vendor/base64/tests/decode.rs - toolchain/rustc - Git at Google

 extern crate base64;

 use base64::*;

 mod helpers;

 use self::helpers::*;

 #[test]
 fn decode_rfc4648_0() {
     compare_decode("", "");
 }

 #[test]
 fn decode_rfc4648_1() {
     compare_decode("f", "Zg==");
 }

 #[test]
 fn decode_rfc4648_1_just_a_bit_of_padding() {
     // allows less padding than required
     compare_decode("f", "Zg=");
 }

 #[test]
 fn decode_rfc4648_1_no_padding() {
     compare_decode("f", "Zg");
 }

 #[test]
 fn decode_rfc4648_2() {
     compare_decode("fo", "Zm8=");
 }

 #[test]
 fn decode_rfc4648_2_no_padding() {
     compare_decode("fo", "Zm8");
 }

 #[test]
 fn decode_rfc4648_3() {
     compare_decode("foo", "Zm9v");
 }

 #[test]
 fn decode_rfc4648_4() {
     compare_decode("foob", "Zm9vYg==");
 }

 #[test]
 fn decode_rfc4648_4_no_padding() {
     compare_decode("foob", "Zm9vYg");
 }

 #[test]
 fn decode_rfc4648_5() {
     compare_decode("fooba", "Zm9vYmE=");
 }

 #[test]
 fn decode_rfc4648_5_no_padding() {
     compare_decode("fooba", "Zm9vYmE");
 }

 #[test]
 fn decode_rfc4648_6() {
     compare_decode("foobar", "Zm9vYmFy");
 }

 #[test]
 fn decode_reject_null() {
     assert_eq!(
         DecodeError::InvalidByte(3, 0x0),
         decode_config("YWx\0pY2U==", config_std_pad()).unwrap_err()
     );
 }

 #[test]
 fn decode_single_pad_byte_after_2_chars_in_trailing_quad_ok() {
     for num_quads in 0..25 {
         let mut s: String = std::iter::repeat("ABCD").take(num_quads).collect();
         s.push_str("Zg=");

         let input_len = num_quads * 3 + 1;

         // Since there are 3 bytes in the trailing quad, want to be sure this allows for the fact
         // that it could be bad padding rather than assuming that it will decode to 2 bytes and
         // therefore allow 1 extra round of fast decode logic (stage 1 / 2).

         let mut decoded = Vec::new();
         decoded.resize(input_len, 0);

         assert_eq!(
             input_len,
             decode_config_slice(&s, STANDARD, &mut decoded).unwrap()
         );
     }
 }

 //this is a MAY in the rfc: https://tools.ietf.org/html/rfc4648#section-3.3
 #[test]
 fn decode_1_pad_byte_in_fast_loop_then_extra_padding_chunk_error() {
     for num_quads in 0..25 {
         let mut s: String = std::iter::repeat("ABCD").take(num_quads).collect();
         s.push_str("YWxpY2U=====");

         // since the first 8 bytes are handled in stage 1 or 2, the padding is detected as a
         // generic invalid byte, not specifcally a padding issue.
         // Could argue that the *next* padding byte (in the next quad) is technically the first
         // erroneous one, but reporting that accurately is more complex and probably nobody cares
         assert_eq!(
             DecodeError::InvalidByte(num_quads * 4 + 7, b'='),
             decode(&s).unwrap_err()
         );
     }
 }

 #[test]
 fn decode_2_pad_bytes_in_leftovers_then_extra_padding_chunk_error() {
     for num_quads in 0..25 {
         let mut s: String = std::iter::repeat("ABCD").take(num_quads).collect();
         s.push_str("YWxpY2UABB====");

         // 6 bytes (4 padding) after last 8-byte chunk, so it's decoded by stage 4.
         // First padding byte is invalid.
         assert_eq!(
             DecodeError::InvalidByte(num_quads * 4 + 10, b'='),
             decode(&s).unwrap_err()
         );
     }
 }

 #[test]
 fn decode_valid_bytes_after_padding_in_leftovers_error() {
     for num_quads in 0..25 {
         let mut s: String = std::iter::repeat("ABCD").take(num_quads).collect();
         s.push_str("YWxpY2UABB=B");

         // 4 bytes after last 8-byte chunk, so it's decoded by stage 4.
         // First (and only) padding byte is invalid.
         assert_eq!(
             DecodeError::InvalidByte(num_quads * 4 + 10, b'='),
             decode(&s).unwrap_err()
         );
     }
 }

 #[test]
 fn decode_absurd_pad_error() {
     for num_quads in 0..25 {
         let mut s: String = std::iter::repeat("ABCD").take(num_quads).collect();
         s.push_str("==Y=Wx===pY=2U=====");

         // Plenty of remaining bytes, so handled by stage 1 or 2.
         // first padding byte
         assert_eq!(
             DecodeError::InvalidByte(num_quads * 4, b'='),
             decode(&s).unwrap_err()
         );
     }
 }

 #[test]
 fn decode_extra_padding_after_1_pad_bytes_in_trailing_quad_returns_error() {
     for num_quads in 0..25 {
         let mut s: String = std::iter::repeat("ABCD").take(num_quads).collect();
         s.push_str("EEE===");

         // handled by stage 1, 2, or 4 depending on length
         // first padding byte -- which would be legal if it was the only padding
         assert_eq!(
             DecodeError::InvalidByte(num_quads * 4 + 3, b'='),
             decode(&s).unwrap_err()
         );
     }
 }

 #[test]
 fn decode_extra_padding_after_2_pad_bytes_in_trailing_quad_2_returns_error() {
     for num_quads in 0..25 {
         let mut s: String = std::iter::repeat("ABCD").take(num_quads).collect();
         s.push_str("EE====");

         // handled by stage 1, 2, or 4 depending on length
         // first padding byte -- which would be legal if it was by itself
         assert_eq!(
             DecodeError::InvalidByte(num_quads * 4 + 2, b'='),
             decode(&s).unwrap_err()
         );
     }
 }

 #[test]
 fn decode_start_quad_with_padding_returns_error() {
     for num_quads in 0..25 {
         // add enough padding to ensure that we'll hit all 4 stages at the different lengths
         for pad_bytes in 1..32 {
             let mut s: String = std::iter::repeat("ABCD").take(num_quads).collect();
             let padding: String = std::iter::repeat("=").take(pad_bytes).collect();
             s.push_str(&padding);

             if pad_bytes % 4 == 1 {
                 // detected in early length check
                 assert_eq!(DecodeError::InvalidLength, decode(&s).unwrap_err());
             } else {
                 // padding lengths 2 - 8 are handled by stage 4
                 // padding length >= 8 will hit at least one chunk at stages 1, 2, 3 at different
                 // prefix lengths
                 assert_eq!(
                     DecodeError::InvalidByte(num_quads * 4, b'='),
                     decode(&s).unwrap_err()
                 );
             }
         }
     }
 }

 #[test]
 fn decode_padding_followed_by_non_padding_returns_error() {
     for num_quads in 0..25 {
         for pad_bytes in 0..31 {
             let mut s: String = std::iter::repeat("ABCD").take(num_quads).collect();
             let padding: String = std::iter::repeat("=").take(pad_bytes).collect();
             s.push_str(&padding);
             s.push_str("E");

             if pad_bytes % 4 == 0 {
                 assert_eq!(DecodeError::InvalidLength, decode(&s).unwrap_err());
             } else {
                 // pad len 1 - 8 will be handled by stage 4
                 // pad len 9 (suffix len 10) will have 8 bytes of padding handled by stage 3
                 // first padding byte
                 assert_eq!(
                     DecodeError::InvalidByte(num_quads * 4, b'='),
                     decode(&s).unwrap_err()
                 );
             }
         }
     }
 }

 #[test]
 fn decode_one_char_in_quad_with_padding_error() {
     for num_quads in 0..25 {
         let mut s: String = std::iter::repeat("ABCD").take(num_quads).collect();
         s.push_str("E=");

         assert_eq!(
             DecodeError::InvalidByte(num_quads * 4 + 1, b'='),
             decode(&s).unwrap_err()
         );

         // more padding doesn't change the error
         s.push_str("=");
         assert_eq!(
             DecodeError::InvalidByte(num_quads * 4 + 1, b'='),
             decode(&s).unwrap_err()
         );

         s.push_str("=");
         assert_eq!(
             DecodeError::InvalidByte(num_quads * 4 + 1, b'='),
             decode(&s).unwrap_err()
         );
     }
 }

 #[test]
 fn decode_one_char_in_quad_without_padding_error() {
     for num_quads in 0..25 {
         let mut s: String = std::iter::repeat("ABCD").take(num_quads).collect();
         s.push('E');

         assert_eq!(DecodeError::InvalidLength, decode(&s).unwrap_err());
     }
 }

 #[test]
 fn decode_reject_invalid_bytes_with_correct_error() {
     for length in 1..100 {
         for index in 0_usize..length {
             for invalid_byte in " \t\n\r\x0C\x0B\x00%*.".bytes() {
                 let prefix: String = std::iter::repeat("A").take(index).collect();
                 let suffix: String = std::iter::repeat("B").take(length - index - 1).collect();

                 let input = prefix + &String::from_utf8(vec![invalid_byte]).unwrap() + &suffix;
                 assert_eq!(
                     length,
                     input.len(),
                     "length {} error position {}",
                     length,
                     index
                 );

                 if length % 4 == 1 {
                     assert_eq!(DecodeError::InvalidLength, decode(&input).unwrap_err());
                 } else {
                     assert_eq!(
                         DecodeError::InvalidByte(index, invalid_byte),
                         decode(&input).unwrap_err()
                     );
                 }
             }
         }
     }
 }

 fn config_std_pad() -> Config {
     Config::new(CharacterSet::Standard, true)
 }
	extern crate base64;

	use base64::*;

	mod helpers;

	use self::helpers::*;

	#[test]
	fn decode_rfc4648_0() {
	compare_decode("", "");
	}

	#[test]
	fn decode_rfc4648_1() {
	compare_decode("f", "Zg==");
	}

	#[test]
	fn decode_rfc4648_1_just_a_bit_of_padding() {
	// allows less padding than required
	compare_decode("f", "Zg=");
	}

	#[test]
	fn decode_rfc4648_1_no_padding() {
	compare_decode("f", "Zg");
	}

	#[test]
	fn decode_rfc4648_2() {
	compare_decode("fo", "Zm8=");
	}

	#[test]
	fn decode_rfc4648_2_no_padding() {
	compare_decode("fo", "Zm8");
	}

	#[test]
	fn decode_rfc4648_3() {
	compare_decode("foo", "Zm9v");
	}

	#[test]
	fn decode_rfc4648_4() {
	compare_decode("foob", "Zm9vYg==");
	}

	#[test]
	fn decode_rfc4648_4_no_padding() {
	compare_decode("foob", "Zm9vYg");
	}

	#[test]
	fn decode_rfc4648_5() {
	compare_decode("fooba", "Zm9vYmE=");
	}

	#[test]
	fn decode_rfc4648_5_no_padding() {
	compare_decode("fooba", "Zm9vYmE");
	}

	#[test]
	fn decode_rfc4648_6() {
	compare_decode("foobar", "Zm9vYmFy");
	}

	#[test]
	fn decode_reject_null() {
	assert_eq!(
	DecodeError::InvalidByte(3, 0x0),
	decode_config("YWx\0pY2U==", config_std_pad()).unwrap_err()
	);
	}

	#[test]
	fn decode_single_pad_byte_after_2_chars_in_trailing_quad_ok() {
	for num_quads in 0..25 {
	let mut s: String = std::iter::repeat("ABCD").take(num_quads).collect();
	s.push_str("Zg=");

	let input_len = num_quads * 3 + 1;

	// Since there are 3 bytes in the trailing quad, want to be sure this allows for the fact
	// that it could be bad padding rather than assuming that it will decode to 2 bytes and
	// therefore allow 1 extra round of fast decode logic (stage 1 / 2).

	let mut decoded = Vec::new();
	decoded.resize(input_len, 0);

	assert_eq!(
	input_len,
	decode_config_slice(&s, STANDARD, &mut decoded).unwrap()
	);
	}
	}

	//this is a MAY in the rfc: https://tools.ietf.org/html/rfc4648#section-3.3
	#[test]
	fn decode_1_pad_byte_in_fast_loop_then_extra_padding_chunk_error() {
	for num_quads in 0..25 {
	let mut s: String = std::iter::repeat("ABCD").take(num_quads).collect();
	s.push_str("YWxpY2U=====");

	// since the first 8 bytes are handled in stage 1 or 2, the padding is detected as a
	// generic invalid byte, not specifcally a padding issue.
	// Could argue that the next padding byte (in the next quad) is technically the first
	// erroneous one, but reporting that accurately is more complex and probably nobody cares
	assert_eq!(
	DecodeError::InvalidByte(num_quads * 4 + 7, b'='),
	decode(&s).unwrap_err()
	);
	}
	}

	#[test]
	fn decode_2_pad_bytes_in_leftovers_then_extra_padding_chunk_error() {
	for num_quads in 0..25 {
	let mut s: String = std::iter::repeat("ABCD").take(num_quads).collect();
	s.push_str("YWxpY2UABB====");

	// 6 bytes (4 padding) after last 8-byte chunk, so it's decoded by stage 4.
	// First padding byte is invalid.
	assert_eq!(
	DecodeError::InvalidByte(num_quads * 4 + 10, b'='),
	decode(&s).unwrap_err()
	);
	}
	}

	#[test]
	fn decode_valid_bytes_after_padding_in_leftovers_error() {
	for num_quads in 0..25 {
	let mut s: String = std::iter::repeat("ABCD").take(num_quads).collect();
	s.push_str("YWxpY2UABB=B");

	// 4 bytes after last 8-byte chunk, so it's decoded by stage 4.
	// First (and only) padding byte is invalid.
	assert_eq!(
	DecodeError::InvalidByte(num_quads * 4 + 10, b'='),
	decode(&s).unwrap_err()
	);
	}
	}

	#[test]
	fn decode_absurd_pad_error() {
	for num_quads in 0..25 {
	let mut s: String = std::iter::repeat("ABCD").take(num_quads).collect();
	s.push_str("==Y=Wx===pY=2U=====");

	// Plenty of remaining bytes, so handled by stage 1 or 2.
	// first padding byte
	assert_eq!(
	DecodeError::InvalidByte(num_quads * 4, b'='),
	decode(&s).unwrap_err()
	);
	}
	}

	#[test]
	fn decode_extra_padding_after_1_pad_bytes_in_trailing_quad_returns_error() {
	for num_quads in 0..25 {
	let mut s: String = std::iter::repeat("ABCD").take(num_quads).collect();
	s.push_str("EEE===");

	// handled by stage 1, 2, or 4 depending on length
	// first padding byte -- which would be legal if it was the only padding
	assert_eq!(
	DecodeError::InvalidByte(num_quads * 4 + 3, b'='),
	decode(&s).unwrap_err()
	);
	}
	}

	#[test]
	fn decode_extra_padding_after_2_pad_bytes_in_trailing_quad_2_returns_error() {
	for num_quads in 0..25 {
	let mut s: String = std::iter::repeat("ABCD").take(num_quads).collect();
	s.push_str("EE====");

	// handled by stage 1, 2, or 4 depending on length
	// first padding byte -- which would be legal if it was by itself
	assert_eq!(
	DecodeError::InvalidByte(num_quads * 4 + 2, b'='),
	decode(&s).unwrap_err()
	);
	}
	}

	#[test]
	fn decode_start_quad_with_padding_returns_error() {
	for num_quads in 0..25 {
	// add enough padding to ensure that we'll hit all 4 stages at the different lengths
	for pad_bytes in 1..32 {
	let mut s: String = std::iter::repeat("ABCD").take(num_quads).collect();
	let padding: String = std::iter::repeat("=").take(pad_bytes).collect();
	s.push_str(&padding);

	if pad_bytes % 4 == 1 {
	// detected in early length check
	assert_eq!(DecodeError::InvalidLength, decode(&s).unwrap_err());
	} else {
	// padding lengths 2 - 8 are handled by stage 4
	// padding length >= 8 will hit at least one chunk at stages 1, 2, 3 at different
	// prefix lengths
	assert_eq!(
	DecodeError::InvalidByte(num_quads * 4, b'='),
	decode(&s).unwrap_err()
	);
	}
	}
	}
	}

	#[test]
	fn decode_padding_followed_by_non_padding_returns_error() {
	for num_quads in 0..25 {
	for pad_bytes in 0..31 {
	let mut s: String = std::iter::repeat("ABCD").take(num_quads).collect();
	let padding: String = std::iter::repeat("=").take(pad_bytes).collect();
	s.push_str(&padding);
	s.push_str("E");

	if pad_bytes % 4 == 0 {
	assert_eq!(DecodeError::InvalidLength, decode(&s).unwrap_err());
	} else {
	// pad len 1 - 8 will be handled by stage 4
	// pad len 9 (suffix len 10) will have 8 bytes of padding handled by stage 3
	// first padding byte
	assert_eq!(
	DecodeError::InvalidByte(num_quads * 4, b'='),
	decode(&s).unwrap_err()
	);
	}
	}
	}
	}

	#[test]
	fn decode_one_char_in_quad_with_padding_error() {
	for num_quads in 0..25 {
	let mut s: String = std::iter::repeat("ABCD").take(num_quads).collect();
	s.push_str("E=");

	assert_eq!(
	DecodeError::InvalidByte(num_quads * 4 + 1, b'='),
	decode(&s).unwrap_err()
	);

	// more padding doesn't change the error
	s.push_str("=");
	assert_eq!(
	DecodeError::InvalidByte(num_quads * 4 + 1, b'='),
	decode(&s).unwrap_err()
	);

	s.push_str("=");
	assert_eq!(
	DecodeError::InvalidByte(num_quads * 4 + 1, b'='),
	decode(&s).unwrap_err()
	);
	}
	}

	#[test]
	fn decode_one_char_in_quad_without_padding_error() {
	for num_quads in 0..25 {
	let mut s: String = std::iter::repeat("ABCD").take(num_quads).collect();
	s.push('E');

	assert_eq!(DecodeError::InvalidLength, decode(&s).unwrap_err());
	}
	}

	#[test]
	fn decode_reject_invalid_bytes_with_correct_error() {
	for length in 1..100 {
	for index in 0_usize..length {
	for invalid_byte in " \t\n\r\x0C\x0B\x00%*.".bytes() {
	let prefix: String = std::iter::repeat("A").take(index).collect();
	let suffix: String = std::iter::repeat("B").take(length - index - 1).collect();

	let input = prefix + &String::from_utf8(vec![invalid_byte]).unwrap() + &suffix;
	assert_eq!(
	length,
	input.len(),
	"length {} error position {}",
	length,
	index
	);

	if length % 4 == 1 {
	assert_eq!(DecodeError::InvalidLength, decode(&input).unwrap_err());
	} else {
	assert_eq!(
	DecodeError::InvalidByte(index, invalid_byte),
	decode(&input).unwrap_err()
	);
	}
	}
	}
	}
	}

	fn config_std_pad() -> Config {
	Config::new(CharacterSet::Standard, true)
	}