public void TestLongReinterpretation()
{
Assert.AreEqual(
12345.67890,
FloatHelper.ReinterpretAsDouble(FloatHelper.ReinterpretAsLong(12345.67890)),
"Number hasn't changed after mirrored reinterpretation"
);
}
public void TestIntegerReinterpretation()
{
Assert.AreEqual(
12345.0f,
FloatHelper.ReinterpretAsFloat(FloatHelper.ReinterpretAsInt(12345.0f)),
"Number hasn't changed after mirrored reinterpretation"
);
}
public void TestFloatComparison()
{
Assert.IsTrue(
FloatHelper.AreAlmostEqual(0.00000001f, 0.0000000100000008f, 1),
"Minimal difference between very small floating point numbers is considered equal"
);
Assert.IsFalse(
FloatHelper.AreAlmostEqual(0.00000001f, 0.0000000100000017f, 1),
"Larger difference between very small floating point numbers is not considered equal"
);
Assert.IsTrue(
FloatHelper.AreAlmostEqual(1000000.00f, 1000000.06f, 1),
"Minimal difference between very large floating point numbers is considered equal"
);
Assert.IsFalse(
FloatHelper.AreAlmostEqual(1000000.00f, 1000000.13f, 1),
"Larger difference between very large floating point numbers is not considered equal"
);
}
public void TestDoubleComparison()
{
Assert.IsTrue(
FloatHelper.AreAlmostEqual(0.00000001, 0.000000010000000000000002, 1),
"Minimal difference between very small double precision floating point " +
"numbers is considered equal"
);
Assert.IsFalse(
FloatHelper.AreAlmostEqual(0.00000001, 0.000000010000000000000004, 1),
"Larger difference between very small double precision floating point " +
"numbers is not considered equal"
);
Assert.IsTrue(
FloatHelper.AreAlmostEqual(1000000.00, 1000000.0000000001, 1),
"Minimal difference between very large double precision floating point " +
"numbers is considered equal"
);
Assert.IsFalse(
FloatHelper.AreAlmostEqual(1000000.00, 1000000.0000000002, 1),
"Larger difference between very large double precision floating point " +
"numbers is not considered equal"
);
}
/// <summary>
/// Appends a double precision floating point value to a string builder
/// without generating garbage
/// </summary>
/// <param name="builder">String builder the value will be appended to</param>
/// <param name="value">Value that will be appended to the string builder</param>
/// <param name="decimalPlaces">Maximum number of decimal places to display</param>
/// <returns>Whether the value was inside the algorithm's supported range</returns>
/// <remarks>
/// Uses an algorithm that covers the sane range of possible values but will
/// fail to render extreme values, NaNs and infinity. In these cases, false
/// is returned and the traditional double.ToString() method can be used.
/// </remarks>
public static bool Append(StringBuilder builder, double value, int decimalPlaces)
{
const long ExponentBits = 0x7FF; // Bit mask for the exponent bits
const int FractionalBitCount = 52; // Number of bits for fractional part
const int ExponentBias = 1023; // Bias subtraced from exponent
const int NumericBitCount = 63; // Bits without sign
// You don't need modify these as they're calculated based on
// the constants assigned above.
const long FractionalBits = (2L << FractionalBitCount) - 1;
const long HighestFractionalBit = (1L << FractionalBitCount);
const int FractionalBitCountPlusOne = FractionalBitCount + 1;
long longValue = FloatHelper.ReinterpretAsLong(value);
long exponent = ((longValue >> FractionalBitCount) & ExponentBits) - ExponentBias;
long mantissa = (longValue & FractionalBits) | HighestFractionalBit;
long integral;
long fractional;
if (exponent >= 0)
{
if (exponent >= FractionalBitCount)
{
if (exponent >= NumericBitCount)
{
return(false);
}
integral = mantissa << (int)(exponent - FractionalBitCount);
fractional = 0;
}
else
{
integral = mantissa >> (int)(FractionalBitCount - exponent);
fractional = (mantissa << (int)(exponent + 1)) & FractionalBits;
}
}
else
{
if (exponent < -FractionalBitCount)
{
return(false);
}
integral = 0;
fractional = (mantissa & FractionalBits) >> -(int)(exponent + 1);
}
// Build the integral part
if (longValue < 0)
{
builder.Append('-');
}
if (integral == 0)
{
builder.Append('0');
}
else
{
recursiveAppend(builder, integral);
}
if (decimalPlaces > 0)
{
builder.Append('.');
// Build the fractional part
if (fractional == 0)
{
builder.Append('0');
}
else
{
while (fractional != 0)
{
fractional *= 10;
long digit = (fractional >> FractionalBitCountPlusOne);
builder.Append(numbers[digit]);
fractional &= FractionalBits;
--decimalPlaces;
if (decimalPlaces == 0)
{
break;
}
}
}
}
return(true);
}
