test/src/stdlib/strtof_test.cpp - llvm-project/libc - Git at Google

 //===-- Unittests for strtof ---------------------------------------------===//
 //
 // Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions.
 // See https://llvm.org/LICENSE.txt for license information.
 // SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception
 //
 //===----------------------------------------------------------------------===//

 #include "src/__support/FPUtil/FPBits.h"
 #include "src/stdlib/strtof.h"

 #include "utils/UnitTest/Test.h"

 #include <errno.h>
 #include <limits.h>
 #include <stddef.h>

 class LlvmLibcStrToFTest : public __llvm_libc::testing::Test {
 public:
   void runTest(const char *inputString, const ptrdiff_t expectedStrLen,
                const uint32_t expectedRawData, const int expectedErrno = 0) {
     // expectedRawData is the expected float result as a uint32_t, organized
     // according to IEEE754:
     //
     // +-- 1 Sign Bit      +-- 23 Mantissa bits
     // |                   |
     // |        +----------+----------+
     // |        |                     |
     // SEEEEEEEEMMMMMMMMMMMMMMMMMMMMMMM
     //  |      |
     //  +--+---+
     //     |
     //     +-- 8 Exponent Bits
     //
     //  This is so that the result can be compared in parts.
     char *strEnd = nullptr;

     __llvm_libc::fputil::FPBits<float> expectedFP =
         __llvm_libc::fputil::FPBits<float>(expectedRawData);

     errno = 0;
     float result = __llvm_libc::strtof(inputString, &strEnd);

     __llvm_libc::fputil::FPBits<float> actualFP =
         __llvm_libc::fputil::FPBits<float>(result);

     EXPECT_EQ(strEnd - inputString, expectedStrLen);

     EXPECT_EQ(actualFP.bits, expectedFP.bits);
     EXPECT_EQ(actualFP.getSign(), expectedFP.getSign());
     EXPECT_EQ(actualFP.getExponent(), expectedFP.getExponent());
     EXPECT_EQ(actualFP.getMantissa(), expectedFP.getMantissa());
     EXPECT_EQ(errno, expectedErrno);
   }
 };

 // This is the set of tests that I have working (verified correct when compared
 // to system libc). This is here so I don't break more things when I try to fix
 // them.

 TEST_F(LlvmLibcStrToFTest, BasicDecimalTests) {
   runTest("1", 1, 0x3f800000);
   runTest("123", 3, 0x42f60000);
   runTest("1234567890", 10, 0x4e932c06u);
   runTest("123456789012345678901", 21, 0x60d629d4);
   runTest("0.1", 3, 0x3dcccccdu);
   runTest(".1", 2, 0x3dcccccdu);
   runTest("-0.123456789", 12, 0xbdfcd6eau);
   runTest("0.11111111111111111111", 22, 0x3de38e39u);
   runTest("0.0000000000000000000000001", 27, 0x15f79688u);
 }

 TEST_F(LlvmLibcStrToFTest, DecimalOutOfRangeTests) {
   runTest("555E36", 6, 0x7f800000, ERANGE);
   runTest("1e-10000", 8, 0x0, ERANGE);
 }

 TEST_F(LlvmLibcStrToFTest, DecimalsWithRoundingProblems) {
   runTest("20040229", 8, 0x4b98e512);
   runTest("20040401", 8, 0x4b98e568);
   runTest("9E9", 3, 0x50061c46);
 }

 TEST_F(LlvmLibcStrToFTest, DecimalSubnormals) {
   runTest("1.4012984643248170709237295832899161312802619418765e-45", 55, 0x1,
           ERANGE);
 }

 TEST_F(LlvmLibcStrToFTest, DecimalWithLongExponent) {
   runTest("1e2147483648", 12, 0x7f800000, ERANGE);
   runTest("1e2147483646", 12, 0x7f800000, ERANGE);
   runTest("100e2147483646", 14, 0x7f800000, ERANGE);
   runTest("1e-2147483647", 13, 0x0, ERANGE);
   runTest("1e-2147483649", 13, 0x0, ERANGE);
 }

 TEST_F(LlvmLibcStrToFTest, BasicHexadecimalTests) {
   runTest("0x1", 3, 0x3f800000);
   runTest("0x10", 4, 0x41800000);
   runTest("0x11", 4, 0x41880000);
   runTest("0x0.1234", 8, 0x3d91a000);
 }

 TEST_F(LlvmLibcStrToFTest, HexadecimalSubnormalTests) {
   runTest("0x0.0000000000000000000000000000000002", 38, 0x4000, ERANGE);

   // This is the largest subnormal number as represented in hex
   runTest("0x0.00000000000000000000000000000003fffff8", 42, 0x7fffff, ERANGE);
 }

 TEST_F(LlvmLibcStrToFTest, HexadecimalSubnormalRoundingTests) {
   // This is the largest subnormal number that gets rounded down to 0 (as a
   // float)
   runTest("0x0.00000000000000000000000000000000000004", 42, 0x0, ERANGE);

   // This is slightly larger, and thus rounded up
   runTest("0x0.000000000000000000000000000000000000041", 43, 0x00000001,
           ERANGE);

   // These check that we're rounding to even properly
   runTest("0x0.0000000000000000000000000000000000000b", 42, 0x00000001, ERANGE);
   runTest("0x0.0000000000000000000000000000000000000c", 42, 0x00000002, ERANGE);

   // These check that we're rounding to even properly even when the input bits
   // are longer than the bit fields can contain.
   runTest("0x1.000000000000000000000p-150", 30, 0x00000000, ERANGE);
   runTest("0x1.000010000000000001000p-150", 30, 0x00000001, ERANGE);
   runTest("0x1.000100000000000001000p-134", 30, 0x00008001, ERANGE);
   runTest("0x1.FFFFFC000000000001000p-127", 30, 0x007FFFFF, ERANGE);
   runTest("0x1.FFFFFE000000000000000p-127", 30, 0x00800000);
 }

 TEST_F(LlvmLibcStrToFTest, HexadecimalNormalRoundingTests) {
   // This also checks the round to even behavior by checking three adjacent
   // numbers.
   // This gets rounded down to even
   runTest("0x123456500", 11, 0x4f91a2b2);
   // This doesn't get rounded at all
   runTest("0x123456600", 11, 0x4f91a2b3);
   // This gets rounded up to even
   runTest("0x123456700", 11, 0x4f91a2b4);
   // Correct rounding for long input
   runTest("0x1.000001000000000000000", 25, 0x3f800000);
   runTest("0x1.000001000000000000100", 25, 0x3f800001);
 }

 TEST_F(LlvmLibcStrToFTest, HexadecimalsWithRoundingProblems) {
   runTest("0xFFFFFFFF", 10, 0x4f800000);
 }

 TEST_F(LlvmLibcStrToFTest, HexadecimalOutOfRangeTests) {
   runTest("0x123456789123456789123456789123456789", 38, 0x7f800000, ERANGE);
   runTest("-0x123456789123456789123456789123456789", 39, 0xff800000, ERANGE);
   runTest("0x0.00000000000000000000000000000000000001", 42, 0x0, ERANGE);
 }

 TEST_F(LlvmLibcStrToFTest, InfTests) {
   runTest("INF", 3, 0x7f800000);
   runTest("INFinity", 8, 0x7f800000);
   runTest("infnity", 3, 0x7f800000);
   runTest("infinit", 3, 0x7f800000);
   runTest("infinfinit", 3, 0x7f800000);
   runTest("innf", 0, 0x0);
   runTest("-inf", 4, 0xff800000);
   runTest("-iNfInItY", 9, 0xff800000);
 }

 TEST_F(LlvmLibcStrToFTest, SimpleNaNTests) {
   runTest("NaN", 3, 0x7fc00000);
   runTest("-nAn", 4, 0xffc00000);
 }

 // These NaNs are of the form `NaN(n-character-sequence)` where the
 // n-character-sequence is 0 or more letters or numbers. If there is anything
 // other than a letter or a number, then the valid number is just `NaN`. If
 // the sequence is valid, then the interpretation of them is implementation
 // defined, in this case it's passed to strtoll with an automatic base, and
 // the result is put into the mantissa if it takes up the whole width of the
 // parentheses.
 TEST_F(LlvmLibcStrToFTest, NaNWithParenthesesEmptyTest) {
   runTest("NaN()", 5, 0x7fc00000);
 }

 TEST_F(LlvmLibcStrToFTest, NaNWithParenthesesValidNumberTests) {
   runTest("NaN(1234)", 9, 0x7fc004d2);
   runTest("NaN(0x1234)", 11, 0x7fc01234);
   runTest("NaN(01234)", 10, 0x7fc0029c);
 }

 TEST_F(LlvmLibcStrToFTest, NaNWithParenthesesInvalidSequenceTests) {
   runTest("NaN( 1234)", 3, 0x7fc00000);
   runTest("NaN(-1234)", 3, 0x7fc00000);
   runTest("NaN(asd&f)", 3, 0x7fc00000);
   runTest("NaN(123 )", 3, 0x7fc00000);
   runTest("NaN(123+asdf)", 3, 0x7fc00000);
   runTest("NaN(123", 3, 0x7fc00000);
 }

 TEST_F(LlvmLibcStrToFTest, NaNWithParenthesesValidSequenceInvalidNumberTests) {
   runTest("NaN(1a)", 7, 0x7fc00000);
   runTest("NaN(asdf)", 9, 0x7fc00000);
   runTest("NaN(1A1)", 8, 0x7fc00000);
 }
	//===-- Unittests for strtof ---------------------------------------------===//
	//
	// Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions.
	// See https://llvm.org/LICENSE.txt for license information.
	// SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception
	//
	//===----------------------------------------------------------------------===//

	#include "src/__support/FPUtil/FPBits.h"
	#include "src/stdlib/strtof.h"

	#include "utils/UnitTest/Test.h"

	#include <errno.h>
	#include <limits.h>
	#include <stddef.h>

	class LlvmLibcStrToFTest : public __llvm_libc::testing::Test {
	public:
	void runTest(const char *inputString, const ptrdiff_t expectedStrLen,
	const uint32_t expectedRawData, const int expectedErrno = 0) {
	// expectedRawData is the expected float result as a uint32_t, organized
	// according to IEEE754:
	//
	// +-- 1 Sign Bit +-- 23 Mantissa bits
	// \| \|
	// \| +----------+----------+
	// \| \| \|
	// SEEEEEEEEMMMMMMMMMMMMMMMMMMMMMMM
	// \| \|
	// +--+---+
	// \|
	// +-- 8 Exponent Bits
	//
	// This is so that the result can be compared in parts.
	char *strEnd = nullptr;

	__llvm_libc::fputil::FPBits<float> expectedFP =
	__llvm_libc::fputil::FPBits<float>(expectedRawData);

	errno = 0;
	float result = __llvm_libc::strtof(inputString, &strEnd);

	__llvm_libc::fputil::FPBits<float> actualFP =
	__llvm_libc::fputil::FPBits<float>(result);

	EXPECT_EQ(strEnd - inputString, expectedStrLen);

	EXPECT_EQ(actualFP.bits, expectedFP.bits);
	EXPECT_EQ(actualFP.getSign(), expectedFP.getSign());
	EXPECT_EQ(actualFP.getExponent(), expectedFP.getExponent());
	EXPECT_EQ(actualFP.getMantissa(), expectedFP.getMantissa());
	EXPECT_EQ(errno, expectedErrno);
	}
	};

	// This is the set of tests that I have working (verified correct when compared
	// to system libc). This is here so I don't break more things when I try to fix
	// them.

	TEST_F(LlvmLibcStrToFTest, BasicDecimalTests) {
	runTest("1", 1, 0x3f800000);
	runTest("123", 3, 0x42f60000);
	runTest("1234567890", 10, 0x4e932c06u);
	runTest("123456789012345678901", 21, 0x60d629d4);
	runTest("0.1", 3, 0x3dcccccdu);
	runTest(".1", 2, 0x3dcccccdu);
	runTest("-0.123456789", 12, 0xbdfcd6eau);
	runTest("0.11111111111111111111", 22, 0x3de38e39u);
	runTest("0.0000000000000000000000001", 27, 0x15f79688u);
	}

	TEST_F(LlvmLibcStrToFTest, DecimalOutOfRangeTests) {
	runTest("555E36", 6, 0x7f800000, ERANGE);
	runTest("1e-10000", 8, 0x0, ERANGE);
	}

	TEST_F(LlvmLibcStrToFTest, DecimalsWithRoundingProblems) {
	runTest("20040229", 8, 0x4b98e512);
	runTest("20040401", 8, 0x4b98e568);
	runTest("9E9", 3, 0x50061c46);
	}

	TEST_F(LlvmLibcStrToFTest, DecimalSubnormals) {
	runTest("1.4012984643248170709237295832899161312802619418765e-45", 55, 0x1,
	ERANGE);
	}

	TEST_F(LlvmLibcStrToFTest, DecimalWithLongExponent) {
	runTest("1e2147483648", 12, 0x7f800000, ERANGE);
	runTest("1e2147483646", 12, 0x7f800000, ERANGE);
	runTest("100e2147483646", 14, 0x7f800000, ERANGE);
	runTest("1e-2147483647", 13, 0x0, ERANGE);
	runTest("1e-2147483649", 13, 0x0, ERANGE);
	}

	TEST_F(LlvmLibcStrToFTest, BasicHexadecimalTests) {
	runTest("0x1", 3, 0x3f800000);
	runTest("0x10", 4, 0x41800000);
	runTest("0x11", 4, 0x41880000);
	runTest("0x0.1234", 8, 0x3d91a000);
	}

	TEST_F(LlvmLibcStrToFTest, HexadecimalSubnormalTests) {
	runTest("0x0.0000000000000000000000000000000002", 38, 0x4000, ERANGE);

	// This is the largest subnormal number as represented in hex
	runTest("0x0.00000000000000000000000000000003fffff8", 42, 0x7fffff, ERANGE);
	}

	TEST_F(LlvmLibcStrToFTest, HexadecimalSubnormalRoundingTests) {
	// This is the largest subnormal number that gets rounded down to 0 (as a
	// float)
	runTest("0x0.00000000000000000000000000000000000004", 42, 0x0, ERANGE);

	// This is slightly larger, and thus rounded up
	runTest("0x0.000000000000000000000000000000000000041", 43, 0x00000001,
	ERANGE);

	// These check that we're rounding to even properly
	runTest("0x0.0000000000000000000000000000000000000b", 42, 0x00000001, ERANGE);
	runTest("0x0.0000000000000000000000000000000000000c", 42, 0x00000002, ERANGE);

	// These check that we're rounding to even properly even when the input bits
	// are longer than the bit fields can contain.
	runTest("0x1.000000000000000000000p-150", 30, 0x00000000, ERANGE);
	runTest("0x1.000010000000000001000p-150", 30, 0x00000001, ERANGE);
	runTest("0x1.000100000000000001000p-134", 30, 0x00008001, ERANGE);
	runTest("0x1.FFFFFC000000000001000p-127", 30, 0x007FFFFF, ERANGE);
	runTest("0x1.FFFFFE000000000000000p-127", 30, 0x00800000);
	}

	TEST_F(LlvmLibcStrToFTest, HexadecimalNormalRoundingTests) {
	// This also checks the round to even behavior by checking three adjacent
	// numbers.
	// This gets rounded down to even
	runTest("0x123456500", 11, 0x4f91a2b2);
	// This doesn't get rounded at all
	runTest("0x123456600", 11, 0x4f91a2b3);
	// This gets rounded up to even
	runTest("0x123456700", 11, 0x4f91a2b4);
	// Correct rounding for long input
	runTest("0x1.000001000000000000000", 25, 0x3f800000);
	runTest("0x1.000001000000000000100", 25, 0x3f800001);
	}

	TEST_F(LlvmLibcStrToFTest, HexadecimalsWithRoundingProblems) {
	runTest("0xFFFFFFFF", 10, 0x4f800000);
	}

	TEST_F(LlvmLibcStrToFTest, HexadecimalOutOfRangeTests) {
	runTest("0x123456789123456789123456789123456789", 38, 0x7f800000, ERANGE);
	runTest("-0x123456789123456789123456789123456789", 39, 0xff800000, ERANGE);
	runTest("0x0.00000000000000000000000000000000000001", 42, 0x0, ERANGE);
	}

	TEST_F(LlvmLibcStrToFTest, InfTests) {
	runTest("INF", 3, 0x7f800000);
	runTest("INFinity", 8, 0x7f800000);
	runTest("infnity", 3, 0x7f800000);
	runTest("infinit", 3, 0x7f800000);
	runTest("infinfinit", 3, 0x7f800000);
	runTest("innf", 0, 0x0);
	runTest("-inf", 4, 0xff800000);
	runTest("-iNfInItY", 9, 0xff800000);
	}

	TEST_F(LlvmLibcStrToFTest, SimpleNaNTests) {
	runTest("NaN", 3, 0x7fc00000);
	runTest("-nAn", 4, 0xffc00000);
	}

	// These NaNs are of the form `NaN(n-character-sequence)` where the
	// n-character-sequence is 0 or more letters or numbers. If there is anything
	// other than a letter or a number, then the valid number is just `NaN`. If
	// the sequence is valid, then the interpretation of them is implementation
	// defined, in this case it's passed to strtoll with an automatic base, and
	// the result is put into the mantissa if it takes up the whole width of the
	// parentheses.
	TEST_F(LlvmLibcStrToFTest, NaNWithParenthesesEmptyTest) {
	runTest("NaN()", 5, 0x7fc00000);
	}

	TEST_F(LlvmLibcStrToFTest, NaNWithParenthesesValidNumberTests) {
	runTest("NaN(1234)", 9, 0x7fc004d2);
	runTest("NaN(0x1234)", 11, 0x7fc01234);
	runTest("NaN(01234)", 10, 0x7fc0029c);
	}

	TEST_F(LlvmLibcStrToFTest, NaNWithParenthesesInvalidSequenceTests) {
	runTest("NaN( 1234)", 3, 0x7fc00000);
	runTest("NaN(-1234)", 3, 0x7fc00000);
	runTest("NaN(asd&f)", 3, 0x7fc00000);
	runTest("NaN(123 )", 3, 0x7fc00000);
	runTest("NaN(123+asdf)", 3, 0x7fc00000);
	runTest("NaN(123", 3, 0x7fc00000);
	}

	TEST_F(LlvmLibcStrToFTest, NaNWithParenthesesValidSequenceInvalidNumberTests) {
	runTest("NaN(1a)", 7, 0x7fc00000);
	runTest("NaN(asdf)", 9, 0x7fc00000);
	runTest("NaN(1A1)", 8, 0x7fc00000);
	}