// Translated from C to Rust. The original C code can be found at // https://github.com/ulfjack/ryu and carries the following license: // // Copyright 2018 Ulf Adams // // The contents of this file may be used under the terms of the Apache License, // Version 2.0. // // (See accompanying file LICENSE-Apache or copy at // http://www.apache.org/licenses/LICENSE-2.0) // // Alternatively, the contents of this file may be used under the terms of // the Boost Software License, Version 1.0. // (See accompanying file LICENSE-Boost or copy at // https://www.boost.org/LICENSE_1_0.txt) // // Unless required by applicable law or agreed to in writing, this software // is distributed on an "AS IS" BASIS, WITHOUT WARRANTIES OR CONDITIONS OF ANY // KIND, either express or implied. #![cfg(not(feature = "small"))] #![allow(dead_code)] #[path = "../src/common.rs"] mod common; #[path = "../src/d2s_full_table.rs"] mod d2s_full_table; #[path = "../src/d2s_intrinsics.rs"] mod d2s_intrinsics; #[path = "../src/d2s.rs"] mod d2s; #[path = "../src/s2d.rs"] mod s2d; #[path = "../src/parse.rs"] mod parse; use crate::parse::Error; use crate::s2d::s2d; impl PartialEq for Error { fn eq(&self, other: &Self) -> bool { *self as u8 == *other as u8 } } #[test] fn test_bad_input() { assert_eq!(Error::MalformedInput, s2d(b"x").unwrap_err()); assert_eq!(Error::MalformedInput, s2d(b"1..1").unwrap_err()); assert_eq!(Error::MalformedInput, s2d(b"..").unwrap_err()); assert_eq!(Error::MalformedInput, s2d(b"1..1").unwrap_err()); assert_eq!(Error::MalformedInput, s2d(b"1ee1").unwrap_err()); assert_eq!(Error::MalformedInput, s2d(b"1e.1").unwrap_err()); assert_eq!(Error::InputTooShort, s2d(b"").unwrap_err()); assert_eq!(Error::InputTooLong, s2d(b"123456789012345678").unwrap_err()); assert_eq!(Error::InputTooLong, s2d(b"1e12345").unwrap_err()); } #[test] fn test_basic() { assert_eq!(0.0, s2d(b"0").unwrap()); assert_eq!(-0.0, s2d(b"-0").unwrap()); assert_eq!(1.0, s2d(b"1").unwrap()); assert_eq!(2.0, s2d(b"2").unwrap()); assert_eq!(123456789.0, s2d(b"123456789").unwrap()); assert_eq!(123.456, s2d(b"123.456").unwrap()); assert_eq!(123.456, s2d(b"123456e-3").unwrap()); assert_eq!(123.456, s2d(b"1234.56e-1").unwrap()); assert_eq!(1.453, s2d(b"1.453").unwrap()); assert_eq!(1453.0, s2d(b"1.453e+3").unwrap()); assert_eq!(0.0, s2d(b".0").unwrap()); assert_eq!(1.0, s2d(b"1e0").unwrap()); assert_eq!(1.0, s2d(b"1E0").unwrap()); assert_eq!(1.0, s2d(b"000001.000000").unwrap()); } #[test] fn test_min_max() { assert_eq!( 1.7976931348623157e308, s2d(b"1.7976931348623157e308").unwrap(), ); assert_eq!(5E-324, s2d(b"5E-324").unwrap()); } #[test] fn test_mantissa_rounding_overflow() { // This results in binary mantissa that is all ones and requires rounding up // because it is closer to 1 than to the next smaller float. This is a // regression test that the mantissa overflow is handled correctly by // increasing the exponent. assert_eq!(1.0, s2d(b"0.99999999999999999").unwrap()); // This number overflows the mantissa *and* the IEEE exponent. assert_eq!(f64::INFINITY, s2d(b"1.7976931348623159e308").unwrap()); } #[test] fn test_underflow() { assert_eq!(0.0, s2d(b"2.4e-324").unwrap()); assert_eq!(0.0, s2d(b"1e-324").unwrap()); assert_eq!(0.0, s2d(b"9.99999e-325").unwrap()); // These are just about halfway between 0 and the smallest float. // The first is just below the halfway point, the second just above. assert_eq!(0.0, s2d(b"2.4703282292062327e-324").unwrap()); assert_eq!(5e-324, s2d(b"2.4703282292062328e-324").unwrap()); } #[test] fn test_overflow() { assert_eq!(f64::INFINITY, s2d(b"2e308").unwrap()); assert_eq!(f64::INFINITY, s2d(b"1e309").unwrap()); } #[test] fn test_table_size_denormal() { assert_eq!(5e-324, s2d(b"4.9406564584124654e-324").unwrap()); } #[test] fn test_issue157() { assert_eq!( 1.2999999999999999E+154, s2d(b"1.2999999999999999E+154").unwrap(), ); }