forked from KolibriOS/kolibrios
182 lines
6.6 KiB
C++
182 lines
6.6 KiB
C++
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#ifndef __numbers_h__
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#define __numbers_h__
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#include "lispenvironment.h"
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#include "yacasbase.h"
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/// Whether the numeric library supports 1.0E-10 and such.
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LispInt NumericSupportForMantissa();
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LispObject* GcdInteger(LispObject* int1, LispObject* int2, LispEnvironment& aEnvironment);
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LispObject* SinFloat(LispObject* int1, LispEnvironment& aEnvironment,LispInt aPrecision);
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LispObject* CosFloat(LispObject* int1, LispEnvironment& aEnvironment,LispInt aPrecision);
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LispObject* TanFloat(LispObject* int1, LispEnvironment& aEnvironment,LispInt aPrecision);
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LispObject* ArcSinFloat(LispObject* int1, LispEnvironment& aEnvironment,LispInt aPrecision);
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LispObject* ExpFloat(LispObject* int1, LispEnvironment& aEnvironment,LispInt aPrecision);
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LispObject* LnFloat(LispObject* int1, LispEnvironment& aEnvironment,LispInt aPrecision);
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LispObject* SqrtFloat(LispObject* int1, LispEnvironment& aEnvironment,LispInt aPrecision);
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LispObject* ModFloat( LispObject* int1, LispObject* int2, LispEnvironment& aEnvironment,
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LispInt aPrecision);
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LispObject* PowerFloat(LispObject* int1, LispObject* int2,
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LispEnvironment& aEnvironment,LispInt aPrecision);
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LispObject* ShiftLeft( LispObject* int1, LispObject* int2, LispEnvironment& aEnvironment,LispInt aPrecision);
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LispObject* ShiftRight( LispObject* int1, LispObject* int2, LispEnvironment& aEnvironment,LispInt aPrecision);
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LispObject* LispFactorial(LispObject* int1, LispEnvironment& aEnvironment,LispInt aPrecision);
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// methods generally useful for all numeric libraries
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const unsigned GUARD_BITS = 8; // we leave this many guard bits untruncated in various situations when we need to truncate precision by hand
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template<class T> inline T MAX(T x, T y) { if (x<y) return y; else return x; }
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template<class T> inline T MIN(T x, T y) { if (x>y) return y; else return x; }
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const long DIST_BITS = 1; // at least this many bits of difference - used in precision tracking
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/// DIST(x, y) returns 1 if abs(x-y) >= DIST_BITS. See documentation for precision tracking.
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template<class T> inline T DIST(T x, T y) { return (x>=y+DIST_BITS || y>=x+DIST_BITS) ? 0 : 1; }
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/** Base number class.
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*/
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class ANumber;
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/// Main class for multiple-precision arithmetic.
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/// All calculations are done at given precision. Integers grow as needed, floats don't grow beyond given precision.
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class BigNumber : public YacasBase
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{
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public: //constructors
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BigNumber(const LispChar * aString,LispInt aPrecision,LispInt aBase=10);
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/// copy constructor
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BigNumber(const BigNumber& aOther);
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// no constructors from int or double to avoid automatic conversions
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BigNumber(LispInt aPrecision = 20);
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~BigNumber();
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// assign from another number
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void SetTo(const BigNumber& aOther);
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// assign from string, precision in base digits
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void SetTo(const LispChar * aString,LispInt aPrecision,LispInt aBase=10);
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// assign from a platform type
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void SetTo(long value);
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inline void SetTo(LispInt value) { SetTo(long(value)); };
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void SetTo(double value);
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public: // Convert back to other types
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/// ToString : return string representation of number in aResult to given precision (base digits)
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void ToString(LispString& aResult, LispInt aPrecision, LispInt aBase=10) const;
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/// Give approximate representation as a double number
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double Double() const;
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public://basic object manipulation
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LispBoolean Equals(const BigNumber& aOther) const;
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LispBoolean IsInt() const;
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LispBoolean IsIntValue() const;
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LispBoolean IsSmall() const;
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void BecomeInt();
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void BecomeFloat(LispInt aPrecision=0);
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LispBoolean LessThan(const BigNumber& aOther) const;
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public://arithmetic
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/// Multiply two numbers at given precision and put result in *this
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void Multiply(const BigNumber& aX, const BigNumber& aY, LispInt aPrecision);
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/** Multiply two numbers, and add to *this (this is useful and generally efficient to implement).
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* This is most likely going to be used by internal functions only, using aResult as an accumulator.
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*/
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void MultiplyAdd(const BigNumber& aX, const BigNumber& aY, LispInt aPrecision);
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/// Add two numbers at given precision and return result in *this
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void Add(const BigNumber& aX, const BigNumber& aY, LispInt aPrecision);
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/// Negate the given number, return result in *this
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void Negate(const BigNumber& aX);
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/// Divide two numbers and return result in *this. Note: if the two arguments are integer, it should return an integer result!
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void Divide(const BigNumber& aX, const BigNumber& aY, LispInt aPrecision);
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/// integer operation: *this = y mod z
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void Mod(const BigNumber& aY, const BigNumber& aZ);
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/// For debugging purposes, dump internal state of this object into a string
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void DumpDebugInfo();
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public:
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/// assign self to Floor(aX) if possible
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void Floor(const BigNumber& aX);
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/// set precision (in bits)
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void Precision(LispInt aPrecision);
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public:/// Bitwise operations, return result in *this.
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void ShiftLeft( const BigNumber& aX, LispInt aNrToShift);
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void ShiftRight( const BigNumber& aX, LispInt aNrToShift);
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void BitAnd(const BigNumber& aX, const BigNumber& aY);
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void BitOr(const BigNumber& aX, const BigNumber& aY);
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void BitXor(const BigNumber& aX, const BigNumber& aY);
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void BitNot(const BigNumber& aX);
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/// Bit count operation: return the number of significant bits if integer, return the binary exponent if float (shortcut for binary logarithm)
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/// give bit count as a platform integer
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signed long BitCount() const;
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/// Give sign (-1, 0, 1)
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LispInt Sign() const;
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public:
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inline LispInt GetPrecision() const {return iPrecision;};
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private:
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BigNumber& operator=(const BigNumber& aOther)
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{
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// copy constructor not written yet, hence the assert
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LISPASSERT(0);
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return *this;
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}
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public:
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ReferenceCount iReferenceCount;
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private:
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LispInt iPrecision;
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public:
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/// Internal library wrapper starts here.
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inline void SetIsInteger(LispBoolean aIsInteger) {iType = (aIsInteger ? KInt : KFloat);}
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enum ENumType
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{
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KInt = 0,
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KFloat
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};
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ENumType iType;
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ANumber* iNumber;
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/// Internal library wrapper ends here.
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};
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/// bits_to_digits and digits_to_bits, utility functions
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/// to convert the number of digits in some base (usually 10) to bits and back
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// lookup table for Ln(n)/Ln(2). This works whether or not we have math.h.
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// table range is from 2 to this value:
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unsigned log2_table_range();
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// convert the number of digits in given base to the number of bits, and back.
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// need to round the number of digits.
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// These functions only work for aBase inside the allowed table range.
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unsigned long digits_to_bits(unsigned long aDigits, unsigned aBase);
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unsigned long bits_to_digits(unsigned long abits, unsigned aBase);
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#endif
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