third_party/bigint/BigInteger.hh - pdfium - Git at Google

 // Copyright 2014 PDFium Authors. All rights reserved.
 // Use of this source code is governed by a BSD-style license that can be
 // found in the LICENSE file.

 // Original code by Matt McCutchen, see the LICENSE file.

 #ifndef BIGINTEGER_H
 #define BIGINTEGER_H

 #include "BigUnsigned.hh"

 /* A BigInteger object represents a signed integer of size limited only by
  * available memory.  BigUnsigneds support most mathematical operators and can
  * be converted to and from most primitive integer types.
  *
  * A BigInteger is just an aggregate of a BigUnsigned and a sign.  (It is no
  * longer derived from BigUnsigned because that led to harmful implicit
  * conversions.) */
 class BigInteger {

 public:
 	typedef BigUnsigned::Blk Blk;
 	typedef BigUnsigned::Index Index;
 	typedef BigUnsigned::CmpRes CmpRes;
 	static const CmpRes
 		less    = BigUnsigned::less   ,
 		equal   = BigUnsigned::equal  ,
 		greater = BigUnsigned::greater;
 	// Enumeration for the sign of a BigInteger.
 	enum Sign { negative = -1, zero = 0, positive = 1 };

 protected:
 	Sign sign;
 	BigUnsigned mag;

 public:
 	// Constructs zero.
 	BigInteger() : sign(zero), mag() {}

 	// Copy constructor
 	BigInteger(const BigInteger &x) : sign(x.sign), mag(x.mag) {};

 	// Assignment operator
 	void operator=(const BigInteger &x);

 	// Constructor that copies from a given array of blocks with a sign.
 	BigInteger(const Blk *b, Index blen, Sign s);

 	// Nonnegative constructor that copies from a given array of blocks.
 	BigInteger(const Blk *b, Index blen) : mag(b, blen) {
 		sign = mag.isZero() ? zero : positive;
 	}

 	// Constructor from a BigUnsigned and a sign
 	BigInteger(const BigUnsigned &x, Sign s);

 	// Nonnegative constructor from a BigUnsigned
 	BigInteger(const BigUnsigned &x) : mag(x) {
 		sign = mag.isZero() ? zero : positive;
 	}

 	// Constructors from primitive integer types
 	BigInteger(unsigned long  x);
 	BigInteger(         long  x);
 	BigInteger(unsigned int   x);
 	BigInteger(         int   x);
 	BigInteger(unsigned short x);
 	BigInteger(         short x);

 	/* Converters to primitive integer types
 	 * The implicit conversion operators caused trouble, so these are now
 	 * named. */
 	unsigned long  toUnsignedLong () const;
 	long           toLong         () const;
 	unsigned int   toUnsignedInt  () const;
 	int            toInt          () const;
 	unsigned short toUnsignedShort() const;
 	short          toShort        () const;
 protected:
 	// Helper
 	template <class X> X convertToUnsignedPrimitive() const;
 	template <class X, class UX> X convertToSignedPrimitive() const;
 public:

 	// ACCESSORS
 	Sign getSign() const { return sign; }
 	/* The client can't do any harm by holding a read-only reference to the
 	 * magnitude. */
 	const BigUnsigned &getMagnitude() const { return mag; }

 	// Some accessors that go through to the magnitude
 	Index getLength() const { return mag.getLength(); }
 	Index getCapacity() const { return mag.getCapacity(); }
 	Blk getBlock(Index i) const { return mag.getBlock(i); }
 	bool isZero() const { return sign == zero; } // A bit special

 	// COMPARISONS

 	// Compares this to x like Perl's <=>
 	CmpRes compareTo(const BigInteger &x) const;

 	// Ordinary comparison operators
 	bool operator ==(const BigInteger &x) const {
 		return sign == x.sign && mag == x.mag;
 	}
 	bool operator !=(const BigInteger &x) const { return !operator ==(x); };
 	bool operator < (const BigInteger &x) const { return compareTo(x) == less   ; }
 	bool operator <=(const BigInteger &x) const { return compareTo(x) != greater; }
 	bool operator >=(const BigInteger &x) const { return compareTo(x) != less   ; }
 	bool operator > (const BigInteger &x) const { return compareTo(x) == greater; }

 	// OPERATORS -- See the discussion in BigUnsigned.hh.
 	void add     (const BigInteger &a, const BigInteger &b);
 	void subtract(const BigInteger &a, const BigInteger &b);
 	void multiply(const BigInteger &a, const BigInteger &b);
 	/* See the comment on BigUnsigned::divideWithRemainder.  Semantics
 	 * differ from those of primitive integers when negatives and/or zeros
 	 * are involved. */
 	void divideWithRemainder(const BigInteger &b, BigInteger &q);
 	void negate(const BigInteger &a);

 	/* Bitwise operators are not provided for BigIntegers.  Use
 	 * getMagnitude to get the magnitude and operate on that instead. */

 	BigInteger operator +(const BigInteger &x) const;
 	BigInteger operator -(const BigInteger &x) const;
 	BigInteger operator *(const BigInteger &x) const;
 	BigInteger operator /(const BigInteger &x) const;
 	BigInteger operator %(const BigInteger &x) const;
 	BigInteger operator -() const;

 	void operator +=(const BigInteger &x);
 	void operator -=(const BigInteger &x);
 	void operator *=(const BigInteger &x);
 	void operator /=(const BigInteger &x);
 	void operator %=(const BigInteger &x);
 	void flipSign();

 	// INCREMENT/DECREMENT OPERATORS
 	void operator ++(   );
 	void operator ++(int);
 	void operator --(   );
 	void operator --(int);
 };

 // NORMAL OPERATORS
 /* These create an object to hold the result and invoke
  * the appropriate put-here operation on it, passing
  * this and x.  The new object is then returned. */
 inline BigInteger BigInteger::operator +(const BigInteger &x) const {
 	BigInteger ans;
 	ans.add(*this, x);
 	return ans;
 }
 inline BigInteger BigInteger::operator -(const BigInteger &x) const {
 	BigInteger ans;
 	ans.subtract(*this, x);
 	return ans;
 }
 inline BigInteger BigInteger::operator *(const BigInteger &x) const {
 	BigInteger ans;
 	ans.multiply(*this, x);
 	return ans;
 }
 inline BigInteger BigInteger::operator /(const BigInteger &x) const {
 	if (x.isZero())
         abort();
 	BigInteger q, r;
 	r = *this;
 	r.divideWithRemainder(x, q);
 	return q;
 }
 inline BigInteger BigInteger::operator %(const BigInteger &x) const {
 	if (x.isZero())
         abort();
 	BigInteger q, r;
 	r = *this;
 	r.divideWithRemainder(x, q);
 	return r;
 }
 inline BigInteger BigInteger::operator -() const {
 	BigInteger ans;
 	ans.negate(*this);
 	return ans;
 }

 /*
  * ASSIGNMENT OPERATORS
  *
  * Now the responsibility for making a temporary copy if necessary
  * belongs to the put-here operations.  See Assignment Operators in
  * BigUnsigned.hh.
  */
 inline void BigInteger::operator +=(const BigInteger &x) {
 	add(*this, x);
 }
 inline void BigInteger::operator -=(const BigInteger &x) {
 	subtract(*this, x);
 }
 inline void BigInteger::operator *=(const BigInteger &x) {
 	multiply(*this, x);
 }
 inline void BigInteger::operator /=(const BigInteger &x) {
 	if (x.isZero())
         abort();
 	/* The following technique is slightly faster than copying *this first
 	 * when x is large. */
 	BigInteger q;
 	divideWithRemainder(x, q);
 	// *this contains the remainder, but we overwrite it with the quotient.
 	*this = q;
 }
 inline void BigInteger::operator %=(const BigInteger &x) {
 	if (x.isZero())
         abort();
 	BigInteger q;
 	// Mods *this by x.  Don't care about quotient left in q.
 	divideWithRemainder(x, q);
 }
 // This one is trivial
 inline void BigInteger::flipSign() {
 	sign = Sign(-sign);
 }

 #endif
	// Copyright 2014 PDFium Authors. All rights reserved.
	// Use of this source code is governed by a BSD-style license that can be
	// found in the LICENSE file.

	// Original code by Matt McCutchen, see the LICENSE file.

	#ifndef BIGINTEGER_H
	#define BIGINTEGER_H

	#include "BigUnsigned.hh"

	/* A BigInteger object represents a signed integer of size limited only by
	* available memory. BigUnsigneds support most mathematical operators and can
	* be converted to and from most primitive integer types.
	*
	* A BigInteger is just an aggregate of a BigUnsigned and a sign. (It is no
	* longer derived from BigUnsigned because that led to harmful implicit
	* conversions.) */
	class BigInteger {

	public:
	typedef BigUnsigned::Blk Blk;
	typedef BigUnsigned::Index Index;
	typedef BigUnsigned::CmpRes CmpRes;
	static const CmpRes
	less = BigUnsigned::less ,
	equal = BigUnsigned::equal ,
	greater = BigUnsigned::greater;
	// Enumeration for the sign of a BigInteger.
	enum Sign { negative = -1, zero = 0, positive = 1 };

	protected:
	Sign sign;
	BigUnsigned mag;

	public:
	// Constructs zero.
	BigInteger() : sign(zero), mag() {}

	// Copy constructor
	BigInteger(const BigInteger &x) : sign(x.sign), mag(x.mag) {};

	// Assignment operator
	void operator=(const BigInteger &x);

	// Constructor that copies from a given array of blocks with a sign.
	BigInteger(const Blk *b, Index blen, Sign s);

	// Nonnegative constructor that copies from a given array of blocks.
	BigInteger(const Blk *b, Index blen) : mag(b, blen) {
	sign = mag.isZero() ? zero : positive;
	}

	// Constructor from a BigUnsigned and a sign
	BigInteger(const BigUnsigned &x, Sign s);

	// Nonnegative constructor from a BigUnsigned
	BigInteger(const BigUnsigned &x) : mag(x) {
	sign = mag.isZero() ? zero : positive;
	}

	// Constructors from primitive integer types
	BigInteger(unsigned long x);
	BigInteger( long x);
	BigInteger(unsigned int x);
	BigInteger( int x);
	BigInteger(unsigned short x);
	BigInteger( short x);

	/* Converters to primitive integer types
	* The implicit conversion operators caused trouble, so these are now
	* named. */
	unsigned long toUnsignedLong () const;
	long toLong () const;
	unsigned int toUnsignedInt () const;
	int toInt () const;
	unsigned short toUnsignedShort() const;
	short toShort () const;
	protected:
	// Helper
	template <class X> X convertToUnsignedPrimitive() const;
	template <class X, class UX> X convertToSignedPrimitive() const;
	public:

	// ACCESSORS
	Sign getSign() const { return sign; }
	/* The client can't do any harm by holding a read-only reference to the
	* magnitude. */
	const BigUnsigned &getMagnitude() const { return mag; }

	// Some accessors that go through to the magnitude
	Index getLength() const { return mag.getLength(); }
	Index getCapacity() const { return mag.getCapacity(); }
	Blk getBlock(Index i) const { return mag.getBlock(i); }
	bool isZero() const { return sign == zero; } // A bit special

	// COMPARISONS

	// Compares this to x like Perl's <=>
	CmpRes compareTo(const BigInteger &x) const;

	// Ordinary comparison operators
	bool operator ==(const BigInteger &x) const {
	return sign == x.sign && mag == x.mag;
	}
	bool operator !=(const BigInteger &x) const { return !operator ==(x); };
	bool operator < (const BigInteger &x) const { return compareTo(x) == less ; }
	bool operator <=(const BigInteger &x) const { return compareTo(x) != greater; }
	bool operator >=(const BigInteger &x) const { return compareTo(x) != less ; }
	bool operator > (const BigInteger &x) const { return compareTo(x) == greater; }

	// OPERATORS -- See the discussion in BigUnsigned.hh.
	void add (const BigInteger &a, const BigInteger &b);
	void subtract(const BigInteger &a, const BigInteger &b);
	void multiply(const BigInteger &a, const BigInteger &b);
	/* See the comment on BigUnsigned::divideWithRemainder. Semantics
	* differ from those of primitive integers when negatives and/or zeros
	* are involved. */
	void divideWithRemainder(const BigInteger &b, BigInteger &q);
	void negate(const BigInteger &a);

	/* Bitwise operators are not provided for BigIntegers. Use
	* getMagnitude to get the magnitude and operate on that instead. */

	BigInteger operator +(const BigInteger &x) const;
	BigInteger operator -(const BigInteger &x) const;
	BigInteger operator *(const BigInteger &x) const;
	BigInteger operator /(const BigInteger &x) const;
	BigInteger operator %(const BigInteger &x) const;
	BigInteger operator -() const;

	void operator +=(const BigInteger &x);
	void operator -=(const BigInteger &x);
	void operator *=(const BigInteger &x);
	void operator /=(const BigInteger &x);
	void operator %=(const BigInteger &x);
	void flipSign();

	// INCREMENT/DECREMENT OPERATORS
	void operator ++( );
	void operator ++(int);
	void operator --( );
	void operator --(int);
	};

	// NORMAL OPERATORS
	/* These create an object to hold the result and invoke
	* the appropriate put-here operation on it, passing
	* this and x. The new object is then returned. */
	inline BigInteger BigInteger::operator +(const BigInteger &x) const {
	BigInteger ans;
	ans.add(*this, x);
	return ans;
	}
	inline BigInteger BigInteger::operator -(const BigInteger &x) const {
	BigInteger ans;
	ans.subtract(*this, x);
	return ans;
	}
	inline BigInteger BigInteger::operator *(const BigInteger &x) const {
	BigInteger ans;
	ans.multiply(*this, x);
	return ans;
	}
	inline BigInteger BigInteger::operator /(const BigInteger &x) const {
	if (x.isZero())
	abort();
	BigInteger q, r;
	r = *this;
	r.divideWithRemainder(x, q);
	return q;
	}
	inline BigInteger BigInteger::operator %(const BigInteger &x) const {
	if (x.isZero())
	abort();
	BigInteger q, r;
	r = *this;
	r.divideWithRemainder(x, q);
	return r;
	}
	inline BigInteger BigInteger::operator -() const {
	BigInteger ans;
	ans.negate(*this);
	return ans;
	}

	/*
	* ASSIGNMENT OPERATORS
	*
	* Now the responsibility for making a temporary copy if necessary
	* belongs to the put-here operations. See Assignment Operators in
	* BigUnsigned.hh.
	*/
	inline void BigInteger::operator +=(const BigInteger &x) {
	add(*this, x);
	}
	inline void BigInteger::operator -=(const BigInteger &x) {
	subtract(*this, x);
	}
	inline void BigInteger::operator *=(const BigInteger &x) {
	multiply(*this, x);
	}
	inline void BigInteger::operator /=(const BigInteger &x) {
	if (x.isZero())
	abort();
	/* The following technique is slightly faster than copying *this first
	* when x is large. */
	BigInteger q;
	divideWithRemainder(x, q);
	// *this contains the remainder, but we overwrite it with the quotient.
	*this = q;
	}
	inline void BigInteger::operator %=(const BigInteger &x) {
	if (x.isZero())
	abort();
	BigInteger q;
	// Mods *this by x. Don't care about quotient left in q.
	divideWithRemainder(x, q);
	}
	// This one is trivial
	inline void BigInteger::flipSign() {
	sign = Sign(-sign);
	}

	#endif