public int CompareTo(FastInteger fint)
{
switch (this.integerMode)
{
case IntegerMode.SmallValue:
return(-fint.CompareToInt(this.smallValue));
case IntegerMode.LargeValue:
return(-fint.CompareTo(this.largeValue));
default: throw new InvalidOperationException();
}
}
public void ShiftToDigits(
FastInteger bits,
FastInteger preShift,
bool truncate)
{
if (bits.Sign < 0)
{
throw new ArgumentException("bits's sign(" + bits.Sign +
") is less than 0");
}
if (preShift != null && preShift.Sign > 0)
{
this.knownBitLength = this.knownBitLength ?? this.CalcKnownBitLength();
// DebugUtility.Log("bits=" + bits + " pre=" + preShift + " known=" +
// (//kbl) + " [" + this.shiftedBigInt + "]");
if (this.knownBitLength.CompareTo(bits) <= 0)
{
// Known digit length is already small enough
// NOTE: For BitShiftAccumulator, truncating and shifting
// are the same, unlike in DigitShiftAccumulator
this.ShiftRight(preShift);
VerifyKnownLength();
return;
}
else
{
FastInteger bitDiff = this.knownBitLength.Copy()
.Subtract(bits);
// DebugUtility.Log("bitDiff=" + bitDiff);
int cmp = bitDiff.CompareTo(preShift);
if (cmp <= 0)
{
// NOTE: For BitShiftAccumulator, truncating and shifting
// are the same, unlike in DigitShiftAccumulator
this.ShiftRight(preShift);
VerifyKnownLength();
return;
}
else
{
// NOTE: For BitShiftAccumulator, truncating and shifting
// are the same, unlike in DigitShiftAccumulator
this.ShiftRight(bitDiff);
VerifyKnownLength();
return;
}
}
}
if (bits.CanFitInInt32())
{
this.ShiftToDigitsInt(bits.ToInt32());
VerifyKnownLength();
}
else
{
this.knownBitLength = this.knownBitLength ?? this.CalcKnownBitLength();
EInteger bigintDiff = this.knownBitLength.ToEInteger();
EInteger bitsBig = bits.ToEInteger();
bigintDiff -= (EInteger)bitsBig;
if (bigintDiff.Sign > 0)
{
// current length is greater than the
// desired bit length
this.ShiftRight(FastInteger.FromBig(bigintDiff));
}
VerifyKnownLength();
}
}
public static THelper PreRound <THelper>(
THelper val,
EContext ctx,
IRadixMath <THelper> wrapper)
{
if (ctx == null || !ctx.HasMaxPrecision)
{
return(val);
}
IRadixMathHelper <THelper> helper = wrapper.GetHelper();
int thisFlags = helper.GetFlags(val);
if ((thisFlags & BigNumberFlags.FlagSpecial) != 0)
{
// Infinity or NaN
return(val);
}
FastInteger fastPrecision = FastInteger.FromBig(ctx.Precision);
EInteger mant = helper.GetMantissa(val).Abs();
// Rounding is only to be done if the digit count is
// too big (distinguishing this case is material
// if the value also has an exponent that's out of range)
FastInteger[] digitBounds = NumberUtility.DigitLengthBounds(
helper,
mant);
if (digitBounds[1].CompareTo(fastPrecision) <= 0)
{
// Upper bound is less than or equal to precision
return(val);
}
EContext ctx2 = ctx;
if (digitBounds[0].CompareTo(fastPrecision) <= 0)
{
// Lower bound is less than or equal to precision, so
// calculate digit length more precisely
FastInteger digits = helper.GetDigitLength(mant);
ctx2 = ctx.WithBlankFlags().WithTraps(0);
if (digits.CompareTo(fastPrecision) <= 0)
{
return(val);
}
}
val = wrapper.RoundToPrecision(val, ctx2);
// the only time rounding can signal an invalid
// operation is if an operand is a signaling NaN, but
// this was already checked beforehand
#if DEBUG
if ((ctx2.Flags & EContext.FlagInvalid) != 0)
{
throw new ArgumentException("doesn't" +
"\u0020satisfy(ctx2.Flags&FlagInvalid)==0");
}
#endif
if ((ctx2.Flags & EContext.FlagInexact) != 0)
{
if (ctx.HasFlags)
{
ctx.Flags |= BigNumberFlags.LostDigitsFlags;
}
}
if ((ctx2.Flags & EContext.FlagRounded) != 0)
{
if (ctx.HasFlags)
{
ctx.Flags |= EContext.FlagRounded;
}
}
if ((ctx2.Flags & EContext.FlagOverflow) != 0)
{
bool neg = (thisFlags & BigNumberFlags.FlagNegative) != 0;
if (ctx.HasFlags)
{
ctx.Flags |= EContext.FlagLostDigits;
ctx.Flags |= EContext.FlagOverflow |
EContext.FlagInexact | EContext.FlagRounded;
}
}
return(val);
}
public static EInteger ReduceTrailingZeros(
EInteger bigmant,
FastInteger exponentMutable,
int radix,
FastInteger digits,
FastInteger precision,
FastInteger idealExp)
{
#if DEBUG
if (precision != null && digits == null)
{
throw new ArgumentException("doesn't satisfy precision==null ||" +
"\u0020digits!=null");
}
if (!(bigmant.Sign >= 0))
{
throw new ArgumentException("doesn't satisfy bigmant.Sign >= 0");
}
#endif
if (bigmant.IsZero)
{
exponentMutable.SetInt(0);
return(bigmant);
}
if (radix == 2)
{
if (!bigmant.IsEven)
{
return(bigmant);
}
long lowbit = bigmant.GetLowBitAsInt64();
if (lowbit != Int64.MaxValue)
{
if (precision != null && digits.CompareTo(precision) >= 0)
{
// Limit by digits minus precision
EInteger tmp = digits.ToEInteger().Subtract(precision.ToEInteger());
if (tmp.CompareTo(EInteger.FromInt64(lowbit)) < 0)
{
lowbit = tmp.ToInt64Checked();
}
}
if (idealExp != null && exponentMutable.CompareTo(idealExp) <= 0)
{
// Limit by idealExp minus exponentMutable
EInteger tmp =
idealExp.ToEInteger().Subtract(exponentMutable.ToEInteger());
if (tmp.CompareTo(EInteger.FromInt64(lowbit)) < 0)
{
lowbit = tmp.ToInt64Checked();
}
}
bigmant = (lowbit <= Int32.MaxValue) ?
bigmant.ShiftRight((int)lowbit) :
bigmant.ShiftRight(EInteger.FromInt64(lowbit));
if (digits != null)
{
digits.SubtractInt64(lowbit);
}
if (exponentMutable != null)
{
exponentMutable.AddInt64(lowbit);
}
return(bigmant);
}
}
var bigradix = (EInteger)radix;
var bitsToShift = new FastInteger(0);
while (!bigmant.IsZero)
{
if (precision != null && digits.CompareTo(precision) == 0)
{
break;
}
if (idealExp != null && exponentMutable.CompareTo(idealExp) == 0)
{
break;
}
EInteger bigrem;
EInteger bigquo;
EInteger[] divrem = bigmant.DivRem(bigradix);
bigquo = divrem[0];
bigrem = divrem[1];
if (!bigrem.IsZero)
{
break;
}
bigmant = bigquo;
exponentMutable.Increment();
if (digits != null)
{
digits.Decrement();
}
}
return(bigmant);
}
public static EInteger ReduceTrailingZeros(
EInteger bigmant,
FastInteger exponentMutable,
int radix,
FastInteger digits,
FastInteger precision,
FastInteger idealExp) {
#if DEBUG
if (precision != null && digits == null) {
throw new ArgumentException("doesn't satisfy precision==null || digits!=null");
}
#endif
if (bigmant.IsZero) {
exponentMutable.SetInt(0);
return bigmant;
}
var bigradix = (EInteger)radix;
var bitToTest = 0;
var bitsToShift = new FastInteger(0);
while (!bigmant.IsZero) {
if (precision != null && digits.CompareTo(precision) == 0) {
break;
}
if (idealExp != null && exponentMutable.CompareTo(idealExp) == 0) {
break;
}
if (radix == 2) {
if (bitToTest < Int32.MaxValue) {
if (bigmant.GetSignedBit(bitToTest)) {
break;
}
++bitToTest;
bitsToShift.Increment();
} else {
if (!bigmant.IsEven) {
break;
}
bigmant >>= 1;
}
} else {
EInteger bigrem;
EInteger bigquo;
{
EInteger[] divrem = bigmant.DivRem(bigradix);
bigquo = divrem[0];
bigrem = divrem[1]; }
if (!bigrem.IsZero) {
break;
}
bigmant = bigquo;
}
exponentMutable.Increment();
if (digits != null) {
digits.Decrement();
}
}
if (radix == 2 && !bitsToShift.IsValueZero) {
while (bitsToShift.CompareToInt(1000000) > 0) {
bigmant >>= 1000000;
bitsToShift.SubtractInt(1000000);
}
int tmpshift = bitsToShift.AsInt32();
bigmant >>= tmpshift;
}
return bigmant;
}
private T PostProcessEx(
T thisValue,
EContext ctxDest,
EContext ctxSrc,
bool afterDivision,
bool afterQuantize)
{
int thisFlags = this.GetHelper().GetFlags(thisValue);
if (ctxDest != null && ctxSrc != null)
{
if (ctxDest.HasFlags)
{
if (!ctxSrc.ClampNormalExponents)
{
ctxSrc.Flags &= ~EContext.FlagClamped;
}
ctxDest.Flags |= ctxSrc.Flags;
if ((ctxSrc.Flags & EContext.FlagSubnormal) != 0)
{
// Treat subnormal numbers as underflows
ctxDest.Flags |= EContext.FlagUnderflow |
EContext.FlagSubnormal | EContext.FlagInexact | EContext.FlagRounded;
}
}
}
if ((thisFlags & BigNumberFlags.FlagSpecial) != 0)
{
return((ctxDest.Flags == 0) ? this.SignalInvalid(ctxDest) : thisValue);
}
EInteger mant = this.GetHelper().GetMantissa(thisValue).Abs();
if (mant.IsZero)
{
return(afterQuantize ? this.GetHelper().CreateNewWithFlags(
mant,
this.GetHelper().GetExponent(thisValue),
0) : this.wrapper.RoundToPrecision(
this.GetHelper().ValueOf(0),
ctxDest));
}
if (afterQuantize)
{
return(thisValue);
}
EInteger exp = this.GetHelper().GetExponent(thisValue);
if (exp.Sign > 0)
{
FastInteger fastExp = FastInteger.FromBig(exp);
if (ctxDest == null || !ctxDest.HasMaxPrecision)
{
mant = this.GetHelper().MultiplyByRadixPower(mant, fastExp);
return(this.GetHelper().CreateNewWithFlags(
mant,
EInteger.Zero,
thisFlags));
}
if (!ctxDest.ExponentWithinRange(exp))
{
return(thisValue);
}
FastInteger prec = FastInteger.FromBig(ctxDest.Precision);
FastInteger digits = this.GetHelper().GetDigitLength(mant);
prec.Subtract(digits);
if (prec.Sign > 0 && prec.CompareTo(fastExp) >= 0)
{
mant = this.GetHelper().MultiplyByRadixPower(mant, fastExp);
return(this.GetHelper().CreateNewWithFlags(
mant,
EInteger.Zero,
thisFlags));
}
if (afterDivision)
{
int radix = this.GetHelper().GetRadix();
mant = NumberUtility.ReduceTrailingZeros(
mant,
fastExp,
radix,
null,
null,
null);
thisValue = this.GetHelper().CreateNewWithFlags(
mant,
fastExp.ToEInteger(),
thisFlags);
}
}
else if (afterDivision && exp.Sign < 0)
{
FastInteger fastExp = FastInteger.FromBig(exp);
int radix = this.GetHelper().GetRadix();
mant = NumberUtility.ReduceTrailingZeros(
mant, fastExp, radix, null, null, new FastInteger(0));
thisValue = this.GetHelper().CreateNewWithFlags(
mant,
fastExp.ToEInteger(),
thisFlags);
}
return(thisValue);
}