! {
	fn quickcheck_forward_reverse_graphemes_extended(s: String) -> bool {
	let a = s.graphemes(true).collect::<Vec<_>>();
	let mut b = s.graphemes(true).rev().collect::<Vec<_>>();
	b.reverse();
	a == b
	}

	fn quickcheck_forward_reverse_graphemes_legacy(s: String) -> bool {
	let a = s.graphemes(false).collect::<Vec<_>>();
	let mut b = s.graphemes(false).rev().collect::<Vec<_>>();
	b.reverse();
	a == b
	}

	fn quickcheck_join_graphemes(s: String) -> bool {
	let a = s.graphemes(true).collect::<String>();
	let b = s.graphemes(false).collect::<String>();
	a == s && b == s
	}

	fn quickcheck_forward_reverse_words(s: String) -> bool {
	let a = s.split_word_bounds().collect::<Vec<_>>();
	let mut b = s.split_word_bounds().rev().collect::<Vec<_>>();
	b.reverse();
	a == b
	}

	fn quickcheck_join_words(s: String) -> bool {
	let a = s.split_word_bounds().collect::<String>();
	a == s
	}
	}