public static void ParseDecTest(
string ln,
IDictionary <string, string> context)
{
Match match;
if (ln.Contains("-- "))
{
ln = ln.Substring(0, ln.IndexOf("-- ", StringComparison.Ordinal));
}
match = (!ln.Contains(":")) ? null : ValuePropertyLine.Match(ln);
if (match != null && match.Success)
{
context[match.Groups[1].ToString().ToLowerInvariant()] =
match.Groups[2].ToString();
return;
}
match = ValueTestLine.Match(ln);
if (match.Success)
{
string name = match.Groups[1].ToString();
string op = match.Groups[2].ToString();
string input1 = match.Groups[3].ToString();
string input2 = match.Groups[4].ToString();
string input3 = match.Groups[5].ToString();
string output = match.Groups[6].ToString();
string flags = match.Groups[7].ToString();
input1 = ValueQuotes.Replace(input1, String.Empty);
input2 = ValueQuotes.Replace(input2, String.Empty);
input3 = ValueQuotes.Replace(input3, String.Empty);
output = ValueQuotes.Replace(output, String.Empty);
bool extended = GetKeyOrDefault(context, "extended", "1").Equals("1");
bool clamp = GetKeyOrDefault(context, "clamp", "0").Equals("1");
int precision = Convert.ToInt32(
context["precision"],
System.Globalization.CultureInfo.InvariantCulture);
int minexponent = Convert.ToInt32(
context["minexponent"],
System.Globalization.CultureInfo.InvariantCulture);
int maxexponent = Convert.ToInt32(
context["maxexponent"],
System.Globalization.CultureInfo.InvariantCulture);
// Skip tests that take null as input or output;
// also skip tests that take a hex number format
if (input1.Contains("#") || input2.Contains("#") ||
input3.Contains("#") || output.Contains("#"))
{
return;
}
// Skip some tests that assume a maximum
// supported precision of 999999999
if (name.Equals("pow250") || name.Equals("pow251") ||
name.Equals("pow252"))
{
return;
}
// Skip some test cases that are incorrect
// (all simplified arithmetic test cases)
if (!extended)
{
if (name.Equals("ln116") ||
name.Equals("qua530") || // assumes that the input will underflow
// to 0
name.Equals("qua531") || // assumes that the input will underflow
// to 0
name.Equals("rpow068") || name.Equals("rpow159") ||
name.Equals("rpow217") || name.Equals("rpow272") ||
name.Equals("rpow324") || name.Equals("rpow327") ||
// following cases incorrectly remove trailing zeros
name.Equals("sqtx2207") || name.Equals("sqtx2231") ||
name.Equals("sqtx2271") || name.Equals("sqtx2327") ||
name.Equals("sqtx2399") || name.Equals("sqtx2487") ||
name.Equals("sqtx2591") || name.Equals("sqtx2711") ||
name.Equals("sqtx2847"))
{
return;
}
}
if (input1.Contains("?"))
{
return;
}
if (flags.Contains("Invalid_context"))
{
return;
}
EContext ctx = EContext.ForPrecision(precision)
.WithExponentClamp(clamp).WithExponentRange(
minexponent,
maxexponent);
string rounding = context["rounding"];
if (rounding.Equals("half_up"))
{
ctx = ctx.WithRounding(ERounding.HalfUp);
}
if (rounding.Equals("half_down"))
{
ctx = ctx.WithRounding(ERounding.HalfDown);
}
if (rounding.Equals("half_even"))
{
ctx = ctx.WithRounding(ERounding.HalfEven);
}
if (rounding.Equals("up"))
{
ctx = ctx.WithRounding(ERounding.Up);
}
if (rounding.Equals("down"))
{
ctx = ctx.WithRounding(ERounding.Down);
}
if (rounding.Equals("ceiling"))
{
ctx = ctx.WithRounding(ERounding.Ceiling);
}
if (rounding.Equals("floor"))
{
ctx = ctx.WithRounding(ERounding.Floor);
}
if (rounding.Equals("05up"))
{
ctx = ctx.WithRounding(ERounding.ZeroFiveUp);
}
if (!extended)
{
ctx = ctx.WithSimplified(true);
}
ctx = ctx.WithBlankFlags();
EDecimal d1 = EDecimal.Zero, d2 = null, d2a = null;
if (!op.Equals("toSci") && !op.Equals("toEng"))
{
d1 = String.IsNullOrEmpty(input1) ? EDecimal.Zero :
EDecimal.FromString(input1);
d2 = String.IsNullOrEmpty(input2) ? null :
EDecimal.FromString(input2);
d2a = String.IsNullOrEmpty(input3) ? null :
EDecimal.FromString(input3);
}
EDecimal d3 = null;
if (op.Equals("fma") && !extended)
{
// This implementation does implement multiply-and-add
// in the simplified arithmetic, even though the test cases expect
// an invalid operation to be raised. This seems to be allowed
// under appendix A, which merely says that multiply-and-add
// "is not defined" in the simplified arithmetic.
return;
}
if (op.Equals("multiply"))
{
d3 = d1.Multiply(d2, ctx);
}
else if (op.Equals("toSci")) // handled below
{
}
else if (op.Equals("toEng")) // handled below
{
}
else if (op.Equals("fma"))
{
d3 = d1.MultiplyAndAdd(d2, d2a, ctx);
}
else if (op.Equals("min"))
{
d3 = EDecimal.Min(d1, d2, ctx);
}
else if (op.Equals("max"))
{
d3 = EDecimal.Max(d1, d2, ctx);
}
else if (op.Equals("minmag"))
{
d3 = EDecimal.MinMagnitude(d1, d2, ctx);
}
else if (op.Equals("maxmag"))
{
d3 = EDecimal.MaxMagnitude(d1, d2, ctx);
}
else if (op.Equals("compare"))
{
d3 = d1.CompareToWithContext(d2, ctx);
}
else if (op.Equals("comparetotal"))
{
d3 = d1.CompareToTotal(d2, ctx);
}
else if (op.Equals("comparetotmag"))
{
d3 = EDecimal.FromInt32(d1.CompareToTotalMagnitude(d2));
}
else if (op.Equals("copyabs"))
{
d3 = d1.Abs();
}
else if (op.Equals("copynegate"))
{
d3 = d1.Negate();
}
else if (op.Equals("copysign"))
{
d3 = d1.CopySign(d2);
}
else if (op.Equals("comparesig"))
{
d3 = d1.CompareToSignal(d2, ctx);
}
else if (op.Equals("subtract"))
{
d3 = d1.Subtract(d2, ctx);
}
else if (op.Equals("tointegral"))
{
d3 = d1.RoundToIntegerNoRoundedFlag(ctx);
}
else if (op.Equals("tointegralx"))
{
d3 = d1.RoundToIntegerExact(ctx);
}
else if (op.Equals("divideint"))
{
d3 = d1.DivideToIntegerZeroScale(d2, ctx);
}
else if (op.Equals("divide"))
{
d3 = d1.Divide(d2, ctx);
}
else if (op.Equals("remainder"))
{
d3 = d1.Remainder(d2, ctx);
}
else if (op.Equals("exp"))
{
d3 = d1.Exp(ctx);
}
else if (op.Equals("ln"))
{
d3 = d1.Log(ctx);
}
else if (op.Equals("log10"))
{
d3 = d1.Log10(ctx);
}
else if (op.Equals("power"))
{
d3 = d1.Pow(d2, ctx);
}
else if (op.Equals("squareroot"))
{
d3 = d1.Sqrt(ctx);
}
else if (op.Equals("remaindernear"))
{
d3 = d1.RemainderNear(d2, ctx);
}
else if (op.Equals("nexttoward"))
{
d3 = d1.NextToward(d2, ctx);
}
else if (op.Equals("nextplus"))
{
d3 = d1.NextPlus(ctx);
}
else if (op.Equals("nextminus"))
{
d3 = d1.NextMinus(ctx);
}
else if (op.Equals("copy"))
{
d3 = d1;
}
else if (op.Equals("abs"))
{
d3 = d1.Abs(ctx);
}
else if (op.Equals("reduce"))
{
d3 = d1.Reduce(ctx);
}
else if (op.Equals("quantize"))
{
d3 = d1.Quantize(d2, ctx);
}
else if (op.Equals("add"))
{
d3 = d1.Add(d2, ctx);
}
else if (op.Equals("minus"))
{
d3 = d1.Negate(ctx);
}
else if (op.Equals("apply"))
{
d3 = d1.RoundToPrecision(ctx);
}
else if (op.Equals("plus"))
{
d3 = d1.Plus(ctx);
}
else
{
// Console.WriteLine("unknown op "+op);
return;
}
bool invalid = flags.Contains("Division_impossible") ||
flags.Contains("Division_undefined") ||
flags.Contains("Invalid_operation");
bool divzero = flags.Contains("Division_by_zero");
var expectedFlags = 0;
if (flags.Contains("Inexact") || flags.Contains("inexact"))
{
expectedFlags |= EContext.FlagInexact;
}
if (flags.Contains("Subnormal"))
{
expectedFlags |= EContext.FlagSubnormal;
}
if (flags.Contains("Rounded") || flags.Contains("rounded"))
{
expectedFlags |= EContext.FlagRounded;
}
if (flags.Contains("Underflow"))
{
expectedFlags |= EContext.FlagUnderflow;
}
if (flags.Contains("Overflow"))
{
expectedFlags |= EContext.FlagOverflow;
}
if (flags.Contains("Clamped"))
{
if (extended || clamp)
{
expectedFlags |= EContext.FlagClamped;
}
}
if (flags.Contains("Lost_digits"))
{
expectedFlags |= EContext.FlagLostDigits;
}
bool conversionError = flags.Contains("Conversion_syntax");
if (invalid)
{
expectedFlags |= EContext.FlagInvalid;
}
if (divzero)
{
expectedFlags |= EContext.FlagDivideByZero;
}
if (op.Equals("toSci"))
{
try {
d1 = EDecimal.FromString(input1, ctx);
Assert.IsTrue(!conversionError, "Expected no conversion error");
String converted = d1.ToString();
if (!output.Equals("?"))
{
Assert.AreEqual(output, converted, input1);
}
} catch (FormatException) {
Assert.IsTrue(conversionError, "Expected conversion error");
}
}
else if (op.Equals("toEng"))
{
try {
d1 = EDecimal.FromString(input1, ctx);
Assert.IsTrue(!conversionError, "Expected no conversion error");
String converted = d1.ToEngineeringString();
if (!output.Equals("?"))
{
Assert.AreEqual(output, converted, input1);
}
} catch (FormatException) {
Assert.IsTrue(conversionError, "Expected conversion error");
}
}
else
{
if (!output.Equals("?"))
{
if (output == null && d3 != null)
{
Assert.Fail(name + ": d3 must be null");
}
if (output != null && !d3.ToString().Equals(output))
{
EDecimal d4 = EDecimal.FromString(output);
{
object objectTemp = output;
object objectTemp2 = d3.ToString();
string messageTemp = name + ": expected: [" + d4.UnsignedMantissa +
" " + d4.Exponent +
"]\\n" + "but was: [" + d3.UnsignedMantissa + " " +
d3.Exponent + "]";
Assert.AreEqual(objectTemp, objectTemp2, messageTemp);
}
}
}
}
// Don't check flags for five simplified arithmetic
// test cases that say to set the rounded flag; the
// extended arithmetic counterparts for at least
// some of them have no flags in their
// result.
if (!name.Equals("pow118") && !name.Equals("pow119") &&
!name.Equals("pow120") && !name.Equals("pow121") &&
!name.Equals("pow122"))
{
AssertFlags(expectedFlags, ctx.Flags, name);
}
}
}
